ScalingIntelligence/swe-bench-verified-codebase-content

hash stringlengths 64 64	content stringlengths 0 1.51M
215f5f73b2075562ae87610060003ef7bdba266813666636542a14607377e7f2	from __future__ import print_function, division from sympy.core.sympify import _sympify from sympy.core import S, Basic from sympy.matrices.expressions.matexpr import ShapeError from sympy.matrices.expressions.matpow import MatPow class Inverse(MatPow): """ The multiplicative inverse of a matrix expression This is a symbolic object that simply stores its argument without evaluating it. To actually compute the inverse, use the ``.inverse()`` method of matrices. Examples ======== >>> from sympy import MatrixSymbol, Inverse >>> A = MatrixSymbol('A', 3, 3) >>> B = MatrixSymbol('B', 3, 3) >>> Inverse(A) A*(-1) >>> A.inverse() == Inverse(A) True >>> (AB).inverse() B*(-1)A*(-1) >>> Inverse(AB) (AB)(-1) """ is_Inverse = True exp = S(-1) def __new__(cls, mat, exp=S(-1)): # exp is there to make it consistent with # inverse.func(inverse.args) == inverse mat = _sympify(mat) if not mat.is_Matrix: raise TypeError("mat should be a matrix") if not mat.is_square: raise ShapeError("Inverse of non-square matrix %s" % mat) return Basic.__new__(cls, mat, exp) @property def arg(self): return self.args[0] @property def shape(self): return self.arg.shape def _eval_inverse(self): return self.arg def _eval_determinant(self): from sympy.matrices.expressions.determinant import det return 1/det(self.arg) def doit(self, hints): if 'inv_expand' in hints and hints['inv_expand'] == False: return self if hints.get('deep', True): return self.arg.doit(hints).inverse() else: return self.arg.inverse() def _eval_derivative_matrix_lines(self, x): arg = self.args[0] lines = arg._eval_derivative_matrix_lines(x) for line in lines: line.first_pointer = -self.T line.second_pointer = self return lines from sympy.assumptions.ask import ask, Q from sympy.assumptions.refine import handlers_dict def refine_Inverse(expr, assumptions): """ >>> from sympy import MatrixSymbol, Q, assuming, refine >>> X = MatrixSymbol('X', 2, 2) >>> X.I X**(-1) >>> with assuming(Q.orthogonal(X)): ... print(refine(X.I)) X.T """ if ask(Q.orthogonal(expr), assumptions): return expr.arg.T elif ask(Q.unitary(expr), assumptions): return expr.arg.conjugate() elif ask(Q.singular(expr), assumptions): raise ValueError("Inverse of singular matrix %s" % expr.arg) return expr handlers_dict['Inverse'] = refine_Inverse
a39d18890036bc8abf86fcdbdac876544a11fca59716a318146301db76251b15	""" A module which handles Matrix Expressions """ from .slice import MatrixSlice from .blockmatrix import BlockMatrix, BlockDiagMatrix, block_collapse, blockcut from .funcmatrix import FunctionMatrix from .inverse import Inverse from .matadd import MatAdd from .matexpr import (Identity, MatrixExpr, MatrixSymbol, ZeroMatrix, matrix_symbols) from .matmul import MatMul from .matpow import MatPow from .trace import Trace, trace from .determinant import Determinant, det from .transpose import Transpose from .adjoint import Adjoint from .hadamard import hadamard_product, HadamardProduct, hadamard_power, HadamardPower from .diagonal import DiagonalMatrix, DiagonalOf, DiagonalizeVector, diagonalize_vector from .dotproduct import DotProduct from .kronecker import kronecker_product, KroneckerProduct, combine_kronecker
82671b9e3ca44ec0dd8460e47ec71764c92bfa0f750102d52aedce74f6435634	from __future__ import print_function, division from sympy import Basic from sympy.functions import adjoint, conjugate from sympy.matrices.expressions.matexpr import MatrixExpr class Transpose(MatrixExpr): """ The transpose of a matrix expression. This is a symbolic object that simply stores its argument without evaluating it. To actually compute the transpose, use the ``transpose()`` function, or the ``.T`` attribute of matrices. Examples ======== >>> from sympy.matrices import MatrixSymbol, Transpose >>> from sympy.functions import transpose >>> A = MatrixSymbol('A', 3, 5) >>> B = MatrixSymbol('B', 5, 3) >>> Transpose(A) A.T >>> A.T == transpose(A) == Transpose(A) True >>> Transpose(AB) (AB).T >>> transpose(AB) B.TA.T """ is_Transpose = True def doit(self, hints): arg = self.arg if hints.get('deep', True) and isinstance(arg, Basic): arg = arg.doit(hints) _eval_transpose = getattr(arg, '_eval_transpose', None) if _eval_transpose is not None: result = _eval_transpose() return result if result is not None else Transpose(arg) else: return Transpose(arg) @property def arg(self): return self.args[0] @property def shape(self): return self.arg.shape[::-1] def _entry(self, i, j, expand=False): return self.arg._entry(j, i, expand=expand) def _eval_adjoint(self): return conjugate(self.arg) def _eval_conjugate(self): return adjoint(self.arg) def _eval_transpose(self): return self.arg def _eval_trace(self): from .trace import Trace return Trace(self.arg) # Trace(X.T) => Trace(X) def _eval_determinant(self): from sympy.matrices.expressions.determinant import det return det(self.arg) def _eval_derivative_matrix_lines(self, x): lines = self.args[0]._eval_derivative_matrix_lines(x) return [i.transpose() for i in lines] def transpose(expr): """Matrix transpose""" return Transpose(expr).doit(deep=False) from sympy.assumptions.ask import ask, Q from sympy.assumptions.refine import handlers_dict def refine_Transpose(expr, assumptions): """ >>> from sympy import MatrixSymbol, Q, assuming, refine >>> X = MatrixSymbol('X', 2, 2) >>> X.T X.T >>> with assuming(Q.symmetric(X)): ... print(refine(X.T)) X """ if ask(Q.symmetric(expr), assumptions): return expr.arg return expr handlers_dict['Transpose'] = refine_Transpose
450b2af2a85ce4bd71a1106c6c43753f89cb2565969a9aaea6c1bc36335c933b	from __future__ import print_function, division from sympy import Number from sympy.core import Mul, Basic, sympify from sympy.core.compatibility import range from sympy.functions import adjoint from sympy.matrices.expressions.transpose import transpose from sympy.strategies import (rm_id, unpack, typed, flatten, exhaust, do_one, new) from sympy.matrices.expressions.matexpr import (MatrixExpr, ShapeError, Identity, ZeroMatrix, GenericIdentity) from sympy.matrices.expressions.matpow import MatPow from sympy.matrices.matrices import MatrixBase # XXX: MatMul should perhaps not subclass directly from Mul class MatMul(MatrixExpr, Mul): """ A product of matrix expressions Examples ======== >>> from sympy import MatMul, MatrixSymbol >>> A = MatrixSymbol('A', 5, 4) >>> B = MatrixSymbol('B', 4, 3) >>> C = MatrixSymbol('C', 3, 6) >>> MatMul(A, B, C) ABC """ is_MatMul = True def __new__(cls, args, kwargs): check = kwargs.get('check', True) if not args: return GenericIdentity() # This must be removed aggressively in the constructor to avoid # TypeErrors from GenericIdentity().shape args = filter(lambda i: GenericIdentity() != i, args) args = list(map(sympify, args)) obj = Basic.__new__(cls, args) factor, matrices = obj.as_coeff_matrices() if check: validate(matrices) if not matrices: # Should it be # # return Basic.__neq__(cls, factor, GenericIdentity()) ? return factor return obj @property def shape(self): matrices = [arg for arg in self.args if arg.is_Matrix] return (matrices[0].rows, matrices[-1].cols) def _entry(self, i, j, expand=True): from sympy import Dummy, Sum, Mul, ImmutableMatrix, Integer coeff, matrices = self.as_coeff_matrices() if len(matrices) == 1: # situation like 2X, matmul is just X return coeff * matrices[0][i, j] indices = [None](len(matrices) + 1) ind_ranges = [None](len(matrices) - 1) indices[0] = i indices[-1] = j for i in range(1, len(matrices)): indices[i] = Dummy("i_%i" % i) for i, arg in enumerate(matrices[:-1]): ind_ranges[i] = arg.shape[1] - 1 matrices = [arg[indices[i], indices[i+1]] for i, arg in enumerate(matrices)] expr_in_sum = Mul.fromiter(matrices) if any(v.has(ImmutableMatrix) for v in matrices): expand = True result = coeffSum( expr_in_sum, zip(indices[1:-1], [0]len(ind_ranges), ind_ranges) ) # Don't waste time in result.doit() if the sum bounds are symbolic if not any(isinstance(v, (Integer, int)) for v in ind_ranges): expand = False return result.doit() if expand else result def as_coeff_matrices(self): scalars = [x for x in self.args if not x.is_Matrix] matrices = [x for x in self.args if x.is_Matrix] coeff = Mul(scalars) if coeff.is_commutative is False: raise NotImplementedError("noncommutative scalars in MatMul are not supported.") return coeff, matrices def as_coeff_mmul(self): coeff, matrices = self.as_coeff_matrices() return coeff, MatMul(matrices) def _eval_transpose(self): return MatMul([transpose(arg) for arg in self.args[::-1]]).doit() def _eval_adjoint(self): return MatMul([adjoint(arg) for arg in self.args[::-1]]).doit() def _eval_trace(self): factor, mmul = self.as_coeff_mmul() if factor != 1: from .trace import trace return factor trace(mmul.doit()) else: raise NotImplementedError("Can't simplify any further") def _eval_determinant(self): from sympy.matrices.expressions.determinant import Determinant factor, matrices = self.as_coeff_matrices() square_matrices = only_squares(matrices) return factorself.rows Mul(list(map(Determinant, square_matrices))) def _eval_inverse(self): try: return MatMul([ arg.inverse() if isinstance(arg, MatrixExpr) else arg-1 for arg in self.args[::-1]]).doit() except ShapeError: from sympy.matrices.expressions.inverse import Inverse return Inverse(self) def doit(self, kwargs): deep = kwargs.get('deep', True) if deep: args = [arg.doit(*kwargs) for arg in self.args] else: args = self.args # treat scalarMatrixSymbol or scalarMatPow separately mats = [arg for arg in self.args if arg.is_Matrix] expr = canonicalize(MatMul(args)) return expr # Needed for partial compatibility with Mul def args_cnc(self, *kwargs): coeff_c = [x for x in self.args if x.is_commutative] coeff_nc = [x for x in self.args if not x.is_commutative] return [coeff_c, coeff_nc] def _eval_derivative_matrix_lines(self, x): from .transpose import Transpose with_x_ind = [i for i, arg in enumerate(self.args) if arg.has(x)] lines = [] for ind in with_x_ind: left_args = self.args[:ind] right_args = self.args[ind+1:] right_mat = MatMul.fromiter(right_args) left_rev = MatMul.fromiter([Transpose(i).doit() if i.is_Matrix else i for i in reversed(left_args)]) d = self.args[ind]._eval_derivative_matrix_lines(x) for i in d: i.append_first(left_rev) i.append_second(right_mat) lines.append(i) return lines def validate(matrices): """ Checks for valid shapes for args of MatMul """ for i in range(len(matrices)-1): A, B = matrices[i:i+2] if A.cols != B.rows: raise ShapeError("Matrices %s and %s are not aligned"%(A, B)) # Rules def newmul(args): if args[0] == 1: args = args[1:] return new(MatMul, args) def any_zeros(mul): if any([arg.is_zero or (arg.is_Matrix and arg.is_ZeroMatrix) for arg in mul.args]): matrices = [arg for arg in mul.args if arg.is_Matrix] return ZeroMatrix(matrices[0].rows, matrices[-1].cols) return mul def merge_explicit(matmul): """ Merge explicit MatrixBase arguments >>> from sympy import MatrixSymbol, eye, Matrix, MatMul, pprint >>> from sympy.matrices.expressions.matmul import merge_explicit >>> A = MatrixSymbol('A', 2, 2) >>> B = Matrix([[1, 1], [1, 1]]) >>> C = Matrix([[1, 2], [3, 4]]) >>> X = MatMul(A, B, C) >>> pprint(X) [1 1] [1 2] A[ ][ ] [1 1] [3 4] >>> pprint(merge_explicit(X)) [4 6] A[ ] [4 6] >>> X = MatMul(B, A, C) >>> pprint(X) [1 1] [1 2] [ ]A[ ] [1 1] [3 4] >>> pprint(merge_explicit(X)) [1 1] [1 2] [ ]A[ ] [1 1] [3 4] """ if not any(isinstance(arg, MatrixBase) for arg in matmul.args): return matmul newargs = [] last = matmul.args[0] for arg in matmul.args[1:]: if isinstance(arg, (MatrixBase, Number)) and isinstance(last, (MatrixBase, Number)): last = last arg else: newargs.append(last) last = arg newargs.append(last) return MatMul(newargs) def xxinv(mul): """ Y X * X.I -> Y """ from sympy.matrices.expressions.inverse import Inverse factor, matrices = mul.as_coeff_matrices() for i, (X, Y) in enumerate(zip(matrices[:-1], matrices[1:])): try: if X.is_square and Y.is_square: _X, x_exp = X, 1 _Y, y_exp = Y, 1 if isinstance(X, MatPow) and not isinstance(X, Inverse): _X, x_exp = X.args if isinstance(Y, MatPow) and not isinstance(Y, Inverse): _Y, y_exp = Y.args if _X == _Y.inverse(): if x_exp - y_exp > 0: I = _X(x_exp-y_exp) else: I = _Y(y_exp-x_exp) return newmul(factor, (matrices[:i] + [I] + matrices[i+2:])) except ValueError: # Y might not be invertible pass return mul def remove_ids(mul): """ Remove Identities from a MatMul This is a modified version of sympy.strategies.rm_id. This is necesssary because MatMul may contain both MatrixExprs and Exprs as args. See Also ======== sympy.strategies.rm_id """ # Separate Exprs from MatrixExprs in args factor, mmul = mul.as_coeff_mmul() # Apply standard rm_id for MatMuls result = rm_id(lambda x: x.is_Identity is True)(mmul) if result != mmul: return newmul(factor, result.args) # Recombine and return else: return mul def factor_in_front(mul): factor, matrices = mul.as_coeff_matrices() if factor != 1: return newmul(factor, matrices) return mul def combine_powers(mul): # combine consecutive powers with the same base into one # e.g. AA2 -> A3 from sympy.matrices.expressions import MatPow factor, mmul = mul.as_coeff_mmul() args = [] base = None exp = 0 for arg in mmul.args: if isinstance(arg, MatPow): current_base = arg.args[0] current_exp = arg.args[1] else: current_base = arg current_exp = 1 if current_base == base: exp += current_exp else: if not base is None: if exp == 1: args.append(base) else: args.append(baseexp) exp = current_exp base = current_base if exp == 1: args.append(base) else: args.append(baseexp) return newmul(factor, args) rules = (any_zeros, remove_ids, xxinv, unpack, rm_id(lambda x: x == 1), merge_explicit, factor_in_front, flatten, combine_powers) canonicalize = exhaust(typed({MatMul: do_one(rules)})) def only_squares(matrices): """factor matrices only if they are square""" if matrices[0].rows != matrices[-1].cols: raise RuntimeError("Invalid matrices being multiplied") out = [] start = 0 for i, M in enumerate(matrices): if M.cols == matrices[start].rows: out.append(MatMul(matrices[start:i+1]).doit()) start = i+1 return out from sympy.assumptions.ask import ask, Q from sympy.assumptions.refine import handlers_dict def refine_MatMul(expr, assumptions): """ >>> from sympy import MatrixSymbol, Q, assuming, refine >>> X = MatrixSymbol('X', 2, 2) >>> expr = X * X.T >>> print(expr) XX.T >>> with assuming(Q.orthogonal(X)): ... print(refine(expr)) I """ newargs = [] exprargs = [] for args in expr.args: if args.is_Matrix: exprargs.append(args) else: newargs.append(args) last = exprargs[0] for arg in exprargs[1:]: if arg == last.T and ask(Q.orthogonal(arg), assumptions): last = Identity(arg.shape[0]) elif arg == last.conjugate() and ask(Q.unitary(arg), assumptions): last = Identity(arg.shape[0]) else: newargs.append(last) last = arg newargs.append(last) return MatMul(newargs) handlers_dict['MatMul'] = refine_MatMul
5b5a396990f223948d1ad4d9b61f9e361592baad115fc4a54f1f7ccee9f225c9	from __future__ import print_function, division from functools import wraps, reduce import collections from sympy.core import S, Symbol, Tuple, Integer, Basic, Expr, Eq, Mul, Add from sympy.core.decorators import call_highest_priority from sympy.core.compatibility import range, SYMPY_INTS, default_sort_key, string_types from sympy.core.sympify import SympifyError, _sympify from sympy.functions import conjugate, adjoint from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.matrices import ShapeError from sympy.simplify import simplify from sympy.utilities.misc import filldedent def _sympifyit(arg, retval=None): # This version of _sympifyit sympifies MutableMatrix objects def deco(func): @wraps(func) def __sympifyit_wrapper(a, b): try: b = _sympify(b) return func(a, b) except SympifyError: return retval return __sympifyit_wrapper return deco class MatrixExpr(Expr): """Superclass for Matrix Expressions MatrixExprs represent abstract matrices, linear transformations represented within a particular basis. Examples ======== >>> from sympy import MatrixSymbol >>> A = MatrixSymbol('A', 3, 3) >>> y = MatrixSymbol('y', 3, 1) >>> x = (A.TA).I A * y See Also ======== MatrixSymbol, MatAdd, MatMul, Transpose, Inverse """ # Should not be considered iterable by the # sympy.core.compatibility.iterable function. Subclass that actually are # iterable (i.e., explicit matrices) should set this to True. _iterable = False _op_priority = 11.0 is_Matrix = True is_MatrixExpr = True is_Identity = None is_Inverse = False is_Transpose = False is_ZeroMatrix = False is_MatAdd = False is_MatMul = False is_commutative = False is_number = False is_symbol = False def __new__(cls, args, kwargs): args = map(_sympify, args) return Basic.__new__(cls, args, *kwargs) # The following is adapted from the core Expr object def __neg__(self): return MatMul(S.NegativeOne, self).doit() def __abs__(self): raise NotImplementedError @_sympifyit('other', NotImplemented) @call_highest_priority('__radd__') def __add__(self, other): return MatAdd(self, other, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__add__') def __radd__(self, other): return MatAdd(other, self, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rsub__') def __sub__(self, other): return MatAdd(self, -other, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__sub__') def __rsub__(self, other): return MatAdd(other, -self, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rmul__') def __mul__(self, other): return MatMul(self, other).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rmul__') def __matmul__(self, other): return MatMul(self, other).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__mul__') def __rmul__(self, other): return MatMul(other, self).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__mul__') def __rmatmul__(self, other): return MatMul(other, self).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rpow__') def __pow__(self, other): if not self.is_square: raise ShapeError("Power of non-square matrix %s" % self) elif self.is_Identity: return self elif other is S.Zero: return Identity(self.rows) elif other is S.One: return self return MatPow(self, other).doit(deep=False) @_sympifyit('other', NotImplemented) @call_highest_priority('__pow__') def __rpow__(self, other): raise NotImplementedError("Matrix Power not defined") @_sympifyit('other', NotImplemented) @call_highest_priority('__rdiv__') def __div__(self, other): return self other*S.NegativeOne @_sympifyit('other', NotImplemented) @call_highest_priority('__div__') def __rdiv__(self, other): raise NotImplementedError() #return MatMul(other, Pow(self, S.NegativeOne)) __truediv__ = __div__ __rtruediv__ = __rdiv__ @property def rows(self): return self.shape[0] @property def cols(self): return self.shape[1] @property def is_square(self): return self.rows == self.cols def _eval_conjugate(self): from sympy.matrices.expressions.adjoint import Adjoint from sympy.matrices.expressions.transpose import Transpose return Adjoint(Transpose(self)) def as_real_imag(self): from sympy import I real = (S(1)/2) (self + self._eval_conjugate()) im = (self - self._eval_conjugate())/(2I) return (real, im) def _eval_inverse(self): from sympy.matrices.expressions.inverse import Inverse return Inverse(self) def _eval_transpose(self): return Transpose(self) def _eval_power(self, exp): return MatPow(self, exp) def _eval_simplify(self, kwargs): if self.is_Atom: return self else: return self.__class__([simplify(x, *kwargs) for x in self.args]) def _eval_adjoint(self): from sympy.matrices.expressions.adjoint import Adjoint return Adjoint(self) def _eval_derivative(self, x): return _matrix_derivative(self, x) def _eval_derivative_n_times(self, x, n): return Basic._eval_derivative_n_times(self, x, n) def _visit_eval_derivative_scalar(self, x): # `x` is a scalar: if x.has(self): return _matrix_derivative(x, self) else: return ZeroMatrix(self.shape) def _visit_eval_derivative_array(self, x): if x.has(self): return _matrix_derivative(x, self) else: from sympy import Derivative return Derivative(x, self) def _accept_eval_derivative(self, s): return s._visit_eval_derivative_array(self) def _entry(self, i, j, *kwargs): raise NotImplementedError( "Indexing not implemented for %s" % self.__class__.__name__) def adjoint(self): return adjoint(self) def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ return S.One, self def conjugate(self): return conjugate(self) def transpose(self): from sympy.matrices.expressions.transpose import transpose return transpose(self) T = property(transpose, None, None, 'Matrix transposition.') def inverse(self): return self._eval_inverse() inv = inverse @property def I(self): return self.inverse() def valid_index(self, i, j): def is_valid(idx): return isinstance(idx, (int, Integer, Symbol, Expr)) return (is_valid(i) and is_valid(j) and (self.rows is None or (0 <= i) != False and (i < self.rows) != False) and (0 <= j) != False and (j < self.cols) != False) def __getitem__(self, key): if not isinstance(key, tuple) and isinstance(key, slice): from sympy.matrices.expressions.slice import MatrixSlice return MatrixSlice(self, key, (0, None, 1)) if isinstance(key, tuple) and len(key) == 2: i, j = key if isinstance(i, slice) or isinstance(j, slice): from sympy.matrices.expressions.slice import MatrixSlice return MatrixSlice(self, i, j) i, j = _sympify(i), _sympify(j) if self.valid_index(i, j) != False: return self._entry(i, j) else: raise IndexError("Invalid indices (%s, %s)" % (i, j)) elif isinstance(key, (SYMPY_INTS, Integer)): # row-wise decomposition of matrix rows, cols = self.shape # allow single indexing if number of columns is known if not isinstance(cols, Integer): raise IndexError(filldedent(''' Single indexing is only supported when the number of columns is known.''')) key = _sympify(key) i = key // cols j = key % cols if self.valid_index(i, j) != False: return self._entry(i, j) else: raise IndexError("Invalid index %s" % key) elif isinstance(key, (Symbol, Expr)): raise IndexError(filldedent(''' Only integers may be used when addressing the matrix with a single index.''')) raise IndexError("Invalid index, wanted %s[i,j]" % self) def as_explicit(self): """ Returns a dense Matrix with elements represented explicitly Returns an object of type ImmutableDenseMatrix. Examples ======== >>> from sympy import Identity >>> I = Identity(3) >>> I I >>> I.as_explicit() Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) See Also ======== as_mutable: returns mutable Matrix type """ from sympy.matrices.immutable import ImmutableDenseMatrix return ImmutableDenseMatrix([[ self[i, j] for j in range(self.cols)] for i in range(self.rows)]) def as_mutable(self): """ Returns a dense, mutable matrix with elements represented explicitly Examples ======== >>> from sympy import Identity >>> I = Identity(3) >>> I I >>> I.shape (3, 3) >>> I.as_mutable() Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) See Also ======== as_explicit: returns ImmutableDenseMatrix """ return self.as_explicit().as_mutable() def __array__(self): from numpy import empty a = empty(self.shape, dtype=object) for i in range(self.rows): for j in range(self.cols): a[i, j] = self[i, j] return a def equals(self, other): """ Test elementwise equality between matrices, potentially of different types >>> from sympy import Identity, eye >>> Identity(3).equals(eye(3)) True """ return self.as_explicit().equals(other) def canonicalize(self): return self def as_coeff_mmul(self): return 1, MatMul(self) @staticmethod def from_index_summation(expr, first_index=None, last_index=None, dimensions=None): r""" Parse expression of matrices with explicitly summed indices into a matrix expression without indices, if possible. This transformation expressed in mathematical notation: `\sum_{j=0}^{N-1} A_{i,j} B_{j,k} \Longrightarrow \mathbf{A}\cdot \mathbf{B}` Optional parameter ``first_index``: specify which free index to use as the index starting the expression. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> expr = Sum(A[i, j]B[j, k], (j, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) AB Transposition is detected: >>> expr = Sum(A[j, i]B[j, k], (j, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) A.TB Detect the trace: >>> expr = Sum(A[i, i], (i, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) Trace(A) More complicated expressions: >>> expr = Sum(A[i, j]B[k, j]A[l, k], (j, 0, N-1), (k, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) AB.TA.T """ from sympy import Sum, Mul, Add, MatMul, transpose, trace from sympy.strategies.traverse import bottom_up def remove_matelement(expr, i1, i2): def repl_match(pos): def func(x): if not isinstance(x, MatrixElement): return False if x.args[pos] != i1: return False if x.args[3-pos] == 0: if x.args[0].shape[2-pos] == 1: return True else: return False return True return func expr = expr.replace(repl_match(1), lambda x: x.args[0]) expr = expr.replace(repl_match(2), lambda x: transpose(x.args[0])) # Make sure that all Mul are transformed to MatMul and that they # are flattened: rule = bottom_up(lambda x: reduce(lambda a, b: ab, x.args) if isinstance(x, (Mul, MatMul)) else x) return rule(expr) def recurse_expr(expr, index_ranges={}): if expr.is_Mul: nonmatargs = [] pos_arg = [] pos_ind = [] dlinks = {} link_ind = [] counter = 0 args_ind = [] for arg in expr.args: retvals = recurse_expr(arg, index_ranges) assert isinstance(retvals, list) if isinstance(retvals, list): for i in retvals: args_ind.append(i) else: args_ind.append(retvals) for arg_symbol, arg_indices in args_ind: if arg_indices is None: nonmatargs.append(arg_symbol) continue if isinstance(arg_symbol, MatrixElement): arg_symbol = arg_symbol.args[0] pos_arg.append(arg_symbol) pos_ind.append(arg_indices) link_ind.append([None]len(arg_indices)) for i, ind in enumerate(arg_indices): if ind in dlinks: other_i = dlinks[ind] link_ind[counter][i] = other_i link_ind[other_i[0]][other_i[1]] = (counter, i) dlinks[ind] = (counter, i) counter += 1 counter2 = 0 lines = {} while counter2 < len(link_ind): for i, e in enumerate(link_ind): if None in e: line_start_index = (i, e.index(None)) break cur_ind_pos = line_start_index cur_line = [] index1 = pos_ind[cur_ind_pos[0]][cur_ind_pos[1]] while True: d, r = cur_ind_pos if pos_arg[d] != 1: if r % 2 == 1: cur_line.append(transpose(pos_arg[d])) else: cur_line.append(pos_arg[d]) next_ind_pos = link_ind[d][1-r] counter2 += 1 # Mark as visited, there will be no `None` anymore: link_ind[d] = (-1, -1) if next_ind_pos is None: index2 = pos_ind[d][1-r] lines[(index1, index2)] = cur_line break cur_ind_pos = next_ind_pos ret_indices = list(j for i in lines for j in i) lines = {k: MatMul.fromiter(v) if len(v) != 1 else v[0] for k, v in lines.items()} return [(Mul.fromiter(nonmatargs), None)] + [ (MatrixElement(a, i, j), (i, j)) for (i, j), a in lines.items() ] elif expr.is_Add: res = [recurse_expr(i) for i in expr.args] d = collections.defaultdict(list) for res_addend in res: scalar = 1 for elem, indices in res_addend: if indices is None: scalar = elem continue indices = tuple(sorted(indices, key=default_sort_key)) d[indices].append(scalarremove_matelement(elem, indices)) scalar = 1 return [(MatrixElement(Add.fromiter(v), k), k) for k, v in d.items()] elif isinstance(expr, KroneckerDelta): i1, i2 = expr.args if dimensions is not None: identity = Identity(dimensions[0]) else: identity = S.One return [(MatrixElement(identity, i1, i2), (i1, i2))] elif isinstance(expr, MatrixElement): matrix_symbol, i1, i2 = expr.args if i1 in index_ranges: r1, r2 = index_ranges[i1] if r1 != 0 or matrix_symbol.shape[0] != r2+1: raise ValueError("index range mismatch: {0} vs. (0, {1})".format( (r1, r2), matrix_symbol.shape[0])) if i2 in index_ranges: r1, r2 = index_ranges[i2] if r1 != 0 or matrix_symbol.shape[1] != r2+1: raise ValueError("index range mismatch: {0} vs. (0, {1})".format( (r1, r2), matrix_symbol.shape[1])) if (i1 == i2) and (i1 in index_ranges): return [(trace(matrix_symbol), None)] return [(MatrixElement(matrix_symbol, i1, i2), (i1, i2))] elif isinstance(expr, Sum): return recurse_expr( expr.args[0], index_ranges={i[0]: i[1:] for i in expr.args[1:]} ) else: return [(expr, None)] retvals = recurse_expr(expr) factors, indices = zip(retvals) retexpr = Mul.fromiter(factors) if len(indices) == 0 or list(set(indices)) == [None]: return retexpr if first_index is None: for i in indices: if i is not None: ind0 = i break return remove_matelement(retexpr, ind0) else: return remove_matelement(retexpr, first_index, last_index) def applyfunc(self, func): from .applyfunc import ElementwiseApplyFunction return ElementwiseApplyFunction(func, self) def _eval_Eq(self, other): if not isinstance(other, MatrixExpr): return False if self.shape != other.shape: return False if (self - other).is_ZeroMatrix: return True return Eq(self, other, evaluate=False) def get_postprocessor(cls): def _postprocessor(expr): # To avoid circular imports, we can't have MatMul/MatAdd on the top level mat_class = {Mul: MatMul, Add: MatAdd}[cls] nonmatrices = [] matrices = [] for term in expr.args: if isinstance(term, MatrixExpr): matrices.append(term) else: nonmatrices.append(term) if not matrices: return cls._from_args(nonmatrices) if nonmatrices: if cls == Mul: for i in range(len(matrices)): if not matrices[i].is_MatrixExpr: # If one of the matrices explicit, absorb the scalar into it # (doit will combine all explicit matrices into one, so it # doesn't matter which) matrices[i] = matrices[i].__mul__(cls._from_args(nonmatrices)) nonmatrices = [] break else: # Maintain the ability to create Add(scalar, matrix) without # raising an exception. That way different algorithms can # replace matrix expressions with non-commutative symbols to # manipulate them like non-commutative scalars. return cls._from_args(nonmatrices + [mat_class(matrices).doit(deep=False)]) return mat_class(cls._from_args(nonmatrices), matrices).doit(deep=False) return _postprocessor Basic._constructor_postprocessor_mapping[MatrixExpr] = { "Mul": [get_postprocessor(Mul)], "Add": [get_postprocessor(Add)], } def _matrix_derivative(expr, x): from sympy import Derivative lines = expr._eval_derivative_matrix_lines(x) parts = [i.build() for i in lines] def _get_shape(elem): if isinstance(elem, MatrixExpr): return elem.shape return (1, 1) def get_rank(parts): return sum([j not in (1, None) for i in parts for j in _get_shape(i)]) ranks = [get_rank(i) for i in parts] rank = ranks[0] def contract_one_dims(parts): if len(parts) == 1: return parts[0] else: p1, p2 = parts[:2] if p2.is_Matrix: p2 = p2.T pbase = p1p2 if len(parts) == 2: return pbase else: # len(parts) > 2 if pbase.is_Matrix: raise ValueError("") return pbaseMul.fromiter(parts[2:]) if rank <= 2: return Add.fromiter([contract_one_dims(i) for i in parts]) return Derivative(expr, x) class MatrixElement(Expr): parent = property(lambda self: self.args[0]) i = property(lambda self: self.args[1]) j = property(lambda self: self.args[2]) _diff_wrt = True is_symbol = True is_commutative = True def __new__(cls, name, n, m): n, m = map(_sympify, (n, m)) from sympy import MatrixBase if isinstance(name, (MatrixBase,)): if n.is_Integer and m.is_Integer: return name[n, m] if isinstance(name, string_types): name = Symbol(name) name = _sympify(name) obj = Expr.__new__(cls, name, n, m) return obj def doit(self, kwargs): deep = kwargs.get('deep', True) if deep: args = [arg.doit(kwargs) for arg in self.args] else: args = self.args return args[0][args[1], args[2]] @property def indices(self): return self.args[1:] def _eval_derivative(self, v): from sympy import Sum, symbols, Dummy if not isinstance(v, MatrixElement): from sympy import MatrixBase if isinstance(self.parent, MatrixBase): return self.parent.diff(v)[self.i, self.j] return S.Zero M = self.args[0] if M == v.args[0]: return KroneckerDelta(self.args[1], v.args[1])KroneckerDelta(self.args[2], v.args[2]) if isinstance(M, Inverse): i, j = self.args[1:] i1, i2 = symbols("z1, z2", cls=Dummy) Y = M.args[0] r1, r2 = Y.shape return -Sum(M[i, i1]Y[i1, i2].diff(v)M[i2, j], (i1, 0, r1-1), (i2, 0, r2-1)) if self.has(v.args[0]): return None return S.Zero class MatrixSymbol(MatrixExpr): """Symbolic representation of a Matrix object Creates a SymPy Symbol to represent a Matrix. This matrix has a shape and can be included in Matrix Expressions Examples ======== >>> from sympy import MatrixSymbol, Identity >>> A = MatrixSymbol('A', 3, 4) # A 3 by 4 Matrix >>> B = MatrixSymbol('B', 4, 3) # A 4 by 3 Matrix >>> A.shape (3, 4) >>> 2AB + Identity(3) I + 2AB """ is_commutative = False is_symbol = True _diff_wrt = True def __new__(cls, name, n, m): n, m = _sympify(n), _sympify(m) if isinstance(name, string_types): name = Symbol(name) obj = Basic.__new__(cls, name, n, m) return obj def _hashable_content(self): return (self.name, self.shape) @property def shape(self): return self.args[1:3] @property def name(self): return self.args[0].name def _eval_subs(self, old, new): # only do substitutions in shape shape = Tuple(self.shape)._subs(old, new) return MatrixSymbol(self.name, shape) def __call__(self, args): raise TypeError("%s object is not callable" % self.__class__) def _entry(self, i, j, kwargs): return MatrixElement(self, i, j) @property def free_symbols(self): return set((self,)) def doit(self, hints): if hints.get('deep', True): return type(self)(self.name, self.args[1].doit(hints), self.args[2].doit(hints)) else: return self def _eval_simplify(self, *kwargs): return self def _eval_derivative_matrix_lines(self, x): if self != x: first = ZeroMatrix(x.shape[0], self.shape[0]) if self.shape[0] != 1 else S.Zero second = ZeroMatrix(x.shape[1], self.shape[1]) if self.shape[1] != 1 else S.Zero return [_LeftRightArgs( [first, second], )] else: first = Identity(self.shape[0]) if self.shape[0] != 1 else S.One second = Identity(self.shape[1]) if self.shape[1] != 1 else S.One return [_LeftRightArgs( [first, second], )] class Identity(MatrixExpr): """The Matrix Identity I - multiplicative identity Examples ======== >>> from sympy.matrices import Identity, MatrixSymbol >>> A = MatrixSymbol('A', 3, 5) >>> I = Identity(3) >>> IA A """ is_Identity = True def __new__(cls, n): return super(Identity, cls).__new__(cls, _sympify(n)) @property def rows(self): return self.args[0] @property def cols(self): return self.args[0] @property def shape(self): return (self.args[0], self.args[0]) @property def is_square(self): return True def _eval_transpose(self): return self def _eval_trace(self): return self.rows def _eval_inverse(self): return self def conjugate(self): return self def _entry(self, i, j, *kwargs): eq = Eq(i, j) if eq is S.true: return S.One elif eq is S.false: return S.Zero return KroneckerDelta(i, j) def _eval_determinant(self): return S.One class GenericIdentity(Identity): """ An identity matrix without a specified shape This exists primarily so MatMul() with no arguments can return something meaningful. """ def __new__(cls): # super(Identity, cls) instead of super(GenericIdentity, cls) because # Identity.__new__ doesn't have the same signature return super(Identity, cls).__new__(cls) @property def rows(self): raise TypeError("GenericIdentity does not have a specified shape") @property def cols(self): raise TypeError("GenericIdentity does not have a specified shape") @property def shape(self): raise TypeError("GenericIdentity does not have a specified shape") # Avoid Matrix.__eq__ which might call .shape def __eq__(self, other): return isinstance(other, GenericIdentity) def __ne__(self, other): return not (self == other) def __hash__(self): return super(GenericIdentity, self).__hash__() class ZeroMatrix(MatrixExpr): """The Matrix Zero 0 - additive identity Examples ======== >>> from sympy import MatrixSymbol, ZeroMatrix >>> A = MatrixSymbol('A', 3, 5) >>> Z = ZeroMatrix(3, 5) >>> A + Z A >>> ZA.T 0 """ is_ZeroMatrix = True def __new__(cls, m, n): return super(ZeroMatrix, cls).__new__(cls, m, n) @property def shape(self): return (self.args[0], self.args[1]) @_sympifyit('other', NotImplemented) @call_highest_priority('__rpow__') def __pow__(self, other): if other != 1 and not self.is_square: raise ShapeError("Power of non-square matrix %s" % self) if other == 0: return Identity(self.rows) if other < 1: raise ValueError("Matrix det == 0; not invertible.") return self def _eval_transpose(self): return ZeroMatrix(self.cols, self.rows) def _eval_trace(self): return S.Zero def _eval_determinant(self): return S.Zero def conjugate(self): return self def _entry(self, i, j, *kwargs): return S.Zero def __nonzero__(self): return False __bool__ = __nonzero__ class GenericZeroMatrix(ZeroMatrix): """ A zero matrix without a specified shape This exists primarily so MatAdd() with no arguments can return something meaningful. """ def __new__(cls): # super(ZeroMatrix, cls) instead of super(GenericZeroMatrix, cls) # because ZeroMatrix.__new__ doesn't have the same signature return super(ZeroMatrix, cls).__new__(cls) @property def rows(self): raise TypeError("GenericZeroMatrix does not have a specified shape") @property def cols(self): raise TypeError("GenericZeroMatrix does not have a specified shape") @property def shape(self): raise TypeError("GenericZeroMatrix does not have a specified shape") # Avoid Matrix.__eq__ which might call .shape def __eq__(self, other): return isinstance(other, GenericZeroMatrix) def __ne__(self, other): return not (self == other) def __hash__(self): return super(GenericZeroMatrix, self).__hash__() def matrix_symbols(expr): return [sym for sym in expr.free_symbols if sym.is_Matrix] class _LeftRightArgs(object): r""" Helper class to compute matrix derivatives. The logic: when an expression is derived by a matrix `X_{mn}`, two lines of matrix multiplications are created: the one contracted to `m` (first line), and the one contracted to `n` (second line). Transposition flips the side by which new matrices are connected to the lines. The trace connects the end of the two lines. """ def __init__(self, lines, higher=S.One): self._lines = [i for i in lines] self._first_pointer_parent = self._lines self._first_pointer_index = 0 self._second_pointer_parent = self._lines self._second_pointer_index = 1 self.higher = higher @property def first_pointer(self): return self._first_pointer_parent[self._first_pointer_index] @first_pointer.setter def first_pointer(self, value): self._first_pointer_parent[self._first_pointer_index] = value @property def second_pointer(self): return self._second_pointer_parent[self._second_pointer_index] @second_pointer.setter def second_pointer(self, value): self._second_pointer_parent[self._second_pointer_index] = value def __repr__(self): try: built = [self._build(i) for i in self._lines] except Exception: built = self._lines return "_LeftRightArgs(lines=%s, higher=%s)" % ( built, self.higher, ) def transpose(self): self._first_pointer_parent, self._second_pointer_parent = self._second_pointer_parent, self._first_pointer_parent self._first_pointer_index, self._second_pointer_index = self._second_pointer_index, self._first_pointer_index return self @staticmethod def _build(expr): from sympy.core.expr import ExprBuilder if isinstance(expr, ExprBuilder): return expr.build() if isinstance(expr, list): if len(expr) == 1: return expr[0] else: return expr[0]([_LeftRightArgs._build(i) for i in expr[1]]) else: return expr def build(self): data = [self._build(i) for i in self._lines] if self.higher != 1: data += [self._build(self.higher)] data = [i.doit() for i in data] return data def matrix_form(self): if self.first != 1 and self.higher != 1: raise ValueError("higher dimensional array cannot be represented") def _get_shape(elem): if isinstance(elem, MatrixExpr): return elem.shape return (None, None) if _get_shape(self.first)[1] != _get_shape(self.second)[1]: # Remove one-dimensional identity matrices: # (this is needed by `a.diff(a)` where `a` is a vector) if _get_shape(self.second) == (1, 1): return self.firstself.second[0, 0] if _get_shape(self.first) == (1, 1): return self.first[1, 1]self.second.T raise ValueError("incompatible shapes") if self.first != 1: return self.firstself.second.T else: return self.higher def rank(self): """ Number of dimensions different from trivial (warning: not related to matrix rank). """ rank = 0 if self.first != 1: rank += sum([i != 1 for i in self.first.shape]) if self.second != 1: rank += sum([i != 1 for i in self.second.shape]) if self.higher != 1: rank += 2 return rank def append_first(self, other): self.first_pointer = other def append_second(self, other): self.second_pointer *= other def __hash__(self): return hash((self.first, self.second)) def __eq__(self, other): if not isinstance(other, _LeftRightArgs): return False return (self.first == other.first) and (self.second == other.second) from .matmul import MatMul from .matadd import MatAdd from .matpow import MatPow from .transpose import Transpose from .inverse import Inverse
0bf6ba905fe45969ea04ca4daf711af59e9d63dacc3972d9462752b7d24c6bd8	from __future__ import print_function, division from sympy.core.sympify import _sympify from sympy.matrices.expressions import MatrixExpr from sympy.core import S, Eq, Ge from sympy.functions.special.tensor_functions import KroneckerDelta class DiagonalMatrix(MatrixExpr): """DiagonalMatrix(M) will create a matrix expression that behaves as though all off-diagonal elements, `M[i, j]` where `i != j`, are zero. Examples ======== >>> from sympy import MatrixSymbol, DiagonalMatrix, Symbol >>> n = Symbol('n', integer=True) >>> m = Symbol('m', integer=True) >>> D = DiagonalMatrix(MatrixSymbol('x', 2, 3)) >>> D[1, 2] 0 >>> D[1, 1] x[1, 1] The length of the diagonal -- the lesser of the two dimensions of `M` -- is accessed through the `diagonal_length` property: >>> D.diagonal_length 2 >>> DiagonalMatrix(MatrixSymbol('x', n + 1, n)).diagonal_length n When one of the dimensions is symbolic the other will be treated as though it is smaller: >>> tall = DiagonalMatrix(MatrixSymbol('x', n, 3)) >>> tall.diagonal_length 3 >>> tall[10, 1] 0 When the size of the diagonal is not known, a value of None will be returned: >>> DiagonalMatrix(MatrixSymbol('x', n, m)).diagonal_length is None True """ arg = property(lambda self: self.args[0]) shape = property(lambda self: self.arg.shape) @property def diagonal_length(self): r, c = self.shape if r.is_Integer and c.is_Integer: m = min(r, c) elif r.is_Integer and not c.is_Integer: m = r elif c.is_Integer and not r.is_Integer: m = c elif r == c: m = r else: try: m = min(r, c) except TypeError: m = None return m def _entry(self, i, j): if self.diagonal_length is not None: if Ge(i, self.diagonal_length) is S.true: return S.Zero elif Ge(j, self.diagonal_length) is S.true: return S.Zero eq = Eq(i, j) if eq is S.true: return self.arg[i, i] elif eq is S.false: return S.Zero return self.arg[i, j]KroneckerDelta(i, j) class DiagonalOf(MatrixExpr): """DiagonalOf(M) will create a matrix expression that is equivalent to the diagonal of `M`, represented as a single column matrix. Examples ======== >>> from sympy import MatrixSymbol, DiagonalOf, Symbol >>> n = Symbol('n', integer=True) >>> m = Symbol('m', integer=True) >>> x = MatrixSymbol('x', 2, 3) >>> diag = DiagonalOf(x) >>> diag.shape (2, 1) The diagonal can be addressed like a matrix or vector and will return the corresponding element of the original matrix: >>> diag[1, 0] == diag[1] == x[1, 1] True The length of the diagonal -- the lesser of the two dimensions of `M` -- is accessed through the `diagonal_length` property: >>> diag.diagonal_length 2 >>> DiagonalOf(MatrixSymbol('x', n + 1, n)).diagonal_length n When only one of the dimensions is symbolic the other will be treated as though it is smaller: >>> dtall = DiagonalOf(MatrixSymbol('x', n, 3)) >>> dtall.diagonal_length 3 When the size of the diagonal is not known, a value of None will be returned: >>> DiagonalOf(MatrixSymbol('x', n, m)).diagonal_length is None True """ arg = property(lambda self: self.args[0]) @property def shape(self): r, c = self.arg.shape if r.is_Integer and c.is_Integer: m = min(r, c) elif r.is_Integer and not c.is_Integer: m = r elif c.is_Integer and not r.is_Integer: m = c elif r == c: m = r else: try: m = min(r, c) except TypeError: m = None return m, S.One @property def diagonal_length(self): return self.shape[0] def _entry(self, i, j): return self.arg[i, i] class DiagonalizeVector(MatrixExpr): """ Turn a vector into a diagonal matrix. """ def __new__(cls, vector): obj = MatrixExpr.__new__(cls, vector) shape = vector.shape dim = shape[1] if shape[0] == 1 else shape[0] if vector.shape[0] != 1: obj._iscolumn = True else: obj._iscolumn = False obj._shape = (dim, dim) obj._vector = vector return obj @property def shape(self): return self._shape def _entry(self, i, j, kwargs): if self._iscolumn: result = self._vector._entry(i, 0) else: result = self._vector._entry(0, j) if i != j: result = KroneckerDelta(i, j) return result def _eval_transpose(self): return self def as_explicit(self): from sympy import diag return diag(*list(self._vector.as_explicit())) def diagonalize_vector(vector): from sympy import Transpose vector = _sympify(vector) if vector.shape == (1, 1): return vector if vector.is_Identity: return vector if isinstance(vector, Transpose): vector = vector.arg return DiagonalizeVector(vector)
3a5020bff249a2fcc2d1871cb60b5d40c069385cebe3d9528725e38c1df8fc07	from __future__ import print_function, division from sympy import Basic, Expr, sympify, S from sympy.matrices.matrices import MatrixBase from .matexpr import ShapeError class Trace(Expr): """Matrix Trace Represents the trace of a matrix expression. Examples ======== >>> from sympy import MatrixSymbol, Trace, eye >>> A = MatrixSymbol('A', 3, 3) >>> Trace(A) Trace(A) """ is_Trace = True is_commutative = True def __new__(cls, mat): mat = sympify(mat) if not mat.is_Matrix: raise TypeError("input to Trace, %s, is not a matrix" % str(mat)) if not mat.is_square: raise ShapeError("Trace of a non-square matrix") return Basic.__new__(cls, mat) def _eval_transpose(self): return self def _eval_derivative(self, v): from sympy.matrices.expressions.matexpr import _matrix_derivative return _matrix_derivative(self, v) def _eval_derivative_matrix_lines(self, x): r = self.args[0]._eval_derivative_matrix_lines(x) for lr in r: if lr.higher == 1: lr.higher = lr._lines[0] lr._lines[1].T else: # This is not a matrix line: lr.higher = Trace(lr._lines[0] lr._lines[1].T) lr._lines = [S.One, S.One] lr._first_pointer_parent = lr._lines lr._second_pointer_parent = lr._lines lr._first_pointer_index = 0 lr._second_pointer_index = 1 return r @property def arg(self): return self.args[0] def doit(self, kwargs): if kwargs.get('deep', True): arg = self.arg.doit(kwargs) try: return arg._eval_trace() except (AttributeError, NotImplementedError): return Trace(arg) else: # _eval_trace would go too deep here if isinstance(self.arg, MatrixBase): return trace(self.arg) else: return Trace(self.arg) def _eval_rewrite_as_Sum(self, expr, *kwargs): from sympy import Sum, Dummy i = Dummy('i') return Sum(self.arg[i, i], (i, 0, self.arg.rows-1)).doit() def trace(expr): """Trace of a Matrix. Sum of the diagonal elements. Examples ======== >>> from sympy import trace, Symbol, MatrixSymbol, pprint, eye >>> n = Symbol('n') >>> X = MatrixSymbol('X', n, n) # A square matrix >>> trace(2X) 2*Trace(X) >>> trace(eye(3)) 3 """ return Trace(expr).doit()
cbe584b00a135b6731dd1c871fb9d1c8e7df5a7bd8d16c8a59fd488a3705165b	from __future__ import print_function, division from sympy.core import Mul, sympify from sympy.matrices.expressions.matexpr import MatrixExpr, ShapeError from sympy.strategies import unpack, flatten, condition, exhaust, do_one def hadamard_product(matrices): """ Return the elementwise (aka Hadamard) product of matrices. Examples ======== >>> from sympy.matrices import hadamard_product, MatrixSymbol >>> A = MatrixSymbol('A', 2, 3) >>> B = MatrixSymbol('B', 2, 3) >>> hadamard_product(A) A >>> hadamard_product(A, B) A.B >>> hadamard_product(A, B)[0, 1] A[0, 1]B[0, 1] """ if not matrices: raise TypeError("Empty Hadamard product is undefined") validate(matrices) if len(matrices) == 1: return matrices[0] else: matrices = [i for i in matrices if not i.is_Identity] return HadamardProduct(matrices).doit() class HadamardProduct(MatrixExpr): """ Elementwise product of matrix expressions This is a symbolic object that simply stores its argument without evaluating it. To actually compute the product, use the function ``hadamard_product()``. >>> from sympy.matrices import hadamard_product, HadamardProduct, MatrixSymbol >>> A = MatrixSymbol('A', 5, 5) >>> B = MatrixSymbol('B', 5, 5) >>> isinstance(hadamard_product(A, B), HadamardProduct) True """ is_HadamardProduct = True def __new__(cls, args, *kwargs): args = list(map(sympify, args)) check = kwargs.get('check', True) if check: validate(args) return super(HadamardProduct, cls).__new__(cls, args) @property def shape(self): return self.args[0].shape def _entry(self, i, j): return Mul([arg._entry(i, j) for arg in self.args]) def _eval_transpose(self): from sympy.matrices.expressions.transpose import transpose return HadamardProduct(list(map(transpose, self.args))) def doit(self, ignored): return canonicalize(self) def validate(args): if not all(arg.is_Matrix for arg in args): raise TypeError("Mix of Matrix and Scalar symbols") A = args[0] for B in args[1:]: if A.shape != B.shape: raise ShapeError("Matrices %s and %s are not aligned" % (A, B)) rules = (unpack, flatten) canonicalize = exhaust(condition(lambda x: isinstance(x, HadamardProduct), do_one(rules))) def hadamard_power(base, exp): base = sympify(base) exp = sympify(exp) if exp == 1: return base if not base.is_Matrix: return baseexp if exp.is_Matrix: raise ValueError("cannot raise expression to a matrix") return HadamardPower(base, exp) class HadamardPower(MatrixExpr): """ Elementwise power of matrix expressions """ def __new__(cls, base, exp): base = sympify(base) exp = sympify(exp) obj = super(HadamardPower, cls).__new__(cls, base, exp) return obj @property def base(self): return self._args[0] @property def exp(self): return self._args[1] @property def shape(self): return self.base.shape def _entry(self, i, j, kwargs): return self.base[i, j]*self.exp def _eval_transpose(self): from sympy.matrices.expressions.transpose import transpose return HadamardPower(transpose(self.base), self.exp)
39bbf729ad5208a8987ab5851f26053a01832d2453700b27bf9c0cc4603f3573	from __future__ import print_function, division from sympy import ask, Q from sympy.core import Basic, Add, sympify from sympy.core.compatibility import range from sympy.strategies import typed, exhaust, condition, do_one, unpack from sympy.strategies.traverse import bottom_up from sympy.utilities import sift from sympy.utilities.misc import filldedent from sympy.matrices.expressions.matexpr import MatrixExpr, ZeroMatrix, Identity from sympy.matrices.expressions.matmul import MatMul from sympy.matrices.expressions.matadd import MatAdd from sympy.matrices.expressions.matpow import MatPow from sympy.matrices.expressions.transpose import Transpose, transpose from sympy.matrices.expressions.trace import Trace from sympy.matrices.expressions.determinant import det, Determinant from sympy.matrices.expressions.slice import MatrixSlice from sympy.matrices.expressions.inverse import Inverse from sympy.matrices import Matrix, ShapeError from sympy.functions.elementary.complexes import re, im class BlockMatrix(MatrixExpr): """A BlockMatrix is a Matrix comprised of other matrices. The submatrices are stored in a SymPy Matrix object but accessed as part of a Matrix Expression >>> from sympy import (MatrixSymbol, BlockMatrix, symbols, ... Identity, ZeroMatrix, block_collapse) >>> n,m,l = symbols('n m l') >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> Z = MatrixSymbol('Z', n, m) >>> B = BlockMatrix([[X, Z], [ZeroMatrix(m,n), Y]]) >>> print(B) Matrix([ [X, Z], [0, Y]]) >>> C = BlockMatrix([[Identity(n), Z]]) >>> print(C) Matrix([[I, Z]]) >>> print(block_collapse(CB)) Matrix([[X, Z + ZY]]) Some matrices might be comprised of rows of blocks with the matrices in each row having the same height and the rows all having the same total number of columns but not having the same number of columns for each matrix in each row. In this case, the matrix is not a block matrix and should be instantiated by Matrix. >>> from sympy import ones, Matrix >>> dat = [ ... [ones(3,2), ones(3,3)2], ... [ones(2,3)3, ones(2,2)4]] ... >>> BlockMatrix(dat) Traceback (most recent call last): ... ValueError: Although this matrix is comprised of blocks, the blocks do not fill the matrix in a size-symmetric fashion. To create a full matrix from these arguments, pass them directly to Matrix. >>> Matrix(dat) Matrix([ [1, 1, 2, 2, 2], [1, 1, 2, 2, 2], [1, 1, 2, 2, 2], [3, 3, 3, 4, 4], [3, 3, 3, 4, 4]]) See Also ======== sympy.matrices.matrices.MatrixBase.irregular """ def __new__(cls, args, *kwargs): from sympy.matrices.immutable import ImmutableDenseMatrix from sympy.matrices import zeros from sympy.matrices.matrices import MatrixBase from sympy.utilities.iterables import is_sequence isMat = lambda i: getattr(i, 'is_Matrix', False) if len(args) != 1 or \ not is_sequence(args[0]) or \ len(set([isMat(r) for r in args[0]])) != 1: raise ValueError(filldedent(''' expecting a sequence of 1 or more rows containing Matrices.''')) rows = args[0] if args else [] if not isMat(rows): if rows and isMat(rows[0]): rows = [rows] # rows is not list of lists or [] # regularity check # same number of matrices in each row blocky = ok = len(set([len(r) for r in rows])) == 1 if ok: # same number of rows for each matrix in a row for r in rows: ok = len(set([i.rows for i in r])) == 1 if not ok: break blocky = ok # same number of cols for each matrix in each col for c in range(len(rows[0])): ok = len(set([rows[i][c].cols for i in range(len(rows))])) == 1 if not ok: break if not ok: # same total cols in each row ok = len(set([ sum([i.cols for i in r]) for r in rows])) == 1 if blocky and ok: raise ValueError(filldedent(''' Although this matrix is comprised of blocks, the blocks do not fill the matrix in a size-symmetric fashion. To create a full matrix from these arguments, pass them directly to Matrix.''')) raise ValueError(filldedent(''' When there are not the same number of rows in each row's matrices or there are not the same number of total columns in each row, the matrix is not a block matrix. If this matrix is known to consist of blocks fully filling a 2-D space then see Matrix.irregular.''')) mat = ImmutableDenseMatrix(rows, evaluate=False) obj = Basic.__new__(cls, mat) return obj @property def shape(self): numrows = numcols = 0 M = self.blocks for i in range(M.shape[0]): numrows += M[i, 0].shape[0] for i in range(M.shape[1]): numcols += M[0, i].shape[1] return (numrows, numcols) @property def blockshape(self): return self.blocks.shape @property def blocks(self): return self.args[0] @property def rowblocksizes(self): return [self.blocks[i, 0].rows for i in range(self.blockshape[0])] @property def colblocksizes(self): return [self.blocks[0, i].cols for i in range(self.blockshape[1])] def structurally_equal(self, other): return (isinstance(other, BlockMatrix) and self.shape == other.shape and self.blockshape == other.blockshape and self.rowblocksizes == other.rowblocksizes and self.colblocksizes == other.colblocksizes) def _blockmul(self, other): if (isinstance(other, BlockMatrix) and self.colblocksizes == other.rowblocksizes): return BlockMatrix(self.blocksother.blocks) return self * other def _blockadd(self, other): if (isinstance(other, BlockMatrix) and self.structurally_equal(other)): return BlockMatrix(self.blocks + other.blocks) return self + other def _eval_transpose(self): # Flip all the individual matrices matrices = [transpose(matrix) for matrix in self.blocks] # Make a copy M = Matrix(self.blockshape[0], self.blockshape[1], matrices) # Transpose the block structure M = M.transpose() return BlockMatrix(M) def _eval_trace(self): if self.rowblocksizes == self.colblocksizes: return Add([Trace(self.blocks[i, i]) for i in range(self.blockshape[0])]) raise NotImplementedError( "Can't perform trace of irregular blockshape") def _eval_determinant(self): if self.blockshape == (2, 2): [[A, B], [C, D]] = self.blocks.tolist() if ask(Q.invertible(A)): return det(A)det(D - CA.IB) elif ask(Q.invertible(D)): return det(D)det(A - BD.IC) return Determinant(self) def as_real_imag(self): real_matrices = [re(matrix) for matrix in self.blocks] real_matrices = Matrix(self.blockshape[0], self.blockshape[1], real_matrices) im_matrices = [im(matrix) for matrix in self.blocks] im_matrices = Matrix(self.blockshape[0], self.blockshape[1], im_matrices) return (real_matrices, im_matrices) def transpose(self): """Return transpose of matrix. Examples ======== >>> from sympy import MatrixSymbol, BlockMatrix, ZeroMatrix >>> from sympy.abc import l, m, n >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> Z = MatrixSymbol('Z', n, m) >>> B = BlockMatrix([[X, Z], [ZeroMatrix(m,n), Y]]) >>> B.transpose() Matrix([ [X.T, 0], [Z.T, Y.T]]) >>> _.transpose() Matrix([ [X, Z], [0, Y]]) """ return self._eval_transpose() def _entry(self, i, j): # Find row entry for row_block, numrows in enumerate(self.rowblocksizes): if (i < numrows) != False: break else: i -= numrows for col_block, numcols in enumerate(self.colblocksizes): if (j < numcols) != False: break else: j -= numcols return self.blocks[row_block, col_block][i, j] @property def is_Identity(self): if self.blockshape[0] != self.blockshape[1]: return False for i in range(self.blockshape[0]): for j in range(self.blockshape[1]): if i==j and not self.blocks[i, j].is_Identity: return False if i!=j and not self.blocks[i, j].is_ZeroMatrix: return False return True @property def is_structurally_symmetric(self): return self.rowblocksizes == self.colblocksizes def equals(self, other): if self == other: return True if (isinstance(other, BlockMatrix) and self.blocks == other.blocks): return True return super(BlockMatrix, self).equals(other) class BlockDiagMatrix(BlockMatrix): """ A BlockDiagMatrix is a BlockMatrix with matrices only along the diagonal >>> from sympy import MatrixSymbol, BlockDiagMatrix, symbols, Identity >>> n, m, l = symbols('n m l') >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> BlockDiagMatrix(X, Y) Matrix([ [X, 0], [0, Y]]) See Also ======== sympy.matrices.common.diag """ def __new__(cls, mats): return Basic.__new__(BlockDiagMatrix, mats) @property def diag(self): return self.args @property def blocks(self): from sympy.matrices.immutable import ImmutableDenseMatrix mats = self.args data = [[mats[i] if i == j else ZeroMatrix(mats[i].rows, mats[j].cols) for j in range(len(mats))] for i in range(len(mats))] return ImmutableDenseMatrix(data) @property def shape(self): return (sum(block.rows for block in self.args), sum(block.cols for block in self.args)) @property def blockshape(self): n = len(self.args) return (n, n) @property def rowblocksizes(self): return [block.rows for block in self.args] @property def colblocksizes(self): return [block.cols for block in self.args] def _eval_inverse(self, expand='ignored'): return BlockDiagMatrix([mat.inverse() for mat in self.args]) def _blockmul(self, other): if (isinstance(other, BlockDiagMatrix) and self.colblocksizes == other.rowblocksizes): return BlockDiagMatrix([ab for a, b in zip(self.args, other.args)]) else: return BlockMatrix._blockmul(self, other) def _blockadd(self, other): if (isinstance(other, BlockDiagMatrix) and self.blockshape == other.blockshape and self.rowblocksizes == other.rowblocksizes and self.colblocksizes == other.colblocksizes): return BlockDiagMatrix([a + b for a, b in zip(self.args, other.args)]) else: return BlockMatrix._blockadd(self, other) def block_collapse(expr): """Evaluates a block matrix expression >>> from sympy import MatrixSymbol, BlockMatrix, symbols, \ Identity, Matrix, ZeroMatrix, block_collapse >>> n,m,l = symbols('n m l') >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> Z = MatrixSymbol('Z', n, m) >>> B = BlockMatrix([[X, Z], [ZeroMatrix(m, n), Y]]) >>> print(B) Matrix([ [X, Z], [0, Y]]) >>> C = BlockMatrix([[Identity(n), Z]]) >>> print(C) Matrix([[I, Z]]) >>> print(block_collapse(CB)) Matrix([[X, Z + ZY]]) """ hasbm = lambda expr: isinstance(expr, MatrixExpr) and expr.has(BlockMatrix) rule = exhaust( bottom_up(exhaust(condition(hasbm, typed( {MatAdd: do_one(bc_matadd, bc_block_plus_ident), MatMul: do_one(bc_matmul, bc_dist), MatPow: bc_matmul, Transpose: bc_transpose, Inverse: bc_inverse, BlockMatrix: do_one(bc_unpack, deblock)}))))) result = rule(expr) doit = getattr(result, 'doit', None) if doit is not None: return doit() else: return result def bc_unpack(expr): if expr.blockshape == (1, 1): return expr.blocks[0, 0] return expr def bc_matadd(expr): args = sift(expr.args, lambda M: isinstance(M, BlockMatrix)) blocks = args[True] if not blocks: return expr nonblocks = args[False] block = blocks[0] for b in blocks[1:]: block = block._blockadd(b) if nonblocks: return MatAdd(nonblocks) + block else: return block def bc_block_plus_ident(expr): idents = [arg for arg in expr.args if arg.is_Identity] if not idents: return expr blocks = [arg for arg in expr.args if isinstance(arg, BlockMatrix)] if (blocks and all(b.structurally_equal(blocks[0]) for b in blocks) and blocks[0].is_structurally_symmetric): block_id = BlockDiagMatrix([Identity(k) for k in blocks[0].rowblocksizes]) return MatAdd(block_id len(idents), blocks).doit() return expr def bc_dist(expr): """ Turn a[X, Y] into [aX, aY] """ factor, mat = expr.as_coeff_mmul() if factor != 1 and isinstance(unpack(mat), BlockMatrix): B = unpack(mat).blocks return BlockMatrix([[factor * B[i, j] for j in range(B.cols)] for i in range(B.rows)]) return expr def bc_matmul(expr): if isinstance(expr, MatPow): if expr.args[1].is_Integer: factor, matrices = (1, [expr.args[0]]expr.args[1]) else: return expr else: factor, matrices = expr.as_coeff_matrices() i = 0 while (i+1 < len(matrices)): A, B = matrices[i:i+2] if isinstance(A, BlockMatrix) and isinstance(B, BlockMatrix): matrices[i] = A._blockmul(B) matrices.pop(i+1) elif isinstance(A, BlockMatrix): matrices[i] = A._blockmul(BlockMatrix([[B]])) matrices.pop(i+1) elif isinstance(B, BlockMatrix): matrices[i] = BlockMatrix([[A]])._blockmul(B) matrices.pop(i+1) else: i+=1 return MatMul(factor, matrices).doit() def bc_transpose(expr): return BlockMatrix(block_collapse(expr.arg).blocks.applyfunc(transpose).T) def bc_inverse(expr): expr2 = blockinverse_1x1(expr) if expr != expr2: return expr2 return blockinverse_2x2(Inverse(reblock_2x2(expr.arg))) def blockinverse_1x1(expr): if isinstance(expr.arg, BlockMatrix) and expr.arg.blockshape == (1, 1): mat = Matrix([[expr.arg.blocks[0].inverse()]]) return BlockMatrix(mat) return expr def blockinverse_2x2(expr): if isinstance(expr.arg, BlockMatrix) and expr.arg.blockshape == (2, 2): # Cite: The Matrix Cookbook Section 9.1.3 [[A, B], [C, D]] = expr.arg.blocks.tolist() return BlockMatrix([[ (A - BD.IC).I, (-A).IB(D - CA.IB).I], [-(D - CA.IB).ICA.I, (D - CA.IB).I]]) else: return expr def deblock(B): """ Flatten a BlockMatrix of BlockMatrices """ if not isinstance(B, BlockMatrix) or not B.blocks.has(BlockMatrix): return B wrap = lambda x: x if isinstance(x, BlockMatrix) else BlockMatrix([[x]]) bb = B.blocks.applyfunc(wrap) # everything is a block from sympy import Matrix try: MM = Matrix(0, sum(bb[0, i].blocks.shape[1] for i in range(bb.shape[1])), []) for row in range(0, bb.shape[0]): M = Matrix(bb[row, 0].blocks) for col in range(1, bb.shape[1]): M = M.row_join(bb[row, col].blocks) MM = MM.col_join(M) return BlockMatrix(MM) except ShapeError: return B def reblock_2x2(B): """ Reblock a BlockMatrix so that it has 2x2 blocks of block matrices """ if not isinstance(B, BlockMatrix) or not all(d > 2 for d in B.blocks.shape): return B BM = BlockMatrix # for brevity's sake return BM([[ B.blocks[0, 0], BM(B.blocks[0, 1:])], [BM(B.blocks[1:, 0]), BM(B.blocks[1:, 1:])]]) def bounds(sizes): """ Convert sequence of numbers into pairs of low-high pairs >>> from sympy.matrices.expressions.blockmatrix import bounds >>> bounds((1, 10, 50)) [(0, 1), (1, 11), (11, 61)] """ low = 0 rv = [] for size in sizes: rv.append((low, low + size)) low += size return rv def blockcut(expr, rowsizes, colsizes): """ Cut a matrix expression into Blocks >>> from sympy import ImmutableMatrix, blockcut >>> M = ImmutableMatrix(4, 4, range(16)) >>> B = blockcut(M, (1, 3), (1, 3)) >>> type(B).__name__ 'BlockMatrix' >>> ImmutableMatrix(B.blocks[0, 1]) Matrix([[1, 2, 3]]) """ rowbounds = bounds(rowsizes) colbounds = bounds(colsizes) return BlockMatrix([[MatrixSlice(expr, rowbound, colbound) for colbound in colbounds] for rowbound in rowbounds])
1ed819a5ea5b768e89f006b3c5581718e4a2ac3d2bb48fbd4ef3c541eb6ba435	from __future__ import print_function, division from sympy.core.compatibility import reduce from operator import add from sympy.core import Add, Basic, sympify from sympy.functions import adjoint from sympy.matrices.matrices import MatrixBase from sympy.matrices.expressions.transpose import transpose from sympy.strategies import (rm_id, unpack, flatten, sort, condition, exhaust, do_one, glom) from sympy.matrices.expressions.matexpr import (MatrixExpr, ShapeError, ZeroMatrix, GenericZeroMatrix) from sympy.utilities import default_sort_key, sift # XXX: MatAdd should perhaps not subclass directly from Add class MatAdd(MatrixExpr, Add): """A Sum of Matrix Expressions MatAdd inherits from and operates like SymPy Add Examples ======== >>> from sympy import MatAdd, MatrixSymbol >>> A = MatrixSymbol('A', 5, 5) >>> B = MatrixSymbol('B', 5, 5) >>> C = MatrixSymbol('C', 5, 5) >>> MatAdd(A, B, C) A + B + C """ is_MatAdd = True def __new__(cls, args, kwargs): if not args: return GenericZeroMatrix() # This must be removed aggressively in the constructor to avoid # TypeErrors from GenericZeroMatrix().shape args = filter(lambda i: GenericZeroMatrix() != i, args) args = list(map(sympify, args)) check = kwargs.get('check', False) obj = Basic.__new__(cls, args) if check: if all(not isinstance(i, MatrixExpr) for i in args): return Add.fromiter(args) validate(args) return obj @property def shape(self): return self.args[0].shape def _entry(self, i, j, expand=None): return Add([arg._entry(i, j) for arg in self.args]) def _eval_transpose(self): return MatAdd([transpose(arg) for arg in self.args]).doit() def _eval_adjoint(self): return MatAdd([adjoint(arg) for arg in self.args]).doit() def _eval_trace(self): from .trace import trace return Add([trace(arg) for arg in self.args]).doit() def doit(self, kwargs): deep = kwargs.get('deep', True) if deep: args = [arg.doit(kwargs) for arg in self.args] else: args = self.args return canonicalize(MatAdd(args)) def _eval_derivative_matrix_lines(self, x): add_lines = [arg._eval_derivative_matrix_lines(x) for arg in self.args] return [j for i in add_lines for j in i] def validate(args): if not all(arg.is_Matrix for arg in args): raise TypeError("Mix of Matrix and Scalar symbols") A = args[0] for B in args[1:]: if A.shape != B.shape: raise ShapeError("Matrices %s and %s are not aligned"%(A, B)) factor_of = lambda arg: arg.as_coeff_mmul()[0] matrix_of = lambda arg: unpack(arg.as_coeff_mmul()[1]) def combine(cnt, mat): if cnt == 1: return mat else: return cnt mat def merge_explicit(matadd): """ Merge explicit MatrixBase arguments Examples ======== >>> from sympy import MatrixSymbol, eye, Matrix, MatAdd, pprint >>> from sympy.matrices.expressions.matadd import merge_explicit >>> A = MatrixSymbol('A', 2, 2) >>> B = eye(2) >>> C = Matrix([[1, 2], [3, 4]]) >>> X = MatAdd(A, B, C) >>> pprint(X) [1 0] [1 2] A + [ ] + [ ] [0 1] [3 4] >>> pprint(merge_explicit(X)) [2 2] A + [ ] [3 5] """ groups = sift(matadd.args, lambda arg: isinstance(arg, MatrixBase)) if len(groups[True]) > 1: return MatAdd((groups[False] + [reduce(add, groups[True])])) else: return matadd rules = (rm_id(lambda x: x == 0 or isinstance(x, ZeroMatrix)), unpack, flatten, glom(matrix_of, factor_of, combine), merge_explicit, sort(default_sort_key)) canonicalize = exhaust(condition(lambda x: isinstance(x, MatAdd), do_one(rules)))
b4616cab2c9531ea25b080171d4dfc481576fe082fb81831495b16d824a60442	from sympy.matrices.expressions.blockmatrix import (block_collapse, bc_matmul, bc_block_plus_ident, BlockDiagMatrix, BlockMatrix, bc_dist, bc_matadd, bc_transpose, blockcut, reblock_2x2, deblock) from sympy.matrices.expressions import (MatrixSymbol, Identity, Inverse, trace, Transpose, det) from sympy.matrices import Matrix, ImmutableMatrix, ones from sympy.core import Tuple, symbols, Expr from sympy.core.compatibility import range from sympy.functions import transpose i, j, k, l, m, n, p = symbols('i:n, p', integer=True) A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, n) C = MatrixSymbol('C', n, n) D = MatrixSymbol('D', n, n) G = MatrixSymbol('G', n, n) H = MatrixSymbol('H', n, n) b1 = BlockMatrix([[G, H]]) b2 = BlockMatrix([[G], [H]]) def test_bc_matmul(): assert bc_matmul(Hb1b2G) == BlockMatrix([[(HGG + HHH)G]]) def test_bc_matadd(): assert bc_matadd(BlockMatrix([[G, H]]) + BlockMatrix([[H, H]])) == \ BlockMatrix([[G+H, H+H]]) def test_bc_transpose(): assert bc_transpose(Transpose(BlockMatrix([[A, B], [C, D]]))) == \ BlockMatrix([[A.T, C.T], [B.T, D.T]]) def test_bc_dist_diag(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', m, m) C = MatrixSymbol('C', l, l) X = BlockDiagMatrix(A, B, C) assert bc_dist(X+X).equals(BlockDiagMatrix(2A, 2B, 2C)) def test_block_plus_ident(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, m) C = MatrixSymbol('C', m, n) D = MatrixSymbol('D', m, m) X = BlockMatrix([[A, B], [C, D]]) assert bc_block_plus_ident(X+Identity(m+n)) == \ BlockDiagMatrix(Identity(n), Identity(m)) + X def test_BlockMatrix(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', n, k) C = MatrixSymbol('C', l, m) D = MatrixSymbol('D', l, k) M = MatrixSymbol('M', m + k, p) N = MatrixSymbol('N', l + n, k + m) X = BlockMatrix(Matrix([[A, B], [C, D]])) assert X.__class__(X.args) == X # block_collapse does nothing on normal inputs E = MatrixSymbol('E', n, m) assert block_collapse(A + 2E) == A + 2E F = MatrixSymbol('F', m, m) assert block_collapse(E.TAF) == E.TAF assert X.shape == (l + n, k + m) assert X.blockshape == (2, 2) assert transpose(X) == BlockMatrix(Matrix([[A.T, C.T], [B.T, D.T]])) assert transpose(X).shape == X.shape[::-1] # Test that BlockMatrices and MatrixSymbols can still mix assert (XM).is_MatMul assert X._blockmul(M).is_MatMul assert (XM).shape == (n + l, p) assert (X + N).is_MatAdd assert X._blockadd(N).is_MatAdd assert (X + N).shape == X.shape E = MatrixSymbol('E', m, 1) F = MatrixSymbol('F', k, 1) Y = BlockMatrix(Matrix([[E], [F]])) assert (XY).shape == (l + n, 1) assert block_collapse(XY).blocks[0, 0] == AE + BF assert block_collapse(XY).blocks[1, 0] == CE + DF # block_collapse passes down into container objects, transposes, and inverse assert block_collapse(transpose(XY)) == transpose(block_collapse(XY)) assert block_collapse(Tuple(XY, 2X)) == ( block_collapse(XY), block_collapse(2X)) # Make sure that MatrixSymbols will enter 1x1 BlockMatrix if it simplifies Ab = BlockMatrix([[A]]) Z = MatrixSymbol('Z', A.shape) assert block_collapse(Ab + Z) == A + Z def test_BlockMatrix_trace(): A, B, C, D = [MatrixSymbol(s, 3, 3) for s in 'ABCD'] X = BlockMatrix([[A, B], [C, D]]) assert trace(X) == trace(A) + trace(D) def test_BlockMatrix_Determinant(): A, B, C, D = [MatrixSymbol(s, 3, 3) for s in 'ABCD'] X = BlockMatrix([[A, B], [C, D]]) from sympy import assuming, Q with assuming(Q.invertible(A)): assert det(X) == det(A) * det(D - CA.IB) assert isinstance(det(X), Expr) def test_squareBlockMatrix(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, m) C = MatrixSymbol('C', m, n) D = MatrixSymbol('D', m, m) X = BlockMatrix([[A, B], [C, D]]) Y = BlockMatrix([[A]]) assert X.is_square assert (block_collapse(X + Identity(m + n)) == BlockMatrix([[A + Identity(n), B], [C, D + Identity(m)]])) Q = X + Identity(m + n) assert (X + MatrixSymbol('Q', n + m, n + m)).is_MatAdd assert (X * MatrixSymbol('Q', n + m, n + m)).is_MatMul assert block_collapse(Y.I) == A.I assert block_collapse(X.inverse()) == BlockMatrix([ [(-BD.IC + A).I, -A.IB(D + -CA.IB).I], [-(D - CA.IB).ICA.I, (D - CA.IB).I]]) assert isinstance(X.inverse(), Inverse) assert not X.is_Identity Z = BlockMatrix([[Identity(n), B], [C, D]]) assert not Z.is_Identity def test_BlockDiagMatrix(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', m, m) C = MatrixSymbol('C', l, l) M = MatrixSymbol('M', n + m + l, n + m + l) X = BlockDiagMatrix(A, B, C) Y = BlockDiagMatrix(A, 2B, 3C) assert X.blocks[1, 1] == B assert X.shape == (n + m + l, n + m + l) assert all(X.blocks[i, j].is_ZeroMatrix if i != j else X.blocks[i, j] in [A, B, C] for i in range(3) for j in range(3)) assert X.__class__(X.args) == X assert isinstance(block_collapse(X.I X), Identity) assert bc_matmul(XX) == BlockDiagMatrix(AA, BB, CC) assert block_collapse(XX) == BlockDiagMatrix(AA, BB, CC) #XXX: should be == ?? assert block_collapse(X + X).equals(BlockDiagMatrix(2A, 2B, 2C)) assert block_collapse(XY) == BlockDiagMatrix(AA, 2BB, 3CC) assert block_collapse(X + Y) == BlockDiagMatrix(2A, 3B, 4C) # Ensure that BlockDiagMatrices can still interact with normal MatrixExprs assert (X(2M)).is_MatMul assert (X + (2*M)).is_MatAdd assert (X._blockmul(M)).is_MatMul assert (X._blockadd(M)).is_MatAdd def test_blockcut(): A = MatrixSymbol('A', n, m) B = blockcut(A, (n/2, n/2), (m/2, m/2)) assert A[i, j] == B[i, j] assert B == BlockMatrix([[A[:n/2, :m/2], A[:n/2, m/2:]], [A[n/2:, :m/2], A[n/2:, m/2:]]]) M = ImmutableMatrix(4, 4, range(16)) B = blockcut(M, (2, 2), (2, 2)) assert M == ImmutableMatrix(B) B = blockcut(M, (1, 3), (2, 2)) assert ImmutableMatrix(B.blocks[0, 1]) == ImmutableMatrix([[2, 3]]) def test_reblock_2x2(): B = BlockMatrix([[MatrixSymbol('A_%d%d'%(i,j), 2, 2) for j in range(3)] for i in range(3)]) assert B.blocks.shape == (3, 3) BB = reblock_2x2(B) assert BB.blocks.shape == (2, 2) assert B.shape == BB.shape assert B.as_explicit() == BB.as_explicit() def test_deblock(): B = BlockMatrix([[MatrixSymbol('A_%d%d'%(i,j), n, n) for j in range(4)] for i in range(4)]) assert deblock(reblock_2x2(B)) == B
4d80c000291c5c7ce096dc58a0107e44cac2ba84a6478cfe001f85a37c660616	""" Some examples have been taken from: http://www.math.uwaterloo.ca/~hwolkowi//matrixcookbook.pdf """ from sympy import MatrixSymbol, Inverse, symbols, Determinant, Trace, Derivative, sin, exp, cos, tan, log from sympy import MatAdd, Identity, MatMul, ZeroMatrix k = symbols("k") X = MatrixSymbol("X", k, k) x = MatrixSymbol("x", k, 1) y = MatrixSymbol("y", k, 1) A = MatrixSymbol("A", k, k) B = MatrixSymbol("B", k, k) C = MatrixSymbol("C", k, k) D = MatrixSymbol("D", k, k) a = MatrixSymbol("a", k, 1) b = MatrixSymbol("b", k, 1) c = MatrixSymbol("c", k, 1) d = MatrixSymbol("d", k, 1) def _check_derivative_with_explicit_matrix(expr, x, diffexpr, dim=2): # TODO: this is commented because it slows down the tests. return expr = expr.xreplace({k: dim}) x = x.xreplace({k: dim}) diffexpr = diffexpr.xreplace({k: dim}) expr = expr.as_explicit() x = x.as_explicit() diffexpr = diffexpr.as_explicit() assert expr.diff(x).reshape(diffexpr.shape).tomatrix() == diffexpr def test_matrix_derivative_non_matrix_result(): # This is a 4-dimensional array: assert A.diff(A) == Derivative(A, A) assert A.T.diff(A) == Derivative(A.T, A) assert (2A).diff(A) == Derivative(2A, A) assert MatAdd(A, A).diff(A) == Derivative(MatAdd(A, A), A) assert (A + B).diff(A) == Derivative(A + B, A) # TODO: `B` can be removed. def test_matrix_derivative_trivial_cases(): # Cookbook example 33: # TODO: find a way to represent a four-dimensional zero-array: assert X.diff(A) == Derivative(X, A) def test_matrix_derivative_with_inverse(): # Cookbook example 61: expr = a.TInverse(X)b assert expr.diff(X) == -Inverse(X).Tab.TInverse(X).T # Cookbook example 62: expr = Determinant(Inverse(X)) # Not implemented yet: # assert expr.diff(X) == -Determinant(X.inv())(X.inv()).T # Cookbook example 63: expr = Trace(AInverse(X)B) assert expr.diff(X) == -(X(-1)BAX(-1)).T # Cookbook example 64: expr = Trace(Inverse(X + A)) assert expr.diff(X) == -(Inverse(X + A)).T2 def test_matrix_derivative_vectors_and_scalars(): assert x.diff(x) == Identity(k) assert x.T.diff(x) == Identity(k) # Cookbook example 69: expr = x.Ta assert expr.diff(x) == a expr = a.Tx assert expr.diff(x) == a # Cookbook example 70: expr = a.TXb assert expr.diff(X) == ab.T # Cookbook example 71: expr = a.TX.Tb assert expr.diff(X) == ba.T # Cookbook example 72: expr = a.TXa assert expr.diff(X) == aa.T expr = a.TX.Ta assert expr.diff(X) == aa.T # Cookbook example 77: expr = b.TX.TXc assert expr.diff(X) == Xbc.T + Xcb.T # Cookbook example 78: expr = (Bx + b).TC(Dx + d) assert expr.diff(x) == B.TC(Dx + d) + D.TC.T(Bx + b) # Cookbook example 81: expr = x.TBx assert expr.diff(x) == Bx + B.Tx # Cookbook example 82: expr = b.TX.TDXc assert expr.diff(X) == D.TXbc.T + DXcb.T # Cookbook example 83: expr = (Xb + c).TD(Xb + c) assert expr.diff(X) == D(Xb + c)b.T + D.T(Xb + c)b.T def test_matrix_derivatives_of_traces(): expr = Trace(A)A assert expr.diff(A) == Derivative(Trace(A)A, A) ## First order: # Cookbook example 99: expr = Trace(X) assert expr.diff(X) == Identity(k) # Cookbook example 100: expr = Trace(XA) assert expr.diff(X) == A.T # Cookbook example 101: expr = Trace(AXB) assert expr.diff(X) == A.TB.T # Cookbook example 102: expr = Trace(AX.TB) assert expr.diff(X) == BA # Cookbook example 103: expr = Trace(X.TA) assert expr.diff(X) == A # Cookbook example 104: expr = Trace(AX.T) assert expr.diff(X) == A # Cookbook example 105: # TODO: TensorProduct is not supported #expr = Trace(TensorProduct(A, X)) #assert expr.diff(X) == Trace(A)Identity(k) ## Second order: # Cookbook example 106: expr = Trace(X2) assert expr.diff(X) == 2X.T # Cookbook example 107: expr = Trace(X*2B) assert expr.diff(X) == (XB + BX).T expr = Trace(MatMul(X, X, B)) assert expr.diff(X) == (XB + BX).T # Cookbook example 108: expr = Trace(X.TBX) assert expr.diff(X) == BX + B.TX # Cookbook example 109: expr = Trace(BXX.T) assert expr.diff(X) == BX + B.TX # Cookbook example 110: expr = Trace(XX.TB) assert expr.diff(X) == BX + B.TX # Cookbook example 111: expr = Trace(XBX.T) assert expr.diff(X) == XB.T + XB # Cookbook example 112: expr = Trace(BX.TX) assert expr.diff(X) == XB.T + XB # Cookbook example 113: expr = Trace(X.TXB) assert expr.diff(X) == XB.T + XB # Cookbook example 114: expr = Trace(AXBX) assert expr.diff(X) == A.TX.TB.T + B.TX.TA.T # Cookbook example 115: expr = Trace(X.TX) assert expr.diff(X) == 2X expr = Trace(XX.T) assert expr.diff(X) == 2X # Cookbook example 116: expr = Trace(B.TX.TCXB) assert expr.diff(X) == C.TXBB.T + CXBB.T # Cookbook example 117: expr = Trace(X.TBXC) assert expr.diff(X) == BXC + B.TXC.T # Cookbook example 118: expr = Trace(AXBX.TC) assert expr.diff(X) == A.TC.TXB.T + CAXB # Cookbook example 119: expr = Trace((AXB + C)(AXB + C).T) assert expr.diff(X) == 2A.T(AXB + C)B.T # Cookbook example 120: # TODO: no support for TensorProduct. # expr = Trace(TensorProduct(X, X)) # expr = Trace(X)Trace(X) # expr.diff(X) == 2Trace(X)Identity(k) # Higher Order # Cookbook example 121: expr = Trace(Xk) #assert expr.diff(X) == k(X*(k-1)).T # Cookbook example 122: expr = Trace(AX*k) #assert expr.diff(X) == # Needs indices # Cookbook example 123: expr = Trace(B.TX.TCXX.TCXB) assert expr.diff(X) == CXX.TCXBB.T + C.TXBB.TX.TC.TX + CXBB.TX.TCX + C.TXX.TC.TXBB.T # Other # Cookbook example 124: expr = Trace(AX(-1)B) assert expr.diff(X) == -Inverse(X).TA.TB.TInverse(X).T # Cookbook example 125: expr = Trace(Inverse(X.TCX)A) # Warning: result in the cookbook is equivalent if B and C are symmetric: assert expr.diff(X) == - X.inv().TA.TX.inv()C.inv().TX.inv().T - X.inv().TAX.inv()C.inv()X.inv().T # Cookbook example 126: expr = Trace((X.TCX).inv()(X.TBX)) assert expr.diff(X) == -2CX(X.TCX).inv()X.TBX(X.TCX).inv() + 2BX(X.TCX).inv() # Cookbook example 127: expr = Trace((A + X.TCX).inv()(X.TBX)) # Warning: result in the cookbook is equivalent if B and C are symmetric: assert expr.diff(X) == BXInverse(A + X.TCX) - CXInverse(A + X.TCX)X.TBXInverse(A + X.TCX) - C.TXInverse(A.T + (CX).TX)X.TB.TXInverse(A.T + (CX).TX) + B.TXInverse(A.T + (CX).TX) def test_derivatives_of_complicated_matrix_expr(): expr = a.T(AX(X.TB + XA) + B.TX.T(ab.T(XDX.T + X(X.TB + AX)DB - X.TC.TA)B + B(XD.T + BAXA.T - 3XD))B + 42XBX.TA.T(X + X.T))b result = (B(BAXA.T - 3XD + XD.T) + ab.T(X(AX + X.TB)DB + XDX.T - X.TC.TA)B)Bba.TB.T + B*2ba.TB.TX.Tab.TXD + 42AXB.TX.Tab.T + BDB3ba.TB.TX.Tab.TX + Bba.TAX + 42ab.T(X + X.T)AXB.T + ba.TXBab.TB.T*2XD.T + ba.TXBab.TB.T3D.T(B.TX + X.TA.T) + 42ba.TXBX.TA.T + 42A.T(X + X.T)ba.TXB + A.TB.T*2XBab.TB.TA + A.Tab.T(A.TX.T + B.TX) + A.TX.Tba.TXBab.TB.T*3D.T + B.TXBab.TB.TD - 3B.TXBab.TB.TD.T - C.TAB2ba.TB.TX.Tab.T + X.TA.Tab.TA.T assert expr.diff(X) == result def test_mixed_deriv_mixed_expressions(): expr = 3Trace(A) assert expr.diff(A) == 3Identity(k) expr = k deriv = expr.diff(A) assert isinstance(deriv, ZeroMatrix) assert deriv == ZeroMatrix(k, k) expr = Trace(A)2 assert expr.diff(A) == (2Trace(A))Identity(k) expr = Trace(A)A # TODO: this is not yet supported: assert expr.diff(A) == Derivative(expr, A) expr = Trace(Trace(A)A) assert expr.diff(A) == (2Trace(A))Identity(k) expr = Trace(Trace(Trace(A)A)A) assert expr.diff(A) == (3Trace(A)*2)Identity(k) def test_derivatives_elementwise_applyfunc(): from sympy.matrices.expressions.diagonal import DiagonalizeVector expr = x.applyfunc(tan) assert expr.diff(x) == DiagonalizeVector(x.applyfunc(lambda x: tan(x)*2 + 1)) _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = Ax.applyfunc(exp) assert expr.diff(x) == DiagonalizeVector(x.applyfunc(exp))A.T _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = x.TAx + ky.applyfunc(sin).Tx assert expr.diff(x) == A.Tx + Ax + ky.applyfunc(sin) _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = x.applyfunc(sin).Ty assert expr.diff(x) == DiagonalizeVector(x.applyfunc(cos))y _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = (a.T * X * b).applyfunc(sin) assert expr.diff(X) == a(a.TXb).applyfunc(cos)b.T _check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * X.applyfunc(sin) * b assert expr.diff(X) == DiagonalizeVector(a)X.applyfunc(cos)DiagonalizeVector(b) _check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * (AXB).applyfunc(sin) * b assert expr.diff(X) == A.TDiagonalizeVector(a)(AXB).applyfunc(cos)DiagonalizeVector(b)B.T _check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * (AXb).applyfunc(sin) * b.T # TODO: not implemented #assert expr.diff(X) == ... #_check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * (AX.applyfunc(sin)B).applyfunc(log) * b # assert expr.diff(X) == ... expr = a.T * (X.applyfunc(sin)).applyfunc(log) * b # assert expr.diff(X) == ...
97074ccdaed08509fe02c2d47912608af6efd30040a53c867171b9cf08a029ea	from sympy import (KroneckerDelta, diff, Piecewise, Sum, Dummy, factor, expand, zeros, gcd_terms, Eq) from sympy.core import S, symbols, Add, Mul, SympifyError from sympy.core.compatibility import long from sympy.functions import transpose, sin, cos, sqrt, cbrt, exp from sympy.simplify import simplify from sympy.matrices import (Identity, ImmutableMatrix, Inverse, MatAdd, MatMul, MatPow, Matrix, MatrixExpr, MatrixSymbol, ShapeError, ZeroMatrix, SparseMatrix, Transpose, Adjoint) from sympy.matrices.expressions.matexpr import (MatrixElement, GenericZeroMatrix, GenericIdentity) from sympy.utilities.pytest import raises, XFAIL n, m, l, k, p = symbols('n m l k p', integer=True) x = symbols('x') A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) C = MatrixSymbol('C', n, n) D = MatrixSymbol('D', n, n) E = MatrixSymbol('E', m, n) w = MatrixSymbol('w', n, 1) def test_shape(): assert A.shape == (n, m) assert (AB).shape == (n, l) raises(ShapeError, lambda: BA) def test_matexpr(): assert (xA).shape == A.shape assert (xA).__class__ == MatMul assert 2A - A - A == ZeroMatrix(A.shape) assert (AB).shape == (n, l) def test_subs(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) C = MatrixSymbol('C', m, l) assert A.subs(n, m).shape == (m, m) assert (AB).subs(B, C) == AC assert (AB).subs(l, n).is_square def test_ZeroMatrix(): A = MatrixSymbol('A', n, m) Z = ZeroMatrix(n, m) assert A + Z == A assert AZ.T == ZeroMatrix(n, n) assert ZA.T == ZeroMatrix(n, n) assert A - A == ZeroMatrix(A.shape) assert not Z assert transpose(Z) == ZeroMatrix(m, n) assert Z.conjugate() == Z assert ZeroMatrix(n, n)0 == Identity(n) with raises(ShapeError): Z0 with raises(ShapeError): Z2 def test_ZeroMatrix_doit(): Znn = ZeroMatrix(Add(n, n, evaluate=False), n) assert isinstance(Znn.rows, Add) assert Znn.doit() == ZeroMatrix(2n, n) assert isinstance(Znn.doit().rows, Mul) def test_Identity(): A = MatrixSymbol('A', n, m) i, j = symbols('i j') In = Identity(n) Im = Identity(m) assert AIm == A assert InA == A assert transpose(In) == In assert In.inverse() == In assert In.conjugate() == In assert In[i, j] != 0 assert Sum(In[i, j], (i, 0, n-1), (j, 0, n-1)).subs(n,3).doit() == 3 assert Sum(Sum(In[i, j], (i, 0, n-1)), (j, 0, n-1)).subs(n,3).doit() == 3 def test_Identity_doit(): Inn = Identity(Add(n, n, evaluate=False)) assert isinstance(Inn.rows, Add) assert Inn.doit() == Identity(2n) assert isinstance(Inn.doit().rows, Mul) def test_addition(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', n, m) assert isinstance(A + B, MatAdd) assert (A + B).shape == A.shape assert isinstance(A - A + 2B, MatMul) raises(ShapeError, lambda: A + B.T) raises(TypeError, lambda: A + 1) raises(TypeError, lambda: 5 + A) raises(TypeError, lambda: 5 - A) assert A + ZeroMatrix(n, m) - A == ZeroMatrix(n, m) with raises(TypeError): ZeroMatrix(n,m) + S(0) def test_multiplication(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) C = MatrixSymbol('C', n, n) assert (2AB).shape == (n, l) assert (A0B) == ZeroMatrix(n, l) raises(ShapeError, lambda: BA) assert (2A).shape == A.shape assert A * ZeroMatrix(m, m) * B == ZeroMatrix(n, l) assert C * Identity(n) * C.I == Identity(n) assert B/2 == S.HalfB raises(NotImplementedError, lambda: 2/B) A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, n) assert Identity(n) (A + B) == A + B assert A*2A == A3 assert A2(A.I)3 == A.I assert A3(A.I)2 == A def test_MatPow(): A = MatrixSymbol('A', n, n) AA = MatPow(A, 2) assert AA.exp == 2 assert AA.base == A assert (An).exp == n assert A0 == Identity(n) assert A1 == A assert A2 == AA assert A-1 == Inverse(A) assert (A-1)-1 == A assert (A2)3 == A6 assert AS.Half == sqrt(A) assert A(S(1)/3) == cbrt(A) raises(ShapeError, lambda: MatrixSymbol('B', 3, 2)2) def test_MatrixSymbol(): n, m, t = symbols('n,m,t') X = MatrixSymbol('X', n, m) assert X.shape == (n, m) raises(TypeError, lambda: MatrixSymbol('X', n, m)(t)) # issue 5855 assert X.doit() == X def test_dense_conversion(): X = MatrixSymbol('X', 2, 2) assert ImmutableMatrix(X) == ImmutableMatrix(2, 2, lambda i, j: X[i, j]) assert Matrix(X) == Matrix(2, 2, lambda i, j: X[i, j]) def test_free_symbols(): assert (CD).free_symbols == set((C, D)) def test_zero_matmul(): assert isinstance(S.Zero MatrixSymbol('X', 2, 2), MatrixExpr) def test_matadd_simplify(): A = MatrixSymbol('A', 1, 1) assert simplify(MatAdd(A, ImmutableMatrix([[sin(x)2 + cos(x)2]]))) == \ MatAdd(A, ImmutableMatrix([[1]])) def test_matmul_simplify(): A = MatrixSymbol('A', 1, 1) assert simplify(MatMul(A, ImmutableMatrix([[sin(x)2 + cos(x)2]]))) == \ MatMul(A, ImmutableMatrix([[1]])) def test_invariants(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) X = MatrixSymbol('X', n, n) objs = [Identity(n), ZeroMatrix(m, n), A, MatMul(A, B), MatAdd(A, A), Transpose(A), Adjoint(A), Inverse(X), MatPow(X, 2), MatPow(X, -1), MatPow(X, 0)] for obj in objs: assert obj == obj.__class__(obj.args) def test_indexing(): A = MatrixSymbol('A', n, m) A[1, 2] A[l, k] A[l+1, k+1] def test_single_indexing(): A = MatrixSymbol('A', 2, 3) assert A[1] == A[0, 1] assert A[long(1)] == A[0, 1] assert A[3] == A[1, 0] assert list(A[:2, :2]) == [A[0, 0], A[0, 1], A[1, 0], A[1, 1]] raises(IndexError, lambda: A[6]) raises(IndexError, lambda: A[n]) B = MatrixSymbol('B', n, m) raises(IndexError, lambda: B[1]) B = MatrixSymbol('B', n, 3) assert B[3] == B[1, 0] def test_MatrixElement_commutative(): assert A[0, 1]A[1, 0] == A[1, 0]A[0, 1] def test_MatrixSymbol_determinant(): A = MatrixSymbol('A', 4, 4) assert A.as_explicit().det() == A[0, 0]A[1, 1]A[2, 2]A[3, 3] - \ A[0, 0]A[1, 1]A[2, 3]A[3, 2] - A[0, 0]A[1, 2]A[2, 1]A[3, 3] + \ A[0, 0]A[1, 2]A[2, 3]A[3, 1] + A[0, 0]A[1, 3]A[2, 1]A[3, 2] - \ A[0, 0]A[1, 3]A[2, 2]A[3, 1] - A[0, 1]A[1, 0]A[2, 2]A[3, 3] + \ A[0, 1]A[1, 0]A[2, 3]A[3, 2] + A[0, 1]A[1, 2]A[2, 0]A[3, 3] - \ A[0, 1]A[1, 2]A[2, 3]A[3, 0] - A[0, 1]A[1, 3]A[2, 0]A[3, 2] + \ A[0, 1]A[1, 3]A[2, 2]A[3, 0] + A[0, 2]A[1, 0]A[2, 1]A[3, 3] - \ A[0, 2]A[1, 0]A[2, 3]A[3, 1] - A[0, 2]A[1, 1]A[2, 0]A[3, 3] + \ A[0, 2]A[1, 1]A[2, 3]A[3, 0] + A[0, 2]A[1, 3]A[2, 0]A[3, 1] - \ A[0, 2]A[1, 3]A[2, 1]A[3, 0] - A[0, 3]A[1, 0]A[2, 1]A[3, 2] + \ A[0, 3]A[1, 0]A[2, 2]A[3, 1] + A[0, 3]A[1, 1]A[2, 0]A[3, 2] - \ A[0, 3]A[1, 1]A[2, 2]A[3, 0] - A[0, 3]A[1, 2]A[2, 0]A[3, 1] + \ A[0, 3]A[1, 2]A[2, 1]A[3, 0] def test_MatrixElement_diff(): assert (A[3, 0]A[0, 0]).diff(A[0, 0]) == A[3, 0] def test_MatrixElement_doit(): u = MatrixSymbol('u', 2, 1) v = ImmutableMatrix([3, 5]) assert u[0, 0].subs(u, v).doit() == v[0, 0] def test_identity_powers(): M = Identity(n) assert MatPow(M, 3).doit() == M3 assert Mn == M assert MatPow(M, 0).doit() == M2 assert M-2 == M assert MatPow(M, -2).doit() == M0 N = Identity(3) assert MatPow(N, 2).doit() == Nn assert MatPow(N, 3).doit() == N assert MatPow(N, -2).doit() == N4 assert MatPow(N, 2).doit() == N0 def test_Zero_power(): z1 = ZeroMatrix(n, n) assert z14 == z1 raises(ValueError, lambda:z1-2) assert z10 == Identity(n) assert MatPow(z1, 2).doit() == z12 raises(ValueError, lambda:MatPow(z1, -2).doit()) z2 = ZeroMatrix(3, 3) assert MatPow(z2, 4).doit() == z24 raises(ValueError, lambda:z2-3) assert z23 == MatPow(z2, 3).doit() assert z20 == Identity(3) raises(ValueError, lambda:MatPow(z2, -1).doit()) def test_matrixelement_diff(): dexpr = diff((Dw)[k,0], w[p,0]) assert w[k, p].diff(w[k, p]) == 1 assert w[k, p].diff(w[0, 0]) == KroneckerDelta(0, k)KroneckerDelta(0, p) assert str(dexpr) == "Sum(KroneckerDelta(_i_1, p)D[k, _i_1], (_i_1, 0, n - 1))" assert str(dexpr.doit()) == 'Piecewise((D[k, p], (p >= 0) & (p <= n - 1)), (0, True))' # TODO: bug with .dummy_eq( ), the previous 2 lines should be replaced by: return # stop eval _i_1 = Dummy("_i_1") assert dexpr.dummy_eq(Sum(KroneckerDelta(_i_1, p)D[k, _i_1], (_i_1, 0, n - 1))) assert dexpr.doit().dummy_eq(Piecewise((D[k, p], (p >= 0) & (p <= n - 1)), (0, True))) def test_MatrixElement_with_values(): x, y, z, w = symbols("x y z w") M = Matrix([[x, y], [z, w]]) i, j = symbols("i, j") Mij = M[i, j] assert isinstance(Mij, MatrixElement) Ms = SparseMatrix([[2, 3], [4, 5]]) msij = Ms[i, j] assert isinstance(msij, MatrixElement) for oi, oj in [(0, 0), (0, 1), (1, 0), (1, 1)]: assert Mij.subs({i: oi, j: oj}) == M[oi, oj] assert msij.subs({i: oi, j: oj}) == Ms[oi, oj] A = MatrixSymbol("A", 2, 2) assert A[0, 0].subs(A, M) == x assert A[i, j].subs(A, M) == M[i, j] assert M[i, j].subs(M, A) == A[i, j] assert isinstance(M[3i - 2, j], MatrixElement) assert M[3i - 2, j].subs({i: 1, j: 0}) == M[1, 0] assert isinstance(M[i, 0], MatrixElement) assert M[i, 0].subs(i, 0) == M[0, 0] assert M[0, i].subs(i, 1) == M[0, 1] assert M[i, j].diff(x) == Matrix([[1, 0], [0, 0]])[i, j] raises(ValueError, lambda: M[i, 2]) raises(ValueError, lambda: M[i, -1]) raises(ValueError, lambda: M[2, i]) raises(ValueError, lambda: M[-1, i]) def test_inv(): B = MatrixSymbol('B', 3, 3) assert B.inv() == B*-1 @XFAIL def test_factor_expand(): A = MatrixSymbol("A", n, n) B = MatrixSymbol("B", n, n) expr1 = (A + B)(C + D) expr2 = AC + BC + AD + BD assert expr1 != expr2 assert expand(expr1) == expr2 assert factor(expr2) == expr1 expr = B*(-1)(A*(-1)B(-1) - A(-1)CB(-1))(-1)A(-1) I = Identity(n) # Ideally we get the first, but we at least don't want a wrong answer assert factor(expr) in [I - C, B-1(A*-1(I - C)B-1)-1A*-1] def test_issue_2749(): A = MatrixSymbol("A", 5, 2) assert (A.T A).I.as_explicit() == Matrix([[(A.T * A).I[0, 0], (A.T * A).I[0, 1]], \ [(A.T * A).I[1, 0], (A.T * A).I[1, 1]]]) def test_issue_2750(): x = MatrixSymbol('x', 1, 1) assert (x.Tx).as_explicit()-1 == Matrix([[x[0, 0](-2)]]) def test_issue_7842(): A = MatrixSymbol('A', 3, 1) B = MatrixSymbol('B', 2, 1) assert Eq(A, B) == False assert Eq(A[1,0], B[1, 0]).func is Eq A = ZeroMatrix(2, 3) B = ZeroMatrix(2, 3) assert Eq(A, B) == True def test_generic_zero_matrix(): z = GenericZeroMatrix() A = MatrixSymbol("A", n, n) assert z == z assert z != A assert A != z assert z.is_ZeroMatrix raises(TypeError, lambda: z.shape) raises(TypeError, lambda: z.rows) raises(TypeError, lambda: z.cols) assert MatAdd() == z assert MatAdd(z, A) == MatAdd(A) # Make sure it is hashable hash(z) def test_generic_identity(): I = GenericIdentity() A = MatrixSymbol("A", n, n) assert I == I assert I != A assert A != I assert I.is_Identity assert I-1 == I raises(TypeError, lambda: I.shape) raises(TypeError, lambda: I.rows) raises(TypeError, lambda: I.cols) assert MatMul() == I assert MatMul(I, A) == MatMul(A) # Make sure it is hashable hash(I) def test_MatMul_postprocessor(): z = zeros(2) z1 = ZeroMatrix(2, 2) assert Mul(0, z) == Mul(z, 0) in [z, z1] M = Matrix([[1, 2], [3, 4]]) Mx = Matrix([[x, 2x], [3x, 4x]]) assert Mul(x, M) == Mul(M, x) == Mx A = MatrixSymbol("A", 2, 2) assert Mul(A, M) == MatMul(A, M) assert Mul(M, A) == MatMul(M, A) # Scalars should be absorbed into constant matrices a = Mul(x, M, A) b = Mul(M, x, A) c = Mul(M, A, x) assert a == b == c == MatMul(Mx, A) a = Mul(x, A, M) b = Mul(A, x, M) c = Mul(A, M, x) assert a == b == c == MatMul(A, Mx) assert Mul(M, M) == M2 assert Mul(A, M, M) == MatMul(A, M2) assert Mul(M, M, A) == MatMul(M2, A) assert Mul(M, A, M) == MatMul(M, A, M) assert Mul(A, x, M, M, x) == MatMul(A, Mx2) @XFAIL def test_MatAdd_postprocessor_xfail(): # This is difficult to get working because of the way that Add processes # its args. z = zeros(2) assert Add(z, S.NaN) == Add(S.NaN, z) def test_MatAdd_postprocessor(): # Some of these are nonsensical, but we do not raise errors for Add # because that breaks algorithms that want to replace matrices with dummy # symbols. z = zeros(2) assert Add(0, z) == Add(z, 0) == z a = Add(S.Infinity, z) assert a == Add(z, S.Infinity) assert isinstance(a, Add) assert a.args == (S.Infinity, z) a = Add(S.ComplexInfinity, z) assert a == Add(z, S.ComplexInfinity) assert isinstance(a, Add) assert a.args == (S.ComplexInfinity, z) a = Add(z, S.NaN) # assert a == Add(S.NaN, z) # See the XFAIL above assert isinstance(a, Add) assert a.args == (S.NaN, z) M = Matrix([[1, 2], [3, 4]]) a = Add(x, M) assert a == Add(M, x) assert isinstance(a, Add) assert a.args == (x, M) A = MatrixSymbol("A", 2, 2) assert Add(A, M) == Add(M, A) == A + M # Scalars should be absorbed into constant matrices (producing an error) a = Add(x, M, A) assert a == Add(M, x, A) == Add(M, A, x) == Add(x, A, M) == Add(A, x, M) == Add(A, M, x) assert isinstance(a, Add) assert a.args == (x, A + M) assert Add(M, M) == 2M assert Add(M, A, M) == Add(M, M, A) == Add(A, M, M) == A + 2M a = Add(A, x, M, M, x) assert isinstance(a, Add) assert a.args == (2x, A + 2M) def test_simplify_matrix_expressions(): # Various simplification functions assert type(gcd_terms(CD + DC)) == MatAdd a = gcd_terms(2CD + 4DC) assert type(a) == MatMul assert a.args == (2, (CD + 2DC)) def test_exp(): A = MatrixSymbol('A', 2, 2) B = MatrixSymbol('B', 2, 2) expr1 = exp(A)exp(B) expr2 = exp(B)*exp(A) assert expr1 != expr2 assert expr1 - expr2 != 0 assert not isinstance(expr1, exp) assert not isinstance(expr2, exp) def test_invalid_args(): raises(SympifyError, lambda: MatrixSymbol(1, 2, 'A'))
0baf4ec1f64124064f718a76bd0546f178333f73b310093f24fe921dadc43dfc	from sympy.matrices.expressions import MatrixSymbol from sympy.matrices.expressions.diagonal import DiagonalMatrix, DiagonalOf, DiagonalizeVector, diagonalize_vector from sympy import Symbol, ask, Q, KroneckerDelta, Identity, Matrix from sympy.utilities.pytest import raises n = Symbol('n') m = Symbol('m') def test_DiagonalMatrix(): x = MatrixSymbol('x', n, m) D = DiagonalMatrix(x) assert D.diagonal_length is None assert D.shape == (n, m) x = MatrixSymbol('x', n, n) D = DiagonalMatrix(x) assert D.diagonal_length == n assert D.shape == (n, n) assert D[1, 2] == 0 assert D[1, 1] == x[1, 1] i = Symbol('i') j = Symbol('j') x = MatrixSymbol('x', 3, 3) ij = DiagonalMatrix(x)[i, j] assert ij != 0 assert ij.subs({i:0, j:0}) == x[0, 0] assert ij.subs({i:0, j:1}) == 0 assert ij.subs({i:1, j:1}) == x[1, 1] assert ask(Q.diagonal(D)) # affirm that D is diagonal x = MatrixSymbol('x', n, 3) D = DiagonalMatrix(x) assert D.diagonal_length == 3 assert D.shape == (n, 3) assert D[2, m] == KroneckerDelta(2, m)x[2, m] assert D[3, m] == 0 raises(IndexError, lambda: D[m, 3]) x = MatrixSymbol('x', 3, n) D = DiagonalMatrix(x) assert D.diagonal_length == 3 assert D.shape == (3, n) assert D[m, 2] == KroneckerDelta(m, 2)x[m, 2] assert D[m, 3] == 0 raises(IndexError, lambda: D[3, m]) x = MatrixSymbol('x', n, m) D = DiagonalMatrix(x) assert D.diagonal_length is None assert D.shape == (n, m) assert D[m, 4] != 0 x = MatrixSymbol('x', 3, 4) assert [DiagonalMatrix(x)[i] for i in range(12)] == [ x[0, 0], 0, 0, 0, 0, x[1, 1], 0, 0, 0, 0, x[2, 2], 0] # shape is retained, issue 12427 assert ( DiagonalMatrix(MatrixSymbol('x', 3, 4))* DiagonalMatrix(MatrixSymbol('x', 4, 2))).shape == (3, 2) def test_DiagonalOf(): x = MatrixSymbol('x', n, n) d = DiagonalOf(x) assert d.shape == (n, 1) assert d.diagonal_length == n assert d[2, 0] == d[2] == x[2, 2] x = MatrixSymbol('x', n, m) d = DiagonalOf(x) assert d.shape == (None, 1) assert d.diagonal_length is None assert d[2, 0] == d[2] == x[2, 2] d = DiagonalOf(MatrixSymbol('x', 4, 3)) assert d.shape == (3, 1) d = DiagonalOf(MatrixSymbol('x', n, 3)) assert d.shape == (3, 1) d = DiagonalOf(MatrixSymbol('x', 3, n)) assert d.shape == (3, 1) x = MatrixSymbol('x', n, m) assert [DiagonalOf(x)[i] for i in range(4)] ==[ x[0, 0], x[1, 1], x[2, 2], x[3, 3]] def test_DiagonalizeVector(): x = MatrixSymbol('x', n, 1) d = DiagonalizeVector(x) assert d.shape == (n, n) assert d[0, 1] == 0 assert d[0, 0] == x[0, 0] a = MatrixSymbol('a', 1, 1) d = diagonalize_vector(a) assert isinstance(d, MatrixSymbol) assert a == d assert diagonalize_vector(Identity(3)) == Identity(3) assert isinstance(DiagonalizeVector(Identity(3)), DiagonalizeVector) # A diagonal matrix is equal to its transpose: assert DiagonalizeVector(x).T == DiagonalizeVector(x) assert diagonalize_vector(x.T) == DiagonalizeVector(x) dx = DiagonalizeVector(x) assert dx[0, 0] == x[0, 0] assert dx[1, 1] == x[1, 0] assert dx[0, 1] == 0 assert dx[0, m] == x[0, 0]KroneckerDelta(0, m) z = MatrixSymbol('z', 1, n) dz = DiagonalizeVector(z) assert dz[0, 0] == z[0, 0] assert dz[1, 1] == z[0, 1] assert dz[0, 1] == 0 assert dz[0, m] == z[0, m]KroneckerDelta(0, m) v = MatrixSymbol('v', 3, 1) dv = DiagonalizeVector(v) assert dv.as_explicit() == Matrix([ [v[0, 0], 0, 0], [0, v[1, 0], 0], [0, 0, v[2, 0]], ]) v = MatrixSymbol('v', 1, 3) dv = DiagonalizeVector(v) assert dv.as_explicit() == Matrix([ [v[0, 0], 0, 0], [0, v[0, 1], 0], [0, 0, v[0, 2]], ])
ca58d9c2aaf5864ae8c2d83938e931924999913fd72e5b2ec95c1abc2159da87	from sympy.matrices.expressions.applyfunc import ElementwiseApplyFunction from sympy import (Matrix, Lambda, MatrixBase, MatrixSymbol, exp, symbols, MatMul, sin) from sympy.utilities.pytest import raises from sympy.matrices.common import ShapeError X = MatrixSymbol("X", 3, 3) Y = MatrixSymbol("Y", 3, 3) k = symbols("k") Xk = MatrixSymbol("X", k, k) Xd = X.as_explicit() x, y, z, t = symbols("x y z t") def test_applyfunc_matrix(): double = Lambda(x, x2) expr = ElementwiseApplyFunction(double, Xd) assert isinstance(expr, ElementwiseApplyFunction) assert expr.doit() == Xd.applyfunc(lambda x: x2) assert expr.shape == (3, 3) assert expr.func(expr.args) == expr assert expr[0, 0] == double(Xd[0, 0]) expr = ElementwiseApplyFunction(double, X) assert isinstance(expr, ElementwiseApplyFunction) assert isinstance(expr.doit(), ElementwiseApplyFunction) assert expr == X.applyfunc(double) assert expr.func(expr.args) == expr expr = ElementwiseApplyFunction(exp, XY) assert expr.expr == XY assert expr.function == exp assert expr == (XY).applyfunc(exp) assert expr.func(expr.args) == expr assert isinstance(Xexpr, MatMul) assert (Xexpr).shape == (3, 3) Z = MatrixSymbol("Z", 2, 3) assert (Zexpr).shape == (2, 3) expr = ElementwiseApplyFunction(exp, Z.T)ElementwiseApplyFunction(exp, Z) assert expr.shape == (3, 3) expr = ElementwiseApplyFunction(exp, Z)ElementwiseApplyFunction(exp, Z.T) assert expr.shape == (2, 2) raises(ShapeError, lambda: ElementwiseApplyFunction(exp, Z)ElementwiseApplyFunction(exp, Z)) M = Matrix([[x, y], [z, t]]) expr = ElementwiseApplyFunction(sin, M) assert isinstance(expr, ElementwiseApplyFunction) assert expr.function == sin assert expr.expr == M assert expr.doit() == M.applyfunc(sin) assert expr.doit() == Matrix([[sin(x), sin(y)], [sin(z), sin(t)]]) assert expr.func(expr.args) == expr expr = ElementwiseApplyFunction(double, Xk) assert expr.doit() == expr assert expr.subs(k, 2).shape == (2, 2) assert (exprexpr).shape == (k, k) M = MatrixSymbol("M", k, t) expr2 = M.TexprM assert isinstance(expr2, MatMul) assert expr2.args[1] == expr assert expr2.shape == (t, t) expr3 = exprM assert expr3.shape == (k, t) raises(ShapeError, lambda: Mexpr) expr1 = ElementwiseApplyFunction(lambda x: x+1, Xk) expr2 = ElementwiseApplyFunction(lambda x: x, Xk) assert expr1 != expr2 def test_applyfunc_entry(): af = X.applyfunc(sin) assert af[0, 0] == sin(X[0, 0]) af = Xd.applyfunc(sin) assert af[0, 0] == sin(X[0, 0]) def test_applyfunc_as_explicit(): af = X.applyfunc(sin) assert af.as_explicit() == Matrix([ [sin(X[0, 0]), sin(X[0, 1]), sin(X[0, 2])], [sin(X[1, 0]), sin(X[1, 1]), sin(X[1, 2])], [sin(X[2, 0]), sin(X[2, 1]), sin(X[2, 2])], ])
35f11b5ae906fdbbcbc92bb092e3835bdbfcea0ce3998c0823e59411be31ee76	from sympy import Identity from sympy.core import symbols from sympy.utilities.pytest import raises from sympy.matrices import ShapeError, MatrixSymbol from sympy.matrices.expressions import (HadamardProduct, hadamard_product, HadamardPower, hadamard_power) n, m, k = symbols('n,m,k') Z = MatrixSymbol('Z', n, n) A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', n, m) C = MatrixSymbol('C', m, k) def test_HadamardProduct(): assert HadamardProduct(A, B, A).shape == A.shape raises(ShapeError, lambda: HadamardProduct(A, B.T)) raises(TypeError, lambda: HadamardProduct(A, n)) raises(TypeError, lambda: HadamardProduct(A, 1)) assert HadamardProduct(A, 2B, -A)[1, 1] == \ -2 A[1, 1] * B[1, 1] * A[1, 1] mix = HadamardProduct(ZA, B)C assert mix.shape == (n, k) assert set(HadamardProduct(A, B, A).T.args) == set((A.T, A.T, B.T)) def test_HadamardProduct_isnt_commutative(): assert HadamardProduct(A, B) != HadamardProduct(B, A) def test_mixed_indexing(): X = MatrixSymbol('X', 2, 2) Y = MatrixSymbol('Y', 2, 2) Z = MatrixSymbol('Z', 2, 2) assert (XHadamardProduct(Y, Z))[0, 0] == \ X[0, 0]Y[0, 0]Z[0, 0] + X[0, 1]Y[1, 0]Z[1, 0] def test_canonicalize(): X = MatrixSymbol('X', 2, 2) expr = HadamardProduct(X, check=False) assert isinstance(expr, HadamardProduct) expr2 = expr.doit() # unpack is called assert isinstance(expr2, MatrixSymbol) def test_hadamard(): m, n, p = symbols('m, n, p', integer=True) A = MatrixSymbol('A', m, n) B = MatrixSymbol('B', m, n) C = MatrixSymbol('C', m, p) X = MatrixSymbol('X', m, m) I = Identity(m) with raises(TypeError): hadamard_product() assert hadamard_product(A) == A assert isinstance(hadamard_product(A, B), HadamardProduct) assert hadamard_product(A, B).doit() == hadamard_product(A, B) with raises(ShapeError): hadamard_product(A, C) hadamard_product(A, I) assert hadamard_product(X, I) == X assert isinstance(hadamard_product(X, I), MatrixSymbol) def test_hadamard_power(): m, n, p = symbols('m, n, p', integer=True) A = MatrixSymbol('A', m, n) B = MatrixSymbol('B', m, n) C = MatrixSymbol('C', m, p) assert hadamard_power(A, 1) == A assert isinstance(hadamard_power(A, 2), HadamardPower) assert hadamard_power(A, n).T == hadamard_power(A.T, n) assert hadamard_power(A, n)[0, 0] == A[0, 0]n assert hadamard_power(m, n) == mn raises(ValueError, lambda: hadamard_power(A, A)) # Testing printer: assert str(hadamard_power(A, n)) == "A.n" assert str(hadamard_power(A, 1+n)) == "A.(n + 1)" assert str(hadamard_power(AB.T, 1+n)) == "(AB.T).*(n + 1)"
c358f2b6c522470c58e953e50b9b979fd7e0241428ea8c1601b8f605cf783726	from sympy import Min, Max, Set, Lambda, symbols, S, oo from sympy.core import Basic, Expr, Integer from sympy.core.numbers import Infinity, NegativeInfinity, Zero from sympy.multipledispatch import dispatch from sympy.sets import Interval, FiniteSet, Union, ImageSet _x, _y = symbols("x y") @dispatch(Basic, Basic) def _set_pow(x, y): return None @dispatch(Set, Set) def _set_pow(x, y): return ImageSet(Lambda((_x, _y), (_x _y)), x, y) @dispatch(Expr, Expr) def _set_pow(x, y): return xy @dispatch(Interval, Zero) def _set_pow(x, z): return FiniteSet(S.One) @dispatch(Interval, Integer) def _set_pow(x, exponent): """ Powers in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ s1 = x.startexponent s2 = x.endexponent if ((s2 > s1) if exponent > 0 else (x.end > -x.start)) == True: left_open = x.left_open right_open = x.right_open # TODO: handle unevaluated condition. sleft = s2 else: # TODO: `s2 > s1` could be unevaluated. left_open = x.right_open right_open = x.left_open sleft = s1 if x.start.is_positive: return Interval( Min(s1, s2), Max(s1, s2), left_open, right_open) elif x.end.is_negative: return Interval( Min(s1, s2), Max(s1, s2), left_open, right_open) # Case where x.start < 0 and x.end > 0: if exponent.is_odd: if exponent.is_negative: if x.start.is_zero: return Interval(s2, oo, x.right_open) if x.end.is_zero: return Interval(-oo, s1, True, x.left_open) return Union(Interval(-oo, s1, True, x.left_open), Interval(s2, oo, x.right_open)) else: return Interval(s1, s2, x.left_open, x.right_open) elif exponent.is_even: if exponent.is_negative: if x.start.is_zero: return Interval(s2, oo, x.right_open) if x.end.is_zero: return Interval(s1, oo, x.left_open) return Interval(0, oo) else: return Interval(S.Zero, sleft, S.Zero not in x, left_open) @dispatch(Interval, Infinity) def _set_pow(b, e): # TODO: add logic for open intervals? if b.start.is_nonnegative: if b.end < 1: return FiniteSet(S.Zero) if b.start > 1: return FiniteSet(S.Infinity) return Interval(0, oo) elif b.end.is_negative: if b.start > -1: return FiniteSet(S.Zero) if b.end < -1: return FiniteSet(-oo, oo) return Interval(-oo, oo) else: if b.start > -1: if b.end < 1: return FiniteSet(S.Zero) return Interval(0, oo) return Interval(-oo, oo) @dispatch(Interval, NegativeInfinity) def _set_pow(b, e): from sympy.sets.setexpr import set_div return _set_pow(set_div(S.One, b), oo)
952b5954aef2c9ebfcdad563cd66bf1436f1fe4cd2d01f4dd6163e8be4008074	from sympy import (S, Dummy, Lambda, symbols, Interval, Intersection, Set, EmptySet, FiniteSet, Union, ComplexRegion, ProductSet) from sympy.multipledispatch import dispatch from sympy.sets.conditionset import ConditionSet from sympy.sets.fancysets import Integers, Naturals, Reals, Range, ImageSet from sympy.sets.sets import UniversalSet, imageset @dispatch(ConditionSet, ConditionSet) def intersection_sets(a, b): return None @dispatch(ConditionSet, Set) def intersection_sets(a, b): return ConditionSet(a.sym, a.condition, Intersection(a.base_set, b)) @dispatch(Naturals, Interval) def intersection_sets(a, b): return Intersection(S.Integers, b, Interval(a._inf, S.Infinity)) @dispatch(Interval, Naturals) def intersection_sets(a, b): return intersection_sets(b, a) @dispatch(Integers, Interval) def intersection_sets(a, b): from sympy.functions.elementary.integers import floor, ceiling if b._inf == S.NegativeInfinity and b._sup == S.Infinity: return a s = Range(ceiling(b.left), floor(b.right) + 1) return intersection_sets(s, b) # take out endpoints if open interval @dispatch(ComplexRegion, Set) def intersection_sets(self, other): if other.is_ComplexRegion: # self in rectangular form if (not self.polar) and (not other.polar): return ComplexRegion(Intersection(self.sets, other.sets)) # self in polar form elif self.polar and other.polar: r1, theta1 = self.a_interval, self.b_interval r2, theta2 = other.a_interval, other.b_interval new_r_interval = Intersection(r1, r2) new_theta_interval = Intersection(theta1, theta2) # 0 and 2Pi means the same if ((2S.Pi in theta1 and S.Zero in theta2) or (2S.Pi in theta2 and S.Zero in theta1)): new_theta_interval = Union(new_theta_interval, FiniteSet(0)) return ComplexRegion(new_r_intervalnew_theta_interval, polar=True) if other.is_subset(S.Reals): new_interval = [] x = symbols("x", cls=Dummy, real=True) # self in rectangular form if not self.polar: for element in self.psets: if S.Zero in element.args[1]: new_interval.append(element.args[0]) new_interval = Union(new_interval) return Intersection(new_interval, other) # self in polar form elif self.polar: for element in self.psets: if S.Zero in element.args[1]: new_interval.append(element.args[0]) if S.Pi in element.args[1]: new_interval.append(ImageSet(Lambda(x, -x), element.args[0])) if S.Zero in element.args[0]: new_interval.append(FiniteSet(0)) new_interval = Union(new_interval) return Intersection(new_interval, other) @dispatch(Integers, Reals) def intersection_sets(a, b): return a @dispatch(Range, Interval) def intersection_sets(a, b): from sympy.functions.elementary.integers import floor, ceiling from sympy.functions.elementary.miscellaneous import Min, Max if not all(i.is_number for i in b.args[:2]): return # In case of null Range, return an EmptySet. if a.size == 0: return S.EmptySet # trim down to self's size, and represent # as a Range with step 1. start = ceiling(max(b.inf, a.inf)) if start not in b: start += 1 end = floor(min(b.sup, a.sup)) if end not in b: end -= 1 return intersection_sets(a, Range(start, end + 1)) @dispatch(Range, Naturals) def intersection_sets(a, b): return intersection_sets(a, Interval(1, S.Infinity)) @dispatch(Naturals, Range) def intersection_sets(a, b): return intersection_sets(b, a) @dispatch(Range, Range) def intersection_sets(a, b): from sympy.solvers.diophantine import diop_linear from sympy.core.numbers import ilcm from sympy import sign # non-overlap quick exits if not b: return S.EmptySet if not a: return S.EmptySet if b.sup < a.inf: return S.EmptySet if b.inf > a.sup: return S.EmptySet # work with finite end at the start r1 = a if r1.start.is_infinite: r1 = r1.reversed r2 = b if r2.start.is_infinite: r2 = r2.reversed # this equation represents the values of the Range; # it's a linear equation eq = lambda r, i: r.start + ir.step # we want to know when the two equations might # have integer solutions so we use the diophantine # solver va, vb = diop_linear(eq(r1, Dummy()) - eq(r2, Dummy())) # check for no solution no_solution = va is None and vb is None if no_solution: return S.EmptySet # there is a solution # ------------------- # find the coincident point, c a0 = va.as_coeff_Add()[0] c = eq(r1, a0) # find the first point, if possible, in each range # since c may not be that point def _first_finite_point(r1, c): if c == r1.start: return c # st is the signed step we need to take to # get from c to r1.start st = sign(r1.start - c)step # use Range to calculate the first point: # we want to get as close as possible to # r1.start; the Range will not be null since # it will at least contain c s1 = Range(c, r1.start + st, st)[-1] if s1 == r1.start: pass else: # if we didn't hit r1.start then, if the # sign of st didn't match the sign of r1.step # we are off by one and s1 is not in r1 if sign(r1.step) != sign(st): s1 -= st if s1 not in r1: return return s1 # calculate the step size of the new Range step = abs(ilcm(r1.step, r2.step)) s1 = _first_finite_point(r1, c) if s1 is None: return S.EmptySet s2 = _first_finite_point(r2, c) if s2 is None: return S.EmptySet # replace the corresponding start or stop in # the original Ranges with these points; the # result must have at least one point since # we know that s1 and s2 are in the Ranges def _updated_range(r, first): st = sign(r.step)step if r.start.is_finite: rv = Range(first, r.stop, st) else: rv = Range(r.start, first + st, st) return rv r1 = _updated_range(a, s1) r2 = _updated_range(b, s2) # work with them both in the increasing direction if sign(r1.step) < 0: r1 = r1.reversed if sign(r2.step) < 0: r2 = r2.reversed # return clipped Range with positive step; it # can't be empty at this point start = max(r1.start, r2.start) stop = min(r1.stop, r2.stop) return Range(start, stop, step) @dispatch(Range, Integers) def intersection_sets(a, b): return a @dispatch(ImageSet, Set) def intersection_sets(self, other): from sympy.solvers.diophantine import diophantine if self.base_set is S.Integers: g = None if isinstance(other, ImageSet) and other.base_set is S.Integers: g = other.lamda.expr m = other.lamda.variables[0] elif other is S.Integers: m = g = Dummy('x') if g is not None: f = self.lamda.expr n = self.lamda.variables[0] # Diophantine sorts the solutions according to the alphabetic # order of the variable names, since the result should not depend # on the variable name, they are replaced by the dummy variables # below a, b = Dummy('a'), Dummy('b') f, g = f.subs(n, a), g.subs(m, b) solns_set = diophantine(f - g) if solns_set == set(): return EmptySet() solns = list(diophantine(f - g)) if len(solns) != 1: return # since 'a' < 'b', select soln for n nsol = solns[0][0] t = nsol.free_symbols.pop() return imageset(Lambda(n, f.subs(a, nsol.subs(t, n))), S.Integers) if other == S.Reals: from sympy.solvers.solveset import solveset_real from sympy.core.function import expand_complex if len(self.lamda.variables) > 1: return None f = self.lamda.expr n = self.lamda.variables[0] n_ = Dummy(n.name, real=True) f_ = f.subs(n, n_) re, im = f_.as_real_imag() im = expand_complex(im) return imageset(Lambda(n_, re), self.base_set.intersect( solveset_real(im, n_))) elif isinstance(other, Interval): from sympy.solvers.solveset import (invert_real, invert_complex, solveset) f = self.lamda.expr n = self.lamda.variables[0] base_set = self.base_set new_inf, new_sup = None, None new_lopen, new_ropen = other.left_open, other.right_open if f.is_real: inverter = invert_real else: inverter = invert_complex g1, h1 = inverter(f, other.inf, n) g2, h2 = inverter(f, other.sup, n) if all(isinstance(i, FiniteSet) for i in (h1, h2)): if g1 == n: if len(h1) == 1: new_inf = h1.args[0] if g2 == n: if len(h2) == 1: new_sup = h2.args[0] # TODO: Design a technique to handle multiple-inverse # functions # Any of the new boundary values cannot be determined if any(i is None for i in (new_sup, new_inf)): return range_set = S.EmptySet if all(i.is_real for i in (new_sup, new_inf)): # this assumes continuity of underlying function # however fixes the case when it is decreasing if new_inf > new_sup: new_inf, new_sup = new_sup, new_inf new_interval = Interval(new_inf, new_sup, new_lopen, new_ropen) range_set = base_set.intersect(new_interval) else: if other.is_subset(S.Reals): solutions = solveset(f, n, S.Reals) if not isinstance(range_set, (ImageSet, ConditionSet)): range_set = solutions.intersect(other) else: return if range_set is S.EmptySet: return S.EmptySet elif isinstance(range_set, Range) and range_set.size is not S.Infinity: range_set = FiniteSet(list(range_set)) if range_set is not None: return imageset(Lambda(n, f), range_set) return else: return @dispatch(ProductSet, ProductSet) def intersection_sets(a, b): if len(b.args) != len(a.args): return S.EmptySet return ProductSet(i.intersect(j) for i, j in zip(a.sets, b.sets)) @dispatch(Interval, Interval) def intersection_sets(a, b): # handle (-oo, oo) infty = S.NegativeInfinity, S.Infinity if a == Interval(infty): l, r = a.left, a.right if l.is_real or l in infty or r.is_real or r in infty: return b # We can't intersect [0,3] with [x,6] -- we don't know if x>0 or x<0 if not a._is_comparable(b): return None empty = False if a.start <= b.end and b.start <= a.end: # Get topology right. if a.start < b.start: start = b.start left_open = b.left_open elif a.start > b.start: start = a.start left_open = a.left_open else: start = a.start left_open = a.left_open or b.left_open if a.end < b.end: end = a.end right_open = a.right_open elif a.end > b.end: end = b.end right_open = b.right_open else: end = a.end right_open = a.right_open or b.right_open if end - start == 0 and (left_open or right_open): empty = True else: empty = True if empty: return S.EmptySet return Interval(start, end, left_open, right_open) @dispatch(EmptySet, Set) def intersection_sets(a, b): return S.EmptySet @dispatch(UniversalSet, Set) def intersection_sets(a, b): return b @dispatch(FiniteSet, FiniteSet) def intersection_sets(a, b): return FiniteSet((a._elements & b._elements)) @dispatch(FiniteSet, Set) def intersection_sets(a, b): try: return FiniteSet(*[el for el in a if el in b]) except TypeError: return None # could not evaluate `el in b` due to symbolic ranges. @dispatch(Set, Set) def intersection_sets(a, b): return None
7559b6fa3111ac33099490e68920e116725ca93aee49b5b62411292c6ac5aaad	from sympy import symbols, S from sympy.core import Basic, Expr from sympy.core.numbers import Infinity, NegativeInfinity from sympy.multipledispatch import dispatch from sympy.sets import Interval, FiniteSet _x, _y = symbols("x y") @dispatch(Basic, Basic) def _set_add(x, y): return None @dispatch(Expr, Expr) def _set_add(x, y): return x+y @dispatch(Interval, Interval) def _set_add(x, y): """ Additions in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ return Interval(x.start + y.start, x.end + y.end, x.left_open or y.left_open, x.right_open or y.right_open) @dispatch(Interval, Infinity) def _set_add(x, y): if x.start == S.NegativeInfinity: return Interval(-oo, oo) return FiniteSet({S.Infinity}) @dispatch(Interval, NegativeInfinity) def _set_add(x, y): if x.end == S.Infinity: return Interval(-oo, oo) return FiniteSet({S.NegativeInfinity}) @dispatch(Basic, Basic) def _set_sub(x, y): return None @dispatch(Expr, Expr) def _set_sub(x, y): return x-y @dispatch(Interval, Interval) def _set_sub(x, y): """ Subtractions in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ return Interval(x.start - y.end, x.end - y.start, x.left_open or y.right_open, x.right_open or y.left_open) @dispatch(Interval, Infinity) def _set_sub(x, y): if self.start is S.NegativeInfinity: return Interval(-oo, oo) return FiniteSet(-oo) @dispatch(Interval, NegativeInfinity) def _set_sub(x, y): if self.start is S.NegativeInfinity: return Interval(-oo, oo) return FiniteSet(-oo)
375e39efb591310d87dd88672643be5c82c3b5863b1bea01ad5c2678480e2e8a	from sympy import (Interval, Intersection, Set, EmptySet, S, sympify, FiniteSet, Union, ComplexRegion, ProductSet) from sympy.multipledispatch import dispatch from sympy.sets.fancysets import Integers from sympy.sets.sets import UniversalSet @dispatch(Integers, Set) def union_sets(a, b): intersect = Intersection(a, b) if intersect == a: return b elif intersect == b: return a @dispatch(ComplexRegion, Set) def union_sets(a, b): if b.is_subset(S.Reals): # treat a subset of reals as a complex region b = ComplexRegion.from_real(b) if b.is_ComplexRegion: # a in rectangular form if (not a.polar) and (not b.polar): return ComplexRegion(Union(a.sets, b.sets)) # a in polar form elif a.polar and b.polar: return ComplexRegion(Union(a.sets, b.sets), polar=True) return None @dispatch(EmptySet, Set) def union_sets(a, b): return b @dispatch(UniversalSet, Set) def union_sets(a, b): return a @dispatch(ProductSet, ProductSet) def union_sets(a, b): if b.is_subset(a): return a if len(b.args) != len(a.args): return None if a.args[0] == b.args[0]: return a.args[0] * Union(ProductSet(a.args[1:]), ProductSet(b.args[1:])) if a.args[-1] == b.args[-1]: return Union(ProductSet(a.args[:-1]), ProductSet(b.args[:-1])) * a.args[-1] return None @dispatch(ProductSet, Set) def union_sets(a, b): if b.is_subset(a): return a return None @dispatch(Interval, Interval) def union_sets(a, b): if a._is_comparable(b): from sympy.functions.elementary.miscellaneous import Min, Max # Non-overlapping intervals end = Min(a.end, b.end) start = Max(a.start, b.start) if (end < start or (end == start and (end not in a and end not in b))): return None else: start = Min(a.start, b.start) end = Max(a.end, b.end) left_open = ((a.start != start or a.left_open) and (b.start != start or b.left_open)) right_open = ((a.end != end or a.right_open) and (b.end != end or b.right_open)) return Interval(start, end, left_open, right_open) @dispatch(Interval, UniversalSet) def union_sets(a, b): return S.UniversalSet @dispatch(Interval, Set) def union_sets(a, b): # If I have open end points and these endpoints are contained in b # But only in case, when endpoints are finite. Because # interval does not contain oo or -oo. open_left_in_b_and_finite = (a.left_open and sympify(b.contains(a.start)) is S.true and a.start.is_finite) open_right_in_b_and_finite = (a.right_open and sympify(b.contains(a.end)) is S.true and a.end.is_finite) if open_left_in_b_and_finite or open_right_in_b_and_finite: # Fill in my end points and return open_left = a.left_open and a.start not in b open_right = a.right_open and a.end not in b new_a = Interval(a.start, a.end, open_left, open_right) return set((new_a, b)) return None @dispatch(FiniteSet, FiniteSet) def union_sets(a, b): return FiniteSet((a._elements \| b._elements)) @dispatch(FiniteSet, Set) def union_sets(a, b): # If `b` set contains one of my elements, remove it from `a` if any(b.contains(x) == True for x in a): return set(( FiniteSet([x for x in a if not b.contains(x)]), b)) return None @dispatch(Set, Set) def union_sets(a, b): return None
0b99ab616107cd996e1d0764c962c9b42447fa05f2a335955b773db7cbac14ae	from sympy import Set, symbols, exp, log, S, Wild from sympy.core import Expr, Add from sympy.core.function import Lambda, _coeff_isneg, FunctionClass from sympy.logic.boolalg import true from sympy.multipledispatch import dispatch from sympy.sets import (imageset, Interval, FiniteSet, Union, ImageSet, EmptySet, Intersection, Range) from sympy.sets.fancysets import Integers _x, _y = symbols("x y") FunctionUnion = (FunctionClass, Lambda) @dispatch(FunctionClass, Set) def _set_function(f, x): return None @dispatch(FunctionUnion, FiniteSet) def _set_function(f, x): return FiniteSet(map(f, x)) @dispatch(Lambda, Interval) def _set_function(f, x): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.solvers.solveset import solveset from sympy.core.function import diff, Lambda from sympy.series import limit from sympy.calculus.singularities import singularities from sympy.sets import Complement # TODO: handle functions with infinitely many solutions (eg, sin, tan) # TODO: handle multivariate functions expr = f.expr if len(expr.free_symbols) > 1 or len(f.variables) != 1: return var = f.variables[0] if expr.is_Piecewise: result = S.EmptySet domain_set = x for (p_expr, p_cond) in expr.args: if p_cond is true: intrvl = domain_set else: intrvl = p_cond.as_set() intrvl = Intersection(domain_set, intrvl) if p_expr.is_Number: image = FiniteSet(p_expr) else: image = imageset(Lambda(var, p_expr), intrvl) result = Union(result, image) # remove the part which has been `imaged` domain_set = Complement(domain_set, intrvl) if domain_set.is_EmptySet: break return result if not x.start.is_comparable or not x.end.is_comparable: return try: sing = [i for i in singularities(expr, var) if i.is_real and i in x] except NotImplementedError: return if x.left_open: _start = limit(expr, var, x.start, dir="+") elif x.start not in sing: _start = f(x.start) if x.right_open: _end = limit(expr, var, x.end, dir="-") elif x.end not in sing: _end = f(x.end) if len(sing) == 0: solns = list(solveset(diff(expr, var), var)) extr = [_start, _end] + [f(i) for i in solns if i.is_real and i in x] start, end = Min(extr), Max(extr) left_open, right_open = False, False if _start <= _end: # the minimum or maximum value can occur simultaneously # on both the edge of the interval and in some interior # point if start == _start and start not in solns: left_open = x.left_open if end == _end and end not in solns: right_open = x.right_open else: if start == _end and start not in solns: left_open = x.right_open if end == _start and end not in solns: right_open = x.left_open return Interval(start, end, left_open, right_open) else: return imageset(f, Interval(x.start, sing[0], x.left_open, True)) + \ Union([imageset(f, Interval(sing[i], sing[i + 1], True, True)) for i in range(0, len(sing) - 1)]) + \ imageset(f, Interval(sing[-1], x.end, True, x.right_open)) @dispatch(FunctionClass, Interval) def _set_function(f, x): if f == exp: return Interval(exp(x.start), exp(x.end), x.left_open, x.right_open) elif f == log: return Interval(log(x.start), log(x.end), x.left_open, x.right_open) return ImageSet(Lambda(_x, f(_x)), x) @dispatch(FunctionUnion, Union) def _set_function(f, x): return Union((imageset(f, arg) for arg in x.args)) @dispatch(FunctionUnion, Intersection) def _set_function(f, x): from sympy.sets.sets import is_function_invertible_in_set # If the function is invertible, intersect the maps of the sets. if is_function_invertible_in_set(f, x): return Intersection((imageset(f, arg) for arg in x.args)) else: return ImageSet(Lambda(_x, f(_x)), x) @dispatch(FunctionUnion, EmptySet) def _set_function(f, x): return x @dispatch(FunctionUnion, Set) def _set_function(f, x): return ImageSet(Lambda(_x, f(_x)), x) @dispatch(FunctionUnion, Range) def _set_function(f, self): from sympy.core.function import expand_mul if not self: return S.EmptySet if not isinstance(f.expr, Expr): return if self.size == 1: return FiniteSet(f(self[0])) if f is S.IdentityFunction: return self x = f.variables[0] expr = f.expr # handle f that is linear in f's variable if x not in expr.free_symbols or x in expr.diff(x).free_symbols: return if self.start.is_finite: F = f(self.stepx + self.start) # for i in range(len(self)) else: F = f(-self.stepx + self[-1]) F = expand_mul(F) if F != expr: return imageset(x, F, Range(self.size)) @dispatch(FunctionUnion, Integers) def _set_function(f, self): expr = f.expr if not isinstance(expr, Expr): return if len(f.variables) > 1: return n = f.variables[0] # f(x) + c and f(-x) + c cover the same integers # so choose the form that has the fewest negatives c = f(0) fx = f(n) - c f_x = f(-n) - c neg_count = lambda e: sum(_coeff_isneg(_) for _ in Add.make_args(e)) if neg_count(f_x) < neg_count(fx): expr = f_x + c a = Wild('a', exclude=[n]) b = Wild('b', exclude=[n]) match = expr.match(an + b) if match and match[a]: # canonical shift expr = match[a]n + match[b] % match[a] if expr != f.expr: return ImageSet(Lambda(n, expr), S.Integers)
2071057783a1e860dd35aca3e4ba135f251f1c3ee3b2bfbb1fd302747db768bf	from sympy import Set, symbols from sympy.core import Basic, Expr from sympy.multipledispatch import dispatch from sympy.sets import Interval _x, _y = symbols("x y") @dispatch(Basic, Basic) def _set_mul(x, y): return None @dispatch(Set, Set) def _set_mul(x, y): return None @dispatch(Expr, Expr) def _set_mul(x, y): return xy @dispatch(Interval, Interval) def _set_mul(x, y): """ Multiplications in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ # TODO: some intervals containing 0 and oo will fail as 0oo returns nan. comvals = ( (x.start * y.start, bool(x.left_open or y.left_open)), (x.start * y.end, bool(x.left_open or y.right_open)), (x.end * y.start, bool(x.right_open or y.left_open)), (x.end * y.end, bool(x.right_open or y.right_open)), ) # TODO: handle symbolic intervals minval, minopen = min(comvals) maxval, maxopen = max(comvals) return Interval( minval, maxval, minopen, maxopen ) return SetExpr(Interval(start, end)) @dispatch(Basic, Basic) def _set_div(x, y): return None @dispatch(Expr, Expr) def _set_div(x, y): return x/y @dispatch(Set, Set) def _set_div(x, y): return None @dispatch(Interval, Interval) def _set_div(x, y): """ Divisions in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ from sympy.sets.setexpr import set_mul from sympy import oo if (y.start*y.end).is_negative: return Interval(-oo, oo) if y.start == 0: s2 = oo else: s2 = 1/y.start if y.end == 0: s1 = -oo else: s1 = 1/y.end return set_mul(x, Interval(s1, s2, y.right_open, y.left_open))
fd0ee6cfec09669a48f0ae461822658e3cc91852e879f9b3b19337a8ac14860f	from sympy import (pi, sin, cos, Symbol, Integral, Sum, sqrt, log, oo, LambertW, I, meijerg, exp_polar, Max, Piecewise, And) from sympy.plotting import (plot, plot_parametric, plot3d_parametric_line, plot3d, plot3d_parametric_surface) from sympy.plotting.plot import unset_show, plot_contour, PlotGrid from sympy.utilities import lambdify as lambdify_ from sympy.utilities.pytest import skip, raises, warns from sympy.plotting.experimental_lambdify import lambdify from sympy.external import import_module from tempfile import NamedTemporaryFile import os unset_show() # XXX: We could implement this as a context manager instead # That would need rewriting the plot_and_save() function # entirely class TmpFileManager: tmp_files = [] @classmethod def tmp_file(cls, name=''): cls.tmp_files.append(NamedTemporaryFile(prefix=name, suffix='.png').name) return cls.tmp_files[-1] @classmethod def cleanup(cls): for file in cls.tmp_files: try: os.remove(file) except OSError: # If the file doesn't exist, for instance, if the test failed. pass def plot_and_save_1(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Examples from the 'introduction' notebook ### p = plot(x) p = plot(xsin(x), xcos(x)) p.extend(p) p[0].line_color = lambda a: a p[1].line_color = 'b' p.title = 'Big title' p.xlabel = 'the x axis' p[1].label = 'straight line' p.legend = True p.aspect_ratio = (1, 1) p.xlim = (-15, 20) p.save(tmp_file('%s_basic_options_and_colors' % name)) p._backend.close() p.extend(plot(x + 1)) p.append(plot(x + 3, x2)[1]) p.save(tmp_file('%s_plot_extend_append' % name)) p[2] = plot(x2, (x, -2, 3)) p.save(tmp_file('%s_plot_setitem' % name)) p._backend.close() p = plot(sin(x), (x, -2pi, 4pi)) p.save(tmp_file('%s_line_explicit' % name)) p._backend.close() p = plot(sin(x)) p.save(tmp_file('%s_line_default_range' % name)) p._backend.close() p = plot((x2, (x, -5, 5)), (x3, (x, -3, 3))) p.save(tmp_file('%s_line_multiple_range' % name)) p._backend.close() raises(ValueError, lambda: plot(x, y)) #Piecewise plots p = plot(Piecewise((1, x > 0), (0, True)), (x, -1, 1)) p.save(tmp_file('%s_plot_piecewise' % name)) p._backend.close() p = plot(Piecewise((x, x < 1), (x2, True)), (x, -3, 3)) p.save(tmp_file('%s_plot_piecewise_2' % name)) p._backend.close() # test issue 7471 p1 = plot(x) p2 = plot(3) p1.extend(p2) p.save(tmp_file('%s_horizontal_line' % name)) p._backend.close() # test issue 10925 f = Piecewise((-1, x < -1), (x, And(-1 <= x, x < 0)), \ (x2, And(0 <= x, x < 1)), (x*3, x >= 1)) p = plot(f, (x, -3, 3)) p.save(tmp_file('%s_plot_piecewise_3' % name)) p._backend.close() def plot_and_save_2(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') #parametric 2d plots. #Single plot with default range. plot_parametric(sin(x), cos(x)).save(tmp_file()) #Single plot with range. p = plot_parametric(sin(x), cos(x), (x, -5, 5)) p.save(tmp_file('%s_parametric_range' % name)) p._backend.close() #Multiple plots with same range. p = plot_parametric((sin(x), cos(x)), (x, sin(x))) p.save(tmp_file('%s_parametric_multiple' % name)) p._backend.close() #Multiple plots with different ranges. p = plot_parametric((sin(x), cos(x), (x, -3, 3)), (x, sin(x), (x, -5, 5))) p.save(tmp_file('%s_parametric_multiple_ranges' % name)) p._backend.close() #depth of recursion specified. p = plot_parametric(x, sin(x), depth=13) p.save(tmp_file('%s_recursion_depth' % name)) p._backend.close() #No adaptive sampling. p = plot_parametric(cos(x), sin(x), adaptive=False, nb_of_points=500) p.save(tmp_file('%s_adaptive' % name)) p._backend.close() #3d parametric plots p = plot3d_parametric_line(sin(x), cos(x), x) p.save(tmp_file('%s_3d_line' % name)) p._backend.close() p = plot3d_parametric_line( (sin(x), cos(x), x, (x, -5, 5)), (cos(x), sin(x), x, (x, -3, 3))) p.save(tmp_file('%s_3d_line_multiple' % name)) p._backend.close() p = plot3d_parametric_line(sin(x), cos(x), x, nb_of_points=30) p.save(tmp_file('%s_3d_line_points' % name)) p._backend.close() # 3d surface single plot. p = plot3d(x y) p.save(tmp_file('%s_surface' % name)) p._backend.close() # Multiple 3D plots with same range. p = plot3d(-x * y, x * y, (x, -5, 5)) p.save(tmp_file('%s_surface_multiple' % name)) p._backend.close() # Multiple 3D plots with different ranges. p = plot3d( (x * y, (x, -3, 3), (y, -3, 3)), (-x * y, (x, -3, 3), (y, -3, 3))) p.save(tmp_file('%s_surface_multiple_ranges' % name)) p._backend.close() # Single Parametric 3D plot p = plot3d_parametric_surface(sin(x + y), cos(x - y), x - y) p.save(tmp_file('%s_parametric_surface' % name)) p._backend.close() # Multiple Parametric 3D plots. p = plot3d_parametric_surface( (xsin(z), xcos(z), z, (x, -5, 5), (z, -5, 5)), (sin(x + y), cos(x - y), x - y, (x, -5, 5), (y, -5, 5))) p.save(tmp_file('%s_parametric_surface' % name)) p._backend.close() # Single Contour plot. p = plot_contour(sin(x)sin(y), (x, -5, 5), (y, -5, 5)) p.save(tmp_file('%s_contour_plot' % name)) p._backend.close() # Multiple Contour plots with same range. p = plot_contour(x2 + y2, x3 + y3, (x, -5, 5), (y, -5, 5)) p.save(tmp_file('%s_contour_plot' % name)) p._backend.close() # Multiple Contour plots with different range. p = plot_contour((x2 + y2, (x, -5, 5), (y, -5, 5)), (x3 + y3, (x, -3, 3), (y, -3, 3))) p.save(tmp_file('%s_contour_plot' % name)) p._backend.close() def plot_and_save_3(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Examples from the 'colors' notebook ### p = plot(sin(x)) p[0].line_color = lambda a: a p.save(tmp_file('%s_colors_line_arity1' % name)) p[0].line_color = lambda a, b: b p.save(tmp_file('%s_colors_line_arity2' % name)) p._backend.close() p = plot(xsin(x), xcos(x), (x, 0, 10)) p[0].line_color = lambda a: a p.save(tmp_file('%s_colors_param_line_arity1' % name)) p[0].line_color = lambda a, b: a p.save(tmp_file('%s_colors_param_line_arity2a' % name)) p[0].line_color = lambda a, b: b p.save(tmp_file('%s_colors_param_line_arity2b' % name)) p._backend.close() p = plot3d_parametric_line(sin(x) + 0.1sin(x)cos(7x), cos(x) + 0.1cos(x)cos(7x), 0.1sin(7x), (x, 0, 2pi)) p[0].line_color = lambdify_(x, sin(4x)) p.save(tmp_file('%s_colors_3d_line_arity1' % name)) p[0].line_color = lambda a, b: b p.save(tmp_file('%s_colors_3d_line_arity2' % name)) p[0].line_color = lambda a, b, c: c p.save(tmp_file('%s_colors_3d_line_arity3' % name)) p._backend.close() p = plot3d(sin(x)y, (x, 0, 6pi), (y, -5, 5)) p[0].surface_color = lambda a: a p.save(tmp_file('%s_colors_surface_arity1' % name)) p[0].surface_color = lambda a, b: b p.save(tmp_file('%s_colors_surface_arity2' % name)) p[0].surface_color = lambda a, b, c: c p.save(tmp_file('%s_colors_surface_arity3a' % name)) p[0].surface_color = lambdify_((x, y, z), sqrt((x - 3pi)2 + y2)) p.save(tmp_file('%s_colors_surface_arity3b' % name)) p._backend.close() p = plot3d_parametric_surface(x * cos(4 * y), x * sin(4 * y), y, (x, -1, 1), (y, -1, 1)) p[0].surface_color = lambda a: a p.save(tmp_file('%s_colors_param_surf_arity1' % name)) p[0].surface_color = lambda a, b: ab p.save(tmp_file('%s_colors_param_surf_arity2' % name)) p[0].surface_color = lambdify_((x, y, z), sqrt(x2 + y2 + z2)) p.save(tmp_file('%s_colors_param_surf_arity3' % name)) p._backend.close() def plot_and_save_4(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Examples from the 'advanced' notebook ### # XXX: This raises the warning "The evaluation of the expression is # problematic. We are trying a failback method that may still work. Please # report this as a bug." It has to use the fallback because using evalf() # is the only way to evaluate the integral. We should perhaps just remove # that warning. with warns(UserWarning, match="The evaluation of the expression is problematic"): i = Integral(log((sin(x)2 + 1)sqrt(x2 + 1)), (x, 0, y)) p = plot(i, (y, 1, 5)) p.save(tmp_file('%s_advanced_integral' % name)) p._backend.close() def plot_and_save_5(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') s = Sum(1/xy, (x, 1, oo)) p = plot(s, (y, 2, 10)) p.save(tmp_file('%s_advanced_inf_sum' % name)) p._backend.close() p = plot(Sum(1/x, (x, 1, y)), (y, 2, 10), show=False) p[0].only_integers = True p[0].steps = True p.save(tmp_file('%s_advanced_fin_sum' % name)) p._backend.close() def plot_and_save_6(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Test expressions that can not be translated to np and generate complex # results. ### plot(sin(x) + Icos(x)).save(tmp_file()) plot(sqrt(sqrt(-x))).save(tmp_file()) plot(LambertW(x)).save(tmp_file()) plot(sqrt(LambertW(x))).save(tmp_file()) #Characteristic function of a StudentT distribution with nu=10 plot((meijerg(((1 / 2,), ()), ((5, 0, 1 / 2), ()), 5 x*2 exp_polar(-Ipi)/2) + meijerg(((1/2,), ()), ((5, 0, 1/2), ()), 5x*2 exp_polar(Ipi)/2)) / (48 pi), (x, 1e-6, 1e-2)).save(tmp_file()) def plotgrid_and_save(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') p1 = plot(x) p2 = plot_parametric((sin(x), cos(x)), (x, sin(x)), show=False) p3 = plot_parametric(cos(x), sin(x), adaptive=False, nb_of_points=500, show=False) p4 = plot3d_parametric_line(sin(x), cos(x), x, show=False) # symmetric grid p = PlotGrid(2, 2, p1, p2, p3, p4) p.save(tmp_file('%s_grid1' % name)) p._backend.close() # grid size greater than the number of subplots p = PlotGrid(3, 4, p1, p2, p3, p4) p.save(tmp_file('%s_grid2' % name)) p._backend.close() p5 = plot(cos(x),(x, -pi, pi), show=False) p5[0].line_color = lambda a: a p6 = plot(Piecewise((1, x > 0), (0, True)), (x, -1, 1), show=False) p7 = plot_contour((x2 + y2, (x, -5, 5), (y, -5, 5)), (x3 + y3, (x, -3, 3), (y, -3, 3)), show=False) # unsymmetric grid (subplots in one line) p = PlotGrid(1, 3, p5, p6, p7) p.save(tmp_file('%s_grid3' % name)) p._backend.close() def test_matplotlib_1(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_1('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_2(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_2('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_3(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_3('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_4(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_4('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_5(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_5('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_6(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_6('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_7(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plotgrid_and_save('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") # Tests for exception handling in experimental_lambdify def test_experimental_lambify(): x = Symbol('x') f = lambdify([x], Max(x, 5)) # XXX should f be tested? If f(2) is attempted, an # error is raised because a complex produced during wrapping of the arg # is being compared with an int. assert Max(2, 5) == 5 assert Max(5, 7) == 7 x = Symbol('x-3') f = lambdify([x], x + 1) assert f(1) == 2 def test_append_issue_7140(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if not matplotlib: skip("Matplotlib not the default backend") x = Symbol('x') p1 = plot(x) p2 = plot(x**2) p3 = plot(x + 2) # append a series p2.append(p1[0]) assert len(p2._series) == 2 with raises(TypeError): p1.append(p2) with raises(TypeError): p1.append(p2._series) def test_issue_15265(): from sympy.core.sympify import sympify from sympy.core.singleton import S matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if not matplotlib: skip("Matplotlib not the default backend") x = Symbol('x') eqn = sin(x) p = plot(eqn, xlim=(-S.Pi, S.Pi), ylim=(-1, 1)) p._backend.close() p = plot(eqn, xlim=(-1, 1), ylim=(-S.Pi, S.Pi)) p._backend.close() p = plot(eqn, xlim=(-1, 1), ylim=(sympify('-3.14'), sympify('3.14'))) p._backend.close() p = plot(eqn, xlim=(sympify('-3.14'), sympify('3.14')), ylim=(-1, 1)) p._backend.close() raises(ValueError, lambda: plot(eqn, xlim=(-S.ImaginaryUnit, 1), ylim=(-1, 1))) raises(ValueError, lambda: plot(eqn, xlim=(-1, 1), ylim=(-1, S.ImaginaryUnit))) raises(ValueError, lambda: plot(eqn, xlim=(-S.Infinity, 1), ylim=(-1, 1))) raises(ValueError, lambda: plot(eqn, xlim=(-1, 1), ylim=(-1, S.Infinity)))
de6273a6ea687e884c572921338dc7573c9560430c6141c24c7530b8f15a81ee	from __future__ import print_function, division from sympy import Symbol, sympify from sympy.core.compatibility import is_sequence, range, string_types from sympy.geometry.entity import GeometryEntity from .plot_interval import PlotInterval from .plot_object import PlotObject from .util import parse_option_string class PlotMode(PlotObject): """ Grandparent class for plotting modes. Serves as interface for registration, lookup, and init of modes. To create a new plot mode, inherit from PlotModeBase or one of its children, such as PlotSurface or PlotCurve. """ ## Class-level attributes ## used to register and lookup ## plot modes. See PlotModeBase ## for descriptions and usage. i_vars, d_vars = '', '' intervals = [] aliases = [] is_default = False ## Draw is the only method here which ## is meant to be overridden in child ## classes, and PlotModeBase provides ## a base implementation. def draw(self): raise NotImplementedError() ## Everything else in this file has to ## do with registration and retrieval ## of plot modes. This is where I've ## hidden much of the ugliness of automatic ## plot mode divination... ## Plot mode registry data structures _mode_alias_list = [] _mode_map = { 1: {1: {}, 2: {}}, 2: {1: {}, 2: {}}, 3: {1: {}, 2: {}}, } # [d][i][alias_str]: class _mode_default_map = { 1: {}, 2: {}, 3: {}, } # [d][i]: class _i_var_max, _d_var_max = 2, 3 def __new__(cls, args, kwargs): """ This is the function which interprets arguments given to Plot.__init__ and Plot.__setattr__. Returns an initialized instance of the appropriate child class. """ newargs, newkwargs = PlotMode._extract_options(args, kwargs) mode_arg = newkwargs.get('mode', '') # Interpret the arguments d_vars, intervals = PlotMode._interpret_args(newargs) i_vars = PlotMode._find_i_vars(d_vars, intervals) i, d = max([len(i_vars), len(intervals)]), len(d_vars) # Find the appropriate mode subcls = PlotMode._get_mode(mode_arg, i, d) # Create the object o = object.__new__(subcls) # Do some setup for the mode instance o.d_vars = d_vars o._fill_i_vars(i_vars) o._fill_intervals(intervals) o.options = newkwargs return o @staticmethod def _get_mode(mode_arg, i_var_count, d_var_count): """ Tries to return an appropriate mode class. Intended to be called only by __new__. mode_arg Can be a string or a class. If it is a PlotMode subclass, it is simply returned. If it is a string, it can an alias for a mode or an empty string. In the latter case, we try to find a default mode for the i_var_count and d_var_count. i_var_count The number of independent variables needed to evaluate the d_vars. d_var_count The number of dependent variables; usually the number of functions to be evaluated in plotting. For example, a Cartesian function y = f(x) has one i_var (x) and one d_var (y). A parametric form x,y,z = f(u,v), f(u,v), f(u,v) has two two i_vars (u,v) and three d_vars (x,y,z). """ # if the mode_arg is simply a PlotMode class, # check that the mode supports the numbers # of independent and dependent vars, then # return it try: m = None if issubclass(mode_arg, PlotMode): m = mode_arg except TypeError: pass if m: if not m._was_initialized: raise ValueError(("To use unregistered plot mode %s " "you must first call %s._init_mode().") % (m.__name__, m.__name__)) if d_var_count != m.d_var_count: raise ValueError(("%s can only plot functions " "with %i dependent variables.") % (m.__name__, m.d_var_count)) if i_var_count > m.i_var_count: raise ValueError(("%s cannot plot functions " "with more than %i independent " "variables.") % (m.__name__, m.i_var_count)) return m # If it is a string, there are two possibilities. if isinstance(mode_arg, string_types): i, d = i_var_count, d_var_count if i > PlotMode._i_var_max: raise ValueError(var_count_error(True, True)) if d > PlotMode._d_var_max: raise ValueError(var_count_error(False, True)) # If the string is '', try to find a suitable # default mode if not mode_arg: return PlotMode._get_default_mode(i, d) # Otherwise, interpret the string as a mode # alias (e.g. 'cartesian', 'parametric', etc) else: return PlotMode._get_aliased_mode(mode_arg, i, d) else: raise ValueError("PlotMode argument must be " "a class or a string") @staticmethod def _get_default_mode(i, d, i_vars=-1): if i_vars == -1: i_vars = i try: return PlotMode._mode_default_map[d][i] except KeyError: # Keep looking for modes in higher i var counts # which support the given d var count until we # reach the max i_var count. if i < PlotMode._i_var_max: return PlotMode._get_default_mode(i + 1, d, i_vars) else: raise ValueError(("Couldn't find a default mode " "for %i independent and %i " "dependent variables.") % (i_vars, d)) @staticmethod def _get_aliased_mode(alias, i, d, i_vars=-1): if i_vars == -1: i_vars = i if alias not in PlotMode._mode_alias_list: raise ValueError(("Couldn't find a mode called" " %s. Known modes: %s.") % (alias, ", ".join(PlotMode._mode_alias_list))) try: return PlotMode._mode_map[d][i][alias] except TypeError: # Keep looking for modes in higher i var counts # which support the given d var count and alias # until we reach the max i_var count. if i < PlotMode._i_var_max: return PlotMode._get_aliased_mode(alias, i + 1, d, i_vars) else: raise ValueError(("Couldn't find a %s mode " "for %i independent and %i " "dependent variables.") % (alias, i_vars, d)) @classmethod def _register(cls): """ Called once for each user-usable plot mode. For Cartesian2D, it is invoked after the class definition: Cartesian2D._register() """ name = cls.__name__ cls._init_mode() try: i, d = cls.i_var_count, cls.d_var_count # Add the mode to _mode_map under all # given aliases for a in cls.aliases: if a not in PlotMode._mode_alias_list: # Also track valid aliases, so # we can quickly know when given # an invalid one in _get_mode. PlotMode._mode_alias_list.append(a) PlotMode._mode_map[d][i][a] = cls if cls.is_default: # If this mode was marked as the # default for this d,i combination, # also set that. PlotMode._mode_default_map[d][i] = cls except Exception as e: raise RuntimeError(("Failed to register " "plot mode %s. Reason: %s") % (name, (str(e)))) @classmethod def _init_mode(cls): """ Initializes the plot mode based on the 'mode-specific parameters' above. Only intended to be called by PlotMode._register(). To use a mode without registering it, you can directly call ModeSubclass._init_mode(). """ def symbols_list(symbol_str): return [Symbol(s) for s in symbol_str] # Convert the vars strs into # lists of symbols. cls.i_vars = symbols_list(cls.i_vars) cls.d_vars = symbols_list(cls.d_vars) # Var count is used often, calculate # it once here cls.i_var_count = len(cls.i_vars) cls.d_var_count = len(cls.d_vars) if cls.i_var_count > PlotMode._i_var_max: raise ValueError(var_count_error(True, False)) if cls.d_var_count > PlotMode._d_var_max: raise ValueError(var_count_error(False, False)) # Try to use first alias as primary_alias if len(cls.aliases) > 0: cls.primary_alias = cls.aliases[0] else: cls.primary_alias = cls.__name__ di = cls.intervals if len(di) != cls.i_var_count: raise ValueError("Plot mode must provide a " "default interval for each i_var.") for i in range(cls.i_var_count): # default intervals must be given [min,max,steps] # (no var, but they must be in the same order as i_vars) if len(di[i]) != 3: raise ValueError("length should be equal to 3") # Initialize an incomplete interval, # to later be filled with a var when # the mode is instantiated. di[i] = PlotInterval(None, di[i]) # To prevent people from using modes # without these required fields set up. cls._was_initialized = True _was_initialized = False ## Initializer Helper Methods @staticmethod def _find_i_vars(functions, intervals): i_vars = [] # First, collect i_vars in the # order they are given in any # intervals. for i in intervals: if i.v is None: continue elif i.v in i_vars: raise ValueError(("Multiple intervals given " "for %s.") % (str(i.v))) i_vars.append(i.v) # Then, find any remaining # i_vars in given functions # (aka d_vars) for f in functions: for a in f.free_symbols: if a not in i_vars: i_vars.append(a) return i_vars def _fill_i_vars(self, i_vars): # copy default i_vars self.i_vars = [Symbol(str(i)) for i in self.i_vars] # replace with given i_vars for i in range(len(i_vars)): self.i_vars[i] = i_vars[i] def _fill_intervals(self, intervals): # copy default intervals self.intervals = [PlotInterval(i) for i in self.intervals] # track i_vars used so far v_used = [] # fill copy of default # intervals with given info for i in range(len(intervals)): self.intervals[i].fill_from(intervals[i]) if self.intervals[i].v is not None: v_used.append(self.intervals[i].v) # Find any orphan intervals and # assign them i_vars for i in range(len(self.intervals)): if self.intervals[i].v is None: u = [v for v in self.i_vars if v not in v_used] if len(u) == 0: raise ValueError("length should not be equal to 0") self.intervals[i].v = u[0] v_used.append(u[0]) @staticmethod def _interpret_args(args): interval_wrong_order = "PlotInterval %s was given before any function(s)." interpret_error = "Could not interpret %s as a function or interval." functions, intervals = [], [] if isinstance(args[0], GeometryEntity): for coords in list(args[0].arbitrary_point()): functions.append(coords) intervals.append(PlotInterval.try_parse(args[0].plot_interval())) else: for a in args: i = PlotInterval.try_parse(a) if i is not None: if len(functions) == 0: raise ValueError(interval_wrong_order % (str(i))) else: intervals.append(i) else: if is_sequence(a, include=str): raise ValueError(interpret_error % (str(a))) try: f = sympify(a) functions.append(f) except TypeError: raise ValueError(interpret_error % str(a)) return functions, intervals @staticmethod def _extract_options(args, kwargs): newkwargs, newargs = {}, [] for a in args: if isinstance(a, string_types): newkwargs = dict(newkwargs, parse_option_string(a)) else: newargs.append(a) newkwargs = dict(newkwargs, kwargs) return newargs, newkwargs def var_count_error(is_independent, is_plotting): """ Used to format an error message which differs slightly in 4 places. """ if is_plotting: v = "Plotting" else: v = "Registering plot modes" if is_independent: n, s = PlotMode._i_var_max, "independent" else: n, s = PlotMode._d_var_max, "dependent" return ("%s with more than %i %s variables " "is not supported.") % (v, n, s)
93fa7af79a7db2d6d0a4b34d7f4072b8d41613459432fca3a3c17d5ca495344b	from __future__ import print_function, division from pyglet.window import Window from pyglet.clock import Clock from threading import Thread, Lock gl_lock = Lock() class ManagedWindow(Window): """ A pyglet window with an event loop which executes automatically in a separate thread. Behavior is added by creating a subclass which overrides setup, update, and/or draw. """ fps_limit = 30 default_win_args = dict(width=600, height=500, vsync=False, resizable=True) def __init__(self, win_args): """ It is best not to override this function in the child class, unless you need to take additional arguments. Do any OpenGL initialization calls in setup(). """ # check if this is run from the doctester if win_args.get('runfromdoctester', False): return self.win_args = dict(self.default_win_args, win_args) self.Thread = Thread(target=self.__event_loop__) self.Thread.start() def __event_loop__(self, win_args): """ The event loop thread function. Do not override or call directly (it is called by __init__). """ gl_lock.acquire() try: try: super(ManagedWindow, self).__init__(self.win_args) self.switch_to() self.setup() except Exception as e: print("Window initialization failed: %s" % (str(e))) self.has_exit = True finally: gl_lock.release() clock = Clock() clock.set_fps_limit(self.fps_limit) while not self.has_exit: dt = clock.tick() gl_lock.acquire() try: try: self.switch_to() self.dispatch_events() self.clear() self.update(dt) self.draw() self.flip() except Exception as e: print("Uncaught exception in event loop: %s" % str(e)) self.has_exit = True finally: gl_lock.release() super(ManagedWindow, self).close() def close(self): """ Closes the window. """ self.has_exit = True def setup(self): """ Called once before the event loop begins. Override this method in a child class. This is the best place to put things like OpenGL initialization calls. """ pass def update(self, dt): """ Called before draw during each iteration of the event loop. dt is the elapsed time in seconds since the last update. OpenGL rendering calls are best put in draw() rather than here. """ pass def draw(self): """ Called after update during each iteration of the event loop. Put OpenGL rendering calls here. """ pass if __name__ == '__main__': ManagedWindow()
557da6fd9606fd8df270846b48fab1434a1594e941d814085fe3b11fae270b6b	"""Plotting module that can plot 2D and 3D functions """ from sympy.utilities.decorator import doctest_depends_on try: @doctest_depends_on(modules=('pyglet',)) def PygletPlot(args, kwargs): """ Plot Examples ============= See examples/advanced/pyglet_plotting.py for many more examples. >>> from sympy.plotting.pygletplot import PygletPlot as Plot >>> from sympy import symbols >>> from sympy.abc import x, y, z >>> Plot(xy*3-yx3) [0]: -x3y + xy*3, 'mode=cartesian' >>> p = Plot() >>> p[1] = xy >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p = Plot() >>> p[1] = x2+y2 >>> p[2] = -x2-y2 Variable Intervals ================== The basic format is [var, min, max, steps], but the syntax is flexible and arguments left out are taken from the defaults for the current coordinate mode: >>> Plot(x2) # implies [x,-5,5,100] [0]: x2, 'mode=cartesian' >>> Plot(x2, [], []) # [x,-1,1,40], [y,-1,1,40] [0]: x2, 'mode=cartesian' >>> Plot(x2-y2, [100], [100]) # [x,-1,1,100], [y,-1,1,100] [0]: x2 - y2, 'mode=cartesian' >>> Plot(x2, [x,-13,13,100]) [0]: x2, 'mode=cartesian' >>> Plot(x2, [-13,13]) # [x,-13,13,100] [0]: x2, 'mode=cartesian' >>> Plot(x2, [x,-13,13]) # [x,-13,13,100] [0]: x2, 'mode=cartesian' >>> Plot(1x, [], [x], mode='cylindrical') ... # [unbound_theta,0,2Pi,40], [x,-1,1,20] [0]: x, 'mode=cartesian' Coordinate Modes ================ Plot supports several curvilinear coordinate modes, and they independent for each plotted function. You can specify a coordinate mode explicitly with the 'mode' named argument, but it can be automatically determined for Cartesian or parametric plots, and therefore must only be specified for polar, cylindrical, and spherical modes. Specifically, Plot(function arguments) and Plot[n] = (function arguments) will interpret your arguments as a Cartesian plot if you provide one function and a parametric plot if you provide two or three functions. Similarly, the arguments will be interpreted as a curve if one variable is used, and a surface if two are used. Supported mode names by number of variables: 1: parametric, cartesian, polar 2: parametric, cartesian, cylindrical = polar, spherical >>> Plot(1, mode='spherical') Calculator-like Interface ========================= >>> p = Plot(visible=False) >>> f = x2 >>> p[1] = f >>> p[2] = f.diff(x) >>> p[3] = f.diff(x).diff(x) >>> p [1]: x2, 'mode=cartesian' [2]: 2x, 'mode=cartesian' [3]: 2, 'mode=cartesian' >>> p.show() >>> p.clear() >>> p <blank plot> >>> p[1] = x2+y2 >>> p[1].style = 'solid' >>> p[2] = -x2-y2 >>> p[2].style = 'wireframe' >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p[1].style = 'both' >>> p[2].style = 'both' >>> p.close() Plot Window Keyboard Controls ============================= Screen Rotation: X,Y axis Arrow Keys, A,S,D,W, Numpad 4,6,8,2 Z axis Q,E, Numpad 7,9 Model Rotation: Z axis Z,C, Numpad 1,3 Zoom: R,F, PgUp,PgDn, Numpad +,- Reset Camera: X, Numpad 5 Camera Presets: XY F1 XZ F2 YZ F3 Perspective F4 Sensitivity Modifier: SHIFT Axes Toggle: Visible F5 Colors F6 Close Window: ESCAPE ============================= """ from sympy.plotting.pygletplot.plot import PygletPlot return PygletPlot(args, *kwargs) except Exception as e: def PygletPlot(args, **kwargs): raise e
3041e5eec67b04b0e6ea6d7088afc15b074f03491ed1c6d0266a69f6d0b80ba9	from __future__ import print_function, division try: from ctypes import c_float except ImportError: pass import pyglet.gl as pgl from math import sqrt as _sqrt, acos as _acos def cross(a, b): return (a[1] * b[2] - a[2] * b[1], a[2] * b[0] - a[0] * b[2], a[0] * b[1] - a[1] * b[0]) def dot(a, b): return a[0] * b[0] + a[1] * b[1] + a[2] * b[2] def mag(a): return _sqrt(a[0]2 + a[1]2 + a[2]2) def norm(a): m = mag(a) return (a[0] / m, a[1] / m, a[2] / m) def get_sphere_mapping(x, y, width, height): x = min([max([x, 0]), width]) y = min([max([y, 0]), height]) sr = _sqrt((width/2)2 + (height/2)2) sx = ((x - width / 2) / sr) sy = ((y - height / 2) / sr) sz = 1.0 - sx2 - sy*2 if sz > 0.0: sz = _sqrt(sz) return (sx, sy, sz) else: sz = 0 return norm((sx, sy, sz)) rad2deg = 180.0 / 3.141592 def get_spherical_rotatation(p1, p2, width, height, theta_multiplier): v1 = get_sphere_mapping(p1[0], p1[1], width, height) v2 = get_sphere_mapping(p2[0], p2[1], width, height) d = min(max([dot(v1, v2), -1]), 1) if abs(d - 1.0) < 0.000001: return None raxis = norm( cross(v1, v2) ) rtheta = theta_multiplier rad2deg * _acos(d) pgl.glPushMatrix() pgl.glLoadIdentity() pgl.glRotatef(rtheta, raxis) mat = (c_float16)() pgl.glGetFloatv(pgl.GL_MODELVIEW_MATRIX, mat) pgl.glPopMatrix() return mat
2517b74f0d865287183a1884aca29efd651ceacb8e4add60b04a650d895e9a0f	from __future__ import print_function, division from threading import RLock # it is sufficient to import "pyglet" here once try: import pyglet.gl as pgl except ImportError: raise ImportError("pyglet is required for plotting.\n " "visit http://www.pyglet.org/") from sympy.core.compatibility import is_sequence, SYMPY_INTS from sympy.core.numbers import Integer from sympy.geometry.entity import GeometryEntity from sympy.plotting.pygletplot.plot_axes import PlotAxes from sympy.plotting.pygletplot.plot_mode import PlotMode from sympy.plotting.pygletplot.plot_object import PlotObject from sympy.plotting.pygletplot.plot_window import PlotWindow from sympy.plotting.pygletplot.util import parse_option_string from sympy.utilities.decorator import doctest_depends_on from time import sleep from os import getcwd, listdir import ctypes @doctest_depends_on(modules=('pyglet',)) class PygletPlot(object): """ Plot Examples ============= See examples/advanced/pyglet_plotting.py for many more examples. >>> from sympy.plotting.pygletplot import PygletPlot as Plot >>> from sympy.abc import x, y, z >>> Plot(xy3-yx3) [0]: -x3y + xy*3, 'mode=cartesian' >>> p = Plot() >>> p[1] = xy >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p = Plot() >>> p[1] = x2+y2 >>> p[2] = -x2-y2 Variable Intervals ================== The basic format is [var, min, max, steps], but the syntax is flexible and arguments left out are taken from the defaults for the current coordinate mode: >>> Plot(x2) # implies [x,-5,5,100] [0]: x2, 'mode=cartesian' >>> Plot(x2, [], []) # [x,-1,1,40], [y,-1,1,40] [0]: x2, 'mode=cartesian' >>> Plot(x2-y2, [100], [100]) # [x,-1,1,100], [y,-1,1,100] [0]: x2 - y2, 'mode=cartesian' >>> Plot(x2, [x,-13,13,100]) [0]: x2, 'mode=cartesian' >>> Plot(x2, [-13,13]) # [x,-13,13,100] [0]: x2, 'mode=cartesian' >>> Plot(x2, [x,-13,13]) # [x,-13,13,10] [0]: x2, 'mode=cartesian' >>> Plot(1x, [], [x], mode='cylindrical') ... # [unbound_theta,0,2Pi,40], [x,-1,1,20] [0]: x, 'mode=cartesian' Coordinate Modes ================ Plot supports several curvilinear coordinate modes, and they independent for each plotted function. You can specify a coordinate mode explicitly with the 'mode' named argument, but it can be automatically determined for Cartesian or parametric plots, and therefore must only be specified for polar, cylindrical, and spherical modes. Specifically, Plot(function arguments) and Plot[n] = (function arguments) will interpret your arguments as a Cartesian plot if you provide one function and a parametric plot if you provide two or three functions. Similarly, the arguments will be interpreted as a curve if one variable is used, and a surface if two are used. Supported mode names by number of variables: 1: parametric, cartesian, polar 2: parametric, cartesian, cylindrical = polar, spherical >>> Plot(1, mode='spherical') Calculator-like Interface ========================= >>> p = Plot(visible=False) >>> f = x2 >>> p[1] = f >>> p[2] = f.diff(x) >>> p[3] = f.diff(x).diff(x) >>> p [1]: x2, 'mode=cartesian' [2]: 2x, 'mode=cartesian' [3]: 2, 'mode=cartesian' >>> p.show() >>> p.clear() >>> p <blank plot> >>> p[1] = x2+y2 >>> p[1].style = 'solid' >>> p[2] = -x2-y2 >>> p[2].style = 'wireframe' >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p[1].style = 'both' >>> p[2].style = 'both' >>> p.close() Plot Window Keyboard Controls ============================= Screen Rotation: X,Y axis Arrow Keys, A,S,D,W, Numpad 4,6,8,2 Z axis Q,E, Numpad 7,9 Model Rotation: Z axis Z,C, Numpad 1,3 Zoom: R,F, PgUp,PgDn, Numpad +,- Reset Camera: X, Numpad 5 Camera Presets: XY F1 XZ F2 YZ F3 Perspective F4 Sensitivity Modifier: SHIFT Axes Toggle: Visible F5 Colors F6 Close Window: ESCAPE ============================= """ @doctest_depends_on(modules=('pyglet',)) def __init__(self, fargs, win_args): """ Positional Arguments ==================== Any given positional arguments are used to initialize a plot function at index 1. In other words... >>> from sympy.plotting.pygletplot import PygletPlot as Plot >>> from sympy.core import Symbol >>> from sympy.abc import x >>> p = Plot(x2, visible=False) ...is equivalent to... >>> p = Plot(visible=False) >>> p[1] = x2 Note that in earlier versions of the plotting module, you were able to specify multiple functions in the initializer. This functionality has been dropped in favor of better automatic plot plot_mode detection. Named Arguments =============== axes An option string of the form "key1=value1; key2 = value2" which can use the following options: style = ordinate none OR frame OR box OR ordinate stride = 0.25 val OR (val_x, val_y, val_z) overlay = True (draw on top of plot) True OR False colored = False (False uses Black, True uses colors R,G,B = X,Y,Z) True OR False label_axes = False (display axis names at endpoints) True OR False visible = True (show immediately True OR False The following named arguments are passed as arguments to window initialization: antialiasing = True True OR False ortho = False True OR False invert_mouse_zoom = False True OR False """ # Register the plot modes from . import plot_modes self._win_args = win_args self._window = None self._render_lock = RLock() self._functions = {} self._pobjects = [] self._screenshot = ScreenShot(self) axe_options = parse_option_string(win_args.pop('axes', '')) self.axes = PlotAxes(axe_options) self._pobjects.append(self.axes) self[0] = fargs if win_args.get('visible', True): self.show() ## Window Interfaces def show(self): """ Creates and displays a plot window, or activates it (gives it focus) if it has already been created. """ if self._window and not self._window.has_exit: self._window.activate() else: self._win_args['visible'] = True self.axes.reset_resources() #if hasattr(self, '_doctest_depends_on'): # self._win_args['runfromdoctester'] = True self._window = PlotWindow(self, *self._win_args) def close(self): """ Closes the plot window. """ if self._window: self._window.close() def saveimage(self, outfile=None, format='', size=(600, 500)): """ Saves a screen capture of the plot window to an image file. If outfile is given, it can either be a path or a file object. Otherwise a png image will be saved to the current working directory. If the format is omitted, it is determined from the filename extension. """ self._screenshot.save(outfile, format, size) ## Function List Interfaces def clear(self): """ Clears the function list of this plot. """ self._render_lock.acquire() self._functions = {} self.adjust_all_bounds() self._render_lock.release() def __getitem__(self, i): """ Returns the function at position i in the function list. """ return self._functions[i] def __setitem__(self, i, args): """ Parses and adds a PlotMode to the function list. """ if not (isinstance(i, (SYMPY_INTS, Integer)) and i >= 0): raise ValueError("Function index must " "be an integer >= 0.") if isinstance(args, PlotObject): f = args else: if (not is_sequence(args)) or isinstance(args, GeometryEntity): args = [args] if len(args) == 0: return # no arguments given kwargs = dict(bounds_callback=self.adjust_all_bounds) f = PlotMode(args, *kwargs) if f: self._render_lock.acquire() self._functions[i] = f self._render_lock.release() else: raise ValueError("Failed to parse '%s'." % ', '.join(str(a) for a in args)) def __delitem__(self, i): """ Removes the function in the function list at position i. """ self._render_lock.acquire() del self._functions[i] self.adjust_all_bounds() self._render_lock.release() def firstavailableindex(self): """ Returns the first unused index in the function list. """ i = 0 self._render_lock.acquire() while i in self._functions: i += 1 self._render_lock.release() return i def append(self, args): """ Parses and adds a PlotMode to the function list at the first available index. """ self.__setitem__(self.firstavailableindex(), args) def __len__(self): """ Returns the number of functions in the function list. """ return len(self._functions) def __iter__(self): """ Allows iteration of the function list. """ return self._functions.itervalues() def __repr__(self): return str(self) def __str__(self): """ Returns a string containing a new-line separated list of the functions in the function list. """ s = "" if len(self._functions) == 0: s += "<blank plot>" else: self._render_lock.acquire() s += "\n".join(["%s[%i]: %s" % ("", i, str(self._functions[i])) for i in self._functions]) self._render_lock.release() return s def adjust_all_bounds(self): self._render_lock.acquire() self.axes.reset_bounding_box() for f in self._functions: self.axes.adjust_bounds(self._functions[f].bounds) self._render_lock.release() def wait_for_calculations(self): sleep(0) self._render_lock.acquire() for f in self._functions: a = self._functions[f]._get_calculating_verts b = self._functions[f]._get_calculating_cverts while a() or b(): sleep(0) self._render_lock.release() class ScreenShot: def __init__(self, plot): self._plot = plot self.screenshot_requested = False self.outfile = None self.format = '' self.invisibleMode = False self.flag = 0 def __nonzero__(self): return self.screenshot_requested __bool__ = __nonzero__ def _execute_saving(self): if self.flag < 3: self.flag += 1 return size_x, size_y = self._plot._window.get_size() size = size_xsize_y4ctypes.sizeof(ctypes.c_ubyte) image = ctypes.create_string_buffer(size) pgl.glReadPixels(0, 0, size_x, size_y, pgl.GL_RGBA, pgl.GL_UNSIGNED_BYTE, image) from PIL import Image im = Image.frombuffer('RGBA', (size_x, size_y), image.raw, 'raw', 'RGBA', 0, 1) im.transpose(Image.FLIP_TOP_BOTTOM).save(self.outfile, self.format) self.flag = 0 self.screenshot_requested = False if self.invisibleMode: self._plot._window.close() def save(self, outfile=None, format='', size=(600, 500)): self.outfile = outfile self.format = format self.size = size self.screenshot_requested = True if not self._plot._window or self._plot._window.has_exit: self._plot._win_args['visible'] = False self._plot._win_args['width'] = size[0] self._plot._win_args['height'] = size[1] self._plot.axes.reset_resources() self._plot._window = PlotWindow(self._plot, *self._plot._win_args) self.invisibleMode = True if self.outfile is None: self.outfile = self._create_unique_path() print(self.outfile) def _create_unique_path(self): cwd = getcwd() l = listdir(cwd) path = '' i = 0 while True: if not 'plot_%s.png' % i in l: path = cwd + '/plot_%s.png' % i break i += 1 return path
f16436d1c9ce168bba211d7d2a659787af2626af15183271cd604d0a2bfc6688	from __future__ import print_function, division import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import is_sequence from sympy.plotting.pygletplot.color_scheme import ColorScheme from sympy.plotting.pygletplot.plot_mode import PlotMode from time import sleep from threading import Thread, Event, RLock import warnings class PlotModeBase(PlotMode): """ Intended parent class for plotting modes. Provides base functionality in conjunction with its parent, PlotMode. """ ## ## Class-Level Attributes ## """ The following attributes are meant to be set at the class level, and serve as parameters to the plot mode registry (in PlotMode). See plot_modes.py for concrete examples. """ """ i_vars 'x' for Cartesian2D 'xy' for Cartesian3D etc. d_vars 'y' for Cartesian2D 'r' for Polar etc. """ i_vars, d_vars = '', '' """ intervals Default intervals for each i_var, and in the same order. Specified [min, max, steps]. No variable can be given (it is bound later). """ intervals = [] """ aliases A list of strings which can be used to access this mode. 'cartesian' for Cartesian2D and Cartesian3D 'polar' for Polar 'cylindrical', 'polar' for Cylindrical Note that _init_mode chooses the first alias in the list as the mode's primary_alias, which will be displayed to the end user in certain contexts. """ aliases = [] """ is_default Whether to set this mode as the default for arguments passed to PlotMode() containing the same number of d_vars as this mode and at most the same number of i_vars. """ is_default = False """ All of the above attributes are defined in PlotMode. The following ones are specific to PlotModeBase. """ """ A list of the render styles. Do not modify. """ styles = {'wireframe': 1, 'solid': 2, 'both': 3} """ style_override Always use this style if not blank. """ style_override = '' """ default_wireframe_color default_solid_color Can be used when color is None or being calculated. Used by PlotCurve and PlotSurface, but not anywhere in PlotModeBase. """ default_wireframe_color = (0.85, 0.85, 0.85) default_solid_color = (0.6, 0.6, 0.9) default_rot_preset = 'xy' ## ## Instance-Level Attributes ## ## 'Abstract' member functions def _get_evaluator(self): if self.use_lambda_eval: try: e = self._get_lambda_evaluator() return e except Exception: warnings.warn("\nWarning: creating lambda evaluator failed. " "Falling back on sympy subs evaluator.") return self._get_sympy_evaluator() def _get_sympy_evaluator(self): raise NotImplementedError() def _get_lambda_evaluator(self): raise NotImplementedError() def _on_calculate_verts(self): raise NotImplementedError() def _on_calculate_cverts(self): raise NotImplementedError() ## Base member functions def __init__(self, args, kwargs): self.verts = [] self.cverts = [] self.bounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] self.cbounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] self._draw_lock = RLock() self._calculating_verts = Event() self._calculating_cverts = Event() self._calculating_verts_pos = 0.0 self._calculating_verts_len = 0.0 self._calculating_cverts_pos = 0.0 self._calculating_cverts_len = 0.0 self._max_render_stack_size = 3 self._draw_wireframe = [-1] self._draw_solid = [-1] self._style = None self._color = None self.predraw = [] self.postdraw = [] self.use_lambda_eval = self.options.pop('use_sympy_eval', None) is None self.style = self.options.pop('style', '') self.color = self.options.pop('color', 'rainbow') self.bounds_callback = kwargs.pop('bounds_callback', None) self._on_calculate() def synchronized(f): def w(self, args, *kwargs): self._draw_lock.acquire() try: r = f(self, args, *kwargs) return r finally: self._draw_lock.release() return w @synchronized def push_wireframe(self, function): """ Push a function which performs gl commands used to build a display list. (The list is built outside of the function) """ assert callable(function) self._draw_wireframe.append(function) if len(self._draw_wireframe) > self._max_render_stack_size: del self._draw_wireframe[1] # leave marker element @synchronized def push_solid(self, function): """ Push a function which performs gl commands used to build a display list. (The list is built outside of the function) """ assert callable(function) self._draw_solid.append(function) if len(self._draw_solid) > self._max_render_stack_size: del self._draw_solid[1] # leave marker element def _create_display_list(self, function): dl = pgl.glGenLists(1) pgl.glNewList(dl, pgl.GL_COMPILE) function() pgl.glEndList() return dl def _render_stack_top(self, render_stack): top = render_stack[-1] if top == -1: return -1 # nothing to display elif callable(top): dl = self._create_display_list(top) render_stack[-1] = (dl, top) return dl # display newly added list elif len(top) == 2: if pgl.GL_TRUE == pgl.glIsList(top[0]): return top[0] # display stored list dl = self._create_display_list(top[1]) render_stack[-1] = (dl, top[1]) return dl # display regenerated list def _draw_solid_display_list(self, dl): pgl.glPushAttrib(pgl.GL_ENABLE_BIT \| pgl.GL_POLYGON_BIT) pgl.glPolygonMode(pgl.GL_FRONT_AND_BACK, pgl.GL_FILL) pgl.glCallList(dl) pgl.glPopAttrib() def _draw_wireframe_display_list(self, dl): pgl.glPushAttrib(pgl.GL_ENABLE_BIT \| pgl.GL_POLYGON_BIT) pgl.glPolygonMode(pgl.GL_FRONT_AND_BACK, pgl.GL_LINE) pgl.glEnable(pgl.GL_POLYGON_OFFSET_LINE) pgl.glPolygonOffset(-0.005, -50.0) pgl.glCallList(dl) pgl.glPopAttrib() @synchronized def draw(self): for f in self.predraw: if callable(f): f() if self.style_override: style = self.styles[self.style_override] else: style = self.styles[self._style] # Draw solid component if style includes solid if style & 2: dl = self._render_stack_top(self._draw_solid) if dl > 0 and pgl.GL_TRUE == pgl.glIsList(dl): self._draw_solid_display_list(dl) # Draw wireframe component if style includes wireframe if style & 1: dl = self._render_stack_top(self._draw_wireframe) if dl > 0 and pgl.GL_TRUE == pgl.glIsList(dl): self._draw_wireframe_display_list(dl) for f in self.postdraw: if callable(f): f() def _on_change_color(self, color): Thread(target=self._calculate_cverts).start() def _on_calculate(self): Thread(target=self._calculate_all).start() def _calculate_all(self): self._calculate_verts() self._calculate_cverts() def _calculate_verts(self): if self._calculating_verts.isSet(): return self._calculating_verts.set() try: self._on_calculate_verts() finally: self._calculating_verts.clear() if callable(self.bounds_callback): self.bounds_callback() def _calculate_cverts(self): if self._calculating_verts.isSet(): return while self._calculating_cverts.isSet(): sleep(0) # wait for previous calculation self._calculating_cverts.set() try: self._on_calculate_cverts() finally: self._calculating_cverts.clear() def _get_calculating_verts(self): return self._calculating_verts.isSet() def _get_calculating_verts_pos(self): return self._calculating_verts_pos def _get_calculating_verts_len(self): return self._calculating_verts_len def _get_calculating_cverts(self): return self._calculating_cverts.isSet() def _get_calculating_cverts_pos(self): return self._calculating_cverts_pos def _get_calculating_cverts_len(self): return self._calculating_cverts_len ## Property handlers def _get_style(self): return self._style @synchronized def _set_style(self, v): if v is None: return if v == '': step_max = 0 for i in self.intervals: if i.v_steps is None: continue step_max = max([step_max, int(i.v_steps)]) v = ['both', 'solid'][step_max > 40] if v not in self.styles: raise ValueError("v should be there in self.styles") if v == self._style: return self._style = v def _get_color(self): return self._color @synchronized def _set_color(self, v): try: if v is not None: if is_sequence(v): v = ColorScheme(v) else: v = ColorScheme(v) if repr(v) == repr(self._color): return self._on_change_color(v) self._color = v except Exception as e: raise RuntimeError(("Color change failed. " "Reason: %s" % (str(e)))) style = property(_get_style, _set_style) color = property(_get_color, _set_color) calculating_verts = property(_get_calculating_verts) calculating_verts_pos = property(_get_calculating_verts_pos) calculating_verts_len = property(_get_calculating_verts_len) calculating_cverts = property(_get_calculating_cverts) calculating_cverts_pos = property(_get_calculating_cverts_pos) calculating_cverts_len = property(_get_calculating_cverts_len) ## String representations def __str__(self): f = ", ".join(str(d) for d in self.d_vars) o = "'mode=%s'" % (self.primary_alias) return ", ".join([f, o]) def __repr__(self): f = ", ".join(str(d) for d in self.d_vars) i = ", ".join(str(i) for i in self.intervals) d = [('mode', self.primary_alias), ('color', str(self.color)), ('style', str(self.style))] o = "'%s'" % (("; ".join("%s=%s" % (k, v) for k, v in d if v != 'None'))) return ", ".join([f, i, o])
a86e2d3570c701c3d01b863086f758dec39ea4b95ab781bb3ee6119b92ca97e9	from __future__ import print_function, division import pyglet.gl as pgl from sympy.plotting.pygletplot.plot_rotation import get_spherical_rotatation from sympy.plotting.pygletplot.util import get_model_matrix, model_to_screen, \ screen_to_model, vec_subs class PlotCamera(object): min_dist = 0.05 max_dist = 500.0 min_ortho_dist = 100.0 max_ortho_dist = 10000.0 _default_dist = 6.0 _default_ortho_dist = 600.0 rot_presets = { 'xy': (0, 0, 0), 'xz': (-90, 0, 0), 'yz': (0, 90, 0), 'perspective': (-45, 0, -45) } def __init__(self, window, ortho=False): self.window = window self.axes = self.window.plot.axes self.ortho = ortho self.reset() def init_rot_matrix(self): pgl.glPushMatrix() pgl.glLoadIdentity() self._rot = get_model_matrix() pgl.glPopMatrix() def set_rot_preset(self, preset_name): self.init_rot_matrix() try: r = self.rot_presets[preset_name] except AttributeError: raise ValueError( "%s is not a valid rotation preset." % preset_name) try: self.euler_rotate(r[0], 1, 0, 0) self.euler_rotate(r[1], 0, 1, 0) self.euler_rotate(r[2], 0, 0, 1) except AttributeError: pass def reset(self): self._dist = 0.0 self._x, self._y = 0.0, 0.0 self._rot = None if self.ortho: self._dist = self._default_ortho_dist else: self._dist = self._default_dist self.init_rot_matrix() def mult_rot_matrix(self, rot): pgl.glPushMatrix() pgl.glLoadMatrixf(rot) pgl.glMultMatrixf(self._rot) self._rot = get_model_matrix() pgl.glPopMatrix() def setup_projection(self): pgl.glMatrixMode(pgl.GL_PROJECTION) pgl.glLoadIdentity() if self.ortho: # yep, this is pseudo ortho (don't tell anyone) pgl.gluPerspective( 0.3, float(self.window.width)/float(self.window.height), self.min_ortho_dist - 0.01, self.max_ortho_dist + 0.01) else: pgl.gluPerspective( 30.0, float(self.window.width)/float(self.window.height), self.min_dist - 0.01, self.max_dist + 0.01) pgl.glMatrixMode(pgl.GL_MODELVIEW) def _get_scale(self): return 1.0, 1.0, 1.0 def apply_transformation(self): pgl.glLoadIdentity() pgl.glTranslatef(self._x, self._y, -self._dist) if self._rot is not None: pgl.glMultMatrixf(self._rot) pgl.glScalef(self._get_scale()) def spherical_rotate(self, p1, p2, sensitivity=1.0): mat = get_spherical_rotatation(p1, p2, self.window.width, self.window.height, sensitivity) if mat is not None: self.mult_rot_matrix(mat) def euler_rotate(self, angle, x, y, z): pgl.glPushMatrix() pgl.glLoadMatrixf(self._rot) pgl.glRotatef(angle, x, y, z) self._rot = get_model_matrix() pgl.glPopMatrix() def zoom_relative(self, clicks, sensitivity): if self.ortho: dist_d = clicks sensitivity * 50.0 min_dist = self.min_ortho_dist max_dist = self.max_ortho_dist else: dist_d = clicks * sensitivity min_dist = self.min_dist max_dist = self.max_dist new_dist = (self._dist - dist_d) if (clicks < 0 and new_dist < max_dist) or new_dist > min_dist: self._dist = new_dist def mouse_translate(self, x, y, dx, dy): pgl.glPushMatrix() pgl.glLoadIdentity() pgl.glTranslatef(0, 0, -self._dist) z = model_to_screen(0, 0, 0)[2] d = vec_subs(screen_to_model(x, y, z), screen_to_model(x - dx, y - dy, z)) pgl.glPopMatrix() self._x += d[0] self._y += d[1]
ebdb658dfc6a323c9925f46e3344591ab345843daa48ece37fda8ff90e471efa	from __future__ import print_function, division from sympy import Basic, Symbol, symbols, lambdify from sympy.core.compatibility import range, string_types from .util import interpolate, rinterpolate, create_bounds, update_bounds from sympy.utilities.iterables import sift class ColorGradient(object): colors = [0.4, 0.4, 0.4], [0.9, 0.9, 0.9] intervals = 0.0, 1.0 def __init__(self, args): if len(args) == 2: self.colors = list(args) self.intervals = [0.0, 1.0] elif len(args) > 0: if len(args) % 2 != 0: raise ValueError("len(args) should be even") self.colors = [args[i] for i in range(1, len(args), 2)] self.intervals = [args[i] for i in range(0, len(args), 2)] assert len(self.colors) == len(self.intervals) def copy(self): c = ColorGradient() c.colors = [e[::] for e in self.colors] c.intervals = self.intervals[::] return c def _find_interval(self, v): m = len(self.intervals) i = 0 while i < m - 1 and self.intervals[i] <= v: i += 1 return i def _interpolate_axis(self, axis, v): i = self._find_interval(v) v = rinterpolate(self.intervals[i - 1], self.intervals[i], v) return interpolate(self.colors[i - 1][axis], self.colors[i][axis], v) def __call__(self, r, g, b): c = self._interpolate_axis return c(0, r), c(1, g), c(2, b) default_color_schemes = {} # defined at the bottom of this file class ColorScheme(object): def __init__(self, args, *kwargs): self.args = args self.f, self.gradient = None, ColorGradient() if len(args) == 1 and not isinstance(args[0], Basic) and callable(args[0]): self.f = args[0] elif len(args) == 1 and isinstance(args[0], string_types): if args[0] in default_color_schemes: cs = default_color_schemes[args[0]] self.f, self.gradient = cs.f, cs.gradient.copy() else: self.f = lambdify('x,y,z,u,v', args[0]) else: self.f, self.gradient = self._interpret_args(args) self._test_color_function() if not isinstance(self.gradient, ColorGradient): raise ValueError("Color gradient not properly initialized. " "(Not a ColorGradient instance.)") def _interpret_args(self, args): f, gradient = None, self.gradient atoms, lists = self._sort_args(args) s = self._pop_symbol_list(lists) s = self._fill_in_vars(s) # prepare the error message for lambdification failure f_str = ', '.join(str(fa) for fa in atoms) s_str = (str(sa) for sa in s) s_str = ', '.join(sa for sa in s_str if sa.find('unbound') < 0) f_error = ValueError("Could not interpret arguments " "%s as functions of %s." % (f_str, s_str)) # try to lambdify args if len(atoms) == 1: fv = atoms[0] try: f = lambdify(s, [fv, fv, fv]) except TypeError: raise f_error elif len(atoms) == 3: fr, fg, fb = atoms try: f = lambdify(s, [fr, fg, fb]) except TypeError: raise f_error else: raise ValueError("A ColorScheme must provide 1 or 3 " "functions in x, y, z, u, and/or v.") # try to intrepret any given color information if len(lists) == 0: gargs = [] elif len(lists) == 1: gargs = lists[0] elif len(lists) == 2: try: (r1, g1, b1), (r2, g2, b2) = lists except TypeError: raise ValueError("If two color arguments are given, " "they must be given in the format " "(r1, g1, b1), (r2, g2, b2).") gargs = lists elif len(lists) == 3: try: (r1, r2), (g1, g2), (b1, b2) = lists except Exception: raise ValueError("If three color arguments are given, " "they must be given in the format " "(r1, r2), (g1, g2), (b1, b2). To create " "a multi-step gradient, use the syntax " "[0, colorStart, step1, color1, ..., 1, " "colorEnd].") gargs = [[r1, g1, b1], [r2, g2, b2]] else: raise ValueError("Don't know what to do with collection " "arguments %s." % (', '.join(str(l) for l in lists))) if gargs: try: gradient = ColorGradient(gargs) except Exception as ex: raise ValueError(("Could not initialize a gradient " "with arguments %s. Inner " "exception: %s") % (gargs, str(ex))) return f, gradient def _pop_symbol_list(self, lists): symbol_lists = [] for l in lists: mark = True for s in l: if s is not None and not isinstance(s, Symbol): mark = False break if mark: lists.remove(l) symbol_lists.append(l) if len(symbol_lists) == 1: return symbol_lists[0] elif len(symbol_lists) == 0: return [] else: raise ValueError("Only one list of Symbols " "can be given for a color scheme.") def _fill_in_vars(self, args): defaults = symbols('x,y,z,u,v') v_error = ValueError("Could not find what to plot.") if len(args) == 0: return defaults if not isinstance(args, (tuple, list)): raise v_error if len(args) == 0: return defaults for s in args: if s is not None and not isinstance(s, Symbol): raise v_error # when vars are given explicitly, any vars # not given are marked 'unbound' as to not # be accidentally used in an expression vars = [Symbol('unbound%i' % (i)) for i in range(1, 6)] # interpret as t if len(args) == 1: vars[3] = args[0] # interpret as u,v elif len(args) == 2: if args[0] is not None: vars[3] = args[0] if args[1] is not None: vars[4] = args[1] # interpret as x,y,z elif len(args) >= 3: # allow some of x,y,z to be # left unbound if not given if args[0] is not None: vars[0] = args[0] if args[1] is not None: vars[1] = args[1] if args[2] is not None: vars[2] = args[2] # interpret the rest as t if len(args) >= 4: vars[3] = args[3] # ...or u,v if len(args) >= 5: vars[4] = args[4] return vars def _sort_args(self, args): lists, atoms = sift(args, lambda a: isinstance(a, (tuple, list)), binary=True) return atoms, lists def _test_color_function(self): if not callable(self.f): raise ValueError("Color function is not callable.") try: result = self.f(0, 0, 0, 0, 0) if len(result) != 3: raise ValueError("length should be equal to 3") except TypeError: raise ValueError("Color function needs to accept x,y,z,u,v, " "as arguments even if it doesn't use all of them.") except AssertionError: raise ValueError("Color function needs to return 3-tuple r,g,b.") except Exception: pass # color function probably not valid at 0,0,0,0,0 def __call__(self, x, y, z, u, v): try: return self.f(x, y, z, u, v) except Exception: return None def apply_to_curve(self, verts, u_set, set_len=None, inc_pos=None): """ Apply this color scheme to a set of vertices over a single independent variable u. """ bounds = create_bounds() cverts = list() if callable(set_len): set_len(len(u_set)2) # calculate f() = r,g,b for each vert # and find the min and max for r,g,b for _u in range(len(u_set)): if verts[_u] is None: cverts.append(None) else: x, y, z = verts[_u] u, v = u_set[_u], None c = self(x, y, z, u, v) if c is not None: c = list(c) update_bounds(bounds, c) cverts.append(c) if callable(inc_pos): inc_pos() # scale and apply gradient for _u in range(len(u_set)): if cverts[_u] is not None: for _c in range(3): # scale from [f_min, f_max] to [0,1] cverts[_u][_c] = rinterpolate(bounds[_c][0], bounds[_c][1], cverts[_u][_c]) # apply gradient cverts[_u] = self.gradient(cverts[_u]) if callable(inc_pos): inc_pos() return cverts def apply_to_surface(self, verts, u_set, v_set, set_len=None, inc_pos=None): """ Apply this color scheme to a set of vertices over two independent variables u and v. """ bounds = create_bounds() cverts = list() if callable(set_len): set_len(len(u_set)len(v_set)2) # calculate f() = r,g,b for each vert # and find the min and max for r,g,b for _u in range(len(u_set)): column = list() for _v in range(len(v_set)): if verts[_u][_v] is None: column.append(None) else: x, y, z = verts[_u][_v] u, v = u_set[_u], v_set[_v] c = self(x, y, z, u, v) if c is not None: c = list(c) update_bounds(bounds, c) column.append(c) if callable(inc_pos): inc_pos() cverts.append(column) # scale and apply gradient for _u in range(len(u_set)): for _v in range(len(v_set)): if cverts[_u][_v] is not None: # scale from [f_min, f_max] to [0,1] for _c in range(3): cverts[_u][_v][_c] = rinterpolate(bounds[_c][0], bounds[_c][1], cverts[_u][_v][_c]) # apply gradient cverts[_u][_v] = self.gradient(*cverts[_u][_v]) if callable(inc_pos): inc_pos() return cverts def str_base(self): return ", ".join(str(a) for a in self.args) def __repr__(self): return "%s" % (self.str_base()) x, y, z, t, u, v = symbols('x,y,z,t,u,v') default_color_schemes['rainbow'] = ColorScheme(z, y, x) default_color_schemes['zfade'] = ColorScheme(z, (0.4, 0.4, 0.97), (0.97, 0.4, 0.4), (None, None, z)) default_color_schemes['zfade3'] = ColorScheme(z, (None, None, z), [0.00, (0.2, 0.2, 1.0), 0.35, (0.2, 0.8, 0.4), 0.50, (0.3, 0.9, 0.3), 0.65, (0.4, 0.8, 0.2), 1.00, (1.0, 0.2, 0.2)]) default_color_schemes['zfade4'] = ColorScheme(z, (None, None, z), [0.0, (0.3, 0.3, 1.0), 0.30, (0.3, 1.0, 0.3), 0.55, (0.95, 1.0, 0.2), 0.65, (1.0, 0.95, 0.2), 0.85, (1.0, 0.7, 0.2), 1.0, (1.0, 0.3, 0.2)])
b6ca067e3d600e93c50b05f305f6e1dbdee659d70d5006565f56c83c3fd28d5c	from __future__ import print_function, division from pyglet.window import key from pyglet.window.mouse import LEFT, RIGHT, MIDDLE from sympy.plotting.pygletplot.util import get_direction_vectors, get_basis_vectors class PlotController(object): normal_mouse_sensitivity = 4.0 modified_mouse_sensitivity = 1.0 normal_key_sensitivity = 160.0 modified_key_sensitivity = 40.0 keymap = { key.LEFT: 'left', key.A: 'left', key.NUM_4: 'left', key.RIGHT: 'right', key.D: 'right', key.NUM_6: 'right', key.UP: 'up', key.W: 'up', key.NUM_8: 'up', key.DOWN: 'down', key.S: 'down', key.NUM_2: 'down', key.Z: 'rotate_z_neg', key.NUM_1: 'rotate_z_neg', key.C: 'rotate_z_pos', key.NUM_3: 'rotate_z_pos', key.Q: 'spin_left', key.NUM_7: 'spin_left', key.E: 'spin_right', key.NUM_9: 'spin_right', key.X: 'reset_camera', key.NUM_5: 'reset_camera', key.NUM_ADD: 'zoom_in', key.PAGEUP: 'zoom_in', key.R: 'zoom_in', key.NUM_SUBTRACT: 'zoom_out', key.PAGEDOWN: 'zoom_out', key.F: 'zoom_out', key.RSHIFT: 'modify_sensitivity', key.LSHIFT: 'modify_sensitivity', key.F1: 'rot_preset_xy', key.F2: 'rot_preset_xz', key.F3: 'rot_preset_yz', key.F4: 'rot_preset_perspective', key.F5: 'toggle_axes', key.F6: 'toggle_axe_colors', key.F8: 'save_image' } def __init__(self, window, *kwargs): self.invert_mouse_zoom = kwargs.pop('invert_mouse_zoom', False) self.window = window self.camera = window.camera self.action = { # Rotation around the view Y (up) vector 'left': False, 'right': False, # Rotation around the view X vector 'up': False, 'down': False, # Rotation around the view Z vector 'spin_left': False, 'spin_right': False, # Rotation around the model Z vector 'rotate_z_neg': False, 'rotate_z_pos': False, # Reset to the default rotation 'reset_camera': False, # Performs camera z-translation 'zoom_in': False, 'zoom_out': False, # Use alternative sensitivity (speed) 'modify_sensitivity': False, # Rotation presets 'rot_preset_xy': False, 'rot_preset_xz': False, 'rot_preset_yz': False, 'rot_preset_perspective': False, # axes 'toggle_axes': False, 'toggle_axe_colors': False, # screenshot 'save_image': False } def update(self, dt): z = 0 if self.action['zoom_out']: z -= 1 if self.action['zoom_in']: z += 1 if z != 0: self.camera.zoom_relative(z/10.0, self.get_key_sensitivity()/10.0) dx, dy, dz = 0, 0, 0 if self.action['left']: dx -= 1 if self.action['right']: dx += 1 if self.action['up']: dy -= 1 if self.action['down']: dy += 1 if self.action['spin_left']: dz += 1 if self.action['spin_right']: dz -= 1 if not self.is_2D(): if dx != 0: self.camera.euler_rotate(dxdtself.get_key_sensitivity(), (get_direction_vectors()[1])) if dy != 0: self.camera.euler_rotate(dydtself.get_key_sensitivity(), (get_direction_vectors()[0])) if dz != 0: self.camera.euler_rotate(dzdtself.get_key_sensitivity(), (get_direction_vectors()[2])) else: self.camera.mouse_translate(0, 0, dxdtself.get_key_sensitivity(), -dydtself.get_key_sensitivity()) rz = 0 if self.action['rotate_z_neg'] and not self.is_2D(): rz -= 1 if self.action['rotate_z_pos'] and not self.is_2D(): rz += 1 if rz != 0: self.camera.euler_rotate(rzdtself.get_key_sensitivity(), (get_basis_vectors()[2])) if self.action['reset_camera']: self.camera.reset() if self.action['rot_preset_xy']: self.camera.set_rot_preset('xy') if self.action['rot_preset_xz']: self.camera.set_rot_preset('xz') if self.action['rot_preset_yz']: self.camera.set_rot_preset('yz') if self.action['rot_preset_perspective']: self.camera.set_rot_preset('perspective') if self.action['toggle_axes']: self.action['toggle_axes'] = False self.camera.axes.toggle_visible() if self.action['toggle_axe_colors']: self.action['toggle_axe_colors'] = False self.camera.axes.toggle_colors() if self.action['save_image']: self.action['save_image'] = False self.window.plot.saveimage() return True def get_mouse_sensitivity(self): if self.action['modify_sensitivity']: return self.modified_mouse_sensitivity else: return self.normal_mouse_sensitivity def get_key_sensitivity(self): if self.action['modify_sensitivity']: return self.modified_key_sensitivity else: return self.normal_key_sensitivity def on_key_press(self, symbol, modifiers): if symbol in self.keymap: self.action[self.keymap[symbol]] = True def on_key_release(self, symbol, modifiers): if symbol in self.keymap: self.action[self.keymap[symbol]] = False def on_mouse_drag(self, x, y, dx, dy, buttons, modifiers): if buttons & LEFT: if self.is_2D(): self.camera.mouse_translate(x, y, dx, dy) else: self.camera.spherical_rotate((x - dx, y - dy), (x, y), self.get_mouse_sensitivity()) if buttons & MIDDLE: self.camera.zoom_relative([1, -1][self.invert_mouse_zoom]dy, self.get_mouse_sensitivity()/20.0) if buttons & RIGHT: self.camera.mouse_translate(x, y, dx, dy) def on_mouse_scroll(self, x, y, dx, dy): self.camera.zoom_relative([1, -1][self.invert_mouse_zoom]*dy, self.get_mouse_sensitivity()) def is_2D(self): functions = self.window.plot._functions for i in functions: if len(functions[i].i_vars) > 1 or len(functions[i].d_vars) > 2: return False return True
947d1ea379fad7042f321b974af5ba790e32ef8502d6c159a28c0838f9d1cf12	from __future__ import print_function, division import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import range from sympy.plotting.pygletplot.plot_mode_base import PlotModeBase class PlotCurve(PlotModeBase): style_override = 'wireframe' def _on_calculate_verts(self): self.t_interval = self.intervals[0] self.t_set = list(self.t_interval.frange()) self.bounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] evaluate = self._get_evaluator() self._calculating_verts_pos = 0.0 self._calculating_verts_len = float(self.t_interval.v_len) self.verts = list() b = self.bounds for t in self.t_set: try: _e = evaluate(t) # calculate vertex except (NameError, ZeroDivisionError): _e = None if _e is not None: # update bounding box for axis in range(3): b[axis][0] = min([b[axis][0], _e[axis]]) b[axis][1] = max([b[axis][1], _e[axis]]) self.verts.append(_e) self._calculating_verts_pos += 1.0 for axis in range(3): b[axis][2] = b[axis][1] - b[axis][0] if b[axis][2] == 0.0: b[axis][2] = 1.0 self.push_wireframe(self.draw_verts(False)) def _on_calculate_cverts(self): if not self.verts or not self.color: return def set_work_len(n): self._calculating_cverts_len = float(n) def inc_work_pos(): self._calculating_cverts_pos += 1.0 set_work_len(1) self._calculating_cverts_pos = 0 self.cverts = self.color.apply_to_curve(self.verts, self.t_set, set_len=set_work_len, inc_pos=inc_work_pos) self.push_wireframe(self.draw_verts(True)) def calculate_one_cvert(self, t): vert = self.verts[t] return self.color(vert[0], vert[1], vert[2], self.t_set[t], None) def draw_verts(self, use_cverts): def f(): pgl.glBegin(pgl.GL_LINE_STRIP) for t in range(len(self.t_set)): p = self.verts[t] if p is None: pgl.glEnd() pgl.glBegin(pgl.GL_LINE_STRIP) continue if use_cverts: c = self.cverts[t] if c is None: c = (0, 0, 0) pgl.glColor3f(c) else: pgl.glColor3f(self.default_wireframe_color) pgl.glVertex3f(*p) pgl.glEnd() return f
d468d037ac1a373a2d0a0831a1f5cc82981e499489912f722553f82b6856c900	from __future__ import print_function, division import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import range from sympy.plotting.pygletplot.plot_mode_base import PlotModeBase class PlotSurface(PlotModeBase): default_rot_preset = 'perspective' def _on_calculate_verts(self): self.u_interval = self.intervals[0] self.u_set = list(self.u_interval.frange()) self.v_interval = self.intervals[1] self.v_set = list(self.v_interval.frange()) self.bounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] evaluate = self._get_evaluator() self._calculating_verts_pos = 0.0 self._calculating_verts_len = float( self.u_interval.v_lenself.v_interval.v_len) verts = list() b = self.bounds for u in self.u_set: column = list() for v in self.v_set: try: _e = evaluate(u, v) # calculate vertex except ZeroDivisionError: _e = None if _e is not None: # update bounding box for axis in range(3): b[axis][0] = min([b[axis][0], _e[axis]]) b[axis][1] = max([b[axis][1], _e[axis]]) column.append(_e) self._calculating_verts_pos += 1.0 verts.append(column) for axis in range(3): b[axis][2] = b[axis][1] - b[axis][0] if b[axis][2] == 0.0: b[axis][2] = 1.0 self.verts = verts self.push_wireframe(self.draw_verts(False, False)) self.push_solid(self.draw_verts(False, True)) def _on_calculate_cverts(self): if not self.verts or not self.color: return def set_work_len(n): self._calculating_cverts_len = float(n) def inc_work_pos(): self._calculating_cverts_pos += 1.0 set_work_len(1) self._calculating_cverts_pos = 0 self.cverts = self.color.apply_to_surface(self.verts, self.u_set, self.v_set, set_len=set_work_len, inc_pos=inc_work_pos) self.push_solid(self.draw_verts(True, True)) def calculate_one_cvert(self, u, v): vert = self.verts[u][v] return self.color(vert[0], vert[1], vert[2], self.u_set[u], self.v_set[v]) def draw_verts(self, use_cverts, use_solid_color): def f(): for u in range(1, len(self.u_set)): pgl.glBegin(pgl.GL_QUAD_STRIP) for v in range(len(self.v_set)): pa = self.verts[u - 1][v] pb = self.verts[u][v] if pa is None or pb is None: pgl.glEnd() pgl.glBegin(pgl.GL_QUAD_STRIP) continue if use_cverts: ca = self.cverts[u - 1][v] cb = self.cverts[u][v] if ca is None: ca = (0, 0, 0) if cb is None: cb = (0, 0, 0) else: if use_solid_color: ca = cb = self.default_solid_color else: ca = cb = self.default_wireframe_color pgl.glColor3f(ca) pgl.glVertex3f(pa) pgl.glColor3f(cb) pgl.glVertex3f(*pb) pgl.glEnd() return f
3a4cef03a4b43308a62cd3df32fcf73b3ce65692e6f52fbed938338d631deba5	from __future__ import print_function, division from sympy import Symbol, sympify from sympy.core.compatibility import range, string_types from sympy.core.numbers import Integer class PlotInterval(object): """ """ _v, _v_min, _v_max, _v_steps = None, None, None, None def require_all_args(f): def check(self, args, kwargs): for g in [self._v, self._v_min, self._v_max, self._v_steps]: if g is None: raise ValueError("PlotInterval is incomplete.") return f(self, args, *kwargs) return check def __init__(self, args): if len(args) == 1: if isinstance(args[0], PlotInterval): self.fill_from(args[0]) return elif isinstance(args[0], string_types): try: args = eval(args[0]) except TypeError: s_eval_error = "Could not interpret string %s." raise ValueError(s_eval_error % (args[0])) elif isinstance(args[0], (tuple, list)): args = args[0] else: raise ValueError("Not an interval.") if not isinstance(args, (tuple, list)) or len(args) > 4: f_error = "PlotInterval must be a tuple or list of length 4 or less." raise ValueError(f_error) args = list(args) if len(args) > 0 and (args[0] is None or isinstance(args[0], Symbol)): self.v = args.pop(0) if len(args) in [2, 3]: self.v_min = args.pop(0) self.v_max = args.pop(0) if len(args) == 1: self.v_steps = args.pop(0) elif len(args) == 1: self.v_steps = args.pop(0) def get_v(self): return self._v def set_v(self, v): if v is None: self._v = None return if not isinstance(v, Symbol): raise ValueError("v must be a sympy Symbol.") self._v = v def get_v_min(self): return self._v_min def set_v_min(self, v_min): if v_min is None: self._v_min = None return try: self._v_min = sympify(v_min) float(self._v_min.evalf()) except TypeError: raise ValueError("v_min could not be interpreted as a number.") def get_v_max(self): return self._v_max def set_v_max(self, v_max): if v_max is None: self._v_max = None return try: self._v_max = sympify(v_max) float(self._v_max.evalf()) except TypeError: raise ValueError("v_max could not be interpreted as a number.") def get_v_steps(self): return self._v_steps def set_v_steps(self, v_steps): if v_steps is None: self._v_steps = None return if isinstance(v_steps, int): v_steps = Integer(v_steps) elif not isinstance(v_steps, Integer): raise ValueError("v_steps must be an int or sympy Integer.") if v_steps <= Integer(0): raise ValueError("v_steps must be positive.") self._v_steps = v_steps @require_all_args def get_v_len(self): return self.v_steps + 1 v = property(get_v, set_v) v_min = property(get_v_min, set_v_min) v_max = property(get_v_max, set_v_max) v_steps = property(get_v_steps, set_v_steps) v_len = property(get_v_len) def fill_from(self, b): if b.v is not None: self.v = b.v if b.v_min is not None: self.v_min = b.v_min if b.v_max is not None: self.v_max = b.v_max if b.v_steps is not None: self.v_steps = b.v_steps @staticmethod def try_parse(args): """ Returns a PlotInterval if args can be interpreted as such, otherwise None. """ if len(args) == 1 and isinstance(args[0], PlotInterval): return args[0] try: return PlotInterval(args) except ValueError: return None def _str_base(self): return ",".join([str(self.v), str(self.v_min), str(self.v_max), str(self.v_steps)]) def __repr__(self): """ A string representing the interval in class constructor form. """ return "PlotInterval(%s)" % (self._str_base()) def __str__(self): """ A string representing the interval in list form. """ return "[%s]" % (self._str_base()) @require_all_args def assert_complete(self): pass @require_all_args def vrange(self): """ Yields v_steps+1 sympy numbers ranging from v_min to v_max. """ d = (self.v_max - self.v_min) / self.v_steps for i in range(self.v_steps + 1): a = self.v_min + (d * Integer(i)) yield a @require_all_args def vrange2(self): """ Yields v_steps pairs of sympy numbers ranging from (v_min, v_min + step) to (v_max - step, v_max). """ d = (self.v_max - self.v_min) / self.v_steps a = self.v_min + (d * Integer(0)) for i in range(self.v_steps): b = self.v_min + (d * Integer(i + 1)) yield a, b a = b def frange(self): for i in self.vrange(): yield float(i.evalf())
83f9b6af3ed1419443b8733d48685c5d1071197d037943983631113dd42c8811	from __future__ import print_function, division from sympy import lambdify from sympy.core.numbers import pi from sympy.functions import sin, cos from sympy.plotting.pygletplot.plot_curve import PlotCurve from sympy.plotting.pygletplot.plot_surface import PlotSurface from math import sin as p_sin from math import cos as p_cos def float_vec3(f): def inner(args): v = f(args) return float(v[0]), float(v[1]), float(v[2]) return inner class Cartesian2D(PlotCurve): i_vars, d_vars = 'x', 'y' intervals = [[-5, 5, 100]] aliases = ['cartesian'] is_default = True def _get_sympy_evaluator(self): fy = self.d_vars[0] x = self.t_interval.v @float_vec3 def e(_x): return (_x, fy.subs(x, _x), 0.0) return e def _get_lambda_evaluator(self): fy = self.d_vars[0] x = self.t_interval.v return lambdify([x], [x, fy, 0.0]) class Cartesian3D(PlotSurface): i_vars, d_vars = 'xy', 'z' intervals = [[-1, 1, 40], [-1, 1, 40]] aliases = ['cartesian', 'monge'] is_default = True def _get_sympy_evaluator(self): fz = self.d_vars[0] x = self.u_interval.v y = self.v_interval.v @float_vec3 def e(_x, _y): return (_x, _y, fz.subs(x, _x).subs(y, _y)) return e def _get_lambda_evaluator(self): fz = self.d_vars[0] x = self.u_interval.v y = self.v_interval.v return lambdify([x, y], [x, y, fz]) class ParametricCurve2D(PlotCurve): i_vars, d_vars = 't', 'xy' intervals = [[0, 2pi, 100]] aliases = ['parametric'] is_default = True def _get_sympy_evaluator(self): fx, fy = self.d_vars t = self.t_interval.v @float_vec3 def e(_t): return (fx.subs(t, _t), fy.subs(t, _t), 0.0) return e def _get_lambda_evaluator(self): fx, fy = self.d_vars t = self.t_interval.v return lambdify([t], [fx, fy, 0.0]) class ParametricCurve3D(PlotCurve): i_vars, d_vars = 't', 'xyz' intervals = [[0, 2pi, 100]] aliases = ['parametric'] is_default = True def _get_sympy_evaluator(self): fx, fy, fz = self.d_vars t = self.t_interval.v @float_vec3 def e(_t): return (fx.subs(t, _t), fy.subs(t, _t), fz.subs(t, _t)) return e def _get_lambda_evaluator(self): fx, fy, fz = self.d_vars t = self.t_interval.v return lambdify([t], [fx, fy, fz]) class ParametricSurface(PlotSurface): i_vars, d_vars = 'uv', 'xyz' intervals = [[-1, 1, 40], [-1, 1, 40]] aliases = ['parametric'] is_default = True def _get_sympy_evaluator(self): fx, fy, fz = self.d_vars u = self.u_interval.v v = self.v_interval.v @float_vec3 def e(_u, _v): return (fx.subs(u, _u).subs(v, _v), fy.subs(u, _u).subs(v, _v), fz.subs(u, _u).subs(v, _v)) return e def _get_lambda_evaluator(self): fx, fy, fz = self.d_vars u = self.u_interval.v v = self.v_interval.v return lambdify([u, v], [fx, fy, fz]) class Polar(PlotCurve): i_vars, d_vars = 't', 'r' intervals = [[0, 2pi, 100]] aliases = ['polar'] is_default = False def _get_sympy_evaluator(self): fr = self.d_vars[0] t = self.t_interval.v def e(_t): _r = float(fr.subs(t, _t)) return (_rp_cos(_t), _rp_sin(_t), 0.0) return e def _get_lambda_evaluator(self): fr = self.d_vars[0] t = self.t_interval.v fx, fy = frcos(t), frsin(t) return lambdify([t], [fx, fy, 0.0]) class Cylindrical(PlotSurface): i_vars, d_vars = 'th', 'r' intervals = [[0, 2pi, 40], [-1, 1, 20]] aliases = ['cylindrical', 'polar'] is_default = False def _get_sympy_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v h = self.v_interval.v def e(_t, _h): _r = float(fr.subs(t, _t).subs(h, _h)) return (_rp_cos(_t), _rp_sin(_t), _h) return e def _get_lambda_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v h = self.v_interval.v fx, fy = frcos(t), frsin(t) return lambdify([t, h], [fx, fy, h]) class Spherical(PlotSurface): i_vars, d_vars = 'tp', 'r' intervals = [[0, 2pi, 40], [0, pi, 20]] aliases = ['spherical'] is_default = False def _get_sympy_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v p = self.v_interval.v def e(_t, _p): _r = float(fr.subs(t, _t).subs(p, _p)) return (_rp_cos(_t)p_sin(_p), _rp_sin(_t)p_sin(_p), _rp_cos(_p)) return e def _get_lambda_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v p = self.v_interval.v fx = fr * cos(t) * sin(p) fy = fr * sin(t) * sin(p) fz = fr * cos(p) return lambdify([t, p], [fx, fy, fz]) Cartesian2D._register() Cartesian3D._register() ParametricCurve2D._register() ParametricCurve3D._register() ParametricSurface._register() Polar._register() Cylindrical._register() Spherical._register()
7082237a33ebdb621078e1387306cbb88dca200b23de9242083a25a4ab00b4ed	from __future__ import print_function, division try: from ctypes import c_float, c_int, c_double except ImportError: pass import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import range, string_types def get_model_matrix(array_type=c_float, glGetMethod=pgl.glGetFloatv): """ Returns the current modelview matrix. """ m = (array_type16)() glGetMethod(pgl.GL_MODELVIEW_MATRIX, m) return m def get_projection_matrix(array_type=c_float, glGetMethod=pgl.glGetFloatv): """ Returns the current modelview matrix. """ m = (array_type16)() glGetMethod(pgl.GL_PROJECTION_MATRIX, m) return m def get_viewport(): """ Returns the current viewport. """ m = (c_int4)() pgl.glGetIntegerv(pgl.GL_VIEWPORT, m) return m def get_direction_vectors(): m = get_model_matrix() return ((m[0], m[4], m[8]), (m[1], m[5], m[9]), (m[2], m[6], m[10])) def get_view_direction_vectors(): m = get_model_matrix() return ((m[0], m[1], m[2]), (m[4], m[5], m[6]), (m[8], m[9], m[10])) def get_basis_vectors(): return ((1, 0, 0), (0, 1, 0), (0, 0, 1)) def screen_to_model(x, y, z): m = get_model_matrix(c_double, pgl.glGetDoublev) p = get_projection_matrix(c_double, pgl.glGetDoublev) w = get_viewport() mx, my, mz = c_double(), c_double(), c_double() pgl.gluUnProject(x, y, z, m, p, w, mx, my, mz) return float(mx.value), float(my.value), float(mz.value) def model_to_screen(x, y, z): m = get_model_matrix(c_double, pgl.glGetDoublev) p = get_projection_matrix(c_double, pgl.glGetDoublev) w = get_viewport() mx, my, mz = c_double(), c_double(), c_double() pgl.gluProject(x, y, z, m, p, w, mx, my, mz) return float(mx.value), float(my.value), float(mz.value) def vec_subs(a, b): return tuple(a[i] - b[i] for i in range(len(a))) def billboard_matrix(): """ Removes rotational components of current matrix so that primitives are always drawn facing the viewer. \|1\|0\|0\|x\| \|0\|1\|0\|x\| \|0\|0\|1\|x\| (x means left unchanged) \|x\|x\|x\|x\| """ m = get_model_matrix() # XXX: for i in range(11): m[i] = i ? m[0] = 1 m[1] = 0 m[2] = 0 m[4] = 0 m[5] = 1 m[6] = 0 m[8] = 0 m[9] = 0 m[10] = 1 pgl.glLoadMatrixf(m) def create_bounds(): return [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] def update_bounds(b, v): if v is None: return for axis in range(3): b[axis][0] = min([b[axis][0], v[axis]]) b[axis][1] = max([b[axis][1], v[axis]]) def interpolate(a_min, a_max, a_ratio): return a_min + a_ratio (a_max - a_min) def rinterpolate(a_min, a_max, a_value): a_range = a_max - a_min if a_max == a_min: a_range = 1.0 return (a_value - a_min) / float(a_range) def interpolate_color(color1, color2, ratio): return tuple(interpolate(color1[i], color2[i], ratio) for i in range(3)) def scale_value(v, v_min, v_len): return (v - v_min) / v_len def scale_value_list(flist): v_min, v_max = min(flist), max(flist) v_len = v_max - v_min return list(scale_value(f, v_min, v_len) for f in flist) def strided_range(r_min, r_max, stride, max_steps=50): o_min, o_max = r_min, r_max if abs(r_min - r_max) < 0.001: return [] try: range(int(r_min - r_max)) except (TypeError, OverflowError): return [] if r_min > r_max: raise ValueError("r_min can not be greater than r_max") r_min_s = (r_min % stride) r_max_s = stride - (r_max % stride) if abs(r_max_s - stride) < 0.001: r_max_s = 0.0 r_min -= r_min_s r_max += r_max_s r_steps = int((r_max - r_min)/stride) if max_steps and r_steps > max_steps: return strided_range(o_min, o_max, stride2) return [r_min] + list(r_min + estride for e in range(1, r_steps + 1)) + [r_max] def parse_option_string(s): if not isinstance(s, string_types): return None options = {} for token in s.split(';'): pieces = token.split('=') if len(pieces) == 1: option, value = pieces[0], "" elif len(pieces) == 2: option, value = pieces else: raise ValueError("Plot option string '%s' is malformed." % (s)) options[option.strip()] = value.strip() return options def dot_product(v1, v2): return sum(v1[i]v2[i] for i in range(3)) def vec_sub(v1, v2): return tuple(v1[i] - v2[i] for i in range(3)) def vec_mag(v): return sum(v[i]2 for i in range(3))*(0.5)
a0ba992d23f237e107570f3aa608ce6954e8e3e859cedeaefd8da6677b7b5bfe	from __future__ import print_function, division from time import clock import pyglet.gl as pgl from sympy.plotting.pygletplot.managed_window import ManagedWindow from sympy.plotting.pygletplot.plot_camera import PlotCamera from sympy.plotting.pygletplot.plot_controller import PlotController class PlotWindow(ManagedWindow): def __init__(self, plot, antialiasing=True, ortho=False, invert_mouse_zoom=False, linewidth=1.5, caption="SymPy Plot", kwargs): """ Named Arguments =============== antialiasing = True True OR False ortho = False True OR False invert_mouse_zoom = False True OR False """ self.plot = plot self.camera = None self._calculating = False self.antialiasing = antialiasing self.ortho = ortho self.invert_mouse_zoom = invert_mouse_zoom self.linewidth = linewidth self.title = caption self.last_caption_update = 0 self.caption_update_interval = 0.2 self.drawing_first_object = True super(PlotWindow, self).__init__(kwargs) def setup(self): self.camera = PlotCamera(self, ortho=self.ortho) self.controller = PlotController(self, invert_mouse_zoom=self.invert_mouse_zoom) self.push_handlers(self.controller) pgl.glClearColor(1.0, 1.0, 1.0, 0.0) pgl.glClearDepth(1.0) pgl.glDepthFunc(pgl.GL_LESS) pgl.glEnable(pgl.GL_DEPTH_TEST) pgl.glEnable(pgl.GL_LINE_SMOOTH) pgl.glShadeModel(pgl.GL_SMOOTH) pgl.glLineWidth(self.linewidth) pgl.glEnable(pgl.GL_BLEND) pgl.glBlendFunc(pgl.GL_SRC_ALPHA, pgl.GL_ONE_MINUS_SRC_ALPHA) if self.antialiasing: pgl.glHint(pgl.GL_LINE_SMOOTH_HINT, pgl.GL_NICEST) pgl.glHint(pgl.GL_POLYGON_SMOOTH_HINT, pgl.GL_NICEST) self.camera.setup_projection() def on_resize(self, w, h): super(PlotWindow, self).on_resize(w, h) if self.camera is not None: self.camera.setup_projection() def update(self, dt): self.controller.update(dt) def draw(self): self.plot._render_lock.acquire() self.camera.apply_transformation() calc_verts_pos, calc_verts_len = 0, 0 calc_cverts_pos, calc_cverts_len = 0, 0 should_update_caption = (clock() - self.last_caption_update > self.caption_update_interval) if len(self.plot._functions.values()) == 0: self.drawing_first_object = True try: dict.iteritems except AttributeError: # Python 3 iterfunctions = iter(self.plot._functions.values()) else: # Python 2 iterfunctions = self.plot._functions.itervalues() for r in iterfunctions: if self.drawing_first_object: self.camera.set_rot_preset(r.default_rot_preset) self.drawing_first_object = False pgl.glPushMatrix() r._draw() pgl.glPopMatrix() # might as well do this while we are # iterating and have the lock rather # than locking and iterating twice # per frame: if should_update_caption: try: if r.calculating_verts: calc_verts_pos += r.calculating_verts_pos calc_verts_len += r.calculating_verts_len if r.calculating_cverts: calc_cverts_pos += r.calculating_cverts_pos calc_cverts_len += r.calculating_cverts_len except ValueError: pass for r in self.plot._pobjects: pgl.glPushMatrix() r._draw() pgl.glPopMatrix() if should_update_caption: self.update_caption(calc_verts_pos, calc_verts_len, calc_cverts_pos, calc_cverts_len) self.last_caption_update = clock() if self.plot._screenshot: self.plot._screenshot._execute_saving() self.plot._render_lock.release() def update_caption(self, calc_verts_pos, calc_verts_len, calc_cverts_pos, calc_cverts_len): caption = self.title if calc_verts_len or calc_cverts_len: caption += " (calculating" if calc_verts_len > 0: p = (calc_verts_pos / calc_verts_len) * 100 caption += " vertices %i%%" % (p) if calc_cverts_len > 0: p = (calc_cverts_pos / calc_cverts_len) * 100 caption += " colors %i%%" % (p) caption += ")" if self.caption != caption: self.set_caption(caption)
b42587ae5bc1653676c961b8af5316f0e186562ef427694c92ace3143e7050c3	from __future__ import print_function, division import pyglet.gl as pgl from pyglet import font from sympy.core import S from sympy.core.compatibility import is_sequence from sympy.plotting.pygletplot.plot_object import PlotObject from sympy.plotting.pygletplot.util import billboard_matrix, dot_product, \ get_direction_vectors, strided_range, vec_mag, vec_sub class PlotAxes(PlotObject): def __init__(self, args, kwargs): # initialize style parameter style = kwargs.pop('style', '').lower() # allow alias kwargs to override style kwarg if kwargs.pop('none', None) is not None: style = 'none' if kwargs.pop('frame', None) is not None: style = 'frame' if kwargs.pop('box', None) is not None: style = 'box' if kwargs.pop('ordinate', None) is not None: style = 'ordinate' if style in ['', 'ordinate']: self._render_object = PlotAxesOrdinate(self) elif style in ['frame', 'box']: self._render_object = PlotAxesFrame(self) elif style in ['none']: self._render_object = None else: raise ValueError(("Unrecognized axes style %s.") % (style)) # initialize stride parameter stride = kwargs.pop('stride', 0.25) try: stride = eval(stride) except TypeError: pass if is_sequence(stride): if len(stride) != 3: raise ValueError("length should be equal to 3") self._stride = stride else: self._stride = [stride, stride, stride] self._tick_length = float(kwargs.pop('tick_length', 0.1)) # setup bounding box and ticks self._origin = [0, 0, 0] self.reset_bounding_box() def flexible_boolean(input, default): if input in [True, False]: return input if input in ['f', 'F', 'false', 'False']: return False if input in ['t', 'T', 'true', 'True']: return True return default # initialize remaining parameters self.visible = flexible_boolean(kwargs.pop('visible', ''), True) self._overlay = flexible_boolean(kwargs.pop('overlay', ''), True) self._colored = flexible_boolean(kwargs.pop('colored', ''), False) self._label_axes = flexible_boolean( kwargs.pop('label_axes', ''), False) self._label_ticks = flexible_boolean( kwargs.pop('label_ticks', ''), True) # setup label font self.font_face = kwargs.pop('font_face', 'Arial') self.font_size = kwargs.pop('font_size', 28) # this is also used to reinit the # font on window close/reopen self.reset_resources() def reset_resources(self): self.label_font = None def reset_bounding_box(self): self._bounding_box = [[None, None], [None, None], [None, None]] self._axis_ticks = [[], [], []] def draw(self): if self._render_object: pgl.glPushAttrib(pgl.GL_ENABLE_BIT \| pgl.GL_POLYGON_BIT \| pgl.GL_DEPTH_BUFFER_BIT) if self._overlay: pgl.glDisable(pgl.GL_DEPTH_TEST) self._render_object.draw() pgl.glPopAttrib() def adjust_bounds(self, child_bounds): b = self._bounding_box c = child_bounds for i in [0, 1, 2]: if abs(c[i][0]) is S.Infinity or abs(c[i][1]) is S.Infinity: continue b[i][0] = c[i][0] if b[i][0] is None else min([b[i][0], c[i][0]]) b[i][1] = c[i][1] if b[i][1] is None else max([b[i][1], c[i][1]]) self._bounding_box = b self._recalculate_axis_ticks(i) def _recalculate_axis_ticks(self, axis): b = self._bounding_box if b[axis][0] is None or b[axis][1] is None: self._axis_ticks[axis] = [] else: self._axis_ticks[axis] = strided_range(b[axis][0], b[axis][1], self._stride[axis]) def toggle_visible(self): self.visible = not self.visible def toggle_colors(self): self._colored = not self._colored class PlotAxesBase(PlotObject): def __init__(self, parent_axes): self._p = parent_axes def draw(self): color = [([0.2, 0.1, 0.3], [0.2, 0.1, 0.3], [0.2, 0.1, 0.3]), ([0.9, 0.3, 0.5], [0.5, 1.0, 0.5], [0.3, 0.3, 0.9])][self._p._colored] self.draw_background(color) self.draw_axis(2, color[2]) self.draw_axis(1, color[1]) self.draw_axis(0, color[0]) def draw_background(self, color): pass # optional def draw_axis(self, axis, color): raise NotImplementedError() def draw_text(self, text, position, color, scale=1.0): if len(color) == 3: color = (color[0], color[1], color[2], 1.0) if self._p.label_font is None: self._p.label_font = font.load(self._p.font_face, self._p.font_size, bold=True, italic=False) label = font.Text(self._p.label_font, text, color=color, valign=font.Text.BASELINE, halign=font.Text.CENTER) pgl.glPushMatrix() pgl.glTranslatef(position) billboard_matrix() scale_factor = 0.005 * scale pgl.glScalef(scale_factor, scale_factor, scale_factor) pgl.glColor4f(0, 0, 0, 0) label.draw() pgl.glPopMatrix() def draw_line(self, v, color): o = self._p._origin pgl.glBegin(pgl.GL_LINES) pgl.glColor3f(color) pgl.glVertex3f(v[0][0] + o[0], v[0][1] + o[1], v[0][2] + o[2]) pgl.glVertex3f(v[1][0] + o[0], v[1][1] + o[1], v[1][2] + o[2]) pgl.glEnd() class PlotAxesOrdinate(PlotAxesBase): def __init__(self, parent_axes): super(PlotAxesOrdinate, self).__init__(parent_axes) def draw_axis(self, axis, color): ticks = self._p._axis_ticks[axis] radius = self._p._tick_length / 2.0 if len(ticks) < 2: return # calculate the vector for this axis axis_lines = [[0, 0, 0], [0, 0, 0]] axis_lines[0][axis], axis_lines[1][axis] = ticks[0], ticks[-1] axis_vector = vec_sub(axis_lines[1], axis_lines[0]) # calculate angle to the z direction vector pos_z = get_direction_vectors()[2] d = abs(dot_product(axis_vector, pos_z)) d = d / vec_mag(axis_vector) # don't draw labels if we're looking down the axis labels_visible = abs(d - 1.0) > 0.02 # draw the ticks and labels for tick in ticks: self.draw_tick_line(axis, color, radius, tick, labels_visible) # draw the axis line and labels self.draw_axis_line(axis, color, ticks[0], ticks[-1], labels_visible) def draw_axis_line(self, axis, color, a_min, a_max, labels_visible): axis_line = [[0, 0, 0], [0, 0, 0]] axis_line[0][axis], axis_line[1][axis] = a_min, a_max self.draw_line(axis_line, color) if labels_visible: self.draw_axis_line_labels(axis, color, axis_line) def draw_axis_line_labels(self, axis, color, axis_line): if not self._p._label_axes: return axis_labels = [axis_line[0][::], axis_line[1][::]] axis_labels[0][axis] -= 0.3 axis_labels[1][axis] += 0.3 a_str = ['X', 'Y', 'Z'][axis] self.draw_text("-" + a_str, axis_labels[0], color) self.draw_text("+" + a_str, axis_labels[1], color) def draw_tick_line(self, axis, color, radius, tick, labels_visible): tick_axis = {0: 1, 1: 0, 2: 1}[axis] tick_line = [[0, 0, 0], [0, 0, 0]] tick_line[0][axis] = tick_line[1][axis] = tick tick_line[0][tick_axis], tick_line[1][tick_axis] = -radius, radius self.draw_line(tick_line, color) if labels_visible: self.draw_tick_line_label(axis, color, radius, tick) def draw_tick_line_label(self, axis, color, radius, tick): if not self._p._label_axes: return tick_label_vector = [0, 0, 0] tick_label_vector[axis] = tick tick_label_vector[{0: 1, 1: 0, 2: 1}[axis]] = [-1, 1, 1][ axis] radius * 3.5 self.draw_text(str(tick), tick_label_vector, color, scale=0.5) class PlotAxesFrame(PlotAxesBase): def __init__(self, parent_axes): super(PlotAxesFrame, self).__init__(parent_axes) def draw_background(self, color): pass def draw_axis(self, axis, color): raise NotImplementedError()
b7491187f3548a4aa6457af8582722b52317c0e6897681d90167239e2428f068	#!/usr/bin/env python """ Program to test that all methods/functions have at least one example doctest. Also checks if docstrings are imported into Sphinx. For this to work, the Sphinx docs need to be built first. Use "cd doc; make html" to build the Sphinx docs. Usage: ./bin/coverage_doctest.py sympy/core or ./bin/coverage_doctest.py sympy/core/basic.py If no arguments are given, all files in sympy/ are checked. """ from __future__ import print_function import os import sys import inspect from argparse import ArgumentParser, RawDescriptionHelpFormatter try: from HTMLParser import HTMLParser except ImportError: # It's html.parser in Python 3 from html.parser import HTMLParser from sympy.utilities.misc import filldedent # Load color templates, used from sympy/utilities/runtests.py color_templates = ( ("Black", "0;30"), ("Red", "0;31"), ("Green", "0;32"), ("Brown", "0;33"), ("Blue", "0;34"), ("Purple", "0;35"), ("Cyan", "0;36"), ("LightGray", "0;37"), ("DarkGray", "1;30"), ("LightRed", "1;31"), ("LightGreen", "1;32"), ("Yellow", "1;33"), ("LightBlue", "1;34"), ("LightPurple", "1;35"), ("LightCyan", "1;36"), ("White", "1;37"), ) colors = {} for name, value in color_templates: colors[name] = value c_normal = '\033[0m' c_color = '\033[%sm' def print_header(name, underline=None, color=None): print() if color: print("%s%s%s" % (c_color % colors[color], name, c_normal)) else: print(name) if underline and not color: print(underlinelen(name)) def print_coverage(module_path, c, c_md, c_mdt, c_idt, c_sph, f, f_md, f_mdt, f_idt, f_sph, score, total_doctests, total_members, sphinx_score, total_sphinx, verbose=False, no_color=False, sphinx=True): """ Prints details (depending on verbose) of a module """ doctest_color = "Brown" sphinx_color = "DarkGray" less_100_color = "Red" less_50_color = "LightRed" equal_100_color = "Green" big_header_color = "LightPurple" small_header_color = "Purple" if no_color: score_string = "Doctests: %s%% (%s of %s)" % (score, total_doctests, total_members) elif score < 100: if score < 50: score_string = "%sDoctests:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[doctest_color], c_normal, c_color % colors[less_50_color], score, total_doctests, total_members, c_normal) else: score_string = "%sDoctests:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[doctest_color], c_normal, c_color % colors[less_100_color], score, total_doctests, total_members, c_normal) else: score_string = "%sDoctests:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[doctest_color], c_normal, c_color % colors[equal_100_color], score, total_doctests, total_members, c_normal) if sphinx: if no_color: sphinx_score_string = "Sphinx: %s%% (%s of %s)" % (sphinx_score, total_members - total_sphinx, total_members) elif sphinx_score < 100: if sphinx_score < 50: sphinx_score_string = "%sSphinx:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[sphinx_color], c_normal, c_color % colors[less_50_color], sphinx_score, total_members - total_sphinx, total_members, c_normal) else: sphinx_score_string = "%sSphinx:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[sphinx_color], c_normal, c_color % colors[less_100_color], sphinx_score, total_members - total_sphinx, total_members, c_normal) else: sphinx_score_string = "%sSphinx:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[sphinx_color], c_normal, c_color % colors[equal_100_color], sphinx_score, total_members - total_sphinx, total_members, c_normal) if verbose: print('\n' + '-'70) print(module_path) print('-'70) else: if sphinx: print("%s: %s %s" % (module_path, score_string, sphinx_score_string)) else: print("%s: %s" % (module_path, score_string)) if verbose: print_header('CLASSES', '', not no_color and big_header_color) if not c: print_header('No classes found!') else: if c_md: print_header('Missing docstrings', '-', not no_color and small_header_color) for md in c_md: print(' * ' + md) if c_mdt: print_header('Missing doctests', '-', not no_color and small_header_color) for md in c_mdt: print(' * ' + md) if c_idt: # Use "# indirect doctest" in the docstring to # suppress this warning. print_header('Indirect doctests', '-', not no_color and small_header_color) for md in c_idt: print(' * ' + md) print('\n Use \"# indirect doctest\" in the docstring to suppress this warning') if c_sph: print_header('Not imported into Sphinx', '-', not no_color and small_header_color) for md in c_sph: print(' * ' + md) print_header('FUNCTIONS', '', not no_color and big_header_color) if not f: print_header('No functions found!') else: if f_md: print_header('Missing docstrings', '-', not no_color and small_header_color) for md in f_md: print(' ' + md) if f_mdt: print_header('Missing doctests', '-', not no_color and small_header_color) for md in f_mdt: print(' * ' + md) if f_idt: print_header('Indirect doctests', '-', not no_color and small_header_color) for md in f_idt: print(' * ' + md) print('\n Use \"# indirect doctest\" in the docstring to suppress this warning') if f_sph: print_header('Not imported into Sphinx', '-', not no_color and small_header_color) for md in f_sph: print(' * ' + md) if verbose: print('\n' + '-'70) print(score_string) if sphinx: print(sphinx_score_string) print('-'70) def _is_indirect(member, doc): """ Given string repr of doc and member checks if the member contains indirect documentation """ d = member in doc e = 'indirect doctest' in doc if not d and not e: return True else: return False def _get_arg_list(name, fobj): """ Given a function object, constructs a list of arguments and their defaults. Takes care of varargs and kwargs """ trunc = 20 # Sometimes argument length can be huge argspec = inspect.getargspec(fobj) arg_list = [] if argspec.args: for arg in argspec.args: arg_list.append(str(arg)) arg_list.reverse() # Now add the defaults if argspec.defaults: for i in range(len(argspec.defaults)): arg_list[i] = str(arg_list[i]) + '=' + str(argspec.defaults[-i]) # Get the list in right order arg_list.reverse() # Add var args if argspec.varargs: arg_list.append(argspec.varargs) if argspec.keywords: arg_list.append(argspec.keywords) # Truncate long arguments arg_list = [x[:trunc] for x in arg_list] # Construct the parameter string (enclosed in brackets) str_param = "%s(%s)" % (name, ', '.join(arg_list)) return str_param def get_mod_name(path, base): """ Gets a module name, given the path of file/dir and base dir of sympy """ rel_path = os.path.relpath(path, base) # Remove the file extension rel_path, ign = os.path.splitext(rel_path) # Replace separators by . for module path file_module = "" h, t = os.path.split(rel_path) while h or t: if t: file_module = t + '.' + file_module h, t = os.path.split(h) return file_module[:-1] class FindInSphinx(HTMLParser): is_imported = [] def handle_starttag(self, tag, attr): a = dict(attr) if tag == "div" and a.get('class', None) == "viewcode-block": self.is_imported.append(a['id']) def find_sphinx(name, mod_path, found={}): if mod_path in found: # Cache results return name in found[mod_path] doc_path = mod_path.split('.') doc_path[-1] += '.html' sphinx_path = os.path.join(sympy_top, 'doc', '_build', 'html', '_modules', doc_path) if not os.path.exists(sphinx_path): return False with open(sphinx_path) as f: html_txt = f.read() p = FindInSphinx() p.feed(html_txt) found[mod_path] = p.is_imported return name in p.is_imported def process_function(name, c_name, b_obj, mod_path, f_sk, f_md, f_mdt, f_idt, f_has_doctest, sk_list, sph, sphinx=True): """ Processes a function to get information regarding documentation. It is assume that the function calling this subrouting has already verified that it is a valid module function. """ if name in sk_list: return False, False # We add in the end, as inspect.getsourcelines is slow add_md = False add_mdt = False add_idt = False in_sphinx = True f_doctest = False function = False if inspect.isclass(b_obj): obj = getattr(b_obj, name) obj_name = c_name + '.' + name else: obj = b_obj obj_name = name full_name = _get_arg_list(name, obj) if name.startswith('_'): f_sk.append(full_name) else: doc = obj.__doc__ if type(doc) is str: if not doc: add_md = True elif not '>>>' in doc: add_mdt = True elif _is_indirect(name, doc): add_idt = True else: f_doctest = True elif doc is None: # this was a function defined in the docstring f_doctest = True else: assert None, type(doc) function = True if sphinx: in_sphinx = find_sphinx(obj_name, mod_path) if add_md or add_mdt or add_idt or not in_sphinx: try: line_no = inspect.getsourcelines(obj)[1] except IOError: # Raised when source does not exist # which means the function is not there. return False, False full_name = "LINE %d: %s" % (line_no, full_name) if add_md: f_md.append(full_name) elif add_mdt: f_mdt.append(full_name) elif add_idt: f_idt.append(full_name) if not in_sphinx: sph.append(full_name) return f_doctest, function def process_class(c_name, obj, c_sk, c_md, c_mdt, c_idt, c_has_doctest, mod_path, sph, sphinx=True): """ Extracts information about the class regarding documentation. It is assumed that the function calling this subroutine has already checked that the class is valid. """ # Skip class case if c_name.startswith('_'): c_sk.append(c_name) return False, False, None c = False c_dt = False # Get the line number of class try: source, line_no = inspect.getsourcelines(obj) except IOError: # Raised when source does not exist # which means the class is not there. return False, False, None c = True full_name = "LINE %d: %s" % (line_no, c_name) doc = obj.__doc__ if type(doc) is str: if not doc: c_md.append(full_name) elif not '>>>' in doc: c_mdt.append(full_name) elif _is_indirect(c_name, doc): c_idt.append(full_name) else: c_dt = True c_has_doctest.append(full_name) elif doc is None: # this was a class defined in the docstring c_dt = True c_has_doctest.append(full_name) else: assert None, type(doc) in_sphinx = False if sphinx: in_sphinx = find_sphinx(c_name, mod_path) if not in_sphinx: sph.append(full_name) return c_dt, c, source def coverage(module_path, verbose=False, no_color=False, sphinx=True): """ Given a module path, builds an index of all classes and functions contained. It then goes through each of the classes/functions to get the docstring and doctest coverage of the module. """ # Import the package and find members m = None try: __import__(module_path) m = sys.modules[module_path] except Exception as a: # Most likely cause, absence of __init__ print("%s could not be loaded due to %s." % (module_path, repr(a))) return 0, 0, 0 c_skipped = [] c_md = [] c_mdt = [] c_has_doctest = [] c_idt = [] classes = 0 c_doctests = 0 c_sph = [] f_skipped = [] f_md = [] f_mdt = [] f_has_doctest = [] f_idt = [] functions = 0 f_doctests = 0 f_sph = [] skip_members = ['__abstractmethods__'] # Get the list of members m_members = dir(m) for member in m_members: # Check for skipped functions first, they throw nasty errors # when combined with getattr if member in skip_members: continue # Identify if the member (class/def) is a part of this module obj = getattr(m, member) obj_mod = inspect.getmodule(obj) # Function not a part of this module if not obj_mod or not obj_mod.__name__ == module_path: continue # If it's a function if inspect.isfunction(obj) or inspect.ismethod(obj): f_dt, f = process_function(member, '', obj, module_path, f_skipped, f_md, f_mdt, f_idt, f_has_doctest, skip_members, f_sph, sphinx=sphinx) if f: functions += 1 if f_dt: f_doctests += 1 # If it's a class, look at it's methods too elif inspect.isclass(obj): # Process the class first c_dt, c, source = process_class(member, obj, c_skipped, c_md, c_mdt, c_idt, c_has_doctest, module_path, c_sph, sphinx=sphinx) if not c: continue else: classes += 1 if c_dt: c_doctests += 1 # Iterate through it's members for f_name in obj.__dict__: if f_name in skip_members or f_name.startswith('_'): continue # Check if def funcname appears in source if not ("def " + f_name) in ' '.join(source): continue # Identify the module of the current class member f_obj = getattr(obj, f_name) obj_mod = inspect.getmodule(f_obj) # Function not a part of this module if not obj_mod or not obj_mod.__name__ == module_path: continue # If it's a function if inspect.isfunction(f_obj) or inspect.ismethod(f_obj): f_dt, f = process_function(f_name, member, obj, module_path, f_skipped, f_md, f_mdt, f_idt, f_has_doctest, skip_members, f_sph, sphinx=sphinx) if f: functions += 1 if f_dt: f_doctests += 1 # Evaluate the percent coverage total_doctests = c_doctests + f_doctests total_members = classes + functions if total_members: score = 100 float(total_doctests) / (total_members) else: score = 100 score = int(score) if sphinx: total_sphinx = len(c_sph) + len(f_sph) if total_members: sphinx_score = 100 - 100 * float(total_sphinx) / total_members else: sphinx_score = 100 sphinx_score = int(sphinx_score) else: total_sphinx = 0 sphinx_score = 0 # Sort functions/classes by line number c_md = sorted(c_md, key=lambda x: int(x.split()[1][:-1])) c_mdt = sorted(c_mdt, key=lambda x: int(x.split()[1][:-1])) c_idt = sorted(c_idt, key=lambda x: int(x.split()[1][:-1])) f_md = sorted(f_md, key=lambda x: int(x.split()[1][:-1])) f_mdt = sorted(f_mdt, key=lambda x: int(x.split()[1][:-1])) f_idt = sorted(f_idt, key=lambda x: int(x.split()[1][:-1])) print_coverage(module_path, classes, c_md, c_mdt, c_idt, c_sph, functions, f_md, f_mdt, f_idt, f_sph, score, total_doctests, total_members, sphinx_score, total_sphinx, verbose=verbose, no_color=no_color, sphinx=sphinx) return total_doctests, total_sphinx, total_members def go(sympy_top, file, verbose=False, no_color=False, exact=True, sphinx=True): # file names containing any string in skip_paths will be skipped, skip_paths = [] if os.path.isdir(file): doctests, total_sphinx, num_functions = 0, 0, 0 for F in os.listdir(file): _doctests, _total_sphinx, _num_functions = go(sympy_top, '%s/%s' % (file, F), verbose=verbose, no_color=no_color, exact=False, sphinx=sphinx) doctests += _doctests total_sphinx += _total_sphinx num_functions += _num_functions return doctests, total_sphinx, num_functions if (not (file.endswith('.py') or file.endswith('.pyx')) or file.endswith('__init__.py') or not exact and ('test_' in file or 'bench_' in file or any(name in file for name in skip_paths))): return 0, 0, 0 if not os.path.exists(file): print("File(%s does not exist." % file) sys.exit(1) # Relpath for constructing the module name return coverage(get_mod_name(file, sympy_top), verbose=verbose, no_color=no_color, sphinx=sphinx) if __name__ == "__main__": bintest_dir = os.path.abspath(os.path.dirname(__file__)) # bin/cover... sympy_top = os.path.split(bintest_dir)[0] # ../ sympy_dir = os.path.join(sympy_top, 'sympy') # ../sympy/ if os.path.isdir(sympy_dir): sys.path.insert(0, sympy_top) usage = "usage: ./bin/doctest_coverage.py PATHS" parser = ArgumentParser( description=__doc__, usage=usage, formatter_class=RawDescriptionHelpFormatter, ) parser.add_argument("path", nargs='', default=[os.path.join(sympy_top, 'sympy')]) parser.add_argument("-v", "--verbose", action="store_true", dest="verbose", default=False) parser.add_argument("--no-colors", action="store_true", dest="no_color", help="use no colors", default=False) parser.add_argument("--no-sphinx", action="store_false", dest="sphinx", help="don't report Sphinx coverage", default=True) args = parser.parse_args() if args.sphinx and not os.path.exists(os.path.join(sympy_top, 'doc', '_build', 'html')): print(filldedent(""" Cannot check Sphinx coverage without a documentation build. To build the docs, run "cd doc; make html". To skip checking Sphinx coverage, pass --no-sphinx. """)) sys.exit(1) full_coverage = True for file in args.path: file = os.path.normpath(file) print('DOCTEST COVERAGE for %s' % (file)) print('='70) print() doctests, total_sphinx, num_functions = go(sympy_top, file, verbose=args.verbose, no_color=args.no_color, sphinx=args.sphinx) if num_functions == 0: score = 100 sphinx_score = 100 else: score = 100 * float(doctests) / num_functions score = int(score) if doctests < num_functions: full_coverage = False if args.sphinx: sphinx_score = 100 - 100 * float(total_sphinx) / num_functions sphinx_score = int(sphinx_score) if total_sphinx > 0: full_coverage = False print() print('='*70) if args.no_color: print("TOTAL DOCTEST SCORE for %s: %s%% (%s of %s)" % \ (get_mod_name(file, sympy_top), score, doctests, num_functions)) elif score < 100: print("TOTAL DOCTEST SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Red"]), score, doctests, num_functions, c_normal)) else: print("TOTAL DOCTEST SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Green"]), score, doctests, num_functions, c_normal)) if args.sphinx: if args.no_color: print("TOTAL SPHINX SCORE for %s: %s%% (%s of %s)" % \ (get_mod_name(file, sympy_top), sphinx_score, num_functions - total_sphinx, num_functions)) elif sphinx_score < 100: print("TOTAL SPHINX SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Red"]), sphinx_score, num_functions - total_sphinx, num_functions, c_normal)) else: print("TOTAL SPHINX SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Green"]), sphinx_score, num_functions - total_sphinx, num_functions, c_normal)) print() sys.exit(not full_coverage)
d9828efdbac58756521d0d2bb11e426760659d60dd63ca2cbac3a4efed9d32df	#!/usr/bin/env python """ Script to generate test coverage reports. Usage: $ bin/coverage_report.py This will create a directory covhtml with the coverage reports. To restrict the analysis to a directory, you just need to pass its name as argument. For example: $ bin/coverage_report.py sympy/logic runs only the tests in sympy/logic/ and reports only on the modules in sympy/logic/. To also run slow tests use --slow option. You can also get a report on the parts of the whole sympy code covered by the tests in sympy/logic/ by following up the previous command with $ bin/coverage_report.py -c """ from __future__ import print_function import os import re import sys from argparse import ArgumentParser minver = '3.4' try: import coverage if coverage.__version__ < minver: raise ImportError except ImportError: print( "You need to install module coverage (version %s or newer required).\n" "See https://coverage.readthedocs.io/en/latest/ or \n" "https://launchpad.net/ubuntu/+source/python-coverage/" % minver) sys.exit(-1) omit_dir_patterns = ['.tests', 'benchmark', 'examples', 'pyglet', 'test_external'] omit_dir_re = re.compile(r'\|'.join(omit_dir_patterns)) source_re = re.compile(r'.\.py$') def generate_covered_files(top_dir): for dirpath, dirnames, filenames in os.walk(top_dir): omit_dirs = [dirn for dirn in dirnames if omit_dir_re.match(dirn)] for x in omit_dirs: dirnames.remove(x) for filename in filenames: if source_re.match(filename): yield os.path.join(dirpath, filename) def make_report( test_args, source_dir='sympy/', report_dir='covhtml', use_cache=False, slow=False ): # code adapted from /bin/test from get_sympy import path_hack sympy_top = path_hack() os.chdir(sympy_top) cov = coverage.coverage() cov.exclude("raise NotImplementedError") cov.exclude("def canonize") # this should be "@decorated" cov.exclude("def __mathml__") if use_cache: cov.load() else: cov.erase() cov.start() import sympy sympy.test(*test_args, subprocess=False, slow=slow) #sympy.doctest() # coverage doesn't play well with doctests cov.stop() try: cov.save() except PermissionError: import warnings warnings.warn( "PermissionError has been raised while saving the " \ "coverage result.", RuntimeWarning ) covered_files = list(generate_covered_files(source_dir)) cov.html_report(morfs=covered_files, directory=report_dir) parser = ArgumentParser() parser.add_argument( '-c', '--use-cache', action='store_true', default=False, help='Use cached data.') parser.add_argument( '-d', '--report-dir', default='covhtml', help='Directory to put the generated report in.') parser.add_argument( "--slow", action="store_true", dest="slow", default=False, help="Run slow functions also.") options, args = parser.parse_known_args() if __name__ == '__main__': report_dir = options.report_dir use_cache = options.use_cache slow = options.slow make_report( args, report_dir=report_dir, use_cache=use_cache, slow=slow) print("The generated coverage report is in covhtml directory.") print( "Open %s in your web browser to view the report" % os.sep.join([report_dir, 'index.html']) )
e6bb04e29ed5d1e3c7f98082ec05fd27a9ea1c67464f7911bca4b3ea22319679	#!/usr/bin/env python """ A tool to help keep .mailmap up-to-date with the current git authors. See also bin/authors_update.py """ import codecs import sys import os if sys.version_info < (3, 6): sys.exit("This script requires Python 3.6 or newer") from subprocess import run, PIPE from distutils.version import LooseVersion from collections import defaultdict, OrderedDict def red(text): return "\033[31m%s\033[0m" % text def yellow(text): return "\033[33m%s\033[0m" % text def blue(text): return "\033[34m%s\033[0m" % text # put sympy on the path mailmap_update_path = os.path.abspath(__file__) mailmap_update_dir = os.path.dirname(mailmap_update_path) sympy_top = os.path.split(mailmap_update_dir)[0] sympy_dir = os.path.join(sympy_top, 'sympy') if os.path.isdir(sympy_dir): sys.path.insert(0, sympy_top) from sympy.utilities.misc import filldedent from sympy.utilities.iterables import sift # check git version minimal = '1.8.4.2' git_ver = run(['git', '--version'], stdout=PIPE, encoding='utf-8').stdout[12:] if LooseVersion(git_ver) < LooseVersion(minimal): print(yellow("Please use a git version >= %s" % minimal)) def author_name(line): assert line.count("<") == line.count(">") == 1 assert line.endswith(">") return line.split("<", 1)[0].strip() def author_email(line): assert line.count("<") == line.count(">") == 1 assert line.endswith(">") return line.split("<", 1)[1][:-1].strip() sysexit = 0 print(blue("checking git authors...")) # read git authors git_command = ['git', 'log', '--format=%aN <%aE>'] git_people = sorted(set(run(git_command, stdout=PIPE, encoding='utf-8').stdout.strip().split("\n"))) # check for ambiguous emails dups = defaultdict(list) near_dups = defaultdict(list) for i in git_people: k = i.split('<')[1] dups[k].append(i) near_dups[k.lower()].append((k, i)) multi = [k for k in dups if len(dups[k]) > 1] if multi: print() print(red(filldedent(""" Ambiguous email address error: each address should refer to a single author. Disambiguate the following in .mailmap. Then re-run this script."""))) for k in multi: print() for e in sorted(dups[k]): print('\t%s' % e) sysexit = 1 # warn for nearly ambiguous email addresses dups = near_dups # some may have been real dups, so disregard those # for which all email addresses were the same multi = [k for k in dups if len(dups[k]) > 1 and len(set([i for i, _ in dups[k]])) > 1] if multi: # not fatal but make it red print() print(red(filldedent(""" Ambiguous email address warning: git treats the following as distinct but .mailmap will treat them the same. If these are not all the same person then, when making an entry in .mailmap, be sure to include both commit name and address (not just the address)."""))) for k in multi: print() for _, e in sorted(dups[k]): print('\t%s' % e) # warn for ambiguous names dups = defaultdict(list) for i in git_people: dups[author_name(i)].append(i) multi = [k for k in dups if len(dups[k]) > 1] if multi: print() print(yellow(filldedent(""" Ambiguous name warning: if a person uses more than one email address, entries should be added to .mailmap to merge them into a single canonical address. Then re-run this script. """))) for k in multi: print() for e in sorted(dups[k]): print('\t%s' % e) bad_names = [] bad_emails = [] for i in git_people: name = author_name(i) email = author_email(i) if '@' in name: bad_names.append(i) elif '@' not in email: bad_emails.append(i) if bad_names: print() print(yellow(filldedent(""" The following people appear to have an email address listed for their name. Entries should be added to .mailmap so that names are formatted like "Name <email address>". """))) for i in bad_names: print("\t%s" % i) # TODO: Should we check for bad emails as well? Some people have empty email # addresses. The above check seems to catch people who get the name and email # backwards, so let's leave this alone for now. # if bad_emails: # print() # print(yellow(filldedent(""" # The following names do not appear to have valid # emails. Entries should be added to .mailmap that # use a proper email address. If there is no email # address for a person, use "[email protected]". # """))) # for i in bad_emails: # print("\t%s" % i) print() print(blue("checking .mailmap...")) # put entries in order -- this will help the user # to see if there are already existing entries for an author file = codecs.open(os.path.realpath(os.path.join( __file__, os.path.pardir, os.path.pardir, ".mailmap")), "r", "utf-8").read() blankline = not file or file.endswith('\n') lines = file.splitlines() def key(line): # return lower case first address on line or # raise an error if not an entry if '#' in line: line = line.split('#')[0] L, R = line.count("<"), line.count(">") assert L == R and L in (1, 2) return line.split(">", 1)[0].split("<")[1].lower() who = OrderedDict() for i, line in enumerate(lines): try: who.setdefault(key(line), []).append(line) except AssertionError: who[i] = [line] out = [] for k in who: # put long entries before short since if they match, the # short entries will be ignored. The ORDER MATTERS # so don't re-order the lines for a given address. # Other tidying up could be done but we won't do that here. def short_entry(line): if line.count('<') == 2: if line.split('>', 1)[1].split('<')[0].strip(): return False return True if len(who[k]) == 1: line = who[k][0] if not line.strip(): continue # ignore blank lines out.append(line) else: uniq = list(OrderedDict.fromkeys(who[k])) short, long = sift(uniq, short_entry, binary=True) out.extend(long) out.extend(short) if out != lines or not blankline: # write lines with codecs.open(os.path.realpath(os.path.join( __file__, os.path.pardir, os.path.pardir, ".mailmap")), "w", "utf-8") as fd: fd.write('\n'.join(out)) fd.write('\n') print() if out != lines: print(yellow('.mailmap lines were re-ordered.')) else: print(yellow('blank line added to end of .mailmap')) sys.exit(sysexit)
699110cb0bb7c9e0fd4a7f851cba89d032dfe923bda52a88ee488cebd5c46cbb	""" SymPy statistics module Introduces a random variable type into the SymPy language. Random variables may be declared using prebuilt functions such as Normal, Exponential, Coin, Die, etc... or built with functions like FiniteRV. Queries on random expressions can be made using the functions ========================= ============================= Expression Meaning ------------------------- ----------------------------- ``P(condition)`` Probability ``E(expression)`` Expected value ``H(expression)`` Entropy ``variance(expression)`` Variance ``density(expression)`` Probability Density Function ``sample(expression)`` Produce a realization ``where(condition)`` Where the condition is true ========================= ============================= Examples ======== >>> from sympy.stats import P, E, variance, Die, Normal >>> from sympy import Eq, simplify >>> X, Y = Die('X', 6), Die('Y', 6) # Define two six sided dice >>> Z = Normal('Z', 0, 1) # Declare a Normal random variable with mean 0, std 1 >>> P(X>3) # Probability X is greater than 3 1/2 >>> E(X+Y) # Expectation of the sum of two dice 7 >>> variance(X+Y) # Variance of the sum of two dice 35/6 >>> simplify(P(Z>1)) # Probability of Z being greater than 1 1/2 - erf(sqrt(2)/2)/2 """ __all__ = [] from . import rv_interface from .rv_interface import ( cdf, characteristic_function, covariance, density, dependent, E, given, independent, P, pspace, random_symbols, sample, sample_iter, skewness, std, variance, where, correlation, moment, cmoment, smoment, sampling_density, moment_generating_function, entropy, H ) __all__.extend(rv_interface.__all__) from . import frv_types from .frv_types import ( Bernoulli, Binomial, Coin, Die, DiscreteUniform, FiniteRV, Hypergeometric, Rademacher, ) __all__.extend(frv_types.__all__) from . import crv_types from .crv_types import ( ContinuousRV, Arcsin, Benini, Beta, BetaPrime, Cauchy, Chi, ChiNoncentral, ChiSquared, Dagum, Erlang, Exponential, FDistribution, FisherZ, Frechet, Gamma, GammaInverse, Gumbel, Gompertz, Kumaraswamy, Laplace, Logistic, LogNormal, Maxwell, Nakagami, Normal, Pareto, QuadraticU, RaisedCosine, Rayleigh, ShiftedGompertz, StudentT, Trapezoidal, Triangular, Uniform, UniformSum, VonMises, Weibull, WignerSemicircle ) __all__.extend(crv_types.__all__) from . import drv_types from .drv_types import (Geometric, Logarithmic, NegativeBinomial, Poisson, YuleSimon, Zeta) __all__.extend(drv_types.__all__) from . import symbolic_probability from .symbolic_probability import Probability, Expectation, Variance, Covariance __all__.extend(symbolic_probability.__all__)
18cfc133b498c3ce24cc5dd77d99d9676308bc8b0b4f4c5c88b4e4294f11aba5	from __future__ import print_function, division from .rv import (probability, expectation, density, where, given, pspace, cdf, characteristic_function, sample, sample_iter, random_symbols, independent, dependent, sampling_density, moment_generating_function) from sympy import sqrt, log, Piecewise, Symbol, Eq, Lambda, exp __all__ = ['P', 'E', 'H', 'density', 'where', 'given', 'sample', 'cdf', 'characteristic_function', 'pspace', 'sample_iter', 'variance', 'std', 'skewness', 'covariance', 'dependent', 'independent', 'random_symbols', 'correlation', 'moment', 'cmoment', 'sampling_density', 'moment_generating_function'] def moment(X, n, c=0, condition=None, kwargs): """ Return the nth moment of a random expression about c i.e. E((X-c)n) Default value of c is 0. Examples ======== >>> from sympy.stats import Die, moment, E >>> X = Die('X', 6) >>> moment(X, 1, 6) -5/2 >>> moment(X, 2) 91/6 >>> moment(X, 1) == E(X) True """ return expectation((X - c)n, condition, kwargs) def variance(X, condition=None, kwargs): """ Variance of a random expression Expectation of (X-E(X))2 Examples ======== >>> from sympy.stats import Die, E, Bernoulli, variance >>> from sympy import simplify, Symbol >>> X = Die('X', 6) >>> p = Symbol('p') >>> B = Bernoulli('B', p, 1, 0) >>> variance(2X) 35/3 >>> simplify(variance(B)) p(1 - p) """ return cmoment(X, 2, condition, kwargs) def standard_deviation(X, condition=None, kwargs): """ Standard Deviation of a random expression Square root of the Expectation of (X-E(X))*2 Examples ======== >>> from sympy.stats import Bernoulli, std >>> from sympy import Symbol, simplify >>> p = Symbol('p') >>> B = Bernoulli('B', p, 1, 0) >>> simplify(std(B)) sqrt(p(1 - p)) """ return sqrt(variance(X, condition, kwargs)) std = standard_deviation def entropy(expr, condition=None, kwargs): """ Calculuates entropy of a probability distribution Parameters ========== expression : the random expression whose entropy is to be calculated condition : optional, to specify conditions on random expression b: base of the logarithm, optional By default, it is taken as Euler's number Retruns ======= result : Entropy of the expression, a constant Examples ======== >>> from sympy.stats import Normal, Die, entropy >>> X = Normal('X', 0, 1) >>> entropy(X) log(2)/2 + 1/2 + log(pi)/2 >>> D = Die('D', 4) >>> entropy(D) log(4) References ========== .. [1] https://en.wikipedia.org/wiki/Entropy_(information_theory) .. [2] https://www.crmarsh.com/static/pdf/Charles_Marsh_Continuous_Entropy.pdf .. [3] http://www.math.uconn.edu/~kconrad/blurbs/analysis/entropypost.pdf """ pdf = density(expr, condition, *kwargs) base = kwargs.get('b', exp(1)) if isinstance(pdf, dict): return sum([-problog(prob, base) for prob in pdf.values()]) return expectation(-log(pdf(expr), base)) def covariance(X, Y, condition=None, *kwargs): """ Covariance of two random expressions The expectation that the two variables will rise and fall together Covariance(X,Y) = E( (X-E(X)) (Y-E(Y)) ) Examples ======== >>> from sympy.stats import Exponential, covariance >>> from sympy import Symbol >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> X = Exponential('X', rate) >>> Y = Exponential('Y', rate) >>> covariance(X, X) lambda*(-2) >>> covariance(X, Y) 0 >>> covariance(X, Y + rateX) 1/lambda """ return expectation( (X - expectation(X, condition, *kwargs)) (Y - expectation(Y, condition, kwargs)), condition, kwargs) def correlation(X, Y, condition=None, *kwargs): """ Correlation of two random expressions, also known as correlation coefficient or Pearson's correlation The normalized expectation that the two variables will rise and fall together Correlation(X,Y) = E( (X-E(X)) (Y-E(Y)) / (sigma(X) * sigma(Y)) ) Examples ======== >>> from sympy.stats import Exponential, correlation >>> from sympy import Symbol >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> X = Exponential('X', rate) >>> Y = Exponential('Y', rate) >>> correlation(X, X) 1 >>> correlation(X, Y) 0 >>> correlation(X, Y + rateX) 1/sqrt(1 + lambda(-2)) """ return covariance(X, Y, condition, kwargs)/(std(X, condition, kwargs) std(Y, condition, kwargs)) def cmoment(X, n, condition=None, kwargs): """ Return the nth central moment of a random expression about its mean i.e. E((X - E(X))n) Examples ======== >>> from sympy.stats import Die, cmoment, variance >>> X = Die('X', 6) >>> cmoment(X, 3) 0 >>> cmoment(X, 2) 35/12 >>> cmoment(X, 2) == variance(X) True """ mu = expectation(X, condition, kwargs) return moment(X, n, mu, condition, kwargs) def smoment(X, n, condition=None, kwargs): """ Return the nth Standardized moment of a random expression i.e. E( ((X - mu)/sigma(X))*n ) Examples ======== >>> from sympy.stats import skewness, Exponential, smoment >>> from sympy import Symbol >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> Y = Exponential('Y', rate) >>> smoment(Y, 4) 9 >>> smoment(Y, 4) == smoment(3Y, 4) True >>> smoment(Y, 3) == skewness(Y) True """ sigma = std(X, condition, kwargs) return (1/sigma)ncmoment(X, n, condition, kwargs) def skewness(X, condition=None, kwargs): """ Measure of the asymmetry of the probability distribution Positive skew indicates that most of the values lie to the right of the mean skewness(X) = E( ((X - E(X))/sigma)3 ) Examples ======== >>> from sympy.stats import skewness, Exponential, Normal >>> from sympy import Symbol >>> X = Normal('X', 0, 1) >>> skewness(X) 0 >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> Y = Exponential('Y', rate) >>> skewness(Y) 2 """ return smoment(X, 3, condition, *kwargs) P = probability E = expectation H = entropy
7bc83add187ba123faa678f1d93eeb798518ed3f70f23c7c2f11504630409923	""" Main Random Variables Module Defines abstract random variable type. Contains interfaces for probability space object (PSpace) as well as standard operators, P, E, sample, density, where See Also ======== sympy.stats.crv sympy.stats.frv sympy.stats.rv_interface """ from __future__ import print_function, division from sympy import (Basic, S, Expr, Symbol, Tuple, And, Add, Eq, lambdify, Equality, Lambda, sympify, Dummy, Ne, KroneckerDelta, DiracDelta, Mul) from sympy.abc import x from sympy.core.compatibility import string_types from sympy.core.relational import Relational from sympy.logic.boolalg import Boolean from sympy.sets.sets import FiniteSet, ProductSet, Intersection from sympy.solvers.solveset import solveset class RandomDomain(Basic): """ Represents a set of variables and the values which they can take See Also ======== sympy.stats.crv.ContinuousDomain sympy.stats.frv.FiniteDomain """ is_ProductDomain = False is_Finite = False is_Continuous = False is_Discrete = False def __new__(cls, symbols, args): symbols = FiniteSet(symbols) return Basic.__new__(cls, symbols, args) @property def symbols(self): return self.args[0] @property def set(self): return self.args[1] def __contains__(self, other): raise NotImplementedError() def compute_expectation(self, expr): raise NotImplementedError() class SingleDomain(RandomDomain): """ A single variable and its domain See Also ======== sympy.stats.crv.SingleContinuousDomain sympy.stats.frv.SingleFiniteDomain """ def __new__(cls, symbol, set): assert symbol.is_Symbol return Basic.__new__(cls, symbol, set) @property def symbol(self): return self.args[0] @property def symbols(self): return FiniteSet(self.symbol) def __contains__(self, other): if len(other) != 1: return False sym, val = tuple(other)[0] return self.symbol == sym and val in self.set class ConditionalDomain(RandomDomain): """ A RandomDomain with an attached condition See Also ======== sympy.stats.crv.ConditionalContinuousDomain sympy.stats.frv.ConditionalFiniteDomain """ def __new__(cls, fulldomain, condition): condition = condition.xreplace(dict((rs, rs.symbol) for rs in random_symbols(condition))) return Basic.__new__(cls, fulldomain, condition) @property def symbols(self): return self.fulldomain.symbols @property def fulldomain(self): return self.args[0] @property def condition(self): return self.args[1] @property def set(self): raise NotImplementedError("Set of Conditional Domain not Implemented") def as_boolean(self): return And(self.fulldomain.as_boolean(), self.condition) class PSpace(Basic): """ A Probability Space Probability Spaces encode processes that equal different values probabilistically. These underly Random Symbols which occur in SymPy expressions and contain the mechanics to evaluate statistical statements. See Also ======== sympy.stats.crv.ContinuousPSpace sympy.stats.frv.FinitePSpace """ is_Finite = None is_Continuous = None is_Discrete = None is_real = None @property def domain(self): return self.args[0] @property def density(self): return self.args[1] @property def values(self): return frozenset(RandomSymbol(sym, self) for sym in self.symbols) @property def symbols(self): return self.domain.symbols def where(self, condition): raise NotImplementedError() def compute_density(self, expr): raise NotImplementedError() def sample(self): raise NotImplementedError() def probability(self, condition): raise NotImplementedError() def compute_expectation(self, expr): raise NotImplementedError() class SinglePSpace(PSpace): """ Represents the probabilities of a set of random events that can be attributed to a single variable/symbol. """ def __new__(cls, s, distribution): if isinstance(s, string_types): s = Symbol(s) if not isinstance(s, Symbol): raise TypeError("s should have been string or Symbol") return Basic.__new__(cls, s, distribution) @property def value(self): return RandomSymbol(self.symbol, self) @property def symbol(self): return self.args[0] @property def distribution(self): return self.args[1] @property def pdf(self): return self.distribution.pdf(self.symbol) class RandomSymbol(Expr): """ Random Symbols represent ProbabilitySpaces in SymPy Expressions In principle they can take on any value that their symbol can take on within the associated PSpace with probability determined by the PSpace Density. Random Symbols contain pspace and symbol properties. The pspace property points to the represented Probability Space The symbol is a standard SymPy Symbol that is used in that probability space for example in defining a density. You can form normal SymPy expressions using RandomSymbols and operate on those expressions with the Functions E - Expectation of a random expression P - Probability of a condition density - Probability Density of an expression given - A new random expression (with new random symbols) given a condition An object of the RandomSymbol type should almost never be created by the user. They tend to be created instead by the PSpace class's value method. Traditionally a user doesn't even do this but instead calls one of the convenience functions Normal, Exponential, Coin, Die, FiniteRV, etc.... """ def __new__(cls, symbol, pspace=None): from sympy.stats.joint_rv import JointRandomSymbol if pspace is None: # Allow single arg, representing pspace == PSpace() pspace = PSpace() if not isinstance(symbol, Symbol): raise TypeError("symbol should be of type Symbol") if not isinstance(pspace, PSpace): raise TypeError("pspace variable should be of type PSpace") if cls == JointRandomSymbol and isinstance(pspace, SinglePSpace): cls = RandomSymbol return Basic.__new__(cls, symbol, pspace) is_finite = True is_symbol = True is_Atom = True _diff_wrt = True pspace = property(lambda self: self.args[1]) symbol = property(lambda self: self.args[0]) name = property(lambda self: self.symbol.name) def _eval_is_positive(self): return self.symbol.is_positive def _eval_is_integer(self): return self.symbol.is_integer def _eval_is_real(self): return self.symbol.is_real or self.pspace.is_real @property def is_commutative(self): return self.symbol.is_commutative def _hashable_content(self): return self.pspace, self.symbol @property def free_symbols(self): return {self} class ProductPSpace(PSpace): """ Abstract class for representing probability spaces with multiple random variables. See Also ======== sympy.stats.rv.IndependentProductPSpace sympy.stats.joint_rv.JointPSpace """ pass class IndependentProductPSpace(ProductPSpace): """ A probability space resulting from the merger of two independent probability spaces. Often created using the function, pspace """ def __new__(cls, spaces): rs_space_dict = {} for space in spaces: for value in space.values: rs_space_dict[value] = space symbols = FiniteSet([val.symbol for val in rs_space_dict.keys()]) # Overlapping symbols from sympy.stats.joint_rv import MarginalDistribution, CompoundDistribution if len(symbols) < sum(len(space.symbols) for space in spaces if not isinstance(space.distribution, ( CompoundDistribution, MarginalDistribution))): raise ValueError("Overlapping Random Variables") if all(space.is_Finite for space in spaces): from sympy.stats.frv import ProductFinitePSpace cls = ProductFinitePSpace obj = Basic.__new__(cls, FiniteSet(spaces)) return obj @property def pdf(self): p = Mul([space.pdf for space in self.spaces]) return p.subs(dict((rv, rv.symbol) for rv in self.values)) @property def rs_space_dict(self): d = {} for space in self.spaces: for value in space.values: d[value] = space return d @property def symbols(self): return FiniteSet([val.symbol for val in self.rs_space_dict.keys()]) @property def spaces(self): return FiniteSet(self.args) @property def values(self): return sumsets(space.values for space in self.spaces) def compute_expectation(self, expr, rvs=None, evaluate=False, kwargs): rvs = rvs or self.values rvs = frozenset(rvs) for space in self.spaces: expr = space.compute_expectation(expr, rvs & space.values, evaluate=False, kwargs) if evaluate and hasattr(expr, 'doit'): return expr.doit(*kwargs) return expr @property def domain(self): return ProductDomain([space.domain for space in self.spaces]) @property def density(self): raise NotImplementedError("Density not available for ProductSpaces") def sample(self): return {k: v for space in self.spaces for k, v in space.sample().items()} def probability(self, condition, kwargs): cond_inv = False if isinstance(condition, Ne): condition = Eq(condition.args[0], condition.args[1]) cond_inv = True expr = condition.lhs - condition.rhs rvs = random_symbols(expr) z = Dummy('z', real=True, Finite=True) dens = self.compute_density(expr) if any([pspace(rv).is_Continuous for rv in rvs]): from sympy.stats.crv import (ContinuousDistributionHandmade, SingleContinuousPSpace) if expr in self.values: # Marginalize all other random symbols out of the density randomsymbols = tuple(set(self.values) - frozenset([expr])) symbols = tuple(rs.symbol for rs in randomsymbols) pdf = self.domain.integrate(self.pdf, symbols, kwargs) return Lambda(expr.symbol, pdf) dens = ContinuousDistributionHandmade(dens) space = SingleContinuousPSpace(z, dens) result = space.probability(condition.__class__(space.value, 0)) else: from sympy.stats.drv import (DiscreteDistributionHandmade, SingleDiscretePSpace) dens = DiscreteDistributionHandmade(dens) space = SingleDiscretePSpace(z, dens) result = space.probability(condition.__class__(space.value, 0)) return result if not cond_inv else S.One - result def compute_density(self, expr, kwargs): z = Dummy('z', real=True, finite=True) rvs = random_symbols(expr) if any(pspace(rv).is_Continuous for rv in rvs): expr = self.compute_expectation(DiracDelta(expr - z), kwargs) else: expr = self.compute_expectation(KroneckerDelta(expr, z), kwargs) return Lambda(z, expr) def compute_cdf(self, expr, kwargs): raise ValueError("CDF not well defined on multivariate expressions") def conditional_space(self, condition, normalize=True, kwargs): rvs = random_symbols(condition) condition = condition.xreplace(dict((rv, rv.symbol) for rv in self.values)) if any([pspace(rv).is_Continuous for rv in rvs]): from sympy.stats.crv import (ConditionalContinuousDomain, ContinuousPSpace) space = ContinuousPSpace domain = ConditionalContinuousDomain(self.domain, condition) elif any([pspace(rv).is_Discrete for rv in rvs]): from sympy.stats.drv import (ConditionalDiscreteDomain, DiscretePSpace) space = DiscretePSpace domain = ConditionalDiscreteDomain(self.domain, condition) elif all([pspace(rv).is_Finite for rv in rvs]): from sympy.stats.frv import FinitePSpace return FinitePSpace.conditional_space(self, condition) if normalize: replacement = {rv: Dummy(str(rv)) for rv in self.symbols} norm = domain.compute_expectation(self.pdf, kwargs) pdf = self.pdf / norm.xreplace(replacement) density = Lambda(domain.symbols, pdf) return space(domain, density) class ProductDomain(RandomDomain): """ A domain resulting from the merger of two independent domains See Also ======== sympy.stats.crv.ProductContinuousDomain sympy.stats.frv.ProductFiniteDomain """ is_ProductDomain = True def __new__(cls, domains): # Flatten any product of products domains2 = [] for domain in domains: if not domain.is_ProductDomain: domains2.append(domain) else: domains2.extend(domain.domains) domains2 = FiniteSet(domains2) if all(domain.is_Finite for domain in domains2): from sympy.stats.frv import ProductFiniteDomain cls = ProductFiniteDomain if all(domain.is_Continuous for domain in domains2): from sympy.stats.crv import ProductContinuousDomain cls = ProductContinuousDomain if all(domain.is_Discrete for domain in domains2): from sympy.stats.drv import ProductDiscreteDomain cls = ProductDiscreteDomain return Basic.__new__(cls, domains2) @property def sym_domain_dict(self): return dict((symbol, domain) for domain in self.domains for symbol in domain.symbols) @property def symbols(self): return FiniteSet([sym for domain in self.domains for sym in domain.symbols]) @property def domains(self): return self.args @property def set(self): return ProductSet(domain.set for domain in self.domains) def __contains__(self, other): # Split event into each subdomain for domain in self.domains: # Collect the parts of this event which associate to this domain elem = frozenset([item for item in other if sympify(domain.symbols.contains(item[0])) is S.true]) # Test this sub-event if elem not in domain: return False # All subevents passed return True def as_boolean(self): return And([domain.as_boolean() for domain in self.domains]) def random_symbols(expr): """ Returns all RandomSymbols within a SymPy Expression. """ atoms = getattr(expr, 'atoms', None) if atoms is not None: return list(atoms(RandomSymbol)) else: return [] def pspace(expr): """ Returns the underlying Probability Space of a random expression. For internal use. Examples ======== >>> from sympy.stats import pspace, Normal >>> from sympy.stats.rv import IndependentProductPSpace >>> X = Normal('X', 0, 1) >>> pspace(2X + 1) == X.pspace True """ expr = sympify(expr) if isinstance(expr, RandomSymbol) and expr.pspace is not None: return expr.pspace rvs = random_symbols(expr) if not rvs: raise ValueError("Expression containing Random Variable expected, not %s" % (expr)) # If only one space present if all(rv.pspace == rvs[0].pspace for rv in rvs): return rvs[0].pspace # Otherwise make a product space return IndependentProductPSpace([rv.pspace for rv in rvs]) def sumsets(sets): """ Union of sets """ return frozenset().union(sets) def rs_swap(a, b): """ Build a dictionary to swap RandomSymbols based on their underlying symbol. i.e. if ``X = ('x', pspace1)`` and ``Y = ('x', pspace2)`` then ``X`` and ``Y`` match and the key, value pair ``{X:Y}`` will appear in the result Inputs: collections a and b of random variables which share common symbols Output: dict mapping RVs in a to RVs in b """ d = {} for rsa in a: d[rsa] = [rsb for rsb in b if rsa.symbol == rsb.symbol][0] return d def given(expr, condition=None, *kwargs): r""" Conditional Random Expression From a random expression and a condition on that expression creates a new probability space from the condition and returns the same expression on that conditional probability space. Examples ======== >>> from sympy.stats import given, density, Die >>> X = Die('X', 6) >>> Y = given(X, X > 3) >>> density(Y).dict {4: 1/3, 5: 1/3, 6: 1/3} Following convention, if the condition is a random symbol then that symbol is considered fixed. >>> from sympy.stats import Normal >>> from sympy import pprint >>> from sympy.abc import z >>> X = Normal('X', 0, 1) >>> Y = Normal('Y', 0, 1) >>> pprint(density(X + Y, Y)(z), use_unicode=False) 2 -(-Y + z) ----------- ___ 2 \/ 2 e ------------------ ____ 2\/ pi """ if not random_symbols(condition) or pspace_independent(expr, condition): return expr if isinstance(condition, RandomSymbol): condition = Eq(condition, condition.symbol) condsymbols = random_symbols(condition) if (isinstance(condition, Equality) and len(condsymbols) == 1 and not isinstance(pspace(expr).domain, ConditionalDomain)): rv = tuple(condsymbols)[0] results = solveset(condition, rv) if isinstance(results, Intersection) and S.Reals in results.args: results = list(results.args[1]) sums = 0 for res in results: temp = expr.subs(rv, res) if temp == True: return True if temp != False: sums += expr.subs(rv, res) if sums == 0: return False return sums # Get full probability space of both the expression and the condition fullspace = pspace(Tuple(expr, condition)) # Build new space given the condition space = fullspace.conditional_space(condition, kwargs) # Dictionary to swap out RandomSymbols in expr with new RandomSymbols # That point to the new conditional space swapdict = rs_swap(fullspace.values, space.values) # Swap random variables in the expression expr = expr.xreplace(swapdict) return expr def expectation(expr, condition=None, numsamples=None, evaluate=True, kwargs): """ Returns the expected value of a random expression Parameters ========== expr : Expr containing RandomSymbols The expression of which you want to compute the expectation value given : Expr containing RandomSymbols A conditional expression. E(X, X>0) is expectation of X given X > 0 numsamples : int Enables sampling and approximates the expectation with this many samples evalf : Bool (defaults to True) If sampling return a number rather than a complex expression evaluate : Bool (defaults to True) In case of continuous systems return unevaluated integral Examples ======== >>> from sympy.stats import E, Die >>> X = Die('X', 6) >>> E(X) 7/2 >>> E(2X + 1) 8 >>> E(X, X > 3) # Expectation of X given that it is above 3 5 """ if not random_symbols(expr): # expr isn't random? return expr if numsamples: # Computing by monte carlo sampling? return sampling_E(expr, condition, numsamples=numsamples) # Create new expr and recompute E if condition is not None: # If there is a condition return expectation(given(expr, condition), evaluate=evaluate) # A few known statements for efficiency if expr.is_Add: # We know that E is Linear return Add([expectation(arg, evaluate=evaluate) for arg in expr.args]) # Otherwise case is simple, pass work off to the ProbabilitySpace result = pspace(expr).compute_expectation(expr, evaluate=evaluate, kwargs) if evaluate and hasattr(result, 'doit'): return result.doit(kwargs) else: return result def probability(condition, given_condition=None, numsamples=None, evaluate=True, kwargs): """ Probability that a condition is true, optionally given a second condition Parameters ========== condition : Combination of Relationals containing RandomSymbols The condition of which you want to compute the probability given_condition : Combination of Relationals containing RandomSymbols A conditional expression. P(X > 1, X > 0) is expectation of X > 1 given X > 0 numsamples : int Enables sampling and approximates the probability with this many samples evaluate : Bool (defaults to True) In case of continuous systems return unevaluated integral Examples ======== >>> from sympy.stats import P, Die >>> from sympy import Eq >>> X, Y = Die('X', 6), Die('Y', 6) >>> P(X > 3) 1/2 >>> P(Eq(X, 5), X > 2) # Probability that X == 5 given that X > 2 1/4 >>> P(X > Y) 5/12 """ condition = sympify(condition) given_condition = sympify(given_condition) if given_condition is not None and \ not isinstance(given_condition, (Relational, Boolean)): raise ValueError("%s is not a relational or combination of relationals" % (given_condition)) if given_condition == False: return S.Zero if not isinstance(condition, (Relational, Boolean)): raise ValueError("%s is not a relational or combination of relationals" % (condition)) if condition is S.true: return S.One if condition is S.false: return S.Zero if numsamples: return sampling_P(condition, given_condition, numsamples=numsamples, kwargs) if given_condition is not None: # If there is a condition # Recompute on new conditional expr return probability(given(condition, given_condition, kwargs), kwargs) # Otherwise pass work off to the ProbabilitySpace result = pspace(condition).probability(condition, kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result class Density(Basic): expr = property(lambda self: self.args[0]) @property def condition(self): if len(self.args) > 1: return self.args[1] else: return None def doit(self, evaluate=True, kwargs): from sympy.stats.joint_rv import JointPSpace expr, condition = self.expr, self.condition if condition is not None: # Recompute on new conditional expr expr = given(expr, condition, kwargs) if isinstance(expr, RandomSymbol) and \ isinstance(expr.pspace, JointPSpace): return expr.pspace.distribution if not random_symbols(expr): return Lambda(x, DiracDelta(x - expr)) if (isinstance(expr, RandomSymbol) and hasattr(expr.pspace, 'distribution') and isinstance(pspace(expr), (SinglePSpace))): return expr.pspace.distribution result = pspace(expr).compute_density(expr, kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def density(expr, condition=None, evaluate=True, numsamples=None, kwargs): """ Probability density of a random expression, optionally given a second condition. This density will take on different forms for different types of probability spaces. Discrete variables produce Dicts. Continuous variables produce Lambdas. Parameters ========== expr : Expr containing RandomSymbols The expression of which you want to compute the density value condition : Relational containing RandomSymbols A conditional expression. density(X > 1, X > 0) is density of X > 1 given X > 0 numsamples : int Enables sampling and approximates the density with this many samples Examples ======== >>> from sympy.stats import density, Die, Normal >>> from sympy import Symbol >>> x = Symbol('x') >>> D = Die('D', 6) >>> X = Normal(x, 0, 1) >>> density(D).dict {1: 1/6, 2: 1/6, 3: 1/6, 4: 1/6, 5: 1/6, 6: 1/6} >>> density(2D).dict {2: 1/6, 4: 1/6, 6: 1/6, 8: 1/6, 10: 1/6, 12: 1/6} >>> density(X)(x) sqrt(2)exp(-x2/2)/(2sqrt(pi)) """ if numsamples: return sampling_density(expr, condition, numsamples=numsamples, kwargs) return Density(expr, condition).doit(evaluate=evaluate, kwargs) def cdf(expr, condition=None, evaluate=True, *kwargs): """ Cumulative Distribution Function of a random expression. optionally given a second condition This density will take on different forms for different types of probability spaces. Discrete variables produce Dicts. Continuous variables produce Lambdas. Examples ======== >>> from sympy.stats import density, Die, Normal, cdf >>> D = Die('D', 6) >>> X = Normal('X', 0, 1) >>> density(D).dict {1: 1/6, 2: 1/6, 3: 1/6, 4: 1/6, 5: 1/6, 6: 1/6} >>> cdf(D) {1: 1/6, 2: 1/3, 3: 1/2, 4: 2/3, 5: 5/6, 6: 1} >>> cdf(3D, D > 2) {9: 1/4, 12: 1/2, 15: 3/4, 18: 1} >>> cdf(X) Lambda(_z, erf(sqrt(2)_z/2)/2 + 1/2) """ if condition is not None: # If there is a condition # Recompute on new conditional expr return cdf(given(expr, condition, kwargs), kwargs) # Otherwise pass work off to the ProbabilitySpace result = pspace(expr).compute_cdf(expr, kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def characteristic_function(expr, condition=None, evaluate=True, kwargs): """ Characteristic function of a random expression, optionally given a second condition Returns a Lambda Examples ======== >>> from sympy.stats import Normal, DiscreteUniform, Poisson, characteristic_function >>> X = Normal('X', 0, 1) >>> characteristic_function(X) Lambda(_t, exp(-_t2/2)) >>> Y = DiscreteUniform('Y', [1, 2, 7]) >>> characteristic_function(Y) Lambda(_t, exp(7_tI)/3 + exp(2_tI)/3 + exp(_tI)/3) >>> Z = Poisson('Z', 2) >>> characteristic_function(Z) Lambda(_t, exp(2exp(_tI) - 2)) """ if condition is not None: return characteristic_function(given(expr, condition, kwargs), kwargs) result = pspace(expr).compute_characteristic_function(expr, kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def moment_generating_function(expr, condition=None, evaluate=True, kwargs): if condition is not None: return moment_generating_function(given(expr, condition, kwargs), kwargs) result = pspace(expr).compute_moment_generating_function(expr, kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def where(condition, given_condition=None, kwargs): """ Returns the domain where a condition is True. Examples ======== >>> from sympy.stats import where, Die, Normal >>> from sympy import symbols, And >>> D1, D2 = Die('a', 6), Die('b', 6) >>> a, b = D1.symbol, D2.symbol >>> X = Normal('x', 0, 1) >>> where(X2<1) Domain: (-1 < x) & (x < 1) >>> where(X2<1).set Interval.open(-1, 1) >>> where(And(D1<=D2 , D2<3)) Domain: (Eq(a, 1) & Eq(b, 1)) \| (Eq(a, 1) & Eq(b, 2)) \| (Eq(a, 2) & Eq(b, 2)) """ if given_condition is not None: # If there is a condition # Recompute on new conditional expr return where(given(condition, given_condition, kwargs), kwargs) # Otherwise pass work off to the ProbabilitySpace return pspace(condition).where(condition, kwargs) def sample(expr, condition=None, kwargs): """ A realization of the random expression Examples ======== >>> from sympy.stats import Die, sample >>> X, Y, Z = Die('X', 6), Die('Y', 6), Die('Z', 6) >>> die_roll = sample(X + Y + Z) # A random realization of three dice """ return next(sample_iter(expr, condition, numsamples=1)) def sample_iter(expr, condition=None, numsamples=S.Infinity, *kwargs): """ Returns an iterator of realizations from the expression given a condition Parameters ========== expr: Expr Random expression to be realized condition: Expr, optional A conditional expression numsamples: integer, optional Length of the iterator (defaults to infinity) Examples ======== >>> from sympy.stats import Normal, sample_iter >>> X = Normal('X', 0, 1) >>> expr = XX + 3 >>> iterator = sample_iter(expr, numsamples=3) >>> list(iterator) # doctest: +SKIP [12, 4, 7] See Also ======== sample sampling_P sampling_E sample_iter_lambdify sample_iter_subs """ # lambdify is much faster but not as robust try: return sample_iter_lambdify(expr, condition, numsamples, kwargs) # use subs when lambdify fails except TypeError: return sample_iter_subs(expr, condition, numsamples, kwargs) def sample_iter_lambdify(expr, condition=None, numsamples=S.Infinity, kwargs): """ See sample_iter Uses lambdify for computation. This is fast but does not always work. """ if condition: ps = pspace(Tuple(expr, condition)) else: ps = pspace(expr) rvs = list(ps.values) fn = lambdify(rvs, expr, kwargs) if condition: given_fn = lambdify(rvs, condition, *kwargs) # Check that lambdify can handle the expression # Some operations like Sum can prove difficult try: d = ps.sample() # a dictionary that maps RVs to values args = [d[rv] for rv in rvs] fn(args) if condition: given_fn(args) except Exception: raise TypeError("Expr/condition too complex for lambdify") def return_generator(): count = 0 while count < numsamples: d = ps.sample() # a dictionary that maps RVs to values args = [d[rv] for rv in rvs] if condition: # Check that these values satisfy the condition gd = given_fn(args) if gd != True and gd != False: raise ValueError( "Conditions must not contain free symbols") if not gd: # If the values don't satisfy then try again continue yield fn(args) count += 1 return return_generator() def sample_iter_subs(expr, condition=None, numsamples=S.Infinity, kwargs): """ See sample_iter Uses subs for computation. This is slow but almost always works. """ if condition is not None: ps = pspace(Tuple(expr, condition)) else: ps = pspace(expr) count = 0 while count < numsamples: d = ps.sample() # a dictionary that maps RVs to values if condition is not None: # Check that these values satisfy the condition gd = condition.xreplace(d) if gd != True and gd != False: raise ValueError("Conditions must not contain free symbols") if not gd: # If the values don't satisfy then try again continue yield expr.xreplace(d) count += 1 def sampling_P(condition, given_condition=None, numsamples=1, evalf=True, kwargs): """ Sampling version of P See Also ======== P sampling_E sampling_density """ count_true = 0 count_false = 0 samples = sample_iter(condition, given_condition, numsamples=numsamples, kwargs) for sample in samples: if sample != True and sample != False: raise ValueError("Conditions must not contain free symbols") if sample: count_true += 1 else: count_false += 1 result = S(count_true) / numsamples if evalf: return result.evalf() else: return result def sampling_E(expr, given_condition=None, numsamples=1, evalf=True, kwargs): """ Sampling version of E See Also ======== P sampling_P sampling_density """ samples = sample_iter(expr, given_condition, numsamples=numsamples, kwargs) result = Add(list(samples)) / numsamples if evalf: return result.evalf() else: return result def sampling_density(expr, given_condition=None, numsamples=1, kwargs): """ Sampling version of density See Also ======== density sampling_P sampling_E """ results = {} for result in sample_iter(expr, given_condition, numsamples=numsamples, kwargs): results[result] = results.get(result, 0) + 1 return results def dependent(a, b): """ Dependence of two random expressions Two expressions are independent if knowledge of one does not change computations on the other. Examples ======== >>> from sympy.stats import Normal, dependent, given >>> from sympy import Tuple, Eq >>> X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) >>> dependent(X, Y) False >>> dependent(2X + Y, -Y) True >>> X, Y = given(Tuple(X, Y), Eq(X + Y, 3)) >>> dependent(X, Y) True See Also ======== independent """ if pspace_independent(a, b): return False z = Symbol('z', real=True) # Dependent if density is unchanged when one is given information about # the other return (density(a, Eq(b, z)) != density(a) or density(b, Eq(a, z)) != density(b)) def independent(a, b): """ Independence of two random expressions Two expressions are independent if knowledge of one does not change computations on the other. Examples ======== >>> from sympy.stats import Normal, independent, given >>> from sympy import Tuple, Eq >>> X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) >>> independent(X, Y) True >>> independent(2X + Y, -Y) False >>> X, Y = given(Tuple(X, Y), Eq(X + Y, 3)) >>> independent(X, Y) False See Also ======== dependent """ return not dependent(a, b) def pspace_independent(a, b): """ Tests for independence between a and b by checking if their PSpaces have overlapping symbols. This is a sufficient but not necessary condition for independence and is intended to be used internally. Notes ===== pspace_independent(a, b) implies independent(a, b) independent(a, b) does not imply pspace_independent(a, b) """ a_symbols = set(pspace(b).symbols) b_symbols = set(pspace(a).symbols) if len(set(random_symbols(a)).intersection(random_symbols(b))) != 0: return False if len(a_symbols.intersection(b_symbols)) == 0: return True return None def rv_subs(expr, symbols=None): """ Given a random expression replace all random variables with their symbols. If symbols keyword is given restrict the swap to only the symbols listed. """ if symbols is None: symbols = random_symbols(expr) if not symbols: return expr swapdict = {rv: rv.symbol for rv in symbols} return expr.xreplace(swapdict) class NamedArgsMixin(object): _argnames = () def __getattr__(self, attr): try: return self.args[self._argnames.index(attr)] except ValueError: raise AttributeError("'%s' object has no attribute '%s'" % ( type(self).__name__, attr)) def _value_check(condition, message): """ Check a condition on input value. Raises ValueError with message if condition is not True """ if condition == False: raise ValueError(message)
ca00bbf6349d4706bf76ffbb02d069191ca731707deb926320f66406e951c4f2	from __future__ import print_function, division from collections import defaultdict from sympy.core import (Basic, S, Add, Mul, Pow, Symbol, sympify, expand_mul, expand_func, Function, Dummy, Expr, factor_terms, expand_power_exp) from sympy.core.compatibility import iterable, ordered, range, as_int from sympy.core.evaluate import global_evaluate from sympy.core.function import expand_log, count_ops, _mexpand, _coeff_isneg, nfloat from sympy.core.numbers import Float, I, pi, Rational, Integer from sympy.core.rules import Transform from sympy.core.sympify import _sympify from sympy.functions import gamma, exp, sqrt, log, exp_polar, piecewise_fold from sympy.functions.combinatorial.factorials import CombinatorialFunction from sympy.functions.elementary.complexes import unpolarify from sympy.functions.elementary.exponential import ExpBase from sympy.functions.elementary.hyperbolic import HyperbolicFunction from sympy.functions.elementary.integers import ceiling from sympy.functions.elementary.trigonometric import TrigonometricFunction from sympy.functions.special.bessel import besselj, besseli, besselk, jn, bessely from sympy.polys import together, cancel, factor from sympy.simplify.combsimp import combsimp from sympy.simplify.cse_opts import sub_pre, sub_post from sympy.simplify.powsimp import powsimp from sympy.simplify.radsimp import radsimp, fraction from sympy.simplify.sqrtdenest import sqrtdenest from sympy.simplify.trigsimp import trigsimp, exptrigsimp from sympy.utilities.iterables import has_variety, sift import mpmath def separatevars(expr, symbols=[], dict=False, force=False): """ Separates variables in an expression, if possible. By default, it separates with respect to all symbols in an expression and collects constant coefficients that are independent of symbols. If dict=True then the separated terms will be returned in a dictionary keyed to their corresponding symbols. By default, all symbols in the expression will appear as keys; if symbols are provided, then all those symbols will be used as keys, and any terms in the expression containing other symbols or non-symbols will be returned keyed to the string 'coeff'. (Passing None for symbols will return the expression in a dictionary keyed to 'coeff'.) If force=True, then bases of powers will be separated regardless of assumptions on the symbols involved. Notes ===== The order of the factors is determined by Mul, so that the separated expressions may not necessarily be grouped together. Although factoring is necessary to separate variables in some expressions, it is not necessary in all cases, so one should not count on the returned factors being factored. Examples ======== >>> from sympy.abc import x, y, z, alpha >>> from sympy import separatevars, sin >>> separatevars((xy)y) (xy)*y >>> separatevars((xy)y, force=True) xyyy >>> e = 2x*2zsin(y)+2zx2 >>> separatevars(e) 2x*2z(sin(y) + 1) >>> separatevars(e, symbols=(x, y), dict=True) {'coeff': 2z, x: x*2, y: sin(y) + 1} >>> separatevars(e, [x, y, alpha], dict=True) {'coeff': 2z, alpha: 1, x: x*2, y: sin(y) + 1} If the expression is not really separable, or is only partially separable, separatevars will do the best it can to separate it by using factoring. >>> separatevars(x + xy - 3x2) -x(3x - y - 1) If the expression is not separable then expr is returned unchanged or (if dict=True) then None is returned. >>> eq = 2x + ysin(x) >>> separatevars(eq) == eq True >>> separatevars(2x + ysin(x), symbols=(x, y), dict=True) == None True """ expr = sympify(expr) if dict: return _separatevars_dict(_separatevars(expr, force), symbols) else: return _separatevars(expr, force) def _separatevars(expr, force): if len(expr.free_symbols) == 1: return expr # don't destroy a Mul since much of the work may already be done if expr.is_Mul: args = list(expr.args) changed = False for i, a in enumerate(args): args[i] = separatevars(a, force) changed = changed or args[i] != a if changed: expr = expr.func(args) return expr # get a Pow ready for expansion if expr.is_Pow: expr = Pow(separatevars(expr.base, force=force), expr.exp) # First try other expansion methods expr = expr.expand(mul=False, multinomial=False, force=force) _expr, reps = posify(expr) if force else (expr, {}) expr = factor(_expr).subs(reps) if not expr.is_Add: return expr # Find any common coefficients to pull out args = list(expr.args) commonc = args[0].args_cnc(cset=True, warn=False)[0] for i in args[1:]: commonc &= i.args_cnc(cset=True, warn=False)[0] commonc = Mul(commonc) commonc = commonc.as_coeff_Mul()[1] # ignore constants commonc_set = commonc.args_cnc(cset=True, warn=False)[0] # remove them for i, a in enumerate(args): c, nc = a.args_cnc(cset=True, warn=False) c = c - commonc_set args[i] = Mul(c)Mul(nc) nonsepar = Add(args) if len(nonsepar.free_symbols) > 1: _expr = nonsepar _expr, reps = posify(_expr) if force else (_expr, {}) _expr = (factor(_expr)).subs(reps) if not _expr.is_Add: nonsepar = _expr return commoncnonsepar def _separatevars_dict(expr, symbols): if symbols: if not all((t.is_Atom for t in symbols)): raise ValueError("symbols must be Atoms.") symbols = list(symbols) elif symbols is None: return {'coeff': expr} else: symbols = list(expr.free_symbols) if not symbols: return None ret = dict(((i, []) for i in symbols + ['coeff'])) for i in Mul.make_args(expr): expsym = i.free_symbols intersection = set(symbols).intersection(expsym) if len(intersection) > 1: return None if len(intersection) == 0: # There are no symbols, so it is part of the coefficient ret['coeff'].append(i) else: ret[intersection.pop()].append(i) # rebuild for k, v in ret.items(): ret[k] = Mul(v) return ret def _is_sum_surds(p): args = p.args if p.is_Add else [p] for y in args: if not ((y2).is_Rational and y.is_real): return False return True def posify(eq): """Return eq (with generic symbols made positive) and a dictionary containing the mapping between the old and new symbols. Any symbol that has positive=None will be replaced with a positive dummy symbol having the same name. This replacement will allow more symbolic processing of expressions, especially those involving powers and logarithms. A dictionary that can be sent to subs to restore eq to its original symbols is also returned. >>> from sympy import posify, Symbol, log, solve >>> from sympy.abc import x >>> posify(x + Symbol('p', positive=True) + Symbol('n', negative=True)) (_x + n + p, {_x: x}) >>> eq = 1/x >>> log(eq).expand() log(1/x) >>> log(posify(eq)[0]).expand() -log(_x) >>> p, rep = posify(eq) >>> log(p).expand().subs(rep) -log(x) It is possible to apply the same transformations to an iterable of expressions: >>> eq = x2 - 4 >>> solve(eq, x) [-2, 2] >>> eq_x, reps = posify([eq, x]); eq_x [_x2 - 4, _x] >>> solve(eq_x) [2] """ eq = sympify(eq) if iterable(eq): f = type(eq) eq = list(eq) syms = set() for e in eq: syms = syms.union(e.atoms(Symbol)) reps = {} for s in syms: reps.update(dict((v, k) for k, v in posify(s)[1].items())) for i, e in enumerate(eq): eq[i] = e.subs(reps) return f(eq), {r: s for s, r in reps.items()} reps = {s: Dummy(s.name, positive=True, s.assumptions0) for s in eq.free_symbols if s.is_positive is None} eq = eq.subs(reps) return eq, {r: s for s, r in reps.items()} def hypersimp(f, k): """Given combinatorial term f(k) simplify its consecutive term ratio i.e. f(k+1)/f(k). The input term can be composed of functions and integer sequences which have equivalent representation in terms of gamma special function. The algorithm performs three basic steps: 1. Rewrite all functions in terms of gamma, if possible. 2. Rewrite all occurrences of gamma in terms of products of gamma and rising factorial with integer, absolute constant exponent. 3. Perform simplification of nested fractions, powers and if the resulting expression is a quotient of polynomials, reduce their total degree. If f(k) is hypergeometric then as result we arrive with a quotient of polynomials of minimal degree. Otherwise None is returned. For more information on the implemented algorithm refer to: 1. W. Koepf, Algorithms for m-fold Hypergeometric Summation, Journal of Symbolic Computation (1995) 20, 399-417 """ f = sympify(f) g = f.subs(k, k + 1) / f g = g.rewrite(gamma) g = expand_func(g) g = powsimp(g, deep=True, combine='exp') if g.is_rational_function(k): return simplify(g, ratio=S.Infinity) else: return None def hypersimilar(f, g, k): """Returns True if 'f' and 'g' are hyper-similar. Similarity in hypergeometric sense means that a quotient of f(k) and g(k) is a rational function in k. This procedure is useful in solving recurrence relations. For more information see hypersimp(). """ f, g = list(map(sympify, (f, g))) h = (f/g).rewrite(gamma) h = h.expand(func=True, basic=False) return h.is_rational_function(k) def signsimp(expr, evaluate=None): """Make all Add sub-expressions canonical wrt sign. If an Add subexpression, ``a``, can have a sign extracted, as determined by could_extract_minus_sign, it is replaced with Mul(-1, a, evaluate=False). This allows signs to be extracted from powers and products. Examples ======== >>> from sympy import signsimp, exp, symbols >>> from sympy.abc import x, y >>> i = symbols('i', odd=True) >>> n = -1 + 1/x >>> n/x/(-n)2 - 1/n/x (-1 + 1/x)/(x(1 - 1/x)2) - 1/(x(-1 + 1/x)) >>> signsimp(_) 0 >>> xn + x-n x(-1 + 1/x) + x(1 - 1/x) >>> signsimp(_) 0 Since powers automatically handle leading signs >>> (-2)i -2i signsimp can be used to put the base of a power with an integer exponent into canonical form: >>> ni (-1 + 1/x)i By default, signsimp doesn't leave behind any hollow simplification: if making an Add canonical wrt sign didn't change the expression, the original Add is restored. If this is not desired then the keyword ``evaluate`` can be set to False: >>> e = exp(y - x) >>> signsimp(e) == e True >>> signsimp(e, evaluate=False) exp(-(x - y)) """ if evaluate is None: evaluate = global_evaluate[0] expr = sympify(expr) if not isinstance(expr, Expr) or expr.is_Atom: return expr e = sub_post(sub_pre(expr)) if not isinstance(e, Expr) or e.is_Atom: return e if e.is_Add: return e.func([signsimp(a, evaluate) for a in e.args]) if evaluate: e = e.xreplace({m: -(-m) for m in e.atoms(Mul) if -(-m) != m}) return e def simplify(expr, ratio=1.7, measure=count_ops, rational=False, inverse=False): """Simplifies the given expression. Simplification is not a well defined term and the exact strategies this function tries can change in the future versions of SymPy. If your algorithm relies on "simplification" (whatever it is), try to determine what you need exactly - is it powsimp()?, radsimp()?, together()?, logcombine()?, or something else? And use this particular function directly, because those are well defined and thus your algorithm will be robust. Nonetheless, especially for interactive use, or when you don't know anything about the structure of the expression, simplify() tries to apply intelligent heuristics to make the input expression "simpler". For example: >>> from sympy import simplify, cos, sin >>> from sympy.abc import x, y >>> a = (x + x2)/(xsin(y)*2 + xcos(y)2) >>> a (x2 + x)/(xsin(y)2 + xcos(y)2) >>> simplify(a) x + 1 Note that we could have obtained the same result by using specific simplification functions: >>> from sympy import trigsimp, cancel >>> trigsimp(a) (x2 + x)/x >>> cancel(_) x + 1 In some cases, applying :func:`simplify` may actually result in some more complicated expression. The default ``ratio=1.7`` prevents more extreme cases: if (result length)/(input length) > ratio, then input is returned unmodified. The ``measure`` parameter lets you specify the function used to determine how complex an expression is. The function should take a single argument as an expression and return a number such that if expression ``a`` is more complex than expression ``b``, then ``measure(a) > measure(b)``. The default measure function is :func:`count_ops`, which returns the total number of operations in the expression. For example, if ``ratio=1``, ``simplify`` output can't be longer than input. :: >>> from sympy import sqrt, simplify, count_ops, oo >>> root = 1/(sqrt(2)+3) Since ``simplify(root)`` would result in a slightly longer expression, root is returned unchanged instead:: >>> simplify(root, ratio=1) == root True If ``ratio=oo``, simplify will be applied anyway:: >>> count_ops(simplify(root, ratio=oo)) > count_ops(root) True Note that the shortest expression is not necessary the simplest, so setting ``ratio`` to 1 may not be a good idea. Heuristically, the default value ``ratio=1.7`` seems like a reasonable choice. You can easily define your own measure function based on what you feel should represent the "size" or "complexity" of the input expression. Note that some choices, such as ``lambda expr: len(str(expr))`` may appear to be good metrics, but have other problems (in this case, the measure function may slow down simplify too much for very large expressions). If you don't know what a good metric would be, the default, ``count_ops``, is a good one. For example: >>> from sympy import symbols, log >>> a, b = symbols('a b', positive=True) >>> g = log(a) + log(b) + log(a)log(1/b) >>> h = simplify(g) >>> h log(ab(1 - log(a))) >>> count_ops(g) 8 >>> count_ops(h) 5 So you can see that ``h`` is simpler than ``g`` using the count_ops metric. However, we may not like how ``simplify`` (in this case, using ``logcombine``) has created the ``b(log(1/a) + 1)`` term. A simple way to reduce this would be to give more weight to powers as operations in ``count_ops``. We can do this by using the ``visual=True`` option: >>> print(count_ops(g, visual=True)) 2ADD + DIV + 4LOG + MUL >>> print(count_ops(h, visual=True)) 2LOG + MUL + POW + SUB >>> from sympy import Symbol, S >>> def my_measure(expr): ... POW = Symbol('POW') ... # Discourage powers by giving POW a weight of 10 ... count = count_ops(expr, visual=True).subs(POW, 10) ... # Every other operation gets a weight of 1 (the default) ... count = count.replace(Symbol, type(S.One)) ... return count >>> my_measure(g) 8 >>> my_measure(h) 14 >>> 15./8 > 1.7 # 1.7 is the default ratio True >>> simplify(g, measure=my_measure) -log(a)log(b) + log(a) + log(b) Note that because ``simplify()`` internally tries many different simplification strategies and then compares them using the measure function, we get a completely different result that is still different from the input expression by doing this. If rational=True, Floats will be recast as Rationals before simplification. If rational=None, Floats will be recast as Rationals but the result will be recast as Floats. If rational=False(default) then nothing will be done to the Floats. If inverse=True, it will be assumed that a composition of inverse functions, such as sin and asin, can be cancelled in any order. For example, ``asin(sin(x))`` will yield ``x`` without checking whether x belongs to the set where this relation is true. The default is False. """ expr = sympify(expr) kwargs = dict(ratio=ratio, measure=measure, rational=rational, inverse=inverse) _eval_simplify = getattr(expr, '_eval_simplify', None) if _eval_simplify is not None: return _eval_simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse) original_expr = expr = signsimp(expr) from sympy.simplify.hyperexpand import hyperexpand from sympy.functions.special.bessel import BesselBase from sympy import Sum, Product, Integral if not isinstance(expr, Basic) or not expr.args: # XXX: temporary hack return expr if inverse and expr.has(Function): expr = inversecombine(expr) if not expr.args: # simplified to atomic return expr if not isinstance(expr, (Add, Mul, Pow, ExpBase)): return expr.func([simplify(x, kwargs) for x in expr.args]) if not expr.is_commutative: expr = nc_simplify(expr) # TODO: Apply different strategies, considering expression pattern: # is it a purely rational function? Is there any trigonometric function?... # See also https://github.com/sympy/sympy/pull/185. def shorter(choices): '''Return the choice that has the fewest ops. In case of a tie, the expression listed first is selected.''' if not has_variety(choices): return choices[0] return min(choices, key=measure) # rationalize Floats floats = False if rational is not False and expr.has(Float): floats = True expr = nsimplify(expr, rational=True) expr = bottom_up(expr, lambda w: getattr(w, 'normal', lambda: w)()) expr = Mul(powsimp(expr).as_content_primitive()) _e = cancel(expr) expr1 = shorter(_e, _mexpand(_e).cancel()) # issue 6829 expr2 = shorter(together(expr, deep=True), together(expr1, deep=True)) if ratio is S.Infinity: expr = expr2 else: expr = shorter(expr2, expr1, expr) if not isinstance(expr, Basic): # XXX: temporary hack return expr expr = factor_terms(expr, sign=False) # hyperexpand automatically only works on hypergeometric terms expr = hyperexpand(expr) expr = piecewise_fold(expr) if expr.has(BesselBase): expr = besselsimp(expr) if expr.has(TrigonometricFunction, HyperbolicFunction): expr = trigsimp(expr, deep=True) if expr.has(log): expr = shorter(expand_log(expr, deep=True), logcombine(expr)) if expr.has(CombinatorialFunction, gamma): # expression with gamma functions or non-integer arguments is # automatically passed to gammasimp expr = combsimp(expr) if expr.has(Sum): expr = sum_simplify(expr, kwargs) if expr.has(Integral): expr = expr.xreplace(dict([ (i, factor_terms(i)) for i in expr.atoms(Integral)])) if expr.has(Product): expr = product_simplify(expr) from sympy.physics.units import Quantity from sympy.physics.units.util import quantity_simplify if expr.has(Quantity): expr = quantity_simplify(expr) short = shorter(powsimp(expr, combine='exp', deep=True), powsimp(expr), expr) short = shorter(short, cancel(short)) short = shorter(short, factor_terms(short), expand_power_exp(expand_mul(short))) if short.has(TrigonometricFunction, HyperbolicFunction, ExpBase): short = exptrigsimp(short) # get rid of hollow 2-arg Mul factorization hollow_mul = Transform( lambda x: Mul(x.args), lambda x: x.is_Mul and len(x.args) == 2 and x.args[0].is_Number and x.args[1].is_Add and x.is_commutative) expr = short.xreplace(hollow_mul) numer, denom = expr.as_numer_denom() if denom.is_Add: n, d = fraction(radsimp(1/denom, symbolic=False, max_terms=1)) if n is not S.One: expr = (numern).expand()/d if expr.could_extract_minus_sign(): n, d = fraction(expr) if d != 0: expr = signsimp(-n/(-d)) if measure(expr) > ratiomeasure(original_expr): expr = original_expr # restore floats if floats and rational is None: expr = nfloat(expr, exponent=False) return expr def sum_simplify(s, kwargs): """Main function for Sum simplification""" from sympy.concrete.summations import Sum from sympy.core.function import expand if not isinstance(s, Add): s = s.xreplace(dict([(a, sum_simplify(a, kwargs)) for a in s.atoms(Add) if a.has(Sum)])) s = expand(s) if not isinstance(s, Add): return s terms = s.args s_t = [] # Sum Terms o_t = [] # Other Terms for term in terms: sum_terms, other = sift(Mul.make_args(term), lambda i: isinstance(i, Sum), binary=True) if not sum_terms: o_t.append(term) continue other = [Mul(other)] s_t.append(Mul((other + [s._eval_simplify(*kwargs) for s in sum_terms]))) result = Add(sum_combine(s_t), o_t) return result def sum_combine(s_t): """Helper function for Sum simplification Attempts to simplify a list of sums, by combining limits / sum function's returns the simplified sum """ from sympy.concrete.summations import Sum used = [False] * len(s_t) for method in range(2): for i, s_term1 in enumerate(s_t): if not used[i]: for j, s_term2 in enumerate(s_t): if not used[j] and i != j: temp = sum_add(s_term1, s_term2, method) if isinstance(temp, Sum) or isinstance(temp, Mul): s_t[i] = temp s_term1 = s_t[i] used[j] = True result = S.Zero for i, s_term in enumerate(s_t): if not used[i]: result = Add(result, s_term) return result def factor_sum(self, limits=None, radical=False, clear=False, fraction=False, sign=True): """Return Sum with constant factors extracted. If ``limits`` is specified then ``self`` is the summand; the other keywords are passed to ``factor_terms``. Examples ======== >>> from sympy import Sum, Integral >>> from sympy.abc import x, y >>> from sympy.simplify.simplify import factor_sum >>> s = Sum(xy, (x, 1, 3)) >>> factor_sum(s) ySum(x, (x, 1, 3)) >>> factor_sum(s.function, s.limits) ySum(x, (x, 1, 3)) """ # XXX deprecate in favor of direct call to factor_terms from sympy.concrete.summations import Sum kwargs = dict(radical=radical, clear=clear, fraction=fraction, sign=sign) expr = Sum(self, limits) if limits else self return factor_terms(expr, *kwargs) def sum_add(self, other, method=0): """Helper function for Sum simplification""" from sympy.concrete.summations import Sum from sympy import Mul #we know this is something in terms of a constant a sum #so we temporarily put the constants inside for simplification #then simplify the result def __refactor(val): args = Mul.make_args(val) sumv = next(x for x in args if isinstance(x, Sum)) constant = Mul([x for x in args if x != sumv]) return Sum(constant sumv.function, sumv.limits) if isinstance(self, Mul): rself = __refactor(self) else: rself = self if isinstance(other, Mul): rother = __refactor(other) else: rother = other if type(rself) == type(rother): if method == 0: if rself.limits == rother.limits: return factor_sum(Sum(rself.function + rother.function, rself.limits)) elif method == 1: if simplify(rself.function - rother.function) == 0: if len(rself.limits) == len(rother.limits) == 1: i = rself.limits[0][0] x1 = rself.limits[0][1] y1 = rself.limits[0][2] j = rother.limits[0][0] x2 = rother.limits[0][1] y2 = rother.limits[0][2] if i == j: if x2 == y1 + 1: return factor_sum(Sum(rself.function, (i, x1, y2))) elif x1 == y2 + 1: return factor_sum(Sum(rself.function, (i, x2, y1))) return Add(self, other) def product_simplify(s): """Main function for Product simplification""" from sympy.concrete.products import Product terms = Mul.make_args(s) p_t = [] # Product Terms o_t = [] # Other Terms for term in terms: if isinstance(term, Product): p_t.append(term) else: o_t.append(term) used = [False] * len(p_t) for method in range(2): for i, p_term1 in enumerate(p_t): if not used[i]: for j, p_term2 in enumerate(p_t): if not used[j] and i != j: if isinstance(product_mul(p_term1, p_term2, method), Product): p_t[i] = product_mul(p_term1, p_term2, method) used[j] = True result = Mul(o_t) for i, p_term in enumerate(p_t): if not used[i]: result = Mul(result, p_term) return result def product_mul(self, other, method=0): """Helper function for Product simplification""" from sympy.concrete.products import Product if type(self) == type(other): if method == 0: if self.limits == other.limits: return Product(self.function other.function, self.limits) elif method == 1: if simplify(self.function - other.function) == 0: if len(self.limits) == len(other.limits) == 1: i = self.limits[0][0] x1 = self.limits[0][1] y1 = self.limits[0][2] j = other.limits[0][0] x2 = other.limits[0][1] y2 = other.limits[0][2] if i == j: if x2 == y1 + 1: return Product(self.function, (i, x1, y2)) elif x1 == y2 + 1: return Product(self.function, (i, x2, y1)) return Mul(self, other) def _nthroot_solve(p, n, prec): """ helper function for ``nthroot`` It denests ``pRational(1, n)`` using its minimal polynomial """ from sympy.polys.numberfields import _minimal_polynomial_sq from sympy.solvers import solve while n % 2 == 0: p = sqrtdenest(sqrt(p)) n = n // 2 if n == 1: return p pn = pRational(1, n) x = Symbol('x') f = _minimal_polynomial_sq(p, n, x) if f is None: return None sols = solve(f, x) for sol in sols: if abs(sol - pn).n() < 1./10prec: sol = sqrtdenest(sol) if _mexpand(soln) == p: return sol def logcombine(expr, force=False): """ Takes logarithms and combines them using the following rules: - log(x) + log(y) == log(xy) if both are positive - alog(x) == log(xa) if x is positive and a is real If ``force`` is True then the assumptions above will be assumed to hold if there is no assumption already in place on a quantity. For example, if ``a`` is imaginary or the argument negative, force will not perform a combination but if ``a`` is a symbol with no assumptions the change will take place. Examples ======== >>> from sympy import Symbol, symbols, log, logcombine, I >>> from sympy.abc import a, x, y, z >>> logcombine(alog(x) + log(y) - log(z)) alog(x) + log(y) - log(z) >>> logcombine(alog(x) + log(y) - log(z), force=True) log(x*ay/z) >>> x,y,z = symbols('x,y,z', positive=True) >>> a = Symbol('a', real=True) >>> logcombine(alog(x) + log(y) - log(z)) log(xay/z) The transformation is limited to factors and/or terms that contain logs, so the result depends on the initial state of expansion: >>> eq = (2 + 3I)log(x) >>> logcombine(eq, force=True) == eq True >>> logcombine(eq.expand(), force=True) log(x*2) + Ilog(x*3) See Also ======== posify: replace all symbols with symbols having positive assumptions sympy.core.function.expand_log: expand the logarithms of products and powers; the opposite of logcombine """ def f(rv): if not (rv.is_Add or rv.is_Mul): return rv def gooda(a): # bool to tell whether the leading ``a`` in ``alog(x)`` # could appear as log(x*a) return (a is not S.NegativeOne and # -1 could* go, but we disallow (a.is_real or force and a.is_real is not False)) def goodlog(l): # bool to tell whether log ``l``'s argument can combine with others a = l.args[0] return a.is_positive or force and a.is_nonpositive is not False other = [] logs = [] log1 = defaultdict(list) for a in Add.make_args(rv): if isinstance(a, log) and goodlog(a): log1[()].append(([], a)) elif not a.is_Mul: other.append(a) else: ot = [] co = [] lo = [] for ai in a.args: if ai.is_Rational and ai < 0: ot.append(S.NegativeOne) co.append(-ai) elif isinstance(ai, log) and goodlog(ai): lo.append(ai) elif gooda(ai): co.append(ai) else: ot.append(ai) if len(lo) > 1: logs.append((ot, co, lo)) elif lo: log1[tuple(ot)].append((co, lo[0])) else: other.append(a) # if there is only one log in other, put it with the # good logs if len(other) == 1 and isinstance(other[0], log): log1[()].append(([], other.pop())) # if there is only one log at each coefficient and none have # an exponent to place inside the log then there is nothing to do if not logs and all(len(log1[k]) == 1 and log1[k][0] == [] for k in log1): return rv # collapse multi-logs as far as possible in a canonical way # TODO: see if xlog(a)+xlog(a)log(b) -> xlog(a)(1+log(b))? # -- in this case, it's unambiguous, but if it were were a log(c) in # each term then it's arbitrary whether they are grouped by log(a) or # by log(c). So for now, just leave this alone; it's probably better to # let the user decide for o, e, l in logs: l = list(ordered(l)) e = log(l.pop(0).args[0]Mul(e)) while l: li = l.pop(0) e = log(li.args[0]*e) c, l = Mul(o), e if isinstance(l, log): # it should be, but check to be sure log1[(c,)].append(([], l)) else: other.append(cl) # logs that have the same coefficient can multiply for k in list(log1.keys()): log1[Mul(k)] = log(logcombine(Mul([ l.args[0]Mul(c) for c, l in log1.pop(k)]), force=force), evaluate=False) # logs that have oppositely signed coefficients can divide for k in ordered(list(log1.keys())): if not k in log1: # already popped as -k continue if -k in log1: # figure out which has the minus sign; the one with # more op counts should be the one num, den = k, -k if num.count_ops() > den.count_ops(): num, den = den, num other.append( numlog(log1.pop(num).args[0]/log1.pop(den).args[0], evaluate=False)) else: other.append(klog1.pop(k)) return Add(other) return bottom_up(expr, f) def inversecombine(expr): """Simplify the composition of a function and its inverse. No attention is paid to whether the inverse is a left inverse or a right inverse; thus, the result will in general not be equivalent to the original expression. Examples ======== >>> from sympy.simplify.simplify import inversecombine >>> from sympy import asin, sin, log, exp >>> from sympy.abc import x >>> inversecombine(asin(sin(x))) x >>> inversecombine(2log(exp(3x))) 6x """ def f(rv): if rv.is_Function and hasattr(rv, "inverse"): if (len(rv.args) == 1 and len(rv.args[0].args) == 1 and isinstance(rv.args[0], rv.inverse(argindex=1))): rv = rv.args[0].args[0] return rv return bottom_up(expr, f) def walk(e, target): """iterate through the args that are the given types (target) and return a list of the args that were traversed; arguments that are not of the specified types are not traversed. Examples ======== >>> from sympy.simplify.simplify import walk >>> from sympy import Min, Max >>> from sympy.abc import x, y, z >>> list(walk(Min(x, Max(y, Min(1, z))), Min)) [Min(x, Max(y, Min(1, z)))] >>> list(walk(Min(x, Max(y, Min(1, z))), Min, Max)) [Min(x, Max(y, Min(1, z))), Max(y, Min(1, z)), Min(1, z)] See Also ======== bottom_up """ if isinstance(e, target): yield e for i in e.args: for w in walk(i, target): yield w def bottom_up(rv, F, atoms=False, nonbasic=False): """Apply ``F`` to all expressions in an expression tree from the bottom up. If ``atoms`` is True, apply ``F`` even if there are no args; if ``nonbasic`` is True, try to apply ``F`` to non-Basic objects. """ args = getattr(rv, 'args', None) if args is not None: if args: args = tuple([bottom_up(a, F, atoms, nonbasic) for a in args]) if args != rv.args: rv = rv.func(args) rv = F(rv) elif atoms: rv = F(rv) else: if nonbasic: try: rv = F(rv) except TypeError: pass return rv def besselsimp(expr): """ Simplify bessel-type functions. This routine tries to simplify bessel-type functions. Currently it only works on the Bessel J and I functions, however. It works by looking at all such functions in turn, and eliminating factors of "I" and "-1" (actually their polar equivalents) in front of the argument. Then, functions of half-integer order are rewritten using strigonometric functions and functions of integer order (> 1) are rewritten using functions of low order. Finally, if the expression was changed, compute factorization of the result with factor(). >>> from sympy import besselj, besseli, besselsimp, polar_lift, I, S >>> from sympy.abc import z, nu >>> besselsimp(besselj(nu, zpolar_lift(-1))) exp(Ipinu)besselj(nu, z) >>> besselsimp(besseli(nu, zpolar_lift(-I))) exp(-Ipinu/2)besselj(nu, z) >>> besselsimp(besseli(S(-1)/2, z)) sqrt(2)cosh(z)/(sqrt(pi)sqrt(z)) >>> besselsimp(zbesseli(0, z) + z(besseli(2, z))/2 + besseli(1, z)) 3zbesseli(0, z)/2 """ # TODO # - better algorithm? # - simplify (cos(pib)besselj(b,z) - besselj(-b,z))/sin(pib) ... # - use contiguity relations? def replacer(fro, to, factors): factors = set(factors) def repl(nu, z): if factors.intersection(Mul.make_args(z)): return to(nu, z) return fro(nu, z) return repl def torewrite(fro, to): def tofunc(nu, z): return fro(nu, z).rewrite(to) return tofunc def tominus(fro): def tofunc(nu, z): return exp(Ipinu)fro(nu, exp_polar(-Ipi)z) return tofunc orig_expr = expr ifactors = [I, exp_polar(Ipi/2), exp_polar(-Ipi/2)] expr = expr.replace( besselj, replacer(besselj, torewrite(besselj, besseli), ifactors)) expr = expr.replace( besseli, replacer(besseli, torewrite(besseli, besselj), ifactors)) minusfactors = [-1, exp_polar(Ipi)] expr = expr.replace( besselj, replacer(besselj, tominus(besselj), minusfactors)) expr = expr.replace( besseli, replacer(besseli, tominus(besseli), minusfactors)) z0 = Dummy('z') def expander(fro): def repl(nu, z): if (nu % 1) == S(1)/2: return simplify(trigsimp(unpolarify( fro(nu, z0).rewrite(besselj).rewrite(jn).expand( func=True)).subs(z0, z))) elif nu.is_Integer and nu > 1: return fro(nu, z).expand(func=True) return fro(nu, z) return repl expr = expr.replace(besselj, expander(besselj)) expr = expr.replace(bessely, expander(bessely)) expr = expr.replace(besseli, expander(besseli)) expr = expr.replace(besselk, expander(besselk)) if expr != orig_expr: expr = expr.factor() return expr def nthroot(expr, n, max_len=4, prec=15): """ compute a real nth-root of a sum of surds Parameters ========== expr : sum of surds n : integer max_len : maximum number of surds passed as constants to ``nsimplify`` Algorithm ========= First ``nsimplify`` is used to get a candidate root; if it is not a root the minimal polynomial is computed; the answer is one of its roots. Examples ======== >>> from sympy.simplify.simplify import nthroot >>> from sympy import Rational, sqrt >>> nthroot(90 + 34sqrt(7), 3) sqrt(7) + 3 """ expr = sympify(expr) n = sympify(n) p = exprRational(1, n) if not n.is_integer: return p if not _is_sum_surds(expr): return p surds = [] coeff_muls = [x.as_coeff_Mul() for x in expr.args] for x, y in coeff_muls: if not x.is_rational: return p if y is S.One: continue if not (y.is_Pow and y.exp == S.Half and y.base.is_integer): return p surds.append(y) surds.sort() surds = surds[:max_len] if expr < 0 and n % 2 == 1: p = (-expr)Rational(1, n) a = nsimplify(p, constants=surds) res = a if _mexpand(an) == _mexpand(-expr) else p return -res a = nsimplify(p, constants=surds) if _mexpand(a) is not _mexpand(p) and _mexpand(an) == _mexpand(expr): return _mexpand(a) expr = _nthroot_solve(expr, n, prec) if expr is None: return p return expr def nsimplify(expr, constants=(), tolerance=None, full=False, rational=None, rational_conversion='base10'): """ Find a simple representation for a number or, if there are free symbols or if rational=True, then replace Floats with their Rational equivalents. If no change is made and rational is not False then Floats will at least be converted to Rationals. For numerical expressions, a simple formula that numerically matches the given numerical expression is sought (and the input should be possible to evalf to a precision of at least 30 digits). Optionally, a list of (rationally independent) constants to include in the formula may be given. A lower tolerance may be set to find less exact matches. If no tolerance is given then the least precise value will set the tolerance (e.g. Floats default to 15 digits of precision, so would be tolerance=10-15). With full=True, a more extensive search is performed (this is useful to find simpler numbers when the tolerance is set low). When converting to rational, if rational_conversion='base10' (the default), then convert floats to rationals using their base-10 (string) representation. When rational_conversion='exact' it uses the exact, base-2 representation. Examples ======== >>> from sympy import nsimplify, sqrt, GoldenRatio, exp, I, exp, pi >>> nsimplify(4/(1+sqrt(5)), [GoldenRatio]) -2 + 2GoldenRatio >>> nsimplify((1/(exp(3piI/5)+1))) 1/2 - Isqrt(sqrt(5)/10 + 1/4) >>> nsimplify(II, [pi]) exp(-pi/2) >>> nsimplify(pi, tolerance=0.01) 22/7 >>> nsimplify(0.333333333333333, rational=True, rational_conversion='exact') 6004799503160655/18014398509481984 >>> nsimplify(0.333333333333333, rational=True) 1/3 See Also ======== sympy.core.function.nfloat """ try: return sympify(as_int(expr)) except (TypeError, ValueError): pass expr = sympify(expr).xreplace({ Float('inf'): S.Infinity, Float('-inf'): S.NegativeInfinity, }) if expr is S.Infinity or expr is S.NegativeInfinity: return expr if rational or expr.free_symbols: return _real_to_rational(expr, tolerance, rational_conversion) # SymPy's default tolerance for Rationals is 15; other numbers may have # lower tolerances set, so use them to pick the largest tolerance if None # was given if tolerance is None: tolerance = 10-min([15] + [mpmath.libmp.libmpf.prec_to_dps(n._prec) for n in expr.atoms(Float)]) # XXX should prec be set independent of tolerance or should it be computed # from tolerance? prec = 30 bprec = int(prec3.33) constants_dict = {} for constant in constants: constant = sympify(constant) v = constant.evalf(prec) if not v.is_Float: raise ValueError("constants must be real-valued") constants_dict[str(constant)] = v._to_mpmath(bprec) exprval = expr.evalf(prec, chop=True) re, im = exprval.as_real_imag() # safety check to make sure that this evaluated to a number if not (re.is_Number and im.is_Number): return expr def nsimplify_real(x): orig = mpmath.mp.dps xv = x._to_mpmath(bprec) try: # We'll be happy with low precision if a simple fraction if not (tolerance or full): mpmath.mp.dps = 15 rat = mpmath.pslq([xv, 1]) if rat is not None: return Rational(-int(rat[1]), int(rat[0])) mpmath.mp.dps = prec newexpr = mpmath.identify(xv, constants=constants_dict, tol=tolerance, full=full) if not newexpr: raise ValueError if full: newexpr = newexpr[0] expr = sympify(newexpr) if x and not expr: # don't let x become 0 raise ValueError if expr.is_finite is False and not xv in [mpmath.inf, mpmath.ninf]: raise ValueError return expr finally: # even though there are returns above, this is executed # before leaving mpmath.mp.dps = orig try: if re: re = nsimplify_real(re) if im: im = nsimplify_real(im) except ValueError: if rational is None: return _real_to_rational(expr, rational_conversion=rational_conversion) return expr rv = re + imS.ImaginaryUnit # if there was a change or rational is explicitly not wanted # return the value, else return the Rational representation if rv != expr or rational is False: return rv return _real_to_rational(expr, rational_conversion=rational_conversion) def _real_to_rational(expr, tolerance=None, rational_conversion='base10'): """ Replace all reals in expr with rationals. Examples ======== >>> from sympy import Rational >>> from sympy.simplify.simplify import _real_to_rational >>> from sympy.abc import x >>> _real_to_rational(.76 + .1x*.5) sqrt(x)/10 + 19/25 If rational_conversion='base10', this uses the base-10 string. If rational_conversion='exact', the exact, base-2 representation is used. >>> _real_to_rational(0.333333333333333, rational_conversion='exact') 6004799503160655/18014398509481984 >>> _real_to_rational(0.333333333333333) 1/3 """ expr = _sympify(expr) inf = Float('inf') p = expr reps = {} reduce_num = None if tolerance is not None and tolerance < 1: reduce_num = ceiling(1/tolerance) for fl in p.atoms(Float): key = fl if reduce_num is not None: r = Rational(fl).limit_denominator(reduce_num) elif (tolerance is not None and tolerance >= 1 and fl.is_Integer is False): r = Rational(toleranceround(fl/tolerance) ).limit_denominator(int(tolerance)) else: if rational_conversion == 'exact': r = Rational(fl) reps[key] = r continue elif rational_conversion != 'base10': raise ValueError("rational_conversion must be 'base10' or 'exact'") r = nsimplify(fl, rational=False) # e.g. log(3).n() -> log(3) instead of a Rational if fl and not r: r = Rational(fl) elif not r.is_Rational: if fl == inf or fl == -inf: r = S.ComplexInfinity elif fl < 0: fl = -fl d = Pow(10, int((mpmath.log(fl)/mpmath.log(10)))) r = -Rational(str(fl/d))d elif fl > 0: d = Pow(10, int((mpmath.log(fl)/mpmath.log(10)))) r = Rational(str(fl/d))d else: r = Integer(0) reps[key] = r return p.subs(reps, simultaneous=True) def clear_coefficients(expr, rhs=S.Zero): """Return `p, r` where `p` is the expression obtained when Rational additive and multiplicative coefficients of `expr` have been stripped away in a naive fashion (i.e. without simplification). The operations needed to remove the coefficients will be applied to `rhs` and returned as `r`. Examples ======== >>> from sympy.simplify.simplify import clear_coefficients >>> from sympy.abc import x, y >>> from sympy import Dummy >>> expr = 4y(6x + 3) >>> clear_coefficients(expr - 2) (y(2x + 1), 1/6) When solving 2 or more expressions like `expr = a`, `expr = b`, etc..., it is advantageous to provide a Dummy symbol for `rhs` and simply replace it with `a`, `b`, etc... in `r`. >>> rhs = Dummy('rhs') >>> clear_coefficients(expr, rhs) (y(2x + 1), _rhs/12) >>> _[1].subs(rhs, 2) 1/6 """ was = None free = expr.free_symbols if expr.is_Rational: return (S.Zero, rhs - expr) while expr and was != expr: was = expr m, expr = ( expr.as_content_primitive() if free else factor_terms(expr).as_coeff_Mul(rational=True)) rhs /= m c, expr = expr.as_coeff_Add(rational=True) rhs -= c expr = signsimp(expr, evaluate = False) if _coeff_isneg(expr): expr = -expr rhs = -rhs return expr, rhs def nc_simplify(expr, deep=True): ''' Simplify a non-commutative expression composed of multiplication and raising to a power by grouping repeated subterms into one power. Priority is given to simplifications that give the fewest number of arguments in the end (for example, in ababcabc simplifying to (ab)2cabc gives 5 arguments while ab(abc)2 has 3). If `expr` is a sum of such terms, the sum of the simplified terms is returned. Keyword argument `deep` controls whether or not subexpressions nested deeper inside the main expression are simplified. See examples below. Setting `deep` to `False` can save time on nested expressions that don't need simplifying on all levels. Examples ======== >>> from sympy import symbols >>> from sympy.simplify.simplify import nc_simplify >>> a, b, c = symbols("a b c", commutative=False) >>> nc_simplify(ababcabc) ab(abc)2 >>> expr = a2ba*4ba4 >>> nc_simplify(expr) a2(ba4)2 >>> nc_simplify(ababc2(ab)2c*2) ((ab)*2c2)2 >>> nc_simplify(abab + 2aca*2ca2ca) (ab)*2 + 2(aca)3 >>> nc_simplify(b-1a-1(ab)2) ab >>> nc_simplify(a*-1b*-1ca) (ba)*(-1)ca >>> expr = (abab)*2acac >>> nc_simplify(expr) (ab)*4(ac)2 >>> nc_simplify(expr, deep=False) (abab)*2(ac)2 ''' from sympy.matrices.expressions import (MatrixExpr, MatAdd, MatMul, MatPow, MatrixSymbol) from sympy.core.exprtools import factor_nc if isinstance(expr, MatrixExpr): expr = expr.doit(inv_expand=False) _Add, _Mul, _Pow, _Symbol = MatAdd, MatMul, MatPow, MatrixSymbol else: _Add, _Mul, _Pow, _Symbol = Add, Mul, Pow, Symbol # =========== Auxiliary functions ======================== def _overlaps(args): # Calculate a list of lists m such that m[i][j] contains the lengths # of all possible overlaps between args[:i+1] and args[i+1+j:]. # An overlap is a suffix of the prefix that matches a prefix # of the suffix. # For example, let expr=cabababab. Then m[3][0] contains # the lengths of overlaps of cabab with abab. The overlaps # are abab, ab and the empty word so that m[3][0]=[4,2,0]. # All overlaps rather than only the longest one are recorded # because this information helps calculate other overlap lengths. m = [[([1, 0] if a == args[0] else [0]) for a in args[1:]]] for i in range(1, len(args)): overlaps = [] j = 0 for j in range(len(args) - i - 1): overlap = [] for v in m[i-1][j+1]: if j + i + 1 + v < len(args) and args[i] == args[j+i+1+v]: overlap.append(v + 1) overlap += [0] overlaps.append(overlap) m.append(overlaps) return m def _reduce_inverses(_args): # replace consecutive negative powers by an inverse # of a product of positive powers, e.g. a*-1b*-1c # will simplify to (ab)-1c; # return that new args list and the number of negative # powers in it (inv_tot) inv_tot = 0 # total number of inverses inverses = [] args = [] for arg in _args: if isinstance(arg, _Pow) and arg.args[1] < 0: inverses = [arg-1] + inverses inv_tot += 1 else: if len(inverses) == 1: args.append(inverses[0]-1) elif len(inverses) > 1: args.append(_Pow(_Mul(inverses), -1)) inv_tot -= len(inverses) - 1 inverses = [] args.append(arg) if inverses: args.append(_Pow(_Mul(inverses), -1)) inv_tot -= len(inverses) - 1 return inv_tot, tuple(args) def get_score(s): # compute the number of arguments of s # (including in nested expressions) overall # but ignore exponents if isinstance(s, _Pow): return get_score(s.args[0]) elif isinstance(s, (_Add, _Mul)): return sum([get_score(a) for a in s.args]) return 1 def compare(s, alt_s): # compare two possible simplifications and return a # "better" one if s != alt_s and get_score(alt_s) < get_score(s): return alt_s return s # ======================================================== if not isinstance(expr, (_Add, _Mul, _Pow)) or expr.is_commutative: return expr args = expr.args[:] if isinstance(expr, _Pow): if deep: return _Pow(nc_simplify(args[0]), args[1]).doit() else: return expr elif isinstance(expr, _Add): return _Add([nc_simplify(a, deep=deep) for a in args]).doit() else: # get the non-commutative part c_args, args = expr.args_cnc() com_coeff = Mul(c_args) if com_coeff != 1: return com_coeffnc_simplify(expr/com_coeff, deep=deep) inv_tot, args = _reduce_inverses(args) # if most arguments are negative, work with the inverse # of the expression, e.g. a-1ba-1c*-1 will become # (cab-1a)*-1 at the end so can work with cab-1a invert = False if inv_tot > len(args)/2: invert = True args = [a*-1 for a in args[::-1]] if deep: args = tuple(nc_simplify(a) for a in args) m = _overlaps(args) # simps will be {subterm: end} where `end` is the ending # index of a sequence of repetitions of subterm; # this is for not wasting time with subterms that are part # of longer, already considered sequences simps = {} post = 1 pre = 1 # the simplification coefficient is the number of # arguments by which contracting a given sequence # would reduce the word; e.g. in ababcabc, # contracting abab to (ab)*2 removes 3 arguments # while abcabc to (abc)*2 removes 6. It's # better to contract the latter so simplification # with a maximum simplification coefficient will be chosen max_simp_coeff = 0 simp = None # information about future simplification for i in range(1, len(args)): simp_coeff = 0 l = 0 # length of a subterm p = 0 # the power of a subterm if i < len(args) - 1: rep = m[i][0] start = i # starting index of the repeated sequence end = i+1 # ending index of the repeated sequence if i == len(args)-1 or rep == [0]: # no subterm is repeated at this stage, at least as # far as the arguments are concerned - there may be # a repetition if powers are taken into account if (isinstance(args[i], _Pow) and not isinstance(args[i].args[0], _Symbol)): subterm = args[i].args[0].args l = len(subterm) if args[i-l:i] == subterm: # e.g. ab in ab(ab)2 is not repeated # in args (= [a, b, (ab)*2]) but it # can be matched here p += 1 start -= l if args[i+1:i+1+l] == subterm: # e.g. ab in (ab)2ab p += 1 end += l if p: p += args[i].args[1] else: continue else: l = rep[0] # length of the longest repeated subterm at this point start -= l - 1 subterm = args[start:end] p = 2 end += l if subterm in simps and simps[subterm] >= start: # the subterm is part of a sequence that # has already been considered continue # count how many times it's repeated while end < len(args): if l in m[end-1][0]: p += 1 end += l elif isinstance(args[end], _Pow) and args[end].args[0].args == subterm: # for cases like abab(ab)*2ab p += args[end].args[1] end += 1 else: break # see if another match can be made, e.g. # for ba*2 in ba*2ba3 or ab in # a*2bab pre_exp = 0 pre_arg = 1 if start - l >= 0 and args[start-l+1:start] == subterm[1:]: if isinstance(subterm[0], _Pow): pre_arg = subterm[0].args[0] exp = subterm[0].args[1] else: pre_arg = subterm[0] exp = 1 if isinstance(args[start-l], _Pow) and args[start-l].args[0] == pre_arg: pre_exp = args[start-l].args[1] - exp start -= l p += 1 elif args[start-l] == pre_arg: pre_exp = 1 - exp start -= l p += 1 post_exp = 0 post_arg = 1 if end + l - 1 < len(args) and args[end:end+l-1] == subterm[:-1]: if isinstance(subterm[-1], _Pow): post_arg = subterm[-1].args[0] exp = subterm[-1].args[1] else: post_arg = subterm[-1] exp = 1 if isinstance(args[end+l-1], _Pow) and args[end+l-1].args[0] == post_arg: post_exp = args[end+l-1].args[1] - exp end += l p += 1 elif args[end+l-1] == post_arg: post_exp = 1 - exp end += l p += 1 # Consider aba*2ba2ba: # ba*2 is explicitly repeated, but note # that in this case aba is also repeated # so there are two possible simplifications: # a(ba2)3a*-1 or (aba)3 # The latter is obviously simpler. # But in aba2b*2a*2 the simplifications are # a(ba2)2 and (aba)3a in which case # it's better to stick with the shorter subterm if post_exp and exp % 2 == 0 and start > 0: exp = exp/2 _pre_exp = 1 _post_exp = 1 if isinstance(args[start-1], _Pow) and args[start-1].args[0] == post_arg: _post_exp = post_exp + exp _pre_exp = args[start-1].args[1] - exp elif args[start-1] == post_arg: _post_exp = post_exp + exp _pre_exp = 1 - exp if _pre_exp == 0 or _post_exp == 0: if not pre_exp: start -= 1 post_exp = _post_exp pre_exp = _pre_exp pre_arg = post_arg subterm = (post_argexp,) + subterm[:-1] + (post_argexp,) simp_coeff += end-start if post_exp: simp_coeff -= 1 if pre_exp: simp_coeff -= 1 simps[subterm] = end if simp_coeff > max_simp_coeff: max_simp_coeff = simp_coeff simp = (start, _Mul(subterm), p, end, l) pre = pre_argpre_exp post = post_argpost_exp if simp: subterm = _Pow(nc_simplify(simp[1], deep=deep), simp[2]) pre = nc_simplify(_Mul(args[:simp[0]])pre, deep=deep) post = postnc_simplify(_Mul(args[simp[3]:]), deep=deep) simp = presubtermpost if pre != 1 or post != 1: # new simplifications may be possible but no need # to recurse over arguments simp = nc_simplify(simp, deep=False) else: simp = _Mul(args) if invert: simp = _Pow(simp, -1) # see if factor_nc(expr) is simplified better if not isinstance(expr, MatrixExpr): f_expr = factor_nc(expr) if f_expr != expr: alt_simp = nc_simplify(f_expr, deep=deep) simp = compare(simp, alt_simp) else: simp = simp.doit(inv_expand=False) return simp
8403ddb547b404cf3814f307315c376ee2301170f5d325440fb3ca7f9d74f305	import bisect import itertools from functools import reduce from collections import defaultdict from sympy import Indexed, IndexedBase, Tuple, Sum, Add, S, Integer, diagonalize_vector, DiagonalizeVector from sympy.combinatorics import Permutation from sympy.core.basic import Basic from sympy.core.compatibility import accumulate, default_sort_key from sympy.core.mul import Mul from sympy.core.sympify import _sympify from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.matrices.expressions import (MatAdd, MatMul, Trace, Transpose, MatrixSymbol) from sympy.matrices.expressions.matexpr import MatrixExpr, MatrixElement from sympy.tensor.array import NDimArray class _CodegenArrayAbstract(Basic): @property def subranks(self): """ Returns the ranks of the objects in the uppermost tensor product inside the current object. In case no tensor products are contained, return the atomic ranks. Examples ======== >>> from sympy.codegen.array_utils import CodegenArrayTensorProduct, CodegenArrayContraction >>> from sympy import MatrixSymbol >>> M = MatrixSymbol("M", 3, 3) >>> N = MatrixSymbol("N", 3, 3) >>> P = MatrixSymbol("P", 3, 3) Important: do not confuse the rank of the matrix with the rank of an array. >>> tp = CodegenArrayTensorProduct(M, N, P) >>> tp.subranks [2, 2, 2] >>> co = CodegenArrayContraction(tp, (1, 2), (3, 4)) >>> co.subranks [2, 2, 2] """ return self._subranks[:] def subrank(self): """ The sum of ``subranks``. """ return sum(self.subranks) @property def shape(self): return self._shape class CodegenArrayContraction(_CodegenArrayAbstract): r""" This class is meant to represent contractions of arrays in a form easily processable by the code printers. """ def __new__(cls, expr, contraction_indices, kwargs): contraction_indices = _sort_contraction_indices(contraction_indices) expr = _sympify(expr) if len(contraction_indices) == 0: return expr if isinstance(expr, CodegenArrayContraction): return cls._flatten(expr, contraction_indices) obj = Basic.__new__(cls, expr, contraction_indices) obj._subranks = _get_subranks(expr) obj._mapping = _get_mapping_from_subranks(obj._subranks) free_indices_to_position = {i: i for i in range(sum(obj._subranks)) if all([i not in cind for cind in contraction_indices])} obj._free_indices_to_position = free_indices_to_position shape = expr.shape cls._validate(expr, contraction_indices) if shape: shape = tuple(shp for i, shp in enumerate(shape) if not any(i in j for j in contraction_indices)) obj._shape = shape return obj @staticmethod def _validate(expr, contraction_indices): shape = expr.shape if shape is None: return # Check that no contraction happens when the shape is mismatched: for i in contraction_indices: if len(set(shape[j] for j in i if shape[j] != -1)) != 1: raise ValueError("contracting indices of different dimensions") @classmethod def _push_indices_down(cls, contraction_indices, indices): flattened_contraction_indices = [j for i in contraction_indices for j in i] flattened_contraction_indices.sort() transform = _build_push_indices_down_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) @classmethod def _push_indices_up(cls, contraction_indices, indices): flattened_contraction_indices = [j for i in contraction_indices for j in i] flattened_contraction_indices.sort() transform = _build_push_indices_up_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) def split_multiple_contractions(self): """ Recognize multiple contractions and attempt at rewriting them as paired-contractions. """ from sympy import ask, Q contraction_indices = self.contraction_indices if isinstance(self.expr, CodegenArrayTensorProduct): args = list(self.expr.args) else: args = [self.expr] # TODO: unify API, best location in CodegenArrayTensorProduct subranks = [get_rank(i) for i in args] # TODO: unify API mapping = _get_mapping_from_subranks(subranks) reverse_mapping = {v:k for k, v in mapping.items()} new_contraction_indices = [] for indl, links in enumerate(contraction_indices): if len(links) <= 2: new_contraction_indices.append(links) continue # Check multiple contractions: # # Examples: # # `A_ij b_j0 C_jk` ===> `ADiagonalizeVector(b)C` # # Care for: # - matrix being diagonalized (i.e. `A_ii`) # - vectors being diagonalized (i.e. `a_i0`) # Also consider the case of diagonal matrices being contracted: current_dimension = self.expr.shape[links[0]] tuple_links = [mapping[i] for i in links] arg_indices, arg_positions = zip(tuple_links) args_updates = {} if len(arg_indices) != len(set(arg_indices)): # Maybe trace should be supported? raise NotImplementedError not_vectors = [] vectors = [] for arg_ind, arg_pos in tuple_links: mat = args[arg_ind] other_arg_pos = 1-arg_pos other_arg_abs = reverse_mapping[arg_ind, other_arg_pos] if (((1 not in mat.shape) and (not ask(Q.diagonal(mat)))) or ((current_dimension == 1) is True and mat.shape != (1, 1)) or any([other_arg_abs in l for li, l in enumerate(contraction_indices) if li != indl]) ): not_vectors.append((arg_ind, arg_pos)) continue args_updates[arg_ind] = diagonalize_vector(mat) vectors.append((arg_ind, arg_pos)) vectors.append((arg_ind, 1-arg_pos)) if len(not_vectors) > 2: new_contraction_indices.append(links) continue if len(not_vectors) == 0: new_sequence = vectors[:1] + vectors[2:] elif len(not_vectors) == 1: new_sequence = not_vectors[:1] + vectors[:-1] else: new_sequence = not_vectors[:1] + vectors + not_vectors[1:] for i in range(0, len(new_sequence) - 1, 2): arg1, pos1 = new_sequence[i] arg2, pos2 = new_sequence[i+1] if arg1 == arg2: raise NotImplementedError continue abspos1 = reverse_mapping[arg1, pos1] abspos2 = reverse_mapping[arg2, pos2] new_contraction_indices.append((abspos1, abspos2)) for ind, newarg in args_updates.items(): args[ind] = newarg return CodegenArrayContraction( CodegenArrayTensorProduct(args), new_contraction_indices ) def flatten_contraction_of_diagonal(self): if not isinstance(self.expr, CodegenArrayDiagonal): return self contraction_down = self.expr._push_indices_down(self.expr.diagonal_indices, self.contraction_indices) new_contraction_indices = [] diagonal_indices = self.expr.diagonal_indices[:] for i in contraction_down: contraction_group = list(i) for j in i: diagonal_with = [k for k in diagonal_indices if j in k] contraction_group.extend([l for k in diagonal_with for l in k]) diagonal_indices = [k for k in diagonal_indices if k not in diagonal_with] new_contraction_indices.append(sorted(set(contraction_group))) new_contraction_indices = CodegenArrayDiagonal._push_indices_up(diagonal_indices, new_contraction_indices) return CodegenArrayContraction( CodegenArrayDiagonal( self.expr.expr, diagonal_indices ), new_contraction_indices ) @staticmethod def _get_free_indices_to_position_map(free_indices, contraction_indices): free_indices_to_position = {} flattened_contraction_indices = [j for i in contraction_indices for j in i] counter = 0 for ind in free_indices: while counter in flattened_contraction_indices: counter += 1 free_indices_to_position[ind] = counter counter += 1 return free_indices_to_position @staticmethod def _get_index_shifts(expr): """ Get the mapping of indices at the positions before the contraction occures. Examples ======== >>> from sympy.codegen.array_utils import CodegenArrayContraction, CodegenArrayTensorProduct >>> from sympy import MatrixSymbol >>> M = MatrixSymbol("M", 3, 3) >>> N = MatrixSymbol("N", 3, 3) >>> cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), [1, 2]) >>> cg._get_index_shifts(cg) [0, 2] Indeed, ``cg`` after the contraction has two dimensions, 0 and 1. They need to be shifted by 0 and 2 to get the corresponding positions before the contraction (that is, 0 and 3). """ inner_contraction_indices = expr.contraction_indices all_inner = [j for i in inner_contraction_indices for j in i] all_inner.sort() # TODO: add API for total rank and cumulative rank: total_rank = get_rank(expr) inner_rank = len(all_inner) outer_rank = total_rank - inner_rank shifts = [0 for i in range(outer_rank)] counter = 0 pointer = 0 for i in range(outer_rank): while pointer < inner_rank and counter >= all_inner[pointer]: counter += 1 pointer += 1 shifts[i] += pointer counter += 1 return shifts @staticmethod def _convert_outer_indices_to_inner_indices(expr, outer_contraction_indices): shifts = CodegenArrayContraction._get_index_shifts(expr) outer_contraction_indices = tuple(tuple(shifts[j] + j for j in i) for i in outer_contraction_indices) return outer_contraction_indices @staticmethod def _flatten(expr, outer_contraction_indices): inner_contraction_indices = expr.contraction_indices outer_contraction_indices = CodegenArrayContraction._convert_outer_indices_to_inner_indices(expr, outer_contraction_indices) contraction_indices = inner_contraction_indices + outer_contraction_indices return CodegenArrayContraction(expr.expr, contraction_indices) def _get_contraction_tuples(self): r""" Return tuples containing the argument index and position within the argument of the index position. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction, CodegenArrayTensorProduct >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (1, 2)) >>> cg._get_contraction_tuples() [[(0, 1), (1, 0)]] Here the contraction pair `(1, 2)` meaning that the 2nd and 3rd indices of the tensor product `A\otimes B` are contracted, has been transformed into `(0, 1)` and `(1, 0)`, identifying the same indices in a different notation. `(0, 1)` is the second index (1) of the first argument (i.e. 0 or `A`). `(1, 0)` is the first index (i.e. 0) of the second argument (i.e. 1 or `B`). """ mapping = self._mapping return [[mapping[j] for j in i] for i in self.contraction_indices] @staticmethod def _contraction_tuples_to_contraction_indices(expr, contraction_tuples): # TODO: check that `expr` has `.subranks`: ranks = expr.subranks cumulative_ranks = [0] + list(accumulate(ranks)) return [tuple(cumulative_ranks[j]+k for j, k in i) for i in contraction_tuples] @property def free_indices(self): return self._free_indices[:] @property def free_indices_to_position(self): return dict(self._free_indices_to_position) @property def expr(self): return self.args[0] @property def contraction_indices(self): return self.args[1:] def _contraction_indices_to_components(self): expr = self.expr if not isinstance(expr, CodegenArrayTensorProduct): raise NotImplementedError("only for contractions of tensor products") ranks = expr.subranks mapping = {} counter = 0 for i, rank in enumerate(ranks): for j in range(rank): mapping[counter] = (i, j) counter += 1 return mapping def sort_args_by_name(self): """ Sort arguments in the tensor product so that their order is lexicographical. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> C = MatrixSymbol("C", N, N) >>> D = MatrixSymbol("D", N, N) >>> cg = CodegenArrayContraction.from_MatMul(CDAB) >>> cg CodegenArrayContraction(CodegenArrayTensorProduct(C, D, A, B), (1, 2), (3, 4), (5, 6)) >>> cg.sort_args_by_name() CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C, D), (0, 7), (1, 2), (5, 6)) """ expr = self.expr if not isinstance(expr, CodegenArrayTensorProduct): return self args = expr.args sorted_data = sorted(enumerate(args), key=lambda x: default_sort_key(x[1])) pos_sorted, args_sorted = zip(sorted_data) reordering_map = {i: pos_sorted.index(i) for i, arg in enumerate(args)} contraction_tuples = self._get_contraction_tuples() contraction_tuples = [[(reordering_map[j], k) for j, k in i] for i in contraction_tuples] c_tp = CodegenArrayTensorProduct(args_sorted) new_contr_indices = self._contraction_tuples_to_contraction_indices( c_tp, contraction_tuples ) return CodegenArrayContraction(c_tp, new_contr_indices) def _get_contraction_links(self): r""" Returns a dictionary of links between arguments in the tensor product being contracted. See the example for an explanation of the values. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> C = MatrixSymbol("C", N, N) >>> D = MatrixSymbol("D", N, N) Matrix multiplications are pairwise contractions between neighboring matrices: `A_{ij} B_{jk} C_{kl} D_{lm}` >>> cg = CodegenArrayContraction.from_MatMul(ABCD) >>> cg CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C, D), (1, 2), (3, 4), (5, 6)) >>> cg._get_contraction_links() {0: {1: (1, 0)}, 1: {0: (0, 1), 1: (2, 0)}, 2: {0: (1, 1), 1: (3, 0)}, 3: {0: (2, 1)}} This dictionary is interpreted as follows: argument in position 0 (i.e. matrix `A`) has its second index (i.e. 1) contracted to `(1, 0)`, that is argument in position 1 (matrix `B`) on the first index slot of `B`, this is the contraction provided by the index `j` from `A`. The argument in position 1 (that is, matrix `B`) has two contractions, the ones provided by the indices `j` and `k`, respectively the first and second indices (0 and 1 in the sub-dict). The link `(0, 1)` and `(2, 0)` respectively. `(0, 1)` is the index slot 1 (the 2nd) of argument in position 0 (that is, `A_{\ldot j}`), and so on. """ args, dlinks = _get_contraction_links([self], self.subranks, self.contraction_indices) return dlinks @staticmethod def from_MatMul(expr): args_nonmat = [] args = [] contractions = [] for arg in expr.args: if isinstance(arg, MatrixExpr): args.append(arg) else: args_nonmat.append(arg) contractions = [(2i+1, 2i+2) for i in range(len(args)-1)] return Mul.fromiter(args_nonmat)CodegenArrayContraction( CodegenArrayTensorProduct(args), contractions ) def get_shape(expr): if hasattr(expr, "shape"): return expr.shape return () class CodegenArrayTensorProduct(_CodegenArrayAbstract): r""" Class to represent the tensor product of array-like objects. """ def __new__(cls, args): args = [_sympify(arg) for arg in args] args = cls._flatten(args) ranks = [get_rank(arg) for arg in args] if len(args) == 1: return args[0] # If there are contraction objects inside, transform the whole # expression into `CodegenArrayContraction`: contractions = {i: arg for i, arg in enumerate(args) if isinstance(arg, CodegenArrayContraction)} if contractions: cumulative_ranks = list(accumulate([0] + ranks))[:-1] tp = cls([arg.expr if isinstance(arg, CodegenArrayContraction) else arg for arg in args]) contraction_indices = [tuple(cumulative_ranks[i] + k for k in j) for i, arg in contractions.items() for j in arg.contraction_indices] return CodegenArrayContraction(tp, contraction_indices) #newargs = [i for i in args if hasattr(i, "shape")] #coeff = reduce(lambda x, y: xy, [i for i in args if not hasattr(i, "shape")], S.One) #newargs[0] = coeff obj = Basic.__new__(cls, args) obj._subranks = ranks shapes = [get_shape(i) for i in args] if any(i is None for i in shapes): obj._shape = None else: obj._shape = tuple(j for i in shapes for j in i) return obj @classmethod def _flatten(cls, args): args = [i for arg in args for i in (arg.args if isinstance(arg, cls) else [arg])] return args class CodegenArrayElementwiseAdd(_CodegenArrayAbstract): r""" Class for elementwise array additions. """ def __new__(cls, args): args = [_sympify(arg) for arg in args] obj = Basic.__new__(cls, args) ranks = [get_rank(arg) for arg in args] ranks = list(set(ranks)) if len(ranks) != 1: raise ValueError("summing arrays of different ranks") obj._subranks = ranks shapes = [arg.shape for arg in args] if len(set([i for i in shapes if i is not None])) > 1: raise ValueError("mismatching shapes in addition") if any(i is None for i in shapes): obj._shape = None else: obj._shape = shapes[0] return obj class CodegenArrayPermuteDims(_CodegenArrayAbstract): r""" Class to represent permutation of axes of arrays. Examples ======== >>> from sympy.codegen.array_utils import CodegenArrayPermuteDims >>> from sympy import MatrixSymbol >>> M = MatrixSymbol("M", 3, 3) >>> cg = CodegenArrayPermuteDims(M, [1, 0]) The object ``cg`` represents the transposition of ``M``, as the permutation ``[1, 0]`` will act on its indices by switching them: `M_{ij} \Rightarrow M_{ji}` This is evident when transforming back to matrix form: >>> from sympy.codegen.array_utils import recognize_matrix_expression >>> recognize_matrix_expression(cg) M.T >>> N = MatrixSymbol("N", 3, 2) >>> cg = CodegenArrayPermuteDims(N, [1, 0]) >>> cg.shape (2, 3) """ def __new__(cls, expr, permutation): from sympy.combinatorics import Permutation expr = _sympify(expr) permutation = Permutation(permutation) plist = permutation.args[0] if plist == sorted(plist): return expr obj = Basic.__new__(cls, expr, permutation) obj._subranks = [get_rank(expr)] shape = expr.shape if shape is None: obj._shape = None else: obj._shape = tuple(shape[permutation(i)] for i in range(len(shape))) return obj @property def expr(self): return self.args[0] @property def permutation(self): return self.args[1] def nest_permutation(self): r""" Nest the permutation down the expression tree. Examples ======== >>> from sympy.codegen.array_utils import (CodegenArrayPermuteDims, CodegenArrayTensorProduct, nest_permutation) >>> from sympy import MatrixSymbol >>> from sympy.combinatorics import Permutation >>> Permutation.print_cyclic = True >>> M = MatrixSymbol("M", 3, 3) >>> N = MatrixSymbol("N", 3, 3) >>> cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [1, 0, 3, 2]) >>> cg CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), (0 1)(2 3)) >>> nest_permutation(cg) CodegenArrayTensorProduct(CodegenArrayPermuteDims(M, (0 1)), CodegenArrayPermuteDims(N, (0 1))) In ``cg`` both ``M`` and ``N`` are transposed. The cyclic representation of the permutation after the tensor product is `(0 1)(2 3)`. After nesting it down the expression tree, the usual transposition permutation `(0 1)` appears. """ expr = self.expr if isinstance(expr, CodegenArrayTensorProduct): # Check if the permutation keeps the subranks separated: subranks = expr.subranks subrank = expr.subrank() l = list(range(subrank)) p = [self.permutation(i) for i in l] dargs = {} counter = 0 for i, arg in zip(subranks, expr.args): p0 = p[counter:counter+i] counter += i s0 = sorted(p0) if not all([s0[j+1]-s0[j] == 1 for j in range(len(s0)-1)]): # Cross-argument permutations, impossible to nest the object: return self subpermutation = [p0.index(j) for j in s0] dargs[s0[0]] = CodegenArrayPermuteDims(arg, subpermutation) # Read the arguments sorting the according to the keys of the dict: args = [dargs[i] for i in sorted(dargs)] return CodegenArrayTensorProduct(args) elif isinstance(expr, CodegenArrayContraction): # Invert tree hierarchy: put the contraction above. cycles = self.permutation.cyclic_form newcycles = CodegenArrayContraction._convert_outer_indices_to_inner_indices(expr, cycles) newpermutation = Permutation(newcycles) new_contr_indices = [tuple(newpermutation(j) for j in i) for i in expr.contraction_indices] return CodegenArrayContraction(CodegenArrayPermuteDims(expr.expr, newpermutation), new_contr_indices) elif isinstance(expr, CodegenArrayElementwiseAdd): return CodegenArrayElementwiseAdd([CodegenArrayPermuteDims(arg, self.permutation) for arg in expr.args]) return self def nest_permutation(expr): if isinstance(expr, CodegenArrayPermuteDims): return expr.nest_permutation() else: return expr class CodegenArrayDiagonal(_CodegenArrayAbstract): r""" Class to represent the diagonal operator. In a 2-dimensional array it returns the diagonal, this looks like the operation: `A_{ij} \rightarrow A_{ii}` The diagonal over axes 1 and 2 (the second and third) of the tensor product of two 2-dimensional arrays `A \otimes B` is `\Big[ A_{ab} B_{cd} \Big]_{abcd} \rightarrow \Big[ A_{ai} B_{id} \Big]_{adi}` In this last example the array expression has been reduced from 4-dimensional to 3-dimensional. Notice that no contraction has occurred, rather there is a new index `i` for the diagonal, contraction would have reduced the array to 2 dimensions. Notice that the diagonalized out dimensions are added as new dimensions at the end of the indices. """ def __new__(cls, expr, diagonal_indices): expr = _sympify(expr) diagonal_indices = [Tuple(sorted(i)) for i in diagonal_indices] if isinstance(expr, CodegenArrayDiagonal): return cls._flatten(expr, diagonal_indices) shape = expr.shape if shape is not None: diagonal_indices = [i for i in diagonal_indices if len(i) > 1] cls._validate(expr, diagonal_indices) #diagonal_indices = cls._remove_trivial_dimensions(shape, diagonal_indices) # Get new shape: shp1 = tuple(shp for i,shp in enumerate(shape) if not any(i in j for j in diagonal_indices)) shp2 = tuple(shape[i[0]] for i in diagonal_indices) shape = shp1 + shp2 if len(diagonal_indices) == 0: return expr obj = Basic.__new__(cls, expr, diagonal_indices) obj._subranks = _get_subranks(expr) obj._shape = shape return obj @staticmethod def _validate(expr, diagonal_indices): # Check that no diagonalization happens on indices with mismatched # dimensions: shape = expr.shape for i in diagonal_indices: if len(set(shape[j] for j in i)) != 1: raise ValueError("diagonalizing indices of different dimensions") @staticmethod def _remove_trivial_dimensions(shape, diagonal_indices): return [tuple(j for j in i) for i in diagonal_indices if shape[i[0]] != 1] @property def expr(self): return self.args[0] @property def diagonal_indices(self): return self.args[1:] @staticmethod def _flatten(expr, outer_diagonal_indices): inner_diagonal_indices = expr.diagonal_indices all_inner = [j for i in inner_diagonal_indices for j in i] all_inner.sort() # TODO: add API for total rank and cumulative rank: total_rank = get_rank(expr) inner_rank = len(all_inner) outer_rank = total_rank - inner_rank shifts = [0 for i in range(outer_rank)] counter = 0 pointer = 0 for i in range(outer_rank): while pointer < inner_rank and counter >= all_inner[pointer]: counter += 1 pointer += 1 shifts[i] += pointer counter += 1 outer_diagonal_indices = tuple(tuple(shifts[j] + j for j in i) for i in outer_diagonal_indices) diagonal_indices = inner_diagonal_indices + outer_diagonal_indices return CodegenArrayDiagonal(expr.expr, diagonal_indices) @classmethod def _push_indices_down(cls, diagonal_indices, indices): flattened_contraction_indices = [j for i in diagonal_indices for j in i[1:]] flattened_contraction_indices.sort() transform = _build_push_indices_down_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) @classmethod def _push_indices_up(cls, diagonal_indices, indices): flattened_contraction_indices = [j for i in diagonal_indices for j in i[1:]] flattened_contraction_indices.sort() transform = _build_push_indices_up_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) def transform_to_product(self): from sympy import ask, Q diagonal_indices = self.diagonal_indices if isinstance(self.expr, CodegenArrayContraction): # invert Diagonal and Contraction: diagonal_down = CodegenArrayContraction._push_indices_down( self.expr.contraction_indices, diagonal_indices ) newexpr = CodegenArrayDiagonal( self.expr.expr, diagonal_down ).transform_to_product() contraction_up = newexpr._push_indices_up( diagonal_down, self.expr.contraction_indices ) return CodegenArrayContraction( newexpr, contraction_up ) if not isinstance(self.expr, CodegenArrayTensorProduct): return self args = list(self.expr.args) # TODO: unify API subranks = [get_rank(i) for i in args] # TODO: unify API mapping = _get_mapping_from_subranks(subranks) new_contraction_indices = [] drop_diagonal_indices = [] for indl, links in enumerate(diagonal_indices): if len(links) > 2: continue # Also consider the case of diagonal matrices being contracted: current_dimension = self.expr.shape[links[0]] if current_dimension == 1: drop_diagonal_indices.append(indl) continue tuple_links = [mapping[i] for i in links] arg_indices, arg_positions = zip(tuple_links) if len(arg_indices) != len(set(arg_indices)): # Maybe trace should be supported? raise NotImplementedError args_updates = {} count_nondiagonal = 0 last = None expression_is_square = False # Check that all args are vectors: for arg_ind, arg_pos in tuple_links: mat = args[arg_ind] if 1 in mat.shape and mat.shape != (1, 1): args_updates[arg_ind] = DiagonalizeVector(mat) last = arg_ind else: expression_is_square = True if not ask(Q.diagonal(mat)): count_nondiagonal += 1 if count_nondiagonal > 1: break if count_nondiagonal > 1: continue # TODO: if count_nondiagonal == 0 then the sub-expression can be recognized as HadamardProduct. for arg_ind, newmat in args_updates.items(): if not expression_is_square and arg_ind == last: continue #pass args[arg_ind] = newmat drop_diagonal_indices.append(indl) new_contraction_indices.append(links) new_diagonal_indices = CodegenArrayContraction._push_indices_up( new_contraction_indices, [e for i, e in enumerate(diagonal_indices) if i not in drop_diagonal_indices] ) return CodegenArrayDiagonal( CodegenArrayContraction( CodegenArrayTensorProduct(args), new_contraction_indices ), new_diagonal_indices ) def get_rank(expr): if isinstance(expr, (MatrixExpr, MatrixElement)): return 2 if isinstance(expr, _CodegenArrayAbstract): return expr.subrank() if isinstance(expr, NDimArray): return expr.rank() if isinstance(expr, Indexed): return expr.rank if isinstance(expr, IndexedBase): shape = expr.shape if shape is None: return -1 else: return len(shape) if isinstance(expr, _RecognizeMatOp): return expr.rank() if isinstance(expr, _RecognizeMatMulLines): return expr.rank() return 0 def _get_subranks(expr): if isinstance(expr, _CodegenArrayAbstract): return expr.subranks else: return [get_rank(expr)] def _get_mapping_from_subranks(subranks): mapping = {} counter = 0 for i, rank in enumerate(subranks): for j in range(rank): mapping[counter] = (i, j) counter += 1 return mapping def _get_contraction_links(args, subranks, contraction_indices): mapping = _get_mapping_from_subranks(subranks) contraction_tuples = [[mapping[j] for j in i] for i in contraction_indices] dlinks = defaultdict(dict) for links in contraction_tuples: if len(links) == 2: (arg1, pos1), (arg2, pos2) = links dlinks[arg1][pos1] = (arg2, pos2) dlinks[arg2][pos2] = (arg1, pos1) continue return args, dict(dlinks) def _sort_contraction_indices(pairing_indices): pairing_indices = [Tuple(sorted(i)) for i in pairing_indices] pairing_indices.sort(key=lambda x: min(x)) return pairing_indices def _get_diagonal_indices(flattened_indices): axes_contraction = defaultdict(list) for i, ind in enumerate(flattened_indices): if isinstance(ind, (int, Integer)): # If the indices is a number, there can be no diagonal operation: continue axes_contraction[ind].append(i) axes_contraction = {k: v for k, v in axes_contraction.items() if len(v) > 1} # Put the diagonalized indices at the end: ret_indices = [i for i in flattened_indices if i not in axes_contraction] diag_indices = list(axes_contraction) diag_indices.sort(key=lambda x: flattened_indices.index(x)) diagonal_indices = [tuple(axes_contraction[i]) for i in diag_indices] ret_indices += diag_indices ret_indices = tuple(ret_indices) return diagonal_indices, ret_indices def _get_argindex(subindices, ind): for i, sind in enumerate(subindices): if ind == sind: return i if isinstance(sind, (set, frozenset)) and ind in sind: return i raise IndexError("%s not found in %s" % (ind, subindices)) def _codegen_array_parse(expr): if isinstance(expr, Sum): function = expr.function summation_indices = expr.variables subexpr, subindices = _codegen_array_parse(function) # Check dimensional consistency: shape = subexpr.shape if shape: for ind, istart, iend in expr.limits: i = _get_argindex(subindices, ind) if istart != 0 or iend+1 != shape[i]: raise ValueError("summation index and array dimension mismatch: %s" % ind) contraction_indices = [] subindices = list(subindices) if isinstance(subexpr, CodegenArrayDiagonal): diagonal_indices = list(subexpr.diagonal_indices) dindices = subindices[-len(diagonal_indices):] subindices = subindices[:-len(diagonal_indices)] for index in summation_indices: if index in dindices: position = dindices.index(index) contraction_indices.append(diagonal_indices[position]) diagonal_indices[position] = None diagonal_indices = [i for i in diagonal_indices if i is not None] for i, ind in enumerate(subindices): if ind in summation_indices: pass if diagonal_indices: subexpr = CodegenArrayDiagonal(subexpr.expr, diagonal_indices) else: subexpr = subexpr.expr axes_contraction = defaultdict(list) for i, ind in enumerate(subindices): if ind in summation_indices: axes_contraction[ind].append(i) subindices[i] = None for k, v in axes_contraction.items(): contraction_indices.append(tuple(v)) free_indices = [i for i in subindices if i is not None] indices_ret = list(free_indices) indices_ret.sort(key=lambda x: free_indices.index(x)) return CodegenArrayContraction( subexpr, contraction_indices, free_indices=free_indices ), tuple(indices_ret) if isinstance(expr, Mul): args, indices = zip([_codegen_array_parse(arg) for arg in expr.args]) # Check if there are KroneckerDelta objects: kronecker_delta_repl = {} for arg in args: if not isinstance(arg, KroneckerDelta): continue # Diagonalize two indices: i, j = arg.indices kindices = set(arg.indices) if i in kronecker_delta_repl: kindices.update(kronecker_delta_repl[i]) if j in kronecker_delta_repl: kindices.update(kronecker_delta_repl[j]) kindices = frozenset(kindices) for index in kindices: kronecker_delta_repl[index] = kindices # Remove KroneckerDelta objects, their relations should be handled by # CodegenArrayDiagonal: newargs = [] newindices = [] for arg, loc_indices in zip(args, indices): if isinstance(arg, KroneckerDelta): continue newargs.append(arg) newindices.append(loc_indices) flattened_indices = [kronecker_delta_repl.get(j, j) for i in newindices for j in i] diagonal_indices, ret_indices = _get_diagonal_indices(flattened_indices) tp = CodegenArrayTensorProduct(newargs) if diagonal_indices: return (CodegenArrayDiagonal(tp, diagonal_indices), ret_indices) else: return tp, ret_indices if isinstance(expr, MatrixElement): indices = expr.args[1:] diagonal_indices, ret_indices = _get_diagonal_indices(indices) if diagonal_indices: return (CodegenArrayDiagonal(expr.args[0], diagonal_indices), ret_indices) else: return expr.args[0], ret_indices if isinstance(expr, Indexed): indices = expr.indices diagonal_indices, ret_indices = _get_diagonal_indices(indices) if diagonal_indices: return (CodegenArrayDiagonal(expr.base, diagonal_indices), ret_indices) else: return expr.args[0], ret_indices if isinstance(expr, IndexedBase): raise NotImplementedError if isinstance(expr, KroneckerDelta): return expr, expr.indices if isinstance(expr, Add): args, indices = zip([_codegen_array_parse(arg) for arg in expr.args]) args = list(args) # Check if all indices are compatible. Otherwise expand the dimensions: index0set = set(indices[0]) index0 = indices[0] for i in range(1, len(args)): if set(indices[i]) != index0set: raise NotImplementedError("indices must be the same") permutation = Permutation([index0.index(j) for j in indices[i]]) # Perform index permutations: args[i] = CodegenArrayPermuteDims(args[i], permutation) return CodegenArrayElementwiseAdd(args), index0 return expr, () raise NotImplementedError("could not recognize expression %s" % expr) def _parse_matrix_expression(expr): if isinstance(expr, MatMul): args_nonmat = [] args = [] contractions = [] for arg in expr.args: if isinstance(arg, MatrixExpr): args.append(arg) else: args_nonmat.append(arg) contractions = [(2i+1, 2i+2) for i in range(len(args)-1)] return Mul.fromiter(args_nonmat)CodegenArrayContraction( CodegenArrayTensorProduct([_parse_matrix_expression(arg) for arg in args]), contractions ) elif isinstance(expr, MatAdd): return CodegenArrayElementwiseAdd( [_parse_matrix_expression(arg) for arg in expr.args] ) elif isinstance(expr, Transpose): return CodegenArrayPermuteDims( _parse_matrix_expression(expr.args[0]), [1, 0] ) else: return expr def parse_indexed_expression(expr, first_indices=None): r""" Parse indexed expression into a form useful for code generation. Examples ======== >>> from sympy.codegen.array_utils import parse_indexed_expression >>> from sympy import MatrixSymbol, Sum, symbols >>> from sympy.combinatorics import Permutation >>> Permutation.print_cyclic = True >>> i, j, k, d = symbols("i j k d") >>> M = MatrixSymbol("M", d, d) >>> N = MatrixSymbol("N", d, d) Recognize the trace in summation form: >>> expr = Sum(M[i, i], (i, 0, d-1)) >>> parse_indexed_expression(expr) CodegenArrayContraction(M, (0, 1)) Recognize the extraction of the diagonal by using the same index `i` on both axes of the matrix: >>> expr = M[i, i] >>> parse_indexed_expression(expr) CodegenArrayDiagonal(M, (0, 1)) This function can help perform the transformation expressed in two different mathematical notations as: `\sum_{j=0}^{N-1} A_{i,j} B_{j,k} \Longrightarrow \mathbf{A}\cdot \mathbf{B}` Recognize the matrix multiplication in summation form: >>> expr = Sum(M[i, j]N[j, k], (j, 0, d-1)) >>> parse_indexed_expression(expr) CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) Specify that ``k`` has to be the starting index: >>> parse_indexed_expression(expr, first_indices=[k]) CodegenArrayPermuteDims(CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)), (0 1)) """ result, indices = _codegen_array_parse(expr) if not first_indices: return result for i in first_indices: if i not in indices: first_indices.remove(i) #raise ValueError("index %s not found or not a free index" % i) first_indices.extend([i for i in indices if i not in first_indices]) permutation = [first_indices.index(i) for i in indices] return CodegenArrayPermuteDims(result, permutation) def _has_multiple_lines(expr): if isinstance(expr, _RecognizeMatMulLines): return True if isinstance(expr, _RecognizeMatOp): return expr.multiple_lines return False class _RecognizeMatOp(object): """ Class to help parsing matrix multiplication lines. """ def __init__(self, operator, args): self.operator = operator self.args = args if any(_has_multiple_lines(arg) for arg in args): multiple_lines = True else: multiple_lines = False self.multiple_lines = multiple_lines def rank(self): if self.operator == Trace: return 0 # TODO: check return 2 def __repr__(self): op = self.operator if op == MatMul: s = "" elif op == MatAdd: s = "+" else: s = op.__name__ return "_RecognizeMatOp(%s, %s)" % (s, repr(self.args)) return "_RecognizeMatOp(%s)" % (s.join(repr(i) for i in self.args)) def __eq__(self, other): if not isinstance(other, type(self)): return False if self.operator != other.operator: return False if self.args != other.args: return False return True def __iter__(self): return iter(self.args) class _RecognizeMatMulLines(list): """ This class handles multiple parsed multiplication lines. """ def __new__(cls, args): if len(args) == 1: return args[0] return list.__new__(cls, args) def rank(self): return reduce(lambda x, y: xy, [get_rank(i) for i in self], S.One) def __repr__(self): return "_RecognizeMatMulLines(%s)" % super(_RecognizeMatMulLines, self).__repr__() def _support_function_tp1_recognize(contraction_indices, args): if not isinstance(args, list): args = [args] subranks = [get_rank(i) for i in args] coeff = reduce(lambda x, y: xy, [arg for arg, srank in zip(args, subranks) if srank == 0], S.One) mapping = _get_mapping_from_subranks(subranks) reverse_mapping = {v:k for k, v in mapping.items()} args, dlinks = _get_contraction_links(args, subranks, contraction_indices) flatten_contractions = [j for i in contraction_indices for j in i] total_rank = sum(subranks) # TODO: turn `free_indices` into a list? free_indices = {i: i for i in range(total_rank) if i not in flatten_contractions} return_list = [] while dlinks: if free_indices: first_index, starting_argind = min(free_indices.items(), key=lambda x: x[1]) free_indices.pop(first_index) starting_argind, starting_pos = mapping[starting_argind] else: # Maybe a Trace first_index = None starting_argind = min(dlinks) starting_pos = 0 current_argind, current_pos = starting_argind, starting_pos matmul_args = [] last_index = None while True: elem = args[current_argind] if current_pos == 1: elem = _RecognizeMatOp(Transpose, [elem]) matmul_args.append(elem) other_pos = 1 - current_pos if current_argind not in dlinks: other_absolute = reverse_mapping[current_argind, other_pos] free_indices.pop(other_absolute, None) break link_dict = dlinks.pop(current_argind) if other_pos not in link_dict: if free_indices: last_index = [i for i, j in free_indices.items() if mapping[j] == (current_argind, other_pos)][0] else: last_index = None break if len(link_dict) > 2: raise NotImplementedError("not a matrix multiplication line") # Get the last element of `link_dict` as the next link. The last # element is the correct start for trace expressions: current_argind, current_pos = link_dict[other_pos] if current_argind == starting_argind: # This is a trace: if len(matmul_args) > 1: matmul_args = [_RecognizeMatOp(Trace, [_RecognizeMatOp(MatMul, matmul_args)])] elif args[current_argind].shape != (1, 1): matmul_args = [_RecognizeMatOp(Trace, matmul_args)] break dlinks.pop(starting_argind, None) free_indices.pop(last_index, None) return_list.append(_RecognizeMatOp(MatMul, matmul_args)) if coeff != 1: # Let's inject the coefficient: return_list[0].args.insert(0, coeff) return _RecognizeMatMulLines(return_list) def recognize_matrix_expression(expr): r""" Recognize matrix expressions in codegen objects. If more than one matrix multiplication line have been detected, return a list with the matrix expressions. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction, CodegenArrayTensorProduct >>> from sympy.codegen.array_utils import recognize_matrix_expression, parse_indexed_expression >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> C = MatrixSymbol("C", N, N) >>> D = MatrixSymbol("D", N, N) >>> expr = Sum(A[i, j]B[j, k], (j, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) AB >>> cg = parse_indexed_expression(expr, first_indices=[k]) >>> recognize_matrix_expression(cg) (AB).T Transposition is detected: >>> expr = Sum(A[j, i]B[j, k], (j, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) A.TB >>> cg = parse_indexed_expression(expr, first_indices=[k]) >>> recognize_matrix_expression(cg) (A.TB).T Detect the trace: >>> expr = Sum(A[i, i], (i, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) Trace(A) Recognize some more complex traces: >>> expr = Sum(A[i, j]B[j, i], (i, 0, N-1), (j, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) Trace(AB) More complicated expressions: >>> expr = Sum(A[i, j]B[k, j]A[l, k], (j, 0, N-1), (k, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) AB.TA.T Expressions constructed from matrix expressions do not contain literal indices, the positions of free indices are returned instead: >>> expr = AB >>> cg = CodegenArrayContraction.from_MatMul(expr) >>> recognize_matrix_expression(cg) AB If more than one line of matrix multiplications is detected, return separate matrix multiplication factors: >>> cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C, D), (1, 2), (5, 6)) >>> recognize_matrix_expression(cg) [AB, CD] The two lines have free indices at axes 0, 3 and 4, 7, respectively. """ # TODO: expr has to be a CodegenArray... type rec = _recognize_matrix_expression(expr) return _unfold_recognized_expr(rec) def _recognize_matrix_expression(expr): if isinstance(expr, CodegenArrayContraction): # Apply some transformations: expr = expr.flatten_contraction_of_diagonal() expr = expr.split_multiple_contractions() args = _recognize_matrix_expression(expr.expr) contraction_indices = expr.contraction_indices if isinstance(args, _RecognizeMatOp) and args.operator == MatAdd: addends = [] for arg in args.args: addends.append(_support_function_tp1_recognize(contraction_indices, arg)) return _RecognizeMatOp(MatAdd, addends) elif isinstance(args, _RecognizeMatMulLines): return _support_function_tp1_recognize(contraction_indices, args) return _support_function_tp1_recognize(contraction_indices, [args]) elif isinstance(expr, CodegenArrayElementwiseAdd): add_args = [] for arg in expr.args: add_args.append(_recognize_matrix_expression(arg)) return _RecognizeMatOp(MatAdd, add_args) elif isinstance(expr, (MatrixSymbol, IndexedBase)): return expr elif isinstance(expr, CodegenArrayPermuteDims): if expr.permutation.args[0] == [1, 0]: return _RecognizeMatOp(Transpose, [_recognize_matrix_expression(expr.expr)]) elif isinstance(expr.expr, CodegenArrayTensorProduct): ranks = expr.expr.subranks newrange = [expr.permutation(i) for i in range(sum(ranks))] newpos = [] counter = 0 for rank in ranks: newpos.append(newrange[counter:counter+rank]) counter += rank newargs = [] for pos, arg in zip(newpos, expr.expr.args): if pos == sorted(pos): newargs.append((_recognize_matrix_expression(arg), pos[0])) elif len(pos) == 2: newargs.append((_RecognizeMatOp(Transpose, [_recognize_matrix_expression(arg)]), pos[0])) else: raise NotImplementedError newargs.sort(key=lambda x: x[1]) newargs = [i[0] for i in newargs] return _RecognizeMatMulLines(newargs) else: raise NotImplementedError elif isinstance(expr, CodegenArrayTensorProduct): args = [_recognize_matrix_expression(arg) for arg in expr.args] multiple_lines = [_has_multiple_lines(arg) for arg in args] if any(multiple_lines): if any(a.operator != MatAdd for i, a in enumerate(args) if multiple_lines[i] and isinstance(a, _RecognizeMatOp)): raise NotImplementedError getargs = lambda x: x.args if isinstance(x, _RecognizeMatOp) else list(x) expand_args = [getargs(arg) if multiple_lines[i] else [arg] for i, arg in enumerate(args)] it = itertools.product(expand_args) ret = _RecognizeMatOp(MatAdd, [_RecognizeMatMulLines([k for j in i for k in (j if isinstance(j, _RecognizeMatMulLines) else [j])]) for i in it]) return ret return _RecognizeMatMulLines(args) elif isinstance(expr, CodegenArrayDiagonal): pexpr = expr.transform_to_product() if expr == pexpr: return expr return _recognize_matrix_expression(pexpr) elif isinstance(expr, Transpose): return expr elif isinstance(expr, MatrixExpr): return expr return expr def _suppress_trivial_dims_in_tensor_product(mat_list): # Recognize expressions like [x, y] with shape (k, 1, k, 1) as `xy.T`. # The matrix expression has to be equivalent to the tensor product of the matrices, with trivial dimensions (i.e. dim=1) dropped. # That is, add contractions over trivial dimensions: mat_11 = [] mat_k1 = [] last_dim = mat_list[0].shape[0] for mat in mat_list: if mat.shape == (1, 1): mat_11.append(mat) elif 1 in mat.shape: if mat.shape[0] == 1: mat_k1.append(mat.T) else: mat_k1.append(mat) else: return mat_list if len(mat_k1) > 2: return mat_list a = MatMul.fromiter(mat_k1[:1]) b = MatMul.fromiter(mat_k1[1:]) x = MatMul.fromiter(mat_11) return axb.T def _unfold_recognized_expr(expr): if isinstance(expr, _RecognizeMatOp): return expr.operator([_unfold_recognized_expr(i) for i in expr.args]) elif isinstance(expr, _RecognizeMatMulLines): unfolded = [_unfold_recognized_expr(i) for i in expr] mat_list = [i for i in unfolded if isinstance(i, MatrixExpr)] scalar_list = [i for i in unfolded if i not in mat_list] scalar = Mul.fromiter(scalar_list) mat_list = [i.doit() for i in mat_list] mat_list = [i for i in mat_list if not (i.shape == (1, 1) and i.is_Identity)] if mat_list: mat_list[0] = scalar if len(mat_list) == 1: return mat_list[0].doit() else: return _suppress_trivial_dims_in_tensor_product(mat_list) else: return scalar else: return expr def _apply_recursively_over_nested_lists(func, arr): if isinstance(arr, (tuple, list, Tuple)): return tuple(_apply_recursively_over_nested_lists(func, i) for i in arr) elif isinstance(arr, Tuple): return Tuple.fromiter(_apply_recursively_over_nested_lists(func, i) for i in arr) else: return func(arr) def _build_push_indices_up_func_transformation(flattened_contraction_indices): shifts = {0: 0} i = 0 cumulative = 0 while i < len(flattened_contraction_indices): j = 1 while i+j < len(flattened_contraction_indices): if flattened_contraction_indices[i] + j != flattened_contraction_indices[i+j]: break j += 1 cumulative += j shifts[flattened_contraction_indices[i]] = cumulative i += j shift_keys = sorted(shifts.keys()) def func(idx): return shifts[shift_keys[bisect.bisect_right(shift_keys, idx)-1]] def transform(j): if j in flattened_contraction_indices: return None else: return j - func(j) return transform def _build_push_indices_down_func_transformation(flattened_contraction_indices): N = flattened_contraction_indices[-1]+2 shifts = [i for i in range(N) if i not in flattened_contraction_indices] def transform(j): if j < len(shifts): return shifts[j] else: return j + shifts[-1] - len(shifts) + 1 return transform
d29055cd0c82ef93ce704887573e6af53885421c4cfb7310d7b95c42715dd8aa	""" Classes and functions useful for rewriting expressions for optimized code generation. Some languages (or standards thereof), e.g. C99, offer specialized math functions for better performance and/or precision. Using the ``optimize`` function in this module, together with a collection of rules (represented as instances of ``Optimization``), one can rewrite the expressions for this purpose:: >>> from sympy import Symbol, exp, log >>> from sympy.codegen.rewriting import optimize, optims_c99 >>> x = Symbol('x') >>> optimize(3exp(2x) - 3, optims_c99) 3expm1(2x) >>> optimize(exp(2x) - 3, optims_c99) exp(2x) - 3 >>> optimize(log(3x + 3), optims_c99) log1p(x) + log(3) >>> optimize(log(2x + 3), optims_c99) log(2x + 3) The ``optims_c99`` imported above is tuple containing the following instances (which may be imported from ``sympy.codegen.rewriting``): - ``expm1_opt`` - ``log1p_opt`` - ``exp2_opt`` - ``log2_opt`` - ``log2const_opt`` """ from __future__ import (absolute_import, division, print_function) from itertools import chain from sympy import log, exp, Max, Min, Wild, expand_log, Dummy from sympy.codegen.cfunctions import log1p, log2, exp2, expm1 from sympy.core.expr import UnevaluatedExpr from sympy.core.mul import Mul from sympy.core.power import Pow from sympy.utilities.iterables import sift class Optimization(object): """ Abstract base class for rewriting optimization. Subclasses should implement ``__call__`` taking an expression as argument. Parameters ========== cost_function : callable returning number priority : number """ def __init__(self, cost_function=None, priority=1): self.cost_function = cost_function self.priority=priority class ReplaceOptim(Optimization): """ Rewriting optimization calling replace on expressions. The instance can be used as a function on expressions for which it will apply the ``replace`` method (see :meth:`sympy.core.basic.Basic.replace`). Parameters ========== query : first argument passed to replace value : second argument passed to replace Examples ======== >>> from sympy import Symbol, Pow >>> from sympy.codegen.rewriting import ReplaceOptim >>> from sympy.codegen.cfunctions import exp2 >>> x = Symbol('x') >>> exp2_opt = ReplaceOptim(lambda p: p.is_Pow and p.base == 2, ... lambda p: exp2(p.exp)) >>> exp2_opt(2x) exp2(x) """ def __init__(self, query, value, kwargs): super(ReplaceOptim, self).__init__(kwargs) self.query = query self.value = value def __call__(self, expr): return expr.replace(self.query, self.value) def optimize(expr, optimizations): """ Apply optimizations to an expression. Parameters ========== expr : expression optimizations : iterable of ``Optimization`` instances The optimizations will be sorted with respect to ``priority`` (highest first). Examples ======== >>> from sympy import log, Symbol >>> from sympy.codegen.rewriting import optims_c99, optimize >>> x = Symbol('x') >>> optimize(log(x+3)/log(2) + log(x2 + 1), optims_c99) log1p(x2) + log2(x + 3) """ for optim in sorted(optimizations, key=lambda opt: opt.priority, reverse=True): new_expr = optim(expr) if optim.cost_function is None: expr = new_expr else: before, after = map(lambda x: optim.cost_function(x), (expr, new_expr)) if before > after: expr = new_expr return expr exp2_opt = ReplaceOptim( lambda p: p.is_Pow and p.base == 2, lambda p: exp2(p.exp) ) _d = Wild('d', properties=[lambda x: x.is_Dummy]) _u = Wild('u', properties=[lambda x: not x.is_number and not x.is_Add]) _v = Wild('v') _w = Wild('w') log2_opt = ReplaceOptim(_vlog(_w)/log(2), _vlog2(_w), cost_function=lambda expr: expr.count( lambda e: ( # division & eval of transcendentals are expensive floating point operations... e.is_Pow and e.exp.is_negative # division or (isinstance(e, (log, log2)) and not e.args[0].is_number)) # transcendental ) ) log2const_opt = ReplaceOptim(log(2)log2(_w), log(_w)) logsumexp_2terms_opt = ReplaceOptim( lambda l: (isinstance(l, log) and l.args[0].is_Add and len(l.args[0].args) == 2 and all(isinstance(t, exp) for t in l.args[0].args)), lambda l: ( Max([e.args[0] for e in l.args[0].args]) + log1p(exp(Min([e.args[0] for e in l.args[0].args]))) ) ) def _try_expm1(expr): protected, old_new = expr.replace(exp, lambda arg: Dummy(), map=True) factored = protected.factor() new_old = {v: k for k, v in old_new.items()} return factored.replace(_d - 1, lambda d: expm1(new_old[d].args[0])).xreplace(new_old) def _expm1_value(e): numbers, non_num = sift(e.args, lambda arg: arg.is_number, binary=True) non_num_exp, non_num_other = sift(non_num, lambda arg: arg.has(exp), binary=True) numsum = sum(numbers) new_exp_terms, done = [], False for exp_term in non_num_exp: if done: new_exp_terms.append(exp_term) else: looking_at = exp_term + numsum attempt = _try_expm1(looking_at) if looking_at == attempt: new_exp_terms.append(exp_term) else: done = True new_exp_terms.append(attempt) if not done: new_exp_terms.append(numsum) return e.func(chain(new_exp_terms, non_num_other)) expm1_opt = ReplaceOptim(lambda e: e.is_Add, _expm1_value) log1p_opt = ReplaceOptim( lambda e: isinstance(e, log), lambda l: expand_log(l.replace( log, lambda arg: log(arg.factor()) )).replace(log(_u+1), log1p(_u)) ) def create_expand_pow_optimization(limit): """ Creates an instance of :class:`ReplaceOptim` for expanding ``Pow``. The requirements for expansions are that the base needs to be a symbol and the exponent needs to be an Integer (and be less than or equal to ``limit``). Parameters ========== limit : int The highest power which is expanded into multiplication. Examples ======== >>> from sympy import Symbol, sin >>> from sympy.codegen.rewriting import create_expand_pow_optimization >>> x = Symbol('x') >>> expand_opt = create_expand_pow_optimization(3) >>> expand_opt(x5 + x3) x5 + xxx >>> expand_opt(x5 + x3 + sin(x)3) x5 + sin(x)3 + xxx """ return ReplaceOptim( lambda e: e.is_Pow and e.base.is_symbol and e.exp.is_Integer and abs(e.exp) <= limit, lambda p: ( UnevaluatedExpr(Mul(([p.base]+p.exp), evaluate=False)) if p.exp > 0 else 1/UnevaluatedExpr(Mul(([p.base]*-p.exp), evaluate=False)) )) # Collections of optimizations: optims_c99 = (expm1_opt, log1p_opt, exp2_opt, log2_opt, log2const_opt)
4af858b273fa71dd29c406f026acf68138c90be73806beb8c9134a84a1129eb8	""" Types used to represent a full function/module as an Abstract Syntax Tree. Most types are small, and are merely used as tokens in the AST. A tree diagram has been included below to illustrate the relationships between the AST types. AST Type Tree ------------- :: Basic \|--->AssignmentBase \| \|--->Assignment \| \|--->AugmentedAssignment \| \|--->AddAugmentedAssignment \| \|--->SubAugmentedAssignment \| \|--->MulAugmentedAssignment \| \|--->DivAugmentedAssignment \| \|--->ModAugmentedAssignment \| \|--->CodeBlock \| \| \|--->Token \| \|--->Attribute \| \|--->For \| \|--->String \| \| \|--->QuotedString \| \| \|--->Comment \| \|--->Type \| \| \|--->IntBaseType \| \| \| \|--->_SizedIntType \| \| \| \|--->SignedIntType \| \| \| \|--->UnsignedIntType \| \| \|--->FloatBaseType \| \| \|--->FloatType \| \| \|--->ComplexBaseType \| \| \|--->ComplexType \| \|--->Node \| \| \|--->Variable \| \| \| \|---> Pointer \| \| \|--->FunctionPrototype \| \| \|--->FunctionDefinition \| \|--->Element \| \|--->Declaration \| \|--->While \| \|--->Scope \| \|--->Stream \| \|--->Print \| \|--->FunctionCall \| \|--->BreakToken \| \|--->ContinueToken \| \|--->NoneToken \| \|--->Statement \|--->Return Predefined types ---------------- A number of ``Type`` instances are provided in the ``sympy.codegen.ast`` module for convenience. Perhaps the two most common ones for code-generation (of numeric codes) are ``float32`` and ``float64`` (known as single and double precision respectively). There are also precision generic versions of Types (for which the codeprinters selects the underlying data type at time of printing): ``real``, ``integer``, ``complex_``, ``bool_``. The other ``Type`` instances defined are: - ``intc``: Integer type used by C's "int". - ``intp``: Integer type used by C's "unsigned". - ``int8``, ``int16``, ``int32``, ``int64``: n-bit integers. - ``uint8``, ``uint16``, ``uint32``, ``uint64``: n-bit unsigned integers. - ``float80``: known as "extended precision" on modern x86/amd64 hardware. - ``complex64``: Complex number represented by two ``float32`` numbers - ``complex128``: Complex number represented by two ``float64`` numbers Using the nodes --------------- It is possible to construct simple algorithms using the AST nodes. Let's construct a loop applying Newton's method:: >>> from sympy import symbols, cos >>> from sympy.codegen.ast import While, Assignment, aug_assign, Print >>> t, dx, x = symbols('tol delta val') >>> expr = cos(x) - x3 >>> whl = While(abs(dx) > t, [ ... Assignment(dx, -expr/expr.diff(x)), ... aug_assign(x, '+', dx), ... Print([x]) ... ]) >>> from sympy.printing import pycode >>> py_str = pycode(whl) >>> print(py_str) while (abs(delta) > tol): delta = (val3 - math.cos(val))/(-3val2 - math.sin(val)) val += delta print(val) >>> import math >>> tol, val, delta = 1e-5, 0.5, float('inf') >>> exec(py_str) 1.1121416371 0.909672693737 0.867263818209 0.865477135298 0.865474033111 >>> print('%3.1g' % (math.cos(val) - val3)) -3e-11 If we want to generate Fortran code for the same while loop we simple call ``fcode``:: >>> from sympy.printing.fcode import fcode >>> print(fcode(whl, standard=2003, source_format='free')) do while (abs(delta) > tol) delta = (val3 - cos(val))/(-3val*2 - sin(val)) val = val + delta print , val end do There is a function constructing a loop (or a complete function) like this in :mod:`sympy.codegen.algorithms`. """ from __future__ import print_function, division from itertools import chain from collections import defaultdict from sympy.core import Symbol, Tuple, Dummy from sympy.core.basic import Basic from sympy.core.compatibility import string_types from sympy.core.expr import Expr from sympy.core.numbers import Float, Integer, oo from sympy.core.relational import Lt, Le, Ge, Gt from sympy.core.sympify import _sympify, sympify, SympifyError from sympy.utilities.iterables import iterable def _mk_Tuple(args): """ Create a Sympy Tuple object from an iterable, converting Python strings to AST strings. Parameters ========== args: iterable Arguments to :class:`sympy.Tuple`. Returns ======= sympy.Tuple """ args = [String(arg) if isinstance(arg, string_types) else arg for arg in args] return Tuple(args) class Token(Basic): """ Base class for the AST types. Defining fields are set in ``__slots__``. Attributes (defined in __slots__) are only allowed to contain instances of Basic (unless atomic, see ``String``). The arguments to ``__new__()`` correspond to the attributes in the order defined in ``__slots__`. The ``defaults`` class attribute is a dictionary mapping attribute names to their default values. Subclasses should not need to override the ``__new__()`` method. They may define a class or static method named ``_construct_<attr>`` for each attribute to process the value passed to ``__new__()``. Attributes listed in the class attribute ``not_in_args`` are not passed to :class:`sympy.Basic`. """ __slots__ = [] defaults = {} not_in_args = [] indented_args = ['body'] @property def is_Atom(self): return len(self.__slots__) == 0 @classmethod def _get_constructor(cls, attr): """ Get the constructor function for an attribute by name. """ return getattr(cls, '_construct_%s' % attr, lambda x: x) @classmethod def _construct(cls, attr, arg): """ Construct an attribute value from argument passed to ``__new__()``. """ if arg == None: # Must be "== None", cannot be "is None" return cls.defaults.get(attr, none) else: if isinstance(arg, Dummy): # sympy's replace uses Dummy instances return arg else: return cls._get_constructor(attr)(arg) def __new__(cls, args, *kwargs): # Pass through existing instances when given as sole argument if len(args) == 1 and not kwargs and isinstance(args[0], cls): return args[0] if len(args) > len(cls.__slots__): raise ValueError("Too many arguments (%d), expected at most %d" % (len(args), len(cls.__slots__))) attrvals = [] # Process positional arguments for attrname, argval in zip(cls.__slots__, args): if attrname in kwargs: raise TypeError('Got multiple values for attribute %r' % attrname) attrvals.append(cls._construct(attrname, argval)) # Process keyword arguments for attrname in cls.__slots__[len(args):]: if attrname in kwargs: argval = kwargs.pop(attrname) elif attrname in cls.defaults: argval = cls.defaults[attrname] else: raise TypeError('No value for %r given and attribute has no default' % attrname) attrvals.append(cls._construct(attrname, argval)) if kwargs: raise ValueError("Unknown keyword arguments: %s" % ' '.join(kwargs)) # Parent constructor basic_args = [ val for attr, val in zip(cls.__slots__, attrvals) if attr not in cls.not_in_args ] obj = Basic.__new__(cls, basic_args) # Set attributes for attr, arg in zip(cls.__slots__, attrvals): setattr(obj, attr, arg) return obj def __eq__(self, other): if not isinstance(other, self.__class__): return False for attr in self.__slots__: if getattr(self, attr) != getattr(other, attr): return False return True def _hashable_content(self): return tuple([getattr(self, attr) for attr in self.__slots__]) def __hash__(self): return super(Token, self).__hash__() def _joiner(self, k, indent_level): return (',\n' + ' 'indent_level) if k in self.indented_args else ', ' def _indented(self, printer, k, v, args, *kwargs): il = printer._context['indent_level'] def _print(arg): if isinstance(arg, Token): return printer._print(arg, args, joiner=self._joiner(k, il), *kwargs) else: return printer._print(v, args, *kwargs) if isinstance(v, Tuple): joined = self._joiner(k, il).join([_print(arg) for arg in v.args]) if k in self.indented_args: return '(\n' + ' 'il + joined + ',\n' + ' '(il - 4) + ')' else: return ('({0},)' if len(v.args) == 1 else '({0})').format(joined) else: return _print(v) def _sympyrepr(self, printer, args, *kwargs): from sympy.printing.printer import printer_context exclude = kwargs.get('exclude', ()) values = [getattr(self, k) for k in self.__slots__] indent_level = printer._context.get('indent_level', 0) joiner = kwargs.pop('joiner', ', ') arg_reprs = [] for i, (attr, value) in enumerate(zip(self.__slots__, values)): if attr in exclude: continue # Skip attributes which have the default value if attr in self.defaults and value == self.defaults[attr]: continue ilvl = indent_level + 4 if attr in self.indented_args else 0 with printer_context(printer, indent_level=ilvl): indented = self._indented(printer, attr, value, args, *kwargs) arg_reprs.append(('{1}' if i == 0 else '{0}={1}').format(attr, indented.lstrip())) return "{0}({1})".format(self.__class__.__name__, joiner.join(arg_reprs)) _sympystr = _sympyrepr def __repr__(self): # sympy.core.Basic.__repr__ uses sstr from sympy.printing import srepr return srepr(self) def kwargs(self, exclude=(), apply=None): """ Get instance's attributes as dict of keyword arguments. Parameters ========== exclude : collection of str Collection of keywords to exclude. apply : callable, optional Function to apply to all values. """ kwargs = {k: getattr(self, k) for k in self.__slots__ if k not in exclude} if apply is not None: return {k: apply(v) for k, v in kwargs.items()} else: return kwargs class BreakToken(Token): """ Represents 'break' in C/Python ('exit' in Fortran). Use the premade instance ``break_`` or instantiate manually. Examples ======== >>> from sympy.printing import ccode, fcode >>> from sympy.codegen.ast import break_ >>> ccode(break_) 'break' >>> fcode(break_, source_format='free') 'exit' """ break_ = BreakToken() class ContinueToken(Token): """ Represents 'continue' in C/Python ('cycle' in Fortran) Use the premade instance ``continue_`` or instantiate manually. Examples ======== >>> from sympy.printing import ccode, fcode >>> from sympy.codegen.ast import continue_ >>> ccode(continue_) 'continue' >>> fcode(continue_, source_format='free') 'cycle' """ continue_ = ContinueToken() class NoneToken(Token): """ The AST equivalence of Python's NoneType The corresponding instance of Python's ``None`` is ``none``. Examples ======== >>> from sympy.codegen.ast import none, Variable >>> from sympy.printing.pycode import pycode >>> print(pycode(Variable('x').as_Declaration(value=none))) x = None """ def __eq__(self, other): return other is None or isinstance(other, NoneToken) def _hashable_content(self): return () def __hash__(self): return super(NoneToken, self).__hash__() none = NoneToken() class AssignmentBase(Basic): """ Abstract base class for Assignment and AugmentedAssignment. Attributes: =========== op : str Symbol for assignment operator, e.g. "=", "+=", etc. """ def __new__(cls, lhs, rhs): lhs = _sympify(lhs) rhs = _sympify(rhs) cls._check_args(lhs, rhs) return super(AssignmentBase, cls).__new__(cls, lhs, rhs) @property def lhs(self): return self.args[0] @property def rhs(self): return self.args[1] @classmethod def _check_args(cls, lhs, rhs): """ Check arguments to __new__ and raise exception if any problems found. Derived classes may wish to override this. """ from sympy.matrices.expressions.matexpr import ( MatrixElement, MatrixSymbol) from sympy.tensor.indexed import Indexed # Tuple of things that can be on the lhs of an assignment assignable = (Symbol, MatrixSymbol, MatrixElement, Indexed, Element, Variable) if not isinstance(lhs, assignable): raise TypeError("Cannot assign to lhs of type %s." % type(lhs)) # Indexed types implement shape, but don't define it until later. This # causes issues in assignment validation. For now, matrices are defined # as anything with a shape that is not an Indexed lhs_is_mat = hasattr(lhs, 'shape') and not isinstance(lhs, Indexed) rhs_is_mat = hasattr(rhs, 'shape') and not isinstance(rhs, Indexed) # If lhs and rhs have same structure, then this assignment is ok if lhs_is_mat: if not rhs_is_mat: raise ValueError("Cannot assign a scalar to a matrix.") elif lhs.shape != rhs.shape: raise ValueError("Dimensions of lhs and rhs don't align.") elif rhs_is_mat and not lhs_is_mat: raise ValueError("Cannot assign a matrix to a scalar.") class Assignment(AssignmentBase): """ Represents variable assignment for code generation. Parameters ========== lhs : Expr Sympy object representing the lhs of the expression. These should be singular objects, such as one would use in writing code. Notable types include Symbol, MatrixSymbol, MatrixElement, and Indexed. Types that subclass these types are also supported. rhs : Expr Sympy object representing the rhs of the expression. This can be any type, provided its shape corresponds to that of the lhs. For example, a Matrix type can be assigned to MatrixSymbol, but not to Symbol, as the dimensions will not align. Examples ======== >>> from sympy import symbols, MatrixSymbol, Matrix >>> from sympy.codegen.ast import Assignment >>> x, y, z = symbols('x, y, z') >>> Assignment(x, y) Assignment(x, y) >>> Assignment(x, 0) Assignment(x, 0) >>> A = MatrixSymbol('A', 1, 3) >>> mat = Matrix([x, y, z]).T >>> Assignment(A, mat) Assignment(A, Matrix([[x, y, z]])) >>> Assignment(A[0, 1], x) Assignment(A[0, 1], x) """ op = ':=' class AugmentedAssignment(AssignmentBase): """ Base class for augmented assignments. Attributes: =========== binop : str Symbol for binary operation being applied in the assignment, such as "+", "", etc. """ @property def op(self): return self.binop + '=' class AddAugmentedAssignment(AugmentedAssignment): binop = '+' class SubAugmentedAssignment(AugmentedAssignment): binop = '-' class MulAugmentedAssignment(AugmentedAssignment): binop = '' class DivAugmentedAssignment(AugmentedAssignment): binop = '/' class ModAugmentedAssignment(AugmentedAssignment): binop = '%' # Mapping from binary op strings to AugmentedAssignment subclasses augassign_classes = { cls.binop: cls for cls in [ AddAugmentedAssignment, SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment ] } def aug_assign(lhs, op, rhs): """ Create 'lhs op= rhs'. Represents augmented variable assignment for code generation. This is a convenience function. You can also use the AugmentedAssignment classes directly, like AddAugmentedAssignment(x, y). Parameters ========== lhs : Expr Sympy object representing the lhs of the expression. These should be singular objects, such as one would use in writing code. Notable types include Symbol, MatrixSymbol, MatrixElement, and Indexed. Types that subclass these types are also supported. op : str Operator (+, -, /, \\, %). rhs : Expr Sympy object representing the rhs of the expression. This can be any type, provided its shape corresponds to that of the lhs. For example, a Matrix type can be assigned to MatrixSymbol, but not to Symbol, as the dimensions will not align. Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import aug_assign >>> x, y = symbols('x, y') >>> aug_assign(x, '+', y) AddAugmentedAssignment(x, y) """ if op not in augassign_classes: raise ValueError("Unrecognized operator %s" % op) return augassign_classes[op](lhs, rhs) class CodeBlock(Basic): """ Represents a block of code For now only assignments are supported. This restriction will be lifted in the future. Useful attributes on this object are: ``left_hand_sides``: Tuple of left-hand sides of assignments, in order. ``left_hand_sides``: Tuple of right-hand sides of assignments, in order. ``free_symbols``: Free symbols of the expressions in the right-hand sides which do not appear in the left-hand side of an assignment. Useful methods on this object are: ``topological_sort``: Class method. Return a CodeBlock with assignments sorted so that variables are assigned before they are used. ``cse``: Return a new CodeBlock with common subexpressions eliminated and pulled out as assignments. Examples ======== >>> from sympy import symbols, ccode >>> from sympy.codegen.ast import CodeBlock, Assignment >>> x, y = symbols('x y') >>> c = CodeBlock(Assignment(x, 1), Assignment(y, x + 1)) >>> print(ccode(c)) x = 1; y = x + 1; """ def __new__(cls, args): left_hand_sides = [] right_hand_sides = [] for i in args: if isinstance(i, Assignment): lhs, rhs = i.args left_hand_sides.append(lhs) right_hand_sides.append(rhs) obj = Basic.__new__(cls, args) obj.left_hand_sides = Tuple(left_hand_sides) obj.right_hand_sides = Tuple(right_hand_sides) return obj def __iter__(self): return iter(self.args) def _sympyrepr(self, printer, args, kwargs): il = printer._context.get('indent_level', 0) joiner = ',\n' + ' 'il joined = joiner.join(map(printer._print, self.args)) return ('{0}(\n'.format(' '(il-4) + self.__class__.__name__,) + ' 'il + joined + '\n' + ' '(il - 4) + ')') _sympystr = _sympyrepr @property def free_symbols(self): return super(CodeBlock, self).free_symbols - set(self.left_hand_sides) @classmethod def topological_sort(cls, assignments): """ Return a CodeBlock with topologically sorted assignments so that variables are assigned before they are used. The existing order of assignments is preserved as much as possible. This function assumes that variables are assigned to only once. This is a class constructor so that the default constructor for CodeBlock can error when variables are used before they are assigned. Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import CodeBlock, Assignment >>> x, y, z = symbols('x y z') >>> assignments = [ ... Assignment(x, y + z), ... Assignment(y, z + 1), ... Assignment(z, 2), ... ] >>> CodeBlock.topological_sort(assignments) CodeBlock( Assignment(z, 2), Assignment(y, z + 1), Assignment(x, y + z) ) """ from sympy.utilities.iterables import topological_sort if not all(isinstance(i, Assignment) for i in assignments): # Will support more things later raise NotImplementedError("CodeBlock.topological_sort only supports Assignments") if any(isinstance(i, AugmentedAssignment) for i in assignments): raise NotImplementedError("CodeBlock.topological_sort doesn't yet work with AugmentedAssignments") # Create a graph where the nodes are assignments and there is a directed edge # between nodes that use a variable and nodes that assign that # variable, like # [(x := 1, y := x + 1), (x := 1, z := y + z), (y := x + 1, z := y + z)] # If we then topologically sort these nodes, they will be in # assignment order, like # x := 1 # y := x + 1 # z := y + z # A = The nodes # # enumerate keeps nodes in the same order they are already in if # possible. It will also allow us to handle duplicate assignments to # the same variable when those are implemented. A = list(enumerate(assignments)) # var_map = {variable: [nodes for which this variable is assigned to]} # like {x: [(1, x := y + z), (4, x := 2 w)], ...} var_map = defaultdict(list) for node in A: i, a = node var_map[a.lhs].append(node) # E = Edges in the graph E = [] for dst_node in A: i, a = dst_node for s in a.rhs.free_symbols: for src_node in var_map[s]: E.append((src_node, dst_node)) ordered_assignments = topological_sort([A, E]) # De-enumerate the result return cls([a for i, a in ordered_assignments]) def cse(self, symbols=None, optimizations=None, postprocess=None, order='canonical'): """ Return a new code block with common subexpressions eliminated See the docstring of :func:`sympy.simplify.cse_main.cse` for more information. Examples ======== >>> from sympy import symbols, sin >>> from sympy.codegen.ast import CodeBlock, Assignment >>> x, y, z = symbols('x y z') >>> c = CodeBlock( ... Assignment(x, 1), ... Assignment(y, sin(x) + 1), ... Assignment(z, sin(x) - 1), ... ) ... >>> c.cse() CodeBlock( Assignment(x, 1), Assignment(x0, sin(x)), Assignment(y, x0 + 1), Assignment(z, x0 - 1) ) """ from sympy.simplify.cse_main import cse from sympy.utilities.iterables import numbered_symbols, filter_symbols # Check that the CodeBlock only contains assignments to unique variables if not all(isinstance(i, Assignment) for i in self.args): # Will support more things later raise NotImplementedError("CodeBlock.cse only supports Assignments") if any(isinstance(i, AugmentedAssignment) for i in self.args): raise NotImplementedError("CodeBlock.cse doesn't yet work with AugmentedAssignments") for i, lhs in enumerate(self.left_hand_sides): if lhs in self.left_hand_sides[:i]: raise NotImplementedError("Duplicate assignments to the same " "variable are not yet supported (%s)" % lhs) # Ensure new symbols for subexpressions do not conflict with existing existing_symbols = self.atoms(Symbol) if symbols is None: symbols = numbered_symbols() symbols = filter_symbols(symbols, existing_symbols) replacements, reduced_exprs = cse(list(self.right_hand_sides), symbols=symbols, optimizations=optimizations, postprocess=postprocess, order=order) new_block = [Assignment(var, expr) for var, expr in zip(self.left_hand_sides, reduced_exprs)] new_assignments = [Assignment(var, expr) for var, expr in replacements] return self.topological_sort(new_assignments + new_block) class For(Token): """Represents a 'for-loop' in the code. Expressions are of the form: "for target in iter: body..." Parameters ========== target : symbol iter : iterable body : CodeBlock or iterable ! When passed an iterable it is used to instantiate a CodeBlock. Examples ======== >>> from sympy import symbols, Range >>> from sympy.codegen.ast import aug_assign, For >>> x, i, j, k = symbols('x i j k') >>> for_i = For(i, Range(10), [aug_assign(x, '+', ijk)]) >>> for_i # doctest: -NORMALIZE_WHITESPACE For(i, iterable=Range(0, 10, 1), body=CodeBlock( AddAugmentedAssignment(x, ijk) )) >>> for_ji = For(j, Range(7), [for_i]) >>> for_ji # doctest: -NORMALIZE_WHITESPACE For(j, iterable=Range(0, 7, 1), body=CodeBlock( For(i, iterable=Range(0, 10, 1), body=CodeBlock( AddAugmentedAssignment(x, ijk) )) )) >>> for_kji =For(k, Range(5), [for_ji]) >>> for_kji # doctest: -NORMALIZE_WHITESPACE For(k, iterable=Range(0, 5, 1), body=CodeBlock( For(j, iterable=Range(0, 7, 1), body=CodeBlock( For(i, iterable=Range(0, 10, 1), body=CodeBlock( AddAugmentedAssignment(x, ijk) )) )) )) """ __slots__ = ['target', 'iterable', 'body'] _construct_target = staticmethod(_sympify) @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(itr) @classmethod def _construct_iterable(cls, itr): if not iterable(itr): raise TypeError("iterable must be an iterable") if isinstance(itr, list): # _sympify errors on lists because they are mutable itr = tuple(itr) return _sympify(itr) class String(Token): """ SymPy object representing a string. Atomic object which is not an expression (as opposed to Symbol). Parameters ========== text : str Examples ======== >>> from sympy.codegen.ast import String >>> f = String('foo') >>> f foo >>> str(f) 'foo' >>> f.text 'foo' >>> print(repr(f)) String('foo') """ __slots__ = ['text'] not_in_args = ['text'] is_Atom = True @classmethod def _construct_text(cls, text): if not isinstance(text, string_types): raise TypeError("Argument text is not a string type.") return text def _sympystr(self, printer, args, kwargs): return self.text class QuotedString(String): """ Represents a string which should be printed with quotes. """ class Comment(String): """ Represents a comment. """ class Node(Token): """ Subclass of Token, carrying the attribute 'attrs' (Tuple) Examples ======== >>> from sympy.codegen.ast import Node, value_const, pointer_const >>> n1 = Node([value_const]) >>> n1.attr_params('value_const') # get the parameters of attribute (by name) () >>> from sympy.codegen.fnodes import dimension >>> n2 = Node([value_const, dimension(5, 3)]) >>> n2.attr_params(value_const) # get the parameters of attribute (by Attribute instance) () >>> n2.attr_params('dimension') # get the parameters of attribute (by name) (5, 3) >>> n2.attr_params(pointer_const) is None True """ __slots__ = ['attrs'] defaults = {'attrs': Tuple()} _construct_attrs = staticmethod(_mk_Tuple) def attr_params(self, looking_for): """ Returns the parameters of the Attribute with name ``looking_for`` in self.attrs """ for attr in self.attrs: if str(attr.name) == str(looking_for): return attr.parameters class Type(Token): """ Represents a type. The naming is a super-set of NumPy naming. Type has a classmethod ``from_expr`` which offer type deduction. It also has a method ``cast_check`` which casts the argument to its type, possibly raising an exception if rounding error is not within tolerances, or if the value is not representable by the underlying data type (e.g. unsigned integers). Parameters ========== name : str Name of the type, e.g. ``object``, ``int16``, ``float16`` (where the latter two would use the ``Type`` sub-classes ``IntType`` and ``FloatType`` respectively). If a ``Type`` instance is given, the said instance is returned. Examples ======== >>> from sympy.codegen.ast import Type >>> t = Type.from_expr(42) >>> t integer >>> print(repr(t)) IntBaseType(String('integer')) >>> from sympy.codegen.ast import uint8 >>> uint8.cast_check(-1) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Minimum value for data type bigger than new value. >>> from sympy.codegen.ast import float32 >>> v6 = 0.123456 >>> float32.cast_check(v6) 0.123456 >>> v10 = 12345.67894 >>> float32.cast_check(v10) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Casting gives a significantly different value. >>> boost_mp50 = Type('boost::multiprecision::cpp_dec_float_50') >>> from sympy import Symbol >>> from sympy.printing.cxxcode import cxxcode >>> from sympy.codegen.ast import Declaration, Variable >>> cxxcode(Declaration(Variable('x', type=boost_mp50))) 'boost::multiprecision::cpp_dec_float_50 x' References ========== .. [1] https://docs.scipy.org/doc/numpy/user/basics.types.html """ __slots__ = ['name'] _construct_name = String def _sympystr(self, printer, args, *kwargs): return str(self.name) @classmethod def from_expr(cls, expr): """ Deduces type from an expression or a ``Symbol``. Parameters ========== expr : number or SymPy object The type will be deduced from type or properties. Examples ======== >>> from sympy.codegen.ast import Type, integer, complex_ >>> Type.from_expr(2) == integer True >>> from sympy import Symbol >>> Type.from_expr(Symbol('z', complex=True)) == complex_ True >>> Type.from_expr(sum) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Could not deduce type from expr. Raises ====== ValueError when type deduction fails. """ if isinstance(expr, (float, Float)): return real if isinstance(expr, (int, Integer)) or getattr(expr, 'is_integer', False): return integer if getattr(expr, 'is_real', False): return real if isinstance(expr, complex) or getattr(expr, 'is_complex', False): return complex_ if isinstance(expr, bool) or getattr(expr, 'is_Relational', False): return bool_ else: raise ValueError("Could not deduce type from expr.") def _check(self, value): pass def cast_check(self, value, rtol=None, atol=0, limits=None, precision_targets=None): """ Casts a value to the data type of the instance. Parameters ========== value : number rtol : floating point number Relative tolerance. (will be deduced if not given). atol : floating point number Absolute tolerance (in addition to ``rtol``). limits : dict Values given by ``limits.h``, x86/IEEE754 defaults if not given. Default: :attr:`default_limits`. type_aliases : dict Maps substitutions for Type, e.g. {integer: int64, real: float32} Examples ======== >>> from sympy.codegen.ast import Type, integer, float32, int8 >>> integer.cast_check(3.0) == 3 True >>> float32.cast_check(1e-40) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Minimum value for data type bigger than new value. >>> int8.cast_check(256) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Maximum value for data type smaller than new value. >>> v10 = 12345.67894 >>> float32.cast_check(v10) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Casting gives a significantly different value. >>> from sympy.codegen.ast import float64 >>> float64.cast_check(v10) 12345.67894 >>> from sympy import Float >>> v18 = Float('0.123456789012345646') >>> float64.cast_check(v18) Traceback (most recent call last): ... ValueError: Casting gives a significantly different value. >>> from sympy.codegen.ast import float80 >>> float80.cast_check(v18) 0.123456789012345649 """ val = sympify(value) ten = Integer(10) exp10 = getattr(self, 'decimal_dig', None) if rtol is None: rtol = 1e-15 if exp10 is None else 2.0ten*(-exp10) def tol(num): return atol + rtolabs(num) new_val = self.cast_nocheck(value) self._check(new_val) delta = new_val - val if abs(delta) > tol(val): # rounding, e.g. int(3.5) != 3.5 raise ValueError("Casting gives a significantly different value.") return new_val class IntBaseType(Type): """ Integer base type, contains no size information. """ __slots__ = ['name'] cast_nocheck = lambda self, i: Integer(int(i)) class _SizedIntType(IntBaseType): __slots__ = ['name', 'nbits'] _construct_nbits = Integer def _check(self, value): if value < self.min: raise ValueError("Value is too small: %d < %d" % (value, self.min)) if value > self.max: raise ValueError("Value is too big: %d > %d" % (value, self.max)) class SignedIntType(_SizedIntType): """ Represents a signed integer type. """ @property def min(self): return -2(self.nbits-1) @property def max(self): return 2(self.nbits-1) - 1 class UnsignedIntType(_SizedIntType): """ Represents an unsigned integer type. """ @property def min(self): return 0 @property def max(self): return 2self.nbits - 1 two = Integer(2) class FloatBaseType(Type): """ Represents a floating point number type. """ cast_nocheck = Float class FloatType(FloatBaseType): """ Represents a floating point type with fixed bit width. Base 2 & one sign bit is assumed. Parameters ========== name : str Name of the type. nbits : integer Number of bits used (storage). nmant : integer Number of bits used to represent the mantissa. nexp : integer Number of bits used to represent the mantissa. Examples ======== >>> from sympy import S, Float >>> from sympy.codegen.ast import FloatType >>> half_precision = FloatType('f16', nbits=16, nmant=10, nexp=5) >>> half_precision.max 65504 >>> half_precision.tiny == S(2)-14 True >>> half_precision.eps == S(2)-10 True >>> half_precision.dig == 3 True >>> half_precision.decimal_dig == 5 True >>> half_precision.cast_check(1.0) 1.0 >>> half_precision.cast_check(1e5) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Maximum value for data type smaller than new value. """ __slots__ = ['name', 'nbits', 'nmant', 'nexp'] _construct_nbits = _construct_nmant = _construct_nexp = Integer @property def max_exponent(self): """ The largest positive number n, such that 2(n - 1) is a representable finite value. """ # cf. C++'s ``std::numeric_limits::max_exponent`` return two(self.nexp - 1) @property def min_exponent(self): """ The lowest negative number n, such that 2(n - 1) is a valid normalized number. """ # cf. C++'s ``std::numeric_limits::min_exponent`` return 3 - self.max_exponent @property def max(self): """ Maximum value representable. """ return (1 - two*-(self.nmant+1))twoself.max_exponent @property def tiny(self): """ The minimum positive normalized value. """ # See C macros: FLT_MIN, DBL_MIN, LDBL_MIN # or C++'s ``std::numeric_limits::min`` # or numpy.finfo(dtype).tiny return two(self.min_exponent - 1) @property def eps(self): """ Difference between 1.0 and the next representable value. """ return two*(-self.nmant) @property def dig(self): """ Number of decimal digits that are guaranteed to be preserved in text. When converting text -> float -> text, you are guaranteed that at least ``dig`` number of digits are preserved with respect to rounding or overflow. """ from sympy.functions import floor, log return floor(self.nmant log(2)/log(10)) @property def decimal_dig(self): """ Number of digits needed to store & load without loss. Number of decimal digits needed to guarantee that two consecutive conversions (float -> text -> float) to be idempotent. This is useful when one do not want to loose precision due to rounding errors when storing a floating point value as text. """ from sympy.functions import ceiling, log return ceiling((self.nmant + 1) * log(2)/log(10) + 1) def cast_nocheck(self, value): """ Casts without checking if out of bounds or subnormal. """ if value == oo: # float(oo) or oo return float(oo) elif value == -oo: # float(-oo) or -oo return float(-oo) return Float(str(sympify(value).evalf(self.decimal_dig)), self.decimal_dig) def _check(self, value): if value < -self.max: raise ValueError("Value is too small: %d < %d" % (value, -self.max)) if value > self.max: raise ValueError("Value is too big: %d > %d" % (value, self.max)) if abs(value) < self.tiny: raise ValueError("Smallest (absolute) value for data type bigger than new value.") class ComplexBaseType(FloatBaseType): def cast_nocheck(self, value): """ Casts without checking if out of bounds or subnormal. """ from sympy.functions import re, im return ( super(ComplexBaseType, self).cast_nocheck(re(value)) + super(ComplexBaseType, self).cast_nocheck(im(value))1j ) def _check(self, value): from sympy.functions import re, im super(ComplexBaseType, self)._check(re(value)) super(ComplexBaseType, self)._check(im(value)) class ComplexType(ComplexBaseType, FloatType): """ Represents a complex floating point number. """ # NumPy types: intc = IntBaseType('intc') intp = IntBaseType('intp') int8 = SignedIntType('int8', 8) int16 = SignedIntType('int16', 16) int32 = SignedIntType('int32', 32) int64 = SignedIntType('int64', 64) uint8 = UnsignedIntType('uint8', 8) uint16 = UnsignedIntType('uint16', 16) uint32 = UnsignedIntType('uint32', 32) uint64 = UnsignedIntType('uint64', 64) float16 = FloatType('float16', 16, nexp=5, nmant=10) # IEEE 754 binary16, Half precision float32 = FloatType('float32', 32, nexp=8, nmant=23) # IEEE 754 binary32, Single precision float64 = FloatType('float64', 64, nexp=11, nmant=52) # IEEE 754 binary64, Double precision float80 = FloatType('float80', 80, nexp=15, nmant=63) # x86 extended precision (1 integer part bit), "long double" float128 = FloatType('float128', 128, nexp=15, nmant=112) # IEEE 754 binary128, Quadruple precision float256 = FloatType('float256', 256, nexp=19, nmant=236) # IEEE 754 binary256, Octuple precision complex64 = ComplexType('complex64', nbits=64, float32.kwargs(exclude=('name', 'nbits'))) complex128 = ComplexType('complex128', nbits=128, float64.kwargs(exclude=('name', 'nbits'))) # Generic types (precision may be chosen by code printers): untyped = Type('untyped') real = FloatBaseType('real') integer = IntBaseType('integer') complex_ = ComplexBaseType('complex') bool_ = Type('bool') class Attribute(Token): """ Attribute (possibly parametrized) For use with :class:`sympy.codegen.ast.Node` (which takes instances of ``Attribute`` as ``attrs``). Parameters ========== name : str parameters : Tuple Examples ======== >>> from sympy.codegen.ast import Attribute >>> volatile = Attribute('volatile') >>> volatile volatile >>> print(repr(volatile)) Attribute(String('volatile')) >>> a = Attribute('foo', [1, 2, 3]) >>> a foo(1, 2, 3) >>> a.parameters == (1, 2, 3) True """ __slots__ = ['name', 'parameters'] defaults = {'parameters': Tuple()} _construct_name = String _construct_parameters = staticmethod(_mk_Tuple) def _sympystr(self, printer, args, *kwargs): result = str(self.name) if self.parameters: result += '(%s)' % ', '.join(map(lambda arg: printer._print( arg, args, kwargs), self.parameters)) return result value_const = Attribute('value_const') pointer_const = Attribute('pointer_const') class Variable(Node): """ Represents a variable Parameters ========== symbol : Symbol type : Type (optional) Type of the variable. attrs : iterable of Attribute instances Will be stored as a Tuple. Examples ======== >>> from sympy import Symbol >>> from sympy.codegen.ast import Variable, float32, integer >>> x = Symbol('x') >>> v = Variable(x, type=float32) >>> v.attrs () >>> v == Variable('x') False >>> v == Variable('x', type=float32) True >>> v Variable(x, type=float32) One may also construct a ``Variable`` instance with the type deduced from assumptions about the symbol using the ``deduced`` classmethod: >>> i = Symbol('i', integer=True) >>> v = Variable.deduced(i) >>> v.type == integer True >>> v == Variable('i') False >>> from sympy.codegen.ast import value_const >>> value_const in v.attrs False >>> w = Variable('w', attrs=[value_const]) >>> w Variable(w, attrs=(value_const,)) >>> value_const in w.attrs True >>> w.as_Declaration(value=42) Declaration(Variable(w, value=42, attrs=(value_const,))) """ __slots__ = ['symbol', 'type', 'value'] + Node.__slots__ defaults = dict(chain(Node.defaults.items(), { 'type': untyped, 'value': none }.items())) _construct_symbol = staticmethod(sympify) _construct_value = staticmethod(sympify) @classmethod def deduced(cls, symbol, value=None, attrs=Tuple(), cast_check=True): """ Alt. constructor with type deduction from ``Type.from_expr``. Deduces type primarily from ``symbol``, secondarily from ``value``. Parameters ========== symbol : Symbol value : expr (optional) value of the variable. attrs : iterable of Attribute instances cast_check : bool Whether to apply ``Type.cast_check`` on ``value``. Examples ======== >>> from sympy import Symbol >>> from sympy.codegen.ast import Variable, complex_ >>> n = Symbol('n', integer=True) >>> str(Variable.deduced(n).type) 'integer' >>> x = Symbol('x', real=True) >>> v = Variable.deduced(x) >>> v.type real >>> z = Symbol('z', complex=True) >>> Variable.deduced(z).type == complex_ True """ if isinstance(symbol, Variable): return symbol try: type_ = Type.from_expr(symbol) except ValueError: type_ = Type.from_expr(value) if value is not None and cast_check: value = type_.cast_check(value) return cls(symbol, type=type_, value=value, attrs=attrs) def as_Declaration(self, kwargs): """ Convenience method for creating a Declaration instance. If the variable of the Declaration need to wrap a modified variable keyword arguments may be passed (overriding e.g. the ``value`` of the Variable instance). Examples ======== >>> from sympy.codegen.ast import Variable >>> x = Variable('x') >>> decl1 = x.as_Declaration() >>> decl1.variable.value == None True >>> decl2 = x.as_Declaration(value=42.0) >>> decl2.variable.value == 42 True """ kw = self.kwargs() kw.update(kwargs) return Declaration(self.func(*kw)) def _relation(self, rhs, op): try: rhs = _sympify(rhs) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, rhs)) return op(self, rhs, evaluate=False) __lt__ = lambda self, other: self._relation(other, Lt) __le__ = lambda self, other: self._relation(other, Le) __ge__ = lambda self, other: self._relation(other, Ge) __gt__ = lambda self, other: self._relation(other, Gt) class Pointer(Variable): """ Represents a pointer. See ``Variable``. Examples ======== Can create instances of ``Element``: >>> from sympy import Symbol >>> from sympy.codegen.ast import Pointer >>> i = Symbol('i', integer=True) >>> p = Pointer('x') >>> p[i+1] Element(x, indices=((i + 1,),)) """ def __getitem__(self, key): try: return Element(self.symbol, key) except TypeError: return Element(self.symbol, (key,)) class Element(Token): """ Element in (a possibly N-dimensional) array. Examples ======== >>> from sympy.codegen.ast import Element >>> elem = Element('x', 'ijk') >>> elem.symbol.name == 'x' True >>> elem.indices (i, j, k) >>> from sympy import ccode >>> ccode(elem) 'x[i][j][k]' >>> ccode(Element('x', 'ijk', strides='lmn', offset='o')) 'x[il + jm + kn + o]' """ __slots__ = ['symbol', 'indices', 'strides', 'offset'] defaults = {'strides': none, 'offset': none} _construct_symbol = staticmethod(sympify) _construct_indices = staticmethod(lambda arg: Tuple(arg)) _construct_strides = staticmethod(lambda arg: Tuple(arg)) _construct_offset = staticmethod(sympify) class Declaration(Token): """ Represents a variable declaration Parameters ========== variable : Variable Examples ======== >>> from sympy import Symbol >>> from sympy.codegen.ast import Declaration, Type, Variable, integer, untyped >>> z = Declaration('z') >>> z.variable.type == untyped True >>> z.variable.value == None True """ __slots__ = ['variable'] _construct_variable = Variable class While(Token): """ Represents a 'for-loop' in the code. Expressions are of the form: "while condition: body..." Parameters ========== condition : expression convertable to Boolean body : CodeBlock or iterable When passed an iterable it is used to instantiate a CodeBlock. Examples ======== >>> from sympy import symbols, Gt, Abs >>> from sympy.codegen import aug_assign, Assignment, While >>> x, dx = symbols('x dx') >>> expr = 1 - x*2 >>> whl = While(Gt(Abs(dx), 1e-9), [ ... Assignment(dx, -expr/expr.diff(x)), ... aug_assign(x, '+', dx) ... ]) """ __slots__ = ['condition', 'body'] _construct_condition = staticmethod(lambda cond: _sympify(cond)) @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(itr) class Scope(Token): """ Represents a scope in the code. Parameters ========== body : CodeBlock or iterable When passed an iterable it is used to instantiate a CodeBlock. """ __slots__ = ['body'] @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(itr) class Stream(Token): """ Represents a stream. There are two predefined Stream instances ``stdout`` & ``stderr``. Parameters ========== name : str Examples ======== >>> from sympy import Symbol >>> from sympy.printing.pycode import pycode >>> from sympy.codegen.ast import Print, stderr, QuotedString >>> print(pycode(Print(['x'], file=stderr))) print(x, file=sys.stderr) >>> x = Symbol('x') >>> print(pycode(Print([QuotedString('x')], file=stderr))) # print literally "x" print("x", file=sys.stderr) """ __slots__ = ['name'] _construct_name = String stdout = Stream('stdout') stderr = Stream('stderr') class Print(Token): """ Represents print command in the code. Parameters ========== formatstring : str args : Basic instances (or convertible to such through sympify) Examples ======== >>> from sympy.codegen.ast import Print >>> from sympy.printing.pycode import pycode >>> print(pycode(Print('x y'.split(), "coordinate: %12.5g %12.5g"))) print("coordinate: %12.5g %12.5g" % (x, y)) """ __slots__ = ['print_args', 'format_string', 'file'] defaults = {'format_string': none, 'file': none} _construct_print_args = staticmethod(_mk_Tuple) _construct_format_string = QuotedString _construct_file = Stream class FunctionPrototype(Node): """ Represents a function prototype Allows the user to generate forward declaration in e.g. C/C++. Parameters ========== return_type : Type name : str parameters: iterable of Variable instances attrs : iterable of Attribute instances Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import real, FunctionPrototype >>> from sympy.printing.ccode import ccode >>> x, y = symbols('x y', real=True) >>> fp = FunctionPrototype(real, 'foo', [x, y]) >>> ccode(fp) 'double foo(double x, double y)' """ __slots__ = ['return_type', 'name', 'parameters', 'attrs'] _construct_return_type = Type _construct_name = String @staticmethod def _construct_parameters(args): def _var(arg): if isinstance(arg, Declaration): return arg.variable elif isinstance(arg, Variable): return arg else: return Variable.deduced(arg) return Tuple(map(_var, args)) @classmethod def from_FunctionDefinition(cls, func_def): if not isinstance(func_def, FunctionDefinition): raise TypeError("func_def is not an instance of FunctionDefiniton") return cls(func_def.kwargs(exclude=('body',))) class FunctionDefinition(FunctionPrototype): """ Represents a function definition in the code. Parameters ========== return_type : Type name : str parameters: iterable of Variable instances body : CodeBlock or iterable attrs : iterable of Attribute instances Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import real, FunctionPrototype >>> from sympy.printing.ccode import ccode >>> x, y = symbols('x y', real=True) >>> fp = FunctionPrototype(real, 'foo', [x, y]) >>> ccode(fp) 'double foo(double x, double y)' >>> from sympy.codegen.ast import FunctionDefinition, Return >>> body = [Return(xy)] >>> fd = FunctionDefinition.from_FunctionPrototype(fp, body) >>> print(ccode(fd)) double foo(double x, double y){ return xy; } """ __slots__ = FunctionPrototype.__slots__[:-1] + ['body', 'attrs'] @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(itr) @classmethod def from_FunctionPrototype(cls, func_proto, body): if not isinstance(func_proto, FunctionPrototype): raise TypeError("func_proto is not an instance of FunctionPrototype") return cls(body=body, *func_proto.kwargs()) class Return(Basic): """ Represents a return command in the code. """ class FunctionCall(Token, Expr): """ Represents a call to a function in the code. Parameters ========== name : str function_args : Tuple Examples ======== >>> from sympy.codegen.ast import FunctionCall >>> from sympy.printing.pycode import pycode >>> fcall = FunctionCall('foo', 'bar baz'.split()) >>> print(pycode(fcall)) foo(bar, baz) """ __slots__ = ['name', 'function_args'] _construct_name = String _construct_function_args = staticmethod(lambda args: Tuple(args))
f808ffabaf0ce83aabb250aa387d571885f62a26e56d19dcbabbd4918cad71f0	""" The contents of this file are the return value of ``sympy.assumptions.ask.compute_known_facts``. Do NOT manually edit this file. Instead, run ./bin/ask_update.py. """ from sympy.core.cache import cacheit from sympy.logic.boolalg import And from sympy.assumptions.ask import Q # -{ Known facts in Conjunctive Normal Form }- @cacheit def get_known_facts_cnf(): return And( Q.invertible \| Q.singular, Q.algebraic \| ~Q.rational, Q.antihermitian \| ~Q.imaginary, Q.complex \| ~Q.algebraic, Q.complex \| ~Q.imaginary, Q.complex \| ~Q.real, Q.complex \| ~Q.transcendental, Q.complex_elements \| ~Q.real_elements, Q.even \| ~Q.zero, Q.extended_real \| ~Q.infinite, Q.extended_real \| ~Q.real, Q.finite \| ~Q.algebraic, Q.finite \| ~Q.irrational, Q.finite \| ~Q.rational, Q.finite \| ~Q.transcendental, Q.fullrank \| ~Q.invertible, Q.hermitian \| ~Q.real, Q.integer \| ~Q.even, Q.integer \| ~Q.odd, Q.integer \| ~Q.prime, Q.invertible \| ~Q.positive_definite, Q.invertible \| ~Q.unitary, Q.lower_triangular \| ~Q.diagonal, Q.nonnegative \| ~Q.positive, Q.nonnegative \| ~Q.zero, Q.nonpositive \| ~Q.negative, Q.nonpositive \| ~Q.zero, Q.nonzero \| ~Q.negative, Q.nonzero \| ~Q.positive, Q.normal \| ~Q.diagonal, Q.normal \| ~Q.unitary, Q.positive \| ~Q.prime, Q.positive_definite \| ~Q.orthogonal, Q.rational \| ~Q.integer, Q.real \| ~Q.irrational, Q.real \| ~Q.negative, Q.real \| ~Q.positive, Q.real \| ~Q.rational, Q.real \| ~Q.zero, Q.real_elements \| ~Q.integer_elements, Q.square \| ~Q.invertible, Q.square \| ~Q.normal, Q.square \| ~Q.symmetric, Q.symmetric \| ~Q.diagonal, Q.triangular \| ~Q.lower_triangular, Q.triangular \| ~Q.unit_triangular, Q.triangular \| ~Q.upper_triangular, Q.unitary \| ~Q.orthogonal, Q.upper_triangular \| ~Q.diagonal, ~Q.algebraic \| ~Q.transcendental, ~Q.antihermitian \| ~Q.hermitian, ~Q.composite \| ~Q.prime, ~Q.even \| ~Q.odd, ~Q.finite \| ~Q.infinite, ~Q.imaginary \| ~Q.real, ~Q.invertible \| ~Q.singular, ~Q.irrational \| ~Q.rational, ~Q.negative \| ~Q.positive, ~Q.negative \| ~Q.zero, ~Q.positive \| ~Q.zero, Q.even \| Q.odd \| ~Q.integer, Q.infinite \| Q.real \| ~Q.extended_real, Q.lower_triangular \| Q.upper_triangular \| ~Q.triangular, Q.negative \| Q.positive \| ~Q.nonzero, Q.negative \| Q.zero \| ~Q.nonpositive, Q.positive \| Q.zero \| ~Q.nonnegative, Q.diagonal \| ~Q.lower_triangular \| ~Q.upper_triangular, Q.invertible \| ~Q.fullrank \| ~Q.square, Q.orthogonal \| ~Q.real \| ~Q.unitary, Q.negative \| Q.positive \| Q.zero \| ~Q.real, Q.algebraic \| Q.transcendental \| ~Q.complex \| ~Q.finite, Q.composite \| Q.prime \| ~Q.integer \| ~Q.positive, Q.irrational \| Q.rational \| ~Q.finite \| ~Q.real ) # -{ Known facts in compressed sets }- @cacheit def get_known_facts_dict(): return { Q.algebraic: set([Q.algebraic, Q.complex, Q.finite]), Q.antihermitian: set([Q.antihermitian]), Q.commutative: set([Q.commutative]), Q.complex: set([Q.complex]), Q.complex_elements: set([Q.complex_elements]), Q.composite: set([Q.composite]), Q.diagonal: set([Q.diagonal, Q.lower_triangular, Q.normal, Q.square, Q.symmetric, Q.triangular, Q.upper_triangular]), Q.even: set([Q.algebraic, Q.complex, Q.even, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.rational, Q.real]), Q.extended_real: set([Q.extended_real]), Q.finite: set([Q.finite]), Q.fullrank: set([Q.fullrank]), Q.hermitian: set([Q.hermitian]), Q.imaginary: set([Q.antihermitian, Q.complex, Q.imaginary]), Q.infinite: set([Q.extended_real, Q.infinite]), Q.integer: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.rational, Q.real]), Q.integer_elements: set([Q.complex_elements, Q.integer_elements, Q.real_elements]), Q.invertible: set([Q.fullrank, Q.invertible, Q.square]), Q.irrational: set([Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.irrational, Q.nonzero, Q.real]), Q.is_true: set([Q.is_true]), Q.lower_triangular: set([Q.lower_triangular, Q.triangular]), Q.negative: set([Q.complex, Q.extended_real, Q.hermitian, Q.negative, Q.nonpositive, Q.nonzero, Q.real]), Q.nonnegative: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonnegative, Q.real]), Q.nonpositive: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonpositive, Q.real]), Q.nonzero: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonzero, Q.real]), Q.normal: set([Q.normal, Q.square]), Q.odd: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.nonzero, Q.odd, Q.rational, Q.real]), Q.orthogonal: set([Q.fullrank, Q.invertible, Q.normal, Q.orthogonal, Q.positive_definite, Q.square, Q.unitary]), Q.positive: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonnegative, Q.nonzero, Q.positive, Q.real]), Q.positive_definite: set([Q.fullrank, Q.invertible, Q.positive_definite, Q.square]), Q.prime: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.nonnegative, Q.nonzero, Q.positive, Q.prime, Q.rational, Q.real]), Q.rational: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.rational, Q.real]), Q.real: set([Q.complex, Q.extended_real, Q.hermitian, Q.real]), Q.real_elements: set([Q.complex_elements, Q.real_elements]), Q.singular: set([Q.singular]), Q.square: set([Q.square]), Q.symmetric: set([Q.square, Q.symmetric]), Q.transcendental: set([Q.complex, Q.finite, Q.transcendental]), Q.triangular: set([Q.triangular]), Q.unit_triangular: set([Q.triangular, Q.unit_triangular]), Q.unitary: set([Q.fullrank, Q.invertible, Q.normal, Q.square, Q.unitary]), Q.upper_triangular: set([Q.triangular, Q.upper_triangular]), Q.zero: set([Q.algebraic, Q.complex, Q.even, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.nonnegative, Q.nonpositive, Q.rational, Q.real, Q.zero]), }
95bdf8a63ba0db1226ee70918028f8fe97f2b36d6b877869502d8e40589b8871	"""Module for querying SymPy objects about assumptions.""" from __future__ import print_function, division from sympy.assumptions.assume import (global_assumptions, Predicate, AppliedPredicate) from sympy.core import sympify from sympy.core.cache import cacheit from sympy.core.decorators import deprecated from sympy.core.relational import Relational from sympy.logic.boolalg import (to_cnf, And, Not, Or, Implies, Equivalent, BooleanFunction, BooleanAtom) from sympy.logic.inference import satisfiable from sympy.utilities.decorator import memoize_property # Deprecated predicates should be added to this list deprecated_predicates = [ 'bounded', 'infinity', 'infinitesimal' ] # Memoization storage for predicates predicate_storage = {} predicate_memo = memoize_property(predicate_storage) # Memoization is necessary for the properties of AssumptionKeys to # ensure that only one object of Predicate objects are created. # This is because assumption handlers are registered on those objects. class AssumptionKeys(object): """ This class contains all the supported keys by ``ask``. """ @predicate_memo def hermitian(self): """ Hermitian predicate. ``ask(Q.hermitian(x))`` is true iff ``x`` belongs to the set of Hermitian operators. References ========== .. [1] http://mathworld.wolfram.com/HermitianOperator.html """ # TODO: Add examples return Predicate('hermitian') @predicate_memo def antihermitian(self): """ Antihermitian predicate. ``Q.antihermitian(x)`` is true iff ``x`` belongs to the field of antihermitian operators, i.e., operators in the form ``xI``, where ``x`` is Hermitian. References ========== .. [1] http://mathworld.wolfram.com/HermitianOperator.html """ # TODO: Add examples return Predicate('antihermitian') @predicate_memo def real(self): r""" Real number predicate. ``Q.real(x)`` is true iff ``x`` is a real number, i.e., it is in the interval `(-\infty, \infty)`. Note that, in particular the infinities are not real. Use ``Q.extended_real`` if you want to consider those as well. A few important facts about reals: - Every real number is positive, negative, or zero. Furthermore, because these sets are pairwise disjoint, each real number is exactly one of those three. - Every real number is also complex. - Every real number is finite. - Every real number is either rational or irrational. - Every real number is either algebraic or transcendental. - The facts ``Q.negative``, ``Q.zero``, ``Q.positive``, ``Q.nonnegative``, ``Q.nonpositive``, ``Q.nonzero``, ``Q.integer``, ``Q.rational``, and ``Q.irrational`` all imply ``Q.real``, as do all facts that imply those facts. - The facts ``Q.algebraic``, and ``Q.transcendental`` do not imply ``Q.real``; they imply ``Q.complex``. An algebraic or transcendental number may or may not be real. - The "non" facts (i.e., ``Q.nonnegative``, ``Q.nonzero``, ``Q.nonpositive`` and ``Q.noninteger``) are not equivalent to not the fact, but rather, not the fact and* ``Q.real``. For example, ``Q.nonnegative`` means ``~Q.negative & Q.real``. So for example, ``I`` is not nonnegative, nonzero, or nonpositive. Examples ======== >>> from sympy import Q, ask, symbols >>> x = symbols('x') >>> ask(Q.real(x), Q.positive(x)) True >>> ask(Q.real(0)) True References ========== .. [1] https://en.wikipedia.org/wiki/Real_number """ return Predicate('real') @predicate_memo def extended_real(self): r""" Extended real predicate. ``Q.extended_real(x)`` is true iff ``x`` is a real number or `\{-\infty, \infty\}`. See documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import ask, Q, oo, I >>> ask(Q.extended_real(1)) True >>> ask(Q.extended_real(I)) False >>> ask(Q.extended_real(oo)) True """ return Predicate('extended_real') @predicate_memo def imaginary(self): """ Imaginary number predicate. ``Q.imaginary(x)`` is true iff ``x`` can be written as a real number multiplied by the imaginary unit ``I``. Please note that ``0`` is not considered to be an imaginary number. Examples ======== >>> from sympy import Q, ask, I >>> ask(Q.imaginary(3I)) True >>> ask(Q.imaginary(2 + 3I)) False >>> ask(Q.imaginary(0)) False References ========== .. [1] https://en.wikipedia.org/wiki/Imaginary_number """ return Predicate('imaginary') @predicate_memo def complex(self): """ Complex number predicate. ``Q.complex(x)`` is true iff ``x`` belongs to the set of complex numbers. Note that every complex number is finite. Examples ======== >>> from sympy import Q, Symbol, ask, I, oo >>> x = Symbol('x') >>> ask(Q.complex(0)) True >>> ask(Q.complex(2 + 3I)) True >>> ask(Q.complex(oo)) False References ========== .. [1] https://en.wikipedia.org/wiki/Complex_number """ return Predicate('complex') @predicate_memo def algebraic(self): r""" Algebraic number predicate. ``Q.algebraic(x)`` is true iff ``x`` belongs to the set of algebraic numbers. ``x`` is algebraic if there is some polynomial in ``p(x)\in \mathbb\{Q\}[x]`` such that ``p(x) = 0``. Examples ======== >>> from sympy import ask, Q, sqrt, I, pi >>> ask(Q.algebraic(sqrt(2))) True >>> ask(Q.algebraic(I)) True >>> ask(Q.algebraic(pi)) False References ========== .. [1] https://en.wikipedia.org/wiki/Algebraic_number """ return Predicate('algebraic') @predicate_memo def transcendental(self): """ Transcedental number predicate. ``Q.transcendental(x)`` is true iff ``x`` belongs to the set of transcendental numbers. A transcendental number is a real or complex number that is not algebraic. """ # TODO: Add examples return Predicate('transcendental') @predicate_memo def integer(self): """ Integer predicate. ``Q.integer(x)`` is true iff ``x`` belongs to the set of integer numbers. Examples ======== >>> from sympy import Q, ask, S >>> ask(Q.integer(5)) True >>> ask(Q.integer(S(1)/2)) False References ========== .. [1] https://en.wikipedia.org/wiki/Integer """ return Predicate('integer') @predicate_memo def rational(self): """ Rational number predicate. ``Q.rational(x)`` is true iff ``x`` belongs to the set of rational numbers. Examples ======== >>> from sympy import ask, Q, pi, S >>> ask(Q.rational(0)) True >>> ask(Q.rational(S(1)/2)) True >>> ask(Q.rational(pi)) False References ========== https://en.wikipedia.org/wiki/Rational_number """ return Predicate('rational') @predicate_memo def irrational(self): """ Irrational number predicate. ``Q.irrational(x)`` is true iff ``x`` is any real number that cannot be expressed as a ratio of integers. Examples ======== >>> from sympy import ask, Q, pi, S, I >>> ask(Q.irrational(0)) False >>> ask(Q.irrational(S(1)/2)) False >>> ask(Q.irrational(pi)) True >>> ask(Q.irrational(I)) False References ========== .. [1] https://en.wikipedia.org/wiki/Irrational_number """ return Predicate('irrational') @predicate_memo def finite(self): """ Finite predicate. ``Q.finite(x)`` is true if ``x`` is neither an infinity nor a ``NaN``. In other words, ``ask(Q.finite(x))`` is true for all ``x`` having a bounded absolute value. Examples ======== >>> from sympy import Q, ask, Symbol, S, oo, I >>> x = Symbol('x') >>> ask(Q.finite(S.NaN)) False >>> ask(Q.finite(oo)) False >>> ask(Q.finite(1)) True >>> ask(Q.finite(2 + 3I)) True References ========== .. [1] https://en.wikipedia.org/wiki/Finite """ return Predicate('finite') @predicate_memo @deprecated(useinstead="finite", issue=9425, deprecated_since_version="1.0") def bounded(self): """ See documentation of ``Q.finite``. """ return Predicate('finite') @predicate_memo def infinite(self): """ Infinite number predicate. ``Q.infinite(x)`` is true iff the absolute value of ``x`` is infinity. """ # TODO: Add examples return Predicate('infinite') @predicate_memo @deprecated(useinstead="infinite", issue=9426, deprecated_since_version="1.0") def infinity(self): """ See documentation of ``Q.infinite``. """ return Predicate('infinite') @predicate_memo @deprecated(useinstead="zero", issue=9675, deprecated_since_version="1.0") def infinitesimal(self): """ See documentation of ``Q.zero``. """ return Predicate('zero') @predicate_memo def positive(self): r""" Positive real number predicate. ``Q.positive(x)`` is true iff ``x`` is real and `x > 0`, that is if ``x`` is in the interval `(0, \infty)`. In particular, infinity is not positive. A few important facts about positive numbers: - Note that ``Q.nonpositive`` and ``~Q.positive`` are not the same thing. ``~Q.positive(x)`` simply means that ``x`` is not positive, whereas ``Q.nonpositive(x)`` means that ``x`` is real and not positive, i.e., ``Q.nonpositive(x)`` is logically equivalent to `Q.negative(x) \| Q.zero(x)``. So for example, ``~Q.positive(I)`` is true, whereas ``Q.nonpositive(I)`` is false. - See the documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import Q, ask, symbols, I >>> x = symbols('x') >>> ask(Q.positive(x), Q.real(x) & ~Q.negative(x) & ~Q.zero(x)) True >>> ask(Q.positive(1)) True >>> ask(Q.nonpositive(I)) False >>> ask(~Q.positive(I)) True """ return Predicate('positive') @predicate_memo def negative(self): r""" Negative number predicate. ``Q.negative(x)`` is true iff ``x`` is a real number and :math:`x < 0`, that is, it is in the interval :math:`(-\infty, 0)`. Note in particular that negative infinity is not negative. A few important facts about negative numbers: - Note that ``Q.nonnegative`` and ``~Q.negative`` are not the same thing. ``~Q.negative(x)`` simply means that ``x`` is not negative, whereas ``Q.nonnegative(x)`` means that ``x`` is real and not negative, i.e., ``Q.nonnegative(x)`` is logically equivalent to ``Q.zero(x) \| Q.positive(x)``. So for example, ``~Q.negative(I)`` is true, whereas ``Q.nonnegative(I)`` is false. - See the documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import Q, ask, symbols, I >>> x = symbols('x') >>> ask(Q.negative(x), Q.real(x) & ~Q.positive(x) & ~Q.zero(x)) True >>> ask(Q.negative(-1)) True >>> ask(Q.nonnegative(I)) False >>> ask(~Q.negative(I)) True """ return Predicate('negative') @predicate_memo def zero(self): """ Zero number predicate. ``ask(Q.zero(x))`` is true iff the value of ``x`` is zero. Examples ======== >>> from sympy import ask, Q, oo, symbols >>> x, y = symbols('x, y') >>> ask(Q.zero(0)) True >>> ask(Q.zero(1/oo)) True >>> ask(Q.zero(0oo)) False >>> ask(Q.zero(1)) False >>> ask(Q.zero(xy), Q.zero(x) \| Q.zero(y)) True """ return Predicate('zero') @predicate_memo def nonzero(self): """ Nonzero real number predicate. ``ask(Q.nonzero(x))`` is true iff ``x`` is real and ``x`` is not zero. Note in particular that ``Q.nonzero(x)`` is false if ``x`` is not real. Use ``~Q.zero(x)`` if you want the negation of being zero without any real assumptions. A few important facts about nonzero numbers: - ``Q.nonzero`` is logically equivalent to ``Q.positive \| Q.negative``. - See the documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import Q, ask, symbols, I, oo >>> x = symbols('x') >>> print(ask(Q.nonzero(x), ~Q.zero(x))) None >>> ask(Q.nonzero(x), Q.positive(x)) True >>> ask(Q.nonzero(x), Q.zero(x)) False >>> ask(Q.nonzero(0)) False >>> ask(Q.nonzero(I)) False >>> ask(~Q.zero(I)) True >>> ask(Q.nonzero(oo)) #doctest: +SKIP False """ return Predicate('nonzero') @predicate_memo def nonpositive(self): """ Nonpositive real number predicate. ``ask(Q.nonpositive(x))`` is true iff ``x`` belongs to the set of negative numbers including zero. - Note that ``Q.nonpositive`` and ``~Q.positive`` are not the same thing. ``~Q.positive(x)`` simply means that ``x`` is not positive, whereas ``Q.nonpositive(x)`` means that ``x`` is real and not positive, i.e., ``Q.nonpositive(x)`` is logically equivalent to `Q.negative(x) \| Q.zero(x)``. So for example, ``~Q.positive(I)`` is true, whereas ``Q.nonpositive(I)`` is false. Examples ======== >>> from sympy import Q, ask, I >>> ask(Q.nonpositive(-1)) True >>> ask(Q.nonpositive(0)) True >>> ask(Q.nonpositive(1)) False >>> ask(Q.nonpositive(I)) False >>> ask(Q.nonpositive(-I)) False """ return Predicate('nonpositive') @predicate_memo def nonnegative(self): """ Nonnegative real number predicate. ``ask(Q.nonnegative(x))`` is true iff ``x`` belongs to the set of positive numbers including zero. - Note that ``Q.nonnegative`` and ``~Q.negative`` are not the same thing. ``~Q.negative(x)`` simply means that ``x`` is not negative, whereas ``Q.nonnegative(x)`` means that ``x`` is real and not negative, i.e., ``Q.nonnegative(x)`` is logically equivalent to ``Q.zero(x) \| Q.positive(x)``. So for example, ``~Q.negative(I)`` is true, whereas ``Q.nonnegative(I)`` is false. Examples ======== >>> from sympy import Q, ask, I >>> ask(Q.nonnegative(1)) True >>> ask(Q.nonnegative(0)) True >>> ask(Q.nonnegative(-1)) False >>> ask(Q.nonnegative(I)) False >>> ask(Q.nonnegative(-I)) False """ return Predicate('nonnegative') @predicate_memo def even(self): """ Even number predicate. ``ask(Q.even(x))`` is true iff ``x`` belongs to the set of even integers. Examples ======== >>> from sympy import Q, ask, pi >>> ask(Q.even(0)) True >>> ask(Q.even(2)) True >>> ask(Q.even(3)) False >>> ask(Q.even(pi)) False """ return Predicate('even') @predicate_memo def odd(self): """ Odd number predicate. ``ask(Q.odd(x))`` is true iff ``x`` belongs to the set of odd numbers. Examples ======== >>> from sympy import Q, ask, pi >>> ask(Q.odd(0)) False >>> ask(Q.odd(2)) False >>> ask(Q.odd(3)) True >>> ask(Q.odd(pi)) False """ return Predicate('odd') @predicate_memo def prime(self): """ Prime number predicate. ``ask(Q.prime(x))`` is true iff ``x`` is a natural number greater than 1 that has no positive divisors other than ``1`` and the number itself. Examples ======== >>> from sympy import Q, ask >>> ask(Q.prime(0)) False >>> ask(Q.prime(1)) False >>> ask(Q.prime(2)) True >>> ask(Q.prime(20)) False >>> ask(Q.prime(-3)) False """ return Predicate('prime') @predicate_memo def composite(self): """ Composite number predicate. ``ask(Q.composite(x))`` is true iff ``x`` is a positive integer and has at least one positive divisor other than ``1`` and the number itself. Examples ======== >>> from sympy import Q, ask >>> ask(Q.composite(0)) False >>> ask(Q.composite(1)) False >>> ask(Q.composite(2)) False >>> ask(Q.composite(20)) True """ return Predicate('composite') @predicate_memo def commutative(self): """ Commutative predicate. ``ask(Q.commutative(x))`` is true iff ``x`` commutes with any other object with respect to multiplication operation. """ # TODO: Add examples return Predicate('commutative') @predicate_memo def is_true(self): """ Generic predicate. ``ask(Q.is_true(x))`` is true iff ``x`` is true. This only makes sense if ``x`` is a predicate. Examples ======== >>> from sympy import ask, Q, symbols >>> x = symbols('x') >>> ask(Q.is_true(True)) True """ return Predicate('is_true') @predicate_memo def symmetric(self): """ Symmetric matrix predicate. ``Q.symmetric(x)`` is true iff ``x`` is a square matrix and is equal to its transpose. Every square diagonal matrix is a symmetric matrix. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.symmetric(XZ), Q.symmetric(X) & Q.symmetric(Z)) True >>> ask(Q.symmetric(X + Z), Q.symmetric(X) & Q.symmetric(Z)) True >>> ask(Q.symmetric(Y)) False References ========== .. [1] https://en.wikipedia.org/wiki/Symmetric_matrix """ # TODO: Add handlers to make these keys work with # actual matrices and add more examples in the docstring. return Predicate('symmetric') @predicate_memo def invertible(self): """ Invertible matrix predicate. ``Q.invertible(x)`` is true iff ``x`` is an invertible matrix. A square matrix is called invertible only if its determinant is 0. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.invertible(XY), Q.invertible(X)) False >>> ask(Q.invertible(XZ), Q.invertible(X) & Q.invertible(Z)) True >>> ask(Q.invertible(X), Q.fullrank(X) & Q.square(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Invertible_matrix """ return Predicate('invertible') @predicate_memo def orthogonal(self): """ Orthogonal matrix predicate. ``Q.orthogonal(x)`` is true iff ``x`` is an orthogonal matrix. A square matrix ``M`` is an orthogonal matrix if it satisfies ``M^TM = MM^T = I`` where ``M^T`` is the transpose matrix of ``M`` and ``I`` is an identity matrix. Note that an orthogonal matrix is necessarily invertible. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.orthogonal(Y)) False >>> ask(Q.orthogonal(XZX), Q.orthogonal(X) & Q.orthogonal(Z)) True >>> ask(Q.orthogonal(Identity(3))) True >>> ask(Q.invertible(X), Q.orthogonal(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Orthogonal_matrix """ return Predicate('orthogonal') @predicate_memo def unitary(self): """ Unitary matrix predicate. ``Q.unitary(x)`` is true iff ``x`` is a unitary matrix. Unitary matrix is an analogue to orthogonal matrix. A square matrix ``M`` with complex elements is unitary if :math:``M^TM = MM^T= I`` where :math:``M^T`` is the conjugate transpose matrix of ``M``. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.unitary(Y)) False >>> ask(Q.unitary(XZX), Q.unitary(X) & Q.unitary(Z)) True >>> ask(Q.unitary(Identity(3))) True References ========== .. [1] https://en.wikipedia.org/wiki/Unitary_matrix """ return Predicate('unitary') @predicate_memo def positive_definite(self): r""" Positive definite matrix predicate. If ``M`` is a :math:``n \times n`` symmetric real matrix, it is said to be positive definite if :math:`Z^TMZ` is positive for every non-zero column vector ``Z`` of ``n`` real numbers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.positive_definite(Y)) False >>> ask(Q.positive_definite(Identity(3))) True >>> ask(Q.positive_definite(X + Z), Q.positive_definite(X) & ... Q.positive_definite(Z)) True References ========== .. [1] https://en.wikipedia.org/wiki/Positive-definite_matrix """ return Predicate('positive_definite') @predicate_memo def upper_triangular(self): """ Upper triangular matrix predicate. A matrix ``M`` is called upper triangular matrix if :math:`M_{ij}=0` for :math:`i<j`. Examples ======== >>> from sympy import Q, ask, ZeroMatrix, Identity >>> ask(Q.upper_triangular(Identity(3))) True >>> ask(Q.upper_triangular(ZeroMatrix(3, 3))) True References ========== .. [1] http://mathworld.wolfram.com/UpperTriangularMatrix.html """ return Predicate('upper_triangular') @predicate_memo def lower_triangular(self): """ Lower triangular matrix predicate. A matrix ``M`` is called lower triangular matrix if :math:`a_{ij}=0` for :math:`i>j`. Examples ======== >>> from sympy import Q, ask, ZeroMatrix, Identity >>> ask(Q.lower_triangular(Identity(3))) True >>> ask(Q.lower_triangular(ZeroMatrix(3, 3))) True References ========== .. [1] http://mathworld.wolfram.com/LowerTriangularMatrix.html """ return Predicate('lower_triangular') @predicate_memo def diagonal(self): """ Diagonal matrix predicate. ``Q.diagonal(x)`` is true iff ``x`` is a diagonal matrix. A diagonal matrix is a matrix in which the entries outside the main diagonal are all zero. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, ZeroMatrix >>> X = MatrixSymbol('X', 2, 2) >>> ask(Q.diagonal(ZeroMatrix(3, 3))) True >>> ask(Q.diagonal(X), Q.lower_triangular(X) & ... Q.upper_triangular(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Diagonal_matrix """ return Predicate('diagonal') @predicate_memo def fullrank(self): """ Fullrank matrix predicate. ``Q.fullrank(x)`` is true iff ``x`` is a full rank matrix. A matrix is full rank if all rows and columns of the matrix are linearly independent. A square matrix is full rank iff its determinant is nonzero. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, ZeroMatrix, Identity >>> X = MatrixSymbol('X', 2, 2) >>> ask(Q.fullrank(X.T), Q.fullrank(X)) True >>> ask(Q.fullrank(ZeroMatrix(3, 3))) False >>> ask(Q.fullrank(Identity(3))) True """ return Predicate('fullrank') @predicate_memo def square(self): """ Square matrix predicate. ``Q.square(x)`` is true iff ``x`` is a square matrix. A square matrix is a matrix with the same number of rows and columns. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, ZeroMatrix, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('X', 2, 3) >>> ask(Q.square(X)) True >>> ask(Q.square(Y)) False >>> ask(Q.square(ZeroMatrix(3, 3))) True >>> ask(Q.square(Identity(3))) True References ========== .. [1] https://en.wikipedia.org/wiki/Square_matrix """ return Predicate('square') @predicate_memo def integer_elements(self): """ Integer elements matrix predicate. ``Q.integer_elements(x)`` is true iff all the elements of ``x`` are integers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.integer(X[1, 2]), Q.integer_elements(X)) True """ return Predicate('integer_elements') @predicate_memo def real_elements(self): """ Real elements matrix predicate. ``Q.real_elements(x)`` is true iff all the elements of ``x`` are real numbers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.real(X[1, 2]), Q.real_elements(X)) True """ return Predicate('real_elements') @predicate_memo def complex_elements(self): """ Complex elements matrix predicate. ``Q.complex_elements(x)`` is true iff all the elements of ``x`` are complex numbers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.complex(X[1, 2]), Q.complex_elements(X)) True >>> ask(Q.complex_elements(X), Q.integer_elements(X)) True """ return Predicate('complex_elements') @predicate_memo def singular(self): """ Singular matrix predicate. A matrix is singular iff the value of its determinant is 0. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.singular(X), Q.invertible(X)) False >>> ask(Q.singular(X), ~Q.invertible(X)) True References ========== .. [1] http://mathworld.wolfram.com/SingularMatrix.html """ return Predicate('singular') @predicate_memo def normal(self): """ Normal matrix predicate. A matrix is normal if it commutes with its conjugate transpose. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.normal(X), Q.unitary(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Normal_matrix """ return Predicate('normal') @predicate_memo def triangular(self): """ Triangular matrix predicate. ``Q.triangular(X)`` is true if ``X`` is one that is either lower triangular or upper triangular. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.triangular(X), Q.upper_triangular(X)) True >>> ask(Q.triangular(X), Q.lower_triangular(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Triangular_matrix """ return Predicate('triangular') @predicate_memo def unit_triangular(self): """ Unit triangular matrix predicate. A unit triangular matrix is a triangular matrix with 1s on the diagonal. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.triangular(X), Q.unit_triangular(X)) True """ return Predicate('unit_triangular') Q = AssumptionKeys() def _extract_facts(expr, symbol, check_reversed_rel=True): """ Helper for ask(). Extracts the facts relevant to the symbol from an assumption. Returns None if there is nothing to extract. """ if isinstance(symbol, Relational): if check_reversed_rel: rev = _extract_facts(expr, symbol.reversed, False) if rev is not None: return rev if isinstance(expr, bool): return if not expr.has(symbol): return if isinstance(expr, AppliedPredicate): if expr.arg == symbol: return expr.func else: return if isinstance(expr, Not) and expr.args[0].func in (And, Or): cls = Or if expr.args[0] == And else And expr = cls([~arg for arg in expr.args[0].args]) args = [_extract_facts(arg, symbol) for arg in expr.args] if isinstance(expr, And): args = [x for x in args if x is not None] if args: return expr.func(args) if args and all(x is not None for x in args): return expr.func(args) def ask(proposition, assumptions=True, context=global_assumptions): """ Method for inferring properties about objects. Syntax * ask(proposition) * ask(proposition, assumptions) where ``proposition`` is any boolean expression Examples ======== >>> from sympy import ask, Q, pi >>> from sympy.abc import x, y >>> ask(Q.rational(pi)) False >>> ask(Q.even(xy), Q.even(x) & Q.integer(y)) True >>> ask(Q.prime(4x), Q.integer(x)) False Remarks Relations in assumptions are not implemented (yet), so the following will not give a meaningful result. >>> ask(Q.positive(x), Q.is_true(x > 0)) # doctest: +SKIP It is however a work in progress. """ from sympy.assumptions.satask import satask if not isinstance(proposition, (BooleanFunction, AppliedPredicate, bool, BooleanAtom)): raise TypeError("proposition must be a valid logical expression") if not isinstance(assumptions, (BooleanFunction, AppliedPredicate, bool, BooleanAtom)): raise TypeError("assumptions must be a valid logical expression") if isinstance(proposition, AppliedPredicate): key, expr = proposition.func, sympify(proposition.arg) else: key, expr = Q.is_true, sympify(proposition) assumptions = And(assumptions, And(context)) assumptions = to_cnf(assumptions) local_facts = _extract_facts(assumptions, expr) known_facts_cnf = get_known_facts_cnf() known_facts_dict = get_known_facts_dict() if local_facts and satisfiable(And(local_facts, known_facts_cnf)) is False: raise ValueError("inconsistent assumptions %s" % assumptions) # direct resolution method, no logic res = key(expr)._eval_ask(assumptions) if res is not None: return bool(res) if local_facts is None: return satask(proposition, assumptions=assumptions, context=context) # See if there's a straight-forward conclusion we can make for the inference if local_facts.is_Atom: if key in known_facts_dict[local_facts]: return True if Not(key) in known_facts_dict[local_facts]: return False elif (isinstance(local_facts, And) and all(k in known_facts_dict for k in local_facts.args)): for assum in local_facts.args: if assum.is_Atom: if key in known_facts_dict[assum]: return True if Not(key) in known_facts_dict[assum]: return False elif isinstance(assum, Not) and assum.args[0].is_Atom: if key in known_facts_dict[assum]: return False if Not(key) in known_facts_dict[assum]: return True elif (isinstance(key, Predicate) and isinstance(local_facts, Not) and local_facts.args[0].is_Atom): if local_facts.args[0] in known_facts_dict[key]: return False # Failing all else, we do a full logical inference res = ask_full_inference(key, local_facts, known_facts_cnf) if res is None: return satask(proposition, assumptions=assumptions, context=context) return res def ask_full_inference(proposition, assumptions, known_facts_cnf): """ Method for inferring properties about objects. """ if not satisfiable(And(known_facts_cnf, assumptions, proposition)): return False if not satisfiable(And(known_facts_cnf, assumptions, Not(proposition))): return True return None def register_handler(key, handler): """ Register a handler in the ask system. key must be a string and handler a class inheriting from AskHandler:: >>> from sympy.assumptions import register_handler, ask, Q >>> from sympy.assumptions.handlers import AskHandler >>> class MersenneHandler(AskHandler): ... # Mersenne numbers are in the form 2n - 1, n integer ... @staticmethod ... def Integer(expr, assumptions): ... from sympy import log ... return ask(Q.integer(log(expr + 1, 2))) >>> register_handler('mersenne', MersenneHandler) >>> ask(Q.mersenne(7)) True """ if type(key) is Predicate: key = key.name Qkey = getattr(Q, key, None) if Qkey is not None: Qkey.add_handler(handler) else: setattr(Q, key, Predicate(key, handlers=[handler])) def remove_handler(key, handler): """Removes a handler from the ask system. Same syntax as register_handler""" if type(key) is Predicate: key = key.name getattr(Q, key).remove_handler(handler) def single_fact_lookup(known_facts_keys, known_facts_cnf): # Compute the quick lookup for single facts mapping = {} for key in known_facts_keys: mapping[key] = {key} for other_key in known_facts_keys: if other_key != key: if ask_full_inference(other_key, key, known_facts_cnf): mapping[key].add(other_key) return mapping def compute_known_facts(known_facts, known_facts_keys): """Compute the various forms of knowledge compilation used by the assumptions system. This function is typically applied to the results of the ``get_known_facts`` and ``get_known_facts_keys`` functions defined at the bottom of this file. """ from textwrap import dedent, wrap fact_string = dedent('''\ """ The contents of this file are the return value of ``sympy.assumptions.ask.compute_known_facts``. Do NOT manually edit this file. Instead, run ./bin/ask_update.py. """ from sympy.core.cache import cacheit from sympy.logic.boolalg import And from sympy.assumptions.ask import Q # -{ Known facts in Conjunctive Normal Form }- @cacheit def get_known_facts_cnf(): return And( %s ) # -{ Known facts in compressed sets }- @cacheit def get_known_facts_dict(): return { %s } ''') # Compute the known facts in CNF form for logical inference LINE = ",\n " HANG = ' '8 cnf = to_cnf(known_facts) c = LINE.join([str(a) for a in cnf.args]) mapping = single_fact_lookup(known_facts_keys, cnf) items = sorted(mapping.items(), key=str) keys = [str(i[0]) for i in items] values = ['set(%s)' % sorted(i[1], key=str) for i in items] m = LINE.join(['\n'.join( wrap("%s: %s" % (k, v), subsequent_indent=HANG, break_long_words=False)) for k, v in zip(keys, values)]) + ',' return fact_string % (c, m) # handlers tells us what ask handler we should use # for a particular key _val_template = 'sympy.assumptions.handlers.%s' _handlers = [ ("antihermitian", "sets.AskAntiHermitianHandler"), ("finite", "calculus.AskFiniteHandler"), ("commutative", "AskCommutativeHandler"), ("complex", "sets.AskComplexHandler"), ("composite", "ntheory.AskCompositeHandler"), ("even", "ntheory.AskEvenHandler"), ("extended_real", "sets.AskExtendedRealHandler"), ("hermitian", "sets.AskHermitianHandler"), ("imaginary", "sets.AskImaginaryHandler"), ("integer", "sets.AskIntegerHandler"), ("irrational", "sets.AskIrrationalHandler"), ("rational", "sets.AskRationalHandler"), ("negative", "order.AskNegativeHandler"), ("nonzero", "order.AskNonZeroHandler"), ("nonpositive", "order.AskNonPositiveHandler"), ("nonnegative", "order.AskNonNegativeHandler"), ("zero", "order.AskZeroHandler"), ("positive", "order.AskPositiveHandler"), ("prime", "ntheory.AskPrimeHandler"), ("real", "sets.AskRealHandler"), ("odd", "ntheory.AskOddHandler"), ("algebraic", "sets.AskAlgebraicHandler"), ("is_true", "common.TautologicalHandler"), ("symmetric", "matrices.AskSymmetricHandler"), ("invertible", "matrices.AskInvertibleHandler"), ("orthogonal", "matrices.AskOrthogonalHandler"), ("unitary", "matrices.AskUnitaryHandler"), ("positive_definite", "matrices.AskPositiveDefiniteHandler"), ("upper_triangular", "matrices.AskUpperTriangularHandler"), ("lower_triangular", "matrices.AskLowerTriangularHandler"), ("diagonal", "matrices.AskDiagonalHandler"), ("fullrank", "matrices.AskFullRankHandler"), ("square", "matrices.AskSquareHandler"), ("integer_elements", "matrices.AskIntegerElementsHandler"), ("real_elements", "matrices.AskRealElementsHandler"), ("complex_elements", "matrices.AskComplexElementsHandler"), ] for name, value in _handlers: register_handler(name, _val_template % value) @cacheit def get_known_facts_keys(): return [ getattr(Q, attr) for attr in Q.__class__.__dict__ if not (attr.startswith('__') or attr in deprecated_predicates)] @cacheit def get_known_facts(): return And( Implies(Q.infinite, ~Q.finite), Implies(Q.real, Q.complex), Implies(Q.real, Q.hermitian), Equivalent(Q.extended_real, Q.real \| Q.infinite), Equivalent(Q.even \| Q.odd, Q.integer), Implies(Q.even, ~Q.odd), Equivalent(Q.prime, Q.integer & Q.positive & ~Q.composite), Implies(Q.integer, Q.rational), Implies(Q.rational, Q.algebraic), Implies(Q.irrational, Q.finite), Implies(Q.algebraic, Q.complex), Implies(Q.algebraic, Q.finite), Equivalent(Q.transcendental \| Q.algebraic, Q.complex & Q.finite), Implies(Q.transcendental, ~Q.algebraic), Implies(Q.transcendental, Q.finite), Implies(Q.imaginary, Q.complex & ~Q.real), Implies(Q.imaginary, Q.antihermitian), Implies(Q.antihermitian, ~Q.hermitian), Equivalent(Q.irrational \| Q.rational, Q.real & Q.finite), Implies(Q.irrational, ~Q.rational), Implies(Q.zero, Q.even), Equivalent(Q.real, Q.negative \| Q.zero \| Q.positive), Implies(Q.zero, ~Q.negative & ~Q.positive), Implies(Q.negative, ~Q.positive), Equivalent(Q.nonnegative, Q.zero \| Q.positive), Equivalent(Q.nonpositive, Q.zero \| Q.negative), Equivalent(Q.nonzero, Q.negative \| Q.positive), Implies(Q.orthogonal, Q.positive_definite), Implies(Q.orthogonal, Q.unitary), Implies(Q.unitary & Q.real, Q.orthogonal), Implies(Q.unitary, Q.normal), Implies(Q.unitary, Q.invertible), Implies(Q.normal, Q.square), Implies(Q.diagonal, Q.normal), Implies(Q.positive_definite, Q.invertible), Implies(Q.diagonal, Q.upper_triangular), Implies(Q.diagonal, Q.lower_triangular), Implies(Q.lower_triangular, Q.triangular), Implies(Q.upper_triangular, Q.triangular), Implies(Q.triangular, Q.upper_triangular \| Q.lower_triangular), Implies(Q.upper_triangular & Q.lower_triangular, Q.diagonal), Implies(Q.diagonal, Q.symmetric), Implies(Q.unit_triangular, Q.triangular), Implies(Q.invertible, Q.fullrank), Implies(Q.invertible, Q.square), Implies(Q.symmetric, Q.square), Implies(Q.fullrank & Q.square, Q.invertible), Equivalent(Q.invertible, ~Q.singular), Implies(Q.integer_elements, Q.real_elements), Implies(Q.real_elements, Q.complex_elements), ) from sympy.assumptions.ask_generated import ( get_known_facts_dict, get_known_facts_cnf)
0dacb82142d10b7b1d93490003fa36df812848b27cf23fde3e0f8e30bdba295f	r""" This module contains :py:meth:`~sympy.solvers.ode.dsolve` and different helper functions that it uses. :py:meth:`~sympy.solvers.ode.dsolve` solves ordinary differential equations. See the docstring on the various functions for their uses. Note that partial differential equations support is in ``pde.py``. Note that hint functions have docstrings describing their various methods, but they are intended for internal use. Use ``dsolve(ode, func, hint=hint)`` to solve an ODE using a specific hint. See also the docstring on :py:meth:`~sympy.solvers.ode.dsolve`. Functions in this module These are the user functions in this module: - :py:meth:`~sympy.solvers.ode.dsolve` - Solves ODEs. - :py:meth:`~sympy.solvers.ode.classify_ode` - Classifies ODEs into possible hints for :py:meth:`~sympy.solvers.ode.dsolve`. - :py:meth:`~sympy.solvers.ode.checkodesol` - Checks if an equation is the solution to an ODE. - :py:meth:`~sympy.solvers.ode.homogeneous_order` - Returns the homogeneous order of an expression. - :py:meth:`~sympy.solvers.ode.infinitesimals` - Returns the infinitesimals of the Lie group of point transformations of an ODE, such that it is invariant. - :py:meth:`~sympy.solvers.ode_checkinfsol` - Checks if the given infinitesimals are the actual infinitesimals of a first order ODE. These are the non-solver helper functions that are for internal use. The user should use the various options to :py:meth:`~sympy.solvers.ode.dsolve` to obtain the functionality provided by these functions: - :py:meth:`~sympy.solvers.ode.odesimp` - Does all forms of ODE simplification. - :py:meth:`~sympy.solvers.ode.ode_sol_simplicity` - A key function for comparing solutions by simplicity. - :py:meth:`~sympy.solvers.ode.constantsimp` - Simplifies arbitrary constants. - :py:meth:`~sympy.solvers.ode.constant_renumber` - Renumber arbitrary constants. - :py:meth:`~sympy.solvers.ode._handle_Integral` - Evaluate unevaluated Integrals. See also the docstrings of these functions. Currently implemented solver methods The following methods are implemented for solving ordinary differential equations. See the docstrings of the various hint functions for more information on each (run ``help(ode)``): - 1st order separable differential equations. - 1st order differential equations whose coefficients or `dx` and `dy` are functions homogeneous of the same order. - 1st order exact differential equations. - 1st order linear differential equations. - 1st order Bernoulli differential equations. - Power series solutions for first order differential equations. - Lie Group method of solving first order differential equations. - 2nd order Liouville differential equations. - Power series solutions for second order differential equations at ordinary and regular singular points. - `n`\th order differential equation that can be solved with algebraic rearrangement and integration. - `n`\th order linear homogeneous differential equation with constant coefficients. - `n`\th order linear inhomogeneous differential equation with constant coefficients using the method of undetermined coefficients. - `n`\th order linear inhomogeneous differential equation with constant coefficients using the method of variation of parameters. Philosophy behind this module This module is designed to make it easy to add new ODE solving methods without having to mess with the solving code for other methods. The idea is that there is a :py:meth:`~sympy.solvers.ode.classify_ode` function, which takes in an ODE and tells you what hints, if any, will solve the ODE. It does this without attempting to solve the ODE, so it is fast. Each solving method is a hint, and it has its own function, named ``ode_<hint>``. That function takes in the ODE and any match expression gathered by :py:meth:`~sympy.solvers.ode.classify_ode` and returns a solved result. If this result has any integrals in it, the hint function will return an unevaluated :py:class:`~sympy.integrals.Integral` class. :py:meth:`~sympy.solvers.ode.dsolve`, which is the user wrapper function around all of this, will then call :py:meth:`~sympy.solvers.ode.odesimp` on the result, which, among other things, will attempt to solve the equation for the dependent variable (the function we are solving for), simplify the arbitrary constants in the expression, and evaluate any integrals, if the hint allows it. How to add new solution methods If you have an ODE that you want :py:meth:`~sympy.solvers.ode.dsolve` to be able to solve, try to avoid adding special case code here. Instead, try finding a general method that will solve your ODE, as well as others. This way, the :py:mod:`~sympy.solvers.ode` module will become more robust, and unhindered by special case hacks. WolphramAlpha and Maple's DETools[odeadvisor] function are two resources you can use to classify a specific ODE. It is also better for a method to work with an `n`\th order ODE instead of only with specific orders, if possible. To add a new method, there are a few things that you need to do. First, you need a hint name for your method. Try to name your hint so that it is unambiguous with all other methods, including ones that may not be implemented yet. If your method uses integrals, also include a ``hint_Integral`` hint. If there is more than one way to solve ODEs with your method, include a hint for each one, as well as a ``<hint>_best`` hint. Your ``ode_<hint>_best()`` function should choose the best using min with ``ode_sol_simplicity`` as the key argument. See :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_best`, for example. The function that uses your method will be called ``ode_<hint>()``, so the hint must only use characters that are allowed in a Python function name (alphanumeric characters and the underscore '``_``' character). Include a function for every hint, except for ``_Integral`` hints (:py:meth:`~sympy.solvers.ode.dsolve` takes care of those automatically). Hint names should be all lowercase, unless a word is commonly capitalized (such as Integral or Bernoulli). If you have a hint that you do not want to run with ``all_Integral`` that doesn't have an ``_Integral`` counterpart (such as a best hint that would defeat the purpose of ``all_Integral``), you will need to remove it manually in the :py:meth:`~sympy.solvers.ode.dsolve` code. See also the :py:meth:`~sympy.solvers.ode.classify_ode` docstring for guidelines on writing a hint name. Determine in general how the solutions returned by your method compare with other methods that can potentially solve the same ODEs. Then, put your hints in the :py:data:`~sympy.solvers.ode.allhints` tuple in the order that they should be called. The ordering of this tuple determines which hints are default. Note that exceptions are ok, because it is easy for the user to choose individual hints with :py:meth:`~sympy.solvers.ode.dsolve`. In general, ``_Integral`` variants should go at the end of the list, and ``_best`` variants should go before the various hints they apply to. For example, the ``undetermined_coefficients`` hint comes before the ``variation_of_parameters`` hint because, even though variation of parameters is more general than undetermined coefficients, undetermined coefficients generally returns cleaner results for the ODEs that it can solve than variation of parameters does, and it does not require integration, so it is much faster. Next, you need to have a match expression or a function that matches the type of the ODE, which you should put in :py:meth:`~sympy.solvers.ode.classify_ode` (if the match function is more than just a few lines, like :py:meth:`~sympy.solvers.ode._undetermined_coefficients_match`, it should go outside of :py:meth:`~sympy.solvers.ode.classify_ode`). It should match the ODE without solving for it as much as possible, so that :py:meth:`~sympy.solvers.ode.classify_ode` remains fast and is not hindered by bugs in solving code. Be sure to consider corner cases. For example, if your solution method involves dividing by something, make sure you exclude the case where that division will be 0. In most cases, the matching of the ODE will also give you the various parts that you need to solve it. You should put that in a dictionary (``.match()`` will do this for you), and add that as ``matching_hints['hint'] = matchdict`` in the relevant part of :py:meth:`~sympy.solvers.ode.classify_ode`. :py:meth:`~sympy.solvers.ode.classify_ode` will then send this to :py:meth:`~sympy.solvers.ode.dsolve`, which will send it to your function as the ``match`` argument. Your function should be named ``ode_<hint>(eq, func, order, match)`. If you need to send more information, put it in the ``match`` dictionary. For example, if you had to substitute in a dummy variable in :py:meth:`~sympy.solvers.ode.classify_ode` to match the ODE, you will need to pass it to your function using the `match` dict to access it. You can access the independent variable using ``func.args[0]``, and the dependent variable (the function you are trying to solve for) as ``func.func``. If, while trying to solve the ODE, you find that you cannot, raise ``NotImplementedError``. :py:meth:`~sympy.solvers.ode.dsolve` will catch this error with the ``all`` meta-hint, rather than causing the whole routine to fail. Add a docstring to your function that describes the method employed. Like with anything else in SymPy, you will need to add a doctest to the docstring, in addition to real tests in ``test_ode.py``. Try to maintain consistency with the other hint functions' docstrings. Add your method to the list at the top of this docstring. Also, add your method to ``ode.rst`` in the ``docs/src`` directory, so that the Sphinx docs will pull its docstring into the main SymPy documentation. Be sure to make the Sphinx documentation by running ``make html`` from within the doc directory to verify that the docstring formats correctly. If your solution method involves integrating, use :py:meth:`Integral() <sympy.integrals.integrals.Integral>` instead of :py:meth:`~sympy.core.expr.Expr.integrate`. This allows the user to bypass hard/slow integration by using the ``_Integral`` variant of your hint. In most cases, calling :py:meth:`sympy.core.basic.Basic.doit` will integrate your solution. If this is not the case, you will need to write special code in :py:meth:`~sympy.solvers.ode._handle_Integral`. Arbitrary constants should be symbols named ``C1``, ``C2``, and so on. All solution methods should return an equality instance. If you need an arbitrary number of arbitrary constants, you can use ``constants = numbered_symbols(prefix='C', cls=Symbol, start=1)``. If it is possible to solve for the dependent function in a general way, do so. Otherwise, do as best as you can, but do not call solve in your ``ode_<hint>()`` function. :py:meth:`~sympy.solvers.ode.odesimp` will attempt to solve the solution for you, so you do not need to do that. Lastly, if your ODE has a common simplification that can be applied to your solutions, you can add a special case in :py:meth:`~sympy.solvers.ode.odesimp` for it. For example, solutions returned from the ``1st_homogeneous_coeff`` hints often have many :py:meth:`~sympy.functions.log` terms, so :py:meth:`~sympy.solvers.ode.odesimp` calls :py:meth:`~sympy.simplify.simplify.logcombine` on them (it also helps to write the arbitrary constant as ``log(C1)`` instead of ``C1`` in this case). Also consider common ways that you can rearrange your solution to have :py:meth:`~sympy.solvers.ode.constantsimp` take better advantage of it. It is better to put simplification in :py:meth:`~sympy.solvers.ode.odesimp` than in your method, because it can then be turned off with the simplify flag in :py:meth:`~sympy.solvers.ode.dsolve`. If you have any extraneous simplification in your function, be sure to only run it using ``if match.get('simplify', True):``, especially if it can be slow or if it can reduce the domain of the solution. Finally, as with every contribution to SymPy, your method will need to be tested. Add a test for each method in ``test_ode.py``. Follow the conventions there, i.e., test the solver using ``dsolve(eq, f(x), hint=your_hint)``, and also test the solution using :py:meth:`~sympy.solvers.ode.checkodesol` (you can put these in a separate tests and skip/XFAIL if it runs too slow/doesn't work). Be sure to call your hint specifically in :py:meth:`~sympy.solvers.ode.dsolve`, that way the test won't be broken simply by the introduction of another matching hint. If your method works for higher order (>1) ODEs, you will need to run ``sol = constant_renumber(sol, 'C', 1, order)`` for each solution, where ``order`` is the order of the ODE. This is because ``constant_renumber`` renumbers the arbitrary constants by printing order, which is platform dependent. Try to test every corner case of your solver, including a range of orders if it is a `n`\th order solver, but if your solver is slow, such as if it involves hard integration, try to keep the test run time down. Feel free to refactor existing hints to avoid duplicating code or creating inconsistencies. If you can show that your method exactly duplicates an existing method, including in the simplicity and speed of obtaining the solutions, then you can remove the old, less general method. The existing code is tested extensively in ``test_ode.py``, so if anything is broken, one of those tests will surely fail. """ from __future__ import print_function, division from collections import defaultdict from itertools import islice from sympy.core import Add, S, Mul, Pow, oo from sympy.core.compatibility import ordered, iterable, is_sequence, range, string_types from sympy.core.containers import Tuple from sympy.core.exprtools import factor_terms from sympy.core.expr import AtomicExpr, Expr from sympy.core.function import (Function, Derivative, AppliedUndef, diff, expand, expand_mul, Subs, _mexpand) from sympy.core.multidimensional import vectorize from sympy.core.numbers import NaN, zoo, I, Number from sympy.core.relational import Equality, Eq from sympy.core.symbol import Symbol, Wild, Dummy, symbols from sympy.core.sympify import sympify from sympy.logic.boolalg import (BooleanAtom, And, Not, BooleanTrue, BooleanFalse) from sympy.functions import cos, exp, im, log, re, sin, tan, sqrt, \ atan2, conjugate, Piecewise from sympy.functions.combinatorial.factorials import factorial from sympy.integrals.integrals import Integral, integrate from sympy.matrices import wronskian, Matrix, eye, zeros from sympy.polys import (Poly, RootOf, rootof, terms_gcd, PolynomialError, lcm, roots) from sympy.polys.polyroots import roots_quartic from sympy.polys.polytools import cancel, degree, div from sympy.series import Order from sympy.series.series import series from sympy.simplify import collect, logcombine, powsimp, separatevars, \ simplify, trigsimp, posify, cse from sympy.simplify.powsimp import powdenest from sympy.simplify.radsimp import collect_const from sympy.solvers import solve from sympy.solvers.pde import pdsolve from sympy.utilities import numbered_symbols, default_sort_key, sift from sympy.solvers.deutils import _preprocess, ode_order, _desolve #: This is a list of hints in the order that they should be preferred by #: :py:meth:`~sympy.solvers.ode.classify_ode`. In general, hints earlier in the #: list should produce simpler solutions than those later in the list (for #: ODEs that fit both). For now, the order of this list is based on empirical #: observations by the developers of SymPy. #: #: The hint used by :py:meth:`~sympy.solvers.ode.dsolve` for a specific ODE #: can be overridden (see the docstring). #: #: In general, ``_Integral`` hints are grouped at the end of the list, unless #: there is a method that returns an unevaluable integral most of the time #: (which go near the end of the list anyway). ``default``, ``all``, #: ``best``, and ``all_Integral`` meta-hints should not be included in this #: list, but ``_best`` and ``_Integral`` hints should be included. allhints = ( "nth_algebraic", "separable", "1st_exact", "1st_linear", "Bernoulli", "Riccati_special_minus2", "1st_homogeneous_coeff_best", "1st_homogeneous_coeff_subs_indep_div_dep", "1st_homogeneous_coeff_subs_dep_div_indep", "almost_linear", "linear_coefficients", "separable_reduced", "1st_power_series", "lie_group", "nth_linear_constant_coeff_homogeneous", "nth_linear_euler_eq_homogeneous", "nth_linear_constant_coeff_undetermined_coefficients", "nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients", "nth_linear_constant_coeff_variation_of_parameters", "nth_linear_euler_eq_nonhomogeneous_variation_of_parameters", "Liouville", "nth_order_reducible", "2nd_power_series_ordinary", "2nd_power_series_regular", "nth_algebraic_Integral", "separable_Integral", "1st_exact_Integral", "1st_linear_Integral", "Bernoulli_Integral", "1st_homogeneous_coeff_subs_indep_div_dep_Integral", "1st_homogeneous_coeff_subs_dep_div_indep_Integral", "almost_linear_Integral", "linear_coefficients_Integral", "separable_reduced_Integral", "nth_linear_constant_coeff_variation_of_parameters_Integral", "nth_linear_euler_eq_nonhomogeneous_variation_of_parameters_Integral", "Liouville_Integral", ) lie_heuristics = ( "abaco1_simple", "abaco1_product", "abaco2_similar", "abaco2_unique_unknown", "abaco2_unique_general", "linear", "function_sum", "bivariate", "chi" ) def sub_func_doit(eq, func, new): r""" When replacing the func with something else, we usually want the derivative evaluated, so this function helps in making that happen. Examples ======== >>> from sympy import Derivative, symbols, Function >>> from sympy.solvers.ode import sub_func_doit >>> x, z = symbols('x, z') >>> y = Function('y') >>> sub_func_doit(3Derivative(y(x), x) - 1, y(x), x) 2 >>> sub_func_doit(xDerivative(y(x), x) - y(x)*2 + y(x), y(x), ... 1/(x(z + 1/x))) x(-1/(x2(z + 1/x)) + 1/(x*3(z + 1/x)*2)) + 1/(x(z + 1/x)) ...- 1/(x*2(z + 1/x)*2) """ reps= {func: new} for d in eq.atoms(Derivative): if d.expr == func: reps[d] = new.diff(d.variable_count) else: reps[d] = d.xreplace({func: new}).doit(deep=False) return eq.xreplace(reps) def get_numbered_constants(eq, num=1, start=1, prefix='C'): """ Returns a list of constants that do not occur in eq already. """ ncs = iter_numbered_constants(eq, start, prefix) Cs = [next(ncs) for i in range(num)] return (Cs[0] if num == 1 else tuple(Cs)) def iter_numbered_constants(eq, start=1, prefix='C'): """ Returns an iterator of constants that do not occur in eq already. """ if isinstance(eq, Expr): eq = [eq] elif not iterable(eq): raise ValueError("Expected Expr or iterable but got %s" % eq) atom_set = set().union([i.free_symbols for i in eq]) func_set = set().union([i.atoms(Function) for i in eq]) if func_set: atom_set \|= {Symbol(str(f.func)) for f in func_set} return numbered_symbols(start=start, prefix=prefix, exclude=atom_set) def dsolve(eq, func=None, hint="default", simplify=True, ics= None, xi=None, eta=None, x0=0, n=6, kwargs): r""" Solves any (supported) kind of ordinary differential equation and system of ordinary differential equations. For single ordinary differential equation ========================================= It is classified under this when number of equation in ``eq`` is one. Usage ``dsolve(eq, f(x), hint)`` -> Solve ordinary differential equation ``eq`` for function ``f(x)``, using method ``hint``. Details ``eq`` can be any supported ordinary differential equation (see the :py:mod:`~sympy.solvers.ode` docstring for supported methods). This can either be an :py:class:`~sympy.core.relational.Equality`, or an expression, which is assumed to be equal to ``0``. ``f(x)`` is a function of one variable whose derivatives in that variable make up the ordinary differential equation ``eq``. In many cases it is not necessary to provide this; it will be autodetected (and an error raised if it couldn't be detected). ``hint`` is the solving method that you want dsolve to use. Use ``classify_ode(eq, f(x))`` to get all of the possible hints for an ODE. The default hint, ``default``, will use whatever hint is returned first by :py:meth:`~sympy.solvers.ode.classify_ode`. See Hints below for more options that you can use for hint. ``simplify`` enables simplification by :py:meth:`~sympy.solvers.ode.odesimp`. See its docstring for more information. Turn this off, for example, to disable solving of solutions for ``func`` or simplification of arbitrary constants. It will still integrate with this hint. Note that the solution may contain more arbitrary constants than the order of the ODE with this option enabled. ``xi`` and ``eta`` are the infinitesimal functions of an ordinary differential equation. They are the infinitesimals of the Lie group of point transformations for which the differential equation is invariant. The user can specify values for the infinitesimals. If nothing is specified, ``xi`` and ``eta`` are calculated using :py:meth:`~sympy.solvers.ode.infinitesimals` with the help of various heuristics. ``ics`` is the set of initial/boundary conditions for the differential equation. It should be given in the form of ``{f(x0): x1, f(x).diff(x).subs(x, x2): x3}`` and so on. For power series solutions, if no initial conditions are specified ``f(0)`` is assumed to be ``C0`` and the power series solution is calculated about 0. ``x0`` is the point about which the power series solution of a differential equation is to be evaluated. ``n`` gives the exponent of the dependent variable up to which the power series solution of a differential equation is to be evaluated. Hints Aside from the various solving methods, there are also some meta-hints that you can pass to :py:meth:`~sympy.solvers.ode.dsolve`: ``default``: This uses whatever hint is returned first by :py:meth:`~sympy.solvers.ode.classify_ode`. This is the default argument to :py:meth:`~sympy.solvers.ode.dsolve`. ``all``: To make :py:meth:`~sympy.solvers.ode.dsolve` apply all relevant classification hints, use ``dsolve(ODE, func, hint="all")``. This will return a dictionary of ``hint:solution`` terms. If a hint causes dsolve to raise the ``NotImplementedError``, value of that hint's key will be the exception object raised. The dictionary will also include some special keys: - ``order``: The order of the ODE. See also :py:meth:`~sympy.solvers.deutils.ode_order` in ``deutils.py``. - ``best``: The simplest hint; what would be returned by ``best`` below. - ``best_hint``: The hint that would produce the solution given by ``best``. If more than one hint produces the best solution, the first one in the tuple returned by :py:meth:`~sympy.solvers.ode.classify_ode` is chosen. - ``default``: The solution that would be returned by default. This is the one produced by the hint that appears first in the tuple returned by :py:meth:`~sympy.solvers.ode.classify_ode`. ``all_Integral``: This is the same as ``all``, except if a hint also has a corresponding ``_Integral`` hint, it only returns the ``_Integral`` hint. This is useful if ``all`` causes :py:meth:`~sympy.solvers.ode.dsolve` to hang because of a difficult or impossible integral. This meta-hint will also be much faster than ``all``, because :py:meth:`~sympy.core.expr.Expr.integrate` is an expensive routine. ``best``: To have :py:meth:`~sympy.solvers.ode.dsolve` try all methods and return the simplest one. This takes into account whether the solution is solvable in the function, whether it contains any Integral classes (i.e. unevaluatable integrals), and which one is the shortest in size. See also the :py:meth:`~sympy.solvers.ode.classify_ode` docstring for more info on hints, and the :py:mod:`~sympy.solvers.ode` docstring for a list of all supported hints. Tips - You can declare the derivative of an unknown function this way: >>> from sympy import Function, Derivative >>> from sympy.abc import x # x is the independent variable >>> f = Function("f")(x) # f is a function of x >>> # f_ will be the derivative of f with respect to x >>> f_ = Derivative(f, x) - See ``test_ode.py`` for many tests, which serves also as a set of examples for how to use :py:meth:`~sympy.solvers.ode.dsolve`. - :py:meth:`~sympy.solvers.ode.dsolve` always returns an :py:class:`~sympy.core.relational.Equality` class (except for the case when the hint is ``all`` or ``all_Integral``). If possible, it solves the solution explicitly for the function being solved for. Otherwise, it returns an implicit solution. - Arbitrary constants are symbols named ``C1``, ``C2``, and so on. - Because all solutions should be mathematically equivalent, some hints may return the exact same result for an ODE. Often, though, two different hints will return the same solution formatted differently. The two should be equivalent. Also note that sometimes the values of the arbitrary constants in two different solutions may not be the same, because one constant may have "absorbed" other constants into it. - Do ``help(ode.ode_<hintname>)`` to get help more information on a specific hint, where ``<hintname>`` is the name of a hint without ``_Integral``. For system of ordinary differential equations ============================================= Usage ``dsolve(eq, func)`` -> Solve a system of ordinary differential equations ``eq`` for ``func`` being list of functions including `x(t)`, `y(t)`, `z(t)` where number of functions in the list depends upon the number of equations provided in ``eq``. Details ``eq`` can be any supported system of ordinary differential equations This can either be an :py:class:`~sympy.core.relational.Equality`, or an expression, which is assumed to be equal to ``0``. ``func`` holds ``x(t)`` and ``y(t)`` being functions of one variable which together with some of their derivatives make up the system of ordinary differential equation ``eq``. It is not necessary to provide this; it will be autodetected (and an error raised if it couldn't be detected). Hints** The hints are formed by parameters returned by classify_sysode, combining them give hints name used later for forming method name. Examples ======== >>> from sympy import Function, dsolve, Eq, Derivative, sin, cos, symbols >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(Derivative(f(x), x, x) + 9f(x), f(x)) Eq(f(x), C1sin(3x) + C2cos(3x)) >>> eq = sin(x)cos(f(x)) + cos(x)sin(f(x))f(x).diff(x) >>> dsolve(eq, hint='1st_exact') [Eq(f(x), -acos(C1/cos(x)) + 2pi), Eq(f(x), acos(C1/cos(x)))] >>> dsolve(eq, hint='almost_linear') [Eq(f(x), -acos(C1/cos(x)) + 2pi), Eq(f(x), acos(C1/cos(x)))] >>> t = symbols('t') >>> x, y = symbols('x, y', cls=Function) >>> eq = (Eq(Derivative(x(t),t), 12tx(t) + 8y(t)), Eq(Derivative(y(t),t), 21x(t) + 7ty(t))) >>> dsolve(eq) [Eq(x(t), C1x0(t) + C2x0(t)Integral(8exp(Integral(7t, t))exp(Integral(12t, t))/x0(t)2, t)), Eq(y(t), C1y0(t) + C2(y0(t)Integral(8exp(Integral(7t, t))exp(Integral(12t, t))/x0(t)*2, t) + exp(Integral(7t, t))exp(Integral(12t, t))/x0(t)))] >>> eq = (Eq(Derivative(x(t),t),x(t)y(t)sin(t)), Eq(Derivative(y(t),t),y(t)*2sin(t))) >>> dsolve(eq) {Eq(x(t), -exp(C1)/(C2exp(C1) - cos(t))), Eq(y(t), -1/(C1 - cos(t)))} """ if iterable(eq): match = classify_sysode(eq, func) eq = match['eq'] order = match['order'] func = match['func'] t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] # keep highest order term coefficient positive for i in range(len(eq)): for func_ in func: if isinstance(func_, list): pass else: if eq[i].coeff(diff(func[i],t,ode_order(eq[i], func[i]))).is_negative: eq[i] = -eq[i] match['eq'] = eq if len(set(order.values()))!=1: raise ValueError("It solves only those systems of equations whose orders are equal") match['order'] = list(order.values())[0] def recur_len(l): return sum(recur_len(item) if isinstance(item,list) else 1 for item in l) if recur_len(func) != len(eq): raise ValueError("dsolve() and classify_sysode() work with " "number of functions being equal to number of equations") if match['type_of_equation'] is None: raise NotImplementedError else: if match['is_linear'] == True: if match['no_of_equation'] > 3: solvefunc = globals()['sysode_linear_neq_order%(order)s' % match] else: solvefunc = globals()['sysode_linear_%(no_of_equation)seq_order%(order)s' % match] else: solvefunc = globals()['sysode_nonlinear_%(no_of_equation)seq_order%(order)s' % match] sols = solvefunc(match) if ics: constants = Tuple(sols).free_symbols - Tuple(eq).free_symbols solved_constants = solve_ics(sols, func, constants, ics) return [sol.subs(solved_constants) for sol in sols] return sols else: given_hint = hint # hint given by the user # See the docstring of _desolve for more details. hints = _desolve(eq, func=func, hint=hint, simplify=True, xi=xi, eta=eta, type='ode', ics=ics, x0=x0, n=n, kwargs) eq = hints.pop('eq', eq) all_ = hints.pop('all', False) if all_: retdict = {} failed_hints = {} gethints = classify_ode(eq, dict=True) orderedhints = gethints['ordered_hints'] for hint in hints: try: rv = _helper_simplify(eq, hint, hints[hint], simplify) except NotImplementedError as detail: failed_hints[hint] = detail else: retdict[hint] = rv func = hints[hint]['func'] retdict['best'] = min(list(retdict.values()), key=lambda x: ode_sol_simplicity(x, func, trysolving=not simplify)) if given_hint == 'best': return retdict['best'] for i in orderedhints: if retdict['best'] == retdict.get(i, None): retdict['best_hint'] = i break retdict['default'] = gethints['default'] retdict['order'] = gethints['order'] retdict.update(failed_hints) return retdict else: # The key 'hint' stores the hint needed to be solved for. hint = hints['hint'] return _helper_simplify(eq, hint, hints, simplify, ics=ics) def _helper_simplify(eq, hint, match, simplify=True, ics=None, kwargs): r""" Helper function of dsolve that calls the respective :py:mod:`~sympy.solvers.ode` functions to solve for the ordinary differential equations. This minimizes the computation in calling :py:meth:`~sympy.solvers.deutils._desolve` multiple times. """ r = match if hint.endswith('_Integral'): solvefunc = globals()['ode_' + hint[:-len('_Integral')]] else: solvefunc = globals()['ode_' + hint] func = r['func'] order = r['order'] match = r[hint] free = eq.free_symbols cons = lambda s: s.free_symbols.difference(free) if simplify: # odesimp() will attempt to integrate, if necessary, apply constantsimp(), # attempt to solve for func, and apply any other hint specific # simplifications sols = solvefunc(eq, func, order, match) if isinstance(sols, Expr): rv = odesimp(eq, sols, func, hint) else: rv = [odesimp(eq, s, func, hint) for s in sols] else: # We still want to integrate (you can disable it separately with the hint) match['simplify'] = False # Some hints can take advantage of this option rv = _handle_Integral(solvefunc(eq, func, order, match), func, hint) if ics and not 'power_series' in hint: if isinstance(rv, Expr): solved_constants = solve_ics([rv], [r['func']], cons(rv), ics) rv = rv.subs(solved_constants) else: rv1 = [] for s in rv: try: solved_constants = solve_ics([s], [r['func']], cons(s), ics) except ValueError: continue rv1.append(s.subs(solved_constants)) if len(rv1) == 1: return rv1[0] rv = rv1 return rv def solve_ics(sols, funcs, constants, ics): """ Solve for the constants given initial conditions ``sols`` is a list of solutions. ``funcs`` is a list of functions. ``constants`` is a list of constants. ``ics`` is the set of initial/boundary conditions for the differential equation. It should be given in the form of ``{f(x0): x1, f(x).diff(x).subs(x, x2): x3}`` and so on. Returns a dictionary mapping constants to values. ``solution.subs(constants)`` will replace the constants in ``solution``. Example ======= >>> # From dsolve(f(x).diff(x) - f(x), f(x)) >>> from sympy import symbols, Eq, exp, Function >>> from sympy.solvers.ode import solve_ics >>> f = Function('f') >>> x, C1 = symbols('x C1') >>> sols = [Eq(f(x), C1exp(x))] >>> funcs = [f(x)] >>> constants = [C1] >>> ics = {f(0): 2} >>> solved_constants = solve_ics(sols, funcs, constants, ics) >>> solved_constants {C1: 2} >>> sols[0].subs(solved_constants) Eq(f(x), 2exp(x)) """ # Assume ics are of the form f(x0): value or Subs(diff(f(x), x, n), (x, # x0)): value (currently checked by classify_ode). To solve, replace x # with x0, f(x0) with value, then solve for constants. For f^(n)(x0), # differentiate the solution n times, so that f^(n)(x) appears. x = funcs[0].args[0] diff_sols = [] subs_sols = [] diff_variables = set() for funcarg, value in ics.items(): if isinstance(funcarg, AppliedUndef): x0 = funcarg.args[0] matching_func = [f for f in funcs if f.func == funcarg.func][0] S = sols elif isinstance(funcarg, (Subs, Derivative)): if isinstance(funcarg, Subs): # Make sure it stays a subs. Otherwise subs below will produce # a different looking term. funcarg = funcarg.doit() if isinstance(funcarg, Subs): deriv = funcarg.expr x0 = funcarg.point[0] variables = funcarg.expr.variables matching_func = deriv elif isinstance(funcarg, Derivative): deriv = funcarg x0 = funcarg.variables[0] variables = (x,)len(funcarg.variables) matching_func = deriv.subs(x0, x) if variables not in diff_variables: for sol in sols: if sol.has(deriv.expr.func): diff_sols.append(Eq(sol.lhs.diff(variables), sol.rhs.diff(variables))) diff_variables.add(variables) S = diff_sols else: raise NotImplementedError("Unrecognized initial condition") for sol in S: if sol.has(matching_func): sol2 = sol sol2 = sol2.subs(x, x0) sol2 = sol2.subs(funcarg, value) # This check is necessary because of issue #15724 if not isinstance(sol2, BooleanAtom) or not subs_sols: subs_sols = [s for s in subs_sols if not isinstance(s, BooleanAtom)] subs_sols.append(sol2) # TODO: Use solveset here try: solved_constants = solve(subs_sols, constants, dict=True) except NotImplementedError: solved_constants = [] # XXX: We can't differentiate between the solution not existing because of # invalid initial conditions, and not existing because solve is not smart # enough. If we could use solveset, this might be improvable, but for now, # we use NotImplementedError in this case. if not solved_constants: raise ValueError("Couldn't solve for initial conditions") if solved_constants == True: raise ValueError("Initial conditions did not produce any solutions for constants. Perhaps they are degenerate.") if len(solved_constants) > 1: raise NotImplementedError("Initial conditions produced too many solutions for constants") return solved_constants[0] def classify_ode(eq, func=None, dict=False, ics=None, *kwargs): r""" Returns a tuple of possible :py:meth:`~sympy.solvers.ode.dsolve` classifications for an ODE. The tuple is ordered so that first item is the classification that :py:meth:`~sympy.solvers.ode.dsolve` uses to solve the ODE by default. In general, classifications at the near the beginning of the list will produce better solutions faster than those near the end, thought there are always exceptions. To make :py:meth:`~sympy.solvers.ode.dsolve` use a different classification, use ``dsolve(ODE, func, hint=<classification>)``. See also the :py:meth:`~sympy.solvers.ode.dsolve` docstring for different meta-hints you can use. If ``dict`` is true, :py:meth:`~sympy.solvers.ode.classify_ode` will return a dictionary of ``hint:match`` expression terms. This is intended for internal use by :py:meth:`~sympy.solvers.ode.dsolve`. Note that because dictionaries are ordered arbitrarily, this will most likely not be in the same order as the tuple. You can get help on different hints by executing ``help(ode.ode_hintname)``, where ``hintname`` is the name of the hint without ``_Integral``. See :py:data:`~sympy.solvers.ode.allhints` or the :py:mod:`~sympy.solvers.ode` docstring for a list of all supported hints that can be returned from :py:meth:`~sympy.solvers.ode.classify_ode`. Notes ===== These are remarks on hint names. ``_Integral`` If a classification has ``_Integral`` at the end, it will return the expression with an unevaluated :py:class:`~sympy.integrals.Integral` class in it. Note that a hint may do this anyway if :py:meth:`~sympy.core.expr.Expr.integrate` cannot do the integral, though just using an ``_Integral`` will do so much faster. Indeed, an ``_Integral`` hint will always be faster than its corresponding hint without ``_Integral`` because :py:meth:`~sympy.core.expr.Expr.integrate` is an expensive routine. If :py:meth:`~sympy.solvers.ode.dsolve` hangs, it is probably because :py:meth:`~sympy.core.expr.Expr.integrate` is hanging on a tough or impossible integral. Try using an ``_Integral`` hint or ``all_Integral`` to get it return something. Note that some hints do not have ``_Integral`` counterparts. This is because :py:meth:`~sympy.solvers.ode.integrate` is not used in solving the ODE for those method. For example, `n`\th order linear homogeneous ODEs with constant coefficients do not require integration to solve, so there is no ``nth_linear_homogeneous_constant_coeff_Integrate`` hint. You can easily evaluate any unevaluated :py:class:`~sympy.integrals.Integral`\s in an expression by doing ``expr.doit()``. Ordinals Some hints contain an ordinal such as ``1st_linear``. This is to help differentiate them from other hints, as well as from other methods that may not be implemented yet. If a hint has ``nth`` in it, such as the ``nth_linear`` hints, this means that the method used to applies to ODEs of any order. ``indep`` and ``dep`` Some hints contain the words ``indep`` or ``dep``. These reference the independent variable and the dependent function, respectively. For example, if an ODE is in terms of `f(x)`, then ``indep`` will refer to `x` and ``dep`` will refer to `f`. ``subs`` If a hints has the word ``subs`` in it, it means the the ODE is solved by substituting the expression given after the word ``subs`` for a single dummy variable. This is usually in terms of ``indep`` and ``dep`` as above. The substituted expression will be written only in characters allowed for names of Python objects, meaning operators will be spelled out. For example, ``indep``/``dep`` will be written as ``indep_div_dep``. ``coeff`` The word ``coeff`` in a hint refers to the coefficients of something in the ODE, usually of the derivative terms. See the docstring for the individual methods for more info (``help(ode)``). This is contrast to ``coefficients``, as in ``undetermined_coefficients``, which refers to the common name of a method. ``_best`` Methods that have more than one fundamental way to solve will have a hint for each sub-method and a ``_best`` meta-classification. This will evaluate all hints and return the best, using the same considerations as the normal ``best`` meta-hint. Examples ======== >>> from sympy import Function, classify_ode, Eq >>> from sympy.abc import x >>> f = Function('f') >>> classify_ode(Eq(f(x).diff(x), 0), f(x)) ('nth_algebraic', 'separable', '1st_linear', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_homogeneous', 'nth_linear_euler_eq_homogeneous', 'nth_algebraic_Integral', 'separable_Integral', '1st_linear_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral') >>> classify_ode(f(x).diff(x, 2) + 3f(x).diff(x) + 2f(x) - 4) ('nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', 'nth_linear_constant_coeff_variation_of_parameters_Integral') """ ics = sympify(ics) prep = kwargs.pop('prep', True) if func and len(func.args) != 1: raise ValueError("dsolve() and classify_ode() only " "work with functions of one variable, not %s" % func) if prep or func is None: eq, func_ = _preprocess(eq, func) if func is None: func = func_ x = func.args[0] f = func.func y = Dummy('y') xi = kwargs.get('xi') eta = kwargs.get('eta') terms = kwargs.get('n') if isinstance(eq, Equality): if eq.rhs != 0: return classify_ode(eq.lhs - eq.rhs, func, dict=dict, ics=ics, xi=xi, n=terms, eta=eta, prep=False) eq = eq.lhs order = ode_order(eq, f(x)) # hint:matchdict or hint:(tuple of matchdicts) # Also will contain "default":<default hint> and "order":order items. matching_hints = {"order": order} if not order: if dict: matching_hints["default"] = None return matching_hints else: return () df = f(x).diff(x) a = Wild('a', exclude=[f(x)]) b = Wild('b', exclude=[f(x)]) c = Wild('c', exclude=[f(x)]) d = Wild('d', exclude=[df, f(x).diff(x, 2)]) e = Wild('e', exclude=[df]) k = Wild('k', exclude=[df]) n = Wild('n', exclude=[x, f(x), df]) c1 = Wild('c1', exclude=[x]) a2 = Wild('a2', exclude=[x, f(x), df]) b2 = Wild('b2', exclude=[x, f(x), df]) c2 = Wild('c2', exclude=[x, f(x), df]) d2 = Wild('d2', exclude=[x, f(x), df]) a3 = Wild('a3', exclude=[f(x), df, f(x).diff(x, 2)]) b3 = Wild('b3', exclude=[f(x), df, f(x).diff(x, 2)]) c3 = Wild('c3', exclude=[f(x), df, f(x).diff(x, 2)]) r3 = {'xi': xi, 'eta': eta} # Used for the lie_group hint boundary = {} # Used to extract initial conditions C1 = Symbol("C1") eq = expand(eq) # Preprocessing to get the initial conditions out if ics is not None: for funcarg in ics: # Separating derivatives if isinstance(funcarg, (Subs, Derivative)): # f(x).diff(x).subs(x, 0) is a Subs, but f(x).diff(x).subs(x, # y) is a Derivative if isinstance(funcarg, Subs): deriv = funcarg.expr old = funcarg.variables[0] new = funcarg.point[0] elif isinstance(funcarg, Derivative): deriv = funcarg # No information on this. Just assume it was x old = x new = funcarg.variables[0] if (isinstance(deriv, Derivative) and isinstance(deriv.args[0], AppliedUndef) and deriv.args[0].func == f and len(deriv.args[0].args) == 1 and old == x and not new.has(x) and all(i == deriv.variables[0] for i in deriv.variables) and not ics[funcarg].has(f)): dorder = ode_order(deriv, x) temp = 'f' + str(dorder) boundary.update({temp: new, temp + 'val': ics[funcarg]}) else: raise ValueError("Enter valid boundary conditions for Derivatives") # Separating functions elif isinstance(funcarg, AppliedUndef): if (funcarg.func == f and len(funcarg.args) == 1 and not funcarg.args[0].has(x) and not ics[funcarg].has(f)): boundary.update({'f0': funcarg.args[0], 'f0val': ics[funcarg]}) else: raise ValueError("Enter valid boundary conditions for Function") else: raise ValueError("Enter boundary conditions of the form ics={f(point}: value, f(x).diff(x, order).subs(x, point): value}") # Precondition to try remove f(x) from highest order derivative reduced_eq = None if eq.is_Add: deriv_coef = eq.coeff(f(x).diff(x, order)) if deriv_coef not in (1, 0): r = deriv_coef.match(af(x)c1) if r and r[c1]: den = f(x)r[c1] reduced_eq = Add([arg/den for arg in eq.args]) if not reduced_eq: reduced_eq = eq if order == 1: ## Linear case: a(x)y'+b(x)y+c(x) == 0 if eq.is_Add: ind, dep = reduced_eq.as_independent(f) else: u = Dummy('u') ind, dep = (reduced_eq + u).as_independent(f) ind, dep = [tmp.subs(u, 0) for tmp in [ind, dep]] r = {a: dep.coeff(df), b: dep.coeff(f(x)), c: ind} # double check f[a] since the preconditioning may have failed if not r[a].has(f) and not r[b].has(f) and ( r[a]df + r[b]f(x) + r[c]).expand() - reduced_eq == 0: r['a'] = a r['b'] = b r['c'] = c matching_hints["1st_linear"] = r matching_hints["1st_linear_Integral"] = r ## Bernoulli case: a(x)y'+b(x)y+c(x)y*n == 0 r = collect( reduced_eq, f(x), exact=True).match(adf + bf(x) + cf(x)*n) if r and r[c] != 0 and r[n] != 1: # See issue 4676 r['a'] = a r['b'] = b r['c'] = c r['n'] = n matching_hints["Bernoulli"] = r matching_hints["Bernoulli_Integral"] = r ## Riccati special n == -2 case: a2y'+b2y2+c2y/x+d2/x*2 == 0 r = collect(reduced_eq, f(x), exact=True).match(a2df + b2f(x)2 + c2f(x)/x + d2/x*2) if r and r[b2] != 0 and (r[c2] != 0 or r[d2] != 0): r['a2'] = a2 r['b2'] = b2 r['c2'] = c2 r['d2'] = d2 matching_hints["Riccati_special_minus2"] = r # NON-REDUCED FORM OF EQUATION matches r = collect(eq, df, exact=True).match(d + e df) if r: r['d'] = d r['e'] = e r['y'] = y r[d] = r[d].subs(f(x), y) r[e] = r[e].subs(f(x), y) # FIRST ORDER POWER SERIES WHICH NEEDS INITIAL CONDITIONS # TODO: Hint first order series should match only if d/e is analytic. # For now, only d/e and (d/e).diff(arg) is checked for existence at # at a given point. # This is currently done internally in ode_1st_power_series. point = boundary.get('f0', 0) value = boundary.get('f0val', C1) check = cancel(r[d]/r[e]) check1 = check.subs({x: point, y: value}) if not check1.has(oo) and not check1.has(zoo) and \ not check1.has(NaN) and not check1.has(-oo): check2 = (check1.diff(x)).subs({x: point, y: value}) if not check2.has(oo) and not check2.has(zoo) and \ not check2.has(NaN) and not check2.has(-oo): rseries = r.copy() rseries.update({'terms': terms, 'f0': point, 'f0val': value}) matching_hints["1st_power_series"] = rseries r3.update(r) ## Exact Differential Equation: P(x, y) + Q(x, y)y' = 0 where # dP/dy == dQ/dx try: if r[d] != 0: numerator = simplify(r[d].diff(y) - r[e].diff(x)) # The following few conditions try to convert a non-exact # differential equation into an exact one. # References : Differential equations with applications # and historical notes - George E. Simmons if numerator: # If (dP/dy - dQ/dx) / Q = f(x) # then exp(integral(f(x))equation becomes exact factor = simplify(numerator/r[e]) variables = factor.free_symbols if len(variables) == 1 and x == variables.pop(): factor = exp(Integral(factor).doit()) r[d] = factor r[e] = factor matching_hints["1st_exact"] = r matching_hints["1st_exact_Integral"] = r else: # If (dP/dy - dQ/dx) / -P = f(y) # then exp(integral(f(y))equation becomes exact factor = simplify(-numerator/r[d]) variables = factor.free_symbols if len(variables) == 1 and y == variables.pop(): factor = exp(Integral(factor).doit()) r[d] = factor r[e] = factor matching_hints["1st_exact"] = r matching_hints["1st_exact_Integral"] = r else: matching_hints["1st_exact"] = r matching_hints["1st_exact_Integral"] = r except NotImplementedError: # Differentiating the coefficients might fail because of things # like f(2x).diff(x). See issue 4624 and issue 4719. pass # Any first order ODE can be ideally solved by the Lie Group # method matching_hints["lie_group"] = r3 # This match is used for several cases below; we now collect on # f(x) so the matching works. r = collect(reduced_eq, df, exact=True).match(d + edf) if r: # Using r[d] and r[e] without any modification for hints # linear-coefficients and separable-reduced. num, den = r[d], r[e] # ODE = d/e + df r['d'] = d r['e'] = e r['y'] = y r[d] = num.subs(f(x), y) r[e] = den.subs(f(x), y) ## Separable Case: y' == P(y)Q(x) r[d] = separatevars(r[d]) r[e] = separatevars(r[e]) # m1[coeff]m1[x]m1[y] + m2[coeff]m2[x]m2[y]y' m1 = separatevars(r[d], dict=True, symbols=(x, y)) m2 = separatevars(r[e], dict=True, symbols=(x, y)) if m1 and m2: r1 = {'m1': m1, 'm2': m2, 'y': y} matching_hints["separable"] = r1 matching_hints["separable_Integral"] = r1 ## First order equation with homogeneous coefficients: # dy/dx == F(y/x) or dy/dx == F(x/y) ordera = homogeneous_order(r[d], x, y) if ordera is not None: orderb = homogeneous_order(r[e], x, y) if ordera == orderb: # u1=y/x and u2=x/y u1 = Dummy('u1') u2 = Dummy('u2') s = "1st_homogeneous_coeff_subs" s1 = s + "_dep_div_indep" s2 = s + "_indep_div_dep" if simplify((r[d] + u1r[e]).subs({x: 1, y: u1})) != 0: matching_hints[s1] = r matching_hints[s1 + "_Integral"] = r if simplify((r[e] + u2r[d]).subs({x: u2, y: 1})) != 0: matching_hints[s2] = r matching_hints[s2 + "_Integral"] = r if s1 in matching_hints and s2 in matching_hints: matching_hints["1st_homogeneous_coeff_best"] = r ## Linear coefficients of the form # y'+ F((ax + by + c)/(a'x + b'y + c')) = 0 # that can be reduced to homogeneous form. F = num/den params = _linear_coeff_match(F, func) if params: xarg, yarg = params u = Dummy('u') t = Dummy('t') # Dummy substitution for df and f(x). dummy_eq = reduced_eq.subs(((df, t), (f(x), u))) reps = ((x, x + xarg), (u, u + yarg), (t, df), (u, f(x))) dummy_eq = simplify(dummy_eq.subs(reps)) # get the re-cast values for e and d r2 = collect(expand(dummy_eq), [df, f(x)]).match(edf + d) if r2: orderd = homogeneous_order(r2[d], x, f(x)) if orderd is not None: ordere = homogeneous_order(r2[e], x, f(x)) if orderd == ordere: # Match arguments are passed in such a way that it # is coherent with the already existing homogeneous # functions. r2[d] = r2[d].subs(f(x), y) r2[e] = r2[e].subs(f(x), y) r2.update({'xarg': xarg, 'yarg': yarg, 'd': d, 'e': e, 'y': y}) matching_hints["linear_coefficients"] = r2 matching_hints["linear_coefficients_Integral"] = r2 ## Equation of the form y' + (y/x)H(x^ny) = 0 # that can be reduced to separable form factor = simplify(x/f(x)num/den) # Try representing factor in terms of x^ny # where n is lowest power of x in factor; # first remove terms like sqrt(2)3 from factor.atoms(Mul) u = None for mul in ordered(factor.atoms(Mul)): if mul.has(x): _, u = mul.as_independent(x, f(x)) break if u and u.has(f(x)): h = x*(degree(Poly(u.subs(f(x), y), gen=x)))f(x) p = Wild('p') if (u/h == 1) or ((u/h).simplify().match(x*p)): t = Dummy('t') r2 = {'t': t} xpart, ypart = u.as_independent(f(x)) test = factor.subs(((u, t), (1/u, 1/t))) free = test.free_symbols if len(free) == 1 and free.pop() == t: r2.update({'power': xpart.as_base_exp()[1], 'u': test}) matching_hints["separable_reduced"] = r2 matching_hints["separable_reduced_Integral"] = r2 ## Almost-linear equation of the form f(x)g(y)y' + k(x)l(y) + m(x) = 0 r = collect(eq, [df, f(x)]).match(edf + d) if r: r2 = r.copy() r2[c] = S.Zero if r2[d].is_Add: # Separate the terms having f(x) to r[d] and # remaining to r[c] no_f, r2[d] = r2[d].as_independent(f(x)) r2[c] += no_f factor = simplify(r2[d].diff(f(x))/r[e]) if factor and not factor.has(f(x)): r2[d] = factor_terms(r2[d]) u = r2[d].as_independent(f(x), as_Add=False)[1] r2.update({'a': e, 'b': d, 'c': c, 'u': u}) r2[d] /= u r2[e] /= u.diff(f(x)) matching_hints["almost_linear"] = r2 matching_hints["almost_linear_Integral"] = r2 elif order == 2: # Liouville ODE in the form # f(x).diff(x, 2) + g(f(x))(f(x).diff(x))*2 + h(x)f(x).diff(x) # See Goldstein and Braun, "Advanced Methods for the Solution of # Differential Equations", pg. 98 s = df(x).diff(x, 2) + edf*2 + kdf r = reduced_eq.match(s) if r and r[d] != 0: y = Dummy('y') g = simplify(r[e]/r[d]).subs(f(x), y) h = simplify(r[k]/r[d]).subs(f(x), y) if y in h.free_symbols or x in g.free_symbols: pass else: r = {'g': g, 'h': h, 'y': y} matching_hints["Liouville"] = r matching_hints["Liouville_Integral"] = r # Homogeneous second order differential equation of the form # a3f(x).diff(x, 2) + b3f(x).diff(x) + c3, where # for simplicity, a3, b3 and c3 are assumed to be polynomials. # It has a definite power series solution at point x0 if, b3/a3 and c3/a3 # are analytic at x0. deq = a3(f(x).diff(x, 2)) + b3df + c3f(x) r = collect(reduced_eq, [f(x).diff(x, 2), f(x).diff(x), f(x)]).match(deq) ordinary = False if r and r[a3] != 0: if all([r[key].is_polynomial() for key in r]): p = cancel(r[b3]/r[a3]) # Used below q = cancel(r[c3]/r[a3]) # Used below point = kwargs.get('x0', 0) check = p.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): check = q.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): ordinary = True r.update({'a3': a3, 'b3': b3, 'c3': c3, 'x0': point, 'terms': terms}) matching_hints["2nd_power_series_ordinary"] = r # Checking if the differential equation has a regular singular point # at x0. It has a regular singular point at x0, if (b3/a3)(x - x0) # and (c3/a3)((x - x0)2) are analytic at x0. if not ordinary: p = cancel((x - point)p) check = p.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): q = cancel(((x - point)*2)q) check = q.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): coeff_dict = {'p': p, 'q': q, 'x0': point, 'terms': terms} matching_hints["2nd_power_series_regular"] = coeff_dict if order > 0: # Any ODE that can be solved with a substitution and # repeated integration e.g.: # `d^2/dx^2(y) + xd/dx(y) = constant #f'(x) must be finite for this to work r = _nth_order_reducible_match(reduced_eq, func) if r: matching_hints['nth_order_reducible'] = r # Any ODE that can be solved with a combination of algebra and # integrals e.g.: # d^3/dx^3(x y) = F(x) r = _nth_algebraic_match(reduced_eq, func) if r['solutions']: matching_hints['nth_algebraic'] = r matching_hints['nth_algebraic_Integral'] = r # nth order linear ODE # a_n(x)y^(n) + ... + a_1(x)y' + a_0(x)y = F(x) = b r = _nth_linear_match(reduced_eq, func, order) # Constant coefficient case (a_i is constant for all i) if r and not any(r[i].has(x) for i in r if i >= 0): # Inhomogeneous case: F(x) is not identically 0 if r[-1]: undetcoeff = _undetermined_coefficients_match(r[-1], x) s = "nth_linear_constant_coeff_variation_of_parameters" matching_hints[s] = r matching_hints[s + "_Integral"] = r if undetcoeff['test']: r['trialset'] = undetcoeff['trialset'] matching_hints[ "nth_linear_constant_coeff_undetermined_coefficients" ] = r # Homogeneous case: F(x) is identically 0 else: matching_hints["nth_linear_constant_coeff_homogeneous"] = r # nth order Euler equation a_nx*ny^(n) + ... + a_1xy' + a_0y = F(x) #In case of Homogeneous euler equation F(x) = 0 def _test_term(coeff, order): r""" Linear Euler ODEs have the form Kx*orderdiff(y(x),x,order) = F(x), where K is independent of x and y(x), order>= 0. So we need to check that for each term, coeff == Kxorder from some K. We have a few cases, since coeff may have several different types. """ if order < 0: raise ValueError("order should be greater than 0") if coeff == 0: return True if order == 0: if x in coeff.free_symbols: return False return True if coeff.is_Mul: if coeff.has(f(x)): return False return xorder in coeff.args elif coeff.is_Pow: return coeff.as_base_exp() == (x, order) elif order == 1: return x == coeff return False # Find coefficient for higest derivative, multiply coefficients to # bring the equation into Euler form if possible r_rescaled = None if r is not None: coeff = r[order] factor = xorder / coeff r_rescaled = {i: factorr[i] for i in r} if r_rescaled and not any(not _test_term(r_rescaled[i], i) for i in r_rescaled if i != 'trialset' and i >= 0): if not r_rescaled[-1]: matching_hints["nth_linear_euler_eq_homogeneous"] = r_rescaled else: matching_hints["nth_linear_euler_eq_nonhomogeneous_variation_of_parameters"] = r_rescaled matching_hints["nth_linear_euler_eq_nonhomogeneous_variation_of_parameters_Integral"] = r_rescaled e, re = posify(r_rescaled[-1].subs(x, exp(x))) undetcoeff = _undetermined_coefficients_match(e.subs(re), x) if undetcoeff['test']: r_rescaled['trialset'] = undetcoeff['trialset'] matching_hints["nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients"] = r_rescaled # Order keys based on allhints. retlist = [i for i in allhints if i in matching_hints] if dict: # Dictionaries are ordered arbitrarily, so make note of which # hint would come first for dsolve(). Use an ordered dict in Py 3. matching_hints["default"] = retlist[0] if retlist else None matching_hints["ordered_hints"] = tuple(retlist) return matching_hints else: return tuple(retlist) def classify_sysode(eq, funcs=None, *kwargs): r""" Returns a dictionary of parameter names and values that define the system of ordinary differential equations in ``eq``. The parameters are further used in :py:meth:`~sympy.solvers.ode.dsolve` for solving that system. The parameter names and values are: 'is_linear' (boolean), which tells whether the given system is linear. Note that "linear" here refers to the operator: terms such as ``xdiff(x,t)`` are nonlinear, whereas terms like ``sin(t)diff(x,t)`` are still linear operators. 'func' (list) contains the :py:class:`~sympy.core.function.Function`s that appear with a derivative in the ODE, i.e. those that we are trying to solve the ODE for. 'order' (dict) with the maximum derivative for each element of the 'func' parameter. 'func_coeff' (dict) with the coefficient for each triple ``(equation number, function, order)```. The coefficients are those subexpressions that do not appear in 'func', and hence can be considered constant for purposes of ODE solving. 'eq' (list) with the equations from ``eq``, sympified and transformed into expressions (we are solving for these expressions to be zero). 'no_of_equations' (int) is the number of equations (same as ``len(eq)``). 'type_of_equation' (string) is an internal classification of the type of ODE. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode-toc1.htm -A. D. Polyanin and A. V. Manzhirov, Handbook of Mathematics for Engineers and Scientists Examples ======== >>> from sympy import Function, Eq, symbols, diff >>> from sympy.solvers.ode import classify_sysode >>> from sympy.abc import t >>> f, x, y = symbols('f, x, y', cls=Function) >>> k, l, m, n = symbols('k, l, m, n', Integer=True) >>> x1 = diff(x(t), t) ; y1 = diff(y(t), t) >>> x2 = diff(x(t), t, t) ; y2 = diff(y(t), t, t) >>> eq = (Eq(5x1, 12x(t) - 6y(t)), Eq(2y1, 11x(t) + 3y(t))) >>> classify_sysode(eq) {'eq': [-12x(t) + 6y(t) + 5Derivative(x(t), t), -11x(t) - 3y(t) + 2Derivative(y(t), t)], 'func': [x(t), y(t)], 'func_coeff': {(0, x(t), 0): -12, (0, x(t), 1): 5, (0, y(t), 0): 6, (0, y(t), 1): 0, (1, x(t), 0): -11, (1, x(t), 1): 0, (1, y(t), 0): -3, (1, y(t), 1): 2}, 'is_linear': True, 'no_of_equation': 2, 'order': {x(t): 1, y(t): 1}, 'type_of_equation': 'type1'} >>> eq = (Eq(diff(x(t),t), 5tx(t) + t2y(t)), Eq(diff(y(t),t), -t*2x(t) + 5ty(t))) >>> classify_sysode(eq) {'eq': [-t*2y(t) - 5tx(t) + Derivative(x(t), t), t*2x(t) - 5ty(t) + Derivative(y(t), t)], 'func': [x(t), y(t)], 'func_coeff': {(0, x(t), 0): -5t, (0, x(t), 1): 1, (0, y(t), 0): -t2, (0, y(t), 1): 0, (1, x(t), 0): t2, (1, x(t), 1): 0, (1, y(t), 0): -5t, (1, y(t), 1): 1}, 'is_linear': True, 'no_of_equation': 2, 'order': {x(t): 1, y(t): 1}, 'type_of_equation': 'type4'} """ # Sympify equations and convert iterables of equations into # a list of equations def _sympify(eq): return list(map(sympify, eq if iterable(eq) else [eq])) eq, funcs = (_sympify(w) for w in [eq, funcs]) for i, fi in enumerate(eq): if isinstance(fi, Equality): eq[i] = fi.lhs - fi.rhs matching_hints = {"no_of_equation":i+1} matching_hints['eq'] = eq if i==0: raise ValueError("classify_sysode() works for systems of ODEs. " "For scalar ODEs, classify_ode should be used") t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] # find all the functions if not given order = dict() if funcs==[None]: funcs = [] for eqs in eq: derivs = eqs.atoms(Derivative) func = set().union([d.atoms(AppliedUndef) for d in derivs]) for func_ in func: funcs.append(func_) funcs = list(set(funcs)) if len(funcs) != len(eq): raise ValueError("Number of functions given is not equal to the number of equations %s" % funcs) func_dict = dict() for func in funcs: if not order.get(func, False): max_order = 0 for i, eqs_ in enumerate(eq): order_ = ode_order(eqs_,func) if max_order < order_: max_order = order_ eq_no = i if eq_no in func_dict: list_func = [] list_func.append(func_dict[eq_no]) list_func.append(func) func_dict[eq_no] = list_func else: func_dict[eq_no] = func order[func] = max_order funcs = [func_dict[i] for i in range(len(func_dict))] matching_hints['func'] = funcs for func in funcs: if isinstance(func, list): for func_elem in func: if len(func_elem.args) != 1: raise ValueError("dsolve() and classify_sysode() work with " "functions of one variable only, not %s" % func) else: if func and len(func.args) != 1: raise ValueError("dsolve() and classify_sysode() work with " "functions of one variable only, not %s" % func) # find the order of all equation in system of odes matching_hints["order"] = order # find coefficients of terms f(t), diff(f(t),t) and higher derivatives # and similarly for other functions g(t), diff(g(t),t) in all equations. # Here j denotes the equation number, funcs[l] denotes the function about # which we are talking about and k denotes the order of function funcs[l] # whose coefficient we are calculating. def linearity_check(eqs, j, func, is_linear_): for k in range(order[func] + 1): func_coef[j, func, k] = collect(eqs.expand(), [diff(func, t, k)]).coeff(diff(func, t, k)) if is_linear_ == True: if func_coef[j, func, k] == 0: if k == 0: coef = eqs.as_independent(func, as_Add=True)[1] for xr in range(1, ode_order(eqs,func) + 1): coef -= eqs.as_independent(diff(func, t, xr), as_Add=True)[1] if coef != 0: is_linear_ = False else: if eqs.as_independent(diff(func, t, k), as_Add=True)[1]: is_linear_ = False else: for func_ in funcs: if isinstance(func_, list): for elem_func_ in func_: dep = func_coef[j, func, k].as_independent(elem_func_, as_Add=True)[1] if dep != 0: is_linear_ = False else: dep = func_coef[j, func, k].as_independent(func_, as_Add=True)[1] if dep != 0: is_linear_ = False return is_linear_ func_coef = {} is_linear = True for j, eqs in enumerate(eq): for func in funcs: if isinstance(func, list): for func_elem in func: is_linear = linearity_check(eqs, j, func_elem, is_linear) else: is_linear = linearity_check(eqs, j, func, is_linear) matching_hints['func_coeff'] = func_coef matching_hints['is_linear'] = is_linear if len(set(order.values())) == 1: order_eq = list(matching_hints['order'].values())[0] if matching_hints['is_linear'] == True: if matching_hints['no_of_equation'] == 2: if order_eq == 1: type_of_equation = check_linear_2eq_order1(eq, funcs, func_coef) elif order_eq == 2: type_of_equation = check_linear_2eq_order2(eq, funcs, func_coef) else: type_of_equation = None elif matching_hints['no_of_equation'] == 3: if order_eq == 1: type_of_equation = check_linear_3eq_order1(eq, funcs, func_coef) if type_of_equation is None: type_of_equation = check_linear_neq_order1(eq, funcs, func_coef) else: type_of_equation = None else: if order_eq == 1: type_of_equation = check_linear_neq_order1(eq, funcs, func_coef) else: type_of_equation = None else: if matching_hints['no_of_equation'] == 2: if order_eq == 1: type_of_equation = check_nonlinear_2eq_order1(eq, funcs, func_coef) else: type_of_equation = None elif matching_hints['no_of_equation'] == 3: if order_eq == 1: type_of_equation = check_nonlinear_3eq_order1(eq, funcs, func_coef) else: type_of_equation = None else: type_of_equation = None else: type_of_equation = None matching_hints['type_of_equation'] = type_of_equation return matching_hints def check_linear_2eq_order1(eq, func, func_coef): x = func[0].func y = func[1].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] r = dict() # for equations Eq(a1diff(x(t),t), b1x(t) + c1y(t) + d1) # and Eq(a2diff(y(t),t), b2x(t) + c2y(t) + d2) r['a1'] = fc[0,x(t),1] ; r['a2'] = fc[1,y(t),1] r['b1'] = -fc[0,x(t),0]/fc[0,x(t),1] ; r['b2'] = -fc[1,x(t),0]/fc[1,y(t),1] r['c1'] = -fc[0,y(t),0]/fc[0,x(t),1] ; r['c2'] = -fc[1,y(t),0]/fc[1,y(t),1] forcing = [S(0),S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t)): forcing[i] += j if not (forcing[0].has(t) or forcing[1].has(t)): # We can handle homogeneous case and simple constant forcings r['d1'] = forcing[0] r['d2'] = forcing[1] else: # Issue #9244: nonhomogeneous linear systems are not supported return None # Conditions to check for type 6 whose equations are Eq(diff(x(t),t), f(t)x(t) + g(t)y(t)) and # Eq(diff(y(t),t), a[f(t) + ah(t)]x(t) + a[g(t) - h(t)]y(t)) p = 0 q = 0 p1 = cancel(r['b2']/(cancel(r['b2']/r['c2']).as_numer_denom()[0])) p2 = cancel(r['b1']/(cancel(r['b1']/r['c1']).as_numer_denom()[0])) for n, i in enumerate([p1, p2]): for j in Mul.make_args(collect_const(i)): if not j.has(t): q = j if q and n==0: if ((r['b2']/j - r['b1'])/(r['c1'] - r['c2']/j)) == j: p = 1 elif q and n==1: if ((r['b1']/j - r['b2'])/(r['c2'] - r['c1']/j)) == j: p = 2 # End of condition for type 6 if r['d1']!=0 or r['d2']!=0: if not r['d1'].has(t) and not r['d2'].has(t): if all(not r[k].has(t) for k in 'a1 a2 b1 b2 c1 c2'.split()): # Equations for type 2 are Eq(a1diff(x(t),t),b1x(t)+c1y(t)+d1) and Eq(a2diff(y(t),t),b2x(t)+c2y(t)+d2) return "type2" else: return None else: if all(not r[k].has(t) for k in 'a1 a2 b1 b2 c1 c2'.split()): # Equations for type 1 are Eq(a1diff(x(t),t),b1x(t)+c1y(t)) and Eq(a2diff(y(t),t),b2x(t)+c2y(t)) return "type1" else: r['b1'] = r['b1']/r['a1'] ; r['b2'] = r['b2']/r['a2'] r['c1'] = r['c1']/r['a1'] ; r['c2'] = r['c2']/r['a2'] if (r['b1'] == r['c2']) and (r['c1'] == r['b2']): # Equation for type 3 are Eq(diff(x(t),t), f(t)x(t) + g(t)y(t)) and Eq(diff(y(t),t), g(t)x(t) + f(t)y(t)) return "type3" elif (r['b1'] == r['c2']) and (r['c1'] == -r['b2']) or (r['b1'] == -r['c2']) and (r['c1'] == r['b2']): # Equation for type 4 are Eq(diff(x(t),t), f(t)x(t) + g(t)y(t)) and Eq(diff(y(t),t), -g(t)x(t) + f(t)y(t)) return "type4" elif (not cancel(r['b2']/r['c1']).has(t) and not cancel((r['c2']-r['b1'])/r['c1']).has(t)) \ or (not cancel(r['b1']/r['c2']).has(t) and not cancel((r['c1']-r['b2'])/r['c2']).has(t)): # Equations for type 5 are Eq(diff(x(t),t), f(t)x(t) + g(t)y(t)) and Eq(diff(y(t),t), ag(t)x(t) + [f(t) + bg(t)]y(t) return "type5" elif p: return "type6" else: # Equations for type 7 are Eq(diff(x(t),t), f(t)x(t) + g(t)y(t)) and Eq(diff(y(t),t), h(t)x(t) + p(t)y(t)) return "type7" def check_linear_2eq_order2(eq, func, func_coef): x = func[0].func y = func[1].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] r = dict() a = Wild('a', exclude=[1/t]) b = Wild('b', exclude=[1/t2]) u = Wild('u', exclude=[t, t2]) v = Wild('v', exclude=[t, t2]) w = Wild('w', exclude=[t, t2]) p = Wild('p', exclude=[t, t2]) r['a1'] = fc[0,x(t),2] ; r['a2'] = fc[1,y(t),2] r['b1'] = fc[0,x(t),1] ; r['b2'] = fc[1,x(t),1] r['c1'] = fc[0,y(t),1] ; r['c2'] = fc[1,y(t),1] r['d1'] = fc[0,x(t),0] ; r['d2'] = fc[1,x(t),0] r['e1'] = fc[0,y(t),0] ; r['e2'] = fc[1,y(t),0] const = [S(0), S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not (j.has(x(t)) or j.has(y(t))): const[i] += j r['f1'] = const[0] r['f2'] = const[1] if r['f1']!=0 or r['f2']!=0: if all(not r[k].has(t) for k in 'a1 a2 d1 d2 e1 e2 f1 f2'.split()) \ and r['b1']==r['c1']==r['b2']==r['c2']==0: return "type2" elif all(not r[k].has(t) for k in 'a1 a2 b1 b2 c1 c2 d1 d2 e1 e1'.split()): p = [S(0), S(0)] ; q = [S(0), S(0)] for n, e in enumerate([r['f1'], r['f2']]): if e.has(t): tpart = e.as_independent(t, Mul)[1] for i in Mul.make_args(tpart): if i.has(exp): b, e = i.as_base_exp() co = e.coeff(t) if co and not co.has(t) and co.has(I): p[n] = 1 else: q[n] = 1 else: q[n] = 1 else: q[n] = 1 if p[0]==1 and p[1]==1 and q[0]==0 and q[1]==0: return "type4" else: return None else: return None else: if r['b1']==r['b2']==r['c1']==r['c2']==0 and all(not r[k].has(t) \ for k in 'a1 a2 d1 d2 e1 e2'.split()): return "type1" elif r['b1']==r['e1']==r['c2']==r['d2']==0 and all(not r[k].has(t) \ for k in 'a1 a2 b2 c1 d1 e2'.split()) and r['c1'] == -r['b2'] and \ r['d1'] == r['e2']: return "type3" elif cancel(-r['b2']/r['d2'])==t and cancel(-r['c1']/r['e1'])==t and not \ (r['d2']/r['a2']).has(t) and not (r['e1']/r['a1']).has(t) and \ r['b1']==r['d1']==r['c2']==r['e2']==0: return "type5" elif ((r['a1']/r['d1']).expand()).match((p(ut2+vt+w)*2).expand()) and not \ (cancel(r['a1']r['d2']/(r['a2']r['d1']))).has(t) and not (r['d1']/r['e1']).has(t) and not \ (r['d2']/r['e2']).has(t) and r['b1'] == r['b2'] == r['c1'] == r['c2'] == 0: return "type10" elif not cancel(r['d1']/r['e1']).has(t) and not cancel(r['d2']/r['e2']).has(t) and not \ cancel(r['d1']r['a2']/(r['d2']r['a1'])).has(t) and r['b1']==r['b2']==r['c1']==r['c2']==0: return "type6" elif not cancel(r['b1']/r['c1']).has(t) and not cancel(r['b2']/r['c2']).has(t) and not \ cancel(r['b1']r['a2']/(r['b2']r['a1'])).has(t) and r['d1']==r['d2']==r['e1']==r['e2']==0: return "type7" elif cancel(-r['b2']/r['d2'])==t and cancel(-r['c1']/r['e1'])==t and not \ cancel(r['e1']r['a2']/(r['d2']r['a1'])).has(t) and r['e1'].has(t) \ and r['b1']==r['d1']==r['c2']==r['e2']==0: return "type8" elif (r['b1']/r['a1']).match(a/t) and (r['b2']/r['a2']).match(a/t) and not \ (r['b1']/r['c1']).has(t) and not (r['b2']/r['c2']).has(t) and \ (r['d1']/r['a1']).match(b/t2) and (r['d2']/r['a2']).match(b/t2) \ and not (r['d1']/r['e1']).has(t) and not (r['d2']/r['e2']).has(t): return "type9" elif -r['b1']/r['d1']==-r['c1']/r['e1']==-r['b2']/r['d2']==-r['c2']/r['e2']==t: return "type11" else: return None def check_linear_3eq_order1(eq, func, func_coef): x = func[0].func y = func[1].func z = func[2].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] r = dict() r['a1'] = fc[0,x(t),1]; r['a2'] = fc[1,y(t),1]; r['a3'] = fc[2,z(t),1] r['b1'] = fc[0,x(t),0]; r['b2'] = fc[1,x(t),0]; r['b3'] = fc[2,x(t),0] r['c1'] = fc[0,y(t),0]; r['c2'] = fc[1,y(t),0]; r['c3'] = fc[2,y(t),0] r['d1'] = fc[0,z(t),0]; r['d2'] = fc[1,z(t),0]; r['d3'] = fc[2,z(t),0] forcing = [S(0), S(0), S(0)] for i in range(3): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t), z(t)): forcing[i] += j if forcing[0].has(t) or forcing[1].has(t) or forcing[2].has(t): # We can handle homogeneous case and simple constant forcings. # Issue #9244: nonhomogeneous linear systems are not supported return None if all(not r[k].has(t) for k in 'a1 a2 a3 b1 b2 b3 c1 c2 c3 d1 d2 d3'.split()): if r['c1']==r['d1']==r['d2']==0: return 'type1' elif r['c1'] == -r['b2'] and r['d1'] == -r['b3'] and r['d2'] == -r['c3'] \ and r['b1'] == r['c2'] == r['d3'] == 0: return 'type2' elif r['b1'] == r['c2'] == r['d3'] == 0 and r['c1']/r['a1'] == -r['d1']/r['a1'] \ and r['d2']/r['a2'] == -r['b2']/r['a2'] and r['b3']/r['a3'] == -r['c3']/r['a3']: return 'type3' else: return None else: for k1 in 'c1 d1 b2 d2 b3 c3'.split(): if r[k1] == 0: continue else: if all(not cancel(r[k1]/r[k]).has(t) for k in 'd1 b2 d2 b3 c3'.split() if r[k]!=0) \ and all(not cancel(r[k1]/(r['b1'] - r[k])).has(t) for k in 'b1 c2 d3'.split() if r['b1']!=r[k]): return 'type4' else: break return None def check_linear_neq_order1(eq, func, func_coef): fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] n = len(eq) for i in range(n): for j in range(n): if (fc[i, func[j], 0]/fc[i, func[i], 1]).has(t): return None if len(eq) == 3: return 'type6' return 'type1' def check_nonlinear_2eq_order1(eq, func, func_coef): t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] f = Wild('f') g = Wild('g') u, v = symbols('u, v', cls=Dummy) def check_type(x, y): r1 = eq[0].match(tdiff(x(t),t) - x(t) + f) r2 = eq[1].match(tdiff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = eq[0].match(diff(x(t),t) - x(t)/t + f/t) r2 = eq[1].match(diff(y(t),t) - y(t)/t + g/t) if not (r1 and r2): r1 = (-eq[0]).match(tdiff(x(t),t) - x(t) + f) r2 = (-eq[1]).match(tdiff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = (-eq[0]).match(diff(x(t),t) - x(t)/t + f/t) r2 = (-eq[1]).match(diff(y(t),t) - y(t)/t + g/t) if r1 and r2 and not (r1[f].subs(diff(x(t),t),u).subs(diff(y(t),t),v).has(t) \ or r2[g].subs(diff(x(t),t),u).subs(diff(y(t),t),v).has(t)): return 'type5' else: return None for func_ in func: if isinstance(func_, list): x = func[0][0].func y = func[0][1].func eq_type = check_type(x, y) if not eq_type: eq_type = check_type(y, x) return eq_type x = func[0].func y = func[1].func fc = func_coef n = Wild('n', exclude=[x(t),y(t)]) f1 = Wild('f1', exclude=[v,t]) f2 = Wild('f2', exclude=[v,t]) g1 = Wild('g1', exclude=[u,t]) g2 = Wild('g2', exclude=[u,t]) for i in range(2): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs r = eq[0].match(diff(x(t),t) - x(t)nf) if r: g = (diff(y(t),t) - eq[1])/r[f] if r and not (g.has(x(t)) or g.subs(y(t),v).has(t) or r[f].subs(x(t),u).subs(y(t),v).has(t)): return 'type1' r = eq[0].match(diff(x(t),t) - exp(nx(t))f) if r: g = (diff(y(t),t) - eq[1])/r[f] if r and not (g.has(x(t)) or g.subs(y(t),v).has(t) or r[f].subs(x(t),u).subs(y(t),v).has(t)): return 'type2' g = Wild('g') r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) if r1 and r2 and not (r1[f].subs(x(t),u).subs(y(t),v).has(t) or \ r2[g].subs(x(t),u).subs(y(t),v).has(t)): return 'type3' r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) num, den = ( (r1[f].subs(x(t),u).subs(y(t),v))/ (r2[g].subs(x(t),u).subs(y(t),v))).as_numer_denom() R1 = num.match(f1g1) R2 = den.match(f2g2) # phi = (r1[f].subs(x(t),u).subs(y(t),v))/num if R1 and R2: return 'type4' return None def check_nonlinear_2eq_order2(eq, func, func_coef): return None def check_nonlinear_3eq_order1(eq, func, func_coef): x = func[0].func y = func[1].func z = func[2].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] u, v, w = symbols('u, v, w', cls=Dummy) a = Wild('a', exclude=[x(t), y(t), z(t), t]) b = Wild('b', exclude=[x(t), y(t), z(t), t]) c = Wild('c', exclude=[x(t), y(t), z(t), t]) f = Wild('f') F1 = Wild('F1') F2 = Wild('F2') F3 = Wild('F3') for i in range(3): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs r1 = eq[0].match(diff(x(t),t) - ay(t)z(t)) r2 = eq[1].match(diff(y(t),t) - bz(t)x(t)) r3 = eq[2].match(diff(z(t),t) - cx(t)y(t)) if r1 and r2 and r3: num1, den1 = r1[a].as_numer_denom() num2, den2 = r2[b].as_numer_denom() num3, den3 = r3[c].as_numer_denom() if solve([num1u-den1(v-w), num2v-den2(w-u), num3w-den3(u-v)],[u, v]): return 'type1' r = eq[0].match(diff(x(t),t) - y(t)z(t)f) if r: r1 = collect_const(r[f]).match(af) r2 = ((diff(y(t),t) - eq[1])/r1[f]).match(bz(t)x(t)) r3 = ((diff(z(t),t) - eq[2])/r1[f]).match(cx(t)y(t)) if r1 and r2 and r3: num1, den1 = r1[a].as_numer_denom() num2, den2 = r2[b].as_numer_denom() num3, den3 = r3[c].as_numer_denom() if solve([num1u-den1(v-w), num2v-den2(w-u), num3w-den3(u-v)],[u, v]): return 'type2' r = eq[0].match(diff(x(t),t) - (F2-F3)) if r: r1 = collect_const(r[F2]).match(cF2) r1.update(collect_const(r[F3]).match(bF3)) if r1: if eq[1].has(r1[F2]) and not eq[1].has(r1[F3]): r1[F2], r1[F3] = r1[F3], r1[F2] r1[c], r1[b] = -r1[b], -r1[c] r2 = eq[1].match(diff(y(t),t) - ar1[F3] + r1[c]F1) if r2: r3 = (eq[2] == diff(z(t),t) - r1[b]r2[F1] + r2[a]r1[F2]) if r1 and r2 and r3: return 'type3' r = eq[0].match(diff(x(t),t) - z(t)F2 + y(t)F3) if r: r1 = collect_const(r[F2]).match(cF2) r1.update(collect_const(r[F3]).match(bF3)) if r1: if eq[1].has(r1[F2]) and not eq[1].has(r1[F3]): r1[F2], r1[F3] = r1[F3], r1[F2] r1[c], r1[b] = -r1[b], -r1[c] r2 = (diff(y(t),t) - eq[1]).match(ax(t)r1[F3] - r1[c]z(t)F1) if r2: r3 = (diff(z(t),t) - eq[2] == r1[b]y(t)r2[F1] - r2[a]x(t)r1[F2]) if r1 and r2 and r3: return 'type4' r = (diff(x(t),t) - eq[0]).match(x(t)(F2 - F3)) if r: r1 = collect_const(r[F2]).match(cF2) r1.update(collect_const(r[F3]).match(bF3)) if r1: if eq[1].has(r1[F2]) and not eq[1].has(r1[F3]): r1[F2], r1[F3] = r1[F3], r1[F2] r1[c], r1[b] = -r1[b], -r1[c] r2 = (diff(y(t),t) - eq[1]).match(y(t)(ar1[F3] - r1[c]F1)) if r2: r3 = (diff(z(t),t) - eq[2] == z(t)(r1[b]r2[F1] - r2[a]r1[F2])) if r1 and r2 and r3: return 'type5' return None def check_nonlinear_3eq_order2(eq, func, func_coef): return None def checksysodesol(eqs, sols, func=None): r""" Substitutes corresponding ``sols`` for each functions into each ``eqs`` and checks that the result of substitutions for each equation is ``0``. The equations and solutions passed can be any iterable. This only works when each ``sols`` have one function only, like `x(t)` or `y(t)`. For each function, ``sols`` can have a single solution or a list of solutions. In most cases it will not be necessary to explicitly identify the function, but if the function cannot be inferred from the original equation it can be supplied through the ``func`` argument. When a sequence of equations is passed, the same sequence is used to return the result for each equation with each function substituted with corresponding solutions. It tries the following method to find zero equivalence for each equation: Substitute the solutions for functions, like `x(t)` and `y(t)` into the original equations containing those functions. This function returns a tuple. The first item in the tuple is ``True`` if the substitution results for each equation is ``0``, and ``False`` otherwise. The second item in the tuple is what the substitution results in. Each element of the ``list`` should always be ``0`` corresponding to each equation if the first item is ``True``. Note that sometimes this function may return ``False``, but with an expression that is identically equal to ``0``, instead of returning ``True``. This is because :py:meth:`~sympy.simplify.simplify.simplify` cannot reduce the expression to ``0``. If an expression returned by each function vanishes identically, then ``sols`` really is a solution to ``eqs``. If this function seems to hang, it is probably because of a difficult simplification. Examples ======== >>> from sympy import Eq, diff, symbols, sin, cos, exp, sqrt, S, Function >>> from sympy.solvers.ode import checksysodesol >>> C1, C2 = symbols('C1:3') >>> t = symbols('t') >>> x, y = symbols('x, y', cls=Function) >>> eq = (Eq(diff(x(t),t), x(t) + y(t) + 17), Eq(diff(y(t),t), -2x(t) + y(t) + 12)) >>> sol = [Eq(x(t), (C1sin(sqrt(2)t) + C2cos(sqrt(2)t))exp(t) - S(5)/3), ... Eq(y(t), (sqrt(2)C1cos(sqrt(2)t) - sqrt(2)C2sin(sqrt(2)t))exp(t) - S(46)/3)] >>> checksysodesol(eq, sol) (True, [0, 0]) >>> eq = (Eq(diff(x(t),t),x(t)y(t)4), Eq(diff(y(t),t),y(t)3)) >>> sol = [Eq(x(t), C1exp(-1/(4(C2 + t)))), Eq(y(t), -sqrt(2)sqrt(-1/(C2 + t))/2), ... Eq(x(t), C1exp(-1/(4(C2 + t)))), Eq(y(t), sqrt(2)sqrt(-1/(C2 + t))/2)] >>> checksysodesol(eq, sol) (True, [0, 0]) """ def _sympify(eq): return list(map(sympify, eq if iterable(eq) else [eq])) eqs = _sympify(eqs) for i in range(len(eqs)): if isinstance(eqs[i], Equality): eqs[i] = eqs[i].lhs - eqs[i].rhs if func is None: funcs = [] for eq in eqs: derivs = eq.atoms(Derivative) func = set().union([d.atoms(AppliedUndef) for d in derivs]) for func_ in func: funcs.append(func_) funcs = list(set(funcs)) if not all(isinstance(func, AppliedUndef) and len(func.args) == 1 for func in funcs)\ and len({func.args for func in funcs})!=1: raise ValueError("func must be a function of one variable, not %s" % func) for sol in sols: if len(sol.atoms(AppliedUndef)) != 1: raise ValueError("solutions should have one function only") if len(funcs) != len({sol.lhs for sol in sols}): raise ValueError("number of solutions provided does not match the number of equations") dictsol = dict() for sol in sols: func = list(sol.atoms(AppliedUndef))[0] if sol.rhs == func: sol = sol.reversed solved = sol.lhs == func and not sol.rhs.has(func) if not solved: rhs = solve(sol, func) if not rhs: raise NotImplementedError else: rhs = sol.rhs dictsol[func] = rhs checkeq = [] for eq in eqs: for func in funcs: eq = sub_func_doit(eq, func, dictsol[func]) ss = simplify(eq) if ss != 0: eq = ss.expand(force=True) else: eq = 0 checkeq.append(eq) if len(set(checkeq)) == 1 and list(set(checkeq))[0] == 0: return (True, checkeq) else: return (False, checkeq) @vectorize(0) def odesimp(ode, eq, func, hint): r""" Simplifies solutions of ODEs, including trying to solve for ``func`` and running :py:meth:`~sympy.solvers.ode.constantsimp`. It may use knowledge of the type of solution that the hint returns to apply additional simplifications. It also attempts to integrate any :py:class:`~sympy.integrals.Integral`\s in the expression, if the hint is not an ``_Integral`` hint. This function should have no effect on expressions returned by :py:meth:`~sympy.solvers.ode.dsolve`, as :py:meth:`~sympy.solvers.ode.dsolve` already calls :py:meth:`~sympy.solvers.ode.odesimp`, but the individual hint functions do not call :py:meth:`~sympy.solvers.ode.odesimp` (because the :py:meth:`~sympy.solvers.ode.dsolve` wrapper does). Therefore, this function is designed for mainly internal use. Examples ======== >>> from sympy import sin, symbols, dsolve, pprint, Function >>> from sympy.solvers.ode import odesimp >>> x , u2, C1= symbols('x,u2,C1') >>> f = Function('f') >>> eq = dsolve(xf(x).diff(x) - f(x) - xsin(f(x)/x), f(x), ... hint='1st_homogeneous_coeff_subs_indep_div_dep_Integral', ... simplify=False) >>> pprint(eq, wrap_line=False) x ---- f(x) / \| \| / 1 \ \| -\|u2 + -------\| \| \| /1 \\| \| \| sin\|--\|\| \| \ \u2// log(f(x)) = log(C1) + \| ---------------- d(u2) \| 2 \| u2 \| / >>> pprint(odesimp(eq, f(x), 1, {C1}, ... hint='1st_homogeneous_coeff_subs_indep_div_dep' ... )) #doctest: +SKIP x --------- = C1 /f(x)\ tan\|----\| \2x / """ x = func.args[0] f = func.func C1 = get_numbered_constants(eq, num=1) constants = eq.free_symbols - ode.free_symbols # First, integrate if the hint allows it. eq = _handle_Integral(eq, func, hint) if hint.startswith("nth_linear_euler_eq_nonhomogeneous"): eq = simplify(eq) if not isinstance(eq, Equality): raise TypeError("eq should be an instance of Equality") # Second, clean up the arbitrary constants. # Right now, nth linear hints can put as many as 2order constants in an # expression. If that number grows with another hint, the third argument # here should be raised accordingly, or constantsimp() rewritten to handle # an arbitrary number of constants. eq = constantsimp(eq, constants) # Lastly, now that we have cleaned up the expression, try solving for func. # When CRootOf is implemented in solve(), we will want to return a CRootOf # every time instead of an Equality. # Get the f(x) on the left if possible. if eq.rhs == func and not eq.lhs.has(func): eq = [Eq(eq.rhs, eq.lhs)] # make sure we are working with lists of solutions in simplified form. if eq.lhs == func and not eq.rhs.has(func): # The solution is already solved eq = [eq] # special simplification of the rhs if hint.startswith("nth_linear_constant_coeff"): # Collect terms to make the solution look nice. # This is also necessary for constantsimp to remove unnecessary # terms from the particular solution from variation of parameters # # Collect is not behaving reliably here. The results for # some linear constant-coefficient equations with repeated # roots do not properly simplify all constants sometimes. # 'collectterms' gives different orders sometimes, and results # differ in collect based on that order. The # sort-reverse trick fixes things, but may fail in the # future. In addition, collect is splitting exponentials with # rational powers for no reason. We have to do a match # to fix this using Wilds. global collectterms try: collectterms.sort(key=default_sort_key) collectterms.reverse() except Exception: pass assert len(eq) == 1 and eq[0].lhs == f(x) sol = eq[0].rhs sol = expand_mul(sol) for i, reroot, imroot in collectterms: sol = collect(sol, xiexp(rerootx)sin(abs(imroot)x)) sol = collect(sol, xiexp(rerootx)cos(imrootx)) for i, reroot, imroot in collectterms: sol = collect(sol, xiexp(rerootx)) del collectterms # Collect is splitting exponentials with rational powers for # no reason. We call powsimp to fix. sol = powsimp(sol) eq[0] = Eq(f(x), sol) else: # The solution is not solved, so try to solve it try: floats = any(i.is_Float for i in eq.atoms(Number)) eqsol = solve(eq, func, force=True, rational=False if floats else None) if not eqsol: raise NotImplementedError except (NotImplementedError, PolynomialError): eq = [eq] else: def _expand(expr): numer, denom = expr.as_numer_denom() if denom.is_Add: return expr else: return powsimp(expr.expand(), combine='exp', deep=True) # XXX: the rest of odesimp() expects each ``t`` to be in a # specific normal form: rational expression with numerator # expanded, but with combined exponential functions (at # least in this setup all tests pass). eq = [Eq(f(x), _expand(t)) for t in eqsol] # special simplification of the lhs. if hint.startswith("1st_homogeneous_coeff"): for j, eqi in enumerate(eq): newi = logcombine(eqi, force=True) if isinstance(newi.lhs, log) and newi.rhs == 0: newi = Eq(newi.lhs.args[0]/C1, C1) eq[j] = newi # We cleaned up the constants before solving to help the solve engine with # a simpler expression, but the solved expression could have introduced # things like -C1, so rerun constantsimp() one last time before returning. for i, eqi in enumerate(eq): eq[i] = constantsimp(eqi, constants) eq[i] = constant_renumber(eq[i], ode.free_symbols) # If there is only 1 solution, return it; # otherwise return the list of solutions. if len(eq) == 1: eq = eq[0] return eq def checkodesol(ode, sol, func=None, order='auto', solve_for_func=True): r""" Substitutes ``sol`` into ``ode`` and checks that the result is ``0``. This only works when ``func`` is one function, like `f(x)`. ``sol`` can be a single solution or a list of solutions. Each solution may be an :py:class:`~sympy.core.relational.Equality` that the solution satisfies, e.g. ``Eq(f(x), C1), Eq(f(x) + C1, 0)``; or simply an :py:class:`~sympy.core.expr.Expr`, e.g. ``f(x) - C1``. In most cases it will not be necessary to explicitly identify the function, but if the function cannot be inferred from the original equation it can be supplied through the ``func`` argument. If a sequence of solutions is passed, the same sort of container will be used to return the result for each solution. It tries the following methods, in order, until it finds zero equivalence: 1. Substitute the solution for `f` in the original equation. This only works if ``ode`` is solved for `f`. It will attempt to solve it first unless ``solve_for_func == False``. 2. Take `n` derivatives of the solution, where `n` is the order of ``ode``, and check to see if that is equal to the solution. This only works on exact ODEs. 3. Take the 1st, 2nd, ..., `n`\th derivatives of the solution, each time solving for the derivative of `f` of that order (this will always be possible because `f` is a linear operator). Then back substitute each derivative into ``ode`` in reverse order. This function returns a tuple. The first item in the tuple is ``True`` if the substitution results in ``0``, and ``False`` otherwise. The second item in the tuple is what the substitution results in. It should always be ``0`` if the first item is ``True``. Sometimes this function will return ``False`` even when an expression is identically equal to ``0``. This happens when :py:meth:`~sympy.simplify.simplify.simplify` does not reduce the expression to ``0``. If an expression returned by this function vanishes identically, then ``sol`` really is a solution to the ``ode``. If this function seems to hang, it is probably because of a hard simplification. To use this function to test, test the first item of the tuple. Examples ======== >>> from sympy import Eq, Function, checkodesol, symbols >>> x, C1 = symbols('x,C1') >>> f = Function('f') >>> checkodesol(f(x).diff(x), Eq(f(x), C1)) (True, 0) >>> assert checkodesol(f(x).diff(x), C1)[0] >>> assert not checkodesol(f(x).diff(x), x)[0] >>> checkodesol(f(x).diff(x, 2), x2) (False, 2) """ if not isinstance(ode, Equality): ode = Eq(ode, 0) if func is None: try: _, func = _preprocess(ode.lhs) except ValueError: funcs = [s.atoms(AppliedUndef) for s in ( sol if is_sequence(sol, set) else [sol])] funcs = set().union(funcs) if len(funcs) != 1: raise ValueError( 'must pass func arg to checkodesol for this case.') func = funcs.pop() if not isinstance(func, AppliedUndef) or len(func.args) != 1: raise ValueError( "func must be a function of one variable, not %s" % func) if is_sequence(sol, set): return type(sol)([checkodesol(ode, i, order=order, solve_for_func=solve_for_func) for i in sol]) if not isinstance(sol, Equality): sol = Eq(func, sol) elif sol.rhs == func: sol = sol.reversed if order == 'auto': order = ode_order(ode, func) solved = sol.lhs == func and not sol.rhs.has(func) if solve_for_func and not solved: rhs = solve(sol, func) if rhs: eqs = [Eq(func, t) for t in rhs] if len(rhs) == 1: eqs = eqs[0] return checkodesol(ode, eqs, order=order, solve_for_func=False) s = True testnum = 0 x = func.args[0] while s: if testnum == 0: # First pass, try substituting a solved solution directly into the # ODE. This has the highest chance of succeeding. ode_diff = ode.lhs - ode.rhs if sol.lhs == func: s = sub_func_doit(ode_diff, func, sol.rhs) else: testnum += 1 continue ss = simplify(s) if ss: # with the new numer_denom in power.py, if we do a simple # expansion then testnum == 0 verifies all solutions. s = ss.expand(force=True) else: s = 0 testnum += 1 elif testnum == 1: # Second pass. If we cannot substitute f, try seeing if the nth # derivative is equal, this will only work for odes that are exact, # by definition. s = simplify( trigsimp(diff(sol.lhs, x, order) - diff(sol.rhs, x, order)) - trigsimp(ode.lhs) + trigsimp(ode.rhs)) # s2 = simplify( # diff(sol.lhs, x, order) - diff(sol.rhs, x, order) - \ # ode.lhs + ode.rhs) testnum += 1 elif testnum == 2: # Third pass. Try solving for df/dx and substituting that into the # ODE. Thanks to Chris Smith for suggesting this method. Many of # the comments below are his, too. # The method: # - Take each of 1..n derivatives of the solution. # - Solve each nth derivative for d^(n)f/dx^(n) # (the differential of that order) # - Back substitute into the ODE in decreasing order # (i.e., n, n-1, ...) # - Check the result for zero equivalence if sol.lhs == func and not sol.rhs.has(func): diffsols = {0: sol.rhs} elif sol.rhs == func and not sol.lhs.has(func): diffsols = {0: sol.lhs} else: diffsols = {} sol = sol.lhs - sol.rhs for i in range(1, order + 1): # Differentiation is a linear operator, so there should always # be 1 solution. Nonetheless, we test just to make sure. # We only need to solve once. After that, we automatically # have the solution to the differential in the order we want. if i == 1: ds = sol.diff(x) try: sdf = solve(ds, func.diff(x, i)) if not sdf: raise NotImplementedError except NotImplementedError: testnum += 1 break else: diffsols[i] = sdf[0] else: # This is what the solution says df/dx should be. diffsols[i] = diffsols[i - 1].diff(x) # Make sure the above didn't fail. if testnum > 2: continue else: # Substitute it into ODE to check for self consistency. lhs, rhs = ode.lhs, ode.rhs for i in range(order, -1, -1): if i == 0 and 0 not in diffsols: # We can only substitute f(x) if the solution was # solved for f(x). break lhs = sub_func_doit(lhs, func.diff(x, i), diffsols[i]) rhs = sub_func_doit(rhs, func.diff(x, i), diffsols[i]) ode_or_bool = Eq(lhs, rhs) ode_or_bool = simplify(ode_or_bool) if isinstance(ode_or_bool, (bool, BooleanAtom)): if ode_or_bool: lhs = rhs = S.Zero else: lhs = ode_or_bool.lhs rhs = ode_or_bool.rhs # No sense in overworking simplify -- just prove that the # numerator goes to zero num = trigsimp((lhs - rhs).as_numer_denom()[0]) # since solutions are obtained using force=True we test # using the same level of assumptions ## replace function with dummy so assumptions will work _func = Dummy('func') num = num.subs(func, _func) ## posify the expression num, reps = posify(num) s = simplify(num).xreplace(reps).xreplace({_func: func}) testnum += 1 else: break if not s: return (True, s) elif s is True: # The code above never was able to change s raise NotImplementedError("Unable to test if " + str(sol) + " is a solution to " + str(ode) + ".") else: return (False, s) def ode_sol_simplicity(sol, func, trysolving=True): r""" Returns an extended integer representing how simple a solution to an ODE is. The following things are considered, in order from most simple to least: - ``sol`` is solved for ``func``. - ``sol`` is not solved for ``func``, but can be if passed to solve (e.g., a solution returned by ``dsolve(ode, func, simplify=False``). - If ``sol`` is not solved for ``func``, then base the result on the length of ``sol``, as computed by ``len(str(sol))``. - If ``sol`` has any unevaluated :py:class:`~sympy.integrals.Integral`\s, this will automatically be considered less simple than any of the above. This function returns an integer such that if solution A is simpler than solution B by above metric, then ``ode_sol_simplicity(sola, func) < ode_sol_simplicity(solb, func)``. Currently, the following are the numbers returned, but if the heuristic is ever improved, this may change. Only the ordering is guaranteed. +----------------------------------------------+-------------------+ \| Simplicity \| Return \| +==============================================+===================+ \| ``sol`` solved for ``func`` \| ``-2`` \| +----------------------------------------------+-------------------+ \| ``sol`` not solved for ``func`` but can be \| ``-1`` \| +----------------------------------------------+-------------------+ \| ``sol`` is not solved nor solvable for \| ``len(str(sol))`` \| \| ``func`` \| \| +----------------------------------------------+-------------------+ \| ``sol`` contains an \| ``oo`` \| \| :py:class:`~sympy.integrals.Integral` \| \| +----------------------------------------------+-------------------+ ``oo`` here means the SymPy infinity, which should compare greater than any integer. If you already know :py:meth:`~sympy.solvers.solvers.solve` cannot solve ``sol``, you can use ``trysolving=False`` to skip that step, which is the only potentially slow step. For example, :py:meth:`~sympy.solvers.ode.dsolve` with the ``simplify=False`` flag should do this. If ``sol`` is a list of solutions, if the worst solution in the list returns ``oo`` it returns that, otherwise it returns ``len(str(sol))``, that is, the length of the string representation of the whole list. Examples ======== This function is designed to be passed to ``min`` as the key argument, such as ``min(listofsolutions, key=lambda i: ode_sol_simplicity(i, f(x)))``. >>> from sympy import symbols, Function, Eq, tan, cos, sqrt, Integral >>> from sympy.solvers.ode import ode_sol_simplicity >>> x, C1, C2 = symbols('x, C1, C2') >>> f = Function('f') >>> ode_sol_simplicity(Eq(f(x), C1x2), f(x)) -2 >>> ode_sol_simplicity(Eq(x2 + f(x), C1), f(x)) -1 >>> ode_sol_simplicity(Eq(f(x), C1Integral(2x, x)), f(x)) oo >>> eq1 = Eq(f(x)/tan(f(x)/(2x)), C1) >>> eq2 = Eq(f(x)/tan(f(x)/(2x) + f(x)), C2) >>> [ode_sol_simplicity(eq, f(x)) for eq in [eq1, eq2]] [28, 35] >>> min([eq1, eq2], key=lambda i: ode_sol_simplicity(i, f(x))) Eq(f(x)/tan(f(x)/(2x)), C1) """ # TODO: if two solutions are solved for f(x), we still want to be # able to get the simpler of the two # See the docstring for the coercion rules. We check easier (faster) # things here first, to save time. if iterable(sol): # See if there are Integrals for i in sol: if ode_sol_simplicity(i, func, trysolving=trysolving) == oo: return oo return len(str(sol)) if sol.has(Integral): return oo # Next, try to solve for func. This code will change slightly when CRootOf # is implemented in solve(). Probably a CRootOf solution should fall # somewhere between a normal solution and an unsolvable expression. # First, see if they are already solved if sol.lhs == func and not sol.rhs.has(func) or \ sol.rhs == func and not sol.lhs.has(func): return -2 # We are not so lucky, try solving manually if trysolving: try: sols = solve(sol, func) if not sols: raise NotImplementedError except NotImplementedError: pass else: return -1 # Finally, a naive computation based on the length of the string version # of the expression. This may favor combined fractions because they # will not have duplicate denominators, and may slightly favor expressions # with fewer additions and subtractions, as those are separated by spaces # by the printer. # Additional ideas for simplicity heuristics are welcome, like maybe # checking if a equation has a larger domain, or if constantsimp has # introduced arbitrary constants numbered higher than the order of a # given ODE that sol is a solution of. return len(str(sol)) def _get_constant_subexpressions(expr, Cs): Cs = set(Cs) Ces = [] def _recursive_walk(expr): expr_syms = expr.free_symbols if expr_syms and expr_syms.issubset(Cs): Ces.append(expr) else: if expr.func == exp: expr = expr.expand(mul=True) if expr.func in (Add, Mul): d = sift(expr.args, lambda i : i.free_symbols.issubset(Cs)) if len(d[True]) > 1: x = expr.func(d[True]) if not x.is_number: Ces.append(x) elif isinstance(expr, Integral): if expr.free_symbols.issubset(Cs) and \ all(len(x) == 3 for x in expr.limits): Ces.append(expr) for i in expr.args: _recursive_walk(i) return _recursive_walk(expr) return Ces def __remove_linear_redundancies(expr, Cs): cnts = {i: expr.count(i) for i in Cs} Cs = [i for i in Cs if cnts[i] > 0] def _linear(expr): if isinstance(expr, Add): xs = [i for i in Cs if expr.count(i)==cnts[i] \ and 0 == expr.diff(i, 2)] d = {} for x in xs: y = expr.diff(x) if y not in d: d[y]=[] d[y].append(x) for y in d: if len(d[y]) > 1: d[y].sort(key=str) for x in d[y][1:]: expr = expr.subs(x, 0) return expr def _recursive_walk(expr): if len(expr.args) != 0: expr = expr.func([_recursive_walk(i) for i in expr.args]) expr = _linear(expr) return expr if isinstance(expr, Equality): lhs, rhs = [_recursive_walk(i) for i in expr.args] f = lambda i: isinstance(i, Number) or i in Cs if isinstance(lhs, Symbol) and lhs in Cs: rhs, lhs = lhs, rhs if lhs.func in (Add, Symbol) and rhs.func in (Add, Symbol): dlhs = sift([lhs] if isinstance(lhs, AtomicExpr) else lhs.args, f) drhs = sift([rhs] if isinstance(rhs, AtomicExpr) else rhs.args, f) for i in [True, False]: for hs in [dlhs, drhs]: if i not in hs: hs[i] = [0] # this calculation can be simplified lhs = Add(dlhs[False]) - Add(drhs[False]) rhs = Add(drhs[True]) - Add(dlhs[True]) elif lhs.func in (Mul, Symbol) and rhs.func in (Mul, Symbol): dlhs = sift([lhs] if isinstance(lhs, AtomicExpr) else lhs.args, f) if True in dlhs: if False not in dlhs: dlhs[False] = [1] lhs = Mul(dlhs[False]) rhs = rhs/Mul(dlhs[True]) return Eq(lhs, rhs) else: return _recursive_walk(expr) @vectorize(0) def constantsimp(expr, constants): r""" Simplifies an expression with arbitrary constants in it. This function is written specifically to work with :py:meth:`~sympy.solvers.ode.dsolve`, and is not intended for general use. Simplification is done by "absorbing" the arbitrary constants into other arbitrary constants, numbers, and symbols that they are not independent of. The symbols must all have the same name with numbers after it, for example, ``C1``, ``C2``, ``C3``. The ``symbolname`` here would be '``C``', the ``startnumber`` would be 1, and the ``endnumber`` would be 3. If the arbitrary constants are independent of the variable ``x``, then the independent symbol would be ``x``. There is no need to specify the dependent function, such as ``f(x)``, because it already has the independent symbol, ``x``, in it. Because terms are "absorbed" into arbitrary constants and because constants are renumbered after simplifying, the arbitrary constants in expr are not necessarily equal to the ones of the same name in the returned result. If two or more arbitrary constants are added, multiplied, or raised to the power of each other, they are first absorbed together into a single arbitrary constant. Then the new constant is combined into other terms if necessary. Absorption of constants is done with limited assistance: 1. terms of :py:class:`~sympy.core.add.Add`\s are collected to try join constants so `e^x (C_1 \cos(x) + C_2 \cos(x))` will simplify to `e^x C_1 \cos(x)`; 2. powers with exponents that are :py:class:`~sympy.core.add.Add`\s are expanded so `e^{C_1 + x}` will be simplified to `C_1 e^x`. Use :py:meth:`~sympy.solvers.ode.constant_renumber` to renumber constants after simplification or else arbitrary numbers on constants may appear, e.g. `C_1 + C_3 x`. In rare cases, a single constant can be "simplified" into two constants. Every differential equation solution should have as many arbitrary constants as the order of the differential equation. The result here will be technically correct, but it may, for example, have `C_1` and `C_2` in an expression, when `C_1` is actually equal to `C_2`. Use your discretion in such situations, and also take advantage of the ability to use hints in :py:meth:`~sympy.solvers.ode.dsolve`. Examples ======== >>> from sympy import symbols >>> from sympy.solvers.ode import constantsimp >>> C1, C2, C3, x, y = symbols('C1, C2, C3, x, y') >>> constantsimp(2C1x, {C1, C2, C3}) C1x >>> constantsimp(C1 + 2 + x, {C1, C2, C3}) C1 + x >>> constantsimp(C1C2 + 2 + C2 + C3x, {C1, C2, C3}) C1 + C3x """ # This function works recursively. The idea is that, for Mul, # Add, Pow, and Function, if the class has a constant in it, then # we can simplify it, which we do by recursing down and # simplifying up. Otherwise, we can skip that part of the # expression. Cs = constants orig_expr = expr constant_subexprs = _get_constant_subexpressions(expr, Cs) for xe in constant_subexprs: xes = list(xe.free_symbols) if not xes: continue if all([expr.count(c) == xe.count(c) for c in xes]): xes.sort(key=str) expr = expr.subs(xe, xes[0]) # try to perform common sub-expression elimination of constant terms try: commons, rexpr = cse(expr) commons.reverse() rexpr = rexpr[0] for s in commons: cs = list(s[1].atoms(Symbol)) if len(cs) == 1 and cs[0] in Cs and \ cs[0] not in rexpr.atoms(Symbol) and \ not any(cs[0] in ex for ex in commons if ex != s): rexpr = rexpr.subs(s[0], cs[0]) else: rexpr = rexpr.subs(s) expr = rexpr except Exception: pass expr = __remove_linear_redundancies(expr, Cs) def _conditional_term_factoring(expr): new_expr = terms_gcd(expr, clear=False, deep=True, expand=False) # we do not want to factor exponentials, so handle this separately if new_expr.is_Mul: infac = False asfac = False for m in new_expr.args: if isinstance(m, exp): asfac = True elif m.is_Add: infac = any(isinstance(fi, exp) for t in m.args for fi in Mul.make_args(t)) if asfac and infac: new_expr = expr break return new_expr expr = _conditional_term_factoring(expr) # call recursively if more simplification is possible if orig_expr != expr: return constantsimp(expr, Cs) return expr def constant_renumber(expr, variables=None, newconstants=None): r""" Renumber arbitrary constants in ``expr`` to use the symbol names as given in ``newconstants``. In the process, this reorders expression terms in a standard way. If ``newconstants`` is not provided then the new constant names will be ``C1``, ``C2`` etc. Otherwise ``newconstants`` should be an iterable giving the new symbols to use for the constants in order. The ``variables`` argument is a list of non-constant symbols. All other free symbols found in ``expr`` are assumed to be constants and will be renumbered. If ``variables`` is not given then any numbered symbol beginning with ``C`` (e.g. ``C1``) is assumed to be a constant. Symbols are renumbered based on ``.sort_key()``, so they should be numbered roughly in the order that they appear in the final, printed expression. Note that this ordering is based in part on hashes, so it can produce different results on different machines. The structure of this function is very similar to that of :py:meth:`~sympy.solvers.ode.constantsimp`. Examples ======== >>> from sympy import symbols, Eq, pprint >>> from sympy.solvers.ode import constant_renumber >>> x, C1, C2, C3 = symbols('x,C1:4') >>> expr = C3 + C2x + C1x2 >>> expr C1x*2 + C2x + C3 >>> constant_renumber(expr) C1 + C2x + C3x*2 The ``variables`` argument specifies which are constants so that the other symbols will not be renumbered: >>> constant_renumber(expr, [C1, x]) C1x*2 + C2 + C3x The ``newconstants`` argument is used to specify what symbols to use when replacing the constants: >>> constant_renumber(expr, [x], newconstants=symbols('E1:4')) E1 + E2x + E3x*2 """ if type(expr) in (set, list, tuple): renumbered = [constant_renumber(e, variables, newconstants) for e in expr] return type(expr)(renumbered) # Symbols in solution but not ODE are constants if variables is not None: variables = set(variables) constantsymbols = list(expr.free_symbols - variables) # Any Cn is a constant... else: variables = set() isconstant = lambda s: s.startswith('C') and s[1:].isdigit() constantsymbols = [sym for sym in expr.free_symbols if isconstant(sym.name)] # Find new constants checking that they aren't alread in the ODE if newconstants is None: iter_constants = numbered_symbols(start=1, prefix='C', exclude=variables) else: iter_constants = (sym for sym in newconstants if sym not in variables) global newstartnumber newstartnumber = 1 endnumber = len(constantsymbols) constants_found = [None](endnumber + 2) # make a mapping to send all constantsymbols to S.One and use # that to make sure that term ordering is not dependent on # the indexed value of C C_1 = [(ci, S.One) for ci in constantsymbols] sort_key=lambda arg: default_sort_key(arg.subs(C_1)) def _constant_renumber(expr): r""" We need to have an internal recursive function so that newstartnumber maintains its values throughout recursive calls. """ # FIXME: Use nonlocal here when support for Py2 is dropped: global newstartnumber if isinstance(expr, Equality): return Eq( _constant_renumber(expr.lhs), _constant_renumber(expr.rhs)) if type(expr) not in (Mul, Add, Pow) and not expr.is_Function and \ not expr.has(constantsymbols): # Base case, as above. Hope there aren't constants inside # of some other class, because they won't be renumbered. return expr elif expr.is_Piecewise: return expr elif expr in constantsymbols: if expr not in constants_found: constants_found[newstartnumber] = expr newstartnumber += 1 return expr elif expr.is_Function or expr.is_Pow or isinstance(expr, Tuple): return expr.func( [_constant_renumber(x) for x in expr.args]) else: sortedargs = list(expr.args) sortedargs.sort(key=sort_key) return expr.func([_constant_renumber(x) for x in sortedargs]) expr = _constant_renumber(expr) # Don't renumber symbols present in the ODE. constants_found = [c for c in constants_found if c not in variables] # Renumbering happens here expr = expr.subs(zip(constants_found[1:], iter_constants), simultaneous=True) return expr def _handle_Integral(expr, func, hint): r""" Converts a solution with Integrals in it into an actual solution. For most hints, this simply runs ``expr.doit()``. """ global y x = func.args[0] f = func.func if hint == "1st_exact": sol = (expr.doit()).subs(y, f(x)) del y elif hint == "1st_exact_Integral": sol = Eq(Subs(expr.lhs, y, f(x)), expr.rhs) del y elif hint == "nth_linear_constant_coeff_homogeneous": sol = expr elif not hint.endswith("_Integral"): sol = expr.doit() else: sol = expr return sol # FIXME: replace the general solution in the docstring with # dsolve(equation, hint='1st_exact_Integral'). You will need to be able # to have assumptions on P and Q that dP/dy = dQ/dx. def ode_1st_exact(eq, func, order, match): r""" Solves 1st order exact ordinary differential equations. A 1st order differential equation is called exact if it is the total differential of a function. That is, the differential equation .. math:: P(x, y) \,\partial{}x + Q(x, y) \,\partial{}y = 0 is exact if there is some function `F(x, y)` such that `P(x, y) = \partial{}F/\partial{}x` and `Q(x, y) = \partial{}F/\partial{}y`. It can be shown that a necessary and sufficient condition for a first order ODE to be exact is that `\partial{}P/\partial{}y = \partial{}Q/\partial{}x`. Then, the solution will be as given below:: >>> from sympy import Function, Eq, Integral, symbols, pprint >>> x, y, t, x0, y0, C1= symbols('x,y,t,x0,y0,C1') >>> P, Q, F= map(Function, ['P', 'Q', 'F']) >>> pprint(Eq(Eq(F(x, y), Integral(P(t, y), (t, x0, x)) + ... Integral(Q(x0, t), (t, y0, y))), C1)) x y / / \| \| F(x, y) = \| P(t, y) dt + \| Q(x0, t) dt = C1 \| \| / / x0 y0 Where the first partials of `P` and `Q` exist and are continuous in a simply connected region. A note: SymPy currently has no way to represent inert substitution on an expression, so the hint ``1st_exact_Integral`` will return an integral with `dy`. This is supposed to represent the function that you are solving for. Examples ======== >>> from sympy import Function, dsolve, cos, sin >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(cos(f(x)) - (xsin(f(x)) - f(x)*2)f(x).diff(x), ... f(x), hint='1st_exact') Eq(xcos(f(x)) + f(x)3/3, C1) References ========== - https://en.wikipedia.org/wiki/Exact_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 73 # indirect doctest """ x = func.args[0] r = match # d+ediff(f(x),x) e = r[r['e']] d = r[r['d']] global y # This is the only way to pass dummy y to _handle_Integral y = r['y'] C1 = get_numbered_constants(eq, num=1) # Refer Joel Moses, "Symbolic Integration - The Stormy Decade", # Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 # which gives the method to solve an exact differential equation. sol = Integral(d, x) + Integral((e - (Integral(d, x).diff(y))), y) return Eq(sol, C1) def ode_1st_homogeneous_coeff_best(eq, func, order, match): r""" Returns the best solution to an ODE from the two hints ``1st_homogeneous_coeff_subs_dep_div_indep`` and ``1st_homogeneous_coeff_subs_indep_div_dep``. This is as determined by :py:meth:`~sympy.solvers.ode.ode_sol_simplicity`. See the :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep` and :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep` docstrings for more information on these hints. Note that there is no ``ode_1st_homogeneous_coeff_best_Integral`` hint. Examples ======== >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(2xf(x) + (x2 + f(x)2)f(x).diff(x), f(x), ... hint='1st_homogeneous_coeff_best', simplify=False)) / 2 \ \| 3x \| log\|----- + 1\| \| 2 \| \f (x) / log(f(x)) = log(C1) - -------------- 3 References ========== - https://en.wikipedia.org/wiki/Homogeneous_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 59 # indirect doctest """ # There are two substitutions that solve the equation, u1=y/x and u2=x/y # They produce different integrals, so try them both and see which # one is easier. sol1 = ode_1st_homogeneous_coeff_subs_indep_div_dep(eq, func, order, match) sol2 = ode_1st_homogeneous_coeff_subs_dep_div_indep(eq, func, order, match) simplify = match.get('simplify', True) if simplify: # why is odesimp called here? Should it be at the usual spot? sol1 = odesimp(eq, sol1, func, "1st_homogeneous_coeff_subs_indep_div_dep") sol2 = odesimp(eq, sol2, func, "1st_homogeneous_coeff_subs_dep_div_indep") return min([sol1, sol2], key=lambda x: ode_sol_simplicity(x, func, trysolving=not simplify)) def ode_1st_homogeneous_coeff_subs_dep_div_indep(eq, func, order, match): r""" Solves a 1st order differential equation with homogeneous coefficients using the substitution `u_1 = \frac{\text{<dependent variable>}}{\text{<independent variable>}}`. This is a differential equation .. math:: P(x, y) + Q(x, y) dy/dx = 0 such that `P` and `Q` are homogeneous and of the same order. A function `F(x, y)` is homogeneous of order `n` if `F(x t, y t) = t^n F(x, y)`. Equivalently, `F(x, y)` can be rewritten as `G(y/x)` or `H(x/y)`. See also the docstring of :py:meth:`~sympy.solvers.ode.homogeneous_order`. If the coefficients `P` and `Q` in the differential equation above are homogeneous functions of the same order, then it can be shown that the substitution `y = u_1 x` (i.e. `u_1 = y/x`) will turn the differential equation into an equation separable in the variables `x` and `u`. If `h(u_1)` is the function that results from making the substitution `u_1 = f(x)/x` on `P(x, f(x))` and `g(u_2)` is the function that results from the substitution on `Q(x, f(x))` in the differential equation `P(x, f(x)) + Q(x, f(x)) f'(x) = 0`, then the general solution is:: >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f, g, h = map(Function, ['f', 'g', 'h']) >>> genform = g(f(x)/x) + h(f(x)/x)f(x).diff(x) >>> pprint(genform) /f(x)\ /f(x)\ d g\|----\| + h\|----\|--(f(x)) \ x / \ x / dx >>> pprint(dsolve(genform, f(x), ... hint='1st_homogeneous_coeff_subs_dep_div_indep_Integral')) f(x) ---- x / \| \| -h(u1) log(x) = C1 + \| ---------------- d(u1) \| u1h(u1) + g(u1) \| / Where `u_1 h(u_1) + g(u_1) \ne 0` and `x \ne 0`. See also the docstrings of :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_best` and :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep`. Examples ======== >>> from sympy import Function, dsolve >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(2xf(x) + (x2 + f(x)2)f(x).diff(x), f(x), ... hint='1st_homogeneous_coeff_subs_dep_div_indep', simplify=False)) / 3 \ \|3f(x) f (x)\| log\|------ + -----\| \| x 3 \| \ x / log(x) = log(C1) - ------------------- 3 References ========== - https://en.wikipedia.org/wiki/Homogeneous_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 59 # indirect doctest """ x = func.args[0] f = func.func u = Dummy('u') u1 = Dummy('u1') # u1 == f(x)/x r = match # d+ediff(f(x),x) C1 = get_numbered_constants(eq, num=1) xarg = match.get('xarg', 0) yarg = match.get('yarg', 0) int = Integral( (-r[r['e']]/(r[r['d']] + u1r[r['e']])).subs({x: 1, r['y']: u1}), (u1, None, f(x)/x)) sol = logcombine(Eq(log(x), int + log(C1)), force=True) sol = sol.subs(f(x), u).subs(((u, u - yarg), (x, x - xarg), (u, f(x)))) return sol def ode_1st_homogeneous_coeff_subs_indep_div_dep(eq, func, order, match): r""" Solves a 1st order differential equation with homogeneous coefficients using the substitution `u_2 = \frac{\text{<independent variable>}}{\text{<dependent variable>}}`. This is a differential equation .. math:: P(x, y) + Q(x, y) dy/dx = 0 such that `P` and `Q` are homogeneous and of the same order. A function `F(x, y)` is homogeneous of order `n` if `F(x t, y t) = t^n F(x, y)`. Equivalently, `F(x, y)` can be rewritten as `G(y/x)` or `H(x/y)`. See also the docstring of :py:meth:`~sympy.solvers.ode.homogeneous_order`. If the coefficients `P` and `Q` in the differential equation above are homogeneous functions of the same order, then it can be shown that the substitution `x = u_2 y` (i.e. `u_2 = x/y`) will turn the differential equation into an equation separable in the variables `y` and `u_2`. If `h(u_2)` is the function that results from making the substitution `u_2 = x/f(x)` on `P(x, f(x))` and `g(u_2)` is the function that results from the substitution on `Q(x, f(x))` in the differential equation `P(x, f(x)) + Q(x, f(x)) f'(x) = 0`, then the general solution is: >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f, g, h = map(Function, ['f', 'g', 'h']) >>> genform = g(x/f(x)) + h(x/f(x))f(x).diff(x) >>> pprint(genform) / x \ / x \ d g\|----\| + h\|----\|--(f(x)) \f(x)/ \f(x)/ dx >>> pprint(dsolve(genform, f(x), ... hint='1st_homogeneous_coeff_subs_indep_div_dep_Integral')) x ---- f(x) / \| \| -g(u2) \| ---------------- d(u2) \| u2g(u2) + h(u2) \| / <BLANKLINE> f(x) = C1e Where `u_2 g(u_2) + h(u_2) \ne 0` and `f(x) \ne 0`. See also the docstrings of :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_best` and :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep`. Examples ======== >>> from sympy import Function, pprint, dsolve >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(2xf(x) + (x2 + f(x)2)f(x).diff(x), f(x), ... hint='1st_homogeneous_coeff_subs_indep_div_dep', ... simplify=False)) / 2 \ \| 3x \| log\|----- + 1\| \| 2 \| \f (x) / log(f(x)) = log(C1) - -------------- 3 References ========== - https://en.wikipedia.org/wiki/Homogeneous_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 59 # indirect doctest """ x = func.args[0] f = func.func u = Dummy('u') u2 = Dummy('u2') # u2 == x/f(x) r = match # d+ediff(f(x),x) C1 = get_numbered_constants(eq, num=1) xarg = match.get('xarg', 0) # If xarg present take xarg, else zero yarg = match.get('yarg', 0) # If yarg present take yarg, else zero int = Integral( simplify( (-r[r['d']]/(r[r['e']] + u2r[r['d']])).subs({x: u2, r['y']: 1})), (u2, None, x/f(x))) sol = logcombine(Eq(log(f(x)), int + log(C1)), force=True) sol = sol.subs(f(x), u).subs(((u, u - yarg), (x, x - xarg), (u, f(x)))) return sol # XXX: Should this function maybe go somewhere else? def homogeneous_order(eq, symbols): r""" Returns the order `n` if `g` is homogeneous and ``None`` if it is not homogeneous. Determines if a function is homogeneous and if so of what order. A function `f(x, y, \cdots)` is homogeneous of order `n` if `f(t x, t y, \cdots) = t^n f(x, y, \cdots)`. If the function is of two variables, `F(x, y)`, then `f` being homogeneous of any order is equivalent to being able to rewrite `F(x, y)` as `G(x/y)` or `H(y/x)`. This fact is used to solve 1st order ordinary differential equations whose coefficients are homogeneous of the same order (see the docstrings of :py:meth:`~solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep` and :py:meth:`~solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep`). Symbols can be functions, but every argument of the function must be a symbol, and the arguments of the function that appear in the expression must match those given in the list of symbols. If a declared function appears with different arguments than given in the list of symbols, ``None`` is returned. Examples ======== >>> from sympy import Function, homogeneous_order, sqrt >>> from sympy.abc import x, y >>> f = Function('f') >>> homogeneous_order(f(x), f(x)) is None True >>> homogeneous_order(f(x,y), f(y, x), x, y) is None True >>> homogeneous_order(f(x), f(x), x) 1 >>> homogeneous_order(x*2f(x)/sqrt(x2+f(x)2), x, f(x)) 2 >>> homogeneous_order(x*2+f(x), x, f(x)) is None True """ if not symbols: raise ValueError("homogeneous_order: no symbols were given.") symset = set(symbols) eq = sympify(eq) # The following are not supported if eq.has(Order, Derivative): return None # These are all constants if (eq.is_Number or eq.is_NumberSymbol or eq.is_number ): return S.Zero # Replace all functions with dummy variables dum = numbered_symbols(prefix='d', cls=Dummy) newsyms = set() for i in [j for j in symset if getattr(j, 'is_Function')]: iargs = set(i.args) if iargs.difference(symset): return None else: dummyvar = next(dum) eq = eq.subs(i, dummyvar) symset.remove(i) newsyms.add(dummyvar) symset.update(newsyms) if not eq.free_symbols & symset: return None # assuming order of a nested function can only be equal to zero if isinstance(eq, Function): return None if homogeneous_order( eq.args[0], tuple(symset)) != 0 else S.Zero # make the replacement of x with xt and see if t can be factored out t = Dummy('t', positive=True) # It is sufficient that t > 0 eqs = separatevars(eq.subs([(i, ti) for i in symset]), [t], dict=True)[t] if eqs is S.One: return S.Zero # there was no term with only t i, d = eqs.as_independent(t, as_Add=False) b, e = d.as_base_exp() if b == t: return e def ode_1st_linear(eq, func, order, match): r""" Solves 1st order linear differential equations. These are differential equations of the form .. math:: dy/dx + P(x) y = Q(x)\text{.} These kinds of differential equations can be solved in a general way. The integrating factor `e^{\int P(x) \,dx}` will turn the equation into a separable equation. The general solution is:: >>> from sympy import Function, dsolve, Eq, pprint, diff, sin >>> from sympy.abc import x >>> f, P, Q = map(Function, ['f', 'P', 'Q']) >>> genform = Eq(f(x).diff(x) + P(x)f(x), Q(x)) >>> pprint(genform) d P(x)f(x) + --(f(x)) = Q(x) dx >>> pprint(dsolve(genform, f(x), hint='1st_linear_Integral')) / / \ \| \| \| \| \| / \| / \| \| \| \| \| \| \| \| P(x) dx \| - \| P(x) dx \| \| \| \| \| \| \| / \| / f(x) = \|C1 + \| Q(x)e dx\|e \| \| \| \ / / Examples ======== >>> f = Function('f') >>> pprint(dsolve(Eq(xdiff(f(x), x) - f(x), x2sin(x)), ... f(x), '1st_linear')) f(x) = x(C1 - cos(x)) References ========== - https://en.wikipedia.org/wiki/Linear_differential_equation#First_order_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 92 # indirect doctest """ x = func.args[0] f = func.func r = match # adiff(f(x),x) + bf(x) + c C1 = get_numbered_constants(eq, num=1) t = exp(Integral(r[r['b']]/r[r['a']], x)) tt = Integral(t(-r[r['c']]/r[r['a']]), x) f = match.get('u', f(x)) # take almost-linear u if present, else f(x) return Eq(f, (tt + C1)/t) def ode_Bernoulli(eq, func, order, match): r""" Solves Bernoulli differential equations. These are equations of the form .. math:: dy/dx + P(x) y = Q(x) y^n\text{, }n \ne 1`\text{.} The substitution `w = 1/y^{1-n}` will transform an equation of this form into one that is linear (see the docstring of :py:meth:`~sympy.solvers.ode.ode_1st_linear`). The general solution is:: >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x, n >>> f, P, Q = map(Function, ['f', 'P', 'Q']) >>> genform = Eq(f(x).diff(x) + P(x)f(x), Q(x)f(x)*n) >>> pprint(genform) d n P(x)f(x) + --(f(x)) = Q(x)f (x) dx >>> pprint(dsolve(genform, f(x), hint='Bernoulli_Integral')) #doctest: +SKIP 1 ---- 1 - n // / \ \ \|\| \| \| \| \|\| \| / \| / \| \|\| \| \| \| \| \| \|\| \| (1 - n) \| P(x) dx \| (-1 + n)* \| P(x) dx\| \|\| \| \| \| \| \| \|\| \| / \| / \| f(x) = \|\|C1 + (-1 + n)* \| -Q(x)e dx\|e \| \|\| \| \| \| \\ / / / Note that the equation is separable when `n = 1` (see the docstring of :py:meth:`~sympy.solvers.ode.ode_separable`). >>> pprint(dsolve(Eq(f(x).diff(x) + P(x)f(x), Q(x)f(x)), f(x), ... hint='separable_Integral')) f(x) / \| / \| 1 \| \| - dy = C1 + \| (-P(x) + Q(x)) dx \| y \| \| / / Examples ======== >>> from sympy import Function, dsolve, Eq, pprint, log >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(Eq(xf(x).diff(x) + f(x), log(x)f(x)*2), ... f(x), hint='Bernoulli')) 1 f(x) = ------------------- / log(x) 1\ x\|C1 + ------ + -\| \ x x/ References ========== - https://en.wikipedia.org/wiki/Bernoulli_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 95 # indirect doctest """ x = func.args[0] f = func.func r = match # adiff(f(x),x) + bf(x) + cf(x)n, n != 1 C1 = get_numbered_constants(eq, num=1) t = exp((1 - r[r['n']])Integral(r[r['b']]/r[r['a']], x)) tt = (r[r['n']] - 1)Integral(tr[r['c']]/r[r['a']], x) return Eq(f(x), ((tt + C1)/t)*(1/(1 - r[r['n']]))) def ode_Riccati_special_minus2(eq, func, order, match): r""" The general Riccati equation has the form .. math:: dy/dx = f(x) y^2 + g(x) y + h(x)\text{.} While it does not have a general solution [1], the "special" form, `dy/dx = a y^2 - b x^c`, does have solutions in many cases [2]. This routine returns a solution for `a(dy/dx) = b y^2 + c y/x + d/x^2` that is obtained by using a suitable change of variables to reduce it to the special form and is valid when neither `a` nor `b` are zero and either `c` or `d` is zero. >>> from sympy.abc import x, y, a, b, c, d >>> from sympy.solvers.ode import dsolve, checkodesol >>> from sympy import pprint, Function >>> f = Function('f') >>> y = f(x) >>> genform = ay.diff(x) - (by2 + cy/x + d/x*2) >>> sol = dsolve(genform, y) >>> pprint(sol, wrap_line=False) / / __________________ \\ \| __________________ \| / 2 \|\| \| / 2 \| \/ 4bd - (a + c) log(x)\|\| -\|a + c - \/ 4bd - (a + c) tan\|C1 + ----------------------------\|\| \ \ 2a // f(x) = ------------------------------------------------------------------------ 2bx >>> checkodesol(genform, sol, order=1)[0] True References ========== 1. http://www.maplesoft.com/support/help/Maple/view.aspx?path=odeadvisor/Riccati 2. http://eqworld.ipmnet.ru/en/solutions/ode/ode0106.pdf - http://eqworld.ipmnet.ru/en/solutions/ode/ode0123.pdf """ x = func.args[0] f = func.func r = match # a2diff(f(x),x) + b2f(x) + c2f(x)/x + d2/x2 a2, b2, c2, d2 = [r[r[s]] for s in 'a2 b2 c2 d2'.split()] C1 = get_numbered_constants(eq, num=1) mu = sqrt(4d2b2 - (a2 - c2)2) return Eq(f(x), (a2 - c2 - mutan(mu/(2a2)log(x) + C1))/(2b2x)) def ode_Liouville(eq, func, order, match): r""" Solves 2nd order Liouville differential equations. The general form of a Liouville ODE is .. math:: \frac{d^2 y}{dx^2} + g(y) \left(\! \frac{dy}{dx}\!\right)^2 + h(x) \frac{dy}{dx}\text{.} The general solution is: >>> from sympy import Function, dsolve, Eq, pprint, diff >>> from sympy.abc import x >>> f, g, h = map(Function, ['f', 'g', 'h']) >>> genform = Eq(diff(f(x),x,x) + g(f(x))diff(f(x),x)2 + ... h(x)diff(f(x),x), 0) >>> pprint(genform) 2 2 /d \ d d g(f(x))\|--(f(x))\| + h(x)--(f(x)) + ---(f(x)) = 0 \dx / dx 2 dx >>> pprint(dsolve(genform, f(x), hint='Liouville_Integral')) f(x) / / \| \| \| / \| / \| \| \| \| \| - \| h(x) dx \| \| g(y) dy \| \| \| \| \| / \| / C1 + C2* \| e dx + \| e dy = 0 \| \| / / Examples ======== >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(diff(f(x), x, x) + diff(f(x), x)*2/f(x) + ... diff(f(x), x)/x, f(x), hint='Liouville')) ________________ ________________ [f(x) = -\/ C1 + C2log(x) , f(x) = \/ C1 + C2log(x) ] References ========== - Goldstein and Braun, "Advanced Methods for the Solution of Differential Equations", pp. 98 - http://www.maplesoft.com/support/help/Maple/view.aspx?path=odeadvisor/Liouville # indirect doctest """ # Liouville ODE: # f(x).diff(x, 2) + g(f(x))(f(x).diff(x, 2))*2 + h(x)f(x).diff(x) # See Goldstein and Braun, "Advanced Methods for the Solution of # Differential Equations", pg. 98, as well as # http://www.maplesoft.com/support/help/view.aspx?path=odeadvisor/Liouville x = func.args[0] f = func.func r = match # f(x).diff(x, 2) + gf(x).diff(x)2 + hf(x).diff(x) y = r['y'] C1, C2 = get_numbered_constants(eq, num=2) int = Integral(exp(Integral(r['g'], y)), (y, None, f(x))) sol = Eq(int + C1Integral(exp(-Integral(r['h'], x)), x) + C2, 0) return sol def ode_2nd_power_series_ordinary(eq, func, order, match): r""" Gives a power series solution to a second order homogeneous differential equation with polynomial coefficients at an ordinary point. A homogenous differential equation is of the form .. math :: P(x)\frac{d^2y}{dx^2} + Q(x)\frac{dy}{dx} + R(x) = 0 For simplicity it is assumed that `P(x)`, `Q(x)` and `R(x)` are polynomials, it is sufficient that `\frac{Q(x)}{P(x)}` and `\frac{R(x)}{P(x)}` exists at `x_{0}`. A recurrence relation is obtained by substituting `y` as `\sum_{n=0}^\infty a_{n}x^{n}`, in the differential equation, and equating the nth term. Using this relation various terms can be generated. Examples ======== >>> from sympy import dsolve, Function, pprint >>> from sympy.abc import x, y >>> f = Function("f") >>> eq = f(x).diff(x, 2) + f(x) >>> pprint(dsolve(eq, hint='2nd_power_series_ordinary')) / 4 2 \ / 2\ \|x x \| \| x \| / 6\ f(x) = C2\|-- - -- + 1\| + C1x\|1 - --\| + O\x / \24 2 / \ 6 / References ========== - http://tutorial.math.lamar.edu/Classes/DE/SeriesSolutions.aspx - George E. Simmons, "Differential Equations with Applications and Historical Notes", p.p 176 - 184 """ x = func.args[0] f = func.func C0, C1 = get_numbered_constants(eq, num=2) n = Dummy("n", integer=True) s = Wild("s") k = Wild("k", exclude=[x]) x0 = match.get('x0') terms = match.get('terms', 5) p = match[match['a3']] q = match[match['b3']] r = match[match['c3']] seriesdict = {} recurr = Function("r") # Generating the recurrence relation which works this way: # for the second order term the summation begins at n = 2. The coefficients # p is multiplied with an(n - 1)(n - 2)xn-2 and a substitution is made such that # the exponent of x becomes n. # For example, if p is x, then the second degree recurrence term is # an(n - 1)(n - 2)x*n-1, substituting (n - 1) as n, it transforms to # an+1n(n - 1)x*n. # A similar process is done with the first order and zeroth order term. coefflist = [(recurr(n), r), (nrecurr(n), q), (n(n - 1)recurr(n), p)] for index, coeff in enumerate(coefflist): if coeff[1]: f2 = powsimp(expand((coeff[1](x - x0)(n - index)).subs(x, x + x0))) if f2.is_Add: addargs = f2.args else: addargs = [f2] for arg in addargs: powm = arg.match(sx*k) term = coeff[0]powm[s] if not powm[k].is_Symbol: term = term.subs(n, n - powm[k].as_independent(n)[0]) startind = powm[k].subs(n, index) # Seeing if the startterm can be reduced further. # If it vanishes for n lesser than startind, it is # equal to summation from n. if startind: for i in reversed(range(startind)): if not term.subs(n, i): seriesdict[term] = i else: seriesdict[term] = i + 1 break else: seriesdict[term] = S(0) # Stripping of terms so that the sum starts with the same number. teq = S(0) suminit = seriesdict.values() rkeys = seriesdict.keys() req = Add(rkeys) if any(suminit): maxval = max(suminit) for term in seriesdict: val = seriesdict[term] if val != maxval: for i in range(val, maxval): teq += term.subs(n, val) finaldict = {} if teq: fargs = teq.atoms(AppliedUndef) if len(fargs) == 1: finaldict[fargs.pop()] = 0 else: maxf = max(fargs, key = lambda x: x.args[0]) sol = solve(teq, maxf) if isinstance(sol, list): sol = sol[0] finaldict[maxf] = sol # Finding the recurrence relation in terms of the largest term. fargs = req.atoms(AppliedUndef) maxf = max(fargs, key = lambda x: x.args[0]) minf = min(fargs, key = lambda x: x.args[0]) if minf.args[0].is_Symbol: startiter = 0 else: startiter = -minf.args[0].as_independent(n)[0] lhs = maxf rhs = solve(req, maxf) if isinstance(rhs, list): rhs = rhs[0] # Checking how many values are already present tcounter = len([t for t in finaldict.values() if t]) for _ in range(tcounter, terms - 3): # Assuming c0 and c1 to be arbitrary check = rhs.subs(n, startiter) nlhs = lhs.subs(n, startiter) nrhs = check.subs(finaldict) finaldict[nlhs] = nrhs startiter += 1 # Post processing series = C0 + C1(x - x0) for term in finaldict: if finaldict[term]: fact = term.args[0] series += (finaldict[term].subs([(recurr(0), C0), (recurr(1), C1)])( x - x0)fact) series = collect(expand_mul(series), [C0, C1]) + Order(xterms) return Eq(f(x), series) def ode_2nd_power_series_regular(eq, func, order, match): r""" Gives a power series solution to a second order homogeneous differential equation with polynomial coefficients at a regular point. A second order homogenous differential equation is of the form .. math :: P(x)\frac{d^2y}{dx^2} + Q(x)\frac{dy}{dx} + R(x) = 0 A point is said to regular singular at `x0` if `x - x0\frac{Q(x)}{P(x)}` and `(x - x0)^{2}\frac{R(x)}{P(x)}` are analytic at `x0`. For simplicity `P(x)`, `Q(x)` and `R(x)` are assumed to be polynomials. The algorithm for finding the power series solutions is: 1. Try expressing `(x - x0)P(x)` and `((x - x0)^{2})Q(x)` as power series solutions about x0. Find `p0` and `q0` which are the constants of the power series expansions. 2. Solve the indicial equation `f(m) = m(m - 1) + mp0 + q0`, to obtain the roots `m1` and `m2` of the indicial equation. 3. If `m1 - m2` is a non integer there exists two series solutions. If `m1 = m2`, there exists only one solution. If `m1 - m2` is an integer, then the existence of one solution is confirmed. The other solution may or may not exist. The power series solution is of the form `x^{m}\sum_{n=0}^\infty a_{n}x^{n}`. The coefficients are determined by the following recurrence relation. `a_{n} = -\frac{\sum_{k=0}^{n-1} q_{n-k} + (m + k)p_{n-k}}{f(m + n)}`. For the case in which `m1 - m2` is an integer, it can be seen from the recurrence relation that for the lower root `m`, when `n` equals the difference of both the roots, the denominator becomes zero. So if the numerator is not equal to zero, a second series solution exists. Examples ======== >>> from sympy import dsolve, Function, pprint >>> from sympy.abc import x, y >>> f = Function("f") >>> eq = x(f(x).diff(x, 2)) + 2(f(x).diff(x)) + xf(x) >>> pprint(dsolve(eq)) / 6 4 2 \ \| x x x \| / 4 2 \ C1\|- --- + -- - -- + 1\| \| x x \| \ 720 24 2 / / 6\ f(x) = C2\|--- - -- + 1\| + ------------------------ + O\x / \120 6 / x References ========== - George E. Simmons, "Differential Equations with Applications and Historical Notes", p.p 176 - 184 """ x = func.args[0] f = func.func C0, C1 = get_numbered_constants(eq, num=2) m = Dummy("m") # for solving the indicial equation x0 = match.get('x0') terms = match.get('terms', 5) p = match['p'] q = match['q'] # Generating the indicial equation indicial = [] for term in [p, q]: if not term.has(x): indicial.append(term) else: term = series(term, n=1, x0=x0) if isinstance(term, Order): indicial.append(S(0)) else: for arg in term.args: if not arg.has(x): indicial.append(arg) break p0, q0 = indicial sollist = solve(m(m - 1) + mp0 + q0, m) if sollist and isinstance(sollist, list) and all( [sol.is_real for sol in sollist]): serdict1 = {} serdict2 = {} if len(sollist) == 1: # Only one series solution exists in this case. m1 = m2 = sollist.pop() if terms-m1-1 <= 0: return Eq(f(x), Order(terms)) serdict1 = _frobenius(terms-m1-1, m1, p0, q0, p, q, x0, x, C0) else: m1 = sollist[0] m2 = sollist[1] if m1 < m2: m1, m2 = m2, m1 # Irrespective of whether m1 - m2 is an integer or not, one # Frobenius series solution exists. serdict1 = _frobenius(terms-m1-1, m1, p0, q0, p, q, x0, x, C0) if not (m1 - m2).is_integer: # Second frobenius series solution exists. serdict2 = _frobenius(terms-m2-1, m2, p0, q0, p, q, x0, x, C1) else: # Check if second frobenius series solution exists. serdict2 = _frobenius(terms-m2-1, m2, p0, q0, p, q, x0, x, C1, check=m1) if serdict1: finalseries1 = C0 for key in serdict1: power = int(key.name[1:]) finalseries1 += serdict1[key](x - x0)power finalseries1 = (x - x0)m1finalseries1 finalseries2 = S(0) if serdict2: for key in serdict2: power = int(key.name[1:]) finalseries2 += serdict2[key](x - x0)power finalseries2 += C1 finalseries2 = (x - x0)m2finalseries2 return Eq(f(x), collect(finalseries1 + finalseries2, [C0, C1]) + Order(xterms)) def _frobenius(n, m, p0, q0, p, q, x0, x, c, check=None): r""" Returns a dict with keys as coefficients and values as their values in terms of C0 """ n = int(n) # In cases where m1 - m2 is not an integer m2 = check d = Dummy("d") numsyms = numbered_symbols("C", start=0) numsyms = [next(numsyms) for i in range(n + 1)] serlist = [] for ser in [p, q]: # Order term not present if ser.is_polynomial(x) and Poly(ser, x).degree() <= n: if x0: ser = ser.subs(x, x + x0) dict_ = Poly(ser, x).as_dict() # Order term present else: tseries = series(ser, x=x0, n=n+1) # Removing order dict_ = Poly(list(ordered(tseries.args))[: -1], x).as_dict() # Fill in with zeros, if coefficients are zero. for i in range(n + 1): if (i,) not in dict_: dict_[(i,)] = S(0) serlist.append(dict_) pseries = serlist[0] qseries = serlist[1] indicial = d(d - 1) + dp0 + q0 frobdict = {} for i in range(1, n + 1): num = c(mpseries[(i,)] + qseries[(i,)]) for j in range(1, i): sym = Symbol("C" + str(j)) num += frobdict[sym]((m + j)pseries[(i - j,)] + qseries[(i - j,)]) # Checking for cases when m1 - m2 is an integer. If num equals zero # then a second Frobenius series solution cannot be found. If num is not zero # then set constant as zero and proceed. if m2 is not None and i == m2 - m: if num: return False else: frobdict[numsyms[i]] = S(0) else: frobdict[numsyms[i]] = -num/(indicial.subs(d, m+i)) return frobdict def _nth_order_reducible_match(eq, func): r""" Matches any differential equation that can be rewritten with a smaller order. Only derivatives of ``func`` alone, wrt a single variable, are considered, and only in them should ``func`` appear. """ # ODE only handles functions of 1 variable so this affirms that state assert len(func.args) == 1 x = func.args[0] vc = [d.variable_count[0] for d in eq.atoms(Derivative) if d.expr == func and len(d.variable_count) == 1] ords = [c for v, c in vc if v == x] if len(ords) < 2: return smallest = min(ords) # make sure func does not appear outside of derivatives D = Dummy() if eq.subs(func.diff(x, smallest), D).has(func): return return {'n': smallest} def ode_nth_order_reducible(eq, func, order, match): r""" Solves ODEs that only involve derivatives of the dependent variable using a substitution of the form `f^n(x) = g(x)`. For example any second order ODE of the form `f''(x) = h(f'(x), x)` can be transformed into a pair of 1st order ODEs `g'(x) = h(g(x), x)` and `f'(x) = g(x)`. Usually the 1st order ODE for `g` is easier to solve. If that gives an explicit solution for `g` then `f` is found simply by integration. Examples ======== >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> eq = Eq(xf(x).diff(x)*2 + f(x).diff(x, 2)) >>> dsolve(eq, f(x), hint='nth_order_reducible') ... # doctest: +NORMALIZE_WHITESPACE Eq(f(x), C1 - sqrt(-1/C2)log(-C2sqrt(-1/C2) + x) + sqrt(-1/C2)log(C2sqrt(-1/C2) + x)) """ x = func.args[0] f = func.func n = match['n'] # get a unique function name for g names = [a.name for a in eq.atoms(AppliedUndef)] while True: name = Dummy().name if name not in names: g = Function(name) break w = f(x).diff(x, n) geq = eq.subs(w, g(x)) gsol = dsolve(geq, g(x)) if not isinstance(gsol, list): gsol = [gsol] # Might be multiple solutions to the reduced ODE: fsol = [] for gsoli in gsol: fsoli = dsolve(gsoli.subs(g(x), w), f(x)) # or do integration n times fsol.append(fsoli) if len(fsol) == 1: fsol = fsol[0] return fsol def _nth_algebraic_match(eq, func): r""" Matches any differential equation that nth_algebraic can solve. Uses `sympy.solve` but teaches it how to integrate derivatives. This involves calling `sympy.solve` and does most of the work of finding a solution (apart from evaluating the integrals). """ # Each integration should generate a different constant constants = iter_numbered_constants(eq) constant = lambda: next(constants, None) # Like Derivative but "invertible" class diffx(Function): def inverse(self): # We mustn't use integrate here because fx has been replaced by _t # in the equation so integrals will not be correct while solve is # still working. return lambda expr: Integral(expr, var) + constant() # Replace derivatives wrt the independent variable with diffx def replace(eq, var): def expand_diffx(args): differand, diffs = args[0], args[1:] toreplace = differand for v, n in diffs: for _ in range(n): if v == var: toreplace = diffx(toreplace) else: toreplace = Derivative(toreplace, v) return toreplace return eq.replace(Derivative, expand_diffx) # Restore derivatives in solution afterwards def unreplace(eq, var): return eq.replace(diffx, lambda e: Derivative(e, var)) # The independent variable var = func.args[0] subs_eqn = replace(eq, var) try: # turn off simplification to protect Integrals that have # _t instead of fx in them and would otherwise factor # as t_Integral(1, x) solns = solve(subs_eqn, func, simplify=False) except NotImplementedError: solns = [] solns = [simplify(unreplace(soln, var)) for soln in solns] solns = [Equality(func, soln) for soln in solns] return {'var':var, 'solutions':solns} def ode_nth_algebraic(eq, func, order, match): r""" Solves an `n`\th order ordinary differential equation using algebra and integrals. There is no general form for the kind of equation that this can solve. The the equation is solved algebraically treating differentiation as an invertible algebraic function. Examples ======== >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> eq = Eq(f(x) (f(x).diff(x)*2 - 1), 0) >>> dsolve(eq, f(x), hint='nth_algebraic') ... # doctest: +NORMALIZE_WHITESPACE [Eq(f(x), 0), Eq(f(x), C1 - x), Eq(f(x), C1 + x)] Note that this solver can return algebraic solutions that do not have any integration constants (f(x) = 0 in the above example). # indirect doctest """ solns = match['solutions'] var = match['var'] solns = _nth_algebraic_remove_redundant_solutions(eq, solns, order, var) if len(solns) == 1: return solns[0] else: return solns # FIXME: Maybe something like this function should be applied to the solutions # returned by dsolve in general rather than just for nth_algebraic... def _nth_algebraic_remove_redundant_solutions(eq, solns, order, var): r""" Remove redundant solutions from the set of solutions returned by nth_algebraic. This function is needed because otherwise nth_algebraic can return redundant solutions where both algebraic solutions and integral solutions are found to the ODE. As an example consider: eq = Eq(f(x) f(x).diff(x), 0) There are two ways to find solutions to eq. The first is the algebraic solution f(x)=0. The second is to solve the equation f(x).diff(x) = 0 leading to the solution f(x) = C1. In this particular case we then see that the first solution is a special case of the second and we don't want to return it. This does not always happen for algebraic solutions though since if we have eq = Eq(f(x)(1 + f(x).diff(x)), 0) then we get the algebraic solution f(x) = 0 and the integral solution f(x) = -x + C1 and in this case the two solutions are not equivalent wrt initial conditions so both should be returned. """ def is_special_case_of(soln1, soln2): return _nth_algebraic_is_special_case_of(soln1, soln2, eq, order, var) unique_solns = [] for soln1 in solns: for soln2 in unique_solns[:]: if is_special_case_of(soln1, soln2): break elif is_special_case_of(soln2, soln1): unique_solns.remove(soln2) else: unique_solns.append(soln1) return unique_solns def _nth_algebraic_is_special_case_of(soln1, soln2, eq, order, var): r""" True if soln1 is found to be a special case of soln2 wrt some value of the constants that appear in soln2. False otherwise. """ # The solutions returned by nth_algebraic should be given explicitly as in # Eq(f(x), expr). We will equate the RHSs of the two solutions giving an # equation f1(x) = f2(x). # # Since this is supposed to hold for all x it also holds for derivatives # f1'(x) and f2'(x). For an order n ode we should be able to differentiate # each solution n times to get n+1 equations. # # We then try to solve those n+1 equations for the integrations constants # in f2(x). If we can find a solution that doesn't depend on x then it # means that some value of the constants in f1(x) is a special case of # f2(x) corresponding to a paritcular choice of the integration constants. constants1 = soln1.free_symbols.difference(eq.free_symbols) constants2 = soln2.free_symbols.difference(eq.free_symbols) constants1_new = get_numbered_constants(soln1.rhs - soln2.rhs, len(constants1)) if len(constants1) == 1: constants1_new = {constants1_new} for c_old, c_new in zip(constants1, constants1_new): soln1 = soln1.subs(c_old, c_new) # n equations for f1(x)=f2(x), f1'(x)=f2'(x), ... lhs = soln1.rhs.doit() rhs = soln2.rhs.doit() eqns = [Eq(lhs, rhs)] for n in range(1, order): lhs = lhs.diff(var) rhs = rhs.diff(var) eq = Eq(lhs, rhs) eqns.append(eq) # BooleanTrue/False awkwardly show up for trivial equations if any(isinstance(eq, BooleanFalse) for eq in eqns): return False eqns = [eq for eq in eqns if not isinstance(eq, BooleanTrue)] constant_solns = solve(eqns, constants2) # Sometimes returns a dict and sometimes a list of dicts if isinstance(constant_solns, dict): constant_solns = [constant_solns] # If any solution gives all constants as expressions that don't depend on # x then there exists constants for soln2 that give soln1 for constant_soln in constant_solns: if not any(c.has(var) for c in constant_soln.values()): return True return False def _nth_linear_match(eq, func, order): r""" Matches a differential equation to the linear form: .. math:: a_n(x) y^{(n)} + \cdots + a_1(x)y' + a_0(x) y + B(x) = 0 Returns a dict of order:coeff terms, where order is the order of the derivative on each term, and coeff is the coefficient of that derivative. The key ``-1`` holds the function `B(x)`. Returns ``None`` if the ODE is not linear. This function assumes that ``func`` has already been checked to be good. Examples ======== >>> from sympy import Function, cos, sin >>> from sympy.abc import x >>> from sympy.solvers.ode import _nth_linear_match >>> f = Function('f') >>> _nth_linear_match(f(x).diff(x, 3) + 2f(x).diff(x) + ... xf(x).diff(x, 2) + cos(x)f(x).diff(x) + x - f(x) - ... sin(x), f(x), 3) {-1: x - sin(x), 0: -1, 1: cos(x) + 2, 2: x, 3: 1} >>> _nth_linear_match(f(x).diff(x, 3) + 2f(x).diff(x) + ... xf(x).diff(x, 2) + cos(x)f(x).diff(x) + x - f(x) - ... sin(f(x)), f(x), 3) == None True """ x = func.args[0] one_x = {x} terms = {i: S.Zero for i in range(-1, order + 1)} for i in Add.make_args(eq): if not i.has(func): terms[-1] += i else: c, f = i.as_independent(func) if (isinstance(f, Derivative) and set(f.variables) == one_x and f.args[0] == func): terms[f.derivative_count] += c elif f == func: terms[len(f.args[1:])] += c else: return None return terms def ode_nth_linear_euler_eq_homogeneous(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear homogeneous variable-coefficient Cauchy-Euler equidimensional ordinary differential equation. This is an equation with form `0 = a_0 f(x) + a_1 x f'(x) + a_2 x^2 f''(x) \cdots`. These equations can be solved in a general manner, by substituting solutions of the form `f(x) = x^r`, and deriving a characteristic equation for `r`. When there are repeated roots, we include extra terms of the form `C_{r k} \ln^k(x) x^r`, where `C_{r k}` is an arbitrary integration constant, `r` is a root of the characteristic equation, and `k` ranges over the multiplicity of `r`. In the cases where the roots are complex, solutions of the form `C_1 x^a \sin(b \log(x)) + C_2 x^a \cos(b \log(x))` are returned, based on expansions with Euler's formula. The general solution is the sum of the terms found. If SymPy cannot find exact roots to the characteristic equation, a :py:class:`~sympy.polys.rootoftools.CRootOf` instance will be returned instead. >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(4x*2f(x).diff(x, 2) + f(x), f(x), ... hint='nth_linear_euler_eq_homogeneous') ... # doctest: +NORMALIZE_WHITESPACE Eq(f(x), sqrt(x)(C1 + C2log(x))) Note that because this method does not involve integration, there is no ``nth_linear_euler_eq_homogeneous_Integral`` hint. The following is for internal use: - ``returns = 'sol'`` returns the solution to the ODE. - ``returns = 'list'`` returns a list of linearly independent solutions, corresponding to the fundamental solution set, for use with non homogeneous solution methods like variation of parameters and undetermined coefficients. Note that, though the solutions should be linearly independent, this function does not explicitly check that. You can do ``assert simplify(wronskian(sollist)) != 0`` to check for linear independence. Also, ``assert len(sollist) == order`` will need to pass. - ``returns = 'both'``, return a dictionary ``{'sol': <solution to ODE>, 'list': <list of linearly independent solutions>}``. Examples ======== >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f = Function('f') >>> eq = f(x).diff(x, 2)x2 - 4f(x).diff(x)x + 6f(x) >>> pprint(dsolve(eq, f(x), ... hint='nth_linear_euler_eq_homogeneous')) 2 f(x) = x (C1 + C2x) References ========== - https://en.wikipedia.org/wiki/Cauchy%E2%80%93Euler_equation - C. Bender & S. Orszag, "Advanced Mathematical Methods for Scientists and Engineers", Springer 1999, pp. 12 # indirect doctest """ global collectterms collectterms = [] x = func.args[0] f = func.func r = match # First, set up characteristic equation. chareq, symbol = S.Zero, Dummy('x') for i in r.keys(): if not isinstance(i, string_types) and i >= 0: chareq += (r[i]diff(xsymbol, x, i)x*-symbol).expand() chareq = Poly(chareq, symbol) chareqroots = [rootof(chareq, k) for k in range(chareq.degree())] # A generator of constants constants = list(get_numbered_constants(eq, num=chareq.degree()2)) constants.reverse() # Create a dict root: multiplicity or charroots charroots = defaultdict(int) for root in chareqroots: charroots[root] += 1 gsol = S(0) # We need keep track of terms so we can run collect() at the end. # This is necessary for constantsimp to work properly. ln = log for root, multiplicity in charroots.items(): for i in range(multiplicity): if isinstance(root, RootOf): gsol += (x*root) constants.pop() if multiplicity != 1: raise ValueError("Value should be 1") collectterms = [(0, root, 0)] + collectterms elif root.is_real: gsol += ln(x)*i(x*root) constants.pop() collectterms = [(i, root, 0)] + collectterms else: reroot = re(root) imroot = im(root) gsol += ln(x)*i (x*reroot) ( constants.pop() * sin(abs(imroot)ln(x)) + constants.pop() cos(imrootln(x))) # Preserve ordering (multiplicity, real part, imaginary part) # It will be assumed implicitly when constructing # fundamental solution sets. collectterms = [(i, reroot, imroot)] + collectterms if returns == 'sol': return Eq(f(x), gsol) elif returns in ('list' 'both'): # HOW TO TEST THIS CODE? (dsolve does not pass 'returns' through) # Create a list of (hopefully) linearly independent solutions gensols = [] # Keep track of when to use sin or cos for nonzero imroot for i, reroot, imroot in collectterms: if imroot == 0: gensols.append(ln(x)ixreroot) else: sin_form = ln(x)ixrerootsin(abs(imroot)ln(x)) if sin_form in gensols: cos_form = ln(x)ix*rerootcos(imrootln(x)) gensols.append(cos_form) else: gensols.append(sin_form) if returns == 'list': return gensols else: return {'sol': Eq(f(x), gsol), 'list': gensols} else: raise ValueError('Unknown value for key "returns".') def ode_nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear non homogeneous Cauchy-Euler equidimensional ordinary differential equation using undetermined coefficients. This is an equation with form `g(x) = a_0 f(x) + a_1 x f'(x) + a_2 x^2 f''(x) \cdots`. These equations can be solved in a general manner, by substituting solutions of the form `x = exp(t)`, and deriving a characteristic equation of form `g(exp(t)) = b_0 f(t) + b_1 f'(t) + b_2 f''(t) \cdots` which can be then solved by nth_linear_constant_coeff_undetermined_coefficients if g(exp(t)) has finite number of linearly independent derivatives. Functions that fit this requirement are finite sums functions of the form `a x^i e^{b x} \sin(c x + d)` or `a x^i e^{b x} \cos(c x + d)`, where `i` is a non-negative integer and `a`, `b`, `c`, and `d` are constants. For example any polynomial in `x`, functions like `x^2 e^{2 x}`, `x \sin(x)`, and `e^x \cos(x)` can all be used. Products of `\sin`'s and `\cos`'s have a finite number of derivatives, because they can be expanded into `\sin(a x)` and `\cos(b x)` terms. However, SymPy currently cannot do that expansion, so you will need to manually rewrite the expression in terms of the above to use this method. So, for example, you will need to manually convert `\sin^2(x)` into `(1 + \cos(2 x))/2` to properly apply the method of undetermined coefficients on it. After replacement of x by exp(t), this method works by creating a trial function from the expression and all of its linear independent derivatives and substituting them into the original ODE. The coefficients for each term will be a system of linear equations, which are be solved for and substituted, giving the solution. If any of the trial functions are linearly dependent on the solution to the homogeneous equation, they are multiplied by sufficient `x` to make them linearly independent. Examples ======== >>> from sympy import dsolve, Function, Derivative, log >>> from sympy.abc import x >>> f = Function('f') >>> eq = x2Derivative(f(x), x, x) - 2xDerivative(f(x), x) + 2f(x) - log(x) >>> dsolve(eq, f(x), ... hint='nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients').expand() Eq(f(x), C1x + C2x2 + log(x)/2 + 3/4) """ x = func.args[0] f = func.func r = match chareq, eq, symbol = S.Zero, S.Zero, Dummy('x') for i in r.keys(): if not isinstance(i, string_types) and i >= 0: chareq += (r[i]diff(x*symbol, x, i)x-symbol).expand() for i in range(1,degree(Poly(chareq, symbol))+1): eq += chareq.coeff(symboli)diff(f(x), x, i) if chareq.as_coeff_add(symbol)[0]: eq += chareq.as_coeff_add(symbol)[0]f(x) e, re = posify(r[-1].subs(x, exp(x))) eq += e.subs(re) match = _nth_linear_match(eq, f(x), ode_order(eq, f(x))) match['trialset'] = r['trialset'] return ode_nth_linear_constant_coeff_undetermined_coefficients(eq, func, order, match).subs(x, log(x)).subs(f(log(x)), f(x)).expand() def ode_nth_linear_euler_eq_nonhomogeneous_variation_of_parameters(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear non homogeneous Cauchy-Euler equidimensional ordinary differential equation using variation of parameters. This is an equation with form `g(x) = a_0 f(x) + a_1 x f'(x) + a_2 x^2 f''(x) \cdots`. This method works by assuming that the particular solution takes the form .. math:: \sum_{x=1}^{n} c_i(x) y_i(x) {a_n} {x^n} \text{,} where `y_i` is the `i`\th solution to the homogeneous equation. The solution is then solved using Wronskian's and Cramer's Rule. The particular solution is given by multiplying eq given below with `a_n x^{n}` .. math:: \sum_{x=1}^n \left( \int \frac{W_i(x)}{W(x)} \,dx \right) y_i(x) \text{,} where `W(x)` is the Wronskian of the fundamental system (the system of `n` linearly independent solutions to the homogeneous equation), and `W_i(x)` is the Wronskian of the fundamental system with the `i`\th column replaced with `[0, 0, \cdots, 0, \frac{x^{- n}}{a_n} g{\left(x \right)}]`. This method is general enough to solve any `n`\th order inhomogeneous linear differential equation, but sometimes SymPy cannot simplify the Wronskian well enough to integrate it. If this method hangs, try using the ``nth_linear_constant_coeff_variation_of_parameters_Integral`` hint and simplifying the integrals manually. Also, prefer using ``nth_linear_constant_coeff_undetermined_coefficients`` when it applies, because it doesn't use integration, making it faster and more reliable. Warning, using simplify=False with 'nth_linear_constant_coeff_variation_of_parameters' in :py:meth:`~sympy.solvers.ode.dsolve` may cause it to hang, because it will not attempt to simplify the Wronskian before integrating. It is recommended that you only use simplify=False with 'nth_linear_constant_coeff_variation_of_parameters_Integral' for this method, especially if the solution to the homogeneous equation has trigonometric functions in it. Examples ======== >>> from sympy import Function, dsolve, Derivative >>> from sympy.abc import x >>> f = Function('f') >>> eq = x*2Derivative(f(x), x, x) - 2xDerivative(f(x), x) + 2f(x) - x4 >>> dsolve(eq, f(x), ... hint='nth_linear_euler_eq_nonhomogeneous_variation_of_parameters').expand() Eq(f(x), C1x + C2x2 + x4/6) """ x = func.args[0] f = func.func r = match gensol = ode_nth_linear_euler_eq_homogeneous(eq, func, order, match, returns='both') match.update(gensol) r[-1] = r[-1]/r[ode_order(eq, f(x))] sol = _solve_variation_of_parameters(eq, func, order, match) return Eq(f(x), r['sol'].rhs + (sol.rhs - r['sol'].rhs)r[ode_order(eq, f(x))]) def ode_almost_linear(eq, func, order, match): r""" Solves an almost-linear differential equation. The general form of an almost linear differential equation is .. math:: f(x) g(y) y + k(x) l(y) + m(x) = 0 \text{where} l'(y) = g(y)\text{.} This can be solved by substituting `l(y) = u(y)`. Making the given substitution reduces it to a linear differential equation of the form `u' + P(x) u + Q(x) = 0`. The general solution is >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x, y, n >>> f, g, k, l = map(Function, ['f', 'g', 'k', 'l']) >>> genform = Eq(f(x)(l(y).diff(y)) + k(x)l(y) + g(x), 0) >>> pprint(genform) d f(x)--(l(y)) + g(x) + k(x)l(y) = 0 dy >>> pprint(dsolve(genform, hint = 'almost_linear')) / // yk(x) \\ \| \|\| ------ \|\| \| \|\| f(x) \|\| -yk(x) \| \|\|-g(x)e \|\| -------- \| \|\|-------------- for k(x) != 0\|\| f(x) l(y) = \|C1 + \|< k(x) \|\|e \| \|\| \|\| \| \|\| -yg(x) \|\| \| \|\| -------- otherwise \|\| \| \|\| f(x) \|\| \ \\ // See Also ======== :meth:`sympy.solvers.ode.ode_1st_linear` Examples ======== >>> from sympy import Function, Derivative, pprint >>> from sympy.solvers.ode import dsolve, classify_ode >>> from sympy.abc import x >>> f = Function('f') >>> d = f(x).diff(x) >>> eq = xd + xf(x) + 1 >>> dsolve(eq, f(x), hint='almost_linear') Eq(f(x), (C1 - Ei(x))exp(-x)) >>> pprint(dsolve(eq, f(x), hint='almost_linear')) -x f(x) = (C1 - Ei(x))e References ========== - Joel Moses, "Symbolic Integration - The Stormy Decade", Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 """ # Since ode_1st_linear has already been implemented, and the # coefficients have been modified to the required form in # classify_ode, just passing eq, func, order and match to # ode_1st_linear will give the required output. return ode_1st_linear(eq, func, order, match) def _linear_coeff_match(expr, func): r""" Helper function to match hint ``linear_coefficients``. Matches the expression to the form `(a_1 x + b_1 f(x) + c_1)/(a_2 x + b_2 f(x) + c_2)` where the following conditions hold: 1. `a_1`, `b_1`, `c_1`, `a_2`, `b_2`, `c_2` are Rationals; 2. `c_1` or `c_2` are not equal to zero; 3. `a_2 b_1 - a_1 b_2` is not equal to zero. Return ``xarg``, ``yarg`` where 1. ``xarg`` = `(b_2 c_1 - b_1 c_2)/(a_2 b_1 - a_1 b_2)` 2. ``yarg`` = `(a_1 c_2 - a_2 c_1)/(a_2 b_1 - a_1 b_2)` Examples ======== >>> from sympy import Function >>> from sympy.abc import x >>> from sympy.solvers.ode import _linear_coeff_match >>> from sympy.functions.elementary.trigonometric import sin >>> f = Function('f') >>> _linear_coeff_match(( ... (-25f(x) - 8x + 62)/(4f(x) + 11x - 11)), f(x)) (1/9, 22/9) >>> _linear_coeff_match( ... sin((-5f(x) - 8x + 6)/(4f(x) + x - 1)), f(x)) (19/27, 2/27) >>> _linear_coeff_match(sin(f(x)/x), f(x)) """ f = func.func x = func.args[0] def abc(eq): r''' Internal function of _linear_coeff_match that returns Rationals a, b, c if eq is ax + bf(x) + c, else None. ''' eq = _mexpand(eq) c = eq.as_independent(x, f(x), as_Add=True)[0] if not c.is_Rational: return a = eq.coeff(x) if not a.is_Rational: return b = eq.coeff(f(x)) if not b.is_Rational: return if eq == ax + bf(x) + c: return a, b, c def match(arg): r''' Internal function of _linear_coeff_match that returns Rationals a1, b1, c1, a2, b2, c2 and a2b1 - a1b2 of the expression (a1x + b1f(x) + c1)/(a2x + b2f(x) + c2) if one of c1 or c2 and a2b1 - a1b2 is non-zero, else None. ''' n, d = arg.together().as_numer_denom() m = abc(n) if m is not None: a1, b1, c1 = m m = abc(d) if m is not None: a2, b2, c2 = m d = a2b1 - a1b2 if (c1 or c2) and d: return a1, b1, c1, a2, b2, c2, d m = [fi.args[0] for fi in expr.atoms(Function) if fi.func != f and len(fi.args) == 1 and not fi.args[0].is_Function] or {expr} m1 = match(m.pop()) if m1 and all(match(mi) == m1 for mi in m): a1, b1, c1, a2, b2, c2, denom = m1 return (b2c1 - b1c2)/denom, (a1c2 - a2c1)/denom def ode_linear_coefficients(eq, func, order, match): r""" Solves a differential equation with linear coefficients. The general form of a differential equation with linear coefficients is .. math:: y' + F\left(\!\frac{a_1 x + b_1 y + c_1}{a_2 x + b_2 y + c_2}\!\right) = 0\text{,} where `a_1`, `b_1`, `c_1`, `a_2`, `b_2`, `c_2` are constants and `a_1 b_2 - a_2 b_1 \ne 0`. This can be solved by substituting: .. math:: x = x' + \frac{b_2 c_1 - b_1 c_2}{a_2 b_1 - a_1 b_2} y = y' + \frac{a_1 c_2 - a_2 c_1}{a_2 b_1 - a_1 b_2}\text{.} This substitution reduces the equation to a homogeneous differential equation. See Also ======== :meth:`sympy.solvers.ode.ode_1st_homogeneous_coeff_best` :meth:`sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep` :meth:`sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep` Examples ======== >>> from sympy import Function, Derivative, pprint >>> from sympy.solvers.ode import dsolve, classify_ode >>> from sympy.abc import x >>> f = Function('f') >>> df = f(x).diff(x) >>> eq = (x + f(x) + 1)df + (f(x) - 6x + 1) >>> dsolve(eq, hint='linear_coefficients') [Eq(f(x), -x - sqrt(C1 + 7x2) - 1), Eq(f(x), -x + sqrt(C1 + 7x*2) - 1)] >>> pprint(dsolve(eq, hint='linear_coefficients')) ___________ ___________ / 2 / 2 [f(x) = -x - \/ C1 + 7x - 1, f(x) = -x + \/ C1 + 7x - 1] References ========== - Joel Moses, "Symbolic Integration - The Stormy Decade", Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 """ return ode_1st_homogeneous_coeff_best(eq, func, order, match) def ode_separable_reduced(eq, func, order, match): r""" Solves a differential equation that can be reduced to the separable form. The general form of this equation is .. math:: y' + (y/x) H(x^n y) = 0\text{}. This can be solved by substituting `u(y) = x^n y`. The equation then reduces to the separable form `\frac{u'}{u (\mathrm{power} - H(u))} - \frac{1}{x} = 0`. The general solution is: >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x, n >>> f, g = map(Function, ['f', 'g']) >>> genform = f(x).diff(x) + (f(x)/x)g(x*nf(x)) >>> pprint(genform) / n \ d f(x)g\x f(x)/ --(f(x)) + --------------- dx x >>> pprint(dsolve(genform, hint='separable_reduced')) n x f(x) / \| \| 1 \| ------------ dy = C1 + log(x) \| y(n - g(y)) \| / See Also ======== :meth:`sympy.solvers.ode.ode_separable` Examples ======== >>> from sympy import Function, Derivative, pprint >>> from sympy.solvers.ode import dsolve, classify_ode >>> from sympy.abc import x >>> f = Function('f') >>> d = f(x).diff(x) >>> eq = (x - x*2f(x))d - f(x) >>> dsolve(eq, hint='separable_reduced') [Eq(f(x), (1 - sqrt(C1x*2 + 1))/x), Eq(f(x), (sqrt(C1x*2 + 1) + 1)/x)] >>> pprint(dsolve(eq, hint='separable_reduced')) ___________ ___________ / 2 / 2 1 - \/ C1x + 1 \/ C1x + 1 + 1 [f(x) = ------------------, f(x) = ------------------] x x References ========== - Joel Moses, "Symbolic Integration - The Stormy Decade", Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 """ # Arguments are passed in a way so that they are coherent with the # ode_separable function x = func.args[0] f = func.func y = Dummy('y') u = match['u'].subs(match['t'], y) ycoeff = 1/(y(match['power'] - u)) m1 = {y: 1, x: -1/x, 'coeff': 1} m2 = {y: ycoeff, x: 1, 'coeff': 1} r = {'m1': m1, 'm2': m2, 'y': y, 'hint': x*match['power']f(x)} return ode_separable(eq, func, order, r) def ode_1st_power_series(eq, func, order, match): r""" The power series solution is a method which gives the Taylor series expansion to the solution of a differential equation. For a first order differential equation `\frac{dy}{dx} = h(x, y)`, a power series solution exists at a point `x = x_{0}` if `h(x, y)` is analytic at `x_{0}`. The solution is given by .. math:: y(x) = y(x_{0}) + \sum_{n = 1}^{\infty} \frac{F_{n}(x_{0},b)(x - x_{0})^n}{n!}, where `y(x_{0}) = b` is the value of y at the initial value of `x_{0}`. To compute the values of the `F_{n}(x_{0},b)` the following algorithm is followed, until the required number of terms are generated. 1. `F_1 = h(x_{0}, b)` 2. `F_{n+1} = \frac{\partial F_{n}}{\partial x} + \frac{\partial F_{n}}{\partial y}F_{1}` Examples ======== >>> from sympy import Function, Derivative, pprint, exp >>> from sympy.solvers.ode import dsolve >>> from sympy.abc import x >>> f = Function('f') >>> eq = exp(x)(f(x).diff(x)) - f(x) >>> pprint(dsolve(eq, hint='1st_power_series')) 3 4 5 C1x C1x C1x / 6\ f(x) = C1 + C1x - ----- + ----- + ----- + O\x / 6 24 60 References ========== - Travis W. Walker, Analytic power series technique for solving first-order differential equations, p.p 17, 18 """ x = func.args[0] y = match['y'] f = func.func h = -match[match['d']]/match[match['e']] point = match.get('f0') value = match.get('f0val') terms = match.get('terms') # First term F = h if not h: return Eq(f(x), value) # Initialization series = value if terms > 1: hc = h.subs({x: point, y: value}) if hc.has(oo) or hc.has(NaN) or hc.has(zoo): # Derivative does not exist, not analytic return Eq(f(x), oo) elif hc: series += hc(x - point) for factcount in range(2, terms): Fnew = F.diff(x) + F.diff(y)h Fnewc = Fnew.subs({x: point, y: value}) # Same logic as above if Fnewc.has(oo) or Fnewc.has(NaN) or Fnewc.has(-oo) or Fnewc.has(zoo): return Eq(f(x), oo) series += Fnewc((x - point)factcount)/factorial(factcount) F = Fnew series += Order(xterms) return Eq(f(x), series) def ode_nth_linear_constant_coeff_homogeneous(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear homogeneous differential equation with constant coefficients. This is an equation of the form .. math:: a_n f^{(n)}(x) + a_{n-1} f^{(n-1)}(x) + \cdots + a_1 f'(x) + a_0 f(x) = 0\text{.} These equations can be solved in a general manner, by taking the roots of the characteristic equation `a_n m^n + a_{n-1} m^{n-1} + \cdots + a_1 m + a_0 = 0`. The solution will then be the sum of `C_n x^i e^{r x}` terms, for each where `C_n` is an arbitrary constant, `r` is a root of the characteristic equation and `i` is one of each from 0 to the multiplicity of the root - 1 (for example, a root 3 of multiplicity 2 would create the terms `C_1 e^{3 x} + C_2 x e^{3 x}`). The exponential is usually expanded for complex roots using Euler's equation `e^{I x} = \cos(x) + I \sin(x)`. Complex roots always come in conjugate pairs in polynomials with real coefficients, so the two roots will be represented (after simplifying the constants) as `e^{a x} \left(C_1 \cos(b x) + C_2 \sin(b x)\right)`. If SymPy cannot find exact roots to the characteristic equation, a :py:class:`~sympy.polys.rootoftools.CRootOf` instance will be return instead. >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(f(x).diff(x, 5) + 10f(x).diff(x) - 2f(x), f(x), ... hint='nth_linear_constant_coeff_homogeneous') ... # doctest: +NORMALIZE_WHITESPACE Eq(f(x), C5exp(xCRootOf(_x*5 + 10_x - 2, 0)) + (C1sin(xim(CRootOf(_x*5 + 10_x - 2, 1))) + C2cos(xim(CRootOf(_x*5 + 10_x - 2, 1))))exp(xre(CRootOf(_x*5 + 10_x - 2, 1))) + (C3sin(xim(CRootOf(_x*5 + 10_x - 2, 3))) + C4cos(xim(CRootOf(_x*5 + 10_x - 2, 3))))exp(xre(CRootOf(_x*5 + 10_x - 2, 3)))) Note that because this method does not involve integration, there is no ``nth_linear_constant_coeff_homogeneous_Integral`` hint. The following is for internal use: - ``returns = 'sol'`` returns the solution to the ODE. - ``returns = 'list'`` returns a list of linearly independent solutions, for use with non homogeneous solution methods like variation of parameters and undetermined coefficients. Note that, though the solutions should be linearly independent, this function does not explicitly check that. You can do ``assert simplify(wronskian(sollist)) != 0`` to check for linear independence. Also, ``assert len(sollist) == order`` will need to pass. - ``returns = 'both'``, return a dictionary ``{'sol': <solution to ODE>, 'list': <list of linearly independent solutions>}``. Examples ======== >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x, 4) + 2f(x).diff(x, 3) - ... 2f(x).diff(x, 2) - 6f(x).diff(x) + 5f(x), f(x), ... hint='nth_linear_constant_coeff_homogeneous')) x -2x f(x) = (C1 + C2x)e + (C3sin(x) + C4cos(x))e References ========== - https://en.wikipedia.org/wiki/Linear_differential_equation section: Nonhomogeneous_equation_with_constant_coefficients - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 211 # indirect doctest """ x = func.args[0] f = func.func r = match # First, set up characteristic equation. chareq, symbol = S.Zero, Dummy('x') for i in r.keys(): if type(i) == str or i < 0: pass else: chareq += r[i]symboli chareq = Poly(chareq, symbol) # Can't just call roots because it doesn't return rootof for unsolveable # polynomials. chareqroots = roots(chareq, multiple=True) if len(chareqroots) != order: chareqroots = [rootof(chareq, k) for k in range(chareq.degree())] chareq_is_complex = not all([i.is_real for i in chareq.all_coeffs()]) # A generator of constants constants = list(get_numbered_constants(eq, num=chareq.degree()2)) # Create a dict root: multiplicity or charroots charroots = defaultdict(int) for root in chareqroots: charroots[root] += 1 # We need to keep track of terms so we can run collect() at the end. # This is necessary for constantsimp to work properly. global collectterms collectterms = [] gensols = [] conjugate_roots = [] # used to prevent double-use of conjugate roots # Loop over roots in theorder provided by roots/rootof... for root in chareqroots: # but don't repoeat multiple roots. if root not in charroots: continue multiplicity = charroots.pop(root) for i in range(multiplicity): if chareq_is_complex: gensols.append(x*iexp(rootx)) collectterms = [(i, root, 0)] + collectterms continue reroot = re(root) imroot = im(root) if imroot.has(atan2) and reroot.has(atan2): # Remove this condition when re and im stop returning # circular atan2 usages. gensols.append(xiexp(rootx)) collectterms = [(i, root, 0)] + collectterms else: if root in conjugate_roots: collectterms = [(i, reroot, imroot)] + collectterms continue if imroot == 0: gensols.append(xiexp(rerootx)) collectterms = [(i, reroot, 0)] + collectterms continue conjugate_roots.append(conjugate(root)) gensols.append(xiexp(rerootx) sin(abs(imroot) * x)) gensols.append(x*iexp(rerootx) cos( imroot * x)) # This ordering is important collectterms = [(i, reroot, imroot)] + collectterms if returns == 'list': return gensols elif returns in ('sol' 'both'): gsol = Add([ij for (i, j) in zip(constants, gensols)]) if returns == 'sol': return Eq(f(x), gsol) else: return {'sol': Eq(f(x), gsol), 'list': gensols} else: raise ValueError('Unknown value for key "returns".') def ode_nth_linear_constant_coeff_undetermined_coefficients(eq, func, order, match): r""" Solves an `n`\th order linear differential equation with constant coefficients using the method of undetermined coefficients. This method works on differential equations of the form .. math:: a_n f^{(n)}(x) + a_{n-1} f^{(n-1)}(x) + \cdots + a_1 f'(x) + a_0 f(x) = P(x)\text{,} where `P(x)` is a function that has a finite number of linearly independent derivatives. Functions that fit this requirement are finite sums functions of the form `a x^i e^{b x} \sin(c x + d)` or `a x^i e^{b x} \cos(c x + d)`, where `i` is a non-negative integer and `a`, `b`, `c`, and `d` are constants. For example any polynomial in `x`, functions like `x^2 e^{2 x}`, `x \sin(x)`, and `e^x \cos(x)` can all be used. Products of `\sin`'s and `\cos`'s have a finite number of derivatives, because they can be expanded into `\sin(a x)` and `\cos(b x)` terms. However, SymPy currently cannot do that expansion, so you will need to manually rewrite the expression in terms of the above to use this method. So, for example, you will need to manually convert `\sin^2(x)` into `(1 + \cos(2 x))/2` to properly apply the method of undetermined coefficients on it. This method works by creating a trial function from the expression and all of its linear independent derivatives and substituting them into the original ODE. The coefficients for each term will be a system of linear equations, which are be solved for and substituted, giving the solution. If any of the trial functions are linearly dependent on the solution to the homogeneous equation, they are multiplied by sufficient `x` to make them linearly independent. Examples ======== >>> from sympy import Function, dsolve, pprint, exp, cos >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x, 2) + 2f(x).diff(x) + f(x) - ... 4exp(-x)x2 + cos(2x), f(x), ... hint='nth_linear_constant_coeff_undetermined_coefficients')) / 4\ \| x \| -x 4sin(2x) 3cos(2x) f(x) = \|C1 + C2x + --\|e - ---------- + ---------- \ 3 / 25 25 References ========== - https://en.wikipedia.org/wiki/Method_of_undetermined_coefficients - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 221 # indirect doctest """ gensol = ode_nth_linear_constant_coeff_homogeneous(eq, func, order, match, returns='both') match.update(gensol) return _solve_undetermined_coefficients(eq, func, order, match) def _solve_undetermined_coefficients(eq, func, order, match): r""" Helper function for the method of undetermined coefficients. See the :py:meth:`~sympy.solvers.ode.ode_nth_linear_constant_coeff_undetermined_coefficients` docstring for more information on this method. The parameter ``match`` should be a dictionary that has the following keys: ``list`` A list of solutions to the homogeneous equation, such as the list returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='list')``. ``sol`` The general solution, such as the solution returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='sol')``. ``trialset`` The set of trial functions as returned by ``_undetermined_coefficients_match()['trialset']``. """ x = func.args[0] f = func.func r = match coeffs = numbered_symbols('a', cls=Dummy) coefflist = [] gensols = r['list'] gsol = r['sol'] trialset = r['trialset'] notneedset = set([]) global collectterms if len(gensols) != order: raise NotImplementedError("Cannot find " + str(order) + " solutions to the homogeneous equation necessary to apply" + " undetermined coefficients to " + str(eq) + " (number of terms != order)") usedsin = set([]) mult = 0 # The multiplicity of the root getmult = True for i, reroot, imroot in collectterms: if getmult: mult = i + 1 getmult = False if i == 0: getmult = True if imroot: # Alternate between sin and cos if (i, reroot) in usedsin: check = x*iexp(rerootx)cos(imrootx) else: check = xiexp(rerootx)sin(abs(imroot)x) usedsin.add((i, reroot)) else: check = xiexp(rerootx) if check in trialset: # If an element of the trial function is already part of the # homogeneous solution, we need to multiply by sufficient x to # make it linearly independent. We also don't need to bother # checking for the coefficients on those elements, since we # already know it will be 0. while True: if checkx*mult in trialset: mult += 1 else: break trialset.add(checkx*mult) notneedset.add(check) newtrialset = trialset - notneedset trialfunc = 0 for i in newtrialset: c = next(coeffs) coefflist.append(c) trialfunc += ci eqs = sub_func_doit(eq, f(x), trialfunc) coeffsdict = dict(list(zip(trialset, [0](len(trialset) + 1)))) eqs = _mexpand(eqs) for i in Add.make_args(eqs): s = separatevars(i, dict=True, symbols=[x]) coeffsdict[s[x]] += s['coeff'] coeffvals = solve(list(coeffsdict.values()), coefflist) if not coeffvals: raise NotImplementedError( "Could not solve `%s` using the " "method of undetermined coefficients " "(unable to solve for coefficients)." % eq) psol = trialfunc.subs(coeffvals) return Eq(f(x), gsol.rhs + psol) def _undetermined_coefficients_match(expr, x): r""" Returns a trial function match if undetermined coefficients can be applied to ``expr``, and ``None`` otherwise. A trial expression can be found for an expression for use with the method of undetermined coefficients if the expression is an additive/multiplicative combination of constants, polynomials in `x` (the independent variable of expr), `\sin(a x + b)`, `\cos(a x + b)`, and `e^{a x}` terms (in other words, it has a finite number of linearly independent derivatives). Note that you may still need to multiply each term returned here by sufficient `x` to make it linearly independent with the solutions to the homogeneous equation. This is intended for internal use by ``undetermined_coefficients`` hints. SymPy currently has no way to convert `\sin^n(x) \cos^m(y)` into a sum of only `\sin(a x)` and `\cos(b x)` terms, so these are not implemented. So, for example, you will need to manually convert `\sin^2(x)` into `[1 + \cos(2 x)]/2` to properly apply the method of undetermined coefficients on it. Examples ======== >>> from sympy import log, exp >>> from sympy.solvers.ode import _undetermined_coefficients_match >>> from sympy.abc import x >>> _undetermined_coefficients_match(9xexp(x) + exp(-x), x) {'test': True, 'trialset': {xexp(x), exp(-x), exp(x)}} >>> _undetermined_coefficients_match(log(x), x) {'test': False} """ a = Wild('a', exclude=[x]) b = Wild('b', exclude=[x]) expr = powsimp(expr, combine='exp') # exp(x)exp(2x + 1) => exp(3x + 1) retdict = {} def _test_term(expr, x): r""" Test if ``expr`` fits the proper form for undetermined coefficients. """ if not expr.has(x): return True elif expr.is_Add: return all(_test_term(i, x) for i in expr.args) elif expr.is_Mul: if expr.has(sin, cos): foundtrig = False # Make sure that there is only one trig function in the args. # See the docstring. for i in expr.args: if i.has(sin, cos): if foundtrig: return False else: foundtrig = True return all(_test_term(i, x) for i in expr.args) elif expr.is_Function: if expr.func in (sin, cos, exp): if expr.args[0].match(ax + b): return True else: return False else: return False elif expr.is_Pow and expr.base.is_Symbol and expr.exp.is_Integer and \ expr.exp >= 0: return True elif expr.is_Pow and expr.base.is_number: if expr.exp.match(ax + b): return True else: return False elif expr.is_Symbol or expr.is_number: return True else: return False def _get_trial_set(expr, x, exprs=set([])): r""" Returns a set of trial terms for undetermined coefficients. The idea behind undetermined coefficients is that the terms expression repeat themselves after a finite number of derivatives, except for the coefficients (they are linearly dependent). So if we collect these, we should have the terms of our trial function. """ def _remove_coefficient(expr, x): r""" Returns the expression without a coefficient. Similar to expr.as_independent(x)[1], except it only works multiplicatively. """ term = S.One if expr.is_Mul: for i in expr.args: if i.has(x): term = i elif expr.has(x): term = expr return term expr = expand_mul(expr) if expr.is_Add: for term in expr.args: if _remove_coefficient(term, x) in exprs: pass else: exprs.add(_remove_coefficient(term, x)) exprs = exprs.union(_get_trial_set(term, x, exprs)) else: term = _remove_coefficient(expr, x) tmpset = exprs.union({term}) oldset = set([]) while tmpset != oldset: # If you get stuck in this loop, then _test_term is probably # broken oldset = tmpset.copy() expr = expr.diff(x) term = _remove_coefficient(expr, x) if term.is_Add: tmpset = tmpset.union(_get_trial_set(term, x, tmpset)) else: tmpset.add(term) exprs = tmpset return exprs retdict['test'] = _test_term(expr, x) if retdict['test']: # Try to generate a list of trial solutions that will have the # undetermined coefficients. Note that if any of these are not linearly # independent with any of the solutions to the homogeneous equation, # then they will need to be multiplied by sufficient x to make them so. # This function DOES NOT do that (it doesn't even look at the # homogeneous equation). retdict['trialset'] = _get_trial_set(expr, x) return retdict def ode_nth_linear_constant_coeff_variation_of_parameters(eq, func, order, match): r""" Solves an `n`\th order linear differential equation with constant coefficients using the method of variation of parameters. This method works on any differential equations of the form .. math:: f^{(n)}(x) + a_{n-1} f^{(n-1)}(x) + \cdots + a_1 f'(x) + a_0 f(x) = P(x)\text{.} This method works by assuming that the particular solution takes the form .. math:: \sum_{x=1}^{n} c_i(x) y_i(x)\text{,} where `y_i` is the `i`\th solution to the homogeneous equation. The solution is then solved using Wronskian's and Cramer's Rule. The particular solution is given by .. math:: \sum_{x=1}^n \left( \int \frac{W_i(x)}{W(x)} \,dx \right) y_i(x) \text{,} where `W(x)` is the Wronskian of the fundamental system (the system of `n` linearly independent solutions to the homogeneous equation), and `W_i(x)` is the Wronskian of the fundamental system with the `i`\th column replaced with `[0, 0, \cdots, 0, P(x)]`. This method is general enough to solve any `n`\th order inhomogeneous linear differential equation with constant coefficients, but sometimes SymPy cannot simplify the Wronskian well enough to integrate it. If this method hangs, try using the ``nth_linear_constant_coeff_variation_of_parameters_Integral`` hint and simplifying the integrals manually. Also, prefer using ``nth_linear_constant_coeff_undetermined_coefficients`` when it applies, because it doesn't use integration, making it faster and more reliable. Warning, using simplify=False with 'nth_linear_constant_coeff_variation_of_parameters' in :py:meth:`~sympy.solvers.ode.dsolve` may cause it to hang, because it will not attempt to simplify the Wronskian before integrating. It is recommended that you only use simplify=False with 'nth_linear_constant_coeff_variation_of_parameters_Integral' for this method, especially if the solution to the homogeneous equation has trigonometric functions in it. Examples ======== >>> from sympy import Function, dsolve, pprint, exp, log >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x, 3) - 3f(x).diff(x, 2) + ... 3f(x).diff(x) - f(x) - exp(x)log(x), f(x), ... hint='nth_linear_constant_coeff_variation_of_parameters')) / 3 \ \| 2 x (6log(x) - 11)\| x f(x) = \|C1 + C2x + C3x + ------------------\|e \ 36 / References ========== - https://en.wikipedia.org/wiki/Variation_of_parameters - http://planetmath.org/VariationOfParameters - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 233 # indirect doctest """ gensol = ode_nth_linear_constant_coeff_homogeneous(eq, func, order, match, returns='both') match.update(gensol) return _solve_variation_of_parameters(eq, func, order, match) def _solve_variation_of_parameters(eq, func, order, match): r""" Helper function for the method of variation of parameters and nonhomogeneous euler eq. See the :py:meth:`~sympy.solvers.ode.ode_nth_linear_constant_coeff_variation_of_parameters` docstring for more information on this method. The parameter ``match`` should be a dictionary that has the following keys: ``list`` A list of solutions to the homogeneous equation, such as the list returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='list')``. ``sol`` The general solution, such as the solution returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='sol')``. """ x = func.args[0] f = func.func r = match psol = 0 gensols = r['list'] gsol = r['sol'] wr = wronskian(gensols, x) if r.get('simplify', True): wr = simplify(wr) # We need much better simplification for # some ODEs. See issue 4662, for example. # To reduce commonly occurring sin(x)2 + cos(x)2 to 1 wr = trigsimp(wr, deep=True, recursive=True) if not wr: # The wronskian will be 0 iff the solutions are not linearly # independent. raise NotImplementedError("Cannot find " + str(order) + " solutions to the homogeneous equation necessary to apply " + "variation of parameters to " + str(eq) + " (Wronskian == 0)") if len(gensols) != order: raise NotImplementedError("Cannot find " + str(order) + " solutions to the homogeneous equation necessary to apply " + "variation of parameters to " + str(eq) + " (number of terms != order)") negoneterm = (-1)*(order) for i in gensols: psol += negonetermIntegral(wronskian([sol for sol in gensols if sol != i], x)r[-1]/wr, x)i/r[order] negoneterm = -1 if r.get('simplify', True): psol = simplify(psol) psol = trigsimp(psol, deep=True) return Eq(f(x), gsol.rhs + psol) def ode_separable(eq, func, order, match): r""" Solves separable 1st order differential equations. This is any differential equation that can be written as `P(y) \tfrac{dy}{dx} = Q(x)`. The solution can then just be found by rearranging terms and integrating: `\int P(y) \,dy = \int Q(x) \,dx`. This hint uses :py:meth:`sympy.simplify.simplify.separatevars` as its back end, so if a separable equation is not caught by this solver, it is most likely the fault of that function. :py:meth:`~sympy.simplify.simplify.separatevars` is smart enough to do most expansion and factoring necessary to convert a separable equation `F(x, y)` into the proper form `P(x)\cdot{}Q(y)`. The general solution is:: >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x >>> a, b, c, d, f = map(Function, ['a', 'b', 'c', 'd', 'f']) >>> genform = Eq(a(x)b(f(x))f(x).diff(x), c(x)d(f(x))) >>> pprint(genform) d a(x)b(f(x))--(f(x)) = c(x)d(f(x)) dx >>> pprint(dsolve(genform, f(x), hint='separable_Integral')) f(x) / / \| \| \| b(y) \| c(x) \| ---- dy = C1 + \| ---- dx \| d(y) \| a(x) \| \| / / Examples ======== >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(Eq(f(x)f(x).diff(x) + x, 3xf(x)*2), f(x), ... hint='separable', simplify=False)) / 2 \ 2 log\3f (x) - 1/ x ---------------- = C1 + -- 6 2 References ========== - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 52 # indirect doctest """ x = func.args[0] f = func.func C1 = get_numbered_constants(eq, num=1) r = match # {'m1':m1, 'm2':m2, 'y':y} u = r.get('hint', f(x)) # get u from separable_reduced else get f(x) return Eq(Integral(r['m2']['coeff']r['m2'][r['y']]/r['m1'][r['y']], (r['y'], None, u)), Integral(-r['m1']['coeff']r['m1'][x]/ r['m2'][x], x) + C1) def checkinfsol(eq, infinitesimals, func=None, order=None): r""" This function is used to check if the given infinitesimals are the actual infinitesimals of the given first order differential equation. This method is specific to the Lie Group Solver of ODEs. As of now, it simply checks, by substituting the infinitesimals in the partial differential equation. .. math:: \frac{\partial \eta}{\partial x} + \left(\frac{\partial \eta}{\partial y} - \frac{\partial \xi}{\partial x}\right)h - \frac{\partial \xi}{\partial y}h^{2} - \xi\frac{\partial h}{\partial x} - \eta\frac{\partial h}{\partial y} = 0 where `\eta`, and `\xi` are the infinitesimals and `h(x,y) = \frac{dy}{dx}` The infinitesimals should be given in the form of a list of dicts ``[{xi(x, y): inf, eta(x, y): inf}]``, corresponding to the output of the function infinitesimals. It returns a list of values of the form ``[(True/False, sol)]`` where ``sol`` is the value obtained after substituting the infinitesimals in the PDE. If it is ``True``, then ``sol`` would be 0. """ if isinstance(eq, Equality): eq = eq.lhs - eq.rhs if not func: eq, func = _preprocess(eq) variables = func.args if len(variables) != 1: raise ValueError("ODE's have only one independent variable") else: x = variables[0] if not order: order = ode_order(eq, func) if order != 1: raise NotImplementedError("Lie groups solver has been implemented " "only for first order differential equations") else: df = func.diff(x) a = Wild('a', exclude = [df]) b = Wild('b', exclude = [df]) match = collect(expand(eq), df).match(adf + b) if match: h = -simplify(match[b]/match[a]) else: try: sol = solve(eq, df) except NotImplementedError: raise NotImplementedError("Infinitesimals for the " "first order ODE could not be found") else: h = sol[0] # Find infinitesimals for one solution y = Dummy('y') h = h.subs(func, y) xi = Function('xi')(x, y) eta = Function('eta')(x, y) dxi = Function('xi')(x, func) deta = Function('eta')(x, func) pde = (eta.diff(x) + (eta.diff(y) - xi.diff(x))h - (xi.diff(y))h2 - xi(h.diff(x)) - eta(h.diff(y))) soltup = [] for sol in infinitesimals: tsol = {xi: S(sol[dxi]).subs(func, y), eta: S(sol[deta]).subs(func, y)} sol = simplify(pde.subs(tsol).doit()) if sol: soltup.append((False, sol.subs(y, func))) else: soltup.append((True, 0)) return soltup def ode_lie_group(eq, func, order, match): r""" This hint implements the Lie group method of solving first order differential equations. The aim is to convert the given differential equation from the given coordinate given system into another coordinate system where it becomes invariant under the one-parameter Lie group of translations. The converted ODE is quadrature and can be solved easily. It makes use of the :py:meth:`sympy.solvers.ode.infinitesimals` function which returns the infinitesimals of the transformation. The coordinates `r` and `s` can be found by solving the following Partial Differential Equations. .. math :: \xi\frac{\partial r}{\partial x} + \eta\frac{\partial r}{\partial y} = 0 .. math :: \xi\frac{\partial s}{\partial x} + \eta\frac{\partial s}{\partial y} = 1 The differential equation becomes separable in the new coordinate system .. math :: \frac{ds}{dr} = \frac{\frac{\partial s}{\partial x} + h(x, y)\frac{\partial s}{\partial y}}{ \frac{\partial r}{\partial x} + h(x, y)\frac{\partial r}{\partial y}} After finding the solution by integration, it is then converted back to the original coordinate system by substituting `r` and `s` in terms of `x` and `y` again. Examples ======== >>> from sympy import Function, dsolve, Eq, exp, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x) + 2xf(x) - xexp(-x*2), f(x), ... hint='lie_group')) / 2\ 2 \| x \| -x f(x) = \|C1 + --\|e \ 2 / References ========== - Solving differential equations by Symmetry Groups, John Starrett, pp. 1 - pp. 14 """ heuristics = lie_heuristics inf = {} f = func.func x = func.args[0] df = func.diff(x) xi = Function("xi") eta = Function("eta") xis = match.pop('xi') etas = match.pop('eta') if match: h = -simplify(match[match['d']]/match[match['e']]) y = match['y'] else: try: sol = solve(eq, df) if sol == []: raise NotImplementedError except NotImplementedError: raise NotImplementedError("Unable to solve the differential equation " + str(eq) + " by the lie group method") else: y = Dummy("y") h = sol[0].subs(func, y) if xis is not None and etas is not None: inf = [{xi(x, f(x)): S(xis), eta(x, f(x)): S(etas)}] if not checkinfsol(eq, inf, func=f(x), order=1)[0][0]: raise ValueError("The given infinitesimals xi and eta" " are not the infinitesimals to the given equation") else: heuristics = ["user_defined"] match = {'h': h, 'y': y} # This is done so that if: # a] solve raises a NotImplementedError. # b] any heuristic raises a ValueError # another heuristic can be used. tempsol = [] # Used by solve below for heuristic in heuristics: try: if not inf: inf = infinitesimals(eq, hint=heuristic, func=func, order=1, match=match) except ValueError: continue else: for infsim in inf: xiinf = (infsim[xi(x, func)]).subs(func, y) etainf = (infsim[eta(x, func)]).subs(func, y) # This condition creates recursion while using pdsolve. # Since the first step while solving a PDE of form # a(f(x, y).diff(x)) + b(f(x, y).diff(y)) + c = 0 # is to solve the ODE dy/dx = b/a if simplify(etainf/xiinf) == h: continue rpde = f(x, y).diff(x)xiinf + f(x, y).diff(y)etainf r = pdsolve(rpde, func=f(x, y)).rhs s = pdsolve(rpde - 1, func=f(x, y)).rhs newcoord = [_lie_group_remove(coord) for coord in [r, s]] r = Dummy("r") s = Dummy("s") C1 = Symbol("C1") rcoord = newcoord[0] scoord = newcoord[-1] try: sol = solve([r - rcoord, s - scoord], x, y, dict=True) except NotImplementedError: continue else: sol = sol[0] xsub = sol[x] ysub = sol[y] num = simplify(scoord.diff(x) + scoord.diff(y)h) denom = simplify(rcoord.diff(x) + rcoord.diff(y)h) if num and denom: diffeq = simplify((num/denom).subs([(x, xsub), (y, ysub)])) sep = separatevars(diffeq, symbols=[r, s], dict=True) if sep: # Trying to separate, r and s coordinates deq = integrate((1/sep[s]), s) + C1 - integrate(sep['coeff']sep[r], r) # Substituting and reverting back to original coordinates deq = deq.subs([(r, rcoord), (s, scoord)]) try: sdeq = solve(deq, y) except NotImplementedError: tempsol.append(deq) else: if len(sdeq) == 1: return Eq(f(x), sdeq.pop()) else: return [Eq(f(x), sol) for sol in sdeq] elif denom: # (ds/dr) is zero which means s is constant return Eq(f(x), solve(scoord - C1, y)[0]) elif num: # (dr/ds) is zero which means r is constant return Eq(f(x), solve(rcoord - C1, y)[0]) # If nothing works, return solution as it is, without solving for y if tempsol: if len(tempsol) == 1: return Eq(tempsol.pop().subs(y, f(x)), 0) else: return [Eq(sol.subs(y, f(x)), 0) for sol in tempsol] raise NotImplementedError("The given ODE " + str(eq) + " cannot be solved by" + " the lie group method") def _lie_group_remove(coords): r""" This function is strictly meant for internal use by the Lie group ODE solving method. It replaces arbitrary functions returned by pdsolve with either 0 or 1 or the args of the arbitrary function. The algorithm used is: 1] If coords is an instance of an Undefined Function, then the args are returned 2] If the arbitrary function is present in an Add object, it is replaced by zero. 3] If the arbitrary function is present in an Mul object, it is replaced by one. 4] If coords has no Undefined Function, it is returned as it is. Examples ======== >>> from sympy.solvers.ode import _lie_group_remove >>> from sympy import Function >>> from sympy.abc import x, y >>> F = Function("F") >>> eq = x2y >>> _lie_group_remove(eq) x*2y >>> eq = F(x*2y) >>> _lie_group_remove(eq) x*2y >>> eq = y*2x + F(x*3) >>> _lie_group_remove(eq) xy2 >>> eq = (F(x3) + y)x4 >>> _lie_group_remove(eq) x4y """ if isinstance(coords, AppliedUndef): return coords.args[0] elif coords.is_Add: subfunc = coords.atoms(AppliedUndef) if subfunc: for func in subfunc: coords = coords.subs(func, 0) return coords elif coords.is_Pow: base, expr = coords.as_base_exp() base = _lie_group_remove(base) expr = _lie_group_remove(expr) return base*expr elif coords.is_Mul: mulargs = [] coordargs = coords.args for arg in coordargs: if not isinstance(coords, AppliedUndef): mulargs.append(_lie_group_remove(arg)) return Mul(mulargs) return coords def infinitesimals(eq, func=None, order=None, hint='default', match=None): r""" The infinitesimal functions of an ordinary differential equation, `\xi(x,y)` and `\eta(x,y)`, are the infinitesimals of the Lie group of point transformations for which the differential equation is invariant. So, the ODE `y'=f(x,y)` would admit a Lie group `x^=X(x,y;\varepsilon)=x+\varepsilon\xi(x,y)`, `y^=Y(x,y;\varepsilon)=y+\varepsilon\eta(x,y)` such that `(y^)'=f(x^, y^)`. A change of coordinates, to `r(x,y)` and `s(x,y)`, can be performed so this Lie group becomes the translation group, `r^=r` and `s^=s+\varepsilon`. They are tangents to the coordinate curves of the new system. Consider the transformation `(x, y) \to (X, Y)` such that the differential equation remains invariant. `\xi` and `\eta` are the tangents to the transformed coordinates `X` and `Y`, at `\varepsilon=0`. .. math:: \left(\frac{\partial X(x,y;\varepsilon)}{\partial\varepsilon }\right)\|_{\varepsilon=0} = \xi, \left(\frac{\partial Y(x,y;\varepsilon)}{\partial\varepsilon }\right)\|_{\varepsilon=0} = \eta, The infinitesimals can be found by solving the following PDE: >>> from sympy import Function, diff, Eq, pprint >>> from sympy.abc import x, y >>> xi, eta, h = map(Function, ['xi', 'eta', 'h']) >>> h = h(x, y) # dy/dx = h >>> eta = eta(x, y) >>> xi = xi(x, y) >>> genform = Eq(eta.diff(x) + (eta.diff(y) - xi.diff(x))h ... - (xi.diff(y))h2 - xi(h.diff(x)) - eta(h.diff(y)), 0) >>> pprint(genform) /d d \ d 2 d \|--(eta(x, y)) - --(xi(x, y))\|h(x, y) - eta(x, y)--(h(x, y)) - h (x, y)--(x \dy dx / dy dy <BLANKLINE> d d i(x, y)) - xi(x, y)--(h(x, y)) + --(eta(x, y)) = 0 dx dx Solving the above mentioned PDE is not trivial, and can be solved only by making intelligent assumptions for `\xi` and `\eta` (heuristics). Once an infinitesimal is found, the attempt to find more heuristics stops. This is done to optimise the speed of solving the differential equation. If a list of all the infinitesimals is needed, ``hint`` should be flagged as ``all``, which gives the complete list of infinitesimals. If the infinitesimals for a particular heuristic needs to be found, it can be passed as a flag to ``hint``. Examples ======== >>> from sympy import Function, diff >>> from sympy.solvers.ode import infinitesimals >>> from sympy.abc import x >>> f = Function('f') >>> eq = f(x).diff(x) - x2f(x) >>> infinitesimals(eq) [{eta(x, f(x)): exp(x*3/3), xi(x, f(x)): 0}] References ========== - Solving differential equations by Symmetry Groups, John Starrett, pp. 1 - pp. 14 """ if isinstance(eq, Equality): eq = eq.lhs - eq.rhs if not func: eq, func = _preprocess(eq) variables = func.args if len(variables) != 1: raise ValueError("ODE's have only one independent variable") else: x = variables[0] if not order: order = ode_order(eq, func) if order != 1: raise NotImplementedError("Infinitesimals for only " "first order ODE's have been implemented") else: df = func.diff(x) # Matching differential equation of the form adf + b a = Wild('a', exclude = [df]) b = Wild('b', exclude = [df]) if match: # Used by lie_group hint h = match['h'] y = match['y'] else: match = collect(expand(eq), df).match(adf + b) if match: h = -simplify(match[b]/match[a]) else: try: sol = solve(eq, df) except NotImplementedError: raise NotImplementedError("Infinitesimals for the " "first order ODE could not be found") else: h = sol[0] # Find infinitesimals for one solution y = Dummy("y") h = h.subs(func, y) u = Dummy("u") hx = h.diff(x) hy = h.diff(y) hinv = ((1/h).subs([(x, u), (y, x)])).subs(u, y) # Inverse ODE match = {'h': h, 'func': func, 'hx': hx, 'hy': hy, 'y': y, 'hinv': hinv} if hint == 'all': xieta = [] for heuristic in lie_heuristics: function = globals()['lie_heuristic_' + heuristic] inflist = function(match, comp=True) if inflist: xieta.extend([inf for inf in inflist if inf not in xieta]) if xieta: return xieta else: raise NotImplementedError("Infinitesimals could not be found for " "the given ODE") elif hint == 'default': for heuristic in lie_heuristics: function = globals()['lie_heuristic_' + heuristic] xieta = function(match, comp=False) if xieta: return xieta raise NotImplementedError("Infinitesimals could not be found for" " the given ODE") elif hint not in lie_heuristics: raise ValueError("Heuristic not recognized: " + hint) else: function = globals()['lie_heuristic_' + hint] xieta = function(match, comp=True) if xieta: return xieta else: raise ValueError("Infinitesimals could not be found using the" " given heuristic") def lie_heuristic_abaco1_simple(match, comp=False): r""" The first heuristic uses the following four sets of assumptions on `\xi` and `\eta` .. math:: \xi = 0, \eta = f(x) .. math:: \xi = 0, \eta = f(y) .. math:: \xi = f(x), \eta = 0 .. math:: \xi = f(y), \eta = 0 The success of this heuristic is determined by algebraic factorisation. For the first assumption `\xi = 0` and `\eta` to be a function of `x`, the PDE .. math:: \frac{\partial \eta}{\partial x} + (\frac{\partial \eta}{\partial y} - \frac{\partial \xi}{\partial x})h - \frac{\partial \xi}{\partial y}h^{2} - \xi\frac{\partial h}{\partial x} - \eta\frac{\partial h}{\partial y} = 0 reduces to `f'(x) - f\frac{\partial h}{\partial y} = 0` If `\frac{\partial h}{\partial y}` is a function of `x`, then this can usually be integrated easily. A similar idea is applied to the other 3 assumptions as well. References ========== - E.S Cheb-Terrab, L.G.S Duarte and L.A,C.P da Mota, Computer Algebra Solving of First Order ODEs Using Symmetry Methods, pp. 8 """ xieta = [] y = match['y'] h = match['h'] func = match['func'] x = func.args[0] hx = match['hx'] hy = match['hy'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) hysym = hy.free_symbols if y not in hysym: try: fx = exp(integrate(hy, x)) except NotImplementedError: pass else: inf = {xi: S(0), eta: fx} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) factor = hy/h facsym = factor.free_symbols if x not in facsym: try: fy = exp(integrate(factor, y)) except NotImplementedError: pass else: inf = {xi: S(0), eta: fy.subs(y, func)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) factor = -hx/h facsym = factor.free_symbols if y not in facsym: try: fx = exp(integrate(factor, x)) except NotImplementedError: pass else: inf = {xi: fx, eta: S(0)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) factor = -hx/(h2) facsym = factor.free_symbols if x not in facsym: try: fy = exp(integrate(factor, y)) except NotImplementedError: pass else: inf = {xi: fy.subs(y, func), eta: S(0)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) if xieta: return xieta def lie_heuristic_abaco1_product(match, comp=False): r""" The second heuristic uses the following two assumptions on `\xi` and `\eta` .. math:: \eta = 0, \xi = f(x)g(y) .. math:: \eta = f(x)g(y), \xi = 0 The first assumption of this heuristic holds good if `\frac{1}{h^{2}}\frac{\partial^2}{\partial x \partial y}\log(h)` is separable in `x` and `y`, then the separated factors containing `x` is `f(x)`, and `g(y)` is obtained by .. math:: e^{\int f\frac{\partial}{\partial x}\left(\frac{1}{fh}\right)\,dy} provided `f\frac{\partial}{\partial x}\left(\frac{1}{fh}\right)` is a function of `y` only. The second assumption holds good if `\frac{dy}{dx} = h(x, y)` is rewritten as `\frac{dy}{dx} = \frac{1}{h(y, x)}` and the same properties of the first assumption satisfies. After obtaining `f(x)` and `g(y)`, the coordinates are again interchanged, to get `\eta` as `f(x)g(y)` References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 7 - pp. 8 """ xieta = [] y = match['y'] h = match['h'] hinv = match['hinv'] func = match['func'] x = func.args[0] xi = Function('xi')(x, func) eta = Function('eta')(x, func) inf = separatevars(((log(h).diff(y)).diff(x))/h*2, dict=True, symbols=[x, y]) if inf and inf['coeff']: fx = inf[x] gy = simplify(fx((1/(fxh)).diff(x))) gysyms = gy.free_symbols if x not in gysyms: gy = exp(integrate(gy, y)) inf = {eta: S(0), xi: (fxgy).subs(y, func)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) u1 = Dummy("u1") inf = separatevars(((log(hinv).diff(y)).diff(x))/hinv*2, dict=True, symbols=[x, y]) if inf and inf['coeff']: fx = inf[x] gy = simplify(fx((1/(fxhinv)).diff(x))) gysyms = gy.free_symbols if x not in gysyms: gy = exp(integrate(gy, y)) etaval = fxgy etaval = (etaval.subs([(x, u1), (y, x)])).subs(u1, y) inf = {eta: etaval.subs(y, func), xi: S(0)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) if xieta: return xieta def lie_heuristic_bivariate(match, comp=False): r""" The third heuristic assumes the infinitesimals `\xi` and `\eta` to be bi-variate polynomials in `x` and `y`. The assumption made here for the logic below is that `h` is a rational function in `x` and `y` though that may not be necessary for the infinitesimals to be bivariate polynomials. The coefficients of the infinitesimals are found out by substituting them in the PDE and grouping similar terms that are polynomials and since they form a linear system, solve and check for non trivial solutions. The degree of the assumed bivariates are increased till a certain maximum value. References ========== - Lie Groups and Differential Equations pp. 327 - pp. 329 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) if h.is_rational_function(): # The maximum degree that the infinitesimals can take is # calculated by this technique. etax, etay, etad, xix, xiy, xid = symbols("etax etay etad xix xiy xid") ipde = etax + (etay - xix)h - xiyh*2 - xidhx - etadhy num, denom = cancel(ipde).as_numer_denom() deg = Poly(num, x, y).total_degree() deta = Function('deta')(x, y) dxi = Function('dxi')(x, y) ipde = (deta.diff(x) + (deta.diff(y) - dxi.diff(x))h - (dxi.diff(y))h2 - dxihx - detahy) xieq = Symbol("xi0") etaeq = Symbol("eta0") for i in range(deg + 1): if i: xieq += Add([ Symbol("xi_" + str(power) + "_" + str(i - power))xpowery*(i - power) for power in range(i + 1)]) etaeq += Add([ Symbol("eta_" + str(power) + "_" + str(i - power))xpowery*(i - power) for power in range(i + 1)]) pden, denom = (ipde.subs({dxi: xieq, deta: etaeq}).doit()).as_numer_denom() pden = expand(pden) # If the individual terms are monomials, the coefficients # are grouped if pden.is_polynomial(x, y) and pden.is_Add: polyy = Poly(pden, x, y).as_dict() if polyy: symset = xieq.free_symbols.union(etaeq.free_symbols) - {x, y} soldict = solve(polyy.values(), symset) if isinstance(soldict, list): soldict = soldict[0] if any(soldict.values()): xired = xieq.subs(soldict) etared = etaeq.subs(soldict) # Scaling is done by substituting one for the parameters # This can be any number except zero. dict_ = dict((sym, 1) for sym in symset) inf = {eta: etared.subs(dict_).subs(y, func), xi: xired.subs(dict_).subs(y, func)} return [inf] def lie_heuristic_chi(match, comp=False): r""" The aim of the fourth heuristic is to find the function `\chi(x, y)` that satisfies the PDE `\frac{d\chi}{dx} + h\frac{d\chi}{dx} - \frac{\partial h}{\partial y}\chi = 0`. This assumes `\chi` to be a bivariate polynomial in `x` and `y`. By intuition, `h` should be a rational function in `x` and `y`. The method used here is to substitute a general binomial for `\chi` up to a certain maximum degree is reached. The coefficients of the polynomials, are calculated by by collecting terms of the same order in `x` and `y`. After finding `\chi`, the next step is to use `\eta = \xih + \chi`, to determine `\xi` and `\eta`. This can be done by dividing `\chi` by `h` which would give `-\xi` as the quotient and `\eta` as the remainder. References ========== - E.S Cheb-Terrab, L.G.S Duarte and L.A,C.P da Mota, Computer Algebra Solving of First Order ODEs Using Symmetry Methods, pp. 8 """ h = match['h'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) if h.is_rational_function(): schi, schix, schiy = symbols("schi, schix, schiy") cpde = schix + hschiy - hyschi num, denom = cancel(cpde).as_numer_denom() deg = Poly(num, x, y).total_degree() chi = Function('chi')(x, y) chix = chi.diff(x) chiy = chi.diff(y) cpde = chix + hchiy - hychi chieq = Symbol("chi") for i in range(1, deg + 1): chieq += Add([ Symbol("chi_" + str(power) + "_" + str(i - power))xpowery*(i - power) for power in range(i + 1)]) cnum, cden = cancel(cpde.subs({chi : chieq}).doit()).as_numer_denom() cnum = expand(cnum) if cnum.is_polynomial(x, y) and cnum.is_Add: cpoly = Poly(cnum, x, y).as_dict() if cpoly: solsyms = chieq.free_symbols - {x, y} soldict = solve(cpoly.values(), solsyms) if isinstance(soldict, list): soldict = soldict[0] if any(soldict.values()): chieq = chieq.subs(soldict) dict_ = dict((sym, 1) for sym in solsyms) chieq = chieq.subs(dict_) # After finding chi, the main aim is to find out # eta, xi by the equation eta = xih + chi # One method to set xi, would be rearranging it to # (eta/h) - xi = (chi/h). This would mean dividing # chi by h would give -xi as the quotient and eta # as the remainder. Thanks to Sean Vig for suggesting # this method. xic, etac = div(chieq, h) inf = {eta: etac.subs(y, func), xi: -xic.subs(y, func)} return [inf] def lie_heuristic_function_sum(match, comp=False): r""" This heuristic uses the following two assumptions on `\xi` and `\eta` .. math:: \eta = 0, \xi = f(x) + g(y) .. math:: \eta = f(x) + g(y), \xi = 0 The first assumption of this heuristic holds good if .. math:: \frac{\partial}{\partial y}[(h\frac{\partial^{2}}{ \partial x^{2}}(h^{-1}))^{-1}] is separable in `x` and `y`, 1. The separated factors containing `y` is `\frac{\partial g}{\partial y}`. From this `g(y)` can be determined. 2. The separated factors containing `x` is `f''(x)`. 3. `h\frac{\partial^{2}}{\partial x^{2}}(h^{-1})` equals `\frac{f''(x)}{f(x) + g(y)}`. From this `f(x)` can be determined. The second assumption holds good if `\frac{dy}{dx} = h(x, y)` is rewritten as `\frac{dy}{dx} = \frac{1}{h(y, x)}` and the same properties of the first assumption satisfies. After obtaining `f(x)` and `g(y)`, the coordinates are again interchanged, to get `\eta` as `f(x) + g(y)`. For both assumptions, the constant factors are separated among `g(y)` and `f''(x)`, such that `f''(x)` obtained from 3] is the same as that obtained from 2]. If not possible, then this heuristic fails. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 7 - pp. 8 """ xieta = [] h = match['h'] func = match['func'] hinv = match['hinv'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) for odefac in [h, hinv]: factor = odefac((1/odefac).diff(x, 2)) sep = separatevars((1/factor).diff(y), dict=True, symbols=[x, y]) if sep and sep['coeff'] and sep[x].has(x) and sep[y].has(y): k = Dummy("k") try: gy = kintegrate(sep[y], y) except NotImplementedError: pass else: fdd = 1/(ksep[x]sep['coeff']) fx = simplify(fdd/factor - gy) check = simplify(fx.diff(x, 2) - fdd) if fx: if not check: fx = fx.subs(k, 1) gy = (gy/k) else: sol = solve(check, k) if sol: sol = sol[0] fx = fx.subs(k, sol) gy = (gy/k)sol else: continue if odefac == hinv: # Inverse ODE fx = fx.subs(x, y) gy = gy.subs(y, x) etaval = factor_terms(fx + gy) if etaval.is_Mul: etaval = Mul([arg for arg in etaval.args if arg.has(x, y)]) if odefac == hinv: # Inverse ODE inf = {eta: etaval.subs(y, func), xi : S(0)} else: inf = {xi: etaval.subs(y, func), eta : S(0)} if not comp: return [inf] else: xieta.append(inf) if xieta: return xieta def lie_heuristic_abaco2_similar(match, comp=False): r""" This heuristic uses the following two assumptions on `\xi` and `\eta` .. math:: \eta = g(x), \xi = f(x) .. math:: \eta = f(y), \xi = g(y) For the first assumption, 1. First `\frac{\frac{\partial h}{\partial y}}{\frac{\partial^{2} h}{ \partial yy}}` is calculated. Let us say this value is A 2. If this is constant, then `h` is matched to the form `A(x) + B(x)e^{ \frac{y}{C}}` then, `\frac{e^{\int \frac{A(x)}{C} \,dx}}{B(x)}` gives `f(x)` and `A(x)f(x)` gives `g(x)` 3. Otherwise `\frac{\frac{\partial A}{\partial X}}{\frac{\partial A}{ \partial Y}} = \gamma` is calculated. If a] `\gamma` is a function of `x` alone b] `\frac{\gamma\frac{\partial h}{\partial y} - \gamma'(x) - \frac{ \partial h}{\partial x}}{h + \gamma} = G` is a function of `x` alone. then, `e^{\int G \,dx}` gives `f(x)` and `-\gammaf(x)` gives `g(x)` The second assumption holds good if `\frac{dy}{dx} = h(x, y)` is rewritten as `\frac{dy}{dx} = \frac{1}{h(y, x)}` and the same properties of the first assumption satisfies. After obtaining `f(x)` and `g(x)`, the coordinates are again interchanged, to get `\xi` as `f(x^)` and `\eta` as `g(y^)` References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] hinv = match['hinv'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) factor = cancel(h.diff(y)/h.diff(y, 2)) factorx = factor.diff(x) factory = factor.diff(y) if not factor.has(x) and not factor.has(y): A = Wild('A', exclude=[y]) B = Wild('B', exclude=[y]) C = Wild('C', exclude=[x, y]) match = h.match(A + Bexp(y/C)) try: tau = exp(-integrate(match[A]/match[C]), x)/match[B] except NotImplementedError: pass else: gx = match[A]tau return [{xi: tau, eta: gx}] else: gamma = cancel(factorx/factory) if not gamma.has(y): tauint = cancel((gammahy - gamma.diff(x) - hx)/(h + gamma)) if not tauint.has(y): try: tau = exp(integrate(tauint, x)) except NotImplementedError: pass else: gx = -taugamma return [{xi: tau, eta: gx}] factor = cancel(hinv.diff(y)/hinv.diff(y, 2)) factorx = factor.diff(x) factory = factor.diff(y) if not factor.has(x) and not factor.has(y): A = Wild('A', exclude=[y]) B = Wild('B', exclude=[y]) C = Wild('C', exclude=[x, y]) match = h.match(A + Bexp(y/C)) try: tau = exp(-integrate(match[A]/match[C]), x)/match[B] except NotImplementedError: pass else: gx = match[A]tau return [{eta: tau.subs(x, func), xi: gx.subs(x, func)}] else: gamma = cancel(factorx/factory) if not gamma.has(y): tauint = cancel((gammahinv.diff(y) - gamma.diff(x) - hinv.diff(x))/( hinv + gamma)) if not tauint.has(y): try: tau = exp(integrate(tauint, x)) except NotImplementedError: pass else: gx = -taugamma return [{eta: tau.subs(x, func), xi: gx.subs(x, func)}] def lie_heuristic_abaco2_unique_unknown(match, comp=False): r""" This heuristic assumes the presence of unknown functions or known functions with non-integer powers. 1. A list of all functions and non-integer powers containing x and y 2. Loop over each element `f` in the list, find `\frac{\frac{\partial f}{\partial x}}{ \frac{\partial f}{\partial x}} = R` If it is separable in `x` and `y`, let `X` be the factors containing `x`. Then a] Check if `\xi = X` and `\eta = -\frac{X}{R}` satisfy the PDE. If yes, then return `\xi` and `\eta` b] Check if `\xi = \frac{-R}{X}` and `\eta = -\frac{1}{X}` satisfy the PDE. If yes, then return `\xi` and `\eta` If not, then check if a] :math:`\xi = -R,\eta = 1` b] :math:`\xi = 1, \eta = -\frac{1}{R}` are solutions. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) funclist = [] for atom in h.atoms(Pow): base, exp = atom.as_base_exp() if base.has(x) and base.has(y): if not exp.is_Integer: funclist.append(atom) for function in h.atoms(AppliedUndef): syms = function.free_symbols if x in syms and y in syms: funclist.append(function) for f in funclist: frac = cancel(f.diff(y)/f.diff(x)) sep = separatevars(frac, dict=True, symbols=[x, y]) if sep and sep['coeff']: xitry1 = sep[x] etatry1 = -1/(sep[y]sep['coeff']) pde1 = etatry1.diff(y)h - xitry1.diff(x)h - xitry1hx - etatry1hy if not simplify(pde1): return [{xi: xitry1, eta: etatry1.subs(y, func)}] xitry2 = 1/etatry1 etatry2 = 1/xitry1 pde2 = etatry2.diff(x) - (xitry2.diff(y))h2 - xitry2hx - etatry2hy if not simplify(expand(pde2)): return [{xi: xitry2.subs(y, func), eta: etatry2}] else: etatry = -1/frac pde = etatry.diff(x) + etatry.diff(y)h - hx - etatryhy if not simplify(pde): return [{xi: S(1), eta: etatry.subs(y, func)}] xitry = -frac pde = -xitry.diff(x)h -xitry.diff(y)h2 - xitryhx -hy if not simplify(expand(pde)): return [{xi: xitry.subs(y, func), eta: S(1)}] def lie_heuristic_abaco2_unique_general(match, comp=False): r""" This heuristic finds if infinitesimals of the form `\eta = f(x)`, `\xi = g(y)` without making any assumptions on `h`. The complete sequence of steps is given in the paper mentioned below. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) A = hx.diff(y) B = hy.diff(y) + hy2 C = hx.diff(x) - hx2 if not (A and B and C): return Ax = A.diff(x) Ay = A.diff(y) Axy = Ax.diff(y) Axx = Ax.diff(x) Ayy = Ay.diff(y) D = simplify(2Axy + hxAy - Axhy + (hxhy + 2A)A)A - 3AxAy if not D: E1 = simplify(3Ax2 + ((hx2 + 2C)A - 2Axx)A) if E1: E2 = simplify((2Ayy + (2B - hy*2)A)A - 3Ay*2) if not E2: E3 = simplify( E1((28Ax + 4hxA)A*3 - E1(hyA + Ay)) - E1.diff(x)8A4) if not E3: etaval = cancel((4A*3(Ax - hxA) + E1(hyA - Ay))/(S(2)AE1)) if x not in etaval: try: etaval = exp(integrate(etaval, y)) except NotImplementedError: pass else: xival = -4A*3etaval/E1 if y not in xival: return [{xi: xival, eta: etaval.subs(y, func)}] else: E1 = simplify((2Ayy + (2B - hy*2)A)A - 3Ay*2) if E1: E2 = simplify( 4A*3D - D*2 + E1((2Axx - (hx2 + 2C)A)A - 3Ax2)) if not E2: E3 = simplify( -(AD)E1.diff(y) + ((E1.diff(x) - hyD)A + 3AyD + (Ahx - 3Ax)E1)E1) if not E3: etaval = cancel(((Ahx - Ax)E1 - (Ay + Ahy)D)/(S(2)AD)) if x not in etaval: try: etaval = exp(integrate(etaval, y)) except NotImplementedError: pass else: xival = -E1etaval/D if y not in xival: return [{xi: xival, eta: etaval.subs(y, func)}] def lie_heuristic_linear(match, comp=False): r""" This heuristic assumes 1. `\xi = ax + by + c` and 2. `\eta = fx + gy + h` After substituting the following assumptions in the determining PDE, it reduces to .. math:: f + (g - a)h - bh^{2} - (ax + by + c)\frac{\partial h}{\partial x} - (fx + gy + c)\frac{\partial h}{\partial y} Solving the reduced PDE obtained, using the method of characteristics, becomes impractical. The method followed is grouping similar terms and solving the system of linear equations obtained. The difference between the bivariate heuristic is that `h` need not be a rational function in this case. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) coeffdict = {} symbols = numbered_symbols("c", cls=Dummy) symlist = [next(symbols) for _ in islice(symbols, 6)] C0, C1, C2, C3, C4, C5 = symlist pde = C3 + (C4 - C0)h - (C0x + C1y + C2)hx - (C3x + C4y + C5)hy - C1h*2 pde, denom = pde.as_numer_denom() pde = powsimp(expand(pde)) if pde.is_Add: terms = pde.args for term in terms: if term.is_Mul: rem = Mul([m for m in term.args if not m.has(x, y)]) xypart = term/rem if xypart not in coeffdict: coeffdict[xypart] = rem else: coeffdict[xypart] += rem else: if term not in coeffdict: coeffdict[term] = S(1) else: coeffdict[term] += S(1) sollist = coeffdict.values() soldict = solve(sollist, symlist) if soldict: if isinstance(soldict, list): soldict = soldict[0] subval = soldict.values() if any(t for t in subval): onedict = dict(zip(symlist, [1]6)) xival = C0x + C1func + C2 etaval = C3x + C4func + C5 xival = xival.subs(soldict) etaval = etaval.subs(soldict) xival = xival.subs(onedict) etaval = etaval.subs(onedict) return [{xi: xival, eta: etaval}] def sysode_linear_2eq_order1(match_): x = match_['func'][0].func y = match_['func'][1].func func = match_['func'] fc = match_['func_coeff'] eq = match_['eq'] r = dict() t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] for i in range(2): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs # for equations Eq(a1diff(x(t),t), ax(t) + by(t) + k1) # and Eq(a2diff(x(t),t), cx(t) + dy(t) + k2) r['a'] = -fc[0,x(t),0]/fc[0,x(t),1] r['c'] = -fc[1,x(t),0]/fc[1,y(t),1] r['b'] = -fc[0,y(t),0]/fc[0,x(t),1] r['d'] = -fc[1,y(t),0]/fc[1,y(t),1] forcing = [S(0),S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t)): forcing[i] += j if not (forcing[0].has(t) or forcing[1].has(t)): r['k1'] = forcing[0] r['k2'] = forcing[1] else: raise NotImplementedError("Only homogeneous problems are supported" + " (and constant inhomogeneity)") if match_['type_of_equation'] == 'type1': sol = _linear_2eq_order1_type1(x, y, t, r, eq) if match_['type_of_equation'] == 'type2': gsol = _linear_2eq_order1_type1(x, y, t, r, eq) psol = _linear_2eq_order1_type2(x, y, t, r, eq) sol = [Eq(x(t), gsol[0].rhs+psol[0]), Eq(y(t), gsol[1].rhs+psol[1])] if match_['type_of_equation'] == 'type3': sol = _linear_2eq_order1_type3(x, y, t, r, eq) if match_['type_of_equation'] == 'type4': sol = _linear_2eq_order1_type4(x, y, t, r, eq) if match_['type_of_equation'] == 'type5': sol = _linear_2eq_order1_type5(x, y, t, r, eq) if match_['type_of_equation'] == 'type6': sol = _linear_2eq_order1_type6(x, y, t, r, eq) if match_['type_of_equation'] == 'type7': sol = _linear_2eq_order1_type7(x, y, t, r, eq) return sol def _linear_2eq_order1_type1(x, y, t, r, eq): r""" It is classified under system of two linear homogeneous first-order constant-coefficient ordinary differential equations. The equations which come under this type are .. math:: x' = ax + by, .. math:: y' = cx + dy The characteristics equation is written as .. math:: \lambda^{2} + (a+d) \lambda + ad - bc = 0 and its discriminant is `D = (a-d)^{2} + 4bc`. There are several cases 1. Case when `ad - bc \neq 0`. The origin of coordinates, `x = y = 0`, is the only stationary point; it is - a node if `D = 0` - a node if `D > 0` and `ad - bc > 0` - a saddle if `D > 0` and `ad - bc < 0` - a focus if `D < 0` and `a + d \neq 0` - a centre if `D < 0` and `a + d \neq 0`. 1.1. If `D > 0`. The characteristic equation has two distinct real roots `\lambda_1` and `\lambda_ 2` . The general solution of the system in question is expressed as .. math:: x = C_1 b e^{\lambda_1 t} + C_2 b e^{\lambda_2 t} .. math:: y = C_1 (\lambda_1 - a) e^{\lambda_1 t} + C_2 (\lambda_2 - a) e^{\lambda_2 t} where `C_1` and `C_2` being arbitrary constants 1.2. If `D < 0`. The characteristics equation has two conjugate roots, `\lambda_1 = \sigma + i \beta` and `\lambda_2 = \sigma - i \beta`. The general solution of the system is given by .. math:: x = b e^{\sigma t} (C_1 \sin(\beta t) + C_2 \cos(\beta t)) .. math:: y = e^{\sigma t} ([(\sigma - a) C_1 - \beta C_2] \sin(\beta t) + [\beta C_1 + (\sigma - a) C_2 \cos(\beta t)]) 1.3. If `D = 0` and `a \neq d`. The characteristic equation has two equal roots, `\lambda_1 = \lambda_2`. The general solution of the system is written as .. math:: x = 2b (C_1 + \frac{C_2}{a-d} + C_2 t) e^{\frac{a+d}{2} t} .. math:: y = [(d - a) C_1 + C_2 + (d - a) C_2 t] e^{\frac{a+d}{2} t} 1.4. If `D = 0` and `a = d \neq 0` and `b = 0` .. math:: x = C_1 e^{a t} , y = (c C_1 t + C_2) e^{a t} 1.5. If `D = 0` and `a = d \neq 0` and `c = 0` .. math:: x = (b C_1 t + C_2) e^{a t} , y = C_1 e^{a t} 2. Case when `ad - bc = 0` and `a^{2} + b^{2} > 0`. The whole straight line `ax + by = 0` consists of singular points. The original system of differential equations can be rewritten as .. math:: x' = ax + by , y' = k (ax + by) 2.1 If `a + bk \neq 0`, solution will be .. math:: x = b C_1 + C_2 e^{(a + bk) t} , y = -a C_1 + k C_2 e^{(a + bk) t} 2.2 If `a + bk = 0`, solution will be .. math:: x = C_1 (bk t - 1) + b C_2 t , y = k^{2} b C_1 t + (b k^{2} t + 1) C_2 """ C1, C2 = get_numbered_constants(eq, num=2) a, b, c, d = r['a'], r['b'], r['c'], r['d'] real_coeff = all(v.is_real for v in (a, b, c, d)) D = (a - d)2 + 4bc l1 = (a + d + sqrt(D))/2 l2 = (a + d - sqrt(D))/2 equal_roots = Eq(D, 0).expand() gsol1, gsol2 = [], [] # Solutions have exponential form if either D > 0 with real coefficients # or D != 0 with complex coefficients. Eigenvalues are distinct. # For each eigenvalue lam, pick an eigenvector, making sure we don't get (0, 0) # The candidates are (b, lam-a) and (lam-d, c). exponential_form = D > 0 if real_coeff else Not(equal_roots) bad_ab_vector1 = And(Eq(b, 0), Eq(l1, a)) bad_ab_vector2 = And(Eq(b, 0), Eq(l2, a)) vector1 = Matrix((Piecewise((l1 - d, bad_ab_vector1), (b, True)), Piecewise((c, bad_ab_vector1), (l1 - a, True)))) vector2 = Matrix((Piecewise((l2 - d, bad_ab_vector2), (b, True)), Piecewise((c, bad_ab_vector2), (l2 - a, True)))) sol_vector = C1exp(l1t)vector1 + C2exp(l2t)vector2 gsol1.append((sol_vector[0], exponential_form)) gsol2.append((sol_vector[1], exponential_form)) # Solutions have trigonometric form for real coefficients with D < 0 # Both b and c are nonzero in this case, so (b, lam-a) is an eigenvector # It splits into real/imag parts as (b, sigma-a) and (0, beta). Then # multiply it by C1(cos(betat) + IC2sin(betat)) and separate real/imag trigonometric_form = D < 0 if real_coeff else False sigma = re(l1) if im(l1).is_positive: beta = im(l1) else: beta = im(l2) vector1 = Matrix((b, sigma - a)) vector2 = Matrix((0, beta)) sol_vector = exp(sigmat) * (C1(cos(betat)vector1 - sin(betat)vector2) + \ C2(sin(betat)vector1 + cos(betat)vector2)) gsol1.append((sol_vector[0], trigonometric_form)) gsol2.append((sol_vector[1], trigonometric_form)) # Final case is D == 0, a single eigenvalue. If the eigenspace is 2-dimensional # then we have a scalar matrix, deal with this case first. scalar_matrix = And(Eq(a, d), Eq(b, 0), Eq(c, 0)) vector1 = Matrix((S.One, S.Zero)) vector2 = Matrix((S.Zero, S.One)) sol_vector = exp(l1t) (C1vector1 + C2vector2) gsol1.append((sol_vector[0], scalar_matrix)) gsol2.append((sol_vector[1], scalar_matrix)) # Have one eigenvector. Get a generalized eigenvector from (A-lam)vector2 = vector1 vector1 = Matrix((Piecewise((l1 - d, bad_ab_vector1), (b, True)), Piecewise((c, bad_ab_vector1), (l1 - a, True)))) vector2 = Matrix((Piecewise((S.One, bad_ab_vector1), (S.Zero, Eq(a, l1)), (b/(a - l1), True)), Piecewise((S.Zero, bad_ab_vector1), (S.One, Eq(a, l1)), (S.Zero, True)))) sol_vector = exp(l1t) * (C1vector1 + C2(vector2 + tvector1)) gsol1.append((sol_vector[0], equal_roots)) gsol2.append((sol_vector[1], equal_roots)) return [Eq(x(t), Piecewise(gsol1)), Eq(y(t), Piecewise(gsol2))] def _linear_2eq_order1_type2(x, y, t, r, eq): r""" The equations of this type are .. math:: x' = ax + by + k1 , y' = cx + dy + k2 The general solution of this system is given by sum of its particular solution and the general solution of the corresponding homogeneous system is obtained from type1. 1. When `ad - bc \neq 0`. The particular solution will be `x = x_0` and `y = y_0` where `x_0` and `y_0` are determined by solving linear system of equations .. math:: a x_0 + b y_0 + k1 = 0 , c x_0 + d y_0 + k2 = 0 2. When `ad - bc = 0` and `a^{2} + b^{2} > 0`. In this case, the system of equation becomes .. math:: x' = ax + by + k_1 , y' = k (ax + by) + k_2 2.1 If `\sigma = a + bk \neq 0`, particular solution is given by .. math:: x = b \sigma^{-1} (c_1 k - c_2) t - \sigma^{-2} (a c_1 + b c_2) .. math:: y = kx + (c_2 - c_1 k) t 2.2 If `\sigma = a + bk = 0`, particular solution is given by .. math:: x = \frac{1}{2} b (c_2 - c_1 k) t^{2} + c_1 t .. math:: y = kx + (c_2 - c_1 k) t """ r['k1'] = -r['k1']; r['k2'] = -r['k2'] if (r['a']r['d'] - r['b']r['c']) != 0: x0, y0 = symbols('x0, y0', cls=Dummy) sol = solve((r['a']x0+r['b']y0+r['k1'], r['c']x0+r['d']y0+r['k2']), x0, y0) psol = [sol[x0], sol[y0]] elif (r['a']r['d'] - r['b']r['c']) == 0 and (r['a']2+r['b']2) > 0: k = r['c']/r['a'] sigma = r['a'] + r['b']k if sigma != 0: sol1 = r['b']sigma-1(r['k1']k-r['k2'])t - sigma*-2(r['a']r['k1']+r['b']r['k2']) sol2 = ksol1 + (r['k2']-r['k1']k)t else: # FIXME: a previous typo fix shows this is not covered by tests sol1 = r['b'](r['k2']-r['k1']k)t*2 + r['k1']t sol2 = ksol1 + (r['k2']-r['k1']k)t psol = [sol1, sol2] return psol def _linear_2eq_order1_type3(x, y, t, r, eq): r""" The equations of this type of ode are .. math:: x' = f(t) x + g(t) y .. math:: y' = g(t) x + f(t) y The solution of such equations is given by .. math:: x = e^{F} (C_1 e^{G} + C_2 e^{-G}) , y = e^{F} (C_1 e^{G} - C_2 e^{-G}) where `C_1` and `C_2` are arbitrary constants, and .. math:: F = \int f(t) \,dt , G = \int g(t) \,dt """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) F = Integral(r['a'], t) G = Integral(r['b'], t) sol1 = exp(F)(C1exp(G) + C2exp(-G)) sol2 = exp(F)(C1exp(G) - C2exp(-G)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type4(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = -g(t) x + f(t) y The solution is given by .. math:: x = F (C_1 \cos(G) + C_2 \sin(G)), y = F (-C_1 \sin(G) + C_2 \cos(G)) where `C_1` and `C_2` are arbitrary constants, and .. math:: F = \int f(t) \,dt , G = \int g(t) \,dt """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) if r['b'] == -r['c']: F = exp(Integral(r['a'], t)) G = Integral(r['b'], t) sol1 = F(C1cos(G) + C2sin(G)) sol2 = F(-C1sin(G) + C2cos(G)) elif r['d'] == -r['a']: F = exp(Integral(r['c'], t)) G = Integral(r['d'], t) sol1 = F(-C1sin(G) + C2cos(G)) sol2 = F(C1cos(G) + C2sin(G)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type5(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = a g(t) x + [f(t) + b g(t)] y The transformation of .. math:: x = e^{\int f(t) \,dt} u , y = e^{\int f(t) \,dt} v , T = \int g(t) \,dt leads to a system of constant coefficient linear differential equations .. math:: u'(T) = v , v'(T) = au + bv """ u, v = symbols('u, v', cls=Function) T = Symbol('T') if not cancel(r['c']/r['b']).has(t): p = cancel(r['c']/r['b']) q = cancel((r['d']-r['a'])/r['b']) eq = (Eq(diff(u(T),T), v(T)), Eq(diff(v(T),T), pu(T)+qv(T))) sol = dsolve(eq) sol1 = exp(Integral(r['a'], t))sol[0].rhs.subs(T, Integral(r['b'], t)) sol2 = exp(Integral(r['a'], t))sol[1].rhs.subs(T, Integral(r['b'], t)) if not cancel(r['a']/r['d']).has(t): p = cancel(r['a']/r['d']) q = cancel((r['b']-r['c'])/r['d']) sol = dsolve(Eq(diff(u(T),T), v(T)), Eq(diff(v(T),T), pu(T)+qv(T))) sol1 = exp(Integral(r['c'], t))sol[1].rhs.subs(T, Integral(r['d'], t)) sol2 = exp(Integral(r['c'], t))sol[0].rhs.subs(T, Integral(r['d'], t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type6(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = a [f(t) + a h(t)] x + a [g(t) - h(t)] y This is solved by first multiplying the first equation by `-a` and adding it to the second equation to obtain .. math:: y' - a x' = -a h(t) (y - a x) Setting `U = y - ax` and integrating the equation we arrive at .. math:: y - ax = C_1 e^{-a \int h(t) \,dt} and on substituting the value of y in first equation give rise to first order ODEs. After solving for `x`, we can obtain `y` by substituting the value of `x` in second equation. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) p = 0 q = 0 p1 = cancel(r['c']/cancel(r['c']/r['d']).as_numer_denom()[0]) p2 = cancel(r['a']/cancel(r['a']/r['b']).as_numer_denom()[0]) for n, i in enumerate([p1, p2]): for j in Mul.make_args(collect_const(i)): if not j.has(t): q = j if q!=0 and n==0: if ((r['c']/j - r['a'])/(r['b'] - r['d']/j)) == j: p = 1 s = j break if q!=0 and n==1: if ((r['a']/j - r['c'])/(r['d'] - r['b']/j)) == j: p = 2 s = j break if p == 1: equ = diff(x(t),t) - r['a']x(t) - r['b'](sx(t) + C1exp(-sIntegral(r['b'] - r['d']/s, t))) hint1 = classify_ode(equ)[1] sol1 = dsolve(equ, hint=hint1+'_Integral').rhs sol2 = ssol1 + C1exp(-sIntegral(r['b'] - r['d']/s, t)) elif p ==2: equ = diff(y(t),t) - r['c']y(t) - r['d']sy(t) + C1exp(-sIntegral(r['d'] - r['b']/s, t)) hint1 = classify_ode(equ)[1] sol2 = dsolve(equ, hint=hint1+'_Integral').rhs sol1 = ssol2 + C1exp(-sIntegral(r['d'] - r['b']/s, t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type7(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = h(t) x + p(t) y Differentiating the first equation and substituting the value of `y` from second equation will give a second-order linear equation .. math:: g x'' - (fg + gp + g') x' + (fgp - g^{2} h + f g' - f' g) x = 0 This above equation can be easily integrated if following conditions are satisfied. 1. `fgp - g^{2} h + f g' - f' g = 0` 2. `fgp - g^{2} h + f g' - f' g = ag, fg + gp + g' = bg` If first condition is satisfied then it is solved by current dsolve solver and in second case it becomes a constant coefficient differential equation which is also solved by current solver. Otherwise if the above condition fails then, a particular solution is assumed as `x = x_0(t)` and `y = y_0(t)` Then the general solution is expressed as .. math:: x = C_1 x_0(t) + C_2 x_0(t) \int \frac{g(t) F(t) P(t)}{x_0^{2}(t)} \,dt .. math:: y = C_1 y_0(t) + C_2 [\frac{F(t) P(t)}{x_0(t)} + y_0(t) \int \frac{g(t) F(t) P(t)}{x_0^{2}(t)} \,dt] where C1 and C2 are arbitrary constants and .. math:: F(t) = e^{\int f(t) \,dt} , P(t) = e^{\int p(t) \,dt} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) e1 = r['a']r['b']r['c'] - r['b']2r['c'] + r['a']diff(r['b'],t) - diff(r['a'],t)r['b'] e2 = r['a']r['c']r['d'] - r['b']r['c']2 + diff(r['c'],t)r['d'] - r['c']diff(r['d'],t) m1 = r['a']r['b'] + r['b']r['d'] + diff(r['b'],t) m2 = r['a']r['c'] + r['c']r['d'] + diff(r['c'],t) if e1 == 0: sol1 = dsolve(r['b']diff(x(t),t,t) - m1diff(x(t),t)).rhs sol2 = dsolve(diff(y(t),t) - r['c']sol1 - r['d']y(t)).rhs elif e2 == 0: sol2 = dsolve(r['c']diff(y(t),t,t) - m2diff(y(t),t)).rhs sol1 = dsolve(diff(x(t),t) - r['a']x(t) - r['b']sol2).rhs elif not (e1/r['b']).has(t) and not (m1/r['b']).has(t): sol1 = dsolve(diff(x(t),t,t) - (m1/r['b'])diff(x(t),t) - (e1/r['b'])x(t)).rhs sol2 = dsolve(diff(y(t),t) - r['c']sol1 - r['d']y(t)).rhs elif not (e2/r['c']).has(t) and not (m2/r['c']).has(t): sol2 = dsolve(diff(y(t),t,t) - (m2/r['c'])diff(y(t),t) - (e2/r['c'])y(t)).rhs sol1 = dsolve(diff(x(t),t) - r['a']x(t) - r['b']sol2).rhs else: x0 = Function('x0')(t) # x0 and y0 being particular solutions y0 = Function('y0')(t) F = exp(Integral(r['a'],t)) P = exp(Integral(r['d'],t)) sol1 = C1x0 + C2x0Integral(r['b']FP/x0*2, t) sol2 = C1y0 + C2(FP/x0 + y0Integral(r['b']FP/x02, t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def sysode_linear_2eq_order2(match_): x = match_['func'][0].func y = match_['func'][1].func func = match_['func'] fc = match_['func_coeff'] eq = match_['eq'] r = dict() t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] for i in range(2): eqs = [] for terms in Add.make_args(eq[i]): eqs.append(terms/fc[i,func[i],2]) eq[i] = Add(eqs) # for equations Eq(diff(x(t),t,t), a1diff(x(t),t)+b1diff(y(t),t)+c1x(t)+d1y(t)+e1) # and Eq(a2diff(y(t),t,t), a2diff(x(t),t)+b2diff(y(t),t)+c2x(t)+d2y(t)+e2) r['a1'] = -fc[0,x(t),1]/fc[0,x(t),2] ; r['a2'] = -fc[1,x(t),1]/fc[1,y(t),2] r['b1'] = -fc[0,y(t),1]/fc[0,x(t),2] ; r['b2'] = -fc[1,y(t),1]/fc[1,y(t),2] r['c1'] = -fc[0,x(t),0]/fc[0,x(t),2] ; r['c2'] = -fc[1,x(t),0]/fc[1,y(t),2] r['d1'] = -fc[0,y(t),0]/fc[0,x(t),2] ; r['d2'] = -fc[1,y(t),0]/fc[1,y(t),2] const = [S(0), S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not (j.has(x(t)) or j.has(y(t))): const[i] += j r['e1'] = -const[0] r['e2'] = -const[1] if match_['type_of_equation'] == 'type1': sol = _linear_2eq_order2_type1(x, y, t, r, eq) elif match_['type_of_equation'] == 'type2': gsol = _linear_2eq_order2_type1(x, y, t, r, eq) psol = _linear_2eq_order2_type2(x, y, t, r, eq) sol = [Eq(x(t), gsol[0].rhs+psol[0]), Eq(y(t), gsol[1].rhs+psol[1])] elif match_['type_of_equation'] == 'type3': sol = _linear_2eq_order2_type3(x, y, t, r, eq) elif match_['type_of_equation'] == 'type4': sol = _linear_2eq_order2_type4(x, y, t, r, eq) elif match_['type_of_equation'] == 'type5': sol = _linear_2eq_order2_type5(x, y, t, r, eq) elif match_['type_of_equation'] == 'type6': sol = _linear_2eq_order2_type6(x, y, t, r, eq) elif match_['type_of_equation'] == 'type7': sol = _linear_2eq_order2_type7(x, y, t, r, eq) elif match_['type_of_equation'] == 'type8': sol = _linear_2eq_order2_type8(x, y, t, r, eq) elif match_['type_of_equation'] == 'type9': sol = _linear_2eq_order2_type9(x, y, t, r, eq) elif match_['type_of_equation'] == 'type10': sol = _linear_2eq_order2_type10(x, y, t, r, eq) elif match_['type_of_equation'] == 'type11': sol = _linear_2eq_order2_type11(x, y, t, r, eq) return sol def _linear_2eq_order2_type1(x, y, t, r, eq): r""" System of two constant-coefficient second-order linear homogeneous differential equations .. math:: x'' = ax + by .. math:: y'' = cx + dy The characteristic equation for above equations .. math:: \lambda^4 - (a + d) \lambda^2 + ad - bc = 0 whose discriminant is `D = (a - d)^2 + 4bc \neq 0` 1. When `ad - bc \neq 0` 1.1. If `D \neq 0`. The characteristic equation has four distinct roots, `\lambda_1, \lambda_2, \lambda_3, \lambda_4`. The general solution of the system is .. math:: x = C_1 b e^{\lambda_1 t} + C_2 b e^{\lambda_2 t} + C_3 b e^{\lambda_3 t} + C_4 b e^{\lambda_4 t} .. math:: y = C_1 (\lambda_1^{2} - a) e^{\lambda_1 t} + C_2 (\lambda_2^{2} - a) e^{\lambda_2 t} + C_3 (\lambda_3^{2} - a) e^{\lambda_3 t} + C_4 (\lambda_4^{2} - a) e^{\lambda_4 t} where `C_1,..., C_4` are arbitrary constants. 1.2. If `D = 0` and `a \neq d`: .. math:: x = 2 C_1 (bt + \frac{2bk}{a - d}) e^{\frac{kt}{2}} + 2 C_2 (bt + \frac{2bk}{a - d}) e^{\frac{-kt}{2}} + 2b C_3 t e^{\frac{kt}{2}} + 2b C_4 t e^{\frac{-kt}{2}} .. math:: y = C_1 (d - a) t e^{\frac{kt}{2}} + C_2 (d - a) t e^{\frac{-kt}{2}} + C_3 [(d - a) t + 2k] e^{\frac{kt}{2}} + C_4 [(d - a) t - 2k] e^{\frac{-kt}{2}} where `C_1,..., C_4` are arbitrary constants and `k = \sqrt{2 (a + d)}` 1.3. If `D = 0` and `a = d \neq 0` and `b = 0`: .. math:: x = 2 \sqrt{a} C_1 e^{\sqrt{a} t} + 2 \sqrt{a} C_2 e^{-\sqrt{a} t} .. math:: y = c C_1 t e^{\sqrt{a} t} - c C_2 t e^{-\sqrt{a} t} + C_3 e^{\sqrt{a} t} + C_4 e^{-\sqrt{a} t} 1.4. If `D = 0` and `a = d \neq 0` and `c = 0`: .. math:: x = b C_1 t e^{\sqrt{a} t} - b C_2 t e^{-\sqrt{a} t} + C_3 e^{\sqrt{a} t} + C_4 e^{-\sqrt{a} t} .. math:: y = 2 \sqrt{a} C_1 e^{\sqrt{a} t} + 2 \sqrt{a} C_2 e^{-\sqrt{a} t} 2. When `ad - bc = 0` and `a^2 + b^2 > 0`. Then the original system becomes .. math:: x'' = ax + by .. math:: y'' = k (ax + by) 2.1. If `a + bk \neq 0`: .. math:: x = C_1 e^{t \sqrt{a + bk}} + C_2 e^{-t \sqrt{a + bk}} + C_3 bt + C_4 b .. math:: y = C_1 k e^{t \sqrt{a + bk}} + C_2 k e^{-t \sqrt{a + bk}} - C_3 at - C_4 a 2.2. If `a + bk = 0`: .. math:: x = C_1 b t^3 + C_2 b t^2 + C_3 t + C_4 .. math:: y = kx + 6 C_1 t + 2 C_2 """ r['a'] = r['c1'] r['b'] = r['d1'] r['c'] = r['c2'] r['d'] = r['d2'] l = Symbol('l') C1, C2, C3, C4 = get_numbered_constants(eq, num=4) chara_eq = l4 - (r['a']+r['d'])l*2 + r['a']r['d'] - r['b']r['c'] l1 = rootof(chara_eq, 0) l2 = rootof(chara_eq, 1) l3 = rootof(chara_eq, 2) l4 = rootof(chara_eq, 3) D = (r['a'] - r['d'])2 + 4r['b']r['c'] if (r['a']r['d'] - r['b']r['c']) != 0: if D != 0: gsol1 = C1r['b']exp(l1t) + C2r['b']exp(l2t) + C3r['b']exp(l3t) \ + C4r['b']exp(l4t) gsol2 = C1(l1*2-r['a'])exp(l1t) + C2(l2*2-r['a'])exp(l2t) + \ C3(l3*2-r['a'])exp(l3t) + C4(l4*2-r['a'])exp(l4t) else: if r['a'] != r['d']: k = sqrt(2(r['a']+r['d'])) mid = r['b']t+2r['b']k/(r['a']-r['d']) gsol1 = 2C1midexp(kt/2) + 2C2midexp(-kt/2) + \ 2r['b']C3texp(kt/2) + 2r['b']C4texp(-kt/2) gsol2 = C1(r['d']-r['a'])texp(kt/2) + C2(r['d']-r['a'])texp(-kt/2) + \ C3((r['d']-r['a'])t+2k)exp(kt/2) + C4((r['d']-r['a'])t-2k)exp(-kt/2) elif r['a'] == r['d'] != 0 and r['b'] == 0: sa = sqrt(r['a']) gsol1 = 2saC1exp(sat) + 2saC2exp(-sat) gsol2 = r['c']C1texp(sat)-r['c']C2texp(-sat)+C3exp(sat)+C4exp(-sat) elif r['a'] == r['d'] != 0 and r['c'] == 0: sa = sqrt(r['a']) gsol1 = r['b']C1texp(sat)-r['b']C2texp(-sat)+C3exp(sat)+C4exp(-sat) gsol2 = 2saC1exp(sat) + 2saC2exp(-sat) elif (r['a']r['d'] - r['b']r['c']) == 0 and (r['a']2 + r['b']2) > 0: k = r['c']/r['a'] if r['a'] + r['b']k != 0: mid = sqrt(r['a'] + r['b']k) gsol1 = C1exp(midt) + C2exp(-midt) + C3r['b']t + C4r['b'] gsol2 = C1kexp(midt) + C2kexp(-midt) - C3r['a']t - C4r['a'] else: gsol1 = C1r['b']t3 + C2r['b']t2 + C3t + C4 gsol2 = kgsol1 + 6C1t + 2C2 return [Eq(x(t), gsol1), Eq(y(t), gsol2)] def _linear_2eq_order2_type2(x, y, t, r, eq): r""" The equations in this type are .. math:: x'' = a_1 x + b_1 y + c_1 .. math:: y'' = a_2 x + b_2 y + c_2 The general solution of this system is given by the sum of its particular solution and the general solution of the homogeneous system. The general solution is given by the linear system of 2 equation of order 2 and type 1 1. If `a_1 b_2 - a_2 b_1 \neq 0`. A particular solution will be `x = x_0` and `y = y_0` where the constants `x_0` and `y_0` are determined by solving the linear algebraic system .. math:: a_1 x_0 + b_1 y_0 + c_1 = 0, a_2 x_0 + b_2 y_0 + c_2 = 0 2. If `a_1 b_2 - a_2 b_1 = 0` and `a_1^2 + b_1^2 > 0`. In this case, the system in question becomes .. math:: x'' = ax + by + c_1, y'' = k (ax + by) + c_2 2.1. If `\sigma = a + bk \neq 0`, the particular solution will be .. math:: x = \frac{1}{2} b \sigma^{-1} (c_1 k - c_2) t^2 - \sigma^{-2} (a c_1 + b c_2) .. math:: y = kx + \frac{1}{2} (c_2 - c_1 k) t^2 2.2. If `\sigma = a + bk = 0`, the particular solution will be .. math:: x = \frac{1}{24} b (c_2 - c_1 k) t^4 + \frac{1}{2} c_1 t^2 .. math:: y = kx + \frac{1}{2} (c_2 - c_1 k) t^2 """ x0, y0 = symbols('x0, y0') if r['c1']r['d2'] - r['c2']r['d1'] != 0: sol = solve((r['c1']x0+r['d1']y0+r['e1'], r['c2']x0+r['d2']y0+r['e2']), x0, y0) psol = [sol[x0], sol[y0]] elif r['c1']r['d2'] - r['c2']r['d1'] == 0 and (r['c1']2 + r['d1']2) > 0: k = r['c2']/r['c1'] sig = r['c1'] + r['d1']k if sig != 0: psol1 = r['d1']sig*-1(r['e1']k-r['e2'])t2/2 - \ sig-2(r['c1']r['e1']+r['d1']r['e2']) psol2 = kpsol1 + (r['e2'] - r['e1']k)t*2/2 psol = [psol1, psol2] else: psol1 = r['d1'](r['e2']-r['e1']k)t*4/24 + r['e1']t*2/2 psol2 = kpsol1 + (r['e2']-r['e1']k)t2/2 psol = [psol1, psol2] return psol def _linear_2eq_order2_type3(x, y, t, r, eq): r""" These type of equation is used for describing the horizontal motion of a pendulum taking into account the Earth rotation. The solution is given with `a^2 + 4b > 0`: .. math:: x = C_1 \cos(\alpha t) + C_2 \sin(\alpha t) + C_3 \cos(\beta t) + C_4 \sin(\beta t) .. math:: y = -C_1 \sin(\alpha t) + C_2 \cos(\alpha t) - C_3 \sin(\beta t) + C_4 \cos(\beta t) where `C_1,...,C_4` and .. math:: \alpha = \frac{1}{2} a + \frac{1}{2} \sqrt{a^2 + 4b}, \beta = \frac{1}{2} a - \frac{1}{2} \sqrt{a^2 + 4b} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) if r['b1']2 - 4r['c1'] > 0: r['a'] = r['b1'] ; r['b'] = -r['c1'] alpha = r['a']/2 + sqrt(r['a']2 + 4r['b'])/2 beta = r['a']/2 - sqrt(r['a']*2 + 4r['b'])/2 sol1 = C1cos(alphat) + C2sin(alphat) + C3cos(betat) + C4sin(betat) sol2 = -C1sin(alphat) + C2cos(alphat) - C3sin(betat) + C4cos(betat) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type4(x, y, t, r, eq): r""" These equations are found in the theory of oscillations .. math:: x'' + a_1 x' + b_1 y' + c_1 x + d_1 y = k_1 e^{i \omega t} .. math:: y'' + a_2 x' + b_2 y' + c_2 x + d_2 y = k_2 e^{i \omega t} The general solution of this linear nonhomogeneous system of constant-coefficient differential equations is given by the sum of its particular solution and the general solution of the corresponding homogeneous system (with `k_1 = k_2 = 0`) 1. A particular solution is obtained by the method of undetermined coefficients: .. math:: x = A_* e^{i \omega t}, y = B_* e^{i \omega t} On substituting these expressions into the original system of differential equations, one arrive at a linear nonhomogeneous system of algebraic equations for the coefficients `A` and `B`. 2. The general solution of the homogeneous system of differential equations is determined by a linear combination of linearly independent particular solutions determined by the method of undetermined coefficients in the form of exponentials: .. math:: x = A e^{\lambda t}, y = B e^{\lambda t} On substituting these expressions into the original system and collecting the coefficients of the unknown `A` and `B`, one obtains .. math:: (\lambda^{2} + a_1 \lambda + c_1) A + (b_1 \lambda + d_1) B = 0 .. math:: (a_2 \lambda + c_2) A + (\lambda^{2} + b_2 \lambda + d_2) B = 0 The determinant of this system must vanish for nontrivial solutions A, B to exist. This requirement results in the following characteristic equation for `\lambda` .. math:: (\lambda^2 + a_1 \lambda + c_1) (\lambda^2 + b_2 \lambda + d_2) - (b_1 \lambda + d_1) (a_2 \lambda + c_2) = 0 If all roots `k_1,...,k_4` of this equation are distinct, the general solution of the original system of the differential equations has the form .. math:: x = C_1 (b_1 \lambda_1 + d_1) e^{\lambda_1 t} - C_2 (b_1 \lambda_2 + d_1) e^{\lambda_2 t} - C_3 (b_1 \lambda_3 + d_1) e^{\lambda_3 t} - C_4 (b_1 \lambda_4 + d_1) e^{\lambda_4 t} .. math:: y = C_1 (\lambda_1^{2} + a_1 \lambda_1 + c_1) e^{\lambda_1 t} + C_2 (\lambda_2^{2} + a_1 \lambda_2 + c_1) e^{\lambda_2 t} + C_3 (\lambda_3^{2} + a_1 \lambda_3 + c_1) e^{\lambda_3 t} + C_4 (\lambda_4^{2} + a_1 \lambda_4 + c_1) e^{\lambda_4 t} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) k = Symbol('k') Ra, Ca, Rb, Cb = symbols('Ra, Ca, Rb, Cb') a1 = r['a1'] ; a2 = r['a2'] b1 = r['b1'] ; b2 = r['b2'] c1 = r['c1'] ; c2 = r['c2'] d1 = r['d1'] ; d2 = r['d2'] k1 = r['e1'].expand().as_independent(t)[0] k2 = r['e2'].expand().as_independent(t)[0] ew1 = r['e1'].expand().as_independent(t)[1] ew2 = powdenest(ew1).as_base_exp()[1] ew3 = collect(ew2, t).coeff(t) w = cancel(ew3/I) # The particular solution is assumed to be (Ra+ICa)exp(Iwt) and # (Rb+ICb)exp(Iwt) for x(t) and y(t) respectively peq1 = (-w*2+c1)Ra - a1wCa + d1Rb - b1wCb - k1 peq2 = a1wRa + (-w2+c1)Ca + b1wRb + d1Cb peq3 = c2Ra - a2wCa + (-w*2+d2)Rb - b2wCb - k2 peq4 = a2wRa + c2Ca + b2wRb + (-w2+d2)Cb # FIXME: solve for what in what? Ra, Rb, etc I guess # but then psol not used for anything? psol = solve([peq1, peq2, peq3, peq4]) chareq = (k*2+a1k+c1)(k2+b2k+d2) - (b1k+d1)(a2k+c2) [k1, k2, k3, k4] = roots_quartic(Poly(chareq)) sol1 = -C1(b1k1+d1)exp(k1t) - C2(b1k2+d1)exp(k2t) - \ C3(b1k3+d1)exp(k3t) - C4(b1k4+d1)exp(k4t) + (Ra+ICa)exp(Iwt) a1_ = (a1-1) sol2 = C1(k1*2+a1_k1+c1)exp(k1t) + C2(k22+a1_k2+c1)exp(k2t) + \ C3(k32+a1_k3+c1)exp(k3t) + C4(k42+a1_k4+c1)exp(k4t) + (Rb+ICb)exp(Iwt) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type5(x, y, t, r, eq): r""" The equation which come under this category are .. math:: x'' = a (t y' - y) .. math:: y'' = b (t x' - x) The transformation .. math:: u = t x' - x, b = t y' - y leads to the first-order system .. math:: u' = atv, v' = btu The general solution of this system is given by If `ab > 0`: .. math:: u = C_1 a e^{\frac{1}{2} \sqrt{ab} t^2} + C_2 a e^{-\frac{1}{2} \sqrt{ab} t^2} .. math:: v = C_1 \sqrt{ab} e^{\frac{1}{2} \sqrt{ab} t^2} - C_2 \sqrt{ab} e^{-\frac{1}{2} \sqrt{ab} t^2} If `ab < 0`: .. math:: u = C_1 a \cos(\frac{1}{2} \sqrt{\left\|ab\right\|} t^2) + C_2 a \sin(-\frac{1}{2} \sqrt{\left\|ab\right\|} t^2) .. math:: v = C_1 \sqrt{\left\|ab\right\|} \sin(\frac{1}{2} \sqrt{\left\|ab\right\|} t^2) + C_2 \sqrt{\left\|ab\right\|} \cos(-\frac{1}{2} \sqrt{\left\|ab\right\|} t^2) where `C_1` and `C_2` are arbitrary constants. On substituting the value of `u` and `v` in above equations and integrating the resulting expressions, the general solution will become .. math:: x = C_3 t + t \int \frac{u}{t^2} \,dt, y = C_4 t + t \int \frac{u}{t^2} \,dt where `C_3` and `C_4` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) r['a'] = -r['d1'] ; r['b'] = -r['c2'] mul = sqrt(abs(r['a']r['b'])) if r['a']r['b'] > 0: u = C1r['a']exp(mult2/2) + C2r['a']exp(-mult*2/2) v = C1mulexp(mult*2/2) - C2mulexp(-mult*2/2) else: u = C1r['a']cos(mult*2/2) + C2r['a']sin(mult*2/2) v = -C1mulsin(mult*2/2) + C2mulcos(mult*2/2) sol1 = C3t + tIntegral(u/t2, t) sol2 = C4t + tIntegral(v/t2, t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type6(x, y, t, r, eq): r""" The equations are .. math:: x'' = f(t) (a_1 x + b_1 y) .. math:: y'' = f(t) (a_2 x + b_2 y) If `k_1` and `k_2` are roots of the quadratic equation .. math:: k^2 - (a_1 + b_2) k + a_1 b_2 - a_2 b_1 = 0 Then by multiplying appropriate constants and adding together original equations we obtain two independent equations: .. math:: z_1'' = k_1 f(t) z_1, z_1 = a_2 x + (k_1 - a_1) y .. math:: z_2'' = k_2 f(t) z_2, z_2 = a_2 x + (k_2 - a_1) y Solving the equations will give the values of `x` and `y` after obtaining the value of `z_1` and `z_2` by solving the differential equation and substituting the result. """ k = Symbol('k') z = Function('z') num, den = cancel( (r['c1']x(t) + r['d1']y(t))/ (r['c2']x(t) + r['d2']y(t))).as_numer_denom() f = r['c1']/num.coeff(x(t)) a1 = num.coeff(x(t)) b1 = num.coeff(y(t)) a2 = den.coeff(x(t)) b2 = den.coeff(y(t)) chareq = k2 - (a1 + b2)k + a1b2 - a2b1 k1, k2 = [rootof(chareq, k) for k in range(Poly(chareq).degree())] z1 = dsolve(diff(z(t),t,t) - k1fz(t)).rhs z2 = dsolve(diff(z(t),t,t) - k2fz(t)).rhs sol1 = (k1z2 - k2z1 + a1(z1 - z2))/(a2(k1-k2)) sol2 = (z1 - z2)/(k1 - k2) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type7(x, y, t, r, eq): r""" The equations are given as .. math:: x'' = f(t) (a_1 x' + b_1 y') .. math:: y'' = f(t) (a_2 x' + b_2 y') If `k_1` and 'k_2` are roots of the quadratic equation .. math:: k^2 - (a_1 + b_2) k + a_1 b_2 - a_2 b_1 = 0 Then the system can be reduced by adding together the two equations multiplied by appropriate constants give following two independent equations: .. math:: z_1'' = k_1 f(t) z_1', z_1 = a_2 x + (k_1 - a_1) y .. math:: z_2'' = k_2 f(t) z_2', z_2 = a_2 x + (k_2 - a_1) y Integrating these and returning to the original variables, one arrives at a linear algebraic system for the unknowns `x` and `y`: .. math:: a_2 x + (k_1 - a_1) y = C_1 \int e^{k_1 F(t)} \,dt + C_2 .. math:: a_2 x + (k_2 - a_1) y = C_3 \int e^{k_2 F(t)} \,dt + C_4 where `C_1,...,C_4` are arbitrary constants and `F(t) = \int f(t) \,dt` """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) k = Symbol('k') num, den = cancel( (r['a1']x(t) + r['b1']y(t))/ (r['a2']x(t) + r['b2']y(t))).as_numer_denom() f = r['a1']/num.coeff(x(t)) a1 = num.coeff(x(t)) b1 = num.coeff(y(t)) a2 = den.coeff(x(t)) b2 = den.coeff(y(t)) chareq = k*2 - (a1 + b2)k + a1b2 - a2b1 [k1, k2] = [rootof(chareq, k) for k in range(Poly(chareq).degree())] F = Integral(f, t) z1 = C1Integral(exp(k1F), t) + C2 z2 = C3Integral(exp(k2F), t) + C4 sol1 = (k1z2 - k2z1 + a1(z1 - z2))/(a2(k1-k2)) sol2 = (z1 - z2)/(k1 - k2) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type8(x, y, t, r, eq): r""" The equation of this category are .. math:: x'' = a f(t) (t y' - y) .. math:: y'' = b f(t) (t x' - x) The transformation .. math:: u = t x' - x, v = t y' - y leads to the system of first-order equations .. math:: u' = a t f(t) v, v' = b t f(t) u The general solution of this system has the form If `ab > 0`: .. math:: u = C_1 a e^{\sqrt{ab} \int t f(t) \,dt} + C_2 a e^{-\sqrt{ab} \int t f(t) \,dt} .. math:: v = C_1 \sqrt{ab} e^{\sqrt{ab} \int t f(t) \,dt} - C_2 \sqrt{ab} e^{-\sqrt{ab} \int t f(t) \,dt} If `ab < 0`: .. math:: u = C_1 a \cos(\sqrt{\left\|ab\right\|} \int t f(t) \,dt) + C_2 a \sin(-\sqrt{\left\|ab\right\|} \int t f(t) \,dt) .. math:: v = C_1 \sqrt{\left\|ab\right\|} \sin(\sqrt{\left\|ab\right\|} \int t f(t) \,dt) + C_2 \sqrt{\left\|ab\right\|} \cos(-\sqrt{\left\|ab\right\|} \int t f(t) \,dt) where `C_1` and `C_2` are arbitrary constants. On substituting the value of `u` and `v` in above equations and integrating the resulting expressions, the general solution will become .. math:: x = C_3 t + t \int \frac{u}{t^2} \,dt, y = C_4 t + t \int \frac{u}{t^2} \,dt where `C_3` and `C_4` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) num, den = cancel(r['d1']/r['c2']).as_numer_denom() f = -r['d1']/num a = num b = den mul = sqrt(abs(ab)) Igral = Integral(tf, t) if ab > 0: u = C1aexp(mulIgral) + C2aexp(-mulIgral) v = C1mulexp(mulIgral) - C2mulexp(-mulIgral) else: u = C1acos(mulIgral) + C2asin(mulIgral) v = -C1mulsin(mulIgral) + C2mulcos(mulIgral) sol1 = C3t + tIntegral(u/t2, t) sol2 = C4t + tIntegral(v/t2, t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type9(x, y, t, r, eq): r""" .. math:: t^2 x'' + a_1 t x' + b_1 t y' + c_1 x + d_1 y = 0 .. math:: t^2 y'' + a_2 t x' + b_2 t y' + c_2 x + d_2 y = 0 These system of equations are euler type. The substitution of `t = \sigma e^{\tau} (\sigma \neq 0)` leads to the system of constant coefficient linear differential equations .. math:: x'' + (a_1 - 1) x' + b_1 y' + c_1 x + d_1 y = 0 .. math:: y'' + a_2 x' + (b_2 - 1) y' + c_2 x + d_2 y = 0 The general solution of the homogeneous system of differential equations is determined by a linear combination of linearly independent particular solutions determined by the method of undetermined coefficients in the form of exponentials .. math:: x = A e^{\lambda t}, y = B e^{\lambda t} On substituting these expressions into the original system and collecting the coefficients of the unknown `A` and `B`, one obtains .. math:: (\lambda^{2} + (a_1 - 1) \lambda + c_1) A + (b_1 \lambda + d_1) B = 0 .. math:: (a_2 \lambda + c_2) A + (\lambda^{2} + (b_2 - 1) \lambda + d_2) B = 0 The determinant of this system must vanish for nontrivial solutions A, B to exist. This requirement results in the following characteristic equation for `\lambda` .. math:: (\lambda^2 + (a_1 - 1) \lambda + c_1) (\lambda^2 + (b_2 - 1) \lambda + d_2) - (b_1 \lambda + d_1) (a_2 \lambda + c_2) = 0 If all roots `k_1,...,k_4` of this equation are distinct, the general solution of the original system of the differential equations has the form .. math:: x = C_1 (b_1 \lambda_1 + d_1) e^{\lambda_1 t} - C_2 (b_1 \lambda_2 + d_1) e^{\lambda_2 t} - C_3 (b_1 \lambda_3 + d_1) e^{\lambda_3 t} - C_4 (b_1 \lambda_4 + d_1) e^{\lambda_4 t} .. math:: y = C_1 (\lambda_1^{2} + (a_1 - 1) \lambda_1 + c_1) e^{\lambda_1 t} + C_2 (\lambda_2^{2} + (a_1 - 1) \lambda_2 + c_1) e^{\lambda_2 t} + C_3 (\lambda_3^{2} + (a_1 - 1) \lambda_3 + c_1) e^{\lambda_3 t} + C_4 (\lambda_4^{2} + (a_1 - 1) \lambda_4 + c_1) e^{\lambda_4 t} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) k = Symbol('k') a1 = -r['a1']t; a2 = -r['a2']t b1 = -r['b1']t; b2 = -r['b2']t c1 = -r['c1']t*2; c2 = -r['c2']t*2 d1 = -r['d1']t*2; d2 = -r['d2']t2 eq = (k2+(a1-1)k+c1)(k*2+(b2-1)k+d2)-(b1k+d1)(a2k+c2) [k1, k2, k3, k4] = roots_quartic(Poly(eq)) sol1 = -C1(b1k1+d1)exp(k1log(t)) - C2(b1k2+d1)exp(k2log(t)) - \ C3(b1k3+d1)exp(k3log(t)) - C4(b1k4+d1)exp(k4log(t)) a1_ = (a1-1) sol2 = C1(k1*2+a1_k1+c1)exp(k1log(t)) + C2(k22+a1_k2+c1)exp(k2log(t)) \ + C3(k32+a1_k3+c1)exp(k3log(t)) + C4(k42+a1_k4+c1)exp(k4log(t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type10(x, y, t, r, eq): r""" The equation of this category are .. math:: (\alpha t^2 + \beta t + \gamma)^{2} x'' = ax + by .. math:: (\alpha t^2 + \beta t + \gamma)^{2} y'' = cx + dy The transformation .. math:: \tau = \int \frac{1}{\alpha t^2 + \beta t + \gamma} \,dt , u = \frac{x}{\sqrt{\left\|\alpha t^2 + \beta t + \gamma\right\|}} , v = \frac{y}{\sqrt{\left\|\alpha t^2 + \beta t + \gamma\right\|}} leads to a constant coefficient linear system of equations .. math:: u'' = (a - \alpha \gamma + \frac{1}{4} \beta^{2}) u + b v .. math:: v'' = c u + (d - \alpha \gamma + \frac{1}{4} \beta^{2}) v These system of equations obtained can be solved by type1 of System of two constant-coefficient second-order linear homogeneous differential equations. """ u, v = symbols('u, v', cls=Function) assert False p = Wild('p', exclude=[t, t2]) q = Wild('q', exclude=[t, t2]) s = Wild('s', exclude=[t, t2]) n = Wild('n', exclude=[t, t2]) num, den = r['c1'].as_numer_denom() dic = den.match((n(pt*2+qt+s)*2).expand()) eqz = dic[p]t*2 + dic[q]t + dic[s] a = num/dic[n] b = cancel(r['d1']eqz2) c = cancel(r['c2']eqz*2) d = cancel(r['d2']eqz*2) [msol1, msol2] = dsolve([Eq(diff(u(t), t, t), (a - dic[p]dic[s] + dic[q]*2/4)u(t) \ + bv(t)), Eq(diff(v(t),t,t), cu(t) + (d - dic[p]dic[s] + dic[q]2/4)v(t))]) sol1 = (msol1.rhssqrt(abs(eqz))).subs(t, Integral(1/eqz, t)) sol2 = (msol2.rhssqrt(abs(eqz))).subs(t, Integral(1/eqz, t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type11(x, y, t, r, eq): r""" The equations which comes under this type are .. math:: x'' = f(t) (t x' - x) + g(t) (t y' - y) .. math:: y'' = h(t) (t x' - x) + p(t) (t y' - y) The transformation .. math:: u = t x' - x, v = t y' - y leads to the linear system of first-order equations .. math:: u' = t f(t) u + t g(t) v, v' = t h(t) u + t p(t) v On substituting the value of `u` and `v` in transformed equation gives value of `x` and `y` as .. math:: x = C_3 t + t \int \frac{u}{t^2} \,dt , y = C_4 t + t \int \frac{v}{t^2} \,dt. where `C_3` and `C_4` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) u, v = symbols('u, v', cls=Function) f = -r['c1'] ; g = -r['d1'] h = -r['c2'] ; p = -r['d2'] [msol1, msol2] = dsolve([Eq(diff(u(t),t), tfu(t) + tgv(t)), Eq(diff(v(t),t), thu(t) + tpv(t))]) sol1 = C3t + tIntegral(msol1.rhs/t*2, t) sol2 = C4t + tIntegral(msol2.rhs/t2, t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def sysode_linear_3eq_order1(match_): x = match_['func'][0].func y = match_['func'][1].func z = match_['func'][2].func func = match_['func'] fc = match_['func_coeff'] eq = match_['eq'] r = dict() t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] for i in range(3): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs # for equations: # Eq(g1diff(x(t),t), a1x(t)+b1y(t)+c1z(t)+d1), # Eq(g2diff(y(t),t), a2x(t)+b2y(t)+c2z(t)+d2), and # Eq(g3diff(z(t),t), a3x(t)+b3y(t)+c3z(t)+d3) r['a1'] = fc[0,x(t),0]/fc[0,x(t),1]; r['a2'] = fc[1,x(t),0]/fc[1,y(t),1]; r['a3'] = fc[2,x(t),0]/fc[2,z(t),1] r['b1'] = fc[0,y(t),0]/fc[0,x(t),1]; r['b2'] = fc[1,y(t),0]/fc[1,y(t),1]; r['b3'] = fc[2,y(t),0]/fc[2,z(t),1] r['c1'] = fc[0,z(t),0]/fc[0,x(t),1]; r['c2'] = fc[1,z(t),0]/fc[1,y(t),1]; r['c3'] = fc[2,z(t),0]/fc[2,z(t),1] for i in range(3): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t), z(t)): raise NotImplementedError("Only homogeneous problems are supported, non-homogenous are not supported currently.") if match_['type_of_equation'] == 'type1': sol = _linear_3eq_order1_type1(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type2': sol = _linear_3eq_order1_type2(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type3': sol = _linear_3eq_order1_type3(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type4': sol = _linear_3eq_order1_type4(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type6': sol = _linear_neq_order1_type1(match_) return sol def _linear_3eq_order1_type1(x, y, z, t, r, eq): r""" .. math:: x' = ax .. math:: y' = bx + cy .. math:: z' = dx + ky + pz Solution of such equations are forward substitution. Solving first equations gives the value of `x`, substituting it in second and third equation and solving second equation gives `y` and similarly substituting `y` in third equation give `z`. .. math:: x = C_1 e^{at} .. math:: y = \frac{b C_1}{a - c} e^{at} + C_2 e^{ct} .. math:: z = \frac{C_1}{a - p} (d + \frac{bk}{a - c}) e^{at} + \frac{k C_2}{c - p} e^{ct} + C_3 e^{pt} where `C_1, C_2` and `C_3` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) a = -r['a1']; b = -r['a2']; c = -r['b2'] d = -r['a3']; k = -r['b3']; p = -r['c3'] sol1 = C1exp(at) sol2 = bC1exp(at)/(a-c) + C2exp(ct) sol3 = C1(d+bk/(a-c))exp(at)/(a-p) + kC2exp(ct)/(c-p) + C3exp(pt) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def _linear_3eq_order1_type2(x, y, z, t, r, eq): r""" The equations of this type are .. math:: x' = cy - bz .. math:: y' = az - cx .. math:: z' = bx - ay 1. First integral: .. math:: ax + by + cz = A \qquad - (1) .. math:: x^2 + y^2 + z^2 = B^2 \qquad - (2) where `A` and `B` are arbitrary constants. It follows from these integrals that the integral lines are circles formed by the intersection of the planes `(1)` and sphere `(2)` 2. Solution: .. math:: x = a C_0 + k C_1 \cos(kt) + (c C_2 - b C_3) \sin(kt) .. math:: y = b C_0 + k C_2 \cos(kt) + (a C_2 - c C_3) \sin(kt) .. math:: z = c C_0 + k C_3 \cos(kt) + (b C_2 - a C_3) \sin(kt) where `k = \sqrt{a^2 + b^2 + c^2}` and the four constants of integration, `C_1,...,C_4` are constrained by a single relation, .. math:: a C_1 + b C_2 + c C_3 = 0 """ C0, C1, C2, C3 = get_numbered_constants(eq, num=4, start=0) a = -r['c2']; b = -r['a3']; c = -r['b1'] k = sqrt(a2 + b2 + c2) C3 = (-aC1 - bC2)/c sol1 = aC0 + kC1cos(kt) + (cC2-bC3)sin(kt) sol2 = bC0 + kC2cos(kt) + (aC3-cC1)sin(kt) sol3 = cC0 + kC3cos(kt) + (bC1-aC2)sin(kt) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def _linear_3eq_order1_type3(x, y, z, t, r, eq): r""" Equations of this system of ODEs .. math:: a x' = bc (y - z) .. math:: b y' = ac (z - x) .. math:: c z' = ab (x - y) 1. First integral: .. math:: a^2 x + b^2 y + c^2 z = A where A is an arbitrary constant. It follows that the integral lines are plane curves. 2. Solution: .. math:: x = C_0 + k C_1 \cos(kt) + a^{-1} bc (C_2 - C_3) \sin(kt) .. math:: y = C_0 + k C_2 \cos(kt) + a b^{-1} c (C_3 - C_1) \sin(kt) .. math:: z = C_0 + k C_3 \cos(kt) + ab c^{-1} (C_1 - C_2) \sin(kt) where `k = \sqrt{a^2 + b^2 + c^2}` and the four constants of integration, `C_1,...,C_4` are constrained by a single relation .. math:: a^2 C_1 + b^2 C_2 + c^2 C_3 = 0 """ C0, C1, C2, C3 = get_numbered_constants(eq, num=4, start=0) c = sqrt(r['b1']r['c2']) b = sqrt(r['b1']r['a3']) a = sqrt(r['c2']r['a3']) C3 = (-a*2C1-b*2C2)/c2 k = sqrt(a2 + b2 + c2) sol1 = C0 + kC1cos(kt) + a-1bc(C2-C3)sin(kt) sol2 = C0 + kC2cos(kt) + ab*-1c(C3-C1)sin(kt) sol3 = C0 + kC3cos(kt) + abc*-1(C1-C2)sin(kt) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def _linear_3eq_order1_type4(x, y, z, t, r, eq): r""" Equations: .. math:: x' = (a_1 f(t) + g(t)) x + a_2 f(t) y + a_3 f(t) z .. math:: y' = b_1 f(t) x + (b_2 f(t) + g(t)) y + b_3 f(t) z .. math:: z' = c_1 f(t) x + c_2 f(t) y + (c_3 f(t) + g(t)) z The transformation .. math:: x = e^{\int g(t) \,dt} u, y = e^{\int g(t) \,dt} v, z = e^{\int g(t) \,dt} w, \tau = \int f(t) \,dt leads to the system of constant coefficient linear differential equations .. math:: u' = a_1 u + a_2 v + a_3 w .. math:: v' = b_1 u + b_2 v + b_3 w .. math:: w' = c_1 u + c_2 v + c_3 w These system of equations are solved by homogeneous linear system of constant coefficients of `n` equations of first order. Then substituting the value of `u, v` and `w` in transformed equation gives value of `x, y` and `z`. """ u, v, w = symbols('u, v, w', cls=Function) a2, a3 = cancel(r['b1']/r['c1']).as_numer_denom() f = cancel(r['b1']/a2) b1 = cancel(r['a2']/f); b3 = cancel(r['c2']/f) c1 = cancel(r['a3']/f); c2 = cancel(r['b3']/f) a1, g = div(r['a1'],f) b2 = div(r['b2'],f)[0] c3 = div(r['c3'],f)[0] trans_eq = (diff(u(t),t)-a1u(t)-a2v(t)-a3w(t), diff(v(t),t)-b1u(t)-\ b2v(t)-b3w(t), diff(w(t),t)-c1u(t)-c2v(t)-c3w(t)) sol = dsolve(trans_eq) sol1 = exp(Integral(g,t))((sol[0].rhs).subs(t, Integral(f,t))) sol2 = exp(Integral(g,t))((sol[1].rhs).subs(t, Integral(f,t))) sol3 = exp(Integral(g,t))((sol[2].rhs).subs(t, Integral(f,t))) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def sysode_linear_neq_order1(match_): sol = _linear_neq_order1_type1(match_) return sol def _linear_neq_order1_type1(match_): r""" System of n first-order constant-coefficient linear nonhomogeneous differential equation .. math:: y'_k = a_{k1} y_1 + a_{k2} y_2 +...+ a_{kn} y_n; k = 1,2,...,n or that can be written as `\vec{y'} = A . \vec{y}` where `\vec{y}` is matrix of `y_k` for `k = 1,2,...n` and `A` is a `n \times n` matrix. Since these equations are equivalent to a first order homogeneous linear differential equation. So the general solution will contain `n` linearly independent parts and solution will consist some type of exponential functions. Assuming `y = \vec{v} e^{rt}` is a solution of the system where `\vec{v}` is a vector of coefficients of `y_1,...,y_n`. Substituting `y` and `y' = r v e^{r t}` into the equation `\vec{y'} = A . \vec{y}`, we get .. math:: r \vec{v} e^{rt} = A \vec{v} e^{rt} .. math:: r \vec{v} = A \vec{v} where `r` comes out to be eigenvalue of `A` and vector `\vec{v}` is the eigenvector of `A` corresponding to `r`. There are three possibilities of eigenvalues of `A` - `n` distinct real eigenvalues - complex conjugate eigenvalues - eigenvalues with multiplicity `k` 1. When all eigenvalues `r_1,..,r_n` are distinct with `n` different eigenvectors `v_1,...v_n` then the solution is given by .. math:: \vec{y} = C_1 e^{r_1 t} \vec{v_1} + C_2 e^{r_2 t} \vec{v_2} +...+ C_n e^{r_n t} \vec{v_n} where `C_1,C_2,...,C_n` are arbitrary constants. 2. When some eigenvalues are complex then in order to make the solution real, we take a linear combination: if `r = a + bi` has an eigenvector `\vec{v} = \vec{w_1} + i \vec{w_2}` then to obtain real-valued solutions to the system, replace the complex-valued solutions `e^{rx} \vec{v}` with real-valued solution `e^{ax} (\vec{w_1} \cos(bx) - \vec{w_2} \sin(bx))` and for `r = a - bi` replace the solution `e^{-r x} \vec{v}` with `e^{ax} (\vec{w_1} \sin(bx) + \vec{w_2} \cos(bx))` 3. If some eigenvalues are repeated. Then we get fewer than `n` linearly independent eigenvectors, we miss some of the solutions and need to construct the missing ones. We do this via generalized eigenvectors, vectors which are not eigenvectors but are close enough that we can use to write down the remaining solutions. For a eigenvalue `r` with eigenvector `\vec{w}` we obtain `\vec{w_2},...,\vec{w_k}` using .. math:: (A - r I) . \vec{w_2} = \vec{w} .. math:: (A - r I) . \vec{w_3} = \vec{w_2} .. math:: \vdots .. math:: (A - r I) . \vec{w_k} = \vec{w_{k-1}} Then the solutions to the system for the eigenspace are `e^{rt} [\vec{w}], e^{rt} [t \vec{w} + \vec{w_2}], e^{rt} [\frac{t^2}{2} \vec{w} + t \vec{w_2} + \vec{w_3}], ...,e^{rt} [\frac{t^{k-1}}{(k-1)!} \vec{w} + \frac{t^{k-2}}{(k-2)!} \vec{w_2} +...+ t \vec{w_{k-1}} + \vec{w_k}]` So, If `\vec{y_1},...,\vec{y_n}` are `n` solution of obtained from three categories of `A`, then general solution to the system `\vec{y'} = A . \vec{y}` .. math:: \vec{y} = C_1 \vec{y_1} + C_2 \vec{y_2} + \cdots + C_n \vec{y_n} """ eq = match_['eq'] func = match_['func'] fc = match_['func_coeff'] n = len(eq) t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] constants = numbered_symbols(prefix='C', cls=Symbol, start=1) M = Matrix(n,n,lambda i,j:-fc[i,func[j],0]) evector = M.eigenvects(simplify=True) def is_complex(mat, root): return Matrix(n, 1, lambda i,j: re(mat[i])cos(im(root)t) - im(mat[i])sin(im(root)t)) def is_complex_conjugate(mat, root): return Matrix(n, 1, lambda i,j: re(mat[i])sin(abs(im(root))t) + im(mat[i])cos(im(root)t)abs(im(root))/im(root)) conjugate_root = [] e_vector = zeros(n,1) for evects in evector: if evects[0] not in conjugate_root: # If number of column of an eigenvector is not equal to the multiplicity # of its eigenvalue then the legt eigenvectors are calculated if len(evects[2])!=evects[1]: var_mat = Matrix(n, 1, lambda i,j: Symbol('x'+str(i))) Mnew = (M - evects[0]eye(evects[2][-1].rows))var_mat w = [0 for i in range(evects[1])] w[0] = evects[2][-1] for r in range(1, evects[1]): w_ = Mnew - w[r-1] sol_dict = solve(list(w_), var_mat[1:]) sol_dict[var_mat[0]] = var_mat[0] for key, value in sol_dict.items(): sol_dict[key] = value.subs(var_mat[0],1) w[r] = Matrix(n, 1, lambda i,j: sol_dict[var_mat[i]]) evects[2].append(w[r]) for i in range(evects[1]): C = next(constants) for j in range(i+1): if evects[0].has(I): evects[2][j] = simplify(evects[2][j]) e_vector += Cis_complex(evects[2][j], evects[0])t(i-j)exp(re(evects[0])t)/factorial(i-j) C = next(constants) e_vector += Cis_complex_conjugate(evects[2][j], evects[0])t(i-j)exp(re(evects[0])t)/factorial(i-j) else: e_vector += Cevects[2][j]t(i-j)exp(evects[0]t)/factorial(i-j) if evects[0].has(I): conjugate_root.append(conjugate(evects[0])) sol = [] for i in range(len(eq)): sol.append(Eq(func[i],e_vector[i])) return sol def sysode_nonlinear_2eq_order1(match_): func = match_['func'] eq = match_['eq'] fc = match_['func_coeff'] t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] if match_['type_of_equation'] == 'type5': sol = _nonlinear_2eq_order1_type5(func, t, eq) return sol x = func[0].func y = func[1].func for i in range(2): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs if match_['type_of_equation'] == 'type1': sol = _nonlinear_2eq_order1_type1(x, y, t, eq) elif match_['type_of_equation'] == 'type2': sol = _nonlinear_2eq_order1_type2(x, y, t, eq) elif match_['type_of_equation'] == 'type3': sol = _nonlinear_2eq_order1_type3(x, y, t, eq) elif match_['type_of_equation'] == 'type4': sol = _nonlinear_2eq_order1_type4(x, y, t, eq) return sol def _nonlinear_2eq_order1_type1(x, y, t, eq): r""" Equations: .. math:: x' = x^n F(x,y) .. math:: y' = g(y) F(x,y) Solution: .. math:: x = \varphi(y), \int \frac{1}{g(y) F(\varphi(y),y)} \,dy = t + C_2 where if `n \neq 1` .. math:: \varphi = [C_1 + (1-n) \int \frac{1}{g(y)} \,dy]^{\frac{1}{1-n}} if `n = 1` .. math:: \varphi = C_1 e^{\int \frac{1}{g(y)} \,dy} where `C_1` and `C_2` are arbitrary constants. """ C1, C2 = get_numbered_constants(eq, num=2) n = Wild('n', exclude=[x(t),y(t)]) f = Wild('f') u, v = symbols('u, v') r = eq[0].match(diff(x(t),t) - x(t)nf) g = ((diff(y(t),t) - eq[1])/r[f]).subs(y(t),v) F = r[f].subs(x(t),u).subs(y(t),v) n = r[n] if n!=1: phi = (C1 + (1-n)Integral(1/g, v))(1/(1-n)) else: phi = C1exp(Integral(1/g, v)) phi = phi.doit() sol2 = solve(Integral(1/(gF.subs(u,phi)), v).doit() - t - C2, v) sol = [] for sols in sol2: sol.append(Eq(x(t),phi.subs(v, sols))) sol.append(Eq(y(t), sols)) return sol def _nonlinear_2eq_order1_type2(x, y, t, eq): r""" Equations: .. math:: x' = e^{\lambda x} F(x,y) .. math:: y' = g(y) F(x,y) Solution: .. math:: x = \varphi(y), \int \frac{1}{g(y) F(\varphi(y),y)} \,dy = t + C_2 where if `\lambda \neq 0` .. math:: \varphi = -\frac{1}{\lambda} log(C_1 - \lambda \int \frac{1}{g(y)} \,dy) if `\lambda = 0` .. math:: \varphi = C_1 + \int \frac{1}{g(y)} \,dy where `C_1` and `C_2` are arbitrary constants. """ C1, C2 = get_numbered_constants(eq, num=2) n = Wild('n', exclude=[x(t),y(t)]) f = Wild('f') u, v = symbols('u, v') r = eq[0].match(diff(x(t),t) - exp(nx(t))f) g = ((diff(y(t),t) - eq[1])/r[f]).subs(y(t),v) F = r[f].subs(x(t),u).subs(y(t),v) n = r[n] if n: phi = -1/nlog(C1 - nIntegral(1/g, v)) else: phi = C1 + Integral(1/g, v) phi = phi.doit() sol2 = solve(Integral(1/(gF.subs(u,phi)), v).doit() - t - C2, v) sol = [] for sols in sol2: sol.append(Eq(x(t),phi.subs(v, sols))) sol.append(Eq(y(t), sols)) return sol def _nonlinear_2eq_order1_type3(x, y, t, eq): r""" Autonomous system of general form .. math:: x' = F(x,y) .. math:: y' = G(x,y) Assuming `y = y(x, C_1)` where `C_1` is an arbitrary constant is the general solution of the first-order equation .. math:: F(x,y) y'_x = G(x,y) Then the general solution of the original system of equations has the form .. math:: \int \frac{1}{F(x,y(x,C_1))} \,dx = t + C_1 """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) v = Function('v') u = Symbol('u') f = Wild('f') g = Wild('g') r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) F = r1[f].subs(x(t), u).subs(y(t), v(u)) G = r2[g].subs(x(t), u).subs(y(t), v(u)) sol2r = dsolve(Eq(diff(v(u), u), G/F)) for sol2s in sol2r: sol1 = solve(Integral(1/F.subs(v(u), sol2s.rhs), u).doit() - t - C2, u) sol = [] for sols in sol1: sol.append(Eq(x(t), sols)) sol.append(Eq(y(t), (sol2s.rhs).subs(u, sols))) return sol def _nonlinear_2eq_order1_type4(x, y, t, eq): r""" Equation: .. math:: x' = f_1(x) g_1(y) \phi(x,y,t) .. math:: y' = f_2(x) g_2(y) \phi(x,y,t) First integral: .. math:: \int \frac{f_2(x)}{f_1(x)} \,dx - \int \frac{g_1(y)}{g_2(y)} \,dy = C where `C` is an arbitrary constant. On solving the first integral for `x` (resp., `y` ) and on substituting the resulting expression into either equation of the original solution, one arrives at a first-order equation for determining `y` (resp., `x` ). """ C1, C2 = get_numbered_constants(eq, num=2) u, v = symbols('u, v') U, V = symbols('U, V', cls=Function) f = Wild('f') g = Wild('g') f1 = Wild('f1', exclude=[v,t]) f2 = Wild('f2', exclude=[v,t]) g1 = Wild('g1', exclude=[u,t]) g2 = Wild('g2', exclude=[u,t]) r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) num, den = ( (r1[f].subs(x(t),u).subs(y(t),v))/ (r2[g].subs(x(t),u).subs(y(t),v))).as_numer_denom() R1 = num.match(f1g1) R2 = den.match(f2g2) phi = (r1[f].subs(x(t),u).subs(y(t),v))/num F1 = R1[f1]; F2 = R2[f2] G1 = R1[g1]; G2 = R2[g2] sol1r = solve(Integral(F2/F1, u).doit() - Integral(G1/G2,v).doit() - C1, u) sol2r = solve(Integral(F2/F1, u).doit() - Integral(G1/G2,v).doit() - C1, v) sol = [] for sols in sol1r: sol.append(Eq(y(t), dsolve(diff(V(t),t) - F2.subs(u,sols).subs(v,V(t))G2.subs(v,V(t))phi.subs(u,sols).subs(v,V(t))).rhs)) for sols in sol2r: sol.append(Eq(x(t), dsolve(diff(U(t),t) - F1.subs(u,U(t))G1.subs(v,sols).subs(u,U(t))phi.subs(v,sols).subs(u,U(t))).rhs)) return set(sol) def _nonlinear_2eq_order1_type5(func, t, eq): r""" Clairaut system of ODEs .. math:: x = t x' + F(x',y') .. math:: y = t y' + G(x',y') The following are solutions of the system `(i)` straight lines: .. math:: x = C_1 t + F(C_1, C_2), y = C_2 t + G(C_1, C_2) where `C_1` and `C_2` are arbitrary constants; `(ii)` envelopes of the above lines; `(iii)` continuously differentiable lines made up from segments of the lines `(i)` and `(ii)`. """ C1, C2 = get_numbered_constants(eq, num=2) f = Wild('f') g = Wild('g') def check_type(x, y): r1 = eq[0].match(tdiff(x(t),t) - x(t) + f) r2 = eq[1].match(tdiff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = eq[0].match(diff(x(t),t) - x(t)/t + f/t) r2 = eq[1].match(diff(y(t),t) - y(t)/t + g/t) if not (r1 and r2): r1 = (-eq[0]).match(tdiff(x(t),t) - x(t) + f) r2 = (-eq[1]).match(tdiff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = (-eq[0]).match(diff(x(t),t) - x(t)/t + f/t) r2 = (-eq[1]).match(diff(y(t),t) - y(t)/t + g/t) return [r1, r2] for func_ in func: if isinstance(func_, list): x = func[0][0].func y = func[0][1].func [r1, r2] = check_type(x, y) if not (r1 and r2): [r1, r2] = check_type(y, x) x, y = y, x x1 = diff(x(t),t); y1 = diff(y(t),t) return {Eq(x(t), C1t + r1[f].subs(x1,C1).subs(y1,C2)), Eq(y(t), C2t + r2[g].subs(x1,C1).subs(y1,C2))} def sysode_nonlinear_3eq_order1(match_): x = match_['func'][0].func y = match_['func'][1].func z = match_['func'][2].func eq = match_['eq'] t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] if match_['type_of_equation'] == 'type1': sol = _nonlinear_3eq_order1_type1(x, y, z, t, eq) if match_['type_of_equation'] == 'type2': sol = _nonlinear_3eq_order1_type2(x, y, z, t, eq) if match_['type_of_equation'] == 'type3': sol = _nonlinear_3eq_order1_type3(x, y, z, t, eq) if match_['type_of_equation'] == 'type4': sol = _nonlinear_3eq_order1_type4(x, y, z, t, eq) if match_['type_of_equation'] == 'type5': sol = _nonlinear_3eq_order1_type5(x, y, z, t, eq) return sol def _nonlinear_3eq_order1_type1(x, y, z, t, eq): r""" Equations: .. math:: a x' = (b - c) y z, \enspace b y' = (c - a) z x, \enspace c z' = (a - b) x y First Integrals: .. math:: a x^{2} + b y^{2} + c z^{2} = C_1 .. math:: a^{2} x^{2} + b^{2} y^{2} + c^{2} z^{2} = C_2 where `C_1` and `C_2` are arbitrary constants. On solving the integrals for `y` and `z` and on substituting the resulting expressions into the first equation of the system, we arrives at a separable first-order equation on `x`. Similarly doing that for other two equations, we will arrive at first order equation on `y` and `z` too. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0401.pdf """ C1, C2 = get_numbered_constants(eq, num=2) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) r = (diff(x(t),t) - eq[0]).match(py(t)z(t)) r.update((diff(y(t),t) - eq[1]).match(qz(t)x(t))) r.update((diff(z(t),t) - eq[2]).match(sx(t)y(t))) n1, d1 = r[p].as_numer_denom() n2, d2 = r[q].as_numer_denom() n3, d3 = r[s].as_numer_denom() val = solve([n1u-d1v+d1w, d2u+n2v-d2w, d3u-d3v-n3w],[u,v]) vals = [val[v], val[u]] c = lcm(vals[0].as_numer_denom()[1], vals[1].as_numer_denom()[1]) b = vals[0].subs(w, c) a = vals[1].subs(w, c) y_x = sqrt(((cC1-C2) - a(c-a)x(t)*2)/(b(c-b))) z_x = sqrt(((bC1-C2) - a(b-a)x(t)2)/(c(b-c))) z_y = sqrt(((aC1-C2) - b(a-b)y(t)2)/(c(a-c))) x_y = sqrt(((cC1-C2) - b(c-b)y(t)2)/(a(c-a))) x_z = sqrt(((bC1-C2) - c(b-c)z(t)2)/(a(b-a))) y_z = sqrt(((aC1-C2) - c(a-c)z(t)2)/(b(a-b))) sol1 = dsolve(adiff(x(t),t) - (b-c)y_xz_x) sol2 = dsolve(bdiff(y(t),t) - (c-a)z_yx_y) sol3 = dsolve(cdiff(z(t),t) - (a-b)x_zy_z) return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type2(x, y, z, t, eq): r""" Equations: .. math:: a x' = (b - c) y z f(x, y, z, t) .. math:: b y' = (c - a) z x f(x, y, z, t) .. math:: c z' = (a - b) x y f(x, y, z, t) First Integrals: .. math:: a x^{2} + b y^{2} + c z^{2} = C_1 .. math:: a^{2} x^{2} + b^{2} y^{2} + c^{2} z^{2} = C_2 where `C_1` and `C_2` are arbitrary constants. On solving the integrals for `y` and `z` and on substituting the resulting expressions into the first equation of the system, we arrives at a first-order differential equations on `x`. Similarly doing that for other two equations we will arrive at first order equation on `y` and `z`. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0402.pdf """ C1, C2 = get_numbered_constants(eq, num=2) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) f = Wild('f') r1 = (diff(x(t),t) - eq[0]).match(y(t)z(t)f) r = collect_const(r1[f]).match(pf) r.update(((diff(y(t),t) - eq[1])/r[f]).match(qz(t)x(t))) r.update(((diff(z(t),t) - eq[2])/r[f]).match(sx(t)y(t))) n1, d1 = r[p].as_numer_denom() n2, d2 = r[q].as_numer_denom() n3, d3 = r[s].as_numer_denom() val = solve([n1u-d1v+d1w, d2u+n2v-d2w, -d3u+d3v+n3w],[u,v]) vals = [val[v], val[u]] c = lcm(vals[0].as_numer_denom()[1], vals[1].as_numer_denom()[1]) a = vals[0].subs(w, c) b = vals[1].subs(w, c) y_x = sqrt(((cC1-C2) - a(c-a)x(t)*2)/(b(c-b))) z_x = sqrt(((bC1-C2) - a(b-a)x(t)2)/(c(b-c))) z_y = sqrt(((aC1-C2) - b(a-b)y(t)2)/(c(a-c))) x_y = sqrt(((cC1-C2) - b(c-b)y(t)2)/(a(c-a))) x_z = sqrt(((bC1-C2) - c(b-c)z(t)2)/(a(b-a))) y_z = sqrt(((aC1-C2) - c(a-c)z(t)2)/(b(a-b))) sol1 = dsolve(adiff(x(t),t) - (b-c)y_xz_xr[f]) sol2 = dsolve(bdiff(y(t),t) - (c-a)z_yx_yr[f]) sol3 = dsolve(cdiff(z(t),t) - (a-b)x_zy_zr[f]) return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type3(x, y, z, t, eq): r""" Equations: .. math:: x' = c F_2 - b F_3, \enspace y' = a F_3 - c F_1, \enspace z' = b F_1 - a F_2 where `F_n = F_n(x, y, z, t)`. 1. First Integral: .. math:: a x + b y + c z = C_1, where C is an arbitrary constant. 2. If we assume function `F_n` to be independent of `t`,i.e, `F_n` = `F_n (x, y, z)` Then, on eliminating `t` and `z` from the first two equation of the system, one arrives at the first-order equation .. math:: \frac{dy}{dx} = \frac{a F_3 (x, y, z) - c F_1 (x, y, z)}{c F_2 (x, y, z) - b F_3 (x, y, z)} where `z = \frac{1}{c} (C_1 - a x - b y)` References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0404.pdf """ C1 = get_numbered_constants(eq, num=1) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) F1, F2, F3 = symbols('F1, F2, F3', cls=Wild) r1 = (diff(x(t), t) - eq[0]).match(F2-F3) r = collect_const(r1[F2]).match(sF2) r.update(collect_const(r1[F3]).match(qF3)) if eq[1].has(r[F2]) and not eq[1].has(r[F3]): r[F2], r[F3] = r[F3], r[F2] r[s], r[q] = -r[q], -r[s] r.update((diff(y(t), t) - eq[1]).match(pr[F3] - r[s]F1)) a = r[p]; b = r[q]; c = r[s] F1 = r[F1].subs(x(t), u).subs(y(t),v).subs(z(t), w) F2 = r[F2].subs(x(t), u).subs(y(t),v).subs(z(t), w) F3 = r[F3].subs(x(t), u).subs(y(t),v).subs(z(t), w) z_xy = (C1-au-bv)/c y_zx = (C1-au-cw)/b x_yz = (C1-bv-cw)/a y_x = dsolve(diff(v(u),u) - ((aF3-cF1)/(cF2-bF3)).subs(w,z_xy).subs(v,v(u))).rhs z_x = dsolve(diff(w(u),u) - ((bF1-aF2)/(cF2-bF3)).subs(v,y_zx).subs(w,w(u))).rhs z_y = dsolve(diff(w(v),v) - ((bF1-aF2)/(aF3-cF1)).subs(u,x_yz).subs(w,w(v))).rhs x_y = dsolve(diff(u(v),v) - ((cF2-bF3)/(aF3-cF1)).subs(w,z_xy).subs(u,u(v))).rhs y_z = dsolve(diff(v(w),w) - ((aF3-cF1)/(bF1-aF2)).subs(u,x_yz).subs(v,v(w))).rhs x_z = dsolve(diff(u(w),w) - ((cF2-bF3)/(bF1-aF2)).subs(v,y_zx).subs(u,u(w))).rhs sol1 = dsolve(diff(u(t),t) - (cF2 - bF3).subs(v,y_x).subs(w,z_x).subs(u,u(t))).rhs sol2 = dsolve(diff(v(t),t) - (aF3 - cF1).subs(u,x_y).subs(w,z_y).subs(v,v(t))).rhs sol3 = dsolve(diff(w(t),t) - (bF1 - aF2).subs(u,x_z).subs(v,y_z).subs(w,w(t))).rhs return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type4(x, y, z, t, eq): r""" Equations: .. math:: x' = c z F_2 - b y F_3, \enspace y' = a x F_3 - c z F_1, \enspace z' = b y F_1 - a x F_2 where `F_n = F_n (x, y, z, t)` 1. First integral: .. math:: a x^{2} + b y^{2} + c z^{2} = C_1 where `C` is an arbitrary constant. 2. Assuming the function `F_n` is independent of `t`: `F_n = F_n (x, y, z)`. Then on eliminating `t` and `z` from the first two equations of the system, one arrives at the first-order equation .. math:: \frac{dy}{dx} = \frac{a x F_3 (x, y, z) - c z F_1 (x, y, z)} {c z F_2 (x, y, z) - b y F_3 (x, y, z)} where `z = \pm \sqrt{\frac{1}{c} (C_1 - a x^{2} - b y^{2})}` References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0405.pdf """ C1 = get_numbered_constants(eq, num=1) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) F1, F2, F3 = symbols('F1, F2, F3', cls=Wild) r1 = eq[0].match(diff(x(t),t) - z(t)F2 + y(t)F3) r = collect_const(r1[F2]).match(sF2) r.update(collect_const(r1[F3]).match(qF3)) if eq[1].has(r[F2]) and not eq[1].has(r[F3]): r[F2], r[F3] = r[F3], r[F2] r[s], r[q] = -r[q], -r[s] r.update((diff(y(t),t) - eq[1]).match(px(t)r[F3] - r[s]z(t)F1)) a = r[p]; b = r[q]; c = r[s] F1 = r[F1].subs(x(t),u).subs(y(t),v).subs(z(t),w) F2 = r[F2].subs(x(t),u).subs(y(t),v).subs(z(t),w) F3 = r[F3].subs(x(t),u).subs(y(t),v).subs(z(t),w) x_yz = sqrt((C1 - bv2 - cw*2)/a) y_zx = sqrt((C1 - cw*2 - au*2)/b) z_xy = sqrt((C1 - au*2 - bv*2)/c) y_x = dsolve(diff(v(u),u) - ((auF3-cwF1)/(cwF2-bvF3)).subs(w,z_xy).subs(v,v(u))).rhs z_x = dsolve(diff(w(u),u) - ((bvF1-auF2)/(cwF2-bvF3)).subs(v,y_zx).subs(w,w(u))).rhs z_y = dsolve(diff(w(v),v) - ((bvF1-auF2)/(auF3-cwF1)).subs(u,x_yz).subs(w,w(v))).rhs x_y = dsolve(diff(u(v),v) - ((cwF2-bvF3)/(auF3-cwF1)).subs(w,z_xy).subs(u,u(v))).rhs y_z = dsolve(diff(v(w),w) - ((auF3-cwF1)/(bvF1-auF2)).subs(u,x_yz).subs(v,v(w))).rhs x_z = dsolve(diff(u(w),w) - ((cwF2-bvF3)/(bvF1-auF2)).subs(v,y_zx).subs(u,u(w))).rhs sol1 = dsolve(diff(u(t),t) - (cwF2 - bvF3).subs(v,y_x).subs(w,z_x).subs(u,u(t))).rhs sol2 = dsolve(diff(v(t),t) - (auF3 - cwF1).subs(u,x_y).subs(w,z_y).subs(v,v(t))).rhs sol3 = dsolve(diff(w(t),t) - (bvF1 - auF2).subs(u,x_z).subs(v,y_z).subs(w,w(t))).rhs return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type5(x, y, z, t, eq): r""" .. math:: x' = x (c F_2 - b F_3), \enspace y' = y (a F_3 - c F_1), \enspace z' = z (b F_1 - a F_2) where `F_n = F_n (x, y, z, t)` and are arbitrary functions. First Integral: .. math:: \left\|x\right\|^{a} \left\|y\right\|^{b} \left\|z\right\|^{c} = C_1 where `C` is an arbitrary constant. If the function `F_n` is independent of `t`, then, by eliminating `t` and `z` from the first two equations of the system, one arrives at a first-order equation. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0406.pdf """ C1 = get_numbered_constants(eq, num=1) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) F1, F2, F3 = symbols('F1, F2, F3', cls=Wild) r1 = eq[0].match(diff(x(t), t) - x(t)(F2 - F3)) r = collect_const(r1[F2]).match(sF2) r.update(collect_const(r1[F3]).match(qF3)) if eq[1].has(r[F2]) and not eq[1].has(r[F3]): r[F2], r[F3] = r[F3], r[F2] r[s], r[q] = -r[q], -r[s] r.update((diff(y(t), t) - eq[1]).match(y(t)(pr[F3] - r[s]F1))) a = r[p]; b = r[q]; c = r[s] F1 = r[F1].subs(x(t), u).subs(y(t), v).subs(z(t), w) F2 = r[F2].subs(x(t), u).subs(y(t), v).subs(z(t), w) F3 = r[F3].subs(x(t), u).subs(y(t), v).subs(z(t), w) x_yz = (C1v*-bw-c)-a y_zx = (C1w-cu-a)-b z_xy = (C1u-av-b)-c y_x = dsolve(diff(v(u), u) - ((v(aF3 - cF1))/(u(cF2 - bF3))).subs(w, z_xy).subs(v, v(u))).rhs z_x = dsolve(diff(w(u), u) - ((w(bF1 - aF2))/(u(cF2 - bF3))).subs(v, y_zx).subs(w, w(u))).rhs z_y = dsolve(diff(w(v), v) - ((w(bF1 - aF2))/(v(aF3 - cF1))).subs(u, x_yz).subs(w, w(v))).rhs x_y = dsolve(diff(u(v), v) - ((u(cF2 - bF3))/(v(aF3 - cF1))).subs(w, z_xy).subs(u, u(v))).rhs y_z = dsolve(diff(v(w), w) - ((v(aF3 - cF1))/(w(bF1 - aF2))).subs(u, x_yz).subs(v, v(w))).rhs x_z = dsolve(diff(u(w), w) - ((u(cF2 - bF3))/(w(bF1 - aF2))).subs(v, y_zx).subs(u, u(w))).rhs sol1 = dsolve(diff(u(t), t) - (u(cF2 - bF3)).subs(v, y_x).subs(w, z_x).subs(u, u(t))).rhs sol2 = dsolve(diff(v(t), t) - (v(aF3 - cF1)).subs(u, x_y).subs(w, z_y).subs(v, v(t))).rhs sol3 = dsolve(diff(w(t), t) - (w(bF1 - a*F2)).subs(u, x_z).subs(v, y_z).subs(w, w(t))).rhs return [sol1, sol2, sol3]
9905b5bef7330ece978fcff4a4b0f2187692c7f087efa7537f11f567d200d649	""" This module contains functions to: - solve a single equation for a single variable, in any domain either real or complex. - solve a single transcendental equation for a single variable in any domain either real or complex. (currently supports solving in real domain only) - solve a system of linear equations with N variables and M equations. - solve a system of Non Linear Equations with N variables and M equations """ from __future__ import print_function, division from sympy.core.sympify import sympify from sympy.core import (S, Pow, Dummy, pi, Expr, Wild, Mul, Equality, Add) from sympy.core.containers import Tuple from sympy.core.facts import InconsistentAssumptions from sympy.core.numbers import I, Number, Rational, oo from sympy.core.function import (Lambda, expand_complex, AppliedUndef, expand_log, _mexpand) from sympy.core.relational import Eq, Ne from sympy.core.symbol import Symbol from sympy.core.sympify import _sympify from sympy.simplify.simplify import simplify, fraction, trigsimp from sympy.simplify import powdenest, logcombine from sympy.functions import (log, Abs, tan, cot, sin, cos, sec, csc, exp, acos, asin, acsc, asec, arg, piecewise_fold, Piecewise) from sympy.functions.elementary.trigonometric import (TrigonometricFunction, HyperbolicFunction) from sympy.functions.elementary.miscellaneous import real_root from sympy.logic.boolalg import And from sympy.sets import (FiniteSet, EmptySet, imageset, Interval, Intersection, Union, ConditionSet, ImageSet, Complement, Contains) from sympy.sets.sets import Set from sympy.matrices import Matrix, MatrixBase from sympy.polys import (roots, Poly, degree, together, PolynomialError, RootOf, factor) from sympy.polys.polyerrors import CoercionFailed from sympy.solvers.solvers import (checksol, denoms, unrad, _simple_dens, recast_to_symbols) from sympy.solvers.polysys import solve_poly_system from sympy.solvers.inequalities import solve_univariate_inequality from sympy.utilities import filldedent from sympy.utilities.iterables import numbered_symbols, has_dups from sympy.calculus.util import periodicity, continuous_domain from sympy.core.compatibility import ordered, default_sort_key, is_sequence from types import GeneratorType from collections import defaultdict def _masked(f, atoms): """Return ``f``, with all objects given by ``atoms`` replaced with Dummy symbols, ``d``, and the list of replacements, ``(d, e)``, where ``e`` is an object of type given by ``atoms`` in which any other instances of atoms have been recursively replaced with Dummy symbols, too. The tuples are ordered so that if they are applied in sequence, the origin ``f`` will be restored. Examples ======== >>> from sympy import cos >>> from sympy.abc import x >>> from sympy.solvers.solveset import _masked >>> f = cos(cos(x) + 1) >>> f, reps = _masked(cos(1 + cos(x)), cos) >>> f _a1 >>> reps [(_a1, cos(_a0 + 1)), (_a0, cos(x))] >>> for d, e in reps: ... f = f.xreplace({d: e}) >>> f cos(cos(x) + 1) """ sym = numbered_symbols('a', cls=Dummy, real=True) mask = [] for a in ordered(f.atoms(atoms)): for i in mask: a = a.replace(i) mask.append((a, next(sym))) for i, (o, n) in enumerate(mask): f = f.replace(o, n) mask[i] = (n, o) mask = list(reversed(mask)) return f, mask def _invert(f_x, y, x, domain=S.Complexes): r""" Reduce the complex valued equation ``f(x) = y`` to a set of equations ``{g(x) = h_1(y), g(x) = h_2(y), ..., g(x) = h_n(y) }`` where ``g(x)`` is a simpler function than ``f(x)``. The return value is a tuple ``(g(x), set_h)``, where ``g(x)`` is a function of ``x`` and ``set_h`` is the set of function ``{h_1(y), h_2(y), ..., h_n(y)}``. Here, ``y`` is not necessarily a symbol. The ``set_h`` contains the functions, along with the information about the domain in which they are valid, through set operations. For instance, if ``y = Abs(x) - n`` is inverted in the real domain, then ``set_h`` is not simply `{-n, n}` as the nature of `n` is unknown; rather, it is: `Intersection([0, oo) {n}) U Intersection((-oo, 0], {-n})` By default, the complex domain is used which means that inverting even seemingly simple functions like ``exp(x)`` will give very different results from those obtained in the real domain. (In the case of ``exp(x)``, the inversion via ``log`` is multi-valued in the complex domain, having infinitely many branches.) If you are working with real values only (or you are not sure which function to use) you should probably set the domain to ``S.Reals`` (or use `invert\_real` which does that automatically). Examples ======== >>> from sympy.solvers.solveset import invert_complex, invert_real >>> from sympy.abc import x, y >>> from sympy import exp, log When does exp(x) == y? >>> invert_complex(exp(x), y, x) (x, ImageSet(Lambda(_n, I(2_npi + arg(y)) + log(Abs(y))), Integers)) >>> invert_real(exp(x), y, x) (x, Intersection({log(y)}, Reals)) When does exp(x) == 1? >>> invert_complex(exp(x), 1, x) (x, ImageSet(Lambda(_n, 2_nIpi), Integers)) >>> invert_real(exp(x), 1, x) (x, {0}) See Also ======== invert_real, invert_complex """ x = sympify(x) if not x.is_Symbol: raise ValueError("x must be a symbol") f_x = sympify(f_x) if x not in f_x.free_symbols: raise ValueError("Inverse of constant function doesn't exist") y = sympify(y) if x in y.free_symbols: raise ValueError("y should be independent of x ") if domain.is_subset(S.Reals): x1, s = _invert_real(f_x, FiniteSet(y), x) else: x1, s = _invert_complex(f_x, FiniteSet(y), x) if not isinstance(s, FiniteSet) or x1 != x: return x1, s return x1, s.intersection(domain) invert_complex = _invert def invert_real(f_x, y, x, domain=S.Reals): """ Inverts a real-valued function. Same as _invert, but sets the domain to ``S.Reals`` before inverting. """ return _invert(f_x, y, x, domain) def _invert_real(f, g_ys, symbol): """Helper function for _invert.""" if f == symbol: return (f, g_ys) n = Dummy('n', real=True) if hasattr(f, 'inverse') and not isinstance(f, ( TrigonometricFunction, HyperbolicFunction, )): if len(f.args) > 1: raise ValueError("Only functions with one argument are supported.") return _invert_real(f.args[0], imageset(Lambda(n, f.inverse()(n)), g_ys), symbol) if isinstance(f, Abs): return _invert_abs(f.args[0], g_ys, symbol) if f.is_Add: # f = g + h g, h = f.as_independent(symbol) if g is not S.Zero: return _invert_real(h, imageset(Lambda(n, n - g), g_ys), symbol) if f.is_Mul: # f = gh g, h = f.as_independent(symbol) if g is not S.One: return _invert_real(h, imageset(Lambda(n, n/g), g_ys), symbol) if f.is_Pow: base, expo = f.args base_has_sym = base.has(symbol) expo_has_sym = expo.has(symbol) if not expo_has_sym: res = imageset(Lambda(n, real_root(n, expo)), g_ys) if expo.is_rational: numer, denom = expo.as_numer_denom() if denom % 2 == 0: base_positive = solveset(base >= 0, symbol, S.Reals) res = imageset(Lambda(n, real_root(n, expo) ), g_ys.intersect( Interval.Ropen(S.Zero, S.Infinity))) _inv, _set = _invert_real(base, res, symbol) return (_inv, _set.intersect(base_positive)) elif numer % 2 == 0: n = Dummy('n') neg_res = imageset(Lambda(n, -n), res) return _invert_real(base, res + neg_res, symbol) else: return _invert_real(base, res, symbol) else: if not base.is_positive: raise ValueError("xw where w is irrational is not " "defined for negative x") return _invert_real(base, res, symbol) if not base_has_sym: rhs = g_ys.args[0] if base.is_positive: return _invert_real(expo, imageset(Lambda(n, log(n, base, evaluate=False)), g_ys), symbol) elif base.is_negative: from sympy.core.power import integer_log s, b = integer_log(rhs, base) if b: return _invert_real(expo, FiniteSet(s), symbol) else: return _invert_real(expo, S.EmptySet, symbol) elif base.is_zero: one = Eq(rhs, 1) if one == S.true: # special case: 0x - 1 return _invert_real(expo, FiniteSet(0), symbol) elif one == S.false: return _invert_real(expo, S.EmptySet, symbol) if isinstance(f, TrigonometricFunction): if isinstance(g_ys, FiniteSet): def inv(trig): if isinstance(f, (sin, csc)): F = asin if isinstance(f, sin) else acsc return (lambda a: npi + (-1)nF(a),) if isinstance(f, (cos, sec)): F = acos if isinstance(f, cos) else asec return ( lambda a: 2npi + F(a), lambda a: 2npi - F(a),) if isinstance(f, (tan, cot)): return (lambda a: npi + f.inverse()(a),) n = Dummy('n', integer=True) invs = S.EmptySet for L in inv(f): invs += Union([imageset(Lambda(n, L(g)), S.Integers) for g in g_ys]) return _invert_real(f.args[0], invs, symbol) return (f, g_ys) def _invert_complex(f, g_ys, symbol): """Helper function for _invert.""" if f == symbol: return (f, g_ys) n = Dummy('n') if f.is_Add: # f = g + h g, h = f.as_independent(symbol) if g is not S.Zero: return _invert_complex(h, imageset(Lambda(n, n - g), g_ys), symbol) if f.is_Mul: # f = gh g, h = f.as_independent(symbol) if g is not S.One: if g in set([S.NegativeInfinity, S.ComplexInfinity, S.Infinity]): return (h, S.EmptySet) return _invert_complex(h, imageset(Lambda(n, n/g), g_ys), symbol) if hasattr(f, 'inverse') and \ not isinstance(f, TrigonometricFunction) and \ not isinstance(f, HyperbolicFunction) and \ not isinstance(f, exp): if len(f.args) > 1: raise ValueError("Only functions with one argument are supported.") return _invert_complex(f.args[0], imageset(Lambda(n, f.inverse()(n)), g_ys), symbol) if isinstance(f, exp): if isinstance(g_ys, FiniteSet): exp_invs = Union([imageset(Lambda(n, I(2npi + arg(g_y)) + log(Abs(g_y))), S.Integers) for g_y in g_ys if g_y != 0]) return _invert_complex(f.args[0], exp_invs, symbol) return (f, g_ys) def _invert_abs(f, g_ys, symbol): """Helper function for inverting absolute value functions. Returns the complete result of inverting an absolute value function along with the conditions which must also be satisfied. If it is certain that all these conditions are met, a `FiniteSet` of all possible solutions is returned. If any condition cannot be satisfied, an `EmptySet` is returned. Otherwise, a `ConditionSet` of the solutions, with all the required conditions specified, is returned. """ if not g_ys.is_FiniteSet: # this could be used for FiniteSet, but the # results are more compact if they aren't, e.g. # ConditionSet(x, Contains(n, Interval(0, oo)), {-n, n}) vs # Union(Intersection(Interval(0, oo), {n}), Intersection(Interval(-oo, 0), {-n})) # for the solution of abs(x) - n pos = Intersection(g_ys, Interval(0, S.Infinity)) parg = _invert_real(f, pos, symbol) narg = _invert_real(-f, pos, symbol) if parg[0] != narg[0]: raise NotImplementedError return parg[0], Union(narg[1], parg[1]) # check conditions: all these must be true. If any are unknown # then return them as conditions which must be satisfied unknown = [] for a in g_ys.args: ok = a.is_nonnegative if a.is_Number else a.is_positive if ok is None: unknown.append(a) elif not ok: return symbol, S.EmptySet if unknown: conditions = And([Contains(i, Interval(0, oo)) for i in unknown]) else: conditions = True n = Dummy('n', real=True) # this is slightly different than above: instead of solving # +/-f on positive values, here we solve for f on +/- g_ys g_x, values = _invert_real(f, Union( imageset(Lambda(n, n), g_ys), imageset(Lambda(n, -n), g_ys)), symbol) return g_x, ConditionSet(g_x, conditions, values) def domain_check(f, symbol, p): """Returns False if point p is infinite or any subexpression of f is infinite or becomes so after replacing symbol with p. If none of these conditions is met then True will be returned. Examples ======== >>> from sympy import Mul, oo >>> from sympy.abc import x >>> from sympy.solvers.solveset import domain_check >>> g = 1/(1 + (1/(x + 1))2) >>> domain_check(g, x, -1) False >>> domain_check(x2, x, 0) True >>> domain_check(1/x, x, oo) False * The function relies on the assumption that the original form of the equation has not been changed by automatic simplification. >>> domain_check(x/x, x, 0) # x/x is automatically simplified to 1 True * To deal with automatic evaluations use evaluate=False: >>> domain_check(Mul(x, 1/x, evaluate=False), x, 0) False """ f, p = sympify(f), sympify(p) if p.is_infinite: return False return _domain_check(f, symbol, p) def _domain_check(f, symbol, p): # helper for domain check if f.is_Atom and f.is_finite: return True elif f.subs(symbol, p).is_infinite: return False else: return all([_domain_check(g, symbol, p) for g in f.args]) def _is_finite_with_finite_vars(f, domain=S.Complexes): """ Return True if the given expression is finite. For symbols that don't assign a value for `complex` and/or `real`, the domain will be used to assign a value; symbols that don't assign a value for `finite` will be made finite. All other assumptions are left unmodified. """ def assumptions(s): A = s.assumptions0 A.setdefault('finite', A.get('finite', True)) if domain.is_subset(S.Reals): # if this gets set it will make complex=True, too A.setdefault('real', True) else: # don't change 'real' because being complex implies # nothing about being real A.setdefault('complex', True) return A reps = {s: Dummy(assumptions(s)) for s in f.free_symbols} return f.xreplace(reps).is_finite def _is_function_class_equation(func_class, f, symbol): """ Tests whether the equation is an equation of the given function class. The given equation belongs to the given function class if it is comprised of functions of the function class which are multiplied by or added to expressions independent of the symbol. In addition, the arguments of all such functions must be linear in the symbol as well. Examples ======== >>> from sympy.solvers.solveset import _is_function_class_equation >>> from sympy import tan, sin, tanh, sinh, exp >>> from sympy.abc import x >>> from sympy.functions.elementary.trigonometric import (TrigonometricFunction, ... HyperbolicFunction) >>> _is_function_class_equation(TrigonometricFunction, exp(x) + tan(x), x) False >>> _is_function_class_equation(TrigonometricFunction, tan(x) + sin(x), x) True >>> _is_function_class_equation(TrigonometricFunction, tan(x2), x) False >>> _is_function_class_equation(TrigonometricFunction, tan(x + 2), x) True >>> _is_function_class_equation(HyperbolicFunction, tanh(x) + sinh(x), x) True """ if f.is_Mul or f.is_Add: return all(_is_function_class_equation(func_class, arg, symbol) for arg in f.args) if f.is_Pow: if not f.exp.has(symbol): return _is_function_class_equation(func_class, f.base, symbol) else: return False if not f.has(symbol): return True if isinstance(f, func_class): try: g = Poly(f.args[0], symbol) return g.degree() <= 1 except PolynomialError: return False else: return False def _solve_as_rational(f, symbol, domain): """ solve rational functions""" f = together(f, deep=True) g, h = fraction(f) if not h.has(symbol): try: return _solve_as_poly(g, symbol, domain) except NotImplementedError: # The polynomial formed from g could end up having # coefficients in a ring over which finding roots # isn't implemented yet, e.g. ZZ[a] for some symbol a return ConditionSet(symbol, Eq(f, 0), domain) except CoercionFailed: # contained oo, zoo or nan return S.EmptySet else: valid_solns = _solveset(g, symbol, domain) invalid_solns = _solveset(h, symbol, domain) return valid_solns - invalid_solns def _solve_trig(f, symbol, domain): """Function to call other helpers to solve trigonometric equations """ sol1 = sol = None try: sol1 = _solve_trig1(f, symbol, domain) except BaseException as error: pass if sol1 is None or isinstance(sol1, ConditionSet): try: sol = _solve_trig2(f, symbol, domain) except BaseException as error: sol = sol1 if isinstance(sol1, ConditionSet) and isinstance(sol, ConditionSet): if sol1.count_ops() < sol.count_ops(): sol = sol1 else: sol = sol1 if sol is None: raise NotImplementedError(filldedent(''' Solution to this kind of trigonometric equations is yet to be implemented''')) return sol def _solve_trig1(f, symbol, domain): """Primary Helper to solve trigonometric equations """ f = trigsimp(f) f_original = f f = f.rewrite(exp) f = together(f) g, h = fraction(f) y = Dummy('y') g, h = g.expand(), h.expand() g, h = g.subs(exp(Isymbol), y), h.subs(exp(Isymbol), y) if g.has(symbol) or h.has(symbol): return ConditionSet(symbol, Eq(f, 0), S.Reals) solns = solveset_complex(g, y) - solveset_complex(h, y) if isinstance(solns, ConditionSet): raise NotImplementedError if isinstance(solns, FiniteSet): if any(isinstance(s, RootOf) for s in solns): raise NotImplementedError result = Union([invert_complex(exp(Isymbol), s, symbol)[1] for s in solns]) return Intersection(result, domain) elif solns is S.EmptySet: return S.EmptySet else: return ConditionSet(symbol, Eq(f_original, 0), S.Reals) def _solve_trig2(f, symbol, domain): """Secondary helper to solve trigonometric equations, called when first helper fails """ from sympy import ilcm, igcd, expand_trig, degree, simplify f = trigsimp(f) f_original = f trig_functions = f.atoms(sin, cos, tan, sec, cot, csc) trig_arguments = [e.args[0] for e in trig_functions] denominators = [] numerators = [] for ar in trig_arguments: try: poly_ar = Poly(ar, symbol) except ValueError: raise ValueError("give up, we can't solve if this is not a polynomial in x") if poly_ar.degree() > 1: # degree >1 still bad raise ValueError("degree of variable inside polynomial should not exceed one") if poly_ar.degree() == 0: # degree 0, don't care continue c = poly_ar.all_coeffs()[0] # got the coefficient of 'symbol' numerators.append(Rational(c).p) denominators.append(Rational(c).q) x = Dummy('x') # ilcm() and igcd() require more than one argument if len(numerators) > 1: mu = Rational(2)ilcm(denominators)/igcd(numerators) else: assert len(numerators) == 1 mu = Rational(2)denominators[0]/numerators[0] f = f.subs(symbol, mux) f = f.rewrite(tan) f = expand_trig(f) f = together(f) g, h = fraction(f) y = Dummy('y') g, h = g.expand(), h.expand() g, h = g.subs(tan(x), y), h.subs(tan(x), y) if g.has(x) or h.has(x): return ConditionSet(symbol, Eq(f_original, 0), domain) solns = solveset(g, y, S.Reals) - solveset(h, y, S.Reals) if isinstance(solns, FiniteSet): result = Union([invert_real(tan(symbol/mu), s, symbol)[1] for s in solns]) dsol = invert_real(tan(symbol/mu), oo, symbol)[1] if degree(h) > degree(g): # If degree(denom)>degree(num) then there result = Union(result, dsol) # would be another sol at Lim(denom-->oo) return Intersection(result, domain) elif solns is S.EmptySet: return S.EmptySet else: return ConditionSet(symbol, Eq(f_original, 0), S.Reals) def _solve_as_poly(f, symbol, domain=S.Complexes): """ Solve the equation using polynomial techniques if it already is a polynomial equation or, with a change of variables, can be made so. """ result = None if f.is_polynomial(symbol): solns = roots(f, symbol, cubics=True, quartics=True, quintics=True, domain='EX') num_roots = sum(solns.values()) if degree(f, symbol) <= num_roots: result = FiniteSet(solns.keys()) else: poly = Poly(f, symbol) solns = poly.all_roots() if poly.degree() <= len(solns): result = FiniteSet(solns) else: result = ConditionSet(symbol, Eq(f, 0), domain) else: poly = Poly(f) if poly is None: result = ConditionSet(symbol, Eq(f, 0), domain) gens = [g for g in poly.gens if g.has(symbol)] if len(gens) == 1: poly = Poly(poly, gens[0]) gen = poly.gen deg = poly.degree() poly = Poly(poly.as_expr(), poly.gen, composite=True) poly_solns = FiniteSet(roots(poly, cubics=True, quartics=True, quintics=True).keys()) if len(poly_solns) < deg: result = ConditionSet(symbol, Eq(f, 0), domain) if gen != symbol: y = Dummy('y') inverter = invert_real if domain.is_subset(S.Reals) else invert_complex lhs, rhs_s = inverter(gen, y, symbol) if lhs == symbol: result = Union([rhs_s.subs(y, s) for s in poly_solns]) else: result = ConditionSet(symbol, Eq(f, 0), domain) else: result = ConditionSet(symbol, Eq(f, 0), domain) if result is not None: if isinstance(result, FiniteSet): # this is to simplify solutions like -sqrt(-I) to sqrt(2)/2 # - sqrt(2)I/2. We are not expanding for solution with symbols # or undefined functions because that makes the solution more complicated. # For example, expand_complex(a) returns re(a) + Iim(a) if all([s.atoms(Symbol, AppliedUndef) == set() and not isinstance(s, RootOf) for s in result]): s = Dummy('s') result = imageset(Lambda(s, expand_complex(s)), result) if isinstance(result, FiniteSet): result = result.intersection(domain) return result else: return ConditionSet(symbol, Eq(f, 0), domain) def _has_rational_power(expr, symbol): """ Returns (bool, den) where bool is True if the term has a non-integer rational power and den is the denominator of the expression's exponent. Examples ======== >>> from sympy.solvers.solveset import _has_rational_power >>> from sympy import sqrt >>> from sympy.abc import x >>> _has_rational_power(sqrt(x), x) (True, 2) >>> _has_rational_power(x*2, x) (False, 1) """ a, p, q = Wild('a'), Wild('p'), Wild('q') pattern_match = expr.match(ap*q) or {} if pattern_match.get(a, S.Zero) is S.Zero: return (False, S.One) elif p not in pattern_match.keys(): return (False, S.One) elif isinstance(pattern_match[q], Rational) \ and pattern_match[p].has(symbol): if not pattern_match[q].q == S.One: return (True, pattern_match[q].q) if not isinstance(pattern_match[a], Pow) \ or isinstance(pattern_match[a], Mul): return (False, S.One) else: return _has_rational_power(pattern_match[a], symbol) def _solve_radical(f, symbol, solveset_solver): """ Helper function to solve equations with radicals """ eq, cov = unrad(f) if not cov: result = solveset_solver(eq, symbol) - \ Union([solveset_solver(g, symbol) for g in denoms(f, symbol)]) else: y, yeq = cov if not solveset_solver(y - I, y): yreal = Dummy('yreal', real=True) yeq = yeq.xreplace({y: yreal}) eq = eq.xreplace({y: yreal}) y = yreal g_y_s = solveset_solver(yeq, symbol) f_y_sols = solveset_solver(eq, y) result = Union([imageset(Lambda(y, g_y), f_y_sols) for g_y in g_y_s]) if isinstance(result, Complement) or isinstance(result,ConditionSet): solution_set = result else: f_set = [] # solutions for FiniteSet c_set = [] # solutions for ConditionSet for s in result: if checksol(f, symbol, s): f_set.append(s) else: c_set.append(s) solution_set = FiniteSet(f_set) + ConditionSet(symbol, Eq(f, 0), FiniteSet(c_set)) return solution_set def _solve_abs(f, symbol, domain): """ Helper function to solve equation involving absolute value function """ if not domain.is_subset(S.Reals): raise ValueError(filldedent(''' Absolute values cannot be inverted in the complex domain.''')) p, q, r = Wild('p'), Wild('q'), Wild('r') pattern_match = f.match(pAbs(q) + r) or {} f_p, f_q, f_r = [pattern_match.get(i, S.Zero) for i in (p, q, r)] if not (f_p.is_zero or f_q.is_zero): domain = continuous_domain(f_q, symbol, domain) q_pos_cond = solve_univariate_inequality(f_q >= 0, symbol, relational=False, domain=domain, continuous=True) q_neg_cond = q_pos_cond.complement(domain) sols_q_pos = solveset_real(f_pf_q + f_r, symbol).intersect(q_pos_cond) sols_q_neg = solveset_real(f_p(-f_q) + f_r, symbol).intersect(q_neg_cond) return Union(sols_q_pos, sols_q_neg) else: return ConditionSet(symbol, Eq(f, 0), domain) def solve_decomposition(f, symbol, domain): """ Function to solve equations via the principle of "Decomposition and Rewriting". Examples ======== >>> from sympy import exp, sin, Symbol, pprint, S >>> from sympy.solvers.solveset import solve_decomposition as sd >>> x = Symbol('x') >>> f1 = exp(2x) - 3exp(x) + 2 >>> sd(f1, x, S.Reals) {0, log(2)} >>> f2 = sin(x)*2 + 2sin(x) + 1 >>> pprint(sd(f2, x, S.Reals), use_unicode=False) 3pi {2npi + ---- \| n in Integers} 2 >>> f3 = sin(x + 2) >>> pprint(sd(f3, x, S.Reals), use_unicode=False) {2npi - 2 \| n in Integers} U {2npi - 2 + pi \| n in Integers} """ from sympy.solvers.decompogen import decompogen from sympy.calculus.util import function_range # decompose the given function g_s = decompogen(f, symbol) # `y_s` represents the set of values for which the function `g` is to be # solved. # `solutions` represent the solutions of the equations `g = y_s` or # `g = 0` depending on the type of `y_s`. # As we are interested in solving the equation: f = 0 y_s = FiniteSet(0) for g in g_s: frange = function_range(g, symbol, domain) y_s = Intersection(frange, y_s) result = S.EmptySet if isinstance(y_s, FiniteSet): for y in y_s: solutions = solveset(Eq(g, y), symbol, domain) if not isinstance(solutions, ConditionSet): result += solutions else: if isinstance(y_s, ImageSet): iter_iset = (y_s,) elif isinstance(y_s, Union): iter_iset = y_s.args elif isinstance(y_s, EmptySet): # y_s is not in the range of g in g_s, so no solution exists #in the given domain return y_s for iset in iter_iset: new_solutions = solveset(Eq(iset.lamda.expr, g), symbol, domain) dummy_var = tuple(iset.lamda.expr.free_symbols)[0] base_set = iset.base_set if isinstance(new_solutions, FiniteSet): new_exprs = new_solutions elif isinstance(new_solutions, Intersection): if isinstance(new_solutions.args[1], FiniteSet): new_exprs = new_solutions.args[1] for new_expr in new_exprs: result += ImageSet(Lambda(dummy_var, new_expr), base_set) if result is S.EmptySet: return ConditionSet(symbol, Eq(f, 0), domain) y_s = result return y_s def _solveset(f, symbol, domain, _check=False): """Helper for solveset to return a result from an expression that has already been sympify'ed and is known to contain the given symbol.""" # _check controls whether the answer is checked or not from sympy.simplify.simplify import signsimp orig_f = f if f.is_Mul: coeff, f = f.as_independent(symbol, as_Add=False) if coeff in set([S.ComplexInfinity, S.NegativeInfinity, S.Infinity]): f = together(orig_f) elif f.is_Add: a, h = f.as_independent(symbol) m, h = h.as_independent(symbol, as_Add=False) if m not in set([S.ComplexInfinity, S.Zero, S.Infinity, S.NegativeInfinity]): f = a/m + h # XXX condition `m != 0` should be added to soln # assign the solvers to use solver = lambda f, x, domain=domain: _solveset(f, x, domain) inverter = lambda f, rhs, symbol: _invert(f, rhs, symbol, domain) result = EmptySet() if f.expand().is_zero: return domain elif not f.has(symbol): return EmptySet() elif f.is_Mul and all(_is_finite_with_finite_vars(m, domain) for m in f.args): # if f(x) and g(x) are both finite we can say that the solution of # f(x)g(x) == 0 is same as Union(f(x) == 0, g(x) == 0) is not true in # general. g(x) can grow to infinitely large for the values where # f(x) == 0. To be sure that we are not silently allowing any # wrong solutions we are using this technique only if both f and g are # finite for a finite input. result = Union([solver(m, symbol) for m in f.args]) elif _is_function_class_equation(TrigonometricFunction, f, symbol) or \ _is_function_class_equation(HyperbolicFunction, f, symbol): result = _solve_trig(f, symbol, domain) elif isinstance(f, arg): a = f.args[0] result = solveset_real(a > 0, symbol) elif f.is_Piecewise: result = EmptySet() expr_set_pairs = f.as_expr_set_pairs(domain) for (expr, in_set) in expr_set_pairs: if in_set.is_Relational: in_set = in_set.as_set() solns = solver(expr, symbol, in_set) result += solns elif isinstance(f, Eq): result = solver(Add(f.lhs, - f.rhs, evaluate=False), symbol, domain) elif f.is_Relational: if not domain.is_subset(S.Reals): raise NotImplementedError(filldedent(''' Inequalities in the complex domain are not supported. Try the real domain by setting domain=S.Reals''')) try: result = solve_univariate_inequality( f, symbol, domain=domain, relational=False) except NotImplementedError: result = ConditionSet(symbol, f, domain) return result else: lhs, rhs_s = inverter(f, 0, symbol) if lhs == symbol: # do some very minimal simplification since # repeated inversion may have left the result # in a state that other solvers (e.g. poly) # would have simplified; this is done here # rather than in the inverter since here it # is only done once whereas there it would # be repeated for each step of the inversion if isinstance(rhs_s, FiniteSet): rhs_s = FiniteSet([Mul(* signsimp(i).as_content_primitive()) for i in rhs_s]) result = rhs_s elif isinstance(rhs_s, FiniteSet): for equation in [lhs - rhs for rhs in rhs_s]: if equation == f: if any(_has_rational_power(g, symbol)[0] for g in equation.args) or _has_rational_power( equation, symbol)[0]: result += _solve_radical(equation, symbol, solver) elif equation.has(Abs): result += _solve_abs(f, symbol, domain) else: result_rational = _solve_as_rational(equation, symbol, domain) if isinstance(result_rational, ConditionSet): # may be a transcendental type equation result += _transolve(equation, symbol, domain) else: result += result_rational else: result += solver(equation, symbol) elif rhs_s is not S.EmptySet: result = ConditionSet(symbol, Eq(f, 0), domain) if isinstance(result, ConditionSet): num, den = f.as_numer_denom() if den.has(symbol): _result = _solveset(num, symbol, domain) if not isinstance(_result, ConditionSet): singularities = _solveset(den, symbol, domain) result = _result - singularities if _check: if isinstance(result, ConditionSet): # it wasn't solved or has enumerated all conditions # -- leave it alone return result # whittle away all but the symbol-containing core # to use this for testing fx = orig_f.as_independent(symbol, as_Add=True)[1] fx = fx.as_independent(symbol, as_Add=False)[1] if isinstance(result, FiniteSet): # check the result for invalid solutions result = FiniteSet([s for s in result if isinstance(s, RootOf) or domain_check(fx, symbol, s)]) return result def _term_factors(f): """ Iterator to get the factors of all terms present in the given equation. Parameters ========== f : Expr Equation that needs to be addressed Returns ======= Factors of all terms present in the equation. Examples ======== >>> from sympy import symbols >>> from sympy.solvers.solveset import _term_factors >>> x = symbols('x') >>> list(_term_factors(-2 - x2 + x(x + 1))) [-2, -1, x2, x, x + 1] """ for add_arg in Add.make_args(f): for mul_arg in Mul.make_args(add_arg): yield mul_arg def _solve_exponential(lhs, rhs, symbol, domain): r""" Helper function for solving (supported) exponential equations. Exponential equations are the sum of (currently) at most two terms with one or both of them having a power with a symbol-dependent exponent. For example .. math:: 5^{2x + 3} - 5^{3x - 1} .. math:: 4^{5 - 9x} - e^{2 - x} Parameters ========== lhs, rhs : Expr The exponential equation to be solved, `lhs = rhs` symbol : Symbol The variable in which the equation is solved domain : Set A set over which the equation is solved. Returns ======= A set of solutions satisfying the given equation. A ``ConditionSet`` if the equation is unsolvable or if the assumptions are not properly defined, in that case a different style of ``ConditionSet`` is returned having the solution(s) of the equation with the desired assumptions. Examples ======== >>> from sympy.solvers.solveset import _solve_exponential as solve_expo >>> from sympy import symbols, S >>> x = symbols('x', real=True) >>> a, b = symbols('a b') >>> solve_expo(2x + 3x - 5x, 0, x, S.Reals) # not solvable ConditionSet(x, Eq(2x + 3x - 5x, 0), Reals) >>> solve_expo(ax - bx, 0, x, S.Reals) # solvable but incorrect assumptions ConditionSet(x, (a > 0) & (b > 0), {0}) >>> solve_expo(3(2x) - 2(x + 3), 0, x, S.Reals) {-3log(2)/(-2log(3) + log(2))} >>> solve_expo(2x - 4x, 0, x, S.Reals) {0} Proof of correctness of the method The logarithm function is the inverse of the exponential function. The defining relation between exponentiation and logarithm is: .. math:: {\log_b x} = y \enspace if \enspace b^y = x Therefore if we are given an equation with exponent terms, we can convert every term to its corresponding logarithmic form. This is achieved by taking logarithms and expanding the equation using logarithmic identities so that it can easily be handled by ``solveset``. For example: .. math:: 3^{2x} = 2^{x + 3} Taking log both sides will reduce the equation to .. math:: (2x)\log(3) = (x + 3)\log(2) This form can be easily handed by ``solveset``. """ unsolved_result = ConditionSet(symbol, Eq(lhs - rhs, 0), domain) newlhs = powdenest(lhs) if lhs != newlhs: # it may also be advantageous to factor the new expr return _solveset(factor(newlhs - rhs), symbol, domain) # try again with _solveset if not (isinstance(lhs, Add) and len(lhs.args) == 2): # solving for the sum of more than two powers is possible # but not yet implemented return unsolved_result if rhs != 0: return unsolved_result a, b = list(ordered(lhs.args)) a_term = a.as_independent(symbol)[1] b_term = b.as_independent(symbol)[1] a_base, a_exp = a_term.base, a_term.exp b_base, b_exp = b_term.base, b_term.exp from sympy.functions.elementary.complexes import im if domain.is_subset(S.Reals): conditions = And( a_base > 0, b_base > 0, Eq(im(a_exp), 0), Eq(im(b_exp), 0)) else: conditions = And( Ne(a_base, 0), Ne(b_base, 0)) L, R = map(lambda i: expand_log(log(i), force=True), (a, -b)) solutions = _solveset(L - R, symbol, domain) return ConditionSet(symbol, conditions, solutions) def _is_exponential(f, symbol): r""" Return ``True`` if one or more terms contain ``symbol`` only in exponents, else ``False``. Parameters ========== f : Expr The equation to be checked symbol : Symbol The variable in which the equation is checked Examples ======== >>> from sympy import symbols, cos, exp >>> from sympy.solvers.solveset import _is_exponential as check >>> x, y = symbols('x y') >>> check(y, y) False >>> check(xy - 1, y) True >>> check(xy2y - 1, y) True >>> check(exp(x + 3) + 3x, x) True >>> check(cos(2x), x) False Philosophy behind the helper The function extracts each term of the equation and checks if it is of exponential form w.r.t ``symbol``. """ rv = False for expr_arg in _term_factors(f): if symbol not in expr_arg.free_symbols: continue if (isinstance(expr_arg, Pow) and symbol not in expr_arg.base.free_symbols or isinstance(expr_arg, exp)): rv = True # symbol in exponent else: return False # dependent on symbol in non-exponential way return rv def _solve_logarithm(lhs, rhs, symbol, domain): r""" Helper to solve logarithmic equations which are reducible to a single instance of `\log`. Logarithmic equations are (currently) the equations that contains `\log` terms which can be reduced to a single `\log` term or a constant using various logarithmic identities. For example: .. math:: \log(x) + \log(x - 4) can be reduced to: .. math:: \log(x(x - 4)) Parameters ========== lhs, rhs : Expr The logarithmic equation to be solved, `lhs = rhs` symbol : Symbol The variable in which the equation is solved domain : Set A set over which the equation is solved. Returns ======= A set of solutions satisfying the given equation. A ``ConditionSet`` if the equation is unsolvable. Examples ======== >>> from sympy import symbols, log, S >>> from sympy.solvers.solveset import _solve_logarithm as solve_log >>> x = symbols('x') >>> f = log(x - 3) + log(x + 3) >>> solve_log(f, 0, x, S.Reals) {-sqrt(10), sqrt(10)} * Proof of correctness A logarithm is another way to write exponent and is defined by .. math:: {\log_b x} = y \enspace if \enspace b^y = x When one side of the equation contains a single logarithm, the equation can be solved by rewriting the equation as an equivalent exponential equation as defined above. But if one side contains more than one logarithm, we need to use the properties of logarithm to condense it into a single logarithm. Take for example .. math:: \log(2x) - 15 = 0 contains single logarithm, therefore we can directly rewrite it to exponential form as .. math:: x = \frac{e^{15}}{2} But if the equation has more than one logarithm as .. math:: \log(x - 3) + \log(x + 3) = 0 we use logarithmic identities to convert it into a reduced form Using, .. math:: \log(a) + \log(b) = \log(ab) the equation becomes, .. math:: \log((x - 3)(x + 3)) This equation contains one logarithm and can be solved by rewriting to exponents. """ new_lhs = logcombine(lhs, force=True) new_f = new_lhs - rhs return _solveset(new_f, symbol, domain) def _is_logarithmic(f, symbol): r""" Return ``True`` if the equation is in the form `a\log(f(x)) + b\log(g(x)) + ... + c` else ``False``. Parameters ========== f : Expr The equation to be checked symbol : Symbol The variable in which the equation is checked Returns ======= ``True`` if the equation is logarithmic otherwise ``False``. Examples ======== >>> from sympy import symbols, tan, log >>> from sympy.solvers.solveset import _is_logarithmic as check >>> x, y = symbols('x y') >>> check(log(x + 2) - log(x + 3), x) True >>> check(tan(log(2x)), x) False >>> check(xlog(x), x) False >>> check(x + log(x), x) False >>> check(y + log(x), x) True * Philosophy behind the helper The function extracts each term and checks whether it is logarithmic w.r.t ``symbol``. """ rv = False for term in Add.make_args(f): saw_log = False for term_arg in Mul.make_args(term): if symbol not in term_arg.free_symbols: continue if isinstance(term_arg, log): if saw_log: return False # more than one log in term saw_log = True else: return False # dependent on symbol in non-log way if saw_log: rv = True return rv def _transolve(f, symbol, domain): r""" Function to solve transcendental equations. It is a helper to ``solveset`` and should be used internally. ``_transolve`` currently supports the following class of equations: - Exponential equations - Logarithmic equations Parameters ========== f : Any transcendental equation that needs to be solved. This needs to be an expression, which is assumed to be equal to ``0``. symbol : The variable for which the equation is solved. This needs to be of class ``Symbol``. domain : A set over which the equation is solved. This needs to be of class ``Set``. Returns ======= Set A set of values for ``symbol`` for which ``f`` is equal to zero. An ``EmptySet`` is returned if ``f`` does not have solutions in respective domain. A ``ConditionSet`` is returned as unsolved object if algorithms to evaluate complete solution are not yet implemented. How to use ``_transolve`` ========================= ``_transolve`` should not be used as an independent function, because it assumes that the equation (``f``) and the ``symbol`` comes from ``solveset`` and might have undergone a few modification(s). To use ``_transolve`` as an independent function the equation (``f``) and the ``symbol`` should be passed as they would have been by ``solveset``. Examples ======== >>> from sympy.solvers.solveset import _transolve as transolve >>> from sympy.solvers.solvers import _tsolve as tsolve >>> from sympy import symbols, S, pprint >>> x = symbols('x', real=True) # assumption added >>> transolve(5(x - 3) - 3(2x + 1), x, S.Reals) {-(log(3) + 3log(5))/(-log(5) + 2log(3))} How ``_transolve`` works ======================== ``_transolve`` uses two types of helper functions to solve equations of a particular class: Identifying helpers: To determine whether a given equation belongs to a certain class of equation or not. Returns either ``True`` or ``False``. Solving helpers: Once an equation is identified, a corresponding helper either solves the equation or returns a form of the equation that ``solveset`` might better be able to handle. Philosophy behind the module The purpose of ``_transolve`` is to take equations which are not already polynomial in their generator(s) and to either recast them as such through a valid transformation or to solve them outright. A pair of helper functions for each class of supported transcendental functions are employed for this purpose. One identifies the transcendental form of an equation and the other either solves it or recasts it into a tractable form that can be solved by ``solveset``. For example, an equation in the form `ab^{f(x)} - cd^{g(x)} = 0` can be transformed to `\log(a) + f(x)\log(b) - \log(c) - g(x)\log(d) = 0` (under certain assumptions) and this can be solved with ``solveset`` if `f(x)` and `g(x)` are in polynomial form. How ``_transolve`` is better than ``_tsolve`` ============================================= 1) Better output ``_transolve`` provides expressions in a more simplified form. Consider a simple exponential equation >>> f = 3*(2x) - 2*(x + 3) >>> pprint(transolve(f, x, S.Reals), use_unicode=False) -3log(2) {------------------} -2log(3) + log(2) >>> pprint(tsolve(f, x), use_unicode=False) / 3 \ \| --------\| \| log(2/9)\| [-log\2 /] 2) Extensible The API of ``_transolve`` is designed such that it is easily extensible, i.e. the code that solves a given class of equations is encapsulated in a helper and not mixed in with the code of ``_transolve`` itself. 3) Modular ``_transolve`` is designed to be modular i.e, for every class of equation a separate helper for identification and solving is implemented. This makes it easy to change or modify any of the method implemented directly in the helpers without interfering with the actual structure of the API. 4) Faster Computation Solving equation via ``_transolve`` is much faster as compared to ``_tsolve``. In ``solve``, attempts are made computing every possibility to get the solutions. This series of attempts makes solving a bit slow. In ``_transolve``, computation begins only after a particular type of equation is identified. How to add new class of equations ================================= Adding a new class of equation solver is a three-step procedure: - Identify the type of the equations Determine the type of the class of equations to which they belong: it could be of ``Add``, ``Pow``, etc. types. Separate internal functions are used for each type. Write identification and solving helpers and use them from within the routine for the given type of equation (after adding it, if necessary). Something like: .. code-block:: python def add_type(lhs, rhs, x): .... if _is_exponential(lhs, x): new_eq = _solve_exponential(lhs, rhs, x) .... rhs, lhs = eq.as_independent(x) if lhs.is_Add: result = add_type(lhs, rhs, x) - Define the identification helper. - Define the solving helper. Apart from this, a few other things needs to be taken care while adding an equation solver: - Naming conventions: Name of the identification helper should be as ``_is_class`` where class will be the name or abbreviation of the class of equation. The solving helper will be named as ``_solve_class``. For example: for exponential equations it becomes ``_is_exponential`` and ``_solve_expo``. - The identifying helpers should take two input parameters, the equation to be checked and the variable for which a solution is being sought, while solving helpers would require an additional domain parameter. - Be sure to consider corner cases. - Add tests for each helper. - Add a docstring to your helper that describes the method implemented. The documentation of the helpers should identify: - the purpose of the helper, - the method used to identify and solve the equation, - a proof of correctness - the return values of the helpers """ def add_type(lhs, rhs, symbol, domain): """ Helper for ``_transolve`` to handle equations of ``Add`` type, i.e. equations taking the form as ``af(x) + bg(x) + .... = c``. For example: 4x + 8x = 0 """ result = ConditionSet(symbol, Eq(lhs - rhs, 0), domain) # check if it is exponential type equation if _is_exponential(lhs, symbol): result = _solve_exponential(lhs, rhs, symbol, domain) # check if it is logarithmic type equation elif _is_logarithmic(lhs, symbol): result = _solve_logarithm(lhs, rhs, symbol, domain) return result result = ConditionSet(symbol, Eq(f, 0), domain) # invert_complex handles the call to the desired inverter based # on the domain specified. lhs, rhs_s = invert_complex(f, 0, symbol, domain) if isinstance(rhs_s, FiniteSet): assert (len(rhs_s.args)) == 1 rhs = rhs_s.args[0] if lhs.is_Add: result = add_type(lhs, rhs, symbol, domain) else: result = rhs_s return result def solveset(f, symbol=None, domain=S.Complexes): r"""Solves a given inequality or equation with set as output Parameters ========== f : Expr or a relational. The target equation or inequality symbol : Symbol The variable for which the equation is solved domain : Set The domain over which the equation is solved Returns ======= Set A set of values for `symbol` for which `f` is True or is equal to zero. An `EmptySet` is returned if `f` is False or nonzero. A `ConditionSet` is returned as unsolved object if algorithms to evaluate complete solution are not yet implemented. `solveset` claims to be complete in the solution set that it returns. Raises ====== NotImplementedError The algorithms to solve inequalities in complex domain are not yet implemented. ValueError The input is not valid. RuntimeError It is a bug, please report to the github issue tracker. Notes ===== Python interprets 0 and 1 as False and True, respectively, but in this function they refer to solutions of an expression. So 0 and 1 return the Domain and EmptySet, respectively, while True and False return the opposite (as they are assumed to be solutions of relational expressions). See Also ======== solveset_real: solver for real domain solveset_complex: solver for complex domain Examples ======== >>> from sympy import exp, sin, Symbol, pprint, S >>> from sympy.solvers.solveset import solveset, solveset_real The default domain is complex. Not specifying a domain will lead to the solving of the equation in the complex domain (and this is not affected by the assumptions on the symbol): >>> x = Symbol('x') >>> pprint(solveset(exp(x) - 1, x), use_unicode=False) {2nIpi \| n in Integers} >>> x = Symbol('x', real=True) >>> pprint(solveset(exp(x) - 1, x), use_unicode=False) {2nIpi \| n in Integers} * If you want to use `solveset` to solve the equation in the real domain, provide a real domain. (Using ``solveset_real`` does this automatically.) >>> R = S.Reals >>> x = Symbol('x') >>> solveset(exp(x) - 1, x, R) {0} >>> solveset_real(exp(x) - 1, x) {0} The solution is mostly unaffected by assumptions on the symbol, but there may be some slight difference: >>> pprint(solveset(sin(x)/x,x), use_unicode=False) ({2npi \| n in Integers} \ {0}) U ({2npi + pi \| n in Integers} \ {0}) >>> p = Symbol('p', positive=True) >>> pprint(solveset(sin(p)/p, p), use_unicode=False) {2npi \| n in Integers} U {2npi + pi \| n in Integers} * Inequalities can be solved over the real domain only. Use of a complex domain leads to a NotImplementedError. >>> solveset(exp(x) > 1, x, R) Interval.open(0, oo) """ f = sympify(f) symbol = sympify(symbol) if f is S.true: return domain if f is S.false: return S.EmptySet if not isinstance(f, (Expr, Number)): raise ValueError("%s is not a valid SymPy expression" % f) if not isinstance(symbol, Expr) and symbol is not None: raise ValueError("%s is not a valid SymPy symbol" % symbol) if not isinstance(domain, Set): raise ValueError("%s is not a valid domain" %(domain)) free_symbols = f.free_symbols if symbol is None and not free_symbols: b = Eq(f, 0) if b is S.true: return domain elif b is S.false: return S.EmptySet else: raise NotImplementedError(filldedent(''' relationship between value and 0 is unknown: %s''' % b)) if symbol is None: if len(free_symbols) == 1: symbol = free_symbols.pop() elif free_symbols: raise ValueError(filldedent(''' The independent variable must be specified for a multivariate equation.''')) elif not isinstance(symbol, Symbol): f, s, swap = recast_to_symbols([f], [symbol]) # the xreplace will be needed if a ConditionSet is returned return solveset(f[0], s[0], domain).xreplace(swap) if domain.is_subset(S.Reals): if not symbol.is_real: assumptions = symbol.assumptions0 assumptions['real'] = True try: r = Dummy('r', *assumptions) return solveset(f.xreplace({symbol: r}), r, domain ).xreplace({r: symbol}) except InconsistentAssumptions: pass # Abs has its own handling method which avoids the # rewriting property that the first piece of abs(x) # is for x >= 0 and the 2nd piece for x < 0 -- solutions # can look better if the 2nd condition is x <= 0. Since # the solution is a set, duplication of results is not # an issue, e.g. {y, -y} when y is 0 will be {0} f, mask = _masked(f, Abs) f = f.rewrite(Piecewise) # everything that's not an Abs for d, e in mask: # everything in* an Abs e = e.func(e.args[0].rewrite(Piecewise)) f = f.xreplace({d: e}) f = piecewise_fold(f) return _solveset(f, symbol, domain, _check=True) def solveset_real(f, symbol): return solveset(f, symbol, S.Reals) def solveset_complex(f, symbol): return solveset(f, symbol, S.Complexes) def solvify(f, symbol, domain): """Solves an equation using solveset and returns the solution in accordance with the `solve` output API. Returns ======= We classify the output based on the type of solution returned by `solveset`. Solution \| Output ---------------------------------------- FiniteSet \| list ImageSet, \| list (if `f` is periodic) Union \| EmptySet \| empty list Others \| None Raises ====== NotImplementedError A ConditionSet is the input. Examples ======== >>> from sympy.solvers.solveset import solvify, solveset >>> from sympy.abc import x >>> from sympy import S, tan, sin, exp >>> solvify(x*2 - 9, x, S.Reals) [-3, 3] >>> solvify(sin(x) - 1, x, S.Reals) [pi/2] >>> solvify(tan(x), x, S.Reals) [0] >>> solvify(exp(x) - 1, x, S.Complexes) >>> solvify(exp(x) - 1, x, S.Reals) [0] """ solution_set = solveset(f, symbol, domain) result = None if solution_set is S.EmptySet: result = [] elif isinstance(solution_set, ConditionSet): raise NotImplementedError('solveset is unable to solve this equation.') elif isinstance(solution_set, FiniteSet): result = list(solution_set) else: period = periodicity(f, symbol) if period is not None: solutions = S.EmptySet iter_solutions = () if isinstance(solution_set, ImageSet): iter_solutions = (solution_set,) elif isinstance(solution_set, Union): if all(isinstance(i, ImageSet) for i in solution_set.args): iter_solutions = solution_set.args for solution in iter_solutions: solutions += solution.intersect(Interval(0, period, False, True)) if isinstance(solutions, FiniteSet): result = list(solutions) else: solution = solution_set.intersect(domain) if isinstance(solution, FiniteSet): result += solution return result ############################################################################### ################################ LINSOLVE ##################################### ############################################################################### def linear_coeffs(eq, syms, *_kw): """Return a list whose elements are the coefficients of the corresponding symbols in the sum of terms in ``eq``. The additive constant is returned as the last element of the list. Examples ======== >>> from sympy.solvers.solveset import linear_coeffs >>> from sympy.abc import x, y, z >>> linear_coeffs(3x + 2y - 1, x, y) [3, 2, -1] It is not necessary to expand the expression: >>> linear_coeffs(x + y(z(x3 + 2) + 3), x) [3yz + 1, y(2z + 3)] But if there are nonlinear or cross terms -- even if they would cancel after simplification -- an error is raised so the situation does not pass silently past the caller's attention: >>> eq = 1/x(x - 1) + 1/x >>> linear_coeffs(eq.expand(), x) [0, 1] >>> linear_coeffs(eq, x) Traceback (most recent call last): ... ValueError: nonlinear term encountered: 1/x >>> linear_coeffs(x(y + 1) - xy, x, y) Traceback (most recent call last): ... ValueError: nonlinear term encountered: x(y + 1) """ d = defaultdict(list) c, terms = _sympify(eq).as_coeff_add(syms) d[0].extend(Add.make_args(c)) for t in terms: m, f = t.as_coeff_mul(syms) if len(f) != 1: break f = f[0] if f in syms: d[f].append(m) elif f.is_Add: d1 = linear_coeffs(f, syms, {'dict': True}) d[0].append(md1.pop(0)) for xf, vf in d1.items(): d[xf].append(mvf) else: break else: for k, v in d.items(): d[k] = Add(v) if not _kw: return [d.get(s, S.Zero) for s in syms] + [d[0]] return d # default is still list but this won't matter raise ValueError('nonlinear term encountered: %s' % t) def linear_eq_to_matrix(equations, symbols): r""" Converts a given System of Equations into Matrix form. Here `equations` must be a linear system of equations in `symbols`. Element M[i, j] corresponds to the coefficient of the jth symbol in the ith equation. The Matrix form corresponds to the augmented matrix form. For example: .. math:: 4x + 2y + 3z = 1 .. math:: 3x + y + z = -6 .. math:: 2x + 4y + 9z = 2 This system would return `A` & `b` as given below: :: [ 4 2 3 ] [ 1 ] A = [ 3 1 1 ] b = [-6 ] [ 2 4 9 ] [ 2 ] The only simplification performed is to convert `Eq(a, b) -> a - b`. Raises ====== ValueError The equations contain a nonlinear term. The symbols are not given or are not unique. Examples ======== >>> from sympy import linear_eq_to_matrix, symbols >>> c, x, y, z = symbols('c, x, y, z') The coefficients (numerical or symbolic) of the symbols will be returned as matrices: >>> eqns = [cx + z - 1 - c, y + z, x - y] >>> A, b = linear_eq_to_matrix(eqns, [x, y, z]) >>> A Matrix([ [c, 0, 1], [0, 1, 1], [1, -1, 0]]) >>> b Matrix([ [c + 1], [ 0], [ 0]]) This routine does not simplify expressions and will raise an error if nonlinearity is encountered: >>> eqns = [ ... (x*2 - 3x)/(x - 3) - 3, ... y*2 - 3y - y(y - 4) + x - 4] >>> linear_eq_to_matrix(eqns, [x, y]) Traceback (most recent call last): ... ValueError: The term (x2 - 3x)/(x - 3) is nonlinear in {x, y} Simplifying these equations will discard the removable singularity in the first, reveal the linear structure of the second: >>> [e.simplify() for e in eqns] [x - 3, x + y - 4] Any such simplification needed to eliminate nonlinear terms must be done before calling this routine. """ if not symbols: raise ValueError(filldedent(''' Symbols must be given, for which coefficients are to be found. ''')) if hasattr(symbols[0], '__iter__'): symbols = symbols[0] for i in symbols: if not isinstance(i, Symbol): raise ValueError(filldedent(''' Expecting a Symbol but got %s ''' % i)) if has_dups(symbols): raise ValueError('Symbols must be unique') equations = sympify(equations) if isinstance(equations, MatrixBase): equations = list(equations) elif isinstance(equations, Expr): equations = [equations] elif not is_sequence(equations): raise ValueError(filldedent(''' Equation(s) must be given as a sequence, Expr, Eq or Matrix. ''')) A, b = [], [] for i, f in enumerate(equations): if isinstance(f, Equality): f = f.rewrite(Add, evaluate=False) coeff_list = linear_coeffs(f, symbols) b.append(-coeff_list.pop()) A.append(coeff_list) A, b = map(Matrix, (A, b)) return A, b def linsolve(system, symbols): r""" Solve system of N linear equations with M variables; both underdetermined and overdetermined systems are supported. The possible number of solutions is zero, one or infinite. Zero solutions throws a ValueError, whereas infinite solutions are represented parametrically in terms of the given symbols. For unique solution a FiniteSet of ordered tuples is returned. All Standard input formats are supported: For the given set of Equations, the respective input types are given below: .. math:: 3x + 2y - z = 1 .. math:: 2x - 2y + 4z = -2 .. math:: 2x - y + 2z = 0 * Augmented Matrix Form, `system` given below: :: [3 2 -1 1] system = [2 -2 4 -2] [2 -1 2 0] * List Of Equations Form `system = [3x + 2y - z - 1, 2x - 2y + 4z + 2, 2x - y + 2z]` * Input A & b Matrix Form (from Ax = b) are given as below: :: [3 2 -1 ] [ 1 ] A = [2 -2 4 ] b = [ -2 ] [2 -1 2 ] [ 0 ] `system = (A, b)` Symbols can always be passed but are actually only needed when 1) a system of equations is being passed and 2) the system is passed as an underdetermined matrix and one wants to control the name of the free variables in the result. An error is raised if no symbols are used for case 1, but if no symbols are provided for case 2, internally generated symbols will be provided. When providing symbols for case 2, there should be at least as many symbols are there are columns in matrix A. The algorithm used here is Gauss-Jordan elimination, which results, after elimination, in a row echelon form matrix. Returns ======= A FiniteSet containing an ordered tuple of values for the unknowns for which the `system` has a solution. (Wrapping the tuple in FiniteSet is used to maintain a consistent output format throughout solveset.) Returns EmptySet(), if the linear system is inconsistent. Raises ====== ValueError The input is not valid. The symbols are not given. Examples ======== >>> from sympy import Matrix, S, linsolve, symbols >>> x, y, z = symbols("x, y, z") >>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 10]]) >>> b = Matrix([3, 6, 9]) >>> A Matrix([ [1, 2, 3], [4, 5, 6], [7, 8, 10]]) >>> b Matrix([ [3], [6], [9]]) >>> linsolve((A, b), [x, y, z]) {(-1, 2, 0)} * Parametric Solution: In case the system is underdetermined, the function will return a parametric solution in terms of the given symbols. Those that are free will be returned unchanged. e.g. in the system below, `z` is returned as the solution for variable z; it can take on any value. >>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) >>> b = Matrix([3, 6, 9]) >>> linsolve((A, b), x, y, z) {(z - 1, 2 - 2z, z)} If no symbols are given, internally generated symbols will be used. The `tau0` in the 3rd position indicates (as before) that the 3rd variable -- whatever it's named -- can take on any value: >>> linsolve((A, b)) {(tau0 - 1, 2 - 2tau0, tau0)} * List of Equations as input >>> Eqns = [3x + 2y - z - 1, 2x - 2y + 4z + 2, - x + y/2 - z] >>> linsolve(Eqns, x, y, z) {(1, -2, -2)} Augmented Matrix as input >>> aug = Matrix([[2, 1, 3, 1], [2, 6, 8, 3], [6, 8, 18, 5]]) >>> aug Matrix([ [2, 1, 3, 1], [2, 6, 8, 3], [6, 8, 18, 5]]) >>> linsolve(aug, x, y, z) {(3/10, 2/5, 0)} * Solve for symbolic coefficients >>> a, b, c, d, e, f = symbols('a, b, c, d, e, f') >>> eqns = [ax + by - c, dx + ey - f] >>> linsolve(eqns, x, y) {((-bf + ce)/(ae - bd), (af - cd)/(ae - bd))} * A degenerate system returns solution as set of given symbols. >>> system = Matrix(([0, 0, 0], [0, 0, 0], [0, 0, 0])) >>> linsolve(system, x, y) {(x, y)} * For an empty system linsolve returns empty set >>> linsolve([], x) EmptySet() * An error is raised if, after expansion, any nonlinearity is detected: >>> linsolve([x(1/x - 1), (y - 1)2 - y2 + 1], x, y) {(1, 1)} >>> linsolve([x2 - 1], x) Traceback (most recent call last): ... ValueError: The term x2 is nonlinear in {x} """ if not system: return S.EmptySet # If second argument is an iterable if symbols and hasattr(symbols[0], '__iter__'): symbols = symbols[0] sym_gen = isinstance(symbols, GeneratorType) swap = {} b = None # if we don't get b the input was bad syms_needed_msg = None # unpack system if hasattr(system, '__iter__'): # 1). (A, b) if len(system) == 2 and isinstance(system[0], Matrix): A, b = system # 2). (eq1, eq2, ...) if not isinstance(system[0], Matrix): if sym_gen or not symbols: raise ValueError(filldedent(''' When passing a system of equations, the explicit symbols for which a solution is being sought must be given as a sequence, too. ''')) system = [ _mexpand(i.lhs - i.rhs if isinstance(i, Eq) else i, recursive=True) for i in system] system, symbols, swap = recast_to_symbols(system, symbols) A, b = linear_eq_to_matrix(system, symbols) syms_needed_msg = 'free symbols in the equations provided' elif isinstance(system, Matrix) and not ( symbols and not isinstance(symbols, GeneratorType) and isinstance(symbols[0], Matrix)): # 3). A augmented with b A, b = system[:, :-1], system[:, -1:] if b is None: raise ValueError("Invalid arguments") syms_needed_msg = syms_needed_msg or 'columns of A' if sym_gen: symbols = [next(symbols) for i in range(A.cols)] if any(set(symbols) & (A.free_symbols \| b.free_symbols)): raise ValueError(filldedent(''' At least one of the symbols provided already appears in the system to be solved. One way to avoid this is to use Dummy symbols in the generator, e.g. numbered_symbols('%s', cls=Dummy) ''' % symbols[0].name.rstrip('1234567890'))) try: solution, params, free_syms = A.gauss_jordan_solve(b, freevar=True) except ValueError: # No solution return S.EmptySet # Replace free parameters with free symbols if params: if not symbols: symbols = [_ for _ in params] # re-use the parameters but put them in order # params [x, y, z] # free_symbols [2, 0, 4] # idx [1, 0, 2] idx = list(zip(sorted(zip(free_syms, range(len(free_syms))))))[1] # simultaneous replacements {y: x, x: y, z: z} replace_dict = dict(zip(symbols, [symbols[i] for i in idx])) elif len(symbols) >= A.cols: replace_dict = {v: symbols[free_syms[k]] for k, v in enumerate(params)} else: raise IndexError(filldedent(''' the number of symbols passed should have a length equal to the number of %s. ''' % syms_needed_msg)) solution = [sol.xreplace(replace_dict) for sol in solution] solution = [simplify(sol).xreplace(swap) for sol in solution] return FiniteSet(tuple(solution)) ############################################################################## # ------------------------------nonlinsolve ---------------------------------# ############################################################################## def _return_conditionset(eqs, symbols): # return conditionset condition_set = ConditionSet( Tuple(symbols), FiniteSet(eqs), S.Complexes) return condition_set def substitution(system, symbols, result=[{}], known_symbols=[], exclude=[], all_symbols=None): r""" Solves the `system` using substitution method. It is used in `nonlinsolve`. This will be called from `nonlinsolve` when any equation(s) is non polynomial equation. Parameters ========== system : list of equations The target system of equations symbols : list of symbols to be solved. The variable(s) for which the system is solved known_symbols : list of solved symbols Values are known for these variable(s) result : An empty list or list of dict If No symbol values is known then empty list otherwise symbol as keys and corresponding value in dict. exclude : Set of expression. Mostly denominator expression(s) of the equations of the system. Final solution should not satisfy these expressions. all_symbols : known_symbols + symbols(unsolved). Returns ======= A FiniteSet of ordered tuple of values of `all_symbols` for which the `system` has solution. Order of values in the tuple is same as symbols present in the parameter `all_symbols`. If parameter `all_symbols` is None then same as symbols present in the parameter `symbols`. Please note that general FiniteSet is unordered, the solution returned here is not simply a FiniteSet of solutions, rather it is a FiniteSet of ordered tuple, i.e. the first & only argument to FiniteSet is a tuple of solutions, which is ordered, & hence the returned solution is ordered. Also note that solution could also have been returned as an ordered tuple, FiniteSet is just a wrapper `{}` around the tuple. It has no other significance except for the fact it is just used to maintain a consistent output format throughout the solveset. Raises ====== ValueError The input is not valid. The symbols are not given. AttributeError The input symbols are not `Symbol` type. Examples ======== >>> from sympy.core.symbol import symbols >>> x, y = symbols('x, y', real=True) >>> from sympy.solvers.solveset import substitution >>> substitution([x + y], [x], [{y: 1}], [y], set([]), [x, y]) {(-1, 1)} * when you want soln should not satisfy eq `x + 1 = 0` >>> substitution([x + y], [x], [{y: 1}], [y], set([x + 1]), [y, x]) EmptySet() >>> substitution([x + y], [x], [{y: 1}], [y], set([x - 1]), [y, x]) {(1, -1)} >>> substitution([x + y - 1, y - x*2 + 5], [x, y]) {(-3, 4), (2, -1)} Returns both real and complex solution >>> x, y, z = symbols('x, y, z') >>> from sympy import exp, sin >>> substitution([exp(x) - sin(y), y*2 - 4], [x, y]) {(log(sin(2)), 2), (ImageSet(Lambda(_n, I(2_npi + pi) + log(sin(2))), Integers), -2), (ImageSet(Lambda(_n, 2_nIpi + Mod(log(sin(2)), 2Ipi)), Integers), 2)} >>> eqs = [z2 + exp(2x) - sin(y), -3 + exp(-y)] >>> substitution(eqs, [y, z]) {(-log(3), -sqrt(-exp(2x) - sin(log(3)))), (-log(3), sqrt(-exp(2x) - sin(log(3)))), (ImageSet(Lambda(_n, 2_nIpi + Mod(-log(3), 2Ipi)), Integers), ImageSet(Lambda(_n, -sqrt(-exp(2x) + sin(2_nIpi + Mod(-log(3), 2Ipi)))), Integers)), (ImageSet(Lambda(_n, 2_nIpi + Mod(-log(3), 2Ipi)), Integers), ImageSet(Lambda(_n, sqrt(-exp(2x) + sin(2_nIpi + Mod(-log(3), 2Ipi)))), Integers))} """ from sympy import Complement from sympy.core.compatibility import is_sequence if not system: return S.EmptySet if not symbols: msg = ('Symbols must be given, for which solution of the ' 'system is to be found.') raise ValueError(filldedent(msg)) if not is_sequence(symbols): msg = ('symbols should be given as a sequence, e.g. a list.' 'Not type %s: %s') raise TypeError(filldedent(msg % (type(symbols), symbols))) sym = getattr(symbols[0], 'is_Symbol', False) if not sym: msg = ('Iterable of symbols must be given as ' 'second argument, not type %s: %s') raise ValueError(filldedent(msg % (type(symbols[0]), symbols[0]))) # By default `all_symbols` will be same as `symbols` if all_symbols is None: all_symbols = symbols old_result = result # storing complements and intersection for particular symbol complements = {} intersections = {} # when total_solveset_call is equals to total_conditionset # means solvest fail to solve all the eq. total_conditionset = -1 total_solveset_call = -1 def _unsolved_syms(eq, sort=False): """Returns the unsolved symbol present in the equation `eq`. """ free = eq.free_symbols unsolved = (free - set(known_symbols)) & set(all_symbols) if sort: unsolved = list(unsolved) unsolved.sort(key=default_sort_key) return unsolved # end of _unsolved_syms() # sort such that equation with the fewest potential symbols is first. # means eq with less number of variable first in the list. eqs_in_better_order = list( ordered(system, lambda _: len(_unsolved_syms(_)))) def add_intersection_complement(result, sym_set, *flags): # If solveset have returned some intersection/complement # for any symbol. It will be added in final solution. final_result = [] for res in result: res_copy = res for key_res, value_res in res.items(): # Intersection/complement is in Interval or Set. intersection_true = flags.get('Intersection', True) complements_true = flags.get('Complement', True) for key_sym, value_sym in sym_set.items(): if key_sym == key_res: if intersection_true: # testcase is not added for this line(intersection) new_value = \ Intersection(FiniteSet(value_res), value_sym) if new_value is not S.EmptySet: res_copy[key_res] = new_value if complements_true: new_value = \ Complement(FiniteSet(value_res), value_sym) if new_value is not S.EmptySet: res_copy[key_res] = new_value final_result.append(res_copy) return final_result # end of def add_intersection_complement() def _extract_main_soln(sol, soln_imageset): """separate the Complements, Intersections, ImageSet lambda expr and it's base_set. """ # if there is union, then need to check # Complement, Intersection, Imageset. # Order should not be changed. if isinstance(sol, Complement): # extract solution and complement complements[sym] = sol.args[1] sol = sol.args[0] # complement will be added at the end # using `add_intersection_complement` method if isinstance(sol, Intersection): # Interval/Set will be at 0th index always if sol.args[0] != Interval(-oo, oo): # sometimes solveset returns soln # with intersection `S.Reals`, to confirm that # soln is in `domain=S.Reals` or not. We don't consider # that intersection. intersections[sym] = sol.args[0] sol = sol.args[1] # after intersection and complement Imageset should # be checked. if isinstance(sol, ImageSet): soln_imagest = sol expr2 = sol.lamda.expr sol = FiniteSet(expr2) soln_imageset[expr2] = soln_imagest # if there is union of Imageset or other in soln. # no testcase is written for this if block if isinstance(sol, Union): sol_args = sol.args sol = S.EmptySet # We need in sequence so append finteset elements # and then imageset or other. for sol_arg2 in sol_args: if isinstance(sol_arg2, FiniteSet): sol += sol_arg2 else: # ImageSet, Intersection, complement then # append them directly sol += FiniteSet(sol_arg2) if not isinstance(sol, FiniteSet): sol = FiniteSet(sol) return sol, soln_imageset # end of def _extract_main_soln() # helper function for _append_new_soln def _check_exclude(rnew, imgset_yes): rnew_ = rnew if imgset_yes: # replace all dummy variables (Imageset lambda variables) # with zero before `checksol`. Considering fundamental soln # for `checksol`. rnew_copy = rnew.copy() dummy_n = imgset_yes[0] for key_res, value_res in rnew_copy.items(): rnew_copy[key_res] = value_res.subs(dummy_n, 0) rnew_ = rnew_copy # satisfy_exclude == true if it satisfies the expr of `exclude` list. try: # something like : `Mod(-log(3), 2Ipi)` can't be # simplified right now, so `checksol` returns `TypeError`. # when this issue is fixed this try block should be # removed. Mod(-log(3), 2Ipi) == -log(3) satisfy_exclude = any( checksol(d, rnew_) for d in exclude) except TypeError: satisfy_exclude = None return satisfy_exclude # end of def _check_exclude() # helper function for _append_new_soln def _restore_imgset(rnew, original_imageset, newresult): restore_sym = set(rnew.keys()) & \ set(original_imageset.keys()) for key_sym in restore_sym: img = original_imageset[key_sym] rnew[key_sym] = img if rnew not in newresult: newresult.append(rnew) # end of def _restore_imgset() def _append_eq(eq, result, res, delete_soln, n=None): u = Dummy('u') if n: eq = eq.subs(n, 0) satisfy = checksol(u, u, eq, minimal=True) if satisfy is False: delete_soln = True res = {} else: result.append(res) return result, res, delete_soln def _append_new_soln(rnew, sym, sol, imgset_yes, soln_imageset, original_imageset, newresult, eq=None): """If `rnew` (A dict <symbol: soln>) contains valid soln append it to `newresult` list. `imgset_yes` is (base, dummy_var) if there was imageset in previously calculated result(otherwise empty tuple). `original_imageset` is dict of imageset expr and imageset from this result. `soln_imageset` dict of imageset expr and imageset of new soln. """ satisfy_exclude = _check_exclude(rnew, imgset_yes) delete_soln = False # soln should not satisfy expr present in `exclude` list. if not satisfy_exclude: local_n = None # if it is imageset if imgset_yes: local_n = imgset_yes[0] base = imgset_yes[1] if sym and sol: # when `sym` and `sol` is `None` means no new # soln. In that case we will append rnew directly after # substituting original imagesets in rnew values if present # (second last line of this function using _restore_imgset) dummy_list = list(sol.atoms(Dummy)) # use one dummy `n` which is in # previous imageset local_n_list = [ local_n for i in range( 0, len(dummy_list))] dummy_zip = zip(dummy_list, local_n_list) lam = Lambda(local_n, sol.subs(dummy_zip)) rnew[sym] = ImageSet(lam, base) if eq is not None: newresult, rnew, delete_soln = _append_eq( eq, newresult, rnew, delete_soln, local_n) elif eq is not None: newresult, rnew, delete_soln = _append_eq( eq, newresult, rnew, delete_soln) elif soln_imageset: rnew[sym] = soln_imageset[sol] # restore original imageset _restore_imgset(rnew, original_imageset, newresult) else: newresult.append(rnew) elif satisfy_exclude: delete_soln = True rnew = {} _restore_imgset(rnew, original_imageset, newresult) return newresult, delete_soln # end of def _append_new_soln() def _new_order_result(result, eq): # separate first, second priority. `res` that makes `eq` value equals # to zero, should be used first then other result(second priority). # If it is not done then we may miss some soln. first_priority = [] second_priority = [] for res in result: if not any(isinstance(val, ImageSet) for val in res.values()): if eq.subs(res) == 0: first_priority.append(res) else: second_priority.append(res) if first_priority or second_priority: return first_priority + second_priority return result def _solve_using_known_values(result, solver): """Solves the system using already known solution (result contains the dict <symbol: value>). solver is `solveset_complex` or `solveset_real`. """ # stores imageset <expr: imageset(Lambda(n, expr), base)>. soln_imageset = {} total_solvest_call = 0 total_conditionst = 0 # sort such that equation with the fewest potential symbols is first. # means eq with less variable first for index, eq in enumerate(eqs_in_better_order): newresult = [] original_imageset = {} # if imageset expr is used to solve other symbol imgset_yes = False result = _new_order_result(result, eq) for res in result: got_symbol = set() # symbols solved in one iteration if soln_imageset: # find the imageset and use its expr. for key_res, value_res in res.items(): if isinstance(value_res, ImageSet): res[key_res] = value_res.lamda.expr original_imageset[key_res] = value_res dummy_n = value_res.lamda.expr.atoms(Dummy).pop() base = value_res.base_set imgset_yes = (dummy_n, base) # update eq with everything that is known so far eq2 = eq.subs(res) unsolved_syms = _unsolved_syms(eq2, sort=True) if not unsolved_syms: if res: newresult, delete_res = _append_new_soln( res, None, None, imgset_yes, soln_imageset, original_imageset, newresult, eq2) if delete_res: # `delete_res` is true, means substituting `res` in # eq2 doesn't return `zero` or deleting the `res` # (a soln) since it staisfies expr of `exclude` # list. result.remove(res) continue # skip as it's independent of desired symbols depen = eq2.as_independent(unsolved_syms)[0] if depen.has(Abs) and solver == solveset_complex: # Absolute values cannot be inverted in the # complex domain continue soln_imageset = {} for sym in unsolved_syms: not_solvable = False try: soln = solver(eq2, sym) total_solvest_call += 1 soln_new = S.EmptySet if isinstance(soln, Complement): # separate solution and complement complements[sym] = soln.args[1] soln = soln.args[0] # complement will be added at the end if isinstance(soln, Intersection): # Interval will be at 0th index always if soln.args[0] != Interval(-oo, oo): # sometimes solveset returns soln # with intersection S.Reals, to confirm that # soln is in domain=S.Reals intersections[sym] = soln.args[0] soln_new += soln.args[1] soln = soln_new if soln_new else soln if index > 0 and solver == solveset_real: # one symbol's real soln , another symbol may have # corresponding complex soln. if not isinstance(soln, (ImageSet, ConditionSet)): soln += solveset_complex(eq2, sym) except NotImplementedError: # If sovleset is not able to solve equation `eq2`. Next # time we may get soln using next equation `eq2` continue if isinstance(soln, ConditionSet): soln = S.EmptySet # don't do `continue` we may get soln # in terms of other symbol(s) not_solvable = True total_conditionst += 1 if soln is not S.EmptySet: soln, soln_imageset = _extract_main_soln( soln, soln_imageset) for sol in soln: # sol is not a `Union` since we checked it # before this loop sol, soln_imageset = _extract_main_soln( sol, soln_imageset) sol = set(sol).pop() free = sol.free_symbols if got_symbol and any([ ss in free for ss in got_symbol ]): # sol depends on previously solved symbols # then continue continue rnew = res.copy() # put each solution in res and append the new result # in the new result list (solution for symbol `s`) # along with old results. for k, v in res.items(): if isinstance(v, Expr): # if any unsolved symbol is present # Then subs known value rnew[k] = v.subs(sym, sol) # and add this new solution if soln_imageset: # replace all lambda variables with 0. imgst = soln_imageset[sol] rnew[sym] = imgst.lamda( [0 for i in range(0, len( imgst.lamda.variables))]) else: rnew[sym] = sol newresult, delete_res = _append_new_soln( rnew, sym, sol, imgset_yes, soln_imageset, original_imageset, newresult) if delete_res: # deleting the `res` (a soln) since it staisfies # eq of `exclude` list result.remove(res) # solution got for sym if not not_solvable: got_symbol.add(sym) # next time use this new soln if newresult: result = newresult return result, total_solvest_call, total_conditionst # end def _solve_using_know_values() new_result_real, solve_call1, cnd_call1 = _solve_using_known_values( old_result, solveset_real) new_result_complex, solve_call2, cnd_call2 = _solve_using_known_values( old_result, solveset_complex) # when `total_solveset_call` is equals to `total_conditionset` # means solvest fails to solve all the eq. # return conditionset in this case total_conditionset += (cnd_call1 + cnd_call2) total_solveset_call += (solve_call1 + solve_call2) if total_conditionset == total_solveset_call and total_solveset_call != -1: return _return_conditionset(eqs_in_better_order, all_symbols) # overall result result = new_result_real + new_result_complex result_all_variables = [] result_infinite = [] for res in result: if not res: # means {None : None} continue # If length < len(all_symbols) means infinite soln. # Some or all the soln is dependent on 1 symbol. # eg. {x: y+2} then final soln {x: y+2, y: y} if len(res) < len(all_symbols): solved_symbols = res.keys() unsolved = list(filter( lambda x: x not in solved_symbols, all_symbols)) for unsolved_sym in unsolved: res[unsolved_sym] = unsolved_sym result_infinite.append(res) if res not in result_all_variables: result_all_variables.append(res) if result_infinite: # we have general soln # eg : [{x: -1, y : 1}, {x : -y , y: y}] then # return [{x : -y, y : y}] result_all_variables = result_infinite if intersections and complements: # no testcase is added for this block result_all_variables = add_intersection_complement( result_all_variables, intersections, Intersection=True, Complement=True) elif intersections: result_all_variables = add_intersection_complement( result_all_variables, intersections, Intersection=True) elif complements: result_all_variables = add_intersection_complement( result_all_variables, complements, Complement=True) # convert to ordered tuple result = S.EmptySet for r in result_all_variables: temp = [r[symb] for symb in all_symbols] result += FiniteSet(tuple(temp)) return result # end of def substitution() def _solveset_work(system, symbols): soln = solveset(system[0], symbols[0]) if isinstance(soln, FiniteSet): _soln = FiniteSet([tuple((s,)) for s in soln]) return _soln else: return FiniteSet(tuple(FiniteSet(soln))) def _handle_positive_dimensional(polys, symbols, denominators): from sympy.polys.polytools import groebner # substitution method where new system is groebner basis of the system _symbols = list(symbols) _symbols.sort(key=default_sort_key) basis = groebner(polys, _symbols, polys=True) new_system = [] for poly_eq in basis: new_system.append(poly_eq.as_expr()) result = [{}] result = substitution( new_system, symbols, result, [], denominators) return result # end of def _handle_positive_dimensional() def _handle_zero_dimensional(polys, symbols, system): # solve 0 dimensional poly system using `solve_poly_system` result = solve_poly_system(polys, symbols) # May be some extra soln is added because # we used `unrad` in `_separate_poly_nonpoly`, so # need to check and remove if it is not a soln. result_update = S.EmptySet for res in result: dict_sym_value = dict(list(zip(symbols, res))) if all(checksol(eq, dict_sym_value) for eq in system): result_update += FiniteSet(res) return result_update # end of def _handle_zero_dimensional() def _separate_poly_nonpoly(system, symbols): polys = [] polys_expr = [] nonpolys = [] denominators = set() poly = None for eq in system: # Store denom expression if it contains symbol denominators.update(_simple_dens(eq, symbols)) # try to remove sqrt and rational power without_radicals = unrad(simplify(eq)) if without_radicals: eq_unrad, cov = without_radicals if not cov: eq = eq_unrad if isinstance(eq, Expr): eq = eq.as_numer_denom()[0] poly = eq.as_poly(symbols, extension=True) elif simplify(eq).is_number: continue if poly is not None: polys.append(poly) polys_expr.append(poly.as_expr()) else: nonpolys.append(eq) return polys, polys_expr, nonpolys, denominators # end of def _separate_poly_nonpoly() def nonlinsolve(system, symbols): r""" Solve system of N non linear equations with M variables, which means both under and overdetermined systems are supported. Positive dimensional system is also supported (A system with infinitely many solutions is said to be positive-dimensional). In Positive dimensional system solution will be dependent on at least one symbol. Returns both real solution and complex solution(If system have). The possible number of solutions is zero, one or infinite. Parameters ========== system : list of equations The target system of equations symbols : list of Symbols symbols should be given as a sequence eg. list Returns ======= A FiniteSet of ordered tuple of values of `symbols` for which the `system` has solution. Order of values in the tuple is same as symbols present in the parameter `symbols`. Please note that general FiniteSet is unordered, the solution returned here is not simply a FiniteSet of solutions, rather it is a FiniteSet of ordered tuple, i.e. the first & only argument to FiniteSet is a tuple of solutions, which is ordered, & hence the returned solution is ordered. Also note that solution could also have been returned as an ordered tuple, FiniteSet is just a wrapper `{}` around the tuple. It has no other significance except for the fact it is just used to maintain a consistent output format throughout the solveset. For the given set of Equations, the respective input types are given below: .. math:: xy - 1 = 0 .. math:: 4x2 + y2 - 5 = 0 `system = [xy - 1, 4x2 + y2 - 5]` `symbols = [x, y]` Raises ====== ValueError The input is not valid. The symbols are not given. AttributeError The input symbols are not `Symbol` type. Examples ======== >>> from sympy.core.symbol import symbols >>> from sympy.solvers.solveset import nonlinsolve >>> x, y, z = symbols('x, y, z', real=True) >>> nonlinsolve([xy - 1, 4x2 + y2 - 5], [x, y]) {(-1, -1), (-1/2, -2), (1/2, 2), (1, 1)} 1. Positive dimensional system and complements: >>> from sympy import pprint >>> from sympy.polys.polytools import is_zero_dimensional >>> a, b, c, d = symbols('a, b, c, d', real=True) >>> eq1 = a + b + c + d >>> eq2 = ab + bc + cd + da >>> eq3 = abc + bcd + cda + dab >>> eq4 = abcd - 1 >>> system = [eq1, eq2, eq3, eq4] >>> is_zero_dimensional(system) False >>> pprint(nonlinsolve(system, [a, b, c, d]), use_unicode=False) -1 1 1 -1 {(---, -d, -, {d} \ {0}), (-, -d, ---, {d} \ {0})} d d d d >>> nonlinsolve([(x+y)2 - 4, x + y - 2], [x, y]) {(2 - y, y)} 2. If some of the equations are non polynomial equation then `nonlinsolve` will call `substitution` function and returns real and complex solutions, if present. >>> from sympy import exp, sin >>> nonlinsolve([exp(x) - sin(y), y2 - 4], [x, y]) {(log(sin(2)), 2), (ImageSet(Lambda(_n, I(2_npi + pi) + log(sin(2))), Integers), -2), (ImageSet(Lambda(_n, 2_nIpi + Mod(log(sin(2)), 2Ipi)), Integers), 2)} 3. If system is Non linear polynomial zero dimensional then it returns both solution (real and complex solutions, if present using `solve_poly_system`): >>> from sympy import sqrt >>> nonlinsolve([x2 - 2y*2 -2, xy - 2], [x, y]) {(-2, -1), (2, 1), (-sqrt(2)I, sqrt(2)I), (sqrt(2)I, -sqrt(2)I)} 4. `nonlinsolve` can solve some linear(zero or positive dimensional) system (because it is using `groebner` function to get the groebner basis and then `substitution` function basis as the new `system`). But it is not recommended to solve linear system using `nonlinsolve`, because `linsolve` is better for all kind of linear system. >>> nonlinsolve([x + 2y -z - 3, x - y - 4z + 9 , y + z - 4], [x, y, z]) {(3z - 5, 4 - z, z)} 5. System having polynomial equations and only real solution is present (will be solved using `solve_poly_system`): >>> e1 = sqrt(x2 + y2) - 10 >>> e2 = sqrt(y2 + (-x + 10)2) - 3 >>> nonlinsolve((e1, e2), (x, y)) {(191/20, -3sqrt(391)/20), (191/20, 3sqrt(391)/20)} >>> nonlinsolve([x2 + 2/y - 2, x + y - 3], [x, y]) {(1, 2), (1 - sqrt(5), 2 + sqrt(5)), (1 + sqrt(5), 2 - sqrt(5))} >>> nonlinsolve([x2 + 2/y - 2, x + y - 3], [y, x]) {(2, 1), (2 - sqrt(5), 1 + sqrt(5)), (2 + sqrt(5), 1 - sqrt(5))} 6. It is better to use symbols instead of Trigonometric Function or Function (e.g. replace `sin(x)` with symbol, replace `f(x)` with symbol and so on. Get soln from `nonlinsolve` and then using `solveset` get the value of `x`) How nonlinsolve is better than old solver `_solve_system` : =========================================================== 1. A positive dimensional system solver : nonlinsolve can return solution for positive dimensional system. It finds the Groebner Basis of the positive dimensional system(calling it as basis) then we can start solving equation(having least number of variable first in the basis) using solveset and substituting that solved solutions into other equation(of basis) to get solution in terms of minimum variables. Here the important thing is how we are substituting the known values and in which equations. 2. Real and Complex both solutions : nonlinsolve returns both real and complex solution. If all the equations in the system are polynomial then using `solve_poly_system` both real and complex solution is returned. If all the equations in the system are not polynomial equation then goes to `substitution` method with this polynomial and non polynomial equation(s), to solve for unsolved variables. Here to solve for particular variable solveset_real and solveset_complex is used. For both real and complex solution function `_solve_using_know_values` is used inside `substitution` function.(`substitution` function will be called when there is any non polynomial equation(s) is present). When solution is valid then add its general solution in the final result. 3. Complement and Intersection will be added if any : nonlinsolve maintains dict for complements and Intersections. If solveset find complements or/and Intersection with any Interval or set during the execution of `substitution` function ,then complement or/and Intersection for that variable is added before returning final solution. """ from sympy.polys.polytools import is_zero_dimensional from sympy.polys import RR if not system: return S.EmptySet if not symbols: msg = ('Symbols must be given, for which solution of the ' 'system is to be found.') raise ValueError(filldedent(msg)) if hasattr(symbols[0], '__iter__'): symbols = symbols[0] if not is_sequence(symbols) or not symbols: msg = ('Symbols must be given, for which solution of the ' 'system is to be found.') raise IndexError(filldedent(msg)) system, symbols, swap = recast_to_symbols(system, symbols) if swap: soln = nonlinsolve(system, symbols) return FiniteSet([tuple(i.xreplace(swap) for i in s) for s in soln]) if len(system) == 1 and len(symbols) == 1: return _solveset_work(system, symbols) # main code of def nonlinsolve() starts from here polys, polys_expr, nonpolys, denominators = _separate_poly_nonpoly( system, symbols) if len(symbols) == len(polys): # If all the equations in the system are poly if is_zero_dimensional(polys, symbols): # finite number of soln (Zero dimensional system) try: return _handle_zero_dimensional(polys, symbols, system) except NotImplementedError: # Right now it doesn't fail for any polynomial system of # equation. If `solve_poly_system` fails then `substitution` # method will handle it. result = substitution( polys_expr, symbols, exclude=denominators) return result # positive dimensional system res = _handle_positive_dimensional(polys, symbols, denominators) if isinstance(res, EmptySet) and any(not p.domain.is_Exact for p in polys): raise NotImplementedError("Equation not in exact domain. Try converting to rational") else: return res else: # If all the equations are not polynomial. # Use `substitution` method for the system result = substitution( polys_expr + nonpolys, symbols, exclude=denominators) return result
dc9f7abcaeac2264c9eb775d18273e657213ad1fc9a8db6e0c2897aa4f9ca547	"""Calculus-related methods.""" from .euler import euler_equations from .singularities import (singularities, is_increasing, is_strictly_increasing, is_decreasing, is_strictly_decreasing, is_monotonic) from .finite_diff import finite_diff_weights, apply_finite_diff, as_finite_diff, differentiate_finite from .util import (periodicity, not_empty_in, AccumBounds, is_convex, stationary_points, minimum, maximum) __all__ = [ 'euler_equations', 'singularities', 'is_increasing', 'is_strictly_increasing', 'is_decreasing', 'is_strictly_decreasing', 'is_monotonic', 'finite_diff_weights', 'apply_finite_diff', 'as_finite_diff', 'differentiate_finite', 'periodicity', 'not_empty_in', 'AccumBounds', 'is_convex', 'stationary_points', 'minimum', 'maximum' ]
c83f43d4fa6d2f01ecb082abdaaf8fd1ed073d2e7b6e45ebf8c0fcf75e80ecd3	from sympy import Order, S, log, limit, lcm_list, Abs, im, re, Dummy from sympy.core import Add, Mul, Pow from sympy.core.basic import Basic from sympy.core.compatibility import iterable from sympy.core.expr import AtomicExpr, Expr from sympy.core.numbers import _sympifyit, oo from sympy.core.sympify import _sympify from sympy.functions.elementary.miscellaneous import Min, Max from sympy.logic.boolalg import And from sympy.polys.rationaltools import together from sympy.sets.sets import (Interval, Intersection, FiniteSet, Union, Complement, EmptySet) from sympy.simplify.radsimp import denom from sympy.solvers.inequalities import solve_univariate_inequality from sympy.utilities import filldedent def continuous_domain(f, symbol, domain): """ Returns the intervals in the given domain for which the function is continuous. This method is limited by the ability to determine the various singularities and discontinuities of the given function. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for which the intervals are to be determined. domain : Interval The domain over which the continuity of the symbol has to be checked. Examples ======== >>> from sympy import Symbol, S, tan, log, pi, sqrt >>> from sympy.sets import Interval >>> from sympy.calculus.util import continuous_domain >>> x = Symbol('x') >>> continuous_domain(1/x, x, S.Reals) Union(Interval.open(-oo, 0), Interval.open(0, oo)) >>> continuous_domain(tan(x), x, Interval(0, pi)) Union(Interval.Ropen(0, pi/2), Interval.Lopen(pi/2, pi)) >>> continuous_domain(sqrt(x - 2), x, Interval(-5, 5)) Interval(2, 5) >>> continuous_domain(log(2x - 1), x, S.Reals) Interval.open(1/2, oo) Returns ======= Interval Union of all intervals where the function is continuous. Raises ====== NotImplementedError If the method to determine continuity of such a function has not yet been developed. """ from sympy.solvers.inequalities import solve_univariate_inequality from sympy.solvers.solveset import solveset, _has_rational_power if domain.is_subset(S.Reals): constrained_interval = domain for atom in f.atoms(Pow): predicate, denomin = _has_rational_power(atom, symbol) if predicate and denomin == 2: constraint = solve_univariate_inequality(atom.base >= 0, symbol).as_set() constrained_interval = Intersection(constraint, constrained_interval) for atom in f.atoms(log): constraint = solve_univariate_inequality(atom.args[0] > 0, symbol).as_set() constrained_interval = Intersection(constraint, constrained_interval) domain = constrained_interval try: if f.has(Abs): sings = solveset(1/f, symbol, domain) + \ solveset(denom(together(f)), symbol, domain) else: for atom in f.atoms(Pow): predicate, denomin = _has_rational_power(atom, symbol) if predicate and denomin == 2: sings = solveset(1/f, symbol, domain) +\ solveset(denom(together(f)), symbol, domain) break else: sings = Intersection(solveset(1/f, symbol), domain) + \ solveset(denom(together(f)), symbol, domain) except NotImplementedError: raise NotImplementedError("Methods for determining the continuous domains" " of this function have not been developed.") return domain - sings def function_range(f, symbol, domain): """ Finds the range of a function in a given domain. This method is limited by the ability to determine the singularities and determine limits. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for which the range of function is to be determined. domain : Interval The domain under which the range of the function has to be found. Examples ======== >>> from sympy import Symbol, S, exp, log, pi, sqrt, sin, tan >>> from sympy.sets import Interval >>> from sympy.calculus.util import function_range >>> x = Symbol('x') >>> function_range(sin(x), x, Interval(0, 2pi)) Interval(-1, 1) >>> function_range(tan(x), x, Interval(-pi/2, pi/2)) Interval(-oo, oo) >>> function_range(1/x, x, S.Reals) Union(Interval.open(-oo, 0), Interval.open(0, oo)) >>> function_range(exp(x), x, S.Reals) Interval.open(0, oo) >>> function_range(log(x), x, S.Reals) Interval(-oo, oo) >>> function_range(sqrt(x), x , Interval(-5, 9)) Interval(0, 3) Returns ======= Interval Union of all ranges for all intervals under domain where function is continuous. Raises ====== NotImplementedError If any of the intervals, in the given domain, for which function is continuous are not finite or real, OR if the critical points of the function on the domain can't be found. """ from sympy.solvers.solveset import solveset if isinstance(domain, EmptySet): return S.EmptySet period = periodicity(f, symbol) if period is S.Zero: # the expression is constant wrt symbol return FiniteSet(f.expand()) if period is not None: if isinstance(domain, Interval): if (domain.inf - domain.sup).is_infinite: domain = Interval(0, period) elif isinstance(domain, Union): for sub_dom in domain.args: if isinstance(sub_dom, Interval) and \ ((sub_dom.inf - sub_dom.sup).is_infinite): domain = Interval(0, period) intervals = continuous_domain(f, symbol, domain) range_int = S.EmptySet if isinstance(intervals,(Interval, FiniteSet)): interval_iter = (intervals,) elif isinstance(intervals, Union): interval_iter = intervals.args else: raise NotImplementedError(filldedent(''' Unable to find range for the given domain. ''')) for interval in interval_iter: if isinstance(interval, FiniteSet): for singleton in interval: if singleton in domain: range_int += FiniteSet(f.subs(symbol, singleton)) elif isinstance(interval, Interval): vals = S.EmptySet critical_points = S.EmptySet critical_values = S.EmptySet bounds = ((interval.left_open, interval.inf, '+'), (interval.right_open, interval.sup, '-')) for is_open, limit_point, direction in bounds: if is_open: critical_values += FiniteSet(limit(f, symbol, limit_point, direction)) vals += critical_values else: vals += FiniteSet(f.subs(symbol, limit_point)) solution = solveset(f.diff(symbol), symbol, interval) if not iterable(solution): raise NotImplementedError('Unable to find critical points for {}'.format(f)) critical_points += solution for critical_point in critical_points: vals += FiniteSet(f.subs(symbol, critical_point)) left_open, right_open = False, False if critical_values is not S.EmptySet: if critical_values.inf == vals.inf: left_open = True if critical_values.sup == vals.sup: right_open = True range_int += Interval(vals.inf, vals.sup, left_open, right_open) else: raise NotImplementedError(filldedent(''' Unable to find range for the given domain. ''')) return range_int def not_empty_in(finset_intersection, syms): """ Finds the domain of the functions in `finite_set` in which the `finite_set` is not-empty Parameters ========== finset_intersection : The unevaluated intersection of FiniteSet containing real-valued functions with Union of Sets syms : Tuple of symbols Symbol for which domain is to be found Raises ====== NotImplementedError The algorithms to find the non-emptiness of the given FiniteSet are not yet implemented. ValueError The input is not valid. RuntimeError It is a bug, please report it to the github issue tracker (https://github.com/sympy/sympy/issues). Examples ======== >>> from sympy import FiniteSet, Interval, not_empty_in, oo >>> from sympy.abc import x >>> not_empty_in(FiniteSet(x/2).intersect(Interval(0, 1)), x) Interval(0, 2) >>> not_empty_in(FiniteSet(x, x2).intersect(Interval(1, 2)), x) Union(Interval(-sqrt(2), -1), Interval(1, 2)) >>> not_empty_in(FiniteSet(x2/(x + 2)).intersect(Interval(1, oo)), x) Union(Interval.Lopen(-2, -1), Interval(2, oo)) """ # TODO: handle piecewise defined functions # TODO: handle transcendental functions # TODO: handle multivariate functions if len(syms) == 0: raise ValueError("One or more symbols must be given in syms.") if finset_intersection.is_EmptySet: return EmptySet() if isinstance(finset_intersection, Union): elm_in_sets = finset_intersection.args[0] return Union(not_empty_in(finset_intersection.args[1], syms), elm_in_sets) if isinstance(finset_intersection, FiniteSet): finite_set = finset_intersection _sets = S.Reals else: finite_set = finset_intersection.args[1] _sets = finset_intersection.args[0] if not isinstance(finite_set, FiniteSet): raise ValueError('A FiniteSet must be given, not %s: %s' % (type(finite_set), finite_set)) if len(syms) == 1: symb = syms[0] else: raise NotImplementedError('more than one variables %s not handled' % (syms,)) def elm_domain(expr, intrvl): """ Finds the domain of an expression in any given interval """ from sympy.solvers.solveset import solveset _start = intrvl.start _end = intrvl.end _singularities = solveset(expr.as_numer_denom()[1], symb, domain=S.Reals) if intrvl.right_open: if _end is S.Infinity: _domain1 = S.Reals else: _domain1 = solveset(expr < _end, symb, domain=S.Reals) else: _domain1 = solveset(expr <= _end, symb, domain=S.Reals) if intrvl.left_open: if _start is S.NegativeInfinity: _domain2 = S.Reals else: _domain2 = solveset(expr > _start, symb, domain=S.Reals) else: _domain2 = solveset(expr >= _start, symb, domain=S.Reals) # domain in the interval expr_with_sing = Intersection(_domain1, _domain2) expr_domain = Complement(expr_with_sing, _singularities) return expr_domain if isinstance(_sets, Interval): return Union([elm_domain(element, _sets) for element in finite_set]) if isinstance(_sets, Union): _domain = S.EmptySet for intrvl in _sets.args: _domain_element = Union([elm_domain(element, intrvl) for element in finite_set]) _domain = Union(_domain, _domain_element) return _domain def periodicity(f, symbol, check=False): """ Tests the given function for periodicity in the given symbol. Parameters ========== f : Expr. The concerned function. symbol : Symbol The variable for which the period is to be determined. check : Boolean, optional The flag to verify whether the value being returned is a period or not. Returns ======= period The period of the function is returned. `None` is returned when the function is aperiodic or has a complex period. The value of `0` is returned as the period of a constant function. Raises ====== NotImplementedError The value of the period computed cannot be verified. Notes ===== Currently, we do not support functions with a complex period. The period of functions having complex periodic values such as `exp`, `sinh` is evaluated to `None`. The value returned might not be the "fundamental" period of the given function i.e. it may not be the smallest periodic value of the function. The verification of the period through the `check` flag is not reliable due to internal simplification of the given expression. Hence, it is set to `False` by default. Examples ======== >>> from sympy import Symbol, sin, cos, tan, exp >>> from sympy.calculus.util import periodicity >>> x = Symbol('x') >>> f = sin(x) + sin(2x) + sin(3x) >>> periodicity(f, x) 2pi >>> periodicity(sin(x)cos(x), x) pi >>> periodicity(exp(tan(2x) - 1), x) pi/2 >>> periodicity(sin(4x)*cos(2x), x) pi >>> periodicity(exp(x), x) """ from sympy.core.function import diff from sympy.core.mod import Mod from sympy.core.relational import Relational from sympy.functions.elementary.exponential import exp from sympy.functions.elementary.complexes import Abs from sympy.functions.elementary.trigonometric import ( TrigonometricFunction, sin, cos, csc, sec) from sympy.simplify.simplify import simplify from sympy.solvers.decompogen import decompogen from sympy.polys.polytools import degree, lcm_list temp = Dummy('x', real=True) f = f.subs(symbol, temp) symbol = temp def _check(orig_f, period): '''Return the checked period or raise an error.''' new_f = orig_f.subs(symbol, symbol + period) if new_f.equals(orig_f): return period else: raise NotImplementedError(filldedent(''' The period of the given function cannot be verified. When `%s` was replaced with `%s + %s` in `%s`, the result was `%s` which was not recognized as being the same as the original function. So either the period was wrong or the two forms were not recognized as being equal. Set check=False to obtain the value.''' % (symbol, symbol, period, orig_f, new_f))) orig_f = f period = None if isinstance(f, Relational): f = f.lhs - f.rhs f = simplify(f) if symbol not in f.free_symbols: return S.Zero if isinstance(f, TrigonometricFunction): try: period = f.period(symbol) except NotImplementedError: pass if isinstance(f, Abs): arg = f.args[0] if isinstance(arg, (sec, csc, cos)): # all but tan and cot might have a # a period that is half as large # so recast as sin arg = sin(arg.args[0]) period = periodicity(arg, symbol) if period is not None and isinstance(arg, sin): # the argument of Abs was a trigonometric other than # cot or tan; test to see if the half-period # is valid. Abs(arg) has behaviour equivalent to # orig_f, so use that for test: orig_f = Abs(arg) try: return _check(orig_f, period/2) except NotImplementedError as err: if check: raise NotImplementedError(err) # else let new orig_f and period be # checked below if isinstance(f, exp): if im(f) != 0: period_real = periodicity(re(f), symbol) period_imag = periodicity(im(f), symbol) if period_real is not None and period_imag is not None: period = lcim([period_real, period_imag]) if f.is_Pow: base, expo = f.args base_has_sym = base.has(symbol) expo_has_sym = expo.has(symbol) if base_has_sym and not expo_has_sym: period = periodicity(base, symbol) elif expo_has_sym and not base_has_sym: period = periodicity(expo, symbol) else: period = _periodicity(f.args, symbol) elif f.is_Mul: coeff, g = f.as_independent(symbol, as_Add=False) if isinstance(g, TrigonometricFunction) or coeff is not S.One: period = periodicity(g, symbol) else: period = _periodicity(g.args, symbol) elif f.is_Add: k, g = f.as_independent(symbol) if k is not S.Zero: return periodicity(g, symbol) period = _periodicity(g.args, symbol) elif isinstance(f, Mod): a, n = f.args if a == symbol: period = n elif isinstance(a, TrigonometricFunction): period = periodicity(a, symbol) #check if 'f' is linear in 'symbol' elif (a.is_polynomial(symbol) and degree(a, symbol) == 1 and symbol not in n.free_symbols): period = Abs(n / a.diff(symbol)) elif period is None: from sympy.solvers.decompogen import compogen g_s = decompogen(f, symbol) num_of_gs = len(g_s) if num_of_gs > 1: for index, g in enumerate(reversed(g_s)): start_index = num_of_gs - 1 - index g = compogen(g_s[start_index:], symbol) if g != orig_f and g != f: # Fix for issue 12620 period = periodicity(g, symbol) if period is not None: break if period is not None: if check: return _check(orig_f, period) return period return None def _periodicity(args, symbol): """ Helper for `periodicity` to find the period of a list of simpler functions. It uses the `lcim` method to find the least common period of all the functions. Parameters ========== args : Tuple of Symbol All the symbols present in a function. symbol : Symbol The symbol over which the function is to be evaluated. Returns ======= period The least common period of the function for all the symbols of the function. None if for at least one of the symbols the function is aperiodic """ periods = [] for f in args: period = periodicity(f, symbol) if period is None: return None if period is not S.Zero: periods.append(period) if len(periods) > 1: return lcim(periods) return periods[0] def lcim(numbers): """Returns the least common integral multiple of a list of numbers. The numbers can be rational or irrational or a mixture of both. `None` is returned for incommensurable numbers. Parameters ========== numbers : list Numbers (rational and/or irrational) for which lcim is to be found. Returns ======= number lcim if it exists, otherwise `None` for incommensurable numbers. Examples ======== >>> from sympy import S, pi >>> from sympy.calculus.util import lcim >>> lcim([S(1)/2, S(3)/4, S(5)/6]) 15/2 >>> lcim([2pi, 3pi, pi, pi/2]) 6pi >>> lcim([S(1), 2pi]) """ result = None if all(num.is_irrational for num in numbers): factorized_nums = list(map(lambda num: num.factor(), numbers)) factors_num = list( map(lambda num: num.as_coeff_Mul(), factorized_nums)) term = factors_num[0][1] if all(factor == term for coeff, factor in factors_num): common_term = term coeffs = [coeff for coeff, factor in factors_num] result = lcm_list(coeffs) * common_term elif all(num.is_rational for num in numbers): result = lcm_list(numbers) else: pass return result def is_convex(f, syms, kwargs): """Determines the convexity of the function passed in the argument. Parameters ========== f : Expr The concerned function. syms : Tuple of symbols The variables with respect to which the convexity is to be determined. domain : Interval, optional The domain over which the convexity of the function has to be checked. If unspecified, S.Reals will be the default domain. Returns ======= Boolean The method returns `True` if the function is convex otherwise it returns `False`. Raises ====== NotImplementedError The check for the convexity of multivariate functions is not implemented yet. Notes ===== To determine concavity of a function pass `-f` as the concerned function. To determine logarithmic convexity of a function pass log(f) as concerned function. To determine logartihmic concavity of a function pass -log(f) as concerned function. Currently, convexity check of multivariate functions is not handled. Examples ======== >>> from sympy import symbols, exp, oo, Interval >>> from sympy.calculus.util import is_convex >>> x = symbols('x') >>> is_convex(exp(x), x) True >>> is_convex(x3, x, domain = Interval(-1, oo)) False References ========== .. [1] https://en.wikipedia.org/wiki/Convex_function .. [2] http://www.ifp.illinois.edu/~angelia/L3_convfunc.pdf .. [3] https://en.wikipedia.org/wiki/Logarithmically_convex_function .. [4] https://en.wikipedia.org/wiki/Logarithmically_concave_function .. [5] https://en.wikipedia.org/wiki/Concave_function """ if len(syms) > 1: raise NotImplementedError( "The check for the convexity of multivariate functions is not implemented yet.") f = _sympify(f) domain = kwargs.get('domain', S.Reals) var = syms[0] condition = f.diff(var, 2) < 0 if solve_univariate_inequality(condition, var, False, domain): return False return True def stationary_points(f, symbol, domain=S.Reals): """ Returns the stationary points of a function (where derivative of the function is 0) in the given domain. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for which the stationary points are to be determined. domain : Interval The domain over which the stationary points have to be checked. If unspecified, S.Reals will be the default domain. Examples ======== >>> from sympy import Symbol, S, sin, log, pi, pprint, stationary_points >>> from sympy.sets import Interval >>> x = Symbol('x') >>> stationary_points(1/x, x, S.Reals) EmptySet() >>> pprint(stationary_points(sin(x), x), use_unicode=False) pi 3pi {2npi + -- \| n in Integers} U {2npi + ---- \| n in Integers} 2 2 >>> stationary_points(sin(x),x, Interval(0, 4pi)) {pi/2, 3pi/2, 5pi/2, 7pi/2} """ from sympy import solveset, diff if isinstance(domain, EmptySet): return S.EmptySet domain = continuous_domain(f, symbol, domain) set = solveset(diff(f, symbol), symbol, domain) return set def maximum(f, symbol, domain=S.Reals): """ Returns the maximum value of a function in the given domain. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for maximum value needs to be determined. domain : Interval The domain over which the maximum have to be checked. If unspecified, then Global maximum is returned. Examples ======== >>> from sympy import Symbol, S, sin, cos, pi, maximum >>> from sympy.sets import Interval >>> x = Symbol('x') >>> f = -x*2 + 2x + 5 >>> maximum(f, x, S.Reals) 6 >>> maximum(sin(x), x, Interval(-pi, pi/4)) sqrt(2)/2 >>> maximum(sin(x)cos(x), x) 1/2 """ from sympy import Symbol if isinstance(symbol, Symbol): if isinstance(domain, EmptySet): raise ValueError("Maximum value not defined for empty domain.") return function_range(f, symbol, domain).sup else: raise ValueError("%s is not a valid symbol." % symbol) def minimum(f, symbol, domain=S.Reals): """ Returns the minimum value of a function in the given domain. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for minimum value needs to be determined. domain : Interval The domain over which the minimum have to be checked. If unspecified, then Global minimum is returned. Examples ======== >>> from sympy import Symbol, S, sin, cos, minimum >>> from sympy.sets import Interval >>> x = Symbol('x') >>> f = x2 + 2x + 5 >>> minimum(f, x, S.Reals) 4 >>> minimum(sin(x), x, Interval(2, 3)) sin(3) >>> minimum(sin(x)cos(x), x) -1/2 """ from sympy import Symbol if isinstance(symbol, Symbol): if isinstance(domain, EmptySet): raise ValueError("Minimum value not defined for empty domain.") return function_range(f, symbol, domain).inf else: raise ValueError("%s is not a valid symbol." % symbol) class AccumulationBounds(AtomicExpr): r""" # Note AccumulationBounds has an alias: AccumBounds AccumulationBounds represent an interval `[a, b]`, which is always closed at the ends. Here `a` and `b` can be any value from extended real numbers. The intended meaning of AccummulationBounds is to give an approximate location of the accumulation points of a real function at a limit point. Let `a` and `b` be reals such that a <= b. `\left\langle a, b\right\rangle = \{x \in \mathbb{R} \mid a \le x \le b\}` `\left\langle -\infty, b\right\rangle = \{x \in \mathbb{R} \mid x \le b\} \cup \{-\infty, \infty\}` `\left\langle a, \infty \right\rangle = \{x \in \mathbb{R} \mid a \le x\} \cup \{-\infty, \infty\}` `\left\langle -\infty, \infty \right\rangle = \mathbb{R} \cup \{-\infty, \infty\}` `oo` and `-oo` are added to the second and third definition respectively, since if either `-oo` or `oo` is an argument, then the other one should be included (though not as an end point). This is forced, since we have, for example, `1/AccumBounds(0, 1) = AccumBounds(1, oo)`, and the limit at `0` is not one-sided. As x tends to `0-`, then `1/x -> -oo`, so `-oo` should be interpreted as belonging to `AccumBounds(1, oo)` though it need not appear explicitly. In many cases it suffices to know that the limit set is bounded. However, in some other cases more exact information could be useful. For example, all accumulation values of cos(x) + 1 are non-negative. (AccumBounds(-1, 1) + 1 = AccumBounds(0, 2)) A AccumulationBounds object is defined to be real AccumulationBounds, if its end points are finite reals. Let `X`, `Y` be real AccumulationBounds, then their sum, difference, product are defined to be the following sets: `X + Y = \{ x+y \mid x \in X \cap y \in Y\}` `X - Y = \{ x-y \mid x \in X \cap y \in Y\}` `X Y = \{ xy \mid x \in X \cap y \in Y\}` There is, however, no consensus on Interval division. `X / Y = \{ z \mid \exists x \in X, y \in Y \mid y \neq 0, z = x/y\}` Note: According to this definition the quotient of two AccumulationBounds may not be a AccumulationBounds object but rather a union of AccumulationBounds. Note ==== The main focus in the interval arithmetic is on the simplest way to calculate upper and lower endpoints for the range of values of a function in one or more variables. These barriers are not necessarily the supremum or infimum, since the precise calculation of those values can be difficult or impossible. Examples ======== >>> from sympy import AccumBounds, sin, exp, log, pi, E, S, oo >>> from sympy.abc import x >>> AccumBounds(0, 1) + AccumBounds(1, 2) AccumBounds(1, 3) >>> AccumBounds(0, 1) - AccumBounds(0, 2) AccumBounds(-2, 1) >>> AccumBounds(-2, 3)AccumBounds(-1, 1) AccumBounds(-3, 3) >>> AccumBounds(1, 2)AccumBounds(3, 5) AccumBounds(3, 10) The exponentiation of AccumulationBounds is defined as follows: If 0 does not belong to `X` or `n > 0` then `X^n = \{ x^n \mid x \in X\}` otherwise `X^n = \{ x^n \mid x \neq 0, x \in X\} \cup \{-\infty, \infty\}` Here for fractional `n`, the part of `X` resulting in a complex AccumulationBounds object is neglected. >>> AccumBounds(-1, 4)(S(1)/2) AccumBounds(0, 2) >>> AccumBounds(1, 2)2 AccumBounds(1, 4) >>> AccumBounds(-1, oo)(-1) AccumBounds(-oo, oo) Note: `<a, b>^2` is not same as `<a, b><a, b>` >>> AccumBounds(-1, 1)2 AccumBounds(0, 1) >>> AccumBounds(1, 3) < 4 True >>> AccumBounds(1, 3) < -1 False Some elementary functions can also take AccumulationBounds as input. A function `f` evaluated for some real AccumulationBounds `<a, b>` is defined as `f(\left\langle a, b\right\rangle) = \{ f(x) \mid a \le x \le b \}` >>> sin(AccumBounds(pi/6, pi/3)) AccumBounds(1/2, sqrt(3)/2) >>> exp(AccumBounds(0, 1)) AccumBounds(1, E) >>> log(AccumBounds(1, E)) AccumBounds(0, 1) Some symbol in an expression can be substituted for a AccumulationBounds object. But it doesn't necessarily evaluate the AccumulationBounds for that expression. Same expression can be evaluated to different values depending upon the form it is used for substitution. For example: >>> (x2 + 2x + 1).subs(x, AccumBounds(-1, 1)) AccumBounds(-1, 4) >>> ((x + 1)2).subs(x, AccumBounds(-1, 1)) AccumBounds(0, 4) References ========== .. [1] https://en.wikipedia.org/wiki/Interval_arithmetic .. [2] http://fab.cba.mit.edu/classes/S62.12/docs/Hickey_interval.pdf Notes ===== Do not use ``AccumulationBounds`` for floating point interval arithmetic calculations, use ``mpmath.iv`` instead. """ is_real = True def __new__(cls, min, max): min = _sympify(min) max = _sympify(max) inftys = [S.Infinity, S.NegativeInfinity] # Only allow real intervals (use symbols with 'is_real=True'). if not (min.is_real or min in inftys) \ or not (max.is_real or max in inftys): raise ValueError("Only real AccumulationBounds are supported") # Make sure that the created AccumBounds object will be valid. if max.is_comparable and min.is_comparable: if max < min: raise ValueError( "Lower limit should be smaller than upper limit") if max == min: return max return Basic.__new__(cls, min, max) # setting the operation priority _op_priority = 11.0 @property def min(self): """ Returns the minimum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).min 1 """ return self.args[0] @property def max(self): """ Returns the maximum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).max 3 """ return self.args[1] @property def delta(self): """ Returns the difference of maximum possible value attained by AccumulationBounds object and minimum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).delta 2 """ return self.max - self.min @property def mid(self): """ Returns the mean of maximum possible value attained by AccumulationBounds object and minimum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).mid 2 """ return (self.min + self.max) / 2 @_sympifyit('other', NotImplemented) def _eval_power(self, other): return self.__pow__(other) @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): return AccumBounds( Add(self.min, other.min), Add(self.max, other.max)) if other is S.Infinity and self.min is S.NegativeInfinity or \ other is S.NegativeInfinity and self.max is S.Infinity: return AccumBounds(-oo, oo) elif other.is_real: return AccumBounds(Add(self.min, other), Add(self.max, other)) return Add(self, other, evaluate=False) return NotImplemented __radd__ = __add__ def __neg__(self): return AccumBounds(-self.max, -self.min) @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): return AccumBounds( Add(self.min, -other.max), Add(self.max, -other.min)) if other is S.NegativeInfinity and self.min is S.NegativeInfinity or \ other is S.Infinity and self.max is S.Infinity: return AccumBounds(-oo, oo) elif other.is_real: return AccumBounds( Add(self.min, -other), Add(self.max, -other)) return Add(self, -other, evaluate=False) return NotImplemented @_sympifyit('other', NotImplemented) def __rsub__(self, other): return self.__neg__() + other @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): return AccumBounds(Min(Mul(self.min, other.min), Mul(self.min, other.max), Mul(self.max, other.min), Mul(self.max, other.max)), Max(Mul(self.min, other.min), Mul(self.min, other.max), Mul(self.max, other.min), Mul(self.max, other.max))) if other is S.Infinity: if self.min.is_zero: return AccumBounds(0, oo) if self.max.is_zero: return AccumBounds(-oo, 0) if other is S.NegativeInfinity: if self.min.is_zero: return AccumBounds(-oo, 0) if self.max.is_zero: return AccumBounds(0, oo) if other.is_real: if other.is_zero: if self == AccumBounds(-oo, oo): return AccumBounds(-oo, oo) if self.max is S.Infinity: return AccumBounds(0, oo) if self.min is S.NegativeInfinity: return AccumBounds(-oo, 0) return S.Zero if other.is_positive: return AccumBounds( Mul(self.min, other), Mul(self.max, other)) elif other.is_negative: return AccumBounds( Mul(self.max, other), Mul(self.min, other)) if isinstance(other, Order): return other return Mul(self, other, evaluate=False) return NotImplemented __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): if S.Zero not in other: return self AccumBounds(1/other.max, 1/other.min) if S.Zero in self and S.Zero in other: if self.min.is_zero and other.min.is_zero: return AccumBounds(0, oo) if self.max.is_zero and other.min.is_zero: return AccumBounds(-oo, 0) return AccumBounds(-oo, oo) if self.max.is_negative: if other.min.is_negative: if other.max.is_zero: return AccumBounds(self.max / other.min, oo) if other.max.is_positive: # the actual answer is a Union of AccumBounds, # Union(AccumBounds(-oo, self.max/other.max), # AccumBounds(self.max/other.min, oo)) return AccumBounds(-oo, oo) if other.min.is_zero and other.max.is_positive: return AccumBounds(-oo, self.max / other.max) if self.min.is_positive: if other.min.is_negative: if other.max.is_zero: return AccumBounds(-oo, self.min / other.min) if other.max.is_positive: # the actual answer is a Union of AccumBounds, # Union(AccumBounds(-oo, self.min/other.min), # AccumBounds(self.min/other.max, oo)) return AccumBounds(-oo, oo) if other.min.is_zero and other.max.is_positive: return AccumBounds(self.min / other.max, oo) elif other.is_real: if other is S.Infinity or other is S.NegativeInfinity: if self == AccumBounds(-oo, oo): return AccumBounds(-oo, oo) if self.max is S.Infinity: return AccumBounds(Min(0, other), Max(0, other)) if self.min is S.NegativeInfinity: return AccumBounds(Min(0, -other), Max(0, -other)) if other.is_positive: return AccumBounds(self.min / other, self.max / other) elif other.is_negative: return AccumBounds(self.max / other, self.min / other) return Mul(self, 1 / other, evaluate=False) return NotImplemented __truediv__ = __div__ @_sympifyit('other', NotImplemented) def __rdiv__(self, other): if isinstance(other, Expr): if other.is_real: if other.is_zero: return S.Zero if S.Zero in self: if self.min == S.Zero: if other.is_positive: return AccumBounds(Mul(other, 1 / self.max), oo) if other.is_negative: return AccumBounds(-oo, Mul(other, 1 / self.max)) if self.max == S.Zero: if other.is_positive: return AccumBounds(-oo, Mul(other, 1 / self.min)) if other.is_negative: return AccumBounds(Mul(other, 1 / self.min), oo) return AccumBounds(-oo, oo) else: return AccumBounds(Min(other / self.min, other / self.max), Max(other / self.min, other / self.max)) return Mul(other, 1 / self, evaluate=False) else: return NotImplemented __rtruediv__ = __rdiv__ @_sympifyit('other', NotImplemented) def __pow__(self, other): from sympy.functions.elementary.miscellaneous import real_root if isinstance(other, Expr): if other is S.Infinity: if self.min.is_nonnegative: if self.max < 1: return S.Zero if self.min > 1: return S.Infinity return AccumBounds(0, oo) elif self.max.is_negative: if self.min > -1: return S.Zero if self.max < -1: return FiniteSet(-oo, oo) return AccumBounds(-oo, oo) else: if self.min > -1: if self.max < 1: return S.Zero return AccumBounds(0, oo) return AccumBounds(-oo, oo) if other is S.NegativeInfinity: return (1 / self)oo if other.is_real and other.is_number: if other.is_zero: return S.One if other.is_Integer: if self.min.is_positive: return AccumBounds( Min(self.min other, self.max other), Max(self.min other, self.max other)) elif self.max.is_negative: return AccumBounds( Min(self.max other, self.min other), Max(self.max other, self.min other)) if other % 2 == 0: if other.is_negative: if self.min.is_zero: return AccumBounds(self.maxother, oo) if self.max.is_zero: return AccumBounds(self.minother, oo) return AccumBounds(0, oo) return AccumBounds( S.Zero, Max(self.minother, self.maxother)) else: if other.is_negative: if self.min.is_zero: return AccumBounds(self.maxother, oo) if self.max.is_zero: return AccumBounds(-oo, self.minother) return AccumBounds(-oo, oo) return AccumBounds(self.minother, self.maxother) num, den = other.as_numer_denom() if num == S(1): if den % 2 == 0: if S.Zero in self: if self.min.is_negative: return AccumBounds(0, real_root(self.max, den)) return AccumBounds(real_root(self.min, den), real_root(self.max, den)) num_pow = selfnum return num_pow**(1 / den) return Pow(self, other, evaluate=False) return NotImplemented def __abs__(self): if self.max.is_negative: return self.__neg__() elif self.min.is_negative: return AccumBounds(S.Zero, Max(abs(self.min), self.max)) else: return self def __lt__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is less than the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) < AccumBounds(4, oo) True >>> AccumBounds(1, 4) < AccumBounds(3, 4) AccumBounds(1, 4) < AccumBounds(3, 4) >>> AccumBounds(1, oo) < -1 False """ other = _sympify(other) if isinstance(other, AccumBounds): if self.max < other.min: return True if self.min >= other.max: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.max < other: return True if self.min >= other: return False return super(AccumulationBounds, self).__lt__(other) def __le__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is less than or equal to the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational. Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) <= AccumBounds(4, oo) True >>> AccumBounds(1, 4) <= AccumBounds(3, 4) AccumBounds(1, 4) <= AccumBounds(3, 4) >>> AccumBounds(1, 3) <= 0 False """ other = _sympify(other) if isinstance(other, AccumBounds): if self.max <= other.min: return True if self.min > other.max: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.max <= other: return True if self.min > other: return False return super(AccumulationBounds, self).__le__(other) def __gt__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is greater than the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational. Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) > AccumBounds(4, oo) False >>> AccumBounds(1, 4) > AccumBounds(3, 4) AccumBounds(1, 4) > AccumBounds(3, 4) >>> AccumBounds(1, oo) > -1 True """ other = _sympify(other) if isinstance(other, AccumBounds): if self.min > other.max: return True if self.max <= other.min: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.min > other: return True if self.max <= other: return False return super(AccumulationBounds, self).__gt__(other) def __ge__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is less that the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational. Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) >= AccumBounds(4, oo) False >>> AccumBounds(1, 4) >= AccumBounds(3, 4) AccumBounds(1, 4) >= AccumBounds(3, 4) >>> AccumBounds(1, oo) >= 1 True """ other = _sympify(other) if isinstance(other, AccumBounds): if self.min >= other.max: return True if self.max < other.min: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.min >= other: return True if self.max < other: return False return super(AccumulationBounds, self).__ge__(other) def __contains__(self, other): """ Returns True if other is contained in self, where other belongs to extended real numbers, False if not contained, otherwise TypeError is raised. Examples ======== >>> from sympy import AccumBounds, oo >>> 1 in AccumBounds(-1, 3) True -oo and oo go together as limits (in AccumulationBounds). >>> -oo in AccumBounds(1, oo) True >>> oo in AccumBounds(-oo, 0) True """ other = _sympify(other) if other is S.Infinity or other is S.NegativeInfinity: if self.min is S.NegativeInfinity or self.max is S.Infinity: return True return False rv = And(self.min <= other, self.max >= other) if rv not in (True, False): raise TypeError("input failed to evaluate") return rv def intersection(self, other): """ Returns the intersection of 'self' and 'other'. Here other can be an instance of FiniteSet or AccumulationBounds. Examples ======== >>> from sympy import AccumBounds, FiniteSet >>> AccumBounds(1, 3).intersection(AccumBounds(2, 4)) AccumBounds(2, 3) >>> AccumBounds(1, 3).intersection(AccumBounds(4, 6)) EmptySet() >>> AccumBounds(1, 4).intersection(FiniteSet(1, 2, 5)) {1, 2} """ if not isinstance(other, (AccumBounds, FiniteSet)): raise TypeError( "Input must be AccumulationBounds or FiniteSet object") if isinstance(other, FiniteSet): fin_set = S.EmptySet for i in other: if i in self: fin_set = fin_set + FiniteSet(i) return fin_set if self.max < other.min or self.min > other.max: return S.EmptySet if self.min <= other.min: if self.max <= other.max: return AccumBounds(other.min, self.max) if self.max > other.max: return other if other.min <= self.min: if other.max < self.max: return AccumBounds(self.min, other.max) if other.max > self.max: return self def union(self, other): # TODO : Devise a better method for Union of AccumBounds # this method is not actually correct and # can be made better if not isinstance(other, AccumBounds): raise TypeError( "Input must be AccumulationBounds or FiniteSet object") if self.min <= other.min and self.max >= other.min: return AccumBounds(self.min, Max(self.max, other.max)) if other.min <= self.min and other.max >= self.min: return AccumBounds(other.min, Max(self.max, other.max)) # setting an alias for AccumulationBounds AccumBounds = AccumulationBounds
c5e850695a053a34d55a1339298ed0a3c869e1620f1d3ae554a5fd270f65a24a	""" Generic SymPy-Independent Strategies """ from __future__ import print_function, division from sympy.core.compatibility import get_function_name identity = lambda x: x def exhaust(rule): """ Apply a rule repeatedly until it has no effect """ def exhaustive_rl(expr): new, old = rule(expr), expr while new != old: new, old = rule(new), new return new return exhaustive_rl def memoize(rule): """ Memoized version of a rule """ cache = {} def memoized_rl(expr): if expr in cache: return cache[expr] else: result = rule(expr) cache[expr] = result return result return memoized_rl def condition(cond, rule): """ Only apply rule if condition is true """ def conditioned_rl(expr): if cond(expr): return rule(expr) else: return expr return conditioned_rl def chain(rules): """ Compose a sequence of rules so that they apply to the expr sequentially """ def chain_rl(expr): for rule in rules: expr = rule(expr) return expr return chain_rl def debug(rule, file=None): """ Print out before and after expressions each time rule is used """ if file is None: from sys import stdout file = stdout def debug_rl(args, *kwargs): expr = args[0] result = rule(args, *kwargs) if result != expr: file.write("Rule: %s\n" % get_function_name(rule)) file.write("In: %s\nOut: %s\n\n"%(expr, result)) return result return debug_rl def null_safe(rule): """ Return original expr if rule returns None """ def null_safe_rl(expr): result = rule(expr) if result is None: return expr else: return result return null_safe_rl def tryit(rule): """ Return original expr if rule raises exception """ def try_rl(expr): try: return rule(expr) except Exception: return expr return try_rl def do_one(rules): """ Try each of the rules until one works. Then stop. """ def do_one_rl(expr): for rl in rules: result = rl(expr) if result != expr: return result return expr return do_one_rl def switch(key, ruledict): """ Select a rule based on the result of key called on the function """ def switch_rl(expr): rl = ruledict.get(key(expr), identity) return rl(expr) return switch_rl def minimize(rules, *kwargs): """ Select result of rules that minimizes objective >>> from sympy.strategies import minimize >>> inc = lambda x: x + 1 >>> dec = lambda x: x - 1 >>> rl = minimize(inc, dec) >>> rl(4) 3 >>> rl = minimize(inc, dec, objective=lambda x: -x) # maximize >>> rl(4) 5 """ objective = kwargs.get('objective', identity) def minrule(expr): return min([rule(expr) for rule in rules], key=objective) return minrule
e940ef5d609e4969e6bea9db12538f9027af9fd3bc1ae524bb99da53ad2be4fd	""" module for generating C, C++, Fortran77, Fortran90, Julia, Rust and Octave/Matlab routines that evaluate sympy expressions. This module is work in progress. Only the milestones with a '+' character in the list below have been completed. --- How is sympy.utilities.codegen different from sympy.printing.ccode? --- We considered the idea to extend the printing routines for sympy functions in such a way that it prints complete compilable code, but this leads to a few unsurmountable issues that can only be tackled with dedicated code generator: - For C, one needs both a code and a header file, while the printing routines generate just one string. This code generator can be extended to support .pyf files for f2py. - SymPy functions are not concerned with programming-technical issues, such as input, output and input-output arguments. Other examples are contiguous or non-contiguous arrays, including headers of other libraries such as gsl or others. - It is highly interesting to evaluate several sympy functions in one C routine, eventually sharing common intermediate results with the help of the cse routine. This is more than just printing. - From the programming perspective, expressions with constants should be evaluated in the code generator as much as possible. This is different for printing. --- Basic assumptions --- * A generic Routine data structure describes the routine that must be translated into C/Fortran/... code. This data structure covers all features present in one or more of the supported languages. * Descendants from the CodeGen class transform multiple Routine instances into compilable code. Each derived class translates into a specific language. * In many cases, one wants a simple workflow. The friendly functions in the last part are a simple api on top of the Routine/CodeGen stuff. They are easier to use, but are less powerful. --- Milestones --- + First working version with scalar input arguments, generating C code, tests + Friendly functions that are easier to use than the rigorous Routine/CodeGen workflow. + Integer and Real numbers as input and output + Output arguments + InputOutput arguments + Sort input/output arguments properly + Contiguous array arguments (numpy matrices) + Also generate .pyf code for f2py (in autowrap module) + Isolate constants and evaluate them beforehand in double precision + Fortran 90 + Octave/Matlab - Common Subexpression Elimination - User defined comments in the generated code - Optional extra include lines for libraries/objects that can eval special functions - Test other C compilers and libraries: gcc, tcc, libtcc, gcc+gsl, ... - Contiguous array arguments (sympy matrices) - Non-contiguous array arguments (sympy matrices) - ccode must raise an error when it encounters something that can not be translated into c. ccode(integrate(sin(x)/x, x)) does not make sense. - Complex numbers as input and output - A default complex datatype - Include extra information in the header: date, user, hostname, sha1 hash, ... - Fortran 77 - C++ - Python - Julia - Rust - ... """ from __future__ import print_function, division import os import textwrap from sympy import __version__ as sympy_version from sympy.core import Symbol, S, Tuple, Equality, Function, Basic from sympy.core.compatibility import is_sequence, StringIO, string_types from sympy.printing.ccode import c_code_printers from sympy.printing.codeprinter import AssignmentError from sympy.printing.fcode import FCodePrinter from sympy.printing.julia import JuliaCodePrinter from sympy.printing.octave import OctaveCodePrinter from sympy.printing.rust import RustCodePrinter from sympy.tensor import Idx, Indexed, IndexedBase from sympy.matrices import (MatrixSymbol, ImmutableMatrix, MatrixBase, MatrixExpr, MatrixSlice) __all__ = [ # description of routines "Routine", "DataType", "default_datatypes", "get_default_datatype", "Argument", "InputArgument", "OutputArgument", "Result", # routines -> code "CodeGen", "CCodeGen", "FCodeGen", "JuliaCodeGen", "OctaveCodeGen", "RustCodeGen", # friendly functions "codegen", "make_routine", ] # # Description of routines # class Routine(object): """Generic description of evaluation routine for set of expressions. A CodeGen class can translate instances of this class into code in a particular language. The routine specification covers all the features present in these languages. The CodeGen part must raise an exception when certain features are not present in the target language. For example, multiple return values are possible in Python, but not in C or Fortran. Another example: Fortran and Python support complex numbers, while C does not. """ def __init__(self, name, arguments, results, local_vars, global_vars): """Initialize a Routine instance. Parameters ========== name : string Name of the routine. arguments : list of Arguments These are things that appear in arguments of a routine, often appearing on the right-hand side of a function call. These are commonly InputArguments but in some languages, they can also be OutputArguments or InOutArguments (e.g., pass-by-reference in C code). results : list of Results These are the return values of the routine, often appearing on the left-hand side of a function call. The difference between Results and OutputArguments and when you should use each is language-specific. local_vars : list of Results These are variables that will be defined at the beginning of the function. global_vars : list of Symbols Variables which will not be passed into the function. """ # extract all input symbols and all symbols appearing in an expression input_symbols = set([]) symbols = set([]) for arg in arguments: if isinstance(arg, OutputArgument): symbols.update(arg.expr.free_symbols - arg.expr.atoms(Indexed)) elif isinstance(arg, InputArgument): input_symbols.add(arg.name) elif isinstance(arg, InOutArgument): input_symbols.add(arg.name) symbols.update(arg.expr.free_symbols - arg.expr.atoms(Indexed)) else: raise ValueError("Unknown Routine argument: %s" % arg) for r in results: if not isinstance(r, Result): raise ValueError("Unknown Routine result: %s" % r) symbols.update(r.expr.free_symbols - r.expr.atoms(Indexed)) local_symbols = set() for r in local_vars: if isinstance(r, Result): symbols.update(r.expr.free_symbols - r.expr.atoms(Indexed)) local_symbols.add(r.name) else: local_symbols.add(r) symbols = set([s.label if isinstance(s, Idx) else s for s in symbols]) # Check that all symbols in the expressions are covered by # InputArguments/InOutArguments---subset because user could # specify additional (unused) InputArguments or local_vars. notcovered = symbols.difference( input_symbols.union(local_symbols).union(global_vars)) if notcovered != set([]): raise ValueError("Symbols needed for output are not in input " + ", ".join([str(x) for x in notcovered])) self.name = name self.arguments = arguments self.results = results self.local_vars = local_vars self.global_vars = global_vars def __str__(self): return self.__class__.__name__ + "({name!r}, {arguments}, {results}, {local_vars}, {global_vars})".format(*self.__dict__) __repr__ = __str__ @property def variables(self): """Returns a set of all variables possibly used in the routine. For routines with unnamed return values, the dummies that may or may not be used will be included in the set. """ v = set(self.local_vars) for arg in self.arguments: v.add(arg.name) for res in self.results: v.add(res.result_var) return v @property def result_variables(self): """Returns a list of OutputArgument, InOutArgument and Result. If return values are present, they are at the end ot the list. """ args = [arg for arg in self.arguments if isinstance( arg, (OutputArgument, InOutArgument))] args.extend(self.results) return args class DataType(object): """Holds strings for a certain datatype in different languages.""" def __init__(self, cname, fname, pyname, jlname, octname, rsname): self.cname = cname self.fname = fname self.pyname = pyname self.jlname = jlname self.octname = octname self.rsname = rsname default_datatypes = { "int": DataType("int", "INTEGER4", "int", "", "", "i32"), "float": DataType("double", "REAL8", "float", "", "", "f64"), "complex": DataType("double", "COMPLEX16", "complex", "", "", "float") #FIXME: # complex is only supported in fortran, python, julia, and octave. # So to not break c or rust code generation, we stick with double or # float, respecitvely (but actually should raise an exeption for # explicitly complex variables (x.is_complex==True)) } COMPLEX_ALLOWED = False def get_default_datatype(expr, complex_allowed=None): """Derives an appropriate datatype based on the expression.""" if complex_allowed is None: complex_allowed = COMPLEX_ALLOWED if complex_allowed: final_dtype = "complex" else: final_dtype = "float" if expr.is_integer: return default_datatypes["int"] elif expr.is_real: return default_datatypes["float"] elif isinstance(expr, MatrixBase): #check all entries dt = "int" for element in expr: if dt is "int" and not element.is_integer: dt = "float" if dt is "float" and not element.is_real: return default_datatypes[final_dtype] return default_datatypes[dt] else: return default_datatypes[final_dtype] class Variable(object): """Represents a typed variable.""" def __init__(self, name, datatype=None, dimensions=None, precision=None): """Return a new variable. Parameters ========== name : Symbol or MatrixSymbol datatype : optional When not given, the data type will be guessed based on the assumptions on the symbol argument. dimension : sequence containing tupes, optional If present, the argument is interpreted as an array, where this sequence of tuples specifies (lower, upper) bounds for each index of the array. precision : int, optional Controls the precision of floating point constants. """ if not isinstance(name, (Symbol, MatrixSymbol)): raise TypeError("The first argument must be a sympy symbol.") if datatype is None: datatype = get_default_datatype(name) elif not isinstance(datatype, DataType): raise TypeError("The (optional) `datatype' argument must be an " "instance of the DataType class.") if dimensions and not isinstance(dimensions, (tuple, list)): raise TypeError( "The dimension argument must be a sequence of tuples") self._name = name self._datatype = { 'C': datatype.cname, 'FORTRAN': datatype.fname, 'JULIA': datatype.jlname, 'OCTAVE': datatype.octname, 'PYTHON': datatype.pyname, 'RUST': datatype.rsname, } self.dimensions = dimensions self.precision = precision def __str__(self): return "%s(%r)" % (self.__class__.__name__, self.name) __repr__ = __str__ @property def name(self): return self._name def get_datatype(self, language): """Returns the datatype string for the requested language. Examples ======== >>> from sympy import Symbol >>> from sympy.utilities.codegen import Variable >>> x = Variable(Symbol('x')) >>> x.get_datatype('c') 'double' >>> x.get_datatype('fortran') 'REAL8' """ try: return self._datatype[language.upper()] except KeyError: raise CodeGenError("Has datatypes for languages: %s" % ", ".join(self._datatype)) class Argument(Variable): """An abstract Argument data structure: a name and a data type. This structure is refined in the descendants below. """ pass class InputArgument(Argument): pass class ResultBase(object): """Base class for all "outgoing" information from a routine. Objects of this class stores a sympy expression, and a sympy object representing a result variable that will be used in the generated code only if necessary. """ def __init__(self, expr, result_var): self.expr = expr self.result_var = result_var def __str__(self): return "%s(%r, %r)" % (self.__class__.__name__, self.expr, self.result_var) __repr__ = __str__ class OutputArgument(Argument, ResultBase): """OutputArgument are always initialized in the routine.""" def __init__(self, name, result_var, expr, datatype=None, dimensions=None, precision=None): """Return a new variable. Parameters ========== name : Symbol, MatrixSymbol The name of this variable. When used for code generation, this might appear, for example, in the prototype of function in the argument list. result_var : Symbol, Indexed Something that can be used to assign a value to this variable. Typically the same as `name` but for Indexed this should be e.g., "y[i]" whereas `name` should be the Symbol "y". expr : object The expression that should be output, typically a SymPy expression. datatype : optional When not given, the data type will be guessed based on the assumptions on the symbol argument. dimension : sequence containing tupes, optional If present, the argument is interpreted as an array, where this sequence of tuples specifies (lower, upper) bounds for each index of the array. precision : int, optional Controls the precision of floating point constants. """ Argument.__init__(self, name, datatype, dimensions, precision) ResultBase.__init__(self, expr, result_var) def __str__(self): return "%s(%r, %r, %r)" % (self.__class__.__name__, self.name, self.result_var, self.expr) __repr__ = __str__ class InOutArgument(Argument, ResultBase): """InOutArgument are never initialized in the routine.""" def __init__(self, name, result_var, expr, datatype=None, dimensions=None, precision=None): if not datatype: datatype = get_default_datatype(expr) Argument.__init__(self, name, datatype, dimensions, precision) ResultBase.__init__(self, expr, result_var) __init__.__doc__ = OutputArgument.__init__.__doc__ def __str__(self): return "%s(%r, %r, %r)" % (self.__class__.__name__, self.name, self.expr, self.result_var) __repr__ = __str__ class Result(Variable, ResultBase): """An expression for a return value. The name result is used to avoid conflicts with the reserved word "return" in the python language. It is also shorter than ReturnValue. These may or may not need a name in the destination (e.g., "return(xy)" might return a value without ever naming it). """ def __init__(self, expr, name=None, result_var=None, datatype=None, dimensions=None, precision=None): """Initialize a return value. Parameters ========== expr : SymPy expression name : Symbol, MatrixSymbol, optional The name of this return variable. When used for code generation, this might appear, for example, in the prototype of function in a list of return values. A dummy name is generated if omitted. result_var : Symbol, Indexed, optional Something that can be used to assign a value to this variable. Typically the same as `name` but for Indexed this should be e.g., "y[i]" whereas `name` should be the Symbol "y". Defaults to `name` if omitted. datatype : optional When not given, the data type will be guessed based on the assumptions on the expr argument. dimension : sequence containing tupes, optional If present, this variable is interpreted as an array, where this sequence of tuples specifies (lower, upper) bounds for each index of the array. precision : int, optional Controls the precision of floating point constants. """ # Basic because it is the base class for all types of expressions if not isinstance(expr, (Basic, MatrixBase)): raise TypeError("The first argument must be a sympy expression.") if name is None: name = 'result_%d' % abs(hash(expr)) if datatype is None: #try to infer data type from the expression datatype = get_default_datatype(expr) if isinstance(name, string_types): if isinstance(expr, (MatrixBase, MatrixExpr)): name = MatrixSymbol(name, expr.shape) else: name = Symbol(name) if result_var is None: result_var = name Variable.__init__(self, name, datatype=datatype, dimensions=dimensions, precision=precision) ResultBase.__init__(self, expr, result_var) def __str__(self): return "%s(%r, %r, %r)" % (self.__class__.__name__, self.expr, self.name, self.result_var) __repr__ = __str__ # # Transformation of routine objects into code # class CodeGen(object): """Abstract class for the code generators.""" printer = None # will be set to an instance of a CodePrinter subclass def _indent_code(self, codelines): return self.printer.indent_code(codelines) def _printer_method_with_settings(self, method, settings=None, args, *kwargs): settings = settings or {} ori = {k: self.printer._settings[k] for k in settings} for k, v in settings.items(): self.printer._settings[k] = v result = getattr(self.printer, method)(args, *kwargs) for k, v in ori.items(): self.printer._settings[k] = v return result def _get_symbol(self, s): """Returns the symbol as fcode prints it.""" if self.printer._settings['human']: expr_str = self.printer.doprint(s) else: constants, not_supported, expr_str = self.printer.doprint(s) if constants or not_supported: raise ValueError("Failed to print %s" % str(s)) return expr_str.strip() def __init__(self, project="project", cse=False): """Initialize a code generator. Derived classes will offer more options that affect the generated code. """ self.project = project self.cse = cse def routine(self, name, expr, argument_sequence=None, global_vars=None): """Creates an Routine object that is appropriate for this language. This implementation is appropriate for at least C/Fortran. Subclasses can override this if necessary. Here, we assume at most one return value (the l-value) which must be scalar. Additional outputs are OutputArguments (e.g., pointers on right-hand-side or pass-by-reference). Matrices are always returned via OutputArguments. If ``argument_sequence`` is None, arguments will be ordered alphabetically, but with all InputArguments first, and then OutputArgument and InOutArguments. """ if self.cse: from sympy.simplify.cse_main import cse if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") for e in expr: if not e.is_Equality: raise CodeGenError("Lists of expressions must all be Equalities. {} is not.".format(e)) # create a list of right hand sides and simplify them rhs = [e.rhs for e in expr] common, simplified = cse(rhs) # pack the simplified expressions back up with their left hand sides expr = [Equality(e.lhs, rhs) for e, rhs in zip(expr, simplified)] else: rhs = [expr] if isinstance(expr, Equality): common, simplified = cse(expr.rhs) #, ignore=in_out_args) expr = Equality(expr.lhs, simplified[0]) else: common, simplified = cse(expr) expr = simplified local_vars = [Result(b,a) for a,b in common] local_symbols = set([a for a,_ in common]) local_expressions = Tuple([b for _,b in common]) else: local_expressions = Tuple() if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(expr) else: expressions = Tuple(expr) if self.cse: if {i.label for i in expressions.atoms(Idx)} != set(): raise CodeGenError("CSE and Indexed expressions do not play well together yet") else: # local variables for indexed expressions local_vars = {i.label for i in expressions.atoms(Idx)} local_symbols = local_vars # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments symbols = (expressions.free_symbols \| local_expressions.free_symbols) - local_symbols - global_vars new_symbols = set([]) new_symbols.update(symbols) for symbol in symbols: if isinstance(symbol, Idx): new_symbols.remove(symbol) new_symbols.update(symbol.args[1].free_symbols) if isinstance(symbol, Indexed): new_symbols.remove(symbol) symbols = new_symbols # Decide whether to use output argument or return value return_val = [] output_args = [] for expr in expressions: if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs if isinstance(out_arg, Indexed): dims = tuple([ (S.Zero, dim - 1) for dim in out_arg.shape]) symbol = out_arg.base.label elif isinstance(out_arg, Symbol): dims = [] symbol = out_arg elif isinstance(out_arg, MatrixSymbol): dims = tuple([ (S.Zero, dim - 1) for dim in out_arg.shape]) symbol = out_arg else: raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") if expr.has(symbol): output_args.append( InOutArgument(symbol, out_arg, expr, dimensions=dims)) else: output_args.append( OutputArgument(symbol, out_arg, expr, dimensions=dims)) # remove duplicate arguments when they are not local variables if symbol not in local_vars: # avoid duplicate arguments symbols.remove(symbol) elif isinstance(expr, (ImmutableMatrix, MatrixSlice)): # Create a "dummy" MatrixSymbol to use as the Output arg out_arg = MatrixSymbol('out_%s' % abs(hash(expr)), expr.shape) dims = tuple([(S.Zero, dim - 1) for dim in out_arg.shape]) output_args.append( OutputArgument(out_arg, out_arg, expr, dimensions=dims)) else: return_val.append(Result(expr)) arg_list = [] # setup input argument list array_symbols = {} for array in expressions.atoms(Indexed) \| local_expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol) \| local_expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): if symbol in array_symbols: dims = [] array = array_symbols[symbol] for dim in array.shape: dims.append((S.Zero, dim - 1)) metadata = {'dimensions': dims} else: metadata = {} arg_list.append(InputArgument(symbol, *metadata)) output_args.sort(key=lambda x: str(x.name)) arg_list.extend(output_args) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_val, local_vars, global_vars) def write(self, routines, prefix, to_files=False, header=True, empty=True): """Writes all the source code files for the given routines. The generated source is returned as a list of (filename, contents) tuples, or is written to files (see below). Each filename consists of the given prefix, appended with an appropriate extension. Parameters ========== routines : list A list of Routine instances to be written prefix : string The prefix for the output files to_files : bool, optional When True, the output is written to files. Otherwise, a list of (filename, contents) tuples is returned. [default: False] header : bool, optional When True, a header comment is included on top of each source file. [default: True] empty : bool, optional When True, empty lines are included to structure the source files. [default: True] """ if to_files: for dump_fn in self.dump_fns: filename = "%s.%s" % (prefix, dump_fn.extension) with open(filename, "w") as f: dump_fn(self, routines, f, prefix, header, empty) else: result = [] for dump_fn in self.dump_fns: filename = "%s.%s" % (prefix, dump_fn.extension) contents = StringIO() dump_fn(self, routines, contents, prefix, header, empty) result.append((filename, contents.getvalue())) return result def dump_code(self, routines, f, prefix, header=True, empty=True): """Write the code by calling language specific methods. The generated file contains all the definitions of the routines in low-level code and refers to the header file if appropriate. Parameters ========== routines : list A list of Routine instances. f : file-like Where to write the file. prefix : string The filename prefix, used to refer to the proper header file. Only the basename of the prefix is used. header : bool, optional When True, a header comment is included on top of each source file. [default : True] empty : bool, optional When True, empty lines are included to structure the source files. [default : True] """ code_lines = self._preprocessor_statements(prefix) for routine in routines: if empty: code_lines.append("\n") code_lines.extend(self._get_routine_opening(routine)) code_lines.extend(self._declare_arguments(routine)) code_lines.extend(self._declare_globals(routine)) code_lines.extend(self._declare_locals(routine)) if empty: code_lines.append("\n") code_lines.extend(self._call_printer(routine)) if empty: code_lines.append("\n") code_lines.extend(self._get_routine_ending(routine)) code_lines = self._indent_code(''.join(code_lines)) if header: code_lines = ''.join(self._get_header() + [code_lines]) if code_lines: f.write(code_lines) class CodeGenError(Exception): pass class CodeGenArgumentListError(Exception): @property def missing_args(self): return self.args[1] header_comment = """Code generated with sympy %(version)s See http://www.sympy.org/ for more information. This file is part of '%(project)s' """ class CCodeGen(CodeGen): """Generator for C code. The .write() method inherited from CodeGen will output a code file and an interface file, <prefix>.c and <prefix>.h respectively. """ code_extension = "c" interface_extension = "h" standard = 'c99' def __init__(self, project="project", printer=None, preprocessor_statements=None, cse=False): super(CCodeGen, self).__init__(project=project, cse=cse) self.printer = printer or c_code_printers[self.standard.lower()]() self.preprocessor_statements = preprocessor_statements if preprocessor_statements is None: self.preprocessor_statements = ['#include <math.h>'] def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] code_lines.append("/" + ""78 + '\n') tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): code_lines.append(" %s\n" % line.center(76)) code_lines.append(" " + ""78 + "/\n") return code_lines def get_prototype(self, routine): """Returns a string for the function prototype of the routine. If the routine has multiple result objects, an CodeGenError is raised. See: https://en.wikipedia.org/wiki/Function_prototype """ if len(routine.results) > 1: raise CodeGenError("C only supports a single or no return value.") elif len(routine.results) == 1: ctype = routine.results[0].get_datatype('C') else: ctype = "void" type_args = [] for arg in routine.arguments: name = self.printer.doprint(arg.name) if arg.dimensions or isinstance(arg, ResultBase): type_args.append((arg.get_datatype('C'), "%s" % name)) else: type_args.append((arg.get_datatype('C'), name)) arguments = ", ".join([ "%s %s" % t for t in type_args]) return "%s %s(%s)" % (ctype, routine.name, arguments) def _preprocessor_statements(self, prefix): code_lines = [] code_lines.append('#include "{}.h"'.format(os.path.basename(prefix))) code_lines.extend(self.preprocessor_statements) code_lines = ['{}\n'.format(l) for l in code_lines] return code_lines def _get_routine_opening(self, routine): prototype = self.get_prototype(routine) return ["%s {\n" % prototype] def _declare_arguments(self, routine): # arguments are declared in prototype return [] def _declare_globals(self, routine): # global variables are not explicitly declared within C functions return [] def _declare_locals(self, routine): # Compose a list of symbols to be dereferenced in the function # body. These are the arguments that were passed by a reference # pointer, excluding arrays. dereference = [] for arg in routine.arguments: if isinstance(arg, ResultBase) and not arg.dimensions: dereference.append(arg.name) code_lines = [] for result in routine.local_vars: # local variables that are simple symbols such as those used as indices into # for loops are defined declared elsewhere. if not isinstance(result, Result): continue if result.name != result.result_var: raise CodeGen("Result variable and name should match: {}".format(result)) assign_to = result.name t = result.get_datatype('c') if isinstance(result.expr, (MatrixBase, MatrixExpr)): dims = result.expr.shape if dims[1] != 1: raise CodeGenError("Only column vectors are supported in local variabels. Local result {} has dimensions {}".format(result, dims)) code_lines.append("{0} {1}[{2}];\n".format(t, str(assign_to), dims[0])) prefix = "" else: prefix = "const {0} ".format(t) constants, not_c, c_expr = self._printer_method_with_settings( 'doprint', dict(human=False, dereference=dereference), result.expr, assign_to=assign_to) for name, value in sorted(constants, key=str): code_lines.append("double const %s = %s;\n" % (name, value)) code_lines.append("{}{}\n".format(prefix, c_expr)) return code_lines def _call_printer(self, routine): code_lines = [] # Compose a list of symbols to be dereferenced in the function # body. These are the arguments that were passed by a reference # pointer, excluding arrays. dereference = [] for arg in routine.arguments: if isinstance(arg, ResultBase) and not arg.dimensions: dereference.append(arg.name) return_val = None for result in routine.result_variables: if isinstance(result, Result): assign_to = routine.name + "_result" t = result.get_datatype('c') code_lines.append("{0} {1};\n".format(t, str(assign_to))) return_val = assign_to else: assign_to = result.result_var try: constants, not_c, c_expr = self._printer_method_with_settings( 'doprint', dict(human=False, dereference=dereference), result.expr, assign_to=assign_to) except AssignmentError: assign_to = result.result_var code_lines.append( "%s %s;\n" % (result.get_datatype('c'), str(assign_to))) constants, not_c, c_expr = self._printer_method_with_settings( 'doprint', dict(human=False, dereference=dereference), result.expr, assign_to=assign_to) for name, value in sorted(constants, key=str): code_lines.append("double const %s = %s;\n" % (name, value)) code_lines.append("%s\n" % c_expr) if return_val: code_lines.append(" return %s;\n" % return_val) return code_lines def _get_routine_ending(self, routine): return ["}\n"] def dump_c(self, routines, f, prefix, header=True, empty=True): self.dump_code(routines, f, prefix, header, empty) dump_c.extension = code_extension dump_c.__doc__ = CodeGen.dump_code.__doc__ def dump_h(self, routines, f, prefix, header=True, empty=True): """Writes the C header file. This file contains all the function declarations. Parameters ========== routines : list A list of Routine instances. f : file-like Where to write the file. prefix : string The filename prefix, used to construct the include guards. Only the basename of the prefix is used. header : bool, optional When True, a header comment is included on top of each source file. [default : True] empty : bool, optional When True, empty lines are included to structure the source files. [default : True] """ if header: print(''.join(self._get_header()), file=f) guard_name = "%s__%s__H" % (self.project.replace( " ", "_").upper(), prefix.replace("/", "_").upper()) # include guards if empty: print(file=f) print("#ifndef %s" % guard_name, file=f) print("#define %s" % guard_name, file=f) if empty: print(file=f) # declaration of the function prototypes for routine in routines: prototype = self.get_prototype(routine) print("%s;" % prototype, file=f) # end if include guards if empty: print(file=f) print("#endif", file=f) if empty: print(file=f) dump_h.extension = interface_extension # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_c, dump_h] class C89CodeGen(CCodeGen): standard = 'C89' class C99CodeGen(CCodeGen): standard = 'C99' class FCodeGen(CodeGen): """Generator for Fortran 95 code The .write() method inherited from CodeGen will output a code file and an interface file, <prefix>.f90 and <prefix>.h respectively. """ code_extension = "f90" interface_extension = "h" def __init__(self, project='project', printer=None): super(FCodeGen, self).__init__(project) self.printer = printer or FCodePrinter() def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] code_lines.append("!" + ""78 + '\n') tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): code_lines.append("!%s\n" % line.center(76)) code_lines.append("!" + ""78 + '\n') return code_lines def _preprocessor_statements(self, prefix): return [] def _get_routine_opening(self, routine): """Returns the opening statements of the fortran routine.""" code_list = [] if len(routine.results) > 1: raise CodeGenError( "Fortran only supports a single or no return value.") elif len(routine.results) == 1: result = routine.results[0] code_list.append(result.get_datatype('fortran')) code_list.append("function") else: code_list.append("subroutine") args = ", ".join("%s" % self._get_symbol(arg.name) for arg in routine.arguments) call_sig = "{0}({1})\n".format(routine.name, args) # Fortran 95 requires all lines be less than 132 characters, so wrap # this line before appending. call_sig = ' &\n'.join(textwrap.wrap(call_sig, width=60, break_long_words=False)) + '\n' code_list.append(call_sig) code_list = [' '.join(code_list)] code_list.append('implicit none\n') return code_list def _declare_arguments(self, routine): # argument type declarations code_list = [] array_list = [] scalar_list = [] for arg in routine.arguments: if isinstance(arg, InputArgument): typeinfo = "%s, intent(in)" % arg.get_datatype('fortran') elif isinstance(arg, InOutArgument): typeinfo = "%s, intent(inout)" % arg.get_datatype('fortran') elif isinstance(arg, OutputArgument): typeinfo = "%s, intent(out)" % arg.get_datatype('fortran') else: raise CodeGenError("Unknown Argument type: %s" % type(arg)) fprint = self._get_symbol if arg.dimensions: # fortran arrays start at 1 dimstr = ", ".join(["%s:%s" % ( fprint(dim[0] + 1), fprint(dim[1] + 1)) for dim in arg.dimensions]) typeinfo += ", dimension(%s)" % dimstr array_list.append("%s :: %s\n" % (typeinfo, fprint(arg.name))) else: scalar_list.append("%s :: %s\n" % (typeinfo, fprint(arg.name))) # scalars first, because they can be used in array declarations code_list.extend(scalar_list) code_list.extend(array_list) return code_list def _declare_globals(self, routine): # Global variables not explicitly declared within Fortran 90 functions. # Note: a future F77 mode may need to generate "common" blocks. return [] def _declare_locals(self, routine): code_list = [] for var in sorted(routine.local_vars, key=str): typeinfo = get_default_datatype(var) code_list.append("%s :: %s\n" % ( typeinfo.fname, self._get_symbol(var))) return code_list def _get_routine_ending(self, routine): """Returns the closing statements of the fortran routine.""" if len(routine.results) == 1: return ["end function\n"] else: return ["end subroutine\n"] def get_interface(self, routine): """Returns a string for the function interface. The routine should have a single result object, which can be None. If the routine has multiple result objects, a CodeGenError is raised. See: https://en.wikipedia.org/wiki/Function_prototype """ prototype = [ "interface\n" ] prototype.extend(self._get_routine_opening(routine)) prototype.extend(self._declare_arguments(routine)) prototype.extend(self._get_routine_ending(routine)) prototype.append("end interface\n") return "".join(prototype) def _call_printer(self, routine): declarations = [] code_lines = [] for result in routine.result_variables: if isinstance(result, Result): assign_to = routine.name elif isinstance(result, (OutputArgument, InOutArgument)): assign_to = result.result_var constants, not_fortran, f_expr = self._printer_method_with_settings( 'doprint', dict(human=False, source_format='free', standard=95), result.expr, assign_to=assign_to) for obj, v in sorted(constants, key=str): t = get_default_datatype(obj) declarations.append( "%s, parameter :: %s = %s\n" % (t.fname, obj, v)) for obj in sorted(not_fortran, key=str): t = get_default_datatype(obj) if isinstance(obj, Function): name = obj.func else: name = obj declarations.append("%s :: %s\n" % (t.fname, name)) code_lines.append("%s\n" % f_expr) return declarations + code_lines def _indent_code(self, codelines): return self._printer_method_with_settings( 'indent_code', dict(human=False, source_format='free'), codelines) def dump_f95(self, routines, f, prefix, header=True, empty=True): # check that symbols are unique with ignorecase for r in routines: lowercase = {str(x).lower() for x in r.variables} orig_case = {str(x) for x in r.variables} if len(lowercase) < len(orig_case): raise CodeGenError("Fortran ignores case. Got symbols: %s" % (", ".join([str(var) for var in r.variables]))) self.dump_code(routines, f, prefix, header, empty) dump_f95.extension = code_extension dump_f95.__doc__ = CodeGen.dump_code.__doc__ def dump_h(self, routines, f, prefix, header=True, empty=True): """Writes the interface to a header file. This file contains all the function declarations. Parameters ========== routines : list A list of Routine instances. f : file-like Where to write the file. prefix : string The filename prefix. header : bool, optional When True, a header comment is included on top of each source file. [default : True] empty : bool, optional When True, empty lines are included to structure the source files. [default : True] """ if header: print(''.join(self._get_header()), file=f) if empty: print(file=f) # declaration of the function prototypes for routine in routines: prototype = self.get_interface(routine) f.write(prototype) if empty: print(file=f) dump_h.extension = interface_extension # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_f95, dump_h] class JuliaCodeGen(CodeGen): """Generator for Julia code. The .write() method inherited from CodeGen will output a code file <prefix>.jl. """ code_extension = "jl" def __init__(self, project='project', printer=None): super(JuliaCodeGen, self).__init__(project) self.printer = printer or JuliaCodePrinter() def routine(self, name, expr, argument_sequence, global_vars): """Specialized Routine creation for Julia.""" if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(expr) else: expressions = Tuple(expr) # local variables local_vars = {i.label for i in expressions.atoms(Idx)} # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments old_symbols = expressions.free_symbols - local_vars - global_vars symbols = set([]) for s in old_symbols: if isinstance(s, Idx): symbols.update(s.args[1].free_symbols) elif not isinstance(s, Indexed): symbols.add(s) # Julia supports multiple return values return_vals = [] output_args = [] for (i, expr) in enumerate(expressions): if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs symbol = out_arg if isinstance(out_arg, Indexed): dims = tuple([ (S.One, dim) for dim in out_arg.shape]) symbol = out_arg.base.label output_args.append(InOutArgument(symbol, out_arg, expr, dimensions=dims)) if not isinstance(out_arg, (Indexed, Symbol, MatrixSymbol)): raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") return_vals.append(Result(expr, name=symbol, result_var=out_arg)) if not expr.has(symbol): # this is a pure output: remove from the symbols list, so # it doesn't become an input. symbols.remove(symbol) else: # we have no name for this output return_vals.append(Result(expr, name='out%d' % (i+1))) # setup input argument list output_args.sort(key=lambda x: str(x.name)) arg_list = list(output_args) array_symbols = {} for array in expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): arg_list.append(InputArgument(symbol)) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_vals, local_vars, global_vars) def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): if line == '': code_lines.append("#\n") else: code_lines.append("# %s\n" % line) return code_lines def _preprocessor_statements(self, prefix): return [] def _get_routine_opening(self, routine): """Returns the opening statements of the routine.""" code_list = [] code_list.append("function ") # Inputs args = [] for i, arg in enumerate(routine.arguments): if isinstance(arg, OutputArgument): raise CodeGenError("Julia: invalid argument of type %s" % str(type(arg))) if isinstance(arg, (InputArgument, InOutArgument)): args.append("%s" % self._get_symbol(arg.name)) args = ", ".join(args) code_list.append("%s(%s)\n" % (routine.name, args)) code_list = [ "".join(code_list) ] return code_list def _declare_arguments(self, routine): return [] def _declare_globals(self, routine): return [] def _declare_locals(self, routine): return [] def _get_routine_ending(self, routine): outs = [] for result in routine.results: if isinstance(result, Result): # Note: name not result_var; want `y` not `y[i]` for Indexed s = self._get_symbol(result.name) else: raise CodeGenError("unexpected object in Routine results") outs.append(s) return ["return " + ", ".join(outs) + "\nend\n"] def _call_printer(self, routine): declarations = [] code_lines = [] for i, result in enumerate(routine.results): if isinstance(result, Result): assign_to = result.result_var else: raise CodeGenError("unexpected object in Routine results") constants, not_supported, jl_expr = self._printer_method_with_settings( 'doprint', dict(human=False), result.expr, assign_to=assign_to) for obj, v in sorted(constants, key=str): declarations.append( "%s = %s\n" % (obj, v)) for obj in sorted(not_supported, key=str): if isinstance(obj, Function): name = obj.func else: name = obj declarations.append( "# unsupported: %s\n" % (name)) code_lines.append("%s\n" % (jl_expr)) return declarations + code_lines def _indent_code(self, codelines): # Note that indenting seems to happen twice, first # statement-by-statement by JuliaPrinter then again here. p = JuliaCodePrinter({'human': False}) return p.indent_code(codelines) def dump_jl(self, routines, f, prefix, header=True, empty=True): self.dump_code(routines, f, prefix, header, empty) dump_jl.extension = code_extension dump_jl.__doc__ = CodeGen.dump_code.__doc__ # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_jl] class OctaveCodeGen(CodeGen): """Generator for Octave code. The .write() method inherited from CodeGen will output a code file <prefix>.m. Octave .m files usually contain one function. That function name should match the filename (``prefix``). If you pass multiple ``name_expr`` pairs, the latter ones are presumed to be private functions accessed by the primary function. You should only pass inputs to ``argument_sequence``: outputs are ordered according to their order in ``name_expr``. """ code_extension = "m" def __init__(self, project='project', printer=None): super(OctaveCodeGen, self).__init__(project) self.printer = printer or OctaveCodePrinter() def routine(self, name, expr, argument_sequence, global_vars): """Specialized Routine creation for Octave.""" # FIXME: this is probably general enough for other high-level # languages, perhaps its the C/Fortran one that is specialized! if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(expr) else: expressions = Tuple(expr) # local variables local_vars = {i.label for i in expressions.atoms(Idx)} # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments old_symbols = expressions.free_symbols - local_vars - global_vars symbols = set([]) for s in old_symbols: if isinstance(s, Idx): symbols.update(s.args[1].free_symbols) elif not isinstance(s, Indexed): symbols.add(s) # Octave supports multiple return values return_vals = [] for (i, expr) in enumerate(expressions): if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs symbol = out_arg if isinstance(out_arg, Indexed): symbol = out_arg.base.label if not isinstance(out_arg, (Indexed, Symbol, MatrixSymbol)): raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") return_vals.append(Result(expr, name=symbol, result_var=out_arg)) if not expr.has(symbol): # this is a pure output: remove from the symbols list, so # it doesn't become an input. symbols.remove(symbol) else: # we have no name for this output return_vals.append(Result(expr, name='out%d' % (i+1))) # setup input argument list arg_list = [] array_symbols = {} for array in expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): arg_list.append(InputArgument(symbol)) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_vals, local_vars, global_vars) def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): if line == '': code_lines.append("%\n") else: code_lines.append("%% %s\n" % line) return code_lines def _preprocessor_statements(self, prefix): return [] def _get_routine_opening(self, routine): """Returns the opening statements of the routine.""" code_list = [] code_list.append("function ") # Outputs outs = [] for i, result in enumerate(routine.results): if isinstance(result, Result): # Note: name not result_var; want `y` not `y(i)` for Indexed s = self._get_symbol(result.name) else: raise CodeGenError("unexpected object in Routine results") outs.append(s) if len(outs) > 1: code_list.append("[" + (", ".join(outs)) + "]") else: code_list.append("".join(outs)) code_list.append(" = ") # Inputs args = [] for i, arg in enumerate(routine.arguments): if isinstance(arg, (OutputArgument, InOutArgument)): raise CodeGenError("Octave: invalid argument of type %s" % str(type(arg))) if isinstance(arg, InputArgument): args.append("%s" % self._get_symbol(arg.name)) args = ", ".join(args) code_list.append("%s(%s)\n" % (routine.name, args)) code_list = [ "".join(code_list) ] return code_list def _declare_arguments(self, routine): return [] def _declare_globals(self, routine): if not routine.global_vars: return [] s = " ".join(sorted([self._get_symbol(g) for g in routine.global_vars])) return ["global " + s + "\n"] def _declare_locals(self, routine): return [] def _get_routine_ending(self, routine): return ["end\n"] def _call_printer(self, routine): declarations = [] code_lines = [] for i, result in enumerate(routine.results): if isinstance(result, Result): assign_to = result.result_var else: raise CodeGenError("unexpected object in Routine results") constants, not_supported, oct_expr = self._printer_method_with_settings( 'doprint', dict(human=False), result.expr, assign_to=assign_to) for obj, v in sorted(constants, key=str): declarations.append( " %s = %s; %% constant\n" % (obj, v)) for obj in sorted(not_supported, key=str): if isinstance(obj, Function): name = obj.func else: name = obj declarations.append( " %% unsupported: %s\n" % (name)) code_lines.append("%s\n" % (oct_expr)) return declarations + code_lines def _indent_code(self, codelines): return self._printer_method_with_settings( 'indent_code', dict(human=False), codelines) def dump_m(self, routines, f, prefix, header=True, empty=True, inline=True): # Note used to call self.dump_code() but we need more control for header code_lines = self._preprocessor_statements(prefix) for i, routine in enumerate(routines): if i > 0: if empty: code_lines.append("\n") code_lines.extend(self._get_routine_opening(routine)) if i == 0: if routine.name != prefix: raise ValueError('Octave function name should match prefix') if header: code_lines.append("%" + prefix.upper() + " Autogenerated by sympy\n") code_lines.append(''.join(self._get_header())) code_lines.extend(self._declare_arguments(routine)) code_lines.extend(self._declare_globals(routine)) code_lines.extend(self._declare_locals(routine)) if empty: code_lines.append("\n") code_lines.extend(self._call_printer(routine)) if empty: code_lines.append("\n") code_lines.extend(self._get_routine_ending(routine)) code_lines = self._indent_code(''.join(code_lines)) if code_lines: f.write(code_lines) dump_m.extension = code_extension dump_m.__doc__ = CodeGen.dump_code.__doc__ # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_m] class RustCodeGen(CodeGen): """Generator for Rust code. The .write() method inherited from CodeGen will output a code file <prefix>.rs """ code_extension = "rs" def __init__(self, project="project", printer=None): super(RustCodeGen, self).__init__(project=project) self.printer = printer or RustCodePrinter() def routine(self, name, expr, argument_sequence, global_vars): """Specialized Routine creation for Rust.""" if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(expr) else: expressions = Tuple(expr) # local variables local_vars = set([i.label for i in expressions.atoms(Idx)]) # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments symbols = expressions.free_symbols - local_vars - global_vars - expressions.atoms(Indexed) # Rust supports multiple return values return_vals = [] output_args = [] for (i, expr) in enumerate(expressions): if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs symbol = out_arg if isinstance(out_arg, Indexed): dims = tuple([ (S.One, dim) for dim in out_arg.shape]) symbol = out_arg.base.label output_args.append(InOutArgument(symbol, out_arg, expr, dimensions=dims)) if not isinstance(out_arg, (Indexed, Symbol, MatrixSymbol)): raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") return_vals.append(Result(expr, name=symbol, result_var=out_arg)) if not expr.has(symbol): # this is a pure output: remove from the symbols list, so # it doesn't become an input. symbols.remove(symbol) else: # we have no name for this output return_vals.append(Result(expr, name='out%d' % (i+1))) # setup input argument list output_args.sort(key=lambda x: str(x.name)) arg_list = list(output_args) array_symbols = {} for array in expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): arg_list.append(InputArgument(symbol)) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_vals, local_vars, global_vars) def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] code_lines.append("/\n") tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): code_lines.append((" %s" % line.center(76)).rstrip() + "\n") code_lines.append(" /\n") return code_lines def get_prototype(self, routine): """Returns a string for the function prototype of the routine. If the routine has multiple result objects, an CodeGenError is raised. See: https://en.wikipedia.org/wiki/Function_prototype """ results = [i.get_datatype('Rust') for i in routine.results] if len(results) == 1: rstype = " -> " + results[0] elif len(routine.results) > 1: rstype = " -> (" + ", ".join(results) + ")" else: rstype = "" type_args = [] for arg in routine.arguments: name = self.printer.doprint(arg.name) if arg.dimensions or isinstance(arg, ResultBase): type_args.append(("%s" % name, arg.get_datatype('Rust'))) else: type_args.append((name, arg.get_datatype('Rust'))) arguments = ", ".join([ "%s: %s" % t for t in type_args]) return "fn %s(%s)%s" % (routine.name, arguments, rstype) def _preprocessor_statements(self, prefix): code_lines = [] # code_lines.append("use std::f64::consts::;\n") return code_lines def _get_routine_opening(self, routine): prototype = self.get_prototype(routine) return ["%s {\n" % prototype] def _declare_arguments(self, routine): # arguments are declared in prototype return [] def _declare_globals(self, routine): # global variables are not explicitly declared within C functions return [] def _declare_locals(self, routine): # loop variables are declared in loop statement return [] def _call_printer(self, routine): code_lines = [] declarations = [] returns = [] # Compose a list of symbols to be dereferenced in the function # body. These are the arguments that were passed by a reference # pointer, excluding arrays. dereference = [] for arg in routine.arguments: if isinstance(arg, ResultBase) and not arg.dimensions: dereference.append(arg.name) for i, result in enumerate(routine.results): if isinstance(result, Result): assign_to = result.result_var returns.append(str(result.result_var)) else: raise CodeGenError("unexpected object in Routine results") constants, not_supported, rs_expr = self._printer_method_with_settings( 'doprint', dict(human=False), result.expr, assign_to=assign_to) for name, value in sorted(constants, key=str): declarations.append("const %s: f64 = %s;\n" % (name, value)) for obj in sorted(not_supported, key=str): if isinstance(obj, Function): name = obj.func else: name = obj declarations.append("// unsupported: %s\n" % (name)) code_lines.append("let %s\n" % rs_expr); if len(returns) > 1: returns = ['(' + ', '.join(returns) + ')'] returns.append('\n') return declarations + code_lines + returns def _get_routine_ending(self, routine): return ["}\n"] def dump_rs(self, routines, f, prefix, header=True, empty=True): self.dump_code(routines, f, prefix, header, empty) dump_rs.extension = code_extension dump_rs.__doc__ = CodeGen.dump_code.__doc__ # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_rs] def get_code_generator(language, project=None, standard=None, printer = None): if language == 'C': if standard is None: pass elif standard.lower() == 'c89': language = 'C89' elif standard.lower() == 'c99': language = 'C99' CodeGenClass = {"C": CCodeGen, "C89": C89CodeGen, "C99": C99CodeGen, "F95": FCodeGen, "JULIA": JuliaCodeGen, "OCTAVE": OctaveCodeGen, "RUST": RustCodeGen}.get(language.upper()) if CodeGenClass is None: raise ValueError("Language '%s' is not supported." % language) return CodeGenClass(project, printer) # # Friendly functions # def codegen(name_expr, language=None, prefix=None, project="project", to_files=False, header=True, empty=True, argument_sequence=None, global_vars=None, standard=None, code_gen=None, printer = None): """Generate source code for expressions in a given language. Parameters ========== name_expr : tuple, or list of tuples A single (name, expression) tuple or a list of (name, expression) tuples. Each tuple corresponds to a routine. If the expression is an equality (an instance of class Equality) the left hand side is considered an output argument. If expression is an iterable, then the routine will have multiple outputs. language : string, A string that indicates the source code language. This is case insensitive. Currently, 'C', 'F95' and 'Octave' are supported. 'Octave' generates code compatible with both Octave and Matlab. prefix : string, optional A prefix for the names of the files that contain the source code. Language-dependent suffixes will be appended. If omitted, the name of the first name_expr tuple is used. project : string, optional A project name, used for making unique preprocessor instructions. [default: "project"] to_files : bool, optional When True, the code will be written to one or more files with the given prefix, otherwise strings with the names and contents of these files are returned. [default: False] header : bool, optional When True, a header is written on top of each source file. [default: True] empty : bool, optional When True, empty lines are used to structure the code. [default: True] argument_sequence : iterable, optional Sequence of arguments for the routine in a preferred order. A CodeGenError is raised if required arguments are missing. Redundant arguments are used without warning. If omitted, arguments will be ordered alphabetically, but with all input arguments first, and then output or in-out arguments. global_vars : iterable, optional Sequence of global variables used by the routine. Variables listed here will not show up as function arguments. standard : string code_gen : CodeGen instance An instance of a CodeGen subclass. Overrides ``language``. Examples ======== >>> from sympy.utilities.codegen import codegen >>> from sympy.abc import x, y, z >>> [(c_name, c_code), (h_name, c_header)] = codegen( ... ("f", x+yz), "C89", "test", header=False, empty=False) >>> print(c_name) test.c >>> print(c_code) #include "test.h" #include <math.h> double f(double x, double y, double z) { double f_result; f_result = x + yz; return f_result; } <BLANKLINE> >>> print(h_name) test.h >>> print(c_header) #ifndef PROJECT__TEST__H #define PROJECT__TEST__H double f(double x, double y, double z); #endif <BLANKLINE> Another example using Equality objects to give named outputs. Here the filename (prefix) is taken from the first (name, expr) pair. >>> from sympy.abc import f, g >>> from sympy import Eq >>> [(c_name, c_code), (h_name, c_header)] = codegen( ... [("myfcn", x + y), ("fcn2", [Eq(f, 2x), Eq(g, y)])], ... "C99", header=False, empty=False) >>> print(c_name) myfcn.c >>> print(c_code) #include "myfcn.h" #include <math.h> double myfcn(double x, double y) { double myfcn_result; myfcn_result = x + y; return myfcn_result; } void fcn2(double x, double y, double f, double g) { (f) = 2x; (g) = y; } <BLANKLINE> If the generated function(s) will be part of a larger project where various global variables have been defined, the 'global_vars' option can be used to remove the specified variables from the function signature >>> from sympy.utilities.codegen import codegen >>> from sympy.abc import x, y, z >>> [(f_name, f_code), header] = codegen( ... ("f", x+yz), "F95", header=False, empty=False, ... argument_sequence=(x, y), global_vars=(z,)) >>> print(f_code) REAL8 function f(x, y) implicit none REAL8, intent(in) :: x REAL8, intent(in) :: y f = x + yz end function <BLANKLINE> """ # Initialize the code generator. if language is None: if code_gen is None: raise ValueError("Need either language or code_gen") else: if code_gen is not None: raise ValueError("You cannot specify both language and code_gen.") code_gen = get_code_generator(language, project, standard, printer) if isinstance(name_expr[0], string_types): # single tuple is given, turn it into a singleton list with a tuple. name_expr = [name_expr] if prefix is None: prefix = name_expr[0][0] # Construct Routines appropriate for this code_gen from (name, expr) pairs. routines = [] for name, expr in name_expr: routines.append(code_gen.routine(name, expr, argument_sequence, global_vars)) # Write the code. return code_gen.write(routines, prefix, to_files, header, empty) def make_routine(name, expr, argument_sequence=None, global_vars=None, language="F95"): """A factory that makes an appropriate Routine from an expression. Parameters ========== name : string The name of this routine in the generated code. expr : expression or list/tuple of expressions A SymPy expression that the Routine instance will represent. If given a list or tuple of expressions, the routine will be considered to have multiple return values and/or output arguments. argument_sequence : list or tuple, optional List arguments for the routine in a preferred order. If omitted, the results are language dependent, for example, alphabetical order or in the same order as the given expressions. global_vars : iterable, optional Sequence of global variables used by the routine. Variables listed here will not show up as function arguments. language : string, optional Specify a target language. The Routine itself should be language-agnostic but the precise way one is created, error checking, etc depend on the language. [default: "F95"]. A decision about whether to use output arguments or return values is made depending on both the language and the particular mathematical expressions. For an expression of type Equality, the left hand side is typically made into an OutputArgument (or perhaps an InOutArgument if appropriate). Otherwise, typically, the calculated expression is made a return values of the routine. Examples ======== >>> from sympy.utilities.codegen import make_routine >>> from sympy.abc import x, y, f, g >>> from sympy import Eq >>> r = make_routine('test', [Eq(f, 2x), Eq(g, x + y)]) >>> [arg.result_var for arg in r.results] [] >>> [arg.name for arg in r.arguments] [x, y, f, g] >>> [arg.name for arg in r.result_variables] [f, g] >>> r.local_vars set() Another more complicated example with a mixture of specified and automatically-assigned names. Also has Matrix output. >>> from sympy import Matrix >>> r = make_routine('fcn', [xy, Eq(f, 1), Eq(g, x + g), Matrix([[x, 2]])]) >>> [arg.result_var for arg in r.results] # doctest: +SKIP [result_5397460570204848505] >>> [arg.expr for arg in r.results] [xy] >>> [arg.name for arg in r.arguments] # doctest: +SKIP [x, y, f, g, out_8598435338387848786] We can examine the various arguments more closely: >>> from sympy.utilities.codegen import (InputArgument, OutputArgument, ... InOutArgument) >>> [a.name for a in r.arguments if isinstance(a, InputArgument)] [x, y] >>> [a.name for a in r.arguments if isinstance(a, OutputArgument)] # doctest: +SKIP [f, out_8598435338387848786] >>> [a.expr for a in r.arguments if isinstance(a, OutputArgument)] [1, Matrix([[x, 2]])] >>> [a.name for a in r.arguments if isinstance(a, InOutArgument)] [g] >>> [a.expr for a in r.arguments if isinstance(a, InOutArgument)] [g + x] """ # initialize a new code generator code_gen = get_code_generator(language) return code_gen.routine(name, expr, argument_sequence, global_vars)
840546895b1011b9812ededbdfe36cb91b75cd9a024a358e3dbedf5960fd4b86	"""A module providing information about the necessity of brackets""" from __future__ import print_function, division from sympy.core.function import _coeff_isneg # Default precedence values for some basic types PRECEDENCE = { "Lambda": 1, "Xor": 10, "Or": 20, "And": 30, "Relational": 35, "Add": 40, "Mul": 50, "Pow": 60, "Func": 70, "Not": 100, "Atom": 1000, "BitwiseOr": 36, "BitwiseAnd": 38 } # A dictionary assigning precedence values to certain classes. These values are # treated like they were inherited, so not every single class has to be named # here. # Do not use this with printers other than StrPrinter PRECEDENCE_VALUES = { "Equivalent": PRECEDENCE["Xor"], "Xor": PRECEDENCE["Xor"], "Implies": PRECEDENCE["Xor"], "Or": PRECEDENCE["Or"], "And": PRECEDENCE["And"], "Add": PRECEDENCE["Add"], "Pow": PRECEDENCE["Pow"], "Relational": PRECEDENCE["Relational"], "Sub": PRECEDENCE["Add"], "Not": PRECEDENCE["Not"], "Function" : PRECEDENCE["Func"], "NegativeInfinity": PRECEDENCE["Add"], "MatAdd": PRECEDENCE["Add"], "MatPow": PRECEDENCE["Pow"], "TensAdd": PRECEDENCE["Add"], # As soon as `TensMul` is a subclass of `Mul`, remove this: "TensMul": PRECEDENCE["Mul"], "HadamardProduct": PRECEDENCE["Mul"], "HadamardPower": PRECEDENCE["Pow"], "KroneckerProduct": PRECEDENCE["Mul"], "Equality": PRECEDENCE["Mul"], "Unequality": PRECEDENCE["Mul"], } # Sometimes it's not enough to assign a fixed precedence value to a # class. Then a function can be inserted in this dictionary that takes # an instance of this class as argument and returns the appropriate # precedence value. # Precedence functions def precedence_Mul(item): if _coeff_isneg(item): return PRECEDENCE["Add"] return PRECEDENCE["Mul"] def precedence_Rational(item): if item.p < 0: return PRECEDENCE["Add"] return PRECEDENCE["Mul"] def precedence_Integer(item): if item.p < 0: return PRECEDENCE["Add"] return PRECEDENCE["Atom"] def precedence_Float(item): if item < 0: return PRECEDENCE["Add"] return PRECEDENCE["Atom"] def precedence_PolyElement(item): if item.is_generator: return PRECEDENCE["Atom"] elif item.is_ground: return precedence(item.coeff(1)) elif item.is_term: return PRECEDENCE["Mul"] else: return PRECEDENCE["Add"] def precedence_FracElement(item): if item.denom == 1: return precedence_PolyElement(item.numer) else: return PRECEDENCE["Mul"] def precedence_UnevaluatedExpr(item): return precedence(item.args[0]) PRECEDENCE_FUNCTIONS = { "Integer": precedence_Integer, "Mul": precedence_Mul, "Rational": precedence_Rational, "Float": precedence_Float, "PolyElement": precedence_PolyElement, "FracElement": precedence_FracElement, "UnevaluatedExpr": precedence_UnevaluatedExpr, } def precedence(item): """Returns the precedence of a given object. This is the precedence for StrPrinter. """ if hasattr(item, "precedence"): return item.precedence try: mro = item.__class__.__mro__ except AttributeError: return PRECEDENCE["Atom"] for i in mro: n = i.__name__ if n in PRECEDENCE_FUNCTIONS: return PRECEDENCE_FUNCTIONS[n](item) elif n in PRECEDENCE_VALUES: return PRECEDENCE_VALUES[n] return PRECEDENCE["Atom"] def precedence_traditional(item): """Returns the precedence of a given object according to the traditional rules of mathematics. This is the precedence for the LaTeX and pretty printer. """ # Integral, Sum, Product, Limit have the precedence of Mul in LaTeX, # the precedence of Atom for other printers: from sympy import Integral, Sum, Product, Limit, Derivative, Transpose, Adjoint from sympy.core.expr import UnevaluatedExpr from sympy.tensor.functions import TensorProduct if isinstance(item, (Integral, Sum, Product, Limit, Derivative, TensorProduct)): return PRECEDENCE["Mul"] elif isinstance(item, (Transpose, Adjoint)): return PRECEDENCE["Pow"] elif (item.__class__.__name__ in ("Dot", "Cross", "Gradient", "Divergence", "Curl", "Laplacian")): return PRECEDENCE["Mul"]-1 elif isinstance(item, UnevaluatedExpr): return precedence_traditional(item.args[0]) else: return precedence(item)
86cc27f1beac98e70baf14f01f19ec2b3b7798697709f6ce36e10d79ca578e77	""" A Printer for generating readable representation of most sympy classes. """ from __future__ import print_function, division from sympy.core import S, Rational, Pow, Basic, Mul from sympy.core.mul import _keep_coeff from sympy.core.compatibility import string_types from .printer import Printer from sympy.printing.precedence import precedence, PRECEDENCE from mpmath.libmp import prec_to_dps, to_str as mlib_to_str from sympy.utilities import default_sort_key class StrPrinter(Printer): printmethod = "_sympystr" _default_settings = { "order": None, "full_prec": "auto", "sympy_integers": False, "abbrev": False, } _relationals = dict() def parenthesize(self, item, level, strict=False): if (precedence(item) < level) or ((not strict) and precedence(item) <= level): return "(%s)" % self._print(item) else: return self._print(item) def stringify(self, args, sep, level=0): return sep.join([self.parenthesize(item, level) for item in args]) def emptyPrinter(self, expr): if isinstance(expr, string_types): return expr elif isinstance(expr, Basic): return repr(expr) else: return str(expr) def _print_Add(self, expr, order=None): if self.order == 'none': terms = list(expr.args) else: terms = self._as_ordered_terms(expr, order=order) PREC = precedence(expr) l = [] for term in terms: t = self._print(term) if t.startswith('-'): sign = "-" t = t[1:] else: sign = "+" if precedence(term) < PREC: l.extend([sign, "(%s)" % t]) else: l.extend([sign, t]) sign = l.pop(0) if sign == '+': sign = "" return sign + ' '.join(l) def _print_BooleanTrue(self, expr): return "True" def _print_BooleanFalse(self, expr): return "False" def _print_Not(self, expr): return '~%s' %(self.parenthesize(expr.args[0],PRECEDENCE["Not"])) def _print_And(self, expr): return self.stringify(expr.args, " & ", PRECEDENCE["BitwiseAnd"]) def _print_Or(self, expr): return self.stringify(expr.args, " \| ", PRECEDENCE["BitwiseOr"]) def _print_AppliedPredicate(self, expr): return '%s(%s)' % (self._print(expr.func), self._print(expr.arg)) def _print_Basic(self, expr): l = [self._print(o) for o in expr.args] return expr.__class__.__name__ + "(%s)" % ", ".join(l) def _print_BlockMatrix(self, B): if B.blocks.shape == (1, 1): self._print(B.blocks[0, 0]) return self._print(B.blocks) def _print_Catalan(self, expr): return 'Catalan' def _print_ComplexInfinity(self, expr): return 'zoo' def _print_ConditionSet(self, s): args = tuple([self._print(i) for i in (s.sym, s.condition)]) if s.base_set is S.UniversalSet: return 'ConditionSet(%s, %s)' % args args += (self._print(s.base_set),) return 'ConditionSet(%s, %s, %s)' % args def _print_Derivative(self, expr): dexpr = expr.expr dvars = [i[0] if i[1] == 1 else i for i in expr.variable_count] return 'Derivative(%s)' % ", ".join(map(lambda arg: self._print(arg), [dexpr] + dvars)) def _print_dict(self, d): keys = sorted(d.keys(), key=default_sort_key) items = [] for key in keys: item = "%s: %s" % (self._print(key), self._print(d[key])) items.append(item) return "{%s}" % ", ".join(items) def _print_Dict(self, expr): return self._print_dict(expr) def _print_RandomDomain(self, d): if hasattr(d, 'as_boolean'): return 'Domain: ' + self._print(d.as_boolean()) elif hasattr(d, 'set'): return ('Domain: ' + self._print(d.symbols) + ' in ' + self._print(d.set)) else: return 'Domain on ' + self._print(d.symbols) def _print_Dummy(self, expr): return '_' + expr.name def _print_EulerGamma(self, expr): return 'EulerGamma' def _print_Exp1(self, expr): return 'E' def _print_ExprCondPair(self, expr): return '(%s, %s)' % (self._print(expr.expr), self._print(expr.cond)) def _print_FiniteSet(self, s): s = sorted(s, key=default_sort_key) if len(s) > 10: printset = s[:3] + ['...'] + s[-3:] else: printset = s return '{' + ', '.join(self._print(el) for el in printset) + '}' def _print_Function(self, expr): return expr.func.__name__ + "(%s)" % self.stringify(expr.args, ", ") def _print_GeometryEntity(self, expr): # GeometryEntity is special -- it's base is tuple return str(expr) def _print_GoldenRatio(self, expr): return 'GoldenRatio' def _print_TribonacciConstant(self, expr): return 'TribonacciConstant' def _print_ImaginaryUnit(self, expr): return 'I' def _print_Infinity(self, expr): return 'oo' def _print_Integral(self, expr): def _xab_tostr(xab): if len(xab) == 1: return self._print(xab[0]) else: return self._print((xab[0],) + tuple(xab[1:])) L = ', '.join([_xab_tostr(l) for l in expr.limits]) return 'Integral(%s, %s)' % (self._print(expr.function), L) def _print_Interval(self, i): fin = 'Interval{m}({a}, {b})' a, b, l, r = i.args if a.is_infinite and b.is_infinite: m = '' elif a.is_infinite and not r: m = '' elif b.is_infinite and not l: m = '' elif not l and not r: m = '' elif l and r: m = '.open' elif l: m = '.Lopen' else: m = '.Ropen' return fin.format({'a': a, 'b': b, 'm': m}) def _print_AccumulationBounds(self, i): return "AccumBounds(%s, %s)" % (self._print(i.min), self._print(i.max)) def _print_Inverse(self, I): return "%s(-1)" % self.parenthesize(I.arg, PRECEDENCE["Pow"]) def _print_Lambda(self, obj): args, expr = obj.args if len(args) == 1: return "Lambda(%s, %s)" % (self._print(args.args[0]), self._print(expr)) else: arg_string = ", ".join(self._print(arg) for arg in args) return "Lambda((%s), %s)" % (arg_string, self._print(expr)) def _print_LatticeOp(self, expr): args = sorted(expr.args, key=default_sort_key) return expr.func.__name__ + "(%s)" % ", ".join(self._print(arg) for arg in args) def _print_Limit(self, expr): e, z, z0, dir = expr.args if str(dir) == "+": return "Limit(%s, %s, %s)" % tuple(map(self._print, (e, z, z0))) else: return "Limit(%s, %s, %s, dir='%s')" % tuple(map(self._print, (e, z, z0, dir))) def _print_list(self, expr): return "[%s]" % self.stringify(expr, ", ") def _print_MatrixBase(self, expr): return expr._format_str(self) _print_MutableSparseMatrix = \ _print_ImmutableSparseMatrix = \ _print_Matrix = \ _print_DenseMatrix = \ _print_MutableDenseMatrix = \ _print_ImmutableMatrix = \ _print_ImmutableDenseMatrix = \ _print_MatrixBase def _print_MatrixElement(self, expr): return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) \ + '[%s, %s]' % (self._print(expr.i), self._print(expr.j)) def _print_MatrixSlice(self, expr): def strslice(x): x = list(x) if x[2] == 1: del x[2] if x[1] == x[0] + 1: del x[1] if x[0] == 0: x[0] = '' return ':'.join(map(lambda arg: self._print(arg), x)) return (self._print(expr.parent) + '[' + strslice(expr.rowslice) + ', ' + strslice(expr.colslice) + ']') def _print_DeferredVector(self, expr): return expr.name def _print_Mul(self, expr): prec = precedence(expr) c, e = expr.as_coeff_Mul() if c < 0: expr = _keep_coeff(-c, e) sign = "-" else: sign = "" a = [] # items in the numerator b = [] # items that are in the denominator (if any) pow_paren = [] # Will collect all pow with more than one base element and exp = -1 if self.order not in ('old', 'none'): args = expr.as_ordered_factors() else: # use make_args in case expr was something like -x -> x args = Mul.make_args(expr) # Gather args for numerator/denominator for item in args: if item.is_commutative and item.is_Pow and item.exp.is_Rational and item.exp.is_negative: if item.exp != -1: b.append(Pow(item.base, -item.exp, evaluate=False)) else: if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 pow_paren.append(item) b.append(Pow(item.base, -item.exp)) elif item.is_Rational and item is not S.Infinity: if item.p != 1: a.append(Rational(item.p)) if item.q != 1: b.append(Rational(item.q)) else: a.append(item) a = a or [S.One] a_str = [self.parenthesize(x, prec, strict=False) for x in a] b_str = [self.parenthesize(x, prec, strict=False) for x in b] # To parenthesize Pow with exp = -1 and having more than one Symbol for item in pow_paren: if item.base in b: b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] if not b: return sign + ''.join(a_str) elif len(b) == 1: return sign + ''.join(a_str) + "/" + b_str[0] else: return sign + ''.join(a_str) + "/(%s)" % ''.join(b_str) def _print_MatMul(self, expr): c, m = expr.as_coeff_mmul() if c.is_number and c < 0: expr = _keep_coeff(-c, m) sign = "-" else: sign = "" return sign + ''.join( [self.parenthesize(arg, precedence(expr)) for arg in expr.args] ) def _print_HadamardProduct(self, expr): return '.'.join([self.parenthesize(arg, precedence(expr)) for arg in expr.args]) def _print_HadamardPower(self, expr): PREC = precedence(expr) return '.*'.join([ self.parenthesize(expr.base, PREC), self.parenthesize(expr.exp, PREC) ]) def _print_ElementwiseApplyFunction(self, expr): return "{0}({1}...)".format( expr.function, self._print(expr.expr), ) def _print_NaN(self, expr): return 'nan' def _print_NegativeInfinity(self, expr): return '-oo' def _print_Order(self, expr): if not expr.variables or all(p is S.Zero for p in expr.point): if len(expr.variables) <= 1: return 'O(%s)' % self._print(expr.expr) else: return 'O(%s)' % self.stringify((expr.expr,) + expr.variables, ', ', 0) else: return 'O(%s)' % self.stringify(expr.args, ', ', 0) def _print_Ordinal(self, expr): return expr.__str__() def _print_Cycle(self, expr): return expr.__str__() def _print_Permutation(self, expr): from sympy.combinatorics.permutations import Permutation, Cycle if Permutation.print_cyclic: if not expr.size: return '()' # before taking Cycle notation, see if the last element is # a singleton and move it to the head of the string s = Cycle(expr)(expr.size - 1).__repr__()[len('Cycle'):] last = s.rfind('(') if not last == 0 and ',' not in s[last:]: s = s[last:] + s[:last] s = s.replace(',', '') return s else: s = expr.support() if not s: if expr.size < 5: return 'Permutation(%s)' % self._print(expr.array_form) return 'Permutation([], size=%s)' % self._print(expr.size) trim = self._print(expr.array_form[:s[-1] + 1]) + ', size=%s' % self._print(expr.size) use = full = self._print(expr.array_form) if len(trim) < len(full): use = trim return 'Permutation(%s)' % use def _print_Subs(self, obj): expr, old, new = obj.args if len(obj.point) == 1: old = old[0] new = new[0] return "Subs(%s, %s, %s)" % ( self._print(expr), self._print(old), self._print(new)) def _print_TensorIndex(self, expr): return expr._print() def _print_TensorHead(self, expr): return expr._print() def _print_Tensor(self, expr): return expr._print() def _print_TensMul(self, expr): # prints expressions like "A(a)", "3A(a)", "(1+x)A(a)" sign, args = expr._get_args_for_traditional_printer() return sign + "".join( [self.parenthesize(arg, precedence(expr)) for arg in args] ) def _print_TensAdd(self, expr): return expr._print() def _print_PermutationGroup(self, expr): p = [' %s' % self._print(a) for a in expr.args] return 'PermutationGroup([\n%s])' % ',\n'.join(p) def _print_Pi(self, expr): return 'pi' def _print_PolyRing(self, ring): return "Polynomial ring in %s over %s with %s order" % \ (", ".join(map(lambda rs: self._print(rs), ring.symbols)), self._print(ring.domain), self._print(ring.order)) def _print_FracField(self, field): return "Rational function field in %s over %s with %s order" % \ (", ".join(map(lambda fs: self._print(fs), field.symbols)), self._print(field.domain), self._print(field.order)) def _print_FreeGroupElement(self, elm): return elm.__str__() def _print_PolyElement(self, poly): return poly.str(self, PRECEDENCE, "%s*%s", "") def _print_FracElement(self, frac): if frac.denom == 1: return self._print(frac.numer) else: numer = self.parenthesize(frac.numer, PRECEDENCE["Mul"], strict=True) denom = self.parenthesize(frac.denom, PRECEDENCE["Atom"], strict=True) return numer + "/" + denom def _print_Poly(self, expr): ATOM_PREC = PRECEDENCE["Atom"] - 1 terms, gens = [], [ self.parenthesize(s, ATOM_PREC) for s in expr.gens ] for monom, coeff in expr.terms(): s_monom = [] for i, exp in enumerate(monom): if exp > 0: if exp == 1: s_monom.append(gens[i]) else: s_monom.append(gens[i] + "*%d" % exp) s_monom = "".join(s_monom) if coeff.is_Add: if s_monom: s_coeff = "(" + self._print(coeff) + ")" else: s_coeff = self._print(coeff) else: if s_monom: if coeff is S.One: terms.extend(['+', s_monom]) continue if coeff is S.NegativeOne: terms.extend(['-', s_monom]) continue s_coeff = self._print(coeff) if not s_monom: s_term = s_coeff else: s_term = s_coeff + "" + s_monom if s_term.startswith('-'): terms.extend(['-', s_term[1:]]) else: terms.extend(['+', s_term]) if terms[0] in ['-', '+']: modifier = terms.pop(0) if modifier == '-': terms[0] = '-' + terms[0] format = expr.__class__.__name__ + "(%s, %s" from sympy.polys.polyerrors import PolynomialError try: format += ", modulus=%s" % expr.get_modulus() except PolynomialError: format += ", domain='%s'" % expr.get_domain() format += ")" for index, item in enumerate(gens): if len(item) > 2 and (item[:1] == "(" and item[len(item) - 1:] == ")"): gens[index] = item[1:len(item) - 1] return format % (' '.join(terms), ', '.join(gens)) def _print_ProductSet(self, p): return ' x '.join(self._print(set) for set in p.sets) def _print_UniversalSet(self, p): return 'UniversalSet' def _print_AlgebraicNumber(self, expr): if expr.is_aliased: return self._print(expr.as_poly().as_expr()) else: return self._print(expr.as_expr()) def _print_Pow(self, expr, rational=False): PREC = precedence(expr) if expr.exp is S.Half and not rational: return "sqrt(%s)" % self._print(expr.base) if expr.is_commutative: if -expr.exp is S.Half and not rational: # Note: Don't test "expr.exp == -S.Half" here, because that will # match -0.5, which we don't want. return "%s/sqrt(%s)" % tuple(map(lambda arg: self._print(arg), (S.One, expr.base))) if expr.exp is -S.One: # Similarly to the S.Half case, don't test with "==" here. return '%s/%s' % (self._print(S.One), self.parenthesize(expr.base, PREC, strict=False)) e = self.parenthesize(expr.exp, PREC, strict=False) if self.printmethod == '_sympyrepr' and expr.exp.is_Rational and expr.exp.q != 1: # the parenthesized exp should be '(Rational(a, b))' so strip parens, # but just check to be sure. if e.startswith('(Rational'): return '%s%s' % (self.parenthesize(expr.base, PREC, strict=False), e[1:-1]) return '%s%s' % (self.parenthesize(expr.base, PREC, strict=False), e) def _print_UnevaluatedExpr(self, expr): return self._print(expr.args[0]) def _print_MatPow(self, expr): PREC = precedence(expr) return '%s%s' % (self.parenthesize(expr.base, PREC, strict=False), self.parenthesize(expr.exp, PREC, strict=False)) def _print_ImmutableDenseNDimArray(self, expr): return str(expr) def _print_ImmutableSparseNDimArray(self, expr): return str(expr) def _print_Integer(self, expr): if self._settings.get("sympy_integers", False): return "S(%s)" % (expr) return str(expr.p) def _print_Integers(self, expr): return 'Integers' def _print_Naturals(self, expr): return 'Naturals' def _print_Naturals0(self, expr): return 'Naturals0' def _print_Reals(self, expr): return 'Reals' def _print_int(self, expr): return str(expr) def _print_mpz(self, expr): return str(expr) def _print_Rational(self, expr): if expr.q == 1: return str(expr.p) else: if self._settings.get("sympy_integers", False): return "S(%s)/%s" % (expr.p, expr.q) return "%s/%s" % (expr.p, expr.q) def _print_PythonRational(self, expr): if expr.q == 1: return str(expr.p) else: return "%d/%d" % (expr.p, expr.q) def _print_Fraction(self, expr): if expr.denominator == 1: return str(expr.numerator) else: return "%s/%s" % (expr.numerator, expr.denominator) def _print_mpq(self, expr): if expr.denominator == 1: return str(expr.numerator) else: return "%s/%s" % (expr.numerator, expr.denominator) def _print_Float(self, expr): prec = expr._prec if prec < 5: dps = 0 else: dps = prec_to_dps(expr._prec) if self._settings["full_prec"] is True: strip = False elif self._settings["full_prec"] is False: strip = True elif self._settings["full_prec"] == "auto": strip = self._print_level > 1 rv = mlib_to_str(expr._mpf_, dps, strip_zeros=strip) if rv.startswith('-.0'): rv = '-0.' + rv[3:] elif rv.startswith('.0'): rv = '0.' + rv[2:] if rv.startswith('+'): # e.g., +inf -> inf rv = rv[1:] return rv def _print_Relational(self, expr): charmap = { "==": "Eq", "!=": "Ne", ":=": "Assignment", '+=': "AddAugmentedAssignment", "-=": "SubAugmentedAssignment", "=": "MulAugmentedAssignment", "/=": "DivAugmentedAssignment", "%=": "ModAugmentedAssignment", } if expr.rel_op in charmap: return '%s(%s, %s)' % (charmap[expr.rel_op], self._print(expr.lhs), self._print(expr.rhs)) return '%s %s %s' % (self.parenthesize(expr.lhs, precedence(expr)), self._relationals.get(expr.rel_op) or expr.rel_op, self.parenthesize(expr.rhs, precedence(expr))) def _print_ComplexRootOf(self, expr): return "CRootOf(%s, %d)" % (self._print_Add(expr.expr, order='lex'), expr.index) def _print_RootSum(self, expr): args = [self._print_Add(expr.expr, order='lex')] if expr.fun is not S.IdentityFunction: args.append(self._print(expr.fun)) return "RootSum(%s)" % ", ".join(args) def _print_GroebnerBasis(self, basis): cls = basis.__class__.__name__ exprs = [self._print_Add(arg, order=basis.order) for arg in basis.exprs] exprs = "[%s]" % ", ".join(exprs) gens = [ self._print(gen) for gen in basis.gens ] domain = "domain='%s'" % self._print(basis.domain) order = "order='%s'" % self._print(basis.order) args = [exprs] + gens + [domain, order] return "%s(%s)" % (cls, ", ".join(args)) def _print_set(self, s): items = sorted(s, key=default_sort_key) args = ', '.join(self._print(item) for item in items) if not args: return "set()" return '{%s}' % args def _print_frozenset(self, s): if not s: return "frozenset()" return "frozenset(%s)" % self._print_set(s) def _print_SparseMatrix(self, expr): from sympy.matrices import Matrix return self._print(Matrix(expr)) def _print_Sum(self, expr): def _xab_tostr(xab): if len(xab) == 1: return self._print(xab[0]) else: return self._print((xab[0],) + tuple(xab[1:])) L = ', '.join([_xab_tostr(l) for l in expr.limits]) return 'Sum(%s, %s)' % (self._print(expr.function), L) def _print_Symbol(self, expr): return expr.name _print_MatrixSymbol = _print_Symbol _print_RandomSymbol = _print_Symbol def _print_Identity(self, expr): return "I" def _print_ZeroMatrix(self, expr): return "0" def _print_Predicate(self, expr): return "Q.%s" % expr.name def _print_str(self, expr): return str(expr) def _print_tuple(self, expr): if len(expr) == 1: return "(%s,)" % self._print(expr[0]) else: return "(%s)" % self.stringify(expr, ", ") def _print_Tuple(self, expr): return self._print_tuple(expr) def _print_Transpose(self, T): return "%s.T" % self.parenthesize(T.arg, PRECEDENCE["Pow"]) def _print_Uniform(self, expr): return "Uniform(%s, %s)" % (self._print(expr.a), self._print(expr.b)) def _print_Union(self, expr): return 'Union(%s)' %(', '.join([self._print(a) for a in expr.args])) def _print_Complement(self, expr): return r' \ '.join(self._print(set_) for set_ in expr.args) def _print_Quantity(self, expr): if self._settings.get("abbrev", False): return "%s" % expr.abbrev return "%s" % expr.name def _print_Quaternion(self, expr): s = [self.parenthesize(i, PRECEDENCE["Mul"], strict=True) for i in expr.args] a = [s[0]] + [i+""+j for i, j in zip(s[1:], "ijk")] return " + ".join(a) def _print_Dimension(self, expr): return str(expr) def _print_Wild(self, expr): return expr.name + '_' def _print_WildFunction(self, expr): return expr.name + '_' def _print_Zero(self, expr): if self._settings.get("sympy_integers", False): return "S(0)" return "0" def _print_DMP(self, p): from sympy.core.sympify import SympifyError try: if p.ring is not None: # TODO incorporate order return self._print(p.ring.to_sympy(p)) except SympifyError: pass cls = p.__class__.__name__ rep = self._print(p.rep) dom = self._print(p.dom) ring = self._print(p.ring) return "%s(%s, %s, %s)" % (cls, rep, dom, ring) def _print_DMF(self, expr): return self._print_DMP(expr) def _print_Object(self, obj): return 'Object("%s")' % obj.name def _print_IdentityMorphism(self, morphism): return 'IdentityMorphism(%s)' % morphism.domain def _print_NamedMorphism(self, morphism): return 'NamedMorphism(%s, %s, "%s")' % \ (morphism.domain, morphism.codomain, morphism.name) def _print_Category(self, category): return 'Category("%s")' % category.name def _print_BaseScalarField(self, field): return field._coord_sys._names[field._index] def _print_BaseVectorField(self, field): return 'e_%s' % field._coord_sys._names[field._index] def _print_Differential(self, diff): field = diff._form_field if hasattr(field, '_coord_sys'): return 'd%s' % field._coord_sys._names[field._index] else: return 'd(%s)' % self._print(field) def _print_Tr(self, expr): #TODO : Handle indices return "%s(%s)" % ("Tr", self._print(expr.args[0])) def sstr(expr, settings): """Returns the expression as a string. For large expressions where speed is a concern, use the setting order='none'. If abbrev=True setting is used then units are printed in abbreviated form. Examples ======== >>> from sympy import symbols, Eq, sstr >>> a, b = symbols('a b') >>> sstr(Eq(a + b, 0)) 'Eq(a + b, 0)' """ p = StrPrinter(settings) s = p.doprint(expr) return s class StrReprPrinter(StrPrinter): """(internal) -- see sstrrepr""" def _print_str(self, s): return repr(s) def sstrrepr(expr, *settings): """return expr in mixed str/repr form i.e. strings are returned in repr form with quotes, and everything else is returned in str form. This function could be useful for hooking into sys.displayhook """ p = StrReprPrinter(settings) s = p.doprint(expr) return s
e2bb497d83ce2485be0d9a2b068d6cf93e02bc99d758bb6ab5abee7025e96d69	from __future__ import print_function, division def pprint_nodes(subtrees): """ Prettyprints systems of nodes. Examples ======== >>> from sympy.printing.tree import pprint_nodes >>> print(pprint_nodes(["a", "b1\\nb2", "c"])) +-a +-b1 \| b2 +-c """ def indent(s, type=1): x = s.split("\n") r = "+-%s\n" % x[0] for a in x[1:]: if a == "": continue if type == 1: r += "\| %s\n" % a else: r += " %s\n" % a return r if not subtrees: return "" f = "" for a in subtrees[:-1]: f += indent(a) f += indent(subtrees[-1], 2) return f def print_node(node): """ Returns information about the "node". This includes class name, string representation and assumptions. """ s = "%s: %s\n" % (node.__class__.__name__, str(node)) d = node._assumptions if d: for a in sorted(d): v = d[a] if v is None: continue s += "%s: %s\n" % (a, v) return s def tree(node): """ Returns a tree representation of "node" as a string. It uses print_node() together with pprint_nodes() on node.args recursively. See Also ======== print_tree """ subtrees = [] for arg in node.args: subtrees.append(tree(arg)) s = print_node(node) + pprint_nodes(subtrees) return s def print_tree(node): """ Prints a tree representation of "node". Examples ======== >>> from sympy.printing import print_tree >>> from sympy import Symbol >>> x = Symbol('x', odd=True) >>> y = Symbol('y', even=True) >>> print_tree(yx) Pow: yx +-Symbol: y \| algebraic: True \| commutative: True \| complex: True \| even: True \| finite: True \| hermitian: True \| imaginary: False \| infinite: False \| integer: True \| irrational: False \| noninteger: False \| odd: False \| rational: True \| real: True \| transcendental: False +-Symbol: x algebraic: True commutative: True complex: True even: False finite: True hermitian: True imaginary: False infinite: False integer: True irrational: False noninteger: False nonzero: True odd: True rational: True real: True transcendental: False zero: False See Also ======== tree """ print(tree(node))
a66182cb6debf5fae3986d438267dd0c85f50249b8add1bd8d1f38658b5f3a6b	""" A Printer which converts an expression into its LaTeX equivalent. """ from __future__ import print_function, division import itertools from sympy.core import S, Add, Symbol, Mod from sympy.core.alphabets import greeks from sympy.core.containers import Tuple from sympy.core.function import _coeff_isneg, AppliedUndef, Derivative from sympy.core.operations import AssocOp from sympy.core.sympify import SympifyError from sympy.logic.boolalg import true # sympy.printing imports from sympy.printing.precedence import precedence_traditional from sympy.printing.printer import Printer from sympy.printing.conventions import split_super_sub, requires_partial from sympy.printing.precedence import precedence, PRECEDENCE import mpmath.libmp as mlib from mpmath.libmp import prec_to_dps from sympy.core.compatibility import default_sort_key, range from sympy.utilities.iterables import has_variety import re # Hand-picked functions which can be used directly in both LaTeX and MathJax # Complete list at # https://docs.mathjax.org/en/latest/tex.html#supported-latex-commands # This variable only contains those functions which sympy uses. accepted_latex_functions = ['arcsin', 'arccos', 'arctan', 'sin', 'cos', 'tan', 'sinh', 'cosh', 'tanh', 'sqrt', 'ln', 'log', 'sec', 'csc', 'cot', 'coth', 're', 'im', 'frac', 'root', 'arg', ] tex_greek_dictionary = { 'Alpha': 'A', 'Beta': 'B', 'Gamma': r'\Gamma', 'Delta': r'\Delta', 'Epsilon': 'E', 'Zeta': 'Z', 'Eta': 'H', 'Theta': r'\Theta', 'Iota': 'I', 'Kappa': 'K', 'Lambda': r'\Lambda', 'Mu': 'M', 'Nu': 'N', 'Xi': r'\Xi', 'omicron': 'o', 'Omicron': 'O', 'Pi': r'\Pi', 'Rho': 'P', 'Sigma': r'\Sigma', 'Tau': 'T', 'Upsilon': r'\Upsilon', 'Phi': r'\Phi', 'Chi': 'X', 'Psi': r'\Psi', 'Omega': r'\Omega', 'lamda': r'\lambda', 'Lamda': r'\Lambda', 'khi': r'\chi', 'Khi': r'X', 'varepsilon': r'\varepsilon', 'varkappa': r'\varkappa', 'varphi': r'\varphi', 'varpi': r'\varpi', 'varrho': r'\varrho', 'varsigma': r'\varsigma', 'vartheta': r'\vartheta', } other_symbols = set(['aleph', 'beth', 'daleth', 'gimel', 'ell', 'eth', 'hbar', 'hslash', 'mho', 'wp', ]) # Variable name modifiers modifier_dict = { # Accents 'mathring': lambda s: r'\mathring{'+s+r'}', 'ddddot': lambda s: r'\ddddot{'+s+r'}', 'dddot': lambda s: r'\dddot{'+s+r'}', 'ddot': lambda s: r'\ddot{'+s+r'}', 'dot': lambda s: r'\dot{'+s+r'}', 'check': lambda s: r'\check{'+s+r'}', 'breve': lambda s: r'\breve{'+s+r'}', 'acute': lambda s: r'\acute{'+s+r'}', 'grave': lambda s: r'\grave{'+s+r'}', 'tilde': lambda s: r'\tilde{'+s+r'}', 'hat': lambda s: r'\hat{'+s+r'}', 'bar': lambda s: r'\bar{'+s+r'}', 'vec': lambda s: r'\vec{'+s+r'}', 'prime': lambda s: "{"+s+"}'", 'prm': lambda s: "{"+s+"}'", # Faces 'bold': lambda s: r'\boldsymbol{'+s+r'}', 'bm': lambda s: r'\boldsymbol{'+s+r'}', 'cal': lambda s: r'\mathcal{'+s+r'}', 'scr': lambda s: r'\mathscr{'+s+r'}', 'frak': lambda s: r'\mathfrak{'+s+r'}', # Brackets 'norm': lambda s: r'\left\\|{'+s+r'}\right\\|', 'avg': lambda s: r'\left\langle{'+s+r'}\right\rangle', 'abs': lambda s: r'\left\|{'+s+r'}\right\|', 'mag': lambda s: r'\left\|{'+s+r'}\right\|', } greek_letters_set = frozenset(greeks) _between_two_numbers_p = ( re.compile(r'[0-9][} ]$'), # search re.compile(r'[{ ][-+0-9]'), # match ) class LatexPrinter(Printer): printmethod = "_latex" _default_settings = { "fold_frac_powers": False, "fold_func_brackets": False, "fold_short_frac": None, "inv_trig_style": "abbreviated", "itex": False, "ln_notation": False, "long_frac_ratio": None, "mat_delim": "[", "mat_str": None, "mode": "plain", "mul_symbol": None, "order": None, "symbol_names": {}, "root_notation": True, "mat_symbol_style": "plain", "imaginary_unit": "i", "gothic_re_im": False, } def __init__(self, settings=None): Printer.__init__(self, settings) if 'mode' in self._settings: valid_modes = ['inline', 'plain', 'equation', 'equation'] if self._settings['mode'] not in valid_modes: raise ValueError("'mode' must be one of 'inline', 'plain', " "'equation' or 'equation'") if self._settings['fold_short_frac'] is None and \ self._settings['mode'] == 'inline': self._settings['fold_short_frac'] = True mul_symbol_table = { None: r" ", "ldot": r" \,.\, ", "dot": r" \cdot ", "times": r" \times " } try: self._settings['mul_symbol_latex'] = \ mul_symbol_table[self._settings['mul_symbol']] except KeyError: self._settings['mul_symbol_latex'] = \ self._settings['mul_symbol'] try: self._settings['mul_symbol_latex_numbers'] = \ mul_symbol_table[self._settings['mul_symbol'] or 'dot'] except KeyError: if (self._settings['mul_symbol'].strip() in ['', ' ', '\\', '\\,', '\\:', '\\;', '\\quad']): self._settings['mul_symbol_latex_numbers'] = \ mul_symbol_table['dot'] else: self._settings['mul_symbol_latex_numbers'] = \ self._settings['mul_symbol'] self._delim_dict = {'(': ')', '[': ']'} imaginary_unit_table = { None: r"i", "i": r"i", "ri": r"\mathrm{i}", "ti": r"\text{i}", "j": r"j", "rj": r"\mathrm{j}", "tj": r"\text{j}", } try: self._settings['imaginary_unit_latex'] = \ imaginary_unit_table[self._settings['imaginary_unit']] except KeyError: self._settings['imaginary_unit_latex'] = \ self._settings['imaginary_unit'] def parenthesize(self, item, level, strict=False): prec_val = precedence_traditional(item) if (prec_val < level) or ((not strict) and prec_val <= level): return r"\left({}\right)".format(self._print(item)) else: return self._print(item) def doprint(self, expr): tex = Printer.doprint(self, expr) if self._settings['mode'] == 'plain': return tex elif self._settings['mode'] == 'inline': return r"$%s$" % tex elif self._settings['itex']: return r"$$%s$$" % tex else: env_str = self._settings['mode'] return r"\begin{%s}%s\end{%s}" % (env_str, tex, env_str) def _needs_brackets(self, expr): """ Returns True if the expression needs to be wrapped in brackets when printed, False otherwise. For example: a + b => True; a => False; 10 => False; -10 => True. """ return not ((expr.is_Integer and expr.is_nonnegative) or (expr.is_Atom and (expr is not S.NegativeOne and expr.is_Rational is False))) def _needs_function_brackets(self, expr): """ Returns True if the expression needs to be wrapped in brackets when passed as an argument to a function, False otherwise. This is a more liberal version of _needs_brackets, in that many expressions which need to be wrapped in brackets when added/subtracted/raised to a power do not need them when passed to a function. Such an example is ab. """ if not self._needs_brackets(expr): return False else: # Muls of the form abc... can be folded if expr.is_Mul and not self._mul_is_clean(expr): return True # Pows which don't need brackets can be folded elif expr.is_Pow and not self._pow_is_clean(expr): return True # Add and Function always need brackets elif expr.is_Add or expr.is_Function: return True else: return False def _needs_mul_brackets(self, expr, first=False, last=False): """ Returns True if the expression needs to be wrapped in brackets when printed as part of a Mul, False otherwise. This is True for Add, but also for some container objects that would not need brackets when appearing last in a Mul, e.g. an Integral. ``last=True`` specifies that this expr is the last to appear in a Mul. ``first=True`` specifies that this expr is the first to appear in a Mul. """ from sympy import Integral, Product, Sum if expr.is_Mul: if not first and _coeff_isneg(expr): return True elif precedence_traditional(expr) < PRECEDENCE["Mul"]: return True elif expr.is_Relational: return True if expr.is_Piecewise: return True if any([expr.has(x) for x in (Mod,)]): return True if (not last and any([expr.has(x) for x in (Integral, Product, Sum)])): return True return False def _needs_add_brackets(self, expr): """ Returns True if the expression needs to be wrapped in brackets when printed as part of an Add, False otherwise. This is False for most things. """ if expr.is_Relational: return True if any([expr.has(x) for x in (Mod,)]): return True if expr.is_Add: return True return False def _mul_is_clean(self, expr): for arg in expr.args: if arg.is_Function: return False return True def _pow_is_clean(self, expr): return not self._needs_brackets(expr.base) def _do_exponent(self, expr, exp): if exp is not None: return r"\left(%s\right)^{%s}" % (expr, exp) else: return expr def _print_Basic(self, expr): ls = [self._print(o) for o in expr.args] return self._deal_with_super_sub(expr.__class__.__name__) + \ r"\left(%s\right)" % ", ".join(ls) def _print_bool(self, e): return r"\text{%s}" % e _print_BooleanTrue = _print_bool _print_BooleanFalse = _print_bool def _print_NoneType(self, e): return r"\text{%s}" % e def _print_Add(self, expr, order=None): if self.order == 'none': terms = list(expr.args) else: terms = self._as_ordered_terms(expr, order=order) tex = "" for i, term in enumerate(terms): if i == 0: pass elif _coeff_isneg(term): tex += " - " term = -term else: tex += " + " term_tex = self._print(term) if self._needs_add_brackets(term): term_tex = r"\left(%s\right)" % term_tex tex += term_tex return tex def _print_Cycle(self, expr): from sympy.combinatorics.permutations import Permutation if expr.size == 0: return r"\left( \right)" expr = Permutation(expr) expr_perm = expr.cyclic_form siz = expr.size if expr.array_form[-1] == siz - 1: expr_perm = expr_perm + [[siz - 1]] term_tex = '' for i in expr_perm: term_tex += str(i).replace(',', r"\;") term_tex = term_tex.replace('[', r"\left( ") term_tex = term_tex.replace(']', r"\right)") return term_tex _print_Permutation = _print_Cycle def _print_Float(self, expr): # Based off of that in StrPrinter dps = prec_to_dps(expr._prec) str_real = mlib.to_str(expr._mpf_, dps, strip_zeros=True) # Must always have a mul symbol (as 2.5 10^{20} just looks odd) # thus we use the number separator separator = self._settings['mul_symbol_latex_numbers'] if 'e' in str_real: (mant, exp) = str_real.split('e') if exp[0] == '+': exp = exp[1:] return r"%s%s10^{%s}" % (mant, separator, exp) elif str_real == "+inf": return r"\infty" elif str_real == "-inf": return r"- \infty" else: return str_real def _print_Cross(self, expr): vec1 = expr._expr1 vec2 = expr._expr2 return r"%s \times %s" % (self.parenthesize(vec1, PRECEDENCE['Mul']), self.parenthesize(vec2, PRECEDENCE['Mul'])) def _print_Curl(self, expr): vec = expr._expr return r"\nabla\times %s" % self.parenthesize(vec, PRECEDENCE['Mul']) def _print_Divergence(self, expr): vec = expr._expr return r"\nabla\cdot %s" % self.parenthesize(vec, PRECEDENCE['Mul']) def _print_Dot(self, expr): vec1 = expr._expr1 vec2 = expr._expr2 return r"%s \cdot %s" % (self.parenthesize(vec1, PRECEDENCE['Mul']), self.parenthesize(vec2, PRECEDENCE['Mul'])) def _print_Gradient(self, expr): func = expr._expr return r"\nabla %s" % self.parenthesize(func, PRECEDENCE['Mul']) def _print_Laplacian(self, expr): func = expr._expr return r"\triangle %s" % self.parenthesize(func, PRECEDENCE['Mul']) def _print_Mul(self, expr): from sympy.core.power import Pow from sympy.physics.units import Quantity include_parens = False if _coeff_isneg(expr): expr = -expr tex = "- " if expr.is_Add: tex += "(" include_parens = True else: tex = "" from sympy.simplify import fraction numer, denom = fraction(expr, exact=True) separator = self._settings['mul_symbol_latex'] numbersep = self._settings['mul_symbol_latex_numbers'] def convert(expr): if not expr.is_Mul: return str(self._print(expr)) else: _tex = last_term_tex = "" if self.order not in ('old', 'none'): args = expr.as_ordered_factors() else: args = list(expr.args) # If quantities are present append them at the back args = sorted(args, key=lambda x: isinstance(x, Quantity) or (isinstance(x, Pow) and isinstance(x.base, Quantity))) for i, term in enumerate(args): term_tex = self._print(term) if self._needs_mul_brackets(term, first=(i == 0), last=(i == len(args) - 1)): term_tex = r"\left(%s\right)" % term_tex if _between_two_numbers_p[0].search(last_term_tex) and \ _between_two_numbers_p[1].match(term_tex): # between two numbers _tex += numbersep elif _tex: _tex += separator _tex += term_tex last_term_tex = term_tex return _tex if denom is S.One and Pow(1, -1, evaluate=False) not in expr.args: # use the original expression here, since fraction() may have # altered it when producing numer and denom tex += convert(expr) else: snumer = convert(numer) sdenom = convert(denom) ldenom = len(sdenom.split()) ratio = self._settings['long_frac_ratio'] if self._settings['fold_short_frac'] and ldenom <= 2 and \ "^" not in sdenom: # handle short fractions if self._needs_mul_brackets(numer, last=False): tex += r"\left(%s\right) / %s" % (snumer, sdenom) else: tex += r"%s / %s" % (snumer, sdenom) elif ratio is not None and \ len(snumer.split()) > ratioldenom: # handle long fractions if self._needs_mul_brackets(numer, last=True): tex += r"\frac{1}{%s}%s\left(%s\right)" \ % (sdenom, separator, snumer) elif numer.is_Mul: # split a long numerator a = S.One b = S.One for x in numer.args: if self._needs_mul_brackets(x, last=False) or \ len(convert(ax).split()) > ratioldenom or \ (b.is_commutative is x.is_commutative is False): b = x else: a = x if self._needs_mul_brackets(b, last=True): tex += r"\frac{%s}{%s}%s\left(%s\right)" \ % (convert(a), sdenom, separator, convert(b)) else: tex += r"\frac{%s}{%s}%s%s" \ % (convert(a), sdenom, separator, convert(b)) else: tex += r"\frac{1}{%s}%s%s" % (sdenom, separator, snumer) else: tex += r"\frac{%s}{%s}" % (snumer, sdenom) if include_parens: tex += ")" return tex def _print_Pow(self, expr): # Treat x*Rational(1,n) as special case if expr.exp.is_Rational and abs(expr.exp.p) == 1 and expr.exp.q != 1 \ and self._settings['root_notation']: base = self._print(expr.base) expq = expr.exp.q if expq == 2: tex = r"\sqrt{%s}" % base elif self._settings['itex']: tex = r"\root{%d}{%s}" % (expq, base) else: tex = r"\sqrt[%d]{%s}" % (expq, base) if expr.exp.is_negative: return r"\frac{1}{%s}" % tex else: return tex elif self._settings['fold_frac_powers'] \ and expr.exp.is_Rational \ and expr.exp.q != 1: base = self.parenthesize(expr.base, PRECEDENCE['Pow']) p, q = expr.exp.p, expr.exp.q # issue #12886: add parentheses for superscripts raised to powers if '^' in base and expr.base.is_Symbol: base = r"\left(%s\right)" % base if expr.base.is_Function: return self._print(expr.base, exp="%s/%s" % (p, q)) return r"%s^{%s/%s}" % (base, p, q) elif expr.exp.is_Rational and expr.exp.is_negative and \ expr.base.is_commutative: # special case for 1^(-x), issue 9216 if expr.base == 1: return r"%s^{%s}" % (expr.base, expr.exp) # things like 1/x return self._print_Mul(expr) else: if expr.base.is_Function: return self._print(expr.base, exp=self._print(expr.exp)) else: tex = r"%s^{%s}" return self._helper_print_standard_power(expr, tex) def _helper_print_standard_power(self, expr, template): exp = self._print(expr.exp) # issue #12886: add parentheses around superscripts raised # to powers base = self.parenthesize(expr.base, PRECEDENCE['Pow']) if '^' in base and expr.base.is_Symbol: base = r"\left(%s\right)" % base elif (isinstance(expr.base, Derivative) and base.startswith(r'\left(') and re.match(r'\\left\(\\d?d?dot', base) and base.endswith(r'\right)')): # don't use parentheses around dotted derivative base = base[6: -7] # remove outermost added parens return template % (base, exp) def _print_UnevaluatedExpr(self, expr): return self._print(expr.args[0]) def _print_Sum(self, expr): if len(expr.limits) == 1: tex = r"\sum_{%s=%s}^{%s} " % \ tuple([self._print(i) for i in expr.limits[0]]) else: def _format_ineq(l): return r"%s \leq %s \leq %s" % \ tuple([self._print(s) for s in (l[1], l[0], l[2])]) tex = r"\sum_{\substack{%s}} " % \ str.join('\\\\', [_format_ineq(l) for l in expr.limits]) if isinstance(expr.function, Add): tex += r"\left(%s\right)" % self._print(expr.function) else: tex += self._print(expr.function) return tex def _print_Product(self, expr): if len(expr.limits) == 1: tex = r"\prod_{%s=%s}^{%s} " % \ tuple([self._print(i) for i in expr.limits[0]]) else: def _format_ineq(l): return r"%s \leq %s \leq %s" % \ tuple([self._print(s) for s in (l[1], l[0], l[2])]) tex = r"\prod_{\substack{%s}} " % \ str.join('\\\\', [_format_ineq(l) for l in expr.limits]) if isinstance(expr.function, Add): tex += r"\left(%s\right)" % self._print(expr.function) else: tex += self._print(expr.function) return tex def _print_BasisDependent(self, expr): from sympy.vector import Vector o1 = [] if expr == expr.zero: return expr.zero._latex_form if isinstance(expr, Vector): items = expr.separate().items() else: items = [(0, expr)] for system, vect in items: inneritems = list(vect.components.items()) inneritems.sort(key=lambda x: x[0].__str__()) for k, v in inneritems: if v == 1: o1.append(' + ' + k._latex_form) elif v == -1: o1.append(' - ' + k._latex_form) else: arg_str = '(' + LatexPrinter().doprint(v) + ')' o1.append(' + ' + arg_str + k._latex_form) outstr = (''.join(o1)) if outstr[1] != '-': outstr = outstr[3:] else: outstr = outstr[1:] return outstr def _print_Indexed(self, expr): tex_base = self._print(expr.base) tex = '{'+tex_base+'}'+'_{%s}' % ','.join( map(self._print, expr.indices)) return tex def _print_IndexedBase(self, expr): return self._print(expr.label) def _print_Derivative(self, expr): if requires_partial(expr): diff_symbol = r'\partial' else: diff_symbol = r'd' tex = "" dim = 0 for x, num in reversed(expr.variable_count): dim += num if num == 1: tex += r"%s %s" % (diff_symbol, self._print(x)) else: tex += r"%s %s^{%s}" % (diff_symbol, self._print(x), num) if dim == 1: tex = r"\frac{%s}{%s}" % (diff_symbol, tex) else: tex = r"\frac{%s^{%s}}{%s}" % (diff_symbol, dim, tex) return r"%s %s" % (tex, self.parenthesize(expr.expr, PRECEDENCE["Mul"], strict=True)) def _print_Subs(self, subs): expr, old, new = subs.args latex_expr = self._print(expr) latex_old = (self._print(e) for e in old) latex_new = (self._print(e) for e in new) latex_subs = r'\\ '.join( e[0] + '=' + e[1] for e in zip(latex_old, latex_new)) return r'\left. %s \right\|_{\substack{ %s }}' % (latex_expr, latex_subs) def _print_Integral(self, expr): tex, symbols = "", [] # Only up to \iiiint exists if len(expr.limits) <= 4 and all(len(lim) == 1 for lim in expr.limits): # Use len(expr.limits)-1 so that syntax highlighters don't think # \" is an escaped quote tex = r"\i" + "i"(len(expr.limits) - 1) + "nt" symbols = [r"\, d%s" % self._print(symbol[0]) for symbol in expr.limits] else: for lim in reversed(expr.limits): symbol = lim[0] tex += r"\int" if len(lim) > 1: if self._settings['mode'] != 'inline' \ and not self._settings['itex']: tex += r"\limits" if len(lim) == 3: tex += "_{%s}^{%s}" % (self._print(lim[1]), self._print(lim[2])) if len(lim) == 2: tex += "^{%s}" % (self._print(lim[1])) symbols.insert(0, r"\, d%s" % self._print(symbol)) return r"%s %s%s" % (tex, self.parenthesize(expr.function, PRECEDENCE["Mul"], strict=True), "".join(symbols)) def _print_Limit(self, expr): e, z, z0, dir = expr.args tex = r"\lim_{%s \to " % self._print(z) if str(dir) == '+-' or z0 in (S.Infinity, S.NegativeInfinity): tex += r"%s}" % self._print(z0) else: tex += r"%s^%s}" % (self._print(z0), self._print(dir)) if isinstance(e, AssocOp): return r"%s\left(%s\right)" % (tex, self._print(e)) else: return r"%s %s" % (tex, self._print(e)) def _hprint_Function(self, func): r''' Logic to decide how to render a function to latex - if it is a recognized latex name, use the appropriate latex command - if it is a single letter, just use that letter - if it is a longer name, then put \operatorname{} around it and be mindful of undercores in the name ''' func = self._deal_with_super_sub(func) if func in accepted_latex_functions: name = r"\%s" % func elif len(func) == 1 or func.startswith('\\'): name = func else: name = r"\operatorname{%s}" % func return name def _print_Function(self, expr, exp=None): r''' Render functions to LaTeX, handling functions that LaTeX knows about e.g., sin, cos, ... by using the proper LaTeX command (\sin, \cos, ...). For single-letter function names, render them as regular LaTeX math symbols. For multi-letter function names that LaTeX does not know about, (e.g., Li, sech) use \operatorname{} so that the function name is rendered in Roman font and LaTeX handles spacing properly. expr is the expression involving the function exp is an exponent ''' func = expr.func.__name__ if hasattr(self, '_print_' + func) and \ not isinstance(expr, AppliedUndef): return getattr(self, '_print_' + func)(expr, exp) else: args = [str(self._print(arg)) for arg in expr.args] # How inverse trig functions should be displayed, formats are: # abbreviated: asin, full: arcsin, power: sin^-1 inv_trig_style = self._settings['inv_trig_style'] # If we are dealing with a power-style inverse trig function inv_trig_power_case = False # If it is applicable to fold the argument brackets can_fold_brackets = self._settings['fold_func_brackets'] and \ len(args) == 1 and \ not self._needs_function_brackets(expr.args[0]) inv_trig_table = ["asin", "acos", "atan", "acsc", "asec", "acot"] # If the function is an inverse trig function, handle the style if func in inv_trig_table: if inv_trig_style == "abbreviated": pass elif inv_trig_style == "full": func = "arc" + func[1:] elif inv_trig_style == "power": func = func[1:] inv_trig_power_case = True # Can never fold brackets if we're raised to a power if exp is not None: can_fold_brackets = False if inv_trig_power_case: if func in accepted_latex_functions: name = r"\%s^{-1}" % func else: name = r"\operatorname{%s}^{-1}" % func elif exp is not None: name = r'%s^{%s}' % (self._hprint_Function(func), exp) else: name = self._hprint_Function(func) if can_fold_brackets: if func in accepted_latex_functions: # Wrap argument safely to avoid parse-time conflicts # with the function name itself name += r" {%s}" else: name += r"%s" else: name += r"{\left(%s \right)}" if inv_trig_power_case and exp is not None: name += r"^{%s}" % exp return name % ",".join(args) def _print_UndefinedFunction(self, expr): return self._hprint_Function(str(expr)) def _print_ElementwiseApplyFunction(self, expr): return r"%s\left({%s}\ldots\right)" % ( self._print(expr.function), self._print(expr.expr), ) @property def _special_function_classes(self): from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.functions.special.gamma_functions import gamma, lowergamma from sympy.functions.special.beta_functions import beta from sympy.functions.special.delta_functions import DiracDelta from sympy.functions.special.error_functions import Chi return {KroneckerDelta: r'\delta', gamma: r'\Gamma', lowergamma: r'\gamma', beta: r'\operatorname{B}', DiracDelta: r'\delta', Chi: r'\operatorname{Chi}'} def _print_FunctionClass(self, expr): for cls in self._special_function_classes: if issubclass(expr, cls) and expr.__name__ == cls.__name__: return self._special_function_classes[cls] return self._hprint_Function(str(expr)) def _print_Lambda(self, expr): symbols, expr = expr.args if len(symbols) == 1: symbols = self._print(symbols[0]) else: symbols = self._print(tuple(symbols)) tex = r"\left( %s \mapsto %s \right)" % (symbols, self._print(expr)) return tex def _hprint_variadic_function(self, expr, exp=None): args = sorted(expr.args, key=default_sort_key) texargs = [r"%s" % self._print(symbol) for symbol in args] tex = r"\%s\left(%s\right)" % (self._print((str(expr.func)).lower()), ", ".join(texargs)) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex _print_Min = _print_Max = _hprint_variadic_function def _print_floor(self, expr, exp=None): tex = r"\left\lfloor{%s}\right\rfloor" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_ceiling(self, expr, exp=None): tex = r"\left\lceil{%s}\right\rceil" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_log(self, expr, exp=None): if not self._settings["ln_notation"]: tex = r"\log{\left(%s \right)}" % self._print(expr.args[0]) else: tex = r"\ln{\left(%s \right)}" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_Abs(self, expr, exp=None): tex = r"\left\|{%s}\right\|" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex _print_Determinant = _print_Abs def _print_re(self, expr, exp=None): if self._settings['gothic_re_im']: tex = r"\Re{%s}" % self.parenthesize(expr.args[0], PRECEDENCE['Atom']) else: tex = r"\operatorname{{re}}{{{}}}".format(self.parenthesize(expr.args[0], PRECEDENCE['Atom'])) return self._do_exponent(tex, exp) def _print_im(self, expr, exp=None): if self._settings['gothic_re_im']: tex = r"\Im{%s}" % self.parenthesize(expr.args[0], PRECEDENCE['Atom']) else: tex = r"\operatorname{{im}}{{{}}}".format(self.parenthesize(expr.args[0], PRECEDENCE['Atom'])) return self._do_exponent(tex, exp) def _print_Not(self, e): from sympy import Equivalent, Implies if isinstance(e.args[0], Equivalent): return self._print_Equivalent(e.args[0], r"\not\Leftrightarrow") if isinstance(e.args[0], Implies): return self._print_Implies(e.args[0], r"\not\Rightarrow") if (e.args[0].is_Boolean): return r"\neg (%s)" % self._print(e.args[0]) else: return r"\neg %s" % self._print(e.args[0]) def _print_LogOp(self, args, char): arg = args[0] if arg.is_Boolean and not arg.is_Not: tex = r"\left(%s\right)" % self._print(arg) else: tex = r"%s" % self._print(arg) for arg in args[1:]: if arg.is_Boolean and not arg.is_Not: tex += r" %s \left(%s\right)" % (char, self._print(arg)) else: tex += r" %s %s" % (char, self._print(arg)) return tex def _print_And(self, e): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, r"\wedge") def _print_Or(self, e): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, r"\vee") def _print_Xor(self, e): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, r"\veebar") def _print_Implies(self, e, altchar=None): return self._print_LogOp(e.args, altchar or r"\Rightarrow") def _print_Equivalent(self, e, altchar=None): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, altchar or r"\Leftrightarrow") def _print_conjugate(self, expr, exp=None): tex = r"\overline{%s}" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_polar_lift(self, expr, exp=None): func = r"\operatorname{polar\_lift}" arg = r"{\left(%s \right)}" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}%s" % (func, exp, arg) else: return r"%s%s" % (func, arg) def _print_ExpBase(self, expr, exp=None): # TODO should exp_polar be printed differently? # what about exp_polar(0), exp_polar(1)? tex = r"e^{%s}" % self._print(expr.args[0]) return self._do_exponent(tex, exp) def _print_elliptic_k(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"K^{%s}%s" % (exp, tex) else: return r"K%s" % tex def _print_elliptic_f(self, expr, exp=None): tex = r"\left(%s\middle\| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"F^{%s}%s" % (exp, tex) else: return r"F%s" % tex def _print_elliptic_e(self, expr, exp=None): if len(expr.args) == 2: tex = r"\left(%s\middle\| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1])) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"E^{%s}%s" % (exp, tex) else: return r"E%s" % tex def _print_elliptic_pi(self, expr, exp=None): if len(expr.args) == 3: tex = r"\left(%s; %s\middle\| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1]), self._print(expr.args[2])) else: tex = r"\left(%s\middle\| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\Pi^{%s}%s" % (exp, tex) else: return r"\Pi%s" % tex def _print_beta(self, expr, exp=None): tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\operatorname{B}^{%s}%s" % (exp, tex) else: return r"\operatorname{B}%s" % tex def _print_uppergamma(self, expr, exp=None): tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\Gamma^{%s}%s" % (exp, tex) else: return r"\Gamma%s" % tex def _print_lowergamma(self, expr, exp=None): tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\gamma^{%s}%s" % (exp, tex) else: return r"\gamma%s" % tex def _hprint_one_arg_func(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}%s" % (self._print(expr.func), exp, tex) else: return r"%s%s" % (self._print(expr.func), tex) _print_gamma = _hprint_one_arg_func def _print_Chi(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\operatorname{Chi}^{%s}%s" % (exp, tex) else: return r"\operatorname{Chi}%s" % tex def _print_expint(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[1]) nu = self._print(expr.args[0]) if exp is not None: return r"\operatorname{E}_{%s}^{%s}%s" % (nu, exp, tex) else: return r"\operatorname{E}_{%s}%s" % (nu, tex) def _print_fresnels(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"S^{%s}%s" % (exp, tex) else: return r"S%s" % tex def _print_fresnelc(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"C^{%s}%s" % (exp, tex) else: return r"C%s" % tex def _print_subfactorial(self, expr, exp=None): tex = r"!%s" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) if exp is not None: return r"\left(%s\right)^{%s}" % (tex, exp) else: return tex def _print_factorial(self, expr, exp=None): tex = r"%s!" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_factorial2(self, expr, exp=None): tex = r"%s!!" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_binomial(self, expr, exp=None): tex = r"{\binom{%s}{%s}}" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_RisingFactorial(self, expr, exp=None): n, k = expr.args base = r"%s" % self.parenthesize(n, PRECEDENCE['Func']) tex = r"{%s}^{\left(%s\right)}" % (base, self._print(k)) return self._do_exponent(tex, exp) def _print_FallingFactorial(self, expr, exp=None): n, k = expr.args sub = r"%s" % self.parenthesize(k, PRECEDENCE['Func']) tex = r"{\left(%s\right)}_{%s}" % (self._print(n), sub) return self._do_exponent(tex, exp) def _hprint_BesselBase(self, expr, exp, sym): tex = r"%s" % (sym) need_exp = False if exp is not None: if tex.find('^') == -1: tex = r"%s^{%s}" % (tex, self._print(exp)) else: need_exp = True tex = r"%s_{%s}\left(%s\right)" % (tex, self._print(expr.order), self._print(expr.argument)) if need_exp: tex = self._do_exponent(tex, exp) return tex def _hprint_vec(self, vec): if not vec: return "" s = "" for i in vec[:-1]: s += "%s, " % self._print(i) s += self._print(vec[-1]) return s def _print_besselj(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'J') def _print_besseli(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'I') def _print_besselk(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'K') def _print_bessely(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'Y') def _print_yn(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'y') def _print_jn(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'j') def _print_hankel1(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'H^{(1)}') def _print_hankel2(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'H^{(2)}') def _print_hn1(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'h^{(1)}') def _print_hn2(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'h^{(2)}') def _hprint_airy(self, expr, exp=None, notation=""): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}%s" % (notation, exp, tex) else: return r"%s%s" % (notation, tex) def _hprint_airy_prime(self, expr, exp=None, notation=""): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"{%s^\prime}^{%s}%s" % (notation, exp, tex) else: return r"%s^\prime%s" % (notation, tex) def _print_airyai(self, expr, exp=None): return self._hprint_airy(expr, exp, 'Ai') def _print_airybi(self, expr, exp=None): return self._hprint_airy(expr, exp, 'Bi') def _print_airyaiprime(self, expr, exp=None): return self._hprint_airy_prime(expr, exp, 'Ai') def _print_airybiprime(self, expr, exp=None): return self._hprint_airy_prime(expr, exp, 'Bi') def _print_hyper(self, expr, exp=None): tex = r"{{}_{%s}F_{%s}\left(\begin{matrix} %s \\ %s \end{matrix}" \ r"\middle\| {%s} \right)}" % \ (self._print(len(expr.ap)), self._print(len(expr.bq)), self._hprint_vec(expr.ap), self._hprint_vec(expr.bq), self._print(expr.argument)) if exp is not None: tex = r"{%s}^{%s}" % (tex, self._print(exp)) return tex def _print_meijerg(self, expr, exp=None): tex = r"{G_{%s, %s}^{%s, %s}\left(\begin{matrix} %s & %s \\" \ r"%s & %s \end{matrix} \middle\| {%s} \right)}" % \ (self._print(len(expr.ap)), self._print(len(expr.bq)), self._print(len(expr.bm)), self._print(len(expr.an)), self._hprint_vec(expr.an), self._hprint_vec(expr.aother), self._hprint_vec(expr.bm), self._hprint_vec(expr.bother), self._print(expr.argument)) if exp is not None: tex = r"{%s}^{%s}" % (tex, self._print(exp)) return tex def _print_dirichlet_eta(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\eta^{%s}%s" % (self._print(exp), tex) return r"\eta%s" % tex def _print_zeta(self, expr, exp=None): if len(expr.args) == 2: tex = r"\left(%s, %s\right)" % tuple(map(self._print, expr.args)) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\zeta^{%s}%s" % (self._print(exp), tex) return r"\zeta%s" % tex def _print_lerchphi(self, expr, exp=None): tex = r"\left(%s, %s, %s\right)" % tuple(map(self._print, expr.args)) if exp is None: return r"\Phi%s" % tex return r"\Phi^{%s}%s" % (self._print(exp), tex) def _print_polylog(self, expr, exp=None): s, z = map(self._print, expr.args) tex = r"\left(%s\right)" % z if exp is None: return r"\operatorname{Li}_{%s}%s" % (s, tex) return r"\operatorname{Li}_{%s}^{%s}%s" % (s, self._print(exp), tex) def _print_jacobi(self, expr, exp=None): n, a, b, x = map(self._print, expr.args) tex = r"P_{%s}^{\left(%s,%s\right)}\left(%s\right)" % (n, a, b, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_gegenbauer(self, expr, exp=None): n, a, x = map(self._print, expr.args) tex = r"C_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_chebyshevt(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"T_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_chebyshevu(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"U_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_legendre(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"P_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_assoc_legendre(self, expr, exp=None): n, a, x = map(self._print, expr.args) tex = r"P_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_hermite(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"H_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_laguerre(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"L_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_assoc_laguerre(self, expr, exp=None): n, a, x = map(self._print, expr.args) tex = r"L_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_Ynm(self, expr, exp=None): n, m, theta, phi = map(self._print, expr.args) tex = r"Y_{%s}^{%s}\left(%s,%s\right)" % (n, m, theta, phi) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_Znm(self, expr, exp=None): n, m, theta, phi = map(self._print, expr.args) tex = r"Z_{%s}^{%s}\left(%s,%s\right)" % (n, m, theta, phi) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_Rational(self, expr): if expr.q != 1: sign = "" p = expr.p if expr.p < 0: sign = "- " p = -p if self._settings['fold_short_frac']: return r"%s%d / %d" % (sign, p, expr.q) return r"%s\frac{%d}{%d}" % (sign, p, expr.q) else: return self._print(expr.p) def _print_Order(self, expr): s = self._print(expr.expr) if expr.point and any(p != S.Zero for p in expr.point) or \ len(expr.variables) > 1: s += '; ' if len(expr.variables) > 1: s += self._print(expr.variables) elif expr.variables: s += self._print(expr.variables[0]) s += r'\rightarrow ' if len(expr.point) > 1: s += self._print(expr.point) else: s += self._print(expr.point[0]) return r"O\left(%s\right)" % s def _print_Symbol(self, expr, style='plain'): if expr in self._settings['symbol_names']: return self._settings['symbol_names'][expr] result = self._deal_with_super_sub(expr.name) if \ '\\' not in expr.name else expr.name if style == 'bold': result = r"\mathbf{{{}}}".format(result) return result _print_RandomSymbol = _print_Symbol def _print_MatrixSymbol(self, expr): return self._print_Symbol(expr, style=self._settings['mat_symbol_style']) def _deal_with_super_sub(self, string): if '{' in string: return string name, supers, subs = split_super_sub(string) name = translate(name) supers = [translate(sup) for sup in supers] subs = [translate(sub) for sub in subs] # glue all items together: if supers: name += "^{%s}" % " ".join(supers) if subs: name += "_{%s}" % " ".join(subs) return name def _print_Relational(self, expr): if self._settings['itex']: gt = r"\gt" lt = r"\lt" else: gt = ">" lt = "<" charmap = { "==": "=", ">": gt, "<": lt, ">=": r"\geq", "<=": r"\leq", "!=": r"\neq", } return "%s %s %s" % (self._print(expr.lhs), charmap[expr.rel_op], self._print(expr.rhs)) def _print_Piecewise(self, expr): ecpairs = [r"%s & \text{for}\: %s" % (self._print(e), self._print(c)) for e, c in expr.args[:-1]] if expr.args[-1].cond == true: ecpairs.append(r"%s & \text{otherwise}" % self._print(expr.args[-1].expr)) else: ecpairs.append(r"%s & \text{for}\: %s" % (self._print(expr.args[-1].expr), self._print(expr.args[-1].cond))) tex = r"\begin{cases} %s \end{cases}" return tex % r" \\".join(ecpairs) def _print_MatrixBase(self, expr): lines = [] for line in range(expr.rows): # horrible, should be 'rows' lines.append(" & ".join([self._print(i) for i in expr[line, :]])) mat_str = self._settings['mat_str'] if mat_str is None: if self._settings['mode'] == 'inline': mat_str = 'smallmatrix' else: if (expr.cols <= 10) is True: mat_str = 'matrix' else: mat_str = 'array' out_str = r'\begin{%MATSTR%}%s\end{%MATSTR%}' out_str = out_str.replace('%MATSTR%', mat_str) if mat_str == 'array': out_str = out_str.replace('%s', '{' + 'c'expr.cols + '}%s') if self._settings['mat_delim']: left_delim = self._settings['mat_delim'] right_delim = self._delim_dict[left_delim] out_str = r'\left' + left_delim + out_str + \ r'\right' + right_delim return out_str % r"\\".join(lines) _print_ImmutableMatrix = _print_ImmutableDenseMatrix \ = _print_Matrix \ = _print_MatrixBase def _print_MatrixElement(self, expr): return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True)\ + '_{%s, %s}' % (self._print(expr.i), self._print(expr.j)) def _print_MatrixSlice(self, expr): def latexslice(x): x = list(x) if x[2] == 1: del x[2] if x[1] == x[0] + 1: del x[1] if x[0] == 0: x[0] = '' return ':'.join(map(self._print, x)) return (self._print(expr.parent) + r'\left[' + latexslice(expr.rowslice) + ', ' + latexslice(expr.colslice) + r'\right]') def _print_BlockMatrix(self, expr): return self._print(expr.blocks) def _print_Transpose(self, expr): mat = expr.arg from sympy.matrices import MatrixSymbol if not isinstance(mat, MatrixSymbol): return r"\left(%s\right)^{T}" % self._print(mat) else: return "%s^{T}" % self.parenthesize(mat, precedence_traditional(expr), True) def _print_Trace(self, expr): mat = expr.arg return r"\operatorname{tr}\left(%s \right)" % self._print(mat) def _print_Adjoint(self, expr): mat = expr.arg from sympy.matrices import MatrixSymbol if not isinstance(mat, MatrixSymbol): return r"\left(%s\right)^{\dagger}" % self._print(mat) else: return r"%s^{\dagger}" % self._print(mat) def _print_MatMul(self, expr): from sympy import MatMul, Mul parens = lambda x: self.parenthesize(x, precedence_traditional(expr), False) args = expr.args if isinstance(args[0], Mul): args = args[0].as_ordered_factors() + list(args[1:]) else: args = list(args) if isinstance(expr, MatMul) and _coeff_isneg(expr): if args[0] == -1: args = args[1:] else: args[0] = -args[0] return '- ' + ' '.join(map(parens, args)) else: return ' '.join(map(parens, args)) def _print_Mod(self, expr, exp=None): if exp is not None: return r'\left(%s\bmod{%s}\right)^{%s}' % \ (self.parenthesize(expr.args[0], PRECEDENCE['Mul'], strict=True), self._print(expr.args[1]), self._print(exp)) return r'%s\bmod{%s}' % (self.parenthesize(expr.args[0], PRECEDENCE['Mul'], strict=True), self._print(expr.args[1])) def _print_HadamardProduct(self, expr): args = expr.args prec = PRECEDENCE['Pow'] parens = self.parenthesize return r' \circ '.join( map(lambda arg: parens(arg, prec, strict=True), args)) def _print_HadamardPower(self, expr): template = r"%s^{\circ {%s}}" return self._helper_print_standard_power(expr, template) def _print_KroneckerProduct(self, expr): args = expr.args prec = PRECEDENCE['Pow'] parens = self.parenthesize return r' \otimes '.join( map(lambda arg: parens(arg, prec, strict=True), args)) def _print_MatPow(self, expr): base, exp = expr.base, expr.exp from sympy.matrices import MatrixSymbol if not isinstance(base, MatrixSymbol): return "\\left(%s\\right)^{%s}" % (self._print(base), self._print(exp)) else: return "%s^{%s}" % (self._print(base), self._print(exp)) def _print_ZeroMatrix(self, Z): return r"\mathbb{0}" def _print_OneMatrix(self, O): return r"\mathbb{1}" def _print_Identity(self, I): return r"\mathbb{I}" def _print_NDimArray(self, expr): if expr.rank() == 0: return self._print(expr[()]) mat_str = self._settings['mat_str'] if mat_str is None: if self._settings['mode'] == 'inline': mat_str = 'smallmatrix' else: if (expr.rank() == 0) or (expr.shape[-1] <= 10): mat_str = 'matrix' else: mat_str = 'array' block_str = r'\begin{%MATSTR%}%s\end{%MATSTR%}' block_str = block_str.replace('%MATSTR%', mat_str) if self._settings['mat_delim']: left_delim = self._settings['mat_delim'] right_delim = self._delim_dict[left_delim] block_str = r'\left' + left_delim + block_str + \ r'\right' + right_delim if expr.rank() == 0: return block_str % "" level_str = [[]] + [[] for i in range(expr.rank())] shape_ranges = [list(range(i)) for i in expr.shape] for outer_i in itertools.product(shape_ranges): level_str[-1].append(self._print(expr[outer_i])) even = True for back_outer_i in range(expr.rank()-1, -1, -1): if len(level_str[back_outer_i+1]) < expr.shape[back_outer_i]: break if even: level_str[back_outer_i].append( r" & ".join(level_str[back_outer_i+1])) else: level_str[back_outer_i].append( block_str % (r"\\".join(level_str[back_outer_i+1]))) if len(level_str[back_outer_i+1]) == 1: level_str[back_outer_i][-1] = r"\left[" + \ level_str[back_outer_i][-1] + r"\right]" even = not even level_str[back_outer_i+1] = [] out_str = level_str[0][0] if expr.rank() % 2 == 1: out_str = block_str % out_str return out_str _print_ImmutableDenseNDimArray = _print_NDimArray _print_ImmutableSparseNDimArray = _print_NDimArray _print_MutableDenseNDimArray = _print_NDimArray _print_MutableSparseNDimArray = _print_NDimArray def _printer_tensor_indices(self, name, indices, index_map={}): out_str = self._print(name) last_valence = None prev_map = None for index in indices: new_valence = index.is_up if ((index in index_map) or prev_map) and \ last_valence == new_valence: out_str += "," if last_valence != new_valence: if last_valence is not None: out_str += "}" if index.is_up: out_str += "{}^{" else: out_str += "{}_{" out_str += self._print(index.args[0]) if index in index_map: out_str += "=" out_str += self._print(index_map[index]) prev_map = True else: prev_map = False last_valence = new_valence if last_valence is not None: out_str += "}" return out_str def _print_Tensor(self, expr): name = expr.args[0].args[0] indices = expr.get_indices() return self._printer_tensor_indices(name, indices) def _print_TensorElement(self, expr): name = expr.expr.args[0].args[0] indices = expr.expr.get_indices() index_map = expr.index_map return self._printer_tensor_indices(name, indices, index_map) def _print_TensMul(self, expr): # prints expressions like "A(a)", "3A(a)", "(1+x)A(a)" sign, args = expr._get_args_for_traditional_printer() return sign + "".join( [self.parenthesize(arg, precedence(expr)) for arg in args] ) def _print_TensAdd(self, expr): a = [] args = expr.args for x in args: a.append(self.parenthesize(x, precedence(expr))) a.sort() s = ' + '.join(a) s = s.replace('+ -', '- ') return s def _print_TensorIndex(self, expr): return "{}%s{%s}" % ( "^" if expr.is_up else "_", self._print(expr.args[0]) ) def _print_UniversalSet(self, expr): return r"\mathbb{U}" def _print_tuple(self, expr): return r"\left( %s\right)" % \ r", \ ".join([self._print(i) for i in expr]) def _print_TensorProduct(self, expr): elements = [self._print(a) for a in expr.args] return r' \otimes '.join(elements) def _print_WedgeProduct(self, expr): elements = [self._print(a) for a in expr.args] return r' \wedge '.join(elements) def _print_Tuple(self, expr): return self._print_tuple(expr) def _print_list(self, expr): return r"\left[ %s\right]" % \ r", \ ".join([self._print(i) for i in expr]) def _print_dict(self, d): keys = sorted(d.keys(), key=default_sort_key) items = [] for key in keys: val = d[key] items.append("%s : %s" % (self._print(key), self._print(val))) return r"\left\{ %s\right\}" % r", \ ".join(items) def _print_Dict(self, expr): return self._print_dict(expr) def _print_DiracDelta(self, expr, exp=None): if len(expr.args) == 1 or expr.args[1] == 0: tex = r"\delta\left(%s\right)" % self._print(expr.args[0]) else: tex = r"\delta^{\left( %s \right)}\left( %s \right)" % ( self._print(expr.args[1]), self._print(expr.args[0])) if exp: tex = r"\left(%s\right)^{%s}" % (tex, exp) return tex def _print_SingularityFunction(self, expr): shift = self._print(expr.args[0] - expr.args[1]) power = self._print(expr.args[2]) tex = r"{\left\langle %s \right\rangle}^{%s}" % (shift, power) return tex def _print_Heaviside(self, expr, exp=None): tex = r"\theta\left(%s\right)" % self._print(expr.args[0]) if exp: tex = r"\left(%s\right)^{%s}" % (tex, exp) return tex def _print_KroneckerDelta(self, expr, exp=None): i = self._print(expr.args[0]) j = self._print(expr.args[1]) if expr.args[0].is_Atom and expr.args[1].is_Atom: tex = r'\delta_{%s %s}' % (i, j) else: tex = r'\delta_{%s, %s}' % (i, j) if exp is not None: tex = r'\left(%s\right)^{%s}' % (tex, exp) return tex def _print_LeviCivita(self, expr, exp=None): indices = map(self._print, expr.args) if all(x.is_Atom for x in expr.args): tex = r'\varepsilon_{%s}' % " ".join(indices) else: tex = r'\varepsilon_{%s}' % ", ".join(indices) if exp: tex = r'\left(%s\right)^{%s}' % (tex, exp) return tex def _print_ProductSet(self, p): if len(p.sets) > 1 and not has_variety(p.sets): return self._print(p.sets[0]) + "^{%d}" % len(p.sets) else: return r" \times ".join(self._print(set) for set in p.sets) def _print_RandomDomain(self, d): if hasattr(d, 'as_boolean'): return '\\text{Domain: }' + self._print(d.as_boolean()) elif hasattr(d, 'set'): return ('\\text{Domain: }' + self._print(d.symbols) + '\\text{ in }' + self._print(d.set)) elif hasattr(d, 'symbols'): return '\\text{Domain on }' + self._print(d.symbols) else: return self._print(None) def _print_FiniteSet(self, s): items = sorted(s.args, key=default_sort_key) return self._print_set(items) def _print_set(self, s): items = sorted(s, key=default_sort_key) items = ", ".join(map(self._print, items)) return r"\left\{%s\right\}" % items _print_frozenset = _print_set def _print_Range(self, s): dots = r'\ldots' if s.start.is_infinite: printset = dots, s[-1] - s.step, s[-1] elif s.stop.is_infinite: it = iter(s) printset = next(it), next(it), dots elif len(s) > 4: it = iter(s) printset = next(it), next(it), dots, s[-1] else: printset = tuple(s) return (r"\left\{" + r", ".join(self._print(el) for el in printset) + r"\right\}") def _print_bernoulli(self, expr, exp=None): tex = r"B_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex _print_bell = _print_bernoulli def _print_fibonacci(self, expr, exp=None): tex = r"F_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_lucas(self, expr, exp=None): tex = r"L_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_tribonacci(self, expr, exp=None): tex = r"T_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_SeqFormula(self, s): if len(s.start.free_symbols) > 0 or len(s.stop.free_symbols) > 0: return r"\left\{%s\right\}_{%s=%s}^{%s}" % ( self._print(s.formula), self._print(s.variables[0]), self._print(s.start), self._print(s.stop) ) if s.start is S.NegativeInfinity: stop = s.stop printset = (r'\ldots', s.coeff(stop - 3), s.coeff(stop - 2), s.coeff(stop - 1), s.coeff(stop)) elif s.stop is S.Infinity or s.length > 4: printset = s[:4] printset.append(r'\ldots') else: printset = tuple(s) return (r"\left[" + r", ".join(self._print(el) for el in printset) + r"\right]") _print_SeqPer = _print_SeqFormula _print_SeqAdd = _print_SeqFormula _print_SeqMul = _print_SeqFormula def _print_Interval(self, i): if i.start == i.end: return r"\left\{%s\right\}" % self._print(i.start) else: if i.left_open: left = '(' else: left = '[' if i.right_open: right = ')' else: right = ']' return r"\left%s%s, %s\right%s" % \ (left, self._print(i.start), self._print(i.end), right) def _print_AccumulationBounds(self, i): return r"\left\langle %s, %s\right\rangle" % \ (self._print(i.min), self._print(i.max)) def _print_Union(self, u): return r" \cup ".join([self._print(i) for i in u.args]) def _print_Complement(self, u): return r" \setminus ".join([self._print(i) for i in u.args]) def _print_Intersection(self, u): return r" \cap ".join([self._print(i) for i in u.args]) def _print_SymmetricDifference(self, u): return r" \triangle ".join([self._print(i) for i in u.args]) def _print_EmptySet(self, e): return r"\emptyset" def _print_Naturals(self, n): return r"\mathbb{N}" def _print_Naturals0(self, n): return r"\mathbb{N}_0" def _print_Integers(self, i): return r"\mathbb{Z}" def _print_Reals(self, i): return r"\mathbb{R}" def _print_Complexes(self, i): return r"\mathbb{C}" def _print_ImageSet(self, s): sets = s.args[1:] varsets = [r"%s \in %s" % (self._print(var), self._print(setv)) for var, setv in zip(s.lamda.variables, sets)] return r"\left\{%s\; \|\; %s\right\}" % ( self._print(s.lamda.expr), ', '.join(varsets)) def _print_ConditionSet(self, s): vars_print = ', '.join([self._print(var) for var in Tuple(s.sym)]) if s.base_set is S.UniversalSet: return r"\left\{%s \mid %s \right\}" % \ (vars_print, self._print(s.condition.as_expr())) return r"\left\{%s \mid %s \in %s \wedge %s \right\}" % ( vars_print, vars_print, self._print(s.base_set), self._print(s.condition)) def _print_ComplexRegion(self, s): vars_print = ', '.join([self._print(var) for var in s.variables]) return r"\left\{%s\; \|\; %s \in %s \right\}" % ( self._print(s.expr), vars_print, self._print(s.sets)) def _print_Contains(self, e): return r"%s \in %s" % tuple(self._print(a) for a in e.args) def _print_FourierSeries(self, s): return self._print_Add(s.truncate()) + self._print(r' + \ldots') def _print_FormalPowerSeries(self, s): return self._print_Add(s.infinite) def _print_FiniteField(self, expr): return r"\mathbb{F}_{%s}" % expr.mod def _print_IntegerRing(self, expr): return r"\mathbb{Z}" def _print_RationalField(self, expr): return r"\mathbb{Q}" def _print_RealField(self, expr): return r"\mathbb{R}" def _print_ComplexField(self, expr): return r"\mathbb{C}" def _print_PolynomialRing(self, expr): domain = self._print(expr.domain) symbols = ", ".join(map(self._print, expr.symbols)) return r"%s\left[%s\right]" % (domain, symbols) def _print_FractionField(self, expr): domain = self._print(expr.domain) symbols = ", ".join(map(self._print, expr.symbols)) return r"%s\left(%s\right)" % (domain, symbols) def _print_PolynomialRingBase(self, expr): domain = self._print(expr.domain) symbols = ", ".join(map(self._print, expr.symbols)) inv = "" if not expr.is_Poly: inv = r"S_<^{-1}" return r"%s%s\left[%s\right]" % (inv, domain, symbols) def _print_Poly(self, poly): cls = poly.__class__.__name__ terms = [] for monom, coeff in poly.terms(): s_monom = '' for i, exp in enumerate(monom): if exp > 0: if exp == 1: s_monom += self._print(poly.gens[i]) else: s_monom += self._print(pow(poly.gens[i], exp)) if coeff.is_Add: if s_monom: s_coeff = r"\left(%s\right)" % self._print(coeff) else: s_coeff = self._print(coeff) else: if s_monom: if coeff is S.One: terms.extend(['+', s_monom]) continue if coeff is S.NegativeOne: terms.extend(['-', s_monom]) continue s_coeff = self._print(coeff) if not s_monom: s_term = s_coeff else: s_term = s_coeff + " " + s_monom if s_term.startswith('-'): terms.extend(['-', s_term[1:]]) else: terms.extend(['+', s_term]) if terms[0] in ['-', '+']: modifier = terms.pop(0) if modifier == '-': terms[0] = '-' + terms[0] expr = ' '.join(terms) gens = list(map(self._print, poly.gens)) domain = "domain=%s" % self._print(poly.get_domain()) args = ", ".join([expr] + gens + [domain]) if cls in accepted_latex_functions: tex = r"\%s {\left(%s \right)}" % (cls, args) else: tex = r"\operatorname{%s}{\left( %s \right)}" % (cls, args) return tex def _print_ComplexRootOf(self, root): cls = root.__class__.__name__ if cls == "ComplexRootOf": cls = "CRootOf" expr = self._print(root.expr) index = root.index if cls in accepted_latex_functions: return r"\%s {\left(%s, %d\right)}" % (cls, expr, index) else: return r"\operatorname{%s} {\left(%s, %d\right)}" % (cls, expr, index) def _print_RootSum(self, expr): cls = expr.__class__.__name__ args = [self._print(expr.expr)] if expr.fun is not S.IdentityFunction: args.append(self._print(expr.fun)) if cls in accepted_latex_functions: return r"\%s {\left(%s\right)}" % (cls, ", ".join(args)) else: return r"\operatorname{%s} {\left(%s\right)}" % (cls, ", ".join(args)) def _print_PolyElement(self, poly): mul_symbol = self._settings['mul_symbol_latex'] return poly.str(self, PRECEDENCE, "{%s}^{%d}", mul_symbol) def _print_FracElement(self, frac): if frac.denom == 1: return self._print(frac.numer) else: numer = self._print(frac.numer) denom = self._print(frac.denom) return r"\frac{%s}{%s}" % (numer, denom) def _print_euler(self, expr, exp=None): m, x = (expr.args[0], None) if len(expr.args) == 1 else expr.args tex = r"E_{%s}" % self._print(m) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) if x is not None: tex = r"%s\left(%s\right)" % (tex, self._print(x)) return tex def _print_catalan(self, expr, exp=None): tex = r"C_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_UnifiedTransform(self, expr, s, inverse=False): return r"\mathcal{{{}}}{}_{{{}}}\left[{}\right]\left({}\right)".format(s, '^{-1}' if inverse else '', self._print(expr.args[1]), self._print(expr.args[0]), self._print(expr.args[2])) def _print_MellinTransform(self, expr): return self._print_UnifiedTransform(expr, 'M') def _print_InverseMellinTransform(self, expr): return self._print_UnifiedTransform(expr, 'M', True) def _print_LaplaceTransform(self, expr): return self._print_UnifiedTransform(expr, 'L') def _print_InverseLaplaceTransform(self, expr): return self._print_UnifiedTransform(expr, 'L', True) def _print_FourierTransform(self, expr): return self._print_UnifiedTransform(expr, 'F') def _print_InverseFourierTransform(self, expr): return self._print_UnifiedTransform(expr, 'F', True) def _print_SineTransform(self, expr): return self._print_UnifiedTransform(expr, 'SIN') def _print_InverseSineTransform(self, expr): return self._print_UnifiedTransform(expr, 'SIN', True) def _print_CosineTransform(self, expr): return self._print_UnifiedTransform(expr, 'COS') def _print_InverseCosineTransform(self, expr): return self._print_UnifiedTransform(expr, 'COS', True) def _print_DMP(self, p): try: if p.ring is not None: # TODO incorporate order return self._print(p.ring.to_sympy(p)) except SympifyError: pass return self._print(repr(p)) def _print_DMF(self, p): return self._print_DMP(p) def _print_Object(self, object): return self._print(Symbol(object.name)) def _print_Morphism(self, morphism): domain = self._print(morphism.domain) codomain = self._print(morphism.codomain) return "%s\\rightarrow %s" % (domain, codomain) def _print_NamedMorphism(self, morphism): pretty_name = self._print(Symbol(morphism.name)) pretty_morphism = self._print_Morphism(morphism) return "%s:%s" % (pretty_name, pretty_morphism) def _print_IdentityMorphism(self, morphism): from sympy.categories import NamedMorphism return self._print_NamedMorphism(NamedMorphism( morphism.domain, morphism.codomain, "id")) def _print_CompositeMorphism(self, morphism): # All components of the morphism have names and it is thus # possible to build the name of the composite. component_names_list = [self._print(Symbol(component.name)) for component in morphism.components] component_names_list.reverse() component_names = "\\circ ".join(component_names_list) + ":" pretty_morphism = self._print_Morphism(morphism) return component_names + pretty_morphism def _print_Category(self, morphism): return r"\mathbf{{{}}}".format(self._print(Symbol(morphism.name))) def _print_Diagram(self, diagram): if not diagram.premises: # This is an empty diagram. return self._print(S.EmptySet) latex_result = self._print(diagram.premises) if diagram.conclusions: latex_result += "\\Longrightarrow %s" % \ self._print(diagram.conclusions) return latex_result def _print_DiagramGrid(self, grid): latex_result = "\\begin{array}{%s}\n" % ("c" * grid.width) for i in range(grid.height): for j in range(grid.width): if grid[i, j]: latex_result += latex(grid[i, j]) latex_result += " " if j != grid.width - 1: latex_result += "& " if i != grid.height - 1: latex_result += "\\\\" latex_result += "\n" latex_result += "\\end{array}\n" return latex_result def _print_FreeModule(self, M): return '{{{}}}^{{{}}}'.format(self._print(M.ring), self._print(M.rank)) def _print_FreeModuleElement(self, m): # Print as row vector for convenience, for now. return r"\left[ {} \right]".format(",".join( '{' + self._print(x) + '}' for x in m)) def _print_SubModule(self, m): return r"\left\langle {} \right\rangle".format(",".join( '{' + self._print(x) + '}' for x in m.gens)) def _print_ModuleImplementedIdeal(self, m): return r"\left\langle {} \right\rangle".format(",".join( '{' + self._print(x) + '}' for [x] in m._module.gens)) def _print_Quaternion(self, expr): # TODO: This expression is potentially confusing, # shall we print it as `Quaternion( ... )`? s = [self.parenthesize(i, PRECEDENCE["Mul"], strict=True) for i in expr.args] a = [s[0]] + [i+" "+j for i, j in zip(s[1:], "ijk")] return " + ".join(a) def _print_QuotientRing(self, R): # TODO nicer fractions for few generators... return r"\frac{{{}}}{{{}}}".format(self._print(R.ring), self._print(R.base_ideal)) def _print_QuotientRingElement(self, x): return r"{{{}}} + {{{}}}".format(self._print(x.data), self._print(x.ring.base_ideal)) def _print_QuotientModuleElement(self, m): return r"{{{}}} + {{{}}}".format(self._print(m.data), self._print(m.module.killed_module)) def _print_QuotientModule(self, M): # TODO nicer fractions for few generators... return r"\frac{{{}}}{{{}}}".format(self._print(M.base), self._print(M.killed_module)) def _print_MatrixHomomorphism(self, h): return r"{{{}}} : {{{}}} \to {{{}}}".format(self._print(h._sympy_matrix()), self._print(h.domain), self._print(h.codomain)) def _print_BaseScalarField(self, field): string = field._coord_sys._names[field._index] return r'\mathbf{{{}}}'.format(self._print(Symbol(string))) def _print_BaseVectorField(self, field): string = field._coord_sys._names[field._index] return r'\partial_{{{}}}'.format(self._print(Symbol(string))) def _print_Differential(self, diff): field = diff._form_field if hasattr(field, '_coord_sys'): string = field._coord_sys._names[field._index] return r'\operatorname{{d}}{}'.format(self._print(Symbol(string))) else: string = self._print(field) return r'\operatorname{{d}}\left({}\right)'.format(string) def _print_Tr(self, p): # TODO: Handle indices contents = self._print(p.args[0]) return r'\operatorname{{tr}}\left({}\right)'.format(contents) def _print_totient(self, expr, exp=None): if exp is not None: return r'\left(\phi\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\phi\left(%s\right)' % self._print(expr.args[0]) def _print_reduced_totient(self, expr, exp=None): if exp is not None: return r'\left(\lambda\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\lambda\left(%s\right)' % self._print(expr.args[0]) def _print_divisor_sigma(self, expr, exp=None): if len(expr.args) == 2: tex = r"_%s\left(%s\right)" % tuple(map(self._print, (expr.args[1], expr.args[0]))) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\sigma^{%s}%s" % (self._print(exp), tex) return r"\sigma%s" % tex def _print_udivisor_sigma(self, expr, exp=None): if len(expr.args) == 2: tex = r"_%s\left(%s\right)" % tuple(map(self._print, (expr.args[1], expr.args[0]))) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\sigma^^{%s}%s" % (self._print(exp), tex) return r"\sigma^%s" % tex def _print_primenu(self, expr, exp=None): if exp is not None: return r'\left(\nu\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\nu\left(%s\right)' % self._print(expr.args[0]) def _print_primeomega(self, expr, exp=None): if exp is not None: return r'\left(\Omega\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\Omega\left(%s\right)' % self._print(expr.args[0]) def translate(s): r''' Check for a modifier ending the string. If present, convert the modifier to latex and translate the rest recursively. Given a description of a Greek letter or other special character, return the appropriate latex. Let everything else pass as given. >>> from sympy.printing.latex import translate >>> translate('alphahatdotprime') "{\\dot{\\hat{\\alpha}}}'" ''' # Process the rest tex = tex_greek_dictionary.get(s) if tex: return tex elif s.lower() in greek_letters_set: return "\\" + s.lower() elif s in other_symbols: return "\\" + s else: # Process modifiers, if any, and recurse for key in sorted(modifier_dict.keys(), key=lambda k:len(k), reverse=True): if s.lower().endswith(key) and len(s) > len(key): return modifier_dict[key](translate(s[:-len(key)])) return s def latex(expr, fold_frac_powers=False, fold_func_brackets=False, fold_short_frac=None, inv_trig_style="abbreviated", itex=False, ln_notation=False, long_frac_ratio=None, mat_delim="[", mat_str=None, mode="plain", mul_symbol=None, order=None, symbol_names=None, root_notation=True, mat_symbol_style="plain", imaginary_unit="i", gothic_re_im=False): r"""Convert the given expression to LaTeX string representation. Parameters ========== fold_frac_powers : boolean, optional Emit ``^{p/q}`` instead of ``^{\frac{p}{q}}`` for fractional powers. fold_func_brackets : boolean, optional Fold function brackets where applicable. fold_short_frac : boolean, optional Emit ``p / q`` instead of ``\frac{p}{q}`` when the denominator is simple enough (at most two terms and no powers). The default value is ``True`` for inline mode, ``False`` otherwise. inv_trig_style : string, optional How inverse trig functions should be displayed. Can be one of ``abbreviated``, ``full``, or ``power``. Defaults to ``abbreviated``. itex : boolean, optional Specifies if itex-specific syntax is used, including emitting ``$$...$$``. ln_notation : boolean, optional If set to ``True``, ``\ln`` is used instead of default ``\log``. long_frac_ratio : float or None, optional The allowed ratio of the width of the numerator to the width of the denominator before the printer breaks off long fractions. If ``None`` (the default value), long fractions are not broken up. mat_delim : string, optional The delimiter to wrap around matrices. Can be one of ``[``, ``(``, or the empty string. Defaults to ``[``. mat_str : string, optional Which matrix environment string to emit. ``smallmatrix``, ``matrix``, ``array``, etc. Defaults to ``smallmatrix`` for inline mode, ``matrix`` for matrices of no more than 10 columns, and ``array`` otherwise. mode: string, optional Specifies how the generated code will be delimited. ``mode`` can be one of ``plain``, ``inline``, ``equation`` or ``equation``. If ``mode`` is set to ``plain``, then the resulting code will not be delimited at all (this is the default). If ``mode`` is set to ``inline`` then inline LaTeX ``$...$`` will be used. If ``mode`` is set to ``equation`` or ``equation``, the resulting code will be enclosed in the ``equation`` or ``equation`` environment (remember to import ``amsmath`` for ``equation``), unless the ``itex`` option is set. In the latter case, the ``$$...$$`` syntax is used. mul_symbol : string or None, optional The symbol to use for multiplication. Can be one of ``None``, ``ldot``, ``dot``, or ``times``. order: string, optional Any of the supported monomial orderings (currently ``lex``, ``grlex``, or ``grevlex``), ``old``, and ``none``. This parameter does nothing for Mul objects. Setting order to ``old`` uses the compatibility ordering for Add defined in Printer. For very large expressions, set the ``order`` keyword to ``none`` if speed is a concern. symbol_names : dictionary of strings mapped to symbols, optional Dictionary of symbols and the custom strings they should be emitted as. root_notation : boolean, optional If set to ``False``, exponents of the form 1/n are printed in fractonal form. Default is ``True``, to print exponent in root form. mat_symbol_style : string, optional Can be either ``plain`` (default) or ``bold``. If set to ``bold``, a MatrixSymbol A will be printed as ``\mathbf{A}``, otherwise as ``A``. imaginary_unit : string, optional String to use for the imaginary unit. Defined options are "i" (default) and "j". Adding "r" or "t" in front gives ``\mathrm`` or ``\text``, so "ri" leads to ``\mathrm{i}`` which gives `\mathrm{i}`. gothic_re_im : boolean, optional If set to ``True``, `\Re` and `\Im` is used for ``re`` and ``im``, respectively. The default is ``False`` leading to `\operatorname{re}` and `\operatorname{im}`. Notes ===== Not using a print statement for printing, results in double backslashes for latex commands since that's the way Python escapes backslashes in strings. >>> from sympy import latex, Rational >>> from sympy.abc import tau >>> latex((2tau)Rational(7,2)) '8 \\sqrt{2} \\tau^{\\frac{7}{2}}' >>> print(latex((2tau)*Rational(7,2))) 8 \sqrt{2} \tau^{\frac{7}{2}} Examples ======== >>> from sympy import latex, pi, sin, asin, Integral, Matrix, Rational, log >>> from sympy.abc import x, y, mu, r, tau Basic usage: >>> print(latex((2tau)*Rational(7,2))) 8 \sqrt{2} \tau^{\frac{7}{2}} ``mode`` and ``itex`` options: >>> print(latex((2mu)*Rational(7,2), mode='plain')) 8 \sqrt{2} \mu^{\frac{7}{2}} >>> print(latex((2tau)*Rational(7,2), mode='inline')) $8 \sqrt{2} \tau^{7 / 2}$ >>> print(latex((2mu)*Rational(7,2), mode='equation')) \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} >>> print(latex((2mu)Rational(7,2), mode='equation')) \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} >>> print(latex((2mu)*Rational(7,2), mode='equation', itex=True)) $$8 \sqrt{2} \mu^{\frac{7}{2}}$$ >>> print(latex((2mu)*Rational(7,2), mode='plain')) 8 \sqrt{2} \mu^{\frac{7}{2}} >>> print(latex((2tau)*Rational(7,2), mode='inline')) $8 \sqrt{2} \tau^{7 / 2}$ >>> print(latex((2mu)*Rational(7,2), mode='equation')) \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} >>> print(latex((2mu)Rational(7,2), mode='equation')) \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} >>> print(latex((2mu)*Rational(7,2), mode='equation', itex=True)) $$8 \sqrt{2} \mu^{\frac{7}{2}}$$ Fraction options: >>> print(latex((2tau)*Rational(7,2), fold_frac_powers=True)) 8 \sqrt{2} \tau^{7/2} >>> print(latex((2tau)*sin(Rational(7,2)))) \left(2 \tau\right)^{\sin{\left(\frac{7}{2} \right)}} >>> print(latex((2tau)*sin(Rational(7,2)), fold_func_brackets=True)) \left(2 \tau\right)^{\sin {\frac{7}{2}}} >>> print(latex(3x*2/y)) \frac{3 x^{2}}{y} >>> print(latex(3x*2/y, fold_short_frac=True)) 3 x^{2} / y >>> print(latex(Integral(r, r)/2/pi, long_frac_ratio=2)) \frac{\int r\, dr}{2 \pi} >>> print(latex(Integral(r, r)/2/pi, long_frac_ratio=0)) \frac{1}{2 \pi} \int r\, dr Multiplication options: >>> print(latex((2tau)sin(Rational(7,2)), mul_symbol="times")) \left(2 \times \tau\right)^{\sin{\left(\frac{7}{2} \right)}} Trig options: >>> print(latex(asin(Rational(7,2)))) \operatorname{asin}{\left(\frac{7}{2} \right)} >>> print(latex(asin(Rational(7,2)), inv_trig_style="full")) \arcsin{\left(\frac{7}{2} \right)} >>> print(latex(asin(Rational(7,2)), inv_trig_style="power")) \sin^{-1}{\left(\frac{7}{2} \right)} Matrix options: >>> print(latex(Matrix(2, 1, [x, y]))) \left[\begin{matrix}x\\y\end{matrix}\right] >>> print(latex(Matrix(2, 1, [x, y]), mat_str = "array")) \left[\begin{array}{c}x\\y\end{array}\right] >>> print(latex(Matrix(2, 1, [x, y]), mat_delim="(")) \left(\begin{matrix}x\\y\end{matrix}\right) Custom printing of symbols: >>> print(latex(x2, symbol_names={x: 'x_i'})) x_i^{2} Logarithms: >>> print(latex(log(10))) \log{\left(10 \right)} >>> print(latex(log(10), ln_notation=True)) \ln{\left(10 \right)} ``latex()`` also supports the builtin container types list, tuple, and dictionary. >>> print(latex([2/x, y], mode='inline')) $\left[ 2 / x, \ y\right]$ """ if symbol_names is None: symbol_names = {} settings = { 'fold_frac_powers': fold_frac_powers, 'fold_func_brackets': fold_func_brackets, 'fold_short_frac': fold_short_frac, 'inv_trig_style': inv_trig_style, 'itex': itex, 'ln_notation': ln_notation, 'long_frac_ratio': long_frac_ratio, 'mat_delim': mat_delim, 'mat_str': mat_str, 'mode': mode, 'mul_symbol': mul_symbol, 'order': order, 'symbol_names': symbol_names, 'root_notation': root_notation, 'mat_symbol_style': mat_symbol_style, 'imaginary_unit': imaginary_unit, 'gothic_re_im': gothic_re_im, } return LatexPrinter(settings).doprint(expr) def print_latex(expr, settings): """Prints LaTeX representation of the given expression. Takes the same settings as ``latex()``.""" print(latex(expr, settings))
bde93a64f132110274cad28a3f2979c7abddf091a147ee1a7e013c90946f8dc3	""" A MathML printer. """ from __future__ import print_function, division from sympy import sympify, S, Mul from sympy.core.compatibility import range, string_types, default_sort_key from sympy.core.function import _coeff_isneg from sympy.printing.conventions import split_super_sub, requires_partial from sympy.printing.precedence import precedence_traditional, PRECEDENCE from sympy.printing.pretty.pretty_symbology import greek_unicode from sympy.printing.printer import Printer import mpmath.libmp as mlib from mpmath.libmp import prec_to_dps class MathMLPrinterBase(Printer): """Contains common code required for MathMLContentPrinter and MathMLPresentationPrinter. """ _default_settings = { "order": None, "encoding": "utf-8", "fold_frac_powers": False, "fold_func_brackets": False, "fold_short_frac": None, "inv_trig_style": "abbreviated", "ln_notation": False, "long_frac_ratio": None, "mat_delim": "[", "mat_symbol_style": "plain", "mul_symbol": None, "root_notation": True, "symbol_names": {}, "mul_symbol_mathml_numbers": '·', } def __init__(self, settings=None): Printer.__init__(self, settings) from xml.dom.minidom import Document, Text self.dom = Document() # Workaround to allow strings to remain unescaped # Based on # https://stackoverflow.com/questions/38015864/python-xml-dom-minidom-\ # please-dont-escape-my-strings/38041194 class RawText(Text): def writexml(self, writer, indent='', addindent='', newl=''): if self.data: writer.write(u'{}{}{}'.format(indent, self.data, newl)) def createRawTextNode(data): r = RawText() r.data = data r.ownerDocument = self.dom return r self.dom.createTextNode = createRawTextNode def doprint(self, expr): """ Prints the expression as MathML. """ mathML = Printer._print(self, expr) unistr = mathML.toxml() xmlbstr = unistr.encode('ascii', 'xmlcharrefreplace') res = xmlbstr.decode() return res def apply_patch(self): # Applying the patch of xml.dom.minidom bug # Date: 2011-11-18 # Description: http://ronrothman.com/public/leftbraned/xml-dom-minidom\ # -toprettyxml-and-silly-whitespace/#best-solution # Issue: http://bugs.python.org/issue4147 # Patch: http://hg.python.org/cpython/rev/7262f8f276ff/ from xml.dom.minidom import Element, Text, Node, _write_data def writexml(self, writer, indent="", addindent="", newl=""): # indent = current indentation # addindent = indentation to add to higher levels # newl = newline string writer.write(indent + "<" + self.tagName) attrs = self._get_attributes() a_names = list(attrs.keys()) a_names.sort() for a_name in a_names: writer.write(" %s=\"" % a_name) _write_data(writer, attrs[a_name].value) writer.write("\"") if self.childNodes: writer.write(">") if (len(self.childNodes) == 1 and self.childNodes[0].nodeType == Node.TEXT_NODE): self.childNodes[0].writexml(writer, '', '', '') else: writer.write(newl) for node in self.childNodes: node.writexml( writer, indent + addindent, addindent, newl) writer.write(indent) writer.write("</%s>%s" % (self.tagName, newl)) else: writer.write("/>%s" % (newl)) self._Element_writexml_old = Element.writexml Element.writexml = writexml def writexml(self, writer, indent="", addindent="", newl=""): _write_data(writer, "%s%s%s" % (indent, self.data, newl)) self._Text_writexml_old = Text.writexml Text.writexml = writexml def restore_patch(self): from xml.dom.minidom import Element, Text Element.writexml = self._Element_writexml_old Text.writexml = self._Text_writexml_old class MathMLContentPrinter(MathMLPrinterBase): """Prints an expression to the Content MathML markup language. References: https://www.w3.org/TR/MathML2/chapter4.html """ printmethod = "_mathml_content" def mathml_tag(self, e): """Returns the MathML tag for an expression.""" translate = { 'Add': 'plus', 'Mul': 'times', 'Derivative': 'diff', 'Number': 'cn', 'int': 'cn', 'Pow': 'power', 'Symbol': 'ci', 'MatrixSymbol': 'ci', 'RandomSymbol': 'ci', 'Integral': 'int', 'Sum': 'sum', 'sin': 'sin', 'cos': 'cos', 'tan': 'tan', 'cot': 'cot', 'asin': 'arcsin', 'asinh': 'arcsinh', 'acos': 'arccos', 'acosh': 'arccosh', 'atan': 'arctan', 'atanh': 'arctanh', 'acot': 'arccot', 'atan2': 'arctan', 'log': 'ln', 'Equality': 'eq', 'Unequality': 'neq', 'GreaterThan': 'geq', 'LessThan': 'leq', 'StrictGreaterThan': 'gt', 'StrictLessThan': 'lt', } for cls in e.__class__.__mro__: n = cls.__name__ if n in translate: return translate[n] # Not found in the MRO set n = e.__class__.__name__ return n.lower() def _print_Mul(self, expr): if _coeff_isneg(expr): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('minus')) x.appendChild(self._print_Mul(-expr)) return x from sympy.simplify import fraction numer, denom = fraction(expr) if denom is not S.One: x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('divide')) x.appendChild(self._print(numer)) x.appendChild(self._print(denom)) return x coeff, terms = expr.as_coeff_mul() if coeff is S.One and len(terms) == 1: # XXX since the negative coefficient has been handled, I don't # think a coeff of 1 can remain return self._print(terms[0]) if self.order != 'old': terms = Mul._from_args(terms).as_ordered_factors() x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('times')) if coeff != 1: x.appendChild(self._print(coeff)) for term in terms: x.appendChild(self._print(term)) return x def _print_Add(self, expr, order=None): args = self._as_ordered_terms(expr, order=order) lastProcessed = self._print(args[0]) plusNodes = [] for arg in args[1:]: if _coeff_isneg(arg): # use minus x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('minus')) x.appendChild(lastProcessed) x.appendChild(self._print(-arg)) # invert expression since this is now minused lastProcessed = x if arg == args[-1]: plusNodes.append(lastProcessed) else: plusNodes.append(lastProcessed) lastProcessed = self._print(arg) if arg == args[-1]: plusNodes.append(self._print(arg)) if len(plusNodes) == 1: return lastProcessed x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('plus')) while plusNodes: x.appendChild(plusNodes.pop(0)) return x def _print_MatrixBase(self, m): x = self.dom.createElement('matrix') for i in range(m.rows): x_r = self.dom.createElement('matrixrow') for j in range(m.cols): x_r.appendChild(self._print(m[i, j])) x.appendChild(x_r) return x def _print_Rational(self, e): if e.q == 1: # don't divide x = self.dom.createElement('cn') x.appendChild(self.dom.createTextNode(str(e.p))) return x x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('divide')) # numerator xnum = self.dom.createElement('cn') xnum.appendChild(self.dom.createTextNode(str(e.p))) # denominator xdenom = self.dom.createElement('cn') xdenom.appendChild(self.dom.createTextNode(str(e.q))) x.appendChild(xnum) x.appendChild(xdenom) return x def _print_Limit(self, e): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement(self.mathml_tag(e))) x_1 = self.dom.createElement('bvar') x_2 = self.dom.createElement('lowlimit') x_1.appendChild(self._print(e.args[1])) x_2.appendChild(self._print(e.args[2])) x.appendChild(x_1) x.appendChild(x_2) x.appendChild(self._print(e.args[0])) return x def _print_ImaginaryUnit(self, e): return self.dom.createElement('imaginaryi') def _print_EulerGamma(self, e): return self.dom.createElement('eulergamma') def _print_GoldenRatio(self, e): """We use unicode #x3c6 for Greek letter phi as defined here http://www.w3.org/2003/entities/2007doc/isogrk1.html""" x = self.dom.createElement('cn') x.appendChild(self.dom.createTextNode(u"\N{GREEK SMALL LETTER PHI}")) return x def _print_Exp1(self, e): return self.dom.createElement('exponentiale') def _print_Pi(self, e): return self.dom.createElement('pi') def _print_Infinity(self, e): return self.dom.createElement('infinity') def _print_NegativeInfinity(self, e): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('minus')) x.appendChild(self.dom.createElement('infinity')) return x def _print_Integral(self, e): def lime_recur(limits): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement(self.mathml_tag(e))) bvar_elem = self.dom.createElement('bvar') bvar_elem.appendChild(self._print(limits[0][0])) x.appendChild(bvar_elem) if len(limits[0]) == 3: low_elem = self.dom.createElement('lowlimit') low_elem.appendChild(self._print(limits[0][1])) x.appendChild(low_elem) up_elem = self.dom.createElement('uplimit') up_elem.appendChild(self._print(limits[0][2])) x.appendChild(up_elem) if len(limits[0]) == 2: up_elem = self.dom.createElement('uplimit') up_elem.appendChild(self._print(limits[0][1])) x.appendChild(up_elem) if len(limits) == 1: x.appendChild(self._print(e.function)) else: x.appendChild(lime_recur(limits[1:])) return x limits = list(e.limits) limits.reverse() return lime_recur(limits) def _print_Sum(self, e): # Printer can be shared because Sum and Integral have the # same internal representation. return self._print_Integral(e) def _print_Symbol(self, sym): ci = self.dom.createElement(self.mathml_tag(sym)) def join(items): if len(items) > 1: mrow = self.dom.createElement('mml:mrow') for i, item in enumerate(items): if i > 0: mo = self.dom.createElement('mml:mo') mo.appendChild(self.dom.createTextNode(" ")) mrow.appendChild(mo) mi = self.dom.createElement('mml:mi') mi.appendChild(self.dom.createTextNode(item)) mrow.appendChild(mi) return mrow else: mi = self.dom.createElement('mml:mi') mi.appendChild(self.dom.createTextNode(items[0])) return mi # translate name, supers and subs to unicode characters def translate(s): if s in greek_unicode: return greek_unicode.get(s) else: return s name, supers, subs = split_super_sub(sym.name) name = translate(name) supers = [translate(sup) for sup in supers] subs = [translate(sub) for sub in subs] mname = self.dom.createElement('mml:mi') mname.appendChild(self.dom.createTextNode(name)) if not supers: if not subs: ci.appendChild(self.dom.createTextNode(name)) else: msub = self.dom.createElement('mml:msub') msub.appendChild(mname) msub.appendChild(join(subs)) ci.appendChild(msub) else: if not subs: msup = self.dom.createElement('mml:msup') msup.appendChild(mname) msup.appendChild(join(supers)) ci.appendChild(msup) else: msubsup = self.dom.createElement('mml:msubsup') msubsup.appendChild(mname) msubsup.appendChild(join(subs)) msubsup.appendChild(join(supers)) ci.appendChild(msubsup) return ci _print_MatrixSymbol = _print_Symbol _print_RandomSymbol = _print_Symbol def _print_Pow(self, e): # Here we use root instead of power if the exponent is the reciprocal # of an integer if (self._settings['root_notation'] and e.exp.is_Rational and e.exp.p == 1): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('root')) if e.exp.q != 2: xmldeg = self.dom.createElement('degree') xmlci = self.dom.createElement('ci') xmlci.appendChild(self.dom.createTextNode(str(e.exp.q))) xmldeg.appendChild(xmlci) x.appendChild(xmldeg) x.appendChild(self._print(e.base)) return x x = self.dom.createElement('apply') x_1 = self.dom.createElement(self.mathml_tag(e)) x.appendChild(x_1) x.appendChild(self._print(e.base)) x.appendChild(self._print(e.exp)) return x def _print_Number(self, e): x = self.dom.createElement(self.mathml_tag(e)) x.appendChild(self.dom.createTextNode(str(e))) return x def _print_Derivative(self, e): x = self.dom.createElement('apply') diff_symbol = self.mathml_tag(e) if requires_partial(e): diff_symbol = 'partialdiff' x.appendChild(self.dom.createElement(diff_symbol)) x_1 = self.dom.createElement('bvar') for sym, times in reversed(e.variable_count): x_1.appendChild(self._print(sym)) if times > 1: degree = self.dom.createElement('degree') degree.appendChild(self._print(sympify(times))) x_1.appendChild(degree) x.appendChild(x_1) x.appendChild(self._print(e.expr)) return x def _print_Function(self, e): x = self.dom.createElement("apply") x.appendChild(self.dom.createElement(self.mathml_tag(e))) for arg in e.args: x.appendChild(self._print(arg)) return x def _print_Basic(self, e): x = self.dom.createElement(self.mathml_tag(e)) for arg in e.args: x.appendChild(self._print(arg)) return x def _print_AssocOp(self, e): x = self.dom.createElement('apply') x_1 = self.dom.createElement(self.mathml_tag(e)) x.appendChild(x_1) for arg in e.args: x.appendChild(self._print(arg)) return x def _print_Relational(self, e): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement(self.mathml_tag(e))) x.appendChild(self._print(e.lhs)) x.appendChild(self._print(e.rhs)) return x def _print_list(self, seq): """MathML reference for the <list> element: http://www.w3.org/TR/MathML2/chapter4.html#contm.list""" dom_element = self.dom.createElement('list') for item in seq: dom_element.appendChild(self._print(item)) return dom_element def _print_int(self, p): dom_element = self.dom.createElement(self.mathml_tag(p)) dom_element.appendChild(self.dom.createTextNode(str(p))) return dom_element class MathMLPresentationPrinter(MathMLPrinterBase): """Prints an expression to the Presentation MathML markup language. References: https://www.w3.org/TR/MathML2/chapter3.html """ printmethod = "_mathml_presentation" def mathml_tag(self, e): """Returns the MathML tag for an expression.""" translate = { 'Number': 'mn', 'Limit': '→', 'Derivative': '&dd;', 'int': 'mn', 'Symbol': 'mi', 'Integral': '∫', 'Sum': '∑', 'sin': 'sin', 'cos': 'cos', 'tan': 'tan', 'cot': 'cot', 'asin': 'arcsin', 'asinh': 'arcsinh', 'acos': 'arccos', 'acosh': 'arccosh', 'atan': 'arctan', 'atanh': 'arctanh', 'acot': 'arccot', 'atan2': 'arctan', 'Equality': '=', 'Unequality': '≠', 'GreaterThan': '≥', 'LessThan': '≤', 'StrictGreaterThan': '>', 'StrictLessThan': '<', 'lerchphi': 'Φ', 'zeta': 'ζ', 'dirichlet_eta': 'η', 'elliptic_k': 'Κ', 'lowergamma': 'γ', 'uppergamma': 'Γ', 'gamma': 'Γ', 'totient': 'ϕ', 'reduced_totient': 'λ', 'primenu': 'ν', 'primeomega': 'Ω', 'fresnels': 'S', 'fresnelc': 'C', 'Heaviside': 'Θ', 'BooleanTrue': 'True', 'BooleanFalse': 'False', 'NoneType': 'None', } def mul_symbol_selection(): if (self._settings["mul_symbol"] is None or self._settings["mul_symbol"] == 'None'): return '⁢' elif self._settings["mul_symbol"] == 'times': return '×' elif self._settings["mul_symbol"] == 'dot': return '·' elif self._settings["mul_symbol"] == 'ldot': return '․' elif not isinstance(self._settings["mul_symbol"], string_types): raise TypeError else: return self._settings["mul_symbol"] for cls in e.__class__.__mro__: n = cls.__name__ if n in translate: return translate[n] # Not found in the MRO set if e.__class__.__name__ == "Mul": return mul_symbol_selection() n = e.__class__.__name__ return n.lower() def parenthesize(self, item, level, strict=False): prec_val = precedence_traditional(item) if (prec_val < level) or ((not strict) and prec_val <= level): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(item)) return brac else: return self._print(item) def _print_Mul(self, expr): def multiply(expr, mrow): from sympy.simplify import fraction numer, denom = fraction(expr) if denom is not S.One: frac = self.dom.createElement('mfrac') if self._settings["fold_short_frac"] and len(str(expr)) < 7: frac.setAttribute('bevelled', 'true') xnum = self._print(numer) xden = self._print(denom) frac.appendChild(xnum) frac.appendChild(xden) mrow.appendChild(frac) return mrow coeff, terms = expr.as_coeff_mul() if coeff is S.One and len(terms) == 1: mrow.appendChild(self._print(terms[0])) return mrow if self.order != 'old': terms = Mul._from_args(terms).as_ordered_factors() if coeff != 1: x = self._print(coeff) y = self.dom.createElement('mo') y.appendChild(self.dom.createTextNode(self.mathml_tag(expr))) mrow.appendChild(x) mrow.appendChild(y) for term in terms: x = self._print(term) mrow.appendChild(x) if not term == terms[-1]: y = self.dom.createElement('mo') y.appendChild(self.dom.createTextNode(self.mathml_tag(expr))) mrow.appendChild(y) return mrow mrow = self.dom.createElement('mrow') if _coeff_isneg(expr): x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('-')) mrow.appendChild(x) mrow = multiply(-expr, mrow) else: mrow = multiply(expr, mrow) return mrow def _print_Add(self, expr, order=None): mrow = self.dom.createElement('mrow') args = self._as_ordered_terms(expr, order=order) mrow.appendChild(self._print(args[0])) for arg in args[1:]: if _coeff_isneg(arg): # use minus x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('-')) y = self._print(-arg) # invert expression since this is now minused else: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('+')) y = self._print(arg) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_MatrixBase(self, m): table = self.dom.createElement('mtable') for i in range(m.rows): x = self.dom.createElement('mtr') for j in range(m.cols): y = self.dom.createElement('mtd') y.appendChild(self._print(m[i, j])) x.appendChild(y) table.appendChild(x) if self._settings["mat_delim"] == '': return table brac = self.dom.createElement('mfenced') if self._settings["mat_delim"] == "[": brac.setAttribute('open', '[') brac.setAttribute('close', ']') brac.appendChild(table) return brac def _get_printed_Rational(self, e, folded=None): if e.p < 0: p = -e.p else: p = e.p x = self.dom.createElement('mfrac') if folded or self._settings["fold_short_frac"]: x.setAttribute('bevelled', 'true') x.appendChild(self._print(p)) x.appendChild(self._print(e.q)) if e.p < 0: mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('-')) mrow.appendChild(mo) mrow.appendChild(x) return mrow else: return x def _print_Rational(self, e): if e.q == 1: # don't divide return self._print(e.p) return self._get_printed_Rational(e, self._settings["fold_short_frac"]) def _print_Limit(self, e): mrow = self.dom.createElement('mrow') munder = self.dom.createElement('munder') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('lim')) x = self.dom.createElement('mrow') x_1 = self._print(e.args[1]) arrow = self.dom.createElement('mo') arrow.appendChild(self.dom.createTextNode(self.mathml_tag(e))) x_2 = self._print(e.args[2]) x.appendChild(x_1) x.appendChild(arrow) x.appendChild(x_2) munder.appendChild(mi) munder.appendChild(x) mrow.appendChild(munder) mrow.appendChild(self._print(e.args[0])) return mrow def _print_ImaginaryUnit(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('&ImaginaryI;')) return x def _print_GoldenRatio(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('Φ')) return x def _print_Exp1(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('&ExponentialE;')) return x def _print_Pi(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('π')) return x def _print_Infinity(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('∞')) return x def _print_NegativeInfinity(self, e): mrow = self.dom.createElement('mrow') y = self.dom.createElement('mo') y.appendChild(self.dom.createTextNode('-')) x = self._print_Infinity(e) mrow.appendChild(y) mrow.appendChild(x) return mrow def _print_Integral(self, expr): intsymbols = {1: "∫", 2: "∬", 3: "∭"} mrow = self.dom.createElement('mrow') if len(expr.limits) <= 3 and all(len(lim) == 1 for lim in expr.limits): # Only up to three-integral signs exists mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(intsymbols[len(expr.limits)])) mrow.appendChild(mo) else: # Either more than three or limits provided for lim in reversed(expr.limits): mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(intsymbols[1])) if len(lim) == 1: mrow.appendChild(mo) if len(lim) == 2: msup = self.dom.createElement('msup') msup.appendChild(mo) msup.appendChild(self._print(lim[1])) mrow.appendChild(msup) if len(lim) == 3: msubsup = self.dom.createElement('msubsup') msubsup.appendChild(mo) msubsup.appendChild(self._print(lim[1])) msubsup.appendChild(self._print(lim[2])) mrow.appendChild(msubsup) # print function mrow.appendChild(self.parenthesize(expr.function, PRECEDENCE["Mul"], strict=True)) # print integration variables for lim in reversed(expr.limits): d = self.dom.createElement('mo') d.appendChild(self.dom.createTextNode('&dd;')) mrow.appendChild(d) mrow.appendChild(self._print(lim[0])) return mrow def _print_Sum(self, e): limits = list(e.limits) subsup = self.dom.createElement('munderover') low_elem = self._print(limits[0][1]) up_elem = self._print(limits[0][2]) summand = self.dom.createElement('mo') summand.appendChild(self.dom.createTextNode(self.mathml_tag(e))) low = self.dom.createElement('mrow') var = self._print(limits[0][0]) equal = self.dom.createElement('mo') equal.appendChild(self.dom.createTextNode('=')) low.appendChild(var) low.appendChild(equal) low.appendChild(low_elem) subsup.appendChild(summand) subsup.appendChild(low) subsup.appendChild(up_elem) mrow = self.dom.createElement('mrow') mrow.appendChild(subsup) if len(str(e.function)) == 1: mrow.appendChild(self._print(e.function)) else: fence = self.dom.createElement('mfenced') fence.appendChild(self._print(e.function)) mrow.appendChild(fence) return mrow def _print_Symbol(self, sym, style='plain'): def join(items): if len(items) > 1: mrow = self.dom.createElement('mrow') for i, item in enumerate(items): if i > 0: mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(" ")) mrow.appendChild(mo) mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(item)) mrow.appendChild(mi) return mrow else: mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(items[0])) return mi # translate name, supers and subs to unicode characters def translate(s): if s in greek_unicode: return greek_unicode.get(s) else: return s name, supers, subs = split_super_sub(sym.name) name = translate(name) supers = [translate(sup) for sup in supers] subs = [translate(sub) for sub in subs] mname = self.dom.createElement('mi') mname.appendChild(self.dom.createTextNode(name)) if len(supers) == 0: if len(subs) == 0: x = mname else: x = self.dom.createElement('msub') x.appendChild(mname) x.appendChild(join(subs)) else: if len(subs) == 0: x = self.dom.createElement('msup') x.appendChild(mname) x.appendChild(join(supers)) else: x = self.dom.createElement('msubsup') x.appendChild(mname) x.appendChild(join(subs)) x.appendChild(join(supers)) # Set bold font? if style == 'bold': x.setAttribute('mathvariant', 'bold') return x def _print_MatrixSymbol(self, sym): return self._print_Symbol(sym, style=self._settings['mat_symbol_style']) _print_RandomSymbol = _print_Symbol def _print_conjugate(self, expr): enc = self.dom.createElement('menclose') enc.setAttribute('notation', 'top') enc.appendChild(self._print(expr.args[0])) return enc def _print_operator_after(self, op, expr): row = self.dom.createElement('mrow') row.appendChild(self.parenthesize(expr, PRECEDENCE["Func"])) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(op)) row.appendChild(mo) return row def _print_factorial(self, expr): return self._print_operator_after('!', expr.args[0]) def _print_factorial2(self, expr): return self._print_operator_after('!!', expr.args[0]) def _print_binomial(self, expr): brac = self.dom.createElement('mfenced') frac = self.dom.createElement('mfrac') frac.setAttribute('linethickness', '0') frac.appendChild(self._print(expr.args[0])) frac.appendChild(self._print(expr.args[1])) brac.appendChild(frac) return brac def _print_Pow(self, e): # Here we use root instead of power if the exponent is the # reciprocal of an integer if (e.exp.is_Rational and abs(e.exp.p) == 1 and e.exp.q != 1 and self._settings['root_notation']): if e.exp.q == 2: x = self.dom.createElement('msqrt') x.appendChild(self._print(e.base)) if e.exp.q != 2: x = self.dom.createElement('mroot') x.appendChild(self._print(e.base)) x.appendChild(self._print(e.exp.q)) if e.exp.p == -1: frac = self.dom.createElement('mfrac') frac.appendChild(self._print(1)) frac.appendChild(x) return frac else: return x if e.exp.is_Rational and e.exp.q != 1: if e.exp.is_negative: top = self.dom.createElement('mfrac') top.appendChild(self._print(1)) x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._get_printed_Rational(-e.exp, self._settings['fold_frac_powers'])) top.appendChild(x) return top else: x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._get_printed_Rational(e.exp, self._settings['fold_frac_powers'])) return x if e.exp.is_negative: top = self.dom.createElement('mfrac') top.appendChild(self._print(1)) if e.exp == -1: top.appendChild(self._print(e.base)) else: x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._print(-e.exp)) top.appendChild(x) return top x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._print(e.exp)) return x def _print_Number(self, e): x = self.dom.createElement(self.mathml_tag(e)) x.appendChild(self.dom.createTextNode(str(e))) return x def _print_AccumulationBounds(self, i): brac = self.dom.createElement('mfenced') brac.setAttribute('open', u'\u27e8') brac.setAttribute('close', u'\u27e9') brac.appendChild(self._print(i.min)) brac.appendChild(self._print(i.max)) return brac def _print_Derivative(self, e): if requires_partial(e): d = '∂' else: d = self.mathml_tag(e) # Determine denominator m = self.dom.createElement('mrow') dim = 0 # Total diff dimension, for numerator for sym, num in reversed(e.variable_count): dim += num if num >= 2: x = self.dom.createElement('msup') xx = self.dom.createElement('mo') xx.appendChild(self.dom.createTextNode(d)) x.appendChild(xx) x.appendChild(self._print(num)) else: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(d)) m.appendChild(x) y = self._print(sym) m.appendChild(y) mnum = self.dom.createElement('mrow') if dim >= 2: x = self.dom.createElement('msup') xx = self.dom.createElement('mo') xx.appendChild(self.dom.createTextNode(d)) x.appendChild(xx) x.appendChild(self._print(dim)) else: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(d)) mnum.appendChild(x) mrow = self.dom.createElement('mrow') frac = self.dom.createElement('mfrac') frac.appendChild(mnum) frac.appendChild(m) mrow.appendChild(frac) # Print function mrow.appendChild(self._print(e.expr)) return mrow def _print_Function(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mi') if self.mathml_tag(e) == 'log' and self._settings["ln_notation"]: x.appendChild(self.dom.createTextNode('ln')) else: x.appendChild(self.dom.createTextNode(self.mathml_tag(e))) y = self.dom.createElement('mfenced') for arg in e.args: y.appendChild(self._print(arg)) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_Float(self, expr): # Based off of that in StrPrinter dps = prec_to_dps(expr._prec) str_real = mlib.to_str(expr._mpf_, dps, strip_zeros=True) # Must always have a mul symbol (as 2.5 10^{20} just looks odd) # thus we use the number separator separator = self._settings['mul_symbol_mathml_numbers'] mrow = self.dom.createElement('mrow') if 'e' in str_real: (mant, exp) = str_real.split('e') if exp[0] == '+': exp = exp[1:] mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode(mant)) mrow.appendChild(mn) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(separator)) mrow.appendChild(mo) msup = self.dom.createElement('msup') mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode("10")) msup.appendChild(mn) mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode(exp)) msup.appendChild(mn) mrow.appendChild(msup) return mrow elif str_real == "+inf": return self._print_Infinity(None) elif str_real == "-inf": return self._print_NegativeInfinity(None) else: mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode(str_real)) return mn def _print_polylog(self, expr): mrow = self.dom.createElement('mrow') m = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('Li')) m.appendChild(mi) m.appendChild(self._print(expr.args[0])) mrow.appendChild(m) brac = self.dom.createElement('mfenced') brac.appendChild(self._print(expr.args[1])) mrow.appendChild(brac) return mrow def _print_Basic(self, e): mrow = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) mrow.appendChild(mi) brac = self.dom.createElement('mfenced') for arg in e.args: brac.appendChild(self._print(arg)) mrow.appendChild(brac) return mrow def _print_Tuple(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') for arg in e.args: x.appendChild(self._print(arg)) mrow.appendChild(x) return mrow def _print_Interval(self, i): mrow = self.dom.createElement('mrow') brac = self.dom.createElement('mfenced') if i.start == i.end: # Most often, this type of Interval is converted to a FiniteSet brac.setAttribute('open', '{') brac.setAttribute('close', '}') brac.appendChild(self._print(i.start)) else: if i.left_open: brac.setAttribute('open', '(') else: brac.setAttribute('open', '[') if i.right_open: brac.setAttribute('close', ')') else: brac.setAttribute('close', ']') brac.appendChild(self._print(i.start)) brac.appendChild(self._print(i.end)) mrow.appendChild(brac) return mrow def _print_Abs(self, expr, exp=None): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') x.setAttribute('open', '\|') x.setAttribute('close', '\|') x.appendChild(self._print(expr.args[0])) mrow.appendChild(x) return mrow _print_Determinant = _print_Abs def _print_re_im(self, c, expr): mrow = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'fraktur') mi.appendChild(self.dom.createTextNode(c)) mrow.appendChild(mi) brac = self.dom.createElement('mfenced') brac.appendChild(self._print(expr)) mrow.appendChild(brac) return mrow def _print_re(self, expr, exp=None): return self._print_re_im('R', expr.args[0]) def _print_im(self, expr, exp=None): return self._print_re_im('I', expr.args[0]) def _print_AssocOp(self, e): mrow = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) mrow.appendChild(mi) for arg in e.args: mrow.appendChild(self._print(arg)) return mrow def _print_SetOp(self, expr, symbol): mrow = self.dom.createElement('mrow') mrow.appendChild(self._print(expr.args[0])) for arg in expr.args[1:]: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(symbol)) y = self._print(arg) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_Union(self, expr): return self._print_SetOp(expr, '∪') def _print_Intersection(self, expr): return self._print_SetOp(expr, '∩') def _print_Complement(self, expr): return self._print_SetOp(expr, '∖') def _print_SymmetricDifference(self, expr): return self._print_SetOp(expr, '∆') def _print_FiniteSet(self, s): return self._print_set(s.args) def _print_set(self, s): items = sorted(s, key=default_sort_key) brac = self.dom.createElement('mfenced') brac.setAttribute('open', '{') brac.setAttribute('close', '}') for item in items: brac.appendChild(self._print(item)) return brac _print_frozenset = _print_set def _print_LogOp(self, args, symbol): mrow = self.dom.createElement('mrow') if args[0].is_Boolean and not args[0].is_Not: brac = self.dom.createElement('mfenced') brac.appendChild(self._print(args[0])) mrow.appendChild(brac) else: mrow.appendChild(self._print(args[0])) for arg in args[1:]: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(symbol)) if arg.is_Boolean and not arg.is_Not: y = self.dom.createElement('mfenced') y.appendChild(self._print(arg)) else: y = self._print(arg) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_BasisDependent(self, expr): from sympy.vector import Vector if expr == expr.zero: # Not clear if this is ever called return self._print(expr.zero) if isinstance(expr, Vector): items = expr.separate().items() else: items = [(0, expr)] mrow = self.dom.createElement('mrow') for system, vect in items: inneritems = list(vect.components.items()) inneritems.sort(key = lambda x:x[0].__str__()) for i, (k, v) in enumerate(inneritems): if v == 1: if i: # No + for first item mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('+')) mrow.appendChild(mo) mrow.appendChild(self._print(k)) elif v == -1: mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('-')) mrow.appendChild(mo) mrow.appendChild(self._print(k)) else: if i: # No + for first item mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('+')) mrow.appendChild(mo) mbrac = self.dom.createElement('mfenced') mbrac.appendChild(self._print(v)) mrow.appendChild(mbrac) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('⁢')) mrow.appendChild(mo) mrow.appendChild(self._print(k)) return mrow def _print_And(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '∧') def _print_Or(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '∨') def _print_Xor(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '⊻') def _print_Implies(self, expr): return self._print_LogOp(expr.args, '⇒') def _print_Equivalent(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '⇔') def _print_Not(self, e): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('¬')) mrow.appendChild(mo) if (e.args[0].is_Boolean): x = self.dom.createElement('mfenced') x.appendChild(self._print(e.args[0])) else: x = self._print(e.args[0]) mrow.appendChild(x) return mrow def _print_bool(self, e): mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) return mi _print_BooleanTrue = _print_bool _print_BooleanFalse = _print_bool def _print_NoneType(self, e): mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) return mi def _print_Range(self, s): dots = u"\u2026" brac = self.dom.createElement('mfenced') brac.setAttribute('open', '{') brac.setAttribute('close', '}') if s.start.is_infinite: printset = dots, s[-1] - s.step, s[-1] elif s.stop.is_infinite: it = iter(s) printset = next(it), next(it), dots elif len(s) > 4: it = iter(s) printset = next(it), next(it), dots, s[-1] else: printset = tuple(s) for el in printset: if el == dots: mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(dots)) brac.appendChild(mi) else: brac.appendChild(self._print(el)) return brac def _hprint_variadic_function(self, expr): args = sorted(expr.args, key=default_sort_key) mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode((str(expr.func)).lower())) mrow.appendChild(mo) brac = self.dom.createElement('mfenced') for symbol in args: brac.appendChild(self._print(symbol)) mrow.appendChild(brac) return mrow _print_Min = _print_Max = _hprint_variadic_function def _print_exp(self, expr): msup = self.dom.createElement('msup') msup.appendChild(self._print_Exp1(None)) msup.appendChild(self._print(expr.args[0])) return msup def _print_Relational(self, e): mrow = self.dom.createElement('mrow') mrow.appendChild(self._print(e.lhs)) x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(self.mathml_tag(e))) mrow.appendChild(x) mrow.appendChild(self._print(e.rhs)) return mrow def _print_int(self, p): dom_element = self.dom.createElement(self.mathml_tag(p)) dom_element.appendChild(self.dom.createTextNode(str(p))) return dom_element def _print_BaseScalar(self, e): msub = self.dom.createElement('msub') index, system = e._id mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._variable_names[index])) msub.appendChild(mi) mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._name)) msub.appendChild(mi) return msub def _print_BaseVector(self, e): msub = self.dom.createElement('msub') index, system = e._id mover = self.dom.createElement('mover') mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._vector_names[index])) mover.appendChild(mi) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('^')) mover.appendChild(mo) msub.appendChild(mover) mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._name)) msub.appendChild(mi) return msub def _print_VectorZero(self, e): mover = self.dom.createElement('mover') mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode("0")) mover.appendChild(mi) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('^')) mover.appendChild(mo) return mover def _print_Cross(self, expr): mrow = self.dom.createElement('mrow') vec1 = expr._expr1 vec2 = expr._expr2 mrow.appendChild(self.parenthesize(vec1, PRECEDENCE['Mul'])) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('×')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(vec2, PRECEDENCE['Mul'])) return mrow def _print_Curl(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∇')) mrow.appendChild(mo) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('×')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Divergence(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∇')) mrow.appendChild(mo) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('·')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Dot(self, expr): mrow = self.dom.createElement('mrow') vec1 = expr._expr1 vec2 = expr._expr2 mrow.appendChild(self.parenthesize(vec1, PRECEDENCE['Mul'])) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('·')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(vec2, PRECEDENCE['Mul'])) return mrow def _print_Gradient(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∇')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Laplacian(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∆')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Integers(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℤ')) return x def _print_Complexes(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℂ')) return x def _print_Reals(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℝ')) return x def _print_Naturals(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℕ')) return x def _print_Naturals0(self, e): sub = self.dom.createElement('msub') x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℕ')) sub.appendChild(x) sub.appendChild(self._print(S.Zero)) return sub def _print_SingularityFunction(self, expr): shift = expr.args[0] - expr.args[1] power = expr.args[2] sup = self.dom.createElement('msup') brac = self.dom.createElement('mfenced') brac.setAttribute('open', u'\u27e8') brac.setAttribute('close', u'\u27e9') brac.appendChild(self._print(shift)) sup.appendChild(brac) sup.appendChild(self._print(power)) return sup def _print_NaN(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('NaN')) return x def _print_bernoulli(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('B')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub _print_bell = _print_bernoulli def _print_catalan(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('C')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_fibonacci(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('F')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_lucas(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('L')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_tribonacci(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('T')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_ComplexInfinity(self, e): x = self.dom.createElement('mover') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∞')) x.appendChild(mo) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('~')) x.appendChild(mo) return x def _print_EmptySet(self, e): x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('∅')) return x def _print_UniversalSet(self, e): x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('𝕌')) return x def _print_Adjoint(self, expr): from sympy.matrices import MatrixSymbol mat = expr.arg sup = self.dom.createElement('msup') if not isinstance(mat, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(mat)) sup.appendChild(brac) else: sup.appendChild(self._print(mat)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('†')) sup.appendChild(mo) return sup def _print_Transpose(self, expr): from sympy.matrices import MatrixSymbol mat = expr.arg sup = self.dom.createElement('msup') if not isinstance(mat, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(mat)) sup.appendChild(brac) else: sup.appendChild(self._print(mat)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('T')) sup.appendChild(mo) return sup def _print_Inverse(self, expr): from sympy.matrices import MatrixSymbol mat = expr.arg sup = self.dom.createElement('msup') if not isinstance(mat, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(mat)) sup.appendChild(brac) else: sup.appendChild(self._print(mat)) sup.appendChild(self._print(-1)) return sup def _print_MatMul(self, expr): from sympy import MatMul x = self.dom.createElement('mrow') args = expr.args if isinstance(args[0], Mul): args = args[0].as_ordered_factors() + list(args[1:]) else: args = list(args) if isinstance(expr, MatMul) and _coeff_isneg(expr): if args[0] == -1: args = args[1:] else: args[0] = -args[0] mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('-')) x.appendChild(mo) for arg in args[:-1]: x.appendChild(self.parenthesize(arg, precedence_traditional(expr), False)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('⁢')) x.appendChild(mo) x.appendChild(self.parenthesize(args[-1], precedence_traditional(expr), False)) return x def _print_MatPow(self, expr): from sympy.matrices import MatrixSymbol base, exp = expr.base, expr.exp sup = self.dom.createElement('msup') if not isinstance(base, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(base)) sup.appendChild(brac) else: sup.appendChild(self._print(base)) sup.appendChild(self._print(exp)) return sup def _print_HadamardProduct(self, expr): x = self.dom.createElement('mrow') args = expr.args for arg in args[:-1]: x.appendChild( self.parenthesize(arg, precedence_traditional(expr), False)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∘')) x.appendChild(mo) x.appendChild( self.parenthesize(args[-1], precedence_traditional(expr), False)) return x def _print_ZeroMatrix(self, Z): x = self.dom.createElement('mn') x.appendChild(self.dom.createTextNode('&#x1D7D8')) return x def _print_Identity(self, I): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('𝕀')) return x def _print_floor(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') x.setAttribute('open', u'\u230A') x.setAttribute('close', u'\u230B') x.appendChild(self._print(e.args[0])) mrow.appendChild(x) return mrow def _print_ceiling(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') x.setAttribute('open', u'\u2308') x.setAttribute('close', u'\u2309') x.appendChild(self._print(e.args[0])) mrow.appendChild(x) return mrow def _print_Lambda(self, e): x = self.dom.createElement('mfenced') mrow = self.dom.createElement('mrow') symbols = e.args[0] if len(symbols) == 1: symbols = self._print(symbols[0]) else: symbols = self._print(symbols) mrow.appendChild(symbols) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('↦')) mrow.appendChild(mo) mrow.appendChild(self._print(e.args[1])) x.appendChild(mrow) return x def _print_tuple(self, e): x = self.dom.createElement('mfenced') for i in e: x.appendChild(self._print(i)) return x def _print_IndexedBase(self, e): return self._print(e.label) def _print_Indexed(self, e): x = self.dom.createElement('msub') x.appendChild(self._print(e.base)) if len(e.indices) == 1: x.appendChild(self._print(e.indices[0])) return x x.appendChild(self._print(e.indices)) return x def _print_MatrixElement(self, e): x = self.dom.createElement('msub') x.appendChild(self.parenthesize(e.parent, PRECEDENCE["Atom"], strict = True)) brac = self.dom.createElement('mfenced') brac.setAttribute("open", "") brac.setAttribute("close", "") for i in e.indices: brac.appendChild(self._print(i)) x.appendChild(brac) return x def _print_elliptic_f(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('𝖥')) x.appendChild(mi) y = self.dom.createElement('mfenced') y.setAttribute("separators", "\|") for i in e.args: y.appendChild(self._print(i)) x.appendChild(y) return x def _print_elliptic_e(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('𝖤')) x.appendChild(mi) y = self.dom.createElement('mfenced') y.setAttribute("separators", "\|") for i in e.args: y.appendChild(self._print(i)) x.appendChild(y) return x def _print_elliptic_pi(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('𝛱')) x.appendChild(mi) y = self.dom.createElement('mfenced') if len(e.args) == 2: y.setAttribute("separators", "\|") else: y.setAttribute("separators", ";\|") for i in e.args: y.appendChild(self._print(i)) x.appendChild(y) return x def _print_Ei(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('Ei')) x.appendChild(mi) x.appendChild(self._print(e.args)) return x def _print_expint(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('E')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_jacobi(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('P')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:3])) x.appendChild(y) x.appendChild(self._print(e.args[3:])) return x def _print_gegenbauer(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('C')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:2])) x.appendChild(y) x.appendChild(self._print(e.args[2:])) return x def _print_chebyshevt(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('T')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_chebyshevu(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('U')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_legendre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('P')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_assoc_legendre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('P')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:2])) x.appendChild(y) x.appendChild(self._print(e.args[2:])) return x def _print_laguerre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('L')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_assoc_laguerre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('L')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:2])) x.appendChild(y) x.appendChild(self._print(e.args[2:])) return x def _print_hermite(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('H')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def mathml(expr, printer='content', settings): """Returns the MathML representation of expr. If printer is presentation then prints Presentation MathML else prints content MathML. """ if printer == 'presentation': return MathMLPresentationPrinter(settings).doprint(expr) else: return MathMLContentPrinter(settings).doprint(expr) def print_mathml(expr, printer='content', settings): """ Prints a pretty representation of the MathML code for expr. If printer is presentation then prints Presentation MathML else prints content MathML. Examples ======== >>> ## >>> from sympy.printing.mathml import print_mathml >>> from sympy.abc import x >>> print_mathml(x+1) #doctest: +NORMALIZE_WHITESPACE <apply> <plus/> <ci>x</ci> <cn>1</cn> </apply> >>> print_mathml(x+1, printer='presentation') <mrow> <mi>x</mi> <mo>+</mo> <mn>1</mn> </mrow> """ if printer == 'presentation': s = MathMLPresentationPrinter(settings) else: s = MathMLContentPrinter(settings) xml = s._print(sympify(expr)) s.apply_patch() pretty_xml = xml.toprettyxml() s.restore_patch() print(pretty_xml) # For backward compatibility MathMLPrinter = MathMLContentPrinter
4a9c327ae46a20766719575a47f423463e88e9d4b4bb2e478e6063fa365db895	from __future__ import print_function, division from functools import wraps from sympy.core import Add, Mul, Pow, S, sympify, Float from sympy.core.basic import Basic from sympy.core.compatibility import default_sort_key, string_types from sympy.core.function import Lambda from sympy.core.mul import _keep_coeff from sympy.core.symbol import Symbol from sympy.printing.str import StrPrinter from sympy.printing.precedence import precedence # Backwards compatibility from sympy.codegen.ast import Assignment class requires(object): """ Decorator for registering requirements on print methods. """ def __init__(self, *kwargs): self._req = kwargs def __call__(self, method): def _method_wrapper(self_, args, *kwargs): for k, v in self._req.items(): getattr(self_, k).update(v) return method(self_, args, *kwargs) return wraps(method)(_method_wrapper) class AssignmentError(Exception): """ Raised if an assignment variable for a loop is missing. """ pass class CodePrinter(StrPrinter): """ The base class for code-printing subclasses. """ _operators = { 'and': '&&', 'or': '\|\|', 'not': '!', } _default_settings = { 'order': None, 'full_prec': 'auto', 'error_on_reserved': False, 'reserved_word_suffix': '_', 'human': True, 'inline': False, 'allow_unknown_functions': False, } def __init__(self, settings=None): super(CodePrinter, self).__init__(settings=settings) if not hasattr(self, 'reserved_words'): self.reserved_words = set() def doprint(self, expr, assign_to=None): """ Print the expression as code. Parameters ---------- expr : Expression The expression to be printed. assign_to : Symbol, MatrixSymbol, or string (optional) If provided, the printed code will set the expression to a variable with name ``assign_to``. """ from sympy.matrices.expressions.matexpr import MatrixSymbol if isinstance(assign_to, string_types): if expr.is_Matrix: assign_to = MatrixSymbol(assign_to, expr.shape) else: assign_to = Symbol(assign_to) elif not isinstance(assign_to, (Basic, type(None))): raise TypeError("{0} cannot assign to object of type {1}".format( type(self).__name__, type(assign_to))) if assign_to: expr = Assignment(assign_to, expr) else: # _sympify is not enough b/c it errors on iterables expr = sympify(expr) # keep a set of expressions that are not strictly translatable to Code # and number constants that must be declared and initialized self._not_supported = set() self._number_symbols = set() lines = self._print(expr).splitlines() # format the output if self._settings["human"]: frontlines = [] if self._not_supported: frontlines.append(self._get_comment( "Not supported in {0}:".format(self.language))) for expr in sorted(self._not_supported, key=str): frontlines.append(self._get_comment(type(expr).__name__)) for name, value in sorted(self._number_symbols, key=str): frontlines.append(self._declare_number_const(name, value)) lines = frontlines + lines lines = self._format_code(lines) result = "\n".join(lines) else: lines = self._format_code(lines) num_syms = set([(k, self._print(v)) for k, v in self._number_symbols]) result = (num_syms, self._not_supported, "\n".join(lines)) self._not_supported = set() self._number_symbols = set() return result def _doprint_loops(self, expr, assign_to=None): # Here we print an expression that contains Indexed objects, they # correspond to arrays in the generated code. The low-level implementation # involves looping over array elements and possibly storing results in temporary # variables or accumulate it in the assign_to object. if self._settings.get('contract', True): from sympy.tensor import get_contraction_structure # Setup loops over non-dummy indices -- all terms need these indices = self._get_expression_indices(expr, assign_to) # Setup loops over dummy indices -- each term needs separate treatment dummies = get_contraction_structure(expr) else: indices = [] dummies = {None: (expr,)} openloop, closeloop = self._get_loop_opening_ending(indices) # terms with no summations first if None in dummies: text = StrPrinter.doprint(self, Add(dummies[None])) else: # If all terms have summations we must initialize array to Zero text = StrPrinter.doprint(self, 0) # skip redundant assignments (where lhs == rhs) lhs_printed = self._print(assign_to) lines = [] if text != lhs_printed: lines.extend(openloop) if assign_to is not None: text = self._get_statement("%s = %s" % (lhs_printed, text)) lines.append(text) lines.extend(closeloop) # then terms with summations for d in dummies: if isinstance(d, tuple): indices = self._sort_optimized(d, expr) openloop_d, closeloop_d = self._get_loop_opening_ending( indices) for term in dummies[d]: if term in dummies and not ([list(f.keys()) for f in dummies[term]] == [[None] for f in dummies[term]]): # If one factor in the term has it's own internal # contractions, those must be computed first. # (temporary variables?) raise NotImplementedError( "FIXME: no support for contractions in factor yet") else: # We need the lhs expression as an accumulator for # the loops, i.e # # for (int d=0; d < dim; d++){ # lhs[] = lhs[] + term[][d] # } ^.................. the accumulator # # We check if the expression already contains the # lhs, and raise an exception if it does, as that # syntax is currently undefined. FIXME: What would be # a good interpretation? if assign_to is None: raise AssignmentError( "need assignment variable for loops") if term.has(assign_to): raise ValueError("FIXME: lhs present in rhs,\ this is undefined in CodePrinter") lines.extend(openloop) lines.extend(openloop_d) text = "%s = %s" % (lhs_printed, StrPrinter.doprint( self, assign_to + term)) lines.append(self._get_statement(text)) lines.extend(closeloop_d) lines.extend(closeloop) return "\n".join(lines) def _get_expression_indices(self, expr, assign_to): from sympy.tensor import get_indices rinds, junk = get_indices(expr) linds, junk = get_indices(assign_to) # support broadcast of scalar if linds and not rinds: rinds = linds if rinds != linds: raise ValueError("lhs indices must match non-dummy" " rhs indices in %s" % expr) return self._sort_optimized(rinds, assign_to) def _sort_optimized(self, indices, expr): from sympy.tensor.indexed import Indexed if not indices: return [] # determine optimized loop order by giving a score to each index # the index with the highest score are put in the innermost loop. score_table = {} for i in indices: score_table[i] = 0 arrays = expr.atoms(Indexed) for arr in arrays: for p, ind in enumerate(arr.indices): try: score_table[ind] += self._rate_index_position(p) except KeyError: pass return sorted(indices, key=lambda x: score_table[x]) def _rate_index_position(self, p): """function to calculate score based on position among indices This method is used to sort loops in an optimized order, see CodePrinter._sort_optimized() """ raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _get_statement(self, codestring): """Formats a codestring with the proper line ending.""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _get_comment(self, text): """Formats a text string as a comment.""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _declare_number_const(self, name, value): """Declare a numeric constant at the top of a function""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _format_code(self, lines): """Take in a list of lines of code, and format them accordingly. This may include indenting, wrapping long lines, etc...""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _get_loop_opening_ending(self, indices): """Returns a tuple (open_lines, close_lines) containing lists of codelines""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _print_Dummy(self, expr): if expr.name.startswith('Dummy_'): return '_' + expr.name else: return '%s_%d' % (expr.name, expr.dummy_index) def _print_CodeBlock(self, expr): return '\n'.join([self._print(i) for i in expr.args]) def _print_String(self, string): return str(string) def _print_QuotedString(self, arg): return '"%s"' % arg.text def _print_Comment(self, string): return self._get_comment(str(string)) def _print_Assignment(self, expr): from sympy.functions.elementary.piecewise import Piecewise from sympy.matrices.expressions.matexpr import MatrixSymbol from sympy.tensor.indexed import IndexedBase lhs = expr.lhs rhs = expr.rhs # We special case assignments that take multiple lines if isinstance(expr.rhs, Piecewise): # Here we modify Piecewise so each expression is now # an Assignment, and then continue on the print. expressions = [] conditions = [] for (e, c) in rhs.args: expressions.append(Assignment(lhs, e)) conditions.append(c) temp = Piecewise(zip(expressions, conditions)) return self._print(temp) elif isinstance(lhs, MatrixSymbol): # Here we form an Assignment for each element in the array, # printing each one. lines = [] for (i, j) in self._traverse_matrix_indices(lhs): temp = Assignment(lhs[i, j], rhs[i, j]) code0 = self._print(temp) lines.append(code0) return "\n".join(lines) elif self._settings.get("contract", False) and (lhs.has(IndexedBase) or rhs.has(IndexedBase)): # Here we check if there is looping to be done, and if so # print the required loops. return self._doprint_loops(rhs, lhs) else: lhs_code = self._print(lhs) rhs_code = self._print(rhs) return self._get_statement("%s = %s" % (lhs_code, rhs_code)) def _print_AugmentedAssignment(self, expr): lhs_code = self._print(expr.lhs) rhs_code = self._print(expr.rhs) return self._get_statement("{0} {1} {2}".format( map(lambda arg: self._print(arg), [lhs_code, expr.op, rhs_code]))) def _print_FunctionCall(self, expr): return '%s(%s)' % ( expr.name, ', '.join(map(lambda arg: self._print(arg), expr.function_args))) def _print_Variable(self, expr): return self._print(expr.symbol) def _print_Statement(self, expr): arg, = expr.args return self._get_statement(self._print(arg)) def _print_Symbol(self, expr): name = super(CodePrinter, self)._print_Symbol(expr) if name in self.reserved_words: if self._settings['error_on_reserved']: msg = ('This expression includes the symbol "{}" which is a ' 'reserved keyword in this language.') raise ValueError(msg.format(name)) return name + self._settings['reserved_word_suffix'] else: return name def _print_Function(self, expr): if expr.func.__name__ in self.known_functions: cond_func = self.known_functions[expr.func.__name__] func = None if isinstance(cond_func, string_types): func = cond_func else: for cond, func in cond_func: if cond(expr.args): break if func is not None: try: return func([self.parenthesize(item, 0) for item in expr.args]) except TypeError: return "%s(%s)" % (func, self.stringify(expr.args, ", ")) elif hasattr(expr, '_imp_') and isinstance(expr._imp_, Lambda): # inlined function return self._print(expr._imp_(expr.args)) elif expr.is_Function and self._settings.get('allow_unknown_functions', False): return '%s(%s)' % (self._print(expr.func), ', '.join(map(self._print, expr.args))) else: return self._print_not_supported(expr) _print_Expr = _print_Function def _print_NumberSymbol(self, expr): if self._settings.get("inline", False): return self._print(Float(expr.evalf(self._settings["precision"]))) else: # A Number symbol that is not implemented here or with _printmethod # is registered and evaluated self._number_symbols.add((expr, Float(expr.evalf(self._settings["precision"])))) return str(expr) def _print_Catalan(self, expr): return self._print_NumberSymbol(expr) def _print_EulerGamma(self, expr): return self._print_NumberSymbol(expr) def _print_GoldenRatio(self, expr): return self._print_NumberSymbol(expr) def _print_TribonacciConstant(self, expr): return self._print_NumberSymbol(expr) def _print_Exp1(self, expr): return self._print_NumberSymbol(expr) def _print_Pi(self, expr): return self._print_NumberSymbol(expr) def _print_And(self, expr): PREC = precedence(expr) return (" %s " % self._operators['and']).join(self.parenthesize(a, PREC) for a in sorted(expr.args, key=default_sort_key)) def _print_Or(self, expr): PREC = precedence(expr) return (" %s " % self._operators['or']).join(self.parenthesize(a, PREC) for a in sorted(expr.args, key=default_sort_key)) def _print_Xor(self, expr): if self._operators.get('xor') is None: return self._print_not_supported(expr) PREC = precedence(expr) return (" %s " % self._operators['xor']).join(self.parenthesize(a, PREC) for a in expr.args) def _print_Equivalent(self, expr): if self._operators.get('equivalent') is None: return self._print_not_supported(expr) PREC = precedence(expr) return (" %s " % self._operators['equivalent']).join(self.parenthesize(a, PREC) for a in expr.args) def _print_Not(self, expr): PREC = precedence(expr) return self._operators['not'] + self.parenthesize(expr.args[0], PREC) def _print_Mul(self, expr): prec = precedence(expr) c, e = expr.as_coeff_Mul() if c < 0: expr = _keep_coeff(-c, e) sign = "-" else: sign = "" a = [] # items in the numerator b = [] # items that are in the denominator (if any) pow_paren = [] # Will collect all pow with more than one base element and exp = -1 if self.order not in ('old', 'none'): args = expr.as_ordered_factors() else: # use make_args in case expr was something like -x -> x args = Mul.make_args(expr) # Gather args for numerator/denominator for item in args: if item.is_commutative and item.is_Pow and item.exp.is_Rational and item.exp.is_negative: if item.exp != -1: b.append(Pow(item.base, -item.exp, evaluate=False)) else: if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 pow_paren.append(item) b.append(Pow(item.base, -item.exp)) else: a.append(item) a = a or [S.One] a_str = [self.parenthesize(x, prec) for x in a] b_str = [self.parenthesize(x, prec) for x in b] # To parenthesize Pow with exp = -1 and having more than one Symbol for item in pow_paren: if item.base in b: b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] if not b: return sign + ''.join(a_str) elif len(b) == 1: return sign + ''.join(a_str) + "/" + b_str[0] else: return sign + ''.join(a_str) + "/(%s)" % ''.join(b_str) def _print_not_supported(self, expr): self._not_supported.add(expr) return self.emptyPrinter(expr) # The following can not be simply translated into C or Fortran _print_Basic = _print_not_supported _print_ComplexInfinity = _print_not_supported _print_Derivative = _print_not_supported _print_ExprCondPair = _print_not_supported _print_GeometryEntity = _print_not_supported _print_Infinity = _print_not_supported _print_Integral = _print_not_supported _print_Interval = _print_not_supported _print_AccumulationBounds = _print_not_supported _print_Limit = _print_not_supported _print_Matrix = _print_not_supported _print_ImmutableMatrix = _print_not_supported _print_ImmutableDenseMatrix = _print_not_supported _print_MutableDenseMatrix = _print_not_supported _print_MatrixBase = _print_not_supported _print_DeferredVector = _print_not_supported _print_NaN = _print_not_supported _print_NegativeInfinity = _print_not_supported _print_Order = _print_not_supported _print_RootOf = _print_not_supported _print_RootsOf = _print_not_supported _print_RootSum = _print_not_supported _print_SparseMatrix = _print_not_supported _print_MutableSparseMatrix = _print_not_supported _print_ImmutableSparseMatrix = _print_not_supported _print_Uniform = _print_not_supported _print_Unit = _print_not_supported _print_Wild = _print_not_supported _print_WildFunction = _print_not_supported
84867b6d09f7a0b62c4ed4ecf063df960f5f1e5df9a6d7d1a3ad55ca8b81e9f9	from __future__ import print_function, division from sympy.core.compatibility import range, is_sequence from sympy.external import import_module from sympy.printing.printer import Printer import sympy from functools import partial theano = import_module('theano') if theano: ts = theano.scalar tt = theano.tensor from theano.sandbox import linalg as tlinalg mapping = { sympy.Add: tt.add, sympy.Mul: tt.mul, sympy.Abs: tt.abs_, sympy.sign: tt.sgn, sympy.ceiling: tt.ceil, sympy.floor: tt.floor, sympy.log: tt.log, sympy.exp: tt.exp, sympy.sqrt: tt.sqrt, sympy.cos: tt.cos, sympy.acos: tt.arccos, sympy.sin: tt.sin, sympy.asin: tt.arcsin, sympy.tan: tt.tan, sympy.atan: tt.arctan, sympy.atan2: tt.arctan2, sympy.cosh: tt.cosh, sympy.acosh: tt.arccosh, sympy.sinh: tt.sinh, sympy.asinh: tt.arcsinh, sympy.tanh: tt.tanh, sympy.atanh: tt.arctanh, sympy.re: tt.real, sympy.im: tt.imag, sympy.arg: tt.angle, sympy.erf: tt.erf, sympy.gamma: tt.gamma, sympy.loggamma: tt.gammaln, sympy.Pow: tt.pow, sympy.Eq: tt.eq, sympy.StrictGreaterThan: tt.gt, sympy.StrictLessThan: tt.lt, sympy.LessThan: tt.le, sympy.GreaterThan: tt.ge, sympy.And: tt.and_, sympy.Or: tt.or_, sympy.Max: tt.maximum, # Sympy accept >2 inputs, Theano only 2 sympy.Min: tt.minimum, # Sympy accept >2 inputs, Theano only 2 sympy.conjugate: tt.conj, sympy.numbers.ImaginaryUnit: lambda:tt.complex(0,1), # Matrices sympy.MatAdd: tt.Elemwise(ts.add), sympy.HadamardProduct: tt.Elemwise(ts.mul), sympy.Trace: tlinalg.trace, sympy.Determinant : tlinalg.det, sympy.Inverse: tlinalg.matrix_inverse, sympy.Transpose: tt.DimShuffle((False, False), [1, 0]), } class TheanoPrinter(Printer): """ Code printer which creates Theano symbolic expression graphs. Parameters ========== cache : dict Cache dictionary to use (see :attr:`cache`). If None (default) will use the global cache. To create a printer which does not depend on or alter global state pass an empty dictionary. Note: the dictionary is not copied on initialization of the printer and will be updated in-place, so using the same dict object when creating multiple printers or making multiple calls to :func:`.theano_code` or :func:`.theano_function` means the cache is shared between all these applications. Attributes ========== cache : dict A cache of Theano variables which have been created for Sympy symbol-like objects (e.g. :class:`sympy.core.symbol.Symbol` or :class:`sympy.matrices.expressions.MatrixSymbol`). This is used to ensure that all references to a given symbol in an expression (or multiple expressions) are printed as the same Theano variable, which is created only once. Symbols are differentiated only by name and type. The format of the cache's contents should be considered opaque to the user. """ printmethod = "_theano" def __init__(self, args, kwargs): self.cache = kwargs.pop('cache', dict()) super(TheanoPrinter, self).__init__(args, kwargs) def _get_key(self, s, name=None, dtype=None, broadcastable=None): """ Get the cache key for a Sympy object. Parameters ========== s : sympy.core.basic.Basic Sympy object to get key for. name : str Name of object, if it does not have a ``name`` attribute. """ if name is None: name = s.name return (name, type(s), s.args, dtype, broadcastable) def _get_or_create(self, s, name=None, dtype=None, broadcastable=None): """ Get the Theano variable for a Sympy symbol from the cache, or create it if it does not exist. """ # Defaults if name is None: name = s.name if dtype is None: dtype = 'floatX' if broadcastable is None: broadcastable = () key = self._get_key(s, name, dtype=dtype, broadcastable=broadcastable) if key in self.cache: return self.cache[key] value = tt.tensor(name=name, dtype=dtype, broadcastable=broadcastable) self.cache[key] = value return value def _print_Symbol(self, s, kwargs): dtype = kwargs.get('dtypes', {}).get(s) bc = kwargs.get('broadcastables', {}).get(s) return self._get_or_create(s, dtype=dtype, broadcastable=bc) def _print_AppliedUndef(self, s, kwargs): name = str(type(s)) + '_' + str(s.args[0]) dtype = kwargs.get('dtypes', {}).get(s) bc = kwargs.get('broadcastables', {}).get(s) return self._get_or_create(s, name=name, dtype=dtype, broadcastable=bc) def _print_Basic(self, expr, kwargs): op = mapping[type(expr)] children = [self._print(arg, *kwargs) for arg in expr.args] return op(children) def _print_Number(self, n, kwargs): # Integers already taken care of below, interpret as float return float(n.evalf()) def _print_MatrixSymbol(self, X, kwargs): dtype = kwargs.get('dtypes', {}).get(X) return self._get_or_create(X, dtype=dtype, broadcastable=(None, None)) def _print_DenseMatrix(self, X, kwargs): if not hasattr(tt, 'stacklists'): raise NotImplementedError( "Matrix translation not yet supported in this version of Theano") return tt.stacklists([ [self._print(arg, kwargs) for arg in L] for L in X.tolist() ]) _print_ImmutableMatrix = _print_ImmutableDenseMatrix = _print_DenseMatrix def _print_MatMul(self, expr, kwargs): children = [self._print(arg, kwargs) for arg in expr.args] result = children[0] for child in children[1:]: result = tt.dot(result, child) return result def _print_MatPow(self, expr, kwargs): children = [self._print(arg, kwargs) for arg in expr.args] result = 1 if isinstance(children[1], int) and children[1] > 0: for i in range(children[1]): result = tt.dot(result, children[0]) else: raise NotImplementedError('''Only non-negative integer powers of matrices can be handled by Theano at the moment''') return result def _print_MatrixSlice(self, expr, kwargs): parent = self._print(expr.parent, kwargs) rowslice = self._print(slice(expr.rowslice), kwargs) colslice = self._print(slice(expr.colslice), kwargs) return parent[rowslice, colslice] def _print_BlockMatrix(self, expr, kwargs): nrows, ncols = expr.blocks.shape blocks = [[self._print(expr.blocks[r, c], *kwargs) for c in range(ncols)] for r in range(nrows)] return tt.join(0, [tt.join(1, row) for row in blocks]) def _print_slice(self, expr, kwargs): return slice([self._print(i, kwargs) if isinstance(i, sympy.Basic) else i for i in (expr.start, expr.stop, expr.step)]) def _print_Pi(self, expr, kwargs): return 3.141592653589793 def _print_Piecewise(self, expr, kwargs): import numpy as np e, cond = expr.args[0].args # First condition and corresponding value # Print conditional expression and value for first condition p_cond = self._print(cond, kwargs) p_e = self._print(e, *kwargs) # One condition only if len(expr.args) == 1: # Return value if condition else NaN return tt.switch(p_cond, p_e, np.nan) # Return value_1 if condition_1 else evaluate remaining conditions p_remaining = self._print(sympy.Piecewise(expr.args[1:]), kwargs) return tt.switch(p_cond, p_e, p_remaining) def _print_Rational(self, expr, kwargs): return tt.true_div(self._print(expr.p, kwargs), self._print(expr.q, kwargs)) def _print_Integer(self, expr, kwargs): return expr.p def _print_factorial(self, expr, kwargs): return self._print(sympy.gamma(expr.args[0] + 1), kwargs) def _print_Derivative(self, deriv, kwargs): rv = self._print(deriv.expr, kwargs) for var in deriv.variables: var = self._print(var, kwargs) rv = tt.Rop(rv, var, tt.ones_like(var)) return rv def emptyPrinter(self, expr): return expr def doprint(self, expr, dtypes=None, broadcastables=None): """ Convert a Sympy expression to a Theano graph variable. The ``dtypes`` and ``broadcastables`` arguments are used to specify the data type, dimension, and broadcasting behavior of the Theano variables corresponding to the free symbols in ``expr``. Each is a mapping from Sympy symbols to the value of the corresponding argument to :func:`theano.tensor.Tensor`. See the corresponding `documentation page`__ for more information on broadcasting in Theano. .. __: http://deeplearning.net/software/theano/tutorial/broadcasting.html Parameters ========== expr : sympy.core.expr.Expr Sympy expression to print. dtypes : dict Mapping from Sympy symbols to Theano datatypes to use when creating new Theano variables for those symbols. Corresponds to the ``dtype`` argument to :func:`theano.tensor.Tensor`. Defaults to ``'floatX'`` for symbols not included in the mapping. broadcastables : dict Mapping from Sympy symbols to the value of the ``broadcastable`` argument to :func:`theano.tensor.Tensor` to use when creating Theano variables for those symbols. Defaults to the empty tuple for symbols not included in the mapping (resulting in a scalar). Returns ======= theano.gof.graph.Variable A variable corresponding to the expression's value in a Theano symbolic expression graph. See Also ======== theano.tensor.Tensor """ if dtypes is None: dtypes = {} if broadcastables is None: broadcastables = {} return self._print(expr, dtypes=dtypes, broadcastables=broadcastables) global_cache = {} def theano_code(expr, cache=None, kwargs): """ Convert a Sympy expression into a Theano graph variable. Parameters ========== expr : sympy.core.expr.Expr Sympy expression object to convert. cache : dict Cached Theano variables (see :attr:`.TheanoPrinter.cache`). Defaults to the module-level global cache. dtypes : dict Passed to :meth:`.TheanoPrinter.doprint`. broadcastables : dict Passed to :meth:`.TheanoPrinter.doprint`. Returns ======= theano.gof.graph.Variable A variable corresponding to the expression's value in a Theano symbolic expression graph. """ if not theano: raise ImportError("theano is required for theano_code") if cache is None: cache = global_cache return TheanoPrinter(cache=cache, settings={}).doprint(expr, kwargs) def dim_handling(inputs, dim=None, dims=None, broadcastables=None): """ Get value of ``broadcastables`` argument to :func:`.theano_code` from keyword arguments to :func:`.theano_function`. Included for backwards compatibility. Parameters ========== inputs Sequence of input symbols. dim : int Common number of dimensions for all inputs. Overrides other arguments if given. dims : dict Mapping from input symbols to number of dimensions. Overrides ``broadcastables`` argument if given. broadcastables : dict Explicit value of ``broadcastables`` argument to :meth:`.TheanoPrinter.doprint`. If not None function will return this value unchanged. Returns ======= dict Dictionary mapping elements of ``inputs`` to their "broadcastable" values (tuple of ``bool``s). """ if dim is not None: return {s: (False,) * dim for s in inputs} if dims is not None: maxdim = max(dims.values()) return { s: (False,) * d + (True,) * (maxdim - d) for s, d in dims.items() } if broadcastables is not None: return broadcastables return {} def theano_function(inputs, outputs, scalar=False, kwargs): """ Create a Theano function from SymPy expressions. The inputs and outputs are converted to Theano variables using :func:`.theano_code` and then passed to :func:`theano.function`. Parameters ========== inputs Sequence of symbols which constitute the inputs of the function. outputs Sequence of expressions which constitute the outputs(s) of the function. The free symbols of each expression must be a subset of ``inputs``. scalar : bool Convert 0-dimensional arrays in output to scalars. This will return a Python wrapper function around the Theano function object. cache : dict Cached Theano variables (see :attr:`.TheanoPrinter.cache`). Defaults to the module-level global cache. dtypes : dict Passed to :meth:`.TheanoPrinter.doprint`. broadcastables : dict Passed to :meth:`.TheanoPrinter.doprint`. dims : dict Alternative to ``broadcastables`` argument. Mapping from elements of ``inputs`` to integers indicating the dimension of their associated arrays/tensors. Overrides ``broadcastables`` argument if given. dim : int Another alternative to the ``broadcastables`` argument. Common number of dimensions to use for all arrays/tensors. ``theano_function([x, y], [...], dim=2)`` is equivalent to using ``broadcastables={x: (False, False), y: (False, False)}``. Returns ======= callable A callable object which takes values of ``inputs`` as positional arguments and returns an output array for each of the expressions in ``outputs``. If ``outputs`` is a single expression the function will return a Numpy array, if it is a list of multiple expressions the function will return a list of arrays. See description of the ``squeeze`` argument above for the behavior when a single output is passed in a list. The returned object will either be an instance of :class:`theano.compile.function_module.Function` or a Python wrapper function around one. In both cases, the returned value will have a ``theano_function`` attribute which points to the return value of :func:`theano.function`. Examples ======== >>> from sympy.abc import x, y, z >>> from sympy.printing.theanocode import theano_function A simple function with one input and one output: >>> f1 = theano_function([x], [x2 - 1], scalar=True) >>> f1(3) 8.0 A function with multiple inputs and one output: >>> f2 = theano_function([x, y, z], [(xz + yz)(1/z)], scalar=True) >>> f2(3, 4, 2) 5.0 A function with multiple inputs and multiple outputs: >>> f3 = theano_function([x, y], [x2 + y2, x2 - y2], scalar=True) >>> f3(2, 3) [13.0, -5.0] See also ======== theano.function dim_handling """ if not theano: raise ImportError("theano is required for theano_function") # Pop off non-theano keyword args cache = kwargs.pop('cache', {}) dtypes = kwargs.pop('dtypes', {}) broadcastables = dim_handling( inputs, dim=kwargs.pop('dim', None), dims=kwargs.pop('dims', None), broadcastables=kwargs.pop('broadcastables', None), ) # Print inputs/outputs code = partial(theano_code, cache=cache, dtypes=dtypes, broadcastables=broadcastables) tinputs = list(map(code, inputs)) toutputs = list(map(code, outputs)) #fix constant expressions as variables toutputs = [output if isinstance(output, theano.Variable) else tt.as_tensor_variable(output) for output in toutputs] if len(toutputs) == 1: toutputs = toutputs[0] # Compile theano func func = theano.function(tinputs, toutputs, kwargs) is_0d = [len(o.variable.broadcastable) == 0 for o in func.outputs] # No wrapper required if not scalar or not any(is_0d): func.theano_function = func return func # Create wrapper to convert 0-dimensional outputs to scalars def wrapper(args): out = func(args) # out can be array(1.0) or [array(1.0), array(2.0)] if is_sequence(out): return [o[()] if is_0d[i] else o for i, o in enumerate(out)] else: return out[()] wrapper.__wrapped__ = func wrapper.__doc__ = func.__doc__ wrapper.theano_function = func return wrapper
40669f6e7e4759a0b1f825b8caee86c79f52809237f597fbd5bd2fcf562a0a5c	from __future__ import print_function, division from sympy.concrete.expr_with_limits import AddWithLimits from sympy.core.add import Add from sympy.core.basic import Basic from sympy.core.compatibility import is_sequence from sympy.core.containers import Tuple from sympy.core.expr import Expr from sympy.core.function import diff from sympy.core.mul import Mul from sympy.core.numbers import oo, pi from sympy.core.relational import Ne from sympy.core.singleton import S from sympy.core.symbol import (Dummy, Symbol, Wild) from sympy.core.sympify import sympify from sympy.functions import Piecewise, sqrt, piecewise_fold, tan, cot, atan from sympy.functions.elementary.exponential import log from sympy.functions.elementary.integers import floor from sympy.functions.elementary.complexes import Abs, sign from sympy.functions.elementary.miscellaneous import Min, Max from sympy.integrals.manualintegrate import manualintegrate from sympy.integrals.trigonometry import trigintegrate from sympy.integrals.meijerint import meijerint_definite, meijerint_indefinite from sympy.matrices import MatrixBase from sympy.polys import Poly, PolynomialError from sympy.series import limit from sympy.series.order import Order from sympy.series.formal import FormalPowerSeries from sympy.simplify.fu import sincos_to_sum from sympy.utilities.misc import filldedent class Integral(AddWithLimits): """Represents unevaluated integral.""" __slots__ = ['is_commutative'] def __new__(cls, function, symbols, assumptions): """Create an unevaluated integral. Arguments are an integrand followed by one or more limits. If no limits are given and there is only one free symbol in the expression, that symbol will be used, otherwise an error will be raised. >>> from sympy import Integral >>> from sympy.abc import x, y >>> Integral(x) Integral(x, x) >>> Integral(y) Integral(y, y) When limits are provided, they are interpreted as follows (using ``x`` as though it were the variable of integration): (x,) or x - indefinite integral (x, a) - "evaluate at" integral is an abstract antiderivative (x, a, b) - definite integral The ``as_dummy`` method can be used to see which symbols cannot be targeted by subs: those with a preppended underscore cannot be changed with ``subs``. (Also, the integration variables themselves -- the first element of a limit -- can never be changed by subs.) >>> i = Integral(x, x) >>> at = Integral(x, (x, x)) >>> i.as_dummy() Integral(x, x) >>> at.as_dummy() Integral(_0, (_0, x)) """ #This will help other classes define their own definitions #of behaviour with Integral. if hasattr(function, '_eval_Integral'): return function._eval_Integral(symbols, *assumptions) obj = AddWithLimits.__new__(cls, function, symbols, *assumptions) return obj def __getnewargs__(self): return (self.function,) + tuple([tuple(xab) for xab in self.limits]) @property def free_symbols(self): """ This method returns the symbols that will exist when the integral is evaluated. This is useful if one is trying to determine whether an integral depends on a certain symbol or not. Examples ======== >>> from sympy import Integral >>> from sympy.abc import x, y >>> Integral(x, (x, y, 1)).free_symbols {y} See Also ======== function, limits, variables """ return AddWithLimits.free_symbols.fget(self) def _eval_is_zero(self): # This is a very naive and quick test, not intended to do the integral to # answer whether it is zero or not, e.g. Integral(sin(x), (x, 0, 2pi)) # is zero but this routine should return None for that case. But, like # Mul, there are trivial situations for which the integral will be # zero so we check for those. if self.function.is_zero: return True got_none = False for l in self.limits: if len(l) == 3: z = (l[1] == l[2]) or (l[1] - l[2]).is_zero if z: return True elif z is None: got_none = True free = self.function.free_symbols for xab in self.limits: if len(xab) == 1: free.add(xab[0]) continue if len(xab) == 2 and xab[0] not in free: if xab[1].is_zero: return True elif xab[1].is_zero is None: got_none = True # take integration symbol out of free since it will be replaced # with the free symbols in the limits free.discard(xab[0]) # add in the new symbols for i in xab[1:]: free.update(i.free_symbols) if self.function.is_zero is False and got_none is False: return False def transform(self, x, u): r""" Performs a change of variables from `x` to `u` using the relationship given by `x` and `u` which will define the transformations `f` and `F` (which are inverses of each other) as follows: 1) If `x` is a Symbol (which is a variable of integration) then `u` will be interpreted as some function, f(u), with inverse F(u). This, in effect, just makes the substitution of x with f(x). 2) If `u` is a Symbol then `x` will be interpreted as some function, F(x), with inverse f(u). This is commonly referred to as u-substitution. Once f and F have been identified, the transformation is made as follows: .. math:: \int_a^b x \mathrm{d}x \rightarrow \int_{F(a)}^{F(b)} f(x) \frac{\mathrm{d}}{\mathrm{d}x} where `F(x)` is the inverse of `f(x)` and the limits and integrand have been corrected so as to retain the same value after integration. Notes ===== The mappings, F(x) or f(u), must lead to a unique integral. Linear or rational linear expression, `2x`, `1/x` and `sqrt(x)`, will always work; quadratic expressions like `x2 - 1` are acceptable as long as the resulting integrand does not depend on the sign of the solutions (see examples). The integral will be returned unchanged if `x` is not a variable of integration. `x` must be (or contain) only one of of the integration variables. If `u` has more than one free symbol then it should be sent as a tuple (`u`, `uvar`) where `uvar` identifies which variable is replacing the integration variable. XXX can it contain another integration variable? Examples ======== >>> from sympy.abc import a, b, c, d, x, u, y >>> from sympy import Integral, S, cos, sqrt >>> i = Integral(xcos(x*2 - 1), (x, 0, 1)) transform can change the variable of integration >>> i.transform(x, u) Integral(ucos(u2 - 1), (u, 0, 1)) transform can perform u-substitution as long as a unique integrand is obtained: >>> i.transform(x2 - 1, u) Integral(cos(u)/2, (u, -1, 0)) This attempt fails because x = +/-sqrt(u + 1) and the sign does not cancel out of the integrand: >>> Integral(cos(x2 - 1), (x, 0, 1)).transform(x2 - 1, u) Traceback (most recent call last): ... ValueError: The mapping between F(x) and f(u) did not give a unique integrand. transform can do a substitution. Here, the previous result is transformed back into the original expression using "u-substitution": >>> ui = _ >>> _.transform(sqrt(u + 1), x) == i True We can accomplish the same with a regular substitution: >>> ui.transform(u, x*2 - 1) == i True If the `x` does not contain a symbol of integration then the integral will be returned unchanged. Integral `i` does not have an integration variable `a` so no change is made: >>> i.transform(a, x) == i True When `u` has more than one free symbol the symbol that is replacing `x` must be identified by passing `u` as a tuple: >>> Integral(x, (x, 0, 1)).transform(x, (u + a, u)) Integral(a + u, (u, -a, 1 - a)) >>> Integral(x, (x, 0, 1)).transform(x, (u + a, a)) Integral(a + u, (a, -u, 1 - u)) See Also ======== variables : Lists the integration variables as_dummy : Replace integration variables with dummy ones """ from sympy.solvers.solvers import solve, posify d = Dummy('d') xfree = x.free_symbols.intersection(self.variables) if len(xfree) > 1: raise ValueError( 'F(x) can only contain one of: %s' % self.variables) xvar = xfree.pop() if xfree else d if xvar not in self.variables: return self u = sympify(u) if isinstance(u, Expr): ufree = u.free_symbols if len(ufree) != 1: raise ValueError(filldedent(''' When f(u) has more than one free symbol, the one replacing x must be identified: pass f(u) as (f(u), u)''')) uvar = ufree.pop() else: u, uvar = u if uvar not in u.free_symbols: raise ValueError(filldedent(''' Expecting a tuple (expr, symbol) where symbol identified a free symbol in expr, but symbol is not in expr's free symbols.''')) if not isinstance(uvar, Symbol): raise ValueError(filldedent(''' Expecting a tuple (expr, symbol) but didn't get a symbol; got %s''' % uvar)) if x.is_Symbol and u.is_Symbol: return self.xreplace({x: u}) if not x.is_Symbol and not u.is_Symbol: raise ValueError('either x or u must be a symbol') if uvar == xvar: return self.transform(x, (u.subs(uvar, d), d)).xreplace({d: uvar}) if uvar in self.limits: raise ValueError(filldedent(''' u must contain the same variable as in x or a variable that is not already an integration variable''')) if not x.is_Symbol: F = [x.subs(xvar, d)] soln = solve(u - x, xvar, check=False) if not soln: raise ValueError('no solution for solve(F(x) - f(u), x)') f = [fi.subs(uvar, d) for fi in soln] else: f = [u.subs(uvar, d)] pdiff, reps = posify(u - x) puvar = uvar.subs([(v, k) for k, v in reps.items()]) soln = [s.subs(reps) for s in solve(pdiff, puvar)] if not soln: raise ValueError('no solution for solve(F(x) - f(u), u)') F = [fi.subs(xvar, d) for fi in soln] newfuncs = set([(self.function.subs(xvar, fi)fi.diff(d) ).subs(d, uvar) for fi in f]) if len(newfuncs) > 1: raise ValueError(filldedent(''' The mapping between F(x) and f(u) did not give a unique integrand.''')) newfunc = newfuncs.pop() def _calc_limit_1(F, a, b): """ replace d with a, using subs if possible, otherwise limit where sign of b is considered """ wok = F.subs(d, a) if wok is S.NaN or wok.is_finite is False and a.is_finite: return limit(sign(b)F, d, a) return wok def _calc_limit(a, b): """ replace d with a, using subs if possible, otherwise limit where sign of b is considered """ avals = list({_calc_limit_1(Fi, a, b) for Fi in F}) if len(avals) > 1: raise ValueError(filldedent(''' The mapping between F(x) and f(u) did not give a unique limit.''')) return avals[0] newlimits = [] for xab in self.limits: sym = xab[0] if sym == xvar: if len(xab) == 3: a, b = xab[1:] a, b = _calc_limit(a, b), _calc_limit(b, a) if a - b > 0: a, b = b, a newfunc = -newfunc newlimits.append((uvar, a, b)) elif len(xab) == 2: a = _calc_limit(xab[1], 1) newlimits.append((uvar, a)) else: newlimits.append(uvar) else: newlimits.append(xab) return self.func(newfunc, newlimits) def doit(self, hints): """ Perform the integration using any hints given. Examples ======== >>> from sympy import Integral >>> from sympy.abc import x, i >>> Integral(xi, (i, 1, 3)).doit() Piecewise((x3/log(x) - x/log(x), (x > 1) \| ((x >= 0) & (x < 1))), (2, True)) See Also ======== sympy.integrals.trigonometry.trigintegrate sympy.integrals.risch.heurisch sympy.integrals.rationaltools.ratint as_sum : Approximate the integral using a sum """ if not hints.get('integrals', True): return self deep = hints.get('deep', True) meijerg = hints.get('meijerg', None) conds = hints.get('conds', 'piecewise') risch = hints.get('risch', None) heurisch = hints.get('heurisch', None) manual = hints.get('manual', None) if len(list(filter(None, (manual, meijerg, risch, heurisch)))) > 1: raise ValueError("At most one of manual, meijerg, risch, heurisch can be True") elif manual: meijerg = risch = heurisch = False elif meijerg: manual = risch = heurisch = False elif risch: manual = meijerg = heurisch = False elif heurisch: manual = meijerg = risch = False eval_kwargs = dict(meijerg=meijerg, risch=risch, manual=manual, heurisch=heurisch, conds=conds) if conds not in ['separate', 'piecewise', 'none']: raise ValueError('conds must be one of "separate", "piecewise", ' '"none", got: %s' % conds) if risch and any(len(xab) > 1 for xab in self.limits): raise ValueError('risch=True is only allowed for indefinite integrals.') # check for the trivial zero if self.is_zero: return S.Zero # now compute and check the function function = self.function if deep: function = function.doit(hints) if function.is_zero: return S.Zero # hacks to handle special cases if isinstance(function, MatrixBase): return function.applyfunc( lambda f: self.func(f, self.limits).doit(hints)) if isinstance(function, FormalPowerSeries): if len(self.limits) > 1: raise NotImplementedError xab = self.limits[0] if len(xab) > 1: return function.integrate(xab, eval_kwargs) else: return function.integrate(xab[0], *eval_kwargs) # There is no trivial answer and special handling # is done so continue undone_limits = [] # ulj = free symbols of any undone limits' upper and lower limits ulj = set() for xab in self.limits: # compute uli, the free symbols in the # Upper and Lower limits of limit I if len(xab) == 1: uli = set(xab[:1]) elif len(xab) == 2: uli = xab[1].free_symbols elif len(xab) == 3: uli = xab[1].free_symbols.union(xab[2].free_symbols) # this integral can be done as long as there is no blocking # limit that has been undone. An undone limit is blocking if # it contains an integration variable that is in this limit's # upper or lower free symbols or vice versa if xab[0] in ulj or any(v[0] in uli for v in undone_limits): undone_limits.append(xab) ulj.update(uli) function = self.func(([function] + [xab])) factored_function = function.factor() if not isinstance(factored_function, Integral): function = factored_function continue if function.has(Abs, sign) and ( (len(xab) < 3 and all(x.is_real for x in xab)) or (len(xab) == 3 and all(x.is_real and not x.is_infinite for x in xab[1:]))): # some improper integrals are better off with Abs xr = Dummy("xr", real=True) function = (function.xreplace({xab[0]: xr}) .rewrite(Piecewise).xreplace({xr: xab[0]})) elif function.has(Min, Max): function = function.rewrite(Piecewise) if (function.has(Piecewise) and not isinstance(function, Piecewise)): function = piecewise_fold(function) if isinstance(function, Piecewise): if len(xab) == 1: antideriv = function._eval_integral(xab[0], eval_kwargs) else: antideriv = self._eval_integral( function, xab[0], eval_kwargs) else: # There are a number of tradeoffs in using the # Meijer G method. It can sometimes be a lot faster # than other methods, and sometimes slower. And # there are certain types of integrals for which it # is more likely to work than others. These # heuristics are incorporated in deciding what # integration methods to try, in what order. See the # integrate() docstring for details. def try_meijerg(function, xab): ret = None if len(xab) == 3 and meijerg is not False: x, a, b = xab try: res = meijerint_definite(function, x, a, b) except NotImplementedError: from sympy.integrals.meijerint import _debug _debug('NotImplementedError ' 'from meijerint_definite') res = None if res is not None: f, cond = res if conds == 'piecewise': ret = Piecewise( (f, cond), (self.func( function, (x, a, b)), True)) elif conds == 'separate': if len(self.limits) != 1: raise ValueError(filldedent(''' conds=separate not supported in multiple integrals''')) ret = f, cond else: ret = f return ret meijerg1 = meijerg if (meijerg is not False and len(xab) == 3 and xab[1].is_real and xab[2].is_real and not function.is_Poly and (xab[1].has(oo, -oo) or xab[2].has(oo, -oo))): ret = try_meijerg(function, xab) if ret is not None: function = ret continue meijerg1 = False # If the special meijerg code did not succeed in # finding a definite integral, then the code using # meijerint_indefinite will not either (it might # find an antiderivative, but the answer is likely # to be nonsensical). Thus if we are requested to # only use Meijer G-function methods, we give up at # this stage. Otherwise we just disable G-function # methods. if meijerg1 is False and meijerg is True: antideriv = None else: antideriv = self._eval_integral( function, xab[0], *eval_kwargs) if antideriv is None and meijerg is True: ret = try_meijerg(function, xab) if ret is not None: function = ret continue if not isinstance(antideriv, Integral) and antideriv is not None: sym = xab[0] for atan_term in antideriv.atoms(atan): atan_arg = atan_term.args[0] # Checking `atan_arg` to be linear combination of `tan` or `cot` for tan_part in atan_arg.atoms(tan): x1 = Dummy('x1') tan_exp1 = atan_arg.subs(tan_part, x1) # The coefficient of `tan` should be constant coeff = tan_exp1.diff(x1) if x1 not in coeff.free_symbols: a = tan_part.args[0] antideriv = antideriv.subs(atan_term, Add(atan_term, sign(coeff)pifloor((a-pi/2)/pi))) for cot_part in atan_arg.atoms(cot): x1 = Dummy('x1') cot_exp1 = atan_arg.subs(cot_part, x1) # The coefficient of `cot` should be constant coeff = cot_exp1.diff(x1) if x1 not in coeff.free_symbols: a = cot_part.args[0] antideriv = antideriv.subs(atan_term, Add(atan_term, sign(coeff)pifloor((a)/pi))) if antideriv is None: undone_limits.append(xab) function = self.func(([function] + [xab])).factor() factored_function = function.factor() if not isinstance(factored_function, Integral): function = factored_function continue else: if len(xab) == 1: function = antideriv else: if len(xab) == 3: x, a, b = xab elif len(xab) == 2: x, b = xab a = None else: raise NotImplementedError if deep: if isinstance(a, Basic): a = a.doit(hints) if isinstance(b, Basic): b = b.doit(hints) if antideriv.is_Poly: gens = list(antideriv.gens) gens.remove(x) antideriv = antideriv.as_expr() function = antideriv._eval_interval(x, a, b) function = Poly(function, gens) else: def is_indef_int(g, x): return (isinstance(g, Integral) and any(i == (x,) for i in g.limits)) def eval_factored(f, x, a, b): # _eval_interval for integrals with # (constant) factors # a single indefinite integral is assumed args = [] for g in Mul.make_args(f): if is_indef_int(g, x): args.append(g._eval_interval(x, a, b)) else: args.append(g) return Mul(args) integrals, others, piecewises = [], [], [] for f in Add.make_args(antideriv): if any(is_indef_int(g, x) for g in Mul.make_args(f)): integrals.append(f) elif any(isinstance(g, Piecewise) for g in Mul.make_args(f)): piecewises.append(piecewise_fold(f)) else: others.append(f) uneval = Add([eval_factored(f, x, a, b) for f in integrals]) try: evalued = Add(others)._eval_interval(x, a, b) evalued_pw = piecewise_fold(Add(piecewises))._eval_interval(x, a, b) function = uneval + evalued + evalued_pw except NotImplementedError: # This can happen if _eval_interval depends in a # complicated way on limits that cannot be computed undone_limits.append(xab) function = self.func(([function] + [xab])) factored_function = function.factor() if not isinstance(factored_function, Integral): function = factored_function return function def _eval_derivative(self, sym): """Evaluate the derivative of the current Integral object by differentiating under the integral sign [1], using the Fundamental Theorem of Calculus [2] when possible. Whenever an Integral is encountered that is equivalent to zero or has an integrand that is independent of the variable of integration those integrals are performed. All others are returned as Integral instances which can be resolved with doit() (provided they are integrable). References: [1] https://en.wikipedia.org/wiki/Differentiation_under_the_integral_sign [2] https://en.wikipedia.org/wiki/Fundamental_theorem_of_calculus Examples ======== >>> from sympy import Integral >>> from sympy.abc import x, y >>> i = Integral(x + y, y, (y, 1, x)) >>> i.diff(x) Integral(x + y, (y, x)) + Integral(1, y, (y, 1, x)) >>> i.doit().diff(x) == i.diff(x).doit() True >>> i.diff(y) 0 The previous must be true since there is no y in the evaluated integral: >>> i.free_symbols {x} >>> i.doit() 2x3/3 - x/2 - 1/6 """ # differentiate under the integral sign; we do not # check for regularity conditions (TODO), see issue 4215 # get limits and the function f, limits = self.function, list(self.limits) # the order matters if variables of integration appear in the limits # so work our way in from the outside to the inside. limit = limits.pop(-1) if len(limit) == 3: x, a, b = limit elif len(limit) == 2: x, b = limit a = None else: a = b = None x = limit[0] if limits: # f is the argument to an integral f = self.func(f, tuple(limits)) # assemble the pieces def _do(f, ab): dab_dsym = diff(ab, sym) if not dab_dsym: return S.Zero if isinstance(f, Integral): limits = [(x, x) if (len(l) == 1 and l[0] == x) else l for l in f.limits] f = self.func(f.function, limits) return f.subs(x, ab)dab_dsym rv = S.Zero if b is not None: rv += _do(f, b) if a is not None: rv -= _do(f, a) if len(limit) == 1 and sym == x: # the dummy variable is also the real-world variable arg = f rv += arg else: # the dummy variable might match sym but it's # only a dummy and the actual variable is determined # by the limits, so mask off the variable of integration # while differentiating u = Dummy('u') arg = f.subs(x, u).diff(sym).subs(u, x) if arg: rv += self.func(arg, Tuple(x, a, b)) return rv def _eval_integral(self, f, x, meijerg=None, risch=None, manual=None, heurisch=None, conds='piecewise'): """ Calculate the anti-derivative to the function f(x). The following algorithms are applied (roughly in this order): 1. Simple heuristics (based on pattern matching and integral table): - most frequently used functions (e.g. polynomials, products of trig functions) 2. Integration of rational functions: - A complete algorithm for integrating rational functions is implemented (the Lazard-Rioboo-Trager algorithm). The algorithm also uses the partial fraction decomposition algorithm implemented in apart() as a preprocessor to make this process faster. Note that the integral of a rational function is always elementary, but in general, it may include a RootSum. 3. Full Risch algorithm: - The Risch algorithm is a complete decision procedure for integrating elementary functions, which means that given any elementary function, it will either compute an elementary antiderivative, or else prove that none exists. Currently, part of transcendental case is implemented, meaning elementary integrals containing exponentials, logarithms, and (soon!) trigonometric functions can be computed. The algebraic case, e.g., functions containing roots, is much more difficult and is not implemented yet. - If the routine fails (because the integrand is not elementary, or because a case is not implemented yet), it continues on to the next algorithms below. If the routine proves that the integrals is nonelementary, it still moves on to the algorithms below, because we might be able to find a closed-form solution in terms of special functions. If risch=True, however, it will stop here. 4. The Meijer G-Function algorithm: - This algorithm works by first rewriting the integrand in terms of very general Meijer G-Function (meijerg in SymPy), integrating it, and then rewriting the result back, if possible. This algorithm is particularly powerful for definite integrals (which is actually part of a different method of Integral), since it can compute closed-form solutions of definite integrals even when no closed-form indefinite integral exists. But it also is capable of computing many indefinite integrals as well. - Another advantage of this method is that it can use some results about the Meijer G-Function to give a result in terms of a Piecewise expression, which allows to express conditionally convergent integrals. - Setting meijerg=True will cause integrate() to use only this method. 5. The "manual integration" algorithm: - This algorithm tries to mimic how a person would find an antiderivative by hand, for example by looking for a substitution or applying integration by parts. This algorithm does not handle as many integrands but can return results in a more familiar form. - Sometimes this algorithm can evaluate parts of an integral; in this case integrate() will try to evaluate the rest of the integrand using the other methods here. - Setting manual=True will cause integrate() to use only this method. 6. The Heuristic Risch algorithm: - This is a heuristic version of the Risch algorithm, meaning that it is not deterministic. This is tried as a last resort because it can be very slow. It is still used because not enough of the full Risch algorithm is implemented, so that there are still some integrals that can only be computed using this method. The goal is to implement enough of the Risch and Meijer G-function methods so that this can be deleted. Setting heurisch=True will cause integrate() to use only this method. Set heurisch=False to not use it. """ from sympy.integrals.deltafunctions import deltaintegrate from sympy.integrals.singularityfunctions import singularityintegrate from sympy.integrals.heurisch import heurisch as heurisch_, heurisch_wrapper from sympy.integrals.rationaltools import ratint from sympy.integrals.risch import risch_integrate if risch: try: return risch_integrate(f, x, conds=conds) except NotImplementedError: return None if manual: try: result = manualintegrate(f, x) if result is not None and result.func != Integral: return result except (ValueError, PolynomialError): pass eval_kwargs = dict(meijerg=meijerg, risch=risch, manual=manual, heurisch=heurisch, conds=conds) # if it is a poly(x) then let the polynomial integrate itself (fast) # # It is important to make this check first, otherwise the other code # will return a sympy expression instead of a Polynomial. # # see Polynomial for details. if isinstance(f, Poly) and not (manual or meijerg or risch): return f.integrate(x) # Piecewise antiderivatives need to call special integrate. if isinstance(f, Piecewise): return f.piecewise_integrate(x, *eval_kwargs) # let's cut it short if `f` does not depend on `x`; if # x is only a dummy, that will be handled below if not f.has(x): return fx # try to convert to poly(x) and then integrate if successful (fast) poly = f.as_poly(x) if poly is not None and not (manual or meijerg or risch): return poly.integrate().as_expr() if risch is not False: try: result, i = risch_integrate(f, x, separate_integral=True, conds=conds) except NotImplementedError: pass else: if i: # There was a nonelementary integral. Try integrating it. # if no part of the NonElementaryIntegral is integrated by # the Risch algorithm, then use the original function to # integrate, instead of re-written one if result == 0: from sympy.integrals.risch import NonElementaryIntegral return NonElementaryIntegral(f, x).doit(risch=False) else: return result + i.doit(risch=False) else: return result # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ... # we are going to handle Add terms separately, # if `f` is not Add -- we only have one term # Note that in general, this is a bad idea, because Integral(g1) + # Integral(g2) might not be computable, even if Integral(g1 + g2) is. # For example, Integral(xx + xxlog(x)). But many heuristics only # work term-wise. So we compute this step last, after trying # risch_integrate. We also try risch_integrate again in this loop, # because maybe the integral is a sum of an elementary part and a # nonelementary part (like erf(x) + exp(x)). risch_integrate() is # quite fast, so this is acceptable. parts = [] args = Add.make_args(f) for g in args: coeff, g = g.as_independent(x) # g(x) = const if g is S.One and not meijerg: parts.append(coeffx) continue # g(x) = expr + O(xn) order_term = g.getO() if order_term is not None: h = self._eval_integral(g.removeO(), x, eval_kwargs) if h is not None: h_order_expr = self._eval_integral(order_term.expr, x, *eval_kwargs) if h_order_expr is not None: h_order_term = order_term.func( h_order_expr, order_term.variables) parts.append(coeff(h + h_order_term)) continue # NOTE: if there is O(xn) and we fail to integrate then # there is no point in trying other methods because they # will fail, too. return None # c # g(x) = (ax+b) if g.is_Pow and not g.exp.has(x) and not meijerg: a = Wild('a', exclude=[x]) b = Wild('b', exclude=[x]) M = g.base.match(ax + b) if M is not None: if g.exp == -1: h = log(g.base) elif conds != 'piecewise': h = g.base(g.exp + 1) / (g.exp + 1) else: h1 = log(g.base) h2 = g.base(g.exp + 1) / (g.exp + 1) h = Piecewise((h2, Ne(g.exp, -1)), (h1, True)) parts.append(coeff h / M[a]) continue # poly(x) # g(x) = ------- # poly(x) if g.is_rational_function(x) and not (manual or meijerg or risch): parts.append(coeff * ratint(g, x)) continue if not (manual or meijerg or risch): # g(x) = Mul(trig) h = trigintegrate(g, x, conds=conds) if h is not None: parts.append(coeff * h) continue # g(x) has at least a DiracDelta term h = deltaintegrate(g, x) if h is not None: parts.append(coeff * h) continue # g(x) has at least a Singularity Function term h = singularityintegrate(g, x) if h is not None: parts.append(coeff * h) continue # Try risch again. if risch is not False: try: h, i = risch_integrate(g, x, separate_integral=True, conds=conds) except NotImplementedError: h = None else: if i: h = h + i.doit(risch=False) parts.append(coeffh) continue # fall back to heurisch if heurisch is not False: try: if conds == 'piecewise': h = heurisch_wrapper(g, x, hints=[]) else: h = heurisch_(g, x, hints=[]) except PolynomialError: # XXX: this exception means there is a bug in the # implementation of heuristic Risch integration # algorithm. h = None else: h = None if meijerg is not False and h is None: # rewrite using G functions try: h = meijerint_indefinite(g, x) except NotImplementedError: from sympy.integrals.meijerint import _debug _debug('NotImplementedError from meijerint_definite') res = None if h is not None: parts.append(coeff h) continue if h is None and manual is not False: try: result = manualintegrate(g, x) if result is not None and not isinstance(result, Integral): if result.has(Integral) and not manual: # Try to have other algorithms do the integrals # manualintegrate can't handle, # unless we were asked to use manual only. # Keep the rest of eval_kwargs in case another # method was set to False already new_eval_kwargs = eval_kwargs new_eval_kwargs["manual"] = False result = result.func([ arg.doit(new_eval_kwargs) if arg.has(Integral) else arg for arg in result.args ]).expand(multinomial=False, log=False, power_exp=False, power_base=False) if not result.has(Integral): parts.append(coeff result) continue except (ValueError, PolynomialError): # can't handle some SymPy expressions pass # if we failed maybe it was because we had # a product that could have been expanded, # so let's try an expansion of the whole # thing before giving up; we don't try this # at the outset because there are things # that cannot be solved unless they are # NOT expanded e.g., x*x(1+log(x)). There # should probably be a checker somewhere in this # routine to look for such cases and try to do # collection on the expressions if they are already # in an expanded form if not h and len(args) == 1: f = sincos_to_sum(f).expand(mul=True, deep=False) if f.is_Add: # Note: risch will be identical on the expanded # expression, but maybe it will be able to pick out parts, # like x(exp(x) + erf(x)). return self._eval_integral(f, x, eval_kwargs) if h is not None: parts.append(coeff h) else: return None return Add(parts) def _eval_lseries(self, x, logx): expr = self.as_dummy() symb = x for l in expr.limits: if x in l[1:]: symb = l[0] break for term in expr.function.lseries(symb, logx): yield integrate(term, expr.limits) def _eval_nseries(self, x, n, logx): expr = self.as_dummy() symb = x for l in expr.limits: if x in l[1:]: symb = l[0] break terms, order = expr.function.nseries( x=symb, n=n, logx=logx).as_coeff_add(Order) order = [o.subs(symb, x) for o in order] return integrate(terms, expr.limits) + Add(order)x def _eval_as_leading_term(self, x): series_gen = self.args[0].lseries(x) for leading_term in series_gen: if leading_term != 0: break return integrate(leading_term, self.args[1:]) def _eval_simplify(self, ratio=1.7, measure=None, rational=False, inverse=False): from sympy.core.exprtools import factor_terms from sympy.simplify.simplify import simplify expr = factor_terms(self) kwargs = dict(ratio=ratio, measure=measure, rational=rational, inverse=inverse) if isinstance(expr, Integral): return expr.func([simplify(i, kwargs) for i in expr.args]) return expr.simplify(kwargs) def as_sum(self, n=None, method="midpoint", evaluate=True): """ Approximates a definite integral by a sum. Arguments --------- n The number of subintervals to use, optional. method One of: 'left', 'right', 'midpoint', 'trapezoid'. evaluate If False, returns an unevaluated Sum expression. The default is True, evaluate the sum. These methods of approximate integration are described in [1]. [1] https://en.wikipedia.org/wiki/Riemann_sum#Methods Examples ======== >>> from sympy import sin, sqrt >>> from sympy.abc import x, n >>> from sympy.integrals import Integral >>> e = Integral(sin(x), (x, 3, 7)) >>> e Integral(sin(x), (x, 3, 7)) For demonstration purposes, this interval will only be split into 2 regions, bounded by [3, 5] and [5, 7]. The left-hand rule uses function evaluations at the left of each interval: >>> e.as_sum(2, 'left') 2sin(5) + 2sin(3) The midpoint rule uses evaluations at the center of each interval: >>> e.as_sum(2, 'midpoint') 2sin(4) + 2sin(6) The right-hand rule uses function evaluations at the right of each interval: >>> e.as_sum(2, 'right') 2sin(5) + 2sin(7) The trapezoid rule uses function evaluations on both sides of the intervals. This is equivalent to taking the average of the left and right hand rule results: >>> e.as_sum(2, 'trapezoid') 2sin(5) + sin(3) + sin(7) >>> (e.as_sum(2, 'left') + e.as_sum(2, 'right'))/2 == _ True Here, the discontinuity at x = 0 can be avoided by using the midpoint or right-hand method: >>> e = Integral(1/sqrt(x), (x, 0, 1)) >>> e.as_sum(5).n(4) 1.730 >>> e.as_sum(10).n(4) 1.809 >>> e.doit().n(4) # the actual value is 2 2.000 The left- or trapezoid method will encounter the discontinuity and return infinity: >>> e.as_sum(5, 'left') zoo The number of intervals can be symbolic. If omitted, a dummy symbol will be used for it. >>> e = Integral(x*2, (x, 0, 2)) >>> e.as_sum(n, 'right').expand() 8/3 + 4/n + 4/(3n*2) This shows that the midpoint rule is more accurate, as its error term decays as the square of n: >>> e.as_sum(method='midpoint').expand() 8/3 - 2/(3_n*2) A symbolic sum is returned with evaluate=False: >>> e.as_sum(n, 'midpoint', evaluate=False) 2Sum((2_k/n - 1/n)2, (_k, 1, n))/n See Also ======== Integral.doit : Perform the integration using any hints """ from sympy.concrete.summations import Sum limits = self.limits if len(limits) > 1: raise NotImplementedError( "Multidimensional midpoint rule not implemented yet") else: limit = limits[0] if (len(limit) != 3 or limit[1].is_finite is False or limit[2].is_finite is False): raise ValueError("Expecting a definite integral over " "a finite interval.") if n is None: n = Dummy('n', integer=True, positive=True) else: n = sympify(n) if (n.is_positive is False or n.is_integer is False or n.is_finite is False): raise ValueError("n must be a positive integer, got %s" % n) x, a, b = limit dx = (b - a)/n k = Dummy('k', integer=True, positive=True) f = self.function if method == "left": result = dxSum(f.subs(x, a + (k-1)dx), (k, 1, n)) elif method == "right": result = dxSum(f.subs(x, a + kdx), (k, 1, n)) elif method == "midpoint": result = dxSum(f.subs(x, a + kdx - dx/2), (k, 1, n)) elif method == "trapezoid": result = dx((f.subs(x, a) + f.subs(x, b))/2 + Sum(f.subs(x, a + kdx), (k, 1, n - 1))) else: raise ValueError("Unknown method %s" % method) return result.doit() if evaluate else result def _sage_(self): import sage.all as sage f, limits = self.function._sage_(), list(self.limits) for limit in limits: if len(limit) == 1: x = limit[0] f = sage.integral(f, x._sage_(), hold=True) elif len(limit) == 2: x, b = limit f = sage.integral(f, x._sage_(), b._sage_(), hold=True) else: x, a, b = limit f = sage.integral(f, (x._sage_(), a._sage_(), b._sage_()), hold=True) return f def principal_value(self, kwargs): """ Compute the Cauchy Principal Value of the definite integral of a real function in the given interval on the real axis. In mathematics, the Cauchy principal value, is a method for assigning values to certain improper integrals which would otherwise be undefined. Examples ======== >>> from sympy import Dummy, symbols, integrate, limit, oo >>> from sympy.integrals.integrals import Integral >>> from sympy.calculus.singularities import singularities >>> x = symbols('x') >>> Integral(x+1, (x, -oo, oo)).principal_value() oo >>> f = 1 / (x3) >>> Integral(f, (x, -oo, oo)).principal_value() 0 >>> Integral(f, (x, -10, 10)).principal_value() 0 >>> Integral(f, (x, -10, oo)).principal_value() + Integral(f, (x, -oo, 10)).principal_value() 0 References ========== .. [1] https://en.wikipedia.org/wiki/Cauchy_principal_value .. [2] http://mathworld.wolfram.com/CauchyPrincipalValue.html """ from sympy.calculus import singularities if len(self.limits) != 1 or len(list(self.limits[0])) != 3: raise ValueError("You need to insert a variable, lower_limit, and upper_limit correctly to calculate " "cauchy's principal value") x, a, b = self.limits[0] if not (a.is_comparable and b.is_comparable and a <= b): raise ValueError("The lower_limit must be smaller than or equal to the upper_limit to calculate " "cauchy's principal value. Also, a and b need to be comparable.") if a == b: return 0 r = Dummy('r') f = self.function singularities_list = [s for s in singularities(f, x) if s.is_comparable and a <= s <= b] for i in singularities_list: if (i == b) or (i == a): raise ValueError( 'The principal value is not defined in the given interval due to singularity at %d.' % (i)) F = integrate(f, x, kwargs) if F.has(Integral): return self if a is -oo and b is oo: I = limit(F - F.subs(x, -x), x, oo) else: I = limit(F, x, b, '-') - limit(F, x, a, '+') for s in singularities_list: I += limit(((F.subs(x, s - r)) - F.subs(x, s + r)), r, 0, '+') return I def integrate(args, kwargs): """integrate(f, var, ...) Compute definite or indefinite integral of one or more variables using Risch-Norman algorithm and table lookup. This procedure is able to handle elementary algebraic and transcendental functions and also a huge class of special functions, including Airy, Bessel, Whittaker and Lambert. var can be: - a symbol -- indefinite integration - a tuple (symbol, a) -- indefinite integration with result given with `a` replacing `symbol` - a tuple (symbol, a, b) -- definite integration Several variables can be specified, in which case the result is multiple integration. (If var is omitted and the integrand is univariate, the indefinite integral in that variable will be performed.) Indefinite integrals are returned without terms that are independent of the integration variables. (see examples) Definite improper integrals often entail delicate convergence conditions. Pass conds='piecewise', 'separate' or 'none' to have these returned, respectively, as a Piecewise function, as a separate result (i.e. result will be a tuple), or not at all (default is 'piecewise'). Strategy** SymPy uses various approaches to definite integration. One method is to find an antiderivative for the integrand, and then use the fundamental theorem of calculus. Various functions are implemented to integrate polynomial, rational and trigonometric functions, and integrands containing DiracDelta terms. SymPy also implements the part of the Risch algorithm, which is a decision procedure for integrating elementary functions, i.e., the algorithm can either find an elementary antiderivative, or prove that one does not exist. There is also a (very successful, albeit somewhat slow) general implementation of the heuristic Risch algorithm. This algorithm will eventually be phased out as more of the full Risch algorithm is implemented. See the docstring of Integral._eval_integral() for more details on computing the antiderivative using algebraic methods. The option risch=True can be used to use only the (full) Risch algorithm. This is useful if you want to know if an elementary function has an elementary antiderivative. If the indefinite Integral returned by this function is an instance of NonElementaryIntegral, that means that the Risch algorithm has proven that integral to be non-elementary. Note that by default, additional methods (such as the Meijer G method outlined below) are tried on these integrals, as they may be expressible in terms of special functions, so if you only care about elementary answers, use risch=True. Also note that an unevaluated Integral returned by this function is not necessarily a NonElementaryIntegral, even with risch=True, as it may just be an indication that the particular part of the Risch algorithm needed to integrate that function is not yet implemented. Another family of strategies comes from re-writing the integrand in terms of so-called Meijer G-functions. Indefinite integrals of a single G-function can always be computed, and the definite integral of a product of two G-functions can be computed from zero to infinity. Various strategies are implemented to rewrite integrands as G-functions, and use this information to compute integrals (see the ``meijerint`` module). The option manual=True can be used to use only an algorithm that tries to mimic integration by hand. This algorithm does not handle as many integrands as the other algorithms implemented but may return results in a more familiar form. The ``manualintegrate`` module has functions that return the steps used (see the module docstring for more information). In general, the algebraic methods work best for computing antiderivatives of (possibly complicated) combinations of elementary functions. The G-function methods work best for computing definite integrals from zero to infinity of moderately complicated combinations of special functions, or indefinite integrals of very simple combinations of special functions. The strategy employed by the integration code is as follows: - If computing a definite integral, and both limits are real, and at least one limit is +- oo, try the G-function method of definite integration first. - Try to find an antiderivative, using all available methods, ordered by performance (that is try fastest method first, slowest last; in particular polynomial integration is tried first, Meijer G-functions second to last, and heuristic Risch last). - If still not successful, try G-functions irrespective of the limits. The option meijerg=True, False, None can be used to, respectively: always use G-function methods and no others, never use G-function methods, or use all available methods (in order as described above). It defaults to None. Examples ======== >>> from sympy import integrate, log, exp, oo >>> from sympy.abc import a, x, y >>> integrate(xy, x) x2y/2 >>> integrate(log(x), x) xlog(x) - x >>> integrate(log(x), (x, 1, a)) alog(a) - a + 1 >>> integrate(x) x*2/2 Terms that are independent of x are dropped by indefinite integration: >>> from sympy import sqrt >>> integrate(sqrt(1 + x), (x, 0, x)) 2(x + 1)*(3/2)/3 - 2/3 >>> integrate(sqrt(1 + x), x) 2(x + 1)*(3/2)/3 >>> integrate(xy) Traceback (most recent call last): ... ValueError: specify integration variables to integrate xy Note that ``integrate(x)`` syntax is meant only for convenience in interactive sessions and should be avoided in library code. >>> integrate(xaexp(-x), (x, 0, oo)) # same as conds='piecewise' Piecewise((gamma(a + 1), re(a) > -1), (Integral(x*aexp(-x), (x, 0, oo)), True)) >>> integrate(x*aexp(-x), (x, 0, oo), conds='none') gamma(a + 1) >>> integrate(x*aexp(-x), (x, 0, oo), conds='separate') (gamma(a + 1), -re(a) < 1) See Also ======== Integral, Integral.doit """ doit_flags = { 'deep': False, 'meijerg': kwargs.pop('meijerg', None), 'conds': kwargs.pop('conds', 'piecewise'), 'risch': kwargs.pop('risch', None), 'heurisch': kwargs.pop('heurisch', None), 'manual': kwargs.pop('manual', None) } integral = Integral(args, kwargs) if isinstance(integral, Integral): return integral.doit(doit_flags) else: new_args = [a.doit(doit_flags) if isinstance(a, Integral) else a for a in integral.args] return integral.func(new_args) def line_integrate(field, curve, vars): """line_integrate(field, Curve, variables) Compute the line integral. Examples ======== >>> from sympy import Curve, line_integrate, E, ln >>> from sympy.abc import x, y, t >>> C = Curve([Et + 1, Et - 1], (t, 0, ln(2))) >>> line_integrate(x + y, C, [x, y]) 3sqrt(2) See Also ======== integrate, Integral """ from sympy.geometry import Curve F = sympify(field) if not F: raise ValueError( "Expecting function specifying field as first argument.") if not isinstance(curve, Curve): raise ValueError("Expecting Curve entity as second argument.") if not is_sequence(vars): raise ValueError("Expecting ordered iterable for variables.") if len(curve.functions) != len(vars): raise ValueError("Field variable size does not match curve dimension.") if curve.parameter in vars: raise ValueError("Curve parameter clashes with field parameters.") # Calculate derivatives for line parameter functions # F(r) -> F(r(t)) and finally F(r(t)r'(t)) Ft = F dldt = 0 for i, var in enumerate(vars): _f = curve.functions[i] _dn = diff(_f, curve.parameter) # ...arc length dldt = dldt + (_dn * _dn) Ft = Ft.subs(var, _f) Ft = Ft * sqrt(dldt) integral = Integral(Ft, curve.limits).doit(deep=False) return integral
8bdb1482e8a5056f987365334bd527eea9a8d7fa51c3f9ec0e2881419dcc32b4	"""Base class for all the objects in SymPy""" from __future__ import print_function, division from collections import defaultdict from itertools import chain from .assumptions import BasicMeta, ManagedProperties from .cache import cacheit from .sympify import _sympify, sympify, SympifyError from .compatibility import (iterable, Iterator, ordered, string_types, with_metaclass, zip_longest, range, PY3, Mapping) from .singleton import S from inspect import getmro def as_Basic(expr): """Return expr as a Basic instance using strict sympify or raise a TypeError; this is just a wrapper to _sympify, raising a TypeError instead of a SympifyError.""" from sympy.utilities.misc import func_name try: return _sympify(expr) except SympifyError: raise TypeError( 'Argument must be a Basic object, not `%s`' % func_name( expr)) class Basic(with_metaclass(ManagedProperties)): """ Base class for all objects in SymPy. Conventions: 1) Always use ``.args``, when accessing parameters of some instance: >>> from sympy import cot >>> from sympy.abc import x, y >>> cot(x).args (x,) >>> cot(x).args[0] x >>> (xy).args (x, y) >>> (xy).args[1] y 2) Never use internal methods or variables (the ones prefixed with ``_``): >>> cot(x)._args # do not use this, use cot(x).args instead (x,) """ __slots__ = ['_mhash', # hash value '_args', # arguments '_assumptions' ] # To be overridden with True in the appropriate subclasses is_number = False is_Atom = False is_Symbol = False is_symbol = False is_Indexed = False is_Dummy = False is_Wild = False is_Function = False is_Add = False is_Mul = False is_Pow = False is_Number = False is_Float = False is_Rational = False is_Integer = False is_NumberSymbol = False is_Order = False is_Derivative = False is_Piecewise = False is_Poly = False is_AlgebraicNumber = False is_Relational = False is_Equality = False is_Boolean = False is_Not = False is_Matrix = False is_Vector = False is_Point = False is_MatAdd = False is_MatMul = False def __new__(cls, args): obj = object.__new__(cls) obj._assumptions = cls.default_assumptions obj._mhash = None # will be set by __hash__ method. obj._args = args # all items in args must be Basic objects return obj def copy(self): return self.func(self.args) def __reduce_ex__(self, proto): """ Pickling support.""" return type(self), self.__getnewargs__(), self.__getstate__() def __getnewargs__(self): return self.args def __getstate__(self): return {} def __setstate__(self, state): for k, v in state.items(): setattr(self, k, v) def __hash__(self): # hash cannot be cached using cache_it because infinite recurrence # occurs as hash is needed for setting cache dictionary keys h = self._mhash if h is None: h = hash((type(self).__name__,) + self._hashable_content()) self._mhash = h return h def _hashable_content(self): """Return a tuple of information about self that can be used to compute the hash. If a class defines additional attributes, like ``name`` in Symbol, then this method should be updated accordingly to return such relevant attributes. Defining more than _hashable_content is necessary if __eq__ has been defined by a class. See note about this in Basic.__eq__.""" return self._args @property def assumptions0(self): """ Return object `type` assumptions. For example: Symbol('x', real=True) Symbol('x', integer=True) are different objects. In other words, besides Python type (Symbol in this case), the initial assumptions are also forming their typeinfo. Examples ======== >>> from sympy import Symbol >>> from sympy.abc import x >>> x.assumptions0 {'commutative': True} >>> x = Symbol("x", positive=True) >>> x.assumptions0 {'commutative': True, 'complex': True, 'hermitian': True, 'imaginary': False, 'negative': False, 'nonnegative': True, 'nonpositive': False, 'nonzero': True, 'positive': True, 'real': True, 'zero': False} """ return {} def compare(self, other): """ Return -1, 0, 1 if the object is smaller, equal, or greater than other. Not in the mathematical sense. If the object is of a different type from the "other" then their classes are ordered according to the sorted_classes list. Examples ======== >>> from sympy.abc import x, y >>> x.compare(y) -1 >>> x.compare(x) 0 >>> y.compare(x) 1 """ # all redefinitions of __cmp__ method should start with the # following lines: if self is other: return 0 n1 = self.__class__ n2 = other.__class__ c = (n1 > n2) - (n1 < n2) if c: return c # st = self._hashable_content() ot = other._hashable_content() c = (len(st) > len(ot)) - (len(st) < len(ot)) if c: return c for l, r in zip(st, ot): l = Basic(l) if isinstance(l, frozenset) else l r = Basic(r) if isinstance(r, frozenset) else r if isinstance(l, Basic): c = l.compare(r) else: c = (l > r) - (l < r) if c: return c return 0 @staticmethod def _compare_pretty(a, b): from sympy.series.order import Order if isinstance(a, Order) and not isinstance(b, Order): return 1 if not isinstance(a, Order) and isinstance(b, Order): return -1 if a.is_Rational and b.is_Rational: l = a.p * b.q r = b.p * a.q return (l > r) - (l < r) else: from sympy.core.symbol import Wild p1, p2, p3 = Wild("p1"), Wild("p2"), Wild("p3") r_a = a.match(p1 * p2*p3) if r_a and p3 in r_a: a3 = r_a[p3] r_b = b.match(p1 p2p3) if r_b and p3 in r_b: b3 = r_b[p3] c = Basic.compare(a3, b3) if c != 0: return c return Basic.compare(a, b) @classmethod def fromiter(cls, args, assumptions): """ Create a new object from an iterable. This is a convenience function that allows one to create objects from any iterable, without having to convert to a list or tuple first. Examples ======== >>> from sympy import Tuple >>> Tuple.fromiter(i for i in range(5)) (0, 1, 2, 3, 4) """ return cls(tuple(args), assumptions) @classmethod def class_key(cls): """Nice order of classes. """ return 5, 0, cls.__name__ @cacheit def sort_key(self, order=None): """ Return a sort key. Examples ======== >>> from sympy.core import S, I >>> sorted([S(1)/2, I, -I], key=lambda x: x.sort_key()) [1/2, -I, I] >>> S("[x, 1/x, 1/x2, x2, x(1/2), x(1/4), x(3/2)]") [x, 1/x, x(-2), x2, sqrt(x), x(1/4), x(3/2)] >>> sorted(_, key=lambda x: x.sort_key()) [x(-2), 1/x, x(1/4), sqrt(x), x, x(3/2), x2] """ # XXX: remove this when issue 5169 is fixed def inner_key(arg): if isinstance(arg, Basic): return arg.sort_key(order) else: return arg args = self._sorted_args args = len(args), tuple([inner_key(arg) for arg in args]) return self.class_key(), args, S.One.sort_key(), S.One def __eq__(self, other): """Return a boolean indicating whether a == b on the basis of their symbolic trees. This is the same as a.compare(b) == 0 but faster. Notes ===== If a class that overrides __eq__() needs to retain the implementation of __hash__() from a parent class, the interpreter must be told this explicitly by setting __hash__ = <ParentClass>.__hash__. Otherwise the inheritance of __hash__() will be blocked, just as if __hash__ had been explicitly set to None. References ========== from http://docs.python.org/dev/reference/datamodel.html#object.__hash__ """ if self is other: return True tself = type(self) tother = type(other) if tself is not tother: try: other = _sympify(other) tother = type(other) except SympifyError: return NotImplemented # As long as we have the ordering of classes (sympy.core), # comparing types will be slow in Python 2, because it uses # __cmp__. Until we can remove it # (https://github.com/sympy/sympy/issues/4269), we only compare # types in Python 2 directly if they actually have __ne__. if PY3 or type(tself).__ne__ is not type.__ne__: if tself != tother: return False elif tself is not tother: return False return self._hashable_content() == other._hashable_content() def __ne__(self, other): """a != b -> Compare two symbolic trees and see whether they are different this is the same as: a.compare(b) != 0 but faster """ return not self == other def dummy_eq(self, other, symbol=None): """ Compare two expressions and handle dummy symbols. Examples ======== >>> from sympy import Dummy >>> from sympy.abc import x, y >>> u = Dummy('u') >>> (u2 + 1).dummy_eq(x2 + 1) True >>> (u2 + 1) == (x2 + 1) False >>> (u2 + y).dummy_eq(x2 + y, x) True >>> (u2 + y).dummy_eq(x2 + y, y) False """ s = self.as_dummy() o = _sympify(other) o = o.as_dummy() dummy_symbols = [i for i in s.free_symbols if i.is_Dummy] if len(dummy_symbols) == 1: dummy = dummy_symbols.pop() else: return s == o if symbol is None: symbols = o.free_symbols if len(symbols) == 1: symbol = symbols.pop() else: return s == o tmp = dummy.__class__() return s.subs(dummy, tmp) == o.subs(symbol, tmp) # Note, we always use the default ordering (lex) in __str__ and __repr__, # regardless of the global setting. See issue 5487. def __repr__(self): """Method to return the string representation. Return the expression as a string. """ from sympy.printing import sstr return sstr(self, order=None) def __str__(self): from sympy.printing import sstr return sstr(self, order=None) # We don't define _repr_png_ here because it would add a large amount of # data to any notebook containing SymPy expressions, without adding # anything useful to the notebook. It can still enabled manually, e.g., # for the qtconsole, with init_printing(). def _repr_latex_(self): """ IPython/Jupyter LaTeX printing To change the behavior of this (e.g., pass in some settings to LaTeX), use init_printing(). init_printing() will also enable LaTeX printing for built in numeric types like ints and container types that contain SymPy objects, like lists and dictionaries of expressions. """ from sympy.printing.latex import latex s = latex(self, mode='plain') return "$\\displaystyle %s$" % s _repr_latex_orig = _repr_latex_ def atoms(self, types): """Returns the atoms that form the current object. By default, only objects that are truly atomic and can't be divided into smaller pieces are returned: symbols, numbers, and number symbols like I and pi. It is possible to request atoms of any type, however, as demonstrated below. Examples ======== >>> from sympy import I, pi, sin >>> from sympy.abc import x, y >>> (1 + x + 2sin(y + Ipi)).atoms() {1, 2, I, pi, x, y} If one or more types are given, the results will contain only those types of atoms. >>> from sympy import Number, NumberSymbol, Symbol >>> (1 + x + 2sin(y + Ipi)).atoms(Symbol) {x, y} >>> (1 + x + 2sin(y + Ipi)).atoms(Number) {1, 2} >>> (1 + x + 2sin(y + Ipi)).atoms(Number, NumberSymbol) {1, 2, pi} >>> (1 + x + 2sin(y + Ipi)).atoms(Number, NumberSymbol, I) {1, 2, I, pi} Note that I (imaginary unit) and zoo (complex infinity) are special types of number symbols and are not part of the NumberSymbol class. The type can be given implicitly, too: >>> (1 + x + 2sin(y + Ipi)).atoms(x) # x is a Symbol {x, y} Be careful to check your assumptions when using the implicit option since ``S(1).is_Integer = True`` but ``type(S(1))`` is ``One``, a special type of sympy atom, while ``type(S(2))`` is type ``Integer`` and will find all integers in an expression: >>> from sympy import S >>> (1 + x + 2sin(y + Ipi)).atoms(S(1)) {1} >>> (1 + x + 2sin(y + Ipi)).atoms(S(2)) {1, 2} Finally, arguments to atoms() can select more than atomic atoms: any sympy type (loaded in core/__init__.py) can be listed as an argument and those types of "atoms" as found in scanning the arguments of the expression recursively: >>> from sympy import Function, Mul >>> from sympy.core.function import AppliedUndef >>> f = Function('f') >>> (1 + f(x) + 2sin(y + Ipi)).atoms(Function) {f(x), sin(y + Ipi)} >>> (1 + f(x) + 2sin(y + Ipi)).atoms(AppliedUndef) {f(x)} >>> (1 + x + 2sin(y + Ipi)).atoms(Mul) {Ipi, 2sin(y + Ipi)} """ if types: types = tuple( [t if isinstance(t, type) else type(t) for t in types]) else: types = (Atom,) result = set() for expr in preorder_traversal(self): if isinstance(expr, types): result.add(expr) return result @property def free_symbols(self): """Return from the atoms of self those which are free symbols. For most expressions, all symbols are free symbols. For some classes this is not true. e.g. Integrals use Symbols for the dummy variables which are bound variables, so Integral has a method to return all symbols except those. Derivative keeps track of symbols with respect to which it will perform a derivative; those are bound variables, too, so it has its own free_symbols method. Any other method that uses bound variables should implement a free_symbols method.""" return set().union([a.free_symbols for a in self.args]) @property def expr_free_symbols(self): return set([]) def as_dummy(self): """Return the expression with any objects having structurally bound symbols replaced with unique, canonical symbols within the object in which they appear and having only the default assumption for commutativity being True. Examples ======== >>> from sympy import Integral, Symbol >>> from sympy.abc import x, y >>> r = Symbol('r', real=True) >>> Integral(r, (r, x)).as_dummy() Integral(_0, (_0, x)) >>> _.variables[0].is_real is None True Notes ===== Any object that has structural dummy variables should have a property, `bound_symbols` that returns a list of structural dummy symbols of the object itself. Lambda and Subs have bound symbols, but because of how they are cached, they already compare the same regardless of their bound symbols: >>> from sympy import Lambda >>> Lambda(x, x + 1) == Lambda(y, y + 1) True """ def can(x): d = {i: i.as_dummy() for i in x.bound_symbols} # mask free that shadow bound x = x.subs(d) c = x.canonical_variables # replace bound x = x.xreplace(c) # undo masking x = x.xreplace(dict((v, k) for k, v in d.items())) return x return self.replace( lambda x: hasattr(x, 'bound_symbols'), lambda x: can(x)) @property def canonical_variables(self): """Return a dictionary mapping any variable defined in ``self.bound_symbols`` to Symbols that do not clash with any existing symbol in the expression. Examples ======== >>> from sympy import Lambda >>> from sympy.abc import x >>> Lambda(x, 2x).canonical_variables {x: _0} """ from sympy.core.symbol import Symbol from sympy.utilities.iterables import numbered_symbols if not hasattr(self, 'bound_symbols'): return {} dums = numbered_symbols('_') reps = {} v = self.bound_symbols # this free will include bound symbols that are not part of # self's bound symbols free = set([i.name for i in self.atoms(Symbol) - set(v)]) for v in v: d = next(dums) if v.is_Symbol: while v.name == d.name or d.name in free: d = next(dums) reps[v] = d return reps def rcall(self, args): """Apply on the argument recursively through the expression tree. This method is used to simulate a common abuse of notation for operators. For instance in SymPy the the following will not work: ``(x+Lambda(y, 2y))(z) == x+2z``, however you can use >>> from sympy import Lambda >>> from sympy.abc import x, y, z >>> (x + Lambda(y, 2y)).rcall(z) x + 2z """ return Basic._recursive_call(self, args) @staticmethod def _recursive_call(expr_to_call, on_args): """Helper for rcall method. """ from sympy import Symbol def the_call_method_is_overridden(expr): for cls in getmro(type(expr)): if '__call__' in cls.__dict__: return cls != Basic if callable(expr_to_call) and the_call_method_is_overridden(expr_to_call): if isinstance(expr_to_call, Symbol): # XXX When you call a Symbol it is return expr_to_call # transformed into an UndefFunction else: return expr_to_call(on_args) elif expr_to_call.args: args = [Basic._recursive_call( sub, on_args) for sub in expr_to_call.args] return type(expr_to_call)(args) else: return expr_to_call def is_hypergeometric(self, k): from sympy.simplify import hypersimp return hypersimp(self, k) is not None @property def is_comparable(self): """Return True if self can be computed to a real number (or already is a real number) with precision, else False. Examples ======== >>> from sympy import exp_polar, pi, I >>> (Iexp_polar(Ipi/2)).is_comparable True >>> (Iexp_polar(Ipi2)).is_comparable False A False result does not mean that `self` cannot be rewritten into a form that would be comparable. For example, the difference computed below is zero but without simplification it does not evaluate to a zero with precision: >>> e = 2*pi(1 + 2*pi) >>> dif = e - e.expand() >>> dif.is_comparable False >>> dif.n(2)._prec 1 """ is_real = self.is_real if is_real is False: return False if not self.is_number: return False # don't re-eval numbers that are already evaluated since # this will create spurious precision n, i = [p.evalf(2) if not p.is_Number else p for p in self.as_real_imag()] if not (i.is_Number and n.is_Number): return False if i: # if _prec = 1 we can't decide and if not, # the answer is False because numbers with # imaginary parts can't be compared # so return False return False else: return n._prec != 1 @property def func(self): """ The top-level function in an expression. The following should hold for all objects:: >> x == x.func(x.args) Examples ======== >>> from sympy.abc import x >>> a = 2x >>> a.func <class 'sympy.core.mul.Mul'> >>> a.args (2, x) >>> a.func(a.args) 2x >>> a == a.func(a.args) True """ return self.__class__ @property def args(self): """Returns a tuple of arguments of 'self'. Examples ======== >>> from sympy import cot >>> from sympy.abc import x, y >>> cot(x).args (x,) >>> cot(x).args[0] x >>> (xy).args (x, y) >>> (xy).args[1] y Notes ===== Never use self._args, always use self.args. Only use _args in __new__ when creating a new function. Don't override .args() from Basic (so that it's easy to change the interface in the future if needed). """ return self._args @property def _sorted_args(self): """ The same as ``args``. Derived classes which don't fix an order on their arguments should override this method to produce the sorted representation. """ return self.args def as_poly(self, gens, args): """Converts ``self`` to a polynomial or returns ``None``. >>> from sympy import sin >>> from sympy.abc import x, y >>> print((x2 + xy).as_poly()) Poly(x*2 + xy, x, y, domain='ZZ') >>> print((x*2 + xy).as_poly(x, y)) Poly(x*2 + xy, x, y, domain='ZZ') >>> print((x*2 + sin(y)).as_poly(x, y)) None """ from sympy.polys import Poly, PolynomialError try: poly = Poly(self, gens, *args) if not poly.is_Poly: return None else: return poly except PolynomialError: return None def as_content_primitive(self, radical=False, clear=True): """A stub to allow Basic args (like Tuple) to be skipped when computing the content and primitive components of an expression. See Also ======== sympy.core.expr.Expr.as_content_primitive """ return S.One, self def subs(self, args, *kwargs): """ Substitutes old for new in an expression after sympifying args. `args` is either: - two arguments, e.g. foo.subs(old, new) - one iterable argument, e.g. foo.subs(iterable). The iterable may be o an iterable container with (old, new) pairs. In this case the replacements are processed in the order given with successive patterns possibly affecting replacements already made. o a dict or set whose key/value items correspond to old/new pairs. In this case the old/new pairs will be sorted by op count and in case of a tie, by number of args and the default_sort_key. The resulting sorted list is then processed as an iterable container (see previous). If the keyword ``simultaneous`` is True, the subexpressions will not be evaluated until all the substitutions have been made. Examples ======== >>> from sympy import pi, exp, limit, oo >>> from sympy.abc import x, y >>> (1 + xy).subs(x, pi) piy + 1 >>> (1 + xy).subs({x:pi, y:2}) 1 + 2pi >>> (1 + xy).subs([(x, pi), (y, 2)]) 1 + 2pi >>> reps = [(y, x2), (x, 2)] >>> (x + y).subs(reps) 6 >>> (x + y).subs(reversed(reps)) x2 + 2 >>> (x2 + x4).subs(x2, y) y2 + y To replace only the x2 but not the x4, use xreplace: >>> (x2 + x4).xreplace({x2: y}) x4 + y To delay evaluation until all substitutions have been made, set the keyword ``simultaneous`` to True: >>> (x/y).subs([(x, 0), (y, 0)]) 0 >>> (x/y).subs([(x, 0), (y, 0)], simultaneous=True) nan This has the added feature of not allowing subsequent substitutions to affect those already made: >>> ((x + y)/y).subs({x + y: y, y: x + y}) 1 >>> ((x + y)/y).subs({x + y: y, y: x + y}, simultaneous=True) y/(x + y) In order to obtain a canonical result, unordered iterables are sorted by count_op length, number of arguments and by the default_sort_key to break any ties. All other iterables are left unsorted. >>> from sympy import sqrt, sin, cos >>> from sympy.abc import a, b, c, d, e >>> A = (sqrt(sin(2x)), a) >>> B = (sin(2x), b) >>> C = (cos(2x), c) >>> D = (x, d) >>> E = (exp(x), e) >>> expr = sqrt(sin(2x))sin(exp(x)x)cos(2x) + sin(2x) >>> expr.subs(dict([A, B, C, D, E])) acsin(de) + b The resulting expression represents a literal replacement of the old arguments with the new arguments. This may not reflect the limiting behavior of the expression: >>> (x3 - 3x).subs({x: oo}) nan >>> limit(x*3 - 3x, x, oo) oo If the substitution will be followed by numerical evaluation, it is better to pass the substitution to evalf as >>> (1/x).evalf(subs={x: 3.0}, n=21) 0.333333333333333333333 rather than >>> (1/x).subs({x: 3.0}).evalf(21) 0.333333333333333314830 as the former will ensure that the desired level of precision is obtained. See Also ======== replace: replacement capable of doing wildcard-like matching, parsing of match, and conditional replacements xreplace: exact node replacement in expr tree; also capable of using matching rules evalf: calculates the given formula to a desired level of precision """ from sympy.core.containers import Dict from sympy.utilities import default_sort_key from sympy import Dummy, Symbol unordered = False if len(args) == 1: sequence = args[0] if isinstance(sequence, set): unordered = True elif isinstance(sequence, (Dict, Mapping)): unordered = True sequence = sequence.items() elif not iterable(sequence): from sympy.utilities.misc import filldedent raise ValueError(filldedent(""" When a single argument is passed to subs it should be a dictionary of old: new pairs or an iterable of (old, new) tuples.""")) elif len(args) == 2: sequence = [args] else: raise ValueError("subs accepts either 1 or 2 arguments") sequence = list(sequence) for i, s in enumerate(sequence): if isinstance(s[0], string_types): # when old is a string we prefer Symbol s = Symbol(s[0]), s[1] try: s = [sympify(_, strict=not isinstance(_, string_types)) for _ in s] except SympifyError: # if it can't be sympified, skip it sequence[i] = None continue # skip if there is no change sequence[i] = None if _aresame(s) else tuple(s) sequence = list(filter(None, sequence)) if unordered: sequence = dict(sequence) if not all(k.is_Atom for k in sequence): d = {} for o, n in sequence.items(): try: ops = o.count_ops(), len(o.args) except TypeError: ops = (0, 0) d.setdefault(ops, []).append((o, n)) newseq = [] for k in sorted(d.keys(), reverse=True): newseq.extend( sorted([v[0] for v in d[k]], key=default_sort_key)) sequence = [(k, sequence[k]) for k in newseq] del newseq, d else: sequence = sorted([(k, v) for (k, v) in sequence.items()], key=default_sort_key) if kwargs.pop('simultaneous', False): # XXX should this be the default for dict subs? reps = {} rv = self kwargs['hack2'] = True m = Dummy() for old, new in sequence: d = Dummy(commutative=new.is_commutative) # using dm so Subs will be used on dummy variables # in things like Derivative(f(x, y), x) in which x # is both free and bound rv = rv._subs(old, dm, kwargs) if not isinstance(rv, Basic): break reps[d] = new reps[m] = S.One # get rid of m return rv.xreplace(reps) else: rv = self for old, new in sequence: rv = rv._subs(old, new, kwargs) if not isinstance(rv, Basic): break return rv @cacheit def _subs(self, old, new, hints): """Substitutes an expression old -> new. If self is not equal to old then _eval_subs is called. If _eval_subs doesn't want to make any special replacement then a None is received which indicates that the fallback should be applied wherein a search for replacements is made amongst the arguments of self. >>> from sympy import Add >>> from sympy.abc import x, y, z Examples ======== Add's _eval_subs knows how to target x + y in the following so it makes the change: >>> (x + y + z).subs(x + y, 1) z + 1 Add's _eval_subs doesn't need to know how to find x + y in the following: >>> Add._eval_subs(z(x + y) + 3, x + y, 1) is None True The returned None will cause the fallback routine to traverse the args and pass the z(x + y) arg to Mul where the change will take place and the substitution will succeed: >>> (z(x + y) + 3).subs(x + y, 1) z + 3 Developers Notes An _eval_subs routine for a class should be written if: 1) any arguments are not instances of Basic (e.g. bool, tuple); 2) some arguments should not be targeted (as in integration variables); 3) if there is something other than a literal replacement that should be attempted (as in Piecewise where the condition may be updated without doing a replacement). If it is overridden, here are some special cases that might arise: 1) If it turns out that no special change was made and all the original sub-arguments should be checked for replacements then None should be returned. 2) If it is necessary to do substitutions on a portion of the expression then _subs should be called. _subs will handle the case of any sub-expression being equal to old (which usually would not be the case) while its fallback will handle the recursion into the sub-arguments. For example, after Add's _eval_subs removes some matching terms it must process the remaining terms so it calls _subs on each of the un-matched terms and then adds them onto the terms previously obtained. 3) If the initial expression should remain unchanged then the original expression should be returned. (Whenever an expression is returned, modified or not, no further substitution of old -> new is attempted.) Sum's _eval_subs routine uses this strategy when a substitution is attempted on any of its summation variables. """ def fallback(self, old, new): """ Try to replace old with new in any of self's arguments. """ hit = False args = list(self.args) for i, arg in enumerate(args): if not hasattr(arg, '_eval_subs'): continue arg = arg._subs(old, new, *hints) if not _aresame(arg, args[i]): hit = True args[i] = arg if hit: rv = self.func(args) hack2 = hints.get('hack2', False) if hack2 and self.is_Mul and not rv.is_Mul: # 2-arg hack coeff = S.One nonnumber = [] for i in args: if i.is_Number: coeff = i else: nonnumber.append(i) nonnumber = self.func(nonnumber) if coeff is S.One: return nonnumber else: return self.func(coeff, nonnumber, evaluate=False) return rv return self if _aresame(self, old): return new rv = self._eval_subs(old, new) if rv is None: rv = fallback(self, old, new) return rv def _eval_subs(self, old, new): """Override this stub if you want to do anything more than attempt a replacement of old with new in the arguments of self. See also: _subs """ return None def xreplace(self, rule): """ Replace occurrences of objects within the expression. Parameters ========== rule : dict-like Expresses a replacement rule Returns ======= xreplace : the result of the replacement Examples ======== >>> from sympy import symbols, pi, exp >>> x, y, z = symbols('x y z') >>> (1 + xy).xreplace({x: pi}) piy + 1 >>> (1 + xy).xreplace({x: pi, y: 2}) 1 + 2pi Replacements occur only if an entire node in the expression tree is matched: >>> (xy + z).xreplace({xy: pi}) z + pi >>> (xyz).xreplace({xy: pi}) xyz >>> (2x).xreplace({2x: y, x: z}) y >>> (22x).xreplace({2x: y, x: z}) 4z >>> (x + y + 2).xreplace({x + y: 2}) x + y + 2 >>> (x + 2 + exp(x + 2)).xreplace({x + 2: y}) x + exp(y) + 2 xreplace doesn't differentiate between free and bound symbols. In the following, subs(x, y) would not change x since it is a bound symbol, but xreplace does: >>> from sympy import Integral >>> Integral(x, (x, 1, 2x)).xreplace({x: y}) Integral(y, (y, 1, 2y)) Trying to replace x with an expression raises an error: >>> Integral(x, (x, 1, 2x)).xreplace({x: 2y}) # doctest: +SKIP ValueError: Invalid limits given: ((2y, 1, 4y),) See Also ======== replace: replacement capable of doing wildcard-like matching, parsing of match, and conditional replacements subs: substitution of subexpressions as defined by the objects themselves. """ value, _ = self._xreplace(rule) return value def _xreplace(self, rule): """ Helper for xreplace. Tracks whether a replacement actually occurred. """ if self in rule: return rule[self], True elif rule: args = [] changed = False for a in self.args: _xreplace = getattr(a, '_xreplace', None) if _xreplace is not None: a_xr = _xreplace(rule) args.append(a_xr[0]) changed \|= a_xr[1] else: args.append(a) args = tuple(args) if changed: return self.func(args), True return self, False @cacheit def has(self, patterns): """ Test whether any subexpression matches any of the patterns. Examples ======== >>> from sympy import sin >>> from sympy.abc import x, y, z >>> (x2 + sin(xy)).has(z) False >>> (x*2 + sin(xy)).has(x, y, z) True >>> x.has(x) True Note ``has`` is a structural algorithm with no knowledge of mathematics. Consider the following half-open interval: >>> from sympy.sets import Interval >>> i = Interval.Lopen(0, 5); i Interval.Lopen(0, 5) >>> i.args (0, 5, True, False) >>> i.has(4) # there is no "4" in the arguments False >>> i.has(0) # there is a "0" in the arguments True Instead, use ``contains`` to determine whether a number is in the interval or not: >>> i.contains(4) True >>> i.contains(0) False Note that ``expr.has(patterns)`` is exactly equivalent to ``any(expr.has(p) for p in patterns)``. In particular, ``False`` is returned when the list of patterns is empty. >>> x.has() False """ return any(self._has(pattern) for pattern in patterns) def _has(self, pattern): """Helper for .has()""" from sympy.core.function import UndefinedFunction, Function if isinstance(pattern, UndefinedFunction): return any(f.func == pattern or f == pattern for f in self.atoms(Function, UndefinedFunction)) pattern = sympify(pattern) if isinstance(pattern, BasicMeta): return any(isinstance(arg, pattern) for arg in preorder_traversal(self)) _has_matcher = getattr(pattern, '_has_matcher', None) if _has_matcher is not None: match = _has_matcher() return any(match(arg) for arg in preorder_traversal(self)) else: return any(arg == pattern for arg in preorder_traversal(self)) def _has_matcher(self): """Helper for .has()""" return lambda other: self == other def replace(self, query, value, map=False, simultaneous=True, exact=None): """ Replace matching subexpressions of ``self`` with ``value``. If ``map = True`` then also return the mapping {old: new} where ``old`` was a sub-expression found with query and ``new`` is the replacement value for it. If the expression itself doesn't match the query, then the returned value will be ``self.xreplace(map)`` otherwise it should be ``self.subs(ordered(map.items()))``. Traverses an expression tree and performs replacement of matching subexpressions from the bottom to the top of the tree. The default approach is to do the replacement in a simultaneous fashion so changes made are targeted only once. If this is not desired or causes problems, ``simultaneous`` can be set to False. In addition, if an expression containing more than one Wild symbol is being used to match subexpressions and the ``exact`` flag is True, then the match will only succeed if non-zero values are received for each Wild that appears in the match pattern. The list of possible combinations of queries and replacement values is listed below: Examples ======== Initial setup >>> from sympy import log, sin, cos, tan, Wild, Mul, Add >>> from sympy.abc import x, y >>> f = log(sin(x)) + tan(sin(x2)) 1.1. type -> type obj.replace(type, newtype) When object of type ``type`` is found, replace it with the result of passing its argument(s) to ``newtype``. >>> f.replace(sin, cos) log(cos(x)) + tan(cos(x2)) >>> sin(x).replace(sin, cos, map=True) (cos(x), {sin(x): cos(x)}) >>> (xy).replace(Mul, Add) x + y 1.2. type -> func obj.replace(type, func) When object of type ``type`` is found, apply ``func`` to its argument(s). ``func`` must be written to handle the number of arguments of ``type``. >>> f.replace(sin, lambda arg: sin(2arg)) log(sin(2x)) + tan(sin(2x2)) >>> (xy).replace(Mul, lambda args: sin(2Mul(args))) sin(2xy) 2.1. pattern -> expr obj.replace(pattern(wild), expr(wild)) Replace subexpressions matching ``pattern`` with the expression written in terms of the Wild symbols in ``pattern``. >>> a, b = map(Wild, 'ab') >>> f.replace(sin(a), tan(a)) log(tan(x)) + tan(tan(x2)) >>> f.replace(sin(a), tan(a/2)) log(tan(x/2)) + tan(tan(x2/2)) >>> f.replace(sin(a), a) log(x) + tan(x2) >>> (xy).replace(ax, a) y Matching is exact by default when more than one Wild symbol is used: matching fails unless the match gives non-zero values for all Wild symbols: >>> (2x + y).replace(ax + b, b - a) y - 2 >>> (2x).replace(ax + b, b - a) 2x When set to False, the results may be non-intuitive: >>> (2x).replace(ax + b, b - a, exact=False) 2/x 2.2. pattern -> func obj.replace(pattern(wild), lambda wild: expr(wild)) All behavior is the same as in 2.1 but now a function in terms of pattern variables is used rather than an expression: >>> f.replace(sin(a), lambda a: sin(2a)) log(sin(2x)) + tan(sin(2x2)) 3.1. func -> func obj.replace(filter, func) Replace subexpression ``e`` with ``func(e)`` if ``filter(e)`` is True. >>> g = 2sin(x3) >>> g.replace(lambda expr: expr.is_Number, lambda expr: expr2) 4sin(x9) The expression itself is also targeted by the query but is done in such a fashion that changes are not made twice. >>> e = x(xy + 1) >>> e.replace(lambda x: x.is_Mul, lambda x: 2x) 2x(2xy + 1) See Also ======== subs: substitution of subexpressions as defined by the objects themselves. xreplace: exact node replacement in expr tree; also capable of using matching rules """ from sympy.core.symbol import Dummy, Wild from sympy.simplify.simplify import bottom_up try: query = _sympify(query) except SympifyError: pass try: value = _sympify(value) except SympifyError: pass if isinstance(query, type): _query = lambda expr: isinstance(expr, query) if isinstance(value, type): _value = lambda expr, result: value(expr.args) elif callable(value): _value = lambda expr, result: value(expr.args) else: raise TypeError( "given a type, replace() expects another " "type or a callable") elif isinstance(query, Basic): _query = lambda expr: expr.match(query) exact = len(query.atoms(Wild)) > 1 if exact is None else exact if isinstance(value, Basic): if exact: _value = lambda expr, result: (value.subs(result) if all(result.values()) else expr) else: _value = lambda expr, result: value.subs(result) elif callable(value): # match dictionary keys get the trailing underscore stripped # from them and are then passed as keywords to the callable; # if ``exact`` is True, only accept match if there are no null # values amongst those matched. if exact: _value = lambda expr, result: (value( {str(k)[:-1]: v for k, v in result.items()}) if all(val for val in result.values()) else expr) else: _value = lambda expr, result: value( {str(k)[:-1]: v for k, v in result.items()}) else: raise TypeError( "given an expression, replace() expects " "another expression or a callable") elif callable(query): _query = query if callable(value): _value = lambda expr, result: value(expr) else: raise TypeError( "given a callable, replace() expects " "another callable") else: raise TypeError( "first argument to replace() must be a " "type, an expression or a callable") mapping = {} # changes that took place mask = [] # the dummies that were used as change placeholders def rec_replace(expr): result = _query(expr) if result or result == {}: new = _value(expr, result) if new is not None and new != expr: mapping[expr] = new if simultaneous: # don't let this expression be changed during rebuilding com = getattr(new, 'is_commutative', True) if com is None: com = True d = Dummy(commutative=com) mask.append((d, new)) expr = d else: expr = new return expr rv = bottom_up(self, rec_replace, atoms=True) # restore original expressions for Dummy symbols if simultaneous: mask = list(reversed(mask)) for o, n in mask: r = {o: n} rv = rv.xreplace(r) if not map: return rv else: if simultaneous: # restore subexpressions in mapping for o, n in mask: r = {o: n} mapping = {k.xreplace(r): v.xreplace(r) for k, v in mapping.items()} return rv, mapping def find(self, query, group=False): """Find all subexpressions matching a query. """ query = _make_find_query(query) results = list(filter(query, preorder_traversal(self))) if not group: return set(results) else: groups = {} for result in results: if result in groups: groups[result] += 1 else: groups[result] = 1 return groups def count(self, query): """Count the number of matching subexpressions. """ query = _make_find_query(query) return sum(bool(query(sub)) for sub in preorder_traversal(self)) def matches(self, expr, repl_dict={}, old=False): """ Helper method for match() that looks for a match between Wild symbols in self and expressions in expr. Examples ======== >>> from sympy import symbols, Wild, Basic >>> a, b, c = symbols('a b c') >>> x = Wild('x') >>> Basic(a + x, x).matches(Basic(a + b, c)) is None True >>> Basic(a + x, x).matches(Basic(a + b + c, b + c)) {x_: b + c} """ expr = sympify(expr) if not isinstance(expr, self.__class__): return None if self == expr: return repl_dict if len(self.args) != len(expr.args): return None d = repl_dict.copy() for arg, other_arg in zip(self.args, expr.args): if arg == other_arg: continue d = arg.xreplace(d).matches(other_arg, d, old=old) if d is None: return None return d def match(self, pattern, old=False): """ Pattern matching. Wild symbols match all. Return ``None`` when expression (self) does not match with pattern. Otherwise return a dictionary such that:: pattern.xreplace(self.match(pattern)) == self Examples ======== >>> from sympy import Wild >>> from sympy.abc import x, y >>> p = Wild("p") >>> q = Wild("q") >>> r = Wild("r") >>> e = (x+y)(x+y) >>> e.match(pp) {p_: x + y} >>> e.match(p*q) {p_: x + y, q_: x + y} >>> e = (2x)*2 >>> e.match(pq*r) {p_: 4, q_: x, r_: 2} >>> (pq*r).xreplace(e.match(pq*r)) 4x*2 The ``old`` flag will give the old-style pattern matching where expressions and patterns are essentially solved to give the match. Both of the following give None unless ``old=True``: >>> (x - 2).match(p - x, old=True) {p_: 2x - 2} >>> (2/x).match(px, old=True) {p_: 2/x2} """ pattern = sympify(pattern) return pattern.matches(self, old=old) def count_ops(self, visual=None): """wrapper for count_ops that returns the operation count.""" from sympy import count_ops return count_ops(self, visual) def doit(self, hints): """Evaluate objects that are not evaluated by default like limits, integrals, sums and products. All objects of this kind will be evaluated recursively, unless some species were excluded via 'hints' or unless the 'deep' hint was set to 'False'. >>> from sympy import Integral >>> from sympy.abc import x >>> 2Integral(x, x) 2Integral(x, x) >>> (2Integral(x, x)).doit() x*2 >>> (2Integral(x, x)).doit(deep=False) 2Integral(x, x) """ if hints.get('deep', True): terms = [term.doit(hints) if isinstance(term, Basic) else term for term in self.args] return self.func(terms) else: return self def _eval_rewrite(self, pattern, rule, hints): if self.is_Atom: if hasattr(self, rule): return getattr(self, rule)() return self if hints.get('deep', True): args = [a._eval_rewrite(pattern, rule, hints) if isinstance(a, Basic) else a for a in self.args] else: args = self.args if pattern is None or isinstance(self, pattern): if hasattr(self, rule): rewritten = getattr(self, rule)(args, hints) if rewritten is not None: return rewritten return self.func(args) if hints.get('evaluate', True) else self def _accept_eval_derivative(self, s): # This method needs to be overridden by array-like objects return s._visit_eval_derivative_scalar(self) def _visit_eval_derivative_scalar(self, base): # Base is a scalar # Types are (base: scalar, self: scalar) return base._eval_derivative(self) def _visit_eval_derivative_array(self, base): # Types are (base: array/matrix, self: scalar) # Base is some kind of array/matrix, # it should have `.applyfunc(lambda x: x.diff(self)` implemented: return base._eval_derivative_array(self) def _eval_derivative_n_times(self, s, n): # This is the default evaluator for derivatives (as called by `diff` # and `Derivative`), it will attempt a loop to derive the expression # `n` times by calling the corresponding `_eval_derivative` method, # while leaving the derivative unevaluated if `n` is symbolic. This # method should be overridden if the object has a closed form for its # symbolic n-th derivative. from sympy import Integer if isinstance(n, (int, Integer)): obj = self for i in range(n): obj2 = obj._accept_eval_derivative(s) if obj == obj2 or obj2 is None: break obj = obj2 return obj2 else: return None def rewrite(self, args, hints): """ Rewrite functions in terms of other functions. Rewrites expression containing applications of functions of one kind in terms of functions of different kind. For example you can rewrite trigonometric functions as complex exponentials or combinatorial functions as gamma function. As a pattern this function accepts a list of functions to to rewrite (instances of DefinedFunction class). As rule you can use string or a destination function instance (in this case rewrite() will use the str() function). There is also the possibility to pass hints on how to rewrite the given expressions. For now there is only one such hint defined called 'deep'. When 'deep' is set to False it will forbid functions to rewrite their contents. Examples ======== >>> from sympy import sin, exp >>> from sympy.abc import x Unspecified pattern: >>> sin(x).rewrite(exp) -I(exp(Ix) - exp(-Ix))/2 Pattern as a single function: >>> sin(x).rewrite(sin, exp) -I(exp(Ix) - exp(-Ix))/2 Pattern as a list of functions: >>> sin(x).rewrite([sin, ], exp) -I(exp(Ix) - exp(-Ix))/2 """ if not args: return self else: pattern = args[:-1] if isinstance(args[-1], string_types): rule = '_eval_rewrite_as_' + args[-1] else: try: rule = '_eval_rewrite_as_' + args[-1].__name__ except: rule = '_eval_rewrite_as_' + args[-1].__class__.__name__ if not pattern: return self._eval_rewrite(None, rule, hints) else: if iterable(pattern[0]): pattern = pattern[0] pattern = [p for p in pattern if self.has(p)] if pattern: return self._eval_rewrite(tuple(pattern), rule, hints) else: return self _constructor_postprocessor_mapping = {} @classmethod def _exec_constructor_postprocessors(cls, obj): # WARNING: This API is experimental. # This is an experimental API that introduces constructor # postprosessors for SymPy Core elements. If an argument of a SymPy # expression has a `_constructor_postprocessor_mapping` attribute, it will # be interpreted as a dictionary containing lists of postprocessing # functions for matching expression node names. clsname = obj.__class__.__name__ postprocessors = defaultdict(list) for i in obj.args: try: postprocessor_mappings = ( Basic._constructor_postprocessor_mapping[cls].items() for cls in type(i).mro() if cls in Basic._constructor_postprocessor_mapping ) for k, v in chain.from_iterable(postprocessor_mappings): postprocessors[k].extend([j for j in v if j not in postprocessors[k]]) except TypeError: pass for f in postprocessors.get(clsname, []): obj = f(obj) return obj class Atom(Basic): """ A parent class for atomic things. An atom is an expression with no subexpressions. Examples ======== Symbol, Number, Rational, Integer, ... But not: Add, Mul, Pow, ... """ is_Atom = True __slots__ = [] def matches(self, expr, repl_dict={}, old=False): if self == expr: return repl_dict def xreplace(self, rule, hack2=False): return rule.get(self, self) def doit(self, *hints): return self @classmethod def class_key(cls): return 2, 0, cls.__name__ @cacheit def sort_key(self, order=None): return self.class_key(), (1, (str(self),)), S.One.sort_key(), S.One def _eval_simplify(self, ratio, measure, rational, inverse): return self @property def _sorted_args(self): # this is here as a safeguard against accidentally using _sorted_args # on Atoms -- they cannot be rebuilt as atom.func(atom._sorted_args) # since there are no args. So the calling routine should be checking # to see that this property is not called for Atoms. raise AttributeError('Atoms have no args. It might be necessary' ' to make a check for Atoms in the calling code.') def _aresame(a, b): """Return True if a and b are structurally the same, else False. Examples ======== To SymPy, 2.0 == 2: >>> from sympy import S >>> 2.0 == S(2) True Since a simple 'same or not' result is sometimes useful, this routine was written to provide that query: >>> from sympy.core.basic import _aresame >>> _aresame(S(2.0), S(2)) False """ from .function import AppliedUndef, UndefinedFunction as UndefFunc for i, j in zip_longest(preorder_traversal(a), preorder_traversal(b)): if i != j or type(i) != type(j): if ((isinstance(i, UndefFunc) and isinstance(j, UndefFunc)) or (isinstance(i, AppliedUndef) and isinstance(j, AppliedUndef))): if i.class_key() != j.class_key(): return False else: return False return True def _atomic(e, recursive=False): """Return atom-like quantities as far as substitution is concerned: Derivatives, Functions and Symbols. Don't return any 'atoms' that are inside such quantities unless they also appear outside, too, unless `recursive` is True. Examples ======== >>> from sympy import Derivative, Function, cos >>> from sympy.abc import x, y >>> from sympy.core.basic import _atomic >>> f = Function('f') >>> _atomic(x + y) {x, y} >>> _atomic(x + f(y)) {x, f(y)} >>> _atomic(Derivative(f(x), x) + cos(x) + y) {y, cos(x), Derivative(f(x), x)} """ from sympy import Derivative, Function, Symbol pot = preorder_traversal(e) seen = set() if isinstance(e, Basic): free = getattr(e, "free_symbols", None) if free is None: return {e} else: return set() atoms = set() for p in pot: if p in seen: pot.skip() continue seen.add(p) if isinstance(p, Symbol) and p in free: atoms.add(p) elif isinstance(p, (Derivative, Function)): if not recursive: pot.skip() atoms.add(p) return atoms class preorder_traversal(Iterator): """ Do a pre-order traversal of a tree. This iterator recursively yields nodes that it has visited in a pre-order fashion. That is, it yields the current node then descends through the tree breadth-first to yield all of a node's children's pre-order traversal. For an expression, the order of the traversal depends on the order of .args, which in many cases can be arbitrary. Parameters ========== node : sympy expression The expression to traverse. keys : (default None) sort key(s) The key(s) used to sort args of Basic objects. When None, args of Basic objects are processed in arbitrary order. If key is defined, it will be passed along to ordered() as the only key(s) to use to sort the arguments; if ``key`` is simply True then the default keys of ordered will be used. Yields ====== subtree : sympy expression All of the subtrees in the tree. Examples ======== >>> from sympy import symbols >>> from sympy.core.basic import preorder_traversal >>> x, y, z = symbols('x y z') The nodes are returned in the order that they are encountered unless key is given; simply passing key=True will guarantee that the traversal is unique. >>> list(preorder_traversal((x + y)z, keys=None)) # doctest: +SKIP [z(x + y), z, x + y, y, x] >>> list(preorder_traversal((x + y)z, keys=True)) [z(x + y), z, x + y, x, y] """ def __init__(self, node, keys=None): self._skip_flag = False self._pt = self._preorder_traversal(node, keys) def _preorder_traversal(self, node, keys): yield node if self._skip_flag: self._skip_flag = False return if isinstance(node, Basic): if not keys and hasattr(node, '_argset'): # LatticeOp keeps args as a set. We should use this if we # don't care about the order, to prevent unnecessary sorting. args = node._argset else: args = node.args if keys: if keys != True: args = ordered(args, keys, default=False) else: args = ordered(args) for arg in args: for subtree in self._preorder_traversal(arg, keys): yield subtree elif iterable(node): for item in node: for subtree in self._preorder_traversal(item, keys): yield subtree def skip(self): """ Skip yielding current node's (last yielded node's) subtrees. Examples ======== >>> from sympy.core import symbols >>> from sympy.core.basic import preorder_traversal >>> x, y, z = symbols('x y z') >>> pt = preorder_traversal((x+yz)z) >>> for i in pt: ... print(i) ... if i == x+yz: ... pt.skip() z(x + yz) z x + yz """ self._skip_flag = True def __next__(self): return next(self._pt) def __iter__(self): return self def _make_find_query(query): """Convert the argument of Basic.find() into a callable""" try: query = sympify(query) except SympifyError: pass if isinstance(query, type): return lambda expr: isinstance(expr, query) elif isinstance(query, Basic): return lambda expr: expr.match(query) is not None return query
5b80b2c6e01f5d665c9428266977c1c18bc7d2dfe6eb220b4ba50bfebab68d14	from __future__ import print_function, division from math import log as _log from .sympify import _sympify from .cache import cacheit from .singleton import S from .expr import Expr from .evalf import PrecisionExhausted from .function import (_coeff_isneg, expand_complex, expand_multinomial, expand_mul) from .logic import fuzzy_bool, fuzzy_not, fuzzy_and from .compatibility import as_int, range from .evaluate import global_evaluate from sympy.utilities.iterables import sift from mpmath.libmp import sqrtrem as mpmath_sqrtrem from math import sqrt as _sqrt def isqrt(n): """Return the largest integer less than or equal to sqrt(n).""" if n < 17984395633462800708566937239552: return int(_sqrt(n)) return integer_nthroot(int(n), 2)[0] def integer_nthroot(y, n): """ Return a tuple containing x = floor(y(1/n)) and a boolean indicating whether the result is exact (that is, whether xn == y). Examples ======== >>> from sympy import integer_nthroot >>> integer_nthroot(16, 2) (4, True) >>> integer_nthroot(26, 2) (5, False) To simply determine if a number is a perfect square, the is_square function should be used: >>> from sympy.ntheory.primetest import is_square >>> is_square(26) False See Also ======== sympy.ntheory.primetest.is_square integer_log """ y, n = as_int(y), as_int(n) if y < 0: raise ValueError("y must be nonnegative") if n < 1: raise ValueError("n must be positive") if y in (0, 1): return y, True if n == 1: return y, True if n == 2: x, rem = mpmath_sqrtrem(y) return int(x), not rem if n > y: return 1, False # Get initial estimate for Newton's method. Care must be taken to # avoid overflow try: guess = int(y(1./n) + 0.5) except OverflowError: exp = _log(y, 2)/n if exp > 53: shift = int(exp - 53) guess = int(2.0(exp - shift) + 1) << shift else: guess = int(2.0exp) if guess > 250: # Newton iteration xprev, x = -1, guess while 1: t = x*(n - 1) xprev, x = x, ((n - 1)x + y//t)//n if abs(x - xprev) < 2: break else: x = guess # Compensate t = xn while t < y: x += 1 t = xn while t > y: x -= 1 t = xn return int(x), t == y # int converts long to int if possible def integer_log(y, x): """Returns (e, bool) where e is the largest nonnegative integer such that \|y\| >= \|xe\| and bool is True if y == xe Examples ======== >>> from sympy import integer_log >>> integer_log(125, 5) (3, True) >>> integer_log(17, 9) (1, False) >>> integer_log(4, -2) (2, True) >>> integer_log(-125,-5) (3, True) See Also ======== integer_nthroot sympy.ntheory.primetest.is_square sympy.ntheory.factor_.multiplicity sympy.ntheory.factor_.perfect_power """ if x == 1: raise ValueError('x cannot take value as 1') if y == 0: raise ValueError('y cannot take value as 0') if x in (-2, 2): x = int(x) y = as_int(y) e = y.bit_length() - 1 return e, xe == y if x < 0: n, b = integer_log(y if y > 0 else -y, -x) return n, b and bool(n % 2 if y < 0 else not n % 2) x = as_int(x) y = as_int(y) r = e = 0 while y >= x: d = x m = 1 while y >= d: y, rem = divmod(y, d) r = r or rem e += m if y > d: d = d m = 2 return e, r == 0 and y == 1 class Pow(Expr): """ Defines the expression xy as "x raised to a power y" Singleton definitions involving (0, 1, -1, oo, -oo, I, -I): +--------------+---------+-----------------------------------------------+ \| expr \| value \| reason \| +==============+=========+===============================================+ \| z0 \| 1 \| Although arguments over 00 exist, see [2]. \| +--------------+---------+-----------------------------------------------+ \| z1 \| z \| \| +--------------+---------+-----------------------------------------------+ \| (-oo)(-1) \| 0 \| \| +--------------+---------+-----------------------------------------------+ \| (-1)-1 \| -1 \| \| +--------------+---------+-----------------------------------------------+ \| S.Zero-1 \| zoo \| This is not strictly true, as 0-1 may be \| \| \| \| undefined, but is convenient in some contexts \| \| \| \| where the base is assumed to be positive. \| +--------------+---------+-----------------------------------------------+ \| 1-1 \| 1 \| \| +--------------+---------+-----------------------------------------------+ \| oo-1 \| 0 \| \| +--------------+---------+-----------------------------------------------+ \| 0oo \| 0 \| Because for all complex numbers z near \| \| \| \| 0, zoo -> 0. \| +--------------+---------+-----------------------------------------------+ \| 0-oo \| zoo \| This is not strictly true, as 0oo may be \| \| \| \| oscillating between positive and negative \| \| \| \| values or rotating in the complex plane. \| \| \| \| It is convenient, however, when the base \| \| \| \| is positive. \| +--------------+---------+-----------------------------------------------+ \| 1oo \| nan \| Because there are various cases where \| \| 1-oo \| \| lim(x(t),t)=1, lim(y(t),t)=oo (or -oo), \| \| \| \| but lim( x(t)y(t), t) != 1. See [3]. \| +--------------+---------+-----------------------------------------------+ \| bzoo \| nan \| Because bz has no limit as z -> zoo \| +--------------+---------+-----------------------------------------------+ \| (-1)oo \| nan \| Because of oscillations in the limit. \| \| (-1)(-oo) \| \| \| +--------------+---------+-----------------------------------------------+ \| oooo \| oo \| \| +--------------+---------+-----------------------------------------------+ \| oo-oo \| 0 \| \| +--------------+---------+-----------------------------------------------+ \| (-oo)oo \| nan \| \| \| (-oo)-oo \| \| \| +--------------+---------+-----------------------------------------------+ \| ooI \| nan \| ooe could probably be best thought of as \| \| (-oo)I \| \| the limit of xe for real x as x tends to \| \| \| \| oo. If e is I, then the limit does not exist \| \| \| \| and nan is used to indicate that. \| +--------------+---------+-----------------------------------------------+ \| oo(1+I) \| zoo \| If the real part of e is positive, then the \| \| (-oo)(1+I) \| \| limit of abs(xe) is oo. So the limit value \| \| \| \| is zoo. \| +--------------+---------+-----------------------------------------------+ \| oo(-1+I) \| 0 \| If the real part of e is negative, then the \| \| -oo(-1+I) \| \| limit is 0. \| +--------------+---------+-----------------------------------------------+ Because symbolic computations are more flexible that floating point calculations and we prefer to never return an incorrect answer, we choose not to conform to all IEEE 754 conventions. This helps us avoid extra test-case code in the calculation of limits. See Also ======== sympy.core.numbers.Infinity sympy.core.numbers.NegativeInfinity sympy.core.numbers.NaN References ========== .. [1] https://en.wikipedia.org/wiki/Exponentiation .. [2] https://en.wikipedia.org/wiki/Exponentiation#Zero_to_the_power_of_zero .. [3] https://en.wikipedia.org/wiki/Indeterminate_forms """ is_Pow = True __slots__ = ['is_commutative'] @cacheit def __new__(cls, b, e, evaluate=None): if evaluate is None: evaluate = global_evaluate[0] from sympy.functions.elementary.exponential import exp_polar b = _sympify(b) e = _sympify(e) if evaluate: if e is S.ComplexInfinity: return S.NaN if e is S.Zero: return S.One elif e is S.One: return b # Only perform autosimplification if exponent or base is a Symbol or number elif (b.is_Symbol or b.is_number) and (e.is_Symbol or e.is_number) and\ e.is_integer and _coeff_isneg(b): if e.is_even: b = -b elif e.is_odd: return -Pow(-b, e) if S.NaN in (b, e): # XXX S.NaNx -> S.NaN under assumption that x != 0 return S.NaN elif b is S.One: if abs(e).is_infinite: return S.NaN return S.One else: # recognize base as E if not e.is_Atom and b is not S.Exp1 and not isinstance(b, exp_polar): from sympy import numer, denom, log, sign, im, factor_terms c, ex = factor_terms(e, sign=False).as_coeff_Mul() den = denom(ex) if isinstance(den, log) and den.args[0] == b: return S.Exp1(cnumer(ex)) elif den.is_Add: s = sign(im(b)) if s.is_Number and s and den == \ log(-factor_terms(b, sign=False)) + sS.ImaginaryUnitS.Pi: return S.Exp1(cnumer(ex)) obj = b._eval_power(e) if obj is not None: return obj obj = Expr.__new__(cls, b, e) obj = cls._exec_constructor_postprocessors(obj) if not isinstance(obj, Pow): return obj obj.is_commutative = (b.is_commutative and e.is_commutative) return obj @property def base(self): return self._args[0] @property def exp(self): return self._args[1] @classmethod def class_key(cls): return 3, 2, cls.__name__ def _eval_refine(self, assumptions): from sympy.assumptions.ask import ask, Q b, e = self.as_base_exp() if ask(Q.integer(e), assumptions) and _coeff_isneg(b): if ask(Q.even(e), assumptions): return Pow(-b, e) elif ask(Q.odd(e), assumptions): return -Pow(-b, e) def _eval_power(self, other): from sympy import Abs, arg, exp, floor, im, log, re, sign b, e = self.as_base_exp() if b is S.NaN: return (be)other # let __new__ handle it s = None if other.is_integer: s = 1 elif b.is_polar: # e.g. exp_polar, besselj, var('p', polar=True)... s = 1 elif e.is_real is not None: # helper functions =========================== def _half(e): """Return True if the exponent has a literal 2 as the denominator, else None.""" if getattr(e, 'q', None) == 2: return True n, d = e.as_numer_denom() if n.is_integer and d == 2: return True def _n2(e): """Return ``e`` evaluated to a Number with 2 significant digits, else None.""" try: rv = e.evalf(2, strict=True) if rv.is_Number: return rv except PrecisionExhausted: pass # =================================================== if e.is_real: # we need _half(other) with constant floor or # floor(S.Half - earg(b)/2/pi) == 0 # handle -1 as special case if e == -1: # floor arg. is 1/2 + arg(b)/2/pi if _half(other): if b.is_negative is True: return S.NegativeOneotherPow(-b, eother) if b.is_real is False: return Pow(b.conjugate()/Abs(b)2, other) elif e.is_even: if b.is_real: b = abs(b) if b.is_imaginary: b = abs(im(b))S.ImaginaryUnit if (abs(e) < 1) == True or e == 1: s = 1 # floor = 0 elif b.is_nonnegative: s = 1 # floor = 0 elif re(b).is_nonnegative and (abs(e) < 2) == True: s = 1 # floor = 0 elif fuzzy_not(im(b).is_zero) and abs(e) == 2: s = 1 # floor = 0 elif _half(other): s = exp(2S.PiS.ImaginaryUnitotherfloor( S.Half - earg(b)/(2S.Pi))) if s.is_real and _n2(sign(s) - s) == 0: s = sign(s) else: s = None else: # e.is_real is False requires: # _half(other) with constant floor or # floor(S.Half - im(elog(b))/2/pi) == 0 try: s = exp(2S.ImaginaryUnitS.Piother* floor(S.Half - im(elog(b))/2/S.Pi)) # be careful to test that s is -1 or 1 b/c sign(I) == I: # so check that s is real if s.is_real and _n2(sign(s) - s) == 0: s = sign(s) else: s = None except PrecisionExhausted: s = None if s is not None: return sPow(b, eother) def _eval_Mod(self, q): if self.exp.is_integer and self.exp.is_positive: if q.is_integer and self.base % q == 0: return S.Zero ''' For unevaluated Integer power, use built-in pow modular exponentiation, if powers are not too large wrt base. ''' if self.base.is_Integer and self.exp.is_Integer and q.is_Integer: b, e, m = int(self.base), int(self.exp), int(q) # For very large powers, use totient reduction if e >= lg(m). # Bound on m, is for safe factorization memory wise ie m^(1/4). # For pollard-rho to be faster than built-in pow lg(e) > m^(1/4) # check is added. mb = m.bit_length() if mb <= 80 and e >= mb and e.bit_length()4 >= m: from sympy.ntheory import totient phi = totient(m) return pow(b, phi + e%phi, m) else: return pow(b, e, m) def _eval_is_even(self): if self.exp.is_integer and self.exp.is_positive: return self.base.is_even def _eval_is_positive(self): from sympy import log if self.base == self.exp: if self.base.is_nonnegative: return True elif self.base.is_positive: if self.exp.is_real: return True elif self.base.is_negative: if self.exp.is_even: return True if self.exp.is_odd: return False elif self.base.is_zero: if self.exp.is_real: return self.exp.is_zero elif self.base.is_nonpositive: if self.exp.is_odd: return False elif self.base.is_imaginary: if self.exp.is_integer: m = self.exp % 4 if m.is_zero: return True if m.is_integer and m.is_zero is False: return False if self.exp.is_imaginary: return log(self.base).is_imaginary def _eval_is_negative(self): if self.base.is_negative: if self.exp.is_odd: return True if self.exp.is_even: return False elif self.base.is_positive: if self.exp.is_real: return False elif self.base.is_zero: if self.exp.is_real: return False elif self.base.is_nonnegative: if self.exp.is_nonnegative: return False elif self.base.is_nonpositive: if self.exp.is_even: return False elif self.base.is_real: if self.exp.is_even: return False def _eval_is_zero(self): if self.base.is_zero: if self.exp.is_positive: return True elif self.exp.is_nonpositive: return False elif self.base.is_zero is False: if self.exp.is_finite: return False elif self.exp.is_infinite: if (1 - abs(self.base)).is_positive: return self.exp.is_positive elif (1 - abs(self.base)).is_negative: return self.exp.is_negative else: # when self.base.is_zero is None return None def _eval_is_integer(self): b, e = self.args if b.is_rational: if b.is_integer is False and e.is_positive: return False # ratnonneg if b.is_integer and e.is_integer: if b is S.NegativeOne: return True if e.is_nonnegative or e.is_positive: return True if b.is_integer and e.is_negative and (e.is_finite or e.is_integer): if fuzzy_not((b - 1).is_zero) and fuzzy_not((b + 1).is_zero): return False if b.is_Number and e.is_Number: check = self.func(self.args) return check.is_Integer def _eval_is_real(self): from sympy import arg, exp, log, Mul real_b = self.base.is_real if real_b is None: if self.base.func == exp and self.base.args[0].is_imaginary: return self.exp.is_imaginary return real_e = self.exp.is_real if real_e is None: return if real_b and real_e: if self.base.is_positive: return True elif self.base.is_nonnegative: if self.exp.is_nonnegative: return True else: if self.exp.is_integer: return True elif self.base.is_negative: if self.exp.is_Rational: return False if real_e and self.exp.is_negative: return Pow(self.base, -self.exp).is_real im_b = self.base.is_imaginary im_e = self.exp.is_imaginary if im_b: if self.exp.is_integer: if self.exp.is_even: return True elif self.exp.is_odd: return False elif im_e and log(self.base).is_imaginary: return True elif self.exp.is_Add: c, a = self.exp.as_coeff_Add() if c and c.is_Integer: return Mul( self.basec, self.basea, evaluate=False).is_real elif self.base in (-S.ImaginaryUnit, S.ImaginaryUnit): if (self.exp/2).is_integer is False: return False if real_b and im_e: if self.base is S.NegativeOne: return True c = self.exp.coeff(S.ImaginaryUnit) if c: ok = (clog(self.base)/S.Pi).is_Integer if ok is not None: return ok if real_b is False: # we already know it's not imag i = arg(self.base)self.exp/S.Pi return i.is_integer def _eval_is_complex(self): if all(a.is_complex for a in self.args): return True def _eval_is_imaginary(self): from sympy import arg, log if self.base.is_imaginary: if self.exp.is_integer: odd = self.exp.is_odd if odd is not None: return odd return if self.exp.is_imaginary: imlog = log(self.base).is_imaginary if imlog is not None: return False # I*i -> real; (2I)*i -> complex ==> not imaginary if self.base.is_real and self.exp.is_real: if self.base.is_positive: return False else: rat = self.exp.is_rational if not rat: return rat if self.exp.is_integer: return False else: half = (2self.exp).is_integer if half: return self.base.is_negative return half if self.base.is_real is False: # we already know it's not imag i = arg(self.base)self.exp/S.Pi isodd = (2i).is_odd if isodd is not None: return isodd if self.exp.is_negative: return (1/self).is_imaginary def _eval_is_odd(self): if self.exp.is_integer: if self.exp.is_positive: return self.base.is_odd elif self.exp.is_nonnegative and self.base.is_odd: return True elif self.base is S.NegativeOne: return True def _eval_is_finite(self): if self.exp.is_negative: if self.base.is_zero: return False if self.base.is_infinite: return True c1 = self.base.is_finite if c1 is None: return c2 = self.exp.is_finite if c2 is None: return if c1 and c2: if self.exp.is_nonnegative or fuzzy_not(self.base.is_zero): return True def _eval_is_prime(self): ''' An integer raised to the n(>=2)-th power cannot be a prime. ''' if self.base.is_integer and self.exp.is_integer and (self.exp - 1).is_positive: return False def _eval_is_composite(self): """ A power is composite if both base and exponent are greater than 1 """ if (self.base.is_integer and self.exp.is_integer and ((self.base - 1).is_positive and (self.exp - 1).is_positive or (self.base + 1).is_negative and self.exp.is_positive and self.exp.is_even)): return True def _eval_is_polar(self): return self.base.is_polar def _eval_subs(self, old, new): from sympy import exp, log, Symbol def _check(ct1, ct2, old): """Return (bool, pow, remainder_pow) where, if bool is True, then the exponent of Pow `old` will combine with `pow` so the substitution is valid, otherwise bool will be False. For noncommutative objects, `pow` will be an integer, and a factor `Pow(old.base, remainder_pow)` needs to be included. If there is no such factor, None is returned. For commutative objects, remainder_pow is always None. cti are the coefficient and terms of an exponent of self or old In this _eval_subs routine a change like (b*(2x)).subs(bx, y) will give y2 since (bx)2 == b*(2x); if that equality does not hold then the substitution should not occur so `bool` will be False. """ coeff1, terms1 = ct1 coeff2, terms2 = ct2 if terms1 == terms2: if old.is_commutative: # Allow fractional powers for commutative objects pow = coeff1/coeff2 try: pow = as_int(pow, strict=False) combines = True except ValueError: combines = isinstance(Pow._eval_power( Pow(old.as_base_exp(), evaluate=False), pow), (Pow, exp, Symbol)) return combines, pow, None else: # With noncommutative symbols, substitute only integer powers if not isinstance(terms1, tuple): terms1 = (terms1,) if not all(term.is_integer for term in terms1): return False, None, None try: # Round pow toward zero pow, remainder = divmod(as_int(coeff1), as_int(coeff2)) if pow < 0 and remainder != 0: pow += 1 remainder -= as_int(coeff2) if remainder == 0: remainder_pow = None else: remainder_pow = Mul(remainder, terms1) return True, pow, remainder_pow except ValueError: # Can't substitute pass return False, None, None if old == self.base: return newself.exp._subs(old, new) # issue 10829: (4x - 3y + 2).subs(2x, y) -> y2 - 3y + 2 if isinstance(old, self.func) and self.exp == old.exp: l = log(self.base, old.base) if l.is_Number: return Pow(new, l) if isinstance(old, self.func) and self.base == old.base: if self.exp.is_Add is False: ct1 = self.exp.as_independent(Symbol, as_Add=False) ct2 = old.exp.as_independent(Symbol, as_Add=False) ok, pow, remainder_pow = _check(ct1, ct2, old) if ok: # issue 5180: (x*(6y)).subs(x*(3y),z)->z2 result = self.func(new, pow) if remainder_pow is not None: result = Mul(result, Pow(old.base, remainder_pow)) return result else: # b(6x + a).subs(b(3x), y) -> y*2 ba # exp(exp(x) + exp(x2)).subs(exp(exp(x)), w) -> w * exp(exp(x2)) oarg = old.exp new_l = [] o_al = [] ct2 = oarg.as_coeff_mul() for a in self.exp.args: newa = a._subs(old, new) ct1 = newa.as_coeff_mul() ok, pow, remainder_pow = _check(ct1, ct2, old) if ok: new_l.append(newpow) if remainder_pow is not None: o_al.append(remainder_pow) continue elif not old.is_commutative and not newa.is_integer: # If any term in the exponent is non-integer, # we do not do any substitutions in the noncommutative case return o_al.append(newa) if new_l: expo = Add(o_al) new_l.append(Pow(self.base, expo, evaluate=False) if expo != 1 else self.base) return Mul(new_l) if isinstance(old, exp) and self.exp.is_real and self.base.is_positive: ct1 = old.args[0].as_independent(Symbol, as_Add=False) ct2 = (self.explog(self.base)).as_independent( Symbol, as_Add=False) ok, pow, remainder_pow = _check(ct1, ct2, old) if ok: result = self.func(new, pow) # (2x).subs(exp(xlog(2)), z) -> z if remainder_pow is not None: result = Mul(result, Pow(old.base, remainder_pow)) return result def as_base_exp(self): """Return base and exp of self. If base is 1/Integer, then return Integer, -exp. If this extra processing is not needed, the base and exp properties will give the raw arguments Examples ======== >>> from sympy import Pow, S >>> p = Pow(S.Half, 2, evaluate=False) >>> p.as_base_exp() (2, -2) >>> p.args (1/2, 2) """ b, e = self.args if b.is_Rational and b.p == 1 and b.q != 1: return Integer(b.q), -e return b, e def _eval_adjoint(self): from sympy.functions.elementary.complexes import adjoint i, p = self.exp.is_integer, self.base.is_positive if i: return adjoint(self.base)self.exp if p: return self.baseadjoint(self.exp) if i is False and p is False: expanded = expand_complex(self) if expanded != self: return adjoint(expanded) def _eval_conjugate(self): from sympy.functions.elementary.complexes import conjugate as c i, p = self.exp.is_integer, self.base.is_positive if i: return c(self.base)self.exp if p: return self.basec(self.exp) if i is False and p is False: expanded = expand_complex(self) if expanded != self: return c(expanded) if self.is_real: return self def _eval_transpose(self): from sympy.functions.elementary.complexes import transpose i, p = self.exp.is_integer, self.base.is_complex if p: return self.baseself.exp if i: return transpose(self.base)self.exp if i is False and p is False: expanded = expand_complex(self) if expanded != self: return transpose(expanded) def _eval_expand_power_exp(self, hints): """a(n + m) -> a*na*m""" b = self.base e = self.exp if e.is_Add and e.is_commutative: expr = [] for x in e.args: expr.append(self.func(self.base, x)) return Mul(expr) return self.func(b, e) def _eval_expand_power_base(self, *hints): """(ab)n -> an * bn""" force = hints.get('force', False) b = self.base e = self.exp if not b.is_Mul: return self cargs, nc = b.args_cnc(split_1=False) # expand each term - this is top-level-only # expansion but we have to watch out for things # that don't have an _eval_expand method if nc: nc = [i._eval_expand_power_base(hints) if hasattr(i, '_eval_expand_power_base') else i for i in nc] if e.is_Integer: if e.is_positive: rv = Mul(nce) else: rv = Mul([i-1 for i in nc[::-1]]-e) if cargs: rv = Mul(cargs)*e return rv if not cargs: return self.func(Mul(nc), e, evaluate=False) nc = [Mul(nc)] # sift the commutative bases other, maybe_real = sift(cargs, lambda x: x.is_real is False, binary=True) def pred(x): if x is S.ImaginaryUnit: return S.ImaginaryUnit polar = x.is_polar if polar: return True if polar is None: return fuzzy_bool(x.is_nonnegative) sifted = sift(maybe_real, pred) nonneg = sifted[True] other += sifted[None] neg = sifted[False] imag = sifted[S.ImaginaryUnit] if imag: I = S.ImaginaryUnit i = len(imag) % 4 if i == 0: pass elif i == 1: other.append(I) elif i == 2: if neg: nonn = -neg.pop() if nonn is not S.One: nonneg.append(nonn) else: neg.append(S.NegativeOne) else: if neg: nonn = -neg.pop() if nonn is not S.One: nonneg.append(nonn) else: neg.append(S.NegativeOne) other.append(I) del imag # bring out the bases that can be separated from the base if force or e.is_integer: # treat all commutatives the same and put nc in other cargs = nonneg + neg + other other = nc else: # this is just like what is happening automatically, except # that now we are doing it for an arbitrary exponent for which # no automatic expansion is done assert not e.is_Integer # handle negatives by making them all positive and putting # the residual -1 in other if len(neg) > 1: o = S.One if not other and neg[0].is_Number: o = neg.pop(0) if len(neg) % 2: o = -o for n in neg: nonneg.append(-n) if o is not S.One: other.append(o) elif neg and other: if neg[0].is_Number and neg[0] is not S.NegativeOne: other.append(S.NegativeOne) nonneg.append(-neg[0]) else: other.extend(neg) else: other.extend(neg) del neg cargs = nonneg other += nc rv = S.One if cargs: rv = Mul([self.func(b, e, evaluate=False) for b in cargs]) if other: rv = self.func(Mul(other), e, evaluate=False) return rv def _eval_expand_multinomial(self, hints): """(a + b + ..)n -> a*n + na*(n-1)b + .., n is nonzero integer""" base, exp = self.args result = self if exp.is_Rational and exp.p > 0 and base.is_Add: if not exp.is_Integer: n = Integer(exp.p // exp.q) if not n: return result else: radical, result = self.func(base, exp - n), [] expanded_base_n = self.func(base, n) if expanded_base_n.is_Pow: expanded_base_n = \ expanded_base_n._eval_expand_multinomial() for term in Add.make_args(expanded_base_n): result.append(termradical) return Add(result) n = int(exp) if base.is_commutative: order_terms, other_terms = [], [] for b in base.args: if b.is_Order: order_terms.append(b) else: other_terms.append(b) if order_terms: # (f(x) + O(x^n))^m -> f(x)^m + mf(x)^{m-1} O(x^n) f = Add(other_terms) o = Add(order_terms) if n == 2: return expand_multinomial(f*n, deep=False) + nfo else: g = expand_multinomial(f(n - 1), deep=False) return expand_mul(fg, deep=False) + ngo if base.is_number: # Efficiently expand expressions of the form (a + bI)n # where 'a' and 'b' are real numbers and 'n' is integer. a, b = base.as_real_imag() if a.is_Rational and b.is_Rational: if not a.is_Integer: if not b.is_Integer: k = self.func(a.q b.q, n) a, b = a.pb.q, a.qb.p else: k = self.func(a.q, n) a, b = a.p, a.qb elif not b.is_Integer: k = self.func(b.q, n) a, b = ab.q, b.p else: k = 1 a, b, c, d = int(a), int(b), 1, 0 while n: if n & 1: c, d = ac - bd, bc + ad n -= 1 a, b = aa - bb, 2ab n //= 2 I = S.ImaginaryUnit if k == 1: return c + Id else: return Integer(c)/k + Id/k p = other_terms # (x + y)3 -> x3 + 3x2y + 3xy2 + y3 # in this particular example: # p = [x,y]; n = 3 # so now it's easy to get the correct result -- we get the # coefficients first: from sympy import multinomial_coefficients from sympy.polys.polyutils import basic_from_dict expansion_dict = multinomial_coefficients(len(p), n) # in our example: {(3, 0): 1, (1, 2): 3, (0, 3): 1, (2, 1): 3} # and now construct the expression. return basic_from_dict(expansion_dict, p) else: if n == 2: return Add([fg for f in base.args for g in base.args]) else: multi = (base(n - 1))._eval_expand_multinomial() if multi.is_Add: return Add([fg for f in base.args for g in multi.args]) else: # XXX can this ever happen if base was an Add? return Add([fmulti for f in base.args]) elif (exp.is_Rational and exp.p < 0 and base.is_Add and abs(exp.p) > exp.q): return 1 / self.func(base, -exp)._eval_expand_multinomial() elif exp.is_Add and base.is_Number: # a + b a b # n --> n n , where n, a, b are Numbers coeff, tail = S.One, S.Zero for term in exp.args: if term.is_Number: coeff = self.func(base, term) else: tail += term return coeff * self.func(base, tail) else: return result def as_real_imag(self, deep=True, hints): from sympy import atan2, cos, im, re, sin from sympy.polys.polytools import poly if self.exp.is_Integer: exp = self.exp re, im = self.base.as_real_imag(deep=deep) if not im: return self, S.Zero a, b = symbols('a b', cls=Dummy) if exp >= 0: if re.is_Number and im.is_Number: # We can be more efficient in this case expr = expand_multinomial(self.baseexp) if expr != self: return expr.as_real_imag() expr = poly( (a + b)*exp) # a = re, b = im; expr = (a + bI)exp else: mag = re2 + im*2 re, im = re/mag, -im/mag if re.is_Number and im.is_Number: # We can be more efficient in this case expr = expand_multinomial((re + imS.ImaginaryUnit)-exp) if expr != self: return expr.as_real_imag() expr = poly((a + b)-exp) # Terms with even b powers will be real r = [i for i in expr.terms() if not i[0][1] % 2] re_part = Add([cca*aab*bb for (aa, bb), cc in r]) # Terms with odd b powers will be imaginary r = [i for i in expr.terms() if i[0][1] % 4 == 1] im_part1 = Add([ccaaab*bb for (aa, bb), cc in r]) r = [i for i in expr.terms() if i[0][1] % 4 == 3] im_part3 = Add([ccaaab*bb for (aa, bb), cc in r]) return (re_part.subs({a: re, b: S.ImaginaryUnitim}), im_part1.subs({a: re, b: im}) + im_part3.subs({a: re, b: -im})) elif self.exp.is_Rational: re, im = self.base.as_real_imag(deep=deep) if im.is_zero and self.exp is S.Half: if re.is_nonnegative: return self, S.Zero if re.is_nonpositive: return S.Zero, (-self.base)self.exp # XXX: This is not totally correct since for x(p/q) with # x being imaginary there are actually q roots, but # only a single one is returned from here. r = self.func(self.func(re, 2) + self.func(im, 2), S.Half) t = atan2(im, re) rp, tp = self.func(r, self.exp), tself.exp return (rpcos(tp), rpsin(tp)) else: if deep: hints['complex'] = False expanded = self.expand(deep, hints) if hints.get('ignore') == expanded: return None else: return (re(expanded), im(expanded)) else: return (re(self), im(self)) def _eval_derivative(self, s): from sympy import log dbase = self.base.diff(s) dexp = self.exp.diff(s) return self (dexp * log(self.base) + dbase * self.exp/self.base) def _eval_evalf(self, prec): base, exp = self.as_base_exp() base = base._evalf(prec) if not exp.is_Integer: exp = exp._evalf(prec) if exp.is_negative and base.is_number and base.is_real is False: base = base.conjugate() / (base * base.conjugate())._evalf(prec) exp = -exp return self.func(base, exp).expand() return self.func(base, exp) def _eval_is_polynomial(self, syms): if self.exp.has(syms): return False if self.base.has(syms): return bool(self.base._eval_is_polynomial(syms) and self.exp.is_Integer and (self.exp >= 0)) else: return True def _eval_is_rational(self): # The evaluation of self.func below can be very expensive in the case # of integer*integer if the exponent is large. We should try to exit # before that if possible: if (self.exp.is_integer and self.base.is_rational and fuzzy_not(fuzzy_and([self.exp.is_negative, self.base.is_zero]))): return True p = self.func(self.as_base_exp()) # in case it's unevaluated if not p.is_Pow: return p.is_rational b, e = p.as_base_exp() if e.is_Rational and b.is_Rational: # we didn't check that e is not an Integer # because RationalInteger autosimplifies return False if e.is_integer: if b.is_rational: if fuzzy_not(b.is_zero) or e.is_nonnegative: return True if b == e: # always rational, even for 00 return True elif b.is_irrational: return e.is_zero def _eval_is_algebraic(self): def _is_one(expr): try: return (expr - 1).is_zero except ValueError: # when the operation is not allowed return False if self.base.is_zero or _is_one(self.base): return True elif self.exp.is_rational: if self.base.is_algebraic is False: return self.exp.is_zero return self.base.is_algebraic elif self.base.is_algebraic and self.exp.is_algebraic: if ((fuzzy_not(self.base.is_zero) and fuzzy_not(_is_one(self.base))) or self.base.is_integer is False or self.base.is_irrational): return self.exp.is_rational def _eval_is_rational_function(self, syms): if self.exp.has(syms): return False if self.base.has(syms): return self.base._eval_is_rational_function(syms) and \ self.exp.is_Integer else: return True def _eval_is_algebraic_expr(self, syms): if self.exp.has(syms): return False if self.base.has(syms): return self.base._eval_is_algebraic_expr(syms) and \ self.exp.is_Rational else: return True def _eval_rewrite_as_exp(self, base, expo, kwargs): from sympy import exp, log, I, arg if base.is_zero or base.has(exp) or expo.has(exp): return baseexpo if base.has(Symbol): # delay evaluation if expo is non symbolic # (as exp(xlog(5)) automatically reduces to x5) return exp(log(base)expo, evaluate=expo.has(Symbol)) else: return exp((log(abs(base)) + Iarg(base))expo) def as_numer_denom(self): if not self.is_commutative: return self, S.One base, exp = self.as_base_exp() n, d = base.as_numer_denom() # this should be the same as ExpBase.as_numer_denom wrt # exponent handling neg_exp = exp.is_negative if not neg_exp and not (-exp).is_negative: neg_exp = _coeff_isneg(exp) int_exp = exp.is_integer # the denominator cannot be separated from the numerator if # its sign is unknown unless the exponent is an integer, e.g. # sqrt(a/b) != sqrt(a)/sqrt(b) when a=1 and b=-1. But if the # denominator is negative the numerator and denominator can # be negated and the denominator (now positive) separated. if not (d.is_real or int_exp): n = base d = S.One dnonpos = d.is_nonpositive if dnonpos: n, d = -n, -d elif dnonpos is None and not int_exp: n = base d = S.One if neg_exp: n, d = d, n exp = -exp if exp.is_infinite: if n is S.One and d is not S.One: return n, self.func(d, exp) if n is not S.One and d is S.One: return self.func(n, exp), d return self.func(n, exp), self.func(d, exp) def matches(self, expr, repl_dict={}, old=False): expr = _sympify(expr) # special case, pattern = 1 and expr.exp can match to 0 if expr is S.One: d = repl_dict.copy() d = self.exp.matches(S.Zero, d) if d is not None: return d # make sure the expression to be matched is an Expr if not isinstance(expr, Expr): return None b, e = expr.as_base_exp() # special case number sb, se = self.as_base_exp() if sb.is_Symbol and se.is_Integer and expr: if e.is_rational: return sb.matches(b(e/se), repl_dict) return sb.matches(expr(1/se), repl_dict) d = repl_dict.copy() d = self.base.matches(b, d) if d is None: return None d = self.exp.xreplace(d).matches(e, d) if d is None: return Expr.matches(self, expr, repl_dict) return d def _eval_nseries(self, x, n, logx): # NOTE! This function is an important part of the gruntz algorithm # for computing limits. It has to return a generalized power # series with coefficients in C(log, log(x)). In more detail: # It has to return an expression # c_0xe_0 + c_1xe_1 + ... (finitely many terms) # where e_i are numbers (not necessarily integers) and c_i are # expressions involving only numbers, the log function, and log(x). from sympy import ceiling, collect, exp, log, O, Order, powsimp b, e = self.args if e.is_Integer: if e > 0: # positive integer powers are easy to expand, e.g.: # sin(x)4 = (x - x3/3 + ...)4 = ... return expand_multinomial(self.func(b._eval_nseries(x, n=n, logx=logx), e), deep=False) elif e is S.NegativeOne: # this is also easy to expand using the formula: # 1/(1 + x) = 1 - x + x2 - x3 ... # so we need to rewrite base to the form "1 + x" nuse = n cf = 1 try: ord = b.as_leading_term(x) cf = Order(ord, x).getn() if cf and cf.is_Number: nuse = n + 2ceiling(cf) else: cf = 1 except NotImplementedError: pass b_orig, prefactor = b, O(1, x) while prefactor.is_Order: nuse += 1 b = b_orig._eval_nseries(x, n=nuse, logx=logx) prefactor = b.as_leading_term(x) # express "rest" as: rest = 1 + kxl + ... + O(xn) rest = expand_mul((b - prefactor)/prefactor) if rest.is_Order: return 1/prefactor + rest/prefactor + O(xn, x) k, l = rest.leadterm(x) if l.is_Rational and l > 0: pass elif l.is_number and l > 0: l = l.evalf() elif l == 0: k = k.simplify() if k == 0: # if prefactor == w4 + x*2w*4 + 2xw4, we need to # factor the w4 out using collect: return 1/collect(prefactor, x) else: raise NotImplementedError() else: raise NotImplementedError() if cf < 0: cf = S.One/abs(cf) try: dn = Order(1/prefactor, x).getn() if dn and dn < 0: pass else: dn = 0 except NotImplementedError: dn = 0 terms = [1/prefactor] for m in range(1, ceiling((n - dn + 1)/lcf)): new_term = terms[-1](-rest) if new_term.is_Pow: new_term = new_term._eval_expand_multinomial( deep=False) else: new_term = expand_mul(new_term, deep=False) terms.append(new_term) terms.append(O(xn, x)) return powsimp(Add(terms), deep=True, combine='exp') else: # negative powers are rewritten to the cases above, for # example: # sin(x)(-4) = 1/(sin(x)4) = ... # and expand the denominator: nuse, denominator = n, O(1, x) while denominator.is_Order: denominator = (b*(-e))._eval_nseries(x, n=nuse, logx=logx) nuse += 1 if 1/denominator == self: return self # now we have a type 1/f(x), that we know how to expand return (1/denominator)._eval_nseries(x, n=n, logx=logx) if e.has(Symbol): return exp(elog(b))._eval_nseries(x, n=n, logx=logx) # see if the base is as simple as possible bx = b while bx.is_Pow and bx.exp.is_Rational: bx = bx.base if bx == x: return self # work for b(x)e where e is not an Integer and does not contain x # and hopefully has no other symbols def e2int(e): """return the integer value (if possible) of e and a flag indicating whether it is bounded or not.""" n = e.limit(x, 0) infinite = n.is_infinite if not infinite: # XXX was int or floor intended? int used to behave like floor # so int(-Rational(1, 2)) returned -1 rather than int's 0 try: n = int(n) except TypeError: # well, the n is something more complicated (like 1 + log(2)) try: n = int(n.evalf()) + 1 # XXX why is 1 being added? except TypeError: pass # hope that base allows this to be resolved n = _sympify(n) return n, infinite order = O(xn, x) ei, infinite = e2int(e) b0 = b.limit(x, 0) if infinite and (b0 is S.One or b0.has(Symbol)): # XXX what order if b0 is S.One: resid = (b - 1) if resid.is_positive: return S.Infinity elif resid.is_negative: return S.Zero raise ValueError('cannot determine sign of %s' % resid) return b0ei if (b0 is S.Zero or b0.is_infinite): if infinite is not False: return b0e # XXX what order if not ei.is_number: # if not, how will we proceed? raise ValueError( 'expecting numerical exponent but got %s' % ei) nuse = n - ei if e.is_real and e.is_positive: lt = b.as_leading_term(x) # Try to correct nuse (= m) guess from: # (lt + rest + O(xm))e = # lt*e(1 + rest/lt + O(xm)/lt)e = # lte + ... + O(xm)lt(e - 1) = ... + O(xn) try: cf = Order(lt, x).getn() nuse = ceiling(n - cf(e - 1)) except NotImplementedError: pass bs = b._eval_nseries(x, n=nuse, logx=logx) terms = bs.removeO() if terms.is_Add: bs = terms lt = terms.as_leading_term(x) # bs -> lt + rest -> lt(1 + (bs/lt - 1)) return ((self.func(lt, e) self.func((bs/lt).expand(), e).nseries( x, n=nuse, logx=logx)).expand() + order) if bs.is_Add: from sympy import O # So, bs + O() == terms c = Dummy('c') res = [] for arg in bs.args: if arg.is_Order: arg = carg.expr res.append(arg) bs = Add(res) rv = (bse).series(x).subs(c, O(1, x)) rv += order return rv rv = bse if terms != bs: rv += order return rv # either b0 is bounded but neither 1 nor 0 or e is infinite # b -> b0 + (b - b0) -> b0 * (1 + (b/b0 - 1)) o2 = order(b0-e) z = (b/b0 - 1) o = O(z, x) if o is S.Zero or o2 is S.Zero: infinite = True else: if o.expr.is_number: e2 = log(o2.exprx)/log(x) else: e2 = log(o2.expr)/log(o.expr) n, infinite = e2int(e2) if infinite: # requested accuracy gives infinite series, # order is probably non-polynomial e.g. O(exp(-1/x), x). r = 1 + z else: l = [] g = None for i in range(n + 2): g = self._taylor_term(i, z, g) g = g.nseries(x, n=n, logx=logx) l.append(g) r = Add(l) return expand_mul(rb0*e) + order def _eval_as_leading_term(self, x): from sympy import exp, log if not self.exp.has(x): return self.func(self.base.as_leading_term(x), self.exp) return exp(self.exp log(self.base)).as_leading_term(x) @cacheit def _taylor_term(self, n, x, previous_terms): # of (1 + x)e from sympy import binomial return binomial(self.exp, n) self.func(x, n) def _sage_(self): return self.args[0]._sage_()*self.args[1]._sage_() def as_content_primitive(self, radical=False, clear=True): """Return the tuple (R, self/R) where R is the positive Rational extracted from self. Examples ======== >>> from sympy import sqrt >>> sqrt(4 + 4sqrt(2)).as_content_primitive() (2, sqrt(1 + sqrt(2))) >>> sqrt(3 + 3sqrt(2)).as_content_primitive() (1, sqrt(3)sqrt(1 + sqrt(2))) >>> from sympy import expand_power_base, powsimp, Mul >>> from sympy.abc import x, y >>> ((2x + 2)2).as_content_primitive() (4, (x + 1)2) >>> (4((1 + y)/2)).as_content_primitive() (2, 4(y/2)) >>> (3((1 + y)/2)).as_content_primitive() (1, 3((y + 1)/2)) >>> (3((5 + y)/2)).as_content_primitive() (9, 3((y + 1)/2)) >>> eq = 3(2 + 2x) >>> powsimp(eq) == eq True >>> eq.as_content_primitive() (9, 3*(2x)) >>> powsimp(Mul(_)) 3(2x + 2) >>> eq = (2 + 2x)y >>> s = expand_power_base(eq); s.is_Mul, s (False, (2x + 2)*y) >>> eq.as_content_primitive() (1, (2(x + 1))y) >>> s = expand_power_base(_[1]); s.is_Mul, s (True, 2y(x + 1)y) See docstring of Expr.as_content_primitive for more examples. """ b, e = self.as_base_exp() b = _keep_coeff(b.as_content_primitive(radical=radical, clear=clear)) ce, pe = e.as_content_primitive(radical=radical, clear=clear) if b.is_Rational: #e #= cepe #= ce(h + t) #= ceh + cet #=> self #= b*(ceh)b(cet) #= b*(cehp/cehq)b*(cet) #= b*(iceh + r/cehq)b*(cet) #= b*(iceh)b*(r/cehq)b*(cet) #= b*(iceh)b*(cet + r/cehq) h, t = pe.as_coeff_Add() if h.is_Rational: ceh = ceh c = self.func(b, ceh) r = S.Zero if not c.is_Rational: iceh, r = divmod(ceh.p, ceh.q) c = self.func(b, iceh) return c, self.func(b, _keep_coeff(ce, t + r/ce/ceh.q)) e = _keep_coeff(ce, pe) # be = (ht)e = hete = cmte if e.is_Rational and b.is_Mul: h, t = b.as_content_primitive(radical=radical, clear=clear) # h is positive c, m = self.func(h, e).as_coeff_Mul() # so c is positive m, me = m.as_base_exp() if m is S.One or me == e: # probably always true # return the following, not return c, mPow(t, e) # which would change Pow into Mul; we let sympy # decide what to do by using the unevaluated Mul, e.g # should it stay as sqrt(2 + 2sqrt(5)) or become # sqrt(2)sqrt(1 + sqrt(5)) return c, self.func(_keep_coeff(m, t), e) return S.One, self.func(b, e) def is_constant(self, wrt, flags): expr = self if flags.get('simplify', True): expr = expr.simplify() b, e = expr.as_base_exp() bz = b.equals(0) if bz: # recalculate with assumptions in case it's unevaluated new = be if new != expr: return new.is_constant() econ = e.is_constant(wrt) bcon = b.is_constant(wrt) if bcon: if econ: return True bz = b.equals(0) if bz is False: return False elif bcon is None: return None return e.equals(0) def _eval_difference_delta(self, n, step): b, e = self.args if e.has(n) and not b.has(n): new_e = e.subs(n, n + step) return (b(new_e - e) - 1) self from .add import Add from .numbers import Integer from .mul import Mul, _keep_coeff from .symbol import Symbol, Dummy, symbols
946c4872925588ffcb23cffa550d91c9157e1b6025880efb62d914ff58b78701	"""Tools for manipulating of large commutative expressions. """ from __future__ import print_function, division from sympy.core.add import Add from sympy.core.compatibility import iterable, is_sequence, SYMPY_INTS, range from sympy.core.mul import Mul, _keep_coeff from sympy.core.power import Pow from sympy.core.basic import Basic, preorder_traversal from sympy.core.expr import Expr from sympy.core.sympify import sympify from sympy.core.numbers import Rational, Integer, Number, I from sympy.core.singleton import S from sympy.core.symbol import Dummy from sympy.core.coreerrors import NonCommutativeExpression from sympy.core.containers import Tuple, Dict from sympy.utilities import default_sort_key from sympy.utilities.iterables import (common_prefix, common_suffix, variations, ordered) from collections import defaultdict _eps = Dummy(positive=True) def _isnumber(i): return isinstance(i, (SYMPY_INTS, float)) or i.is_Number def _monotonic_sign(self): """Return the value closest to 0 that ``self`` may have if all symbols are signed and the result is uniformly the same sign for all values of symbols. If a symbol is only signed but not known to be an integer or the result is 0 then a symbol representative of the sign of self will be returned. Otherwise, None is returned if a) the sign could be positive or negative or b) self is not in one of the following forms: - L(x, y, ...) + A: a function linear in all symbols x, y, ... with an additive constant; if A is zero then the function can be a monomial whose sign is monotonic over the range of the variables, e.g. (x + 1)*3 if x is nonnegative. - A/L(x, y, ...) + B: the inverse of a function linear in all symbols x, y, ... that does not have a sign change from positive to negative for any set of values for the variables. - M(x, y, ...) + A: a monomial M whose factors are all signed and a constant, A. - A/M(x, y, ...) + B: the inverse of a monomial and constants A and B. - P(x): a univariate polynomial Examples ======== >>> from sympy.core.exprtools import _monotonic_sign as F >>> from sympy import Dummy, S >>> nn = Dummy(integer=True, nonnegative=True) >>> p = Dummy(integer=True, positive=True) >>> p2 = Dummy(integer=True, positive=True) >>> F(nn + 1) 1 >>> F(p - 1) _nneg >>> F(nnp + 1) 1 >>> F(p2p + 1) 2 >>> F(nn - 1) # could be negative, zero or positive """ if not self.is_real: return if (-self).is_Symbol: rv = _monotonic_sign(-self) return rv if rv is None else -rv if not self.is_Add and self.as_numer_denom()[1].is_number: s = self if s.is_prime: if s.is_odd: return S(3) else: return S(2) elif s.is_composite: if s.is_odd: return S(9) else: return S(4) elif s.is_positive: if s.is_even: if s.is_prime is False: return S(4) else: return S(2) elif s.is_integer: return S.One else: return _eps elif s.is_negative: if s.is_even: return S(-2) elif s.is_integer: return S.NegativeOne else: return -_eps if s.is_zero or s.is_nonpositive or s.is_nonnegative: return S.Zero return None # univariate polynomial free = self.free_symbols if len(free) == 1: if self.is_polynomial(): from sympy.polys.polytools import real_roots from sympy.polys.polyroots import roots from sympy.polys.polyerrors import PolynomialError x = free.pop() x0 = _monotonic_sign(x) if x0 == _eps or x0 == -_eps: x0 = S.Zero if x0 is not None: d = self.diff(x) if d.is_number: currentroots = [] else: try: currentroots = real_roots(d) except (PolynomialError, NotImplementedError): currentroots = [r for r in roots(d, x) if r.is_real] y = self.subs(x, x0) if x.is_nonnegative and all(r <= x0 for r in currentroots): if y.is_nonnegative and d.is_positive: if y: return y if y.is_positive else Dummy('pos', positive=True) else: return Dummy('nneg', nonnegative=True) if y.is_nonpositive and d.is_negative: if y: return y if y.is_negative else Dummy('neg', negative=True) else: return Dummy('npos', nonpositive=True) elif x.is_nonpositive and all(r >= x0 for r in currentroots): if y.is_nonnegative and d.is_negative: if y: return Dummy('pos', positive=True) else: return Dummy('nneg', nonnegative=True) if y.is_nonpositive and d.is_positive: if y: return Dummy('neg', negative=True) else: return Dummy('npos', nonpositive=True) else: n, d = self.as_numer_denom() den = None if n.is_number: den = _monotonic_sign(d) elif not d.is_number: if _monotonic_sign(n) is not None: den = _monotonic_sign(d) if den is not None and (den.is_positive or den.is_negative): v = nden if v.is_positive: return Dummy('pos', positive=True) elif v.is_nonnegative: return Dummy('nneg', nonnegative=True) elif v.is_negative: return Dummy('neg', negative=True) elif v.is_nonpositive: return Dummy('npos', nonpositive=True) return None # multivariate c, a = self.as_coeff_Add() v = None if not a.is_polynomial(): # F/A or A/F where A is a number and F is a signed, rational monomial n, d = a.as_numer_denom() if not (n.is_number or d.is_number): return if ( a.is_Mul or a.is_Pow) and \ a.is_rational and \ all(p.exp.is_Integer for p in a.atoms(Pow) if p.is_Pow) and \ (a.is_positive or a.is_negative): v = S(1) for ai in Mul.make_args(a): if ai.is_number: v = ai continue reps = {} for x in ai.free_symbols: reps[x] = _monotonic_sign(x) if reps[x] is None: return v = ai.subs(reps) elif c: # signed linear expression if not any(p for p in a.atoms(Pow) if not p.is_number) and (a.is_nonpositive or a.is_nonnegative): free = list(a.free_symbols) p = {} for i in free: v = _monotonic_sign(i) if v is None: return p[i] = v or (_eps if i.is_nonnegative else -_eps) v = a.xreplace(p) if v is not None: rv = v + c if v.is_nonnegative and rv.is_positive: return rv.subs(_eps, 0) if v.is_nonpositive and rv.is_negative: return rv.subs(_eps, 0) def decompose_power(expr): """ Decompose power into symbolic base and integer exponent. This is strictly only valid if the exponent from which the integer is extracted is itself an integer or the base is positive. These conditions are assumed and not checked here. Examples ======== >>> from sympy.core.exprtools import decompose_power >>> from sympy.abc import x, y >>> decompose_power(x) (x, 1) >>> decompose_power(x2) (x, 2) >>> decompose_power(x(2y)) (xy, 2) >>> decompose_power(x(2y/3)) (x*(y/3), 2) """ base, exp = expr.as_base_exp() if exp.is_Number: if exp.is_Rational: if not exp.is_Integer: base = Pow(base, Rational(1, exp.q)) exp = exp.p else: base, exp = expr, 1 else: exp, tail = exp.as_coeff_Mul(rational=True) if exp is S.NegativeOne: base, exp = Pow(base, tail), -1 elif exp is not S.One: tail = _keep_coeff(Rational(1, exp.q), tail) base, exp = Pow(base, tail), exp.p else: base, exp = expr, 1 return base, exp def decompose_power_rat(expr): """ Decompose power into symbolic base and rational exponent. """ base, exp = expr.as_base_exp() if exp.is_Number: if not exp.is_Rational: base, exp = expr, 1 else: exp, tail = exp.as_coeff_Mul(rational=True) if exp is S.NegativeOne: base, exp = Pow(base, tail), -1 elif exp is not S.One: tail = _keep_coeff(Rational(1, exp.q), tail) base, exp = Pow(base, tail), exp.p else: base, exp = expr, 1 return base, exp class Factors(object): """Efficient representation of ``f_1f_2...f_n``.""" __slots__ = ['factors', 'gens'] def __init__(self, factors=None): # Factors """Initialize Factors from dict or expr. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x >>> from sympy import I >>> e = 2x3 >>> Factors(e) Factors({2: 1, x: 3}) >>> Factors(e.as_powers_dict()) Factors({2: 1, x: 3}) >>> f = _ >>> f.factors # underlying dictionary {2: 1, x: 3} >>> f.gens # base of each factor frozenset({2, x}) >>> Factors(0) Factors({0: 1}) >>> Factors(I) Factors({I: 1}) Notes ===== Although a dictionary can be passed, only minimal checking is performed: powers of -1 and I are made canonical. """ if isinstance(factors, (SYMPY_INTS, float)): factors = S(factors) if isinstance(factors, Factors): factors = factors.factors.copy() elif factors is None or factors is S.One: factors = {} elif factors is S.Zero or factors == 0: factors = {S.Zero: S.One} elif isinstance(factors, Number): n = factors factors = {} if n < 0: factors[S.NegativeOne] = S.One n = -n if n is not S.One: if n.is_Float or n.is_Integer or n is S.Infinity: factors[n] = S.One elif n.is_Rational: # since we're processing Numbers, the denominator is # stored with a negative exponent; all other factors # are left . if n.p != 1: factors[Integer(n.p)] = S.One factors[Integer(n.q)] = S.NegativeOne else: raise ValueError('Expected Float\|Rational\|Integer, not %s' % n) elif isinstance(factors, Basic) and not factors.args: factors = {factors: S.One} elif isinstance(factors, Expr): c, nc = factors.args_cnc() i = c.count(I) for _ in range(i): c.remove(I) factors = dict(Mul._from_args(c).as_powers_dict()) # Handle all rational Coefficients for f in list(factors.keys()): if isinstance(f, Rational) and not isinstance(f, Integer): p, q = Integer(f.p), Integer(f.q) factors[p] = (factors[p] if p in factors else 0) + factors[f] factors[q] = (factors[q] if q in factors else 0) - factors[f] factors.pop(f) if i: factors[I] = S.Onei if nc: factors[Mul(nc, evaluate=False)] = S.One else: factors = factors.copy() # /!\ should be dict-like # tidy up -/+1 and I exponents if Rational handle = [] for k in factors: if k is I or k in (-1, 1): handle.append(k) if handle: i1 = S.One for k in handle: if not _isnumber(factors[k]): continue i1 = k*factors.pop(k) if i1 is not S.One: for a in i1.args if i1.is_Mul else [i1]: # at worst, -1.0I(-1)e if a is S.NegativeOne: factors[a] = S.One elif a is I: factors[I] = S.One elif a.is_Pow: if S.NegativeOne not in factors: factors[S.NegativeOne] = S.Zero factors[S.NegativeOne] += a.exp elif a == 1: factors[a] = S.One elif a == -1: factors[-a] = S.One factors[S.NegativeOne] = S.One else: raise ValueError('unexpected factor in i1: %s' % a) self.factors = factors keys = getattr(factors, 'keys', None) if keys is None: raise TypeError('expecting Expr or dictionary') self.gens = frozenset(keys()) def __hash__(self): # Factors keys = tuple(ordered(self.factors.keys())) values = [self.factors[k] for k in keys] return hash((keys, values)) def __repr__(self): # Factors return "Factors({%s})" % ', '.join( ['%s: %s' % (k, v) for k, v in ordered(self.factors.items())]) @property def is_zero(self): # Factors """ >>> from sympy.core.exprtools import Factors >>> Factors(0).is_zero True """ f = self.factors return len(f) == 1 and S.Zero in f @property def is_one(self): # Factors """ >>> from sympy.core.exprtools import Factors >>> Factors(1).is_one True """ return not self.factors def as_expr(self): # Factors """Return the underlying expression. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y >>> Factors((xy*2).as_powers_dict()).as_expr() xy*2 """ args = [] for factor, exp in self.factors.items(): if exp != 1: b, e = factor.as_base_exp() if isinstance(exp, int): e = _keep_coeff(Integer(exp), e) elif isinstance(exp, Rational): e = _keep_coeff(exp, e) else: e = exp args.append(b*e) else: args.append(factor) return Mul(args) def mul(self, other): # Factors """Return Factors of ``self * other``. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((xy2).as_powers_dict()) >>> b = Factors((xy/z).as_powers_dict()) >>> a.mul(b) Factors({x: 2, y: 3, z: -1}) >>> ab Factors({x: 2, y: 3, z: -1}) """ if not isinstance(other, Factors): other = Factors(other) if any(f.is_zero for f in (self, other)): return Factors(S.Zero) factors = dict(self.factors) for factor, exp in other.factors.items(): if factor in factors: exp = factors[factor] + exp if not exp: del factors[factor] continue factors[factor] = exp return Factors(factors) def normal(self, other): """Return ``self`` and ``other`` with ``gcd`` removed from each. The only differences between this and method ``div`` is that this is 1) optimized for the case when there are few factors in common and 2) this does not raise an error if ``other`` is zero. See Also ======== div """ if not isinstance(other, Factors): other = Factors(other) if other.is_zero: return (Factors(), Factors(S.Zero)) if self.is_zero: return (Factors(S.Zero), Factors()) self_factors = dict(self.factors) other_factors = dict(other.factors) for factor, self_exp in self.factors.items(): try: other_exp = other.factors[factor] except KeyError: continue exp = self_exp - other_exp if not exp: del self_factors[factor] del other_factors[factor] elif _isnumber(exp): if exp > 0: self_factors[factor] = exp del other_factors[factor] else: del self_factors[factor] other_factors[factor] = -exp else: r = self_exp.extract_additively(other_exp) if r is not None: if r: self_factors[factor] = r del other_factors[factor] else: # should be handled already del self_factors[factor] del other_factors[factor] else: sc, sa = self_exp.as_coeff_Add() if sc: oc, oa = other_exp.as_coeff_Add() diff = sc - oc if diff > 0: self_factors[factor] -= oc other_exp = oa elif diff < 0: self_factors[factor] -= sc other_factors[factor] -= sc other_exp = oa - diff else: self_factors[factor] = sa other_exp = oa if other_exp: other_factors[factor] = other_exp else: del other_factors[factor] return Factors(self_factors), Factors(other_factors) def div(self, other): # Factors """Return ``self`` and ``other`` with ``gcd`` removed from each. This is optimized for the case when there are many factors in common. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> from sympy import S >>> a = Factors((xy*2).as_powers_dict()) >>> a.div(a) (Factors({}), Factors({})) >>> a.div(xz) (Factors({y: 2}), Factors({z: 1})) The ``/`` operator only gives ``quo``: >>> a/x Factors({y: 2}) Factors treats its factors as though they are all in the numerator, so if you violate this assumption the results will be correct but will not strictly correspond to the numerator and denominator of the ratio: >>> a.div(x/z) (Factors({y: 2}), Factors({z: -1})) Factors is also naive about bases: it does not attempt any denesting of Rational-base terms, for example the following does not become 2*(2x)/2. >>> Factors(2*(2x + 2)).div(S(8)) (Factors({2: 2x + 2}), Factors({8: 1})) factor_terms can clean up such Rational-bases powers: >>> from sympy.core.exprtools import factor_terms >>> n, d = Factors(2(2x + 2)).div(S(8)) >>> n.as_expr()/d.as_expr() 2*(2x + 2)/8 >>> factor_terms(_) 2*(2x)/2 """ quo, rem = dict(self.factors), {} if not isinstance(other, Factors): other = Factors(other) if other.is_zero: raise ZeroDivisionError if self.is_zero: return (Factors(S.Zero), Factors()) for factor, exp in other.factors.items(): if factor in quo: d = quo[factor] - exp if _isnumber(d): if d <= 0: del quo[factor] if d >= 0: if d: quo[factor] = d continue exp = -d else: r = quo[factor].extract_additively(exp) if r is not None: if r: quo[factor] = r else: # should be handled already del quo[factor] else: other_exp = exp sc, sa = quo[factor].as_coeff_Add() if sc: oc, oa = other_exp.as_coeff_Add() diff = sc - oc if diff > 0: quo[factor] -= oc other_exp = oa elif diff < 0: quo[factor] -= sc other_exp = oa - diff else: quo[factor] = sa other_exp = oa if other_exp: rem[factor] = other_exp else: assert factor not in rem continue rem[factor] = exp return Factors(quo), Factors(rem) def quo(self, other): # Factors """Return numerator Factor of ``self / other``. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((xy2).as_powers_dict()) >>> b = Factors((xy/z).as_powers_dict()) >>> a.quo(b) # same as a/b Factors({y: 1}) """ return self.div(other)[0] def rem(self, other): # Factors """Return denominator Factors of ``self / other``. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((xy2).as_powers_dict()) >>> b = Factors((xy/z).as_powers_dict()) >>> a.rem(b) Factors({z: -1}) >>> a.rem(a) Factors({}) """ return self.div(other)[1] def pow(self, other): # Factors """Return self raised to a non-negative integer power. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y >>> a = Factors((xy2).as_powers_dict()) >>> a2 Factors({x: 2, y: 4}) """ if isinstance(other, Factors): other = other.as_expr() if other.is_Integer: other = int(other) if isinstance(other, SYMPY_INTS) and other >= 0: factors = {} if other: for factor, exp in self.factors.items(): factors[factor] = expother return Factors(factors) else: raise ValueError("expected non-negative integer, got %s" % other) def gcd(self, other): # Factors """Return Factors of ``gcd(self, other)``. The keys are the intersection of factors with the minimum exponent for each factor. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((xy2).as_powers_dict()) >>> b = Factors((xy/z).as_powers_dict()) >>> a.gcd(b) Factors({x: 1, y: 1}) """ if not isinstance(other, Factors): other = Factors(other) if other.is_zero: return Factors(self.factors) factors = {} for factor, exp in self.factors.items(): factor, exp = sympify(factor), sympify(exp) if factor in other.factors: lt = (exp - other.factors[factor]).is_negative if lt == True: factors[factor] = exp elif lt == False: factors[factor] = other.factors[factor] return Factors(factors) def lcm(self, other): # Factors """Return Factors of ``lcm(self, other)`` which are the union of factors with the maximum exponent for each factor. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((xy2).as_powers_dict()) >>> b = Factors((xy/z).as_powers_dict()) >>> a.lcm(b) Factors({x: 1, y: 2, z: -1}) """ if not isinstance(other, Factors): other = Factors(other) if any(f.is_zero for f in (self, other)): return Factors(S.Zero) factors = dict(self.factors) for factor, exp in other.factors.items(): if factor in factors: exp = max(exp, factors[factor]) factors[factor] = exp return Factors(factors) def __mul__(self, other): # Factors return self.mul(other) def __divmod__(self, other): # Factors return self.div(other) def __div__(self, other): # Factors return self.quo(other) __truediv__ = __div__ def __mod__(self, other): # Factors return self.rem(other) def __pow__(self, other): # Factors return self.pow(other) def __eq__(self, other): # Factors if not isinstance(other, Factors): other = Factors(other) return self.factors == other.factors def __ne__(self, other): # Factors return not self == other class Term(object): """Efficient representation of ``coeff(numer/denom)``. """ __slots__ = ['coeff', 'numer', 'denom'] def __init__(self, term, numer=None, denom=None): # Term if numer is None and denom is None: if not term.is_commutative: raise NonCommutativeExpression( 'commutative expression expected') coeff, factors = term.as_coeff_mul() numer, denom = defaultdict(int), defaultdict(int) for factor in factors: base, exp = decompose_power(factor) if base.is_Add: cont, base = base.primitive() coeff = cont*exp if exp > 0: numer[base] += exp else: denom[base] += -exp numer = Factors(numer) denom = Factors(denom) else: coeff = term if numer is None: numer = Factors() if denom is None: denom = Factors() self.coeff = coeff self.numer = numer self.denom = denom def __hash__(self): # Term return hash((self.coeff, self.numer, self.denom)) def __repr__(self): # Term return "Term(%s, %s, %s)" % (self.coeff, self.numer, self.denom) def as_expr(self): # Term return self.coeff(self.numer.as_expr()/self.denom.as_expr()) def mul(self, other): # Term coeff = self.coeffother.coeff numer = self.numer.mul(other.numer) denom = self.denom.mul(other.denom) numer, denom = numer.normal(denom) return Term(coeff, numer, denom) def inv(self): # Term return Term(1/self.coeff, self.denom, self.numer) def quo(self, other): # Term return self.mul(other.inv()) def pow(self, other): # Term if other < 0: return self.inv().pow(-other) else: return Term(self.coeff * other, self.numer.pow(other), self.denom.pow(other)) def gcd(self, other): # Term return Term(self.coeff.gcd(other.coeff), self.numer.gcd(other.numer), self.denom.gcd(other.denom)) def lcm(self, other): # Term return Term(self.coeff.lcm(other.coeff), self.numer.lcm(other.numer), self.denom.lcm(other.denom)) def __mul__(self, other): # Term if isinstance(other, Term): return self.mul(other) else: return NotImplemented def __div__(self, other): # Term if isinstance(other, Term): return self.quo(other) else: return NotImplemented __truediv__ = __div__ def __pow__(self, other): # Term if isinstance(other, SYMPY_INTS): return self.pow(other) else: return NotImplemented def __eq__(self, other): # Term return (self.coeff == other.coeff and self.numer == other.numer and self.denom == other.denom) def __ne__(self, other): # Term return not self == other def _gcd_terms(terms, isprimitive=False, fraction=True): """Helper function for :func:`gcd_terms`. If ``isprimitive`` is True then the call to primitive for an Add will be skipped. This is useful when the content has already been extrated. If ``fraction`` is True then the expression will appear over a common denominator, the lcm of all term denominators. """ if isinstance(terms, Basic) and not isinstance(terms, Tuple): terms = Add.make_args(terms) terms = list(map(Term, [t for t in terms if t])) # there is some simplification that may happen if we leave this # here rather than duplicate it before the mapping of Term onto # the terms if len(terms) == 0: return S.Zero, S.Zero, S.One if len(terms) == 1: cont = terms[0].coeff numer = terms[0].numer.as_expr() denom = terms[0].denom.as_expr() else: cont = terms[0] for term in terms[1:]: cont = cont.gcd(term) for i, term in enumerate(terms): terms[i] = term.quo(cont) if fraction: denom = terms[0].denom for term in terms[1:]: denom = denom.lcm(term.denom) numers = [] for term in terms: numer = term.numer.mul(denom.quo(term.denom)) numers.append(term.coeffnumer.as_expr()) else: numers = [t.as_expr() for t in terms] denom = Term(S(1)).numer cont = cont.as_expr() numer = Add(numers) denom = denom.as_expr() if not isprimitive and numer.is_Add: _cont, numer = numer.primitive() cont = _cont return cont, numer, denom def gcd_terms(terms, isprimitive=False, clear=True, fraction=True): """Compute the GCD of ``terms`` and put them together. ``terms`` can be an expression or a non-Basic sequence of expressions which will be handled as though they are terms from a sum. If ``isprimitive`` is True the _gcd_terms will not run the primitive method on the terms. ``clear`` controls the removal of integers from the denominator of an Add expression. When True (default), all numerical denominator will be cleared; when False the denominators will be cleared only if all terms had numerical denominators other than 1. ``fraction``, when True (default), will put the expression over a common denominator. Examples ======== >>> from sympy.core import gcd_terms >>> from sympy.abc import x, y >>> gcd_terms((x + 1)2y + (x + 1)y2) y(x + 1)(x + y + 1) >>> gcd_terms(x/2 + 1) (x + 2)/2 >>> gcd_terms(x/2 + 1, clear=False) x/2 + 1 >>> gcd_terms(x/2 + y/2, clear=False) (x + y)/2 >>> gcd_terms(x/2 + 1/x) (x2 + 2)/(2x) >>> gcd_terms(x/2 + 1/x, fraction=False) (x + 2/x)/2 >>> gcd_terms(x/2 + 1/x, fraction=False, clear=False) x/2 + 1/x >>> gcd_terms(x/2/y + 1/x/y) (x*2 + 2)/(2xy) >>> gcd_terms(x/2/y + 1/x/y, clear=False) (x2/2 + 1)/(xy) >>> gcd_terms(x/2/y + 1/x/y, clear=False, fraction=False) (x/2 + 1/x)/y The ``clear`` flag was ignored in this case because the returned expression was a rational expression, not a simple sum. See Also ======== factor_terms, sympy.polys.polytools.terms_gcd """ def mask(terms): """replace nc portions of each term with a unique Dummy symbols and return the replacements to restore them""" args = [(a, []) if a.is_commutative else a.args_cnc() for a in terms] reps = [] for i, (c, nc) in enumerate(args): if nc: nc = Mul(nc) d = Dummy() reps.append((d, nc)) c.append(d) args[i] = Mul(c) else: args[i] = c return args, dict(reps) isadd = isinstance(terms, Add) addlike = isadd or not isinstance(terms, Basic) and \ is_sequence(terms, include=set) and \ not isinstance(terms, Dict) if addlike: if isadd: # i.e. an Add terms = list(terms.args) else: terms = sympify(terms) terms, reps = mask(terms) cont, numer, denom = _gcd_terms(terms, isprimitive, fraction) numer = numer.xreplace(reps) coeff, factors = cont.as_coeff_Mul() if not clear: c, _coeff = coeff.as_coeff_Mul() if not c.is_Integer and not clear and numer.is_Add: n, d = c.as_numer_denom() _numer = numer/d if any(a.as_coeff_Mul()[0].is_Integer for a in _numer.args): numer = _numer coeff = n_coeff return _keep_coeff(coeff, factorsnumer/denom, clear=clear) if not isinstance(terms, Basic): return terms if terms.is_Atom: return terms if terms.is_Mul: c, args = terms.as_coeff_mul() return _keep_coeff(c, Mul([gcd_terms(i, isprimitive, clear, fraction) for i in args]), clear=clear) def handle(a): # don't treat internal args like terms of an Add if not isinstance(a, Expr): if isinstance(a, Basic): return a.func([handle(i) for i in a.args]) return type(a)([handle(i) for i in a]) return gcd_terms(a, isprimitive, clear, fraction) if isinstance(terms, Dict): return Dict([(k, handle(v)) for k, v in terms.args]) return terms.func([handle(i) for i in terms.args]) def _factor_sum_int(expr, *kwargs): """Return Sum or Integral object with factors that are not in the wrt variables removed. In cases where there are additive terms in the function of the object that are independent, the object will be separated into two objects. Examples ======== >>> from sympy import Sum, factor_terms >>> from sympy.abc import x, y >>> factor_terms(Sum(x + y, (x, 1, 3))) ySum(1, (x, 1, 3)) + Sum(x, (x, 1, 3)) >>> factor_terms(Sum(xy, (x, 1, 3))) ySum(x, (x, 1, 3)) Notes ===== If a function in the summand or integrand is replaced with a symbol, then this simplification should not be done or else an incorrect result will be obtained when the symbol is replaced with an expression that depends on the variables of summation/integration: >>> eq = Sum(y, (x, 1, 3)) >>> factor_terms(eq).subs(y, x).doit() 3x >>> eq.subs(y, x).doit() 6 """ result = expr.function if result == 0: return S.Zero limits = expr.limits # get the wrt variables wrt = set([i.args[0] for i in limits]) # factor out any common terms that are independent of wrt f = factor_terms(result, kwargs) i, d = f.as_independent(wrt) if isinstance(f, Add): return i * expr.func(1, limits) + expr.func(d, limits) else: return i * expr.func(d, limits) def factor_terms(expr, radical=False, clear=False, fraction=False, sign=True): """Remove common factors from terms in all arguments without changing the underlying structure of the expr. No expansion or simplification (and no processing of non-commutatives) is performed. If radical=True then a radical common to all terms will be factored out of any Add sub-expressions of the expr. If clear=False (default) then coefficients will not be separated from a single Add if they can be distributed to leave one or more terms with integer coefficients. If fraction=True (default is False) then a common denominator will be constructed for the expression. If sign=True (default) then even if the only factor in common is a -1, it will be factored out of the expression. Examples ======== >>> from sympy import factor_terms, Symbol >>> from sympy.abc import x, y >>> factor_terms(x + x(2 + 4y)3) x(8(2y + 1)*3 + 1) >>> A = Symbol('A', commutative=False) >>> factor_terms(xA + xA + xyA) x(yA + 2A) When ``clear`` is False, a rational will only be factored out of an Add expression if all terms of the Add have coefficients that are fractions: >>> factor_terms(x/2 + 1, clear=False) x/2 + 1 >>> factor_terms(x/2 + 1, clear=True) (x + 2)/2 If a -1 is all that can be factored out, to not factor it out, the flag ``sign`` must be False: >>> factor_terms(-x - y) -(x + y) >>> factor_terms(-x - y, sign=False) -x - y >>> factor_terms(-2x - 2y, sign=False) -2(x + y) See Also ======== gcd_terms, sympy.polys.polytools.terms_gcd """ def do(expr): from sympy.concrete.summations import Sum from sympy.integrals.integrals import Integral is_iterable = iterable(expr) if not isinstance(expr, Basic) or expr.is_Atom: if is_iterable: return type(expr)([do(i) for i in expr]) return expr if expr.is_Pow or expr.is_Function or \ is_iterable or not hasattr(expr, 'args_cnc'): args = expr.args newargs = tuple([do(i) for i in args]) if newargs == args: return expr return expr.func(newargs) if isinstance(expr, (Sum, Integral)): return _factor_sum_int(expr, radical=radical, clear=clear, fraction=fraction, sign=sign) cont, p = expr.as_content_primitive(radical=radical, clear=clear) if p.is_Add: list_args = [do(a) for a in Add.make_args(p)] # get a common negative (if there) which gcd_terms does not remove if all(a.as_coeff_Mul()[0].extract_multiplicatively(-1) is not None for a in list_args): cont = -cont list_args = [-a for a in list_args] # watch out for exp(-(x+2)) which gcd_terms will change to exp(-x-2) special = {} for i, a in enumerate(list_args): b, e = a.as_base_exp() if e.is_Mul and e != Mul(e.args): list_args[i] = Dummy() special[list_args[i]] = a # rebuild p not worrying about the order which gcd_terms will fix p = Add._from_args(list_args) p = gcd_terms(p, isprimitive=True, clear=clear, fraction=fraction).xreplace(special) elif p.args: p = p.func( [do(a) for a in p.args]) rv = _keep_coeff(cont, p, clear=clear, sign=sign) return rv expr = sympify(expr) return do(expr) def _mask_nc(eq, name=None): """ Return ``eq`` with non-commutative objects replaced with Dummy symbols. A dictionary that can be used to restore the original values is returned: if it is None, the expression is noncommutative and cannot be made commutative. The third value returned is a list of any non-commutative symbols that appear in the returned equation. ``name``, if given, is the name that will be used with numbered Dummy variables that will replace the non-commutative objects and is mainly used for doctesting purposes. Notes ===== All non-commutative objects other than Symbols are replaced with a non-commutative Symbol. Identical objects will be identified by identical symbols. If there is only 1 non-commutative object in an expression it will be replaced with a commutative symbol. Otherwise, the non-commutative entities are retained and the calling routine should handle replacements in this case since some care must be taken to keep track of the ordering of symbols when they occur within Muls. Examples ======== >>> from sympy.physics.secondquant import Commutator, NO, F, Fd >>> from sympy import symbols, Mul >>> from sympy.core.exprtools import _mask_nc >>> from sympy.abc import x, y >>> A, B, C = symbols('A,B,C', commutative=False) One nc-symbol: >>> _mask_nc(A2 - x2, 'd') (_d02 - x2, {_d0: A}, []) Multiple nc-symbols: >>> _mask_nc(A2 - B2, 'd') (A2 - B2, {}, [A, B]) An nc-object with nc-symbols but no others outside of it: >>> _mask_nc(1 + xCommutator(A, B), 'd') (_d0x + 1, {_d0: Commutator(A, B)}, []) >>> _mask_nc(NO(Fd(x)F(y)), 'd') (_d0, {_d0: NO(CreateFermion(x)AnnihilateFermion(y))}, []) Multiple nc-objects: >>> eq = xCommutator(A, B) + xCommutator(A, C)Commutator(A, B) >>> _mask_nc(eq, 'd') (x_d0 + x_d1_d0, {_d0: Commutator(A, B), _d1: Commutator(A, C)}, [_d0, _d1]) Multiple nc-objects and nc-symbols: >>> eq = ACommutator(A, B) + BCommutator(A, C) >>> _mask_nc(eq, 'd') (A_d0 + B_d1, {_d0: Commutator(A, B), _d1: Commutator(A, C)}, [_d0, _d1, A, B]) If there is an object that: - doesn't contain nc-symbols - but has arguments which derive from Basic, not Expr - and doesn't define an _eval_is_commutative routine then it will give False (or None?) for the is_commutative test. Such objects are also removed by this routine: >>> from sympy import Basic >>> eq = (1 + Mul(Basic(), Basic(), evaluate=False)) >>> eq.is_commutative False >>> _mask_nc(eq, 'd') (_d0*2 + 1, {_d0: Basic()}, []) """ name = name or 'mask' # Make Dummy() append sequential numbers to the name def numbered_names(): i = 0 while True: yield name + str(i) i += 1 names = numbered_names() def Dummy(args, *kwargs): from sympy import Dummy return Dummy(next(names), args, kwargs) expr = eq if expr.is_commutative: return eq, {}, [] # identify nc-objects; symbols and other rep = [] nc_obj = set() nc_syms = set() pot = preorder_traversal(expr, keys=default_sort_key) for i, a in enumerate(pot): if any(a == r[0] for r in rep): pot.skip() elif not a.is_commutative: if a.is_symbol: nc_syms.add(a) pot.skip() elif not (a.is_Add or a.is_Mul or a.is_Pow): nc_obj.add(a) pot.skip() # If there is only one nc symbol or object, it can be factored regularly # but polys is going to complain, so replace it with a Dummy. if len(nc_obj) == 1 and not nc_syms: rep.append((nc_obj.pop(), Dummy())) elif len(nc_syms) == 1 and not nc_obj: rep.append((nc_syms.pop(), Dummy())) # Any remaining nc-objects will be replaced with an nc-Dummy and # identified as an nc-Symbol to watch out for nc_obj = sorted(nc_obj, key=default_sort_key) for n in nc_obj: nc = Dummy(commutative=False) rep.append((n, nc)) nc_syms.add(nc) expr = expr.subs(rep) nc_syms = list(nc_syms) nc_syms.sort(key=default_sort_key) return expr, {v: k for k, v in rep}, nc_syms def factor_nc(expr): """Return the factored form of ``expr`` while handling non-commutative expressions. Examples ======== >>> from sympy.core.exprtools import factor_nc >>> from sympy import Symbol >>> from sympy.abc import x >>> A = Symbol('A', commutative=False) >>> B = Symbol('B', commutative=False) >>> factor_nc((x2 + 2Ax + A2).expand()) (x + A)2 >>> factor_nc(((x + A)(x + B)).expand()) (x + A)(x + B) """ from sympy.simplify.simplify import powsimp from sympy.polys import gcd, factor def _pemexpand(expr): "Expand with the minimal set of hints necessary to check the result." return expr.expand(deep=True, mul=True, power_exp=True, power_base=False, basic=False, multinomial=True, log=False) expr = sympify(expr) if not isinstance(expr, Expr) or not expr.args: return expr if not expr.is_Add: return expr.func([factor_nc(a) for a in expr.args]) expr, rep, nc_symbols = _mask_nc(expr) if rep: return factor(expr).subs(rep) else: args = [a.args_cnc() for a in Add.make_args(expr)] c = g = l = r = S.One hit = False # find any commutative gcd term for i, a in enumerate(args): if i == 0: c = Mul._from_args(a[0]) elif a[0]: c = gcd(c, Mul._from_args(a[0])) else: c = S.One if c is not S.One: hit = True c, g = c.as_coeff_Mul() if g is not S.One: for i, (cc, _) in enumerate(args): cc = list(Mul.make_args(Mul._from_args(list(cc))/g)) args[i][0] = cc for i, (cc, _) in enumerate(args): cc[0] = cc[0]/c args[i][0] = cc # find any noncommutative common prefix for i, a in enumerate(args): if i == 0: n = a[1][:] else: n = common_prefix(n, a[1]) if not n: # is there a power that can be extracted? if not args[0][1]: break b, e = args[0][1][0].as_base_exp() ok = False if e.is_Integer: for t in args: if not t[1]: break bt, et = t[1][0].as_base_exp() if et.is_Integer and bt == b: e = min(e, et) else: break else: ok = hit = True l = be il = b-e for _ in args: _[1][0] = il_[1][0] break if not ok: break else: hit = True lenn = len(n) l = Mul(n) for _ in args: _[1] = _[1][lenn:] # find any noncommutative common suffix for i, a in enumerate(args): if i == 0: n = a[1][:] else: n = common_suffix(n, a[1]) if not n: # is there a power that can be extracted? if not args[0][1]: break b, e = args[0][1][-1].as_base_exp() ok = False if e.is_Integer: for t in args: if not t[1]: break bt, et = t[1][-1].as_base_exp() if et.is_Integer and bt == b: e = min(e, et) else: break else: ok = hit = True r = be il = b-e for _ in args: _[1][-1] = _[1][-1]il break if not ok: break else: hit = True lenn = len(n) r = Mul(n) for _ in args: _[1] = _[1][:len(_[1]) - lenn] if hit: mid = Add([Mul(cc)Mul(nc) for cc, nc in args]) else: mid = expr # sort the symbols so the Dummys would appear in the same # order as the original symbols, otherwise you may introduce # a factor of -1, e.g. A2 - B2) -- {A:y, B:x} --> y2 - x2 # and the former factors into two terms, (A - B)(A + B) while the # latter factors into 3 terms, (-1)(x - y)(x + y) rep1 = [(n, Dummy()) for n in sorted(nc_symbols, key=default_sort_key)] unrep1 = [(v, k) for k, v in rep1] unrep1.reverse() new_mid, r2, _ = _mask_nc(mid.subs(rep1)) new_mid = powsimp(factor(new_mid)) new_mid = new_mid.subs(r2).subs(unrep1) if new_mid.is_Pow: return _keep_coeff(c, glnew_midr) if new_mid.is_Mul: # XXX TODO there should be a way to inspect what order the terms # must be in and just select the plausible ordering without # checking permutations cfac = [] ncfac = [] for f in new_mid.args: if f.is_commutative: cfac.append(f) else: b, e = f.as_base_exp() if e.is_Integer: ncfac.extend([b]e) else: ncfac.append(f) pre_mid = gMul(cfac)l target = _pemexpand(expr/c) for s in variations(ncfac, len(ncfac)): ok = pre_midMul(s)r if _pemexpand(ok) == target: return _keep_coeff(c, ok) # mid was an Add that didn't factor successfully return _keep_coeff(c, glmid*r)
010c9639af7a0f7514d10d245db6d14c323e8d584a075ef747e406661ec4a9a5	""" This module contains the machinery handling assumptions. All symbolic objects have assumption attributes that can be accessed via .is_<assumption name> attribute. Assumptions determine certain properties of symbolic objects and can have 3 possible values: True, False, None. True is returned if the object has the property and False is returned if it doesn't or can't (i.e. doesn't make sense): >>> from sympy import I >>> I.is_algebraic True >>> I.is_real False >>> I.is_prime False When the property cannot be determined (or when a method is not implemented) None will be returned, e.g. a generic symbol, x, may or may not be positive so a value of None is returned for x.is_positive. By default, all symbolic values are in the largest set in the given context without specifying the property. For example, a symbol that has a property being integer, is also real, complex, etc. Here follows a list of possible assumption names: .. glossary:: commutative object commutes with any other object with respect to multiplication operation. complex object can have only values from the set of complex numbers. imaginary object value is a number that can be written as a real number multiplied by the imaginary unit ``I``. See [3]_. Please note, that ``0`` is not considered to be an imaginary number, see `issue #7649 <https://github.com/sympy/sympy/issues/7649>`_. real object can have only values from the set of real numbers. integer object can have only values from the set of integers. odd even object can have only values from the set of odd (even) integers [2]_. prime object is a natural number greater than ``1`` that has no positive divisors other than ``1`` and itself. See [6]_. composite object is a positive integer that has at least one positive divisor other than ``1`` or the number itself. See [4]_. zero object has the value of ``0``. nonzero object is a real number that is not zero. rational object can have only values from the set of rationals. algebraic object can have only values from the set of algebraic numbers [11]_. transcendental object can have only values from the set of transcendental numbers [10]_. irrational object value cannot be represented exactly by Rational, see [5]_. finite infinite object absolute value is bounded (arbitrarily large). See [7]_, [8]_, [9]_. negative nonnegative object can have only negative (nonnegative) values [1]_. positive nonpositive object can have only positive (only nonpositive) values. hermitian antihermitian object belongs to the field of hermitian (antihermitian) operators. Examples ======== >>> from sympy import Symbol >>> x = Symbol('x', real=True); x x >>> x.is_real True >>> x.is_complex True See Also ======== .. seealso:: :py:class:`sympy.core.numbers.ImaginaryUnit` :py:class:`sympy.core.numbers.Zero` :py:class:`sympy.core.numbers.One` Notes ===== Assumption values are stored in obj._assumptions dictionary or are returned by getter methods (with property decorators) or are attributes of objects/classes. References ========== .. [1] https://en.wikipedia.org/wiki/Negative_number .. [2] https://en.wikipedia.org/wiki/Parity_%28mathematics%29 .. [3] https://en.wikipedia.org/wiki/Imaginary_number .. [4] https://en.wikipedia.org/wiki/Composite_number .. [5] https://en.wikipedia.org/wiki/Irrational_number .. [6] https://en.wikipedia.org/wiki/Prime_number .. [7] https://en.wikipedia.org/wiki/Finite .. [8] https://docs.python.org/3/library/math.html#math.isfinite .. [9] http://docs.scipy.org/doc/numpy/reference/generated/numpy.isfinite.html .. [10] https://en.wikipedia.org/wiki/Transcendental_number .. [11] https://en.wikipedia.org/wiki/Algebraic_number """ from __future__ import print_function, division from sympy.core.facts import FactRules, FactKB from sympy.core.core import BasicMeta from sympy.core.compatibility import integer_types from random import shuffle _assume_rules = FactRules([ 'integer -> rational', 'rational -> real & finite', 'rational -> algebraic', 'algebraic -> complex & finite', 'real -> complex', 'real -> hermitian', 'imaginary -> complex', 'imaginary -> antihermitian', 'complex -> commutative', 'odd == integer & !even', 'even == integer & !odd', 'real == negative \| zero \| positive', 'complex -> infinite \| finite', 'transcendental == complex & !algebraic & finite', 'negative == nonpositive & nonzero', 'positive == nonnegative & nonzero', 'zero == nonnegative & nonpositive', 'nonpositive == real & !positive', 'nonnegative == real & !negative', 'zero -> even & finite', 'prime -> integer & positive', 'composite -> integer & positive & !prime', '!composite -> !positive \| !even \| prime', 'irrational == real & !rational & finite', 'imaginary -> !real', 'infinite -> !finite', 'noninteger == real & !integer', 'nonzero == real & !zero', ]) _assume_defined = _assume_rules.defined_facts.copy() _assume_defined.add('polar') _assume_defined = frozenset(_assume_defined) class StdFactKB(FactKB): """A FactKB specialised for the built-in rules This is the only kind of FactKB that Basic objects should use. """ def __init__(self, facts=None): super(StdFactKB, self).__init__(_assume_rules) # save a copy of the facts dict if not facts: self._generator = {} elif not isinstance(facts, FactKB): self._generator = facts.copy() else: self._generator = facts.generator if facts: self.deduce_all_facts(facts) def copy(self): return self.__class__(self) @property def generator(self): return self._generator.copy() def as_property(fact): """Convert a fact name to the name of the corresponding property""" return 'is_%s' % fact def make_property(fact): """Create the automagic property corresponding to a fact.""" def getit(self): try: return self._assumptions[fact] except KeyError: if self._assumptions is self.default_assumptions: self._assumptions = self.default_assumptions.copy() return _ask(fact, self) getit.func_name = as_property(fact) return property(getit) def _ask(fact, obj): """ Find the truth value for a property of an object. This function is called when a request is made to see what a fact value is. For this we use several techniques: First, the fact-evaluation function is tried, if it exists (for example _eval_is_integer). Then we try related facts. For example rational --> integer another example is joined rule: integer & !odd --> even so in the latter case if we are looking at what 'even' value is, 'integer' and 'odd' facts will be asked. In all cases, when we settle on some fact value, its implications are deduced, and the result is cached in ._assumptions. """ assumptions = obj._assumptions handler_map = obj._prop_handler # Store None into the assumptions so that recursive attempts at # evaluating the same fact don't trigger infinite recursion. assumptions._tell(fact, None) # First try the assumption evaluation function if it exists try: evaluate = handler_map[fact] except KeyError: pass else: a = evaluate(obj) if a is not None: assumptions.deduce_all_facts(((fact, a),)) return a # Try assumption's prerequisites prereq = list(_assume_rules.prereq[fact]) shuffle(prereq) for pk in prereq: if pk in assumptions: continue if pk in handler_map: _ask(pk, obj) # we might have found the value of fact ret_val = assumptions.get(fact) if ret_val is not None: return ret_val # Note: the result has already been cached return None class ManagedProperties(BasicMeta): """Metaclass for classes with old-style assumptions""" def __init__(cls, args, kws): BasicMeta.__init__(cls, args, **kws) local_defs = {} for k in _assume_defined: attrname = as_property(k) v = cls.__dict__.get(attrname, '') if isinstance(v, (bool, integer_types, type(None))): if v is not None: v = bool(v) local_defs[k] = v defs = {} for base in reversed(cls.__bases__): assumptions = getattr(base, '_explicit_class_assumptions', None) if assumptions is not None: defs.update(assumptions) defs.update(local_defs) cls._explicit_class_assumptions = defs cls.default_assumptions = StdFactKB(defs) cls._prop_handler = {} for k in _assume_defined: eval_is_meth = getattr(cls, '_eval_is_%s' % k, None) if eval_is_meth is not None: cls._prop_handler[k] = eval_is_meth # Put definite results directly into the class dict, for speed for k, v in cls.default_assumptions.items(): setattr(cls, as_property(k), v) # protection e.g. for Integer.is_even=F <- (Rational.is_integer=F) derived_from_bases = set() for base in cls.__bases__: default_assumptions = getattr(base, 'default_assumptions', None) # is an assumption-aware class if default_assumptions is not None: derived_from_bases.update(default_assumptions) for fact in derived_from_bases - set(cls.default_assumptions): pname = as_property(fact) if pname not in cls.__dict__: setattr(cls, pname, make_property(fact)) # Finally, add any missing automagic property (e.g. for Basic) for fact in _assume_defined: pname = as_property(fact) if not hasattr(cls, pname): setattr(cls, pname, make_property(fact))
74a47e5114eafab3024b0d9e8cbf9ddd97821fe8905e9ed8c591e757c8f7921e	""" There are three types of functions implemented in SymPy: 1) defined functions (in the sense that they can be evaluated) like exp or sin; they have a name and a body: f = exp 2) undefined function which have a name but no body. Undefined functions can be defined using a Function class as follows: f = Function('f') (the result will be a Function instance) 3) anonymous function (or lambda function) which have a body (defined with dummy variables) but have no name: f = Lambda(x, exp(x)x) f = Lambda((x, y), exp(x)y) The fourth type of functions are composites, like (sin + cos)(x); these work in SymPy core, but are not yet part of SymPy. Examples ======== >>> import sympy >>> f = sympy.Function("f") >>> from sympy.abc import x >>> f(x) f(x) >>> print(sympy.srepr(f(x).func)) Function('f') >>> f(x).args (x,) """ from __future__ import print_function, division from .add import Add from .assumptions import ManagedProperties, _assume_defined from .basic import Basic, _atomic from .cache import cacheit from .compatibility import iterable, is_sequence, as_int, ordered, Iterable from .decorators import _sympifyit from .expr import Expr, AtomicExpr from .numbers import Rational, Float from .operations import LatticeOp from .rules import Transform from .singleton import S from .sympify import sympify from sympy.core.containers import Tuple, Dict from sympy.core.logic import fuzzy_and from sympy.core.compatibility import string_types, with_metaclass, PY3, range from sympy.utilities import default_sort_key from sympy.utilities.misc import filldedent from sympy.utilities.iterables import has_dups, sift from sympy.core.evaluate import global_evaluate import mpmath import mpmath.libmp as mlib import inspect from collections import Counter def _coeff_isneg(a): """Return True if the leading Number is negative. Examples ======== >>> from sympy.core.function import _coeff_isneg >>> from sympy import S, Symbol, oo, pi >>> _coeff_isneg(-3pi) True >>> _coeff_isneg(S(3)) False >>> _coeff_isneg(-oo) True >>> _coeff_isneg(Symbol('n', negative=True)) # coeff is 1 False For matrix expressions: >>> from sympy import MatrixSymbol, sqrt >>> A = MatrixSymbol("A", 3, 3) >>> _coeff_isneg(-sqrt(2)A) True >>> _coeff_isneg(sqrt(2)A) False """ if a.is_MatMul: a = a.args[0] if a.is_Mul: a = a.args[0] return a.is_Number and a.is_negative class PoleError(Exception): pass class ArgumentIndexError(ValueError): def __str__(self): return ("Invalid operation with argument number %s for Function %s" % (self.args[1], self.args[0])) # Python 2/3 version that does not raise a Deprecation warning def arity(cls): """Return the arity of the function if it is known, else None. When default values are specified for some arguments, they are optional and the arity is reported as a tuple of possible values. Examples ======== >>> from sympy.core.function import arity >>> from sympy import log >>> arity(lambda x: x) 1 >>> arity(log) (1, 2) >>> arity(lambda x: sum(x)) is None True """ eval_ = getattr(cls, 'eval', cls) if PY3: parameters = inspect.signature(eval_).parameters.items() if [p for _, p in parameters if p.kind == p.VAR_POSITIONAL]: return p_or_k = [p for _, p in parameters if p.kind == p.POSITIONAL_OR_KEYWORD] # how many have no default and how many have a default value no, yes = map(len, sift(p_or_k, lambda p:p.default == p.empty, binary=True)) return no if not yes else tuple(range(no, no + yes + 1)) else: cls_ = int(hasattr(cls, 'eval')) # correction for cls arguments evalargspec = inspect.getargspec(eval_) if evalargspec.varargs: return else: evalargs = len(evalargspec.args) - cls_ if evalargspec.defaults: # if there are default args then they are optional; the # fewest args will occur when all defaults are used and # the most when none are used (i.e. all args are given) fewest = evalargs - len(evalargspec.defaults) return tuple(range(fewest, evalargs + 1)) return evalargs class FunctionClass(ManagedProperties): """ Base class for function classes. FunctionClass is a subclass of type. Use Function('<function name>' [ , signature ]) to create undefined function classes. """ _new = type.__new__ def __init__(cls, args, kwargs): # honor kwarg value or class-defined value before using # the number of arguments in the eval function (if present) nargs = kwargs.pop('nargs', cls.__dict__.get('nargs', arity(cls))) # Canonicalize nargs here; change to set in nargs. if is_sequence(nargs): if not nargs: raise ValueError(filldedent(''' Incorrectly specified nargs as %s: if there are no arguments, it should be `nargs = 0`; if there are any number of arguments, it should be `nargs = None`''' % str(nargs))) nargs = tuple(ordered(set(nargs))) elif nargs is not None: nargs = (as_int(nargs),) cls._nargs = nargs super(FunctionClass, cls).__init__(args, kwargs) @property def __signature__(self): """ Allow Python 3's inspect.signature to give a useful signature for Function subclasses. """ # Python 3 only, but backports (like the one in IPython) still might # call this. try: from inspect import signature except ImportError: return None # TODO: Look at nargs return signature(self.eval) @property def free_symbols(self): return set() @property def xreplace(self): # Function needs args so we define a property that returns # a function that takes args...and then use that function # to return the right value return lambda rule, _: rule.get(self, self) @property def nargs(self): """Return a set of the allowed number of arguments for the function. Examples ======== >>> from sympy.core.function import Function >>> from sympy.abc import x, y >>> f = Function('f') If the function can take any number of arguments, the set of whole numbers is returned: >>> Function('f').nargs Naturals0 If the function was initialized to accept one or more arguments, a corresponding set will be returned: >>> Function('f', nargs=1).nargs {1} >>> Function('f', nargs=(2, 1)).nargs {1, 2} The undefined function, after application, also has the nargs attribute; the actual number of arguments is always available by checking the ``args`` attribute: >>> f = Function('f') >>> f(1).nargs Naturals0 >>> len(f(1).args) 1 """ from sympy.sets.sets import FiniteSet # XXX it would be nice to handle this in __init__ but there are import # problems with trying to import FiniteSet there return FiniteSet(self._nargs) if self._nargs else S.Naturals0 def __repr__(cls): return cls.__name__ class Application(with_metaclass(FunctionClass, Basic)): """ Base class for applied functions. Instances of Application represent the result of applying an application of any type to any object. """ is_Function = True @cacheit def __new__(cls, args, *options): from sympy.sets.fancysets import Naturals0 from sympy.sets.sets import FiniteSet args = list(map(sympify, args)) evaluate = options.pop('evaluate', global_evaluate[0]) # WildFunction (and anything else like it) may have nargs defined # and we throw that value away here options.pop('nargs', None) if options: raise ValueError("Unknown options: %s" % options) if evaluate: evaluated = cls.eval(args) if evaluated is not None: return evaluated obj = super(Application, cls).__new__(cls, args, options) # make nargs uniform here sentinel = object() objnargs = getattr(obj, "nargs", sentinel) if objnargs is not sentinel: # things passing through here: # - functions subclassed from Function (e.g. myfunc(1).nargs) # - functions like cos(1).nargs # - AppliedUndef with given nargs like Function('f', nargs=1)(1).nargs # Canonicalize nargs here if is_sequence(objnargs): nargs = tuple(ordered(set(objnargs))) elif objnargs is not None: nargs = (as_int(objnargs),) else: nargs = None else: # things passing through here: # - WildFunction('f').nargs # - AppliedUndef with no nargs like Function('f')(1).nargs nargs = obj._nargs # note the underscore here # convert to FiniteSet obj.nargs = FiniteSet(nargs) if nargs else Naturals0() return obj @classmethod def eval(cls, args): """ Returns a canonical form of cls applied to arguments args. The eval() method is called when the class cls is about to be instantiated and it should return either some simplified instance (possible of some other class), or if the class cls should be unmodified, return None. Examples of eval() for the function "sign" --------------------------------------------- .. code-block:: python @classmethod def eval(cls, arg): if arg is S.NaN: return S.NaN if arg is S.Zero: return S.Zero if arg.is_positive: return S.One if arg.is_negative: return S.NegativeOne if isinstance(arg, Mul): coeff, terms = arg.as_coeff_Mul(rational=True) if coeff is not S.One: return cls(coeff) cls(terms) """ return @property def func(self): return self.__class__ def _eval_subs(self, old, new): if (old.is_Function and new.is_Function and callable(old) and callable(new) and old == self.func and len(self.args) in new.nargs): return new([i._subs(old, new) for i in self.args]) class Function(Application, Expr): """ Base class for applied mathematical functions. It also serves as a constructor for undefined function classes. Examples ======== First example shows how to use Function as a constructor for undefined function classes: >>> from sympy import Function, Symbol >>> x = Symbol('x') >>> f = Function('f') >>> g = Function('g')(x) >>> f f >>> f(x) f(x) >>> g g(x) >>> f(x).diff(x) Derivative(f(x), x) >>> g.diff(x) Derivative(g(x), x) Assumptions can be passed to Function. >>> f_real = Function('f', real=True) >>> f_real(x).is_real True Note that assumptions on a function are unrelated to the assumptions on the variable it is called on. If you want to add a relationship, subclass Function and define the appropriate ``_eval_is_assumption`` methods. In the following example Function is used as a base class for ``my_func`` that represents a mathematical function my_func. Suppose that it is well known, that my_func(0)* is 1 and my_func at infinity goes to 0, so we want those two simplifications to occur automatically. Suppose also that my_func(x) is real exactly when x is real. Here is an implementation that honours those requirements: >>> from sympy import Function, S, oo, I, sin >>> class my_func(Function): ... ... @classmethod ... def eval(cls, x): ... if x.is_Number: ... if x is S.Zero: ... return S.One ... elif x is S.Infinity: ... return S.Zero ... ... def _eval_is_real(self): ... return self.args[0].is_real ... >>> x = S('x') >>> my_func(0) + sin(0) 1 >>> my_func(oo) 0 >>> my_func(3.54).n() # Not yet implemented for my_func. my_func(3.54) >>> my_func(I).is_real False In order for ``my_func`` to become useful, several other methods would need to be implemented. See source code of some of the already implemented functions for more complete examples. Also, if the function can take more than one argument, then ``nargs`` must be defined, e.g. if ``my_func`` can take one or two arguments then, >>> class my_func(Function): ... nargs = (1, 2) ... >>> """ @property def _diff_wrt(self): return False @cacheit def __new__(cls, args, options): # Handle calls like Function('f') if cls is Function: return UndefinedFunction(args, *options) n = len(args) if n not in cls.nargs: # XXX: exception message must be in exactly this format to # make it work with NumPy's functions like vectorize(). See, # for example, https://github.com/numpy/numpy/issues/1697. # The ideal solution would be just to attach metadata to # the exception and change NumPy to take advantage of this. temp = ('%(name)s takes %(qual)s %(args)s ' 'argument%(plural)s (%(given)s given)') raise TypeError(temp % { 'name': cls, 'qual': 'exactly' if len(cls.nargs) == 1 else 'at least', 'args': min(cls.nargs), 'plural': 's'(min(cls.nargs) != 1), 'given': n}) evaluate = options.get('evaluate', global_evaluate[0]) result = super(Function, cls).__new__(cls, args, options) if evaluate and isinstance(result, cls) and result.args: pr2 = min(cls._should_evalf(a) for a in result.args) if pr2 > 0: pr = max(cls._should_evalf(a) for a in result.args) result = result.evalf(mlib.libmpf.prec_to_dps(pr)) return result @classmethod def _should_evalf(cls, arg): """ Decide if the function should automatically evalf(). By default (in this implementation), this happens if (and only if) the ARG is a floating point number. This function is used by __new__. Returns the precision to evalf to, or -1 if it shouldn't evalf. """ from sympy.core.evalf import pure_complex if arg.is_Float: return arg._prec if not arg.is_Add: return -1 m = pure_complex(arg) if m is None or not (m[0].is_Float or m[1].is_Float): return -1 l = [i._prec for i in m if i.is_Float] l.append(-1) return max(l) @classmethod def class_key(cls): from sympy.sets.fancysets import Naturals0 funcs = { 'exp': 10, 'log': 11, 'sin': 20, 'cos': 21, 'tan': 22, 'cot': 23, 'sinh': 30, 'cosh': 31, 'tanh': 32, 'coth': 33, 'conjugate': 40, 're': 41, 'im': 42, 'arg': 43, } name = cls.__name__ try: i = funcs[name] except KeyError: i = 0 if isinstance(cls.nargs, Naturals0) else 10000 return 4, i, name @property def is_commutative(self): """ Returns whether the function is commutative. """ if all(getattr(t, 'is_commutative') for t in self.args): return True else: return False def _eval_evalf(self, prec): def _get_mpmath_func(fname): """Lookup mpmath function based on name""" if isinstance(self, AppliedUndef): # Shouldn't lookup in mpmath but might have ._imp_ return None if not hasattr(mpmath, fname): from sympy.utilities.lambdify import MPMATH_TRANSLATIONS fname = MPMATH_TRANSLATIONS.get(fname, None) if fname is None: return None return getattr(mpmath, fname) func = _get_mpmath_func(self.func.__name__) # Fall-back evaluation if func is None: imp = getattr(self, '_imp_', None) if imp is None: return None try: return Float(imp([i.evalf(prec) for i in self.args]), prec) except (TypeError, ValueError) as e: return None # Convert all args to mpf or mpc # Convert the arguments to higher precision than requested for the # final result. # XXX + 5 is a guess, it is similar to what is used in evalf.py. Should # we be more intelligent about it? try: args = [arg._to_mpmath(prec + 5) for arg in self.args] def bad(m): from mpmath import mpf, mpc # the precision of an mpf value is the last element # if that is 1 (and m[1] is not 1 which would indicate a # power of 2), then the eval failed; so check that none of # the arguments failed to compute to a finite precision. # Note: An mpc value has two parts, the re and imag tuple; # check each of those parts, too. Anything else is allowed to # pass if isinstance(m, mpf): m = m._mpf_ return m[1] !=1 and m[-1] == 1 elif isinstance(m, mpc): m, n = m._mpc_ return m[1] !=1 and m[-1] == 1 and \ n[1] !=1 and n[-1] == 1 else: return False if any(bad(a) for a in args): raise ValueError # one or more args failed to compute with significance except ValueError: return with mpmath.workprec(prec): v = func(args) return Expr._from_mpmath(v, prec) def _eval_derivative(self, s): # f(x).diff(s) -> x.diff(s) f.fdiff(1)(s) i = 0 l = [] for a in self.args: i += 1 da = a.diff(s) if da is S.Zero: continue try: df = self.fdiff(i) except ArgumentIndexError: df = Function.fdiff(self, i) l.append(df * da) return Add(l) def _eval_is_commutative(self): return fuzzy_and(a.is_commutative for a in self.args) def _eval_is_complex(self): return fuzzy_and(a.is_complex for a in self.args) def as_base_exp(self): """ Returns the method as the 2-tuple (base, exponent). """ return self, S.One def _eval_aseries(self, n, args0, x, logx): """ Compute an asymptotic expansion around args0, in terms of self.args. This function is only used internally by _eval_nseries and should not be called directly; derived classes can overwrite this to implement asymptotic expansions. """ from sympy.utilities.misc import filldedent raise PoleError(filldedent(''' Asymptotic expansion of %s around %s is not implemented.''' % (type(self), args0))) def _eval_nseries(self, x, n, logx): """ This function does compute series for multivariate functions, but the expansion is always in terms of one* variable. Examples ======== >>> from sympy import atan2 >>> from sympy.abc import x, y >>> atan2(x, y).series(x, n=2) atan2(0, y) + x/y + O(x2) >>> atan2(x, y).series(y, n=2) -y/x + atan2(x, 0) + O(y2) This function also computes asymptotic expansions, if necessary and possible: >>> from sympy import loggamma >>> loggamma(1/x)._eval_nseries(x,0,None) -1/x - log(x)/x + log(x)/2 + O(1) """ from sympy import Order from sympy.sets.sets import FiniteSet args = self.args args0 = [t.limit(x, 0) for t in args] if any(t.is_finite is False for t in args0): from sympy import oo, zoo, nan # XXX could use t.as_leading_term(x) here but it's a little # slower a = [t.compute_leading_term(x, logx=logx) for t in args] a0 = [t.limit(x, 0) for t in a] if any([t.has(oo, -oo, zoo, nan) for t in a0]): return self._eval_aseries(n, args0, x, logx) # Careful: the argument goes to oo, but only logarithmically so. We # are supposed to do a power series expansion "around the # logarithmic term". e.g. # f(1+x+log(x)) # -> f(1+logx) + xf'(1+logx) + O(x2) # where 'logx' is given in the argument a = [t._eval_nseries(x, n, logx) for t in args] z = [r - r0 for (r, r0) in zip(a, a0)] p = [Dummy() for _ in z] q = [] v = None for ai, zi, pi in zip(a0, z, p): if zi.has(x): if v is not None: raise NotImplementedError q.append(ai + pi) v = pi else: q.append(ai) e1 = self.func(q) if v is None: return e1 s = e1._eval_nseries(v, n, logx) o = s.getO() s = s.removeO() s = s.subs(v, zi).expand() + Order(o.expr.subs(v, zi), x) return s if (self.func.nargs is S.Naturals0 or (self.func.nargs == FiniteSet(1) and args0[0]) or any(c > 1 for c in self.func.nargs)): e = self e1 = e.expand() if e == e1: #for example when e = sin(x+1) or e = sin(cos(x)) #let's try the general algorithm term = e.subs(x, S.Zero) if term.is_finite is False or term is S.NaN: raise PoleError("Cannot expand %s around 0" % (self)) series = term fact = S.One _x = Dummy('x') e = e.subs(x, _x) for i in range(n - 1): i += 1 fact = Rational(i) e = e.diff(_x) subs = e.subs(_x, S.Zero) if subs is S.NaN: # try to evaluate a limit if we have to subs = e.limit(_x, S.Zero) if subs.is_finite is False: raise PoleError("Cannot expand %s around 0" % (self)) term = subs(xi)/fact term = term.expand() series += term return series + Order(xn, x) return e1.nseries(x, n=n, logx=logx) arg = self.args[0] l = [] g = None # try to predict a number of terms needed nterms = n + 2 cf = Order(arg.as_leading_term(x), x).getn() if cf != 0: nterms = int(nterms / cf) for i in range(nterms): g = self.taylor_term(i, arg, g) g = g.nseries(x, n=n, logx=logx) l.append(g) return Add(l) + Order(xn, x) def fdiff(self, argindex=1): """ Returns the first derivative of the function. """ if not (1 <= argindex <= len(self.args)): raise ArgumentIndexError(self, argindex) ix = argindex - 1 A = self.args[ix] if A._diff_wrt: if len(self.args) == 1: return Derivative(self, A) if A.is_Symbol: for i, v in enumerate(self.args): if i != ix and A in v.free_symbols: # it can't be in any other argument's free symbols # issue 8510 break else: return Derivative(self, A) else: free = A.free_symbols for i, a in enumerate(self.args): if ix != i and a.free_symbols & free: break else: # there is no possible interaction bewtween args return Derivative(self, A) # See issue 4624 and issue 4719, 5600 and 8510 D = Dummy('xi_%i' % argindex, dummy_index=hash(A)) args = self.args[:ix] + (D,) + self.args[ix + 1:] return Subs(Derivative(self.func(args), D), D, A) def _eval_as_leading_term(self, x): """Stub that should be overridden by new Functions to return the first non-zero term in a series if ever an x-dependent argument whose leading term vanishes as x -> 0 might be encountered. See, for example, cos._eval_as_leading_term. """ from sympy import Order args = [a.as_leading_term(x) for a in self.args] o = Order(1, x) if any(x in a.free_symbols and o.contains(a) for a in args): # Whereas x and any finite number are contained in O(1, x), # expressions like 1/x are not. If any arg simplified to a # vanishing expression as x -> 0 (like x or x*2, but not # 3, 1/x, etc...) then the _eval_as_leading_term is needed # to supply the first non-zero term of the series, # # e.g. expression leading term # ---------- ------------ # cos(1/x) cos(1/x) # cos(cos(x)) cos(1) # cos(x) 1 <- _eval_as_leading_term needed # sin(x) x <- _eval_as_leading_term needed # raise NotImplementedError( '%s has no _eval_as_leading_term routine' % self.func) else: return self.func(args) def _sage_(self): import sage.all as sage fname = self.func.__name__ func = getattr(sage, fname, None) args = [arg._sage_() for arg in self.args] # In the case the function is not known in sage: if func is None: import sympy if getattr(sympy, fname, None) is None: # abstract function return sage.function(fname)(args) else: # the function defined in sympy is not known in sage # this exception is caught in sage raise AttributeError return func(args) class AppliedUndef(Function): """ Base class for expressions resulting from the application of an undefined function. """ is_number = False def __new__(cls, args, options): args = list(map(sympify, args)) obj = super(AppliedUndef, cls).__new__(cls, args, *options) return obj def _eval_as_leading_term(self, x): return self def _sage_(self): import sage.all as sage fname = str(self.func) args = [arg._sage_() for arg in self.args] func = sage.function(fname)(args) return func @property def _diff_wrt(self): """ Allow derivatives wrt to undefined functions. Examples ======== >>> from sympy import Function, Symbol >>> f = Function('f') >>> x = Symbol('x') >>> f(x)._diff_wrt True >>> f(x).diff(x) Derivative(f(x), x) """ return True class UndefinedFunction(FunctionClass): """ The (meta)class of undefined functions. """ def __new__(mcl, name, bases=(AppliedUndef,), __dict__=None, kwargs): __dict__ = __dict__ or {} # Allow Function('f', real=True) __dict__.update({'is_' + arg: val for arg, val in kwargs.items() if arg in _assume_defined}) # You can add other attributes, although they do have to be hashable # (but seriously, if you want to add anything other than assumptions, # just subclass Function) __dict__.update(kwargs) # Save these for __eq__ __dict__.update({'_extra_kwargs': kwargs}) __dict__['__module__'] = None # For pickling ret = super(UndefinedFunction, mcl).__new__(mcl, name, bases, __dict__) ret.name = name return ret def __instancecheck__(cls, instance): return cls in type(instance).__mro__ _extra_kwargs = {} def __hash__(self): return hash((self.class_key(), frozenset(self._extra_kwargs.items()))) def __eq__(self, other): return (isinstance(other, self.__class__) and self.class_key() == other.class_key() and self._extra_kwargs == other._extra_kwargs) def __ne__(self, other): return not self == other class WildFunction(Function, AtomicExpr): """ A WildFunction function matches any function (with its arguments). Examples ======== >>> from sympy import WildFunction, Function, cos >>> from sympy.abc import x, y >>> F = WildFunction('F') >>> f = Function('f') >>> F.nargs Naturals0 >>> x.match(F) >>> F.match(F) {F_: F_} >>> f(x).match(F) {F_: f(x)} >>> cos(x).match(F) {F_: cos(x)} >>> f(x, y).match(F) {F_: f(x, y)} To match functions with a given number of arguments, set ``nargs`` to the desired value at instantiation: >>> F = WildFunction('F', nargs=2) >>> F.nargs {2} >>> f(x).match(F) >>> f(x, y).match(F) {F_: f(x, y)} To match functions with a range of arguments, set ``nargs`` to a tuple containing the desired number of arguments, e.g. if ``nargs = (1, 2)`` then functions with 1 or 2 arguments will be matched. >>> F = WildFunction('F', nargs=(1, 2)) >>> F.nargs {1, 2} >>> f(x).match(F) {F_: f(x)} >>> f(x, y).match(F) {F_: f(x, y)} >>> f(x, y, 1).match(F) """ include = set() def __init__(cls, name, assumptions): from sympy.sets.sets import Set, FiniteSet cls.name = name nargs = assumptions.pop('nargs', S.Naturals0) if not isinstance(nargs, Set): # Canonicalize nargs here. See also FunctionClass. if is_sequence(nargs): nargs = tuple(ordered(set(nargs))) elif nargs is not None: nargs = (as_int(nargs),) nargs = FiniteSet(nargs) cls.nargs = nargs def matches(self, expr, repl_dict={}, old=False): if not isinstance(expr, (AppliedUndef, Function)): return None if len(expr.args) not in self.nargs: return None repl_dict = repl_dict.copy() repl_dict[self] = expr return repl_dict class Derivative(Expr): """ Carries out differentiation of the given expression with respect to symbols. Examples ======== >>> from sympy import Derivative, Function, symbols, Subs >>> from sympy.abc import x, y >>> f, g = symbols('f g', cls=Function) >>> Derivative(x2, x, evaluate=True) 2x Denesting of derivatives retains the ordering of variables: >>> Derivative(Derivative(f(x, y), y), x) Derivative(f(x, y), y, x) Contiguously identical symbols are merged into a tuple giving the symbol and the count: >>> Derivative(f(x), x, x, y, x) Derivative(f(x), (x, 2), y, x) If the derivative cannot be performed, and evaluate is True, the order of the variables of differentiation will be made canonical: >>> Derivative(f(x, y), y, x, evaluate=True) Derivative(f(x, y), x, y) Derivatives with respect to undefined functions can be calculated: >>> Derivative(f(x)*2, f(x), evaluate=True) 2f(x) Such derivatives will show up when the chain rule is used to evalulate a derivative: >>> f(g(x)).diff(x) Derivative(f(g(x)), g(x))Derivative(g(x), x) Substitution is used to represent derivatives of functions with arguments that are not symbols or functions: >>> f(2x + 3).diff(x) == 2Subs(f(y).diff(y), y, 2x + 3) True Notes ===== Simplification of high-order derivatives: Because there can be a significant amount of simplification that can be done when multiple differentiations are performed, results will be automatically simplified in a fairly conservative fashion unless the keyword ``simplify`` is set to False. >>> from sympy import cos, sin, sqrt, diff, Function, symbols >>> from sympy.abc import x, y, z >>> f, g = symbols('f,g', cls=Function) >>> e = sqrt((x + 1)*2 + x) >>> diff(e, (x, 5), simplify=False).count_ops() 136 >>> diff(e, (x, 5)).count_ops() 30 Ordering of variables: If evaluate is set to True and the expression cannot be evaluated, the list of differentiation symbols will be sorted, that is, the expression is assumed to have continuous derivatives up to the order asked. Derivative wrt non-Symbols: For the most part, one may not differentiate wrt non-symbols. For example, we do not allow differentiation wrt `xy` because there are multiple ways of structurally defining where xy appears in an expression: a very strict definition would make (xyz).diff(xy) == 0. Derivatives wrt defined functions (like cos(x)) are not allowed, either: >>> (xyz).diff(xy) Traceback (most recent call last): ... ValueError: Can't calculate derivative wrt xy. To make it easier to work with variational calculus, however, derivatives wrt AppliedUndef and Derivatives are allowed. For example, in the Euler-Lagrange method one may write F(t, u, v) where u = f(t) and v = f'(t). These variables can be written explicity as functions of time:: >>> from sympy.abc import t >>> F = Function('F') >>> U = f(t) >>> V = U.diff(t) The derivative wrt f(t) can be obtained directly: >>> direct = F(t, U, V).diff(U) When differentiation wrt a non-Symbol is attempted, the non-Symbol is temporarily converted to a Symbol while the differentiation is performed and the same answer is obtained: >>> indirect = F(t, U, V).subs(U, x).diff(x).subs(x, U) >>> assert direct == indirect The implication of this non-symbol replacement is that all functions are treated as independent of other functions and the symbols are independent of the functions that contain them:: >>> x.diff(f(x)) 0 >>> g(x).diff(f(x)) 0 It also means that derivatives are assumed to depend only on the variables of differentiation, not on anything contained within the expression being differentiated:: >>> F = f(x) >>> Fx = F.diff(x) >>> Fx.diff(F) # derivative depends on x, not F 0 >>> Fxx = Fx.diff(x) >>> Fxx.diff(Fx) # derivative depends on x, not Fx 0 The last example can be made explicit by showing the replacement of Fx in Fxx with y: >>> Fxx.subs(Fx, y) Derivative(y, x) Since that in itself will evaluate to zero, differentiating wrt Fx will also be zero: >>> _.doit() 0 Replacing undefined functions with concrete expressions One must be careful to replace undefined functions with expressions that contain variables consistent with the function definition and the variables of differentiation or else insconsistent result will be obtained. Consider the following example: >>> eq = f(x)g(y) >>> eq.subs(f(x), xy).diff(x, y).doit() yDerivative(g(y), y) + g(y) >>> eq.diff(x, y).subs(f(x), xy).doit() yDerivative(g(y), y) The results differ because `f(x)` was replaced with an expression that involved both variables of differentiation. In the abstract case, differentiation of `f(x)` by `y` is 0; in the concrete case, the presence of `y` made that derivative nonvanishing and produced the extra `g(y)` term. Defining differentiation for an object An object must define ._eval_derivative(symbol) method that returns the differentiation result. This function only needs to consider the non-trivial case where expr contains symbol and it should call the diff() method internally (not _eval_derivative); Derivative should be the only one to call _eval_derivative. Any class can allow derivatives to be taken with respect to itself (while indicating its scalar nature). See the docstring of Expr._diff_wrt. See Also ======== _sort_variable_count """ is_Derivative = True @property def _diff_wrt(self): """An expression may be differentiated wrt a Derivative if it is in elementary form. Examples ======== >>> from sympy import Function, Derivative, cos >>> from sympy.abc import x >>> f = Function('f') >>> Derivative(f(x), x)._diff_wrt True >>> Derivative(cos(x), x)._diff_wrt False >>> Derivative(x + 1, x)._diff_wrt False A Derivative might be an unevaluated form of what will not be a valid variable of differentiation if evaluated. For example, >>> Derivative(f(f(x)), x).doit() Derivative(f(x), x)Derivative(f(f(x)), f(x)) Such an expression will present the same ambiguities as arise when dealing with any other product, like `2x`, so `_diff_wrt` is False: >>> Derivative(f(f(x)), x)._diff_wrt False """ return self.expr._diff_wrt and isinstance(self.doit(), Derivative) def __new__(cls, expr, variables, *kwargs): from sympy.matrices.common import MatrixCommon from sympy import Integer, MatrixExpr from sympy.tensor.array import Array, NDimArray, derive_by_array from sympy.utilities.misc import filldedent expr = sympify(expr) symbols_or_none = getattr(expr, "free_symbols", None) has_symbol_set = isinstance(symbols_or_none, set) if not has_symbol_set: raise ValueError(filldedent(''' Since there are no variables in the expression %s, it cannot be differentiated.''' % expr)) # determine value for variables if it wasn't given if not variables: variables = expr.free_symbols if len(variables) != 1: if expr.is_number: return S.Zero if len(variables) == 0: raise ValueError(filldedent(''' Since there are no variables in the expression, the variable(s) of differentiation must be supplied to differentiate %s''' % expr)) else: raise ValueError(filldedent(''' Since there is more than one variable in the expression, the variable(s) of differentiation must be supplied to differentiate %s''' % expr)) # Standardize the variables by sympifying them: variables = list(sympify(variables)) # Split the list of variables into a list of the variables we are diff # wrt, where each element of the list has the form (s, count) where # s is the entity to diff wrt and count is the order of the # derivative. variable_count = [] array_likes = (tuple, list, Tuple) for i, v in enumerate(variables): if isinstance(v, Integer): if i == 0: raise ValueError("First variable cannot be a number: %i" % v) count = v prev, prevcount = variable_count[-1] if prevcount != 1: raise TypeError("tuple {0} followed by number {1}".format((prev, prevcount), v)) if count == 0: variable_count.pop() else: variable_count[-1] = Tuple(prev, count) else: if isinstance(v, array_likes): if len(v) == 0: # Ignore empty tuples: Derivative(expr, ... , (), ... ) continue if isinstance(v[0], array_likes): # Derive by array: Derivative(expr, ... , [[x, y, z]], ... ) if len(v) == 1: v = Array(v[0]) count = 1 else: v, count = v v = Array(v) else: v, count = v if count == 0: continue else: count = 1 variable_count.append(Tuple(v, count)) # light evaluation of contiguous, identical # items: (x, 1), (x, 1) -> (x, 2) merged = [] for t in variable_count: v, c = t if c.is_negative: raise ValueError( 'order of differentiation must be nonnegative') if merged and merged[-1][0] == v: c += merged[-1][1] if not c: merged.pop() else: merged[-1] = Tuple(v, c) else: merged.append(t) variable_count = merged # sanity check of variables of differentation; we waited # until the counts were computed since some variables may # have been removed because the count was 0 for v, c in variable_count: # v must have _diff_wrt True if not v._diff_wrt: __ = '' # filler to make error message neater raise ValueError(filldedent(''' Can't calculate derivative wrt %s.%s''' % (v, __))) # We make a special case for 0th derivative, because there is no # good way to unambiguously print this. if len(variable_count) == 0: return expr evaluate = kwargs.get('evaluate', False) if evaluate: if isinstance(expr, Derivative): expr = expr.canonical variable_count = [ (v.canonical if isinstance(v, Derivative) else v, c) for v, c in variable_count] # Look for a quick exit if there are symbols that don't appear in # expression at all. Note, this cannot check non-symbols like # Derivatives as those can be created by intermediate # derivatives. zero = False free = expr.free_symbols for v, c in variable_count: vfree = v.free_symbols if c.is_positive and vfree: if isinstance(v, AppliedUndef): # these match exactly since # x.diff(f(x)) == g(x).diff(f(x)) == 0 # and are not created by differentiation D = Dummy() if not expr.xreplace({v: D}).has(D): zero = True break elif isinstance(v, MatrixExpr): zero = False break elif isinstance(v, Symbol) and v not in free: zero = True break else: if not free & vfree: # e.g. v is IndexedBase or Matrix zero = True break if zero: if isinstance(expr, (MatrixCommon, NDimArray)): return expr.zeros(expr.shape) elif expr.is_scalar: return S.Zero # make the order of symbols canonical #TODO: check if assumption of discontinuous derivatives exist variable_count = cls._sort_variable_count(variable_count) # denest if isinstance(expr, Derivative): variable_count = list(expr.variable_count) + variable_count expr = expr.expr return Derivative(expr, variable_count, kwargs) # we return here if evaluate is False or if there is no # _eval_derivative method if not evaluate or not hasattr(expr, '_eval_derivative'): # return an unevaluated Derivative if evaluate and variable_count == [(expr, 1)] and expr.is_scalar: # special hack providing evaluation for classes # that have defined is_scalar=True but have no # _eval_derivative defined return S.One return Expr.__new__(cls, expr, variable_count) # evaluate the derivative by calling _eval_derivative method # of expr for each variable # ------------------------------------------------------------- nderivs = 0 # how many derivatives were performed unhandled = [] for i, (v, count) in enumerate(variable_count): old_expr = expr old_v = None is_symbol = v.is_symbol or isinstance(v, (Iterable, Tuple, MatrixCommon, NDimArray)) if not is_symbol: old_v = v v = Dummy('xi') expr = expr.xreplace({old_v: v}) # Derivatives and UndefinedFunctions are independent # of all others clashing = not (isinstance(old_v, Derivative) or \ isinstance(old_v, AppliedUndef)) if not v in expr.free_symbols and not clashing: return expr.diff(v) # expr's version of 0 if not old_v.is_scalar and not hasattr( old_v, '_eval_derivative'): # special hack providing evaluation for classes # that have defined is_scalar=True but have no # _eval_derivative defined expr = old_v.diff(old_v) # Evaluate the derivative `n` times. If # `_eval_derivative_n_times` is not overridden by the current # object, the default in `Basic` will call a loop over # `_eval_derivative`: obj = expr._eval_derivative_n_times(v, count) if obj is not None and obj.is_zero: return obj nderivs += count if old_v is not None: if obj is not None: # remove the dummy that was used obj = obj.subs(v, old_v) # restore expr expr = old_expr if obj is None: # we've already checked for quick-exit conditions # that give 0 so the remaining variables # are contained in the expression but the expression # did not compute a derivative so we stop taking # derivatives unhandled = variable_count[i:] break expr = obj # what we have so far can be made canonical expr = expr.replace( lambda x: isinstance(x, Derivative), lambda x: x.canonical) if unhandled: if isinstance(expr, Derivative): unhandled = list(expr.variable_count) + unhandled expr = expr.expr expr = Expr.__new__(cls, expr, unhandled) if (nderivs > 1) == True and kwargs.get('simplify', True): from sympy.core.exprtools import factor_terms from sympy.simplify.simplify import signsimp expr = factor_terms(signsimp(expr)) return expr @property def canonical(cls): return cls.func(cls.expr, Derivative._sort_variable_count(cls.variable_count)) @classmethod def _sort_variable_count(cls, vc): """ Sort (variable, count) pairs into canonical order while retaining order of variables that do not commute during differentiation: symbols and functions commute with each other * derivatives commute with each other * a derivative doesn't commute with anything it contains * any other object is not allowed to commute if it has free symbols in common with another object Examples ======== >>> from sympy import Derivative, Function, symbols, cos >>> vsort = Derivative._sort_variable_count >>> x, y, z = symbols('x y z') >>> f, g, h = symbols('f g h', cls=Function) Contiguous items are collapsed into one pair: >>> vsort([(x, 1), (x, 1)]) [(x, 2)] >>> vsort([(y, 1), (f(x), 1), (y, 1), (f(x), 1)]) [(y, 2), (f(x), 2)] Ordering is canonical. >>> def vsort0(v): ... # docstring helper to ... # change vi -> (vi, 0), sort, and return vi vals ... return [i[0] for i in vsort([(i, 0) for i in v])] >>> vsort0(y, x) [x, y] >>> vsort0(g(y), g(x), f(y)) [f(y), g(x), g(y)] Symbols are sorted as far to the left as possible but never move to the left of a derivative having the same symbol in its variables; the same applies to AppliedUndef which are always sorted after Symbols: >>> dfx = f(x).diff(x) >>> assert vsort0(dfx, y) == [y, dfx] >>> assert vsort0(dfx, x) == [dfx, x] """ from sympy.utilities.iterables import uniq, topological_sort if not vc: return [] vc = list(vc) if len(vc) == 1: return [Tuple(vc[0])] V = list(range(len(vc))) E = [] v = lambda i: vc[i][0] D = Dummy() def _block(d, v, wrt=False): # return True if v should not come before d else False if d == v: return wrt if d.is_Symbol: return False if isinstance(d, Derivative): # a derivative blocks if any of it's variables contain # v; the wrt flag will return True for an exact match # and will cause an AppliedUndef to block if v is in # the arguments if any(_block(k, v, wrt=True) for k in d._wrt_variables): return True return False if not wrt and isinstance(d, AppliedUndef): return False if v.is_Symbol: return v in d.free_symbols if isinstance(v, AppliedUndef): return _block(d.xreplace({v: D}), D) return d.free_symbols & v.free_symbols for i in range(len(vc)): for j in range(i): if _block(v(j), v(i)): E.append((j,i)) # this is the default ordering to use in case of ties O = dict(zip(ordered(uniq([i for i, c in vc])), range(len(vc)))) ix = topological_sort((V, E), key=lambda i: O[v(i)]) # merge counts of contiguously identical items merged = [] for v, c in [vc[i] for i in ix]: if merged and merged[-1][0] == v: merged[-1][1] += c else: merged.append([v, c]) return [Tuple(i) for i in merged] def _eval_is_commutative(self): return self.expr.is_commutative def _eval_derivative(self, v): # If v (the variable of differentiation) is not in # self.variables, we might be able to take the derivative. if v not in self._wrt_variables: dedv = self.expr.diff(v) if isinstance(dedv, Derivative): return dedv.func(dedv.expr, (self.variable_count + dedv.variable_count)) # dedv (d(self.expr)/dv) could have simplified things such that the # derivative wrt things in self.variables can now be done. Thus, # we set evaluate=True to see if there are any other derivatives # that can be done. The most common case is when dedv is a simple # number so that the derivative wrt anything else will vanish. return self.func(dedv, self.variables, evaluate=True) # In this case v was in self.variables so the derivative wrt v has # already been attempted and was not computed, either because it # couldn't be or evaluate=False originally. variable_count = list(self.variable_count) variable_count.append((v, 1)) return self.func(self.expr, variable_count, evaluate=False) def doit(self, hints): expr = self.expr if hints.get('deep', True): expr = expr.doit(hints) hints['evaluate'] = True rv = self.func(expr, self.variable_count, hints) if rv!= self and rv.has(Derivative): rv = rv.doit(hints) return rv @_sympifyit('z0', NotImplementedError) def doit_numerically(self, z0): """ Evaluate the derivative at z numerically. When we can represent derivatives at a point, this should be folded into the normal evalf. For now, we need a special method. """ if len(self.free_symbols) != 1 or len(self.variables) != 1: raise NotImplementedError('partials and higher order derivatives') z = list(self.free_symbols)[0] def eval(x): f0 = self.expr.subs(z, Expr._from_mpmath(x, prec=mpmath.mp.prec)) f0 = f0.evalf(mlib.libmpf.prec_to_dps(mpmath.mp.prec)) return f0._to_mpmath(mpmath.mp.prec) return Expr._from_mpmath(mpmath.diff(eval, z0._to_mpmath(mpmath.mp.prec)), mpmath.mp.prec) @property def expr(self): return self._args[0] @property def _wrt_variables(self): # return the variables of differentiation without # respect to the type of count (int or symbolic) return [i[0] for i in self.variable_count] @property def variables(self): # TODO: deprecate? YES, make this 'enumerated_variables' and # name _wrt_variables as variables # TODO: support for `d^n`? rv = [] for v, count in self.variable_count: if not count.is_Integer: raise TypeError(filldedent(''' Cannot give expansion for symbolic count. If you just want a list of all variables of differentiation, use _wrt_variables.''')) rv.extend([v]count) return tuple(rv) @property def variable_count(self): return self._args[1:] @property def derivative_count(self): return sum([count for var, count in self.variable_count], 0) @property def free_symbols(self): return self.expr.free_symbols def _eval_subs(self, old, new): # The substitution (old, new) cannot be done inside # Derivative(expr, vars) for a variety of reasons # as handled below. if old in self._wrt_variables: # first handle the counts expr = self.func(self.expr, [(v, c.subs(old, new)) for v, c in self.variable_count]) if expr != self: return expr._eval_subs(old, new) # quick exit case if not getattr(new, '_diff_wrt', False): # case (0): new is not a valid variable of # differentiation if isinstance(old, Symbol): # don't introduce a new symbol if the old will do return Subs(self, old, new) else: xi = Dummy('xi') return Subs(self.xreplace({old: xi}), xi, new) # If both are Derivatives with the same expr, check if old is # equivalent to self or if old is a subderivative of self. if old.is_Derivative and old.expr == self.expr: if self.canonical == old.canonical: return new # collections.Counter doesn't have __le__ def _subset(a, b): return all((a[i] <= b[i]) == True for i in a) old_vars = Counter(dict(reversed(old.variable_count))) self_vars = Counter(dict(reversed(self.variable_count))) if _subset(old_vars, self_vars): return Derivative(new, (self_vars - old_vars).items()).canonical args = list(self.args) newargs = list(x._subs(old, new) for x in args) if args[0] == old: # complete replacement of self.expr # we already checked that the new is valid so we know # it won't be a problem should it appear in variables return Derivative(newargs) if newargs[0] != args[0]: # case (1) can't change expr by introducing something that is in # the _wrt_variables if it was already in the expr # e.g. # for Derivative(f(x, g(y)), y), x cannot be replaced with # anything that has y in it; for f(g(x), g(y)).diff(g(y)) # g(x) cannot be replaced with anything that has g(y) syms = {vi: Dummy() for vi in self._wrt_variables if not vi.is_Symbol} wrt = set(syms.get(vi, vi) for vi in self._wrt_variables) forbidden = args[0].xreplace(syms).free_symbols & wrt nfree = new.xreplace(syms).free_symbols ofree = old.xreplace(syms).free_symbols if (nfree - ofree) & forbidden: return Subs(self, old, new) viter = ((i, j) for ((i, _), (j, _)) in zip(newargs[1:], args[1:])) if any(i != j for i, j in viter): # a wrt-variable change # case (2) can't change vars by introducing a variable # that is contained in expr, e.g. # for Derivative(f(z, g(h(x), y)), y), y cannot be changed to # x, h(x), or g(h(x), y) for a in _atomic(self.expr, recursive=True): for i in range(1, len(newargs)): vi, _ = newargs[i] if a == vi and vi != args[i][0]: return Subs(self, old, new) # more arg-wise checks vc = newargs[1:] oldv = self._wrt_variables newe = self.expr subs = [] for i, (vi, ci) in enumerate(vc): if not vi._diff_wrt: # case (3) invalid differentiation expression so # create a replacement dummy xi = Dummy('xi_%i' % i) # replace the old valid variable with the dummy # in the expression newe = newe.xreplace({oldv[i]: xi}) # and replace the bad variable with the dummy vc[i] = (xi, ci) # and record the dummy with the new (invalid) # differentiation expression subs.append((xi, vi)) if subs: # handle any residual substitution in the expression newe = newe._subs(old, new) # return the Subs-wrapped derivative return Subs(Derivative(newe, vc), zip(subs)) # everything was ok return Derivative(newargs) def _eval_lseries(self, x, logx): dx = self.variables for term in self.expr.lseries(x, logx=logx): yield self.func(term, dx) def _eval_nseries(self, x, n, logx): arg = self.expr.nseries(x, n=n, logx=logx) o = arg.getO() dx = self.variables rv = [self.func(a, dx) for a in Add.make_args(arg.removeO())] if o: rv.append(o/x) return Add(rv) def _eval_as_leading_term(self, x): series_gen = self.expr.lseries(x) d = S.Zero for leading_term in series_gen: d = diff(leading_term, self.variables) if d != 0: break return d def _sage_(self): import sage.all as sage args = [arg._sage_() for arg in self.args] return sage.derivative(args) def as_finite_difference(self, points=1, x0=None, wrt=None): """ Expresses a Derivative instance as a finite difference. Parameters ========== points : sequence or coefficient, optional If sequence: discrete values (length >= order+1) of the independent variable used for generating the finite difference weights. If it is a coefficient, it will be used as the step-size for generating an equidistant sequence of length order+1 centered around ``x0``. Default: 1 (step-size 1) x0 : number or Symbol, optional the value of the independent variable (``wrt``) at which the derivative is to be approximated. Default: same as ``wrt``. wrt : Symbol, optional "with respect to" the variable for which the (partial) derivative is to be approximated for. If not provided it is required that the derivative is ordinary. Default: ``None``. Examples ======== >>> from sympy import symbols, Function, exp, sqrt, Symbol >>> x, h = symbols('x h') >>> f = Function('f') >>> f(x).diff(x).as_finite_difference() -f(x - 1/2) + f(x + 1/2) The default step size and number of points are 1 and ``order + 1`` respectively. We can change the step size by passing a symbol as a parameter: >>> f(x).diff(x).as_finite_difference(h) -f(-h/2 + x)/h + f(h/2 + x)/h We can also specify the discretized values to be used in a sequence: >>> f(x).diff(x).as_finite_difference([x, x+h, x+2h]) -3f(x)/(2h) + 2f(h + x)/h - f(2h + x)/(2h) The algorithm is not restricted to use equidistant spacing, nor do we need to make the approximation around ``x0``, but we can get an expression estimating the derivative at an offset: >>> e, sq2 = exp(1), sqrt(2) >>> xl = [x-h, x+h, x+eh] >>> f(x).diff(x, 1).as_finite_difference(xl, x+hsq2) # doctest: +ELLIPSIS 2h((h + sqrt(2)h)/(2h) - (-sqrt(2)h + h)/(2h))f(Eh + x)/... Partial derivatives are also supported: >>> y = Symbol('y') >>> d2fdxdy=f(x,y).diff(x,y) >>> d2fdxdy.as_finite_difference(wrt=x) -Derivative(f(x - 1/2, y), y) + Derivative(f(x + 1/2, y), y) We can apply ``as_finite_difference`` to ``Derivative`` instances in compound expressions using ``replace``: >>> (1 + 42f(x).diff(x)).replace(lambda arg: arg.is_Derivative, ... lambda arg: arg.as_finite_difference()) 42(-f(x - 1/2) + f(x + 1/2)) + 1 See also ======== sympy.calculus.finite_diff.apply_finite_diff sympy.calculus.finite_diff.differentiate_finite sympy.calculus.finite_diff.finite_diff_weights """ from ..calculus.finite_diff import _as_finite_diff return _as_finite_diff(self, points, x0, wrt) class Lambda(Expr): """ Lambda(x, expr) represents a lambda function similar to Python's 'lambda x: expr'. A function of several variables is written as Lambda((x, y, ...), expr). A simple example: >>> from sympy import Lambda >>> from sympy.abc import x >>> f = Lambda(x, x2) >>> f(4) 16 For multivariate functions, use: >>> from sympy.abc import y, z, t >>> f2 = Lambda((x, y, z, t), x + yz + t*z) >>> f2(1, 2, 3, 4) 73 A handy shortcut for lots of arguments: >>> p = x, y, z >>> f = Lambda(p, x + yz) >>> f(p) x + yz """ is_Function = True def __new__(cls, variables, expr): from sympy.sets.sets import FiniteSet v = list(variables) if iterable(variables) else [variables] for i in v: if not getattr(i, 'is_symbol', False): raise TypeError('variable is not a symbol: %s' % i) if len(v) == 1 and v[0] == expr: return S.IdentityFunction obj = Expr.__new__(cls, Tuple(v), sympify(expr)) obj.nargs = FiniteSet(len(v)) return obj @property def variables(self): """The variables used in the internal representation of the function""" return self._args[0] bound_symbols = variables @property def expr(self): """The return value of the function""" return self._args[1] @property def free_symbols(self): return self.expr.free_symbols - set(self.variables) def __call__(self, args): n = len(args) if n not in self.nargs: # Lambda only ever has 1 value in nargs # XXX: exception message must be in exactly this format to # make it work with NumPy's functions like vectorize(). See, # for example, https://github.com/numpy/numpy/issues/1697. # The ideal solution would be just to attach metadata to # the exception and change NumPy to take advantage of this. ## XXX does this apply to Lambda? If not, remove this comment. temp = ('%(name)s takes exactly %(args)s ' 'argument%(plural)s (%(given)s given)') raise TypeError(temp % { 'name': self, 'args': list(self.nargs)[0], 'plural': 's'(list(self.nargs)[0] != 1), 'given': n}) return self.expr.xreplace(dict(list(zip(self.variables, args)))) def __eq__(self, other): if not isinstance(other, Lambda): return False if self.nargs != other.nargs: return False selfexpr = self.args[1] otherexpr = other.args[1] otherexpr = otherexpr.xreplace(dict(list(zip(other.args[0], self.args[0])))) return selfexpr == otherexpr def __ne__(self, other): return not(self == other) def __hash__(self): return super(Lambda, self).__hash__() def _hashable_content(self): return (self.expr.xreplace(self.canonical_variables),) @property def is_identity(self): """Return ``True`` if this ``Lambda`` is an identity function. """ if len(self.args) == 2: return self.args[0] == self.args[1] else: return None class Subs(Expr): """ Represents unevaluated substitutions of an expression. ``Subs(expr, x, x0)`` receives 3 arguments: an expression, a variable or list of distinct variables and a point or list of evaluation points corresponding to those variables. ``Subs`` objects are generally useful to represent unevaluated derivatives calculated at a point. The variables may be expressions, but they are subjected to the limitations of subs(), so it is usually a good practice to use only symbols for variables, since in that case there can be no ambiguity. There's no automatic expansion - use the method .doit() to effect all possible substitutions of the object and also of objects inside the expression. When evaluating derivatives at a point that is not a symbol, a Subs object is returned. One is also able to calculate derivatives of Subs objects - in this case the expression is always expanded (for the unevaluated form, use Derivative()). Examples ======== >>> from sympy import Subs, Function, sin, cos >>> from sympy.abc import x, y, z >>> f = Function('f') Subs are created when a particular substitution cannot be made. The x in the derivative cannot be replaced with 0 because 0 is not a valid variables of differentiation: >>> f(x).diff(x).subs(x, 0) Subs(Derivative(f(x), x), x, 0) Once f is known, the derivative and evaluation at 0 can be done: >>> _.subs(f, sin).doit() == sin(x).diff(x).subs(x, 0) == cos(0) True Subs can also be created directly with one or more variables: >>> Subs(f(x)sin(y) + z, (x, y), (0, 1)) Subs(z + f(x)sin(y), (x, y), (0, 1)) >>> _.doit() z + f(0)sin(1) Notes ===== In order to allow expressions to combine before doit is done, a representation of the Subs expression is used internally to make expressions that are superficially different compare the same: >>> a, b = Subs(x, x, 0), Subs(y, y, 0) >>> a + b 2Subs(x, x, 0) This can lead to unexpected consequences when using methods like `has` that are cached: >>> s = Subs(x, x, 0) >>> s.has(x), s.has(y) (True, False) >>> ss = s.subs(x, y) >>> ss.has(x), ss.has(y) (True, False) >>> s, ss (Subs(x, x, 0), Subs(y, y, 0)) """ def __new__(cls, expr, variables, point, assumptions): from sympy import Symbol if not is_sequence(variables, Tuple): variables = [variables] variables = Tuple(variables) if has_dups(variables): repeated = [str(v) for v, i in Counter(variables).items() if i > 1] __ = ', '.join(repeated) raise ValueError(filldedent(''' The following expressions appear more than once: %s ''' % __)) point = Tuple((point if is_sequence(point, Tuple) else [point])) if len(point) != len(variables): raise ValueError('Number of point values must be the same as ' 'the number of variables.') if not point: return sympify(expr) # denest if isinstance(expr, Subs): variables = expr.variables + variables point = expr.point + point expr = expr.expr else: expr = sympify(expr) # use symbols with names equal to the point value (with preppended _) # to give a variable-independent expression pre = "_" pts = sorted(set(point), key=default_sort_key) from sympy.printing import StrPrinter class CustomStrPrinter(StrPrinter): def _print_Dummy(self, expr): return str(expr) + str(expr.dummy_index) def mystr(expr, settings): p = CustomStrPrinter(settings) return p.doprint(expr) while 1: s_pts = {p: Symbol(pre + mystr(p)) for p in pts} reps = [(v, s_pts[p]) for v, p in zip(variables, point)] # if any underscore-preppended symbol is already a free symbol # and is a variable with a different point value, then there # is a clash, e.g. _0 clashes in Subs(_0 + _1, (_0, _1), (1, 0)) # because the new symbol that would be created is _1 but _1 # is already mapped to 0 so __0 and __1 are used for the new # symbols if any(r in expr.free_symbols and r in variables and Symbol(pre + mystr(point[variables.index(r)])) != r for _, r in reps): pre += "_" continue break obj = Expr.__new__(cls, expr, Tuple(variables), point) obj._expr = expr.xreplace(dict(reps)) return obj def _eval_is_commutative(self): return self.expr.is_commutative def doit(self, *hints): e, v, p = self.args # remove self mappings for i, (vi, pi) in enumerate(zip(v, p)): if vi == pi: v = v[:i] + v[i + 1:] p = p[:i] + p[i + 1:] if not v: return self.expr if isinstance(e, Derivative): # apply functions first, e.g. f -> cos undone = [] for i, vi in enumerate(v): if isinstance(vi, FunctionClass): e = e.subs(vi, p[i]) else: undone.append((vi, p[i])) if not isinstance(e, Derivative): e = e.doit() if isinstance(e, Derivative): # do Subs that aren't related to differentiation undone2 = [] D = Dummy() for vi, pi in undone: if D not in e.xreplace({vi: D}).free_symbols: e = e.subs(vi, pi) else: undone2.append((vi, pi)) undone = undone2 # differentiate wrt variables that are present wrt = [] D = Dummy() expr = e.expr free = expr.free_symbols for vi, ci in e.variable_count: if isinstance(vi, Symbol) and vi in free: expr = expr.diff((vi, ci)) elif D in expr.subs(vi, D).free_symbols: expr = expr.diff((vi, ci)) else: wrt.append((vi, ci)) # inject remaining subs rv = expr.subs(undone) # do remaining differentiation in order given* for vc in wrt: rv = rv.diff(vc) else: # inject remaining subs rv = e.subs(undone) else: rv = e.doit(hints).subs(list(zip(v, p))) if hints.get('deep', True) and rv != self: rv = rv.doit(hints) return rv def evalf(self, prec=None, options): return self.doit().evalf(prec, options) n = evalf @property def variables(self): """The variables to be evaluated""" return self._args[1] bound_symbols = variables @property def expr(self): """The expression on which the substitution operates""" return self._args[0] @property def point(self): """The values for which the variables are to be substituted""" return self._args[2] @property def free_symbols(self): return (self.expr.free_symbols - set(self.variables) \| set(self.point.free_symbols)) @property def expr_free_symbols(self): return (self.expr.expr_free_symbols - set(self.variables) \| set(self.point.expr_free_symbols)) def __eq__(self, other): if not isinstance(other, Subs): return False return self._hashable_content() == other._hashable_content() def __ne__(self, other): return not(self == other) def __hash__(self): return super(Subs, self).__hash__() def _hashable_content(self): return (self._expr.xreplace(self.canonical_variables), ) + tuple(ordered([(v, p) for v, p in zip(self.variables, self.point) if not self.expr.has(v)])) def _eval_subs(self, old, new): # Subs doit will do the variables in order; the semantics # of subs for Subs is have the following invariant for # Subs object foo: # foo.doit().subs(reps) == foo.subs(reps).doit() pt = list(self.point) if old in self.variables: if _atomic(new) == set([new]) and not any( i.has(new) for i in self.args): # the substitution is neutral return self.xreplace({old: new}) # any occurance of old before this point will get # handled by replacements from here on i = self.variables.index(old) for j in range(i, len(self.variables)): pt[j] = pt[j]._subs(old, new) return self.func(self.expr, self.variables, pt) v = [i._subs(old, new) for i in self.variables] if v != list(self.variables): return self.func(self.expr, self.variables + (old,), pt + [new]) expr = self.expr._subs(old, new) pt = [i._subs(old, new) for i in self.point] return self.func(expr, v, pt) def _eval_derivative(self, s): # Apply the chain rule of the derivative on the substitution variables: val = Add.fromiter(p.diff(s) * Subs(self.expr.diff(v), self.variables, self.point).doit() for v, p in zip(self.variables, self.point)) # Check if there are free symbols in `self.expr`: # First get the `expr_free_symbols`, which returns the free symbols # that are directly contained in an expression node (i.e. stop # searching if the node isn't an expression). At this point turn the # expressions into `free_symbols` and check if there are common free # symbols in `self.expr` and the deriving factor. fs1 = {j for i in self.expr_free_symbols for j in i.free_symbols} if len(fs1 & s.free_symbols) > 0: val += Subs(self.expr.diff(s), self.variables, self.point).doit() return val def _eval_nseries(self, x, n, logx): if x in self.point: # x is the variable being substituted into apos = self.point.index(x) other = self.variables[apos] else: other = x arg = self.expr.nseries(other, n=n, logx=logx) o = arg.getO() terms = Add.make_args(arg.removeO()) rv = Add([self.func(a, self.args[1:]) for a in terms]) if o: rv += o.subs(other, x) return rv def _eval_as_leading_term(self, x): if x in self.point: ipos = self.point.index(x) xvar = self.variables[ipos] return self.expr.as_leading_term(xvar) if x in self.variables: # if `x` is a dummy variable, it means it won't exist after the # substitution has been performed: return self # The variable is independent of the substitution: return self.expr.as_leading_term(x) def diff(f, symbols, kwargs): """ Differentiate f with respect to symbols. This is just a wrapper to unify .diff() and the Derivative class; its interface is similar to that of integrate(). You can use the same shortcuts for multiple variables as with Derivative. For example, diff(f(x), x, x, x) and diff(f(x), x, 3) both return the third derivative of f(x). You can pass evaluate=False to get an unevaluated Derivative class. Note that if there are 0 symbols (such as diff(f(x), x, 0), then the result will be the function (the zeroth derivative), even if evaluate=False. Examples ======== >>> from sympy import sin, cos, Function, diff >>> from sympy.abc import x, y >>> f = Function('f') >>> diff(sin(x), x) cos(x) >>> diff(f(x), x, x, x) Derivative(f(x), (x, 3)) >>> diff(f(x), x, 3) Derivative(f(x), (x, 3)) >>> diff(sin(x)cos(y), x, 2, y, 2) sin(x)cos(y) >>> type(diff(sin(x), x)) cos >>> type(diff(sin(x), x, evaluate=False)) <class 'sympy.core.function.Derivative'> >>> type(diff(sin(x), x, 0)) sin >>> type(diff(sin(x), x, 0, evaluate=False)) sin >>> diff(sin(x)) cos(x) >>> diff(sin(xy)) Traceback (most recent call last): ... ValueError: specify differentiation variables to differentiate sin(xy) Note that ``diff(sin(x))`` syntax is meant only for convenience in interactive sessions and should be avoided in library code. References ========== http://reference.wolfram.com/legacy/v5_2/Built-inFunctions/AlgebraicComputation/Calculus/D.html See Also ======== Derivative sympy.geometry.util.idiff: computes the derivative implicitly """ if hasattr(f, 'diff'): return f.diff(symbols, *kwargs) kwargs.setdefault('evaluate', True) return Derivative(f, symbols, kwargs) def expand(e, deep=True, modulus=None, power_base=True, power_exp=True, mul=True, log=True, multinomial=True, basic=True, hints): r""" Expand an expression using methods given as hints. Hints evaluated unless explicitly set to False are: ``basic``, ``log``, ``multinomial``, ``mul``, ``power_base``, and ``power_exp`` The following hints are supported but not applied unless set to True: ``complex``, ``func``, and ``trig``. In addition, the following meta-hints are supported by some or all of the other hints: ``frac``, ``numer``, ``denom``, ``modulus``, and ``force``. ``deep`` is supported by all hints. Additionally, subclasses of Expr may define their own hints or meta-hints. The ``basic`` hint is used for any special rewriting of an object that should be done automatically (along with the other hints like ``mul``) when expand is called. This is a catch-all hint to handle any sort of expansion that may not be described by the existing hint names. To use this hint an object should override the ``_eval_expand_basic`` method. Objects may also define their own expand methods, which are not run by default. See the API section below. If ``deep`` is set to ``True`` (the default), things like arguments of functions are recursively expanded. Use ``deep=False`` to only expand on the top level. If the ``force`` hint is used, assumptions about variables will be ignored in making the expansion. Hints ===== These hints are run by default mul --- Distributes multiplication over addition: >>> from sympy import cos, exp, sin >>> from sympy.abc import x, y, z >>> (y(x + z)).expand(mul=True) xy + yz multinomial ----------- Expand (x + y + ...)n where n is a positive integer. >>> ((x + y + z)2).expand(multinomial=True) x2 + 2xy + 2xz + y2 + 2yz + z2 power_exp --------- Expand addition in exponents into multiplied bases. >>> exp(x + y).expand(power_exp=True) exp(x)exp(y) >>> (2(x + y)).expand(power_exp=True) 2x2y power_base ---------- Split powers of multiplied bases. This only happens by default if assumptions allow, or if the ``force`` meta-hint is used: >>> ((xy)*z).expand(power_base=True) (xy)*z >>> ((xy)z).expand(power_base=True, force=True) xzyz >>> ((2y)z).expand(power_base=True) 2zyz Note that in some cases where this expansion always holds, SymPy performs it automatically: >>> (xy)2 x2y2 log --- Pull out power of an argument as a coefficient and split logs products into sums of logs. Note that these only work if the arguments of the log function have the proper assumptions--the arguments must be positive and the exponents must be real--or else the ``force`` hint must be True: >>> from sympy import log, symbols >>> log(x2y).expand(log=True) log(x*2y) >>> log(x*2y).expand(log=True, force=True) 2log(x) + log(y) >>> x, y = symbols('x,y', positive=True) >>> log(x2y).expand(log=True) 2log(x) + log(y) basic ----- This hint is intended primarily as a way for custom subclasses to enable expansion by default. These hints are not run by default: complex ------- Split an expression into real and imaginary parts. >>> x, y = symbols('x,y') >>> (x + y).expand(complex=True) re(x) + re(y) + Iim(x) + Iim(y) >>> cos(x).expand(complex=True) -Isin(re(x))sinh(im(x)) + cos(re(x))cosh(im(x)) Note that this is just a wrapper around ``as_real_imag()``. Most objects that wish to redefine ``_eval_expand_complex()`` should consider redefining ``as_real_imag()`` instead. func ---- Expand other functions. >>> from sympy import gamma >>> gamma(x + 1).expand(func=True) xgamma(x) trig ---- Do trigonometric expansions. >>> cos(x + y).expand(trig=True) -sin(x)sin(y) + cos(x)cos(y) >>> sin(2x).expand(trig=True) 2sin(x)cos(x) Note that the forms of ``sin(nx)`` and ``cos(nx)`` in terms of ``sin(x)`` and ``cos(x)`` are not unique, due to the identity `\sin^2(x) + \cos^2(x) = 1`. The current implementation uses the form obtained from Chebyshev polynomials, but this may change. See `this MathWorld article <http://mathworld.wolfram.com/Multiple-AngleFormulas.html>`_ for more information. Notes ===== - You can shut off unwanted methods:: >>> (exp(x + y)(x + y)).expand() xexp(x)exp(y) + yexp(x)exp(y) >>> (exp(x + y)(x + y)).expand(power_exp=False) xexp(x + y) + yexp(x + y) >>> (exp(x + y)(x + y)).expand(mul=False) (x + y)exp(x)exp(y) - Use deep=False to only expand on the top level:: >>> exp(x + exp(x + y)).expand() exp(x)exp(exp(x)exp(y)) >>> exp(x + exp(x + y)).expand(deep=False) exp(x)exp(exp(x + y)) - Hints are applied in an arbitrary, but consistent order (in the current implementation, they are applied in alphabetical order, except multinomial comes before mul, but this may change). Because of this, some hints may prevent expansion by other hints if they are applied first. For example, ``mul`` may distribute multiplications and prevent ``log`` and ``power_base`` from expanding them. Also, if ``mul`` is applied before ``multinomial`, the expression might not be fully distributed. The solution is to use the various ``expand_hint`` helper functions or to use ``hint=False`` to this function to finely control which hints are applied. Here are some examples:: >>> from sympy import expand, expand_mul, expand_power_base >>> x, y, z = symbols('x,y,z', positive=True) >>> expand(log(x(y + z))) log(x) + log(y + z) Here, we see that ``log`` was applied before ``mul``. To get the mul expanded form, either of the following will work:: >>> expand_mul(log(x(y + z))) log(xy + xz) >>> expand(log(x(y + z)), log=False) log(xy + xz) A similar thing can happen with the ``power_base`` hint:: >>> expand((x(y + z))*x) (xy + xz)x To get the ``power_base`` expanded form, either of the following will work:: >>> expand((x(y + z))x, mul=False) xx(y + z)x >>> expand_power_base((x(y + z))x) xx(y + z)x >>> expand((x + y)y/x) y + y*2/x The parts of a rational expression can be targeted:: >>> expand((x + y)y/x/(x + 1), frac=True) (xy + y2)/(x2 + x) >>> expand((x + y)y/x/(x + 1), numer=True) (xy + y2)/(x(x + 1)) >>> expand((x + y)y/x/(x + 1), denom=True) y(x + y)/(x*2 + x) - The ``modulus`` meta-hint can be used to reduce the coefficients of an expression post-expansion:: >>> expand((3x + 1)*2) 9x*2 + 6x + 1 >>> expand((3x + 1)2, modulus=5) 4x2 + x + 1 - Either ``expand()`` the function or ``.expand()`` the method can be used. Both are equivalent:: >>> expand((x + 1)2) x*2 + 2x + 1 >>> ((x + 1)2).expand() x2 + 2x + 1 API === Objects can define their own expand hints by defining ``_eval_expand_hint()``. The function should take the form:: def _eval_expand_hint(self, hints): # Only apply the method to the top-level expression ... See also the example below. Objects should define ``_eval_expand_hint()`` methods only if ``hint`` applies to that specific object. The generic ``_eval_expand_hint()`` method defined in Expr will handle the no-op case. Each hint should be responsible for expanding that hint only. Furthermore, the expansion should be applied to the top-level expression only. ``expand()`` takes care of the recursion that happens when ``deep=True``. You should only call ``_eval_expand_hint()`` methods directly if you are 100% sure that the object has the method, as otherwise you are liable to get unexpected ``AttributeError``s. Note, again, that you do not need to recursively apply the hint to args of your object: this is handled automatically by ``expand()``. ``_eval_expand_hint()`` should generally not be used at all outside of an ``_eval_expand_hint()`` method. If you want to apply a specific expansion from within another method, use the public ``expand()`` function, method, or ``expand_hint()`` functions. In order for expand to work, objects must be rebuildable by their args, i.e., ``obj.func(obj.args) == obj`` must hold. Expand methods are passed ``*hints`` so that expand hints may use 'metahints'--hints that control how different expand methods are applied. For example, the ``force=True`` hint described above that causes ``expand(log=True)`` to ignore assumptions is such a metahint. The ``deep`` meta-hint is handled exclusively by ``expand()`` and is not passed to ``_eval_expand_hint()`` methods. Note that expansion hints should generally be methods that perform some kind of 'expansion'. For hints that simply rewrite an expression, use the .rewrite() API. Examples ======== >>> from sympy import Expr, sympify >>> class MyClass(Expr): ... def __new__(cls, args): ... args = sympify(args) ... return Expr.__new__(cls, args) ... ... def _eval_expand_double(self, hints): ... ''' ... Doubles the args of MyClass. ... ... If there more than four args, doubling is not performed, ... unless force=True is also used (False by default). ... ''' ... force = hints.pop('force', False) ... if not force and len(self.args) > 4: ... return self ... return self.func((self.args + self.args)) ... >>> a = MyClass(1, 2, MyClass(3, 4)) >>> a MyClass(1, 2, MyClass(3, 4)) >>> a.expand(double=True) MyClass(1, 2, MyClass(3, 4, 3, 4), 1, 2, MyClass(3, 4, 3, 4)) >>> a.expand(double=True, deep=False) MyClass(1, 2, MyClass(3, 4), 1, 2, MyClass(3, 4)) >>> b = MyClass(1, 2, 3, 4, 5) >>> b.expand(double=True) MyClass(1, 2, 3, 4, 5) >>> b.expand(double=True, force=True) MyClass(1, 2, 3, 4, 5, 1, 2, 3, 4, 5) See Also ======== expand_log, expand_mul, expand_multinomial, expand_complex, expand_trig, expand_power_base, expand_power_exp, expand_func, hyperexpand """ # don't modify this; modify the Expr.expand method hints['power_base'] = power_base hints['power_exp'] = power_exp hints['mul'] = mul hints['log'] = log hints['multinomial'] = multinomial hints['basic'] = basic return sympify(e).expand(deep=deep, modulus=modulus, *hints) # This is a special application of two hints def _mexpand(expr, recursive=False): # expand multinomials and then expand products; this may not always # be sufficient to give a fully expanded expression (see # test_issue_8247_8354 in test_arit) if expr is None: return was = None while was != expr: was, expr = expr, expand_mul(expand_multinomial(expr)) if not recursive: break return expr # These are simple wrappers around single hints. def expand_mul(expr, deep=True): """ Wrapper around expand that only uses the mul hint. See the expand docstring for more information. Examples ======== >>> from sympy import symbols, expand_mul, exp, log >>> x, y = symbols('x,y', positive=True) >>> expand_mul(exp(x+y)(x+y)log(xy*2)) xexp(x + y)log(xy*2) + yexp(x + y)log(xy2) """ return sympify(expr).expand(deep=deep, mul=True, power_exp=False, power_base=False, basic=False, multinomial=False, log=False) def expand_multinomial(expr, deep=True): """ Wrapper around expand that only uses the multinomial hint. See the expand docstring for more information. Examples ======== >>> from sympy import symbols, expand_multinomial, exp >>> x, y = symbols('x y', positive=True) >>> expand_multinomial((x + exp(x + 1))2) x*2 + 2xexp(x + 1) + exp(2x + 2) """ return sympify(expr).expand(deep=deep, mul=False, power_exp=False, power_base=False, basic=False, multinomial=True, log=False) def expand_log(expr, deep=True, force=False): """ Wrapper around expand that only uses the log hint. See the expand docstring for more information. Examples ======== >>> from sympy import symbols, expand_log, exp, log >>> x, y = symbols('x,y', positive=True) >>> expand_log(exp(x+y)(x+y)log(xy2)) (x + y)(log(x) + 2log(y))exp(x + y) """ return sympify(expr).expand(deep=deep, log=True, mul=False, power_exp=False, power_base=False, multinomial=False, basic=False, force=force) def expand_func(expr, deep=True): """ Wrapper around expand that only uses the func hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_func, gamma >>> from sympy.abc import x >>> expand_func(gamma(x + 2)) x(x + 1)gamma(x) """ return sympify(expr).expand(deep=deep, func=True, basic=False, log=False, mul=False, power_exp=False, power_base=False, multinomial=False) def expand_trig(expr, deep=True): """ Wrapper around expand that only uses the trig hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_trig, sin >>> from sympy.abc import x, y >>> expand_trig(sin(x+y)(x+y)) (x + y)(sin(x)cos(y) + sin(y)cos(x)) """ return sympify(expr).expand(deep=deep, trig=True, basic=False, log=False, mul=False, power_exp=False, power_base=False, multinomial=False) def expand_complex(expr, deep=True): """ Wrapper around expand that only uses the complex hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_complex, exp, sqrt, I >>> from sympy.abc import z >>> expand_complex(exp(z)) Iexp(re(z))sin(im(z)) + exp(re(z))cos(im(z)) >>> expand_complex(sqrt(I)) sqrt(2)/2 + sqrt(2)I/2 See Also ======== Expr.as_real_imag """ return sympify(expr).expand(deep=deep, complex=True, basic=False, log=False, mul=False, power_exp=False, power_base=False, multinomial=False) def expand_power_base(expr, deep=True, force=False): """ Wrapper around expand that only uses the power_base hint. See the expand docstring for more information. A wrapper to expand(power_base=True) which separates a power with a base that is a Mul into a product of powers, without performing any other expansions, provided that assumptions about the power's base and exponent allow. deep=False (default is True) will only apply to the top-level expression. force=True (default is False) will cause the expansion to ignore assumptions about the base and exponent. When False, the expansion will only happen if the base is non-negative or the exponent is an integer. >>> from sympy.abc import x, y, z >>> from sympy import expand_power_base, sin, cos, exp >>> (xy)2 x2y*2 >>> (2x)*y (2x)y >>> expand_power_base(_) 2yxy >>> expand_power_base((xy)*z) (xy)*z >>> expand_power_base((xy)z, force=True) xzyz >>> expand_power_base(sin((xy)*z), deep=False) sin((xy)*z) >>> expand_power_base(sin((xy)z), force=True) sin(xzyz) >>> expand_power_base((2sin(x))*y + (2cos(x))y) 2ysin(x)y + 2ycos(x)*y >>> expand_power_base((2exp(y))x) 2xexp(y)x >>> expand_power_base((2cos(x))y) 2ycos(x)y Notice that sums are left untouched. If this is not the desired behavior, apply full ``expand()`` to the expression: >>> expand_power_base(((x+y)z)2) z2(x + y)2 >>> (((x+y)z)2).expand() x2z2 + 2xyz2 + y2z2 >>> expand_power_base((2y)(1+z)) 2(z + 1)y(z + 1) >>> ((2y)*(1+z)).expand() 22*zyyz """ return sympify(expr).expand(deep=deep, log=False, mul=False, power_exp=False, power_base=True, multinomial=False, basic=False, force=force) def expand_power_exp(expr, deep=True): """ Wrapper around expand that only uses the power_exp hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_power_exp >>> from sympy.abc import x, y >>> expand_power_exp(x(y + 2)) x2xy """ return sympify(expr).expand(deep=deep, complex=False, basic=False, log=False, mul=False, power_exp=True, power_base=False, multinomial=False) def count_ops(expr, visual=False): """ Return a representation (integer or expression) of the operations in expr. If ``visual`` is ``False`` (default) then the sum of the coefficients of the visual expression will be returned. If ``visual`` is ``True`` then the number of each type of operation is shown with the core class types (or their virtual equivalent) multiplied by the number of times they occur. If expr is an iterable, the sum of the op counts of the items will be returned. Examples ======== >>> from sympy.abc import a, b, x, y >>> from sympy import sin, count_ops Although there isn't a SUB object, minus signs are interpreted as either negations or subtractions: >>> (x - y).count_ops(visual=True) SUB >>> (-x).count_ops(visual=True) NEG Here, there are two Adds and a Pow: >>> (1 + a + b2).count_ops(visual=True) 2ADD + POW In the following, an Add, Mul, Pow and two functions: >>> (sin(x)x + sin(x)*2).count_ops(visual=True) ADD + MUL + POW + 2SIN for a total of 5: >>> (sin(x)x + sin(x)2).count_ops(visual=False) 5 Note that "what you type" is not always what you get. The expression 1/x/y is translated by sympy into 1/(xy) so it gives a DIV and MUL rather than two DIVs: >>> (1/x/y).count_ops(visual=True) DIV + MUL The visual option can be used to demonstrate the difference in operations for expressions in different forms. Here, the Horner representation is compared with the expanded form of a polynomial: >>> eq=x(1 + x(2 + x(3 + x))) >>> count_ops(eq.expand(), visual=True) - count_ops(eq, visual=True) -MUL + 3POW The count_ops function also handles iterables: >>> count_ops([x, sin(x), None, True, x + 2], visual=False) 2 >>> count_ops([x, sin(x), None, True, x + 2], visual=True) ADD + SIN >>> count_ops({x: sin(x), x + 2: y + 1}, visual=True) 2ADD + SIN """ from sympy import Integral, Symbol from sympy.core.relational import Relational from sympy.simplify.radsimp import fraction from sympy.logic.boolalg import BooleanFunction from sympy.utilities.misc import func_name expr = sympify(expr) if isinstance(expr, Expr) and not expr.is_Relational: ops = [] args = [expr] NEG = Symbol('NEG') DIV = Symbol('DIV') SUB = Symbol('SUB') ADD = Symbol('ADD') while args: a = args.pop() if a.is_Rational: #-1/3 = NEG + DIV if a is not S.One: if a.p < 0: ops.append(NEG) if a.q != 1: ops.append(DIV) continue elif a.is_Mul or a.is_MatMul: if _coeff_isneg(a): ops.append(NEG) if a.args[0] is S.NegativeOne: a = a.as_two_terms()[1] else: a = -a n, d = fraction(a) if n.is_Integer: ops.append(DIV) if n < 0: ops.append(NEG) args.append(d) continue # won't be -Mul but could be Add elif d is not S.One: if not d.is_Integer: args.append(d) ops.append(DIV) args.append(n) continue # could be -Mul elif a.is_Add or a.is_MatAdd: aargs = list(a.args) negs = 0 for i, ai in enumerate(aargs): if _coeff_isneg(ai): negs += 1 args.append(-ai) if i > 0: ops.append(SUB) else: args.append(ai) if i > 0: ops.append(ADD) if negs == len(aargs): # -x - y = NEG + SUB ops.append(NEG) elif _coeff_isneg(aargs[0]): # -x + y = SUB, but already recorded ADD ops.append(SUB - ADD) continue if a.is_Pow and a.exp is S.NegativeOne: ops.append(DIV) args.append(a.base) # won't be -Mul but could be Add continue if (a.is_Mul or a.is_Pow or a.is_Function or isinstance(a, Derivative) or isinstance(a, Integral)): o = Symbol(a.func.__name__.upper()) # count the args if (a.is_Mul or isinstance(a, LatticeOp)): ops.append(o(len(a.args) - 1)) else: ops.append(o) if not a.is_Symbol: args.extend(a.args) elif type(expr) is dict: ops = [count_ops(k, visual=visual) + count_ops(v, visual=visual) for k, v in expr.items()] elif iterable(expr): ops = [count_ops(i, visual=visual) for i in expr] elif isinstance(expr, (Relational, BooleanFunction)): ops = [] for arg in expr.args: ops.append(count_ops(arg, visual=True)) o = Symbol(func_name(expr, short=True).upper()) ops.append(o) elif not isinstance(expr, Basic): ops = [] else: # it's Basic not isinstance(expr, Expr): if not isinstance(expr, Basic): raise TypeError("Invalid type of expr") else: ops = [] args = [expr] while args: a = args.pop() if a.args: o = Symbol(a.func.__name__.upper()) if a.is_Boolean: ops.append(o(len(a.args)-1)) else: ops.append(o) args.extend(a.args) if not ops: if visual: return S.Zero return 0 ops = Add(ops) if visual: return ops if ops.is_Number: return int(ops) return sum(int((a.args or [1])[0]) for a in Add.make_args(ops)) def nfloat(expr, n=15, exponent=False): """Make all Rationals in expr Floats except those in exponents (unless the exponents flag is set to True). Examples ======== >>> from sympy.core.function import nfloat >>> from sympy.abc import x, y >>> from sympy import cos, pi, sqrt >>> nfloat(x4 + x/2 + cos(pi/3) + 1 + sqrt(y)) x4 + 0.5x + sqrt(y) + 1.5 >>> nfloat(x4 + sqrt(y), exponent=True) x4.0 + y0.5 """ from sympy.core.power import Pow from sympy.polys.rootoftools import RootOf if iterable(expr, exclude=string_types): if isinstance(expr, (dict, Dict)): return type(expr)([(k, nfloat(v, n, exponent)) for k, v in list(expr.items())]) return type(expr)([nfloat(a, n, exponent) for a in expr]) rv = sympify(expr) if rv.is_Number: return Float(rv, n) elif rv.is_number: # evalf doesn't always set the precision rv = rv.n(n) if rv.is_Number: rv = Float(rv.n(n), n) else: pass # pure_complex(rv) is likely True return rv # watch out for RootOf instances that don't like to have # their exponents replaced with Dummies and also sometimes have # problems with evaluating at low precision (issue 6393) rv = rv.xreplace({ro: ro.n(n) for ro in rv.atoms(RootOf)}) if not exponent: reps = [(p, Pow(p.base, Dummy())) for p in rv.atoms(Pow)] rv = rv.xreplace(dict(reps)) rv = rv.n(n) if not exponent: rv = rv.xreplace({d.exp: p.exp for p, d in reps}) else: # Pow._eval_evalf special cases Integer exponents so if # exponent is suppose to be handled we have to do so here rv = rv.xreplace(Transform( lambda x: Pow(x.base, Float(x.exp, n)), lambda x: x.is_Pow and x.exp.is_Integer)) return rv.xreplace(Transform( lambda x: x.func(nfloat(x.args, n, exponent)), lambda x: isinstance(x, Function))) from sympy.core.symbol import Dummy, Symbol
759834573c11db3c55ec09e2d908ad08e484b9aec3605ce3696e13b1b1f46231	from __future__ import print_function, division from .sympify import sympify, _sympify, SympifyError from .basic import Basic, Atom from .singleton import S from .evalf import EvalfMixin, pure_complex from .decorators import _sympifyit, call_highest_priority from .cache import cacheit from .compatibility import reduce, as_int, default_sort_key, range, Iterable from sympy.utilities.misc import func_name from mpmath.libmp import mpf_log, prec_to_dps from collections import defaultdict class Expr(Basic, EvalfMixin): """ Base class for algebraic expressions. Everything that requires arithmetic operations to be defined should subclass this class, instead of Basic (which should be used only for argument storage and expression manipulation, i.e. pattern matching, substitutions, etc). See Also ======== sympy.core.basic.Basic """ __slots__ = [] is_scalar = True # self derivative is 1 @property def _diff_wrt(self): """Return True if one can differentiate with respect to this object, else False. Subclasses such as Symbol, Function and Derivative return True to enable derivatives wrt them. The implementation in Derivative separates the Symbol and non-Symbol (_diff_wrt=True) variables and temporarily converts the non-Symbols into Symbols when performing the differentiation. By default, any object deriving from Expr will behave like a scalar with self.diff(self) == 1. If this is not desired then the object must also set `is_scalar = False` or else define an _eval_derivative routine. Note, see the docstring of Derivative for how this should work mathematically. In particular, note that expr.subs(yourclass, Symbol) should be well-defined on a structural level, or this will lead to inconsistent results. Examples ======== >>> from sympy import Expr >>> e = Expr() >>> e._diff_wrt False >>> class MyScalar(Expr): ... _diff_wrt = True ... >>> MyScalar().diff(MyScalar()) 1 >>> class MySymbol(Expr): ... _diff_wrt = True ... is_scalar = False ... >>> MySymbol().diff(MySymbol()) Derivative(MySymbol(), MySymbol()) """ return False @cacheit def sort_key(self, order=None): coeff, expr = self.as_coeff_Mul() if expr.is_Pow: expr, exp = expr.args else: expr, exp = expr, S.One if expr.is_Dummy: args = (expr.sort_key(),) elif expr.is_Atom: args = (str(expr),) else: if expr.is_Add: args = expr.as_ordered_terms(order=order) elif expr.is_Mul: args = expr.as_ordered_factors(order=order) else: args = expr.args args = tuple( [ default_sort_key(arg, order=order) for arg in args ]) args = (len(args), tuple(args)) exp = exp.sort_key(order=order) return expr.class_key(), args, exp, coeff # *************** # * Arithmetics * # ************* # Expr and its sublcasses use _op_priority to determine which object # passed to a binary special method (__mul__, etc.) will handle the # operation. In general, the 'call_highest_priority' decorator will choose # the object with the highest _op_priority to handle the call. # Custom subclasses that want to define their own binary special methods # should set an _op_priority value that is higher than the default. # # NOTE*: # This is a temporary fix, and will eventually be replaced with # something better and more powerful. See issue 5510. _op_priority = 10.0 def __pos__(self): return self def __neg__(self): return Mul(S.NegativeOne, self) def __abs__(self): from sympy import Abs return Abs(self) @_sympifyit('other', NotImplemented) @call_highest_priority('__radd__') def __add__(self, other): return Add(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__add__') def __radd__(self, other): return Add(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rsub__') def __sub__(self, other): return Add(self, -other) @_sympifyit('other', NotImplemented) @call_highest_priority('__sub__') def __rsub__(self, other): return Add(other, -self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rmul__') def __mul__(self, other): return Mul(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__mul__') def __rmul__(self, other): return Mul(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rpow__') def _pow(self, other): return Pow(self, other) def __pow__(self, other, mod=None): if mod is None: return self._pow(other) try: _self, other, mod = as_int(self), as_int(other), as_int(mod) if other >= 0: return pow(_self, other, mod) else: from sympy.core.numbers import mod_inverse return mod_inverse(pow(_self, -other, mod), mod) except ValueError: power = self._pow(other) try: return power%mod except TypeError: return NotImplemented @_sympifyit('other', NotImplemented) @call_highest_priority('__pow__') def __rpow__(self, other): return Pow(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rdiv__') def __div__(self, other): return Mul(self, Pow(other, S.NegativeOne)) @_sympifyit('other', NotImplemented) @call_highest_priority('__div__') def __rdiv__(self, other): return Mul(other, Pow(self, S.NegativeOne)) __truediv__ = __div__ __rtruediv__ = __rdiv__ @_sympifyit('other', NotImplemented) @call_highest_priority('__rmod__') def __mod__(self, other): return Mod(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__mod__') def __rmod__(self, other): return Mod(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rfloordiv__') def __floordiv__(self, other): from sympy.functions.elementary.integers import floor return floor(self / other) @_sympifyit('other', NotImplemented) @call_highest_priority('__floordiv__') def __rfloordiv__(self, other): from sympy.functions.elementary.integers import floor return floor(other / self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rdivmod__') def __divmod__(self, other): from sympy.functions.elementary.integers import floor return floor(self / other), Mod(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__divmod__') def __rdivmod__(self, other): from sympy.functions.elementary.integers import floor return floor(other / self), Mod(other, self) def __int__(self): # Although we only need to round to the units position, we'll # get one more digit so the extra testing below can be avoided # unless the rounded value rounded to an integer, e.g. if an # expression were equal to 1.9 and we rounded to the unit position # we would get a 2 and would not know if this rounded up or not # without doing a test (as done below). But if we keep an extra # digit we know that 1.9 is not the same as 1 and there is no # need for further testing: our int value is correct. If the value # were 1.99, however, this would round to 2.0 and our int value is # off by one. So...if our round value is the same as the int value # (regardless of how much extra work we do to calculate extra decimal # places) we need to test whether we are off by one. from sympy import Dummy if not self.is_number: raise TypeError("can't convert symbols to int") r = self.round(2) if not r.is_Number: raise TypeError("can't convert complex to int") if r in (S.NaN, S.Infinity, S.NegativeInfinity): raise TypeError("can't convert %s to int" % r) i = int(r) if not i: return 0 # off-by-one check if i == r and not (self - i).equals(0): isign = 1 if i > 0 else -1 x = Dummy() # in the following (self - i).evalf(2) will not always work while # (self - r).evalf(2) and the use of subs does; if the test that # was added when this comment was added passes, it might be safe # to simply use sign to compute this rather than doing this by hand: diff_sign = 1 if (self - x).evalf(2, subs={x: i}) > 0 else -1 if diff_sign != isign: i -= isign return i __long__ = __int__ def __float__(self): # Don't bother testing if it's a number; if it's not this is going # to fail, and if it is we still need to check that it evalf'ed to # a number. result = self.evalf() if result.is_Number: return float(result) if result.is_number and result.as_real_imag()[1]: raise TypeError("can't convert complex to float") raise TypeError("can't convert expression to float") def __complex__(self): result = self.evalf() re, im = result.as_real_imag() return complex(float(re), float(im)) def __ge__(self, other): from sympy import GreaterThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 >= 0) if self.is_real or other.is_real: dif = self - other if dif.is_nonnegative is not None and \ dif.is_nonnegative is not dif.is_negative: return sympify(dif.is_nonnegative) return GreaterThan(self, other, evaluate=False) def __le__(self, other): from sympy import LessThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 <= 0) if self.is_real or other.is_real: dif = self - other if dif.is_nonpositive is not None and \ dif.is_nonpositive is not dif.is_positive: return sympify(dif.is_nonpositive) return LessThan(self, other, evaluate=False) def __gt__(self, other): from sympy import StrictGreaterThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 > 0) if self.is_real or other.is_real: dif = self - other if dif.is_positive is not None and \ dif.is_positive is not dif.is_nonpositive: return sympify(dif.is_positive) return StrictGreaterThan(self, other, evaluate=False) def __lt__(self, other): from sympy import StrictLessThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 < 0) if self.is_real or other.is_real: dif = self - other if dif.is_negative is not None and \ dif.is_negative is not dif.is_nonnegative: return sympify(dif.is_negative) return StrictLessThan(self, other, evaluate=False) def __trunc__(self): if not self.is_number: raise TypeError("can't truncate symbols and expressions") else: return Integer(self) @staticmethod def _from_mpmath(x, prec): from sympy import Float if hasattr(x, "_mpf_"): return Float._new(x._mpf_, prec) elif hasattr(x, "_mpc_"): re, im = x._mpc_ re = Float._new(re, prec) im = Float._new(im, prec)S.ImaginaryUnit return re + im else: raise TypeError("expected mpmath number (mpf or mpc)") @property def is_number(self): """Returns True if ``self`` has no free symbols and no undefined functions (AppliedUndef, to be precise). It will be faster than ``if not self.free_symbols``, however, since ``is_number`` will fail as soon as it hits a free symbol or undefined function. Examples ======== >>> from sympy import log, Integral, cos, sin, pi >>> from sympy.core.function import Function >>> from sympy.abc import x >>> f = Function('f') >>> x.is_number False >>> f(1).is_number False >>> (2x).is_number False >>> (2 + Integral(2, x)).is_number False >>> (2 + Integral(2, (x, 1, 2))).is_number True Not all numbers are Numbers in the SymPy sense: >>> pi.is_number, pi.is_Number (True, False) If something is a number it should evaluate to a number with real and imaginary parts that are Numbers; the result may not be comparable, however, since the real and/or imaginary part of the result may not have precision. >>> cos(1).is_number and cos(1).is_comparable True >>> z = cos(1)2 + sin(1)2 - 1 >>> z.is_number True >>> z.is_comparable False See Also ======== sympy.core.basic.is_comparable """ return all(obj.is_number for obj in self.args) def _random(self, n=None, re_min=-1, im_min=-1, re_max=1, im_max=1): """Return self evaluated, if possible, replacing free symbols with random complex values, if necessary. The random complex value for each free symbol is generated by the random_complex_number routine giving real and imaginary parts in the range given by the re_min, re_max, im_min, and im_max values. The returned value is evaluated to a precision of n (if given) else the maximum of 15 and the precision needed to get more than 1 digit of precision. If the expression could not be evaluated to a number, or could not be evaluated to more than 1 digit of precision, then None is returned. Examples ======== >>> from sympy import sqrt >>> from sympy.abc import x, y >>> x._random() # doctest: +SKIP 0.0392918155679172 + 0.916050214307199I >>> x._random(2) # doctest: +SKIP -0.77 - 0.87I >>> (x + y/2)._random(2) # doctest: +SKIP -0.57 + 0.16I >>> sqrt(2)._random(2) 1.4 See Also ======== sympy.utilities.randtest.random_complex_number """ free = self.free_symbols prec = 1 if free: from sympy.utilities.randtest import random_complex_number a, c, b, d = re_min, re_max, im_min, im_max reps = dict(list(zip(free, [random_complex_number(a, b, c, d, rational=True) for zi in free]))) try: nmag = abs(self.evalf(2, subs=reps)) except (ValueError, TypeError): # if an out of range value resulted in evalf problems # then return None -- XXX is there a way to know how to # select a good random number for a given expression? # e.g. when calculating n! negative values for n should not # be used return None else: reps = {} nmag = abs(self.evalf(2)) if not hasattr(nmag, '_prec'): # e.g. exp_polar(2Ipi) doesn't evaluate but is_number is True return None if nmag._prec == 1: # increase the precision up to the default maximum # precision to see if we can get any significance from mpmath.libmp.libintmath import giant_steps from sympy.core.evalf import DEFAULT_MAXPREC as target # evaluate for prec in giant_steps(2, target): nmag = abs(self.evalf(prec, subs=reps)) if nmag._prec != 1: break if nmag._prec != 1: if n is None: n = max(prec, 15) return self.evalf(n, subs=reps) # never got any significance return None def is_constant(self, wrt, flags): """Return True if self is constant, False if not, or None if the constancy could not be determined conclusively. If an expression has no free symbols then it is a constant. If there are free symbols it is possible that the expression is a constant, perhaps (but not necessarily) zero. To test such expressions, two strategies are tried: 1) numerical evaluation at two random points. If two such evaluations give two different values and the values have a precision greater than 1 then self is not constant. If the evaluations agree or could not be obtained with any precision, no decision is made. The numerical testing is done only if ``wrt`` is different than the free symbols. 2) differentiation with respect to variables in 'wrt' (or all free symbols if omitted) to see if the expression is constant or not. This will not always lead to an expression that is zero even though an expression is constant (see added test in test_expr.py). If all derivatives are zero then self is constant with respect to the given symbols. If neither evaluation nor differentiation can prove the expression is constant, None is returned unless two numerical values happened to be the same and the flag ``failing_number`` is True -- in that case the numerical value will be returned. If flag simplify=False is passed, self will not be simplified; the default is True since self should be simplified before testing. Examples ======== >>> from sympy import cos, sin, Sum, S, pi >>> from sympy.abc import a, n, x, y >>> x.is_constant() False >>> S(2).is_constant() True >>> Sum(x, (x, 1, 10)).is_constant() True >>> Sum(x, (x, 1, n)).is_constant() False >>> Sum(x, (x, 1, n)).is_constant(y) True >>> Sum(x, (x, 1, n)).is_constant(n) False >>> Sum(x, (x, 1, n)).is_constant(x) True >>> eq = acos(x)*2 + asin(x)2 - a >>> eq.is_constant() True >>> eq.subs({x: pi, a: 2}) == eq.subs({x: pi, a: 3}) == 0 True >>> (0x).is_constant() False >>> x.is_constant() False >>> (xx).is_constant() False >>> one = cos(x)2 + sin(x)2 >>> one.is_constant() True >>> ((one - 1)(x + 1)).is_constant() in (True, False) # could be 0 or 1 True """ simplify = flags.get('simplify', True) if self.is_number: return True free = self.free_symbols if not free: return True # assume f(1) is some constant # if we are only interested in some symbols and they are not in the # free symbols then this expression is constant wrt those symbols wrt = set(wrt) if wrt and not wrt & free: return True wrt = wrt or free # simplify unless this has already been done expr = self if simplify: expr = expr.simplify() # is_zero should be a quick assumptions check; it can be wrong for # numbers (see test_is_not_constant test), giving False when it # shouldn't, but hopefully it will never give True unless it is sure. if expr.is_zero: return True # try numerical evaluation to see if we get two different values failing_number = None if wrt == free: # try 0 (for a) and 1 (for b) try: a = expr.subs(list(zip(free, [0]len(free))), simultaneous=True) if a is S.NaN: # evaluation may succeed when substitution fails a = expr._random(None, 0, 0, 0, 0) except ZeroDivisionError: a = None if a is not None and a is not S.NaN: try: b = expr.subs(list(zip(free, [1]len(free))), simultaneous=True) if b is S.NaN: # evaluation may succeed when substitution fails b = expr._random(None, 1, 0, 1, 0) except ZeroDivisionError: b = None if b is not None and b is not S.NaN and b.equals(a) is False: return False # try random real b = expr._random(None, -1, 0, 1, 0) if b is not None and b is not S.NaN and b.equals(a) is False: return False # try random complex b = expr._random() if b is not None and b is not S.NaN: if b.equals(a) is False: return False failing_number = a if a.is_number else b # now we will test each wrt symbol (or all free symbols) to see if the # expression depends on them or not using differentiation. This is # not sufficient for all expressions, however, so we don't return # False if we get a derivative other than 0 with free symbols. for w in wrt: deriv = expr.diff(w) if simplify: deriv = deriv.simplify() if deriv != 0: if not (pure_complex(deriv, or_real=True)): if flags.get('failing_number', False): return failing_number elif deriv.free_symbols: # dead line provided _random returns None in such cases return None return False return True def equals(self, other, failing_expression=False): """Return True if self == other, False if it doesn't, or None. If failing_expression is True then the expression which did not simplify to a 0 will be returned instead of None. If ``self`` is a Number (or complex number) that is not zero, then the result is False. If ``self`` is a number and has not evaluated to zero, evalf will be used to test whether the expression evaluates to zero. If it does so and the result has significance (i.e. the precision is either -1, for a Rational result, or is greater than 1) then the evalf value will be used to return True or False. """ from sympy.simplify.simplify import nsimplify, simplify from sympy.solvers.solveset import solveset from sympy.polys.polyerrors import NotAlgebraic from sympy.polys.numberfields import minimal_polynomial other = sympify(other) if self == other: return True # they aren't the same so see if we can make the difference 0; # don't worry about doing simplification steps one at a time # because if the expression ever goes to 0 then the subsequent # simplification steps that are done will be very fast. diff = factor_terms(simplify(self - other), radical=True) if not diff: return True if not diff.has(Add, Mod): # if there is no expanding to be done after simplifying # then this can't be a zero return False constant = diff.is_constant(simplify=False, failing_number=True) if constant is False: return False if constant is None and not diff.is_number: # e.g. unless the right simplification is done, a symbolic # zero is possible (see expression of issue 6829: without # simplification constant will be None). return if constant is True: ndiff = diff._random() if ndiff: return False # sometimes we can use a simplified result to give a clue as to # what the expression should be; if the expression is not zero # then we should have been able to compute that and so now # we can just consider the cases where the approximation appears # to be zero -- we try to prove it via minimal_polynomial. if diff.is_number: approx = diff.nsimplify() if not approx: # try to prove via self-consistency surds = [s for s in diff.atoms(Pow) if s.args[0].is_Integer] # it seems to work better to try big ones first surds.sort(key=lambda x: -x.args[0]) for s in surds: try: # simplify is False here -- this expression has already # been identified as being hard to identify as zero; # we will handle the checking ourselves using nsimplify # to see if we are in the right ballpark or not and if so # then the simplification will be attempted. if s.is_Symbol: sol = list(solveset(diff, s)) else: sol = [s] if sol: if s in sol: return True if s.is_real: if any(nsimplify(si, [s]) == s and simplify(si) == s for si in sol): return True except NotImplementedError: pass # try to prove with minimal_polynomial but know when # not to use this or else it can take a long time. e.g. issue 8354 if True: # change True to condition that assures non-hang try: mp = minimal_polynomial(diff) if mp.is_Symbol: return True return False except (NotAlgebraic, NotImplementedError): pass # diff has not simplified to zero; constant is either None, True # or the number with significance (prec != 1) that was randomly # calculated twice as the same value. if constant not in (True, None) and constant != 0: return False if failing_expression: return diff return None def _eval_is_positive(self): from sympy.polys.numberfields import minimal_polynomial from sympy.polys.polyerrors import NotAlgebraic if self.is_number: if self.is_real is False: return False # check to see that we can get a value try: n2 = self._eval_evalf(2) # XXX: This shouldn't be caught here # Catches ValueError: hypsum() failed to converge to the requested # 34 bits of accuracy except ValueError: return None if n2 is None: return None if getattr(n2, '_prec', 1) == 1: # no significance return None if n2 == S.NaN: return None n, i = self.evalf(2).as_real_imag() if not i.is_Number or not n.is_Number: return False if n._prec != 1 and i._prec != 1: return bool(not i and n > 0) elif n._prec == 1 and (not i or i._prec == 1) and \ self.is_algebraic and not self.has(Function): try: if minimal_polynomial(self).is_Symbol: return False except (NotAlgebraic, NotImplementedError): pass def _eval_is_negative(self): from sympy.polys.numberfields import minimal_polynomial from sympy.polys.polyerrors import NotAlgebraic if self.is_number: if self.is_real is False: return False # check to see that we can get a value try: n2 = self._eval_evalf(2) # XXX: This shouldn't be caught here # Catches ValueError: hypsum() failed to converge to the requested # 34 bits of accuracy except ValueError: return None if n2 is None: return None if getattr(n2, '_prec', 1) == 1: # no significance return None if n2 == S.NaN: return None n, i = self.evalf(2).as_real_imag() if not i.is_Number or not n.is_Number: return False if n._prec != 1 and i._prec != 1: return bool(not i and n < 0) elif n._prec == 1 and (not i or i._prec == 1) and \ self.is_algebraic and not self.has(Function): try: if minimal_polynomial(self).is_Symbol: return False except (NotAlgebraic, NotImplementedError): pass def _eval_interval(self, x, a, b): """ Returns evaluation over an interval. For most functions this is: self.subs(x, b) - self.subs(x, a), possibly using limit() if NaN is returned from subs, or if singularities are found between a and b. If b or a is None, it only evaluates -self.subs(x, a) or self.subs(b, x), respectively. """ from sympy.series import limit, Limit from sympy.solvers.solveset import solveset from sympy.sets.sets import Interval from sympy.functions.elementary.exponential import log from sympy.calculus.util import AccumBounds if (a is None and b is None): raise ValueError('Both interval ends cannot be None.') if a == b: return 0 if a is None: A = 0 else: A = self.subs(x, a) if A.has(S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity, AccumBounds): if (a < b) != False: A = limit(self, x, a,"+") else: A = limit(self, x, a,"-") if A is S.NaN: return A if isinstance(A, Limit): raise NotImplementedError("Could not compute limit") if b is None: B = 0 else: B = self.subs(x, b) if B.has(S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity, AccumBounds): if (a < b) != False: B = limit(self, x, b,"-") else: B = limit(self, x, b,"+") if isinstance(B, Limit): raise NotImplementedError("Could not compute limit") if (a and b) is None: return B - A value = B - A if a.is_comparable and b.is_comparable: if a < b: domain = Interval(a, b) else: domain = Interval(b, a) # check the singularities of self within the interval # if singularities is a ConditionSet (not iterable), catch the exception and pass singularities = solveset(self.cancel().as_numer_denom()[1], x, domain=domain) for logterm in self.atoms(log): singularities = singularities \| solveset(logterm.args[0], x, domain=domain) try: for s in singularities: if value is S.NaN: # no need to keep adding, it will stay NaN break if not s.is_comparable: continue if (a < s) == (s < b) == True: value += -limit(self, x, s, "+") + limit(self, x, s, "-") elif (b < s) == (s < a) == True: value += limit(self, x, s, "+") - limit(self, x, s, "-") except TypeError: pass return value def _eval_power(self, other): # subclass to compute selfother for cases when # other is not NaN, 0, or 1 return None def _eval_conjugate(self): if self.is_real: return self elif self.is_imaginary: return -self def conjugate(self): from sympy.functions.elementary.complexes import conjugate as c return c(self) def _eval_transpose(self): from sympy.functions.elementary.complexes import conjugate if self.is_complex: return self elif self.is_hermitian: return conjugate(self) elif self.is_antihermitian: return -conjugate(self) def transpose(self): from sympy.functions.elementary.complexes import transpose return transpose(self) def _eval_adjoint(self): from sympy.functions.elementary.complexes import conjugate, transpose if self.is_hermitian: return self elif self.is_antihermitian: return -self obj = self._eval_conjugate() if obj is not None: return transpose(obj) obj = self._eval_transpose() if obj is not None: return conjugate(obj) def adjoint(self): from sympy.functions.elementary.complexes import adjoint return adjoint(self) @classmethod def _parse_order(cls, order): """Parse and configure the ordering of terms. """ from sympy.polys.orderings import monomial_key startswith = getattr(order, "startswith", None) if startswith is None: reverse = False else: reverse = startswith('rev-') if reverse: order = order[4:] monom_key = monomial_key(order) def neg(monom): result = [] for m in monom: if isinstance(m, tuple): result.append(neg(m)) else: result.append(-m) return tuple(result) def key(term): _, ((re, im), monom, ncpart) = term monom = neg(monom_key(monom)) ncpart = tuple([e.sort_key(order=order) for e in ncpart]) coeff = ((bool(im), im), (re, im)) return monom, ncpart, coeff return key, reverse def as_ordered_factors(self, order=None): """Return list of ordered factors (if Mul) else [self].""" return [self] def as_ordered_terms(self, order=None, data=False): """ Transform an expression to an ordered list of terms. Examples ======== >>> from sympy import sin, cos >>> from sympy.abc import x >>> (sin(x)2cos(x) + sin(x)2 + 1).as_ordered_terms() [sin(x)2cos(x), sin(x)*2, 1] """ from .numbers import Number, NumberSymbol if order is None and self.is_Add: # Spot the special case of Add(Number, Mul(Number, expr)) with the # first number positive and thhe second number nagative key = lambda x:not isinstance(x, (Number, NumberSymbol)) add_args = sorted(Add.make_args(self), key=key) if (len(add_args) == 2 and isinstance(add_args[0], (Number, NumberSymbol)) and isinstance(add_args[1], Mul)): mul_args = sorted(Mul.make_args(add_args[1]), key=key) if (len(mul_args) == 2 and isinstance(mul_args[0], Number) and add_args[0].is_positive and mul_args[0].is_negative): return add_args key, reverse = self._parse_order(order) terms, gens = self.as_terms() if not any(term.is_Order for term, _ in terms): ordered = sorted(terms, key=key, reverse=reverse) else: _terms, _order = [], [] for term, repr in terms: if not term.is_Order: _terms.append((term, repr)) else: _order.append((term, repr)) ordered = sorted(_terms, key=key, reverse=True) \ + sorted(_order, key=key, reverse=True) if data: return ordered, gens else: return [term for term, _ in ordered] def as_terms(self): """Transform an expression to a list of terms. """ from .add import Add from .mul import Mul from .exprtools import decompose_power gens, terms = set([]), [] for term in Add.make_args(self): coeff, _term = term.as_coeff_Mul() coeff = complex(coeff) cpart, ncpart = {}, [] if _term is not S.One: for factor in Mul.make_args(_term): if factor.is_number: try: coeff = complex(factor) except (TypeError, ValueError): pass else: continue if factor.is_commutative: base, exp = decompose_power(factor) cpart[base] = exp gens.add(base) else: ncpart.append(factor) coeff = coeff.real, coeff.imag ncpart = tuple(ncpart) terms.append((term, (coeff, cpart, ncpart))) gens = sorted(gens, key=default_sort_key) k, indices = len(gens), {} for i, g in enumerate(gens): indices[g] = i result = [] for term, (coeff, cpart, ncpart) in terms: monom = [0]k for base, exp in cpart.items(): monom[indices[base]] = exp result.append((term, (coeff, tuple(monom), ncpart))) return result, gens def removeO(self): """Removes the additive O(..) symbol if there is one""" return self def getO(self): """Returns the additive O(..) symbol if there is one, else None.""" return None def getn(self): """ Returns the order of the expression. The order is determined either from the O(...) term. If there is no O(...) term, it returns None. Examples ======== >>> from sympy import O >>> from sympy.abc import x >>> (1 + x + O(x2)).getn() 2 >>> (1 + x).getn() """ from sympy import Dummy, Symbol o = self.getO() if o is None: return None elif o.is_Order: o = o.expr if o is S.One: return S.Zero if o.is_Symbol: return S.One if o.is_Pow: return o.args[1] if o.is_Mul: # xnlog(x)n or xn/log(x)*n for oi in o.args: if oi.is_Symbol: return S.One if oi.is_Pow: syms = oi.atoms(Symbol) if len(syms) == 1: x = syms.pop() oi = oi.subs(x, Dummy('x', positive=True)) if oi.base.is_Symbol and oi.exp.is_Rational: return abs(oi.exp) raise NotImplementedError('not sure of order of %s' % o) def count_ops(self, visual=None): """wrapper for count_ops that returns the operation count.""" from .function import count_ops return count_ops(self, visual) def args_cnc(self, cset=False, warn=True, split_1=True): """Return [commutative factors, non-commutative factors] of self. self is treated as a Mul and the ordering of the factors is maintained. If ``cset`` is True the commutative factors will be returned in a set. If there were repeated factors (as may happen with an unevaluated Mul) then an error will be raised unless it is explicitly suppressed by setting ``warn`` to False. Note: -1 is always separated from a Number unless split_1 is False. >>> from sympy import symbols, oo >>> A, B = symbols('A B', commutative=0) >>> x, y = symbols('x y') >>> (-2xy).args_cnc() [[-1, 2, x, y], []] >>> (-2.5x).args_cnc() [[-1, 2.5, x], []] >>> (-2xABy).args_cnc() [[-1, 2, x, y], [A, B]] >>> (-2xABy).args_cnc(split_1=False) [[-2, x, y], [A, B]] >>> (-2xy).args_cnc(cset=True) [{-1, 2, x, y}, []] The arg is always treated as a Mul: >>> (-2 + x + A).args_cnc() [[], [x - 2 + A]] >>> (-oo).args_cnc() # -oo is a singleton [[-1, oo], []] """ if self.is_Mul: args = list(self.args) else: args = [self] for i, mi in enumerate(args): if not mi.is_commutative: c = args[:i] nc = args[i:] break else: c = args nc = [] if c and split_1 and ( c[0].is_Number and c[0].is_negative and c[0] is not S.NegativeOne): c[:1] = [S.NegativeOne, -c[0]] if cset: clen = len(c) c = set(c) if clen and warn and len(c) != clen: raise ValueError('repeated commutative arguments: %s' % [ci for ci in c if list(self.args).count(ci) > 1]) return [c, nc] def coeff(self, x, n=1, right=False): """ Returns the coefficient from the term(s) containing ``x*n``. If ``n`` is zero then all terms independent of ``x`` will be returned. When ``x`` is noncommutative, the coefficient to the left (default) or right of ``x`` can be returned. The keyword 'right' is ignored when ``x`` is commutative. See Also ======== as_coefficient: separate the expression into a coefficient and factor as_coeff_Add: separate the additive constant from an expression as_coeff_Mul: separate the multiplicative constant from an expression as_independent: separate x-dependent terms/factors from others sympy.polys.polytools.coeff_monomial: efficiently find the single coefficient of a monomial in Poly sympy.polys.polytools.nth: like coeff_monomial but powers of monomial terms are used Examples ======== >>> from sympy import symbols >>> from sympy.abc import x, y, z You can select terms that have an explicit negative in front of them: >>> (-x + 2y).coeff(-1) x >>> (x - 2y).coeff(-1) 2y You can select terms with no Rational coefficient: >>> (x + 2y).coeff(1) x >>> (3 + 2x + 4x2).coeff(1) 0 You can select terms independent of x by making n=0; in this case expr.as_independent(x)[0] is returned (and 0 will be returned instead of None): >>> (3 + 2x + 4x2).coeff(x, 0) 3 >>> eq = ((x + 1)3).expand() + 1 >>> eq x3 + 3x*2 + 3x + 2 >>> [eq.coeff(x, i) for i in reversed(range(4))] [1, 3, 3, 2] >>> eq -= 2 >>> [eq.coeff(x, i) for i in reversed(range(4))] [1, 3, 3, 0] You can select terms that have a numerical term in front of them: >>> (-x - 2y).coeff(2) -y >>> from sympy import sqrt >>> (x + sqrt(2)x).coeff(sqrt(2)) x The matching is exact: >>> (3 + 2x + 4x*2).coeff(x) 2 >>> (3 + 2x + 4x2).coeff(x2) 4 >>> (3 + 2x + 4x2).coeff(x3) 0 >>> (z(x + y)2).coeff((x + y)2) z >>> (z(x + y)2).coeff(x + y) 0 In addition, no factoring is done, so 1 + z(1 + y) is not obtained from the following: >>> (x + z(x + xy)).coeff(x) 1 If such factoring is desired, factor_terms can be used first: >>> from sympy import factor_terms >>> factor_terms(x + z(x + xy)).coeff(x) z(y + 1) + 1 >>> n, m, o = symbols('n m o', commutative=False) >>> n.coeff(n) 1 >>> (3n).coeff(n) 3 >>> (nm + mnm).coeff(n) # = (1 + m)nm 1 + m >>> (nm + mnm).coeff(n, right=True) # = (1 + m)nm m If there is more than one possible coefficient 0 is returned: >>> (nm + mn).coeff(n) 0 If there is only one possible coefficient, it is returned: >>> (nm + xmn).coeff(mn) x >>> (nm + xmn).coeff(mn, right=1) 1 """ x = sympify(x) if not isinstance(x, Basic): return S.Zero n = as_int(n) if not x: return S.Zero if x == self: if n == 1: return S.One return S.Zero if x is S.One: co = [a for a in Add.make_args(self) if a.as_coeff_Mul()[0] is S.One] if not co: return S.Zero return Add(co) if n == 0: if x.is_Add and self.is_Add: c = self.coeff(x, right=right) if not c: return S.Zero if not right: return self - Add([ax for a in Add.make_args(c)]) return self - Add([xa for a in Add.make_args(c)]) return self.as_independent(x, as_Add=True)[0] # continue with the full method, looking for this power of x: x = xn def incommon(l1, l2): if not l1 or not l2: return [] n = min(len(l1), len(l2)) for i in range(n): if l1[i] != l2[i]: return l1[:i] return l1[:] def find(l, sub, first=True): """ Find where list sub appears in list l. When ``first`` is True the first occurrence from the left is returned, else the last occurrence is returned. Return None if sub is not in l. >> l = range(5)2 >> find(l, [2, 3]) 2 >> find(l, [2, 3], first=0) 7 >> find(l, [2, 4]) None """ if not sub or not l or len(sub) > len(l): return None n = len(sub) if not first: l.reverse() sub.reverse() for i in range(0, len(l) - n + 1): if all(l[i + j] == sub[j] for j in range(n)): break else: i = None if not first: l.reverse() sub.reverse() if i is not None and not first: i = len(l) - (i + n) return i co = [] args = Add.make_args(self) self_c = self.is_commutative x_c = x.is_commutative if self_c and not x_c: return S.Zero if self_c: xargs = x.args_cnc(cset=True, warn=False)[0] for a in args: margs = a.args_cnc(cset=True, warn=False)[0] if len(xargs) > len(margs): continue resid = margs.difference(xargs) if len(resid) + len(xargs) == len(margs): co.append(Mul(resid)) if co == []: return S.Zero elif co: return Add(co) elif x_c: xargs = x.args_cnc(cset=True, warn=False)[0] for a in args: margs, nc = a.args_cnc(cset=True) if len(xargs) > len(margs): continue resid = margs.difference(xargs) if len(resid) + len(xargs) == len(margs): co.append(Mul((list(resid) + nc))) if co == []: return S.Zero elif co: return Add(co) else: # both nc xargs, nx = x.args_cnc(cset=True) # find the parts that pass the commutative terms for a in args: margs, nc = a.args_cnc(cset=True) if len(xargs) > len(margs): continue resid = margs.difference(xargs) if len(resid) + len(xargs) == len(margs): co.append((resid, nc)) # now check the non-comm parts if not co: return S.Zero if all(n == co[0][1] for r, n in co): ii = find(co[0][1], nx, right) if ii is not None: if not right: return Mul(Add([Mul(r) for r, c in co]), Mul(co[0][1][:ii])) else: return Mul(co[0][1][ii + len(nx):]) beg = reduce(incommon, (n[1] for n in co)) if beg: ii = find(beg, nx, right) if ii is not None: if not right: gcdc = co[0][0] for i in range(1, len(co)): gcdc = gcdc.intersection(co[i][0]) if not gcdc: break return Mul((list(gcdc) + beg[:ii])) else: m = ii + len(nx) return Add([Mul((list(r) + n[m:])) for r, n in co]) end = list(reversed( reduce(incommon, (list(reversed(n[1])) for n in co)))) if end: ii = find(end, nx, right) if ii is not None: if not right: return Add([Mul((list(r) + n[:-len(end) + ii])) for r, n in co]) else: return Mul(end[ii + len(nx):]) # look for single match hit = None for i, (r, n) in enumerate(co): ii = find(n, nx, right) if ii is not None: if not hit: hit = ii, r, n else: break else: if hit: ii, r, n = hit if not right: return Mul((list(r) + n[:ii])) else: return Mul(n[ii + len(nx):]) return S.Zero def as_expr(self, gens): """ Convert a polynomial to a SymPy expression. Examples ======== >>> from sympy import sin >>> from sympy.abc import x, y >>> f = (x2 + xy).as_poly(x, y) >>> f.as_expr() x*2 + xy >>> sin(x).as_expr() sin(x) """ return self def as_coefficient(self, expr): """ Extracts symbolic coefficient at the given expression. In other words, this functions separates 'self' into the product of 'expr' and 'expr'-free coefficient. If such separation is not possible it will return None. Examples ======== >>> from sympy import E, pi, sin, I, Poly >>> from sympy.abc import x >>> E.as_coefficient(E) 1 >>> (2E).as_coefficient(E) 2 >>> (2sin(E)E).as_coefficient(E) Two terms have E in them so a sum is returned. (If one were desiring the coefficient of the term exactly matching E then the constant from the returned expression could be selected. Or, for greater precision, a method of Poly can be used to indicate the desired term from which the coefficient is desired.) >>> (2E + xE).as_coefficient(E) x + 2 >>> _.args[0] # just want the exact match 2 >>> p = Poly(2E + xE); p Poly(xE + 2E, x, E, domain='ZZ') >>> p.coeff_monomial(E) 2 >>> p.nth(0, 1) 2 Since the following cannot be written as a product containing E as a factor, None is returned. (If the coefficient ``2x`` is desired then the ``coeff`` method should be used.) >>> (2Ex + x).as_coefficient(E) >>> (2Ex + x).coeff(E) 2x >>> (E(x + 1) + x).as_coefficient(E) >>> (2piI).as_coefficient(piI) 2 >>> (2I).as_coefficient(piI) See Also ======== coeff: return sum of terms have a given factor as_coeff_Add: separate the additive constant from an expression as_coeff_Mul: separate the multiplicative constant from an expression as_independent: separate x-dependent terms/factors from others sympy.polys.polytools.coeff_monomial: efficiently find the single coefficient of a monomial in Poly sympy.polys.polytools.nth: like coeff_monomial but powers of monomial terms are used """ r = self.extract_multiplicatively(expr) if r and not r.has(expr): return r def as_independent(self, deps, *hint): """ A mostly naive separation of a Mul or Add into arguments that are not are dependent on deps. To obtain as complete a separation of variables as possible, use a separation method first, e.g.: separatevars() to change Mul, Add and Pow (including exp) into Mul * .expand(mul=True) to change Add or Mul into Add * .expand(log=True) to change log expr into an Add The only non-naive thing that is done here is to respect noncommutative ordering of variables and to always return (0, 0) for `self` of zero regardless of hints. For nonzero `self`, the returned tuple (i, d) has the following interpretation: * i will has no variable that appears in deps * d will either have terms that contain variables that are in deps, or be equal to 0 (when self is an Add) or 1 (when self is a Mul) * if self is an Add then self = i + d * if self is a Mul then self = id otherwise (self, S.One) or (S.One, self) is returned. To force the expression to be treated as an Add, use the hint as_Add=True Examples ======== -- self is an Add >>> from sympy import sin, cos, exp >>> from sympy.abc import x, y, z >>> (x + xy).as_independent(x) (0, xy + x) >>> (x + xy).as_independent(y) (x, xy) >>> (2xsin(x) + y + x + z).as_independent(x) (y + z, 2xsin(x) + x) >>> (2xsin(x) + y + x + z).as_independent(x, y) (z, 2xsin(x) + x + y) -- self is a Mul >>> (xsin(x)cos(y)).as_independent(x) (cos(y), xsin(x)) non-commutative terms cannot always be separated out when self is a Mul >>> from sympy import symbols >>> n1, n2, n3 = symbols('n1 n2 n3', commutative=False) >>> (n1 + n1n2).as_independent(n2) (n1, n1n2) >>> (n2n1 + n1n2).as_independent(n2) (0, n1n2 + n2n1) >>> (n1n2n3).as_independent(n1) (1, n1n2n3) >>> (n1n2n3).as_independent(n2) (n1, n2n3) >>> ((x-n1)(x-y)).as_independent(x) (1, (x - y)(x - n1)) -- self is anything else: >>> (sin(x)).as_independent(x) (1, sin(x)) >>> (sin(x)).as_independent(y) (sin(x), 1) >>> exp(x+y).as_independent(x) (1, exp(x + y)) -- force self to be treated as an Add: >>> (3x).as_independent(x, as_Add=True) (0, 3x) -- force self to be treated as a Mul: >>> (3+x).as_independent(x, as_Add=False) (1, x + 3) >>> (-3+x).as_independent(x, as_Add=False) (1, x - 3) Note how the below differs from the above in making the constant on the dep term positive. >>> (y(-3+x)).as_independent(x) (y, x - 3) -- use .as_independent() for true independence testing instead of .has(). The former considers only symbols in the free symbols while the latter considers all symbols >>> from sympy import Integral >>> I = Integral(x, (x, 1, 2)) >>> I.has(x) True >>> x in I.free_symbols False >>> I.as_independent(x) == (I, 1) True >>> (I + x).as_independent(x) == (I, x) True Note: when trying to get independent terms, a separation method might need to be used first. In this case, it is important to keep track of what you send to this routine so you know how to interpret the returned values >>> from sympy import separatevars, log >>> separatevars(exp(x+y)).as_independent(x) (exp(y), exp(x)) >>> (x + xy).as_independent(y) (x, xy) >>> separatevars(x + xy).as_independent(y) (x, y + 1) >>> (x(1 + y)).as_independent(y) (x, y + 1) >>> (x(1 + y)).expand(mul=True).as_independent(y) (x, xy) >>> a, b=symbols('a b', positive=True) >>> (log(ab).expand(log=True)).as_independent(b) (log(a), log(b)) See Also ======== .separatevars(), .expand(log=True), Add.as_two_terms(), Mul.as_two_terms(), .as_coeff_add(), .as_coeff_mul() """ from .symbol import Symbol from .add import _unevaluated_Add from .mul import _unevaluated_Mul from sympy.utilities.iterables import sift if self.is_zero: return S.Zero, S.Zero func = self.func if hint.get('as_Add', isinstance(self, Add) ): want = Add else: want = Mul # sift out deps into symbolic and other and ignore # all symbols but those that are in the free symbols sym = set() other = [] for d in deps: if isinstance(d, Symbol): # Symbol.is_Symbol is True sym.add(d) else: other.append(d) def has(e): """return the standard has() if there are no literal symbols, else check to see that symbol-deps are in the free symbols.""" has_other = e.has(other) if not sym: return has_other return has_other or e.has((e.free_symbols & sym)) if (want is not func or func is not Add and func is not Mul): if has(self): return (want.identity, self) else: return (self, want.identity) else: if func is Add: args = list(self.args) else: args, nc = self.args_cnc() d = sift(args, lambda x: has(x)) depend = d[True] indep = d[False] if func is Add: # all terms were treated as commutative return (Add(indep), _unevaluated_Add(depend)) else: # handle noncommutative by stopping at first dependent term for i, n in enumerate(nc): if has(n): depend.extend(nc[i:]) break indep.append(n) return Mul(indep), ( Mul(depend, evaluate=False) if nc else _unevaluated_Mul(depend)) def as_real_imag(self, deep=True, hints): """Performs complex expansion on 'self' and returns a tuple containing collected both real and imaginary parts. This method can't be confused with re() and im() functions, which does not perform complex expansion at evaluation. However it is possible to expand both re() and im() functions and get exactly the same results as with a single call to this function. >>> from sympy import symbols, I >>> x, y = symbols('x,y', real=True) >>> (x + yI).as_real_imag() (x, y) >>> from sympy.abc import z, w >>> (z + wI).as_real_imag() (re(z) - im(w), re(w) + im(z)) """ from sympy import im, re if hints.get('ignore') == self: return None else: return (re(self), im(self)) def as_powers_dict(self): """Return self as a dictionary of factors with each factor being treated as a power. The keys are the bases of the factors and the values, the corresponding exponents. The resulting dictionary should be used with caution if the expression is a Mul and contains non- commutative factors since the order that they appeared will be lost in the dictionary. See Also ======== as_ordered_factors: An alternative for noncommutative applications, returning an ordered list of factors. args_cnc: Similar to as_ordered_factors, but guarantees separation of commutative and noncommutative factors. """ d = defaultdict(int) d.update(dict([self.as_base_exp()])) return d def as_coefficients_dict(self): """Return a dictionary mapping terms to their Rational coefficient. Since the dictionary is a defaultdict, inquiries about terms which were not present will return a coefficient of 0. If an expression is not an Add it is considered to have a single term. Examples ======== >>> from sympy.abc import a, x >>> (3x + ax + 4).as_coefficients_dict() {1: 4, x: 3, ax: 1} >>> _[a] 0 >>> (3ax).as_coefficients_dict() {ax: 3} """ c, m = self.as_coeff_Mul() if not c.is_Rational: c = S.One m = self d = defaultdict(int) d.update({m: c}) return d def as_base_exp(self): # a -> b * e return self, S.One def as_coeff_mul(self, deps, kwargs): """Return the tuple (c, args) where self is written as a Mul, ``m``. c should be a Rational multiplied by any factors of the Mul that are independent of deps. args should be a tuple of all other factors of m; args is empty if self is a Number or if self is independent of deps (when given). This should be used when you don't know if self is a Mul or not but you want to treat self as a Mul or if you want to process the individual arguments of the tail of self as a Mul. - if you know self is a Mul and want only the head, use self.args[0]; - if you don't want to process the arguments of the tail but need the tail then use self.as_two_terms() which gives the head and tail; - if you want to split self into an independent and dependent parts use ``self.as_independent(deps)`` >>> from sympy import S >>> from sympy.abc import x, y >>> (S(3)).as_coeff_mul() (3, ()) >>> (3xy).as_coeff_mul() (3, (x, y)) >>> (3xy).as_coeff_mul(x) (3y, (x,)) >>> (3y).as_coeff_mul(x) (3y, ()) """ if deps: if not self.has(deps): return self, tuple() return S.One, (self,) def as_coeff_add(self, deps): """Return the tuple (c, args) where self is written as an Add, ``a``. c should be a Rational added to any terms of the Add that are independent of deps. args should be a tuple of all other terms of ``a``; args is empty if self is a Number or if self is independent of deps (when given). This should be used when you don't know if self is an Add or not but you want to treat self as an Add or if you want to process the individual arguments of the tail of self as an Add. - if you know self is an Add and want only the head, use self.args[0]; - if you don't want to process the arguments of the tail but need the tail then use self.as_two_terms() which gives the head and tail. - if you want to split self into an independent and dependent parts use ``self.as_independent(deps)`` >>> from sympy import S >>> from sympy.abc import x, y >>> (S(3)).as_coeff_add() (3, ()) >>> (3 + x).as_coeff_add() (3, (x,)) >>> (3 + x + y).as_coeff_add(x) (y + 3, (x,)) >>> (3 + y).as_coeff_add(x) (y + 3, ()) """ if deps: if not self.has(deps): return self, tuple() return S.Zero, (self,) def primitive(self): """Return the positive Rational that can be extracted non-recursively from every term of self (i.e., self is treated like an Add). This is like the as_coeff_Mul() method but primitive always extracts a positive Rational (never a negative or a Float). Examples ======== >>> from sympy.abc import x >>> (3(x + 1)2).primitive() (3, (x + 1)2) >>> a = (6x + 2); a.primitive() (2, 3x + 1) >>> b = (x/2 + 3); b.primitive() (1/2, x + 6) >>> (ab).primitive() == (1, ab) True """ if not self: return S.One, S.Zero c, r = self.as_coeff_Mul(rational=True) if c.is_negative: c, r = -c, -r return c, r def as_content_primitive(self, radical=False, clear=True): """This method should recursively remove a Rational from all arguments and return that (content) and the new self (primitive). The content should always be positive and ``Mul(foo.as_content_primitive()) == foo``. The primitive need not be in canonical form and should try to preserve the underlying structure if possible (i.e. expand_mul should not be applied to self). Examples ======== >>> from sympy import sqrt >>> from sympy.abc import x, y, z >>> eq = 2 + 2x + 2y(3 + 3y) The as_content_primitive function is recursive and retains structure: >>> eq.as_content_primitive() (2, x + 3y(y + 1) + 1) Integer powers will have Rationals extracted from the base: >>> ((2 + 6x)*2).as_content_primitive() (4, (3x + 1)*2) >>> ((2 + 6x)*(2y)).as_content_primitive() (1, (2(3x + 1))*(2y)) Terms may end up joining once their as_content_primitives are added: >>> ((5(x(1 + y)) + 2x(3 + 3y))).as_content_primitive() (11, x(y + 1)) >>> ((3(x(1 + y)) + 2x(3 + 3y))).as_content_primitive() (9, x(y + 1)) >>> ((3(z(1 + y)) + 2.0x(3 + 3y))).as_content_primitive() (1, 6.0x(y + 1) + 3z(y + 1)) >>> ((5(x(1 + y)) + 2x(3 + 3y))2).as_content_primitive() (121, x2(y + 1)2) >>> ((5(x(1 + y)) + 2.0x(3 + 3y))*2).as_content_primitive() (1, 121.0x*2(y + 1)*2) Radical content can also be factored out of the primitive: >>> (2sqrt(2) + 4sqrt(10)).as_content_primitive(radical=True) (2, sqrt(2)(1 + 2sqrt(5))) If clear=False (default is True) then content will not be removed from an Add if it can be distributed to leave one or more terms with integer coefficients. >>> (x/2 + y).as_content_primitive() (1/2, x + 2y) >>> (x/2 + y).as_content_primitive(clear=False) (1, x/2 + y) """ return S.One, self def as_numer_denom(self): """ expression -> a/b -> a, b This is just a stub that should be defined by an object's class methods to get anything else. See Also ======== normal: return a/b instead of a, b """ return self, S.One def normal(self): from .mul import _unevaluated_Mul n, d = self.as_numer_denom() if d is S.One: return n if d.is_Number: return _unevaluated_Mul(n, 1/d) else: return n/d def extract_multiplicatively(self, c): """Return None if it's not possible to make self in the form c * something in a nice way, i.e. preserving the properties of arguments of self. Examples ======== >>> from sympy import symbols, Rational >>> x, y = symbols('x,y', real=True) >>> ((xy)3).extract_multiplicatively(x2 y) xy2 >>> ((xy)3).extract_multiplicatively(x4 * y) >>> (2x).extract_multiplicatively(2) x >>> (2x).extract_multiplicatively(3) >>> (Rational(1, 2)x).extract_multiplicatively(3) x/6 """ c = sympify(c) if self is S.NaN: return None if c is S.One: return self elif c == self: return S.One if c.is_Add: cc, pc = c.primitive() if cc is not S.One: c = Mul(cc, pc, evaluate=False) if c.is_Mul: a, b = c.as_two_terms() x = self.extract_multiplicatively(a) if x is not None: return x.extract_multiplicatively(b) quotient = self / c if self.is_Number: if self is S.Infinity: if c.is_positive: return S.Infinity elif self is S.NegativeInfinity: if c.is_negative: return S.Infinity elif c.is_positive: return S.NegativeInfinity elif self is S.ComplexInfinity: if not c.is_zero: return S.ComplexInfinity elif self.is_Integer: if not quotient.is_Integer: return None elif self.is_positive and quotient.is_negative: return None else: return quotient elif self.is_Rational: if not quotient.is_Rational: return None elif self.is_positive and quotient.is_negative: return None else: return quotient elif self.is_Float: if not quotient.is_Float: return None elif self.is_positive and quotient.is_negative: return None else: return quotient elif self.is_NumberSymbol or self.is_Symbol or self is S.ImaginaryUnit: if quotient.is_Mul and len(quotient.args) == 2: if quotient.args[0].is_Integer and quotient.args[0].is_positive and quotient.args[1] == self: return quotient elif quotient.is_Integer and c.is_Number: return quotient elif self.is_Add: cs, ps = self.primitive() # assert cs >= 1 if c.is_Number and c is not S.NegativeOne: # assert c != 1 (handled at top) if cs is not S.One: if c.is_negative: xc = -(cs.extract_multiplicatively(-c)) else: xc = cs.extract_multiplicatively(c) if xc is not None: return xcps # rely on 2-arg Mul to restore Add return # \|c\| != 1 can only be extracted from cs if c == ps: return cs # check args of ps newargs = [] for arg in ps.args: newarg = arg.extract_multiplicatively(c) if newarg is None: return # all or nothing newargs.append(newarg) # args should be in same order so use unevaluated return if cs is not S.One: return Add._from_args([cst for t in newargs]) else: return Add._from_args(newargs) elif self.is_Mul: args = list(self.args) for i, arg in enumerate(args): newarg = arg.extract_multiplicatively(c) if newarg is not None: args[i] = newarg return Mul(args) elif self.is_Pow: if c.is_Pow and c.base == self.base: new_exp = self.exp.extract_additively(c.exp) if new_exp is not None: return self.base (new_exp) elif c == self.base: new_exp = self.exp.extract_additively(1) if new_exp is not None: return self.base (new_exp) def extract_additively(self, c): """Return self - c if it's possible to subtract c from self and make all matching coefficients move towards zero, else return None. Examples ======== >>> from sympy.abc import x, y >>> e = 2x + 3 >>> e.extract_additively(x + 1) x + 2 >>> e.extract_additively(3x) >>> e.extract_additively(4) >>> (y(x + 1)).extract_additively(x + 1) >>> ((x + 1)(x + 2y + 1) + 3).extract_additively(x + 1) (x + 1)(x + 2y) + 3 Sometimes auto-expansion will return a less simplified result than desired; gcd_terms might be used in such cases: >>> from sympy import gcd_terms >>> (4x(y + 1) + y).extract_additively(x) 4x(y + 1) + x(4y + 3) - x(4y + 4) + y >>> gcd_terms(_) x(4y + 3) + y See Also ======== extract_multiplicatively coeff as_coefficient """ c = sympify(c) if self is S.NaN: return None if c is S.Zero: return self elif c == self: return S.Zero elif self is S.Zero: return None if self.is_Number: if not c.is_Number: return None co = self diff = co - c # XXX should we match types? i.e should 3 - .1 succeed? if (co > 0 and diff > 0 and diff < co or co < 0 and diff < 0 and diff > co): return diff return None if c.is_Number: co, t = self.as_coeff_Add() xa = co.extract_additively(c) if xa is None: return None return xa + t # handle the args[0].is_Number case separately # since we will have trouble looking for the coeff of # a number. if c.is_Add and c.args[0].is_Number: # whole term as a term factor co = self.coeff(c) xa0 = (co.extract_additively(1) or 0)c if xa0: diff = self - coc return (xa0 + (diff.extract_additively(c) or diff)) or None # term-wise h, t = c.as_coeff_Add() sh, st = self.as_coeff_Add() xa = sh.extract_additively(h) if xa is None: return None xa2 = st.extract_additively(t) if xa2 is None: return None return xa + xa2 # whole term as a term factor co = self.coeff(c) xa0 = (co.extract_additively(1) or 0)c if xa0: diff = self - coc return (xa0 + (diff.extract_additively(c) or diff)) or None # term-wise coeffs = [] for a in Add.make_args(c): ac, at = a.as_coeff_Mul() co = self.coeff(at) if not co: return None coc, cot = co.as_coeff_Add() xa = coc.extract_additively(ac) if xa is None: return None self -= coat coeffs.append((cot + xa)at) coeffs.append(self) return Add(coeffs) @property def expr_free_symbols(self): """ Like ``free_symbols``, but returns the free symbols only if they are contained in an expression node. Examples ======== >>> from sympy.abc import x, y >>> (x + y).expr_free_symbols {x, y} If the expression is contained in a non-expression object, don't return the free symbols. Compare: >>> from sympy import Tuple >>> t = Tuple(x + y) >>> t.expr_free_symbols set() >>> t.free_symbols {x, y} """ return {j for i in self.args for j in i.expr_free_symbols} def could_extract_minus_sign(self): """Return True if self is not in a canonical form with respect to its sign. For most expressions, e, there will be a difference in e and -e. When there is, True will be returned for one and False for the other; False will be returned if there is no difference. Examples ======== >>> from sympy.abc import x, y >>> e = x - y >>> {i.could_extract_minus_sign() for i in (e, -e)} {False, True} """ negative_self = -self if self == negative_self: return False # e.g. zoox == -zoox self_has_minus = (self.extract_multiplicatively(-1) is not None) negative_self_has_minus = ( (negative_self).extract_multiplicatively(-1) is not None) if self_has_minus != negative_self_has_minus: return self_has_minus else: if self.is_Add: # We choose the one with less arguments with minus signs all_args = len(self.args) negative_args = len([False for arg in self.args if arg.could_extract_minus_sign()]) positive_args = all_args - negative_args if positive_args > negative_args: return False elif positive_args < negative_args: return True elif self.is_Mul: # We choose the one with an odd number of minus signs num, den = self.as_numer_denom() args = Mul.make_args(num) + Mul.make_args(den) arg_signs = [arg.could_extract_minus_sign() for arg in args] negative_args = list(filter(None, arg_signs)) return len(negative_args) % 2 == 1 # As a last resort, we choose the one with greater value of .sort_key() return bool(self.sort_key() < negative_self.sort_key()) def extract_branch_factor(self, allow_half=False): """ Try to write self as ``exp_polar(2piIn)z`` in a nice way. Return (z, n). >>> from sympy import exp_polar, I, pi >>> from sympy.abc import x, y >>> exp_polar(Ipi).extract_branch_factor() (exp_polar(Ipi), 0) >>> exp_polar(2Ipi).extract_branch_factor() (1, 1) >>> exp_polar(-piI).extract_branch_factor() (exp_polar(Ipi), -1) >>> exp_polar(3piI + x).extract_branch_factor() (exp_polar(x + Ipi), 1) >>> (yexp_polar(-5piI)exp_polar(3piI + 2pix)).extract_branch_factor() (yexp_polar(2pix), -1) >>> exp_polar(-Ipi/2).extract_branch_factor() (exp_polar(-Ipi/2), 0) If allow_half is True, also extract exp_polar(Ipi): >>> exp_polar(Ipi).extract_branch_factor(allow_half=True) (1, 1/2) >>> exp_polar(2Ipi).extract_branch_factor(allow_half=True) (1, 1) >>> exp_polar(3Ipi).extract_branch_factor(allow_half=True) (1, 3/2) >>> exp_polar(-Ipi).extract_branch_factor(allow_half=True) (1, -1/2) """ from sympy import exp_polar, pi, I, ceiling, Add n = S(0) res = S(1) args = Mul.make_args(self) exps = [] for arg in args: if isinstance(arg, exp_polar): exps += [arg.exp] else: res = arg piimult = S(0) extras = [] while exps: exp = exps.pop() if exp.is_Add: exps += exp.args continue if exp.is_Mul: coeff = exp.as_coefficient(piI) if coeff is not None: piimult += coeff continue extras += [exp] if piimult.is_number: coeff = piimult tail = () else: coeff, tail = piimult.as_coeff_add(piimult.free_symbols) # round down to nearest multiple of 2 branchfact = ceiling(coeff/2 - S(1)/2)2 n += branchfact/2 c = coeff - branchfact if allow_half: nc = c.extract_additively(1) if nc is not None: n += S(1)/2 c = nc newexp = piIAdd(((c, ) + tail)) + Add(extras) if newexp != 0: res = exp_polar(newexp) return res, n def _eval_is_polynomial(self, syms): if self.free_symbols.intersection(syms) == set([]): return True return False def is_polynomial(self, syms): r""" Return True if self is a polynomial in syms and False otherwise. This checks if self is an exact polynomial in syms. This function returns False for expressions that are "polynomials" with symbolic exponents. Thus, you should be able to apply polynomial algorithms to expressions for which this returns True, and Poly(expr, \syms) should work if and only if expr.is_polynomial(\syms) returns True. The polynomial does not have to be in expanded form. If no symbols are given, all free symbols in the expression will be used. This is not part of the assumptions system. You cannot do Symbol('z', polynomial=True). Examples ======== >>> from sympy import Symbol >>> x = Symbol('x') >>> ((x2 + 1)4).is_polynomial(x) True >>> ((x2 + 1)4).is_polynomial() True >>> (2x + 1).is_polynomial(x) False >>> n = Symbol('n', nonnegative=True, integer=True) >>> (xn + 1).is_polynomial(x) False This function does not attempt any nontrivial simplifications that may result in an expression that does not appear to be a polynomial to become one. >>> from sympy import sqrt, factor, cancel >>> y = Symbol('y', positive=True) >>> a = sqrt(y2 + 2y + 1) >>> a.is_polynomial(y) False >>> factor(a) y + 1 >>> factor(a).is_polynomial(y) True >>> b = (y*2 + 2y + 1)/(y + 1) >>> b.is_polynomial(y) False >>> cancel(b) y + 1 >>> cancel(b).is_polynomial(y) True See also .is_rational_function() """ if syms: syms = set(map(sympify, syms)) else: syms = self.free_symbols if syms.intersection(self.free_symbols) == set([]): # constant polynomial return True else: return self._eval_is_polynomial(syms) def _eval_is_rational_function(self, syms): if self.free_symbols.intersection(syms) == set([]): return True return False def is_rational_function(self, syms): """ Test whether function is a ratio of two polynomials in the given symbols, syms. When syms is not given, all free symbols will be used. The rational function does not have to be in expanded or in any kind of canonical form. This function returns False for expressions that are "rational functions" with symbolic exponents. Thus, you should be able to call .as_numer_denom() and apply polynomial algorithms to the result for expressions for which this returns True. This is not part of the assumptions system. You cannot do Symbol('z', rational_function=True). Examples ======== >>> from sympy import Symbol, sin >>> from sympy.abc import x, y >>> (x/y).is_rational_function() True >>> (x2).is_rational_function() True >>> (x/sin(y)).is_rational_function(y) False >>> n = Symbol('n', integer=True) >>> (xn + 1).is_rational_function(x) False This function does not attempt any nontrivial simplifications that may result in an expression that does not appear to be a rational function to become one. >>> from sympy import sqrt, factor >>> y = Symbol('y', positive=True) >>> a = sqrt(y2 + 2y + 1)/y >>> a.is_rational_function(y) False >>> factor(a) (y + 1)/y >>> factor(a).is_rational_function(y) True See also is_algebraic_expr(). """ if self in [S.NaN, S.Infinity, -S.Infinity, S.ComplexInfinity]: return False if syms: syms = set(map(sympify, syms)) else: syms = self.free_symbols if syms.intersection(self.free_symbols) == set([]): # constant rational function return True else: return self._eval_is_rational_function(syms) def _eval_is_algebraic_expr(self, syms): if self.free_symbols.intersection(syms) == set([]): return True return False def is_algebraic_expr(self, syms): """ This tests whether a given expression is algebraic or not, in the given symbols, syms. When syms is not given, all free symbols will be used. The rational function does not have to be in expanded or in any kind of canonical form. This function returns False for expressions that are "algebraic expressions" with symbolic exponents. This is a simple extension to the is_rational_function, including rational exponentiation. Examples ======== >>> from sympy import Symbol, sqrt >>> x = Symbol('x', real=True) >>> sqrt(1 + x).is_rational_function() False >>> sqrt(1 + x).is_algebraic_expr() True This function does not attempt any nontrivial simplifications that may result in an expression that does not appear to be an algebraic expression to become one. >>> from sympy import exp, factor >>> a = sqrt(exp(x)2 + 2exp(x) + 1)/(exp(x) + 1) >>> a.is_algebraic_expr(x) False >>> factor(a).is_algebraic_expr() True See Also ======== is_rational_function() References ========== - https://en.wikipedia.org/wiki/Algebraic_expression """ if syms: syms = set(map(sympify, syms)) else: syms = self.free_symbols if syms.intersection(self.free_symbols) == set([]): # constant algebraic expression return True else: return self._eval_is_algebraic_expr(syms) ################################################################################### ##################### SERIES, LEADING TERM, LIMIT, ORDER METHODS ################## ################################################################################### def series(self, x=None, x0=0, n=6, dir="+", logx=None): """ Series expansion of "self" around ``x = x0`` yielding either terms of the series one by one (the lazy series given when n=None), else all the terms at once when n != None. Returns the series expansion of "self" around the point ``x = x0`` with respect to ``x`` up to ``O((x - x0)n, x, x0)`` (default n is 6). If ``x=None`` and ``self`` is univariate, the univariate symbol will be supplied, otherwise an error will be raised. >>> from sympy import cos, exp >>> from sympy.abc import x, y >>> cos(x).series() 1 - x2/2 + x4/24 + O(x6) >>> cos(x).series(n=4) 1 - x2/2 + O(x4) >>> cos(x).series(x, x0=1, n=2) cos(1) - (x - 1)sin(1) + O((x - 1)2, (x, 1)) >>> e = cos(x + exp(y)) >>> e.series(y, n=2) cos(x + 1) - ysin(x + 1) + O(y*2) >>> e.series(x, n=2) cos(exp(y)) - xsin(exp(y)) + O(x2) If ``n=None`` then a generator of the series terms will be returned. >>> term=cos(x).series(n=None) >>> [next(term) for i in range(2)] [1, -x2/2] For ``dir=+`` (default) the series is calculated from the right and for ``dir=-`` the series from the left. For smooth functions this flag will not alter the results. >>> abs(x).series(dir="+") x >>> abs(x).series(dir="-") -x """ from sympy import collect, Dummy, Order, Rational, Symbol, ceiling if x is None: syms = self.free_symbols if not syms: return self elif len(syms) > 1: raise ValueError('x must be given for multivariate functions.') x = syms.pop() if isinstance(x, Symbol): dep = x in self.free_symbols else: d = Dummy() dep = d in self.xreplace({x: d}).free_symbols if not dep: if n is None: return (s for s in [self]) else: return self if len(dir) != 1 or dir not in '+-': raise ValueError("Dir must be '+' or '-'") if x0 in [S.Infinity, S.NegativeInfinity]: sgn = 1 if x0 is S.Infinity else -1 s = self.subs(x, sgn/x).series(x, n=n, dir='+') if n is None: return (si.subs(x, sgn/x) for si in s) return s.subs(x, sgn/x) # use rep to shift origin to x0 and change sign (if dir is negative) # and undo the process with rep2 if x0 or dir == '-': if dir == '-': rep = -x + x0 rep2 = -x rep2b = x0 else: rep = x + x0 rep2 = x rep2b = -x0 s = self.subs(x, rep).series(x, x0=0, n=n, dir='+', logx=logx) if n is None: # lseries... return (si.subs(x, rep2 + rep2b) for si in s) return s.subs(x, rep2 + rep2b) # from here on it's x0=0 and dir='+' handling if x.is_positive is x.is_negative is None or x.is_Symbol is not True: # replace x with an x that has a positive assumption xpos = Dummy('x', positive=True, finite=True) rv = self.subs(x, xpos).series(xpos, x0, n, dir, logx=logx) if n is None: return (s.subs(xpos, x) for s in rv) else: return rv.subs(xpos, x) if n is not None: # nseries handling s1 = self._eval_nseries(x, n=n, logx=logx) o = s1.getO() or S.Zero if o: # make sure the requested order is returned ngot = o.getn() if ngot > n: # leave o in its current form (e.g. with xlog(x)) so # it eats terms properly, then replace it below if n != 0: s1 += o.subs(x, xRational(n, ngot)) else: s1 += Order(1, x) elif ngot < n: # increase the requested number of terms to get the desired # number keep increasing (up to 9) until the received order # is different than the original order and then predict how # many additional terms are needed for more in range(1, 9): s1 = self._eval_nseries(x, n=n + more, logx=logx) newn = s1.getn() if newn != ngot: ndo = n + ceiling((n - ngot)more/(newn - ngot)) s1 = self._eval_nseries(x, n=ndo, logx=logx) while s1.getn() < n: s1 = self._eval_nseries(x, n=ndo, logx=logx) ndo += 1 break else: raise ValueError('Could not calculate %s terms for %s' % (str(n), self)) s1 += Order(xn, x) o = s1.getO() s1 = s1.removeO() else: o = Order(xn, x) s1done = s1.doit() if (s1done + o).removeO() == s1done: o = S.Zero try: return collect(s1, x) + o except NotImplementedError: return s1 + o else: # lseries handling def yield_lseries(s): """Return terms of lseries one at a time.""" for si in s: if not si.is_Add: yield si continue # yield terms 1 at a time if possible # by increasing order until all the # terms have been returned yielded = 0 o = Order(si, x)x ndid = 0 ndo = len(si.args) while 1: do = (si - yielded + o).removeO() o = x if not do or do.is_Order: continue if do.is_Add: ndid += len(do.args) else: ndid += 1 yield do if ndid == ndo: break yielded += do return yield_lseries(self.removeO()._eval_lseries(x, logx=logx)) def taylor_term(self, n, x, previous_terms): """General method for the taylor term. This method is slow, because it differentiates n-times. Subclasses can redefine it to make it faster by using the "previous_terms". """ from sympy import Dummy, factorial x = sympify(x) _x = Dummy('x') return self.subs(x, _x).diff(_x, n).subs(_x, x).subs(x, 0) xn / factorial(n) def lseries(self, x=None, x0=0, dir='+', logx=None): """ Wrapper for series yielding an iterator of the terms of the series. Note: an infinite series will yield an infinite iterator. The following, for exaxmple, will never terminate. It will just keep printing terms of the sin(x) series:: for term in sin(x).lseries(x): print term The advantage of lseries() over nseries() is that many times you are just interested in the next term in the series (i.e. the first term for example), but you don't know how many you should ask for in nseries() using the "n" parameter. See also nseries(). """ return self.series(x, x0, n=None, dir=dir, logx=logx) def _eval_lseries(self, x, logx=None): # default implementation of lseries is using nseries(), and adaptively # increasing the "n". As you can see, it is not very efficient, because # we are calculating the series over and over again. Subclasses should # override this method and implement much more efficient yielding of # terms. n = 0 series = self._eval_nseries(x, n=n, logx=logx) if not series.is_Order: if series.is_Add: yield series.removeO() else: yield series return while series.is_Order: n += 1 series = self._eval_nseries(x, n=n, logx=logx) e = series.removeO() yield e while 1: while 1: n += 1 series = self._eval_nseries(x, n=n, logx=logx).removeO() if e != series: break yield series - e e = series def nseries(self, x=None, x0=0, n=6, dir='+', logx=None): """ Wrapper to _eval_nseries if assumptions allow, else to series. If x is given, x0 is 0, dir='+', and self has x, then _eval_nseries is called. This calculates "n" terms in the innermost expressions and then builds up the final series just by "cross-multiplying" everything out. The optional ``logx`` parameter can be used to replace any log(x) in the returned series with a symbolic value to avoid evaluating log(x) at 0. A symbol to use in place of log(x) should be provided. Advantage -- it's fast, because we don't have to determine how many terms we need to calculate in advance. Disadvantage -- you may end up with less terms than you may have expected, but the O(xn) term appended will always be correct and so the result, though perhaps shorter, will also be correct. If any of those assumptions is not met, this is treated like a wrapper to series which will try harder to return the correct number of terms. See also lseries(). Examples ======== >>> from sympy import sin, log, Symbol >>> from sympy.abc import x, y >>> sin(x).nseries(x, 0, 6) x - x3/6 + x5/120 + O(x6) >>> log(x+1).nseries(x, 0, 5) x - x2/2 + x3/3 - x4/4 + O(x5) Handling of the ``logx`` parameter --- in the following example the expansion fails since ``sin`` does not have an asymptotic expansion at -oo (the limit of log(x) as x approaches 0): >>> e = sin(log(x)) >>> e.nseries(x, 0, 6) Traceback (most recent call last): ... PoleError: ... ... >>> logx = Symbol('logx') >>> e.nseries(x, 0, 6, logx=logx) sin(logx) In the following example, the expansion works but gives only an Order term unless the ``logx`` parameter is used: >>> e = xy >>> e.nseries(x, 0, 2) O(log(x)*2) >>> e.nseries(x, 0, 2, logx=logx) exp(logxy) """ if x and not x in self.free_symbols: return self if x is None or x0 or dir != '+': # {see XPOS above} or (x.is_positive == x.is_negative == None): return self.series(x, x0, n, dir) else: return self._eval_nseries(x, n=n, logx=logx) def _eval_nseries(self, x, n, logx): """ Return terms of series for self up to O(xn) at x=0 from the positive direction. This is a method that should be overridden in subclasses. Users should never call this method directly (use .nseries() instead), so you don't have to write docstrings for _eval_nseries(). """ from sympy.utilities.misc import filldedent raise NotImplementedError(filldedent(""" The _eval_nseries method should be added to %s to give terms up to O(xn) at x=0 from the positive direction so it is available when nseries calls it.""" % self.func) ) def limit(self, x, xlim, dir='+'): """ Compute limit x->xlim. """ from sympy.series.limits import limit return limit(self, x, xlim, dir) def compute_leading_term(self, x, logx=None): """ as_leading_term is only allowed for results of .series() This is a wrapper to compute a series first. """ from sympy import Dummy, log from sympy.series.gruntz import calculate_series if self.removeO() == 0: return self if logx is None: d = Dummy('logx') s = calculate_series(self, x, d).subs(d, log(x)) else: s = calculate_series(self, x, logx) return s.as_leading_term(x) @cacheit def as_leading_term(self, symbols): """ Returns the leading (nonzero) term of the series expansion of self. The _eval_as_leading_term routines are used to do this, and they must always return a non-zero value. Examples ======== >>> from sympy.abc import x >>> (1 + x + x2).as_leading_term(x) 1 >>> (1/x2 + x + x2).as_leading_term(x) x(-2) """ from sympy import powsimp if len(symbols) > 1: c = self for x in symbols: c = c.as_leading_term(x) return c elif not symbols: return self x = sympify(symbols[0]) if not x.is_symbol: raise ValueError('expecting a Symbol but got %s' % x) if x not in self.free_symbols: return self obj = self._eval_as_leading_term(x) if obj is not None: return powsimp(obj, deep=True, combine='exp') raise NotImplementedError('as_leading_term(%s, %s)' % (self, x)) def _eval_as_leading_term(self, x): return self def as_coeff_exponent(self, x): """ ``cx*e -> c,e`` where x can be any symbolic expression. """ from sympy import collect s = collect(self, x) c, p = s.as_coeff_mul(x) if len(p) == 1: b, e = p[0].as_base_exp() if b == x: return c, e return s, S.Zero def leadterm(self, x): """ Returns the leading term axb as a tuple (a, b). Examples ======== >>> from sympy.abc import x >>> (1+x+x2).leadterm(x) (1, 0) >>> (1/x2+x+x2).leadterm(x) (1, -2) """ from sympy import Dummy, log l = self.as_leading_term(x) d = Dummy('logx') if l.has(log(x)): l = l.subs(log(x), d) c, e = l.as_coeff_exponent(x) if x in c.free_symbols: from sympy.utilities.misc import filldedent raise ValueError(filldedent(""" cannot compute leadterm(%s, %s). The coefficient should have been free of x but got %s""" % (self, x, c))) c = c.subs(d, log(x)) return c, e def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ return S.One, self def as_coeff_Add(self, rational=False): """Efficiently extract the coefficient of a summation. """ return S.Zero, self def fps(self, x=None, x0=0, dir=1, hyper=True, order=4, rational=True, full=False): """ Compute formal power power series of self. See the docstring of the :func:`fps` function in sympy.series.formal for more information. """ from sympy.series.formal import fps return fps(self, x, x0, dir, hyper, order, rational, full) def fourier_series(self, limits=None): """Compute fourier sine/cosine series of self. See the docstring of the :func:`fourier_series` in sympy.series.fourier for more information. """ from sympy.series.fourier import fourier_series return fourier_series(self, limits) ################################################################################### ##################### DERIVATIVE, INTEGRAL, FUNCTIONAL METHODS #################### ################################################################################### def diff(self, symbols, assumptions): assumptions.setdefault("evaluate", True) return Derivative(self, symbols, assumptions) ########################################################################### ###################### EXPRESSION EXPANSION METHODS ####################### ########################################################################### # Relevant subclasses should override _eval_expand_hint() methods. See # the docstring of expand() for more info. def _eval_expand_complex(self, hints): real, imag = self.as_real_imag(*hints) return real + S.ImaginaryUnitimag @staticmethod def _expand_hint(expr, hint, deep=True, hints): """ Helper for ``expand()``. Recursively calls ``expr._eval_expand_hint()``. Returns ``(expr, hit)``, where expr is the (possibly) expanded ``expr`` and ``hit`` is ``True`` if ``expr`` was truly expanded and ``False`` otherwise. """ hit = False # XXX: Hack to support non-Basic args # \| # V if deep and getattr(expr, 'args', ()) and not expr.is_Atom: sargs = [] for arg in expr.args: arg, arghit = Expr._expand_hint(arg, hint, hints) hit \|= arghit sargs.append(arg) if hit: expr = expr.func(sargs) if hasattr(expr, hint): newexpr = getattr(expr, hint)(hints) if newexpr != expr: return (newexpr, True) return (expr, hit) @cacheit def expand(self, deep=True, modulus=None, power_base=True, power_exp=True, mul=True, log=True, multinomial=True, basic=True, hints): """ Expand an expression using hints. See the docstring of the expand() function in sympy.core.function for more information. """ from sympy.simplify.radsimp import fraction hints.update(power_base=power_base, power_exp=power_exp, mul=mul, log=log, multinomial=multinomial, basic=basic) expr = self if hints.pop('frac', False): n, d = [a.expand(deep=deep, modulus=modulus, hints) for a in fraction(self)] return n/d elif hints.pop('denom', False): n, d = fraction(self) return n/d.expand(deep=deep, modulus=modulus, hints) elif hints.pop('numer', False): n, d = fraction(self) return n.expand(deep=deep, modulus=modulus, hints)/d # Although the hints are sorted here, an earlier hint may get applied # at a given node in the expression tree before another because of how # the hints are applied. e.g. expand(log(x(y + z))) -> log(xy + # xz) because while applying log at the top level, log and mul are # applied at the deeper level in the tree so that when the log at the # upper level gets applied, the mul has already been applied at the # lower level. # Additionally, because hints are only applied once, the expression # may not be expanded all the way. For example, if mul is applied # before multinomial, x(x + 1)2 won't be expanded all the way. For # now, we just use a special case to make multinomial run before mul, # so that at least polynomials will be expanded all the way. In the # future, smarter heuristics should be applied. # TODO: Smarter heuristics def _expand_hint_key(hint): """Make multinomial come before mul""" if hint == 'mul': return 'mulz' return hint for hint in sorted(hints.keys(), key=_expand_hint_key): use_hint = hints[hint] if use_hint: hint = '_eval_expand_' + hint expr, hit = Expr._expand_hint(expr, hint, deep=deep, hints) while True: was = expr if hints.get('multinomial', False): expr, _ = Expr._expand_hint( expr, '_eval_expand_multinomial', deep=deep, hints) if hints.get('mul', False): expr, _ = Expr._expand_hint( expr, '_eval_expand_mul', deep=deep, hints) if hints.get('log', False): expr, _ = Expr._expand_hint( expr, '_eval_expand_log', deep=deep, hints) if expr == was: break if modulus is not None: modulus = sympify(modulus) if not modulus.is_Integer or modulus <= 0: raise ValueError( "modulus must be a positive integer, got %s" % modulus) terms = [] for term in Add.make_args(expr): coeff, tail = term.as_coeff_Mul(rational=True) coeff %= modulus if coeff: terms.append(coefftail) expr = Add(terms) return expr ########################################################################### ################### GLOBAL ACTION VERB WRAPPER METHODS #################### ########################################################################### def integrate(self, args, *kwargs): """See the integrate function in sympy.integrals""" from sympy.integrals import integrate return integrate(self, args, *kwargs) def simplify(self, ratio=1.7, measure=None, rational=False, inverse=False): """See the simplify function in sympy.simplify""" from sympy.simplify import simplify from sympy.core.function import count_ops measure = measure or count_ops return simplify(self, ratio, measure) def nsimplify(self, constants=[], tolerance=None, full=False): """See the nsimplify function in sympy.simplify""" from sympy.simplify import nsimplify return nsimplify(self, constants, tolerance, full) def separate(self, deep=False, force=False): """See the separate function in sympy.simplify""" from sympy.core.function import expand_power_base return expand_power_base(self, deep=deep, force=force) def collect(self, syms, func=None, evaluate=True, exact=False, distribute_order_term=True): """See the collect function in sympy.simplify""" from sympy.simplify import collect return collect(self, syms, func, evaluate, exact, distribute_order_term) def together(self, args, *kwargs): """See the together function in sympy.polys""" from sympy.polys import together return together(self, args, kwargs) def apart(self, x=None, args): """See the apart function in sympy.polys""" from sympy.polys import apart return apart(self, x, args) def ratsimp(self): """See the ratsimp function in sympy.simplify""" from sympy.simplify import ratsimp return ratsimp(self) def trigsimp(self, args): """See the trigsimp function in sympy.simplify""" from sympy.simplify import trigsimp return trigsimp(self, args) def radsimp(self, kwargs): """See the radsimp function in sympy.simplify""" from sympy.simplify import radsimp return radsimp(self, *kwargs) def powsimp(self, args, *kwargs): """See the powsimp function in sympy.simplify""" from sympy.simplify import powsimp return powsimp(self, args, *kwargs) def combsimp(self): """See the combsimp function in sympy.simplify""" from sympy.simplify import combsimp return combsimp(self) def gammasimp(self): """See the gammasimp function in sympy.simplify""" from sympy.simplify import gammasimp return gammasimp(self) def factor(self, gens, *args): """See the factor() function in sympy.polys.polytools""" from sympy.polys import factor return factor(self, gens, *args) def refine(self, assumption=True): """See the refine function in sympy.assumptions""" from sympy.assumptions import refine return refine(self, assumption) def cancel(self, gens, *args): """See the cancel function in sympy.polys""" from sympy.polys import cancel return cancel(self, gens, *args) def invert(self, g, gens, *args): """Return the multiplicative inverse of ``self`` mod ``g`` where ``self`` (and ``g``) may be symbolic expressions). See Also ======== sympy.core.numbers.mod_inverse, sympy.polys.polytools.invert """ from sympy.polys.polytools import invert from sympy.core.numbers import mod_inverse if self.is_number and getattr(g, 'is_number', True): return mod_inverse(self, g) return invert(self, g, gens, *args) def round(self, n=None): """Return x rounded to the given decimal place. If a complex number would results, apply round to the real and imaginary components of the number. Examples ======== >>> from sympy import pi, E, I, S, Add, Mul, Number >>> pi.round() 3 >>> pi.round(2) 3.14 >>> (2pi + EI).round() 6 + 3I The round method has a chopping effect: >>> (2pi + I/10).round() 6 >>> (pi/10 + 2I).round() 2I >>> (pi/10 + EI).round(2) 0.31 + 2.72I Notes ===== The Python builtin function, round, always returns a float in Python 2 while the SymPy round method (and round with a Number argument in Python 3) returns a Number. >>> from sympy.core.compatibility import PY3 >>> isinstance(round(S(123), -2), Number if PY3 else float) True For a consistent behavior, and Python 3 rounding rules, import `round` from sympy.core.compatibility. >>> from sympy.core.compatibility import round >>> isinstance(round(S(123), -2), Number) True """ from sympy.core.power import integer_log from sympy.core.numbers import Float x = self if not x.is_number: raise TypeError("can't round symbolic expression") if not x.is_Atom: if not pure_complex(x.n(2), or_real=True): raise TypeError( 'Expected a number but got %s:' % func_name(x)) elif x in (S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity): return x if not x.is_real: i, r = x.as_real_imag() return i.round(n) + S.ImaginaryUnitr.round(n) if not x: return S.Zero if n is None else x p = as_int(n or 0) if x.is_Integer: # XXX return Integer(round(int(x), p)) when Py2 is dropped if p >= 0: return x m = 10*-p i, r = divmod(abs(x), m) if i%2 and 2r == m: i += 1 elif 2r > m: i += 1 if x < 0: i = -1 return im digits_to_decimal = _mag(x) allow = digits_needed = digits_to_decimal + p precs = [f._prec for f in x.atoms(Float)] dps = prec_to_dps(max(precs)) if precs else None if dps is None: # assume everything is exact so use the Python # float default or whatever was requested dps = max(15, allow) else: allow = min(allow, dps) # this will shift all digits to right of decimal # and give us dps to work with as an int shift = -digits_to_decimal + dps extra = 1 # how far we look past known digits # NOTE # mpmath will calculate the binary representation to # an arbitrary number of digits but we must base our # answer on a finite number of those digits, e.g. # .575 2589569785738035/252 in binary. # mpmath shows us that the first 18 digits are # >>> Float(.575).n(18) # 0.574999999999999956 # The default precision is 15 digits and if we ask # for 15 we get # >>> Float(.575).n(15) # 0.575000000000000 # mpmath handles rounding at the 15th digit. But we # need to be careful since the user might be asking # for rounding at the last digit and our semantics # are to round toward the even final digit when there # is a tie. So the extra digit will be used to make # that decision. In this case, the value is the same # to 15 digits: # >>> Float(.575).n(16) # 0.5750000000000000 # Now converting this to the 15 known digits gives # 575000000000000.0 # which rounds to integer # 5750000000000000 # And now we can round to the desired digt, e.g. at # the second from the left and we get # 5800000000000000 # and rescaling that gives # 0.58 # as the final result. # If the value is made slightly less than 0.575 we might # still obtain the same value: # >>> Float(.575-1e-16).n(16)10*15 # 574999999999999.8 # What 15 digits best represents the known digits (which are # to the left of the decimal? 5750000000000000, the same as # before. The only way we will round down (in this case) is # if we declared that we had more than 15 digits of precision. # For example, if we use 16 digits of precision, the integer # we deal with is # >>> Float(.575-1e-16).n(17)10*16 # 5749999999999998.4 # and this now rounds to 5749999999999998 and (if we round to # the 2nd digit from the left) we get 5700000000000000. # xf = x.n(dps + extra)Pow(10, shift) xi = Integer(xf) # use the last digit to select the value of xi # nearest to x before rounding at the desired digit sign = 1 if x > 0 else -1 dif2 = sign(xf - xi).n(extra) if dif2 < 0: raise NotImplementedError( 'not expecting int(x) to round away from 0') if dif2 > .5: xi += sign # round away from 0 elif dif2 == .5: xi += sign if xi%2 else -sign # round toward even # shift p to the new position ip = p - shift # let Python handle the int rounding then rescale xr = xi.round(ip) # when Py2 is drop make this round(xi.p, ip) # restore scale rv = Rational(xr, Pow(10, shift)) # return Float or Integer if rv.is_Integer: if n is None: # the single-arg case return rv # use str or else it won't be a float return Float(str(rv), digits_needed) else: if not allow and rv > self: allow += 1 return Float(rv, allow) __round__ = round def _eval_derivative_matrix_lines(self, x): from sympy.matrices.expressions.matexpr import _LeftRightArgs return [_LeftRightArgs([S.One, S.One], higher=self._eval_derivative(x))] class AtomicExpr(Atom, Expr): """ A parent class for object which are both atoms and Exprs. For example: Symbol, Number, Rational, Integer, ... But not: Add, Mul, Pow, ... """ is_number = False is_Atom = True __slots__ = [] def _eval_derivative(self, s): if self == s: return S.One return S.Zero def _eval_derivative_n_times(self, s, n): from sympy import Piecewise, Eq from sympy import Tuple, MatrixExpr from sympy.matrices.common import MatrixCommon if isinstance(s, (MatrixCommon, Tuple, Iterable, MatrixExpr)): return super(AtomicExpr, self)._eval_derivative_n_times(s, n) if self == s: return Piecewise((self, Eq(n, 0)), (1, Eq(n, 1)), (0, True)) else: return Piecewise((self, Eq(n, 0)), (0, True)) def _eval_is_polynomial(self, syms): return True def _eval_is_rational_function(self, syms): return True def _eval_is_algebraic_expr(self, syms): return True def _eval_nseries(self, x, n, logx): return self @property def expr_free_symbols(self): return {self} def _mag(x): """Return integer ``i`` such that .1 <= x/10i < 1 Examples ======== >>> from sympy.core.expr import _mag >>> from sympy import Float >>> _mag(Float(.1)) 0 >>> _mag(Float(.01)) -1 >>> _mag(Float(1234)) 4 """ from math import log10, ceil, log from sympy import Float xpos = abs(x.n()) if not xpos: return S.Zero try: mag_first_dig = int(ceil(log10(xpos))) except (ValueError, OverflowError): mag_first_dig = int(ceil(Float(mpf_log(xpos._mpf_, 53))/log(10))) # check that we aren't off by 1 if (xpos/10mag_first_dig) >= 1: assert 1 <= (xpos/10mag_first_dig) < 10 mag_first_dig += 1 return mag_first_dig class UnevaluatedExpr(Expr): """ Expression that is not evaluated unless released. Examples ======== >>> from sympy import UnevaluatedExpr >>> from sympy.abc import a, b, x, y >>> x(1/x) 1 >>> xUnevaluatedExpr(1/x) x1/x """ def __new__(cls, arg, kwargs): arg = _sympify(arg) obj = Expr.__new__(cls, arg, kwargs) return obj def doit(self, kwargs): if kwargs.get("deep", True): return self.args[0].doit(kwargs) else: return self.args[0] def _n2(a, b): """Return (a - b).evalf(2) if a and b are comparable, else None. This should only be used when a and b are already sympified. """ # /!\ it is very important (see issue 8245) not to # use a re-evaluated number in the calculation of dif if a.is_comparable and b.is_comparable: dif = (a - b).evalf(2) if dif.is_comparable: return dif def unchanged(func, args): """Return True if `func` applied to the `args` is unchanged. Can be used instead of `assert foo == foo`. Examples ======== >>> from sympy.core.expr import unchanged >>> from sympy.functions.elementary.trigonometric import cos >>> from sympy.core.numbers import pi >>> unchanged(cos, 1) # instead of assert cos(1) == cos(1) True >>> unchanged(cos, pi) False """ f = func(args) return f.func == func and f.args == tuple([sympify(a) for a in args]) class ExprBuilder(object): def __init__(self, op, args=[], validator=None, check=True): if not hasattr(op, "__call__"): raise TypeError("op {} needs to be callable".format(op)) self.op = op self.args = args self.validator = validator if (validator is not None) and check: self.validate() @staticmethod def _build_args(args): return [i.build() if isinstance(i, ExprBuilder) else i for i in args] def validate(self): if self.validator is None: return args = self._build_args(self.args) self.validator(args) def build(self, check=True): args = self._build_args(self.args) if self.validator and check: self.validator(args) return self.op(args) def append_argument(self, arg, check=True): self.args.append(arg) if self.validator and check: self.validate(self.args) def __getitem__(self, item): if item == 0: return self.op else: return self.args[item-1] def __repr__(self): return str(self.build()) def search_element(self, elem): for i, arg in enumerate(self.args): if isinstance(arg, ExprBuilder): ret = arg.search_index(elem) if ret is not None: return (i,) + ret elif id(arg) == id(elem): return (i,) return None from .mul import Mul from .add import Add from .power import Pow from .function import Derivative, Function from .mod import Mod from .exprtools import factor_terms from .numbers import Integer, Rational
4f40d9dfe729e1798baaac412c8466a10a6609fbfbb7d340a02371e0ba62cc96	from __future__ import print_function, division import decimal import fractions import math import re as regex from .containers import Tuple from .sympify import converter, sympify, _sympify, SympifyError, _convert_numpy_types from .singleton import S, Singleton from .expr import Expr, AtomicExpr from .decorators import _sympifyit from .cache import cacheit, clear_cache from .logic import fuzzy_not from sympy.core.compatibility import ( as_int, integer_types, long, string_types, with_metaclass, HAS_GMPY, SYMPY_INTS, int_info) from sympy.core.cache import lru_cache import mpmath import mpmath.libmp as mlib from mpmath.libmp.backend import MPZ from mpmath.libmp import mpf_pow, mpf_pi, mpf_e, phi_fixed from mpmath.ctx_mp import mpnumeric from mpmath.libmp.libmpf import ( finf as _mpf_inf, fninf as _mpf_ninf, fnan as _mpf_nan, fzero as _mpf_zero, _normalize as mpf_normalize, prec_to_dps) from sympy.utilities.misc import debug, filldedent from .evaluate import global_evaluate from sympy.utilities.exceptions import SymPyDeprecationWarning rnd = mlib.round_nearest _LOG2 = math.log(2) def comp(z1, z2, tol=None): """Return a bool indicating whether the error between z1 and z2 is <= tol. If ``tol`` is None then True will be returned if there is a significant difference between the numbers: ``abs(z1 - z2)10p <= 1/2`` where ``p`` is the lower of the precisions of the values. A comparison of strings will be made if ``z1`` is a Number and a) ``z2`` is a string or b) ``tol`` is '' and ``z2`` is a Number. When ``tol`` is a nonzero value, if z2 is non-zero and ``\|z1\| > 1`` the error is normalized by ``\|z1\|``, so if you want to see if the absolute error between ``z1`` and ``z2`` is <= ``tol`` then call this as ``comp(z1 - z2, 0, tol)``. """ if type(z2) is str: if not isinstance(z1, Number): raise ValueError('when z2 is a str z1 must be a Number') return str(z1) == z2 if not z1: z1, z2 = z2, z1 if not z1: return True if not tol: if tol is None: if type(z2) is str and getattr(z1, 'is_Number', False): return str(z1) == z2 a, b = Float(z1), Float(z2) return int(abs(a - b)10*prec_to_dps( min(a._prec, b._prec)))2 <= 1 elif all(getattr(i, 'is_Number', False) for i in (z1, z2)): return z1._prec == z2._prec and str(z1) == str(z2) raise ValueError('exact comparison requires two Numbers') diff = abs(z1 - z2) az1 = abs(z1) if z2 and az1 > 1: return diff/az1 <= tol else: return diff <= tol def mpf_norm(mpf, prec): """Return the mpf tuple normalized appropriately for the indicated precision after doing a check to see if zero should be returned or not when the mantissa is 0. ``mpf_normlize`` always assumes that this is zero, but it may not be since the mantissa for mpf's values "+inf", "-inf" and "nan" have a mantissa of zero, too. Note: this is not intended to validate a given mpf tuple, so sending mpf tuples that were not created by mpmath may produce bad results. This is only a wrapper to ``mpf_normalize`` which provides the check for non- zero mpfs that have a 0 for the mantissa. """ sign, man, expt, bc = mpf if not man: # hack for mpf_normalize which does not do this; # it assumes that if man is zero the result is 0 # (see issue 6639) if not bc: return _mpf_zero else: # don't change anything; this should already # be a well formed mpf tuple return mpf # Necessary if mpmath is using the gmpy backend from mpmath.libmp.backend import MPZ rv = mpf_normalize(sign, MPZ(man), expt, bc, prec, rnd) return rv # TODO: we should use the warnings module _errdict = {"divide": False} def seterr(divide=False): """ Should sympy raise an exception on 0/0 or return a nan? divide == True .... raise an exception divide == False ... return nan """ if _errdict["divide"] != divide: clear_cache() _errdict["divide"] = divide def _as_integer_ratio(p): neg_pow, man, expt, bc = getattr(p, '_mpf_', mpmath.mpf(p)._mpf_) p = [1, -1][neg_pow % 2]man if expt < 0: q = 2-expt else: q = 1 p = 2expt return int(p), int(q) def _decimal_to_Rational_prec(dec): """Convert an ordinary decimal instance to a Rational.""" if not dec.is_finite(): raise TypeError("dec must be finite, got %s." % dec) s, d, e = dec.as_tuple() prec = len(d) if e >= 0: # it's an integer rv = Integer(int(dec)) else: s = (-1)s d = sum([di10i for i, di in enumerate(reversed(d))]) rv = Rational(sd, 10*-e) return rv, prec _floatpat = regex.compile(r"[-+]?((\d\.\d+)\|(\d+\.?))") def _literal_float(f): """Return True if n starts like a floating point number.""" return bool(_floatpat.match(f)) # (a,b) -> gcd(a,b) # TODO caching with decorator, but not to degrade performance @lru_cache(1024) def igcd(args): """Computes nonnegative integer greatest common divisor. The algorithm is based on the well known Euclid's algorithm. To improve speed, igcd() has its own caching mechanism implemented. Examples ======== >>> from sympy.core.numbers import igcd >>> igcd(2, 4) 2 >>> igcd(5, 10, 15) 5 """ if len(args) < 2: raise TypeError( 'igcd() takes at least 2 arguments (%s given)' % len(args)) args_temp = [abs(as_int(i)) for i in args] if 1 in args_temp: return 1 a = args_temp.pop() for b in args_temp: a = igcd2(a, b) if b else a return a try: from math import gcd as igcd2 except ImportError: def igcd2(a, b): """Compute gcd of two Python integers a and b.""" if (a.bit_length() > BIGBITS and b.bit_length() > BIGBITS): return igcd_lehmer(a, b) a, b = abs(a), abs(b) while b: a, b = b, a % b return a # Use Lehmer's algorithm only for very large numbers. # The limit could be different on Python 2.7 and 3.x. # If so, then this could be defined in compatibility.py. BIGBITS = 5000 def igcd_lehmer(a, b): """Computes greatest common divisor of two integers. Euclid's algorithm for the computation of the greatest common divisor gcd(a, b) of two (positive) integers a and b is based on the division identity a = qb + r, where the quotient q and the remainder r are integers and 0 <= r < b. Then each common divisor of a and b divides r, and it follows that gcd(a, b) == gcd(b, r). The algorithm works by constructing the sequence r0, r1, r2, ..., where r0 = a, r1 = b, and each rn is the remainder from the division of the two preceding elements. In Python, q = a // b and r = a % b are obtained by the floor division and the remainder operations, respectively. These are the most expensive arithmetic operations, especially for large a and b. Lehmer's algorithm is based on the observation that the quotients qn = r(n-1) // rn are in general small integers even when a and b are very large. Hence the quotients can be usually determined from a relatively small number of most significant bits. The efficiency of the algorithm is further enhanced by not computing each long remainder in Euclid's sequence. The remainders are linear combinations of a and b with integer coefficients derived from the quotients. The coefficients can be computed as far as the quotients can be determined from the chosen most significant parts of a and b. Only then a new pair of consecutive remainders is computed and the algorithm starts anew with this pair. References ========== .. [1] https://en.wikipedia.org/wiki/Lehmer%27s_GCD_algorithm """ a, b = abs(as_int(a)), abs(as_int(b)) if a < b: a, b = b, a # The algorithm works by using one or two digit division # whenever possible. The outer loop will replace the # pair (a, b) with a pair of shorter consecutive elements # of the Euclidean gcd sequence until a and b # fit into two Python (long) int digits. nbits = 2int_info.bits_per_digit while a.bit_length() > nbits and b != 0: # Quotients are mostly small integers that can # be determined from most significant bits. n = a.bit_length() - nbits x, y = int(a >> n), int(b >> n) # most significant bits # Elements of the Euclidean gcd sequence are linear # combinations of a and b with integer coefficients. # Compute the coefficients of consecutive pairs # a' = Aa + Bb, b' = Ca + Db # using small integer arithmetic as far as possible. A, B, C, D = 1, 0, 0, 1 # initial values while True: # The coefficients alternate in sign while looping. # The inner loop combines two steps to keep track # of the signs. # At this point we have # A > 0, B <= 0, C <= 0, D > 0, # x' = x + B <= x < x" = x + A, # y' = y + C <= y < y" = y + D, # and # x'N <= a' < x"N, y'N <= b' < y"N, # where N = 2n. # Now, if y' > 0, and x"//y' and x'//y" agree, # then their common value is equal to q = a'//b'. # In addition, # x'%y" = x' - qy" < x" - qy' = x"%y', # and # (x'%y")N < a'%b' < (x"%y')N. # On the other hand, we also have x//y == q, # and therefore # x'%y" = x + B - q(y + D) = x%y + B', # x"%y' = x + A - q(y + C) = x%y + A', # where # B' = B - qD < 0, A' = A - qC > 0. if y + C <= 0: break q = (x + A) // (y + C) # Now x'//y" <= q, and equality holds if # x' - qy" = (x - qy) + (B - qD) >= 0. # This is a minor optimization to avoid division. x_qy, B_qD = x - qy, B - qD if x_qy + B_qD < 0: break # Next step in the Euclidean sequence. x, y = y, x_qy A, B, C, D = C, D, A - qC, B_qD # At this point the signs of the coefficients # change and their roles are interchanged. # A <= 0, B > 0, C > 0, D < 0, # x' = x + A <= x < x" = x + B, # y' = y + D < y < y" = y + C. if y + D <= 0: break q = (x + B) // (y + D) x_qy, A_qC = x - qy, A - qC if x_qy + A_qC < 0: break x, y = y, x_qy A, B, C, D = C, D, A_qC, B - qD # Now the conditions on top of the loop # are again satisfied. # A > 0, B < 0, C < 0, D > 0. if B == 0: # This can only happen when y == 0 in the beginning # and the inner loop does nothing. # Long division is forced. a, b = b, a % b continue # Compute new long arguments using the coefficients. a, b = Aa + Bb, Ca + Db # Small divisors. Finish with the standard algorithm. while b: a, b = b, a % b return a def ilcm(args): """Computes integer least common multiple. Examples ======== >>> from sympy.core.numbers import ilcm >>> ilcm(5, 10) 10 >>> ilcm(7, 3) 21 >>> ilcm(5, 10, 15) 30 """ if len(args) < 2: raise TypeError( 'ilcm() takes at least 2 arguments (%s given)' % len(args)) if 0 in args: return 0 a = args[0] for b in args[1:]: a = a // igcd(a, b) b # since gcd(a,b) \| a return a def igcdex(a, b): """Returns x, y, g such that g = xa + yb = gcd(a, b). >>> from sympy.core.numbers import igcdex >>> igcdex(2, 3) (-1, 1, 1) >>> igcdex(10, 12) (-1, 1, 2) >>> x, y, g = igcdex(100, 2004) >>> x, y, g (-20, 1, 4) >>> x100 + y2004 4 """ if (not a) and (not b): return (0, 1, 0) if not a: return (0, b//abs(b), abs(b)) if not b: return (a//abs(a), 0, abs(a)) if a < 0: a, x_sign = -a, -1 else: x_sign = 1 if b < 0: b, y_sign = -b, -1 else: y_sign = 1 x, y, r, s = 1, 0, 0, 1 while b: (c, q) = (a % b, a // b) (a, b, r, s, x, y) = (b, c, x - qr, y - qs, r, s) return (xx_sign, yy_sign, a) def mod_inverse(a, m): """ Return the number c such that, (a * c) = 1 (mod m) where c has the same sign as m. If no such value exists, a ValueError is raised. Examples ======== >>> from sympy import S >>> from sympy.core.numbers import mod_inverse Suppose we wish to find multiplicative inverse x of 3 modulo 11. This is the same as finding x such that 3 * x = 1 (mod 11). One value of x that satisfies this congruence is 4. Because 3 * 4 = 12 and 12 = 1 (mod 11). This is the value return by mod_inverse: >>> mod_inverse(3, 11) 4 >>> mod_inverse(-3, 11) 7 When there is a common factor between the numerators of ``a`` and ``m`` the inverse does not exist: >>> mod_inverse(2, 4) Traceback (most recent call last): ... ValueError: inverse of 2 mod 4 does not exist >>> mod_inverse(S(2)/7, S(5)/2) 7/2 References ========== - https://en.wikipedia.org/wiki/Modular_multiplicative_inverse - https://en.wikipedia.org/wiki/Extended_Euclidean_algorithm """ c = None try: a, m = as_int(a), as_int(m) if m != 1 and m != -1: x, y, g = igcdex(a, m) if g == 1: c = x % m except ValueError: a, m = sympify(a), sympify(m) if not (a.is_number and m.is_number): raise TypeError(filldedent(''' Expected numbers for arguments; symbolic `mod_inverse` is not implemented but symbolic expressions can be handled with the similar function, sympy.polys.polytools.invert''')) big = (m > 1) if not (big is S.true or big is S.false): raise ValueError('m > 1 did not evaluate; try to simplify %s' % m) elif big: c = 1/a if c is None: raise ValueError('inverse of %s (mod %s) does not exist' % (a, m)) return c class Number(AtomicExpr): """Represents atomic numbers in SymPy. Floating point numbers are represented by the Float class. Rational numbers (of any size) are represented by the Rational class. Integer numbers (of any size) are represented by the Integer class. Float and Rational are subclasses of Number; Integer is a subclass of Rational. For example, ``2/3`` is represented as ``Rational(2, 3)`` which is a different object from the floating point number obtained with Python division ``2/3``. Even for numbers that are exactly represented in binary, there is a difference between how two forms, such as ``Rational(1, 2)`` and ``Float(0.5)``, are used in SymPy. The rational form is to be preferred in symbolic computations. Other kinds of numbers, such as algebraic numbers ``sqrt(2)`` or complex numbers ``3 + 4I``, are not instances of Number class as they are not atomic. See Also ======== Float, Integer, Rational """ is_commutative = True is_number = True is_Number = True __slots__ = [] # Used to make max(x._prec, y._prec) return x._prec when only x is a float _prec = -1 def __new__(cls, obj): if len(obj) == 1: obj = obj[0] if isinstance(obj, Number): return obj if isinstance(obj, SYMPY_INTS): return Integer(obj) if isinstance(obj, tuple) and len(obj) == 2: return Rational(obj) if isinstance(obj, (float, mpmath.mpf, decimal.Decimal)): return Float(obj) if isinstance(obj, string_types): val = sympify(obj) if isinstance(val, Number): return val else: raise ValueError('String "%s" does not denote a Number' % obj) msg = "expected str\|int\|long\|float\|Decimal\|Number object but got %r" raise TypeError(msg % type(obj).__name__) def invert(self, other, gens, *args): from sympy.polys.polytools import invert if getattr(other, 'is_number', True): return mod_inverse(self, other) return invert(self, other, gens, *args) def __divmod__(self, other): from .containers import Tuple try: other = Number(other) except TypeError: msg = "unsupported operand type(s) for divmod(): '%s' and '%s'" raise TypeError(msg % (type(self).__name__, type(other).__name__)) if not other: raise ZeroDivisionError('modulo by zero') if self.is_Integer and other.is_Integer: return Tuple(divmod(self.p, other.p)) else: rat = self/other w = int(rat) if rat > 0 else int(rat) - 1 r = self - otherw return Tuple(w, r) def __rdivmod__(self, other): try: other = Number(other) except TypeError: msg = "unsupported operand type(s) for divmod(): '%s' and '%s'" raise TypeError(msg % (type(other).__name__, type(self).__name__)) return divmod(other, self) def _as_mpf_val(self, prec): """Evaluation of mpf tuple accurate to at least prec bits.""" raise NotImplementedError('%s needs ._as_mpf_val() method' % (self.__class__.__name__)) def _eval_evalf(self, prec): return Float._new(self._as_mpf_val(prec), prec) def _as_mpf_op(self, prec): prec = max(prec, self._prec) return self._as_mpf_val(prec), prec def __float__(self): return mlib.to_float(self._as_mpf_val(53)) def floor(self): raise NotImplementedError('%s needs .floor() method' % (self.__class__.__name__)) def ceiling(self): raise NotImplementedError('%s needs .ceiling() method' % (self.__class__.__name__)) def _eval_conjugate(self): return self def _eval_order(self, symbols): from sympy import Order # Order(5, x, y) -> Order(1,x,y) return Order(S.One, symbols) def _eval_subs(self, old, new): if old == -self: return -new return self # there is no other possibility def _eval_is_finite(self): return True @classmethod def class_key(cls): return 1, 0, 'Number' @cacheit def sort_key(self, order=None): return self.class_key(), (0, ()), (), self @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity: return S.Infinity elif other is S.NegativeInfinity: return S.NegativeInfinity return AtomicExpr.__add__(self, other) @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity: return S.NegativeInfinity elif other is S.NegativeInfinity: return S.Infinity return AtomicExpr.__sub__(self, other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity: if self.is_zero: return S.NaN elif self.is_positive: return S.Infinity else: return S.NegativeInfinity elif other is S.NegativeInfinity: if self.is_zero: return S.NaN elif self.is_positive: return S.NegativeInfinity else: return S.Infinity elif isinstance(other, Tuple): return NotImplemented return AtomicExpr.__mul__(self, other) @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity or other is S.NegativeInfinity: return S.Zero return AtomicExpr.__div__(self, other) __truediv__ = __div__ def __eq__(self, other): raise NotImplementedError('%s needs .__eq__() method' % (self.__class__.__name__)) def __ne__(self, other): raise NotImplementedError('%s needs .__ne__() method' % (self.__class__.__name__)) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) raise NotImplementedError('%s needs .__lt__() method' % (self.__class__.__name__)) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) raise NotImplementedError('%s needs .__le__() method' % (self.__class__.__name__)) def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) return _sympify(other).__lt__(self) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) return _sympify(other).__le__(self) def __hash__(self): return super(Number, self).__hash__() def is_constant(self, wrt, *flags): return True def as_coeff_mul(self, deps, *kwargs): # a -> ct if self.is_Rational or not kwargs.pop('rational', True): return self, tuple() elif self.is_negative: return S.NegativeOne, (-self,) return S.One, (self,) def as_coeff_add(self, deps): # a -> c + t if self.is_Rational: return self, tuple() return S.Zero, (self,) def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ if rational and not self.is_Rational: return S.One, self return (self, S.One) if self else (S.One, self) def as_coeff_Add(self, rational=False): """Efficiently extract the coefficient of a summation. """ if not rational: return self, S.Zero return S.Zero, self def gcd(self, other): """Compute GCD of `self` and `other`. """ from sympy.polys import gcd return gcd(self, other) def lcm(self, other): """Compute LCM of `self` and `other`. """ from sympy.polys import lcm return lcm(self, other) def cofactors(self, other): """Compute GCD and cofactors of `self` and `other`. """ from sympy.polys import cofactors return cofactors(self, other) class Float(Number): """Represent a floating-point number of arbitrary precision. Examples ======== >>> from sympy import Float >>> Float(3.5) 3.50000000000000 >>> Float(3) 3.00000000000000 Creating Floats from strings (and Python ``int`` and ``long`` types) will give a minimum precision of 15 digits, but the precision will automatically increase to capture all digits entered. >>> Float(1) 1.00000000000000 >>> Float(1020) 100000000000000000000. >>> Float('1e20') 100000000000000000000. However, floating-point* numbers (Python ``float`` types) retain only 15 digits of precision: >>> Float(1e20) 1.00000000000000e+20 >>> Float(1.23456789123456789) 1.23456789123457 It may be preferable to enter high-precision decimal numbers as strings: Float('1.23456789123456789') 1.23456789123456789 The desired number of digits can also be specified: >>> Float('1e-3', 3) 0.00100 >>> Float(100, 4) 100.0 Float can automatically count significant figures if a null string is sent for the precision; spaces or underscores are also allowed. (Auto- counting is only allowed for strings, ints and longs). >>> Float('123 456 789.123_456', '') 123456789.123456 >>> Float('12e-3', '') 0.012 >>> Float(3, '') 3. If a number is written in scientific notation, only the digits before the exponent are considered significant if a decimal appears, otherwise the "e" signifies only how to move the decimal: >>> Float('60.e2', '') # 2 digits significant 6.0e+3 >>> Float('60e2', '') # 4 digits significant 6000. >>> Float('600e-2', '') # 3 digits significant 6.00 Notes ===== Floats are inexact by their nature unless their value is a binary-exact value. >>> approx, exact = Float(.1, 1), Float(.125, 1) For calculation purposes, evalf needs to be able to change the precision but this will not increase the accuracy of the inexact value. The following is the most accurate 5-digit approximation of a value of 0.1 that had only 1 digit of precision: >>> approx.evalf(5) 0.099609 By contrast, 0.125 is exact in binary (as it is in base 10) and so it can be passed to Float or evalf to obtain an arbitrary precision with matching accuracy: >>> Float(exact, 5) 0.12500 >>> exact.evalf(20) 0.12500000000000000000 Trying to make a high-precision Float from a float is not disallowed, but one must keep in mind that the underlying float (not the apparent decimal value) is being obtained with high precision. For example, 0.3 does not have a finite binary representation. The closest rational is the fraction 5404319552844595/254. So if you try to obtain a Float of 0.3 to 20 digits of precision you will not see the same thing as 0.3 followed by 19 zeros: >>> Float(0.3, 20) 0.29999999999999998890 If you want a 20-digit value of the decimal 0.3 (not the floating point approximation of 0.3) you should send the 0.3 as a string. The underlying representation is still binary but a higher precision than Python's float is used: >>> Float('0.3', 20) 0.30000000000000000000 Although you can increase the precision of an existing Float using Float it will not increase the accuracy -- the underlying value is not changed: >>> def show(f): # binary rep of Float ... from sympy import Mul, Pow ... s, m, e, b = f._mpf_ ... v = Mul(int(m), Pow(2, int(e), evaluate=False), evaluate=False) ... print('%s at prec=%s' % (v, f._prec)) ... >>> t = Float('0.3', 3) >>> show(t) 4915/214 at prec=13 >>> show(Float(t, 20)) # higher prec, not higher accuracy 4915/214 at prec=70 >>> show(Float(t, 2)) # lower prec 307/210 at prec=10 The same thing happens when evalf is used on a Float: >>> show(t.evalf(20)) 4915/214 at prec=70 >>> show(t.evalf(2)) 307/210 at prec=10 Finally, Floats can be instantiated with an mpf tuple (n, c, p) to produce the number (-1)*nc2p: >>> n, c, p = 1, 5, 0 >>> (-1)nc2p -5 >>> Float((1, 5, 0)) -5.00000000000000 An actual mpf tuple also contains the number of bits in c as the last element of the tuple: >>> _._mpf_ (1, 5, 0, 3) This is not needed for instantiation and is not the same thing as the precision. The mpf tuple and the precision are two separate quantities that Float tracks. """ __slots__ = ['_mpf_', '_prec'] # A Float represents many real numbers, # both rational and irrational. is_rational = None is_irrational = None is_number = True is_real = True is_Float = True def __new__(cls, num, dps=None, prec=None, precision=None): if prec is not None: SymPyDeprecationWarning( feature="Using 'prec=XX' to denote decimal precision", useinstead="'dps=XX' for decimal precision and 'precision=XX' "\ "for binary precision", issue=12820, deprecated_since_version="1.1").warn() dps = prec del prec # avoid using this deprecated kwarg if dps is not None and precision is not None: raise ValueError('Both decimal and binary precision supplied. ' 'Supply only one. ') if isinstance(num, string_types): # Float already accepts spaces as digit separators; in Py 3.6 # underscores are allowed. In anticipation of that, we ignore # legally placed underscores num = num.replace(' ', '') if '_' in num: if num.startswith('_') or num.endswith('_') or any( i in num for i in ('__', '_.', '._')): # copy Py 3.6 error raise ValueError("could not convert string to float: '%s'" % num) num = num.replace('_', '') if num.startswith('.') and len(num) > 1: num = '0' + num elif num.startswith('-.') and len(num) > 2: num = '-0.' + num[2:] elif num == 'inf' or num == '+inf': return S.Infinity elif num == '-inf': return S.NegativeInfinity elif isinstance(num, float) and num == 0: num = '0' elif isinstance(num, float) and num == float('inf'): return S.Infinity elif isinstance(num, float) and num == float('-inf'): return S.NegativeInfinity elif isinstance(num, (SYMPY_INTS, Integer)): num = str(num) # faster than mlib.from_int elif num is S.Infinity: return num elif num is S.NegativeInfinity: return num elif type(num).__module__ == 'numpy': # support for numpy datatypes num = _convert_numpy_types(num) elif isinstance(num, mpmath.mpf): if precision is None: if dps is None: precision = num.context.prec num = num._mpf_ if dps is None and precision is None: dps = 15 if isinstance(num, Float): return num if isinstance(num, string_types) and _literal_float(num): try: Num = decimal.Decimal(num) except decimal.InvalidOperation: pass else: isint = '.' not in num num, dps = _decimal_to_Rational_prec(Num) if num.is_Integer and isint: dps = max(dps, len(str(num).lstrip('-'))) dps = max(15, dps) precision = mlib.libmpf.dps_to_prec(dps) elif precision == '' and dps is None or precision is None and dps == '': if not isinstance(num, string_types): raise ValueError('The null string can only be used when ' 'the number to Float is passed as a string or an integer.') ok = None if _literal_float(num): try: Num = decimal.Decimal(num) except decimal.InvalidOperation: pass else: isint = '.' not in num num, dps = _decimal_to_Rational_prec(Num) if num.is_Integer and isint: dps = max(dps, len(str(num).lstrip('-'))) precision = mlib.libmpf.dps_to_prec(dps) ok = True if ok is None: raise ValueError('string-float not recognized: %s' % num) # decimal precision(dps) is set and maybe binary precision(precision) # as well.From here on binary precision is used to compute the Float. # Hence, if supplied use binary precision else translate from decimal # precision. if precision is None or precision == '': precision = mlib.libmpf.dps_to_prec(dps) precision = int(precision) if isinstance(num, float): _mpf_ = mlib.from_float(num, precision, rnd) elif isinstance(num, string_types): _mpf_ = mlib.from_str(num, precision, rnd) elif isinstance(num, decimal.Decimal): if num.is_finite(): _mpf_ = mlib.from_str(str(num), precision, rnd) elif num.is_nan(): return S.NaN elif num.is_infinite(): if num > 0: return S.Infinity else: return S.NegativeInfinity else: raise ValueError("unexpected decimal value %s" % str(num)) elif isinstance(num, tuple) and len(num) in (3, 4): if type(num[1]) is str: # it's a hexadecimal (coming from a pickled object) # assume that it is in standard form num = list(num) # If we're loading an object pickled in Python 2 into # Python 3, we may need to strip a tailing 'L' because # of a shim for int on Python 3, see issue #13470. if num[1].endswith('L'): num[1] = num[1][:-1] num[1] = MPZ(num[1], 16) _mpf_ = tuple(num) else: if len(num) == 4: # handle normalization hack return Float._new(num, precision) else: return (S.NegativeOnenum[0]num[1]S(2)num[2]).evalf(precision) else: try: _mpf_ = num._as_mpf_val(precision) except (NotImplementedError, AttributeError): _mpf_ = mpmath.mpf(num, prec=precision)._mpf_ # special cases if _mpf_ == _mpf_zero: pass # we want a Float elif _mpf_ == _mpf_nan: return S.NaN elif _mpf_ == _mpf_inf: return S.Infinity elif _mpf_ == _mpf_ninf: return S.NegativeInfinity obj = Expr.__new__(cls) obj._mpf_ = _mpf_ obj._prec = precision return obj @classmethod def _new(cls, _mpf_, _prec): # special cases if _mpf_ == _mpf_zero: return S.Zero # XXX this is different from Float which gives 0.0 elif _mpf_ == _mpf_nan: return S.NaN elif _mpf_ == _mpf_inf: return S.Infinity elif _mpf_ == _mpf_ninf: return S.NegativeInfinity obj = Expr.__new__(cls) obj._mpf_ = mpf_norm(_mpf_, _prec) # XXX: Should this be obj._prec = obj._mpf_[3]? obj._prec = _prec return obj # mpz can't be pickled def __getnewargs__(self): return (mlib.to_pickable(self._mpf_),) def __getstate__(self): return {'_prec': self._prec} def _hashable_content(self): return (self._mpf_, self._prec) def floor(self): return Integer(int(mlib.to_int( mlib.mpf_floor(self._mpf_, self._prec)))) def ceiling(self): return Integer(int(mlib.to_int( mlib.mpf_ceil(self._mpf_, self._prec)))) @property def num(self): return mpmath.mpf(self._mpf_) def _as_mpf_val(self, prec): rv = mpf_norm(self._mpf_, prec) if rv != self._mpf_ and self._prec == prec: debug(self._mpf_, rv) return rv def _as_mpf_op(self, prec): return self._mpf_, max(prec, self._prec) def _eval_is_finite(self): if self._mpf_ in (_mpf_inf, _mpf_ninf): return False return True def _eval_is_infinite(self): if self._mpf_ in (_mpf_inf, _mpf_ninf): return True return False def _eval_is_integer(self): return self._mpf_ == _mpf_zero def _eval_is_negative(self): if self._mpf_ == _mpf_ninf: return True if self._mpf_ == _mpf_inf: return False return self.num < 0 def _eval_is_positive(self): if self._mpf_ == _mpf_inf: return True if self._mpf_ == _mpf_ninf: return False return self.num > 0 def _eval_is_zero(self): return self._mpf_ == _mpf_zero def __nonzero__(self): return self._mpf_ != _mpf_zero __bool__ = __nonzero__ def __neg__(self): return Float._new(mlib.mpf_neg(self._mpf_), self._prec) @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_add(self._mpf_, rhs, prec, rnd), prec) return Number.__add__(self, other) @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_sub(self._mpf_, rhs, prec, rnd), prec) return Number.__sub__(self, other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_mul(self._mpf_, rhs, prec, rnd), prec) return Number.__mul__(self, other) @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number) and other != 0 and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_div(self._mpf_, rhs, prec, rnd), prec) return Number.__div__(self, other) __truediv__ = __div__ @_sympifyit('other', NotImplemented) def __mod__(self, other): if isinstance(other, Rational) and other.q != 1 and global_evaluate[0]: # calculate mod with Rationals, then* round the result return Float(Rational.__mod__(Rational(self), other), precision=self._prec) if isinstance(other, Float) and global_evaluate[0]: r = self/other if r == int(r): return Float(0, precision=max(self._prec, other._prec)) if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_mod(self._mpf_, rhs, prec, rnd), prec) return Number.__mod__(self, other) @_sympifyit('other', NotImplemented) def __rmod__(self, other): if isinstance(other, Float) and global_evaluate[0]: return other.__mod__(self) if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_mod(rhs, self._mpf_, prec, rnd), prec) return Number.__rmod__(self, other) def _eval_power(self, expt): """ expt is symbolic object but not equal to 0, 1 (-p)*r -> exp(rlog(-p)) -> exp(r(log(p) + IPi)) -> -> p*r(sin(Pir) + cos(Pir)I) """ if self == 0: if expt.is_positive: return S.Zero if expt.is_negative: return S.Infinity if isinstance(expt, Number): if isinstance(expt, Integer): prec = self._prec return Float._new( mlib.mpf_pow_int(self._mpf_, expt.p, prec, rnd), prec) elif isinstance(expt, Rational) and \ expt.p == 1 and expt.q % 2 and self.is_negative: return Pow(S.NegativeOne, expt, evaluate=False)( -self)._eval_power(expt) expt, prec = expt._as_mpf_op(self._prec) mpfself = self._mpf_ try: y = mpf_pow(mpfself, expt, prec, rnd) return Float._new(y, prec) except mlib.ComplexResult: re, im = mlib.mpc_pow( (mpfself, _mpf_zero), (expt, _mpf_zero), prec, rnd) return Float._new(re, prec) + \ Float._new(im, prec)S.ImaginaryUnit def __abs__(self): return Float._new(mlib.mpf_abs(self._mpf_), self._prec) def __int__(self): if self._mpf_ == _mpf_zero: return 0 return int(mlib.to_int(self._mpf_)) # uses round_fast = round_down __long__ = __int__ def __eq__(self, other): if isinstance(other, float): # coerce to Float at same precision o = Float(other) try: ompf = o._as_mpf_val(self._prec) except ValueError: return False return bool(mlib.mpf_eq(self._mpf_, ompf)) try: other = _sympify(other) except SympifyError: return NotImplemented if other.is_NumberSymbol: if other.is_irrational: return False return other.__eq__(self) if other.is_Float: return bool(mlib.mpf_eq(self._mpf_, other._mpf_)) if other.is_Number: # numbers should compare at the same precision; # all _as_mpf_val routines should be sure to abide # by the request to change the prec if necessary; if # they don't, the equality test will fail since it compares # the mpf tuples ompf = other._as_mpf_val(self._prec) return bool(mlib.mpf_eq(self._mpf_, ompf)) return False # Float != non-Number def __ne__(self, other): return not self == other def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_NumberSymbol: return other.__lt__(self) if other.is_Rational and not other.is_Integer: self = other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_gt(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__gt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_NumberSymbol: return other.__le__(self) if other.is_Rational and not other.is_Integer: self = other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_ge(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__ge__(self, other) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_NumberSymbol: return other.__gt__(self) if other.is_Rational and not other.is_Integer: self = other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_lt(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__lt__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_NumberSymbol: return other.__ge__(self) if other.is_Rational and not other.is_Integer: self = other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_le(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__le__(self, other) def __hash__(self): return super(Float, self).__hash__() def epsilon_eq(self, other, epsilon="1e-15"): return abs(self - other) < Float(epsilon) def _sage_(self): import sage.all as sage return sage.RealNumber(str(self)) def __format__(self, format_spec): return format(decimal.Decimal(str(self)), format_spec) # Add sympify converters converter[float] = converter[decimal.Decimal] = Float # this is here to work nicely in Sage RealNumber = Float class Rational(Number): """Represents rational numbers (p/q) of any size. Examples ======== >>> from sympy import Rational, nsimplify, S, pi >>> Rational(1, 2) 1/2 Rational is unprejudiced in accepting input. If a float is passed, the underlying value of the binary representation will be returned: >>> Rational(.5) 1/2 >>> Rational(.2) 3602879701896397/18014398509481984 If the simpler representation of the float is desired then consider limiting the denominator to the desired value or convert the float to a string (which is roughly equivalent to limiting the denominator to 1012): >>> Rational(str(.2)) 1/5 >>> Rational(.2).limit_denominator(1012) 1/5 An arbitrarily precise Rational is obtained when a string literal is passed: >>> Rational("1.23") 123/100 >>> Rational('1e-2') 1/100 >>> Rational(".1") 1/10 >>> Rational('1e-2/3.2') 1/320 The conversion of other types of strings can be handled by the sympify() function, and conversion of floats to expressions or simple fractions can be handled with nsimplify: >>> S('.[3]') # repeating digits in brackets 1/3 >>> S('32/10') # general expressions 9/10 >>> nsimplify(.3) # numbers that have a simple form 3/10 But if the input does not reduce to a literal Rational, an error will be raised: >>> Rational(pi) Traceback (most recent call last): ... TypeError: invalid input: pi Low-level --------- Access numerator and denominator as .p and .q: >>> r = Rational(3, 4) >>> r 3/4 >>> r.p 3 >>> r.q 4 Note that p and q return integers (not SymPy Integers) so some care is needed when using them in expressions: >>> r.p/r.q 0.75 See Also ======== sympify, sympy.simplify.simplify.nsimplify """ is_real = True is_integer = False is_rational = True is_number = True __slots__ = ['p', 'q'] is_Rational = True @cacheit def __new__(cls, p, q=None, gcd=None): if q is None: if isinstance(p, Rational): return p if isinstance(p, SYMPY_INTS): pass else: if isinstance(p, (float, Float)): return Rational(_as_integer_ratio(p)) if not isinstance(p, string_types): try: p = sympify(p) except (SympifyError, SyntaxError): pass # error will raise below else: if p.count('/') > 1: raise TypeError('invalid input: %s' % p) p = p.replace(' ', '') pq = p.rsplit('/', 1) if len(pq) == 2: p, q = pq fp = fractions.Fraction(p) fq = fractions.Fraction(q) p = fp/fq try: p = fractions.Fraction(p) except ValueError: pass # error will raise below else: return Rational(p.numerator, p.denominator, 1) if not isinstance(p, Rational): raise TypeError('invalid input: %s' % p) q = 1 gcd = 1 else: p = Rational(p) q = Rational(q) if isinstance(q, Rational): p = q.q q = q.p if isinstance(p, Rational): q = p.q p = p.p # p and q are now integers if q == 0: if p == 0: if _errdict["divide"]: raise ValueError("Indeterminate 0/0") else: return S.NaN return S.ComplexInfinity if q < 0: q = -q p = -p if not gcd: gcd = igcd(abs(p), q) if gcd > 1: p //= gcd q //= gcd if q == 1: return Integer(p) if p == 1 and q == 2: return S.Half obj = Expr.__new__(cls) obj.p = p obj.q = q return obj def limit_denominator(self, max_denominator=1000000): """Closest Rational to self with denominator at most max_denominator. >>> from sympy import Rational >>> Rational('3.141592653589793').limit_denominator(10) 22/7 >>> Rational('3.141592653589793').limit_denominator(100) 311/99 """ f = fractions.Fraction(self.p, self.q) return Rational(f.limit_denominator(fractions.Fraction(int(max_denominator)))) def __getnewargs__(self): return (self.p, self.q) def _hashable_content(self): return (self.p, self.q) def _eval_is_positive(self): return self.p > 0 def _eval_is_zero(self): return self.p == 0 def __neg__(self): return Rational(-self.p, self.q) @_sympifyit('other', NotImplemented) def __add__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.p + self.qother.p, self.q, 1) elif isinstance(other, Rational): #TODO: this can probably be optimized more return Rational(self.pother.q + self.qother.p, self.qother.q) elif isinstance(other, Float): return other + self else: return Number.__add__(self, other) return Number.__add__(self, other) __radd__ = __add__ @_sympifyit('other', NotImplemented) def __sub__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.p - self.qother.p, self.q, 1) elif isinstance(other, Rational): return Rational(self.pother.q - self.qother.p, self.qother.q) elif isinstance(other, Float): return -other + self else: return Number.__sub__(self, other) return Number.__sub__(self, other) @_sympifyit('other', NotImplemented) def __rsub__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.qother.p - self.p, self.q, 1) elif isinstance(other, Rational): return Rational(self.qother.p - self.pother.q, self.qother.q) elif isinstance(other, Float): return -self + other else: return Number.__rsub__(self, other) return Number.__rsub__(self, other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.pother.p, self.q, igcd(other.p, self.q)) elif isinstance(other, Rational): return Rational(self.pother.p, self.qother.q, igcd(self.p, other.q)igcd(self.q, other.p)) elif isinstance(other, Float): return otherself else: return Number.__mul__(self, other) return Number.__mul__(self, other) __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if global_evaluate[0]: if isinstance(other, Integer): if self.p and other.p == S.Zero: return S.ComplexInfinity else: return Rational(self.p, self.qother.p, igcd(self.p, other.p)) elif isinstance(other, Rational): return Rational(self.pother.q, self.qother.p, igcd(self.p, other.p)igcd(self.q, other.q)) elif isinstance(other, Float): return self(1/other) else: return Number.__div__(self, other) return Number.__div__(self, other) @_sympifyit('other', NotImplemented) def __rdiv__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(other.pself.q, self.p, igcd(self.p, other.p)) elif isinstance(other, Rational): return Rational(other.pself.q, other.qself.p, igcd(self.p, other.p)igcd(self.q, other.q)) elif isinstance(other, Float): return other(1/self) else: return Number.__rdiv__(self, other) return Number.__rdiv__(self, other) __truediv__ = __div__ @_sympifyit('other', NotImplemented) def __mod__(self, other): if global_evaluate[0]: if isinstance(other, Rational): n = (self.pother.q) // (other.pself.q) return Rational(self.pother.q - nother.pself.q, self.qother.q) if isinstance(other, Float): # calculate mod with Rationals, then* round the answer return Float(self.__mod__(Rational(other)), precision=other._prec) return Number.__mod__(self, other) return Number.__mod__(self, other) @_sympifyit('other', NotImplemented) def __rmod__(self, other): if isinstance(other, Rational): return Rational.__mod__(other, self) return Number.__rmod__(self, other) def _eval_power(self, expt): if isinstance(expt, Number): if isinstance(expt, Float): return self._eval_evalf(expt._prec)expt if expt.is_negative: # (3/4)-2 -> (4/3)2 ne = -expt if (ne is S.One): return Rational(self.q, self.p) if self.is_negative: return S.NegativeOneexptRational(self.q, -self.p)ne else: return Rational(self.q, self.p)ne if expt is S.Infinity: # -oo already caught by test for negative if self.p > self.q: # (3/2)oo -> oo return S.Infinity if self.p < -self.q: # (-3/2)oo -> oo + Ioo return S.Infinity + S.InfinityS.ImaginaryUnit return S.Zero if isinstance(expt, Integer): # (4/3)2 -> 42 / 32 return Rational(self.pexpt.p, self.qexpt.p, 1) if isinstance(expt, Rational): if self.p != 1: # (4/3)(5/6) -> 4(5/6)3(-5/6) return Integer(self.p)exptInteger(self.q)(-expt) # as the above caught negative self.p, now self is positive return Integer(self.q)Rational( expt.p(expt.q - 1), expt.q) / \ Integer(self.q)Integer(expt.p) if self.is_negative and expt.is_even: return (-self)expt return def _as_mpf_val(self, prec): return mlib.from_rational(self.p, self.q, prec, rnd) def _mpmath_(self, prec, rnd): return mpmath.make_mpf(mlib.from_rational(self.p, self.q, prec, rnd)) def __abs__(self): return Rational(abs(self.p), self.q) def __int__(self): p, q = self.p, self.q if p < 0: return -int(-p//q) return int(p//q) __long__ = __int__ def floor(self): return Integer(self.p // self.q) def ceiling(self): return -Integer(-self.p // self.q) def __eq__(self, other): try: other = _sympify(other) except SympifyError: return NotImplemented if other.is_NumberSymbol: if other.is_irrational: return False return other.__eq__(self) if other.is_Number: if other.is_Rational: # a Rational is always in reduced form so will never be 2/4 # so we can just check equivalence of args return self.p == other.p and self.q == other.q if other.is_Float: return mlib.mpf_eq(self._as_mpf_val(other._prec), other._mpf_) return False def __ne__(self, other): return not self == other def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_NumberSymbol: return other.__lt__(self) expr = self if other.is_Number: if other.is_Rational: return _sympify(bool(self.pother.q > self.qother.p)) if other.is_Float: return _sympify(bool(mlib.mpf_gt( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.qother return Expr.__gt__(expr, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_NumberSymbol: return other.__le__(self) expr = self if other.is_Number: if other.is_Rational: return _sympify(bool(self.pother.q >= self.qother.p)) if other.is_Float: return _sympify(bool(mlib.mpf_ge( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.qother return Expr.__ge__(expr, other) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_NumberSymbol: return other.__gt__(self) expr = self if other.is_Number: if other.is_Rational: return _sympify(bool(self.pother.q < self.qother.p)) if other.is_Float: return _sympify(bool(mlib.mpf_lt( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.qother return Expr.__lt__(expr, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) expr = self if other.is_NumberSymbol: return other.__ge__(self) elif other.is_Number: if other.is_Rational: return _sympify(bool(self.pother.q <= self.qother.p)) if other.is_Float: return _sympify(bool(mlib.mpf_le( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.qother return Expr.__le__(expr, other) def __hash__(self): return super(Rational, self).__hash__() def factors(self, limit=None, use_trial=True, use_rho=False, use_pm1=False, verbose=False, visual=False): """A wrapper to factorint which return factors of self that are smaller than limit (or cheap to compute). Special methods of factoring are disabled by default so that only trial division is used. """ from sympy.ntheory import factorrat return factorrat(self, limit=limit, use_trial=use_trial, use_rho=use_rho, use_pm1=use_pm1, verbose=verbose).copy() @_sympifyit('other', NotImplemented) def gcd(self, other): if isinstance(other, Rational): if other is S.Zero: return other return Rational( Integer(igcd(self.p, other.p)), Integer(ilcm(self.q, other.q))) return Number.gcd(self, other) @_sympifyit('other', NotImplemented) def lcm(self, other): if isinstance(other, Rational): return Rational( self.p // igcd(self.p, other.p) * other.p, igcd(self.q, other.q)) return Number.lcm(self, other) def as_numer_denom(self): return Integer(self.p), Integer(self.q) def _sage_(self): import sage.all as sage return sage.Integer(self.p)/sage.Integer(self.q) def as_content_primitive(self, radical=False, clear=True): """Return the tuple (R, self/R) where R is the positive Rational extracted from self. Examples ======== >>> from sympy import S >>> (S(-3)/2).as_content_primitive() (3/2, -1) See docstring of Expr.as_content_primitive for more examples. """ if self: if self.is_positive: return self, S.One return -self, S.NegativeOne return S.One, self def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ return self, S.One def as_coeff_Add(self, rational=False): """Efficiently extract the coefficient of a summation. """ return self, S.Zero class Integer(Rational): """Represents integer numbers of any size. Examples ======== >>> from sympy import Integer >>> Integer(3) 3 If a float or a rational is passed to Integer, the fractional part will be discarded; the effect is of rounding toward zero. >>> Integer(3.8) 3 >>> Integer(-3.8) -3 A string is acceptable input if it can be parsed as an integer: >>> Integer("9" * 20) 99999999999999999999 It is rarely needed to explicitly instantiate an Integer, because Python integers are automatically converted to Integer when they are used in SymPy expressions. """ q = 1 is_integer = True is_number = True is_Integer = True __slots__ = ['p'] def _as_mpf_val(self, prec): return mlib.from_int(self.p, prec, rnd) def _mpmath_(self, prec, rnd): return mpmath.make_mpf(self._as_mpf_val(prec)) @cacheit def __new__(cls, i): if isinstance(i, string_types): i = i.replace(' ', '') # whereas we cannot, in general, make a Rational from an # arbitrary expression, we can make an Integer unambiguously # (except when a non-integer expression happens to round to # an integer). So we proceed by taking int() of the input and # let the int routines determine whether the expression can # be made into an int or whether an error should be raised. try: ival = int(i) except TypeError: raise TypeError( "Argument of Integer should be of numeric type, got %s." % i) # We only work with well-behaved integer types. This converts, for # example, numpy.int32 instances. if ival == 1: return S.One if ival == -1: return S.NegativeOne if ival == 0: return S.Zero obj = Expr.__new__(cls) obj.p = ival return obj def __getnewargs__(self): return (self.p,) # Arithmetic operations are here for efficiency def __int__(self): return self.p __long__ = __int__ def floor(self): return Integer(self.p) def ceiling(self): return Integer(self.p) def __neg__(self): return Integer(-self.p) def __abs__(self): if self.p >= 0: return self else: return Integer(-self.p) def __divmod__(self, other): from .containers import Tuple if isinstance(other, Integer) and global_evaluate[0]: return Tuple((divmod(self.p, other.p))) else: return Number.__divmod__(self, other) def __rdivmod__(self, other): from .containers import Tuple if isinstance(other, integer_types) and global_evaluate[0]: return Tuple((divmod(other, self.p))) else: try: other = Number(other) except TypeError: msg = "unsupported operand type(s) for divmod(): '%s' and '%s'" oname = type(other).__name__ sname = type(self).__name__ raise TypeError(msg % (oname, sname)) return Number.__divmod__(other, self) # TODO make it decorator + bytecodehacks? def __add__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p + other) elif isinstance(other, Integer): return Integer(self.p + other.p) elif isinstance(other, Rational): return Rational(self.pother.q + other.p, other.q, 1) return Rational.__add__(self, other) else: return Add(self, other) def __radd__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other + self.p) elif isinstance(other, Rational): return Rational(other.p + self.pother.q, other.q, 1) return Rational.__radd__(self, other) return Rational.__radd__(self, other) def __sub__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p - other) elif isinstance(other, Integer): return Integer(self.p - other.p) elif isinstance(other, Rational): return Rational(self.pother.q - other.p, other.q, 1) return Rational.__sub__(self, other) return Rational.__sub__(self, other) def __rsub__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other - self.p) elif isinstance(other, Rational): return Rational(other.p - self.pother.q, other.q, 1) return Rational.__rsub__(self, other) return Rational.__rsub__(self, other) def __mul__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.pother) elif isinstance(other, Integer): return Integer(self.pother.p) elif isinstance(other, Rational): return Rational(self.pother.p, other.q, igcd(self.p, other.q)) return Rational.__mul__(self, other) return Rational.__mul__(self, other) def __rmul__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(otherself.p) elif isinstance(other, Rational): return Rational(other.pself.p, other.q, igcd(self.p, other.q)) return Rational.__rmul__(self, other) return Rational.__rmul__(self, other) def __mod__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p % other) elif isinstance(other, Integer): return Integer(self.p % other.p) return Rational.__mod__(self, other) return Rational.__mod__(self, other) def __rmod__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other % self.p) elif isinstance(other, Integer): return Integer(other.p % self.p) return Rational.__rmod__(self, other) return Rational.__rmod__(self, other) def __eq__(self, other): if isinstance(other, integer_types): return (self.p == other) elif isinstance(other, Integer): return (self.p == other.p) return Rational.__eq__(self, other) def __ne__(self, other): return not self == other def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_Integer: return _sympify(self.p > other.p) return Rational.__gt__(self, other) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_Integer: return _sympify(self.p < other.p) return Rational.__lt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_Integer: return _sympify(self.p >= other.p) return Rational.__ge__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_Integer: return _sympify(self.p <= other.p) return Rational.__le__(self, other) def __hash__(self): return hash(self.p) def __index__(self): return self.p ######################################## def _eval_is_odd(self): return bool(self.p % 2) def _eval_power(self, expt): """ Tries to do some simplifications on selfexpt Returns None if no further simplifications can be done When exponent is a fraction (so we have for example a square root), we try to find a simpler representation by factoring the argument up to factors of 215, e.g. - sqrt(4) becomes 2 - sqrt(-4) becomes 2I - (2*(3+7)3(6+7))Rational(1,7) becomes 618(3/7) Further simplification would require a special call to factorint on the argument which is not done here for sake of speed. """ from sympy import perfect_power if expt is S.Infinity: if self.p > S.One: return S.Infinity # cases -1, 0, 1 are done in their respective classes return S.Infinity + S.ImaginaryUnitS.Infinity if expt is S.NegativeInfinity: return Rational(1, self)S.Infinity if not isinstance(expt, Number): # simplify when expt is even # (-2)k --> 2k if self.is_negative and expt.is_even: return (-self)expt if isinstance(expt, Float): # Rational knows how to exponentiate by a Float return super(Integer, self)._eval_power(expt) if not isinstance(expt, Rational): return if expt is S.Half and self.is_negative: # we extract I for this special case since everyone is doing so return S.ImaginaryUnitPow(-self, expt) if expt.is_negative: # invert base and change sign on exponent ne = -expt if self.is_negative: return S.NegativeOneexptRational(1, -self)ne else: return Rational(1, self.p)ne # see if base is a perfect root, sqrt(4) --> 2 x, xexact = integer_nthroot(abs(self.p), expt.q) if xexact: # if it's a perfect root we've finished result = Integer(x*abs(expt.p)) if self.is_negative: result = S.NegativeOneexpt return result # The following is an algorithm where we collect perfect roots # from the factors of base. # if it's not an nth root, it still might be a perfect power b_pos = int(abs(self.p)) p = perfect_power(b_pos) if p is not False: dict = {p[0]: p[1]} else: dict = Integer(b_pos).factors(limit=215) # now process the dict of factors out_int = 1 # integer part out_rad = 1 # extracted radicals sqr_int = 1 sqr_gcd = 0 sqr_dict = {} for prime, exponent in dict.items(): exponent = expt.p # remove multiples of expt.q: (212)(1/10) -> 2(22)(1/10) div_e, div_m = divmod(exponent, expt.q) if div_e > 0: out_int = primediv_e if div_m > 0: # see if the reduced exponent shares a gcd with e.q # (22)(1/10) -> 2(1/5) g = igcd(div_m, expt.q) if g != 1: out_rad = Pow(prime, Rational(div_m//g, expt.q//g)) else: sqr_dict[prime] = div_m # identify gcd of remaining powers for p, ex in sqr_dict.items(): if sqr_gcd == 0: sqr_gcd = ex else: sqr_gcd = igcd(sqr_gcd, ex) if sqr_gcd == 1: break for k, v in sqr_dict.items(): sqr_int = k(v//sqr_gcd) if sqr_int == b_pos and out_int == 1 and out_rad == 1: result = None else: result = out_intout_radPow(sqr_int, Rational(sqr_gcd, expt.q)) if self.is_negative: result = Pow(S.NegativeOne, expt) return result def _eval_is_prime(self): from sympy.ntheory import isprime return isprime(self) def _eval_is_composite(self): if self > 1: return fuzzy_not(self.is_prime) else: return False def as_numer_denom(self): return self, S.One def __floordiv__(self, other): return Integer(self.p // Integer(other).p) def __rfloordiv__(self, other): return Integer(Integer(other).p // self.p) # Add sympify converters for i_type in integer_types: converter[i_type] = Integer class AlgebraicNumber(Expr): """Class for representing algebraic numbers in SymPy. """ __slots__ = ['rep', 'root', 'alias', 'minpoly'] is_AlgebraicNumber = True is_algebraic = True is_number = True def __new__(cls, expr, coeffs=None, alias=None, *args): """Construct a new algebraic number. """ from sympy import Poly from sympy.polys.polyclasses import ANP, DMP from sympy.polys.numberfields import minimal_polynomial from sympy.core.symbol import Symbol expr = sympify(expr) if isinstance(expr, (tuple, Tuple)): minpoly, root = expr if not minpoly.is_Poly: minpoly = Poly(minpoly) elif expr.is_AlgebraicNumber: minpoly, root = expr.minpoly, expr.root else: minpoly, root = minimal_polynomial( expr, args.get('gen'), polys=True), expr dom = minpoly.get_domain() if coeffs is not None: if not isinstance(coeffs, ANP): rep = DMP.from_sympy_list(sympify(coeffs), 0, dom) scoeffs = Tuple(coeffs) else: rep = DMP.from_list(coeffs.to_list(), 0, dom) scoeffs = Tuple(coeffs.to_list()) if rep.degree() >= minpoly.degree(): rep = rep.rem(minpoly.rep) else: rep = DMP.from_list([1, 0], 0, dom) scoeffs = Tuple(1, 0) sargs = (root, scoeffs) if alias is not None: if not isinstance(alias, Symbol): alias = Symbol(alias) sargs = sargs + (alias,) obj = Expr.__new__(cls, sargs) obj.rep = rep obj.root = root obj.alias = alias obj.minpoly = minpoly return obj def __hash__(self): return super(AlgebraicNumber, self).__hash__() def _eval_evalf(self, prec): return self.as_expr()._evalf(prec) @property def is_aliased(self): """Returns ``True`` if ``alias`` was set. """ return self.alias is not None def as_poly(self, x=None): """Create a Poly instance from ``self``. """ from sympy import Dummy, Poly, PurePoly if x is not None: return Poly.new(self.rep, x) else: if self.alias is not None: return Poly.new(self.rep, self.alias) else: return PurePoly.new(self.rep, Dummy('x')) def as_expr(self, x=None): """Create a Basic expression from ``self``. """ return self.as_poly(x or self.root).as_expr().expand() def coeffs(self): """Returns all SymPy coefficients of an algebraic number. """ return [ self.rep.dom.to_sympy(c) for c in self.rep.all_coeffs() ] def native_coeffs(self): """Returns all native coefficients of an algebraic number. """ return self.rep.all_coeffs() def to_algebraic_integer(self): """Convert ``self`` to an algebraic integer. """ from sympy import Poly f = self.minpoly if f.LC() == 1: return self coeff = f.LC()*(f.degree() - 1) poly = f.compose(Poly(f.gen/f.LC())) minpoly = polycoeff root = f.LC()self.root return AlgebraicNumber((minpoly, root), self.coeffs()) def _eval_simplify(self, ratio, measure, rational, inverse): from sympy.polys import CRootOf, minpoly for r in [r for r in self.minpoly.all_roots() if r.func != CRootOf]: if minpoly(self.root - r).is_Symbol: # use the matching root if it's simpler if measure(r) < ratiomeasure(self.root): return AlgebraicNumber(r) return self class RationalConstant(Rational): """ Abstract base class for rationals with specific behaviors Derived classes must define class attributes p and q and should probably all be singletons. """ __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) class IntegerConstant(Integer): __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) class Zero(with_metaclass(Singleton, IntegerConstant)): """The number zero. Zero is a singleton, and can be accessed by ``S.Zero`` Examples ======== >>> from sympy import S, Integer, zoo >>> Integer(0) is S.Zero True >>> 1/S.Zero zoo References ========== .. [1] https://en.wikipedia.org/wiki/Zero """ p = 0 q = 1 is_positive = False is_negative = False is_zero = True is_number = True __slots__ = [] @staticmethod def __abs__(): return S.Zero @staticmethod def __neg__(): return S.Zero def _eval_power(self, expt): if expt.is_positive: return self if expt.is_negative: return S.ComplexInfinity if expt.is_real is False: return S.NaN # infinities are already handled with pos and neg # tests above; now throw away leading numbers on Mul # exponent coeff, terms = expt.as_coeff_Mul() if coeff.is_negative: return S.ComplexInfinityterms if coeff is not S.One: # there is a Number to discard return selfterms def _eval_order(self, symbols): # Order(0,x) -> 0 return self def __nonzero__(self): return False __bool__ = __nonzero__ def as_coeff_Mul(self, rational=False): # XXX this routine should be deleted """Efficiently extract the coefficient of a summation. """ return S.One, self class One(with_metaclass(Singleton, IntegerConstant)): """The number one. One is a singleton, and can be accessed by ``S.One``. Examples ======== >>> from sympy import S, Integer >>> Integer(1) is S.One True References ========== .. [1] https://en.wikipedia.org/wiki/1_%28number%29 """ is_number = True p = 1 q = 1 __slots__ = [] @staticmethod def __abs__(): return S.One @staticmethod def __neg__(): return S.NegativeOne def _eval_power(self, expt): return self def _eval_order(self, symbols): return @staticmethod def factors(limit=None, use_trial=True, use_rho=False, use_pm1=False, verbose=False, visual=False): if visual: return S.One else: return {} class NegativeOne(with_metaclass(Singleton, IntegerConstant)): """The number negative one. NegativeOne is a singleton, and can be accessed by ``S.NegativeOne``. Examples ======== >>> from sympy import S, Integer >>> Integer(-1) is S.NegativeOne True See Also ======== One References ========== .. [1] https://en.wikipedia.org/wiki/%E2%88%921_%28number%29 """ is_number = True p = -1 q = 1 __slots__ = [] @staticmethod def __abs__(): return S.One @staticmethod def __neg__(): return S.One def _eval_power(self, expt): if expt.is_odd: return S.NegativeOne if expt.is_even: return S.One if isinstance(expt, Number): if isinstance(expt, Float): return Float(-1.0)expt if expt is S.NaN: return S.NaN if expt is S.Infinity or expt is S.NegativeInfinity: return S.NaN if expt is S.Half: return S.ImaginaryUnit if isinstance(expt, Rational): if expt.q == 2: return S.ImaginaryUnitInteger(expt.p) i, r = divmod(expt.p, expt.q) if i: return self*iselfRational(r, expt.q) return class Half(with_metaclass(Singleton, RationalConstant)): """The rational number 1/2. Half is a singleton, and can be accessed by ``S.Half``. Examples ======== >>> from sympy import S, Rational >>> Rational(1, 2) is S.Half True References ========== .. [1] https://en.wikipedia.org/wiki/One_half """ is_number = True p = 1 q = 2 __slots__ = [] @staticmethod def __abs__(): return S.Half class Infinity(with_metaclass(Singleton, Number)): r"""Positive infinite quantity. In real analysis the symbol `\infty` denotes an unbounded limit: `x\to\infty` means that `x` grows without bound. Infinity is often used not only to define a limit but as a value in the affinely extended real number system. Points labeled `+\infty` and `-\infty` can be added to the topological space of the real numbers, producing the two-point compactification of the real numbers. Adding algebraic properties to this gives us the extended real numbers. Infinity is a singleton, and can be accessed by ``S.Infinity``, or can be imported as ``oo``. Examples ======== >>> from sympy import oo, exp, limit, Symbol >>> 1 + oo oo >>> 42/oo 0 >>> x = Symbol('x') >>> limit(exp(x), x, oo) oo See Also ======== NegativeInfinity, NaN References ========== .. [1] https://en.wikipedia.org/wiki/Infinity """ is_commutative = True is_positive = True is_infinite = True is_number = True is_prime = False __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"\infty" def _eval_subs(self, old, new): if self == old: return new @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number): if other is S.NegativeInfinity or other is S.NaN: return S.NaN return self return NotImplemented __radd__ = __add__ @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number): if other is S.Infinity or other is S.NaN: return S.NaN return self return NotImplemented @_sympifyit('other', NotImplemented) def __rsub__(self, other): return (-self).__add__(other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number): if other.is_zero or other is S.NaN: return S.NaN if other.is_positive: return self return S.NegativeInfinity return NotImplemented __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number): if other is S.Infinity or \ other is S.NegativeInfinity or \ other is S.NaN: return S.NaN if other.is_nonnegative: return self return S.NegativeInfinity return NotImplemented __truediv__ = __div__ def __abs__(self): return S.Infinity def __neg__(self): return S.NegativeInfinity def _eval_power(self, expt): """ ``expt`` is symbolic object but not equal to 0 or 1. ================ ======= ============================== Expression Result Notes ================ ======= ============================== ``oo nan`` ``nan`` ``oo -p`` ``0`` ``p`` is number, ``oo`` ================ ======= ============================== See Also ======== Pow NaN NegativeInfinity """ from sympy.functions import re if expt.is_positive: return S.Infinity if expt.is_negative: return S.Zero if expt is S.NaN: return S.NaN if expt is S.ComplexInfinity: return S.NaN if expt.is_real is False and expt.is_number: expt_real = re(expt) if expt_real.is_positive: return S.ComplexInfinity if expt_real.is_negative: return S.Zero if expt_real.is_zero: return S.NaN return selfexpt.evalf() def _as_mpf_val(self, prec): return mlib.finf def _sage_(self): import sage.all as sage return sage.oo def __hash__(self): return super(Infinity, self).__hash__() def __eq__(self, other): return other is S.Infinity or other == float('inf') def __ne__(self, other): return other is not S.Infinity and other != float('inf') def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_real: return S.false return Expr.__lt__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_real: if other.is_finite or other is S.NegativeInfinity: return S.false elif other.is_nonpositive: return S.false elif other.is_infinite and other.is_positive: return S.true return Expr.__le__(self, other) def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_real: if other.is_finite or other is S.NegativeInfinity: return S.true elif other.is_nonpositive: return S.true elif other.is_infinite and other.is_positive: return S.false return Expr.__gt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_real: return S.true return Expr.__ge__(self, other) def __mod__(self, other): return S.NaN __rmod__ = __mod__ def floor(self): return self def ceiling(self): return self oo = S.Infinity class NegativeInfinity(with_metaclass(Singleton, Number)): """Negative infinite quantity. NegativeInfinity is a singleton, and can be accessed by ``S.NegativeInfinity``. See Also ======== Infinity """ is_commutative = True is_negative = True is_infinite = True is_number = True __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"-\infty" def _eval_subs(self, old, new): if self == old: return new @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number): if other is S.Infinity or other is S.NaN: return S.NaN return self return NotImplemented __radd__ = __add__ @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number): if other is S.NegativeInfinity or other is S.NaN: return S.NaN return self return NotImplemented @_sympifyit('other', NotImplemented) def __rsub__(self, other): return (-self).__add__(other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number): if other.is_zero or other is S.NaN: return S.NaN if other.is_positive: return self return S.Infinity return NotImplemented __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number): if other is S.Infinity or \ other is S.NegativeInfinity or \ other is S.NaN: return S.NaN if other.is_nonnegative: return self return S.Infinity return NotImplemented __truediv__ = __div__ def __abs__(self): return S.Infinity def __neg__(self): return S.Infinity def _eval_power(self, expt): """ ``expt`` is symbolic object but not equal to 0 or 1. ================ ======= ============================== Expression Result Notes ================ ======= ============================== ``(-oo) nan`` ``nan`` ``(-oo) oo`` ``nan`` ``(-oo) -oo`` ``nan`` ``(-oo) e`` ``oo`` ``e`` is positive even integer ``(-oo) o`` ``-oo`` ``o`` is positive odd integer ================ ======= ============================== See Also ======== Infinity Pow NaN """ if expt.is_number: if expt is S.NaN or \ expt is S.Infinity or \ expt is S.NegativeInfinity: return S.NaN if isinstance(expt, Integer) and expt.is_positive: if expt.is_odd: return S.NegativeInfinity else: return S.Infinity return S.NegativeOneexptS.Infinityexpt def _as_mpf_val(self, prec): return mlib.fninf def _sage_(self): import sage.all as sage return -(sage.oo) def __hash__(self): return super(NegativeInfinity, self).__hash__() def __eq__(self, other): return other is S.NegativeInfinity or other == float('-inf') def __ne__(self, other): return other is not S.NegativeInfinity and other != float('-inf') def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_real: if other.is_finite or other is S.Infinity: return S.true elif other.is_nonnegative: return S.true elif other.is_infinite and other.is_negative: return S.false return Expr.__lt__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_real: return S.true return Expr.__le__(self, other) def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_real: return S.false return Expr.__gt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_real: if other.is_finite or other is S.Infinity: return S.false elif other.is_nonnegative: return S.false elif other.is_infinite and other.is_negative: return S.true return Expr.__ge__(self, other) def __mod__(self, other): return S.NaN __rmod__ = __mod__ def floor(self): return self def ceiling(self): return self class NaN(with_metaclass(Singleton, Number)): """ Not a Number. This serves as a place holder for numeric values that are indeterminate. Most operations on NaN, produce another NaN. Most indeterminate forms, such as ``0/0`` or ``oo - oo` produce NaN. Two exceptions are ``00`` and ``oo0``, which all produce ``1`` (this is consistent with Python's float). NaN is loosely related to floating point nan, which is defined in the IEEE 754 floating point standard, and corresponds to the Python ``float('nan')``. Differences are noted below. NaN is mathematically not equal to anything else, even NaN itself. This explains the initially counter-intuitive results with ``Eq`` and ``==`` in the examples below. NaN is not comparable so inequalities raise a TypeError. This is in constrast with floating point nan where all inequalities are false. NaN is a singleton, and can be accessed by ``S.NaN``, or can be imported as ``nan``. Examples ======== >>> from sympy import nan, S, oo, Eq >>> nan is S.NaN True >>> oo - oo nan >>> nan + 1 nan >>> Eq(nan, nan) # mathematical equality False >>> nan == nan # structural equality True References ========== .. [1] https://en.wikipedia.org/wiki/NaN """ is_commutative = True is_real = None is_rational = None is_algebraic = None is_transcendental = None is_integer = None is_comparable = False is_finite = None is_zero = None is_prime = None is_positive = None is_negative = None is_number = True __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"\text{NaN}" @_sympifyit('other', NotImplemented) def __add__(self, other): return self @_sympifyit('other', NotImplemented) def __sub__(self, other): return self @_sympifyit('other', NotImplemented) def __mul__(self, other): return self @_sympifyit('other', NotImplemented) def __div__(self, other): return self __truediv__ = __div__ def floor(self): return self def ceiling(self): return self def _as_mpf_val(self, prec): return _mpf_nan def _sage_(self): import sage.all as sage return sage.NaN def __hash__(self): return super(NaN, self).__hash__() def __eq__(self, other): # NaN is structurally equal to another NaN return other is S.NaN def __ne__(self, other): return other is not S.NaN def _eval_Eq(self, other): # NaN is not mathematically equal to anything, even NaN return S.false # Expr will _sympify and raise TypeError __gt__ = Expr.__gt__ __ge__ = Expr.__ge__ __lt__ = Expr.__lt__ __le__ = Expr.__le__ nan = S.NaN class ComplexInfinity(with_metaclass(Singleton, AtomicExpr)): r"""Complex infinity. In complex analysis the symbol `\tilde\infty`, called "complex infinity", represents a quantity with infinite magnitude, but undetermined complex phase. ComplexInfinity is a singleton, and can be accessed by ``S.ComplexInfinity``, or can be imported as ``zoo``. Examples ======== >>> from sympy import zoo, oo >>> zoo + 42 zoo >>> 42/zoo 0 >>> zoo + zoo nan >>> zoozoo zoo See Also ======== Infinity """ is_commutative = True is_infinite = True is_number = True is_prime = False is_complex = True is_real = False __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"\tilde{\infty}" @staticmethod def __abs__(): return S.Infinity def floor(self): return self def ceiling(self): return self @staticmethod def __neg__(): return S.ComplexInfinity def _eval_power(self, expt): if expt is S.ComplexInfinity: return S.NaN if isinstance(expt, Number): if expt is S.Zero: return S.NaN else: if expt.is_positive: return S.ComplexInfinity else: return S.Zero def _sage_(self): import sage.all as sage return sage.UnsignedInfinityRing.gen() zoo = S.ComplexInfinity class NumberSymbol(AtomicExpr): is_commutative = True is_finite = True is_number = True __slots__ = [] is_NumberSymbol = True def __new__(cls): return AtomicExpr.__new__(cls) def approximation(self, number_cls): """ Return an interval with number_cls endpoints that contains the value of NumberSymbol. If not implemented, then return None. """ def _eval_evalf(self, prec): return Float._new(self._as_mpf_val(prec), prec) def __eq__(self, other): try: other = _sympify(other) except SympifyError: return NotImplemented if self is other: return True if other.is_Number and self.is_irrational: return False return False # NumberSymbol != non-(Number\|self) def __ne__(self, other): return not self == other def __le__(self, other): if self is other: return S.true return Expr.__le__(self, other) def __ge__(self, other): if self is other: return S.true return Expr.__ge__(self, other) def __int__(self): # subclass with appropriate return value raise NotImplementedError def __long__(self): return self.__int__() def __hash__(self): return super(NumberSymbol, self).__hash__() class Exp1(with_metaclass(Singleton, NumberSymbol)): r"""The `e` constant. The transcendental number `e = 2.718281828\ldots` is the base of the natural logarithm and of the exponential function, `e = \exp(1)`. Sometimes called Euler's number or Napier's constant. Exp1 is a singleton, and can be accessed by ``S.Exp1``, or can be imported as ``E``. Examples ======== >>> from sympy import exp, log, E >>> E is exp(1) True >>> log(E) 1 References ========== .. [1] https://en.wikipedia.org/wiki/E_%28mathematical_constant%29 """ is_real = True is_positive = True is_negative = False # XXX Forces is_negative/is_nonnegative is_irrational = True is_number = True is_algebraic = False is_transcendental = True __slots__ = [] def _latex(self, printer): return r"e" @staticmethod def __abs__(): return S.Exp1 def __int__(self): return 2 def _as_mpf_val(self, prec): return mpf_e(prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (Integer(2), Integer(3)) elif issubclass(number_cls, Rational): pass def _eval_power(self, expt): from sympy import exp return exp(expt) def _eval_rewrite_as_sin(self, *kwargs): from sympy import sin I = S.ImaginaryUnit return sin(I + S.Pi/2) - Isin(I) def _eval_rewrite_as_cos(self, *kwargs): from sympy import cos I = S.ImaginaryUnit return cos(I) + Icos(I + S.Pi/2) def _sage_(self): import sage.all as sage return sage.e E = S.Exp1 class Pi(with_metaclass(Singleton, NumberSymbol)): r"""The `\pi` constant. The transcendental number `\pi = 3.141592654\ldots` represents the ratio of a circle's circumference to its diameter, the area of the unit circle, the half-period of trigonometric functions, and many other things in mathematics. Pi is a singleton, and can be accessed by ``S.Pi``, or can be imported as ``pi``. Examples ======== >>> from sympy import S, pi, oo, sin, exp, integrate, Symbol >>> S.Pi pi >>> pi > 3 True >>> pi.is_irrational True >>> x = Symbol('x') >>> sin(x + 2pi) sin(x) >>> integrate(exp(-x2), (x, -oo, oo)) sqrt(pi) References ========== .. [1] https://en.wikipedia.org/wiki/Pi """ is_real = True is_positive = True is_negative = False is_irrational = True is_number = True is_algebraic = False is_transcendental = True __slots__ = [] def _latex(self, printer): return r"\pi" @staticmethod def __abs__(): return S.Pi def __int__(self): return 3 def _as_mpf_val(self, prec): return mpf_pi(prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (Integer(3), Integer(4)) elif issubclass(number_cls, Rational): return (Rational(223, 71), Rational(22, 7)) def _sage_(self): import sage.all as sage return sage.pi pi = S.Pi class GoldenRatio(with_metaclass(Singleton, NumberSymbol)): r"""The golden ratio, `\phi`. `\phi = \frac{1 + \sqrt{5}}{2}` is algebraic number. Two quantities are in the golden ratio if their ratio is the same as the ratio of their sum to the larger of the two quantities, i.e. their maximum. GoldenRatio is a singleton, and can be accessed by ``S.GoldenRatio``. Examples ======== >>> from sympy import S >>> S.GoldenRatio > 1 True >>> S.GoldenRatio.expand(func=True) 1/2 + sqrt(5)/2 >>> S.GoldenRatio.is_irrational True References ========== .. [1] https://en.wikipedia.org/wiki/Golden_ratio """ is_real = True is_positive = True is_negative = False is_irrational = True is_number = True is_algebraic = True is_transcendental = False __slots__ = [] def _latex(self, printer): return r"\phi" def __int__(self): return 1 def _as_mpf_val(self, prec): # XXX track down why this has to be increased rv = mlib.from_man_exp(phi_fixed(prec + 10), -prec - 10) return mpf_norm(rv, prec) def _eval_expand_func(self, hints): from sympy import sqrt return S.Half + S.Halfsqrt(5) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.One, Rational(2)) elif issubclass(number_cls, Rational): pass def _sage_(self): import sage.all as sage return sage.golden_ratio _eval_rewrite_as_sqrt = _eval_expand_func class TribonacciConstant(with_metaclass(Singleton, NumberSymbol)): r"""The tribonacci constant. The tribonacci numbers are like the Fibonacci numbers, but instead of starting with two predetermined terms, the sequence starts with three predetermined terms and each term afterwards is the sum of the preceding three terms. The tribonacci constant is the ratio toward which adjacent tribonacci numbers tend. It is a root of the polynomial `x^3 - x^2 - x - 1 = 0`, and also satisfies the equation `x + x^{-3} = 2`. TribonacciConstant is a singleton, and can be accessed by ``S.TribonacciConstant``. Examples ======== >>> from sympy import S >>> S.TribonacciConstant > 1 True >>> S.TribonacciConstant.expand(func=True) 1/3 + (19 - 3sqrt(33))(1/3)/3 + (3sqrt(33) + 19)(1/3)/3 >>> S.TribonacciConstant.is_irrational True >>> S.TribonacciConstant.n(20) 1.8392867552141611326 References ========== .. [1] https://en.wikipedia.org/wiki/Generalizations_of_Fibonacci_numbers#Tribonacci_numbers """ is_real = True is_positive = True is_negative = False is_irrational = True is_number = True is_algebraic = True is_transcendental = False __slots__ = [] def _latex(self, printer): return r"\text{TribonacciConstant}" def __int__(self): return 2 def _eval_evalf(self, prec): rv = self._eval_expand_func(function=True)._eval_evalf(prec + 4) return Float(rv, precision=prec) def _eval_expand_func(self, hints): from sympy import sqrt, cbrt return (1 + cbrt(19 - 3sqrt(33)) + cbrt(19 + 3sqrt(33))) / 3 def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.One, Rational(2)) elif issubclass(number_cls, Rational): pass _eval_rewrite_as_sqrt = _eval_expand_func class EulerGamma(with_metaclass(Singleton, NumberSymbol)): r"""The Euler-Mascheroni constant. `\gamma = 0.5772157\ldots` (also called Euler's constant) is a mathematical constant recurring in analysis and number theory. It is defined as the limiting difference between the harmonic series and the natural logarithm: .. math:: \gamma = \lim\limits_{n\to\infty} \left(\sum\limits_{k=1}^n\frac{1}{k} - \ln n\right) EulerGamma is a singleton, and can be accessed by ``S.EulerGamma``. Examples ======== >>> from sympy import S >>> S.EulerGamma.is_irrational >>> S.EulerGamma > 0 True >>> S.EulerGamma > 1 False References ========== .. [1] https://en.wikipedia.org/wiki/Euler%E2%80%93Mascheroni_constant """ is_real = True is_positive = True is_negative = False is_irrational = None is_number = True __slots__ = [] def _latex(self, printer): return r"\gamma" def __int__(self): return 0 def _as_mpf_val(self, prec): # XXX track down why this has to be increased v = mlib.libhyper.euler_fixed(prec + 10) rv = mlib.from_man_exp(v, -prec - 10) return mpf_norm(rv, prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.Zero, S.One) elif issubclass(number_cls, Rational): return (S.Half, Rational(3, 5)) def _sage_(self): import sage.all as sage return sage.euler_gamma class Catalan(with_metaclass(Singleton, NumberSymbol)): r"""Catalan's constant. `K = 0.91596559\ldots` is given by the infinite series .. math:: K = \sum_{k=0}^{\infty} \frac{(-1)^k}{(2k+1)^2} Catalan is a singleton, and can be accessed by ``S.Catalan``. Examples ======== >>> from sympy import S >>> S.Catalan.is_irrational >>> S.Catalan > 0 True >>> S.Catalan > 1 False References ========== .. [1] https://en.wikipedia.org/wiki/Catalan%27s_constant """ is_real = True is_positive = True is_negative = False is_irrational = None is_number = True __slots__ = [] def __int__(self): return 0 def _as_mpf_val(self, prec): # XXX track down why this has to be increased v = mlib.catalan_fixed(prec + 10) rv = mlib.from_man_exp(v, -prec - 10) return mpf_norm(rv, prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.Zero, S.One) elif issubclass(number_cls, Rational): return (Rational(9, 10), S.One) def _sage_(self): import sage.all as sage return sage.catalan class ImaginaryUnit(with_metaclass(Singleton, AtomicExpr)): r"""The imaginary unit, `i = \sqrt{-1}`. I is a singleton, and can be accessed by ``S.I``, or can be imported as ``I``. Examples ======== >>> from sympy import I, sqrt >>> sqrt(-1) I >>> II -1 >>> 1/I -I References ========== .. [1] https://en.wikipedia.org/wiki/Imaginary_unit """ is_commutative = True is_imaginary = True is_finite = True is_number = True is_algebraic = True is_transcendental = False __slots__ = [] def _latex(self, printer): return printer._settings['imaginary_unit_latex'] @staticmethod def __abs__(): return S.One def _eval_evalf(self, prec): return self def _eval_conjugate(self): return -S.ImaginaryUnit def _eval_power(self, expt): """ b is I = sqrt(-1) e is symbolic object but not equal to 0, 1 Ir -> (-1)(r/2) -> exp(r/2PiI) -> sin(Pir/2) + cos(Pir/2)I, r is decimal I0 mod 4 -> 1 I1 mod 4 -> I I2 mod 4 -> -1 I3 mod 4 -> -I """ if isinstance(expt, Number): if isinstance(expt, Integer): expt = expt.p % 4 if expt == 0: return S.One if expt == 1: return S.ImaginaryUnit if expt == 2: return -S.One return -S.ImaginaryUnit return def as_base_exp(self): return S.NegativeOne, S.Half def _sage_(self): import sage.all as sage return sage.I @property def _mpc_(self): return (Float(0)._mpf_, Float(1)._mpf_) I = S.ImaginaryUnit def sympify_fractions(f): return Rational(f.numerator, f.denominator, 1) converter[fractions.Fraction] = sympify_fractions try: if HAS_GMPY == 2: import gmpy2 as gmpy elif HAS_GMPY == 1: import gmpy else: raise ImportError def sympify_mpz(x): return Integer(long(x)) def sympify_mpq(x): return Rational(long(x.numerator), long(x.denominator)) converter[type(gmpy.mpz(1))] = sympify_mpz converter[type(gmpy.mpq(1, 2))] = sympify_mpq except ImportError: pass def sympify_mpmath(x): return Expr._from_mpmath(x, x.context.prec) converter[mpnumeric] = sympify_mpmath def sympify_mpq(x): p, q = x._mpq_ return Rational(p, q, 1) converter[type(mpmath.rational.mpq(1, 2))] = sympify_mpq def sympify_complex(a): real, imag = list(map(sympify, (a.real, a.imag))) return real + S.ImaginaryUnit*imag converter[complex] = sympify_complex from .power import Pow, integer_nthroot from .mul import Mul Mul.identity = One() from .add import Add Add.identity = Zero()
ecaf9178de4a8436b4d06de7f293265a82447e5f260be4139f31da36e8bf4470	from __future__ import print_function, division from sympy.core.sympify import _sympify, sympify from sympy.core.basic import Basic from sympy.core.cache import cacheit from sympy.core.compatibility import ordered, range from sympy.core.logic import fuzzy_and from sympy.core.evaluate import global_evaluate from sympy.utilities.iterables import sift class AssocOp(Basic): """ Associative operations, can separate noncommutative and commutative parts. (a op b) op c == a op (b op c) == a op b op c. Base class for Add and Mul. This is an abstract base class, concrete derived classes must define the attribute `identity`. """ # for performance reason, we don't let is_commutative go to assumptions, # and keep it right here __slots__ = ['is_commutative'] @cacheit def __new__(cls, args, options): from sympy import Order args = list(map(_sympify, args)) args = [a for a in args if a is not cls.identity] evaluate = options.get('evaluate') if evaluate is None: evaluate = global_evaluate[0] if not evaluate: obj = cls._from_args(args) obj = cls._exec_constructor_postprocessors(obj) return obj if len(args) == 0: return cls.identity if len(args) == 1: return args[0] c_part, nc_part, order_symbols = cls.flatten(args) is_commutative = not nc_part obj = cls._from_args(c_part + nc_part, is_commutative) obj = cls._exec_constructor_postprocessors(obj) if order_symbols is not None: return Order(obj, order_symbols) return obj @classmethod def _from_args(cls, args, is_commutative=None): """Create new instance with already-processed args""" if len(args) == 0: return cls.identity elif len(args) == 1: return args[0] obj = super(AssocOp, cls).__new__(cls, args) if is_commutative is None: is_commutative = fuzzy_and(a.is_commutative for a in args) obj.is_commutative = is_commutative return obj def _new_rawargs(self, args, *kwargs): """Create new instance of own class with args exactly as provided by caller but returning the self class identity if args is empty. This is handy when we want to optimize things, e.g. >>> from sympy import Mul, S >>> from sympy.abc import x, y >>> e = Mul(3, x, y) >>> e.args (3, x, y) >>> Mul(e.args[1:]) xy >>> e._new_rawargs(e.args[1:]) # the same as above, but faster xy Note: use this with caution. There is no checking of arguments at all. This is best used when you are rebuilding an Add or Mul after simply removing one or more args. If, for example, modifications, result in extra 1s being inserted (as when collecting an expression's numerators and denominators) they will not show up in the result but a Mul will be returned nonetheless: >>> m = (xy)._new_rawargs(S.One, x); m x >>> m == x False >>> m.is_Mul True Another issue to be aware of is that the commutativity of the result is based on the commutativity of self. If you are rebuilding the terms that came from a commutative object then there will be no problem, but if self was non-commutative then what you are rebuilding may now be commutative. Although this routine tries to do as little as possible with the input, getting the commutativity right is important, so this level of safety is enforced: commutativity will always be recomputed if self is non-commutative and kwarg `reeval=False` has not been passed. """ if kwargs.pop('reeval', True) and self.is_commutative is False: is_commutative = None else: is_commutative = self.is_commutative return self._from_args(args, is_commutative) @classmethod def flatten(cls, seq): """Return seq so that none of the elements are of type `cls`. This is the vanilla routine that will be used if a class derived from AssocOp does not define its own flatten routine.""" # apply associativity, no commutativity property is used new_seq = [] while seq: o = seq.pop() if o.__class__ is cls: # classes must match exactly seq.extend(o.args) else: new_seq.append(o) new_seq.reverse() # c_part, nc_part, order_symbols return [], new_seq, None def _matches_commutative(self, expr, repl_dict={}, old=False): """ Matches Add/Mul "pattern" to an expression "expr". repl_dict ... a dictionary of (wild: expression) pairs, that get returned with the results This function is the main workhorse for Add/Mul. For instance: >>> from sympy import symbols, Wild, sin >>> a = Wild("a") >>> b = Wild("b") >>> c = Wild("c") >>> x, y, z = symbols("x y z") >>> (a+sin(b)c)._matches_commutative(x+sin(y)z) {a_: x, b_: y, c_: z} In the example above, "a+sin(b)c" is the pattern, and "x+sin(y)z" is the expression. The repl_dict contains parts that were already matched. For example here: >>> (x+sin(b)c)._matches_commutative(x+sin(y)z, repl_dict={a: x}) {a_: x, b_: y, c_: z} the only function of the repl_dict is to return it in the result, e.g. if you omit it: >>> (x+sin(b)c)._matches_commutative(x+sin(y)z) {b_: y, c_: z} the "a: x" is not returned in the result, but otherwise it is equivalent. """ # make sure expr is Expr if pattern is Expr from .expr import Add, Expr from sympy import Mul if isinstance(self, Expr) and not isinstance(expr, Expr): return None # handle simple patterns if self == expr: return repl_dict d = self._matches_simple(expr, repl_dict) if d is not None: return d # eliminate exact part from pattern: (2+a+w1+w2).matches(expr) -> (w1+w2).matches(expr-a-2) from .function import WildFunction from .symbol import Wild wild_part, exact_part = sift(self.args, lambda p: p.has(Wild, WildFunction) and not expr.has(p), binary=True) if not exact_part: wild_part = list(ordered(wild_part)) else: exact = self._new_rawargs(exact_part) free = expr.free_symbols if free and (exact.free_symbols - free): # there are symbols in the exact part that are not # in the expr; but if there are no free symbols, let # the matching continue return None newexpr = self._combine_inverse(expr, exact) if not old and (expr.is_Add or expr.is_Mul): if newexpr.count_ops() > expr.count_ops(): return None newpattern = self._new_rawargs(wild_part) return newpattern.matches(newexpr, repl_dict) # now to real work ;) i = 0 saw = set() while expr not in saw: saw.add(expr) expr_list = (self.identity,) + tuple(ordered(self.make_args(expr))) for last_op in reversed(expr_list): for w in reversed(wild_part): d1 = w.matches(last_op, repl_dict) if d1 is not None: d2 = self.xreplace(d1).matches(expr, d1) if d2 is not None: return d2 if i == 0: if self.is_Mul: # make e*i look like Mul if expr.is_Pow and expr.exp.is_Integer: if expr.exp > 0: expr = Mul([expr.base, expr.base*(expr.exp - 1)], evaluate=False) else: expr = Mul([1/expr.base, expr.base*(expr.exp + 1)], evaluate=False) i += 1 continue elif self.is_Add: # make ie look like Add c, e = expr.as_coeff_Mul() if abs(c) > 1: if c > 0: expr = Add([e, (c - 1)e], evaluate=False) else: expr = Add([-e, (c + 1)e], evaluate=False) i += 1 continue # try collection on non-Wild symbols from sympy.simplify.radsimp import collect was = expr did = set() for w in reversed(wild_part): c, w = w.as_coeff_mul(Wild) free = c.free_symbols - did if free: did.update(free) expr = collect(expr, free) if expr != was: i += 0 continue break # if we didn't continue, there is nothing more to do return def _has_matcher(self): """Helper for .has()""" def _ncsplit(expr): # this is not the same as args_cnc because here # we don't assume expr is a Mul -- hence deal with args -- # and always return a set. cpart, ncpart = sift(expr.args, lambda arg: arg.is_commutative is True, binary=True) return set(cpart), ncpart c, nc = _ncsplit(self) cls = self.__class__ def is_in(expr): if expr == self: return True elif not isinstance(expr, Basic): return False elif isinstance(expr, cls): _c, _nc = _ncsplit(expr) if (c & _c) == c: if not nc: return True elif len(nc) <= len(_nc): for i in range(len(_nc) - len(nc) + 1): if _nc[i:i + len(nc)] == nc: return True return False return is_in def _eval_evalf(self, prec): """ Evaluate the parts of self that are numbers; if the whole thing was a number with no functions it would have been evaluated, but it wasn't so we must judiciously extract the numbers and reconstruct the object. This is not simply replacing numbers with evaluated numbers. Nunmbers should be handled in the largest pure-number expression as possible. So the code below separates ``self`` into number and non-number parts and evaluates the number parts and walks the args of the non-number part recursively (doing the same thing). """ from .add import Add from .mul import Mul from .symbol import Symbol from .function import AppliedUndef if isinstance(self, (Mul, Add)): x, tail = self.as_independent(Symbol, AppliedUndef) # if x is an AssocOp Function then the _evalf below will # call _eval_evalf (here) so we must break the recursion if not (tail is self.identity or isinstance(x, AssocOp) and x.is_Function or x is self.identity and isinstance(tail, AssocOp)): # here, we have a number so we just call to _evalf with prec; # prec is not the same as n, it is the binary precision so # that's why we don't call to evalf. x = x._evalf(prec) if x is not self.identity else self.identity args = [] tail_args = tuple(self.func.make_args(tail)) for a in tail_args: # here we call to _eval_evalf since we don't know what we # are dealing with and all other _eval_evalf routines should # be doing the same thing (i.e. taking binary prec and # finding the evalf-able args) newa = a._eval_evalf(prec) if newa is None: args.append(a) else: args.append(newa) return self.func(x, args) # this is the same as above, but there were no pure-number args to # deal with args = [] for a in self.args: newa = a._eval_evalf(prec) if newa is None: args.append(a) else: args.append(newa) return self.func(args) @classmethod def make_args(cls, expr): """ Return a sequence of elements `args` such that cls(args) == expr >>> from sympy import Symbol, Mul, Add >>> x, y = map(Symbol, 'xy') >>> Mul.make_args(xy) (x, y) >>> Add.make_args(xy) (xy,) >>> set(Add.make_args(xy + y)) == set([y, xy]) True """ if isinstance(expr, cls): return expr.args else: return (sympify(expr),) class ShortCircuit(Exception): pass class LatticeOp(AssocOp): """ Join/meet operations of an algebraic lattice[1]. These binary operations are associative (op(op(a, b), c) = op(a, op(b, c))), commutative (op(a, b) = op(b, a)) and idempotent (op(a, a) = op(a) = a). Common examples are AND, OR, Union, Intersection, max or min. They have an identity element (op(identity, a) = a) and an absorbing element conventionally called zero (op(zero, a) = zero). This is an abstract base class, concrete derived classes must declare attributes zero and identity. All defining properties are then respected. >>> from sympy import Integer >>> from sympy.core.operations import LatticeOp >>> class my_join(LatticeOp): ... zero = Integer(0) ... identity = Integer(1) >>> my_join(2, 3) == my_join(3, 2) True >>> my_join(2, my_join(3, 4)) == my_join(2, 3, 4) True >>> my_join(0, 1, 4, 2, 3, 4) 0 >>> my_join(1, 2) 2 References: [1] - https://en.wikipedia.org/wiki/Lattice_%28order%29 """ is_commutative = True def __new__(cls, args, options): args = (_sympify(arg) for arg in args) try: # /!\ args is a generator and _new_args_filter # must be careful to handle as such; this # is done so short-circuiting can be done # without having to sympify all values _args = frozenset(cls._new_args_filter(args)) except ShortCircuit: return sympify(cls.zero) if not _args: return sympify(cls.identity) elif len(_args) == 1: return set(_args).pop() else: # XXX in almost every other case for __new__, _args is # passed along, but the expectation here is for _args obj = super(AssocOp, cls).__new__(cls, _args) obj._argset = _args return obj @classmethod def _new_args_filter(cls, arg_sequence, call_cls=None): """Generator filtering args""" ncls = call_cls or cls for arg in arg_sequence: if arg == ncls.zero: raise ShortCircuit(arg) elif arg == ncls.identity: continue elif arg.func == ncls: for x in arg.args: yield x else: yield arg @classmethod def make_args(cls, expr): """ Return a set of args such that cls(*arg_set) == expr. """ if isinstance(expr, cls): return expr._argset else: return frozenset([sympify(expr)]) @property @cacheit def args(self): return tuple(ordered(self._argset)) @staticmethod def _compare_pretty(a, b): return (str(a) > str(b)) - (str(a) < str(b))
1bb672709eb717759fd695f5e22bf4a0d6cd82c8350b1dce51ac36d00039ec9d	""" Reimplementations of constructs introduced in later versions of Python than we support. Also some functions that are needed SymPy-wide and are located here for easy import. """ from __future__ import print_function, division import operator from collections import defaultdict from sympy.external import import_module """ Python 2 and Python 3 compatible imports String and Unicode compatible changes: * `unicode()` removed in Python 3, import `unicode` for Python 2/3 compatible function * `unichr()` removed in Python 3, import `unichr` for Python 2/3 compatible function * Use `u()` for escaped unicode sequences (e.g. u'\u2020' -> u('\u2020')) * Use `u_decode()` to decode utf-8 formatted unicode strings * `string_types` gives str in Python 3, unicode and str in Python 2, equivalent to basestring Integer related changes: * `long()` removed in Python 3, import `long` for Python 2/3 compatible function * `integer_types` gives int in Python 3, int and long in Python 2 Types related changes: * `class_types` gives type in Python 3, type and ClassType in Python 2 Renamed function attributes: * Python 2 `.func_code`, Python 3 `.__func__`, access with `get_function_code()` * Python 2 `.func_globals`, Python 3 `.__globals__`, access with `get_function_globals()` * Python 2 `.func_name`, Python 3 `.__name__`, access with `get_function_name()` Moved modules: * `reduce()` * `StringIO()` * `cStringIO()` (same as `StingIO()` in Python 3) * Python 2 `__builtins__`, access with Python 3 name, `builtins` Iterator/list changes: * `xrange` renamed as `range` in Python 3, import `range` for Python 2/3 compatible iterator version of range. exec: * Use `exec_()`, with parameters `exec_(code, globs=None, locs=None)` Metaclasses: * Use `with_metaclass()`, examples below * Define class `Foo` with metaclass `Meta`, and no parent: class Foo(with_metaclass(Meta)): pass * Define class `Foo` with metaclass `Meta` and parent class `Bar`: class Foo(with_metaclass(Meta, Bar)): pass """ import sys PY3 = sys.version_info[0] > 2 if PY3: class_types = type, integer_types = (int,) string_types = (str,) long = int int_info = sys.int_info # String / unicode compatibility unicode = str unichr = chr def u_decode(x): return x Iterator = object # Moved definitions get_function_code = operator.attrgetter("__code__") get_function_globals = operator.attrgetter("__globals__") get_function_name = operator.attrgetter("__name__") import builtins from functools import reduce from io import StringIO cStringIO = StringIO exec_ = getattr(builtins, "exec") range = range round = round from collections.abc import (Mapping, Callable, MutableMapping, MutableSet, Iterable, Hashable) from inspect import unwrap from itertools import accumulate else: import codecs import types class_types = (type, types.ClassType) integer_types = (int, long) string_types = (str, unicode) long = long int_info = sys.long_info # String / unicode compatibility unicode = unicode unichr = unichr def u_decode(x): return x.decode('utf-8') class Iterator(object): def next(self): return type(self).__next__(self) # Moved definitions get_function_code = operator.attrgetter("func_code") get_function_globals = operator.attrgetter("func_globals") get_function_name = operator.attrgetter("func_name") import __builtin__ as builtins reduce = reduce from StringIO import StringIO from cStringIO import StringIO as cStringIO def exec_(_code_, _globs_=None, _locs_=None): """Execute code in a namespace.""" if _globs_ is None: frame = sys._getframe(1) _globs_ = frame.f_globals if _locs_ is None: _locs_ = frame.f_locals del frame elif _locs_ is None: _locs_ = _globs_ exec("exec _code_ in _globs_, _locs_") range = xrange _round = round def round(x, args): try: return x.__round__(args) except (AttributeError, TypeError): return _round(x, args) from collections import (Mapping, Callable, MutableMapping, MutableSet, Iterable, Hashable) def unwrap(func, stop=None): """Get the object wrapped by func. Follows the chain of :attr:`__wrapped__` attributes returning the last object in the chain. stop* is an optional callback accepting an object in the wrapper chain as its sole argument that allows the unwrapping to be terminated early if the callback returns a true value. If the callback never returns a true value, the last object in the chain is returned as usual. For example, :func:`signature` uses this to stop unwrapping if any object in the chain has a ``__signature__`` attribute defined. :exc:`ValueError` is raised if a cycle is encountered. """ if stop is None: def _is_wrapper(f): return hasattr(f, '__wrapped__') else: def _is_wrapper(f): return hasattr(f, '__wrapped__') and not stop(f) f = func # remember the original func for error reporting memo = {id(f)} # Memoise by id to tolerate non-hashable objects while _is_wrapper(func): func = func.__wrapped__ id_func = id(func) if id_func in memo: raise ValueError('wrapper loop when unwrapping {!r}'.format(f)) memo.add(id_func) return func def accumulate(iterable, func=operator.add): state = iterable[0] yield state for i in iterable[1:]: state = func(state, i) yield state def with_metaclass(meta, bases): """ Create a base class with a metaclass. For example, if you have the metaclass >>> class Meta(type): ... pass Use this as the metaclass by doing >>> from sympy.core.compatibility import with_metaclass >>> class MyClass(with_metaclass(Meta, object)): ... pass This is equivalent to the Python 2:: class MyClass(object): __metaclass__ = Meta or Python 3:: class MyClass(object, metaclass=Meta): pass That is, the first argument is the metaclass, and the remaining arguments are the base classes. Note that if the base class is just ``object``, you may omit it. >>> MyClass.__mro__ (<class '...MyClass'>, <... 'object'>) >>> type(MyClass) <class '...Meta'> """ # This requires a bit of explanation: the basic idea is to make a dummy # metaclass for one level of class instantiation that replaces itself with # the actual metaclass. # Code copied from the 'six' library. class metaclass(meta): def __new__(cls, name, this_bases, d): return meta(name, bases, d) return type.__new__(metaclass, "NewBase", (), {}) # These are in here because telling if something is an iterable just by calling # hasattr(obj, "__iter__") behaves differently in Python 2 and Python 3. In # particular, hasattr(str, "__iter__") is False in Python 2 and True in Python 3. # I think putting them here also makes it easier to use them in the core. class NotIterable: """ Use this as mixin when creating a class which is not supposed to return true when iterable() is called on its instances because calling list() on the instance, for example, would result in an infinite loop. """ pass def iterable(i, exclude=(string_types, dict, NotIterable)): """ Return a boolean indicating whether ``i`` is SymPy iterable. True also indicates that the iterator is finite, e.g. you can call list(...) on the instance. When SymPy is working with iterables, it is almost always assuming that the iterable is not a string or a mapping, so those are excluded by default. If you want a pure Python definition, make exclude=None. To exclude multiple items, pass them as a tuple. You can also set the _iterable attribute to True or False on your class, which will override the checks here, including the exclude test. As a rule of thumb, some SymPy functions use this to check if they should recursively map over an object. If an object is technically iterable in the Python sense but does not desire this behavior (e.g., because its iteration is not finite, or because iteration might induce an unwanted computation), it should disable it by setting the _iterable attribute to False. See also: is_sequence Examples ======== >>> from sympy.utilities.iterables import iterable >>> from sympy import Tuple >>> things = [[1], (1,), set([1]), Tuple(1), (j for j in [1, 2]), {1:2}, '1', 1] >>> for i in things: ... print('%s %s' % (iterable(i), type(i))) True <... 'list'> True <... 'tuple'> True <... 'set'> True <class 'sympy.core.containers.Tuple'> True <... 'generator'> False <... 'dict'> False <... 'str'> False <... 'int'> >>> iterable({}, exclude=None) True >>> iterable({}, exclude=str) True >>> iterable("no", exclude=str) False """ if hasattr(i, '_iterable'): return i._iterable try: iter(i) except TypeError: return False if exclude: return not isinstance(i, exclude) return True def is_sequence(i, include=None): """ Return a boolean indicating whether ``i`` is a sequence in the SymPy sense. If anything that fails the test below should be included as being a sequence for your application, set 'include' to that object's type; multiple types should be passed as a tuple of types. Note: although generators can generate a sequence, they often need special handling to make sure their elements are captured before the generator is exhausted, so these are not included by default in the definition of a sequence. See also: iterable Examples ======== >>> from sympy.utilities.iterables import is_sequence >>> from types import GeneratorType >>> is_sequence([]) True >>> is_sequence(set()) False >>> is_sequence('abc') False >>> is_sequence('abc', include=str) True >>> generator = (c for c in 'abc') >>> is_sequence(generator) False >>> is_sequence(generator, include=(str, GeneratorType)) True """ return (hasattr(i, '__getitem__') and iterable(i) or bool(include) and isinstance(i, include)) try: from itertools import zip_longest except ImportError: # Python 2.7 from itertools import izip_longest as zip_longest try: # Python 2.7 from string import maketrans except ImportError: maketrans = str.maketrans def as_int(n, strict=True): """ Convert the argument to a builtin integer. The return value is guaranteed to be equal to the input. ValueError is raised if the input has a non-integral value. When ``strict`` is False, non-integer input that compares equal to the integer value will not raise an error. Examples ======== >>> from sympy.core.compatibility import as_int >>> from sympy import sqrt, S The function is primarily concerned with sanitizing input for functions that need to work with builtin integers, so anything that is unambiguously an integer should be returned as an int: >>> as_int(S(3)) 3 Floats, being of limited precision, are not assumed to be exact and will raise an error unless the ``strict`` flag is False. This precision issue becomes apparent for large floating point numbers: >>> big = 1e23 >>> type(big) is float True >>> big == int(big) True >>> as_int(big) Traceback (most recent call last): ... ValueError: ... is not an integer >>> as_int(big, strict=False) 99999999999999991611392 Input that might be a complex representation of an integer value is also rejected by default: >>> one = sqrt(3 + 2sqrt(2)) - sqrt(2) >>> int(one) == 1 True >>> as_int(one) Traceback (most recent call last): ... ValueError: ... is not an integer """ from sympy.core.numbers import Integer try: if strict and not isinstance(n, SYMPY_INTS + (Integer,)): raise TypeError result = int(n) if result != n: raise TypeError return result except TypeError: raise ValueError('%s is not an integer' % (n,)) def default_sort_key(item, order=None): """Return a key that can be used for sorting. The key has the structure: (class_key, (len(args), args), exponent.sort_key(), coefficient) This key is supplied by the sort_key routine of Basic objects when ``item`` is a Basic object or an object (other than a string) that sympifies to a Basic object. Otherwise, this function produces the key. The ``order`` argument is passed along to the sort_key routine and is used to determine how the terms within an expression are ordered. (See examples below) ``order`` options are: 'lex', 'grlex', 'grevlex', and reversed values of the same (e.g. 'rev-lex'). The default order value is None (which translates to 'lex'). Examples ======== >>> from sympy import S, I, default_sort_key, sin, cos, sqrt >>> from sympy.core.function import UndefinedFunction >>> from sympy.abc import x The following are equivalent ways of getting the key for an object: >>> x.sort_key() == default_sort_key(x) True Here are some examples of the key that is produced: >>> default_sort_key(UndefinedFunction('f')) ((0, 0, 'UndefinedFunction'), (1, ('f',)), ((1, 0, 'Number'), (0, ()), (), 1), 1) >>> default_sort_key('1') ((0, 0, 'str'), (1, ('1',)), ((1, 0, 'Number'), (0, ()), (), 1), 1) >>> default_sort_key(S.One) ((1, 0, 'Number'), (0, ()), (), 1) >>> default_sort_key(2) ((1, 0, 'Number'), (0, ()), (), 2) While sort_key is a method only defined for SymPy objects, default_sort_key will accept anything as an argument so it is more robust as a sorting key. For the following, using key= lambda i: i.sort_key() would fail because 2 doesn't have a sort_key method; that's why default_sort_key is used. Note, that it also handles sympification of non-string items likes ints: >>> a = [2, I, -I] >>> sorted(a, key=default_sort_key) [2, -I, I] The returned key can be used anywhere that a key can be specified for a function, e.g. sort, min, max, etc...: >>> a.sort(key=default_sort_key); a[0] 2 >>> min(a, key=default_sort_key) 2 Note ---- The key returned is useful for getting items into a canonical order that will be the same across platforms. It is not directly useful for sorting lists of expressions: >>> a, b = x, 1/x Since ``a`` has only 1 term, its value of sort_key is unaffected by ``order``: >>> a.sort_key() == a.sort_key('rev-lex') True If ``a`` and ``b`` are combined then the key will differ because there are terms that can be ordered: >>> eq = a + b >>> eq.sort_key() == eq.sort_key('rev-lex') False >>> eq.as_ordered_terms() [x, 1/x] >>> eq.as_ordered_terms('rev-lex') [1/x, x] But since the keys for each of these terms are independent of ``order``'s value, they don't sort differently when they appear separately in a list: >>> sorted(eq.args, key=default_sort_key) [1/x, x] >>> sorted(eq.args, key=lambda i: default_sort_key(i, order='rev-lex')) [1/x, x] The order of terms obtained when using these keys is the order that would be obtained if those terms were factors in a product. Although it is useful for quickly putting expressions in canonical order, it does not sort expressions based on their complexity defined by the number of operations, power of variables and others: >>> sorted([sin(x)cos(x), sin(x)], key=default_sort_key) [sin(x)cos(x), sin(x)] >>> sorted([x, x2, sqrt(x), x3], key=default_sort_key) [sqrt(x), x, x2, x3] See Also ======== ordered, sympy.core.expr.as_ordered_factors, sympy.core.expr.as_ordered_terms """ from .singleton import S from .basic import Basic from .sympify import sympify, SympifyError from .compatibility import iterable if isinstance(item, Basic): return item.sort_key(order=order) if iterable(item, exclude=string_types): if isinstance(item, dict): args = item.items() unordered = True elif isinstance(item, set): args = item unordered = True else: # e.g. tuple, list args = list(item) unordered = False args = [default_sort_key(arg, order=order) for arg in args] if unordered: # e.g. dict, set args = sorted(args) cls_index, args = 10, (len(args), tuple(args)) else: if not isinstance(item, string_types): try: item = sympify(item) except SympifyError: # e.g. lambda x: x pass else: if isinstance(item, Basic): # e.g int -> Integer return default_sort_key(item) # e.g. UndefinedFunction # e.g. str cls_index, args = 0, (1, (str(item),)) return (cls_index, 0, item.__class__.__name__ ), args, S.One.sort_key(), S.One def _nodes(e): """ A helper for ordered() which returns the node count of ``e`` which for Basic objects is the number of Basic nodes in the expression tree but for other objects is 1 (unless the object is an iterable or dict for which the sum of nodes is returned). """ from .basic import Basic if isinstance(e, Basic): return e.count(Basic) elif iterable(e): return 1 + sum(_nodes(ei) for ei in e) elif isinstance(e, dict): return 1 + sum(_nodes(k) + _nodes(v) for k, v in e.items()) else: return 1 def ordered(seq, keys=None, default=True, warn=False): """Return an iterator of the seq where keys are used to break ties in a conservative fashion: if, after applying a key, there are no ties then no other keys will be computed. Two default keys will be applied if 1) keys are not provided or 2) the given keys don't resolve all ties (but only if `default` is True). The two keys are `_nodes` (which places smaller expressions before large) and `default_sort_key` which (if the `sort_key` for an object is defined properly) should resolve any ties. If ``warn`` is True then an error will be raised if there were no keys remaining to break ties. This can be used if it was expected that there should be no ties between items that are not identical. Examples ======== >>> from sympy.utilities.iterables import ordered >>> from sympy import count_ops >>> from sympy.abc import x, y The count_ops is not sufficient to break ties in this list and the first two items appear in their original order (i.e. the sorting is stable): >>> list(ordered([y + 2, x + 2, x2 + y + 3], ... count_ops, default=False, warn=False)) ... [y + 2, x + 2, x2 + y + 3] The default_sort_key allows the tie to be broken: >>> list(ordered([y + 2, x + 2, x2 + y + 3])) ... [x + 2, y + 2, x2 + y + 3] Here, sequences are sorted by length, then sum: >>> seq, keys = [[[1, 2, 1], [0, 3, 1], [1, 1, 3], [2], [1]], [ ... lambda x: len(x), ... lambda x: sum(x)]] ... >>> list(ordered(seq, keys, default=False, warn=False)) [[1], [2], [1, 2, 1], [0, 3, 1], [1, 1, 3]] If ``warn`` is True, an error will be raised if there were not enough keys to break ties: >>> list(ordered(seq, keys, default=False, warn=True)) Traceback (most recent call last): ... ValueError: not enough keys to break ties Notes ===== The decorated sort is one of the fastest ways to sort a sequence for which special item comparison is desired: the sequence is decorated, sorted on the basis of the decoration (e.g. making all letters lower case) and then undecorated. If one wants to break ties for items that have the same decorated value, a second key can be used. But if the second key is expensive to compute then it is inefficient to decorate all items with both keys: only those items having identical first key values need to be decorated. This function applies keys successively only when needed to break ties. By yielding an iterator, use of the tie-breaker is delayed as long as possible. This function is best used in cases when use of the first key is expected to be a good hashing function; if there are no unique hashes from application of a key then that key should not have been used. The exception, however, is that even if there are many collisions, if the first group is small and one does not need to process all items in the list then time will not be wasted sorting what one was not interested in. For example, if one were looking for the minimum in a list and there were several criteria used to define the sort order, then this function would be good at returning that quickly if the first group of candidates is small relative to the number of items being processed. """ d = defaultdict(list) if keys: if not isinstance(keys, (list, tuple)): keys = [keys] keys = list(keys) f = keys.pop(0) for a in seq: d[f(a)].append(a) else: if not default: raise ValueError('if default=False then keys must be provided') d[None].extend(seq) for k in sorted(d.keys()): if len(d[k]) > 1: if keys: d[k] = ordered(d[k], keys, default, warn) elif default: d[k] = ordered(d[k], (_nodes, default_sort_key,), default=False, warn=warn) elif warn: from sympy.utilities.iterables import uniq u = list(uniq(d[k])) if len(u) > 1: raise ValueError( 'not enough keys to break ties: %s' % u) for v in d[k]: yield v d.pop(k) # If HAS_GMPY is 0, no supported version of gmpy is available. Otherwise, # HAS_GMPY contains the major version number of gmpy; i.e. 1 for gmpy, and # 2 for gmpy2. # Versions of gmpy prior to 1.03 do not work correctly with int(largempz) # For example, int(gmpy.mpz(2*256)) would raise OverflowError. # See issue 4980. # Minimum version of gmpy changed to 1.13 to allow a single code base to also # work with gmpy2. def _getenv(key, default=None): from os import getenv return getenv(key, default) GROUND_TYPES = _getenv('SYMPY_GROUND_TYPES', 'auto').lower() HAS_GMPY = 0 if GROUND_TYPES != 'python': # Don't try to import gmpy2 if ground types is set to gmpy1. This is # primarily intended for testing. if GROUND_TYPES != 'gmpy1': gmpy = import_module('gmpy2', min_module_version='2.0.0', module_version_attr='version', module_version_attr_call_args=()) if gmpy: HAS_GMPY = 2 else: GROUND_TYPES = 'gmpy' if not HAS_GMPY: gmpy = import_module('gmpy', min_module_version='1.13', module_version_attr='version', module_version_attr_call_args=()) if gmpy: HAS_GMPY = 1 if GROUND_TYPES == 'auto': if HAS_GMPY: GROUND_TYPES = 'gmpy' else: GROUND_TYPES = 'python' if GROUND_TYPES == 'gmpy' and not HAS_GMPY: from warnings import warn warn("gmpy library is not installed, switching to 'python' ground types") GROUND_TYPES = 'python' # SYMPY_INTS is a tuple containing the base types for valid integer types. SYMPY_INTS = integer_types if GROUND_TYPES == 'gmpy': SYMPY_INTS += (type(gmpy.mpz(0)),) # lru_cache compatible with py2.7 copied directly from # https://code.activestate.com/ # recipes/578078-py26-and-py30-backport-of-python-33s-lru-cache/ from collections import namedtuple from functools import update_wrapper from threading import RLock _CacheInfo = namedtuple("CacheInfo", ["hits", "misses", "maxsize", "currsize"]) class _HashedSeq(list): __slots__ = 'hashvalue' def __init__(self, tup, hash=hash): self[:] = tup self.hashvalue = hash(tup) def __hash__(self): return self.hashvalue def _make_key(args, kwds, typed, kwd_mark = (object(),), fasttypes = set((int, str, frozenset, type(None))), sorted=sorted, tuple=tuple, type=type, len=len): 'Make a cache key from optionally typed positional and keyword arguments' key = args if kwds: sorted_items = sorted(kwds.items()) key += kwd_mark for item in sorted_items: key += item if typed: key += tuple(type(v) for v in args) if kwds: key += tuple(type(v) for k, v in sorted_items) elif len(key) == 1 and type(key[0]) in fasttypes: return key[0] return _HashedSeq(key) def lru_cache(maxsize=100, typed=False): """Least-recently-used cache decorator. If maxsize* is set to None, the LRU features are disabled and the cache can grow without bound. If typed is True, arguments of different types will be cached separately. For example, f(3.0) and f(3) will be treated as distinct calls with distinct results. Arguments to the cached function must be hashable. View the cache statistics named tuple (hits, misses, maxsize, currsize) with f.cache_info(). Clear the cache and statistics with f.cache_clear(). Access the underlying function with f.__wrapped__. See: https://en.wikipedia.org/wiki/Cache_algorithms#Least_Recently_Used """ # Users should only access the lru_cache through its public API: # cache_info, cache_clear, and f.__wrapped__ # The internals of the lru_cache are encapsulated for thread safety and # to allow the implementation to change (including a possible C version). def decorating_function(user_function): cache = dict() stats = [0, 0] # make statistics updateable non-locally HITS, MISSES = 0, 1 # names for the stats fields make_key = _make_key cache_get = cache.get # bound method to lookup key or return None _len = len # localize the global len() function lock = RLock() # because linkedlist updates aren't threadsafe root = [] # root of the circular doubly linked list root[:] = [root, root, None, None] # initialize by pointing to self nonlocal_root = [root] # make updateable non-locally PREV, NEXT, KEY, RESULT = 0, 1, 2, 3 # names for the link fields if maxsize == 0: def wrapper(args, kwds): # no caching, just do a statistics update after a successful call result = user_function(args, *kwds) stats[MISSES] += 1 return result elif maxsize is None: def wrapper(args, *kwds): # simple caching without ordering or size limit key = make_key(args, kwds, typed) result = cache_get(key, root) # root used here as a unique not-found sentinel if result is not root: stats[HITS] += 1 return result result = user_function(args, *kwds) cache[key] = result stats[MISSES] += 1 return result else: def wrapper(args, *kwds): # size limited caching that tracks accesses by recency try: key = make_key(args, kwds, typed) if kwds or typed else args except TypeError: stats[MISSES] += 1 return user_function(args, *kwds) with lock: link = cache_get(key) if link is not None: # record recent use of the key by moving it to the front of the list root, = nonlocal_root link_prev, link_next, key, result = link link_prev[NEXT] = link_next link_next[PREV] = link_prev last = root[PREV] last[NEXT] = root[PREV] = link link[PREV] = last link[NEXT] = root stats[HITS] += 1 return result result = user_function(args, **kwds) with lock: root, = nonlocal_root if key in cache: # getting here means that this same key was added to the # cache while the lock was released. since the link # update is already done, we need only return the # computed result and update the count of misses. pass elif _len(cache) >= maxsize: # use the old root to store the new key and result oldroot = root oldroot[KEY] = key oldroot[RESULT] = result # empty the oldest link and make it the new root root = nonlocal_root[0] = oldroot[NEXT] oldkey = root[KEY] oldvalue = root[RESULT] root[KEY] = root[RESULT] = None # now update the cache dictionary for the new links del cache[oldkey] cache[key] = oldroot else: # put result in a new link at the front of the list last = root[PREV] link = [last, root, key, result] last[NEXT] = root[PREV] = cache[key] = link stats[MISSES] += 1 return result def cache_info(): """Report cache statistics""" with lock: return _CacheInfo(stats[HITS], stats[MISSES], maxsize, len(cache)) def cache_clear(): """Clear the cache and cache statistics""" with lock: cache.clear() root = nonlocal_root[0] root[:] = [root, root, None, None] stats[:] = [0, 0] wrapper.__wrapped__ = user_function wrapper.cache_info = cache_info wrapper.cache_clear = cache_clear return update_wrapper(wrapper, user_function) return decorating_function ### End of backported lru_cache if sys.version_info[:2] >= (3, 3): # 3.2 has an lru_cache with an incompatible API from functools import lru_cache try: from itertools import filterfalse except ImportError: # Python 2.7 def filterfalse(pred, itr): return filter(lambda x: not pred(x), itr)
ffb64f545d86050727bec7569564f81851771f369b1675fa4095d87eb66604dc	"""Algorithms for computing symbolic roots of polynomials. """ from __future__ import print_function, division import math from sympy.core import S, I, pi from sympy.core.compatibility import ordered, range, reduce from sympy.core.exprtools import factor_terms from sympy.core.function import _mexpand from sympy.core.logic import fuzzy_not from sympy.core.mul import expand_2arg, Mul from sympy.core.numbers import Rational, igcd, comp from sympy.core.power import Pow from sympy.core.relational import Eq from sympy.core.symbol import Dummy, Symbol, symbols from sympy.core.sympify import sympify from sympy.functions import exp, sqrt, im, cos, acos, Piecewise from sympy.functions.elementary.miscellaneous import root from sympy.ntheory import divisors, isprime, nextprime from sympy.polys.polyerrors import (PolynomialError, GeneratorsNeeded, DomainError) from sympy.polys.polyquinticconst import PolyQuintic from sympy.polys.polytools import Poly, cancel, factor, gcd_list, discriminant from sympy.polys.rationaltools import together from sympy.polys.specialpolys import cyclotomic_poly from sympy.simplify import simplify, powsimp from sympy.utilities import public def roots_linear(f): """Returns a list of roots of a linear polynomial.""" r = -f.nth(0)/f.nth(1) dom = f.get_domain() if not dom.is_Numerical: if dom.is_Composite: r = factor(r) else: r = simplify(r) return [r] def roots_quadratic(f): """Returns a list of roots of a quadratic polynomial. If the domain is ZZ then the roots will be sorted with negatives coming before positives. The ordering will be the same for any numerical coefficients as long as the assumptions tested are correct, otherwise the ordering will not be sorted (but will be canonical). """ a, b, c = f.all_coeffs() dom = f.get_domain() def _sqrt(d): # remove squares from square root since both will be represented # in the results; a similar thing is happening in roots() but # must be duplicated here because not all quadratics are binomials co = [] other = [] for di in Mul.make_args(d): if di.is_Pow and di.exp.is_Integer and di.exp % 2 == 0: co.append(Pow(di.base, di.exp//2)) else: other.append(di) if co: d = Mul(other) co = Mul(co) return cosqrt(d) return sqrt(d) def _simplify(expr): if dom.is_Composite: return factor(expr) else: return simplify(expr) if c is S.Zero: r0, r1 = S.Zero, -b/a if not dom.is_Numerical: r1 = _simplify(r1) elif r1.is_negative: r0, r1 = r1, r0 elif b is S.Zero: r = -c/a if not dom.is_Numerical: r = _simplify(r) R = _sqrt(r) r0 = -R r1 = R else: d = b2 - 4ac A = 2a B = -b/A if not dom.is_Numerical: d = _simplify(d) B = _simplify(B) D = factor_terms(_sqrt(d)/A) r0 = B - D r1 = B + D if a.is_negative: r0, r1 = r1, r0 elif not dom.is_Numerical: r0, r1 = [expand_2arg(i) for i in (r0, r1)] return [r0, r1] def roots_cubic(f, trig=False): """Returns a list of roots of a cubic polynomial. References ========== [1] https://en.wikipedia.org/wiki/Cubic_function, General formula for roots, (accessed November 17, 2014). """ if trig: a, b, c, d = f.all_coeffs() p = (3ac - b2)/3/a2 q = (2b3 - 9abc + 27a2d)/(27a3) D = 18abcd - 4b*3d + b*2c*2 - 4ac3 - 27a*2d*2 if (D > 0) == True: rv = [] for k in range(3): rv.append(2sqrt(-p/3)cos(acos(3q/2/psqrt(-3/p))/3 - k2pi/3)) return [i - b/3/a for i in rv] _, a, b, c = f.monic().all_coeffs() if c is S.Zero: x1, x2 = roots([1, a, b], multiple=True) return [x1, S.Zero, x2] p = b - a2/3 q = c - ab/3 + 2a3/27 pon3 = p/3 aon3 = a/3 u1 = None if p is S.Zero: if q is S.Zero: return [-aon3]3 if q.is_real: if q.is_positive: u1 = -root(q, 3) elif q.is_negative: u1 = root(-q, 3) elif q is S.Zero: y1, y2 = roots([1, 0, p], multiple=True) return [tmp - aon3 for tmp in [y1, S.Zero, y2]] elif q.is_real and q.is_negative: u1 = -root(-q/2 + sqrt(q2/4 + pon33), 3) coeff = Isqrt(3)/2 if u1 is None: u1 = S(1) u2 = -S.Half + coeff u3 = -S.Half - coeff a, b, c, d = S(1), a, b, c D0 = b2 - 3ac D1 = 2b*3 - 9abc + 27a2d C = root((D1 + sqrt(D1*2 - 4D0*3))/2, 3) return [-(b + ukC + D0/C/uk)/3/a for uk in [u1, u2, u3]] u2 = u1(-S.Half + coeff) u3 = u1(-S.Half - coeff) if p is S.Zero: return [u1 - aon3, u2 - aon3, u3 - aon3] soln = [ -u1 + pon3/u1 - aon3, -u2 + pon3/u2 - aon3, -u3 + pon3/u3 - aon3 ] return soln def _roots_quartic_euler(p, q, r, a): """ Descartes-Euler solution of the quartic equation Parameters ========== p, q, r: coefficients of ``x*4 + px*2 + qx + r`` a: shift of the roots Notes ===== This is a helper function for ``roots_quartic``. Look for solutions of the form :: ``x1 = sqrt(R) - sqrt(A + Bsqrt(R))`` ``x2 = -sqrt(R) - sqrt(A - Bsqrt(R))`` ``x3 = -sqrt(R) + sqrt(A - Bsqrt(R))`` ``x4 = sqrt(R) + sqrt(A + Bsqrt(R))`` To satisfy the quartic equation one must have ``p = -2(R + A); q = -4BR; r = (R - A)2 - B2R`` so that ``R`` must satisfy the Descartes-Euler resolvent equation ``64R3 + 32pR2 + (4p*2 - 16r)R - q2 = 0`` If the resolvent does not have a rational solution, return None; in that case it is likely that the Ferrari method gives a simpler solution. Examples ======== >>> from sympy import S >>> from sympy.polys.polyroots import _roots_quartic_euler >>> p, q, r = -S(64)/5, -S(512)/125, -S(1024)/3125 >>> _roots_quartic_euler(p, q, r, S(0))[0] -sqrt(32sqrt(5)/125 + 16/5) + 4sqrt(5)/5 """ # solve the resolvent equation x = Dummy('x') eq = 64x*3 + 32px2 + (4p*2 - 16r)x - q2 xsols = list(roots(Poly(eq, x), cubics=False).keys()) xsols = [sol for sol in xsols if sol.is_rational and sol.is_nonzero] if not xsols: return None R = max(xsols) c1 = sqrt(R) B = -qc1/(4R) A = -R - p/2 c2 = sqrt(A + B) c3 = sqrt(A - B) return [c1 - c2 - a, -c1 - c3 - a, -c1 + c3 - a, c1 + c2 - a] def roots_quartic(f): r""" Returns a list of roots of a quartic polynomial. There are many references for solving quartic expressions available [1-5]. This reviewer has found that many of them require one to select from among 2 or more possible sets of solutions and that some solutions work when one is searching for real roots but don't work when searching for complex roots (though this is not always stated clearly). The following routine has been tested and found to be correct for 0, 2 or 4 complex roots. The quasisymmetric case solution [6] looks for quartics that have the form `x4 + Ax*3 + Bx*2 + Cx + D = 0` where `(C/A)*2 = D`. Although no general solution that is always applicable for all coefficients is known to this reviewer, certain conditions are tested to determine the simplest 4 expressions that can be returned: 1) `f = c + a(a*2/8 - b/2) == 0` 2) `g = d - a(a(3a*2/256 - b/16) + c/4) = 0` 3) if `f != 0` and `g != 0` and `p = -d + ac/4 - b2/12` then a) `p == 0` b) `p != 0` Examples ======== >>> from sympy import Poly, symbols, I >>> from sympy.polys.polyroots import roots_quartic >>> r = roots_quartic(Poly('x4-6x3+17x*2-26x+20')) >>> # 4 complex roots: 1+-Isqrt(3), 2+-I >>> sorted(str(tmp.evalf(n=2)) for tmp in r) ['1.0 + 1.7I', '1.0 - 1.7I', '2.0 + 1.0I', '2.0 - 1.0I'] References ========== 1. http://mathforum.org/dr.math/faq/faq.cubic.equations.html 2. https://en.wikipedia.org/wiki/Quartic_function#Summary_of_Ferrari.27s_method 3. http://planetmath.org/encyclopedia/GaloisTheoreticDerivationOfTheQuarticFormula.html 4. http://staff.bath.ac.uk/masjhd/JHD-CA.pdf 5. http://www.albmath.org/files/Math_5713.pdf 6. http://www.statemaster.com/encyclopedia/Quartic-equation 7. eqworld.ipmnet.ru/en/solutions/ae/ae0108.pdf """ _, a, b, c, d = f.monic().all_coeffs() if not d: return [S.Zero] + roots([1, a, b, c], multiple=True) elif (c/a)2 == d: x, m = f.gen, c/a g = Poly(x2 + ax + b - 2m, x) z1, z2 = roots_quadratic(g) h1 = Poly(x2 - z1x + m, x) h2 = Poly(x*2 - z2x + m, x) r1 = roots_quadratic(h1) r2 = roots_quadratic(h2) return r1 + r2 else: a2 = a*2 e = b - 3a2/8 f = _mexpand(c + a(a2/8 - b/2)) g = _mexpand(d - a(a(3a2/256 - b/16) + c/4)) aon4 = a/4 if f is S.Zero: y1, y2 = [sqrt(tmp) for tmp in roots([1, e, g], multiple=True)] return [tmp - aon4 for tmp in [-y1, -y2, y1, y2]] if g is S.Zero: y = [S.Zero] + roots([1, 0, e, f], multiple=True) return [tmp - aon4 for tmp in y] else: # Descartes-Euler method, see [7] sols = _roots_quartic_euler(e, f, g, aon4) if sols: return sols # Ferrari method, see [1, 2] a2 = a*2 e = b - 3a2/8 f = c + a(a2/8 - b/2) g = d - a(a(3a2/256 - b/16) + c/4) p = -e2/12 - g q = -e3/108 + eg/3 - f2/8 TH = Rational(1, 3) def _ans(y): w = sqrt(e + 2y) arg1 = 3e + 2y arg2 = 2f/w ans = [] for s in [-1, 1]: root = sqrt(-(arg1 + sarg2)) for t in [-1, 1]: ans.append((sw - troot)/2 - aon4) return ans # p == 0 case y1 = -5e/6 - qTH if p.is_zero: return _ans(y1) # if p != 0 then u below is not 0 root = sqrt(q2/4 + p3/27) r = -q/2 + root # or -q/2 - root u = rTH # primary root of solve(x3 - r, x) y2 = -5e/6 + u - p/u/3 if fuzzy_not(p.is_zero): return _ans(y2) # sort it out once they know the values of the coefficients return [Piecewise((a1, Eq(p, 0)), (a2, True)) for a1, a2 in zip(_ans(y1), _ans(y2))] def roots_binomial(f): """Returns a list of roots of a binomial polynomial. If the domain is ZZ then the roots will be sorted with negatives coming before positives. The ordering will be the same for any numerical coefficients as long as the assumptions tested are correct, otherwise the ordering will not be sorted (but will be canonical). """ n = f.degree() a, b = f.nth(n), f.nth(0) base = -cancel(b/a) alpha = root(base, n) if alpha.is_number: alpha = alpha.expand(complex=True) # define some parameters that will allow us to order the roots. # If the domain is ZZ this is guaranteed to return roots sorted # with reals before non-real roots and non-real sorted according # to real part and imaginary part, e.g. -1, 1, -1 + I, 2 - I neg = base.is_negative even = n % 2 == 0 if neg: if even == True and (base + 1).is_positive: big = True else: big = False # get the indices in the right order so the computed # roots will be sorted when the domain is ZZ ks = [] imax = n//2 if even: ks.append(imax) imax -= 1 if not neg: ks.append(0) for i in range(imax, 0, -1): if neg: ks.extend([i, -i]) else: ks.extend([-i, i]) if neg: ks.append(0) if big: for i in range(0, len(ks), 2): pair = ks[i: i + 2] pair = list(reversed(pair)) # compute the roots roots, d = [], 2Ipi/n for k in ks: zeta = exp(kd).expand(complex=True) roots.append((alphazeta).expand(power_base=False)) return roots def _inv_totient_estimate(m): """ Find ``(L, U)`` such that ``L <= phi^-1(m) <= U``. Examples ======== >>> from sympy.polys.polyroots import _inv_totient_estimate >>> _inv_totient_estimate(192) (192, 840) >>> _inv_totient_estimate(400) (400, 1750) """ primes = [ d + 1 for d in divisors(m) if isprime(d + 1) ] a, b = 1, 1 for p in primes: a = p b = p - 1 L = m U = int(math.ceil(m(float(a)/b))) P = p = 2 primes = [] while P <= U: p = nextprime(p) primes.append(p) P = p P //= p b = 1 for p in primes[:-1]: b = p - 1 U = int(math.ceil(m(float(P)/b))) return L, U def roots_cyclotomic(f, factor=False): """Compute roots of cyclotomic polynomials. """ L, U = _inv_totient_estimate(f.degree()) for n in range(L, U + 1): g = cyclotomic_poly(n, f.gen, polys=True) if f == g: break else: # pragma: no cover raise RuntimeError("failed to find index of a cyclotomic polynomial") roots = [] if not factor: # get the indices in the right order so the computed # roots will be sorted h = n//2 ks = [i for i in range(1, n + 1) if igcd(i, n) == 1] ks.sort(key=lambda x: (x, -1) if x <= h else (abs(x - n), 1)) d = 2Ipi/n for k in reversed(ks): roots.append(exp(kd).expand(complex=True)) else: g = Poly(f, extension=root(-1, n)) for h, _ in ordered(g.factor_list()[1]): roots.append(-h.TC()) return roots def roots_quintic(f): """ Calculate exact roots of a solvable quintic """ result = [] coeff_5, coeff_4, p, q, r, s = f.all_coeffs() # Eqn must be of the form x^5 + px^3 + qx^2 + rx + s if coeff_4: return result if coeff_5 != 1: l = [p/coeff_5, q/coeff_5, r/coeff_5, s/coeff_5] if not all(coeff.is_Rational for coeff in l): return result f = Poly(f/coeff_5) quintic = PolyQuintic(f) # Eqn standardized. Algo for solving starts here if not f.is_irreducible: return result f20 = quintic.f20 # Check if f20 has linear factors over domain Z if f20.is_irreducible: return result # Now, we know that f is solvable for _factor in f20.factor_list()[1]: if _factor[0].is_linear: theta = _factor[0].root(0) break d = discriminant(f) delta = sqrt(d) # zeta = a fifth root of unity zeta1, zeta2, zeta3, zeta4 = quintic.zeta T = quintic.T(theta, d) tol = S(1e-10) alpha = T[1] + T[2]delta alpha_bar = T[1] - T[2]delta beta = T[3] + T[4]delta beta_bar = T[3] - T[4]delta disc = alpha2 - 4beta disc_bar = alpha_bar*2 - 4beta_bar l0 = quintic.l0(theta) l1 = _quintic_simplify((-alpha + sqrt(disc)) / S(2)) l4 = _quintic_simplify((-alpha - sqrt(disc)) / S(2)) l2 = _quintic_simplify((-alpha_bar + sqrt(disc_bar)) / S(2)) l3 = _quintic_simplify((-alpha_bar - sqrt(disc_bar)) / S(2)) order = quintic.order(theta, d) test = (orderdelta.n()) - ( (l1.n() - l4.n())(l2.n() - l3.n()) ) # Comparing floats if not comp(test, 0, tol): l2, l3 = l3, l2 # Now we have correct order of l's R1 = l0 + l1zeta1 + l2zeta2 + l3zeta3 + l4zeta4 R2 = l0 + l3zeta1 + l1zeta2 + l4zeta3 + l2zeta4 R3 = l0 + l2zeta1 + l4zeta2 + l1zeta3 + l3zeta4 R4 = l0 + l4zeta1 + l3zeta2 + l2zeta3 + l1zeta4 Res = [None, [None]5, [None]5, [None]5, [None]5] Res_n = [None, [None]5, [None]5, [None]5, [None]5] sol = Symbol('sol') # Simplifying improves performance a lot for exact expressions R1 = _quintic_simplify(R1) R2 = _quintic_simplify(R2) R3 = _quintic_simplify(R3) R4 = _quintic_simplify(R4) # Solve imported here. Causing problems if imported as 'solve' # and hence the changed name from sympy.solvers.solvers import solve as _solve a, b = symbols('a b', cls=Dummy) _sol = _solve( sol*5 - a - Ib, sol) for i in range(5): _sol[i] = factor(_sol[i]) R1 = R1.as_real_imag() R2 = R2.as_real_imag() R3 = R3.as_real_imag() R4 = R4.as_real_imag() for i, currentroot in enumerate(_sol): Res[1][i] = _quintic_simplify(currentroot.subs({ a: R1[0], b: R1[1] })) Res[2][i] = _quintic_simplify(currentroot.subs({ a: R2[0], b: R2[1] })) Res[3][i] = _quintic_simplify(currentroot.subs({ a: R3[0], b: R3[1] })) Res[4][i] = _quintic_simplify(currentroot.subs({ a: R4[0], b: R4[1] })) for i in range(1, 5): for j in range(5): Res_n[i][j] = Res[i][j].n() Res[i][j] = _quintic_simplify(Res[i][j]) r1 = Res[1][0] r1_n = Res_n[1][0] for i in range(5): if comp(im(r1_nRes_n[4][i]), 0, tol): r4 = Res[4][i] break # Now we have various Res values. Each will be a list of five # values. We have to pick one r value from those five for each Res u, v = quintic.uv(theta, d) testplus = (u + vdeltasqrt(5)).n() testminus = (u - vdeltasqrt(5)).n() # Evaluated numbers suffixed with _n # We will use evaluated numbers for calculation. Much faster. r4_n = r4.n() r2 = r3 = None for i in range(5): r2temp_n = Res_n[2][i] for j in range(5): # Again storing away the exact number and using # evaluated numbers in computations r3temp_n = Res_n[3][j] if (comp((r1_nr2temp_n*2 + r4_nr3temp_n*2 - testplus).n(), 0, tol) and comp((r3temp_nr1_n*2 + r2temp_nr4_n*2 - testminus).n(), 0, tol)): r2 = Res[2][i] r3 = Res[3][j] break if r2: break # Now, we have r's so we can get roots x1 = (r1 + r2 + r3 + r4)/5 x2 = (r1zeta4 + r2zeta3 + r3zeta2 + r4zeta1)/5 x3 = (r1zeta3 + r2zeta1 + r3zeta4 + r4zeta2)/5 x4 = (r1zeta2 + r2zeta4 + r3zeta1 + r4zeta3)/5 x5 = (r1zeta1 + r2zeta2 + r3zeta3 + r4zeta4)/5 result = [x1, x2, x3, x4, x5] # Now check if solutions are distinct saw = set() for r in result: r = r.n(2) if r in saw: # Roots were identical. Abort, return [] # and fall back to usual solve return [] saw.add(r) return result def _quintic_simplify(expr): expr = powsimp(expr) expr = cancel(expr) return together(expr) def _integer_basis(poly): """Compute coefficient basis for a polynomial over integers. Returns the integer ``div`` such that substituting ``x = divy`` ``p(x) = mq(y)`` where the coefficients of ``q`` are smaller than those of ``p``. For example ``x5 + 512x + 1024 = 0`` with ``div = 4`` becomes ``y*5 + 2y + 1 = 0`` Returns the integer ``div`` or ``None`` if there is no possible scaling. Examples ======== >>> from sympy.polys import Poly >>> from sympy.abc import x >>> from sympy.polys.polyroots import _integer_basis >>> p = Poly(x*5 + 512x + 1024, x, domain='ZZ') >>> _integer_basis(p) 4 """ monoms, coeffs = list(zip(poly.terms())) monoms, = list(zip(monoms)) coeffs = list(map(abs, coeffs)) if coeffs[0] < coeffs[-1]: coeffs = list(reversed(coeffs)) n = monoms[0] monoms = [n - i for i in reversed(monoms)] else: return None monoms = monoms[:-1] coeffs = coeffs[:-1] divs = reversed(divisors(gcd_list(coeffs))[1:]) try: div = next(divs) except StopIteration: return None while True: for monom, coeff in zip(monoms, coeffs): if coeff % div*monom != 0: try: div = next(divs) except StopIteration: return None else: break else: return div def preprocess_roots(poly): """Try to get rid of symbolic coefficients from ``poly``. """ coeff = S.One poly_func = poly.func try: _, poly = poly.clear_denoms(convert=True) except DomainError: return coeff, poly poly = poly.primitive()[1] poly = poly.retract() # TODO: This is fragile. Figure out how to make this independent of construct_domain(). if poly.get_domain().is_Poly and all(c.is_term for c in poly.rep.coeffs()): poly = poly.inject() strips = list(zip(poly.monoms())) gens = list(poly.gens[1:]) base, strips = strips[0], strips[1:] for gen, strip in zip(list(gens), strips): reverse = False if strip[0] < strip[-1]: strip = reversed(strip) reverse = True ratio = None for a, b in zip(base, strip): if not a and not b: continue elif not a or not b: break elif b % a != 0: break else: _ratio = b // a if ratio is None: ratio = _ratio elif ratio != _ratio: break else: if reverse: ratio = -ratio poly = poly.eval(gen, 1) coeff = gen(-ratio) gens.remove(gen) if gens: poly = poly.eject(gens) if poly.is_univariate and poly.get_domain().is_ZZ: basis = _integer_basis(poly) if basis is not None: n = poly.degree() def func(k, coeff): return coeff//basis*(n - k[0]) poly = poly.termwise(func) coeff = basis if not isinstance(poly, poly_func): poly = poly_func(poly) return coeff, poly @public def roots(f, gens, flags): """ Computes symbolic roots of a univariate polynomial. Given a univariate polynomial f with symbolic coefficients (or a list of the polynomial's coefficients), returns a dictionary with its roots and their multiplicities. Only roots expressible via radicals will be returned. To get a complete set of roots use RootOf class or numerical methods instead. By default cubic and quartic formulas are used in the algorithm. To disable them because of unreadable output set ``cubics=False`` or ``quartics=False`` respectively. If cubic roots are real but are expressed in terms of complex numbers (casus irreducibilis [1]) the ``trig`` flag can be set to True to have the solutions returned in terms of cosine and inverse cosine functions. To get roots from a specific domain set the ``filter`` flag with one of the following specifiers: Z, Q, R, I, C. By default all roots are returned (this is equivalent to setting ``filter='C'``). By default a dictionary is returned giving a compact result in case of multiple roots. However to get a list containing all those roots set the ``multiple`` flag to True; the list will have identical roots appearing next to each other in the result. (For a given Poly, the all_roots method will give the roots in sorted numerical order.) Examples ======== >>> from sympy import Poly, roots >>> from sympy.abc import x, y >>> roots(x2 - 1, x) {-1: 1, 1: 1} >>> p = Poly(x2-1, x) >>> roots(p) {-1: 1, 1: 1} >>> p = Poly(x2-y, x, y) >>> roots(Poly(p, x)) {-sqrt(y): 1, sqrt(y): 1} >>> roots(x2 - y, x) {-sqrt(y): 1, sqrt(y): 1} >>> roots([1, 0, -1]) {-1: 1, 1: 1} References ========== .. [1] https://en.wikipedia.org/wiki/Cubic_function#Trigonometric_.28and_hyperbolic.29_method """ from sympy.polys.polytools import to_rational_coeffs flags = dict(flags) auto = flags.pop('auto', True) cubics = flags.pop('cubics', True) trig = flags.pop('trig', False) quartics = flags.pop('quartics', True) quintics = flags.pop('quintics', False) multiple = flags.pop('multiple', False) filter = flags.pop('filter', None) predicate = flags.pop('predicate', None) if isinstance(f, list): if gens: raise ValueError('redundant generators given') x = Dummy('x') poly, i = {}, len(f) - 1 for coeff in f: poly[i], i = sympify(coeff), i - 1 f = Poly(poly, x, field=True) else: try: f = Poly(f, gens, flags) if f.length == 2 and f.degree() != 1: # check for foon factors in the constant n = f.degree() npow_bases = [] others = [] expr = f.as_expr() con = expr.as_independent(gens)[0] for p in Mul.make_args(con): if p.is_Pow and not p.exp % n: npow_bases.append(p.base(p.exp/n)) else: others.append(p) if npow_bases: b = Mul(npow_bases) B = Dummy() d = roots(Poly(expr - con + B*nMul(others), gens, *flags), gens, *flags) rv = {} for k, v in d.items(): rv[k.subs(B, b)] = v return rv except GeneratorsNeeded: if multiple: return [] else: return {} if f.is_multivariate: raise PolynomialError('multivariate polynomials are not supported') def _update_dict(result, currentroot, k): if currentroot in result: result[currentroot] += k else: result[currentroot] = k def _try_decompose(f): """Find roots using functional decomposition. """ factors, roots = f.decompose(), [] for currentroot in _try_heuristics(factors[0]): roots.append(currentroot) for currentfactor in factors[1:]: previous, roots = list(roots), [] for currentroot in previous: g = currentfactor - Poly(currentroot, f.gen) for currentroot in _try_heuristics(g): roots.append(currentroot) return roots def _try_heuristics(f): """Find roots using formulas and some tricks. """ if f.is_ground: return [] if f.is_monomial: return [S(0)]f.degree() if f.length() == 2: if f.degree() == 1: return list(map(cancel, roots_linear(f))) else: return roots_binomial(f) result = [] for i in [-1, 1]: if not f.eval(i): f = f.quo(Poly(f.gen - i, f.gen)) result.append(i) break n = f.degree() if n == 1: result += list(map(cancel, roots_linear(f))) elif n == 2: result += list(map(cancel, roots_quadratic(f))) elif f.is_cyclotomic: result += roots_cyclotomic(f) elif n == 3 and cubics: result += roots_cubic(f, trig=trig) elif n == 4 and quartics: result += roots_quartic(f) elif n == 5 and quintics: result += roots_quintic(f) return result (k,), f = f.terms_gcd() if not k: zeros = {} else: zeros = {S(0): k} coeff, f = preprocess_roots(f) if auto and f.get_domain().is_Ring: f = f.to_field() rescale_x = None translate_x = None result = {} if not f.is_ground: dom = f.get_domain() if not dom.is_Exact and dom.is_Numerical: for r in f.nroots(): _update_dict(result, r, 1) elif f.degree() == 1: result[roots_linear(f)[0]] = 1 elif f.length() == 2: roots_fun = roots_quadratic if f.degree() == 2 else roots_binomial for r in roots_fun(f): _update_dict(result, r, 1) else: _, factors = Poly(f.as_expr()).factor_list() if len(factors) == 1 and f.degree() == 2: for r in roots_quadratic(f): _update_dict(result, r, 1) else: if len(factors) == 1 and factors[0][1] == 1: if f.get_domain().is_EX: res = to_rational_coeffs(f) if res: if res[0] is None: translate_x, f = res[2:] else: rescale_x, f = res[1], res[-1] result = roots(f) if not result: for currentroot in _try_decompose(f): _update_dict(result, currentroot, 1) else: for r in _try_heuristics(f): _update_dict(result, r, 1) else: for currentroot in _try_decompose(f): _update_dict(result, currentroot, 1) else: for currentfactor, k in factors: for r in _try_heuristics(Poly(currentfactor, f.gen, field=True)): _update_dict(result, r, k) if coeff is not S.One: _result, result, = result, {} for currentroot, k in _result.items(): result[coeffcurrentroot] = k result.update(zeros) if filter not in [None, 'C']: handlers = { 'Z': lambda r: r.is_Integer, 'Q': lambda r: r.is_Rational, 'R': lambda r: r.is_real, 'I': lambda r: r.is_imaginary, } try: query = handlers[filter] except KeyError: raise ValueError("Invalid filter: %s" % filter) for zero in dict(result).keys(): if not query(zero): del result[zero] if predicate is not None: for zero in dict(result).keys(): if not predicate(zero): del result[zero] if rescale_x: result1 = {} for k, v in result.items(): result1[krescale_x] = v result = result1 if translate_x: result1 = {} for k, v in result.items(): result1[k + translate_x] = v result = result1 if not multiple: return result else: zeros = [] for zero in ordered(result): zeros.extend([zero]result[zero]) return zeros def root_factors(f, gens, args): """ Returns all factors of a univariate polynomial. Examples ======== >>> from sympy.abc import x, y >>> from sympy.polys.polyroots import root_factors >>> root_factors(x2 - y, x) [x - sqrt(y), x + sqrt(y)] """ args = dict(args) filter = args.pop('filter', None) F = Poly(f, gens, args) if not F.is_Poly: return [f] if F.is_multivariate: raise ValueError('multivariate polynomials are not supported') x = F.gens[0] zeros = roots(F, filter=filter) if not zeros: factors = [F] else: factors, N = [], 0 for r, n in ordered(zeros.items()): factors, N = factors + [Poly(x - r, x)]n, N + n if N < F.degree(): G = reduce(lambda p, q: p*q, factors) factors.append(F.quo(G)) if not isinstance(f, Poly): factors = [ f.as_expr() for f in factors ] return factors
9bd810abbe8c751da79198d97f58cb747ab6f45deb38a46b689e84eaba92792a	"""Arithmetics for dense recursive polynomials in ``K[x]`` or ``K[X]``. """ from __future__ import print_function, division from sympy.core.compatibility import range from sympy.polys.densebasic import ( dup_slice, dup_LC, dmp_LC, dup_degree, dmp_degree, dup_strip, dmp_strip, dmp_zero_p, dmp_zero, dmp_one_p, dmp_one, dmp_ground, dmp_zeros) from sympy.polys.polyerrors import (ExactQuotientFailed, PolynomialDivisionFailed) def dup_add_term(f, c, i, K): """ Add ``cxi`` to ``f`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add_term(x2 - 1, ZZ(2), 4) 2x4 + x2 - 1 """ if not c: return f n = len(f) m = n - i - 1 if i == n - 1: return dup_strip([f[0] + c] + f[1:]) else: if i >= n: return [c] + [K.zero](i - n) + f else: return f[:m] + [f[m] + c] + f[m + 1:] def dmp_add_term(f, c, i, u, K): """ Add ``c(x_2..x_u)x_0*i`` to ``f`` in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add_term(xy + 1, 2, 2) 2x2 + xy + 1 """ if not u: return dup_add_term(f, c, i, K) v = u - 1 if dmp_zero_p(c, v): return f n = len(f) m = n - i - 1 if i == n - 1: return dmp_strip([dmp_add(f[0], c, v, K)] + f[1:], u) else: if i >= n: return [c] + dmp_zeros(i - n, v, K) + f else: return f[:m] + [dmp_add(f[m], c, v, K)] + f[m + 1:] def dup_sub_term(f, c, i, K): """ Subtract ``cxi`` from ``f`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub_term(2x4 + x2 - 1, ZZ(2), 4) x*2 - 1 """ if not c: return f n = len(f) m = n - i - 1 if i == n - 1: return dup_strip([f[0] - c] + f[1:]) else: if i >= n: return [-c] + [K.zero](i - n) + f else: return f[:m] + [f[m] - c] + f[m + 1:] def dmp_sub_term(f, c, i, u, K): """ Subtract ``c(x_2..x_u)x_0i`` from ``f`` in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub_term(2x*2 + xy + 1, 2, 2) xy + 1 """ if not u: return dup_add_term(f, -c, i, K) v = u - 1 if dmp_zero_p(c, v): return f n = len(f) m = n - i - 1 if i == n - 1: return dmp_strip([dmp_sub(f[0], c, v, K)] + f[1:], u) else: if i >= n: return [dmp_neg(c, v, K)] + dmp_zeros(i - n, v, K) + f else: return f[:m] + [dmp_sub(f[m], c, v, K)] + f[m + 1:] def dup_mul_term(f, c, i, K): """ Multiply ``f`` by ``cxi`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_mul_term(x2 - 1, ZZ(3), 2) 3x4 - 3x*2 """ if not c or not f: return [] else: return [ cf c for cf in f ] + [K.zero]i def dmp_mul_term(f, c, i, u, K): """ Multiply ``f`` by ``c(x_2..x_u)x_0i`` in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_mul_term(x2y + x, 3y, 2) 3x4y*2 + 3x*3y """ if not u: return dup_mul_term(f, c, i, K) v = u - 1 if dmp_zero_p(f, u): return f if dmp_zero_p(c, v): return dmp_zero(u) else: return [ dmp_mul(cf, c, v, K) for cf in f ] + dmp_zeros(i, v, K) def dup_add_ground(f, c, K): """ Add an element of the ground domain to ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add_ground(x*3 + 2x*2 + 3x + 4, ZZ(4)) x*3 + 2x*2 + 3x + 8 """ return dup_add_term(f, c, 0, K) def dmp_add_ground(f, c, u, K): """ Add an element of the ground domain to ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add_ground(x*3 + 2x*2 + 3x + 4, ZZ(4)) x*3 + 2x*2 + 3x + 8 """ return dmp_add_term(f, dmp_ground(c, u - 1), 0, u, K) def dup_sub_ground(f, c, K): """ Subtract an element of the ground domain from ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub_ground(x*3 + 2x*2 + 3x + 4, ZZ(4)) x*3 + 2x*2 + 3x """ return dup_sub_term(f, c, 0, K) def dmp_sub_ground(f, c, u, K): """ Subtract an element of the ground domain from ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub_ground(x*3 + 2x*2 + 3x + 4, ZZ(4)) x*3 + 2x*2 + 3x """ return dmp_sub_term(f, dmp_ground(c, u - 1), 0, u, K) def dup_mul_ground(f, c, K): """ Multiply ``f`` by a constant value in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_mul_ground(x*2 + 2x - 1, ZZ(3)) 3x2 + 6x - 3 """ if not c or not f: return [] else: return [ cf * c for cf in f ] def dmp_mul_ground(f, c, u, K): """ Multiply ``f`` by a constant value in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_mul_ground(2x + 2y, ZZ(3)) 6x + 6y """ if not u: return dup_mul_ground(f, c, K) v = u - 1 return [ dmp_mul_ground(cf, c, v, K) for cf in f ] def dup_quo_ground(f, c, K): """ Quotient by a constant in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_quo_ground(3x2 + 2, ZZ(2)) x2 + 1 >>> R, x = ring("x", QQ) >>> R.dup_quo_ground(3x*2 + 2, QQ(2)) 3/2x*2 + 1 """ if not c: raise ZeroDivisionError('polynomial division') if not f: return f if K.is_Field: return [ K.quo(cf, c) for cf in f ] else: return [ cf // c for cf in f ] def dmp_quo_ground(f, c, u, K): """ Quotient by a constant in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_quo_ground(2x*2y + 3x, ZZ(2)) x2y + x >>> R, x,y = ring("x,y", QQ) >>> R.dmp_quo_ground(2x2y + 3x, QQ(2)) x2y + 3/2x """ if not u: return dup_quo_ground(f, c, K) v = u - 1 return [ dmp_quo_ground(cf, c, v, K) for cf in f ] def dup_exquo_ground(f, c, K): """ Exact quotient by a constant in ``K[x]``. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x = ring("x", QQ) >>> R.dup_exquo_ground(x2 + 2, QQ(2)) 1/2x2 + 1 """ if not c: raise ZeroDivisionError('polynomial division') if not f: return f return [ K.exquo(cf, c) for cf in f ] def dmp_exquo_ground(f, c, u, K): """ Exact quotient by a constant in ``K[X]``. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x,y = ring("x,y", QQ) >>> R.dmp_exquo_ground(x2y + 2x, QQ(2)) 1/2x2y + x """ if not u: return dup_exquo_ground(f, c, K) v = u - 1 return [ dmp_exquo_ground(cf, c, v, K) for cf in f ] def dup_lshift(f, n, K): """ Efficiently multiply ``f`` by ``xn`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_lshift(x2 + 1, 2) x4 + x2 """ if not f: return f else: return f + [K.zero]n def dup_rshift(f, n, K): """ Efficiently divide ``f`` by ``xn`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_rshift(x4 + x2, 2) x2 + 1 >>> R.dup_rshift(x4 + x2 + 2, 2) x2 + 1 """ return f[:-n] def dup_abs(f, K): """ Make all coefficients positive in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_abs(x2 - 1) x2 + 1 """ return [ K.abs(coeff) for coeff in f ] def dmp_abs(f, u, K): """ Make all coefficients positive in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_abs(x2y - x) x*2y + x """ if not u: return dup_abs(f, K) v = u - 1 return [ dmp_abs(cf, v, K) for cf in f ] def dup_neg(f, K): """ Negate a polynomial in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_neg(x2 - 1) -x2 + 1 """ return [ -coeff for coeff in f ] def dmp_neg(f, u, K): """ Negate a polynomial in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_neg(x*2y - x) -x*2y + x """ if not u: return dup_neg(f, K) v = u - 1 return [ dmp_neg(cf, v, K) for cf in f ] def dup_add(f, g, K): """ Add dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add(x2 - 1, x - 2) x2 + x - 3 """ if not f: return g if not g: return f df = dup_degree(f) dg = dup_degree(g) if df == dg: return dup_strip([ a + b for a, b in zip(f, g) ]) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = g[:k], g[k:] return h + [ a + b for a, b in zip(f, g) ] def dmp_add(f, g, u, K): """ Add dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add(x2 + y, x2y + x) x2y + x2 + x + y """ if not u: return dup_add(f, g, K) df = dmp_degree(f, u) if df < 0: return g dg = dmp_degree(g, u) if dg < 0: return f v = u - 1 if df == dg: return dmp_strip([ dmp_add(a, b, v, K) for a, b in zip(f, g) ], u) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = g[:k], g[k:] return h + [ dmp_add(a, b, v, K) for a, b in zip(f, g) ] def dup_sub(f, g, K): """ Subtract dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub(x2 - 1, x - 2) x2 - x + 1 """ if not f: return dup_neg(g, K) if not g: return f df = dup_degree(f) dg = dup_degree(g) if df == dg: return dup_strip([ a - b for a, b in zip(f, g) ]) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = dup_neg(g[:k], K), g[k:] return h + [ a - b for a, b in zip(f, g) ] def dmp_sub(f, g, u, K): """ Subtract dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub(x2 + y, x*2y + x) -x*2y + x*2 - x + y """ if not u: return dup_sub(f, g, K) df = dmp_degree(f, u) if df < 0: return dmp_neg(g, u, K) dg = dmp_degree(g, u) if dg < 0: return f v = u - 1 if df == dg: return dmp_strip([ dmp_sub(a, b, v, K) for a, b in zip(f, g) ], u) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = dmp_neg(g[:k], u, K), g[k:] return h + [ dmp_sub(a, b, v, K) for a, b in zip(f, g) ] def dup_add_mul(f, g, h, K): """ Returns ``f + gh`` where ``f, g, h`` are in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add_mul(x*2 - 1, x - 2, x + 2) 2x*2 - 5 """ return dup_add(f, dup_mul(g, h, K), K) def dmp_add_mul(f, g, h, u, K): """ Returns ``f + gh`` where ``f, g, h`` are in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add_mul(x*2 + y, x, x + 2) 2x*2 + 2x + y """ return dmp_add(f, dmp_mul(g, h, u, K), u, K) def dup_sub_mul(f, g, h, K): """ Returns ``f - gh`` where ``f, g, h`` are in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub_mul(x2 - 1, x - 2, x + 2) 3 """ return dup_sub(f, dup_mul(g, h, K), K) def dmp_sub_mul(f, g, h, u, K): """ Returns ``f - gh`` where ``f, g, h`` are in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub_mul(x*2 + y, x, x + 2) -2x + y """ return dmp_sub(f, dmp_mul(g, h, u, K), u, K) def dup_mul(f, g, K): """ Multiply dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_mul(x - 2, x + 2) x*2 - 4 """ if f == g: return dup_sqr(f, K) if not (f and g): return [] df = dup_degree(f) dg = dup_degree(g) n = max(df, dg) + 1 if n < 100: h = [] for i in range(0, df + dg + 1): coeff = K.zero for j in range(max(0, i - dg), min(df, i) + 1): coeff += f[j]g[i - j] h.append(coeff) return dup_strip(h) else: # Use Karatsuba's algorithm (divide and conquer), see e.g.: # Joris van der Hoeven, Relax But Don't Be Too Lazy, # J. Symbolic Computation, 11 (2002), section 3.1.1. n2 = n//2 fl, gl = dup_slice(f, 0, n2, K), dup_slice(g, 0, n2, K) fh = dup_rshift(dup_slice(f, n2, n, K), n2, K) gh = dup_rshift(dup_slice(g, n2, n, K), n2, K) lo, hi = dup_mul(fl, gl, K), dup_mul(fh, gh, K) mid = dup_mul(dup_add(fl, fh, K), dup_add(gl, gh, K), K) mid = dup_sub(mid, dup_add(lo, hi, K), K) return dup_add(dup_add(lo, dup_lshift(mid, n2, K), K), dup_lshift(hi, 2n2, K), K) def dmp_mul(f, g, u, K): """ Multiply dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_mul(xy + 1, x) x*2y + x """ if not u: return dup_mul(f, g, K) if f == g: return dmp_sqr(f, u, K) df = dmp_degree(f, u) if df < 0: return f dg = dmp_degree(g, u) if dg < 0: return g h, v = [], u - 1 for i in range(0, df + dg + 1): coeff = dmp_zero(v) for j in range(max(0, i - dg), min(df, i) + 1): coeff = dmp_add(coeff, dmp_mul(f[j], g[i - j], v, K), v, K) h.append(coeff) return dmp_strip(h, u) def dup_sqr(f, K): """ Square dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sqr(x2 + 1) x4 + 2x2 + 1 """ df, h = len(f) - 1, [] for i in range(0, 2df + 1): c = K.zero jmin = max(0, i - df) jmax = min(i, df) n = jmax - jmin + 1 jmax = jmin + n // 2 - 1 for j in range(jmin, jmax + 1): c += f[j]f[i - j] c += c if n & 1: elem = f[jmax + 1] c += elem2 h.append(c) return dup_strip(h) def dmp_sqr(f, u, K): """ Square dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sqr(x2 + xy + y2) x4 + 2x3y + 3x2y*2 + 2xy3 + y4 """ if not u: return dup_sqr(f, K) df = dmp_degree(f, u) if df < 0: return f h, v = [], u - 1 for i in range(0, 2df + 1): c = dmp_zero(v) jmin = max(0, i - df) jmax = min(i, df) n = jmax - jmin + 1 jmax = jmin + n // 2 - 1 for j in range(jmin, jmax + 1): c = dmp_add(c, dmp_mul(f[j], f[i - j], v, K), v, K) c = dmp_mul_ground(c, K(2), v, K) if n & 1: elem = dmp_sqr(f[jmax + 1], v, K) c = dmp_add(c, elem, v, K) h.append(c) return dmp_strip(h, u) def dup_pow(f, n, K): """ Raise ``f`` to the ``n``-th power in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pow(x - 2, 3) x*3 - 6x*2 + 12x - 8 """ if not n: return [K.one] if n < 0: raise ValueError("can't raise polynomial to a negative power") if n == 1 or not f or f == [K.one]: return f g = [K.one] while True: n, m = n//2, n if m % 2: g = dup_mul(g, f, K) if not n: break f = dup_sqr(f, K) return g def dmp_pow(f, n, u, K): """ Raise ``f`` to the ``n``-th power in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_pow(xy + 1, 3) x3y*3 + 3x*2y*2 + 3xy + 1 """ if not u: return dup_pow(f, n, K) if not n: return dmp_one(u, K) if n < 0: raise ValueError("can't raise polynomial to a negative power") if n == 1 or dmp_zero_p(f, u) or dmp_one_p(f, u, K): return f g = dmp_one(u, K) while True: n, m = n//2, n if m & 1: g = dmp_mul(g, f, u, K) if not n: break f = dmp_sqr(f, u, K) return g def dup_pdiv(f, g, K): """ Polynomial pseudo-division in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pdiv(x2 + 1, 2x - 4) (2x + 4, 20) """ df = dup_degree(f) dg = dup_degree(g) q, r, dr = [], f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return q, r N = df - dg + 1 lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) j, N = dr - dg, N - 1 Q = dup_mul_ground(q, lc_g, K) q = dup_add_term(Q, lc_r, j, K) R = dup_mul_ground(r, lc_g, K) G = dup_mul_term(g, lc_r, j, K) r = dup_sub(R, G, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) c = lc_gN q = dup_mul_ground(q, c, K) r = dup_mul_ground(r, c, K) return q, r def dup_prem(f, g, K): """ Polynomial pseudo-remainder in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_prem(x2 + 1, 2x - 4) 20 """ df = dup_degree(f) dg = dup_degree(g) r, dr = f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return r N = df - dg + 1 lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) j, N = dr - dg, N - 1 R = dup_mul_ground(r, lc_g, K) G = dup_mul_term(g, lc_r, j, K) r = dup_sub(R, G, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return dup_mul_ground(r, lc_gN, K) def dup_pquo(f, g, K): """ Polynomial exact pseudo-quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pquo(x2 - 1, 2x - 2) 2x + 2 >>> R.dup_pquo(x*2 + 1, 2x - 4) 2x + 4 """ return dup_pdiv(f, g, K)[0] def dup_pexquo(f, g, K): """ Polynomial pseudo-quotient in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pexquo(x2 - 1, 2x - 2) 2x + 2 >>> R.dup_pexquo(x2 + 1, 2x - 4) Traceback (most recent call last): ... ExactQuotientFailed: [2, -4] does not divide [1, 0, 1] """ q, r = dup_pdiv(f, g, K) if not r: return q else: raise ExactQuotientFailed(f, g) def dmp_pdiv(f, g, u, K): """ Polynomial pseudo-division in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_pdiv(x*2 + xy, 2x + 2) (2x + 2y - 2, -4y + 4) """ if not u: return dup_pdiv(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") q, r, dr = dmp_zero(u), f, df if df < dg: return q, r N = df - dg + 1 lc_g = dmp_LC(g, K) while True: lc_r = dmp_LC(r, K) j, N = dr - dg, N - 1 Q = dmp_mul_term(q, lc_g, 0, u, K) q = dmp_add_term(Q, lc_r, j, u, K) R = dmp_mul_term(r, lc_g, 0, u, K) G = dmp_mul_term(g, lc_r, j, u, K) r = dmp_sub(R, G, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) c = dmp_pow(lc_g, N, u - 1, K) q = dmp_mul_term(q, c, 0, u, K) r = dmp_mul_term(r, c, 0, u, K) return q, r def dmp_prem(f, g, u, K): """ Polynomial pseudo-remainder in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_prem(x*2 + xy, 2x + 2) -4y + 4 """ if not u: return dup_prem(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") r, dr = f, df if df < dg: return r N = df - dg + 1 lc_g = dmp_LC(g, K) while True: lc_r = dmp_LC(r, K) j, N = dr - dg, N - 1 R = dmp_mul_term(r, lc_g, 0, u, K) G = dmp_mul_term(g, lc_r, j, u, K) r = dmp_sub(R, G, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) c = dmp_pow(lc_g, N, u - 1, K) return dmp_mul_term(r, c, 0, u, K) def dmp_pquo(f, g, u, K): """ Polynomial exact pseudo-quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> f = x*2 + xy >>> g = 2x + 2y >>> h = 2x + 2 >>> R.dmp_pquo(f, g) 2x >>> R.dmp_pquo(f, h) 2x + 2y - 2 """ return dmp_pdiv(f, g, u, K)[0] def dmp_pexquo(f, g, u, K): """ Polynomial pseudo-quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> f = x*2 + xy >>> g = 2x + 2y >>> h = 2x + 2 >>> R.dmp_pexquo(f, g) 2x >>> R.dmp_pexquo(f, h) Traceback (most recent call last): ... ExactQuotientFailed: [[2], [2]] does not divide [[1], [1, 0], []] """ q, r = dmp_pdiv(f, g, u, K) if dmp_zero_p(r, u): return q else: raise ExactQuotientFailed(f, g) def dup_rr_div(f, g, K): """ Univariate division with remainder over a ring. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_rr_div(x*2 + 1, 2x - 4) (0, x2 + 1) """ df = dup_degree(f) dg = dup_degree(g) q, r, dr = [], f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return q, r lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) if lc_r % lc_g: break c = K.exquo(lc_r, lc_g) j = dr - dg q = dup_add_term(q, c, j, K) h = dup_mul_term(g, c, j, K) r = dup_sub(r, h, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dmp_rr_div(f, g, u, K): """ Multivariate division with remainder over a ring. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_rr_div(x2 + xy, 2x + 2) (0, x*2 + xy) """ if not u: return dup_rr_div(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") q, r, dr = dmp_zero(u), f, df if df < dg: return q, r lc_g, v = dmp_LC(g, K), u - 1 while True: lc_r = dmp_LC(r, K) c, R = dmp_rr_div(lc_r, lc_g, v, K) if not dmp_zero_p(R, v): break j = dr - dg q = dmp_add_term(q, c, j, u, K) h = dmp_mul_term(g, c, j, u, K) r = dmp_sub(r, h, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dup_ff_div(f, g, K): """ Polynomial division with remainder over a field. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x = ring("x", QQ) >>> R.dup_ff_div(x*2 + 1, 2x - 4) (1/2x + 1, 5) """ df = dup_degree(f) dg = dup_degree(g) q, r, dr = [], f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return q, r lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) c = K.exquo(lc_r, lc_g) j = dr - dg q = dup_add_term(q, c, j, K) h = dup_mul_term(g, c, j, K) r = dup_sub(r, h, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif dr == _dr and not K.is_Exact: # remove leading term created by rounding error r = dup_strip(r[1:]) dr = dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dmp_ff_div(f, g, u, K): """ Polynomial division with remainder over a field. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x,y = ring("x,y", QQ) >>> R.dmp_ff_div(x2 + xy, 2x + 2) (1/2x + 1/2y - 1/2, -y + 1) """ if not u: return dup_ff_div(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") q, r, dr = dmp_zero(u), f, df if df < dg: return q, r lc_g, v = dmp_LC(g, K), u - 1 while True: lc_r = dmp_LC(r, K) c, R = dmp_ff_div(lc_r, lc_g, v, K) if not dmp_zero_p(R, v): break j = dr - dg q = dmp_add_term(q, c, j, u, K) h = dmp_mul_term(g, c, j, u, K) r = dmp_sub(r, h, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dup_div(f, g, K): """ Polynomial division with remainder in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_div(x2 + 1, 2x - 4) (0, x2 + 1) >>> R, x = ring("x", QQ) >>> R.dup_div(x2 + 1, 2x - 4) (1/2x + 1, 5) """ if K.is_Field: return dup_ff_div(f, g, K) else: return dup_rr_div(f, g, K) def dup_rem(f, g, K): """ Returns polynomial remainder in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_rem(x*2 + 1, 2x - 4) x2 + 1 >>> R, x = ring("x", QQ) >>> R.dup_rem(x2 + 1, 2x - 4) 5 """ return dup_div(f, g, K)[1] def dup_quo(f, g, K): """ Returns exact polynomial quotient in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_quo(x2 + 1, 2x - 4) 0 >>> R, x = ring("x", QQ) >>> R.dup_quo(x*2 + 1, 2x - 4) 1/2x + 1 """ return dup_div(f, g, K)[0] def dup_exquo(f, g, K): """ Returns polynomial quotient in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_exquo(x2 - 1, x - 1) x + 1 >>> R.dup_exquo(x2 + 1, 2x - 4) Traceback (most recent call last): ... ExactQuotientFailed: [2, -4] does not divide [1, 0, 1] """ q, r = dup_div(f, g, K) if not r: return q else: raise ExactQuotientFailed(f, g) def dmp_div(f, g, u, K): """ Polynomial division with remainder in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_div(x*2 + xy, 2x + 2) (0, x2 + xy) >>> R, x,y = ring("x,y", QQ) >>> R.dmp_div(x*2 + xy, 2x + 2) (1/2x + 1/2y - 1/2, -y + 1) """ if K.is_Field: return dmp_ff_div(f, g, u, K) else: return dmp_rr_div(f, g, u, K) def dmp_rem(f, g, u, K): """ Returns polynomial remainder in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_rem(x2 + xy, 2x + 2) x2 + xy >>> R, x,y = ring("x,y", QQ) >>> R.dmp_rem(x*2 + xy, 2x + 2) -y + 1 """ return dmp_div(f, g, u, K)[1] def dmp_quo(f, g, u, K): """ Returns exact polynomial quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_quo(x2 + xy, 2x + 2) 0 >>> R, x,y = ring("x,y", QQ) >>> R.dmp_quo(x2 + xy, 2x + 2) 1/2x + 1/2y - 1/2 """ return dmp_div(f, g, u, K)[0] def dmp_exquo(f, g, u, K): """ Returns polynomial quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> f = x2 + xy >>> g = x + y >>> h = 2x + 2 >>> R.dmp_exquo(f, g) x >>> R.dmp_exquo(f, h) Traceback (most recent call last): ... ExactQuotientFailed: [[2], [2]] does not divide [[1], [1, 0], []] """ q, r = dmp_div(f, g, u, K) if dmp_zero_p(r, u): return q else: raise ExactQuotientFailed(f, g) def dup_max_norm(f, K): """ Returns maximum norm of a polynomial in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_max_norm(-x2 + 2x - 3) 3 """ if not f: return K.zero else: return max(dup_abs(f, K)) def dmp_max_norm(f, u, K): """ Returns maximum norm of a polynomial in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_max_norm(2xy - x - 3) 3 """ if not u: return dup_max_norm(f, K) v = u - 1 return max([ dmp_max_norm(c, v, K) for c in f ]) def dup_l1_norm(f, K): """ Returns l1 norm of a polynomial in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_l1_norm(2x3 - 3x*2 + 1) 6 """ if not f: return K.zero else: return sum(dup_abs(f, K)) def dmp_l1_norm(f, u, K): """ Returns l1 norm of a polynomial in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_l1_norm(2xy - x - 3) 6 """ if not u: return dup_l1_norm(f, K) v = u - 1 return sum([ dmp_l1_norm(c, v, K) for c in f ]) def dup_expand(polys, K): """ Multiply together several polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_expand([x2 - 1, x, 2]) 2x*3 - 2x """ if not polys: return [K.one] f = polys[0] for g in polys[1:]: f = dup_mul(f, g, K) return f def dmp_expand(polys, u, K): """ Multiply together several polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_expand([x2 + y2, x + 1]) x3 + x2 + xy2 + y*2 """ if not polys: return dmp_one(u, K) f = polys[0] for g in polys[1:]: f = dmp_mul(f, g, u, K) return f
18a862eb464006dde4cdb94e507af82d19b80083000146bbd42661f1747de57e	"""Tools and arithmetics for monomials of distributed polynomials. """ from __future__ import print_function, division from itertools import combinations_with_replacement, product from textwrap import dedent from sympy.core import Mul, S, Tuple, sympify from sympy.core.compatibility import exec_, iterable, range from sympy.polys.polyerrors import ExactQuotientFailed from sympy.polys.polyutils import PicklableWithSlots, dict_from_expr from sympy.utilities import public @public def itermonomials(variables, max_degree, min_degree = 0): r""" Generate a set of monomials of the degree greater than or equal to `min_degree` and less than or equal to `max_degree`. Given a set of variables `V` and a min_degree `N` and a max_degree `M` generate a set of monomials of degree less than or equal to `N` and greater than or equal to `M`. The total number of monomials in commutative variables is huge and is given by the following formula if `M = 0`: .. math:: \frac{(\#V + N)!}{\#V! N!} For example if we would like to generate a dense polynomial of a total degree `N = 50` and `M = 0`, which is the worst case, in 5 variables, assuming that exponents and all of coefficients are 32-bit long and stored in an array we would need almost 80 GiB of memory! Fortunately most polynomials, that we will encounter, are sparse. Examples ======== Consider monomials in commutative variables `x` and `y` and non-commutative variables `a` and `b`:: >>> from sympy import symbols >>> from sympy.polys.monomials import itermonomials >>> from sympy.polys.orderings import monomial_key >>> from sympy.abc import x, y >>> sorted(itermonomials([x, y], 2), key=monomial_key('grlex', [y, x])) [1, x, y, x*2, xy, y2] >>> sorted(itermonomials([x, y], 3), key=monomial_key('grlex', [y, x])) [1, x, y, x2, xy, y2, x3, x2y, xy2, y3] >>> a, b = symbols('a, b', commutative=False) >>> itermonomials([a, b, x], 2) {1, a, a2, b, b2, x, x2, ab, ba, xa, xb} >>> sorted(itermonomials([x, y], 2, 1), key=monomial_key('grlex', [y, x])) [x, y, x2, xy, y*2] """ if max_degree < 0 or min_degree > max_degree: return set() if not variables or max_degree == 0: return {S(1)} # Force to list in case of passed tuple or other incompatible collection variables = list(variables) + [S(1)] if all(variable.is_commutative for variable in variables): monomials_list_comm = [] for item in combinations_with_replacement(variables, max_degree): powers = dict() for variable in variables: powers[variable] = 0 for variable in item: if variable != 1: powers[variable] += 1 if sum(powers.values()) >= min_degree: monomials_list_comm.append(Mul(item)) return set(monomials_list_comm) else: monomials_list_non_comm = [] for item in product(variables, repeat=max_degree): powers = dict() for variable in variables: powers[variable] = 0 for variable in item: if variable != 1: powers[variable] += 1 if sum(powers.values()) >= min_degree: monomials_list_non_comm.append(Mul(item)) return set(monomials_list_non_comm) def monomial_count(V, N): r""" Computes the number of monomials. The number of monomials is given by the following formula: .. math:: \frac{(\#V + N)!}{\#V! N!} where `N` is a total degree and `V` is a set of variables. Examples ======== >>> from sympy.polys.monomials import itermonomials, monomial_count >>> from sympy.polys.orderings import monomial_key >>> from sympy.abc import x, y >>> monomial_count(2, 2) 6 >>> M = itermonomials([x, y], 2) >>> sorted(M, key=monomial_key('grlex', [y, x])) [1, x, y, x2, xy, y2] >>> len(M) 6 """ from sympy import factorial return factorial(V + N) / factorial(V) / factorial(N) def monomial_mul(A, B): """ Multiplication of tuples representing monomials. Examples ======== Lets multiply `x3y4z` with `xy2`:: >>> from sympy.polys.monomials import monomial_mul >>> monomial_mul((3, 4, 1), (1, 2, 0)) (4, 6, 1) which gives `x4y*5z`. """ return tuple([ a + b for a, b in zip(A, B) ]) def monomial_div(A, B): """ Division of tuples representing monomials. Examples ======== Lets divide `x*3y*4z` by `xy2`:: >>> from sympy.polys.monomials import monomial_div >>> monomial_div((3, 4, 1), (1, 2, 0)) (2, 2, 1) which gives `x2y*2z`. However:: >>> monomial_div((3, 4, 1), (1, 2, 2)) is None True `xy2z2` does not divide `x3y4z`. """ C = monomial_ldiv(A, B) if all(c >= 0 for c in C): return tuple(C) else: return None def monomial_ldiv(A, B): """ Division of tuples representing monomials. Examples ======== Lets divide `x*3y*4z` by `xy2`:: >>> from sympy.polys.monomials import monomial_ldiv >>> monomial_ldiv((3, 4, 1), (1, 2, 0)) (2, 2, 1) which gives `x2y*2z`. >>> monomial_ldiv((3, 4, 1), (1, 2, 2)) (2, 2, -1) which gives `x*2y*2z*-1`. """ return tuple([ a - b for a, b in zip(A, B) ]) def monomial_pow(A, n): """Return the n-th pow of the monomial. """ return tuple([ an for a in A ]) def monomial_gcd(A, B): """ Greatest common divisor of tuples representing monomials. Examples ======== Lets compute GCD of `xy4z` and `x*3y*2`:: >>> from sympy.polys.monomials import monomial_gcd >>> monomial_gcd((1, 4, 1), (3, 2, 0)) (1, 2, 0) which gives `xy*2`. """ return tuple([ min(a, b) for a, b in zip(A, B) ]) def monomial_lcm(A, B): """ Least common multiple of tuples representing monomials. Examples ======== Lets compute LCM of `xy*4z` and `x*3y2`:: >>> from sympy.polys.monomials import monomial_lcm >>> monomial_lcm((1, 4, 1), (3, 2, 0)) (3, 4, 1) which gives `x3y4z`. """ return tuple([ max(a, b) for a, b in zip(A, B) ]) def monomial_divides(A, B): """ Does there exist a monomial X such that XA == B? Examples ======== >>> from sympy.polys.monomials import monomial_divides >>> monomial_divides((1, 2), (3, 4)) True >>> monomial_divides((1, 2), (0, 2)) False """ return all(a <= b for a, b in zip(A, B)) def monomial_max(monoms): """ Returns maximal degree for each variable in a set of monomials. Examples ======== Consider monomials `x3y*4z5`, `y5z` and `x6y*3z*9`. We wish to find out what is the maximal degree for each of `x`, `y` and `z` variables:: >>> from sympy.polys.monomials import monomial_max >>> monomial_max((3,4,5), (0,5,1), (6,3,9)) (6, 5, 9) """ M = list(monoms[0]) for N in monoms[1:]: for i, n in enumerate(N): M[i] = max(M[i], n) return tuple(M) def monomial_min(monoms): """ Returns minimal degree for each variable in a set of monomials. Examples ======== Consider monomials `x*3y*4z5`, `y5z` and `x6y*3z*9`. We wish to find out what is the minimal degree for each of `x`, `y` and `z` variables:: >>> from sympy.polys.monomials import monomial_min >>> monomial_min((3,4,5), (0,5,1), (6,3,9)) (0, 3, 1) """ M = list(monoms[0]) for N in monoms[1:]: for i, n in enumerate(N): M[i] = min(M[i], n) return tuple(M) def monomial_deg(M): """ Returns the total degree of a monomial. Examples ======== The total degree of `xy^2` is 3: >>> from sympy.polys.monomials import monomial_deg >>> monomial_deg((1, 2)) 3 """ return sum(M) def term_div(a, b, domain): """Division of two terms in over a ring/field. """ a_lm, a_lc = a b_lm, b_lc = b monom = monomial_div(a_lm, b_lm) if domain.is_Field: if monom is not None: return monom, domain.quo(a_lc, b_lc) else: return None else: if not (monom is None or a_lc % b_lc): return monom, domain.quo(a_lc, b_lc) else: return None class MonomialOps(object): """Code generator of fast monomial arithmetic functions. """ def __init__(self, ngens): self.ngens = ngens def _build(self, code, name): ns = {} exec_(code, ns) return ns[name] def _vars(self, name): return [ "%s%s" % (name, i) for i in range(self.ngens) ] def mul(self): name = "monomial_mul" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s + %s" % (a, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) def pow(self): name = "monomial_pow" template = dedent("""\ def %(name)s(A, k): (%(A)s,) = A return (%(Ak)s,) """) A = self._vars("a") Ak = [ "%sk" % a for a in A ] code = template % dict(name=name, A=", ".join(A), Ak=", ".join(Ak)) return self._build(code, name) def mulpow(self): name = "monomial_mulpow" template = dedent("""\ def %(name)s(A, B, k): (%(A)s,) = A (%(B)s,) = B return (%(ABk)s,) """) A = self._vars("a") B = self._vars("b") ABk = [ "%s + %sk" % (a, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), ABk=", ".join(ABk)) return self._build(code, name) def ldiv(self): name = "monomial_ldiv" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s - %s" % (a, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) def div(self): name = "monomial_div" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B %(RAB)s return (%(R)s,) """) A = self._vars("a") B = self._vars("b") RAB = [ "r%(i)s = a%(i)s - b%(i)s\n if r%(i)s < 0: return None" % dict(i=i) for i in range(self.ngens) ] R = self._vars("r") code = template % dict(name=name, A=", ".join(A), B=", ".join(B), RAB="\n ".join(RAB), R=", ".join(R)) return self._build(code, name) def lcm(self): name = "monomial_lcm" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s if %s >= %s else %s" % (a, a, b, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) def gcd(self): name = "monomial_gcd" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s if %s <= %s else %s" % (a, a, b, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) @public class Monomial(PicklableWithSlots): """Class representing a monomial, i.e. a product of powers. """ __slots__ = ['exponents', 'gens'] def __init__(self, monom, gens=None): if not iterable(monom): rep, gens = dict_from_expr(sympify(monom), gens=gens) if len(rep) == 1 and list(rep.values())[0] == 1: monom = list(rep.keys())[0] else: raise ValueError("Expected a monomial got {}".format(monom)) self.exponents = tuple(map(int, monom)) self.gens = gens def rebuild(self, exponents, gens=None): return self.__class__(exponents, gens or self.gens) def __len__(self): return len(self.exponents) def __iter__(self): return iter(self.exponents) def __getitem__(self, item): return self.exponents[item] def __hash__(self): return hash((self.__class__.__name__, self.exponents, self.gens)) def __str__(self): if self.gens: return "".join([ "%s*%s" % (gen, exp) for gen, exp in zip(self.gens, self.exponents) ]) else: return "%s(%s)" % (self.__class__.__name__, self.exponents) def as_expr(self, gens): """Convert a monomial instance to a SymPy expression. """ gens = gens or self.gens if not gens: raise ValueError( "can't convert %s to an expression without generators" % self) return Mul([ genexp for gen, exp in zip(gens, self.exponents) ]) def __eq__(self, other): if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: return False return self.exponents == exponents def __ne__(self, other): return not self == other def __mul__(self, other): if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise NotImplementedError return self.rebuild(monomial_mul(self.exponents, exponents)) def __div__(self, other): if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise NotImplementedError result = monomial_div(self.exponents, exponents) if result is not None: return self.rebuild(result) else: raise ExactQuotientFailed(self, Monomial(other)) __floordiv__ = __truediv__ = __div__ def __pow__(self, other): n = int(other) if not n: return self.rebuild([0]len(self)) elif n > 0: exponents = self.exponents for i in range(1, n): exponents = monomial_mul(exponents, self.exponents) return self.rebuild(exponents) else: raise ValueError("a non-negative integer expected, got %s" % other) def gcd(self, other): """Greatest common divisor of monomials. """ if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise TypeError( "an instance of Monomial class expected, got %s" % other) return self.rebuild(monomial_gcd(self.exponents, exponents)) def lcm(self, other): """Least common multiple of monomials. """ if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise TypeError( "an instance of Monomial class expected, got %s" % other) return self.rebuild(monomial_lcm(self.exponents, exponents))
722ca075ce43d16a949bf25d18ba72bb0cce112ff25a2d6b1c207810c696c7f1	"""Useful utilities for higher level polynomial classes. """ from __future__ import print_function, division from sympy.core import (S, Add, Mul, Pow, Expr, expand_mul, expand_multinomial) from sympy.core.compatibility import range from sympy.core.exprtools import decompose_power, decompose_power_rat from sympy.core.numbers import Float from sympy.polys.polyerrors import PolynomialError, GeneratorsError from sympy.polys.polyoptions import build_options import re _gens_order = { 'a': 301, 'b': 302, 'c': 303, 'd': 304, 'e': 305, 'f': 306, 'g': 307, 'h': 308, 'i': 309, 'j': 310, 'k': 311, 'l': 312, 'm': 313, 'n': 314, 'o': 315, 'p': 216, 'q': 217, 'r': 218, 's': 219, 't': 220, 'u': 221, 'v': 222, 'w': 223, 'x': 124, 'y': 125, 'z': 126, } _max_order = 1000 _re_gen = re.compile(r"^(.+?)(\d)$") def _nsort(roots, separated=False): """Sort the numerical roots putting the real roots first, then sorting according to real and imaginary parts. If ``separated`` is True, then the real and imaginary roots will be returned in two lists, respectively. This routine tries to avoid issue 6137 by separating the roots into real and imaginary parts before evaluation. In addition, the sorting will raise an error if any computation cannot be done with precision. """ if not all(r.is_number for r in roots): raise NotImplementedError # see issue 6137: # get the real part of the evaluated real and imaginary parts of each root key = [[i.n(2).as_real_imag()[0] for i in r.as_real_imag()] for r in roots] # make sure the parts were computed with precision if any(i._prec == 1 for k in key for i in k): raise NotImplementedError("could not compute root with precision") # insert a key to indicate if the root has an imaginary part key = [(1 if i else 0, r, i) for r, i in key] key = sorted(zip(key, roots)) # return the real and imaginary roots separately if desired if separated: r = [] i = [] for (im, _, _), v in key: if im: i.append(v) else: r.append(v) return r, i _, roots = zip(key) return list(roots) def _sort_gens(gens, *args): """Sort generators in a reasonably intelligent way. """ opt = build_options(args) gens_order, wrt = {}, None if opt is not None: gens_order, wrt = {}, opt.wrt for i, gen in enumerate(opt.sort): gens_order[gen] = i + 1 def order_key(gen): gen = str(gen) if wrt is not None: try: return (-len(wrt) + wrt.index(gen), gen, 0) except ValueError: pass name, index = _re_gen.match(gen).groups() if index: index = int(index) else: index = 0 try: return ( gens_order[name], name, index) except KeyError: pass try: return (_gens_order[name], name, index) except KeyError: pass return (_max_order, name, index) try: gens = sorted(gens, key=order_key) except TypeError: # pragma: no cover pass return tuple(gens) def _unify_gens(f_gens, g_gens): """Unify generators in a reasonably intelligent way. """ f_gens = list(f_gens) g_gens = list(g_gens) if f_gens == g_gens: return tuple(f_gens) gens, common, k = [], [], 0 for gen in f_gens: if gen in g_gens: common.append(gen) for i, gen in enumerate(g_gens): if gen in common: g_gens[i], k = common[k], k + 1 for gen in common: i = f_gens.index(gen) gens.extend(f_gens[:i]) f_gens = f_gens[i + 1:] i = g_gens.index(gen) gens.extend(g_gens[:i]) g_gens = g_gens[i + 1:] gens.append(gen) gens.extend(f_gens) gens.extend(g_gens) return tuple(gens) def _analyze_gens(gens): """Support for passing generators as `gens` and `[gens]`. """ if len(gens) == 1 and hasattr(gens[0], '__iter__'): return tuple(gens[0]) else: return tuple(gens) def _sort_factors(factors, *args): """Sort low-level factors in increasing 'complexity' order. """ def order_if_multiple_key(factor): (f, n) = factor return (len(f), n, f) def order_no_multiple_key(f): return (len(f), f) if args.get('multiple', True): return sorted(factors, key=order_if_multiple_key) else: return sorted(factors, key=order_no_multiple_key) illegal = [S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity] finf = [float(i) for i in illegal[1:3]] def _not_a_coeff(expr): """Do not treat NaN and infinities as valid polynomial coefficients. """ if expr in illegal or expr in finf: return True if type(expr) is float and float(expr) != expr: return True # nan return # could be def _parallel_dict_from_expr_if_gens(exprs, opt): """Transform expressions into a multinomial form given generators. """ k, indices = len(opt.gens), {} for i, g in enumerate(opt.gens): indices[g] = i polys = [] for expr in exprs: poly = {} if expr.is_Equality: expr = expr.lhs - expr.rhs for term in Add.make_args(expr): coeff, monom = [], [0]k for factor in Mul.make_args(term): if not _not_a_coeff(factor) and factor.is_Number: coeff.append(factor) else: try: if opt.series is False: base, exp = decompose_power(factor) if exp < 0: exp, base = -exp, Pow(base, -S.One) else: base, exp = decompose_power_rat(factor) monom[indices[base]] = exp except KeyError: if not factor.free_symbols.intersection(opt.gens): coeff.append(factor) else: raise PolynomialError("%s contains an element of " "the set of generators." % factor) monom = tuple(monom) if monom in poly: poly[monom] += Mul(coeff) else: poly[monom] = Mul(coeff) polys.append(poly) return polys, opt.gens def _parallel_dict_from_expr_no_gens(exprs, opt): """Transform expressions into a multinomial form and figure out generators. """ if opt.domain is not None: def _is_coeff(factor): return factor in opt.domain elif opt.extension is True: def _is_coeff(factor): return factor.is_algebraic elif opt.greedy is not False: def _is_coeff(factor): return False else: def _is_coeff(factor): return factor.is_number gens, reprs = set([]), [] for expr in exprs: terms = [] if expr.is_Equality: expr = expr.lhs - expr.rhs for term in Add.make_args(expr): coeff, elements = [], {} for factor in Mul.make_args(term): if not _not_a_coeff(factor) and (factor.is_Number or _is_coeff(factor)): coeff.append(factor) else: if opt.series is False: base, exp = decompose_power(factor) if exp < 0: exp, base = -exp, Pow(base, -S.One) else: base, exp = decompose_power_rat(factor) elements[base] = elements.setdefault(base, 0) + exp gens.add(base) terms.append((coeff, elements)) reprs.append(terms) gens = _sort_gens(gens, opt=opt) k, indices = len(gens), {} for i, g in enumerate(gens): indices[g] = i polys = [] for terms in reprs: poly = {} for coeff, term in terms: monom = [0]k for base, exp in term.items(): monom[indices[base]] = exp monom = tuple(monom) if monom in poly: poly[monom] += Mul(coeff) else: poly[monom] = Mul(coeff) polys.append(poly) return polys, tuple(gens) def _dict_from_expr_if_gens(expr, opt): """Transform an expression into a multinomial form given generators. """ (poly,), gens = _parallel_dict_from_expr_if_gens((expr,), opt) return poly, gens def _dict_from_expr_no_gens(expr, opt): """Transform an expression into a multinomial form and figure out generators. """ (poly,), gens = _parallel_dict_from_expr_no_gens((expr,), opt) return poly, gens def parallel_dict_from_expr(exprs, args): """Transform expressions into a multinomial form. """ reps, opt = _parallel_dict_from_expr(exprs, build_options(args)) return reps, opt.gens def _parallel_dict_from_expr(exprs, opt): """Transform expressions into a multinomial form. """ if opt.expand is not False: exprs = [ expr.expand() for expr in exprs ] if any(expr.is_commutative is False for expr in exprs): raise PolynomialError('non-commutative expressions are not supported') if opt.gens: reps, gens = _parallel_dict_from_expr_if_gens(exprs, opt) else: reps, gens = _parallel_dict_from_expr_no_gens(exprs, opt) return reps, opt.clone({'gens': gens}) def dict_from_expr(expr, args): """Transform an expression into a multinomial form. """ rep, opt = _dict_from_expr(expr, build_options(args)) return rep, opt.gens def _dict_from_expr(expr, opt): """Transform an expression into a multinomial form. """ if expr.is_commutative is False: raise PolynomialError('non-commutative expressions are not supported') def _is_expandable_pow(expr): return (expr.is_Pow and expr.exp.is_positive and expr.exp.is_Integer and expr.base.is_Add) if opt.expand is not False: if not isinstance(expr, Expr): raise PolynomialError('expression must be of type Expr') expr = expr.expand() # TODO: Integrate this into expand() itself while any(_is_expandable_pow(i) or i.is_Mul and any(_is_expandable_pow(j) for j in i.args) for i in Add.make_args(expr)): expr = expand_multinomial(expr) while any(i.is_Mul and any(j.is_Add for j in i.args) for i in Add.make_args(expr)): expr = expand_mul(expr) if opt.gens: rep, gens = _dict_from_expr_if_gens(expr, opt) else: rep, gens = _dict_from_expr_no_gens(expr, opt) return rep, opt.clone({'gens': gens}) def expr_from_dict(rep, gens): """Convert a multinomial form into an expression. """ result = [] for monom, coeff in rep.items(): term = [coeff] for g, m in zip(gens, monom): if m: term.append(Pow(g, m)) result.append(Mul(term)) return Add(result) parallel_dict_from_basic = parallel_dict_from_expr dict_from_basic = dict_from_expr basic_from_dict = expr_from_dict def _dict_reorder(rep, gens, new_gens): """Reorder levels using dict representation. """ gens = list(gens) monoms = rep.keys() coeffs = rep.values() new_monoms = [ [] for _ in range(len(rep)) ] used_indices = set() for gen in new_gens: try: j = gens.index(gen) used_indices.add(j) for M, new_M in zip(monoms, new_monoms): new_M.append(M[j]) except ValueError: for new_M in new_monoms: new_M.append(0) for i, _ in enumerate(gens): if i not in used_indices: for monom in monoms: if monom[i]: raise GeneratorsError("unable to drop generators") return map(tuple, new_monoms), coeffs class PicklableWithSlots(object): """ Mixin class that allows to pickle objects with ``__slots__``. Examples ======== First define a class that mixes :class:`PicklableWithSlots` in:: >>> from sympy.polys.polyutils import PicklableWithSlots >>> class Some(PicklableWithSlots): ... __slots__ = ['foo', 'bar'] ... ... def __init__(self, foo, bar): ... self.foo = foo ... self.bar = bar To make :mod:`pickle` happy in doctest we have to use these hacks:: >>> from sympy.core.compatibility import builtins >>> builtins.Some = Some >>> from sympy.polys import polyutils >>> polyutils.Some = Some Next lets see if we can create an instance, pickle it and unpickle:: >>> some = Some('abc', 10) >>> some.foo, some.bar ('abc', 10) >>> from pickle import dumps, loads >>> some2 = loads(dumps(some)) >>> some2.foo, some2.bar ('abc', 10) """ __slots__ = [] def __getstate__(self, cls=None): if cls is None: # This is the case for the instance that gets pickled cls = self.__class__ d = {} # Get all data that should be stored from super classes for c in cls.__bases__: if hasattr(c, "__getstate__"): d.update(c.__getstate__(self, c)) # Get all information that should be stored from cls and return the dict for name in cls.__slots__: if hasattr(self, name): d[name] = getattr(self, name) return d def __setstate__(self, d): # All values that were pickled are now assigned to a fresh instance for name, value in d.items(): try: setattr(self, name, value) except AttributeError: # This is needed in cases like Rational :> Half pass
6dd7824f551a3469c07dce7410f0b1a99bc57245f959c305481670deca553bf3	"""Geometrical Points. Contains ======== Point Point2D Point3D When methods of Point require 1 or more points as arguments, they can be passed as a sequence of coordinates or Points: >>> from sympy.geometry.point import Point >>> Point(1, 1).is_collinear((2, 2), (3, 4)) False >>> Point(1, 1).is_collinear(Point(2, 2), Point(3, 4)) False """ from __future__ import division, print_function import warnings from sympy.core import S, sympify, Expr from sympy.core.compatibility import is_sequence from sympy.core.containers import Tuple from sympy.simplify import nsimplify, simplify from sympy.geometry.exceptions import GeometryError from sympy.functions.elementary.miscellaneous import sqrt from sympy.functions.elementary.complexes import im from sympy.matrices import Matrix from sympy.core.numbers import Float from sympy.core.evaluate import global_evaluate from sympy.core.add import Add from sympy.utilities.iterables import uniq from sympy.utilities.misc import filldedent, func_name, Undecidable from .entity import GeometryEntity class Point(GeometryEntity): """A point in a n-dimensional Euclidean space. Parameters ========== coords : sequence of n-coordinate values. In the special case where n=2 or 3, a Point2D or Point3D will be created as appropriate. evaluate : if `True` (default), all floats are turn into exact types. dim : number of coordinates the point should have. If coordinates are unspecified, they are padded with zeros. on_morph : indicates what should happen when the number of coordinates of a point need to be changed by adding or removing zeros. Possible values are `'warn'`, `'error'`, or `ignore` (default). No warning or error is given when `args` is empty and `dim` is given. An error is always raised when trying to remove nonzero coordinates. Attributes ========== length origin: A `Point` representing the origin of the appropriately-dimensioned space. Raises ====== TypeError : When instantiating with anything but a Point or sequence ValueError : when instantiating with a sequence with length < 2 or when trying to reduce dimensions if keyword `on_morph='error'` is set. See Also ======== sympy.geometry.line.Segment : Connects two Points Examples ======== >>> from sympy.geometry import Point >>> from sympy.abc import x >>> Point(1, 2, 3) Point3D(1, 2, 3) >>> Point([1, 2]) Point2D(1, 2) >>> Point(0, x) Point2D(0, x) >>> Point(dim=4) Point(0, 0, 0, 0) Floats are automatically converted to Rational unless the evaluate flag is False: >>> Point(0.5, 0.25) Point2D(1/2, 1/4) >>> Point(0.5, 0.25, evaluate=False) Point2D(0.5, 0.25) """ is_Point = True def __new__(cls, args, *kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) on_morph = kwargs.get('on_morph', 'ignore') # unpack into coords coords = args[0] if len(args) == 1 else args # check args and handle quickly handle Point instances if isinstance(coords, Point): # even if we're mutating the dimension of a point, we # don't reevaluate its coordinates evaluate = False if len(coords) == kwargs.get('dim', len(coords)): return coords if not is_sequence(coords): raise TypeError(filldedent(''' Expecting sequence of coordinates, not `{}`''' .format(func_name(coords)))) # A point where only `dim` is specified is initialized # to zeros. if len(coords) == 0 and kwargs.get('dim', None): coords = (S.Zero,)kwargs.get('dim') coords = Tuple(coords) dim = kwargs.get('dim', len(coords)) if len(coords) < 2: raise ValueError(filldedent(''' Point requires 2 or more coordinates or keyword `dim` > 1.''')) if len(coords) != dim: message = ("Dimension of {} needs to be changed " "from {} to {}.").format(coords, len(coords), dim) if on_morph == 'ignore': pass elif on_morph == "error": raise ValueError(message) elif on_morph == 'warn': warnings.warn(message) else: raise ValueError(filldedent(''' on_morph value should be 'error', 'warn' or 'ignore'.''')) if any(coords[dim:]): raise ValueError('Nonzero coordinates cannot be removed.') if any(a.is_number and im(a) for a in coords): raise ValueError('Imaginary coordinates are not permitted.') if not all(isinstance(a, Expr) for a in coords): raise TypeError('Coordinates must be valid SymPy expressions.') # pad with zeros appropriately coords = coords[:dim] + (S.Zero,)(dim - len(coords)) # Turn any Floats into rationals and simplify # any expressions before we instantiate if evaluate: coords = coords.xreplace(dict( [(f, simplify(nsimplify(f, rational=True))) for f in coords.atoms(Float)])) # return 2D or 3D instances if len(coords) == 2: kwargs['_nocheck'] = True return Point2D(coords, kwargs) elif len(coords) == 3: kwargs['_nocheck'] = True return Point3D(coords, *kwargs) # the general Point return GeometryEntity.__new__(cls, coords) def __abs__(self): """Returns the distance between this point and the origin.""" origin = Point([0]len(self)) return Point.distance(origin, self) def __add__(self, other): """Add other to self by incrementing self's coordinates by those of other. Notes ===== >>> from sympy.geometry.point import Point When sequences of coordinates are passed to Point methods, they are converted to a Point internally. This __add__ method does not do that so if floating point values are used, a floating point result (in terms of SymPy Floats) will be returned. >>> Point(1, 2) + (.1, .2) Point2D(1.1, 2.2) If this is not desired, the `translate` method can be used or another Point can be added: >>> Point(1, 2).translate(.1, .2) Point2D(11/10, 11/5) >>> Point(1, 2) + Point(.1, .2) Point2D(11/10, 11/5) See Also ======== sympy.geometry.point.Point.translate """ try: s, o = Point._normalize_dimension(self, Point(other, evaluate=False)) except TypeError: raise GeometryError("Don't know how to add {} and a Point object".format(other)) coords = [simplify(a + b) for a, b in zip(s, o)] return Point(coords, evaluate=False) def __contains__(self, item): return item in self.args def __div__(self, divisor): """Divide point's coordinates by a factor.""" divisor = sympify(divisor) coords = [simplify(x/divisor) for x in self.args] return Point(coords, evaluate=False) def __eq__(self, other): if not isinstance(other, Point) or len(self.args) != len(other.args): return False return self.args == other.args def __getitem__(self, key): return self.args[key] def __hash__(self): return hash(self.args) def __iter__(self): return self.args.__iter__() def __len__(self): return len(self.args) def __mul__(self, factor): """Multiply point's coordinates by a factor. Notes ===== >>> from sympy.geometry.point import Point When multiplying a Point by a floating point number, the coordinates of the Point will be changed to Floats: >>> Point(1, 2)0.1 Point2D(0.1, 0.2) If this is not desired, the `scale` method can be used or else only multiply or divide by integers: >>> Point(1, 2).scale(1.1, 1.1) Point2D(11/10, 11/5) >>> Point(1, 2)11/10 Point2D(11/10, 11/5) See Also ======== sympy.geometry.point.Point.scale """ factor = sympify(factor) coords = [simplify(xfactor) for x in self.args] return Point(coords, evaluate=False) def __neg__(self): """Negate the point.""" coords = [-x for x in self.args] return Point(coords, evaluate=False) def __sub__(self, other): """Subtract two points, or subtract a factor from this point's coordinates.""" return self + [-x for x in other] @classmethod def _normalize_dimension(cls, points, kwargs): """Ensure that points have the same dimension. By default `on_morph='warn'` is passed to the `Point` constructor.""" # if we have a built-in ambient dimension, use it dim = getattr(cls, '_ambient_dimension', None) # override if we specified it dim = kwargs.get('dim', dim) # if no dim was given, use the highest dimensional point if dim is None: dim = max(i.ambient_dimension for i in points) if all(i.ambient_dimension == dim for i in points): return list(points) kwargs['dim'] = dim kwargs['on_morph'] = kwargs.get('on_morph', 'warn') return [Point(i, kwargs) for i in points] @staticmethod def affine_rank(args): """The affine rank of a set of points is the dimension of the smallest affine space containing all the points. For example, if the points lie on a line (and are not all the same) their affine rank is 1. If the points lie on a plane but not a line, their affine rank is 2. By convention, the empty set has affine rank -1.""" if len(args) == 0: return -1 # make sure we're genuinely points # and translate every point to the origin points = Point._normalize_dimension([Point(i) for i in args]) origin = points[0] points = [i - origin for i in points[1:]] m = Matrix([i.args for i in points]) return m.rank() @property def ambient_dimension(self): """Number of components this point has.""" return getattr(self, '_ambient_dimension', len(self)) @classmethod def are_coplanar(cls, points): """Return True if there exists a plane in which all the points lie. A trivial True value is returned if `len(points) < 3` or all Points are 2-dimensional. Parameters ========== A set of points Raises ====== ValueError : if less than 3 unique points are given Returns ======= boolean Examples ======== >>> from sympy import Point3D >>> p1 = Point3D(1, 2, 2) >>> p2 = Point3D(2, 7, 2) >>> p3 = Point3D(0, 0, 2) >>> p4 = Point3D(1, 1, 2) >>> Point3D.are_coplanar(p1, p2, p3, p4) True >>> p5 = Point3D(0, 1, 3) >>> Point3D.are_coplanar(p1, p2, p3, p5) False """ if len(points) <= 1: return True points = cls._normalize_dimension([Point(i) for i in points]) # quick exit if we are in 2D if points[0].ambient_dimension == 2: return True points = list(uniq(points)) return Point.affine_rank(points) <= 2 def distance(self, other): """The Euclidean distance between self and another GeometricEntity. Returns ======= distance : number or symbolic expression. Raises ====== TypeError : if other is not recognized as a GeometricEntity or is a GeometricEntity for which distance is not defined. See Also ======== sympy.geometry.line.Segment.length sympy.geometry.point.Point.taxicab_distance Examples ======== >>> from sympy.geometry import Point, Line >>> p1, p2 = Point(1, 1), Point(4, 5) >>> l = Line((3, 1), (2, 2)) >>> p1.distance(p2) 5 >>> p1.distance(l) sqrt(2) The computed distance may be symbolic, too: >>> from sympy.abc import x, y >>> p3 = Point(x, y) >>> p3.distance((0, 0)) sqrt(x2 + y2) """ if not isinstance(other, GeometryEntity): try: other = Point(other, dim=self.ambient_dimension) except TypeError: raise TypeError("not recognized as a GeometricEntity: %s" % type(other)) if isinstance(other, Point): s, p = Point._normalize_dimension(self, Point(other)) return sqrt(Add(((a - b)2 for a, b in zip(s, p)))) distance = getattr(other, 'distance', None) if distance is None: raise TypeError("distance between Point and %s is not defined" % type(other)) return distance(self) def dot(self, p): """Return dot product of self with another Point.""" if not is_sequence(p): p = Point(p) # raise the error via Point return Add((ab for a, b in zip(self, p))) def equals(self, other): """Returns whether the coordinates of self and other agree.""" # a point is equal to another point if all its components are equal if not isinstance(other, Point) or len(self) != len(other): return False return all(a.equals(b) for a, b in zip(self, other)) def evalf(self, prec=None, options): """Evaluate the coordinates of the point. This method will, where possible, create and return a new Point where the coordinates are evaluated as floating point numbers to the precision indicated (default=15). Parameters ========== prec : int Returns ======= point : Point Examples ======== >>> from sympy import Point, Rational >>> p1 = Point(Rational(1, 2), Rational(3, 2)) >>> p1 Point2D(1/2, 3/2) >>> p1.evalf() Point2D(0.5, 1.5) """ coords = [x.evalf(prec, options) for x in self.args] return Point(coords, evaluate=False) def intersection(self, other): """The intersection between this point and another GeometryEntity. Parameters ========== other : Point Returns ======= intersection : list of Points Notes ===== The return value will either be an empty list if there is no intersection, otherwise it will contain this point. Examples ======== >>> from sympy import Point >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(0, 0) >>> p1.intersection(p2) [] >>> p1.intersection(p3) [Point2D(0, 0)] """ if not isinstance(other, GeometryEntity): other = Point(other) if isinstance(other, Point): if self == other: return [self] p1, p2 = Point._normalize_dimension(self, other) if p1 == self and p1 == p2: return [self] return [] return other.intersection(self) def is_collinear(self, args): """Returns `True` if there exists a line that contains `self` and `points`. Returns `False` otherwise. A trivially True value is returned if no points are given. Parameters ========== args : sequence of Points Returns ======= is_collinear : boolean See Also ======== sympy.geometry.line.Line Examples ======== >>> from sympy import Point >>> from sympy.abc import x >>> p1, p2 = Point(0, 0), Point(1, 1) >>> p3, p4, p5 = Point(2, 2), Point(x, x), Point(1, 2) >>> Point.is_collinear(p1, p2, p3, p4) True >>> Point.is_collinear(p1, p2, p3, p5) False """ points = (self,) + args points = Point._normalize_dimension([Point(i) for i in points]) points = list(uniq(points)) return Point.affine_rank(points) <= 1 def is_concyclic(self, args): """Do `self` and the given sequence of points lie in a circle? Returns True if the set of points are concyclic and False otherwise. A trivial value of True is returned if there are fewer than 2 other points. Parameters ========== args : sequence of Points Returns ======= is_concyclic : boolean Examples ======== >>> from sympy import Point Define 4 points that are on the unit circle: >>> p1, p2, p3, p4 = Point(1, 0), (0, 1), (-1, 0), (0, -1) >>> p1.is_concyclic() == p1.is_concyclic(p2, p3, p4) == True True Define a point not on that circle: >>> p = Point(1, 1) >>> p.is_concyclic(p1, p2, p3) False """ points = (self,) + args points = Point._normalize_dimension([Point(i) for i in points]) points = list(uniq(points)) if not Point.affine_rank(points) <= 2: return False origin = points[0] points = [p - origin for p in points] # points are concyclic if they are coplanar and # there is a point c so that \|\|p_i-c\|\| == \|\|p_j-c\|\| for all # i and j. Rearranging this equation gives us the following # condition: the matrix `mat` must not a pivot in the last # column. mat = Matrix([list(i) + [i.dot(i)] for i in points]) rref, pivots = mat.rref() if len(origin) not in pivots: return True return False @property def is_nonzero(self): """True if any coordinate is nonzero, False if every coordinate is zero, and None if it cannot be determined.""" is_zero = self.is_zero if is_zero is None: return None return not is_zero def is_scalar_multiple(self, p): """Returns whether each coordinate of `self` is a scalar multiple of the corresponding coordinate in point p. """ s, o = Point._normalize_dimension(self, Point(p)) # 2d points happen a lot, so optimize this function call if s.ambient_dimension == 2: (x1, y1), (x2, y2) = s.args, o.args rv = (x1y2 - x2y1).equals(0) if rv is None: raise Undecidable(filldedent( '''can't determine if %s is a scalar multiple of %s''' % (s, o))) # if the vectors p1 and p2 are linearly dependent, then they must # be scalar multiples of each other m = Matrix([s.args, o.args]) return m.rank() < 2 @property def is_zero(self): """True if every coordinate is zero, False if any coordinate is not zero, and None if it cannot be determined.""" nonzero = [x.is_nonzero for x in self.args] if any(nonzero): return False if any(x is None for x in nonzero): return None return True @property def length(self): """ Treating a Point as a Line, this returns 0 for the length of a Point. Examples ======== >>> from sympy import Point >>> p = Point(0, 1) >>> p.length 0 """ return S.Zero def midpoint(self, p): """The midpoint between self and point p. Parameters ========== p : Point Returns ======= midpoint : Point See Also ======== sympy.geometry.line.Segment.midpoint Examples ======== >>> from sympy.geometry import Point >>> p1, p2 = Point(1, 1), Point(13, 5) >>> p1.midpoint(p2) Point2D(7, 3) """ s, p = Point._normalize_dimension(self, Point(p)) return Point([simplify((a + b)S.Half) for a, b in zip(s, p)]) @property def origin(self): """A point of all zeros of the same ambient dimension as the current point""" return Point([0]len(self), evaluate=False) @property def orthogonal_direction(self): """Returns a non-zero point that is orthogonal to the line containing `self` and the origin. Examples ======== >>> from sympy.geometry import Line, Point >>> a = Point(1, 2, 3) >>> a.orthogonal_direction Point3D(-2, 1, 0) >>> b = _ >>> Line(b, b.origin).is_perpendicular(Line(a, a.origin)) True """ dim = self.ambient_dimension # if a coordinate is zero, we can put a 1 there and zeros elsewhere if self[0] == S.Zero: return Point([1] + (dim - 1)[0]) if self[1] == S.Zero: return Point([0,1] + (dim - 2)[0]) # if the first two coordinates aren't zero, we can create a non-zero # orthogonal vector by swapping them, negating one, and padding with zeros return Point([-self[1], self[0]] + (dim - 2)[0]) @staticmethod def project(a, b): """Project the point `a` onto the line between the origin and point `b` along the normal direction. Parameters ========== a : Point b : Point Returns ======= p : Point See Also ======== sympy.geometry.line.LinearEntity.projection Examples ======== >>> from sympy.geometry import Line, Point >>> a = Point(1, 2) >>> b = Point(2, 5) >>> z = a.origin >>> p = Point.project(a, b) >>> Line(p, a).is_perpendicular(Line(p, b)) True >>> Point.is_collinear(z, p, b) True """ a, b = Point._normalize_dimension(Point(a), Point(b)) if b.is_zero: raise ValueError("Cannot project to the zero vector.") return b(a.dot(b) / b.dot(b)) def taxicab_distance(self, p): """The Taxicab Distance from self to point p. Returns the sum of the horizontal and vertical distances to point p. Parameters ========== p : Point Returns ======= taxicab_distance : The sum of the horizontal and vertical distances to point p. See Also ======== sympy.geometry.point.Point.distance Examples ======== >>> from sympy.geometry import Point >>> p1, p2 = Point(1, 1), Point(4, 5) >>> p1.taxicab_distance(p2) 7 """ s, p = Point._normalize_dimension(self, Point(p)) return Add((abs(a - b) for a, b in zip(s, p))) def canberra_distance(self, p): """The Canberra Distance from self to point p. Returns the weighted sum of horizontal and vertical distances to point p. Parameters ========== p : Point Returns ======= canberra_distance : The weighted sum of horizontal and vertical distances to point p. The weight used is the sum of absolute values of the coordinates. Examples ======== >>> from sympy.geometry import Point >>> p1, p2 = Point(1, 1), Point(3, 3) >>> p1.canberra_distance(p2) 1 >>> p1, p2 = Point(0, 0), Point(3, 3) >>> p1.canberra_distance(p2) 2 Raises ====== ValueError when both vectors are zero. See Also ======== sympy.geometry.point.Point.distance """ s, p = Point._normalize_dimension(self, Point(p)) if self.is_zero and p.is_zero: raise ValueError("Cannot project to the zero vector.") return Add(((abs(a - b)/(abs(a) + abs(b))) for a, b in zip(s, p))) @property def unit(self): """Return the Point that is in the same direction as `self` and a distance of 1 from the origin""" return self / abs(self) n = evalf __truediv__ = __div__ class Point2D(Point): """A point in a 2-dimensional Euclidean space. Parameters ========== coords : sequence of 2 coordinate values. Attributes ========== x y length Raises ====== TypeError When trying to add or subtract points with different dimensions. When trying to create a point with more than two dimensions. When `intersection` is called with object other than a Point. See Also ======== sympy.geometry.line.Segment : Connects two Points Examples ======== >>> from sympy.geometry import Point2D >>> from sympy.abc import x >>> Point2D(1, 2) Point2D(1, 2) >>> Point2D([1, 2]) Point2D(1, 2) >>> Point2D(0, x) Point2D(0, x) Floats are automatically converted to Rational unless the evaluate flag is False: >>> Point2D(0.5, 0.25) Point2D(1/2, 1/4) >>> Point2D(0.5, 0.25, evaluate=False) Point2D(0.5, 0.25) """ _ambient_dimension = 2 def __new__(cls, args, kwargs): if not kwargs.pop('_nocheck', False): kwargs['dim'] = 2 args = Point(args, *kwargs) return GeometryEntity.__new__(cls, args) def __contains__(self, item): return item == self @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ return (self.x, self.y, self.x, self.y) def rotate(self, angle, pt=None): """Rotate ``angle`` radians counterclockwise about Point ``pt``. See Also ======== rotate, scale Examples ======== >>> from sympy import Point2D, pi >>> t = Point2D(1, 0) >>> t.rotate(pi/2) Point2D(0, 1) >>> t.rotate(pi/2, (2, 0)) Point2D(2, -1) """ from sympy import cos, sin, Point c = cos(angle) s = sin(angle) rv = self if pt is not None: pt = Point(pt, dim=2) rv -= pt x, y = rv.args rv = Point(cx - sy, sx + cy) if pt is not None: rv += pt return rv def scale(self, x=1, y=1, pt=None): """Scale the coordinates of the Point by multiplying by ``x`` and ``y`` after subtracting ``pt`` -- default is (0, 0) -- and then adding ``pt`` back again (i.e. ``pt`` is the point of reference for the scaling). See Also ======== rotate, translate Examples ======== >>> from sympy import Point2D >>> t = Point2D(1, 1) >>> t.scale(2) Point2D(2, 1) >>> t.scale(2, 2) Point2D(2, 2) """ if pt: pt = Point(pt, dim=2) return self.translate((-pt).args).scale(x, y).translate(pt.args) return Point(self.xx, self.yy) def transform(self, matrix): """Return the point after applying the transformation described by the 3x3 Matrix, ``matrix``. See Also ======== geometry.entity.rotate geometry.entity.scale geometry.entity.translate """ if not (matrix.is_Matrix and matrix.shape == (3, 3)): raise ValueError("matrix must be a 3x3 matrix") col, row = matrix.shape valid_matrix = matrix.is_square and col == 3 x, y = self.args return Point((Matrix(1, 3, [x, y, 1])matrix).tolist()[0][:2]) def translate(self, x=0, y=0): """Shift the Point by adding x and y to the coordinates of the Point. See Also ======== rotate, scale Examples ======== >>> from sympy import Point2D >>> t = Point2D(0, 1) >>> t.translate(2) Point2D(2, 1) >>> t.translate(2, 2) Point2D(2, 3) >>> t + Point2D(2, 2) Point2D(2, 3) """ return Point(self.x + x, self.y + y) @property def x(self): """ Returns the X coordinate of the Point. Examples ======== >>> from sympy import Point2D >>> p = Point2D(0, 1) >>> p.x 0 """ return self.args[0] @property def y(self): """ Returns the Y coordinate of the Point. Examples ======== >>> from sympy import Point2D >>> p = Point2D(0, 1) >>> p.y 1 """ return self.args[1] class Point3D(Point): """A point in a 3-dimensional Euclidean space. Parameters ========== coords : sequence of 3 coordinate values. Attributes ========== x y z length Raises ====== TypeError When trying to add or subtract points with different dimensions. When `intersection` is called with object other than a Point. Examples ======== >>> from sympy import Point3D >>> from sympy.abc import x >>> Point3D(1, 2, 3) Point3D(1, 2, 3) >>> Point3D([1, 2, 3]) Point3D(1, 2, 3) >>> Point3D(0, x, 3) Point3D(0, x, 3) Floats are automatically converted to Rational unless the evaluate flag is False: >>> Point3D(0.5, 0.25, 2) Point3D(1/2, 1/4, 2) >>> Point3D(0.5, 0.25, 3, evaluate=False) Point3D(0.5, 0.25, 3) """ _ambient_dimension = 3 def __new__(cls, args, kwargs): if not kwargs.pop('_nocheck', False): kwargs['dim'] = 3 args = Point(args, *kwargs) return GeometryEntity.__new__(cls, args) def __contains__(self, item): return item == self @staticmethod def are_collinear(points): """Is a sequence of points collinear? Test whether or not a set of points are collinear. Returns True if the set of points are collinear, or False otherwise. Parameters ========== points : sequence of Point Returns ======= are_collinear : boolean See Also ======== sympy.geometry.line.Line3D Examples ======== >>> from sympy import Point3D, Matrix >>> from sympy.abc import x >>> p1, p2 = Point3D(0, 0, 0), Point3D(1, 1, 1) >>> p3, p4, p5 = Point3D(2, 2, 2), Point3D(x, x, x), Point3D(1, 2, 6) >>> Point3D.are_collinear(p1, p2, p3, p4) True >>> Point3D.are_collinear(p1, p2, p3, p5) False """ return Point.is_collinear(points) def direction_cosine(self, point): """ Gives the direction cosine between 2 points Parameters ========== p : Point3D Returns ======= list Examples ======== >>> from sympy import Point3D >>> p1 = Point3D(1, 2, 3) >>> p1.direction_cosine(Point3D(2, 3, 5)) [sqrt(6)/6, sqrt(6)/6, sqrt(6)/3] """ a = self.direction_ratio(point) b = sqrt(Add((i2 for i in a))) return [(point.x - self.x) / b,(point.y - self.y) / b, (point.z - self.z) / b] def direction_ratio(self, point): """ Gives the direction ratio between 2 points Parameters ========== p : Point3D Returns ======= list Examples ======== >>> from sympy import Point3D >>> p1 = Point3D(1, 2, 3) >>> p1.direction_ratio(Point3D(2, 3, 5)) [1, 1, 2] """ return [(point.x - self.x),(point.y - self.y),(point.z - self.z)] def intersection(self, other): """The intersection between this point and another point. Parameters ========== other : Point Returns ======= intersection : list of Points Notes ===== The return value will either be an empty list if there is no intersection, otherwise it will contain this point. Examples ======== >>> from sympy import Point3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(0, 0, 0) >>> p1.intersection(p2) [] >>> p1.intersection(p3) [Point3D(0, 0, 0)] """ if not isinstance(other, GeometryEntity): other = Point(other, dim=3) if isinstance(other, Point3D): if self == other: return [self] return [] return other.intersection(self) def scale(self, x=1, y=1, z=1, pt=None): """Scale the coordinates of the Point by multiplying by ``x`` and ``y`` after subtracting ``pt`` -- default is (0, 0) -- and then adding ``pt`` back again (i.e. ``pt`` is the point of reference for the scaling). See Also ======== translate Examples ======== >>> from sympy import Point3D >>> t = Point3D(1, 1, 1) >>> t.scale(2) Point3D(2, 1, 1) >>> t.scale(2, 2) Point3D(2, 2, 1) """ if pt: pt = Point3D(pt) return self.translate((-pt).args).scale(x, y, z).translate(pt.args) return Point3D(self.xx, self.yy, self.zz) def transform(self, matrix): """Return the point after applying the transformation described by the 4x4 Matrix, ``matrix``. See Also ======== geometry.entity.rotate geometry.entity.scale geometry.entity.translate """ if not (matrix.is_Matrix and matrix.shape == (4, 4)): raise ValueError("matrix must be a 4x4 matrix") col, row = matrix.shape valid_matrix = matrix.is_square and col == 4 from sympy.matrices.expressions import Transpose x, y, z = self.args m = Transpose(matrix) return Point3D((Matrix(1, 4, [x, y, z, 1])m).tolist()[0][:3]) def translate(self, x=0, y=0, z=0): """Shift the Point by adding x and y to the coordinates of the Point. See Also ======== rotate, scale Examples ======== >>> from sympy import Point3D >>> t = Point3D(0, 1, 1) >>> t.translate(2) Point3D(2, 1, 1) >>> t.translate(2, 2) Point3D(2, 3, 1) >>> t + Point3D(2, 2, 2) Point3D(2, 3, 3) """ return Point3D(self.x + x, self.y + y, self.z + z) @property def x(self): """ Returns the X coordinate of the Point. Examples ======== >>> from sympy import Point3D >>> p = Point3D(0, 1, 3) >>> p.x 0 """ return self.args[0] @property def y(self): """ Returns the Y coordinate of the Point. Examples ======== >>> from sympy import Point3D >>> p = Point3D(0, 1, 2) >>> p.y 1 """ return self.args[1] @property def z(self): """ Returns the Z coordinate of the Point. Examples ======== >>> from sympy import Point3D >>> p = Point3D(0, 1, 1) >>> p.z 1 """ return self.args[2]
7901b9adf9dd534ad7b27d1de84519b4b50bdc0ba70fb267c125e580b0b2282b	"""Geometrical Planes. Contains ======== Plane """ from __future__ import division, print_function from sympy import simplify from sympy.core import Dummy, Rational, S, Symbol from sympy.core.symbol import _symbol from sympy.core.compatibility import is_sequence from sympy.functions.elementary.trigonometric import cos, sin, acos, asin, sqrt from sympy.matrices import Matrix from sympy.polys.polytools import cancel from sympy.solvers import solve, linsolve from sympy.utilities.iterables import uniq from sympy.utilities.misc import filldedent, func_name, Undecidable from .entity import GeometryEntity from .point import Point, Point3D from .line import Line, Ray, Segment, Line3D, LinearEntity3D, Ray3D, Segment3D class Plane(GeometryEntity): """ A plane is a flat, two-dimensional surface. A plane is the two-dimensional analogue of a point (zero-dimensions), a line (one-dimension) and a solid (three-dimensions). A plane can generally be constructed by two types of inputs. They are three non-collinear points and a point and the plane's normal vector. Attributes ========== p1 normal_vector Examples ======== >>> from sympy import Plane, Point3D >>> from sympy.abc import x >>> Plane(Point3D(1, 1, 1), Point3D(2, 3, 4), Point3D(2, 2, 2)) Plane(Point3D(1, 1, 1), (-1, 2, -1)) >>> Plane((1, 1, 1), (2, 3, 4), (2, 2, 2)) Plane(Point3D(1, 1, 1), (-1, 2, -1)) >>> Plane(Point3D(1, 1, 1), normal_vector=(1,4,7)) Plane(Point3D(1, 1, 1), (1, 4, 7)) """ def __new__(cls, p1, a=None, b=None, kwargs): p1 = Point3D(p1, dim=3) if a and b: p2 = Point(a, dim=3) p3 = Point(b, dim=3) if Point3D.are_collinear(p1, p2, p3): raise ValueError('Enter three non-collinear points') a = p1.direction_ratio(p2) b = p1.direction_ratio(p3) normal_vector = tuple(Matrix(a).cross(Matrix(b))) else: a = kwargs.pop('normal_vector', a) if is_sequence(a) and len(a) == 3: normal_vector = Point3D(a).args else: raise ValueError(filldedent(''' Either provide 3 3D points or a point with a normal vector expressed as a sequence of length 3''')) if all(coord.is_zero for coord in normal_vector): raise ValueError('Normal vector cannot be zero vector') return GeometryEntity.__new__(cls, p1, normal_vector, kwargs) def __contains__(self, o): from sympy.geometry.line import LinearEntity, LinearEntity3D x, y, z = map(Dummy, 'xyz') k = self.equation(x, y, z) if isinstance(o, (LinearEntity, LinearEntity3D)): t = Dummy() d = Point3D(o.arbitrary_point(t)) e = k.subs([(x, d.x), (y, d.y), (z, d.z)]) return e.equals(0) try: o = Point(o, dim=3, strict=True) d = k.xreplace(dict(zip((x, y, z), o.args))) return d.equals(0) except TypeError: return False def angle_between(self, o): """Angle between the plane and other geometric entity. Parameters ========== LinearEntity3D, Plane. Returns ======= angle : angle in radians Notes ===== This method accepts only 3D entities as it's parameter, but if you want to calculate the angle between a 2D entity and a plane you should first convert to a 3D entity by projecting onto a desired plane and then proceed to calculate the angle. Examples ======== >>> from sympy import Point3D, Line3D, Plane >>> a = Plane(Point3D(1, 2, 2), normal_vector=(1, 2, 3)) >>> b = Line3D(Point3D(1, 3, 4), Point3D(2, 2, 2)) >>> a.angle_between(b) -asin(sqrt(21)/6) """ from sympy.geometry.line import LinearEntity3D if isinstance(o, LinearEntity3D): a = Matrix(self.normal_vector) b = Matrix(o.direction_ratio) c = a.dot(b) d = sqrt(sum([i2 for i in self.normal_vector])) e = sqrt(sum([i2 for i in o.direction_ratio])) return asin(c/(de)) if isinstance(o, Plane): a = Matrix(self.normal_vector) b = Matrix(o.normal_vector) c = a.dot(b) d = sqrt(sum([i2 for i in self.normal_vector])) e = sqrt(sum([i2 for i in o.normal_vector])) return acos(c/(de)) def arbitrary_point(self, u=None, v=None): """ Returns an arbitrary point on the Plane. If given two parameters, the point ranges over the entire plane. If given 1 or no parameters, returns a point with one parameter which, when varying from 0 to 2pi, moves the point in a circle of radius 1 about p1 of the Plane. Examples ======== >>> from sympy.geometry import Plane, Ray >>> from sympy.abc import u, v, t, r >>> p = Plane((1, 1, 1), normal_vector=(1, 0, 0)) >>> p.arbitrary_point(u, v) Point3D(1, u + 1, v + 1) >>> p.arbitrary_point(t) Point3D(1, cos(t) + 1, sin(t) + 1) While arbitrary values of u and v can move the point anywhere in the plane, the single-parameter point can be used to construct a ray whose arbitrary point can be located at angle t and radius r from p.p1: >>> Ray(p.p1, _).arbitrary_point(r) Point3D(1, rcos(t) + 1, rsin(t) + 1) Returns ======= Point3D """ circle = v is None if circle: u = _symbol(u or 't', real=True) else: u = _symbol(u or 'u', real=True) v = _symbol(v or 'v', real=True) x, y, z = self.normal_vector a, b, c = self.p1.args # x1, y1, z1 is a nonzero vector parallel to the plane if x.is_zero and y.is_zero: x1, y1, z1 = S.One, S.Zero, S.Zero else: x1, y1, z1 = -y, x, S.Zero # x2, y2, z2 is also parallel to the plane, and orthogonal to x1, y1, z1 x2, y2, z2 = tuple(Matrix((x, y, z)).cross(Matrix((x1, y1, z1)))) if circle: x1, y1, z1 = (w/sqrt(x12 + y12 + z12) for w in (x1, y1, z1)) x2, y2, z2 = (w/sqrt(x22 + y22 + z22) for w in (x2, y2, z2)) p = Point3D(a + x1cos(u) + x2sin(u), \ b + y1cos(u) + y2sin(u), \ c + z1cos(u) + z2sin(u)) else: p = Point3D(a + x1u + x2v, b + y1u + y2v, c + z1u + z2v) return p @staticmethod def are_concurrent(planes): """Is a sequence of Planes concurrent? Two or more Planes are concurrent if their intersections are a common line. Parameters ========== planes: list Returns ======= Boolean Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(5, 0, 0), normal_vector=(1, -1, 1)) >>> b = Plane(Point3D(0, -2, 0), normal_vector=(3, 1, 1)) >>> c = Plane(Point3D(0, -1, 0), normal_vector=(5, -1, 9)) >>> Plane.are_concurrent(a, b) True >>> Plane.are_concurrent(a, b, c) False """ planes = list(uniq(planes)) for i in planes: if not isinstance(i, Plane): raise ValueError('All objects should be Planes but got %s' % i.func) if len(planes) < 2: return False planes = list(planes) first = planes.pop(0) sol = first.intersection(planes[0]) if sol == []: return False else: line = sol[0] for i in planes[1:]: l = first.intersection(i) if not l or not l[0] in line: return False return True def distance(self, o): """Distance between the plane and another geometric entity. Parameters ========== Point3D, LinearEntity3D, Plane. Returns ======= distance Notes ===== This method accepts only 3D entities as it's parameter, but if you want to calculate the distance between a 2D entity and a plane you should first convert to a 3D entity by projecting onto a desired plane and then proceed to calculate the distance. Examples ======== >>> from sympy import Point, Point3D, Line, Line3D, Plane >>> a = Plane(Point3D(1, 1, 1), normal_vector=(1, 1, 1)) >>> b = Point3D(1, 2, 3) >>> a.distance(b) sqrt(3) >>> c = Line3D(Point3D(2, 3, 1), Point3D(1, 2, 2)) >>> a.distance(c) 0 """ from sympy.geometry.line import LinearEntity3D if self.intersection(o) != []: return S.Zero if isinstance(o, (Segment3D, Ray3D)): a, b = o.p1, o.p2 pi, = self.intersection(Line3D(a, b)) if pi in o: return self.distance(pi) elif a in Segment3D(pi, b): return self.distance(a) else: assert isinstance(o, Segment3D) is True return self.distance(b) # following code handles `Point3D`, `LinearEntity3D`, `Plane` a = o if isinstance(o, Point3D) else o.p1 n = Point3D(self.normal_vector).unit d = (a - self.p1).dot(n) return abs(d) def equals(self, o): """ Returns True if self and o are the same mathematical entities. Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1, 2, 3), normal_vector=(1, 1, 1)) >>> b = Plane(Point3D(1, 2, 3), normal_vector=(2, 2, 2)) >>> c = Plane(Point3D(1, 2, 3), normal_vector=(-1, 4, 6)) >>> a.equals(a) True >>> a.equals(b) True >>> a.equals(c) False """ if isinstance(o, Plane): a = self.equation() b = o.equation() return simplify(a / b).is_constant() else: return False def equation(self, x=None, y=None, z=None): """The equation of the Plane. Examples ======== >>> from sympy import Point3D, Plane >>> a = Plane(Point3D(1, 1, 2), Point3D(2, 4, 7), Point3D(3, 5, 1)) >>> a.equation() -23x + 11y - 2z + 16 >>> a = Plane(Point3D(1, 4, 2), normal_vector=(6, 6, 6)) >>> a.equation() 6x + 6y + 6z - 42 """ x, y, z = [i if i else Symbol(j, real=True) for i, j in zip((x, y, z), 'xyz')] a = Point3D(x, y, z) b = self.p1.direction_ratio(a) c = self.normal_vector return (sum(ij for i, j in zip(b, c))) def intersection(self, o): """ The intersection with other geometrical entity. Parameters ========== Point, Point3D, LinearEntity, LinearEntity3D, Plane Returns ======= List Examples ======== >>> from sympy import Point, Point3D, Line, Line3D, Plane >>> a = Plane(Point3D(1, 2, 3), normal_vector=(1, 1, 1)) >>> b = Point3D(1, 2, 3) >>> a.intersection(b) [Point3D(1, 2, 3)] >>> c = Line3D(Point3D(1, 4, 7), Point3D(2, 2, 2)) >>> a.intersection(c) [Point3D(2, 2, 2)] >>> d = Plane(Point3D(6, 0, 0), normal_vector=(2, -5, 3)) >>> e = Plane(Point3D(2, 0, 0), normal_vector=(3, 4, -3)) >>> d.intersection(e) [Line3D(Point3D(78/23, -24/23, 0), Point3D(147/23, 321/23, 23))] """ from sympy.geometry.line import LinearEntity, LinearEntity3D if not isinstance(o, GeometryEntity): o = Point(o, dim=3) if isinstance(o, Point): if o in self: return [o] else: return [] if isinstance(o, (LinearEntity, LinearEntity3D)): # recast to 3D p1, p2 = o.p1, o.p2 if isinstance(o, Segment): o = Segment3D(p1, p2) elif isinstance(o, Ray): o = Ray3D(p1, p2) elif isinstance(o, Line): o = Line3D(p1, p2) else: raise ValueError('unhandled linear entity: %s' % o.func) if o in self: return [o] else: t = Dummy() # unnamed else it may clash with a symbol in o a = Point3D(o.arbitrary_point(t)) p1, n = self.p1, Point3D(self.normal_vector) # TODO: Replace solve with solveset, when this line is tested c = solve((a - p1).dot(n), t) if not c: return [] else: c = [i for i in c if i.is_real is not False] if len(c) > 1: c = [i for i in c if i.is_real] if len(c) != 1: raise Undecidable("not sure which point is real") p = a.subs(t, c[0]) if p not in o: return [] # e.g. a segment might not intersect a plane return [p] if isinstance(o, Plane): if self.equals(o): return [self] if self.is_parallel(o): return [] else: x, y, z = map(Dummy, 'xyz') a, b = Matrix([self.normal_vector]), Matrix([o.normal_vector]) c = list(a.cross(b)) d = self.equation(x, y, z) e = o.equation(x, y, z) result = list(linsolve([d, e], x, y, z))[0] for i in (x, y, z): result = result.subs(i, 0) return [Line3D(Point3D(result), direction_ratio=c)] def is_coplanar(self, o): """ Returns True if `o` is coplanar with self, else False. Examples ======== >>> from sympy import Plane, Point3D >>> o = (0, 0, 0) >>> p = Plane(o, (1, 1, 1)) >>> p2 = Plane(o, (2, 2, 2)) >>> p == p2 False >>> p.is_coplanar(p2) True """ if isinstance(o, Plane): x, y, z = map(Dummy, 'xyz') return not cancel(self.equation(x, y, z)/o.equation(x, y, z)).has(x, y, z) if isinstance(o, Point3D): return o in self elif isinstance(o, LinearEntity3D): return all(i in self for i in self) elif isinstance(o, GeometryEntity): # XXX should only be handling 2D objects now return all(i == 0 for i in self.normal_vector[:2]) def is_parallel(self, l): """Is the given geometric entity parallel to the plane? Parameters ========== LinearEntity3D or Plane Returns ======= Boolean Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1,4,6), normal_vector=(2, 4, 6)) >>> b = Plane(Point3D(3,1,3), normal_vector=(4, 8, 12)) >>> a.is_parallel(b) True """ from sympy.geometry.line import LinearEntity3D if isinstance(l, LinearEntity3D): a = l.direction_ratio b = self.normal_vector c = sum([ij for i, j in zip(a, b)]) if c == 0: return True else: return False elif isinstance(l, Plane): a = Matrix(l.normal_vector) b = Matrix(self.normal_vector) if a.cross(b).is_zero: return True else: return False def is_perpendicular(self, l): """is the given geometric entity perpendicualar to the given plane? Parameters ========== LinearEntity3D or Plane Returns ======= Boolean Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1,4,6), normal_vector=(2, 4, 6)) >>> b = Plane(Point3D(2, 2, 2), normal_vector=(-1, 2, -1)) >>> a.is_perpendicular(b) True """ from sympy.geometry.line import LinearEntity3D if isinstance(l, LinearEntity3D): a = Matrix(l.direction_ratio) b = Matrix(self.normal_vector) if a.cross(b).is_zero: return True else: return False elif isinstance(l, Plane): a = Matrix(l.normal_vector) b = Matrix(self.normal_vector) if a.dot(b) == 0: return True else: return False else: return False @property def normal_vector(self): """Normal vector of the given plane. Examples ======== >>> from sympy import Point3D, Plane >>> a = Plane(Point3D(1, 1, 1), Point3D(2, 3, 4), Point3D(2, 2, 2)) >>> a.normal_vector (-1, 2, -1) >>> a = Plane(Point3D(1, 1, 1), normal_vector=(1, 4, 7)) >>> a.normal_vector (1, 4, 7) """ return self.args[1] @property def p1(self): """The only defining point of the plane. Others can be obtained from the arbitrary_point method. See Also ======== sympy.geometry.point.Point3D Examples ======== >>> from sympy import Point3D, Plane >>> a = Plane(Point3D(1, 1, 1), Point3D(2, 3, 4), Point3D(2, 2, 2)) >>> a.p1 Point3D(1, 1, 1) """ return self.args[0] def parallel_plane(self, pt): """ Plane parallel to the given plane and passing through the point pt. Parameters ========== pt: Point3D Returns ======= Plane Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1, 4, 6), normal_vector=(2, 4, 6)) >>> a.parallel_plane(Point3D(2, 3, 5)) Plane(Point3D(2, 3, 5), (2, 4, 6)) """ a = self.normal_vector return Plane(pt, normal_vector=a) def perpendicular_line(self, pt): """A line perpendicular to the given plane. Parameters ========== pt: Point3D Returns ======= Line3D Examples ======== >>> from sympy import Plane, Point3D, Line3D >>> a = Plane(Point3D(1,4,6), normal_vector=(2, 4, 6)) >>> a.perpendicular_line(Point3D(9, 8, 7)) Line3D(Point3D(9, 8, 7), Point3D(11, 12, 13)) """ a = self.normal_vector return Line3D(pt, direction_ratio=a) def perpendicular_plane(self, pts): """ Return a perpendicular passing through the given points. If the direction ratio between the points is the same as the Plane's normal vector then, to select from the infinite number of possible planes, a third point will be chosen on the z-axis (or the y-axis if the normal vector is already parallel to the z-axis). If less than two points are given they will be supplied as follows: if no point is given then pt1 will be self.p1; if a second point is not given it will be a point through pt1 on a line parallel to the z-axis (if the normal is not already the z-axis, otherwise on the line parallel to the y-axis). Parameters ========== pts: 0, 1 or 2 Point3D Returns ======= Plane Examples ======== >>> from sympy import Plane, Point3D, Line3D >>> a, b = Point3D(0, 0, 0), Point3D(0, 1, 0) >>> Z = (0, 0, 1) >>> p = Plane(a, normal_vector=Z) >>> p.perpendicular_plane(a, b) Plane(Point3D(0, 0, 0), (1, 0, 0)) """ if len(pts) > 2: raise ValueError('No more than 2 pts should be provided.') pts = list(pts) if len(pts) == 0: pts.append(self.p1) if len(pts) == 1: x, y, z = self.normal_vector if x == y == 0: dir = (0, 1, 0) else: dir = (0, 0, 1) pts.append(pts[0] + Point3D(dir)) p1, p2 = [Point(i, dim=3) for i in pts] l = Line3D(p1, p2) n = Line3D(p1, direction_ratio=self.normal_vector) if l in n: # XXX should an error be raised instead? # there are infinitely many perpendicular planes; x, y, z = self.normal_vector if x == y == 0: # the z axis is the normal so pick a pt on the y-axis p3 = Point3D(0, 1, 0) # case 1 else: # else pick a pt on the z axis p3 = Point3D(0, 0, 1) # case 2 # in case that point is already given, move it a bit if p3 in l: p3 = 2 # case 3 else: p3 = p1 + Point3D(self.normal_vector) # case 4 return Plane(p1, p2, p3) def projection_line(self, line): """Project the given line onto the plane through the normal plane containing the line. Parameters ========== LinearEntity or LinearEntity3D Returns ======= Point3D, Line3D, Ray3D or Segment3D Notes ===== For the interaction between 2D and 3D lines(segments, rays), you should convert the line to 3D by using this method. For example for finding the intersection between a 2D and a 3D line, convert the 2D line to a 3D line by projecting it on a required plane and then proceed to find the intersection between those lines. Examples ======== >>> from sympy import Plane, Line, Line3D, Point, Point3D >>> a = Plane(Point3D(1, 1, 1), normal_vector=(1, 1, 1)) >>> b = Line(Point3D(1, 1), Point3D(2, 2)) >>> a.projection_line(b) Line3D(Point3D(4/3, 4/3, 1/3), Point3D(5/3, 5/3, -1/3)) >>> c = Line3D(Point3D(1, 1, 1), Point3D(2, 2, 2)) >>> a.projection_line(c) Point3D(1, 1, 1) """ from sympy.geometry.line import LinearEntity, LinearEntity3D if not isinstance(line, (LinearEntity, LinearEntity3D)): raise NotImplementedError('Enter a linear entity only') a, b = self.projection(line.p1), self.projection(line.p2) if a == b: # projection does not imply intersection so for # this case (line parallel to plane's normal) we # return the projection point return a if isinstance(line, (Line, Line3D)): return Line3D(a, b) if isinstance(line, (Ray, Ray3D)): return Ray3D(a, b) if isinstance(line, (Segment, Segment3D)): return Segment3D(a, b) def projection(self, pt): """Project the given point onto the plane along the plane normal. Parameters ========== Point or Point3D Returns ======= Point3D Examples ======== >>> from sympy import Plane, Point, Point3D >>> A = Plane(Point3D(1, 1, 2), normal_vector=(1, 1, 1)) The projection is along the normal vector direction, not the z axis, so (1, 1) does not project to (1, 1, 2) on the plane A: >>> b = Point3D(1, 1) >>> A.projection(b) Point3D(5/3, 5/3, 2/3) >>> _ in A True But the point (1, 1, 2) projects to (1, 1) on the XY-plane: >>> XY = Plane((0, 0, 0), (0, 0, 1)) >>> XY.projection((1, 1, 2)) Point3D(1, 1, 0) """ rv = Point(pt, dim=3) if rv in self: return rv return self.intersection(Line3D(rv, rv + Point3D(self.normal_vector)))[0] def random_point(self, seed=None): """ Returns a random point on the Plane. Returns ======= Point3D Examples ======== >>> from sympy import Plane >>> p = Plane((1, 0, 0), normal_vector=(0, 1, 0)) >>> r = p.random_point(seed=42) # seed value is optional >>> r.n(3) Point3D(2.29, 0, -1.35) The random point can be moved to lie on the circle of radius 1 centered on p1: >>> c = p.p1 + (r - p.p1).unit >>> c.distance(p.p1).equals(1) True """ import random if seed is not None: rng = random.Random(seed) else: rng = random u, v = Dummy('u'), Dummy('v') params = { u: 2Rational(rng.gauss(0, 1)) - 1, v: 2Rational(rng.gauss(0, 1)) - 1} return self.arbitrary_point(u, v).subs(params) def parameter_value(self, other, u, v=None): """Return the parameter(s) corresponding to the given point. Examples ======== >>> from sympy import Plane, Point, pi >>> from sympy.abc import t, u, v >>> p = Plane((2, 0, 0), (0, 0, 1), (0, 1, 0)) By default, the parameter value returned defines a point that is a distance of 1 from the Plane's p1 value and in line with the given point: >>> on_circle = p.arbitrary_point(t).subs(t, pi/4) >>> on_circle.distance(p.p1) 1 >>> p.parameter_value(on_circle, t) {t: pi/4} Moving the point twice as far from p1 does not change the parameter value: >>> off_circle = p.p1 + (on_circle - p.p1)*2 >>> off_circle.distance(p.p1) 2 >>> p.parameter_value(off_circle, t) {t: pi/4} If the 2-value parameter is desired, supply the two parameter symbols and a replacement dictionary will be returned: >>> p.parameter_value(on_circle, u, v) {u: sqrt(10)/10, v: sqrt(10)/30} >>> p.parameter_value(off_circle, u, v) {u: sqrt(10)/5, v: sqrt(10)/15} """ from sympy.geometry.point import Point from sympy.core.symbol import Dummy from sympy.solvers.solvers import solve if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if not isinstance(other, Point): raise ValueError("other must be a point") if other == self.p1: return other if isinstance(u, Symbol) and v is None: delta = self.arbitrary_point(u) - self.p1 eq = delta - (other - self.p1).unit sol = solve(eq, u, dict=True) elif isinstance(u, Symbol) and isinstance(v, Symbol): pt = self.arbitrary_point(u, v) sol = solve(pt - other, (u, v), dict=True) else: raise ValueError('expecting 1 or 2 symbols') if not sol: raise ValueError("Given point is not on %s" % func_name(self)) return sol[0] # {t: tval} or {u: uval, v: vval} @property def ambient_dimension(self): return self.p1.ambient_dimension
7bc84cca939d5cd389b613042a1f033d9f898ad5c91b253e384f2b244acbc194	"""Elliptical geometrical entities. Contains * Ellipse * Circle """ from __future__ import division, print_function from sympy import Expr, Eq from sympy.core import S, pi, sympify from sympy.core.evaluate import global_evaluate from sympy.core.logic import fuzzy_bool from sympy.core.numbers import Rational, oo from sympy.core.compatibility import ordered from sympy.core.symbol import Dummy, _uniquely_named_symbol, _symbol from sympy.simplify import simplify, trigsimp from sympy.functions.elementary.miscellaneous import sqrt, Max from sympy.functions.elementary.trigonometric import cos, sin from sympy.functions.special.elliptic_integrals import elliptic_e from sympy.geometry.exceptions import GeometryError from sympy.geometry.line import Ray2D, Segment2D, Line2D, LinearEntity3D from sympy.polys import DomainError, Poly, PolynomialError from sympy.polys.polyutils import _not_a_coeff, _nsort from sympy.solvers import solve from sympy.solvers.solveset import linear_coeffs from sympy.utilities.misc import filldedent, func_name from .entity import GeometryEntity, GeometrySet from .point import Point, Point2D, Point3D from .line import Line, Segment from .util import idiff import random class Ellipse(GeometrySet): """An elliptical GeometryEntity. Parameters ========== center : Point, optional Default value is Point(0, 0) hradius : number or SymPy expression, optional vradius : number or SymPy expression, optional eccentricity : number or SymPy expression, optional Two of `hradius`, `vradius` and `eccentricity` must be supplied to create an Ellipse. The third is derived from the two supplied. Attributes ========== center hradius vradius area circumference eccentricity periapsis apoapsis focus_distance foci Raises ====== GeometryError When `hradius`, `vradius` and `eccentricity` are incorrectly supplied as parameters. TypeError When `center` is not a Point. See Also ======== Circle Notes ----- Constructed from a center and two radii, the first being the horizontal radius (along the x-axis) and the second being the vertical radius (along the y-axis). When symbolic value for hradius and vradius are used, any calculation that refers to the foci or the major or minor axis will assume that the ellipse has its major radius on the x-axis. If this is not true then a manual rotation is necessary. Examples ======== >>> from sympy import Ellipse, Point, Rational >>> e1 = Ellipse(Point(0, 0), 5, 1) >>> e1.hradius, e1.vradius (5, 1) >>> e2 = Ellipse(Point(3, 1), hradius=3, eccentricity=Rational(4, 5)) >>> e2 Ellipse(Point2D(3, 1), 3, 9/5) """ def __contains__(self, o): if isinstance(o, Point): x = Dummy('x', real=True) y = Dummy('y', real=True) res = self.equation(x, y).subs({x: o.x, y: o.y}) return trigsimp(simplify(res)) is S.Zero elif isinstance(o, Ellipse): return self == o return False def __eq__(self, o): """Is the other GeometryEntity the same as this ellipse?""" return isinstance(o, Ellipse) and (self.center == o.center and self.hradius == o.hradius and self.vradius == o.vradius) def __hash__(self): return super(Ellipse, self).__hash__() def __new__( cls, center=None, hradius=None, vradius=None, eccentricity=None, kwargs): hradius = sympify(hradius) vradius = sympify(vradius) eccentricity = sympify(eccentricity) if center is None: center = Point(0, 0) else: center = Point(center, dim=2) if len(center) != 2: raise ValueError('The center of "{0}" must be a two dimensional point'.format(cls)) if len(list(filter(lambda x: x is not None, (hradius, vradius, eccentricity)))) != 2: raise ValueError(filldedent(''' Exactly two arguments of "hradius", "vradius", and "eccentricity" must not be None.''')) if eccentricity is not None: if hradius is None: hradius = vradius / sqrt(1 - eccentricity2) elif vradius is None: vradius = hradius * sqrt(1 - eccentricity2) if hradius == vradius: return Circle(center, hradius, kwargs) if hradius == 0 or vradius == 0: return Segment(Point(center[0] - hradius, center[1] - vradius), Point(center[0] + hradius, center[1] + vradius)) return GeometryEntity.__new__(cls, center, hradius, vradius, *kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG ellipse element for the Ellipse. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N c = N(self.center) h, v = N(self.hradius), N(self.vradius) return ( '<ellipse fill="{1}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" cx="{2}" cy="{3}" rx="{4}" ry="{5}"/>' ).format(2. scale_factor, fill_color, c.x, c.y, h, v) @property def ambient_dimension(self): return 2 @property def apoapsis(self): """The apoapsis of the ellipse. The greatest distance between the focus and the contour. Returns ======= apoapsis : number See Also ======== periapsis : Returns shortest distance between foci and contour Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.apoapsis 2sqrt(2) + 3 """ return self.major (1 + self.eccentricity) def arbitrary_point(self, parameter='t'): """A parameterized point on the ellipse. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= arbitrary_point : Point Raises ====== ValueError When `parameter` already appears in the functions. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.arbitrary_point() Point2D(3cos(t), 2sin(t)) """ t = _symbol(parameter, real=True) if t.name in (f.name for f in self.free_symbols): raise ValueError(filldedent('Symbol %s already appears in object ' 'and cannot be used as a parameter.' % t.name)) return Point(self.center.x + self.hradiuscos(t), self.center.y + self.vradiussin(t)) @property def area(self): """The area of the ellipse. Returns ======= area : number Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.area 3pi """ return simplify(S.Pi self.hradius * self.vradius) @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ h, v = self.hradius, self.vradius return (self.center.x - h, self.center.y - v, self.center.x + h, self.center.y + v) @property def center(self): """The center of the ellipse. Returns ======= center : number See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.center Point2D(0, 0) """ return self.args[0] @property def circumference(self): """The circumference of the ellipse. Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.circumference 12elliptic_e(8/9) """ if self.eccentricity == 1: # degenerate return 4self.major elif self.eccentricity == 0: # circle return 2piself.hradius else: return 4self.majorelliptic_e(self.eccentricity*2) @property def eccentricity(self): """The eccentricity of the ellipse. Returns ======= eccentricity : number Examples ======== >>> from sympy import Point, Ellipse, sqrt >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, sqrt(2)) >>> e1.eccentricity sqrt(7)/3 """ return self.focus_distance / self.major def encloses_point(self, p): """ Return True if p is enclosed by (is inside of) self. Notes ----- Being on the border of self is considered False. Parameters ========== p : Point Returns ======= encloses_point : True, False or None See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Ellipse, S >>> from sympy.abc import t >>> e = Ellipse((0, 0), 3, 2) >>> e.encloses_point((0, 0)) True >>> e.encloses_point(e.arbitrary_point(t).subs(t, S.Half)) False >>> e.encloses_point((4, 0)) False """ p = Point(p, dim=2) if p in self: return False if len(self.foci) == 2: # if the combined distance from the foci to p (h1 + h2) is less # than the combined distance from the foci to the minor axis # (which is the same as the major axis length) then p is inside # the ellipse h1, h2 = [f.distance(p) for f in self.foci] test = 2self.major - (h1 + h2) else: test = self.radius - self.center.distance(p) return fuzzy_bool(test.is_positive) def equation(self, x='x', y='y', _slope=None): """ Returns the equation of an ellipse aligned with the x and y axes; when slope is given, the equation returned corresponds to an ellipse with a major axis having that slope. Parameters ========== x : str, optional Label for the x-axis. Default value is 'x'. y : str, optional Label for the y-axis. Default value is 'y'. _slope : Expr, optional The slope of the major axis. Ignored when 'None'. Returns ======= equation : sympy expression See Also ======== arbitrary_point : Returns parameterized point on ellipse Examples ======== >>> from sympy import Point, Ellipse, pi >>> from sympy.abc import x, y >>> e1 = Ellipse(Point(1, 0), 3, 2) >>> eq1 = e1.equation(x, y); eq1 y2/4 + (x/3 - 1/3)2 - 1 >>> eq2 = e1.equation(x, y, _slope=1); eq2 (-x + y + 1)2/8 + (x + y - 1)2/18 - 1 A point on e1 satisfies eq1. Let's use one on the x-axis: >>> p1 = e1.center + Point(e1.major, 0) >>> assert eq1.subs(x, p1.x).subs(y, p1.y) == 0 When rotated the same as the rotated ellipse, about the center point of the ellipse, it will satisfy the rotated ellipse's equation, too: >>> r1 = p1.rotate(pi/4, e1.center) >>> assert eq2.subs(x, r1.x).subs(y, r1.y) == 0 References ========== .. [1] https://math.stackexchange.com/questions/108270/what-is-the-equation-of-an-ellipse-that-is-not-aligned-with-the-axis .. [2] https://en.wikipedia.org/wiki/Ellipse#Equation_of_a_shifted_ellipse """ x = _symbol(x, real=True) y = _symbol(y, real=True) dx = x - self.center.x dy = y - self.center.y if _slope is not None: L = (dy - _slopedx)2 l = (_slopedy + dx)2 h = 1 + _slope2 b = hself.major2 a = hself.minor2 return l/b + L/a - 1 else: t1 = (dx/self.hradius)2 t2 = (dy/self.vradius)2 return t1 + t2 - 1 def evolute(self, x='x', y='y'): """The equation of evolute of the ellipse. Parameters ========== x : str, optional Label for the x-axis. Default value is 'x'. y : str, optional Label for the y-axis. Default value is 'y'. Returns ======= equation : sympy expression Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(1, 0), 3, 2) >>> e1.evolute() 2(2/3)y(2/3) + (3x - 3)(2/3) - 5(2/3) """ if len(self.args) != 3: raise NotImplementedError('Evolute of arbitrary Ellipse is not supported.') x = _symbol(x, real=True) y = _symbol(y, real=True) t1 = (self.hradius(x - self.center.x))Rational(2, 3) t2 = (self.vradius(y - self.center.y))Rational(2, 3) return t1 + t2 - (self.hradius2 - self.vradius2)Rational(2, 3) @property def foci(self): """The foci of the ellipse. Notes ----- The foci can only be calculated if the major/minor axes are known. Raises ====== ValueError When the major and minor axis cannot be determined. See Also ======== sympy.geometry.point.Point focus_distance : Returns the distance between focus and center Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.foci (Point2D(-2sqrt(2), 0), Point2D(2sqrt(2), 0)) """ c = self.center hr, vr = self.hradius, self.vradius if hr == vr: return (c, c) # calculate focus distance manually, since focus_distance calls this # routine fd = sqrt(self.major2 - self.minor2) if hr == self.minor: # foci on the y-axis return (c + Point(0, -fd), c + Point(0, fd)) elif hr == self.major: # foci on the x-axis return (c + Point(-fd, 0), c + Point(fd, 0)) @property def focus_distance(self): """The focal distance of the ellipse. The distance between the center and one focus. Returns ======= focus_distance : number See Also ======== foci Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.focus_distance 2sqrt(2) """ return Point.distance(self.center, self.foci[0]) @property def hradius(self): """The horizontal radius of the ellipse. Returns ======= hradius : number See Also ======== vradius, major, minor Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.hradius 3 """ return self.args[1] def intersection(self, o): """The intersection of this ellipse and another geometrical entity `o`. Parameters ========== o : GeometryEntity Returns ======= intersection : list of GeometryEntity objects Notes ----- Currently supports intersections with Point, Line, Segment, Ray, Circle and Ellipse types. See Also ======== sympy.geometry.entity.GeometryEntity Examples ======== >>> from sympy import Ellipse, Point, Line, sqrt >>> e = Ellipse(Point(0, 0), 5, 7) >>> e.intersection(Point(0, 0)) [] >>> e.intersection(Point(5, 0)) [Point2D(5, 0)] >>> e.intersection(Line(Point(0,0), Point(0, 1))) [Point2D(0, -7), Point2D(0, 7)] >>> e.intersection(Line(Point(5,0), Point(5, 1))) [Point2D(5, 0)] >>> e.intersection(Line(Point(6,0), Point(6, 1))) [] >>> e = Ellipse(Point(-1, 0), 4, 3) >>> e.intersection(Ellipse(Point(1, 0), 4, 3)) [Point2D(0, -3sqrt(15)/4), Point2D(0, 3sqrt(15)/4)] >>> e.intersection(Ellipse(Point(5, 0), 4, 3)) [Point2D(2, -3sqrt(7)/4), Point2D(2, 3sqrt(7)/4)] >>> e.intersection(Ellipse(Point(100500, 0), 4, 3)) [] >>> e.intersection(Ellipse(Point(0, 0), 3, 4)) [Point2D(3, 0), Point2D(-363/175, -48sqrt(111)/175), Point2D(-363/175, 48sqrt(111)/175)] >>> e.intersection(Ellipse(Point(-1, 0), 3, 4)) [Point2D(-17/5, -12/5), Point2D(-17/5, 12/5), Point2D(7/5, -12/5), Point2D(7/5, 12/5)] """ # TODO: Replace solve with nonlinsolve, when nonlinsolve will be able to solve in real domain x = Dummy('x', real=True) y = Dummy('y', real=True) if isinstance(o, Point): if o in self: return [o] else: return [] elif isinstance(o, (Segment2D, Ray2D)): ellipse_equation = self.equation(x, y) result = solve([ellipse_equation, Line(o.points[0], o.points[1]).equation(x, y)], [x, y]) return list(ordered([Point(i) for i in result if i in o])) elif isinstance(o, Polygon): return o.intersection(self) elif isinstance(o, (Ellipse, Line2D)): if o == self: return self else: ellipse_equation = self.equation(x, y) return list(ordered([Point(i) for i in solve([ellipse_equation, o.equation(x, y)], [x, y])])) elif isinstance(o, LinearEntity3D): raise TypeError('Entity must be two dimensional, not three dimensional') else: raise TypeError('Intersection not handled for %s' % func_name(o)) def is_tangent(self, o): """Is `o` tangent to the ellipse? Parameters ========== o : GeometryEntity An Ellipse, LinearEntity or Polygon Raises ====== NotImplementedError When the wrong type of argument is supplied. Returns ======= is_tangent: boolean True if o is tangent to the ellipse, False otherwise. See Also ======== tangent_lines Examples ======== >>> from sympy import Point, Ellipse, Line >>> p0, p1, p2 = Point(0, 0), Point(3, 0), Point(3, 3) >>> e1 = Ellipse(p0, 3, 2) >>> l1 = Line(p1, p2) >>> e1.is_tangent(l1) True """ if isinstance(o, Point2D): return False elif isinstance(o, Ellipse): intersect = self.intersection(o) if isinstance(intersect, Ellipse): return True elif intersect: return all((self.tangent_lines(i)[0]).equals((o.tangent_lines(i)[0])) for i in intersect) else: return False elif isinstance(o, Line2D): return len(self.intersection(o)) == 1 elif isinstance(o, Ray2D): intersect = self.intersection(o) if len(intersect) == 1: return intersect[0] != o.source and not self.encloses_point(o.source) else: return False elif isinstance(o, (Segment2D, Polygon)): all_tangents = False segments = o.sides if isinstance(o, Polygon) else [o] for segment in segments: intersect = self.intersection(segment) if len(intersect) == 1: if not any(intersect[0] in i for i in segment.points) \ and all(not self.encloses_point(i) for i in segment.points): all_tangents = True continue else: return False else: return all_tangents return all_tangents elif isinstance(o, (LinearEntity3D, Point3D)): raise TypeError('Entity must be two dimensional, not three dimensional') else: raise TypeError('Is_tangent not handled for %s' % func_name(o)) @property def major(self): """Longer axis of the ellipse (if it can be determined) else hradius. Returns ======= major : number or expression See Also ======== hradius, vradius, minor Examples ======== >>> from sympy import Point, Ellipse, Symbol >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.major 3 >>> a = Symbol('a') >>> b = Symbol('b') >>> Ellipse(p1, a, b).major a >>> Ellipse(p1, b, a).major b >>> m = Symbol('m') >>> M = m + 1 >>> Ellipse(p1, m, M).major m + 1 """ ab = self.args[1:3] if len(ab) == 1: return ab[0] a, b = ab o = b - a < 0 if o == True: return a elif o == False: return b return self.hradius @property def minor(self): """Shorter axis of the ellipse (if it can be determined) else vradius. Returns ======= minor : number or expression See Also ======== hradius, vradius, major Examples ======== >>> from sympy import Point, Ellipse, Symbol >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.minor 1 >>> a = Symbol('a') >>> b = Symbol('b') >>> Ellipse(p1, a, b).minor b >>> Ellipse(p1, b, a).minor a >>> m = Symbol('m') >>> M = m + 1 >>> Ellipse(p1, m, M).minor m """ ab = self.args[1:3] if len(ab) == 1: return ab[0] a, b = ab o = a - b < 0 if o == True: return a elif o == False: return b return self.vradius def normal_lines(self, p, prec=None): """Normal lines between `p` and the ellipse. Parameters ========== p : Point Returns ======= normal_lines : list with 1, 2 or 4 Lines Examples ======== >>> from sympy import Line, Point, Ellipse >>> e = Ellipse((0, 0), 2, 3) >>> c = e.center >>> e.normal_lines(c + Point(1, 0)) [Line2D(Point2D(0, 0), Point2D(1, 0))] >>> e.normal_lines(c) [Line2D(Point2D(0, 0), Point2D(0, 1)), Line2D(Point2D(0, 0), Point2D(1, 0))] Off-axis points require the solution of a quartic equation. This often leads to very large expressions that may be of little practical use. An approximate solution of `prec` digits can be obtained by passing in the desired value: >>> e.normal_lines((3, 3), prec=2) [Line2D(Point2D(-0.81, -2.7), Point2D(0.19, -1.2)), Line2D(Point2D(1.5, -2.0), Point2D(2.5, -2.7))] Whereas the above solution has an operation count of 12, the exact solution has an operation count of 2020. """ p = Point(p, dim=2) # XXX change True to something like self.angle == 0 if the arbitrarily # rotated ellipse is introduced. # https://github.com/sympy/sympy/issues/2815) if True: rv = [] if p.x == self.center.x: rv.append(Line(self.center, slope=oo)) if p.y == self.center.y: rv.append(Line(self.center, slope=0)) if rv: # at these special orientations of p either 1 or 2 normals # exist and we are done return rv # find the 4 normal points and construct lines through them with # the corresponding slope x, y = Dummy('x', real=True), Dummy('y', real=True) eq = self.equation(x, y) dydx = idiff(eq, y, x) norm = -1/dydx slope = Line(p, (x, y)).slope seq = slope - norm # TODO: Replace solve with solveset, when this line is tested yis = solve(seq, y)[0] xeq = eq.subs(y, yis).as_numer_denom()[0].expand() if len(xeq.free_symbols) == 1: try: # this is so much faster, it's worth a try xsol = Poly(xeq, x).real_roots() except (DomainError, PolynomialError, NotImplementedError): # TODO: Replace solve with solveset, when these lines are tested xsol = _nsort(solve(xeq, x), separated=True)[0] points = [Point(i, solve(eq.subs(x, i), y)[0]) for i in xsol] else: raise NotImplementedError( 'intersections for the general ellipse are not supported') slopes = [norm.subs(zip((x, y), pt.args)) for pt in points] if prec is not None: points = [pt.n(prec) for pt in points] slopes = [i if _not_a_coeff(i) else i.n(prec) for i in slopes] return [Line(pt, slope=s) for pt, s in zip(points, slopes)] @property def periapsis(self): """The periapsis of the ellipse. The shortest distance between the focus and the contour. Returns ======= periapsis : number See Also ======== apoapsis : Returns greatest distance between focus and contour Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.periapsis 3 - 2sqrt(2) """ return self.major * (1 - self.eccentricity) @property def semilatus_rectum(self): """ Calculates the semi-latus rectum of the Ellipse. Semi-latus rectum is defined as one half of the the chord through a focus parallel to the conic section directrix of a conic section. Returns ======= semilatus_rectum : number See Also ======== apoapsis : Returns greatest distance between focus and contour periapsis : The shortest distance between the focus and the contour Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.semilatus_rectum 1/3 References ========== [1] http://mathworld.wolfram.com/SemilatusRectum.html [2] https://en.wikipedia.org/wiki/Ellipse#Semi-latus_rectum """ return self.major * (1 - self.eccentricity 2) def auxiliary_circle(self): """Returns a Circle whose diameter is the major axis of the ellipse. Examples ======== >>> from sympy import Circle, Ellipse, Point, symbols >>> c = Point(1, 2) >>> Ellipse(c, 8, 7).auxiliary_circle() Circle(Point2D(1, 2), 8) >>> a, b = symbols('a b') >>> Ellipse(c, a, b).auxiliary_circle() Circle(Point2D(1, 2), Max(a, b)) """ return Circle(self.center, Max(self.hradius, self.vradius)) def director_circle(self): """ Returns a Circle consisting of all points where two perpendicular tangent lines to the ellipse cross each other. Returns ======= Circle A director circle returned as a geometric object. Examples ======== >>> from sympy import Circle, Ellipse, Point, symbols >>> c = Point(3,8) >>> Ellipse(c, 7, 9).director_circle() Circle(Point2D(3, 8), sqrt(130)) >>> a, b = symbols('a b') >>> Ellipse(c, a, b).director_circle() Circle(Point2D(3, 8), sqrt(a2 + b2)) References ========== .. [1] https://en.wikipedia.org/wiki/Director_circle """ return Circle(self.center, sqrt(self.hradius2 + self.vradius*2)) def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the Ellipse. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.plot_interval() [t, -pi, pi] """ t = _symbol(parameter, real=True) return [t, -S.Pi, S.Pi] def random_point(self, seed=None): """A random point on the ellipse. Returns ======= point : Point Examples ======== >>> from sympy import Point, Ellipse, Segment >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.random_point() # gives some random point Point2D(...) >>> p1 = e1.random_point(seed=0); p1.n(2) Point2D(2.1, 1.4) Notes ===== When creating a random point, one may simply replace the parameter with a random number. When doing so, however, the random number should be made a Rational or else the point may not test as being in the ellipse: >>> from sympy.abc import t >>> from sympy import Rational >>> arb = e1.arbitrary_point(t); arb Point2D(3cos(t), 2sin(t)) >>> arb.subs(t, .1) in e1 False >>> arb.subs(t, Rational(.1)) in e1 True >>> arb.subs(t, Rational('.1')) in e1 True See Also ======== sympy.geometry.point.Point arbitrary_point : Returns parameterized point on ellipse """ from sympy import sin, cos, Rational t = _symbol('t', real=True) x, y = self.arbitrary_point(t).args # get a random value in [-1, 1) corresponding to cos(t) # and confirm that it will test as being in the ellipse if seed is not None: rng = random.Random(seed) else: rng = random # simplify this now or else the Float will turn s into a Float r = Rational(rng.random()) c = 2r - 1 s = sqrt(1 - c*2) return Point(x.subs(cos(t), c), y.subs(sin(t), s)) def reflect(self, line): """Override GeometryEntity.reflect since the radius is not a GeometryEntity. Examples ======== >>> from sympy import Circle, Line >>> Circle((0, 1), 1).reflect(Line((0, 0), (1, 1))) Circle(Point2D(1, 0), -1) >>> from sympy import Ellipse, Line, Point >>> Ellipse(Point(3, 4), 1, 3).reflect(Line(Point(0, -4), Point(5, 0))) Traceback (most recent call last): ... NotImplementedError: General Ellipse is not supported but the equation of the reflected Ellipse is given by the zeros of: f(x, y) = (9x/41 + 40y/41 + 37/41)2 + (40x/123 - 3y/41 - 364/123)2 - 1 Notes ===== Until the general ellipse (with no axis parallel to the x-axis) is supported a NotImplemented error is raised and the equation whose zeros define the rotated ellipse is given. """ if line.slope in (0, oo): c = self.center c = c.reflect(line) return self.func(c, -self.hradius, self.vradius) else: x, y = [_uniquely_named_symbol( name, (self, line), real=True) for name in 'xy'] expr = self.equation(x, y) p = Point(x, y).reflect(line) result = expr.subs(zip((x, y), p.args ), simultaneous=True) raise NotImplementedError(filldedent( 'General Ellipse is not supported but the equation ' 'of the reflected Ellipse is given by the zeros of: ' + "f(%s, %s) = %s" % (str(x), str(y), str(result)))) def rotate(self, angle=0, pt=None): """Rotate ``angle`` radians counterclockwise about Point ``pt``. Note: since the general ellipse is not supported, only rotations that are integer multiples of pi/2 are allowed. Examples ======== >>> from sympy import Ellipse, pi >>> Ellipse((1, 0), 2, 1).rotate(pi/2) Ellipse(Point2D(0, 1), 1, 2) >>> Ellipse((1, 0), 2, 1).rotate(pi) Ellipse(Point2D(-1, 0), 2, 1) """ if self.hradius == self.vradius: return self.func(self.center.rotate(angle, pt), self.hradius) if (angle/S.Pi).is_integer: return super(Ellipse, self).rotate(angle, pt) if (2angle/S.Pi).is_integer: return self.func(self.center.rotate(angle, pt), self.vradius, self.hradius) # XXX see https://github.com/sympy/sympy/issues/2815 for general ellipes raise NotImplementedError('Only rotations of pi/2 are currently supported for Ellipse.') def scale(self, x=1, y=1, pt=None): """Override GeometryEntity.scale since it is the major and minor axes which must be scaled and they are not GeometryEntities. Examples ======== >>> from sympy import Ellipse >>> Ellipse((0, 0), 2, 1).scale(2, 4) Circle(Point2D(0, 0), 4) >>> Ellipse((0, 0), 2, 1).scale(2) Ellipse(Point2D(0, 0), 4, 1) """ c = self.center if pt: pt = Point(pt, dim=2) return self.translate((-pt).args).scale(x, y).translate(pt.args) h = self.hradius v = self.vradius return self.func(c.scale(x, y), hradius=hx, vradius=vy) def tangent_lines(self, p): """Tangent lines between `p` and the ellipse. If `p` is on the ellipse, returns the tangent line through point `p`. Otherwise, returns the tangent line(s) from `p` to the ellipse, or None if no tangent line is possible (e.g., `p` inside ellipse). Parameters ========== p : Point Returns ======= tangent_lines : list with 1 or 2 Lines Raises ====== NotImplementedError Can only find tangent lines for a point, `p`, on the ellipse. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Line Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.tangent_lines(Point(3, 0)) [Line2D(Point2D(3, 0), Point2D(3, -12))] """ p = Point(p, dim=2) if self.encloses_point(p): return [] if p in self: delta = self.center - p rise = (self.vradius*2)delta.x run = -(self.hradius*2)delta.y p2 = Point(simplify(p.x + run), simplify(p.y + rise)) return [Line(p, p2)] else: if len(self.foci) == 2: f1, f2 = self.foci maj = self.hradius test = (2maj - Point.distance(f1, p) - Point.distance(f2, p)) else: test = self.radius - Point.distance(self.center, p) if test.is_number and test.is_positive: return [] # else p is outside the ellipse or we can't tell. In case of the # latter, the solutions returned will only be valid if # the point is not inside the ellipse; if it is, nan will result. x, y = Dummy('x'), Dummy('y') eq = self.equation(x, y) dydx = idiff(eq, y, x) slope = Line(p, Point(x, y)).slope # TODO: Replace solve with solveset, when this line is tested tangent_points = solve([slope - dydx, eq], [x, y]) # handle horizontal and vertical tangent lines if len(tangent_points) == 1: assert tangent_points[0][ 0] == p.x or tangent_points[0][1] == p.y return [Line(p, p + Point(1, 0)), Line(p, p + Point(0, 1))] # others return [Line(p, tangent_points[0]), Line(p, tangent_points[1])] @property def vradius(self): """The vertical radius of the ellipse. Returns ======= vradius : number See Also ======== hradius, major, minor Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.vradius 1 """ return self.args[2] def second_moment_of_area(self, point=None): """Returns the second moment and product moment area of an ellipse. Parameters ========== point : Point, two-tuple of sympifiable objects, or None(default=None) point is the point about which second moment of area is to be found. If "point=None" it will be calculated about the axis passing through the centroid of the ellipse. Returns ======= I_xx, I_yy, I_xy : number or sympy expression I_xx, I_yy are second moment of area of an ellise. I_xy is product moment of area of an ellipse. Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.second_moment_of_area() (3pi/4, 27pi/4, 0) References ========== https://en.wikipedia.org/wiki/List_of_second_moments_of_area """ I_xx = (S.Pi(self.hradius)(self.vradius3))/4 I_yy = (S.Pi(self.hradius*3)(self.vradius))/4 I_xy = 0 if point is None: return I_xx, I_yy, I_xy # parallel axis theorem I_xx = I_xx + self.area((point[1] - self.center.y)2) I_yy = I_yy + self.area((point[0] - self.center.x)*2) I_xy = I_xy + self.area(point[0] - self.center.x)(point[1] - self.center.y) return I_xx, I_yy, I_xy class Circle(Ellipse): """A circle in space. Constructed simply from a center and a radius, from three non-collinear points, or the equation of a circle. Parameters ========== center : Point radius : number or sympy expression points : sequence of three Points equation : equation of a circle Attributes ========== radius (synonymous with hradius, vradius, major and minor) circumference equation Raises ====== GeometryError When the given equation is not that of a circle. When trying to construct circle from incorrect parameters. See Also ======== Ellipse, sympy.geometry.point.Point Examples ======== >>> from sympy import Eq >>> from sympy.geometry import Point, Circle >>> from sympy.abc import x, y, a, b A circle constructed from a center and radius: >>> c1 = Circle(Point(0, 0), 5) >>> c1.hradius, c1.vradius, c1.radius (5, 5, 5) A circle constructed from three points: >>> c2 = Circle(Point(0, 0), Point(1, 1), Point(1, 0)) >>> c2.hradius, c2.vradius, c2.radius, c2.center (sqrt(2)/2, sqrt(2)/2, sqrt(2)/2, Point2D(1/2, 1/2)) A circle can be constructed from an equation in the form `ax2 + by2 + gx + hy + c = 0`, too: >>> Circle(x2 + y2 - 25) Circle(Point2D(0, 0), 5) If the variables corresponding to x and y are named something else, their name or symbol can be supplied: >>> Circle(Eq(a2 + b2, 25), x='a', y=b) Circle(Point2D(0, 0), 5) """ def __new__(cls, args, kwargs): from sympy.geometry.util import find from .polygon import Triangle evaluate = kwargs.get('evaluate', global_evaluate[0]) if len(args) == 1 and isinstance(args[0], Expr): x = kwargs.get('x', 'x') y = kwargs.get('y', 'y') equation = args[0] if isinstance(equation, Eq): equation = equation.lhs - equation.rhs x = find(x, equation) y = find(y, equation) try: a, b, c, d, e = linear_coeffs(equation, x2, y2, x, y) except ValueError: raise GeometryError("The given equation is not that of a circle.") if a == 0 or b == 0 or a != b: raise GeometryError("The given equation is not that of a circle.") center_x = -c/a/2 center_y = -d/b/2 r2 = (center_x2) + (center_y2) - e return Circle((center_x, center_y), sqrt(r2), evaluate=evaluate) else: c, r = None, None if len(args) == 3: args = [Point(a, dim=2, evaluate=evaluate) for a in args] t = Triangle(args) if not isinstance(t, Triangle): return t c = t.circumcenter r = t.circumradius elif len(args) == 2: # Assume (center, radius) pair c = Point(args[0], dim=2, evaluate=evaluate) r = args[1] # this will prohibit imaginary radius try: r = Point(r, 0, evaluate=evaluate).x except: raise GeometryError("Circle with imaginary radius is not permitted") if not (c is None or r is None): if r == 0: return c return GeometryEntity.__new__(cls, c, r, *kwargs) raise GeometryError("Circle.__new__ received unknown arguments") @property def circumference(self): """The circumference of the circle. Returns ======= circumference : number or SymPy expression Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(3, 4), 6) >>> c1.circumference 12pi """ return 2 * S.Pi * self.radius def equation(self, x='x', y='y'): """The equation of the circle. Parameters ========== x : str or Symbol, optional Default value is 'x'. y : str or Symbol, optional Default value is 'y'. Returns ======= equation : SymPy expression Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(0, 0), 5) >>> c1.equation() x2 + y2 - 25 """ x = _symbol(x, real=True) y = _symbol(y, real=True) t1 = (x - self.center.x)2 t2 = (y - self.center.y)2 return t1 + t2 - self.major*2 def intersection(self, o): """The intersection of this circle with another geometrical entity. Parameters ========== o : GeometryEntity Returns ======= intersection : list of GeometryEntities Examples ======== >>> from sympy import Point, Circle, Line, Ray >>> p1, p2, p3 = Point(0, 0), Point(5, 5), Point(6, 0) >>> p4 = Point(5, 0) >>> c1 = Circle(p1, 5) >>> c1.intersection(p2) [] >>> c1.intersection(p4) [Point2D(5, 0)] >>> c1.intersection(Ray(p1, p2)) [Point2D(5sqrt(2)/2, 5sqrt(2)/2)] >>> c1.intersection(Line(p2, p3)) [] """ return Ellipse.intersection(self, o) @property def radius(self): """The radius of the circle. Returns ======= radius : number or sympy expression See Also ======== Ellipse.major, Ellipse.minor, Ellipse.hradius, Ellipse.vradius Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(3, 4), 6) >>> c1.radius 6 """ return self.args[1] def reflect(self, line): """Override GeometryEntity.reflect since the radius is not a GeometryEntity. Examples ======== >>> from sympy import Circle, Line >>> Circle((0, 1), 1).reflect(Line((0, 0), (1, 1))) Circle(Point2D(1, 0), -1) """ c = self.center c = c.reflect(line) return self.func(c, -self.radius) def scale(self, x=1, y=1, pt=None): """Override GeometryEntity.scale since the radius is not a GeometryEntity. Examples ======== >>> from sympy import Circle >>> Circle((0, 0), 1).scale(2, 2) Circle(Point2D(0, 0), 2) >>> Circle((0, 0), 1).scale(2, 4) Ellipse(Point2D(0, 0), 2, 4) """ c = self.center if pt: pt = Point(pt, dim=2) return self.translate((-pt).args).scale(x, y).translate(pt.args) c = c.scale(x, y) x, y = [abs(i) for i in (x, y)] if x == y: return self.func(c, xself.radius) h = v = self.radius return Ellipse(c, hradius=hx, vradius=vy) @property def vradius(self): """ This Ellipse property is an alias for the Circle's radius. Whereas hradius, major and minor can use Ellipse's conventions, the vradius does not exist for a circle. It is always a positive value in order that the Circle, like Polygons, will have an area that can be positive or negative as determined by the sign of the hradius. Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(3, 4), 6) >>> c1.vradius 6 """ return abs(self.radius) from .polygon import Polygon
dd799b8566be2c566de8940bdca1e0ad61f4d1fcc05df07c4e91baaacbc4d94c	"""Line-like geometrical entities. Contains ======== LinearEntity Line Ray Segment LinearEntity2D Line2D Ray2D Segment2D LinearEntity3D Line3D Ray3D Segment3D """ from __future__ import division, print_function from sympy import Expr from sympy.core import S, sympify from sympy.core.compatibility import ordered from sympy.core.numbers import Rational, oo from sympy.core.relational import Eq from sympy.core.symbol import _symbol, Dummy from sympy.functions.elementary.trigonometric import (_pi_coeff as pi_coeff, acos, tan, atan2) from sympy.functions.elementary.piecewise import Piecewise from sympy.logic.boolalg import And from sympy.simplify.simplify import simplify from sympy.geometry.exceptions import GeometryError from sympy.core.containers import Tuple from sympy.core.decorators import deprecated from sympy.sets import Intersection from sympy.matrices import Matrix from sympy.solvers.solveset import linear_coeffs from .entity import GeometryEntity, GeometrySet from .point import Point, Point3D from sympy.utilities.misc import Undecidable, filldedent from sympy.utilities.exceptions import SymPyDeprecationWarning class LinearEntity(GeometrySet): """A base class for all linear entities (Line, Ray and Segment) in n-dimensional Euclidean space. Attributes ========== ambient_dimension direction length p1 p2 points Notes ===== This is an abstract class and is not meant to be instantiated. See Also ======== sympy.geometry.entity.GeometryEntity """ def __new__(cls, p1, p2=None, kwargs): p1, p2 = Point._normalize_dimension(p1, p2) if p1 == p2: # sometimes we return a single point if we are not given two unique # points. This is done in the specific subclass raise ValueError( "%s.__new__ requires two unique Points." % cls.__name__) if len(p1) != len(p2): raise ValueError( "%s.__new__ requires two Points of equal dimension." % cls.__name__) return GeometryEntity.__new__(cls, p1, p2, kwargs) def __contains__(self, other): """Return a definitive answer or else raise an error if it cannot be determined that other is on the boundaries of self.""" result = self.contains(other) if result is not None: return result else: raise Undecidable( "can't decide whether '%s' contains '%s'" % (self, other)) def _span_test(self, other): """Test whether the point `other` lies in the positive span of `self`. A point x is 'in front' of a point y if x.dot(y) >= 0. Return -1 if `other` is behind `self.p1`, 0 if `other` is `self.p1` and and 1 if `other` is in front of `self.p1`.""" if self.p1 == other: return 0 rel_pos = other - self.p1 d = self.direction if d.dot(rel_pos) > 0: return 1 return -1 @property def ambient_dimension(self): """A property method that returns the dimension of LinearEntity object. Parameters ========== p1 : LinearEntity Returns ======= dimension : integer Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(1, 1) >>> l1 = Line(p1, p2) >>> l1.ambient_dimension 2 >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0, 0), Point(1, 1, 1) >>> l1 = Line(p1, p2) >>> l1.ambient_dimension 3 """ return len(self.p1) def angle_between(l1, l2): """Return the non-reflex angle formed by rays emanating from the origin with directions the same as the direction vectors of the linear entities. Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= angle : angle in radians Notes ===== From the dot product of vectors v1 and v2 it is known that: ``dot(v1, v2) = \|v1\|\|v2\|cos(A)`` where A is the angle formed between the two vectors. We can get the directional vectors of the two lines and readily find the angle between the two using the above formula. See Also ======== is_perpendicular, Ray2D.closing_angle Examples ======== >>> from sympy import Point, Line, pi >>> e = Line((0, 0), (1, 0)) >>> ne = Line((0, 0), (1, 1)) >>> sw = Line((1, 1), (0, 0)) >>> ne.angle_between(e) pi/4 >>> sw.angle_between(e) 3pi/4 To obtain the non-obtuse angle at the intersection of lines, use the ``smallest_angle_between`` method: >>> sw.smallest_angle_between(e) pi/4 >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(-1, 2, 0) >>> l1, l2 = Line3D(p1, p2), Line3D(p2, p3) >>> l1.angle_between(l2) acos(-sqrt(2)/3) >>> l1.smallest_angle_between(l2) acos(sqrt(2)/3) """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') v1, v2 = l1.direction, l2.direction return acos(v1.dot(v2)/(abs(v1)abs(v2))) def smallest_angle_between(l1, l2): """Return the smallest angle formed at the intersection of the lines containing the linear entities. Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= angle : angle in radians See Also ======== angle_between, is_perpendicular, Ray2D.closing_angle Examples ======== >>> from sympy import Point, Line, pi >>> p1, p2, p3 = Point(0, 0), Point(0, 4), Point(2, -2) >>> l1, l2 = Line(p1, p2), Line(p1, p3) >>> l1.smallest_angle_between(l2) pi/4 See Also ======== angle_between, Ray2D.closing_angle """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') v1, v2 = l1.direction, l2.direction return acos(abs(v1.dot(v2))/(abs(v1)abs(v2))) def arbitrary_point(self, parameter='t'): """A parameterized point on the Line. Parameters ========== parameter : str, optional The name of the parameter which will be used for the parametric point. The default value is 't'. When this parameter is 0, the first point used to define the line will be returned, and when it is 1 the second point will be returned. Returns ======= point : Point Raises ====== ValueError When ``parameter`` already appears in the Line's definition. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(1, 0), Point(5, 3) >>> l1 = Line(p1, p2) >>> l1.arbitrary_point() Point2D(4t + 1, 3t) >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(1, 0, 0), Point3D(5, 3, 1) >>> l1 = Line3D(p1, p2) >>> l1.arbitrary_point() Point3D(4t + 1, 3t, t) """ t = _symbol(parameter, real=True) if t.name in (f.name for f in self.free_symbols): raise ValueError(filldedent(''' Symbol %s already appears in object and cannot be used as a parameter. ''' % t.name)) # multiply on the right so the variable gets # combined with the coordinates of the point return self.p1 + (self.p2 - self.p1)t @staticmethod def are_concurrent(lines): """Is a sequence of linear entities concurrent? Two or more linear entities are concurrent if they all intersect at a single point. Parameters ========== lines : a sequence of linear entities. Returns ======= True : if the set of linear entities intersect in one point False : otherwise. See Also ======== sympy.geometry.util.intersection Examples ======== >>> from sympy import Point, Line, Line3D >>> p1, p2 = Point(0, 0), Point(3, 5) >>> p3, p4 = Point(-2, -2), Point(0, 2) >>> l1, l2, l3 = Line(p1, p2), Line(p1, p3), Line(p1, p4) >>> Line.are_concurrent(l1, l2, l3) True >>> l4 = Line(p2, p3) >>> Line.are_concurrent(l2, l3, l4) False >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(3, 5, 2) >>> p3, p4 = Point3D(-2, -2, -2), Point3D(0, 2, 1) >>> l1, l2, l3 = Line3D(p1, p2), Line3D(p1, p3), Line3D(p1, p4) >>> Line3D.are_concurrent(l1, l2, l3) True >>> l4 = Line3D(p2, p3) >>> Line3D.are_concurrent(l2, l3, l4) False """ common_points = Intersection(lines) if common_points.is_FiniteSet and len(common_points) == 1: return True return False def contains(self, other): """Subclasses should implement this method and should return True if other is on the boundaries of self; False if not on the boundaries of self; None if a determination cannot be made.""" raise NotImplementedError() @property def direction(self): """The direction vector of the LinearEntity. Returns ======= p : a Point; the ray from the origin to this point is the direction of `self` Examples ======== >>> from sympy.geometry import Line >>> a, b = (1, 1), (1, 3) >>> Line(a, b).direction Point2D(0, 2) >>> Line(b, a).direction Point2D(0, -2) This can be reported so the distance from the origin is 1: >>> Line(b, a).direction.unit Point2D(0, -1) See Also ======== sympy.geometry.point.Point.unit """ return self.p2 - self.p1 def intersection(self, other): """The intersection with another geometrical entity. Parameters ========== o : Point or LinearEntity Returns ======= intersection : list of geometrical entities See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line, Segment >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(7, 7) >>> l1 = Line(p1, p2) >>> l1.intersection(p3) [Point2D(7, 7)] >>> p4, p5 = Point(5, 0), Point(0, 3) >>> l2 = Line(p4, p5) >>> l1.intersection(l2) [Point2D(15/8, 15/8)] >>> p6, p7 = Point(0, 5), Point(2, 6) >>> s1 = Segment(p6, p7) >>> l1.intersection(s1) [] >>> from sympy import Point3D, Line3D, Segment3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(7, 7, 7) >>> l1 = Line3D(p1, p2) >>> l1.intersection(p3) [Point3D(7, 7, 7)] >>> l1 = Line3D(Point3D(4,19,12), Point3D(5,25,17)) >>> l2 = Line3D(Point3D(-3, -15, -19), direction_ratio=[2,8,8]) >>> l1.intersection(l2) [Point3D(1, 1, -3)] >>> p6, p7 = Point3D(0, 5, 2), Point3D(2, 6, 3) >>> s1 = Segment3D(p6, p7) >>> l1.intersection(s1) [] """ def intersect_parallel_rays(ray1, ray2): if ray1.direction.dot(ray2.direction) > 0: # rays point in the same direction # so return the one that is "in front" return [ray2] if ray1._span_test(ray2.p1) >= 0 else [ray1] else: # rays point in opposite directions st = ray1._span_test(ray2.p1) if st < 0: return [] elif st == 0: return [ray2.p1] return [Segment(ray1.p1, ray2.p1)] def intersect_parallel_ray_and_segment(ray, seg): st1, st2 = ray._span_test(seg.p1), ray._span_test(seg.p2) if st1 < 0 and st2 < 0: return [] elif st1 >= 0 and st2 >= 0: return [seg] elif st1 >= 0: # st2 < 0: return [Segment(ray.p1, seg.p1)] elif st2 > 0: # st1 <= 0 return [Segment(ray.p1, seg.p2)] def intersect_parallel_segments(seg1, seg2): if seg1.contains(seg2): return [seg2] if seg2.contains(seg1): return [seg1] # direct the segments so they're oriented the same way if seg1.direction.dot(seg2.direction) < 0: seg2 = Segment(seg2.p2, seg2.p1) # order the segments so seg1 is "behind" seg2 if seg1._span_test(seg2.p1) < 0: seg1, seg2 = seg2, seg1 if seg2._span_test(seg1.p2) < 0: return [] return [Segment(seg2.p1, seg1.p2)] if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if other.is_Point: if self.contains(other): return [other] else: return [] elif isinstance(other, LinearEntity): # break into cases based on whether # the lines are parallel, non-parallel intersecting, or skew pts = Point._normalize_dimension(self.p1, self.p2, other.p1, other.p2) rank = Point.affine_rank(pts) if rank == 1: # we're collinear if isinstance(self, Line): return [other] if isinstance(other, Line): return [self] if isinstance(self, Ray) and isinstance(other, Ray): return intersect_parallel_rays(self, other) if isinstance(self, Ray) and isinstance(other, Segment): return intersect_parallel_ray_and_segment(self, other) if isinstance(self, Segment) and isinstance(other, Ray): return intersect_parallel_ray_and_segment(other, self) if isinstance(self, Segment) and isinstance(other, Segment): return intersect_parallel_segments(self, other) elif rank == 2: # we're in the same plane l1 = Line(pts[:2]) l2 = Line(pts[2:]) # check to see if we're parallel. If we are, we can't # be intersecting, since the collinear case was already # handled if l1.direction.is_scalar_multiple(l2.direction): return [] # find the intersection as if everything were lines # by solving the equation td + p1 == sd' + p1' m = Matrix([l1.direction, -l2.direction]).transpose() v = Matrix([l2.p1 - l1.p1]).transpose() # we cannot use m.solve(v) because that only works for square matrices m_rref, pivots = m.col_insert(2, v).rref(simplify=True) # rank == 2 ensures we have 2 pivots, but let's check anyway if len(pivots) != 2: raise GeometryError("Failed when solving Mx=b when M={} and b={}".format(m, v)) coeff = m_rref[0, 2] line_intersection = l1.directioncoeff + self.p1 # if we're both lines, we can skip a containment check if isinstance(self, Line) and isinstance(other, Line): return [line_intersection] if ((isinstance(self, Line) or self.contains(line_intersection)) and other.contains(line_intersection)): return [line_intersection] return [] else: # we're skew return [] return other.intersection(self) def is_parallel(l1, l2): """Are two linear entities parallel? Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= True : if l1 and l2 are parallel, False : otherwise. See Also ======== coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(1, 1) >>> p3, p4 = Point(3, 4), Point(6, 7) >>> l1, l2 = Line(p1, p2), Line(p3, p4) >>> Line.is_parallel(l1, l2) True >>> p5 = Point(6, 6) >>> l3 = Line(p3, p5) >>> Line.is_parallel(l1, l3) False >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(3, 4, 5) >>> p3, p4 = Point3D(2, 1, 1), Point3D(8, 9, 11) >>> l1, l2 = Line3D(p1, p2), Line3D(p3, p4) >>> Line3D.is_parallel(l1, l2) True >>> p5 = Point3D(6, 6, 6) >>> l3 = Line3D(p3, p5) >>> Line3D.is_parallel(l1, l3) False """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') return l1.direction.is_scalar_multiple(l2.direction) def is_perpendicular(l1, l2): """Are two linear entities perpendicular? Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= True : if l1 and l2 are perpendicular, False : otherwise. See Also ======== coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(-1, 1) >>> l1, l2 = Line(p1, p2), Line(p1, p3) >>> l1.is_perpendicular(l2) True >>> p4 = Point(5, 3) >>> l3 = Line(p1, p4) >>> l1.is_perpendicular(l3) False >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(-1, 2, 0) >>> l1, l2 = Line3D(p1, p2), Line3D(p2, p3) >>> l1.is_perpendicular(l2) False >>> p4 = Point3D(5, 3, 7) >>> l3 = Line3D(p1, p4) >>> l1.is_perpendicular(l3) False """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') return S.Zero.equals(l1.direction.dot(l2.direction)) def is_similar(self, other): """ Return True if self and other are contained in the same line. Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 1), Point(3, 4), Point(2, 3) >>> l1 = Line(p1, p2) >>> l2 = Line(p1, p3) >>> l1.is_similar(l2) True """ l = Line(self.p1, self.p2) return l.contains(other) @property def length(self): """ The length of the line. Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(3, 5) >>> l1 = Line(p1, p2) >>> l1.length oo """ return S.Infinity @property def p1(self): """The first defining point of a linear entity. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l = Line(p1, p2) >>> l.p1 Point2D(0, 0) """ return self.args[0] @property def p2(self): """The second defining point of a linear entity. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l = Line(p1, p2) >>> l.p2 Point2D(5, 3) """ return self.args[1] def parallel_line(self, p): """Create a new Line parallel to this linear entity which passes through the point `p`. Parameters ========== p : Point Returns ======= line : Line See Also ======== is_parallel Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(2, 3), Point(-2, 2) >>> l1 = Line(p1, p2) >>> l2 = l1.parallel_line(p3) >>> p3 in l2 True >>> l1.is_parallel(l2) True >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(2, 3, 4), Point3D(-2, 2, 0) >>> l1 = Line3D(p1, p2) >>> l2 = l1.parallel_line(p3) >>> p3 in l2 True >>> l1.is_parallel(l2) True """ p = Point(p, dim=self.ambient_dimension) return Line(p, p + self.direction) def perpendicular_line(self, p): """Create a new Line perpendicular to this linear entity which passes through the point `p`. Parameters ========== p : Point Returns ======= line : Line See Also ======== is_perpendicular, perpendicular_segment Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(2, 3), Point(-2, 2) >>> l1 = Line(p1, p2) >>> l2 = l1.perpendicular_line(p3) >>> p3 in l2 True >>> l1.is_perpendicular(l2) True >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(2, 3, 4), Point3D(-2, 2, 0) >>> l1 = Line3D(p1, p2) >>> l2 = l1.perpendicular_line(p3) >>> p3 in l2 True >>> l1.is_perpendicular(l2) True """ p = Point(p, dim=self.ambient_dimension) if p in self: p = p + self.direction.orthogonal_direction return Line(p, self.projection(p)) def perpendicular_segment(self, p): """Create a perpendicular line segment from `p` to this line. The enpoints of the segment are ``p`` and the closest point in the line containing self. (If self is not a line, the point might not be in self.) Parameters ========== p : Point Returns ======= segment : Segment Notes ===== Returns `p` itself if `p` is on this linear entity. See Also ======== perpendicular_line Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(0, 2) >>> l1 = Line(p1, p2) >>> s1 = l1.perpendicular_segment(p3) >>> l1.is_perpendicular(s1) True >>> p3 in s1 True >>> l1.perpendicular_segment(Point(4, 0)) Segment2D(Point2D(4, 0), Point2D(2, 2)) >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(0, 2, 0) >>> l1 = Line3D(p1, p2) >>> s1 = l1.perpendicular_segment(p3) >>> l1.is_perpendicular(s1) True >>> p3 in s1 True >>> l1.perpendicular_segment(Point3D(4, 0, 0)) Segment3D(Point3D(4, 0, 0), Point3D(4/3, 4/3, 4/3)) """ p = Point(p, dim=self.ambient_dimension) if p in self: return p l = self.perpendicular_line(p) # The intersection should be unique, so unpack the singleton p2, = Intersection(Line(self.p1, self.p2), l) return Segment(p, p2) @property def points(self): """The two points used to define this linear entity. Returns ======= points : tuple of Points See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 11) >>> l1 = Line(p1, p2) >>> l1.points (Point2D(0, 0), Point2D(5, 11)) """ return (self.p1, self.p2) def projection(self, other): """Project a point, line, ray, or segment onto this linear entity. Parameters ========== other : Point or LinearEntity (Line, Ray, Segment) Returns ======= projection : Point or LinearEntity (Line, Ray, Segment) The return type matches the type of the parameter ``other``. Raises ====== GeometryError When method is unable to perform projection. Notes ===== A projection involves taking the two points that define the linear entity and projecting those points onto a Line and then reforming the linear entity using these projections. A point P is projected onto a line L by finding the point on L that is closest to P. This point is the intersection of L and the line perpendicular to L that passes through P. See Also ======== sympy.geometry.point.Point, perpendicular_line Examples ======== >>> from sympy import Point, Line, Segment, Rational >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(Rational(1, 2), 0) >>> l1 = Line(p1, p2) >>> l1.projection(p3) Point2D(1/4, 1/4) >>> p4, p5 = Point(10, 0), Point(12, 1) >>> s1 = Segment(p4, p5) >>> l1.projection(s1) Segment2D(Point2D(5, 5), Point2D(13/2, 13/2)) >>> p1, p2, p3 = Point(0, 0, 1), Point(1, 1, 2), Point(2, 0, 1) >>> l1 = Line(p1, p2) >>> l1.projection(p3) Point3D(2/3, 2/3, 5/3) >>> p4, p5 = Point(10, 0, 1), Point(12, 1, 3) >>> s1 = Segment(p4, p5) >>> l1.projection(s1) Segment3D(Point3D(10/3, 10/3, 13/3), Point3D(5, 5, 6)) """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) def proj_point(p): return Point.project(p - self.p1, self.direction) + self.p1 if isinstance(other, Point): return proj_point(other) elif isinstance(other, LinearEntity): p1, p2 = proj_point(other.p1), proj_point(other.p2) # test to see if we're degenerate if p1 == p2: return p1 projected = other.__class__(p1, p2) projected = Intersection(self, projected) # if we happen to have intersected in only a point, return that if projected.is_FiniteSet and len(projected) == 1: # projected is a set of size 1, so unpack it in `a` a, = projected return a # order args so projection is in the same direction as self if self.direction.dot(projected.direction) < 0: p1, p2 = projected.args projected = projected.func(p2, p1) return projected raise GeometryError( "Do not know how to project %s onto %s" % (other, self)) def random_point(self, seed=None): """A random point on a LinearEntity. Returns ======= point : Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line, Ray, Segment >>> p1, p2 = Point(0, 0), Point(5, 3) >>> line = Line(p1, p2) >>> r = line.random_point(seed=42) # seed value is optional >>> r.n(3) Point2D(-0.72, -0.432) >>> r in line True >>> Ray(p1, p2).random_point(seed=42).n(3) Point2D(0.72, 0.432) >>> Segment(p1, p2).random_point(seed=42).n(3) Point2D(3.2, 1.92) """ import random if seed is not None: rng = random.Random(seed) else: rng = random t = Dummy() pt = self.arbitrary_point(t) if isinstance(self, Ray): v = abs(rng.gauss(0, 1)) elif isinstance(self, Segment): v = rng.random() elif isinstance(self, Line): v = rng.gauss(0, 1) else: raise NotImplementedError('unhandled line type') return pt.subs(t, Rational(v)) class Line(LinearEntity): """An infinite line in space. A 2D line is declared with two distinct points, point and slope, or an equation. A 3D line may be defined with a point and a direction ratio. Parameters ========== p1 : Point p2 : Point slope : sympy expression direction_ratio : list equation : equation of a line Notes ===== `Line` will automatically subclass to `Line2D` or `Line3D` based on the dimension of `p1`. The `slope` argument is only relevant for `Line2D` and the `direction_ratio` argument is only relevant for `Line3D`. See Also ======== sympy.geometry.point.Point sympy.geometry.line.Line2D sympy.geometry.line.Line3D Examples ======== >>> from sympy import Point, Eq >>> from sympy.geometry import Line, Segment >>> from sympy.abc import x, y, a, b >>> L = Line(Point(2,3), Point(3,5)) >>> L Line2D(Point2D(2, 3), Point2D(3, 5)) >>> L.points (Point2D(2, 3), Point2D(3, 5)) >>> L.equation() -2x + y + 1 >>> L.coefficients (-2, 1, 1) Instantiate with keyword ``slope``: >>> Line(Point(0, 0), slope=0) Line2D(Point2D(0, 0), Point2D(1, 0)) Instantiate with another linear object >>> s = Segment((0, 0), (0, 1)) >>> Line(s).equation() x The line corresponding to an equation in the for `ax + by + c = 0`, can be entered: >>> Line(3x + y + 18) Line2D(Point2D(0, -18), Point2D(1, -21)) If `x` or `y` has a different name, then they can be specified, too, as a string (to match the name) or symbol: >>> Line(Eq(3a + b, -18), x='a', y=b) Line2D(Point2D(0, -18), Point2D(1, -21)) """ def __new__(cls, args, kwargs): from sympy.geometry.util import find if len(args) == 1 and isinstance(args[0], Expr): x = kwargs.get('x', 'x') y = kwargs.get('y', 'y') equation = args[0] if isinstance(equation, Eq): equation = equation.lhs - equation.rhs xin, yin = x, y x = find(x, equation) or Dummy() y = find(y, equation) or Dummy() a, b, c = linear_coeffs(equation, x, y) if b: return Line((0, -c/b), slope=-a/b) if a: return Line((-c/a, 0), slope=oo) raise ValueError('neither %s nor %s were found in the equation' % (xin, yin)) else: if len(args) > 0: p1 = args[0] if len(args) > 1: p2 = args[1] else: p2=None if isinstance(p1, LinearEntity): if p2: raise ValueError('If p1 is a LinearEntity, p2 must be None.') dim = len(p1.p1) else: p1 = Point(p1) dim = len(p1) if p2 is not None or isinstance(p2, Point) and p2.ambient_dimension != dim: p2 = Point(p2) if dim == 2: return Line2D(p1, p2, kwargs) elif dim == 3: return Line3D(p1, p2, kwargs) return LinearEntity.__new__(cls, p1, p2, kwargs) def contains(self, other): """ Return True if `other` is on this Line, or False otherwise. Examples ======== >>> from sympy import Line,Point >>> p1, p2 = Point(0, 1), Point(3, 4) >>> l = Line(p1, p2) >>> l.contains(p1) True >>> l.contains((0, 1)) True >>> l.contains((0, 0)) False >>> a = (0, 0, 0) >>> b = (1, 1, 1) >>> c = (2, 2, 2) >>> l1 = Line(a, b) >>> l2 = Line(b, a) >>> l1 == l2 False >>> l1 in l2 True """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): return Point.is_collinear(other, self.p1, self.p2) if isinstance(other, LinearEntity): return Point.is_collinear(self.p1, self.p2, other.p1, other.p2) return False def distance(self, other): """ Finds the shortest distance between a line and a point. Raises ====== NotImplementedError is raised if `other` is not a Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(1, 1) >>> s = Line(p1, p2) >>> s.distance(Point(-1, 1)) sqrt(2) >>> s.distance((-1, 2)) 3sqrt(2)/2 >>> p1, p2 = Point(0, 0, 0), Point(1, 1, 1) >>> s = Line(p1, p2) >>> s.distance(Point(-1, 1, 1)) 2sqrt(6)/3 >>> s.distance((-1, 1, 1)) 2sqrt(6)/3 """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if self.contains(other): return S.Zero return self.perpendicular_segment(other).length @deprecated(useinstead="equals", issue=12860, deprecated_since_version="1.0") def equal(self, other): return self.equals(other) def equals(self, other): """Returns True if self and other are the same mathematical entities""" if not isinstance(other, Line): return False return Point.is_collinear(self.p1, other.p1, self.p2, other.p2) def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of line. Gives values that will produce a line that is +/- 5 units long (where a unit is the distance between the two points that define the line). Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list (plot interval) [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l1 = Line(p1, p2) >>> l1.plot_interval() [t, -5, 5] """ t = _symbol(parameter, real=True) return [t, -5, 5] class Ray(LinearEntity): """A Ray is a semi-line in the space with a source point and a direction. Parameters ========== p1 : Point The source of the Ray p2 : Point or radian value This point determines the direction in which the Ray propagates. If given as an angle it is interpreted in radians with the positive direction being ccw. Attributes ========== source See Also ======== sympy.geometry.line.Ray2D sympy.geometry.line.Ray3D sympy.geometry.point.Point sympy.geometry.line.Line Notes ===== `Ray` will automatically subclass to `Ray2D` or `Ray3D` based on the dimension of `p1`. Examples ======== >>> from sympy import Point, pi >>> from sympy.geometry import Ray >>> r = Ray(Point(2, 3), Point(3, 5)) >>> r Ray2D(Point2D(2, 3), Point2D(3, 5)) >>> r.points (Point2D(2, 3), Point2D(3, 5)) >>> r.source Point2D(2, 3) >>> r.xdirection oo >>> r.ydirection oo >>> r.slope 2 >>> Ray(Point(0, 0), angle=pi/4).slope 1 """ def __new__(cls, p1, p2=None, kwargs): p1 = Point(p1) if p2 is not None: p1, p2 = Point._normalize_dimension(p1, Point(p2)) dim = len(p1) if dim == 2: return Ray2D(p1, p2, kwargs) elif dim == 3: return Ray3D(p1, p2, kwargs) return LinearEntity.__new__(cls, p1, pts, *kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the LinearEntity. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = (N(self.p1), N(self.p2)) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1}".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" ' 'marker-start="url(#markerCircle)" marker-end="url(#markerArrow)"/>' ).format(2. scale_factor, path, fill_color) def contains(self, other): """ Is other GeometryEntity contained in this Ray? Examples ======== >>> from sympy import Ray,Point,Segment >>> p1, p2 = Point(0, 0), Point(4, 4) >>> r = Ray(p1, p2) >>> r.contains(p1) True >>> r.contains((1, 1)) True >>> r.contains((1, 3)) False >>> s = Segment((1, 1), (2, 2)) >>> r.contains(s) True >>> s = Segment((1, 2), (2, 5)) >>> r.contains(s) False >>> r1 = Ray((2, 2), (3, 3)) >>> r.contains(r1) True >>> r1 = Ray((2, 2), (3, 5)) >>> r.contains(r1) False """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): if Point.is_collinear(self.p1, self.p2, other): # if we're in the direction of the ray, our # direction vector dot the ray's direction vector # should be non-negative return bool((self.p2 - self.p1).dot(other - self.p1) >= S.Zero) return False elif isinstance(other, Ray): if Point.is_collinear(self.p1, self.p2, other.p1, other.p2): return bool((self.p2 - self.p1).dot(other.p2 - other.p1) > S.Zero) return False elif isinstance(other, Segment): return other.p1 in self and other.p2 in self # No other known entity can be contained in a Ray return False def distance(self, other): """ Finds the shortest distance between the ray and a point. Raises ====== NotImplementedError is raised if `other` is not a Point Examples ======== >>> from sympy import Point, Ray >>> p1, p2 = Point(0, 0), Point(1, 1) >>> s = Ray(p1, p2) >>> s.distance(Point(-1, -1)) sqrt(2) >>> s.distance((-1, 2)) 3sqrt(2)/2 >>> p1, p2 = Point(0, 0, 0), Point(1, 1, 2) >>> s = Ray(p1, p2) >>> s Ray3D(Point3D(0, 0, 0), Point3D(1, 1, 2)) >>> s.distance(Point(-1, -1, 2)) 4sqrt(3)/3 >>> s.distance((-1, -1, 2)) 4sqrt(3)/3 """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if self.contains(other): return S.Zero proj = Line(self.p1, self.p2).projection(other) if self.contains(proj): return abs(other - proj) else: return abs(other - self.source) def equals(self, other): """Returns True if self and other are the same mathematical entities""" if not isinstance(other, Ray): return False return self.source == other.source and other.p2 in self def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the Ray. Gives values that will produce a ray that is 10 units long (where a unit is the distance between the two points that define the ray). Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Ray, pi >>> r = Ray((0, 0), angle=pi/4) >>> r.plot_interval() [t, 0, 10] """ t = _symbol(parameter, real=True) return [t, 0, 10] @property def source(self): """The point from which the ray emanates. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Ray >>> p1, p2 = Point(0, 0), Point(4, 1) >>> r1 = Ray(p1, p2) >>> r1.source Point2D(0, 0) >>> p1, p2 = Point(0, 0, 0), Point(4, 1, 5) >>> r1 = Ray(p2, p1) >>> r1.source Point3D(4, 1, 5) """ return self.p1 class Segment(LinearEntity): """A line segment in space. Parameters ========== p1 : Point p2 : Point Attributes ========== length : number or sympy expression midpoint : Point See Also ======== sympy.geometry.line.Segment2D sympy.geometry.line.Segment3D sympy.geometry.point.Point sympy.geometry.line.Line Notes ===== If 2D or 3D points are used to define `Segment`, it will be automatically subclassed to `Segment2D` or `Segment3D`. Examples ======== >>> from sympy import Point >>> from sympy.geometry import Segment >>> Segment((1, 0), (1, 1)) # tuples are interpreted as pts Segment2D(Point2D(1, 0), Point2D(1, 1)) >>> s = Segment(Point(4, 3), Point(1, 1)) >>> s.points (Point2D(4, 3), Point2D(1, 1)) >>> s.slope 2/3 >>> s.length sqrt(13) >>> s.midpoint Point2D(5/2, 2) >>> Segment((1, 0, 0), (1, 1, 1)) # tuples are interpreted as pts Segment3D(Point3D(1, 0, 0), Point3D(1, 1, 1)) >>> s = Segment(Point(4, 3, 9), Point(1, 1, 7)); s Segment3D(Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.points (Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.length sqrt(17) >>> s.midpoint Point3D(5/2, 2, 8) """ def __new__(cls, p1, p2, kwargs): p1, p2 = Point._normalize_dimension(Point(p1), Point(p2)) dim = len(p1) if dim == 2: return Segment2D(p1, p2, kwargs) elif dim == 3: return Segment3D(p1, p2, kwargs) return LinearEntity.__new__(cls, p1, p2, kwargs) def contains(self, other): """ Is the other GeometryEntity contained within this Segment? Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 1), Point(3, 4) >>> s = Segment(p1, p2) >>> s2 = Segment(p2, p1) >>> s.contains(s2) True >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 1, 1), Point3D(3, 4, 5) >>> s = Segment3D(p1, p2) >>> s2 = Segment3D(p2, p1) >>> s.contains(s2) True >>> s.contains((p1 + p2) / 2) True """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): if Point.is_collinear(other, self.p1, self.p2): if isinstance(self, Segment2D): # if it is collinear and is in the bounding box of the # segment then it must be on the segment vert = (1/self.slope).equals(0) if vert is False: isin = (self.p1.x - other.x)(self.p2.x - other.x) <= 0 if isin in (True, False): return isin if vert is True: isin = (self.p1.y - other.y)(self.p2.y - other.y) <= 0 if isin in (True, False): return isin # use the triangle inequality d1, d2 = other - self.p1, other - self.p2 d = self.p2 - self.p1 # without the call to simplify, sympy cannot tell that an expression # like (a+b)(a/2+b/2) is always non-negative. If it cannot be # determined, raise an Undecidable error try: # the triangle inequality says that \|d1\|+\|d2\| >= \|d\| and is strict # only if other lies in the line segment return bool(simplify(Eq(abs(d1) + abs(d2) - abs(d), 0))) except TypeError: raise Undecidable("Cannot determine if {} is in {}".format(other, self)) if isinstance(other, Segment): return other.p1 in self and other.p2 in self return False def equals(self, other): """Returns True if self and other are the same mathematical entities""" return isinstance(other, self.func) and list( ordered(self.args)) == list(ordered(other.args)) def distance(self, other): """ Finds the shortest distance between a line segment and a point. Raises ====== NotImplementedError is raised if `other` is not a Point Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 1), Point(3, 4) >>> s = Segment(p1, p2) >>> s.distance(Point(10, 15)) sqrt(170) >>> s.distance((0, 12)) sqrt(73) >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 0, 3), Point3D(1, 1, 4) >>> s = Segment3D(p1, p2) >>> s.distance(Point3D(10, 15, 12)) sqrt(341) >>> s.distance((10, 15, 12)) sqrt(341) """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): vp1 = other - self.p1 vp2 = other - self.p2 dot_prod_sign_1 = self.direction.dot(vp1) >= 0 dot_prod_sign_2 = self.direction.dot(vp2) <= 0 if dot_prod_sign_1 and dot_prod_sign_2: return Line(self.p1, self.p2).distance(other) if dot_prod_sign_1 and not dot_prod_sign_2: return abs(vp2) if not dot_prod_sign_1 and dot_prod_sign_2: return abs(vp1) raise NotImplementedError() @property def length(self): """The length of the line segment. See Also ======== sympy.geometry.point.Point.distance Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 0), Point(4, 3) >>> s1 = Segment(p1, p2) >>> s1.length 5 >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(4, 3, 3) >>> s1 = Segment3D(p1, p2) >>> s1.length sqrt(34) """ return Point.distance(self.p1, self.p2) @property def midpoint(self): """The midpoint of the line segment. See Also ======== sympy.geometry.point.Point.midpoint Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 0), Point(4, 3) >>> s1 = Segment(p1, p2) >>> s1.midpoint Point2D(2, 3/2) >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(4, 3, 3) >>> s1 = Segment3D(p1, p2) >>> s1.midpoint Point3D(2, 3/2, 3/2) """ return Point.midpoint(self.p1, self.p2) def perpendicular_bisector(self, p=None): """The perpendicular bisector of this segment. If no point is specified or the point specified is not on the bisector then the bisector is returned as a Line. Otherwise a Segment is returned that joins the point specified and the intersection of the bisector and the segment. Parameters ========== p : Point Returns ======= bisector : Line or Segment See Also ======== LinearEntity.perpendicular_segment Examples ======== >>> from sympy import Point, Segment >>> p1, p2, p3 = Point(0, 0), Point(6, 6), Point(5, 1) >>> s1 = Segment(p1, p2) >>> s1.perpendicular_bisector() Line2D(Point2D(3, 3), Point2D(-3, 9)) >>> s1.perpendicular_bisector(p3) Segment2D(Point2D(5, 1), Point2D(3, 3)) """ l = self.perpendicular_line(self.midpoint) if p is not None: p2 = Point(p, dim=self.ambient_dimension) if p2 in l: return Segment(p2, self.midpoint) return l def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the Segment gives values that will produce the full segment in a plot. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 0), Point(5, 3) >>> s1 = Segment(p1, p2) >>> s1.plot_interval() [t, 0, 1] """ t = _symbol(parameter, real=True) return [t, 0, 1] class LinearEntity2D(LinearEntity): """A base class for all linear entities (line, ray and segment) in a 2-dimensional Euclidean space. Attributes ========== p1 p2 coefficients slope points Notes ===== This is an abstract class and is not meant to be instantiated. See Also ======== sympy.geometry.entity.GeometryEntity """ @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ verts = self.points xs = [p.x for p in verts] ys = [p.y for p in verts] return (min(xs), min(ys), max(xs), max(ys)) def perpendicular_line(self, p): """Create a new Line perpendicular to this linear entity which passes through the point `p`. Parameters ========== p : Point Returns ======= line : Line See Also ======== is_perpendicular, perpendicular_segment Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(2, 3), Point(-2, 2) >>> l1 = Line(p1, p2) >>> l2 = l1.perpendicular_line(p3) >>> p3 in l2 True >>> l1.is_perpendicular(l2) True """ p = Point(p, dim=self.ambient_dimension) # any two lines in R^2 intersect, so blindly making # a line through p in an orthogonal direction will work return Line(p, p + self.direction.orthogonal_direction) @property def slope(self): """The slope of this linear entity, or infinity if vertical. Returns ======= slope : number or sympy expression See Also ======== coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(3, 5) >>> l1 = Line(p1, p2) >>> l1.slope 5/3 >>> p3 = Point(0, 4) >>> l2 = Line(p1, p3) >>> l2.slope oo """ d1, d2 = (self.p1 - self.p2).args if d1 == 0: return S.Infinity return simplify(d2/d1) class Line2D(LinearEntity2D, Line): """An infinite line in space 2D. A line is declared with two distinct points or a point and slope as defined using keyword `slope`. Parameters ========== p1 : Point pt : Point slope : sympy expression See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point >>> from sympy.abc import L >>> from sympy.geometry import Line, Segment >>> L = Line(Point(2,3), Point(3,5)) >>> L Line2D(Point2D(2, 3), Point2D(3, 5)) >>> L.points (Point2D(2, 3), Point2D(3, 5)) >>> L.equation() -2x + y + 1 >>> L.coefficients (-2, 1, 1) Instantiate with keyword ``slope``: >>> Line(Point(0, 0), slope=0) Line2D(Point2D(0, 0), Point2D(1, 0)) Instantiate with another linear object >>> s = Segment((0, 0), (0, 1)) >>> Line(s).equation() x """ def __new__(cls, p1, pt=None, slope=None, kwargs): if isinstance(p1, LinearEntity): if pt is not None: raise ValueError('When p1 is a LinearEntity, pt should be None') p1, pt = Point._normalize_dimension(p1.args, dim=2) else: p1 = Point(p1, dim=2) if pt is not None and slope is None: try: p2 = Point(pt, dim=2) except (NotImplementedError, TypeError, ValueError): raise ValueError(filldedent(''' The 2nd argument was not a valid Point. If it was a slope, enter it with keyword "slope". ''')) elif slope is not None and pt is None: slope = sympify(slope) if slope.is_finite is False: # when infinite slope, don't change x dx = 0 dy = 1 else: # go over 1 up slope dx = 1 dy = slope # XXX avoiding simplification by adding to coords directly p2 = Point(p1.x + dx, p1.y + dy, evaluate=False) else: raise ValueError('A 2nd Point or keyword "slope" must be used.') return LinearEntity2D.__new__(cls, p1, p2, *kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the LinearEntity. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = (N(self.p1), N(self.p2)) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1}".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" ' 'marker-start="url(#markerReverseArrow)" marker-end="url(#markerArrow)"/>' ).format(2. scale_factor, path, fill_color) @property def coefficients(self): """The coefficients (`a`, `b`, `c`) for `ax + by + c = 0`. See Also ======== sympy.geometry.line.Line.equation Examples ======== >>> from sympy import Point, Line >>> from sympy.abc import x, y >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l = Line(p1, p2) >>> l.coefficients (-3, 5, 0) >>> p3 = Point(x, y) >>> l2 = Line(p1, p3) >>> l2.coefficients (-y, x, 0) """ p1, p2 = self.points if p1.x == p2.x: return (S.One, S.Zero, -p1.x) elif p1.y == p2.y: return (S.Zero, S.One, -p1.y) return tuple([simplify(i) for i in (self.p1.y - self.p2.y, self.p2.x - self.p1.x, self.p1.xself.p2.y - self.p1.yself.p2.x)]) def equation(self, x='x', y='y'): """The equation of the line: ax + by + c. Parameters ========== x : str, optional The name to use for the x-axis, default value is 'x'. y : str, optional The name to use for the y-axis, default value is 'y'. Returns ======= equation : sympy expression See Also ======== LinearEntity.coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(1, 0), Point(5, 3) >>> l1 = Line(p1, p2) >>> l1.equation() -3x + 4y + 3 """ x = _symbol(x, real=True) y = _symbol(y, real=True) p1, p2 = self.points if p1.x == p2.x: return x - p1.x elif p1.y == p2.y: return y - p1.y a, b, c = self.coefficients return ax + by + c class Ray2D(LinearEntity2D, Ray): """ A Ray is a semi-line in the space with a source point and a direction. Parameters ========== p1 : Point The source of the Ray p2 : Point or radian value This point determines the direction in which the Ray propagates. If given as an angle it is interpreted in radians with the positive direction being ccw. Attributes ========== source xdirection ydirection See Also ======== sympy.geometry.point.Point, Line Examples ======== >>> from sympy import Point, pi >>> from sympy.geometry import Ray >>> r = Ray(Point(2, 3), Point(3, 5)) >>> r Ray2D(Point2D(2, 3), Point2D(3, 5)) >>> r.points (Point2D(2, 3), Point2D(3, 5)) >>> r.source Point2D(2, 3) >>> r.xdirection oo >>> r.ydirection oo >>> r.slope 2 >>> Ray(Point(0, 0), angle=pi/4).slope 1 """ def __new__(cls, p1, pt=None, angle=None, *kwargs): p1 = Point(p1, dim=2) if pt is not None and angle is None: try: p2 = Point(pt, dim=2) except (NotImplementedError, TypeError, ValueError): from sympy.utilities.misc import filldedent raise ValueError(filldedent(''' The 2nd argument was not a valid Point; if it was meant to be an angle it should be given with keyword "angle".''')) if p1 == p2: raise ValueError('A Ray requires two distinct points.') elif angle is not None and pt is None: # we need to know if the angle is an odd multiple of pi/2 c = pi_coeff(sympify(angle)) p2 = None if c is not None: if c.is_Rational: if c.q == 2: if c.p == 1: p2 = p1 + Point(0, 1) elif c.p == 3: p2 = p1 + Point(0, -1) elif c.q == 1: if c.p == 0: p2 = p1 + Point(1, 0) elif c.p == 1: p2 = p1 + Point(-1, 0) if p2 is None: c = S.Pi else: c = angle % (2S.Pi) if not p2: m = 2c/S.Pi left = And(1 < m, m < 3) # is it in quadrant 2 or 3? x = Piecewise((-1, left), (Piecewise((0, Eq(m % 1, 0)), (1, True)), True)) y = Piecewise((-tan(c), left), (Piecewise((1, Eq(m, 1)), (-1, Eq(m, 3)), (tan(c), True)), True)) p2 = p1 + Point(x, y) else: raise ValueError('A 2nd point or keyword "angle" must be used.') return LinearEntity2D.__new__(cls, p1, p2, *kwargs) @property def xdirection(self): """The x direction of the ray. Positive infinity if the ray points in the positive x direction, negative infinity if the ray points in the negative x direction, or 0 if the ray is vertical. See Also ======== ydirection Examples ======== >>> from sympy import Point, Ray >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(0, -1) >>> r1, r2 = Ray(p1, p2), Ray(p1, p3) >>> r1.xdirection oo >>> r2.xdirection 0 """ if self.p1.x < self.p2.x: return S.Infinity elif self.p1.x == self.p2.x: return S.Zero else: return S.NegativeInfinity @property def ydirection(self): """The y direction of the ray. Positive infinity if the ray points in the positive y direction, negative infinity if the ray points in the negative y direction, or 0 if the ray is horizontal. See Also ======== xdirection Examples ======== >>> from sympy import Point, Ray >>> p1, p2, p3 = Point(0, 0), Point(-1, -1), Point(-1, 0) >>> r1, r2 = Ray(p1, p2), Ray(p1, p3) >>> r1.ydirection -oo >>> r2.ydirection 0 """ if self.p1.y < self.p2.y: return S.Infinity elif self.p1.y == self.p2.y: return S.Zero else: return S.NegativeInfinity def closing_angle(r1, r2): """Return the angle by which r2 must be rotated so it faces the same direction as r1. Parameters ========== r1 : Ray2D r2 : Ray2D Returns ======= angle : angle in radians (ccw angle is positive) See Also ======== LinearEntity.angle_between Examples ======== >>> from sympy import Ray, pi >>> r1 = Ray((0, 0), (1, 0)) >>> r2 = r1.rotate(-pi/2) >>> angle = r1.closing_angle(r2); angle pi/2 >>> r2.rotate(angle).direction.unit == r1.direction.unit True >>> r2.closing_angle(r1) -pi/2 """ if not all(isinstance(r, Ray2D) for r in (r1, r2)): # although the direction property is defined for # all linear entities, only the Ray is truly a # directed object raise TypeError('Both arguments must be Ray2D objects.') a1 = atan2(list(reversed(r1.direction.args))) a2 = atan2(list(reversed(r2.direction.args))) if a1a2 < 0: a1 = 2S.Pi + a1 if a1 < 0 else a1 a2 = 2S.Pi + a2 if a2 < 0 else a2 return a1 - a2 class Segment2D(LinearEntity2D, Segment): """A line segment in 2D space. Parameters ========== p1 : Point p2 : Point Attributes ========== length : number or sympy expression midpoint : Point See Also ======== sympy.geometry.point.Point, Line Examples ======== >>> from sympy import Point >>> from sympy.geometry import Segment >>> Segment((1, 0), (1, 1)) # tuples are interpreted as pts Segment2D(Point2D(1, 0), Point2D(1, 1)) >>> s = Segment(Point(4, 3), Point(1, 1)); s Segment2D(Point2D(4, 3), Point2D(1, 1)) >>> s.points (Point2D(4, 3), Point2D(1, 1)) >>> s.slope 2/3 >>> s.length sqrt(13) >>> s.midpoint Point2D(5/2, 2) """ def __new__(cls, p1, p2, kwargs): p1 = Point(p1, dim=2) p2 = Point(p2, dim=2) if p1 == p2: return p1 return LinearEntity2D.__new__(cls, p1, p2, kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the LinearEntity. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = (N(self.p1), N(self.p2)) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1}".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" />' ).format(2. * scale_factor, path, fill_color) class LinearEntity3D(LinearEntity): """An base class for all linear entities (line, ray and segment) in a 3-dimensional Euclidean space. Attributes ========== p1 p2 direction_ratio direction_cosine points Notes ===== This is a base class and is not meant to be instantiated. """ def __new__(cls, p1, p2, kwargs): p1 = Point3D(p1, dim=3) p2 = Point3D(p2, dim=3) if p1 == p2: # if it makes sense to return a Point, handle in subclass raise ValueError( "%s.__new__ requires two unique Points." % cls.__name__) return GeometryEntity.__new__(cls, p1, p2, kwargs) ambient_dimension = 3 @property def direction_ratio(self): """The direction ratio of a given line in 3D. See Also ======== sympy.geometry.line.Line.equation Examples ======== >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(5, 3, 1) >>> l = Line3D(p1, p2) >>> l.direction_ratio [5, 3, 1] """ p1, p2 = self.points return p1.direction_ratio(p2) @property def direction_cosine(self): """The normalized direction ratio of a given line in 3D. See Also ======== sympy.geometry.line.Line.equation Examples ======== >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(5, 3, 1) >>> l = Line3D(p1, p2) >>> l.direction_cosine [sqrt(35)/7, 3sqrt(35)/35, sqrt(35)/35] >>> sum(i2 for i in _) 1 """ p1, p2 = self.points return p1.direction_cosine(p2) class Line3D(LinearEntity3D, Line): """An infinite 3D line in space. A line is declared with two distinct points or a point and direction_ratio as defined using keyword `direction_ratio`. Parameters ========== p1 : Point3D pt : Point3D direction_ratio : list See Also ======== sympy.geometry.point.Point3D sympy.geometry.line.Line sympy.geometry.line.Line2D Examples ======== >>> from sympy import Point3D >>> from sympy.geometry import Line3D, Segment3D >>> L = Line3D(Point3D(2, 3, 4), Point3D(3, 5, 1)) >>> L Line3D(Point3D(2, 3, 4), Point3D(3, 5, 1)) >>> L.points (Point3D(2, 3, 4), Point3D(3, 5, 1)) """ def __new__(cls, p1, pt=None, direction_ratio=[], kwargs): if isinstance(p1, LinearEntity3D): if pt is not None: raise ValueError('if p1 is a LinearEntity, pt must be None.') p1, pt = p1.args else: p1 = Point(p1, dim=3) if pt is not None and len(direction_ratio) == 0: pt = Point(pt, dim=3) elif len(direction_ratio) == 3 and pt is None: pt = Point3D(p1.x + direction_ratio[0], p1.y + direction_ratio[1], p1.z + direction_ratio[2]) else: raise ValueError('A 2nd Point or keyword "direction_ratio" must ' 'be used.') return LinearEntity3D.__new__(cls, p1, pt, kwargs) def equation(self, x='x', y='y', z='z', k=None): """Return the equations that define the line in 3D. Parameters ========== x : str, optional The name to use for the x-axis, default value is 'x'. y : str, optional The name to use for the y-axis, default value is 'y'. z : str, optional The name to use for the z-axis, default value is 'z'. Returns ======= equation : Tuple of simultaneous equations Examples ======== >>> from sympy import Point3D, Line3D, solve >>> from sympy.abc import x, y, z >>> p1, p2 = Point3D(1, 0, 0), Point3D(5, 3, 0) >>> l1 = Line3D(p1, p2) >>> eq = l1.equation(x, y, z); eq (-3x + 4y + 3, z) >>> solve(eq.subs(z, 0), (x, y, z)) {x: 4y/3 + 1} """ if k is not None: SymPyDeprecationWarning( feature="equation() no longer needs 'k'", issue=13742, deprecated_since_version="1.2").warn() from sympy import solve x, y, z, k = [_symbol(i, real=True) for i in (x, y, z, 'k')] p1, p2 = self.points d1, d2, d3 = p1.direction_ratio(p2) x1, y1, z1 = p1 v = (x, y, z) eqs = [-d1k + x - x1, -d2k + y - y1, -d3k + z - z1] # eliminate k from equations by solving first eq with k for k for i, e in enumerate(eqs): if e.has(k): kk = solve(eqs[i], k)[0] eqs.pop(i) break return Tuple([i.subs(k, kk).as_numer_denom()[0] for i in eqs]) class Ray3D(LinearEntity3D, Ray): """ A Ray is a semi-line in the space with a source point and a direction. Parameters ========== p1 : Point3D The source of the Ray p2 : Point or a direction vector direction_ratio: Determines the direction in which the Ray propagates. Attributes ========== source xdirection ydirection zdirection See Also ======== sympy.geometry.point.Point3D, Line3D Examples ======== >>> from sympy import Point3D >>> from sympy.geometry import Ray3D >>> r = Ray3D(Point3D(2, 3, 4), Point3D(3, 5, 0)) >>> r Ray3D(Point3D(2, 3, 4), Point3D(3, 5, 0)) >>> r.points (Point3D(2, 3, 4), Point3D(3, 5, 0)) >>> r.source Point3D(2, 3, 4) >>> r.xdirection oo >>> r.ydirection oo >>> r.direction_ratio [1, 2, -4] """ def __new__(cls, p1, pt=None, direction_ratio=[], kwargs): from sympy.utilities.misc import filldedent if isinstance(p1, LinearEntity3D): if pt is not None: raise ValueError('If p1 is a LinearEntity, pt must be None') p1, pt = p1.args else: p1 = Point(p1, dim=3) if pt is not None and len(direction_ratio) == 0: pt = Point(pt, dim=3) elif len(direction_ratio) == 3 and pt is None: pt = Point3D(p1.x + direction_ratio[0], p1.y + direction_ratio[1], p1.z + direction_ratio[2]) else: raise ValueError(filldedent(''' A 2nd Point or keyword "direction_ratio" must be used. ''')) return LinearEntity3D.__new__(cls, p1, pt, kwargs) @property def xdirection(self): """The x direction of the ray. Positive infinity if the ray points in the positive x direction, negative infinity if the ray points in the negative x direction, or 0 if the ray is vertical. See Also ======== ydirection Examples ======== >>> from sympy import Point3D, Ray3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(0, -1, 0) >>> r1, r2 = Ray3D(p1, p2), Ray3D(p1, p3) >>> r1.xdirection oo >>> r2.xdirection 0 """ if self.p1.x < self.p2.x: return S.Infinity elif self.p1.x == self.p2.x: return S.Zero else: return S.NegativeInfinity @property def ydirection(self): """The y direction of the ray. Positive infinity if the ray points in the positive y direction, negative infinity if the ray points in the negative y direction, or 0 if the ray is horizontal. See Also ======== xdirection Examples ======== >>> from sympy import Point3D, Ray3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(-1, -1, -1), Point3D(-1, 0, 0) >>> r1, r2 = Ray3D(p1, p2), Ray3D(p1, p3) >>> r1.ydirection -oo >>> r2.ydirection 0 """ if self.p1.y < self.p2.y: return S.Infinity elif self.p1.y == self.p2.y: return S.Zero else: return S.NegativeInfinity @property def zdirection(self): """The z direction of the ray. Positive infinity if the ray points in the positive z direction, negative infinity if the ray points in the negative z direction, or 0 if the ray is horizontal. See Also ======== xdirection Examples ======== >>> from sympy import Point3D, Ray3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(-1, -1, -1), Point3D(-1, 0, 0) >>> r1, r2 = Ray3D(p1, p2), Ray3D(p1, p3) >>> r1.ydirection -oo >>> r2.ydirection 0 >>> r2.zdirection 0 """ if self.p1.z < self.p2.z: return S.Infinity elif self.p1.z == self.p2.z: return S.Zero else: return S.NegativeInfinity class Segment3D(LinearEntity3D, Segment): """A line segment in a 3D space. Parameters ========== p1 : Point3D p2 : Point3D Attributes ========== length : number or sympy expression midpoint : Point3D See Also ======== sympy.geometry.point.Point3D, Line3D Examples ======== >>> from sympy import Point3D >>> from sympy.geometry import Segment3D >>> Segment3D((1, 0, 0), (1, 1, 1)) # tuples are interpreted as pts Segment3D(Point3D(1, 0, 0), Point3D(1, 1, 1)) >>> s = Segment3D(Point3D(4, 3, 9), Point3D(1, 1, 7)); s Segment3D(Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.points (Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.length sqrt(17) >>> s.midpoint Point3D(5/2, 2, 8) """ def __new__(cls, p1, p2, kwargs): p1 = Point(p1, dim=3) p2 = Point(p2, dim=3) if p1 == p2: return p1 return LinearEntity3D.__new__(cls, p1, p2, kwargs)
e86ac40ab6a8cda9b2266decdd2d70b836a5e02ab9a89c637dc3a9bf85f94a11	from __future__ import division, print_function from sympy.core import Expr, S, Symbol, oo, pi, sympify from sympy.core.compatibility import as_int, range, ordered from sympy.core.symbol import _symbol, Dummy from sympy.functions.elementary.complexes import sign from sympy.functions.elementary.piecewise import Piecewise from sympy.functions.elementary.trigonometric import cos, sin, tan from sympy.geometry.exceptions import GeometryError from sympy.logic import And from sympy.matrices import Matrix from sympy.simplify import simplify from sympy.utilities import default_sort_key from sympy.utilities.iterables import has_dups, has_variety, uniq, rotate_left, least_rotation from sympy.utilities.misc import func_name from .entity import GeometryEntity, GeometrySet from .point import Point from .ellipse import Circle from .line import Line, Segment, Ray from sympy import sqrt import warnings class Polygon(GeometrySet): """A two-dimensional polygon. A simple polygon in space. Can be constructed from a sequence of points or from a center, radius, number of sides and rotation angle. Parameters ========== vertices : sequence of Points Attributes ========== area angles perimeter vertices centroid sides Raises ====== GeometryError If all parameters are not Points. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment, Triangle Notes ===== Polygons are treated as closed paths rather than 2D areas so some calculations can be be negative or positive (e.g., area) based on the orientation of the points. Any consecutive identical points are reduced to a single point and any points collinear and between two points will be removed unless they are needed to define an explicit intersection (see examples). A Triangle, Segment or Point will be returned when there are 3 or fewer points provided. Examples ======== >>> from sympy import Point, Polygon, pi >>> p1, p2, p3, p4, p5 = [(0, 0), (1, 0), (5, 1), (0, 1), (3, 0)] >>> Polygon(p1, p2, p3, p4) Polygon(Point2D(0, 0), Point2D(1, 0), Point2D(5, 1), Point2D(0, 1)) >>> Polygon(p1, p2) Segment2D(Point2D(0, 0), Point2D(1, 0)) >>> Polygon(p1, p2, p5) Segment2D(Point2D(0, 0), Point2D(3, 0)) The area of a polygon is calculated as positive when vertices are traversed in a ccw direction. When the sides of a polygon cross the area will have positive and negative contributions. The following defines a Z shape where the bottom right connects back to the top left. >>> Polygon((0, 2), (2, 2), (0, 0), (2, 0)).area 0 When the the keyword `n` is used to define the number of sides of the Polygon then a RegularPolygon is created and the other arguments are interpreted as center, radius and rotation. The unrotated RegularPolygon will always have a vertex at Point(r, 0) where `r` is the radius of the circle that circumscribes the RegularPolygon. Its method `spin` can be used to increment that angle. >>> p = Polygon((0,0), 1, n=3) >>> p RegularPolygon(Point2D(0, 0), 1, 3, 0) >>> p.vertices[0] Point2D(1, 0) >>> p.args[0] Point2D(0, 0) >>> p.spin(pi/2) >>> p.vertices[0] Point2D(0, 1) """ def __new__(cls, args, kwargs): if kwargs.get('n', 0): n = kwargs.pop('n') args = list(args) # return a virtual polygon with n sides if len(args) == 2: # center, radius args.append(n) elif len(args) == 3: # center, radius, rotation args.insert(2, n) return RegularPolygon(args, kwargs) vertices = [Point(a, dim=2, kwargs) for a in args] # remove consecutive duplicates nodup = [] for p in vertices: if nodup and p == nodup[-1]: continue nodup.append(p) if len(nodup) > 1 and nodup[-1] == nodup[0]: nodup.pop() # last point was same as first # remove collinear points i = -3 while i < len(nodup) - 3 and len(nodup) > 2: a, b, c = nodup[i], nodup[i + 1], nodup[i + 2] if Point.is_collinear(a, b, c): nodup.pop(i + 1) if a == c: nodup.pop(i) else: i += 1 vertices = list(nodup) if len(vertices) > 3: return GeometryEntity.__new__(cls, vertices, kwargs) elif len(vertices) == 3: return Triangle(vertices, *kwargs) elif len(vertices) == 2: return Segment(vertices, *kwargs) else: return Point(vertices, *kwargs) @property def area(self): """ The area of the polygon. Notes ===== The area calculation can be positive or negative based on the orientation of the points. If any side of the polygon crosses any other side, there will be areas having opposite signs. See Also ======== sympy.geometry.ellipse.Ellipse.area Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.area 3 In the Z shaped polygon (with the lower right connecting back to the upper left) the areas cancel out: >>> Z = Polygon((0, 1), (1, 1), (0, 0), (1, 0)) >>> Z.area 0 In the M shaped polygon, areas do not cancel because no side crosses any other (though there is a point of contact). >>> M = Polygon((0, 0), (0, 1), (2, 0), (3, 1), (3, 0)) >>> M.area -3/2 """ area = 0 args = self.args for i in range(len(args)): x1, y1 = args[i - 1].args x2, y2 = args[i].args area += x1y2 - x2y1 return simplify(area) / 2 @staticmethod def _isright(a, b, c): """Return True/False for cw/ccw orientation. Examples ======== >>> from sympy import Point, Polygon >>> a, b, c = [Point(i) for i in [(0, 0), (1, 1), (1, 0)]] >>> Polygon._isright(a, b, c) True >>> Polygon._isright(a, c, b) False """ ba = b - a ca = c - a t_area = simplify(ba.xca.y - ca.xba.y) res = t_area.is_nonpositive if res is None: raise ValueError("Can't determine orientation") return res @property def angles(self): """The internal angle at each vertex. Returns ======= angles : dict A dictionary where each key is a vertex and each value is the internal angle at that vertex. The vertices are represented as Points. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.LinearEntity.angle_between Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.angles[p1] pi/2 >>> poly.angles[p2] acos(-4sqrt(17)/17) """ # Determine orientation of points args = self.vertices cw = self._isright(args[-1], args[0], args[1]) ret = {} for i in range(len(args)): a, b, c = args[i - 2], args[i - 1], args[i] ang = Ray(b, a).angle_between(Ray(b, c)) if cw ^ self._isright(a, b, c): ret[b] = 2S.Pi - ang else: ret[b] = ang return ret @property def ambient_dimension(self): return self.vertices[0].ambient_dimension @property def perimeter(self): """The perimeter of the polygon. Returns ======= perimeter : number or Basic instance See Also ======== sympy.geometry.line.Segment.length Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.perimeter sqrt(17) + 7 """ p = 0 args = self.vertices for i in range(len(args)): p += args[i - 1].distance(args[i]) return simplify(p) @property def vertices(self): """The vertices of the polygon. Returns ======= vertices : list of Points Notes ===== When iterating over the vertices, it is more efficient to index self rather than to request the vertices and index them. Only use the vertices when you want to process all of them at once. This is even more important with RegularPolygons that calculate each vertex. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.vertices [Point2D(0, 0), Point2D(1, 0), Point2D(5, 1), Point2D(0, 1)] >>> poly.vertices[0] Point2D(0, 0) """ return list(self.args) @property def centroid(self): """The centroid of the polygon. Returns ======= centroid : Point See Also ======== sympy.geometry.point.Point, sympy.geometry.util.centroid Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.centroid Point2D(31/18, 11/18) """ A = 1/(6self.area) cx, cy = 0, 0 args = self.args for i in range(len(args)): x1, y1 = args[i - 1].args x2, y2 = args[i].args v = x1y2 - x2y1 cx += v(x1 + x2) cy += v(y1 + y2) return Point(simplify(Acx), simplify(Acy)) def second_moment_of_area(self, point=None): """Returns the second moment and product moment of area of a two dimensional polygon. Parameters ========== point : Point, two-tuple of sympifiable objects, or None(default=None) point is the point about which second moment of area is to be found. If "point=None" it will be calculated about the axis passing through the centroid of the polygon. Returns ======= I_xx, I_yy, I_xy : number or sympy expression I_xx, I_yy are second moment of area of a two dimensional polygon. I_xy is product moment of area of a two dimensional polygon. Examples ======== >>> from sympy import Point, Polygon, symbols >>> a, b = symbols('a, b') >>> p1, p2, p3, p4, p5 = [(0, 0), (a, 0), (a, b), (0, b), (a/3, b/3)] >>> rectangle = Polygon(p1, p2, p3, p4) >>> rectangle.second_moment_of_area() (ab3/12, a3b/12, 0) >>> rectangle.second_moment_of_area(p5) (ab3/9, a3b/9, a*2b*2/36) References ========== https://en.wikipedia.org/wiki/Second_moment_of_area """ I_xx, I_yy, I_xy = 0, 0, 0 args = self.args for i in range(len(args)): x1, y1 = args[i-1].args x2, y2 = args[i].args v = x1y2 - x2y1 I_xx += (y12 + y1y2 + y2*2)v I_yy += (x1*2 + x1x2 + x2*2)v I_xy += (x1y2 + 2x1y1 + 2x2y2 + x2y1)v A = self.area c_x = self.centroid[0] c_y = self.centroid[1] # parallel axis theorem I_xx_c = (I_xx/12) - (A(c_y*2)) I_yy_c = (I_yy/12) - (A(c_x*2)) I_xy_c = (I_xy/24) - (A(c_xc_y)) if point is None: return I_xx_c, I_yy_c, I_xy_c I_xx = (I_xx_c + A((point[1]-c_y)*2)) I_yy = (I_yy_c + A((point[0]-c_x)*2)) I_xy = (I_xy_c + A((point[0]-c_x)(point[1]-c_y))) return I_xx, I_yy, I_xy @property def sides(self): """The directed line segments that form the sides of the polygon. Returns ======= sides : list of sides Each side is a directed Segment. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.sides [Segment2D(Point2D(0, 0), Point2D(1, 0)), Segment2D(Point2D(1, 0), Point2D(5, 1)), Segment2D(Point2D(5, 1), Point2D(0, 1)), Segment2D(Point2D(0, 1), Point2D(0, 0))] """ res = [] args = self.vertices for i in range(-len(args), 0): res.append(Segment(args[i], args[i + 1])) return res @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ verts = self.vertices xs = [p.x for p in verts] ys = [p.y for p in verts] return (min(xs), min(ys), max(xs), max(ys)) def is_convex(self): """Is the polygon convex? A polygon is convex if all its interior angles are less than 180 degrees and there are no intersections between sides. Returns ======= is_convex : boolean True if this polygon is convex, False otherwise. See Also ======== sympy.geometry.util.convex_hull Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.is_convex() True """ # Determine orientation of points args = self.vertices cw = self._isright(args[-2], args[-1], args[0]) for i in range(1, len(args)): if cw ^ self._isright(args[i - 2], args[i - 1], args[i]): return False # check for intersecting sides sides = self.sides for i, si in enumerate(sides): pts = si.args # exclude the sides connected to si for j in range(1 if i == len(sides) - 1 else 0, i - 1): sj = sides[j] if sj.p1 not in pts and sj.p2 not in pts: hit = si.intersection(sj) if hit: return False return True def encloses_point(self, p): """ Return True if p is enclosed by (is inside of) self. Notes ===== Being on the border of self is considered False. Parameters ========== p : Point Returns ======= encloses_point : True, False or None See Also ======== sympy.geometry.point.Point, sympy.geometry.ellipse.Ellipse.encloses_point Examples ======== >>> from sympy import Polygon, Point >>> from sympy.abc import t >>> p = Polygon((0, 0), (4, 0), (4, 4)) >>> p.encloses_point(Point(2, 1)) True >>> p.encloses_point(Point(2, 2)) False >>> p.encloses_point(Point(5, 5)) False References ========== [1] http://paulbourke.net/geometry/polygonmesh/#insidepoly """ p = Point(p, dim=2) if p in self.vertices or any(p in s for s in self.sides): return False # move to p, checking that the result is numeric lit = [] for v in self.vertices: lit.append(v - p) # the difference is simplified if lit[-1].free_symbols: return None poly = Polygon(lit) # polygon closure is assumed in the following test but Polygon removes duplicate pts so # the last point has to be added so all sides are computed. Using Polygon.sides is # not good since Segments are unordered. args = poly.args indices = list(range(-len(args), 1)) if poly.is_convex(): orientation = None for i in indices: a = args[i] b = args[i + 1] test = ((-a.y)(b.x - a.x) - (-a.x)(b.y - a.y)).is_negative if orientation is None: orientation = test elif test is not orientation: return False return True hit_odd = False p1x, p1y = args[0].args for i in indices[1:]: p2x, p2y = args[i].args if 0 > min(p1y, p2y): if 0 <= max(p1y, p2y): if 0 <= max(p1x, p2x): if p1y != p2y: xinters = (-p1y)(p2x - p1x)/(p2y - p1y) + p1x if p1x == p2x or 0 <= xinters: hit_odd = not hit_odd p1x, p1y = p2x, p2y return hit_odd def arbitrary_point(self, parameter='t'): """A parameterized point on the polygon. The parameter, varying from 0 to 1, assigns points to the position on the perimeter that is that fraction of the total perimeter. So the point evaluated at t=1/2 would return the point from the first vertex that is 1/2 way around the polygon. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= arbitrary_point : Point Raises ====== ValueError When `parameter` already appears in the Polygon's definition. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Polygon, S, Symbol >>> t = Symbol('t', real=True) >>> tri = Polygon((0, 0), (1, 0), (1, 1)) >>> p = tri.arbitrary_point('t') >>> perimeter = tri.perimeter >>> s1, s2 = [s.length for s in tri.sides[:2]] >>> p.subs(t, (s1 + s2/2)/perimeter) Point2D(1, 1/2) """ t = _symbol(parameter, real=True) if t.name in (f.name for f in self.free_symbols): raise ValueError('Symbol %s already appears in object and cannot be used as a parameter.' % t.name) sides = [] perimeter = self.perimeter perim_fraction_start = 0 for s in self.sides: side_perim_fraction = s.length/perimeter perim_fraction_end = perim_fraction_start + side_perim_fraction pt = s.arbitrary_point(parameter).subs( t, (t - perim_fraction_start)/side_perim_fraction) sides.append( (pt, (And(perim_fraction_start <= t, t < perim_fraction_end)))) perim_fraction_start = perim_fraction_end return Piecewise(sides) def parameter_value(self, other, t): from sympy.solvers.solvers import solve if not isinstance(other,GeometryEntity): other = Point(other, dim=self.ambient_dimension) if not isinstance(other,Point): raise ValueError("other must be a point") if other.free_symbols: raise NotImplementedError('non-numeric coordinates') unknown = False T = Dummy('t', real=True) p = self.arbitrary_point(T) for pt, cond in p.args: sol = solve(pt - other, T, dict=True) if not sol: continue value = sol[0][T] if simplify(cond.subs(T, value)) == True: return {t: value} unknown = True if unknown: raise ValueError("Given point may not be on %s" % func_name(self)) raise ValueError("Given point is not on %s" % func_name(self)) def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the polygon. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list (plot interval) [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Polygon >>> p = Polygon((0, 0), (1, 0), (1, 1)) >>> p.plot_interval() [t, 0, 1] """ t = Symbol(parameter, real=True) return [t, 0, 1] def intersection(self, o): """The intersection of polygon and geometry entity. The intersection may be empty and can contain individual Points and complete Line Segments. Parameters ========== other: GeometryEntity Returns ======= intersection : list The list of Segments and Points See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment Examples ======== >>> from sympy import Point, Polygon, Line >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly1 = Polygon(p1, p2, p3, p4) >>> p5, p6, p7 = map(Point, [(3, 2), (1, -1), (0, 2)]) >>> poly2 = Polygon(p5, p6, p7) >>> poly1.intersection(poly2) [Point2D(1/3, 1), Point2D(2/3, 0), Point2D(9/5, 1/5), Point2D(7/3, 1)] >>> poly1.intersection(Line(p1, p2)) [Segment2D(Point2D(0, 0), Point2D(1, 0))] >>> poly1.intersection(p1) [Point2D(0, 0)] """ intersection_result = [] k = o.sides if isinstance(o, Polygon) else [o] for side in self.sides: for side1 in k: intersection_result.extend(side.intersection(side1)) intersection_result = list(uniq(intersection_result)) points = [entity for entity in intersection_result if isinstance(entity, Point)] segments = [entity for entity in intersection_result if isinstance(entity, Segment)] if points and segments: points_in_segments = list(uniq([point for point in points for segment in segments if point in segment])) if points_in_segments: for i in points_in_segments: points.remove(i) return list(ordered(segments + points)) else: return list(ordered(intersection_result)) def distance(self, o): """ Returns the shortest distance between self and o. If o is a point, then self does not need to be convex. If o is another polygon self and o must be convex. Examples ======== >>> from sympy import Point, Polygon, RegularPolygon >>> p1, p2 = map(Point, [(0, 0), (7, 5)]) >>> poly = Polygon(RegularPolygon(p1, 1, 3).vertices) >>> poly.distance(p2) sqrt(61) """ if isinstance(o, Point): dist = oo for side in self.sides: current = side.distance(o) if current == 0: return S.Zero elif current < dist: dist = current return dist elif isinstance(o, Polygon) and self.is_convex() and o.is_convex(): return self._do_poly_distance(o) raise NotImplementedError() def _do_poly_distance(self, e2): """ Calculates the least distance between the exteriors of two convex polygons e1 and e2. Does not check for the convexity of the polygons as this is checked by Polygon.distance. Notes ===== - Prints a warning if the two polygons possibly intersect as the return value will not be valid in such a case. For a more through test of intersection use intersection(). See Also ======== sympy.geometry.point.Point.distance Examples ======== >>> from sympy.geometry import Point, Polygon >>> square = Polygon(Point(0, 0), Point(0, 1), Point(1, 1), Point(1, 0)) >>> triangle = Polygon(Point(1, 2), Point(2, 2), Point(2, 1)) >>> square._do_poly_distance(triangle) sqrt(2)/2 Description of method used ========================== Method: [1] http://cgm.cs.mcgill.ca/~orm/mind2p.html Uses rotating calipers: [2] https://en.wikipedia.org/wiki/Rotating_calipers and antipodal points: [3] https://en.wikipedia.org/wiki/Antipodal_point """ e1 = self '''Tests for a possible intersection between the polygons and outputs a warning''' e1_center = e1.centroid e2_center = e2.centroid e1_max_radius = S.Zero e2_max_radius = S.Zero for vertex in e1.vertices: r = Point.distance(e1_center, vertex) if e1_max_radius < r: e1_max_radius = r for vertex in e2.vertices: r = Point.distance(e2_center, vertex) if e2_max_radius < r: e2_max_radius = r center_dist = Point.distance(e1_center, e2_center) if center_dist <= e1_max_radius + e2_max_radius: warnings.warn("Polygons may intersect producing erroneous output") ''' Find the upper rightmost vertex of e1 and the lowest leftmost vertex of e2 ''' e1_ymax = Point(0, -oo) e2_ymin = Point(0, oo) for vertex in e1.vertices: if vertex.y > e1_ymax.y or (vertex.y == e1_ymax.y and vertex.x > e1_ymax.x): e1_ymax = vertex for vertex in e2.vertices: if vertex.y < e2_ymin.y or (vertex.y == e2_ymin.y and vertex.x < e2_ymin.x): e2_ymin = vertex min_dist = Point.distance(e1_ymax, e2_ymin) ''' Produce a dictionary with vertices of e1 as the keys and, for each vertex, the points to which the vertex is connected as its value. The same is then done for e2. ''' e1_connections = {} e2_connections = {} for side in e1.sides: if side.p1 in e1_connections: e1_connections[side.p1].append(side.p2) else: e1_connections[side.p1] = [side.p2] if side.p2 in e1_connections: e1_connections[side.p2].append(side.p1) else: e1_connections[side.p2] = [side.p1] for side in e2.sides: if side.p1 in e2_connections: e2_connections[side.p1].append(side.p2) else: e2_connections[side.p1] = [side.p2] if side.p2 in e2_connections: e2_connections[side.p2].append(side.p1) else: e2_connections[side.p2] = [side.p1] e1_current = e1_ymax e2_current = e2_ymin support_line = Line(Point(S.Zero, S.Zero), Point(S.One, S.Zero)) ''' Determine which point in e1 and e2 will be selected after e2_ymin and e1_ymax, this information combined with the above produced dictionaries determines the path that will be taken around the polygons ''' point1 = e1_connections[e1_ymax][0] point2 = e1_connections[e1_ymax][1] angle1 = support_line.angle_between(Line(e1_ymax, point1)) angle2 = support_line.angle_between(Line(e1_ymax, point2)) if angle1 < angle2: e1_next = point1 elif angle2 < angle1: e1_next = point2 elif Point.distance(e1_ymax, point1) > Point.distance(e1_ymax, point2): e1_next = point2 else: e1_next = point1 point1 = e2_connections[e2_ymin][0] point2 = e2_connections[e2_ymin][1] angle1 = support_line.angle_between(Line(e2_ymin, point1)) angle2 = support_line.angle_between(Line(e2_ymin, point2)) if angle1 > angle2: e2_next = point1 elif angle2 > angle1: e2_next = point2 elif Point.distance(e2_ymin, point1) > Point.distance(e2_ymin, point2): e2_next = point2 else: e2_next = point1 ''' Loop which determines the distance between anti-podal pairs and updates the minimum distance accordingly. It repeats until it reaches the starting position. ''' while True: e1_angle = support_line.angle_between(Line(e1_current, e1_next)) e2_angle = pi - support_line.angle_between(Line( e2_current, e2_next)) if (e1_angle < e2_angle) is True: support_line = Line(e1_current, e1_next) e1_segment = Segment(e1_current, e1_next) min_dist_current = e1_segment.distance(e2_current) if min_dist_current.evalf() < min_dist.evalf(): min_dist = min_dist_current if e1_connections[e1_next][0] != e1_current: e1_current = e1_next e1_next = e1_connections[e1_next][0] else: e1_current = e1_next e1_next = e1_connections[e1_next][1] elif (e1_angle > e2_angle) is True: support_line = Line(e2_next, e2_current) e2_segment = Segment(e2_current, e2_next) min_dist_current = e2_segment.distance(e1_current) if min_dist_current.evalf() < min_dist.evalf(): min_dist = min_dist_current if e2_connections[e2_next][0] != e2_current: e2_current = e2_next e2_next = e2_connections[e2_next][0] else: e2_current = e2_next e2_next = e2_connections[e2_next][1] else: support_line = Line(e1_current, e1_next) e1_segment = Segment(e1_current, e1_next) e2_segment = Segment(e2_current, e2_next) min1 = e1_segment.distance(e2_next) min2 = e2_segment.distance(e1_next) min_dist_current = min(min1, min2) if min_dist_current.evalf() < min_dist.evalf(): min_dist = min_dist_current if e1_connections[e1_next][0] != e1_current: e1_current = e1_next e1_next = e1_connections[e1_next][0] else: e1_current = e1_next e1_next = e1_connections[e1_next][1] if e2_connections[e2_next][0] != e2_current: e2_current = e2_next e2_next = e2_connections[e2_next][0] else: e2_current = e2_next e2_next = e2_connections[e2_next][1] if e1_current == e1_ymax and e2_current == e2_ymin: break return min_dist def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the Polygon. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = map(N, self.vertices) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1} z".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" />' ).format(2. scale_factor, path, fill_color) def _hashable_content(self): D = {} def ref_list(point_list): kee = {} for i, p in enumerate(ordered(set(point_list))): kee[p] = i D[i] = p return [kee[p] for p in point_list] S1 = ref_list(self.args) r_nor = rotate_left(S1, least_rotation(S1)) S2 = ref_list(list(reversed(self.args))) r_rev = rotate_left(S2, least_rotation(S2)) if r_nor < r_rev: r = r_nor else: r = r_rev canonical_args = [ D[order] for order in r ] return tuple(canonical_args) def __contains__(self, o): """ Return True if o is contained within the boundary lines of self.altitudes Parameters ========== other : GeometryEntity Returns ======= contained in : bool The points (and sides, if applicable) are contained in self. See Also ======== sympy.geometry.entity.GeometryEntity.encloses Examples ======== >>> from sympy import Line, Segment, Point >>> p = Point(0, 0) >>> q = Point(1, 1) >>> s = Segment(p, q2) >>> l = Line(p, q) >>> p in q False >>> p in s True >>> q3 in s False >>> s in l True """ if isinstance(o, Polygon): return self == o elif isinstance(o, Segment): return any(o in s for s in self.sides) elif isinstance(o, Point): if o in self.vertices: return True for side in self.sides: if o in side: return True return False class RegularPolygon(Polygon): """ A regular polygon. Such a polygon has all internal angles equal and all sides the same length. Parameters ========== center : Point radius : number or Basic instance The distance from the center to a vertex n : int The number of sides Attributes ========== vertices center radius rotation apothem interior_angle exterior_angle circumcircle incircle angles Raises ====== GeometryError If the `center` is not a Point, or the `radius` is not a number or Basic instance, or the number of sides, `n`, is less than three. Notes ===== A RegularPolygon can be instantiated with Polygon with the kwarg n. Regular polygons are instantiated with a center, radius, number of sides and a rotation angle. Whereas the arguments of a Polygon are vertices, the vertices of the RegularPolygon must be obtained with the vertices method. See Also ======== sympy.geometry.point.Point, Polygon Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> r = RegularPolygon(Point(0, 0), 5, 3) >>> r RegularPolygon(Point2D(0, 0), 5, 3, 0) >>> r.vertices[0] Point2D(5, 0) """ __slots__ = ['_n', '_center', '_radius', '_rot'] def __new__(self, c, r, n, rot=0, kwargs): r, n, rot = map(sympify, (r, n, rot)) c = Point(c, dim=2, kwargs) if not isinstance(r, Expr): raise GeometryError("r must be an Expr object, not %s" % r) if n.is_Number: as_int(n) # let an error raise if necessary if n < 3: raise GeometryError("n must be a >= 3, not %s" % n) obj = GeometryEntity.__new__(self, c, r, n, *kwargs) obj._n = n obj._center = c obj._radius = r obj._rot = rot % (2S.Pi/n) if rot.is_number else rot return obj @property def args(self): """ Returns the center point, the radius, the number of sides, and the orientation angle. Examples ======== >>> from sympy import RegularPolygon, Point >>> r = RegularPolygon(Point(0, 0), 5, 3) >>> r.args (Point2D(0, 0), 5, 3, 0) """ return self._center, self._radius, self._n, self._rot def __str__(self): return 'RegularPolygon(%s, %s, %s, %s)' % tuple(self.args) def __repr__(self): return 'RegularPolygon(%s, %s, %s, %s)' % tuple(self.args) @property def area(self): """Returns the area. Examples ======== >>> from sympy.geometry import RegularPolygon >>> square = RegularPolygon((0, 0), 1, 4) >>> square.area 2 >>> _ == square.length*2 True """ c, r, n, rot = self.args return sign(r)nself.length2/(4tan(pi/n)) @property def length(self): """Returns the length of the sides. The half-length of the side and the apothem form two legs of a right triangle whose hypotenuse is the radius of the regular polygon. Examples ======== >>> from sympy.geometry import RegularPolygon >>> from sympy import sqrt >>> s = square_in_unit_circle = RegularPolygon((0, 0), 1, 4) >>> s.length sqrt(2) >>> sqrt((_/2)2 + s.apothem2) == s.radius True """ return self.radius2sin(pi/self._n) @property def center(self): """The center of the RegularPolygon This is also the center of the circumscribing circle. Returns ======= center : Point See Also ======== sympy.geometry.point.Point, sympy.geometry.ellipse.Ellipse.center Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 5, 4) >>> rp.center Point2D(0, 0) """ return self._center centroid = center @property def circumcenter(self): """ Alias for center. Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 5, 4) >>> rp.circumcenter Point2D(0, 0) """ return self.center @property def radius(self): """Radius of the RegularPolygon This is also the radius of the circumscribing circle. Returns ======= radius : number or instance of Basic See Also ======== sympy.geometry.line.Segment.length, sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.radius r """ return self._radius @property def circumradius(self): """ Alias for radius. Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.circumradius r """ return self.radius @property def rotation(self): """CCW angle by which the RegularPolygon is rotated Returns ======= rotation : number or instance of Basic Examples ======== >>> from sympy import pi >>> from sympy.abc import a >>> from sympy.geometry import RegularPolygon, Point >>> RegularPolygon(Point(0, 0), 3, 4, pi/4).rotation pi/4 Numerical rotation angles are made canonical: >>> RegularPolygon(Point(0, 0), 3, 4, a).rotation a >>> RegularPolygon(Point(0, 0), 3, 4, pi).rotation 0 """ return self._rot @property def apothem(self): """The inradius of the RegularPolygon. The apothem/inradius is the radius of the inscribed circle. Returns ======= apothem : number or instance of Basic See Also ======== sympy.geometry.line.Segment.length, sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.apothem sqrt(2)r/2 """ return self.radius cos(S.Pi/self._n) @property def inradius(self): """ Alias for apothem. Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.inradius sqrt(2)r/2 """ return self.apothem @property def interior_angle(self): """Measure of the interior angles. Returns ======= interior_angle : number See Also ======== sympy.geometry.line.LinearEntity.angle_between Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 8) >>> rp.interior_angle 3pi/4 """ return (self._n - 2)S.Pi/self._n @property def exterior_angle(self): """Measure of the exterior angles. Returns ======= exterior_angle : number See Also ======== sympy.geometry.line.LinearEntity.angle_between Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 8) >>> rp.exterior_angle pi/4 """ return 2S.Pi/self._n @property def circumcircle(self): """The circumcircle of the RegularPolygon. Returns ======= circumcircle : Circle See Also ======== circumcenter, sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 8) >>> rp.circumcircle Circle(Point2D(0, 0), 4) """ return Circle(self.center, self.radius) @property def incircle(self): """The incircle of the RegularPolygon. Returns ======= incircle : Circle See Also ======== inradius, sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 7) >>> rp.incircle Circle(Point2D(0, 0), 4cos(pi/7)) """ return Circle(self.center, self.apothem) @property def angles(self): """ Returns a dictionary with keys, the vertices of the Polygon, and values, the interior angle at each vertex. Examples ======== >>> from sympy import RegularPolygon, Point >>> r = RegularPolygon(Point(0, 0), 5, 3) >>> r.angles {Point2D(-5/2, -5sqrt(3)/2): pi/3, Point2D(-5/2, 5sqrt(3)/2): pi/3, Point2D(5, 0): pi/3} """ ret = {} ang = self.interior_angle for v in self.vertices: ret[v] = ang return ret def encloses_point(self, p): """ Return True if p is enclosed by (is inside of) self. Notes ===== Being on the border of self is considered False. The general Polygon.encloses_point method is called only if a point is not within or beyond the incircle or circumcircle, respectively. Parameters ========== p : Point Returns ======= encloses_point : True, False or None See Also ======== sympy.geometry.ellipse.Ellipse.encloses_point Examples ======== >>> from sympy import RegularPolygon, S, Point, Symbol >>> p = RegularPolygon((0, 0), 3, 4) >>> p.encloses_point(Point(0, 0)) True >>> r, R = p.inradius, p.circumradius >>> p.encloses_point(Point((r + R)/2, 0)) True >>> p.encloses_point(Point(R/2, R/2 + (R - r)/10)) False >>> t = Symbol('t', real=True) >>> p.encloses_point(p.arbitrary_point().subs(t, S.Half)) False >>> p.encloses_point(Point(5, 5)) False """ c = self.center d = Segment(c, p).length if d >= self.radius: return False elif d < self.inradius: return True else: # now enumerate the RegularPolygon like a general polygon. return Polygon.encloses_point(self, p) def spin(self, angle): """Increment in place* the virtual Polygon's rotation by ccw angle. See also: rotate method which moves the center. >>> from sympy import Polygon, Point, pi >>> r = Polygon(Point(0,0), 1, n=3) >>> r.vertices[0] Point2D(1, 0) >>> r.spin(pi/6) >>> r.vertices[0] Point2D(sqrt(3)/2, 1/2) See Also ======== rotation rotate : Creates a copy of the RegularPolygon rotated about a Point """ self._rot += angle def rotate(self, angle, pt=None): """Override GeometryEntity.rotate to first rotate the RegularPolygon about its center. >>> from sympy import Point, RegularPolygon, Polygon, pi >>> t = RegularPolygon(Point(1, 0), 1, 3) >>> t.vertices[0] # vertex on x-axis Point2D(2, 0) >>> t.rotate(pi/2).vertices[0] # vertex on y axis now Point2D(0, 2) See Also ======== rotation spin : Rotates a RegularPolygon in place """ r = type(self)(self.args) # need a copy or else changes are in-place r._rot += angle return GeometryEntity.rotate(r, angle, pt) def scale(self, x=1, y=1, pt=None): """Override GeometryEntity.scale since it is the radius that must be scaled (if x == y) or else a new Polygon must be returned. >>> from sympy import RegularPolygon Symmetric scaling returns a RegularPolygon: >>> RegularPolygon((0, 0), 1, 4).scale(2, 2) RegularPolygon(Point2D(0, 0), 2, 4, 0) Asymmetric scaling returns a kite as a Polygon: >>> RegularPolygon((0, 0), 1, 4).scale(2, 1) Polygon(Point2D(2, 0), Point2D(0, 1), Point2D(-2, 0), Point2D(0, -1)) """ if pt: pt = Point(pt, dim=2) return self.translate((-pt).args).scale(x, y).translate(pt.args) if x != y: return Polygon(self.vertices).scale(x, y) c, r, n, rot = self.args r = x return self.func(c, r, n, rot) def reflect(self, line): """Override GeometryEntity.reflect since this is not made of only points. Examples ======== >>> from sympy import RegularPolygon, Line >>> RegularPolygon((0, 0), 1, 4).reflect(Line((0, 1), slope=-2)) RegularPolygon(Point2D(4/5, 2/5), -1, 4, atan(4/3)) """ c, r, n, rot = self.args v = self.vertices[0] d = v - c cc = c.reflect(line) vv = v.reflect(line) dd = vv - cc # calculate rotation about the new center # which will align the vertices l1 = Ray((0, 0), dd) l2 = Ray((0, 0), d) ang = l1.closing_angle(l2) rot += ang # change sign of radius as point traversal is reversed return self.func(cc, -r, n, rot) @property def vertices(self): """The vertices of the RegularPolygon. Returns ======= vertices : list Each vertex is a Point. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 5, 4) >>> rp.vertices [Point2D(5, 0), Point2D(0, 5), Point2D(-5, 0), Point2D(0, -5)] """ c = self._center r = abs(self._radius) rot = self._rot v = 2S.Pi/self._n return [Point(c.x + rcos(kv + rot), c.y + rsin(kv + rot)) for k in range(self._n)] def __eq__(self, o): if not isinstance(o, Polygon): return False elif not isinstance(o, RegularPolygon): return Polygon.__eq__(o, self) return self.args == o.args def __hash__(self): return super(RegularPolygon, self).__hash__() class Triangle(Polygon): """ A polygon with three vertices and three sides. Parameters ========== points : sequence of Points keyword: asa, sas, or sss to specify sides/angles of the triangle Attributes ========== vertices altitudes orthocenter circumcenter circumradius circumcircle inradius incircle exradii medians medial nine_point_circle Raises ====== GeometryError If the number of vertices is not equal to three, or one of the vertices is not a Point, or a valid keyword is not given. See Also ======== sympy.geometry.point.Point, Polygon Examples ======== >>> from sympy.geometry import Triangle, Point >>> Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) Triangle(Point2D(0, 0), Point2D(4, 0), Point2D(4, 3)) Keywords sss, sas, or asa can be used to give the desired side lengths (in order) and interior angles (in degrees) that define the triangle: >>> Triangle(sss=(3, 4, 5)) Triangle(Point2D(0, 0), Point2D(3, 0), Point2D(3, 4)) >>> Triangle(asa=(30, 1, 30)) Triangle(Point2D(0, 0), Point2D(1, 0), Point2D(1/2, sqrt(3)/6)) >>> Triangle(sas=(1, 45, 2)) Triangle(Point2D(0, 0), Point2D(2, 0), Point2D(sqrt(2)/2, sqrt(2)/2)) """ def __new__(cls, args, kwargs): if len(args) != 3: if 'sss' in kwargs: return _sss([simplify(a) for a in kwargs['sss']]) if 'asa' in kwargs: return _asa([simplify(a) for a in kwargs['asa']]) if 'sas' in kwargs: return _sas([simplify(a) for a in kwargs['sas']]) msg = "Triangle instantiates with three points or a valid keyword." raise GeometryError(msg) vertices = [Point(a, dim=2, *kwargs) for a in args] # remove consecutive duplicates nodup = [] for p in vertices: if nodup and p == nodup[-1]: continue nodup.append(p) if len(nodup) > 1 and nodup[-1] == nodup[0]: nodup.pop() # last point was same as first # remove collinear points i = -3 while i < len(nodup) - 3 and len(nodup) > 2: a, b, c = sorted( [nodup[i], nodup[i + 1], nodup[i + 2]], key=default_sort_key) if Point.is_collinear(a, b, c): nodup[i] = a nodup[i + 1] = None nodup.pop(i + 1) i += 1 vertices = list(filter(lambda x: x is not None, nodup)) if len(vertices) == 3: return GeometryEntity.__new__(cls, vertices, *kwargs) elif len(vertices) == 2: return Segment(vertices, *kwargs) else: return Point(vertices, *kwargs) @property def vertices(self): """The triangle's vertices Returns ======= vertices : tuple Each element in the tuple is a Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Triangle, Point >>> t = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t.vertices (Point2D(0, 0), Point2D(4, 0), Point2D(4, 3)) """ return self.args def is_similar(t1, t2): """Is another triangle similar to this one. Two triangles are similar if one can be uniformly scaled to the other. Parameters ========== other: Triangle Returns ======= is_similar : boolean See Also ======== sympy.geometry.entity.GeometryEntity.is_similar Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t2 = Triangle(Point(0, 0), Point(-4, 0), Point(-4, -3)) >>> t1.is_similar(t2) True >>> t2 = Triangle(Point(0, 0), Point(-4, 0), Point(-4, -4)) >>> t1.is_similar(t2) False """ if not isinstance(t2, Polygon): return False s1_1, s1_2, s1_3 = [side.length for side in t1.sides] s2 = [side.length for side in t2.sides] def _are_similar(u1, u2, u3, v1, v2, v3): e1 = simplify(u1/v1) e2 = simplify(u2/v2) e3 = simplify(u3/v3) return bool(e1 == e2) and bool(e2 == e3) # There's only 6 permutations, so write them out return _are_similar(s1_1, s1_2, s1_3, s2) or \ _are_similar(s1_1, s1_3, s1_2, s2) or \ _are_similar(s1_2, s1_1, s1_3, s2) or \ _are_similar(s1_2, s1_3, s1_1, s2) or \ _are_similar(s1_3, s1_1, s1_2, s2) or \ _are_similar(s1_3, s1_2, s1_1, s2) def is_equilateral(self): """Are all the sides the same length? Returns ======= is_equilateral : boolean See Also ======== sympy.geometry.entity.GeometryEntity.is_similar, RegularPolygon is_isosceles, is_right, is_scalene Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t1.is_equilateral() False >>> from sympy import sqrt >>> t2 = Triangle(Point(0, 0), Point(10, 0), Point(5, 5sqrt(3))) >>> t2.is_equilateral() True """ return not has_variety(s.length for s in self.sides) def is_isosceles(self): """Are two or more of the sides the same length? Returns ======= is_isosceles : boolean See Also ======== is_equilateral, is_right, is_scalene Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(2, 4)) >>> t1.is_isosceles() True """ return has_dups(s.length for s in self.sides) def is_scalene(self): """Are all the sides of the triangle of different lengths? Returns ======= is_scalene : boolean See Also ======== is_equilateral, is_isosceles, is_right Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(1, 4)) >>> t1.is_scalene() True """ return not has_dups(s.length for s in self.sides) def is_right(self): """Is the triangle right-angled. Returns ======= is_right : boolean See Also ======== sympy.geometry.line.LinearEntity.is_perpendicular is_equilateral, is_isosceles, is_scalene Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t1.is_right() True """ s = self.sides return Segment.is_perpendicular(s[0], s[1]) or \ Segment.is_perpendicular(s[1], s[2]) or \ Segment.is_perpendicular(s[0], s[2]) @property def altitudes(self): """The altitudes of the triangle. An altitude of a triangle is a segment through a vertex, perpendicular to the opposite side, with length being the height of the vertex measured from the line containing the side. Returns ======= altitudes : dict The dictionary consists of keys which are vertices and values which are Segments. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment.length Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.altitudes[p1] Segment2D(Point2D(0, 0), Point2D(1/2, 1/2)) """ s = self.sides v = self.vertices return {v[0]: s[1].perpendicular_segment(v[0]), v[1]: s[2].perpendicular_segment(v[1]), v[2]: s[0].perpendicular_segment(v[2])} @property def orthocenter(self): """The orthocenter of the triangle. The orthocenter is the intersection of the altitudes of a triangle. It may lie inside, outside or on the triangle. Returns ======= orthocenter : Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.orthocenter Point2D(0, 0) """ a = self.altitudes v = self.vertices return Line(a[v[0]]).intersection(Line(a[v[1]]))[0] @property def circumcenter(self): """The circumcenter of the triangle The circumcenter is the center of the circumcircle. Returns ======= circumcenter : Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.circumcenter Point2D(1/2, 1/2) """ a, b, c = [x.perpendicular_bisector() for x in self.sides] if not a.intersection(b): print(a,b,a.intersection(b)) return a.intersection(b)[0] @property def circumradius(self): """The radius of the circumcircle of the triangle. Returns ======= circumradius : number of Basic instance See Also ======== sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import Point, Triangle >>> a = Symbol('a') >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, a) >>> t = Triangle(p1, p2, p3) >>> t.circumradius sqrt(a*2/4 + 1/4) """ return Point.distance(self.circumcenter, self.vertices[0]) @property def circumcircle(self): """The circle which passes through the three vertices of the triangle. Returns ======= circumcircle : Circle See Also ======== sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.circumcircle Circle(Point2D(1/2, 1/2), sqrt(2)/2) """ return Circle(self.circumcenter, self.circumradius) def bisectors(self): """The angle bisectors of the triangle. An angle bisector of a triangle is a straight line through a vertex which cuts the corresponding angle in half. Returns ======= bisectors : dict Each key is a vertex (Point) and each value is the corresponding bisector (Segment). See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment Examples ======== >>> from sympy.geometry import Point, Triangle, Segment >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> from sympy import sqrt >>> t.bisectors()[p2] == Segment(Point(1, 0), Point(0, sqrt(2) - 1)) True """ # use lines containing sides so containment check during # intersection calculation can be avoided, thus reducing # the processing time for calculating the bisectors s = [Line(l) for l in self.sides] v = self.vertices c = self.incenter l1 = Segment(v[0], Line(v[0], c).intersection(s[1])[0]) l2 = Segment(v[1], Line(v[1], c).intersection(s[2])[0]) l3 = Segment(v[2], Line(v[2], c).intersection(s[0])[0]) return {v[0]: l1, v[1]: l2, v[2]: l3} @property def incenter(self): """The center of the incircle. The incircle is the circle which lies inside the triangle and touches all three sides. Returns ======= incenter : Point See Also ======== incircle, sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.incenter Point2D(1 - sqrt(2)/2, 1 - sqrt(2)/2) """ s = self.sides l = Matrix([s[i].length for i in [1, 2, 0]]) p = sum(l) v = self.vertices x = simplify(l.dot(Matrix([vi.x for vi in v]))/p) y = simplify(l.dot(Matrix([vi.y for vi in v]))/p) return Point(x, y) @property def inradius(self): """The radius of the incircle. Returns ======= inradius : number of Basic instance See Also ======== incircle, sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(4, 0), Point(0, 3) >>> t = Triangle(p1, p2, p3) >>> t.inradius 1 """ return simplify(2 self.area / self.perimeter) @property def incircle(self): """The incircle of the triangle. The incircle is the circle which lies inside the triangle and touches all three sides. Returns ======= incircle : Circle See Also ======== sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(2, 0), Point(0, 2) >>> t = Triangle(p1, p2, p3) >>> t.incircle Circle(Point2D(2 - sqrt(2), 2 - sqrt(2)), 2 - sqrt(2)) """ return Circle(self.incenter, self.inradius) @property def exradii(self): """The radius of excircles of a triangle. An excircle of the triangle is a circle lying outside the triangle, tangent to one of its sides and tangent to the extensions of the other two. Returns ======= exradii : dict See Also ======== sympy.geometry.polygon.Triangle.inradius Examples ======== The exradius touches the side of the triangle to which it is keyed, e.g. the exradius touching side 2 is: >>> from sympy.geometry import Point, Triangle, Segment2D, Point2D >>> p1, p2, p3 = Point(0, 0), Point(6, 0), Point(0, 2) >>> t = Triangle(p1, p2, p3) >>> t.exradii[t.sides[2]] -2 + sqrt(10) References ========== [1] http://mathworld.wolfram.com/Exradius.html [2] http://mathworld.wolfram.com/Excircles.html """ side = self.sides a = side[0].length b = side[1].length c = side[2].length s = (a+b+c)/2 area = self.area exradii = {self.sides[0]: simplify(area/(s-a)), self.sides[1]: simplify(area/(s-b)), self.sides[2]: simplify(area/(s-c))} return exradii @property def medians(self): """The medians of the triangle. A median of a triangle is a straight line through a vertex and the midpoint of the opposite side, and divides the triangle into two equal areas. Returns ======= medians : dict Each key is a vertex (Point) and each value is the median (Segment) at that point. See Also ======== sympy.geometry.point.Point.midpoint, sympy.geometry.line.Segment.midpoint Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.medians[p1] Segment2D(Point2D(0, 0), Point2D(1/2, 1/2)) """ s = self.sides v = self.vertices return {v[0]: Segment(v[0], s[1].midpoint), v[1]: Segment(v[1], s[2].midpoint), v[2]: Segment(v[2], s[0].midpoint)} @property def medial(self): """The medial triangle of the triangle. The triangle which is formed from the midpoints of the three sides. Returns ======= medial : Triangle See Also ======== sympy.geometry.line.Segment.midpoint Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.medial Triangle(Point2D(1/2, 0), Point2D(1/2, 1/2), Point2D(0, 1/2)) """ s = self.sides return Triangle(s[0].midpoint, s[1].midpoint, s[2].midpoint) @property def nine_point_circle(self): """The nine-point circle of the triangle. Nine-point circle is the circumcircle of the medial triangle, which passes through the feet of altitudes and the middle points of segments connecting the vertices and the orthocenter. Returns ======= nine_point_circle : Circle See also ======== sympy.geometry.line.Segment.midpoint sympy.geometry.polygon.Triangle.medial sympy.geometry.polygon.Triangle.orthocenter Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.nine_point_circle Circle(Point2D(1/4, 1/4), sqrt(2)/4) """ return Circle(self.medial.vertices) @property def eulerline(self): """The Euler line of the triangle. The line which passes through circumcenter, centroid and orthocenter. Returns ======= eulerline : Line (or Point for equilateral triangles in which case all centers coincide) Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.eulerline Line2D(Point2D(0, 0), Point2D(1/2, 1/2)) """ if self.is_equilateral(): return self.orthocenter return Line(self.orthocenter, self.circumcenter) def rad(d): """Return the radian value for the given degrees (pi = 180 degrees).""" return dpi/180 def deg(r): """Return the degree value for the given radians (pi = 180 degrees).""" return r/pi180 def _slope(d): rv = tan(rad(d)) return rv def _asa(d1, l, d2): """Return triangle having side with length l on the x-axis.""" xy = Line((0, 0), slope=_slope(d1)).intersection( Line((l, 0), slope=_slope(180 - d2)))[0] return Triangle((0, 0), (l, 0), xy) def _sss(l1, l2, l3): """Return triangle having side of length l1 on the x-axis.""" c1 = Circle((0, 0), l3) c2 = Circle((l1, 0), l2) inter = [a for a in c1.intersection(c2) if a.y.is_nonnegative] if not inter: return None pt = inter[0] return Triangle((0, 0), (l1, 0), pt) def _sas(l1, d, l2): """Return triangle having side with length l2 on the x-axis.""" p1 = Point(0, 0) p2 = Point(l2, 0) p3 = Point(cos(rad(d))l1, sin(rad(d))*l1) return Triangle(p1, p2, p3)
c99424988fba32cb118bcfe4392c4113b978555a598b898acf45387c94e2c5b6	"""Transform a string with Python-like source code into SymPy expression. """ from __future__ import print_function, division from tokenize import (generate_tokens, untokenize, TokenError, NUMBER, STRING, NAME, OP, ENDMARKER, ERRORTOKEN, NEWLINE) from keyword import iskeyword import ast import unicodedata from sympy.core.compatibility import exec_, StringIO, iterable from sympy.core.basic import Basic from sympy.core import Symbol from sympy.core.function import arity from sympy.utilities.misc import filldedent, func_name def _token_splittable(token): """ Predicate for whether a token name can be split into multiple tokens. A token is splittable if it does not contain an underscore character and it is not the name of a Greek letter. This is used to implicitly convert expressions like 'xyz' into 'xyz'. """ if '_' in token: return False else: try: return not unicodedata.lookup('GREEK SMALL LETTER ' + token) except KeyError: pass if len(token) > 1: return True return False def _token_callable(token, local_dict, global_dict, nextToken=None): """ Predicate for whether a token name represents a callable function. Essentially wraps ``callable``, but looks up the token name in the locals and globals. """ func = local_dict.get(token[1]) if not func: func = global_dict.get(token[1]) return callable(func) and not isinstance(func, Symbol) def _add_factorial_tokens(name, result): if result == [] or result[-1][1] == '(': raise TokenError() beginning = [(NAME, name), (OP, '(')] end = [(OP, ')')] diff = 0 length = len(result) for index, token in enumerate(result[::-1]): toknum, tokval = token i = length - index - 1 if tokval == ')': diff += 1 elif tokval == '(': diff -= 1 if diff == 0: if i - 1 >= 0 and result[i - 1][0] == NAME: return result[:i - 1] + beginning + result[i - 1:] + end else: return result[:i] + beginning + result[i:] + end return result class AppliedFunction(object): """ A group of tokens representing a function and its arguments. `exponent` is for handling the shorthand sin^2, ln^2, etc. """ def __init__(self, function, args, exponent=None): if exponent is None: exponent = [] self.function = function self.args = args self.exponent = exponent self.items = ['function', 'args', 'exponent'] def expand(self): """Return a list of tokens representing the function""" result = [] result.append(self.function) result.extend(self.args) return result def __getitem__(self, index): return getattr(self, self.items[index]) def __repr__(self): return "AppliedFunction(%s, %s, %s)" % (self.function, self.args, self.exponent) class ParenthesisGroup(list): """List of tokens representing an expression in parentheses.""" pass def _flatten(result): result2 = [] for tok in result: if isinstance(tok, AppliedFunction): result2.extend(tok.expand()) else: result2.append(tok) return result2 def _group_parentheses(recursor): def _inner(tokens, local_dict, global_dict): """Group tokens between parentheses with ParenthesisGroup. Also processes those tokens recursively. """ result = [] stacks = [] stacklevel = 0 for token in tokens: if token[0] == OP: if token[1] == '(': stacks.append(ParenthesisGroup([])) stacklevel += 1 elif token[1] == ')': stacks[-1].append(token) stack = stacks.pop() if len(stacks) > 0: # We don't recurse here since the upper-level stack # would reprocess these tokens stacks[-1].extend(stack) else: # Recurse here to handle nested parentheses # Strip off the outer parentheses to avoid an infinite loop inner = stack[1:-1] inner = recursor(inner, local_dict, global_dict) parenGroup = [stack[0]] + inner + [stack[-1]] result.append(ParenthesisGroup(parenGroup)) stacklevel -= 1 continue if stacklevel: stacks[-1].append(token) else: result.append(token) if stacklevel: raise TokenError("Mismatched parentheses") return result return _inner def _apply_functions(tokens, local_dict, global_dict): """Convert a NAME token + ParenthesisGroup into an AppliedFunction. Note that ParenthesisGroups, if not applied to any function, are converted back into lists of tokens. """ result = [] symbol = None for tok in tokens: if tok[0] == NAME: symbol = tok result.append(tok) elif isinstance(tok, ParenthesisGroup): if symbol and _token_callable(symbol, local_dict, global_dict): result[-1] = AppliedFunction(symbol, tok) symbol = None else: result.extend(tok) else: symbol = None result.append(tok) return result def _implicit_multiplication(tokens, local_dict, global_dict): """Implicitly adds '' tokens. Cases: - Two AppliedFunctions next to each other ("sin(x)cos(x)") - AppliedFunction next to an open parenthesis ("sin x (cos x + 1)") - A close parenthesis next to an AppliedFunction ("(x+2)sin x")\ - A close parenthesis next to an open parenthesis ("(x+2)(x+3)") - AppliedFunction next to an implicitly applied function ("sin(x)cos x") """ result = [] for tok, nextTok in zip(tokens, tokens[1:]): result.append(tok) if (isinstance(tok, AppliedFunction) and isinstance(nextTok, AppliedFunction)): result.append((OP, '')) elif (isinstance(tok, AppliedFunction) and nextTok[0] == OP and nextTok[1] == '('): # Applied function followed by an open parenthesis if tok.function[1] == "Function": result[-1].function = (result[-1].function[0], 'Symbol') result.append((OP, '')) elif (tok[0] == OP and tok[1] == ')' and isinstance(nextTok, AppliedFunction)): # Close parenthesis followed by an applied function result.append((OP, '')) elif (tok[0] == OP and tok[1] == ')' and nextTok[0] == NAME): # Close parenthesis followed by an implicitly applied function result.append((OP, '')) elif (tok[0] == nextTok[0] == OP and tok[1] == ')' and nextTok[1] == '('): # Close parenthesis followed by an open parenthesis result.append((OP, '')) elif (isinstance(tok, AppliedFunction) and nextTok[0] == NAME): # Applied function followed by implicitly applied function result.append((OP, '')) elif (tok[0] == NAME and not _token_callable(tok, local_dict, global_dict) and nextTok[0] == OP and nextTok[1] == '('): # Constant followed by parenthesis result.append((OP, '')) elif (tok[0] == NAME and not _token_callable(tok, local_dict, global_dict) and nextTok[0] == NAME and not _token_callable(nextTok, local_dict, global_dict)): # Constant followed by constant result.append((OP, '')) elif (tok[0] == NAME and not _token_callable(tok, local_dict, global_dict) and (isinstance(nextTok, AppliedFunction) or nextTok[0] == NAME)): # Constant followed by (implicitly applied) function result.append((OP, '')) if tokens: result.append(tokens[-1]) return result def _implicit_application(tokens, local_dict, global_dict): """Adds parentheses as needed after functions.""" result = [] appendParen = 0 # number of closing parentheses to add skip = 0 # number of tokens to delay before adding a ')' (to # capture , ^, etc.) exponentSkip = False # skipping tokens before inserting parentheses to # work with function exponentiation for tok, nextTok in zip(tokens, tokens[1:]): result.append(tok) if (tok[0] == NAME and nextTok[0] not in [OP, ENDMARKER, NEWLINE]): if _token_callable(tok, local_dict, global_dict, nextTok): result.append((OP, '(')) appendParen += 1 # name followed by exponent - function exponentiation elif (tok[0] == NAME and nextTok[0] == OP and nextTok[1] == ''): if _token_callable(tok, local_dict, global_dict): exponentSkip = True elif exponentSkip: # if the last token added was an applied function (i.e. the # power of the function exponent) OR a multiplication (as # implicit multiplication would have added an extraneous # multiplication) if (isinstance(tok, AppliedFunction) or (tok[0] == OP and tok[1] == '')): # don't add anything if the next token is a multiplication # or if there's already a parenthesis (if parenthesis, still # stop skipping tokens) if not (nextTok[0] == OP and nextTok[1] == ''): if not(nextTok[0] == OP and nextTok[1] == '('): result.append((OP, '(')) appendParen += 1 exponentSkip = False elif appendParen: if nextTok[0] == OP and nextTok[1] in ('^', '*', ''): skip = 1 continue if skip: skip -= 1 continue result.append((OP, ')')) appendParen -= 1 if tokens: result.append(tokens[-1]) if appendParen: result.extend([(OP, ')')] * appendParen) return result def function_exponentiation(tokens, local_dict, global_dict): """Allows functions to be exponentiated, e.g. ``cos2(x)``. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, function_exponentiation) >>> transformations = standard_transformations + (function_exponentiation,) >>> parse_expr('sin4(x)', transformations=transformations) sin(x)4 """ result = [] exponent = [] consuming_exponent = False level = 0 for tok, nextTok in zip(tokens, tokens[1:]): if tok[0] == NAME and nextTok[0] == OP and nextTok[1] == '': if _token_callable(tok, local_dict, global_dict): consuming_exponent = True elif consuming_exponent: if tok[0] == NAME and tok[1] == 'Function': tok = (NAME, 'Symbol') exponent.append(tok) # only want to stop after hitting ) if tok[0] == nextTok[0] == OP and tok[1] == ')' and nextTok[1] == '(': consuming_exponent = False # if implicit multiplication was used, we may have )( instead if tok[0] == nextTok[0] == OP and tok[1] == '' and nextTok[1] == '(': consuming_exponent = False del exponent[-1] continue elif exponent and not consuming_exponent: if tok[0] == OP: if tok[1] == '(': level += 1 elif tok[1] == ')': level -= 1 if level == 0: result.append(tok) result.extend(exponent) exponent = [] continue result.append(tok) if tokens: result.append(tokens[-1]) if exponent: result.extend(exponent) return result def split_symbols_custom(predicate): """Creates a transformation that splits symbol names. ``predicate`` should return True if the symbol name is to be split. For instance, to retain the default behavior but avoid splitting certain symbol names, a predicate like this would work: >>> from sympy.parsing.sympy_parser import (parse_expr, _token_splittable, ... standard_transformations, implicit_multiplication, ... split_symbols_custom) >>> def can_split(symbol): ... if symbol not in ('list', 'of', 'unsplittable', 'names'): ... return _token_splittable(symbol) ... return False ... >>> transformation = split_symbols_custom(can_split) >>> parse_expr('unsplittable', transformations=standard_transformations + ... (transformation, implicit_multiplication)) unsplittable """ def _split_symbols(tokens, local_dict, global_dict): result = [] split = False split_previous=False for tok in tokens: if split_previous: # throw out closing parenthesis of Symbol that was split split_previous=False continue split_previous=False if tok[0] == NAME and tok[1] in ['Symbol', 'Function']: split = True elif split and tok[0] == NAME: symbol = tok[1][1:-1] if predicate(symbol): tok_type = result[-2][1] # Symbol or Function del result[-2:] # Get rid of the call to Symbol i = 0 while i < len(symbol): char = symbol[i] if char in local_dict or char in global_dict: result.extend([(NAME, "%s" % char)]) elif char.isdigit(): char = [char] for i in range(i + 1, len(symbol)): if not symbol[i].isdigit(): i -= 1 break char.append(symbol[i]) char = ''.join(char) result.extend([(NAME, 'Number'), (OP, '('), (NAME, "'%s'" % char), (OP, ')')]) else: use = tok_type if i == len(symbol) else 'Symbol' result.extend([(NAME, use), (OP, '('), (NAME, "'%s'" % char), (OP, ')')]) i += 1 # Set split_previous=True so will skip # the closing parenthesis of the original Symbol split = False split_previous = True continue else: split = False result.append(tok) return result return _split_symbols #: Splits symbol names for implicit multiplication. #: #: Intended to let expressions like ``xyz`` be parsed as ``xyz``. Does not #: split Greek character names, so ``theta`` will not become #: ``theta``. Generally this should be used with #: ``implicit_multiplication``. split_symbols = split_symbols_custom(_token_splittable) def implicit_multiplication(result, local_dict, global_dict): """Makes the multiplication operator optional in most cases. Use this before :func:`implicit_application`, otherwise expressions like ``sin 2x`` will be parsed as ``x * sin(2)`` rather than ``sin(2x)``. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, implicit_multiplication) >>> transformations = standard_transformations + (implicit_multiplication,) >>> parse_expr('3 x y', transformations=transformations) 3xy """ # These are interdependent steps, so we don't expose them separately for step in (_group_parentheses(implicit_multiplication), _apply_functions, _implicit_multiplication): result = step(result, local_dict, global_dict) result = _flatten(result) return result def implicit_application(result, local_dict, global_dict): """Makes parentheses optional in some cases for function calls. Use this after :func:`implicit_multiplication`, otherwise expressions like ``sin 2x`` will be parsed as ``x sin(2)`` rather than ``sin(2x)``. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, implicit_application) >>> transformations = standard_transformations + (implicit_application,) >>> parse_expr('cot z + csc z', transformations=transformations) cot(z) + csc(z) """ for step in (_group_parentheses(implicit_application), _apply_functions, _implicit_application,): result = step(result, local_dict, global_dict) result = _flatten(result) return result def implicit_multiplication_application(result, local_dict, global_dict): """Allows a slightly relaxed syntax. - Parentheses for single-argument method calls are optional. - Multiplication is implicit. - Symbol names can be split (i.e. spaces are not needed between symbols). - Functions can be exponentiated. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, implicit_multiplication_application) >>> parse_expr("10sin2 x2 + 3xyz + tan theta", ... transformations=(standard_transformations + ... (implicit_multiplication_application,))) 3xyz + 10sin(x2)2 + tan(theta) """ for step in (split_symbols, implicit_multiplication, implicit_application, function_exponentiation): result = step(result, local_dict, global_dict) return result def auto_symbol(tokens, local_dict, global_dict): """Inserts calls to ``Symbol``/``Function`` for undefined variables.""" result = [] prevTok = (None, None) tokens.append((None, None)) # so zip traverses all tokens for tok, nextTok in zip(tokens, tokens[1:]): tokNum, tokVal = tok nextTokNum, nextTokVal = nextTok if tokNum == NAME: name = tokVal if (name in ['True', 'False', 'None'] or iskeyword(name) # Don't convert attribute access or (prevTok[0] == OP and prevTok[1] == '.') # Don't convert keyword arguments or (prevTok[0] == OP and prevTok[1] in ('(', ',') and nextTokNum == OP and nextTokVal == '=')): result.append((NAME, name)) continue elif name in local_dict: if isinstance(local_dict[name], Symbol) and nextTokVal == '(': result.extend([(NAME, 'Function'), (OP, '('), (NAME, repr(str(local_dict[name]))), (OP, ')')]) else: result.append((NAME, name)) continue elif name in global_dict: obj = global_dict[name] if isinstance(obj, (Basic, type)) or callable(obj): result.append((NAME, name)) continue result.extend([ (NAME, 'Symbol' if nextTokVal != '(' else 'Function'), (OP, '('), (NAME, repr(str(name))), (OP, ')'), ]) else: result.append((tokNum, tokVal)) prevTok = (tokNum, tokVal) return result def lambda_notation(tokens, local_dict, global_dict): """Substitutes "lambda" with its Sympy equivalent Lambda(). However, the conversion doesn't take place if only "lambda" is passed because that is a syntax error. """ result = [] flag = False toknum, tokval = tokens[0] tokLen = len(tokens) if toknum == NAME and tokval == 'lambda': if tokLen == 2 or tokLen == 3 and tokens[1][0] == NEWLINE: # In Python 3.6.7+, inputs without a newline get NEWLINE added to # the tokens result.extend(tokens) elif tokLen > 2: result.extend([ (NAME, 'Lambda'), (OP, '('), (OP, '('), (OP, ')'), (OP, ')'), ]) for tokNum, tokVal in tokens[1:]: if tokNum == OP and tokVal == ':': tokVal = ',' flag = True if not flag and tokNum == OP and tokVal in ['', '']: raise TokenError("Starred arguments in lambda not supported") if flag: result.insert(-1, (tokNum, tokVal)) else: result.insert(-2, (tokNum, tokVal)) else: result.extend(tokens) return result def factorial_notation(tokens, local_dict, global_dict): """Allows standard notation for factorial.""" result = [] nfactorial = 0 for toknum, tokval in tokens: if toknum == ERRORTOKEN: op = tokval if op == '!': nfactorial += 1 else: nfactorial = 0 result.append((OP, op)) else: if nfactorial == 1: result = _add_factorial_tokens('factorial', result) elif nfactorial == 2: result = _add_factorial_tokens('factorial2', result) elif nfactorial > 2: raise TokenError nfactorial = 0 result.append((toknum, tokval)) return result def convert_xor(tokens, local_dict, global_dict): """Treats XOR, ``^``, as exponentiation, ````.""" result = [] for toknum, tokval in tokens: if toknum == OP: if tokval == '^': result.append((OP, '*')) else: result.append((toknum, tokval)) else: result.append((toknum, tokval)) return result def repeated_decimals(tokens, local_dict, global_dict): """ Allows 0.2[1] notation to represent the repeated decimal 0.2111... (19/90) Run this before auto_number. """ result = [] def is_digit(s): return all(i in '0123456789_' for i in s) # num will running match any DECIMAL [ INTEGER ] num = [] for toknum, tokval in tokens: if toknum == NUMBER: if (not num and '.' in tokval and 'e' not in tokval.lower() and 'j' not in tokval.lower()): num.append((toknum, tokval)) elif is_digit(tokval)and len(num) == 2: num.append((toknum, tokval)) elif is_digit(tokval) and len(num) == 3 and is_digit(num[-1][1]): # Python 2 tokenizes 00123 as '00', '123' # Python 3 tokenizes 01289 as '012', '89' num.append((toknum, tokval)) else: num = [] elif toknum == OP: if tokval == '[' and len(num) == 1: num.append((OP, tokval)) elif tokval == ']' and len(num) >= 3: num.append((OP, tokval)) elif tokval == '.' and not num: # handle .[1] num.append((NUMBER, '0.')) else: num = [] else: num = [] result.append((toknum, tokval)) if num and num[-1][1] == ']': # pre.post[repetend] = a + b/c + d/e where a = pre, b/c = post, # and d/e = repetend result = result[:-len(num)] pre, post = num[0][1].split('.') repetend = num[2][1] if len(num) == 5: repetend += num[3][1] pre = pre.replace('_', '') post = post.replace('_', '') repetend = repetend.replace('_', '') zeros = '0'len(post) post, repetends = [w.lstrip('0') for w in [post, repetend]] # or else interpreted as octal a = pre or '0' b, c = post or '0', '1' + zeros d, e = repetends, ('9'len(repetend)) + zeros seq = [ (OP, '('), (NAME, 'Integer'), (OP, '('), (NUMBER, a), (OP, ')'), (OP, '+'), (NAME, 'Rational'), (OP, '('), (NUMBER, b), (OP, ','), (NUMBER, c), (OP, ')'), (OP, '+'), (NAME, 'Rational'), (OP, '('), (NUMBER, d), (OP, ','), (NUMBER, e), (OP, ')'), (OP, ')'), ] result.extend(seq) num = [] return result def auto_number(tokens, local_dict, global_dict): """ Converts numeric literals to use SymPy equivalents. Complex numbers use ``I``, integer literals use ``Integer``, and float literals use ``Float``. """ result = [] for toknum, tokval in tokens: if toknum == NUMBER: number = tokval postfix = [] if number.endswith('j') or number.endswith('J'): number = number[:-1] postfix = [(OP, ''), (NAME, 'I')] if '.' in number or (('e' in number or 'E' in number) and not (number.startswith('0x') or number.startswith('0X'))): seq = [(NAME, 'Float'), (OP, '('), (NUMBER, repr(str(number))), (OP, ')')] else: seq = [(NAME, 'Integer'), (OP, '('), ( NUMBER, number), (OP, ')')] result.extend(seq + postfix) else: result.append((toknum, tokval)) return result def rationalize(tokens, local_dict, global_dict): """Converts floats into ``Rational``. Run AFTER ``auto_number``.""" result = [] passed_float = False for toknum, tokval in tokens: if toknum == NAME: if tokval == 'Float': passed_float = True tokval = 'Rational' result.append((toknum, tokval)) elif passed_float == True and toknum == NUMBER: passed_float = False result.append((STRING, tokval)) else: result.append((toknum, tokval)) return result def _transform_equals_sign(tokens, local_dict, global_dict): """Transforms the equals sign ``=`` to instances of Eq. This is a helper function for `convert_equals_signs`. Works with expressions containing one equals sign and no nesting. Expressions like `(1=2)=False` won't work with this and should be used with `convert_equals_signs`. Examples: 1=2 to Eq(1,2) 12=x to Eq(12, x) This does not deal with function arguments yet. """ result = [] if (OP, "=") in tokens: result.append((NAME, "Eq")) result.append((OP, "(")) for index, token in enumerate(tokens): if token == (OP, "="): result.append((OP, ",")) continue result.append(token) result.append((OP, ")")) else: result = tokens return result def convert_equals_signs(result, local_dict, global_dict): """ Transforms all the equals signs ``=`` to instances of Eq. Parses the equals signs in the expression and replaces them with appropriate Eq instances.Also works with nested equals signs. Does not yet play well with function arguments. For example, the expression `(x=y)` is ambiguous and can be interpreted as x being an argument to a function and `convert_equals_signs` won't work for this. See also ======== convert_equality_operators Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, convert_equals_signs) >>> parse_expr("12=x", transformations=( ... standard_transformations + (convert_equals_signs,))) Eq(2, x) >>> parse_expr("(12=x)=False", transformations=( ... standard_transformations + (convert_equals_signs,))) Eq(Eq(2, x), False) """ for step in (_group_parentheses(convert_equals_signs), _apply_functions, _transform_equals_sign): result = step(result, local_dict, global_dict) result = _flatten(result) return result #: Standard transformations for :func:`parse_expr`. #: Inserts calls to :class:`Symbol`, :class:`Integer`, and other SymPy #: datatypes and allows the use of standard factorial notation (e.g. ``x!``). standard_transformations = (lambda_notation, auto_symbol, repeated_decimals, auto_number, factorial_notation) def stringify_expr(s, local_dict, global_dict, transformations): """ Converts the string ``s`` to Python code, in ``local_dict`` Generally, ``parse_expr`` should be used. """ tokens = [] input_code = StringIO(s.strip()) for toknum, tokval, _, _, _ in generate_tokens(input_code.readline): tokens.append((toknum, tokval)) for transform in transformations: tokens = transform(tokens, local_dict, global_dict) return untokenize(tokens) def eval_expr(code, local_dict, global_dict): """ Evaluate Python code generated by ``stringify_expr``. Generally, ``parse_expr`` should be used. """ expr = eval( code, global_dict, local_dict) # take local objects in preference return expr def parse_expr(s, local_dict=None, transformations=standard_transformations, global_dict=None, evaluate=True): """Converts the string ``s`` to a SymPy expression, in ``local_dict`` Parameters ========== s : str The string to parse. local_dict : dict, optional A dictionary of local variables to use when parsing. global_dict : dict, optional A dictionary of global variables. By default, this is initialized with ``from sympy import ``; provide this parameter to override this behavior (for instance, to parse ``"Q & S"``). transformations : tuple, optional A tuple of transformation functions used to modify the tokens of the parsed expression before evaluation. The default transformations convert numeric literals into their SymPy equivalents, convert undefined variables into SymPy symbols, and allow the use of standard mathematical factorial notation (e.g. ``x!``). evaluate : bool, optional When False, the order of the arguments will remain as they were in the string and automatic simplification that would normally occur is suppressed. (see examples) Examples ======== >>> from sympy.parsing.sympy_parser import parse_expr >>> parse_expr("1/2") 1/2 >>> type(_) <class 'sympy.core.numbers.Half'> >>> from sympy.parsing.sympy_parser import standard_transformations,\\ ... implicit_multiplication_application >>> transformations = (standard_transformations + ... (implicit_multiplication_application,)) >>> parse_expr("2x", transformations=transformations) 2x When evaluate=False, some automatic simplifications will not occur: >>> parse_expr("23"), parse_expr("23", evaluate=False) (8, 2*3) In addition the order of the arguments will not be made canonical. This feature allows one to tell exactly how the expression was entered: >>> a = parse_expr('1 + x', evaluate=False) >>> b = parse_expr('x + 1', evaluate=0) >>> a == b False >>> a.args (1, x) >>> b.args (x, 1) See Also ======== stringify_expr, eval_expr, standard_transformations, implicit_multiplication_application """ if local_dict is None: local_dict = {} elif not isinstance(local_dict, dict): raise TypeError('expecting local_dict to be a dict') if global_dict is None: global_dict = {} exec_('from sympy import ', global_dict) elif not isinstance(global_dict, dict): raise TypeError('expecting global_dict to be a dict') transformations = transformations or () if transformations: if not iterable(transformations): raise TypeError( '`transformations` should be a list of functions.') for _ in transformations: if not callable(_): raise TypeError(filldedent(''' expected a function in `transformations`, not %s''' % func_name(_))) if arity(_) != 3: raise TypeError(filldedent(''' a transformation should be function that takes 3 arguments''')) code = stringify_expr(s, local_dict, global_dict, transformations) if not evaluate: code = compile(evaluateFalse(code), '<string>', 'eval') return eval_expr(code, local_dict, global_dict) def evaluateFalse(s): """ Replaces operators with the SymPy equivalent and sets evaluate=False. """ node = ast.parse(s) node = EvaluateFalseTransformer().visit(node) # node is a Module, we want an Expression node = ast.Expression(node.body[0].value) return ast.fix_missing_locations(node) class EvaluateFalseTransformer(ast.NodeTransformer): operators = { ast.Add: 'Add', ast.Mult: 'Mul', ast.Pow: 'Pow', ast.Sub: 'Add', ast.Div: 'Mul', ast.BitOr: 'Or', ast.BitAnd: 'And', ast.BitXor: 'Not', } def flatten(self, args, func): result = [] for arg in args: if isinstance(arg, ast.Call) and arg.func.id == func: result.extend(self.flatten(arg.args, func)) else: result.append(arg) return result def visit_BinOp(self, node): if node.op.__class__ in self.operators: sympy_class = self.operators[node.op.__class__] right = self.visit(node.right) left = self.visit(node.left) if isinstance(node.left, ast.UnaryOp) and (isinstance(node.right, ast.UnaryOp) == 0) and sympy_class in ('Mul',): left, right = right, left if isinstance(node.op, ast.Sub): right = ast.Call( func=ast.Name(id='Mul', ctx=ast.Load()), args=[ast.UnaryOp(op=ast.USub(), operand=ast.Num(1)), right], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) if isinstance(node.op, ast.Div): if isinstance(node.left, ast.UnaryOp): if isinstance(node.right,ast.UnaryOp): left, right = right, left left = ast.Call( func=ast.Name(id='Pow', ctx=ast.Load()), args=[left, ast.UnaryOp(op=ast.USub(), operand=ast.Num(1))], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) else: right = ast.Call( func=ast.Name(id='Pow', ctx=ast.Load()), args=[right, ast.UnaryOp(op=ast.USub(), operand=ast.Num(1))], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) new_node = ast.Call( func=ast.Name(id=sympy_class, ctx=ast.Load()), args=[left, right], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) if sympy_class in ('Add', 'Mul'): # Denest Add or Mul as appropriate new_node.args = self.flatten(new_node.args, sympy_class) return new_node return node
f774726144584e5c84d33d2262d34fe1d3924b84b7c906edc31bca6ac6a62107	r"""Module that defines indexed objects The classes ``IndexedBase``, ``Indexed``, and ``Idx`` represent a matrix element ``M[i, j]`` as in the following diagram:: 1) The Indexed class represents the entire indexed object. \| ___\|___ ' ' M[i, j] / \__\______ \| \| \| \| \| 2) The Idx class represents indices; each Idx can \| optionally contain information about its range. \| 3) IndexedBase represents the 'stem' of an indexed object, here `M`. The stem used by itself is usually taken to represent the entire array. There can be any number of indices on an Indexed object. No transformation properties are implemented in these Base objects, but implicit contraction of repeated indices is supported. Note that the support for complicated (i.e. non-atomic) integer expressions as indices is limited. (This should be improved in future releases.) Examples ======== To express the above matrix element example you would write: >>> from sympy import symbols, IndexedBase, Idx >>> M = IndexedBase('M') >>> i, j = symbols('i j', cls=Idx) >>> M[i, j] M[i, j] Repeated indices in a product implies a summation, so to express a matrix-vector product in terms of Indexed objects: >>> x = IndexedBase('x') >>> M[i, j]x[j] M[i, j]x[j] If the indexed objects will be converted to component based arrays, e.g. with the code printers or the autowrap framework, you also need to provide (symbolic or numerical) dimensions. This can be done by passing an optional shape parameter to IndexedBase upon construction: >>> dim1, dim2 = symbols('dim1 dim2', integer=True) >>> A = IndexedBase('A', shape=(dim1, 2dim1, dim2)) >>> A.shape (dim1, 2dim1, dim2) >>> A[i, j, 3].shape (dim1, 2dim1, dim2) If an IndexedBase object has no shape information, it is assumed that the array is as large as the ranges of its indices: >>> n, m = symbols('n m', integer=True) >>> i = Idx('i', m) >>> j = Idx('j', n) >>> M[i, j].shape (m, n) >>> M[i, j].ranges [(0, m - 1), (0, n - 1)] The above can be compared with the following: >>> A[i, 2, j].shape (dim1, 2dim1, dim2) >>> A[i, 2, j].ranges [(0, m - 1), None, (0, n - 1)] To analyze the structure of indexed expressions, you can use the methods get_indices() and get_contraction_structure(): >>> from sympy.tensor import get_indices, get_contraction_structure >>> get_indices(A[i, j, j]) ({i}, {}) >>> get_contraction_structure(A[i, j, j]) {(j,): {A[i, j, j]}} See the appropriate docstrings for a detailed explanation of the output. """ # TODO: (some ideas for improvement) # # o test and guarantee numpy compatibility # - implement full support for broadcasting # - strided arrays # # o more functions to analyze indexed expressions # - identify standard constructs, e.g matrix-vector product in a subexpression # # o functions to generate component based arrays (numpy and sympy.Matrix) # - generate a single array directly from Indexed # - convert simple sub-expressions # # o sophisticated indexing (possibly in subclasses to preserve simplicity) # - Idx with range smaller than dimension of Indexed # - Idx with stepsize != 1 # - Idx with step determined by function call from __future__ import print_function, division from sympy.core import Expr, Tuple, Symbol, sympify, S from sympy.core.compatibility import (is_sequence, string_types, NotIterable, Iterable) from sympy.core.sympify import _sympify from sympy.functions.special.tensor_functions import KroneckerDelta class IndexException(Exception): pass class Indexed(Expr): """Represents a mathematical object with indices. >>> from sympy import Indexed, IndexedBase, Idx, symbols >>> i, j = symbols('i j', cls=Idx) >>> Indexed('A', i, j) A[i, j] It is recommended that ``Indexed`` objects be created via ``IndexedBase``: >>> A = IndexedBase('A') >>> Indexed('A', i, j) == A[i, j] True """ is_commutative = True is_Indexed = True is_symbol = True is_Atom = True def __new__(cls, base, args, kw_args): from sympy.utilities.misc import filldedent from sympy.tensor.array.ndim_array import NDimArray from sympy.matrices.matrices import MatrixBase if not args: raise IndexException("Indexed needs at least one index.") if isinstance(base, (string_types, Symbol)): base = IndexedBase(base) elif not hasattr(base, '__getitem__') and not isinstance(base, IndexedBase): raise TypeError(filldedent(""" Indexed expects string, Symbol, or IndexedBase as base.""")) args = list(map(sympify, args)) if isinstance(base, (NDimArray, Iterable, Tuple, MatrixBase)) and all([i.is_number for i in args]): if len(args) == 1: return base[args[0]] else: return base[args] return Expr.__new__(cls, base, args, *kw_args) @property def name(self): return str(self) @property def _diff_wrt(self): """Allow derivatives with respect to an ``Indexed`` object.""" return True def _eval_derivative(self, wrt): from sympy.tensor.array.ndim_array import NDimArray if isinstance(wrt, Indexed) and wrt.base == self.base: if len(self.indices) != len(wrt.indices): msg = "Different # of indices: d({!s})/d({!s})".format(self, wrt) raise IndexException(msg) result = S.One for index1, index2 in zip(self.indices, wrt.indices): result = KroneckerDelta(index1, index2) return result elif isinstance(self.base, NDimArray): from sympy.tensor.array import derive_by_array return Indexed(derive_by_array(self.base, wrt), self.args[1:]) else: if Tuple(self.indices).has(wrt): return S.NaN return S.Zero @property def base(self): """Returns the ``IndexedBase`` of the ``Indexed`` object. Examples ======== >>> from sympy import Indexed, IndexedBase, Idx, symbols >>> i, j = symbols('i j', cls=Idx) >>> Indexed('A', i, j).base A >>> B = IndexedBase('B') >>> B == B[i, j].base True """ return self.args[0] @property def indices(self): """ Returns the indices of the ``Indexed`` object. Examples ======== >>> from sympy import Indexed, Idx, symbols >>> i, j = symbols('i j', cls=Idx) >>> Indexed('A', i, j).indices (i, j) """ return self.args[1:] @property def rank(self): """ Returns the rank of the ``Indexed`` object. Examples ======== >>> from sympy import Indexed, Idx, symbols >>> i, j, k, l, m = symbols('i:m', cls=Idx) >>> Indexed('A', i, j).rank 2 >>> q = Indexed('A', i, j, k, l, m) >>> q.rank 5 >>> q.rank == len(q.indices) True """ return len(self.args) - 1 @property def shape(self): """Returns a list with dimensions of each index. Dimensions is a property of the array, not of the indices. Still, if the ``IndexedBase`` does not define a shape attribute, it is assumed that the ranges of the indices correspond to the shape of the array. >>> from sympy import IndexedBase, Idx, symbols >>> n, m = symbols('n m', integer=True) >>> i = Idx('i', m) >>> j = Idx('j', m) >>> A = IndexedBase('A', shape=(n, n)) >>> B = IndexedBase('B') >>> A[i, j].shape (n, n) >>> B[i, j].shape (m, m) """ from sympy.utilities.misc import filldedent if self.base.shape: return self.base.shape sizes = [] for i in self.indices: upper = getattr(i, 'upper', None) lower = getattr(i, 'lower', None) if None in (upper, lower): raise IndexException(filldedent(""" Range is not defined for all indices in: %s""" % self)) try: size = upper - lower + 1 except TypeError: raise IndexException(filldedent(""" Shape cannot be inferred from Idx with undefined range: %s""" % self)) sizes.append(size) return Tuple(sizes) @property def ranges(self): """Returns a list of tuples with lower and upper range of each index. If an index does not define the data members upper and lower, the corresponding slot in the list contains ``None`` instead of a tuple. Examples ======== >>> from sympy import Indexed,Idx, symbols >>> Indexed('A', Idx('i', 2), Idx('j', 4), Idx('k', 8)).ranges [(0, 1), (0, 3), (0, 7)] >>> Indexed('A', Idx('i', 3), Idx('j', 3), Idx('k', 3)).ranges [(0, 2), (0, 2), (0, 2)] >>> x, y, z = symbols('x y z', integer=True) >>> Indexed('A', x, y, z).ranges [None, None, None] """ ranges = [] for i in self.indices: sentinel = object() upper = getattr(i, 'upper', sentinel) lower = getattr(i, 'lower', sentinel) if sentinel not in (upper, lower): ranges.append(Tuple(lower, upper)) else: ranges.append(None) return ranges def _sympystr(self, p): indices = list(map(p.doprint, self.indices)) return "%s[%s]" % (p.doprint(self.base), ", ".join(indices)) @property def free_symbols(self): base_free_symbols = self.base.free_symbols indices_free_symbols = { fs for i in self.indices for fs in i.free_symbols} if base_free_symbols: return {self} \| base_free_symbols \| indices_free_symbols else: return indices_free_symbols @property def expr_free_symbols(self): return {self} class IndexedBase(Expr, NotIterable): """Represent the base or stem of an indexed object The IndexedBase class represent an array that contains elements. The main purpose of this class is to allow the convenient creation of objects of the Indexed class. The __getitem__ method of IndexedBase returns an instance of Indexed. Alone, without indices, the IndexedBase class can be used as a notation for e.g. matrix equations, resembling what you could do with the Symbol class. But, the IndexedBase class adds functionality that is not available for Symbol instances: - An IndexedBase object can optionally store shape information. This can be used in to check array conformance and conditions for numpy broadcasting. (TODO) - An IndexedBase object implements syntactic sugar that allows easy symbolic representation of array operations, using implicit summation of repeated indices. - The IndexedBase object symbolizes a mathematical structure equivalent to arrays, and is recognized as such for code generation and automatic compilation and wrapping. >>> from sympy.tensor import IndexedBase, Idx >>> from sympy import symbols >>> A = IndexedBase('A'); A A >>> type(A) <class 'sympy.tensor.indexed.IndexedBase'> When an IndexedBase object receives indices, it returns an array with named axes, represented by an Indexed object: >>> i, j = symbols('i j', integer=True) >>> A[i, j, 2] A[i, j, 2] >>> type(A[i, j, 2]) <class 'sympy.tensor.indexed.Indexed'> The IndexedBase constructor takes an optional shape argument. If given, it overrides any shape information in the indices. (But not the index ranges!) >>> m, n, o, p = symbols('m n o p', integer=True) >>> i = Idx('i', m) >>> j = Idx('j', n) >>> A[i, j].shape (m, n) >>> B = IndexedBase('B', shape=(o, p)) >>> B[i, j].shape (o, p) """ is_commutative = True is_symbol = True is_Atom = True def __new__(cls, label, shape=None, *kw_args): from sympy import MatrixBase, NDimArray if isinstance(label, string_types): label = Symbol(label) elif isinstance(label, Symbol): pass elif isinstance(label, (MatrixBase, NDimArray)): return label elif isinstance(label, Iterable): return _sympify(label) else: label = _sympify(label) if is_sequence(shape): shape = Tuple(shape) elif shape is not None: shape = Tuple(shape) offset = kw_args.pop('offset', S.Zero) strides = kw_args.pop('strides', None) if shape is not None: obj = Expr.__new__(cls, label, shape) else: obj = Expr.__new__(cls, label) obj._shape = shape obj._offset = offset obj._strides = strides obj._name = str(label) return obj @property def name(self): return self._name def __getitem__(self, indices, *kw_args): if is_sequence(indices): # Special case needed because M[my_tuple] is a syntax error. if self.shape and len(self.shape) != len(indices): raise IndexException("Rank mismatch.") return Indexed(self, indices, kw_args) else: if self.shape and len(self.shape) != 1: raise IndexException("Rank mismatch.") return Indexed(self, indices, kw_args) @property def shape(self): """Returns the shape of the ``IndexedBase`` object. Examples ======== >>> from sympy import IndexedBase, Idx, Symbol >>> from sympy.abc import x, y >>> IndexedBase('A', shape=(x, y)).shape (x, y) Note: If the shape of the ``IndexedBase`` is specified, it will override any shape information given by the indices. >>> A = IndexedBase('A', shape=(x, y)) >>> B = IndexedBase('B') >>> i = Idx('i', 2) >>> j = Idx('j', 1) >>> A[i, j].shape (x, y) >>> B[i, j].shape (2, 1) """ return self._shape @property def strides(self): """Returns the strided scheme for the ``IndexedBase`` object. Normally this is a tuple denoting the number of steps to take in the respective dimension when traversing an array. For code generation purposes strides='C' and strides='F' can also be used. strides='C' would mean that code printer would unroll in row-major order and 'F' means unroll in column major order. """ return self._strides @property def offset(self): """Returns the offset for the ``IndexedBase`` object. This is the value added to the resulting index when the 2D Indexed object is unrolled to a 1D form. Used in code generation. Examples ========== >>> from sympy.printing import ccode >>> from sympy.tensor import IndexedBase, Idx >>> from sympy import symbols >>> l, m, n, o = symbols('l m n o', integer=True) >>> A = IndexedBase('A', strides=(l, m, n), offset=o) >>> i, j, k = map(Idx, 'ijk') >>> ccode(A[i, j, k]) 'A[li + mj + nk + o]' """ return self._offset @property def label(self): """Returns the label of the ``IndexedBase`` object. Examples ======== >>> from sympy import IndexedBase >>> from sympy.abc import x, y >>> IndexedBase('A', shape=(x, y)).label A """ return self.args[0] def _sympystr(self, p): return p.doprint(self.label) class Idx(Expr): """Represents an integer index as an ``Integer`` or integer expression. There are a number of ways to create an ``Idx`` object. The constructor takes two arguments: ``label`` An integer or a symbol that labels the index. ``range`` Optionally you can specify a range as either * ``Symbol`` or integer: This is interpreted as a dimension. Lower and upper bounds are set to ``0`` and ``range - 1``, respectively. * ``tuple``: The two elements are interpreted as the lower and upper bounds of the range, respectively. Note: bounds of the range are assumed to be either integer or infinite (oo and -oo are allowed to specify an unbounded range). If ``n`` is given as a bound, then ``n.is_integer`` must not return false. For convenience, if the label is given as a string it is automatically converted to an integer symbol. (Note: this conversion is not done for range or dimension arguments.) Examples ======== >>> from sympy import IndexedBase, Idx, symbols, oo >>> n, i, L, U = symbols('n i L U', integer=True) If a string is given for the label an integer ``Symbol`` is created and the bounds are both ``None``: >>> idx = Idx('qwerty'); idx qwerty >>> idx.lower, idx.upper (None, None) Both upper and lower bounds can be specified: >>> idx = Idx(i, (L, U)); idx i >>> idx.lower, idx.upper (L, U) When only a single bound is given it is interpreted as the dimension and the lower bound defaults to 0: >>> idx = Idx(i, n); idx.lower, idx.upper (0, n - 1) >>> idx = Idx(i, 4); idx.lower, idx.upper (0, 3) >>> idx = Idx(i, oo); idx.lower, idx.upper (0, oo) """ is_integer = True is_finite = True is_real = True is_symbol = True is_Atom = True _diff_wrt = True def __new__(cls, label, range=None, *kw_args): from sympy.utilities.misc import filldedent if isinstance(label, string_types): label = Symbol(label, integer=True) label, range = list(map(sympify, (label, range))) if label.is_Number: if not label.is_integer: raise TypeError("Index is not an integer number.") return label if not label.is_integer: raise TypeError("Idx object requires an integer label.") elif is_sequence(range): if len(range) != 2: raise ValueError(filldedent(""" Idx range tuple must have length 2, but got %s""" % len(range))) for bound in range: if (bound.is_integer is False and bound is not S.Infinity and bound is not S.NegativeInfinity): raise TypeError("Idx object requires integer bounds.") args = label, Tuple(range) elif isinstance(range, Expr): if not (range.is_integer or range is S.Infinity): raise TypeError("Idx object requires an integer dimension.") args = label, Tuple(0, range - 1) elif range: raise TypeError(filldedent(""" The range must be an ordered iterable or integer SymPy expression.""")) else: args = label, obj = Expr.__new__(cls, args, *kw_args) obj._assumptions["finite"] = True obj._assumptions["real"] = True return obj @property def label(self): """Returns the label (Integer or integer expression) of the Idx object. Examples ======== >>> from sympy import Idx, Symbol >>> x = Symbol('x', integer=True) >>> Idx(x).label x >>> j = Symbol('j', integer=True) >>> Idx(j).label j >>> Idx(j + 1).label j + 1 """ return self.args[0] @property def lower(self): """Returns the lower bound of the ``Idx``. Examples ======== >>> from sympy import Idx >>> Idx('j', 2).lower 0 >>> Idx('j', 5).lower 0 >>> Idx('j').lower is None True """ try: return self.args[1][0] except IndexError: return @property def upper(self): """Returns the upper bound of the ``Idx``. Examples ======== >>> from sympy import Idx >>> Idx('j', 2).upper 1 >>> Idx('j', 5).upper 4 >>> Idx('j').upper is None True """ try: return self.args[1][1] except IndexError: return def _sympystr(self, p): return p.doprint(self.label) @property def name(self): return self.label.name if self.label.is_Symbol else str(self.label) @property def free_symbols(self): return {self} def __le__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.upper is not None and (self.upper <= other_lower) == True: return True if self.lower is not None and (self.lower > other_upper) == True: return False return super(Idx, self).__le__(other) def __ge__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.lower is not None and (self.lower >= other_upper) == True: return True if self.upper is not None and (self.upper < other_lower) == True: return False return super(Idx, self).__ge__(other) def __lt__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.upper is not None and (self.upper < other_lower) == True: return True if self.lower is not None and (self.lower >= other_upper) == True: return False return super(Idx, self).__lt__(other) def __gt__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.lower is not None and (self.lower > other_upper) == True: return True if self.upper is not None and (self.upper <= other_lower) == True: return False return super(Idx, self).__gt__(other)
26ad2a5d12a59f6ffa9f9d0f43fadbfc9f721e05bc8003f619b806de203657ae	""" Boolean algebra module for SymPy """ from __future__ import print_function, division from collections import defaultdict from itertools import combinations, product from sympy.core.add import Add from sympy.core.basic import Basic from sympy.core.cache import cacheit from sympy.core.compatibility import (ordered, range, with_metaclass, as_int) from sympy.core.function import Application, Derivative, count_ops from sympy.core.numbers import Number from sympy.core.operations import LatticeOp from sympy.core.singleton import Singleton, S from sympy.core.sympify import converter, _sympify, sympify from sympy.utilities.iterables import sift, ibin from sympy.utilities.misc import filldedent def as_Boolean(e): """Like bool, return the Boolean value of an expression, e, which can be any instance of Boolean or bool. Examples ======== >>> from sympy import true, false, nan >>> from sympy.logic.boolalg import as_Boolean >>> from sympy.abc import x >>> as_Boolean(1) is true True >>> as_Boolean(x) x >>> as_Boolean(2) Traceback (most recent call last): ... TypeError: expecting bool or Boolean, not `2`. """ from sympy.core.symbol import Symbol if e == True: return S.true if e == False: return S.false if isinstance(e, Symbol): z = e.is_zero if z is None: return e return S.false if z else S.true if isinstance(e, Boolean): return e raise TypeError('expecting bool or Boolean, not `%s`.' % e) class Boolean(Basic): """A boolean object is an object for which logic operations make sense.""" __slots__ = [] def __and__(self, other): """Overloading for & operator""" return And(self, other) __rand__ = __and__ def __or__(self, other): """Overloading for \|""" return Or(self, other) __ror__ = __or__ def __invert__(self): """Overloading for ~""" return Not(self) def __rshift__(self, other): """Overloading for >>""" return Implies(self, other) def __lshift__(self, other): """Overloading for <<""" return Implies(other, self) __rrshift__ = __lshift__ __rlshift__ = __rshift__ def __xor__(self, other): return Xor(self, other) __rxor__ = __xor__ def equals(self, other): """ Returns True if the given formulas have the same truth table. For two formulas to be equal they must have the same literals. Examples ======== >>> from sympy.abc import A, B, C >>> from sympy.logic.boolalg import And, Or, Not >>> (A >> B).equals(~B >> ~A) True >>> Not(And(A, B, C)).equals(And(Not(A), Not(B), Not(C))) False >>> Not(And(A, Not(A))).equals(Or(B, Not(B))) False """ from sympy.logic.inference import satisfiable from sympy.core.relational import Relational if self.has(Relational) or other.has(Relational): raise NotImplementedError('handling of relationals') return self.atoms() == other.atoms() and \ not satisfiable(Not(Equivalent(self, other))) def to_nnf(self, simplify=True): # override where necessary return self def as_set(self): """ Rewrites Boolean expression in terms of real sets. Examples ======== >>> from sympy import Symbol, Eq, Or, And >>> x = Symbol('x', real=True) >>> Eq(x, 0).as_set() {0} >>> (x > 0).as_set() Interval.open(0, oo) >>> And(-2 < x, x < 2).as_set() Interval.open(-2, 2) >>> Or(x < -2, 2 < x).as_set() Union(Interval.open(-oo, -2), Interval.open(2, oo)) """ from sympy.calculus.util import periodicity from sympy.core.relational import Relational free = self.free_symbols if len(free) == 1: x = free.pop() reps = {} for r in self.atoms(Relational): if periodicity(r, x) not in (0, None): s = r._eval_as_set() if s in (S.EmptySet, S.UniversalSet, S.Reals): reps[r] = s.as_relational(x) continue raise NotImplementedError(filldedent(''' as_set is not implemented for relationals with periodic solutions ''')) return self.subs(reps)._eval_as_set() else: raise NotImplementedError("Sorry, as_set has not yet been" " implemented for multivariate" " expressions") @property def binary_symbols(self): from sympy.core.relational import Eq, Ne return set().union([i.binary_symbols for i in self.args if i.is_Boolean or i.is_Symbol or isinstance(i, (Eq, Ne))]) class BooleanAtom(Boolean): """ Base class of BooleanTrue and BooleanFalse. """ is_Boolean = True is_Atom = True _op_priority = 11 # higher than Expr def simplify(self, a, *kw): return self def expand(self, a, *kw): return self @property def canonical(self): return self def _noop(self, other=None): raise TypeError('BooleanAtom not allowed in this context.') __add__ = _noop __radd__ = _noop __sub__ = _noop __rsub__ = _noop __mul__ = _noop __rmul__ = _noop __pow__ = _noop __rpow__ = _noop __rdiv__ = _noop __truediv__ = _noop __div__ = _noop __rtruediv__ = _noop __mod__ = _noop __rmod__ = _noop _eval_power = _noop # /// drop when Py2 is no longer supported def __lt__(self, other): from sympy.utilities.misc import filldedent raise TypeError(filldedent(''' A Boolean argument can only be used in Eq and Ne; all other relationals expect real expressions. ''')) __le__ = __lt__ __gt__ = __lt__ __ge__ = __lt__ # \\\ class BooleanTrue(with_metaclass(Singleton, BooleanAtom)): """ SymPy version of True, a singleton that can be accessed via S.true. This is the SymPy version of True, for use in the logic module. The primary advantage of using true instead of True is that shorthand boolean operations like ~ and >> will work as expected on this class, whereas with True they act bitwise on 1. Functions in the logic module will return this class when they evaluate to true. Notes ===== There is liable to be some confusion as to when ``True`` should be used and when ``S.true`` should be used in various contexts throughout SymPy. An important thing to remember is that ``sympify(True)`` returns ``S.true``. This means that for the most part, you can just use ``True`` and it will automatically be converted to ``S.true`` when necessary, similar to how you can generally use 1 instead of ``S.One``. The rule of thumb is: "If the boolean in question can be replaced by an arbitrary symbolic ``Boolean``, like ``Or(x, y)`` or ``x > 1``, use ``S.true``. Otherwise, use ``True``" In other words, use ``S.true`` only on those contexts where the boolean is being used as a symbolic representation of truth. For example, if the object ends up in the ``.args`` of any expression, then it must necessarily be ``S.true`` instead of ``True``, as elements of ``.args`` must be ``Basic``. On the other hand, ``==`` is not a symbolic operation in SymPy, since it always returns ``True`` or ``False``, and does so in terms of structural equality rather than mathematical, so it should return ``True``. The assumptions system should use ``True`` and ``False``. Aside from not satisfying the above rule of thumb, the assumptions system uses a three-valued logic (``True``, ``False``, ``None``), whereas ``S.true`` and ``S.false`` represent a two-valued logic. When in doubt, use ``True``. "``S.true == True is True``." While "``S.true is True``" is ``False``, "``S.true == True``" is ``True``, so if there is any doubt over whether a function or expression will return ``S.true`` or ``True``, just use ``==`` instead of ``is`` to do the comparison, and it will work in either case. Finally, for boolean flags, it's better to just use ``if x`` instead of ``if x is True``. To quote PEP 8: Don't compare boolean values to ``True`` or ``False`` using ``==``. Yes: ``if greeting:`` * No: ``if greeting == True:`` * Worse: ``if greeting is True:`` Examples ======== >>> from sympy import sympify, true, false, Or >>> sympify(True) True >>> _ is True, _ is true (False, True) >>> Or(true, false) True >>> _ is true True Python operators give a boolean result for true but a bitwise result for True >>> ~true, ~True (False, -2) >>> true >> true, True >> True (True, 0) Python operators give a boolean result for true but a bitwise result for True >>> ~true, ~True (False, -2) >>> true >> true, True >> True (True, 0) See Also ======== sympy.logic.boolalg.BooleanFalse """ def __nonzero__(self): return True __bool__ = __nonzero__ def __hash__(self): return hash(True) @property def negated(self): return S.false def as_set(self): """ Rewrite logic operators and relationals in terms of real sets. Examples ======== >>> from sympy import true >>> true.as_set() UniversalSet """ return S.UniversalSet class BooleanFalse(with_metaclass(Singleton, BooleanAtom)): """ SymPy version of False, a singleton that can be accessed via S.false. This is the SymPy version of False, for use in the logic module. The primary advantage of using false instead of False is that shorthand boolean operations like ~ and >> will work as expected on this class, whereas with False they act bitwise on 0. Functions in the logic module will return this class when they evaluate to false. Notes ====== See note in :py:class`sympy.logic.boolalg.BooleanTrue` Examples ======== >>> from sympy import sympify, true, false, Or >>> sympify(False) False >>> _ is False, _ is false (False, True) >>> Or(true, false) True >>> _ is true True Python operators give a boolean result for false but a bitwise result for False >>> ~false, ~False (True, -1) >>> false >> false, False >> False (True, 0) See Also ======== sympy.logic.boolalg.BooleanTrue """ def __nonzero__(self): return False __bool__ = __nonzero__ def __hash__(self): return hash(False) @property def negated(self): return S.true def as_set(self): """ Rewrite logic operators and relationals in terms of real sets. Examples ======== >>> from sympy import false >>> false.as_set() EmptySet() """ return S.EmptySet true = BooleanTrue() false = BooleanFalse() # We want S.true and S.false to work, rather than S.BooleanTrue and # S.BooleanFalse, but making the class and instance names the same causes some # major issues (like the inability to import the class directly from this # file). S.true = true S.false = false converter[bool] = lambda x: S.true if x else S.false class BooleanFunction(Application, Boolean): """Boolean function is a function that lives in a boolean space It is used as base class for And, Or, Not, etc. """ is_Boolean = True def _eval_simplify(self, ratio, measure, rational, inverse): rv = self.func([a._eval_simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse) for a in self.args]) return simplify_logic(rv) def simplify(self, ratio=1.7, measure=count_ops, rational=False, inverse=False): return self._eval_simplify(ratio, measure, rational, inverse) # /// drop when Py2 is no longer supported def __lt__(self, other): from sympy.utilities.misc import filldedent raise TypeError(filldedent(''' A Boolean argument can only be used in Eq and Ne; all other relationals expect real expressions. ''')) __le__ = __lt__ __ge__ = __lt__ __gt__ = __lt__ # \\\ @classmethod def binary_check_and_simplify(self, args): from sympy.core.relational import Relational, Eq, Ne args = [as_Boolean(i) for i in args] bin = set().union([i.binary_symbols for i in args]) rel = set().union([i.atoms(Relational) for i in args]) reps = {} for x in bin: for r in rel: if x in bin and x in r.free_symbols: if isinstance(r, (Eq, Ne)): if not ( S.true in r.args or S.false in r.args): reps[r] = S.false else: raise TypeError(filldedent(''' Incompatible use of binary symbol `%s` as a real variable in `%s` ''' % (x, r))) return [i.subs(reps) for i in args] def to_nnf(self, simplify=True): return self._to_nnf(self.args, simplify=simplify) @classmethod def _to_nnf(cls, args, *kwargs): simplify = kwargs.get('simplify', True) argset = set([]) for arg in args: if not is_literal(arg): arg = arg.to_nnf(simplify) if simplify: if isinstance(arg, cls): arg = arg.args else: arg = (arg,) for a in arg: if Not(a) in argset: return cls.zero argset.add(a) else: argset.add(arg) return cls(argset) # the diff method below is copied from Expr class def diff(self, symbols, assumptions): assumptions.setdefault("evaluate", True) return Derivative(self, symbols, *assumptions) def _eval_derivative(self, x): from sympy.core.relational import Eq from sympy.functions.elementary.piecewise import Piecewise if x in self.binary_symbols: return Piecewise( (0, Eq(self.subs(x, 0), self.subs(x, 1))), (1, True)) elif x in self.free_symbols: # not implemented, see https://www.encyclopediaofmath.org/ # index.php/Boolean_differential_calculus pass else: return S.Zero def _apply_patternbased_simplification(self, rv, patterns, measure, dominatingvalue, replacementvalue=None): """ Replace patterns of Relational Parameters ========== rv : Expr Boolean expression patterns : tuple Tuple of tuples, with (pattern to simplify, simplified pattern) measure : function Simplification measure dominatingvalue : boolean or None The dominating value for the function of consideration. For example, for And S.false is dominating. As soon as one expression is S.false in And, the whole expression is S.false. replacementvalue : boolean or None, optional The resulting value for the whole expression if one argument evaluates to dominatingvalue. For example, for Nand S.false is dominating, but in this case the resulting value is S.true. Default is None. If replacementvalue is None and dominatingvalue is not None, replacementvalue = dominatingvalue """ from sympy.core.relational import Relational, _canonical if replacementvalue is None and dominatingvalue is not None: replacementvalue = dominatingvalue # Use replacement patterns for Relationals changed = True Rel, nonRel = sift(rv.args, lambda i: isinstance(i, Relational), binary=True) if len(Rel) <= 1: return rv Rel, nonRealRel = sift(rv.args, lambda i: all(s.is_real is not False for s in i.free_symbols), binary=True) Rel = [i.canonical for i in Rel] while changed and len(Rel) >= 2: changed = False # Sort based on ordered Rel = list(ordered(Rel)) # Create a list of possible replacements results = [] # Try all combinations for ((i, pi), (j, pj)) in combinations(enumerate(Rel), 2): for k, (pattern, simp) in enumerate(patterns): res = [] # use SymPy matching oldexpr = rv.func(pi, pj) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) # Try reversing first relational # This and the rest should not be required with a better # canonical oldexpr = rv.func(pi.reversed, pj) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) # Try reversing second relational oldexpr = rv.func(pi, pj.reversed) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) # Try reversing both relationals oldexpr = rv.func(pi.reversed, pj.reversed) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) if res: for tmpres, oldexpr in res: # we have a matching, compute replacement np = simp.subs(tmpres) if np == dominatingvalue: # if dominatingvalue, the whole expression # will be replacementvalue return replacementvalue # add replacement if not isinstance(np, ITE): # We only want to use ITE replacements if # they simplify to a relational costsaving = measure(oldexpr) - measure(np) if costsaving > 0: results.append((costsaving, (i, j, np))) if results: # Sort results based on complexity results = list(reversed(sorted(results, key=lambda pair: pair[0]))) # Replace the one providing most simplification cost, replacement = results[0] i, j, newrel = replacement # Remove the old relationals del Rel[j] del Rel[i] if dominatingvalue is None or newrel != ~dominatingvalue: # Insert the new one (no need to insert a value that will # not affect the result) Rel.append(newrel) # We did change something so try again changed = True rv = rv.func(([_canonical(i) for i in ordered(Rel)] + nonRel + nonRealRel)) return rv class And(LatticeOp, BooleanFunction): """ Logical AND function. It evaluates its arguments in order, giving False immediately if any of them are False, and True if they are all True. Examples ======== >>> from sympy.core import symbols >>> from sympy.abc import x, y >>> from sympy.logic.boolalg import And >>> x & y x & y Notes ===== The ``&`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise and. Hence, ``And(a, b)`` and ``a & b`` will return different things if ``a`` and ``b`` are integers. >>> And(x, y).subs(x, 1) y """ zero = false identity = true nargs = None @classmethod def _new_args_filter(cls, args): newargs = [] rel = [] args = BooleanFunction.binary_check_and_simplify(args) for x in reversed(args): if x.is_Relational: c = x.canonical if c in rel: continue nc = c.negated.canonical if any(r == nc for r in rel): return [S.false] rel.append(c) newargs.append(x) return LatticeOp._new_args_filter(newargs, And) def _eval_simplify(self, ratio, measure, rational, inverse): from sympy.core.relational import Equality, Relational from sympy.solvers.solveset import linear_coeffs # standard simplify rv = super(And, self)._eval_simplify( ratio, measure, rational, inverse) if not isinstance(rv, And): return rv # simplify args that are equalities involving # symbols so x == 0 & x == y -> x==0 & y == 0 Rel, nonRel = sift(rv.args, lambda i: isinstance(i, Relational), binary=True) if not Rel: return rv eqs, other = sift(Rel, lambda i: isinstance(i, Equality), binary=True) if not eqs: return rv reps = {} sifted = {} if eqs: # group by length of free symbols sifted = sift(ordered([ (i.free_symbols, i) for i in eqs]), lambda x: len(x[0])) eqs = [] while 1 in sifted: for free, e in sifted.pop(1): x = free.pop() if e.lhs != x or x in e.rhs.free_symbols: try: m, b = linear_coeffs( e.rewrite(Add, evaluate=False), x) enew = e.func(x, -b/m) if measure(enew) <= ratiomeasure(e): e = enew else: eqs.append(e) continue except ValueError: pass if x in reps: eqs.append(e.func(e.rhs, reps[x])) else: reps[x] = e.rhs eqs.append(e) resifted = defaultdict(list) for k in sifted: for f, e in sifted[k]: e = e.subs(reps) f = e.free_symbols resifted[len(f)].append((f, e)) sifted = resifted for k in sifted: eqs.extend([e for f, e in sifted[k]]) other = [ei.subs(reps) for ei in other] rv = rv.func(([i.canonical for i in (eqs + other)] + nonRel)) patterns = simplify_patterns_and() return self._apply_patternbased_simplification(rv, patterns, measure, False) def _eval_as_set(self): from sympy.sets.sets import Intersection return Intersection([arg.as_set() for arg in self.args]) class Or(LatticeOp, BooleanFunction): """ Logical OR function It evaluates its arguments in order, giving True immediately if any of them are True, and False if they are all False. Examples ======== >>> from sympy.core import symbols >>> from sympy.abc import x, y >>> from sympy.logic.boolalg import Or >>> x \| y x \| y Notes ===== The ``\|`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise or. Hence, ``Or(a, b)`` and ``a \| b`` will return different things if ``a`` and ``b`` are integers. >>> Or(x, y).subs(x, 0) y """ zero = true identity = false @classmethod def _new_args_filter(cls, args): newargs = [] rel = [] args = BooleanFunction.binary_check_and_simplify(args) for x in args: if x.is_Relational: c = x.canonical if c in rel: continue nc = c.negated.canonical if any(r == nc for r in rel): return [S.true] rel.append(c) newargs.append(x) return LatticeOp._new_args_filter(newargs, Or) def _eval_as_set(self): from sympy.sets.sets import Union return Union([arg.as_set() for arg in self.args]) def _eval_simplify(self, ratio, measure, rational, inverse): # standard simplify rv = super(Or, self)._eval_simplify( ratio, measure, rational, inverse) if not isinstance(rv, Or): return rv patterns = simplify_patterns_or() return self._apply_patternbased_simplification(rv, patterns, measure, S.true) class Not(BooleanFunction): """ Logical Not function (negation) Returns True if the statement is False Returns False if the statement is True Examples ======== >>> from sympy.logic.boolalg import Not, And, Or >>> from sympy.abc import x, A, B >>> Not(True) False >>> Not(False) True >>> Not(And(True, False)) True >>> Not(Or(True, False)) False >>> Not(And(And(True, x), Or(x, False))) ~x >>> ~x ~x >>> Not(And(Or(A, B), Or(~A, ~B))) ~((A \| B) & (~A \| ~B)) Notes ===== - The ``~`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise not. In particular, ``~a`` and ``Not(a)`` will be different if ``a`` is an integer. Furthermore, since bools in Python subclass from ``int``, ``~True`` is the same as ``~1`` which is ``-2``, which has a boolean value of True. To avoid this issue, use the SymPy boolean types ``true`` and ``false``. >>> from sympy import true >>> ~True -2 >>> ~true False """ is_Not = True @classmethod def eval(cls, arg): from sympy import ( Equality, GreaterThan, LessThan, StrictGreaterThan, StrictLessThan, Unequality) if isinstance(arg, Number) or arg in (True, False): return false if arg else true if arg.is_Not: return arg.args[0] # Simplify Relational objects. if isinstance(arg, Equality): return Unequality(arg.args) if isinstance(arg, Unequality): return Equality(arg.args) if isinstance(arg, StrictLessThan): return GreaterThan(arg.args) if isinstance(arg, StrictGreaterThan): return LessThan(arg.args) if isinstance(arg, LessThan): return StrictGreaterThan(arg.args) if isinstance(arg, GreaterThan): return StrictLessThan(arg.args) def _eval_as_set(self): """ Rewrite logic operators and relationals in terms of real sets. Examples ======== >>> from sympy import Not, Symbol >>> x = Symbol('x') >>> Not(x > 0).as_set() Interval(-oo, 0) """ return self.args[0].as_set().complement(S.Reals) def to_nnf(self, simplify=True): if is_literal(self): return self expr = self.args[0] func, args = expr.func, expr.args if func == And: return Or._to_nnf([~arg for arg in args], simplify=simplify) if func == Or: return And._to_nnf([~arg for arg in args], simplify=simplify) if func == Implies: a, b = args return And._to_nnf(a, ~b, simplify=simplify) if func == Equivalent: return And._to_nnf(Or(args), Or([~arg for arg in args]), simplify=simplify) if func == Xor: result = [] for i in range(1, len(args)+1, 2): for neg in combinations(args, i): clause = [~s if s in neg else s for s in args] result.append(Or(clause)) return And._to_nnf(result, simplify=simplify) if func == ITE: a, b, c = args return And._to_nnf(Or(a, ~c), Or(~a, ~b), simplify=simplify) raise ValueError("Illegal operator %s in expression" % func) class Xor(BooleanFunction): """ Logical XOR (exclusive OR) function. Returns True if an odd number of the arguments are True and the rest are False. Returns False if an even number of the arguments are True and the rest are False. Examples ======== >>> from sympy.logic.boolalg import Xor >>> from sympy import symbols >>> x, y = symbols('x y') >>> Xor(True, False) True >>> Xor(True, True) False >>> Xor(True, False, True, True, False) True >>> Xor(True, False, True, False) False >>> x ^ y Xor(x, y) Notes ===== The ``^`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise xor. In particular, ``a ^ b`` and ``Xor(a, b)`` will be different if ``a`` and ``b`` are integers. >>> Xor(x, y).subs(y, 0) x """ def __new__(cls, args, kwargs): argset = set([]) obj = super(Xor, cls).__new__(cls, args, *kwargs) for arg in obj._args: if isinstance(arg, Number) or arg in (True, False): if arg: arg = true else: continue if isinstance(arg, Xor): for a in arg.args: argset.remove(a) if a in argset else argset.add(a) elif arg in argset: argset.remove(arg) else: argset.add(arg) rel = [(r, r.canonical, r.negated.canonical) for r in argset if r.is_Relational] odd = False # is number of complimentary pairs odd? start 0 -> False remove = [] for i, (r, c, nc) in enumerate(rel): for j in range(i + 1, len(rel)): rj, cj = rel[j][:2] if cj == nc: odd = ~odd break elif cj == c: break else: continue remove.append((r, rj)) if odd: argset.remove(true) if true in argset else argset.add(true) for a, b in remove: argset.remove(a) argset.remove(b) if len(argset) == 0: return false elif len(argset) == 1: return argset.pop() elif True in argset: argset.remove(True) return Not(Xor(argset)) else: obj._args = tuple(ordered(argset)) obj._argset = frozenset(argset) return obj @property @cacheit def args(self): return tuple(ordered(self._argset)) def to_nnf(self, simplify=True): args = [] for i in range(0, len(self.args)+1, 2): for neg in combinations(self.args, i): clause = [~s if s in neg else s for s in self.args] args.append(Or(clause)) return And._to_nnf(args, simplify=simplify) def _eval_simplify(self, ratio, measure, rational, inverse): # as standard simplify uses simplify_logic which writes things as # And and Or, we only simplify the partial expressions before using # patterns rv = self.func([a._eval_simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse) for a in self.args]) if not isinstance(rv, Xor): # This shouldn't really happen here return rv patterns = simplify_patterns_xor() return self._apply_patternbased_simplification(rv, patterns, measure, None) class Nand(BooleanFunction): """ Logical NAND function. It evaluates its arguments in order, giving True immediately if any of them are False, and False if they are all True. Returns True if any of the arguments are False Returns False if all arguments are True Examples ======== >>> from sympy.logic.boolalg import Nand >>> from sympy import symbols >>> x, y = symbols('x y') >>> Nand(False, True) True >>> Nand(True, True) False >>> Nand(x, y) ~(x & y) """ @classmethod def eval(cls, args): return Not(And(args)) class Nor(BooleanFunction): """ Logical NOR function. It evaluates its arguments in order, giving False immediately if any of them are True, and True if they are all False. Returns False if any argument is True Returns True if all arguments are False Examples ======== >>> from sympy.logic.boolalg import Nor >>> from sympy import symbols >>> x, y = symbols('x y') >>> Nor(True, False) False >>> Nor(True, True) False >>> Nor(False, True) False >>> Nor(False, False) True >>> Nor(x, y) ~(x \| y) """ @classmethod def eval(cls, args): return Not(Or(args)) class Xnor(BooleanFunction): """ Logical XNOR function. Returns False if an odd number of the arguments are True and the rest are False. Returns True if an even number of the arguments are True and the rest are False. Examples ======== >>> from sympy.logic.boolalg import Xnor >>> from sympy import symbols >>> x, y = symbols('x y') >>> Xnor(True, False) False >>> Xnor(True, True) True >>> Xnor(True, False, True, True, False) False >>> Xnor(True, False, True, False) True """ @classmethod def eval(cls, args): return Not(Xor(args)) class Implies(BooleanFunction): """ Logical implication. A implies B is equivalent to !A v B Accepts two Boolean arguments; A and B. Returns False if A is True and B is False Returns True otherwise. Examples ======== >>> from sympy.logic.boolalg import Implies >>> from sympy import symbols >>> x, y = symbols('x y') >>> Implies(True, False) False >>> Implies(False, False) True >>> Implies(True, True) True >>> Implies(False, True) True >>> x >> y Implies(x, y) >>> y << x Implies(x, y) Notes ===== The ``>>`` and ``<<`` operators are provided as a convenience, but note that their use here is different from their normal use in Python, which is bit shifts. Hence, ``Implies(a, b)`` and ``a >> b`` will return different things if ``a`` and ``b`` are integers. In particular, since Python considers ``True`` and ``False`` to be integers, ``True >> True`` will be the same as ``1 >> 1``, i.e., 0, which has a truth value of False. To avoid this issue, use the SymPy objects ``true`` and ``false``. >>> from sympy import true, false >>> True >> False 1 >>> true >> false False """ @classmethod def eval(cls, args): try: newargs = [] for x in args: if isinstance(x, Number) or x in (0, 1): newargs.append(True if x else False) else: newargs.append(x) A, B = newargs except ValueError: raise ValueError( "%d operand(s) used for an Implies " "(pairs are required): %s" % (len(args), str(args))) if A == True or A == False or B == True or B == False: return Or(Not(A), B) elif A == B: return S.true elif A.is_Relational and B.is_Relational: if A.canonical == B.canonical: return S.true if A.negated.canonical == B.canonical: return B else: return Basic.__new__(cls, args) def to_nnf(self, simplify=True): a, b = self.args return Or._to_nnf(~a, b, simplify=simplify) class Equivalent(BooleanFunction): """ Equivalence relation. Equivalent(A, B) is True iff A and B are both True or both False Returns True if all of the arguments are logically equivalent. Returns False otherwise. Examples ======== >>> from sympy.logic.boolalg import Equivalent, And >>> from sympy.abc import x, y >>> Equivalent(False, False, False) True >>> Equivalent(True, False, False) False >>> Equivalent(x, And(x, True)) True """ def __new__(cls, args, *options): from sympy.core.relational import Relational args = [_sympify(arg) for arg in args] argset = set(args) for x in args: if isinstance(x, Number) or x in [True, False]: # Includes 0, 1 argset.discard(x) argset.add(True if x else False) rel = [] for r in argset: if isinstance(r, Relational): rel.append((r, r.canonical, r.negated.canonical)) remove = [] for i, (r, c, nc) in enumerate(rel): for j in range(i + 1, len(rel)): rj, cj = rel[j][:2] if cj == nc: return false elif cj == c: remove.append((r, rj)) break for a, b in remove: argset.remove(a) argset.remove(b) argset.add(True) if len(argset) <= 1: return true if True in argset: argset.discard(True) return And(argset) if False in argset: argset.discard(False) return And([~arg for arg in argset]) _args = frozenset(argset) obj = super(Equivalent, cls).__new__(cls, _args) obj._argset = _args return obj @property @cacheit def args(self): return tuple(ordered(self._argset)) def to_nnf(self, simplify=True): args = [] for a, b in zip(self.args, self.args[1:]): args.append(Or(~a, b)) args.append(Or(~self.args[-1], self.args[0])) return And._to_nnf(args, simplify=simplify) class ITE(BooleanFunction): """ If then else clause. ITE(A, B, C) evaluates and returns the result of B if A is true else it returns the result of C. All args must be Booleans. Examples ======== >>> from sympy.logic.boolalg import ITE, And, Xor, Or >>> from sympy.abc import x, y, z >>> ITE(True, False, True) False >>> ITE(Or(True, False), And(True, True), Xor(True, True)) True >>> ITE(x, y, z) ITE(x, y, z) >>> ITE(True, x, y) x >>> ITE(False, x, y) y >>> ITE(x, y, y) y Trying to use non-Boolean args will generate a TypeError: >>> ITE(True, [], ()) Traceback (most recent call last): ... TypeError: expecting bool, Boolean or ITE, not `[]` """ def __new__(cls, args, kwargs): from sympy.core.relational import Eq, Ne if len(args) != 3: raise ValueError('expecting exactly 3 args') a, b, c = args # check use of binary symbols if isinstance(a, (Eq, Ne)): # in this context, we can evaluate the Eq/Ne # if one arg is a binary symbol and the other # is true/false b, c = map(as_Boolean, (b, c)) bin = set().union([i.binary_symbols for i in (b, c)]) if len(set(a.args) - bin) == 1: # one arg is a binary_symbols _a = a if a.lhs is S.true: a = a.rhs elif a.rhs is S.true: a = a.lhs elif a.lhs is S.false: a = ~a.rhs elif a.rhs is S.false: a = ~a.lhs else: # binary can only equal True or False a = S.false if isinstance(_a, Ne): a = ~a else: a, b, c = BooleanFunction.binary_check_and_simplify( a, b, c) rv = None if kwargs.get('evaluate', True): rv = cls.eval(a, b, c) if rv is None: rv = BooleanFunction.__new__(cls, a, b, c, evaluate=False) return rv @classmethod def eval(cls, args): from sympy.core.relational import Eq, Ne # do the args give a singular result? a, b, c = args if isinstance(a, (Ne, Eq)): _a = a if S.true in a.args: a = a.lhs if a.rhs is S.true else a.rhs elif S.false in a.args: a = ~a.lhs if a.rhs is S.false else ~a.rhs else: _a = None if _a is not None and isinstance(_a, Ne): a = ~a if a is S.true: return b if a is S.false: return c if b == c: return b else: # or maybe the results allow the answer to be expressed # in terms of the condition if b is S.true and c is S.false: return a if b is S.false and c is S.true: return Not(a) if [a, b, c] != args: return cls(a, b, c, evaluate=False) def to_nnf(self, simplify=True): a, b, c = self.args return And._to_nnf(Or(~a, b), Or(a, c), simplify=simplify) def _eval_as_set(self): return self.to_nnf().as_set() def _eval_rewrite_as_Piecewise(self, args, *kwargs): from sympy.functions import Piecewise return Piecewise((args[1], args[0]), (args[2], True)) # end class definitions. Some useful methods def conjuncts(expr): """Return a list of the conjuncts in the expr s. Examples ======== >>> from sympy.logic.boolalg import conjuncts >>> from sympy.abc import A, B >>> conjuncts(A & B) frozenset({A, B}) >>> conjuncts(A \| B) frozenset({A \| B}) """ return And.make_args(expr) def disjuncts(expr): """Return a list of the disjuncts in the sentence s. Examples ======== >>> from sympy.logic.boolalg import disjuncts >>> from sympy.abc import A, B >>> disjuncts(A \| B) frozenset({A, B}) >>> disjuncts(A & B) frozenset({A & B}) """ return Or.make_args(expr) def distribute_and_over_or(expr): """ Given a sentence s consisting of conjunctions and disjunctions of literals, return an equivalent sentence in CNF. Examples ======== >>> from sympy.logic.boolalg import distribute_and_over_or, And, Or, Not >>> from sympy.abc import A, B, C >>> distribute_and_over_or(Or(A, And(Not(B), Not(C)))) (A \| ~B) & (A \| ~C) """ return _distribute((expr, And, Or)) def distribute_or_over_and(expr): """ Given a sentence s consisting of conjunctions and disjunctions of literals, return an equivalent sentence in DNF. Note that the output is NOT simplified. Examples ======== >>> from sympy.logic.boolalg import distribute_or_over_and, And, Or, Not >>> from sympy.abc import A, B, C >>> distribute_or_over_and(And(Or(Not(A), B), C)) (B & C) \| (C & ~A) """ return _distribute((expr, Or, And)) def _distribute(info): """ Distributes info[1] over info[2] with respect to info[0]. """ if isinstance(info[0], info[2]): for arg in info[0].args: if isinstance(arg, info[1]): conj = arg break else: return info[0] rest = info[2]([a for a in info[0].args if a is not conj]) return info[1](list(map(_distribute, [(info[2](c, rest), info[1], info[2]) for c in conj.args]))) elif isinstance(info[0], info[1]): return info[1](list(map(_distribute, [(x, info[1], info[2]) for x in info[0].args]))) else: return info[0] def to_nnf(expr, simplify=True): """ Converts expr to Negation Normal Form. A logical expression is in Negation Normal Form (NNF) if it contains only And, Or and Not, and Not is applied only to literals. If simplify is True, the result contains no redundant clauses. Examples ======== >>> from sympy.abc import A, B, C, D >>> from sympy.logic.boolalg import Not, Equivalent, to_nnf >>> to_nnf(Not((~A & ~B) \| (C & D))) (A \| B) & (~C \| ~D) >>> to_nnf(Equivalent(A >> B, B >> A)) (A \| ~B \| (A & ~B)) & (B \| ~A \| (B & ~A)) """ if is_nnf(expr, simplify): return expr return expr.to_nnf(simplify) def to_cnf(expr, simplify=False): """ Convert a propositional logical sentence s to conjunctive normal form. That is, of the form ((A \| ~B \| ...) & (B \| C \| ...) & ...) If simplify is True, the expr is evaluated to its simplest CNF form using the Quine-McCluskey algorithm. Examples ======== >>> from sympy.logic.boolalg import to_cnf >>> from sympy.abc import A, B, D >>> to_cnf(~(A \| B) \| D) (D \| ~A) & (D \| ~B) >>> to_cnf((A \| B) & (A \| ~A), True) A \| B """ expr = sympify(expr) if not isinstance(expr, BooleanFunction): return expr if simplify: return simplify_logic(expr, 'cnf', True) # Don't convert unless we have to if is_cnf(expr): return expr expr = eliminate_implications(expr) return distribute_and_over_or(expr) def to_dnf(expr, simplify=False): """ Convert a propositional logical sentence s to disjunctive normal form. That is, of the form ((A & ~B & ...) \| (B & C & ...) \| ...) If simplify is True, the expr is evaluated to its simplest DNF form using the Quine-McCluskey algorithm. Examples ======== >>> from sympy.logic.boolalg import to_dnf >>> from sympy.abc import A, B, C >>> to_dnf(B & (A \| C)) (A & B) \| (B & C) >>> to_dnf((A & B) \| (A & ~B) \| (B & C) \| (~B & C), True) A \| C """ expr = sympify(expr) if not isinstance(expr, BooleanFunction): return expr if simplify: return simplify_logic(expr, 'dnf', True) # Don't convert unless we have to if is_dnf(expr): return expr expr = eliminate_implications(expr) return distribute_or_over_and(expr) def is_nnf(expr, simplified=True): """ Checks if expr is in Negation Normal Form. A logical expression is in Negation Normal Form (NNF) if it contains only And, Or and Not, and Not is applied only to literals. If simpified is True, checks if result contains no redundant clauses. Examples ======== >>> from sympy.abc import A, B, C >>> from sympy.logic.boolalg import Not, is_nnf >>> is_nnf(A & B \| ~C) True >>> is_nnf((A \| ~A) & (B \| C)) False >>> is_nnf((A \| ~A) & (B \| C), False) True >>> is_nnf(Not(A & B) \| C) False >>> is_nnf((A >> B) & (B >> A)) False """ expr = sympify(expr) if is_literal(expr): return True stack = [expr] while stack: expr = stack.pop() if expr.func in (And, Or): if simplified: args = expr.args for arg in args: if Not(arg) in args: return False stack.extend(expr.args) elif not is_literal(expr): return False return True def is_cnf(expr): """ Test whether or not an expression is in conjunctive normal form. Examples ======== >>> from sympy.logic.boolalg import is_cnf >>> from sympy.abc import A, B, C >>> is_cnf(A \| B \| C) True >>> is_cnf(A & B & C) True >>> is_cnf((A & B) \| C) False """ return _is_form(expr, And, Or) def is_dnf(expr): """ Test whether or not an expression is in disjunctive normal form. Examples ======== >>> from sympy.logic.boolalg import is_dnf >>> from sympy.abc import A, B, C >>> is_dnf(A \| B \| C) True >>> is_dnf(A & B & C) True >>> is_dnf((A & B) \| C) True >>> is_dnf(A & (B \| C)) False """ return _is_form(expr, Or, And) def _is_form(expr, function1, function2): """ Test whether or not an expression is of the required form. """ expr = sympify(expr) # Special case of an Atom if expr.is_Atom: return True # Special case of a single expression of function2 if isinstance(expr, function2): for lit in expr.args: if isinstance(lit, Not): if not lit.args[0].is_Atom: return False else: if not lit.is_Atom: return False return True # Special case of a single negation if isinstance(expr, Not): if not expr.args[0].is_Atom: return False if not isinstance(expr, function1): return False for cls in expr.args: if cls.is_Atom: continue if isinstance(cls, Not): if not cls.args[0].is_Atom: return False elif not isinstance(cls, function2): return False for lit in cls.args: if isinstance(lit, Not): if not lit.args[0].is_Atom: return False else: if not lit.is_Atom: return False return True def eliminate_implications(expr): """ Change >>, <<, and Equivalent into &, \|, and ~. That is, return an expression that is equivalent to s, but has only &, \|, and ~ as logical operators. Examples ======== >>> from sympy.logic.boolalg import Implies, Equivalent, \ eliminate_implications >>> from sympy.abc import A, B, C >>> eliminate_implications(Implies(A, B)) B \| ~A >>> eliminate_implications(Equivalent(A, B)) (A \| ~B) & (B \| ~A) >>> eliminate_implications(Equivalent(A, B, C)) (A \| ~C) & (B \| ~A) & (C \| ~B) """ return to_nnf(expr, simplify=False) def is_literal(expr): """ Returns True if expr is a literal, else False. Examples ======== >>> from sympy import Or, Q >>> from sympy.abc import A, B >>> from sympy.logic.boolalg import is_literal >>> is_literal(A) True >>> is_literal(~A) True >>> is_literal(Q.zero(A)) True >>> is_literal(A + B) True >>> is_literal(Or(A, B)) False """ if isinstance(expr, Not): return not isinstance(expr.args[0], BooleanFunction) else: return not isinstance(expr, BooleanFunction) def to_int_repr(clauses, symbols): """ Takes clauses in CNF format and puts them into an integer representation. Examples ======== >>> from sympy.logic.boolalg import to_int_repr >>> from sympy.abc import x, y >>> to_int_repr([x \| y, y], [x, y]) == [{1, 2}, {2}] True """ # Convert the symbol list into a dict symbols = dict(list(zip(symbols, list(range(1, len(symbols) + 1))))) def append_symbol(arg, symbols): if isinstance(arg, Not): return -symbols[arg.args[0]] else: return symbols[arg] return [set(append_symbol(arg, symbols) for arg in Or.make_args(c)) for c in clauses] def term_to_integer(term): """ Return an integer corresponding to the base-2 digits given by ``term``. Parameters ========== term : a string or list of ones and zeros Examples ======== >>> from sympy.logic.boolalg import term_to_integer >>> term_to_integer([1, 0, 0]) 4 >>> term_to_integer('100') 4 """ return int(''.join(list(map(str, list(term)))), 2) def integer_to_term(k, n_bits=None): """ Return a list of the base-2 digits in the integer, ``k``. Parameters ========== k : int n_bits : int If ``n_bits`` is given and the number of digits in the binary representation of ``k`` is smaller than ``n_bits`` then left-pad the list with 0s. Examples ======== >>> from sympy.logic.boolalg import integer_to_term >>> integer_to_term(4) [1, 0, 0] >>> integer_to_term(4, 6) [0, 0, 0, 1, 0, 0] """ s = '{0:0{1}b}'.format(abs(as_int(k)), as_int(abs(n_bits or 0))) return list(map(int, s)) def truth_table(expr, variables, input=True): """ Return a generator of all possible configurations of the input variables, and the result of the boolean expression for those values. Parameters ========== expr : string or boolean expression variables : list of variables input : boolean (default True) indicates whether to return the input combinations. Examples ======== >>> from sympy.logic.boolalg import truth_table >>> from sympy.abc import x,y >>> table = truth_table(x >> y, [x, y]) >>> for t in table: ... print('{0} -> {1}'.format(t)) [0, 0] -> True [0, 1] -> True [1, 0] -> False [1, 1] -> True >>> table = truth_table(x \| y, [x, y]) >>> list(table) [([0, 0], False), ([0, 1], True), ([1, 0], True), ([1, 1], True)] If input is false, truth_table returns only a list of truth values. In this case, the corresponding input values of variables can be deduced from the index of a given output. >>> from sympy.logic.boolalg import integer_to_term >>> vars = [y, x] >>> values = truth_table(x >> y, vars, input=False) >>> values = list(values) >>> values [True, False, True, True] >>> for i, value in enumerate(values): ... print('{0} -> {1}'.format(list(zip( ... vars, integer_to_term(i, len(vars)))), value)) [(y, 0), (x, 0)] -> True [(y, 0), (x, 1)] -> False [(y, 1), (x, 0)] -> True [(y, 1), (x, 1)] -> True """ variables = [sympify(v) for v in variables] expr = sympify(expr) if not isinstance(expr, BooleanFunction) and not is_literal(expr): return table = product([0, 1], repeat=len(variables)) for term in table: term = list(term) value = expr.xreplace(dict(zip(variables, term))) if input: yield term, value else: yield value def _check_pair(minterm1, minterm2): """ Checks if a pair of minterms differs by only one bit. If yes, returns index, else returns -1. """ index = -1 for x, (i, j) in enumerate(zip(minterm1, minterm2)): if i != j: if index == -1: index = x else: return -1 return index def _convert_to_varsSOP(minterm, variables): """ Converts a term in the expansion of a function from binary to its variable form (for SOP). """ temp = [] for i, m in enumerate(minterm): if m == 0: temp.append(Not(variables[i])) elif m == 1: temp.append(variables[i]) else: pass # ignore the 3s return And(temp) def _convert_to_varsPOS(maxterm, variables): """ Converts a term in the expansion of a function from binary to its variable form (for POS). """ temp = [] for i, m in enumerate(maxterm): if m == 1: temp.append(Not(variables[i])) elif m == 0: temp.append(variables[i]) else: pass # ignore the 3s return Or(temp) def _simplified_pairs(terms): """ Reduces a set of minterms, if possible, to a simplified set of minterms with one less variable in the terms using QM method. """ simplified_terms = [] todo = list(range(len(terms))) for i, ti in enumerate(terms[:-1]): for j_i, tj in enumerate(terms[(i + 1):]): index = _check_pair(ti, tj) if index != -1: todo[i] = todo[j_i + i + 1] = None newterm = ti[:] newterm[index] = 3 if newterm not in simplified_terms: simplified_terms.append(newterm) simplified_terms.extend( [terms[i] for i in [_ for _ in todo if _ is not None]]) return simplified_terms def _compare_term(minterm, term): """ Return True if a binary term is satisfied by the given term. Used for recognizing prime implicants. """ for i, x in enumerate(term): if x != 3 and x != minterm[i]: return False return True def _rem_redundancy(l1, terms): """ After the truth table has been sufficiently simplified, use the prime implicant table method to recognize and eliminate redundant pairs, and return the essential arguments. """ if len(terms): # Create dominating matrix dommatrix = [[0]len(l1) for n in range(len(terms))] for primei, prime in enumerate(l1): for termi, term in enumerate(terms): if _compare_term(term, prime): dommatrix[termi][primei] = 1 # Non-dominated prime implicants, dominated set to None ndprimeimplicants = list(range(len(l1))) # Non-dominated terms, dominated set to None ndterms = list(range(len(terms))) # Mark dominated rows and columns oldndterms = None oldndprimeimplicants = None while ndterms != oldndterms or \ ndprimeimplicants != oldndprimeimplicants: oldndterms = ndterms[:] oldndprimeimplicants = ndprimeimplicants[:] for rowi, row in enumerate(dommatrix): if ndterms[rowi] is not None: row = [row[i] for i in [_ for _ in ndprimeimplicants if _ is not None]] for row2i, row2 in enumerate(dommatrix): if rowi != row2i and ndterms[row2i] is not None: row2 = [row2[i] for i in [_ for _ in ndprimeimplicants if _ is not None]] if all(a >= b for (a, b) in zip(row2, row)): # row2 dominating row, keep row ndterms[row2i] = None for coli in range(len(l1)): if ndprimeimplicants[coli] is not None: col = [dommatrix[a][coli] for a in range(len(terms))] col = [col[i] for i in [_ for _ in oldndterms if _ is not None]] for col2i in range(len(l1)): if coli != col2i and \ ndprimeimplicants[col2i] is not None: col2 = [dommatrix[a][col2i] for a in range(len(terms))] col2 = [col2[i] for i in [_ for _ in oldndterms if _ is not None]] if all(a >= b for (a, b) in zip(col, col2)): # col dominating col2, keep col ndprimeimplicants[col2i] = None l1 = [l1[i] for i in [_ for _ in ndprimeimplicants if _ is not None]] return l1 else: return [] def _input_to_binlist(inputlist, variables): binlist = [] bits = len(variables) for val in inputlist: if isinstance(val, int): binlist.append(ibin(val, bits)) elif isinstance(val, dict): nonspecvars = list(variables) for key in val.keys(): nonspecvars.remove(key) for t in product([0, 1], repeat=len(nonspecvars)): d = dict(zip(nonspecvars, t)) d.update(val) binlist.append([d[v] for v in variables]) elif isinstance(val, (list, tuple)): if len(val) != bits: raise ValueError("Each term must contain {} bits as there are" "\n{} variables (or be an integer)." "".format(bits, bits)) binlist.append(list(val)) else: raise TypeError("A term list can only contain lists," " ints or dicts.") return binlist def SOPform(variables, minterms, dontcares=None): """ The SOPform function uses simplified_pairs and a redundant group- eliminating algorithm to convert the list of all input combos that generate '1' (the minterms) into the smallest Sum of Products form. The variables must be given as the first argument. Return a logical Or function (i.e., the "sum of products" or "SOP" form) that gives the desired outcome. If there are inputs that can be ignored, pass them as a list, too. The result will be one of the (perhaps many) functions that satisfy the conditions. Examples ======== >>> from sympy.logic import SOPform >>> from sympy import symbols >>> w, x, y, z = symbols('w x y z') >>> minterms = [[0, 0, 0, 1], [0, 0, 1, 1], ... [0, 1, 1, 1], [1, 0, 1, 1], [1, 1, 1, 1]] >>> dontcares = [[0, 0, 0, 0], [0, 0, 1, 0], [0, 1, 0, 1]] >>> SOPform([w, x, y, z], minterms, dontcares) (y & z) \| (z & ~w) The terms can also be represented as integers: >>> minterms = [1, 3, 7, 11, 15] >>> dontcares = [0, 2, 5] >>> SOPform([w, x, y, z], minterms, dontcares) (y & z) \| (z & ~w) They can also be specified using dicts, which does not have to be fully specified: >>> minterms = [{w: 0, x: 1}, {y: 1, z: 1, x: 0}] >>> SOPform([w, x, y, z], minterms) (x & ~w) \| (y & z & ~x) Or a combination: >>> minterms = [4, 7, 11, [1, 1, 1, 1]] >>> dontcares = [{w : 0, x : 0, y: 0}, 5] >>> SOPform([w, x, y, z], minterms, dontcares) (w & y & z) \| (x & y & z) \| (~w & ~y) References ========== .. [1] en.wikipedia.org/wiki/Quine-McCluskey_algorithm """ variables = [sympify(v) for v in variables] if minterms == []: return false minterms = _input_to_binlist(minterms, variables) dontcares = _input_to_binlist((dontcares or []), variables) for d in dontcares: if d in minterms: raise ValueError('%s in minterms is also in dontcares' % d) old = None new = minterms + dontcares while new != old: old = new new = _simplified_pairs(old) essential = _rem_redundancy(new, minterms) return Or([_convert_to_varsSOP(x, variables) for x in essential]) def POSform(variables, minterms, dontcares=None): """ The POSform function uses simplified_pairs and a redundant-group eliminating algorithm to convert the list of all input combinations that generate '1' (the minterms) into the smallest Product of Sums form. The variables must be given as the first argument. Return a logical And function (i.e., the "product of sums" or "POS" form) that gives the desired outcome. If there are inputs that can be ignored, pass them as a list, too. The result will be one of the (perhaps many) functions that satisfy the conditions. Examples ======== >>> from sympy.logic import POSform >>> from sympy import symbols >>> w, x, y, z = symbols('w x y z') >>> minterms = [[0, 0, 0, 1], [0, 0, 1, 1], [0, 1, 1, 1], ... [1, 0, 1, 1], [1, 1, 1, 1]] >>> dontcares = [[0, 0, 0, 0], [0, 0, 1, 0], [0, 1, 0, 1]] >>> POSform([w, x, y, z], minterms, dontcares) z & (y \| ~w) The terms can also be represented as integers: >>> minterms = [1, 3, 7, 11, 15] >>> dontcares = [0, 2, 5] >>> POSform([w, x, y, z], minterms, dontcares) z & (y \| ~w) They can also be specified using dicts, which does not have to be fully specified: >>> minterms = [{w: 0, x: 1}, {y: 1, z: 1, x: 0}] >>> POSform([w, x, y, z], minterms) (x \| y) & (x \| z) & (~w \| ~x) Or a combination: >>> minterms = [4, 7, 11, [1, 1, 1, 1]] >>> dontcares = [{w : 0, x : 0, y: 0}, 5] >>> POSform([w, x, y, z], minterms, dontcares) (w \| x) & (y \| ~w) & (z \| ~y) References ========== .. [1] en.wikipedia.org/wiki/Quine-McCluskey_algorithm """ variables = [sympify(v) for v in variables] if minterms == []: return false minterms = _input_to_binlist(minterms, variables) dontcares = _input_to_binlist((dontcares or []), variables) for d in dontcares: if d in minterms: raise ValueError('%s in minterms is also in dontcares' % d) maxterms = [] for t in product([0, 1], repeat=len(variables)): t = list(t) if (t not in minterms) and (t not in dontcares): maxterms.append(t) old = None new = maxterms + dontcares while new != old: old = new new = _simplified_pairs(old) essential = _rem_redundancy(new, maxterms) return And([_convert_to_varsPOS(x, variables) for x in essential]) def _find_predicates(expr): """Helper to find logical predicates in BooleanFunctions. A logical predicate is defined here as anything within a BooleanFunction that is not a BooleanFunction itself. """ if not isinstance(expr, BooleanFunction): return {expr} return set().union((_find_predicates(i) for i in expr.args)) def simplify_logic(expr, form=None, deep=True, force=False): """ This function simplifies a boolean function to its simplified version in SOP or POS form. The return type is an Or or And object in SymPy. Parameters ========== expr : string or boolean expression form : string ('cnf' or 'dnf') or None (default). If 'cnf' or 'dnf', the simplest expression in the corresponding normal form is returned; if None, the answer is returned according to the form with fewest args (in CNF by default). deep : boolean (default True) Indicates whether to recursively simplify any non-boolean functions contained within the input. force : boolean (default False) As the simplifications require exponential time in the number of variables, there is by default a limit on expressions with 8 variables. When the expression has more than 8 variables only symbolical simplification (controlled by ``deep``) is made. By setting force to ``True``, this limit is removed. Be aware that this can lead to very long simplification times. Examples ======== >>> from sympy.logic import simplify_logic >>> from sympy.abc import x, y, z >>> from sympy import S >>> b = (~x & ~y & ~z) \| ( ~x & ~y & z) >>> simplify_logic(b) ~x & ~y >>> S(b) (z & ~x & ~y) \| (~x & ~y & ~z) >>> simplify_logic(_) ~x & ~y """ if form not in (None, 'cnf', 'dnf'): raise ValueError("form can be cnf or dnf only") expr = sympify(expr) if deep: variables = _find_predicates(expr) from sympy.simplify.simplify import simplify s = [simplify(v) for v in variables] expr = expr.xreplace(dict(zip(variables, s))) if not isinstance(expr, BooleanFunction): return expr # get variables in case not deep or after doing # deep simplification since they may have changed variables = _find_predicates(expr) if not force and len(variables) > 8: return expr # group into constants and variable values c, v = sift(variables, lambda x: x in (True, False), binary=True) variables = c + v truthtable = [] # standardize constants to be 1 or 0 in keeping with truthtable c = [1 if i == True else 0 for i in c] for t in product([0, 1], repeat=len(v)): if expr.xreplace(dict(zip(v, t))) == True: truthtable.append(c + list(t)) big = len(truthtable) >= (2 * (len(variables) - 1)) if form == 'dnf' or form is None and big: return SOPform(variables, truthtable) return POSform(variables, truthtable) def _finger(eq): """ Assign a 5-item fingerprint to each symbol in the equation: [ # of times it appeared as a Symbol, # of times it appeared as a Not(symbol), # of times it appeared as a Symbol in an And or Or, # of times it appeared as a Not(Symbol) in an And or Or, sum of the number of arguments with which it appeared as a Symbol, counting Symbol as 1 and Not(Symbol) as 2 and counting self as 1 ] >>> from sympy.logic.boolalg import _finger as finger >>> from sympy import And, Or, Not >>> from sympy.abc import a, b, x, y >>> eq = Or(And(Not(y), a), And(Not(y), b), And(x, y)) >>> dict(finger(eq)) {(0, 0, 1, 0, 2): [x], (0, 0, 1, 0, 3): [a, b], (0, 0, 1, 2, 2): [y]} >>> dict(finger(x & ~y)) {(0, 1, 0, 0, 0): [y], (1, 0, 0, 0, 0): [x]} The equation must not have more than one level of nesting: >>> dict(finger(And(Or(x, y), y))) {(0, 0, 1, 0, 2): [x], (1, 0, 1, 0, 2): [y]} >>> dict(finger(And(Or(x, And(a, x)), y))) Traceback (most recent call last): ... NotImplementedError: unexpected level of nesting So y and x have unique fingerprints, but a and b do not. """ f = eq.free_symbols d = dict(list(zip(f, [[0] * 5 for fi in f]))) for a in eq.args: if a.is_Symbol: d[a][0] += 1 elif a.is_Not: d[a.args[0]][1] += 1 else: o = len(a.args) + sum(isinstance(ai, Not) for ai in a.args) for ai in a.args: if ai.is_Symbol: d[ai][2] += 1 d[ai][-1] += o elif ai.is_Not: d[ai.args[0]][3] += 1 else: raise NotImplementedError('unexpected level of nesting') inv = defaultdict(list) for k, v in ordered(iter(d.items())): inv[tuple(v)].append(k) return inv def bool_map(bool1, bool2): """ Return the simplified version of bool1, and the mapping of variables that makes the two expressions bool1 and bool2 represent the same logical behaviour for some correspondence between the variables of each. If more than one mappings of this sort exist, one of them is returned. For example, And(x, y) is logically equivalent to And(a, b) for the mapping {x: a, y:b} or {x: b, y:a}. If no such mapping exists, return False. Examples ======== >>> from sympy import SOPform, bool_map, Or, And, Not, Xor >>> from sympy.abc import w, x, y, z, a, b, c, d >>> function1 = SOPform([x, z, y],[[1, 0, 1], [0, 0, 1]]) >>> function2 = SOPform([a, b, c],[[1, 0, 1], [1, 0, 0]]) >>> bool_map(function1, function2) (y & ~z, {y: a, z: b}) The results are not necessarily unique, but they are canonical. Here, ``(w, z)`` could be ``(a, d)`` or ``(d, a)``: >>> eq = Or(And(Not(y), w), And(Not(y), z), And(x, y)) >>> eq2 = Or(And(Not(c), a), And(Not(c), d), And(b, c)) >>> bool_map(eq, eq2) ((x & y) \| (w & ~y) \| (z & ~y), {w: a, x: b, y: c, z: d}) >>> eq = And(Xor(a, b), c, And(c,d)) >>> bool_map(eq, eq.subs(c, x)) (c & d & (a \| b) & (~a \| ~b), {a: a, b: b, c: d, d: x}) """ def match(function1, function2): """Return the mapping that equates variables between two simplified boolean expressions if possible. By "simplified" we mean that a function has been denested and is either an And (or an Or) whose arguments are either symbols (x), negated symbols (Not(x)), or Or (or an And) whose arguments are only symbols or negated symbols. For example, And(x, Not(y), Or(w, Not(z))). Basic.match is not robust enough (see issue 4835) so this is a workaround that is valid for simplified boolean expressions """ # do some quick checks if function1.__class__ != function2.__class__: return None # maybe simplification makes them the same? if len(function1.args) != len(function2.args): return None # maybe simplification makes them the same? if function1.is_Symbol: return {function1: function2} # get the fingerprint dictionaries f1 = _finger(function1) f2 = _finger(function2) # more quick checks if len(f1) != len(f2): return False # assemble the match dictionary if possible matchdict = {} for k in f1.keys(): if k not in f2: return False if len(f1[k]) != len(f2[k]): return False for i, x in enumerate(f1[k]): matchdict[x] = f2[k][i] return matchdict a = simplify_logic(bool1) b = simplify_logic(bool2) m = match(a, b) if m: return a, m return m def simplify_patterns_and(): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.core import Wild from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt a = Wild('a') b = Wild('b') c = Wild('c') # With a better canonical fewer results are required _matchers_and = ((And(Eq(a, b), Ge(a, b)), Eq(a, b)), (And(Eq(a, b), Gt(a, b)), S.false), (And(Eq(a, b), Le(a, b)), Eq(a, b)), (And(Eq(a, b), Lt(a, b)), S.false), (And(Ge(a, b), Gt(a, b)), Gt(a, b)), (And(Ge(a, b), Le(a, b)), Eq(a, b)), (And(Ge(a, b), Lt(a, b)), S.false), (And(Ge(a, b), Ne(a, b)), Gt(a, b)), (And(Gt(a, b), Le(a, b)), S.false), (And(Gt(a, b), Lt(a, b)), S.false), (And(Gt(a, b), Ne(a, b)), Gt(a, b)), (And(Le(a, b), Lt(a, b)), Lt(a, b)), (And(Le(a, b), Ne(a, b)), Lt(a, b)), (And(Lt(a, b), Ne(a, b)), Lt(a, b)), # Min/max (And(Ge(a, b), Ge(a, c)), Ge(a, Max(b, c))), (And(Ge(a, b), Gt(a, c)), ITE(b > c, Ge(a, b), Gt(a, c))), (And(Gt(a, b), Gt(a, c)), Gt(a, Max(b, c))), (And(Le(a, b), Le(a, c)), Le(a, Min(b, c))), (And(Le(a, b), Lt(a, c)), ITE(b < c, Le(a, b), Lt(a, c))), (And(Lt(a, b), Lt(a, c)), Lt(a, Min(b, c))), # Sign (And(Eq(a, b), Eq(a, -b)), And(Eq(a, S(0)), Eq(b, S(0)))), ) return _matchers_and def simplify_patterns_or(): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.core import Wild from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt a = Wild('a') b = Wild('b') c = Wild('c') _matchers_or = ((Or(Eq(a, b), Ge(a, b)), Ge(a, b)), (Or(Eq(a, b), Gt(a, b)), Ge(a, b)), (Or(Eq(a, b), Le(a, b)), Le(a, b)), (Or(Eq(a, b), Lt(a, b)), Le(a, b)), (Or(Ge(a, b), Gt(a, b)), Ge(a, b)), (Or(Ge(a, b), Le(a, b)), S.true), (Or(Ge(a, b), Lt(a, b)), S.true), (Or(Ge(a, b), Ne(a, b)), S.true), (Or(Gt(a, b), Le(a, b)), S.true), (Or(Gt(a, b), Lt(a, b)), Ne(a, b)), (Or(Gt(a, b), Ne(a, b)), Ne(a, b)), (Or(Le(a, b), Lt(a, b)), Le(a, b)), (Or(Le(a, b), Ne(a, b)), S.true), (Or(Lt(a, b), Ne(a, b)), Ne(a, b)), # Min/max (Or(Ge(a, b), Ge(a, c)), Ge(a, Min(b, c))), (Or(Ge(a, b), Gt(a, c)), ITE(b > c, Gt(a, c), Ge(a, b))), (Or(Gt(a, b), Gt(a, c)), Gt(a, Min(b, c))), (Or(Le(a, b), Le(a, c)), Le(a, Max(b, c))), (Or(Le(a, b), Lt(a, c)), ITE(b >= c, Le(a, b), Lt(a, c))), (Or(Lt(a, b), Lt(a, c)), Lt(a, Max(b, c))), ) return _matchers_or def simplify_patterns_xor(): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.core import Wild from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt a = Wild('a') b = Wild('b') c = Wild('c') _matchers_xor = ((Xor(Eq(a, b), Ge(a, b)), Gt(a, b)), (Xor(Eq(a, b), Gt(a, b)), Ge(a, b)), (Xor(Eq(a, b), Le(a, b)), Lt(a, b)), (Xor(Eq(a, b), Lt(a, b)), Le(a, b)), (Xor(Ge(a, b), Gt(a, b)), Eq(a, b)), (Xor(Ge(a, b), Le(a, b)), Ne(a, b)), (Xor(Ge(a, b), Lt(a, b)), S.true), (Xor(Ge(a, b), Ne(a, b)), Le(a, b)), (Xor(Gt(a, b), Le(a, b)), S.true), (Xor(Gt(a, b), Lt(a, b)), Ne(a, b)), (Xor(Gt(a, b), Ne(a, b)), Lt(a, b)), (Xor(Le(a, b), Lt(a, b)), Eq(a, b)), (Xor(Le(a, b), Ne(a, b)), Ge(a, b)), (Xor(Lt(a, b), Ne(a, b)), Gt(a, b)), # Min/max (Xor(Ge(a, b), Ge(a, c)), And(Ge(a, Min(b, c)), Lt(a, Max(b, c)))), (Xor(Ge(a, b), Gt(a, c)), ITE(b > c, And(Gt(a, c), Lt(a, b)), And(Ge(a, b), Le(a, c)))), (Xor(Gt(a, b), Gt(a, c)), And(Gt(a, Min(b, c)), Le(a, Max(b, c)))), (Xor(Le(a, b), Le(a, c)), And(Le(a, Max(b, c)), Gt(a, Min(b, c)))), (Xor(Le(a, b), Lt(a, c)), ITE(b < c, And(Lt(a, c), Gt(a, b)), And(Le(a, b), Ge(a, c)))), (Xor(Lt(a, b), Lt(a, c)), And(Lt(a, Max(b, c)), Ge(a, Min(b, c)))), ) return _matchers_xor
0d59f01ba22fd456d418f95aac125480d0401fc712785c82a06f868c334400f7	"""A module that handles matrices. Includes functions for fast creating matrices like zero, one/eye, random matrix, etc. """ from .common import ShapeError, NonSquareMatrixError from .dense import ( GramSchmidt, casoratian, diag, eye, hessian, jordan_cell, list2numpy, matrix2numpy, matrix_multiply_elementwise, ones, randMatrix, rot_axis1, rot_axis2, rot_axis3, symarray, wronskian, zeros) from .dense import MutableDenseMatrix from .matrices import DeferredVector, MatrixBase Matrix = MutableMatrix = MutableDenseMatrix from .sparse import MutableSparseMatrix from .sparsetools import banded from .immutable import ImmutableDenseMatrix, ImmutableSparseMatrix ImmutableMatrix = ImmutableDenseMatrix SparseMatrix = MutableSparseMatrix from .expressions import ( MatrixSlice, BlockDiagMatrix, BlockMatrix, FunctionMatrix, Identity, Inverse, MatAdd, MatMul, MatPow, MatrixExpr, MatrixSymbol, Trace, Transpose, ZeroMatrix, OneMatrix, blockcut, block_collapse, matrix_symbols, Adjoint, hadamard_product, HadamardProduct, HadamardPower, Determinant, det, diagonalize_vector, DiagonalizeVector, DiagonalMatrix, DiagonalOf, trace, DotProduct, kronecker_product, KroneckerProduct)
cc38817355c3b993604076fed8493c435b24cd67fb03e5a86be119fad08b783f	from __future__ import division, print_function from sympy.core import Basic, Dict, Integer, S, Tuple, sympify from sympy.core.cache import cacheit from sympy.core.sympify import converter as sympify_converter from sympy.matrices.dense import DenseMatrix from sympy.matrices.expressions import MatrixExpr from sympy.matrices.matrices import MatrixBase from sympy.matrices.sparse import MutableSparseMatrix, SparseMatrix def sympify_matrix(arg): return arg.as_immutable() sympify_converter[MatrixBase] = sympify_matrix class ImmutableDenseMatrix(DenseMatrix, MatrixExpr): """Create an immutable version of a matrix. Examples ======== >>> from sympy import eye >>> from sympy.matrices import ImmutableMatrix >>> ImmutableMatrix(eye(3)) Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) >>> _[0, 0] = 42 Traceback (most recent call last): ... TypeError: Cannot set values of ImmutableDenseMatrix """ # MatrixExpr is set as NotIterable, but we want explicit matrices to be # iterable _iterable = True _class_priority = 8 _op_priority = 10.001 def __new__(cls, args, kwargs): return cls._new(args, *kwargs) __hash__ = MatrixExpr.__hash__ @classmethod def _new(cls, args, *kwargs): if len(args) == 1 and isinstance(args[0], ImmutableDenseMatrix): return args[0] if kwargs.get('copy', True) is False: if len(args) != 3: raise TypeError("'copy=False' requires a matrix be initialized as rows,cols,[list]") rows, cols, flat_list = args else: rows, cols, flat_list = cls._handle_creation_inputs(args, *kwargs) flat_list = list(flat_list) # create a shallow copy rows = Integer(rows) cols = Integer(cols) if not isinstance(flat_list, Tuple): flat_list = Tuple(flat_list) return Basic.__new__(cls, rows, cols, flat_list) @property def _mat(self): # self.args[2] is a Tuple. Access to the elements # of a tuple are significantly faster than Tuple, # so return the internal tuple. return self.args[2].args def _entry(self, i, j, *kwargs): return DenseMatrix.__getitem__(self, (i, j)) def __setitem__(self, args): raise TypeError("Cannot set values of {}".format(self.__class__)) def _eval_Eq(self, other): """Helper method for Equality with matrices. Relational automatically converts matrices to ImmutableDenseMatrix instances, so this method only applies here. Returns True if the matrices are definitively the same, False if they are definitively different, and None if undetermined (e.g. if they contain Symbols). Returning None triggers default handling of Equalities. """ if not hasattr(other, 'shape') or self.shape != other.shape: return S.false if isinstance(other, MatrixExpr) and not isinstance( other, ImmutableDenseMatrix): return None diff = self - other return sympify(diff.is_zero) def _eval_extract(self, rowsList, colsList): # self._mat is a Tuple. It is slightly faster to index a # tuple over a Tuple, so grab the internal tuple directly mat = self._mat cols = self.cols indices = (i * cols + j for i in rowsList for j in colsList) return self._new(len(rowsList), len(colsList), Tuple((mat[i] for i in indices), sympify=False), copy=False) @property def cols(self): return int(self.args[1]) @property def rows(self): return int(self.args[0]) @property def shape(self): return tuple(int(i) for i in self.args[:2]) def is_diagonalizable(self, reals_only=False, kwargs): return super(ImmutableDenseMatrix, self).is_diagonalizable( reals_only=reals_only, kwargs) is_diagonalizable.__doc__ = DenseMatrix.is_diagonalizable.__doc__ is_diagonalizable = cacheit(is_diagonalizable) # This is included after the class definition as a workaround for issue 7213. # See https://github.com/sympy/sympy/issues/7213 # the object is non-zero # See https://github.com/sympy/sympy/issues/7213 ImmutableDenseMatrix.is_zero = DenseMatrix.is_zero # make sure ImmutableDenseMatrix is aliased as ImmutableMatrix ImmutableMatrix = ImmutableDenseMatrix class ImmutableSparseMatrix(SparseMatrix, Basic): """Create an immutable version of a sparse matrix. Examples ======== >>> from sympy import eye >>> from sympy.matrices.immutable import ImmutableSparseMatrix >>> ImmutableSparseMatrix(1, 1, {}) Matrix([[0]]) >>> ImmutableSparseMatrix(eye(3)) Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) >>> _[0, 0] = 42 Traceback (most recent call last): ... TypeError: Cannot set values of ImmutableSparseMatrix >>> _.shape (3, 3) """ is_Matrix = True _class_priority = 9 @classmethod def _new(cls, args, *kwargs): s = MutableSparseMatrix(args) rows = Integer(s.rows) cols = Integer(s.cols) mat = Dict(s._smat) obj = Basic.__new__(cls, rows, cols, mat) obj.rows = s.rows obj.cols = s.cols obj._smat = s._smat return obj def __new__(cls, args, kwargs): return cls._new(args, *kwargs) def __setitem__(self, args): raise TypeError("Cannot set values of ImmutableSparseMatrix") def __hash__(self): return hash((type(self).__name__,) + (self.shape, tuple(self._smat))) _eval_Eq = ImmutableDenseMatrix._eval_Eq def is_diagonalizable(self, reals_only=False, kwargs): return super(ImmutableSparseMatrix, self).is_diagonalizable( reals_only=reals_only, kwargs) is_diagonalizable.__doc__ = SparseMatrix.is_diagonalizable.__doc__ is_diagonalizable = cacheit(is_diagonalizable)
f51e19b96615d19960fd53c27d5c6008e50613ebc244255aaa674771982fc4a3	""" Basic methods common to all matrices to be used when creating more advanced matrices (e.g., matrices over rings, etc.). """ from __future__ import division, print_function from collections import defaultdict from inspect import isfunction from sympy.assumptions.refine import refine from sympy.core.basic import Atom from sympy.core.compatibility import ( Iterable, as_int, is_sequence, range, reduce) from sympy.core.decorators import call_highest_priority from sympy.core.expr import Expr from sympy.core.function import count_ops from sympy.core.singleton import S from sympy.core.symbol import Symbol from sympy.core.sympify import sympify from sympy.functions import Abs from sympy.simplify import simplify as _simplify from sympy.utilities.exceptions import SymPyDeprecationWarning from sympy.utilities.iterables import flatten from sympy.utilities.misc import filldedent class MatrixError(Exception): pass class ShapeError(ValueError, MatrixError): """Wrong matrix shape""" pass class NonSquareMatrixError(ShapeError): pass class MatrixRequired(object): """All subclasses of matrix objects must implement the required matrix properties listed here.""" rows = None cols = None shape = None _simplify = None @classmethod def _new(cls, args, kwargs): """`_new` must, at minimum, be callable as `_new(rows, cols, mat) where mat is a flat list of the elements of the matrix.""" raise NotImplementedError("Subclasses must implement this.") def __eq__(self, other): raise NotImplementedError("Subclasses must implement this.") def __getitem__(self, key): """Implementations of __getitem__ should accept ints, in which case the matrix is indexed as a flat list, tuples (i,j) in which case the (i,j) entry is returned, slices, or mixed tuples (a,b) where a and b are any combintion of slices and integers.""" raise NotImplementedError("Subclasses must implement this.") def __len__(self): """The total number of entries in the matrix.""" raise NotImplementedError("Subclasses must implement this.") class MatrixShaping(MatrixRequired): """Provides basic matrix shaping and extracting of submatrices""" def _eval_col_del(self, col): def entry(i, j): return self[i, j] if j < col else self[i, j + 1] return self._new(self.rows, self.cols - 1, entry) def _eval_col_insert(self, pos, other): cols = self.cols def entry(i, j): if j < pos: return self[i, j] elif pos <= j < pos + other.cols: return other[i, j - pos] return self[i, j - other.cols] return self._new(self.rows, self.cols + other.cols, lambda i, j: entry(i, j)) def _eval_col_join(self, other): rows = self.rows def entry(i, j): if i < rows: return self[i, j] return other[i - rows, j] return classof(self, other)._new(self.rows + other.rows, self.cols, lambda i, j: entry(i, j)) def _eval_extract(self, rowsList, colsList): mat = list(self) cols = self.cols indices = (i cols + j for i in rowsList for j in colsList) return self._new(len(rowsList), len(colsList), list(mat[i] for i in indices)) def _eval_get_diag_blocks(self): sub_blocks = [] def recurse_sub_blocks(M): i = 1 while i <= M.shape[0]: if i == 1: to_the_right = M[0, i:] to_the_bottom = M[i:, 0] else: to_the_right = M[:i, i:] to_the_bottom = M[i:, :i] if any(to_the_right) or any(to_the_bottom): i += 1 continue else: sub_blocks.append(M[:i, :i]) if M.shape == M[:i, :i].shape: return else: recurse_sub_blocks(M[i:, i:]) return recurse_sub_blocks(self) return sub_blocks def _eval_row_del(self, row): def entry(i, j): return self[i, j] if i < row else self[i + 1, j] return self._new(self.rows - 1, self.cols, entry) def _eval_row_insert(self, pos, other): entries = list(self) insert_pos = pos * self.cols entries[insert_pos:insert_pos] = list(other) return self._new(self.rows + other.rows, self.cols, entries) def _eval_row_join(self, other): cols = self.cols def entry(i, j): if j < cols: return self[i, j] return other[i, j - cols] return classof(self, other)._new(self.rows, self.cols + other.cols, lambda i, j: entry(i, j)) def _eval_tolist(self): return [list(self[i,:]) for i in range(self.rows)] def _eval_vec(self): rows = self.rows def entry(n, _): # we want to read off the columns first j = n // rows i = n - j * rows return self[i, j] return self._new(len(self), 1, entry) def col_del(self, col): """Delete the specified column.""" if col < 0: col += self.cols if not 0 <= col < self.cols: raise ValueError("Column {} out of range.".format(col)) return self._eval_col_del(col) def col_insert(self, pos, other): """Insert one or more columns at the given column position. Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(3, 1) >>> M.col_insert(1, V) Matrix([ [0, 1, 0, 0], [0, 1, 0, 0], [0, 1, 0, 0]]) See Also ======== col row_insert """ # Allows you to build a matrix even if it is null matrix if not self: return type(self)(other) pos = as_int(pos) if pos < 0: pos = self.cols + pos if pos < 0: pos = 0 elif pos > self.cols: pos = self.cols if self.rows != other.rows: raise ShapeError( "`self` and `other` must have the same number of rows.") return self._eval_col_insert(pos, other) def col_join(self, other): """Concatenates two matrices along self's last and other's first row. Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(1, 3) >>> M.col_join(V) Matrix([ [0, 0, 0], [0, 0, 0], [0, 0, 0], [1, 1, 1]]) See Also ======== col row_join """ # A null matrix can always be stacked (see #10770) if self.rows == 0 and self.cols != other.cols: return self._new(0, other.cols, []).col_join(other) if self.cols != other.cols: raise ShapeError( "`self` and `other` must have the same number of columns.") return self._eval_col_join(other) def col(self, j): """Elementary column selector. Examples ======== >>> from sympy import eye >>> eye(2).col(0) Matrix([ [1], [0]]) See Also ======== row col_op col_swap col_del col_join col_insert """ return self[:, j] def extract(self, rowsList, colsList): """Return a submatrix by specifying a list of rows and columns. Negative indices can be given. All indices must be in the range -n <= i < n where n is the number of rows or columns. Examples ======== >>> from sympy import Matrix >>> m = Matrix(4, 3, range(12)) >>> m Matrix([ [0, 1, 2], [3, 4, 5], [6, 7, 8], [9, 10, 11]]) >>> m.extract([0, 1, 3], [0, 1]) Matrix([ [0, 1], [3, 4], [9, 10]]) Rows or columns can be repeated: >>> m.extract([0, 0, 1], [-1]) Matrix([ [2], [2], [5]]) Every other row can be taken by using range to provide the indices: >>> m.extract(range(0, m.rows, 2), [-1]) Matrix([ [2], [8]]) RowsList or colsList can also be a list of booleans, in which case the rows or columns corresponding to the True values will be selected: >>> m.extract([0, 1, 2, 3], [True, False, True]) Matrix([ [0, 2], [3, 5], [6, 8], [9, 11]]) """ if not is_sequence(rowsList) or not is_sequence(colsList): raise TypeError("rowsList and colsList must be iterable") # ensure rowsList and colsList are lists of integers if rowsList and all(isinstance(i, bool) for i in rowsList): rowsList = [index for index, item in enumerate(rowsList) if item] if colsList and all(isinstance(i, bool) for i in colsList): colsList = [index for index, item in enumerate(colsList) if item] # ensure everything is in range rowsList = [a2idx(k, self.rows) for k in rowsList] colsList = [a2idx(k, self.cols) for k in colsList] return self._eval_extract(rowsList, colsList) def get_diag_blocks(self): """Obtains the square sub-matrices on the main diagonal of a square matrix. Useful for inverting symbolic matrices or solving systems of linear equations which may be decoupled by having a block diagonal structure. Examples ======== >>> from sympy import Matrix >>> from sympy.abc import x, y, z >>> A = Matrix([[1, 3, 0, 0], [y, zz, 0, 0], [0, 0, x, 0], [0, 0, 0, 0]]) >>> a1, a2, a3 = A.get_diag_blocks() >>> a1 Matrix([ [1, 3], [y, z2]]) >>> a2 Matrix([[x]]) >>> a3 Matrix([[0]]) """ return self._eval_get_diag_blocks() @classmethod def hstack(cls, args): """Return a matrix formed by joining args horizontally (i.e. by repeated application of row_join). Examples ======== >>> from sympy.matrices import Matrix, eye >>> Matrix.hstack(eye(2), 2eye(2)) Matrix([ [1, 0, 2, 0], [0, 1, 0, 2]]) """ if len(args) == 0: return cls._new() kls = type(args[0]) return reduce(kls.row_join, args) def reshape(self, rows, cols): """Reshape the matrix. Total number of elements must remain the same. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 3, lambda i, j: 1) >>> m Matrix([ [1, 1, 1], [1, 1, 1]]) >>> m.reshape(1, 6) Matrix([[1, 1, 1, 1, 1, 1]]) >>> m.reshape(3, 2) Matrix([ [1, 1], [1, 1], [1, 1]]) """ if self.rows self.cols != rows * cols: raise ValueError("Invalid reshape parameters %d %d" % (rows, cols)) return self._new(rows, cols, lambda i, j: self[i * cols + j]) def row_del(self, row): """Delete the specified row.""" if row < 0: row += self.rows if not 0 <= row < self.rows: raise ValueError("Row {} out of range.".format(row)) return self._eval_row_del(row) def row_insert(self, pos, other): """Insert one or more rows at the given row position. Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(1, 3) >>> M.row_insert(1, V) Matrix([ [0, 0, 0], [1, 1, 1], [0, 0, 0], [0, 0, 0]]) See Also ======== row col_insert """ # Allows you to build a matrix even if it is null matrix if not self: return self._new(other) pos = as_int(pos) if pos < 0: pos = self.rows + pos if pos < 0: pos = 0 elif pos > self.rows: pos = self.rows if self.cols != other.cols: raise ShapeError( "`self` and `other` must have the same number of columns.") return self._eval_row_insert(pos, other) def row_join(self, other): """Concatenates two matrices along self's last and rhs's first column Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(3, 1) >>> M.row_join(V) Matrix([ [0, 0, 0, 1], [0, 0, 0, 1], [0, 0, 0, 1]]) See Also ======== row col_join """ # A null matrix can always be stacked (see #10770) if self.cols == 0 and self.rows != other.rows: return self._new(other.rows, 0, []).row_join(other) if self.rows != other.rows: raise ShapeError( "`self` and `rhs` must have the same number of rows.") return self._eval_row_join(other) def diagonal(self, k=0): """Returns the kth diagonal of self. The main diagonal corresponds to `k=0`; diagonals above and below correspond to `k > 0` and `k < 0`, respectively. The values of `self[i, j]` for which `j - i = k`, are returned in order of increasing `i + j`, starting with `i + j = \|k\|`. Examples ======== >>> from sympy import Matrix, SparseMatrix >>> m = Matrix(3, 3, lambda i, j: j - i); m Matrix([ [ 0, 1, 2], [-1, 0, 1], [-2, -1, 0]]) >>> _.diagonal() Matrix([[0, 0, 0]]) >>> m.diagonal(1) Matrix([[1, 1]]) >>> m.diagonal(-2) Matrix([[-2]]) Even though the diagonal is returned as a Matrix, the element retrieval can be done with a single index: >>> Matrix.diag(1, 2, 3).diagonal()[1] # instead of [0, 1] 2 See Also ======== diag - to create a diagonal matrix """ rv = [] k = as_int(k) r = 0 if k > 0 else -k c = 0 if r else k while True: if r == self.rows or c == self.cols: break rv.append(self[r, c]) r += 1 c += 1 if not rv: raise ValueError(filldedent(''' The %s diagonal is out of range [%s, %s]''' % ( k, 1 - self.rows, self.cols - 1))) return self._new(1, len(rv), rv) def row(self, i): """Elementary row selector. Examples ======== >>> from sympy import eye >>> eye(2).row(0) Matrix([[1, 0]]) See Also ======== col row_op row_swap row_del row_join row_insert """ return self[i, :] @property def shape(self): """The shape (dimensions) of the matrix as the 2-tuple (rows, cols). Examples ======== >>> from sympy.matrices import zeros >>> M = zeros(2, 3) >>> M.shape (2, 3) >>> M.rows 2 >>> M.cols 3 """ return (self.rows, self.cols) def tolist(self): """Return the Matrix as a nested Python list. Examples ======== >>> from sympy import Matrix, ones >>> m = Matrix(3, 3, range(9)) >>> m Matrix([ [0, 1, 2], [3, 4, 5], [6, 7, 8]]) >>> m.tolist() [[0, 1, 2], [3, 4, 5], [6, 7, 8]] >>> ones(3, 0).tolist() [[], [], []] When there are no rows then it will not be possible to tell how many columns were in the original matrix: >>> ones(0, 3).tolist() [] """ if not self.rows: return [] if not self.cols: return [[] for i in range(self.rows)] return self._eval_tolist() def vec(self): """Return the Matrix converted into a one column matrix by stacking columns Examples ======== >>> from sympy import Matrix >>> m=Matrix([[1, 3], [2, 4]]) >>> m Matrix([ [1, 3], [2, 4]]) >>> m.vec() Matrix([ [1], [2], [3], [4]]) See Also ======== vech """ return self._eval_vec() @classmethod def vstack(cls, args): """Return a matrix formed by joining args vertically (i.e. by repeated application of col_join). Examples ======== >>> from sympy.matrices import Matrix, eye >>> Matrix.vstack(eye(2), 2eye(2)) Matrix([ [1, 0], [0, 1], [2, 0], [0, 2]]) """ if len(args) == 0: return cls._new() kls = type(args[0]) return reduce(kls.col_join, args) class MatrixSpecial(MatrixRequired): """Construction of special matrices""" @classmethod def _eval_diag(cls, rows, cols, diag_dict): """diag_dict is a defaultdict containing all the entries of the diagonal matrix.""" def entry(i, j): return diag_dict[(i, j)] return cls._new(rows, cols, entry) @classmethod def _eval_eye(cls, rows, cols): def entry(i, j): return S.One if i == j else S.Zero return cls._new(rows, cols, entry) @classmethod def _eval_jordan_block(cls, rows, cols, eigenvalue, band='upper'): if band == 'lower': def entry(i, j): if i == j: return eigenvalue elif j + 1 == i: return S.One return S.Zero else: def entry(i, j): if i == j: return eigenvalue elif i + 1 == j: return S.One return S.Zero return cls._new(rows, cols, entry) @classmethod def _eval_ones(cls, rows, cols): def entry(i, j): return S.One return cls._new(rows, cols, entry) @classmethod def _eval_zeros(cls, rows, cols): def entry(i, j): return S.Zero return cls._new(rows, cols, entry) @classmethod def diag(kls, args, kwargs): """Returns a matrix with the specified diagonal. If matrices are passed, a block-diagonal matrix is created (i.e. the "direct sum" of the matrices). kwargs ====== rows : rows of the resulting matrix; computed if not given. cols : columns of the resulting matrix; computed if not given. cls : class for the resulting matrix unpack : bool which, when True (default), unpacks a single sequence rather than interpreting it as a Matrix. strict : bool which, when False (default), allows Matrices to have variable-length rows. Examples ======== >>> from sympy.matrices import Matrix >>> Matrix.diag(1, 2, 3) Matrix([ [1, 0, 0], [0, 2, 0], [0, 0, 3]]) The current default is to unpack a single sequence. If this is not desired, set `unpack=False` and it will be interpreted as a matrix. >>> Matrix.diag([1, 2, 3]) == Matrix.diag(1, 2, 3) True When more than one element is passed, each is interpreted as something to put on the diagonal. Lists are converted to matricecs. Filling of the diagonal always continues from the bottom right hand corner of the previous item: this will create a block-diagonal matrix whether the matrices are square or not. >>> col = [1, 2, 3] >>> row = [[4, 5]] >>> Matrix.diag(col, row) Matrix([ [1, 0, 0], [2, 0, 0], [3, 0, 0], [0, 4, 5]]) When `unpack` is False, elements within a list need not all be of the same length. Setting `strict` to True would raise a ValueError for the following: >>> Matrix.diag([[1, 2, 3], [4, 5], [6]], unpack=False) Matrix([ [1, 2, 3], [4, 5, 0], [6, 0, 0]]) The type of the returned matrix can be set with the ``cls`` keyword. >>> from sympy.matrices import ImmutableMatrix >>> from sympy.utilities.misc import func_name >>> func_name(Matrix.diag(1, cls=ImmutableMatrix)) 'ImmutableDenseMatrix' A zero dimension matrix can be used to position the start of the filling at the start of an arbitrary row or column: >>> from sympy import ones >>> r2 = ones(0, 2) >>> Matrix.diag(r2, 1, 2) Matrix([ [0, 0, 1, 0], [0, 0, 0, 2]]) See Also ======== eye diagonal - to extract a diagonal .dense.diag .expressions.blockmatrix.BlockMatrix """ from sympy.matrices.matrices import MatrixBase from sympy.matrices.dense import Matrix from sympy.matrices.sparse import SparseMatrix klass = kwargs.get('cls', kls) strict = kwargs.get('strict', False) # lists -> Matrices unpack = kwargs.get('unpack', True) # unpack single sequence if unpack and len(args) == 1 and is_sequence(args[0]) and \ not isinstance(args[0], MatrixBase): args = args[0] # fill a default dict with the diagonal entries diag_entries = defaultdict(int) rmax = cmax = 0 # keep track of the biggest index seen for m in args: if isinstance(m, list): if strict: # if malformed, Matrix will raise an error _ = Matrix(m) r, c = _.shape m = _.tolist() else: m = SparseMatrix(m) for (i, j), _ in m._smat.items(): diag_entries[(i + rmax, j + cmax)] = _ r, c = m.shape m = [] # to skip process below elif hasattr(m, 'shape'): # a Matrix # convert to list of lists r, c = m.shape m = m.tolist() else: # in this case, we're a single value diag_entries[(rmax, cmax)] = m rmax += 1 cmax += 1 continue # process list of lists for i in range(len(m)): for j, _ in enumerate(m[i]): diag_entries[(i + rmax, j + cmax)] = _ rmax += r cmax += c rows = kwargs.get('rows', None) cols = kwargs.get('cols', None) if rows is None: rows, cols = cols, rows if rows is None: rows, cols = rmax, cmax else: cols = rows if cols is None else cols if rows < rmax or cols < cmax: raise ValueError(filldedent(''' The constructed matrix is {} x {} but a size of {} x {} was specified.'''.format(rmax, cmax, rows, cols))) return klass._eval_diag(rows, cols, diag_entries) @classmethod def eye(kls, rows, cols=None, kwargs): """Returns an identity matrix. Args ==== rows : rows of the matrix cols : cols of the matrix (if None, cols=rows) kwargs ====== cls : class of the returned matrix """ if cols is None: cols = rows klass = kwargs.get('cls', kls) rows, cols = as_int(rows), as_int(cols) return klass._eval_eye(rows, cols) @classmethod def jordan_block(kls, size=None, eigenvalue=None, kwargs): """Returns a Jordan block Parameters ========== size : Integer, optional Specifies the shape of the Jordan block matrix. eigenvalue : Number or Symbol Specifies the value for the main diagonal of the matrix. .. note:: The keyword ``eigenval`` is also specified as an alias of this keyword, but it is not recommended to use. We may deprecate the alias in later release. band : 'upper' or 'lower', optional Specifies the position of the off-diagonal to put `1` s on. cls : Matrix, optional Specifies the matrix class of the output form. If it is not specified, the class type where the method is being executed on will be returned. rows, cols : Integer, optional Specifies the shape of the Jordan block matrix. See Notes section for the details of how these key works. .. note:: This feature will be deprecated in the future. Returns ======= Matrix A Jordan block matrix. Raises ====== ValueError If insufficient arguments are given for matrix size specification, or no eigenvalue is given. Examples ======== Creating a default Jordan block: >>> from sympy import Matrix >>> from sympy.abc import x >>> Matrix.jordan_block(4, x) Matrix([ [x, 1, 0, 0], [0, x, 1, 0], [0, 0, x, 1], [0, 0, 0, x]]) Creating an alternative Jordan block matrix where `1` is on lower off-diagonal: >>> Matrix.jordan_block(4, x, band='lower') Matrix([ [x, 0, 0, 0], [1, x, 0, 0], [0, 1, x, 0], [0, 0, 1, x]]) Creating a Jordan block with keyword arguments >>> Matrix.jordan_block(size=4, eigenvalue=x) Matrix([ [x, 1, 0, 0], [0, x, 1, 0], [0, 0, x, 1], [0, 0, 0, x]]) Notes ===== .. note:: This feature will be deprecated in the future. The keyword arguments ``size``, ``rows``, ``cols`` relates to the Jordan block size specifications. If you want to create a square Jordan block, specify either one of the three arguments. If you want to create a rectangular Jordan block, specify ``rows`` and ``cols`` individually. +--------------------------------+---------------------+ \| Arguments Given \| Matrix Shape \| +----------+----------+----------+----------+----------+ \| size \| rows \| cols \| rows \| cols \| +==========+==========+==========+==========+==========+ \| size \| Any \| size \| size \| +----------+----------+----------+----------+----------+ \| \| None \| ValueError \| \| +----------+----------+----------+----------+ \| None \| rows \| None \| rows \| rows \| \| +----------+----------+----------+----------+ \| \| None \| cols \| cols \| cols \| + +----------+----------+----------+----------+ \| \| rows \| cols \| rows \| cols \| +----------+----------+----------+----------+----------+ References ========== .. [1] https://en.wikipedia.org/wiki/Jordan_matrix """ if 'rows' in kwargs or 'cols' in kwargs: SymPyDeprecationWarning( feature="Keyword arguments 'rows' or 'cols'", issue=16102, useinstead="a more generic banded matrix constructor", deprecated_since_version="1.4" ).warn() klass = kwargs.pop('cls', kls) band = kwargs.pop('band', 'upper') rows = kwargs.pop('rows', None) cols = kwargs.pop('cols', None) eigenval = kwargs.get('eigenval', None) if eigenvalue is None and eigenval is None: raise ValueError("Must supply an eigenvalue") elif eigenvalue != eigenval and None not in (eigenval, eigenvalue): raise ValueError( "Inconsistent values are given: 'eigenval'={}, " "'eigenvalue'={}".format(eigenval, eigenvalue)) else: if eigenval is not None: eigenvalue = eigenval if (size, rows, cols) == (None, None, None): raise ValueError("Must supply a matrix size") if size is not None: rows, cols = size, size elif rows is not None and cols is None: cols = rows elif cols is not None and rows is None: rows = cols rows, cols = as_int(rows), as_int(cols) return klass._eval_jordan_block(rows, cols, eigenvalue, band) @classmethod def ones(kls, rows, cols=None, kwargs): """Returns a matrix of ones. Args ==== rows : rows of the matrix cols : cols of the matrix (if None, cols=rows) kwargs ====== cls : class of the returned matrix """ if cols is None: cols = rows klass = kwargs.get('cls', kls) rows, cols = as_int(rows), as_int(cols) return klass._eval_ones(rows, cols) @classmethod def zeros(kls, rows, cols=None, kwargs): """Returns a matrix of zeros. Args ==== rows : rows of the matrix cols : cols of the matrix (if None, cols=rows) kwargs ====== cls : class of the returned matrix """ if cols is None: cols = rows klass = kwargs.get('cls', kls) rows, cols = as_int(rows), as_int(cols) return klass._eval_zeros(rows, cols) class MatrixProperties(MatrixRequired): """Provides basic properties of a matrix.""" def _eval_atoms(self, types): result = set() for i in self: result.update(i.atoms(types)) return result def _eval_free_symbols(self): return set().union((i.free_symbols for i in self)) def _eval_has(self, patterns): return any(a.has(patterns) for a in self) def _eval_is_anti_symmetric(self, simpfunc): if not all(simpfunc(self[i, j] + self[j, i]).is_zero for i in range(self.rows) for j in range(self.cols)): return False return True def _eval_is_diagonal(self): for i in range(self.rows): for j in range(self.cols): if i != j and self[i, j]: return False return True # _eval_is_hermitian is called by some general sympy # routines and has a different args signature. Make # sure the names don't clash by adding `_matrix_` in name. def _eval_is_matrix_hermitian(self, simpfunc): mat = self._new(self.rows, self.cols, lambda i, j: simpfunc(self[i, j] - self[j, i].conjugate())) return mat.is_zero def _eval_is_Identity(self): def dirac(i, j): if i == j: return 1 return 0 return all(self[i, j] == dirac(i, j) for i in range(self.rows) for j in range(self.cols)) def _eval_is_lower_hessenberg(self): return all(self[i, j].is_zero for i in range(self.rows) for j in range(i + 2, self.cols)) def _eval_is_lower(self): return all(self[i, j].is_zero for i in range(self.rows) for j in range(i + 1, self.cols)) def _eval_is_symbolic(self): return self.has(Symbol) def _eval_is_symmetric(self, simpfunc): mat = self._new(self.rows, self.cols, lambda i, j: simpfunc(self[i, j] - self[j, i])) return mat.is_zero def _eval_is_zero(self): if any(i.is_zero == False for i in self): return False if any(i.is_zero is None for i in self): return None return True def _eval_is_upper_hessenberg(self): return all(self[i, j].is_zero for i in range(2, self.rows) for j in range(min(self.cols, (i - 1)))) def _eval_values(self): return [i for i in self if not i.is_zero] def atoms(self, types): """Returns the atoms that form the current object. Examples ======== >>> from sympy.abc import x, y >>> from sympy.matrices import Matrix >>> Matrix([[x]]) Matrix([[x]]) >>> _.atoms() {x} """ types = tuple(t if isinstance(t, type) else type(t) for t in types) if not types: types = (Atom,) return self._eval_atoms(types) @property def free_symbols(self): """Returns the free symbols within the matrix. Examples ======== >>> from sympy.abc import x >>> from sympy.matrices import Matrix >>> Matrix([[x], [1]]).free_symbols {x} """ return self._eval_free_symbols() def has(self, patterns): """Test whether any subexpression matches any of the patterns. Examples ======== >>> from sympy import Matrix, SparseMatrix, Float >>> from sympy.abc import x, y >>> A = Matrix(((1, x), (0.2, 3))) >>> B = SparseMatrix(((1, x), (0.2, 3))) >>> A.has(x) True >>> A.has(y) False >>> A.has(Float) True >>> B.has(x) True >>> B.has(y) False >>> B.has(Float) True """ return self._eval_has(patterns) def is_anti_symmetric(self, simplify=True): """Check if matrix M is an antisymmetric matrix, that is, M is a square matrix with all M[i, j] == -M[j, i]. When ``simplify=True`` (default), the sum M[i, j] + M[j, i] is simplified before testing to see if it is zero. By default, the SymPy simplify function is used. To use a custom function set simplify to a function that accepts a single argument which returns a simplified expression. To skip simplification, set simplify to False but note that although this will be faster, it may induce false negatives. Examples ======== >>> from sympy import Matrix, symbols >>> m = Matrix(2, 2, [0, 1, -1, 0]) >>> m Matrix([ [ 0, 1], [-1, 0]]) >>> m.is_anti_symmetric() True >>> x, y = symbols('x y') >>> m = Matrix(2, 3, [0, 0, x, -y, 0, 0]) >>> m Matrix([ [ 0, 0, x], [-y, 0, 0]]) >>> m.is_anti_symmetric() False >>> from sympy.abc import x, y >>> m = Matrix(3, 3, [0, x2 + 2x + 1, y, ... -(x + 1)*2 , 0, xy, ... -y, -xy, 0]) Simplification of matrix elements is done by default so even though two elements which should be equal and opposite wouldn't pass an equality test, the matrix is still reported as anti-symmetric: >>> m[0, 1] == -m[1, 0] False >>> m.is_anti_symmetric() True If 'simplify=False' is used for the case when a Matrix is already simplified, this will speed things up. Here, we see that without simplification the matrix does not appear anti-symmetric: >>> m.is_anti_symmetric(simplify=False) False But if the matrix were already expanded, then it would appear anti-symmetric and simplification in the is_anti_symmetric routine is not needed: >>> m = m.expand() >>> m.is_anti_symmetric(simplify=False) True """ # accept custom simplification simpfunc = simplify if not isfunction(simplify): simpfunc = _simplify if simplify else lambda x: x if not self.is_square: return False return self._eval_is_anti_symmetric(simpfunc) def is_diagonal(self): """Check if matrix is diagonal, that is matrix in which the entries outside the main diagonal are all zero. Examples ======== >>> from sympy import Matrix, diag >>> m = Matrix(2, 2, [1, 0, 0, 2]) >>> m Matrix([ [1, 0], [0, 2]]) >>> m.is_diagonal() True >>> m = Matrix(2, 2, [1, 1, 0, 2]) >>> m Matrix([ [1, 1], [0, 2]]) >>> m.is_diagonal() False >>> m = diag(1, 2, 3) >>> m Matrix([ [1, 0, 0], [0, 2, 0], [0, 0, 3]]) >>> m.is_diagonal() True See Also ======== is_lower is_upper is_diagonalizable diagonalize """ return self._eval_is_diagonal() @property def is_hermitian(self, simplify=True): """Checks if the matrix is Hermitian. In a Hermitian matrix element i,j is the complex conjugate of element j,i. Examples ======== >>> from sympy.matrices import Matrix >>> from sympy import I >>> from sympy.abc import x >>> a = Matrix([[1, I], [-I, 1]]) >>> a Matrix([ [ 1, I], [-I, 1]]) >>> a.is_hermitian True >>> a[0, 0] = 2I >>> a.is_hermitian False >>> a[0, 0] = x >>> a.is_hermitian >>> a[0, 1] = a[1, 0]I >>> a.is_hermitian False """ if not self.is_square: return False simpfunc = simplify if not isfunction(simplify): simpfunc = _simplify if simplify else lambda x: x return self._eval_is_matrix_hermitian(simpfunc) @property def is_Identity(self): if not self.is_square: return False return self._eval_is_Identity() @property def is_lower_hessenberg(self): r"""Checks if the matrix is in the lower-Hessenberg form. The lower hessenberg matrix has zero entries above the first superdiagonal. Examples ======== >>> from sympy.matrices import Matrix >>> a = Matrix([[1, 2, 0, 0], [5, 2, 3, 0], [3, 4, 3, 7], [5, 6, 1, 1]]) >>> a Matrix([ [1, 2, 0, 0], [5, 2, 3, 0], [3, 4, 3, 7], [5, 6, 1, 1]]) >>> a.is_lower_hessenberg True See Also ======== is_upper_hessenberg is_lower """ return self._eval_is_lower_hessenberg() @property def is_lower(self): """Check if matrix is a lower triangular matrix. True can be returned even if the matrix is not square. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, [1, 0, 0, 1]) >>> m Matrix([ [1, 0], [0, 1]]) >>> m.is_lower True >>> m = Matrix(4, 3, [0, 0, 0, 2, 0, 0, 1, 4 , 0, 6, 6, 5]) >>> m Matrix([ [0, 0, 0], [2, 0, 0], [1, 4, 0], [6, 6, 5]]) >>> m.is_lower True >>> from sympy.abc import x, y >>> m = Matrix(2, 2, [x2 + y, y2 + x, 0, x + y]) >>> m Matrix([ [x2 + y, x + y2], [ 0, x + y]]) >>> m.is_lower False See Also ======== is_upper is_diagonal is_lower_hessenberg """ return self._eval_is_lower() @property def is_square(self): """Checks if a matrix is square. A matrix is square if the number of rows equals the number of columns. The empty matrix is square by definition, since the number of rows and the number of columns are both zero. Examples ======== >>> from sympy import Matrix >>> a = Matrix([[1, 2, 3], [4, 5, 6]]) >>> b = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) >>> c = Matrix([]) >>> a.is_square False >>> b.is_square True >>> c.is_square True """ return self.rows == self.cols def is_symbolic(self): """Checks if any elements contain Symbols. Examples ======== >>> from sympy.matrices import Matrix >>> from sympy.abc import x, y >>> M = Matrix([[x, y], [1, 0]]) >>> M.is_symbolic() True """ return self._eval_is_symbolic() def is_symmetric(self, simplify=True): """Check if matrix is symmetric matrix, that is square matrix and is equal to its transpose. By default, simplifications occur before testing symmetry. They can be skipped using 'simplify=False'; while speeding things a bit, this may however induce false negatives. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, [0, 1, 1, 2]) >>> m Matrix([ [0, 1], [1, 2]]) >>> m.is_symmetric() True >>> m = Matrix(2, 2, [0, 1, 2, 0]) >>> m Matrix([ [0, 1], [2, 0]]) >>> m.is_symmetric() False >>> m = Matrix(2, 3, [0, 0, 0, 0, 0, 0]) >>> m Matrix([ [0, 0, 0], [0, 0, 0]]) >>> m.is_symmetric() False >>> from sympy.abc import x, y >>> m = Matrix(3, 3, [1, x2 + 2x + 1, y, (x + 1)2 , 2, 0, y, 0, 3]) >>> m Matrix([ [ 1, x2 + 2x + 1, y], [(x + 1)2, 2, 0], [ y, 0, 3]]) >>> m.is_symmetric() True If the matrix is already simplified, you may speed-up is_symmetric() test by using 'simplify=False'. >>> bool(m.is_symmetric(simplify=False)) False >>> m1 = m.expand() >>> m1.is_symmetric(simplify=False) True """ simpfunc = simplify if not isfunction(simplify): simpfunc = _simplify if simplify else lambda x: x if not self.is_square: return False return self._eval_is_symmetric(simpfunc) @property def is_upper_hessenberg(self): """Checks if the matrix is the upper-Hessenberg form. The upper hessenberg matrix has zero entries below the first subdiagonal. Examples ======== >>> from sympy.matrices import Matrix >>> a = Matrix([[1, 4, 2, 3], [3, 4, 1, 7], [0, 2, 3, 4], [0, 0, 1, 3]]) >>> a Matrix([ [1, 4, 2, 3], [3, 4, 1, 7], [0, 2, 3, 4], [0, 0, 1, 3]]) >>> a.is_upper_hessenberg True See Also ======== is_lower_hessenberg is_upper """ return self._eval_is_upper_hessenberg() @property def is_upper(self): """Check if matrix is an upper triangular matrix. True can be returned even if the matrix is not square. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, [1, 0, 0, 1]) >>> m Matrix([ [1, 0], [0, 1]]) >>> m.is_upper True >>> m = Matrix(4, 3, [5, 1, 9, 0, 4 , 6, 0, 0, 5, 0, 0, 0]) >>> m Matrix([ [5, 1, 9], [0, 4, 6], [0, 0, 5], [0, 0, 0]]) >>> m.is_upper True >>> m = Matrix(2, 3, [4, 2, 5, 6, 1, 1]) >>> m Matrix([ [4, 2, 5], [6, 1, 1]]) >>> m.is_upper False See Also ======== is_lower is_diagonal is_upper_hessenberg """ return all(self[i, j].is_zero for i in range(1, self.rows) for j in range(min(i, self.cols))) @property def is_zero(self): """Checks if a matrix is a zero matrix. A matrix is zero if every element is zero. A matrix need not be square to be considered zero. The empty matrix is zero by the principle of vacuous truth. For a matrix that may or may not be zero (e.g. contains a symbol), this will be None Examples ======== >>> from sympy import Matrix, zeros >>> from sympy.abc import x >>> a = Matrix([[0, 0], [0, 0]]) >>> b = zeros(3, 4) >>> c = Matrix([[0, 1], [0, 0]]) >>> d = Matrix([]) >>> e = Matrix([[x, 0], [0, 0]]) >>> a.is_zero True >>> b.is_zero True >>> c.is_zero False >>> d.is_zero True >>> e.is_zero """ return self._eval_is_zero() def values(self): """Return non-zero values of self.""" return self._eval_values() class MatrixOperations(MatrixRequired): """Provides basic matrix shape and elementwise operations. Should not be instantiated directly.""" def _eval_adjoint(self): return self.transpose().conjugate() def _eval_applyfunc(self, f): out = self._new(self.rows, self.cols, [f(x) for x in self]) return out def _eval_as_real_imag(self): from sympy.functions.elementary.complexes import re, im return (self.applyfunc(re), self.applyfunc(im)) def _eval_conjugate(self): return self.applyfunc(lambda x: x.conjugate()) def _eval_permute_cols(self, perm): # apply the permutation to a list mapping = list(perm) def entry(i, j): return self[i, mapping[j]] return self._new(self.rows, self.cols, entry) def _eval_permute_rows(self, perm): # apply the permutation to a list mapping = list(perm) def entry(i, j): return self[mapping[i], j] return self._new(self.rows, self.cols, entry) def _eval_trace(self): return sum(self[i, i] for i in range(self.rows)) def _eval_transpose(self): return self._new(self.cols, self.rows, lambda i, j: self[j, i]) def adjoint(self): """Conjugate transpose or Hermitian conjugation.""" return self._eval_adjoint() def applyfunc(self, f): """Apply a function to each element of the matrix. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, lambda i, j: i2+j) >>> m Matrix([ [0, 1], [2, 3]]) >>> m.applyfunc(lambda i: 2i) Matrix([ [0, 2], [4, 6]]) """ if not callable(f): raise TypeError("`f` must be callable.") return self._eval_applyfunc(f) def as_real_imag(self): """Returns a tuple containing the (real, imaginary) part of matrix.""" return self._eval_as_real_imag() def conjugate(self): """Return the by-element conjugation. Examples ======== >>> from sympy.matrices import SparseMatrix >>> from sympy import I >>> a = SparseMatrix(((1, 2 + I), (3, 4), (I, -I))) >>> a Matrix([ [1, 2 + I], [3, 4], [I, -I]]) >>> a.C Matrix([ [ 1, 2 - I], [ 3, 4], [-I, I]]) See Also ======== transpose: Matrix transposition H: Hermite conjugation D: Dirac conjugation """ return self._eval_conjugate() def doit(self, kwargs): return self.applyfunc(lambda x: x.doit()) def evalf(self, prec=None, options): """Apply evalf() to each element of self.""" return self.applyfunc(lambda i: i.evalf(prec, options)) def expand(self, deep=True, modulus=None, power_base=True, power_exp=True, mul=True, log=True, multinomial=True, basic=True, hints): """Apply core.function.expand to each entry of the matrix. Examples ======== >>> from sympy.abc import x >>> from sympy.matrices import Matrix >>> Matrix(1, 1, [x(x+1)]) Matrix([[x(x + 1)]]) >>> _.expand() Matrix([[x2 + x]]) """ return self.applyfunc(lambda x: x.expand( deep, modulus, power_base, power_exp, mul, log, multinomial, basic, hints)) @property def H(self): """Return Hermite conjugate. Examples ======== >>> from sympy import Matrix, I >>> m = Matrix((0, 1 + I, 2, 3)) >>> m Matrix([ [ 0], [1 + I], [ 2], [ 3]]) >>> m.H Matrix([[0, 1 - I, 2, 3]]) See Also ======== conjugate: By-element conjugation D: Dirac conjugation """ return self.T.C def permute(self, perm, orientation='rows', direction='forward'): """Permute the rows or columns of a matrix by the given list of swaps. Parameters ========== perm : a permutation. This may be a list swaps (e.g., `[[1, 2], [0, 3]]`), or any valid input to the `Permutation` constructor, including a `Permutation()` itself. If `perm` is given explicitly as a list of indices or a `Permutation`, `direction` has no effect. orientation : ('rows' or 'cols') whether to permute the rows or the columns direction : ('forward', 'backward') whether to apply the permutations from the start of the list first, or from the back of the list first Examples ======== >>> from sympy.matrices import eye >>> M = eye(3) >>> M.permute([[0, 1], [0, 2]], orientation='rows', direction='forward') Matrix([ [0, 0, 1], [1, 0, 0], [0, 1, 0]]) >>> from sympy.matrices import eye >>> M = eye(3) >>> M.permute([[0, 1], [0, 2]], orientation='rows', direction='backward') Matrix([ [0, 1, 0], [0, 0, 1], [1, 0, 0]]) """ # allow british variants and `columns` if direction == 'forwards': direction = 'forward' if direction == 'backwards': direction = 'backward' if orientation == 'columns': orientation = 'cols' if direction not in ('forward', 'backward'): raise TypeError("direction='{}' is an invalid kwarg. " "Try 'forward' or 'backward'".format(direction)) if orientation not in ('rows', 'cols'): raise TypeError("orientation='{}' is an invalid kwarg. " "Try 'rows' or 'cols'".format(orientation)) # ensure all swaps are in range max_index = self.rows if orientation == 'rows' else self.cols if not all(0 <= t <= max_index for t in flatten(list(perm))): raise IndexError("`swap` indices out of range.") # see if we are a list of pairs try: assert len(perm[0]) == 2 # we are a list of swaps, so `direction` matters if direction == 'backward': perm = reversed(perm) # since Permutation doesn't let us have non-disjoint cycles, # we'll construct the explicit mapping ourselves XXX Bug #12479 mapping = list(range(max_index)) for (i, j) in perm: mapping[i], mapping[j] = mapping[j], mapping[i] perm = mapping except (TypeError, AssertionError, IndexError): pass from sympy.combinatorics import Permutation perm = Permutation(perm, size=max_index) if orientation == 'rows': return self._eval_permute_rows(perm) if orientation == 'cols': return self._eval_permute_cols(perm) def permute_cols(self, swaps, direction='forward'): """Alias for `self.permute(swaps, orientation='cols', direction=direction)` See Also ======== permute """ return self.permute(swaps, orientation='cols', direction=direction) def permute_rows(self, swaps, direction='forward'): """Alias for `self.permute(swaps, orientation='rows', direction=direction)` See Also ======== permute """ return self.permute(swaps, orientation='rows', direction=direction) def refine(self, assumptions=True): """Apply refine to each element of the matrix. Examples ======== >>> from sympy import Symbol, Matrix, Abs, sqrt, Q >>> x = Symbol('x') >>> Matrix([[Abs(x)2, sqrt(x2)],[sqrt(x2), Abs(x)2]]) Matrix([ [ Abs(x)2, sqrt(x2)], [sqrt(x2), Abs(x)2]]) >>> _.refine(Q.real(x)) Matrix([ [ x2, Abs(x)], [Abs(x), x2]]) """ return self.applyfunc(lambda x: refine(x, assumptions)) def replace(self, F, G, map=False): """Replaces Function F in Matrix entries with Function G. Examples ======== >>> from sympy import symbols, Function, Matrix >>> F, G = symbols('F, G', cls=Function) >>> M = Matrix(2, 2, lambda i, j: F(i+j)) ; M Matrix([ [F(0), F(1)], [F(1), F(2)]]) >>> N = M.replace(F,G) >>> N Matrix([ [G(0), G(1)], [G(1), G(2)]]) """ return self.applyfunc(lambda x: x.replace(F, G, map)) def simplify(self, ratio=1.7, measure=count_ops, rational=False, inverse=False): """Apply simplify to each element of the matrix. Examples ======== >>> from sympy.abc import x, y >>> from sympy import sin, cos >>> from sympy.matrices import SparseMatrix >>> SparseMatrix(1, 1, [xsin(y)*2 + xcos(y)*2]) Matrix([[xsin(y)*2 + xcos(y)*2]]) >>> _.simplify() Matrix([[x]]) """ return self.applyfunc(lambda x: x.simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse)) def subs(self, args, *kwargs): # should mirror core.basic.subs """Return a new matrix with subs applied to each entry. Examples ======== >>> from sympy.abc import x, y >>> from sympy.matrices import SparseMatrix, Matrix >>> SparseMatrix(1, 1, [x]) Matrix([[x]]) >>> _.subs(x, y) Matrix([[y]]) >>> Matrix(_).subs(y, x) Matrix([[x]]) """ return self.applyfunc(lambda x: x.subs(args, kwargs)) def trace(self): """ Returns the trace of a square matrix i.e. the sum of the diagonal elements. Examples ======== >>> from sympy import Matrix >>> A = Matrix(2, 2, [1, 2, 3, 4]) >>> A.trace() 5 """ if self.rows != self.cols: raise NonSquareMatrixError() return self._eval_trace() def transpose(self): """ Returns the transpose of the matrix. Examples ======== >>> from sympy import Matrix >>> A = Matrix(2, 2, [1, 2, 3, 4]) >>> A.transpose() Matrix([ [1, 3], [2, 4]]) >>> from sympy import Matrix, I >>> m=Matrix(((1, 2+I), (3, 4))) >>> m Matrix([ [1, 2 + I], [3, 4]]) >>> m.transpose() Matrix([ [ 1, 3], [2 + I, 4]]) >>> m.T == m.transpose() True See Also ======== conjugate: By-element conjugation """ return self._eval_transpose() T = property(transpose, None, None, "Matrix transposition.") C = property(conjugate, None, None, "By-element conjugation.") n = evalf def xreplace(self, rule): # should mirror core.basic.xreplace """Return a new matrix with xreplace applied to each entry. Examples ======== >>> from sympy.abc import x, y >>> from sympy.matrices import SparseMatrix, Matrix >>> SparseMatrix(1, 1, [x]) Matrix([[x]]) >>> _.xreplace({x: y}) Matrix([[y]]) >>> Matrix(_).xreplace({y: x}) Matrix([[x]]) """ return self.applyfunc(lambda x: x.xreplace(rule)) _eval_simplify = simplify def _eval_trigsimp(self, opts): from sympy.simplify import trigsimp return self.applyfunc(lambda x: trigsimp(x, *opts)) class MatrixArithmetic(MatrixRequired): """Provides basic matrix arithmetic operations. Should not be instantiated directly.""" _op_priority = 10.01 def _eval_Abs(self): return self._new(self.rows, self.cols, lambda i, j: Abs(self[i, j])) def _eval_add(self, other): return self._new(self.rows, self.cols, lambda i, j: self[i, j] + other[i, j]) def _eval_matrix_mul(self, other): def entry(i, j): try: return sum(self[i,k]other[k,j] for k in range(self.cols)) except TypeError: # Block matrices don't work with `sum` or `Add` (ISSUE #11599) # They don't work with `sum` because `sum` tries to add `0` # initially, and for a matrix, that is a mix of a scalar and # a matrix, which raises a TypeError. Fall back to a # block-matrix-safe way to multiply if the `sum` fails. ret = self[i, 0]other[0, j] for k in range(1, self.cols): ret += self[i, k]other[k, j] return ret return self._new(self.rows, other.cols, entry) def _eval_matrix_mul_elementwise(self, other): return self._new(self.rows, self.cols, lambda i, j: self[i,j]other[i,j]) def _eval_matrix_rmul(self, other): def entry(i, j): return sum(other[i,k]self[k,j] for k in range(other.cols)) return self._new(other.rows, self.cols, entry) def _eval_pow_by_recursion(self, num): if num == 1: return self if num % 2 == 1: return self * self._eval_pow_by_recursion(num - 1) ret = self._eval_pow_by_recursion(num // 2) return ret * ret def _eval_scalar_mul(self, other): return self._new(self.rows, self.cols, lambda i, j: self[i,j]other) def _eval_scalar_rmul(self, other): return self._new(self.rows, self.cols, lambda i, j: otherself[i,j]) def _eval_Mod(self, other): from sympy import Mod return self._new(self.rows, self.cols, lambda i, j: Mod(self[i, j], other)) # python arithmetic functions def __abs__(self): """Returns a new matrix with entry-wise absolute values.""" return self._eval_Abs() @call_highest_priority('__radd__') def __add__(self, other): """Return self + other, raising ShapeError if shapes don't match.""" other = _matrixify(other) # matrix-like objects can have shapes. This is # our first sanity check. if hasattr(other, 'shape'): if self.shape != other.shape: raise ShapeError("Matrix size mismatch: %s + %s" % ( self.shape, other.shape)) # honest sympy matrices defer to their class's routine if getattr(other, 'is_Matrix', False): # call the highest-priority class's _eval_add a, b = self, other if a.__class__ != classof(a, b): b, a = a, b return a._eval_add(b) # Matrix-like objects can be passed to CommonMatrix routines directly. if getattr(other, 'is_MatrixLike', False): return MatrixArithmetic._eval_add(self, other) raise TypeError('cannot add %s and %s' % (type(self), type(other))) @call_highest_priority('__rdiv__') def __div__(self, other): return self * (S.One / other) @call_highest_priority('__rmatmul__') def __matmul__(self, other): other = _matrixify(other) if not getattr(other, 'is_Matrix', False) and not getattr(other, 'is_MatrixLike', False): return NotImplemented return self.__mul__(other) def __mod__(self, other): return self.applyfunc(lambda x: x % other) @call_highest_priority('__rmul__') def __mul__(self, other): """Return selfother where other is either a scalar or a matrix of compatible dimensions. Examples ======== >>> from sympy.matrices import Matrix >>> A = Matrix([[1, 2, 3], [4, 5, 6]]) >>> 2A == A2 == Matrix([[2, 4, 6], [8, 10, 12]]) True >>> B = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) >>> AB Matrix([ [30, 36, 42], [66, 81, 96]]) >>> BA Traceback (most recent call last): ... ShapeError: Matrices size mismatch. >>> See Also ======== matrix_multiply_elementwise """ other = _matrixify(other) # matrix-like objects can have shapes. This is # our first sanity check. if hasattr(other, 'shape') and len(other.shape) == 2: if self.shape[1] != other.shape[0]: raise ShapeError("Matrix size mismatch: %s %s." % ( self.shape, other.shape)) # honest sympy matrices defer to their class's routine if getattr(other, 'is_Matrix', False): return self._eval_matrix_mul(other) # Matrix-like objects can be passed to CommonMatrix routines directly. if getattr(other, 'is_MatrixLike', False): return MatrixArithmetic._eval_matrix_mul(self, other) # if 'other' is not iterable then scalar multiplication. if not isinstance(other, Iterable): try: return self._eval_scalar_mul(other) except TypeError: pass return NotImplemented def __neg__(self): return self._eval_scalar_mul(-1) @call_highest_priority('__rpow__') def __pow__(self, num): if self.rows != self.cols: raise NonSquareMatrixError() a = self jordan_pow = getattr(a, '_matrix_pow_by_jordan_blocks', None) num = sympify(num) if num.is_Number and num % 1 == 0: if a.rows == 1: return a._new([[a[0]*num]]) if num == 0: return self._new(self.rows, self.cols, lambda i, j: int(i == j)) if num < 0: num = -num a = a.inv() # When certain conditions are met, # Jordan block algorithm is faster than # computation by recursion. elif a.rows == 2 and num > 100000 and jordan_pow is not None: try: return jordan_pow(num) except MatrixError: pass return a._eval_pow_by_recursion(num) elif not num.is_Number and num.is_negative is None and a.det() == 0: from sympy.matrices.expressions import MatPow return MatPow(a, num) elif isinstance(num, (Expr, float)): return jordan_pow(num) else: raise TypeError( "Only SymPy expressions or integers are supported as exponent for matrices") @call_highest_priority('__add__') def __radd__(self, other): return self + other @call_highest_priority('__matmul__') def __rmatmul__(self, other): other = _matrixify(other) if not getattr(other, 'is_Matrix', False) and not getattr(other, 'is_MatrixLike', False): return NotImplemented return self.__rmul__(other) @call_highest_priority('__mul__') def __rmul__(self, other): other = _matrixify(other) # matrix-like objects can have shapes. This is # our first sanity check. if hasattr(other, 'shape') and len(other.shape) == 2: if self.shape[0] != other.shape[1]: raise ShapeError("Matrix size mismatch.") # honest sympy matrices defer to their class's routine if getattr(other, 'is_Matrix', False): return other._new(other.as_mutable() self) # Matrix-like objects can be passed to CommonMatrix routines directly. if getattr(other, 'is_MatrixLike', False): return MatrixArithmetic._eval_matrix_rmul(self, other) # if 'other' is not iterable then scalar multiplication. if not isinstance(other, Iterable): try: return self._eval_scalar_rmul(other) except TypeError: pass return NotImplemented @call_highest_priority('__sub__') def __rsub__(self, a): return (-self) + a @call_highest_priority('__rsub__') def __sub__(self, a): return self + (-a) @call_highest_priority('__rtruediv__') def __truediv__(self, other): return self.__div__(other) def multiply_elementwise(self, other): """Return the Hadamard product (elementwise product) of A and B Examples ======== >>> from sympy.matrices import Matrix >>> A = Matrix([[0, 1, 2], [3, 4, 5]]) >>> B = Matrix([[1, 10, 100], [100, 10, 1]]) >>> A.multiply_elementwise(B) Matrix([ [ 0, 10, 200], [300, 40, 5]]) See Also ======== cross dot multiply """ if self.shape != other.shape: raise ShapeError("Matrix shapes must agree {} != {}".format(self.shape, other.shape)) return self._eval_matrix_mul_elementwise(other) class MatrixCommon(MatrixArithmetic, MatrixOperations, MatrixProperties, MatrixSpecial, MatrixShaping): """All common matrix operations including basic arithmetic, shaping, and special matrices like `zeros`, and `eye`.""" _diff_wrt = True class _MinimalMatrix(object): """Class providing the minimum functionality for a matrix-like object and implementing every method required for a `MatrixRequired`. This class does not have everything needed to become a full-fledged SymPy object, but it will satisfy the requirements of anything inheriting from `MatrixRequired`. If you wish to make a specialized matrix type, make sure to implement these methods and properties with the exception of `__init__` and `__repr__` which are included for convenience.""" is_MatrixLike = True _sympify = staticmethod(sympify) _class_priority = 3 is_Matrix = True is_MatrixExpr = False @classmethod def _new(cls, args, kwargs): return cls(args, *kwargs) def __init__(self, rows, cols=None, mat=None): if isfunction(mat): # if we passed in a function, use that to populate the indices mat = list(mat(i, j) for i in range(rows) for j in range(cols)) if cols is None and mat is None: mat = rows rows, cols = getattr(mat, 'shape', (rows, cols)) try: # if we passed in a list of lists, flatten it and set the size if cols is None and mat is None: mat = rows cols = len(mat[0]) rows = len(mat) mat = [x for l in mat for x in l] except (IndexError, TypeError): pass self.mat = tuple(self._sympify(x) for x in mat) self.rows, self.cols = rows, cols if self.rows is None or self.cols is None: raise NotImplementedError("Cannot initialize matrix with given parameters") def __getitem__(self, key): def _normalize_slices(row_slice, col_slice): """Ensure that row_slice and col_slice don't have `None` in their arguments. Any integers are converted to slices of length 1""" if not isinstance(row_slice, slice): row_slice = slice(row_slice, row_slice + 1, None) row_slice = slice(row_slice.indices(self.rows)) if not isinstance(col_slice, slice): col_slice = slice(col_slice, col_slice + 1, None) col_slice = slice(col_slice.indices(self.cols)) return (row_slice, col_slice) def _coord_to_index(i, j): """Return the index in _mat corresponding to the (i,j) position in the matrix. """ return i self.cols + j if isinstance(key, tuple): i, j = key if isinstance(i, slice) or isinstance(j, slice): # if the coordinates are not slices, make them so # and expand the slices so they don't contain `None` i, j = _normalize_slices(i, j) rowsList, colsList = list(range(self.rows))[i], \ list(range(self.cols))[j] indices = (i * self.cols + j for i in rowsList for j in colsList) return self._new(len(rowsList), len(colsList), list(self.mat[i] for i in indices)) # if the key is a tuple of ints, change # it to an array index key = _coord_to_index(i, j) return self.mat[key] def __eq__(self, other): try: classof(self, other) except TypeError: return False return ( self.shape == other.shape and list(self) == list(other)) def __len__(self): return self.rows*self.cols def __repr__(self): return "_MinimalMatrix({}, {}, {})".format(self.rows, self.cols, self.mat) @property def shape(self): return (self.rows, self.cols) class _MatrixWrapper(object): """Wrapper class providing the minimum functionality for a matrix-like object: .rows, .cols, .shape, indexability, and iterability. CommonMatrix math operations should work on matrix-like objects. For example, wrapping a numpy matrix in a MatrixWrapper allows it to be passed to CommonMatrix. """ is_MatrixLike = True def __init__(self, mat, shape=None): self.mat = mat self.rows, self.cols = mat.shape if shape is None else shape def __getattr__(self, attr): """Most attribute access is passed straight through to the stored matrix""" return getattr(self.mat, attr) def __getitem__(self, key): return self.mat.__getitem__(key) def _matrixify(mat): """If `mat` is a Matrix or is matrix-like, return a Matrix or MatrixWrapper object. Otherwise `mat` is passed through without modification.""" if getattr(mat, 'is_Matrix', False): return mat if hasattr(mat, 'shape'): if len(mat.shape) == 2: return _MatrixWrapper(mat) return mat def a2idx(j, n=None): """Return integer after making positive and validating against n.""" if type(j) is not int: jindex = getattr(j, '__index__', None) if jindex is not None: j = jindex() else: raise IndexError("Invalid index a[%r]" % (j,)) if n is not None: if j < 0: j += n if not (j >= 0 and j < n): raise IndexError("Index out of range: a[%s]" % (j,)) return int(j) def classof(A, B): """ Get the type of the result when combining matrices of different types. Currently the strategy is that immutability is contagious. Examples ======== >>> from sympy import Matrix, ImmutableMatrix >>> from sympy.matrices.common import classof >>> M = Matrix([[1, 2], [3, 4]]) # a Mutable Matrix >>> IM = ImmutableMatrix([[1, 2], [3, 4]]) >>> classof(M, IM) <class 'sympy.matrices.immutable.ImmutableDenseMatrix'> """ priority_A = getattr(A, '_class_priority', None) priority_B = getattr(B, '_class_priority', None) if None not in (priority_A, priority_B): if A._class_priority > B._class_priority: return A.__class__ else: return B.__class__ try: import numpy except ImportError: pass else: if isinstance(A, numpy.ndarray): return B.__class__ if isinstance(B, numpy.ndarray): return A.__class__ raise TypeError("Incompatible classes %s, %s" % (A.__class__, B.__class__))
da6102438d5d89f6e4040f9a679182a600cdaefa6c6e4724dbbda0f2f233cebb	from __future__ import print_function, division from itertools import product from sympy.core.basic import Basic from sympy.core.compatibility import (iterable, with_metaclass, ordered, range, PY3) from sympy.core.cache import cacheit from sympy.core.evalf import EvalfMixin from sympy.core.evaluate import global_evaluate from sympy.core.expr import Expr from sympy.core.function import FunctionClass from sympy.core.logic import fuzzy_bool from sympy.core.mul import Mul from sympy.core.numbers import Float from sympy.core.operations import LatticeOp from sympy.core.relational import Eq, Ne from sympy.core.singleton import Singleton, S from sympy.core.symbol import Symbol, Dummy, _uniquely_named_symbol from sympy.core.sympify import _sympify, sympify, converter from sympy.logic.boolalg import And, Or, Not, true, false from sympy.sets.contains import Contains from sympy.utilities import subsets from sympy.utilities.iterables import sift from sympy.utilities.misc import func_name, filldedent from mpmath import mpi, mpf class Set(Basic): """ The base class for any kind of set. This is not meant to be used directly as a container of items. It does not behave like the builtin ``set``; see :class:`FiniteSet` for that. Real intervals are represented by the :class:`Interval` class and unions of sets by the :class:`Union` class. The empty set is represented by the :class:`EmptySet` class and available as a singleton as ``S.EmptySet``. """ is_number = False is_iterable = False is_interval = False is_FiniteSet = False is_Interval = False is_ProductSet = False is_Union = False is_Intersection = None is_EmptySet = None is_UniversalSet = None is_Complement = None is_ComplexRegion = False @staticmethod def _infimum_key(expr): """ Return infimum (if possible) else S.Infinity. """ try: infimum = expr.inf assert infimum.is_comparable except (NotImplementedError, AttributeError, AssertionError, ValueError): infimum = S.Infinity return infimum def union(self, other): """ Returns the union of 'self' and 'other'. Examples ======== As a shortcut it is possible to use the '+' operator: >>> from sympy import Interval, FiniteSet >>> Interval(0, 1).union(Interval(2, 3)) Union(Interval(0, 1), Interval(2, 3)) >>> Interval(0, 1) + Interval(2, 3) Union(Interval(0, 1), Interval(2, 3)) >>> Interval(1, 2, True, True) + FiniteSet(2, 3) Union(Interval.Lopen(1, 2), {3}) Similarly it is possible to use the '-' operator for set differences: >>> Interval(0, 2) - Interval(0, 1) Interval.Lopen(1, 2) >>> Interval(1, 3) - FiniteSet(2) Union(Interval.Ropen(1, 2), Interval.Lopen(2, 3)) """ return Union(self, other) def intersect(self, other): """ Returns the intersection of 'self' and 'other'. >>> from sympy import Interval >>> Interval(1, 3).intersect(Interval(1, 2)) Interval(1, 2) >>> from sympy import imageset, Lambda, symbols, S >>> n, m = symbols('n m') >>> a = imageset(Lambda(n, 2n), S.Integers) >>> a.intersect(imageset(Lambda(m, 2m + 1), S.Integers)) EmptySet() """ return Intersection(self, other) def intersection(self, other): """ Alias for :meth:`intersect()` """ return self.intersect(other) def is_disjoint(self, other): """ Returns True if 'self' and 'other' are disjoint Examples ======== >>> from sympy import Interval >>> Interval(0, 2).is_disjoint(Interval(1, 2)) False >>> Interval(0, 2).is_disjoint(Interval(3, 4)) True References ========== .. [1] https://en.wikipedia.org/wiki/Disjoint_sets """ return self.intersect(other) == S.EmptySet def isdisjoint(self, other): """ Alias for :meth:`is_disjoint()` """ return self.is_disjoint(other) def complement(self, universe): r""" The complement of 'self' w.r.t the given universe. Examples ======== >>> from sympy import Interval, S >>> Interval(0, 1).complement(S.Reals) Union(Interval.open(-oo, 0), Interval.open(1, oo)) >>> Interval(0, 1).complement(S.UniversalSet) UniversalSet \ Interval(0, 1) """ return Complement(universe, self) def _complement(self, other): # this behaves as other - self if isinstance(other, ProductSet): # For each set consider it or it's complement # We need at least one of the sets to be complemented # Consider all 2^n combinations. # We can conveniently represent these options easily using a # ProductSet # XXX: this doesn't work if the dimensions of the sets isn't same. # A - B is essentially same as A if B has a different # dimensionality than A switch_sets = ProductSet(FiniteSet(o, o - s) for s, o in zip(self.sets, other.sets)) product_sets = (ProductSet(set) for set in switch_sets) # Union of all combinations but this one return Union((p for p in product_sets if p != other)) elif isinstance(other, Interval): if isinstance(self, Interval) or isinstance(self, FiniteSet): return Intersection(other, self.complement(S.Reals)) elif isinstance(other, Union): return Union((o - self for o in other.args)) elif isinstance(other, Complement): return Complement(other.args[0], Union(other.args[1], self), evaluate=False) elif isinstance(other, EmptySet): return S.EmptySet elif isinstance(other, FiniteSet): from sympy.utilities.iterables import sift sifted = sift(other, lambda x: fuzzy_bool(self.contains(x))) # ignore those that are contained in self return Union(FiniteSet((sifted[False])), Complement(FiniteSet((sifted[None])), self, evaluate=False) if sifted[None] else S.EmptySet) def symmetric_difference(self, other): """ Returns symmetric difference of `self` and `other`. Examples ======== >>> from sympy import Interval, S >>> Interval(1, 3).symmetric_difference(S.Reals) Union(Interval.open(-oo, 1), Interval.open(3, oo)) >>> Interval(1, 10).symmetric_difference(S.Reals) Union(Interval.open(-oo, 1), Interval.open(10, oo)) >>> from sympy import S, EmptySet >>> S.Reals.symmetric_difference(EmptySet()) Reals References ========== .. [1] https://en.wikipedia.org/wiki/Symmetric_difference """ return SymmetricDifference(self, other) def _symmetric_difference(self, other): return Union(Complement(self, other), Complement(other, self)) @property def inf(self): """ The infimum of 'self' Examples ======== >>> from sympy import Interval, Union >>> Interval(0, 1).inf 0 >>> Union(Interval(0, 1), Interval(2, 3)).inf 0 """ return self._inf @property def _inf(self): raise NotImplementedError("(%s)._inf" % self) @property def sup(self): """ The supremum of 'self' Examples ======== >>> from sympy import Interval, Union >>> Interval(0, 1).sup 1 >>> Union(Interval(0, 1), Interval(2, 3)).sup 3 """ return self._sup @property def _sup(self): raise NotImplementedError("(%s)._sup" % self) def contains(self, other): """ Returns True if 'other' is contained in 'self' as an element. As a shortcut it is possible to use the 'in' operator: Examples ======== >>> from sympy import Interval >>> Interval(0, 1).contains(0.5) True >>> 0.5 in Interval(0, 1) True """ other = sympify(other, strict=True) ret = sympify(self._contains(other)) if ret is None: ret = Contains(other, self, evaluate=False) return ret def _contains(self, other): raise NotImplementedError("(%s)._contains(%s)" % (self, other)) def is_subset(self, other): """ Returns True if 'self' is a subset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 0.5).is_subset(Interval(0, 1)) True >>> Interval(0, 1).is_subset(Interval(0, 1, left_open=True)) False """ if isinstance(other, Set): return self.intersect(other) == self else: raise ValueError("Unknown argument '%s'" % other) def issubset(self, other): """ Alias for :meth:`is_subset()` """ return self.is_subset(other) def is_proper_subset(self, other): """ Returns True if 'self' is a proper subset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 0.5).is_proper_subset(Interval(0, 1)) True >>> Interval(0, 1).is_proper_subset(Interval(0, 1)) False """ if isinstance(other, Set): return self != other and self.is_subset(other) else: raise ValueError("Unknown argument '%s'" % other) def is_superset(self, other): """ Returns True if 'self' is a superset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 0.5).is_superset(Interval(0, 1)) False >>> Interval(0, 1).is_superset(Interval(0, 1, left_open=True)) True """ if isinstance(other, Set): return other.is_subset(self) else: raise ValueError("Unknown argument '%s'" % other) def issuperset(self, other): """ Alias for :meth:`is_superset()` """ return self.is_superset(other) def is_proper_superset(self, other): """ Returns True if 'self' is a proper superset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).is_proper_superset(Interval(0, 0.5)) True >>> Interval(0, 1).is_proper_superset(Interval(0, 1)) False """ if isinstance(other, Set): return self != other and self.is_superset(other) else: raise ValueError("Unknown argument '%s'" % other) def _eval_powerset(self): raise NotImplementedError('Power set not defined for: %s' % self.func) def powerset(self): """ Find the Power set of 'self'. Examples ======== >>> from sympy import FiniteSet, EmptySet >>> A = EmptySet() >>> A.powerset() {EmptySet()} >>> A = FiniteSet(1, 2) >>> a, b, c = FiniteSet(1), FiniteSet(2), FiniteSet(1, 2) >>> A.powerset() == FiniteSet(a, b, c, EmptySet()) True References ========== .. [1] https://en.wikipedia.org/wiki/Power_set """ return self._eval_powerset() @property def measure(self): """ The (Lebesgue) measure of 'self' Examples ======== >>> from sympy import Interval, Union >>> Interval(0, 1).measure 1 >>> Union(Interval(0, 1), Interval(2, 3)).measure 2 """ return self._measure @property def boundary(self): """ The boundary or frontier of a set A point x is on the boundary of a set S if 1. x is in the closure of S. I.e. Every neighborhood of x contains a point in S. 2. x is not in the interior of S. I.e. There does not exist an open set centered on x contained entirely within S. There are the points on the outer rim of S. If S is open then these points need not actually be contained within S. For example, the boundary of an interval is its start and end points. This is true regardless of whether or not the interval is open. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).boundary {0, 1} >>> Interval(0, 1, True, False).boundary {0, 1} """ return self._boundary @property def is_open(self): """ Property method to check whether a set is open. A set is open if and only if it has an empty intersection with its boundary. Examples ======== >>> from sympy import S >>> S.Reals.is_open True """ if not Intersection(self, self.boundary): return True # We can't confidently claim that an intersection exists return None @property def is_closed(self): """ A property method to check whether a set is closed. A set is closed if it's complement is an open set. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).is_closed True """ return self.boundary.is_subset(self) @property def closure(self): """ Property method which returns the closure of a set. The closure is defined as the union of the set itself and its boundary. Examples ======== >>> from sympy import S, Interval >>> S.Reals.closure Reals >>> Interval(0, 1).closure Interval(0, 1) """ return self + self.boundary @property def interior(self): """ Property method which returns the interior of a set. The interior of a set S consists all points of S that do not belong to the boundary of S. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).interior Interval.open(0, 1) >>> Interval(0, 1).boundary.interior EmptySet() """ return self - self.boundary @property def _boundary(self): raise NotImplementedError() @property def _measure(self): raise NotImplementedError("(%s)._measure" % self) def __add__(self, other): return self.union(other) def __or__(self, other): return self.union(other) def __and__(self, other): return self.intersect(other) def __mul__(self, other): return ProductSet(self, other) def __xor__(self, other): return SymmetricDifference(self, other) def __pow__(self, exp): if not sympify(exp).is_Integer and exp >= 0: raise ValueError("%s: Exponent must be a positive Integer" % exp) return ProductSet([self]exp) def __sub__(self, other): return Complement(self, other) def __contains__(self, other): symb = sympify(self.contains(other)) if not (symb is S.true or symb is S.false): raise TypeError('contains did not evaluate to a bool: %r' % symb) return bool(symb) class ProductSet(Set): """ Represents a Cartesian Product of Sets. Returns a Cartesian product given several sets as either an iterable or individual arguments. Can use '' operator on any sets for convenient shorthand. Examples ======== >>> from sympy import Interval, FiniteSet, ProductSet >>> I = Interval(0, 5); S = FiniteSet(1, 2, 3) >>> ProductSet(I, S) Interval(0, 5) x {1, 2, 3} >>> (2, 2) in ProductSet(I, S) True >>> Interval(0, 1) Interval(0, 1) # The unit square Interval(0, 1) x Interval(0, 1) >>> coin = FiniteSet('H', 'T') >>> set(coin*2) {(H, H), (H, T), (T, H), (T, T)} Notes ===== - Passes most operations down to the argument sets - Flattens Products of ProductSets References ========== .. [1] https://en.wikipedia.org/wiki/Cartesian_product """ is_ProductSet = True def __new__(cls, sets, *assumptions): def flatten(arg): if isinstance(arg, Set): if arg.is_ProductSet: return sum(map(flatten, arg.args), []) else: return [arg] elif iterable(arg): return sum(map(flatten, arg), []) raise TypeError("Input must be Sets or iterables of Sets") sets = flatten(list(sets)) if EmptySet() in sets or len(sets) == 0: return EmptySet() if len(sets) == 1: return sets[0] return Basic.__new__(cls, sets, *assumptions) def _eval_Eq(self, other): if not other.is_ProductSet: return if len(self.args) != len(other.args): return false return And((Eq(x, y) for x, y in zip(self.args, other.args))) def _contains(self, element): """ 'in' operator for ProductSets Examples ======== >>> from sympy import Interval >>> (2, 3) in Interval(0, 5) * Interval(0, 5) True >>> (10, 10) in Interval(0, 5) * Interval(0, 5) False Passes operation on to constituent sets """ try: if len(element) != len(self.args): return false except TypeError: # maybe element isn't an iterable return false return And(* [set.contains(item) for set, item in zip(self.sets, element)]) @property def sets(self): return self.args @property def _boundary(self): return Union((ProductSet(b + b.boundary if i != j else b.boundary for j, b in enumerate(self.sets)) for i, a in enumerate(self.sets))) @property def is_iterable(self): """ A property method which tests whether a set is iterable or not. Returns True if set is iterable, otherwise returns False. Examples ======== >>> from sympy import FiniteSet, Interval, ProductSet >>> I = Interval(0, 1) >>> A = FiniteSet(1, 2, 3, 4, 5) >>> I.is_iterable False >>> A.is_iterable True """ return all(set.is_iterable for set in self.sets) def __iter__(self): """ A method which implements is_iterable property method. If self.is_iterable returns True (both constituent sets are iterable), then return the Cartesian Product. Otherwise, raise TypeError. """ if self.is_iterable: return product(self.sets) else: raise TypeError("Not all constituent sets are iterable") @property def _measure(self): measure = 1 for set in self.sets: measure = set.measure return measure def __len__(self): return Mul([len(s) for s in self.args]) def __bool__(self): return all([bool(s) for s in self.args]) __nonzero__ = __bool__ class Interval(Set, EvalfMixin): """ Represents a real interval as a Set. Usage: Returns an interval with end points "start" and "end". For left_open=True (default left_open is False) the interval will be open on the left. Similarly, for right_open=True the interval will be open on the right. Examples ======== >>> from sympy import Symbol, Interval >>> Interval(0, 1) Interval(0, 1) >>> Interval.Ropen(0, 1) Interval.Ropen(0, 1) >>> Interval.Ropen(0, 1) Interval.Ropen(0, 1) >>> Interval.Lopen(0, 1) Interval.Lopen(0, 1) >>> Interval.open(0, 1) Interval.open(0, 1) >>> a = Symbol('a', real=True) >>> Interval(0, a) Interval(0, a) Notes ===== - Only real end points are supported - Interval(a, b) with a > b will return the empty set - Use the evalf() method to turn an Interval into an mpmath 'mpi' interval instance References ========== .. [1] https://en.wikipedia.org/wiki/Interval_%28mathematics%29 """ is_Interval = True def __new__(cls, start, end, left_open=False, right_open=False): start = _sympify(start) end = _sympify(end) left_open = _sympify(left_open) right_open = _sympify(right_open) if not all(isinstance(a, (type(true), type(false))) for a in [left_open, right_open]): raise NotImplementedError( "left_open and right_open can have only true/false values, " "got %s and %s" % (left_open, right_open)) inftys = [S.Infinity, S.NegativeInfinity] # Only allow real intervals (use symbols with 'is_real=True'). if not all(i.is_real is not False or i in inftys for i in (start, end)): raise ValueError("Non-real intervals are not supported") # evaluate if possible if (end < start) == True: return S.EmptySet elif (end - start).is_negative: return S.EmptySet if end == start and (left_open or right_open): return S.EmptySet if end == start and not (left_open or right_open): if start == S.Infinity or start == S.NegativeInfinity: return S.EmptySet return FiniteSet(end) # Make sure infinite interval end points are open. if start == S.NegativeInfinity: left_open = true if end == S.Infinity: right_open = true return Basic.__new__(cls, start, end, left_open, right_open) @property def start(self): """ The left end point of 'self'. This property takes the same value as the 'inf' property. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).start 0 """ return self._args[0] _inf = left = start @classmethod def open(cls, a, b): """Return an interval including neither boundary.""" return cls(a, b, True, True) @classmethod def Lopen(cls, a, b): """Return an interval not including the left boundary.""" return cls(a, b, True, False) @classmethod def Ropen(cls, a, b): """Return an interval not including the right boundary.""" return cls(a, b, False, True) @property def end(self): """ The right end point of 'self'. This property takes the same value as the 'sup' property. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).end 1 """ return self._args[1] _sup = right = end @property def left_open(self): """ True if 'self' is left-open. Examples ======== >>> from sympy import Interval >>> Interval(0, 1, left_open=True).left_open True >>> Interval(0, 1, left_open=False).left_open False """ return self._args[2] @property def right_open(self): """ True if 'self' is right-open. Examples ======== >>> from sympy import Interval >>> Interval(0, 1, right_open=True).right_open True >>> Interval(0, 1, right_open=False).right_open False """ return self._args[3] def _complement(self, other): if other == S.Reals: a = Interval(S.NegativeInfinity, self.start, True, not self.left_open) b = Interval(self.end, S.Infinity, not self.right_open, True) return Union(a, b) if isinstance(other, FiniteSet): nums = [m for m in other.args if m.is_number] if nums == []: return None return Set._complement(self, other) @property def _boundary(self): finite_points = [p for p in (self.start, self.end) if abs(p) != S.Infinity] return FiniteSet(finite_points) def _contains(self, other): if not isinstance(other, Expr) or ( other is S.Infinity or other is S.NegativeInfinity or other is S.NaN or other is S.ComplexInfinity) or other.is_real is False: return false if self.start is S.NegativeInfinity and self.end is S.Infinity: if not other.is_real is None: return other.is_real if self.left_open: expr = other > self.start else: expr = other >= self.start if self.right_open: expr = And(expr, other < self.end) else: expr = And(expr, other <= self.end) return _sympify(expr) @property def _measure(self): return self.end - self.start def to_mpi(self, prec=53): return mpi(mpf(self.start._eval_evalf(prec)), mpf(self.end._eval_evalf(prec))) def _eval_evalf(self, prec): return Interval(self.left._eval_evalf(prec), self.right._eval_evalf(prec), left_open=self.left_open, right_open=self.right_open) def _is_comparable(self, other): is_comparable = self.start.is_comparable is_comparable &= self.end.is_comparable is_comparable &= other.start.is_comparable is_comparable &= other.end.is_comparable return is_comparable @property def is_left_unbounded(self): """Return ``True`` if the left endpoint is negative infinity. """ return self.left is S.NegativeInfinity or self.left == Float("-inf") @property def is_right_unbounded(self): """Return ``True`` if the right endpoint is positive infinity. """ return self.right is S.Infinity or self.right == Float("+inf") def as_relational(self, x): """Rewrite an interval in terms of inequalities and logic operators.""" x = sympify(x) if self.right_open: right = x < self.end else: right = x <= self.end if self.left_open: left = self.start < x else: left = self.start <= x return And(left, right) def _eval_Eq(self, other): if not isinstance(other, Interval): if isinstance(other, FiniteSet): return false elif isinstance(other, Set): return None return false return And(Eq(self.left, other.left), Eq(self.right, other.right), self.left_open == other.left_open, self.right_open == other.right_open) class Union(Set, LatticeOp, EvalfMixin): """ Represents a union of sets as a :class:`Set`. Examples ======== >>> from sympy import Union, Interval >>> Union(Interval(1, 2), Interval(3, 4)) Union(Interval(1, 2), Interval(3, 4)) The Union constructor will always try to merge overlapping intervals, if possible. For example: >>> Union(Interval(1, 2), Interval(2, 3)) Interval(1, 3) See Also ======== Intersection References ========== .. [1] https://en.wikipedia.org/wiki/Union_%28set_theory%29 """ is_Union = True @property def identity(self): return S.EmptySet @property def zero(self): return S.UniversalSet def __new__(cls, args, *kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) # flatten inputs to merge intersections and iterables args = _sympify(args) # Reduce sets using known rules if evaluate: args = list(cls._new_args_filter(args)) return simplify_union(args) args = list(ordered(args, Set._infimum_key)) obj = Basic.__new__(cls, args) obj._argset = frozenset(args) return obj @property @cacheit def args(self): return self._args def _complement(self, universe): # DeMorgan's Law return Intersection(s.complement(universe) for s in self.args) @property def _inf(self): # We use Min so that sup is meaningful in combination with symbolic # interval end points. from sympy.functions.elementary.miscellaneous import Min return Min([set.inf for set in self.args]) @property def _sup(self): # We use Max so that sup is meaningful in combination with symbolic # end points. from sympy.functions.elementary.miscellaneous import Max return Max([set.sup for set in self.args]) def _contains(self, other): return Or([set.contains(other) for set in self.args]) @property def _measure(self): # Measure of a union is the sum of the measures of the sets minus # the sum of their pairwise intersections plus the sum of their # triple-wise intersections minus ... etc... # Sets is a collection of intersections and a set of elementary # sets which made up those intersections (called "sos" for set of sets) # An example element might of this list might be: # ( {A,B,C}, A.intersect(B).intersect(C) ) # Start with just elementary sets ( ({A}, A), ({B}, B), ... ) # Then get and subtract ( ({A,B}, (A int B), ... ) while non-zero sets = [(FiniteSet(s), s) for s in self.args] measure = 0 parity = 1 while sets: # Add up the measure of these sets and add or subtract it to total measure += parity sum(inter.measure for sos, inter in sets) # For each intersection in sets, compute the intersection with every # other set not already part of the intersection. sets = ((sos + FiniteSet(newset), newset.intersect(intersection)) for sos, intersection in sets for newset in self.args if newset not in sos) # Clear out sets with no measure sets = [(sos, inter) for sos, inter in sets if inter.measure != 0] # Clear out duplicates sos_list = [] sets_list = [] for set in sets: if set[0] in sos_list: continue else: sos_list.append(set[0]) sets_list.append(set) sets = sets_list # Flip Parity - next time subtract/add if we added/subtracted here parity = -1 return measure @property def _boundary(self): def boundary_of_set(i): """ The boundary of set i minus interior of all other sets """ b = self.args[i].boundary for j, a in enumerate(self.args): if j != i: b = b - a.interior return b return Union(map(boundary_of_set, range(len(self.args)))) def as_relational(self, symbol): """Rewrite a Union in terms of equalities and logic operators. """ if len(self.args) == 2: a, b = self.args if (a.sup == b.inf and a.inf is S.NegativeInfinity and b.sup is S.Infinity): return And(Ne(symbol, a.sup), symbol < b.sup, symbol > a.inf) return Or([set.as_relational(symbol) for set in self.args]) @property def is_iterable(self): return all(arg.is_iterable for arg in self.args) def _eval_evalf(self, prec): try: return Union((set._eval_evalf(prec) for set in self.args)) except (TypeError, ValueError, NotImplementedError): import sys raise (TypeError("Not all sets are evalf-able"), None, sys.exc_info()[2]) def __iter__(self): import itertools # roundrobin recipe taken from itertools documentation: # https://docs.python.org/2/library/itertools.html#recipes def roundrobin(iterables): "roundrobin('ABC', 'D', 'EF') --> A D E B F C" # Recipe credited to George Sakkis pending = len(iterables) if PY3: nexts = itertools.cycle(iter(it).__next__ for it in iterables) else: nexts = itertools.cycle(iter(it).next for it in iterables) while pending: try: for next in nexts: yield next() except StopIteration: pending -= 1 nexts = itertools.cycle(itertools.islice(nexts, pending)) if all(set.is_iterable for set in self.args): return roundrobin((iter(arg) for arg in self.args)) else: raise TypeError("Not all constituent sets are iterable") class Intersection(Set, LatticeOp): """ Represents an intersection of sets as a :class:`Set`. Examples ======== >>> from sympy import Intersection, Interval >>> Intersection(Interval(1, 3), Interval(2, 4)) Interval(2, 3) We often use the .intersect method >>> Interval(1,3).intersect(Interval(2,4)) Interval(2, 3) See Also ======== Union References ========== .. [1] https://en.wikipedia.org/wiki/Intersection_%28set_theory%29 """ is_Intersection = True @property def identity(self): return S.UniversalSet @property def zero(self): return S.EmptySet def __new__(cls, args, kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) # flatten inputs to merge intersections and iterables args = _sympify(args) # Reduce sets using known rules if evaluate: args = list(cls._new_args_filter(args)) return simplify_intersection(args) args = list(ordered(args, Set._infimum_key)) obj = Basic.__new__(cls, args) obj._argset = frozenset(args) return obj @property @cacheit def args(self): return self._args @property def is_iterable(self): return any(arg.is_iterable for arg in self.args) @property def _inf(self): raise NotImplementedError() @property def _sup(self): raise NotImplementedError() def _contains(self, other): return And([set.contains(other) for set in self.args]) def __iter__(self): no_iter = True for s in self.args: if s.is_iterable: no_iter = False other_sets = set(self.args) - set((s,)) other = Intersection(other_sets, evaluate=False) for x in s: c = sympify(other.contains(x)) if c is S.true: yield x elif c is S.false: pass else: yield c if no_iter: raise ValueError("None of the constituent sets are iterable") @staticmethod def _handle_finite_sets(args): from sympy.core.logic import fuzzy_and, fuzzy_bool from sympy.core.compatibility import zip_longest fs_args, other = sift(args, lambda x: x.is_FiniteSet, binary=True) if not fs_args: return fs_args.sort(key=len) s = fs_args[0] fs_args = fs_args[1:] res = [] unk = [] for x in s: c = fuzzy_and(fuzzy_bool(o.contains(x)) for o in fs_args + other) if c: res.append(x) elif c is None: unk.append(x) else: pass # drop arg res = FiniteSet( res, evaluate=False) if res else S.EmptySet if unk: symbolic_s_list = [x for x in s if x.has(Symbol)] non_symbolic_s = s - FiniteSet( symbolic_s_list, evaluate=False) while fs_args: v = fs_args.pop() if all(i == j for i, j in zip_longest( symbolic_s_list, (x for x in v if x.has(Symbol)))): # all the symbolic elements of `v` are the same # as in `s` so remove the non-symbol containing # expressions from `unk`, since they cannot be # contained for x in non_symbolic_s: if x in unk: unk.remove(x) else: # if only a subset of elements in `s` are # contained in `v` then remove them from `v` # and add this as a new arg contained = [x for x in symbolic_s_list if sympify(v.contains(x)) is S.true] if contained != symbolic_s_list: other.append( v - FiniteSet( contained, evaluate=False)) else: pass # for coverage other_sets = Intersection(other) if not other_sets: return S.EmptySet # b/c we use evaluate=False below elif other_sets == S.UniversalSet: res += FiniteSet(unk) else: res += Intersection( FiniteSet(unk), other_sets, evaluate=False) return res def as_relational(self, symbol): """Rewrite an Intersection in terms of equalities and logic operators""" return And([set.as_relational(symbol) for set in self.args]) class Complement(Set, EvalfMixin): r"""Represents the set difference or relative complement of a set with another set. `A - B = \{x \in A\| x \\notin B\}` Examples ======== >>> from sympy import Complement, FiniteSet >>> Complement(FiniteSet(0, 1, 2), FiniteSet(1)) {0, 2} See Also ========= Intersection, Union References ========== .. [1] http://mathworld.wolfram.com/ComplementSet.html """ is_Complement = True def __new__(cls, a, b, evaluate=True): if evaluate: return Complement.reduce(a, b) return Basic.__new__(cls, a, b) @staticmethod def reduce(A, B): """ Simplify a :class:`Complement`. """ if B == S.UniversalSet or A.is_subset(B): return EmptySet() if isinstance(B, Union): return Intersection((s.complement(A) for s in B.args)) result = B._complement(A) if result is not None: return result else: return Complement(A, B, evaluate=False) def _contains(self, other): A = self.args[0] B = self.args[1] return And(A.contains(other), Not(B.contains(other))) class EmptySet(with_metaclass(Singleton, Set)): """ Represents the empty set. The empty set is available as a singleton as S.EmptySet. Examples ======== >>> from sympy import S, Interval >>> S.EmptySet EmptySet() >>> Interval(1, 2).intersect(S.EmptySet) EmptySet() See Also ======== UniversalSet References ========== .. [1] https://en.wikipedia.org/wiki/Empty_set """ is_EmptySet = True is_FiniteSet = True @property def _measure(self): return 0 def _contains(self, other): return false def as_relational(self, symbol): return false def __len__(self): return 0 def __iter__(self): return iter([]) def _eval_powerset(self): return FiniteSet(self) @property def _boundary(self): return self def _complement(self, other): return other def _symmetric_difference(self, other): return other class UniversalSet(with_metaclass(Singleton, Set)): """ Represents the set of all things. The universal set is available as a singleton as S.UniversalSet Examples ======== >>> from sympy import S, Interval >>> S.UniversalSet UniversalSet >>> Interval(1, 2).intersect(S.UniversalSet) Interval(1, 2) See Also ======== EmptySet References ========== .. [1] https://en.wikipedia.org/wiki/Universal_set """ is_UniversalSet = True def _complement(self, other): return S.EmptySet def _symmetric_difference(self, other): return other @property def _measure(self): return S.Infinity def _contains(self, other): return true def as_relational(self, symbol): return true @property def _boundary(self): return EmptySet() class FiniteSet(Set, EvalfMixin): """ Represents a finite set of discrete numbers Examples ======== >>> from sympy import FiniteSet >>> FiniteSet(1, 2, 3, 4) {1, 2, 3, 4} >>> 3 in FiniteSet(1, 2, 3, 4) True >>> members = [1, 2, 3, 4] >>> f = FiniteSet(members) >>> f {1, 2, 3, 4} >>> f - FiniteSet(2) {1, 3, 4} >>> f + FiniteSet(2, 5) {1, 2, 3, 4, 5} References ========== .. [1] https://en.wikipedia.org/wiki/Finite_set """ is_FiniteSet = True is_iterable = True def __new__(cls, args, *kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) if evaluate: args = list(map(sympify, args)) if len(args) == 0: return EmptySet() else: args = list(map(sympify, args)) args = list(ordered(frozenset(tuple(args)), Set._infimum_key)) obj = Basic.__new__(cls, args) obj._elements = frozenset(args) return obj def _eval_Eq(self, other): if not isinstance(other, FiniteSet): if isinstance(other, Interval): return false elif isinstance(other, Set): return None return false if len(self) != len(other): return false return And((Eq(x, y) for x, y in zip(self.args, other.args))) def __iter__(self): return iter(self.args) def _complement(self, other): if isinstance(other, Interval): nums = sorted(m for m in self.args if m.is_number) if other == S.Reals and nums != []: syms = [m for m in self.args if m.is_Symbol] # Reals cannot contain elements other than numbers and symbols. intervals = [] # Build up a list of intervals between the elements intervals += [Interval(S.NegativeInfinity, nums[0], True, True)] for a, b in zip(nums[:-1], nums[1:]): intervals.append(Interval(a, b, True, True)) # both open intervals.append(Interval(nums[-1], S.Infinity, True, True)) if syms != []: return Complement(Union(intervals, evaluate=False), FiniteSet(syms), evaluate=False) else: return Union(intervals, evaluate=False) elif nums == []: return None elif isinstance(other, FiniteSet): unk = [] for i in self: c = sympify(other.contains(i)) if c is not S.true and c is not S.false: unk.append(i) unk = FiniteSet(unk) if unk == self: return not_true = [] for i in other: c = sympify(self.contains(i)) if c is not S.true: not_true.append(i) return Complement(FiniteSet(not_true), unk) return Set._complement(self, other) def _contains(self, other): """ Tests whether an element, other, is in the set. Relies on Python's set class. This tests for object equality All inputs are sympified Examples ======== >>> from sympy import FiniteSet >>> 1 in FiniteSet(1, 2) True >>> 5 in FiniteSet(1, 2) False """ r = false for e in self._elements: # override global evaluation so we can use Eq to do # do the evaluation t = Eq(e, other, evaluate=True) if t is true: return t elif t is not false: r = None return r @property def _boundary(self): return self @property def _inf(self): from sympy.functions.elementary.miscellaneous import Min return Min(self) @property def _sup(self): from sympy.functions.elementary.miscellaneous import Max return Max(self) @property def measure(self): return 0 def __len__(self): return len(self.args) def as_relational(self, symbol): """Rewrite a FiniteSet in terms of equalities and logic operators. """ from sympy.core.relational import Eq return Or([Eq(symbol, elem) for elem in self]) def compare(self, other): return (hash(self) - hash(other)) def _eval_evalf(self, prec): return FiniteSet([elem._eval_evalf(prec) for elem in self]) def _hashable_content(self): return (self._elements,) @property def _sorted_args(self): return tuple(ordered(self.args, Set._infimum_key)) def _eval_powerset(self): return self.func([self.func(s) for s in subsets(self.args)]) def __ge__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return other.is_subset(self) def __gt__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return self.is_proper_superset(other) def __le__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return self.is_subset(other) def __lt__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return self.is_proper_subset(other) converter[set] = lambda x: FiniteSet(x) converter[frozenset] = lambda x: FiniteSet(x) class SymmetricDifference(Set): """Represents the set of elements which are in either of the sets and not in their intersection. Examples ======== >>> from sympy import SymmetricDifference, FiniteSet >>> SymmetricDifference(FiniteSet(1, 2, 3), FiniteSet(3, 4, 5)) {1, 2, 4, 5} See Also ======== Complement, Union References ========== .. [1] https://en.wikipedia.org/wiki/Symmetric_difference """ is_SymmetricDifference = True def __new__(cls, a, b, evaluate=True): if evaluate: return SymmetricDifference.reduce(a, b) return Basic.__new__(cls, a, b) @staticmethod def reduce(A, B): result = B._symmetric_difference(A) if result is not None: return result else: return SymmetricDifference(A, B, evaluate=False) def imageset(args): r""" Return an image of the set under transformation ``f``. If this function can't compute the image, it returns an unevaluated ImageSet object. .. math:: { f(x) \| x \in self } Examples ======== >>> from sympy import S, Interval, Symbol, imageset, sin, Lambda >>> from sympy.abc import x, y >>> imageset(x, 2x, Interval(0, 2)) Interval(0, 4) >>> imageset(lambda x: 2x, Interval(0, 2)) Interval(0, 4) >>> imageset(Lambda(x, sin(x)), Interval(-2, 1)) ImageSet(Lambda(x, sin(x)), Interval(-2, 1)) >>> imageset(sin, Interval(-2, 1)) ImageSet(Lambda(x, sin(x)), Interval(-2, 1)) >>> imageset(lambda y: x + y, Interval(-2, 1)) ImageSet(Lambda(_x, _x + x), Interval(-2, 1)) Expressions applied to the set of Integers are simplified to show as few negatives as possible and linear expressions are converted to a canonical form. If this is not desirable then the unevaluated ImageSet should be used. >>> imageset(x, -2x + 5, S.Integers) ImageSet(Lambda(x, 2x + 1), Integers) See Also ======== sympy.sets.fancysets.ImageSet """ from sympy.core import Lambda from sympy.sets.fancysets import ImageSet from sympy.sets.setexpr import set_function if len(args) < 2: raise ValueError('imageset expects at least 2 args, got: %s' % len(args)) if isinstance(args[0], (Symbol, tuple)) and len(args) > 2: f = Lambda(args[0], args[1]) set_list = args[2:] else: f = args[0] set_list = args[1:] if isinstance(f, Lambda): pass elif ( isinstance(f, FunctionClass) # like cos or func_name(f) == '<lambda>' ): # TODO: should we support a way to sympify `lambda`? if len(set_list) == 1: var = _uniquely_named_symbol(Symbol('x'), f(Dummy())) expr = f(var) else: var = [Symbol('x%i' % (i+1)) for i in range(len(set_list))] expr = f(var) f = Lambda(var, expr) else: raise TypeError(filldedent(''' expecting lambda, Lambda, or FunctionClass, not \'%s\'.''' % func_name(f))) if any(not isinstance(s, Set) for s in set_list): name = [func_name(s) for s in set_list] raise ValueError( 'arguments after mapping should be sets, not %s' % name) if len(set_list) == 1: set = set_list[0] r = set_function(f, set) if r is None: r = ImageSet(f, set) if isinstance(r, ImageSet): f, set = r.args if f.variables[0] == f.expr: return set if isinstance(set, ImageSet): if len(set.lamda.variables) == 1 and len(f.variables) == 1: return imageset(Lambda(set.lamda.variables[0], f.expr.subs(f.variables[0], set.lamda.expr)), set.base_set) if r is not None: return r return ImageSet(f, set_list) def is_function_invertible_in_set(func, setv): """ Checks whether function ``func`` is invertible when the domain is restricted to set ``setv``. """ from sympy import exp, log # Functions known to always be invertible: if func in (exp, log): return True u = Dummy("u") fdiff = func(u).diff(u) # monotonous functions: # TODO: check subsets (`func` in `setv`) if (fdiff > 0) == True or (fdiff < 0) == True: return True # TODO: support more return None def simplify_union(args): """ Simplify a :class:`Union` using known rules We first start with global rules like 'Merge all FiniteSets' Then we iterate through all pairs and ask the constituent sets if they can simplify themselves with any other constituent. This process depends on ``union_sets(a, b)`` functions. """ from sympy.sets.handlers.union import union_sets # ===== Global Rules ===== if not args: return S.EmptySet for arg in args: if not isinstance(arg, Set): raise TypeError("Input args to Union must be Sets") # Merge all finite sets finite_sets = [x for x in args if x.is_FiniteSet] if len(finite_sets) > 1: a = (x for set in finite_sets for x in set) finite_set = FiniteSet(a) args = [finite_set] + [x for x in args if not x.is_FiniteSet] # ===== Pair-wise Rules ===== # Here we depend on rules built into the constituent sets args = set(args) new_args = True while new_args: for s in args: new_args = False for t in args - set((s,)): new_set = union_sets(s, t) # This returns None if s does not know how to intersect # with t. Returns the newly intersected set otherwise if new_set is not None: if not isinstance(new_set, set): new_set = set((new_set, )) new_args = (args - set((s, t))).union(new_set) break if new_args: args = new_args break if len(args) == 1: return args.pop() else: return Union(args, evaluate=False) def simplify_intersection(args): """ Simplify an intersection using known rules We first start with global rules like 'if any empty sets return empty set' and 'distribute any unions' Then we iterate through all pairs and ask the constituent sets if they can simplify themselves with any other constituent """ # ===== Global Rules ===== if not args: return S.UniversalSet for arg in args: if not isinstance(arg, Set): raise TypeError("Input args to Union must be Sets") # If any EmptySets return EmptySet if any(s.is_EmptySet for s in args): return S.EmptySet # Handle Finite sets rv = Intersection._handle_finite_sets(args) if rv is not None: return rv # If any of the sets are unions, return a Union of Intersections for s in args: if s.is_Union: other_sets = set(args) - set((s,)) if len(other_sets) > 0: other = Intersection(other_sets) return Union((Intersection(arg, other) for arg in s.args)) else: return Union([arg for arg in s.args]) for s in args: if s.is_Complement: args.remove(s) other_sets = args + [s.args[0]] return Complement(Intersection(other_sets), s.args[1]) from sympy.sets.handlers.intersection import intersection_sets # At this stage we are guaranteed not to have any # EmptySets, FiniteSets, or Unions in the intersection # ===== Pair-wise Rules ===== # Here we depend on rules built into the constituent sets args = set(args) new_args = True while new_args: for s in args: new_args = False for t in args - set((s,)): new_set = intersection_sets(s, t) # This returns None if s does not know how to intersect # with t. Returns the newly intersected set otherwise if new_set is not None: new_args = (args - set((s, t))).union(set((new_set, ))) break if new_args: args = new_args break if len(args) == 1: return args.pop() else: return Intersection(args, evaluate=False) def _handle_finite_sets(op, x, y, commutative): # Handle finite sets: fs_args, other = sift([x, y], lambda x: isinstance(x, FiniteSet), binary=True) if len(fs_args) == 2: return FiniteSet([op(i, j) for i in fs_args[0] for j in fs_args[1]]) elif len(fs_args) == 1: sets = [_apply_operation(op, other[0], i, commutative) for i in fs_args[0]] return Union(sets) else: return None def _apply_operation(op, x, y, commutative): from sympy.sets import ImageSet from sympy import symbols,Lambda d = Dummy('d') out = _handle_finite_sets(op, x, y, commutative) if out is None: out = op(x, y) if out is None and commutative: out = op(y, x) if out is None: _x, _y = symbols("x y") if isinstance(x, Set) and not isinstance(y, Set): out = ImageSet(Lambda(d, op(d, y)), x).doit() elif not isinstance(x, Set) and isinstance(y, Set): out = ImageSet(Lambda(d, op(x, d)), y).doit() else: out = ImageSet(Lambda((_x, _y), op(_x, _y)), x, y) return out def set_add(x, y): from sympy.sets.handlers.add import _set_add return _apply_operation(_set_add, x, y, commutative=True) def set_sub(x, y): from sympy.sets.handlers.add import _set_sub return _apply_operation(_set_sub, x, y, commutative=False) def set_mul(x, y): from sympy.sets.handlers.mul import _set_mul return _apply_operation(_set_mul, x, y, commutative=True) def set_div(x, y): from sympy.sets.handlers.mul import _set_div return _apply_operation(_set_div, x, y, commutative=False) def set_pow(x, y): from sympy.sets.handlers.power import _set_pow return _apply_operation(_set_pow, x, y, commutative=False) def set_function(f, x): from sympy.sets.handlers.functions import _set_function return _set_function(f, x)
9545dc4118ecfc8c261c6fae70b89ed3dcd3761a3b9346d4cca8d77290f61e30	from __future__ import print_function, division from sympy import S from sympy.core.basic import Basic from sympy.core.containers import Tuple from sympy.core.expr import Expr from sympy.core.function import Lambda from sympy.core.logic import fuzzy_bool from sympy.core.symbol import Symbol, Dummy from sympy.logic.boolalg import And, as_Boolean from sympy.sets.contains import Contains from sympy.sets.sets import Set, EmptySet, Union, FiniteSet from sympy.utilities.iterables import sift from sympy.utilities.misc import filldedent class ConditionSet(Set): """ Set of elements which satisfies a given condition. {x \| condition(x) is True for x in S} Examples ======== >>> from sympy import Symbol, S, ConditionSet, pi, Eq, sin, Interval >>> from sympy.abc import x, y, z >>> sin_sols = ConditionSet(x, Eq(sin(x), 0), Interval(0, 2pi)) >>> 2pi in sin_sols True >>> pi/2 in sin_sols False >>> 3pi in sin_sols False >>> 5 in ConditionSet(x, x2 > 4, S.Reals) True If the value is not in the base set, the result is false: >>> 5 in ConditionSet(x, x2 > 4, Interval(2, 4)) False Notes ===== Symbols with assumptions should be avoided or else the condition may evaluate without consideration of the set: >>> n = Symbol('n', negative=True) >>> cond = (n > 0); cond False >>> ConditionSet(n, cond, S.Integers) EmptySet() In addition, substitution of a dummy symbol can only be done with a generic symbol with matching commutativity or else a symbol that has identical assumptions. If the base set contains the dummy symbol it is logically distinct and will be the target of substitution. >>> c = ConditionSet(x, x < 1, {x, z}) >>> c.subs(x, y) ConditionSet(x, x < 1, {y, z}) A second substitution is needed to change the dummy symbol, too: >>> _.subs(x, y) ConditionSet(y, y < 1, {y, z}) And trying to replace the dummy symbol with anything but a symbol is ignored: the only change possible will be in the base set: >>> ConditionSet(y, y < 1, {y, z}).subs(y, 1) ConditionSet(y, y < 1, {z}) >>> _.subs(y, 1) ConditionSet(y, y < 1, {z}) Notes ===== If no base set is specified, the universal set is implied: >>> ConditionSet(x, x < 1).base_set UniversalSet Although expressions other than symbols may be used, this is discouraged and will raise an error if the expression is not found in the condition: >>> ConditionSet(x + 1, x + 1 < 1, S.Integers) ConditionSet(x + 1, x + 1 < 1, Integers) >>> ConditionSet(x + 1, x < 1, S.Integers) Traceback (most recent call last): ... ValueError: non-symbol dummy not recognized in condition Although the name is usually respected, it must be replaced if the base set is another ConditionSet and the dummy symbol and appears as a free symbol in the base set and the dummy symbol of the base set appears as a free symbol in the condition: >>> ConditionSet(x, x < y, ConditionSet(y, x + y < 2, S.Integers)) ConditionSet(lambda, (lambda < y) & (lambda + x < 2), Integers) The best way to do anything with the dummy symbol is to access it with the sym property. >>> _.subs(_.sym, Symbol('_x')) ConditionSet(_x, (_x < y) & (_x + x < 2), Integers) """ def __new__(cls, sym, condition, base_set=S.UniversalSet): # nonlinsolve uses ConditionSet to return an unsolved system # of equations (see _return_conditionset in solveset) so until # that is changed we do minimal checking of the args if isinstance(sym, (Tuple, tuple)): # unsolved eqns syntax sym = Tuple(sym) condition = FiniteSet(condition) return Basic.__new__(cls, sym, condition, base_set) condition = as_Boolean(condition) if isinstance(base_set, set): base_set = FiniteSet(base_set) elif not isinstance(base_set, Set): raise TypeError('expecting set for base_set') if condition is S.false: return S.EmptySet if condition is S.true: return base_set if isinstance(base_set, EmptySet): return base_set know = None if isinstance(base_set, FiniteSet): sifted = sift( base_set, lambda _: fuzzy_bool( condition.subs(sym, _))) if sifted[None]: know = FiniteSet(sifted[True]) base_set = FiniteSet(sifted[None]) else: return FiniteSet(*sifted[True]) if isinstance(base_set, cls): s, c, base_set = base_set.args if sym == s: condition = And(condition, c) elif sym not in c.free_symbols: condition = And(condition, c.xreplace({s: sym})) elif s not in condition.free_symbols: condition = And(condition.xreplace({sym: s}), c) sym = s else: # user will have to use cls.sym to get symbol dum = Symbol('lambda') if dum in condition.free_symbols or \ dum in c.free_symbols: dum = Dummy(str(dum)) condition = And( condition.xreplace({sym: dum}), c.xreplace({s: dum})) sym = dum if not isinstance(sym, Symbol): s = Dummy('lambda') if s not in condition.xreplace({sym: s}).free_symbols: raise ValueError( 'non-symbol dummy not recognized in condition') rv = Basic.__new__(cls, sym, condition, base_set) return rv if know is None else Union(know, rv) sym = property(lambda self: self.args[0]) condition = property(lambda self: self.args[1]) base_set = property(lambda self: self.args[2]) @property def free_symbols(self): s, c, b = self.args return (c.free_symbols - s.free_symbols) \| b.free_symbols def contains(self, other): return And(Lambda(self.sym, self.condition)( other), self.base_set.contains(other)) def _eval_subs(self, old, new): if not isinstance(self.sym, Expr): # Don't do anything with the equation set syntax; # that should go away, eventually. return self sym, cond, base = self.args if old == sym: # we try to be as lenient as possible to allow # the dummy symbol to be changed base = base.subs(old, new) if isinstance(new, Symbol): # if the assumptions don't match, the cond # might evaluate or change if (new.assumptions0 == old.assumptions0 or len(new.assumptions0) == 1 and old.is_commutative == new.is_commutative): if base != self.base_set: # it will be aggravating to have the dummy # symbol change if you are trying to target # the base set so if the base set is changed # leave the dummy symbol alone -- a second # subs will be needed to change the dummy return self.func(sym, cond, base) else: return self.func(new, cond.subs(old, new), base) raise ValueError(filldedent(''' A dummy symbol can only be replaced with a symbol having the same assumptions or one having a single assumption having the same commutativity. ''')) # don't target cond: it is there to tell how # the base set should be filtered and if new is not in # the base set then this substitution is ignored return self.func(sym, cond, base) cond = self.condition.subs(old, new) base = self.base_set.subs(old, new) if cond is S.true: return ConditionSet(new, Contains(new, base), base) return self.func(self.sym, cond, base) def dummy_eq(self, other, symbol=None): if not isinstance(other, self.func): return False if isinstance(self.sym, Symbol) != isinstance(other.sym, Symbol): # this test won't be necessary when unsolved equations # syntax is removed return False if symbol: raise ValueError('symbol arg not supported for ConditionSet') o = other if isinstance(self.sym, Symbol) and isinstance(other.sym, Symbol): # this code will not need to be in an if-block when # the unsolved equations syntax is removed o = other.func(self.sym, other.condition.subs(other.sym, self.sym), other.base_set) return self == o
f0a2fb02dddc9c3ac40edcb3a22ec781fadc6b87c7baae62418e0181b3241605	from __future__ import unicode_literals from sympy import (EmptySet, FiniteSet, S, Symbol, Interval, exp, erf, sqrt, symbols, simplify, Eq, cos, And, Tuple, integrate, oo, sin, Sum, Basic, DiracDelta, Lambda, log, pi) from sympy.stats import (Die, Normal, Exponential, FiniteRV, P, E, H, variance, covariance, skewness, density, given, independent, dependent, where, pspace, random_symbols, sample, Geometric) from sympy.stats.rv import (IndependentProductPSpace, rs_swap, Density, NamedArgsMixin, RandomSymbol, PSpace) from sympy.utilities.pytest import raises, XFAIL from sympy.core.compatibility import range from sympy.abc import x def test_where(): X, Y = Die('X'), Die('Y') Z = Normal('Z', 0, 1) assert where(Z2 <= 1).set == Interval(-1, 1) assert where( Z2 <= 1).as_boolean() == Interval(-1, 1).as_relational(Z.symbol) assert where(And(X > Y, Y > 4)).as_boolean() == And( Eq(X.symbol, 6), Eq(Y.symbol, 5)) assert len(where(X < 3).set) == 2 assert 1 in where(X < 3).set X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) assert where(And(X2 <= 1, X >= 0)).set == Interval(0, 1) XX = given(X, And(X2 <= 1, X >= 0)) assert XX.pspace.domain.set == Interval(0, 1) assert XX.pspace.domain.as_boolean() == \ And(0 <= X.symbol, X.symbol*2 <= 1, -oo < X.symbol, X.symbol < oo) with raises(TypeError): XX = given(X, X + 3) def test_random_symbols(): X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) assert set(random_symbols(2X + 1)) == set((X,)) assert set(random_symbols(2X + Y)) == set((X, Y)) assert set(random_symbols(2X + Y.symbol)) == set((X,)) assert set(random_symbols(2)) == set() def test_pspace(): X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) raises(ValueError, lambda: pspace(5 + 3)) raises(ValueError, lambda: pspace(x < 1)) assert pspace(X) == X.pspace assert pspace(2X + 1) == X.pspace assert pspace(2X + Y) == IndependentProductPSpace(Y.pspace, X.pspace) def test_rs_swap(): X = Normal('x', 0, 1) Y = Exponential('y', 1) XX = Normal('x', 0, 2) YY = Normal('y', 0, 3) expr = 2X + Y assert expr.subs(rs_swap((X, Y), (YY, XX))) == 2XX + YY def test_RandomSymbol(): X = Normal('x', 0, 1) Y = Normal('x', 0, 2) assert X.symbol == Y.symbol assert X != Y assert X.name == X.symbol.name X = Normal('lambda', 0, 1) # make sure we can use protected terms X = Normal('Lambda', 0, 1) # make sure we can use SymPy terms def test_RandomSymbol_diff(): X = Normal('x', 0, 1) assert (2X).diff(X) def test_random_symbol_no_pspace(): x = RandomSymbol(Symbol('x')) assert x.pspace == PSpace() def test_overlap(): X = Normal('x', 0, 1) Y = Normal('x', 0, 2) raises(ValueError, lambda: P(X > Y)) def test_IndependentProductPSpace(): X = Normal('X', 0, 1) Y = Normal('Y', 0, 1) px = X.pspace py = Y.pspace assert pspace(X + Y) == IndependentProductPSpace(px, py) assert pspace(X + Y) == IndependentProductPSpace(py, px) def test_E(): assert E(5) == 5 def test_H(): X = Normal('X', 0, 1) D = Die('D', sides = 4) G = Geometric('G', 0.5) assert H(X, X > 0) == -log(2)/2 + S(1)/2 + log(pi)/2 assert H(D, D > 2) == log(2) assert H(G).evalf().round(2) == 1.39 def test_Sample(): X = Die('X', 6) Y = Normal('Y', 0, 1) z = Symbol('z') assert sample(X) in [1, 2, 3, 4, 5, 6] assert sample(X + Y).is_Float P(X + Y > 0, Y < 0, numsamples=10).is_number assert E(X + Y, numsamples=10).is_number assert variance(X + Y, numsamples=10).is_number raises(ValueError, lambda: P(Y > z, numsamples=5)) assert P(sin(Y) <= 1, numsamples=10) == 1 assert P(sin(Y) <= 1, cos(Y) < 1, numsamples=10) == 1 # Make sure this doesn't raise an error E(Sum(1/zY, (z, 1, oo)), Y > 2, numsamples=3) assert all(i in range(1, 7) for i in density(X, numsamples=10)) assert all(i in range(4, 7) for i in density(X, X>3, numsamples=10)) def test_given(): X = Normal('X', 0, 1) Y = Normal('Y', 0, 1) A = given(X, True) B = given(X, Y > 2) assert X == A == B def test_dependence(): X, Y = Die('X'), Die('Y') assert independent(X, 2Y) assert not dependent(X, 2Y) X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) assert independent(X, Y) assert dependent(X, 2X) # Create a dependency XX, YY = given(Tuple(X, Y), Eq(X + Y, 3)) assert dependent(XX, YY) @XFAIL def test_dependent_finite(): X, Y = Die('X'), Die('Y') # Dependence testing requires symbolic conditions which currently break # finite random variables assert dependent(X, Y + X) XX, YY = given(Tuple(X, Y), X + Y > 5) # Create a dependency assert dependent(XX, YY) def test_normality(): X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) x, z = symbols('x, z', real=True, finite=True) dens = density(X - Y, Eq(X + Y, z)) assert integrate(dens(x), (x, -oo, oo)) == 1 def test_Density(): X = Die('X', 6) d = Density(X) assert d.doit() == density(X) def test_NamedArgsMixin(): class Foo(Basic, NamedArgsMixin): _argnames = 'foo', 'bar' a = Foo(1, 2) assert a.foo == 1 assert a.bar == 2 raises(AttributeError, lambda: a.baz) class Bar(Basic, NamedArgsMixin): pass raises(AttributeError, lambda: Bar(1, 2).foo) def test_density_constant(): assert density(3)(2) == 0 assert density(3)(3) == DiracDelta(0) def test_real(): x = Normal('x', 0, 1) assert x.is_real def test_issue_10052(): X = Exponential('X', 3) assert P(X < oo) == 1 assert P(X > oo) == 0 assert P(X < 2, X > oo) == 0 assert P(X < oo, X > oo) == 0 assert P(X < oo, X > 2) == 1 assert P(X < 3, X == 2) == 0 raises(ValueError, lambda: P(1)) raises(ValueError, lambda: P(X < 1, 2)) def test_issue_11934(): density = {0: .5, 1: .5} X = FiniteRV('X', density) assert E(X) == 0.5 assert P( X>= 2) == 0 def test_issue_8129(): X = Exponential('X', 4) assert P(X >= X) == 1 assert P(X > X) == 0 assert P(X > X+1) == 0
2b3e01dc76479f9dc2f962e24fe8254652027eee160efd66559c7d45cb7228af	import sympy import tempfile import os from sympy import symbols, Eq, Mod from sympy.external import import_module from sympy.tensor import IndexedBase, Idx from sympy.utilities.autowrap import autowrap, ufuncify, CodeWrapError from sympy.utilities.pytest import skip numpy = import_module('numpy', min_module_version='1.6.1') Cython = import_module('Cython', min_module_version='0.15.1') f2py = import_module('numpy.f2py', __import__kwargs={'fromlist': ['f2py']}) f2pyworks = False if f2py: try: autowrap(symbols('x'), 'f95', 'f2py') except (CodeWrapError, ImportError, OSError): f2pyworks = False else: f2pyworks = True a, b, c = symbols('a b c') n, m, d = symbols('n m d', integer=True) A, B, C = symbols('A B C', cls=IndexedBase) i = Idx('i', m) j = Idx('j', n) k = Idx('k', d) def has_module(module): """ Return True if module exists, otherwise run skip(). module should be a string. """ # To give a string of the module name to skip(), this function takes a # string. So we don't waste time running import_module() more than once, # just map the three modules tested here in this dict. modnames = {'numpy': numpy, 'Cython': Cython, 'f2py': f2py} if modnames[module]: if module == 'f2py' and not f2pyworks: skip("Couldn't run f2py.") return True skip("Couldn't import %s." % module) # # test runners used by several language-backend combinations # def runtest_autowrap_twice(language, backend): f = autowrap((((a + b)/c)5).expand(), language, backend) g = autowrap((((a + b)/c)4).expand(), language, backend) # check that autowrap updates the module name. Else, g gives the same as f assert f(1, -2, 1) == -1.0 assert g(1, -2, 1) == 1.0 def runtest_autowrap_trace(language, backend): has_module('numpy') trace = autowrap(A[i, i], language, backend) assert trace(numpy.eye(100)) == 100 def runtest_autowrap_matrix_vector(language, backend): has_module('numpy') x, y = symbols('x y', cls=IndexedBase) expr = Eq(y[i], A[i, j]x[j]) mv = autowrap(expr, language, backend) # compare with numpy's dot product M = numpy.random.rand(10, 20) x = numpy.random.rand(20) y = numpy.dot(M, x) assert numpy.sum(numpy.abs(y - mv(M, x))) < 1e-13 def runtest_autowrap_matrix_matrix(language, backend): has_module('numpy') expr = Eq(C[i, j], A[i, k]B[k, j]) matmat = autowrap(expr, language, backend) # compare with numpy's dot product M1 = numpy.random.rand(10, 20) M2 = numpy.random.rand(20, 15) M3 = numpy.dot(M1, M2) assert numpy.sum(numpy.abs(M3 - matmat(M1, M2))) < 1e-13 def runtest_ufuncify(language, backend): has_module('numpy') a, b, c = symbols('a b c') fabc = ufuncify([a, b, c], ab + c, backend=backend) facb = ufuncify([a, c, b], ab + c, backend=backend) grid = numpy.linspace(-2, 2, 50) b = numpy.linspace(-5, 4, 50) c = numpy.linspace(-1, 1, 50) expected = gridb + c numpy.testing.assert_allclose(fabc(grid, b, c), expected) numpy.testing.assert_allclose(facb(grid, c, b), expected) def runtest_issue_10274(language, backend): expr = (a - b + c)(13) tmp = tempfile.mkdtemp() f = autowrap(expr, language, backend, tempdir=tmp, helpers=('helper', a - b + c, (a, b, c))) assert f(1, 1, 1) == 1 for file in os.listdir(tmp): if file.startswith("wrapped_code_") and file.endswith(".c"): fil = open(tmp + '/' + file) lines = fil.readlines() assert lines[0] == "/****************************************************************************\n" assert "Code generated with sympy " + sympy.__version__ in lines[1] assert lines[2:] == [ " \n", " See http://www.sympy.org/ for more information. \n", " \n", " This file is part of 'autowrap' \n", " ***************************************************************************/\n", "#include " + '"' + file[:-1]+ 'h"' + "\n", "#include <math.h>\n", "\n", "double helper(double a, double b, double c) {\n", "\n", " double helper_result;\n", " helper_result = a - b + c;\n", " return helper_result;\n", "\n", "}\n", "\n", "double autofunc(double a, double b, double c) {\n", "\n", " double autofunc_result;\n", " autofunc_result = pow(helper(a, b, c), 13);\n", " return autofunc_result;\n", "\n", "}\n", ] def runtest_issue_15337(language, backend): has_module('numpy') # NOTE : autowrap was originally designed to only accept an iterable for # the kwarg "helpers", but in issue 10274 the user mistakenly thought that # if there was only a single helper it did not need to be passed via an # iterable that wrapped the helper tuple. There were no tests for this # behavior so when the code was changed to accept a single tuple it broke # the original behavior. These tests below ensure that both now work. a, b, c, d, e = symbols('a, b, c, d, e') expr = (a - b + c - d + e)13 exp_res = (1. - 2. + 3. - 4. + 5.)*13 f = autowrap(expr, language, backend, args=(a, b, c, d, e), helpers=('f1', a - b + c, (a, b, c))) numpy.testing.assert_allclose(f(1, 2, 3, 4, 5), exp_res) f = autowrap(expr, language, backend, args=(a, b, c, d, e), helpers=(('f1', a - b, (a, b)), ('f2', c - d, (c, d)))) numpy.testing.assert_allclose(f(1, 2, 3, 4, 5), exp_res) def test_issue_15230(): has_module('f2py') x, y = symbols('x, y') expr = Mod(x, 3.0) - Mod(y, -2.0) f = autowrap(expr, args=[x, y], language='F95') exp_res = float(expr.xreplace({x: 3.5, y: 2.7}).evalf()) assert abs(f(3.5, 2.7) - exp_res) < 1e-14 x, y = symbols('x, y', integer=True) expr = Mod(x, 3) - Mod(y, -2) f = autowrap(expr, args=[x, y], language='F95') assert f(3, 2) == expr.xreplace({x: 3, y: 2}) # # tests of language-backend combinations # # f2py def test_wrap_twice_f95_f2py(): has_module('f2py') runtest_autowrap_twice('f95', 'f2py') def test_autowrap_trace_f95_f2py(): has_module('f2py') runtest_autowrap_trace('f95', 'f2py') def test_autowrap_matrix_vector_f95_f2py(): has_module('f2py') runtest_autowrap_matrix_vector('f95', 'f2py') def test_autowrap_matrix_matrix_f95_f2py(): has_module('f2py') runtest_autowrap_matrix_matrix('f95', 'f2py') def test_ufuncify_f95_f2py(): has_module('f2py') runtest_ufuncify('f95', 'f2py') def test_issue_15337_f95_f2py(): has_module('f2py') runtest_issue_15337('f95', 'f2py') # Cython def test_wrap_twice_c_cython(): has_module('Cython') runtest_autowrap_twice('C', 'cython') def test_autowrap_trace_C_Cython(): has_module('Cython') runtest_autowrap_trace('C99', 'cython') def test_autowrap_matrix_vector_C_cython(): has_module('Cython') runtest_autowrap_matrix_vector('C99', 'cython') def test_autowrap_matrix_matrix_C_cython(): has_module('Cython') runtest_autowrap_matrix_matrix('C99', 'cython') def test_ufuncify_C_Cython(): has_module('Cython') runtest_ufuncify('C99', 'cython') def test_issue_10274_C_cython(): has_module('Cython') runtest_issue_10274('C89', 'cython') def test_issue_15337_C_cython(): has_module('Cython') runtest_issue_15337('C89', 'cython') def test_autowrap_custom_printer(): has_module('Cython') from sympy import pi from sympy.utilities.codegen import C99CodeGen from sympy.printing.ccode import C99CodePrinter from sympy.functions.elementary.exponential import exp class PiPrinter(C99CodePrinter): def _print_Pi(self, expr): return "S_PI" printer = PiPrinter() gen = C99CodeGen(printer=printer) gen.preprocessor_statements.append('#include "shortpi.h"') expr = pi a expected = ( '#include "%s"\n' '#include <math.h>\n' '#include "shortpi.h"\n' '\n' 'double autofunc(double a) {\n' '\n' ' double autofunc_result;\n' ' autofunc_result = S_PIa;\n' ' return autofunc_result;\n' '\n' '}\n' ) tmpdir = tempfile.mkdtemp() # write a trivial header file to use in the generated code open(os.path.join(tmpdir, 'shortpi.h'), 'w').write('#define S_PI 3.14') func = autowrap(expr, backend='cython', tempdir=tmpdir, code_gen=gen) assert func(4.2) == 3.14 4.2 # check that the generated code is correct for filename in os.listdir(tmpdir): if filename.startswith('wrapped_code') and filename.endswith('.c'): with open(os.path.join(tmpdir, filename)) as f: lines = f.readlines() expected = expected % filename.replace('.c', '.h') assert ''.join(lines[7:]) == expected # Numpy def test_ufuncify_numpy(): # This test doesn't use Cython, but if Cython works, then there is a valid # C compiler, which is needed. has_module('Cython') runtest_ufuncify('C99', 'numpy')
6f77352982e364f266138e1dbbe97b8b2c872ff354ce0a208ee976e61a2eafd0	from sympy import ( sqrt, Derivative, symbols, collect, Function, factor, Wild, S, collect_const, log, fraction, I, cos, Add, O,sin, rcollect, Mul, radsimp, diff, root, Symbol, Rational, exp) from sympy.core.mul import _unevaluated_Mul as umul from sympy.simplify.radsimp import _unevaluated_Add, collect_sqrt, fraction_expand from sympy.utilities.pytest import XFAIL, raises from sympy.abc import x, y, z, a, b, c, d def test_radsimp(): r2 = sqrt(2) r3 = sqrt(3) r5 = sqrt(5) r7 = sqrt(7) assert fraction(radsimp(1/r2)) == (sqrt(2), 2) assert radsimp(1/(1 + r2)) == \ -1 + sqrt(2) assert radsimp(1/(r2 + r3)) == \ -sqrt(2) + sqrt(3) assert fraction(radsimp(1/(1 + r2 + r3))) == \ (-sqrt(6) + sqrt(2) + 2, 4) assert fraction(radsimp(1/(r2 + r3 + r5))) == \ (-sqrt(30) + 2sqrt(3) + 3sqrt(2), 12) assert fraction(radsimp(1/(1 + r2 + r3 + r5))) == ( (-34sqrt(10) - 26sqrt(15) - 55sqrt(3) - 61sqrt(2) + 14sqrt(30) + 93 + 46sqrt(6) + 53sqrt(5), 71)) assert fraction(radsimp(1/(r2 + r3 + r5 + r7))) == ( (-50sqrt(42) - 133sqrt(5) - 34sqrt(70) - 145sqrt(3) + 22sqrt(105) + 185sqrt(2) + 62sqrt(30) + 135sqrt(7), 215)) z = radsimp(1/(1 + r2/3 + r3/5 + r5 + r7)) assert len((3616791619821680643598z).args) == 16 assert radsimp(1/z) == 1/z assert radsimp(1/z, max_terms=20).expand() == 1 + r2/3 + r3/5 + r5 + r7 assert radsimp(1/(r23)) == \ sqrt(2)/6 assert radsimp(1/(r2a + r3 + r5 + r7)) == ( (8sqrt(2)a*7 - 8sqrt(7)a6 - 8sqrt(5)a6 - 8sqrt(3)a6 - 180sqrt(2)a5 + 8sqrt(30)a5 + 8sqrt(42)a5 + 8sqrt(70)a5 - 24sqrt(105)a4 + 84sqrt(3)a4 + 100sqrt(5)a4 + 116sqrt(7)a4 - 72sqrt(70)a3 - 40sqrt(42)a3 - 8sqrt(30)a3 + 782sqrt(2)a3 - 462sqrt(3)a2 - 302sqrt(7)a2 - 254sqrt(5)a2 + 120sqrt(105)a2 - 795sqrt(2)a - 62sqrt(30)a + 82sqrt(42)a + 98sqrt(70)a - 118sqrt(105) + 59sqrt(7) + 295sqrt(5) + 531sqrt(3))/(16a*8 - 480a*6 + 3128a*4 - 6360a*2 + 3481)) assert radsimp(1/(r2a + r2b + r3 + r7)) == ( (sqrt(2)a(a + b)2 - 5sqrt(2)a + sqrt(42)a + sqrt(2)b(a + b)*2 - 5sqrt(2)b + sqrt(42)b - sqrt(7)(a + b)2 - sqrt(3)(a + b)*2 - 2sqrt(3) + 2sqrt(7))/(2a*4 + 8a*3b + 12a2b*2 - 20a*2 + 8ab3 - 40ab + 2b*4 - 20b*2 + 8)) assert radsimp(1/(r2a + r2b + r2c + r2d)) == \ sqrt(2)/(2a + 2b + 2c + 2d) assert radsimp(1/(1 + r2a + r2b + r2c + r2d)) == ( (sqrt(2)a + sqrt(2)b + sqrt(2)c + sqrt(2)d - 1)/(2a*2 + 4ab + 4ac + 4ad + 2b*2 + 4bc + 4bd + 2c*2 + 4cd + 2d2 - 1)) assert radsimp((y2 - x)/(y - sqrt(x))) == \ sqrt(x) + y assert radsimp(-(y*2 - x)/(y - sqrt(x))) == \ -(sqrt(x) + y) assert radsimp(1/(1 - I + aI)) == \ (-Ia + 1 + I)/(a2 - 2a + 2) assert radsimp(1/((-x + y)(x - sqrt(y)))) == \ (-x - sqrt(y))/((x - y)(x*2 - y)) e = (3 + 3sqrt(2))x(3x - 3sqrt(y)) assert radsimp(e) == x(3 + 3sqrt(2))(3x - 3sqrt(y)) assert radsimp(1/e) == ( (-9x + 9sqrt(2)x - 9sqrt(y) + 9sqrt(2)sqrt(y))/(9x(9x*2 - 9y))) assert radsimp(1 + 1/(1 + sqrt(3))) == \ Mul(S.Half, -1 + sqrt(3), evaluate=False) + 1 A = symbols("A", commutative=False) assert radsimp(x*2 + sqrt(2)x*2 - sqrt(2)xA) == \ x2 + sqrt(2)x*2 - sqrt(2)xA assert radsimp(1/sqrt(5 + 2 sqrt(6))) == -sqrt(2) + sqrt(3) assert radsimp(1/sqrt(5 + 2 * sqrt(6))3) == -(-sqrt(3) + sqrt(2))3 # issue 6532 assert fraction(radsimp(1/sqrt(x))) == (sqrt(x), x) assert fraction(radsimp(1/sqrt(2x + 3))) == (sqrt(2x + 3), 2x + 3) assert fraction(radsimp(1/sqrt(2(x + 3)))) == (sqrt(2x + 6), 2x + 6) # issue 5994 e = S('-(2 + 2sqrt(2) + 42(1/4))/' '(1 + 2(3/4) + 32(1/4) + 3sqrt(2))') assert radsimp(e).expand() == -22(S(3)/4) - 22*(S(1)/4) + 2 + 2sqrt(2) # issue 5986 (modifications to radimp didn't initially recognize this so # the test is included here) assert radsimp(1/(-sqrt(5)/2 - S(1)/2 + (-sqrt(5)/2 - S(1)/2)*2)) == 1 # from issue 5934 eq = ( (-240sqrt(2)sqrt(sqrt(5) + 5)sqrt(8sqrt(5) + 40) - 360sqrt(2)sqrt(-8sqrt(5) + 40)sqrt(-sqrt(5) + 5) - 120sqrt(10)sqrt(-8sqrt(5) + 40)sqrt(-sqrt(5) + 5) + 120sqrt(2)sqrt(-sqrt(5) + 5)sqrt(8sqrt(5) + 40) + 120sqrt(2)sqrt(-8sqrt(5) + 40)sqrt(sqrt(5) + 5) + 120sqrt(10)sqrt(-sqrt(5) + 5)sqrt(8sqrt(5) + 40) + 120sqrt(10)sqrt(-8sqrt(5) + 40)sqrt(sqrt(5) + 5))/(-36000 - 7200sqrt(5) + (12sqrt(10)sqrt(sqrt(5) + 5) + 24sqrt(10)sqrt(-sqrt(5) + 5))*2)) assert radsimp(eq) is S.NaN # it's 0/0 # work with normal form e = 1/sqrt(sqrt(7)/7 + 2sqrt(2) + 3sqrt(3) + 5sqrt(5)) + 3 assert radsimp(e) == ( -sqrt(sqrt(7) + 14sqrt(2) + 21sqrt(3) + 35sqrt(5))(-11654899sqrt(35) - 1577436sqrt(210) - 1278438sqrt(15) - 1346996sqrt(10) + 1635060sqrt(6) + 5709765 + 7539830sqrt(14) + 8291415sqrt(21))/1300423175 + 3) # obey power rules base = sqrt(3) - sqrt(2) assert radsimp(1/base3) == (sqrt(3) + sqrt(2))3 assert radsimp(1/(-base)3) == -(sqrt(2) + sqrt(3))3 assert radsimp(1/(-base)x) == (-base)(-x) assert radsimp(1/basex) == (sqrt(2) + sqrt(3))x assert radsimp(root(1/(-1 - sqrt(2)), -x)) == (-1)(-1/x)(1 + sqrt(2))*(1/x) # recurse e = cos(1/(1 + sqrt(2))) assert radsimp(e) == cos(-sqrt(2) + 1) assert radsimp(e/2) == cos(-sqrt(2) + 1)/2 assert radsimp(1/e) == 1/cos(-sqrt(2) + 1) assert radsimp(2/e) == 2/cos(-sqrt(2) + 1) assert fraction(radsimp(e/sqrt(x))) == (sqrt(x)cos(-sqrt(2)+1), x) # test that symbolic denominators are not processed r = 1 + sqrt(2) assert radsimp(x/r, symbolic=False) == -x(-sqrt(2) + 1) assert radsimp(x/(y + r), symbolic=False) == x/(y + 1 + sqrt(2)) assert radsimp(x/(y + r)/r, symbolic=False) == \ -x(-sqrt(2) + 1)/(y + 1 + sqrt(2)) # issue 7408 eq = sqrt(x)/sqrt(y) assert radsimp(eq) == umul(sqrt(x), sqrt(y), 1/y) assert radsimp(eq, symbolic=False) == eq # issue 7498 assert radsimp(sqrt(x)/sqrt(y)3) == umul(sqrt(x), sqrt(y3), 1/y3) # for coverage eq = sqrt(x)/y2 assert radsimp(eq) == eq def test_radsimp_issue_3214(): c, p = symbols('c p', positive=True) s = sqrt(c2 - p2) b = (c + Ip - s)/(c + Ip + s) assert radsimp(b) == -I(c + Ip - sqrt(c2 - p2))*2/(2cp) def test_collect_1(): """Collect with respect to a Symbol""" x, y, z, n = symbols('x,y,z,n') assert collect(1, x) == 1 assert collect( x + yx, x ) == x * (1 + y) assert collect( x + x2, x ) == x + x2 assert collect( x*2 + yx2, x ) == (x2)(1 + y) assert collect( x2 + yx, x ) == xy + x2 assert collect( 2x*2 + yx*2 + 3xy, [x] ) == x2(2 + y) + 3xy assert collect( 2x2 + yx*2 + 3xy, [y] ) == 2x*2 + y(x*2 + 3x) assert collect( ((1 + y + x)4).expand(), x) == ((1 + y)4).expand() + \ x(4(1 + y)3).expand() + x2(6(1 + y)2).expand() + \ x3(4(1 + y)).expand() + x*4 # symbols can be given as any iterable expr = x + y assert collect(expr, expr.free_symbols) == expr def test_collect_2(): """Collect with respect to a sum""" a, b, x = symbols('a,b,x') assert collect(a(cos(x) + sin(x)) + b(cos(x) + sin(x)), sin(x) + cos(x)) == (a + b)(cos(x) + sin(x)) def test_collect_3(): """Collect with respect to a product""" a, b, c = symbols('a,b,c') f = Function('f') x, y, z, n = symbols('x,y,z,n') assert collect(-x/8 + xy, -x) == x(y - S(1)/8) assert collect( 1 + x(y2), xy ) == 1 + x(y2) assert collect( xy + axy, xy) == xy(1 + a) assert collect( 1 + xy + axy, xy) == 1 + xy(1 + a) assert collect(axf(x) + b(xf(x)), xf(x)) == x(a + b)f(x) assert collect(axlog(x) + b(xlog(x)), xlog(x)) == x(a + b)log(x) assert collect(ax*2log(x)*2 + b(xlog(x))2, xlog(x)) == \ x*2log(x)*2(a + b) # with respect to a product of three symbols assert collect(yxz + axyz, xyz) == (1 + a)xyz def test_collect_4(): """Collect with respect to a power""" a, b, c, x = symbols('a,b,c,x') assert collect(axc + bxc, xc) == x*c(a + b) # issue 6096: 2 stays with c (unless c is integer or x is positive0 assert collect(ax(2c) + bx(2c), xc) == x(2c)(a + b) def test_collect_5(): """Collect with respect to a tuple""" a, x, y, z, n = symbols('a,x,y,z,n') assert collect(x*2y*4 + z(xy2)2 + z + az, [xy2, z]) in [ z(1 + a + x*2y4) + x2y4, z(1 + a) + x*2y*4(1 + z) ] assert collect((1 + (x + y) + (x + y)*2).expand(), [x, y]) == 1 + y + x(1 + 2y) + x2 + y2 def test_collect_D(): D = Derivative f = Function('f') x, a, b = symbols('x,a,b') fx = D(f(x), x) fxx = D(f(x), x, x) assert collect(afx + bfx, fx) == (a + b)fx assert collect(aD(fx, x) + bD(fx, x), fx) == (a + b)D(fx, x) assert collect(afxx + bfxx, fx) == (a + b)D(fx, x) # issue 4784 assert collect(5f(x) + 3fx, fx) == 5f(x) + 3fx assert collect(f(x) + f(x)diff(f(x), x) + xdiff(f(x), x)f(x), f(x).diff(x)) == \ (xf(x) + f(x))D(f(x), x) + f(x) assert collect(f(x) + f(x)diff(f(x), x) + xdiff(f(x), x)f(x), f(x).diff(x), exact=True) == \ (xf(x) + f(x))D(f(x), x) + f(x) assert collect(1/f(x) + 1/f(x)diff(f(x), x) + xdiff(f(x), x)/f(x), f(x).diff(x), exact=True) == \ (1/f(x) + x/f(x))D(f(x), x) + 1/f(x) e = (1 + xfx + fx)/f(x) assert collect(e.expand(), fx) == fx(x/f(x) + 1/f(x)) + 1/f(x) def test_collect_func(): f = ((x + a + 1)3).expand() assert collect(f, x) == a3 + 3a*2 + 3a + x3 + x2(3a + 3) + \ x(3a*2 + 6a + 3) + 1 assert collect(f, x, factor) == x*3 + 3x*2(a + 1) + 3x(a + 1)2 + \ (a + 1)3 assert collect(f, x, evaluate=False) == { S.One: a*3 + 3a*2 + 3a + 1, x: 3a2 + 6a + 3, x*2: 3a + 3, x3: 1 } assert collect(f, x, factor, evaluate=False) == { S.One: (a + 1)3, x: 3(a + 1)2, x2: umul(S(3), a + 1), x3: 1} def test_collect_order(): a, b, x, t = symbols('a,b,x,t') assert collect(t + tx + tx2 + O(x3), t) == t(1 + x + x2 + O(x3)) assert collect(t + tx + x2 + O(x3), t) == \ t(1 + x + O(x3)) + x2 + O(x*3) f = ax + bx + cx*2 + dx2 + O(x3) g = x(a + b) + x2(c + d) + O(x*3) assert collect(f, x) == g assert collect(f, x, distribute_order_term=False) == g f = sin(a + b).series(b, 0, 10) assert collect(f, [sin(a), cos(a)]) == \ sin(a)cos(b).series(b, 0, 10) + cos(a)sin(b).series(b, 0, 10) assert collect(f, [sin(a), cos(a)], distribute_order_term=False) == \ sin(a)cos(b).series(b, 0, 10).removeO() + \ cos(a)sin(b).series(b, 0, 10).removeO() + O(b10) def test_rcollect(): assert rcollect((x2y + xy + x + y)/(x + y), y) == \ (x + y(1 + x + x*2))/(x + y) assert rcollect(sqrt(-((x + 1)(y + 1))), z) == sqrt(-((x + 1)(y + 1))) def test_collect_D_0(): D = Derivative f = Function('f') x, a, b = symbols('x,a,b') fxx = D(f(x), x, x) assert collect(afxx + bfxx, fxx) == (a + b)fxx def test_collect_Wild(): """Collect with respect to functions with Wild argument""" a, b, x, y = symbols('a b x y') f = Function('f') w1 = Wild('.1') w2 = Wild('.2') assert collect(f(x) + af(x), f(w1)) == (1 + a)f(x) assert collect(f(x, y) + af(x, y), f(w1)) == f(x, y) + af(x, y) assert collect(f(x, y) + af(x, y), f(w1, w2)) == (1 + a)f(x, y) assert collect(f(x, y) + af(x, y), f(w1, w1)) == f(x, y) + af(x, y) assert collect(f(x, x) + af(x, x), f(w1, w1)) == (1 + a)f(x, x) assert collect(a(x + 1)y + (x + 1)y, w1y) == (1 + a)(x + 1)*y assert collect(a(x + 1)y + (x + 1)y, w1*b) == \ a(x + 1)y + (x + 1)y assert collect(a(x + 1)y + (x + 1)y, (x + 1)w2) == \ (1 + a)(x + 1)*y assert collect(a(x + 1)y + (x + 1)y, w1*w2) == (1 + a)(x + 1)*y def test_collect_const(): # coverage not provided by above tests assert collect_const(2sqrt(3) + 4asqrt(5)) == \ 2(2sqrt(5)a + sqrt(3)) # let the primitive reabsorb assert collect_const(2sqrt(3) + 4asqrt(5), sqrt(3)) == \ 2sqrt(3) + 4asqrt(5) assert collect_const(sqrt(2)(1 + sqrt(2)) + sqrt(3) + xsqrt(2)) == \ sqrt(2)(x + 1 + sqrt(2)) + sqrt(3) # issue 5290 assert collect_const(2x + 2y + 1, 2) == \ collect_const(2x + 2y + 1) == \ Add(S(1), Mul(2, x + y, evaluate=False), evaluate=False) assert collect_const(-y - z) == Mul(-1, y + z, evaluate=False) assert collect_const(2x - 2y - 2z, 2) == \ Mul(2, x - y - z, evaluate=False) assert collect_const(2x - 2y - 2z, -2) == \ _unevaluated_Add(2x, Mul(-2, y + z, evaluate=False)) # this is why the content_primitive is used eq = (sqrt(15 + 5sqrt(2))x + sqrt(3 + sqrt(2))y)2 assert collect_sqrt(eq + 2) == \ 2sqrt(sqrt(2) + 3)(sqrt(5)x + y) + 2 # issue 16296 assert collect_const(a + b + x/2 + y/2) == a + b + Mul(S.Half, x + y, evaluate=False) def test_issue_13143(): f = Function('f') fx = f(x).diff(x) e = f(x) + fx + f(x)fx # collect function before derivative assert collect(e, Wild('w')) == f(x)(fx + 1) + fx e = f(x) + f(x)fx + xfxf(x) assert collect(e, fx) == (xf(x) + f(x))fx + f(x) assert collect(e, f(x)) == (xfx + fx + 1)f(x) e = f(x) + fx + f(x)fx assert collect(e, [f(x), fx]) == f(x)(1 + fx) + fx assert collect(e, [fx, f(x)]) == fx(1 + f(x)) + f(x) def test_issue_6097(): assert collect(ay(2.0x) + by(2.0x), yx) == y(2.0x)(a + b) assert collect(a2(2.0x) + b2(2.0x), 2x) == 2(2.0x)(a + b) def test_fraction_expand(): eq = (x + y)y/x assert eq.expand(frac=True) == fraction_expand(eq) == (xy + y2)/x assert eq.expand() == y + y2/x def test_fraction(): x, y, z = map(Symbol, 'xyz') A = Symbol('A', commutative=False) assert fraction(Rational(1, 2)) == (1, 2) assert fraction(x) == (x, 1) assert fraction(1/x) == (1, x) assert fraction(x/y) == (x, y) assert fraction(x/2) == (x, 2) assert fraction(xy/z) == (xy, z) assert fraction(x/(yz)) == (x, yz) assert fraction(1/y2) == (1, y2) assert fraction(x/y2) == (x, y2) assert fraction((x2 + 1)/y) == (x2 + 1, y) assert fraction(x(y + 1)/y7) == (x(y + 1), y*7) assert fraction(exp(-x), exact=True) == (exp(-x), 1) assert fraction((1/(x + y))/2, exact=True) == (1, Mul(2,(x + y), evaluate=False)) assert fraction(xA/y) == (xA, y) assert fraction(xA*-1/y) == (xA*-1, y) n = symbols('n', negative=True) assert fraction(exp(n)) == (1, exp(-n)) assert fraction(exp(-n)) == (exp(-n), 1) p = symbols('p', positive=True) assert fraction(exp(-p)log(p), exact=True) == (exp(-p)log(p), 1) def test_issue_5615(): aA, Re, a, b, D = symbols('aA Re a b D') e = ((D3a + baA3)/Re).expand() assert collect(e, [aA3/Re, a]) == e def test_issue_5933(): from sympy import Polygon, RegularPolygon, denom x = Polygon(RegularPolygon((0, 0), 1, 5).vertices).centroid.x assert abs(denom(x).n()) > 1e-12 assert abs(denom(radsimp(x))) > 1e-12 # in case simplify didn't handle it def test_issue_14608(): a, b = symbols('a b', commutative=False) x, y = symbols('x y') raises(AttributeError, lambda: collect(ab + ba, a)) assert collect(xy + y(x+1), a) == xy + y(x+1) assert collect(xy + y(x+1) + ab + ba, y) == y(2x + 1) + ab + ba
9d804d08d03e9a109d247f8cefaf29a7343bc415c3719308b0e59b52cf31dced	from sympy import ( Abs, acos, Add, asin, atan, Basic, binomial, besselsimp, collect,cos, cosh, cot, coth, count_ops, csch, Derivative, diff, E, Eq, erf, exp, exp_polar, expand, expand_multinomial, factor, factorial, Float, fraction, Function, gamma, GoldenRatio, hyper, hypersimp, I, Integral, integrate, log, logcombine, Lt, Matrix, MatrixSymbol, Mul, nsimplify, O, oo, pi, Piecewise, posify, rad, Rational, root, S, separatevars, signsimp, simplify, sign, sin, sinc, sinh, solve, sqrt, Sum, Symbol, symbols, sympify, tan, tanh, zoo) from sympy.core.mul import _keep_coeff from sympy.simplify.simplify import nthroot, inversecombine from sympy.utilities.pytest import XFAIL, slow from sympy.core.compatibility import range from sympy.abc import x, y, z, t, a, b, c, d, e, f, g, h, i, k def test_issue_7263(): assert abs((simplify(30.82 - 82.52 * sin(rad(11.6))*2)).evalf() - \ 673.447451402970) < 1e-12 @XFAIL def test_factorial_simplify(): # There are more tests in test_factorials.py. These are just to # ensure that simplify() calls factorial_simplify correctly from sympy.specfun.factorials import factorial x = Symbol('x') assert simplify(factorial(x)/x) == factorial(x - 1) assert simplify(factorial(factorial(x))) == factorial(factorial(x)) def test_simplify_expr(): x, y, z, k, n, m, w, s, A = symbols('x,y,z,k,n,m,w,s,A') f = Function('f') assert all(simplify(tmp) == tmp for tmp in [I, E, oo, x, -x, -oo, -E, -I]) e = 1/x + 1/y assert e != (x + y)/(xy) assert simplify(e) == (x + y)/(xy) e = A2s*4/(4pikm*3) assert simplify(e) == e e = (4 + 4x - 2(2 + 2x))/(2 + 2x) assert simplify(e) == 0 e = (-4xy2 - 2y*3 - 2x*2y)/(x + y)*2 assert simplify(e) == -2y e = -x - y - (x + y)*(-1)y2 + (x + y)(-1)x2 assert simplify(e) == -2y e = (x + xy)/x assert simplify(e) == 1 + y e = (f(x) + yf(x))/f(x) assert simplify(e) == 1 + y e = (2 * (1/n - cos(n * pi)/n))/pi assert simplify(e) == (-cos(pin) + 1)/(pin)2 e = integrate(1/(x3 + 1), x).diff(x) assert simplify(e) == 1/(x3 + 1) e = integrate(x/(x2 + 3x + 1), x).diff(x) assert simplify(e) == x/(x*2 + 3x + 1) f = Symbol('f') A = Matrix([[2k - mw*2, -k], [-k, k - mw*2]]).inv() assert simplify((AMatrix([0, f]))[1]) == \ -f(2k - mw2)/(k2 - (k - mw*2)(2k - mw*2)) f = -x + y/(z + t) + zx/(z + t) + za/(z + t) + tx/(z + t) assert simplify(f) == (y + az)/(z + t) # issue 10347 expr = -x(y*2 - 1)(2y2(x*2 - 1)/(a(x2 - y2)2) + (x2 - 1) /(a(x2 - y2)))/(a(x2 - y2)) + x(-2x*2sqrt(-x*2y2 + x2 + y*2 - 1)sin(z)/(a(x2 - y2)2) - x2sqrt(-x*2y2 + x2 + y*2 - 1)sin(z)/(a(x2 - 1)(x2 - y2)) + (x*2sqrt((-x*2 + 1) (y*2 - 1))sqrt(-x*2y2 + x2 + y*2 - 1)sin(z)/(x2 - 1) + sqrt( (-x2 + 1)(y2 - 1))(x(-xy2 + x)/sqrt(-x2y2 + x2 + y2 - 1) + sqrt(-x2y2 + x2 + y*2 - 1))sin(z))/(asqrt((-x2 + 1)( y*2 - 1))(x2 - y2)))sqrt(-x2y2 + x2 + y*2 - 1)sin(z)/(a* (x2 - y2)) + x(-2x*2sqrt(-x*2y2 + x2 + y*2 - 1)cos(z)/(a* (x2 - y2)2) - x2sqrt(-x2y2 + x2 + y*2 - 1)cos(z)/(a* (x*2 - 1)(x2 - y2)) + (x*2sqrt((-x*2 + 1)(y*2 - 1))sqrt(-x*2 y2 + x2 + y*2 - 1)cos(z)/(x*2 - 1) + xsqrt((-x*2 + 1)(y*2 - 1))(-xy2 + x)cos(z)/sqrt(-x*2y2 + x2 + y2 - 1) + sqrt((-x2 + 1)(y2 - 1))sqrt(-x*2y2 + x2 + y*2 - 1)cos(z))/(asqrt((-x2 + 1)(y*2 - 1))(x2 - y2)))sqrt(-x2y2 + x2 + y*2 - 1)cos( z)/(a(x2 - y2)) - ysqrt((-x*2 + 1)(y*2 - 1))(-xysqrt(-x*2 y2 + x2 + y*2 - 1)sin(z)/(a(x2 - y2)(y*2 - 1)) + 2xysqrt( -x*2y2 + x2 + y*2 - 1)sin(z)/(a(x2 - y2)2) + (xysqrt(( -x2 + 1)(y*2 - 1))sqrt(-x*2y2 + x2 + y*2 - 1)sin(z)/(y*2 - 1) + xsqrt((-x*2 + 1)(y*2 - 1))(-x*2y + y)sin(z)/sqrt(-x2y2 + x2 + y*2 - 1))/(asqrt((-x*2 + 1)(y*2 - 1))(x2 - y2)))sin( z)/(a(x2 - y2)) + y(x2 - 1)(-2xy(x2 - 1)/(a(x2 - y2) *2) + 2xy/(a(x2 - y2)))/(a(x2 - y2)) + y(x*2 - 1)(y*2 - 1)(-xysqrt(-x*2y2 + x2 + y*2 - 1)cos(z)/(a(x2 - y2)(y*2 - 1)) + 2xysqrt(-x*2y2 + x2 + y*2 - 1)cos(z)/(a(x2 - y2) 2) + (xysqrt((-x2 + 1)(y*2 - 1))sqrt(-x*2y2 + x2 + y*2 - 1)cos(z)/(y*2 - 1) + xsqrt((-x*2 + 1)(y*2 - 1))(-x*2y + y)cos( z)/sqrt(-x2y2 + x2 + y*2 - 1))/(asqrt((-x*2 + 1)(y*2 - 1) )(x2 - y2)))cos(z)/(asqrt((-x*2 + 1)(y*2 - 1))(x2 - y2) ) - xsqrt((-x2 + 1)(y*2 - 1))sqrt(-x*2y2 + x2 + y*2 - 1)sin( z)2/(a2(x2 - 1)(x2 - y2)(y2 - 1)) - xsqrt((-x*2 + 1)( y*2 - 1))sqrt(-x*2y2 + x2 + y*2 - 1)cos(z)2/(a2(x2 - 1)( x2 - y2)(y2 - 1)) assert simplify(expr) == 2x/(a*2(x2 - y2)) A, B = symbols('A,B', commutative=False) assert simplify(AB - BA) == AB - BA assert simplify(A/(1 + y/x)) == xA/(x + y) assert simplify(A(1/x + 1/y)) == A/x + A/y #(x + y)A/(xy) assert simplify(log(2) + log(3)) == log(6) assert simplify(log(2x) - log(2)) == log(x) assert simplify(hyper([], [], x)) == exp(x) def test_issue_3557(): f_1 = xa + yb + zc - 1 f_2 = xd + ye + zf - 1 f_3 = xg + yh + zi - 1 solutions = solve([f_1, f_2, f_3], x, y, z, simplify=False) assert simplify(solutions[y]) == \ (ai + cd + fg - af - cg - di)/ \ (aei + bfg + cdh - afh - bdi - ceg) def test_simplify_other(): assert simplify(sin(x)2 + cos(x)2) == 1 assert simplify(gamma(x + 1)/gamma(x)) == x assert simplify(sin(x)2 + cos(x)2 + factorial(x)/gamma(x)) == 1 + x assert simplify( Eq(sin(x)2 + cos(x)2, factorial(x)/gamma(x))) == Eq(x, 1) nc = symbols('nc', commutative=False) assert simplify(x + xnc) == x(1 + nc) # issue 6123 # f = exp(-I(ksqrt(t) + x/(2sqrt(t)))2) # ans = integrate(f, (k, -oo, oo), conds='none') ans = I(-pixexp(-3Ipi/4 + Ix2/(4t))erf(xexp(-3Ipi/4)/ (2sqrt(t)))/(2sqrt(t)) + pixexp(-3Ipi/4 + Ix2/(4t))/ (2sqrt(t)))exp(-Ix2/(4t))/(sqrt(pi)x) - Isqrt(pi) * \ (-erf(xexp(Ipi/4)/(2sqrt(t))) + 1)exp(Ipi/4)/(2sqrt(t)) assert simplify(ans) == -(-1)*(S(3)/4)sqrt(pi)/sqrt(t) # issue 6370 assert simplify(2(2 + x)/4) == 2x def test_simplify_complex(): cosAsExp = cos(x)._eval_rewrite_as_exp(x) tanAsExp = tan(x)._eval_rewrite_as_exp(x) assert simplify(cosAsExptanAsExp) == sin(x) # issue 4341 # issue 10124 assert simplify(exp(Matrix([[0, -1], [1, 0]]))) == Matrix([[cos(1), -sin(1)], [sin(1), cos(1)]]) def test_simplify_ratio(): # roots of x3-3x+5 roots = ['(1/2 - sqrt(3)I/2)(sqrt(21)/2 + 5/2)*(1/3) + 1/((1/2 - ' 'sqrt(3)I/2)(sqrt(21)/2 + 5/2)(1/3))', '1/((1/2 + sqrt(3)I/2)(sqrt(21)/2 + 5/2)(1/3)) + ' '(1/2 + sqrt(3)I/2)(sqrt(21)/2 + 5/2)(1/3)', '-(sqrt(21)/2 + 5/2)(1/3) - 1/(sqrt(21)/2 + 5/2)(1/3)'] for r in roots: r = S(r) assert count_ops(simplify(r, ratio=1)) <= count_ops(r) # If ratio=oo, simplify() is always applied: assert simplify(r, ratio=oo) is not r def test_simplify_measure(): measure1 = lambda expr: len(str(expr)) measure2 = lambda expr: -count_ops(expr) # Return the most complicated result expr = (x + 1)/(x + sin(x)2 + cos(x)2) assert measure1(simplify(expr, measure=measure1)) <= measure1(expr) assert measure2(simplify(expr, measure=measure2)) <= measure2(expr) expr2 = Eq(sin(x)2 + cos(x)2, 1) assert measure1(simplify(expr2, measure=measure1)) <= measure1(expr2) assert measure2(simplify(expr2, measure=measure2)) <= measure2(expr2) def test_simplify_rational(): expr = 2x2.y assert simplify(expr, rational = True) == 2(x+y) assert simplify(expr, rational = None) == 2.0*(x+y) assert simplify(expr, rational = False) == expr def test_simplify_issue_1308(): assert simplify(exp(-Rational(1, 2)) + exp(-Rational(3, 2))) == \ (1 + E)exp(-Rational(3, 2)) def test_issue_5652(): assert simplify(E + exp(-E)) == exp(-E) + E n = symbols('n', commutative=False) assert simplify(n + n(-n)) == n + n(-n) def test_simplify_fail1(): x = Symbol('x') y = Symbol('y') e = (x + y)*2/(-4xy2 - 2y*3 - 2x*2y) assert simplify(e) == 1 / (-2y) def test_nthroot(): assert nthroot(90 + 34sqrt(7), 3) == sqrt(7) + 3 q = 1 + sqrt(2) - 2sqrt(3) + sqrt(6) + sqrt(7) assert nthroot(expand_multinomial(q3), 3) == q assert nthroot(41 + 29sqrt(2), 5) == 1 + sqrt(2) assert nthroot(-41 - 29sqrt(2), 5) == -1 - sqrt(2) expr = 1320sqrt(10) + 4216 + 2576sqrt(6) + 1640sqrt(15) assert nthroot(expr, 5) == 1 + sqrt(6) + sqrt(15) q = 1 + sqrt(2) + sqrt(3) + sqrt(5) assert expand_multinomial(nthroot(expand_multinomial(q*5), 5)) == q q = 1 + sqrt(2) + 7sqrt(6) + 2sqrt(10) assert nthroot(expand_multinomial(q5), 5, 8) == q q = 1 + sqrt(2) - 2sqrt(3) + 1171sqrt(6) assert nthroot(expand_multinomial(q3), 3) == q assert nthroot(expand_multinomial(q6), 6) == q def test_nthroot1(): q = 1 + sqrt(2) + sqrt(3) + S(1)/1020 p = expand_multinomial(q5) assert nthroot(p, 5) == q q = 1 + sqrt(2) + sqrt(3) + S(1)/1030 p = expand_multinomial(q5) assert nthroot(p, 5) == q def test_separatevars(): x, y, z, n = symbols('x,y,z,n') assert separatevars(2nxz + 2xyz) == 2xz(n + y) assert separatevars(xz + xyz) == xz(1 + y) assert separatevars(pixz + pixyz) == pixz(1 + y) assert separatevars(xy*2sin(x) + xsin(x)sin(y)) == \ x(sin(y) + y2)sin(x) assert separatevars(xexp(x + y) + xexp(x)) == x(1 + exp(y))exp(x) assert separatevars((x(y + 1))z).is_Pow # != xz(1 + y)*z assert separatevars(1 + x + y + xy) == (x + 1)(y + 1) assert separatevars(y/piexp(-(z - x)/cos(n))) == \ yexp(x/cos(n))exp(-z/cos(n))/pi assert separatevars((x + y)(x - y) + y2 + 2x + 1) == (x + 1)2 # issue 4858 p = Symbol('p', positive=True) assert separatevars(sqrt(p2 + xp2)) == psqrt(1 + x) assert separatevars(sqrt(y(p2 + xp*2))) == psqrt(y(1 + x)) assert separatevars(sqrt(y(p*2 + xp*2)), force=True) == \ psqrt(y)sqrt(1 + x) # issue 4865 assert separatevars(sqrt(xy)).is_Pow assert separatevars(sqrt(xy), force=True) == sqrt(x)sqrt(y) # issue 4957 # any type sequence for symbols is fine assert separatevars(((2x + 2)y), dict=True, symbols=()) == \ {'coeff': 1, x: 2x + 2, y: y} # separable assert separatevars(((2x + 2)y), dict=True, symbols=[x]) == \ {'coeff': y, x: 2x + 2} assert separatevars(((2x + 2)y), dict=True, symbols=[]) == \ {'coeff': 1, x: 2x + 2, y: y} assert separatevars(((2x + 2)y), dict=True) == \ {'coeff': 1, x: 2x + 2, y: y} assert separatevars(((2x + 2)y), dict=True, symbols=None) == \ {'coeff': y(2x + 2)} # not separable assert separatevars(3, dict=True) is None assert separatevars(2x + y, dict=True, symbols=()) is None assert separatevars(2x + y, dict=True) is None assert separatevars(2x + y, dict=True, symbols=None) == {'coeff': 2x + y} # issue 4808 n, m = symbols('n,m', commutative=False) assert separatevars(m + nm) == (1 + n)m assert separatevars(x + xn) == x(1 + n) # issue 4910 f = Function('f') assert separatevars(f(x) + xf(x)) == f(x) + xf(x) # a noncommutable object present eq = x(1 + hyper((), (), yz)) assert separatevars(eq) == eq def test_separatevars_advanced_factor(): x, y, z = symbols('x,y,z') assert separatevars(1 + log(x)log(y) + log(x) + log(y)) == \ (log(x) + 1)(log(y) + 1) assert separatevars(1 + x - log(z) - xlog(z) - exp(y)log(z) - xexp(y)log(z) + xexp(y) + exp(y)) == \ -((x + 1)(log(z) - 1)(exp(y) + 1)) x, y = symbols('x,y', positive=True) assert separatevars(1 + log(xlog(y)) + log(xy)) == \ (log(x) + 1)(log(y) + 1) def test_hypersimp(): n, k = symbols('n,k', integer=True) assert hypersimp(factorial(k), k) == k + 1 assert hypersimp(factorial(k2), k) is None assert hypersimp(1/factorial(k), k) == 1/(k + 1) assert hypersimp(2k/factorial(k)2, k) == 2/(k + 1)2 assert hypersimp(binomial(n, k), k) == (n - k)/(k + 1) assert hypersimp(binomial(n + 1, k), k) == (n - k + 1)/(k + 1) term = (4k + 1)factorial(k)/factorial(2k + 1) assert hypersimp(term, k) == (S(1)/2)((4k + 5)/(3 + 14k + 8k*2)) term = 1/((2k - 1)factorial(2k + 1)) assert hypersimp(term, k) == (k - S(1)/2)/((k + 1)(2k + 1)(2k + 3)) term = binomial(n, k)(-1)k/factorial(k) assert hypersimp(term, k) == (k - n)/(k + 1)2 def test_nsimplify(): x = Symbol("x") assert nsimplify(0) == 0 assert nsimplify(-1) == -1 assert nsimplify(1) == 1 assert nsimplify(1 + x) == 1 + x assert nsimplify(2.7) == Rational(27, 10) assert nsimplify(1 - GoldenRatio) == (1 - sqrt(5))/2 assert nsimplify((1 + sqrt(5))/4, [GoldenRatio]) == GoldenRatio/2 assert nsimplify(2/GoldenRatio, [GoldenRatio]) == 2GoldenRatio - 2 assert nsimplify(exp(5piI/3, evaluate=False)) == \ sympify('1/2 - sqrt(3)I/2') assert nsimplify(sin(3pi/5, evaluate=False)) == \ sympify('sqrt(sqrt(5)/8 + 5/8)') assert nsimplify(sqrt(atan('1', evaluate=False))(2 + I), [pi]) == \ sqrt(pi) + sqrt(pi)/2I assert nsimplify(2 + exp(2atan('1/4')I)) == sympify('49/17 + 8I/17') assert nsimplify(pi, tolerance=0.01) == Rational(22, 7) assert nsimplify(pi, tolerance=0.001) == Rational(355, 113) assert nsimplify(0.33333, tolerance=1e-4) == Rational(1, 3) assert nsimplify(2.0(1/3.), tolerance=0.001) == Rational(635, 504) assert nsimplify(2.0(1/3.), tolerance=0.001, full=True) == \ 2Rational(1, 3) assert nsimplify(x + .5, rational=True) == Rational(1, 2) + x assert nsimplify(1/.3 + x, rational=True) == Rational(10, 3) + x assert nsimplify(log(3).n(), rational=True) == \ sympify('109861228866811/100000000000000') assert nsimplify(Float(0.272198261287950), [pi, log(2)]) == pilog(2)/8 assert nsimplify(Float(0.272198261287950).n(3), [pi, log(2)]) == \ -pi/4 - log(2) + S(7)/4 assert nsimplify(x/7.0) == x/7 assert nsimplify(pi/1e2) == pi/100 assert nsimplify(pi/1e2, rational=False) == pi/100.0 assert nsimplify(pi/1e-7) == 10000000pi assert not nsimplify( factor(-3.0z*2(z2)(-2.5) + 3(z2)(-1.5))).atoms(Float) e = x0.0 assert e.is_Pow and nsimplify(x0.0) == 1 assert nsimplify(3.333333, tolerance=0.1, rational=True) == Rational(10, 3) assert nsimplify(3.333333, tolerance=0.01, rational=True) == Rational(10, 3) assert nsimplify(3.666666, tolerance=0.1, rational=True) == Rational(11, 3) assert nsimplify(3.666666, tolerance=0.01, rational=True) == Rational(11, 3) assert nsimplify(33, tolerance=10, rational=True) == Rational(33) assert nsimplify(33.33, tolerance=10, rational=True) == Rational(30) assert nsimplify(37.76, tolerance=10, rational=True) == Rational(40) assert nsimplify(-203.1) == -S(2031)/10 assert nsimplify(.2, tolerance=0) == S.One/5 assert nsimplify(-.2, tolerance=0) == -S.One/5 assert nsimplify(.2222, tolerance=0) == S(1111)/5000 assert nsimplify(-.2222, tolerance=0) == -S(1111)/5000 # issue 7211, PR 4112 assert nsimplify(S(2e-8)) == S(1)/50000000 # issue 7322 direct test assert nsimplify(1e-42, rational=True) != 0 # issue 10336 inf = Float('inf') infs = (-oo, oo, inf, -inf) for i in infs: ans = sign(i)oo assert nsimplify(i) == ans assert nsimplify(i + x) == x + ans assert nsimplify(0.33333333, rational=True, rational_conversion='exact') == Rational(0.33333333) # Make sure nsimplify on expressions uses full precision assert nsimplify(pi.evalf(100)x, rational_conversion='exact').evalf(100) == pi.evalf(100)x def test_issue_9448(): tmp = sympify("1/(1 - (-1)(2/3) - (-1)(1/3)) + 1/(1 + (-1)(2/3) + (-1)(1/3))") assert nsimplify(tmp) == S(1)/2 def test_extract_minus_sign(): x = Symbol("x") y = Symbol("y") a = Symbol("a") b = Symbol("b") assert simplify(-x/-y) == x/y assert simplify(-x/y) == -x/y assert simplify(x/y) == x/y assert simplify(x/-y) == -x/y assert simplify(-x/0) == zoox assert simplify(S(-5)/0) == zoo assert simplify(-ax/(-y - b)) == ax/(b + y) def test_diff(): x = Symbol("x") y = Symbol("y") f = Function("f") g = Function("g") assert simplify(g(x).diff(x)f(x).diff(x) - f(x).diff(x)g(x).diff(x)) == 0 assert simplify(2f(x)f(x).diff(x) - diff(f(x)2, x)) == 0 assert simplify(diff(1/f(x), x) + f(x).diff(x)/f(x)2) == 0 assert simplify(f(x).diff(x, y) - f(x).diff(y, x)) == 0 def test_logcombine_1(): x, y = symbols("x,y") a = Symbol("a") z, w = symbols("z,w", positive=True) b = Symbol("b", real=True) assert logcombine(log(x) + 2log(y)) == log(x) + 2log(y) assert logcombine(log(x) + 2log(y), force=True) == log(xy2) assert logcombine(alog(w) + log(z)) == alog(w) + log(z) assert logcombine(blog(z) + blog(x)) == log(zb) + blog(x) assert logcombine(blog(z) - log(w)) == log(zb/w) assert logcombine(log(x)log(z)) == log(x)log(z) assert logcombine(log(w)log(x)) == log(w)log(x) assert logcombine(cos(-2log(z) + blog(w))) in [cos(log(wb/z2)), cos(log(z2/wb))] assert logcombine(log(log(x) - log(y)) - log(z), force=True) == \ log(log(x/y)/z) assert logcombine((2 + I)log(x), force=True) == (2 + I)log(x) assert logcombine((x2 + log(x) - log(y))/(xy), force=True) == \ (x*2 + log(x/y))/(xy) # the following could also give log(zxlog(y2)), what we # are testing is that a canonical result is obtained assert logcombine(log(x)2log(y) + log(z), force=True) == \ log(zylog(x2)) assert logcombine((xy + sqrt(x4 + y4) + log(x) - log(y))/(pix*Rational(2, 3) sqrt(y)*3), force=True) == ( xy + sqrt(x4 + y4) + log(x/y))/(pix(S(2)/3)y*(S(3)/2)) assert logcombine(gamma(-log(x/y))acos(-log(x/y)), force=True) == \ acos(-log(x/y))gamma(-log(x/y)) assert logcombine(2log(z)log(w)log(x) + log(z) + log(w)) == \ log(zlog(w2))log(x) + log(wz) assert logcombine(3log(w) + 3log(z)) == log(w*3z*3) assert logcombine(x(y + 1) + log(2) + log(3)) == x(y + 1) + log(6) assert logcombine((x + y)log(w) + (-x - y)log(3)) == (x + y)log(w/3) # a single unknown can combine assert logcombine(log(x) + log(2)) == log(2x) eq = log(abs(x)) + log(abs(y)) assert logcombine(eq) == eq reps = {x: 0, y: 0} assert log(abs(x)abs(y)).subs(reps) != eq.subs(reps) def test_logcombine_complex_coeff(): i = Integral((sin(x2) + cos(x3))/x, x) assert logcombine(i, force=True) == i assert logcombine(i + 2log(x), force=True) == \ i + log(x2) def test_issue_5950(): x, y = symbols("x,y", positive=True) assert logcombine(log(3) - log(2)) == log(Rational(3,2), evaluate=False) assert logcombine(log(x) - log(y)) == log(x/y) assert logcombine(log(Rational(3,2), evaluate=False) - log(2)) == \ log(Rational(3,4), evaluate=False) def test_posify(): from sympy.abc import x assert str(posify( x + Symbol('p', positive=True) + Symbol('n', negative=True))) == '(_x + n + p, {_x: x})' eq, rep = posify(1/x) assert log(eq).expand().subs(rep) == -log(x) assert str(posify([x, 1 + x])) == '([_x, _x + 1], {_x: x})' x = symbols('x') p = symbols('p', positive=True) n = symbols('n', negative=True) orig = [x, n, p] modified, reps = posify(orig) assert str(modified) == '[_x, n, p]' assert [w.subs(reps) for w in modified] == orig assert str(Integral(posify(1/x + y)[0], (y, 1, 3)).expand()) == \ 'Integral(1/_x, (y, 1, 3)) + Integral(_y, (y, 1, 3))' assert str(Sum(posify(1/xn)[0], (n,1,3)).expand()) == \ 'Sum(_x(-n), (n, 1, 3))' # issue 16438 k = Symbol('k', finite=True) eq, rep = posify(k) assert eq.assumptions0 == {'positive': True, 'zero': False, 'imaginary': False, 'nonpositive': False, 'commutative': True, 'hermitian': True, 'real': True, 'nonzero': True, 'nonnegative': True, 'negative': False, 'complex': True, 'finite': True, 'infinite': False} def test_issue_4194(): # simplify should call cancel from sympy.abc import x, y f = Function('f') assert simplify((4x + 6f(y))/(2x + 3f(y))) == 2 @XFAIL def test_simplify_float_vs_integer(): # Test for issue 4473: # https://github.com/sympy/sympy/issues/4473 assert simplify(x2.0 - x2) == 0 assert simplify(x2 - x2.0) == 0 def test_as_content_primitive(): assert (x/2 + y).as_content_primitive() == (S.Half, x + 2y) assert (x/2 + y).as_content_primitive(clear=False) == (S.One, x/2 + y) assert (y(x/2 + y)).as_content_primitive() == (S.Half, y(x + 2y)) assert (y(x/2 + y)).as_content_primitive(clear=False) == (S.One, y(x/2 + y)) # although the _as_content_primitive methods do not alter the underlying structure, # the as_content_primitive function will touch up the expression and join # bases that would otherwise have not been joined. assert ((x(2 + 2x)(3x + 3)2)).as_content_primitive() == \ (18, x(x + 1)*3) assert (2 + 2x + 2y(3 + 3y)).as_content_primitive() == \ (2, x + 3y(y + 1) + 1) assert ((2 + 6x)*2).as_content_primitive() == \ (4, (3x + 1)*2) assert ((2 + 6x)*(2y)).as_content_primitive() == \ (1, (_keep_coeff(S(2), (3x + 1)))(2y)) assert (5 + 10x + 2y(3 + 3y)).as_content_primitive() == \ (1, 10x + 6y(y + 1) + 5) assert ((5(x(1 + y)) + 2x(3 + 3y))).as_content_primitive() == \ (11, x(y + 1)) assert ((5(x(1 + y)) + 2x(3 + 3y))2).as_content_primitive() == \ (121, x2(y + 1)2) assert (y2).as_content_primitive() == \ (1, y2) assert (S.Infinity).as_content_primitive() == (1, oo) eq = x(2 + y) assert (eq).as_content_primitive() == (1, eq) assert (S.Half(2 + x)).as_content_primitive() == (S(1)/4, 2-x) assert ((-S.Half)(2 + x)).as_content_primitive() == \ (S(1)/4, (-S.Half)x) assert ((-S.Half)(2 + x)).as_content_primitive() == \ (S(1)/4, (-S.Half)x) assert (4((1 + y)/2)).as_content_primitive() == (2, 4(y/2)) assert (3((1 + y)/2)).as_content_primitive() == \ (1, 3(Mul(S(1)/2, 1 + y, evaluate=False))) assert (5(S(3)/4)).as_content_primitive() == (1, 5(S(3)/4)) assert (5(S(7)/4)).as_content_primitive() == (5, 5(S(3)/4)) assert Add(5z/7, 0.5x, 3y/2, evaluate=False).as_content_primitive() == \ (S(1)/14, 7.0x + 21y + 10z) assert (2(S(3)/4) + 2(S(1)/4)sqrt(3)).as_content_primitive(radical=True) == \ (1, 2*(S(1)/4)(sqrt(2) + sqrt(3))) def test_signsimp(): e = x(-x + 1) + x(x - 1) assert signsimp(Eq(e, 0)) is S.true assert Abs(x - 1) == Abs(1 - x) assert signsimp(y - x) == y - x assert signsimp(y - x, evaluate=False) == Mul(-1, x - y, evaluate=False) def test_besselsimp(): from sympy import besselj, besseli, exp_polar, cosh, cosine_transform assert besselsimp(exp(-Ipiy/2)besseli(y, zexp_polar(Ipi/2))) == \ besselj(y, z) assert besselsimp(exp(-Ipia/2)besseli(a, 2sqrt(x)exp_polar(Ipi/2))) == \ besselj(a, 2sqrt(x)) assert besselsimp(sqrt(2)sqrt(pi)x*(S(1)/4)exp(Ipi/4)exp(-Ipia/2) * besseli(-S(1)/2, sqrt(x)exp_polar(Ipi/2)) * besseli(a, sqrt(x)exp_polar(Ipi/2))/2) == \ besselj(a, sqrt(x)) * cos(sqrt(x)) assert besselsimp(besseli(S(-1)/2, z)) == \ sqrt(2)cosh(z)/(sqrt(pi)sqrt(z)) assert besselsimp(besseli(a, zexp_polar(-Ipi/2))) == \ exp(-Ipia/2)besselj(a, z) assert cosine_transform(1/tsin(a/t), t, y) == \ sqrt(2)sqrt(pi)besselj(0, 2sqrt(a)sqrt(y))/2 def test_Piecewise(): e1 = x(x + y) - y(x + y) e2 = sin(x)2 + cos(x)2 e3 = expand((x + y)y/x) s1 = simplify(e1) s2 = simplify(e2) s3 = simplify(e3) assert simplify(Piecewise((e1, x < e2), (e3, True))) == \ Piecewise((s1, x < s2), (s3, True)) def test_polymorphism(): class A(Basic): def _eval_simplify(x, kwargs): return 1 a = A(5, 2) assert simplify(a) == 1 def test_issue_from_PR1599(): n1, n2, n3, n4 = symbols('n1 n2 n3 n4', negative=True) assert simplify(Isqrt(n1)) == -sqrt(-n1) def test_issue_6811(): eq = (x + 2y)(2x + 2) assert simplify(eq) == (x + 1)(x + 2y)2 # reject the 2-arg Mul -- these are a headache for test writing assert simplify(eq.expand()) == \ 2x2 + 4xy + 2x + 4y def test_issue_6920(): e = [cos(x) + Isin(x), cos(x) - Isin(x), cosh(x) - sinh(x), cosh(x) + sinh(x)] ok = [exp(Ix), exp(-Ix), exp(-x), exp(x)] # wrap in f to show that the change happens wherever ei occurs f = Function('f') assert [simplify(f(ei)).args[0] for ei in e] == ok def test_issue_7001(): from sympy.abc import r, R assert simplify(-(rPiecewise((4pi/3, r <= R), (-8piR3/(3r*3), True)) + 2Piecewise((4pir/3, r <= R), (4piR*3/(3r*2), True)))/(4pir)) == \ Piecewise((-1, r <= R), (0, True)) def test_inequality_no_auto_simplify(): # no simplify on creation but can be simplified lhs = cos(x)2 + sin(x)2 rhs = 2 e = Lt(lhs, rhs, evaluate=False) assert e is not S.true assert simplify(e) def test_issue_9398(): from sympy import Number, cancel assert cancel(1e-14) != 0 assert cancel(1e-14I) != 0 assert simplify(1e-14) != 0 assert simplify(1e-14I) != 0 assert (INumber(1.)Number(10)Number(-14)).simplify() != 0 assert cancel(1e-20) != 0 assert cancel(1e-20I) != 0 assert simplify(1e-20) != 0 assert simplify(1e-20I) != 0 assert cancel(1e-100) != 0 assert cancel(1e-100I) != 0 assert simplify(1e-100) != 0 assert simplify(1e-100I) != 0 f = Float("1e-1000") assert cancel(f) != 0 assert cancel(fI) != 0 assert simplify(f) != 0 assert simplify(fI) != 0 def test_issue_9324_simplify(): M = MatrixSymbol('M', 10, 10) e = M[0, 0] + M[5, 4] + 1304 assert simplify(e) == e def test_issue_13474(): x = Symbol('x') assert simplify(x + csch(sinc(1))) == x + csch(sinc(1)) def test_simplify_function_inverse(): # "inverse" attribute does not guarantee that f(g(x)) is x # so this simplification should not happen automatically. # See issue #12140 x, y = symbols('x, y') g = Function('g') class f(Function): def inverse(self, argindex=1): return g assert simplify(f(g(x))) == f(g(x)) assert inversecombine(f(g(x))) == x assert simplify(f(g(x)), inverse=True) == x assert simplify(f(g(sin(x)2 + cos(x)2)), inverse=True) == 1 assert simplify(f(g(x, y)), inverse=True) == f(g(x, y)) assert simplify(2asin(sin(3x)), inverse=True) == 6x assert simplify(log(exp(x))) == log(exp(x)) assert simplify(log(exp(x)), inverse=True) == x assert simplify(log(exp(x), 2), inverse=True) == x/log(2) assert simplify(log(exp(x), 2, evaluate=False), inverse=True) == x/log(2) def test_clear_coefficients(): from sympy.simplify.simplify import clear_coefficients assert clear_coefficients(4y(6x + 3)) == (y(2x + 1), 0) assert clear_coefficients(4y(6x + 3) - 2) == (y(2x + 1), S(1)/6) assert clear_coefficients(4y(6x + 3) - 2, x) == (y(2x + 1), x/12 + S(1)/6) assert clear_coefficients(sqrt(2) - 2) == (sqrt(2), 2) assert clear_coefficients(4sqrt(2) - 2) == (sqrt(2), S.Half) assert clear_coefficients(S(3), x) == (0, x - 3) assert clear_coefficients(S.Infinity, x) == (S.Infinity, x) assert clear_coefficients(-S.Pi, x) == (S.Pi, -x) assert clear_coefficients(2 - S.Pi/3, x) == (pi, -3x + 6) def test_nc_simplify(): from sympy.simplify.simplify import nc_simplify from sympy.matrices.expressions import (MatrixExpr, MatAdd, MatMul, MatPow, Identity) from sympy.core import Pow from functools import reduce a, b, c, d = symbols('a b c d', commutative = False) x = Symbol('x') A = MatrixSymbol("A", x, x) B = MatrixSymbol("B", x, x) C = MatrixSymbol("C", x, x) D = MatrixSymbol("D", x, x) subst = {a: A, b: B, c: C, d:D} funcs = {Add: lambda x,y: x+y, Mul: lambda x,y: xy } def _to_matrix(expr): if expr in subst: return subst[expr] if isinstance(expr, Pow): return MatPow(_to_matrix(expr.args[0]), expr.args[1]) elif isinstance(expr, (Add, Mul)): return reduce(funcs[expr.func],[_to_matrix(a) for a in expr.args]) else: return exprIdentity(x) def _check(expr, simplified, deep=True, matrix=True): assert nc_simplify(expr, deep=deep) == simplified assert expand(expr) == expand(simplified) if matrix: m_simp = _to_matrix(simplified).doit(inv_expand=False) assert nc_simplify(_to_matrix(expr), deep=deep) == m_simp _check(abababc(ab)3c, ((ab)3c)*2) _check(ab(ab)*-2ab, 1) _check(a2babab(ab)*-1, a(ab)2, matrix=False) _check(bab2ab2ab2, b(ab2)3) _check(aba2ba2ba3, (aba)3a2) _check(a2ba*4ba4ba2, (a2ba2)3) _check(a3ba4ba4ba, a3(ba4)3a*-3) _check(abab + abcxabc, (ab)2 + x(abc)*2) _check(ababcababc, ((ab)2c)2) _check(b-1a-1(ab)2, ab) _check(a*-1bc-1, (cb*-1a)-1) expr = a3ba*4ba4ba2ba2(ba2)2ba2ba2 for i in range(10): expr = ab _check(expr, a3(ba4)2(ba2)6(ab)10) _check((abab)*2, (abab)*2, deep=False) _check(ab(cd)*2, ab(cd)2) expr = b-1(a-1b-1 - a-1cb-1)-1a-1 assert nc_simplify(expr) == (1-c)-1 # commutative expressions should be returned without an error assert nc_simplify(2x*2) == 2x*2 def test_issue_15965(): A = Sum(zx*y, (x, 1, a)) anew = zSum(x*y, (x, 1, a)) B = Integral(xy, x) bnew = y*Integral(x, x) assert simplify(A + B) == anew + bnew assert simplify(A) == anew assert simplify(B) == bnew
b3ec13913f031deccef286a8bfb6aeb84e973e68e5a9d4429d6dca6858a23228	import math from sympy import ( Float, Idx, IndexedBase, Integer, Matrix, MatrixSymbol, Range, sin, symbols, Symbol, Tuple, Lt, nan, oo ) from sympy.core.relational import StrictLessThan from sympy.utilities.pytest import raises, XFAIL from sympy.codegen.ast import ( Assignment, Attribute, aug_assign, CodeBlock, For, Type, Variable, Pointer, Declaration, AddAugmentedAssignment, SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment, value_const, pointer_const, integer, real, complex_, int8, uint8, float16 as f16, float32 as f32, float64 as f64, float80 as f80, float128 as f128, complex64 as c64, complex128 as c128, While, Scope, String, Print, QuotedString, FunctionPrototype, FunctionDefinition, Return, FunctionCall, untyped, IntBaseType, intc, Node, none, NoneToken, Token, Comment ) x, y, z, t, x0, x1, x2, a, b = symbols("x, y, z, t, x0, x1, x2, a, b") n = symbols("n", integer=True) A = MatrixSymbol('A', 3, 1) mat = Matrix([1, 2, 3]) B = IndexedBase('B') i = Idx("i", n) A22 = MatrixSymbol('A22',2,2) B22 = MatrixSymbol('B22',2,2) def test_Assignment(): # Here we just do things to show they don't error Assignment(x, y) Assignment(x, 0) Assignment(A, mat) Assignment(A[1,0], 0) Assignment(A[1,0], x) Assignment(B[i], x) Assignment(B[i], 0) a = Assignment(x, y) assert a.func(a.args) == a assert a.op == ':=' # Here we test things to show that they error # Matrix to scalar raises(ValueError, lambda: Assignment(B[i], A)) raises(ValueError, lambda: Assignment(B[i], mat)) raises(ValueError, lambda: Assignment(x, mat)) raises(ValueError, lambda: Assignment(x, A)) raises(ValueError, lambda: Assignment(A[1,0], mat)) # Scalar to matrix raises(ValueError, lambda: Assignment(A, x)) raises(ValueError, lambda: Assignment(A, 0)) # Non-atomic lhs raises(TypeError, lambda: Assignment(mat, A)) raises(TypeError, lambda: Assignment(0, x)) raises(TypeError, lambda: Assignment(xx, 1)) raises(TypeError, lambda: Assignment(A + A, mat)) raises(TypeError, lambda: Assignment(B, 0)) def test_AugAssign(): # Here we just do things to show they don't error aug_assign(x, '+', y) aug_assign(x, '+', 0) aug_assign(A, '+', mat) aug_assign(A[1, 0], '+', 0) aug_assign(A[1, 0], '+', x) aug_assign(B[i], '+', x) aug_assign(B[i], '+', 0) # Check creation via aug_assign vs constructor for binop, cls in [ ('+', AddAugmentedAssignment), ('-', SubAugmentedAssignment), ('', MulAugmentedAssignment), ('/', DivAugmentedAssignment), ('%', ModAugmentedAssignment), ]: a = aug_assign(x, binop, y) b = cls(x, y) assert a.func(a.args) == a == b assert a.binop == binop assert a.op == binop + '=' # Here we test things to show that they error # Matrix to scalar raises(ValueError, lambda: aug_assign(B[i], '+', A)) raises(ValueError, lambda: aug_assign(B[i], '+', mat)) raises(ValueError, lambda: aug_assign(x, '+', mat)) raises(ValueError, lambda: aug_assign(x, '+', A)) raises(ValueError, lambda: aug_assign(A[1, 0], '+', mat)) # Scalar to matrix raises(ValueError, lambda: aug_assign(A, '+', x)) raises(ValueError, lambda: aug_assign(A, '+', 0)) # Non-atomic lhs raises(TypeError, lambda: aug_assign(mat, '+', A)) raises(TypeError, lambda: aug_assign(0, '+', x)) raises(TypeError, lambda: aug_assign(x * x, '+', 1)) raises(TypeError, lambda: aug_assign(A + A, '+', mat)) raises(TypeError, lambda: aug_assign(B, '+', 0)) def test_Assignment_printing(): assignment_classes = [ Assignment, AddAugmentedAssignment, SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment, ] pairs = [ (x, 2 * y + 2), (B[i], x), (A22, B22), (A[0, 0], x), ] for cls in assignment_classes: for lhs, rhs in pairs: a = cls(lhs, rhs) assert repr(a) == '%s(%s, %s)' % (cls.__name__, repr(lhs), repr(rhs)) def test_CodeBlock(): c = CodeBlock(Assignment(x, 1), Assignment(y, x + 1)) assert c.func(c.args) == c assert c.left_hand_sides == Tuple(x, y) assert c.right_hand_sides == Tuple(1, x + 1) def test_CodeBlock_topological_sort(): assignments = [ Assignment(x, y + z), Assignment(z, 1), Assignment(t, x), Assignment(y, 2), ] ordered_assignments = [ # Note that the unrelated z=1 and y=2 are kept in that order Assignment(z, 1), Assignment(y, 2), Assignment(x, y + z), Assignment(t, x), ] c1 = CodeBlock.topological_sort(assignments) assert c1 == CodeBlock(ordered_assignments) # Cycle invalid_assignments = [ Assignment(x, y + z), Assignment(z, 1), Assignment(y, x), Assignment(y, 2), ] raises(ValueError, lambda: CodeBlock.topological_sort(invalid_assignments)) # Free symbols free_assignments = [ Assignment(x, y + z), Assignment(z, a * b), Assignment(t, x), Assignment(y, b + 3), ] free_assignments_ordered = [ Assignment(z, a * b), Assignment(y, b + 3), Assignment(x, y + z), Assignment(t, x), ] c2 = CodeBlock.topological_sort(free_assignments) assert c2 == CodeBlock(free_assignments_ordered) def test_CodeBlock_free_symbols(): c1 = CodeBlock( Assignment(x, y + z), Assignment(z, 1), Assignment(t, x), Assignment(y, 2), ) assert c1.free_symbols == set() c2 = CodeBlock( Assignment(x, y + z), Assignment(z, a b), Assignment(t, x), Assignment(y, b + 3), ) assert c2.free_symbols == {a, b} def test_CodeBlock_cse(): c1 = CodeBlock( Assignment(y, 1), Assignment(x, sin(y)), Assignment(z, sin(y)), Assignment(t, xz), ) assert c1.cse() == CodeBlock( Assignment(y, 1), Assignment(x0, sin(y)), Assignment(x, x0), Assignment(z, x0), Assignment(t, xz), ) # Multiple assignments to same symbol not supported raises(NotImplementedError, lambda: CodeBlock( Assignment(x, 1), Assignment(y, 1), Assignment(y, 2) ).cse()) # Check auto-generated symbols do not collide with existing ones c2 = CodeBlock( Assignment(x0, sin(y) + 1), Assignment(x1, 2 * sin(y)), Assignment(z, x * y), ) assert c2.cse() == CodeBlock( Assignment(x2, sin(y)), Assignment(x0, x2 + 1), Assignment(x1, 2 * x2), Assignment(z, x * y), ) def test_CodeBlock_cse__issue_14118(): # see https://github.com/sympy/sympy/issues/14118 c = CodeBlock( Assignment(A22, Matrix([[x, sin(y)],[3, 4]])), Assignment(B22, Matrix([[sin(y), 2sin(y)], [sin(y)2, 7]])) ) assert c.cse() == CodeBlock( Assignment(x0, sin(y)), Assignment(A22, Matrix([[x, x0],[3, 4]])), Assignment(B22, Matrix([[x0, 2x0], [x0*2, 7]])) ) def test_For(): f = For(n, Range(0, 3), (Assignment(A[n, 0], x + n), aug_assign(x, '+', y))) f = For(n, (1, 2, 3, 4, 5), (Assignment(A[n, 0], x + n),)) assert f.func(f.args) == f raises(TypeError, lambda: For(n, x, (x + y,))) def test_none(): assert none.is_Atom assert none == none class Foo(Token): pass foo = Foo() assert foo != none assert none == None assert none == NoneToken() assert none.func(none.args) == none def test_String(): st = String('foobar') assert st.is_Atom assert st == String('foobar') assert st.text == 'foobar' assert st.func(st.kwargs()) == st class Signifier(String): pass si = Signifier('foobar') assert si != st assert si.text == st.text s = String('foo') assert str(s) == 'foo' assert repr(s) == "String('foo')" def test_Comment(): c = Comment('foobar') assert c.text == 'foobar' assert str(c) == 'foobar' def test_Node(): n = Node() assert n == Node() assert n.func(n.args) == n def test_Type(): t = Type('MyType') assert len(t.args) == 1 assert t.name == String('MyType') assert str(t) == 'MyType' assert repr(t) == "Type(String('MyType'))" assert Type(t) == t assert t.func(t.args) == t t1 = Type('t1') t2 = Type('t2') assert t1 != t2 assert t1 == t1 and t2 == t2 t1b = Type('t1') assert t1 == t1b assert t2 != t1b def test_Type__from_expr(): assert Type.from_expr(i) == integer u = symbols('u', real=True) assert Type.from_expr(u) == real assert Type.from_expr(n) == integer assert Type.from_expr(3) == integer assert Type.from_expr(3.0) == real assert Type.from_expr(3+1j) == complex_ raises(ValueError, lambda: Type.from_expr(sum)) def test_Type__cast_check__integers(): # Rounding raises(ValueError, lambda: integer.cast_check(3.5)) assert integer.cast_check('3') == 3 assert integer.cast_check(Float('3.0000000000000000000')) == 3 assert integer.cast_check(Float('3.0000000000000000001')) == 3 # unintuitive maybe? # Range assert int8.cast_check(127.0) == 127 raises(ValueError, lambda: int8.cast_check(128)) assert int8.cast_check(-128) == -128 raises(ValueError, lambda: int8.cast_check(-129)) assert uint8.cast_check(0) == 0 assert uint8.cast_check(128) == 128 raises(ValueError, lambda: uint8.cast_check(256.0)) raises(ValueError, lambda: uint8.cast_check(-1)) def test_Attribute(): noexcept = Attribute('noexcept') assert noexcept == Attribute('noexcept') alignas16 = Attribute('alignas', [16]) alignas32 = Attribute('alignas', [32]) assert alignas16 != alignas32 assert alignas16.func(alignas16.args) == alignas16 def test_Variable(): v = Variable(x, type=real) assert v == Variable(v) assert v == Variable('x', type=real) assert v.symbol == x assert v.type == real assert value_const not in v.attrs assert v.func(v.args) == v assert str(v) == 'Variable(x, type=real)' w = Variable(y, f32, attrs={value_const}) assert w.symbol == y assert w.type == f32 assert value_const in w.attrs assert w.func(w.args) == w v_n = Variable(n, type=Type.from_expr(n)) assert v_n.type == integer assert v_n.func(v_n.args) == v_n v_i = Variable(i, type=Type.from_expr(n)) assert v_i.type == integer assert v_i != v_n a_i = Variable.deduced(i) assert a_i.type == integer assert Variable.deduced(Symbol('x', real=True)).type == real assert a_i.func(a_i.args) == a_i v_n2 = Variable.deduced(n, value=3.5, cast_check=False) assert v_n2.func(v_n2.args) == v_n2 assert abs(v_n2.value - 3.5) < 1e-15 raises(ValueError, lambda: Variable.deduced(n, value=3.5, cast_check=True)) v_n3 = Variable.deduced(n) assert v_n3.type == integer assert str(v_n3) == 'Variable(n, type=integer)' assert Variable.deduced(z, value=3).type == integer assert Variable.deduced(z, value=3.0).type == real assert Variable.deduced(z, value=3.0+1j).type == complex_ def test_Pointer(): p = Pointer(x) assert p.symbol == x assert p.type == untyped assert value_const not in p.attrs assert pointer_const not in p.attrs assert p.func(p.args) == p u = symbols('u', real=True) pu = Pointer(u, type=Type.from_expr(u), attrs={value_const, pointer_const}) assert pu.symbol is u assert pu.type == real assert value_const in pu.attrs assert pointer_const in pu.attrs assert pu.func(pu.args) == pu i = symbols('i', integer=True) deref = pu[i] assert deref.indices == (i,) def test_Declaration(): u = symbols('u', real=True) vu = Variable(u, type=Type.from_expr(u)) assert Declaration(vu).variable.type == real vn = Variable(n, type=Type.from_expr(n)) assert Declaration(vn).variable.type == integer lt = StrictLessThan(vu, vn) assert isinstance(lt, StrictLessThan) vuc = Variable(u, Type.from_expr(u), value=3.0, attrs={value_const}) assert value_const in vuc.attrs assert pointer_const not in vuc.attrs decl = Declaration(vuc) assert decl.variable == vuc assert isinstance(decl.variable.value, Float) assert decl.variable.value == 3.0 assert decl.func(decl.args) == decl assert vuc.as_Declaration() == decl assert vuc.as_Declaration(value=None, attrs=None) == Declaration(vu) vy = Variable(y, type=integer, value=3) decl2 = Declaration(vy) assert decl2.variable == vy assert decl2.variable.value == Integer(3) vi = Variable(i, type=Type.from_expr(i), value=3.0) decl3 = Declaration(vi) assert decl3.variable.type == integer assert decl3.variable.value == 3.0 raises(ValueError, lambda: Declaration(vi, 42)) def test_IntBaseType(): assert intc.name == String('intc') assert intc.args == (intc.name,) assert str(IntBaseType('a').name) == 'a' def test_FloatType(): assert f16.dig == 3 assert f32.dig == 6 assert f64.dig == 15 assert f80.dig == 18 assert f128.dig == 33 assert f16.decimal_dig == 5 assert f32.decimal_dig == 9 assert f64.decimal_dig == 17 assert f80.decimal_dig == 21 assert f128.decimal_dig == 36 assert f16.max_exponent == 16 assert f32.max_exponent == 128 assert f64.max_exponent == 1024 assert f80.max_exponent == 16384 assert f128.max_exponent == 16384 assert f16.min_exponent == -13 assert f32.min_exponent == -125 assert f64.min_exponent == -1021 assert f80.min_exponent == -16381 assert f128.min_exponent == -16381 assert abs(f16.eps / Float('0.00097656', precision=16) - 1) < 0.110-f16.dig assert abs(f32.eps / Float('1.1920929e-07', precision=32) - 1) < 0.110*-f32.dig assert abs(f64.eps / Float('2.2204460492503131e-16', precision=64) - 1) < 0.110*-f64.dig assert abs(f80.eps / Float('1.08420217248550443401e-19', precision=80) - 1) < 0.110*-f80.dig assert abs(f128.eps / Float(' 1.92592994438723585305597794258492732e-34', precision=128) - 1) < 0.110*-f128.dig assert abs(f16.max / Float('65504', precision=16) - 1) < .110*-f16.dig assert abs(f32.max / Float('3.40282347e+38', precision=32) - 1) < 0.110*-f32.dig assert abs(f64.max / Float('1.79769313486231571e+308', precision=64) - 1) < 0.110*-f64.dig # cf. np.finfo(np.float64).max assert abs(f80.max / Float('1.18973149535723176502e+4932', precision=80) - 1) < 0.110*-f80.dig assert abs(f128.max / Float('1.18973149535723176508575932662800702e+4932', precision=128) - 1) < 0.110*-f128.dig # cf. np.finfo(np.float32).tiny assert abs(f16.tiny / Float('6.1035e-05', precision=16) - 1) < 0.110*-f16.dig assert abs(f32.tiny / Float('1.17549435e-38', precision=32) - 1) < 0.110*-f32.dig assert abs(f64.tiny / Float('2.22507385850720138e-308', precision=64) - 1) < 0.110*-f64.dig assert abs(f80.tiny / Float('3.36210314311209350626e-4932', precision=80) - 1) < 0.110*-f80.dig assert abs(f128.tiny / Float('3.3621031431120935062626778173217526e-4932', precision=128) - 1) < 0.110*-f128.dig assert f64.cast_check(0.5) == 0.5 assert abs(f64.cast_check(3.7) - 3.7) < 3e-17 assert isinstance(f64.cast_check(3), (Float, float)) assert f64.cast_nocheck(oo) == float('inf') assert f64.cast_nocheck(-oo) == float('-inf') assert f64.cast_nocheck(float(oo)) == float('inf') assert f64.cast_nocheck(float(-oo)) == float('-inf') assert math.isnan(f64.cast_nocheck(nan)) assert f32 != f64 assert f64 == f64.func(f64.args) def test_Type__cast_check__floating_point(): raises(ValueError, lambda: f32.cast_check(123.45678949)) raises(ValueError, lambda: f32.cast_check(12.345678949)) raises(ValueError, lambda: f32.cast_check(1.2345678949)) raises(ValueError, lambda: f32.cast_check(.12345678949)) assert abs(123.456789049 - f32.cast_check(123.456789049) - 4.9e-8) < 1e-8 assert abs(0.12345678904 - f32.cast_check(0.12345678904) - 4e-11) < 1e-11 dcm21 = Float('0.123456789012345670499') # 21 decimals assert abs(dcm21 - f64.cast_check(dcm21) - 4.99e-19) < 1e-19 f80.cast_check(Float('0.12345678901234567890103', precision=88)) raises(ValueError, lambda: f80.cast_check(Float('0.12345678901234567890149', precision=88))) v10 = 12345.67894 raises(ValueError, lambda: f32.cast_check(v10)) assert abs(Float(str(v10), precision=64+8) - f64.cast_check(v10)) < v101e-16 assert abs(f32.cast_check(2147483647) - 2147483650) < 1 def test_Type__cast_check__complex_floating_point(): val9_11 = 123.456789049 + 0.123456789049j raises(ValueError, lambda: c64.cast_check(.12345678949 + .12345678949j)) assert abs(val9_11 - c64.cast_check(val9_11) - 4.9e-8) < 1e-8 dcm21 = Float('0.123456789012345670499') + 1e-20j # 21 decimals assert abs(dcm21 - c128.cast_check(dcm21) - 4.99e-19) < 1e-19 v19 = Float('0.1234567890123456749') + 1jFloat('0.1234567890123456749') raises(ValueError, lambda: c128.cast_check(v19)) def test_While(): xpp = AddAugmentedAssignment(x, 1) whl1 = While(x < 2, [xpp]) assert whl1.condition.args[0] == x assert whl1.condition.args[1] == 2 assert whl1.condition == Lt(x, 2, evaluate=False) assert whl1.body.args == (xpp,) assert whl1.func(whl1.args) == whl1 cblk = CodeBlock(AddAugmentedAssignment(x, 1)) whl2 = While(x < 2, cblk) assert whl1 == whl2 assert whl1 != While(x < 3, [xpp]) def test_Scope(): assign = Assignment(x, y) incr = AddAugmentedAssignment(x, 1) scp = Scope([assign, incr]) cblk = CodeBlock(assign, incr) assert scp.body == cblk assert scp == Scope(cblk) assert scp != Scope([incr, assign]) assert scp.func(scp.args) == scp def test_Print(): fmt = "%d %.3f" ps = Print([n, x], fmt) assert str(ps.format_string) == fmt assert ps.print_args == Tuple(n, x) assert ps.args == (Tuple(n, x), QuotedString(fmt), none) assert ps == Print((n, x), fmt) assert ps != Print([x, n], fmt) assert ps.func(ps.args) == ps ps2 = Print([n, x]) assert ps2 == Print([n, x]) assert ps2 != ps assert ps2.format_string == None def test_FunctionPrototype_and_FunctionDefinition(): vx = Variable(x, type=real) vn = Variable(n, type=integer) fp1 = FunctionPrototype(real, 'power', [vx, vn]) assert fp1.return_type == real assert fp1.name == String('power') assert fp1.parameters == Tuple(vx, vn) assert fp1 == FunctionPrototype(real, 'power', [vx, vn]) assert fp1 != FunctionPrototype(real, 'power', [vn, vx]) assert fp1.func(fp1.args) == fp1 body = [Assignment(x, x*n), Return(x)] fd1 = FunctionDefinition(real, 'power', [vx, vn], body) assert fd1.return_type == real assert str(fd1.name) == 'power' assert fd1.parameters == Tuple(vx, vn) assert fd1.body == CodeBlock(body) assert fd1 == FunctionDefinition(real, 'power', [vx, vn], body) assert fd1 != FunctionDefinition(real, 'power', [vx, vn], body[::-1]) assert fd1.func(fd1.args) == fd1 fp2 = FunctionPrototype.from_FunctionDefinition(fd1) assert fp2 == fp1 fd2 = FunctionDefinition.from_FunctionPrototype(fp1, body) assert fd2 == fd1 def test_Return(): rs = Return(x) assert rs.args == (x,) assert rs == Return(x) assert rs != Return(y) assert rs.func(rs.args) == rs def test_FunctionCall(): fc = FunctionCall('power', (x, 3)) assert fc.function_args[0] == x assert fc.function_args[1] == 3 assert isinstance(fc.function_args[1], Integer) assert fc == FunctionCall('power', (x, 3)) assert fc != FunctionCall('power', (3, x)) assert fc != FunctionCall('Power', (x, 3)) assert fc.func(*fc.args) == fc def test_ast_replace(): x = Variable('x', real) y = Variable('y', real) n = Variable('n', integer) pwer = FunctionDefinition(real, 'pwer', [x, n], [pow(x.symbol, n.symbol)]) pname = pwer.name pcall = FunctionCall('pwer', [y, 3]) tree1 = CodeBlock(pwer, pcall) assert str(tree1.args[0].name) == 'pwer' assert str(tree1.args[1].name) == 'pwer' for a, b in zip(tree1, [pwer, pcall]): assert a == b tree2 = tree1.replace(pname, String('power')) assert str(tree1.args[0].name) == 'pwer' assert str(tree1.args[1].name) == 'pwer' assert str(tree2.args[0].name) == 'power' assert str(tree2.args[1].name) == 'power'
95e45597dd5f69e2d5a6d9c9d1e70fe2fe00c2158cbb78364ec8e8ef0ebe33d2	from __future__ import (absolute_import, print_function) from sympy import log, exp, Symbol, Pow, sin from sympy.printing.ccode import ccode from sympy.codegen.cfunctions import log2, exp2, expm1, log1p from sympy.codegen.rewriting import ( optimize, log2_opt, exp2_opt, expm1_opt, log1p_opt, optims_c99, create_expand_pow_optimization ) from sympy.utilities.pytest import XFAIL def test_log2_opt(): x = Symbol('x') expr1 = 7log(3x + 5)/(log(2)) opt1 = optimize(expr1, [log2_opt]) assert opt1 == 7log2(3x + 5) assert opt1.rewrite(log) == expr1 expr2 = 3log(5x + 7)/(13log(2)) opt2 = optimize(expr2, [log2_opt]) assert opt2 == 3log2(5x + 7)/13 assert opt2.rewrite(log) == expr2 expr3 = log(x)/log(2) opt3 = optimize(expr3, [log2_opt]) assert opt3 == log2(x) assert opt3.rewrite(log) == expr3 expr4 = log(x)/log(2) + log(x+1) opt4 = optimize(expr4, [log2_opt]) assert opt4 == log2(x) + log(2)log2(x+1) assert opt4.rewrite(log) == expr4 expr5 = log(17) opt5 = optimize(expr5, [log2_opt]) assert opt5 == expr5 expr6 = log(x + 3)/log(2) opt6 = optimize(expr6, [log2_opt]) assert str(opt6) == 'log2(x + 3)' assert opt6.rewrite(log) == expr6 def test_exp2_opt(): x = Symbol('x') expr1 = 1 + 2x opt1 = optimize(expr1, [exp2_opt]) assert opt1 == 1 + exp2(x) assert opt1.rewrite(Pow) == expr1 expr2 = 1 + 3x assert expr2 == optimize(expr2, [exp2_opt]) def test_expm1_opt(): x = Symbol('x') expr1 = exp(x) - 1 opt1 = optimize(expr1, [expm1_opt]) assert expm1(x) - opt1 == 0 assert opt1.rewrite(exp) == expr1 expr2 = 3exp(x) - 3 opt2 = optimize(expr2, [expm1_opt]) assert 3expm1(x) == opt2 assert opt2.rewrite(exp) == expr2 expr3 = 3exp(x) - 5 assert expr3 == optimize(expr3, [expm1_opt]) expr4 = 3exp(x) + log(x) - 3 opt4 = optimize(expr4, [expm1_opt]) assert 3expm1(x) + log(x) == opt4 assert opt4.rewrite(exp) == expr4 expr5 = 3exp(2x) - 3 opt5 = optimize(expr5, [expm1_opt]) assert 3expm1(2x) == opt5 assert opt5.rewrite(exp) == expr5 @XFAIL def test_expm1_two_exp_terms(): x, y = map(Symbol, 'x y'.split()) expr1 = exp(x) + exp(y) - 2 opt1 = optimize(expr1, [expm1_opt]) assert opt1 == expm1(x) + expm1(y) def test_log1p_opt(): x = Symbol('x') expr1 = log(x + 1) opt1 = optimize(expr1, [log1p_opt]) assert log1p(x) - opt1 == 0 assert opt1.rewrite(log) == expr1 expr2 = log(3x + 3) opt2 = optimize(expr2, [log1p_opt]) assert log1p(x) + log(3) == opt2 assert (opt2.rewrite(log) - expr2).simplify() == 0 expr3 = log(2x + 1) opt3 = optimize(expr3, [log1p_opt]) assert log1p(2x) - opt3 == 0 assert opt3.rewrite(log) == expr3 expr4 = log(x+3) opt4 = optimize(expr4, [log1p_opt]) assert str(opt4) == 'log(x + 3)' def test_optims_c99(): x = Symbol('x') expr1 = 2*x + log(x)/log(2) + log(x + 1) + exp(x) - 1 opt1 = optimize(expr1, optims_c99).simplify() assert opt1 == exp2(x) + log2(x) + log1p(x) + expm1(x) assert opt1.rewrite(exp).rewrite(log).rewrite(Pow) == expr1 expr2 = log(x)/log(2) + log(x + 1) opt2 = optimize(expr2, optims_c99) assert opt2 == log2(x) + log1p(x) assert opt2.rewrite(log) == expr2 expr3 = log(x)/log(2) + log(17x + 17) opt3 = optimize(expr3, optims_c99) delta3 = opt3 - (log2(x) + log(17) + log1p(x)) assert delta3 == 0 assert (opt3.rewrite(log) - expr3).simplify() == 0 expr4 = 2*x + 3log(5x + 7)/(13log(2)) + 11exp(x) - 11 + log(17x + 17) opt4 = optimize(expr4, optims_c99).simplify() delta4 = opt4 - (exp2(x) + 3log2(5x + 7)/13 + 11expm1(x) + log(17) + log1p(x)) assert delta4 == 0 assert (opt4.rewrite(exp).rewrite(log).rewrite(Pow) - expr4).simplify() == 0 expr5 = 3exp(2x) - 3 opt5 = optimize(expr5, optims_c99) delta5 = opt5 - 3expm1(2x) assert delta5 == 0 assert opt5.rewrite(exp) == expr5 expr6 = exp(2x) - 3 opt6 = optimize(expr6, optims_c99) delta6 = opt6 - (exp(2x) - 3) assert delta6 == 0 expr7 = log(3x + 3) opt7 = optimize(expr7, optims_c99) delta7 = opt7 - (log(3) + log1p(x)) assert delta7 == 0 assert (opt7.rewrite(log) - expr7).simplify() == 0 expr8 = log(2x + 3) opt8 = optimize(expr8, optims_c99) assert opt8 == expr8 def test_create_expand_pow_optimization(): cc = lambda x: ccode( optimize(x, [create_expand_pow_optimization(4)])) x = Symbol('x') assert cc(x4) == 'xxxx' assert cc(x4 + x2) == 'xx + xxxx' assert cc(x5 + x4) == 'pow(x, 5) + xxxx' assert cc(sin(x)4) == 'pow(sin(x), 4)' # gh issue 15335 assert cc(x(-4)) == '1.0/(xxxx)' assert cc(x(-5)) == 'pow(x, -5)' assert cc(-x4) == '-xxxx' assert cc(x4 - x2) == '-xx + xxxx' i = Symbol('i', integer=True) assert cc(xi - x2) == 'pow(x, i) - xx'
22ef1ea32dafbf71fcba5417cba310ae6ce6bad9d408c25e6c088e5278c58f5c	from sympy import symbols, IndexedBase, HadamardProduct, Identity, cos from sympy.codegen.array_utils import (CodegenArrayContraction, CodegenArrayTensorProduct, CodegenArrayDiagonal, CodegenArrayPermuteDims, CodegenArrayElementwiseAdd, _codegen_array_parse, _recognize_matrix_expression, _RecognizeMatOp, _RecognizeMatMulLines, _unfold_recognized_expr, parse_indexed_expression, recognize_matrix_expression, _parse_matrix_expression) from sympy import (MatrixSymbol, Sum) from sympy.combinatorics import Permutation from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.matrices.expressions.diagonal import DiagonalizeVector from sympy.matrices.expressions.matexpr import MatrixElement from sympy.matrices import (Trace, MatAdd, MatMul, Transpose) from sympy.utilities.pytest import raises, XFAIL A, B = symbols("A B", cls=IndexedBase) i, j, k, l, m, n = symbols("i j k l m n") M = MatrixSymbol("M", k, k) N = MatrixSymbol("N", k, k) P = MatrixSymbol("P", k, k) Q = MatrixSymbol("Q", k, k) def test_codegen_array_contraction_construction(): cg = CodegenArrayContraction(A) assert cg == A s = Sum(A[i]B[i], (i, 0, 3)) cg = parse_indexed_expression(s) assert cg == CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (0, 1)) cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (1, 0)) assert cg == CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (0, 1)) expr = MN result = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) assert CodegenArrayContraction.from_MatMul(expr) == result elem = expr[i, j] assert parse_indexed_expression(elem) == result expr = MNM result = CodegenArrayContraction(CodegenArrayTensorProduct(M, N, M), (1, 2), (3, 4)) assert CodegenArrayContraction.from_MatMul(expr) == result elem = expr[i, j] result = CodegenArrayContraction(CodegenArrayTensorProduct(M, M, N), (1, 4), (2, 5)) cg = parse_indexed_expression(elem) cg = cg.sort_args_by_name() assert cg == result def test_codegen_array_contraction_indices_types(): cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 1)) indtup = cg._get_contraction_tuples() assert indtup == [[(0, 0), (0, 1)]] assert cg._contraction_tuples_to_contraction_indices(cg.expr, indtup) == [(0, 1)] cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) indtup = cg._get_contraction_tuples() assert indtup == [[(0, 1), (1, 0)]] assert cg._contraction_tuples_to_contraction_indices(cg.expr, indtup) == [(1, 2)] cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, M, N), (1, 4), (2, 5)) indtup = cg._get_contraction_tuples() assert indtup == [[(0, 1), (2, 0)], [(1, 0), (2, 1)]] assert cg._contraction_tuples_to_contraction_indices(cg.expr, indtup) == [(1, 4), (2, 5)] def test_codegen_array_recognize_matrix_mul_lines(): cg = CodegenArrayContraction(CodegenArrayTensorProduct(M), (0, 1)) assert recognize_matrix_expression(cg) == Trace(M) cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 1), (2, 3)) assert recognize_matrix_expression(cg) == Trace(M)Trace(N) cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 3), (1, 2)) assert recognize_matrix_expression(cg) == Trace(MN) cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 2), (1, 3)) assert recognize_matrix_expression(cg) == Trace(MN.T) cg = parse_indexed_expression((MNP)[i,j]) assert recognize_matrix_expression(cg) == MNP cg = CodegenArrayContraction.from_MatMul(MNP) assert recognize_matrix_expression(cg) == MNP cg = parse_indexed_expression((MN.TP)[i,j]) assert recognize_matrix_expression(cg) == MN.TP cg = CodegenArrayContraction.from_MatMul(MN.TP) assert recognize_matrix_expression(cg) == MN.TP cg = CodegenArrayContraction(CodegenArrayTensorProduct(M,N,P,Q), (1, 2), (5, 6)) assert recognize_matrix_expression(cg) == [MN, PQ] expr = -2MN elem = expr[i, j] cg = parse_indexed_expression(elem) assert recognize_matrix_expression(cg) == -2MN def test_codegen_array_flatten(): # Flatten nested CodegenArrayTensorProduct objects: expr1 = CodegenArrayTensorProduct(M, N) expr2 = CodegenArrayTensorProduct(P, Q) expr = CodegenArrayTensorProduct(expr1, expr2) assert expr == CodegenArrayTensorProduct(M, N, P, Q) assert expr.args == (M, N, P, Q) # Flatten mixed CodegenArrayTensorProduct and CodegenArrayContraction objects: cg1 = CodegenArrayContraction(expr1, (1, 2)) cg2 = CodegenArrayContraction(expr2, (0, 3)) expr = CodegenArrayTensorProduct(cg1, cg2) assert expr == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (1, 2), (4, 7)) expr = CodegenArrayTensorProduct(M, cg1) assert expr == CodegenArrayContraction(CodegenArrayTensorProduct(M, M, N), (3, 4)) # Flatten nested CodegenArrayContraction objects: cgnested = CodegenArrayContraction(cg1, (0, 1)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 3), (1, 2)) cgnested = CodegenArrayContraction(CodegenArrayTensorProduct(cg1, cg2), (0, 3)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 6), (1, 2), (4, 7)) cg3 = CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (1, 3), (2, 4)) cgnested = CodegenArrayContraction(cg3, (0, 1)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 5), (1, 3), (2, 4)) cgnested = CodegenArrayContraction(cg3, (0, 3), (1, 2)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 7), (1, 3), (2, 4), (5, 6)) cg4 = CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (1, 5), (3, 7)) cgnested = CodegenArrayContraction(cg4, (0, 1)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 2), (1, 5), (3, 7)) cgnested = CodegenArrayContraction(cg4, (0, 1), (2, 3)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 2), (1, 5), (3, 7), (4, 6)) cg = CodegenArrayDiagonal(cg4) assert cg == cg4 assert isinstance(cg, type(cg4)) # Flatten nested CodegenArrayDiagonal objects: cg1 = CodegenArrayDiagonal(expr1, (1, 2)) cg2 = CodegenArrayDiagonal(expr2, (0, 3)) cg3 = CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 3), (2, 4)) cg4 = CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 5), (3, 7)) cgnested = CodegenArrayDiagonal(cg1, (0, 1)) assert cgnested == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N), (1, 2), (0, 3)) cgnested = CodegenArrayDiagonal(cg3, (1, 2)) assert cgnested == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 3), (2, 4), (5, 6)) cgnested = CodegenArrayDiagonal(cg4, (1, 2)) assert cgnested == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 5), (3, 7), (2, 4)) def test_codegen_array_parse(): expr = M[i, j] assert _codegen_array_parse(expr) == (M, (i, j)) expr = M[i, j]N[k, l] assert _codegen_array_parse(expr) == (CodegenArrayTensorProduct(M, N), (i, j, k, l)) expr = M[i, j]N[j, k] assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N), (1, 2)), (i, k, j)) expr = Sum(M[i, j]N[j, k], (j, 0, k-1)) assert _codegen_array_parse(expr) == (CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)), (i, k)) expr = M[i, j] + N[i, j] assert _codegen_array_parse(expr) == (CodegenArrayElementwiseAdd(M, N), (i, j)) expr = M[i, j] + N[j, i] assert _codegen_array_parse(expr) == (CodegenArrayElementwiseAdd(M, CodegenArrayPermuteDims(N, Permutation([1,0]))), (i, j)) expr = M[i, j] + M[j, i] assert _codegen_array_parse(expr) == (CodegenArrayElementwiseAdd(M, CodegenArrayPermuteDims(M, Permutation([1,0]))), (i, j)) expr = (MNP)[i, j] assert _codegen_array_parse(expr) == (CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P), (1, 2), (3, 4)), (i, j)) expr = expr.function # Disregard summation in previous expression ret1, ret2 = _codegen_array_parse(expr) assert ret1 == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P), (1, 2), (3, 4)) assert str(ret2) == "(i, j, _i_1, _i_2)" expr = KroneckerDelta(i, j)M[i, k] assert _codegen_array_parse(expr) == (M, ({i, j}, k)) expr = KroneckerDelta(i, j)KroneckerDelta(j, k)M[i, l] assert _codegen_array_parse(expr) == (M, ({i, j, k}, l)) expr = KroneckerDelta(j, k)(M[i, j]N[k, l] + N[i, j]M[k, l]) assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(CodegenArrayElementwiseAdd( CodegenArrayTensorProduct(M, N), CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), Permutation(0, 2)(1, 3)) ), (1, 2)), (i, l, frozenset({j, k}))) expr = KroneckerDelta(j, m)KroneckerDelta(m, k)(M[i, j]N[k, l] + N[i, j]M[k, l]) assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(CodegenArrayElementwiseAdd( CodegenArrayTensorProduct(M, N), CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), Permutation(0, 2)(1, 3)) ), (1, 2)), (i, l, frozenset({j, m, k}))) expr = KroneckerDelta(i, j)KroneckerDelta(j, k)KroneckerDelta(k,m)M[i, 0]KroneckerDelta(m, n) assert _codegen_array_parse(expr) == (M, ({i,j,k,m,n}, 0)) expr = M[i, i] assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(M, (0, 1)), (i,)) def test_codegen_array_diagonal(): cg = CodegenArrayDiagonal(M, (1, 0)) assert cg == CodegenArrayDiagonal(M, (0, 1)) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P), (4, 1), (2, 0)) assert cg == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P), (1, 4), (0, 2)) def test_codegen_recognize_matrix_expression(): expr = CodegenArrayElementwiseAdd(M, CodegenArrayPermuteDims(M, [1, 0])) rec = _recognize_matrix_expression(expr) assert rec == _RecognizeMatOp(MatAdd, [M, _RecognizeMatOp(Transpose, [M])]) assert _unfold_recognized_expr(rec) == M + Transpose(M) expr = M[i,j] + N[i,j] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [M, N]) assert _unfold_recognized_expr(rec) == M + N expr = M[i,j] + N[j,i] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [M, _RecognizeMatOp(Transpose, [N])]) assert _unfold_recognized_expr(rec) == M + N.T expr = M[i,j]N[k,l] + N[i,j]M[k,l] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [_RecognizeMatMulLines([M, N]), _RecognizeMatMulLines([N, M])]) #assert _unfold_recognized_expr(rec) == TensorProduct(M, N) + TensorProduct(N, M) maybe? expr = (MNP)[i, j] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatMulLines([_RecognizeMatOp(MatMul, [M, N, P])]) assert _unfold_recognized_expr(rec) == MNP expr = Sum(M[i,j](NP)[j,m], (j, 0, k-1)) p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatMul, [M, N, P]) assert _unfold_recognized_expr(rec) == MNP expr = Sum((P[j, m] + P[m, j])(M[i,j]N[m,n] + N[i,j]M[m,n]), (j, 0, k-1), (m, 0, k-1)) p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [ _RecognizeMatOp(MatMul, [M, _RecognizeMatOp(MatAdd, [P, _RecognizeMatOp(Transpose, [P])]), N]), _RecognizeMatOp(MatMul, [N, _RecognizeMatOp(MatAdd, [P, _RecognizeMatOp(Transpose, [P])]), M]) ]) assert _unfold_recognized_expr(rec) == M(P + P.T)N + N(P + P.T)M def test_codegen_array_shape(): expr = CodegenArrayTensorProduct(M, N, P, Q) assert expr.shape == (k, k, k, k, k, k, k, k) Z = MatrixSymbol("Z", m, n) expr = CodegenArrayTensorProduct(M, Z) assert expr.shape == (k, k, m, n) expr2 = CodegenArrayContraction(expr, (0, 1)) assert expr2.shape == (m, n) expr2 = CodegenArrayDiagonal(expr, (0, 1)) assert expr2.shape == (m, n, k) exprp = CodegenArrayPermuteDims(expr, [2, 1, 3, 0]) assert exprp.shape == (m, k, n, k) expr3 = CodegenArrayTensorProduct(N, Z) expr2 = CodegenArrayElementwiseAdd(expr, expr3) assert expr2.shape == (k, k, m, n) # Contraction along axes with discordant dimensions: raises(ValueError, lambda: CodegenArrayContraction(expr, (1, 2))) # Also diagonal needs the same dimensions: raises(ValueError, lambda: CodegenArrayDiagonal(expr, (1, 2))) def test_codegen_array_parse_out_of_bounds(): expr = Sum(M[i, i], (i, 0, 4)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, i], (i, 0, k)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, i], (i, 1, k-1)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, j]N[j,m], (j, 0, 4)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, j]N[j,m], (j, 0, k)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, j]N[j,m], (j, 1, k-1)) raises(ValueError, lambda: parse_indexed_expression(expr)) def test_codegen_permutedims_sink(): cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [0, 1, 3, 2]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(M, CodegenArrayPermuteDims(N, [1, 0])) assert recognize_matrix_expression(sunk) == [M, N.T] cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [1, 0, 3, 2]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(CodegenArrayPermuteDims(M, [1, 0]), CodegenArrayPermuteDims(N, [1, 0])) assert recognize_matrix_expression(sunk) == [M.T, N.T] cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [3, 2, 1, 0]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(CodegenArrayPermuteDims(N, [1, 0]), CodegenArrayPermuteDims(M, [1, 0])) assert recognize_matrix_expression(sunk) == [N.T, M.T] cg = CodegenArrayPermuteDims(CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)), [1, 0]) sunk = cg.nest_permutation() assert sunk == CodegenArrayContraction(CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [[0, 3]]), (1, 2)) cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [1, 0, 3, 2]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(CodegenArrayPermuteDims(M, [1, 0]), CodegenArrayPermuteDims(N, [1, 0])) cg = CodegenArrayPermuteDims(CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P), (1, 2), (3, 4)), [1, 0]) sunk = cg.nest_permutation() assert sunk == CodegenArrayContraction(CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N, P), [[0, 5]]), (1, 2), (3, 4)) sunk2 = sunk.expr.nest_permutation() def test_parsing_of_matrix_expressions(): expr = MN assert _parse_matrix_expression(expr) == CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) expr = Transpose(M) assert _parse_matrix_expression(expr) == CodegenArrayPermuteDims(M, [1, 0]) expr = MTranspose(N) assert _parse_matrix_expression(expr) == CodegenArrayContraction(CodegenArrayTensorProduct(M, CodegenArrayPermuteDims(N, [1, 0])), (1, 2)) def test_special_matrices(): a = MatrixSymbol("a", k, 1) b = MatrixSymbol("b", k, 1) expr = a.Tb elem = expr[0, 0] cg = parse_indexed_expression(elem) assert cg == CodegenArrayContraction(CodegenArrayTensorProduct(a, b), (0, 2)) assert recognize_matrix_expression(cg) == a.Tb def test_push_indices_up_and_down(): indices = list(range(10)) contraction_indices = [(0, 6), (2, 8)] assert CodegenArrayContraction._push_indices_down(contraction_indices, indices) == (1, 3, 4, 5, 7, 9, 10, 11, 12, 13) assert CodegenArrayContraction._push_indices_up(contraction_indices, indices) == (None, 0, None, 1, 2, 3, None, 4, None, 5) assert CodegenArrayDiagonal._push_indices_down(contraction_indices, indices) == (0, 1, 2, 3, 4, 5, 7, 9, 10, 11) assert CodegenArrayDiagonal._push_indices_up(contraction_indices, indices) == (0, 1, 2, 3, 4, 5, None, 6, None, 7) contraction_indices = [(1, 2), (7, 8)] assert CodegenArrayContraction._push_indices_down(contraction_indices, indices) == (0, 3, 4, 5, 6, 9, 10, 11, 12, 13) assert CodegenArrayContraction._push_indices_up(contraction_indices, indices) == (0, None, None, 1, 2, 3, 4, None, None, 5) assert CodegenArrayContraction._push_indices_down(contraction_indices, indices) == (0, 3, 4, 5, 6, 9, 10, 11, 12, 13) assert CodegenArrayDiagonal._push_indices_up(contraction_indices, indices) == (0, 1, None, 2, 3, 4, 5, 6, None, 7) def test_recognize_diagonalized_vectors(): a = MatrixSymbol("a", k, 1) b = MatrixSymbol("b", k, 1) A = MatrixSymbol("A", k, k) B = MatrixSymbol("B", k, k) C = MatrixSymbol("C", k, k) X = MatrixSymbol("X", k, k) x = MatrixSymbol("x", k, 1) I1 = Identity(1) I = Identity(k) # Check matrix recognition over trivial dimensions: cg = CodegenArrayTensorProduct(a, b) assert recognize_matrix_expression(cg) == ab.T cg = CodegenArrayTensorProduct(I1, a, b) assert recognize_matrix_expression(cg) == aI1b.T # Recognize trace inside a tensor product: cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C), (0, 3), (1, 2)) assert recognize_matrix_expression(cg) == Trace(AB)C # Transform diagonal operator to contraction: cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(A, a), (1, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a)), (1, 2)) assert recognize_matrix_expression(cg) == ADiagonalizeVector(a) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(a, b), (0, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(DiagonalizeVector(a), b), (0, 2)) assert recognize_matrix_expression(cg).doit() == DiagonalizeVector(a)b cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(A, a), (0, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a)), (0, 2)) assert recognize_matrix_expression(cg) == A.TDiagonalizeVector(a) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(I, x, I1), (0, 2), (3, 5)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(I, DiagonalizeVector(x), I1), (0, 2)) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(I, x, A, B), (1, 2), (5, 6)) assert cg.transform_to_product() == CodegenArrayDiagonal(CodegenArrayContraction(CodegenArrayTensorProduct(I, DiagonalizeVector(x), A, B), (1, 2)), (3, 4)) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(x, I1), (1, 2)) assert isinstance(cg, CodegenArrayDiagonal) assert cg.diagonal_indices == ((1, 2),) assert recognize_matrix_expression(cg) == x cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(x, I), (0, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(DiagonalizeVector(x), I), (0, 2)) assert recognize_matrix_expression(cg).doit() == DiagonalizeVector(x) cg = CodegenArrayDiagonal(x, (1,)) assert cg == x # Ignore identity matrices with contractions: cg = CodegenArrayContraction(CodegenArrayTensorProduct(I, A, I, I), (0, 2), (1, 3), (5, 7)) assert cg.split_multiple_contractions() == cg assert recognize_matrix_expression(cg) == Trace(A)I cg = CodegenArrayContraction(CodegenArrayTensorProduct(Trace(A) I, I, I), (1, 5), (3, 4)) assert cg.split_multiple_contractions() == cg assert recognize_matrix_expression(cg).doit() == Trace(A)I # Add DiagonalizeVector when required: cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a), (1, 2)) assert cg.split_multiple_contractions() == cg assert recognize_matrix_expression(cg) == Aa cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, B), (1, 2, 4)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), B), (1, 2), (3, 4)) assert recognize_matrix_expression(cg) == ADiagonalizeVector(a)B cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, B), (0, 2, 4)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), B), (0, 2), (3, 4)) assert recognize_matrix_expression(cg) == A.TDiagonalizeVector(a)B cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, b, a.T, B), (0, 2, 4, 7, 9)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), DiagonalizeVector(b), DiagonalizeVector(a), B), (0, 2), (3, 4), (5, 7), (6, 9)) assert recognize_matrix_expression(cg).doit() == A.TDiagonalizeVector(a)DiagonalizeVector(b)DiagonalizeVector(a)B.T cg = CodegenArrayContraction(CodegenArrayTensorProduct(I1, I1, I1), (1, 2, 4)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(I1, I1, I1), (1, 2), (3, 4)) assert recognize_matrix_expression(cg).doit() == Identity(1) cg = CodegenArrayContraction(CodegenArrayTensorProduct(I, I, I, I, A), (1, 2, 8), (5, 6, 9)) assert recognize_matrix_expression(cg.split_multiple_contractions()).doit() == A cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, C, a, B), (1, 2, 4), (5, 6, 8)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), C, DiagonalizeVector(a), B), (1, 2), (3, 4), (5, 6), (7, 8)) assert recognize_matrix_expression(cg) == ADiagonalizeVector(a)CDiagonalizeVector(a)B cg = CodegenArrayContraction(CodegenArrayTensorProduct(a, I1, b, I1, (a.Tb).applyfunc(cos)), (1, 2, 8), (5, 6, 9)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(a, I1, b, I1, (a.Tb).applyfunc(cos)), (1, 2), (3, 8), (5, 6), (7, 9)) assert recognize_matrix_expression(cg) == MatMul(a, I1, (a.Tb).applyfunc(cos), Transpose(I1), b.T) cg = CodegenArrayContraction(CodegenArrayTensorProduct(A.T, a, b, b.T, (AXb).applyfunc(cos)), (1, 2, 8), (5, 6, 9)) assert cg.split_multiple_contractions() == CodegenArrayContraction( CodegenArrayTensorProduct(A.T, DiagonalizeVector(a), b, b.T, (AX*b).applyfunc(cos)), (1, 2), (3, 8), (5, 6, 9)) # assert recognize_matrix_expression(cg) # Check no overlap of lines: cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, C, a, B), (1, 2, 4), (5, 6, 8), (3, 7)) assert cg.split_multiple_contractions() == cg cg = CodegenArrayContraction(CodegenArrayTensorProduct(a, b, A), (0, 2, 4), (1, 3)) assert cg.split_multiple_contractions() == cg
b71efa4d81948a7e1a186be0703fe6278d06fb5878b9ddd96b3938ebe6b915b6	import itertools as it from sympy.core.function import Function from sympy.core.numbers import I, oo, Rational from sympy.core.power import Pow from sympy.core.singleton import S from sympy.core.symbol import Symbol from sympy.functions.elementary.miscellaneous import (sqrt, cbrt, root, Min, Max, real_root) from sympy.functions.elementary.trigonometric import cos, sin from sympy.functions.elementary.exponential import log from sympy.functions.elementary.integers import floor, ceiling from sympy.functions.special.delta_functions import Heaviside from sympy.utilities.lambdify import lambdify from sympy.utilities.pytest import raises, skip, ignore_warnings from sympy.external import import_module def test_Min(): from sympy.abc import x, y, z n = Symbol('n', negative=True) n_ = Symbol('n_', negative=True) nn = Symbol('nn', nonnegative=True) nn_ = Symbol('nn_', nonnegative=True) p = Symbol('p', positive=True) p_ = Symbol('p_', positive=True) np = Symbol('np', nonpositive=True) np_ = Symbol('np_', nonpositive=True) r = Symbol('r', real=True) assert Min(5, 4) == 4 assert Min(-oo, -oo) == -oo assert Min(-oo, n) == -oo assert Min(n, -oo) == -oo assert Min(-oo, np) == -oo assert Min(np, -oo) == -oo assert Min(-oo, 0) == -oo assert Min(0, -oo) == -oo assert Min(-oo, nn) == -oo assert Min(nn, -oo) == -oo assert Min(-oo, p) == -oo assert Min(p, -oo) == -oo assert Min(-oo, oo) == -oo assert Min(oo, -oo) == -oo assert Min(n, n) == n assert Min(n, np) == Min(n, np) assert Min(np, n) == Min(np, n) assert Min(n, 0) == n assert Min(0, n) == n assert Min(n, nn) == n assert Min(nn, n) == n assert Min(n, p) == n assert Min(p, n) == n assert Min(n, oo) == n assert Min(oo, n) == n assert Min(np, np) == np assert Min(np, 0) == np assert Min(0, np) == np assert Min(np, nn) == np assert Min(nn, np) == np assert Min(np, p) == np assert Min(p, np) == np assert Min(np, oo) == np assert Min(oo, np) == np assert Min(0, 0) == 0 assert Min(0, nn) == 0 assert Min(nn, 0) == 0 assert Min(0, p) == 0 assert Min(p, 0) == 0 assert Min(0, oo) == 0 assert Min(oo, 0) == 0 assert Min(nn, nn) == nn assert Min(nn, p) == Min(nn, p) assert Min(p, nn) == Min(p, nn) assert Min(nn, oo) == nn assert Min(oo, nn) == nn assert Min(p, p) == p assert Min(p, oo) == p assert Min(oo, p) == p assert Min(oo, oo) == oo assert Min(n, n_).func is Min assert Min(nn, nn_).func is Min assert Min(np, np_).func is Min assert Min(p, p_).func is Min # lists assert Min() == S.Infinity assert Min(x) == x assert Min(x, y) == Min(y, x) assert Min(x, y, z) == Min(z, y, x) assert Min(x, Min(y, z)) == Min(z, y, x) assert Min(x, Max(y, -oo)) == Min(x, y) assert Min(p, oo, n, p, p, p_) == n assert Min(p_, n_, p) == n_ assert Min(n, oo, -7, p, p, 2) == Min(n, -7) assert Min(2, x, p, n, oo, n_, p, 2, -2, -2) == Min(-2, x, n, n_) assert Min(0, x, 1, y) == Min(0, x, y) assert Min(1000, 100, -100, x, p, n) == Min(n, x, -100) assert Min(cos(x), sin(x)) == Min(cos(x), sin(x)) assert Min(cos(x), sin(x)).subs(x, 1) == cos(1) assert Min(cos(x), sin(x)).subs(x, S(1)/2) == sin(S(1)/2) raises(ValueError, lambda: Min(cos(x), sin(x)).subs(x, I)) raises(ValueError, lambda: Min(I)) raises(ValueError, lambda: Min(I, x)) raises(ValueError, lambda: Min(S.ComplexInfinity, x)) assert Min(1, x).diff(x) == Heaviside(1 - x) assert Min(x, 1).diff(x) == Heaviside(1 - x) assert Min(0, -x, 1 - 2x).diff(x) == -Heaviside(x + Min(0, -2x + 1)) \ - 2Heaviside(2x + Min(0, -x) - 1) # issue 7619 f = Function('f') assert Min(1, 2Min(f(1), 2)) # doesn't fail # issue 7233 e = Min(0, x) assert e.evalf == e.n assert e.n().args == (0, x) # issue 8643 m = Min(n, p_, n_, r) assert m.is_positive is False assert m.is_nonnegative is False assert m.is_negative is True m = Min(p, p_) assert m.is_positive is True assert m.is_nonnegative is True assert m.is_negative is False m = Min(p, nn_, p_) assert m.is_positive is None assert m.is_nonnegative is True assert m.is_negative is False m = Min(nn, p, r) assert m.is_positive is None assert m.is_nonnegative is None assert m.is_negative is None def test_Max(): from sympy.abc import x, y, z n = Symbol('n', negative=True) n_ = Symbol('n_', negative=True) nn = Symbol('nn', nonnegative=True) nn_ = Symbol('nn_', nonnegative=True) p = Symbol('p', positive=True) p_ = Symbol('p_', positive=True) np = Symbol('np', nonpositive=True) np_ = Symbol('np_', nonpositive=True) r = Symbol('r', real=True) assert Max(5, 4) == 5 # lists assert Max() == S.NegativeInfinity assert Max(x) == x assert Max(x, y) == Max(y, x) assert Max(x, y, z) == Max(z, y, x) assert Max(x, Max(y, z)) == Max(z, y, x) assert Max(x, Min(y, oo)) == Max(x, y) assert Max(n, -oo, n_, p, 2) == Max(p, 2) assert Max(n, -oo, n_, p) == p assert Max(2, x, p, n, -oo, S.NegativeInfinity, n_, p, 2) == Max(2, x, p) assert Max(0, x, 1, y) == Max(1, x, y) assert Max(r, r + 1, r - 1) == 1 + r assert Max(1000, 100, -100, x, p, n) == Max(p, x, 1000) assert Max(cos(x), sin(x)) == Max(sin(x), cos(x)) assert Max(cos(x), sin(x)).subs(x, 1) == sin(1) assert Max(cos(x), sin(x)).subs(x, S(1)/2) == cos(S(1)/2) raises(ValueError, lambda: Max(cos(x), sin(x)).subs(x, I)) raises(ValueError, lambda: Max(I)) raises(ValueError, lambda: Max(I, x)) raises(ValueError, lambda: Max(S.ComplexInfinity, 1)) assert Max(n, -oo, n_, p, 2) == Max(p, 2) assert Max(n, -oo, n_, p, 1000) == Max(p, 1000) assert Max(1, x).diff(x) == Heaviside(x - 1) assert Max(x, 1).diff(x) == Heaviside(x - 1) assert Max(x2, 1 + x, 1).diff(x) == \ 2xHeaviside(x2 - Max(1, x + 1)) \ + Heaviside(x - Max(1, x2) + 1) e = Max(0, x) assert e.evalf == e.n assert e.n().args == (0, x) # issue 8643 m = Max(p, p_, n, r) assert m.is_positive is True assert m.is_nonnegative is True assert m.is_negative is False m = Max(n, n_) assert m.is_positive is False assert m.is_nonnegative is False assert m.is_negative is True m = Max(n, n_, r) assert m.is_positive is None assert m.is_nonnegative is None assert m.is_negative is None m = Max(n, nn, r) assert m.is_positive is None assert m.is_nonnegative is True assert m.is_negative is False def test_minmax_assumptions(): r = Symbol('r', real=True) a = Symbol('a', real=True, algebraic=True) t = Symbol('t', real=True, transcendental=True) q = Symbol('q', rational=True) p = Symbol('p', irrational=True) n = Symbol('n', rational=True, integer=False) i = Symbol('i', integer=True) o = Symbol('o', odd=True) e = Symbol('e', even=True) k = Symbol('k', prime=True) reals = [r, a, t, q, p, n, i, o, e, k] for ext in (Max, Min): for x, y in it.product(reals, repeat=2): # Must be real assert ext(x, y).is_real # Algebraic? if x.is_algebraic and y.is_algebraic: assert ext(x, y).is_algebraic elif x.is_transcendental and y.is_transcendental: assert ext(x, y).is_transcendental else: assert ext(x, y).is_algebraic is None # Rational? if x.is_rational and y.is_rational: assert ext(x, y).is_rational elif x.is_irrational and y.is_irrational: assert ext(x, y).is_irrational else: assert ext(x, y).is_rational is None # Integer? if x.is_integer and y.is_integer: assert ext(x, y).is_integer elif x.is_noninteger and y.is_noninteger: assert ext(x, y).is_noninteger else: assert ext(x, y).is_integer is None # Odd? if x.is_odd and y.is_odd: assert ext(x, y).is_odd elif x.is_odd is False and y.is_odd is False: assert ext(x, y).is_odd is False else: assert ext(x, y).is_odd is None # Even? if x.is_even and y.is_even: assert ext(x, y).is_even elif x.is_even is False and y.is_even is False: assert ext(x, y).is_even is False else: assert ext(x, y).is_even is None # Prime? if x.is_prime and y.is_prime: assert ext(x, y).is_prime elif x.is_prime is False and y.is_prime is False: assert ext(x, y).is_prime is False else: assert ext(x, y).is_prime is None def test_issue_8413(): x = Symbol('x', real=True) # we can't evaluate in general because non-reals are not # comparable: Min(floor(3.2 + I), 3.2 + I) -> ValueError assert Min(floor(x), x) == floor(x) assert Min(ceiling(x), x) == x assert Max(floor(x), x) == x assert Max(ceiling(x), x) == ceiling(x) def test_root(): from sympy.abc import x n = Symbol('n', integer=True) k = Symbol('k', integer=True) assert root(2, 2) == sqrt(2) assert root(2, 1) == 2 assert root(2, 3) == 2Rational(1, 3) assert root(2, 3) == cbrt(2) assert root(2, -5) == 2Rational(4, 5)/2 assert root(-2, 1) == -2 assert root(-2, 2) == sqrt(2)I assert root(-2, 1) == -2 assert root(x, 2) == sqrt(x) assert root(x, 1) == x assert root(x, 3) == xRational(1, 3) assert root(x, 3) == cbrt(x) assert root(x, -5) == xRational(-1, 5) assert root(x, n) == x(1/n) assert root(x, -n) == x(-1/n) assert root(x, n, k) == (-1)*(2k/n)x(1/n) def test_real_root(): assert real_root(-8, 3) == -2 assert real_root(-16, 4) == root(-16, 4) r = root(-7, 4) assert real_root(r) == r r1 = root(-1, 3) r2 = r12 r3 = root(-1, 4) assert real_root(r1 + r2 + r3) == -1 + r2 + r3 assert real_root(root(-2, 3)) == -root(2, 3) assert real_root(-8., 3) == -2 x = Symbol('x') n = Symbol('n') g = real_root(x, n) assert g.subs(dict(x=-8, n=3)) == -2 assert g.subs(dict(x=8, n=3)) == 2 # give principle root if there is no real root -- if this is not desired # then maybe a Root class is needed to raise an error instead assert g.subs(dict(x=I, n=3)) == cbrt(I) assert g.subs(dict(x=-8, n=2)) == sqrt(-8) assert g.subs(dict(x=I, n=2)) == sqrt(I) def test_issue_11463(): numpy = import_module('numpy') if not numpy: skip("numpy not installed.") x = Symbol('x') f = lambdify(x, real_root((log(x/(x-2))), 3), 'numpy') # numpy.select evaluates all options before considering conditions, # so it raises a warning about root of negative number which does # not affect the outcome. This warning is suppressed here with ignore_warnings(RuntimeWarning): assert f(numpy.array(-1)) < -1 def test_rewrite_MaxMin_as_Heaviside(): from sympy.abc import x assert Max(0, x).rewrite(Heaviside) == xHeaviside(x) assert Max(3, x).rewrite(Heaviside) == xHeaviside(x - 3) + \ 3Heaviside(-x + 3) assert Max(0, x+2, 2x).rewrite(Heaviside) == \ 2xHeaviside(2x)Heaviside(x - 2) + \ (x + 2)Heaviside(-x + 2)Heaviside(x + 2) assert Min(0, x).rewrite(Heaviside) == xHeaviside(-x) assert Min(3, x).rewrite(Heaviside) == xHeaviside(-x + 3) + \ 3Heaviside(x - 3) assert Min(x, -x, -2).rewrite(Heaviside) == \ xHeaviside(-2x)Heaviside(-x - 2) - \ xHeaviside(2x)Heaviside(x - 2) \ - 2Heaviside(-x + 2)Heaviside(x + 2) def test_rewrite_MaxMin_as_Piecewise(): from sympy import symbols, Piecewise x, y, z, a, b = symbols('x y z a b', real=True) vx, vy, va = symbols('vx vy va') assert Max(a, b).rewrite(Piecewise) == Piecewise((a, a >= b), (b, True)) assert Max(x, y, z).rewrite(Piecewise) == Piecewise((x, (x >= y) & (x >= z)), (y, y >= z), (z, True)) assert Max(x, y, a, b).rewrite(Piecewise) == Piecewise((a, (a >= b) & (a >= x) & (a >= y)), (b, (b >= x) & (b >= y)), (x, x >= y), (y, True)) assert Min(a, b).rewrite(Piecewise) == Piecewise((a, a <= b), (b, True)) assert Min(x, y, z).rewrite(Piecewise) == Piecewise((x, (x <= y) & (x <= z)), (y, y <= z), (z, True)) assert Min(x, y, a, b).rewrite(Piecewise) == Piecewise((a, (a <= b) & (a <= x) & (a <= y)), (b, (b <= x) & (b <= y)), (x, x <= y), (y, True)) # Piecewise rewriting of Min/Max does also takes place for not explicitly real arguments assert Max(vx, vy).rewrite(Piecewise) == Piecewise((vx, vx >= vy), (vy, True)) assert Min(va, vx, vy).rewrite(Piecewise) == Piecewise((va, (va <= vx) & (va <= vy)), (vx, vx <= vy), (vy, True)) def test_issue_11099(): from sympy.abc import x, y # some fixed value tests fixed_test_data = {x: -2, y: 3} assert Min(x, y).evalf(subs=fixed_test_data) == \ Min(x, y).subs(fixed_test_data).evalf() assert Max(x, y).evalf(subs=fixed_test_data) == \ Max(x, y).subs(fixed_test_data).evalf() # randomly generate some test data from random import randint for i in range(20): random_test_data = {x: randint(-100, 100), y: randint(-100, 100)} assert Min(x, y).evalf(subs=random_test_data) == \ Min(x, y).subs(random_test_data).evalf() assert Max(x, y).evalf(subs=random_test_data) == \ Max(x, y).subs(random_test_data).evalf() def test_issue_12638(): from sympy.abc import a, b, c, d assert Min(a, b, c, Max(a, b)) == Min(a, b, c) assert Min(a, b, Max(a, b, c)) == Min(a, b) assert Min(a, b, Max(a, c)) == Min(a, b) def test_instantiation_evaluation(): from sympy.abc import v, w, x, y, z assert Min(1, Max(2, x)) == 1 assert Max(3, Min(2, x)) == 3 assert Min(Max(x, y), Max(x, z)) == Max(x, Min(y, z)) assert set(Min(Max(w, x), Max(y, z)).args) == set( [Max(w, x), Max(y, z)]) assert Min(Max(x, y), Max(x, z), w) == Min( w, Max(x, Min(y, z))) A, B = Min, Max for i in range(2): assert A(x, B(x, y)) == x assert A(x, B(y, A(x, w, z))) == A(x, B(y, A(w, z))) A, B = B, A assert Min(w, Max(x, y), Max(v, x, z)) == Min( w, Max(x, Min(y, Max(v, z)))) def test_rewrite_as_Abs(): from itertools import permutations from sympy.functions.elementary.complexes import Abs from sympy.abc import x, y, z, w def test(e): free = e.free_symbols a = e.rewrite(Abs) assert not a.has(Min, Max) for i in permutations(range(len(free))): reps = dict(zip(free, i)) assert a.xreplace(reps) == e.xreplace(reps) test(Min(x, y)) test(Max(x, y)) test(Min(x, y, z)) test(Min(Max(w, x), Max(y, z))) def test_issue_14000(): assert isinstance(sqrt(4, evaluate=False), Pow) == True assert isinstance(cbrt(3.5, evaluate=False), Pow) == True assert isinstance(root(16, 4, evaluate=False), Pow) == True assert sqrt(4, evaluate=False) == Pow(4, S.Half, evaluate=False) assert cbrt(3.5, evaluate=False) == Pow(3.5, Rational(1, 3), evaluate=False) assert root(4, 2, evaluate=False) == Pow(4, Rational(1, 2), evaluate=False) assert root(16, 4, 2, evaluate=False).has(Pow) == True assert real_root(-8, 3, evaluate=False).has(Pow) == True
9a011ca80e9acf7b40eccb65204d76bd363cbb4cda696f6dba2f5fabf145c41f	from sympy import (acos, acosh, asinh, atan, cos, Derivative, diff, dsolve, Dummy, Eq, Ne, erf, erfi, exp, Function, I, Integral, LambertW, log, O, pi, Rational, rootof, S, simplify, sin, sqrt, Subs, Symbol, tan, asin, sinh, Piecewise, symbols, Poly, sec, Ei, re, im) from sympy.solvers.ode import (_undetermined_coefficients_match, checkodesol, classify_ode, classify_sysode, constant_renumber, constantsimp, homogeneous_order, infinitesimals, checkinfsol, checksysodesol, solve_ics, dsolve, get_numbered_constants) from sympy.solvers.deutils import ode_order from sympy.utilities.pytest import XFAIL, skip, raises, slow, ON_TRAVIS C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, C10 = symbols('C0:11') u, x, y, z = symbols('u,x:z', real=True) f = Function('f') g = Function('g') h = Function('h') # Note: the tests below may fail (but still be correct) if ODE solver, # the integral engine, solve(), or even simplify() changes. Also, in # differently formatted solutions, the arbitrary constants might not be # equal. Using specific hints in tests can help to avoid this. # Tests of order higher than 1 should run the solutions through # constant_renumber because it will normalize it (constant_renumber causes # dsolve() to return different results on different machines) def test_linear_2eq_order1(): x, y, z = symbols('x, y, z', cls=Function) k, l, m, n = symbols('k, l, m, n', Integer=True) t = Symbol('t') x0, y0 = symbols('x0, y0', cls=Function) eq1 = (Eq(diff(x(t),t), 9y(t)), Eq(diff(y(t),t), 12x(t))) sol1 = [Eq(x(t), 9C1exp(6sqrt(3)t) + 9C2exp(-6sqrt(3)t)), \ Eq(y(t), 6sqrt(3)C1exp(6sqrt(3)t) - 6sqrt(3)C2exp(-6sqrt(3)t))] assert checksysodesol(eq1, sol1) == (True, [0, 0]) eq2 = (Eq(diff(x(t),t), 2x(t) + 4y(t)), Eq(diff(y(t),t), 12x(t) + 41y(t))) sol2 = [Eq(x(t), 4C1exp(t(sqrt(1713)/2 + S(43)/2)) + 4C2exp(t(-sqrt(1713)/2 + S(43)/2))), \ Eq(y(t), C1(S(39)/2 + sqrt(1713)/2)exp(t(sqrt(1713)/2 + S(43)/2)) + \ C2(-sqrt(1713)/2 + S(39)/2)exp(t(-sqrt(1713)/2 + S(43)/2)))] assert checksysodesol(eq2, sol2) == (True, [0, 0]) eq3 = (Eq(diff(x(t),t), x(t) + y(t)), Eq(diff(y(t),t), -2x(t) + 2y(t))) sol3 = [Eq(x(t), (C1cos(sqrt(7)t/2) + C2sin(sqrt(7)t/2))exp(3t/2)), \ Eq(y(t), (C1(-sqrt(7)sin(sqrt(7)t/2)/2 + cos(sqrt(7)t/2)/2) + \ C2(sin(sqrt(7)t/2)/2 + sqrt(7)cos(sqrt(7)t/2)/2))exp(3t/2))] assert checksysodesol(eq3, sol3) == (True, [0, 0]) eq4 = (Eq(diff(x(t),t), x(t) + y(t) + 9), Eq(diff(y(t),t), 2x(t) + 5y(t) + 23)) sol4 = [Eq(x(t), C1exp(t(sqrt(6) + 3)) + C2exp(t(-sqrt(6) + 3)) - S(22)/3), \ Eq(y(t), C1(2 + sqrt(6))exp(t(sqrt(6) + 3)) + C2(-sqrt(6) + 2)exp(t(-sqrt(6) + 3)) - S(5)/3)] assert checksysodesol(eq4, sol4) == (True, [0, 0]) eq5 = (Eq(diff(x(t),t), x(t) + y(t) + 81), Eq(diff(y(t),t), -2x(t) + y(t) + 23)) sol5 = [Eq(x(t), (C1cos(sqrt(2)t) + C2sin(sqrt(2)t))exp(t) - S(58)/3), \ Eq(y(t), (-sqrt(2)C1sin(sqrt(2)t) + sqrt(2)C2cos(sqrt(2)t))exp(t) - S(185)/3)] assert checksysodesol(eq5, sol5) == (True, [0, 0]) eq6 = (Eq(diff(x(t),t), 5tx(t) + 2y(t)), Eq(diff(y(t),t), 2x(t) + 5ty(t))) sol6 = [Eq(x(t), (C1exp(2t) + C2exp(-2t))exp(S(5)/2t2)), \ Eq(y(t), (C1exp(2t) - C2exp(-2t))exp(S(5)/2t2))] s = dsolve(eq6) assert checksysodesol(eq6, sol6) == (True, [0, 0]) eq7 = (Eq(diff(x(t),t), 5tx(t) + t2y(t)), Eq(diff(y(t),t), -t*2x(t) + 5ty(t))) sol7 = [Eq(x(t), (C1cos((t3)/3) + C2sin((t*3)/3))exp(S(5)/2t2)), \ Eq(y(t), (-C1sin((t*3)/3) + C2cos((t*3)/3))exp(S(5)/2t2))] assert checksysodesol(eq7, sol7) == (True, [0, 0]) eq8 = (Eq(diff(x(t),t), 5tx(t) + t2y(t)), Eq(diff(y(t),t), -t*2x(t) + (5t+9t*2)y(t))) sol8 = [Eq(x(t), (C1exp((sqrt(77)/2 + S(9)/2)(t*3)/3) + \ C2exp((-sqrt(77)/2 + S(9)/2)(t3)/3))exp(S(5)/2t2)), \ Eq(y(t), (C1(sqrt(77)/2 + S(9)/2)exp((sqrt(77)/2 + S(9)/2)(t*3)/3) + \ C2(-sqrt(77)/2 + S(9)/2)exp((-sqrt(77)/2 + S(9)/2)(t*3)/3))exp(S(5)/2t2))] assert checksysodesol(eq8, sol8) == (True, [0, 0]) eq10 = (Eq(diff(x(t),t), 5tx(t) + t2y(t)), Eq(diff(y(t),t), (1-t*2)x(t) + (5t+9t*2)y(t))) sol10 = [Eq(x(t), C1x0(t) + C2x0(t)Integral(t2exp(Integral(5t, t))exp(Integral(9t2 + 5t, t))/x0(t)*2, t)), \ Eq(y(t), C1y0(t) + C2(y0(t)Integral(t*2exp(Integral(5t, t))exp(Integral(9t2 + 5t, t))/x0(t)*2, t) + \ exp(Integral(5t, t))exp(Integral(9t*2 + 5t, t))/x0(t)))] s = dsolve(eq10) assert s == sol10 # too complicated to test with subs and simplify # assert checksysodesol(eq10, sol10) == (True, [0, 0]) # this one fails def test_linear_2eq_order1_nonhomog_linear(): e = [Eq(diff(f(x), x), f(x) + g(x) + 5x), Eq(diff(g(x), x), f(x) - g(x))] raises(NotImplementedError, lambda: dsolve(e)) def test_linear_2eq_order1_nonhomog(): # Note: once implemented, add some tests esp. with resonance e = [Eq(diff(f(x), x), f(x) + exp(x)), Eq(diff(g(x), x), f(x) + g(x) + xexp(x))] raises(NotImplementedError, lambda: dsolve(e)) def test_linear_2eq_order1_type2_degen(): e = [Eq(diff(f(x), x), f(x) + 5), Eq(diff(g(x), x), f(x) + 7)] s1 = [Eq(f(x), C1exp(x) - 5), Eq(g(x), C1exp(x) - C2 + 2x - 5)] assert checksysodesol(e, s1) == (True, [0, 0]) def test_dsolve_linear_2eq_order1_diag_triangular(): e = [Eq(diff(f(x), x), f(x)), Eq(diff(g(x), x), g(x))] s1 = [Eq(f(x), C1exp(x)), Eq(g(x), C2exp(x))] assert checksysodesol(e, s1) == (True, [0, 0]) e = [Eq(diff(f(x), x), 2f(x)), Eq(diff(g(x), x), 3f(x) + 7g(x))] s1 = [Eq(f(x), -5C2exp(2x)), Eq(g(x), 5C1exp(7x) + 3C2exp(2x))] assert checksysodesol(e, s1) == (True, [0, 0]) def test_sysode_linear_2eq_order1_type1_D_lt_0(): e = [Eq(diff(f(x), x), -9If(x) - 4g(x)), Eq(diff(g(x), x), -4Ig(x))] s1 = [Eq(f(x), -4C1exp(-4Ix) - 4C2exp(-9Ix)), \ Eq(g(x), 5IC1exp(-4Ix))] assert checksysodesol(e, s1) == (True, [0, 0]) def test_sysode_linear_2eq_order1_type1_D_lt_0_b_eq_0(): e = [Eq(diff(f(x), x), -9If(x)), Eq(diff(g(x), x), -4Ig(x))] s1 = [Eq(f(x), -5IC2exp(-9Ix)), Eq(g(x), 5IC1exp(-4Ix))] assert checksysodesol(e, s1) == (True, [0, 0]) def test_sysode_linear_2eq_order1_many_zeros(): t = Symbol('t') corner_cases = [(0, 0, 0, 0), (1, 0, 0, 0), (0, 1, 0, 0), (0, 0, 1, 0), (0, 0, 0, 1), (1, 0, 0, I), (I, 0, 0, -I), (0, I, 0, 0), (0, I, I, 0)] s1 = [[Eq(f(t), C1), Eq(g(t), C2)], [Eq(f(t), C1exp(t)), Eq(g(t), -C2)], [Eq(f(t), C1 + C2t), Eq(g(t), C2)], [Eq(f(t), C2), Eq(g(t), C1 + C2t)], [Eq(f(t), -C2), Eq(g(t), C1exp(t))], [Eq(f(t), C1(1 - I)exp(t)), Eq(g(t), C2(-1 + I)exp(It))], [Eq(f(t), 2IC1exp(It)), Eq(g(t), -2IC2exp(-It))], [Eq(f(t), IC1 + IC2t), Eq(g(t), C2)], [Eq(f(t), IC1exp(It) + IC2exp(-It)), \ Eq(g(t), IC1exp(It) - IC2exp(-It))] ] for r, sol in zip(corner_cases, s1): eq = [Eq(diff(f(t), t), r[0]f(t) + r[1]g(t)), Eq(diff(g(t), t), r[2]f(t) + r[3]g(t))] assert checksysodesol(eq, sol) == (True, [0, 0]) def test_dsolve_linsystem_symbol_piecewise(): u = Symbol('u') # XXX it's more complicated with real u eq = (Eq(diff(f(x), x), 2f(x) + g(x)), Eq(diff(g(x), x), uf(x))) s1 = [Eq(f(x), Piecewise((C1exp(x(sqrt(4u + 4)/2 + 1)) + C2exp(x(-sqrt(4u + 4)/2 + 1)), Ne(4u + 4, 0)), ((C1 + C2(x + Piecewise((0, Eq(sqrt(4u + 4)/2 + 1, 2)), (1/(-sqrt(4u + 4)/2 + 1), True))))exp(x(sqrt(4u + 4)/2 + 1)), True))), Eq(g(x), Piecewise((C1(sqrt(4u + 4)/2 - 1)exp(x(sqrt(4u + 4)/2 + 1)) + C2(-sqrt(4u + 4)/2 - 1)exp(x(-sqrt(4u + 4)/2 + 1)), Ne(4u + 4, 0)), ((C1(sqrt(4u + 4)/2 - 1) + C2(x(sqrt(4u + 4)/2 - 1) + Piecewise((1, Eq(sqrt(4u + 4)/2 + 1, 2)), (0, True))))exp(x(sqrt(4u + 4)/2 + 1)), True)))] assert dsolve(eq) == s1 # FIXME: assert checksysodesol(eq, s) == (True, [0, 0]) # Remove lines below when checksysodesol works s = [(l.lhs, l.rhs) for l in s1] for v in [0, 7, -42, 5I, 3 + 4I]: assert eq[0].subs(s).subs(u, v).doit().simplify() assert eq[1].subs(s).subs(u, v).doit().simplify() # example from https://groups.google.com/d/msg/sympy/xmzoqW6tWaE/sf0bgQrlCgAJ i, r1, c1, r2, c2, t = symbols('i, r1, c1, r2, c2, t') x1 = Function('x1') x2 = Function('x2') eq1 = r1c1Derivative(x1(t), t) + x1(t) - x2(t) - r1i eq2 = r2c1Derivative(x1(t), t) + r2c2Derivative(x2(t), t) + x2(t) - r2i sol = dsolve((eq1, eq2)) # FIXME: assert checksysodesol(eq, sol) == (True, [0, 0]) # Remove line below when checksysodesol works assert all(s.has(Piecewise) for s in sol) @slow def test_linear_2eq_order2(): x, y, z = symbols('x, y, z', cls=Function) k, l, m, n = symbols('k, l, m, n', Integer=True) t, l = symbols('t, l') x0, y0 = symbols('x0, y0', cls=Function) eq1 = (Eq(diff(x(t),t,t), 5x(t) + 43y(t)), Eq(diff(y(t),t,t), x(t) + 9y(t))) sol1 = [Eq(x(t), 43C1exp(trootof(l*4 - 14l*2 + 2, 0)) + 43C2exp(trootof(l*4 - 14l*2 + 2, 1)) + \ 43C3exp(trootof(l*4 - 14l*2 + 2, 2)) + 43C4exp(trootof(l*4 - 14l*2 + 2, 3))), \ Eq(y(t), C1(rootof(l*4 - 14l2 + 2, 0)2 - 5)exp(trootof(l*4 - 14l*2 + 2, 0)) + \ C2(rootof(l*4 - 14l2 + 2, 1)2 - 5)exp(trootof(l*4 - 14l*2 + 2, 1)) + \ C3(rootof(l*4 - 14l2 + 2, 2)2 - 5)exp(trootof(l*4 - 14l*2 + 2, 2)) + \ C4(rootof(l*4 - 14l2 + 2, 3)2 - 5)exp(trootof(l*4 - 14l*2 + 2, 3)))] assert dsolve(eq1) == sol1 # FIXME: assert checksysodesol(eq1, sol1) == (True, [0, 0]) # this one fails eq2 = (Eq(diff(x(t),t,t), 8x(t)+3y(t)+31), Eq(diff(y(t),t,t), 9x(t)+7y(t)+12)) sol2 = [Eq(x(t), 3C1exp(trootof(l*4 - 15l*2 + 29, 0)) + 3C2exp(trootof(l*4 - 15l*2 + 29, 1)) + \ 3C3exp(trootof(l*4 - 15l*2 + 29, 2)) + 3C4exp(trootof(l*4 - 15l*2 + 29, 3)) - S(181)/29), \ Eq(y(t), C1(rootof(l*4 - 15l2 + 29, 0)2 - 8)exp(trootof(l*4 - 15l*2 + 29, 0)) + \ C2(rootof(l*4 - 15l2 + 29, 1)2 - 8)exp(trootof(l*4 - 15l*2 + 29, 1)) + \ C3(rootof(l*4 - 15l2 + 29, 2)2 - 8)exp(trootof(l*4 - 15l*2 + 29, 2)) + \ C4(rootof(l*4 - 15l2 + 29, 3)2 - 8)exp(trootof(l*4 - 15l*2 + 29, 3)) + S(183)/29)] assert dsolve(eq2) == sol2 # FIXME: assert checksysodesol(eq2, sol2) == (True, [0, 0]) # this one fails eq3 = (Eq(diff(x(t),t,t) - 9diff(y(t),t) + 7x(t),0), Eq(diff(y(t),t,t) + 9diff(x(t),t) + 7y(t),0)) sol3 = [Eq(x(t), C1cos(t(S(9)/2 + sqrt(109)/2)) + C2sin(t(S(9)/2 + sqrt(109)/2)) + C3cos(t(-sqrt(109)/2 + S(9)/2)) + \ C4sin(t(-sqrt(109)/2 + S(9)/2))), Eq(y(t), -C1sin(t(S(9)/2 + sqrt(109)/2)) + C2cos(t(S(9)/2 + sqrt(109)/2)) - \ C3sin(t(-sqrt(109)/2 + S(9)/2)) + C4cos(t(-sqrt(109)/2 + S(9)/2)))] assert dsolve(eq3) == sol3 assert checksysodesol(eq3, sol3) == (True, [0, 0]) eq4 = (Eq(diff(x(t),t,t), 9tdiff(y(t),t)-9y(t)), Eq(diff(y(t),t,t),7tdiff(x(t),t)-7x(t))) sol4 = [Eq(x(t), C3t + tIntegral((9C1exp(3sqrt(7)t2/2) + 9C2exp(-3sqrt(7)t2/2))/t2, t)), \ Eq(y(t), C4t + tIntegral((3sqrt(7)C1exp(3sqrt(7)t*2/2) - 3sqrt(7)C2exp(-3sqrt(7)t2/2))/t2, t))] assert dsolve(eq4) == sol4 assert checksysodesol(eq4, sol4) == (True, [0, 0]) eq5 = (Eq(diff(x(t),t,t), (log(t)+t*2)diff(x(t),t)+(log(t)+t*2)3diff(y(t),t)), Eq(diff(y(t),t,t), \ (log(t)+t2)2diff(x(t),t)+(log(t)+t2)9diff(y(t),t))) sol5 = [Eq(x(t), -sqrt(22)(C1Integral(exp((-sqrt(22) + 5)Integral(t*2 + log(t), t)), t) + C2 - \ C3Integral(exp((sqrt(22) + 5)Integral(t2 + log(t), t)), t) - C4 - \ (sqrt(22) + 5)(C1Integral(exp((-sqrt(22) + 5)Integral(t*2 + log(t), t)), t) + C2) + \ (-sqrt(22) + 5)(C3Integral(exp((sqrt(22) + 5)Integral(t*2 + log(t), t)), t) + C4))/88), \ Eq(y(t), -sqrt(22)(C1Integral(exp((-sqrt(22) + 5)Integral(t*2 + log(t), t)), t) + \ C2 - C3Integral(exp((sqrt(22) + 5)Integral(t2 + log(t), t)), t) - C4)/44)] assert dsolve(eq5) == sol5 assert checksysodesol(eq5, sol5) == (True, [0, 0]) eq6 = (Eq(diff(x(t),t,t), log(t)tdiff(y(t),t) - log(t)y(t)), Eq(diff(y(t),t,t), log(t)tdiff(x(t),t) - log(t)x(t))) sol6 = [Eq(x(t), C3t + tIntegral((C1exp(Integral(tlog(t), t)) + \ C2exp(-Integral(tlog(t), t)))/t2, t)), Eq(y(t), C4t + tIntegral((C1exp(Integral(tlog(t), t)) - \ C2exp(-Integral(tlog(t), t)))/t2, t))] assert dsolve(eq6) == sol6 assert checksysodesol(eq6, sol6) == (True, [0, 0]) eq7 = (Eq(diff(x(t),t,t), log(t)(tdiff(x(t),t) - x(t)) + exp(t)(tdiff(y(t),t) - y(t))), \ Eq(diff(y(t),t,t), (t2)(tdiff(x(t),t) - x(t)) + (t)(tdiff(y(t),t) - y(t)))) sol7 = [Eq(x(t), C3t + tIntegral((C1x0(t) + C2x0(t)Integral(texp(t)exp(Integral(t*2, t))\ exp(Integral(tlog(t), t))/x0(t)2, t))/t2, t)), Eq(y(t), C4t + tIntegral((C1y0(t) + \ C2(y0(t)Integral(texp(t)exp(Integral(t*2, t))exp(Integral(tlog(t), t))/x0(t)2, t) + \ exp(Integral(t2, t))exp(Integral(tlog(t), t))/x0(t)))/t2, t))] assert dsolve(eq7) == sol7 # FIXME: assert checksysodesol(eq7, sol7) == (True, [0, 0]) eq8 = (Eq(diff(x(t),t,t), t(4x(t) + 9y(t))), Eq(diff(y(t),t,t), t(12x(t) - 6y(t)))) sol8 = ("[Eq(x(t), -sqrt(133)((-sqrt(133) - 1)(C2(133t8/24 - t3/6 + sqrt(133)t*3/2 + 1) + " "C1t(sqrt(133)t4/6 - t3/12 + 1) + O(t*6)) - (-1 + sqrt(133))(C2(-sqrt(133)t3/6 - t3/6 + 1) + " "C1t(-sqrt(133)t3/12 - t3/12 + 1) + O(t6)) - 4C2(133t8/24 - t3/6 + sqrt(133)t3/2 + 1) + " "4C2(-sqrt(133)t3/6 - t3/6 + 1) - 4C1t(sqrt(133)t4/6 - t3/12 + 1) + " "4C1t(-sqrt(133)t3/12 - t3/12 + 1) + O(t*6))/3192), Eq(y(t), -sqrt(133)(-C2(133t8/24 - t3/6 + " "sqrt(133)t3/2 + 1) + C2(-sqrt(133)t3/6 - t3/6 + 1) - C1t(sqrt(133)t4/6 - t3/12 + 1) + " "C1t(-sqrt(133)t3/12 - t3/12 + 1) + O(t6))/266)]") assert str(dsolve(eq8)) == sol8 # FIXME: assert checksysodesol(eq8, sol8) == (True, [0, 0]) eq9 = (Eq(diff(x(t),t,t), t(4diff(x(t),t) + 9diff(y(t),t))), Eq(diff(y(t),t,t), t(12diff(x(t),t) - 6diff(y(t),t)))) sol9 = [Eq(x(t), -sqrt(133)(4C1Integral(exp((-sqrt(133) - 1)Integral(t, t)), t) + 4C2 - \ 4C3Integral(exp((-1 + sqrt(133))Integral(t, t)), t) - 4C4 - (-1 + sqrt(133))(C1Integral(exp((-sqrt(133) - \ 1)Integral(t, t)), t) + C2) + (-sqrt(133) - 1)(C3Integral(exp((-1 + sqrt(133))Integral(t, t)), t) + \ C4))/3192), Eq(y(t), -sqrt(133)(C1Integral(exp((-sqrt(133) - 1)Integral(t, t)), t) + C2 - \ C3Integral(exp((-1 + sqrt(133))Integral(t, t)), t) - C4)/266)] assert dsolve(eq9) == sol9 assert checksysodesol(eq9, sol9) == (True, [0, 0]) eq10 = (t2diff(x(t),t,t) + 3tdiff(x(t),t) + 4tdiff(y(t),t) + 12x(t) + 9y(t), \ t*2diff(y(t),t,t) + 2tdiff(x(t),t) - 5tdiff(y(t),t) + 15x(t) + 8y(t)) sol10 = [Eq(x(t), -C1(-2sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 13 + 2sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + \ 346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))))exp((-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2 + 1 + sqrt(-284/sqrt(-346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)))/2)log(t)) - \ C2(-2sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 13 - 2sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))))exp((-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2 + 1 - sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)log(t)) - C3t(1 + sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2 + sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)(2sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 13 + 2sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))) - C4t*(-sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2 + 1 + sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))/2)(-2sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))) + 2sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 13)), Eq(y(t), C1(-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 14 + (-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2 + 1 + sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)2 + sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))))exp((-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))/2 + 1 + sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)log(t)) + C2(-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 14 - sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))) + (-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))/2 + 1 - sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)2)exp((-sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))/2 + 1 - sqrt(-284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) - 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)log(t)) + C3t(1 + sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + \ 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2 + sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)(sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))) + 14 + (1 + sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3))/2 + sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + 346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)))/2)2) + C4t*(-sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + \ 346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)))/2 + 1 + sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2)(-sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)*(S(1)/3) + \ 8 + 346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))) + (-sqrt(-2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3) + 8 + \ 346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 284/sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)))/2 + 1 + sqrt(-346/(3(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + \ 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3))/2)2 + sqrt(-346/(3(S(4333)/4 + \ 5sqrt(70771857)/36)(S(1)/3)) + 4 + 2(S(4333)/4 + 5sqrt(70771857)/36)(S(1)/3)) + 14))] assert dsolve(eq10) == sol10 # FIXME: assert checksysodesol(eq10, sol10) == (True, [0, 0]) # this hangs or at least takes a while... def test_linear_3eq_order1(): x, y, z = symbols('x, y, z', cls=Function) t = Symbol('t') eq1 = (Eq(diff(x(t),t), 21x(t)), Eq(diff(y(t),t), 17x(t)+3y(t)), Eq(diff(z(t),t), 5x(t)+7y(t)+9z(t))) sol1 = [Eq(x(t), C1exp(21t)), Eq(y(t), 17C1exp(21t)/18 + C2exp(3t)), \ Eq(z(t), 209C1exp(21t)/216 - 7C2exp(3t)/6 + C3exp(9t))] assert checksysodesol(eq1, sol1) == (True, [0, 0, 0]) eq2 = (Eq(diff(x(t),t),3y(t)-11z(t)),Eq(diff(y(t),t),7z(t)-3x(t)),Eq(diff(z(t),t),11x(t)-7y(t))) sol2 = [Eq(x(t), 7C0 + sqrt(179)C1cos(sqrt(179)t) + (77C1/3 + 130C2/3)sin(sqrt(179)t)), \ Eq(y(t), 11C0 + sqrt(179)C2cos(sqrt(179)t) + (-58C1/3 - 77C2/3)sin(sqrt(179)t)), \ Eq(z(t), 3C0 + sqrt(179)(-7C1/3 - 11C2/3)cos(sqrt(179)t) + (11C1 - 7C2)sin(sqrt(179)t))] assert checksysodesol(eq2, sol2) == (True, [0, 0, 0]) eq3 = (Eq(3diff(x(t),t),45(y(t)-z(t))),Eq(4diff(y(t),t),35(z(t)-x(t))),Eq(5diff(z(t),t),34(x(t)-y(t)))) sol3 = [Eq(x(t), C0 + 5sqrt(2)C1cos(5sqrt(2)t) + (12C1/5 + 164C2/15)sin(5sqrt(2)t)), \ Eq(y(t), C0 + 5sqrt(2)C2cos(5sqrt(2)t) + (-51C1/10 - 12C2/5)sin(5sqrt(2)t)), \ Eq(z(t), C0 + 5sqrt(2)(-9C1/25 - 16C2/25)cos(5sqrt(2)t) + (12C1/5 - 12C2/5)sin(5sqrt(2)t))] assert checksysodesol(eq3, sol3) == (True, [0, 0, 0]) f = t3 + log(t) g = t2 + sin(t) eq4 = (Eq(diff(x(t),t),(4f+g)x(t)-fy(t)-2fz(t)), Eq(diff(y(t),t),2fx(t)+(f+g)y(t)-2fz(t)), Eq(diff(z(t),t),5fx(t)+fy(t)+(-3f+g)z(t))) sol4 = [Eq(x(t), (C1exp(-2Integral(t*3 + log(t), t)) + C2(sqrt(3)sin(sqrt(3)Integral(t*3 + log(t), t))/6 \ + cos(sqrt(3)Integral(t*3 + log(t), t))/2) + C3(sin(sqrt(3)Integral(t3 + log(t), t))/2 - \ sqrt(3)cos(sqrt(3)Integral(t3 + log(t), t))/6))exp(Integral(-t*2 - sin(t), t))), Eq(y(t), \ (C2(sqrt(3)sin(sqrt(3)Integral(t*3 + log(t), t))/6 + cos(sqrt(3)Integral(t*3 + log(t), t))/2) + \ C3(sin(sqrt(3)Integral(t3 + log(t), t))/2 - sqrt(3)cos(sqrt(3)Integral(t3 + log(t), t))/6))\ exp(Integral(-t*2 - sin(t), t))), Eq(z(t), (C1exp(-2Integral(t3 + log(t), t)) + C2cos(sqrt(3)\ Integral(t3 + log(t), t)) + C3sin(sqrt(3)Integral(t3 + log(t), t)))exp(Integral(-t*2 - sin(t), t)))] assert dsolve(eq4) == sol4 # FIXME: assert checksysodesol(eq4, sol4) == (True, [0, 0, 0]) # this one fails eq5 = (Eq(diff(x(t),t),4x(t) - z(t)),Eq(diff(y(t),t),2x(t)+2y(t)-z(t)),Eq(diff(z(t),t),3x(t)+y(t))) sol5 = [Eq(x(t), C1exp(2t) + C2texp(2t) + C2exp(2t) + C3t2exp(2t)/2 + C3texp(2t) + C3exp(2t)), \ Eq(y(t), C1exp(2t) + C2texp(2t) + C2exp(2t) + C3t*2exp(2t)/2 + C3texp(2t)), \ Eq(z(t), 2C1exp(2t) + 2C2texp(2t) + C2exp(2t) + C3t*2exp(2t) + C3texp(2t) + C3exp(2t))] assert checksysodesol(eq5, sol5) == (True, [0, 0, 0]) eq6 = (Eq(diff(x(t),t),4x(t) - y(t) - 2z(t)),Eq(diff(y(t),t),2x(t) + y(t)- 2z(t)),Eq(diff(z(t),t),5x(t)-3z(t))) sol6 = [Eq(x(t), C1exp(2t) + C2(-sin(t)/5 + 3cos(t)/5) + C3(3sin(t)/5 + cos(t)/5)), Eq(y(t), C2(-sin(t)/5 + 3cos(t)/5) + C3(3sin(t)/5 + cos(t)/5)), Eq(z(t), C1exp(2t) + C2cos(t) + C3sin(t))] assert checksysodesol(eq5, sol5) == (True, [0, 0, 0]) def test_linear_3eq_order1_nonhomog(): e = [Eq(diff(f(x), x), -9f(x) - 4g(x)), Eq(diff(g(x), x), -4g(x)), Eq(diff(h(x), x), h(x) + exp(x))] raises(NotImplementedError, lambda: dsolve(e)) @XFAIL def test_linear_3eq_order1_diagonal(): # code makes assumptions about coefficients being nonzero, breaks when assumptions are not true e = [Eq(diff(f(x), x), f(x)), Eq(diff(g(x), x), g(x)), Eq(diff(h(x), x), h(x))] s1 = [Eq(f(x), C1exp(x)), Eq(g(x), C2exp(x)), Eq(h(x), C3exp(x))] s = dsolve(e) assert s == s1 assert checksysodesol(e, s1) == (True, [0, 0, 0]) def test_nonlinear_2eq_order1(): x, y, z = symbols('x, y, z', cls=Function) t = Symbol('t') eq1 = (Eq(diff(x(t),t),x(t)y(t)3), Eq(diff(y(t),t),y(t)5)) sol1 = [ Eq(x(t), C1exp((-1/(4C2 + 4t))*(-S(1)/4))), Eq(y(t), -(-1/(4C2 + 4t))(S(1)/4)), Eq(x(t), C1exp(-1/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), (-1/(4C2 + 4t))(S(1)/4)), Eq(x(t), C1exp(-I/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), -I(-1/(4C2 + 4t))*(S(1)/4)), Eq(x(t), C1exp(I/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), I(-1/(4C2 + 4t))*(S(1)/4))] assert dsolve(eq1) == sol1 assert checksysodesol(eq1, sol1) == (True, [0, 0]) eq2 = (Eq(diff(x(t),t), exp(3x(t))y(t)3),Eq(diff(y(t),t), y(t)5)) sol2 = [ Eq(x(t), -log(C1 - 3/(-1/(4C2 + 4t))(S(1)/4))/3), Eq(y(t), -(-1/(4C2 + 4t))(S(1)/4)), Eq(x(t), -log(C1 + 3/(-1/(4C2 + 4t))(S(1)/4))/3), Eq(y(t), (-1/(4C2 + 4t))(S(1)/4)), Eq(x(t), -log(C1 + 3I/(-1/(4C2 + 4t))*(S(1)/4))/3), Eq(y(t), -I(-1/(4C2 + 4t))*(S(1)/4)), Eq(x(t), -log(C1 - 3I/(-1/(4C2 + 4t))*(S(1)/4))/3), Eq(y(t), I(-1/(4C2 + 4t))*(S(1)/4))] assert dsolve(eq2) == sol2 assert checksysodesol(eq2, sol2) == (True, [0, 0]) eq3 = (Eq(diff(x(t),t), y(t)x(t)), Eq(diff(y(t),t), x(t)3)) tt = S(2)/3 sol3 = [ Eq(x(t), 6tt/(6(-sinh(sqrt(C1)(C2 + t)/2)/sqrt(C1))*tt)), Eq(y(t), sqrt(C1 + C1/sinh(sqrt(C1)(C2 + t)/2)*2)/3)] assert dsolve(eq3) == sol3 # FIXME: assert checksysodesol(eq3, sol3) == (True, [0, 0]) eq4 = (Eq(diff(x(t),t),x(t)y(t)sin(t)2), Eq(diff(y(t),t),y(t)2sin(t)*2)) sol4 = set([Eq(x(t), -2exp(C1)/(C2exp(C1) + t - sin(2t)/2)), Eq(y(t), -2/(C1 + t - sin(2t)/2))]) assert dsolve(eq4) == sol4 # FIXME: assert checksysodesol(eq4, sol4) == (True, [0, 0]) eq5 = (Eq(x(t),tdiff(x(t),t)+diff(x(t),t)diff(y(t),t)), Eq(y(t),tdiff(y(t),t)+diff(y(t),t)*2)) sol5 = set([Eq(x(t), C1C2 + C1t), Eq(y(t), C22 + C2t)]) assert dsolve(eq5) == sol5 assert checksysodesol(eq5, sol5) == (True, [0, 0]) eq6 = (Eq(diff(x(t),t),x(t)*2y(t)3), Eq(diff(y(t),t),y(t)5)) sol6 = [ Eq(x(t), 1/(C1 - 1/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), -(-1/(4C2 + 4t))(S(1)/4)), Eq(x(t), 1/(C1 + (-1/(4C2 + 4t))(-S(1)/4))), Eq(y(t), (-1/(4C2 + 4t))(S(1)/4)), Eq(x(t), 1/(C1 + I/(-1/(4C2 + 4t))(S(1)/4))), Eq(y(t), -I(-1/(4C2 + 4t))*(S(1)/4)), Eq(x(t), 1/(C1 - I/(-1/(4C2 + 4t))(S(1)/4))), Eq(y(t), I(-1/(4C2 + 4t))*(S(1)/4))] assert dsolve(eq6) == sol6 assert checksysodesol(eq6, sol6) == (True, [0, 0]) def test_checksysodesol(): x, y, z = symbols('x, y, z', cls=Function) t = Symbol('t') eq = (Eq(diff(x(t),t), 9y(t)), Eq(diff(y(t),t), 12x(t))) sol = [Eq(x(t), 9C1exp(-6sqrt(3)t) + 9C2exp(6sqrt(3)t)), \ Eq(y(t), -6sqrt(3)C1exp(-6sqrt(3)t) + 6sqrt(3)C2exp(6sqrt(3)t))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 2x(t) + 4y(t)), Eq(diff(y(t),t), 12x(t) + 41y(t))) sol = [Eq(x(t), 4C1exp(t(-sqrt(1713)/2 + S(43)/2)) + 4C2exp(t(sqrt(1713)/2 + \ S(43)/2))), Eq(y(t), C1(-sqrt(1713)/2 + S(39)/2)exp(t(-sqrt(1713)/2 + \ S(43)/2)) + C2(S(39)/2 + sqrt(1713)/2)exp(t(sqrt(1713)/2 + S(43)/2)))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), x(t) + y(t)), Eq(diff(y(t),t), -2x(t) + 2y(t))) sol = [Eq(x(t), (C1sin(sqrt(7)t/2) + C2cos(sqrt(7)t/2))exp(3t/2)), \ Eq(y(t), ((C1/2 - sqrt(7)C2/2)sin(sqrt(7)t/2) + (sqrt(7)C1/2 + \ C2/2)cos(sqrt(7)t/2))exp(3t/2))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), x(t) + y(t) + 9), Eq(diff(y(t),t), 2x(t) + 5y(t) + 23)) sol = [Eq(x(t), C1exp(t(-sqrt(6) + 3)) + C2exp(t(sqrt(6) + 3)) - \ S(22)/3), Eq(y(t), C1(-sqrt(6) + 2)exp(t(-sqrt(6) + 3)) + C2(2 + \ sqrt(6))exp(t(sqrt(6) + 3)) - S(5)/3)] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), x(t) + y(t) + 81), Eq(diff(y(t),t), -2x(t) + y(t) + 23)) sol = [Eq(x(t), (C1sin(sqrt(2)t) + C2cos(sqrt(2)t))exp(t) - S(58)/3), \ Eq(y(t), (sqrt(2)C1cos(sqrt(2)t) - sqrt(2)C2sin(sqrt(2)t))exp(t) - S(185)/3)] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 5tx(t) + 2y(t)), Eq(diff(y(t),t), 2x(t) + 5ty(t))) sol = [Eq(x(t), (C1exp((Integral(2, t).doit())) + C2exp(-(Integral(2, t)).doit()))\ exp((Integral(5t, t)).doit())), Eq(y(t), (C1exp((Integral(2, t)).doit()) - \ C2exp(-(Integral(2, t)).doit()))exp((Integral(5t, t)).doit()))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 5tx(t) + t*2y(t)), Eq(diff(y(t),t), -t*2x(t) + 5ty(t))) sol = [Eq(x(t), (C1cos((Integral(t2, t)).doit()) + C2sin((Integral(t*2, t)).doit()))\ exp((Integral(5t, t)).doit())), Eq(y(t), (-C1sin((Integral(t*2, t)).doit()) + \ C2cos((Integral(t*2, t)).doit()))exp((Integral(5t, t)).doit()))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 5tx(t) + t2y(t)), Eq(diff(y(t),t), -t*2x(t) + (5t+9t*2)y(t))) sol = [Eq(x(t), (C1exp((-sqrt(77)/2 + S(9)/2)(Integral(t*2, t)).doit()) + \ C2exp((sqrt(77)/2 + S(9)/2)(Integral(t2, t)).doit()))exp((Integral(5t, t)).doit())), \ Eq(y(t), (C1(-sqrt(77)/2 + S(9)/2)exp((-sqrt(77)/2 + S(9)/2)(Integral(t*2, t)).doit()) + \ C2(sqrt(77)/2 + S(9)/2)exp((sqrt(77)/2 + S(9)/2)(Integral(t*2, t)).doit()))exp((Integral(5t, t)).doit()))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t), 5x(t) + 43y(t)), Eq(diff(y(t),t,t), x(t) + 9y(t))) root0 = -sqrt(-sqrt(47) + 7) root1 = sqrt(-sqrt(47) + 7) root2 = -sqrt(sqrt(47) + 7) root3 = sqrt(sqrt(47) + 7) sol = [Eq(x(t), 43C1exp(troot0) + 43C2exp(troot1) + 43C3exp(troot2) + 43C4exp(troot3)), \ Eq(y(t), C1(root02 - 5)exp(troot0) + C2(root1*2 - 5)exp(troot1) + \ C3(root2*2 - 5)exp(troot2) + C4(root3*2 - 5)exp(troot3))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t), 8x(t)+3y(t)+31), Eq(diff(y(t),t,t), 9x(t)+7y(t)+12)) root0 = -sqrt(-sqrt(109)/2 + S(15)/2) root1 = sqrt(-sqrt(109)/2 + S(15)/2) root2 = -sqrt(sqrt(109)/2 + S(15)/2) root3 = sqrt(sqrt(109)/2 + S(15)/2) sol = [Eq(x(t), 3C1exp(troot0) + 3C2exp(troot1) + 3C3exp(troot2) + 3C4exp(troot3) - S(181)/29), \ Eq(y(t), C1(root0*2 - 8)exp(troot0) + C2(root1*2 - 8)exp(troot1) + \ C3(root2*2 - 8)exp(troot2) + C4(root3*2 - 8)exp(troot3) + S(183)/29)] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t) - 9diff(y(t),t) + 7x(t),0), Eq(diff(y(t),t,t) + 9diff(x(t),t) + 7y(t),0)) sol = [Eq(x(t), C1cos(t(S(9)/2 + sqrt(109)/2)) + C2sin(t(S(9)/2 + sqrt(109)/2)) + \ C3cos(t(-sqrt(109)/2 + S(9)/2)) + C4sin(t(-sqrt(109)/2 + S(9)/2))), Eq(y(t), -C1sin(t(S(9)/2 + sqrt(109)/2)) \ + C2cos(t(S(9)/2 + sqrt(109)/2)) - C3sin(t(-sqrt(109)/2 + S(9)/2)) + C4cos(t(-sqrt(109)/2 + S(9)/2)))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t), 9tdiff(y(t),t)-9y(t)), Eq(diff(y(t),t,t),7tdiff(x(t),t)-7x(t))) I1 = sqrt(6)7*(S(1)/4)sqrt(pi)erfi(sqrt(6)7*(S(1)/4)t/2)/2 - exp(3sqrt(7)t*2/2)/t I2 = -sqrt(6)7*(S(1)/4)sqrt(pi)erf(sqrt(6)7*(S(1)/4)t/2)/2 - exp(-3sqrt(7)t*2/2)/t sol = [Eq(x(t), C3t + t(9C1I1 + 9C2I2)), Eq(y(t), C4t + t(3sqrt(7)C1I1 - 3sqrt(7)C2I2))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 21x(t)), Eq(diff(y(t),t), 17x(t)+3y(t)), Eq(diff(z(t),t), 5x(t)+7y(t)+9z(t))) sol = [Eq(x(t), C1exp(21t)), Eq(y(t), 17C1exp(21t)/18 + C2exp(3t)), \ Eq(z(t), 209C1exp(21t)/216 - 7C2exp(3t)/6 + C3exp(9t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),3y(t)-11z(t)),Eq(diff(y(t),t),7z(t)-3x(t)),Eq(diff(z(t),t),11x(t)-7y(t))) sol = [Eq(x(t), 7C0 + sqrt(179)C1cos(sqrt(179)t) + (77C1/3 + 130C2/3)sin(sqrt(179)t)), \ Eq(y(t), 11C0 + sqrt(179)C2cos(sqrt(179)t) + (-58C1/3 - 77C2/3)sin(sqrt(179)t)), \ Eq(z(t), 3C0 + sqrt(179)(-7C1/3 - 11C2/3)cos(sqrt(179)t) + (11C1 - 7C2)sin(sqrt(179)t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(3diff(x(t),t),45(y(t)-z(t))),Eq(4diff(y(t),t),35(z(t)-x(t))),Eq(5diff(z(t),t),34(x(t)-y(t)))) sol = [Eq(x(t), C0 + 5sqrt(2)C1cos(5sqrt(2)t) + (12C1/5 + 164C2/15)sin(5sqrt(2)t)), \ Eq(y(t), C0 + 5sqrt(2)C2cos(5sqrt(2)t) + (-51C1/10 - 12C2/5)sin(5sqrt(2)t)), \ Eq(z(t), C0 + 5sqrt(2)(-9C1/25 - 16C2/25)cos(5sqrt(2)t) + (12C1/5 - 12C2/5)sin(5sqrt(2)t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),4x(t) - z(t)),Eq(diff(y(t),t),2x(t)+2y(t)-z(t)),Eq(diff(z(t),t),3x(t)+y(t))) sol = [Eq(x(t), C1exp(2t) + C2texp(2t) + C2exp(2t) + C3t2exp(2t)/2 + C3texp(2t) + C3exp(2t)), \ Eq(y(t), C1exp(2t) + C2texp(2t) + C2exp(2t) + C3t*2exp(2t)/2 + C3texp(2t)), \ Eq(z(t), 2C1exp(2t) + 2C2texp(2t) + C2exp(2t) + C3t*2exp(2t) + C3texp(2t) + C3exp(2t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),4x(t) - y(t) - 2z(t)),Eq(diff(y(t),t),2x(t) + y(t)- 2z(t)),Eq(diff(z(t),t),5x(t)-3z(t))) sol = [Eq(x(t), C1exp(2t) + C2(-sin(t) + 3cos(t)) + C3(3sin(t) + cos(t))), \ Eq(y(t), C2(-sin(t) + 3cos(t)) + C3(3sin(t) + cos(t))), Eq(z(t), C1exp(2t) + 5C2cos(t) + 5C3sin(t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),x(t)y(t)3), Eq(diff(y(t),t),y(t)5)) sol = [Eq(x(t), C1exp((-1/(4C2 + 4t))*(-S(1)/4))), Eq(y(t), -(-1/(4C2 + 4t))(S(1)/4)), \ Eq(x(t), C1exp(-1/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), (-1/(4C2 + 4t))(S(1)/4)), \ Eq(x(t), C1exp(-I/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), -I(-1/(4C2 + 4t))*(S(1)/4)), \ Eq(x(t), C1exp(I/(-1/(4C2 + 4t))*(S(1)/4))), Eq(y(t), I(-1/(4C2 + 4t))*(S(1)/4))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), exp(3x(t))y(t)3),Eq(diff(y(t),t), y(t)5)) sol = [Eq(x(t), -log(C1 - 3/(-1/(4C2 + 4t))(S(1)/4))/3), Eq(y(t), -(-1/(4C2 + 4t))(S(1)/4)), \ Eq(x(t), -log(C1 + 3/(-1/(4C2 + 4t))(S(1)/4))/3), Eq(y(t), (-1/(4C2 + 4t))(S(1)/4)), \ Eq(x(t), -log(C1 + 3I/(-1/(4C2 + 4t))*(S(1)/4))/3), Eq(y(t), -I(-1/(4C2 + 4t))*(S(1)/4)), \ Eq(x(t), -log(C1 - 3I/(-1/(4C2 + 4t))*(S(1)/4))/3), Eq(y(t), I(-1/(4C2 + 4t))*(S(1)/4))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(x(t),tdiff(x(t),t)+diff(x(t),t)diff(y(t),t)), Eq(y(t),tdiff(y(t),t)+diff(y(t),t)*2)) sol = set([Eq(x(t), C1C2 + C1t), Eq(y(t), C22 + C2t)]) assert checksysodesol(eq, sol) == (True, [0, 0]) @slow def test_nonlinear_3eq_order1(): x, y, z = symbols('x, y, z', cls=Function) t, u = symbols('t u') eq1 = (4diff(x(t),t) + 2y(t)z(t), 3diff(y(t),t) - z(t)x(t), 5diff(z(t),t) - x(t)y(t)) sol1 = [Eq(4Integral(1/(sqrt(-4u2 - 3C1 + C2)sqrt(-4u*2 + 5C1 - C2)), (u, x(t))), C3 - sqrt(15)t/15), Eq(3Integral(1/(sqrt(-6u2 - C1 + 5C2)sqrt(3u*2 + C1 - 4C2)), (u, y(t))), C3 + sqrt(5)t/10), Eq(5Integral(1/(sqrt(-10u2 - 3C1 + C2)* sqrt(5u2 + 4C1 - C2)), (u, z(t))), C3 + sqrt(3)t/6)] assert [i.dummy_eq(j) for i, j in zip(dsolve(eq1), sol1)] # FIXME: assert checksysodesol(eq1, sol1) == (True, [0, 0, 0]) eq2 = (4diff(x(t),t) + 2y(t)z(t)sin(t), 3diff(y(t),t) - z(t)x(t)sin(t), 5diff(z(t),t) - x(t)y(t)sin(t)) sol2 = [Eq(3Integral(1/(sqrt(-6u2 - C1 + 5C2)sqrt(3u*2 + C1 - 4C2)), (u, x(t))), C3 + sqrt(5)cos(t)/10), Eq(4Integral(1/(sqrt(-4u2 - 3C1 + C2)sqrt(-4u*2 + 5C1 - C2)), (u, y(t))), C3 - sqrt(15)cos(t)/15), Eq(5Integral(1/(sqrt(-10u2 - 3C1 + C2)* sqrt(5u2 + 4C1 - C2)), (u, z(t))), C3 + sqrt(3)cos(t)/6)] assert [i.dummy_eq(j) for i, j in zip(dsolve(eq2), sol2)] # FIXME: assert checksysodesol(eq2, sol2) == (True, [0, 0, 0]) @slow def test_checkodesol(): from sympy import Ei # For the most part, checkodesol is well tested in the tests below. # These tests only handle cases not checked below. raises(ValueError, lambda: checkodesol(f(x, y).diff(x), Eq(f(x, y), x))) raises(ValueError, lambda: checkodesol(f(x).diff(x), Eq(f(x, y), x), f(x, y))) assert checkodesol(f(x).diff(x), Eq(f(x, y), x)) == \ (False, -f(x).diff(x) + f(x, y).diff(x) - 1) assert checkodesol(f(x).diff(x), Eq(f(x), x)) is not True assert checkodesol(f(x).diff(x), Eq(f(x), x)) == (False, 1) sol1 = Eq(f(x)5 + 11f(x) - 2f(x) + x, 0) assert checkodesol(diff(sol1.lhs, x), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x)exp(f(x)), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 2), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 2)exp(f(x)), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 3), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 3)exp(f(x)), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 3), Eq(f(x), xlog(x))) == \ (False, 60x*4((log(x) + 1)*2 + log(x))( log(x) + 1)log(x)2 - 5x*4log(x)*4 - 9) assert checkodesol(diff(exp(f(x)) + x, x)x, Eq(exp(f(x)) + x, 0)) == \ (True, 0) assert checkodesol(diff(exp(f(x)) + x, x)x, Eq(exp(f(x)) + x, 0), solve_for_func=False) == (True, 0) assert checkodesol(f(x).diff(x, 2), [Eq(f(x), C1 + C2x), Eq(f(x), C2 + C1x), Eq(f(x), C1x + C2x2)]) == \ [(True, 0), (True, 0), (False, C2)] assert checkodesol(f(x).diff(x, 2), set([Eq(f(x), C1 + C2x), Eq(f(x), C2 + C1x), Eq(f(x), C1x + C2x2)])) == \ set([(True, 0), (True, 0), (False, C2)]) assert checkodesol(f(x).diff(x) - 1/f(x)/2, Eq(f(x)2, x)) == \ [(True, 0), (True, 0)] assert checkodesol(f(x).diff(x) - f(x), Eq(C1exp(x), f(x))) == (True, 0) # Based on test_1st_homogeneous_coeff_ode2_eq3sol. Make sure that # checkodesol tries back substituting f(x) when it can. eq3 = xexp(f(x)/x) + f(x) - xf(x).diff(x) sol3 = Eq(f(x), log(log(C1/x)*(-x))) assert not checkodesol(eq3, sol3)[1].has(f(x)) # This case was failing intermittently depending on hash-seed: eqn = Eq(Derivative(xDerivative(f(x), x), x)/x, exp(x)) sol = Eq(f(x), C1 + C2log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] @slow def test_dsolve_options(): eq = xf(x).diff(x) + f(x) a = dsolve(eq, hint='all') b = dsolve(eq, hint='all', simplify=False) c = dsolve(eq, hint='all_Integral') keys = ['1st_exact', '1st_exact_Integral', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_homogeneous_coeff_subs_dep_div_indep_Integral', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_linear', '1st_linear_Integral', 'almost_linear', 'almost_linear_Integral', 'best', 'best_hint', 'default', 'lie_group', 'nth_linear_euler_eq_homogeneous', 'order', 'separable', 'separable_Integral'] Integral_keys = ['1st_exact_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_linear_Integral', 'almost_linear_Integral', 'best', 'best_hint', 'default', 'nth_linear_euler_eq_homogeneous', 'order', 'separable_Integral'] assert sorted(a.keys()) == keys assert a['order'] == ode_order(eq, f(x)) assert a['best'] == Eq(f(x), C1/x) assert dsolve(eq, hint='best') == Eq(f(x), C1/x) assert a['default'] == 'separable' assert a['best_hint'] == 'separable' assert not a['1st_exact'].has(Integral) assert not a['separable'].has(Integral) assert not a['1st_homogeneous_coeff_best'].has(Integral) assert not a['1st_homogeneous_coeff_subs_dep_div_indep'].has(Integral) assert not a['1st_homogeneous_coeff_subs_indep_div_dep'].has(Integral) assert not a['1st_linear'].has(Integral) assert a['1st_linear_Integral'].has(Integral) assert a['1st_exact_Integral'].has(Integral) assert a['1st_homogeneous_coeff_subs_dep_div_indep_Integral'].has(Integral) assert a['1st_homogeneous_coeff_subs_indep_div_dep_Integral'].has(Integral) assert a['separable_Integral'].has(Integral) assert sorted(b.keys()) == keys assert b['order'] == ode_order(eq, f(x)) assert b['best'] == Eq(f(x), C1/x) assert dsolve(eq, hint='best', simplify=False) == Eq(f(x), C1/x) assert b['default'] == 'separable' assert b['best_hint'] == '1st_linear' assert a['separable'] != b['separable'] assert a['1st_homogeneous_coeff_subs_dep_div_indep'] != \ b['1st_homogeneous_coeff_subs_dep_div_indep'] assert a['1st_homogeneous_coeff_subs_indep_div_dep'] != \ b['1st_homogeneous_coeff_subs_indep_div_dep'] assert not b['1st_exact'].has(Integral) assert not b['separable'].has(Integral) assert not b['1st_homogeneous_coeff_best'].has(Integral) assert not b['1st_homogeneous_coeff_subs_dep_div_indep'].has(Integral) assert not b['1st_homogeneous_coeff_subs_indep_div_dep'].has(Integral) assert not b['1st_linear'].has(Integral) assert b['1st_linear_Integral'].has(Integral) assert b['1st_exact_Integral'].has(Integral) assert b['1st_homogeneous_coeff_subs_dep_div_indep_Integral'].has(Integral) assert b['1st_homogeneous_coeff_subs_indep_div_dep_Integral'].has(Integral) assert b['separable_Integral'].has(Integral) assert sorted(c.keys()) == Integral_keys raises(ValueError, lambda: dsolve(eq, hint='notarealhint')) raises(ValueError, lambda: dsolve(eq, hint='Liouville')) assert dsolve(f(x).diff(x) - 1/f(x)2, hint='all')['best'] == \ dsolve(f(x).diff(x) - 1/f(x)2, hint='best') assert dsolve(f(x) + f(x).diff(x) + sin(x).diff(x) + 1, f(x), hint="1st_linear_Integral") == \ Eq(f(x), (C1 + Integral((-sin(x).diff(x) - 1)* exp(Integral(1, x)), x))exp(-Integral(1, x))) def test_classify_ode(): assert classify_ode(f(x).diff(x, 2), f(x)) == \ ( 'nth_algebraic', 'nth_linear_constant_coeff_homogeneous', 'nth_linear_euler_eq_homogeneous', 'Liouville', '2nd_power_series_ordinary', 'nth_algebraic_Integral', 'Liouville_Integral', ) assert classify_ode(f(x), f(x)) == () assert classify_ode(Eq(f(x).diff(x), 0), f(x)) == ( 'nth_algebraic', 'separable', '1st_linear', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_homogeneous', 'nth_linear_euler_eq_homogeneous', 'nth_algebraic_Integral', 'separable_Integral', '1st_linear_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral') assert classify_ode(f(x).diff(x)2, f(x)) == ( 'nth_algebraic', 'lie_group', 'nth_algebraic_Integral') # issue 4749: f(x) should be cleared from highest derivative before classifying a = classify_ode(Eq(f(x).diff(x) + f(x), x), f(x)) b = classify_ode(f(x).diff(x)f(x) + f(x)f(x) - xf(x), f(x)) c = classify_ode(f(x).diff(x)/f(x) + f(x)/f(x) - x/f(x), f(x)) assert a == ('1st_linear', 'Bernoulli', 'almost_linear', '1st_power_series', "lie_group", 'nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', '1st_linear_Integral', 'Bernoulli_Integral', 'almost_linear_Integral', 'nth_linear_constant_coeff_variation_of_parameters_Integral') assert b == c != () assert classify_ode( 2xf(x)f(x).diff(x) + (1 + x)f(x)*2 - exp(x), f(x) ) == ('Bernoulli', 'almost_linear', 'lie_group', 'Bernoulli_Integral', 'almost_linear_Integral') assert 'Riccati_special_minus2' in \ classify_ode(2f(x).diff(x) + f(x)*2 - f(x)/x + 3x*(-2), f(x)) raises(ValueError, lambda: classify_ode(x + f(x, y).diff(x).diff( y), f(x, y))) # issue 5176 k = Symbol('k') assert classify_ode(f(x).diff(x)/(kf(x) + kxf(x)) + 2f(x)/(kf(x) + kxf(x)) + xf(x).diff(x)/(kf(x) + kxf(x)) + z, f(x)) == \ ('separable', '1st_exact', '1st_power_series', 'lie_group', 'separable_Integral', '1st_exact_Integral') # preprocessing ans = ('nth_algebraic', 'separable', '1st_exact', '1st_linear', 'Bernoulli', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', 'nth_linear_euler_eq_nonhomogeneous_variation_of_parameters', 'nth_algebraic_Integral', 'separable_Integral', '1st_exact_Integral', '1st_linear_Integral', 'Bernoulli_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral', 'nth_linear_constant_coeff_variation_of_parameters_Integral', 'nth_linear_euler_eq_nonhomogeneous_variation_of_parameters_Integral') # w/o f(x) given assert classify_ode(diff(f(x) + x, x) + diff(f(x), x)) == ans # w/ f(x) and prep=True assert classify_ode(diff(f(x) + x, x) + diff(f(x), x), f(x), prep=True) == ans assert classify_ode(Eq(2x3f(x).diff(x), 0), f(x)) == \ ('nth_algebraic', 'separable', '1st_linear', '1st_power_series', 'lie_group', 'nth_linear_euler_eq_homogeneous', 'nth_algebraic_Integral', 'separable_Integral', '1st_linear_Integral') assert classify_ode(Eq(2f(x)3f(x).diff(x), 0), f(x)) == \ ('nth_algebraic', 'separable', '1st_power_series', 'lie_group', 'nth_algebraic_Integral', 'separable_Integral') # test issue 13864 assert classify_ode(Eq(diff(f(x), x) - f(x)*x, 0), f(x)) == \ ('1st_power_series', 'lie_group') assert isinstance(classify_ode(Eq(f(x), 5), f(x), dict=True), dict) def test_classify_ode_ics(): # Dummy eq = f(x).diff(x, x) - f(x) # Not f(0) or f'(0) ics = {x: 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) ############################ # f(0) type (AppliedUndef) # ############################ # Wrong function ics = {g(0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Contains x ics = {f(x): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Too many args ics = {f(0, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # point contains f # XXX: Should be NotImplementedError ics = {f(0): f(1)} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Does not raise ics = {f(0): 1} classify_ode(eq, f(x), ics=ics) ##################### # f'(0) type (Subs) # ##################### # Wrong function ics = {g(x).diff(x).subs(x, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Contains x ics = {f(y).diff(y).subs(y, x): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Wrong variable ics = {f(y).diff(y).subs(y, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Too many args ics = {f(x, y).diff(x).subs(x, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Derivative wrt wrong vars ics = {Derivative(f(x), x, y).subs(x, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # point contains f # XXX: Should be NotImplementedError ics = {f(x).diff(x).subs(x, 0): f(0)} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Does not raise ics = {f(x).diff(x).subs(x, 0): 1} classify_ode(eq, f(x), ics=ics) ########################### # f'(y) type (Derivative) # ########################### # Wrong function ics = {g(x).diff(x).subs(x, y): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Contains x ics = {f(y).diff(y).subs(y, x): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Too many args ics = {f(x, y).diff(x).subs(x, y): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Derivative wrt wrong vars ics = {Derivative(f(x), x, z).subs(x, y): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # point contains f # XXX: Should be NotImplementedError ics = {f(x).diff(x).subs(x, y): f(0)} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Does not raise ics = {f(x).diff(x).subs(x, y): 1} classify_ode(eq, f(x), ics=ics) def test_classify_sysode(): # Here x is assumed to be x(t) and y as y(t) for simplicity. # Similarly diff(x,t) and diff(y,y) is assumed to be x1 and y1 respectively. k, l, m, n = symbols('k, l, m, n', Integer=True) k1, k2, k3, l1, l2, l3, m1, m2, m3 = symbols('k1, k2, k3, l1, l2, l3, m1, m2, m3', Integer=True) P, Q, R, p, q, r = symbols('P, Q, R, p, q, r', cls=Function) P1, P2, P3, Q1, Q2, R1, R2 = symbols('P1, P2, P3, Q1, Q2, R1, R2', cls=Function) x, y, z = symbols('x, y, z', cls=Function) t = symbols('t') x1 = diff(x(t),t) ; y1 = diff(y(t),t) ; z1 = diff(z(t),t) x2 = diff(x(t),t,t) ; y2 = diff(y(t),t,t) ; z2 = diff(z(t),t,t) eq1 = (Eq(diff(x(t),t), 5tx(t) + 2y(t)), Eq(diff(y(t),t), 2x(t) + 5ty(t))) sol1 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -5t, (1, x(t), 1): 0, (0, x(t), 1): 1, \ (1, y(t), 0): -5t, (1, x(t), 0): -2, (0, y(t), 1): 0, (0, y(t), 0): -2, (1, y(t), 1): 1}, \ 'type_of_equation': 'type3', 'func': [x(t), y(t)], 'is_linear': True, 'eq': [-5tx(t) - 2y(t) + \ Derivative(x(t), t), -5ty(t) - 2x(t) + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq1) == sol1 eq2 = (Eq(x2, kx(t) - ly1), Eq(y2, lx1 + ky(t))) sol2 = {'order': {y(t): 2, x(t): 2}, 'type_of_equation': 'type3', 'is_linear': True, 'eq': \ [-kx(t) + lDerivative(y(t), t) + Derivative(x(t), t, t), -ky(t) - lDerivative(x(t), t) + \ Derivative(y(t), t, t)], 'no_of_equation': 2, 'func_coeff': {(0, y(t), 0): 0, (0, x(t), 2): 1, \ (1, y(t), 1): 0, (1, y(t), 2): 1, (1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): -k, (1, x(t), 1): \ -l, (0, x(t), 1): 0, (0, y(t), 1): l, (1, x(t), 0): 0, (1, y(t), 0): -k}, 'func': [x(t), y(t)]} assert classify_sysode(eq2) == sol2 eq3 = (Eq(x2+4x1+3y1+9x(t)+7y(t), 11exp(It)), Eq(y2+5x1+8y1+3x(t)+12y(t), 2exp(It))) sol3 = {'no_of_equation': 2, 'func_coeff': {(1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): 9, \ (1, x(t), 1): 5, (0, x(t), 1): 4, (0, y(t), 1): 3, (1, x(t), 0): 3, (1, y(t), 0): 12, (0, y(t), 0): 7, \ (0, x(t), 2): 1, (1, y(t), 2): 1, (1, y(t), 1): 8}, 'type_of_equation': 'type4', 'func': [x(t), y(t)], \ 'is_linear': True, 'eq': [9x(t) + 7y(t) - 11exp(It) + 4Derivative(x(t), t) + 3Derivative(y(t), t) + \ Derivative(x(t), t, t), 3x(t) + 12y(t) - 2exp(It) + 5Derivative(x(t), t) + 8Derivative(y(t), t) + \ Derivative(y(t), t, t)], 'order': {y(t): 2, x(t): 2}} assert classify_sysode(eq3) == sol3 eq4 = (Eq((4t*2 + 7t + 1)*2x2, 5x(t) + 35y(t)), Eq((4t2 + 7t + 1)*2y2, x(t) + 9y(t))) sol4 = {'no_of_equation': 2, 'func_coeff': {(1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): -5, \ (1, x(t), 1): 0, (0, x(t), 1): 0, (0, y(t), 1): 0, (1, x(t), 0): -1, (1, y(t), 0): -9, (0, y(t), 0): -35, \ (0, x(t), 2): 16t*4 + 56t*3 + 57t*2 + 14t + 1, (1, y(t), 2): 16t4 + 56t*3 + 57t*2 + 14t + 1, \ (1, y(t), 1): 0}, 'type_of_equation': 'type10', 'func': [x(t), y(t)], 'is_linear': True, \ 'eq': [(4t2 + 7t + 1)*2Derivative(x(t), t, t) - 5x(t) - 35y(t), (4t2 + 7t + 1)*2Derivative(y(t), t, t)\ - x(t) - 9y(t)], 'order': {y(t): 2, x(t): 2}} assert classify_sysode(eq4) == sol4 eq5 = (Eq(diff(x(t),t), x(t) + y(t) + 9), Eq(diff(y(t),t), 2x(t) + 5y(t) + 23)) sol5 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -1, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): -5, \ (1, x(t), 0): -2, (0, y(t), 1): 0, (0, y(t), 0): -1, (1, y(t), 1): 1}, 'type_of_equation': 'type2', \ 'func': [x(t), y(t)], 'is_linear': True, 'eq': [-x(t) - y(t) + Derivative(x(t), t) - 9, -2x(t) - 5y(t) + \ Derivative(y(t), t) - 23], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq5) == sol5 eq6 = (Eq(x1, exp(kx(t))P(x(t),y(t))), Eq(y1,r(y(t))P(x(t),y(t)))) sol6 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): 0, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): 0, \ (1, x(t), 0): 0, (0, y(t), 1): 0, (0, y(t), 0): 0, (1, y(t), 1): 1}, 'type_of_equation': 'type2', 'func': \ [x(t), y(t)], 'is_linear': False, 'eq': [-P(x(t), y(t))exp(kx(t)) + Derivative(x(t), t), -P(x(t), \ y(t))r(y(t)) + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq6) == sol6 eq7 = (Eq(x1, x(t)2+y(t)/x(t)), Eq(y1, x(t)/y(t))) sol7 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): 0, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): 0, \ (1, x(t), 0): -1/y(t), (0, y(t), 1): 0, (0, y(t), 0): -1/x(t), (1, y(t), 1): 1}, 'type_of_equation': 'type3', \ 'func': [x(t), y(t)], 'is_linear': False, 'eq': [-x(t)2 + Derivative(x(t), t) - y(t)/x(t), -x(t)/y(t) + \ Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq7) == sol7 eq8 = (Eq(x1, P1(x(t))Q1(y(t))R(x(t),y(t),t)), Eq(y1, P1(x(t))Q1(y(t))R(x(t),y(t),t))) sol8 = {'func': [x(t), y(t)], 'is_linear': False, 'type_of_equation': 'type4', 'eq': \ [-P1(x(t))Q1(y(t))R(x(t), y(t), t) + Derivative(x(t), t), -P1(x(t))Q1(y(t))R(x(t), y(t), t) + \ Derivative(y(t), t)], 'func_coeff': {(0, y(t), 1): 0, (1, y(t), 1): 1, (1, x(t), 1): 0, (0, y(t), 0): 0, \ (1, x(t), 0): 0, (0, x(t), 0): 0, (1, y(t), 0): 0, (0, x(t), 1): 1}, 'order': {y(t): 1, x(t): 1}, 'no_of_equation': 2} assert classify_sysode(eq8) == sol8 eq9 = (Eq(x1,3y(t)-11z(t)),Eq(y1,7z(t)-3x(t)),Eq(z1,11x(t)-7y(t))) sol9 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): 0, (2, y(t), 1): 0, (2, z(t), 1): 1, \ (0, x(t), 0): 0, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): 7, (0, x(t), 1): 1, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): 3, (0, z(t), 0): 11, (0, y(t), 0): -3, (1, z(t), 0): -7, (0, z(t), 1): 0, \ (2, x(t), 0): -11, (2, z(t), 0): 0, (1, y(t), 1): 1}, 'type_of_equation': 'type2', 'func': [x(t), y(t), z(t)], \ 'is_linear': True, 'eq': [-3y(t) + 11z(t) + Derivative(x(t), t), 3x(t) - 7z(t) + Derivative(y(t), t), \ -11x(t) + 7y(t) + Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq9) == sol9 eq10 = (x2 + log(t)(tx1 - x(t)) + exp(t)(ty1 - y(t)), y2 + (t2)(tx1 - x(t)) + (t)(ty1 - y(t))) sol10 = {'no_of_equation': 2, 'func_coeff': {(1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): -log(t), \ (1, x(t), 1): t3, (0, x(t), 1): tlog(t), (0, y(t), 1): texp(t), (1, x(t), 0): -t2, (1, y(t), 0): -t, \ (0, y(t), 0): -exp(t), (0, x(t), 2): 1, (1, y(t), 2): 1, (1, y(t), 1): t2}, 'type_of_equation': 'type11', \ 'func': [x(t), y(t)], 'is_linear': True, 'eq': [(tDerivative(x(t), t) - x(t))log(t) + (tDerivative(y(t), t) - \ y(t))exp(t) + Derivative(x(t), t, t), t2(tDerivative(x(t), t) - x(t)) + t(tDerivative(y(t), t) - y(t)) \ + Derivative(y(t), t, t)], 'order': {y(t): 2, x(t): 2}} assert classify_sysode(eq10) == sol10 eq11 = (Eq(x1,x(t)y(t)3), Eq(y1,y(t)5)) sol11 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -y(t)*3, (1, x(t), 1): 0, (0, x(t), 1): 1, \ (1, y(t), 0): 0, (1, x(t), 0): 0, (0, y(t), 1): 0, (0, y(t), 0): 0, (1, y(t), 1): 1}, 'type_of_equation': \ 'type1', 'func': [x(t), y(t)], 'is_linear': False, 'eq': [-x(t)y(t)3 + Derivative(x(t), t), \ -y(t)5 + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq11) == sol11 eq12 = (Eq(x1, y(t)), Eq(y1, x(t))) sol12 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): 0, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): 0, \ (1, x(t), 0): -1, (0, y(t), 1): 0, (0, y(t), 0): -1, (1, y(t), 1): 1}, 'type_of_equation': 'type1', 'func': \ [x(t), y(t)], 'is_linear': True, 'eq': [-y(t) + Derivative(x(t), t), -x(t) + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq12) == sol12 eq13 = (Eq(x1,x(t)y(t)sin(t)2), Eq(y1,y(t)2sin(t)2)) sol13 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -y(t)sin(t)*2, (1, x(t), 1): 0, (0, x(t), 1): 1, \ (1, y(t), 0): 0, (1, x(t), 0): 0, (0, y(t), 1): 0, (0, y(t), 0): -x(t)sin(t)*2, (1, y(t), 1): 1}, \ 'type_of_equation': 'type4', 'func': [x(t), y(t)], 'is_linear': False, 'eq': [-x(t)y(t)sin(t)2 + \ Derivative(x(t), t), -y(t)2sin(t)*2 + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq13) == sol13 eq14 = (Eq(x1, 21x(t)), Eq(y1, 17x(t)+3y(t)), Eq(z1, 5x(t)+7y(t)+9z(t))) sol14 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): -3, (2, y(t), 1): 0, (2, z(t), 1): 1, \ (0, x(t), 0): -21, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): -7, (0, x(t), 1): 1, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): -17, (0, z(t), 0): 0, (0, y(t), 0): 0, (1, z(t), 0): 0, (0, z(t), 1): 0, \ (2, x(t), 0): -5, (2, z(t), 0): -9, (1, y(t), 1): 1}, 'type_of_equation': 'type1', 'func': [x(t), y(t), z(t)], \ 'is_linear': True, 'eq': [-21x(t) + Derivative(x(t), t), -17x(t) - 3y(t) + Derivative(y(t), t), -5x(t) - \ 7y(t) - 9z(t) + Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq14) == sol14 eq15 = (Eq(x1,4x(t)+5y(t)+2z(t)),Eq(y1,x(t)+13y(t)+9z(t)),Eq(z1,32x(t)+41y(t)+11z(t))) sol15 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): -13, (2, y(t), 1): 0, (2, z(t), 1): 1, \ (0, x(t), 0): -4, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): -41, (0, x(t), 1): 1, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): -1, (0, z(t), 0): -2, (0, y(t), 0): -5, (1, z(t), 0): -9, (0, z(t), 1): 0, \ (2, x(t), 0): -32, (2, z(t), 0): -11, (1, y(t), 1): 1}, 'type_of_equation': 'type6', 'func': \ [x(t), y(t), z(t)], 'is_linear': True, 'eq': [-4x(t) - 5y(t) - 2z(t) + Derivative(x(t), t), -x(t) - 13y(t) - \ 9z(t) + Derivative(y(t), t), -32x(t) - 41y(t) - 11z(t) + Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq15) == sol15 eq16 = (Eq(3x1,45(y(t)-z(t))),Eq(4y1,35(z(t)-x(t))),Eq(5z1,34(x(t)-y(t)))) sol16 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): 0, (2, y(t), 1): 0, (2, z(t), 1): 5, \ (0, x(t), 0): 0, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): 12, (0, x(t), 1): 3, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): 15, (0, z(t), 0): 20, (0, y(t), 0): -20, (1, z(t), 0): -15, (0, z(t), 1): 0, \ (2, x(t), 0): -12, (2, z(t), 0): 0, (1, y(t), 1): 4}, 'type_of_equation': 'type3', 'func': [x(t), y(t), z(t)], \ 'is_linear': True, 'eq': [-20y(t) + 20z(t) + 3Derivative(x(t), t), 15x(t) - 15z(t) + 4Derivative(y(t), t), \ -12x(t) + 12y(t) + 5Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq16) == sol16 # issue 8193: funcs parameter for classify_sysode has to actually work assert classify_sysode(eq1, funcs=[x(t), y(t)]) == sol1 def test_solve_ics(): # Basic tests that things work from dsolve. assert dsolve(f(x).diff(x) - 1/f(x), f(x), ics={f(1): 2}) == \ Eq(f(x), sqrt(2 x + 2)) assert dsolve(f(x).diff(x) - f(x), f(x), ics={f(0): 1}) == Eq(f(x), exp(x)) assert dsolve(f(x).diff(x) - f(x), f(x), ics={f(x).diff(x).subs(x, 0): 1}) == Eq(f(x), exp(x)) assert dsolve(f(x).diff(x, x) + f(x), f(x), ics={f(0): 1, f(x).diff(x).subs(x, 0): 1}) == Eq(f(x), sin(x) + cos(x)) assert dsolve([f(x).diff(x) - f(x) + g(x), g(x).diff(x) - g(x) - f(x)], [f(x), g(x)], ics={f(0): 1, g(0): 0}) == [Eq(f(x), exp(x)cos(x)), Eq(g(x), exp(x)sin(x))] # Test cases where dsolve returns two solutions. eq = (x*2f(x)*2 - x).diff(x) assert dsolve(eq, f(x), ics={f(1): 0}) == [Eq(f(x), -sqrt(x - 1)/x), Eq(f(x), sqrt(x - 1)/x)] assert dsolve(eq, f(x), ics={f(x).diff(x).subs(x, 1): 0}) == [Eq(f(x), -sqrt(x - S(1)/2)/x), Eq(f(x), sqrt(x - S(1)/2)/x)] eq = cos(f(x)) - (xsin(f(x)) - f(x)*2)f(x).diff(x) assert dsolve(eq, f(x), ics={f(0):1}, hint='1st_exact', simplify=False) == Eq(xcos(f(x)) + f(x)3/3, S(1)/3) assert dsolve(eq, f(x), ics={f(0):1}, hint='1st_exact', simplify=True) == Eq(xcos(f(x)) + f(x)*3/3, S(1)/3) assert solve_ics([Eq(f(x), C1exp(x))], [f(x)], [C1], {f(0): 1}) == {C1: 1} assert solve_ics([Eq(f(x), C1sin(x) + C2cos(x))], [f(x)], [C1, C2], {f(0): 1, f(pi/2): 1}) == {C1: 1, C2: 1} assert solve_ics([Eq(f(x), C1sin(x) + C2cos(x))], [f(x)], [C1, C2], {f(0): 1, f(x).diff(x).subs(x, 0): 1}) == {C1: 1, C2: 1} assert solve_ics([Eq(f(x), C1sin(x) + C2cos(x))], [f(x)], [C1, C2], {f(0): 1}) == \ {C2: 1} # Some more complicated tests Refer to PR #16098 assert dsolve(f(x).diff(x)(f(x).diff(x, 2)-x), ics={f(0):0, f(x).diff(x).subs(x, 1):0}) == \ [Eq(f(x), 0), Eq(f(x), x * 3 / 6 - x / 2)] assert dsolve(f(x).diff(x)(f(x).diff(x, 2)-x), ics={f(0):0}) == \ [Eq(f(x), 0), Eq(f(x), C2x + x*3/6)] K, r, f0 = symbols('K r f0') sol = Eq(f(x), -Kf0exp(rx)/((K - f0)(-f0exp(rx)/(K - f0) - 1))) assert (dsolve(Eq(f(x).diff(x), r f(x) * (1 - f(x) / K)), f(x), ics={f(0): f0})) == sol #Order dependent issues Refer to PR #16098 assert dsolve(f(x).diff(x)(f(x).diff(x, 2)-x), ics={f(x).diff(x).subs(x,0):0, f(0):0}) == \ [Eq(f(x), 0), Eq(f(x), x * 3 / 6)] assert dsolve(f(x).diff(x)(f(x).diff(x, 2)-x), ics={f(0):0, f(x).diff(x).subs(x,0):0}) == \ [Eq(f(x), 0), Eq(f(x), x * 3 / 6)] # XXX: Ought to be ValueError raises(ValueError, lambda: solve_ics([Eq(f(x), C1sin(x) + C2cos(x))], [f(x)], [C1, C2], {f(0): 1, f(pi): 1})) # Degenerate case. f'(0) is identically 0. raises(ValueError, lambda: solve_ics([Eq(f(x), sqrt(C1 - x*2))], [f(x)], [C1], {f(x).diff(x).subs(x, 0): 0})) EI, q, L = symbols('EI q L') # eq = Eq(EIdiff(f(x), x, 4), q) sols = [Eq(f(x), C1 + C2x + C3x*2 + C4x*3 + qx*4/(24EI))] funcs = [f(x)] constants = [C1, C2, C3, C4] # Test both cases, Derivative (the default from f(x).diff(x).subs(x, L)), # and Subs ics1 = {f(0): 0, f(x).diff(x).subs(x, 0): 0, f(L).diff(L, 2): 0, f(L).diff(L, 3): 0} ics2 = {f(0): 0, f(x).diff(x).subs(x, 0): 0, Subs(f(x).diff(x, 2), x, L): 0, Subs(f(x).diff(x, 3), x, L): 0} solved_constants1 = solve_ics(sols, funcs, constants, ics1) solved_constants2 = solve_ics(sols, funcs, constants, ics2) assert solved_constants1 == solved_constants2 == { C1: 0, C2: 0, C3: L*2q/(4EI), C4: -Lq/(6EI)} def test_ode_order(): f = Function('f') g = Function('g') x = Symbol('x') assert ode_order(3xexp(f(x)), f(x)) == 0 assert ode_order(xdiff(f(x), x) + 3xf(x) - sin(x)/x, f(x)) == 1 assert ode_order(x*2f(x).diff(x, x) + xdiff(f(x), x) - f(x), f(x)) == 2 assert ode_order(diff(xexp(f(x)), x, x), f(x)) == 2 assert ode_order(diff(xdiff(xexp(f(x)), x, x), x), f(x)) == 3 assert ode_order(diff(f(x), x, x), g(x)) == 0 assert ode_order(diff(f(x), x, x)diff(g(x), x), f(x)) == 2 assert ode_order(diff(f(x), x, x)diff(g(x), x), g(x)) == 1 assert ode_order(diff(xdiff(xexp(f(x)), x, x), x), g(x)) == 0 # issue 5835: ode_order has to also work for unevaluated derivatives # (ie, without using doit()). assert ode_order(Derivative(xf(x), x), f(x)) == 1 assert ode_order(xsin(Derivative(xf(x)2, x, x)), f(x)) == 2 assert ode_order(Derivative(xDerivative(xexp(f(x)), x, x), x), g(x)) == 0 assert ode_order(Derivative(f(x), x, x), g(x)) == 0 assert ode_order(Derivative(xexp(f(x)), x, x), f(x)) == 2 assert ode_order(Derivative(f(x), x, x)Derivative(g(x), x), g(x)) == 1 assert ode_order(Derivative(xDerivative(f(x), x, x), x), f(x)) == 3 assert ode_order( xsin(Derivative(xDerivative(f(x), x)*2, x, x)), f(x)) == 3 # In all tests below, checkodesol has the order option set to prevent # superfluous calls to ode_order(), and the solve_for_func flag set to False # because dsolve() already tries to solve for the function, unless the # simplify=False option is set. def test_old_ode_tests(): # These are simple tests from the old ode module eq1 = Eq(f(x).diff(x), 0) eq2 = Eq(3f(x).diff(x) - 5, 0) eq3 = Eq(3f(x).diff(x), 5) eq4 = Eq(9f(x).diff(x, x) + f(x), 0) eq5 = Eq(9f(x).diff(x, x), f(x)) # Type: a(x)f'(x)+b(x)f(x)+c(x)=0 eq6 = Eq(x*2f(x).diff(x) + 3xf(x) - sin(x)/x, 0) eq7 = Eq(f(x).diff(x, x) - 3diff(f(x), x) + 2f(x), 0) # Type: 2nd order, constant coefficients (two real different roots) eq8 = Eq(f(x).diff(x, x) - 4diff(f(x), x) + 4f(x), 0) # Type: 2nd order, constant coefficients (two real equal roots) eq9 = Eq(f(x).diff(x, x) + 2diff(f(x), x) + 3f(x), 0) # Type: 2nd order, constant coefficients (two complex roots) eq10 = Eq(3f(x).diff(x) - 1, 0) eq11 = Eq(xf(x).diff(x) - 1, 0) sol1 = Eq(f(x), C1) sol2 = Eq(f(x), C1 + 5x/3) sol3 = Eq(f(x), C1 + 5x/3) sol4 = Eq(f(x), C1sin(x/3) + C2cos(x/3)) sol5 = Eq(f(x), C1exp(-x/3) + C2exp(x/3)) sol6 = Eq(f(x), (C1 - cos(x))/x*3) sol7 = Eq(f(x), (C1 + C2exp(x))exp(x)) sol8 = Eq(f(x), (C1 + C2x)exp(2x)) sol9 = Eq(f(x), (C1sin(xsqrt(2)) + C2cos(xsqrt(2)))exp(-x)) sol10 = Eq(f(x), C1 + x/3) sol11 = Eq(f(x), C1 + log(x)) assert dsolve(eq1) == sol1 assert dsolve(eq1.lhs) == sol1 assert dsolve(eq2) == sol2 assert dsolve(eq3) == sol3 assert dsolve(eq4) == sol4 assert dsolve(eq5) == sol5 assert dsolve(eq6) == sol6 assert dsolve(eq7) == sol7 assert dsolve(eq8) == sol8 assert dsolve(eq9) == sol9 assert dsolve(eq10) == sol10 assert dsolve(eq11) == sol11 assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=2, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=2, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=2, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=2, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=1, solve_for_func=False)[0] assert checkodesol(eq11, sol11, order=1, solve_for_func=False)[0] def test_1st_linear(): # Type: first order linear form f'(x)+p(x)f(x)=q(x) eq = Eq(f(x).diff(x) + xf(x), x*2) sol = Eq(f(x), (C1 + xexp(x*2/2) - sqrt(2)sqrt(pi)erfi(sqrt(2)x/2)/2)exp(-x2/2)) assert dsolve(eq, hint='1st_linear') == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_Bernoulli(): # Type: Bernoulli, f'(x) + p(x)f(x) == q(x)f(x)n eq = Eq(xf(x).diff(x) + f(x) - f(x)*2, 0) sol = dsolve(eq, f(x), hint='Bernoulli') assert sol == Eq(f(x), 1/(x(C1 + 1/x))) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_Riccati_special_minus2(): # Type: Riccati special alpha = -2, ady/dx + by*2 + cy/x +d/x*2 eq = 2f(x).diff(x) + f(x)*2 - f(x)/x + 3x*(-2) sol = dsolve(eq, f(x), hint='Riccati_special_minus2') assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] @slow def test_1st_exact1(): # Type: Exact differential equation, p(x,f) + q(x,f)f' == 0, # where dp/df == dq/dx eq1 = sin(x)cos(f(x)) + cos(x)sin(f(x))f(x).diff(x) eq2 = (2xf(x) + 1)/f(x) + (f(x) - x)/f(x)2f(x).diff(x) eq3 = 2x + f(x)cos(x) + (2f(x) + sin(x) - sin(f(x)))f(x).diff(x) eq4 = cos(f(x)) - (xsin(f(x)) - f(x)2)f(x).diff(x) eq5 = 2xf(x) + (x2 + f(x)2)f(x).diff(x) sol1 = [Eq(f(x), -acos(C1/cos(x)) + 2pi), Eq(f(x), acos(C1/cos(x)))] sol2 = Eq(f(x), exp(C1 - x*2 + LambertW(-xexp(-C1 + x2)))) sol2b = Eq(log(f(x)) + x/f(x) + x2, C1) sol3 = Eq(f(x)sin(x) + cos(f(x)) + x2 + f(x)2, C1) sol4 = Eq(xcos(f(x)) + f(x)3/3, C1) sol5 = Eq(x2f(x) + f(x)3/3, C1) assert dsolve(eq1, f(x), hint='1st_exact') == sol1 assert dsolve(eq2, f(x), hint='1st_exact') == sol2 assert dsolve(eq3, f(x), hint='1st_exact') == sol3 assert dsolve(eq4, hint='1st_exact') == sol4 assert dsolve(eq5, hint='1st_exact', simplify=False) == sol5 assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] # issue 5080 blocks the testing of this solution # FIXME: assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2b, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=1, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=1, solve_for_func=False)[0] @slow @XFAIL def test_1st_exact2(): """ This is an exact equation that fails under the exact engine. It is caught by first order homogeneous albeit with a much contorted solution. The exact engine fails because of a poorly simplified integral of q(0,y)dy, where q is the function multiplying f'. The solutions should be Eq(sqrt(x2+f(x)2)3+y3, C1). The equation below is equivalent, but it is so complex that checkodesol fails, and takes a long time to do so. """ if ON_TRAVIS: skip("Too slow for travis.") eq = (xsqrt(x2 + f(x)2) - (x*2f(x)/(f(x) - sqrt(x2 + f(x)2)))f(x).diff(x)) sol = dsolve(eq) assert sol == Eq(log(x), C1 - 9sqrt(1 + f(x)2/x2)asinh(f(x)/x)/(-27f(x)/x + 27sqrt(1 + f(x)2/x2)) - 9sqrt(1 + f(x)2/x2)* log(1 - sqrt(1 + f(x)2/x2)f(x)/x + 2f(x)2/x2)/ (-27f(x)/x + 27sqrt(1 + f(x)2/x2)) + 9asinh(f(x)/x)f(x)/(x(-27f(x)/x + 27sqrt(1 + f(x)2/x2))) + 9f(x)log(1 - sqrt(1 + f(x)2/x2)f(x)/x + 2f(x)2/x2)/ (x(-27f(x)/x + 27sqrt(1 + f(x)2/x2)))) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_separable1(): # test_separable1-5 are from Ordinary Differential Equations, Tenenbaum and # Pollard, pg. 55 eq1 = f(x).diff(x) - f(x) eq2 = xf(x).diff(x) - f(x) eq3 = f(x).diff(x) + sin(x) eq4 = f(x)2 + 1 - (x2 + 1)f(x).diff(x) eq5 = f(x).diff(x)/tan(x) - f(x) - 2 eq6 = f(x).diff(x) * (1 - sin(f(x))) - 1 sol1 = Eq(f(x), C1exp(x)) sol2 = Eq(f(x), C1x) sol3 = Eq(f(x), C1 + cos(x)) sol4 = Eq(f(x), tan(C1 + atan(x))) sol5 = Eq(f(x), C1/cos(x) - 2) sol6 = Eq(-x + f(x) + cos(f(x)), C1) assert dsolve(eq1, hint='separable') == sol1 assert dsolve(eq2, hint='separable') == sol2 assert dsolve(eq3, hint='separable') == sol3 assert dsolve(eq4, hint='separable') == sol4 assert dsolve(eq5, hint='separable') == sol5 assert dsolve(eq6, hint='separable') == sol6 assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=1, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=1, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] @slow def test_separable2(): a = Symbol('a') eq6 = f(x)x2f(x).diff(x) - f(x)*3 - 2x*2f(x).diff(x) eq7 = f(x)*2 - 1 - (2f(x) + xf(x))f(x).diff(x) eq8 = xlog(x)f(x).diff(x) + sqrt(1 + f(x)*2) eq9 = exp(x + 1)tan(f(x)) + cos(f(x))f(x).diff(x) eq10 = (xcos(f(x)) + x*2sin(f(x))f(x).diff(x) - a2sin(f(x))f(x).diff(x)) sol6 = Eq(Integral((u - 2)/u3, (u, f(x))), C1 + Integral(x(-2), x)) sol7 = Eq(-log(-1 + f(x)2)/2, C1 - log(2 + x)) sol8 = Eq(asinh(f(x)), C1 - log(log(x))) # integrate cannot handle the integral on the lhs (cos/tan) sol9 = Eq(Integral(cos(u)/tan(u), (u, f(x))), C1 + Integral(-exp(1)exp(x), x)) sol10 = Eq(-log(cos(f(x))), C1 - log(- a2 + x2)/2) assert dsolve(eq6, hint='separable_Integral').dummy_eq(sol6) assert dsolve(eq7, hint='separable', simplify=False) == sol7 assert dsolve(eq8, hint='separable', simplify=False) == sol8 assert dsolve(eq9, hint='separable_Integral').dummy_eq(sol9) assert dsolve(eq10, hint='separable', simplify=False) == sol10 assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=1, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=1, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=1, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=1, solve_for_func=False)[0] def test_separable3(): eq11 = f(x).diff(x) - f(x)tan(x) eq12 = (x - 1)cos(f(x))f(x).diff(x) - 2xsin(f(x)) eq13 = f(x).diff(x) - f(x)log(f(x))/tan(x) sol11 = Eq(f(x), C1/cos(x)) sol12 = Eq(log(sin(f(x))), C1 + 2x + 2log(x - 1)) sol13 = Eq(log(log(f(x))), C1 + log(sin(x))) assert dsolve(eq11, hint='separable') == sol11 assert dsolve(eq12, hint='separable', simplify=False) == sol12 assert dsolve(eq13, hint='separable', simplify=False) == sol13 assert checkodesol(eq11, sol11, order=1, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=1, solve_for_func=False)[0] assert checkodesol(eq13, sol13, order=1, solve_for_func=False)[0] def test_separable4(): # This has a slow integral (1/((1 + y*2)atan(y))), so we isolate it. eq14 = xf(x).diff(x) + (1 + f(x)2)atan(f(x)) sol14 = Eq(log(atan(f(x))), C1 - log(x)) assert dsolve(eq14, hint='separable', simplify=False) == sol14 assert checkodesol(eq14, sol14, order=1, solve_for_func=False)[0] def test_separable5(): eq15 = f(x).diff(x) + x(f(x) + 1) eq16 = exp(f(x)2)(x*2 + 2x + 1) + (xf(x) + f(x))f(x).diff(x) eq17 = f(x).diff(x) + f(x) eq18 = sin(x)cos(2f(x)) + cos(x)sin(2f(x))f(x).diff(x) eq19 = (1 - x)f(x).diff(x) - x(f(x) + 1) eq20 = f(x)diff(f(x), x) + x - 3xf(x)*2 eq21 = f(x).diff(x) - exp(x + f(x)) sol15 = Eq(f(x), -1 + C1exp(-x2/2)) sol16 = Eq(-exp(-f(x)2)/2, C1 - x - x*2/2) sol17 = Eq(f(x), C1exp(-x)) sol18 = Eq(-log(cos(2f(x)))/2, C1 + log(cos(x))) sol19 = Eq(f(x), (C1exp(-x) - x + 1)/(x - 1)) sol20 = Eq(log(-1 + 3f(x)2)/6, C1 + x2/2) sol21 = Eq(-exp(-f(x)), C1 + exp(x)) assert dsolve(eq15, hint='separable') == sol15 assert dsolve(eq16, hint='separable', simplify=False) == sol16 assert dsolve(eq17, hint='separable') == sol17 assert dsolve(eq18, hint='separable', simplify=False) == sol18 assert dsolve(eq19, hint='separable') == sol19 assert dsolve(eq20, hint='separable', simplify=False) == sol20 assert dsolve(eq21, hint='separable', simplify=False) == sol21 assert checkodesol(eq15, sol15, order=1, solve_for_func=False)[0] assert checkodesol(eq16, sol16, order=1, solve_for_func=False)[0] assert checkodesol(eq17, sol17, order=1, solve_for_func=False)[0] assert checkodesol(eq18, sol18, order=1, solve_for_func=False)[0] assert checkodesol(eq19, sol19, order=1, solve_for_func=False)[0] assert checkodesol(eq20, sol20, order=1, solve_for_func=False)[0] assert checkodesol(eq21, sol21, order=1, solve_for_func=False)[0] def test_separable_1_5_checkodesol(): eq12 = (x - 1)cos(f(x))f(x).diff(x) - 2xsin(f(x)) sol12 = Eq(-log(1 - cos(f(x))2)/2, C1 - 2x - 2log(1 - x)) assert checkodesol(eq12, sol12, order=1, solve_for_func=False)[0] def test_homogeneous_order(): assert homogeneous_order(exp(y/x) + tan(y/x), x, y) == 0 assert homogeneous_order(x2 + sin(x)cos(y), x, y) is None assert homogeneous_order(x - y - xsin(y/x), x, y) == 1 assert homogeneous_order((xy + sqrt(x4 + y4) + x*2(log(x) - log(y)))/ (pixRational(2, 3)sqrt(y)*3), x, y) == Rational(-1, 6) assert homogeneous_order(y/xcos(y/x) - x/ysin(y/x) + cos(y/x), x, y) == 0 assert homogeneous_order(f(x), x, f(x)) == 1 assert homogeneous_order(f(x)2, x, f(x)) == 2 assert homogeneous_order(xyz, x, y) == 2 assert homogeneous_order(xyz, x, y, z) == 3 assert homogeneous_order(x2f(x)/sqrt(x2 + f(x)2), f(x)) is None assert homogeneous_order(f(x, y)2, x, f(x, y), y) == 2 assert homogeneous_order(f(x, y)2, x, f(x), y) is None assert homogeneous_order(f(x, y)2, x, f(x, y)) is None assert homogeneous_order(f(y, x)2, x, y, f(x, y)) is None assert homogeneous_order(f(y), f(x), x) is None assert homogeneous_order(-f(x)/x + 1/sin(f(x)/ x), f(x), x) == 0 assert homogeneous_order(log(1/y) + log(x*2), x, y) is None assert homogeneous_order(log(1/y) + log(x), x, y) == 0 assert homogeneous_order(log(x/y), x, y) == 0 assert homogeneous_order(2log(1/y) + 2log(x), x, y) == 0 a = Symbol('a') assert homogeneous_order(alog(1/y) + alog(x), x, y) == 0 assert homogeneous_order(f(x).diff(x), x, y) is None assert homogeneous_order(-f(x).diff(x) + x, x, y) is None assert homogeneous_order(O(x), x, y) is None assert homogeneous_order(x + O(x2), x, y) is None assert homogeneous_order(xpi, x) == pi assert homogeneous_order(xx, x) is None raises(ValueError, lambda: homogeneous_order(xy)) @slow def test_1st_homogeneous_coeff_ode(): # Type: First order homogeneous, y'=f(y/x) eq1 = f(x)/xcos(f(x)/x) - (x/f(x)sin(f(x)/x) + cos(f(x)/x))f(x).diff(x) eq2 = xf(x).diff(x) - f(x) - xsin(f(x)/x) eq3 = f(x) + (xlog(f(x)/x) - 2x)diff(f(x), x) eq4 = 2f(x)exp(x/f(x)) + f(x)f(x).diff(x) - 2xexp(x/f(x))f(x).diff(x) eq5 = 2x2f(x) + f(x)*3 + (xf(x)*2 - 2x*3)f(x).diff(x) eq6 = xexp(f(x)/x) - f(x)sin(f(x)/x) + xsin(f(x)/x)f(x).diff(x) eq7 = (x + sqrt(f(x)*2 - xf(x)))f(x).diff(x) - f(x) eq8 = x + f(x) - (x - f(x))f(x).diff(x) sol1 = Eq(log(x), C1 - log(f(x)sin(f(x)/x)/x)) sol2 = Eq(log(x), log(C1) + log(cos(f(x)/x) - 1)/2 - log(cos(f(x)/x) + 1)/2) sol3 = Eq(f(x), -exp(C1)LambertW(-xexp(-C1 + 1))) sol4 = Eq(log(f(x)), C1 - 2exp(x/f(x))) sol5 = Eq(f(x), exp(2C1 + LambertW(-2x*4exp(-4C1))/2)/x) sol6 = Eq(log(x), C1 + exp(-f(x)/x)sin(f(x)/x)/2 + exp(-f(x)/x)cos(f(x)/x)/2) sol7 = Eq(log(f(x)), C1 - 2sqrt(-x/f(x) + 1)) sol8 = Eq(log(x), C1 - log(sqrt(1 + f(x)2/x2)) + atan(f(x)/x)) # indep_div_dep actually has a simpler solution for eq2, # but it runs too slow assert dsolve(eq1, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol1 assert dsolve(eq2, hint='1st_homogeneous_coeff_subs_dep_div_indep', simplify=False) == sol2 assert dsolve(eq3, hint='1st_homogeneous_coeff_best') == sol3 assert dsolve(eq4, hint='1st_homogeneous_coeff_best') == sol4 assert dsolve(eq5, hint='1st_homogeneous_coeff_best') == sol5 assert dsolve(eq6, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol6 assert dsolve(eq7, hint='1st_homogeneous_coeff_best') == sol7 assert dsolve(eq8, hint='1st_homogeneous_coeff_best') == sol8 # FIXME: sol3 and sol5 don't work with checkodesol (because of LambertW?) # previous code was testing with these other solutions: sol3b = Eq(-f(x)/(1 + log(x/f(x))), C1) sol5b = Eq(log(C1xsqrt(1/x)sqrt(f(x))) + x2/(2f(x)*2), 0) assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3b, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=1, solve_for_func=False)[0] assert checkodesol(eq5, sol5b, order=1, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode_check2(): eq2 = xf(x).diff(x) - f(x) - xsin(f(x)/x) sol2 = Eq(x/tan(f(x)/(2x)), C1) assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] @XFAIL def test_1st_homogeneous_coeff_ode_check3(): skip('This is a known issue.') # checker cannot determine that the following expression is zero: # (False, # x(log(exp(-LambertW(C1x))) + # LambertW(C1x))exp(-LambertW(C1x) + 1)) # This is blocked by issue 5080. eq3 = f(x) + (xlog(f(x)/x) - 2x)diff(f(x), x) sol3a = Eq(f(x), xexp(1 - LambertW(C1x))) assert checkodesol(eq3, sol3a, solve_for_func=True)[0] # Checker can't verify this form either # (False, # C1(log(C1LambertW(C2x)/x) + LambertW(C2x) - 1)LambertW(C2x)) # It is because a = W(a)exp(W(a)), so log(a) == log(W(a)) + W(a) and C2 = # -E/C1 (which can be verified by solving with simplify=False). sol3b = Eq(f(x), C1LambertW(C2x)) assert checkodesol(eq3, sol3b, solve_for_func=True)[0] def test_1st_homogeneous_coeff_ode_check7(): eq7 = (x + sqrt(f(x)2 - xf(x)))f(x).diff(x) - f(x) sol7 = Eq(log(C1f(x)) + 2sqrt(1 - x/f(x)), 0) assert checkodesol(eq7, sol7, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode2(): eq1 = f(x).diff(x) - f(x)/x + 1/sin(f(x)/x) eq2 = x2 + f(x)2 - 2xf(x)f(x).diff(x) eq3 = xexp(f(x)/x) + f(x) - xf(x).diff(x) sol1 = [Eq(f(x), x(-acos(C1 + log(x)) + 2pi)), Eq(f(x), xacos(C1 + log(x)))] sol2 = Eq(log(f(x)), log(C1) + log(x/f(x)) - log(x2/f(x)2 - 1)) sol3 = Eq(f(x), log((1/(C1 - log(x)))x)) # specific hints are applied for speed reasons assert dsolve(eq1, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol1 assert dsolve(eq2, hint='1st_homogeneous_coeff_best', simplify=False) == sol2 assert dsolve(eq3, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol3 # FIXME: sol3 doesn't work with checkodesol (because of x?) # previous code was testing with this other solution: sol3b = Eq(f(x), log(log(C1/x)(-x))) assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3b, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode_check9(): _u2 = Dummy('u2') __a = Dummy('a') eq9 = f(x)2 + (xsqrt(f(x)2 - x2) - xf(x))f(x).diff(x) sol9 = Eq(-Integral(-1/(-(1 - sqrt(1 - _u2*2))_u2 + _u2), (_u2, __a, x/f(x))) + log(C1f(x)), 0) assert checkodesol(eq9, sol9, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode3(): # The standard integration engine cannot handle one of the integrals # involved (see issue 4551). meijerg code comes up with an answer, but in # unconventional form. # checkodesol fails for this equation, so its test is in # test_1st_homogeneous_coeff_ode_check9 above. It has to compare string # expressions because u2 is a dummy variable. eq = f(x)2 + (xsqrt(f(x)2 - x2) - xf(x))f(x).diff(x) sol = Eq(log(f(x)), C1 + Piecewise( (acosh(f(x)/x), abs(f(x)2)/x2 > 1), (-Iasin(f(x)/x), True))) assert dsolve(eq, hint='1st_homogeneous_coeff_subs_indep_div_dep') == sol def test_1st_homogeneous_coeff_corner_case(): eq1 = f(x).diff(x) - f(x)/x c1 = classify_ode(eq1, f(x)) eq2 = xf(x).diff(x) - f(x) c2 = classify_ode(eq2, f(x)) sdi = "1st_homogeneous_coeff_subs_dep_div_indep" sid = "1st_homogeneous_coeff_subs_indep_div_dep" assert sid not in c1 and sdi not in c1 assert sid not in c2 and sdi not in c2 @slow def test_nth_linear_constant_coeff_homogeneous(): # From Exercise 20, in Ordinary Differential Equations, # Tenenbaum and Pollard, pg. 220 a = Symbol('a', positive=True) k = Symbol('k', real=True) eq1 = f(x).diff(x, 2) + 2f(x).diff(x) eq2 = f(x).diff(x, 2) - 3f(x).diff(x) + 2f(x) eq3 = f(x).diff(x, 2) - f(x) eq4 = f(x).diff(x, 3) + f(x).diff(x, 2) - 6f(x).diff(x) eq5 = 6f(x).diff(x, 2) - 11f(x).diff(x) + 4f(x) eq6 = Eq(f(x).diff(x, 2) + 2f(x).diff(x) - f(x), 0) eq7 = diff(f(x), x, 3) + diff(f(x), x, 2) - 10diff(f(x), x) - 6f(x) eq8 = f(x).diff(x, 4) - f(x).diff(x, 3) - 4f(x).diff(x, 2) + \ 4f(x).diff(x) eq9 = f(x).diff(x, 4) + 4f(x).diff(x, 3) + f(x).diff(x, 2) - \ 4f(x).diff(x) - 2f(x) eq10 = f(x).diff(x, 4) - a2f(x) eq11 = f(x).diff(x, 2) - 2kf(x).diff(x) - 2f(x) eq12 = f(x).diff(x, 2) + 4kf(x).diff(x) - 12k*2f(x) eq13 = f(x).diff(x, 4) eq14 = f(x).diff(x, 2) + 4f(x).diff(x) + 4f(x) eq15 = 3f(x).diff(x, 3) + 5f(x).diff(x, 2) + f(x).diff(x) - f(x) eq16 = f(x).diff(x, 3) - 6f(x).diff(x, 2) + 12f(x).diff(x) - 8f(x) eq17 = f(x).diff(x, 2) - 2af(x).diff(x) + a2f(x) eq18 = f(x).diff(x, 4) + 3f(x).diff(x, 3) eq19 = f(x).diff(x, 4) - 2f(x).diff(x, 2) eq20 = f(x).diff(x, 4) + 2f(x).diff(x, 3) - 11f(x).diff(x, 2) - \ 12f(x).diff(x) + 36f(x) eq21 = 36f(x).diff(x, 4) - 37f(x).diff(x, 2) + 4f(x).diff(x) + 5f(x) eq22 = f(x).diff(x, 4) - 8f(x).diff(x, 2) + 16f(x) eq23 = f(x).diff(x, 2) - 2f(x).diff(x) + 5f(x) eq24 = f(x).diff(x, 2) - f(x).diff(x) + f(x) eq25 = f(x).diff(x, 4) + 5f(x).diff(x, 2) + 6f(x) eq26 = f(x).diff(x, 2) - 4f(x).diff(x) + 20f(x) eq27 = f(x).diff(x, 4) + 4f(x).diff(x, 2) + 4f(x) eq28 = f(x).diff(x, 3) + 8f(x) eq29 = f(x).diff(x, 4) + 4f(x).diff(x, 2) eq30 = f(x).diff(x, 5) + 2f(x).diff(x, 3) + f(x).diff(x) eq31 = f(x).diff(x, 4) + f(x).diff(x, 2) + f(x) eq32 = f(x).diff(x, 4) + 4f(x).diff(x, 2) + f(x) sol1 = Eq(f(x), C1 + C2exp(-2x)) sol2 = Eq(f(x), (C1 + C2exp(x))exp(x)) sol3 = Eq(f(x), C1exp(x) + C2exp(-x)) sol4 = Eq(f(x), C1 + C2exp(-3x) + C3exp(2x)) sol5 = Eq(f(x), C1exp(x/2) + C2exp(4x/3)) sol6 = Eq(f(x), C1exp(x(-1 + sqrt(2))) + C2exp(x(-sqrt(2) - 1))) sol7 = Eq(f(x), C1exp(3x) + C2exp(x(-2 - sqrt(2))) + C3exp(x(-2 + sqrt(2)))) sol8 = Eq(f(x), C1 + C2exp(x) + C3exp(-2x) + C4exp(2x)) sol9 = Eq(f(x), C1exp(x) + C2exp(-x) + C3exp(x(-2 + sqrt(2))) + C4exp(x(-2 - sqrt(2)))) sol10 = Eq(f(x), C1sin(xsqrt(a)) + C2cos(xsqrt(a)) + C3exp(xsqrt(a)) + C4exp(-xsqrt(a))) sol11 = Eq(f(x), C1exp(x(k - sqrt(k*2 + 2))) + C2exp(x(k + sqrt(k2 + 2)))) sol12 = Eq(f(x), C1exp(-6kx) + C2exp(2kx)) sol13 = Eq(f(x), C1 + C2x + C3x2 + C4x*3) sol14 = Eq(f(x), (C1 + C2x)exp(-2x)) sol15 = Eq(f(x), (C1 + C2x)exp(-x) + C3exp(x/3)) sol16 = Eq(f(x), (C1 + C2x + C3x2)exp(2x)) sol17 = Eq(f(x), (C1 + C2x)exp(ax)) sol18 = Eq(f(x), C1 + C2x + C3x*2 + C4exp(-3x)) sol19 = Eq(f(x), C1 + C2x + C3exp(xsqrt(2)) + C4exp(-xsqrt(2))) sol20 = Eq(f(x), (C1 + C2x)exp(-3x) + (C3 + C4x)exp(2x)) sol21 = Eq(f(x), C1exp(x/2) + C2exp(-x) + C3exp(-x/3) + C4exp(5x/6)) sol22 = Eq(f(x), (C1 + C2x)exp(-2x) + (C3 + C4x)exp(2x)) sol23 = Eq(f(x), (C1sin(2x) + C2cos(2x))exp(x)) sol24 = Eq(f(x), (C1sin(xsqrt(3)/2) + C2cos(xsqrt(3)/2))exp(x/2)) sol25 = Eq(f(x), C1cos(xsqrt(3)) + C2sin(xsqrt(3)) + C3sin(xsqrt(2)) + C4cos(xsqrt(2))) sol26 = Eq(f(x), (C1sin(4x) + C2cos(4x))exp(2x)) sol27 = Eq(f(x), (C1 + C2x)sin(xsqrt(2)) + (C3 + C4x)cos(xsqrt(2))) sol28 = Eq(f(x), (C1sin(xsqrt(3)) + C2cos(xsqrt(3)))exp(x) + C3exp(-2x)) sol29 = Eq(f(x), C1 + C2sin(2x) + C3cos(2x) + C4x) sol30 = Eq(f(x), C1 + (C2 + C3x)sin(x) + (C4 + C5x)cos(x)) sol31 = Eq(f(x), (C1sin(sqrt(3)x/2) + C2cos(sqrt(3)x/2))/sqrt(exp(x)) + (C3sin(sqrt(3)x/2) + C4cos(sqrt(3)x/2))sqrt(exp(x))) sol32 = Eq(f(x), C1sin(xsqrt(-sqrt(3) + 2)) + C2sin(xsqrt(sqrt(3) + 2)) + C3cos(xsqrt(-sqrt(3) + 2)) + C4cos(xsqrt(sqrt(3) + 2))) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) sol6s = constant_renumber(sol6) sol7s = constant_renumber(sol7) sol8s = constant_renumber(sol8) sol9s = constant_renumber(sol9) sol10s = constant_renumber(sol10) sol11s = constant_renumber(sol11) sol12s = constant_renumber(sol12) sol13s = constant_renumber(sol13) sol14s = constant_renumber(sol14) sol15s = constant_renumber(sol15) sol16s = constant_renumber(sol16) sol17s = constant_renumber(sol17) sol18s = constant_renumber(sol18) sol19s = constant_renumber(sol19) sol20s = constant_renumber(sol20) sol21s = constant_renumber(sol21) sol22s = constant_renumber(sol22) sol23s = constant_renumber(sol23) sol24s = constant_renumber(sol24) sol25s = constant_renumber(sol25) sol26s = constant_renumber(sol26) sol27s = constant_renumber(sol27) sol28s = constant_renumber(sol28) sol29s = constant_renumber(sol29) sol30s = constant_renumber(sol30) assert dsolve(eq1) in (sol1, sol1s) assert dsolve(eq2) in (sol2, sol2s) assert dsolve(eq3) in (sol3, sol3s) assert dsolve(eq4) in (sol4, sol4s) assert dsolve(eq5) in (sol5, sol5s) assert dsolve(eq6) in (sol6, sol6s) assert dsolve(eq7) in (sol7, sol7s) assert dsolve(eq8) in (sol8, sol8s) assert dsolve(eq9) in (sol9, sol9s) assert dsolve(eq10) in (sol10, sol10s) assert dsolve(eq11) in (sol11, sol11s) assert dsolve(eq12) in (sol12, sol12s) assert dsolve(eq13) in (sol13, sol13s) assert dsolve(eq14) in (sol14, sol14s) assert dsolve(eq15) in (sol15, sol15s) assert dsolve(eq16) in (sol16, sol16s) assert dsolve(eq17) in (sol17, sol17s) assert dsolve(eq18) in (sol18, sol18s) assert dsolve(eq19) in (sol19, sol19s) assert dsolve(eq20) in (sol20, sol20s) assert dsolve(eq21) in (sol21, sol21s) assert dsolve(eq22) in (sol22, sol22s) assert dsolve(eq23) in (sol23, sol23s) assert dsolve(eq24) in (sol24, sol24s) assert dsolve(eq25) in (sol25, sol25s) assert dsolve(eq26) in (sol26, sol26s) assert dsolve(eq27) in (sol27, sol27s) assert dsolve(eq28) in (sol28, sol28s) assert dsolve(eq29) in (sol29, sol29s) assert dsolve(eq30) in (sol30, sol30s) assert dsolve(eq31) in (sol31,) assert dsolve(eq32) in (sol32,) assert checkodesol(eq1, sol1, order=2, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=2, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=2, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=3, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=2, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=3, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=4, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=4, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=4, solve_for_func=False)[0] assert checkodesol(eq11, sol11, order=2, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=2, solve_for_func=False)[0] assert checkodesol(eq13, sol13, order=4, solve_for_func=False)[0] assert checkodesol(eq14, sol14, order=2, solve_for_func=False)[0] assert checkodesol(eq15, sol15, order=3, solve_for_func=False)[0] assert checkodesol(eq16, sol16, order=3, solve_for_func=False)[0] assert checkodesol(eq17, sol17, order=2, solve_for_func=False)[0] assert checkodesol(eq18, sol18, order=4, solve_for_func=False)[0] assert checkodesol(eq19, sol19, order=4, solve_for_func=False)[0] assert checkodesol(eq20, sol20, order=4, solve_for_func=False)[0] assert checkodesol(eq21, sol21, order=4, solve_for_func=False)[0] assert checkodesol(eq22, sol22, order=4, solve_for_func=False)[0] assert checkodesol(eq23, sol23, order=2, solve_for_func=False)[0] assert checkodesol(eq24, sol24, order=2, solve_for_func=False)[0] assert checkodesol(eq25, sol25, order=4, solve_for_func=False)[0] assert checkodesol(eq26, sol26, order=2, solve_for_func=False)[0] assert checkodesol(eq27, sol27, order=4, solve_for_func=False)[0] assert checkodesol(eq28, sol28, order=3, solve_for_func=False)[0] assert checkodesol(eq29, sol29, order=4, solve_for_func=False)[0] assert checkodesol(eq30, sol30, order=5, solve_for_func=False)[0] assert checkodesol(eq31, sol31, order=4, solve_for_func=False)[0] assert checkodesol(eq32, sol32, order=4, solve_for_func=False)[0] # Issue #15237 eqn = Derivative(xf(x), x, x, x) hint = 'nth_linear_constant_coeff_homogeneous' raises(ValueError, lambda: dsolve(eqn, f(x), hint, prep=True)) raises(ValueError, lambda: dsolve(eqn, f(x), hint, prep=False)) def test_nth_linear_constant_coeff_homogeneous_rootof(): # One real root, two complex conjugate pairs eq = f(x).diff(x, 5) + 11f(x).diff(x) - 2f(x) r1, r2, r3, r4, r5 = [rootof(x5 + 11x - 2, n) for n in range(5)] sol = Eq(f(x), C5exp(r1x) + exp(re(r2)x) (C1sin(im(r2)x) + C2cos(im(r2)x)) + exp(re(r4)x) (C3sin(im(r4)x) + C4cos(im(r4)x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Three real roots, one complex conjugate pair eq = f(x).diff(x,5) - 3f(x).diff(x) + f(x) r1, r2, r3, r4, r5 = [rootof(x5 - 3x + 1, n) for n in range(5)] sol = Eq(f(x), C3exp(r1x) + C4exp(r2x) + C5exp(r3x) + exp(re(r4)x) (C1sin(im(r4)x) + C2cos(im(r4)x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Five distinct real roots eq = f(x).diff(x,5) - 100f(x).diff(x,3) + 1000f(x).diff(x) + f(x) r1, r2, r3, r4, r5 = [rootof(x*5 - 100x*3 + 1000x + 1, n) for n in range(5)] sol = Eq(f(x), C1exp(r1x) + C2exp(r2x) + C3exp(r3x) + C4exp(r4x) + C5exp(r5x)) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Rational root and unsolvable quintic eq = f(x).diff(x, 6) - 6f(x).diff(x, 5) + 5f(x).diff(x, 4) + 10f(x).diff(x) - 50 f(x) r2, r3, r4, r5, r6 = [rootof(x5 - x4 + 10, n) for n in range(5)] sol = Eq(f(x), C5exp(5x) + C6exp(xr2) + exp(re(r3)x) (C1sin(im(r3)x) + C2cos(im(r3)x)) + exp(re(r5)x) (C3sin(im(r5)x) + C4cos(im(r5)x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Five double roots (this is (x5 - x + 1)2) eq = f(x).diff(x, 10) - 2f(x).diff(x, 6) + 2f(x).diff(x, 5) + f(x).diff(x, 2) - 2f(x).diff(x, 1) + f(x) r1, r2, r3, r4, r5 = [rootof(x5 - x + 1, n) for n in range(5)] sol = Eq(f(x), (C1 + C2 x)exp(r1x) + exp(re(r2)x) ((C3 + C4x)sin(im(r2)x) + (C5 + C6 x)cos(im(r2)x)) + exp(re(r4)x) ((C7 + C8x)sin(im(r4)x) + (C9 + C10x)cos(im(r4)x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... def test_nth_linear_constant_coeff_homogeneous_irrational(): our_hint='nth_linear_constant_coeff_homogeneous' eq = Eq(sqrt(2) * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2sin(2(S(3)/4)x/2) + C3cos(2(S(3)/4)x/2)) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] E = exp(1) eq = Eq(E * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2sin(x/sqrt(E)) + C3cos(x/sqrt(E))) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] eq = Eq(pi * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2sin(x/sqrt(pi)) + C3cos(x/sqrt(pi))) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] eq = Eq(I * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2exp(-sqrt(I)x) + C3exp(sqrt(I)x)) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] @XFAIL @slow def test_nth_linear_constant_coeff_homogeneous_rootof_sol(): if ON_TRAVIS: skip("Too slow for travis.") eq = f(x).diff(x, 5) + 11f(x).diff(x) - 2f(x) sol = Eq(f(x), C1exp(xrootof(x*5 + 11x - 2, 0)) + C2exp(xrootof(x*5 + 11x - 2, 1)) + C3exp(xrootof(x*5 + 11x - 2, 2)) + C4exp(xrootof(x*5 + 11x - 2, 3)) + C5exp(xrootof(x*5 + 11x - 2, 4))) assert checkodesol(eq, sol, order=5, solve_for_func=False)[0] @XFAIL def test_noncircularized_real_imaginary_parts(): # If this passes, lines numbered 3878-3882 (at the time of this commit) # of sympy/solvers/ode.py for nth_linear_constant_coeff_homogeneous # should be removed. y = sqrt(1+x) i, r = im(y), re(y) assert not (i.has(atan2) and r.has(atan2)) @XFAIL def test_collect_respecting_exponentials(): # If this test passes, lines 1306-1311 (at the time of this commit) # of sympy/solvers/ode.py should be removed. sol = 1 + exp(x/2) assert sol == collect( sol, exp(x/3)) def test_undetermined_coefficients_match(): assert _undetermined_coefficients_match(g(x), x) == {'test': False} assert _undetermined_coefficients_match(sin(2x + sqrt(5)), x) == \ {'test': True, 'trialset': set([cos(2x + sqrt(5)), sin(2x + sqrt(5))])} assert _undetermined_coefficients_match(sin(x)cos(x), x) == \ {'test': False} s = set([cos(x), xcos(x), x2cos(x), x*2sin(x), xsin(x), sin(x)]) assert _undetermined_coefficients_match(sin(x)(x*2 + x + 1), x) == \ {'test': True, 'trialset': s} assert _undetermined_coefficients_match( sin(x)x*2 + sin(x)x + sin(x), x) == {'test': True, 'trialset': s} assert _undetermined_coefficients_match( exp(2x)sin(x)(x2 + x + 1), x ) == { 'test': True, 'trialset': set([exp(2x)sin(x), x2exp(2x)sin(x), cos(x)exp(2x), x*2cos(x)exp(2x), xcos(x)exp(2x), xexp(2x)sin(x)])} assert _undetermined_coefficients_match(1/sin(x), x) == {'test': False} assert _undetermined_coefficients_match(log(x), x) == {'test': False} assert _undetermined_coefficients_match(2*(x)(x2 + x + 1), x) == \ {'test': True, 'trialset': set([2x, x2x, x22x])} assert _undetermined_coefficients_match(xy, x) == {'test': False} assert _undetermined_coefficients_match(exp(x)exp(2x + 1), x) == \ {'test': True, 'trialset': set([exp(1 + 3x)])} assert _undetermined_coefficients_match(sin(x)(x*2 + x + 1), x) == \ {'test': True, 'trialset': set([xcos(x), xsin(x), x2cos(x), x*2sin(x), cos(x), sin(x)])} assert _undetermined_coefficients_match(sin(x)(x + sin(x)), x) == \ {'test': False} assert _undetermined_coefficients_match(sin(x)(x + sin(2x)), x) == \ {'test': False} assert _undetermined_coefficients_match(sin(x)tan(x), x) == \ {'test': False} assert _undetermined_coefficients_match( x*2sin(x)exp(x) + xsin(x) + x, x ) == { 'test': True, 'trialset': set([x*2cos(x)exp(x), x, cos(x), S(1), exp(x)sin(x), sin(x), xexp(x)sin(x), xcos(x), xcos(x)exp(x), xsin(x), cos(x)exp(x), x2exp(x)sin(x)])} assert _undetermined_coefficients_match(4xsin(x - 2), x) == { 'trialset': set([xcos(x - 2), xsin(x - 2), cos(x - 2), sin(x - 2)]), 'test': True, } assert _undetermined_coefficients_match(2xx, x) == \ {'test': True, 'trialset': set([2*x, x2x])} assert _undetermined_coefficients_match(2xexp(2x), x) == \ {'test': True, 'trialset': set([2*xexp(2x)])} assert _undetermined_coefficients_match(exp(-x)/x, x) == \ {'test': False} # Below are from Ordinary Differential Equations, # Tenenbaum and Pollard, pg. 231 assert _undetermined_coefficients_match(S(4), x) == \ {'test': True, 'trialset': set([S(1)])} assert _undetermined_coefficients_match(12exp(x), x) == \ {'test': True, 'trialset': set([exp(x)])} assert _undetermined_coefficients_match(exp(Ix), x) == \ {'test': True, 'trialset': set([exp(Ix)])} assert _undetermined_coefficients_match(sin(x), x) == \ {'test': True, 'trialset': set([cos(x), sin(x)])} assert _undetermined_coefficients_match(cos(x), x) == \ {'test': True, 'trialset': set([cos(x), sin(x)])} assert _undetermined_coefficients_match(8 + 6exp(x) + 2sin(x), x) == \ {'test': True, 'trialset': set([S(1), cos(x), sin(x), exp(x)])} assert _undetermined_coefficients_match(x2, x) == \ {'test': True, 'trialset': set([S(1), x, x2])} assert _undetermined_coefficients_match(9xexp(x) + exp(-x), x) == \ {'test': True, 'trialset': set([xexp(x), exp(x), exp(-x)])} assert _undetermined_coefficients_match(2exp(2x)sin(x), x) == \ {'test': True, 'trialset': set([exp(2x)sin(x), cos(x)exp(2x)])} assert _undetermined_coefficients_match(x - sin(x), x) == \ {'test': True, 'trialset': set([S(1), x, cos(x), sin(x)])} assert _undetermined_coefficients_match(x*2 + 2x, x) == \ {'test': True, 'trialset': set([S(1), x, x*2])} assert _undetermined_coefficients_match(4xsin(x), x) == \ {'test': True, 'trialset': set([xcos(x), xsin(x), cos(x), sin(x)])} assert _undetermined_coefficients_match(xsin(2x), x) == \ {'test': True, 'trialset': set([xcos(2x), xsin(2x), cos(2x), sin(2x)])} assert _undetermined_coefficients_match(x2exp(-x), x) == \ {'test': True, 'trialset': set([xexp(-x), x2exp(-x), exp(-x)])} assert _undetermined_coefficients_match(2exp(-x) - x2exp(-x), x) == \ {'test': True, 'trialset': set([xexp(-x), x2exp(-x), exp(-x)])} assert _undetermined_coefficients_match(exp(-2x) + x2, x) == \ {'test': True, 'trialset': set([S(1), x, x2, exp(-2x)])} assert _undetermined_coefficients_match(xexp(-x), x) == \ {'test': True, 'trialset': set([xexp(-x), exp(-x)])} assert _undetermined_coefficients_match(x + exp(2x), x) == \ {'test': True, 'trialset': set([S(1), x, exp(2x)])} assert _undetermined_coefficients_match(sin(x) + exp(-x), x) == \ {'test': True, 'trialset': set([cos(x), sin(x), exp(-x)])} assert _undetermined_coefficients_match(exp(x), x) == \ {'test': True, 'trialset': set([exp(x)])} # converted from sin(x)*2 assert _undetermined_coefficients_match(S(1)/2 - cos(2x)/2, x) == \ {'test': True, 'trialset': set([S(1), cos(2x), sin(2x)])} # converted from exp(2x)sin(x)*2 assert _undetermined_coefficients_match( exp(2x)(S(1)/2 + cos(2x)/2), x ) == { 'test': True, 'trialset': set([exp(2x)sin(2x), cos(2x)exp(2x), exp(2x)])} assert _undetermined_coefficients_match(2x + sin(x) + cos(x), x) == \ {'test': True, 'trialset': set([S(1), x, cos(x), sin(x)])} # converted from sin(2x)sin(x) assert _undetermined_coefficients_match(cos(x)/2 - cos(3x)/2, x) == \ {'test': True, 'trialset': set([cos(x), cos(3x), sin(x), sin(3x)])} assert _undetermined_coefficients_match(cos(x2), x) == {'test': False} assert _undetermined_coefficients_match(2(x2), x) == {'test': False} @slow def test_nth_linear_constant_coeff_undetermined_coefficients(): hint = 'nth_linear_constant_coeff_undetermined_coefficients' g = exp(-x) f2 = f(x).diff(x, 2) c = 3f(x).diff(x, 3) + 5f2 + f(x).diff(x) - f(x) - x eq1 = c - xg eq2 = c - g # 3-27 below are from Ordinary Differential Equations, # Tenenbaum and Pollard, pg. 231 eq3 = f2 + 3f(x).diff(x) + 2f(x) - 4 eq4 = f2 + 3f(x).diff(x) + 2f(x) - 12exp(x) eq5 = f2 + 3f(x).diff(x) + 2f(x) - exp(Ix) eq6 = f2 + 3f(x).diff(x) + 2f(x) - sin(x) eq7 = f2 + 3f(x).diff(x) + 2f(x) - cos(x) eq8 = f2 + 3f(x).diff(x) + 2f(x) - (8 + 6exp(x) + 2sin(x)) eq9 = f2 + f(x).diff(x) + f(x) - x*2 eq10 = f2 - 2f(x).diff(x) - 8f(x) - 9xexp(x) - 10exp(-x) eq11 = f2 - 3f(x).diff(x) - 2exp(2x)sin(x) eq12 = f(x).diff(x, 4) - 2f2 + f(x) - x + sin(x) eq13 = f2 + f(x).diff(x) - x2 - 2x eq14 = f2 + f(x).diff(x) - x - sin(2x) eq15 = f2 + f(x) - 4xsin(x) eq16 = f2 + 4f(x) - xsin(2x) eq17 = f2 + 2f(x).diff(x) + f(x) - x2exp(-x) eq18 = f(x).diff(x, 3) + 3f2 + 3f(x).diff(x) + f(x) - 2exp(-x) + \ x2exp(-x) eq19 = f2 + 3f(x).diff(x) + 2f(x) - exp(-2x) - x2 eq20 = f2 - 3f(x).diff(x) + 2f(x) - xexp(-x) eq21 = f2 + f(x).diff(x) - 6f(x) - x - exp(2x) eq22 = f2 + f(x) - sin(x) - exp(-x) eq23 = f(x).diff(x, 3) - 3f2 + 3f(x).diff(x) - f(x) - exp(x) # sin(x)*2 eq24 = f2 + f(x) - S(1)/2 - cos(2x)/2 # exp(2x)sin(x)*2 eq25 = f(x).diff(x, 3) - f(x).diff(x) - exp(2x)(S(1)/2 - cos(2x)/2) eq26 = (f(x).diff(x, 5) + 2f(x).diff(x, 3) + f(x).diff(x) - 2x - sin(x) - cos(x)) # sin(2x)sin(x), skip 3127 for now, match bug eq27 = f2 + f(x) - cos(x)/2 + cos(3x)/2 eq28 = f(x).diff(x) - 1 sol1 = Eq(f(x), -1 - x + (C1 + C2x - 3x2/32 - x3/24)exp(-x) + C3exp(x/3)) sol2 = Eq(f(x), -1 - x + (C1 + C2x - x*2/8)exp(-x) + C3exp(x/3)) sol3 = Eq(f(x), 2 + C1exp(-x) + C2exp(-2x)) sol4 = Eq(f(x), 2exp(x) + C1exp(-x) + C2exp(-2x)) sol5 = Eq(f(x), C1exp(-2x) + C2exp(-x) + exp(Ix)/10 - 3Iexp(Ix)/10) sol6 = Eq(f(x), -3cos(x)/10 + sin(x)/10 + C1exp(-x) + C2exp(-2x)) sol7 = Eq(f(x), cos(x)/10 + 3sin(x)/10 + C1exp(-x) + C2exp(-2x)) sol8 = Eq(f(x), 4 - 3cos(x)/5 + sin(x)/5 + exp(x) + C1exp(-x) + C2exp(-2x)) sol9 = Eq(f(x), -2x + x*2 + (C1sin(xsqrt(3)/2) + C2cos(xsqrt(3)/2))exp(-x/2)) sol10 = Eq(f(x), -xexp(x) - 2exp(-x) + C1exp(-2x) + C2exp(4x)) sol11 = Eq(f(x), C1 + C2exp(3x) + (-3sin(x) - cos(x))exp(2x)/5) sol12 = Eq(f(x), x - sin(x)/4 + (C1 + C2x)exp(-x) + (C3 + C4x)exp(x)) sol13 = Eq(f(x), C1 + x3/3 + C2exp(-x)) sol14 = Eq(f(x), C1 - x - sin(2x)/5 - cos(2x)/10 + x*2/2 + C2exp(-x)) sol15 = Eq(f(x), (C1 + x)sin(x) + (C2 - x2)cos(x)) sol16 = Eq(f(x), (C1 + x/16)sin(2x) + (C2 - x*2/8)cos(2x)) sol17 = Eq(f(x), (C1 + C2x + x*4/12)exp(-x)) sol18 = Eq(f(x), (C1 + C2x + C3x2 - x5/60 + x*3/3)exp(-x)) sol19 = Eq(f(x), S(7)/4 - 3x/2 + x2/2 + C1exp(-x) + (C2 - x)exp(-2x)) sol20 = Eq(f(x), C1exp(x) + C2exp(2x) + (6x + 5)exp(-x)/36) sol21 = Eq(f(x), -S(1)/36 - x/6 + C1exp(-3x) + (C2 + x/5)exp(2x)) sol22 = Eq(f(x), C1sin(x) + (C2 - x/2)cos(x) + exp(-x)/2) sol23 = Eq(f(x), (C1 + C2x + C3x2 + x3/6)exp(x)) sol24 = Eq(f(x), S(1)/2 - cos(2x)/6 + C1sin(x) + C2cos(x)) sol25 = Eq(f(x), C1 + C2exp(-x) + C3exp(x) + (-21sin(2x) + 27cos(2x) + 130)exp(2x)/1560) sol26 = Eq(f(x), C1 + (C2 + C3x - x*2/8)sin(x) + (C4 + C5x + x2/8)cos(x) + x*2) sol27 = Eq(f(x), cos(3x)/16 + C1cos(x) + (C2 + x/4)sin(x)) sol28 = Eq(f(x), C1 + x) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) sol6s = constant_renumber(sol6) sol7s = constant_renumber(sol7) sol8s = constant_renumber(sol8) sol9s = constant_renumber(sol9) sol10s = constant_renumber(sol10) sol11s = constant_renumber(sol11) sol12s = constant_renumber(sol12) sol13s = constant_renumber(sol13) sol14s = constant_renumber(sol14) sol15s = constant_renumber(sol15) sol16s = constant_renumber(sol16) sol17s = constant_renumber(sol17) sol18s = constant_renumber(sol18) sol19s = constant_renumber(sol19) sol20s = constant_renumber(sol20) sol21s = constant_renumber(sol21) sol22s = constant_renumber(sol22) sol23s = constant_renumber(sol23) sol24s = constant_renumber(sol24) sol25s = constant_renumber(sol25) sol26s = constant_renumber(sol26) sol27s = constant_renumber(sol27) assert dsolve(eq1, hint=hint) in (sol1, sol1s) assert dsolve(eq2, hint=hint) in (sol2, sol2s) assert dsolve(eq3, hint=hint) in (sol3, sol3s) assert dsolve(eq4, hint=hint) in (sol4, sol4s) assert dsolve(eq5, hint=hint) in (sol5, sol5s) assert dsolve(eq6, hint=hint) in (sol6, sol6s) assert dsolve(eq7, hint=hint) in (sol7, sol7s) assert dsolve(eq8, hint=hint) in (sol8, sol8s) assert dsolve(eq9, hint=hint) in (sol9, sol9s) assert dsolve(eq10, hint=hint) in (sol10, sol10s) assert dsolve(eq11, hint=hint) in (sol11, sol11s) assert dsolve(eq12, hint=hint) in (sol12, sol12s) assert dsolve(eq13, hint=hint) in (sol13, sol13s) assert dsolve(eq14, hint=hint) in (sol14, sol14s) assert dsolve(eq15, hint=hint) in (sol15, sol15s) assert dsolve(eq16, hint=hint) in (sol16, sol16s) assert dsolve(eq17, hint=hint) in (sol17, sol17s) assert dsolve(eq18, hint=hint) in (sol18, sol18s) assert dsolve(eq19, hint=hint) in (sol19, sol19s) assert dsolve(eq20, hint=hint) in (sol20, sol20s) assert dsolve(eq21, hint=hint) in (sol21, sol21s) assert dsolve(eq22, hint=hint) in (sol22, sol22s) assert dsolve(eq23, hint=hint) in (sol23, sol23s) assert dsolve(eq24, hint=hint) in (sol24, sol24s) assert dsolve(eq25, hint=hint) in (sol25, sol25s) assert dsolve(eq26, hint=hint) in (sol26, sol26s) assert dsolve(eq27, hint=hint) in (sol27, sol27s) assert dsolve(eq28, hint=hint) == sol28 assert checkodesol(eq1, sol1, order=3, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=3, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=2, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=2, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=2, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=2, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=2, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=2, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=2, solve_for_func=False)[0] assert checkodesol(eq11, sol11, order=2, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=4, solve_for_func=False)[0] assert checkodesol(eq13, sol13, order=2, solve_for_func=False)[0] assert checkodesol(eq14, sol14, order=2, solve_for_func=False)[0] assert checkodesol(eq15, sol15, order=2, solve_for_func=False)[0] assert checkodesol(eq16, sol16, order=2, solve_for_func=False)[0] assert checkodesol(eq17, sol17, order=2, solve_for_func=False)[0] assert checkodesol(eq18, sol18, order=3, solve_for_func=False)[0] assert checkodesol(eq19, sol19, order=2, solve_for_func=False)[0] assert checkodesol(eq20, sol20, order=2, solve_for_func=False)[0] assert checkodesol(eq21, sol21, order=2, solve_for_func=False)[0] assert checkodesol(eq22, sol22, order=2, solve_for_func=False)[0] assert checkodesol(eq23, sol23, order=3, solve_for_func=False)[0] assert checkodesol(eq24, sol24, order=2, solve_for_func=False)[0] assert checkodesol(eq25, sol25, order=3, solve_for_func=False)[0] assert checkodesol(eq26, sol26, order=5, solve_for_func=False)[0] assert checkodesol(eq27, sol27, order=2, solve_for_func=False)[0] assert checkodesol(eq28, sol28, order=1, solve_for_func=False)[0] def test_issue_5787(): # This test case is to show the classification of imaginary constants under # nth_linear_constant_coeff_undetermined_coefficients eq = Eq(diff(f(x), x), If(x) + S(1)/2 - I) our_hint = 'nth_linear_constant_coeff_undetermined_coefficients' assert our_hint in classify_ode(eq) @XFAIL def test_nth_linear_constant_coeff_undetermined_coefficients_imaginary_exp(): # Equivalent to eq26 in # test_nth_linear_constant_coeff_undetermined_coefficients above. # This fails because the algorithm for undetermined coefficients # doesn't know to multiply exp(Ix) by sufficient x because it is linearly # dependent on sin(x) and cos(x). hint = 'nth_linear_constant_coeff_undetermined_coefficients' eq26a = f(x).diff(x, 5) + 2f(x).diff(x, 3) + f(x).diff(x) - 2x - exp(Ix) sol26 = Eq(f(x), C1 + (C2 + C3x - x*2/8)sin(x) + (C4 + C5x + x2/8)cos(x) + x*2) assert dsolve(eq26a, hint=hint) == sol26 assert checkodesol(eq26a, sol26, order=5, solve_for_func=False)[0] @slow def test_nth_linear_constant_coeff_variation_of_parameters(): hint = 'nth_linear_constant_coeff_variation_of_parameters' g = exp(-x) f2 = f(x).diff(x, 2) c = 3f(x).diff(x, 3) + 5f2 + f(x).diff(x) - f(x) - x eq1 = c - xg eq2 = c - g eq3 = f(x).diff(x) - 1 eq4 = f2 + 3f(x).diff(x) + 2f(x) - 4 eq5 = f2 + 3f(x).diff(x) + 2f(x) - 12exp(x) eq6 = f2 - 2f(x).diff(x) - 8f(x) - 9xexp(x) - 10exp(-x) eq7 = f2 + 2f(x).diff(x) + f(x) - x2exp(-x) eq8 = f2 - 3f(x).diff(x) + 2f(x) - xexp(-x) eq9 = f(x).diff(x, 3) - 3f2 + 3f(x).diff(x) - f(x) - exp(x) eq10 = f2 + 2f(x).diff(x) + f(x) - exp(-x)/x eq11 = f2 + f(x) - 1/sin(x)1/cos(x) eq12 = f(x).diff(x, 4) - 1/x sol1 = Eq(f(x), -1 - x + (C1 + C2x - 3x2/32 - x3/24)exp(-x) + C3exp(x/3)) sol2 = Eq(f(x), -1 - x + (C1 + C2x - x*2/8)exp(-x) + C3exp(x/3)) sol3 = Eq(f(x), C1 + x) sol4 = Eq(f(x), 2 + C1exp(-x) + C2exp(-2x)) sol5 = Eq(f(x), 2exp(x) + C1exp(-x) + C2exp(-2x)) sol6 = Eq(f(x), -xexp(x) - 2exp(-x) + C1exp(-2x) + C2exp(4x)) sol7 = Eq(f(x), (C1 + C2x + x4/12)exp(-x)) sol8 = Eq(f(x), C1exp(x) + C2exp(2x) + (6x + 5)exp(-x)/36) sol9 = Eq(f(x), (C1 + C2x + C3x2 + x3/6)exp(x)) sol10 = Eq(f(x), (C1 + x(C2 + log(x)))exp(-x)) sol11 = Eq(f(x), cos(x)(C2 - Integral(1/cos(x), x)) + sin(x)(C1 + Integral(1/sin(x), x))) sol12 = Eq(f(x), C1 + C2x + x3(C3 + log(x)/6) + C4x2) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) sol6s = constant_renumber(sol6) sol7s = constant_renumber(sol7) sol8s = constant_renumber(sol8) sol9s = constant_renumber(sol9) sol10s = constant_renumber(sol10) sol11s = constant_renumber(sol11) sol12s = constant_renumber(sol12) assert dsolve(eq1, hint=hint) in (sol1, sol1s) assert dsolve(eq2, hint=hint) in (sol2, sol2s) assert dsolve(eq3, hint=hint) in (sol3, sol3s) assert dsolve(eq4, hint=hint) in (sol4, sol4s) assert dsolve(eq5, hint=hint) in (sol5, sol5s) assert dsolve(eq6, hint=hint) in (sol6, sol6s) assert dsolve(eq7, hint=hint) in (sol7, sol7s) assert dsolve(eq8, hint=hint) in (sol8, sol8s) assert dsolve(eq9, hint=hint) in (sol9, sol9s) assert dsolve(eq10, hint=hint) in (sol10, sol10s) assert dsolve(eq11, hint=hint + '_Integral') in (sol11, sol11s) assert dsolve(eq12, hint=hint) in (sol12, sol12s) assert checkodesol(eq1, sol1, order=3, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=3, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=2, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=2, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=2, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=2, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=3, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=2, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=4, solve_for_func=False)[0] @slow def test_nth_linear_constant_coeff_variation_of_parameters_simplify_False(): # solve_variation_of_parameters shouldn't attempt to simplify the # Wronskian if simplify=False. If wronskian() ever gets good enough # to simplify the result itself, this test might fail. our_hint = 'nth_linear_constant_coeff_variation_of_parameters_Integral' eq = f(x).diff(x, 5) + 2f(x).diff(x, 3) + f(x).diff(x) - 2x - exp(Ix) sol_simp = dsolve(eq, f(x), hint=our_hint, simplify=True) sol_nsimp = dsolve(eq, f(x), hint=our_hint, simplify=False) assert sol_simp != sol_nsimp assert checkodesol(eq, sol_simp, order=5, solve_for_func=False)[0] assert checkodesol(eq, sol_nsimp, order=5, solve_for_func=False)[0] def test_Liouville_ODE(): hint = 'Liouville' # The first part here used to be test_ODE_1() from test_solvers.py eq1 = diff(f(x), x)/x + diff(f(x), x, x)/2 - diff(f(x), x)*2/2 eq1a = diff(xexp(-f(x)), x, x) # compare to test_unexpanded_Liouville_ODE() below eq2 = (eq1exp(-f(x))/exp(f(x))).expand() eq3 = diff(f(x), x, x) + 1/f(x)(diff(f(x), x))*2 + 1/xdiff(f(x), x) eq4 = xdiff(f(x), x, x) + x/f(x)diff(f(x), x)*2 + xdiff(f(x), x) eq5 = Eq((xexp(f(x))).diff(x, x), 0) sol1 = Eq(f(x), log(x/(C1 + C2x))) sol1a = Eq(C1 + C2/x - exp(-f(x)), 0) sol2 = sol1 sol3 = set( [Eq(f(x), -sqrt(C1 + C2log(x))), Eq(f(x), sqrt(C1 + C2log(x)))]) sol4 = set([Eq(f(x), sqrt(C1 + C2exp(x))exp(-x/2)), Eq(f(x), -sqrt(C1 + C2exp(x))exp(-x/2))]) sol5 = Eq(f(x), log(C1 + C2/x)) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) assert dsolve(eq1, hint=hint) in (sol1, sol1s) assert dsolve(eq1a, hint=hint) in (sol1, sol1s) assert dsolve(eq2, hint=hint) in (sol2, sol2s) assert set(dsolve(eq3, hint=hint)) in (sol3, sol3s) assert set(dsolve(eq4, hint=hint)) in (sol4, sol4s) assert dsolve(eq5, hint=hint) in (sol5, sol5s) assert checkodesol(eq1, sol1, order=2, solve_for_func=False)[0] assert checkodesol(eq1a, sol1a, order=2, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=2, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=2, solve_for_func=False) == {(True, 0)} assert checkodesol(eq4, sol4, order=2, solve_for_func=False) == {(True, 0)} assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] not_Liouville1 = classify_ode(diff(f(x), x)/x + f(x)diff(f(x), x, x)/2 - diff(f(x), x)2/2, f(x)) not_Liouville2 = classify_ode(diff(f(x), x)/x + diff(f(x), x, x)/2 - xdiff(f(x), x)2/2, f(x)) assert hint not in not_Liouville1 assert hint not in not_Liouville2 assert hint + '_Integral' not in not_Liouville1 assert hint + '_Integral' not in not_Liouville2 def test_unexpanded_Liouville_ODE(): # This is the same as eq1 from test_Liouville_ODE() above. eq1 = diff(f(x), x)/x + diff(f(x), x, x)/2 - diff(f(x), x)2/2 eq2 = eq1exp(-f(x))/exp(f(x)) sol2 = Eq(f(x), log(x/(C1 + C2x))) sol2s = constant_renumber(sol2) assert dsolve(eq2) in (sol2, sol2s) assert checkodesol(eq2, sol2, order=2, solve_for_func=False)[0] def test_issue_4785(): from sympy.abc import A eq = x + A(x + diff(f(x), x) + f(x)) + diff(f(x), x) + f(x) + 2 assert classify_ode(eq, f(x)) == ('1st_linear', 'almost_linear', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', '1st_linear_Integral', 'almost_linear_Integral', 'nth_linear_constant_coeff_variation_of_parameters_Integral') # issue 4864 eq = (x2 + f(x)2)f(x).diff(x) - 2xf(x) assert classify_ode(eq, f(x)) == ('1st_exact', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', '1st_exact_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral') def test_issue_4825(): raises(ValueError, lambda: dsolve(f(x, y).diff(x) - yf(x, y), f(x))) assert classify_ode(f(x, y).diff(x) - yf(x, y), f(x), dict=True) == \ {'default': None, 'order': 0} # See also issue 3793, test Z13. raises(ValueError, lambda: dsolve(f(x).diff(x), f(y))) assert classify_ode(f(x).diff(x), f(y), dict=True) == \ {'default': None, 'order': 0} def test_constant_renumber_order_issue_5308(): from sympy.utilities.iterables import variations eq = f(x).diff(x) - y - x assert constant_renumber(C1x + C2y) == \ constant_renumber(C1y + C2x) == \ C1x + C2y e = C1(C2 + x)(C3 + y) for a, b, c in variations([C1, C2, C3], 3): assert constant_renumber(a(b + x)(c + y)) == e def test_issue_5770(): k = Symbol("k", real=True) t = Symbol('t') w = Function('w') sol = dsolve(w(t).diff(t, 6) - k*6w(t), w(t)) assert len([s for s in sol.free_symbols if s.name.startswith('C')]) == 6 assert constantsimp((C1cos(x) + C2cos(x))exp(x), set([C1, C2])) == \ C1cos(x)exp(x) assert constantsimp(C1cos(x) + C2cos(x) + C3sin(x), set([C1, C2, C3])) == \ C1cos(x) + C3sin(x) assert constantsimp(exp(C1 + x), set([C1])) == C1exp(x) assert constantsimp(x + C1 + y, set([C1, y])) == C1 + x assert constantsimp(x + C1 + Integral(x, (x, 1, 2)), set([C1])) == C1 + x def test_issue_5112_5430(): assert homogeneous_order(-log(x) + acosh(x), x) is None assert homogeneous_order(y - log(x), x, y) is None def test_nth_order_linear_euler_eq_homogeneous(): x, t, a, b, c = symbols('x t a b c') y = Function('y') our_hint = "nth_linear_euler_eq_homogeneous" eq = diff(f(t), t, 4)t*4 - 13diff(f(t), t, 2)t2 + 36f(t) assert our_hint in classify_ode(eq) eq = ay(t) + btdiff(y(t), t) + ct*2diff(y(t), t, 2) assert our_hint in classify_ode(eq) eq = Eq(-3diff(f(x), x)x + 2x2diff(f(x), x, x), 0) sol = C1 + C2xRational(5, 2) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(3f(x) - 5diff(f(x), x)x + 2x2diff(f(x), x, x), 0) sol = C1sqrt(x) + C2x*3 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(4f(x) + 5diff(f(x), x)x + x*2diff(f(x), x, x), 0) sol = (C1 + C2log(x))/x2 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(6f(x) - 6diff(f(x), x)x + 1x2diff(f(x), x, x) + x*3diff(f(x), x, x, x), 0) sol = dsolve(eq, f(x), hint=our_hint) sol = C1/x*2 + C2x + C3x3 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(-125f(x) + 61diff(f(x), x)x - 12x2diff(f(x), x, x) + x*3diff(f(x), x, x, x), 0) sol = x*5(C1 + C2log(x) + C3log(x)2) sols = [sol, constant_renumber(sol)] sols += [sols[-1].expand()] assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in sols assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = t2diff(y(t), t, 2) + tdiff(y(t), t) - 9y(t) sol = C1t*3 + C2t*-3 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, y(t), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = sin(x)x*2f(x).diff(x, 2) + sin(x)xf(x).diff(x) + sin(x)f(x) sol = C1sin(log(x)) + C2cos(log(x)) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] def test_nth_order_linear_euler_eq_nonhomogeneous_undetermined_coefficients(): x, t = symbols('x t') a, b, c, d = symbols('a b c d', integer=True) our_hint = "nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients" eq = x4diff(f(x), x, 4) - 13x2diff(f(x), x, 2) + 36f(x) + x assert our_hint in classify_ode(eq, f(x)) eq = ax*2diff(f(x), x, 2) + bxdiff(f(x), x) + cf(x) + dlog(x) assert our_hint in classify_ode(eq, f(x)) eq = Eq(x*2diff(f(x), x, x) + xdiff(f(x), x), 1) sol = C1 + C2log(x) + log(x)2/2 sols = constant_renumber(sol) assert our_hint in classify_ode(eq, f(x)) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x2diff(f(x), x, x) - 2xdiff(f(x), x) + 2f(x), x*3) sol = x(C1 + C2x + Rational(1, 2)x2) sols = constant_renumber(sol) assert our_hint in classify_ode(eq, f(x)) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x2diff(f(x), x, x) - xdiff(f(x), x) - 3f(x), log(x)/x) sol = C1/x + C2x*3 - Rational(1, 16)log(x)/x - Rational(1, 8)log(x)2/x sols = constant_renumber(sol) assert our_hint in classify_ode(eq, f(x)) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x2diff(f(x), x, x) + 3xdiff(f(x), x) - 8f(x), log(x)3 - log(x)) sol = C1/x4 + C2x*2 - Rational(1,8)log(x)*3 - Rational(3,32)log(x)*2 - Rational(1,64)log(x) - Rational(7, 256) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x*3diff(f(x), x, x, x) - 3x2diff(f(x), x, x) + 6xdiff(f(x), x) - 6f(x), log(x)) sol = C1x + C2x2 + C3x*3 - Rational(1, 6)log(x) - Rational(11, 36) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] def test_nth_order_linear_euler_eq_nonhomogeneous_variation_of_parameters(): x, t = symbols('x, t') a, b, c, d = symbols('a, b, c, d', integer=True) our_hint = "nth_linear_euler_eq_nonhomogeneous_variation_of_parameters" eq = Eq(x*2diff(f(x),x,2) - 8xdiff(f(x),x) + 12f(x), x2) assert our_hint in classify_ode(eq, f(x)) eq = Eq(ax*3diff(f(x),x,3) + bx2diff(f(x),x,2) + cxdiff(f(x),x) + df(x), xlog(x)) assert our_hint in classify_ode(eq, f(x)) eq = Eq(x*2Derivative(f(x), x, x) - 2xDerivative(f(x), x) + 2f(x), x4) sol = C1x + C2x2 + x4/6 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(3x*2diff(f(x), x, x) + 6xdiff(f(x), x) - 6f(x), x3exp(x)) sol = C1/x*2 + C2x + xexp(x)/3 - 4exp(x)/3 + 8exp(x)/(3x) - 8exp(x)/(3x2) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x2Derivative(f(x), x, x) - 2xDerivative(f(x), x) + 2f(x), x*4exp(x)) sol = C1x + C2x2 + x2exp(x) - 2xexp(x) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = x2Derivative(f(x), x, x) - 2xDerivative(f(x), x) + 2f(x) - log(x) sol = C1x + C2x2 + log(x)/2 + S(3)/4 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = -exp(x) + (xDerivative(f(x), (x, 2)) + Derivative(f(x), x))/x sol = Eq(f(x), C1 + C2log(x) + exp(x) - Ei(x)) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] def test_issue_5095(): f = Function('f') raises(ValueError, lambda: dsolve(f(x).diff(x)2, f(x), 'separable')) raises(ValueError, lambda: dsolve(f(x).diff(x)2, f(x), 'fdsjf')) def test_almost_linear(): from sympy import Ei A = Symbol('A', positive=True) our_hint = 'almost_linear' f = Function('f') d = f(x).diff(x) eq = x2f(x)*2d + f(x)*3 + 1 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol[0].rhs == (C1exp(3/x) - 1)*(S(1)/3) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = xf(x)d + 2xf(x)2 + 1 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol[0].rhs == -sqrt(C1 - 2Ei(4x))exp(-2x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = xd + xf(x) + 1 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol.rhs == (C1 - Ei(x))exp(-x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] assert our_hint in classify_ode(eq, f(x)) eq = xexp(f(x))d + exp(f(x)) + 3x sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol.rhs == log(C1/x - 3x/2) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = x + A(x + diff(f(x), x) + f(x)) + diff(f(x), x) + f(x) + 2 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol.rhs == (C1 + Piecewise( (x, Eq(A + 1, 0)), ((-Ax + A - x - 1)exp(x)/(A + 1), True)))exp(-x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_exact_enhancement(): f = Function('f')(x) df = Derivative(f, x) eq = f/x*2 + ((fx - 1)/x)df sol = [Eq(f, (isqrt(C1x2 + 1) + 1)/x) for i in (-1, 1)] assert set(dsolve(eq, f)) == set(sol) assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0), (True, 0)] eq = (xf - 1) + df(x2 - xf) sol = [Eq(f, x - sqrt(C1 + x*2 - 2log(x))), Eq(f, x + sqrt(C1 + x*2 - 2log(x)))] assert set(dsolve(eq, f)) == set(sol) assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0), (True, 0)] eq = (x + 2)sin(f) + dfxcos(f) sol = [Eq(f, -asin(C1exp(-x)/x*2) + pi), Eq(f, asin(C1exp(-x)/x*2))] assert set(dsolve(eq, f)) == set(sol) assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0), (True, 0)] @slow def test_separable_reduced(): f = Function('f') x = Symbol('x') df = f(x).diff(x) eq = (x / f(x))df + tan(x*2f(x) / (x*2f(x) - 1)) assert classify_ode(eq) == ('separable_reduced', 'lie_group', 'separable_reduced_Integral') eq = x* df + f(x)* (1 / (x*2f(x) - 1)) assert classify_ode(eq) == ('separable_reduced', 'lie_group', 'separable_reduced_Integral') sol = dsolve(eq, hint = 'separable_reduced', simplify=False) assert sol.lhs == log(x*2f(x))/3 + log(x*2f(x) - S(3)/2)/6 assert sol.rhs == C1 + log(x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = f(x).diff(x) + (f(x) / (x*4f(x) - x)) assert classify_ode(eq) == ('separable_reduced', 'lie_group', 'separable_reduced_Integral') sol = dsolve(eq, hint = 'separable_reduced') # FIXME: This one hangs #assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0)] * 4 assert len(sol) == 4 eq = xdf + f(x)(x*2f(x)) sol = dsolve(eq, hint = 'separable_reduced', simplify=False) assert sol == Eq(log(x*2f(x))/2 - log(x*2f(x) - 2)/2, C1 + log(x)) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_homogeneous_function(): f = Function('f') eq1 = tan(x + f(x)) eq2 = sin((3x)/(4f(x))) eq3 = cos(3x/4f(x)) eq4 = log((3x + 4f(x))/(5f(x) + 7x)) eq5 = exp((2x2)/(3f(x)*2)) eq6 = log((3x + 4f(x))/(5f(x) + 7x) + exp((2x*2)/(3f(x)*2))) eq7 = sin((3x)/(5f(x) + x2)) assert homogeneous_order(eq1, x, f(x)) == None assert homogeneous_order(eq2, x, f(x)) == 0 assert homogeneous_order(eq3, x, f(x)) == None assert homogeneous_order(eq4, x, f(x)) == 0 assert homogeneous_order(eq5, x, f(x)) == 0 assert homogeneous_order(eq6, x, f(x)) == 0 assert homogeneous_order(eq7, x, f(x)) == None def test_linear_coeff_match(): from sympy.solvers.ode import _linear_coeff_match n, d = z(2x + 3f(x) + 5), z(7x + 9f(x) + 11) rat = n/d eq1 = sin(rat) + cos(rat.expand()) eq2 = rat eq3 = log(sin(rat)) ans = (4, -S(13)/3) assert _linear_coeff_match(eq1, f(x)) == ans assert _linear_coeff_match(eq2, f(x)) == ans assert _linear_coeff_match(eq3, f(x)) == ans # no c eq4 = (3x)/f(x) # not x and f(x) eq5 = (3x + 2)/x # denom will be zero eq6 = (3x + 2f(x) + 1)/(3x + 2f(x) + 5) # not rational coefficient eq7 = (3x + 2f(x) + sqrt(2))/(3x + 2f(x) + 5) assert _linear_coeff_match(eq4, f(x)) is None assert _linear_coeff_match(eq5, f(x)) is None assert _linear_coeff_match(eq6, f(x)) is None assert _linear_coeff_match(eq7, f(x)) is None def test_linear_coefficients(): f = Function('f') sol = Eq(f(x), C1/(x2 + 6x + 9) - S(3)/2) eq = f(x).diff(x) + (3 + 2f(x))/(x + 3) assert dsolve(eq, hint='linear_coefficients') == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_constantsimp_take_problem(): c = exp(C1) + 2 assert len(Poly(constantsimp(exp(C1) + c + cx, [C1])).gens) == 2 def test_issue_6879(): f = Function('f') eq = Eq(Derivative(f(x), x, 2) - 2Derivative(f(x), x) + f(x), sin(x)) sol = (C1 + C2x)exp(x) + cos(x)/2 assert dsolve(eq).rhs == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_issue_6989(): f = Function('f') k = Symbol('k') eq = f(x).diff(x) - xexp(-kx) sol = Eq(f(x), C1 + Piecewise( ((-kx - 1)exp(-kx)/k2, Ne(k2, 0)), (x*2/2, True) )) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = -f(x).diff(x) + xexp(-kx) sol = Eq(f(x), C1 + Piecewise( ((-kx - 1)exp(-kx)/k2, Ne(k2, 0)), (+x2/2, True) )) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_heuristic1(): y, a, b, c, a4, a3, a2, a1, a0 = symbols("y a b c a4 a3 a2 a1 a0") y = Symbol('y') f = Function('f') xi = Function('xi') eta = Function('eta') df = f(x).diff(x) eq = Eq(df, x2f(x)) eq1 = f(x).diff(x) + af(x) - cexp(bx) eq2 = f(x).diff(x) + 2xf(x) - xexp(-x2) eq3 = (1 + 2x)df + 2 - 4exp(-f(x)) eq4 = f(x).diff(x) - (a4x4 + a3x*3 + a2x*2 + a1x + a0)(S(-1)/2) eq5 = x2df - f(x) + x2exp(x - (1/x)) eqlist = [eq, eq1, eq2, eq3, eq4, eq5] i = infinitesimals(eq, hint='abaco1_simple') assert i == [{eta(x, f(x)): exp(x3/3), xi(x, f(x)): 0}, {eta(x, f(x)): f(x), xi(x, f(x)): 0}, {eta(x, f(x)): 0, xi(x, f(x)): x(-2)}] i1 = infinitesimals(eq1, hint='abaco1_simple') assert i1 == [{eta(x, f(x)): exp(-ax), xi(x, f(x)): 0}] i2 = infinitesimals(eq2, hint='abaco1_simple') assert i2 == [{eta(x, f(x)): exp(-x2), xi(x, f(x)): 0}] i3 = infinitesimals(eq3, hint='abaco1_simple') assert i3 == [{eta(x, f(x)): 0, xi(x, f(x)): 2x + 1}, {eta(x, f(x)): 0, xi(x, f(x)): 1/(exp(f(x)) - 2)}] i4 = infinitesimals(eq4, hint='abaco1_simple') assert i4 == [{eta(x, f(x)): 1, xi(x, f(x)): 0}, {eta(x, f(x)): 0, xi(x, f(x)): sqrt(a0 + a1x + a2x*2 + a3x*3 + a4x4)}] i5 = infinitesimals(eq5, hint='abaco1_simple') assert i5 == [{xi(x, f(x)): 0, eta(x, f(x)): exp(-1/x)}] ilist = [i, i1, i2, i3, i4, i5] for eq, i in (zip(eqlist, ilist)): check = checkinfsol(eq, i) assert check[0] def test_issue_6247(): eq = x2f(x)2 + xDerivative(f(x), x) sol = Eq(f(x), 2C1/(C1x*2 - 1)) assert dsolve(eq, hint = 'separable_reduced') == sol assert checkodesol(eq, sol, order=1)[0] eq = f(x).diff(x, x) + 4f(x) sol = Eq(f(x), C1sin(2x) + C2cos(2x)) assert dsolve(eq) == sol assert checkodesol(eq, sol, order=1)[0] def test_heuristic2(): y = Symbol('y') xi = Function('xi') eta = Function('eta') df = f(x).diff(x) # This ODE can be solved by the Lie Group method, when there are # better assumptions eq = df - (f(x)/x)(xlog(x*2/f(x)) + 2) i = infinitesimals(eq, hint='abaco1_product') assert i == [{eta(x, f(x)): f(x)exp(-x), xi(x, f(x)): 0}] assert checkinfsol(eq, i)[0] @slow def test_heuristic3(): y = Symbol('y') xi = Function('xi') eta = Function('eta') a, b = symbols("a b") df = f(x).diff(x) eq = x*2df + xf(x) + f(x)2 + x2 i = infinitesimals(eq, hint='bivariate') assert i == [{eta(x, f(x)): f(x), xi(x, f(x)): x}] assert checkinfsol(eq, i)[0] eq = x2(-f(x)*2 + df)- ax*2f(x) + 2 - ax i = infinitesimals(eq, hint='bivariate') assert checkinfsol(eq, i)[0] def test_heuristic_4(): y, a = symbols("y a") xi = Function('xi') eta = Function('eta') eq = x(f(x).diff(x)) + 1 - f(x)*2 i = infinitesimals(eq, hint='chi') assert checkinfsol(eq, i)[0] def test_heuristic_function_sum(): xi = Function('xi') eta = Function('eta') eq = f(x).diff(x) - (3(1 + x2/f(x)2)atan(f(x)/x) + (1 - 2f(x))/x + (1 - 3f(x))(x/f(x)2)) i = infinitesimals(eq, hint='function_sum') assert i == [{eta(x, f(x)): f(x)(-2) + x*(-2), xi(x, f(x)): 0}] assert checkinfsol(eq, i)[0] def test_heuristic_abaco2_similar(): xi = Function('xi') eta = Function('eta') F = Function('F') a, b = symbols("a b") eq = f(x).diff(x) - F(ax + bf(x)) i = infinitesimals(eq, hint='abaco2_similar') assert i == [{eta(x, f(x)): -a/b, xi(x, f(x)): 1}] assert checkinfsol(eq, i)[0] eq = f(x).diff(x) - (f(x)2 / (sin(f(x) - x) - x2 + 2xf(x))) i = infinitesimals(eq, hint='abaco2_similar') assert i == [{eta(x, f(x)): f(x)2, xi(x, f(x)): f(x)2}] assert checkinfsol(eq, i)[0] def test_heuristic_abaco2_unique_unknown(): xi = Function('xi') eta = Function('eta') F = Function('F') a, b = symbols("a b") x = Symbol("x", positive=True) eq = f(x).diff(x) - x(a - 1)(f(x)*(1 - b))F(xa/a + f(x)b/b) i = infinitesimals(eq, hint='abaco2_unique_unknown') assert i == [{eta(x, f(x)): -f(x)f(x)(-b), xi(x, f(x)): xx(-a)}] assert checkinfsol(eq, i)[0] eq = f(x).diff(x) + tan(F(x2 + f(x)*2) + atan(x/f(x))) i = infinitesimals(eq, hint='abaco2_unique_unknown') assert i == [{eta(x, f(x)): x, xi(x, f(x)): -f(x)}] assert checkinfsol(eq, i)[0] eq = (xf(x).diff(x) + f(x) + 2x)2 -4xf(x) -4x*2 -4a i = infinitesimals(eq, hint='abaco2_unique_unknown') assert checkinfsol(eq, i)[0] def test_heuristic_linear(): xi = Function('xi') eta = Function('eta') F = Function('F') a, b, m, n = symbols("a b m n") eq = x*(n(m + 1) - m)(f(x).diff(x)) - af(x)*n -bx*(n(m + 1)) i = infinitesimals(eq, hint='linear') assert checkinfsol(eq, i)[0] @XFAIL def test_kamke(): a, b, alpha, c = symbols("a b alpha c") eq = x*2(af(x)2+(f(x).diff(x))) + bx*alpha + c i = infinitesimals(eq, hint='sum_function') assert checkinfsol(eq, i)[0] def test_series(): # FIXME: Maybe there should be a way to check series solutions # checkodesol doesn't work with them. C1 = Symbol("C1") eq = f(x).diff(x) - f(x) assert dsolve(eq, hint='1st_power_series') == Eq(f(x), C1 + C1x + C1x2/2 + C1x*3/6 + C1x*4/24 + C1x5/120 + O(x6)) eq = f(x).diff(x) - xf(x) assert dsolve(eq, hint='1st_power_series') == Eq(f(x), C1x*4/8 + C1x2/2 + C1 + O(x6)) eq = f(x).diff(x) - sin(xf(x)) sol = Eq(f(x), (x - 2)2(1+ sin(4))cos(4) + (x - 2)sin(4) + 2 + O(x3)) assert dsolve(eq, hint='1st_power_series', ics={f(2): 2}, n=3) == sol @slow def test_lie_group(): C1 = Symbol("C1") x = Symbol("x") # assuming x is real generates an error! a, b, c = symbols("a b c") eq = f(x).diff(x)2 sol = dsolve(eq, f(x), hint='lie_group') assert checkodesol(eq, sol)[0] eq = Eq(f(x).diff(x), x*2f(x)) sol = dsolve(eq, f(x), hint='lie_group') assert sol == Eq(f(x), C1exp(x3)(S(1)/3)) assert checkodesol(eq, sol)[0] eq = f(x).diff(x) + af(x) - cexp(bx) sol = dsolve(eq, f(x), hint='lie_group') assert checkodesol(eq, sol)[0] eq = f(x).diff(x) + 2xf(x) - xexp(-x2) sol = dsolve(eq, f(x), hint='lie_group') actual_sol = Eq(f(x), (C1 + x2/2)exp(-x*2)) errstr = str(eq)+' : '+str(sol)+' == '+str(actual_sol) assert sol == actual_sol, errstr assert checkodesol(eq, sol)[0] eq = (1 + 2x)(f(x).diff(x)) + 2 - 4exp(-f(x)) sol = dsolve(eq, f(x), hint='lie_group') assert sol == Eq(f(x), log(C1/(2x + 1) + 2)) assert checkodesol(eq, sol)[0] eq = x2(f(x).diff(x)) - f(x) + x*2exp(x - (1/x)) sol = dsolve(eq, f(x), hint='lie_group') assert checkodesol(eq, sol)[0] eq = x*2f(x)*2 + xDerivative(f(x), x) sol = dsolve(eq, f(x), hint='lie_group') assert sol == Eq(f(x), 2/(C1 + x*2)) assert checkodesol(eq, sol)[0] @XFAIL def test_lie_group_issue15219(): eqn = exp(f(x).diff(x)-f(x)) assert 'lie_group' not in classify_ode(eqn, f(x)) def test_user_infinitesimals(): x = Symbol("x") # assuming x is real generates an error eq = x(f(x).diff(x)) + 1 - f(x)2 sol = Eq(f(x), (C1 + x2)/(C1 - x2)) infinitesimals = {'xi':sqrt(f(x) - 1)/sqrt(f(x) + 1), 'eta':0} assert dsolve(eq, hint='lie_group', infinitesimals) == sol assert checkodesol(eq, sol) == (True, 0) raises(ValueError, lambda: dsolve(eq, hint='lie_group', xi=0, eta=f(x))) def test_issue_7081(): eq = x(f(x).diff(x)) + 1 - f(x)2 s = Eq(f(x), -1/(-C1 + x2)(C1 + x*2)) assert dsolve(eq) == s assert checkodesol(eq, s) == (True, 0) @slow def test_2nd_power_series_ordinary(): # FIXME: Maybe there should be a way to check series solutions # checkodesol doesn't work with them. C1, C2 = symbols("C1 C2") eq = f(x).diff(x, 2) - xf(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2(x3/6 + 1) + C1x(x3/12 + 1) + O(x6)) assert dsolve(eq, x0=-2) == Eq(f(x), C2((x + 2)4/6 + (x + 2)3/6 - (x + 2)*2 + 1) + C1(x + (x + 2)4/12 - (x + 2)3/3 + S(2)) + O(x*6)) assert dsolve(eq, n=2) == Eq(f(x), C2x + C1 + O(x2)) eq = (1 + x2)(f(x).diff(x, 2)) + 2x(f(x).diff(x)) -2f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2(-x4/3 + x2 + 1) + C1x + O(x*6)) eq = f(x).diff(x, 2) + x(f(x).diff(x)) + f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2( x4/8 - x2/2 + 1) + C1x(-x2/3 + 1) + O(x6)) eq = f(x).diff(x, 2) + f(x).diff(x) - xf(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2( -x4/24 + x3/6 + 1) + C1x(x3/24 + x2/6 - x/2 + 1) + O(x6)) eq = f(x).diff(x, 2) + xf(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq, n=7) == Eq(f(x), C2( x6/180 - x3/6 + 1) + C1x(-x3/12 + 1) + O(x7)) def test_2nd_power_series_regular(): # FIXME: Maybe there should be a way to check series solutions # checkodesol doesn't work with them. C1, C2 = symbols("C1 C2") eq = x2(f(x).diff(x, 2)) - 3x(f(x).diff(x)) + (4x + 4)f(x) assert dsolve(eq) == Eq(f(x), C1x2(-16x3/9 + 4x*2 - 4x + 1) + O(x*6)) eq = 4x*2(f(x).diff(x, 2)) -8x2(f(x).diff(x)) + (4x2 + 1)f(x) assert dsolve(eq) == Eq(f(x), C1sqrt(x)( x4/24 + x3/6 + x2/2 + x + 1) + O(x6)) eq = x*2(f(x).diff(x, 2)) - x*2(f(x).diff(x)) + ( x*2 - 2)f(x) assert dsolve(eq) == Eq(f(x), C1(-x6/720 - 3x5/80 - x4/8 + x*2/2 + x/2 + 1)/x + C2x*2(-x3/60 + x2/20 + x/2 + 1) + O(x6)) eq = x2(f(x).diff(x, 2)) + x(f(x).diff(x)) + (x*2 - S(1)/4)f(x) assert dsolve(eq) == Eq(f(x), C1(x4/24 - x2/2 + 1)/sqrt(x) + C2sqrt(x)(x4/120 - x2/6 + 1) + O(x6)) eq = x(f(x).diff(x, 2)) - f(x).diff(x) + 4x3f(x) assert dsolve(eq) == Eq(f(x), C2(-x4/2 + 1) + C1x2 + O(x6)) def test_issue_7093(): x = Symbol("x") # assuming x is real leads to an error sol = [Eq(f(x), C1 - 2xsqrt(x*3)/5), Eq(f(x), C1 + 2xsqrt(x3)/5)] eq = Derivative(f(x), x)2 - x3 assert set(dsolve(eq)) == set(sol) assert checkodesol(eq, sol) == [(True, 0)] 2 def test_dsolve_linsystem_symbol(): eps = Symbol('epsilon', positive=True) eq1 = (Eq(diff(f(x), x), -epsg(x)), Eq(diff(g(x), x), epsf(x))) sol1 = [Eq(f(x), -C1epscos(epsx) - C2epssin(epsx)), Eq(g(x), -C1epssin(epsx) + C2epscos(epsx))] assert checksysodesol(eq1, sol1) == (True, [0, 0]) def test_C1_function_9239(): t = Symbol('t') C1 = Function('C1') C2 = Function('C2') C3 = Symbol('C3') C4 = Symbol('C4') eq = (Eq(diff(C1(t), t), 9C2(t)), Eq(diff(C2(t), t), 12C1(t))) sol = [Eq(C1(t), 9C3exp(6sqrt(3)t) + 9C4exp(-6sqrt(3)t)), Eq(C2(t), 6sqrt(3)C3exp(6sqrt(3)t) - 6sqrt(3)C4exp(-6sqrt(3)t))] assert checksysodesol(eq, sol) == (True, [0, 0]) def test_issue_15056(): t = Symbol('t') C3 = Symbol('C3') assert get_numbered_constants(Symbol('C1') * Function('C2')(t)) == C3 def test_issue_10379(): t,y = symbols('t,y') eq = f(t).diff(t)-(1-51.05yf(t)) sol = Eq(f(t), (0.019588638589618exp(y(C1 - 51.05t)) + 0.019588638589618)/y) dsolve_sol = dsolve(eq, rational=False) assert str(dsolve_sol) == str(sol) assert checkodesol(eq, dsolve_sol)[0] def test_issue_10867(): x = Symbol('x') eq = Eq(g(x).diff(x).diff(x), (x-2)2 + (x-3)3) sol = Eq(g(x), C1 + C2x + x*5/20 - 2x*4/3 + 23x*3/6 - 23x*2/2) assert dsolve(eq, g(x)) == sol assert checkodesol(eq, sol, order=2, solve_for_func=False) == (True, 0) def test_issue_11290(): eq = cos(f(x)) - (xsin(f(x)) - f(x)*2)f(x).diff(x) sol_1 = dsolve(eq, f(x), simplify=False, hint='1st_exact_Integral') sol_0 = dsolve(eq, f(x), simplify=False, hint='1st_exact') assert sol_1.dummy_eq(Eq(Subs( Integral(u*2 - xsin(u) - Integral(-sin(u), x), u) + Integral(cos(u), x), u, f(x)), C1)) assert sol_1.doit() == sol_0 assert checkodesol(eq, sol_0, order=1, solve_for_func=False) assert checkodesol(eq, sol_1, order=1, solve_for_func=False) def test_issue_4838(): # Issue #15999 eq = f(x).diff(x) - C1f(x) sol = Eq(f(x), C2exp(C1x)) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False) == (True, 0) # Issue #13691 eq = f(x).diff(x) - C1g(x).diff(x) sol = Eq(f(x), C2 + C1g(x)) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, f(x), order=1, solve_for_func=False) == (True, 0) # Issue #4838 eq = f(x).diff(x) - 3C1 - 3x2 sol = Eq(f(x), C2 + 3C1x + x3) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False) == (True, 0) @slow def test_issue_14395(): eq = Derivative(f(x), x, x) + 9f(x) - sec(x) sol = Eq(f(x), (C1 - x/3 + sin(2x)/3)sin(3x) + (C2 + log(cos(x)) - 2log(cos(x)*2)/3 + 2cos(x)*2/3)cos(3x)) assert dsolve(eq, f(x)) == sol # FIXME: assert checkodesol(eq, sol, order=2, solve_for_func=False) == (True, 0) def test_sysode_linear_neq_order1(): from sympy.abc import t Z0 = Function('Z0') Z1 = Function('Z1') Z2 = Function('Z2') Z3 = Function('Z3') k01, k10, k20, k21, k23, k30 = symbols('k01 k10 k20 k21 k23 k30') eq = (Eq(Derivative(Z0(t), t), -k01Z0(t) + k10Z1(t) + k20Z2(t) + k30Z3(t)), Eq(Derivative(Z1(t), t), k01Z0(t) - k10Z1(t) + k21Z2(t)), Eq(Derivative(Z2(t), t), -(k20 + k21 + k23)Z2(t)), Eq(Derivative(Z3(t), t), k23Z2(t) - k30Z3(t))) sols_eq = [Eq(Z0(t), C1k10/k01 + C2(-k10 + k30)exp(-k30t)/(k01 + k10 - k30) - C3exp(t(- k01 - k10)) + C4(k10k20 + k10k21 - k10k30 - k202 - k20k21 - k20k23 + k20k30 + k23k30)exp(t(-k20 - k21 - k23))/(k23(k01 + k10 - k20 - k21 - k23))), Eq(Z1(t), C1 - C2k01exp(-k30t)/(k01 + k10 - k30) + C3exp(t(-k01 - k10)) + C4(k01k20 + k01k21 - k01k30 - k20k21 - k21*2 - k21k23 + k21k30)exp(t(-k20 - k21 - k23))/(k23(k01 + k10 - k20 - k21 - k23))), Eq(Z2(t), C4(-k20 - k21 - k23 + k30)exp(t(-k20 - k21 - k23))/k23), Eq(Z3(t), C2exp(-k30t) + C4exp(t(-k20 - k21 - k23)))] assert dsolve(eq, simplify=False) == sols_eq assert checksysodesol(eq, sols_eq) == (True, [0, 0, 0, 0]) def test_nth_order_reducible(): from sympy.solvers.ode import _nth_order_reducible_match eqn = Eq(xDerivative(f(x), x)*2 + Derivative(f(x), x, 2), 0) sol = Eq(f(x), C1 - sqrt(-1/C2)log(-C2sqrt(-1/C2) + x) + sqrt(-1/C2)log(C2sqrt(-1/C2) + x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert sol == dsolve(eqn, f(x), hint='nth_order_reducible') assert sol == dsolve(eqn, f(x)) F = lambda eq: _nth_order_reducible_match(eq, f(x)) D = Derivative assert F(D(yf(x), x, y) + D(f(x), x)) is None assert F(D(yf(y), y, y) + D(f(y), y)) is None assert F(f(x)D(f(x), x) + D(f(x), x, 2)) is None assert F(D(xf(y), y, 2) + D(uyf(x), x, 3)) is None # no simplification by design assert F(D(f(y), y, 2) + D(f(y), y, 3) + D(f(x), x, 4)) is None assert F(D(f(x), x, 2) + D(f(x), x, 3)) == dict(n=2) eqn = -exp(x) + (xDerivative(f(x), (x, 2)) + Derivative(f(x), x))/x sol = Eq(f(x), C1 + C2log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert sol == dsolve(eqn, f(x)) assert sol == dsolve(eqn, f(x), hint='nth_order_reducible') eqn = Eq(sqrt(2) f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2sin(2(S(3)/4)x/2) + C3cos(2(S(3)/4)x/2)) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert sol == dsolve(eqn, f(x)) assert sol == dsolve(eqn, f(x), hint='nth_order_reducible') eqn = f(x).diff(x, 2) + 2f(x).diff(x) sol = Eq(f(x), C1 + C2exp(-2x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 3) + f(x).diff(x, 2) - 6f(x).diff(x) sol = Eq(f(x), C1 + C2exp(-3x) + C3exp(2x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) - f(x).diff(x, 3) - 4f(x).diff(x, 2) + \ 4f(x).diff(x) sol = Eq(f(x), C1 + C2exp(x) + C3exp(-2x) + C4exp(2x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) + 3f(x).diff(x, 3) sol = Eq(f(x), C1 + C2x + C3x*2 + C4exp(-3x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) - 2f(x).diff(x, 2) sol = Eq(f(x), C1 + C2x + C3exp(xsqrt(2)) + C4exp(-xsqrt(2))) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) + 4f(x).diff(x, 2) sol = Eq(f(x), C1 + C2sin(2x) + C3cos(2x) + C4x) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 5) + 2f(x).diff(x, 3) + f(x).diff(x) # These are equivalent: sol1 = Eq(f(x), C1 + (C2 + C3x)sin(x) + (C4 + C5x)cos(x)) sol2 = Eq(f(x), C1 + C2(xsin(x) + cos(x)) + C3(-xcos(x) + sin(x)) + C4sin(x) + C5cos(x)) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) assert checkodesol(eqn, sol1, order=2, solve_for_func=False) == (True, 0) assert checkodesol(eqn, sol2, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol1, sol1s) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol2, sol2s) # In this case the reduced ODE has two distinct solutions eqn = f(x).diff(x, 2) - f(x).diff(x)*3 sol = [Eq(f(x), C2 - sqrt(2)I(C1 + x)sqrt(1/(C1 + x))), Eq(f(x), C2 + sqrt(2)I(C1 + x)sqrt(1/(C1 + x)))] sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == [(True, 0), (True, 0)] assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) def test_nth_algebraic(): eqn = Eq(Derivative(f(x), x), Derivative(g(x), x)) sol = Eq(f(x), C1 + g(x)) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = (diff(f(x)) - x)(diff(f(x)) + x) sol = [Eq(f(x), C1 - x2/2), Eq(f(x), C1 + x2/2)] assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = (1 - sin(f(x))) * f(x).diff(x) sol = Eq(f(x), C1) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) M, m, r, t = symbols('M m r t') phi = Function('phi') eqn = Eq(-M * phi(t).diff(t), Rational(3, 2) * m * r*2 phi(t).diff(t) * phi(t).diff(t,t)) solns = [Eq(phi(t), C1), Eq(phi(t), C1 + C2t - Mt*2/(3mr2))] assert checkodesol(eqn, solns[0], order=2, solve_for_func=False)[0] assert checkodesol(eqn, solns[1], order=2, solve_for_func=False)[0] assert set(solns) == set(dsolve(eqn, phi(t), hint='nth_algebraic')) assert set(solns) == set(dsolve(eqn, phi(t))) eqn = f(x) f(x).diff(x) * f(x).diff(x, x) sol = Eq(f(x), C1 + C2x) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = f(x) f(x).diff(x) * f(x).diff(x, x) * (f(x) - 1) sol = Eq(f(x), C1 + C2x) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = f(x) f(x).diff(x) * f(x).diff(x, x) * (f(x) - 1) * (f(x).diff(x) - x) solns = [Eq(f(x), C1 + x*2/2), Eq(f(x), C1 + C2x)] assert checkodesol(eqn, solns[0], order=2, solve_for_func=False)[0] assert checkodesol(eqn, solns[1], order=2, solve_for_func=False)[0] assert set(solns) == set(dsolve(eqn, f(x), hint='nth_algebraic')) assert set(solns) == set(dsolve(eqn, f(x))) def test_nth_algebraic_issue15999(): eqn = f(x).diff(x) - C1 sol = Eq(f(x), C1x + C2) # Correct solution assert checkodesol(eqn, sol, order=1, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x), hint='nth_algebraic') == sol assert dsolve(eqn, f(x)) == sol def test_nth_algebraic_redundant_solutions(): # This one has a redundant solution that should be removed eqn = f(x)f(x).diff(x) soln = Eq(f(x), C1) assert checkodesol(eqn, soln, order=1, solve_for_func=False)[0] assert soln == dsolve(eqn, f(x), hint='nth_algebraic') assert soln == dsolve(eqn, f(x)) # This has two integral solutions and no algebraic solutions eqn = (diff(f(x)) - x)(diff(f(x)) + x) sol = [Eq(f(x), C1 - x2/2), Eq(f(x), C1 + x2/2)] assert all(c[0] for c in checkodesol(eqn, sol, order=1, solve_for_func=False)) assert set(sol) == set(dsolve(eqn, f(x), hint='nth_algebraic')) assert set(sol) == set(dsolve(eqn, f(x))) # This one doesn't work with dsolve at the time of writing but the # redundancy checking code should not remove the algebraic solution. from sympy.solvers.ode import _nth_algebraic_remove_redundant_solutions eqn = f(x) + f(x)f(x).diff(x) solns = [Eq(f(x), 0), Eq(f(x), C1 - x)] solns_final = _nth_algebraic_remove_redundant_solutions(eqn, solns, 1, x) assert all(c[0] for c in checkodesol(eqn, solns, order=1, solve_for_func=False)) assert set(solns) == set(solns_final) solns = [Eq(f(x), exp(x)), Eq(f(x), C1exp(C2x))] solns_final = _nth_algebraic_remove_redundant_solutions(eqn, solns, 2, x) assert solns_final == [Eq(f(x), C1exp(C2x))] # This one needs a substitution f' = g. eqn = -exp(x) + (xDerivative(f(x), (x, 2)) + Derivative(f(x), x))/x sol = Eq(f(x), C1 + C2log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x)) # # These tests can be combined with the above test if they get fixed # so that dsolve actually works in all these cases. # # Fails due to division by f(x) eliminating the solution before nth_algebraic # is called. @XFAIL def test_nth_algebraic_find_multiple1(): eqn = f(x) + f(x)f(x).diff(x) solns = [Eq(f(x), 0), Eq(f(x), C1 - x)] assert all(c[0] for c in checkodesol(eqn, solns, order=1, solve_for_func=False)) assert set(solns) == set(dsolve(eqn, f(x))) # prep = True breaks this def test_nth_algebraic_noprep1(): eqn = Derivative(xf(x), x, x, x) sol = Eq(f(x), (C1 + C2x + C3x*2) / x) assert checkodesol(eqn, sol, order=3, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=False, hint='nth_algebraic') @XFAIL def test_nth_algebraic_prep1(): eqn = Derivative(xf(x), x, x, x) sol = Eq(f(x), (C1 + C2x + C3x*2) / x) assert checkodesol(eqn, sol, order=3, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=True, hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) # prep = True breaks this def test_nth_algebraic_noprep2(): eqn = Eq(Derivative(xDerivative(f(x), x), x)/x, exp(x)) sol = Eq(f(x), C1 + C2log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=False, hint='nth_algebraic') @XFAIL def test_nth_algebraic_prep2(): eqn = Eq(Derivative(xDerivative(f(x), x), x)/x, exp(x)) sol = Eq(f(x), C1 + C2log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=True, hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) # This needs a combination of solutions from nth_algebraic and some other # method from dsolve @XFAIL def test_nth_algebraic_find_multiple2(): eqn = f(x)2 + f(x)f(x).diff(x) solns = [Eq(f(x), 0), Eq(f(x), C1exp(-x))] assert all(c[0] for c in checkodesol(eqn, solns, order=1, solve_for_func=False)) assert set(solns) == dsolve(eqn, f(x)) # Needs to be a way to know how to combine derivatives in the expression @XFAIL def test_factoring_ode(): eqn = Derivative(xf(x), x, x, x) + Derivative(f(x), x, x, x) soln = Eq(f(x), (C1x2/2 + C2x + C3 - x)/(1 + x)) assert checkodesol(eqn, soln, order=2, solve_for_func=False)[0] assert soln == dsolve(eqn, f(x)) def test_issue_11542(): m = 96 g = 9.8 k = .2 f1 = g * m t = Symbol('t') v = Function('v') v_equation = dsolve(f1 - k * (v(t) ** 2) - m * Derivative(v(t)), 0) assert str(v_equation) == \ 'Eq(v(t), -68.585712797929/tanh(C1 - 0.142886901662352t))' def test_issue_15913(): eq = -C1/x - 2xf(x) - f(x) + Derivative(f(x), x) sol = C2exp(x2 + x) + exp(x2 + x)Integral(C1exp(-x*2 - x)/x, x) assert checkodesol(eq, sol) == (True, 0) sol = C1 + C2exp(-xy) eq = Derivative(yf(x), x) + f(x).diff(x, 2) assert checkodesol(eq, sol, f(x)) == (True, 0) def test_issue_16146(): raises(ValueError, lambda: dsolve([f(x).diff(x), g(x).diff(x)], [f(x), g(x), h(x)])) raises(ValueError, lambda: dsolve([f(x).diff(x), g(x).diff(x)], [f(x)]))

215f5f73b2075562ae87610060003ef7bdba266813666636542a14607377e7f2

from __future__ import print_function, division from sympy.core.sympify import _sympify from sympy.core import S, Basic from sympy.matrices.expressions.matexpr import ShapeError from sympy.matrices.expressions.matpow import MatPow class Inverse(MatPow): """ The multiplicative inverse of a matrix expression This is a symbolic object that simply stores its argument without evaluating it. To actually compute the inverse, use the ``.inverse()`` method of matrices. Examples ======== >>> from sympy import MatrixSymbol, Inverse >>> A = MatrixSymbol('A', 3, 3) >>> B = MatrixSymbol('B', 3, 3) >>> Inverse(A) A**(-1) >>> A.inverse() == Inverse(A) True >>> (A*B).inverse() B**(-1)*A**(-1) >>> Inverse(A*B) (A*B)**(-1) """ is_Inverse = True exp = S(-1) def __new__(cls, mat, exp=S(-1)): # exp is there to make it consistent with # inverse.func(*inverse.args) == inverse mat = _sympify(mat) if not mat.is_Matrix: raise TypeError("mat should be a matrix") if not mat.is_square: raise ShapeError("Inverse of non-square matrix %s" % mat) return Basic.__new__(cls, mat, exp) @property def arg(self): return self.args[0] @property def shape(self): return self.arg.shape def _eval_inverse(self): return self.arg def _eval_determinant(self): from sympy.matrices.expressions.determinant import det return 1/det(self.arg) def doit(self, **hints): if 'inv_expand' in hints and hints['inv_expand'] == False: return self if hints.get('deep', True): return self.arg.doit(**hints).inverse() else: return self.arg.inverse() def _eval_derivative_matrix_lines(self, x): arg = self.args[0] lines = arg._eval_derivative_matrix_lines(x) for line in lines: line.first_pointer *= -self.T line.second_pointer *= self return lines from sympy.assumptions.ask import ask, Q from sympy.assumptions.refine import handlers_dict def refine_Inverse(expr, assumptions): """ >>> from sympy import MatrixSymbol, Q, assuming, refine >>> X = MatrixSymbol('X', 2, 2) >>> X.I X**(-1) >>> with assuming(Q.orthogonal(X)): ... print(refine(X.I)) X.T """ if ask(Q.orthogonal(expr), assumptions): return expr.arg.T elif ask(Q.unitary(expr), assumptions): return expr.arg.conjugate() elif ask(Q.singular(expr), assumptions): raise ValueError("Inverse of singular matrix %s" % expr.arg) return expr handlers_dict['Inverse'] = refine_Inverse

a39d18890036bc8abf86fcdbdac876544a11fca59716a318146301db76251b15

""" A module which handles Matrix Expressions """ from .slice import MatrixSlice from .blockmatrix import BlockMatrix, BlockDiagMatrix, block_collapse, blockcut from .funcmatrix import FunctionMatrix from .inverse import Inverse from .matadd import MatAdd from .matexpr import (Identity, MatrixExpr, MatrixSymbol, ZeroMatrix, matrix_symbols) from .matmul import MatMul from .matpow import MatPow from .trace import Trace, trace from .determinant import Determinant, det from .transpose import Transpose from .adjoint import Adjoint from .hadamard import hadamard_product, HadamardProduct, hadamard_power, HadamardPower from .diagonal import DiagonalMatrix, DiagonalOf, DiagonalizeVector, diagonalize_vector from .dotproduct import DotProduct from .kronecker import kronecker_product, KroneckerProduct, combine_kronecker

82671b9e3ca44ec0dd8460e47ec71764c92bfa0f750102d52aedce74f6435634

from __future__ import print_function, division from sympy import Basic from sympy.functions import adjoint, conjugate from sympy.matrices.expressions.matexpr import MatrixExpr class Transpose(MatrixExpr): """ The transpose of a matrix expression. This is a symbolic object that simply stores its argument without evaluating it. To actually compute the transpose, use the ``transpose()`` function, or the ``.T`` attribute of matrices. Examples ======== >>> from sympy.matrices import MatrixSymbol, Transpose >>> from sympy.functions import transpose >>> A = MatrixSymbol('A', 3, 5) >>> B = MatrixSymbol('B', 5, 3) >>> Transpose(A) A.T >>> A.T == transpose(A) == Transpose(A) True >>> Transpose(A*B) (A*B).T >>> transpose(A*B) B.T*A.T """ is_Transpose = True def doit(self, **hints): arg = self.arg if hints.get('deep', True) and isinstance(arg, Basic): arg = arg.doit(**hints) _eval_transpose = getattr(arg, '_eval_transpose', None) if _eval_transpose is not None: result = _eval_transpose() return result if result is not None else Transpose(arg) else: return Transpose(arg) @property def arg(self): return self.args[0] @property def shape(self): return self.arg.shape[::-1] def _entry(self, i, j, expand=False): return self.arg._entry(j, i, expand=expand) def _eval_adjoint(self): return conjugate(self.arg) def _eval_conjugate(self): return adjoint(self.arg) def _eval_transpose(self): return self.arg def _eval_trace(self): from .trace import Trace return Trace(self.arg) # Trace(X.T) => Trace(X) def _eval_determinant(self): from sympy.matrices.expressions.determinant import det return det(self.arg) def _eval_derivative_matrix_lines(self, x): lines = self.args[0]._eval_derivative_matrix_lines(x) return [i.transpose() for i in lines] def transpose(expr): """Matrix transpose""" return Transpose(expr).doit(deep=False) from sympy.assumptions.ask import ask, Q from sympy.assumptions.refine import handlers_dict def refine_Transpose(expr, assumptions): """ >>> from sympy import MatrixSymbol, Q, assuming, refine >>> X = MatrixSymbol('X', 2, 2) >>> X.T X.T >>> with assuming(Q.symmetric(X)): ... print(refine(X.T)) X """ if ask(Q.symmetric(expr), assumptions): return expr.arg return expr handlers_dict['Transpose'] = refine_Transpose

450b2af2a85ce4bd71a1106c6c43753f89cb2565969a9aaea6c1bc36335c933b

from __future__ import print_function, division from sympy import Number from sympy.core import Mul, Basic, sympify from sympy.core.compatibility import range from sympy.functions import adjoint from sympy.matrices.expressions.transpose import transpose from sympy.strategies import (rm_id, unpack, typed, flatten, exhaust, do_one, new) from sympy.matrices.expressions.matexpr import (MatrixExpr, ShapeError, Identity, ZeroMatrix, GenericIdentity) from sympy.matrices.expressions.matpow import MatPow from sympy.matrices.matrices import MatrixBase # XXX: MatMul should perhaps not subclass directly from Mul class MatMul(MatrixExpr, Mul): """ A product of matrix expressions Examples ======== >>> from sympy import MatMul, MatrixSymbol >>> A = MatrixSymbol('A', 5, 4) >>> B = MatrixSymbol('B', 4, 3) >>> C = MatrixSymbol('C', 3, 6) >>> MatMul(A, B, C) A*B*C """ is_MatMul = True def __new__(cls, *args, **kwargs): check = kwargs.get('check', True) if not args: return GenericIdentity() # This must be removed aggressively in the constructor to avoid # TypeErrors from GenericIdentity().shape args = filter(lambda i: GenericIdentity() != i, args) args = list(map(sympify, args)) obj = Basic.__new__(cls, *args) factor, matrices = obj.as_coeff_matrices() if check: validate(*matrices) if not matrices: # Should it be # # return Basic.__neq__(cls, factor, GenericIdentity()) ? return factor return obj @property def shape(self): matrices = [arg for arg in self.args if arg.is_Matrix] return (matrices[0].rows, matrices[-1].cols) def _entry(self, i, j, expand=True): from sympy import Dummy, Sum, Mul, ImmutableMatrix, Integer coeff, matrices = self.as_coeff_matrices() if len(matrices) == 1: # situation like 2*X, matmul is just X return coeff * matrices[0][i, j] indices = [None]*(len(matrices) + 1) ind_ranges = [None]*(len(matrices) - 1) indices[0] = i indices[-1] = j for i in range(1, len(matrices)): indices[i] = Dummy("i_%i" % i) for i, arg in enumerate(matrices[:-1]): ind_ranges[i] = arg.shape[1] - 1 matrices = [arg[indices[i], indices[i+1]] for i, arg in enumerate(matrices)] expr_in_sum = Mul.fromiter(matrices) if any(v.has(ImmutableMatrix) for v in matrices): expand = True result = coeff*Sum( expr_in_sum, *zip(indices[1:-1], [0]*len(ind_ranges), ind_ranges) ) # Don't waste time in result.doit() if the sum bounds are symbolic if not any(isinstance(v, (Integer, int)) for v in ind_ranges): expand = False return result.doit() if expand else result def as_coeff_matrices(self): scalars = [x for x in self.args if not x.is_Matrix] matrices = [x for x in self.args if x.is_Matrix] coeff = Mul(*scalars) if coeff.is_commutative is False: raise NotImplementedError("noncommutative scalars in MatMul are not supported.") return coeff, matrices def as_coeff_mmul(self): coeff, matrices = self.as_coeff_matrices() return coeff, MatMul(*matrices) def _eval_transpose(self): return MatMul(*[transpose(arg) for arg in self.args[::-1]]).doit() def _eval_adjoint(self): return MatMul(*[adjoint(arg) for arg in self.args[::-1]]).doit() def _eval_trace(self): factor, mmul = self.as_coeff_mmul() if factor != 1: from .trace import trace return factor * trace(mmul.doit()) else: raise NotImplementedError("Can't simplify any further") def _eval_determinant(self): from sympy.matrices.expressions.determinant import Determinant factor, matrices = self.as_coeff_matrices() square_matrices = only_squares(*matrices) return factor**self.rows * Mul(*list(map(Determinant, square_matrices))) def _eval_inverse(self): try: return MatMul(*[ arg.inverse() if isinstance(arg, MatrixExpr) else arg**-1 for arg in self.args[::-1]]).doit() except ShapeError: from sympy.matrices.expressions.inverse import Inverse return Inverse(self) def doit(self, **kwargs): deep = kwargs.get('deep', True) if deep: args = [arg.doit(**kwargs) for arg in self.args] else: args = self.args # treat scalar*MatrixSymbol or scalar*MatPow separately mats = [arg for arg in self.args if arg.is_Matrix] expr = canonicalize(MatMul(*args)) return expr # Needed for partial compatibility with Mul def args_cnc(self, **kwargs): coeff_c = [x for x in self.args if x.is_commutative] coeff_nc = [x for x in self.args if not x.is_commutative] return [coeff_c, coeff_nc] def _eval_derivative_matrix_lines(self, x): from .transpose import Transpose with_x_ind = [i for i, arg in enumerate(self.args) if arg.has(x)] lines = [] for ind in with_x_ind: left_args = self.args[:ind] right_args = self.args[ind+1:] right_mat = MatMul.fromiter(right_args) left_rev = MatMul.fromiter([Transpose(i).doit() if i.is_Matrix else i for i in reversed(left_args)]) d = self.args[ind]._eval_derivative_matrix_lines(x) for i in d: i.append_first(left_rev) i.append_second(right_mat) lines.append(i) return lines def validate(*matrices): """ Checks for valid shapes for args of MatMul """ for i in range(len(matrices)-1): A, B = matrices[i:i+2] if A.cols != B.rows: raise ShapeError("Matrices %s and %s are not aligned"%(A, B)) # Rules def newmul(*args): if args[0] == 1: args = args[1:] return new(MatMul, *args) def any_zeros(mul): if any([arg.is_zero or (arg.is_Matrix and arg.is_ZeroMatrix) for arg in mul.args]): matrices = [arg for arg in mul.args if arg.is_Matrix] return ZeroMatrix(matrices[0].rows, matrices[-1].cols) return mul def merge_explicit(matmul): """ Merge explicit MatrixBase arguments >>> from sympy import MatrixSymbol, eye, Matrix, MatMul, pprint >>> from sympy.matrices.expressions.matmul import merge_explicit >>> A = MatrixSymbol('A', 2, 2) >>> B = Matrix([[1, 1], [1, 1]]) >>> C = Matrix([[1, 2], [3, 4]]) >>> X = MatMul(A, B, C) >>> pprint(X) [1 1] [1 2] A*[ ]*[ ] [1 1] [3 4] >>> pprint(merge_explicit(X)) [4 6] A*[ ] [4 6] >>> X = MatMul(B, A, C) >>> pprint(X) [1 1] [1 2] [ ]*A*[ ] [1 1] [3 4] >>> pprint(merge_explicit(X)) [1 1] [1 2] [ ]*A*[ ] [1 1] [3 4] """ if not any(isinstance(arg, MatrixBase) for arg in matmul.args): return matmul newargs = [] last = matmul.args[0] for arg in matmul.args[1:]: if isinstance(arg, (MatrixBase, Number)) and isinstance(last, (MatrixBase, Number)): last = last * arg else: newargs.append(last) last = arg newargs.append(last) return MatMul(*newargs) def xxinv(mul): """ Y * X * X.I -> Y """ from sympy.matrices.expressions.inverse import Inverse factor, matrices = mul.as_coeff_matrices() for i, (X, Y) in enumerate(zip(matrices[:-1], matrices[1:])): try: if X.is_square and Y.is_square: _X, x_exp = X, 1 _Y, y_exp = Y, 1 if isinstance(X, MatPow) and not isinstance(X, Inverse): _X, x_exp = X.args if isinstance(Y, MatPow) and not isinstance(Y, Inverse): _Y, y_exp = Y.args if _X == _Y.inverse(): if x_exp - y_exp > 0: I = _X**(x_exp-y_exp) else: I = _Y**(y_exp-x_exp) return newmul(factor, *(matrices[:i] + [I] + matrices[i+2:])) except ValueError: # Y might not be invertible pass return mul def remove_ids(mul): """ Remove Identities from a MatMul This is a modified version of sympy.strategies.rm_id. This is necesssary because MatMul may contain both MatrixExprs and Exprs as args. See Also ======== sympy.strategies.rm_id """ # Separate Exprs from MatrixExprs in args factor, mmul = mul.as_coeff_mmul() # Apply standard rm_id for MatMuls result = rm_id(lambda x: x.is_Identity is True)(mmul) if result != mmul: return newmul(factor, *result.args) # Recombine and return else: return mul def factor_in_front(mul): factor, matrices = mul.as_coeff_matrices() if factor != 1: return newmul(factor, *matrices) return mul def combine_powers(mul): # combine consecutive powers with the same base into one # e.g. A*A**2 -> A**3 from sympy.matrices.expressions import MatPow factor, mmul = mul.as_coeff_mmul() args = [] base = None exp = 0 for arg in mmul.args: if isinstance(arg, MatPow): current_base = arg.args[0] current_exp = arg.args[1] else: current_base = arg current_exp = 1 if current_base == base: exp += current_exp else: if not base is None: if exp == 1: args.append(base) else: args.append(base**exp) exp = current_exp base = current_base if exp == 1: args.append(base) else: args.append(base**exp) return newmul(factor, *args) rules = (any_zeros, remove_ids, xxinv, unpack, rm_id(lambda x: x == 1), merge_explicit, factor_in_front, flatten, combine_powers) canonicalize = exhaust(typed({MatMul: do_one(*rules)})) def only_squares(*matrices): """factor matrices only if they are square""" if matrices[0].rows != matrices[-1].cols: raise RuntimeError("Invalid matrices being multiplied") out = [] start = 0 for i, M in enumerate(matrices): if M.cols == matrices[start].rows: out.append(MatMul(*matrices[start:i+1]).doit()) start = i+1 return out from sympy.assumptions.ask import ask, Q from sympy.assumptions.refine import handlers_dict def refine_MatMul(expr, assumptions): """ >>> from sympy import MatrixSymbol, Q, assuming, refine >>> X = MatrixSymbol('X', 2, 2) >>> expr = X * X.T >>> print(expr) X*X.T >>> with assuming(Q.orthogonal(X)): ... print(refine(expr)) I """ newargs = [] exprargs = [] for args in expr.args: if args.is_Matrix: exprargs.append(args) else: newargs.append(args) last = exprargs[0] for arg in exprargs[1:]: if arg == last.T and ask(Q.orthogonal(arg), assumptions): last = Identity(arg.shape[0]) elif arg == last.conjugate() and ask(Q.unitary(arg), assumptions): last = Identity(arg.shape[0]) else: newargs.append(last) last = arg newargs.append(last) return MatMul(*newargs) handlers_dict['MatMul'] = refine_MatMul

5b5a396990f223948d1ad4d9b61f9e361592baad115fc4a54f1f7ccee9f225c9

from __future__ import print_function, division from functools import wraps, reduce import collections from sympy.core import S, Symbol, Tuple, Integer, Basic, Expr, Eq, Mul, Add from sympy.core.decorators import call_highest_priority from sympy.core.compatibility import range, SYMPY_INTS, default_sort_key, string_types from sympy.core.sympify import SympifyError, _sympify from sympy.functions import conjugate, adjoint from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.matrices import ShapeError from sympy.simplify import simplify from sympy.utilities.misc import filldedent def _sympifyit(arg, retval=None): # This version of _sympifyit sympifies MutableMatrix objects def deco(func): @wraps(func) def __sympifyit_wrapper(a, b): try: b = _sympify(b) return func(a, b) except SympifyError: return retval return __sympifyit_wrapper return deco class MatrixExpr(Expr): """Superclass for Matrix Expressions MatrixExprs represent abstract matrices, linear transformations represented within a particular basis. Examples ======== >>> from sympy import MatrixSymbol >>> A = MatrixSymbol('A', 3, 3) >>> y = MatrixSymbol('y', 3, 1) >>> x = (A.T*A).I * A * y See Also ======== MatrixSymbol, MatAdd, MatMul, Transpose, Inverse """ # Should not be considered iterable by the # sympy.core.compatibility.iterable function. Subclass that actually are # iterable (i.e., explicit matrices) should set this to True. _iterable = False _op_priority = 11.0 is_Matrix = True is_MatrixExpr = True is_Identity = None is_Inverse = False is_Transpose = False is_ZeroMatrix = False is_MatAdd = False is_MatMul = False is_commutative = False is_number = False is_symbol = False def __new__(cls, *args, **kwargs): args = map(_sympify, args) return Basic.__new__(cls, *args, **kwargs) # The following is adapted from the core Expr object def __neg__(self): return MatMul(S.NegativeOne, self).doit() def __abs__(self): raise NotImplementedError @_sympifyit('other', NotImplemented) @call_highest_priority('__radd__') def __add__(self, other): return MatAdd(self, other, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__add__') def __radd__(self, other): return MatAdd(other, self, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rsub__') def __sub__(self, other): return MatAdd(self, -other, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__sub__') def __rsub__(self, other): return MatAdd(other, -self, check=True).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rmul__') def __mul__(self, other): return MatMul(self, other).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rmul__') def __matmul__(self, other): return MatMul(self, other).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__mul__') def __rmul__(self, other): return MatMul(other, self).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__mul__') def __rmatmul__(self, other): return MatMul(other, self).doit() @_sympifyit('other', NotImplemented) @call_highest_priority('__rpow__') def __pow__(self, other): if not self.is_square: raise ShapeError("Power of non-square matrix %s" % self) elif self.is_Identity: return self elif other is S.Zero: return Identity(self.rows) elif other is S.One: return self return MatPow(self, other).doit(deep=False) @_sympifyit('other', NotImplemented) @call_highest_priority('__pow__') def __rpow__(self, other): raise NotImplementedError("Matrix Power not defined") @_sympifyit('other', NotImplemented) @call_highest_priority('__rdiv__') def __div__(self, other): return self * other**S.NegativeOne @_sympifyit('other', NotImplemented) @call_highest_priority('__div__') def __rdiv__(self, other): raise NotImplementedError() #return MatMul(other, Pow(self, S.NegativeOne)) __truediv__ = __div__ __rtruediv__ = __rdiv__ @property def rows(self): return self.shape[0] @property def cols(self): return self.shape[1] @property def is_square(self): return self.rows == self.cols def _eval_conjugate(self): from sympy.matrices.expressions.adjoint import Adjoint from sympy.matrices.expressions.transpose import Transpose return Adjoint(Transpose(self)) def as_real_imag(self): from sympy import I real = (S(1)/2) * (self + self._eval_conjugate()) im = (self - self._eval_conjugate())/(2*I) return (real, im) def _eval_inverse(self): from sympy.matrices.expressions.inverse import Inverse return Inverse(self) def _eval_transpose(self): return Transpose(self) def _eval_power(self, exp): return MatPow(self, exp) def _eval_simplify(self, **kwargs): if self.is_Atom: return self else: return self.__class__(*[simplify(x, **kwargs) for x in self.args]) def _eval_adjoint(self): from sympy.matrices.expressions.adjoint import Adjoint return Adjoint(self) def _eval_derivative(self, x): return _matrix_derivative(self, x) def _eval_derivative_n_times(self, x, n): return Basic._eval_derivative_n_times(self, x, n) def _visit_eval_derivative_scalar(self, x): # `x` is a scalar: if x.has(self): return _matrix_derivative(x, self) else: return ZeroMatrix(*self.shape) def _visit_eval_derivative_array(self, x): if x.has(self): return _matrix_derivative(x, self) else: from sympy import Derivative return Derivative(x, self) def _accept_eval_derivative(self, s): return s._visit_eval_derivative_array(self) def _entry(self, i, j, **kwargs): raise NotImplementedError( "Indexing not implemented for %s" % self.__class__.__name__) def adjoint(self): return adjoint(self) def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ return S.One, self def conjugate(self): return conjugate(self) def transpose(self): from sympy.matrices.expressions.transpose import transpose return transpose(self) T = property(transpose, None, None, 'Matrix transposition.') def inverse(self): return self._eval_inverse() inv = inverse @property def I(self): return self.inverse() def valid_index(self, i, j): def is_valid(idx): return isinstance(idx, (int, Integer, Symbol, Expr)) return (is_valid(i) and is_valid(j) and (self.rows is None or (0 <= i) != False and (i < self.rows) != False) and (0 <= j) != False and (j < self.cols) != False) def __getitem__(self, key): if not isinstance(key, tuple) and isinstance(key, slice): from sympy.matrices.expressions.slice import MatrixSlice return MatrixSlice(self, key, (0, None, 1)) if isinstance(key, tuple) and len(key) == 2: i, j = key if isinstance(i, slice) or isinstance(j, slice): from sympy.matrices.expressions.slice import MatrixSlice return MatrixSlice(self, i, j) i, j = _sympify(i), _sympify(j) if self.valid_index(i, j) != False: return self._entry(i, j) else: raise IndexError("Invalid indices (%s, %s)" % (i, j)) elif isinstance(key, (SYMPY_INTS, Integer)): # row-wise decomposition of matrix rows, cols = self.shape # allow single indexing if number of columns is known if not isinstance(cols, Integer): raise IndexError(filldedent(''' Single indexing is only supported when the number of columns is known.''')) key = _sympify(key) i = key // cols j = key % cols if self.valid_index(i, j) != False: return self._entry(i, j) else: raise IndexError("Invalid index %s" % key) elif isinstance(key, (Symbol, Expr)): raise IndexError(filldedent(''' Only integers may be used when addressing the matrix with a single index.''')) raise IndexError("Invalid index, wanted %s[i,j]" % self) def as_explicit(self): """ Returns a dense Matrix with elements represented explicitly Returns an object of type ImmutableDenseMatrix. Examples ======== >>> from sympy import Identity >>> I = Identity(3) >>> I I >>> I.as_explicit() Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) See Also ======== as_mutable: returns mutable Matrix type """ from sympy.matrices.immutable import ImmutableDenseMatrix return ImmutableDenseMatrix([[ self[i, j] for j in range(self.cols)] for i in range(self.rows)]) def as_mutable(self): """ Returns a dense, mutable matrix with elements represented explicitly Examples ======== >>> from sympy import Identity >>> I = Identity(3) >>> I I >>> I.shape (3, 3) >>> I.as_mutable() Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) See Also ======== as_explicit: returns ImmutableDenseMatrix """ return self.as_explicit().as_mutable() def __array__(self): from numpy import empty a = empty(self.shape, dtype=object) for i in range(self.rows): for j in range(self.cols): a[i, j] = self[i, j] return a def equals(self, other): """ Test elementwise equality between matrices, potentially of different types >>> from sympy import Identity, eye >>> Identity(3).equals(eye(3)) True """ return self.as_explicit().equals(other) def canonicalize(self): return self def as_coeff_mmul(self): return 1, MatMul(self) @staticmethod def from_index_summation(expr, first_index=None, last_index=None, dimensions=None): r""" Parse expression of matrices with explicitly summed indices into a matrix expression without indices, if possible. This transformation expressed in mathematical notation: `\sum_{j=0}^{N-1} A_{i,j} B_{j,k} \Longrightarrow \mathbf{A}\cdot \mathbf{B}` Optional parameter ``first_index``: specify which free index to use as the index starting the expression. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> expr = Sum(A[i, j]*B[j, k], (j, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) A*B Transposition is detected: >>> expr = Sum(A[j, i]*B[j, k], (j, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) A.T*B Detect the trace: >>> expr = Sum(A[i, i], (i, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) Trace(A) More complicated expressions: >>> expr = Sum(A[i, j]*B[k, j]*A[l, k], (j, 0, N-1), (k, 0, N-1)) >>> MatrixExpr.from_index_summation(expr) A*B.T*A.T """ from sympy import Sum, Mul, Add, MatMul, transpose, trace from sympy.strategies.traverse import bottom_up def remove_matelement(expr, i1, i2): def repl_match(pos): def func(x): if not isinstance(x, MatrixElement): return False if x.args[pos] != i1: return False if x.args[3-pos] == 0: if x.args[0].shape[2-pos] == 1: return True else: return False return True return func expr = expr.replace(repl_match(1), lambda x: x.args[0]) expr = expr.replace(repl_match(2), lambda x: transpose(x.args[0])) # Make sure that all Mul are transformed to MatMul and that they # are flattened: rule = bottom_up(lambda x: reduce(lambda a, b: a*b, x.args) if isinstance(x, (Mul, MatMul)) else x) return rule(expr) def recurse_expr(expr, index_ranges={}): if expr.is_Mul: nonmatargs = [] pos_arg = [] pos_ind = [] dlinks = {} link_ind = [] counter = 0 args_ind = [] for arg in expr.args: retvals = recurse_expr(arg, index_ranges) assert isinstance(retvals, list) if isinstance(retvals, list): for i in retvals: args_ind.append(i) else: args_ind.append(retvals) for arg_symbol, arg_indices in args_ind: if arg_indices is None: nonmatargs.append(arg_symbol) continue if isinstance(arg_symbol, MatrixElement): arg_symbol = arg_symbol.args[0] pos_arg.append(arg_symbol) pos_ind.append(arg_indices) link_ind.append([None]*len(arg_indices)) for i, ind in enumerate(arg_indices): if ind in dlinks: other_i = dlinks[ind] link_ind[counter][i] = other_i link_ind[other_i[0]][other_i[1]] = (counter, i) dlinks[ind] = (counter, i) counter += 1 counter2 = 0 lines = {} while counter2 < len(link_ind): for i, e in enumerate(link_ind): if None in e: line_start_index = (i, e.index(None)) break cur_ind_pos = line_start_index cur_line = [] index1 = pos_ind[cur_ind_pos[0]][cur_ind_pos[1]] while True: d, r = cur_ind_pos if pos_arg[d] != 1: if r % 2 == 1: cur_line.append(transpose(pos_arg[d])) else: cur_line.append(pos_arg[d]) next_ind_pos = link_ind[d][1-r] counter2 += 1 # Mark as visited, there will be no `None` anymore: link_ind[d] = (-1, -1) if next_ind_pos is None: index2 = pos_ind[d][1-r] lines[(index1, index2)] = cur_line break cur_ind_pos = next_ind_pos ret_indices = list(j for i in lines for j in i) lines = {k: MatMul.fromiter(v) if len(v) != 1 else v[0] for k, v in lines.items()} return [(Mul.fromiter(nonmatargs), None)] + [ (MatrixElement(a, i, j), (i, j)) for (i, j), a in lines.items() ] elif expr.is_Add: res = [recurse_expr(i) for i in expr.args] d = collections.defaultdict(list) for res_addend in res: scalar = 1 for elem, indices in res_addend: if indices is None: scalar = elem continue indices = tuple(sorted(indices, key=default_sort_key)) d[indices].append(scalar*remove_matelement(elem, *indices)) scalar = 1 return [(MatrixElement(Add.fromiter(v), *k), k) for k, v in d.items()] elif isinstance(expr, KroneckerDelta): i1, i2 = expr.args if dimensions is not None: identity = Identity(dimensions[0]) else: identity = S.One return [(MatrixElement(identity, i1, i2), (i1, i2))] elif isinstance(expr, MatrixElement): matrix_symbol, i1, i2 = expr.args if i1 in index_ranges: r1, r2 = index_ranges[i1] if r1 != 0 or matrix_symbol.shape[0] != r2+1: raise ValueError("index range mismatch: {0} vs. (0, {1})".format( (r1, r2), matrix_symbol.shape[0])) if i2 in index_ranges: r1, r2 = index_ranges[i2] if r1 != 0 or matrix_symbol.shape[1] != r2+1: raise ValueError("index range mismatch: {0} vs. (0, {1})".format( (r1, r2), matrix_symbol.shape[1])) if (i1 == i2) and (i1 in index_ranges): return [(trace(matrix_symbol), None)] return [(MatrixElement(matrix_symbol, i1, i2), (i1, i2))] elif isinstance(expr, Sum): return recurse_expr( expr.args[0], index_ranges={i[0]: i[1:] for i in expr.args[1:]} ) else: return [(expr, None)] retvals = recurse_expr(expr) factors, indices = zip(*retvals) retexpr = Mul.fromiter(factors) if len(indices) == 0 or list(set(indices)) == [None]: return retexpr if first_index is None: for i in indices: if i is not None: ind0 = i break return remove_matelement(retexpr, *ind0) else: return remove_matelement(retexpr, first_index, last_index) def applyfunc(self, func): from .applyfunc import ElementwiseApplyFunction return ElementwiseApplyFunction(func, self) def _eval_Eq(self, other): if not isinstance(other, MatrixExpr): return False if self.shape != other.shape: return False if (self - other).is_ZeroMatrix: return True return Eq(self, other, evaluate=False) def get_postprocessor(cls): def _postprocessor(expr): # To avoid circular imports, we can't have MatMul/MatAdd on the top level mat_class = {Mul: MatMul, Add: MatAdd}[cls] nonmatrices = [] matrices = [] for term in expr.args: if isinstance(term, MatrixExpr): matrices.append(term) else: nonmatrices.append(term) if not matrices: return cls._from_args(nonmatrices) if nonmatrices: if cls == Mul: for i in range(len(matrices)): if not matrices[i].is_MatrixExpr: # If one of the matrices explicit, absorb the scalar into it # (doit will combine all explicit matrices into one, so it # doesn't matter which) matrices[i] = matrices[i].__mul__(cls._from_args(nonmatrices)) nonmatrices = [] break else: # Maintain the ability to create Add(scalar, matrix) without # raising an exception. That way different algorithms can # replace matrix expressions with non-commutative symbols to # manipulate them like non-commutative scalars. return cls._from_args(nonmatrices + [mat_class(*matrices).doit(deep=False)]) return mat_class(cls._from_args(nonmatrices), *matrices).doit(deep=False) return _postprocessor Basic._constructor_postprocessor_mapping[MatrixExpr] = { "Mul": [get_postprocessor(Mul)], "Add": [get_postprocessor(Add)], } def _matrix_derivative(expr, x): from sympy import Derivative lines = expr._eval_derivative_matrix_lines(x) parts = [i.build() for i in lines] def _get_shape(elem): if isinstance(elem, MatrixExpr): return elem.shape return (1, 1) def get_rank(parts): return sum([j not in (1, None) for i in parts for j in _get_shape(i)]) ranks = [get_rank(i) for i in parts] rank = ranks[0] def contract_one_dims(parts): if len(parts) == 1: return parts[0] else: p1, p2 = parts[:2] if p2.is_Matrix: p2 = p2.T pbase = p1*p2 if len(parts) == 2: return pbase else: # len(parts) > 2 if pbase.is_Matrix: raise ValueError("") return pbase*Mul.fromiter(parts[2:]) if rank <= 2: return Add.fromiter([contract_one_dims(i) for i in parts]) return Derivative(expr, x) class MatrixElement(Expr): parent = property(lambda self: self.args[0]) i = property(lambda self: self.args[1]) j = property(lambda self: self.args[2]) _diff_wrt = True is_symbol = True is_commutative = True def __new__(cls, name, n, m): n, m = map(_sympify, (n, m)) from sympy import MatrixBase if isinstance(name, (MatrixBase,)): if n.is_Integer and m.is_Integer: return name[n, m] if isinstance(name, string_types): name = Symbol(name) name = _sympify(name) obj = Expr.__new__(cls, name, n, m) return obj def doit(self, **kwargs): deep = kwargs.get('deep', True) if deep: args = [arg.doit(**kwargs) for arg in self.args] else: args = self.args return args[0][args[1], args[2]] @property def indices(self): return self.args[1:] def _eval_derivative(self, v): from sympy import Sum, symbols, Dummy if not isinstance(v, MatrixElement): from sympy import MatrixBase if isinstance(self.parent, MatrixBase): return self.parent.diff(v)[self.i, self.j] return S.Zero M = self.args[0] if M == v.args[0]: return KroneckerDelta(self.args[1], v.args[1])*KroneckerDelta(self.args[2], v.args[2]) if isinstance(M, Inverse): i, j = self.args[1:] i1, i2 = symbols("z1, z2", cls=Dummy) Y = M.args[0] r1, r2 = Y.shape return -Sum(M[i, i1]*Y[i1, i2].diff(v)*M[i2, j], (i1, 0, r1-1), (i2, 0, r2-1)) if self.has(v.args[0]): return None return S.Zero class MatrixSymbol(MatrixExpr): """Symbolic representation of a Matrix object Creates a SymPy Symbol to represent a Matrix. This matrix has a shape and can be included in Matrix Expressions Examples ======== >>> from sympy import MatrixSymbol, Identity >>> A = MatrixSymbol('A', 3, 4) # A 3 by 4 Matrix >>> B = MatrixSymbol('B', 4, 3) # A 4 by 3 Matrix >>> A.shape (3, 4) >>> 2*A*B + Identity(3) I + 2*A*B """ is_commutative = False is_symbol = True _diff_wrt = True def __new__(cls, name, n, m): n, m = _sympify(n), _sympify(m) if isinstance(name, string_types): name = Symbol(name) obj = Basic.__new__(cls, name, n, m) return obj def _hashable_content(self): return (self.name, self.shape) @property def shape(self): return self.args[1:3] @property def name(self): return self.args[0].name def _eval_subs(self, old, new): # only do substitutions in shape shape = Tuple(*self.shape)._subs(old, new) return MatrixSymbol(self.name, *shape) def __call__(self, *args): raise TypeError("%s object is not callable" % self.__class__) def _entry(self, i, j, **kwargs): return MatrixElement(self, i, j) @property def free_symbols(self): return set((self,)) def doit(self, **hints): if hints.get('deep', True): return type(self)(self.name, self.args[1].doit(**hints), self.args[2].doit(**hints)) else: return self def _eval_simplify(self, **kwargs): return self def _eval_derivative_matrix_lines(self, x): if self != x: first = ZeroMatrix(x.shape[0], self.shape[0]) if self.shape[0] != 1 else S.Zero second = ZeroMatrix(x.shape[1], self.shape[1]) if self.shape[1] != 1 else S.Zero return [_LeftRightArgs( [first, second], )] else: first = Identity(self.shape[0]) if self.shape[0] != 1 else S.One second = Identity(self.shape[1]) if self.shape[1] != 1 else S.One return [_LeftRightArgs( [first, second], )] class Identity(MatrixExpr): """The Matrix Identity I - multiplicative identity Examples ======== >>> from sympy.matrices import Identity, MatrixSymbol >>> A = MatrixSymbol('A', 3, 5) >>> I = Identity(3) >>> I*A A """ is_Identity = True def __new__(cls, n): return super(Identity, cls).__new__(cls, _sympify(n)) @property def rows(self): return self.args[0] @property def cols(self): return self.args[0] @property def shape(self): return (self.args[0], self.args[0]) @property def is_square(self): return True def _eval_transpose(self): return self def _eval_trace(self): return self.rows def _eval_inverse(self): return self def conjugate(self): return self def _entry(self, i, j, **kwargs): eq = Eq(i, j) if eq is S.true: return S.One elif eq is S.false: return S.Zero return KroneckerDelta(i, j) def _eval_determinant(self): return S.One class GenericIdentity(Identity): """ An identity matrix without a specified shape This exists primarily so MatMul() with no arguments can return something meaningful. """ def __new__(cls): # super(Identity, cls) instead of super(GenericIdentity, cls) because # Identity.__new__ doesn't have the same signature return super(Identity, cls).__new__(cls) @property def rows(self): raise TypeError("GenericIdentity does not have a specified shape") @property def cols(self): raise TypeError("GenericIdentity does not have a specified shape") @property def shape(self): raise TypeError("GenericIdentity does not have a specified shape") # Avoid Matrix.__eq__ which might call .shape def __eq__(self, other): return isinstance(other, GenericIdentity) def __ne__(self, other): return not (self == other) def __hash__(self): return super(GenericIdentity, self).__hash__() class ZeroMatrix(MatrixExpr): """The Matrix Zero 0 - additive identity Examples ======== >>> from sympy import MatrixSymbol, ZeroMatrix >>> A = MatrixSymbol('A', 3, 5) >>> Z = ZeroMatrix(3, 5) >>> A + Z A >>> Z*A.T 0 """ is_ZeroMatrix = True def __new__(cls, m, n): return super(ZeroMatrix, cls).__new__(cls, m, n) @property def shape(self): return (self.args[0], self.args[1]) @_sympifyit('other', NotImplemented) @call_highest_priority('__rpow__') def __pow__(self, other): if other != 1 and not self.is_square: raise ShapeError("Power of non-square matrix %s" % self) if other == 0: return Identity(self.rows) if other < 1: raise ValueError("Matrix det == 0; not invertible.") return self def _eval_transpose(self): return ZeroMatrix(self.cols, self.rows) def _eval_trace(self): return S.Zero def _eval_determinant(self): return S.Zero def conjugate(self): return self def _entry(self, i, j, **kwargs): return S.Zero def __nonzero__(self): return False __bool__ = __nonzero__ class GenericZeroMatrix(ZeroMatrix): """ A zero matrix without a specified shape This exists primarily so MatAdd() with no arguments can return something meaningful. """ def __new__(cls): # super(ZeroMatrix, cls) instead of super(GenericZeroMatrix, cls) # because ZeroMatrix.__new__ doesn't have the same signature return super(ZeroMatrix, cls).__new__(cls) @property def rows(self): raise TypeError("GenericZeroMatrix does not have a specified shape") @property def cols(self): raise TypeError("GenericZeroMatrix does not have a specified shape") @property def shape(self): raise TypeError("GenericZeroMatrix does not have a specified shape") # Avoid Matrix.__eq__ which might call .shape def __eq__(self, other): return isinstance(other, GenericZeroMatrix) def __ne__(self, other): return not (self == other) def __hash__(self): return super(GenericZeroMatrix, self).__hash__() def matrix_symbols(expr): return [sym for sym in expr.free_symbols if sym.is_Matrix] class _LeftRightArgs(object): r""" Helper class to compute matrix derivatives. The logic: when an expression is derived by a matrix `X_{mn}`, two lines of matrix multiplications are created: the one contracted to `m` (first line), and the one contracted to `n` (second line). Transposition flips the side by which new matrices are connected to the lines. The trace connects the end of the two lines. """ def __init__(self, lines, higher=S.One): self._lines = [i for i in lines] self._first_pointer_parent = self._lines self._first_pointer_index = 0 self._second_pointer_parent = self._lines self._second_pointer_index = 1 self.higher = higher @property def first_pointer(self): return self._first_pointer_parent[self._first_pointer_index] @first_pointer.setter def first_pointer(self, value): self._first_pointer_parent[self._first_pointer_index] = value @property def second_pointer(self): return self._second_pointer_parent[self._second_pointer_index] @second_pointer.setter def second_pointer(self, value): self._second_pointer_parent[self._second_pointer_index] = value def __repr__(self): try: built = [self._build(i) for i in self._lines] except Exception: built = self._lines return "_LeftRightArgs(lines=%s, higher=%s)" % ( built, self.higher, ) def transpose(self): self._first_pointer_parent, self._second_pointer_parent = self._second_pointer_parent, self._first_pointer_parent self._first_pointer_index, self._second_pointer_index = self._second_pointer_index, self._first_pointer_index return self @staticmethod def _build(expr): from sympy.core.expr import ExprBuilder if isinstance(expr, ExprBuilder): return expr.build() if isinstance(expr, list): if len(expr) == 1: return expr[0] else: return expr[0](*[_LeftRightArgs._build(i) for i in expr[1]]) else: return expr def build(self): data = [self._build(i) for i in self._lines] if self.higher != 1: data += [self._build(self.higher)] data = [i.doit() for i in data] return data def matrix_form(self): if self.first != 1 and self.higher != 1: raise ValueError("higher dimensional array cannot be represented") def _get_shape(elem): if isinstance(elem, MatrixExpr): return elem.shape return (None, None) if _get_shape(self.first)[1] != _get_shape(self.second)[1]: # Remove one-dimensional identity matrices: # (this is needed by `a.diff(a)` where `a` is a vector) if _get_shape(self.second) == (1, 1): return self.first*self.second[0, 0] if _get_shape(self.first) == (1, 1): return self.first[1, 1]*self.second.T raise ValueError("incompatible shapes") if self.first != 1: return self.first*self.second.T else: return self.higher def rank(self): """ Number of dimensions different from trivial (warning: not related to matrix rank). """ rank = 0 if self.first != 1: rank += sum([i != 1 for i in self.first.shape]) if self.second != 1: rank += sum([i != 1 for i in self.second.shape]) if self.higher != 1: rank += 2 return rank def append_first(self, other): self.first_pointer *= other def append_second(self, other): self.second_pointer *= other def __hash__(self): return hash((self.first, self.second)) def __eq__(self, other): if not isinstance(other, _LeftRightArgs): return False return (self.first == other.first) and (self.second == other.second) from .matmul import MatMul from .matadd import MatAdd from .matpow import MatPow from .transpose import Transpose from .inverse import Inverse

0bf6ba905fe45969ea04ca4daf711af59e9d63dacc3972d9462752b7d24c6bd8

from __future__ import print_function, division from sympy.core.sympify import _sympify from sympy.matrices.expressions import MatrixExpr from sympy.core import S, Eq, Ge from sympy.functions.special.tensor_functions import KroneckerDelta class DiagonalMatrix(MatrixExpr): """DiagonalMatrix(M) will create a matrix expression that behaves as though all off-diagonal elements, `M[i, j]` where `i != j`, are zero. Examples ======== >>> from sympy import MatrixSymbol, DiagonalMatrix, Symbol >>> n = Symbol('n', integer=True) >>> m = Symbol('m', integer=True) >>> D = DiagonalMatrix(MatrixSymbol('x', 2, 3)) >>> D[1, 2] 0 >>> D[1, 1] x[1, 1] The length of the diagonal -- the lesser of the two dimensions of `M` -- is accessed through the `diagonal_length` property: >>> D.diagonal_length 2 >>> DiagonalMatrix(MatrixSymbol('x', n + 1, n)).diagonal_length n When one of the dimensions is symbolic the other will be treated as though it is smaller: >>> tall = DiagonalMatrix(MatrixSymbol('x', n, 3)) >>> tall.diagonal_length 3 >>> tall[10, 1] 0 When the size of the diagonal is not known, a value of None will be returned: >>> DiagonalMatrix(MatrixSymbol('x', n, m)).diagonal_length is None True """ arg = property(lambda self: self.args[0]) shape = property(lambda self: self.arg.shape) @property def diagonal_length(self): r, c = self.shape if r.is_Integer and c.is_Integer: m = min(r, c) elif r.is_Integer and not c.is_Integer: m = r elif c.is_Integer and not r.is_Integer: m = c elif r == c: m = r else: try: m = min(r, c) except TypeError: m = None return m def _entry(self, i, j): if self.diagonal_length is not None: if Ge(i, self.diagonal_length) is S.true: return S.Zero elif Ge(j, self.diagonal_length) is S.true: return S.Zero eq = Eq(i, j) if eq is S.true: return self.arg[i, i] elif eq is S.false: return S.Zero return self.arg[i, j]*KroneckerDelta(i, j) class DiagonalOf(MatrixExpr): """DiagonalOf(M) will create a matrix expression that is equivalent to the diagonal of `M`, represented as a single column matrix. Examples ======== >>> from sympy import MatrixSymbol, DiagonalOf, Symbol >>> n = Symbol('n', integer=True) >>> m = Symbol('m', integer=True) >>> x = MatrixSymbol('x', 2, 3) >>> diag = DiagonalOf(x) >>> diag.shape (2, 1) The diagonal can be addressed like a matrix or vector and will return the corresponding element of the original matrix: >>> diag[1, 0] == diag[1] == x[1, 1] True The length of the diagonal -- the lesser of the two dimensions of `M` -- is accessed through the `diagonal_length` property: >>> diag.diagonal_length 2 >>> DiagonalOf(MatrixSymbol('x', n + 1, n)).diagonal_length n When only one of the dimensions is symbolic the other will be treated as though it is smaller: >>> dtall = DiagonalOf(MatrixSymbol('x', n, 3)) >>> dtall.diagonal_length 3 When the size of the diagonal is not known, a value of None will be returned: >>> DiagonalOf(MatrixSymbol('x', n, m)).diagonal_length is None True """ arg = property(lambda self: self.args[0]) @property def shape(self): r, c = self.arg.shape if r.is_Integer and c.is_Integer: m = min(r, c) elif r.is_Integer and not c.is_Integer: m = r elif c.is_Integer and not r.is_Integer: m = c elif r == c: m = r else: try: m = min(r, c) except TypeError: m = None return m, S.One @property def diagonal_length(self): return self.shape[0] def _entry(self, i, j): return self.arg[i, i] class DiagonalizeVector(MatrixExpr): """ Turn a vector into a diagonal matrix. """ def __new__(cls, vector): obj = MatrixExpr.__new__(cls, vector) shape = vector.shape dim = shape[1] if shape[0] == 1 else shape[0] if vector.shape[0] != 1: obj._iscolumn = True else: obj._iscolumn = False obj._shape = (dim, dim) obj._vector = vector return obj @property def shape(self): return self._shape def _entry(self, i, j, **kwargs): if self._iscolumn: result = self._vector._entry(i, 0) else: result = self._vector._entry(0, j) if i != j: result *= KroneckerDelta(i, j) return result def _eval_transpose(self): return self def as_explicit(self): from sympy import diag return diag(*list(self._vector.as_explicit())) def diagonalize_vector(vector): from sympy import Transpose vector = _sympify(vector) if vector.shape == (1, 1): return vector if vector.is_Identity: return vector if isinstance(vector, Transpose): vector = vector.arg return DiagonalizeVector(vector)

3a5020bff249a2fcc2d1871cb60b5d40c069385cebe3d9528725e38c1df8fc07

from __future__ import print_function, division from sympy import Basic, Expr, sympify, S from sympy.matrices.matrices import MatrixBase from .matexpr import ShapeError class Trace(Expr): """Matrix Trace Represents the trace of a matrix expression. Examples ======== >>> from sympy import MatrixSymbol, Trace, eye >>> A = MatrixSymbol('A', 3, 3) >>> Trace(A) Trace(A) """ is_Trace = True is_commutative = True def __new__(cls, mat): mat = sympify(mat) if not mat.is_Matrix: raise TypeError("input to Trace, %s, is not a matrix" % str(mat)) if not mat.is_square: raise ShapeError("Trace of a non-square matrix") return Basic.__new__(cls, mat) def _eval_transpose(self): return self def _eval_derivative(self, v): from sympy.matrices.expressions.matexpr import _matrix_derivative return _matrix_derivative(self, v) def _eval_derivative_matrix_lines(self, x): r = self.args[0]._eval_derivative_matrix_lines(x) for lr in r: if lr.higher == 1: lr.higher *= lr._lines[0] * lr._lines[1].T else: # This is not a matrix line: lr.higher *= Trace(lr._lines[0] * lr._lines[1].T) lr._lines = [S.One, S.One] lr._first_pointer_parent = lr._lines lr._second_pointer_parent = lr._lines lr._first_pointer_index = 0 lr._second_pointer_index = 1 return r @property def arg(self): return self.args[0] def doit(self, **kwargs): if kwargs.get('deep', True): arg = self.arg.doit(**kwargs) try: return arg._eval_trace() except (AttributeError, NotImplementedError): return Trace(arg) else: # _eval_trace would go too deep here if isinstance(self.arg, MatrixBase): return trace(self.arg) else: return Trace(self.arg) def _eval_rewrite_as_Sum(self, expr, **kwargs): from sympy import Sum, Dummy i = Dummy('i') return Sum(self.arg[i, i], (i, 0, self.arg.rows-1)).doit() def trace(expr): """Trace of a Matrix. Sum of the diagonal elements. Examples ======== >>> from sympy import trace, Symbol, MatrixSymbol, pprint, eye >>> n = Symbol('n') >>> X = MatrixSymbol('X', n, n) # A square matrix >>> trace(2*X) 2*Trace(X) >>> trace(eye(3)) 3 """ return Trace(expr).doit()

cbe584b00a135b6731dd1c871fb9d1c8e7df5a7bd8d16c8a59fd488a3705165b

from __future__ import print_function, division from sympy.core import Mul, sympify from sympy.matrices.expressions.matexpr import MatrixExpr, ShapeError from sympy.strategies import unpack, flatten, condition, exhaust, do_one def hadamard_product(*matrices): """ Return the elementwise (aka Hadamard) product of matrices. Examples ======== >>> from sympy.matrices import hadamard_product, MatrixSymbol >>> A = MatrixSymbol('A', 2, 3) >>> B = MatrixSymbol('B', 2, 3) >>> hadamard_product(A) A >>> hadamard_product(A, B) A.*B >>> hadamard_product(A, B)[0, 1] A[0, 1]*B[0, 1] """ if not matrices: raise TypeError("Empty Hadamard product is undefined") validate(*matrices) if len(matrices) == 1: return matrices[0] else: matrices = [i for i in matrices if not i.is_Identity] return HadamardProduct(*matrices).doit() class HadamardProduct(MatrixExpr): """ Elementwise product of matrix expressions This is a symbolic object that simply stores its argument without evaluating it. To actually compute the product, use the function ``hadamard_product()``. >>> from sympy.matrices import hadamard_product, HadamardProduct, MatrixSymbol >>> A = MatrixSymbol('A', 5, 5) >>> B = MatrixSymbol('B', 5, 5) >>> isinstance(hadamard_product(A, B), HadamardProduct) True """ is_HadamardProduct = True def __new__(cls, *args, **kwargs): args = list(map(sympify, args)) check = kwargs.get('check', True) if check: validate(*args) return super(HadamardProduct, cls).__new__(cls, *args) @property def shape(self): return self.args[0].shape def _entry(self, i, j): return Mul(*[arg._entry(i, j) for arg in self.args]) def _eval_transpose(self): from sympy.matrices.expressions.transpose import transpose return HadamardProduct(*list(map(transpose, self.args))) def doit(self, **ignored): return canonicalize(self) def validate(*args): if not all(arg.is_Matrix for arg in args): raise TypeError("Mix of Matrix and Scalar symbols") A = args[0] for B in args[1:]: if A.shape != B.shape: raise ShapeError("Matrices %s and %s are not aligned" % (A, B)) rules = (unpack, flatten) canonicalize = exhaust(condition(lambda x: isinstance(x, HadamardProduct), do_one(*rules))) def hadamard_power(base, exp): base = sympify(base) exp = sympify(exp) if exp == 1: return base if not base.is_Matrix: return base**exp if exp.is_Matrix: raise ValueError("cannot raise expression to a matrix") return HadamardPower(base, exp) class HadamardPower(MatrixExpr): """ Elementwise power of matrix expressions """ def __new__(cls, base, exp): base = sympify(base) exp = sympify(exp) obj = super(HadamardPower, cls).__new__(cls, base, exp) return obj @property def base(self): return self._args[0] @property def exp(self): return self._args[1] @property def shape(self): return self.base.shape def _entry(self, i, j, **kwargs): return self.base[i, j]**self.exp def _eval_transpose(self): from sympy.matrices.expressions.transpose import transpose return HadamardPower(transpose(self.base), self.exp)

39bbf729ad5208a8987ab5851f26053a01832d2453700b27bf9c0cc4603f3573

from __future__ import print_function, division from sympy import ask, Q from sympy.core import Basic, Add, sympify from sympy.core.compatibility import range from sympy.strategies import typed, exhaust, condition, do_one, unpack from sympy.strategies.traverse import bottom_up from sympy.utilities import sift from sympy.utilities.misc import filldedent from sympy.matrices.expressions.matexpr import MatrixExpr, ZeroMatrix, Identity from sympy.matrices.expressions.matmul import MatMul from sympy.matrices.expressions.matadd import MatAdd from sympy.matrices.expressions.matpow import MatPow from sympy.matrices.expressions.transpose import Transpose, transpose from sympy.matrices.expressions.trace import Trace from sympy.matrices.expressions.determinant import det, Determinant from sympy.matrices.expressions.slice import MatrixSlice from sympy.matrices.expressions.inverse import Inverse from sympy.matrices import Matrix, ShapeError from sympy.functions.elementary.complexes import re, im class BlockMatrix(MatrixExpr): """A BlockMatrix is a Matrix comprised of other matrices. The submatrices are stored in a SymPy Matrix object but accessed as part of a Matrix Expression >>> from sympy import (MatrixSymbol, BlockMatrix, symbols, ... Identity, ZeroMatrix, block_collapse) >>> n,m,l = symbols('n m l') >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> Z = MatrixSymbol('Z', n, m) >>> B = BlockMatrix([[X, Z], [ZeroMatrix(m,n), Y]]) >>> print(B) Matrix([ [X, Z], [0, Y]]) >>> C = BlockMatrix([[Identity(n), Z]]) >>> print(C) Matrix([[I, Z]]) >>> print(block_collapse(C*B)) Matrix([[X, Z + Z*Y]]) Some matrices might be comprised of rows of blocks with the matrices in each row having the same height and the rows all having the same total number of columns but not having the same number of columns for each matrix in each row. In this case, the matrix is not a block matrix and should be instantiated by Matrix. >>> from sympy import ones, Matrix >>> dat = [ ... [ones(3,2), ones(3,3)*2], ... [ones(2,3)*3, ones(2,2)*4]] ... >>> BlockMatrix(dat) Traceback (most recent call last): ... ValueError: Although this matrix is comprised of blocks, the blocks do not fill the matrix in a size-symmetric fashion. To create a full matrix from these arguments, pass them directly to Matrix. >>> Matrix(dat) Matrix([ [1, 1, 2, 2, 2], [1, 1, 2, 2, 2], [1, 1, 2, 2, 2], [3, 3, 3, 4, 4], [3, 3, 3, 4, 4]]) See Also ======== sympy.matrices.matrices.MatrixBase.irregular """ def __new__(cls, *args, **kwargs): from sympy.matrices.immutable import ImmutableDenseMatrix from sympy.matrices import zeros from sympy.matrices.matrices import MatrixBase from sympy.utilities.iterables import is_sequence isMat = lambda i: getattr(i, 'is_Matrix', False) if len(args) != 1 or \ not is_sequence(args[0]) or \ len(set([isMat(r) for r in args[0]])) != 1: raise ValueError(filldedent(''' expecting a sequence of 1 or more rows containing Matrices.''')) rows = args[0] if args else [] if not isMat(rows): if rows and isMat(rows[0]): rows = [rows] # rows is not list of lists or [] # regularity check # same number of matrices in each row blocky = ok = len(set([len(r) for r in rows])) == 1 if ok: # same number of rows for each matrix in a row for r in rows: ok = len(set([i.rows for i in r])) == 1 if not ok: break blocky = ok # same number of cols for each matrix in each col for c in range(len(rows[0])): ok = len(set([rows[i][c].cols for i in range(len(rows))])) == 1 if not ok: break if not ok: # same total cols in each row ok = len(set([ sum([i.cols for i in r]) for r in rows])) == 1 if blocky and ok: raise ValueError(filldedent(''' Although this matrix is comprised of blocks, the blocks do not fill the matrix in a size-symmetric fashion. To create a full matrix from these arguments, pass them directly to Matrix.''')) raise ValueError(filldedent(''' When there are not the same number of rows in each row's matrices or there are not the same number of total columns in each row, the matrix is not a block matrix. If this matrix is known to consist of blocks fully filling a 2-D space then see Matrix.irregular.''')) mat = ImmutableDenseMatrix(rows, evaluate=False) obj = Basic.__new__(cls, mat) return obj @property def shape(self): numrows = numcols = 0 M = self.blocks for i in range(M.shape[0]): numrows += M[i, 0].shape[0] for i in range(M.shape[1]): numcols += M[0, i].shape[1] return (numrows, numcols) @property def blockshape(self): return self.blocks.shape @property def blocks(self): return self.args[0] @property def rowblocksizes(self): return [self.blocks[i, 0].rows for i in range(self.blockshape[0])] @property def colblocksizes(self): return [self.blocks[0, i].cols for i in range(self.blockshape[1])] def structurally_equal(self, other): return (isinstance(other, BlockMatrix) and self.shape == other.shape and self.blockshape == other.blockshape and self.rowblocksizes == other.rowblocksizes and self.colblocksizes == other.colblocksizes) def _blockmul(self, other): if (isinstance(other, BlockMatrix) and self.colblocksizes == other.rowblocksizes): return BlockMatrix(self.blocks*other.blocks) return self * other def _blockadd(self, other): if (isinstance(other, BlockMatrix) and self.structurally_equal(other)): return BlockMatrix(self.blocks + other.blocks) return self + other def _eval_transpose(self): # Flip all the individual matrices matrices = [transpose(matrix) for matrix in self.blocks] # Make a copy M = Matrix(self.blockshape[0], self.blockshape[1], matrices) # Transpose the block structure M = M.transpose() return BlockMatrix(M) def _eval_trace(self): if self.rowblocksizes == self.colblocksizes: return Add(*[Trace(self.blocks[i, i]) for i in range(self.blockshape[0])]) raise NotImplementedError( "Can't perform trace of irregular blockshape") def _eval_determinant(self): if self.blockshape == (2, 2): [[A, B], [C, D]] = self.blocks.tolist() if ask(Q.invertible(A)): return det(A)*det(D - C*A.I*B) elif ask(Q.invertible(D)): return det(D)*det(A - B*D.I*C) return Determinant(self) def as_real_imag(self): real_matrices = [re(matrix) for matrix in self.blocks] real_matrices = Matrix(self.blockshape[0], self.blockshape[1], real_matrices) im_matrices = [im(matrix) for matrix in self.blocks] im_matrices = Matrix(self.blockshape[0], self.blockshape[1], im_matrices) return (real_matrices, im_matrices) def transpose(self): """Return transpose of matrix. Examples ======== >>> from sympy import MatrixSymbol, BlockMatrix, ZeroMatrix >>> from sympy.abc import l, m, n >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> Z = MatrixSymbol('Z', n, m) >>> B = BlockMatrix([[X, Z], [ZeroMatrix(m,n), Y]]) >>> B.transpose() Matrix([ [X.T, 0], [Z.T, Y.T]]) >>> _.transpose() Matrix([ [X, Z], [0, Y]]) """ return self._eval_transpose() def _entry(self, i, j): # Find row entry for row_block, numrows in enumerate(self.rowblocksizes): if (i < numrows) != False: break else: i -= numrows for col_block, numcols in enumerate(self.colblocksizes): if (j < numcols) != False: break else: j -= numcols return self.blocks[row_block, col_block][i, j] @property def is_Identity(self): if self.blockshape[0] != self.blockshape[1]: return False for i in range(self.blockshape[0]): for j in range(self.blockshape[1]): if i==j and not self.blocks[i, j].is_Identity: return False if i!=j and not self.blocks[i, j].is_ZeroMatrix: return False return True @property def is_structurally_symmetric(self): return self.rowblocksizes == self.colblocksizes def equals(self, other): if self == other: return True if (isinstance(other, BlockMatrix) and self.blocks == other.blocks): return True return super(BlockMatrix, self).equals(other) class BlockDiagMatrix(BlockMatrix): """ A BlockDiagMatrix is a BlockMatrix with matrices only along the diagonal >>> from sympy import MatrixSymbol, BlockDiagMatrix, symbols, Identity >>> n, m, l = symbols('n m l') >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> BlockDiagMatrix(X, Y) Matrix([ [X, 0], [0, Y]]) See Also ======== sympy.matrices.common.diag """ def __new__(cls, *mats): return Basic.__new__(BlockDiagMatrix, *mats) @property def diag(self): return self.args @property def blocks(self): from sympy.matrices.immutable import ImmutableDenseMatrix mats = self.args data = [[mats[i] if i == j else ZeroMatrix(mats[i].rows, mats[j].cols) for j in range(len(mats))] for i in range(len(mats))] return ImmutableDenseMatrix(data) @property def shape(self): return (sum(block.rows for block in self.args), sum(block.cols for block in self.args)) @property def blockshape(self): n = len(self.args) return (n, n) @property def rowblocksizes(self): return [block.rows for block in self.args] @property def colblocksizes(self): return [block.cols for block in self.args] def _eval_inverse(self, expand='ignored'): return BlockDiagMatrix(*[mat.inverse() for mat in self.args]) def _blockmul(self, other): if (isinstance(other, BlockDiagMatrix) and self.colblocksizes == other.rowblocksizes): return BlockDiagMatrix(*[a*b for a, b in zip(self.args, other.args)]) else: return BlockMatrix._blockmul(self, other) def _blockadd(self, other): if (isinstance(other, BlockDiagMatrix) and self.blockshape == other.blockshape and self.rowblocksizes == other.rowblocksizes and self.colblocksizes == other.colblocksizes): return BlockDiagMatrix(*[a + b for a, b in zip(self.args, other.args)]) else: return BlockMatrix._blockadd(self, other) def block_collapse(expr): """Evaluates a block matrix expression >>> from sympy import MatrixSymbol, BlockMatrix, symbols, \ Identity, Matrix, ZeroMatrix, block_collapse >>> n,m,l = symbols('n m l') >>> X = MatrixSymbol('X', n, n) >>> Y = MatrixSymbol('Y', m ,m) >>> Z = MatrixSymbol('Z', n, m) >>> B = BlockMatrix([[X, Z], [ZeroMatrix(m, n), Y]]) >>> print(B) Matrix([ [X, Z], [0, Y]]) >>> C = BlockMatrix([[Identity(n), Z]]) >>> print(C) Matrix([[I, Z]]) >>> print(block_collapse(C*B)) Matrix([[X, Z + Z*Y]]) """ hasbm = lambda expr: isinstance(expr, MatrixExpr) and expr.has(BlockMatrix) rule = exhaust( bottom_up(exhaust(condition(hasbm, typed( {MatAdd: do_one(bc_matadd, bc_block_plus_ident), MatMul: do_one(bc_matmul, bc_dist), MatPow: bc_matmul, Transpose: bc_transpose, Inverse: bc_inverse, BlockMatrix: do_one(bc_unpack, deblock)}))))) result = rule(expr) doit = getattr(result, 'doit', None) if doit is not None: return doit() else: return result def bc_unpack(expr): if expr.blockshape == (1, 1): return expr.blocks[0, 0] return expr def bc_matadd(expr): args = sift(expr.args, lambda M: isinstance(M, BlockMatrix)) blocks = args[True] if not blocks: return expr nonblocks = args[False] block = blocks[0] for b in blocks[1:]: block = block._blockadd(b) if nonblocks: return MatAdd(*nonblocks) + block else: return block def bc_block_plus_ident(expr): idents = [arg for arg in expr.args if arg.is_Identity] if not idents: return expr blocks = [arg for arg in expr.args if isinstance(arg, BlockMatrix)] if (blocks and all(b.structurally_equal(blocks[0]) for b in blocks) and blocks[0].is_structurally_symmetric): block_id = BlockDiagMatrix(*[Identity(k) for k in blocks[0].rowblocksizes]) return MatAdd(block_id * len(idents), *blocks).doit() return expr def bc_dist(expr): """ Turn a*[X, Y] into [a*X, a*Y] """ factor, mat = expr.as_coeff_mmul() if factor != 1 and isinstance(unpack(mat), BlockMatrix): B = unpack(mat).blocks return BlockMatrix([[factor * B[i, j] for j in range(B.cols)] for i in range(B.rows)]) return expr def bc_matmul(expr): if isinstance(expr, MatPow): if expr.args[1].is_Integer: factor, matrices = (1, [expr.args[0]]*expr.args[1]) else: return expr else: factor, matrices = expr.as_coeff_matrices() i = 0 while (i+1 < len(matrices)): A, B = matrices[i:i+2] if isinstance(A, BlockMatrix) and isinstance(B, BlockMatrix): matrices[i] = A._blockmul(B) matrices.pop(i+1) elif isinstance(A, BlockMatrix): matrices[i] = A._blockmul(BlockMatrix([[B]])) matrices.pop(i+1) elif isinstance(B, BlockMatrix): matrices[i] = BlockMatrix([[A]])._blockmul(B) matrices.pop(i+1) else: i+=1 return MatMul(factor, *matrices).doit() def bc_transpose(expr): return BlockMatrix(block_collapse(expr.arg).blocks.applyfunc(transpose).T) def bc_inverse(expr): expr2 = blockinverse_1x1(expr) if expr != expr2: return expr2 return blockinverse_2x2(Inverse(reblock_2x2(expr.arg))) def blockinverse_1x1(expr): if isinstance(expr.arg, BlockMatrix) and expr.arg.blockshape == (1, 1): mat = Matrix([[expr.arg.blocks[0].inverse()]]) return BlockMatrix(mat) return expr def blockinverse_2x2(expr): if isinstance(expr.arg, BlockMatrix) and expr.arg.blockshape == (2, 2): # Cite: The Matrix Cookbook Section 9.1.3 [[A, B], [C, D]] = expr.arg.blocks.tolist() return BlockMatrix([[ (A - B*D.I*C).I, (-A).I*B*(D - C*A.I*B).I], [-(D - C*A.I*B).I*C*A.I, (D - C*A.I*B).I]]) else: return expr def deblock(B): """ Flatten a BlockMatrix of BlockMatrices """ if not isinstance(B, BlockMatrix) or not B.blocks.has(BlockMatrix): return B wrap = lambda x: x if isinstance(x, BlockMatrix) else BlockMatrix([[x]]) bb = B.blocks.applyfunc(wrap) # everything is a block from sympy import Matrix try: MM = Matrix(0, sum(bb[0, i].blocks.shape[1] for i in range(bb.shape[1])), []) for row in range(0, bb.shape[0]): M = Matrix(bb[row, 0].blocks) for col in range(1, bb.shape[1]): M = M.row_join(bb[row, col].blocks) MM = MM.col_join(M) return BlockMatrix(MM) except ShapeError: return B def reblock_2x2(B): """ Reblock a BlockMatrix so that it has 2x2 blocks of block matrices """ if not isinstance(B, BlockMatrix) or not all(d > 2 for d in B.blocks.shape): return B BM = BlockMatrix # for brevity's sake return BM([[ B.blocks[0, 0], BM(B.blocks[0, 1:])], [BM(B.blocks[1:, 0]), BM(B.blocks[1:, 1:])]]) def bounds(sizes): """ Convert sequence of numbers into pairs of low-high pairs >>> from sympy.matrices.expressions.blockmatrix import bounds >>> bounds((1, 10, 50)) [(0, 1), (1, 11), (11, 61)] """ low = 0 rv = [] for size in sizes: rv.append((low, low + size)) low += size return rv def blockcut(expr, rowsizes, colsizes): """ Cut a matrix expression into Blocks >>> from sympy import ImmutableMatrix, blockcut >>> M = ImmutableMatrix(4, 4, range(16)) >>> B = blockcut(M, (1, 3), (1, 3)) >>> type(B).__name__ 'BlockMatrix' >>> ImmutableMatrix(B.blocks[0, 1]) Matrix([[1, 2, 3]]) """ rowbounds = bounds(rowsizes) colbounds = bounds(colsizes) return BlockMatrix([[MatrixSlice(expr, rowbound, colbound) for colbound in colbounds] for rowbound in rowbounds])

1ed819a5ea5b768e89f006b3c5581718e4a2ac3d2bb48fbd4ef3c541eb6ba435

from __future__ import print_function, division from sympy.core.compatibility import reduce from operator import add from sympy.core import Add, Basic, sympify from sympy.functions import adjoint from sympy.matrices.matrices import MatrixBase from sympy.matrices.expressions.transpose import transpose from sympy.strategies import (rm_id, unpack, flatten, sort, condition, exhaust, do_one, glom) from sympy.matrices.expressions.matexpr import (MatrixExpr, ShapeError, ZeroMatrix, GenericZeroMatrix) from sympy.utilities import default_sort_key, sift # XXX: MatAdd should perhaps not subclass directly from Add class MatAdd(MatrixExpr, Add): """A Sum of Matrix Expressions MatAdd inherits from and operates like SymPy Add Examples ======== >>> from sympy import MatAdd, MatrixSymbol >>> A = MatrixSymbol('A', 5, 5) >>> B = MatrixSymbol('B', 5, 5) >>> C = MatrixSymbol('C', 5, 5) >>> MatAdd(A, B, C) A + B + C """ is_MatAdd = True def __new__(cls, *args, **kwargs): if not args: return GenericZeroMatrix() # This must be removed aggressively in the constructor to avoid # TypeErrors from GenericZeroMatrix().shape args = filter(lambda i: GenericZeroMatrix() != i, args) args = list(map(sympify, args)) check = kwargs.get('check', False) obj = Basic.__new__(cls, *args) if check: if all(not isinstance(i, MatrixExpr) for i in args): return Add.fromiter(args) validate(*args) return obj @property def shape(self): return self.args[0].shape def _entry(self, i, j, expand=None): return Add(*[arg._entry(i, j) for arg in self.args]) def _eval_transpose(self): return MatAdd(*[transpose(arg) for arg in self.args]).doit() def _eval_adjoint(self): return MatAdd(*[adjoint(arg) for arg in self.args]).doit() def _eval_trace(self): from .trace import trace return Add(*[trace(arg) for arg in self.args]).doit() def doit(self, **kwargs): deep = kwargs.get('deep', True) if deep: args = [arg.doit(**kwargs) for arg in self.args] else: args = self.args return canonicalize(MatAdd(*args)) def _eval_derivative_matrix_lines(self, x): add_lines = [arg._eval_derivative_matrix_lines(x) for arg in self.args] return [j for i in add_lines for j in i] def validate(*args): if not all(arg.is_Matrix for arg in args): raise TypeError("Mix of Matrix and Scalar symbols") A = args[0] for B in args[1:]: if A.shape != B.shape: raise ShapeError("Matrices %s and %s are not aligned"%(A, B)) factor_of = lambda arg: arg.as_coeff_mmul()[0] matrix_of = lambda arg: unpack(arg.as_coeff_mmul()[1]) def combine(cnt, mat): if cnt == 1: return mat else: return cnt * mat def merge_explicit(matadd): """ Merge explicit MatrixBase arguments Examples ======== >>> from sympy import MatrixSymbol, eye, Matrix, MatAdd, pprint >>> from sympy.matrices.expressions.matadd import merge_explicit >>> A = MatrixSymbol('A', 2, 2) >>> B = eye(2) >>> C = Matrix([[1, 2], [3, 4]]) >>> X = MatAdd(A, B, C) >>> pprint(X) [1 0] [1 2] A + [ ] + [ ] [0 1] [3 4] >>> pprint(merge_explicit(X)) [2 2] A + [ ] [3 5] """ groups = sift(matadd.args, lambda arg: isinstance(arg, MatrixBase)) if len(groups[True]) > 1: return MatAdd(*(groups[False] + [reduce(add, groups[True])])) else: return matadd rules = (rm_id(lambda x: x == 0 or isinstance(x, ZeroMatrix)), unpack, flatten, glom(matrix_of, factor_of, combine), merge_explicit, sort(default_sort_key)) canonicalize = exhaust(condition(lambda x: isinstance(x, MatAdd), do_one(*rules)))

b4616cab2c9531ea25b080171d4dfc481576fe082fb81831495b16d824a60442

from sympy.matrices.expressions.blockmatrix import (block_collapse, bc_matmul, bc_block_plus_ident, BlockDiagMatrix, BlockMatrix, bc_dist, bc_matadd, bc_transpose, blockcut, reblock_2x2, deblock) from sympy.matrices.expressions import (MatrixSymbol, Identity, Inverse, trace, Transpose, det) from sympy.matrices import Matrix, ImmutableMatrix, ones from sympy.core import Tuple, symbols, Expr from sympy.core.compatibility import range from sympy.functions import transpose i, j, k, l, m, n, p = symbols('i:n, p', integer=True) A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, n) C = MatrixSymbol('C', n, n) D = MatrixSymbol('D', n, n) G = MatrixSymbol('G', n, n) H = MatrixSymbol('H', n, n) b1 = BlockMatrix([[G, H]]) b2 = BlockMatrix([[G], [H]]) def test_bc_matmul(): assert bc_matmul(H*b1*b2*G) == BlockMatrix([[(H*G*G + H*H*H)*G]]) def test_bc_matadd(): assert bc_matadd(BlockMatrix([[G, H]]) + BlockMatrix([[H, H]])) == \ BlockMatrix([[G+H, H+H]]) def test_bc_transpose(): assert bc_transpose(Transpose(BlockMatrix([[A, B], [C, D]]))) == \ BlockMatrix([[A.T, C.T], [B.T, D.T]]) def test_bc_dist_diag(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', m, m) C = MatrixSymbol('C', l, l) X = BlockDiagMatrix(A, B, C) assert bc_dist(X+X).equals(BlockDiagMatrix(2*A, 2*B, 2*C)) def test_block_plus_ident(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, m) C = MatrixSymbol('C', m, n) D = MatrixSymbol('D', m, m) X = BlockMatrix([[A, B], [C, D]]) assert bc_block_plus_ident(X+Identity(m+n)) == \ BlockDiagMatrix(Identity(n), Identity(m)) + X def test_BlockMatrix(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', n, k) C = MatrixSymbol('C', l, m) D = MatrixSymbol('D', l, k) M = MatrixSymbol('M', m + k, p) N = MatrixSymbol('N', l + n, k + m) X = BlockMatrix(Matrix([[A, B], [C, D]])) assert X.__class__(*X.args) == X # block_collapse does nothing on normal inputs E = MatrixSymbol('E', n, m) assert block_collapse(A + 2*E) == A + 2*E F = MatrixSymbol('F', m, m) assert block_collapse(E.T*A*F) == E.T*A*F assert X.shape == (l + n, k + m) assert X.blockshape == (2, 2) assert transpose(X) == BlockMatrix(Matrix([[A.T, C.T], [B.T, D.T]])) assert transpose(X).shape == X.shape[::-1] # Test that BlockMatrices and MatrixSymbols can still mix assert (X*M).is_MatMul assert X._blockmul(M).is_MatMul assert (X*M).shape == (n + l, p) assert (X + N).is_MatAdd assert X._blockadd(N).is_MatAdd assert (X + N).shape == X.shape E = MatrixSymbol('E', m, 1) F = MatrixSymbol('F', k, 1) Y = BlockMatrix(Matrix([[E], [F]])) assert (X*Y).shape == (l + n, 1) assert block_collapse(X*Y).blocks[0, 0] == A*E + B*F assert block_collapse(X*Y).blocks[1, 0] == C*E + D*F # block_collapse passes down into container objects, transposes, and inverse assert block_collapse(transpose(X*Y)) == transpose(block_collapse(X*Y)) assert block_collapse(Tuple(X*Y, 2*X)) == ( block_collapse(X*Y), block_collapse(2*X)) # Make sure that MatrixSymbols will enter 1x1 BlockMatrix if it simplifies Ab = BlockMatrix([[A]]) Z = MatrixSymbol('Z', *A.shape) assert block_collapse(Ab + Z) == A + Z def test_BlockMatrix_trace(): A, B, C, D = [MatrixSymbol(s, 3, 3) for s in 'ABCD'] X = BlockMatrix([[A, B], [C, D]]) assert trace(X) == trace(A) + trace(D) def test_BlockMatrix_Determinant(): A, B, C, D = [MatrixSymbol(s, 3, 3) for s in 'ABCD'] X = BlockMatrix([[A, B], [C, D]]) from sympy import assuming, Q with assuming(Q.invertible(A)): assert det(X) == det(A) * det(D - C*A.I*B) assert isinstance(det(X), Expr) def test_squareBlockMatrix(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, m) C = MatrixSymbol('C', m, n) D = MatrixSymbol('D', m, m) X = BlockMatrix([[A, B], [C, D]]) Y = BlockMatrix([[A]]) assert X.is_square assert (block_collapse(X + Identity(m + n)) == BlockMatrix([[A + Identity(n), B], [C, D + Identity(m)]])) Q = X + Identity(m + n) assert (X + MatrixSymbol('Q', n + m, n + m)).is_MatAdd assert (X * MatrixSymbol('Q', n + m, n + m)).is_MatMul assert block_collapse(Y.I) == A.I assert block_collapse(X.inverse()) == BlockMatrix([ [(-B*D.I*C + A).I, -A.I*B*(D + -C*A.I*B).I], [-(D - C*A.I*B).I*C*A.I, (D - C*A.I*B).I]]) assert isinstance(X.inverse(), Inverse) assert not X.is_Identity Z = BlockMatrix([[Identity(n), B], [C, D]]) assert not Z.is_Identity def test_BlockDiagMatrix(): A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', m, m) C = MatrixSymbol('C', l, l) M = MatrixSymbol('M', n + m + l, n + m + l) X = BlockDiagMatrix(A, B, C) Y = BlockDiagMatrix(A, 2*B, 3*C) assert X.blocks[1, 1] == B assert X.shape == (n + m + l, n + m + l) assert all(X.blocks[i, j].is_ZeroMatrix if i != j else X.blocks[i, j] in [A, B, C] for i in range(3) for j in range(3)) assert X.__class__(*X.args) == X assert isinstance(block_collapse(X.I * X), Identity) assert bc_matmul(X*X) == BlockDiagMatrix(A*A, B*B, C*C) assert block_collapse(X*X) == BlockDiagMatrix(A*A, B*B, C*C) #XXX: should be == ?? assert block_collapse(X + X).equals(BlockDiagMatrix(2*A, 2*B, 2*C)) assert block_collapse(X*Y) == BlockDiagMatrix(A*A, 2*B*B, 3*C*C) assert block_collapse(X + Y) == BlockDiagMatrix(2*A, 3*B, 4*C) # Ensure that BlockDiagMatrices can still interact with normal MatrixExprs assert (X*(2*M)).is_MatMul assert (X + (2*M)).is_MatAdd assert (X._blockmul(M)).is_MatMul assert (X._blockadd(M)).is_MatAdd def test_blockcut(): A = MatrixSymbol('A', n, m) B = blockcut(A, (n/2, n/2), (m/2, m/2)) assert A[i, j] == B[i, j] assert B == BlockMatrix([[A[:n/2, :m/2], A[:n/2, m/2:]], [A[n/2:, :m/2], A[n/2:, m/2:]]]) M = ImmutableMatrix(4, 4, range(16)) B = blockcut(M, (2, 2), (2, 2)) assert M == ImmutableMatrix(B) B = blockcut(M, (1, 3), (2, 2)) assert ImmutableMatrix(B.blocks[0, 1]) == ImmutableMatrix([[2, 3]]) def test_reblock_2x2(): B = BlockMatrix([[MatrixSymbol('A_%d%d'%(i,j), 2, 2) for j in range(3)] for i in range(3)]) assert B.blocks.shape == (3, 3) BB = reblock_2x2(B) assert BB.blocks.shape == (2, 2) assert B.shape == BB.shape assert B.as_explicit() == BB.as_explicit() def test_deblock(): B = BlockMatrix([[MatrixSymbol('A_%d%d'%(i,j), n, n) for j in range(4)] for i in range(4)]) assert deblock(reblock_2x2(B)) == B

4d80c000291c5c7ce096dc58a0107e44cac2ba84a6478cfe001f85a37c660616

""" Some examples have been taken from: http://www.math.uwaterloo.ca/~hwolkowi//matrixcookbook.pdf """ from sympy import MatrixSymbol, Inverse, symbols, Determinant, Trace, Derivative, sin, exp, cos, tan, log from sympy import MatAdd, Identity, MatMul, ZeroMatrix k = symbols("k") X = MatrixSymbol("X", k, k) x = MatrixSymbol("x", k, 1) y = MatrixSymbol("y", k, 1) A = MatrixSymbol("A", k, k) B = MatrixSymbol("B", k, k) C = MatrixSymbol("C", k, k) D = MatrixSymbol("D", k, k) a = MatrixSymbol("a", k, 1) b = MatrixSymbol("b", k, 1) c = MatrixSymbol("c", k, 1) d = MatrixSymbol("d", k, 1) def _check_derivative_with_explicit_matrix(expr, x, diffexpr, dim=2): # TODO: this is commented because it slows down the tests. return expr = expr.xreplace({k: dim}) x = x.xreplace({k: dim}) diffexpr = diffexpr.xreplace({k: dim}) expr = expr.as_explicit() x = x.as_explicit() diffexpr = diffexpr.as_explicit() assert expr.diff(x).reshape(*diffexpr.shape).tomatrix() == diffexpr def test_matrix_derivative_non_matrix_result(): # This is a 4-dimensional array: assert A.diff(A) == Derivative(A, A) assert A.T.diff(A) == Derivative(A.T, A) assert (2*A).diff(A) == Derivative(2*A, A) assert MatAdd(A, A).diff(A) == Derivative(MatAdd(A, A), A) assert (A + B).diff(A) == Derivative(A + B, A) # TODO: `B` can be removed. def test_matrix_derivative_trivial_cases(): # Cookbook example 33: # TODO: find a way to represent a four-dimensional zero-array: assert X.diff(A) == Derivative(X, A) def test_matrix_derivative_with_inverse(): # Cookbook example 61: expr = a.T*Inverse(X)*b assert expr.diff(X) == -Inverse(X).T*a*b.T*Inverse(X).T # Cookbook example 62: expr = Determinant(Inverse(X)) # Not implemented yet: # assert expr.diff(X) == -Determinant(X.inv())*(X.inv()).T # Cookbook example 63: expr = Trace(A*Inverse(X)*B) assert expr.diff(X) == -(X**(-1)*B*A*X**(-1)).T # Cookbook example 64: expr = Trace(Inverse(X + A)) assert expr.diff(X) == -(Inverse(X + A)).T**2 def test_matrix_derivative_vectors_and_scalars(): assert x.diff(x) == Identity(k) assert x.T.diff(x) == Identity(k) # Cookbook example 69: expr = x.T*a assert expr.diff(x) == a expr = a.T*x assert expr.diff(x) == a # Cookbook example 70: expr = a.T*X*b assert expr.diff(X) == a*b.T # Cookbook example 71: expr = a.T*X.T*b assert expr.diff(X) == b*a.T # Cookbook example 72: expr = a.T*X*a assert expr.diff(X) == a*a.T expr = a.T*X.T*a assert expr.diff(X) == a*a.T # Cookbook example 77: expr = b.T*X.T*X*c assert expr.diff(X) == X*b*c.T + X*c*b.T # Cookbook example 78: expr = (B*x + b).T*C*(D*x + d) assert expr.diff(x) == B.T*C*(D*x + d) + D.T*C.T*(B*x + b) # Cookbook example 81: expr = x.T*B*x assert expr.diff(x) == B*x + B.T*x # Cookbook example 82: expr = b.T*X.T*D*X*c assert expr.diff(X) == D.T*X*b*c.T + D*X*c*b.T # Cookbook example 83: expr = (X*b + c).T*D*(X*b + c) assert expr.diff(X) == D*(X*b + c)*b.T + D.T*(X*b + c)*b.T def test_matrix_derivatives_of_traces(): expr = Trace(A)*A assert expr.diff(A) == Derivative(Trace(A)*A, A) ## First order: # Cookbook example 99: expr = Trace(X) assert expr.diff(X) == Identity(k) # Cookbook example 100: expr = Trace(X*A) assert expr.diff(X) == A.T # Cookbook example 101: expr = Trace(A*X*B) assert expr.diff(X) == A.T*B.T # Cookbook example 102: expr = Trace(A*X.T*B) assert expr.diff(X) == B*A # Cookbook example 103: expr = Trace(X.T*A) assert expr.diff(X) == A # Cookbook example 104: expr = Trace(A*X.T) assert expr.diff(X) == A # Cookbook example 105: # TODO: TensorProduct is not supported #expr = Trace(TensorProduct(A, X)) #assert expr.diff(X) == Trace(A)*Identity(k) ## Second order: # Cookbook example 106: expr = Trace(X**2) assert expr.diff(X) == 2*X.T # Cookbook example 107: expr = Trace(X**2*B) assert expr.diff(X) == (X*B + B*X).T expr = Trace(MatMul(X, X, B)) assert expr.diff(X) == (X*B + B*X).T # Cookbook example 108: expr = Trace(X.T*B*X) assert expr.diff(X) == B*X + B.T*X # Cookbook example 109: expr = Trace(B*X*X.T) assert expr.diff(X) == B*X + B.T*X # Cookbook example 110: expr = Trace(X*X.T*B) assert expr.diff(X) == B*X + B.T*X # Cookbook example 111: expr = Trace(X*B*X.T) assert expr.diff(X) == X*B.T + X*B # Cookbook example 112: expr = Trace(B*X.T*X) assert expr.diff(X) == X*B.T + X*B # Cookbook example 113: expr = Trace(X.T*X*B) assert expr.diff(X) == X*B.T + X*B # Cookbook example 114: expr = Trace(A*X*B*X) assert expr.diff(X) == A.T*X.T*B.T + B.T*X.T*A.T # Cookbook example 115: expr = Trace(X.T*X) assert expr.diff(X) == 2*X expr = Trace(X*X.T) assert expr.diff(X) == 2*X # Cookbook example 116: expr = Trace(B.T*X.T*C*X*B) assert expr.diff(X) == C.T*X*B*B.T + C*X*B*B.T # Cookbook example 117: expr = Trace(X.T*B*X*C) assert expr.diff(X) == B*X*C + B.T*X*C.T # Cookbook example 118: expr = Trace(A*X*B*X.T*C) assert expr.diff(X) == A.T*C.T*X*B.T + C*A*X*B # Cookbook example 119: expr = Trace((A*X*B + C)*(A*X*B + C).T) assert expr.diff(X) == 2*A.T*(A*X*B + C)*B.T # Cookbook example 120: # TODO: no support for TensorProduct. # expr = Trace(TensorProduct(X, X)) # expr = Trace(X)*Trace(X) # expr.diff(X) == 2*Trace(X)*Identity(k) # Higher Order # Cookbook example 121: expr = Trace(X**k) #assert expr.diff(X) == k*(X**(k-1)).T # Cookbook example 122: expr = Trace(A*X**k) #assert expr.diff(X) == # Needs indices # Cookbook example 123: expr = Trace(B.T*X.T*C*X*X.T*C*X*B) assert expr.diff(X) == C*X*X.T*C*X*B*B.T + C.T*X*B*B.T*X.T*C.T*X + C*X*B*B.T*X.T*C*X + C.T*X*X.T*C.T*X*B*B.T # Other # Cookbook example 124: expr = Trace(A*X**(-1)*B) assert expr.diff(X) == -Inverse(X).T*A.T*B.T*Inverse(X).T # Cookbook example 125: expr = Trace(Inverse(X.T*C*X)*A) # Warning: result in the cookbook is equivalent if B and C are symmetric: assert expr.diff(X) == - X.inv().T*A.T*X.inv()*C.inv().T*X.inv().T - X.inv().T*A*X.inv()*C.inv()*X.inv().T # Cookbook example 126: expr = Trace((X.T*C*X).inv()*(X.T*B*X)) assert expr.diff(X) == -2*C*X*(X.T*C*X).inv()*X.T*B*X*(X.T*C*X).inv() + 2*B*X*(X.T*C*X).inv() # Cookbook example 127: expr = Trace((A + X.T*C*X).inv()*(X.T*B*X)) # Warning: result in the cookbook is equivalent if B and C are symmetric: assert expr.diff(X) == B*X*Inverse(A + X.T*C*X) - C*X*Inverse(A + X.T*C*X)*X.T*B*X*Inverse(A + X.T*C*X) - C.T*X*Inverse(A.T + (C*X).T*X)*X.T*B.T*X*Inverse(A.T + (C*X).T*X) + B.T*X*Inverse(A.T + (C*X).T*X) def test_derivatives_of_complicated_matrix_expr(): expr = a.T*(A*X*(X.T*B + X*A) + B.T*X.T*(a*b.T*(X*D*X.T + X*(X.T*B + A*X)*D*B - X.T*C.T*A)*B + B*(X*D.T + B*A*X*A.T - 3*X*D))*B + 42*X*B*X.T*A.T*(X + X.T))*b result = (B*(B*A*X*A.T - 3*X*D + X*D.T) + a*b.T*(X*(A*X + X.T*B)*D*B + X*D*X.T - X.T*C.T*A)*B)*B*b*a.T*B.T + B**2*b*a.T*B.T*X.T*a*b.T*X*D + 42*A*X*B.T*X.T*a*b.T + B*D*B**3*b*a.T*B.T*X.T*a*b.T*X + B*b*a.T*A*X + 42*a*b.T*(X + X.T)*A*X*B.T + b*a.T*X*B*a*b.T*B.T**2*X*D.T + b*a.T*X*B*a*b.T*B.T**3*D.T*(B.T*X + X.T*A.T) + 42*b*a.T*X*B*X.T*A.T + 42*A.T*(X + X.T)*b*a.T*X*B + A.T*B.T**2*X*B*a*b.T*B.T*A + A.T*a*b.T*(A.T*X.T + B.T*X) + A.T*X.T*b*a.T*X*B*a*b.T*B.T**3*D.T + B.T*X*B*a*b.T*B.T*D - 3*B.T*X*B*a*b.T*B.T*D.T - C.T*A*B**2*b*a.T*B.T*X.T*a*b.T + X.T*A.T*a*b.T*A.T assert expr.diff(X) == result def test_mixed_deriv_mixed_expressions(): expr = 3*Trace(A) assert expr.diff(A) == 3*Identity(k) expr = k deriv = expr.diff(A) assert isinstance(deriv, ZeroMatrix) assert deriv == ZeroMatrix(k, k) expr = Trace(A)**2 assert expr.diff(A) == (2*Trace(A))*Identity(k) expr = Trace(A)*A # TODO: this is not yet supported: assert expr.diff(A) == Derivative(expr, A) expr = Trace(Trace(A)*A) assert expr.diff(A) == (2*Trace(A))*Identity(k) expr = Trace(Trace(Trace(A)*A)*A) assert expr.diff(A) == (3*Trace(A)**2)*Identity(k) def test_derivatives_elementwise_applyfunc(): from sympy.matrices.expressions.diagonal import DiagonalizeVector expr = x.applyfunc(tan) assert expr.diff(x) == DiagonalizeVector(x.applyfunc(lambda x: tan(x)**2 + 1)) _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = A*x.applyfunc(exp) assert expr.diff(x) == DiagonalizeVector(x.applyfunc(exp))*A.T _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = x.T*A*x + k*y.applyfunc(sin).T*x assert expr.diff(x) == A.T*x + A*x + k*y.applyfunc(sin) _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = x.applyfunc(sin).T*y assert expr.diff(x) == DiagonalizeVector(x.applyfunc(cos))*y _check_derivative_with_explicit_matrix(expr, x, expr.diff(x)) expr = (a.T * X * b).applyfunc(sin) assert expr.diff(X) == a*(a.T*X*b).applyfunc(cos)*b.T _check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * X.applyfunc(sin) * b assert expr.diff(X) == DiagonalizeVector(a)*X.applyfunc(cos)*DiagonalizeVector(b) _check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * (A*X*B).applyfunc(sin) * b assert expr.diff(X) == A.T*DiagonalizeVector(a)*(A*X*B).applyfunc(cos)*DiagonalizeVector(b)*B.T _check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * (A*X*b).applyfunc(sin) * b.T # TODO: not implemented #assert expr.diff(X) == ... #_check_derivative_with_explicit_matrix(expr, X, expr.diff(X)) expr = a.T * (A*X.applyfunc(sin)*B).applyfunc(log) * b # assert expr.diff(X) == ... expr = a.T * (X.applyfunc(sin)).applyfunc(log) * b # assert expr.diff(X) == ...

97074ccdaed08509fe02c2d47912608af6efd30040a53c867171b9cf08a029ea

from sympy import (KroneckerDelta, diff, Piecewise, Sum, Dummy, factor, expand, zeros, gcd_terms, Eq) from sympy.core import S, symbols, Add, Mul, SympifyError from sympy.core.compatibility import long from sympy.functions import transpose, sin, cos, sqrt, cbrt, exp from sympy.simplify import simplify from sympy.matrices import (Identity, ImmutableMatrix, Inverse, MatAdd, MatMul, MatPow, Matrix, MatrixExpr, MatrixSymbol, ShapeError, ZeroMatrix, SparseMatrix, Transpose, Adjoint) from sympy.matrices.expressions.matexpr import (MatrixElement, GenericZeroMatrix, GenericIdentity) from sympy.utilities.pytest import raises, XFAIL n, m, l, k, p = symbols('n m l k p', integer=True) x = symbols('x') A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) C = MatrixSymbol('C', n, n) D = MatrixSymbol('D', n, n) E = MatrixSymbol('E', m, n) w = MatrixSymbol('w', n, 1) def test_shape(): assert A.shape == (n, m) assert (A*B).shape == (n, l) raises(ShapeError, lambda: B*A) def test_matexpr(): assert (x*A).shape == A.shape assert (x*A).__class__ == MatMul assert 2*A - A - A == ZeroMatrix(*A.shape) assert (A*B).shape == (n, l) def test_subs(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) C = MatrixSymbol('C', m, l) assert A.subs(n, m).shape == (m, m) assert (A*B).subs(B, C) == A*C assert (A*B).subs(l, n).is_square def test_ZeroMatrix(): A = MatrixSymbol('A', n, m) Z = ZeroMatrix(n, m) assert A + Z == A assert A*Z.T == ZeroMatrix(n, n) assert Z*A.T == ZeroMatrix(n, n) assert A - A == ZeroMatrix(*A.shape) assert not Z assert transpose(Z) == ZeroMatrix(m, n) assert Z.conjugate() == Z assert ZeroMatrix(n, n)**0 == Identity(n) with raises(ShapeError): Z**0 with raises(ShapeError): Z**2 def test_ZeroMatrix_doit(): Znn = ZeroMatrix(Add(n, n, evaluate=False), n) assert isinstance(Znn.rows, Add) assert Znn.doit() == ZeroMatrix(2*n, n) assert isinstance(Znn.doit().rows, Mul) def test_Identity(): A = MatrixSymbol('A', n, m) i, j = symbols('i j') In = Identity(n) Im = Identity(m) assert A*Im == A assert In*A == A assert transpose(In) == In assert In.inverse() == In assert In.conjugate() == In assert In[i, j] != 0 assert Sum(In[i, j], (i, 0, n-1), (j, 0, n-1)).subs(n,3).doit() == 3 assert Sum(Sum(In[i, j], (i, 0, n-1)), (j, 0, n-1)).subs(n,3).doit() == 3 def test_Identity_doit(): Inn = Identity(Add(n, n, evaluate=False)) assert isinstance(Inn.rows, Add) assert Inn.doit() == Identity(2*n) assert isinstance(Inn.doit().rows, Mul) def test_addition(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', n, m) assert isinstance(A + B, MatAdd) assert (A + B).shape == A.shape assert isinstance(A - A + 2*B, MatMul) raises(ShapeError, lambda: A + B.T) raises(TypeError, lambda: A + 1) raises(TypeError, lambda: 5 + A) raises(TypeError, lambda: 5 - A) assert A + ZeroMatrix(n, m) - A == ZeroMatrix(n, m) with raises(TypeError): ZeroMatrix(n,m) + S(0) def test_multiplication(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) C = MatrixSymbol('C', n, n) assert (2*A*B).shape == (n, l) assert (A*0*B) == ZeroMatrix(n, l) raises(ShapeError, lambda: B*A) assert (2*A).shape == A.shape assert A * ZeroMatrix(m, m) * B == ZeroMatrix(n, l) assert C * Identity(n) * C.I == Identity(n) assert B/2 == S.Half*B raises(NotImplementedError, lambda: 2/B) A = MatrixSymbol('A', n, n) B = MatrixSymbol('B', n, n) assert Identity(n) * (A + B) == A + B assert A**2*A == A**3 assert A**2*(A.I)**3 == A.I assert A**3*(A.I)**2 == A def test_MatPow(): A = MatrixSymbol('A', n, n) AA = MatPow(A, 2) assert AA.exp == 2 assert AA.base == A assert (A**n).exp == n assert A**0 == Identity(n) assert A**1 == A assert A**2 == AA assert A**-1 == Inverse(A) assert (A**-1)**-1 == A assert (A**2)**3 == A**6 assert A**S.Half == sqrt(A) assert A**(S(1)/3) == cbrt(A) raises(ShapeError, lambda: MatrixSymbol('B', 3, 2)**2) def test_MatrixSymbol(): n, m, t = symbols('n,m,t') X = MatrixSymbol('X', n, m) assert X.shape == (n, m) raises(TypeError, lambda: MatrixSymbol('X', n, m)(t)) # issue 5855 assert X.doit() == X def test_dense_conversion(): X = MatrixSymbol('X', 2, 2) assert ImmutableMatrix(X) == ImmutableMatrix(2, 2, lambda i, j: X[i, j]) assert Matrix(X) == Matrix(2, 2, lambda i, j: X[i, j]) def test_free_symbols(): assert (C*D).free_symbols == set((C, D)) def test_zero_matmul(): assert isinstance(S.Zero * MatrixSymbol('X', 2, 2), MatrixExpr) def test_matadd_simplify(): A = MatrixSymbol('A', 1, 1) assert simplify(MatAdd(A, ImmutableMatrix([[sin(x)**2 + cos(x)**2]]))) == \ MatAdd(A, ImmutableMatrix([[1]])) def test_matmul_simplify(): A = MatrixSymbol('A', 1, 1) assert simplify(MatMul(A, ImmutableMatrix([[sin(x)**2 + cos(x)**2]]))) == \ MatMul(A, ImmutableMatrix([[1]])) def test_invariants(): A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', m, l) X = MatrixSymbol('X', n, n) objs = [Identity(n), ZeroMatrix(m, n), A, MatMul(A, B), MatAdd(A, A), Transpose(A), Adjoint(A), Inverse(X), MatPow(X, 2), MatPow(X, -1), MatPow(X, 0)] for obj in objs: assert obj == obj.__class__(*obj.args) def test_indexing(): A = MatrixSymbol('A', n, m) A[1, 2] A[l, k] A[l+1, k+1] def test_single_indexing(): A = MatrixSymbol('A', 2, 3) assert A[1] == A[0, 1] assert A[long(1)] == A[0, 1] assert A[3] == A[1, 0] assert list(A[:2, :2]) == [A[0, 0], A[0, 1], A[1, 0], A[1, 1]] raises(IndexError, lambda: A[6]) raises(IndexError, lambda: A[n]) B = MatrixSymbol('B', n, m) raises(IndexError, lambda: B[1]) B = MatrixSymbol('B', n, 3) assert B[3] == B[1, 0] def test_MatrixElement_commutative(): assert A[0, 1]*A[1, 0] == A[1, 0]*A[0, 1] def test_MatrixSymbol_determinant(): A = MatrixSymbol('A', 4, 4) assert A.as_explicit().det() == A[0, 0]*A[1, 1]*A[2, 2]*A[3, 3] - \ A[0, 0]*A[1, 1]*A[2, 3]*A[3, 2] - A[0, 0]*A[1, 2]*A[2, 1]*A[3, 3] + \ A[0, 0]*A[1, 2]*A[2, 3]*A[3, 1] + A[0, 0]*A[1, 3]*A[2, 1]*A[3, 2] - \ A[0, 0]*A[1, 3]*A[2, 2]*A[3, 1] - A[0, 1]*A[1, 0]*A[2, 2]*A[3, 3] + \ A[0, 1]*A[1, 0]*A[2, 3]*A[3, 2] + A[0, 1]*A[1, 2]*A[2, 0]*A[3, 3] - \ A[0, 1]*A[1, 2]*A[2, 3]*A[3, 0] - A[0, 1]*A[1, 3]*A[2, 0]*A[3, 2] + \ A[0, 1]*A[1, 3]*A[2, 2]*A[3, 0] + A[0, 2]*A[1, 0]*A[2, 1]*A[3, 3] - \ A[0, 2]*A[1, 0]*A[2, 3]*A[3, 1] - A[0, 2]*A[1, 1]*A[2, 0]*A[3, 3] + \ A[0, 2]*A[1, 1]*A[2, 3]*A[3, 0] + A[0, 2]*A[1, 3]*A[2, 0]*A[3, 1] - \ A[0, 2]*A[1, 3]*A[2, 1]*A[3, 0] - A[0, 3]*A[1, 0]*A[2, 1]*A[3, 2] + \ A[0, 3]*A[1, 0]*A[2, 2]*A[3, 1] + A[0, 3]*A[1, 1]*A[2, 0]*A[3, 2] - \ A[0, 3]*A[1, 1]*A[2, 2]*A[3, 0] - A[0, 3]*A[1, 2]*A[2, 0]*A[3, 1] + \ A[0, 3]*A[1, 2]*A[2, 1]*A[3, 0] def test_MatrixElement_diff(): assert (A[3, 0]*A[0, 0]).diff(A[0, 0]) == A[3, 0] def test_MatrixElement_doit(): u = MatrixSymbol('u', 2, 1) v = ImmutableMatrix([3, 5]) assert u[0, 0].subs(u, v).doit() == v[0, 0] def test_identity_powers(): M = Identity(n) assert MatPow(M, 3).doit() == M**3 assert M**n == M assert MatPow(M, 0).doit() == M**2 assert M**-2 == M assert MatPow(M, -2).doit() == M**0 N = Identity(3) assert MatPow(N, 2).doit() == N**n assert MatPow(N, 3).doit() == N assert MatPow(N, -2).doit() == N**4 assert MatPow(N, 2).doit() == N**0 def test_Zero_power(): z1 = ZeroMatrix(n, n) assert z1**4 == z1 raises(ValueError, lambda:z1**-2) assert z1**0 == Identity(n) assert MatPow(z1, 2).doit() == z1**2 raises(ValueError, lambda:MatPow(z1, -2).doit()) z2 = ZeroMatrix(3, 3) assert MatPow(z2, 4).doit() == z2**4 raises(ValueError, lambda:z2**-3) assert z2**3 == MatPow(z2, 3).doit() assert z2**0 == Identity(3) raises(ValueError, lambda:MatPow(z2, -1).doit()) def test_matrixelement_diff(): dexpr = diff((D*w)[k,0], w[p,0]) assert w[k, p].diff(w[k, p]) == 1 assert w[k, p].diff(w[0, 0]) == KroneckerDelta(0, k)*KroneckerDelta(0, p) assert str(dexpr) == "Sum(KroneckerDelta(_i_1, p)*D[k, _i_1], (_i_1, 0, n - 1))" assert str(dexpr.doit()) == 'Piecewise((D[k, p], (p >= 0) & (p <= n - 1)), (0, True))' # TODO: bug with .dummy_eq( ), the previous 2 lines should be replaced by: return # stop eval _i_1 = Dummy("_i_1") assert dexpr.dummy_eq(Sum(KroneckerDelta(_i_1, p)*D[k, _i_1], (_i_1, 0, n - 1))) assert dexpr.doit().dummy_eq(Piecewise((D[k, p], (p >= 0) & (p <= n - 1)), (0, True))) def test_MatrixElement_with_values(): x, y, z, w = symbols("x y z w") M = Matrix([[x, y], [z, w]]) i, j = symbols("i, j") Mij = M[i, j] assert isinstance(Mij, MatrixElement) Ms = SparseMatrix([[2, 3], [4, 5]]) msij = Ms[i, j] assert isinstance(msij, MatrixElement) for oi, oj in [(0, 0), (0, 1), (1, 0), (1, 1)]: assert Mij.subs({i: oi, j: oj}) == M[oi, oj] assert msij.subs({i: oi, j: oj}) == Ms[oi, oj] A = MatrixSymbol("A", 2, 2) assert A[0, 0].subs(A, M) == x assert A[i, j].subs(A, M) == M[i, j] assert M[i, j].subs(M, A) == A[i, j] assert isinstance(M[3*i - 2, j], MatrixElement) assert M[3*i - 2, j].subs({i: 1, j: 0}) == M[1, 0] assert isinstance(M[i, 0], MatrixElement) assert M[i, 0].subs(i, 0) == M[0, 0] assert M[0, i].subs(i, 1) == M[0, 1] assert M[i, j].diff(x) == Matrix([[1, 0], [0, 0]])[i, j] raises(ValueError, lambda: M[i, 2]) raises(ValueError, lambda: M[i, -1]) raises(ValueError, lambda: M[2, i]) raises(ValueError, lambda: M[-1, i]) def test_inv(): B = MatrixSymbol('B', 3, 3) assert B.inv() == B**-1 @XFAIL def test_factor_expand(): A = MatrixSymbol("A", n, n) B = MatrixSymbol("B", n, n) expr1 = (A + B)*(C + D) expr2 = A*C + B*C + A*D + B*D assert expr1 != expr2 assert expand(expr1) == expr2 assert factor(expr2) == expr1 expr = B**(-1)*(A**(-1)*B**(-1) - A**(-1)*C*B**(-1))**(-1)*A**(-1) I = Identity(n) # Ideally we get the first, but we at least don't want a wrong answer assert factor(expr) in [I - C, B**-1*(A**-1*(I - C)*B**-1)**-1*A**-1] def test_issue_2749(): A = MatrixSymbol("A", 5, 2) assert (A.T * A).I.as_explicit() == Matrix([[(A.T * A).I[0, 0], (A.T * A).I[0, 1]], \ [(A.T * A).I[1, 0], (A.T * A).I[1, 1]]]) def test_issue_2750(): x = MatrixSymbol('x', 1, 1) assert (x.T*x).as_explicit()**-1 == Matrix([[x[0, 0]**(-2)]]) def test_issue_7842(): A = MatrixSymbol('A', 3, 1) B = MatrixSymbol('B', 2, 1) assert Eq(A, B) == False assert Eq(A[1,0], B[1, 0]).func is Eq A = ZeroMatrix(2, 3) B = ZeroMatrix(2, 3) assert Eq(A, B) == True def test_generic_zero_matrix(): z = GenericZeroMatrix() A = MatrixSymbol("A", n, n) assert z == z assert z != A assert A != z assert z.is_ZeroMatrix raises(TypeError, lambda: z.shape) raises(TypeError, lambda: z.rows) raises(TypeError, lambda: z.cols) assert MatAdd() == z assert MatAdd(z, A) == MatAdd(A) # Make sure it is hashable hash(z) def test_generic_identity(): I = GenericIdentity() A = MatrixSymbol("A", n, n) assert I == I assert I != A assert A != I assert I.is_Identity assert I**-1 == I raises(TypeError, lambda: I.shape) raises(TypeError, lambda: I.rows) raises(TypeError, lambda: I.cols) assert MatMul() == I assert MatMul(I, A) == MatMul(A) # Make sure it is hashable hash(I) def test_MatMul_postprocessor(): z = zeros(2) z1 = ZeroMatrix(2, 2) assert Mul(0, z) == Mul(z, 0) in [z, z1] M = Matrix([[1, 2], [3, 4]]) Mx = Matrix([[x, 2*x], [3*x, 4*x]]) assert Mul(x, M) == Mul(M, x) == Mx A = MatrixSymbol("A", 2, 2) assert Mul(A, M) == MatMul(A, M) assert Mul(M, A) == MatMul(M, A) # Scalars should be absorbed into constant matrices a = Mul(x, M, A) b = Mul(M, x, A) c = Mul(M, A, x) assert a == b == c == MatMul(Mx, A) a = Mul(x, A, M) b = Mul(A, x, M) c = Mul(A, M, x) assert a == b == c == MatMul(A, Mx) assert Mul(M, M) == M**2 assert Mul(A, M, M) == MatMul(A, M**2) assert Mul(M, M, A) == MatMul(M**2, A) assert Mul(M, A, M) == MatMul(M, A, M) assert Mul(A, x, M, M, x) == MatMul(A, Mx**2) @XFAIL def test_MatAdd_postprocessor_xfail(): # This is difficult to get working because of the way that Add processes # its args. z = zeros(2) assert Add(z, S.NaN) == Add(S.NaN, z) def test_MatAdd_postprocessor(): # Some of these are nonsensical, but we do not raise errors for Add # because that breaks algorithms that want to replace matrices with dummy # symbols. z = zeros(2) assert Add(0, z) == Add(z, 0) == z a = Add(S.Infinity, z) assert a == Add(z, S.Infinity) assert isinstance(a, Add) assert a.args == (S.Infinity, z) a = Add(S.ComplexInfinity, z) assert a == Add(z, S.ComplexInfinity) assert isinstance(a, Add) assert a.args == (S.ComplexInfinity, z) a = Add(z, S.NaN) # assert a == Add(S.NaN, z) # See the XFAIL above assert isinstance(a, Add) assert a.args == (S.NaN, z) M = Matrix([[1, 2], [3, 4]]) a = Add(x, M) assert a == Add(M, x) assert isinstance(a, Add) assert a.args == (x, M) A = MatrixSymbol("A", 2, 2) assert Add(A, M) == Add(M, A) == A + M # Scalars should be absorbed into constant matrices (producing an error) a = Add(x, M, A) assert a == Add(M, x, A) == Add(M, A, x) == Add(x, A, M) == Add(A, x, M) == Add(A, M, x) assert isinstance(a, Add) assert a.args == (x, A + M) assert Add(M, M) == 2*M assert Add(M, A, M) == Add(M, M, A) == Add(A, M, M) == A + 2*M a = Add(A, x, M, M, x) assert isinstance(a, Add) assert a.args == (2*x, A + 2*M) def test_simplify_matrix_expressions(): # Various simplification functions assert type(gcd_terms(C*D + D*C)) == MatAdd a = gcd_terms(2*C*D + 4*D*C) assert type(a) == MatMul assert a.args == (2, (C*D + 2*D*C)) def test_exp(): A = MatrixSymbol('A', 2, 2) B = MatrixSymbol('B', 2, 2) expr1 = exp(A)*exp(B) expr2 = exp(B)*exp(A) assert expr1 != expr2 assert expr1 - expr2 != 0 assert not isinstance(expr1, exp) assert not isinstance(expr2, exp) def test_invalid_args(): raises(SympifyError, lambda: MatrixSymbol(1, 2, 'A'))

0baf4ec1f64124064f718a76bd0546f178333f73b310093f24fe921dadc43dfc

from sympy.matrices.expressions import MatrixSymbol from sympy.matrices.expressions.diagonal import DiagonalMatrix, DiagonalOf, DiagonalizeVector, diagonalize_vector from sympy import Symbol, ask, Q, KroneckerDelta, Identity, Matrix from sympy.utilities.pytest import raises n = Symbol('n') m = Symbol('m') def test_DiagonalMatrix(): x = MatrixSymbol('x', n, m) D = DiagonalMatrix(x) assert D.diagonal_length is None assert D.shape == (n, m) x = MatrixSymbol('x', n, n) D = DiagonalMatrix(x) assert D.diagonal_length == n assert D.shape == (n, n) assert D[1, 2] == 0 assert D[1, 1] == x[1, 1] i = Symbol('i') j = Symbol('j') x = MatrixSymbol('x', 3, 3) ij = DiagonalMatrix(x)[i, j] assert ij != 0 assert ij.subs({i:0, j:0}) == x[0, 0] assert ij.subs({i:0, j:1}) == 0 assert ij.subs({i:1, j:1}) == x[1, 1] assert ask(Q.diagonal(D)) # affirm that D is diagonal x = MatrixSymbol('x', n, 3) D = DiagonalMatrix(x) assert D.diagonal_length == 3 assert D.shape == (n, 3) assert D[2, m] == KroneckerDelta(2, m)*x[2, m] assert D[3, m] == 0 raises(IndexError, lambda: D[m, 3]) x = MatrixSymbol('x', 3, n) D = DiagonalMatrix(x) assert D.diagonal_length == 3 assert D.shape == (3, n) assert D[m, 2] == KroneckerDelta(m, 2)*x[m, 2] assert D[m, 3] == 0 raises(IndexError, lambda: D[3, m]) x = MatrixSymbol('x', n, m) D = DiagonalMatrix(x) assert D.diagonal_length is None assert D.shape == (n, m) assert D[m, 4] != 0 x = MatrixSymbol('x', 3, 4) assert [DiagonalMatrix(x)[i] for i in range(12)] == [ x[0, 0], 0, 0, 0, 0, x[1, 1], 0, 0, 0, 0, x[2, 2], 0] # shape is retained, issue 12427 assert ( DiagonalMatrix(MatrixSymbol('x', 3, 4))* DiagonalMatrix(MatrixSymbol('x', 4, 2))).shape == (3, 2) def test_DiagonalOf(): x = MatrixSymbol('x', n, n) d = DiagonalOf(x) assert d.shape == (n, 1) assert d.diagonal_length == n assert d[2, 0] == d[2] == x[2, 2] x = MatrixSymbol('x', n, m) d = DiagonalOf(x) assert d.shape == (None, 1) assert d.diagonal_length is None assert d[2, 0] == d[2] == x[2, 2] d = DiagonalOf(MatrixSymbol('x', 4, 3)) assert d.shape == (3, 1) d = DiagonalOf(MatrixSymbol('x', n, 3)) assert d.shape == (3, 1) d = DiagonalOf(MatrixSymbol('x', 3, n)) assert d.shape == (3, 1) x = MatrixSymbol('x', n, m) assert [DiagonalOf(x)[i] for i in range(4)] ==[ x[0, 0], x[1, 1], x[2, 2], x[3, 3]] def test_DiagonalizeVector(): x = MatrixSymbol('x', n, 1) d = DiagonalizeVector(x) assert d.shape == (n, n) assert d[0, 1] == 0 assert d[0, 0] == x[0, 0] a = MatrixSymbol('a', 1, 1) d = diagonalize_vector(a) assert isinstance(d, MatrixSymbol) assert a == d assert diagonalize_vector(Identity(3)) == Identity(3) assert isinstance(DiagonalizeVector(Identity(3)), DiagonalizeVector) # A diagonal matrix is equal to its transpose: assert DiagonalizeVector(x).T == DiagonalizeVector(x) assert diagonalize_vector(x.T) == DiagonalizeVector(x) dx = DiagonalizeVector(x) assert dx[0, 0] == x[0, 0] assert dx[1, 1] == x[1, 0] assert dx[0, 1] == 0 assert dx[0, m] == x[0, 0]*KroneckerDelta(0, m) z = MatrixSymbol('z', 1, n) dz = DiagonalizeVector(z) assert dz[0, 0] == z[0, 0] assert dz[1, 1] == z[0, 1] assert dz[0, 1] == 0 assert dz[0, m] == z[0, m]*KroneckerDelta(0, m) v = MatrixSymbol('v', 3, 1) dv = DiagonalizeVector(v) assert dv.as_explicit() == Matrix([ [v[0, 0], 0, 0], [0, v[1, 0], 0], [0, 0, v[2, 0]], ]) v = MatrixSymbol('v', 1, 3) dv = DiagonalizeVector(v) assert dv.as_explicit() == Matrix([ [v[0, 0], 0, 0], [0, v[0, 1], 0], [0, 0, v[0, 2]], ])

ca58d9c2aaf5864ae8c2d83938e931924999913fd72e5b2ec95c1abc2159da87

from sympy.matrices.expressions.applyfunc import ElementwiseApplyFunction from sympy import (Matrix, Lambda, MatrixBase, MatrixSymbol, exp, symbols, MatMul, sin) from sympy.utilities.pytest import raises from sympy.matrices.common import ShapeError X = MatrixSymbol("X", 3, 3) Y = MatrixSymbol("Y", 3, 3) k = symbols("k") Xk = MatrixSymbol("X", k, k) Xd = X.as_explicit() x, y, z, t = symbols("x y z t") def test_applyfunc_matrix(): double = Lambda(x, x**2) expr = ElementwiseApplyFunction(double, Xd) assert isinstance(expr, ElementwiseApplyFunction) assert expr.doit() == Xd.applyfunc(lambda x: x**2) assert expr.shape == (3, 3) assert expr.func(*expr.args) == expr assert expr[0, 0] == double(Xd[0, 0]) expr = ElementwiseApplyFunction(double, X) assert isinstance(expr, ElementwiseApplyFunction) assert isinstance(expr.doit(), ElementwiseApplyFunction) assert expr == X.applyfunc(double) assert expr.func(*expr.args) == expr expr = ElementwiseApplyFunction(exp, X*Y) assert expr.expr == X*Y assert expr.function == exp assert expr == (X*Y).applyfunc(exp) assert expr.func(*expr.args) == expr assert isinstance(X*expr, MatMul) assert (X*expr).shape == (3, 3) Z = MatrixSymbol("Z", 2, 3) assert (Z*expr).shape == (2, 3) expr = ElementwiseApplyFunction(exp, Z.T)*ElementwiseApplyFunction(exp, Z) assert expr.shape == (3, 3) expr = ElementwiseApplyFunction(exp, Z)*ElementwiseApplyFunction(exp, Z.T) assert expr.shape == (2, 2) raises(ShapeError, lambda: ElementwiseApplyFunction(exp, Z)*ElementwiseApplyFunction(exp, Z)) M = Matrix([[x, y], [z, t]]) expr = ElementwiseApplyFunction(sin, M) assert isinstance(expr, ElementwiseApplyFunction) assert expr.function == sin assert expr.expr == M assert expr.doit() == M.applyfunc(sin) assert expr.doit() == Matrix([[sin(x), sin(y)], [sin(z), sin(t)]]) assert expr.func(*expr.args) == expr expr = ElementwiseApplyFunction(double, Xk) assert expr.doit() == expr assert expr.subs(k, 2).shape == (2, 2) assert (expr*expr).shape == (k, k) M = MatrixSymbol("M", k, t) expr2 = M.T*expr*M assert isinstance(expr2, MatMul) assert expr2.args[1] == expr assert expr2.shape == (t, t) expr3 = expr*M assert expr3.shape == (k, t) raises(ShapeError, lambda: M*expr) expr1 = ElementwiseApplyFunction(lambda x: x+1, Xk) expr2 = ElementwiseApplyFunction(lambda x: x, Xk) assert expr1 != expr2 def test_applyfunc_entry(): af = X.applyfunc(sin) assert af[0, 0] == sin(X[0, 0]) af = Xd.applyfunc(sin) assert af[0, 0] == sin(X[0, 0]) def test_applyfunc_as_explicit(): af = X.applyfunc(sin) assert af.as_explicit() == Matrix([ [sin(X[0, 0]), sin(X[0, 1]), sin(X[0, 2])], [sin(X[1, 0]), sin(X[1, 1]), sin(X[1, 2])], [sin(X[2, 0]), sin(X[2, 1]), sin(X[2, 2])], ])

35f11b5ae906fdbbcbc92bb092e3835bdbfcea0ce3998c0823e59411be31ee76

from sympy import Identity from sympy.core import symbols from sympy.utilities.pytest import raises from sympy.matrices import ShapeError, MatrixSymbol from sympy.matrices.expressions import (HadamardProduct, hadamard_product, HadamardPower, hadamard_power) n, m, k = symbols('n,m,k') Z = MatrixSymbol('Z', n, n) A = MatrixSymbol('A', n, m) B = MatrixSymbol('B', n, m) C = MatrixSymbol('C', m, k) def test_HadamardProduct(): assert HadamardProduct(A, B, A).shape == A.shape raises(ShapeError, lambda: HadamardProduct(A, B.T)) raises(TypeError, lambda: HadamardProduct(A, n)) raises(TypeError, lambda: HadamardProduct(A, 1)) assert HadamardProduct(A, 2*B, -A)[1, 1] == \ -2 * A[1, 1] * B[1, 1] * A[1, 1] mix = HadamardProduct(Z*A, B)*C assert mix.shape == (n, k) assert set(HadamardProduct(A, B, A).T.args) == set((A.T, A.T, B.T)) def test_HadamardProduct_isnt_commutative(): assert HadamardProduct(A, B) != HadamardProduct(B, A) def test_mixed_indexing(): X = MatrixSymbol('X', 2, 2) Y = MatrixSymbol('Y', 2, 2) Z = MatrixSymbol('Z', 2, 2) assert (X*HadamardProduct(Y, Z))[0, 0] == \ X[0, 0]*Y[0, 0]*Z[0, 0] + X[0, 1]*Y[1, 0]*Z[1, 0] def test_canonicalize(): X = MatrixSymbol('X', 2, 2) expr = HadamardProduct(X, check=False) assert isinstance(expr, HadamardProduct) expr2 = expr.doit() # unpack is called assert isinstance(expr2, MatrixSymbol) def test_hadamard(): m, n, p = symbols('m, n, p', integer=True) A = MatrixSymbol('A', m, n) B = MatrixSymbol('B', m, n) C = MatrixSymbol('C', m, p) X = MatrixSymbol('X', m, m) I = Identity(m) with raises(TypeError): hadamard_product() assert hadamard_product(A) == A assert isinstance(hadamard_product(A, B), HadamardProduct) assert hadamard_product(A, B).doit() == hadamard_product(A, B) with raises(ShapeError): hadamard_product(A, C) hadamard_product(A, I) assert hadamard_product(X, I) == X assert isinstance(hadamard_product(X, I), MatrixSymbol) def test_hadamard_power(): m, n, p = symbols('m, n, p', integer=True) A = MatrixSymbol('A', m, n) B = MatrixSymbol('B', m, n) C = MatrixSymbol('C', m, p) assert hadamard_power(A, 1) == A assert isinstance(hadamard_power(A, 2), HadamardPower) assert hadamard_power(A, n).T == hadamard_power(A.T, n) assert hadamard_power(A, n)[0, 0] == A[0, 0]**n assert hadamard_power(m, n) == m**n raises(ValueError, lambda: hadamard_power(A, A)) # Testing printer: assert str(hadamard_power(A, n)) == "A.**n" assert str(hadamard_power(A, 1+n)) == "A.**(n + 1)" assert str(hadamard_power(A*B.T, 1+n)) == "(A*B.T).**(n + 1)"

c358f2b6c522470c58e953e50b9b979fd7e0241428ea8c1601b8f605cf783726

from sympy import Min, Max, Set, Lambda, symbols, S, oo from sympy.core import Basic, Expr, Integer from sympy.core.numbers import Infinity, NegativeInfinity, Zero from sympy.multipledispatch import dispatch from sympy.sets import Interval, FiniteSet, Union, ImageSet _x, _y = symbols("x y") @dispatch(Basic, Basic) def _set_pow(x, y): return None @dispatch(Set, Set) def _set_pow(x, y): return ImageSet(Lambda((_x, _y), (_x ** _y)), x, y) @dispatch(Expr, Expr) def _set_pow(x, y): return x**y @dispatch(Interval, Zero) def _set_pow(x, z): return FiniteSet(S.One) @dispatch(Interval, Integer) def _set_pow(x, exponent): """ Powers in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ s1 = x.start**exponent s2 = x.end**exponent if ((s2 > s1) if exponent > 0 else (x.end > -x.start)) == True: left_open = x.left_open right_open = x.right_open # TODO: handle unevaluated condition. sleft = s2 else: # TODO: `s2 > s1` could be unevaluated. left_open = x.right_open right_open = x.left_open sleft = s1 if x.start.is_positive: return Interval( Min(s1, s2), Max(s1, s2), left_open, right_open) elif x.end.is_negative: return Interval( Min(s1, s2), Max(s1, s2), left_open, right_open) # Case where x.start < 0 and x.end > 0: if exponent.is_odd: if exponent.is_negative: if x.start.is_zero: return Interval(s2, oo, x.right_open) if x.end.is_zero: return Interval(-oo, s1, True, x.left_open) return Union(Interval(-oo, s1, True, x.left_open), Interval(s2, oo, x.right_open)) else: return Interval(s1, s2, x.left_open, x.right_open) elif exponent.is_even: if exponent.is_negative: if x.start.is_zero: return Interval(s2, oo, x.right_open) if x.end.is_zero: return Interval(s1, oo, x.left_open) return Interval(0, oo) else: return Interval(S.Zero, sleft, S.Zero not in x, left_open) @dispatch(Interval, Infinity) def _set_pow(b, e): # TODO: add logic for open intervals? if b.start.is_nonnegative: if b.end < 1: return FiniteSet(S.Zero) if b.start > 1: return FiniteSet(S.Infinity) return Interval(0, oo) elif b.end.is_negative: if b.start > -1: return FiniteSet(S.Zero) if b.end < -1: return FiniteSet(-oo, oo) return Interval(-oo, oo) else: if b.start > -1: if b.end < 1: return FiniteSet(S.Zero) return Interval(0, oo) return Interval(-oo, oo) @dispatch(Interval, NegativeInfinity) def _set_pow(b, e): from sympy.sets.setexpr import set_div return _set_pow(set_div(S.One, b), oo)

952b5954aef2c9ebfcdad563cd66bf1436f1fe4cd2d01f4dd6163e8be4008074

from sympy import (S, Dummy, Lambda, symbols, Interval, Intersection, Set, EmptySet, FiniteSet, Union, ComplexRegion, ProductSet) from sympy.multipledispatch import dispatch from sympy.sets.conditionset import ConditionSet from sympy.sets.fancysets import Integers, Naturals, Reals, Range, ImageSet from sympy.sets.sets import UniversalSet, imageset @dispatch(ConditionSet, ConditionSet) def intersection_sets(a, b): return None @dispatch(ConditionSet, Set) def intersection_sets(a, b): return ConditionSet(a.sym, a.condition, Intersection(a.base_set, b)) @dispatch(Naturals, Interval) def intersection_sets(a, b): return Intersection(S.Integers, b, Interval(a._inf, S.Infinity)) @dispatch(Interval, Naturals) def intersection_sets(a, b): return intersection_sets(b, a) @dispatch(Integers, Interval) def intersection_sets(a, b): from sympy.functions.elementary.integers import floor, ceiling if b._inf == S.NegativeInfinity and b._sup == S.Infinity: return a s = Range(ceiling(b.left), floor(b.right) + 1) return intersection_sets(s, b) # take out endpoints if open interval @dispatch(ComplexRegion, Set) def intersection_sets(self, other): if other.is_ComplexRegion: # self in rectangular form if (not self.polar) and (not other.polar): return ComplexRegion(Intersection(self.sets, other.sets)) # self in polar form elif self.polar and other.polar: r1, theta1 = self.a_interval, self.b_interval r2, theta2 = other.a_interval, other.b_interval new_r_interval = Intersection(r1, r2) new_theta_interval = Intersection(theta1, theta2) # 0 and 2*Pi means the same if ((2*S.Pi in theta1 and S.Zero in theta2) or (2*S.Pi in theta2 and S.Zero in theta1)): new_theta_interval = Union(new_theta_interval, FiniteSet(0)) return ComplexRegion(new_r_interval*new_theta_interval, polar=True) if other.is_subset(S.Reals): new_interval = [] x = symbols("x", cls=Dummy, real=True) # self in rectangular form if not self.polar: for element in self.psets: if S.Zero in element.args[1]: new_interval.append(element.args[0]) new_interval = Union(*new_interval) return Intersection(new_interval, other) # self in polar form elif self.polar: for element in self.psets: if S.Zero in element.args[1]: new_interval.append(element.args[0]) if S.Pi in element.args[1]: new_interval.append(ImageSet(Lambda(x, -x), element.args[0])) if S.Zero in element.args[0]: new_interval.append(FiniteSet(0)) new_interval = Union(*new_interval) return Intersection(new_interval, other) @dispatch(Integers, Reals) def intersection_sets(a, b): return a @dispatch(Range, Interval) def intersection_sets(a, b): from sympy.functions.elementary.integers import floor, ceiling from sympy.functions.elementary.miscellaneous import Min, Max if not all(i.is_number for i in b.args[:2]): return # In case of null Range, return an EmptySet. if a.size == 0: return S.EmptySet # trim down to self's size, and represent # as a Range with step 1. start = ceiling(max(b.inf, a.inf)) if start not in b: start += 1 end = floor(min(b.sup, a.sup)) if end not in b: end -= 1 return intersection_sets(a, Range(start, end + 1)) @dispatch(Range, Naturals) def intersection_sets(a, b): return intersection_sets(a, Interval(1, S.Infinity)) @dispatch(Naturals, Range) def intersection_sets(a, b): return intersection_sets(b, a) @dispatch(Range, Range) def intersection_sets(a, b): from sympy.solvers.diophantine import diop_linear from sympy.core.numbers import ilcm from sympy import sign # non-overlap quick exits if not b: return S.EmptySet if not a: return S.EmptySet if b.sup < a.inf: return S.EmptySet if b.inf > a.sup: return S.EmptySet # work with finite end at the start r1 = a if r1.start.is_infinite: r1 = r1.reversed r2 = b if r2.start.is_infinite: r2 = r2.reversed # this equation represents the values of the Range; # it's a linear equation eq = lambda r, i: r.start + i*r.step # we want to know when the two equations might # have integer solutions so we use the diophantine # solver va, vb = diop_linear(eq(r1, Dummy()) - eq(r2, Dummy())) # check for no solution no_solution = va is None and vb is None if no_solution: return S.EmptySet # there is a solution # ------------------- # find the coincident point, c a0 = va.as_coeff_Add()[0] c = eq(r1, a0) # find the first point, if possible, in each range # since c may not be that point def _first_finite_point(r1, c): if c == r1.start: return c # st is the signed step we need to take to # get from c to r1.start st = sign(r1.start - c)*step # use Range to calculate the first point: # we want to get as close as possible to # r1.start; the Range will not be null since # it will at least contain c s1 = Range(c, r1.start + st, st)[-1] if s1 == r1.start: pass else: # if we didn't hit r1.start then, if the # sign of st didn't match the sign of r1.step # we are off by one and s1 is not in r1 if sign(r1.step) != sign(st): s1 -= st if s1 not in r1: return return s1 # calculate the step size of the new Range step = abs(ilcm(r1.step, r2.step)) s1 = _first_finite_point(r1, c) if s1 is None: return S.EmptySet s2 = _first_finite_point(r2, c) if s2 is None: return S.EmptySet # replace the corresponding start or stop in # the original Ranges with these points; the # result must have at least one point since # we know that s1 and s2 are in the Ranges def _updated_range(r, first): st = sign(r.step)*step if r.start.is_finite: rv = Range(first, r.stop, st) else: rv = Range(r.start, first + st, st) return rv r1 = _updated_range(a, s1) r2 = _updated_range(b, s2) # work with them both in the increasing direction if sign(r1.step) < 0: r1 = r1.reversed if sign(r2.step) < 0: r2 = r2.reversed # return clipped Range with positive step; it # can't be empty at this point start = max(r1.start, r2.start) stop = min(r1.stop, r2.stop) return Range(start, stop, step) @dispatch(Range, Integers) def intersection_sets(a, b): return a @dispatch(ImageSet, Set) def intersection_sets(self, other): from sympy.solvers.diophantine import diophantine if self.base_set is S.Integers: g = None if isinstance(other, ImageSet) and other.base_set is S.Integers: g = other.lamda.expr m = other.lamda.variables[0] elif other is S.Integers: m = g = Dummy('x') if g is not None: f = self.lamda.expr n = self.lamda.variables[0] # Diophantine sorts the solutions according to the alphabetic # order of the variable names, since the result should not depend # on the variable name, they are replaced by the dummy variables # below a, b = Dummy('a'), Dummy('b') f, g = f.subs(n, a), g.subs(m, b) solns_set = diophantine(f - g) if solns_set == set(): return EmptySet() solns = list(diophantine(f - g)) if len(solns) != 1: return # since 'a' < 'b', select soln for n nsol = solns[0][0] t = nsol.free_symbols.pop() return imageset(Lambda(n, f.subs(a, nsol.subs(t, n))), S.Integers) if other == S.Reals: from sympy.solvers.solveset import solveset_real from sympy.core.function import expand_complex if len(self.lamda.variables) > 1: return None f = self.lamda.expr n = self.lamda.variables[0] n_ = Dummy(n.name, real=True) f_ = f.subs(n, n_) re, im = f_.as_real_imag() im = expand_complex(im) return imageset(Lambda(n_, re), self.base_set.intersect( solveset_real(im, n_))) elif isinstance(other, Interval): from sympy.solvers.solveset import (invert_real, invert_complex, solveset) f = self.lamda.expr n = self.lamda.variables[0] base_set = self.base_set new_inf, new_sup = None, None new_lopen, new_ropen = other.left_open, other.right_open if f.is_real: inverter = invert_real else: inverter = invert_complex g1, h1 = inverter(f, other.inf, n) g2, h2 = inverter(f, other.sup, n) if all(isinstance(i, FiniteSet) for i in (h1, h2)): if g1 == n: if len(h1) == 1: new_inf = h1.args[0] if g2 == n: if len(h2) == 1: new_sup = h2.args[0] # TODO: Design a technique to handle multiple-inverse # functions # Any of the new boundary values cannot be determined if any(i is None for i in (new_sup, new_inf)): return range_set = S.EmptySet if all(i.is_real for i in (new_sup, new_inf)): # this assumes continuity of underlying function # however fixes the case when it is decreasing if new_inf > new_sup: new_inf, new_sup = new_sup, new_inf new_interval = Interval(new_inf, new_sup, new_lopen, new_ropen) range_set = base_set.intersect(new_interval) else: if other.is_subset(S.Reals): solutions = solveset(f, n, S.Reals) if not isinstance(range_set, (ImageSet, ConditionSet)): range_set = solutions.intersect(other) else: return if range_set is S.EmptySet: return S.EmptySet elif isinstance(range_set, Range) and range_set.size is not S.Infinity: range_set = FiniteSet(*list(range_set)) if range_set is not None: return imageset(Lambda(n, f), range_set) return else: return @dispatch(ProductSet, ProductSet) def intersection_sets(a, b): if len(b.args) != len(a.args): return S.EmptySet return ProductSet(i.intersect(j) for i, j in zip(a.sets, b.sets)) @dispatch(Interval, Interval) def intersection_sets(a, b): # handle (-oo, oo) infty = S.NegativeInfinity, S.Infinity if a == Interval(*infty): l, r = a.left, a.right if l.is_real or l in infty or r.is_real or r in infty: return b # We can't intersect [0,3] with [x,6] -- we don't know if x>0 or x<0 if not a._is_comparable(b): return None empty = False if a.start <= b.end and b.start <= a.end: # Get topology right. if a.start < b.start: start = b.start left_open = b.left_open elif a.start > b.start: start = a.start left_open = a.left_open else: start = a.start left_open = a.left_open or b.left_open if a.end < b.end: end = a.end right_open = a.right_open elif a.end > b.end: end = b.end right_open = b.right_open else: end = a.end right_open = a.right_open or b.right_open if end - start == 0 and (left_open or right_open): empty = True else: empty = True if empty: return S.EmptySet return Interval(start, end, left_open, right_open) @dispatch(EmptySet, Set) def intersection_sets(a, b): return S.EmptySet @dispatch(UniversalSet, Set) def intersection_sets(a, b): return b @dispatch(FiniteSet, FiniteSet) def intersection_sets(a, b): return FiniteSet(*(a._elements & b._elements)) @dispatch(FiniteSet, Set) def intersection_sets(a, b): try: return FiniteSet(*[el for el in a if el in b]) except TypeError: return None # could not evaluate `el in b` due to symbolic ranges. @dispatch(Set, Set) def intersection_sets(a, b): return None

7559b6fa3111ac33099490e68920e116725ca93aee49b5b62411292c6ac5aaad

from sympy import symbols, S from sympy.core import Basic, Expr from sympy.core.numbers import Infinity, NegativeInfinity from sympy.multipledispatch import dispatch from sympy.sets import Interval, FiniteSet _x, _y = symbols("x y") @dispatch(Basic, Basic) def _set_add(x, y): return None @dispatch(Expr, Expr) def _set_add(x, y): return x+y @dispatch(Interval, Interval) def _set_add(x, y): """ Additions in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ return Interval(x.start + y.start, x.end + y.end, x.left_open or y.left_open, x.right_open or y.right_open) @dispatch(Interval, Infinity) def _set_add(x, y): if x.start == S.NegativeInfinity: return Interval(-oo, oo) return FiniteSet({S.Infinity}) @dispatch(Interval, NegativeInfinity) def _set_add(x, y): if x.end == S.Infinity: return Interval(-oo, oo) return FiniteSet({S.NegativeInfinity}) @dispatch(Basic, Basic) def _set_sub(x, y): return None @dispatch(Expr, Expr) def _set_sub(x, y): return x-y @dispatch(Interval, Interval) def _set_sub(x, y): """ Subtractions in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ return Interval(x.start - y.end, x.end - y.start, x.left_open or y.right_open, x.right_open or y.left_open) @dispatch(Interval, Infinity) def _set_sub(x, y): if self.start is S.NegativeInfinity: return Interval(-oo, oo) return FiniteSet(-oo) @dispatch(Interval, NegativeInfinity) def _set_sub(x, y): if self.start is S.NegativeInfinity: return Interval(-oo, oo) return FiniteSet(-oo)

375e39efb591310d87dd88672643be5c82c3b5863b1bea01ad5c2678480e2e8a

from sympy import (Interval, Intersection, Set, EmptySet, S, sympify, FiniteSet, Union, ComplexRegion, ProductSet) from sympy.multipledispatch import dispatch from sympy.sets.fancysets import Integers from sympy.sets.sets import UniversalSet @dispatch(Integers, Set) def union_sets(a, b): intersect = Intersection(a, b) if intersect == a: return b elif intersect == b: return a @dispatch(ComplexRegion, Set) def union_sets(a, b): if b.is_subset(S.Reals): # treat a subset of reals as a complex region b = ComplexRegion.from_real(b) if b.is_ComplexRegion: # a in rectangular form if (not a.polar) and (not b.polar): return ComplexRegion(Union(a.sets, b.sets)) # a in polar form elif a.polar and b.polar: return ComplexRegion(Union(a.sets, b.sets), polar=True) return None @dispatch(EmptySet, Set) def union_sets(a, b): return b @dispatch(UniversalSet, Set) def union_sets(a, b): return a @dispatch(ProductSet, ProductSet) def union_sets(a, b): if b.is_subset(a): return a if len(b.args) != len(a.args): return None if a.args[0] == b.args[0]: return a.args[0] * Union(ProductSet(a.args[1:]), ProductSet(b.args[1:])) if a.args[-1] == b.args[-1]: return Union(ProductSet(a.args[:-1]), ProductSet(b.args[:-1])) * a.args[-1] return None @dispatch(ProductSet, Set) def union_sets(a, b): if b.is_subset(a): return a return None @dispatch(Interval, Interval) def union_sets(a, b): if a._is_comparable(b): from sympy.functions.elementary.miscellaneous import Min, Max # Non-overlapping intervals end = Min(a.end, b.end) start = Max(a.start, b.start) if (end < start or (end == start and (end not in a and end not in b))): return None else: start = Min(a.start, b.start) end = Max(a.end, b.end) left_open = ((a.start != start or a.left_open) and (b.start != start or b.left_open)) right_open = ((a.end != end or a.right_open) and (b.end != end or b.right_open)) return Interval(start, end, left_open, right_open) @dispatch(Interval, UniversalSet) def union_sets(a, b): return S.UniversalSet @dispatch(Interval, Set) def union_sets(a, b): # If I have open end points and these endpoints are contained in b # But only in case, when endpoints are finite. Because # interval does not contain oo or -oo. open_left_in_b_and_finite = (a.left_open and sympify(b.contains(a.start)) is S.true and a.start.is_finite) open_right_in_b_and_finite = (a.right_open and sympify(b.contains(a.end)) is S.true and a.end.is_finite) if open_left_in_b_and_finite or open_right_in_b_and_finite: # Fill in my end points and return open_left = a.left_open and a.start not in b open_right = a.right_open and a.end not in b new_a = Interval(a.start, a.end, open_left, open_right) return set((new_a, b)) return None @dispatch(FiniteSet, FiniteSet) def union_sets(a, b): return FiniteSet(*(a._elements | b._elements)) @dispatch(FiniteSet, Set) def union_sets(a, b): # If `b` set contains one of my elements, remove it from `a` if any(b.contains(x) == True for x in a): return set(( FiniteSet(*[x for x in a if not b.contains(x)]), b)) return None @dispatch(Set, Set) def union_sets(a, b): return None

0b99ab616107cd996e1d0764c962c9b42447fa05f2a335955b773db7cbac14ae

from sympy import Set, symbols, exp, log, S, Wild from sympy.core import Expr, Add from sympy.core.function import Lambda, _coeff_isneg, FunctionClass from sympy.logic.boolalg import true from sympy.multipledispatch import dispatch from sympy.sets import (imageset, Interval, FiniteSet, Union, ImageSet, EmptySet, Intersection, Range) from sympy.sets.fancysets import Integers _x, _y = symbols("x y") FunctionUnion = (FunctionClass, Lambda) @dispatch(FunctionClass, Set) def _set_function(f, x): return None @dispatch(FunctionUnion, FiniteSet) def _set_function(f, x): return FiniteSet(*map(f, x)) @dispatch(Lambda, Interval) def _set_function(f, x): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.solvers.solveset import solveset from sympy.core.function import diff, Lambda from sympy.series import limit from sympy.calculus.singularities import singularities from sympy.sets import Complement # TODO: handle functions with infinitely many solutions (eg, sin, tan) # TODO: handle multivariate functions expr = f.expr if len(expr.free_symbols) > 1 or len(f.variables) != 1: return var = f.variables[0] if expr.is_Piecewise: result = S.EmptySet domain_set = x for (p_expr, p_cond) in expr.args: if p_cond is true: intrvl = domain_set else: intrvl = p_cond.as_set() intrvl = Intersection(domain_set, intrvl) if p_expr.is_Number: image = FiniteSet(p_expr) else: image = imageset(Lambda(var, p_expr), intrvl) result = Union(result, image) # remove the part which has been `imaged` domain_set = Complement(domain_set, intrvl) if domain_set.is_EmptySet: break return result if not x.start.is_comparable or not x.end.is_comparable: return try: sing = [i for i in singularities(expr, var) if i.is_real and i in x] except NotImplementedError: return if x.left_open: _start = limit(expr, var, x.start, dir="+") elif x.start not in sing: _start = f(x.start) if x.right_open: _end = limit(expr, var, x.end, dir="-") elif x.end not in sing: _end = f(x.end) if len(sing) == 0: solns = list(solveset(diff(expr, var), var)) extr = [_start, _end] + [f(i) for i in solns if i.is_real and i in x] start, end = Min(*extr), Max(*extr) left_open, right_open = False, False if _start <= _end: # the minimum or maximum value can occur simultaneously # on both the edge of the interval and in some interior # point if start == _start and start not in solns: left_open = x.left_open if end == _end and end not in solns: right_open = x.right_open else: if start == _end and start not in solns: left_open = x.right_open if end == _start and end not in solns: right_open = x.left_open return Interval(start, end, left_open, right_open) else: return imageset(f, Interval(x.start, sing[0], x.left_open, True)) + \ Union(*[imageset(f, Interval(sing[i], sing[i + 1], True, True)) for i in range(0, len(sing) - 1)]) + \ imageset(f, Interval(sing[-1], x.end, True, x.right_open)) @dispatch(FunctionClass, Interval) def _set_function(f, x): if f == exp: return Interval(exp(x.start), exp(x.end), x.left_open, x.right_open) elif f == log: return Interval(log(x.start), log(x.end), x.left_open, x.right_open) return ImageSet(Lambda(_x, f(_x)), x) @dispatch(FunctionUnion, Union) def _set_function(f, x): return Union(*(imageset(f, arg) for arg in x.args)) @dispatch(FunctionUnion, Intersection) def _set_function(f, x): from sympy.sets.sets import is_function_invertible_in_set # If the function is invertible, intersect the maps of the sets. if is_function_invertible_in_set(f, x): return Intersection(*(imageset(f, arg) for arg in x.args)) else: return ImageSet(Lambda(_x, f(_x)), x) @dispatch(FunctionUnion, EmptySet) def _set_function(f, x): return x @dispatch(FunctionUnion, Set) def _set_function(f, x): return ImageSet(Lambda(_x, f(_x)), x) @dispatch(FunctionUnion, Range) def _set_function(f, self): from sympy.core.function import expand_mul if not self: return S.EmptySet if not isinstance(f.expr, Expr): return if self.size == 1: return FiniteSet(f(self[0])) if f is S.IdentityFunction: return self x = f.variables[0] expr = f.expr # handle f that is linear in f's variable if x not in expr.free_symbols or x in expr.diff(x).free_symbols: return if self.start.is_finite: F = f(self.step*x + self.start) # for i in range(len(self)) else: F = f(-self.step*x + self[-1]) F = expand_mul(F) if F != expr: return imageset(x, F, Range(self.size)) @dispatch(FunctionUnion, Integers) def _set_function(f, self): expr = f.expr if not isinstance(expr, Expr): return if len(f.variables) > 1: return n = f.variables[0] # f(x) + c and f(-x) + c cover the same integers # so choose the form that has the fewest negatives c = f(0) fx = f(n) - c f_x = f(-n) - c neg_count = lambda e: sum(_coeff_isneg(_) for _ in Add.make_args(e)) if neg_count(f_x) < neg_count(fx): expr = f_x + c a = Wild('a', exclude=[n]) b = Wild('b', exclude=[n]) match = expr.match(a*n + b) if match and match[a]: # canonical shift expr = match[a]*n + match[b] % match[a] if expr != f.expr: return ImageSet(Lambda(n, expr), S.Integers)

2071057783a1e860dd35aca3e4ba135f251f1c3ee3b2bfbb1fd302747db768bf

from sympy import Set, symbols from sympy.core import Basic, Expr from sympy.multipledispatch import dispatch from sympy.sets import Interval _x, _y = symbols("x y") @dispatch(Basic, Basic) def _set_mul(x, y): return None @dispatch(Set, Set) def _set_mul(x, y): return None @dispatch(Expr, Expr) def _set_mul(x, y): return x*y @dispatch(Interval, Interval) def _set_mul(x, y): """ Multiplications in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ # TODO: some intervals containing 0 and oo will fail as 0*oo returns nan. comvals = ( (x.start * y.start, bool(x.left_open or y.left_open)), (x.start * y.end, bool(x.left_open or y.right_open)), (x.end * y.start, bool(x.right_open or y.left_open)), (x.end * y.end, bool(x.right_open or y.right_open)), ) # TODO: handle symbolic intervals minval, minopen = min(comvals) maxval, maxopen = max(comvals) return Interval( minval, maxval, minopen, maxopen ) return SetExpr(Interval(start, end)) @dispatch(Basic, Basic) def _set_div(x, y): return None @dispatch(Expr, Expr) def _set_div(x, y): return x/y @dispatch(Set, Set) def _set_div(x, y): return None @dispatch(Interval, Interval) def _set_div(x, y): """ Divisions in interval arithmetic https://en.wikipedia.org/wiki/Interval_arithmetic """ from sympy.sets.setexpr import set_mul from sympy import oo if (y.start*y.end).is_negative: return Interval(-oo, oo) if y.start == 0: s2 = oo else: s2 = 1/y.start if y.end == 0: s1 = -oo else: s1 = 1/y.end return set_mul(x, Interval(s1, s2, y.right_open, y.left_open))

fd0ee6cfec09669a48f0ae461822658e3cc91852e879f9b3b19337a8ac14860f

from sympy import (pi, sin, cos, Symbol, Integral, Sum, sqrt, log, oo, LambertW, I, meijerg, exp_polar, Max, Piecewise, And) from sympy.plotting import (plot, plot_parametric, plot3d_parametric_line, plot3d, plot3d_parametric_surface) from sympy.plotting.plot import unset_show, plot_contour, PlotGrid from sympy.utilities import lambdify as lambdify_ from sympy.utilities.pytest import skip, raises, warns from sympy.plotting.experimental_lambdify import lambdify from sympy.external import import_module from tempfile import NamedTemporaryFile import os unset_show() # XXX: We could implement this as a context manager instead # That would need rewriting the plot_and_save() function # entirely class TmpFileManager: tmp_files = [] @classmethod def tmp_file(cls, name=''): cls.tmp_files.append(NamedTemporaryFile(prefix=name, suffix='.png').name) return cls.tmp_files[-1] @classmethod def cleanup(cls): for file in cls.tmp_files: try: os.remove(file) except OSError: # If the file doesn't exist, for instance, if the test failed. pass def plot_and_save_1(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Examples from the 'introduction' notebook ### p = plot(x) p = plot(x*sin(x), x*cos(x)) p.extend(p) p[0].line_color = lambda a: a p[1].line_color = 'b' p.title = 'Big title' p.xlabel = 'the x axis' p[1].label = 'straight line' p.legend = True p.aspect_ratio = (1, 1) p.xlim = (-15, 20) p.save(tmp_file('%s_basic_options_and_colors' % name)) p._backend.close() p.extend(plot(x + 1)) p.append(plot(x + 3, x**2)[1]) p.save(tmp_file('%s_plot_extend_append' % name)) p[2] = plot(x**2, (x, -2, 3)) p.save(tmp_file('%s_plot_setitem' % name)) p._backend.close() p = plot(sin(x), (x, -2*pi, 4*pi)) p.save(tmp_file('%s_line_explicit' % name)) p._backend.close() p = plot(sin(x)) p.save(tmp_file('%s_line_default_range' % name)) p._backend.close() p = plot((x**2, (x, -5, 5)), (x**3, (x, -3, 3))) p.save(tmp_file('%s_line_multiple_range' % name)) p._backend.close() raises(ValueError, lambda: plot(x, y)) #Piecewise plots p = plot(Piecewise((1, x > 0), (0, True)), (x, -1, 1)) p.save(tmp_file('%s_plot_piecewise' % name)) p._backend.close() p = plot(Piecewise((x, x < 1), (x**2, True)), (x, -3, 3)) p.save(tmp_file('%s_plot_piecewise_2' % name)) p._backend.close() # test issue 7471 p1 = plot(x) p2 = plot(3) p1.extend(p2) p.save(tmp_file('%s_horizontal_line' % name)) p._backend.close() # test issue 10925 f = Piecewise((-1, x < -1), (x, And(-1 <= x, x < 0)), \ (x**2, And(0 <= x, x < 1)), (x**3, x >= 1)) p = plot(f, (x, -3, 3)) p.save(tmp_file('%s_plot_piecewise_3' % name)) p._backend.close() def plot_and_save_2(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') #parametric 2d plots. #Single plot with default range. plot_parametric(sin(x), cos(x)).save(tmp_file()) #Single plot with range. p = plot_parametric(sin(x), cos(x), (x, -5, 5)) p.save(tmp_file('%s_parametric_range' % name)) p._backend.close() #Multiple plots with same range. p = plot_parametric((sin(x), cos(x)), (x, sin(x))) p.save(tmp_file('%s_parametric_multiple' % name)) p._backend.close() #Multiple plots with different ranges. p = plot_parametric((sin(x), cos(x), (x, -3, 3)), (x, sin(x), (x, -5, 5))) p.save(tmp_file('%s_parametric_multiple_ranges' % name)) p._backend.close() #depth of recursion specified. p = plot_parametric(x, sin(x), depth=13) p.save(tmp_file('%s_recursion_depth' % name)) p._backend.close() #No adaptive sampling. p = plot_parametric(cos(x), sin(x), adaptive=False, nb_of_points=500) p.save(tmp_file('%s_adaptive' % name)) p._backend.close() #3d parametric plots p = plot3d_parametric_line(sin(x), cos(x), x) p.save(tmp_file('%s_3d_line' % name)) p._backend.close() p = plot3d_parametric_line( (sin(x), cos(x), x, (x, -5, 5)), (cos(x), sin(x), x, (x, -3, 3))) p.save(tmp_file('%s_3d_line_multiple' % name)) p._backend.close() p = plot3d_parametric_line(sin(x), cos(x), x, nb_of_points=30) p.save(tmp_file('%s_3d_line_points' % name)) p._backend.close() # 3d surface single plot. p = plot3d(x * y) p.save(tmp_file('%s_surface' % name)) p._backend.close() # Multiple 3D plots with same range. p = plot3d(-x * y, x * y, (x, -5, 5)) p.save(tmp_file('%s_surface_multiple' % name)) p._backend.close() # Multiple 3D plots with different ranges. p = plot3d( (x * y, (x, -3, 3), (y, -3, 3)), (-x * y, (x, -3, 3), (y, -3, 3))) p.save(tmp_file('%s_surface_multiple_ranges' % name)) p._backend.close() # Single Parametric 3D plot p = plot3d_parametric_surface(sin(x + y), cos(x - y), x - y) p.save(tmp_file('%s_parametric_surface' % name)) p._backend.close() # Multiple Parametric 3D plots. p = plot3d_parametric_surface( (x*sin(z), x*cos(z), z, (x, -5, 5), (z, -5, 5)), (sin(x + y), cos(x - y), x - y, (x, -5, 5), (y, -5, 5))) p.save(tmp_file('%s_parametric_surface' % name)) p._backend.close() # Single Contour plot. p = plot_contour(sin(x)*sin(y), (x, -5, 5), (y, -5, 5)) p.save(tmp_file('%s_contour_plot' % name)) p._backend.close() # Multiple Contour plots with same range. p = plot_contour(x**2 + y**2, x**3 + y**3, (x, -5, 5), (y, -5, 5)) p.save(tmp_file('%s_contour_plot' % name)) p._backend.close() # Multiple Contour plots with different range. p = plot_contour((x**2 + y**2, (x, -5, 5), (y, -5, 5)), (x**3 + y**3, (x, -3, 3), (y, -3, 3))) p.save(tmp_file('%s_contour_plot' % name)) p._backend.close() def plot_and_save_3(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Examples from the 'colors' notebook ### p = plot(sin(x)) p[0].line_color = lambda a: a p.save(tmp_file('%s_colors_line_arity1' % name)) p[0].line_color = lambda a, b: b p.save(tmp_file('%s_colors_line_arity2' % name)) p._backend.close() p = plot(x*sin(x), x*cos(x), (x, 0, 10)) p[0].line_color = lambda a: a p.save(tmp_file('%s_colors_param_line_arity1' % name)) p[0].line_color = lambda a, b: a p.save(tmp_file('%s_colors_param_line_arity2a' % name)) p[0].line_color = lambda a, b: b p.save(tmp_file('%s_colors_param_line_arity2b' % name)) p._backend.close() p = plot3d_parametric_line(sin(x) + 0.1*sin(x)*cos(7*x), cos(x) + 0.1*cos(x)*cos(7*x), 0.1*sin(7*x), (x, 0, 2*pi)) p[0].line_color = lambdify_(x, sin(4*x)) p.save(tmp_file('%s_colors_3d_line_arity1' % name)) p[0].line_color = lambda a, b: b p.save(tmp_file('%s_colors_3d_line_arity2' % name)) p[0].line_color = lambda a, b, c: c p.save(tmp_file('%s_colors_3d_line_arity3' % name)) p._backend.close() p = plot3d(sin(x)*y, (x, 0, 6*pi), (y, -5, 5)) p[0].surface_color = lambda a: a p.save(tmp_file('%s_colors_surface_arity1' % name)) p[0].surface_color = lambda a, b: b p.save(tmp_file('%s_colors_surface_arity2' % name)) p[0].surface_color = lambda a, b, c: c p.save(tmp_file('%s_colors_surface_arity3a' % name)) p[0].surface_color = lambdify_((x, y, z), sqrt((x - 3*pi)**2 + y**2)) p.save(tmp_file('%s_colors_surface_arity3b' % name)) p._backend.close() p = plot3d_parametric_surface(x * cos(4 * y), x * sin(4 * y), y, (x, -1, 1), (y, -1, 1)) p[0].surface_color = lambda a: a p.save(tmp_file('%s_colors_param_surf_arity1' % name)) p[0].surface_color = lambda a, b: a*b p.save(tmp_file('%s_colors_param_surf_arity2' % name)) p[0].surface_color = lambdify_((x, y, z), sqrt(x**2 + y**2 + z**2)) p.save(tmp_file('%s_colors_param_surf_arity3' % name)) p._backend.close() def plot_and_save_4(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Examples from the 'advanced' notebook ### # XXX: This raises the warning "The evaluation of the expression is # problematic. We are trying a failback method that may still work. Please # report this as a bug." It has to use the fallback because using evalf() # is the only way to evaluate the integral. We should perhaps just remove # that warning. with warns(UserWarning, match="The evaluation of the expression is problematic"): i = Integral(log((sin(x)**2 + 1)*sqrt(x**2 + 1)), (x, 0, y)) p = plot(i, (y, 1, 5)) p.save(tmp_file('%s_advanced_integral' % name)) p._backend.close() def plot_and_save_5(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') s = Sum(1/x**y, (x, 1, oo)) p = plot(s, (y, 2, 10)) p.save(tmp_file('%s_advanced_inf_sum' % name)) p._backend.close() p = plot(Sum(1/x, (x, 1, y)), (y, 2, 10), show=False) p[0].only_integers = True p[0].steps = True p.save(tmp_file('%s_advanced_fin_sum' % name)) p._backend.close() def plot_and_save_6(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') ### # Test expressions that can not be translated to np and generate complex # results. ### plot(sin(x) + I*cos(x)).save(tmp_file()) plot(sqrt(sqrt(-x))).save(tmp_file()) plot(LambertW(x)).save(tmp_file()) plot(sqrt(LambertW(x))).save(tmp_file()) #Characteristic function of a StudentT distribution with nu=10 plot((meijerg(((1 / 2,), ()), ((5, 0, 1 / 2), ()), 5 * x**2 * exp_polar(-I*pi)/2) + meijerg(((1/2,), ()), ((5, 0, 1/2), ()), 5*x**2 * exp_polar(I*pi)/2)) / (48 * pi), (x, 1e-6, 1e-2)).save(tmp_file()) def plotgrid_and_save(name): tmp_file = TmpFileManager.tmp_file x = Symbol('x') y = Symbol('y') z = Symbol('z') p1 = plot(x) p2 = plot_parametric((sin(x), cos(x)), (x, sin(x)), show=False) p3 = plot_parametric(cos(x), sin(x), adaptive=False, nb_of_points=500, show=False) p4 = plot3d_parametric_line(sin(x), cos(x), x, show=False) # symmetric grid p = PlotGrid(2, 2, p1, p2, p3, p4) p.save(tmp_file('%s_grid1' % name)) p._backend.close() # grid size greater than the number of subplots p = PlotGrid(3, 4, p1, p2, p3, p4) p.save(tmp_file('%s_grid2' % name)) p._backend.close() p5 = plot(cos(x),(x, -pi, pi), show=False) p5[0].line_color = lambda a: a p6 = plot(Piecewise((1, x > 0), (0, True)), (x, -1, 1), show=False) p7 = plot_contour((x**2 + y**2, (x, -5, 5), (y, -5, 5)), (x**3 + y**3, (x, -3, 3), (y, -3, 3)), show=False) # unsymmetric grid (subplots in one line) p = PlotGrid(1, 3, p5, p6, p7) p.save(tmp_file('%s_grid3' % name)) p._backend.close() def test_matplotlib_1(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_1('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_2(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_2('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_3(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_3('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_4(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_4('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_5(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_5('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_6(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plot_and_save_6('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") def test_matplotlib_7(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if matplotlib: try: plotgrid_and_save('test') finally: # clean up TmpFileManager.cleanup() else: skip("Matplotlib not the default backend") # Tests for exception handling in experimental_lambdify def test_experimental_lambify(): x = Symbol('x') f = lambdify([x], Max(x, 5)) # XXX should f be tested? If f(2) is attempted, an # error is raised because a complex produced during wrapping of the arg # is being compared with an int. assert Max(2, 5) == 5 assert Max(5, 7) == 7 x = Symbol('x-3') f = lambdify([x], x + 1) assert f(1) == 2 def test_append_issue_7140(): matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if not matplotlib: skip("Matplotlib not the default backend") x = Symbol('x') p1 = plot(x) p2 = plot(x**2) p3 = plot(x + 2) # append a series p2.append(p1[0]) assert len(p2._series) == 2 with raises(TypeError): p1.append(p2) with raises(TypeError): p1.append(p2._series) def test_issue_15265(): from sympy.core.sympify import sympify from sympy.core.singleton import S matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,)) if not matplotlib: skip("Matplotlib not the default backend") x = Symbol('x') eqn = sin(x) p = plot(eqn, xlim=(-S.Pi, S.Pi), ylim=(-1, 1)) p._backend.close() p = plot(eqn, xlim=(-1, 1), ylim=(-S.Pi, S.Pi)) p._backend.close() p = plot(eqn, xlim=(-1, 1), ylim=(sympify('-3.14'), sympify('3.14'))) p._backend.close() p = plot(eqn, xlim=(sympify('-3.14'), sympify('3.14')), ylim=(-1, 1)) p._backend.close() raises(ValueError, lambda: plot(eqn, xlim=(-S.ImaginaryUnit, 1), ylim=(-1, 1))) raises(ValueError, lambda: plot(eqn, xlim=(-1, 1), ylim=(-1, S.ImaginaryUnit))) raises(ValueError, lambda: plot(eqn, xlim=(-S.Infinity, 1), ylim=(-1, 1))) raises(ValueError, lambda: plot(eqn, xlim=(-1, 1), ylim=(-1, S.Infinity)))

de6273a6ea687e884c572921338dc7573c9560430c6141c24c7530b8f15a81ee

from __future__ import print_function, division from sympy import Symbol, sympify from sympy.core.compatibility import is_sequence, range, string_types from sympy.geometry.entity import GeometryEntity from .plot_interval import PlotInterval from .plot_object import PlotObject from .util import parse_option_string class PlotMode(PlotObject): """ Grandparent class for plotting modes. Serves as interface for registration, lookup, and init of modes. To create a new plot mode, inherit from PlotModeBase or one of its children, such as PlotSurface or PlotCurve. """ ## Class-level attributes ## used to register and lookup ## plot modes. See PlotModeBase ## for descriptions and usage. i_vars, d_vars = '', '' intervals = [] aliases = [] is_default = False ## Draw is the only method here which ## is meant to be overridden in child ## classes, and PlotModeBase provides ## a base implementation. def draw(self): raise NotImplementedError() ## Everything else in this file has to ## do with registration and retrieval ## of plot modes. This is where I've ## hidden much of the ugliness of automatic ## plot mode divination... ## Plot mode registry data structures _mode_alias_list = [] _mode_map = { 1: {1: {}, 2: {}}, 2: {1: {}, 2: {}}, 3: {1: {}, 2: {}}, } # [d][i][alias_str]: class _mode_default_map = { 1: {}, 2: {}, 3: {}, } # [d][i]: class _i_var_max, _d_var_max = 2, 3 def __new__(cls, *args, **kwargs): """ This is the function which interprets arguments given to Plot.__init__ and Plot.__setattr__. Returns an initialized instance of the appropriate child class. """ newargs, newkwargs = PlotMode._extract_options(args, kwargs) mode_arg = newkwargs.get('mode', '') # Interpret the arguments d_vars, intervals = PlotMode._interpret_args(newargs) i_vars = PlotMode._find_i_vars(d_vars, intervals) i, d = max([len(i_vars), len(intervals)]), len(d_vars) # Find the appropriate mode subcls = PlotMode._get_mode(mode_arg, i, d) # Create the object o = object.__new__(subcls) # Do some setup for the mode instance o.d_vars = d_vars o._fill_i_vars(i_vars) o._fill_intervals(intervals) o.options = newkwargs return o @staticmethod def _get_mode(mode_arg, i_var_count, d_var_count): """ Tries to return an appropriate mode class. Intended to be called only by __new__. mode_arg Can be a string or a class. If it is a PlotMode subclass, it is simply returned. If it is a string, it can an alias for a mode or an empty string. In the latter case, we try to find a default mode for the i_var_count and d_var_count. i_var_count The number of independent variables needed to evaluate the d_vars. d_var_count The number of dependent variables; usually the number of functions to be evaluated in plotting. For example, a Cartesian function y = f(x) has one i_var (x) and one d_var (y). A parametric form x,y,z = f(u,v), f(u,v), f(u,v) has two two i_vars (u,v) and three d_vars (x,y,z). """ # if the mode_arg is simply a PlotMode class, # check that the mode supports the numbers # of independent and dependent vars, then # return it try: m = None if issubclass(mode_arg, PlotMode): m = mode_arg except TypeError: pass if m: if not m._was_initialized: raise ValueError(("To use unregistered plot mode %s " "you must first call %s._init_mode().") % (m.__name__, m.__name__)) if d_var_count != m.d_var_count: raise ValueError(("%s can only plot functions " "with %i dependent variables.") % (m.__name__, m.d_var_count)) if i_var_count > m.i_var_count: raise ValueError(("%s cannot plot functions " "with more than %i independent " "variables.") % (m.__name__, m.i_var_count)) return m # If it is a string, there are two possibilities. if isinstance(mode_arg, string_types): i, d = i_var_count, d_var_count if i > PlotMode._i_var_max: raise ValueError(var_count_error(True, True)) if d > PlotMode._d_var_max: raise ValueError(var_count_error(False, True)) # If the string is '', try to find a suitable # default mode if not mode_arg: return PlotMode._get_default_mode(i, d) # Otherwise, interpret the string as a mode # alias (e.g. 'cartesian', 'parametric', etc) else: return PlotMode._get_aliased_mode(mode_arg, i, d) else: raise ValueError("PlotMode argument must be " "a class or a string") @staticmethod def _get_default_mode(i, d, i_vars=-1): if i_vars == -1: i_vars = i try: return PlotMode._mode_default_map[d][i] except KeyError: # Keep looking for modes in higher i var counts # which support the given d var count until we # reach the max i_var count. if i < PlotMode._i_var_max: return PlotMode._get_default_mode(i + 1, d, i_vars) else: raise ValueError(("Couldn't find a default mode " "for %i independent and %i " "dependent variables.") % (i_vars, d)) @staticmethod def _get_aliased_mode(alias, i, d, i_vars=-1): if i_vars == -1: i_vars = i if alias not in PlotMode._mode_alias_list: raise ValueError(("Couldn't find a mode called" " %s. Known modes: %s.") % (alias, ", ".join(PlotMode._mode_alias_list))) try: return PlotMode._mode_map[d][i][alias] except TypeError: # Keep looking for modes in higher i var counts # which support the given d var count and alias # until we reach the max i_var count. if i < PlotMode._i_var_max: return PlotMode._get_aliased_mode(alias, i + 1, d, i_vars) else: raise ValueError(("Couldn't find a %s mode " "for %i independent and %i " "dependent variables.") % (alias, i_vars, d)) @classmethod def _register(cls): """ Called once for each user-usable plot mode. For Cartesian2D, it is invoked after the class definition: Cartesian2D._register() """ name = cls.__name__ cls._init_mode() try: i, d = cls.i_var_count, cls.d_var_count # Add the mode to _mode_map under all # given aliases for a in cls.aliases: if a not in PlotMode._mode_alias_list: # Also track valid aliases, so # we can quickly know when given # an invalid one in _get_mode. PlotMode._mode_alias_list.append(a) PlotMode._mode_map[d][i][a] = cls if cls.is_default: # If this mode was marked as the # default for this d,i combination, # also set that. PlotMode._mode_default_map[d][i] = cls except Exception as e: raise RuntimeError(("Failed to register " "plot mode %s. Reason: %s") % (name, (str(e)))) @classmethod def _init_mode(cls): """ Initializes the plot mode based on the 'mode-specific parameters' above. Only intended to be called by PlotMode._register(). To use a mode without registering it, you can directly call ModeSubclass._init_mode(). """ def symbols_list(symbol_str): return [Symbol(s) for s in symbol_str] # Convert the vars strs into # lists of symbols. cls.i_vars = symbols_list(cls.i_vars) cls.d_vars = symbols_list(cls.d_vars) # Var count is used often, calculate # it once here cls.i_var_count = len(cls.i_vars) cls.d_var_count = len(cls.d_vars) if cls.i_var_count > PlotMode._i_var_max: raise ValueError(var_count_error(True, False)) if cls.d_var_count > PlotMode._d_var_max: raise ValueError(var_count_error(False, False)) # Try to use first alias as primary_alias if len(cls.aliases) > 0: cls.primary_alias = cls.aliases[0] else: cls.primary_alias = cls.__name__ di = cls.intervals if len(di) != cls.i_var_count: raise ValueError("Plot mode must provide a " "default interval for each i_var.") for i in range(cls.i_var_count): # default intervals must be given [min,max,steps] # (no var, but they must be in the same order as i_vars) if len(di[i]) != 3: raise ValueError("length should be equal to 3") # Initialize an incomplete interval, # to later be filled with a var when # the mode is instantiated. di[i] = PlotInterval(None, *di[i]) # To prevent people from using modes # without these required fields set up. cls._was_initialized = True _was_initialized = False ## Initializer Helper Methods @staticmethod def _find_i_vars(functions, intervals): i_vars = [] # First, collect i_vars in the # order they are given in any # intervals. for i in intervals: if i.v is None: continue elif i.v in i_vars: raise ValueError(("Multiple intervals given " "for %s.") % (str(i.v))) i_vars.append(i.v) # Then, find any remaining # i_vars in given functions # (aka d_vars) for f in functions: for a in f.free_symbols: if a not in i_vars: i_vars.append(a) return i_vars def _fill_i_vars(self, i_vars): # copy default i_vars self.i_vars = [Symbol(str(i)) for i in self.i_vars] # replace with given i_vars for i in range(len(i_vars)): self.i_vars[i] = i_vars[i] def _fill_intervals(self, intervals): # copy default intervals self.intervals = [PlotInterval(i) for i in self.intervals] # track i_vars used so far v_used = [] # fill copy of default # intervals with given info for i in range(len(intervals)): self.intervals[i].fill_from(intervals[i]) if self.intervals[i].v is not None: v_used.append(self.intervals[i].v) # Find any orphan intervals and # assign them i_vars for i in range(len(self.intervals)): if self.intervals[i].v is None: u = [v for v in self.i_vars if v not in v_used] if len(u) == 0: raise ValueError("length should not be equal to 0") self.intervals[i].v = u[0] v_used.append(u[0]) @staticmethod def _interpret_args(args): interval_wrong_order = "PlotInterval %s was given before any function(s)." interpret_error = "Could not interpret %s as a function or interval." functions, intervals = [], [] if isinstance(args[0], GeometryEntity): for coords in list(args[0].arbitrary_point()): functions.append(coords) intervals.append(PlotInterval.try_parse(args[0].plot_interval())) else: for a in args: i = PlotInterval.try_parse(a) if i is not None: if len(functions) == 0: raise ValueError(interval_wrong_order % (str(i))) else: intervals.append(i) else: if is_sequence(a, include=str): raise ValueError(interpret_error % (str(a))) try: f = sympify(a) functions.append(f) except TypeError: raise ValueError(interpret_error % str(a)) return functions, intervals @staticmethod def _extract_options(args, kwargs): newkwargs, newargs = {}, [] for a in args: if isinstance(a, string_types): newkwargs = dict(newkwargs, **parse_option_string(a)) else: newargs.append(a) newkwargs = dict(newkwargs, **kwargs) return newargs, newkwargs def var_count_error(is_independent, is_plotting): """ Used to format an error message which differs slightly in 4 places. """ if is_plotting: v = "Plotting" else: v = "Registering plot modes" if is_independent: n, s = PlotMode._i_var_max, "independent" else: n, s = PlotMode._d_var_max, "dependent" return ("%s with more than %i %s variables " "is not supported.") % (v, n, s)

93fa7af79a7db2d6d0a4b34d7f4072b8d41613459432fca3a3c17d5ca495344b

from __future__ import print_function, division from pyglet.window import Window from pyglet.clock import Clock from threading import Thread, Lock gl_lock = Lock() class ManagedWindow(Window): """ A pyglet window with an event loop which executes automatically in a separate thread. Behavior is added by creating a subclass which overrides setup, update, and/or draw. """ fps_limit = 30 default_win_args = dict(width=600, height=500, vsync=False, resizable=True) def __init__(self, **win_args): """ It is best not to override this function in the child class, unless you need to take additional arguments. Do any OpenGL initialization calls in setup(). """ # check if this is run from the doctester if win_args.get('runfromdoctester', False): return self.win_args = dict(self.default_win_args, **win_args) self.Thread = Thread(target=self.__event_loop__) self.Thread.start() def __event_loop__(self, **win_args): """ The event loop thread function. Do not override or call directly (it is called by __init__). """ gl_lock.acquire() try: try: super(ManagedWindow, self).__init__(**self.win_args) self.switch_to() self.setup() except Exception as e: print("Window initialization failed: %s" % (str(e))) self.has_exit = True finally: gl_lock.release() clock = Clock() clock.set_fps_limit(self.fps_limit) while not self.has_exit: dt = clock.tick() gl_lock.acquire() try: try: self.switch_to() self.dispatch_events() self.clear() self.update(dt) self.draw() self.flip() except Exception as e: print("Uncaught exception in event loop: %s" % str(e)) self.has_exit = True finally: gl_lock.release() super(ManagedWindow, self).close() def close(self): """ Closes the window. """ self.has_exit = True def setup(self): """ Called once before the event loop begins. Override this method in a child class. This is the best place to put things like OpenGL initialization calls. """ pass def update(self, dt): """ Called before draw during each iteration of the event loop. dt is the elapsed time in seconds since the last update. OpenGL rendering calls are best put in draw() rather than here. """ pass def draw(self): """ Called after update during each iteration of the event loop. Put OpenGL rendering calls here. """ pass if __name__ == '__main__': ManagedWindow()

557da6fd9606fd8df270846b48fab1434a1594e941d814085fe3b11fae270b6b

"""Plotting module that can plot 2D and 3D functions """ from sympy.utilities.decorator import doctest_depends_on try: @doctest_depends_on(modules=('pyglet',)) def PygletPlot(*args, **kwargs): """ Plot Examples ============= See examples/advanced/pyglet_plotting.py for many more examples. >>> from sympy.plotting.pygletplot import PygletPlot as Plot >>> from sympy import symbols >>> from sympy.abc import x, y, z >>> Plot(x*y**3-y*x**3) [0]: -x**3*y + x*y**3, 'mode=cartesian' >>> p = Plot() >>> p[1] = x*y >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p = Plot() >>> p[1] = x**2+y**2 >>> p[2] = -x**2-y**2 Variable Intervals ================== The basic format is [var, min, max, steps], but the syntax is flexible and arguments left out are taken from the defaults for the current coordinate mode: >>> Plot(x**2) # implies [x,-5,5,100] [0]: x**2, 'mode=cartesian' >>> Plot(x**2, [], []) # [x,-1,1,40], [y,-1,1,40] [0]: x**2, 'mode=cartesian' >>> Plot(x**2-y**2, [100], [100]) # [x,-1,1,100], [y,-1,1,100] [0]: x**2 - y**2, 'mode=cartesian' >>> Plot(x**2, [x,-13,13,100]) [0]: x**2, 'mode=cartesian' >>> Plot(x**2, [-13,13]) # [x,-13,13,100] [0]: x**2, 'mode=cartesian' >>> Plot(x**2, [x,-13,13]) # [x,-13,13,100] [0]: x**2, 'mode=cartesian' >>> Plot(1*x, [], [x], mode='cylindrical') ... # [unbound_theta,0,2*Pi,40], [x,-1,1,20] [0]: x, 'mode=cartesian' Coordinate Modes ================ Plot supports several curvilinear coordinate modes, and they independent for each plotted function. You can specify a coordinate mode explicitly with the 'mode' named argument, but it can be automatically determined for Cartesian or parametric plots, and therefore must only be specified for polar, cylindrical, and spherical modes. Specifically, Plot(function arguments) and Plot[n] = (function arguments) will interpret your arguments as a Cartesian plot if you provide one function and a parametric plot if you provide two or three functions. Similarly, the arguments will be interpreted as a curve if one variable is used, and a surface if two are used. Supported mode names by number of variables: 1: parametric, cartesian, polar 2: parametric, cartesian, cylindrical = polar, spherical >>> Plot(1, mode='spherical') Calculator-like Interface ========================= >>> p = Plot(visible=False) >>> f = x**2 >>> p[1] = f >>> p[2] = f.diff(x) >>> p[3] = f.diff(x).diff(x) >>> p [1]: x**2, 'mode=cartesian' [2]: 2*x, 'mode=cartesian' [3]: 2, 'mode=cartesian' >>> p.show() >>> p.clear() >>> p <blank plot> >>> p[1] = x**2+y**2 >>> p[1].style = 'solid' >>> p[2] = -x**2-y**2 >>> p[2].style = 'wireframe' >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p[1].style = 'both' >>> p[2].style = 'both' >>> p.close() Plot Window Keyboard Controls ============================= Screen Rotation: X,Y axis Arrow Keys, A,S,D,W, Numpad 4,6,8,2 Z axis Q,E, Numpad 7,9 Model Rotation: Z axis Z,C, Numpad 1,3 Zoom: R,F, PgUp,PgDn, Numpad +,- Reset Camera: X, Numpad 5 Camera Presets: XY F1 XZ F2 YZ F3 Perspective F4 Sensitivity Modifier: SHIFT Axes Toggle: Visible F5 Colors F6 Close Window: ESCAPE ============================= """ from sympy.plotting.pygletplot.plot import PygletPlot return PygletPlot(*args, **kwargs) except Exception as e: def PygletPlot(*args, **kwargs): raise e

3041e5eec67b04b0e6ea6d7088afc15b074f03491ed1c6d0266a69f6d0b80ba9

from __future__ import print_function, division try: from ctypes import c_float except ImportError: pass import pyglet.gl as pgl from math import sqrt as _sqrt, acos as _acos def cross(a, b): return (a[1] * b[2] - a[2] * b[1], a[2] * b[0] - a[0] * b[2], a[0] * b[1] - a[1] * b[0]) def dot(a, b): return a[0] * b[0] + a[1] * b[1] + a[2] * b[2] def mag(a): return _sqrt(a[0]**2 + a[1]**2 + a[2]**2) def norm(a): m = mag(a) return (a[0] / m, a[1] / m, a[2] / m) def get_sphere_mapping(x, y, width, height): x = min([max([x, 0]), width]) y = min([max([y, 0]), height]) sr = _sqrt((width/2)**2 + (height/2)**2) sx = ((x - width / 2) / sr) sy = ((y - height / 2) / sr) sz = 1.0 - sx**2 - sy**2 if sz > 0.0: sz = _sqrt(sz) return (sx, sy, sz) else: sz = 0 return norm((sx, sy, sz)) rad2deg = 180.0 / 3.141592 def get_spherical_rotatation(p1, p2, width, height, theta_multiplier): v1 = get_sphere_mapping(p1[0], p1[1], width, height) v2 = get_sphere_mapping(p2[0], p2[1], width, height) d = min(max([dot(v1, v2), -1]), 1) if abs(d - 1.0) < 0.000001: return None raxis = norm( cross(v1, v2) ) rtheta = theta_multiplier * rad2deg * _acos(d) pgl.glPushMatrix() pgl.glLoadIdentity() pgl.glRotatef(rtheta, *raxis) mat = (c_float*16)() pgl.glGetFloatv(pgl.GL_MODELVIEW_MATRIX, mat) pgl.glPopMatrix() return mat

2517b74f0d865287183a1884aca29efd651ceacb8e4add60b04a650d895e9a0f

from __future__ import print_function, division from threading import RLock # it is sufficient to import "pyglet" here once try: import pyglet.gl as pgl except ImportError: raise ImportError("pyglet is required for plotting.\n " "visit http://www.pyglet.org/") from sympy.core.compatibility import is_sequence, SYMPY_INTS from sympy.core.numbers import Integer from sympy.geometry.entity import GeometryEntity from sympy.plotting.pygletplot.plot_axes import PlotAxes from sympy.plotting.pygletplot.plot_mode import PlotMode from sympy.plotting.pygletplot.plot_object import PlotObject from sympy.plotting.pygletplot.plot_window import PlotWindow from sympy.plotting.pygletplot.util import parse_option_string from sympy.utilities.decorator import doctest_depends_on from time import sleep from os import getcwd, listdir import ctypes @doctest_depends_on(modules=('pyglet',)) class PygletPlot(object): """ Plot Examples ============= See examples/advanced/pyglet_plotting.py for many more examples. >>> from sympy.plotting.pygletplot import PygletPlot as Plot >>> from sympy.abc import x, y, z >>> Plot(x*y**3-y*x**3) [0]: -x**3*y + x*y**3, 'mode=cartesian' >>> p = Plot() >>> p[1] = x*y >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p = Plot() >>> p[1] = x**2+y**2 >>> p[2] = -x**2-y**2 Variable Intervals ================== The basic format is [var, min, max, steps], but the syntax is flexible and arguments left out are taken from the defaults for the current coordinate mode: >>> Plot(x**2) # implies [x,-5,5,100] [0]: x**2, 'mode=cartesian' >>> Plot(x**2, [], []) # [x,-1,1,40], [y,-1,1,40] [0]: x**2, 'mode=cartesian' >>> Plot(x**2-y**2, [100], [100]) # [x,-1,1,100], [y,-1,1,100] [0]: x**2 - y**2, 'mode=cartesian' >>> Plot(x**2, [x,-13,13,100]) [0]: x**2, 'mode=cartesian' >>> Plot(x**2, [-13,13]) # [x,-13,13,100] [0]: x**2, 'mode=cartesian' >>> Plot(x**2, [x,-13,13]) # [x,-13,13,10] [0]: x**2, 'mode=cartesian' >>> Plot(1*x, [], [x], mode='cylindrical') ... # [unbound_theta,0,2*Pi,40], [x,-1,1,20] [0]: x, 'mode=cartesian' Coordinate Modes ================ Plot supports several curvilinear coordinate modes, and they independent for each plotted function. You can specify a coordinate mode explicitly with the 'mode' named argument, but it can be automatically determined for Cartesian or parametric plots, and therefore must only be specified for polar, cylindrical, and spherical modes. Specifically, Plot(function arguments) and Plot[n] = (function arguments) will interpret your arguments as a Cartesian plot if you provide one function and a parametric plot if you provide two or three functions. Similarly, the arguments will be interpreted as a curve if one variable is used, and a surface if two are used. Supported mode names by number of variables: 1: parametric, cartesian, polar 2: parametric, cartesian, cylindrical = polar, spherical >>> Plot(1, mode='spherical') Calculator-like Interface ========================= >>> p = Plot(visible=False) >>> f = x**2 >>> p[1] = f >>> p[2] = f.diff(x) >>> p[3] = f.diff(x).diff(x) >>> p [1]: x**2, 'mode=cartesian' [2]: 2*x, 'mode=cartesian' [3]: 2, 'mode=cartesian' >>> p.show() >>> p.clear() >>> p <blank plot> >>> p[1] = x**2+y**2 >>> p[1].style = 'solid' >>> p[2] = -x**2-y**2 >>> p[2].style = 'wireframe' >>> p[1].color = z, (0.4,0.4,0.9), (0.9,0.4,0.4) >>> p[1].style = 'both' >>> p[2].style = 'both' >>> p.close() Plot Window Keyboard Controls ============================= Screen Rotation: X,Y axis Arrow Keys, A,S,D,W, Numpad 4,6,8,2 Z axis Q,E, Numpad 7,9 Model Rotation: Z axis Z,C, Numpad 1,3 Zoom: R,F, PgUp,PgDn, Numpad +,- Reset Camera: X, Numpad 5 Camera Presets: XY F1 XZ F2 YZ F3 Perspective F4 Sensitivity Modifier: SHIFT Axes Toggle: Visible F5 Colors F6 Close Window: ESCAPE ============================= """ @doctest_depends_on(modules=('pyglet',)) def __init__(self, *fargs, **win_args): """ Positional Arguments ==================== Any given positional arguments are used to initialize a plot function at index 1. In other words... >>> from sympy.plotting.pygletplot import PygletPlot as Plot >>> from sympy.core import Symbol >>> from sympy.abc import x >>> p = Plot(x**2, visible=False) ...is equivalent to... >>> p = Plot(visible=False) >>> p[1] = x**2 Note that in earlier versions of the plotting module, you were able to specify multiple functions in the initializer. This functionality has been dropped in favor of better automatic plot plot_mode detection. Named Arguments =============== axes An option string of the form "key1=value1; key2 = value2" which can use the following options: style = ordinate none OR frame OR box OR ordinate stride = 0.25 val OR (val_x, val_y, val_z) overlay = True (draw on top of plot) True OR False colored = False (False uses Black, True uses colors R,G,B = X,Y,Z) True OR False label_axes = False (display axis names at endpoints) True OR False visible = True (show immediately True OR False The following named arguments are passed as arguments to window initialization: antialiasing = True True OR False ortho = False True OR False invert_mouse_zoom = False True OR False """ # Register the plot modes from . import plot_modes self._win_args = win_args self._window = None self._render_lock = RLock() self._functions = {} self._pobjects = [] self._screenshot = ScreenShot(self) axe_options = parse_option_string(win_args.pop('axes', '')) self.axes = PlotAxes(**axe_options) self._pobjects.append(self.axes) self[0] = fargs if win_args.get('visible', True): self.show() ## Window Interfaces def show(self): """ Creates and displays a plot window, or activates it (gives it focus) if it has already been created. """ if self._window and not self._window.has_exit: self._window.activate() else: self._win_args['visible'] = True self.axes.reset_resources() #if hasattr(self, '_doctest_depends_on'): # self._win_args['runfromdoctester'] = True self._window = PlotWindow(self, **self._win_args) def close(self): """ Closes the plot window. """ if self._window: self._window.close() def saveimage(self, outfile=None, format='', size=(600, 500)): """ Saves a screen capture of the plot window to an image file. If outfile is given, it can either be a path or a file object. Otherwise a png image will be saved to the current working directory. If the format is omitted, it is determined from the filename extension. """ self._screenshot.save(outfile, format, size) ## Function List Interfaces def clear(self): """ Clears the function list of this plot. """ self._render_lock.acquire() self._functions = {} self.adjust_all_bounds() self._render_lock.release() def __getitem__(self, i): """ Returns the function at position i in the function list. """ return self._functions[i] def __setitem__(self, i, args): """ Parses and adds a PlotMode to the function list. """ if not (isinstance(i, (SYMPY_INTS, Integer)) and i >= 0): raise ValueError("Function index must " "be an integer >= 0.") if isinstance(args, PlotObject): f = args else: if (not is_sequence(args)) or isinstance(args, GeometryEntity): args = [args] if len(args) == 0: return # no arguments given kwargs = dict(bounds_callback=self.adjust_all_bounds) f = PlotMode(*args, **kwargs) if f: self._render_lock.acquire() self._functions[i] = f self._render_lock.release() else: raise ValueError("Failed to parse '%s'." % ', '.join(str(a) for a in args)) def __delitem__(self, i): """ Removes the function in the function list at position i. """ self._render_lock.acquire() del self._functions[i] self.adjust_all_bounds() self._render_lock.release() def firstavailableindex(self): """ Returns the first unused index in the function list. """ i = 0 self._render_lock.acquire() while i in self._functions: i += 1 self._render_lock.release() return i def append(self, *args): """ Parses and adds a PlotMode to the function list at the first available index. """ self.__setitem__(self.firstavailableindex(), args) def __len__(self): """ Returns the number of functions in the function list. """ return len(self._functions) def __iter__(self): """ Allows iteration of the function list. """ return self._functions.itervalues() def __repr__(self): return str(self) def __str__(self): """ Returns a string containing a new-line separated list of the functions in the function list. """ s = "" if len(self._functions) == 0: s += "<blank plot>" else: self._render_lock.acquire() s += "\n".join(["%s[%i]: %s" % ("", i, str(self._functions[i])) for i in self._functions]) self._render_lock.release() return s def adjust_all_bounds(self): self._render_lock.acquire() self.axes.reset_bounding_box() for f in self._functions: self.axes.adjust_bounds(self._functions[f].bounds) self._render_lock.release() def wait_for_calculations(self): sleep(0) self._render_lock.acquire() for f in self._functions: a = self._functions[f]._get_calculating_verts b = self._functions[f]._get_calculating_cverts while a() or b(): sleep(0) self._render_lock.release() class ScreenShot: def __init__(self, plot): self._plot = plot self.screenshot_requested = False self.outfile = None self.format = '' self.invisibleMode = False self.flag = 0 def __nonzero__(self): return self.screenshot_requested __bool__ = __nonzero__ def _execute_saving(self): if self.flag < 3: self.flag += 1 return size_x, size_y = self._plot._window.get_size() size = size_x*size_y*4*ctypes.sizeof(ctypes.c_ubyte) image = ctypes.create_string_buffer(size) pgl.glReadPixels(0, 0, size_x, size_y, pgl.GL_RGBA, pgl.GL_UNSIGNED_BYTE, image) from PIL import Image im = Image.frombuffer('RGBA', (size_x, size_y), image.raw, 'raw', 'RGBA', 0, 1) im.transpose(Image.FLIP_TOP_BOTTOM).save(self.outfile, self.format) self.flag = 0 self.screenshot_requested = False if self.invisibleMode: self._plot._window.close() def save(self, outfile=None, format='', size=(600, 500)): self.outfile = outfile self.format = format self.size = size self.screenshot_requested = True if not self._plot._window or self._plot._window.has_exit: self._plot._win_args['visible'] = False self._plot._win_args['width'] = size[0] self._plot._win_args['height'] = size[1] self._plot.axes.reset_resources() self._plot._window = PlotWindow(self._plot, **self._plot._win_args) self.invisibleMode = True if self.outfile is None: self.outfile = self._create_unique_path() print(self.outfile) def _create_unique_path(self): cwd = getcwd() l = listdir(cwd) path = '' i = 0 while True: if not 'plot_%s.png' % i in l: path = cwd + '/plot_%s.png' % i break i += 1 return path

f16436d1c9ce168bba211d7d2a659787af2626af15183271cd604d0a2bfc6688

from __future__ import print_function, division import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import is_sequence from sympy.plotting.pygletplot.color_scheme import ColorScheme from sympy.plotting.pygletplot.plot_mode import PlotMode from time import sleep from threading import Thread, Event, RLock import warnings class PlotModeBase(PlotMode): """ Intended parent class for plotting modes. Provides base functionality in conjunction with its parent, PlotMode. """ ## ## Class-Level Attributes ## """ The following attributes are meant to be set at the class level, and serve as parameters to the plot mode registry (in PlotMode). See plot_modes.py for concrete examples. """ """ i_vars 'x' for Cartesian2D 'xy' for Cartesian3D etc. d_vars 'y' for Cartesian2D 'r' for Polar etc. """ i_vars, d_vars = '', '' """ intervals Default intervals for each i_var, and in the same order. Specified [min, max, steps]. No variable can be given (it is bound later). """ intervals = [] """ aliases A list of strings which can be used to access this mode. 'cartesian' for Cartesian2D and Cartesian3D 'polar' for Polar 'cylindrical', 'polar' for Cylindrical Note that _init_mode chooses the first alias in the list as the mode's primary_alias, which will be displayed to the end user in certain contexts. """ aliases = [] """ is_default Whether to set this mode as the default for arguments passed to PlotMode() containing the same number of d_vars as this mode and at most the same number of i_vars. """ is_default = False """ All of the above attributes are defined in PlotMode. The following ones are specific to PlotModeBase. """ """ A list of the render styles. Do not modify. """ styles = {'wireframe': 1, 'solid': 2, 'both': 3} """ style_override Always use this style if not blank. """ style_override = '' """ default_wireframe_color default_solid_color Can be used when color is None or being calculated. Used by PlotCurve and PlotSurface, but not anywhere in PlotModeBase. """ default_wireframe_color = (0.85, 0.85, 0.85) default_solid_color = (0.6, 0.6, 0.9) default_rot_preset = 'xy' ## ## Instance-Level Attributes ## ## 'Abstract' member functions def _get_evaluator(self): if self.use_lambda_eval: try: e = self._get_lambda_evaluator() return e except Exception: warnings.warn("\nWarning: creating lambda evaluator failed. " "Falling back on sympy subs evaluator.") return self._get_sympy_evaluator() def _get_sympy_evaluator(self): raise NotImplementedError() def _get_lambda_evaluator(self): raise NotImplementedError() def _on_calculate_verts(self): raise NotImplementedError() def _on_calculate_cverts(self): raise NotImplementedError() ## Base member functions def __init__(self, *args, **kwargs): self.verts = [] self.cverts = [] self.bounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] self.cbounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] self._draw_lock = RLock() self._calculating_verts = Event() self._calculating_cverts = Event() self._calculating_verts_pos = 0.0 self._calculating_verts_len = 0.0 self._calculating_cverts_pos = 0.0 self._calculating_cverts_len = 0.0 self._max_render_stack_size = 3 self._draw_wireframe = [-1] self._draw_solid = [-1] self._style = None self._color = None self.predraw = [] self.postdraw = [] self.use_lambda_eval = self.options.pop('use_sympy_eval', None) is None self.style = self.options.pop('style', '') self.color = self.options.pop('color', 'rainbow') self.bounds_callback = kwargs.pop('bounds_callback', None) self._on_calculate() def synchronized(f): def w(self, *args, **kwargs): self._draw_lock.acquire() try: r = f(self, *args, **kwargs) return r finally: self._draw_lock.release() return w @synchronized def push_wireframe(self, function): """ Push a function which performs gl commands used to build a display list. (The list is built outside of the function) """ assert callable(function) self._draw_wireframe.append(function) if len(self._draw_wireframe) > self._max_render_stack_size: del self._draw_wireframe[1] # leave marker element @synchronized def push_solid(self, function): """ Push a function which performs gl commands used to build a display list. (The list is built outside of the function) """ assert callable(function) self._draw_solid.append(function) if len(self._draw_solid) > self._max_render_stack_size: del self._draw_solid[1] # leave marker element def _create_display_list(self, function): dl = pgl.glGenLists(1) pgl.glNewList(dl, pgl.GL_COMPILE) function() pgl.glEndList() return dl def _render_stack_top(self, render_stack): top = render_stack[-1] if top == -1: return -1 # nothing to display elif callable(top): dl = self._create_display_list(top) render_stack[-1] = (dl, top) return dl # display newly added list elif len(top) == 2: if pgl.GL_TRUE == pgl.glIsList(top[0]): return top[0] # display stored list dl = self._create_display_list(top[1]) render_stack[-1] = (dl, top[1]) return dl # display regenerated list def _draw_solid_display_list(self, dl): pgl.glPushAttrib(pgl.GL_ENABLE_BIT | pgl.GL_POLYGON_BIT) pgl.glPolygonMode(pgl.GL_FRONT_AND_BACK, pgl.GL_FILL) pgl.glCallList(dl) pgl.glPopAttrib() def _draw_wireframe_display_list(self, dl): pgl.glPushAttrib(pgl.GL_ENABLE_BIT | pgl.GL_POLYGON_BIT) pgl.glPolygonMode(pgl.GL_FRONT_AND_BACK, pgl.GL_LINE) pgl.glEnable(pgl.GL_POLYGON_OFFSET_LINE) pgl.glPolygonOffset(-0.005, -50.0) pgl.glCallList(dl) pgl.glPopAttrib() @synchronized def draw(self): for f in self.predraw: if callable(f): f() if self.style_override: style = self.styles[self.style_override] else: style = self.styles[self._style] # Draw solid component if style includes solid if style & 2: dl = self._render_stack_top(self._draw_solid) if dl > 0 and pgl.GL_TRUE == pgl.glIsList(dl): self._draw_solid_display_list(dl) # Draw wireframe component if style includes wireframe if style & 1: dl = self._render_stack_top(self._draw_wireframe) if dl > 0 and pgl.GL_TRUE == pgl.glIsList(dl): self._draw_wireframe_display_list(dl) for f in self.postdraw: if callable(f): f() def _on_change_color(self, color): Thread(target=self._calculate_cverts).start() def _on_calculate(self): Thread(target=self._calculate_all).start() def _calculate_all(self): self._calculate_verts() self._calculate_cverts() def _calculate_verts(self): if self._calculating_verts.isSet(): return self._calculating_verts.set() try: self._on_calculate_verts() finally: self._calculating_verts.clear() if callable(self.bounds_callback): self.bounds_callback() def _calculate_cverts(self): if self._calculating_verts.isSet(): return while self._calculating_cverts.isSet(): sleep(0) # wait for previous calculation self._calculating_cverts.set() try: self._on_calculate_cverts() finally: self._calculating_cverts.clear() def _get_calculating_verts(self): return self._calculating_verts.isSet() def _get_calculating_verts_pos(self): return self._calculating_verts_pos def _get_calculating_verts_len(self): return self._calculating_verts_len def _get_calculating_cverts(self): return self._calculating_cverts.isSet() def _get_calculating_cverts_pos(self): return self._calculating_cverts_pos def _get_calculating_cverts_len(self): return self._calculating_cverts_len ## Property handlers def _get_style(self): return self._style @synchronized def _set_style(self, v): if v is None: return if v == '': step_max = 0 for i in self.intervals: if i.v_steps is None: continue step_max = max([step_max, int(i.v_steps)]) v = ['both', 'solid'][step_max > 40] if v not in self.styles: raise ValueError("v should be there in self.styles") if v == self._style: return self._style = v def _get_color(self): return self._color @synchronized def _set_color(self, v): try: if v is not None: if is_sequence(v): v = ColorScheme(*v) else: v = ColorScheme(v) if repr(v) == repr(self._color): return self._on_change_color(v) self._color = v except Exception as e: raise RuntimeError(("Color change failed. " "Reason: %s" % (str(e)))) style = property(_get_style, _set_style) color = property(_get_color, _set_color) calculating_verts = property(_get_calculating_verts) calculating_verts_pos = property(_get_calculating_verts_pos) calculating_verts_len = property(_get_calculating_verts_len) calculating_cverts = property(_get_calculating_cverts) calculating_cverts_pos = property(_get_calculating_cverts_pos) calculating_cverts_len = property(_get_calculating_cverts_len) ## String representations def __str__(self): f = ", ".join(str(d) for d in self.d_vars) o = "'mode=%s'" % (self.primary_alias) return ", ".join([f, o]) def __repr__(self): f = ", ".join(str(d) for d in self.d_vars) i = ", ".join(str(i) for i in self.intervals) d = [('mode', self.primary_alias), ('color', str(self.color)), ('style', str(self.style))] o = "'%s'" % (("; ".join("%s=%s" % (k, v) for k, v in d if v != 'None'))) return ", ".join([f, i, o])

a86e2d3570c701c3d01b863086f758dec39ea4b95ab781bb3ee6119b92ca97e9

from __future__ import print_function, division import pyglet.gl as pgl from sympy.plotting.pygletplot.plot_rotation import get_spherical_rotatation from sympy.plotting.pygletplot.util import get_model_matrix, model_to_screen, \ screen_to_model, vec_subs class PlotCamera(object): min_dist = 0.05 max_dist = 500.0 min_ortho_dist = 100.0 max_ortho_dist = 10000.0 _default_dist = 6.0 _default_ortho_dist = 600.0 rot_presets = { 'xy': (0, 0, 0), 'xz': (-90, 0, 0), 'yz': (0, 90, 0), 'perspective': (-45, 0, -45) } def __init__(self, window, ortho=False): self.window = window self.axes = self.window.plot.axes self.ortho = ortho self.reset() def init_rot_matrix(self): pgl.glPushMatrix() pgl.glLoadIdentity() self._rot = get_model_matrix() pgl.glPopMatrix() def set_rot_preset(self, preset_name): self.init_rot_matrix() try: r = self.rot_presets[preset_name] except AttributeError: raise ValueError( "%s is not a valid rotation preset." % preset_name) try: self.euler_rotate(r[0], 1, 0, 0) self.euler_rotate(r[1], 0, 1, 0) self.euler_rotate(r[2], 0, 0, 1) except AttributeError: pass def reset(self): self._dist = 0.0 self._x, self._y = 0.0, 0.0 self._rot = None if self.ortho: self._dist = self._default_ortho_dist else: self._dist = self._default_dist self.init_rot_matrix() def mult_rot_matrix(self, rot): pgl.glPushMatrix() pgl.glLoadMatrixf(rot) pgl.glMultMatrixf(self._rot) self._rot = get_model_matrix() pgl.glPopMatrix() def setup_projection(self): pgl.glMatrixMode(pgl.GL_PROJECTION) pgl.glLoadIdentity() if self.ortho: # yep, this is pseudo ortho (don't tell anyone) pgl.gluPerspective( 0.3, float(self.window.width)/float(self.window.height), self.min_ortho_dist - 0.01, self.max_ortho_dist + 0.01) else: pgl.gluPerspective( 30.0, float(self.window.width)/float(self.window.height), self.min_dist - 0.01, self.max_dist + 0.01) pgl.glMatrixMode(pgl.GL_MODELVIEW) def _get_scale(self): return 1.0, 1.0, 1.0 def apply_transformation(self): pgl.glLoadIdentity() pgl.glTranslatef(self._x, self._y, -self._dist) if self._rot is not None: pgl.glMultMatrixf(self._rot) pgl.glScalef(*self._get_scale()) def spherical_rotate(self, p1, p2, sensitivity=1.0): mat = get_spherical_rotatation(p1, p2, self.window.width, self.window.height, sensitivity) if mat is not None: self.mult_rot_matrix(mat) def euler_rotate(self, angle, x, y, z): pgl.glPushMatrix() pgl.glLoadMatrixf(self._rot) pgl.glRotatef(angle, x, y, z) self._rot = get_model_matrix() pgl.glPopMatrix() def zoom_relative(self, clicks, sensitivity): if self.ortho: dist_d = clicks * sensitivity * 50.0 min_dist = self.min_ortho_dist max_dist = self.max_ortho_dist else: dist_d = clicks * sensitivity min_dist = self.min_dist max_dist = self.max_dist new_dist = (self._dist - dist_d) if (clicks < 0 and new_dist < max_dist) or new_dist > min_dist: self._dist = new_dist def mouse_translate(self, x, y, dx, dy): pgl.glPushMatrix() pgl.glLoadIdentity() pgl.glTranslatef(0, 0, -self._dist) z = model_to_screen(0, 0, 0)[2] d = vec_subs(screen_to_model(x, y, z), screen_to_model(x - dx, y - dy, z)) pgl.glPopMatrix() self._x += d[0] self._y += d[1]

ebdb658dfc6a323c9925f46e3344591ab345843daa48ece37fda8ff90e471efa

from __future__ import print_function, division from sympy import Basic, Symbol, symbols, lambdify from sympy.core.compatibility import range, string_types from .util import interpolate, rinterpolate, create_bounds, update_bounds from sympy.utilities.iterables import sift class ColorGradient(object): colors = [0.4, 0.4, 0.4], [0.9, 0.9, 0.9] intervals = 0.0, 1.0 def __init__(self, *args): if len(args) == 2: self.colors = list(args) self.intervals = [0.0, 1.0] elif len(args) > 0: if len(args) % 2 != 0: raise ValueError("len(args) should be even") self.colors = [args[i] for i in range(1, len(args), 2)] self.intervals = [args[i] for i in range(0, len(args), 2)] assert len(self.colors) == len(self.intervals) def copy(self): c = ColorGradient() c.colors = [e[::] for e in self.colors] c.intervals = self.intervals[::] return c def _find_interval(self, v): m = len(self.intervals) i = 0 while i < m - 1 and self.intervals[i] <= v: i += 1 return i def _interpolate_axis(self, axis, v): i = self._find_interval(v) v = rinterpolate(self.intervals[i - 1], self.intervals[i], v) return interpolate(self.colors[i - 1][axis], self.colors[i][axis], v) def __call__(self, r, g, b): c = self._interpolate_axis return c(0, r), c(1, g), c(2, b) default_color_schemes = {} # defined at the bottom of this file class ColorScheme(object): def __init__(self, *args, **kwargs): self.args = args self.f, self.gradient = None, ColorGradient() if len(args) == 1 and not isinstance(args[0], Basic) and callable(args[0]): self.f = args[0] elif len(args) == 1 and isinstance(args[0], string_types): if args[0] in default_color_schemes: cs = default_color_schemes[args[0]] self.f, self.gradient = cs.f, cs.gradient.copy() else: self.f = lambdify('x,y,z,u,v', args[0]) else: self.f, self.gradient = self._interpret_args(args) self._test_color_function() if not isinstance(self.gradient, ColorGradient): raise ValueError("Color gradient not properly initialized. " "(Not a ColorGradient instance.)") def _interpret_args(self, args): f, gradient = None, self.gradient atoms, lists = self._sort_args(args) s = self._pop_symbol_list(lists) s = self._fill_in_vars(s) # prepare the error message for lambdification failure f_str = ', '.join(str(fa) for fa in atoms) s_str = (str(sa) for sa in s) s_str = ', '.join(sa for sa in s_str if sa.find('unbound') < 0) f_error = ValueError("Could not interpret arguments " "%s as functions of %s." % (f_str, s_str)) # try to lambdify args if len(atoms) == 1: fv = atoms[0] try: f = lambdify(s, [fv, fv, fv]) except TypeError: raise f_error elif len(atoms) == 3: fr, fg, fb = atoms try: f = lambdify(s, [fr, fg, fb]) except TypeError: raise f_error else: raise ValueError("A ColorScheme must provide 1 or 3 " "functions in x, y, z, u, and/or v.") # try to intrepret any given color information if len(lists) == 0: gargs = [] elif len(lists) == 1: gargs = lists[0] elif len(lists) == 2: try: (r1, g1, b1), (r2, g2, b2) = lists except TypeError: raise ValueError("If two color arguments are given, " "they must be given in the format " "(r1, g1, b1), (r2, g2, b2).") gargs = lists elif len(lists) == 3: try: (r1, r2), (g1, g2), (b1, b2) = lists except Exception: raise ValueError("If three color arguments are given, " "they must be given in the format " "(r1, r2), (g1, g2), (b1, b2). To create " "a multi-step gradient, use the syntax " "[0, colorStart, step1, color1, ..., 1, " "colorEnd].") gargs = [[r1, g1, b1], [r2, g2, b2]] else: raise ValueError("Don't know what to do with collection " "arguments %s." % (', '.join(str(l) for l in lists))) if gargs: try: gradient = ColorGradient(*gargs) except Exception as ex: raise ValueError(("Could not initialize a gradient " "with arguments %s. Inner " "exception: %s") % (gargs, str(ex))) return f, gradient def _pop_symbol_list(self, lists): symbol_lists = [] for l in lists: mark = True for s in l: if s is not None and not isinstance(s, Symbol): mark = False break if mark: lists.remove(l) symbol_lists.append(l) if len(symbol_lists) == 1: return symbol_lists[0] elif len(symbol_lists) == 0: return [] else: raise ValueError("Only one list of Symbols " "can be given for a color scheme.") def _fill_in_vars(self, args): defaults = symbols('x,y,z,u,v') v_error = ValueError("Could not find what to plot.") if len(args) == 0: return defaults if not isinstance(args, (tuple, list)): raise v_error if len(args) == 0: return defaults for s in args: if s is not None and not isinstance(s, Symbol): raise v_error # when vars are given explicitly, any vars # not given are marked 'unbound' as to not # be accidentally used in an expression vars = [Symbol('unbound%i' % (i)) for i in range(1, 6)] # interpret as t if len(args) == 1: vars[3] = args[0] # interpret as u,v elif len(args) == 2: if args[0] is not None: vars[3] = args[0] if args[1] is not None: vars[4] = args[1] # interpret as x,y,z elif len(args) >= 3: # allow some of x,y,z to be # left unbound if not given if args[0] is not None: vars[0] = args[0] if args[1] is not None: vars[1] = args[1] if args[2] is not None: vars[2] = args[2] # interpret the rest as t if len(args) >= 4: vars[3] = args[3] # ...or u,v if len(args) >= 5: vars[4] = args[4] return vars def _sort_args(self, args): lists, atoms = sift(args, lambda a: isinstance(a, (tuple, list)), binary=True) return atoms, lists def _test_color_function(self): if not callable(self.f): raise ValueError("Color function is not callable.") try: result = self.f(0, 0, 0, 0, 0) if len(result) != 3: raise ValueError("length should be equal to 3") except TypeError: raise ValueError("Color function needs to accept x,y,z,u,v, " "as arguments even if it doesn't use all of them.") except AssertionError: raise ValueError("Color function needs to return 3-tuple r,g,b.") except Exception: pass # color function probably not valid at 0,0,0,0,0 def __call__(self, x, y, z, u, v): try: return self.f(x, y, z, u, v) except Exception: return None def apply_to_curve(self, verts, u_set, set_len=None, inc_pos=None): """ Apply this color scheme to a set of vertices over a single independent variable u. """ bounds = create_bounds() cverts = list() if callable(set_len): set_len(len(u_set)*2) # calculate f() = r,g,b for each vert # and find the min and max for r,g,b for _u in range(len(u_set)): if verts[_u] is None: cverts.append(None) else: x, y, z = verts[_u] u, v = u_set[_u], None c = self(x, y, z, u, v) if c is not None: c = list(c) update_bounds(bounds, c) cverts.append(c) if callable(inc_pos): inc_pos() # scale and apply gradient for _u in range(len(u_set)): if cverts[_u] is not None: for _c in range(3): # scale from [f_min, f_max] to [0,1] cverts[_u][_c] = rinterpolate(bounds[_c][0], bounds[_c][1], cverts[_u][_c]) # apply gradient cverts[_u] = self.gradient(*cverts[_u]) if callable(inc_pos): inc_pos() return cverts def apply_to_surface(self, verts, u_set, v_set, set_len=None, inc_pos=None): """ Apply this color scheme to a set of vertices over two independent variables u and v. """ bounds = create_bounds() cverts = list() if callable(set_len): set_len(len(u_set)*len(v_set)*2) # calculate f() = r,g,b for each vert # and find the min and max for r,g,b for _u in range(len(u_set)): column = list() for _v in range(len(v_set)): if verts[_u][_v] is None: column.append(None) else: x, y, z = verts[_u][_v] u, v = u_set[_u], v_set[_v] c = self(x, y, z, u, v) if c is not None: c = list(c) update_bounds(bounds, c) column.append(c) if callable(inc_pos): inc_pos() cverts.append(column) # scale and apply gradient for _u in range(len(u_set)): for _v in range(len(v_set)): if cverts[_u][_v] is not None: # scale from [f_min, f_max] to [0,1] for _c in range(3): cverts[_u][_v][_c] = rinterpolate(bounds[_c][0], bounds[_c][1], cverts[_u][_v][_c]) # apply gradient cverts[_u][_v] = self.gradient(*cverts[_u][_v]) if callable(inc_pos): inc_pos() return cverts def str_base(self): return ", ".join(str(a) for a in self.args) def __repr__(self): return "%s" % (self.str_base()) x, y, z, t, u, v = symbols('x,y,z,t,u,v') default_color_schemes['rainbow'] = ColorScheme(z, y, x) default_color_schemes['zfade'] = ColorScheme(z, (0.4, 0.4, 0.97), (0.97, 0.4, 0.4), (None, None, z)) default_color_schemes['zfade3'] = ColorScheme(z, (None, None, z), [0.00, (0.2, 0.2, 1.0), 0.35, (0.2, 0.8, 0.4), 0.50, (0.3, 0.9, 0.3), 0.65, (0.4, 0.8, 0.2), 1.00, (1.0, 0.2, 0.2)]) default_color_schemes['zfade4'] = ColorScheme(z, (None, None, z), [0.0, (0.3, 0.3, 1.0), 0.30, (0.3, 1.0, 0.3), 0.55, (0.95, 1.0, 0.2), 0.65, (1.0, 0.95, 0.2), 0.85, (1.0, 0.7, 0.2), 1.0, (1.0, 0.3, 0.2)])

b6ca067e3d600e93c50b05f305f6e1dbdee659d70d5006565f56c83c3fd28d5c

from __future__ import print_function, division from pyglet.window import key from pyglet.window.mouse import LEFT, RIGHT, MIDDLE from sympy.plotting.pygletplot.util import get_direction_vectors, get_basis_vectors class PlotController(object): normal_mouse_sensitivity = 4.0 modified_mouse_sensitivity = 1.0 normal_key_sensitivity = 160.0 modified_key_sensitivity = 40.0 keymap = { key.LEFT: 'left', key.A: 'left', key.NUM_4: 'left', key.RIGHT: 'right', key.D: 'right', key.NUM_6: 'right', key.UP: 'up', key.W: 'up', key.NUM_8: 'up', key.DOWN: 'down', key.S: 'down', key.NUM_2: 'down', key.Z: 'rotate_z_neg', key.NUM_1: 'rotate_z_neg', key.C: 'rotate_z_pos', key.NUM_3: 'rotate_z_pos', key.Q: 'spin_left', key.NUM_7: 'spin_left', key.E: 'spin_right', key.NUM_9: 'spin_right', key.X: 'reset_camera', key.NUM_5: 'reset_camera', key.NUM_ADD: 'zoom_in', key.PAGEUP: 'zoom_in', key.R: 'zoom_in', key.NUM_SUBTRACT: 'zoom_out', key.PAGEDOWN: 'zoom_out', key.F: 'zoom_out', key.RSHIFT: 'modify_sensitivity', key.LSHIFT: 'modify_sensitivity', key.F1: 'rot_preset_xy', key.F2: 'rot_preset_xz', key.F3: 'rot_preset_yz', key.F4: 'rot_preset_perspective', key.F5: 'toggle_axes', key.F6: 'toggle_axe_colors', key.F8: 'save_image' } def __init__(self, window, **kwargs): self.invert_mouse_zoom = kwargs.pop('invert_mouse_zoom', False) self.window = window self.camera = window.camera self.action = { # Rotation around the view Y (up) vector 'left': False, 'right': False, # Rotation around the view X vector 'up': False, 'down': False, # Rotation around the view Z vector 'spin_left': False, 'spin_right': False, # Rotation around the model Z vector 'rotate_z_neg': False, 'rotate_z_pos': False, # Reset to the default rotation 'reset_camera': False, # Performs camera z-translation 'zoom_in': False, 'zoom_out': False, # Use alternative sensitivity (speed) 'modify_sensitivity': False, # Rotation presets 'rot_preset_xy': False, 'rot_preset_xz': False, 'rot_preset_yz': False, 'rot_preset_perspective': False, # axes 'toggle_axes': False, 'toggle_axe_colors': False, # screenshot 'save_image': False } def update(self, dt): z = 0 if self.action['zoom_out']: z -= 1 if self.action['zoom_in']: z += 1 if z != 0: self.camera.zoom_relative(z/10.0, self.get_key_sensitivity()/10.0) dx, dy, dz = 0, 0, 0 if self.action['left']: dx -= 1 if self.action['right']: dx += 1 if self.action['up']: dy -= 1 if self.action['down']: dy += 1 if self.action['spin_left']: dz += 1 if self.action['spin_right']: dz -= 1 if not self.is_2D(): if dx != 0: self.camera.euler_rotate(dx*dt*self.get_key_sensitivity(), *(get_direction_vectors()[1])) if dy != 0: self.camera.euler_rotate(dy*dt*self.get_key_sensitivity(), *(get_direction_vectors()[0])) if dz != 0: self.camera.euler_rotate(dz*dt*self.get_key_sensitivity(), *(get_direction_vectors()[2])) else: self.camera.mouse_translate(0, 0, dx*dt*self.get_key_sensitivity(), -dy*dt*self.get_key_sensitivity()) rz = 0 if self.action['rotate_z_neg'] and not self.is_2D(): rz -= 1 if self.action['rotate_z_pos'] and not self.is_2D(): rz += 1 if rz != 0: self.camera.euler_rotate(rz*dt*self.get_key_sensitivity(), *(get_basis_vectors()[2])) if self.action['reset_camera']: self.camera.reset() if self.action['rot_preset_xy']: self.camera.set_rot_preset('xy') if self.action['rot_preset_xz']: self.camera.set_rot_preset('xz') if self.action['rot_preset_yz']: self.camera.set_rot_preset('yz') if self.action['rot_preset_perspective']: self.camera.set_rot_preset('perspective') if self.action['toggle_axes']: self.action['toggle_axes'] = False self.camera.axes.toggle_visible() if self.action['toggle_axe_colors']: self.action['toggle_axe_colors'] = False self.camera.axes.toggle_colors() if self.action['save_image']: self.action['save_image'] = False self.window.plot.saveimage() return True def get_mouse_sensitivity(self): if self.action['modify_sensitivity']: return self.modified_mouse_sensitivity else: return self.normal_mouse_sensitivity def get_key_sensitivity(self): if self.action['modify_sensitivity']: return self.modified_key_sensitivity else: return self.normal_key_sensitivity def on_key_press(self, symbol, modifiers): if symbol in self.keymap: self.action[self.keymap[symbol]] = True def on_key_release(self, symbol, modifiers): if symbol in self.keymap: self.action[self.keymap[symbol]] = False def on_mouse_drag(self, x, y, dx, dy, buttons, modifiers): if buttons & LEFT: if self.is_2D(): self.camera.mouse_translate(x, y, dx, dy) else: self.camera.spherical_rotate((x - dx, y - dy), (x, y), self.get_mouse_sensitivity()) if buttons & MIDDLE: self.camera.zoom_relative([1, -1][self.invert_mouse_zoom]*dy, self.get_mouse_sensitivity()/20.0) if buttons & RIGHT: self.camera.mouse_translate(x, y, dx, dy) def on_mouse_scroll(self, x, y, dx, dy): self.camera.zoom_relative([1, -1][self.invert_mouse_zoom]*dy, self.get_mouse_sensitivity()) def is_2D(self): functions = self.window.plot._functions for i in functions: if len(functions[i].i_vars) > 1 or len(functions[i].d_vars) > 2: return False return True

947d1ea379fad7042f321b974af5ba790e32ef8502d6c159a28c0838f9d1cf12

from __future__ import print_function, division import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import range from sympy.plotting.pygletplot.plot_mode_base import PlotModeBase class PlotCurve(PlotModeBase): style_override = 'wireframe' def _on_calculate_verts(self): self.t_interval = self.intervals[0] self.t_set = list(self.t_interval.frange()) self.bounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] evaluate = self._get_evaluator() self._calculating_verts_pos = 0.0 self._calculating_verts_len = float(self.t_interval.v_len) self.verts = list() b = self.bounds for t in self.t_set: try: _e = evaluate(t) # calculate vertex except (NameError, ZeroDivisionError): _e = None if _e is not None: # update bounding box for axis in range(3): b[axis][0] = min([b[axis][0], _e[axis]]) b[axis][1] = max([b[axis][1], _e[axis]]) self.verts.append(_e) self._calculating_verts_pos += 1.0 for axis in range(3): b[axis][2] = b[axis][1] - b[axis][0] if b[axis][2] == 0.0: b[axis][2] = 1.0 self.push_wireframe(self.draw_verts(False)) def _on_calculate_cverts(self): if not self.verts or not self.color: return def set_work_len(n): self._calculating_cverts_len = float(n) def inc_work_pos(): self._calculating_cverts_pos += 1.0 set_work_len(1) self._calculating_cverts_pos = 0 self.cverts = self.color.apply_to_curve(self.verts, self.t_set, set_len=set_work_len, inc_pos=inc_work_pos) self.push_wireframe(self.draw_verts(True)) def calculate_one_cvert(self, t): vert = self.verts[t] return self.color(vert[0], vert[1], vert[2], self.t_set[t], None) def draw_verts(self, use_cverts): def f(): pgl.glBegin(pgl.GL_LINE_STRIP) for t in range(len(self.t_set)): p = self.verts[t] if p is None: pgl.glEnd() pgl.glBegin(pgl.GL_LINE_STRIP) continue if use_cverts: c = self.cverts[t] if c is None: c = (0, 0, 0) pgl.glColor3f(*c) else: pgl.glColor3f(*self.default_wireframe_color) pgl.glVertex3f(*p) pgl.glEnd() return f

d468d037ac1a373a2d0a0831a1f5cc82981e499489912f722553f82b6856c900

from __future__ import print_function, division import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import range from sympy.plotting.pygletplot.plot_mode_base import PlotModeBase class PlotSurface(PlotModeBase): default_rot_preset = 'perspective' def _on_calculate_verts(self): self.u_interval = self.intervals[0] self.u_set = list(self.u_interval.frange()) self.v_interval = self.intervals[1] self.v_set = list(self.v_interval.frange()) self.bounds = [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] evaluate = self._get_evaluator() self._calculating_verts_pos = 0.0 self._calculating_verts_len = float( self.u_interval.v_len*self.v_interval.v_len) verts = list() b = self.bounds for u in self.u_set: column = list() for v in self.v_set: try: _e = evaluate(u, v) # calculate vertex except ZeroDivisionError: _e = None if _e is not None: # update bounding box for axis in range(3): b[axis][0] = min([b[axis][0], _e[axis]]) b[axis][1] = max([b[axis][1], _e[axis]]) column.append(_e) self._calculating_verts_pos += 1.0 verts.append(column) for axis in range(3): b[axis][2] = b[axis][1] - b[axis][0] if b[axis][2] == 0.0: b[axis][2] = 1.0 self.verts = verts self.push_wireframe(self.draw_verts(False, False)) self.push_solid(self.draw_verts(False, True)) def _on_calculate_cverts(self): if not self.verts or not self.color: return def set_work_len(n): self._calculating_cverts_len = float(n) def inc_work_pos(): self._calculating_cverts_pos += 1.0 set_work_len(1) self._calculating_cverts_pos = 0 self.cverts = self.color.apply_to_surface(self.verts, self.u_set, self.v_set, set_len=set_work_len, inc_pos=inc_work_pos) self.push_solid(self.draw_verts(True, True)) def calculate_one_cvert(self, u, v): vert = self.verts[u][v] return self.color(vert[0], vert[1], vert[2], self.u_set[u], self.v_set[v]) def draw_verts(self, use_cverts, use_solid_color): def f(): for u in range(1, len(self.u_set)): pgl.glBegin(pgl.GL_QUAD_STRIP) for v in range(len(self.v_set)): pa = self.verts[u - 1][v] pb = self.verts[u][v] if pa is None or pb is None: pgl.glEnd() pgl.glBegin(pgl.GL_QUAD_STRIP) continue if use_cverts: ca = self.cverts[u - 1][v] cb = self.cverts[u][v] if ca is None: ca = (0, 0, 0) if cb is None: cb = (0, 0, 0) else: if use_solid_color: ca = cb = self.default_solid_color else: ca = cb = self.default_wireframe_color pgl.glColor3f(*ca) pgl.glVertex3f(*pa) pgl.glColor3f(*cb) pgl.glVertex3f(*pb) pgl.glEnd() return f

3a4cef03a4b43308a62cd3df32fcf73b3ce65692e6f52fbed938338d631deba5

from __future__ import print_function, division from sympy import Symbol, sympify from sympy.core.compatibility import range, string_types from sympy.core.numbers import Integer class PlotInterval(object): """ """ _v, _v_min, _v_max, _v_steps = None, None, None, None def require_all_args(f): def check(self, *args, **kwargs): for g in [self._v, self._v_min, self._v_max, self._v_steps]: if g is None: raise ValueError("PlotInterval is incomplete.") return f(self, *args, **kwargs) return check def __init__(self, *args): if len(args) == 1: if isinstance(args[0], PlotInterval): self.fill_from(args[0]) return elif isinstance(args[0], string_types): try: args = eval(args[0]) except TypeError: s_eval_error = "Could not interpret string %s." raise ValueError(s_eval_error % (args[0])) elif isinstance(args[0], (tuple, list)): args = args[0] else: raise ValueError("Not an interval.") if not isinstance(args, (tuple, list)) or len(args) > 4: f_error = "PlotInterval must be a tuple or list of length 4 or less." raise ValueError(f_error) args = list(args) if len(args) > 0 and (args[0] is None or isinstance(args[0], Symbol)): self.v = args.pop(0) if len(args) in [2, 3]: self.v_min = args.pop(0) self.v_max = args.pop(0) if len(args) == 1: self.v_steps = args.pop(0) elif len(args) == 1: self.v_steps = args.pop(0) def get_v(self): return self._v def set_v(self, v): if v is None: self._v = None return if not isinstance(v, Symbol): raise ValueError("v must be a sympy Symbol.") self._v = v def get_v_min(self): return self._v_min def set_v_min(self, v_min): if v_min is None: self._v_min = None return try: self._v_min = sympify(v_min) float(self._v_min.evalf()) except TypeError: raise ValueError("v_min could not be interpreted as a number.") def get_v_max(self): return self._v_max def set_v_max(self, v_max): if v_max is None: self._v_max = None return try: self._v_max = sympify(v_max) float(self._v_max.evalf()) except TypeError: raise ValueError("v_max could not be interpreted as a number.") def get_v_steps(self): return self._v_steps def set_v_steps(self, v_steps): if v_steps is None: self._v_steps = None return if isinstance(v_steps, int): v_steps = Integer(v_steps) elif not isinstance(v_steps, Integer): raise ValueError("v_steps must be an int or sympy Integer.") if v_steps <= Integer(0): raise ValueError("v_steps must be positive.") self._v_steps = v_steps @require_all_args def get_v_len(self): return self.v_steps + 1 v = property(get_v, set_v) v_min = property(get_v_min, set_v_min) v_max = property(get_v_max, set_v_max) v_steps = property(get_v_steps, set_v_steps) v_len = property(get_v_len) def fill_from(self, b): if b.v is not None: self.v = b.v if b.v_min is not None: self.v_min = b.v_min if b.v_max is not None: self.v_max = b.v_max if b.v_steps is not None: self.v_steps = b.v_steps @staticmethod def try_parse(*args): """ Returns a PlotInterval if args can be interpreted as such, otherwise None. """ if len(args) == 1 and isinstance(args[0], PlotInterval): return args[0] try: return PlotInterval(*args) except ValueError: return None def _str_base(self): return ",".join([str(self.v), str(self.v_min), str(self.v_max), str(self.v_steps)]) def __repr__(self): """ A string representing the interval in class constructor form. """ return "PlotInterval(%s)" % (self._str_base()) def __str__(self): """ A string representing the interval in list form. """ return "[%s]" % (self._str_base()) @require_all_args def assert_complete(self): pass @require_all_args def vrange(self): """ Yields v_steps+1 sympy numbers ranging from v_min to v_max. """ d = (self.v_max - self.v_min) / self.v_steps for i in range(self.v_steps + 1): a = self.v_min + (d * Integer(i)) yield a @require_all_args def vrange2(self): """ Yields v_steps pairs of sympy numbers ranging from (v_min, v_min + step) to (v_max - step, v_max). """ d = (self.v_max - self.v_min) / self.v_steps a = self.v_min + (d * Integer(0)) for i in range(self.v_steps): b = self.v_min + (d * Integer(i + 1)) yield a, b a = b def frange(self): for i in self.vrange(): yield float(i.evalf())

83f9b6af3ed1419443b8733d48685c5d1071197d037943983631113dd42c8811

from __future__ import print_function, division from sympy import lambdify from sympy.core.numbers import pi from sympy.functions import sin, cos from sympy.plotting.pygletplot.plot_curve import PlotCurve from sympy.plotting.pygletplot.plot_surface import PlotSurface from math import sin as p_sin from math import cos as p_cos def float_vec3(f): def inner(*args): v = f(*args) return float(v[0]), float(v[1]), float(v[2]) return inner class Cartesian2D(PlotCurve): i_vars, d_vars = 'x', 'y' intervals = [[-5, 5, 100]] aliases = ['cartesian'] is_default = True def _get_sympy_evaluator(self): fy = self.d_vars[0] x = self.t_interval.v @float_vec3 def e(_x): return (_x, fy.subs(x, _x), 0.0) return e def _get_lambda_evaluator(self): fy = self.d_vars[0] x = self.t_interval.v return lambdify([x], [x, fy, 0.0]) class Cartesian3D(PlotSurface): i_vars, d_vars = 'xy', 'z' intervals = [[-1, 1, 40], [-1, 1, 40]] aliases = ['cartesian', 'monge'] is_default = True def _get_sympy_evaluator(self): fz = self.d_vars[0] x = self.u_interval.v y = self.v_interval.v @float_vec3 def e(_x, _y): return (_x, _y, fz.subs(x, _x).subs(y, _y)) return e def _get_lambda_evaluator(self): fz = self.d_vars[0] x = self.u_interval.v y = self.v_interval.v return lambdify([x, y], [x, y, fz]) class ParametricCurve2D(PlotCurve): i_vars, d_vars = 't', 'xy' intervals = [[0, 2*pi, 100]] aliases = ['parametric'] is_default = True def _get_sympy_evaluator(self): fx, fy = self.d_vars t = self.t_interval.v @float_vec3 def e(_t): return (fx.subs(t, _t), fy.subs(t, _t), 0.0) return e def _get_lambda_evaluator(self): fx, fy = self.d_vars t = self.t_interval.v return lambdify([t], [fx, fy, 0.0]) class ParametricCurve3D(PlotCurve): i_vars, d_vars = 't', 'xyz' intervals = [[0, 2*pi, 100]] aliases = ['parametric'] is_default = True def _get_sympy_evaluator(self): fx, fy, fz = self.d_vars t = self.t_interval.v @float_vec3 def e(_t): return (fx.subs(t, _t), fy.subs(t, _t), fz.subs(t, _t)) return e def _get_lambda_evaluator(self): fx, fy, fz = self.d_vars t = self.t_interval.v return lambdify([t], [fx, fy, fz]) class ParametricSurface(PlotSurface): i_vars, d_vars = 'uv', 'xyz' intervals = [[-1, 1, 40], [-1, 1, 40]] aliases = ['parametric'] is_default = True def _get_sympy_evaluator(self): fx, fy, fz = self.d_vars u = self.u_interval.v v = self.v_interval.v @float_vec3 def e(_u, _v): return (fx.subs(u, _u).subs(v, _v), fy.subs(u, _u).subs(v, _v), fz.subs(u, _u).subs(v, _v)) return e def _get_lambda_evaluator(self): fx, fy, fz = self.d_vars u = self.u_interval.v v = self.v_interval.v return lambdify([u, v], [fx, fy, fz]) class Polar(PlotCurve): i_vars, d_vars = 't', 'r' intervals = [[0, 2*pi, 100]] aliases = ['polar'] is_default = False def _get_sympy_evaluator(self): fr = self.d_vars[0] t = self.t_interval.v def e(_t): _r = float(fr.subs(t, _t)) return (_r*p_cos(_t), _r*p_sin(_t), 0.0) return e def _get_lambda_evaluator(self): fr = self.d_vars[0] t = self.t_interval.v fx, fy = fr*cos(t), fr*sin(t) return lambdify([t], [fx, fy, 0.0]) class Cylindrical(PlotSurface): i_vars, d_vars = 'th', 'r' intervals = [[0, 2*pi, 40], [-1, 1, 20]] aliases = ['cylindrical', 'polar'] is_default = False def _get_sympy_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v h = self.v_interval.v def e(_t, _h): _r = float(fr.subs(t, _t).subs(h, _h)) return (_r*p_cos(_t), _r*p_sin(_t), _h) return e def _get_lambda_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v h = self.v_interval.v fx, fy = fr*cos(t), fr*sin(t) return lambdify([t, h], [fx, fy, h]) class Spherical(PlotSurface): i_vars, d_vars = 'tp', 'r' intervals = [[0, 2*pi, 40], [0, pi, 20]] aliases = ['spherical'] is_default = False def _get_sympy_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v p = self.v_interval.v def e(_t, _p): _r = float(fr.subs(t, _t).subs(p, _p)) return (_r*p_cos(_t)*p_sin(_p), _r*p_sin(_t)*p_sin(_p), _r*p_cos(_p)) return e def _get_lambda_evaluator(self): fr = self.d_vars[0] t = self.u_interval.v p = self.v_interval.v fx = fr * cos(t) * sin(p) fy = fr * sin(t) * sin(p) fz = fr * cos(p) return lambdify([t, p], [fx, fy, fz]) Cartesian2D._register() Cartesian3D._register() ParametricCurve2D._register() ParametricCurve3D._register() ParametricSurface._register() Polar._register() Cylindrical._register() Spherical._register()

7082237a33ebdb621078e1387306cbb88dca200b23de9242083a25a4ab00b4ed

from __future__ import print_function, division try: from ctypes import c_float, c_int, c_double except ImportError: pass import pyglet.gl as pgl from sympy.core import S from sympy.core.compatibility import range, string_types def get_model_matrix(array_type=c_float, glGetMethod=pgl.glGetFloatv): """ Returns the current modelview matrix. """ m = (array_type*16)() glGetMethod(pgl.GL_MODELVIEW_MATRIX, m) return m def get_projection_matrix(array_type=c_float, glGetMethod=pgl.glGetFloatv): """ Returns the current modelview matrix. """ m = (array_type*16)() glGetMethod(pgl.GL_PROJECTION_MATRIX, m) return m def get_viewport(): """ Returns the current viewport. """ m = (c_int*4)() pgl.glGetIntegerv(pgl.GL_VIEWPORT, m) return m def get_direction_vectors(): m = get_model_matrix() return ((m[0], m[4], m[8]), (m[1], m[5], m[9]), (m[2], m[6], m[10])) def get_view_direction_vectors(): m = get_model_matrix() return ((m[0], m[1], m[2]), (m[4], m[5], m[6]), (m[8], m[9], m[10])) def get_basis_vectors(): return ((1, 0, 0), (0, 1, 0), (0, 0, 1)) def screen_to_model(x, y, z): m = get_model_matrix(c_double, pgl.glGetDoublev) p = get_projection_matrix(c_double, pgl.glGetDoublev) w = get_viewport() mx, my, mz = c_double(), c_double(), c_double() pgl.gluUnProject(x, y, z, m, p, w, mx, my, mz) return float(mx.value), float(my.value), float(mz.value) def model_to_screen(x, y, z): m = get_model_matrix(c_double, pgl.glGetDoublev) p = get_projection_matrix(c_double, pgl.glGetDoublev) w = get_viewport() mx, my, mz = c_double(), c_double(), c_double() pgl.gluProject(x, y, z, m, p, w, mx, my, mz) return float(mx.value), float(my.value), float(mz.value) def vec_subs(a, b): return tuple(a[i] - b[i] for i in range(len(a))) def billboard_matrix(): """ Removes rotational components of current matrix so that primitives are always drawn facing the viewer. |1|0|0|x| |0|1|0|x| |0|0|1|x| (x means left unchanged) |x|x|x|x| """ m = get_model_matrix() # XXX: for i in range(11): m[i] = i ? m[0] = 1 m[1] = 0 m[2] = 0 m[4] = 0 m[5] = 1 m[6] = 0 m[8] = 0 m[9] = 0 m[10] = 1 pgl.glLoadMatrixf(m) def create_bounds(): return [[S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0], [S.Infinity, -S.Infinity, 0]] def update_bounds(b, v): if v is None: return for axis in range(3): b[axis][0] = min([b[axis][0], v[axis]]) b[axis][1] = max([b[axis][1], v[axis]]) def interpolate(a_min, a_max, a_ratio): return a_min + a_ratio * (a_max - a_min) def rinterpolate(a_min, a_max, a_value): a_range = a_max - a_min if a_max == a_min: a_range = 1.0 return (a_value - a_min) / float(a_range) def interpolate_color(color1, color2, ratio): return tuple(interpolate(color1[i], color2[i], ratio) for i in range(3)) def scale_value(v, v_min, v_len): return (v - v_min) / v_len def scale_value_list(flist): v_min, v_max = min(flist), max(flist) v_len = v_max - v_min return list(scale_value(f, v_min, v_len) for f in flist) def strided_range(r_min, r_max, stride, max_steps=50): o_min, o_max = r_min, r_max if abs(r_min - r_max) < 0.001: return [] try: range(int(r_min - r_max)) except (TypeError, OverflowError): return [] if r_min > r_max: raise ValueError("r_min can not be greater than r_max") r_min_s = (r_min % stride) r_max_s = stride - (r_max % stride) if abs(r_max_s - stride) < 0.001: r_max_s = 0.0 r_min -= r_min_s r_max += r_max_s r_steps = int((r_max - r_min)/stride) if max_steps and r_steps > max_steps: return strided_range(o_min, o_max, stride*2) return [r_min] + list(r_min + e*stride for e in range(1, r_steps + 1)) + [r_max] def parse_option_string(s): if not isinstance(s, string_types): return None options = {} for token in s.split(';'): pieces = token.split('=') if len(pieces) == 1: option, value = pieces[0], "" elif len(pieces) == 2: option, value = pieces else: raise ValueError("Plot option string '%s' is malformed." % (s)) options[option.strip()] = value.strip() return options def dot_product(v1, v2): return sum(v1[i]*v2[i] for i in range(3)) def vec_sub(v1, v2): return tuple(v1[i] - v2[i] for i in range(3)) def vec_mag(v): return sum(v[i]**2 for i in range(3))**(0.5)

a0ba992d23f237e107570f3aa608ce6954e8e3e859cedeaefd8da6677b7b5bfe

from __future__ import print_function, division from time import clock import pyglet.gl as pgl from sympy.plotting.pygletplot.managed_window import ManagedWindow from sympy.plotting.pygletplot.plot_camera import PlotCamera from sympy.plotting.pygletplot.plot_controller import PlotController class PlotWindow(ManagedWindow): def __init__(self, plot, antialiasing=True, ortho=False, invert_mouse_zoom=False, linewidth=1.5, caption="SymPy Plot", **kwargs): """ Named Arguments =============== antialiasing = True True OR False ortho = False True OR False invert_mouse_zoom = False True OR False """ self.plot = plot self.camera = None self._calculating = False self.antialiasing = antialiasing self.ortho = ortho self.invert_mouse_zoom = invert_mouse_zoom self.linewidth = linewidth self.title = caption self.last_caption_update = 0 self.caption_update_interval = 0.2 self.drawing_first_object = True super(PlotWindow, self).__init__(**kwargs) def setup(self): self.camera = PlotCamera(self, ortho=self.ortho) self.controller = PlotController(self, invert_mouse_zoom=self.invert_mouse_zoom) self.push_handlers(self.controller) pgl.glClearColor(1.0, 1.0, 1.0, 0.0) pgl.glClearDepth(1.0) pgl.glDepthFunc(pgl.GL_LESS) pgl.glEnable(pgl.GL_DEPTH_TEST) pgl.glEnable(pgl.GL_LINE_SMOOTH) pgl.glShadeModel(pgl.GL_SMOOTH) pgl.glLineWidth(self.linewidth) pgl.glEnable(pgl.GL_BLEND) pgl.glBlendFunc(pgl.GL_SRC_ALPHA, pgl.GL_ONE_MINUS_SRC_ALPHA) if self.antialiasing: pgl.glHint(pgl.GL_LINE_SMOOTH_HINT, pgl.GL_NICEST) pgl.glHint(pgl.GL_POLYGON_SMOOTH_HINT, pgl.GL_NICEST) self.camera.setup_projection() def on_resize(self, w, h): super(PlotWindow, self).on_resize(w, h) if self.camera is not None: self.camera.setup_projection() def update(self, dt): self.controller.update(dt) def draw(self): self.plot._render_lock.acquire() self.camera.apply_transformation() calc_verts_pos, calc_verts_len = 0, 0 calc_cverts_pos, calc_cverts_len = 0, 0 should_update_caption = (clock() - self.last_caption_update > self.caption_update_interval) if len(self.plot._functions.values()) == 0: self.drawing_first_object = True try: dict.iteritems except AttributeError: # Python 3 iterfunctions = iter(self.plot._functions.values()) else: # Python 2 iterfunctions = self.plot._functions.itervalues() for r in iterfunctions: if self.drawing_first_object: self.camera.set_rot_preset(r.default_rot_preset) self.drawing_first_object = False pgl.glPushMatrix() r._draw() pgl.glPopMatrix() # might as well do this while we are # iterating and have the lock rather # than locking and iterating twice # per frame: if should_update_caption: try: if r.calculating_verts: calc_verts_pos += r.calculating_verts_pos calc_verts_len += r.calculating_verts_len if r.calculating_cverts: calc_cverts_pos += r.calculating_cverts_pos calc_cverts_len += r.calculating_cverts_len except ValueError: pass for r in self.plot._pobjects: pgl.glPushMatrix() r._draw() pgl.glPopMatrix() if should_update_caption: self.update_caption(calc_verts_pos, calc_verts_len, calc_cverts_pos, calc_cverts_len) self.last_caption_update = clock() if self.plot._screenshot: self.plot._screenshot._execute_saving() self.plot._render_lock.release() def update_caption(self, calc_verts_pos, calc_verts_len, calc_cverts_pos, calc_cverts_len): caption = self.title if calc_verts_len or calc_cverts_len: caption += " (calculating" if calc_verts_len > 0: p = (calc_verts_pos / calc_verts_len) * 100 caption += " vertices %i%%" % (p) if calc_cverts_len > 0: p = (calc_cverts_pos / calc_cverts_len) * 100 caption += " colors %i%%" % (p) caption += ")" if self.caption != caption: self.set_caption(caption)

b42587ae5bc1653676c961b8af5316f0e186562ef427694c92ace3143e7050c3

from __future__ import print_function, division import pyglet.gl as pgl from pyglet import font from sympy.core import S from sympy.core.compatibility import is_sequence from sympy.plotting.pygletplot.plot_object import PlotObject from sympy.plotting.pygletplot.util import billboard_matrix, dot_product, \ get_direction_vectors, strided_range, vec_mag, vec_sub class PlotAxes(PlotObject): def __init__(self, *args, **kwargs): # initialize style parameter style = kwargs.pop('style', '').lower() # allow alias kwargs to override style kwarg if kwargs.pop('none', None) is not None: style = 'none' if kwargs.pop('frame', None) is not None: style = 'frame' if kwargs.pop('box', None) is not None: style = 'box' if kwargs.pop('ordinate', None) is not None: style = 'ordinate' if style in ['', 'ordinate']: self._render_object = PlotAxesOrdinate(self) elif style in ['frame', 'box']: self._render_object = PlotAxesFrame(self) elif style in ['none']: self._render_object = None else: raise ValueError(("Unrecognized axes style %s.") % (style)) # initialize stride parameter stride = kwargs.pop('stride', 0.25) try: stride = eval(stride) except TypeError: pass if is_sequence(stride): if len(stride) != 3: raise ValueError("length should be equal to 3") self._stride = stride else: self._stride = [stride, stride, stride] self._tick_length = float(kwargs.pop('tick_length', 0.1)) # setup bounding box and ticks self._origin = [0, 0, 0] self.reset_bounding_box() def flexible_boolean(input, default): if input in [True, False]: return input if input in ['f', 'F', 'false', 'False']: return False if input in ['t', 'T', 'true', 'True']: return True return default # initialize remaining parameters self.visible = flexible_boolean(kwargs.pop('visible', ''), True) self._overlay = flexible_boolean(kwargs.pop('overlay', ''), True) self._colored = flexible_boolean(kwargs.pop('colored', ''), False) self._label_axes = flexible_boolean( kwargs.pop('label_axes', ''), False) self._label_ticks = flexible_boolean( kwargs.pop('label_ticks', ''), True) # setup label font self.font_face = kwargs.pop('font_face', 'Arial') self.font_size = kwargs.pop('font_size', 28) # this is also used to reinit the # font on window close/reopen self.reset_resources() def reset_resources(self): self.label_font = None def reset_bounding_box(self): self._bounding_box = [[None, None], [None, None], [None, None]] self._axis_ticks = [[], [], []] def draw(self): if self._render_object: pgl.glPushAttrib(pgl.GL_ENABLE_BIT | pgl.GL_POLYGON_BIT | pgl.GL_DEPTH_BUFFER_BIT) if self._overlay: pgl.glDisable(pgl.GL_DEPTH_TEST) self._render_object.draw() pgl.glPopAttrib() def adjust_bounds(self, child_bounds): b = self._bounding_box c = child_bounds for i in [0, 1, 2]: if abs(c[i][0]) is S.Infinity or abs(c[i][1]) is S.Infinity: continue b[i][0] = c[i][0] if b[i][0] is None else min([b[i][0], c[i][0]]) b[i][1] = c[i][1] if b[i][1] is None else max([b[i][1], c[i][1]]) self._bounding_box = b self._recalculate_axis_ticks(i) def _recalculate_axis_ticks(self, axis): b = self._bounding_box if b[axis][0] is None or b[axis][1] is None: self._axis_ticks[axis] = [] else: self._axis_ticks[axis] = strided_range(b[axis][0], b[axis][1], self._stride[axis]) def toggle_visible(self): self.visible = not self.visible def toggle_colors(self): self._colored = not self._colored class PlotAxesBase(PlotObject): def __init__(self, parent_axes): self._p = parent_axes def draw(self): color = [([0.2, 0.1, 0.3], [0.2, 0.1, 0.3], [0.2, 0.1, 0.3]), ([0.9, 0.3, 0.5], [0.5, 1.0, 0.5], [0.3, 0.3, 0.9])][self._p._colored] self.draw_background(color) self.draw_axis(2, color[2]) self.draw_axis(1, color[1]) self.draw_axis(0, color[0]) def draw_background(self, color): pass # optional def draw_axis(self, axis, color): raise NotImplementedError() def draw_text(self, text, position, color, scale=1.0): if len(color) == 3: color = (color[0], color[1], color[2], 1.0) if self._p.label_font is None: self._p.label_font = font.load(self._p.font_face, self._p.font_size, bold=True, italic=False) label = font.Text(self._p.label_font, text, color=color, valign=font.Text.BASELINE, halign=font.Text.CENTER) pgl.glPushMatrix() pgl.glTranslatef(*position) billboard_matrix() scale_factor = 0.005 * scale pgl.glScalef(scale_factor, scale_factor, scale_factor) pgl.glColor4f(0, 0, 0, 0) label.draw() pgl.glPopMatrix() def draw_line(self, v, color): o = self._p._origin pgl.glBegin(pgl.GL_LINES) pgl.glColor3f(*color) pgl.glVertex3f(v[0][0] + o[0], v[0][1] + o[1], v[0][2] + o[2]) pgl.glVertex3f(v[1][0] + o[0], v[1][1] + o[1], v[1][2] + o[2]) pgl.glEnd() class PlotAxesOrdinate(PlotAxesBase): def __init__(self, parent_axes): super(PlotAxesOrdinate, self).__init__(parent_axes) def draw_axis(self, axis, color): ticks = self._p._axis_ticks[axis] radius = self._p._tick_length / 2.0 if len(ticks) < 2: return # calculate the vector for this axis axis_lines = [[0, 0, 0], [0, 0, 0]] axis_lines[0][axis], axis_lines[1][axis] = ticks[0], ticks[-1] axis_vector = vec_sub(axis_lines[1], axis_lines[0]) # calculate angle to the z direction vector pos_z = get_direction_vectors()[2] d = abs(dot_product(axis_vector, pos_z)) d = d / vec_mag(axis_vector) # don't draw labels if we're looking down the axis labels_visible = abs(d - 1.0) > 0.02 # draw the ticks and labels for tick in ticks: self.draw_tick_line(axis, color, radius, tick, labels_visible) # draw the axis line and labels self.draw_axis_line(axis, color, ticks[0], ticks[-1], labels_visible) def draw_axis_line(self, axis, color, a_min, a_max, labels_visible): axis_line = [[0, 0, 0], [0, 0, 0]] axis_line[0][axis], axis_line[1][axis] = a_min, a_max self.draw_line(axis_line, color) if labels_visible: self.draw_axis_line_labels(axis, color, axis_line) def draw_axis_line_labels(self, axis, color, axis_line): if not self._p._label_axes: return axis_labels = [axis_line[0][::], axis_line[1][::]] axis_labels[0][axis] -= 0.3 axis_labels[1][axis] += 0.3 a_str = ['X', 'Y', 'Z'][axis] self.draw_text("-" + a_str, axis_labels[0], color) self.draw_text("+" + a_str, axis_labels[1], color) def draw_tick_line(self, axis, color, radius, tick, labels_visible): tick_axis = {0: 1, 1: 0, 2: 1}[axis] tick_line = [[0, 0, 0], [0, 0, 0]] tick_line[0][axis] = tick_line[1][axis] = tick tick_line[0][tick_axis], tick_line[1][tick_axis] = -radius, radius self.draw_line(tick_line, color) if labels_visible: self.draw_tick_line_label(axis, color, radius, tick) def draw_tick_line_label(self, axis, color, radius, tick): if not self._p._label_axes: return tick_label_vector = [0, 0, 0] tick_label_vector[axis] = tick tick_label_vector[{0: 1, 1: 0, 2: 1}[axis]] = [-1, 1, 1][ axis] * radius * 3.5 self.draw_text(str(tick), tick_label_vector, color, scale=0.5) class PlotAxesFrame(PlotAxesBase): def __init__(self, parent_axes): super(PlotAxesFrame, self).__init__(parent_axes) def draw_background(self, color): pass def draw_axis(self, axis, color): raise NotImplementedError()

b7491187f3548a4aa6457af8582722b52317c0e6897681d90167239e2428f068

#!/usr/bin/env python """ Program to test that all methods/functions have at least one example doctest. Also checks if docstrings are imported into Sphinx. For this to work, the Sphinx docs need to be built first. Use "cd doc; make html" to build the Sphinx docs. Usage: ./bin/coverage_doctest.py sympy/core or ./bin/coverage_doctest.py sympy/core/basic.py If no arguments are given, all files in sympy/ are checked. """ from __future__ import print_function import os import sys import inspect from argparse import ArgumentParser, RawDescriptionHelpFormatter try: from HTMLParser import HTMLParser except ImportError: # It's html.parser in Python 3 from html.parser import HTMLParser from sympy.utilities.misc import filldedent # Load color templates, used from sympy/utilities/runtests.py color_templates = ( ("Black", "0;30"), ("Red", "0;31"), ("Green", "0;32"), ("Brown", "0;33"), ("Blue", "0;34"), ("Purple", "0;35"), ("Cyan", "0;36"), ("LightGray", "0;37"), ("DarkGray", "1;30"), ("LightRed", "1;31"), ("LightGreen", "1;32"), ("Yellow", "1;33"), ("LightBlue", "1;34"), ("LightPurple", "1;35"), ("LightCyan", "1;36"), ("White", "1;37"), ) colors = {} for name, value in color_templates: colors[name] = value c_normal = '\033[0m' c_color = '\033[%sm' def print_header(name, underline=None, color=None): print() if color: print("%s%s%s" % (c_color % colors[color], name, c_normal)) else: print(name) if underline and not color: print(underline*len(name)) def print_coverage(module_path, c, c_md, c_mdt, c_idt, c_sph, f, f_md, f_mdt, f_idt, f_sph, score, total_doctests, total_members, sphinx_score, total_sphinx, verbose=False, no_color=False, sphinx=True): """ Prints details (depending on verbose) of a module """ doctest_color = "Brown" sphinx_color = "DarkGray" less_100_color = "Red" less_50_color = "LightRed" equal_100_color = "Green" big_header_color = "LightPurple" small_header_color = "Purple" if no_color: score_string = "Doctests: %s%% (%s of %s)" % (score, total_doctests, total_members) elif score < 100: if score < 50: score_string = "%sDoctests:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[doctest_color], c_normal, c_color % colors[less_50_color], score, total_doctests, total_members, c_normal) else: score_string = "%sDoctests:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[doctest_color], c_normal, c_color % colors[less_100_color], score, total_doctests, total_members, c_normal) else: score_string = "%sDoctests:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[doctest_color], c_normal, c_color % colors[equal_100_color], score, total_doctests, total_members, c_normal) if sphinx: if no_color: sphinx_score_string = "Sphinx: %s%% (%s of %s)" % (sphinx_score, total_members - total_sphinx, total_members) elif sphinx_score < 100: if sphinx_score < 50: sphinx_score_string = "%sSphinx:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[sphinx_color], c_normal, c_color % colors[less_50_color], sphinx_score, total_members - total_sphinx, total_members, c_normal) else: sphinx_score_string = "%sSphinx:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[sphinx_color], c_normal, c_color % colors[less_100_color], sphinx_score, total_members - total_sphinx, total_members, c_normal) else: sphinx_score_string = "%sSphinx:%s %s%s%% (%s of %s)%s" % \ (c_color % colors[sphinx_color], c_normal, c_color % colors[equal_100_color], sphinx_score, total_members - total_sphinx, total_members, c_normal) if verbose: print('\n' + '-'*70) print(module_path) print('-'*70) else: if sphinx: print("%s: %s %s" % (module_path, score_string, sphinx_score_string)) else: print("%s: %s" % (module_path, score_string)) if verbose: print_header('CLASSES', '*', not no_color and big_header_color) if not c: print_header('No classes found!') else: if c_md: print_header('Missing docstrings', '-', not no_color and small_header_color) for md in c_md: print(' * ' + md) if c_mdt: print_header('Missing doctests', '-', not no_color and small_header_color) for md in c_mdt: print(' * ' + md) if c_idt: # Use "# indirect doctest" in the docstring to # suppress this warning. print_header('Indirect doctests', '-', not no_color and small_header_color) for md in c_idt: print(' * ' + md) print('\n Use \"# indirect doctest\" in the docstring to suppress this warning') if c_sph: print_header('Not imported into Sphinx', '-', not no_color and small_header_color) for md in c_sph: print(' * ' + md) print_header('FUNCTIONS', '*', not no_color and big_header_color) if not f: print_header('No functions found!') else: if f_md: print_header('Missing docstrings', '-', not no_color and small_header_color) for md in f_md: print(' * ' + md) if f_mdt: print_header('Missing doctests', '-', not no_color and small_header_color) for md in f_mdt: print(' * ' + md) if f_idt: print_header('Indirect doctests', '-', not no_color and small_header_color) for md in f_idt: print(' * ' + md) print('\n Use \"# indirect doctest\" in the docstring to suppress this warning') if f_sph: print_header('Not imported into Sphinx', '-', not no_color and small_header_color) for md in f_sph: print(' * ' + md) if verbose: print('\n' + '-'*70) print(score_string) if sphinx: print(sphinx_score_string) print('-'*70) def _is_indirect(member, doc): """ Given string repr of doc and member checks if the member contains indirect documentation """ d = member in doc e = 'indirect doctest' in doc if not d and not e: return True else: return False def _get_arg_list(name, fobj): """ Given a function object, constructs a list of arguments and their defaults. Takes care of varargs and kwargs """ trunc = 20 # Sometimes argument length can be huge argspec = inspect.getargspec(fobj) arg_list = [] if argspec.args: for arg in argspec.args: arg_list.append(str(arg)) arg_list.reverse() # Now add the defaults if argspec.defaults: for i in range(len(argspec.defaults)): arg_list[i] = str(arg_list[i]) + '=' + str(argspec.defaults[-i]) # Get the list in right order arg_list.reverse() # Add var args if argspec.varargs: arg_list.append(argspec.varargs) if argspec.keywords: arg_list.append(argspec.keywords) # Truncate long arguments arg_list = [x[:trunc] for x in arg_list] # Construct the parameter string (enclosed in brackets) str_param = "%s(%s)" % (name, ', '.join(arg_list)) return str_param def get_mod_name(path, base): """ Gets a module name, given the path of file/dir and base dir of sympy """ rel_path = os.path.relpath(path, base) # Remove the file extension rel_path, ign = os.path.splitext(rel_path) # Replace separators by . for module path file_module = "" h, t = os.path.split(rel_path) while h or t: if t: file_module = t + '.' + file_module h, t = os.path.split(h) return file_module[:-1] class FindInSphinx(HTMLParser): is_imported = [] def handle_starttag(self, tag, attr): a = dict(attr) if tag == "div" and a.get('class', None) == "viewcode-block": self.is_imported.append(a['id']) def find_sphinx(name, mod_path, found={}): if mod_path in found: # Cache results return name in found[mod_path] doc_path = mod_path.split('.') doc_path[-1] += '.html' sphinx_path = os.path.join(sympy_top, 'doc', '_build', 'html', '_modules', *doc_path) if not os.path.exists(sphinx_path): return False with open(sphinx_path) as f: html_txt = f.read() p = FindInSphinx() p.feed(html_txt) found[mod_path] = p.is_imported return name in p.is_imported def process_function(name, c_name, b_obj, mod_path, f_sk, f_md, f_mdt, f_idt, f_has_doctest, sk_list, sph, sphinx=True): """ Processes a function to get information regarding documentation. It is assume that the function calling this subrouting has already verified that it is a valid module function. """ if name in sk_list: return False, False # We add in the end, as inspect.getsourcelines is slow add_md = False add_mdt = False add_idt = False in_sphinx = True f_doctest = False function = False if inspect.isclass(b_obj): obj = getattr(b_obj, name) obj_name = c_name + '.' + name else: obj = b_obj obj_name = name full_name = _get_arg_list(name, obj) if name.startswith('_'): f_sk.append(full_name) else: doc = obj.__doc__ if type(doc) is str: if not doc: add_md = True elif not '>>>' in doc: add_mdt = True elif _is_indirect(name, doc): add_idt = True else: f_doctest = True elif doc is None: # this was a function defined in the docstring f_doctest = True else: assert None, type(doc) function = True if sphinx: in_sphinx = find_sphinx(obj_name, mod_path) if add_md or add_mdt or add_idt or not in_sphinx: try: line_no = inspect.getsourcelines(obj)[1] except IOError: # Raised when source does not exist # which means the function is not there. return False, False full_name = "LINE %d: %s" % (line_no, full_name) if add_md: f_md.append(full_name) elif add_mdt: f_mdt.append(full_name) elif add_idt: f_idt.append(full_name) if not in_sphinx: sph.append(full_name) return f_doctest, function def process_class(c_name, obj, c_sk, c_md, c_mdt, c_idt, c_has_doctest, mod_path, sph, sphinx=True): """ Extracts information about the class regarding documentation. It is assumed that the function calling this subroutine has already checked that the class is valid. """ # Skip class case if c_name.startswith('_'): c_sk.append(c_name) return False, False, None c = False c_dt = False # Get the line number of class try: source, line_no = inspect.getsourcelines(obj) except IOError: # Raised when source does not exist # which means the class is not there. return False, False, None c = True full_name = "LINE %d: %s" % (line_no, c_name) doc = obj.__doc__ if type(doc) is str: if not doc: c_md.append(full_name) elif not '>>>' in doc: c_mdt.append(full_name) elif _is_indirect(c_name, doc): c_idt.append(full_name) else: c_dt = True c_has_doctest.append(full_name) elif doc is None: # this was a class defined in the docstring c_dt = True c_has_doctest.append(full_name) else: assert None, type(doc) in_sphinx = False if sphinx: in_sphinx = find_sphinx(c_name, mod_path) if not in_sphinx: sph.append(full_name) return c_dt, c, source def coverage(module_path, verbose=False, no_color=False, sphinx=True): """ Given a module path, builds an index of all classes and functions contained. It then goes through each of the classes/functions to get the docstring and doctest coverage of the module. """ # Import the package and find members m = None try: __import__(module_path) m = sys.modules[module_path] except Exception as a: # Most likely cause, absence of __init__ print("%s could not be loaded due to %s." % (module_path, repr(a))) return 0, 0, 0 c_skipped = [] c_md = [] c_mdt = [] c_has_doctest = [] c_idt = [] classes = 0 c_doctests = 0 c_sph = [] f_skipped = [] f_md = [] f_mdt = [] f_has_doctest = [] f_idt = [] functions = 0 f_doctests = 0 f_sph = [] skip_members = ['__abstractmethods__'] # Get the list of members m_members = dir(m) for member in m_members: # Check for skipped functions first, they throw nasty errors # when combined with getattr if member in skip_members: continue # Identify if the member (class/def) is a part of this module obj = getattr(m, member) obj_mod = inspect.getmodule(obj) # Function not a part of this module if not obj_mod or not obj_mod.__name__ == module_path: continue # If it's a function if inspect.isfunction(obj) or inspect.ismethod(obj): f_dt, f = process_function(member, '', obj, module_path, f_skipped, f_md, f_mdt, f_idt, f_has_doctest, skip_members, f_sph, sphinx=sphinx) if f: functions += 1 if f_dt: f_doctests += 1 # If it's a class, look at it's methods too elif inspect.isclass(obj): # Process the class first c_dt, c, source = process_class(member, obj, c_skipped, c_md, c_mdt, c_idt, c_has_doctest, module_path, c_sph, sphinx=sphinx) if not c: continue else: classes += 1 if c_dt: c_doctests += 1 # Iterate through it's members for f_name in obj.__dict__: if f_name in skip_members or f_name.startswith('_'): continue # Check if def funcname appears in source if not ("def " + f_name) in ' '.join(source): continue # Identify the module of the current class member f_obj = getattr(obj, f_name) obj_mod = inspect.getmodule(f_obj) # Function not a part of this module if not obj_mod or not obj_mod.__name__ == module_path: continue # If it's a function if inspect.isfunction(f_obj) or inspect.ismethod(f_obj): f_dt, f = process_function(f_name, member, obj, module_path, f_skipped, f_md, f_mdt, f_idt, f_has_doctest, skip_members, f_sph, sphinx=sphinx) if f: functions += 1 if f_dt: f_doctests += 1 # Evaluate the percent coverage total_doctests = c_doctests + f_doctests total_members = classes + functions if total_members: score = 100 * float(total_doctests) / (total_members) else: score = 100 score = int(score) if sphinx: total_sphinx = len(c_sph) + len(f_sph) if total_members: sphinx_score = 100 - 100 * float(total_sphinx) / total_members else: sphinx_score = 100 sphinx_score = int(sphinx_score) else: total_sphinx = 0 sphinx_score = 0 # Sort functions/classes by line number c_md = sorted(c_md, key=lambda x: int(x.split()[1][:-1])) c_mdt = sorted(c_mdt, key=lambda x: int(x.split()[1][:-1])) c_idt = sorted(c_idt, key=lambda x: int(x.split()[1][:-1])) f_md = sorted(f_md, key=lambda x: int(x.split()[1][:-1])) f_mdt = sorted(f_mdt, key=lambda x: int(x.split()[1][:-1])) f_idt = sorted(f_idt, key=lambda x: int(x.split()[1][:-1])) print_coverage(module_path, classes, c_md, c_mdt, c_idt, c_sph, functions, f_md, f_mdt, f_idt, f_sph, score, total_doctests, total_members, sphinx_score, total_sphinx, verbose=verbose, no_color=no_color, sphinx=sphinx) return total_doctests, total_sphinx, total_members def go(sympy_top, file, verbose=False, no_color=False, exact=True, sphinx=True): # file names containing any string in skip_paths will be skipped, skip_paths = [] if os.path.isdir(file): doctests, total_sphinx, num_functions = 0, 0, 0 for F in os.listdir(file): _doctests, _total_sphinx, _num_functions = go(sympy_top, '%s/%s' % (file, F), verbose=verbose, no_color=no_color, exact=False, sphinx=sphinx) doctests += _doctests total_sphinx += _total_sphinx num_functions += _num_functions return doctests, total_sphinx, num_functions if (not (file.endswith('.py') or file.endswith('.pyx')) or file.endswith('__init__.py') or not exact and ('test_' in file or 'bench_' in file or any(name in file for name in skip_paths))): return 0, 0, 0 if not os.path.exists(file): print("File(%s does not exist." % file) sys.exit(1) # Relpath for constructing the module name return coverage(get_mod_name(file, sympy_top), verbose=verbose, no_color=no_color, sphinx=sphinx) if __name__ == "__main__": bintest_dir = os.path.abspath(os.path.dirname(__file__)) # bin/cover... sympy_top = os.path.split(bintest_dir)[0] # ../ sympy_dir = os.path.join(sympy_top, 'sympy') # ../sympy/ if os.path.isdir(sympy_dir): sys.path.insert(0, sympy_top) usage = "usage: ./bin/doctest_coverage.py PATHS" parser = ArgumentParser( description=__doc__, usage=usage, formatter_class=RawDescriptionHelpFormatter, ) parser.add_argument("path", nargs='*', default=[os.path.join(sympy_top, 'sympy')]) parser.add_argument("-v", "--verbose", action="store_true", dest="verbose", default=False) parser.add_argument("--no-colors", action="store_true", dest="no_color", help="use no colors", default=False) parser.add_argument("--no-sphinx", action="store_false", dest="sphinx", help="don't report Sphinx coverage", default=True) args = parser.parse_args() if args.sphinx and not os.path.exists(os.path.join(sympy_top, 'doc', '_build', 'html')): print(filldedent(""" Cannot check Sphinx coverage without a documentation build. To build the docs, run "cd doc; make html". To skip checking Sphinx coverage, pass --no-sphinx. """)) sys.exit(1) full_coverage = True for file in args.path: file = os.path.normpath(file) print('DOCTEST COVERAGE for %s' % (file)) print('='*70) print() doctests, total_sphinx, num_functions = go(sympy_top, file, verbose=args.verbose, no_color=args.no_color, sphinx=args.sphinx) if num_functions == 0: score = 100 sphinx_score = 100 else: score = 100 * float(doctests) / num_functions score = int(score) if doctests < num_functions: full_coverage = False if args.sphinx: sphinx_score = 100 - 100 * float(total_sphinx) / num_functions sphinx_score = int(sphinx_score) if total_sphinx > 0: full_coverage = False print() print('='*70) if args.no_color: print("TOTAL DOCTEST SCORE for %s: %s%% (%s of %s)" % \ (get_mod_name(file, sympy_top), score, doctests, num_functions)) elif score < 100: print("TOTAL DOCTEST SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Red"]), score, doctests, num_functions, c_normal)) else: print("TOTAL DOCTEST SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Green"]), score, doctests, num_functions, c_normal)) if args.sphinx: if args.no_color: print("TOTAL SPHINX SCORE for %s: %s%% (%s of %s)" % \ (get_mod_name(file, sympy_top), sphinx_score, num_functions - total_sphinx, num_functions)) elif sphinx_score < 100: print("TOTAL SPHINX SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Red"]), sphinx_score, num_functions - total_sphinx, num_functions, c_normal)) else: print("TOTAL SPHINX SCORE for %s: %s%s%% (%s of %s)%s" % \ (get_mod_name(file, sympy_top), c_color % (colors["Green"]), sphinx_score, num_functions - total_sphinx, num_functions, c_normal)) print() sys.exit(not full_coverage)

d9828efdbac58756521d0d2bb11e426760659d60dd63ca2cbac3a4efed9d32df

#!/usr/bin/env python """ Script to generate test coverage reports. Usage: $ bin/coverage_report.py This will create a directory covhtml with the coverage reports. To restrict the analysis to a directory, you just need to pass its name as argument. For example: $ bin/coverage_report.py sympy/logic runs only the tests in sympy/logic/ and reports only on the modules in sympy/logic/. To also run slow tests use --slow option. You can also get a report on the parts of the whole sympy code covered by the tests in sympy/logic/ by following up the previous command with $ bin/coverage_report.py -c """ from __future__ import print_function import os import re import sys from argparse import ArgumentParser minver = '3.4' try: import coverage if coverage.__version__ < minver: raise ImportError except ImportError: print( "You need to install module coverage (version %s or newer required).\n" "See https://coverage.readthedocs.io/en/latest/ or \n" "https://launchpad.net/ubuntu/+source/python-coverage/" % minver) sys.exit(-1) omit_dir_patterns = ['.*tests', 'benchmark', 'examples', 'pyglet', 'test_external'] omit_dir_re = re.compile(r'|'.join(omit_dir_patterns)) source_re = re.compile(r'.*\.py$') def generate_covered_files(top_dir): for dirpath, dirnames, filenames in os.walk(top_dir): omit_dirs = [dirn for dirn in dirnames if omit_dir_re.match(dirn)] for x in omit_dirs: dirnames.remove(x) for filename in filenames: if source_re.match(filename): yield os.path.join(dirpath, filename) def make_report( test_args, source_dir='sympy/', report_dir='covhtml', use_cache=False, slow=False ): # code adapted from /bin/test from get_sympy import path_hack sympy_top = path_hack() os.chdir(sympy_top) cov = coverage.coverage() cov.exclude("raise NotImplementedError") cov.exclude("def canonize") # this should be "@decorated" cov.exclude("def __mathml__") if use_cache: cov.load() else: cov.erase() cov.start() import sympy sympy.test(*test_args, subprocess=False, slow=slow) #sympy.doctest() # coverage doesn't play well with doctests cov.stop() try: cov.save() except PermissionError: import warnings warnings.warn( "PermissionError has been raised while saving the " \ "coverage result.", RuntimeWarning ) covered_files = list(generate_covered_files(source_dir)) cov.html_report(morfs=covered_files, directory=report_dir) parser = ArgumentParser() parser.add_argument( '-c', '--use-cache', action='store_true', default=False, help='Use cached data.') parser.add_argument( '-d', '--report-dir', default='covhtml', help='Directory to put the generated report in.') parser.add_argument( "--slow", action="store_true", dest="slow", default=False, help="Run slow functions also.") options, args = parser.parse_known_args() if __name__ == '__main__': report_dir = options.report_dir use_cache = options.use_cache slow = options.slow make_report( args, report_dir=report_dir, use_cache=use_cache, slow=slow) print("The generated coverage report is in covhtml directory.") print( "Open %s in your web browser to view the report" % os.sep.join([report_dir, 'index.html']) )

e6bb04e29ed5d1e3c7f98082ec05fd27a9ea1c67464f7911bca4b3ea22319679

#!/usr/bin/env python """ A tool to help keep .mailmap up-to-date with the current git authors. See also bin/authors_update.py """ import codecs import sys import os if sys.version_info < (3, 6): sys.exit("This script requires Python 3.6 or newer") from subprocess import run, PIPE from distutils.version import LooseVersion from collections import defaultdict, OrderedDict def red(text): return "\033[31m%s\033[0m" % text def yellow(text): return "\033[33m%s\033[0m" % text def blue(text): return "\033[34m%s\033[0m" % text # put sympy on the path mailmap_update_path = os.path.abspath(__file__) mailmap_update_dir = os.path.dirname(mailmap_update_path) sympy_top = os.path.split(mailmap_update_dir)[0] sympy_dir = os.path.join(sympy_top, 'sympy') if os.path.isdir(sympy_dir): sys.path.insert(0, sympy_top) from sympy.utilities.misc import filldedent from sympy.utilities.iterables import sift # check git version minimal = '1.8.4.2' git_ver = run(['git', '--version'], stdout=PIPE, encoding='utf-8').stdout[12:] if LooseVersion(git_ver) < LooseVersion(minimal): print(yellow("Please use a git version >= %s" % minimal)) def author_name(line): assert line.count("<") == line.count(">") == 1 assert line.endswith(">") return line.split("<", 1)[0].strip() def author_email(line): assert line.count("<") == line.count(">") == 1 assert line.endswith(">") return line.split("<", 1)[1][:-1].strip() sysexit = 0 print(blue("checking git authors...")) # read git authors git_command = ['git', 'log', '--format=%aN <%aE>'] git_people = sorted(set(run(git_command, stdout=PIPE, encoding='utf-8').stdout.strip().split("\n"))) # check for ambiguous emails dups = defaultdict(list) near_dups = defaultdict(list) for i in git_people: k = i.split('<')[1] dups[k].append(i) near_dups[k.lower()].append((k, i)) multi = [k for k in dups if len(dups[k]) > 1] if multi: print() print(red(filldedent(""" Ambiguous email address error: each address should refer to a single author. Disambiguate the following in .mailmap. Then re-run this script."""))) for k in multi: print() for e in sorted(dups[k]): print('\t%s' % e) sysexit = 1 # warn for nearly ambiguous email addresses dups = near_dups # some may have been real dups, so disregard those # for which all email addresses were the same multi = [k for k in dups if len(dups[k]) > 1 and len(set([i for i, _ in dups[k]])) > 1] if multi: # not fatal but make it red print() print(red(filldedent(""" Ambiguous email address warning: git treats the following as distinct but .mailmap will treat them the same. If these are not all the same person then, when making an entry in .mailmap, be sure to include both commit name and address (not just the address)."""))) for k in multi: print() for _, e in sorted(dups[k]): print('\t%s' % e) # warn for ambiguous names dups = defaultdict(list) for i in git_people: dups[author_name(i)].append(i) multi = [k for k in dups if len(dups[k]) > 1] if multi: print() print(yellow(filldedent(""" Ambiguous name warning: if a person uses more than one email address, entries should be added to .mailmap to merge them into a single canonical address. Then re-run this script. """))) for k in multi: print() for e in sorted(dups[k]): print('\t%s' % e) bad_names = [] bad_emails = [] for i in git_people: name = author_name(i) email = author_email(i) if '@' in name: bad_names.append(i) elif '@' not in email: bad_emails.append(i) if bad_names: print() print(yellow(filldedent(""" The following people appear to have an email address listed for their name. Entries should be added to .mailmap so that names are formatted like "Name <email address>". """))) for i in bad_names: print("\t%s" % i) # TODO: Should we check for bad emails as well? Some people have empty email # addresses. The above check seems to catch people who get the name and email # backwards, so let's leave this alone for now. # if bad_emails: # print() # print(yellow(filldedent(""" # The following names do not appear to have valid # emails. Entries should be added to .mailmap that # use a proper email address. If there is no email # address for a person, use "[email protected]". # """))) # for i in bad_emails: # print("\t%s" % i) print() print(blue("checking .mailmap...")) # put entries in order -- this will help the user # to see if there are already existing entries for an author file = codecs.open(os.path.realpath(os.path.join( __file__, os.path.pardir, os.path.pardir, ".mailmap")), "r", "utf-8").read() blankline = not file or file.endswith('\n') lines = file.splitlines() def key(line): # return lower case first address on line or # raise an error if not an entry if '#' in line: line = line.split('#')[0] L, R = line.count("<"), line.count(">") assert L == R and L in (1, 2) return line.split(">", 1)[0].split("<")[1].lower() who = OrderedDict() for i, line in enumerate(lines): try: who.setdefault(key(line), []).append(line) except AssertionError: who[i] = [line] out = [] for k in who: # put long entries before short since if they match, the # short entries will be ignored. The ORDER MATTERS # so don't re-order the lines for a given address. # Other tidying up could be done but we won't do that here. def short_entry(line): if line.count('<') == 2: if line.split('>', 1)[1].split('<')[0].strip(): return False return True if len(who[k]) == 1: line = who[k][0] if not line.strip(): continue # ignore blank lines out.append(line) else: uniq = list(OrderedDict.fromkeys(who[k])) short, long = sift(uniq, short_entry, binary=True) out.extend(long) out.extend(short) if out != lines or not blankline: # write lines with codecs.open(os.path.realpath(os.path.join( __file__, os.path.pardir, os.path.pardir, ".mailmap")), "w", "utf-8") as fd: fd.write('\n'.join(out)) fd.write('\n') print() if out != lines: print(yellow('.mailmap lines were re-ordered.')) else: print(yellow('blank line added to end of .mailmap')) sys.exit(sysexit)

699110cb0bb7c9e0fd4a7f851cba89d032dfe923bda52a88ee488cebd5c46cbb

""" SymPy statistics module Introduces a random variable type into the SymPy language. Random variables may be declared using prebuilt functions such as Normal, Exponential, Coin, Die, etc... or built with functions like FiniteRV. Queries on random expressions can be made using the functions ========================= ============================= Expression Meaning ------------------------- ----------------------------- ``P(condition)`` Probability ``E(expression)`` Expected value ``H(expression)`` Entropy ``variance(expression)`` Variance ``density(expression)`` Probability Density Function ``sample(expression)`` Produce a realization ``where(condition)`` Where the condition is true ========================= ============================= Examples ======== >>> from sympy.stats import P, E, variance, Die, Normal >>> from sympy import Eq, simplify >>> X, Y = Die('X', 6), Die('Y', 6) # Define two six sided dice >>> Z = Normal('Z', 0, 1) # Declare a Normal random variable with mean 0, std 1 >>> P(X>3) # Probability X is greater than 3 1/2 >>> E(X+Y) # Expectation of the sum of two dice 7 >>> variance(X+Y) # Variance of the sum of two dice 35/6 >>> simplify(P(Z>1)) # Probability of Z being greater than 1 1/2 - erf(sqrt(2)/2)/2 """ __all__ = [] from . import rv_interface from .rv_interface import ( cdf, characteristic_function, covariance, density, dependent, E, given, independent, P, pspace, random_symbols, sample, sample_iter, skewness, std, variance, where, correlation, moment, cmoment, smoment, sampling_density, moment_generating_function, entropy, H ) __all__.extend(rv_interface.__all__) from . import frv_types from .frv_types import ( Bernoulli, Binomial, Coin, Die, DiscreteUniform, FiniteRV, Hypergeometric, Rademacher, ) __all__.extend(frv_types.__all__) from . import crv_types from .crv_types import ( ContinuousRV, Arcsin, Benini, Beta, BetaPrime, Cauchy, Chi, ChiNoncentral, ChiSquared, Dagum, Erlang, Exponential, FDistribution, FisherZ, Frechet, Gamma, GammaInverse, Gumbel, Gompertz, Kumaraswamy, Laplace, Logistic, LogNormal, Maxwell, Nakagami, Normal, Pareto, QuadraticU, RaisedCosine, Rayleigh, ShiftedGompertz, StudentT, Trapezoidal, Triangular, Uniform, UniformSum, VonMises, Weibull, WignerSemicircle ) __all__.extend(crv_types.__all__) from . import drv_types from .drv_types import (Geometric, Logarithmic, NegativeBinomial, Poisson, YuleSimon, Zeta) __all__.extend(drv_types.__all__) from . import symbolic_probability from .symbolic_probability import Probability, Expectation, Variance, Covariance __all__.extend(symbolic_probability.__all__)

18cfc133b498c3ce24cc5dd77d99d9676308bc8b0b4f4c5c88b4e4294f11aba5

from __future__ import print_function, division from .rv import (probability, expectation, density, where, given, pspace, cdf, characteristic_function, sample, sample_iter, random_symbols, independent, dependent, sampling_density, moment_generating_function) from sympy import sqrt, log, Piecewise, Symbol, Eq, Lambda, exp __all__ = ['P', 'E', 'H', 'density', 'where', 'given', 'sample', 'cdf', 'characteristic_function', 'pspace', 'sample_iter', 'variance', 'std', 'skewness', 'covariance', 'dependent', 'independent', 'random_symbols', 'correlation', 'moment', 'cmoment', 'sampling_density', 'moment_generating_function'] def moment(X, n, c=0, condition=None, **kwargs): """ Return the nth moment of a random expression about c i.e. E((X-c)**n) Default value of c is 0. Examples ======== >>> from sympy.stats import Die, moment, E >>> X = Die('X', 6) >>> moment(X, 1, 6) -5/2 >>> moment(X, 2) 91/6 >>> moment(X, 1) == E(X) True """ return expectation((X - c)**n, condition, **kwargs) def variance(X, condition=None, **kwargs): """ Variance of a random expression Expectation of (X-E(X))**2 Examples ======== >>> from sympy.stats import Die, E, Bernoulli, variance >>> from sympy import simplify, Symbol >>> X = Die('X', 6) >>> p = Symbol('p') >>> B = Bernoulli('B', p, 1, 0) >>> variance(2*X) 35/3 >>> simplify(variance(B)) p*(1 - p) """ return cmoment(X, 2, condition, **kwargs) def standard_deviation(X, condition=None, **kwargs): """ Standard Deviation of a random expression Square root of the Expectation of (X-E(X))**2 Examples ======== >>> from sympy.stats import Bernoulli, std >>> from sympy import Symbol, simplify >>> p = Symbol('p') >>> B = Bernoulli('B', p, 1, 0) >>> simplify(std(B)) sqrt(p*(1 - p)) """ return sqrt(variance(X, condition, **kwargs)) std = standard_deviation def entropy(expr, condition=None, **kwargs): """ Calculuates entropy of a probability distribution Parameters ========== expression : the random expression whose entropy is to be calculated condition : optional, to specify conditions on random expression b: base of the logarithm, optional By default, it is taken as Euler's number Retruns ======= result : Entropy of the expression, a constant Examples ======== >>> from sympy.stats import Normal, Die, entropy >>> X = Normal('X', 0, 1) >>> entropy(X) log(2)/2 + 1/2 + log(pi)/2 >>> D = Die('D', 4) >>> entropy(D) log(4) References ========== .. [1] https://en.wikipedia.org/wiki/Entropy_(information_theory) .. [2] https://www.crmarsh.com/static/pdf/Charles_Marsh_Continuous_Entropy.pdf .. [3] http://www.math.uconn.edu/~kconrad/blurbs/analysis/entropypost.pdf """ pdf = density(expr, condition, **kwargs) base = kwargs.get('b', exp(1)) if isinstance(pdf, dict): return sum([-prob*log(prob, base) for prob in pdf.values()]) return expectation(-log(pdf(expr), base)) def covariance(X, Y, condition=None, **kwargs): """ Covariance of two random expressions The expectation that the two variables will rise and fall together Covariance(X,Y) = E( (X-E(X)) * (Y-E(Y)) ) Examples ======== >>> from sympy.stats import Exponential, covariance >>> from sympy import Symbol >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> X = Exponential('X', rate) >>> Y = Exponential('Y', rate) >>> covariance(X, X) lambda**(-2) >>> covariance(X, Y) 0 >>> covariance(X, Y + rate*X) 1/lambda """ return expectation( (X - expectation(X, condition, **kwargs)) * (Y - expectation(Y, condition, **kwargs)), condition, **kwargs) def correlation(X, Y, condition=None, **kwargs): """ Correlation of two random expressions, also known as correlation coefficient or Pearson's correlation The normalized expectation that the two variables will rise and fall together Correlation(X,Y) = E( (X-E(X)) * (Y-E(Y)) / (sigma(X) * sigma(Y)) ) Examples ======== >>> from sympy.stats import Exponential, correlation >>> from sympy import Symbol >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> X = Exponential('X', rate) >>> Y = Exponential('Y', rate) >>> correlation(X, X) 1 >>> correlation(X, Y) 0 >>> correlation(X, Y + rate*X) 1/sqrt(1 + lambda**(-2)) """ return covariance(X, Y, condition, **kwargs)/(std(X, condition, **kwargs) * std(Y, condition, **kwargs)) def cmoment(X, n, condition=None, **kwargs): """ Return the nth central moment of a random expression about its mean i.e. E((X - E(X))**n) Examples ======== >>> from sympy.stats import Die, cmoment, variance >>> X = Die('X', 6) >>> cmoment(X, 3) 0 >>> cmoment(X, 2) 35/12 >>> cmoment(X, 2) == variance(X) True """ mu = expectation(X, condition, **kwargs) return moment(X, n, mu, condition, **kwargs) def smoment(X, n, condition=None, **kwargs): """ Return the nth Standardized moment of a random expression i.e. E( ((X - mu)/sigma(X))**n ) Examples ======== >>> from sympy.stats import skewness, Exponential, smoment >>> from sympy import Symbol >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> Y = Exponential('Y', rate) >>> smoment(Y, 4) 9 >>> smoment(Y, 4) == smoment(3*Y, 4) True >>> smoment(Y, 3) == skewness(Y) True """ sigma = std(X, condition, **kwargs) return (1/sigma)**n*cmoment(X, n, condition, **kwargs) def skewness(X, condition=None, **kwargs): """ Measure of the asymmetry of the probability distribution Positive skew indicates that most of the values lie to the right of the mean skewness(X) = E( ((X - E(X))/sigma)**3 ) Examples ======== >>> from sympy.stats import skewness, Exponential, Normal >>> from sympy import Symbol >>> X = Normal('X', 0, 1) >>> skewness(X) 0 >>> rate = Symbol('lambda', positive=True, real=True, finite=True) >>> Y = Exponential('Y', rate) >>> skewness(Y) 2 """ return smoment(X, 3, condition, **kwargs) P = probability E = expectation H = entropy

7bc83add187ba123faa678f1d93eeb798518ed3f70f23c7c2f11504630409923

""" Main Random Variables Module Defines abstract random variable type. Contains interfaces for probability space object (PSpace) as well as standard operators, P, E, sample, density, where See Also ======== sympy.stats.crv sympy.stats.frv sympy.stats.rv_interface """ from __future__ import print_function, division from sympy import (Basic, S, Expr, Symbol, Tuple, And, Add, Eq, lambdify, Equality, Lambda, sympify, Dummy, Ne, KroneckerDelta, DiracDelta, Mul) from sympy.abc import x from sympy.core.compatibility import string_types from sympy.core.relational import Relational from sympy.logic.boolalg import Boolean from sympy.sets.sets import FiniteSet, ProductSet, Intersection from sympy.solvers.solveset import solveset class RandomDomain(Basic): """ Represents a set of variables and the values which they can take See Also ======== sympy.stats.crv.ContinuousDomain sympy.stats.frv.FiniteDomain """ is_ProductDomain = False is_Finite = False is_Continuous = False is_Discrete = False def __new__(cls, symbols, *args): symbols = FiniteSet(*symbols) return Basic.__new__(cls, symbols, *args) @property def symbols(self): return self.args[0] @property def set(self): return self.args[1] def __contains__(self, other): raise NotImplementedError() def compute_expectation(self, expr): raise NotImplementedError() class SingleDomain(RandomDomain): """ A single variable and its domain See Also ======== sympy.stats.crv.SingleContinuousDomain sympy.stats.frv.SingleFiniteDomain """ def __new__(cls, symbol, set): assert symbol.is_Symbol return Basic.__new__(cls, symbol, set) @property def symbol(self): return self.args[0] @property def symbols(self): return FiniteSet(self.symbol) def __contains__(self, other): if len(other) != 1: return False sym, val = tuple(other)[0] return self.symbol == sym and val in self.set class ConditionalDomain(RandomDomain): """ A RandomDomain with an attached condition See Also ======== sympy.stats.crv.ConditionalContinuousDomain sympy.stats.frv.ConditionalFiniteDomain """ def __new__(cls, fulldomain, condition): condition = condition.xreplace(dict((rs, rs.symbol) for rs in random_symbols(condition))) return Basic.__new__(cls, fulldomain, condition) @property def symbols(self): return self.fulldomain.symbols @property def fulldomain(self): return self.args[0] @property def condition(self): return self.args[1] @property def set(self): raise NotImplementedError("Set of Conditional Domain not Implemented") def as_boolean(self): return And(self.fulldomain.as_boolean(), self.condition) class PSpace(Basic): """ A Probability Space Probability Spaces encode processes that equal different values probabilistically. These underly Random Symbols which occur in SymPy expressions and contain the mechanics to evaluate statistical statements. See Also ======== sympy.stats.crv.ContinuousPSpace sympy.stats.frv.FinitePSpace """ is_Finite = None is_Continuous = None is_Discrete = None is_real = None @property def domain(self): return self.args[0] @property def density(self): return self.args[1] @property def values(self): return frozenset(RandomSymbol(sym, self) for sym in self.symbols) @property def symbols(self): return self.domain.symbols def where(self, condition): raise NotImplementedError() def compute_density(self, expr): raise NotImplementedError() def sample(self): raise NotImplementedError() def probability(self, condition): raise NotImplementedError() def compute_expectation(self, expr): raise NotImplementedError() class SinglePSpace(PSpace): """ Represents the probabilities of a set of random events that can be attributed to a single variable/symbol. """ def __new__(cls, s, distribution): if isinstance(s, string_types): s = Symbol(s) if not isinstance(s, Symbol): raise TypeError("s should have been string or Symbol") return Basic.__new__(cls, s, distribution) @property def value(self): return RandomSymbol(self.symbol, self) @property def symbol(self): return self.args[0] @property def distribution(self): return self.args[1] @property def pdf(self): return self.distribution.pdf(self.symbol) class RandomSymbol(Expr): """ Random Symbols represent ProbabilitySpaces in SymPy Expressions In principle they can take on any value that their symbol can take on within the associated PSpace with probability determined by the PSpace Density. Random Symbols contain pspace and symbol properties. The pspace property points to the represented Probability Space The symbol is a standard SymPy Symbol that is used in that probability space for example in defining a density. You can form normal SymPy expressions using RandomSymbols and operate on those expressions with the Functions E - Expectation of a random expression P - Probability of a condition density - Probability Density of an expression given - A new random expression (with new random symbols) given a condition An object of the RandomSymbol type should almost never be created by the user. They tend to be created instead by the PSpace class's value method. Traditionally a user doesn't even do this but instead calls one of the convenience functions Normal, Exponential, Coin, Die, FiniteRV, etc.... """ def __new__(cls, symbol, pspace=None): from sympy.stats.joint_rv import JointRandomSymbol if pspace is None: # Allow single arg, representing pspace == PSpace() pspace = PSpace() if not isinstance(symbol, Symbol): raise TypeError("symbol should be of type Symbol") if not isinstance(pspace, PSpace): raise TypeError("pspace variable should be of type PSpace") if cls == JointRandomSymbol and isinstance(pspace, SinglePSpace): cls = RandomSymbol return Basic.__new__(cls, symbol, pspace) is_finite = True is_symbol = True is_Atom = True _diff_wrt = True pspace = property(lambda self: self.args[1]) symbol = property(lambda self: self.args[0]) name = property(lambda self: self.symbol.name) def _eval_is_positive(self): return self.symbol.is_positive def _eval_is_integer(self): return self.symbol.is_integer def _eval_is_real(self): return self.symbol.is_real or self.pspace.is_real @property def is_commutative(self): return self.symbol.is_commutative def _hashable_content(self): return self.pspace, self.symbol @property def free_symbols(self): return {self} class ProductPSpace(PSpace): """ Abstract class for representing probability spaces with multiple random variables. See Also ======== sympy.stats.rv.IndependentProductPSpace sympy.stats.joint_rv.JointPSpace """ pass class IndependentProductPSpace(ProductPSpace): """ A probability space resulting from the merger of two independent probability spaces. Often created using the function, pspace """ def __new__(cls, *spaces): rs_space_dict = {} for space in spaces: for value in space.values: rs_space_dict[value] = space symbols = FiniteSet(*[val.symbol for val in rs_space_dict.keys()]) # Overlapping symbols from sympy.stats.joint_rv import MarginalDistribution, CompoundDistribution if len(symbols) < sum(len(space.symbols) for space in spaces if not isinstance(space.distribution, ( CompoundDistribution, MarginalDistribution))): raise ValueError("Overlapping Random Variables") if all(space.is_Finite for space in spaces): from sympy.stats.frv import ProductFinitePSpace cls = ProductFinitePSpace obj = Basic.__new__(cls, *FiniteSet(*spaces)) return obj @property def pdf(self): p = Mul(*[space.pdf for space in self.spaces]) return p.subs(dict((rv, rv.symbol) for rv in self.values)) @property def rs_space_dict(self): d = {} for space in self.spaces: for value in space.values: d[value] = space return d @property def symbols(self): return FiniteSet(*[val.symbol for val in self.rs_space_dict.keys()]) @property def spaces(self): return FiniteSet(*self.args) @property def values(self): return sumsets(space.values for space in self.spaces) def compute_expectation(self, expr, rvs=None, evaluate=False, **kwargs): rvs = rvs or self.values rvs = frozenset(rvs) for space in self.spaces: expr = space.compute_expectation(expr, rvs & space.values, evaluate=False, **kwargs) if evaluate and hasattr(expr, 'doit'): return expr.doit(**kwargs) return expr @property def domain(self): return ProductDomain(*[space.domain for space in self.spaces]) @property def density(self): raise NotImplementedError("Density not available for ProductSpaces") def sample(self): return {k: v for space in self.spaces for k, v in space.sample().items()} def probability(self, condition, **kwargs): cond_inv = False if isinstance(condition, Ne): condition = Eq(condition.args[0], condition.args[1]) cond_inv = True expr = condition.lhs - condition.rhs rvs = random_symbols(expr) z = Dummy('z', real=True, Finite=True) dens = self.compute_density(expr) if any([pspace(rv).is_Continuous for rv in rvs]): from sympy.stats.crv import (ContinuousDistributionHandmade, SingleContinuousPSpace) if expr in self.values: # Marginalize all other random symbols out of the density randomsymbols = tuple(set(self.values) - frozenset([expr])) symbols = tuple(rs.symbol for rs in randomsymbols) pdf = self.domain.integrate(self.pdf, symbols, **kwargs) return Lambda(expr.symbol, pdf) dens = ContinuousDistributionHandmade(dens) space = SingleContinuousPSpace(z, dens) result = space.probability(condition.__class__(space.value, 0)) else: from sympy.stats.drv import (DiscreteDistributionHandmade, SingleDiscretePSpace) dens = DiscreteDistributionHandmade(dens) space = SingleDiscretePSpace(z, dens) result = space.probability(condition.__class__(space.value, 0)) return result if not cond_inv else S.One - result def compute_density(self, expr, **kwargs): z = Dummy('z', real=True, finite=True) rvs = random_symbols(expr) if any(pspace(rv).is_Continuous for rv in rvs): expr = self.compute_expectation(DiracDelta(expr - z), **kwargs) else: expr = self.compute_expectation(KroneckerDelta(expr, z), **kwargs) return Lambda(z, expr) def compute_cdf(self, expr, **kwargs): raise ValueError("CDF not well defined on multivariate expressions") def conditional_space(self, condition, normalize=True, **kwargs): rvs = random_symbols(condition) condition = condition.xreplace(dict((rv, rv.symbol) for rv in self.values)) if any([pspace(rv).is_Continuous for rv in rvs]): from sympy.stats.crv import (ConditionalContinuousDomain, ContinuousPSpace) space = ContinuousPSpace domain = ConditionalContinuousDomain(self.domain, condition) elif any([pspace(rv).is_Discrete for rv in rvs]): from sympy.stats.drv import (ConditionalDiscreteDomain, DiscretePSpace) space = DiscretePSpace domain = ConditionalDiscreteDomain(self.domain, condition) elif all([pspace(rv).is_Finite for rv in rvs]): from sympy.stats.frv import FinitePSpace return FinitePSpace.conditional_space(self, condition) if normalize: replacement = {rv: Dummy(str(rv)) for rv in self.symbols} norm = domain.compute_expectation(self.pdf, **kwargs) pdf = self.pdf / norm.xreplace(replacement) density = Lambda(domain.symbols, pdf) return space(domain, density) class ProductDomain(RandomDomain): """ A domain resulting from the merger of two independent domains See Also ======== sympy.stats.crv.ProductContinuousDomain sympy.stats.frv.ProductFiniteDomain """ is_ProductDomain = True def __new__(cls, *domains): # Flatten any product of products domains2 = [] for domain in domains: if not domain.is_ProductDomain: domains2.append(domain) else: domains2.extend(domain.domains) domains2 = FiniteSet(*domains2) if all(domain.is_Finite for domain in domains2): from sympy.stats.frv import ProductFiniteDomain cls = ProductFiniteDomain if all(domain.is_Continuous for domain in domains2): from sympy.stats.crv import ProductContinuousDomain cls = ProductContinuousDomain if all(domain.is_Discrete for domain in domains2): from sympy.stats.drv import ProductDiscreteDomain cls = ProductDiscreteDomain return Basic.__new__(cls, *domains2) @property def sym_domain_dict(self): return dict((symbol, domain) for domain in self.domains for symbol in domain.symbols) @property def symbols(self): return FiniteSet(*[sym for domain in self.domains for sym in domain.symbols]) @property def domains(self): return self.args @property def set(self): return ProductSet(domain.set for domain in self.domains) def __contains__(self, other): # Split event into each subdomain for domain in self.domains: # Collect the parts of this event which associate to this domain elem = frozenset([item for item in other if sympify(domain.symbols.contains(item[0])) is S.true]) # Test this sub-event if elem not in domain: return False # All subevents passed return True def as_boolean(self): return And(*[domain.as_boolean() for domain in self.domains]) def random_symbols(expr): """ Returns all RandomSymbols within a SymPy Expression. """ atoms = getattr(expr, 'atoms', None) if atoms is not None: return list(atoms(RandomSymbol)) else: return [] def pspace(expr): """ Returns the underlying Probability Space of a random expression. For internal use. Examples ======== >>> from sympy.stats import pspace, Normal >>> from sympy.stats.rv import IndependentProductPSpace >>> X = Normal('X', 0, 1) >>> pspace(2*X + 1) == X.pspace True """ expr = sympify(expr) if isinstance(expr, RandomSymbol) and expr.pspace is not None: return expr.pspace rvs = random_symbols(expr) if not rvs: raise ValueError("Expression containing Random Variable expected, not %s" % (expr)) # If only one space present if all(rv.pspace == rvs[0].pspace for rv in rvs): return rvs[0].pspace # Otherwise make a product space return IndependentProductPSpace(*[rv.pspace for rv in rvs]) def sumsets(sets): """ Union of sets """ return frozenset().union(*sets) def rs_swap(a, b): """ Build a dictionary to swap RandomSymbols based on their underlying symbol. i.e. if ``X = ('x', pspace1)`` and ``Y = ('x', pspace2)`` then ``X`` and ``Y`` match and the key, value pair ``{X:Y}`` will appear in the result Inputs: collections a and b of random variables which share common symbols Output: dict mapping RVs in a to RVs in b """ d = {} for rsa in a: d[rsa] = [rsb for rsb in b if rsa.symbol == rsb.symbol][0] return d def given(expr, condition=None, **kwargs): r""" Conditional Random Expression From a random expression and a condition on that expression creates a new probability space from the condition and returns the same expression on that conditional probability space. Examples ======== >>> from sympy.stats import given, density, Die >>> X = Die('X', 6) >>> Y = given(X, X > 3) >>> density(Y).dict {4: 1/3, 5: 1/3, 6: 1/3} Following convention, if the condition is a random symbol then that symbol is considered fixed. >>> from sympy.stats import Normal >>> from sympy import pprint >>> from sympy.abc import z >>> X = Normal('X', 0, 1) >>> Y = Normal('Y', 0, 1) >>> pprint(density(X + Y, Y)(z), use_unicode=False) 2 -(-Y + z) ----------- ___ 2 \/ 2 *e ------------------ ____ 2*\/ pi """ if not random_symbols(condition) or pspace_independent(expr, condition): return expr if isinstance(condition, RandomSymbol): condition = Eq(condition, condition.symbol) condsymbols = random_symbols(condition) if (isinstance(condition, Equality) and len(condsymbols) == 1 and not isinstance(pspace(expr).domain, ConditionalDomain)): rv = tuple(condsymbols)[0] results = solveset(condition, rv) if isinstance(results, Intersection) and S.Reals in results.args: results = list(results.args[1]) sums = 0 for res in results: temp = expr.subs(rv, res) if temp == True: return True if temp != False: sums += expr.subs(rv, res) if sums == 0: return False return sums # Get full probability space of both the expression and the condition fullspace = pspace(Tuple(expr, condition)) # Build new space given the condition space = fullspace.conditional_space(condition, **kwargs) # Dictionary to swap out RandomSymbols in expr with new RandomSymbols # That point to the new conditional space swapdict = rs_swap(fullspace.values, space.values) # Swap random variables in the expression expr = expr.xreplace(swapdict) return expr def expectation(expr, condition=None, numsamples=None, evaluate=True, **kwargs): """ Returns the expected value of a random expression Parameters ========== expr : Expr containing RandomSymbols The expression of which you want to compute the expectation value given : Expr containing RandomSymbols A conditional expression. E(X, X>0) is expectation of X given X > 0 numsamples : int Enables sampling and approximates the expectation with this many samples evalf : Bool (defaults to True) If sampling return a number rather than a complex expression evaluate : Bool (defaults to True) In case of continuous systems return unevaluated integral Examples ======== >>> from sympy.stats import E, Die >>> X = Die('X', 6) >>> E(X) 7/2 >>> E(2*X + 1) 8 >>> E(X, X > 3) # Expectation of X given that it is above 3 5 """ if not random_symbols(expr): # expr isn't random? return expr if numsamples: # Computing by monte carlo sampling? return sampling_E(expr, condition, numsamples=numsamples) # Create new expr and recompute E if condition is not None: # If there is a condition return expectation(given(expr, condition), evaluate=evaluate) # A few known statements for efficiency if expr.is_Add: # We know that E is Linear return Add(*[expectation(arg, evaluate=evaluate) for arg in expr.args]) # Otherwise case is simple, pass work off to the ProbabilitySpace result = pspace(expr).compute_expectation(expr, evaluate=evaluate, **kwargs) if evaluate and hasattr(result, 'doit'): return result.doit(**kwargs) else: return result def probability(condition, given_condition=None, numsamples=None, evaluate=True, **kwargs): """ Probability that a condition is true, optionally given a second condition Parameters ========== condition : Combination of Relationals containing RandomSymbols The condition of which you want to compute the probability given_condition : Combination of Relationals containing RandomSymbols A conditional expression. P(X > 1, X > 0) is expectation of X > 1 given X > 0 numsamples : int Enables sampling and approximates the probability with this many samples evaluate : Bool (defaults to True) In case of continuous systems return unevaluated integral Examples ======== >>> from sympy.stats import P, Die >>> from sympy import Eq >>> X, Y = Die('X', 6), Die('Y', 6) >>> P(X > 3) 1/2 >>> P(Eq(X, 5), X > 2) # Probability that X == 5 given that X > 2 1/4 >>> P(X > Y) 5/12 """ condition = sympify(condition) given_condition = sympify(given_condition) if given_condition is not None and \ not isinstance(given_condition, (Relational, Boolean)): raise ValueError("%s is not a relational or combination of relationals" % (given_condition)) if given_condition == False: return S.Zero if not isinstance(condition, (Relational, Boolean)): raise ValueError("%s is not a relational or combination of relationals" % (condition)) if condition is S.true: return S.One if condition is S.false: return S.Zero if numsamples: return sampling_P(condition, given_condition, numsamples=numsamples, **kwargs) if given_condition is not None: # If there is a condition # Recompute on new conditional expr return probability(given(condition, given_condition, **kwargs), **kwargs) # Otherwise pass work off to the ProbabilitySpace result = pspace(condition).probability(condition, **kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result class Density(Basic): expr = property(lambda self: self.args[0]) @property def condition(self): if len(self.args) > 1: return self.args[1] else: return None def doit(self, evaluate=True, **kwargs): from sympy.stats.joint_rv import JointPSpace expr, condition = self.expr, self.condition if condition is not None: # Recompute on new conditional expr expr = given(expr, condition, **kwargs) if isinstance(expr, RandomSymbol) and \ isinstance(expr.pspace, JointPSpace): return expr.pspace.distribution if not random_symbols(expr): return Lambda(x, DiracDelta(x - expr)) if (isinstance(expr, RandomSymbol) and hasattr(expr.pspace, 'distribution') and isinstance(pspace(expr), (SinglePSpace))): return expr.pspace.distribution result = pspace(expr).compute_density(expr, **kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def density(expr, condition=None, evaluate=True, numsamples=None, **kwargs): """ Probability density of a random expression, optionally given a second condition. This density will take on different forms for different types of probability spaces. Discrete variables produce Dicts. Continuous variables produce Lambdas. Parameters ========== expr : Expr containing RandomSymbols The expression of which you want to compute the density value condition : Relational containing RandomSymbols A conditional expression. density(X > 1, X > 0) is density of X > 1 given X > 0 numsamples : int Enables sampling and approximates the density with this many samples Examples ======== >>> from sympy.stats import density, Die, Normal >>> from sympy import Symbol >>> x = Symbol('x') >>> D = Die('D', 6) >>> X = Normal(x, 0, 1) >>> density(D).dict {1: 1/6, 2: 1/6, 3: 1/6, 4: 1/6, 5: 1/6, 6: 1/6} >>> density(2*D).dict {2: 1/6, 4: 1/6, 6: 1/6, 8: 1/6, 10: 1/6, 12: 1/6} >>> density(X)(x) sqrt(2)*exp(-x**2/2)/(2*sqrt(pi)) """ if numsamples: return sampling_density(expr, condition, numsamples=numsamples, **kwargs) return Density(expr, condition).doit(evaluate=evaluate, **kwargs) def cdf(expr, condition=None, evaluate=True, **kwargs): """ Cumulative Distribution Function of a random expression. optionally given a second condition This density will take on different forms for different types of probability spaces. Discrete variables produce Dicts. Continuous variables produce Lambdas. Examples ======== >>> from sympy.stats import density, Die, Normal, cdf >>> D = Die('D', 6) >>> X = Normal('X', 0, 1) >>> density(D).dict {1: 1/6, 2: 1/6, 3: 1/6, 4: 1/6, 5: 1/6, 6: 1/6} >>> cdf(D) {1: 1/6, 2: 1/3, 3: 1/2, 4: 2/3, 5: 5/6, 6: 1} >>> cdf(3*D, D > 2) {9: 1/4, 12: 1/2, 15: 3/4, 18: 1} >>> cdf(X) Lambda(_z, erf(sqrt(2)*_z/2)/2 + 1/2) """ if condition is not None: # If there is a condition # Recompute on new conditional expr return cdf(given(expr, condition, **kwargs), **kwargs) # Otherwise pass work off to the ProbabilitySpace result = pspace(expr).compute_cdf(expr, **kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def characteristic_function(expr, condition=None, evaluate=True, **kwargs): """ Characteristic function of a random expression, optionally given a second condition Returns a Lambda Examples ======== >>> from sympy.stats import Normal, DiscreteUniform, Poisson, characteristic_function >>> X = Normal('X', 0, 1) >>> characteristic_function(X) Lambda(_t, exp(-_t**2/2)) >>> Y = DiscreteUniform('Y', [1, 2, 7]) >>> characteristic_function(Y) Lambda(_t, exp(7*_t*I)/3 + exp(2*_t*I)/3 + exp(_t*I)/3) >>> Z = Poisson('Z', 2) >>> characteristic_function(Z) Lambda(_t, exp(2*exp(_t*I) - 2)) """ if condition is not None: return characteristic_function(given(expr, condition, **kwargs), **kwargs) result = pspace(expr).compute_characteristic_function(expr, **kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def moment_generating_function(expr, condition=None, evaluate=True, **kwargs): if condition is not None: return moment_generating_function(given(expr, condition, **kwargs), **kwargs) result = pspace(expr).compute_moment_generating_function(expr, **kwargs) if evaluate and hasattr(result, 'doit'): return result.doit() else: return result def where(condition, given_condition=None, **kwargs): """ Returns the domain where a condition is True. Examples ======== >>> from sympy.stats import where, Die, Normal >>> from sympy import symbols, And >>> D1, D2 = Die('a', 6), Die('b', 6) >>> a, b = D1.symbol, D2.symbol >>> X = Normal('x', 0, 1) >>> where(X**2<1) Domain: (-1 < x) & (x < 1) >>> where(X**2<1).set Interval.open(-1, 1) >>> where(And(D1<=D2 , D2<3)) Domain: (Eq(a, 1) & Eq(b, 1)) | (Eq(a, 1) & Eq(b, 2)) | (Eq(a, 2) & Eq(b, 2)) """ if given_condition is not None: # If there is a condition # Recompute on new conditional expr return where(given(condition, given_condition, **kwargs), **kwargs) # Otherwise pass work off to the ProbabilitySpace return pspace(condition).where(condition, **kwargs) def sample(expr, condition=None, **kwargs): """ A realization of the random expression Examples ======== >>> from sympy.stats import Die, sample >>> X, Y, Z = Die('X', 6), Die('Y', 6), Die('Z', 6) >>> die_roll = sample(X + Y + Z) # A random realization of three dice """ return next(sample_iter(expr, condition, numsamples=1)) def sample_iter(expr, condition=None, numsamples=S.Infinity, **kwargs): """ Returns an iterator of realizations from the expression given a condition Parameters ========== expr: Expr Random expression to be realized condition: Expr, optional A conditional expression numsamples: integer, optional Length of the iterator (defaults to infinity) Examples ======== >>> from sympy.stats import Normal, sample_iter >>> X = Normal('X', 0, 1) >>> expr = X*X + 3 >>> iterator = sample_iter(expr, numsamples=3) >>> list(iterator) # doctest: +SKIP [12, 4, 7] See Also ======== sample sampling_P sampling_E sample_iter_lambdify sample_iter_subs """ # lambdify is much faster but not as robust try: return sample_iter_lambdify(expr, condition, numsamples, **kwargs) # use subs when lambdify fails except TypeError: return sample_iter_subs(expr, condition, numsamples, **kwargs) def sample_iter_lambdify(expr, condition=None, numsamples=S.Infinity, **kwargs): """ See sample_iter Uses lambdify for computation. This is fast but does not always work. """ if condition: ps = pspace(Tuple(expr, condition)) else: ps = pspace(expr) rvs = list(ps.values) fn = lambdify(rvs, expr, **kwargs) if condition: given_fn = lambdify(rvs, condition, **kwargs) # Check that lambdify can handle the expression # Some operations like Sum can prove difficult try: d = ps.sample() # a dictionary that maps RVs to values args = [d[rv] for rv in rvs] fn(*args) if condition: given_fn(*args) except Exception: raise TypeError("Expr/condition too complex for lambdify") def return_generator(): count = 0 while count < numsamples: d = ps.sample() # a dictionary that maps RVs to values args = [d[rv] for rv in rvs] if condition: # Check that these values satisfy the condition gd = given_fn(*args) if gd != True and gd != False: raise ValueError( "Conditions must not contain free symbols") if not gd: # If the values don't satisfy then try again continue yield fn(*args) count += 1 return return_generator() def sample_iter_subs(expr, condition=None, numsamples=S.Infinity, **kwargs): """ See sample_iter Uses subs for computation. This is slow but almost always works. """ if condition is not None: ps = pspace(Tuple(expr, condition)) else: ps = pspace(expr) count = 0 while count < numsamples: d = ps.sample() # a dictionary that maps RVs to values if condition is not None: # Check that these values satisfy the condition gd = condition.xreplace(d) if gd != True and gd != False: raise ValueError("Conditions must not contain free symbols") if not gd: # If the values don't satisfy then try again continue yield expr.xreplace(d) count += 1 def sampling_P(condition, given_condition=None, numsamples=1, evalf=True, **kwargs): """ Sampling version of P See Also ======== P sampling_E sampling_density """ count_true = 0 count_false = 0 samples = sample_iter(condition, given_condition, numsamples=numsamples, **kwargs) for sample in samples: if sample != True and sample != False: raise ValueError("Conditions must not contain free symbols") if sample: count_true += 1 else: count_false += 1 result = S(count_true) / numsamples if evalf: return result.evalf() else: return result def sampling_E(expr, given_condition=None, numsamples=1, evalf=True, **kwargs): """ Sampling version of E See Also ======== P sampling_P sampling_density """ samples = sample_iter(expr, given_condition, numsamples=numsamples, **kwargs) result = Add(*list(samples)) / numsamples if evalf: return result.evalf() else: return result def sampling_density(expr, given_condition=None, numsamples=1, **kwargs): """ Sampling version of density See Also ======== density sampling_P sampling_E """ results = {} for result in sample_iter(expr, given_condition, numsamples=numsamples, **kwargs): results[result] = results.get(result, 0) + 1 return results def dependent(a, b): """ Dependence of two random expressions Two expressions are independent if knowledge of one does not change computations on the other. Examples ======== >>> from sympy.stats import Normal, dependent, given >>> from sympy import Tuple, Eq >>> X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) >>> dependent(X, Y) False >>> dependent(2*X + Y, -Y) True >>> X, Y = given(Tuple(X, Y), Eq(X + Y, 3)) >>> dependent(X, Y) True See Also ======== independent """ if pspace_independent(a, b): return False z = Symbol('z', real=True) # Dependent if density is unchanged when one is given information about # the other return (density(a, Eq(b, z)) != density(a) or density(b, Eq(a, z)) != density(b)) def independent(a, b): """ Independence of two random expressions Two expressions are independent if knowledge of one does not change computations on the other. Examples ======== >>> from sympy.stats import Normal, independent, given >>> from sympy import Tuple, Eq >>> X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) >>> independent(X, Y) True >>> independent(2*X + Y, -Y) False >>> X, Y = given(Tuple(X, Y), Eq(X + Y, 3)) >>> independent(X, Y) False See Also ======== dependent """ return not dependent(a, b) def pspace_independent(a, b): """ Tests for independence between a and b by checking if their PSpaces have overlapping symbols. This is a sufficient but not necessary condition for independence and is intended to be used internally. Notes ===== pspace_independent(a, b) implies independent(a, b) independent(a, b) does not imply pspace_independent(a, b) """ a_symbols = set(pspace(b).symbols) b_symbols = set(pspace(a).symbols) if len(set(random_symbols(a)).intersection(random_symbols(b))) != 0: return False if len(a_symbols.intersection(b_symbols)) == 0: return True return None def rv_subs(expr, symbols=None): """ Given a random expression replace all random variables with their symbols. If symbols keyword is given restrict the swap to only the symbols listed. """ if symbols is None: symbols = random_symbols(expr) if not symbols: return expr swapdict = {rv: rv.symbol for rv in symbols} return expr.xreplace(swapdict) class NamedArgsMixin(object): _argnames = () def __getattr__(self, attr): try: return self.args[self._argnames.index(attr)] except ValueError: raise AttributeError("'%s' object has no attribute '%s'" % ( type(self).__name__, attr)) def _value_check(condition, message): """ Check a condition on input value. Raises ValueError with message if condition is not True """ if condition == False: raise ValueError(message)

ca00bbf6349d4706bf76ffbb02d069191ca731707deb926320f66406e951c4f2

from __future__ import print_function, division from collections import defaultdict from sympy.core import (Basic, S, Add, Mul, Pow, Symbol, sympify, expand_mul, expand_func, Function, Dummy, Expr, factor_terms, expand_power_exp) from sympy.core.compatibility import iterable, ordered, range, as_int from sympy.core.evaluate import global_evaluate from sympy.core.function import expand_log, count_ops, _mexpand, _coeff_isneg, nfloat from sympy.core.numbers import Float, I, pi, Rational, Integer from sympy.core.rules import Transform from sympy.core.sympify import _sympify from sympy.functions import gamma, exp, sqrt, log, exp_polar, piecewise_fold from sympy.functions.combinatorial.factorials import CombinatorialFunction from sympy.functions.elementary.complexes import unpolarify from sympy.functions.elementary.exponential import ExpBase from sympy.functions.elementary.hyperbolic import HyperbolicFunction from sympy.functions.elementary.integers import ceiling from sympy.functions.elementary.trigonometric import TrigonometricFunction from sympy.functions.special.bessel import besselj, besseli, besselk, jn, bessely from sympy.polys import together, cancel, factor from sympy.simplify.combsimp import combsimp from sympy.simplify.cse_opts import sub_pre, sub_post from sympy.simplify.powsimp import powsimp from sympy.simplify.radsimp import radsimp, fraction from sympy.simplify.sqrtdenest import sqrtdenest from sympy.simplify.trigsimp import trigsimp, exptrigsimp from sympy.utilities.iterables import has_variety, sift import mpmath def separatevars(expr, symbols=[], dict=False, force=False): """ Separates variables in an expression, if possible. By default, it separates with respect to all symbols in an expression and collects constant coefficients that are independent of symbols. If dict=True then the separated terms will be returned in a dictionary keyed to their corresponding symbols. By default, all symbols in the expression will appear as keys; if symbols are provided, then all those symbols will be used as keys, and any terms in the expression containing other symbols or non-symbols will be returned keyed to the string 'coeff'. (Passing None for symbols will return the expression in a dictionary keyed to 'coeff'.) If force=True, then bases of powers will be separated regardless of assumptions on the symbols involved. Notes ===== The order of the factors is determined by Mul, so that the separated expressions may not necessarily be grouped together. Although factoring is necessary to separate variables in some expressions, it is not necessary in all cases, so one should not count on the returned factors being factored. Examples ======== >>> from sympy.abc import x, y, z, alpha >>> from sympy import separatevars, sin >>> separatevars((x*y)**y) (x*y)**y >>> separatevars((x*y)**y, force=True) x**y*y**y >>> e = 2*x**2*z*sin(y)+2*z*x**2 >>> separatevars(e) 2*x**2*z*(sin(y) + 1) >>> separatevars(e, symbols=(x, y), dict=True) {'coeff': 2*z, x: x**2, y: sin(y) + 1} >>> separatevars(e, [x, y, alpha], dict=True) {'coeff': 2*z, alpha: 1, x: x**2, y: sin(y) + 1} If the expression is not really separable, or is only partially separable, separatevars will do the best it can to separate it by using factoring. >>> separatevars(x + x*y - 3*x**2) -x*(3*x - y - 1) If the expression is not separable then expr is returned unchanged or (if dict=True) then None is returned. >>> eq = 2*x + y*sin(x) >>> separatevars(eq) == eq True >>> separatevars(2*x + y*sin(x), symbols=(x, y), dict=True) == None True """ expr = sympify(expr) if dict: return _separatevars_dict(_separatevars(expr, force), symbols) else: return _separatevars(expr, force) def _separatevars(expr, force): if len(expr.free_symbols) == 1: return expr # don't destroy a Mul since much of the work may already be done if expr.is_Mul: args = list(expr.args) changed = False for i, a in enumerate(args): args[i] = separatevars(a, force) changed = changed or args[i] != a if changed: expr = expr.func(*args) return expr # get a Pow ready for expansion if expr.is_Pow: expr = Pow(separatevars(expr.base, force=force), expr.exp) # First try other expansion methods expr = expr.expand(mul=False, multinomial=False, force=force) _expr, reps = posify(expr) if force else (expr, {}) expr = factor(_expr).subs(reps) if not expr.is_Add: return expr # Find any common coefficients to pull out args = list(expr.args) commonc = args[0].args_cnc(cset=True, warn=False)[0] for i in args[1:]: commonc &= i.args_cnc(cset=True, warn=False)[0] commonc = Mul(*commonc) commonc = commonc.as_coeff_Mul()[1] # ignore constants commonc_set = commonc.args_cnc(cset=True, warn=False)[0] # remove them for i, a in enumerate(args): c, nc = a.args_cnc(cset=True, warn=False) c = c - commonc_set args[i] = Mul(*c)*Mul(*nc) nonsepar = Add(*args) if len(nonsepar.free_symbols) > 1: _expr = nonsepar _expr, reps = posify(_expr) if force else (_expr, {}) _expr = (factor(_expr)).subs(reps) if not _expr.is_Add: nonsepar = _expr return commonc*nonsepar def _separatevars_dict(expr, symbols): if symbols: if not all((t.is_Atom for t in symbols)): raise ValueError("symbols must be Atoms.") symbols = list(symbols) elif symbols is None: return {'coeff': expr} else: symbols = list(expr.free_symbols) if not symbols: return None ret = dict(((i, []) for i in symbols + ['coeff'])) for i in Mul.make_args(expr): expsym = i.free_symbols intersection = set(symbols).intersection(expsym) if len(intersection) > 1: return None if len(intersection) == 0: # There are no symbols, so it is part of the coefficient ret['coeff'].append(i) else: ret[intersection.pop()].append(i) # rebuild for k, v in ret.items(): ret[k] = Mul(*v) return ret def _is_sum_surds(p): args = p.args if p.is_Add else [p] for y in args: if not ((y**2).is_Rational and y.is_real): return False return True def posify(eq): """Return eq (with generic symbols made positive) and a dictionary containing the mapping between the old and new symbols. Any symbol that has positive=None will be replaced with a positive dummy symbol having the same name. This replacement will allow more symbolic processing of expressions, especially those involving powers and logarithms. A dictionary that can be sent to subs to restore eq to its original symbols is also returned. >>> from sympy import posify, Symbol, log, solve >>> from sympy.abc import x >>> posify(x + Symbol('p', positive=True) + Symbol('n', negative=True)) (_x + n + p, {_x: x}) >>> eq = 1/x >>> log(eq).expand() log(1/x) >>> log(posify(eq)[0]).expand() -log(_x) >>> p, rep = posify(eq) >>> log(p).expand().subs(rep) -log(x) It is possible to apply the same transformations to an iterable of expressions: >>> eq = x**2 - 4 >>> solve(eq, x) [-2, 2] >>> eq_x, reps = posify([eq, x]); eq_x [_x**2 - 4, _x] >>> solve(*eq_x) [2] """ eq = sympify(eq) if iterable(eq): f = type(eq) eq = list(eq) syms = set() for e in eq: syms = syms.union(e.atoms(Symbol)) reps = {} for s in syms: reps.update(dict((v, k) for k, v in posify(s)[1].items())) for i, e in enumerate(eq): eq[i] = e.subs(reps) return f(eq), {r: s for s, r in reps.items()} reps = {s: Dummy(s.name, positive=True, **s.assumptions0) for s in eq.free_symbols if s.is_positive is None} eq = eq.subs(reps) return eq, {r: s for s, r in reps.items()} def hypersimp(f, k): """Given combinatorial term f(k) simplify its consecutive term ratio i.e. f(k+1)/f(k). The input term can be composed of functions and integer sequences which have equivalent representation in terms of gamma special function. The algorithm performs three basic steps: 1. Rewrite all functions in terms of gamma, if possible. 2. Rewrite all occurrences of gamma in terms of products of gamma and rising factorial with integer, absolute constant exponent. 3. Perform simplification of nested fractions, powers and if the resulting expression is a quotient of polynomials, reduce their total degree. If f(k) is hypergeometric then as result we arrive with a quotient of polynomials of minimal degree. Otherwise None is returned. For more information on the implemented algorithm refer to: 1. W. Koepf, Algorithms for m-fold Hypergeometric Summation, Journal of Symbolic Computation (1995) 20, 399-417 """ f = sympify(f) g = f.subs(k, k + 1) / f g = g.rewrite(gamma) g = expand_func(g) g = powsimp(g, deep=True, combine='exp') if g.is_rational_function(k): return simplify(g, ratio=S.Infinity) else: return None def hypersimilar(f, g, k): """Returns True if 'f' and 'g' are hyper-similar. Similarity in hypergeometric sense means that a quotient of f(k) and g(k) is a rational function in k. This procedure is useful in solving recurrence relations. For more information see hypersimp(). """ f, g = list(map(sympify, (f, g))) h = (f/g).rewrite(gamma) h = h.expand(func=True, basic=False) return h.is_rational_function(k) def signsimp(expr, evaluate=None): """Make all Add sub-expressions canonical wrt sign. If an Add subexpression, ``a``, can have a sign extracted, as determined by could_extract_minus_sign, it is replaced with Mul(-1, a, evaluate=False). This allows signs to be extracted from powers and products. Examples ======== >>> from sympy import signsimp, exp, symbols >>> from sympy.abc import x, y >>> i = symbols('i', odd=True) >>> n = -1 + 1/x >>> n/x/(-n)**2 - 1/n/x (-1 + 1/x)/(x*(1 - 1/x)**2) - 1/(x*(-1 + 1/x)) >>> signsimp(_) 0 >>> x*n + x*-n x*(-1 + 1/x) + x*(1 - 1/x) >>> signsimp(_) 0 Since powers automatically handle leading signs >>> (-2)**i -2**i signsimp can be used to put the base of a power with an integer exponent into canonical form: >>> n**i (-1 + 1/x)**i By default, signsimp doesn't leave behind any hollow simplification: if making an Add canonical wrt sign didn't change the expression, the original Add is restored. If this is not desired then the keyword ``evaluate`` can be set to False: >>> e = exp(y - x) >>> signsimp(e) == e True >>> signsimp(e, evaluate=False) exp(-(x - y)) """ if evaluate is None: evaluate = global_evaluate[0] expr = sympify(expr) if not isinstance(expr, Expr) or expr.is_Atom: return expr e = sub_post(sub_pre(expr)) if not isinstance(e, Expr) or e.is_Atom: return e if e.is_Add: return e.func(*[signsimp(a, evaluate) for a in e.args]) if evaluate: e = e.xreplace({m: -(-m) for m in e.atoms(Mul) if -(-m) != m}) return e def simplify(expr, ratio=1.7, measure=count_ops, rational=False, inverse=False): """Simplifies the given expression. Simplification is not a well defined term and the exact strategies this function tries can change in the future versions of SymPy. If your algorithm relies on "simplification" (whatever it is), try to determine what you need exactly - is it powsimp()?, radsimp()?, together()?, logcombine()?, or something else? And use this particular function directly, because those are well defined and thus your algorithm will be robust. Nonetheless, especially for interactive use, or when you don't know anything about the structure of the expression, simplify() tries to apply intelligent heuristics to make the input expression "simpler". For example: >>> from sympy import simplify, cos, sin >>> from sympy.abc import x, y >>> a = (x + x**2)/(x*sin(y)**2 + x*cos(y)**2) >>> a (x**2 + x)/(x*sin(y)**2 + x*cos(y)**2) >>> simplify(a) x + 1 Note that we could have obtained the same result by using specific simplification functions: >>> from sympy import trigsimp, cancel >>> trigsimp(a) (x**2 + x)/x >>> cancel(_) x + 1 In some cases, applying :func:`simplify` may actually result in some more complicated expression. The default ``ratio=1.7`` prevents more extreme cases: if (result length)/(input length) > ratio, then input is returned unmodified. The ``measure`` parameter lets you specify the function used to determine how complex an expression is. The function should take a single argument as an expression and return a number such that if expression ``a`` is more complex than expression ``b``, then ``measure(a) > measure(b)``. The default measure function is :func:`count_ops`, which returns the total number of operations in the expression. For example, if ``ratio=1``, ``simplify`` output can't be longer than input. :: >>> from sympy import sqrt, simplify, count_ops, oo >>> root = 1/(sqrt(2)+3) Since ``simplify(root)`` would result in a slightly longer expression, root is returned unchanged instead:: >>> simplify(root, ratio=1) == root True If ``ratio=oo``, simplify will be applied anyway:: >>> count_ops(simplify(root, ratio=oo)) > count_ops(root) True Note that the shortest expression is not necessary the simplest, so setting ``ratio`` to 1 may not be a good idea. Heuristically, the default value ``ratio=1.7`` seems like a reasonable choice. You can easily define your own measure function based on what you feel should represent the "size" or "complexity" of the input expression. Note that some choices, such as ``lambda expr: len(str(expr))`` may appear to be good metrics, but have other problems (in this case, the measure function may slow down simplify too much for very large expressions). If you don't know what a good metric would be, the default, ``count_ops``, is a good one. For example: >>> from sympy import symbols, log >>> a, b = symbols('a b', positive=True) >>> g = log(a) + log(b) + log(a)*log(1/b) >>> h = simplify(g) >>> h log(a*b**(1 - log(a))) >>> count_ops(g) 8 >>> count_ops(h) 5 So you can see that ``h`` is simpler than ``g`` using the count_ops metric. However, we may not like how ``simplify`` (in this case, using ``logcombine``) has created the ``b**(log(1/a) + 1)`` term. A simple way to reduce this would be to give more weight to powers as operations in ``count_ops``. We can do this by using the ``visual=True`` option: >>> print(count_ops(g, visual=True)) 2*ADD + DIV + 4*LOG + MUL >>> print(count_ops(h, visual=True)) 2*LOG + MUL + POW + SUB >>> from sympy import Symbol, S >>> def my_measure(expr): ... POW = Symbol('POW') ... # Discourage powers by giving POW a weight of 10 ... count = count_ops(expr, visual=True).subs(POW, 10) ... # Every other operation gets a weight of 1 (the default) ... count = count.replace(Symbol, type(S.One)) ... return count >>> my_measure(g) 8 >>> my_measure(h) 14 >>> 15./8 > 1.7 # 1.7 is the default ratio True >>> simplify(g, measure=my_measure) -log(a)*log(b) + log(a) + log(b) Note that because ``simplify()`` internally tries many different simplification strategies and then compares them using the measure function, we get a completely different result that is still different from the input expression by doing this. If rational=True, Floats will be recast as Rationals before simplification. If rational=None, Floats will be recast as Rationals but the result will be recast as Floats. If rational=False(default) then nothing will be done to the Floats. If inverse=True, it will be assumed that a composition of inverse functions, such as sin and asin, can be cancelled in any order. For example, ``asin(sin(x))`` will yield ``x`` without checking whether x belongs to the set where this relation is true. The default is False. """ expr = sympify(expr) kwargs = dict(ratio=ratio, measure=measure, rational=rational, inverse=inverse) _eval_simplify = getattr(expr, '_eval_simplify', None) if _eval_simplify is not None: return _eval_simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse) original_expr = expr = signsimp(expr) from sympy.simplify.hyperexpand import hyperexpand from sympy.functions.special.bessel import BesselBase from sympy import Sum, Product, Integral if not isinstance(expr, Basic) or not expr.args: # XXX: temporary hack return expr if inverse and expr.has(Function): expr = inversecombine(expr) if not expr.args: # simplified to atomic return expr if not isinstance(expr, (Add, Mul, Pow, ExpBase)): return expr.func(*[simplify(x, **kwargs) for x in expr.args]) if not expr.is_commutative: expr = nc_simplify(expr) # TODO: Apply different strategies, considering expression pattern: # is it a purely rational function? Is there any trigonometric function?... # See also https://github.com/sympy/sympy/pull/185. def shorter(*choices): '''Return the choice that has the fewest ops. In case of a tie, the expression listed first is selected.''' if not has_variety(choices): return choices[0] return min(choices, key=measure) # rationalize Floats floats = False if rational is not False and expr.has(Float): floats = True expr = nsimplify(expr, rational=True) expr = bottom_up(expr, lambda w: getattr(w, 'normal', lambda: w)()) expr = Mul(*powsimp(expr).as_content_primitive()) _e = cancel(expr) expr1 = shorter(_e, _mexpand(_e).cancel()) # issue 6829 expr2 = shorter(together(expr, deep=True), together(expr1, deep=True)) if ratio is S.Infinity: expr = expr2 else: expr = shorter(expr2, expr1, expr) if not isinstance(expr, Basic): # XXX: temporary hack return expr expr = factor_terms(expr, sign=False) # hyperexpand automatically only works on hypergeometric terms expr = hyperexpand(expr) expr = piecewise_fold(expr) if expr.has(BesselBase): expr = besselsimp(expr) if expr.has(TrigonometricFunction, HyperbolicFunction): expr = trigsimp(expr, deep=True) if expr.has(log): expr = shorter(expand_log(expr, deep=True), logcombine(expr)) if expr.has(CombinatorialFunction, gamma): # expression with gamma functions or non-integer arguments is # automatically passed to gammasimp expr = combsimp(expr) if expr.has(Sum): expr = sum_simplify(expr, **kwargs) if expr.has(Integral): expr = expr.xreplace(dict([ (i, factor_terms(i)) for i in expr.atoms(Integral)])) if expr.has(Product): expr = product_simplify(expr) from sympy.physics.units import Quantity from sympy.physics.units.util import quantity_simplify if expr.has(Quantity): expr = quantity_simplify(expr) short = shorter(powsimp(expr, combine='exp', deep=True), powsimp(expr), expr) short = shorter(short, cancel(short)) short = shorter(short, factor_terms(short), expand_power_exp(expand_mul(short))) if short.has(TrigonometricFunction, HyperbolicFunction, ExpBase): short = exptrigsimp(short) # get rid of hollow 2-arg Mul factorization hollow_mul = Transform( lambda x: Mul(*x.args), lambda x: x.is_Mul and len(x.args) == 2 and x.args[0].is_Number and x.args[1].is_Add and x.is_commutative) expr = short.xreplace(hollow_mul) numer, denom = expr.as_numer_denom() if denom.is_Add: n, d = fraction(radsimp(1/denom, symbolic=False, max_terms=1)) if n is not S.One: expr = (numer*n).expand()/d if expr.could_extract_minus_sign(): n, d = fraction(expr) if d != 0: expr = signsimp(-n/(-d)) if measure(expr) > ratio*measure(original_expr): expr = original_expr # restore floats if floats and rational is None: expr = nfloat(expr, exponent=False) return expr def sum_simplify(s, **kwargs): """Main function for Sum simplification""" from sympy.concrete.summations import Sum from sympy.core.function import expand if not isinstance(s, Add): s = s.xreplace(dict([(a, sum_simplify(a, **kwargs)) for a in s.atoms(Add) if a.has(Sum)])) s = expand(s) if not isinstance(s, Add): return s terms = s.args s_t = [] # Sum Terms o_t = [] # Other Terms for term in terms: sum_terms, other = sift(Mul.make_args(term), lambda i: isinstance(i, Sum), binary=True) if not sum_terms: o_t.append(term) continue other = [Mul(*other)] s_t.append(Mul(*(other + [s._eval_simplify(**kwargs) for s in sum_terms]))) result = Add(sum_combine(s_t), *o_t) return result def sum_combine(s_t): """Helper function for Sum simplification Attempts to simplify a list of sums, by combining limits / sum function's returns the simplified sum """ from sympy.concrete.summations import Sum used = [False] * len(s_t) for method in range(2): for i, s_term1 in enumerate(s_t): if not used[i]: for j, s_term2 in enumerate(s_t): if not used[j] and i != j: temp = sum_add(s_term1, s_term2, method) if isinstance(temp, Sum) or isinstance(temp, Mul): s_t[i] = temp s_term1 = s_t[i] used[j] = True result = S.Zero for i, s_term in enumerate(s_t): if not used[i]: result = Add(result, s_term) return result def factor_sum(self, limits=None, radical=False, clear=False, fraction=False, sign=True): """Return Sum with constant factors extracted. If ``limits`` is specified then ``self`` is the summand; the other keywords are passed to ``factor_terms``. Examples ======== >>> from sympy import Sum, Integral >>> from sympy.abc import x, y >>> from sympy.simplify.simplify import factor_sum >>> s = Sum(x*y, (x, 1, 3)) >>> factor_sum(s) y*Sum(x, (x, 1, 3)) >>> factor_sum(s.function, s.limits) y*Sum(x, (x, 1, 3)) """ # XXX deprecate in favor of direct call to factor_terms from sympy.concrete.summations import Sum kwargs = dict(radical=radical, clear=clear, fraction=fraction, sign=sign) expr = Sum(self, *limits) if limits else self return factor_terms(expr, **kwargs) def sum_add(self, other, method=0): """Helper function for Sum simplification""" from sympy.concrete.summations import Sum from sympy import Mul #we know this is something in terms of a constant * a sum #so we temporarily put the constants inside for simplification #then simplify the result def __refactor(val): args = Mul.make_args(val) sumv = next(x for x in args if isinstance(x, Sum)) constant = Mul(*[x for x in args if x != sumv]) return Sum(constant * sumv.function, *sumv.limits) if isinstance(self, Mul): rself = __refactor(self) else: rself = self if isinstance(other, Mul): rother = __refactor(other) else: rother = other if type(rself) == type(rother): if method == 0: if rself.limits == rother.limits: return factor_sum(Sum(rself.function + rother.function, *rself.limits)) elif method == 1: if simplify(rself.function - rother.function) == 0: if len(rself.limits) == len(rother.limits) == 1: i = rself.limits[0][0] x1 = rself.limits[0][1] y1 = rself.limits[0][2] j = rother.limits[0][0] x2 = rother.limits[0][1] y2 = rother.limits[0][2] if i == j: if x2 == y1 + 1: return factor_sum(Sum(rself.function, (i, x1, y2))) elif x1 == y2 + 1: return factor_sum(Sum(rself.function, (i, x2, y1))) return Add(self, other) def product_simplify(s): """Main function for Product simplification""" from sympy.concrete.products import Product terms = Mul.make_args(s) p_t = [] # Product Terms o_t = [] # Other Terms for term in terms: if isinstance(term, Product): p_t.append(term) else: o_t.append(term) used = [False] * len(p_t) for method in range(2): for i, p_term1 in enumerate(p_t): if not used[i]: for j, p_term2 in enumerate(p_t): if not used[j] and i != j: if isinstance(product_mul(p_term1, p_term2, method), Product): p_t[i] = product_mul(p_term1, p_term2, method) used[j] = True result = Mul(*o_t) for i, p_term in enumerate(p_t): if not used[i]: result = Mul(result, p_term) return result def product_mul(self, other, method=0): """Helper function for Product simplification""" from sympy.concrete.products import Product if type(self) == type(other): if method == 0: if self.limits == other.limits: return Product(self.function * other.function, *self.limits) elif method == 1: if simplify(self.function - other.function) == 0: if len(self.limits) == len(other.limits) == 1: i = self.limits[0][0] x1 = self.limits[0][1] y1 = self.limits[0][2] j = other.limits[0][0] x2 = other.limits[0][1] y2 = other.limits[0][2] if i == j: if x2 == y1 + 1: return Product(self.function, (i, x1, y2)) elif x1 == y2 + 1: return Product(self.function, (i, x2, y1)) return Mul(self, other) def _nthroot_solve(p, n, prec): """ helper function for ``nthroot`` It denests ``p**Rational(1, n)`` using its minimal polynomial """ from sympy.polys.numberfields import _minimal_polynomial_sq from sympy.solvers import solve while n % 2 == 0: p = sqrtdenest(sqrt(p)) n = n // 2 if n == 1: return p pn = p**Rational(1, n) x = Symbol('x') f = _minimal_polynomial_sq(p, n, x) if f is None: return None sols = solve(f, x) for sol in sols: if abs(sol - pn).n() < 1./10**prec: sol = sqrtdenest(sol) if _mexpand(sol**n) == p: return sol def logcombine(expr, force=False): """ Takes logarithms and combines them using the following rules: - log(x) + log(y) == log(x*y) if both are positive - a*log(x) == log(x**a) if x is positive and a is real If ``force`` is True then the assumptions above will be assumed to hold if there is no assumption already in place on a quantity. For example, if ``a`` is imaginary or the argument negative, force will not perform a combination but if ``a`` is a symbol with no assumptions the change will take place. Examples ======== >>> from sympy import Symbol, symbols, log, logcombine, I >>> from sympy.abc import a, x, y, z >>> logcombine(a*log(x) + log(y) - log(z)) a*log(x) + log(y) - log(z) >>> logcombine(a*log(x) + log(y) - log(z), force=True) log(x**a*y/z) >>> x,y,z = symbols('x,y,z', positive=True) >>> a = Symbol('a', real=True) >>> logcombine(a*log(x) + log(y) - log(z)) log(x**a*y/z) The transformation is limited to factors and/or terms that contain logs, so the result depends on the initial state of expansion: >>> eq = (2 + 3*I)*log(x) >>> logcombine(eq, force=True) == eq True >>> logcombine(eq.expand(), force=True) log(x**2) + I*log(x**3) See Also ======== posify: replace all symbols with symbols having positive assumptions sympy.core.function.expand_log: expand the logarithms of products and powers; the opposite of logcombine """ def f(rv): if not (rv.is_Add or rv.is_Mul): return rv def gooda(a): # bool to tell whether the leading ``a`` in ``a*log(x)`` # could appear as log(x**a) return (a is not S.NegativeOne and # -1 *could* go, but we disallow (a.is_real or force and a.is_real is not False)) def goodlog(l): # bool to tell whether log ``l``'s argument can combine with others a = l.args[0] return a.is_positive or force and a.is_nonpositive is not False other = [] logs = [] log1 = defaultdict(list) for a in Add.make_args(rv): if isinstance(a, log) and goodlog(a): log1[()].append(([], a)) elif not a.is_Mul: other.append(a) else: ot = [] co = [] lo = [] for ai in a.args: if ai.is_Rational and ai < 0: ot.append(S.NegativeOne) co.append(-ai) elif isinstance(ai, log) and goodlog(ai): lo.append(ai) elif gooda(ai): co.append(ai) else: ot.append(ai) if len(lo) > 1: logs.append((ot, co, lo)) elif lo: log1[tuple(ot)].append((co, lo[0])) else: other.append(a) # if there is only one log in other, put it with the # good logs if len(other) == 1 and isinstance(other[0], log): log1[()].append(([], other.pop())) # if there is only one log at each coefficient and none have # an exponent to place inside the log then there is nothing to do if not logs and all(len(log1[k]) == 1 and log1[k][0] == [] for k in log1): return rv # collapse multi-logs as far as possible in a canonical way # TODO: see if x*log(a)+x*log(a)*log(b) -> x*log(a)*(1+log(b))? # -- in this case, it's unambiguous, but if it were were a log(c) in # each term then it's arbitrary whether they are grouped by log(a) or # by log(c). So for now, just leave this alone; it's probably better to # let the user decide for o, e, l in logs: l = list(ordered(l)) e = log(l.pop(0).args[0]**Mul(*e)) while l: li = l.pop(0) e = log(li.args[0]**e) c, l = Mul(*o), e if isinstance(l, log): # it should be, but check to be sure log1[(c,)].append(([], l)) else: other.append(c*l) # logs that have the same coefficient can multiply for k in list(log1.keys()): log1[Mul(*k)] = log(logcombine(Mul(*[ l.args[0]**Mul(*c) for c, l in log1.pop(k)]), force=force), evaluate=False) # logs that have oppositely signed coefficients can divide for k in ordered(list(log1.keys())): if not k in log1: # already popped as -k continue if -k in log1: # figure out which has the minus sign; the one with # more op counts should be the one num, den = k, -k if num.count_ops() > den.count_ops(): num, den = den, num other.append( num*log(log1.pop(num).args[0]/log1.pop(den).args[0], evaluate=False)) else: other.append(k*log1.pop(k)) return Add(*other) return bottom_up(expr, f) def inversecombine(expr): """Simplify the composition of a function and its inverse. No attention is paid to whether the inverse is a left inverse or a right inverse; thus, the result will in general not be equivalent to the original expression. Examples ======== >>> from sympy.simplify.simplify import inversecombine >>> from sympy import asin, sin, log, exp >>> from sympy.abc import x >>> inversecombine(asin(sin(x))) x >>> inversecombine(2*log(exp(3*x))) 6*x """ def f(rv): if rv.is_Function and hasattr(rv, "inverse"): if (len(rv.args) == 1 and len(rv.args[0].args) == 1 and isinstance(rv.args[0], rv.inverse(argindex=1))): rv = rv.args[0].args[0] return rv return bottom_up(expr, f) def walk(e, *target): """iterate through the args that are the given types (target) and return a list of the args that were traversed; arguments that are not of the specified types are not traversed. Examples ======== >>> from sympy.simplify.simplify import walk >>> from sympy import Min, Max >>> from sympy.abc import x, y, z >>> list(walk(Min(x, Max(y, Min(1, z))), Min)) [Min(x, Max(y, Min(1, z)))] >>> list(walk(Min(x, Max(y, Min(1, z))), Min, Max)) [Min(x, Max(y, Min(1, z))), Max(y, Min(1, z)), Min(1, z)] See Also ======== bottom_up """ if isinstance(e, target): yield e for i in e.args: for w in walk(i, *target): yield w def bottom_up(rv, F, atoms=False, nonbasic=False): """Apply ``F`` to all expressions in an expression tree from the bottom up. If ``atoms`` is True, apply ``F`` even if there are no args; if ``nonbasic`` is True, try to apply ``F`` to non-Basic objects. """ args = getattr(rv, 'args', None) if args is not None: if args: args = tuple([bottom_up(a, F, atoms, nonbasic) for a in args]) if args != rv.args: rv = rv.func(*args) rv = F(rv) elif atoms: rv = F(rv) else: if nonbasic: try: rv = F(rv) except TypeError: pass return rv def besselsimp(expr): """ Simplify bessel-type functions. This routine tries to simplify bessel-type functions. Currently it only works on the Bessel J and I functions, however. It works by looking at all such functions in turn, and eliminating factors of "I" and "-1" (actually their polar equivalents) in front of the argument. Then, functions of half-integer order are rewritten using strigonometric functions and functions of integer order (> 1) are rewritten using functions of low order. Finally, if the expression was changed, compute factorization of the result with factor(). >>> from sympy import besselj, besseli, besselsimp, polar_lift, I, S >>> from sympy.abc import z, nu >>> besselsimp(besselj(nu, z*polar_lift(-1))) exp(I*pi*nu)*besselj(nu, z) >>> besselsimp(besseli(nu, z*polar_lift(-I))) exp(-I*pi*nu/2)*besselj(nu, z) >>> besselsimp(besseli(S(-1)/2, z)) sqrt(2)*cosh(z)/(sqrt(pi)*sqrt(z)) >>> besselsimp(z*besseli(0, z) + z*(besseli(2, z))/2 + besseli(1, z)) 3*z*besseli(0, z)/2 """ # TODO # - better algorithm? # - simplify (cos(pi*b)*besselj(b,z) - besselj(-b,z))/sin(pi*b) ... # - use contiguity relations? def replacer(fro, to, factors): factors = set(factors) def repl(nu, z): if factors.intersection(Mul.make_args(z)): return to(nu, z) return fro(nu, z) return repl def torewrite(fro, to): def tofunc(nu, z): return fro(nu, z).rewrite(to) return tofunc def tominus(fro): def tofunc(nu, z): return exp(I*pi*nu)*fro(nu, exp_polar(-I*pi)*z) return tofunc orig_expr = expr ifactors = [I, exp_polar(I*pi/2), exp_polar(-I*pi/2)] expr = expr.replace( besselj, replacer(besselj, torewrite(besselj, besseli), ifactors)) expr = expr.replace( besseli, replacer(besseli, torewrite(besseli, besselj), ifactors)) minusfactors = [-1, exp_polar(I*pi)] expr = expr.replace( besselj, replacer(besselj, tominus(besselj), minusfactors)) expr = expr.replace( besseli, replacer(besseli, tominus(besseli), minusfactors)) z0 = Dummy('z') def expander(fro): def repl(nu, z): if (nu % 1) == S(1)/2: return simplify(trigsimp(unpolarify( fro(nu, z0).rewrite(besselj).rewrite(jn).expand( func=True)).subs(z0, z))) elif nu.is_Integer and nu > 1: return fro(nu, z).expand(func=True) return fro(nu, z) return repl expr = expr.replace(besselj, expander(besselj)) expr = expr.replace(bessely, expander(bessely)) expr = expr.replace(besseli, expander(besseli)) expr = expr.replace(besselk, expander(besselk)) if expr != orig_expr: expr = expr.factor() return expr def nthroot(expr, n, max_len=4, prec=15): """ compute a real nth-root of a sum of surds Parameters ========== expr : sum of surds n : integer max_len : maximum number of surds passed as constants to ``nsimplify`` Algorithm ========= First ``nsimplify`` is used to get a candidate root; if it is not a root the minimal polynomial is computed; the answer is one of its roots. Examples ======== >>> from sympy.simplify.simplify import nthroot >>> from sympy import Rational, sqrt >>> nthroot(90 + 34*sqrt(7), 3) sqrt(7) + 3 """ expr = sympify(expr) n = sympify(n) p = expr**Rational(1, n) if not n.is_integer: return p if not _is_sum_surds(expr): return p surds = [] coeff_muls = [x.as_coeff_Mul() for x in expr.args] for x, y in coeff_muls: if not x.is_rational: return p if y is S.One: continue if not (y.is_Pow and y.exp == S.Half and y.base.is_integer): return p surds.append(y) surds.sort() surds = surds[:max_len] if expr < 0 and n % 2 == 1: p = (-expr)**Rational(1, n) a = nsimplify(p, constants=surds) res = a if _mexpand(a**n) == _mexpand(-expr) else p return -res a = nsimplify(p, constants=surds) if _mexpand(a) is not _mexpand(p) and _mexpand(a**n) == _mexpand(expr): return _mexpand(a) expr = _nthroot_solve(expr, n, prec) if expr is None: return p return expr def nsimplify(expr, constants=(), tolerance=None, full=False, rational=None, rational_conversion='base10'): """ Find a simple representation for a number or, if there are free symbols or if rational=True, then replace Floats with their Rational equivalents. If no change is made and rational is not False then Floats will at least be converted to Rationals. For numerical expressions, a simple formula that numerically matches the given numerical expression is sought (and the input should be possible to evalf to a precision of at least 30 digits). Optionally, a list of (rationally independent) constants to include in the formula may be given. A lower tolerance may be set to find less exact matches. If no tolerance is given then the least precise value will set the tolerance (e.g. Floats default to 15 digits of precision, so would be tolerance=10**-15). With full=True, a more extensive search is performed (this is useful to find simpler numbers when the tolerance is set low). When converting to rational, if rational_conversion='base10' (the default), then convert floats to rationals using their base-10 (string) representation. When rational_conversion='exact' it uses the exact, base-2 representation. Examples ======== >>> from sympy import nsimplify, sqrt, GoldenRatio, exp, I, exp, pi >>> nsimplify(4/(1+sqrt(5)), [GoldenRatio]) -2 + 2*GoldenRatio >>> nsimplify((1/(exp(3*pi*I/5)+1))) 1/2 - I*sqrt(sqrt(5)/10 + 1/4) >>> nsimplify(I**I, [pi]) exp(-pi/2) >>> nsimplify(pi, tolerance=0.01) 22/7 >>> nsimplify(0.333333333333333, rational=True, rational_conversion='exact') 6004799503160655/18014398509481984 >>> nsimplify(0.333333333333333, rational=True) 1/3 See Also ======== sympy.core.function.nfloat """ try: return sympify(as_int(expr)) except (TypeError, ValueError): pass expr = sympify(expr).xreplace({ Float('inf'): S.Infinity, Float('-inf'): S.NegativeInfinity, }) if expr is S.Infinity or expr is S.NegativeInfinity: return expr if rational or expr.free_symbols: return _real_to_rational(expr, tolerance, rational_conversion) # SymPy's default tolerance for Rationals is 15; other numbers may have # lower tolerances set, so use them to pick the largest tolerance if None # was given if tolerance is None: tolerance = 10**-min([15] + [mpmath.libmp.libmpf.prec_to_dps(n._prec) for n in expr.atoms(Float)]) # XXX should prec be set independent of tolerance or should it be computed # from tolerance? prec = 30 bprec = int(prec*3.33) constants_dict = {} for constant in constants: constant = sympify(constant) v = constant.evalf(prec) if not v.is_Float: raise ValueError("constants must be real-valued") constants_dict[str(constant)] = v._to_mpmath(bprec) exprval = expr.evalf(prec, chop=True) re, im = exprval.as_real_imag() # safety check to make sure that this evaluated to a number if not (re.is_Number and im.is_Number): return expr def nsimplify_real(x): orig = mpmath.mp.dps xv = x._to_mpmath(bprec) try: # We'll be happy with low precision if a simple fraction if not (tolerance or full): mpmath.mp.dps = 15 rat = mpmath.pslq([xv, 1]) if rat is not None: return Rational(-int(rat[1]), int(rat[0])) mpmath.mp.dps = prec newexpr = mpmath.identify(xv, constants=constants_dict, tol=tolerance, full=full) if not newexpr: raise ValueError if full: newexpr = newexpr[0] expr = sympify(newexpr) if x and not expr: # don't let x become 0 raise ValueError if expr.is_finite is False and not xv in [mpmath.inf, mpmath.ninf]: raise ValueError return expr finally: # even though there are returns above, this is executed # before leaving mpmath.mp.dps = orig try: if re: re = nsimplify_real(re) if im: im = nsimplify_real(im) except ValueError: if rational is None: return _real_to_rational(expr, rational_conversion=rational_conversion) return expr rv = re + im*S.ImaginaryUnit # if there was a change or rational is explicitly not wanted # return the value, else return the Rational representation if rv != expr or rational is False: return rv return _real_to_rational(expr, rational_conversion=rational_conversion) def _real_to_rational(expr, tolerance=None, rational_conversion='base10'): """ Replace all reals in expr with rationals. Examples ======== >>> from sympy import Rational >>> from sympy.simplify.simplify import _real_to_rational >>> from sympy.abc import x >>> _real_to_rational(.76 + .1*x**.5) sqrt(x)/10 + 19/25 If rational_conversion='base10', this uses the base-10 string. If rational_conversion='exact', the exact, base-2 representation is used. >>> _real_to_rational(0.333333333333333, rational_conversion='exact') 6004799503160655/18014398509481984 >>> _real_to_rational(0.333333333333333) 1/3 """ expr = _sympify(expr) inf = Float('inf') p = expr reps = {} reduce_num = None if tolerance is not None and tolerance < 1: reduce_num = ceiling(1/tolerance) for fl in p.atoms(Float): key = fl if reduce_num is not None: r = Rational(fl).limit_denominator(reduce_num) elif (tolerance is not None and tolerance >= 1 and fl.is_Integer is False): r = Rational(tolerance*round(fl/tolerance) ).limit_denominator(int(tolerance)) else: if rational_conversion == 'exact': r = Rational(fl) reps[key] = r continue elif rational_conversion != 'base10': raise ValueError("rational_conversion must be 'base10' or 'exact'") r = nsimplify(fl, rational=False) # e.g. log(3).n() -> log(3) instead of a Rational if fl and not r: r = Rational(fl) elif not r.is_Rational: if fl == inf or fl == -inf: r = S.ComplexInfinity elif fl < 0: fl = -fl d = Pow(10, int((mpmath.log(fl)/mpmath.log(10)))) r = -Rational(str(fl/d))*d elif fl > 0: d = Pow(10, int((mpmath.log(fl)/mpmath.log(10)))) r = Rational(str(fl/d))*d else: r = Integer(0) reps[key] = r return p.subs(reps, simultaneous=True) def clear_coefficients(expr, rhs=S.Zero): """Return `p, r` where `p` is the expression obtained when Rational additive and multiplicative coefficients of `expr` have been stripped away in a naive fashion (i.e. without simplification). The operations needed to remove the coefficients will be applied to `rhs` and returned as `r`. Examples ======== >>> from sympy.simplify.simplify import clear_coefficients >>> from sympy.abc import x, y >>> from sympy import Dummy >>> expr = 4*y*(6*x + 3) >>> clear_coefficients(expr - 2) (y*(2*x + 1), 1/6) When solving 2 or more expressions like `expr = a`, `expr = b`, etc..., it is advantageous to provide a Dummy symbol for `rhs` and simply replace it with `a`, `b`, etc... in `r`. >>> rhs = Dummy('rhs') >>> clear_coefficients(expr, rhs) (y*(2*x + 1), _rhs/12) >>> _[1].subs(rhs, 2) 1/6 """ was = None free = expr.free_symbols if expr.is_Rational: return (S.Zero, rhs - expr) while expr and was != expr: was = expr m, expr = ( expr.as_content_primitive() if free else factor_terms(expr).as_coeff_Mul(rational=True)) rhs /= m c, expr = expr.as_coeff_Add(rational=True) rhs -= c expr = signsimp(expr, evaluate = False) if _coeff_isneg(expr): expr = -expr rhs = -rhs return expr, rhs def nc_simplify(expr, deep=True): ''' Simplify a non-commutative expression composed of multiplication and raising to a power by grouping repeated subterms into one power. Priority is given to simplifications that give the fewest number of arguments in the end (for example, in a*b*a*b*c*a*b*c simplifying to (a*b)**2*c*a*b*c gives 5 arguments while a*b*(a*b*c)**2 has 3). If `expr` is a sum of such terms, the sum of the simplified terms is returned. Keyword argument `deep` controls whether or not subexpressions nested deeper inside the main expression are simplified. See examples below. Setting `deep` to `False` can save time on nested expressions that don't need simplifying on all levels. Examples ======== >>> from sympy import symbols >>> from sympy.simplify.simplify import nc_simplify >>> a, b, c = symbols("a b c", commutative=False) >>> nc_simplify(a*b*a*b*c*a*b*c) a*b*(a*b*c)**2 >>> expr = a**2*b*a**4*b*a**4 >>> nc_simplify(expr) a**2*(b*a**4)**2 >>> nc_simplify(a*b*a*b*c**2*(a*b)**2*c**2) ((a*b)**2*c**2)**2 >>> nc_simplify(a*b*a*b + 2*a*c*a**2*c*a**2*c*a) (a*b)**2 + 2*(a*c*a)**3 >>> nc_simplify(b**-1*a**-1*(a*b)**2) a*b >>> nc_simplify(a**-1*b**-1*c*a) (b*a)**(-1)*c*a >>> expr = (a*b*a*b)**2*a*c*a*c >>> nc_simplify(expr) (a*b)**4*(a*c)**2 >>> nc_simplify(expr, deep=False) (a*b*a*b)**2*(a*c)**2 ''' from sympy.matrices.expressions import (MatrixExpr, MatAdd, MatMul, MatPow, MatrixSymbol) from sympy.core.exprtools import factor_nc if isinstance(expr, MatrixExpr): expr = expr.doit(inv_expand=False) _Add, _Mul, _Pow, _Symbol = MatAdd, MatMul, MatPow, MatrixSymbol else: _Add, _Mul, _Pow, _Symbol = Add, Mul, Pow, Symbol # =========== Auxiliary functions ======================== def _overlaps(args): # Calculate a list of lists m such that m[i][j] contains the lengths # of all possible overlaps between args[:i+1] and args[i+1+j:]. # An overlap is a suffix of the prefix that matches a prefix # of the suffix. # For example, let expr=c*a*b*a*b*a*b*a*b. Then m[3][0] contains # the lengths of overlaps of c*a*b*a*b with a*b*a*b. The overlaps # are a*b*a*b, a*b and the empty word so that m[3][0]=[4,2,0]. # All overlaps rather than only the longest one are recorded # because this information helps calculate other overlap lengths. m = [[([1, 0] if a == args[0] else [0]) for a in args[1:]]] for i in range(1, len(args)): overlaps = [] j = 0 for j in range(len(args) - i - 1): overlap = [] for v in m[i-1][j+1]: if j + i + 1 + v < len(args) and args[i] == args[j+i+1+v]: overlap.append(v + 1) overlap += [0] overlaps.append(overlap) m.append(overlaps) return m def _reduce_inverses(_args): # replace consecutive negative powers by an inverse # of a product of positive powers, e.g. a**-1*b**-1*c # will simplify to (a*b)**-1*c; # return that new args list and the number of negative # powers in it (inv_tot) inv_tot = 0 # total number of inverses inverses = [] args = [] for arg in _args: if isinstance(arg, _Pow) and arg.args[1] < 0: inverses = [arg**-1] + inverses inv_tot += 1 else: if len(inverses) == 1: args.append(inverses[0]**-1) elif len(inverses) > 1: args.append(_Pow(_Mul(*inverses), -1)) inv_tot -= len(inverses) - 1 inverses = [] args.append(arg) if inverses: args.append(_Pow(_Mul(*inverses), -1)) inv_tot -= len(inverses) - 1 return inv_tot, tuple(args) def get_score(s): # compute the number of arguments of s # (including in nested expressions) overall # but ignore exponents if isinstance(s, _Pow): return get_score(s.args[0]) elif isinstance(s, (_Add, _Mul)): return sum([get_score(a) for a in s.args]) return 1 def compare(s, alt_s): # compare two possible simplifications and return a # "better" one if s != alt_s and get_score(alt_s) < get_score(s): return alt_s return s # ======================================================== if not isinstance(expr, (_Add, _Mul, _Pow)) or expr.is_commutative: return expr args = expr.args[:] if isinstance(expr, _Pow): if deep: return _Pow(nc_simplify(args[0]), args[1]).doit() else: return expr elif isinstance(expr, _Add): return _Add(*[nc_simplify(a, deep=deep) for a in args]).doit() else: # get the non-commutative part c_args, args = expr.args_cnc() com_coeff = Mul(*c_args) if com_coeff != 1: return com_coeff*nc_simplify(expr/com_coeff, deep=deep) inv_tot, args = _reduce_inverses(args) # if most arguments are negative, work with the inverse # of the expression, e.g. a**-1*b*a**-1*c**-1 will become # (c*a*b**-1*a)**-1 at the end so can work with c*a*b**-1*a invert = False if inv_tot > len(args)/2: invert = True args = [a**-1 for a in args[::-1]] if deep: args = tuple(nc_simplify(a) for a in args) m = _overlaps(args) # simps will be {subterm: end} where `end` is the ending # index of a sequence of repetitions of subterm; # this is for not wasting time with subterms that are part # of longer, already considered sequences simps = {} post = 1 pre = 1 # the simplification coefficient is the number of # arguments by which contracting a given sequence # would reduce the word; e.g. in a*b*a*b*c*a*b*c, # contracting a*b*a*b to (a*b)**2 removes 3 arguments # while a*b*c*a*b*c to (a*b*c)**2 removes 6. It's # better to contract the latter so simplification # with a maximum simplification coefficient will be chosen max_simp_coeff = 0 simp = None # information about future simplification for i in range(1, len(args)): simp_coeff = 0 l = 0 # length of a subterm p = 0 # the power of a subterm if i < len(args) - 1: rep = m[i][0] start = i # starting index of the repeated sequence end = i+1 # ending index of the repeated sequence if i == len(args)-1 or rep == [0]: # no subterm is repeated at this stage, at least as # far as the arguments are concerned - there may be # a repetition if powers are taken into account if (isinstance(args[i], _Pow) and not isinstance(args[i].args[0], _Symbol)): subterm = args[i].args[0].args l = len(subterm) if args[i-l:i] == subterm: # e.g. a*b in a*b*(a*b)**2 is not repeated # in args (= [a, b, (a*b)**2]) but it # can be matched here p += 1 start -= l if args[i+1:i+1+l] == subterm: # e.g. a*b in (a*b)**2*a*b p += 1 end += l if p: p += args[i].args[1] else: continue else: l = rep[0] # length of the longest repeated subterm at this point start -= l - 1 subterm = args[start:end] p = 2 end += l if subterm in simps and simps[subterm] >= start: # the subterm is part of a sequence that # has already been considered continue # count how many times it's repeated while end < len(args): if l in m[end-1][0]: p += 1 end += l elif isinstance(args[end], _Pow) and args[end].args[0].args == subterm: # for cases like a*b*a*b*(a*b)**2*a*b p += args[end].args[1] end += 1 else: break # see if another match can be made, e.g. # for b*a**2 in b*a**2*b*a**3 or a*b in # a**2*b*a*b pre_exp = 0 pre_arg = 1 if start - l >= 0 and args[start-l+1:start] == subterm[1:]: if isinstance(subterm[0], _Pow): pre_arg = subterm[0].args[0] exp = subterm[0].args[1] else: pre_arg = subterm[0] exp = 1 if isinstance(args[start-l], _Pow) and args[start-l].args[0] == pre_arg: pre_exp = args[start-l].args[1] - exp start -= l p += 1 elif args[start-l] == pre_arg: pre_exp = 1 - exp start -= l p += 1 post_exp = 0 post_arg = 1 if end + l - 1 < len(args) and args[end:end+l-1] == subterm[:-1]: if isinstance(subterm[-1], _Pow): post_arg = subterm[-1].args[0] exp = subterm[-1].args[1] else: post_arg = subterm[-1] exp = 1 if isinstance(args[end+l-1], _Pow) and args[end+l-1].args[0] == post_arg: post_exp = args[end+l-1].args[1] - exp end += l p += 1 elif args[end+l-1] == post_arg: post_exp = 1 - exp end += l p += 1 # Consider a*b*a**2*b*a**2*b*a: # b*a**2 is explicitly repeated, but note # that in this case a*b*a is also repeated # so there are two possible simplifications: # a*(b*a**2)**3*a**-1 or (a*b*a)**3 # The latter is obviously simpler. # But in a*b*a**2*b**2*a**2 the simplifications are # a*(b*a**2)**2 and (a*b*a)**3*a in which case # it's better to stick with the shorter subterm if post_exp and exp % 2 == 0 and start > 0: exp = exp/2 _pre_exp = 1 _post_exp = 1 if isinstance(args[start-1], _Pow) and args[start-1].args[0] == post_arg: _post_exp = post_exp + exp _pre_exp = args[start-1].args[1] - exp elif args[start-1] == post_arg: _post_exp = post_exp + exp _pre_exp = 1 - exp if _pre_exp == 0 or _post_exp == 0: if not pre_exp: start -= 1 post_exp = _post_exp pre_exp = _pre_exp pre_arg = post_arg subterm = (post_arg**exp,) + subterm[:-1] + (post_arg**exp,) simp_coeff += end-start if post_exp: simp_coeff -= 1 if pre_exp: simp_coeff -= 1 simps[subterm] = end if simp_coeff > max_simp_coeff: max_simp_coeff = simp_coeff simp = (start, _Mul(*subterm), p, end, l) pre = pre_arg**pre_exp post = post_arg**post_exp if simp: subterm = _Pow(nc_simplify(simp[1], deep=deep), simp[2]) pre = nc_simplify(_Mul(*args[:simp[0]])*pre, deep=deep) post = post*nc_simplify(_Mul(*args[simp[3]:]), deep=deep) simp = pre*subterm*post if pre != 1 or post != 1: # new simplifications may be possible but no need # to recurse over arguments simp = nc_simplify(simp, deep=False) else: simp = _Mul(*args) if invert: simp = _Pow(simp, -1) # see if factor_nc(expr) is simplified better if not isinstance(expr, MatrixExpr): f_expr = factor_nc(expr) if f_expr != expr: alt_simp = nc_simplify(f_expr, deep=deep) simp = compare(simp, alt_simp) else: simp = simp.doit(inv_expand=False) return simp

8403ddb547b404cf3814f307315c376ee2301170f5d325440fb3ca7f9d74f305

import bisect import itertools from functools import reduce from collections import defaultdict from sympy import Indexed, IndexedBase, Tuple, Sum, Add, S, Integer, diagonalize_vector, DiagonalizeVector from sympy.combinatorics import Permutation from sympy.core.basic import Basic from sympy.core.compatibility import accumulate, default_sort_key from sympy.core.mul import Mul from sympy.core.sympify import _sympify from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.matrices.expressions import (MatAdd, MatMul, Trace, Transpose, MatrixSymbol) from sympy.matrices.expressions.matexpr import MatrixExpr, MatrixElement from sympy.tensor.array import NDimArray class _CodegenArrayAbstract(Basic): @property def subranks(self): """ Returns the ranks of the objects in the uppermost tensor product inside the current object. In case no tensor products are contained, return the atomic ranks. Examples ======== >>> from sympy.codegen.array_utils import CodegenArrayTensorProduct, CodegenArrayContraction >>> from sympy import MatrixSymbol >>> M = MatrixSymbol("M", 3, 3) >>> N = MatrixSymbol("N", 3, 3) >>> P = MatrixSymbol("P", 3, 3) Important: do not confuse the rank of the matrix with the rank of an array. >>> tp = CodegenArrayTensorProduct(M, N, P) >>> tp.subranks [2, 2, 2] >>> co = CodegenArrayContraction(tp, (1, 2), (3, 4)) >>> co.subranks [2, 2, 2] """ return self._subranks[:] def subrank(self): """ The sum of ``subranks``. """ return sum(self.subranks) @property def shape(self): return self._shape class CodegenArrayContraction(_CodegenArrayAbstract): r""" This class is meant to represent contractions of arrays in a form easily processable by the code printers. """ def __new__(cls, expr, *contraction_indices, **kwargs): contraction_indices = _sort_contraction_indices(contraction_indices) expr = _sympify(expr) if len(contraction_indices) == 0: return expr if isinstance(expr, CodegenArrayContraction): return cls._flatten(expr, *contraction_indices) obj = Basic.__new__(cls, expr, *contraction_indices) obj._subranks = _get_subranks(expr) obj._mapping = _get_mapping_from_subranks(obj._subranks) free_indices_to_position = {i: i for i in range(sum(obj._subranks)) if all([i not in cind for cind in contraction_indices])} obj._free_indices_to_position = free_indices_to_position shape = expr.shape cls._validate(expr, *contraction_indices) if shape: shape = tuple(shp for i, shp in enumerate(shape) if not any(i in j for j in contraction_indices)) obj._shape = shape return obj @staticmethod def _validate(expr, *contraction_indices): shape = expr.shape if shape is None: return # Check that no contraction happens when the shape is mismatched: for i in contraction_indices: if len(set(shape[j] for j in i if shape[j] != -1)) != 1: raise ValueError("contracting indices of different dimensions") @classmethod def _push_indices_down(cls, contraction_indices, indices): flattened_contraction_indices = [j for i in contraction_indices for j in i] flattened_contraction_indices.sort() transform = _build_push_indices_down_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) @classmethod def _push_indices_up(cls, contraction_indices, indices): flattened_contraction_indices = [j for i in contraction_indices for j in i] flattened_contraction_indices.sort() transform = _build_push_indices_up_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) def split_multiple_contractions(self): """ Recognize multiple contractions and attempt at rewriting them as paired-contractions. """ from sympy import ask, Q contraction_indices = self.contraction_indices if isinstance(self.expr, CodegenArrayTensorProduct): args = list(self.expr.args) else: args = [self.expr] # TODO: unify API, best location in CodegenArrayTensorProduct subranks = [get_rank(i) for i in args] # TODO: unify API mapping = _get_mapping_from_subranks(subranks) reverse_mapping = {v:k for k, v in mapping.items()} new_contraction_indices = [] for indl, links in enumerate(contraction_indices): if len(links) <= 2: new_contraction_indices.append(links) continue # Check multiple contractions: # # Examples: # # * `A_ij b_j0 C_jk` ===> `A*DiagonalizeVector(b)*C` # # Care for: # - matrix being diagonalized (i.e. `A_ii`) # - vectors being diagonalized (i.e. `a_i0`) # Also consider the case of diagonal matrices being contracted: current_dimension = self.expr.shape[links[0]] tuple_links = [mapping[i] for i in links] arg_indices, arg_positions = zip(*tuple_links) args_updates = {} if len(arg_indices) != len(set(arg_indices)): # Maybe trace should be supported? raise NotImplementedError not_vectors = [] vectors = [] for arg_ind, arg_pos in tuple_links: mat = args[arg_ind] other_arg_pos = 1-arg_pos other_arg_abs = reverse_mapping[arg_ind, other_arg_pos] if (((1 not in mat.shape) and (not ask(Q.diagonal(mat)))) or ((current_dimension == 1) is True and mat.shape != (1, 1)) or any([other_arg_abs in l for li, l in enumerate(contraction_indices) if li != indl]) ): not_vectors.append((arg_ind, arg_pos)) continue args_updates[arg_ind] = diagonalize_vector(mat) vectors.append((arg_ind, arg_pos)) vectors.append((arg_ind, 1-arg_pos)) if len(not_vectors) > 2: new_contraction_indices.append(links) continue if len(not_vectors) == 0: new_sequence = vectors[:1] + vectors[2:] elif len(not_vectors) == 1: new_sequence = not_vectors[:1] + vectors[:-1] else: new_sequence = not_vectors[:1] + vectors + not_vectors[1:] for i in range(0, len(new_sequence) - 1, 2): arg1, pos1 = new_sequence[i] arg2, pos2 = new_sequence[i+1] if arg1 == arg2: raise NotImplementedError continue abspos1 = reverse_mapping[arg1, pos1] abspos2 = reverse_mapping[arg2, pos2] new_contraction_indices.append((abspos1, abspos2)) for ind, newarg in args_updates.items(): args[ind] = newarg return CodegenArrayContraction( CodegenArrayTensorProduct(*args), *new_contraction_indices ) def flatten_contraction_of_diagonal(self): if not isinstance(self.expr, CodegenArrayDiagonal): return self contraction_down = self.expr._push_indices_down(self.expr.diagonal_indices, self.contraction_indices) new_contraction_indices = [] diagonal_indices = self.expr.diagonal_indices[:] for i in contraction_down: contraction_group = list(i) for j in i: diagonal_with = [k for k in diagonal_indices if j in k] contraction_group.extend([l for k in diagonal_with for l in k]) diagonal_indices = [k for k in diagonal_indices if k not in diagonal_with] new_contraction_indices.append(sorted(set(contraction_group))) new_contraction_indices = CodegenArrayDiagonal._push_indices_up(diagonal_indices, new_contraction_indices) return CodegenArrayContraction( CodegenArrayDiagonal( self.expr.expr, *diagonal_indices ), *new_contraction_indices ) @staticmethod def _get_free_indices_to_position_map(free_indices, contraction_indices): free_indices_to_position = {} flattened_contraction_indices = [j for i in contraction_indices for j in i] counter = 0 for ind in free_indices: while counter in flattened_contraction_indices: counter += 1 free_indices_to_position[ind] = counter counter += 1 return free_indices_to_position @staticmethod def _get_index_shifts(expr): """ Get the mapping of indices at the positions before the contraction occures. Examples ======== >>> from sympy.codegen.array_utils import CodegenArrayContraction, CodegenArrayTensorProduct >>> from sympy import MatrixSymbol >>> M = MatrixSymbol("M", 3, 3) >>> N = MatrixSymbol("N", 3, 3) >>> cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), [1, 2]) >>> cg._get_index_shifts(cg) [0, 2] Indeed, ``cg`` after the contraction has two dimensions, 0 and 1. They need to be shifted by 0 and 2 to get the corresponding positions before the contraction (that is, 0 and 3). """ inner_contraction_indices = expr.contraction_indices all_inner = [j for i in inner_contraction_indices for j in i] all_inner.sort() # TODO: add API for total rank and cumulative rank: total_rank = get_rank(expr) inner_rank = len(all_inner) outer_rank = total_rank - inner_rank shifts = [0 for i in range(outer_rank)] counter = 0 pointer = 0 for i in range(outer_rank): while pointer < inner_rank and counter >= all_inner[pointer]: counter += 1 pointer += 1 shifts[i] += pointer counter += 1 return shifts @staticmethod def _convert_outer_indices_to_inner_indices(expr, *outer_contraction_indices): shifts = CodegenArrayContraction._get_index_shifts(expr) outer_contraction_indices = tuple(tuple(shifts[j] + j for j in i) for i in outer_contraction_indices) return outer_contraction_indices @staticmethod def _flatten(expr, *outer_contraction_indices): inner_contraction_indices = expr.contraction_indices outer_contraction_indices = CodegenArrayContraction._convert_outer_indices_to_inner_indices(expr, *outer_contraction_indices) contraction_indices = inner_contraction_indices + outer_contraction_indices return CodegenArrayContraction(expr.expr, *contraction_indices) def _get_contraction_tuples(self): r""" Return tuples containing the argument index and position within the argument of the index position. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction, CodegenArrayTensorProduct >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (1, 2)) >>> cg._get_contraction_tuples() [[(0, 1), (1, 0)]] Here the contraction pair `(1, 2)` meaning that the 2nd and 3rd indices of the tensor product `A\otimes B` are contracted, has been transformed into `(0, 1)` and `(1, 0)`, identifying the same indices in a different notation. `(0, 1)` is the second index (1) of the first argument (i.e. 0 or `A`). `(1, 0)` is the first index (i.e. 0) of the second argument (i.e. 1 or `B`). """ mapping = self._mapping return [[mapping[j] for j in i] for i in self.contraction_indices] @staticmethod def _contraction_tuples_to_contraction_indices(expr, contraction_tuples): # TODO: check that `expr` has `.subranks`: ranks = expr.subranks cumulative_ranks = [0] + list(accumulate(ranks)) return [tuple(cumulative_ranks[j]+k for j, k in i) for i in contraction_tuples] @property def free_indices(self): return self._free_indices[:] @property def free_indices_to_position(self): return dict(self._free_indices_to_position) @property def expr(self): return self.args[0] @property def contraction_indices(self): return self.args[1:] def _contraction_indices_to_components(self): expr = self.expr if not isinstance(expr, CodegenArrayTensorProduct): raise NotImplementedError("only for contractions of tensor products") ranks = expr.subranks mapping = {} counter = 0 for i, rank in enumerate(ranks): for j in range(rank): mapping[counter] = (i, j) counter += 1 return mapping def sort_args_by_name(self): """ Sort arguments in the tensor product so that their order is lexicographical. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> C = MatrixSymbol("C", N, N) >>> D = MatrixSymbol("D", N, N) >>> cg = CodegenArrayContraction.from_MatMul(C*D*A*B) >>> cg CodegenArrayContraction(CodegenArrayTensorProduct(C, D, A, B), (1, 2), (3, 4), (5, 6)) >>> cg.sort_args_by_name() CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C, D), (0, 7), (1, 2), (5, 6)) """ expr = self.expr if not isinstance(expr, CodegenArrayTensorProduct): return self args = expr.args sorted_data = sorted(enumerate(args), key=lambda x: default_sort_key(x[1])) pos_sorted, args_sorted = zip(*sorted_data) reordering_map = {i: pos_sorted.index(i) for i, arg in enumerate(args)} contraction_tuples = self._get_contraction_tuples() contraction_tuples = [[(reordering_map[j], k) for j, k in i] for i in contraction_tuples] c_tp = CodegenArrayTensorProduct(*args_sorted) new_contr_indices = self._contraction_tuples_to_contraction_indices( c_tp, contraction_tuples ) return CodegenArrayContraction(c_tp, *new_contr_indices) def _get_contraction_links(self): r""" Returns a dictionary of links between arguments in the tensor product being contracted. See the example for an explanation of the values. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> C = MatrixSymbol("C", N, N) >>> D = MatrixSymbol("D", N, N) Matrix multiplications are pairwise contractions between neighboring matrices: `A_{ij} B_{jk} C_{kl} D_{lm}` >>> cg = CodegenArrayContraction.from_MatMul(A*B*C*D) >>> cg CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C, D), (1, 2), (3, 4), (5, 6)) >>> cg._get_contraction_links() {0: {1: (1, 0)}, 1: {0: (0, 1), 1: (2, 0)}, 2: {0: (1, 1), 1: (3, 0)}, 3: {0: (2, 1)}} This dictionary is interpreted as follows: argument in position 0 (i.e. matrix `A`) has its second index (i.e. 1) contracted to `(1, 0)`, that is argument in position 1 (matrix `B`) on the first index slot of `B`, this is the contraction provided by the index `j` from `A`. The argument in position 1 (that is, matrix `B`) has two contractions, the ones provided by the indices `j` and `k`, respectively the first and second indices (0 and 1 in the sub-dict). The link `(0, 1)` and `(2, 0)` respectively. `(0, 1)` is the index slot 1 (the 2nd) of argument in position 0 (that is, `A_{\ldot j}`), and so on. """ args, dlinks = _get_contraction_links([self], self.subranks, *self.contraction_indices) return dlinks @staticmethod def from_MatMul(expr): args_nonmat = [] args = [] contractions = [] for arg in expr.args: if isinstance(arg, MatrixExpr): args.append(arg) else: args_nonmat.append(arg) contractions = [(2*i+1, 2*i+2) for i in range(len(args)-1)] return Mul.fromiter(args_nonmat)*CodegenArrayContraction( CodegenArrayTensorProduct(*args), *contractions ) def get_shape(expr): if hasattr(expr, "shape"): return expr.shape return () class CodegenArrayTensorProduct(_CodegenArrayAbstract): r""" Class to represent the tensor product of array-like objects. """ def __new__(cls, *args): args = [_sympify(arg) for arg in args] args = cls._flatten(args) ranks = [get_rank(arg) for arg in args] if len(args) == 1: return args[0] # If there are contraction objects inside, transform the whole # expression into `CodegenArrayContraction`: contractions = {i: arg for i, arg in enumerate(args) if isinstance(arg, CodegenArrayContraction)} if contractions: cumulative_ranks = list(accumulate([0] + ranks))[:-1] tp = cls(*[arg.expr if isinstance(arg, CodegenArrayContraction) else arg for arg in args]) contraction_indices = [tuple(cumulative_ranks[i] + k for k in j) for i, arg in contractions.items() for j in arg.contraction_indices] return CodegenArrayContraction(tp, *contraction_indices) #newargs = [i for i in args if hasattr(i, "shape")] #coeff = reduce(lambda x, y: x*y, [i for i in args if not hasattr(i, "shape")], S.One) #newargs[0] *= coeff obj = Basic.__new__(cls, *args) obj._subranks = ranks shapes = [get_shape(i) for i in args] if any(i is None for i in shapes): obj._shape = None else: obj._shape = tuple(j for i in shapes for j in i) return obj @classmethod def _flatten(cls, args): args = [i for arg in args for i in (arg.args if isinstance(arg, cls) else [arg])] return args class CodegenArrayElementwiseAdd(_CodegenArrayAbstract): r""" Class for elementwise array additions. """ def __new__(cls, *args): args = [_sympify(arg) for arg in args] obj = Basic.__new__(cls, *args) ranks = [get_rank(arg) for arg in args] ranks = list(set(ranks)) if len(ranks) != 1: raise ValueError("summing arrays of different ranks") obj._subranks = ranks shapes = [arg.shape for arg in args] if len(set([i for i in shapes if i is not None])) > 1: raise ValueError("mismatching shapes in addition") if any(i is None for i in shapes): obj._shape = None else: obj._shape = shapes[0] return obj class CodegenArrayPermuteDims(_CodegenArrayAbstract): r""" Class to represent permutation of axes of arrays. Examples ======== >>> from sympy.codegen.array_utils import CodegenArrayPermuteDims >>> from sympy import MatrixSymbol >>> M = MatrixSymbol("M", 3, 3) >>> cg = CodegenArrayPermuteDims(M, [1, 0]) The object ``cg`` represents the transposition of ``M``, as the permutation ``[1, 0]`` will act on its indices by switching them: `M_{ij} \Rightarrow M_{ji}` This is evident when transforming back to matrix form: >>> from sympy.codegen.array_utils import recognize_matrix_expression >>> recognize_matrix_expression(cg) M.T >>> N = MatrixSymbol("N", 3, 2) >>> cg = CodegenArrayPermuteDims(N, [1, 0]) >>> cg.shape (2, 3) """ def __new__(cls, expr, permutation): from sympy.combinatorics import Permutation expr = _sympify(expr) permutation = Permutation(permutation) plist = permutation.args[0] if plist == sorted(plist): return expr obj = Basic.__new__(cls, expr, permutation) obj._subranks = [get_rank(expr)] shape = expr.shape if shape is None: obj._shape = None else: obj._shape = tuple(shape[permutation(i)] for i in range(len(shape))) return obj @property def expr(self): return self.args[0] @property def permutation(self): return self.args[1] def nest_permutation(self): r""" Nest the permutation down the expression tree. Examples ======== >>> from sympy.codegen.array_utils import (CodegenArrayPermuteDims, CodegenArrayTensorProduct, nest_permutation) >>> from sympy import MatrixSymbol >>> from sympy.combinatorics import Permutation >>> Permutation.print_cyclic = True >>> M = MatrixSymbol("M", 3, 3) >>> N = MatrixSymbol("N", 3, 3) >>> cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [1, 0, 3, 2]) >>> cg CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), (0 1)(2 3)) >>> nest_permutation(cg) CodegenArrayTensorProduct(CodegenArrayPermuteDims(M, (0 1)), CodegenArrayPermuteDims(N, (0 1))) In ``cg`` both ``M`` and ``N`` are transposed. The cyclic representation of the permutation after the tensor product is `(0 1)(2 3)`. After nesting it down the expression tree, the usual transposition permutation `(0 1)` appears. """ expr = self.expr if isinstance(expr, CodegenArrayTensorProduct): # Check if the permutation keeps the subranks separated: subranks = expr.subranks subrank = expr.subrank() l = list(range(subrank)) p = [self.permutation(i) for i in l] dargs = {} counter = 0 for i, arg in zip(subranks, expr.args): p0 = p[counter:counter+i] counter += i s0 = sorted(p0) if not all([s0[j+1]-s0[j] == 1 for j in range(len(s0)-1)]): # Cross-argument permutations, impossible to nest the object: return self subpermutation = [p0.index(j) for j in s0] dargs[s0[0]] = CodegenArrayPermuteDims(arg, subpermutation) # Read the arguments sorting the according to the keys of the dict: args = [dargs[i] for i in sorted(dargs)] return CodegenArrayTensorProduct(*args) elif isinstance(expr, CodegenArrayContraction): # Invert tree hierarchy: put the contraction above. cycles = self.permutation.cyclic_form newcycles = CodegenArrayContraction._convert_outer_indices_to_inner_indices(expr, *cycles) newpermutation = Permutation(newcycles) new_contr_indices = [tuple(newpermutation(j) for j in i) for i in expr.contraction_indices] return CodegenArrayContraction(CodegenArrayPermuteDims(expr.expr, newpermutation), *new_contr_indices) elif isinstance(expr, CodegenArrayElementwiseAdd): return CodegenArrayElementwiseAdd(*[CodegenArrayPermuteDims(arg, self.permutation) for arg in expr.args]) return self def nest_permutation(expr): if isinstance(expr, CodegenArrayPermuteDims): return expr.nest_permutation() else: return expr class CodegenArrayDiagonal(_CodegenArrayAbstract): r""" Class to represent the diagonal operator. In a 2-dimensional array it returns the diagonal, this looks like the operation: `A_{ij} \rightarrow A_{ii}` The diagonal over axes 1 and 2 (the second and third) of the tensor product of two 2-dimensional arrays `A \otimes B` is `\Big[ A_{ab} B_{cd} \Big]_{abcd} \rightarrow \Big[ A_{ai} B_{id} \Big]_{adi}` In this last example the array expression has been reduced from 4-dimensional to 3-dimensional. Notice that no contraction has occurred, rather there is a new index `i` for the diagonal, contraction would have reduced the array to 2 dimensions. Notice that the diagonalized out dimensions are added as new dimensions at the end of the indices. """ def __new__(cls, expr, *diagonal_indices): expr = _sympify(expr) diagonal_indices = [Tuple(*sorted(i)) for i in diagonal_indices] if isinstance(expr, CodegenArrayDiagonal): return cls._flatten(expr, *diagonal_indices) shape = expr.shape if shape is not None: diagonal_indices = [i for i in diagonal_indices if len(i) > 1] cls._validate(expr, *diagonal_indices) #diagonal_indices = cls._remove_trivial_dimensions(shape, *diagonal_indices) # Get new shape: shp1 = tuple(shp for i,shp in enumerate(shape) if not any(i in j for j in diagonal_indices)) shp2 = tuple(shape[i[0]] for i in diagonal_indices) shape = shp1 + shp2 if len(diagonal_indices) == 0: return expr obj = Basic.__new__(cls, expr, *diagonal_indices) obj._subranks = _get_subranks(expr) obj._shape = shape return obj @staticmethod def _validate(expr, *diagonal_indices): # Check that no diagonalization happens on indices with mismatched # dimensions: shape = expr.shape for i in diagonal_indices: if len(set(shape[j] for j in i)) != 1: raise ValueError("diagonalizing indices of different dimensions") @staticmethod def _remove_trivial_dimensions(shape, *diagonal_indices): return [tuple(j for j in i) for i in diagonal_indices if shape[i[0]] != 1] @property def expr(self): return self.args[0] @property def diagonal_indices(self): return self.args[1:] @staticmethod def _flatten(expr, *outer_diagonal_indices): inner_diagonal_indices = expr.diagonal_indices all_inner = [j for i in inner_diagonal_indices for j in i] all_inner.sort() # TODO: add API for total rank and cumulative rank: total_rank = get_rank(expr) inner_rank = len(all_inner) outer_rank = total_rank - inner_rank shifts = [0 for i in range(outer_rank)] counter = 0 pointer = 0 for i in range(outer_rank): while pointer < inner_rank and counter >= all_inner[pointer]: counter += 1 pointer += 1 shifts[i] += pointer counter += 1 outer_diagonal_indices = tuple(tuple(shifts[j] + j for j in i) for i in outer_diagonal_indices) diagonal_indices = inner_diagonal_indices + outer_diagonal_indices return CodegenArrayDiagonal(expr.expr, *diagonal_indices) @classmethod def _push_indices_down(cls, diagonal_indices, indices): flattened_contraction_indices = [j for i in diagonal_indices for j in i[1:]] flattened_contraction_indices.sort() transform = _build_push_indices_down_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) @classmethod def _push_indices_up(cls, diagonal_indices, indices): flattened_contraction_indices = [j for i in diagonal_indices for j in i[1:]] flattened_contraction_indices.sort() transform = _build_push_indices_up_func_transformation(flattened_contraction_indices) return _apply_recursively_over_nested_lists(transform, indices) def transform_to_product(self): from sympy import ask, Q diagonal_indices = self.diagonal_indices if isinstance(self.expr, CodegenArrayContraction): # invert Diagonal and Contraction: diagonal_down = CodegenArrayContraction._push_indices_down( self.expr.contraction_indices, diagonal_indices ) newexpr = CodegenArrayDiagonal( self.expr.expr, *diagonal_down ).transform_to_product() contraction_up = newexpr._push_indices_up( diagonal_down, self.expr.contraction_indices ) return CodegenArrayContraction( newexpr, *contraction_up ) if not isinstance(self.expr, CodegenArrayTensorProduct): return self args = list(self.expr.args) # TODO: unify API subranks = [get_rank(i) for i in args] # TODO: unify API mapping = _get_mapping_from_subranks(subranks) new_contraction_indices = [] drop_diagonal_indices = [] for indl, links in enumerate(diagonal_indices): if len(links) > 2: continue # Also consider the case of diagonal matrices being contracted: current_dimension = self.expr.shape[links[0]] if current_dimension == 1: drop_diagonal_indices.append(indl) continue tuple_links = [mapping[i] for i in links] arg_indices, arg_positions = zip(*tuple_links) if len(arg_indices) != len(set(arg_indices)): # Maybe trace should be supported? raise NotImplementedError args_updates = {} count_nondiagonal = 0 last = None expression_is_square = False # Check that all args are vectors: for arg_ind, arg_pos in tuple_links: mat = args[arg_ind] if 1 in mat.shape and mat.shape != (1, 1): args_updates[arg_ind] = DiagonalizeVector(mat) last = arg_ind else: expression_is_square = True if not ask(Q.diagonal(mat)): count_nondiagonal += 1 if count_nondiagonal > 1: break if count_nondiagonal > 1: continue # TODO: if count_nondiagonal == 0 then the sub-expression can be recognized as HadamardProduct. for arg_ind, newmat in args_updates.items(): if not expression_is_square and arg_ind == last: continue #pass args[arg_ind] = newmat drop_diagonal_indices.append(indl) new_contraction_indices.append(links) new_diagonal_indices = CodegenArrayContraction._push_indices_up( new_contraction_indices, [e for i, e in enumerate(diagonal_indices) if i not in drop_diagonal_indices] ) return CodegenArrayDiagonal( CodegenArrayContraction( CodegenArrayTensorProduct(*args), *new_contraction_indices ), *new_diagonal_indices ) def get_rank(expr): if isinstance(expr, (MatrixExpr, MatrixElement)): return 2 if isinstance(expr, _CodegenArrayAbstract): return expr.subrank() if isinstance(expr, NDimArray): return expr.rank() if isinstance(expr, Indexed): return expr.rank if isinstance(expr, IndexedBase): shape = expr.shape if shape is None: return -1 else: return len(shape) if isinstance(expr, _RecognizeMatOp): return expr.rank() if isinstance(expr, _RecognizeMatMulLines): return expr.rank() return 0 def _get_subranks(expr): if isinstance(expr, _CodegenArrayAbstract): return expr.subranks else: return [get_rank(expr)] def _get_mapping_from_subranks(subranks): mapping = {} counter = 0 for i, rank in enumerate(subranks): for j in range(rank): mapping[counter] = (i, j) counter += 1 return mapping def _get_contraction_links(args, subranks, *contraction_indices): mapping = _get_mapping_from_subranks(subranks) contraction_tuples = [[mapping[j] for j in i] for i in contraction_indices] dlinks = defaultdict(dict) for links in contraction_tuples: if len(links) == 2: (arg1, pos1), (arg2, pos2) = links dlinks[arg1][pos1] = (arg2, pos2) dlinks[arg2][pos2] = (arg1, pos1) continue return args, dict(dlinks) def _sort_contraction_indices(pairing_indices): pairing_indices = [Tuple(*sorted(i)) for i in pairing_indices] pairing_indices.sort(key=lambda x: min(x)) return pairing_indices def _get_diagonal_indices(flattened_indices): axes_contraction = defaultdict(list) for i, ind in enumerate(flattened_indices): if isinstance(ind, (int, Integer)): # If the indices is a number, there can be no diagonal operation: continue axes_contraction[ind].append(i) axes_contraction = {k: v for k, v in axes_contraction.items() if len(v) > 1} # Put the diagonalized indices at the end: ret_indices = [i for i in flattened_indices if i not in axes_contraction] diag_indices = list(axes_contraction) diag_indices.sort(key=lambda x: flattened_indices.index(x)) diagonal_indices = [tuple(axes_contraction[i]) for i in diag_indices] ret_indices += diag_indices ret_indices = tuple(ret_indices) return diagonal_indices, ret_indices def _get_argindex(subindices, ind): for i, sind in enumerate(subindices): if ind == sind: return i if isinstance(sind, (set, frozenset)) and ind in sind: return i raise IndexError("%s not found in %s" % (ind, subindices)) def _codegen_array_parse(expr): if isinstance(expr, Sum): function = expr.function summation_indices = expr.variables subexpr, subindices = _codegen_array_parse(function) # Check dimensional consistency: shape = subexpr.shape if shape: for ind, istart, iend in expr.limits: i = _get_argindex(subindices, ind) if istart != 0 or iend+1 != shape[i]: raise ValueError("summation index and array dimension mismatch: %s" % ind) contraction_indices = [] subindices = list(subindices) if isinstance(subexpr, CodegenArrayDiagonal): diagonal_indices = list(subexpr.diagonal_indices) dindices = subindices[-len(diagonal_indices):] subindices = subindices[:-len(diagonal_indices)] for index in summation_indices: if index in dindices: position = dindices.index(index) contraction_indices.append(diagonal_indices[position]) diagonal_indices[position] = None diagonal_indices = [i for i in diagonal_indices if i is not None] for i, ind in enumerate(subindices): if ind in summation_indices: pass if diagonal_indices: subexpr = CodegenArrayDiagonal(subexpr.expr, *diagonal_indices) else: subexpr = subexpr.expr axes_contraction = defaultdict(list) for i, ind in enumerate(subindices): if ind in summation_indices: axes_contraction[ind].append(i) subindices[i] = None for k, v in axes_contraction.items(): contraction_indices.append(tuple(v)) free_indices = [i for i in subindices if i is not None] indices_ret = list(free_indices) indices_ret.sort(key=lambda x: free_indices.index(x)) return CodegenArrayContraction( subexpr, *contraction_indices, free_indices=free_indices ), tuple(indices_ret) if isinstance(expr, Mul): args, indices = zip(*[_codegen_array_parse(arg) for arg in expr.args]) # Check if there are KroneckerDelta objects: kronecker_delta_repl = {} for arg in args: if not isinstance(arg, KroneckerDelta): continue # Diagonalize two indices: i, j = arg.indices kindices = set(arg.indices) if i in kronecker_delta_repl: kindices.update(kronecker_delta_repl[i]) if j in kronecker_delta_repl: kindices.update(kronecker_delta_repl[j]) kindices = frozenset(kindices) for index in kindices: kronecker_delta_repl[index] = kindices # Remove KroneckerDelta objects, their relations should be handled by # CodegenArrayDiagonal: newargs = [] newindices = [] for arg, loc_indices in zip(args, indices): if isinstance(arg, KroneckerDelta): continue newargs.append(arg) newindices.append(loc_indices) flattened_indices = [kronecker_delta_repl.get(j, j) for i in newindices for j in i] diagonal_indices, ret_indices = _get_diagonal_indices(flattened_indices) tp = CodegenArrayTensorProduct(*newargs) if diagonal_indices: return (CodegenArrayDiagonal(tp, *diagonal_indices), ret_indices) else: return tp, ret_indices if isinstance(expr, MatrixElement): indices = expr.args[1:] diagonal_indices, ret_indices = _get_diagonal_indices(indices) if diagonal_indices: return (CodegenArrayDiagonal(expr.args[0], *diagonal_indices), ret_indices) else: return expr.args[0], ret_indices if isinstance(expr, Indexed): indices = expr.indices diagonal_indices, ret_indices = _get_diagonal_indices(indices) if diagonal_indices: return (CodegenArrayDiagonal(expr.base, *diagonal_indices), ret_indices) else: return expr.args[0], ret_indices if isinstance(expr, IndexedBase): raise NotImplementedError if isinstance(expr, KroneckerDelta): return expr, expr.indices if isinstance(expr, Add): args, indices = zip(*[_codegen_array_parse(arg) for arg in expr.args]) args = list(args) # Check if all indices are compatible. Otherwise expand the dimensions: index0set = set(indices[0]) index0 = indices[0] for i in range(1, len(args)): if set(indices[i]) != index0set: raise NotImplementedError("indices must be the same") permutation = Permutation([index0.index(j) for j in indices[i]]) # Perform index permutations: args[i] = CodegenArrayPermuteDims(args[i], permutation) return CodegenArrayElementwiseAdd(*args), index0 return expr, () raise NotImplementedError("could not recognize expression %s" % expr) def _parse_matrix_expression(expr): if isinstance(expr, MatMul): args_nonmat = [] args = [] contractions = [] for arg in expr.args: if isinstance(arg, MatrixExpr): args.append(arg) else: args_nonmat.append(arg) contractions = [(2*i+1, 2*i+2) for i in range(len(args)-1)] return Mul.fromiter(args_nonmat)*CodegenArrayContraction( CodegenArrayTensorProduct(*[_parse_matrix_expression(arg) for arg in args]), *contractions ) elif isinstance(expr, MatAdd): return CodegenArrayElementwiseAdd( *[_parse_matrix_expression(arg) for arg in expr.args] ) elif isinstance(expr, Transpose): return CodegenArrayPermuteDims( _parse_matrix_expression(expr.args[0]), [1, 0] ) else: return expr def parse_indexed_expression(expr, first_indices=None): r""" Parse indexed expression into a form useful for code generation. Examples ======== >>> from sympy.codegen.array_utils import parse_indexed_expression >>> from sympy import MatrixSymbol, Sum, symbols >>> from sympy.combinatorics import Permutation >>> Permutation.print_cyclic = True >>> i, j, k, d = symbols("i j k d") >>> M = MatrixSymbol("M", d, d) >>> N = MatrixSymbol("N", d, d) Recognize the trace in summation form: >>> expr = Sum(M[i, i], (i, 0, d-1)) >>> parse_indexed_expression(expr) CodegenArrayContraction(M, (0, 1)) Recognize the extraction of the diagonal by using the same index `i` on both axes of the matrix: >>> expr = M[i, i] >>> parse_indexed_expression(expr) CodegenArrayDiagonal(M, (0, 1)) This function can help perform the transformation expressed in two different mathematical notations as: `\sum_{j=0}^{N-1} A_{i,j} B_{j,k} \Longrightarrow \mathbf{A}\cdot \mathbf{B}` Recognize the matrix multiplication in summation form: >>> expr = Sum(M[i, j]*N[j, k], (j, 0, d-1)) >>> parse_indexed_expression(expr) CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) Specify that ``k`` has to be the starting index: >>> parse_indexed_expression(expr, first_indices=[k]) CodegenArrayPermuteDims(CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)), (0 1)) """ result, indices = _codegen_array_parse(expr) if not first_indices: return result for i in first_indices: if i not in indices: first_indices.remove(i) #raise ValueError("index %s not found or not a free index" % i) first_indices.extend([i for i in indices if i not in first_indices]) permutation = [first_indices.index(i) for i in indices] return CodegenArrayPermuteDims(result, permutation) def _has_multiple_lines(expr): if isinstance(expr, _RecognizeMatMulLines): return True if isinstance(expr, _RecognizeMatOp): return expr.multiple_lines return False class _RecognizeMatOp(object): """ Class to help parsing matrix multiplication lines. """ def __init__(self, operator, args): self.operator = operator self.args = args if any(_has_multiple_lines(arg) for arg in args): multiple_lines = True else: multiple_lines = False self.multiple_lines = multiple_lines def rank(self): if self.operator == Trace: return 0 # TODO: check return 2 def __repr__(self): op = self.operator if op == MatMul: s = "*" elif op == MatAdd: s = "+" else: s = op.__name__ return "_RecognizeMatOp(%s, %s)" % (s, repr(self.args)) return "_RecognizeMatOp(%s)" % (s.join(repr(i) for i in self.args)) def __eq__(self, other): if not isinstance(other, type(self)): return False if self.operator != other.operator: return False if self.args != other.args: return False return True def __iter__(self): return iter(self.args) class _RecognizeMatMulLines(list): """ This class handles multiple parsed multiplication lines. """ def __new__(cls, args): if len(args) == 1: return args[0] return list.__new__(cls, args) def rank(self): return reduce(lambda x, y: x*y, [get_rank(i) for i in self], S.One) def __repr__(self): return "_RecognizeMatMulLines(%s)" % super(_RecognizeMatMulLines, self).__repr__() def _support_function_tp1_recognize(contraction_indices, args): if not isinstance(args, list): args = [args] subranks = [get_rank(i) for i in args] coeff = reduce(lambda x, y: x*y, [arg for arg, srank in zip(args, subranks) if srank == 0], S.One) mapping = _get_mapping_from_subranks(subranks) reverse_mapping = {v:k for k, v in mapping.items()} args, dlinks = _get_contraction_links(args, subranks, *contraction_indices) flatten_contractions = [j for i in contraction_indices for j in i] total_rank = sum(subranks) # TODO: turn `free_indices` into a list? free_indices = {i: i for i in range(total_rank) if i not in flatten_contractions} return_list = [] while dlinks: if free_indices: first_index, starting_argind = min(free_indices.items(), key=lambda x: x[1]) free_indices.pop(first_index) starting_argind, starting_pos = mapping[starting_argind] else: # Maybe a Trace first_index = None starting_argind = min(dlinks) starting_pos = 0 current_argind, current_pos = starting_argind, starting_pos matmul_args = [] last_index = None while True: elem = args[current_argind] if current_pos == 1: elem = _RecognizeMatOp(Transpose, [elem]) matmul_args.append(elem) other_pos = 1 - current_pos if current_argind not in dlinks: other_absolute = reverse_mapping[current_argind, other_pos] free_indices.pop(other_absolute, None) break link_dict = dlinks.pop(current_argind) if other_pos not in link_dict: if free_indices: last_index = [i for i, j in free_indices.items() if mapping[j] == (current_argind, other_pos)][0] else: last_index = None break if len(link_dict) > 2: raise NotImplementedError("not a matrix multiplication line") # Get the last element of `link_dict` as the next link. The last # element is the correct start for trace expressions: current_argind, current_pos = link_dict[other_pos] if current_argind == starting_argind: # This is a trace: if len(matmul_args) > 1: matmul_args = [_RecognizeMatOp(Trace, [_RecognizeMatOp(MatMul, matmul_args)])] elif args[current_argind].shape != (1, 1): matmul_args = [_RecognizeMatOp(Trace, matmul_args)] break dlinks.pop(starting_argind, None) free_indices.pop(last_index, None) return_list.append(_RecognizeMatOp(MatMul, matmul_args)) if coeff != 1: # Let's inject the coefficient: return_list[0].args.insert(0, coeff) return _RecognizeMatMulLines(return_list) def recognize_matrix_expression(expr): r""" Recognize matrix expressions in codegen objects. If more than one matrix multiplication line have been detected, return a list with the matrix expressions. Examples ======== >>> from sympy import MatrixSymbol, MatrixExpr, Sum, Symbol >>> from sympy.abc import i, j, k, l, N >>> from sympy.codegen.array_utils import CodegenArrayContraction, CodegenArrayTensorProduct >>> from sympy.codegen.array_utils import recognize_matrix_expression, parse_indexed_expression >>> A = MatrixSymbol("A", N, N) >>> B = MatrixSymbol("B", N, N) >>> C = MatrixSymbol("C", N, N) >>> D = MatrixSymbol("D", N, N) >>> expr = Sum(A[i, j]*B[j, k], (j, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) A*B >>> cg = parse_indexed_expression(expr, first_indices=[k]) >>> recognize_matrix_expression(cg) (A*B).T Transposition is detected: >>> expr = Sum(A[j, i]*B[j, k], (j, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) A.T*B >>> cg = parse_indexed_expression(expr, first_indices=[k]) >>> recognize_matrix_expression(cg) (A.T*B).T Detect the trace: >>> expr = Sum(A[i, i], (i, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) Trace(A) Recognize some more complex traces: >>> expr = Sum(A[i, j]*B[j, i], (i, 0, N-1), (j, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) Trace(A*B) More complicated expressions: >>> expr = Sum(A[i, j]*B[k, j]*A[l, k], (j, 0, N-1), (k, 0, N-1)) >>> cg = parse_indexed_expression(expr) >>> recognize_matrix_expression(cg) A*B.T*A.T Expressions constructed from matrix expressions do not contain literal indices, the positions of free indices are returned instead: >>> expr = A*B >>> cg = CodegenArrayContraction.from_MatMul(expr) >>> recognize_matrix_expression(cg) A*B If more than one line of matrix multiplications is detected, return separate matrix multiplication factors: >>> cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C, D), (1, 2), (5, 6)) >>> recognize_matrix_expression(cg) [A*B, C*D] The two lines have free indices at axes 0, 3 and 4, 7, respectively. """ # TODO: expr has to be a CodegenArray... type rec = _recognize_matrix_expression(expr) return _unfold_recognized_expr(rec) def _recognize_matrix_expression(expr): if isinstance(expr, CodegenArrayContraction): # Apply some transformations: expr = expr.flatten_contraction_of_diagonal() expr = expr.split_multiple_contractions() args = _recognize_matrix_expression(expr.expr) contraction_indices = expr.contraction_indices if isinstance(args, _RecognizeMatOp) and args.operator == MatAdd: addends = [] for arg in args.args: addends.append(_support_function_tp1_recognize(contraction_indices, arg)) return _RecognizeMatOp(MatAdd, addends) elif isinstance(args, _RecognizeMatMulLines): return _support_function_tp1_recognize(contraction_indices, args) return _support_function_tp1_recognize(contraction_indices, [args]) elif isinstance(expr, CodegenArrayElementwiseAdd): add_args = [] for arg in expr.args: add_args.append(_recognize_matrix_expression(arg)) return _RecognizeMatOp(MatAdd, add_args) elif isinstance(expr, (MatrixSymbol, IndexedBase)): return expr elif isinstance(expr, CodegenArrayPermuteDims): if expr.permutation.args[0] == [1, 0]: return _RecognizeMatOp(Transpose, [_recognize_matrix_expression(expr.expr)]) elif isinstance(expr.expr, CodegenArrayTensorProduct): ranks = expr.expr.subranks newrange = [expr.permutation(i) for i in range(sum(ranks))] newpos = [] counter = 0 for rank in ranks: newpos.append(newrange[counter:counter+rank]) counter += rank newargs = [] for pos, arg in zip(newpos, expr.expr.args): if pos == sorted(pos): newargs.append((_recognize_matrix_expression(arg), pos[0])) elif len(pos) == 2: newargs.append((_RecognizeMatOp(Transpose, [_recognize_matrix_expression(arg)]), pos[0])) else: raise NotImplementedError newargs.sort(key=lambda x: x[1]) newargs = [i[0] for i in newargs] return _RecognizeMatMulLines(newargs) else: raise NotImplementedError elif isinstance(expr, CodegenArrayTensorProduct): args = [_recognize_matrix_expression(arg) for arg in expr.args] multiple_lines = [_has_multiple_lines(arg) for arg in args] if any(multiple_lines): if any(a.operator != MatAdd for i, a in enumerate(args) if multiple_lines[i] and isinstance(a, _RecognizeMatOp)): raise NotImplementedError getargs = lambda x: x.args if isinstance(x, _RecognizeMatOp) else list(x) expand_args = [getargs(arg) if multiple_lines[i] else [arg] for i, arg in enumerate(args)] it = itertools.product(*expand_args) ret = _RecognizeMatOp(MatAdd, [_RecognizeMatMulLines([k for j in i for k in (j if isinstance(j, _RecognizeMatMulLines) else [j])]) for i in it]) return ret return _RecognizeMatMulLines(args) elif isinstance(expr, CodegenArrayDiagonal): pexpr = expr.transform_to_product() if expr == pexpr: return expr return _recognize_matrix_expression(pexpr) elif isinstance(expr, Transpose): return expr elif isinstance(expr, MatrixExpr): return expr return expr def _suppress_trivial_dims_in_tensor_product(mat_list): # Recognize expressions like [x, y] with shape (k, 1, k, 1) as `x*y.T`. # The matrix expression has to be equivalent to the tensor product of the matrices, with trivial dimensions (i.e. dim=1) dropped. # That is, add contractions over trivial dimensions: mat_11 = [] mat_k1 = [] last_dim = mat_list[0].shape[0] for mat in mat_list: if mat.shape == (1, 1): mat_11.append(mat) elif 1 in mat.shape: if mat.shape[0] == 1: mat_k1.append(mat.T) else: mat_k1.append(mat) else: return mat_list if len(mat_k1) > 2: return mat_list a = MatMul.fromiter(mat_k1[:1]) b = MatMul.fromiter(mat_k1[1:]) x = MatMul.fromiter(mat_11) return a*x*b.T def _unfold_recognized_expr(expr): if isinstance(expr, _RecognizeMatOp): return expr.operator(*[_unfold_recognized_expr(i) for i in expr.args]) elif isinstance(expr, _RecognizeMatMulLines): unfolded = [_unfold_recognized_expr(i) for i in expr] mat_list = [i for i in unfolded if isinstance(i, MatrixExpr)] scalar_list = [i for i in unfolded if i not in mat_list] scalar = Mul.fromiter(scalar_list) mat_list = [i.doit() for i in mat_list] mat_list = [i for i in mat_list if not (i.shape == (1, 1) and i.is_Identity)] if mat_list: mat_list[0] *= scalar if len(mat_list) == 1: return mat_list[0].doit() else: return _suppress_trivial_dims_in_tensor_product(mat_list) else: return scalar else: return expr def _apply_recursively_over_nested_lists(func, arr): if isinstance(arr, (tuple, list, Tuple)): return tuple(_apply_recursively_over_nested_lists(func, i) for i in arr) elif isinstance(arr, Tuple): return Tuple.fromiter(_apply_recursively_over_nested_lists(func, i) for i in arr) else: return func(arr) def _build_push_indices_up_func_transformation(flattened_contraction_indices): shifts = {0: 0} i = 0 cumulative = 0 while i < len(flattened_contraction_indices): j = 1 while i+j < len(flattened_contraction_indices): if flattened_contraction_indices[i] + j != flattened_contraction_indices[i+j]: break j += 1 cumulative += j shifts[flattened_contraction_indices[i]] = cumulative i += j shift_keys = sorted(shifts.keys()) def func(idx): return shifts[shift_keys[bisect.bisect_right(shift_keys, idx)-1]] def transform(j): if j in flattened_contraction_indices: return None else: return j - func(j) return transform def _build_push_indices_down_func_transformation(flattened_contraction_indices): N = flattened_contraction_indices[-1]+2 shifts = [i for i in range(N) if i not in flattened_contraction_indices] def transform(j): if j < len(shifts): return shifts[j] else: return j + shifts[-1] - len(shifts) + 1 return transform

d29055cd0c82ef93ce704887573e6af53885421c4cfb7310d7b95c42715dd8aa

""" Classes and functions useful for rewriting expressions for optimized code generation. Some languages (or standards thereof), e.g. C99, offer specialized math functions for better performance and/or precision. Using the ``optimize`` function in this module, together with a collection of rules (represented as instances of ``Optimization``), one can rewrite the expressions for this purpose:: >>> from sympy import Symbol, exp, log >>> from sympy.codegen.rewriting import optimize, optims_c99 >>> x = Symbol('x') >>> optimize(3*exp(2*x) - 3, optims_c99) 3*expm1(2*x) >>> optimize(exp(2*x) - 3, optims_c99) exp(2*x) - 3 >>> optimize(log(3*x + 3), optims_c99) log1p(x) + log(3) >>> optimize(log(2*x + 3), optims_c99) log(2*x + 3) The ``optims_c99`` imported above is tuple containing the following instances (which may be imported from ``sympy.codegen.rewriting``): - ``expm1_opt`` - ``log1p_opt`` - ``exp2_opt`` - ``log2_opt`` - ``log2const_opt`` """ from __future__ import (absolute_import, division, print_function) from itertools import chain from sympy import log, exp, Max, Min, Wild, expand_log, Dummy from sympy.codegen.cfunctions import log1p, log2, exp2, expm1 from sympy.core.expr import UnevaluatedExpr from sympy.core.mul import Mul from sympy.core.power import Pow from sympy.utilities.iterables import sift class Optimization(object): """ Abstract base class for rewriting optimization. Subclasses should implement ``__call__`` taking an expression as argument. Parameters ========== cost_function : callable returning number priority : number """ def __init__(self, cost_function=None, priority=1): self.cost_function = cost_function self.priority=priority class ReplaceOptim(Optimization): """ Rewriting optimization calling replace on expressions. The instance can be used as a function on expressions for which it will apply the ``replace`` method (see :meth:`sympy.core.basic.Basic.replace`). Parameters ========== query : first argument passed to replace value : second argument passed to replace Examples ======== >>> from sympy import Symbol, Pow >>> from sympy.codegen.rewriting import ReplaceOptim >>> from sympy.codegen.cfunctions import exp2 >>> x = Symbol('x') >>> exp2_opt = ReplaceOptim(lambda p: p.is_Pow and p.base == 2, ... lambda p: exp2(p.exp)) >>> exp2_opt(2**x) exp2(x) """ def __init__(self, query, value, **kwargs): super(ReplaceOptim, self).__init__(**kwargs) self.query = query self.value = value def __call__(self, expr): return expr.replace(self.query, self.value) def optimize(expr, optimizations): """ Apply optimizations to an expression. Parameters ========== expr : expression optimizations : iterable of ``Optimization`` instances The optimizations will be sorted with respect to ``priority`` (highest first). Examples ======== >>> from sympy import log, Symbol >>> from sympy.codegen.rewriting import optims_c99, optimize >>> x = Symbol('x') >>> optimize(log(x+3)/log(2) + log(x**2 + 1), optims_c99) log1p(x**2) + log2(x + 3) """ for optim in sorted(optimizations, key=lambda opt: opt.priority, reverse=True): new_expr = optim(expr) if optim.cost_function is None: expr = new_expr else: before, after = map(lambda x: optim.cost_function(x), (expr, new_expr)) if before > after: expr = new_expr return expr exp2_opt = ReplaceOptim( lambda p: p.is_Pow and p.base == 2, lambda p: exp2(p.exp) ) _d = Wild('d', properties=[lambda x: x.is_Dummy]) _u = Wild('u', properties=[lambda x: not x.is_number and not x.is_Add]) _v = Wild('v') _w = Wild('w') log2_opt = ReplaceOptim(_v*log(_w)/log(2), _v*log2(_w), cost_function=lambda expr: expr.count( lambda e: ( # division & eval of transcendentals are expensive floating point operations... e.is_Pow and e.exp.is_negative # division or (isinstance(e, (log, log2)) and not e.args[0].is_number)) # transcendental ) ) log2const_opt = ReplaceOptim(log(2)*log2(_w), log(_w)) logsumexp_2terms_opt = ReplaceOptim( lambda l: (isinstance(l, log) and l.args[0].is_Add and len(l.args[0].args) == 2 and all(isinstance(t, exp) for t in l.args[0].args)), lambda l: ( Max(*[e.args[0] for e in l.args[0].args]) + log1p(exp(Min(*[e.args[0] for e in l.args[0].args]))) ) ) def _try_expm1(expr): protected, old_new = expr.replace(exp, lambda arg: Dummy(), map=True) factored = protected.factor() new_old = {v: k for k, v in old_new.items()} return factored.replace(_d - 1, lambda d: expm1(new_old[d].args[0])).xreplace(new_old) def _expm1_value(e): numbers, non_num = sift(e.args, lambda arg: arg.is_number, binary=True) non_num_exp, non_num_other = sift(non_num, lambda arg: arg.has(exp), binary=True) numsum = sum(numbers) new_exp_terms, done = [], False for exp_term in non_num_exp: if done: new_exp_terms.append(exp_term) else: looking_at = exp_term + numsum attempt = _try_expm1(looking_at) if looking_at == attempt: new_exp_terms.append(exp_term) else: done = True new_exp_terms.append(attempt) if not done: new_exp_terms.append(numsum) return e.func(*chain(new_exp_terms, non_num_other)) expm1_opt = ReplaceOptim(lambda e: e.is_Add, _expm1_value) log1p_opt = ReplaceOptim( lambda e: isinstance(e, log), lambda l: expand_log(l.replace( log, lambda arg: log(arg.factor()) )).replace(log(_u+1), log1p(_u)) ) def create_expand_pow_optimization(limit): """ Creates an instance of :class:`ReplaceOptim` for expanding ``Pow``. The requirements for expansions are that the base needs to be a symbol and the exponent needs to be an Integer (and be less than or equal to ``limit``). Parameters ========== limit : int The highest power which is expanded into multiplication. Examples ======== >>> from sympy import Symbol, sin >>> from sympy.codegen.rewriting import create_expand_pow_optimization >>> x = Symbol('x') >>> expand_opt = create_expand_pow_optimization(3) >>> expand_opt(x**5 + x**3) x**5 + x*x*x >>> expand_opt(x**5 + x**3 + sin(x)**3) x**5 + sin(x)**3 + x*x*x """ return ReplaceOptim( lambda e: e.is_Pow and e.base.is_symbol and e.exp.is_Integer and abs(e.exp) <= limit, lambda p: ( UnevaluatedExpr(Mul(*([p.base]*+p.exp), evaluate=False)) if p.exp > 0 else 1/UnevaluatedExpr(Mul(*([p.base]*-p.exp), evaluate=False)) )) # Collections of optimizations: optims_c99 = (expm1_opt, log1p_opt, exp2_opt, log2_opt, log2const_opt)

4af858b273fa71dd29c406f026acf68138c90be73806beb8c9134a84a1129eb8

""" Types used to represent a full function/module as an Abstract Syntax Tree. Most types are small, and are merely used as tokens in the AST. A tree diagram has been included below to illustrate the relationships between the AST types. AST Type Tree ------------- :: *Basic* |--->AssignmentBase | |--->Assignment | |--->AugmentedAssignment | |--->AddAugmentedAssignment | |--->SubAugmentedAssignment | |--->MulAugmentedAssignment | |--->DivAugmentedAssignment | |--->ModAugmentedAssignment | |--->CodeBlock | | |--->Token | |--->Attribute | |--->For | |--->String | | |--->QuotedString | | |--->Comment | |--->Type | | |--->IntBaseType | | | |--->_SizedIntType | | | |--->SignedIntType | | | |--->UnsignedIntType | | |--->FloatBaseType | | |--->FloatType | | |--->ComplexBaseType | | |--->ComplexType | |--->Node | | |--->Variable | | | |---> Pointer | | |--->FunctionPrototype | | |--->FunctionDefinition | |--->Element | |--->Declaration | |--->While | |--->Scope | |--->Stream | |--->Print | |--->FunctionCall | |--->BreakToken | |--->ContinueToken | |--->NoneToken | |--->Statement |--->Return Predefined types ---------------- A number of ``Type`` instances are provided in the ``sympy.codegen.ast`` module for convenience. Perhaps the two most common ones for code-generation (of numeric codes) are ``float32`` and ``float64`` (known as single and double precision respectively). There are also precision generic versions of Types (for which the codeprinters selects the underlying data type at time of printing): ``real``, ``integer``, ``complex_``, ``bool_``. The other ``Type`` instances defined are: - ``intc``: Integer type used by C's "int". - ``intp``: Integer type used by C's "unsigned". - ``int8``, ``int16``, ``int32``, ``int64``: n-bit integers. - ``uint8``, ``uint16``, ``uint32``, ``uint64``: n-bit unsigned integers. - ``float80``: known as "extended precision" on modern x86/amd64 hardware. - ``complex64``: Complex number represented by two ``float32`` numbers - ``complex128``: Complex number represented by two ``float64`` numbers Using the nodes --------------- It is possible to construct simple algorithms using the AST nodes. Let's construct a loop applying Newton's method:: >>> from sympy import symbols, cos >>> from sympy.codegen.ast import While, Assignment, aug_assign, Print >>> t, dx, x = symbols('tol delta val') >>> expr = cos(x) - x**3 >>> whl = While(abs(dx) > t, [ ... Assignment(dx, -expr/expr.diff(x)), ... aug_assign(x, '+', dx), ... Print([x]) ... ]) >>> from sympy.printing import pycode >>> py_str = pycode(whl) >>> print(py_str) while (abs(delta) > tol): delta = (val**3 - math.cos(val))/(-3*val**2 - math.sin(val)) val += delta print(val) >>> import math >>> tol, val, delta = 1e-5, 0.5, float('inf') >>> exec(py_str) 1.1121416371 0.909672693737 0.867263818209 0.865477135298 0.865474033111 >>> print('%3.1g' % (math.cos(val) - val**3)) -3e-11 If we want to generate Fortran code for the same while loop we simple call ``fcode``:: >>> from sympy.printing.fcode import fcode >>> print(fcode(whl, standard=2003, source_format='free')) do while (abs(delta) > tol) delta = (val**3 - cos(val))/(-3*val**2 - sin(val)) val = val + delta print *, val end do There is a function constructing a loop (or a complete function) like this in :mod:`sympy.codegen.algorithms`. """ from __future__ import print_function, division from itertools import chain from collections import defaultdict from sympy.core import Symbol, Tuple, Dummy from sympy.core.basic import Basic from sympy.core.compatibility import string_types from sympy.core.expr import Expr from sympy.core.numbers import Float, Integer, oo from sympy.core.relational import Lt, Le, Ge, Gt from sympy.core.sympify import _sympify, sympify, SympifyError from sympy.utilities.iterables import iterable def _mk_Tuple(args): """ Create a Sympy Tuple object from an iterable, converting Python strings to AST strings. Parameters ========== args: iterable Arguments to :class:`sympy.Tuple`. Returns ======= sympy.Tuple """ args = [String(arg) if isinstance(arg, string_types) else arg for arg in args] return Tuple(*args) class Token(Basic): """ Base class for the AST types. Defining fields are set in ``__slots__``. Attributes (defined in __slots__) are only allowed to contain instances of Basic (unless atomic, see ``String``). The arguments to ``__new__()`` correspond to the attributes in the order defined in ``__slots__`. The ``defaults`` class attribute is a dictionary mapping attribute names to their default values. Subclasses should not need to override the ``__new__()`` method. They may define a class or static method named ``_construct_<attr>`` for each attribute to process the value passed to ``__new__()``. Attributes listed in the class attribute ``not_in_args`` are not passed to :class:`sympy.Basic`. """ __slots__ = [] defaults = {} not_in_args = [] indented_args = ['body'] @property def is_Atom(self): return len(self.__slots__) == 0 @classmethod def _get_constructor(cls, attr): """ Get the constructor function for an attribute by name. """ return getattr(cls, '_construct_%s' % attr, lambda x: x) @classmethod def _construct(cls, attr, arg): """ Construct an attribute value from argument passed to ``__new__()``. """ if arg == None: # Must be "== None", cannot be "is None" return cls.defaults.get(attr, none) else: if isinstance(arg, Dummy): # sympy's replace uses Dummy instances return arg else: return cls._get_constructor(attr)(arg) def __new__(cls, *args, **kwargs): # Pass through existing instances when given as sole argument if len(args) == 1 and not kwargs and isinstance(args[0], cls): return args[0] if len(args) > len(cls.__slots__): raise ValueError("Too many arguments (%d), expected at most %d" % (len(args), len(cls.__slots__))) attrvals = [] # Process positional arguments for attrname, argval in zip(cls.__slots__, args): if attrname in kwargs: raise TypeError('Got multiple values for attribute %r' % attrname) attrvals.append(cls._construct(attrname, argval)) # Process keyword arguments for attrname in cls.__slots__[len(args):]: if attrname in kwargs: argval = kwargs.pop(attrname) elif attrname in cls.defaults: argval = cls.defaults[attrname] else: raise TypeError('No value for %r given and attribute has no default' % attrname) attrvals.append(cls._construct(attrname, argval)) if kwargs: raise ValueError("Unknown keyword arguments: %s" % ' '.join(kwargs)) # Parent constructor basic_args = [ val for attr, val in zip(cls.__slots__, attrvals) if attr not in cls.not_in_args ] obj = Basic.__new__(cls, *basic_args) # Set attributes for attr, arg in zip(cls.__slots__, attrvals): setattr(obj, attr, arg) return obj def __eq__(self, other): if not isinstance(other, self.__class__): return False for attr in self.__slots__: if getattr(self, attr) != getattr(other, attr): return False return True def _hashable_content(self): return tuple([getattr(self, attr) for attr in self.__slots__]) def __hash__(self): return super(Token, self).__hash__() def _joiner(self, k, indent_level): return (',\n' + ' '*indent_level) if k in self.indented_args else ', ' def _indented(self, printer, k, v, *args, **kwargs): il = printer._context['indent_level'] def _print(arg): if isinstance(arg, Token): return printer._print(arg, *args, joiner=self._joiner(k, il), **kwargs) else: return printer._print(v, *args, **kwargs) if isinstance(v, Tuple): joined = self._joiner(k, il).join([_print(arg) for arg in v.args]) if k in self.indented_args: return '(\n' + ' '*il + joined + ',\n' + ' '*(il - 4) + ')' else: return ('({0},)' if len(v.args) == 1 else '({0})').format(joined) else: return _print(v) def _sympyrepr(self, printer, *args, **kwargs): from sympy.printing.printer import printer_context exclude = kwargs.get('exclude', ()) values = [getattr(self, k) for k in self.__slots__] indent_level = printer._context.get('indent_level', 0) joiner = kwargs.pop('joiner', ', ') arg_reprs = [] for i, (attr, value) in enumerate(zip(self.__slots__, values)): if attr in exclude: continue # Skip attributes which have the default value if attr in self.defaults and value == self.defaults[attr]: continue ilvl = indent_level + 4 if attr in self.indented_args else 0 with printer_context(printer, indent_level=ilvl): indented = self._indented(printer, attr, value, *args, **kwargs) arg_reprs.append(('{1}' if i == 0 else '{0}={1}').format(attr, indented.lstrip())) return "{0}({1})".format(self.__class__.__name__, joiner.join(arg_reprs)) _sympystr = _sympyrepr def __repr__(self): # sympy.core.Basic.__repr__ uses sstr from sympy.printing import srepr return srepr(self) def kwargs(self, exclude=(), apply=None): """ Get instance's attributes as dict of keyword arguments. Parameters ========== exclude : collection of str Collection of keywords to exclude. apply : callable, optional Function to apply to all values. """ kwargs = {k: getattr(self, k) for k in self.__slots__ if k not in exclude} if apply is not None: return {k: apply(v) for k, v in kwargs.items()} else: return kwargs class BreakToken(Token): """ Represents 'break' in C/Python ('exit' in Fortran). Use the premade instance ``break_`` or instantiate manually. Examples ======== >>> from sympy.printing import ccode, fcode >>> from sympy.codegen.ast import break_ >>> ccode(break_) 'break' >>> fcode(break_, source_format='free') 'exit' """ break_ = BreakToken() class ContinueToken(Token): """ Represents 'continue' in C/Python ('cycle' in Fortran) Use the premade instance ``continue_`` or instantiate manually. Examples ======== >>> from sympy.printing import ccode, fcode >>> from sympy.codegen.ast import continue_ >>> ccode(continue_) 'continue' >>> fcode(continue_, source_format='free') 'cycle' """ continue_ = ContinueToken() class NoneToken(Token): """ The AST equivalence of Python's NoneType The corresponding instance of Python's ``None`` is ``none``. Examples ======== >>> from sympy.codegen.ast import none, Variable >>> from sympy.printing.pycode import pycode >>> print(pycode(Variable('x').as_Declaration(value=none))) x = None """ def __eq__(self, other): return other is None or isinstance(other, NoneToken) def _hashable_content(self): return () def __hash__(self): return super(NoneToken, self).__hash__() none = NoneToken() class AssignmentBase(Basic): """ Abstract base class for Assignment and AugmentedAssignment. Attributes: =========== op : str Symbol for assignment operator, e.g. "=", "+=", etc. """ def __new__(cls, lhs, rhs): lhs = _sympify(lhs) rhs = _sympify(rhs) cls._check_args(lhs, rhs) return super(AssignmentBase, cls).__new__(cls, lhs, rhs) @property def lhs(self): return self.args[0] @property def rhs(self): return self.args[1] @classmethod def _check_args(cls, lhs, rhs): """ Check arguments to __new__ and raise exception if any problems found. Derived classes may wish to override this. """ from sympy.matrices.expressions.matexpr import ( MatrixElement, MatrixSymbol) from sympy.tensor.indexed import Indexed # Tuple of things that can be on the lhs of an assignment assignable = (Symbol, MatrixSymbol, MatrixElement, Indexed, Element, Variable) if not isinstance(lhs, assignable): raise TypeError("Cannot assign to lhs of type %s." % type(lhs)) # Indexed types implement shape, but don't define it until later. This # causes issues in assignment validation. For now, matrices are defined # as anything with a shape that is not an Indexed lhs_is_mat = hasattr(lhs, 'shape') and not isinstance(lhs, Indexed) rhs_is_mat = hasattr(rhs, 'shape') and not isinstance(rhs, Indexed) # If lhs and rhs have same structure, then this assignment is ok if lhs_is_mat: if not rhs_is_mat: raise ValueError("Cannot assign a scalar to a matrix.") elif lhs.shape != rhs.shape: raise ValueError("Dimensions of lhs and rhs don't align.") elif rhs_is_mat and not lhs_is_mat: raise ValueError("Cannot assign a matrix to a scalar.") class Assignment(AssignmentBase): """ Represents variable assignment for code generation. Parameters ========== lhs : Expr Sympy object representing the lhs of the expression. These should be singular objects, such as one would use in writing code. Notable types include Symbol, MatrixSymbol, MatrixElement, and Indexed. Types that subclass these types are also supported. rhs : Expr Sympy object representing the rhs of the expression. This can be any type, provided its shape corresponds to that of the lhs. For example, a Matrix type can be assigned to MatrixSymbol, but not to Symbol, as the dimensions will not align. Examples ======== >>> from sympy import symbols, MatrixSymbol, Matrix >>> from sympy.codegen.ast import Assignment >>> x, y, z = symbols('x, y, z') >>> Assignment(x, y) Assignment(x, y) >>> Assignment(x, 0) Assignment(x, 0) >>> A = MatrixSymbol('A', 1, 3) >>> mat = Matrix([x, y, z]).T >>> Assignment(A, mat) Assignment(A, Matrix([[x, y, z]])) >>> Assignment(A[0, 1], x) Assignment(A[0, 1], x) """ op = ':=' class AugmentedAssignment(AssignmentBase): """ Base class for augmented assignments. Attributes: =========== binop : str Symbol for binary operation being applied in the assignment, such as "+", "*", etc. """ @property def op(self): return self.binop + '=' class AddAugmentedAssignment(AugmentedAssignment): binop = '+' class SubAugmentedAssignment(AugmentedAssignment): binop = '-' class MulAugmentedAssignment(AugmentedAssignment): binop = '*' class DivAugmentedAssignment(AugmentedAssignment): binop = '/' class ModAugmentedAssignment(AugmentedAssignment): binop = '%' # Mapping from binary op strings to AugmentedAssignment subclasses augassign_classes = { cls.binop: cls for cls in [ AddAugmentedAssignment, SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment ] } def aug_assign(lhs, op, rhs): """ Create 'lhs op= rhs'. Represents augmented variable assignment for code generation. This is a convenience function. You can also use the AugmentedAssignment classes directly, like AddAugmentedAssignment(x, y). Parameters ========== lhs : Expr Sympy object representing the lhs of the expression. These should be singular objects, such as one would use in writing code. Notable types include Symbol, MatrixSymbol, MatrixElement, and Indexed. Types that subclass these types are also supported. op : str Operator (+, -, /, \\*, %). rhs : Expr Sympy object representing the rhs of the expression. This can be any type, provided its shape corresponds to that of the lhs. For example, a Matrix type can be assigned to MatrixSymbol, but not to Symbol, as the dimensions will not align. Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import aug_assign >>> x, y = symbols('x, y') >>> aug_assign(x, '+', y) AddAugmentedAssignment(x, y) """ if op not in augassign_classes: raise ValueError("Unrecognized operator %s" % op) return augassign_classes[op](lhs, rhs) class CodeBlock(Basic): """ Represents a block of code For now only assignments are supported. This restriction will be lifted in the future. Useful attributes on this object are: ``left_hand_sides``: Tuple of left-hand sides of assignments, in order. ``left_hand_sides``: Tuple of right-hand sides of assignments, in order. ``free_symbols``: Free symbols of the expressions in the right-hand sides which do not appear in the left-hand side of an assignment. Useful methods on this object are: ``topological_sort``: Class method. Return a CodeBlock with assignments sorted so that variables are assigned before they are used. ``cse``: Return a new CodeBlock with common subexpressions eliminated and pulled out as assignments. Examples ======== >>> from sympy import symbols, ccode >>> from sympy.codegen.ast import CodeBlock, Assignment >>> x, y = symbols('x y') >>> c = CodeBlock(Assignment(x, 1), Assignment(y, x + 1)) >>> print(ccode(c)) x = 1; y = x + 1; """ def __new__(cls, *args): left_hand_sides = [] right_hand_sides = [] for i in args: if isinstance(i, Assignment): lhs, rhs = i.args left_hand_sides.append(lhs) right_hand_sides.append(rhs) obj = Basic.__new__(cls, *args) obj.left_hand_sides = Tuple(*left_hand_sides) obj.right_hand_sides = Tuple(*right_hand_sides) return obj def __iter__(self): return iter(self.args) def _sympyrepr(self, printer, *args, **kwargs): il = printer._context.get('indent_level', 0) joiner = ',\n' + ' '*il joined = joiner.join(map(printer._print, self.args)) return ('{0}(\n'.format(' '*(il-4) + self.__class__.__name__,) + ' '*il + joined + '\n' + ' '*(il - 4) + ')') _sympystr = _sympyrepr @property def free_symbols(self): return super(CodeBlock, self).free_symbols - set(self.left_hand_sides) @classmethod def topological_sort(cls, assignments): """ Return a CodeBlock with topologically sorted assignments so that variables are assigned before they are used. The existing order of assignments is preserved as much as possible. This function assumes that variables are assigned to only once. This is a class constructor so that the default constructor for CodeBlock can error when variables are used before they are assigned. Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import CodeBlock, Assignment >>> x, y, z = symbols('x y z') >>> assignments = [ ... Assignment(x, y + z), ... Assignment(y, z + 1), ... Assignment(z, 2), ... ] >>> CodeBlock.topological_sort(assignments) CodeBlock( Assignment(z, 2), Assignment(y, z + 1), Assignment(x, y + z) ) """ from sympy.utilities.iterables import topological_sort if not all(isinstance(i, Assignment) for i in assignments): # Will support more things later raise NotImplementedError("CodeBlock.topological_sort only supports Assignments") if any(isinstance(i, AugmentedAssignment) for i in assignments): raise NotImplementedError("CodeBlock.topological_sort doesn't yet work with AugmentedAssignments") # Create a graph where the nodes are assignments and there is a directed edge # between nodes that use a variable and nodes that assign that # variable, like # [(x := 1, y := x + 1), (x := 1, z := y + z), (y := x + 1, z := y + z)] # If we then topologically sort these nodes, they will be in # assignment order, like # x := 1 # y := x + 1 # z := y + z # A = The nodes # # enumerate keeps nodes in the same order they are already in if # possible. It will also allow us to handle duplicate assignments to # the same variable when those are implemented. A = list(enumerate(assignments)) # var_map = {variable: [nodes for which this variable is assigned to]} # like {x: [(1, x := y + z), (4, x := 2 * w)], ...} var_map = defaultdict(list) for node in A: i, a = node var_map[a.lhs].append(node) # E = Edges in the graph E = [] for dst_node in A: i, a = dst_node for s in a.rhs.free_symbols: for src_node in var_map[s]: E.append((src_node, dst_node)) ordered_assignments = topological_sort([A, E]) # De-enumerate the result return cls(*[a for i, a in ordered_assignments]) def cse(self, symbols=None, optimizations=None, postprocess=None, order='canonical'): """ Return a new code block with common subexpressions eliminated See the docstring of :func:`sympy.simplify.cse_main.cse` for more information. Examples ======== >>> from sympy import symbols, sin >>> from sympy.codegen.ast import CodeBlock, Assignment >>> x, y, z = symbols('x y z') >>> c = CodeBlock( ... Assignment(x, 1), ... Assignment(y, sin(x) + 1), ... Assignment(z, sin(x) - 1), ... ) ... >>> c.cse() CodeBlock( Assignment(x, 1), Assignment(x0, sin(x)), Assignment(y, x0 + 1), Assignment(z, x0 - 1) ) """ from sympy.simplify.cse_main import cse from sympy.utilities.iterables import numbered_symbols, filter_symbols # Check that the CodeBlock only contains assignments to unique variables if not all(isinstance(i, Assignment) for i in self.args): # Will support more things later raise NotImplementedError("CodeBlock.cse only supports Assignments") if any(isinstance(i, AugmentedAssignment) for i in self.args): raise NotImplementedError("CodeBlock.cse doesn't yet work with AugmentedAssignments") for i, lhs in enumerate(self.left_hand_sides): if lhs in self.left_hand_sides[:i]: raise NotImplementedError("Duplicate assignments to the same " "variable are not yet supported (%s)" % lhs) # Ensure new symbols for subexpressions do not conflict with existing existing_symbols = self.atoms(Symbol) if symbols is None: symbols = numbered_symbols() symbols = filter_symbols(symbols, existing_symbols) replacements, reduced_exprs = cse(list(self.right_hand_sides), symbols=symbols, optimizations=optimizations, postprocess=postprocess, order=order) new_block = [Assignment(var, expr) for var, expr in zip(self.left_hand_sides, reduced_exprs)] new_assignments = [Assignment(var, expr) for var, expr in replacements] return self.topological_sort(new_assignments + new_block) class For(Token): """Represents a 'for-loop' in the code. Expressions are of the form: "for target in iter: body..." Parameters ========== target : symbol iter : iterable body : CodeBlock or iterable ! When passed an iterable it is used to instantiate a CodeBlock. Examples ======== >>> from sympy import symbols, Range >>> from sympy.codegen.ast import aug_assign, For >>> x, i, j, k = symbols('x i j k') >>> for_i = For(i, Range(10), [aug_assign(x, '+', i*j*k)]) >>> for_i # doctest: -NORMALIZE_WHITESPACE For(i, iterable=Range(0, 10, 1), body=CodeBlock( AddAugmentedAssignment(x, i*j*k) )) >>> for_ji = For(j, Range(7), [for_i]) >>> for_ji # doctest: -NORMALIZE_WHITESPACE For(j, iterable=Range(0, 7, 1), body=CodeBlock( For(i, iterable=Range(0, 10, 1), body=CodeBlock( AddAugmentedAssignment(x, i*j*k) )) )) >>> for_kji =For(k, Range(5), [for_ji]) >>> for_kji # doctest: -NORMALIZE_WHITESPACE For(k, iterable=Range(0, 5, 1), body=CodeBlock( For(j, iterable=Range(0, 7, 1), body=CodeBlock( For(i, iterable=Range(0, 10, 1), body=CodeBlock( AddAugmentedAssignment(x, i*j*k) )) )) )) """ __slots__ = ['target', 'iterable', 'body'] _construct_target = staticmethod(_sympify) @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(*itr) @classmethod def _construct_iterable(cls, itr): if not iterable(itr): raise TypeError("iterable must be an iterable") if isinstance(itr, list): # _sympify errors on lists because they are mutable itr = tuple(itr) return _sympify(itr) class String(Token): """ SymPy object representing a string. Atomic object which is not an expression (as opposed to Symbol). Parameters ========== text : str Examples ======== >>> from sympy.codegen.ast import String >>> f = String('foo') >>> f foo >>> str(f) 'foo' >>> f.text 'foo' >>> print(repr(f)) String('foo') """ __slots__ = ['text'] not_in_args = ['text'] is_Atom = True @classmethod def _construct_text(cls, text): if not isinstance(text, string_types): raise TypeError("Argument text is not a string type.") return text def _sympystr(self, printer, *args, **kwargs): return self.text class QuotedString(String): """ Represents a string which should be printed with quotes. """ class Comment(String): """ Represents a comment. """ class Node(Token): """ Subclass of Token, carrying the attribute 'attrs' (Tuple) Examples ======== >>> from sympy.codegen.ast import Node, value_const, pointer_const >>> n1 = Node([value_const]) >>> n1.attr_params('value_const') # get the parameters of attribute (by name) () >>> from sympy.codegen.fnodes import dimension >>> n2 = Node([value_const, dimension(5, 3)]) >>> n2.attr_params(value_const) # get the parameters of attribute (by Attribute instance) () >>> n2.attr_params('dimension') # get the parameters of attribute (by name) (5, 3) >>> n2.attr_params(pointer_const) is None True """ __slots__ = ['attrs'] defaults = {'attrs': Tuple()} _construct_attrs = staticmethod(_mk_Tuple) def attr_params(self, looking_for): """ Returns the parameters of the Attribute with name ``looking_for`` in self.attrs """ for attr in self.attrs: if str(attr.name) == str(looking_for): return attr.parameters class Type(Token): """ Represents a type. The naming is a super-set of NumPy naming. Type has a classmethod ``from_expr`` which offer type deduction. It also has a method ``cast_check`` which casts the argument to its type, possibly raising an exception if rounding error is not within tolerances, or if the value is not representable by the underlying data type (e.g. unsigned integers). Parameters ========== name : str Name of the type, e.g. ``object``, ``int16``, ``float16`` (where the latter two would use the ``Type`` sub-classes ``IntType`` and ``FloatType`` respectively). If a ``Type`` instance is given, the said instance is returned. Examples ======== >>> from sympy.codegen.ast import Type >>> t = Type.from_expr(42) >>> t integer >>> print(repr(t)) IntBaseType(String('integer')) >>> from sympy.codegen.ast import uint8 >>> uint8.cast_check(-1) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Minimum value for data type bigger than new value. >>> from sympy.codegen.ast import float32 >>> v6 = 0.123456 >>> float32.cast_check(v6) 0.123456 >>> v10 = 12345.67894 >>> float32.cast_check(v10) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Casting gives a significantly different value. >>> boost_mp50 = Type('boost::multiprecision::cpp_dec_float_50') >>> from sympy import Symbol >>> from sympy.printing.cxxcode import cxxcode >>> from sympy.codegen.ast import Declaration, Variable >>> cxxcode(Declaration(Variable('x', type=boost_mp50))) 'boost::multiprecision::cpp_dec_float_50 x' References ========== .. [1] https://docs.scipy.org/doc/numpy/user/basics.types.html """ __slots__ = ['name'] _construct_name = String def _sympystr(self, printer, *args, **kwargs): return str(self.name) @classmethod def from_expr(cls, expr): """ Deduces type from an expression or a ``Symbol``. Parameters ========== expr : number or SymPy object The type will be deduced from type or properties. Examples ======== >>> from sympy.codegen.ast import Type, integer, complex_ >>> Type.from_expr(2) == integer True >>> from sympy import Symbol >>> Type.from_expr(Symbol('z', complex=True)) == complex_ True >>> Type.from_expr(sum) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Could not deduce type from expr. Raises ====== ValueError when type deduction fails. """ if isinstance(expr, (float, Float)): return real if isinstance(expr, (int, Integer)) or getattr(expr, 'is_integer', False): return integer if getattr(expr, 'is_real', False): return real if isinstance(expr, complex) or getattr(expr, 'is_complex', False): return complex_ if isinstance(expr, bool) or getattr(expr, 'is_Relational', False): return bool_ else: raise ValueError("Could not deduce type from expr.") def _check(self, value): pass def cast_check(self, value, rtol=None, atol=0, limits=None, precision_targets=None): """ Casts a value to the data type of the instance. Parameters ========== value : number rtol : floating point number Relative tolerance. (will be deduced if not given). atol : floating point number Absolute tolerance (in addition to ``rtol``). limits : dict Values given by ``limits.h``, x86/IEEE754 defaults if not given. Default: :attr:`default_limits`. type_aliases : dict Maps substitutions for Type, e.g. {integer: int64, real: float32} Examples ======== >>> from sympy.codegen.ast import Type, integer, float32, int8 >>> integer.cast_check(3.0) == 3 True >>> float32.cast_check(1e-40) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Minimum value for data type bigger than new value. >>> int8.cast_check(256) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Maximum value for data type smaller than new value. >>> v10 = 12345.67894 >>> float32.cast_check(v10) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Casting gives a significantly different value. >>> from sympy.codegen.ast import float64 >>> float64.cast_check(v10) 12345.67894 >>> from sympy import Float >>> v18 = Float('0.123456789012345646') >>> float64.cast_check(v18) Traceback (most recent call last): ... ValueError: Casting gives a significantly different value. >>> from sympy.codegen.ast import float80 >>> float80.cast_check(v18) 0.123456789012345649 """ val = sympify(value) ten = Integer(10) exp10 = getattr(self, 'decimal_dig', None) if rtol is None: rtol = 1e-15 if exp10 is None else 2.0*ten**(-exp10) def tol(num): return atol + rtol*abs(num) new_val = self.cast_nocheck(value) self._check(new_val) delta = new_val - val if abs(delta) > tol(val): # rounding, e.g. int(3.5) != 3.5 raise ValueError("Casting gives a significantly different value.") return new_val class IntBaseType(Type): """ Integer base type, contains no size information. """ __slots__ = ['name'] cast_nocheck = lambda self, i: Integer(int(i)) class _SizedIntType(IntBaseType): __slots__ = ['name', 'nbits'] _construct_nbits = Integer def _check(self, value): if value < self.min: raise ValueError("Value is too small: %d < %d" % (value, self.min)) if value > self.max: raise ValueError("Value is too big: %d > %d" % (value, self.max)) class SignedIntType(_SizedIntType): """ Represents a signed integer type. """ @property def min(self): return -2**(self.nbits-1) @property def max(self): return 2**(self.nbits-1) - 1 class UnsignedIntType(_SizedIntType): """ Represents an unsigned integer type. """ @property def min(self): return 0 @property def max(self): return 2**self.nbits - 1 two = Integer(2) class FloatBaseType(Type): """ Represents a floating point number type. """ cast_nocheck = Float class FloatType(FloatBaseType): """ Represents a floating point type with fixed bit width. Base 2 & one sign bit is assumed. Parameters ========== name : str Name of the type. nbits : integer Number of bits used (storage). nmant : integer Number of bits used to represent the mantissa. nexp : integer Number of bits used to represent the mantissa. Examples ======== >>> from sympy import S, Float >>> from sympy.codegen.ast import FloatType >>> half_precision = FloatType('f16', nbits=16, nmant=10, nexp=5) >>> half_precision.max 65504 >>> half_precision.tiny == S(2)**-14 True >>> half_precision.eps == S(2)**-10 True >>> half_precision.dig == 3 True >>> half_precision.decimal_dig == 5 True >>> half_precision.cast_check(1.0) 1.0 >>> half_precision.cast_check(1e5) # doctest: +ELLIPSIS Traceback (most recent call last): ... ValueError: Maximum value for data type smaller than new value. """ __slots__ = ['name', 'nbits', 'nmant', 'nexp'] _construct_nbits = _construct_nmant = _construct_nexp = Integer @property def max_exponent(self): """ The largest positive number n, such that 2**(n - 1) is a representable finite value. """ # cf. C++'s ``std::numeric_limits::max_exponent`` return two**(self.nexp - 1) @property def min_exponent(self): """ The lowest negative number n, such that 2**(n - 1) is a valid normalized number. """ # cf. C++'s ``std::numeric_limits::min_exponent`` return 3 - self.max_exponent @property def max(self): """ Maximum value representable. """ return (1 - two**-(self.nmant+1))*two**self.max_exponent @property def tiny(self): """ The minimum positive normalized value. """ # See C macros: FLT_MIN, DBL_MIN, LDBL_MIN # or C++'s ``std::numeric_limits::min`` # or numpy.finfo(dtype).tiny return two**(self.min_exponent - 1) @property def eps(self): """ Difference between 1.0 and the next representable value. """ return two**(-self.nmant) @property def dig(self): """ Number of decimal digits that are guaranteed to be preserved in text. When converting text -> float -> text, you are guaranteed that at least ``dig`` number of digits are preserved with respect to rounding or overflow. """ from sympy.functions import floor, log return floor(self.nmant * log(2)/log(10)) @property def decimal_dig(self): """ Number of digits needed to store & load without loss. Number of decimal digits needed to guarantee that two consecutive conversions (float -> text -> float) to be idempotent. This is useful when one do not want to loose precision due to rounding errors when storing a floating point value as text. """ from sympy.functions import ceiling, log return ceiling((self.nmant + 1) * log(2)/log(10) + 1) def cast_nocheck(self, value): """ Casts without checking if out of bounds or subnormal. """ if value == oo: # float(oo) or oo return float(oo) elif value == -oo: # float(-oo) or -oo return float(-oo) return Float(str(sympify(value).evalf(self.decimal_dig)), self.decimal_dig) def _check(self, value): if value < -self.max: raise ValueError("Value is too small: %d < %d" % (value, -self.max)) if value > self.max: raise ValueError("Value is too big: %d > %d" % (value, self.max)) if abs(value) < self.tiny: raise ValueError("Smallest (absolute) value for data type bigger than new value.") class ComplexBaseType(FloatBaseType): def cast_nocheck(self, value): """ Casts without checking if out of bounds or subnormal. """ from sympy.functions import re, im return ( super(ComplexBaseType, self).cast_nocheck(re(value)) + super(ComplexBaseType, self).cast_nocheck(im(value))*1j ) def _check(self, value): from sympy.functions import re, im super(ComplexBaseType, self)._check(re(value)) super(ComplexBaseType, self)._check(im(value)) class ComplexType(ComplexBaseType, FloatType): """ Represents a complex floating point number. """ # NumPy types: intc = IntBaseType('intc') intp = IntBaseType('intp') int8 = SignedIntType('int8', 8) int16 = SignedIntType('int16', 16) int32 = SignedIntType('int32', 32) int64 = SignedIntType('int64', 64) uint8 = UnsignedIntType('uint8', 8) uint16 = UnsignedIntType('uint16', 16) uint32 = UnsignedIntType('uint32', 32) uint64 = UnsignedIntType('uint64', 64) float16 = FloatType('float16', 16, nexp=5, nmant=10) # IEEE 754 binary16, Half precision float32 = FloatType('float32', 32, nexp=8, nmant=23) # IEEE 754 binary32, Single precision float64 = FloatType('float64', 64, nexp=11, nmant=52) # IEEE 754 binary64, Double precision float80 = FloatType('float80', 80, nexp=15, nmant=63) # x86 extended precision (1 integer part bit), "long double" float128 = FloatType('float128', 128, nexp=15, nmant=112) # IEEE 754 binary128, Quadruple precision float256 = FloatType('float256', 256, nexp=19, nmant=236) # IEEE 754 binary256, Octuple precision complex64 = ComplexType('complex64', nbits=64, **float32.kwargs(exclude=('name', 'nbits'))) complex128 = ComplexType('complex128', nbits=128, **float64.kwargs(exclude=('name', 'nbits'))) # Generic types (precision may be chosen by code printers): untyped = Type('untyped') real = FloatBaseType('real') integer = IntBaseType('integer') complex_ = ComplexBaseType('complex') bool_ = Type('bool') class Attribute(Token): """ Attribute (possibly parametrized) For use with :class:`sympy.codegen.ast.Node` (which takes instances of ``Attribute`` as ``attrs``). Parameters ========== name : str parameters : Tuple Examples ======== >>> from sympy.codegen.ast import Attribute >>> volatile = Attribute('volatile') >>> volatile volatile >>> print(repr(volatile)) Attribute(String('volatile')) >>> a = Attribute('foo', [1, 2, 3]) >>> a foo(1, 2, 3) >>> a.parameters == (1, 2, 3) True """ __slots__ = ['name', 'parameters'] defaults = {'parameters': Tuple()} _construct_name = String _construct_parameters = staticmethod(_mk_Tuple) def _sympystr(self, printer, *args, **kwargs): result = str(self.name) if self.parameters: result += '(%s)' % ', '.join(map(lambda arg: printer._print( arg, *args, **kwargs), self.parameters)) return result value_const = Attribute('value_const') pointer_const = Attribute('pointer_const') class Variable(Node): """ Represents a variable Parameters ========== symbol : Symbol type : Type (optional) Type of the variable. attrs : iterable of Attribute instances Will be stored as a Tuple. Examples ======== >>> from sympy import Symbol >>> from sympy.codegen.ast import Variable, float32, integer >>> x = Symbol('x') >>> v = Variable(x, type=float32) >>> v.attrs () >>> v == Variable('x') False >>> v == Variable('x', type=float32) True >>> v Variable(x, type=float32) One may also construct a ``Variable`` instance with the type deduced from assumptions about the symbol using the ``deduced`` classmethod: >>> i = Symbol('i', integer=True) >>> v = Variable.deduced(i) >>> v.type == integer True >>> v == Variable('i') False >>> from sympy.codegen.ast import value_const >>> value_const in v.attrs False >>> w = Variable('w', attrs=[value_const]) >>> w Variable(w, attrs=(value_const,)) >>> value_const in w.attrs True >>> w.as_Declaration(value=42) Declaration(Variable(w, value=42, attrs=(value_const,))) """ __slots__ = ['symbol', 'type', 'value'] + Node.__slots__ defaults = dict(chain(Node.defaults.items(), { 'type': untyped, 'value': none }.items())) _construct_symbol = staticmethod(sympify) _construct_value = staticmethod(sympify) @classmethod def deduced(cls, symbol, value=None, attrs=Tuple(), cast_check=True): """ Alt. constructor with type deduction from ``Type.from_expr``. Deduces type primarily from ``symbol``, secondarily from ``value``. Parameters ========== symbol : Symbol value : expr (optional) value of the variable. attrs : iterable of Attribute instances cast_check : bool Whether to apply ``Type.cast_check`` on ``value``. Examples ======== >>> from sympy import Symbol >>> from sympy.codegen.ast import Variable, complex_ >>> n = Symbol('n', integer=True) >>> str(Variable.deduced(n).type) 'integer' >>> x = Symbol('x', real=True) >>> v = Variable.deduced(x) >>> v.type real >>> z = Symbol('z', complex=True) >>> Variable.deduced(z).type == complex_ True """ if isinstance(symbol, Variable): return symbol try: type_ = Type.from_expr(symbol) except ValueError: type_ = Type.from_expr(value) if value is not None and cast_check: value = type_.cast_check(value) return cls(symbol, type=type_, value=value, attrs=attrs) def as_Declaration(self, **kwargs): """ Convenience method for creating a Declaration instance. If the variable of the Declaration need to wrap a modified variable keyword arguments may be passed (overriding e.g. the ``value`` of the Variable instance). Examples ======== >>> from sympy.codegen.ast import Variable >>> x = Variable('x') >>> decl1 = x.as_Declaration() >>> decl1.variable.value == None True >>> decl2 = x.as_Declaration(value=42.0) >>> decl2.variable.value == 42 True """ kw = self.kwargs() kw.update(kwargs) return Declaration(self.func(**kw)) def _relation(self, rhs, op): try: rhs = _sympify(rhs) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, rhs)) return op(self, rhs, evaluate=False) __lt__ = lambda self, other: self._relation(other, Lt) __le__ = lambda self, other: self._relation(other, Le) __ge__ = lambda self, other: self._relation(other, Ge) __gt__ = lambda self, other: self._relation(other, Gt) class Pointer(Variable): """ Represents a pointer. See ``Variable``. Examples ======== Can create instances of ``Element``: >>> from sympy import Symbol >>> from sympy.codegen.ast import Pointer >>> i = Symbol('i', integer=True) >>> p = Pointer('x') >>> p[i+1] Element(x, indices=((i + 1,),)) """ def __getitem__(self, key): try: return Element(self.symbol, key) except TypeError: return Element(self.symbol, (key,)) class Element(Token): """ Element in (a possibly N-dimensional) array. Examples ======== >>> from sympy.codegen.ast import Element >>> elem = Element('x', 'ijk') >>> elem.symbol.name == 'x' True >>> elem.indices (i, j, k) >>> from sympy import ccode >>> ccode(elem) 'x[i][j][k]' >>> ccode(Element('x', 'ijk', strides='lmn', offset='o')) 'x[i*l + j*m + k*n + o]' """ __slots__ = ['symbol', 'indices', 'strides', 'offset'] defaults = {'strides': none, 'offset': none} _construct_symbol = staticmethod(sympify) _construct_indices = staticmethod(lambda arg: Tuple(*arg)) _construct_strides = staticmethod(lambda arg: Tuple(*arg)) _construct_offset = staticmethod(sympify) class Declaration(Token): """ Represents a variable declaration Parameters ========== variable : Variable Examples ======== >>> from sympy import Symbol >>> from sympy.codegen.ast import Declaration, Type, Variable, integer, untyped >>> z = Declaration('z') >>> z.variable.type == untyped True >>> z.variable.value == None True """ __slots__ = ['variable'] _construct_variable = Variable class While(Token): """ Represents a 'for-loop' in the code. Expressions are of the form: "while condition: body..." Parameters ========== condition : expression convertable to Boolean body : CodeBlock or iterable When passed an iterable it is used to instantiate a CodeBlock. Examples ======== >>> from sympy import symbols, Gt, Abs >>> from sympy.codegen import aug_assign, Assignment, While >>> x, dx = symbols('x dx') >>> expr = 1 - x**2 >>> whl = While(Gt(Abs(dx), 1e-9), [ ... Assignment(dx, -expr/expr.diff(x)), ... aug_assign(x, '+', dx) ... ]) """ __slots__ = ['condition', 'body'] _construct_condition = staticmethod(lambda cond: _sympify(cond)) @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(*itr) class Scope(Token): """ Represents a scope in the code. Parameters ========== body : CodeBlock or iterable When passed an iterable it is used to instantiate a CodeBlock. """ __slots__ = ['body'] @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(*itr) class Stream(Token): """ Represents a stream. There are two predefined Stream instances ``stdout`` & ``stderr``. Parameters ========== name : str Examples ======== >>> from sympy import Symbol >>> from sympy.printing.pycode import pycode >>> from sympy.codegen.ast import Print, stderr, QuotedString >>> print(pycode(Print(['x'], file=stderr))) print(x, file=sys.stderr) >>> x = Symbol('x') >>> print(pycode(Print([QuotedString('x')], file=stderr))) # print literally "x" print("x", file=sys.stderr) """ __slots__ = ['name'] _construct_name = String stdout = Stream('stdout') stderr = Stream('stderr') class Print(Token): """ Represents print command in the code. Parameters ========== formatstring : str *args : Basic instances (or convertible to such through sympify) Examples ======== >>> from sympy.codegen.ast import Print >>> from sympy.printing.pycode import pycode >>> print(pycode(Print('x y'.split(), "coordinate: %12.5g %12.5g"))) print("coordinate: %12.5g %12.5g" % (x, y)) """ __slots__ = ['print_args', 'format_string', 'file'] defaults = {'format_string': none, 'file': none} _construct_print_args = staticmethod(_mk_Tuple) _construct_format_string = QuotedString _construct_file = Stream class FunctionPrototype(Node): """ Represents a function prototype Allows the user to generate forward declaration in e.g. C/C++. Parameters ========== return_type : Type name : str parameters: iterable of Variable instances attrs : iterable of Attribute instances Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import real, FunctionPrototype >>> from sympy.printing.ccode import ccode >>> x, y = symbols('x y', real=True) >>> fp = FunctionPrototype(real, 'foo', [x, y]) >>> ccode(fp) 'double foo(double x, double y)' """ __slots__ = ['return_type', 'name', 'parameters', 'attrs'] _construct_return_type = Type _construct_name = String @staticmethod def _construct_parameters(args): def _var(arg): if isinstance(arg, Declaration): return arg.variable elif isinstance(arg, Variable): return arg else: return Variable.deduced(arg) return Tuple(*map(_var, args)) @classmethod def from_FunctionDefinition(cls, func_def): if not isinstance(func_def, FunctionDefinition): raise TypeError("func_def is not an instance of FunctionDefiniton") return cls(**func_def.kwargs(exclude=('body',))) class FunctionDefinition(FunctionPrototype): """ Represents a function definition in the code. Parameters ========== return_type : Type name : str parameters: iterable of Variable instances body : CodeBlock or iterable attrs : iterable of Attribute instances Examples ======== >>> from sympy import symbols >>> from sympy.codegen.ast import real, FunctionPrototype >>> from sympy.printing.ccode import ccode >>> x, y = symbols('x y', real=True) >>> fp = FunctionPrototype(real, 'foo', [x, y]) >>> ccode(fp) 'double foo(double x, double y)' >>> from sympy.codegen.ast import FunctionDefinition, Return >>> body = [Return(x*y)] >>> fd = FunctionDefinition.from_FunctionPrototype(fp, body) >>> print(ccode(fd)) double foo(double x, double y){ return x*y; } """ __slots__ = FunctionPrototype.__slots__[:-1] + ['body', 'attrs'] @classmethod def _construct_body(cls, itr): if isinstance(itr, CodeBlock): return itr else: return CodeBlock(*itr) @classmethod def from_FunctionPrototype(cls, func_proto, body): if not isinstance(func_proto, FunctionPrototype): raise TypeError("func_proto is not an instance of FunctionPrototype") return cls(body=body, **func_proto.kwargs()) class Return(Basic): """ Represents a return command in the code. """ class FunctionCall(Token, Expr): """ Represents a call to a function in the code. Parameters ========== name : str function_args : Tuple Examples ======== >>> from sympy.codegen.ast import FunctionCall >>> from sympy.printing.pycode import pycode >>> fcall = FunctionCall('foo', 'bar baz'.split()) >>> print(pycode(fcall)) foo(bar, baz) """ __slots__ = ['name', 'function_args'] _construct_name = String _construct_function_args = staticmethod(lambda args: Tuple(*args))

f808ffabaf0ce83aabb250aa387d571885f62a26e56d19dcbabbd4918cad71f0

""" The contents of this file are the return value of ``sympy.assumptions.ask.compute_known_facts``. Do NOT manually edit this file. Instead, run ./bin/ask_update.py. """ from sympy.core.cache import cacheit from sympy.logic.boolalg import And from sympy.assumptions.ask import Q # -{ Known facts in Conjunctive Normal Form }- @cacheit def get_known_facts_cnf(): return And( Q.invertible | Q.singular, Q.algebraic | ~Q.rational, Q.antihermitian | ~Q.imaginary, Q.complex | ~Q.algebraic, Q.complex | ~Q.imaginary, Q.complex | ~Q.real, Q.complex | ~Q.transcendental, Q.complex_elements | ~Q.real_elements, Q.even | ~Q.zero, Q.extended_real | ~Q.infinite, Q.extended_real | ~Q.real, Q.finite | ~Q.algebraic, Q.finite | ~Q.irrational, Q.finite | ~Q.rational, Q.finite | ~Q.transcendental, Q.fullrank | ~Q.invertible, Q.hermitian | ~Q.real, Q.integer | ~Q.even, Q.integer | ~Q.odd, Q.integer | ~Q.prime, Q.invertible | ~Q.positive_definite, Q.invertible | ~Q.unitary, Q.lower_triangular | ~Q.diagonal, Q.nonnegative | ~Q.positive, Q.nonnegative | ~Q.zero, Q.nonpositive | ~Q.negative, Q.nonpositive | ~Q.zero, Q.nonzero | ~Q.negative, Q.nonzero | ~Q.positive, Q.normal | ~Q.diagonal, Q.normal | ~Q.unitary, Q.positive | ~Q.prime, Q.positive_definite | ~Q.orthogonal, Q.rational | ~Q.integer, Q.real | ~Q.irrational, Q.real | ~Q.negative, Q.real | ~Q.positive, Q.real | ~Q.rational, Q.real | ~Q.zero, Q.real_elements | ~Q.integer_elements, Q.square | ~Q.invertible, Q.square | ~Q.normal, Q.square | ~Q.symmetric, Q.symmetric | ~Q.diagonal, Q.triangular | ~Q.lower_triangular, Q.triangular | ~Q.unit_triangular, Q.triangular | ~Q.upper_triangular, Q.unitary | ~Q.orthogonal, Q.upper_triangular | ~Q.diagonal, ~Q.algebraic | ~Q.transcendental, ~Q.antihermitian | ~Q.hermitian, ~Q.composite | ~Q.prime, ~Q.even | ~Q.odd, ~Q.finite | ~Q.infinite, ~Q.imaginary | ~Q.real, ~Q.invertible | ~Q.singular, ~Q.irrational | ~Q.rational, ~Q.negative | ~Q.positive, ~Q.negative | ~Q.zero, ~Q.positive | ~Q.zero, Q.even | Q.odd | ~Q.integer, Q.infinite | Q.real | ~Q.extended_real, Q.lower_triangular | Q.upper_triangular | ~Q.triangular, Q.negative | Q.positive | ~Q.nonzero, Q.negative | Q.zero | ~Q.nonpositive, Q.positive | Q.zero | ~Q.nonnegative, Q.diagonal | ~Q.lower_triangular | ~Q.upper_triangular, Q.invertible | ~Q.fullrank | ~Q.square, Q.orthogonal | ~Q.real | ~Q.unitary, Q.negative | Q.positive | Q.zero | ~Q.real, Q.algebraic | Q.transcendental | ~Q.complex | ~Q.finite, Q.composite | Q.prime | ~Q.integer | ~Q.positive, Q.irrational | Q.rational | ~Q.finite | ~Q.real ) # -{ Known facts in compressed sets }- @cacheit def get_known_facts_dict(): return { Q.algebraic: set([Q.algebraic, Q.complex, Q.finite]), Q.antihermitian: set([Q.antihermitian]), Q.commutative: set([Q.commutative]), Q.complex: set([Q.complex]), Q.complex_elements: set([Q.complex_elements]), Q.composite: set([Q.composite]), Q.diagonal: set([Q.diagonal, Q.lower_triangular, Q.normal, Q.square, Q.symmetric, Q.triangular, Q.upper_triangular]), Q.even: set([Q.algebraic, Q.complex, Q.even, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.rational, Q.real]), Q.extended_real: set([Q.extended_real]), Q.finite: set([Q.finite]), Q.fullrank: set([Q.fullrank]), Q.hermitian: set([Q.hermitian]), Q.imaginary: set([Q.antihermitian, Q.complex, Q.imaginary]), Q.infinite: set([Q.extended_real, Q.infinite]), Q.integer: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.rational, Q.real]), Q.integer_elements: set([Q.complex_elements, Q.integer_elements, Q.real_elements]), Q.invertible: set([Q.fullrank, Q.invertible, Q.square]), Q.irrational: set([Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.irrational, Q.nonzero, Q.real]), Q.is_true: set([Q.is_true]), Q.lower_triangular: set([Q.lower_triangular, Q.triangular]), Q.negative: set([Q.complex, Q.extended_real, Q.hermitian, Q.negative, Q.nonpositive, Q.nonzero, Q.real]), Q.nonnegative: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonnegative, Q.real]), Q.nonpositive: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonpositive, Q.real]), Q.nonzero: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonzero, Q.real]), Q.normal: set([Q.normal, Q.square]), Q.odd: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.nonzero, Q.odd, Q.rational, Q.real]), Q.orthogonal: set([Q.fullrank, Q.invertible, Q.normal, Q.orthogonal, Q.positive_definite, Q.square, Q.unitary]), Q.positive: set([Q.complex, Q.extended_real, Q.hermitian, Q.nonnegative, Q.nonzero, Q.positive, Q.real]), Q.positive_definite: set([Q.fullrank, Q.invertible, Q.positive_definite, Q.square]), Q.prime: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.nonnegative, Q.nonzero, Q.positive, Q.prime, Q.rational, Q.real]), Q.rational: set([Q.algebraic, Q.complex, Q.extended_real, Q.finite, Q.hermitian, Q.rational, Q.real]), Q.real: set([Q.complex, Q.extended_real, Q.hermitian, Q.real]), Q.real_elements: set([Q.complex_elements, Q.real_elements]), Q.singular: set([Q.singular]), Q.square: set([Q.square]), Q.symmetric: set([Q.square, Q.symmetric]), Q.transcendental: set([Q.complex, Q.finite, Q.transcendental]), Q.triangular: set([Q.triangular]), Q.unit_triangular: set([Q.triangular, Q.unit_triangular]), Q.unitary: set([Q.fullrank, Q.invertible, Q.normal, Q.square, Q.unitary]), Q.upper_triangular: set([Q.triangular, Q.upper_triangular]), Q.zero: set([Q.algebraic, Q.complex, Q.even, Q.extended_real, Q.finite, Q.hermitian, Q.integer, Q.nonnegative, Q.nonpositive, Q.rational, Q.real, Q.zero]), }

95bdf8a63ba0db1226ee70918028f8fe97f2b36d6b877869502d8e40589b8871

"""Module for querying SymPy objects about assumptions.""" from __future__ import print_function, division from sympy.assumptions.assume import (global_assumptions, Predicate, AppliedPredicate) from sympy.core import sympify from sympy.core.cache import cacheit from sympy.core.decorators import deprecated from sympy.core.relational import Relational from sympy.logic.boolalg import (to_cnf, And, Not, Or, Implies, Equivalent, BooleanFunction, BooleanAtom) from sympy.logic.inference import satisfiable from sympy.utilities.decorator import memoize_property # Deprecated predicates should be added to this list deprecated_predicates = [ 'bounded', 'infinity', 'infinitesimal' ] # Memoization storage for predicates predicate_storage = {} predicate_memo = memoize_property(predicate_storage) # Memoization is necessary for the properties of AssumptionKeys to # ensure that only one object of Predicate objects are created. # This is because assumption handlers are registered on those objects. class AssumptionKeys(object): """ This class contains all the supported keys by ``ask``. """ @predicate_memo def hermitian(self): """ Hermitian predicate. ``ask(Q.hermitian(x))`` is true iff ``x`` belongs to the set of Hermitian operators. References ========== .. [1] http://mathworld.wolfram.com/HermitianOperator.html """ # TODO: Add examples return Predicate('hermitian') @predicate_memo def antihermitian(self): """ Antihermitian predicate. ``Q.antihermitian(x)`` is true iff ``x`` belongs to the field of antihermitian operators, i.e., operators in the form ``x*I``, where ``x`` is Hermitian. References ========== .. [1] http://mathworld.wolfram.com/HermitianOperator.html """ # TODO: Add examples return Predicate('antihermitian') @predicate_memo def real(self): r""" Real number predicate. ``Q.real(x)`` is true iff ``x`` is a real number, i.e., it is in the interval `(-\infty, \infty)`. Note that, in particular the infinities are not real. Use ``Q.extended_real`` if you want to consider those as well. A few important facts about reals: - Every real number is positive, negative, or zero. Furthermore, because these sets are pairwise disjoint, each real number is exactly one of those three. - Every real number is also complex. - Every real number is finite. - Every real number is either rational or irrational. - Every real number is either algebraic or transcendental. - The facts ``Q.negative``, ``Q.zero``, ``Q.positive``, ``Q.nonnegative``, ``Q.nonpositive``, ``Q.nonzero``, ``Q.integer``, ``Q.rational``, and ``Q.irrational`` all imply ``Q.real``, as do all facts that imply those facts. - The facts ``Q.algebraic``, and ``Q.transcendental`` do not imply ``Q.real``; they imply ``Q.complex``. An algebraic or transcendental number may or may not be real. - The "non" facts (i.e., ``Q.nonnegative``, ``Q.nonzero``, ``Q.nonpositive`` and ``Q.noninteger``) are not equivalent to not the fact, but rather, not the fact *and* ``Q.real``. For example, ``Q.nonnegative`` means ``~Q.negative & Q.real``. So for example, ``I`` is not nonnegative, nonzero, or nonpositive. Examples ======== >>> from sympy import Q, ask, symbols >>> x = symbols('x') >>> ask(Q.real(x), Q.positive(x)) True >>> ask(Q.real(0)) True References ========== .. [1] https://en.wikipedia.org/wiki/Real_number """ return Predicate('real') @predicate_memo def extended_real(self): r""" Extended real predicate. ``Q.extended_real(x)`` is true iff ``x`` is a real number or `\{-\infty, \infty\}`. See documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import ask, Q, oo, I >>> ask(Q.extended_real(1)) True >>> ask(Q.extended_real(I)) False >>> ask(Q.extended_real(oo)) True """ return Predicate('extended_real') @predicate_memo def imaginary(self): """ Imaginary number predicate. ``Q.imaginary(x)`` is true iff ``x`` can be written as a real number multiplied by the imaginary unit ``I``. Please note that ``0`` is not considered to be an imaginary number. Examples ======== >>> from sympy import Q, ask, I >>> ask(Q.imaginary(3*I)) True >>> ask(Q.imaginary(2 + 3*I)) False >>> ask(Q.imaginary(0)) False References ========== .. [1] https://en.wikipedia.org/wiki/Imaginary_number """ return Predicate('imaginary') @predicate_memo def complex(self): """ Complex number predicate. ``Q.complex(x)`` is true iff ``x`` belongs to the set of complex numbers. Note that every complex number is finite. Examples ======== >>> from sympy import Q, Symbol, ask, I, oo >>> x = Symbol('x') >>> ask(Q.complex(0)) True >>> ask(Q.complex(2 + 3*I)) True >>> ask(Q.complex(oo)) False References ========== .. [1] https://en.wikipedia.org/wiki/Complex_number """ return Predicate('complex') @predicate_memo def algebraic(self): r""" Algebraic number predicate. ``Q.algebraic(x)`` is true iff ``x`` belongs to the set of algebraic numbers. ``x`` is algebraic if there is some polynomial in ``p(x)\in \mathbb\{Q\}[x]`` such that ``p(x) = 0``. Examples ======== >>> from sympy import ask, Q, sqrt, I, pi >>> ask(Q.algebraic(sqrt(2))) True >>> ask(Q.algebraic(I)) True >>> ask(Q.algebraic(pi)) False References ========== .. [1] https://en.wikipedia.org/wiki/Algebraic_number """ return Predicate('algebraic') @predicate_memo def transcendental(self): """ Transcedental number predicate. ``Q.transcendental(x)`` is true iff ``x`` belongs to the set of transcendental numbers. A transcendental number is a real or complex number that is not algebraic. """ # TODO: Add examples return Predicate('transcendental') @predicate_memo def integer(self): """ Integer predicate. ``Q.integer(x)`` is true iff ``x`` belongs to the set of integer numbers. Examples ======== >>> from sympy import Q, ask, S >>> ask(Q.integer(5)) True >>> ask(Q.integer(S(1)/2)) False References ========== .. [1] https://en.wikipedia.org/wiki/Integer """ return Predicate('integer') @predicate_memo def rational(self): """ Rational number predicate. ``Q.rational(x)`` is true iff ``x`` belongs to the set of rational numbers. Examples ======== >>> from sympy import ask, Q, pi, S >>> ask(Q.rational(0)) True >>> ask(Q.rational(S(1)/2)) True >>> ask(Q.rational(pi)) False References ========== https://en.wikipedia.org/wiki/Rational_number """ return Predicate('rational') @predicate_memo def irrational(self): """ Irrational number predicate. ``Q.irrational(x)`` is true iff ``x`` is any real number that cannot be expressed as a ratio of integers. Examples ======== >>> from sympy import ask, Q, pi, S, I >>> ask(Q.irrational(0)) False >>> ask(Q.irrational(S(1)/2)) False >>> ask(Q.irrational(pi)) True >>> ask(Q.irrational(I)) False References ========== .. [1] https://en.wikipedia.org/wiki/Irrational_number """ return Predicate('irrational') @predicate_memo def finite(self): """ Finite predicate. ``Q.finite(x)`` is true if ``x`` is neither an infinity nor a ``NaN``. In other words, ``ask(Q.finite(x))`` is true for all ``x`` having a bounded absolute value. Examples ======== >>> from sympy import Q, ask, Symbol, S, oo, I >>> x = Symbol('x') >>> ask(Q.finite(S.NaN)) False >>> ask(Q.finite(oo)) False >>> ask(Q.finite(1)) True >>> ask(Q.finite(2 + 3*I)) True References ========== .. [1] https://en.wikipedia.org/wiki/Finite """ return Predicate('finite') @predicate_memo @deprecated(useinstead="finite", issue=9425, deprecated_since_version="1.0") def bounded(self): """ See documentation of ``Q.finite``. """ return Predicate('finite') @predicate_memo def infinite(self): """ Infinite number predicate. ``Q.infinite(x)`` is true iff the absolute value of ``x`` is infinity. """ # TODO: Add examples return Predicate('infinite') @predicate_memo @deprecated(useinstead="infinite", issue=9426, deprecated_since_version="1.0") def infinity(self): """ See documentation of ``Q.infinite``. """ return Predicate('infinite') @predicate_memo @deprecated(useinstead="zero", issue=9675, deprecated_since_version="1.0") def infinitesimal(self): """ See documentation of ``Q.zero``. """ return Predicate('zero') @predicate_memo def positive(self): r""" Positive real number predicate. ``Q.positive(x)`` is true iff ``x`` is real and `x > 0`, that is if ``x`` is in the interval `(0, \infty)`. In particular, infinity is not positive. A few important facts about positive numbers: - Note that ``Q.nonpositive`` and ``~Q.positive`` are *not* the same thing. ``~Q.positive(x)`` simply means that ``x`` is not positive, whereas ``Q.nonpositive(x)`` means that ``x`` is real and not positive, i.e., ``Q.nonpositive(x)`` is logically equivalent to `Q.negative(x) | Q.zero(x)``. So for example, ``~Q.positive(I)`` is true, whereas ``Q.nonpositive(I)`` is false. - See the documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import Q, ask, symbols, I >>> x = symbols('x') >>> ask(Q.positive(x), Q.real(x) & ~Q.negative(x) & ~Q.zero(x)) True >>> ask(Q.positive(1)) True >>> ask(Q.nonpositive(I)) False >>> ask(~Q.positive(I)) True """ return Predicate('positive') @predicate_memo def negative(self): r""" Negative number predicate. ``Q.negative(x)`` is true iff ``x`` is a real number and :math:`x < 0`, that is, it is in the interval :math:`(-\infty, 0)`. Note in particular that negative infinity is not negative. A few important facts about negative numbers: - Note that ``Q.nonnegative`` and ``~Q.negative`` are *not* the same thing. ``~Q.negative(x)`` simply means that ``x`` is not negative, whereas ``Q.nonnegative(x)`` means that ``x`` is real and not negative, i.e., ``Q.nonnegative(x)`` is logically equivalent to ``Q.zero(x) | Q.positive(x)``. So for example, ``~Q.negative(I)`` is true, whereas ``Q.nonnegative(I)`` is false. - See the documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import Q, ask, symbols, I >>> x = symbols('x') >>> ask(Q.negative(x), Q.real(x) & ~Q.positive(x) & ~Q.zero(x)) True >>> ask(Q.negative(-1)) True >>> ask(Q.nonnegative(I)) False >>> ask(~Q.negative(I)) True """ return Predicate('negative') @predicate_memo def zero(self): """ Zero number predicate. ``ask(Q.zero(x))`` is true iff the value of ``x`` is zero. Examples ======== >>> from sympy import ask, Q, oo, symbols >>> x, y = symbols('x, y') >>> ask(Q.zero(0)) True >>> ask(Q.zero(1/oo)) True >>> ask(Q.zero(0*oo)) False >>> ask(Q.zero(1)) False >>> ask(Q.zero(x*y), Q.zero(x) | Q.zero(y)) True """ return Predicate('zero') @predicate_memo def nonzero(self): """ Nonzero real number predicate. ``ask(Q.nonzero(x))`` is true iff ``x`` is real and ``x`` is not zero. Note in particular that ``Q.nonzero(x)`` is false if ``x`` is not real. Use ``~Q.zero(x)`` if you want the negation of being zero without any real assumptions. A few important facts about nonzero numbers: - ``Q.nonzero`` is logically equivalent to ``Q.positive | Q.negative``. - See the documentation of ``Q.real`` for more information about related facts. Examples ======== >>> from sympy import Q, ask, symbols, I, oo >>> x = symbols('x') >>> print(ask(Q.nonzero(x), ~Q.zero(x))) None >>> ask(Q.nonzero(x), Q.positive(x)) True >>> ask(Q.nonzero(x), Q.zero(x)) False >>> ask(Q.nonzero(0)) False >>> ask(Q.nonzero(I)) False >>> ask(~Q.zero(I)) True >>> ask(Q.nonzero(oo)) #doctest: +SKIP False """ return Predicate('nonzero') @predicate_memo def nonpositive(self): """ Nonpositive real number predicate. ``ask(Q.nonpositive(x))`` is true iff ``x`` belongs to the set of negative numbers including zero. - Note that ``Q.nonpositive`` and ``~Q.positive`` are *not* the same thing. ``~Q.positive(x)`` simply means that ``x`` is not positive, whereas ``Q.nonpositive(x)`` means that ``x`` is real and not positive, i.e., ``Q.nonpositive(x)`` is logically equivalent to `Q.negative(x) | Q.zero(x)``. So for example, ``~Q.positive(I)`` is true, whereas ``Q.nonpositive(I)`` is false. Examples ======== >>> from sympy import Q, ask, I >>> ask(Q.nonpositive(-1)) True >>> ask(Q.nonpositive(0)) True >>> ask(Q.nonpositive(1)) False >>> ask(Q.nonpositive(I)) False >>> ask(Q.nonpositive(-I)) False """ return Predicate('nonpositive') @predicate_memo def nonnegative(self): """ Nonnegative real number predicate. ``ask(Q.nonnegative(x))`` is true iff ``x`` belongs to the set of positive numbers including zero. - Note that ``Q.nonnegative`` and ``~Q.negative`` are *not* the same thing. ``~Q.negative(x)`` simply means that ``x`` is not negative, whereas ``Q.nonnegative(x)`` means that ``x`` is real and not negative, i.e., ``Q.nonnegative(x)`` is logically equivalent to ``Q.zero(x) | Q.positive(x)``. So for example, ``~Q.negative(I)`` is true, whereas ``Q.nonnegative(I)`` is false. Examples ======== >>> from sympy import Q, ask, I >>> ask(Q.nonnegative(1)) True >>> ask(Q.nonnegative(0)) True >>> ask(Q.nonnegative(-1)) False >>> ask(Q.nonnegative(I)) False >>> ask(Q.nonnegative(-I)) False """ return Predicate('nonnegative') @predicate_memo def even(self): """ Even number predicate. ``ask(Q.even(x))`` is true iff ``x`` belongs to the set of even integers. Examples ======== >>> from sympy import Q, ask, pi >>> ask(Q.even(0)) True >>> ask(Q.even(2)) True >>> ask(Q.even(3)) False >>> ask(Q.even(pi)) False """ return Predicate('even') @predicate_memo def odd(self): """ Odd number predicate. ``ask(Q.odd(x))`` is true iff ``x`` belongs to the set of odd numbers. Examples ======== >>> from sympy import Q, ask, pi >>> ask(Q.odd(0)) False >>> ask(Q.odd(2)) False >>> ask(Q.odd(3)) True >>> ask(Q.odd(pi)) False """ return Predicate('odd') @predicate_memo def prime(self): """ Prime number predicate. ``ask(Q.prime(x))`` is true iff ``x`` is a natural number greater than 1 that has no positive divisors other than ``1`` and the number itself. Examples ======== >>> from sympy import Q, ask >>> ask(Q.prime(0)) False >>> ask(Q.prime(1)) False >>> ask(Q.prime(2)) True >>> ask(Q.prime(20)) False >>> ask(Q.prime(-3)) False """ return Predicate('prime') @predicate_memo def composite(self): """ Composite number predicate. ``ask(Q.composite(x))`` is true iff ``x`` is a positive integer and has at least one positive divisor other than ``1`` and the number itself. Examples ======== >>> from sympy import Q, ask >>> ask(Q.composite(0)) False >>> ask(Q.composite(1)) False >>> ask(Q.composite(2)) False >>> ask(Q.composite(20)) True """ return Predicate('composite') @predicate_memo def commutative(self): """ Commutative predicate. ``ask(Q.commutative(x))`` is true iff ``x`` commutes with any other object with respect to multiplication operation. """ # TODO: Add examples return Predicate('commutative') @predicate_memo def is_true(self): """ Generic predicate. ``ask(Q.is_true(x))`` is true iff ``x`` is true. This only makes sense if ``x`` is a predicate. Examples ======== >>> from sympy import ask, Q, symbols >>> x = symbols('x') >>> ask(Q.is_true(True)) True """ return Predicate('is_true') @predicate_memo def symmetric(self): """ Symmetric matrix predicate. ``Q.symmetric(x)`` is true iff ``x`` is a square matrix and is equal to its transpose. Every square diagonal matrix is a symmetric matrix. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.symmetric(X*Z), Q.symmetric(X) & Q.symmetric(Z)) True >>> ask(Q.symmetric(X + Z), Q.symmetric(X) & Q.symmetric(Z)) True >>> ask(Q.symmetric(Y)) False References ========== .. [1] https://en.wikipedia.org/wiki/Symmetric_matrix """ # TODO: Add handlers to make these keys work with # actual matrices and add more examples in the docstring. return Predicate('symmetric') @predicate_memo def invertible(self): """ Invertible matrix predicate. ``Q.invertible(x)`` is true iff ``x`` is an invertible matrix. A square matrix is called invertible only if its determinant is 0. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.invertible(X*Y), Q.invertible(X)) False >>> ask(Q.invertible(X*Z), Q.invertible(X) & Q.invertible(Z)) True >>> ask(Q.invertible(X), Q.fullrank(X) & Q.square(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Invertible_matrix """ return Predicate('invertible') @predicate_memo def orthogonal(self): """ Orthogonal matrix predicate. ``Q.orthogonal(x)`` is true iff ``x`` is an orthogonal matrix. A square matrix ``M`` is an orthogonal matrix if it satisfies ``M^TM = MM^T = I`` where ``M^T`` is the transpose matrix of ``M`` and ``I`` is an identity matrix. Note that an orthogonal matrix is necessarily invertible. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.orthogonal(Y)) False >>> ask(Q.orthogonal(X*Z*X), Q.orthogonal(X) & Q.orthogonal(Z)) True >>> ask(Q.orthogonal(Identity(3))) True >>> ask(Q.invertible(X), Q.orthogonal(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Orthogonal_matrix """ return Predicate('orthogonal') @predicate_memo def unitary(self): """ Unitary matrix predicate. ``Q.unitary(x)`` is true iff ``x`` is a unitary matrix. Unitary matrix is an analogue to orthogonal matrix. A square matrix ``M`` with complex elements is unitary if :math:``M^TM = MM^T= I`` where :math:``M^T`` is the conjugate transpose matrix of ``M``. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.unitary(Y)) False >>> ask(Q.unitary(X*Z*X), Q.unitary(X) & Q.unitary(Z)) True >>> ask(Q.unitary(Identity(3))) True References ========== .. [1] https://en.wikipedia.org/wiki/Unitary_matrix """ return Predicate('unitary') @predicate_memo def positive_definite(self): r""" Positive definite matrix predicate. If ``M`` is a :math:``n \times n`` symmetric real matrix, it is said to be positive definite if :math:`Z^TMZ` is positive for every non-zero column vector ``Z`` of ``n`` real numbers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('Y', 2, 3) >>> Z = MatrixSymbol('Z', 2, 2) >>> ask(Q.positive_definite(Y)) False >>> ask(Q.positive_definite(Identity(3))) True >>> ask(Q.positive_definite(X + Z), Q.positive_definite(X) & ... Q.positive_definite(Z)) True References ========== .. [1] https://en.wikipedia.org/wiki/Positive-definite_matrix """ return Predicate('positive_definite') @predicate_memo def upper_triangular(self): """ Upper triangular matrix predicate. A matrix ``M`` is called upper triangular matrix if :math:`M_{ij}=0` for :math:`i<j`. Examples ======== >>> from sympy import Q, ask, ZeroMatrix, Identity >>> ask(Q.upper_triangular(Identity(3))) True >>> ask(Q.upper_triangular(ZeroMatrix(3, 3))) True References ========== .. [1] http://mathworld.wolfram.com/UpperTriangularMatrix.html """ return Predicate('upper_triangular') @predicate_memo def lower_triangular(self): """ Lower triangular matrix predicate. A matrix ``M`` is called lower triangular matrix if :math:`a_{ij}=0` for :math:`i>j`. Examples ======== >>> from sympy import Q, ask, ZeroMatrix, Identity >>> ask(Q.lower_triangular(Identity(3))) True >>> ask(Q.lower_triangular(ZeroMatrix(3, 3))) True References ========== .. [1] http://mathworld.wolfram.com/LowerTriangularMatrix.html """ return Predicate('lower_triangular') @predicate_memo def diagonal(self): """ Diagonal matrix predicate. ``Q.diagonal(x)`` is true iff ``x`` is a diagonal matrix. A diagonal matrix is a matrix in which the entries outside the main diagonal are all zero. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, ZeroMatrix >>> X = MatrixSymbol('X', 2, 2) >>> ask(Q.diagonal(ZeroMatrix(3, 3))) True >>> ask(Q.diagonal(X), Q.lower_triangular(X) & ... Q.upper_triangular(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Diagonal_matrix """ return Predicate('diagonal') @predicate_memo def fullrank(self): """ Fullrank matrix predicate. ``Q.fullrank(x)`` is true iff ``x`` is a full rank matrix. A matrix is full rank if all rows and columns of the matrix are linearly independent. A square matrix is full rank iff its determinant is nonzero. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, ZeroMatrix, Identity >>> X = MatrixSymbol('X', 2, 2) >>> ask(Q.fullrank(X.T), Q.fullrank(X)) True >>> ask(Q.fullrank(ZeroMatrix(3, 3))) False >>> ask(Q.fullrank(Identity(3))) True """ return Predicate('fullrank') @predicate_memo def square(self): """ Square matrix predicate. ``Q.square(x)`` is true iff ``x`` is a square matrix. A square matrix is a matrix with the same number of rows and columns. Examples ======== >>> from sympy import Q, ask, MatrixSymbol, ZeroMatrix, Identity >>> X = MatrixSymbol('X', 2, 2) >>> Y = MatrixSymbol('X', 2, 3) >>> ask(Q.square(X)) True >>> ask(Q.square(Y)) False >>> ask(Q.square(ZeroMatrix(3, 3))) True >>> ask(Q.square(Identity(3))) True References ========== .. [1] https://en.wikipedia.org/wiki/Square_matrix """ return Predicate('square') @predicate_memo def integer_elements(self): """ Integer elements matrix predicate. ``Q.integer_elements(x)`` is true iff all the elements of ``x`` are integers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.integer(X[1, 2]), Q.integer_elements(X)) True """ return Predicate('integer_elements') @predicate_memo def real_elements(self): """ Real elements matrix predicate. ``Q.real_elements(x)`` is true iff all the elements of ``x`` are real numbers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.real(X[1, 2]), Q.real_elements(X)) True """ return Predicate('real_elements') @predicate_memo def complex_elements(self): """ Complex elements matrix predicate. ``Q.complex_elements(x)`` is true iff all the elements of ``x`` are complex numbers. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.complex(X[1, 2]), Q.complex_elements(X)) True >>> ask(Q.complex_elements(X), Q.integer_elements(X)) True """ return Predicate('complex_elements') @predicate_memo def singular(self): """ Singular matrix predicate. A matrix is singular iff the value of its determinant is 0. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.singular(X), Q.invertible(X)) False >>> ask(Q.singular(X), ~Q.invertible(X)) True References ========== .. [1] http://mathworld.wolfram.com/SingularMatrix.html """ return Predicate('singular') @predicate_memo def normal(self): """ Normal matrix predicate. A matrix is normal if it commutes with its conjugate transpose. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.normal(X), Q.unitary(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Normal_matrix """ return Predicate('normal') @predicate_memo def triangular(self): """ Triangular matrix predicate. ``Q.triangular(X)`` is true if ``X`` is one that is either lower triangular or upper triangular. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.triangular(X), Q.upper_triangular(X)) True >>> ask(Q.triangular(X), Q.lower_triangular(X)) True References ========== .. [1] https://en.wikipedia.org/wiki/Triangular_matrix """ return Predicate('triangular') @predicate_memo def unit_triangular(self): """ Unit triangular matrix predicate. A unit triangular matrix is a triangular matrix with 1s on the diagonal. Examples ======== >>> from sympy import Q, ask, MatrixSymbol >>> X = MatrixSymbol('X', 4, 4) >>> ask(Q.triangular(X), Q.unit_triangular(X)) True """ return Predicate('unit_triangular') Q = AssumptionKeys() def _extract_facts(expr, symbol, check_reversed_rel=True): """ Helper for ask(). Extracts the facts relevant to the symbol from an assumption. Returns None if there is nothing to extract. """ if isinstance(symbol, Relational): if check_reversed_rel: rev = _extract_facts(expr, symbol.reversed, False) if rev is not None: return rev if isinstance(expr, bool): return if not expr.has(symbol): return if isinstance(expr, AppliedPredicate): if expr.arg == symbol: return expr.func else: return if isinstance(expr, Not) and expr.args[0].func in (And, Or): cls = Or if expr.args[0] == And else And expr = cls(*[~arg for arg in expr.args[0].args]) args = [_extract_facts(arg, symbol) for arg in expr.args] if isinstance(expr, And): args = [x for x in args if x is not None] if args: return expr.func(*args) if args and all(x is not None for x in args): return expr.func(*args) def ask(proposition, assumptions=True, context=global_assumptions): """ Method for inferring properties about objects. **Syntax** * ask(proposition) * ask(proposition, assumptions) where ``proposition`` is any boolean expression Examples ======== >>> from sympy import ask, Q, pi >>> from sympy.abc import x, y >>> ask(Q.rational(pi)) False >>> ask(Q.even(x*y), Q.even(x) & Q.integer(y)) True >>> ask(Q.prime(4*x), Q.integer(x)) False **Remarks** Relations in assumptions are not implemented (yet), so the following will not give a meaningful result. >>> ask(Q.positive(x), Q.is_true(x > 0)) # doctest: +SKIP It is however a work in progress. """ from sympy.assumptions.satask import satask if not isinstance(proposition, (BooleanFunction, AppliedPredicate, bool, BooleanAtom)): raise TypeError("proposition must be a valid logical expression") if not isinstance(assumptions, (BooleanFunction, AppliedPredicate, bool, BooleanAtom)): raise TypeError("assumptions must be a valid logical expression") if isinstance(proposition, AppliedPredicate): key, expr = proposition.func, sympify(proposition.arg) else: key, expr = Q.is_true, sympify(proposition) assumptions = And(assumptions, And(*context)) assumptions = to_cnf(assumptions) local_facts = _extract_facts(assumptions, expr) known_facts_cnf = get_known_facts_cnf() known_facts_dict = get_known_facts_dict() if local_facts and satisfiable(And(local_facts, known_facts_cnf)) is False: raise ValueError("inconsistent assumptions %s" % assumptions) # direct resolution method, no logic res = key(expr)._eval_ask(assumptions) if res is not None: return bool(res) if local_facts is None: return satask(proposition, assumptions=assumptions, context=context) # See if there's a straight-forward conclusion we can make for the inference if local_facts.is_Atom: if key in known_facts_dict[local_facts]: return True if Not(key) in known_facts_dict[local_facts]: return False elif (isinstance(local_facts, And) and all(k in known_facts_dict for k in local_facts.args)): for assum in local_facts.args: if assum.is_Atom: if key in known_facts_dict[assum]: return True if Not(key) in known_facts_dict[assum]: return False elif isinstance(assum, Not) and assum.args[0].is_Atom: if key in known_facts_dict[assum]: return False if Not(key) in known_facts_dict[assum]: return True elif (isinstance(key, Predicate) and isinstance(local_facts, Not) and local_facts.args[0].is_Atom): if local_facts.args[0] in known_facts_dict[key]: return False # Failing all else, we do a full logical inference res = ask_full_inference(key, local_facts, known_facts_cnf) if res is None: return satask(proposition, assumptions=assumptions, context=context) return res def ask_full_inference(proposition, assumptions, known_facts_cnf): """ Method for inferring properties about objects. """ if not satisfiable(And(known_facts_cnf, assumptions, proposition)): return False if not satisfiable(And(known_facts_cnf, assumptions, Not(proposition))): return True return None def register_handler(key, handler): """ Register a handler in the ask system. key must be a string and handler a class inheriting from AskHandler:: >>> from sympy.assumptions import register_handler, ask, Q >>> from sympy.assumptions.handlers import AskHandler >>> class MersenneHandler(AskHandler): ... # Mersenne numbers are in the form 2**n - 1, n integer ... @staticmethod ... def Integer(expr, assumptions): ... from sympy import log ... return ask(Q.integer(log(expr + 1, 2))) >>> register_handler('mersenne', MersenneHandler) >>> ask(Q.mersenne(7)) True """ if type(key) is Predicate: key = key.name Qkey = getattr(Q, key, None) if Qkey is not None: Qkey.add_handler(handler) else: setattr(Q, key, Predicate(key, handlers=[handler])) def remove_handler(key, handler): """Removes a handler from the ask system. Same syntax as register_handler""" if type(key) is Predicate: key = key.name getattr(Q, key).remove_handler(handler) def single_fact_lookup(known_facts_keys, known_facts_cnf): # Compute the quick lookup for single facts mapping = {} for key in known_facts_keys: mapping[key] = {key} for other_key in known_facts_keys: if other_key != key: if ask_full_inference(other_key, key, known_facts_cnf): mapping[key].add(other_key) return mapping def compute_known_facts(known_facts, known_facts_keys): """Compute the various forms of knowledge compilation used by the assumptions system. This function is typically applied to the results of the ``get_known_facts`` and ``get_known_facts_keys`` functions defined at the bottom of this file. """ from textwrap import dedent, wrap fact_string = dedent('''\ """ The contents of this file are the return value of ``sympy.assumptions.ask.compute_known_facts``. Do NOT manually edit this file. Instead, run ./bin/ask_update.py. """ from sympy.core.cache import cacheit from sympy.logic.boolalg import And from sympy.assumptions.ask import Q # -{ Known facts in Conjunctive Normal Form }- @cacheit def get_known_facts_cnf(): return And( %s ) # -{ Known facts in compressed sets }- @cacheit def get_known_facts_dict(): return { %s } ''') # Compute the known facts in CNF form for logical inference LINE = ",\n " HANG = ' '*8 cnf = to_cnf(known_facts) c = LINE.join([str(a) for a in cnf.args]) mapping = single_fact_lookup(known_facts_keys, cnf) items = sorted(mapping.items(), key=str) keys = [str(i[0]) for i in items] values = ['set(%s)' % sorted(i[1], key=str) for i in items] m = LINE.join(['\n'.join( wrap("%s: %s" % (k, v), subsequent_indent=HANG, break_long_words=False)) for k, v in zip(keys, values)]) + ',' return fact_string % (c, m) # handlers tells us what ask handler we should use # for a particular key _val_template = 'sympy.assumptions.handlers.%s' _handlers = [ ("antihermitian", "sets.AskAntiHermitianHandler"), ("finite", "calculus.AskFiniteHandler"), ("commutative", "AskCommutativeHandler"), ("complex", "sets.AskComplexHandler"), ("composite", "ntheory.AskCompositeHandler"), ("even", "ntheory.AskEvenHandler"), ("extended_real", "sets.AskExtendedRealHandler"), ("hermitian", "sets.AskHermitianHandler"), ("imaginary", "sets.AskImaginaryHandler"), ("integer", "sets.AskIntegerHandler"), ("irrational", "sets.AskIrrationalHandler"), ("rational", "sets.AskRationalHandler"), ("negative", "order.AskNegativeHandler"), ("nonzero", "order.AskNonZeroHandler"), ("nonpositive", "order.AskNonPositiveHandler"), ("nonnegative", "order.AskNonNegativeHandler"), ("zero", "order.AskZeroHandler"), ("positive", "order.AskPositiveHandler"), ("prime", "ntheory.AskPrimeHandler"), ("real", "sets.AskRealHandler"), ("odd", "ntheory.AskOddHandler"), ("algebraic", "sets.AskAlgebraicHandler"), ("is_true", "common.TautologicalHandler"), ("symmetric", "matrices.AskSymmetricHandler"), ("invertible", "matrices.AskInvertibleHandler"), ("orthogonal", "matrices.AskOrthogonalHandler"), ("unitary", "matrices.AskUnitaryHandler"), ("positive_definite", "matrices.AskPositiveDefiniteHandler"), ("upper_triangular", "matrices.AskUpperTriangularHandler"), ("lower_triangular", "matrices.AskLowerTriangularHandler"), ("diagonal", "matrices.AskDiagonalHandler"), ("fullrank", "matrices.AskFullRankHandler"), ("square", "matrices.AskSquareHandler"), ("integer_elements", "matrices.AskIntegerElementsHandler"), ("real_elements", "matrices.AskRealElementsHandler"), ("complex_elements", "matrices.AskComplexElementsHandler"), ] for name, value in _handlers: register_handler(name, _val_template % value) @cacheit def get_known_facts_keys(): return [ getattr(Q, attr) for attr in Q.__class__.__dict__ if not (attr.startswith('__') or attr in deprecated_predicates)] @cacheit def get_known_facts(): return And( Implies(Q.infinite, ~Q.finite), Implies(Q.real, Q.complex), Implies(Q.real, Q.hermitian), Equivalent(Q.extended_real, Q.real | Q.infinite), Equivalent(Q.even | Q.odd, Q.integer), Implies(Q.even, ~Q.odd), Equivalent(Q.prime, Q.integer & Q.positive & ~Q.composite), Implies(Q.integer, Q.rational), Implies(Q.rational, Q.algebraic), Implies(Q.irrational, Q.finite), Implies(Q.algebraic, Q.complex), Implies(Q.algebraic, Q.finite), Equivalent(Q.transcendental | Q.algebraic, Q.complex & Q.finite), Implies(Q.transcendental, ~Q.algebraic), Implies(Q.transcendental, Q.finite), Implies(Q.imaginary, Q.complex & ~Q.real), Implies(Q.imaginary, Q.antihermitian), Implies(Q.antihermitian, ~Q.hermitian), Equivalent(Q.irrational | Q.rational, Q.real & Q.finite), Implies(Q.irrational, ~Q.rational), Implies(Q.zero, Q.even), Equivalent(Q.real, Q.negative | Q.zero | Q.positive), Implies(Q.zero, ~Q.negative & ~Q.positive), Implies(Q.negative, ~Q.positive), Equivalent(Q.nonnegative, Q.zero | Q.positive), Equivalent(Q.nonpositive, Q.zero | Q.negative), Equivalent(Q.nonzero, Q.negative | Q.positive), Implies(Q.orthogonal, Q.positive_definite), Implies(Q.orthogonal, Q.unitary), Implies(Q.unitary & Q.real, Q.orthogonal), Implies(Q.unitary, Q.normal), Implies(Q.unitary, Q.invertible), Implies(Q.normal, Q.square), Implies(Q.diagonal, Q.normal), Implies(Q.positive_definite, Q.invertible), Implies(Q.diagonal, Q.upper_triangular), Implies(Q.diagonal, Q.lower_triangular), Implies(Q.lower_triangular, Q.triangular), Implies(Q.upper_triangular, Q.triangular), Implies(Q.triangular, Q.upper_triangular | Q.lower_triangular), Implies(Q.upper_triangular & Q.lower_triangular, Q.diagonal), Implies(Q.diagonal, Q.symmetric), Implies(Q.unit_triangular, Q.triangular), Implies(Q.invertible, Q.fullrank), Implies(Q.invertible, Q.square), Implies(Q.symmetric, Q.square), Implies(Q.fullrank & Q.square, Q.invertible), Equivalent(Q.invertible, ~Q.singular), Implies(Q.integer_elements, Q.real_elements), Implies(Q.real_elements, Q.complex_elements), ) from sympy.assumptions.ask_generated import ( get_known_facts_dict, get_known_facts_cnf)

0dacb82142d10b7b1d93490003fa36df812848b27cf23fde3e0f8e30bdba295f

r""" This module contains :py:meth:`~sympy.solvers.ode.dsolve` and different helper functions that it uses. :py:meth:`~sympy.solvers.ode.dsolve` solves ordinary differential equations. See the docstring on the various functions for their uses. Note that partial differential equations support is in ``pde.py``. Note that hint functions have docstrings describing their various methods, but they are intended for internal use. Use ``dsolve(ode, func, hint=hint)`` to solve an ODE using a specific hint. See also the docstring on :py:meth:`~sympy.solvers.ode.dsolve`. **Functions in this module** These are the user functions in this module: - :py:meth:`~sympy.solvers.ode.dsolve` - Solves ODEs. - :py:meth:`~sympy.solvers.ode.classify_ode` - Classifies ODEs into possible hints for :py:meth:`~sympy.solvers.ode.dsolve`. - :py:meth:`~sympy.solvers.ode.checkodesol` - Checks if an equation is the solution to an ODE. - :py:meth:`~sympy.solvers.ode.homogeneous_order` - Returns the homogeneous order of an expression. - :py:meth:`~sympy.solvers.ode.infinitesimals` - Returns the infinitesimals of the Lie group of point transformations of an ODE, such that it is invariant. - :py:meth:`~sympy.solvers.ode_checkinfsol` - Checks if the given infinitesimals are the actual infinitesimals of a first order ODE. These are the non-solver helper functions that are for internal use. The user should use the various options to :py:meth:`~sympy.solvers.ode.dsolve` to obtain the functionality provided by these functions: - :py:meth:`~sympy.solvers.ode.odesimp` - Does all forms of ODE simplification. - :py:meth:`~sympy.solvers.ode.ode_sol_simplicity` - A key function for comparing solutions by simplicity. - :py:meth:`~sympy.solvers.ode.constantsimp` - Simplifies arbitrary constants. - :py:meth:`~sympy.solvers.ode.constant_renumber` - Renumber arbitrary constants. - :py:meth:`~sympy.solvers.ode._handle_Integral` - Evaluate unevaluated Integrals. See also the docstrings of these functions. **Currently implemented solver methods** The following methods are implemented for solving ordinary differential equations. See the docstrings of the various hint functions for more information on each (run ``help(ode)``): - 1st order separable differential equations. - 1st order differential equations whose coefficients or `dx` and `dy` are functions homogeneous of the same order. - 1st order exact differential equations. - 1st order linear differential equations. - 1st order Bernoulli differential equations. - Power series solutions for first order differential equations. - Lie Group method of solving first order differential equations. - 2nd order Liouville differential equations. - Power series solutions for second order differential equations at ordinary and regular singular points. - `n`\th order differential equation that can be solved with algebraic rearrangement and integration. - `n`\th order linear homogeneous differential equation with constant coefficients. - `n`\th order linear inhomogeneous differential equation with constant coefficients using the method of undetermined coefficients. - `n`\th order linear inhomogeneous differential equation with constant coefficients using the method of variation of parameters. **Philosophy behind this module** This module is designed to make it easy to add new ODE solving methods without having to mess with the solving code for other methods. The idea is that there is a :py:meth:`~sympy.solvers.ode.classify_ode` function, which takes in an ODE and tells you what hints, if any, will solve the ODE. It does this without attempting to solve the ODE, so it is fast. Each solving method is a hint, and it has its own function, named ``ode_<hint>``. That function takes in the ODE and any match expression gathered by :py:meth:`~sympy.solvers.ode.classify_ode` and returns a solved result. If this result has any integrals in it, the hint function will return an unevaluated :py:class:`~sympy.integrals.Integral` class. :py:meth:`~sympy.solvers.ode.dsolve`, which is the user wrapper function around all of this, will then call :py:meth:`~sympy.solvers.ode.odesimp` on the result, which, among other things, will attempt to solve the equation for the dependent variable (the function we are solving for), simplify the arbitrary constants in the expression, and evaluate any integrals, if the hint allows it. **How to add new solution methods** If you have an ODE that you want :py:meth:`~sympy.solvers.ode.dsolve` to be able to solve, try to avoid adding special case code here. Instead, try finding a general method that will solve your ODE, as well as others. This way, the :py:mod:`~sympy.solvers.ode` module will become more robust, and unhindered by special case hacks. WolphramAlpha and Maple's DETools[odeadvisor] function are two resources you can use to classify a specific ODE. It is also better for a method to work with an `n`\th order ODE instead of only with specific orders, if possible. To add a new method, there are a few things that you need to do. First, you need a hint name for your method. Try to name your hint so that it is unambiguous with all other methods, including ones that may not be implemented yet. If your method uses integrals, also include a ``hint_Integral`` hint. If there is more than one way to solve ODEs with your method, include a hint for each one, as well as a ``<hint>_best`` hint. Your ``ode_<hint>_best()`` function should choose the best using min with ``ode_sol_simplicity`` as the key argument. See :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_best`, for example. The function that uses your method will be called ``ode_<hint>()``, so the hint must only use characters that are allowed in a Python function name (alphanumeric characters and the underscore '``_``' character). Include a function for every hint, except for ``_Integral`` hints (:py:meth:`~sympy.solvers.ode.dsolve` takes care of those automatically). Hint names should be all lowercase, unless a word is commonly capitalized (such as Integral or Bernoulli). If you have a hint that you do not want to run with ``all_Integral`` that doesn't have an ``_Integral`` counterpart (such as a best hint that would defeat the purpose of ``all_Integral``), you will need to remove it manually in the :py:meth:`~sympy.solvers.ode.dsolve` code. See also the :py:meth:`~sympy.solvers.ode.classify_ode` docstring for guidelines on writing a hint name. Determine *in general* how the solutions returned by your method compare with other methods that can potentially solve the same ODEs. Then, put your hints in the :py:data:`~sympy.solvers.ode.allhints` tuple in the order that they should be called. The ordering of this tuple determines which hints are default. Note that exceptions are ok, because it is easy for the user to choose individual hints with :py:meth:`~sympy.solvers.ode.dsolve`. In general, ``_Integral`` variants should go at the end of the list, and ``_best`` variants should go before the various hints they apply to. For example, the ``undetermined_coefficients`` hint comes before the ``variation_of_parameters`` hint because, even though variation of parameters is more general than undetermined coefficients, undetermined coefficients generally returns cleaner results for the ODEs that it can solve than variation of parameters does, and it does not require integration, so it is much faster. Next, you need to have a match expression or a function that matches the type of the ODE, which you should put in :py:meth:`~sympy.solvers.ode.classify_ode` (if the match function is more than just a few lines, like :py:meth:`~sympy.solvers.ode._undetermined_coefficients_match`, it should go outside of :py:meth:`~sympy.solvers.ode.classify_ode`). It should match the ODE without solving for it as much as possible, so that :py:meth:`~sympy.solvers.ode.classify_ode` remains fast and is not hindered by bugs in solving code. Be sure to consider corner cases. For example, if your solution method involves dividing by something, make sure you exclude the case where that division will be 0. In most cases, the matching of the ODE will also give you the various parts that you need to solve it. You should put that in a dictionary (``.match()`` will do this for you), and add that as ``matching_hints['hint'] = matchdict`` in the relevant part of :py:meth:`~sympy.solvers.ode.classify_ode`. :py:meth:`~sympy.solvers.ode.classify_ode` will then send this to :py:meth:`~sympy.solvers.ode.dsolve`, which will send it to your function as the ``match`` argument. Your function should be named ``ode_<hint>(eq, func, order, match)`. If you need to send more information, put it in the ``match`` dictionary. For example, if you had to substitute in a dummy variable in :py:meth:`~sympy.solvers.ode.classify_ode` to match the ODE, you will need to pass it to your function using the `match` dict to access it. You can access the independent variable using ``func.args[0]``, and the dependent variable (the function you are trying to solve for) as ``func.func``. If, while trying to solve the ODE, you find that you cannot, raise ``NotImplementedError``. :py:meth:`~sympy.solvers.ode.dsolve` will catch this error with the ``all`` meta-hint, rather than causing the whole routine to fail. Add a docstring to your function that describes the method employed. Like with anything else in SymPy, you will need to add a doctest to the docstring, in addition to real tests in ``test_ode.py``. Try to maintain consistency with the other hint functions' docstrings. Add your method to the list at the top of this docstring. Also, add your method to ``ode.rst`` in the ``docs/src`` directory, so that the Sphinx docs will pull its docstring into the main SymPy documentation. Be sure to make the Sphinx documentation by running ``make html`` from within the doc directory to verify that the docstring formats correctly. If your solution method involves integrating, use :py:meth:`Integral() <sympy.integrals.integrals.Integral>` instead of :py:meth:`~sympy.core.expr.Expr.integrate`. This allows the user to bypass hard/slow integration by using the ``_Integral`` variant of your hint. In most cases, calling :py:meth:`sympy.core.basic.Basic.doit` will integrate your solution. If this is not the case, you will need to write special code in :py:meth:`~sympy.solvers.ode._handle_Integral`. Arbitrary constants should be symbols named ``C1``, ``C2``, and so on. All solution methods should return an equality instance. If you need an arbitrary number of arbitrary constants, you can use ``constants = numbered_symbols(prefix='C', cls=Symbol, start=1)``. If it is possible to solve for the dependent function in a general way, do so. Otherwise, do as best as you can, but do not call solve in your ``ode_<hint>()`` function. :py:meth:`~sympy.solvers.ode.odesimp` will attempt to solve the solution for you, so you do not need to do that. Lastly, if your ODE has a common simplification that can be applied to your solutions, you can add a special case in :py:meth:`~sympy.solvers.ode.odesimp` for it. For example, solutions returned from the ``1st_homogeneous_coeff`` hints often have many :py:meth:`~sympy.functions.log` terms, so :py:meth:`~sympy.solvers.ode.odesimp` calls :py:meth:`~sympy.simplify.simplify.logcombine` on them (it also helps to write the arbitrary constant as ``log(C1)`` instead of ``C1`` in this case). Also consider common ways that you can rearrange your solution to have :py:meth:`~sympy.solvers.ode.constantsimp` take better advantage of it. It is better to put simplification in :py:meth:`~sympy.solvers.ode.odesimp` than in your method, because it can then be turned off with the simplify flag in :py:meth:`~sympy.solvers.ode.dsolve`. If you have any extraneous simplification in your function, be sure to only run it using ``if match.get('simplify', True):``, especially if it can be slow or if it can reduce the domain of the solution. Finally, as with every contribution to SymPy, your method will need to be tested. Add a test for each method in ``test_ode.py``. Follow the conventions there, i.e., test the solver using ``dsolve(eq, f(x), hint=your_hint)``, and also test the solution using :py:meth:`~sympy.solvers.ode.checkodesol` (you can put these in a separate tests and skip/XFAIL if it runs too slow/doesn't work). Be sure to call your hint specifically in :py:meth:`~sympy.solvers.ode.dsolve`, that way the test won't be broken simply by the introduction of another matching hint. If your method works for higher order (>1) ODEs, you will need to run ``sol = constant_renumber(sol, 'C', 1, order)`` for each solution, where ``order`` is the order of the ODE. This is because ``constant_renumber`` renumbers the arbitrary constants by printing order, which is platform dependent. Try to test every corner case of your solver, including a range of orders if it is a `n`\th order solver, but if your solver is slow, such as if it involves hard integration, try to keep the test run time down. Feel free to refactor existing hints to avoid duplicating code or creating inconsistencies. If you can show that your method exactly duplicates an existing method, including in the simplicity and speed of obtaining the solutions, then you can remove the old, less general method. The existing code is tested extensively in ``test_ode.py``, so if anything is broken, one of those tests will surely fail. """ from __future__ import print_function, division from collections import defaultdict from itertools import islice from sympy.core import Add, S, Mul, Pow, oo from sympy.core.compatibility import ordered, iterable, is_sequence, range, string_types from sympy.core.containers import Tuple from sympy.core.exprtools import factor_terms from sympy.core.expr import AtomicExpr, Expr from sympy.core.function import (Function, Derivative, AppliedUndef, diff, expand, expand_mul, Subs, _mexpand) from sympy.core.multidimensional import vectorize from sympy.core.numbers import NaN, zoo, I, Number from sympy.core.relational import Equality, Eq from sympy.core.symbol import Symbol, Wild, Dummy, symbols from sympy.core.sympify import sympify from sympy.logic.boolalg import (BooleanAtom, And, Not, BooleanTrue, BooleanFalse) from sympy.functions import cos, exp, im, log, re, sin, tan, sqrt, \ atan2, conjugate, Piecewise from sympy.functions.combinatorial.factorials import factorial from sympy.integrals.integrals import Integral, integrate from sympy.matrices import wronskian, Matrix, eye, zeros from sympy.polys import (Poly, RootOf, rootof, terms_gcd, PolynomialError, lcm, roots) from sympy.polys.polyroots import roots_quartic from sympy.polys.polytools import cancel, degree, div from sympy.series import Order from sympy.series.series import series from sympy.simplify import collect, logcombine, powsimp, separatevars, \ simplify, trigsimp, posify, cse from sympy.simplify.powsimp import powdenest from sympy.simplify.radsimp import collect_const from sympy.solvers import solve from sympy.solvers.pde import pdsolve from sympy.utilities import numbered_symbols, default_sort_key, sift from sympy.solvers.deutils import _preprocess, ode_order, _desolve #: This is a list of hints in the order that they should be preferred by #: :py:meth:`~sympy.solvers.ode.classify_ode`. In general, hints earlier in the #: list should produce simpler solutions than those later in the list (for #: ODEs that fit both). For now, the order of this list is based on empirical #: observations by the developers of SymPy. #: #: The hint used by :py:meth:`~sympy.solvers.ode.dsolve` for a specific ODE #: can be overridden (see the docstring). #: #: In general, ``_Integral`` hints are grouped at the end of the list, unless #: there is a method that returns an unevaluable integral most of the time #: (which go near the end of the list anyway). ``default``, ``all``, #: ``best``, and ``all_Integral`` meta-hints should not be included in this #: list, but ``_best`` and ``_Integral`` hints should be included. allhints = ( "nth_algebraic", "separable", "1st_exact", "1st_linear", "Bernoulli", "Riccati_special_minus2", "1st_homogeneous_coeff_best", "1st_homogeneous_coeff_subs_indep_div_dep", "1st_homogeneous_coeff_subs_dep_div_indep", "almost_linear", "linear_coefficients", "separable_reduced", "1st_power_series", "lie_group", "nth_linear_constant_coeff_homogeneous", "nth_linear_euler_eq_homogeneous", "nth_linear_constant_coeff_undetermined_coefficients", "nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients", "nth_linear_constant_coeff_variation_of_parameters", "nth_linear_euler_eq_nonhomogeneous_variation_of_parameters", "Liouville", "nth_order_reducible", "2nd_power_series_ordinary", "2nd_power_series_regular", "nth_algebraic_Integral", "separable_Integral", "1st_exact_Integral", "1st_linear_Integral", "Bernoulli_Integral", "1st_homogeneous_coeff_subs_indep_div_dep_Integral", "1st_homogeneous_coeff_subs_dep_div_indep_Integral", "almost_linear_Integral", "linear_coefficients_Integral", "separable_reduced_Integral", "nth_linear_constant_coeff_variation_of_parameters_Integral", "nth_linear_euler_eq_nonhomogeneous_variation_of_parameters_Integral", "Liouville_Integral", ) lie_heuristics = ( "abaco1_simple", "abaco1_product", "abaco2_similar", "abaco2_unique_unknown", "abaco2_unique_general", "linear", "function_sum", "bivariate", "chi" ) def sub_func_doit(eq, func, new): r""" When replacing the func with something else, we usually want the derivative evaluated, so this function helps in making that happen. Examples ======== >>> from sympy import Derivative, symbols, Function >>> from sympy.solvers.ode import sub_func_doit >>> x, z = symbols('x, z') >>> y = Function('y') >>> sub_func_doit(3*Derivative(y(x), x) - 1, y(x), x) 2 >>> sub_func_doit(x*Derivative(y(x), x) - y(x)**2 + y(x), y(x), ... 1/(x*(z + 1/x))) x*(-1/(x**2*(z + 1/x)) + 1/(x**3*(z + 1/x)**2)) + 1/(x*(z + 1/x)) ...- 1/(x**2*(z + 1/x)**2) """ reps= {func: new} for d in eq.atoms(Derivative): if d.expr == func: reps[d] = new.diff(*d.variable_count) else: reps[d] = d.xreplace({func: new}).doit(deep=False) return eq.xreplace(reps) def get_numbered_constants(eq, num=1, start=1, prefix='C'): """ Returns a list of constants that do not occur in eq already. """ ncs = iter_numbered_constants(eq, start, prefix) Cs = [next(ncs) for i in range(num)] return (Cs[0] if num == 1 else tuple(Cs)) def iter_numbered_constants(eq, start=1, prefix='C'): """ Returns an iterator of constants that do not occur in eq already. """ if isinstance(eq, Expr): eq = [eq] elif not iterable(eq): raise ValueError("Expected Expr or iterable but got %s" % eq) atom_set = set().union(*[i.free_symbols for i in eq]) func_set = set().union(*[i.atoms(Function) for i in eq]) if func_set: atom_set |= {Symbol(str(f.func)) for f in func_set} return numbered_symbols(start=start, prefix=prefix, exclude=atom_set) def dsolve(eq, func=None, hint="default", simplify=True, ics= None, xi=None, eta=None, x0=0, n=6, **kwargs): r""" Solves any (supported) kind of ordinary differential equation and system of ordinary differential equations. For single ordinary differential equation ========================================= It is classified under this when number of equation in ``eq`` is one. **Usage** ``dsolve(eq, f(x), hint)`` -> Solve ordinary differential equation ``eq`` for function ``f(x)``, using method ``hint``. **Details** ``eq`` can be any supported ordinary differential equation (see the :py:mod:`~sympy.solvers.ode` docstring for supported methods). This can either be an :py:class:`~sympy.core.relational.Equality`, or an expression, which is assumed to be equal to ``0``. ``f(x)`` is a function of one variable whose derivatives in that variable make up the ordinary differential equation ``eq``. In many cases it is not necessary to provide this; it will be autodetected (and an error raised if it couldn't be detected). ``hint`` is the solving method that you want dsolve to use. Use ``classify_ode(eq, f(x))`` to get all of the possible hints for an ODE. The default hint, ``default``, will use whatever hint is returned first by :py:meth:`~sympy.solvers.ode.classify_ode`. See Hints below for more options that you can use for hint. ``simplify`` enables simplification by :py:meth:`~sympy.solvers.ode.odesimp`. See its docstring for more information. Turn this off, for example, to disable solving of solutions for ``func`` or simplification of arbitrary constants. It will still integrate with this hint. Note that the solution may contain more arbitrary constants than the order of the ODE with this option enabled. ``xi`` and ``eta`` are the infinitesimal functions of an ordinary differential equation. They are the infinitesimals of the Lie group of point transformations for which the differential equation is invariant. The user can specify values for the infinitesimals. If nothing is specified, ``xi`` and ``eta`` are calculated using :py:meth:`~sympy.solvers.ode.infinitesimals` with the help of various heuristics. ``ics`` is the set of initial/boundary conditions for the differential equation. It should be given in the form of ``{f(x0): x1, f(x).diff(x).subs(x, x2): x3}`` and so on. For power series solutions, if no initial conditions are specified ``f(0)`` is assumed to be ``C0`` and the power series solution is calculated about 0. ``x0`` is the point about which the power series solution of a differential equation is to be evaluated. ``n`` gives the exponent of the dependent variable up to which the power series solution of a differential equation is to be evaluated. **Hints** Aside from the various solving methods, there are also some meta-hints that you can pass to :py:meth:`~sympy.solvers.ode.dsolve`: ``default``: This uses whatever hint is returned first by :py:meth:`~sympy.solvers.ode.classify_ode`. This is the default argument to :py:meth:`~sympy.solvers.ode.dsolve`. ``all``: To make :py:meth:`~sympy.solvers.ode.dsolve` apply all relevant classification hints, use ``dsolve(ODE, func, hint="all")``. This will return a dictionary of ``hint:solution`` terms. If a hint causes dsolve to raise the ``NotImplementedError``, value of that hint's key will be the exception object raised. The dictionary will also include some special keys: - ``order``: The order of the ODE. See also :py:meth:`~sympy.solvers.deutils.ode_order` in ``deutils.py``. - ``best``: The simplest hint; what would be returned by ``best`` below. - ``best_hint``: The hint that would produce the solution given by ``best``. If more than one hint produces the best solution, the first one in the tuple returned by :py:meth:`~sympy.solvers.ode.classify_ode` is chosen. - ``default``: The solution that would be returned by default. This is the one produced by the hint that appears first in the tuple returned by :py:meth:`~sympy.solvers.ode.classify_ode`. ``all_Integral``: This is the same as ``all``, except if a hint also has a corresponding ``_Integral`` hint, it only returns the ``_Integral`` hint. This is useful if ``all`` causes :py:meth:`~sympy.solvers.ode.dsolve` to hang because of a difficult or impossible integral. This meta-hint will also be much faster than ``all``, because :py:meth:`~sympy.core.expr.Expr.integrate` is an expensive routine. ``best``: To have :py:meth:`~sympy.solvers.ode.dsolve` try all methods and return the simplest one. This takes into account whether the solution is solvable in the function, whether it contains any Integral classes (i.e. unevaluatable integrals), and which one is the shortest in size. See also the :py:meth:`~sympy.solvers.ode.classify_ode` docstring for more info on hints, and the :py:mod:`~sympy.solvers.ode` docstring for a list of all supported hints. **Tips** - You can declare the derivative of an unknown function this way: >>> from sympy import Function, Derivative >>> from sympy.abc import x # x is the independent variable >>> f = Function("f")(x) # f is a function of x >>> # f_ will be the derivative of f with respect to x >>> f_ = Derivative(f, x) - See ``test_ode.py`` for many tests, which serves also as a set of examples for how to use :py:meth:`~sympy.solvers.ode.dsolve`. - :py:meth:`~sympy.solvers.ode.dsolve` always returns an :py:class:`~sympy.core.relational.Equality` class (except for the case when the hint is ``all`` or ``all_Integral``). If possible, it solves the solution explicitly for the function being solved for. Otherwise, it returns an implicit solution. - Arbitrary constants are symbols named ``C1``, ``C2``, and so on. - Because all solutions should be mathematically equivalent, some hints may return the exact same result for an ODE. Often, though, two different hints will return the same solution formatted differently. The two should be equivalent. Also note that sometimes the values of the arbitrary constants in two different solutions may not be the same, because one constant may have "absorbed" other constants into it. - Do ``help(ode.ode_<hintname>)`` to get help more information on a specific hint, where ``<hintname>`` is the name of a hint without ``_Integral``. For system of ordinary differential equations ============================================= **Usage** ``dsolve(eq, func)`` -> Solve a system of ordinary differential equations ``eq`` for ``func`` being list of functions including `x(t)`, `y(t)`, `z(t)` where number of functions in the list depends upon the number of equations provided in ``eq``. **Details** ``eq`` can be any supported system of ordinary differential equations This can either be an :py:class:`~sympy.core.relational.Equality`, or an expression, which is assumed to be equal to ``0``. ``func`` holds ``x(t)`` and ``y(t)`` being functions of one variable which together with some of their derivatives make up the system of ordinary differential equation ``eq``. It is not necessary to provide this; it will be autodetected (and an error raised if it couldn't be detected). **Hints** The hints are formed by parameters returned by classify_sysode, combining them give hints name used later for forming method name. Examples ======== >>> from sympy import Function, dsolve, Eq, Derivative, sin, cos, symbols >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(Derivative(f(x), x, x) + 9*f(x), f(x)) Eq(f(x), C1*sin(3*x) + C2*cos(3*x)) >>> eq = sin(x)*cos(f(x)) + cos(x)*sin(f(x))*f(x).diff(x) >>> dsolve(eq, hint='1st_exact') [Eq(f(x), -acos(C1/cos(x)) + 2*pi), Eq(f(x), acos(C1/cos(x)))] >>> dsolve(eq, hint='almost_linear') [Eq(f(x), -acos(C1/cos(x)) + 2*pi), Eq(f(x), acos(C1/cos(x)))] >>> t = symbols('t') >>> x, y = symbols('x, y', cls=Function) >>> eq = (Eq(Derivative(x(t),t), 12*t*x(t) + 8*y(t)), Eq(Derivative(y(t),t), 21*x(t) + 7*t*y(t))) >>> dsolve(eq) [Eq(x(t), C1*x0(t) + C2*x0(t)*Integral(8*exp(Integral(7*t, t))*exp(Integral(12*t, t))/x0(t)**2, t)), Eq(y(t), C1*y0(t) + C2*(y0(t)*Integral(8*exp(Integral(7*t, t))*exp(Integral(12*t, t))/x0(t)**2, t) + exp(Integral(7*t, t))*exp(Integral(12*t, t))/x0(t)))] >>> eq = (Eq(Derivative(x(t),t),x(t)*y(t)*sin(t)), Eq(Derivative(y(t),t),y(t)**2*sin(t))) >>> dsolve(eq) {Eq(x(t), -exp(C1)/(C2*exp(C1) - cos(t))), Eq(y(t), -1/(C1 - cos(t)))} """ if iterable(eq): match = classify_sysode(eq, func) eq = match['eq'] order = match['order'] func = match['func'] t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] # keep highest order term coefficient positive for i in range(len(eq)): for func_ in func: if isinstance(func_, list): pass else: if eq[i].coeff(diff(func[i],t,ode_order(eq[i], func[i]))).is_negative: eq[i] = -eq[i] match['eq'] = eq if len(set(order.values()))!=1: raise ValueError("It solves only those systems of equations whose orders are equal") match['order'] = list(order.values())[0] def recur_len(l): return sum(recur_len(item) if isinstance(item,list) else 1 for item in l) if recur_len(func) != len(eq): raise ValueError("dsolve() and classify_sysode() work with " "number of functions being equal to number of equations") if match['type_of_equation'] is None: raise NotImplementedError else: if match['is_linear'] == True: if match['no_of_equation'] > 3: solvefunc = globals()['sysode_linear_neq_order%(order)s' % match] else: solvefunc = globals()['sysode_linear_%(no_of_equation)seq_order%(order)s' % match] else: solvefunc = globals()['sysode_nonlinear_%(no_of_equation)seq_order%(order)s' % match] sols = solvefunc(match) if ics: constants = Tuple(*sols).free_symbols - Tuple(*eq).free_symbols solved_constants = solve_ics(sols, func, constants, ics) return [sol.subs(solved_constants) for sol in sols] return sols else: given_hint = hint # hint given by the user # See the docstring of _desolve for more details. hints = _desolve(eq, func=func, hint=hint, simplify=True, xi=xi, eta=eta, type='ode', ics=ics, x0=x0, n=n, **kwargs) eq = hints.pop('eq', eq) all_ = hints.pop('all', False) if all_: retdict = {} failed_hints = {} gethints = classify_ode(eq, dict=True) orderedhints = gethints['ordered_hints'] for hint in hints: try: rv = _helper_simplify(eq, hint, hints[hint], simplify) except NotImplementedError as detail: failed_hints[hint] = detail else: retdict[hint] = rv func = hints[hint]['func'] retdict['best'] = min(list(retdict.values()), key=lambda x: ode_sol_simplicity(x, func, trysolving=not simplify)) if given_hint == 'best': return retdict['best'] for i in orderedhints: if retdict['best'] == retdict.get(i, None): retdict['best_hint'] = i break retdict['default'] = gethints['default'] retdict['order'] = gethints['order'] retdict.update(failed_hints) return retdict else: # The key 'hint' stores the hint needed to be solved for. hint = hints['hint'] return _helper_simplify(eq, hint, hints, simplify, ics=ics) def _helper_simplify(eq, hint, match, simplify=True, ics=None, **kwargs): r""" Helper function of dsolve that calls the respective :py:mod:`~sympy.solvers.ode` functions to solve for the ordinary differential equations. This minimizes the computation in calling :py:meth:`~sympy.solvers.deutils._desolve` multiple times. """ r = match if hint.endswith('_Integral'): solvefunc = globals()['ode_' + hint[:-len('_Integral')]] else: solvefunc = globals()['ode_' + hint] func = r['func'] order = r['order'] match = r[hint] free = eq.free_symbols cons = lambda s: s.free_symbols.difference(free) if simplify: # odesimp() will attempt to integrate, if necessary, apply constantsimp(), # attempt to solve for func, and apply any other hint specific # simplifications sols = solvefunc(eq, func, order, match) if isinstance(sols, Expr): rv = odesimp(eq, sols, func, hint) else: rv = [odesimp(eq, s, func, hint) for s in sols] else: # We still want to integrate (you can disable it separately with the hint) match['simplify'] = False # Some hints can take advantage of this option rv = _handle_Integral(solvefunc(eq, func, order, match), func, hint) if ics and not 'power_series' in hint: if isinstance(rv, Expr): solved_constants = solve_ics([rv], [r['func']], cons(rv), ics) rv = rv.subs(solved_constants) else: rv1 = [] for s in rv: try: solved_constants = solve_ics([s], [r['func']], cons(s), ics) except ValueError: continue rv1.append(s.subs(solved_constants)) if len(rv1) == 1: return rv1[0] rv = rv1 return rv def solve_ics(sols, funcs, constants, ics): """ Solve for the constants given initial conditions ``sols`` is a list of solutions. ``funcs`` is a list of functions. ``constants`` is a list of constants. ``ics`` is the set of initial/boundary conditions for the differential equation. It should be given in the form of ``{f(x0): x1, f(x).diff(x).subs(x, x2): x3}`` and so on. Returns a dictionary mapping constants to values. ``solution.subs(constants)`` will replace the constants in ``solution``. Example ======= >>> # From dsolve(f(x).diff(x) - f(x), f(x)) >>> from sympy import symbols, Eq, exp, Function >>> from sympy.solvers.ode import solve_ics >>> f = Function('f') >>> x, C1 = symbols('x C1') >>> sols = [Eq(f(x), C1*exp(x))] >>> funcs = [f(x)] >>> constants = [C1] >>> ics = {f(0): 2} >>> solved_constants = solve_ics(sols, funcs, constants, ics) >>> solved_constants {C1: 2} >>> sols[0].subs(solved_constants) Eq(f(x), 2*exp(x)) """ # Assume ics are of the form f(x0): value or Subs(diff(f(x), x, n), (x, # x0)): value (currently checked by classify_ode). To solve, replace x # with x0, f(x0) with value, then solve for constants. For f^(n)(x0), # differentiate the solution n times, so that f^(n)(x) appears. x = funcs[0].args[0] diff_sols = [] subs_sols = [] diff_variables = set() for funcarg, value in ics.items(): if isinstance(funcarg, AppliedUndef): x0 = funcarg.args[0] matching_func = [f for f in funcs if f.func == funcarg.func][0] S = sols elif isinstance(funcarg, (Subs, Derivative)): if isinstance(funcarg, Subs): # Make sure it stays a subs. Otherwise subs below will produce # a different looking term. funcarg = funcarg.doit() if isinstance(funcarg, Subs): deriv = funcarg.expr x0 = funcarg.point[0] variables = funcarg.expr.variables matching_func = deriv elif isinstance(funcarg, Derivative): deriv = funcarg x0 = funcarg.variables[0] variables = (x,)*len(funcarg.variables) matching_func = deriv.subs(x0, x) if variables not in diff_variables: for sol in sols: if sol.has(deriv.expr.func): diff_sols.append(Eq(sol.lhs.diff(*variables), sol.rhs.diff(*variables))) diff_variables.add(variables) S = diff_sols else: raise NotImplementedError("Unrecognized initial condition") for sol in S: if sol.has(matching_func): sol2 = sol sol2 = sol2.subs(x, x0) sol2 = sol2.subs(funcarg, value) # This check is necessary because of issue #15724 if not isinstance(sol2, BooleanAtom) or not subs_sols: subs_sols = [s for s in subs_sols if not isinstance(s, BooleanAtom)] subs_sols.append(sol2) # TODO: Use solveset here try: solved_constants = solve(subs_sols, constants, dict=True) except NotImplementedError: solved_constants = [] # XXX: We can't differentiate between the solution not existing because of # invalid initial conditions, and not existing because solve is not smart # enough. If we could use solveset, this might be improvable, but for now, # we use NotImplementedError in this case. if not solved_constants: raise ValueError("Couldn't solve for initial conditions") if solved_constants == True: raise ValueError("Initial conditions did not produce any solutions for constants. Perhaps they are degenerate.") if len(solved_constants) > 1: raise NotImplementedError("Initial conditions produced too many solutions for constants") return solved_constants[0] def classify_ode(eq, func=None, dict=False, ics=None, **kwargs): r""" Returns a tuple of possible :py:meth:`~sympy.solvers.ode.dsolve` classifications for an ODE. The tuple is ordered so that first item is the classification that :py:meth:`~sympy.solvers.ode.dsolve` uses to solve the ODE by default. In general, classifications at the near the beginning of the list will produce better solutions faster than those near the end, thought there are always exceptions. To make :py:meth:`~sympy.solvers.ode.dsolve` use a different classification, use ``dsolve(ODE, func, hint=<classification>)``. See also the :py:meth:`~sympy.solvers.ode.dsolve` docstring for different meta-hints you can use. If ``dict`` is true, :py:meth:`~sympy.solvers.ode.classify_ode` will return a dictionary of ``hint:match`` expression terms. This is intended for internal use by :py:meth:`~sympy.solvers.ode.dsolve`. Note that because dictionaries are ordered arbitrarily, this will most likely not be in the same order as the tuple. You can get help on different hints by executing ``help(ode.ode_hintname)``, where ``hintname`` is the name of the hint without ``_Integral``. See :py:data:`~sympy.solvers.ode.allhints` or the :py:mod:`~sympy.solvers.ode` docstring for a list of all supported hints that can be returned from :py:meth:`~sympy.solvers.ode.classify_ode`. Notes ===== These are remarks on hint names. ``_Integral`` If a classification has ``_Integral`` at the end, it will return the expression with an unevaluated :py:class:`~sympy.integrals.Integral` class in it. Note that a hint may do this anyway if :py:meth:`~sympy.core.expr.Expr.integrate` cannot do the integral, though just using an ``_Integral`` will do so much faster. Indeed, an ``_Integral`` hint will always be faster than its corresponding hint without ``_Integral`` because :py:meth:`~sympy.core.expr.Expr.integrate` is an expensive routine. If :py:meth:`~sympy.solvers.ode.dsolve` hangs, it is probably because :py:meth:`~sympy.core.expr.Expr.integrate` is hanging on a tough or impossible integral. Try using an ``_Integral`` hint or ``all_Integral`` to get it return something. Note that some hints do not have ``_Integral`` counterparts. This is because :py:meth:`~sympy.solvers.ode.integrate` is not used in solving the ODE for those method. For example, `n`\th order linear homogeneous ODEs with constant coefficients do not require integration to solve, so there is no ``nth_linear_homogeneous_constant_coeff_Integrate`` hint. You can easily evaluate any unevaluated :py:class:`~sympy.integrals.Integral`\s in an expression by doing ``expr.doit()``. Ordinals Some hints contain an ordinal such as ``1st_linear``. This is to help differentiate them from other hints, as well as from other methods that may not be implemented yet. If a hint has ``nth`` in it, such as the ``nth_linear`` hints, this means that the method used to applies to ODEs of any order. ``indep`` and ``dep`` Some hints contain the words ``indep`` or ``dep``. These reference the independent variable and the dependent function, respectively. For example, if an ODE is in terms of `f(x)`, then ``indep`` will refer to `x` and ``dep`` will refer to `f`. ``subs`` If a hints has the word ``subs`` in it, it means the the ODE is solved by substituting the expression given after the word ``subs`` for a single dummy variable. This is usually in terms of ``indep`` and ``dep`` as above. The substituted expression will be written only in characters allowed for names of Python objects, meaning operators will be spelled out. For example, ``indep``/``dep`` will be written as ``indep_div_dep``. ``coeff`` The word ``coeff`` in a hint refers to the coefficients of something in the ODE, usually of the derivative terms. See the docstring for the individual methods for more info (``help(ode)``). This is contrast to ``coefficients``, as in ``undetermined_coefficients``, which refers to the common name of a method. ``_best`` Methods that have more than one fundamental way to solve will have a hint for each sub-method and a ``_best`` meta-classification. This will evaluate all hints and return the best, using the same considerations as the normal ``best`` meta-hint. Examples ======== >>> from sympy import Function, classify_ode, Eq >>> from sympy.abc import x >>> f = Function('f') >>> classify_ode(Eq(f(x).diff(x), 0), f(x)) ('nth_algebraic', 'separable', '1st_linear', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_homogeneous', 'nth_linear_euler_eq_homogeneous', 'nth_algebraic_Integral', 'separable_Integral', '1st_linear_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral') >>> classify_ode(f(x).diff(x, 2) + 3*f(x).diff(x) + 2*f(x) - 4) ('nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', 'nth_linear_constant_coeff_variation_of_parameters_Integral') """ ics = sympify(ics) prep = kwargs.pop('prep', True) if func and len(func.args) != 1: raise ValueError("dsolve() and classify_ode() only " "work with functions of one variable, not %s" % func) if prep or func is None: eq, func_ = _preprocess(eq, func) if func is None: func = func_ x = func.args[0] f = func.func y = Dummy('y') xi = kwargs.get('xi') eta = kwargs.get('eta') terms = kwargs.get('n') if isinstance(eq, Equality): if eq.rhs != 0: return classify_ode(eq.lhs - eq.rhs, func, dict=dict, ics=ics, xi=xi, n=terms, eta=eta, prep=False) eq = eq.lhs order = ode_order(eq, f(x)) # hint:matchdict or hint:(tuple of matchdicts) # Also will contain "default":<default hint> and "order":order items. matching_hints = {"order": order} if not order: if dict: matching_hints["default"] = None return matching_hints else: return () df = f(x).diff(x) a = Wild('a', exclude=[f(x)]) b = Wild('b', exclude=[f(x)]) c = Wild('c', exclude=[f(x)]) d = Wild('d', exclude=[df, f(x).diff(x, 2)]) e = Wild('e', exclude=[df]) k = Wild('k', exclude=[df]) n = Wild('n', exclude=[x, f(x), df]) c1 = Wild('c1', exclude=[x]) a2 = Wild('a2', exclude=[x, f(x), df]) b2 = Wild('b2', exclude=[x, f(x), df]) c2 = Wild('c2', exclude=[x, f(x), df]) d2 = Wild('d2', exclude=[x, f(x), df]) a3 = Wild('a3', exclude=[f(x), df, f(x).diff(x, 2)]) b3 = Wild('b3', exclude=[f(x), df, f(x).diff(x, 2)]) c3 = Wild('c3', exclude=[f(x), df, f(x).diff(x, 2)]) r3 = {'xi': xi, 'eta': eta} # Used for the lie_group hint boundary = {} # Used to extract initial conditions C1 = Symbol("C1") eq = expand(eq) # Preprocessing to get the initial conditions out if ics is not None: for funcarg in ics: # Separating derivatives if isinstance(funcarg, (Subs, Derivative)): # f(x).diff(x).subs(x, 0) is a Subs, but f(x).diff(x).subs(x, # y) is a Derivative if isinstance(funcarg, Subs): deriv = funcarg.expr old = funcarg.variables[0] new = funcarg.point[0] elif isinstance(funcarg, Derivative): deriv = funcarg # No information on this. Just assume it was x old = x new = funcarg.variables[0] if (isinstance(deriv, Derivative) and isinstance(deriv.args[0], AppliedUndef) and deriv.args[0].func == f and len(deriv.args[0].args) == 1 and old == x and not new.has(x) and all(i == deriv.variables[0] for i in deriv.variables) and not ics[funcarg].has(f)): dorder = ode_order(deriv, x) temp = 'f' + str(dorder) boundary.update({temp: new, temp + 'val': ics[funcarg]}) else: raise ValueError("Enter valid boundary conditions for Derivatives") # Separating functions elif isinstance(funcarg, AppliedUndef): if (funcarg.func == f and len(funcarg.args) == 1 and not funcarg.args[0].has(x) and not ics[funcarg].has(f)): boundary.update({'f0': funcarg.args[0], 'f0val': ics[funcarg]}) else: raise ValueError("Enter valid boundary conditions for Function") else: raise ValueError("Enter boundary conditions of the form ics={f(point}: value, f(x).diff(x, order).subs(x, point): value}") # Precondition to try remove f(x) from highest order derivative reduced_eq = None if eq.is_Add: deriv_coef = eq.coeff(f(x).diff(x, order)) if deriv_coef not in (1, 0): r = deriv_coef.match(a*f(x)**c1) if r and r[c1]: den = f(x)**r[c1] reduced_eq = Add(*[arg/den for arg in eq.args]) if not reduced_eq: reduced_eq = eq if order == 1: ## Linear case: a(x)*y'+b(x)*y+c(x) == 0 if eq.is_Add: ind, dep = reduced_eq.as_independent(f) else: u = Dummy('u') ind, dep = (reduced_eq + u).as_independent(f) ind, dep = [tmp.subs(u, 0) for tmp in [ind, dep]] r = {a: dep.coeff(df), b: dep.coeff(f(x)), c: ind} # double check f[a] since the preconditioning may have failed if not r[a].has(f) and not r[b].has(f) and ( r[a]*df + r[b]*f(x) + r[c]).expand() - reduced_eq == 0: r['a'] = a r['b'] = b r['c'] = c matching_hints["1st_linear"] = r matching_hints["1st_linear_Integral"] = r ## Bernoulli case: a(x)*y'+b(x)*y+c(x)*y**n == 0 r = collect( reduced_eq, f(x), exact=True).match(a*df + b*f(x) + c*f(x)**n) if r and r[c] != 0 and r[n] != 1: # See issue 4676 r['a'] = a r['b'] = b r['c'] = c r['n'] = n matching_hints["Bernoulli"] = r matching_hints["Bernoulli_Integral"] = r ## Riccati special n == -2 case: a2*y'+b2*y**2+c2*y/x+d2/x**2 == 0 r = collect(reduced_eq, f(x), exact=True).match(a2*df + b2*f(x)**2 + c2*f(x)/x + d2/x**2) if r and r[b2] != 0 and (r[c2] != 0 or r[d2] != 0): r['a2'] = a2 r['b2'] = b2 r['c2'] = c2 r['d2'] = d2 matching_hints["Riccati_special_minus2"] = r # NON-REDUCED FORM OF EQUATION matches r = collect(eq, df, exact=True).match(d + e * df) if r: r['d'] = d r['e'] = e r['y'] = y r[d] = r[d].subs(f(x), y) r[e] = r[e].subs(f(x), y) # FIRST ORDER POWER SERIES WHICH NEEDS INITIAL CONDITIONS # TODO: Hint first order series should match only if d/e is analytic. # For now, only d/e and (d/e).diff(arg) is checked for existence at # at a given point. # This is currently done internally in ode_1st_power_series. point = boundary.get('f0', 0) value = boundary.get('f0val', C1) check = cancel(r[d]/r[e]) check1 = check.subs({x: point, y: value}) if not check1.has(oo) and not check1.has(zoo) and \ not check1.has(NaN) and not check1.has(-oo): check2 = (check1.diff(x)).subs({x: point, y: value}) if not check2.has(oo) and not check2.has(zoo) and \ not check2.has(NaN) and not check2.has(-oo): rseries = r.copy() rseries.update({'terms': terms, 'f0': point, 'f0val': value}) matching_hints["1st_power_series"] = rseries r3.update(r) ## Exact Differential Equation: P(x, y) + Q(x, y)*y' = 0 where # dP/dy == dQ/dx try: if r[d] != 0: numerator = simplify(r[d].diff(y) - r[e].diff(x)) # The following few conditions try to convert a non-exact # differential equation into an exact one. # References : Differential equations with applications # and historical notes - George E. Simmons if numerator: # If (dP/dy - dQ/dx) / Q = f(x) # then exp(integral(f(x))*equation becomes exact factor = simplify(numerator/r[e]) variables = factor.free_symbols if len(variables) == 1 and x == variables.pop(): factor = exp(Integral(factor).doit()) r[d] *= factor r[e] *= factor matching_hints["1st_exact"] = r matching_hints["1st_exact_Integral"] = r else: # If (dP/dy - dQ/dx) / -P = f(y) # then exp(integral(f(y))*equation becomes exact factor = simplify(-numerator/r[d]) variables = factor.free_symbols if len(variables) == 1 and y == variables.pop(): factor = exp(Integral(factor).doit()) r[d] *= factor r[e] *= factor matching_hints["1st_exact"] = r matching_hints["1st_exact_Integral"] = r else: matching_hints["1st_exact"] = r matching_hints["1st_exact_Integral"] = r except NotImplementedError: # Differentiating the coefficients might fail because of things # like f(2*x).diff(x). See issue 4624 and issue 4719. pass # Any first order ODE can be ideally solved by the Lie Group # method matching_hints["lie_group"] = r3 # This match is used for several cases below; we now collect on # f(x) so the matching works. r = collect(reduced_eq, df, exact=True).match(d + e*df) if r: # Using r[d] and r[e] without any modification for hints # linear-coefficients and separable-reduced. num, den = r[d], r[e] # ODE = d/e + df r['d'] = d r['e'] = e r['y'] = y r[d] = num.subs(f(x), y) r[e] = den.subs(f(x), y) ## Separable Case: y' == P(y)*Q(x) r[d] = separatevars(r[d]) r[e] = separatevars(r[e]) # m1[coeff]*m1[x]*m1[y] + m2[coeff]*m2[x]*m2[y]*y' m1 = separatevars(r[d], dict=True, symbols=(x, y)) m2 = separatevars(r[e], dict=True, symbols=(x, y)) if m1 and m2: r1 = {'m1': m1, 'm2': m2, 'y': y} matching_hints["separable"] = r1 matching_hints["separable_Integral"] = r1 ## First order equation with homogeneous coefficients: # dy/dx == F(y/x) or dy/dx == F(x/y) ordera = homogeneous_order(r[d], x, y) if ordera is not None: orderb = homogeneous_order(r[e], x, y) if ordera == orderb: # u1=y/x and u2=x/y u1 = Dummy('u1') u2 = Dummy('u2') s = "1st_homogeneous_coeff_subs" s1 = s + "_dep_div_indep" s2 = s + "_indep_div_dep" if simplify((r[d] + u1*r[e]).subs({x: 1, y: u1})) != 0: matching_hints[s1] = r matching_hints[s1 + "_Integral"] = r if simplify((r[e] + u2*r[d]).subs({x: u2, y: 1})) != 0: matching_hints[s2] = r matching_hints[s2 + "_Integral"] = r if s1 in matching_hints and s2 in matching_hints: matching_hints["1st_homogeneous_coeff_best"] = r ## Linear coefficients of the form # y'+ F((a*x + b*y + c)/(a'*x + b'y + c')) = 0 # that can be reduced to homogeneous form. F = num/den params = _linear_coeff_match(F, func) if params: xarg, yarg = params u = Dummy('u') t = Dummy('t') # Dummy substitution for df and f(x). dummy_eq = reduced_eq.subs(((df, t), (f(x), u))) reps = ((x, x + xarg), (u, u + yarg), (t, df), (u, f(x))) dummy_eq = simplify(dummy_eq.subs(reps)) # get the re-cast values for e and d r2 = collect(expand(dummy_eq), [df, f(x)]).match(e*df + d) if r2: orderd = homogeneous_order(r2[d], x, f(x)) if orderd is not None: ordere = homogeneous_order(r2[e], x, f(x)) if orderd == ordere: # Match arguments are passed in such a way that it # is coherent with the already existing homogeneous # functions. r2[d] = r2[d].subs(f(x), y) r2[e] = r2[e].subs(f(x), y) r2.update({'xarg': xarg, 'yarg': yarg, 'd': d, 'e': e, 'y': y}) matching_hints["linear_coefficients"] = r2 matching_hints["linear_coefficients_Integral"] = r2 ## Equation of the form y' + (y/x)*H(x^n*y) = 0 # that can be reduced to separable form factor = simplify(x/f(x)*num/den) # Try representing factor in terms of x^n*y # where n is lowest power of x in factor; # first remove terms like sqrt(2)*3 from factor.atoms(Mul) u = None for mul in ordered(factor.atoms(Mul)): if mul.has(x): _, u = mul.as_independent(x, f(x)) break if u and u.has(f(x)): h = x**(degree(Poly(u.subs(f(x), y), gen=x)))*f(x) p = Wild('p') if (u/h == 1) or ((u/h).simplify().match(x**p)): t = Dummy('t') r2 = {'t': t} xpart, ypart = u.as_independent(f(x)) test = factor.subs(((u, t), (1/u, 1/t))) free = test.free_symbols if len(free) == 1 and free.pop() == t: r2.update({'power': xpart.as_base_exp()[1], 'u': test}) matching_hints["separable_reduced"] = r2 matching_hints["separable_reduced_Integral"] = r2 ## Almost-linear equation of the form f(x)*g(y)*y' + k(x)*l(y) + m(x) = 0 r = collect(eq, [df, f(x)]).match(e*df + d) if r: r2 = r.copy() r2[c] = S.Zero if r2[d].is_Add: # Separate the terms having f(x) to r[d] and # remaining to r[c] no_f, r2[d] = r2[d].as_independent(f(x)) r2[c] += no_f factor = simplify(r2[d].diff(f(x))/r[e]) if factor and not factor.has(f(x)): r2[d] = factor_terms(r2[d]) u = r2[d].as_independent(f(x), as_Add=False)[1] r2.update({'a': e, 'b': d, 'c': c, 'u': u}) r2[d] /= u r2[e] /= u.diff(f(x)) matching_hints["almost_linear"] = r2 matching_hints["almost_linear_Integral"] = r2 elif order == 2: # Liouville ODE in the form # f(x).diff(x, 2) + g(f(x))*(f(x).diff(x))**2 + h(x)*f(x).diff(x) # See Goldstein and Braun, "Advanced Methods for the Solution of # Differential Equations", pg. 98 s = d*f(x).diff(x, 2) + e*df**2 + k*df r = reduced_eq.match(s) if r and r[d] != 0: y = Dummy('y') g = simplify(r[e]/r[d]).subs(f(x), y) h = simplify(r[k]/r[d]).subs(f(x), y) if y in h.free_symbols or x in g.free_symbols: pass else: r = {'g': g, 'h': h, 'y': y} matching_hints["Liouville"] = r matching_hints["Liouville_Integral"] = r # Homogeneous second order differential equation of the form # a3*f(x).diff(x, 2) + b3*f(x).diff(x) + c3, where # for simplicity, a3, b3 and c3 are assumed to be polynomials. # It has a definite power series solution at point x0 if, b3/a3 and c3/a3 # are analytic at x0. deq = a3*(f(x).diff(x, 2)) + b3*df + c3*f(x) r = collect(reduced_eq, [f(x).diff(x, 2), f(x).diff(x), f(x)]).match(deq) ordinary = False if r and r[a3] != 0: if all([r[key].is_polynomial() for key in r]): p = cancel(r[b3]/r[a3]) # Used below q = cancel(r[c3]/r[a3]) # Used below point = kwargs.get('x0', 0) check = p.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): check = q.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): ordinary = True r.update({'a3': a3, 'b3': b3, 'c3': c3, 'x0': point, 'terms': terms}) matching_hints["2nd_power_series_ordinary"] = r # Checking if the differential equation has a regular singular point # at x0. It has a regular singular point at x0, if (b3/a3)*(x - x0) # and (c3/a3)*((x - x0)**2) are analytic at x0. if not ordinary: p = cancel((x - point)*p) check = p.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): q = cancel(((x - point)**2)*q) check = q.subs(x, point) if not check.has(oo) and not check.has(NaN) and \ not check.has(zoo) and not check.has(-oo): coeff_dict = {'p': p, 'q': q, 'x0': point, 'terms': terms} matching_hints["2nd_power_series_regular"] = coeff_dict if order > 0: # Any ODE that can be solved with a substitution and # repeated integration e.g.: # `d^2/dx^2(y) + x*d/dx(y) = constant #f'(x) must be finite for this to work r = _nth_order_reducible_match(reduced_eq, func) if r: matching_hints['nth_order_reducible'] = r # Any ODE that can be solved with a combination of algebra and # integrals e.g.: # d^3/dx^3(x y) = F(x) r = _nth_algebraic_match(reduced_eq, func) if r['solutions']: matching_hints['nth_algebraic'] = r matching_hints['nth_algebraic_Integral'] = r # nth order linear ODE # a_n(x)y^(n) + ... + a_1(x)y' + a_0(x)y = F(x) = b r = _nth_linear_match(reduced_eq, func, order) # Constant coefficient case (a_i is constant for all i) if r and not any(r[i].has(x) for i in r if i >= 0): # Inhomogeneous case: F(x) is not identically 0 if r[-1]: undetcoeff = _undetermined_coefficients_match(r[-1], x) s = "nth_linear_constant_coeff_variation_of_parameters" matching_hints[s] = r matching_hints[s + "_Integral"] = r if undetcoeff['test']: r['trialset'] = undetcoeff['trialset'] matching_hints[ "nth_linear_constant_coeff_undetermined_coefficients" ] = r # Homogeneous case: F(x) is identically 0 else: matching_hints["nth_linear_constant_coeff_homogeneous"] = r # nth order Euler equation a_n*x**n*y^(n) + ... + a_1*x*y' + a_0*y = F(x) #In case of Homogeneous euler equation F(x) = 0 def _test_term(coeff, order): r""" Linear Euler ODEs have the form K*x**order*diff(y(x),x,order) = F(x), where K is independent of x and y(x), order>= 0. So we need to check that for each term, coeff == K*x**order from some K. We have a few cases, since coeff may have several different types. """ if order < 0: raise ValueError("order should be greater than 0") if coeff == 0: return True if order == 0: if x in coeff.free_symbols: return False return True if coeff.is_Mul: if coeff.has(f(x)): return False return x**order in coeff.args elif coeff.is_Pow: return coeff.as_base_exp() == (x, order) elif order == 1: return x == coeff return False # Find coefficient for higest derivative, multiply coefficients to # bring the equation into Euler form if possible r_rescaled = None if r is not None: coeff = r[order] factor = x**order / coeff r_rescaled = {i: factor*r[i] for i in r} if r_rescaled and not any(not _test_term(r_rescaled[i], i) for i in r_rescaled if i != 'trialset' and i >= 0): if not r_rescaled[-1]: matching_hints["nth_linear_euler_eq_homogeneous"] = r_rescaled else: matching_hints["nth_linear_euler_eq_nonhomogeneous_variation_of_parameters"] = r_rescaled matching_hints["nth_linear_euler_eq_nonhomogeneous_variation_of_parameters_Integral"] = r_rescaled e, re = posify(r_rescaled[-1].subs(x, exp(x))) undetcoeff = _undetermined_coefficients_match(e.subs(re), x) if undetcoeff['test']: r_rescaled['trialset'] = undetcoeff['trialset'] matching_hints["nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients"] = r_rescaled # Order keys based on allhints. retlist = [i for i in allhints if i in matching_hints] if dict: # Dictionaries are ordered arbitrarily, so make note of which # hint would come first for dsolve(). Use an ordered dict in Py 3. matching_hints["default"] = retlist[0] if retlist else None matching_hints["ordered_hints"] = tuple(retlist) return matching_hints else: return tuple(retlist) def classify_sysode(eq, funcs=None, **kwargs): r""" Returns a dictionary of parameter names and values that define the system of ordinary differential equations in ``eq``. The parameters are further used in :py:meth:`~sympy.solvers.ode.dsolve` for solving that system. The parameter names and values are: 'is_linear' (boolean), which tells whether the given system is linear. Note that "linear" here refers to the operator: terms such as ``x*diff(x,t)`` are nonlinear, whereas terms like ``sin(t)*diff(x,t)`` are still linear operators. 'func' (list) contains the :py:class:`~sympy.core.function.Function`s that appear with a derivative in the ODE, i.e. those that we are trying to solve the ODE for. 'order' (dict) with the maximum derivative for each element of the 'func' parameter. 'func_coeff' (dict) with the coefficient for each triple ``(equation number, function, order)```. The coefficients are those subexpressions that do not appear in 'func', and hence can be considered constant for purposes of ODE solving. 'eq' (list) with the equations from ``eq``, sympified and transformed into expressions (we are solving for these expressions to be zero). 'no_of_equations' (int) is the number of equations (same as ``len(eq)``). 'type_of_equation' (string) is an internal classification of the type of ODE. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode-toc1.htm -A. D. Polyanin and A. V. Manzhirov, Handbook of Mathematics for Engineers and Scientists Examples ======== >>> from sympy import Function, Eq, symbols, diff >>> from sympy.solvers.ode import classify_sysode >>> from sympy.abc import t >>> f, x, y = symbols('f, x, y', cls=Function) >>> k, l, m, n = symbols('k, l, m, n', Integer=True) >>> x1 = diff(x(t), t) ; y1 = diff(y(t), t) >>> x2 = diff(x(t), t, t) ; y2 = diff(y(t), t, t) >>> eq = (Eq(5*x1, 12*x(t) - 6*y(t)), Eq(2*y1, 11*x(t) + 3*y(t))) >>> classify_sysode(eq) {'eq': [-12*x(t) + 6*y(t) + 5*Derivative(x(t), t), -11*x(t) - 3*y(t) + 2*Derivative(y(t), t)], 'func': [x(t), y(t)], 'func_coeff': {(0, x(t), 0): -12, (0, x(t), 1): 5, (0, y(t), 0): 6, (0, y(t), 1): 0, (1, x(t), 0): -11, (1, x(t), 1): 0, (1, y(t), 0): -3, (1, y(t), 1): 2}, 'is_linear': True, 'no_of_equation': 2, 'order': {x(t): 1, y(t): 1}, 'type_of_equation': 'type1'} >>> eq = (Eq(diff(x(t),t), 5*t*x(t) + t**2*y(t)), Eq(diff(y(t),t), -t**2*x(t) + 5*t*y(t))) >>> classify_sysode(eq) {'eq': [-t**2*y(t) - 5*t*x(t) + Derivative(x(t), t), t**2*x(t) - 5*t*y(t) + Derivative(y(t), t)], 'func': [x(t), y(t)], 'func_coeff': {(0, x(t), 0): -5*t, (0, x(t), 1): 1, (0, y(t), 0): -t**2, (0, y(t), 1): 0, (1, x(t), 0): t**2, (1, x(t), 1): 0, (1, y(t), 0): -5*t, (1, y(t), 1): 1}, 'is_linear': True, 'no_of_equation': 2, 'order': {x(t): 1, y(t): 1}, 'type_of_equation': 'type4'} """ # Sympify equations and convert iterables of equations into # a list of equations def _sympify(eq): return list(map(sympify, eq if iterable(eq) else [eq])) eq, funcs = (_sympify(w) for w in [eq, funcs]) for i, fi in enumerate(eq): if isinstance(fi, Equality): eq[i] = fi.lhs - fi.rhs matching_hints = {"no_of_equation":i+1} matching_hints['eq'] = eq if i==0: raise ValueError("classify_sysode() works for systems of ODEs. " "For scalar ODEs, classify_ode should be used") t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] # find all the functions if not given order = dict() if funcs==[None]: funcs = [] for eqs in eq: derivs = eqs.atoms(Derivative) func = set().union(*[d.atoms(AppliedUndef) for d in derivs]) for func_ in func: funcs.append(func_) funcs = list(set(funcs)) if len(funcs) != len(eq): raise ValueError("Number of functions given is not equal to the number of equations %s" % funcs) func_dict = dict() for func in funcs: if not order.get(func, False): max_order = 0 for i, eqs_ in enumerate(eq): order_ = ode_order(eqs_,func) if max_order < order_: max_order = order_ eq_no = i if eq_no in func_dict: list_func = [] list_func.append(func_dict[eq_no]) list_func.append(func) func_dict[eq_no] = list_func else: func_dict[eq_no] = func order[func] = max_order funcs = [func_dict[i] for i in range(len(func_dict))] matching_hints['func'] = funcs for func in funcs: if isinstance(func, list): for func_elem in func: if len(func_elem.args) != 1: raise ValueError("dsolve() and classify_sysode() work with " "functions of one variable only, not %s" % func) else: if func and len(func.args) != 1: raise ValueError("dsolve() and classify_sysode() work with " "functions of one variable only, not %s" % func) # find the order of all equation in system of odes matching_hints["order"] = order # find coefficients of terms f(t), diff(f(t),t) and higher derivatives # and similarly for other functions g(t), diff(g(t),t) in all equations. # Here j denotes the equation number, funcs[l] denotes the function about # which we are talking about and k denotes the order of function funcs[l] # whose coefficient we are calculating. def linearity_check(eqs, j, func, is_linear_): for k in range(order[func] + 1): func_coef[j, func, k] = collect(eqs.expand(), [diff(func, t, k)]).coeff(diff(func, t, k)) if is_linear_ == True: if func_coef[j, func, k] == 0: if k == 0: coef = eqs.as_independent(func, as_Add=True)[1] for xr in range(1, ode_order(eqs,func) + 1): coef -= eqs.as_independent(diff(func, t, xr), as_Add=True)[1] if coef != 0: is_linear_ = False else: if eqs.as_independent(diff(func, t, k), as_Add=True)[1]: is_linear_ = False else: for func_ in funcs: if isinstance(func_, list): for elem_func_ in func_: dep = func_coef[j, func, k].as_independent(elem_func_, as_Add=True)[1] if dep != 0: is_linear_ = False else: dep = func_coef[j, func, k].as_independent(func_, as_Add=True)[1] if dep != 0: is_linear_ = False return is_linear_ func_coef = {} is_linear = True for j, eqs in enumerate(eq): for func in funcs: if isinstance(func, list): for func_elem in func: is_linear = linearity_check(eqs, j, func_elem, is_linear) else: is_linear = linearity_check(eqs, j, func, is_linear) matching_hints['func_coeff'] = func_coef matching_hints['is_linear'] = is_linear if len(set(order.values())) == 1: order_eq = list(matching_hints['order'].values())[0] if matching_hints['is_linear'] == True: if matching_hints['no_of_equation'] == 2: if order_eq == 1: type_of_equation = check_linear_2eq_order1(eq, funcs, func_coef) elif order_eq == 2: type_of_equation = check_linear_2eq_order2(eq, funcs, func_coef) else: type_of_equation = None elif matching_hints['no_of_equation'] == 3: if order_eq == 1: type_of_equation = check_linear_3eq_order1(eq, funcs, func_coef) if type_of_equation is None: type_of_equation = check_linear_neq_order1(eq, funcs, func_coef) else: type_of_equation = None else: if order_eq == 1: type_of_equation = check_linear_neq_order1(eq, funcs, func_coef) else: type_of_equation = None else: if matching_hints['no_of_equation'] == 2: if order_eq == 1: type_of_equation = check_nonlinear_2eq_order1(eq, funcs, func_coef) else: type_of_equation = None elif matching_hints['no_of_equation'] == 3: if order_eq == 1: type_of_equation = check_nonlinear_3eq_order1(eq, funcs, func_coef) else: type_of_equation = None else: type_of_equation = None else: type_of_equation = None matching_hints['type_of_equation'] = type_of_equation return matching_hints def check_linear_2eq_order1(eq, func, func_coef): x = func[0].func y = func[1].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] r = dict() # for equations Eq(a1*diff(x(t),t), b1*x(t) + c1*y(t) + d1) # and Eq(a2*diff(y(t),t), b2*x(t) + c2*y(t) + d2) r['a1'] = fc[0,x(t),1] ; r['a2'] = fc[1,y(t),1] r['b1'] = -fc[0,x(t),0]/fc[0,x(t),1] ; r['b2'] = -fc[1,x(t),0]/fc[1,y(t),1] r['c1'] = -fc[0,y(t),0]/fc[0,x(t),1] ; r['c2'] = -fc[1,y(t),0]/fc[1,y(t),1] forcing = [S(0),S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t)): forcing[i] += j if not (forcing[0].has(t) or forcing[1].has(t)): # We can handle homogeneous case and simple constant forcings r['d1'] = forcing[0] r['d2'] = forcing[1] else: # Issue #9244: nonhomogeneous linear systems are not supported return None # Conditions to check for type 6 whose equations are Eq(diff(x(t),t), f(t)*x(t) + g(t)*y(t)) and # Eq(diff(y(t),t), a*[f(t) + a*h(t)]x(t) + a*[g(t) - h(t)]*y(t)) p = 0 q = 0 p1 = cancel(r['b2']/(cancel(r['b2']/r['c2']).as_numer_denom()[0])) p2 = cancel(r['b1']/(cancel(r['b1']/r['c1']).as_numer_denom()[0])) for n, i in enumerate([p1, p2]): for j in Mul.make_args(collect_const(i)): if not j.has(t): q = j if q and n==0: if ((r['b2']/j - r['b1'])/(r['c1'] - r['c2']/j)) == j: p = 1 elif q and n==1: if ((r['b1']/j - r['b2'])/(r['c2'] - r['c1']/j)) == j: p = 2 # End of condition for type 6 if r['d1']!=0 or r['d2']!=0: if not r['d1'].has(t) and not r['d2'].has(t): if all(not r[k].has(t) for k in 'a1 a2 b1 b2 c1 c2'.split()): # Equations for type 2 are Eq(a1*diff(x(t),t),b1*x(t)+c1*y(t)+d1) and Eq(a2*diff(y(t),t),b2*x(t)+c2*y(t)+d2) return "type2" else: return None else: if all(not r[k].has(t) for k in 'a1 a2 b1 b2 c1 c2'.split()): # Equations for type 1 are Eq(a1*diff(x(t),t),b1*x(t)+c1*y(t)) and Eq(a2*diff(y(t),t),b2*x(t)+c2*y(t)) return "type1" else: r['b1'] = r['b1']/r['a1'] ; r['b2'] = r['b2']/r['a2'] r['c1'] = r['c1']/r['a1'] ; r['c2'] = r['c2']/r['a2'] if (r['b1'] == r['c2']) and (r['c1'] == r['b2']): # Equation for type 3 are Eq(diff(x(t),t), f(t)*x(t) + g(t)*y(t)) and Eq(diff(y(t),t), g(t)*x(t) + f(t)*y(t)) return "type3" elif (r['b1'] == r['c2']) and (r['c1'] == -r['b2']) or (r['b1'] == -r['c2']) and (r['c1'] == r['b2']): # Equation for type 4 are Eq(diff(x(t),t), f(t)*x(t) + g(t)*y(t)) and Eq(diff(y(t),t), -g(t)*x(t) + f(t)*y(t)) return "type4" elif (not cancel(r['b2']/r['c1']).has(t) and not cancel((r['c2']-r['b1'])/r['c1']).has(t)) \ or (not cancel(r['b1']/r['c2']).has(t) and not cancel((r['c1']-r['b2'])/r['c2']).has(t)): # Equations for type 5 are Eq(diff(x(t),t), f(t)*x(t) + g(t)*y(t)) and Eq(diff(y(t),t), a*g(t)*x(t) + [f(t) + b*g(t)]*y(t) return "type5" elif p: return "type6" else: # Equations for type 7 are Eq(diff(x(t),t), f(t)*x(t) + g(t)*y(t)) and Eq(diff(y(t),t), h(t)*x(t) + p(t)*y(t)) return "type7" def check_linear_2eq_order2(eq, func, func_coef): x = func[0].func y = func[1].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] r = dict() a = Wild('a', exclude=[1/t]) b = Wild('b', exclude=[1/t**2]) u = Wild('u', exclude=[t, t**2]) v = Wild('v', exclude=[t, t**2]) w = Wild('w', exclude=[t, t**2]) p = Wild('p', exclude=[t, t**2]) r['a1'] = fc[0,x(t),2] ; r['a2'] = fc[1,y(t),2] r['b1'] = fc[0,x(t),1] ; r['b2'] = fc[1,x(t),1] r['c1'] = fc[0,y(t),1] ; r['c2'] = fc[1,y(t),1] r['d1'] = fc[0,x(t),0] ; r['d2'] = fc[1,x(t),0] r['e1'] = fc[0,y(t),0] ; r['e2'] = fc[1,y(t),0] const = [S(0), S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not (j.has(x(t)) or j.has(y(t))): const[i] += j r['f1'] = const[0] r['f2'] = const[1] if r['f1']!=0 or r['f2']!=0: if all(not r[k].has(t) for k in 'a1 a2 d1 d2 e1 e2 f1 f2'.split()) \ and r['b1']==r['c1']==r['b2']==r['c2']==0: return "type2" elif all(not r[k].has(t) for k in 'a1 a2 b1 b2 c1 c2 d1 d2 e1 e1'.split()): p = [S(0), S(0)] ; q = [S(0), S(0)] for n, e in enumerate([r['f1'], r['f2']]): if e.has(t): tpart = e.as_independent(t, Mul)[1] for i in Mul.make_args(tpart): if i.has(exp): b, e = i.as_base_exp() co = e.coeff(t) if co and not co.has(t) and co.has(I): p[n] = 1 else: q[n] = 1 else: q[n] = 1 else: q[n] = 1 if p[0]==1 and p[1]==1 and q[0]==0 and q[1]==0: return "type4" else: return None else: return None else: if r['b1']==r['b2']==r['c1']==r['c2']==0 and all(not r[k].has(t) \ for k in 'a1 a2 d1 d2 e1 e2'.split()): return "type1" elif r['b1']==r['e1']==r['c2']==r['d2']==0 and all(not r[k].has(t) \ for k in 'a1 a2 b2 c1 d1 e2'.split()) and r['c1'] == -r['b2'] and \ r['d1'] == r['e2']: return "type3" elif cancel(-r['b2']/r['d2'])==t and cancel(-r['c1']/r['e1'])==t and not \ (r['d2']/r['a2']).has(t) and not (r['e1']/r['a1']).has(t) and \ r['b1']==r['d1']==r['c2']==r['e2']==0: return "type5" elif ((r['a1']/r['d1']).expand()).match((p*(u*t**2+v*t+w)**2).expand()) and not \ (cancel(r['a1']*r['d2']/(r['a2']*r['d1']))).has(t) and not (r['d1']/r['e1']).has(t) and not \ (r['d2']/r['e2']).has(t) and r['b1'] == r['b2'] == r['c1'] == r['c2'] == 0: return "type10" elif not cancel(r['d1']/r['e1']).has(t) and not cancel(r['d2']/r['e2']).has(t) and not \ cancel(r['d1']*r['a2']/(r['d2']*r['a1'])).has(t) and r['b1']==r['b2']==r['c1']==r['c2']==0: return "type6" elif not cancel(r['b1']/r['c1']).has(t) and not cancel(r['b2']/r['c2']).has(t) and not \ cancel(r['b1']*r['a2']/(r['b2']*r['a1'])).has(t) and r['d1']==r['d2']==r['e1']==r['e2']==0: return "type7" elif cancel(-r['b2']/r['d2'])==t and cancel(-r['c1']/r['e1'])==t and not \ cancel(r['e1']*r['a2']/(r['d2']*r['a1'])).has(t) and r['e1'].has(t) \ and r['b1']==r['d1']==r['c2']==r['e2']==0: return "type8" elif (r['b1']/r['a1']).match(a/t) and (r['b2']/r['a2']).match(a/t) and not \ (r['b1']/r['c1']).has(t) and not (r['b2']/r['c2']).has(t) and \ (r['d1']/r['a1']).match(b/t**2) and (r['d2']/r['a2']).match(b/t**2) \ and not (r['d1']/r['e1']).has(t) and not (r['d2']/r['e2']).has(t): return "type9" elif -r['b1']/r['d1']==-r['c1']/r['e1']==-r['b2']/r['d2']==-r['c2']/r['e2']==t: return "type11" else: return None def check_linear_3eq_order1(eq, func, func_coef): x = func[0].func y = func[1].func z = func[2].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] r = dict() r['a1'] = fc[0,x(t),1]; r['a2'] = fc[1,y(t),1]; r['a3'] = fc[2,z(t),1] r['b1'] = fc[0,x(t),0]; r['b2'] = fc[1,x(t),0]; r['b3'] = fc[2,x(t),0] r['c1'] = fc[0,y(t),0]; r['c2'] = fc[1,y(t),0]; r['c3'] = fc[2,y(t),0] r['d1'] = fc[0,z(t),0]; r['d2'] = fc[1,z(t),0]; r['d3'] = fc[2,z(t),0] forcing = [S(0), S(0), S(0)] for i in range(3): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t), z(t)): forcing[i] += j if forcing[0].has(t) or forcing[1].has(t) or forcing[2].has(t): # We can handle homogeneous case and simple constant forcings. # Issue #9244: nonhomogeneous linear systems are not supported return None if all(not r[k].has(t) for k in 'a1 a2 a3 b1 b2 b3 c1 c2 c3 d1 d2 d3'.split()): if r['c1']==r['d1']==r['d2']==0: return 'type1' elif r['c1'] == -r['b2'] and r['d1'] == -r['b3'] and r['d2'] == -r['c3'] \ and r['b1'] == r['c2'] == r['d3'] == 0: return 'type2' elif r['b1'] == r['c2'] == r['d3'] == 0 and r['c1']/r['a1'] == -r['d1']/r['a1'] \ and r['d2']/r['a2'] == -r['b2']/r['a2'] and r['b3']/r['a3'] == -r['c3']/r['a3']: return 'type3' else: return None else: for k1 in 'c1 d1 b2 d2 b3 c3'.split(): if r[k1] == 0: continue else: if all(not cancel(r[k1]/r[k]).has(t) for k in 'd1 b2 d2 b3 c3'.split() if r[k]!=0) \ and all(not cancel(r[k1]/(r['b1'] - r[k])).has(t) for k in 'b1 c2 d3'.split() if r['b1']!=r[k]): return 'type4' else: break return None def check_linear_neq_order1(eq, func, func_coef): fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] n = len(eq) for i in range(n): for j in range(n): if (fc[i, func[j], 0]/fc[i, func[i], 1]).has(t): return None if len(eq) == 3: return 'type6' return 'type1' def check_nonlinear_2eq_order1(eq, func, func_coef): t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] f = Wild('f') g = Wild('g') u, v = symbols('u, v', cls=Dummy) def check_type(x, y): r1 = eq[0].match(t*diff(x(t),t) - x(t) + f) r2 = eq[1].match(t*diff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = eq[0].match(diff(x(t),t) - x(t)/t + f/t) r2 = eq[1].match(diff(y(t),t) - y(t)/t + g/t) if not (r1 and r2): r1 = (-eq[0]).match(t*diff(x(t),t) - x(t) + f) r2 = (-eq[1]).match(t*diff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = (-eq[0]).match(diff(x(t),t) - x(t)/t + f/t) r2 = (-eq[1]).match(diff(y(t),t) - y(t)/t + g/t) if r1 and r2 and not (r1[f].subs(diff(x(t),t),u).subs(diff(y(t),t),v).has(t) \ or r2[g].subs(diff(x(t),t),u).subs(diff(y(t),t),v).has(t)): return 'type5' else: return None for func_ in func: if isinstance(func_, list): x = func[0][0].func y = func[0][1].func eq_type = check_type(x, y) if not eq_type: eq_type = check_type(y, x) return eq_type x = func[0].func y = func[1].func fc = func_coef n = Wild('n', exclude=[x(t),y(t)]) f1 = Wild('f1', exclude=[v,t]) f2 = Wild('f2', exclude=[v,t]) g1 = Wild('g1', exclude=[u,t]) g2 = Wild('g2', exclude=[u,t]) for i in range(2): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs r = eq[0].match(diff(x(t),t) - x(t)**n*f) if r: g = (diff(y(t),t) - eq[1])/r[f] if r and not (g.has(x(t)) or g.subs(y(t),v).has(t) or r[f].subs(x(t),u).subs(y(t),v).has(t)): return 'type1' r = eq[0].match(diff(x(t),t) - exp(n*x(t))*f) if r: g = (diff(y(t),t) - eq[1])/r[f] if r and not (g.has(x(t)) or g.subs(y(t),v).has(t) or r[f].subs(x(t),u).subs(y(t),v).has(t)): return 'type2' g = Wild('g') r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) if r1 and r2 and not (r1[f].subs(x(t),u).subs(y(t),v).has(t) or \ r2[g].subs(x(t),u).subs(y(t),v).has(t)): return 'type3' r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) num, den = ( (r1[f].subs(x(t),u).subs(y(t),v))/ (r2[g].subs(x(t),u).subs(y(t),v))).as_numer_denom() R1 = num.match(f1*g1) R2 = den.match(f2*g2) # phi = (r1[f].subs(x(t),u).subs(y(t),v))/num if R1 and R2: return 'type4' return None def check_nonlinear_2eq_order2(eq, func, func_coef): return None def check_nonlinear_3eq_order1(eq, func, func_coef): x = func[0].func y = func[1].func z = func[2].func fc = func_coef t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] u, v, w = symbols('u, v, w', cls=Dummy) a = Wild('a', exclude=[x(t), y(t), z(t), t]) b = Wild('b', exclude=[x(t), y(t), z(t), t]) c = Wild('c', exclude=[x(t), y(t), z(t), t]) f = Wild('f') F1 = Wild('F1') F2 = Wild('F2') F3 = Wild('F3') for i in range(3): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs r1 = eq[0].match(diff(x(t),t) - a*y(t)*z(t)) r2 = eq[1].match(diff(y(t),t) - b*z(t)*x(t)) r3 = eq[2].match(diff(z(t),t) - c*x(t)*y(t)) if r1 and r2 and r3: num1, den1 = r1[a].as_numer_denom() num2, den2 = r2[b].as_numer_denom() num3, den3 = r3[c].as_numer_denom() if solve([num1*u-den1*(v-w), num2*v-den2*(w-u), num3*w-den3*(u-v)],[u, v]): return 'type1' r = eq[0].match(diff(x(t),t) - y(t)*z(t)*f) if r: r1 = collect_const(r[f]).match(a*f) r2 = ((diff(y(t),t) - eq[1])/r1[f]).match(b*z(t)*x(t)) r3 = ((diff(z(t),t) - eq[2])/r1[f]).match(c*x(t)*y(t)) if r1 and r2 and r3: num1, den1 = r1[a].as_numer_denom() num2, den2 = r2[b].as_numer_denom() num3, den3 = r3[c].as_numer_denom() if solve([num1*u-den1*(v-w), num2*v-den2*(w-u), num3*w-den3*(u-v)],[u, v]): return 'type2' r = eq[0].match(diff(x(t),t) - (F2-F3)) if r: r1 = collect_const(r[F2]).match(c*F2) r1.update(collect_const(r[F3]).match(b*F3)) if r1: if eq[1].has(r1[F2]) and not eq[1].has(r1[F3]): r1[F2], r1[F3] = r1[F3], r1[F2] r1[c], r1[b] = -r1[b], -r1[c] r2 = eq[1].match(diff(y(t),t) - a*r1[F3] + r1[c]*F1) if r2: r3 = (eq[2] == diff(z(t),t) - r1[b]*r2[F1] + r2[a]*r1[F2]) if r1 and r2 and r3: return 'type3' r = eq[0].match(diff(x(t),t) - z(t)*F2 + y(t)*F3) if r: r1 = collect_const(r[F2]).match(c*F2) r1.update(collect_const(r[F3]).match(b*F3)) if r1: if eq[1].has(r1[F2]) and not eq[1].has(r1[F3]): r1[F2], r1[F3] = r1[F3], r1[F2] r1[c], r1[b] = -r1[b], -r1[c] r2 = (diff(y(t),t) - eq[1]).match(a*x(t)*r1[F3] - r1[c]*z(t)*F1) if r2: r3 = (diff(z(t),t) - eq[2] == r1[b]*y(t)*r2[F1] - r2[a]*x(t)*r1[F2]) if r1 and r2 and r3: return 'type4' r = (diff(x(t),t) - eq[0]).match(x(t)*(F2 - F3)) if r: r1 = collect_const(r[F2]).match(c*F2) r1.update(collect_const(r[F3]).match(b*F3)) if r1: if eq[1].has(r1[F2]) and not eq[1].has(r1[F3]): r1[F2], r1[F3] = r1[F3], r1[F2] r1[c], r1[b] = -r1[b], -r1[c] r2 = (diff(y(t),t) - eq[1]).match(y(t)*(a*r1[F3] - r1[c]*F1)) if r2: r3 = (diff(z(t),t) - eq[2] == z(t)*(r1[b]*r2[F1] - r2[a]*r1[F2])) if r1 and r2 and r3: return 'type5' return None def check_nonlinear_3eq_order2(eq, func, func_coef): return None def checksysodesol(eqs, sols, func=None): r""" Substitutes corresponding ``sols`` for each functions into each ``eqs`` and checks that the result of substitutions for each equation is ``0``. The equations and solutions passed can be any iterable. This only works when each ``sols`` have one function only, like `x(t)` or `y(t)`. For each function, ``sols`` can have a single solution or a list of solutions. In most cases it will not be necessary to explicitly identify the function, but if the function cannot be inferred from the original equation it can be supplied through the ``func`` argument. When a sequence of equations is passed, the same sequence is used to return the result for each equation with each function substituted with corresponding solutions. It tries the following method to find zero equivalence for each equation: Substitute the solutions for functions, like `x(t)` and `y(t)` into the original equations containing those functions. This function returns a tuple. The first item in the tuple is ``True`` if the substitution results for each equation is ``0``, and ``False`` otherwise. The second item in the tuple is what the substitution results in. Each element of the ``list`` should always be ``0`` corresponding to each equation if the first item is ``True``. Note that sometimes this function may return ``False``, but with an expression that is identically equal to ``0``, instead of returning ``True``. This is because :py:meth:`~sympy.simplify.simplify.simplify` cannot reduce the expression to ``0``. If an expression returned by each function vanishes identically, then ``sols`` really is a solution to ``eqs``. If this function seems to hang, it is probably because of a difficult simplification. Examples ======== >>> from sympy import Eq, diff, symbols, sin, cos, exp, sqrt, S, Function >>> from sympy.solvers.ode import checksysodesol >>> C1, C2 = symbols('C1:3') >>> t = symbols('t') >>> x, y = symbols('x, y', cls=Function) >>> eq = (Eq(diff(x(t),t), x(t) + y(t) + 17), Eq(diff(y(t),t), -2*x(t) + y(t) + 12)) >>> sol = [Eq(x(t), (C1*sin(sqrt(2)*t) + C2*cos(sqrt(2)*t))*exp(t) - S(5)/3), ... Eq(y(t), (sqrt(2)*C1*cos(sqrt(2)*t) - sqrt(2)*C2*sin(sqrt(2)*t))*exp(t) - S(46)/3)] >>> checksysodesol(eq, sol) (True, [0, 0]) >>> eq = (Eq(diff(x(t),t),x(t)*y(t)**4), Eq(diff(y(t),t),y(t)**3)) >>> sol = [Eq(x(t), C1*exp(-1/(4*(C2 + t)))), Eq(y(t), -sqrt(2)*sqrt(-1/(C2 + t))/2), ... Eq(x(t), C1*exp(-1/(4*(C2 + t)))), Eq(y(t), sqrt(2)*sqrt(-1/(C2 + t))/2)] >>> checksysodesol(eq, sol) (True, [0, 0]) """ def _sympify(eq): return list(map(sympify, eq if iterable(eq) else [eq])) eqs = _sympify(eqs) for i in range(len(eqs)): if isinstance(eqs[i], Equality): eqs[i] = eqs[i].lhs - eqs[i].rhs if func is None: funcs = [] for eq in eqs: derivs = eq.atoms(Derivative) func = set().union(*[d.atoms(AppliedUndef) for d in derivs]) for func_ in func: funcs.append(func_) funcs = list(set(funcs)) if not all(isinstance(func, AppliedUndef) and len(func.args) == 1 for func in funcs)\ and len({func.args for func in funcs})!=1: raise ValueError("func must be a function of one variable, not %s" % func) for sol in sols: if len(sol.atoms(AppliedUndef)) != 1: raise ValueError("solutions should have one function only") if len(funcs) != len({sol.lhs for sol in sols}): raise ValueError("number of solutions provided does not match the number of equations") dictsol = dict() for sol in sols: func = list(sol.atoms(AppliedUndef))[0] if sol.rhs == func: sol = sol.reversed solved = sol.lhs == func and not sol.rhs.has(func) if not solved: rhs = solve(sol, func) if not rhs: raise NotImplementedError else: rhs = sol.rhs dictsol[func] = rhs checkeq = [] for eq in eqs: for func in funcs: eq = sub_func_doit(eq, func, dictsol[func]) ss = simplify(eq) if ss != 0: eq = ss.expand(force=True) else: eq = 0 checkeq.append(eq) if len(set(checkeq)) == 1 and list(set(checkeq))[0] == 0: return (True, checkeq) else: return (False, checkeq) @vectorize(0) def odesimp(ode, eq, func, hint): r""" Simplifies solutions of ODEs, including trying to solve for ``func`` and running :py:meth:`~sympy.solvers.ode.constantsimp`. It may use knowledge of the type of solution that the hint returns to apply additional simplifications. It also attempts to integrate any :py:class:`~sympy.integrals.Integral`\s in the expression, if the hint is not an ``_Integral`` hint. This function should have no effect on expressions returned by :py:meth:`~sympy.solvers.ode.dsolve`, as :py:meth:`~sympy.solvers.ode.dsolve` already calls :py:meth:`~sympy.solvers.ode.odesimp`, but the individual hint functions do not call :py:meth:`~sympy.solvers.ode.odesimp` (because the :py:meth:`~sympy.solvers.ode.dsolve` wrapper does). Therefore, this function is designed for mainly internal use. Examples ======== >>> from sympy import sin, symbols, dsolve, pprint, Function >>> from sympy.solvers.ode import odesimp >>> x , u2, C1= symbols('x,u2,C1') >>> f = Function('f') >>> eq = dsolve(x*f(x).diff(x) - f(x) - x*sin(f(x)/x), f(x), ... hint='1st_homogeneous_coeff_subs_indep_div_dep_Integral', ... simplify=False) >>> pprint(eq, wrap_line=False) x ---- f(x) / | | / 1 \ | -|u2 + -------| | | /1 \| | | sin|--|| | \ \u2// log(f(x)) = log(C1) + | ---------------- d(u2) | 2 | u2 | / >>> pprint(odesimp(eq, f(x), 1, {C1}, ... hint='1st_homogeneous_coeff_subs_indep_div_dep' ... )) #doctest: +SKIP x --------- = C1 /f(x)\ tan|----| \2*x / """ x = func.args[0] f = func.func C1 = get_numbered_constants(eq, num=1) constants = eq.free_symbols - ode.free_symbols # First, integrate if the hint allows it. eq = _handle_Integral(eq, func, hint) if hint.startswith("nth_linear_euler_eq_nonhomogeneous"): eq = simplify(eq) if not isinstance(eq, Equality): raise TypeError("eq should be an instance of Equality") # Second, clean up the arbitrary constants. # Right now, nth linear hints can put as many as 2*order constants in an # expression. If that number grows with another hint, the third argument # here should be raised accordingly, or constantsimp() rewritten to handle # an arbitrary number of constants. eq = constantsimp(eq, constants) # Lastly, now that we have cleaned up the expression, try solving for func. # When CRootOf is implemented in solve(), we will want to return a CRootOf # every time instead of an Equality. # Get the f(x) on the left if possible. if eq.rhs == func and not eq.lhs.has(func): eq = [Eq(eq.rhs, eq.lhs)] # make sure we are working with lists of solutions in simplified form. if eq.lhs == func and not eq.rhs.has(func): # The solution is already solved eq = [eq] # special simplification of the rhs if hint.startswith("nth_linear_constant_coeff"): # Collect terms to make the solution look nice. # This is also necessary for constantsimp to remove unnecessary # terms from the particular solution from variation of parameters # # Collect is not behaving reliably here. The results for # some linear constant-coefficient equations with repeated # roots do not properly simplify all constants sometimes. # 'collectterms' gives different orders sometimes, and results # differ in collect based on that order. The # sort-reverse trick fixes things, but may fail in the # future. In addition, collect is splitting exponentials with # rational powers for no reason. We have to do a match # to fix this using Wilds. global collectterms try: collectterms.sort(key=default_sort_key) collectterms.reverse() except Exception: pass assert len(eq) == 1 and eq[0].lhs == f(x) sol = eq[0].rhs sol = expand_mul(sol) for i, reroot, imroot in collectterms: sol = collect(sol, x**i*exp(reroot*x)*sin(abs(imroot)*x)) sol = collect(sol, x**i*exp(reroot*x)*cos(imroot*x)) for i, reroot, imroot in collectterms: sol = collect(sol, x**i*exp(reroot*x)) del collectterms # Collect is splitting exponentials with rational powers for # no reason. We call powsimp to fix. sol = powsimp(sol) eq[0] = Eq(f(x), sol) else: # The solution is not solved, so try to solve it try: floats = any(i.is_Float for i in eq.atoms(Number)) eqsol = solve(eq, func, force=True, rational=False if floats else None) if not eqsol: raise NotImplementedError except (NotImplementedError, PolynomialError): eq = [eq] else: def _expand(expr): numer, denom = expr.as_numer_denom() if denom.is_Add: return expr else: return powsimp(expr.expand(), combine='exp', deep=True) # XXX: the rest of odesimp() expects each ``t`` to be in a # specific normal form: rational expression with numerator # expanded, but with combined exponential functions (at # least in this setup all tests pass). eq = [Eq(f(x), _expand(t)) for t in eqsol] # special simplification of the lhs. if hint.startswith("1st_homogeneous_coeff"): for j, eqi in enumerate(eq): newi = logcombine(eqi, force=True) if isinstance(newi.lhs, log) and newi.rhs == 0: newi = Eq(newi.lhs.args[0]/C1, C1) eq[j] = newi # We cleaned up the constants before solving to help the solve engine with # a simpler expression, but the solved expression could have introduced # things like -C1, so rerun constantsimp() one last time before returning. for i, eqi in enumerate(eq): eq[i] = constantsimp(eqi, constants) eq[i] = constant_renumber(eq[i], ode.free_symbols) # If there is only 1 solution, return it; # otherwise return the list of solutions. if len(eq) == 1: eq = eq[0] return eq def checkodesol(ode, sol, func=None, order='auto', solve_for_func=True): r""" Substitutes ``sol`` into ``ode`` and checks that the result is ``0``. This only works when ``func`` is one function, like `f(x)`. ``sol`` can be a single solution or a list of solutions. Each solution may be an :py:class:`~sympy.core.relational.Equality` that the solution satisfies, e.g. ``Eq(f(x), C1), Eq(f(x) + C1, 0)``; or simply an :py:class:`~sympy.core.expr.Expr`, e.g. ``f(x) - C1``. In most cases it will not be necessary to explicitly identify the function, but if the function cannot be inferred from the original equation it can be supplied through the ``func`` argument. If a sequence of solutions is passed, the same sort of container will be used to return the result for each solution. It tries the following methods, in order, until it finds zero equivalence: 1. Substitute the solution for `f` in the original equation. This only works if ``ode`` is solved for `f`. It will attempt to solve it first unless ``solve_for_func == False``. 2. Take `n` derivatives of the solution, where `n` is the order of ``ode``, and check to see if that is equal to the solution. This only works on exact ODEs. 3. Take the 1st, 2nd, ..., `n`\th derivatives of the solution, each time solving for the derivative of `f` of that order (this will always be possible because `f` is a linear operator). Then back substitute each derivative into ``ode`` in reverse order. This function returns a tuple. The first item in the tuple is ``True`` if the substitution results in ``0``, and ``False`` otherwise. The second item in the tuple is what the substitution results in. It should always be ``0`` if the first item is ``True``. Sometimes this function will return ``False`` even when an expression is identically equal to ``0``. This happens when :py:meth:`~sympy.simplify.simplify.simplify` does not reduce the expression to ``0``. If an expression returned by this function vanishes identically, then ``sol`` really is a solution to the ``ode``. If this function seems to hang, it is probably because of a hard simplification. To use this function to test, test the first item of the tuple. Examples ======== >>> from sympy import Eq, Function, checkodesol, symbols >>> x, C1 = symbols('x,C1') >>> f = Function('f') >>> checkodesol(f(x).diff(x), Eq(f(x), C1)) (True, 0) >>> assert checkodesol(f(x).diff(x), C1)[0] >>> assert not checkodesol(f(x).diff(x), x)[0] >>> checkodesol(f(x).diff(x, 2), x**2) (False, 2) """ if not isinstance(ode, Equality): ode = Eq(ode, 0) if func is None: try: _, func = _preprocess(ode.lhs) except ValueError: funcs = [s.atoms(AppliedUndef) for s in ( sol if is_sequence(sol, set) else [sol])] funcs = set().union(*funcs) if len(funcs) != 1: raise ValueError( 'must pass func arg to checkodesol for this case.') func = funcs.pop() if not isinstance(func, AppliedUndef) or len(func.args) != 1: raise ValueError( "func must be a function of one variable, not %s" % func) if is_sequence(sol, set): return type(sol)([checkodesol(ode, i, order=order, solve_for_func=solve_for_func) for i in sol]) if not isinstance(sol, Equality): sol = Eq(func, sol) elif sol.rhs == func: sol = sol.reversed if order == 'auto': order = ode_order(ode, func) solved = sol.lhs == func and not sol.rhs.has(func) if solve_for_func and not solved: rhs = solve(sol, func) if rhs: eqs = [Eq(func, t) for t in rhs] if len(rhs) == 1: eqs = eqs[0] return checkodesol(ode, eqs, order=order, solve_for_func=False) s = True testnum = 0 x = func.args[0] while s: if testnum == 0: # First pass, try substituting a solved solution directly into the # ODE. This has the highest chance of succeeding. ode_diff = ode.lhs - ode.rhs if sol.lhs == func: s = sub_func_doit(ode_diff, func, sol.rhs) else: testnum += 1 continue ss = simplify(s) if ss: # with the new numer_denom in power.py, if we do a simple # expansion then testnum == 0 verifies all solutions. s = ss.expand(force=True) else: s = 0 testnum += 1 elif testnum == 1: # Second pass. If we cannot substitute f, try seeing if the nth # derivative is equal, this will only work for odes that are exact, # by definition. s = simplify( trigsimp(diff(sol.lhs, x, order) - diff(sol.rhs, x, order)) - trigsimp(ode.lhs) + trigsimp(ode.rhs)) # s2 = simplify( # diff(sol.lhs, x, order) - diff(sol.rhs, x, order) - \ # ode.lhs + ode.rhs) testnum += 1 elif testnum == 2: # Third pass. Try solving for df/dx and substituting that into the # ODE. Thanks to Chris Smith for suggesting this method. Many of # the comments below are his, too. # The method: # - Take each of 1..n derivatives of the solution. # - Solve each nth derivative for d^(n)f/dx^(n) # (the differential of that order) # - Back substitute into the ODE in decreasing order # (i.e., n, n-1, ...) # - Check the result for zero equivalence if sol.lhs == func and not sol.rhs.has(func): diffsols = {0: sol.rhs} elif sol.rhs == func and not sol.lhs.has(func): diffsols = {0: sol.lhs} else: diffsols = {} sol = sol.lhs - sol.rhs for i in range(1, order + 1): # Differentiation is a linear operator, so there should always # be 1 solution. Nonetheless, we test just to make sure. # We only need to solve once. After that, we automatically # have the solution to the differential in the order we want. if i == 1: ds = sol.diff(x) try: sdf = solve(ds, func.diff(x, i)) if not sdf: raise NotImplementedError except NotImplementedError: testnum += 1 break else: diffsols[i] = sdf[0] else: # This is what the solution says df/dx should be. diffsols[i] = diffsols[i - 1].diff(x) # Make sure the above didn't fail. if testnum > 2: continue else: # Substitute it into ODE to check for self consistency. lhs, rhs = ode.lhs, ode.rhs for i in range(order, -1, -1): if i == 0 and 0 not in diffsols: # We can only substitute f(x) if the solution was # solved for f(x). break lhs = sub_func_doit(lhs, func.diff(x, i), diffsols[i]) rhs = sub_func_doit(rhs, func.diff(x, i), diffsols[i]) ode_or_bool = Eq(lhs, rhs) ode_or_bool = simplify(ode_or_bool) if isinstance(ode_or_bool, (bool, BooleanAtom)): if ode_or_bool: lhs = rhs = S.Zero else: lhs = ode_or_bool.lhs rhs = ode_or_bool.rhs # No sense in overworking simplify -- just prove that the # numerator goes to zero num = trigsimp((lhs - rhs).as_numer_denom()[0]) # since solutions are obtained using force=True we test # using the same level of assumptions ## replace function with dummy so assumptions will work _func = Dummy('func') num = num.subs(func, _func) ## posify the expression num, reps = posify(num) s = simplify(num).xreplace(reps).xreplace({_func: func}) testnum += 1 else: break if not s: return (True, s) elif s is True: # The code above never was able to change s raise NotImplementedError("Unable to test if " + str(sol) + " is a solution to " + str(ode) + ".") else: return (False, s) def ode_sol_simplicity(sol, func, trysolving=True): r""" Returns an extended integer representing how simple a solution to an ODE is. The following things are considered, in order from most simple to least: - ``sol`` is solved for ``func``. - ``sol`` is not solved for ``func``, but can be if passed to solve (e.g., a solution returned by ``dsolve(ode, func, simplify=False``). - If ``sol`` is not solved for ``func``, then base the result on the length of ``sol``, as computed by ``len(str(sol))``. - If ``sol`` has any unevaluated :py:class:`~sympy.integrals.Integral`\s, this will automatically be considered less simple than any of the above. This function returns an integer such that if solution A is simpler than solution B by above metric, then ``ode_sol_simplicity(sola, func) < ode_sol_simplicity(solb, func)``. Currently, the following are the numbers returned, but if the heuristic is ever improved, this may change. Only the ordering is guaranteed. +----------------------------------------------+-------------------+ | Simplicity | Return | +==============================================+===================+ | ``sol`` solved for ``func`` | ``-2`` | +----------------------------------------------+-------------------+ | ``sol`` not solved for ``func`` but can be | ``-1`` | +----------------------------------------------+-------------------+ | ``sol`` is not solved nor solvable for | ``len(str(sol))`` | | ``func`` | | +----------------------------------------------+-------------------+ | ``sol`` contains an | ``oo`` | | :py:class:`~sympy.integrals.Integral` | | +----------------------------------------------+-------------------+ ``oo`` here means the SymPy infinity, which should compare greater than any integer. If you already know :py:meth:`~sympy.solvers.solvers.solve` cannot solve ``sol``, you can use ``trysolving=False`` to skip that step, which is the only potentially slow step. For example, :py:meth:`~sympy.solvers.ode.dsolve` with the ``simplify=False`` flag should do this. If ``sol`` is a list of solutions, if the worst solution in the list returns ``oo`` it returns that, otherwise it returns ``len(str(sol))``, that is, the length of the string representation of the whole list. Examples ======== This function is designed to be passed to ``min`` as the key argument, such as ``min(listofsolutions, key=lambda i: ode_sol_simplicity(i, f(x)))``. >>> from sympy import symbols, Function, Eq, tan, cos, sqrt, Integral >>> from sympy.solvers.ode import ode_sol_simplicity >>> x, C1, C2 = symbols('x, C1, C2') >>> f = Function('f') >>> ode_sol_simplicity(Eq(f(x), C1*x**2), f(x)) -2 >>> ode_sol_simplicity(Eq(x**2 + f(x), C1), f(x)) -1 >>> ode_sol_simplicity(Eq(f(x), C1*Integral(2*x, x)), f(x)) oo >>> eq1 = Eq(f(x)/tan(f(x)/(2*x)), C1) >>> eq2 = Eq(f(x)/tan(f(x)/(2*x) + f(x)), C2) >>> [ode_sol_simplicity(eq, f(x)) for eq in [eq1, eq2]] [28, 35] >>> min([eq1, eq2], key=lambda i: ode_sol_simplicity(i, f(x))) Eq(f(x)/tan(f(x)/(2*x)), C1) """ # TODO: if two solutions are solved for f(x), we still want to be # able to get the simpler of the two # See the docstring for the coercion rules. We check easier (faster) # things here first, to save time. if iterable(sol): # See if there are Integrals for i in sol: if ode_sol_simplicity(i, func, trysolving=trysolving) == oo: return oo return len(str(sol)) if sol.has(Integral): return oo # Next, try to solve for func. This code will change slightly when CRootOf # is implemented in solve(). Probably a CRootOf solution should fall # somewhere between a normal solution and an unsolvable expression. # First, see if they are already solved if sol.lhs == func and not sol.rhs.has(func) or \ sol.rhs == func and not sol.lhs.has(func): return -2 # We are not so lucky, try solving manually if trysolving: try: sols = solve(sol, func) if not sols: raise NotImplementedError except NotImplementedError: pass else: return -1 # Finally, a naive computation based on the length of the string version # of the expression. This may favor combined fractions because they # will not have duplicate denominators, and may slightly favor expressions # with fewer additions and subtractions, as those are separated by spaces # by the printer. # Additional ideas for simplicity heuristics are welcome, like maybe # checking if a equation has a larger domain, or if constantsimp has # introduced arbitrary constants numbered higher than the order of a # given ODE that sol is a solution of. return len(str(sol)) def _get_constant_subexpressions(expr, Cs): Cs = set(Cs) Ces = [] def _recursive_walk(expr): expr_syms = expr.free_symbols if expr_syms and expr_syms.issubset(Cs): Ces.append(expr) else: if expr.func == exp: expr = expr.expand(mul=True) if expr.func in (Add, Mul): d = sift(expr.args, lambda i : i.free_symbols.issubset(Cs)) if len(d[True]) > 1: x = expr.func(*d[True]) if not x.is_number: Ces.append(x) elif isinstance(expr, Integral): if expr.free_symbols.issubset(Cs) and \ all(len(x) == 3 for x in expr.limits): Ces.append(expr) for i in expr.args: _recursive_walk(i) return _recursive_walk(expr) return Ces def __remove_linear_redundancies(expr, Cs): cnts = {i: expr.count(i) for i in Cs} Cs = [i for i in Cs if cnts[i] > 0] def _linear(expr): if isinstance(expr, Add): xs = [i for i in Cs if expr.count(i)==cnts[i] \ and 0 == expr.diff(i, 2)] d = {} for x in xs: y = expr.diff(x) if y not in d: d[y]=[] d[y].append(x) for y in d: if len(d[y]) > 1: d[y].sort(key=str) for x in d[y][1:]: expr = expr.subs(x, 0) return expr def _recursive_walk(expr): if len(expr.args) != 0: expr = expr.func(*[_recursive_walk(i) for i in expr.args]) expr = _linear(expr) return expr if isinstance(expr, Equality): lhs, rhs = [_recursive_walk(i) for i in expr.args] f = lambda i: isinstance(i, Number) or i in Cs if isinstance(lhs, Symbol) and lhs in Cs: rhs, lhs = lhs, rhs if lhs.func in (Add, Symbol) and rhs.func in (Add, Symbol): dlhs = sift([lhs] if isinstance(lhs, AtomicExpr) else lhs.args, f) drhs = sift([rhs] if isinstance(rhs, AtomicExpr) else rhs.args, f) for i in [True, False]: for hs in [dlhs, drhs]: if i not in hs: hs[i] = [0] # this calculation can be simplified lhs = Add(*dlhs[False]) - Add(*drhs[False]) rhs = Add(*drhs[True]) - Add(*dlhs[True]) elif lhs.func in (Mul, Symbol) and rhs.func in (Mul, Symbol): dlhs = sift([lhs] if isinstance(lhs, AtomicExpr) else lhs.args, f) if True in dlhs: if False not in dlhs: dlhs[False] = [1] lhs = Mul(*dlhs[False]) rhs = rhs/Mul(*dlhs[True]) return Eq(lhs, rhs) else: return _recursive_walk(expr) @vectorize(0) def constantsimp(expr, constants): r""" Simplifies an expression with arbitrary constants in it. This function is written specifically to work with :py:meth:`~sympy.solvers.ode.dsolve`, and is not intended for general use. Simplification is done by "absorbing" the arbitrary constants into other arbitrary constants, numbers, and symbols that they are not independent of. The symbols must all have the same name with numbers after it, for example, ``C1``, ``C2``, ``C3``. The ``symbolname`` here would be '``C``', the ``startnumber`` would be 1, and the ``endnumber`` would be 3. If the arbitrary constants are independent of the variable ``x``, then the independent symbol would be ``x``. There is no need to specify the dependent function, such as ``f(x)``, because it already has the independent symbol, ``x``, in it. Because terms are "absorbed" into arbitrary constants and because constants are renumbered after simplifying, the arbitrary constants in expr are not necessarily equal to the ones of the same name in the returned result. If two or more arbitrary constants are added, multiplied, or raised to the power of each other, they are first absorbed together into a single arbitrary constant. Then the new constant is combined into other terms if necessary. Absorption of constants is done with limited assistance: 1. terms of :py:class:`~sympy.core.add.Add`\s are collected to try join constants so `e^x (C_1 \cos(x) + C_2 \cos(x))` will simplify to `e^x C_1 \cos(x)`; 2. powers with exponents that are :py:class:`~sympy.core.add.Add`\s are expanded so `e^{C_1 + x}` will be simplified to `C_1 e^x`. Use :py:meth:`~sympy.solvers.ode.constant_renumber` to renumber constants after simplification or else arbitrary numbers on constants may appear, e.g. `C_1 + C_3 x`. In rare cases, a single constant can be "simplified" into two constants. Every differential equation solution should have as many arbitrary constants as the order of the differential equation. The result here will be technically correct, but it may, for example, have `C_1` and `C_2` in an expression, when `C_1` is actually equal to `C_2`. Use your discretion in such situations, and also take advantage of the ability to use hints in :py:meth:`~sympy.solvers.ode.dsolve`. Examples ======== >>> from sympy import symbols >>> from sympy.solvers.ode import constantsimp >>> C1, C2, C3, x, y = symbols('C1, C2, C3, x, y') >>> constantsimp(2*C1*x, {C1, C2, C3}) C1*x >>> constantsimp(C1 + 2 + x, {C1, C2, C3}) C1 + x >>> constantsimp(C1*C2 + 2 + C2 + C3*x, {C1, C2, C3}) C1 + C3*x """ # This function works recursively. The idea is that, for Mul, # Add, Pow, and Function, if the class has a constant in it, then # we can simplify it, which we do by recursing down and # simplifying up. Otherwise, we can skip that part of the # expression. Cs = constants orig_expr = expr constant_subexprs = _get_constant_subexpressions(expr, Cs) for xe in constant_subexprs: xes = list(xe.free_symbols) if not xes: continue if all([expr.count(c) == xe.count(c) for c in xes]): xes.sort(key=str) expr = expr.subs(xe, xes[0]) # try to perform common sub-expression elimination of constant terms try: commons, rexpr = cse(expr) commons.reverse() rexpr = rexpr[0] for s in commons: cs = list(s[1].atoms(Symbol)) if len(cs) == 1 and cs[0] in Cs and \ cs[0] not in rexpr.atoms(Symbol) and \ not any(cs[0] in ex for ex in commons if ex != s): rexpr = rexpr.subs(s[0], cs[0]) else: rexpr = rexpr.subs(*s) expr = rexpr except Exception: pass expr = __remove_linear_redundancies(expr, Cs) def _conditional_term_factoring(expr): new_expr = terms_gcd(expr, clear=False, deep=True, expand=False) # we do not want to factor exponentials, so handle this separately if new_expr.is_Mul: infac = False asfac = False for m in new_expr.args: if isinstance(m, exp): asfac = True elif m.is_Add: infac = any(isinstance(fi, exp) for t in m.args for fi in Mul.make_args(t)) if asfac and infac: new_expr = expr break return new_expr expr = _conditional_term_factoring(expr) # call recursively if more simplification is possible if orig_expr != expr: return constantsimp(expr, Cs) return expr def constant_renumber(expr, variables=None, newconstants=None): r""" Renumber arbitrary constants in ``expr`` to use the symbol names as given in ``newconstants``. In the process, this reorders expression terms in a standard way. If ``newconstants`` is not provided then the new constant names will be ``C1``, ``C2`` etc. Otherwise ``newconstants`` should be an iterable giving the new symbols to use for the constants in order. The ``variables`` argument is a list of non-constant symbols. All other free symbols found in ``expr`` are assumed to be constants and will be renumbered. If ``variables`` is not given then any numbered symbol beginning with ``C`` (e.g. ``C1``) is assumed to be a constant. Symbols are renumbered based on ``.sort_key()``, so they should be numbered roughly in the order that they appear in the final, printed expression. Note that this ordering is based in part on hashes, so it can produce different results on different machines. The structure of this function is very similar to that of :py:meth:`~sympy.solvers.ode.constantsimp`. Examples ======== >>> from sympy import symbols, Eq, pprint >>> from sympy.solvers.ode import constant_renumber >>> x, C1, C2, C3 = symbols('x,C1:4') >>> expr = C3 + C2*x + C1*x**2 >>> expr C1*x**2 + C2*x + C3 >>> constant_renumber(expr) C1 + C2*x + C3*x**2 The ``variables`` argument specifies which are constants so that the other symbols will not be renumbered: >>> constant_renumber(expr, [C1, x]) C1*x**2 + C2 + C3*x The ``newconstants`` argument is used to specify what symbols to use when replacing the constants: >>> constant_renumber(expr, [x], newconstants=symbols('E1:4')) E1 + E2*x + E3*x**2 """ if type(expr) in (set, list, tuple): renumbered = [constant_renumber(e, variables, newconstants) for e in expr] return type(expr)(renumbered) # Symbols in solution but not ODE are constants if variables is not None: variables = set(variables) constantsymbols = list(expr.free_symbols - variables) # Any Cn is a constant... else: variables = set() isconstant = lambda s: s.startswith('C') and s[1:].isdigit() constantsymbols = [sym for sym in expr.free_symbols if isconstant(sym.name)] # Find new constants checking that they aren't alread in the ODE if newconstants is None: iter_constants = numbered_symbols(start=1, prefix='C', exclude=variables) else: iter_constants = (sym for sym in newconstants if sym not in variables) global newstartnumber newstartnumber = 1 endnumber = len(constantsymbols) constants_found = [None]*(endnumber + 2) # make a mapping to send all constantsymbols to S.One and use # that to make sure that term ordering is not dependent on # the indexed value of C C_1 = [(ci, S.One) for ci in constantsymbols] sort_key=lambda arg: default_sort_key(arg.subs(C_1)) def _constant_renumber(expr): r""" We need to have an internal recursive function so that newstartnumber maintains its values throughout recursive calls. """ # FIXME: Use nonlocal here when support for Py2 is dropped: global newstartnumber if isinstance(expr, Equality): return Eq( _constant_renumber(expr.lhs), _constant_renumber(expr.rhs)) if type(expr) not in (Mul, Add, Pow) and not expr.is_Function and \ not expr.has(*constantsymbols): # Base case, as above. Hope there aren't constants inside # of some other class, because they won't be renumbered. return expr elif expr.is_Piecewise: return expr elif expr in constantsymbols: if expr not in constants_found: constants_found[newstartnumber] = expr newstartnumber += 1 return expr elif expr.is_Function or expr.is_Pow or isinstance(expr, Tuple): return expr.func( *[_constant_renumber(x) for x in expr.args]) else: sortedargs = list(expr.args) sortedargs.sort(key=sort_key) return expr.func(*[_constant_renumber(x) for x in sortedargs]) expr = _constant_renumber(expr) # Don't renumber symbols present in the ODE. constants_found = [c for c in constants_found if c not in variables] # Renumbering happens here expr = expr.subs(zip(constants_found[1:], iter_constants), simultaneous=True) return expr def _handle_Integral(expr, func, hint): r""" Converts a solution with Integrals in it into an actual solution. For most hints, this simply runs ``expr.doit()``. """ global y x = func.args[0] f = func.func if hint == "1st_exact": sol = (expr.doit()).subs(y, f(x)) del y elif hint == "1st_exact_Integral": sol = Eq(Subs(expr.lhs, y, f(x)), expr.rhs) del y elif hint == "nth_linear_constant_coeff_homogeneous": sol = expr elif not hint.endswith("_Integral"): sol = expr.doit() else: sol = expr return sol # FIXME: replace the general solution in the docstring with # dsolve(equation, hint='1st_exact_Integral'). You will need to be able # to have assumptions on P and Q that dP/dy = dQ/dx. def ode_1st_exact(eq, func, order, match): r""" Solves 1st order exact ordinary differential equations. A 1st order differential equation is called exact if it is the total differential of a function. That is, the differential equation .. math:: P(x, y) \,\partial{}x + Q(x, y) \,\partial{}y = 0 is exact if there is some function `F(x, y)` such that `P(x, y) = \partial{}F/\partial{}x` and `Q(x, y) = \partial{}F/\partial{}y`. It can be shown that a necessary and sufficient condition for a first order ODE to be exact is that `\partial{}P/\partial{}y = \partial{}Q/\partial{}x`. Then, the solution will be as given below:: >>> from sympy import Function, Eq, Integral, symbols, pprint >>> x, y, t, x0, y0, C1= symbols('x,y,t,x0,y0,C1') >>> P, Q, F= map(Function, ['P', 'Q', 'F']) >>> pprint(Eq(Eq(F(x, y), Integral(P(t, y), (t, x0, x)) + ... Integral(Q(x0, t), (t, y0, y))), C1)) x y / / | | F(x, y) = | P(t, y) dt + | Q(x0, t) dt = C1 | | / / x0 y0 Where the first partials of `P` and `Q` exist and are continuous in a simply connected region. A note: SymPy currently has no way to represent inert substitution on an expression, so the hint ``1st_exact_Integral`` will return an integral with `dy`. This is supposed to represent the function that you are solving for. Examples ======== >>> from sympy import Function, dsolve, cos, sin >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(cos(f(x)) - (x*sin(f(x)) - f(x)**2)*f(x).diff(x), ... f(x), hint='1st_exact') Eq(x*cos(f(x)) + f(x)**3/3, C1) References ========== - https://en.wikipedia.org/wiki/Exact_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 73 # indirect doctest """ x = func.args[0] r = match # d+e*diff(f(x),x) e = r[r['e']] d = r[r['d']] global y # This is the only way to pass dummy y to _handle_Integral y = r['y'] C1 = get_numbered_constants(eq, num=1) # Refer Joel Moses, "Symbolic Integration - The Stormy Decade", # Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 # which gives the method to solve an exact differential equation. sol = Integral(d, x) + Integral((e - (Integral(d, x).diff(y))), y) return Eq(sol, C1) def ode_1st_homogeneous_coeff_best(eq, func, order, match): r""" Returns the best solution to an ODE from the two hints ``1st_homogeneous_coeff_subs_dep_div_indep`` and ``1st_homogeneous_coeff_subs_indep_div_dep``. This is as determined by :py:meth:`~sympy.solvers.ode.ode_sol_simplicity`. See the :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep` and :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep` docstrings for more information on these hints. Note that there is no ``ode_1st_homogeneous_coeff_best_Integral`` hint. Examples ======== >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(2*x*f(x) + (x**2 + f(x)**2)*f(x).diff(x), f(x), ... hint='1st_homogeneous_coeff_best', simplify=False)) / 2 \ | 3*x | log|----- + 1| | 2 | \f (x) / log(f(x)) = log(C1) - -------------- 3 References ========== - https://en.wikipedia.org/wiki/Homogeneous_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 59 # indirect doctest """ # There are two substitutions that solve the equation, u1=y/x and u2=x/y # They produce different integrals, so try them both and see which # one is easier. sol1 = ode_1st_homogeneous_coeff_subs_indep_div_dep(eq, func, order, match) sol2 = ode_1st_homogeneous_coeff_subs_dep_div_indep(eq, func, order, match) simplify = match.get('simplify', True) if simplify: # why is odesimp called here? Should it be at the usual spot? sol1 = odesimp(eq, sol1, func, "1st_homogeneous_coeff_subs_indep_div_dep") sol2 = odesimp(eq, sol2, func, "1st_homogeneous_coeff_subs_dep_div_indep") return min([sol1, sol2], key=lambda x: ode_sol_simplicity(x, func, trysolving=not simplify)) def ode_1st_homogeneous_coeff_subs_dep_div_indep(eq, func, order, match): r""" Solves a 1st order differential equation with homogeneous coefficients using the substitution `u_1 = \frac{\text{<dependent variable>}}{\text{<independent variable>}}`. This is a differential equation .. math:: P(x, y) + Q(x, y) dy/dx = 0 such that `P` and `Q` are homogeneous and of the same order. A function `F(x, y)` is homogeneous of order `n` if `F(x t, y t) = t^n F(x, y)`. Equivalently, `F(x, y)` can be rewritten as `G(y/x)` or `H(x/y)`. See also the docstring of :py:meth:`~sympy.solvers.ode.homogeneous_order`. If the coefficients `P` and `Q` in the differential equation above are homogeneous functions of the same order, then it can be shown that the substitution `y = u_1 x` (i.e. `u_1 = y/x`) will turn the differential equation into an equation separable in the variables `x` and `u`. If `h(u_1)` is the function that results from making the substitution `u_1 = f(x)/x` on `P(x, f(x))` and `g(u_2)` is the function that results from the substitution on `Q(x, f(x))` in the differential equation `P(x, f(x)) + Q(x, f(x)) f'(x) = 0`, then the general solution is:: >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f, g, h = map(Function, ['f', 'g', 'h']) >>> genform = g(f(x)/x) + h(f(x)/x)*f(x).diff(x) >>> pprint(genform) /f(x)\ /f(x)\ d g|----| + h|----|*--(f(x)) \ x / \ x / dx >>> pprint(dsolve(genform, f(x), ... hint='1st_homogeneous_coeff_subs_dep_div_indep_Integral')) f(x) ---- x / | | -h(u1) log(x) = C1 + | ---------------- d(u1) | u1*h(u1) + g(u1) | / Where `u_1 h(u_1) + g(u_1) \ne 0` and `x \ne 0`. See also the docstrings of :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_best` and :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep`. Examples ======== >>> from sympy import Function, dsolve >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(2*x*f(x) + (x**2 + f(x)**2)*f(x).diff(x), f(x), ... hint='1st_homogeneous_coeff_subs_dep_div_indep', simplify=False)) / 3 \ |3*f(x) f (x)| log|------ + -----| | x 3 | \ x / log(x) = log(C1) - ------------------- 3 References ========== - https://en.wikipedia.org/wiki/Homogeneous_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 59 # indirect doctest """ x = func.args[0] f = func.func u = Dummy('u') u1 = Dummy('u1') # u1 == f(x)/x r = match # d+e*diff(f(x),x) C1 = get_numbered_constants(eq, num=1) xarg = match.get('xarg', 0) yarg = match.get('yarg', 0) int = Integral( (-r[r['e']]/(r[r['d']] + u1*r[r['e']])).subs({x: 1, r['y']: u1}), (u1, None, f(x)/x)) sol = logcombine(Eq(log(x), int + log(C1)), force=True) sol = sol.subs(f(x), u).subs(((u, u - yarg), (x, x - xarg), (u, f(x)))) return sol def ode_1st_homogeneous_coeff_subs_indep_div_dep(eq, func, order, match): r""" Solves a 1st order differential equation with homogeneous coefficients using the substitution `u_2 = \frac{\text{<independent variable>}}{\text{<dependent variable>}}`. This is a differential equation .. math:: P(x, y) + Q(x, y) dy/dx = 0 such that `P` and `Q` are homogeneous and of the same order. A function `F(x, y)` is homogeneous of order `n` if `F(x t, y t) = t^n F(x, y)`. Equivalently, `F(x, y)` can be rewritten as `G(y/x)` or `H(x/y)`. See also the docstring of :py:meth:`~sympy.solvers.ode.homogeneous_order`. If the coefficients `P` and `Q` in the differential equation above are homogeneous functions of the same order, then it can be shown that the substitution `x = u_2 y` (i.e. `u_2 = x/y`) will turn the differential equation into an equation separable in the variables `y` and `u_2`. If `h(u_2)` is the function that results from making the substitution `u_2 = x/f(x)` on `P(x, f(x))` and `g(u_2)` is the function that results from the substitution on `Q(x, f(x))` in the differential equation `P(x, f(x)) + Q(x, f(x)) f'(x) = 0`, then the general solution is: >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f, g, h = map(Function, ['f', 'g', 'h']) >>> genform = g(x/f(x)) + h(x/f(x))*f(x).diff(x) >>> pprint(genform) / x \ / x \ d g|----| + h|----|*--(f(x)) \f(x)/ \f(x)/ dx >>> pprint(dsolve(genform, f(x), ... hint='1st_homogeneous_coeff_subs_indep_div_dep_Integral')) x ---- f(x) / | | -g(u2) | ---------------- d(u2) | u2*g(u2) + h(u2) | / <BLANKLINE> f(x) = C1*e Where `u_2 g(u_2) + h(u_2) \ne 0` and `f(x) \ne 0`. See also the docstrings of :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_best` and :py:meth:`~sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep`. Examples ======== >>> from sympy import Function, pprint, dsolve >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(2*x*f(x) + (x**2 + f(x)**2)*f(x).diff(x), f(x), ... hint='1st_homogeneous_coeff_subs_indep_div_dep', ... simplify=False)) / 2 \ | 3*x | log|----- + 1| | 2 | \f (x) / log(f(x)) = log(C1) - -------------- 3 References ========== - https://en.wikipedia.org/wiki/Homogeneous_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 59 # indirect doctest """ x = func.args[0] f = func.func u = Dummy('u') u2 = Dummy('u2') # u2 == x/f(x) r = match # d+e*diff(f(x),x) C1 = get_numbered_constants(eq, num=1) xarg = match.get('xarg', 0) # If xarg present take xarg, else zero yarg = match.get('yarg', 0) # If yarg present take yarg, else zero int = Integral( simplify( (-r[r['d']]/(r[r['e']] + u2*r[r['d']])).subs({x: u2, r['y']: 1})), (u2, None, x/f(x))) sol = logcombine(Eq(log(f(x)), int + log(C1)), force=True) sol = sol.subs(f(x), u).subs(((u, u - yarg), (x, x - xarg), (u, f(x)))) return sol # XXX: Should this function maybe go somewhere else? def homogeneous_order(eq, *symbols): r""" Returns the order `n` if `g` is homogeneous and ``None`` if it is not homogeneous. Determines if a function is homogeneous and if so of what order. A function `f(x, y, \cdots)` is homogeneous of order `n` if `f(t x, t y, \cdots) = t^n f(x, y, \cdots)`. If the function is of two variables, `F(x, y)`, then `f` being homogeneous of any order is equivalent to being able to rewrite `F(x, y)` as `G(x/y)` or `H(y/x)`. This fact is used to solve 1st order ordinary differential equations whose coefficients are homogeneous of the same order (see the docstrings of :py:meth:`~solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep` and :py:meth:`~solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep`). Symbols can be functions, but every argument of the function must be a symbol, and the arguments of the function that appear in the expression must match those given in the list of symbols. If a declared function appears with different arguments than given in the list of symbols, ``None`` is returned. Examples ======== >>> from sympy import Function, homogeneous_order, sqrt >>> from sympy.abc import x, y >>> f = Function('f') >>> homogeneous_order(f(x), f(x)) is None True >>> homogeneous_order(f(x,y), f(y, x), x, y) is None True >>> homogeneous_order(f(x), f(x), x) 1 >>> homogeneous_order(x**2*f(x)/sqrt(x**2+f(x)**2), x, f(x)) 2 >>> homogeneous_order(x**2+f(x), x, f(x)) is None True """ if not symbols: raise ValueError("homogeneous_order: no symbols were given.") symset = set(symbols) eq = sympify(eq) # The following are not supported if eq.has(Order, Derivative): return None # These are all constants if (eq.is_Number or eq.is_NumberSymbol or eq.is_number ): return S.Zero # Replace all functions with dummy variables dum = numbered_symbols(prefix='d', cls=Dummy) newsyms = set() for i in [j for j in symset if getattr(j, 'is_Function')]: iargs = set(i.args) if iargs.difference(symset): return None else: dummyvar = next(dum) eq = eq.subs(i, dummyvar) symset.remove(i) newsyms.add(dummyvar) symset.update(newsyms) if not eq.free_symbols & symset: return None # assuming order of a nested function can only be equal to zero if isinstance(eq, Function): return None if homogeneous_order( eq.args[0], *tuple(symset)) != 0 else S.Zero # make the replacement of x with x*t and see if t can be factored out t = Dummy('t', positive=True) # It is sufficient that t > 0 eqs = separatevars(eq.subs([(i, t*i) for i in symset]), [t], dict=True)[t] if eqs is S.One: return S.Zero # there was no term with only t i, d = eqs.as_independent(t, as_Add=False) b, e = d.as_base_exp() if b == t: return e def ode_1st_linear(eq, func, order, match): r""" Solves 1st order linear differential equations. These are differential equations of the form .. math:: dy/dx + P(x) y = Q(x)\text{.} These kinds of differential equations can be solved in a general way. The integrating factor `e^{\int P(x) \,dx}` will turn the equation into a separable equation. The general solution is:: >>> from sympy import Function, dsolve, Eq, pprint, diff, sin >>> from sympy.abc import x >>> f, P, Q = map(Function, ['f', 'P', 'Q']) >>> genform = Eq(f(x).diff(x) + P(x)*f(x), Q(x)) >>> pprint(genform) d P(x)*f(x) + --(f(x)) = Q(x) dx >>> pprint(dsolve(genform, f(x), hint='1st_linear_Integral')) / / \ | | | | | / | / | | | | | | | | P(x) dx | - | P(x) dx | | | | | | | / | / f(x) = |C1 + | Q(x)*e dx|*e | | | \ / / Examples ======== >>> f = Function('f') >>> pprint(dsolve(Eq(x*diff(f(x), x) - f(x), x**2*sin(x)), ... f(x), '1st_linear')) f(x) = x*(C1 - cos(x)) References ========== - https://en.wikipedia.org/wiki/Linear_differential_equation#First_order_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 92 # indirect doctest """ x = func.args[0] f = func.func r = match # a*diff(f(x),x) + b*f(x) + c C1 = get_numbered_constants(eq, num=1) t = exp(Integral(r[r['b']]/r[r['a']], x)) tt = Integral(t*(-r[r['c']]/r[r['a']]), x) f = match.get('u', f(x)) # take almost-linear u if present, else f(x) return Eq(f, (tt + C1)/t) def ode_Bernoulli(eq, func, order, match): r""" Solves Bernoulli differential equations. These are equations of the form .. math:: dy/dx + P(x) y = Q(x) y^n\text{, }n \ne 1`\text{.} The substitution `w = 1/y^{1-n}` will transform an equation of this form into one that is linear (see the docstring of :py:meth:`~sympy.solvers.ode.ode_1st_linear`). The general solution is:: >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x, n >>> f, P, Q = map(Function, ['f', 'P', 'Q']) >>> genform = Eq(f(x).diff(x) + P(x)*f(x), Q(x)*f(x)**n) >>> pprint(genform) d n P(x)*f(x) + --(f(x)) = Q(x)*f (x) dx >>> pprint(dsolve(genform, f(x), hint='Bernoulli_Integral')) #doctest: +SKIP 1 ---- 1 - n // / \ \ || | | | || | / | / | || | | | | | || | (1 - n)* | P(x) dx | (-1 + n)* | P(x) dx| || | | | | | || | / | / | f(x) = ||C1 + (-1 + n)* | -Q(x)*e dx|*e | || | | | \\ / / / Note that the equation is separable when `n = 1` (see the docstring of :py:meth:`~sympy.solvers.ode.ode_separable`). >>> pprint(dsolve(Eq(f(x).diff(x) + P(x)*f(x), Q(x)*f(x)), f(x), ... hint='separable_Integral')) f(x) / | / | 1 | | - dy = C1 + | (-P(x) + Q(x)) dx | y | | / / Examples ======== >>> from sympy import Function, dsolve, Eq, pprint, log >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(Eq(x*f(x).diff(x) + f(x), log(x)*f(x)**2), ... f(x), hint='Bernoulli')) 1 f(x) = ------------------- / log(x) 1\ x*|C1 + ------ + -| \ x x/ References ========== - https://en.wikipedia.org/wiki/Bernoulli_differential_equation - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 95 # indirect doctest """ x = func.args[0] f = func.func r = match # a*diff(f(x),x) + b*f(x) + c*f(x)**n, n != 1 C1 = get_numbered_constants(eq, num=1) t = exp((1 - r[r['n']])*Integral(r[r['b']]/r[r['a']], x)) tt = (r[r['n']] - 1)*Integral(t*r[r['c']]/r[r['a']], x) return Eq(f(x), ((tt + C1)/t)**(1/(1 - r[r['n']]))) def ode_Riccati_special_minus2(eq, func, order, match): r""" The general Riccati equation has the form .. math:: dy/dx = f(x) y^2 + g(x) y + h(x)\text{.} While it does not have a general solution [1], the "special" form, `dy/dx = a y^2 - b x^c`, does have solutions in many cases [2]. This routine returns a solution for `a(dy/dx) = b y^2 + c y/x + d/x^2` that is obtained by using a suitable change of variables to reduce it to the special form and is valid when neither `a` nor `b` are zero and either `c` or `d` is zero. >>> from sympy.abc import x, y, a, b, c, d >>> from sympy.solvers.ode import dsolve, checkodesol >>> from sympy import pprint, Function >>> f = Function('f') >>> y = f(x) >>> genform = a*y.diff(x) - (b*y**2 + c*y/x + d/x**2) >>> sol = dsolve(genform, y) >>> pprint(sol, wrap_line=False) / / __________________ \\ | __________________ | / 2 || | / 2 | \/ 4*b*d - (a + c) *log(x)|| -|a + c - \/ 4*b*d - (a + c) *tan|C1 + ----------------------------|| \ \ 2*a // f(x) = ------------------------------------------------------------------------ 2*b*x >>> checkodesol(genform, sol, order=1)[0] True References ========== 1. http://www.maplesoft.com/support/help/Maple/view.aspx?path=odeadvisor/Riccati 2. http://eqworld.ipmnet.ru/en/solutions/ode/ode0106.pdf - http://eqworld.ipmnet.ru/en/solutions/ode/ode0123.pdf """ x = func.args[0] f = func.func r = match # a2*diff(f(x),x) + b2*f(x) + c2*f(x)/x + d2/x**2 a2, b2, c2, d2 = [r[r[s]] for s in 'a2 b2 c2 d2'.split()] C1 = get_numbered_constants(eq, num=1) mu = sqrt(4*d2*b2 - (a2 - c2)**2) return Eq(f(x), (a2 - c2 - mu*tan(mu/(2*a2)*log(x) + C1))/(2*b2*x)) def ode_Liouville(eq, func, order, match): r""" Solves 2nd order Liouville differential equations. The general form of a Liouville ODE is .. math:: \frac{d^2 y}{dx^2} + g(y) \left(\! \frac{dy}{dx}\!\right)^2 + h(x) \frac{dy}{dx}\text{.} The general solution is: >>> from sympy import Function, dsolve, Eq, pprint, diff >>> from sympy.abc import x >>> f, g, h = map(Function, ['f', 'g', 'h']) >>> genform = Eq(diff(f(x),x,x) + g(f(x))*diff(f(x),x)**2 + ... h(x)*diff(f(x),x), 0) >>> pprint(genform) 2 2 /d \ d d g(f(x))*|--(f(x))| + h(x)*--(f(x)) + ---(f(x)) = 0 \dx / dx 2 dx >>> pprint(dsolve(genform, f(x), hint='Liouville_Integral')) f(x) / / | | | / | / | | | | | - | h(x) dx | | g(y) dy | | | | | / | / C1 + C2* | e dx + | e dy = 0 | | / / Examples ======== >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(diff(f(x), x, x) + diff(f(x), x)**2/f(x) + ... diff(f(x), x)/x, f(x), hint='Liouville')) ________________ ________________ [f(x) = -\/ C1 + C2*log(x) , f(x) = \/ C1 + C2*log(x) ] References ========== - Goldstein and Braun, "Advanced Methods for the Solution of Differential Equations", pp. 98 - http://www.maplesoft.com/support/help/Maple/view.aspx?path=odeadvisor/Liouville # indirect doctest """ # Liouville ODE: # f(x).diff(x, 2) + g(f(x))*(f(x).diff(x, 2))**2 + h(x)*f(x).diff(x) # See Goldstein and Braun, "Advanced Methods for the Solution of # Differential Equations", pg. 98, as well as # http://www.maplesoft.com/support/help/view.aspx?path=odeadvisor/Liouville x = func.args[0] f = func.func r = match # f(x).diff(x, 2) + g*f(x).diff(x)**2 + h*f(x).diff(x) y = r['y'] C1, C2 = get_numbered_constants(eq, num=2) int = Integral(exp(Integral(r['g'], y)), (y, None, f(x))) sol = Eq(int + C1*Integral(exp(-Integral(r['h'], x)), x) + C2, 0) return sol def ode_2nd_power_series_ordinary(eq, func, order, match): r""" Gives a power series solution to a second order homogeneous differential equation with polynomial coefficients at an ordinary point. A homogenous differential equation is of the form .. math :: P(x)\frac{d^2y}{dx^2} + Q(x)\frac{dy}{dx} + R(x) = 0 For simplicity it is assumed that `P(x)`, `Q(x)` and `R(x)` are polynomials, it is sufficient that `\frac{Q(x)}{P(x)}` and `\frac{R(x)}{P(x)}` exists at `x_{0}`. A recurrence relation is obtained by substituting `y` as `\sum_{n=0}^\infty a_{n}x^{n}`, in the differential equation, and equating the nth term. Using this relation various terms can be generated. Examples ======== >>> from sympy import dsolve, Function, pprint >>> from sympy.abc import x, y >>> f = Function("f") >>> eq = f(x).diff(x, 2) + f(x) >>> pprint(dsolve(eq, hint='2nd_power_series_ordinary')) / 4 2 \ / 2\ |x x | | x | / 6\ f(x) = C2*|-- - -- + 1| + C1*x*|1 - --| + O\x / \24 2 / \ 6 / References ========== - http://tutorial.math.lamar.edu/Classes/DE/SeriesSolutions.aspx - George E. Simmons, "Differential Equations with Applications and Historical Notes", p.p 176 - 184 """ x = func.args[0] f = func.func C0, C1 = get_numbered_constants(eq, num=2) n = Dummy("n", integer=True) s = Wild("s") k = Wild("k", exclude=[x]) x0 = match.get('x0') terms = match.get('terms', 5) p = match[match['a3']] q = match[match['b3']] r = match[match['c3']] seriesdict = {} recurr = Function("r") # Generating the recurrence relation which works this way: # for the second order term the summation begins at n = 2. The coefficients # p is multiplied with an*(n - 1)*(n - 2)*x**n-2 and a substitution is made such that # the exponent of x becomes n. # For example, if p is x, then the second degree recurrence term is # an*(n - 1)*(n - 2)*x**n-1, substituting (n - 1) as n, it transforms to # an+1*n*(n - 1)*x**n. # A similar process is done with the first order and zeroth order term. coefflist = [(recurr(n), r), (n*recurr(n), q), (n*(n - 1)*recurr(n), p)] for index, coeff in enumerate(coefflist): if coeff[1]: f2 = powsimp(expand((coeff[1]*(x - x0)**(n - index)).subs(x, x + x0))) if f2.is_Add: addargs = f2.args else: addargs = [f2] for arg in addargs: powm = arg.match(s*x**k) term = coeff[0]*powm[s] if not powm[k].is_Symbol: term = term.subs(n, n - powm[k].as_independent(n)[0]) startind = powm[k].subs(n, index) # Seeing if the startterm can be reduced further. # If it vanishes for n lesser than startind, it is # equal to summation from n. if startind: for i in reversed(range(startind)): if not term.subs(n, i): seriesdict[term] = i else: seriesdict[term] = i + 1 break else: seriesdict[term] = S(0) # Stripping of terms so that the sum starts with the same number. teq = S(0) suminit = seriesdict.values() rkeys = seriesdict.keys() req = Add(*rkeys) if any(suminit): maxval = max(suminit) for term in seriesdict: val = seriesdict[term] if val != maxval: for i in range(val, maxval): teq += term.subs(n, val) finaldict = {} if teq: fargs = teq.atoms(AppliedUndef) if len(fargs) == 1: finaldict[fargs.pop()] = 0 else: maxf = max(fargs, key = lambda x: x.args[0]) sol = solve(teq, maxf) if isinstance(sol, list): sol = sol[0] finaldict[maxf] = sol # Finding the recurrence relation in terms of the largest term. fargs = req.atoms(AppliedUndef) maxf = max(fargs, key = lambda x: x.args[0]) minf = min(fargs, key = lambda x: x.args[0]) if minf.args[0].is_Symbol: startiter = 0 else: startiter = -minf.args[0].as_independent(n)[0] lhs = maxf rhs = solve(req, maxf) if isinstance(rhs, list): rhs = rhs[0] # Checking how many values are already present tcounter = len([t for t in finaldict.values() if t]) for _ in range(tcounter, terms - 3): # Assuming c0 and c1 to be arbitrary check = rhs.subs(n, startiter) nlhs = lhs.subs(n, startiter) nrhs = check.subs(finaldict) finaldict[nlhs] = nrhs startiter += 1 # Post processing series = C0 + C1*(x - x0) for term in finaldict: if finaldict[term]: fact = term.args[0] series += (finaldict[term].subs([(recurr(0), C0), (recurr(1), C1)])*( x - x0)**fact) series = collect(expand_mul(series), [C0, C1]) + Order(x**terms) return Eq(f(x), series) def ode_2nd_power_series_regular(eq, func, order, match): r""" Gives a power series solution to a second order homogeneous differential equation with polynomial coefficients at a regular point. A second order homogenous differential equation is of the form .. math :: P(x)\frac{d^2y}{dx^2} + Q(x)\frac{dy}{dx} + R(x) = 0 A point is said to regular singular at `x0` if `x - x0\frac{Q(x)}{P(x)}` and `(x - x0)^{2}\frac{R(x)}{P(x)}` are analytic at `x0`. For simplicity `P(x)`, `Q(x)` and `R(x)` are assumed to be polynomials. The algorithm for finding the power series solutions is: 1. Try expressing `(x - x0)P(x)` and `((x - x0)^{2})Q(x)` as power series solutions about x0. Find `p0` and `q0` which are the constants of the power series expansions. 2. Solve the indicial equation `f(m) = m(m - 1) + m*p0 + q0`, to obtain the roots `m1` and `m2` of the indicial equation. 3. If `m1 - m2` is a non integer there exists two series solutions. If `m1 = m2`, there exists only one solution. If `m1 - m2` is an integer, then the existence of one solution is confirmed. The other solution may or may not exist. The power series solution is of the form `x^{m}\sum_{n=0}^\infty a_{n}x^{n}`. The coefficients are determined by the following recurrence relation. `a_{n} = -\frac{\sum_{k=0}^{n-1} q_{n-k} + (m + k)p_{n-k}}{f(m + n)}`. For the case in which `m1 - m2` is an integer, it can be seen from the recurrence relation that for the lower root `m`, when `n` equals the difference of both the roots, the denominator becomes zero. So if the numerator is not equal to zero, a second series solution exists. Examples ======== >>> from sympy import dsolve, Function, pprint >>> from sympy.abc import x, y >>> f = Function("f") >>> eq = x*(f(x).diff(x, 2)) + 2*(f(x).diff(x)) + x*f(x) >>> pprint(dsolve(eq)) / 6 4 2 \ | x x x | / 4 2 \ C1*|- --- + -- - -- + 1| | x x | \ 720 24 2 / / 6\ f(x) = C2*|--- - -- + 1| + ------------------------ + O\x / \120 6 / x References ========== - George E. Simmons, "Differential Equations with Applications and Historical Notes", p.p 176 - 184 """ x = func.args[0] f = func.func C0, C1 = get_numbered_constants(eq, num=2) m = Dummy("m") # for solving the indicial equation x0 = match.get('x0') terms = match.get('terms', 5) p = match['p'] q = match['q'] # Generating the indicial equation indicial = [] for term in [p, q]: if not term.has(x): indicial.append(term) else: term = series(term, n=1, x0=x0) if isinstance(term, Order): indicial.append(S(0)) else: for arg in term.args: if not arg.has(x): indicial.append(arg) break p0, q0 = indicial sollist = solve(m*(m - 1) + m*p0 + q0, m) if sollist and isinstance(sollist, list) and all( [sol.is_real for sol in sollist]): serdict1 = {} serdict2 = {} if len(sollist) == 1: # Only one series solution exists in this case. m1 = m2 = sollist.pop() if terms-m1-1 <= 0: return Eq(f(x), Order(terms)) serdict1 = _frobenius(terms-m1-1, m1, p0, q0, p, q, x0, x, C0) else: m1 = sollist[0] m2 = sollist[1] if m1 < m2: m1, m2 = m2, m1 # Irrespective of whether m1 - m2 is an integer or not, one # Frobenius series solution exists. serdict1 = _frobenius(terms-m1-1, m1, p0, q0, p, q, x0, x, C0) if not (m1 - m2).is_integer: # Second frobenius series solution exists. serdict2 = _frobenius(terms-m2-1, m2, p0, q0, p, q, x0, x, C1) else: # Check if second frobenius series solution exists. serdict2 = _frobenius(terms-m2-1, m2, p0, q0, p, q, x0, x, C1, check=m1) if serdict1: finalseries1 = C0 for key in serdict1: power = int(key.name[1:]) finalseries1 += serdict1[key]*(x - x0)**power finalseries1 = (x - x0)**m1*finalseries1 finalseries2 = S(0) if serdict2: for key in serdict2: power = int(key.name[1:]) finalseries2 += serdict2[key]*(x - x0)**power finalseries2 += C1 finalseries2 = (x - x0)**m2*finalseries2 return Eq(f(x), collect(finalseries1 + finalseries2, [C0, C1]) + Order(x**terms)) def _frobenius(n, m, p0, q0, p, q, x0, x, c, check=None): r""" Returns a dict with keys as coefficients and values as their values in terms of C0 """ n = int(n) # In cases where m1 - m2 is not an integer m2 = check d = Dummy("d") numsyms = numbered_symbols("C", start=0) numsyms = [next(numsyms) for i in range(n + 1)] serlist = [] for ser in [p, q]: # Order term not present if ser.is_polynomial(x) and Poly(ser, x).degree() <= n: if x0: ser = ser.subs(x, x + x0) dict_ = Poly(ser, x).as_dict() # Order term present else: tseries = series(ser, x=x0, n=n+1) # Removing order dict_ = Poly(list(ordered(tseries.args))[: -1], x).as_dict() # Fill in with zeros, if coefficients are zero. for i in range(n + 1): if (i,) not in dict_: dict_[(i,)] = S(0) serlist.append(dict_) pseries = serlist[0] qseries = serlist[1] indicial = d*(d - 1) + d*p0 + q0 frobdict = {} for i in range(1, n + 1): num = c*(m*pseries[(i,)] + qseries[(i,)]) for j in range(1, i): sym = Symbol("C" + str(j)) num += frobdict[sym]*((m + j)*pseries[(i - j,)] + qseries[(i - j,)]) # Checking for cases when m1 - m2 is an integer. If num equals zero # then a second Frobenius series solution cannot be found. If num is not zero # then set constant as zero and proceed. if m2 is not None and i == m2 - m: if num: return False else: frobdict[numsyms[i]] = S(0) else: frobdict[numsyms[i]] = -num/(indicial.subs(d, m+i)) return frobdict def _nth_order_reducible_match(eq, func): r""" Matches any differential equation that can be rewritten with a smaller order. Only derivatives of ``func`` alone, wrt a single variable, are considered, and only in them should ``func`` appear. """ # ODE only handles functions of 1 variable so this affirms that state assert len(func.args) == 1 x = func.args[0] vc = [d.variable_count[0] for d in eq.atoms(Derivative) if d.expr == func and len(d.variable_count) == 1] ords = [c for v, c in vc if v == x] if len(ords) < 2: return smallest = min(ords) # make sure func does not appear outside of derivatives D = Dummy() if eq.subs(func.diff(x, smallest), D).has(func): return return {'n': smallest} def ode_nth_order_reducible(eq, func, order, match): r""" Solves ODEs that only involve derivatives of the dependent variable using a substitution of the form `f^n(x) = g(x)`. For example any second order ODE of the form `f''(x) = h(f'(x), x)` can be transformed into a pair of 1st order ODEs `g'(x) = h(g(x), x)` and `f'(x) = g(x)`. Usually the 1st order ODE for `g` is easier to solve. If that gives an explicit solution for `g` then `f` is found simply by integration. Examples ======== >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> eq = Eq(x*f(x).diff(x)**2 + f(x).diff(x, 2)) >>> dsolve(eq, f(x), hint='nth_order_reducible') ... # doctest: +NORMALIZE_WHITESPACE Eq(f(x), C1 - sqrt(-1/C2)*log(-C2*sqrt(-1/C2) + x) + sqrt(-1/C2)*log(C2*sqrt(-1/C2) + x)) """ x = func.args[0] f = func.func n = match['n'] # get a unique function name for g names = [a.name for a in eq.atoms(AppliedUndef)] while True: name = Dummy().name if name not in names: g = Function(name) break w = f(x).diff(x, n) geq = eq.subs(w, g(x)) gsol = dsolve(geq, g(x)) if not isinstance(gsol, list): gsol = [gsol] # Might be multiple solutions to the reduced ODE: fsol = [] for gsoli in gsol: fsoli = dsolve(gsoli.subs(g(x), w), f(x)) # or do integration n times fsol.append(fsoli) if len(fsol) == 1: fsol = fsol[0] return fsol def _nth_algebraic_match(eq, func): r""" Matches any differential equation that nth_algebraic can solve. Uses `sympy.solve` but teaches it how to integrate derivatives. This involves calling `sympy.solve` and does most of the work of finding a solution (apart from evaluating the integrals). """ # Each integration should generate a different constant constants = iter_numbered_constants(eq) constant = lambda: next(constants, None) # Like Derivative but "invertible" class diffx(Function): def inverse(self): # We mustn't use integrate here because fx has been replaced by _t # in the equation so integrals will not be correct while solve is # still working. return lambda expr: Integral(expr, var) + constant() # Replace derivatives wrt the independent variable with diffx def replace(eq, var): def expand_diffx(*args): differand, diffs = args[0], args[1:] toreplace = differand for v, n in diffs: for _ in range(n): if v == var: toreplace = diffx(toreplace) else: toreplace = Derivative(toreplace, v) return toreplace return eq.replace(Derivative, expand_diffx) # Restore derivatives in solution afterwards def unreplace(eq, var): return eq.replace(diffx, lambda e: Derivative(e, var)) # The independent variable var = func.args[0] subs_eqn = replace(eq, var) try: # turn off simplification to protect Integrals that have # _t instead of fx in them and would otherwise factor # as t_*Integral(1, x) solns = solve(subs_eqn, func, simplify=False) except NotImplementedError: solns = [] solns = [simplify(unreplace(soln, var)) for soln in solns] solns = [Equality(func, soln) for soln in solns] return {'var':var, 'solutions':solns} def ode_nth_algebraic(eq, func, order, match): r""" Solves an `n`\th order ordinary differential equation using algebra and integrals. There is no general form for the kind of equation that this can solve. The the equation is solved algebraically treating differentiation as an invertible algebraic function. Examples ======== >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> eq = Eq(f(x) * (f(x).diff(x)**2 - 1), 0) >>> dsolve(eq, f(x), hint='nth_algebraic') ... # doctest: +NORMALIZE_WHITESPACE [Eq(f(x), 0), Eq(f(x), C1 - x), Eq(f(x), C1 + x)] Note that this solver can return algebraic solutions that do not have any integration constants (f(x) = 0 in the above example). # indirect doctest """ solns = match['solutions'] var = match['var'] solns = _nth_algebraic_remove_redundant_solutions(eq, solns, order, var) if len(solns) == 1: return solns[0] else: return solns # FIXME: Maybe something like this function should be applied to the solutions # returned by dsolve in general rather than just for nth_algebraic... def _nth_algebraic_remove_redundant_solutions(eq, solns, order, var): r""" Remove redundant solutions from the set of solutions returned by nth_algebraic. This function is needed because otherwise nth_algebraic can return redundant solutions where both algebraic solutions and integral solutions are found to the ODE. As an example consider: eq = Eq(f(x) * f(x).diff(x), 0) There are two ways to find solutions to eq. The first is the algebraic solution f(x)=0. The second is to solve the equation f(x).diff(x) = 0 leading to the solution f(x) = C1. In this particular case we then see that the first solution is a special case of the second and we don't want to return it. This does not always happen for algebraic solutions though since if we have eq = Eq(f(x)*(1 + f(x).diff(x)), 0) then we get the algebraic solution f(x) = 0 and the integral solution f(x) = -x + C1 and in this case the two solutions are not equivalent wrt initial conditions so both should be returned. """ def is_special_case_of(soln1, soln2): return _nth_algebraic_is_special_case_of(soln1, soln2, eq, order, var) unique_solns = [] for soln1 in solns: for soln2 in unique_solns[:]: if is_special_case_of(soln1, soln2): break elif is_special_case_of(soln2, soln1): unique_solns.remove(soln2) else: unique_solns.append(soln1) return unique_solns def _nth_algebraic_is_special_case_of(soln1, soln2, eq, order, var): r""" True if soln1 is found to be a special case of soln2 wrt some value of the constants that appear in soln2. False otherwise. """ # The solutions returned by nth_algebraic should be given explicitly as in # Eq(f(x), expr). We will equate the RHSs of the two solutions giving an # equation f1(x) = f2(x). # # Since this is supposed to hold for all x it also holds for derivatives # f1'(x) and f2'(x). For an order n ode we should be able to differentiate # each solution n times to get n+1 equations. # # We then try to solve those n+1 equations for the integrations constants # in f2(x). If we can find a solution that doesn't depend on x then it # means that some value of the constants in f1(x) is a special case of # f2(x) corresponding to a paritcular choice of the integration constants. constants1 = soln1.free_symbols.difference(eq.free_symbols) constants2 = soln2.free_symbols.difference(eq.free_symbols) constants1_new = get_numbered_constants(soln1.rhs - soln2.rhs, len(constants1)) if len(constants1) == 1: constants1_new = {constants1_new} for c_old, c_new in zip(constants1, constants1_new): soln1 = soln1.subs(c_old, c_new) # n equations for f1(x)=f2(x), f1'(x)=f2'(x), ... lhs = soln1.rhs.doit() rhs = soln2.rhs.doit() eqns = [Eq(lhs, rhs)] for n in range(1, order): lhs = lhs.diff(var) rhs = rhs.diff(var) eq = Eq(lhs, rhs) eqns.append(eq) # BooleanTrue/False awkwardly show up for trivial equations if any(isinstance(eq, BooleanFalse) for eq in eqns): return False eqns = [eq for eq in eqns if not isinstance(eq, BooleanTrue)] constant_solns = solve(eqns, constants2) # Sometimes returns a dict and sometimes a list of dicts if isinstance(constant_solns, dict): constant_solns = [constant_solns] # If any solution gives all constants as expressions that don't depend on # x then there exists constants for soln2 that give soln1 for constant_soln in constant_solns: if not any(c.has(var) for c in constant_soln.values()): return True return False def _nth_linear_match(eq, func, order): r""" Matches a differential equation to the linear form: .. math:: a_n(x) y^{(n)} + \cdots + a_1(x)y' + a_0(x) y + B(x) = 0 Returns a dict of order:coeff terms, where order is the order of the derivative on each term, and coeff is the coefficient of that derivative. The key ``-1`` holds the function `B(x)`. Returns ``None`` if the ODE is not linear. This function assumes that ``func`` has already been checked to be good. Examples ======== >>> from sympy import Function, cos, sin >>> from sympy.abc import x >>> from sympy.solvers.ode import _nth_linear_match >>> f = Function('f') >>> _nth_linear_match(f(x).diff(x, 3) + 2*f(x).diff(x) + ... x*f(x).diff(x, 2) + cos(x)*f(x).diff(x) + x - f(x) - ... sin(x), f(x), 3) {-1: x - sin(x), 0: -1, 1: cos(x) + 2, 2: x, 3: 1} >>> _nth_linear_match(f(x).diff(x, 3) + 2*f(x).diff(x) + ... x*f(x).diff(x, 2) + cos(x)*f(x).diff(x) + x - f(x) - ... sin(f(x)), f(x), 3) == None True """ x = func.args[0] one_x = {x} terms = {i: S.Zero for i in range(-1, order + 1)} for i in Add.make_args(eq): if not i.has(func): terms[-1] += i else: c, f = i.as_independent(func) if (isinstance(f, Derivative) and set(f.variables) == one_x and f.args[0] == func): terms[f.derivative_count] += c elif f == func: terms[len(f.args[1:])] += c else: return None return terms def ode_nth_linear_euler_eq_homogeneous(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear homogeneous variable-coefficient Cauchy-Euler equidimensional ordinary differential equation. This is an equation with form `0 = a_0 f(x) + a_1 x f'(x) + a_2 x^2 f''(x) \cdots`. These equations can be solved in a general manner, by substituting solutions of the form `f(x) = x^r`, and deriving a characteristic equation for `r`. When there are repeated roots, we include extra terms of the form `C_{r k} \ln^k(x) x^r`, where `C_{r k}` is an arbitrary integration constant, `r` is a root of the characteristic equation, and `k` ranges over the multiplicity of `r`. In the cases where the roots are complex, solutions of the form `C_1 x^a \sin(b \log(x)) + C_2 x^a \cos(b \log(x))` are returned, based on expansions with Euler's formula. The general solution is the sum of the terms found. If SymPy cannot find exact roots to the characteristic equation, a :py:class:`~sympy.polys.rootoftools.CRootOf` instance will be returned instead. >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(4*x**2*f(x).diff(x, 2) + f(x), f(x), ... hint='nth_linear_euler_eq_homogeneous') ... # doctest: +NORMALIZE_WHITESPACE Eq(f(x), sqrt(x)*(C1 + C2*log(x))) Note that because this method does not involve integration, there is no ``nth_linear_euler_eq_homogeneous_Integral`` hint. The following is for internal use: - ``returns = 'sol'`` returns the solution to the ODE. - ``returns = 'list'`` returns a list of linearly independent solutions, corresponding to the fundamental solution set, for use with non homogeneous solution methods like variation of parameters and undetermined coefficients. Note that, though the solutions should be linearly independent, this function does not explicitly check that. You can do ``assert simplify(wronskian(sollist)) != 0`` to check for linear independence. Also, ``assert len(sollist) == order`` will need to pass. - ``returns = 'both'``, return a dictionary ``{'sol': <solution to ODE>, 'list': <list of linearly independent solutions>}``. Examples ======== >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f = Function('f') >>> eq = f(x).diff(x, 2)*x**2 - 4*f(x).diff(x)*x + 6*f(x) >>> pprint(dsolve(eq, f(x), ... hint='nth_linear_euler_eq_homogeneous')) 2 f(x) = x *(C1 + C2*x) References ========== - https://en.wikipedia.org/wiki/Cauchy%E2%80%93Euler_equation - C. Bender & S. Orszag, "Advanced Mathematical Methods for Scientists and Engineers", Springer 1999, pp. 12 # indirect doctest """ global collectterms collectterms = [] x = func.args[0] f = func.func r = match # First, set up characteristic equation. chareq, symbol = S.Zero, Dummy('x') for i in r.keys(): if not isinstance(i, string_types) and i >= 0: chareq += (r[i]*diff(x**symbol, x, i)*x**-symbol).expand() chareq = Poly(chareq, symbol) chareqroots = [rootof(chareq, k) for k in range(chareq.degree())] # A generator of constants constants = list(get_numbered_constants(eq, num=chareq.degree()*2)) constants.reverse() # Create a dict root: multiplicity or charroots charroots = defaultdict(int) for root in chareqroots: charroots[root] += 1 gsol = S(0) # We need keep track of terms so we can run collect() at the end. # This is necessary for constantsimp to work properly. ln = log for root, multiplicity in charroots.items(): for i in range(multiplicity): if isinstance(root, RootOf): gsol += (x**root) * constants.pop() if multiplicity != 1: raise ValueError("Value should be 1") collectterms = [(0, root, 0)] + collectterms elif root.is_real: gsol += ln(x)**i*(x**root) * constants.pop() collectterms = [(i, root, 0)] + collectterms else: reroot = re(root) imroot = im(root) gsol += ln(x)**i * (x**reroot) * ( constants.pop() * sin(abs(imroot)*ln(x)) + constants.pop() * cos(imroot*ln(x))) # Preserve ordering (multiplicity, real part, imaginary part) # It will be assumed implicitly when constructing # fundamental solution sets. collectterms = [(i, reroot, imroot)] + collectterms if returns == 'sol': return Eq(f(x), gsol) elif returns in ('list' 'both'): # HOW TO TEST THIS CODE? (dsolve does not pass 'returns' through) # Create a list of (hopefully) linearly independent solutions gensols = [] # Keep track of when to use sin or cos for nonzero imroot for i, reroot, imroot in collectterms: if imroot == 0: gensols.append(ln(x)**i*x**reroot) else: sin_form = ln(x)**i*x**reroot*sin(abs(imroot)*ln(x)) if sin_form in gensols: cos_form = ln(x)**i*x**reroot*cos(imroot*ln(x)) gensols.append(cos_form) else: gensols.append(sin_form) if returns == 'list': return gensols else: return {'sol': Eq(f(x), gsol), 'list': gensols} else: raise ValueError('Unknown value for key "returns".') def ode_nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear non homogeneous Cauchy-Euler equidimensional ordinary differential equation using undetermined coefficients. This is an equation with form `g(x) = a_0 f(x) + a_1 x f'(x) + a_2 x^2 f''(x) \cdots`. These equations can be solved in a general manner, by substituting solutions of the form `x = exp(t)`, and deriving a characteristic equation of form `g(exp(t)) = b_0 f(t) + b_1 f'(t) + b_2 f''(t) \cdots` which can be then solved by nth_linear_constant_coeff_undetermined_coefficients if g(exp(t)) has finite number of linearly independent derivatives. Functions that fit this requirement are finite sums functions of the form `a x^i e^{b x} \sin(c x + d)` or `a x^i e^{b x} \cos(c x + d)`, where `i` is a non-negative integer and `a`, `b`, `c`, and `d` are constants. For example any polynomial in `x`, functions like `x^2 e^{2 x}`, `x \sin(x)`, and `e^x \cos(x)` can all be used. Products of `\sin`'s and `\cos`'s have a finite number of derivatives, because they can be expanded into `\sin(a x)` and `\cos(b x)` terms. However, SymPy currently cannot do that expansion, so you will need to manually rewrite the expression in terms of the above to use this method. So, for example, you will need to manually convert `\sin^2(x)` into `(1 + \cos(2 x))/2` to properly apply the method of undetermined coefficients on it. After replacement of x by exp(t), this method works by creating a trial function from the expression and all of its linear independent derivatives and substituting them into the original ODE. The coefficients for each term will be a system of linear equations, which are be solved for and substituted, giving the solution. If any of the trial functions are linearly dependent on the solution to the homogeneous equation, they are multiplied by sufficient `x` to make them linearly independent. Examples ======== >>> from sympy import dsolve, Function, Derivative, log >>> from sympy.abc import x >>> f = Function('f') >>> eq = x**2*Derivative(f(x), x, x) - 2*x*Derivative(f(x), x) + 2*f(x) - log(x) >>> dsolve(eq, f(x), ... hint='nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients').expand() Eq(f(x), C1*x + C2*x**2 + log(x)/2 + 3/4) """ x = func.args[0] f = func.func r = match chareq, eq, symbol = S.Zero, S.Zero, Dummy('x') for i in r.keys(): if not isinstance(i, string_types) and i >= 0: chareq += (r[i]*diff(x**symbol, x, i)*x**-symbol).expand() for i in range(1,degree(Poly(chareq, symbol))+1): eq += chareq.coeff(symbol**i)*diff(f(x), x, i) if chareq.as_coeff_add(symbol)[0]: eq += chareq.as_coeff_add(symbol)[0]*f(x) e, re = posify(r[-1].subs(x, exp(x))) eq += e.subs(re) match = _nth_linear_match(eq, f(x), ode_order(eq, f(x))) match['trialset'] = r['trialset'] return ode_nth_linear_constant_coeff_undetermined_coefficients(eq, func, order, match).subs(x, log(x)).subs(f(log(x)), f(x)).expand() def ode_nth_linear_euler_eq_nonhomogeneous_variation_of_parameters(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear non homogeneous Cauchy-Euler equidimensional ordinary differential equation using variation of parameters. This is an equation with form `g(x) = a_0 f(x) + a_1 x f'(x) + a_2 x^2 f''(x) \cdots`. This method works by assuming that the particular solution takes the form .. math:: \sum_{x=1}^{n} c_i(x) y_i(x) {a_n} {x^n} \text{,} where `y_i` is the `i`\th solution to the homogeneous equation. The solution is then solved using Wronskian's and Cramer's Rule. The particular solution is given by multiplying eq given below with `a_n x^{n}` .. math:: \sum_{x=1}^n \left( \int \frac{W_i(x)}{W(x)} \,dx \right) y_i(x) \text{,} where `W(x)` is the Wronskian of the fundamental system (the system of `n` linearly independent solutions to the homogeneous equation), and `W_i(x)` is the Wronskian of the fundamental system with the `i`\th column replaced with `[0, 0, \cdots, 0, \frac{x^{- n}}{a_n} g{\left(x \right)}]`. This method is general enough to solve any `n`\th order inhomogeneous linear differential equation, but sometimes SymPy cannot simplify the Wronskian well enough to integrate it. If this method hangs, try using the ``nth_linear_constant_coeff_variation_of_parameters_Integral`` hint and simplifying the integrals manually. Also, prefer using ``nth_linear_constant_coeff_undetermined_coefficients`` when it applies, because it doesn't use integration, making it faster and more reliable. Warning, using simplify=False with 'nth_linear_constant_coeff_variation_of_parameters' in :py:meth:`~sympy.solvers.ode.dsolve` may cause it to hang, because it will not attempt to simplify the Wronskian before integrating. It is recommended that you only use simplify=False with 'nth_linear_constant_coeff_variation_of_parameters_Integral' for this method, especially if the solution to the homogeneous equation has trigonometric functions in it. Examples ======== >>> from sympy import Function, dsolve, Derivative >>> from sympy.abc import x >>> f = Function('f') >>> eq = x**2*Derivative(f(x), x, x) - 2*x*Derivative(f(x), x) + 2*f(x) - x**4 >>> dsolve(eq, f(x), ... hint='nth_linear_euler_eq_nonhomogeneous_variation_of_parameters').expand() Eq(f(x), C1*x + C2*x**2 + x**4/6) """ x = func.args[0] f = func.func r = match gensol = ode_nth_linear_euler_eq_homogeneous(eq, func, order, match, returns='both') match.update(gensol) r[-1] = r[-1]/r[ode_order(eq, f(x))] sol = _solve_variation_of_parameters(eq, func, order, match) return Eq(f(x), r['sol'].rhs + (sol.rhs - r['sol'].rhs)*r[ode_order(eq, f(x))]) def ode_almost_linear(eq, func, order, match): r""" Solves an almost-linear differential equation. The general form of an almost linear differential equation is .. math:: f(x) g(y) y + k(x) l(y) + m(x) = 0 \text{where} l'(y) = g(y)\text{.} This can be solved by substituting `l(y) = u(y)`. Making the given substitution reduces it to a linear differential equation of the form `u' + P(x) u + Q(x) = 0`. The general solution is >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x, y, n >>> f, g, k, l = map(Function, ['f', 'g', 'k', 'l']) >>> genform = Eq(f(x)*(l(y).diff(y)) + k(x)*l(y) + g(x), 0) >>> pprint(genform) d f(x)*--(l(y)) + g(x) + k(x)*l(y) = 0 dy >>> pprint(dsolve(genform, hint = 'almost_linear')) / // y*k(x) \\ | || ------ || | || f(x) || -y*k(x) | ||-g(x)*e || -------- | ||-------------- for k(x) != 0|| f(x) l(y) = |C1 + |< k(x) ||*e | || || | || -y*g(x) || | || -------- otherwise || | || f(x) || \ \\ // See Also ======== :meth:`sympy.solvers.ode.ode_1st_linear` Examples ======== >>> from sympy import Function, Derivative, pprint >>> from sympy.solvers.ode import dsolve, classify_ode >>> from sympy.abc import x >>> f = Function('f') >>> d = f(x).diff(x) >>> eq = x*d + x*f(x) + 1 >>> dsolve(eq, f(x), hint='almost_linear') Eq(f(x), (C1 - Ei(x))*exp(-x)) >>> pprint(dsolve(eq, f(x), hint='almost_linear')) -x f(x) = (C1 - Ei(x))*e References ========== - Joel Moses, "Symbolic Integration - The Stormy Decade", Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 """ # Since ode_1st_linear has already been implemented, and the # coefficients have been modified to the required form in # classify_ode, just passing eq, func, order and match to # ode_1st_linear will give the required output. return ode_1st_linear(eq, func, order, match) def _linear_coeff_match(expr, func): r""" Helper function to match hint ``linear_coefficients``. Matches the expression to the form `(a_1 x + b_1 f(x) + c_1)/(a_2 x + b_2 f(x) + c_2)` where the following conditions hold: 1. `a_1`, `b_1`, `c_1`, `a_2`, `b_2`, `c_2` are Rationals; 2. `c_1` or `c_2` are not equal to zero; 3. `a_2 b_1 - a_1 b_2` is not equal to zero. Return ``xarg``, ``yarg`` where 1. ``xarg`` = `(b_2 c_1 - b_1 c_2)/(a_2 b_1 - a_1 b_2)` 2. ``yarg`` = `(a_1 c_2 - a_2 c_1)/(a_2 b_1 - a_1 b_2)` Examples ======== >>> from sympy import Function >>> from sympy.abc import x >>> from sympy.solvers.ode import _linear_coeff_match >>> from sympy.functions.elementary.trigonometric import sin >>> f = Function('f') >>> _linear_coeff_match(( ... (-25*f(x) - 8*x + 62)/(4*f(x) + 11*x - 11)), f(x)) (1/9, 22/9) >>> _linear_coeff_match( ... sin((-5*f(x) - 8*x + 6)/(4*f(x) + x - 1)), f(x)) (19/27, 2/27) >>> _linear_coeff_match(sin(f(x)/x), f(x)) """ f = func.func x = func.args[0] def abc(eq): r''' Internal function of _linear_coeff_match that returns Rationals a, b, c if eq is a*x + b*f(x) + c, else None. ''' eq = _mexpand(eq) c = eq.as_independent(x, f(x), as_Add=True)[0] if not c.is_Rational: return a = eq.coeff(x) if not a.is_Rational: return b = eq.coeff(f(x)) if not b.is_Rational: return if eq == a*x + b*f(x) + c: return a, b, c def match(arg): r''' Internal function of _linear_coeff_match that returns Rationals a1, b1, c1, a2, b2, c2 and a2*b1 - a1*b2 of the expression (a1*x + b1*f(x) + c1)/(a2*x + b2*f(x) + c2) if one of c1 or c2 and a2*b1 - a1*b2 is non-zero, else None. ''' n, d = arg.together().as_numer_denom() m = abc(n) if m is not None: a1, b1, c1 = m m = abc(d) if m is not None: a2, b2, c2 = m d = a2*b1 - a1*b2 if (c1 or c2) and d: return a1, b1, c1, a2, b2, c2, d m = [fi.args[0] for fi in expr.atoms(Function) if fi.func != f and len(fi.args) == 1 and not fi.args[0].is_Function] or {expr} m1 = match(m.pop()) if m1 and all(match(mi) == m1 for mi in m): a1, b1, c1, a2, b2, c2, denom = m1 return (b2*c1 - b1*c2)/denom, (a1*c2 - a2*c1)/denom def ode_linear_coefficients(eq, func, order, match): r""" Solves a differential equation with linear coefficients. The general form of a differential equation with linear coefficients is .. math:: y' + F\left(\!\frac{a_1 x + b_1 y + c_1}{a_2 x + b_2 y + c_2}\!\right) = 0\text{,} where `a_1`, `b_1`, `c_1`, `a_2`, `b_2`, `c_2` are constants and `a_1 b_2 - a_2 b_1 \ne 0`. This can be solved by substituting: .. math:: x = x' + \frac{b_2 c_1 - b_1 c_2}{a_2 b_1 - a_1 b_2} y = y' + \frac{a_1 c_2 - a_2 c_1}{a_2 b_1 - a_1 b_2}\text{.} This substitution reduces the equation to a homogeneous differential equation. See Also ======== :meth:`sympy.solvers.ode.ode_1st_homogeneous_coeff_best` :meth:`sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_indep_div_dep` :meth:`sympy.solvers.ode.ode_1st_homogeneous_coeff_subs_dep_div_indep` Examples ======== >>> from sympy import Function, Derivative, pprint >>> from sympy.solvers.ode import dsolve, classify_ode >>> from sympy.abc import x >>> f = Function('f') >>> df = f(x).diff(x) >>> eq = (x + f(x) + 1)*df + (f(x) - 6*x + 1) >>> dsolve(eq, hint='linear_coefficients') [Eq(f(x), -x - sqrt(C1 + 7*x**2) - 1), Eq(f(x), -x + sqrt(C1 + 7*x**2) - 1)] >>> pprint(dsolve(eq, hint='linear_coefficients')) ___________ ___________ / 2 / 2 [f(x) = -x - \/ C1 + 7*x - 1, f(x) = -x + \/ C1 + 7*x - 1] References ========== - Joel Moses, "Symbolic Integration - The Stormy Decade", Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 """ return ode_1st_homogeneous_coeff_best(eq, func, order, match) def ode_separable_reduced(eq, func, order, match): r""" Solves a differential equation that can be reduced to the separable form. The general form of this equation is .. math:: y' + (y/x) H(x^n y) = 0\text{}. This can be solved by substituting `u(y) = x^n y`. The equation then reduces to the separable form `\frac{u'}{u (\mathrm{power} - H(u))} - \frac{1}{x} = 0`. The general solution is: >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x, n >>> f, g = map(Function, ['f', 'g']) >>> genform = f(x).diff(x) + (f(x)/x)*g(x**n*f(x)) >>> pprint(genform) / n \ d f(x)*g\x *f(x)/ --(f(x)) + --------------- dx x >>> pprint(dsolve(genform, hint='separable_reduced')) n x *f(x) / | | 1 | ------------ dy = C1 + log(x) | y*(n - g(y)) | / See Also ======== :meth:`sympy.solvers.ode.ode_separable` Examples ======== >>> from sympy import Function, Derivative, pprint >>> from sympy.solvers.ode import dsolve, classify_ode >>> from sympy.abc import x >>> f = Function('f') >>> d = f(x).diff(x) >>> eq = (x - x**2*f(x))*d - f(x) >>> dsolve(eq, hint='separable_reduced') [Eq(f(x), (1 - sqrt(C1*x**2 + 1))/x), Eq(f(x), (sqrt(C1*x**2 + 1) + 1)/x)] >>> pprint(dsolve(eq, hint='separable_reduced')) ___________ ___________ / 2 / 2 1 - \/ C1*x + 1 \/ C1*x + 1 + 1 [f(x) = ------------------, f(x) = ------------------] x x References ========== - Joel Moses, "Symbolic Integration - The Stormy Decade", Communications of the ACM, Volume 14, Number 8, August 1971, pp. 558 """ # Arguments are passed in a way so that they are coherent with the # ode_separable function x = func.args[0] f = func.func y = Dummy('y') u = match['u'].subs(match['t'], y) ycoeff = 1/(y*(match['power'] - u)) m1 = {y: 1, x: -1/x, 'coeff': 1} m2 = {y: ycoeff, x: 1, 'coeff': 1} r = {'m1': m1, 'm2': m2, 'y': y, 'hint': x**match['power']*f(x)} return ode_separable(eq, func, order, r) def ode_1st_power_series(eq, func, order, match): r""" The power series solution is a method which gives the Taylor series expansion to the solution of a differential equation. For a first order differential equation `\frac{dy}{dx} = h(x, y)`, a power series solution exists at a point `x = x_{0}` if `h(x, y)` is analytic at `x_{0}`. The solution is given by .. math:: y(x) = y(x_{0}) + \sum_{n = 1}^{\infty} \frac{F_{n}(x_{0},b)(x - x_{0})^n}{n!}, where `y(x_{0}) = b` is the value of y at the initial value of `x_{0}`. To compute the values of the `F_{n}(x_{0},b)` the following algorithm is followed, until the required number of terms are generated. 1. `F_1 = h(x_{0}, b)` 2. `F_{n+1} = \frac{\partial F_{n}}{\partial x} + \frac{\partial F_{n}}{\partial y}F_{1}` Examples ======== >>> from sympy import Function, Derivative, pprint, exp >>> from sympy.solvers.ode import dsolve >>> from sympy.abc import x >>> f = Function('f') >>> eq = exp(x)*(f(x).diff(x)) - f(x) >>> pprint(dsolve(eq, hint='1st_power_series')) 3 4 5 C1*x C1*x C1*x / 6\ f(x) = C1 + C1*x - ----- + ----- + ----- + O\x / 6 24 60 References ========== - Travis W. Walker, Analytic power series technique for solving first-order differential equations, p.p 17, 18 """ x = func.args[0] y = match['y'] f = func.func h = -match[match['d']]/match[match['e']] point = match.get('f0') value = match.get('f0val') terms = match.get('terms') # First term F = h if not h: return Eq(f(x), value) # Initialization series = value if terms > 1: hc = h.subs({x: point, y: value}) if hc.has(oo) or hc.has(NaN) or hc.has(zoo): # Derivative does not exist, not analytic return Eq(f(x), oo) elif hc: series += hc*(x - point) for factcount in range(2, terms): Fnew = F.diff(x) + F.diff(y)*h Fnewc = Fnew.subs({x: point, y: value}) # Same logic as above if Fnewc.has(oo) or Fnewc.has(NaN) or Fnewc.has(-oo) or Fnewc.has(zoo): return Eq(f(x), oo) series += Fnewc*((x - point)**factcount)/factorial(factcount) F = Fnew series += Order(x**terms) return Eq(f(x), series) def ode_nth_linear_constant_coeff_homogeneous(eq, func, order, match, returns='sol'): r""" Solves an `n`\th order linear homogeneous differential equation with constant coefficients. This is an equation of the form .. math:: a_n f^{(n)}(x) + a_{n-1} f^{(n-1)}(x) + \cdots + a_1 f'(x) + a_0 f(x) = 0\text{.} These equations can be solved in a general manner, by taking the roots of the characteristic equation `a_n m^n + a_{n-1} m^{n-1} + \cdots + a_1 m + a_0 = 0`. The solution will then be the sum of `C_n x^i e^{r x}` terms, for each where `C_n` is an arbitrary constant, `r` is a root of the characteristic equation and `i` is one of each from 0 to the multiplicity of the root - 1 (for example, a root 3 of multiplicity 2 would create the terms `C_1 e^{3 x} + C_2 x e^{3 x}`). The exponential is usually expanded for complex roots using Euler's equation `e^{I x} = \cos(x) + I \sin(x)`. Complex roots always come in conjugate pairs in polynomials with real coefficients, so the two roots will be represented (after simplifying the constants) as `e^{a x} \left(C_1 \cos(b x) + C_2 \sin(b x)\right)`. If SymPy cannot find exact roots to the characteristic equation, a :py:class:`~sympy.polys.rootoftools.CRootOf` instance will be return instead. >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> dsolve(f(x).diff(x, 5) + 10*f(x).diff(x) - 2*f(x), f(x), ... hint='nth_linear_constant_coeff_homogeneous') ... # doctest: +NORMALIZE_WHITESPACE Eq(f(x), C5*exp(x*CRootOf(_x**5 + 10*_x - 2, 0)) + (C1*sin(x*im(CRootOf(_x**5 + 10*_x - 2, 1))) + C2*cos(x*im(CRootOf(_x**5 + 10*_x - 2, 1))))*exp(x*re(CRootOf(_x**5 + 10*_x - 2, 1))) + (C3*sin(x*im(CRootOf(_x**5 + 10*_x - 2, 3))) + C4*cos(x*im(CRootOf(_x**5 + 10*_x - 2, 3))))*exp(x*re(CRootOf(_x**5 + 10*_x - 2, 3)))) Note that because this method does not involve integration, there is no ``nth_linear_constant_coeff_homogeneous_Integral`` hint. The following is for internal use: - ``returns = 'sol'`` returns the solution to the ODE. - ``returns = 'list'`` returns a list of linearly independent solutions, for use with non homogeneous solution methods like variation of parameters and undetermined coefficients. Note that, though the solutions should be linearly independent, this function does not explicitly check that. You can do ``assert simplify(wronskian(sollist)) != 0`` to check for linear independence. Also, ``assert len(sollist) == order`` will need to pass. - ``returns = 'both'``, return a dictionary ``{'sol': <solution to ODE>, 'list': <list of linearly independent solutions>}``. Examples ======== >>> from sympy import Function, dsolve, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x, 4) + 2*f(x).diff(x, 3) - ... 2*f(x).diff(x, 2) - 6*f(x).diff(x) + 5*f(x), f(x), ... hint='nth_linear_constant_coeff_homogeneous')) x -2*x f(x) = (C1 + C2*x)*e + (C3*sin(x) + C4*cos(x))*e References ========== - https://en.wikipedia.org/wiki/Linear_differential_equation section: Nonhomogeneous_equation_with_constant_coefficients - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 211 # indirect doctest """ x = func.args[0] f = func.func r = match # First, set up characteristic equation. chareq, symbol = S.Zero, Dummy('x') for i in r.keys(): if type(i) == str or i < 0: pass else: chareq += r[i]*symbol**i chareq = Poly(chareq, symbol) # Can't just call roots because it doesn't return rootof for unsolveable # polynomials. chareqroots = roots(chareq, multiple=True) if len(chareqroots) != order: chareqroots = [rootof(chareq, k) for k in range(chareq.degree())] chareq_is_complex = not all([i.is_real for i in chareq.all_coeffs()]) # A generator of constants constants = list(get_numbered_constants(eq, num=chareq.degree()*2)) # Create a dict root: multiplicity or charroots charroots = defaultdict(int) for root in chareqroots: charroots[root] += 1 # We need to keep track of terms so we can run collect() at the end. # This is necessary for constantsimp to work properly. global collectterms collectterms = [] gensols = [] conjugate_roots = [] # used to prevent double-use of conjugate roots # Loop over roots in theorder provided by roots/rootof... for root in chareqroots: # but don't repoeat multiple roots. if root not in charroots: continue multiplicity = charroots.pop(root) for i in range(multiplicity): if chareq_is_complex: gensols.append(x**i*exp(root*x)) collectterms = [(i, root, 0)] + collectterms continue reroot = re(root) imroot = im(root) if imroot.has(atan2) and reroot.has(atan2): # Remove this condition when re and im stop returning # circular atan2 usages. gensols.append(x**i*exp(root*x)) collectterms = [(i, root, 0)] + collectterms else: if root in conjugate_roots: collectterms = [(i, reroot, imroot)] + collectterms continue if imroot == 0: gensols.append(x**i*exp(reroot*x)) collectterms = [(i, reroot, 0)] + collectterms continue conjugate_roots.append(conjugate(root)) gensols.append(x**i*exp(reroot*x) * sin(abs(imroot) * x)) gensols.append(x**i*exp(reroot*x) * cos( imroot * x)) # This ordering is important collectterms = [(i, reroot, imroot)] + collectterms if returns == 'list': return gensols elif returns in ('sol' 'both'): gsol = Add(*[i*j for (i, j) in zip(constants, gensols)]) if returns == 'sol': return Eq(f(x), gsol) else: return {'sol': Eq(f(x), gsol), 'list': gensols} else: raise ValueError('Unknown value for key "returns".') def ode_nth_linear_constant_coeff_undetermined_coefficients(eq, func, order, match): r""" Solves an `n`\th order linear differential equation with constant coefficients using the method of undetermined coefficients. This method works on differential equations of the form .. math:: a_n f^{(n)}(x) + a_{n-1} f^{(n-1)}(x) + \cdots + a_1 f'(x) + a_0 f(x) = P(x)\text{,} where `P(x)` is a function that has a finite number of linearly independent derivatives. Functions that fit this requirement are finite sums functions of the form `a x^i e^{b x} \sin(c x + d)` or `a x^i e^{b x} \cos(c x + d)`, where `i` is a non-negative integer and `a`, `b`, `c`, and `d` are constants. For example any polynomial in `x`, functions like `x^2 e^{2 x}`, `x \sin(x)`, and `e^x \cos(x)` can all be used. Products of `\sin`'s and `\cos`'s have a finite number of derivatives, because they can be expanded into `\sin(a x)` and `\cos(b x)` terms. However, SymPy currently cannot do that expansion, so you will need to manually rewrite the expression in terms of the above to use this method. So, for example, you will need to manually convert `\sin^2(x)` into `(1 + \cos(2 x))/2` to properly apply the method of undetermined coefficients on it. This method works by creating a trial function from the expression and all of its linear independent derivatives and substituting them into the original ODE. The coefficients for each term will be a system of linear equations, which are be solved for and substituted, giving the solution. If any of the trial functions are linearly dependent on the solution to the homogeneous equation, they are multiplied by sufficient `x` to make them linearly independent. Examples ======== >>> from sympy import Function, dsolve, pprint, exp, cos >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x, 2) + 2*f(x).diff(x) + f(x) - ... 4*exp(-x)*x**2 + cos(2*x), f(x), ... hint='nth_linear_constant_coeff_undetermined_coefficients')) / 4\ | x | -x 4*sin(2*x) 3*cos(2*x) f(x) = |C1 + C2*x + --|*e - ---------- + ---------- \ 3 / 25 25 References ========== - https://en.wikipedia.org/wiki/Method_of_undetermined_coefficients - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 221 # indirect doctest """ gensol = ode_nth_linear_constant_coeff_homogeneous(eq, func, order, match, returns='both') match.update(gensol) return _solve_undetermined_coefficients(eq, func, order, match) def _solve_undetermined_coefficients(eq, func, order, match): r""" Helper function for the method of undetermined coefficients. See the :py:meth:`~sympy.solvers.ode.ode_nth_linear_constant_coeff_undetermined_coefficients` docstring for more information on this method. The parameter ``match`` should be a dictionary that has the following keys: ``list`` A list of solutions to the homogeneous equation, such as the list returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='list')``. ``sol`` The general solution, such as the solution returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='sol')``. ``trialset`` The set of trial functions as returned by ``_undetermined_coefficients_match()['trialset']``. """ x = func.args[0] f = func.func r = match coeffs = numbered_symbols('a', cls=Dummy) coefflist = [] gensols = r['list'] gsol = r['sol'] trialset = r['trialset'] notneedset = set([]) global collectterms if len(gensols) != order: raise NotImplementedError("Cannot find " + str(order) + " solutions to the homogeneous equation necessary to apply" + " undetermined coefficients to " + str(eq) + " (number of terms != order)") usedsin = set([]) mult = 0 # The multiplicity of the root getmult = True for i, reroot, imroot in collectterms: if getmult: mult = i + 1 getmult = False if i == 0: getmult = True if imroot: # Alternate between sin and cos if (i, reroot) in usedsin: check = x**i*exp(reroot*x)*cos(imroot*x) else: check = x**i*exp(reroot*x)*sin(abs(imroot)*x) usedsin.add((i, reroot)) else: check = x**i*exp(reroot*x) if check in trialset: # If an element of the trial function is already part of the # homogeneous solution, we need to multiply by sufficient x to # make it linearly independent. We also don't need to bother # checking for the coefficients on those elements, since we # already know it will be 0. while True: if check*x**mult in trialset: mult += 1 else: break trialset.add(check*x**mult) notneedset.add(check) newtrialset = trialset - notneedset trialfunc = 0 for i in newtrialset: c = next(coeffs) coefflist.append(c) trialfunc += c*i eqs = sub_func_doit(eq, f(x), trialfunc) coeffsdict = dict(list(zip(trialset, [0]*(len(trialset) + 1)))) eqs = _mexpand(eqs) for i in Add.make_args(eqs): s = separatevars(i, dict=True, symbols=[x]) coeffsdict[s[x]] += s['coeff'] coeffvals = solve(list(coeffsdict.values()), coefflist) if not coeffvals: raise NotImplementedError( "Could not solve `%s` using the " "method of undetermined coefficients " "(unable to solve for coefficients)." % eq) psol = trialfunc.subs(coeffvals) return Eq(f(x), gsol.rhs + psol) def _undetermined_coefficients_match(expr, x): r""" Returns a trial function match if undetermined coefficients can be applied to ``expr``, and ``None`` otherwise. A trial expression can be found for an expression for use with the method of undetermined coefficients if the expression is an additive/multiplicative combination of constants, polynomials in `x` (the independent variable of expr), `\sin(a x + b)`, `\cos(a x + b)`, and `e^{a x}` terms (in other words, it has a finite number of linearly independent derivatives). Note that you may still need to multiply each term returned here by sufficient `x` to make it linearly independent with the solutions to the homogeneous equation. This is intended for internal use by ``undetermined_coefficients`` hints. SymPy currently has no way to convert `\sin^n(x) \cos^m(y)` into a sum of only `\sin(a x)` and `\cos(b x)` terms, so these are not implemented. So, for example, you will need to manually convert `\sin^2(x)` into `[1 + \cos(2 x)]/2` to properly apply the method of undetermined coefficients on it. Examples ======== >>> from sympy import log, exp >>> from sympy.solvers.ode import _undetermined_coefficients_match >>> from sympy.abc import x >>> _undetermined_coefficients_match(9*x*exp(x) + exp(-x), x) {'test': True, 'trialset': {x*exp(x), exp(-x), exp(x)}} >>> _undetermined_coefficients_match(log(x), x) {'test': False} """ a = Wild('a', exclude=[x]) b = Wild('b', exclude=[x]) expr = powsimp(expr, combine='exp') # exp(x)*exp(2*x + 1) => exp(3*x + 1) retdict = {} def _test_term(expr, x): r""" Test if ``expr`` fits the proper form for undetermined coefficients. """ if not expr.has(x): return True elif expr.is_Add: return all(_test_term(i, x) for i in expr.args) elif expr.is_Mul: if expr.has(sin, cos): foundtrig = False # Make sure that there is only one trig function in the args. # See the docstring. for i in expr.args: if i.has(sin, cos): if foundtrig: return False else: foundtrig = True return all(_test_term(i, x) for i in expr.args) elif expr.is_Function: if expr.func in (sin, cos, exp): if expr.args[0].match(a*x + b): return True else: return False else: return False elif expr.is_Pow and expr.base.is_Symbol and expr.exp.is_Integer and \ expr.exp >= 0: return True elif expr.is_Pow and expr.base.is_number: if expr.exp.match(a*x + b): return True else: return False elif expr.is_Symbol or expr.is_number: return True else: return False def _get_trial_set(expr, x, exprs=set([])): r""" Returns a set of trial terms for undetermined coefficients. The idea behind undetermined coefficients is that the terms expression repeat themselves after a finite number of derivatives, except for the coefficients (they are linearly dependent). So if we collect these, we should have the terms of our trial function. """ def _remove_coefficient(expr, x): r""" Returns the expression without a coefficient. Similar to expr.as_independent(x)[1], except it only works multiplicatively. """ term = S.One if expr.is_Mul: for i in expr.args: if i.has(x): term *= i elif expr.has(x): term = expr return term expr = expand_mul(expr) if expr.is_Add: for term in expr.args: if _remove_coefficient(term, x) in exprs: pass else: exprs.add(_remove_coefficient(term, x)) exprs = exprs.union(_get_trial_set(term, x, exprs)) else: term = _remove_coefficient(expr, x) tmpset = exprs.union({term}) oldset = set([]) while tmpset != oldset: # If you get stuck in this loop, then _test_term is probably # broken oldset = tmpset.copy() expr = expr.diff(x) term = _remove_coefficient(expr, x) if term.is_Add: tmpset = tmpset.union(_get_trial_set(term, x, tmpset)) else: tmpset.add(term) exprs = tmpset return exprs retdict['test'] = _test_term(expr, x) if retdict['test']: # Try to generate a list of trial solutions that will have the # undetermined coefficients. Note that if any of these are not linearly # independent with any of the solutions to the homogeneous equation, # then they will need to be multiplied by sufficient x to make them so. # This function DOES NOT do that (it doesn't even look at the # homogeneous equation). retdict['trialset'] = _get_trial_set(expr, x) return retdict def ode_nth_linear_constant_coeff_variation_of_parameters(eq, func, order, match): r""" Solves an `n`\th order linear differential equation with constant coefficients using the method of variation of parameters. This method works on any differential equations of the form .. math:: f^{(n)}(x) + a_{n-1} f^{(n-1)}(x) + \cdots + a_1 f'(x) + a_0 f(x) = P(x)\text{.} This method works by assuming that the particular solution takes the form .. math:: \sum_{x=1}^{n} c_i(x) y_i(x)\text{,} where `y_i` is the `i`\th solution to the homogeneous equation. The solution is then solved using Wronskian's and Cramer's Rule. The particular solution is given by .. math:: \sum_{x=1}^n \left( \int \frac{W_i(x)}{W(x)} \,dx \right) y_i(x) \text{,} where `W(x)` is the Wronskian of the fundamental system (the system of `n` linearly independent solutions to the homogeneous equation), and `W_i(x)` is the Wronskian of the fundamental system with the `i`\th column replaced with `[0, 0, \cdots, 0, P(x)]`. This method is general enough to solve any `n`\th order inhomogeneous linear differential equation with constant coefficients, but sometimes SymPy cannot simplify the Wronskian well enough to integrate it. If this method hangs, try using the ``nth_linear_constant_coeff_variation_of_parameters_Integral`` hint and simplifying the integrals manually. Also, prefer using ``nth_linear_constant_coeff_undetermined_coefficients`` when it applies, because it doesn't use integration, making it faster and more reliable. Warning, using simplify=False with 'nth_linear_constant_coeff_variation_of_parameters' in :py:meth:`~sympy.solvers.ode.dsolve` may cause it to hang, because it will not attempt to simplify the Wronskian before integrating. It is recommended that you only use simplify=False with 'nth_linear_constant_coeff_variation_of_parameters_Integral' for this method, especially if the solution to the homogeneous equation has trigonometric functions in it. Examples ======== >>> from sympy import Function, dsolve, pprint, exp, log >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x, 3) - 3*f(x).diff(x, 2) + ... 3*f(x).diff(x) - f(x) - exp(x)*log(x), f(x), ... hint='nth_linear_constant_coeff_variation_of_parameters')) / 3 \ | 2 x *(6*log(x) - 11)| x f(x) = |C1 + C2*x + C3*x + ------------------|*e \ 36 / References ========== - https://en.wikipedia.org/wiki/Variation_of_parameters - http://planetmath.org/VariationOfParameters - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 233 # indirect doctest """ gensol = ode_nth_linear_constant_coeff_homogeneous(eq, func, order, match, returns='both') match.update(gensol) return _solve_variation_of_parameters(eq, func, order, match) def _solve_variation_of_parameters(eq, func, order, match): r""" Helper function for the method of variation of parameters and nonhomogeneous euler eq. See the :py:meth:`~sympy.solvers.ode.ode_nth_linear_constant_coeff_variation_of_parameters` docstring for more information on this method. The parameter ``match`` should be a dictionary that has the following keys: ``list`` A list of solutions to the homogeneous equation, such as the list returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='list')``. ``sol`` The general solution, such as the solution returned by ``ode_nth_linear_constant_coeff_homogeneous(returns='sol')``. """ x = func.args[0] f = func.func r = match psol = 0 gensols = r['list'] gsol = r['sol'] wr = wronskian(gensols, x) if r.get('simplify', True): wr = simplify(wr) # We need much better simplification for # some ODEs. See issue 4662, for example. # To reduce commonly occurring sin(x)**2 + cos(x)**2 to 1 wr = trigsimp(wr, deep=True, recursive=True) if not wr: # The wronskian will be 0 iff the solutions are not linearly # independent. raise NotImplementedError("Cannot find " + str(order) + " solutions to the homogeneous equation necessary to apply " + "variation of parameters to " + str(eq) + " (Wronskian == 0)") if len(gensols) != order: raise NotImplementedError("Cannot find " + str(order) + " solutions to the homogeneous equation necessary to apply " + "variation of parameters to " + str(eq) + " (number of terms != order)") negoneterm = (-1)**(order) for i in gensols: psol += negoneterm*Integral(wronskian([sol for sol in gensols if sol != i], x)*r[-1]/wr, x)*i/r[order] negoneterm *= -1 if r.get('simplify', True): psol = simplify(psol) psol = trigsimp(psol, deep=True) return Eq(f(x), gsol.rhs + psol) def ode_separable(eq, func, order, match): r""" Solves separable 1st order differential equations. This is any differential equation that can be written as `P(y) \tfrac{dy}{dx} = Q(x)`. The solution can then just be found by rearranging terms and integrating: `\int P(y) \,dy = \int Q(x) \,dx`. This hint uses :py:meth:`sympy.simplify.simplify.separatevars` as its back end, so if a separable equation is not caught by this solver, it is most likely the fault of that function. :py:meth:`~sympy.simplify.simplify.separatevars` is smart enough to do most expansion and factoring necessary to convert a separable equation `F(x, y)` into the proper form `P(x)\cdot{}Q(y)`. The general solution is:: >>> from sympy import Function, dsolve, Eq, pprint >>> from sympy.abc import x >>> a, b, c, d, f = map(Function, ['a', 'b', 'c', 'd', 'f']) >>> genform = Eq(a(x)*b(f(x))*f(x).diff(x), c(x)*d(f(x))) >>> pprint(genform) d a(x)*b(f(x))*--(f(x)) = c(x)*d(f(x)) dx >>> pprint(dsolve(genform, f(x), hint='separable_Integral')) f(x) / / | | | b(y) | c(x) | ---- dy = C1 + | ---- dx | d(y) | a(x) | | / / Examples ======== >>> from sympy import Function, dsolve, Eq >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(Eq(f(x)*f(x).diff(x) + x, 3*x*f(x)**2), f(x), ... hint='separable', simplify=False)) / 2 \ 2 log\3*f (x) - 1/ x ---------------- = C1 + -- 6 2 References ========== - M. Tenenbaum & H. Pollard, "Ordinary Differential Equations", Dover 1963, pp. 52 # indirect doctest """ x = func.args[0] f = func.func C1 = get_numbered_constants(eq, num=1) r = match # {'m1':m1, 'm2':m2, 'y':y} u = r.get('hint', f(x)) # get u from separable_reduced else get f(x) return Eq(Integral(r['m2']['coeff']*r['m2'][r['y']]/r['m1'][r['y']], (r['y'], None, u)), Integral(-r['m1']['coeff']*r['m1'][x]/ r['m2'][x], x) + C1) def checkinfsol(eq, infinitesimals, func=None, order=None): r""" This function is used to check if the given infinitesimals are the actual infinitesimals of the given first order differential equation. This method is specific to the Lie Group Solver of ODEs. As of now, it simply checks, by substituting the infinitesimals in the partial differential equation. .. math:: \frac{\partial \eta}{\partial x} + \left(\frac{\partial \eta}{\partial y} - \frac{\partial \xi}{\partial x}\right)*h - \frac{\partial \xi}{\partial y}*h^{2} - \xi\frac{\partial h}{\partial x} - \eta\frac{\partial h}{\partial y} = 0 where `\eta`, and `\xi` are the infinitesimals and `h(x,y) = \frac{dy}{dx}` The infinitesimals should be given in the form of a list of dicts ``[{xi(x, y): inf, eta(x, y): inf}]``, corresponding to the output of the function infinitesimals. It returns a list of values of the form ``[(True/False, sol)]`` where ``sol`` is the value obtained after substituting the infinitesimals in the PDE. If it is ``True``, then ``sol`` would be 0. """ if isinstance(eq, Equality): eq = eq.lhs - eq.rhs if not func: eq, func = _preprocess(eq) variables = func.args if len(variables) != 1: raise ValueError("ODE's have only one independent variable") else: x = variables[0] if not order: order = ode_order(eq, func) if order != 1: raise NotImplementedError("Lie groups solver has been implemented " "only for first order differential equations") else: df = func.diff(x) a = Wild('a', exclude = [df]) b = Wild('b', exclude = [df]) match = collect(expand(eq), df).match(a*df + b) if match: h = -simplify(match[b]/match[a]) else: try: sol = solve(eq, df) except NotImplementedError: raise NotImplementedError("Infinitesimals for the " "first order ODE could not be found") else: h = sol[0] # Find infinitesimals for one solution y = Dummy('y') h = h.subs(func, y) xi = Function('xi')(x, y) eta = Function('eta')(x, y) dxi = Function('xi')(x, func) deta = Function('eta')(x, func) pde = (eta.diff(x) + (eta.diff(y) - xi.diff(x))*h - (xi.diff(y))*h**2 - xi*(h.diff(x)) - eta*(h.diff(y))) soltup = [] for sol in infinitesimals: tsol = {xi: S(sol[dxi]).subs(func, y), eta: S(sol[deta]).subs(func, y)} sol = simplify(pde.subs(tsol).doit()) if sol: soltup.append((False, sol.subs(y, func))) else: soltup.append((True, 0)) return soltup def ode_lie_group(eq, func, order, match): r""" This hint implements the Lie group method of solving first order differential equations. The aim is to convert the given differential equation from the given coordinate given system into another coordinate system where it becomes invariant under the one-parameter Lie group of translations. The converted ODE is quadrature and can be solved easily. It makes use of the :py:meth:`sympy.solvers.ode.infinitesimals` function which returns the infinitesimals of the transformation. The coordinates `r` and `s` can be found by solving the following Partial Differential Equations. .. math :: \xi\frac{\partial r}{\partial x} + \eta\frac{\partial r}{\partial y} = 0 .. math :: \xi\frac{\partial s}{\partial x} + \eta\frac{\partial s}{\partial y} = 1 The differential equation becomes separable in the new coordinate system .. math :: \frac{ds}{dr} = \frac{\frac{\partial s}{\partial x} + h(x, y)\frac{\partial s}{\partial y}}{ \frac{\partial r}{\partial x} + h(x, y)\frac{\partial r}{\partial y}} After finding the solution by integration, it is then converted back to the original coordinate system by substituting `r` and `s` in terms of `x` and `y` again. Examples ======== >>> from sympy import Function, dsolve, Eq, exp, pprint >>> from sympy.abc import x >>> f = Function('f') >>> pprint(dsolve(f(x).diff(x) + 2*x*f(x) - x*exp(-x**2), f(x), ... hint='lie_group')) / 2\ 2 | x | -x f(x) = |C1 + --|*e \ 2 / References ========== - Solving differential equations by Symmetry Groups, John Starrett, pp. 1 - pp. 14 """ heuristics = lie_heuristics inf = {} f = func.func x = func.args[0] df = func.diff(x) xi = Function("xi") eta = Function("eta") xis = match.pop('xi') etas = match.pop('eta') if match: h = -simplify(match[match['d']]/match[match['e']]) y = match['y'] else: try: sol = solve(eq, df) if sol == []: raise NotImplementedError except NotImplementedError: raise NotImplementedError("Unable to solve the differential equation " + str(eq) + " by the lie group method") else: y = Dummy("y") h = sol[0].subs(func, y) if xis is not None and etas is not None: inf = [{xi(x, f(x)): S(xis), eta(x, f(x)): S(etas)}] if not checkinfsol(eq, inf, func=f(x), order=1)[0][0]: raise ValueError("The given infinitesimals xi and eta" " are not the infinitesimals to the given equation") else: heuristics = ["user_defined"] match = {'h': h, 'y': y} # This is done so that if: # a] solve raises a NotImplementedError. # b] any heuristic raises a ValueError # another heuristic can be used. tempsol = [] # Used by solve below for heuristic in heuristics: try: if not inf: inf = infinitesimals(eq, hint=heuristic, func=func, order=1, match=match) except ValueError: continue else: for infsim in inf: xiinf = (infsim[xi(x, func)]).subs(func, y) etainf = (infsim[eta(x, func)]).subs(func, y) # This condition creates recursion while using pdsolve. # Since the first step while solving a PDE of form # a*(f(x, y).diff(x)) + b*(f(x, y).diff(y)) + c = 0 # is to solve the ODE dy/dx = b/a if simplify(etainf/xiinf) == h: continue rpde = f(x, y).diff(x)*xiinf + f(x, y).diff(y)*etainf r = pdsolve(rpde, func=f(x, y)).rhs s = pdsolve(rpde - 1, func=f(x, y)).rhs newcoord = [_lie_group_remove(coord) for coord in [r, s]] r = Dummy("r") s = Dummy("s") C1 = Symbol("C1") rcoord = newcoord[0] scoord = newcoord[-1] try: sol = solve([r - rcoord, s - scoord], x, y, dict=True) except NotImplementedError: continue else: sol = sol[0] xsub = sol[x] ysub = sol[y] num = simplify(scoord.diff(x) + scoord.diff(y)*h) denom = simplify(rcoord.diff(x) + rcoord.diff(y)*h) if num and denom: diffeq = simplify((num/denom).subs([(x, xsub), (y, ysub)])) sep = separatevars(diffeq, symbols=[r, s], dict=True) if sep: # Trying to separate, r and s coordinates deq = integrate((1/sep[s]), s) + C1 - integrate(sep['coeff']*sep[r], r) # Substituting and reverting back to original coordinates deq = deq.subs([(r, rcoord), (s, scoord)]) try: sdeq = solve(deq, y) except NotImplementedError: tempsol.append(deq) else: if len(sdeq) == 1: return Eq(f(x), sdeq.pop()) else: return [Eq(f(x), sol) for sol in sdeq] elif denom: # (ds/dr) is zero which means s is constant return Eq(f(x), solve(scoord - C1, y)[0]) elif num: # (dr/ds) is zero which means r is constant return Eq(f(x), solve(rcoord - C1, y)[0]) # If nothing works, return solution as it is, without solving for y if tempsol: if len(tempsol) == 1: return Eq(tempsol.pop().subs(y, f(x)), 0) else: return [Eq(sol.subs(y, f(x)), 0) for sol in tempsol] raise NotImplementedError("The given ODE " + str(eq) + " cannot be solved by" + " the lie group method") def _lie_group_remove(coords): r""" This function is strictly meant for internal use by the Lie group ODE solving method. It replaces arbitrary functions returned by pdsolve with either 0 or 1 or the args of the arbitrary function. The algorithm used is: 1] If coords is an instance of an Undefined Function, then the args are returned 2] If the arbitrary function is present in an Add object, it is replaced by zero. 3] If the arbitrary function is present in an Mul object, it is replaced by one. 4] If coords has no Undefined Function, it is returned as it is. Examples ======== >>> from sympy.solvers.ode import _lie_group_remove >>> from sympy import Function >>> from sympy.abc import x, y >>> F = Function("F") >>> eq = x**2*y >>> _lie_group_remove(eq) x**2*y >>> eq = F(x**2*y) >>> _lie_group_remove(eq) x**2*y >>> eq = y**2*x + F(x**3) >>> _lie_group_remove(eq) x*y**2 >>> eq = (F(x**3) + y)*x**4 >>> _lie_group_remove(eq) x**4*y """ if isinstance(coords, AppliedUndef): return coords.args[0] elif coords.is_Add: subfunc = coords.atoms(AppliedUndef) if subfunc: for func in subfunc: coords = coords.subs(func, 0) return coords elif coords.is_Pow: base, expr = coords.as_base_exp() base = _lie_group_remove(base) expr = _lie_group_remove(expr) return base**expr elif coords.is_Mul: mulargs = [] coordargs = coords.args for arg in coordargs: if not isinstance(coords, AppliedUndef): mulargs.append(_lie_group_remove(arg)) return Mul(*mulargs) return coords def infinitesimals(eq, func=None, order=None, hint='default', match=None): r""" The infinitesimal functions of an ordinary differential equation, `\xi(x,y)` and `\eta(x,y)`, are the infinitesimals of the Lie group of point transformations for which the differential equation is invariant. So, the ODE `y'=f(x,y)` would admit a Lie group `x^*=X(x,y;\varepsilon)=x+\varepsilon\xi(x,y)`, `y^*=Y(x,y;\varepsilon)=y+\varepsilon\eta(x,y)` such that `(y^*)'=f(x^*, y^*)`. A change of coordinates, to `r(x,y)` and `s(x,y)`, can be performed so this Lie group becomes the translation group, `r^*=r` and `s^*=s+\varepsilon`. They are tangents to the coordinate curves of the new system. Consider the transformation `(x, y) \to (X, Y)` such that the differential equation remains invariant. `\xi` and `\eta` are the tangents to the transformed coordinates `X` and `Y`, at `\varepsilon=0`. .. math:: \left(\frac{\partial X(x,y;\varepsilon)}{\partial\varepsilon }\right)|_{\varepsilon=0} = \xi, \left(\frac{\partial Y(x,y;\varepsilon)}{\partial\varepsilon }\right)|_{\varepsilon=0} = \eta, The infinitesimals can be found by solving the following PDE: >>> from sympy import Function, diff, Eq, pprint >>> from sympy.abc import x, y >>> xi, eta, h = map(Function, ['xi', 'eta', 'h']) >>> h = h(x, y) # dy/dx = h >>> eta = eta(x, y) >>> xi = xi(x, y) >>> genform = Eq(eta.diff(x) + (eta.diff(y) - xi.diff(x))*h ... - (xi.diff(y))*h**2 - xi*(h.diff(x)) - eta*(h.diff(y)), 0) >>> pprint(genform) /d d \ d 2 d |--(eta(x, y)) - --(xi(x, y))|*h(x, y) - eta(x, y)*--(h(x, y)) - h (x, y)*--(x \dy dx / dy dy <BLANKLINE> d d i(x, y)) - xi(x, y)*--(h(x, y)) + --(eta(x, y)) = 0 dx dx Solving the above mentioned PDE is not trivial, and can be solved only by making intelligent assumptions for `\xi` and `\eta` (heuristics). Once an infinitesimal is found, the attempt to find more heuristics stops. This is done to optimise the speed of solving the differential equation. If a list of all the infinitesimals is needed, ``hint`` should be flagged as ``all``, which gives the complete list of infinitesimals. If the infinitesimals for a particular heuristic needs to be found, it can be passed as a flag to ``hint``. Examples ======== >>> from sympy import Function, diff >>> from sympy.solvers.ode import infinitesimals >>> from sympy.abc import x >>> f = Function('f') >>> eq = f(x).diff(x) - x**2*f(x) >>> infinitesimals(eq) [{eta(x, f(x)): exp(x**3/3), xi(x, f(x)): 0}] References ========== - Solving differential equations by Symmetry Groups, John Starrett, pp. 1 - pp. 14 """ if isinstance(eq, Equality): eq = eq.lhs - eq.rhs if not func: eq, func = _preprocess(eq) variables = func.args if len(variables) != 1: raise ValueError("ODE's have only one independent variable") else: x = variables[0] if not order: order = ode_order(eq, func) if order != 1: raise NotImplementedError("Infinitesimals for only " "first order ODE's have been implemented") else: df = func.diff(x) # Matching differential equation of the form a*df + b a = Wild('a', exclude = [df]) b = Wild('b', exclude = [df]) if match: # Used by lie_group hint h = match['h'] y = match['y'] else: match = collect(expand(eq), df).match(a*df + b) if match: h = -simplify(match[b]/match[a]) else: try: sol = solve(eq, df) except NotImplementedError: raise NotImplementedError("Infinitesimals for the " "first order ODE could not be found") else: h = sol[0] # Find infinitesimals for one solution y = Dummy("y") h = h.subs(func, y) u = Dummy("u") hx = h.diff(x) hy = h.diff(y) hinv = ((1/h).subs([(x, u), (y, x)])).subs(u, y) # Inverse ODE match = {'h': h, 'func': func, 'hx': hx, 'hy': hy, 'y': y, 'hinv': hinv} if hint == 'all': xieta = [] for heuristic in lie_heuristics: function = globals()['lie_heuristic_' + heuristic] inflist = function(match, comp=True) if inflist: xieta.extend([inf for inf in inflist if inf not in xieta]) if xieta: return xieta else: raise NotImplementedError("Infinitesimals could not be found for " "the given ODE") elif hint == 'default': for heuristic in lie_heuristics: function = globals()['lie_heuristic_' + heuristic] xieta = function(match, comp=False) if xieta: return xieta raise NotImplementedError("Infinitesimals could not be found for" " the given ODE") elif hint not in lie_heuristics: raise ValueError("Heuristic not recognized: " + hint) else: function = globals()['lie_heuristic_' + hint] xieta = function(match, comp=True) if xieta: return xieta else: raise ValueError("Infinitesimals could not be found using the" " given heuristic") def lie_heuristic_abaco1_simple(match, comp=False): r""" The first heuristic uses the following four sets of assumptions on `\xi` and `\eta` .. math:: \xi = 0, \eta = f(x) .. math:: \xi = 0, \eta = f(y) .. math:: \xi = f(x), \eta = 0 .. math:: \xi = f(y), \eta = 0 The success of this heuristic is determined by algebraic factorisation. For the first assumption `\xi = 0` and `\eta` to be a function of `x`, the PDE .. math:: \frac{\partial \eta}{\partial x} + (\frac{\partial \eta}{\partial y} - \frac{\partial \xi}{\partial x})*h - \frac{\partial \xi}{\partial y}*h^{2} - \xi*\frac{\partial h}{\partial x} - \eta*\frac{\partial h}{\partial y} = 0 reduces to `f'(x) - f\frac{\partial h}{\partial y} = 0` If `\frac{\partial h}{\partial y}` is a function of `x`, then this can usually be integrated easily. A similar idea is applied to the other 3 assumptions as well. References ========== - E.S Cheb-Terrab, L.G.S Duarte and L.A,C.P da Mota, Computer Algebra Solving of First Order ODEs Using Symmetry Methods, pp. 8 """ xieta = [] y = match['y'] h = match['h'] func = match['func'] x = func.args[0] hx = match['hx'] hy = match['hy'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) hysym = hy.free_symbols if y not in hysym: try: fx = exp(integrate(hy, x)) except NotImplementedError: pass else: inf = {xi: S(0), eta: fx} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) factor = hy/h facsym = factor.free_symbols if x not in facsym: try: fy = exp(integrate(factor, y)) except NotImplementedError: pass else: inf = {xi: S(0), eta: fy.subs(y, func)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) factor = -hx/h facsym = factor.free_symbols if y not in facsym: try: fx = exp(integrate(factor, x)) except NotImplementedError: pass else: inf = {xi: fx, eta: S(0)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) factor = -hx/(h**2) facsym = factor.free_symbols if x not in facsym: try: fy = exp(integrate(factor, y)) except NotImplementedError: pass else: inf = {xi: fy.subs(y, func), eta: S(0)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) if xieta: return xieta def lie_heuristic_abaco1_product(match, comp=False): r""" The second heuristic uses the following two assumptions on `\xi` and `\eta` .. math:: \eta = 0, \xi = f(x)*g(y) .. math:: \eta = f(x)*g(y), \xi = 0 The first assumption of this heuristic holds good if `\frac{1}{h^{2}}\frac{\partial^2}{\partial x \partial y}\log(h)` is separable in `x` and `y`, then the separated factors containing `x` is `f(x)`, and `g(y)` is obtained by .. math:: e^{\int f\frac{\partial}{\partial x}\left(\frac{1}{f*h}\right)\,dy} provided `f\frac{\partial}{\partial x}\left(\frac{1}{f*h}\right)` is a function of `y` only. The second assumption holds good if `\frac{dy}{dx} = h(x, y)` is rewritten as `\frac{dy}{dx} = \frac{1}{h(y, x)}` and the same properties of the first assumption satisfies. After obtaining `f(x)` and `g(y)`, the coordinates are again interchanged, to get `\eta` as `f(x)*g(y)` References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 7 - pp. 8 """ xieta = [] y = match['y'] h = match['h'] hinv = match['hinv'] func = match['func'] x = func.args[0] xi = Function('xi')(x, func) eta = Function('eta')(x, func) inf = separatevars(((log(h).diff(y)).diff(x))/h**2, dict=True, symbols=[x, y]) if inf and inf['coeff']: fx = inf[x] gy = simplify(fx*((1/(fx*h)).diff(x))) gysyms = gy.free_symbols if x not in gysyms: gy = exp(integrate(gy, y)) inf = {eta: S(0), xi: (fx*gy).subs(y, func)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) u1 = Dummy("u1") inf = separatevars(((log(hinv).diff(y)).diff(x))/hinv**2, dict=True, symbols=[x, y]) if inf and inf['coeff']: fx = inf[x] gy = simplify(fx*((1/(fx*hinv)).diff(x))) gysyms = gy.free_symbols if x not in gysyms: gy = exp(integrate(gy, y)) etaval = fx*gy etaval = (etaval.subs([(x, u1), (y, x)])).subs(u1, y) inf = {eta: etaval.subs(y, func), xi: S(0)} if not comp: return [inf] if comp and inf not in xieta: xieta.append(inf) if xieta: return xieta def lie_heuristic_bivariate(match, comp=False): r""" The third heuristic assumes the infinitesimals `\xi` and `\eta` to be bi-variate polynomials in `x` and `y`. The assumption made here for the logic below is that `h` is a rational function in `x` and `y` though that may not be necessary for the infinitesimals to be bivariate polynomials. The coefficients of the infinitesimals are found out by substituting them in the PDE and grouping similar terms that are polynomials and since they form a linear system, solve and check for non trivial solutions. The degree of the assumed bivariates are increased till a certain maximum value. References ========== - Lie Groups and Differential Equations pp. 327 - pp. 329 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) if h.is_rational_function(): # The maximum degree that the infinitesimals can take is # calculated by this technique. etax, etay, etad, xix, xiy, xid = symbols("etax etay etad xix xiy xid") ipde = etax + (etay - xix)*h - xiy*h**2 - xid*hx - etad*hy num, denom = cancel(ipde).as_numer_denom() deg = Poly(num, x, y).total_degree() deta = Function('deta')(x, y) dxi = Function('dxi')(x, y) ipde = (deta.diff(x) + (deta.diff(y) - dxi.diff(x))*h - (dxi.diff(y))*h**2 - dxi*hx - deta*hy) xieq = Symbol("xi0") etaeq = Symbol("eta0") for i in range(deg + 1): if i: xieq += Add(*[ Symbol("xi_" + str(power) + "_" + str(i - power))*x**power*y**(i - power) for power in range(i + 1)]) etaeq += Add(*[ Symbol("eta_" + str(power) + "_" + str(i - power))*x**power*y**(i - power) for power in range(i + 1)]) pden, denom = (ipde.subs({dxi: xieq, deta: etaeq}).doit()).as_numer_denom() pden = expand(pden) # If the individual terms are monomials, the coefficients # are grouped if pden.is_polynomial(x, y) and pden.is_Add: polyy = Poly(pden, x, y).as_dict() if polyy: symset = xieq.free_symbols.union(etaeq.free_symbols) - {x, y} soldict = solve(polyy.values(), *symset) if isinstance(soldict, list): soldict = soldict[0] if any(soldict.values()): xired = xieq.subs(soldict) etared = etaeq.subs(soldict) # Scaling is done by substituting one for the parameters # This can be any number except zero. dict_ = dict((sym, 1) for sym in symset) inf = {eta: etared.subs(dict_).subs(y, func), xi: xired.subs(dict_).subs(y, func)} return [inf] def lie_heuristic_chi(match, comp=False): r""" The aim of the fourth heuristic is to find the function `\chi(x, y)` that satisfies the PDE `\frac{d\chi}{dx} + h\frac{d\chi}{dx} - \frac{\partial h}{\partial y}\chi = 0`. This assumes `\chi` to be a bivariate polynomial in `x` and `y`. By intuition, `h` should be a rational function in `x` and `y`. The method used here is to substitute a general binomial for `\chi` up to a certain maximum degree is reached. The coefficients of the polynomials, are calculated by by collecting terms of the same order in `x` and `y`. After finding `\chi`, the next step is to use `\eta = \xi*h + \chi`, to determine `\xi` and `\eta`. This can be done by dividing `\chi` by `h` which would give `-\xi` as the quotient and `\eta` as the remainder. References ========== - E.S Cheb-Terrab, L.G.S Duarte and L.A,C.P da Mota, Computer Algebra Solving of First Order ODEs Using Symmetry Methods, pp. 8 """ h = match['h'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) if h.is_rational_function(): schi, schix, schiy = symbols("schi, schix, schiy") cpde = schix + h*schiy - hy*schi num, denom = cancel(cpde).as_numer_denom() deg = Poly(num, x, y).total_degree() chi = Function('chi')(x, y) chix = chi.diff(x) chiy = chi.diff(y) cpde = chix + h*chiy - hy*chi chieq = Symbol("chi") for i in range(1, deg + 1): chieq += Add(*[ Symbol("chi_" + str(power) + "_" + str(i - power))*x**power*y**(i - power) for power in range(i + 1)]) cnum, cden = cancel(cpde.subs({chi : chieq}).doit()).as_numer_denom() cnum = expand(cnum) if cnum.is_polynomial(x, y) and cnum.is_Add: cpoly = Poly(cnum, x, y).as_dict() if cpoly: solsyms = chieq.free_symbols - {x, y} soldict = solve(cpoly.values(), *solsyms) if isinstance(soldict, list): soldict = soldict[0] if any(soldict.values()): chieq = chieq.subs(soldict) dict_ = dict((sym, 1) for sym in solsyms) chieq = chieq.subs(dict_) # After finding chi, the main aim is to find out # eta, xi by the equation eta = xi*h + chi # One method to set xi, would be rearranging it to # (eta/h) - xi = (chi/h). This would mean dividing # chi by h would give -xi as the quotient and eta # as the remainder. Thanks to Sean Vig for suggesting # this method. xic, etac = div(chieq, h) inf = {eta: etac.subs(y, func), xi: -xic.subs(y, func)} return [inf] def lie_heuristic_function_sum(match, comp=False): r""" This heuristic uses the following two assumptions on `\xi` and `\eta` .. math:: \eta = 0, \xi = f(x) + g(y) .. math:: \eta = f(x) + g(y), \xi = 0 The first assumption of this heuristic holds good if .. math:: \frac{\partial}{\partial y}[(h\frac{\partial^{2}}{ \partial x^{2}}(h^{-1}))^{-1}] is separable in `x` and `y`, 1. The separated factors containing `y` is `\frac{\partial g}{\partial y}`. From this `g(y)` can be determined. 2. The separated factors containing `x` is `f''(x)`. 3. `h\frac{\partial^{2}}{\partial x^{2}}(h^{-1})` equals `\frac{f''(x)}{f(x) + g(y)}`. From this `f(x)` can be determined. The second assumption holds good if `\frac{dy}{dx} = h(x, y)` is rewritten as `\frac{dy}{dx} = \frac{1}{h(y, x)}` and the same properties of the first assumption satisfies. After obtaining `f(x)` and `g(y)`, the coordinates are again interchanged, to get `\eta` as `f(x) + g(y)`. For both assumptions, the constant factors are separated among `g(y)` and `f''(x)`, such that `f''(x)` obtained from 3] is the same as that obtained from 2]. If not possible, then this heuristic fails. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 7 - pp. 8 """ xieta = [] h = match['h'] func = match['func'] hinv = match['hinv'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) for odefac in [h, hinv]: factor = odefac*((1/odefac).diff(x, 2)) sep = separatevars((1/factor).diff(y), dict=True, symbols=[x, y]) if sep and sep['coeff'] and sep[x].has(x) and sep[y].has(y): k = Dummy("k") try: gy = k*integrate(sep[y], y) except NotImplementedError: pass else: fdd = 1/(k*sep[x]*sep['coeff']) fx = simplify(fdd/factor - gy) check = simplify(fx.diff(x, 2) - fdd) if fx: if not check: fx = fx.subs(k, 1) gy = (gy/k) else: sol = solve(check, k) if sol: sol = sol[0] fx = fx.subs(k, sol) gy = (gy/k)*sol else: continue if odefac == hinv: # Inverse ODE fx = fx.subs(x, y) gy = gy.subs(y, x) etaval = factor_terms(fx + gy) if etaval.is_Mul: etaval = Mul(*[arg for arg in etaval.args if arg.has(x, y)]) if odefac == hinv: # Inverse ODE inf = {eta: etaval.subs(y, func), xi : S(0)} else: inf = {xi: etaval.subs(y, func), eta : S(0)} if not comp: return [inf] else: xieta.append(inf) if xieta: return xieta def lie_heuristic_abaco2_similar(match, comp=False): r""" This heuristic uses the following two assumptions on `\xi` and `\eta` .. math:: \eta = g(x), \xi = f(x) .. math:: \eta = f(y), \xi = g(y) For the first assumption, 1. First `\frac{\frac{\partial h}{\partial y}}{\frac{\partial^{2} h}{ \partial yy}}` is calculated. Let us say this value is A 2. If this is constant, then `h` is matched to the form `A(x) + B(x)e^{ \frac{y}{C}}` then, `\frac{e^{\int \frac{A(x)}{C} \,dx}}{B(x)}` gives `f(x)` and `A(x)*f(x)` gives `g(x)` 3. Otherwise `\frac{\frac{\partial A}{\partial X}}{\frac{\partial A}{ \partial Y}} = \gamma` is calculated. If a] `\gamma` is a function of `x` alone b] `\frac{\gamma\frac{\partial h}{\partial y} - \gamma'(x) - \frac{ \partial h}{\partial x}}{h + \gamma} = G` is a function of `x` alone. then, `e^{\int G \,dx}` gives `f(x)` and `-\gamma*f(x)` gives `g(x)` The second assumption holds good if `\frac{dy}{dx} = h(x, y)` is rewritten as `\frac{dy}{dx} = \frac{1}{h(y, x)}` and the same properties of the first assumption satisfies. After obtaining `f(x)` and `g(x)`, the coordinates are again interchanged, to get `\xi` as `f(x^*)` and `\eta` as `g(y^*)` References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] hinv = match['hinv'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) factor = cancel(h.diff(y)/h.diff(y, 2)) factorx = factor.diff(x) factory = factor.diff(y) if not factor.has(x) and not factor.has(y): A = Wild('A', exclude=[y]) B = Wild('B', exclude=[y]) C = Wild('C', exclude=[x, y]) match = h.match(A + B*exp(y/C)) try: tau = exp(-integrate(match[A]/match[C]), x)/match[B] except NotImplementedError: pass else: gx = match[A]*tau return [{xi: tau, eta: gx}] else: gamma = cancel(factorx/factory) if not gamma.has(y): tauint = cancel((gamma*hy - gamma.diff(x) - hx)/(h + gamma)) if not tauint.has(y): try: tau = exp(integrate(tauint, x)) except NotImplementedError: pass else: gx = -tau*gamma return [{xi: tau, eta: gx}] factor = cancel(hinv.diff(y)/hinv.diff(y, 2)) factorx = factor.diff(x) factory = factor.diff(y) if not factor.has(x) and not factor.has(y): A = Wild('A', exclude=[y]) B = Wild('B', exclude=[y]) C = Wild('C', exclude=[x, y]) match = h.match(A + B*exp(y/C)) try: tau = exp(-integrate(match[A]/match[C]), x)/match[B] except NotImplementedError: pass else: gx = match[A]*tau return [{eta: tau.subs(x, func), xi: gx.subs(x, func)}] else: gamma = cancel(factorx/factory) if not gamma.has(y): tauint = cancel((gamma*hinv.diff(y) - gamma.diff(x) - hinv.diff(x))/( hinv + gamma)) if not tauint.has(y): try: tau = exp(integrate(tauint, x)) except NotImplementedError: pass else: gx = -tau*gamma return [{eta: tau.subs(x, func), xi: gx.subs(x, func)}] def lie_heuristic_abaco2_unique_unknown(match, comp=False): r""" This heuristic assumes the presence of unknown functions or known functions with non-integer powers. 1. A list of all functions and non-integer powers containing x and y 2. Loop over each element `f` in the list, find `\frac{\frac{\partial f}{\partial x}}{ \frac{\partial f}{\partial x}} = R` If it is separable in `x` and `y`, let `X` be the factors containing `x`. Then a] Check if `\xi = X` and `\eta = -\frac{X}{R}` satisfy the PDE. If yes, then return `\xi` and `\eta` b] Check if `\xi = \frac{-R}{X}` and `\eta = -\frac{1}{X}` satisfy the PDE. If yes, then return `\xi` and `\eta` If not, then check if a] :math:`\xi = -R,\eta = 1` b] :math:`\xi = 1, \eta = -\frac{1}{R}` are solutions. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) funclist = [] for atom in h.atoms(Pow): base, exp = atom.as_base_exp() if base.has(x) and base.has(y): if not exp.is_Integer: funclist.append(atom) for function in h.atoms(AppliedUndef): syms = function.free_symbols if x in syms and y in syms: funclist.append(function) for f in funclist: frac = cancel(f.diff(y)/f.diff(x)) sep = separatevars(frac, dict=True, symbols=[x, y]) if sep and sep['coeff']: xitry1 = sep[x] etatry1 = -1/(sep[y]*sep['coeff']) pde1 = etatry1.diff(y)*h - xitry1.diff(x)*h - xitry1*hx - etatry1*hy if not simplify(pde1): return [{xi: xitry1, eta: etatry1.subs(y, func)}] xitry2 = 1/etatry1 etatry2 = 1/xitry1 pde2 = etatry2.diff(x) - (xitry2.diff(y))*h**2 - xitry2*hx - etatry2*hy if not simplify(expand(pde2)): return [{xi: xitry2.subs(y, func), eta: etatry2}] else: etatry = -1/frac pde = etatry.diff(x) + etatry.diff(y)*h - hx - etatry*hy if not simplify(pde): return [{xi: S(1), eta: etatry.subs(y, func)}] xitry = -frac pde = -xitry.diff(x)*h -xitry.diff(y)*h**2 - xitry*hx -hy if not simplify(expand(pde)): return [{xi: xitry.subs(y, func), eta: S(1)}] def lie_heuristic_abaco2_unique_general(match, comp=False): r""" This heuristic finds if infinitesimals of the form `\eta = f(x)`, `\xi = g(y)` without making any assumptions on `h`. The complete sequence of steps is given in the paper mentioned below. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) A = hx.diff(y) B = hy.diff(y) + hy**2 C = hx.diff(x) - hx**2 if not (A and B and C): return Ax = A.diff(x) Ay = A.diff(y) Axy = Ax.diff(y) Axx = Ax.diff(x) Ayy = Ay.diff(y) D = simplify(2*Axy + hx*Ay - Ax*hy + (hx*hy + 2*A)*A)*A - 3*Ax*Ay if not D: E1 = simplify(3*Ax**2 + ((hx**2 + 2*C)*A - 2*Axx)*A) if E1: E2 = simplify((2*Ayy + (2*B - hy**2)*A)*A - 3*Ay**2) if not E2: E3 = simplify( E1*((28*Ax + 4*hx*A)*A**3 - E1*(hy*A + Ay)) - E1.diff(x)*8*A**4) if not E3: etaval = cancel((4*A**3*(Ax - hx*A) + E1*(hy*A - Ay))/(S(2)*A*E1)) if x not in etaval: try: etaval = exp(integrate(etaval, y)) except NotImplementedError: pass else: xival = -4*A**3*etaval/E1 if y not in xival: return [{xi: xival, eta: etaval.subs(y, func)}] else: E1 = simplify((2*Ayy + (2*B - hy**2)*A)*A - 3*Ay**2) if E1: E2 = simplify( 4*A**3*D - D**2 + E1*((2*Axx - (hx**2 + 2*C)*A)*A - 3*Ax**2)) if not E2: E3 = simplify( -(A*D)*E1.diff(y) + ((E1.diff(x) - hy*D)*A + 3*Ay*D + (A*hx - 3*Ax)*E1)*E1) if not E3: etaval = cancel(((A*hx - Ax)*E1 - (Ay + A*hy)*D)/(S(2)*A*D)) if x not in etaval: try: etaval = exp(integrate(etaval, y)) except NotImplementedError: pass else: xival = -E1*etaval/D if y not in xival: return [{xi: xival, eta: etaval.subs(y, func)}] def lie_heuristic_linear(match, comp=False): r""" This heuristic assumes 1. `\xi = ax + by + c` and 2. `\eta = fx + gy + h` After substituting the following assumptions in the determining PDE, it reduces to .. math:: f + (g - a)h - bh^{2} - (ax + by + c)\frac{\partial h}{\partial x} - (fx + gy + c)\frac{\partial h}{\partial y} Solving the reduced PDE obtained, using the method of characteristics, becomes impractical. The method followed is grouping similar terms and solving the system of linear equations obtained. The difference between the bivariate heuristic is that `h` need not be a rational function in this case. References ========== - E.S. Cheb-Terrab, A.D. Roche, Symmetries and First Order ODE Patterns, pp. 10 - pp. 12 """ h = match['h'] hx = match['hx'] hy = match['hy'] func = match['func'] x = func.args[0] y = match['y'] xi = Function('xi')(x, func) eta = Function('eta')(x, func) coeffdict = {} symbols = numbered_symbols("c", cls=Dummy) symlist = [next(symbols) for _ in islice(symbols, 6)] C0, C1, C2, C3, C4, C5 = symlist pde = C3 + (C4 - C0)*h - (C0*x + C1*y + C2)*hx - (C3*x + C4*y + C5)*hy - C1*h**2 pde, denom = pde.as_numer_denom() pde = powsimp(expand(pde)) if pde.is_Add: terms = pde.args for term in terms: if term.is_Mul: rem = Mul(*[m for m in term.args if not m.has(x, y)]) xypart = term/rem if xypart not in coeffdict: coeffdict[xypart] = rem else: coeffdict[xypart] += rem else: if term not in coeffdict: coeffdict[term] = S(1) else: coeffdict[term] += S(1) sollist = coeffdict.values() soldict = solve(sollist, symlist) if soldict: if isinstance(soldict, list): soldict = soldict[0] subval = soldict.values() if any(t for t in subval): onedict = dict(zip(symlist, [1]*6)) xival = C0*x + C1*func + C2 etaval = C3*x + C4*func + C5 xival = xival.subs(soldict) etaval = etaval.subs(soldict) xival = xival.subs(onedict) etaval = etaval.subs(onedict) return [{xi: xival, eta: etaval}] def sysode_linear_2eq_order1(match_): x = match_['func'][0].func y = match_['func'][1].func func = match_['func'] fc = match_['func_coeff'] eq = match_['eq'] r = dict() t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] for i in range(2): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs # for equations Eq(a1*diff(x(t),t), a*x(t) + b*y(t) + k1) # and Eq(a2*diff(x(t),t), c*x(t) + d*y(t) + k2) r['a'] = -fc[0,x(t),0]/fc[0,x(t),1] r['c'] = -fc[1,x(t),0]/fc[1,y(t),1] r['b'] = -fc[0,y(t),0]/fc[0,x(t),1] r['d'] = -fc[1,y(t),0]/fc[1,y(t),1] forcing = [S(0),S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t)): forcing[i] += j if not (forcing[0].has(t) or forcing[1].has(t)): r['k1'] = forcing[0] r['k2'] = forcing[1] else: raise NotImplementedError("Only homogeneous problems are supported" + " (and constant inhomogeneity)") if match_['type_of_equation'] == 'type1': sol = _linear_2eq_order1_type1(x, y, t, r, eq) if match_['type_of_equation'] == 'type2': gsol = _linear_2eq_order1_type1(x, y, t, r, eq) psol = _linear_2eq_order1_type2(x, y, t, r, eq) sol = [Eq(x(t), gsol[0].rhs+psol[0]), Eq(y(t), gsol[1].rhs+psol[1])] if match_['type_of_equation'] == 'type3': sol = _linear_2eq_order1_type3(x, y, t, r, eq) if match_['type_of_equation'] == 'type4': sol = _linear_2eq_order1_type4(x, y, t, r, eq) if match_['type_of_equation'] == 'type5': sol = _linear_2eq_order1_type5(x, y, t, r, eq) if match_['type_of_equation'] == 'type6': sol = _linear_2eq_order1_type6(x, y, t, r, eq) if match_['type_of_equation'] == 'type7': sol = _linear_2eq_order1_type7(x, y, t, r, eq) return sol def _linear_2eq_order1_type1(x, y, t, r, eq): r""" It is classified under system of two linear homogeneous first-order constant-coefficient ordinary differential equations. The equations which come under this type are .. math:: x' = ax + by, .. math:: y' = cx + dy The characteristics equation is written as .. math:: \lambda^{2} + (a+d) \lambda + ad - bc = 0 and its discriminant is `D = (a-d)^{2} + 4bc`. There are several cases 1. Case when `ad - bc \neq 0`. The origin of coordinates, `x = y = 0`, is the only stationary point; it is - a node if `D = 0` - a node if `D > 0` and `ad - bc > 0` - a saddle if `D > 0` and `ad - bc < 0` - a focus if `D < 0` and `a + d \neq 0` - a centre if `D < 0` and `a + d \neq 0`. 1.1. If `D > 0`. The characteristic equation has two distinct real roots `\lambda_1` and `\lambda_ 2` . The general solution of the system in question is expressed as .. math:: x = C_1 b e^{\lambda_1 t} + C_2 b e^{\lambda_2 t} .. math:: y = C_1 (\lambda_1 - a) e^{\lambda_1 t} + C_2 (\lambda_2 - a) e^{\lambda_2 t} where `C_1` and `C_2` being arbitrary constants 1.2. If `D < 0`. The characteristics equation has two conjugate roots, `\lambda_1 = \sigma + i \beta` and `\lambda_2 = \sigma - i \beta`. The general solution of the system is given by .. math:: x = b e^{\sigma t} (C_1 \sin(\beta t) + C_2 \cos(\beta t)) .. math:: y = e^{\sigma t} ([(\sigma - a) C_1 - \beta C_2] \sin(\beta t) + [\beta C_1 + (\sigma - a) C_2 \cos(\beta t)]) 1.3. If `D = 0` and `a \neq d`. The characteristic equation has two equal roots, `\lambda_1 = \lambda_2`. The general solution of the system is written as .. math:: x = 2b (C_1 + \frac{C_2}{a-d} + C_2 t) e^{\frac{a+d}{2} t} .. math:: y = [(d - a) C_1 + C_2 + (d - a) C_2 t] e^{\frac{a+d}{2} t} 1.4. If `D = 0` and `a = d \neq 0` and `b = 0` .. math:: x = C_1 e^{a t} , y = (c C_1 t + C_2) e^{a t} 1.5. If `D = 0` and `a = d \neq 0` and `c = 0` .. math:: x = (b C_1 t + C_2) e^{a t} , y = C_1 e^{a t} 2. Case when `ad - bc = 0` and `a^{2} + b^{2} > 0`. The whole straight line `ax + by = 0` consists of singular points. The original system of differential equations can be rewritten as .. math:: x' = ax + by , y' = k (ax + by) 2.1 If `a + bk \neq 0`, solution will be .. math:: x = b C_1 + C_2 e^{(a + bk) t} , y = -a C_1 + k C_2 e^{(a + bk) t} 2.2 If `a + bk = 0`, solution will be .. math:: x = C_1 (bk t - 1) + b C_2 t , y = k^{2} b C_1 t + (b k^{2} t + 1) C_2 """ C1, C2 = get_numbered_constants(eq, num=2) a, b, c, d = r['a'], r['b'], r['c'], r['d'] real_coeff = all(v.is_real for v in (a, b, c, d)) D = (a - d)**2 + 4*b*c l1 = (a + d + sqrt(D))/2 l2 = (a + d - sqrt(D))/2 equal_roots = Eq(D, 0).expand() gsol1, gsol2 = [], [] # Solutions have exponential form if either D > 0 with real coefficients # or D != 0 with complex coefficients. Eigenvalues are distinct. # For each eigenvalue lam, pick an eigenvector, making sure we don't get (0, 0) # The candidates are (b, lam-a) and (lam-d, c). exponential_form = D > 0 if real_coeff else Not(equal_roots) bad_ab_vector1 = And(Eq(b, 0), Eq(l1, a)) bad_ab_vector2 = And(Eq(b, 0), Eq(l2, a)) vector1 = Matrix((Piecewise((l1 - d, bad_ab_vector1), (b, True)), Piecewise((c, bad_ab_vector1), (l1 - a, True)))) vector2 = Matrix((Piecewise((l2 - d, bad_ab_vector2), (b, True)), Piecewise((c, bad_ab_vector2), (l2 - a, True)))) sol_vector = C1*exp(l1*t)*vector1 + C2*exp(l2*t)*vector2 gsol1.append((sol_vector[0], exponential_form)) gsol2.append((sol_vector[1], exponential_form)) # Solutions have trigonometric form for real coefficients with D < 0 # Both b and c are nonzero in this case, so (b, lam-a) is an eigenvector # It splits into real/imag parts as (b, sigma-a) and (0, beta). Then # multiply it by C1(cos(beta*t) + I*C2*sin(beta*t)) and separate real/imag trigonometric_form = D < 0 if real_coeff else False sigma = re(l1) if im(l1).is_positive: beta = im(l1) else: beta = im(l2) vector1 = Matrix((b, sigma - a)) vector2 = Matrix((0, beta)) sol_vector = exp(sigma*t) * (C1*(cos(beta*t)*vector1 - sin(beta*t)*vector2) + \ C2*(sin(beta*t)*vector1 + cos(beta*t)*vector2)) gsol1.append((sol_vector[0], trigonometric_form)) gsol2.append((sol_vector[1], trigonometric_form)) # Final case is D == 0, a single eigenvalue. If the eigenspace is 2-dimensional # then we have a scalar matrix, deal with this case first. scalar_matrix = And(Eq(a, d), Eq(b, 0), Eq(c, 0)) vector1 = Matrix((S.One, S.Zero)) vector2 = Matrix((S.Zero, S.One)) sol_vector = exp(l1*t) * (C1*vector1 + C2*vector2) gsol1.append((sol_vector[0], scalar_matrix)) gsol2.append((sol_vector[1], scalar_matrix)) # Have one eigenvector. Get a generalized eigenvector from (A-lam)*vector2 = vector1 vector1 = Matrix((Piecewise((l1 - d, bad_ab_vector1), (b, True)), Piecewise((c, bad_ab_vector1), (l1 - a, True)))) vector2 = Matrix((Piecewise((S.One, bad_ab_vector1), (S.Zero, Eq(a, l1)), (b/(a - l1), True)), Piecewise((S.Zero, bad_ab_vector1), (S.One, Eq(a, l1)), (S.Zero, True)))) sol_vector = exp(l1*t) * (C1*vector1 + C2*(vector2 + t*vector1)) gsol1.append((sol_vector[0], equal_roots)) gsol2.append((sol_vector[1], equal_roots)) return [Eq(x(t), Piecewise(*gsol1)), Eq(y(t), Piecewise(*gsol2))] def _linear_2eq_order1_type2(x, y, t, r, eq): r""" The equations of this type are .. math:: x' = ax + by + k1 , y' = cx + dy + k2 The general solution of this system is given by sum of its particular solution and the general solution of the corresponding homogeneous system is obtained from type1. 1. When `ad - bc \neq 0`. The particular solution will be `x = x_0` and `y = y_0` where `x_0` and `y_0` are determined by solving linear system of equations .. math:: a x_0 + b y_0 + k1 = 0 , c x_0 + d y_0 + k2 = 0 2. When `ad - bc = 0` and `a^{2} + b^{2} > 0`. In this case, the system of equation becomes .. math:: x' = ax + by + k_1 , y' = k (ax + by) + k_2 2.1 If `\sigma = a + bk \neq 0`, particular solution is given by .. math:: x = b \sigma^{-1} (c_1 k - c_2) t - \sigma^{-2} (a c_1 + b c_2) .. math:: y = kx + (c_2 - c_1 k) t 2.2 If `\sigma = a + bk = 0`, particular solution is given by .. math:: x = \frac{1}{2} b (c_2 - c_1 k) t^{2} + c_1 t .. math:: y = kx + (c_2 - c_1 k) t """ r['k1'] = -r['k1']; r['k2'] = -r['k2'] if (r['a']*r['d'] - r['b']*r['c']) != 0: x0, y0 = symbols('x0, y0', cls=Dummy) sol = solve((r['a']*x0+r['b']*y0+r['k1'], r['c']*x0+r['d']*y0+r['k2']), x0, y0) psol = [sol[x0], sol[y0]] elif (r['a']*r['d'] - r['b']*r['c']) == 0 and (r['a']**2+r['b']**2) > 0: k = r['c']/r['a'] sigma = r['a'] + r['b']*k if sigma != 0: sol1 = r['b']*sigma**-1*(r['k1']*k-r['k2'])*t - sigma**-2*(r['a']*r['k1']+r['b']*r['k2']) sol2 = k*sol1 + (r['k2']-r['k1']*k)*t else: # FIXME: a previous typo fix shows this is not covered by tests sol1 = r['b']*(r['k2']-r['k1']*k)*t**2 + r['k1']*t sol2 = k*sol1 + (r['k2']-r['k1']*k)*t psol = [sol1, sol2] return psol def _linear_2eq_order1_type3(x, y, t, r, eq): r""" The equations of this type of ode are .. math:: x' = f(t) x + g(t) y .. math:: y' = g(t) x + f(t) y The solution of such equations is given by .. math:: x = e^{F} (C_1 e^{G} + C_2 e^{-G}) , y = e^{F} (C_1 e^{G} - C_2 e^{-G}) where `C_1` and `C_2` are arbitrary constants, and .. math:: F = \int f(t) \,dt , G = \int g(t) \,dt """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) F = Integral(r['a'], t) G = Integral(r['b'], t) sol1 = exp(F)*(C1*exp(G) + C2*exp(-G)) sol2 = exp(F)*(C1*exp(G) - C2*exp(-G)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type4(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = -g(t) x + f(t) y The solution is given by .. math:: x = F (C_1 \cos(G) + C_2 \sin(G)), y = F (-C_1 \sin(G) + C_2 \cos(G)) where `C_1` and `C_2` are arbitrary constants, and .. math:: F = \int f(t) \,dt , G = \int g(t) \,dt """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) if r['b'] == -r['c']: F = exp(Integral(r['a'], t)) G = Integral(r['b'], t) sol1 = F*(C1*cos(G) + C2*sin(G)) sol2 = F*(-C1*sin(G) + C2*cos(G)) elif r['d'] == -r['a']: F = exp(Integral(r['c'], t)) G = Integral(r['d'], t) sol1 = F*(-C1*sin(G) + C2*cos(G)) sol2 = F*(C1*cos(G) + C2*sin(G)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type5(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = a g(t) x + [f(t) + b g(t)] y The transformation of .. math:: x = e^{\int f(t) \,dt} u , y = e^{\int f(t) \,dt} v , T = \int g(t) \,dt leads to a system of constant coefficient linear differential equations .. math:: u'(T) = v , v'(T) = au + bv """ u, v = symbols('u, v', cls=Function) T = Symbol('T') if not cancel(r['c']/r['b']).has(t): p = cancel(r['c']/r['b']) q = cancel((r['d']-r['a'])/r['b']) eq = (Eq(diff(u(T),T), v(T)), Eq(diff(v(T),T), p*u(T)+q*v(T))) sol = dsolve(eq) sol1 = exp(Integral(r['a'], t))*sol[0].rhs.subs(T, Integral(r['b'], t)) sol2 = exp(Integral(r['a'], t))*sol[1].rhs.subs(T, Integral(r['b'], t)) if not cancel(r['a']/r['d']).has(t): p = cancel(r['a']/r['d']) q = cancel((r['b']-r['c'])/r['d']) sol = dsolve(Eq(diff(u(T),T), v(T)), Eq(diff(v(T),T), p*u(T)+q*v(T))) sol1 = exp(Integral(r['c'], t))*sol[1].rhs.subs(T, Integral(r['d'], t)) sol2 = exp(Integral(r['c'], t))*sol[0].rhs.subs(T, Integral(r['d'], t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type6(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = a [f(t) + a h(t)] x + a [g(t) - h(t)] y This is solved by first multiplying the first equation by `-a` and adding it to the second equation to obtain .. math:: y' - a x' = -a h(t) (y - a x) Setting `U = y - ax` and integrating the equation we arrive at .. math:: y - ax = C_1 e^{-a \int h(t) \,dt} and on substituting the value of y in first equation give rise to first order ODEs. After solving for `x`, we can obtain `y` by substituting the value of `x` in second equation. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) p = 0 q = 0 p1 = cancel(r['c']/cancel(r['c']/r['d']).as_numer_denom()[0]) p2 = cancel(r['a']/cancel(r['a']/r['b']).as_numer_denom()[0]) for n, i in enumerate([p1, p2]): for j in Mul.make_args(collect_const(i)): if not j.has(t): q = j if q!=0 and n==0: if ((r['c']/j - r['a'])/(r['b'] - r['d']/j)) == j: p = 1 s = j break if q!=0 and n==1: if ((r['a']/j - r['c'])/(r['d'] - r['b']/j)) == j: p = 2 s = j break if p == 1: equ = diff(x(t),t) - r['a']*x(t) - r['b']*(s*x(t) + C1*exp(-s*Integral(r['b'] - r['d']/s, t))) hint1 = classify_ode(equ)[1] sol1 = dsolve(equ, hint=hint1+'_Integral').rhs sol2 = s*sol1 + C1*exp(-s*Integral(r['b'] - r['d']/s, t)) elif p ==2: equ = diff(y(t),t) - r['c']*y(t) - r['d']*s*y(t) + C1*exp(-s*Integral(r['d'] - r['b']/s, t)) hint1 = classify_ode(equ)[1] sol2 = dsolve(equ, hint=hint1+'_Integral').rhs sol1 = s*sol2 + C1*exp(-s*Integral(r['d'] - r['b']/s, t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order1_type7(x, y, t, r, eq): r""" The equations of this type of ode are . .. math:: x' = f(t) x + g(t) y .. math:: y' = h(t) x + p(t) y Differentiating the first equation and substituting the value of `y` from second equation will give a second-order linear equation .. math:: g x'' - (fg + gp + g') x' + (fgp - g^{2} h + f g' - f' g) x = 0 This above equation can be easily integrated if following conditions are satisfied. 1. `fgp - g^{2} h + f g' - f' g = 0` 2. `fgp - g^{2} h + f g' - f' g = ag, fg + gp + g' = bg` If first condition is satisfied then it is solved by current dsolve solver and in second case it becomes a constant coefficient differential equation which is also solved by current solver. Otherwise if the above condition fails then, a particular solution is assumed as `x = x_0(t)` and `y = y_0(t)` Then the general solution is expressed as .. math:: x = C_1 x_0(t) + C_2 x_0(t) \int \frac{g(t) F(t) P(t)}{x_0^{2}(t)} \,dt .. math:: y = C_1 y_0(t) + C_2 [\frac{F(t) P(t)}{x_0(t)} + y_0(t) \int \frac{g(t) F(t) P(t)}{x_0^{2}(t)} \,dt] where C1 and C2 are arbitrary constants and .. math:: F(t) = e^{\int f(t) \,dt} , P(t) = e^{\int p(t) \,dt} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) e1 = r['a']*r['b']*r['c'] - r['b']**2*r['c'] + r['a']*diff(r['b'],t) - diff(r['a'],t)*r['b'] e2 = r['a']*r['c']*r['d'] - r['b']*r['c']**2 + diff(r['c'],t)*r['d'] - r['c']*diff(r['d'],t) m1 = r['a']*r['b'] + r['b']*r['d'] + diff(r['b'],t) m2 = r['a']*r['c'] + r['c']*r['d'] + diff(r['c'],t) if e1 == 0: sol1 = dsolve(r['b']*diff(x(t),t,t) - m1*diff(x(t),t)).rhs sol2 = dsolve(diff(y(t),t) - r['c']*sol1 - r['d']*y(t)).rhs elif e2 == 0: sol2 = dsolve(r['c']*diff(y(t),t,t) - m2*diff(y(t),t)).rhs sol1 = dsolve(diff(x(t),t) - r['a']*x(t) - r['b']*sol2).rhs elif not (e1/r['b']).has(t) and not (m1/r['b']).has(t): sol1 = dsolve(diff(x(t),t,t) - (m1/r['b'])*diff(x(t),t) - (e1/r['b'])*x(t)).rhs sol2 = dsolve(diff(y(t),t) - r['c']*sol1 - r['d']*y(t)).rhs elif not (e2/r['c']).has(t) and not (m2/r['c']).has(t): sol2 = dsolve(diff(y(t),t,t) - (m2/r['c'])*diff(y(t),t) - (e2/r['c'])*y(t)).rhs sol1 = dsolve(diff(x(t),t) - r['a']*x(t) - r['b']*sol2).rhs else: x0 = Function('x0')(t) # x0 and y0 being particular solutions y0 = Function('y0')(t) F = exp(Integral(r['a'],t)) P = exp(Integral(r['d'],t)) sol1 = C1*x0 + C2*x0*Integral(r['b']*F*P/x0**2, t) sol2 = C1*y0 + C2*(F*P/x0 + y0*Integral(r['b']*F*P/x0**2, t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def sysode_linear_2eq_order2(match_): x = match_['func'][0].func y = match_['func'][1].func func = match_['func'] fc = match_['func_coeff'] eq = match_['eq'] r = dict() t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] for i in range(2): eqs = [] for terms in Add.make_args(eq[i]): eqs.append(terms/fc[i,func[i],2]) eq[i] = Add(*eqs) # for equations Eq(diff(x(t),t,t), a1*diff(x(t),t)+b1*diff(y(t),t)+c1*x(t)+d1*y(t)+e1) # and Eq(a2*diff(y(t),t,t), a2*diff(x(t),t)+b2*diff(y(t),t)+c2*x(t)+d2*y(t)+e2) r['a1'] = -fc[0,x(t),1]/fc[0,x(t),2] ; r['a2'] = -fc[1,x(t),1]/fc[1,y(t),2] r['b1'] = -fc[0,y(t),1]/fc[0,x(t),2] ; r['b2'] = -fc[1,y(t),1]/fc[1,y(t),2] r['c1'] = -fc[0,x(t),0]/fc[0,x(t),2] ; r['c2'] = -fc[1,x(t),0]/fc[1,y(t),2] r['d1'] = -fc[0,y(t),0]/fc[0,x(t),2] ; r['d2'] = -fc[1,y(t),0]/fc[1,y(t),2] const = [S(0), S(0)] for i in range(2): for j in Add.make_args(eq[i]): if not (j.has(x(t)) or j.has(y(t))): const[i] += j r['e1'] = -const[0] r['e2'] = -const[1] if match_['type_of_equation'] == 'type1': sol = _linear_2eq_order2_type1(x, y, t, r, eq) elif match_['type_of_equation'] == 'type2': gsol = _linear_2eq_order2_type1(x, y, t, r, eq) psol = _linear_2eq_order2_type2(x, y, t, r, eq) sol = [Eq(x(t), gsol[0].rhs+psol[0]), Eq(y(t), gsol[1].rhs+psol[1])] elif match_['type_of_equation'] == 'type3': sol = _linear_2eq_order2_type3(x, y, t, r, eq) elif match_['type_of_equation'] == 'type4': sol = _linear_2eq_order2_type4(x, y, t, r, eq) elif match_['type_of_equation'] == 'type5': sol = _linear_2eq_order2_type5(x, y, t, r, eq) elif match_['type_of_equation'] == 'type6': sol = _linear_2eq_order2_type6(x, y, t, r, eq) elif match_['type_of_equation'] == 'type7': sol = _linear_2eq_order2_type7(x, y, t, r, eq) elif match_['type_of_equation'] == 'type8': sol = _linear_2eq_order2_type8(x, y, t, r, eq) elif match_['type_of_equation'] == 'type9': sol = _linear_2eq_order2_type9(x, y, t, r, eq) elif match_['type_of_equation'] == 'type10': sol = _linear_2eq_order2_type10(x, y, t, r, eq) elif match_['type_of_equation'] == 'type11': sol = _linear_2eq_order2_type11(x, y, t, r, eq) return sol def _linear_2eq_order2_type1(x, y, t, r, eq): r""" System of two constant-coefficient second-order linear homogeneous differential equations .. math:: x'' = ax + by .. math:: y'' = cx + dy The characteristic equation for above equations .. math:: \lambda^4 - (a + d) \lambda^2 + ad - bc = 0 whose discriminant is `D = (a - d)^2 + 4bc \neq 0` 1. When `ad - bc \neq 0` 1.1. If `D \neq 0`. The characteristic equation has four distinct roots, `\lambda_1, \lambda_2, \lambda_3, \lambda_4`. The general solution of the system is .. math:: x = C_1 b e^{\lambda_1 t} + C_2 b e^{\lambda_2 t} + C_3 b e^{\lambda_3 t} + C_4 b e^{\lambda_4 t} .. math:: y = C_1 (\lambda_1^{2} - a) e^{\lambda_1 t} + C_2 (\lambda_2^{2} - a) e^{\lambda_2 t} + C_3 (\lambda_3^{2} - a) e^{\lambda_3 t} + C_4 (\lambda_4^{2} - a) e^{\lambda_4 t} where `C_1,..., C_4` are arbitrary constants. 1.2. If `D = 0` and `a \neq d`: .. math:: x = 2 C_1 (bt + \frac{2bk}{a - d}) e^{\frac{kt}{2}} + 2 C_2 (bt + \frac{2bk}{a - d}) e^{\frac{-kt}{2}} + 2b C_3 t e^{\frac{kt}{2}} + 2b C_4 t e^{\frac{-kt}{2}} .. math:: y = C_1 (d - a) t e^{\frac{kt}{2}} + C_2 (d - a) t e^{\frac{-kt}{2}} + C_3 [(d - a) t + 2k] e^{\frac{kt}{2}} + C_4 [(d - a) t - 2k] e^{\frac{-kt}{2}} where `C_1,..., C_4` are arbitrary constants and `k = \sqrt{2 (a + d)}` 1.3. If `D = 0` and `a = d \neq 0` and `b = 0`: .. math:: x = 2 \sqrt{a} C_1 e^{\sqrt{a} t} + 2 \sqrt{a} C_2 e^{-\sqrt{a} t} .. math:: y = c C_1 t e^{\sqrt{a} t} - c C_2 t e^{-\sqrt{a} t} + C_3 e^{\sqrt{a} t} + C_4 e^{-\sqrt{a} t} 1.4. If `D = 0` and `a = d \neq 0` and `c = 0`: .. math:: x = b C_1 t e^{\sqrt{a} t} - b C_2 t e^{-\sqrt{a} t} + C_3 e^{\sqrt{a} t} + C_4 e^{-\sqrt{a} t} .. math:: y = 2 \sqrt{a} C_1 e^{\sqrt{a} t} + 2 \sqrt{a} C_2 e^{-\sqrt{a} t} 2. When `ad - bc = 0` and `a^2 + b^2 > 0`. Then the original system becomes .. math:: x'' = ax + by .. math:: y'' = k (ax + by) 2.1. If `a + bk \neq 0`: .. math:: x = C_1 e^{t \sqrt{a + bk}} + C_2 e^{-t \sqrt{a + bk}} + C_3 bt + C_4 b .. math:: y = C_1 k e^{t \sqrt{a + bk}} + C_2 k e^{-t \sqrt{a + bk}} - C_3 at - C_4 a 2.2. If `a + bk = 0`: .. math:: x = C_1 b t^3 + C_2 b t^2 + C_3 t + C_4 .. math:: y = kx + 6 C_1 t + 2 C_2 """ r['a'] = r['c1'] r['b'] = r['d1'] r['c'] = r['c2'] r['d'] = r['d2'] l = Symbol('l') C1, C2, C3, C4 = get_numbered_constants(eq, num=4) chara_eq = l**4 - (r['a']+r['d'])*l**2 + r['a']*r['d'] - r['b']*r['c'] l1 = rootof(chara_eq, 0) l2 = rootof(chara_eq, 1) l3 = rootof(chara_eq, 2) l4 = rootof(chara_eq, 3) D = (r['a'] - r['d'])**2 + 4*r['b']*r['c'] if (r['a']*r['d'] - r['b']*r['c']) != 0: if D != 0: gsol1 = C1*r['b']*exp(l1*t) + C2*r['b']*exp(l2*t) + C3*r['b']*exp(l3*t) \ + C4*r['b']*exp(l4*t) gsol2 = C1*(l1**2-r['a'])*exp(l1*t) + C2*(l2**2-r['a'])*exp(l2*t) + \ C3*(l3**2-r['a'])*exp(l3*t) + C4*(l4**2-r['a'])*exp(l4*t) else: if r['a'] != r['d']: k = sqrt(2*(r['a']+r['d'])) mid = r['b']*t+2*r['b']*k/(r['a']-r['d']) gsol1 = 2*C1*mid*exp(k*t/2) + 2*C2*mid*exp(-k*t/2) + \ 2*r['b']*C3*t*exp(k*t/2) + 2*r['b']*C4*t*exp(-k*t/2) gsol2 = C1*(r['d']-r['a'])*t*exp(k*t/2) + C2*(r['d']-r['a'])*t*exp(-k*t/2) + \ C3*((r['d']-r['a'])*t+2*k)*exp(k*t/2) + C4*((r['d']-r['a'])*t-2*k)*exp(-k*t/2) elif r['a'] == r['d'] != 0 and r['b'] == 0: sa = sqrt(r['a']) gsol1 = 2*sa*C1*exp(sa*t) + 2*sa*C2*exp(-sa*t) gsol2 = r['c']*C1*t*exp(sa*t)-r['c']*C2*t*exp(-sa*t)+C3*exp(sa*t)+C4*exp(-sa*t) elif r['a'] == r['d'] != 0 and r['c'] == 0: sa = sqrt(r['a']) gsol1 = r['b']*C1*t*exp(sa*t)-r['b']*C2*t*exp(-sa*t)+C3*exp(sa*t)+C4*exp(-sa*t) gsol2 = 2*sa*C1*exp(sa*t) + 2*sa*C2*exp(-sa*t) elif (r['a']*r['d'] - r['b']*r['c']) == 0 and (r['a']**2 + r['b']**2) > 0: k = r['c']/r['a'] if r['a'] + r['b']*k != 0: mid = sqrt(r['a'] + r['b']*k) gsol1 = C1*exp(mid*t) + C2*exp(-mid*t) + C3*r['b']*t + C4*r['b'] gsol2 = C1*k*exp(mid*t) + C2*k*exp(-mid*t) - C3*r['a']*t - C4*r['a'] else: gsol1 = C1*r['b']*t**3 + C2*r['b']*t**2 + C3*t + C4 gsol2 = k*gsol1 + 6*C1*t + 2*C2 return [Eq(x(t), gsol1), Eq(y(t), gsol2)] def _linear_2eq_order2_type2(x, y, t, r, eq): r""" The equations in this type are .. math:: x'' = a_1 x + b_1 y + c_1 .. math:: y'' = a_2 x + b_2 y + c_2 The general solution of this system is given by the sum of its particular solution and the general solution of the homogeneous system. The general solution is given by the linear system of 2 equation of order 2 and type 1 1. If `a_1 b_2 - a_2 b_1 \neq 0`. A particular solution will be `x = x_0` and `y = y_0` where the constants `x_0` and `y_0` are determined by solving the linear algebraic system .. math:: a_1 x_0 + b_1 y_0 + c_1 = 0, a_2 x_0 + b_2 y_0 + c_2 = 0 2. If `a_1 b_2 - a_2 b_1 = 0` and `a_1^2 + b_1^2 > 0`. In this case, the system in question becomes .. math:: x'' = ax + by + c_1, y'' = k (ax + by) + c_2 2.1. If `\sigma = a + bk \neq 0`, the particular solution will be .. math:: x = \frac{1}{2} b \sigma^{-1} (c_1 k - c_2) t^2 - \sigma^{-2} (a c_1 + b c_2) .. math:: y = kx + \frac{1}{2} (c_2 - c_1 k) t^2 2.2. If `\sigma = a + bk = 0`, the particular solution will be .. math:: x = \frac{1}{24} b (c_2 - c_1 k) t^4 + \frac{1}{2} c_1 t^2 .. math:: y = kx + \frac{1}{2} (c_2 - c_1 k) t^2 """ x0, y0 = symbols('x0, y0') if r['c1']*r['d2'] - r['c2']*r['d1'] != 0: sol = solve((r['c1']*x0+r['d1']*y0+r['e1'], r['c2']*x0+r['d2']*y0+r['e2']), x0, y0) psol = [sol[x0], sol[y0]] elif r['c1']*r['d2'] - r['c2']*r['d1'] == 0 and (r['c1']**2 + r['d1']**2) > 0: k = r['c2']/r['c1'] sig = r['c1'] + r['d1']*k if sig != 0: psol1 = r['d1']*sig**-1*(r['e1']*k-r['e2'])*t**2/2 - \ sig**-2*(r['c1']*r['e1']+r['d1']*r['e2']) psol2 = k*psol1 + (r['e2'] - r['e1']*k)*t**2/2 psol = [psol1, psol2] else: psol1 = r['d1']*(r['e2']-r['e1']*k)*t**4/24 + r['e1']*t**2/2 psol2 = k*psol1 + (r['e2']-r['e1']*k)*t**2/2 psol = [psol1, psol2] return psol def _linear_2eq_order2_type3(x, y, t, r, eq): r""" These type of equation is used for describing the horizontal motion of a pendulum taking into account the Earth rotation. The solution is given with `a^2 + 4b > 0`: .. math:: x = C_1 \cos(\alpha t) + C_2 \sin(\alpha t) + C_3 \cos(\beta t) + C_4 \sin(\beta t) .. math:: y = -C_1 \sin(\alpha t) + C_2 \cos(\alpha t) - C_3 \sin(\beta t) + C_4 \cos(\beta t) where `C_1,...,C_4` and .. math:: \alpha = \frac{1}{2} a + \frac{1}{2} \sqrt{a^2 + 4b}, \beta = \frac{1}{2} a - \frac{1}{2} \sqrt{a^2 + 4b} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) if r['b1']**2 - 4*r['c1'] > 0: r['a'] = r['b1'] ; r['b'] = -r['c1'] alpha = r['a']/2 + sqrt(r['a']**2 + 4*r['b'])/2 beta = r['a']/2 - sqrt(r['a']**2 + 4*r['b'])/2 sol1 = C1*cos(alpha*t) + C2*sin(alpha*t) + C3*cos(beta*t) + C4*sin(beta*t) sol2 = -C1*sin(alpha*t) + C2*cos(alpha*t) - C3*sin(beta*t) + C4*cos(beta*t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type4(x, y, t, r, eq): r""" These equations are found in the theory of oscillations .. math:: x'' + a_1 x' + b_1 y' + c_1 x + d_1 y = k_1 e^{i \omega t} .. math:: y'' + a_2 x' + b_2 y' + c_2 x + d_2 y = k_2 e^{i \omega t} The general solution of this linear nonhomogeneous system of constant-coefficient differential equations is given by the sum of its particular solution and the general solution of the corresponding homogeneous system (with `k_1 = k_2 = 0`) 1. A particular solution is obtained by the method of undetermined coefficients: .. math:: x = A_* e^{i \omega t}, y = B_* e^{i \omega t} On substituting these expressions into the original system of differential equations, one arrive at a linear nonhomogeneous system of algebraic equations for the coefficients `A` and `B`. 2. The general solution of the homogeneous system of differential equations is determined by a linear combination of linearly independent particular solutions determined by the method of undetermined coefficients in the form of exponentials: .. math:: x = A e^{\lambda t}, y = B e^{\lambda t} On substituting these expressions into the original system and collecting the coefficients of the unknown `A` and `B`, one obtains .. math:: (\lambda^{2} + a_1 \lambda + c_1) A + (b_1 \lambda + d_1) B = 0 .. math:: (a_2 \lambda + c_2) A + (\lambda^{2} + b_2 \lambda + d_2) B = 0 The determinant of this system must vanish for nontrivial solutions A, B to exist. This requirement results in the following characteristic equation for `\lambda` .. math:: (\lambda^2 + a_1 \lambda + c_1) (\lambda^2 + b_2 \lambda + d_2) - (b_1 \lambda + d_1) (a_2 \lambda + c_2) = 0 If all roots `k_1,...,k_4` of this equation are distinct, the general solution of the original system of the differential equations has the form .. math:: x = C_1 (b_1 \lambda_1 + d_1) e^{\lambda_1 t} - C_2 (b_1 \lambda_2 + d_1) e^{\lambda_2 t} - C_3 (b_1 \lambda_3 + d_1) e^{\lambda_3 t} - C_4 (b_1 \lambda_4 + d_1) e^{\lambda_4 t} .. math:: y = C_1 (\lambda_1^{2} + a_1 \lambda_1 + c_1) e^{\lambda_1 t} + C_2 (\lambda_2^{2} + a_1 \lambda_2 + c_1) e^{\lambda_2 t} + C_3 (\lambda_3^{2} + a_1 \lambda_3 + c_1) e^{\lambda_3 t} + C_4 (\lambda_4^{2} + a_1 \lambda_4 + c_1) e^{\lambda_4 t} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) k = Symbol('k') Ra, Ca, Rb, Cb = symbols('Ra, Ca, Rb, Cb') a1 = r['a1'] ; a2 = r['a2'] b1 = r['b1'] ; b2 = r['b2'] c1 = r['c1'] ; c2 = r['c2'] d1 = r['d1'] ; d2 = r['d2'] k1 = r['e1'].expand().as_independent(t)[0] k2 = r['e2'].expand().as_independent(t)[0] ew1 = r['e1'].expand().as_independent(t)[1] ew2 = powdenest(ew1).as_base_exp()[1] ew3 = collect(ew2, t).coeff(t) w = cancel(ew3/I) # The particular solution is assumed to be (Ra+I*Ca)*exp(I*w*t) and # (Rb+I*Cb)*exp(I*w*t) for x(t) and y(t) respectively peq1 = (-w**2+c1)*Ra - a1*w*Ca + d1*Rb - b1*w*Cb - k1 peq2 = a1*w*Ra + (-w**2+c1)*Ca + b1*w*Rb + d1*Cb peq3 = c2*Ra - a2*w*Ca + (-w**2+d2)*Rb - b2*w*Cb - k2 peq4 = a2*w*Ra + c2*Ca + b2*w*Rb + (-w**2+d2)*Cb # FIXME: solve for what in what? Ra, Rb, etc I guess # but then psol not used for anything? psol = solve([peq1, peq2, peq3, peq4]) chareq = (k**2+a1*k+c1)*(k**2+b2*k+d2) - (b1*k+d1)*(a2*k+c2) [k1, k2, k3, k4] = roots_quartic(Poly(chareq)) sol1 = -C1*(b1*k1+d1)*exp(k1*t) - C2*(b1*k2+d1)*exp(k2*t) - \ C3*(b1*k3+d1)*exp(k3*t) - C4*(b1*k4+d1)*exp(k4*t) + (Ra+I*Ca)*exp(I*w*t) a1_ = (a1-1) sol2 = C1*(k1**2+a1_*k1+c1)*exp(k1*t) + C2*(k2**2+a1_*k2+c1)*exp(k2*t) + \ C3*(k3**2+a1_*k3+c1)*exp(k3*t) + C4*(k4**2+a1_*k4+c1)*exp(k4*t) + (Rb+I*Cb)*exp(I*w*t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type5(x, y, t, r, eq): r""" The equation which come under this category are .. math:: x'' = a (t y' - y) .. math:: y'' = b (t x' - x) The transformation .. math:: u = t x' - x, b = t y' - y leads to the first-order system .. math:: u' = atv, v' = btu The general solution of this system is given by If `ab > 0`: .. math:: u = C_1 a e^{\frac{1}{2} \sqrt{ab} t^2} + C_2 a e^{-\frac{1}{2} \sqrt{ab} t^2} .. math:: v = C_1 \sqrt{ab} e^{\frac{1}{2} \sqrt{ab} t^2} - C_2 \sqrt{ab} e^{-\frac{1}{2} \sqrt{ab} t^2} If `ab < 0`: .. math:: u = C_1 a \cos(\frac{1}{2} \sqrt{\left|ab\right|} t^2) + C_2 a \sin(-\frac{1}{2} \sqrt{\left|ab\right|} t^2) .. math:: v = C_1 \sqrt{\left|ab\right|} \sin(\frac{1}{2} \sqrt{\left|ab\right|} t^2) + C_2 \sqrt{\left|ab\right|} \cos(-\frac{1}{2} \sqrt{\left|ab\right|} t^2) where `C_1` and `C_2` are arbitrary constants. On substituting the value of `u` and `v` in above equations and integrating the resulting expressions, the general solution will become .. math:: x = C_3 t + t \int \frac{u}{t^2} \,dt, y = C_4 t + t \int \frac{u}{t^2} \,dt where `C_3` and `C_4` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) r['a'] = -r['d1'] ; r['b'] = -r['c2'] mul = sqrt(abs(r['a']*r['b'])) if r['a']*r['b'] > 0: u = C1*r['a']*exp(mul*t**2/2) + C2*r['a']*exp(-mul*t**2/2) v = C1*mul*exp(mul*t**2/2) - C2*mul*exp(-mul*t**2/2) else: u = C1*r['a']*cos(mul*t**2/2) + C2*r['a']*sin(mul*t**2/2) v = -C1*mul*sin(mul*t**2/2) + C2*mul*cos(mul*t**2/2) sol1 = C3*t + t*Integral(u/t**2, t) sol2 = C4*t + t*Integral(v/t**2, t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type6(x, y, t, r, eq): r""" The equations are .. math:: x'' = f(t) (a_1 x + b_1 y) .. math:: y'' = f(t) (a_2 x + b_2 y) If `k_1` and `k_2` are roots of the quadratic equation .. math:: k^2 - (a_1 + b_2) k + a_1 b_2 - a_2 b_1 = 0 Then by multiplying appropriate constants and adding together original equations we obtain two independent equations: .. math:: z_1'' = k_1 f(t) z_1, z_1 = a_2 x + (k_1 - a_1) y .. math:: z_2'' = k_2 f(t) z_2, z_2 = a_2 x + (k_2 - a_1) y Solving the equations will give the values of `x` and `y` after obtaining the value of `z_1` and `z_2` by solving the differential equation and substituting the result. """ k = Symbol('k') z = Function('z') num, den = cancel( (r['c1']*x(t) + r['d1']*y(t))/ (r['c2']*x(t) + r['d2']*y(t))).as_numer_denom() f = r['c1']/num.coeff(x(t)) a1 = num.coeff(x(t)) b1 = num.coeff(y(t)) a2 = den.coeff(x(t)) b2 = den.coeff(y(t)) chareq = k**2 - (a1 + b2)*k + a1*b2 - a2*b1 k1, k2 = [rootof(chareq, k) for k in range(Poly(chareq).degree())] z1 = dsolve(diff(z(t),t,t) - k1*f*z(t)).rhs z2 = dsolve(diff(z(t),t,t) - k2*f*z(t)).rhs sol1 = (k1*z2 - k2*z1 + a1*(z1 - z2))/(a2*(k1-k2)) sol2 = (z1 - z2)/(k1 - k2) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type7(x, y, t, r, eq): r""" The equations are given as .. math:: x'' = f(t) (a_1 x' + b_1 y') .. math:: y'' = f(t) (a_2 x' + b_2 y') If `k_1` and 'k_2` are roots of the quadratic equation .. math:: k^2 - (a_1 + b_2) k + a_1 b_2 - a_2 b_1 = 0 Then the system can be reduced by adding together the two equations multiplied by appropriate constants give following two independent equations: .. math:: z_1'' = k_1 f(t) z_1', z_1 = a_2 x + (k_1 - a_1) y .. math:: z_2'' = k_2 f(t) z_2', z_2 = a_2 x + (k_2 - a_1) y Integrating these and returning to the original variables, one arrives at a linear algebraic system for the unknowns `x` and `y`: .. math:: a_2 x + (k_1 - a_1) y = C_1 \int e^{k_1 F(t)} \,dt + C_2 .. math:: a_2 x + (k_2 - a_1) y = C_3 \int e^{k_2 F(t)} \,dt + C_4 where `C_1,...,C_4` are arbitrary constants and `F(t) = \int f(t) \,dt` """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) k = Symbol('k') num, den = cancel( (r['a1']*x(t) + r['b1']*y(t))/ (r['a2']*x(t) + r['b2']*y(t))).as_numer_denom() f = r['a1']/num.coeff(x(t)) a1 = num.coeff(x(t)) b1 = num.coeff(y(t)) a2 = den.coeff(x(t)) b2 = den.coeff(y(t)) chareq = k**2 - (a1 + b2)*k + a1*b2 - a2*b1 [k1, k2] = [rootof(chareq, k) for k in range(Poly(chareq).degree())] F = Integral(f, t) z1 = C1*Integral(exp(k1*F), t) + C2 z2 = C3*Integral(exp(k2*F), t) + C4 sol1 = (k1*z2 - k2*z1 + a1*(z1 - z2))/(a2*(k1-k2)) sol2 = (z1 - z2)/(k1 - k2) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type8(x, y, t, r, eq): r""" The equation of this category are .. math:: x'' = a f(t) (t y' - y) .. math:: y'' = b f(t) (t x' - x) The transformation .. math:: u = t x' - x, v = t y' - y leads to the system of first-order equations .. math:: u' = a t f(t) v, v' = b t f(t) u The general solution of this system has the form If `ab > 0`: .. math:: u = C_1 a e^{\sqrt{ab} \int t f(t) \,dt} + C_2 a e^{-\sqrt{ab} \int t f(t) \,dt} .. math:: v = C_1 \sqrt{ab} e^{\sqrt{ab} \int t f(t) \,dt} - C_2 \sqrt{ab} e^{-\sqrt{ab} \int t f(t) \,dt} If `ab < 0`: .. math:: u = C_1 a \cos(\sqrt{\left|ab\right|} \int t f(t) \,dt) + C_2 a \sin(-\sqrt{\left|ab\right|} \int t f(t) \,dt) .. math:: v = C_1 \sqrt{\left|ab\right|} \sin(\sqrt{\left|ab\right|} \int t f(t) \,dt) + C_2 \sqrt{\left|ab\right|} \cos(-\sqrt{\left|ab\right|} \int t f(t) \,dt) where `C_1` and `C_2` are arbitrary constants. On substituting the value of `u` and `v` in above equations and integrating the resulting expressions, the general solution will become .. math:: x = C_3 t + t \int \frac{u}{t^2} \,dt, y = C_4 t + t \int \frac{u}{t^2} \,dt where `C_3` and `C_4` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) num, den = cancel(r['d1']/r['c2']).as_numer_denom() f = -r['d1']/num a = num b = den mul = sqrt(abs(a*b)) Igral = Integral(t*f, t) if a*b > 0: u = C1*a*exp(mul*Igral) + C2*a*exp(-mul*Igral) v = C1*mul*exp(mul*Igral) - C2*mul*exp(-mul*Igral) else: u = C1*a*cos(mul*Igral) + C2*a*sin(mul*Igral) v = -C1*mul*sin(mul*Igral) + C2*mul*cos(mul*Igral) sol1 = C3*t + t*Integral(u/t**2, t) sol2 = C4*t + t*Integral(v/t**2, t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type9(x, y, t, r, eq): r""" .. math:: t^2 x'' + a_1 t x' + b_1 t y' + c_1 x + d_1 y = 0 .. math:: t^2 y'' + a_2 t x' + b_2 t y' + c_2 x + d_2 y = 0 These system of equations are euler type. The substitution of `t = \sigma e^{\tau} (\sigma \neq 0)` leads to the system of constant coefficient linear differential equations .. math:: x'' + (a_1 - 1) x' + b_1 y' + c_1 x + d_1 y = 0 .. math:: y'' + a_2 x' + (b_2 - 1) y' + c_2 x + d_2 y = 0 The general solution of the homogeneous system of differential equations is determined by a linear combination of linearly independent particular solutions determined by the method of undetermined coefficients in the form of exponentials .. math:: x = A e^{\lambda t}, y = B e^{\lambda t} On substituting these expressions into the original system and collecting the coefficients of the unknown `A` and `B`, one obtains .. math:: (\lambda^{2} + (a_1 - 1) \lambda + c_1) A + (b_1 \lambda + d_1) B = 0 .. math:: (a_2 \lambda + c_2) A + (\lambda^{2} + (b_2 - 1) \lambda + d_2) B = 0 The determinant of this system must vanish for nontrivial solutions A, B to exist. This requirement results in the following characteristic equation for `\lambda` .. math:: (\lambda^2 + (a_1 - 1) \lambda + c_1) (\lambda^2 + (b_2 - 1) \lambda + d_2) - (b_1 \lambda + d_1) (a_2 \lambda + c_2) = 0 If all roots `k_1,...,k_4` of this equation are distinct, the general solution of the original system of the differential equations has the form .. math:: x = C_1 (b_1 \lambda_1 + d_1) e^{\lambda_1 t} - C_2 (b_1 \lambda_2 + d_1) e^{\lambda_2 t} - C_3 (b_1 \lambda_3 + d_1) e^{\lambda_3 t} - C_4 (b_1 \lambda_4 + d_1) e^{\lambda_4 t} .. math:: y = C_1 (\lambda_1^{2} + (a_1 - 1) \lambda_1 + c_1) e^{\lambda_1 t} + C_2 (\lambda_2^{2} + (a_1 - 1) \lambda_2 + c_1) e^{\lambda_2 t} + C_3 (\lambda_3^{2} + (a_1 - 1) \lambda_3 + c_1) e^{\lambda_3 t} + C_4 (\lambda_4^{2} + (a_1 - 1) \lambda_4 + c_1) e^{\lambda_4 t} """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) k = Symbol('k') a1 = -r['a1']*t; a2 = -r['a2']*t b1 = -r['b1']*t; b2 = -r['b2']*t c1 = -r['c1']*t**2; c2 = -r['c2']*t**2 d1 = -r['d1']*t**2; d2 = -r['d2']*t**2 eq = (k**2+(a1-1)*k+c1)*(k**2+(b2-1)*k+d2)-(b1*k+d1)*(a2*k+c2) [k1, k2, k3, k4] = roots_quartic(Poly(eq)) sol1 = -C1*(b1*k1+d1)*exp(k1*log(t)) - C2*(b1*k2+d1)*exp(k2*log(t)) - \ C3*(b1*k3+d1)*exp(k3*log(t)) - C4*(b1*k4+d1)*exp(k4*log(t)) a1_ = (a1-1) sol2 = C1*(k1**2+a1_*k1+c1)*exp(k1*log(t)) + C2*(k2**2+a1_*k2+c1)*exp(k2*log(t)) \ + C3*(k3**2+a1_*k3+c1)*exp(k3*log(t)) + C4*(k4**2+a1_*k4+c1)*exp(k4*log(t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type10(x, y, t, r, eq): r""" The equation of this category are .. math:: (\alpha t^2 + \beta t + \gamma)^{2} x'' = ax + by .. math:: (\alpha t^2 + \beta t + \gamma)^{2} y'' = cx + dy The transformation .. math:: \tau = \int \frac{1}{\alpha t^2 + \beta t + \gamma} \,dt , u = \frac{x}{\sqrt{\left|\alpha t^2 + \beta t + \gamma\right|}} , v = \frac{y}{\sqrt{\left|\alpha t^2 + \beta t + \gamma\right|}} leads to a constant coefficient linear system of equations .. math:: u'' = (a - \alpha \gamma + \frac{1}{4} \beta^{2}) u + b v .. math:: v'' = c u + (d - \alpha \gamma + \frac{1}{4} \beta^{2}) v These system of equations obtained can be solved by type1 of System of two constant-coefficient second-order linear homogeneous differential equations. """ u, v = symbols('u, v', cls=Function) assert False p = Wild('p', exclude=[t, t**2]) q = Wild('q', exclude=[t, t**2]) s = Wild('s', exclude=[t, t**2]) n = Wild('n', exclude=[t, t**2]) num, den = r['c1'].as_numer_denom() dic = den.match((n*(p*t**2+q*t+s)**2).expand()) eqz = dic[p]*t**2 + dic[q]*t + dic[s] a = num/dic[n] b = cancel(r['d1']*eqz**2) c = cancel(r['c2']*eqz**2) d = cancel(r['d2']*eqz**2) [msol1, msol2] = dsolve([Eq(diff(u(t), t, t), (a - dic[p]*dic[s] + dic[q]**2/4)*u(t) \ + b*v(t)), Eq(diff(v(t),t,t), c*u(t) + (d - dic[p]*dic[s] + dic[q]**2/4)*v(t))]) sol1 = (msol1.rhs*sqrt(abs(eqz))).subs(t, Integral(1/eqz, t)) sol2 = (msol2.rhs*sqrt(abs(eqz))).subs(t, Integral(1/eqz, t)) return [Eq(x(t), sol1), Eq(y(t), sol2)] def _linear_2eq_order2_type11(x, y, t, r, eq): r""" The equations which comes under this type are .. math:: x'' = f(t) (t x' - x) + g(t) (t y' - y) .. math:: y'' = h(t) (t x' - x) + p(t) (t y' - y) The transformation .. math:: u = t x' - x, v = t y' - y leads to the linear system of first-order equations .. math:: u' = t f(t) u + t g(t) v, v' = t h(t) u + t p(t) v On substituting the value of `u` and `v` in transformed equation gives value of `x` and `y` as .. math:: x = C_3 t + t \int \frac{u}{t^2} \,dt , y = C_4 t + t \int \frac{v}{t^2} \,dt. where `C_3` and `C_4` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) u, v = symbols('u, v', cls=Function) f = -r['c1'] ; g = -r['d1'] h = -r['c2'] ; p = -r['d2'] [msol1, msol2] = dsolve([Eq(diff(u(t),t), t*f*u(t) + t*g*v(t)), Eq(diff(v(t),t), t*h*u(t) + t*p*v(t))]) sol1 = C3*t + t*Integral(msol1.rhs/t**2, t) sol2 = C4*t + t*Integral(msol2.rhs/t**2, t) return [Eq(x(t), sol1), Eq(y(t), sol2)] def sysode_linear_3eq_order1(match_): x = match_['func'][0].func y = match_['func'][1].func z = match_['func'][2].func func = match_['func'] fc = match_['func_coeff'] eq = match_['eq'] r = dict() t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] for i in range(3): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs # for equations: # Eq(g1*diff(x(t),t), a1*x(t)+b1*y(t)+c1*z(t)+d1), # Eq(g2*diff(y(t),t), a2*x(t)+b2*y(t)+c2*z(t)+d2), and # Eq(g3*diff(z(t),t), a3*x(t)+b3*y(t)+c3*z(t)+d3) r['a1'] = fc[0,x(t),0]/fc[0,x(t),1]; r['a2'] = fc[1,x(t),0]/fc[1,y(t),1]; r['a3'] = fc[2,x(t),0]/fc[2,z(t),1] r['b1'] = fc[0,y(t),0]/fc[0,x(t),1]; r['b2'] = fc[1,y(t),0]/fc[1,y(t),1]; r['b3'] = fc[2,y(t),0]/fc[2,z(t),1] r['c1'] = fc[0,z(t),0]/fc[0,x(t),1]; r['c2'] = fc[1,z(t),0]/fc[1,y(t),1]; r['c3'] = fc[2,z(t),0]/fc[2,z(t),1] for i in range(3): for j in Add.make_args(eq[i]): if not j.has(x(t), y(t), z(t)): raise NotImplementedError("Only homogeneous problems are supported, non-homogenous are not supported currently.") if match_['type_of_equation'] == 'type1': sol = _linear_3eq_order1_type1(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type2': sol = _linear_3eq_order1_type2(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type3': sol = _linear_3eq_order1_type3(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type4': sol = _linear_3eq_order1_type4(x, y, z, t, r, eq) if match_['type_of_equation'] == 'type6': sol = _linear_neq_order1_type1(match_) return sol def _linear_3eq_order1_type1(x, y, z, t, r, eq): r""" .. math:: x' = ax .. math:: y' = bx + cy .. math:: z' = dx + ky + pz Solution of such equations are forward substitution. Solving first equations gives the value of `x`, substituting it in second and third equation and solving second equation gives `y` and similarly substituting `y` in third equation give `z`. .. math:: x = C_1 e^{at} .. math:: y = \frac{b C_1}{a - c} e^{at} + C_2 e^{ct} .. math:: z = \frac{C_1}{a - p} (d + \frac{bk}{a - c}) e^{at} + \frac{k C_2}{c - p} e^{ct} + C_3 e^{pt} where `C_1, C_2` and `C_3` are arbitrary constants. """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) a = -r['a1']; b = -r['a2']; c = -r['b2'] d = -r['a3']; k = -r['b3']; p = -r['c3'] sol1 = C1*exp(a*t) sol2 = b*C1*exp(a*t)/(a-c) + C2*exp(c*t) sol3 = C1*(d+b*k/(a-c))*exp(a*t)/(a-p) + k*C2*exp(c*t)/(c-p) + C3*exp(p*t) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def _linear_3eq_order1_type2(x, y, z, t, r, eq): r""" The equations of this type are .. math:: x' = cy - bz .. math:: y' = az - cx .. math:: z' = bx - ay 1. First integral: .. math:: ax + by + cz = A \qquad - (1) .. math:: x^2 + y^2 + z^2 = B^2 \qquad - (2) where `A` and `B` are arbitrary constants. It follows from these integrals that the integral lines are circles formed by the intersection of the planes `(1)` and sphere `(2)` 2. Solution: .. math:: x = a C_0 + k C_1 \cos(kt) + (c C_2 - b C_3) \sin(kt) .. math:: y = b C_0 + k C_2 \cos(kt) + (a C_2 - c C_3) \sin(kt) .. math:: z = c C_0 + k C_3 \cos(kt) + (b C_2 - a C_3) \sin(kt) where `k = \sqrt{a^2 + b^2 + c^2}` and the four constants of integration, `C_1,...,C_4` are constrained by a single relation, .. math:: a C_1 + b C_2 + c C_3 = 0 """ C0, C1, C2, C3 = get_numbered_constants(eq, num=4, start=0) a = -r['c2']; b = -r['a3']; c = -r['b1'] k = sqrt(a**2 + b**2 + c**2) C3 = (-a*C1 - b*C2)/c sol1 = a*C0 + k*C1*cos(k*t) + (c*C2-b*C3)*sin(k*t) sol2 = b*C0 + k*C2*cos(k*t) + (a*C3-c*C1)*sin(k*t) sol3 = c*C0 + k*C3*cos(k*t) + (b*C1-a*C2)*sin(k*t) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def _linear_3eq_order1_type3(x, y, z, t, r, eq): r""" Equations of this system of ODEs .. math:: a x' = bc (y - z) .. math:: b y' = ac (z - x) .. math:: c z' = ab (x - y) 1. First integral: .. math:: a^2 x + b^2 y + c^2 z = A where A is an arbitrary constant. It follows that the integral lines are plane curves. 2. Solution: .. math:: x = C_0 + k C_1 \cos(kt) + a^{-1} bc (C_2 - C_3) \sin(kt) .. math:: y = C_0 + k C_2 \cos(kt) + a b^{-1} c (C_3 - C_1) \sin(kt) .. math:: z = C_0 + k C_3 \cos(kt) + ab c^{-1} (C_1 - C_2) \sin(kt) where `k = \sqrt{a^2 + b^2 + c^2}` and the four constants of integration, `C_1,...,C_4` are constrained by a single relation .. math:: a^2 C_1 + b^2 C_2 + c^2 C_3 = 0 """ C0, C1, C2, C3 = get_numbered_constants(eq, num=4, start=0) c = sqrt(r['b1']*r['c2']) b = sqrt(r['b1']*r['a3']) a = sqrt(r['c2']*r['a3']) C3 = (-a**2*C1-b**2*C2)/c**2 k = sqrt(a**2 + b**2 + c**2) sol1 = C0 + k*C1*cos(k*t) + a**-1*b*c*(C2-C3)*sin(k*t) sol2 = C0 + k*C2*cos(k*t) + a*b**-1*c*(C3-C1)*sin(k*t) sol3 = C0 + k*C3*cos(k*t) + a*b*c**-1*(C1-C2)*sin(k*t) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def _linear_3eq_order1_type4(x, y, z, t, r, eq): r""" Equations: .. math:: x' = (a_1 f(t) + g(t)) x + a_2 f(t) y + a_3 f(t) z .. math:: y' = b_1 f(t) x + (b_2 f(t) + g(t)) y + b_3 f(t) z .. math:: z' = c_1 f(t) x + c_2 f(t) y + (c_3 f(t) + g(t)) z The transformation .. math:: x = e^{\int g(t) \,dt} u, y = e^{\int g(t) \,dt} v, z = e^{\int g(t) \,dt} w, \tau = \int f(t) \,dt leads to the system of constant coefficient linear differential equations .. math:: u' = a_1 u + a_2 v + a_3 w .. math:: v' = b_1 u + b_2 v + b_3 w .. math:: w' = c_1 u + c_2 v + c_3 w These system of equations are solved by homogeneous linear system of constant coefficients of `n` equations of first order. Then substituting the value of `u, v` and `w` in transformed equation gives value of `x, y` and `z`. """ u, v, w = symbols('u, v, w', cls=Function) a2, a3 = cancel(r['b1']/r['c1']).as_numer_denom() f = cancel(r['b1']/a2) b1 = cancel(r['a2']/f); b3 = cancel(r['c2']/f) c1 = cancel(r['a3']/f); c2 = cancel(r['b3']/f) a1, g = div(r['a1'],f) b2 = div(r['b2'],f)[0] c3 = div(r['c3'],f)[0] trans_eq = (diff(u(t),t)-a1*u(t)-a2*v(t)-a3*w(t), diff(v(t),t)-b1*u(t)-\ b2*v(t)-b3*w(t), diff(w(t),t)-c1*u(t)-c2*v(t)-c3*w(t)) sol = dsolve(trans_eq) sol1 = exp(Integral(g,t))*((sol[0].rhs).subs(t, Integral(f,t))) sol2 = exp(Integral(g,t))*((sol[1].rhs).subs(t, Integral(f,t))) sol3 = exp(Integral(g,t))*((sol[2].rhs).subs(t, Integral(f,t))) return [Eq(x(t), sol1), Eq(y(t), sol2), Eq(z(t), sol3)] def sysode_linear_neq_order1(match_): sol = _linear_neq_order1_type1(match_) return sol def _linear_neq_order1_type1(match_): r""" System of n first-order constant-coefficient linear nonhomogeneous differential equation .. math:: y'_k = a_{k1} y_1 + a_{k2} y_2 +...+ a_{kn} y_n; k = 1,2,...,n or that can be written as `\vec{y'} = A . \vec{y}` where `\vec{y}` is matrix of `y_k` for `k = 1,2,...n` and `A` is a `n \times n` matrix. Since these equations are equivalent to a first order homogeneous linear differential equation. So the general solution will contain `n` linearly independent parts and solution will consist some type of exponential functions. Assuming `y = \vec{v} e^{rt}` is a solution of the system where `\vec{v}` is a vector of coefficients of `y_1,...,y_n`. Substituting `y` and `y' = r v e^{r t}` into the equation `\vec{y'} = A . \vec{y}`, we get .. math:: r \vec{v} e^{rt} = A \vec{v} e^{rt} .. math:: r \vec{v} = A \vec{v} where `r` comes out to be eigenvalue of `A` and vector `\vec{v}` is the eigenvector of `A` corresponding to `r`. There are three possibilities of eigenvalues of `A` - `n` distinct real eigenvalues - complex conjugate eigenvalues - eigenvalues with multiplicity `k` 1. When all eigenvalues `r_1,..,r_n` are distinct with `n` different eigenvectors `v_1,...v_n` then the solution is given by .. math:: \vec{y} = C_1 e^{r_1 t} \vec{v_1} + C_2 e^{r_2 t} \vec{v_2} +...+ C_n e^{r_n t} \vec{v_n} where `C_1,C_2,...,C_n` are arbitrary constants. 2. When some eigenvalues are complex then in order to make the solution real, we take a linear combination: if `r = a + bi` has an eigenvector `\vec{v} = \vec{w_1} + i \vec{w_2}` then to obtain real-valued solutions to the system, replace the complex-valued solutions `e^{rx} \vec{v}` with real-valued solution `e^{ax} (\vec{w_1} \cos(bx) - \vec{w_2} \sin(bx))` and for `r = a - bi` replace the solution `e^{-r x} \vec{v}` with `e^{ax} (\vec{w_1} \sin(bx) + \vec{w_2} \cos(bx))` 3. If some eigenvalues are repeated. Then we get fewer than `n` linearly independent eigenvectors, we miss some of the solutions and need to construct the missing ones. We do this via generalized eigenvectors, vectors which are not eigenvectors but are close enough that we can use to write down the remaining solutions. For a eigenvalue `r` with eigenvector `\vec{w}` we obtain `\vec{w_2},...,\vec{w_k}` using .. math:: (A - r I) . \vec{w_2} = \vec{w} .. math:: (A - r I) . \vec{w_3} = \vec{w_2} .. math:: \vdots .. math:: (A - r I) . \vec{w_k} = \vec{w_{k-1}} Then the solutions to the system for the eigenspace are `e^{rt} [\vec{w}], e^{rt} [t \vec{w} + \vec{w_2}], e^{rt} [\frac{t^2}{2} \vec{w} + t \vec{w_2} + \vec{w_3}], ...,e^{rt} [\frac{t^{k-1}}{(k-1)!} \vec{w} + \frac{t^{k-2}}{(k-2)!} \vec{w_2} +...+ t \vec{w_{k-1}} + \vec{w_k}]` So, If `\vec{y_1},...,\vec{y_n}` are `n` solution of obtained from three categories of `A`, then general solution to the system `\vec{y'} = A . \vec{y}` .. math:: \vec{y} = C_1 \vec{y_1} + C_2 \vec{y_2} + \cdots + C_n \vec{y_n} """ eq = match_['eq'] func = match_['func'] fc = match_['func_coeff'] n = len(eq) t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] constants = numbered_symbols(prefix='C', cls=Symbol, start=1) M = Matrix(n,n,lambda i,j:-fc[i,func[j],0]) evector = M.eigenvects(simplify=True) def is_complex(mat, root): return Matrix(n, 1, lambda i,j: re(mat[i])*cos(im(root)*t) - im(mat[i])*sin(im(root)*t)) def is_complex_conjugate(mat, root): return Matrix(n, 1, lambda i,j: re(mat[i])*sin(abs(im(root))*t) + im(mat[i])*cos(im(root)*t)*abs(im(root))/im(root)) conjugate_root = [] e_vector = zeros(n,1) for evects in evector: if evects[0] not in conjugate_root: # If number of column of an eigenvector is not equal to the multiplicity # of its eigenvalue then the legt eigenvectors are calculated if len(evects[2])!=evects[1]: var_mat = Matrix(n, 1, lambda i,j: Symbol('x'+str(i))) Mnew = (M - evects[0]*eye(evects[2][-1].rows))*var_mat w = [0 for i in range(evects[1])] w[0] = evects[2][-1] for r in range(1, evects[1]): w_ = Mnew - w[r-1] sol_dict = solve(list(w_), var_mat[1:]) sol_dict[var_mat[0]] = var_mat[0] for key, value in sol_dict.items(): sol_dict[key] = value.subs(var_mat[0],1) w[r] = Matrix(n, 1, lambda i,j: sol_dict[var_mat[i]]) evects[2].append(w[r]) for i in range(evects[1]): C = next(constants) for j in range(i+1): if evects[0].has(I): evects[2][j] = simplify(evects[2][j]) e_vector += C*is_complex(evects[2][j], evects[0])*t**(i-j)*exp(re(evects[0])*t)/factorial(i-j) C = next(constants) e_vector += C*is_complex_conjugate(evects[2][j], evects[0])*t**(i-j)*exp(re(evects[0])*t)/factorial(i-j) else: e_vector += C*evects[2][j]*t**(i-j)*exp(evects[0]*t)/factorial(i-j) if evects[0].has(I): conjugate_root.append(conjugate(evects[0])) sol = [] for i in range(len(eq)): sol.append(Eq(func[i],e_vector[i])) return sol def sysode_nonlinear_2eq_order1(match_): func = match_['func'] eq = match_['eq'] fc = match_['func_coeff'] t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] if match_['type_of_equation'] == 'type5': sol = _nonlinear_2eq_order1_type5(func, t, eq) return sol x = func[0].func y = func[1].func for i in range(2): eqs = 0 for terms in Add.make_args(eq[i]): eqs += terms/fc[i,func[i],1] eq[i] = eqs if match_['type_of_equation'] == 'type1': sol = _nonlinear_2eq_order1_type1(x, y, t, eq) elif match_['type_of_equation'] == 'type2': sol = _nonlinear_2eq_order1_type2(x, y, t, eq) elif match_['type_of_equation'] == 'type3': sol = _nonlinear_2eq_order1_type3(x, y, t, eq) elif match_['type_of_equation'] == 'type4': sol = _nonlinear_2eq_order1_type4(x, y, t, eq) return sol def _nonlinear_2eq_order1_type1(x, y, t, eq): r""" Equations: .. math:: x' = x^n F(x,y) .. math:: y' = g(y) F(x,y) Solution: .. math:: x = \varphi(y), \int \frac{1}{g(y) F(\varphi(y),y)} \,dy = t + C_2 where if `n \neq 1` .. math:: \varphi = [C_1 + (1-n) \int \frac{1}{g(y)} \,dy]^{\frac{1}{1-n}} if `n = 1` .. math:: \varphi = C_1 e^{\int \frac{1}{g(y)} \,dy} where `C_1` and `C_2` are arbitrary constants. """ C1, C2 = get_numbered_constants(eq, num=2) n = Wild('n', exclude=[x(t),y(t)]) f = Wild('f') u, v = symbols('u, v') r = eq[0].match(diff(x(t),t) - x(t)**n*f) g = ((diff(y(t),t) - eq[1])/r[f]).subs(y(t),v) F = r[f].subs(x(t),u).subs(y(t),v) n = r[n] if n!=1: phi = (C1 + (1-n)*Integral(1/g, v))**(1/(1-n)) else: phi = C1*exp(Integral(1/g, v)) phi = phi.doit() sol2 = solve(Integral(1/(g*F.subs(u,phi)), v).doit() - t - C2, v) sol = [] for sols in sol2: sol.append(Eq(x(t),phi.subs(v, sols))) sol.append(Eq(y(t), sols)) return sol def _nonlinear_2eq_order1_type2(x, y, t, eq): r""" Equations: .. math:: x' = e^{\lambda x} F(x,y) .. math:: y' = g(y) F(x,y) Solution: .. math:: x = \varphi(y), \int \frac{1}{g(y) F(\varphi(y),y)} \,dy = t + C_2 where if `\lambda \neq 0` .. math:: \varphi = -\frac{1}{\lambda} log(C_1 - \lambda \int \frac{1}{g(y)} \,dy) if `\lambda = 0` .. math:: \varphi = C_1 + \int \frac{1}{g(y)} \,dy where `C_1` and `C_2` are arbitrary constants. """ C1, C2 = get_numbered_constants(eq, num=2) n = Wild('n', exclude=[x(t),y(t)]) f = Wild('f') u, v = symbols('u, v') r = eq[0].match(diff(x(t),t) - exp(n*x(t))*f) g = ((diff(y(t),t) - eq[1])/r[f]).subs(y(t),v) F = r[f].subs(x(t),u).subs(y(t),v) n = r[n] if n: phi = -1/n*log(C1 - n*Integral(1/g, v)) else: phi = C1 + Integral(1/g, v) phi = phi.doit() sol2 = solve(Integral(1/(g*F.subs(u,phi)), v).doit() - t - C2, v) sol = [] for sols in sol2: sol.append(Eq(x(t),phi.subs(v, sols))) sol.append(Eq(y(t), sols)) return sol def _nonlinear_2eq_order1_type3(x, y, t, eq): r""" Autonomous system of general form .. math:: x' = F(x,y) .. math:: y' = G(x,y) Assuming `y = y(x, C_1)` where `C_1` is an arbitrary constant is the general solution of the first-order equation .. math:: F(x,y) y'_x = G(x,y) Then the general solution of the original system of equations has the form .. math:: \int \frac{1}{F(x,y(x,C_1))} \,dx = t + C_1 """ C1, C2, C3, C4 = get_numbered_constants(eq, num=4) v = Function('v') u = Symbol('u') f = Wild('f') g = Wild('g') r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) F = r1[f].subs(x(t), u).subs(y(t), v(u)) G = r2[g].subs(x(t), u).subs(y(t), v(u)) sol2r = dsolve(Eq(diff(v(u), u), G/F)) for sol2s in sol2r: sol1 = solve(Integral(1/F.subs(v(u), sol2s.rhs), u).doit() - t - C2, u) sol = [] for sols in sol1: sol.append(Eq(x(t), sols)) sol.append(Eq(y(t), (sol2s.rhs).subs(u, sols))) return sol def _nonlinear_2eq_order1_type4(x, y, t, eq): r""" Equation: .. math:: x' = f_1(x) g_1(y) \phi(x,y,t) .. math:: y' = f_2(x) g_2(y) \phi(x,y,t) First integral: .. math:: \int \frac{f_2(x)}{f_1(x)} \,dx - \int \frac{g_1(y)}{g_2(y)} \,dy = C where `C` is an arbitrary constant. On solving the first integral for `x` (resp., `y` ) and on substituting the resulting expression into either equation of the original solution, one arrives at a first-order equation for determining `y` (resp., `x` ). """ C1, C2 = get_numbered_constants(eq, num=2) u, v = symbols('u, v') U, V = symbols('U, V', cls=Function) f = Wild('f') g = Wild('g') f1 = Wild('f1', exclude=[v,t]) f2 = Wild('f2', exclude=[v,t]) g1 = Wild('g1', exclude=[u,t]) g2 = Wild('g2', exclude=[u,t]) r1 = eq[0].match(diff(x(t),t) - f) r2 = eq[1].match(diff(y(t),t) - g) num, den = ( (r1[f].subs(x(t),u).subs(y(t),v))/ (r2[g].subs(x(t),u).subs(y(t),v))).as_numer_denom() R1 = num.match(f1*g1) R2 = den.match(f2*g2) phi = (r1[f].subs(x(t),u).subs(y(t),v))/num F1 = R1[f1]; F2 = R2[f2] G1 = R1[g1]; G2 = R2[g2] sol1r = solve(Integral(F2/F1, u).doit() - Integral(G1/G2,v).doit() - C1, u) sol2r = solve(Integral(F2/F1, u).doit() - Integral(G1/G2,v).doit() - C1, v) sol = [] for sols in sol1r: sol.append(Eq(y(t), dsolve(diff(V(t),t) - F2.subs(u,sols).subs(v,V(t))*G2.subs(v,V(t))*phi.subs(u,sols).subs(v,V(t))).rhs)) for sols in sol2r: sol.append(Eq(x(t), dsolve(diff(U(t),t) - F1.subs(u,U(t))*G1.subs(v,sols).subs(u,U(t))*phi.subs(v,sols).subs(u,U(t))).rhs)) return set(sol) def _nonlinear_2eq_order1_type5(func, t, eq): r""" Clairaut system of ODEs .. math:: x = t x' + F(x',y') .. math:: y = t y' + G(x',y') The following are solutions of the system `(i)` straight lines: .. math:: x = C_1 t + F(C_1, C_2), y = C_2 t + G(C_1, C_2) where `C_1` and `C_2` are arbitrary constants; `(ii)` envelopes of the above lines; `(iii)` continuously differentiable lines made up from segments of the lines `(i)` and `(ii)`. """ C1, C2 = get_numbered_constants(eq, num=2) f = Wild('f') g = Wild('g') def check_type(x, y): r1 = eq[0].match(t*diff(x(t),t) - x(t) + f) r2 = eq[1].match(t*diff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = eq[0].match(diff(x(t),t) - x(t)/t + f/t) r2 = eq[1].match(diff(y(t),t) - y(t)/t + g/t) if not (r1 and r2): r1 = (-eq[0]).match(t*diff(x(t),t) - x(t) + f) r2 = (-eq[1]).match(t*diff(y(t),t) - y(t) + g) if not (r1 and r2): r1 = (-eq[0]).match(diff(x(t),t) - x(t)/t + f/t) r2 = (-eq[1]).match(diff(y(t),t) - y(t)/t + g/t) return [r1, r2] for func_ in func: if isinstance(func_, list): x = func[0][0].func y = func[0][1].func [r1, r2] = check_type(x, y) if not (r1 and r2): [r1, r2] = check_type(y, x) x, y = y, x x1 = diff(x(t),t); y1 = diff(y(t),t) return {Eq(x(t), C1*t + r1[f].subs(x1,C1).subs(y1,C2)), Eq(y(t), C2*t + r2[g].subs(x1,C1).subs(y1,C2))} def sysode_nonlinear_3eq_order1(match_): x = match_['func'][0].func y = match_['func'][1].func z = match_['func'][2].func eq = match_['eq'] t = list(list(eq[0].atoms(Derivative))[0].atoms(Symbol))[0] if match_['type_of_equation'] == 'type1': sol = _nonlinear_3eq_order1_type1(x, y, z, t, eq) if match_['type_of_equation'] == 'type2': sol = _nonlinear_3eq_order1_type2(x, y, z, t, eq) if match_['type_of_equation'] == 'type3': sol = _nonlinear_3eq_order1_type3(x, y, z, t, eq) if match_['type_of_equation'] == 'type4': sol = _nonlinear_3eq_order1_type4(x, y, z, t, eq) if match_['type_of_equation'] == 'type5': sol = _nonlinear_3eq_order1_type5(x, y, z, t, eq) return sol def _nonlinear_3eq_order1_type1(x, y, z, t, eq): r""" Equations: .. math:: a x' = (b - c) y z, \enspace b y' = (c - a) z x, \enspace c z' = (a - b) x y First Integrals: .. math:: a x^{2} + b y^{2} + c z^{2} = C_1 .. math:: a^{2} x^{2} + b^{2} y^{2} + c^{2} z^{2} = C_2 where `C_1` and `C_2` are arbitrary constants. On solving the integrals for `y` and `z` and on substituting the resulting expressions into the first equation of the system, we arrives at a separable first-order equation on `x`. Similarly doing that for other two equations, we will arrive at first order equation on `y` and `z` too. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0401.pdf """ C1, C2 = get_numbered_constants(eq, num=2) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) r = (diff(x(t),t) - eq[0]).match(p*y(t)*z(t)) r.update((diff(y(t),t) - eq[1]).match(q*z(t)*x(t))) r.update((diff(z(t),t) - eq[2]).match(s*x(t)*y(t))) n1, d1 = r[p].as_numer_denom() n2, d2 = r[q].as_numer_denom() n3, d3 = r[s].as_numer_denom() val = solve([n1*u-d1*v+d1*w, d2*u+n2*v-d2*w, d3*u-d3*v-n3*w],[u,v]) vals = [val[v], val[u]] c = lcm(vals[0].as_numer_denom()[1], vals[1].as_numer_denom()[1]) b = vals[0].subs(w, c) a = vals[1].subs(w, c) y_x = sqrt(((c*C1-C2) - a*(c-a)*x(t)**2)/(b*(c-b))) z_x = sqrt(((b*C1-C2) - a*(b-a)*x(t)**2)/(c*(b-c))) z_y = sqrt(((a*C1-C2) - b*(a-b)*y(t)**2)/(c*(a-c))) x_y = sqrt(((c*C1-C2) - b*(c-b)*y(t)**2)/(a*(c-a))) x_z = sqrt(((b*C1-C2) - c*(b-c)*z(t)**2)/(a*(b-a))) y_z = sqrt(((a*C1-C2) - c*(a-c)*z(t)**2)/(b*(a-b))) sol1 = dsolve(a*diff(x(t),t) - (b-c)*y_x*z_x) sol2 = dsolve(b*diff(y(t),t) - (c-a)*z_y*x_y) sol3 = dsolve(c*diff(z(t),t) - (a-b)*x_z*y_z) return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type2(x, y, z, t, eq): r""" Equations: .. math:: a x' = (b - c) y z f(x, y, z, t) .. math:: b y' = (c - a) z x f(x, y, z, t) .. math:: c z' = (a - b) x y f(x, y, z, t) First Integrals: .. math:: a x^{2} + b y^{2} + c z^{2} = C_1 .. math:: a^{2} x^{2} + b^{2} y^{2} + c^{2} z^{2} = C_2 where `C_1` and `C_2` are arbitrary constants. On solving the integrals for `y` and `z` and on substituting the resulting expressions into the first equation of the system, we arrives at a first-order differential equations on `x`. Similarly doing that for other two equations we will arrive at first order equation on `y` and `z`. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0402.pdf """ C1, C2 = get_numbered_constants(eq, num=2) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) f = Wild('f') r1 = (diff(x(t),t) - eq[0]).match(y(t)*z(t)*f) r = collect_const(r1[f]).match(p*f) r.update(((diff(y(t),t) - eq[1])/r[f]).match(q*z(t)*x(t))) r.update(((diff(z(t),t) - eq[2])/r[f]).match(s*x(t)*y(t))) n1, d1 = r[p].as_numer_denom() n2, d2 = r[q].as_numer_denom() n3, d3 = r[s].as_numer_denom() val = solve([n1*u-d1*v+d1*w, d2*u+n2*v-d2*w, -d3*u+d3*v+n3*w],[u,v]) vals = [val[v], val[u]] c = lcm(vals[0].as_numer_denom()[1], vals[1].as_numer_denom()[1]) a = vals[0].subs(w, c) b = vals[1].subs(w, c) y_x = sqrt(((c*C1-C2) - a*(c-a)*x(t)**2)/(b*(c-b))) z_x = sqrt(((b*C1-C2) - a*(b-a)*x(t)**2)/(c*(b-c))) z_y = sqrt(((a*C1-C2) - b*(a-b)*y(t)**2)/(c*(a-c))) x_y = sqrt(((c*C1-C2) - b*(c-b)*y(t)**2)/(a*(c-a))) x_z = sqrt(((b*C1-C2) - c*(b-c)*z(t)**2)/(a*(b-a))) y_z = sqrt(((a*C1-C2) - c*(a-c)*z(t)**2)/(b*(a-b))) sol1 = dsolve(a*diff(x(t),t) - (b-c)*y_x*z_x*r[f]) sol2 = dsolve(b*diff(y(t),t) - (c-a)*z_y*x_y*r[f]) sol3 = dsolve(c*diff(z(t),t) - (a-b)*x_z*y_z*r[f]) return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type3(x, y, z, t, eq): r""" Equations: .. math:: x' = c F_2 - b F_3, \enspace y' = a F_3 - c F_1, \enspace z' = b F_1 - a F_2 where `F_n = F_n(x, y, z, t)`. 1. First Integral: .. math:: a x + b y + c z = C_1, where C is an arbitrary constant. 2. If we assume function `F_n` to be independent of `t`,i.e, `F_n` = `F_n (x, y, z)` Then, on eliminating `t` and `z` from the first two equation of the system, one arrives at the first-order equation .. math:: \frac{dy}{dx} = \frac{a F_3 (x, y, z) - c F_1 (x, y, z)}{c F_2 (x, y, z) - b F_3 (x, y, z)} where `z = \frac{1}{c} (C_1 - a x - b y)` References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0404.pdf """ C1 = get_numbered_constants(eq, num=1) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) F1, F2, F3 = symbols('F1, F2, F3', cls=Wild) r1 = (diff(x(t), t) - eq[0]).match(F2-F3) r = collect_const(r1[F2]).match(s*F2) r.update(collect_const(r1[F3]).match(q*F3)) if eq[1].has(r[F2]) and not eq[1].has(r[F3]): r[F2], r[F3] = r[F3], r[F2] r[s], r[q] = -r[q], -r[s] r.update((diff(y(t), t) - eq[1]).match(p*r[F3] - r[s]*F1)) a = r[p]; b = r[q]; c = r[s] F1 = r[F1].subs(x(t), u).subs(y(t),v).subs(z(t), w) F2 = r[F2].subs(x(t), u).subs(y(t),v).subs(z(t), w) F3 = r[F3].subs(x(t), u).subs(y(t),v).subs(z(t), w) z_xy = (C1-a*u-b*v)/c y_zx = (C1-a*u-c*w)/b x_yz = (C1-b*v-c*w)/a y_x = dsolve(diff(v(u),u) - ((a*F3-c*F1)/(c*F2-b*F3)).subs(w,z_xy).subs(v,v(u))).rhs z_x = dsolve(diff(w(u),u) - ((b*F1-a*F2)/(c*F2-b*F3)).subs(v,y_zx).subs(w,w(u))).rhs z_y = dsolve(diff(w(v),v) - ((b*F1-a*F2)/(a*F3-c*F1)).subs(u,x_yz).subs(w,w(v))).rhs x_y = dsolve(diff(u(v),v) - ((c*F2-b*F3)/(a*F3-c*F1)).subs(w,z_xy).subs(u,u(v))).rhs y_z = dsolve(diff(v(w),w) - ((a*F3-c*F1)/(b*F1-a*F2)).subs(u,x_yz).subs(v,v(w))).rhs x_z = dsolve(diff(u(w),w) - ((c*F2-b*F3)/(b*F1-a*F2)).subs(v,y_zx).subs(u,u(w))).rhs sol1 = dsolve(diff(u(t),t) - (c*F2 - b*F3).subs(v,y_x).subs(w,z_x).subs(u,u(t))).rhs sol2 = dsolve(diff(v(t),t) - (a*F3 - c*F1).subs(u,x_y).subs(w,z_y).subs(v,v(t))).rhs sol3 = dsolve(diff(w(t),t) - (b*F1 - a*F2).subs(u,x_z).subs(v,y_z).subs(w,w(t))).rhs return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type4(x, y, z, t, eq): r""" Equations: .. math:: x' = c z F_2 - b y F_3, \enspace y' = a x F_3 - c z F_1, \enspace z' = b y F_1 - a x F_2 where `F_n = F_n (x, y, z, t)` 1. First integral: .. math:: a x^{2} + b y^{2} + c z^{2} = C_1 where `C` is an arbitrary constant. 2. Assuming the function `F_n` is independent of `t`: `F_n = F_n (x, y, z)`. Then on eliminating `t` and `z` from the first two equations of the system, one arrives at the first-order equation .. math:: \frac{dy}{dx} = \frac{a x F_3 (x, y, z) - c z F_1 (x, y, z)} {c z F_2 (x, y, z) - b y F_3 (x, y, z)} where `z = \pm \sqrt{\frac{1}{c} (C_1 - a x^{2} - b y^{2})}` References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0405.pdf """ C1 = get_numbered_constants(eq, num=1) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) F1, F2, F3 = symbols('F1, F2, F3', cls=Wild) r1 = eq[0].match(diff(x(t),t) - z(t)*F2 + y(t)*F3) r = collect_const(r1[F2]).match(s*F2) r.update(collect_const(r1[F3]).match(q*F3)) if eq[1].has(r[F2]) and not eq[1].has(r[F3]): r[F2], r[F3] = r[F3], r[F2] r[s], r[q] = -r[q], -r[s] r.update((diff(y(t),t) - eq[1]).match(p*x(t)*r[F3] - r[s]*z(t)*F1)) a = r[p]; b = r[q]; c = r[s] F1 = r[F1].subs(x(t),u).subs(y(t),v).subs(z(t),w) F2 = r[F2].subs(x(t),u).subs(y(t),v).subs(z(t),w) F3 = r[F3].subs(x(t),u).subs(y(t),v).subs(z(t),w) x_yz = sqrt((C1 - b*v**2 - c*w**2)/a) y_zx = sqrt((C1 - c*w**2 - a*u**2)/b) z_xy = sqrt((C1 - a*u**2 - b*v**2)/c) y_x = dsolve(diff(v(u),u) - ((a*u*F3-c*w*F1)/(c*w*F2-b*v*F3)).subs(w,z_xy).subs(v,v(u))).rhs z_x = dsolve(diff(w(u),u) - ((b*v*F1-a*u*F2)/(c*w*F2-b*v*F3)).subs(v,y_zx).subs(w,w(u))).rhs z_y = dsolve(diff(w(v),v) - ((b*v*F1-a*u*F2)/(a*u*F3-c*w*F1)).subs(u,x_yz).subs(w,w(v))).rhs x_y = dsolve(diff(u(v),v) - ((c*w*F2-b*v*F3)/(a*u*F3-c*w*F1)).subs(w,z_xy).subs(u,u(v))).rhs y_z = dsolve(diff(v(w),w) - ((a*u*F3-c*w*F1)/(b*v*F1-a*u*F2)).subs(u,x_yz).subs(v,v(w))).rhs x_z = dsolve(diff(u(w),w) - ((c*w*F2-b*v*F3)/(b*v*F1-a*u*F2)).subs(v,y_zx).subs(u,u(w))).rhs sol1 = dsolve(diff(u(t),t) - (c*w*F2 - b*v*F3).subs(v,y_x).subs(w,z_x).subs(u,u(t))).rhs sol2 = dsolve(diff(v(t),t) - (a*u*F3 - c*w*F1).subs(u,x_y).subs(w,z_y).subs(v,v(t))).rhs sol3 = dsolve(diff(w(t),t) - (b*v*F1 - a*u*F2).subs(u,x_z).subs(v,y_z).subs(w,w(t))).rhs return [sol1, sol2, sol3] def _nonlinear_3eq_order1_type5(x, y, z, t, eq): r""" .. math:: x' = x (c F_2 - b F_3), \enspace y' = y (a F_3 - c F_1), \enspace z' = z (b F_1 - a F_2) where `F_n = F_n (x, y, z, t)` and are arbitrary functions. First Integral: .. math:: \left|x\right|^{a} \left|y\right|^{b} \left|z\right|^{c} = C_1 where `C` is an arbitrary constant. If the function `F_n` is independent of `t`, then, by eliminating `t` and `z` from the first two equations of the system, one arrives at a first-order equation. References ========== -http://eqworld.ipmnet.ru/en/solutions/sysode/sode0406.pdf """ C1 = get_numbered_constants(eq, num=1) u, v, w = symbols('u, v, w') p = Wild('p', exclude=[x(t), y(t), z(t), t]) q = Wild('q', exclude=[x(t), y(t), z(t), t]) s = Wild('s', exclude=[x(t), y(t), z(t), t]) F1, F2, F3 = symbols('F1, F2, F3', cls=Wild) r1 = eq[0].match(diff(x(t), t) - x(t)*(F2 - F3)) r = collect_const(r1[F2]).match(s*F2) r.update(collect_const(r1[F3]).match(q*F3)) if eq[1].has(r[F2]) and not eq[1].has(r[F3]): r[F2], r[F3] = r[F3], r[F2] r[s], r[q] = -r[q], -r[s] r.update((diff(y(t), t) - eq[1]).match(y(t)*(p*r[F3] - r[s]*F1))) a = r[p]; b = r[q]; c = r[s] F1 = r[F1].subs(x(t), u).subs(y(t), v).subs(z(t), w) F2 = r[F2].subs(x(t), u).subs(y(t), v).subs(z(t), w) F3 = r[F3].subs(x(t), u).subs(y(t), v).subs(z(t), w) x_yz = (C1*v**-b*w**-c)**-a y_zx = (C1*w**-c*u**-a)**-b z_xy = (C1*u**-a*v**-b)**-c y_x = dsolve(diff(v(u), u) - ((v*(a*F3 - c*F1))/(u*(c*F2 - b*F3))).subs(w, z_xy).subs(v, v(u))).rhs z_x = dsolve(diff(w(u), u) - ((w*(b*F1 - a*F2))/(u*(c*F2 - b*F3))).subs(v, y_zx).subs(w, w(u))).rhs z_y = dsolve(diff(w(v), v) - ((w*(b*F1 - a*F2))/(v*(a*F3 - c*F1))).subs(u, x_yz).subs(w, w(v))).rhs x_y = dsolve(diff(u(v), v) - ((u*(c*F2 - b*F3))/(v*(a*F3 - c*F1))).subs(w, z_xy).subs(u, u(v))).rhs y_z = dsolve(diff(v(w), w) - ((v*(a*F3 - c*F1))/(w*(b*F1 - a*F2))).subs(u, x_yz).subs(v, v(w))).rhs x_z = dsolve(diff(u(w), w) - ((u*(c*F2 - b*F3))/(w*(b*F1 - a*F2))).subs(v, y_zx).subs(u, u(w))).rhs sol1 = dsolve(diff(u(t), t) - (u*(c*F2 - b*F3)).subs(v, y_x).subs(w, z_x).subs(u, u(t))).rhs sol2 = dsolve(diff(v(t), t) - (v*(a*F3 - c*F1)).subs(u, x_y).subs(w, z_y).subs(v, v(t))).rhs sol3 = dsolve(diff(w(t), t) - (w*(b*F1 - a*F2)).subs(u, x_z).subs(v, y_z).subs(w, w(t))).rhs return [sol1, sol2, sol3]

9905b5bef7330ece978fcff4a4b0f2187692c7f087efa7537f11f567d200d649

""" This module contains functions to: - solve a single equation for a single variable, in any domain either real or complex. - solve a single transcendental equation for a single variable in any domain either real or complex. (currently supports solving in real domain only) - solve a system of linear equations with N variables and M equations. - solve a system of Non Linear Equations with N variables and M equations """ from __future__ import print_function, division from sympy.core.sympify import sympify from sympy.core import (S, Pow, Dummy, pi, Expr, Wild, Mul, Equality, Add) from sympy.core.containers import Tuple from sympy.core.facts import InconsistentAssumptions from sympy.core.numbers import I, Number, Rational, oo from sympy.core.function import (Lambda, expand_complex, AppliedUndef, expand_log, _mexpand) from sympy.core.relational import Eq, Ne from sympy.core.symbol import Symbol from sympy.core.sympify import _sympify from sympy.simplify.simplify import simplify, fraction, trigsimp from sympy.simplify import powdenest, logcombine from sympy.functions import (log, Abs, tan, cot, sin, cos, sec, csc, exp, acos, asin, acsc, asec, arg, piecewise_fold, Piecewise) from sympy.functions.elementary.trigonometric import (TrigonometricFunction, HyperbolicFunction) from sympy.functions.elementary.miscellaneous import real_root from sympy.logic.boolalg import And from sympy.sets import (FiniteSet, EmptySet, imageset, Interval, Intersection, Union, ConditionSet, ImageSet, Complement, Contains) from sympy.sets.sets import Set from sympy.matrices import Matrix, MatrixBase from sympy.polys import (roots, Poly, degree, together, PolynomialError, RootOf, factor) from sympy.polys.polyerrors import CoercionFailed from sympy.solvers.solvers import (checksol, denoms, unrad, _simple_dens, recast_to_symbols) from sympy.solvers.polysys import solve_poly_system from sympy.solvers.inequalities import solve_univariate_inequality from sympy.utilities import filldedent from sympy.utilities.iterables import numbered_symbols, has_dups from sympy.calculus.util import periodicity, continuous_domain from sympy.core.compatibility import ordered, default_sort_key, is_sequence from types import GeneratorType from collections import defaultdict def _masked(f, *atoms): """Return ``f``, with all objects given by ``atoms`` replaced with Dummy symbols, ``d``, and the list of replacements, ``(d, e)``, where ``e`` is an object of type given by ``atoms`` in which any other instances of atoms have been recursively replaced with Dummy symbols, too. The tuples are ordered so that if they are applied in sequence, the origin ``f`` will be restored. Examples ======== >>> from sympy import cos >>> from sympy.abc import x >>> from sympy.solvers.solveset import _masked >>> f = cos(cos(x) + 1) >>> f, reps = _masked(cos(1 + cos(x)), cos) >>> f _a1 >>> reps [(_a1, cos(_a0 + 1)), (_a0, cos(x))] >>> for d, e in reps: ... f = f.xreplace({d: e}) >>> f cos(cos(x) + 1) """ sym = numbered_symbols('a', cls=Dummy, real=True) mask = [] for a in ordered(f.atoms(*atoms)): for i in mask: a = a.replace(*i) mask.append((a, next(sym))) for i, (o, n) in enumerate(mask): f = f.replace(o, n) mask[i] = (n, o) mask = list(reversed(mask)) return f, mask def _invert(f_x, y, x, domain=S.Complexes): r""" Reduce the complex valued equation ``f(x) = y`` to a set of equations ``{g(x) = h_1(y), g(x) = h_2(y), ..., g(x) = h_n(y) }`` where ``g(x)`` is a simpler function than ``f(x)``. The return value is a tuple ``(g(x), set_h)``, where ``g(x)`` is a function of ``x`` and ``set_h`` is the set of function ``{h_1(y), h_2(y), ..., h_n(y)}``. Here, ``y`` is not necessarily a symbol. The ``set_h`` contains the functions, along with the information about the domain in which they are valid, through set operations. For instance, if ``y = Abs(x) - n`` is inverted in the real domain, then ``set_h`` is not simply `{-n, n}` as the nature of `n` is unknown; rather, it is: `Intersection([0, oo) {n}) U Intersection((-oo, 0], {-n})` By default, the complex domain is used which means that inverting even seemingly simple functions like ``exp(x)`` will give very different results from those obtained in the real domain. (In the case of ``exp(x)``, the inversion via ``log`` is multi-valued in the complex domain, having infinitely many branches.) If you are working with real values only (or you are not sure which function to use) you should probably set the domain to ``S.Reals`` (or use `invert\_real` which does that automatically). Examples ======== >>> from sympy.solvers.solveset import invert_complex, invert_real >>> from sympy.abc import x, y >>> from sympy import exp, log When does exp(x) == y? >>> invert_complex(exp(x), y, x) (x, ImageSet(Lambda(_n, I*(2*_n*pi + arg(y)) + log(Abs(y))), Integers)) >>> invert_real(exp(x), y, x) (x, Intersection({log(y)}, Reals)) When does exp(x) == 1? >>> invert_complex(exp(x), 1, x) (x, ImageSet(Lambda(_n, 2*_n*I*pi), Integers)) >>> invert_real(exp(x), 1, x) (x, {0}) See Also ======== invert_real, invert_complex """ x = sympify(x) if not x.is_Symbol: raise ValueError("x must be a symbol") f_x = sympify(f_x) if x not in f_x.free_symbols: raise ValueError("Inverse of constant function doesn't exist") y = sympify(y) if x in y.free_symbols: raise ValueError("y should be independent of x ") if domain.is_subset(S.Reals): x1, s = _invert_real(f_x, FiniteSet(y), x) else: x1, s = _invert_complex(f_x, FiniteSet(y), x) if not isinstance(s, FiniteSet) or x1 != x: return x1, s return x1, s.intersection(domain) invert_complex = _invert def invert_real(f_x, y, x, domain=S.Reals): """ Inverts a real-valued function. Same as _invert, but sets the domain to ``S.Reals`` before inverting. """ return _invert(f_x, y, x, domain) def _invert_real(f, g_ys, symbol): """Helper function for _invert.""" if f == symbol: return (f, g_ys) n = Dummy('n', real=True) if hasattr(f, 'inverse') and not isinstance(f, ( TrigonometricFunction, HyperbolicFunction, )): if len(f.args) > 1: raise ValueError("Only functions with one argument are supported.") return _invert_real(f.args[0], imageset(Lambda(n, f.inverse()(n)), g_ys), symbol) if isinstance(f, Abs): return _invert_abs(f.args[0], g_ys, symbol) if f.is_Add: # f = g + h g, h = f.as_independent(symbol) if g is not S.Zero: return _invert_real(h, imageset(Lambda(n, n - g), g_ys), symbol) if f.is_Mul: # f = g*h g, h = f.as_independent(symbol) if g is not S.One: return _invert_real(h, imageset(Lambda(n, n/g), g_ys), symbol) if f.is_Pow: base, expo = f.args base_has_sym = base.has(symbol) expo_has_sym = expo.has(symbol) if not expo_has_sym: res = imageset(Lambda(n, real_root(n, expo)), g_ys) if expo.is_rational: numer, denom = expo.as_numer_denom() if denom % 2 == 0: base_positive = solveset(base >= 0, symbol, S.Reals) res = imageset(Lambda(n, real_root(n, expo) ), g_ys.intersect( Interval.Ropen(S.Zero, S.Infinity))) _inv, _set = _invert_real(base, res, symbol) return (_inv, _set.intersect(base_positive)) elif numer % 2 == 0: n = Dummy('n') neg_res = imageset(Lambda(n, -n), res) return _invert_real(base, res + neg_res, symbol) else: return _invert_real(base, res, symbol) else: if not base.is_positive: raise ValueError("x**w where w is irrational is not " "defined for negative x") return _invert_real(base, res, symbol) if not base_has_sym: rhs = g_ys.args[0] if base.is_positive: return _invert_real(expo, imageset(Lambda(n, log(n, base, evaluate=False)), g_ys), symbol) elif base.is_negative: from sympy.core.power import integer_log s, b = integer_log(rhs, base) if b: return _invert_real(expo, FiniteSet(s), symbol) else: return _invert_real(expo, S.EmptySet, symbol) elif base.is_zero: one = Eq(rhs, 1) if one == S.true: # special case: 0**x - 1 return _invert_real(expo, FiniteSet(0), symbol) elif one == S.false: return _invert_real(expo, S.EmptySet, symbol) if isinstance(f, TrigonometricFunction): if isinstance(g_ys, FiniteSet): def inv(trig): if isinstance(f, (sin, csc)): F = asin if isinstance(f, sin) else acsc return (lambda a: n*pi + (-1)**n*F(a),) if isinstance(f, (cos, sec)): F = acos if isinstance(f, cos) else asec return ( lambda a: 2*n*pi + F(a), lambda a: 2*n*pi - F(a),) if isinstance(f, (tan, cot)): return (lambda a: n*pi + f.inverse()(a),) n = Dummy('n', integer=True) invs = S.EmptySet for L in inv(f): invs += Union(*[imageset(Lambda(n, L(g)), S.Integers) for g in g_ys]) return _invert_real(f.args[0], invs, symbol) return (f, g_ys) def _invert_complex(f, g_ys, symbol): """Helper function for _invert.""" if f == symbol: return (f, g_ys) n = Dummy('n') if f.is_Add: # f = g + h g, h = f.as_independent(symbol) if g is not S.Zero: return _invert_complex(h, imageset(Lambda(n, n - g), g_ys), symbol) if f.is_Mul: # f = g*h g, h = f.as_independent(symbol) if g is not S.One: if g in set([S.NegativeInfinity, S.ComplexInfinity, S.Infinity]): return (h, S.EmptySet) return _invert_complex(h, imageset(Lambda(n, n/g), g_ys), symbol) if hasattr(f, 'inverse') and \ not isinstance(f, TrigonometricFunction) and \ not isinstance(f, HyperbolicFunction) and \ not isinstance(f, exp): if len(f.args) > 1: raise ValueError("Only functions with one argument are supported.") return _invert_complex(f.args[0], imageset(Lambda(n, f.inverse()(n)), g_ys), symbol) if isinstance(f, exp): if isinstance(g_ys, FiniteSet): exp_invs = Union(*[imageset(Lambda(n, I*(2*n*pi + arg(g_y)) + log(Abs(g_y))), S.Integers) for g_y in g_ys if g_y != 0]) return _invert_complex(f.args[0], exp_invs, symbol) return (f, g_ys) def _invert_abs(f, g_ys, symbol): """Helper function for inverting absolute value functions. Returns the complete result of inverting an absolute value function along with the conditions which must also be satisfied. If it is certain that all these conditions are met, a `FiniteSet` of all possible solutions is returned. If any condition cannot be satisfied, an `EmptySet` is returned. Otherwise, a `ConditionSet` of the solutions, with all the required conditions specified, is returned. """ if not g_ys.is_FiniteSet: # this could be used for FiniteSet, but the # results are more compact if they aren't, e.g. # ConditionSet(x, Contains(n, Interval(0, oo)), {-n, n}) vs # Union(Intersection(Interval(0, oo), {n}), Intersection(Interval(-oo, 0), {-n})) # for the solution of abs(x) - n pos = Intersection(g_ys, Interval(0, S.Infinity)) parg = _invert_real(f, pos, symbol) narg = _invert_real(-f, pos, symbol) if parg[0] != narg[0]: raise NotImplementedError return parg[0], Union(narg[1], parg[1]) # check conditions: all these must be true. If any are unknown # then return them as conditions which must be satisfied unknown = [] for a in g_ys.args: ok = a.is_nonnegative if a.is_Number else a.is_positive if ok is None: unknown.append(a) elif not ok: return symbol, S.EmptySet if unknown: conditions = And(*[Contains(i, Interval(0, oo)) for i in unknown]) else: conditions = True n = Dummy('n', real=True) # this is slightly different than above: instead of solving # +/-f on positive values, here we solve for f on +/- g_ys g_x, values = _invert_real(f, Union( imageset(Lambda(n, n), g_ys), imageset(Lambda(n, -n), g_ys)), symbol) return g_x, ConditionSet(g_x, conditions, values) def domain_check(f, symbol, p): """Returns False if point p is infinite or any subexpression of f is infinite or becomes so after replacing symbol with p. If none of these conditions is met then True will be returned. Examples ======== >>> from sympy import Mul, oo >>> from sympy.abc import x >>> from sympy.solvers.solveset import domain_check >>> g = 1/(1 + (1/(x + 1))**2) >>> domain_check(g, x, -1) False >>> domain_check(x**2, x, 0) True >>> domain_check(1/x, x, oo) False * The function relies on the assumption that the original form of the equation has not been changed by automatic simplification. >>> domain_check(x/x, x, 0) # x/x is automatically simplified to 1 True * To deal with automatic evaluations use evaluate=False: >>> domain_check(Mul(x, 1/x, evaluate=False), x, 0) False """ f, p = sympify(f), sympify(p) if p.is_infinite: return False return _domain_check(f, symbol, p) def _domain_check(f, symbol, p): # helper for domain check if f.is_Atom and f.is_finite: return True elif f.subs(symbol, p).is_infinite: return False else: return all([_domain_check(g, symbol, p) for g in f.args]) def _is_finite_with_finite_vars(f, domain=S.Complexes): """ Return True if the given expression is finite. For symbols that don't assign a value for `complex` and/or `real`, the domain will be used to assign a value; symbols that don't assign a value for `finite` will be made finite. All other assumptions are left unmodified. """ def assumptions(s): A = s.assumptions0 A.setdefault('finite', A.get('finite', True)) if domain.is_subset(S.Reals): # if this gets set it will make complex=True, too A.setdefault('real', True) else: # don't change 'real' because being complex implies # nothing about being real A.setdefault('complex', True) return A reps = {s: Dummy(**assumptions(s)) for s in f.free_symbols} return f.xreplace(reps).is_finite def _is_function_class_equation(func_class, f, symbol): """ Tests whether the equation is an equation of the given function class. The given equation belongs to the given function class if it is comprised of functions of the function class which are multiplied by or added to expressions independent of the symbol. In addition, the arguments of all such functions must be linear in the symbol as well. Examples ======== >>> from sympy.solvers.solveset import _is_function_class_equation >>> from sympy import tan, sin, tanh, sinh, exp >>> from sympy.abc import x >>> from sympy.functions.elementary.trigonometric import (TrigonometricFunction, ... HyperbolicFunction) >>> _is_function_class_equation(TrigonometricFunction, exp(x) + tan(x), x) False >>> _is_function_class_equation(TrigonometricFunction, tan(x) + sin(x), x) True >>> _is_function_class_equation(TrigonometricFunction, tan(x**2), x) False >>> _is_function_class_equation(TrigonometricFunction, tan(x + 2), x) True >>> _is_function_class_equation(HyperbolicFunction, tanh(x) + sinh(x), x) True """ if f.is_Mul or f.is_Add: return all(_is_function_class_equation(func_class, arg, symbol) for arg in f.args) if f.is_Pow: if not f.exp.has(symbol): return _is_function_class_equation(func_class, f.base, symbol) else: return False if not f.has(symbol): return True if isinstance(f, func_class): try: g = Poly(f.args[0], symbol) return g.degree() <= 1 except PolynomialError: return False else: return False def _solve_as_rational(f, symbol, domain): """ solve rational functions""" f = together(f, deep=True) g, h = fraction(f) if not h.has(symbol): try: return _solve_as_poly(g, symbol, domain) except NotImplementedError: # The polynomial formed from g could end up having # coefficients in a ring over which finding roots # isn't implemented yet, e.g. ZZ[a] for some symbol a return ConditionSet(symbol, Eq(f, 0), domain) except CoercionFailed: # contained oo, zoo or nan return S.EmptySet else: valid_solns = _solveset(g, symbol, domain) invalid_solns = _solveset(h, symbol, domain) return valid_solns - invalid_solns def _solve_trig(f, symbol, domain): """Function to call other helpers to solve trigonometric equations """ sol1 = sol = None try: sol1 = _solve_trig1(f, symbol, domain) except BaseException as error: pass if sol1 is None or isinstance(sol1, ConditionSet): try: sol = _solve_trig2(f, symbol, domain) except BaseException as error: sol = sol1 if isinstance(sol1, ConditionSet) and isinstance(sol, ConditionSet): if sol1.count_ops() < sol.count_ops(): sol = sol1 else: sol = sol1 if sol is None: raise NotImplementedError(filldedent(''' Solution to this kind of trigonometric equations is yet to be implemented''')) return sol def _solve_trig1(f, symbol, domain): """Primary Helper to solve trigonometric equations """ f = trigsimp(f) f_original = f f = f.rewrite(exp) f = together(f) g, h = fraction(f) y = Dummy('y') g, h = g.expand(), h.expand() g, h = g.subs(exp(I*symbol), y), h.subs(exp(I*symbol), y) if g.has(symbol) or h.has(symbol): return ConditionSet(symbol, Eq(f, 0), S.Reals) solns = solveset_complex(g, y) - solveset_complex(h, y) if isinstance(solns, ConditionSet): raise NotImplementedError if isinstance(solns, FiniteSet): if any(isinstance(s, RootOf) for s in solns): raise NotImplementedError result = Union(*[invert_complex(exp(I*symbol), s, symbol)[1] for s in solns]) return Intersection(result, domain) elif solns is S.EmptySet: return S.EmptySet else: return ConditionSet(symbol, Eq(f_original, 0), S.Reals) def _solve_trig2(f, symbol, domain): """Secondary helper to solve trigonometric equations, called when first helper fails """ from sympy import ilcm, igcd, expand_trig, degree, simplify f = trigsimp(f) f_original = f trig_functions = f.atoms(sin, cos, tan, sec, cot, csc) trig_arguments = [e.args[0] for e in trig_functions] denominators = [] numerators = [] for ar in trig_arguments: try: poly_ar = Poly(ar, symbol) except ValueError: raise ValueError("give up, we can't solve if this is not a polynomial in x") if poly_ar.degree() > 1: # degree >1 still bad raise ValueError("degree of variable inside polynomial should not exceed one") if poly_ar.degree() == 0: # degree 0, don't care continue c = poly_ar.all_coeffs()[0] # got the coefficient of 'symbol' numerators.append(Rational(c).p) denominators.append(Rational(c).q) x = Dummy('x') # ilcm() and igcd() require more than one argument if len(numerators) > 1: mu = Rational(2)*ilcm(*denominators)/igcd(*numerators) else: assert len(numerators) == 1 mu = Rational(2)*denominators[0]/numerators[0] f = f.subs(symbol, mu*x) f = f.rewrite(tan) f = expand_trig(f) f = together(f) g, h = fraction(f) y = Dummy('y') g, h = g.expand(), h.expand() g, h = g.subs(tan(x), y), h.subs(tan(x), y) if g.has(x) or h.has(x): return ConditionSet(symbol, Eq(f_original, 0), domain) solns = solveset(g, y, S.Reals) - solveset(h, y, S.Reals) if isinstance(solns, FiniteSet): result = Union(*[invert_real(tan(symbol/mu), s, symbol)[1] for s in solns]) dsol = invert_real(tan(symbol/mu), oo, symbol)[1] if degree(h) > degree(g): # If degree(denom)>degree(num) then there result = Union(result, dsol) # would be another sol at Lim(denom-->oo) return Intersection(result, domain) elif solns is S.EmptySet: return S.EmptySet else: return ConditionSet(symbol, Eq(f_original, 0), S.Reals) def _solve_as_poly(f, symbol, domain=S.Complexes): """ Solve the equation using polynomial techniques if it already is a polynomial equation or, with a change of variables, can be made so. """ result = None if f.is_polynomial(symbol): solns = roots(f, symbol, cubics=True, quartics=True, quintics=True, domain='EX') num_roots = sum(solns.values()) if degree(f, symbol) <= num_roots: result = FiniteSet(*solns.keys()) else: poly = Poly(f, symbol) solns = poly.all_roots() if poly.degree() <= len(solns): result = FiniteSet(*solns) else: result = ConditionSet(symbol, Eq(f, 0), domain) else: poly = Poly(f) if poly is None: result = ConditionSet(symbol, Eq(f, 0), domain) gens = [g for g in poly.gens if g.has(symbol)] if len(gens) == 1: poly = Poly(poly, gens[0]) gen = poly.gen deg = poly.degree() poly = Poly(poly.as_expr(), poly.gen, composite=True) poly_solns = FiniteSet(*roots(poly, cubics=True, quartics=True, quintics=True).keys()) if len(poly_solns) < deg: result = ConditionSet(symbol, Eq(f, 0), domain) if gen != symbol: y = Dummy('y') inverter = invert_real if domain.is_subset(S.Reals) else invert_complex lhs, rhs_s = inverter(gen, y, symbol) if lhs == symbol: result = Union(*[rhs_s.subs(y, s) for s in poly_solns]) else: result = ConditionSet(symbol, Eq(f, 0), domain) else: result = ConditionSet(symbol, Eq(f, 0), domain) if result is not None: if isinstance(result, FiniteSet): # this is to simplify solutions like -sqrt(-I) to sqrt(2)/2 # - sqrt(2)*I/2. We are not expanding for solution with symbols # or undefined functions because that makes the solution more complicated. # For example, expand_complex(a) returns re(a) + I*im(a) if all([s.atoms(Symbol, AppliedUndef) == set() and not isinstance(s, RootOf) for s in result]): s = Dummy('s') result = imageset(Lambda(s, expand_complex(s)), result) if isinstance(result, FiniteSet): result = result.intersection(domain) return result else: return ConditionSet(symbol, Eq(f, 0), domain) def _has_rational_power(expr, symbol): """ Returns (bool, den) where bool is True if the term has a non-integer rational power and den is the denominator of the expression's exponent. Examples ======== >>> from sympy.solvers.solveset import _has_rational_power >>> from sympy import sqrt >>> from sympy.abc import x >>> _has_rational_power(sqrt(x), x) (True, 2) >>> _has_rational_power(x**2, x) (False, 1) """ a, p, q = Wild('a'), Wild('p'), Wild('q') pattern_match = expr.match(a*p**q) or {} if pattern_match.get(a, S.Zero) is S.Zero: return (False, S.One) elif p not in pattern_match.keys(): return (False, S.One) elif isinstance(pattern_match[q], Rational) \ and pattern_match[p].has(symbol): if not pattern_match[q].q == S.One: return (True, pattern_match[q].q) if not isinstance(pattern_match[a], Pow) \ or isinstance(pattern_match[a], Mul): return (False, S.One) else: return _has_rational_power(pattern_match[a], symbol) def _solve_radical(f, symbol, solveset_solver): """ Helper function to solve equations with radicals """ eq, cov = unrad(f) if not cov: result = solveset_solver(eq, symbol) - \ Union(*[solveset_solver(g, symbol) for g in denoms(f, symbol)]) else: y, yeq = cov if not solveset_solver(y - I, y): yreal = Dummy('yreal', real=True) yeq = yeq.xreplace({y: yreal}) eq = eq.xreplace({y: yreal}) y = yreal g_y_s = solveset_solver(yeq, symbol) f_y_sols = solveset_solver(eq, y) result = Union(*[imageset(Lambda(y, g_y), f_y_sols) for g_y in g_y_s]) if isinstance(result, Complement) or isinstance(result,ConditionSet): solution_set = result else: f_set = [] # solutions for FiniteSet c_set = [] # solutions for ConditionSet for s in result: if checksol(f, symbol, s): f_set.append(s) else: c_set.append(s) solution_set = FiniteSet(*f_set) + ConditionSet(symbol, Eq(f, 0), FiniteSet(*c_set)) return solution_set def _solve_abs(f, symbol, domain): """ Helper function to solve equation involving absolute value function """ if not domain.is_subset(S.Reals): raise ValueError(filldedent(''' Absolute values cannot be inverted in the complex domain.''')) p, q, r = Wild('p'), Wild('q'), Wild('r') pattern_match = f.match(p*Abs(q) + r) or {} f_p, f_q, f_r = [pattern_match.get(i, S.Zero) for i in (p, q, r)] if not (f_p.is_zero or f_q.is_zero): domain = continuous_domain(f_q, symbol, domain) q_pos_cond = solve_univariate_inequality(f_q >= 0, symbol, relational=False, domain=domain, continuous=True) q_neg_cond = q_pos_cond.complement(domain) sols_q_pos = solveset_real(f_p*f_q + f_r, symbol).intersect(q_pos_cond) sols_q_neg = solveset_real(f_p*(-f_q) + f_r, symbol).intersect(q_neg_cond) return Union(sols_q_pos, sols_q_neg) else: return ConditionSet(symbol, Eq(f, 0), domain) def solve_decomposition(f, symbol, domain): """ Function to solve equations via the principle of "Decomposition and Rewriting". Examples ======== >>> from sympy import exp, sin, Symbol, pprint, S >>> from sympy.solvers.solveset import solve_decomposition as sd >>> x = Symbol('x') >>> f1 = exp(2*x) - 3*exp(x) + 2 >>> sd(f1, x, S.Reals) {0, log(2)} >>> f2 = sin(x)**2 + 2*sin(x) + 1 >>> pprint(sd(f2, x, S.Reals), use_unicode=False) 3*pi {2*n*pi + ---- | n in Integers} 2 >>> f3 = sin(x + 2) >>> pprint(sd(f3, x, S.Reals), use_unicode=False) {2*n*pi - 2 | n in Integers} U {2*n*pi - 2 + pi | n in Integers} """ from sympy.solvers.decompogen import decompogen from sympy.calculus.util import function_range # decompose the given function g_s = decompogen(f, symbol) # `y_s` represents the set of values for which the function `g` is to be # solved. # `solutions` represent the solutions of the equations `g = y_s` or # `g = 0` depending on the type of `y_s`. # As we are interested in solving the equation: f = 0 y_s = FiniteSet(0) for g in g_s: frange = function_range(g, symbol, domain) y_s = Intersection(frange, y_s) result = S.EmptySet if isinstance(y_s, FiniteSet): for y in y_s: solutions = solveset(Eq(g, y), symbol, domain) if not isinstance(solutions, ConditionSet): result += solutions else: if isinstance(y_s, ImageSet): iter_iset = (y_s,) elif isinstance(y_s, Union): iter_iset = y_s.args elif isinstance(y_s, EmptySet): # y_s is not in the range of g in g_s, so no solution exists #in the given domain return y_s for iset in iter_iset: new_solutions = solveset(Eq(iset.lamda.expr, g), symbol, domain) dummy_var = tuple(iset.lamda.expr.free_symbols)[0] base_set = iset.base_set if isinstance(new_solutions, FiniteSet): new_exprs = new_solutions elif isinstance(new_solutions, Intersection): if isinstance(new_solutions.args[1], FiniteSet): new_exprs = new_solutions.args[1] for new_expr in new_exprs: result += ImageSet(Lambda(dummy_var, new_expr), base_set) if result is S.EmptySet: return ConditionSet(symbol, Eq(f, 0), domain) y_s = result return y_s def _solveset(f, symbol, domain, _check=False): """Helper for solveset to return a result from an expression that has already been sympify'ed and is known to contain the given symbol.""" # _check controls whether the answer is checked or not from sympy.simplify.simplify import signsimp orig_f = f if f.is_Mul: coeff, f = f.as_independent(symbol, as_Add=False) if coeff in set([S.ComplexInfinity, S.NegativeInfinity, S.Infinity]): f = together(orig_f) elif f.is_Add: a, h = f.as_independent(symbol) m, h = h.as_independent(symbol, as_Add=False) if m not in set([S.ComplexInfinity, S.Zero, S.Infinity, S.NegativeInfinity]): f = a/m + h # XXX condition `m != 0` should be added to soln # assign the solvers to use solver = lambda f, x, domain=domain: _solveset(f, x, domain) inverter = lambda f, rhs, symbol: _invert(f, rhs, symbol, domain) result = EmptySet() if f.expand().is_zero: return domain elif not f.has(symbol): return EmptySet() elif f.is_Mul and all(_is_finite_with_finite_vars(m, domain) for m in f.args): # if f(x) and g(x) are both finite we can say that the solution of # f(x)*g(x) == 0 is same as Union(f(x) == 0, g(x) == 0) is not true in # general. g(x) can grow to infinitely large for the values where # f(x) == 0. To be sure that we are not silently allowing any # wrong solutions we are using this technique only if both f and g are # finite for a finite input. result = Union(*[solver(m, symbol) for m in f.args]) elif _is_function_class_equation(TrigonometricFunction, f, symbol) or \ _is_function_class_equation(HyperbolicFunction, f, symbol): result = _solve_trig(f, symbol, domain) elif isinstance(f, arg): a = f.args[0] result = solveset_real(a > 0, symbol) elif f.is_Piecewise: result = EmptySet() expr_set_pairs = f.as_expr_set_pairs(domain) for (expr, in_set) in expr_set_pairs: if in_set.is_Relational: in_set = in_set.as_set() solns = solver(expr, symbol, in_set) result += solns elif isinstance(f, Eq): result = solver(Add(f.lhs, - f.rhs, evaluate=False), symbol, domain) elif f.is_Relational: if not domain.is_subset(S.Reals): raise NotImplementedError(filldedent(''' Inequalities in the complex domain are not supported. Try the real domain by setting domain=S.Reals''')) try: result = solve_univariate_inequality( f, symbol, domain=domain, relational=False) except NotImplementedError: result = ConditionSet(symbol, f, domain) return result else: lhs, rhs_s = inverter(f, 0, symbol) if lhs == symbol: # do some very minimal simplification since # repeated inversion may have left the result # in a state that other solvers (e.g. poly) # would have simplified; this is done here # rather than in the inverter since here it # is only done once whereas there it would # be repeated for each step of the inversion if isinstance(rhs_s, FiniteSet): rhs_s = FiniteSet(*[Mul(* signsimp(i).as_content_primitive()) for i in rhs_s]) result = rhs_s elif isinstance(rhs_s, FiniteSet): for equation in [lhs - rhs for rhs in rhs_s]: if equation == f: if any(_has_rational_power(g, symbol)[0] for g in equation.args) or _has_rational_power( equation, symbol)[0]: result += _solve_radical(equation, symbol, solver) elif equation.has(Abs): result += _solve_abs(f, symbol, domain) else: result_rational = _solve_as_rational(equation, symbol, domain) if isinstance(result_rational, ConditionSet): # may be a transcendental type equation result += _transolve(equation, symbol, domain) else: result += result_rational else: result += solver(equation, symbol) elif rhs_s is not S.EmptySet: result = ConditionSet(symbol, Eq(f, 0), domain) if isinstance(result, ConditionSet): num, den = f.as_numer_denom() if den.has(symbol): _result = _solveset(num, symbol, domain) if not isinstance(_result, ConditionSet): singularities = _solveset(den, symbol, domain) result = _result - singularities if _check: if isinstance(result, ConditionSet): # it wasn't solved or has enumerated all conditions # -- leave it alone return result # whittle away all but the symbol-containing core # to use this for testing fx = orig_f.as_independent(symbol, as_Add=True)[1] fx = fx.as_independent(symbol, as_Add=False)[1] if isinstance(result, FiniteSet): # check the result for invalid solutions result = FiniteSet(*[s for s in result if isinstance(s, RootOf) or domain_check(fx, symbol, s)]) return result def _term_factors(f): """ Iterator to get the factors of all terms present in the given equation. Parameters ========== f : Expr Equation that needs to be addressed Returns ======= Factors of all terms present in the equation. Examples ======== >>> from sympy import symbols >>> from sympy.solvers.solveset import _term_factors >>> x = symbols('x') >>> list(_term_factors(-2 - x**2 + x*(x + 1))) [-2, -1, x**2, x, x + 1] """ for add_arg in Add.make_args(f): for mul_arg in Mul.make_args(add_arg): yield mul_arg def _solve_exponential(lhs, rhs, symbol, domain): r""" Helper function for solving (supported) exponential equations. Exponential equations are the sum of (currently) at most two terms with one or both of them having a power with a symbol-dependent exponent. For example .. math:: 5^{2x + 3} - 5^{3x - 1} .. math:: 4^{5 - 9x} - e^{2 - x} Parameters ========== lhs, rhs : Expr The exponential equation to be solved, `lhs = rhs` symbol : Symbol The variable in which the equation is solved domain : Set A set over which the equation is solved. Returns ======= A set of solutions satisfying the given equation. A ``ConditionSet`` if the equation is unsolvable or if the assumptions are not properly defined, in that case a different style of ``ConditionSet`` is returned having the solution(s) of the equation with the desired assumptions. Examples ======== >>> from sympy.solvers.solveset import _solve_exponential as solve_expo >>> from sympy import symbols, S >>> x = symbols('x', real=True) >>> a, b = symbols('a b') >>> solve_expo(2**x + 3**x - 5**x, 0, x, S.Reals) # not solvable ConditionSet(x, Eq(2**x + 3**x - 5**x, 0), Reals) >>> solve_expo(a**x - b**x, 0, x, S.Reals) # solvable but incorrect assumptions ConditionSet(x, (a > 0) & (b > 0), {0}) >>> solve_expo(3**(2*x) - 2**(x + 3), 0, x, S.Reals) {-3*log(2)/(-2*log(3) + log(2))} >>> solve_expo(2**x - 4**x, 0, x, S.Reals) {0} * Proof of correctness of the method The logarithm function is the inverse of the exponential function. The defining relation between exponentiation and logarithm is: .. math:: {\log_b x} = y \enspace if \enspace b^y = x Therefore if we are given an equation with exponent terms, we can convert every term to its corresponding logarithmic form. This is achieved by taking logarithms and expanding the equation using logarithmic identities so that it can easily be handled by ``solveset``. For example: .. math:: 3^{2x} = 2^{x + 3} Taking log both sides will reduce the equation to .. math:: (2x)\log(3) = (x + 3)\log(2) This form can be easily handed by ``solveset``. """ unsolved_result = ConditionSet(symbol, Eq(lhs - rhs, 0), domain) newlhs = powdenest(lhs) if lhs != newlhs: # it may also be advantageous to factor the new expr return _solveset(factor(newlhs - rhs), symbol, domain) # try again with _solveset if not (isinstance(lhs, Add) and len(lhs.args) == 2): # solving for the sum of more than two powers is possible # but not yet implemented return unsolved_result if rhs != 0: return unsolved_result a, b = list(ordered(lhs.args)) a_term = a.as_independent(symbol)[1] b_term = b.as_independent(symbol)[1] a_base, a_exp = a_term.base, a_term.exp b_base, b_exp = b_term.base, b_term.exp from sympy.functions.elementary.complexes import im if domain.is_subset(S.Reals): conditions = And( a_base > 0, b_base > 0, Eq(im(a_exp), 0), Eq(im(b_exp), 0)) else: conditions = And( Ne(a_base, 0), Ne(b_base, 0)) L, R = map(lambda i: expand_log(log(i), force=True), (a, -b)) solutions = _solveset(L - R, symbol, domain) return ConditionSet(symbol, conditions, solutions) def _is_exponential(f, symbol): r""" Return ``True`` if one or more terms contain ``symbol`` only in exponents, else ``False``. Parameters ========== f : Expr The equation to be checked symbol : Symbol The variable in which the equation is checked Examples ======== >>> from sympy import symbols, cos, exp >>> from sympy.solvers.solveset import _is_exponential as check >>> x, y = symbols('x y') >>> check(y, y) False >>> check(x**y - 1, y) True >>> check(x**y*2**y - 1, y) True >>> check(exp(x + 3) + 3**x, x) True >>> check(cos(2**x), x) False * Philosophy behind the helper The function extracts each term of the equation and checks if it is of exponential form w.r.t ``symbol``. """ rv = False for expr_arg in _term_factors(f): if symbol not in expr_arg.free_symbols: continue if (isinstance(expr_arg, Pow) and symbol not in expr_arg.base.free_symbols or isinstance(expr_arg, exp)): rv = True # symbol in exponent else: return False # dependent on symbol in non-exponential way return rv def _solve_logarithm(lhs, rhs, symbol, domain): r""" Helper to solve logarithmic equations which are reducible to a single instance of `\log`. Logarithmic equations are (currently) the equations that contains `\log` terms which can be reduced to a single `\log` term or a constant using various logarithmic identities. For example: .. math:: \log(x) + \log(x - 4) can be reduced to: .. math:: \log(x(x - 4)) Parameters ========== lhs, rhs : Expr The logarithmic equation to be solved, `lhs = rhs` symbol : Symbol The variable in which the equation is solved domain : Set A set over which the equation is solved. Returns ======= A set of solutions satisfying the given equation. A ``ConditionSet`` if the equation is unsolvable. Examples ======== >>> from sympy import symbols, log, S >>> from sympy.solvers.solveset import _solve_logarithm as solve_log >>> x = symbols('x') >>> f = log(x - 3) + log(x + 3) >>> solve_log(f, 0, x, S.Reals) {-sqrt(10), sqrt(10)} * Proof of correctness A logarithm is another way to write exponent and is defined by .. math:: {\log_b x} = y \enspace if \enspace b^y = x When one side of the equation contains a single logarithm, the equation can be solved by rewriting the equation as an equivalent exponential equation as defined above. But if one side contains more than one logarithm, we need to use the properties of logarithm to condense it into a single logarithm. Take for example .. math:: \log(2x) - 15 = 0 contains single logarithm, therefore we can directly rewrite it to exponential form as .. math:: x = \frac{e^{15}}{2} But if the equation has more than one logarithm as .. math:: \log(x - 3) + \log(x + 3) = 0 we use logarithmic identities to convert it into a reduced form Using, .. math:: \log(a) + \log(b) = \log(ab) the equation becomes, .. math:: \log((x - 3)(x + 3)) This equation contains one logarithm and can be solved by rewriting to exponents. """ new_lhs = logcombine(lhs, force=True) new_f = new_lhs - rhs return _solveset(new_f, symbol, domain) def _is_logarithmic(f, symbol): r""" Return ``True`` if the equation is in the form `a\log(f(x)) + b\log(g(x)) + ... + c` else ``False``. Parameters ========== f : Expr The equation to be checked symbol : Symbol The variable in which the equation is checked Returns ======= ``True`` if the equation is logarithmic otherwise ``False``. Examples ======== >>> from sympy import symbols, tan, log >>> from sympy.solvers.solveset import _is_logarithmic as check >>> x, y = symbols('x y') >>> check(log(x + 2) - log(x + 3), x) True >>> check(tan(log(2*x)), x) False >>> check(x*log(x), x) False >>> check(x + log(x), x) False >>> check(y + log(x), x) True * Philosophy behind the helper The function extracts each term and checks whether it is logarithmic w.r.t ``symbol``. """ rv = False for term in Add.make_args(f): saw_log = False for term_arg in Mul.make_args(term): if symbol not in term_arg.free_symbols: continue if isinstance(term_arg, log): if saw_log: return False # more than one log in term saw_log = True else: return False # dependent on symbol in non-log way if saw_log: rv = True return rv def _transolve(f, symbol, domain): r""" Function to solve transcendental equations. It is a helper to ``solveset`` and should be used internally. ``_transolve`` currently supports the following class of equations: - Exponential equations - Logarithmic equations Parameters ========== f : Any transcendental equation that needs to be solved. This needs to be an expression, which is assumed to be equal to ``0``. symbol : The variable for which the equation is solved. This needs to be of class ``Symbol``. domain : A set over which the equation is solved. This needs to be of class ``Set``. Returns ======= Set A set of values for ``symbol`` for which ``f`` is equal to zero. An ``EmptySet`` is returned if ``f`` does not have solutions in respective domain. A ``ConditionSet`` is returned as unsolved object if algorithms to evaluate complete solution are not yet implemented. How to use ``_transolve`` ========================= ``_transolve`` should not be used as an independent function, because it assumes that the equation (``f``) and the ``symbol`` comes from ``solveset`` and might have undergone a few modification(s). To use ``_transolve`` as an independent function the equation (``f``) and the ``symbol`` should be passed as they would have been by ``solveset``. Examples ======== >>> from sympy.solvers.solveset import _transolve as transolve >>> from sympy.solvers.solvers import _tsolve as tsolve >>> from sympy import symbols, S, pprint >>> x = symbols('x', real=True) # assumption added >>> transolve(5**(x - 3) - 3**(2*x + 1), x, S.Reals) {-(log(3) + 3*log(5))/(-log(5) + 2*log(3))} How ``_transolve`` works ======================== ``_transolve`` uses two types of helper functions to solve equations of a particular class: Identifying helpers: To determine whether a given equation belongs to a certain class of equation or not. Returns either ``True`` or ``False``. Solving helpers: Once an equation is identified, a corresponding helper either solves the equation or returns a form of the equation that ``solveset`` might better be able to handle. * Philosophy behind the module The purpose of ``_transolve`` is to take equations which are not already polynomial in their generator(s) and to either recast them as such through a valid transformation or to solve them outright. A pair of helper functions for each class of supported transcendental functions are employed for this purpose. One identifies the transcendental form of an equation and the other either solves it or recasts it into a tractable form that can be solved by ``solveset``. For example, an equation in the form `ab^{f(x)} - cd^{g(x)} = 0` can be transformed to `\log(a) + f(x)\log(b) - \log(c) - g(x)\log(d) = 0` (under certain assumptions) and this can be solved with ``solveset`` if `f(x)` and `g(x)` are in polynomial form. How ``_transolve`` is better than ``_tsolve`` ============================================= 1) Better output ``_transolve`` provides expressions in a more simplified form. Consider a simple exponential equation >>> f = 3**(2*x) - 2**(x + 3) >>> pprint(transolve(f, x, S.Reals), use_unicode=False) -3*log(2) {------------------} -2*log(3) + log(2) >>> pprint(tsolve(f, x), use_unicode=False) / 3 \ | --------| | log(2/9)| [-log\2 /] 2) Extensible The API of ``_transolve`` is designed such that it is easily extensible, i.e. the code that solves a given class of equations is encapsulated in a helper and not mixed in with the code of ``_transolve`` itself. 3) Modular ``_transolve`` is designed to be modular i.e, for every class of equation a separate helper for identification and solving is implemented. This makes it easy to change or modify any of the method implemented directly in the helpers without interfering with the actual structure of the API. 4) Faster Computation Solving equation via ``_transolve`` is much faster as compared to ``_tsolve``. In ``solve``, attempts are made computing every possibility to get the solutions. This series of attempts makes solving a bit slow. In ``_transolve``, computation begins only after a particular type of equation is identified. How to add new class of equations ================================= Adding a new class of equation solver is a three-step procedure: - Identify the type of the equations Determine the type of the class of equations to which they belong: it could be of ``Add``, ``Pow``, etc. types. Separate internal functions are used for each type. Write identification and solving helpers and use them from within the routine for the given type of equation (after adding it, if necessary). Something like: .. code-block:: python def add_type(lhs, rhs, x): .... if _is_exponential(lhs, x): new_eq = _solve_exponential(lhs, rhs, x) .... rhs, lhs = eq.as_independent(x) if lhs.is_Add: result = add_type(lhs, rhs, x) - Define the identification helper. - Define the solving helper. Apart from this, a few other things needs to be taken care while adding an equation solver: - Naming conventions: Name of the identification helper should be as ``_is_class`` where class will be the name or abbreviation of the class of equation. The solving helper will be named as ``_solve_class``. For example: for exponential equations it becomes ``_is_exponential`` and ``_solve_expo``. - The identifying helpers should take two input parameters, the equation to be checked and the variable for which a solution is being sought, while solving helpers would require an additional domain parameter. - Be sure to consider corner cases. - Add tests for each helper. - Add a docstring to your helper that describes the method implemented. The documentation of the helpers should identify: - the purpose of the helper, - the method used to identify and solve the equation, - a proof of correctness - the return values of the helpers """ def add_type(lhs, rhs, symbol, domain): """ Helper for ``_transolve`` to handle equations of ``Add`` type, i.e. equations taking the form as ``a*f(x) + b*g(x) + .... = c``. For example: 4**x + 8**x = 0 """ result = ConditionSet(symbol, Eq(lhs - rhs, 0), domain) # check if it is exponential type equation if _is_exponential(lhs, symbol): result = _solve_exponential(lhs, rhs, symbol, domain) # check if it is logarithmic type equation elif _is_logarithmic(lhs, symbol): result = _solve_logarithm(lhs, rhs, symbol, domain) return result result = ConditionSet(symbol, Eq(f, 0), domain) # invert_complex handles the call to the desired inverter based # on the domain specified. lhs, rhs_s = invert_complex(f, 0, symbol, domain) if isinstance(rhs_s, FiniteSet): assert (len(rhs_s.args)) == 1 rhs = rhs_s.args[0] if lhs.is_Add: result = add_type(lhs, rhs, symbol, domain) else: result = rhs_s return result def solveset(f, symbol=None, domain=S.Complexes): r"""Solves a given inequality or equation with set as output Parameters ========== f : Expr or a relational. The target equation or inequality symbol : Symbol The variable for which the equation is solved domain : Set The domain over which the equation is solved Returns ======= Set A set of values for `symbol` for which `f` is True or is equal to zero. An `EmptySet` is returned if `f` is False or nonzero. A `ConditionSet` is returned as unsolved object if algorithms to evaluate complete solution are not yet implemented. `solveset` claims to be complete in the solution set that it returns. Raises ====== NotImplementedError The algorithms to solve inequalities in complex domain are not yet implemented. ValueError The input is not valid. RuntimeError It is a bug, please report to the github issue tracker. Notes ===== Python interprets 0 and 1 as False and True, respectively, but in this function they refer to solutions of an expression. So 0 and 1 return the Domain and EmptySet, respectively, while True and False return the opposite (as they are assumed to be solutions of relational expressions). See Also ======== solveset_real: solver for real domain solveset_complex: solver for complex domain Examples ======== >>> from sympy import exp, sin, Symbol, pprint, S >>> from sympy.solvers.solveset import solveset, solveset_real * The default domain is complex. Not specifying a domain will lead to the solving of the equation in the complex domain (and this is not affected by the assumptions on the symbol): >>> x = Symbol('x') >>> pprint(solveset(exp(x) - 1, x), use_unicode=False) {2*n*I*pi | n in Integers} >>> x = Symbol('x', real=True) >>> pprint(solveset(exp(x) - 1, x), use_unicode=False) {2*n*I*pi | n in Integers} * If you want to use `solveset` to solve the equation in the real domain, provide a real domain. (Using ``solveset_real`` does this automatically.) >>> R = S.Reals >>> x = Symbol('x') >>> solveset(exp(x) - 1, x, R) {0} >>> solveset_real(exp(x) - 1, x) {0} The solution is mostly unaffected by assumptions on the symbol, but there may be some slight difference: >>> pprint(solveset(sin(x)/x,x), use_unicode=False) ({2*n*pi | n in Integers} \ {0}) U ({2*n*pi + pi | n in Integers} \ {0}) >>> p = Symbol('p', positive=True) >>> pprint(solveset(sin(p)/p, p), use_unicode=False) {2*n*pi | n in Integers} U {2*n*pi + pi | n in Integers} * Inequalities can be solved over the real domain only. Use of a complex domain leads to a NotImplementedError. >>> solveset(exp(x) > 1, x, R) Interval.open(0, oo) """ f = sympify(f) symbol = sympify(symbol) if f is S.true: return domain if f is S.false: return S.EmptySet if not isinstance(f, (Expr, Number)): raise ValueError("%s is not a valid SymPy expression" % f) if not isinstance(symbol, Expr) and symbol is not None: raise ValueError("%s is not a valid SymPy symbol" % symbol) if not isinstance(domain, Set): raise ValueError("%s is not a valid domain" %(domain)) free_symbols = f.free_symbols if symbol is None and not free_symbols: b = Eq(f, 0) if b is S.true: return domain elif b is S.false: return S.EmptySet else: raise NotImplementedError(filldedent(''' relationship between value and 0 is unknown: %s''' % b)) if symbol is None: if len(free_symbols) == 1: symbol = free_symbols.pop() elif free_symbols: raise ValueError(filldedent(''' The independent variable must be specified for a multivariate equation.''')) elif not isinstance(symbol, Symbol): f, s, swap = recast_to_symbols([f], [symbol]) # the xreplace will be needed if a ConditionSet is returned return solveset(f[0], s[0], domain).xreplace(swap) if domain.is_subset(S.Reals): if not symbol.is_real: assumptions = symbol.assumptions0 assumptions['real'] = True try: r = Dummy('r', **assumptions) return solveset(f.xreplace({symbol: r}), r, domain ).xreplace({r: symbol}) except InconsistentAssumptions: pass # Abs has its own handling method which avoids the # rewriting property that the first piece of abs(x) # is for x >= 0 and the 2nd piece for x < 0 -- solutions # can look better if the 2nd condition is x <= 0. Since # the solution is a set, duplication of results is not # an issue, e.g. {y, -y} when y is 0 will be {0} f, mask = _masked(f, Abs) f = f.rewrite(Piecewise) # everything that's not an Abs for d, e in mask: # everything *in* an Abs e = e.func(e.args[0].rewrite(Piecewise)) f = f.xreplace({d: e}) f = piecewise_fold(f) return _solveset(f, symbol, domain, _check=True) def solveset_real(f, symbol): return solveset(f, symbol, S.Reals) def solveset_complex(f, symbol): return solveset(f, symbol, S.Complexes) def solvify(f, symbol, domain): """Solves an equation using solveset and returns the solution in accordance with the `solve` output API. Returns ======= We classify the output based on the type of solution returned by `solveset`. Solution | Output ---------------------------------------- FiniteSet | list ImageSet, | list (if `f` is periodic) Union | EmptySet | empty list Others | None Raises ====== NotImplementedError A ConditionSet is the input. Examples ======== >>> from sympy.solvers.solveset import solvify, solveset >>> from sympy.abc import x >>> from sympy import S, tan, sin, exp >>> solvify(x**2 - 9, x, S.Reals) [-3, 3] >>> solvify(sin(x) - 1, x, S.Reals) [pi/2] >>> solvify(tan(x), x, S.Reals) [0] >>> solvify(exp(x) - 1, x, S.Complexes) >>> solvify(exp(x) - 1, x, S.Reals) [0] """ solution_set = solveset(f, symbol, domain) result = None if solution_set is S.EmptySet: result = [] elif isinstance(solution_set, ConditionSet): raise NotImplementedError('solveset is unable to solve this equation.') elif isinstance(solution_set, FiniteSet): result = list(solution_set) else: period = periodicity(f, symbol) if period is not None: solutions = S.EmptySet iter_solutions = () if isinstance(solution_set, ImageSet): iter_solutions = (solution_set,) elif isinstance(solution_set, Union): if all(isinstance(i, ImageSet) for i in solution_set.args): iter_solutions = solution_set.args for solution in iter_solutions: solutions += solution.intersect(Interval(0, period, False, True)) if isinstance(solutions, FiniteSet): result = list(solutions) else: solution = solution_set.intersect(domain) if isinstance(solution, FiniteSet): result += solution return result ############################################################################### ################################ LINSOLVE ##################################### ############################################################################### def linear_coeffs(eq, *syms, **_kw): """Return a list whose elements are the coefficients of the corresponding symbols in the sum of terms in ``eq``. The additive constant is returned as the last element of the list. Examples ======== >>> from sympy.solvers.solveset import linear_coeffs >>> from sympy.abc import x, y, z >>> linear_coeffs(3*x + 2*y - 1, x, y) [3, 2, -1] It is not necessary to expand the expression: >>> linear_coeffs(x + y*(z*(x*3 + 2) + 3), x) [3*y*z + 1, y*(2*z + 3)] But if there are nonlinear or cross terms -- even if they would cancel after simplification -- an error is raised so the situation does not pass silently past the caller's attention: >>> eq = 1/x*(x - 1) + 1/x >>> linear_coeffs(eq.expand(), x) [0, 1] >>> linear_coeffs(eq, x) Traceback (most recent call last): ... ValueError: nonlinear term encountered: 1/x >>> linear_coeffs(x*(y + 1) - x*y, x, y) Traceback (most recent call last): ... ValueError: nonlinear term encountered: x*(y + 1) """ d = defaultdict(list) c, terms = _sympify(eq).as_coeff_add(*syms) d[0].extend(Add.make_args(c)) for t in terms: m, f = t.as_coeff_mul(*syms) if len(f) != 1: break f = f[0] if f in syms: d[f].append(m) elif f.is_Add: d1 = linear_coeffs(f, *syms, **{'dict': True}) d[0].append(m*d1.pop(0)) for xf, vf in d1.items(): d[xf].append(m*vf) else: break else: for k, v in d.items(): d[k] = Add(*v) if not _kw: return [d.get(s, S.Zero) for s in syms] + [d[0]] return d # default is still list but this won't matter raise ValueError('nonlinear term encountered: %s' % t) def linear_eq_to_matrix(equations, *symbols): r""" Converts a given System of Equations into Matrix form. Here `equations` must be a linear system of equations in `symbols`. Element M[i, j] corresponds to the coefficient of the jth symbol in the ith equation. The Matrix form corresponds to the augmented matrix form. For example: .. math:: 4x + 2y + 3z = 1 .. math:: 3x + y + z = -6 .. math:: 2x + 4y + 9z = 2 This system would return `A` & `b` as given below: :: [ 4 2 3 ] [ 1 ] A = [ 3 1 1 ] b = [-6 ] [ 2 4 9 ] [ 2 ] The only simplification performed is to convert `Eq(a, b) -> a - b`. Raises ====== ValueError The equations contain a nonlinear term. The symbols are not given or are not unique. Examples ======== >>> from sympy import linear_eq_to_matrix, symbols >>> c, x, y, z = symbols('c, x, y, z') The coefficients (numerical or symbolic) of the symbols will be returned as matrices: >>> eqns = [c*x + z - 1 - c, y + z, x - y] >>> A, b = linear_eq_to_matrix(eqns, [x, y, z]) >>> A Matrix([ [c, 0, 1], [0, 1, 1], [1, -1, 0]]) >>> b Matrix([ [c + 1], [ 0], [ 0]]) This routine does not simplify expressions and will raise an error if nonlinearity is encountered: >>> eqns = [ ... (x**2 - 3*x)/(x - 3) - 3, ... y**2 - 3*y - y*(y - 4) + x - 4] >>> linear_eq_to_matrix(eqns, [x, y]) Traceback (most recent call last): ... ValueError: The term (x**2 - 3*x)/(x - 3) is nonlinear in {x, y} Simplifying these equations will discard the removable singularity in the first, reveal the linear structure of the second: >>> [e.simplify() for e in eqns] [x - 3, x + y - 4] Any such simplification needed to eliminate nonlinear terms must be done before calling this routine. """ if not symbols: raise ValueError(filldedent(''' Symbols must be given, for which coefficients are to be found. ''')) if hasattr(symbols[0], '__iter__'): symbols = symbols[0] for i in symbols: if not isinstance(i, Symbol): raise ValueError(filldedent(''' Expecting a Symbol but got %s ''' % i)) if has_dups(symbols): raise ValueError('Symbols must be unique') equations = sympify(equations) if isinstance(equations, MatrixBase): equations = list(equations) elif isinstance(equations, Expr): equations = [equations] elif not is_sequence(equations): raise ValueError(filldedent(''' Equation(s) must be given as a sequence, Expr, Eq or Matrix. ''')) A, b = [], [] for i, f in enumerate(equations): if isinstance(f, Equality): f = f.rewrite(Add, evaluate=False) coeff_list = linear_coeffs(f, *symbols) b.append(-coeff_list.pop()) A.append(coeff_list) A, b = map(Matrix, (A, b)) return A, b def linsolve(system, *symbols): r""" Solve system of N linear equations with M variables; both underdetermined and overdetermined systems are supported. The possible number of solutions is zero, one or infinite. Zero solutions throws a ValueError, whereas infinite solutions are represented parametrically in terms of the given symbols. For unique solution a FiniteSet of ordered tuples is returned. All Standard input formats are supported: For the given set of Equations, the respective input types are given below: .. math:: 3x + 2y - z = 1 .. math:: 2x - 2y + 4z = -2 .. math:: 2x - y + 2z = 0 * Augmented Matrix Form, `system` given below: :: [3 2 -1 1] system = [2 -2 4 -2] [2 -1 2 0] * List Of Equations Form `system = [3x + 2y - z - 1, 2x - 2y + 4z + 2, 2x - y + 2z]` * Input A & b Matrix Form (from Ax = b) are given as below: :: [3 2 -1 ] [ 1 ] A = [2 -2 4 ] b = [ -2 ] [2 -1 2 ] [ 0 ] `system = (A, b)` Symbols can always be passed but are actually only needed when 1) a system of equations is being passed and 2) the system is passed as an underdetermined matrix and one wants to control the name of the free variables in the result. An error is raised if no symbols are used for case 1, but if no symbols are provided for case 2, internally generated symbols will be provided. When providing symbols for case 2, there should be at least as many symbols are there are columns in matrix A. The algorithm used here is Gauss-Jordan elimination, which results, after elimination, in a row echelon form matrix. Returns ======= A FiniteSet containing an ordered tuple of values for the unknowns for which the `system` has a solution. (Wrapping the tuple in FiniteSet is used to maintain a consistent output format throughout solveset.) Returns EmptySet(), if the linear system is inconsistent. Raises ====== ValueError The input is not valid. The symbols are not given. Examples ======== >>> from sympy import Matrix, S, linsolve, symbols >>> x, y, z = symbols("x, y, z") >>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 10]]) >>> b = Matrix([3, 6, 9]) >>> A Matrix([ [1, 2, 3], [4, 5, 6], [7, 8, 10]]) >>> b Matrix([ [3], [6], [9]]) >>> linsolve((A, b), [x, y, z]) {(-1, 2, 0)} * Parametric Solution: In case the system is underdetermined, the function will return a parametric solution in terms of the given symbols. Those that are free will be returned unchanged. e.g. in the system below, `z` is returned as the solution for variable z; it can take on any value. >>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) >>> b = Matrix([3, 6, 9]) >>> linsolve((A, b), x, y, z) {(z - 1, 2 - 2*z, z)} If no symbols are given, internally generated symbols will be used. The `tau0` in the 3rd position indicates (as before) that the 3rd variable -- whatever it's named -- can take on any value: >>> linsolve((A, b)) {(tau0 - 1, 2 - 2*tau0, tau0)} * List of Equations as input >>> Eqns = [3*x + 2*y - z - 1, 2*x - 2*y + 4*z + 2, - x + y/2 - z] >>> linsolve(Eqns, x, y, z) {(1, -2, -2)} * Augmented Matrix as input >>> aug = Matrix([[2, 1, 3, 1], [2, 6, 8, 3], [6, 8, 18, 5]]) >>> aug Matrix([ [2, 1, 3, 1], [2, 6, 8, 3], [6, 8, 18, 5]]) >>> linsolve(aug, x, y, z) {(3/10, 2/5, 0)} * Solve for symbolic coefficients >>> a, b, c, d, e, f = symbols('a, b, c, d, e, f') >>> eqns = [a*x + b*y - c, d*x + e*y - f] >>> linsolve(eqns, x, y) {((-b*f + c*e)/(a*e - b*d), (a*f - c*d)/(a*e - b*d))} * A degenerate system returns solution as set of given symbols. >>> system = Matrix(([0, 0, 0], [0, 0, 0], [0, 0, 0])) >>> linsolve(system, x, y) {(x, y)} * For an empty system linsolve returns empty set >>> linsolve([], x) EmptySet() * An error is raised if, after expansion, any nonlinearity is detected: >>> linsolve([x*(1/x - 1), (y - 1)**2 - y**2 + 1], x, y) {(1, 1)} >>> linsolve([x**2 - 1], x) Traceback (most recent call last): ... ValueError: The term x**2 is nonlinear in {x} """ if not system: return S.EmptySet # If second argument is an iterable if symbols and hasattr(symbols[0], '__iter__'): symbols = symbols[0] sym_gen = isinstance(symbols, GeneratorType) swap = {} b = None # if we don't get b the input was bad syms_needed_msg = None # unpack system if hasattr(system, '__iter__'): # 1). (A, b) if len(system) == 2 and isinstance(system[0], Matrix): A, b = system # 2). (eq1, eq2, ...) if not isinstance(system[0], Matrix): if sym_gen or not symbols: raise ValueError(filldedent(''' When passing a system of equations, the explicit symbols for which a solution is being sought must be given as a sequence, too. ''')) system = [ _mexpand(i.lhs - i.rhs if isinstance(i, Eq) else i, recursive=True) for i in system] system, symbols, swap = recast_to_symbols(system, symbols) A, b = linear_eq_to_matrix(system, symbols) syms_needed_msg = 'free symbols in the equations provided' elif isinstance(system, Matrix) and not ( symbols and not isinstance(symbols, GeneratorType) and isinstance(symbols[0], Matrix)): # 3). A augmented with b A, b = system[:, :-1], system[:, -1:] if b is None: raise ValueError("Invalid arguments") syms_needed_msg = syms_needed_msg or 'columns of A' if sym_gen: symbols = [next(symbols) for i in range(A.cols)] if any(set(symbols) & (A.free_symbols | b.free_symbols)): raise ValueError(filldedent(''' At least one of the symbols provided already appears in the system to be solved. One way to avoid this is to use Dummy symbols in the generator, e.g. numbered_symbols('%s', cls=Dummy) ''' % symbols[0].name.rstrip('1234567890'))) try: solution, params, free_syms = A.gauss_jordan_solve(b, freevar=True) except ValueError: # No solution return S.EmptySet # Replace free parameters with free symbols if params: if not symbols: symbols = [_ for _ in params] # re-use the parameters but put them in order # params [x, y, z] # free_symbols [2, 0, 4] # idx [1, 0, 2] idx = list(zip(*sorted(zip(free_syms, range(len(free_syms))))))[1] # simultaneous replacements {y: x, x: y, z: z} replace_dict = dict(zip(symbols, [symbols[i] for i in idx])) elif len(symbols) >= A.cols: replace_dict = {v: symbols[free_syms[k]] for k, v in enumerate(params)} else: raise IndexError(filldedent(''' the number of symbols passed should have a length equal to the number of %s. ''' % syms_needed_msg)) solution = [sol.xreplace(replace_dict) for sol in solution] solution = [simplify(sol).xreplace(swap) for sol in solution] return FiniteSet(tuple(solution)) ############################################################################## # ------------------------------nonlinsolve ---------------------------------# ############################################################################## def _return_conditionset(eqs, symbols): # return conditionset condition_set = ConditionSet( Tuple(*symbols), FiniteSet(*eqs), S.Complexes) return condition_set def substitution(system, symbols, result=[{}], known_symbols=[], exclude=[], all_symbols=None): r""" Solves the `system` using substitution method. It is used in `nonlinsolve`. This will be called from `nonlinsolve` when any equation(s) is non polynomial equation. Parameters ========== system : list of equations The target system of equations symbols : list of symbols to be solved. The variable(s) for which the system is solved known_symbols : list of solved symbols Values are known for these variable(s) result : An empty list or list of dict If No symbol values is known then empty list otherwise symbol as keys and corresponding value in dict. exclude : Set of expression. Mostly denominator expression(s) of the equations of the system. Final solution should not satisfy these expressions. all_symbols : known_symbols + symbols(unsolved). Returns ======= A FiniteSet of ordered tuple of values of `all_symbols` for which the `system` has solution. Order of values in the tuple is same as symbols present in the parameter `all_symbols`. If parameter `all_symbols` is None then same as symbols present in the parameter `symbols`. Please note that general FiniteSet is unordered, the solution returned here is not simply a FiniteSet of solutions, rather it is a FiniteSet of ordered tuple, i.e. the first & only argument to FiniteSet is a tuple of solutions, which is ordered, & hence the returned solution is ordered. Also note that solution could also have been returned as an ordered tuple, FiniteSet is just a wrapper `{}` around the tuple. It has no other significance except for the fact it is just used to maintain a consistent output format throughout the solveset. Raises ====== ValueError The input is not valid. The symbols are not given. AttributeError The input symbols are not `Symbol` type. Examples ======== >>> from sympy.core.symbol import symbols >>> x, y = symbols('x, y', real=True) >>> from sympy.solvers.solveset import substitution >>> substitution([x + y], [x], [{y: 1}], [y], set([]), [x, y]) {(-1, 1)} * when you want soln should not satisfy eq `x + 1 = 0` >>> substitution([x + y], [x], [{y: 1}], [y], set([x + 1]), [y, x]) EmptySet() >>> substitution([x + y], [x], [{y: 1}], [y], set([x - 1]), [y, x]) {(1, -1)} >>> substitution([x + y - 1, y - x**2 + 5], [x, y]) {(-3, 4), (2, -1)} * Returns both real and complex solution >>> x, y, z = symbols('x, y, z') >>> from sympy import exp, sin >>> substitution([exp(x) - sin(y), y**2 - 4], [x, y]) {(log(sin(2)), 2), (ImageSet(Lambda(_n, I*(2*_n*pi + pi) + log(sin(2))), Integers), -2), (ImageSet(Lambda(_n, 2*_n*I*pi + Mod(log(sin(2)), 2*I*pi)), Integers), 2)} >>> eqs = [z**2 + exp(2*x) - sin(y), -3 + exp(-y)] >>> substitution(eqs, [y, z]) {(-log(3), -sqrt(-exp(2*x) - sin(log(3)))), (-log(3), sqrt(-exp(2*x) - sin(log(3)))), (ImageSet(Lambda(_n, 2*_n*I*pi + Mod(-log(3), 2*I*pi)), Integers), ImageSet(Lambda(_n, -sqrt(-exp(2*x) + sin(2*_n*I*pi + Mod(-log(3), 2*I*pi)))), Integers)), (ImageSet(Lambda(_n, 2*_n*I*pi + Mod(-log(3), 2*I*pi)), Integers), ImageSet(Lambda(_n, sqrt(-exp(2*x) + sin(2*_n*I*pi + Mod(-log(3), 2*I*pi)))), Integers))} """ from sympy import Complement from sympy.core.compatibility import is_sequence if not system: return S.EmptySet if not symbols: msg = ('Symbols must be given, for which solution of the ' 'system is to be found.') raise ValueError(filldedent(msg)) if not is_sequence(symbols): msg = ('symbols should be given as a sequence, e.g. a list.' 'Not type %s: %s') raise TypeError(filldedent(msg % (type(symbols), symbols))) sym = getattr(symbols[0], 'is_Symbol', False) if not sym: msg = ('Iterable of symbols must be given as ' 'second argument, not type %s: %s') raise ValueError(filldedent(msg % (type(symbols[0]), symbols[0]))) # By default `all_symbols` will be same as `symbols` if all_symbols is None: all_symbols = symbols old_result = result # storing complements and intersection for particular symbol complements = {} intersections = {} # when total_solveset_call is equals to total_conditionset # means solvest fail to solve all the eq. total_conditionset = -1 total_solveset_call = -1 def _unsolved_syms(eq, sort=False): """Returns the unsolved symbol present in the equation `eq`. """ free = eq.free_symbols unsolved = (free - set(known_symbols)) & set(all_symbols) if sort: unsolved = list(unsolved) unsolved.sort(key=default_sort_key) return unsolved # end of _unsolved_syms() # sort such that equation with the fewest potential symbols is first. # means eq with less number of variable first in the list. eqs_in_better_order = list( ordered(system, lambda _: len(_unsolved_syms(_)))) def add_intersection_complement(result, sym_set, **flags): # If solveset have returned some intersection/complement # for any symbol. It will be added in final solution. final_result = [] for res in result: res_copy = res for key_res, value_res in res.items(): # Intersection/complement is in Interval or Set. intersection_true = flags.get('Intersection', True) complements_true = flags.get('Complement', True) for key_sym, value_sym in sym_set.items(): if key_sym == key_res: if intersection_true: # testcase is not added for this line(intersection) new_value = \ Intersection(FiniteSet(value_res), value_sym) if new_value is not S.EmptySet: res_copy[key_res] = new_value if complements_true: new_value = \ Complement(FiniteSet(value_res), value_sym) if new_value is not S.EmptySet: res_copy[key_res] = new_value final_result.append(res_copy) return final_result # end of def add_intersection_complement() def _extract_main_soln(sol, soln_imageset): """separate the Complements, Intersections, ImageSet lambda expr and it's base_set. """ # if there is union, then need to check # Complement, Intersection, Imageset. # Order should not be changed. if isinstance(sol, Complement): # extract solution and complement complements[sym] = sol.args[1] sol = sol.args[0] # complement will be added at the end # using `add_intersection_complement` method if isinstance(sol, Intersection): # Interval/Set will be at 0th index always if sol.args[0] != Interval(-oo, oo): # sometimes solveset returns soln # with intersection `S.Reals`, to confirm that # soln is in `domain=S.Reals` or not. We don't consider # that intersection. intersections[sym] = sol.args[0] sol = sol.args[1] # after intersection and complement Imageset should # be checked. if isinstance(sol, ImageSet): soln_imagest = sol expr2 = sol.lamda.expr sol = FiniteSet(expr2) soln_imageset[expr2] = soln_imagest # if there is union of Imageset or other in soln. # no testcase is written for this if block if isinstance(sol, Union): sol_args = sol.args sol = S.EmptySet # We need in sequence so append finteset elements # and then imageset or other. for sol_arg2 in sol_args: if isinstance(sol_arg2, FiniteSet): sol += sol_arg2 else: # ImageSet, Intersection, complement then # append them directly sol += FiniteSet(sol_arg2) if not isinstance(sol, FiniteSet): sol = FiniteSet(sol) return sol, soln_imageset # end of def _extract_main_soln() # helper function for _append_new_soln def _check_exclude(rnew, imgset_yes): rnew_ = rnew if imgset_yes: # replace all dummy variables (Imageset lambda variables) # with zero before `checksol`. Considering fundamental soln # for `checksol`. rnew_copy = rnew.copy() dummy_n = imgset_yes[0] for key_res, value_res in rnew_copy.items(): rnew_copy[key_res] = value_res.subs(dummy_n, 0) rnew_ = rnew_copy # satisfy_exclude == true if it satisfies the expr of `exclude` list. try: # something like : `Mod(-log(3), 2*I*pi)` can't be # simplified right now, so `checksol` returns `TypeError`. # when this issue is fixed this try block should be # removed. Mod(-log(3), 2*I*pi) == -log(3) satisfy_exclude = any( checksol(d, rnew_) for d in exclude) except TypeError: satisfy_exclude = None return satisfy_exclude # end of def _check_exclude() # helper function for _append_new_soln def _restore_imgset(rnew, original_imageset, newresult): restore_sym = set(rnew.keys()) & \ set(original_imageset.keys()) for key_sym in restore_sym: img = original_imageset[key_sym] rnew[key_sym] = img if rnew not in newresult: newresult.append(rnew) # end of def _restore_imgset() def _append_eq(eq, result, res, delete_soln, n=None): u = Dummy('u') if n: eq = eq.subs(n, 0) satisfy = checksol(u, u, eq, minimal=True) if satisfy is False: delete_soln = True res = {} else: result.append(res) return result, res, delete_soln def _append_new_soln(rnew, sym, sol, imgset_yes, soln_imageset, original_imageset, newresult, eq=None): """If `rnew` (A dict <symbol: soln>) contains valid soln append it to `newresult` list. `imgset_yes` is (base, dummy_var) if there was imageset in previously calculated result(otherwise empty tuple). `original_imageset` is dict of imageset expr and imageset from this result. `soln_imageset` dict of imageset expr and imageset of new soln. """ satisfy_exclude = _check_exclude(rnew, imgset_yes) delete_soln = False # soln should not satisfy expr present in `exclude` list. if not satisfy_exclude: local_n = None # if it is imageset if imgset_yes: local_n = imgset_yes[0] base = imgset_yes[1] if sym and sol: # when `sym` and `sol` is `None` means no new # soln. In that case we will append rnew directly after # substituting original imagesets in rnew values if present # (second last line of this function using _restore_imgset) dummy_list = list(sol.atoms(Dummy)) # use one dummy `n` which is in # previous imageset local_n_list = [ local_n for i in range( 0, len(dummy_list))] dummy_zip = zip(dummy_list, local_n_list) lam = Lambda(local_n, sol.subs(dummy_zip)) rnew[sym] = ImageSet(lam, base) if eq is not None: newresult, rnew, delete_soln = _append_eq( eq, newresult, rnew, delete_soln, local_n) elif eq is not None: newresult, rnew, delete_soln = _append_eq( eq, newresult, rnew, delete_soln) elif soln_imageset: rnew[sym] = soln_imageset[sol] # restore original imageset _restore_imgset(rnew, original_imageset, newresult) else: newresult.append(rnew) elif satisfy_exclude: delete_soln = True rnew = {} _restore_imgset(rnew, original_imageset, newresult) return newresult, delete_soln # end of def _append_new_soln() def _new_order_result(result, eq): # separate first, second priority. `res` that makes `eq` value equals # to zero, should be used first then other result(second priority). # If it is not done then we may miss some soln. first_priority = [] second_priority = [] for res in result: if not any(isinstance(val, ImageSet) for val in res.values()): if eq.subs(res) == 0: first_priority.append(res) else: second_priority.append(res) if first_priority or second_priority: return first_priority + second_priority return result def _solve_using_known_values(result, solver): """Solves the system using already known solution (result contains the dict <symbol: value>). solver is `solveset_complex` or `solveset_real`. """ # stores imageset <expr: imageset(Lambda(n, expr), base)>. soln_imageset = {} total_solvest_call = 0 total_conditionst = 0 # sort such that equation with the fewest potential symbols is first. # means eq with less variable first for index, eq in enumerate(eqs_in_better_order): newresult = [] original_imageset = {} # if imageset expr is used to solve other symbol imgset_yes = False result = _new_order_result(result, eq) for res in result: got_symbol = set() # symbols solved in one iteration if soln_imageset: # find the imageset and use its expr. for key_res, value_res in res.items(): if isinstance(value_res, ImageSet): res[key_res] = value_res.lamda.expr original_imageset[key_res] = value_res dummy_n = value_res.lamda.expr.atoms(Dummy).pop() base = value_res.base_set imgset_yes = (dummy_n, base) # update eq with everything that is known so far eq2 = eq.subs(res) unsolved_syms = _unsolved_syms(eq2, sort=True) if not unsolved_syms: if res: newresult, delete_res = _append_new_soln( res, None, None, imgset_yes, soln_imageset, original_imageset, newresult, eq2) if delete_res: # `delete_res` is true, means substituting `res` in # eq2 doesn't return `zero` or deleting the `res` # (a soln) since it staisfies expr of `exclude` # list. result.remove(res) continue # skip as it's independent of desired symbols depen = eq2.as_independent(unsolved_syms)[0] if depen.has(Abs) and solver == solveset_complex: # Absolute values cannot be inverted in the # complex domain continue soln_imageset = {} for sym in unsolved_syms: not_solvable = False try: soln = solver(eq2, sym) total_solvest_call += 1 soln_new = S.EmptySet if isinstance(soln, Complement): # separate solution and complement complements[sym] = soln.args[1] soln = soln.args[0] # complement will be added at the end if isinstance(soln, Intersection): # Interval will be at 0th index always if soln.args[0] != Interval(-oo, oo): # sometimes solveset returns soln # with intersection S.Reals, to confirm that # soln is in domain=S.Reals intersections[sym] = soln.args[0] soln_new += soln.args[1] soln = soln_new if soln_new else soln if index > 0 and solver == solveset_real: # one symbol's real soln , another symbol may have # corresponding complex soln. if not isinstance(soln, (ImageSet, ConditionSet)): soln += solveset_complex(eq2, sym) except NotImplementedError: # If sovleset is not able to solve equation `eq2`. Next # time we may get soln using next equation `eq2` continue if isinstance(soln, ConditionSet): soln = S.EmptySet # don't do `continue` we may get soln # in terms of other symbol(s) not_solvable = True total_conditionst += 1 if soln is not S.EmptySet: soln, soln_imageset = _extract_main_soln( soln, soln_imageset) for sol in soln: # sol is not a `Union` since we checked it # before this loop sol, soln_imageset = _extract_main_soln( sol, soln_imageset) sol = set(sol).pop() free = sol.free_symbols if got_symbol and any([ ss in free for ss in got_symbol ]): # sol depends on previously solved symbols # then continue continue rnew = res.copy() # put each solution in res and append the new result # in the new result list (solution for symbol `s`) # along with old results. for k, v in res.items(): if isinstance(v, Expr): # if any unsolved symbol is present # Then subs known value rnew[k] = v.subs(sym, sol) # and add this new solution if soln_imageset: # replace all lambda variables with 0. imgst = soln_imageset[sol] rnew[sym] = imgst.lamda( *[0 for i in range(0, len( imgst.lamda.variables))]) else: rnew[sym] = sol newresult, delete_res = _append_new_soln( rnew, sym, sol, imgset_yes, soln_imageset, original_imageset, newresult) if delete_res: # deleting the `res` (a soln) since it staisfies # eq of `exclude` list result.remove(res) # solution got for sym if not not_solvable: got_symbol.add(sym) # next time use this new soln if newresult: result = newresult return result, total_solvest_call, total_conditionst # end def _solve_using_know_values() new_result_real, solve_call1, cnd_call1 = _solve_using_known_values( old_result, solveset_real) new_result_complex, solve_call2, cnd_call2 = _solve_using_known_values( old_result, solveset_complex) # when `total_solveset_call` is equals to `total_conditionset` # means solvest fails to solve all the eq. # return conditionset in this case total_conditionset += (cnd_call1 + cnd_call2) total_solveset_call += (solve_call1 + solve_call2) if total_conditionset == total_solveset_call and total_solveset_call != -1: return _return_conditionset(eqs_in_better_order, all_symbols) # overall result result = new_result_real + new_result_complex result_all_variables = [] result_infinite = [] for res in result: if not res: # means {None : None} continue # If length < len(all_symbols) means infinite soln. # Some or all the soln is dependent on 1 symbol. # eg. {x: y+2} then final soln {x: y+2, y: y} if len(res) < len(all_symbols): solved_symbols = res.keys() unsolved = list(filter( lambda x: x not in solved_symbols, all_symbols)) for unsolved_sym in unsolved: res[unsolved_sym] = unsolved_sym result_infinite.append(res) if res not in result_all_variables: result_all_variables.append(res) if result_infinite: # we have general soln # eg : [{x: -1, y : 1}, {x : -y , y: y}] then # return [{x : -y, y : y}] result_all_variables = result_infinite if intersections and complements: # no testcase is added for this block result_all_variables = add_intersection_complement( result_all_variables, intersections, Intersection=True, Complement=True) elif intersections: result_all_variables = add_intersection_complement( result_all_variables, intersections, Intersection=True) elif complements: result_all_variables = add_intersection_complement( result_all_variables, complements, Complement=True) # convert to ordered tuple result = S.EmptySet for r in result_all_variables: temp = [r[symb] for symb in all_symbols] result += FiniteSet(tuple(temp)) return result # end of def substitution() def _solveset_work(system, symbols): soln = solveset(system[0], symbols[0]) if isinstance(soln, FiniteSet): _soln = FiniteSet(*[tuple((s,)) for s in soln]) return _soln else: return FiniteSet(tuple(FiniteSet(soln))) def _handle_positive_dimensional(polys, symbols, denominators): from sympy.polys.polytools import groebner # substitution method where new system is groebner basis of the system _symbols = list(symbols) _symbols.sort(key=default_sort_key) basis = groebner(polys, _symbols, polys=True) new_system = [] for poly_eq in basis: new_system.append(poly_eq.as_expr()) result = [{}] result = substitution( new_system, symbols, result, [], denominators) return result # end of def _handle_positive_dimensional() def _handle_zero_dimensional(polys, symbols, system): # solve 0 dimensional poly system using `solve_poly_system` result = solve_poly_system(polys, *symbols) # May be some extra soln is added because # we used `unrad` in `_separate_poly_nonpoly`, so # need to check and remove if it is not a soln. result_update = S.EmptySet for res in result: dict_sym_value = dict(list(zip(symbols, res))) if all(checksol(eq, dict_sym_value) for eq in system): result_update += FiniteSet(res) return result_update # end of def _handle_zero_dimensional() def _separate_poly_nonpoly(system, symbols): polys = [] polys_expr = [] nonpolys = [] denominators = set() poly = None for eq in system: # Store denom expression if it contains symbol denominators.update(_simple_dens(eq, symbols)) # try to remove sqrt and rational power without_radicals = unrad(simplify(eq)) if without_radicals: eq_unrad, cov = without_radicals if not cov: eq = eq_unrad if isinstance(eq, Expr): eq = eq.as_numer_denom()[0] poly = eq.as_poly(*symbols, extension=True) elif simplify(eq).is_number: continue if poly is not None: polys.append(poly) polys_expr.append(poly.as_expr()) else: nonpolys.append(eq) return polys, polys_expr, nonpolys, denominators # end of def _separate_poly_nonpoly() def nonlinsolve(system, *symbols): r""" Solve system of N non linear equations with M variables, which means both under and overdetermined systems are supported. Positive dimensional system is also supported (A system with infinitely many solutions is said to be positive-dimensional). In Positive dimensional system solution will be dependent on at least one symbol. Returns both real solution and complex solution(If system have). The possible number of solutions is zero, one or infinite. Parameters ========== system : list of equations The target system of equations symbols : list of Symbols symbols should be given as a sequence eg. list Returns ======= A FiniteSet of ordered tuple of values of `symbols` for which the `system` has solution. Order of values in the tuple is same as symbols present in the parameter `symbols`. Please note that general FiniteSet is unordered, the solution returned here is not simply a FiniteSet of solutions, rather it is a FiniteSet of ordered tuple, i.e. the first & only argument to FiniteSet is a tuple of solutions, which is ordered, & hence the returned solution is ordered. Also note that solution could also have been returned as an ordered tuple, FiniteSet is just a wrapper `{}` around the tuple. It has no other significance except for the fact it is just used to maintain a consistent output format throughout the solveset. For the given set of Equations, the respective input types are given below: .. math:: x*y - 1 = 0 .. math:: 4*x**2 + y**2 - 5 = 0 `system = [x*y - 1, 4*x**2 + y**2 - 5]` `symbols = [x, y]` Raises ====== ValueError The input is not valid. The symbols are not given. AttributeError The input symbols are not `Symbol` type. Examples ======== >>> from sympy.core.symbol import symbols >>> from sympy.solvers.solveset import nonlinsolve >>> x, y, z = symbols('x, y, z', real=True) >>> nonlinsolve([x*y - 1, 4*x**2 + y**2 - 5], [x, y]) {(-1, -1), (-1/2, -2), (1/2, 2), (1, 1)} 1. Positive dimensional system and complements: >>> from sympy import pprint >>> from sympy.polys.polytools import is_zero_dimensional >>> a, b, c, d = symbols('a, b, c, d', real=True) >>> eq1 = a + b + c + d >>> eq2 = a*b + b*c + c*d + d*a >>> eq3 = a*b*c + b*c*d + c*d*a + d*a*b >>> eq4 = a*b*c*d - 1 >>> system = [eq1, eq2, eq3, eq4] >>> is_zero_dimensional(system) False >>> pprint(nonlinsolve(system, [a, b, c, d]), use_unicode=False) -1 1 1 -1 {(---, -d, -, {d} \ {0}), (-, -d, ---, {d} \ {0})} d d d d >>> nonlinsolve([(x+y)**2 - 4, x + y - 2], [x, y]) {(2 - y, y)} 2. If some of the equations are non polynomial equation then `nonlinsolve` will call `substitution` function and returns real and complex solutions, if present. >>> from sympy import exp, sin >>> nonlinsolve([exp(x) - sin(y), y**2 - 4], [x, y]) {(log(sin(2)), 2), (ImageSet(Lambda(_n, I*(2*_n*pi + pi) + log(sin(2))), Integers), -2), (ImageSet(Lambda(_n, 2*_n*I*pi + Mod(log(sin(2)), 2*I*pi)), Integers), 2)} 3. If system is Non linear polynomial zero dimensional then it returns both solution (real and complex solutions, if present using `solve_poly_system`): >>> from sympy import sqrt >>> nonlinsolve([x**2 - 2*y**2 -2, x*y - 2], [x, y]) {(-2, -1), (2, 1), (-sqrt(2)*I, sqrt(2)*I), (sqrt(2)*I, -sqrt(2)*I)} 4. `nonlinsolve` can solve some linear(zero or positive dimensional) system (because it is using `groebner` function to get the groebner basis and then `substitution` function basis as the new `system`). But it is not recommended to solve linear system using `nonlinsolve`, because `linsolve` is better for all kind of linear system. >>> nonlinsolve([x + 2*y -z - 3, x - y - 4*z + 9 , y + z - 4], [x, y, z]) {(3*z - 5, 4 - z, z)} 5. System having polynomial equations and only real solution is present (will be solved using `solve_poly_system`): >>> e1 = sqrt(x**2 + y**2) - 10 >>> e2 = sqrt(y**2 + (-x + 10)**2) - 3 >>> nonlinsolve((e1, e2), (x, y)) {(191/20, -3*sqrt(391)/20), (191/20, 3*sqrt(391)/20)} >>> nonlinsolve([x**2 + 2/y - 2, x + y - 3], [x, y]) {(1, 2), (1 - sqrt(5), 2 + sqrt(5)), (1 + sqrt(5), 2 - sqrt(5))} >>> nonlinsolve([x**2 + 2/y - 2, x + y - 3], [y, x]) {(2, 1), (2 - sqrt(5), 1 + sqrt(5)), (2 + sqrt(5), 1 - sqrt(5))} 6. It is better to use symbols instead of Trigonometric Function or Function (e.g. replace `sin(x)` with symbol, replace `f(x)` with symbol and so on. Get soln from `nonlinsolve` and then using `solveset` get the value of `x`) How nonlinsolve is better than old solver `_solve_system` : =========================================================== 1. A positive dimensional system solver : nonlinsolve can return solution for positive dimensional system. It finds the Groebner Basis of the positive dimensional system(calling it as basis) then we can start solving equation(having least number of variable first in the basis) using solveset and substituting that solved solutions into other equation(of basis) to get solution in terms of minimum variables. Here the important thing is how we are substituting the known values and in which equations. 2. Real and Complex both solutions : nonlinsolve returns both real and complex solution. If all the equations in the system are polynomial then using `solve_poly_system` both real and complex solution is returned. If all the equations in the system are not polynomial equation then goes to `substitution` method with this polynomial and non polynomial equation(s), to solve for unsolved variables. Here to solve for particular variable solveset_real and solveset_complex is used. For both real and complex solution function `_solve_using_know_values` is used inside `substitution` function.(`substitution` function will be called when there is any non polynomial equation(s) is present). When solution is valid then add its general solution in the final result. 3. Complement and Intersection will be added if any : nonlinsolve maintains dict for complements and Intersections. If solveset find complements or/and Intersection with any Interval or set during the execution of `substitution` function ,then complement or/and Intersection for that variable is added before returning final solution. """ from sympy.polys.polytools import is_zero_dimensional from sympy.polys import RR if not system: return S.EmptySet if not symbols: msg = ('Symbols must be given, for which solution of the ' 'system is to be found.') raise ValueError(filldedent(msg)) if hasattr(symbols[0], '__iter__'): symbols = symbols[0] if not is_sequence(symbols) or not symbols: msg = ('Symbols must be given, for which solution of the ' 'system is to be found.') raise IndexError(filldedent(msg)) system, symbols, swap = recast_to_symbols(system, symbols) if swap: soln = nonlinsolve(system, symbols) return FiniteSet(*[tuple(i.xreplace(swap) for i in s) for s in soln]) if len(system) == 1 and len(symbols) == 1: return _solveset_work(system, symbols) # main code of def nonlinsolve() starts from here polys, polys_expr, nonpolys, denominators = _separate_poly_nonpoly( system, symbols) if len(symbols) == len(polys): # If all the equations in the system are poly if is_zero_dimensional(polys, symbols): # finite number of soln (Zero dimensional system) try: return _handle_zero_dimensional(polys, symbols, system) except NotImplementedError: # Right now it doesn't fail for any polynomial system of # equation. If `solve_poly_system` fails then `substitution` # method will handle it. result = substitution( polys_expr, symbols, exclude=denominators) return result # positive dimensional system res = _handle_positive_dimensional(polys, symbols, denominators) if isinstance(res, EmptySet) and any(not p.domain.is_Exact for p in polys): raise NotImplementedError("Equation not in exact domain. Try converting to rational") else: return res else: # If all the equations are not polynomial. # Use `substitution` method for the system result = substitution( polys_expr + nonpolys, symbols, exclude=denominators) return result

dc9f7abcaeac2264c9eb775d18273e657213ad1fc9a8db6e0c2897aa4f9ca547

"""Calculus-related methods.""" from .euler import euler_equations from .singularities import (singularities, is_increasing, is_strictly_increasing, is_decreasing, is_strictly_decreasing, is_monotonic) from .finite_diff import finite_diff_weights, apply_finite_diff, as_finite_diff, differentiate_finite from .util import (periodicity, not_empty_in, AccumBounds, is_convex, stationary_points, minimum, maximum) __all__ = [ 'euler_equations', 'singularities', 'is_increasing', 'is_strictly_increasing', 'is_decreasing', 'is_strictly_decreasing', 'is_monotonic', 'finite_diff_weights', 'apply_finite_diff', 'as_finite_diff', 'differentiate_finite', 'periodicity', 'not_empty_in', 'AccumBounds', 'is_convex', 'stationary_points', 'minimum', 'maximum' ]

c83f43d4fa6d2f01ecb082abdaaf8fd1ed073d2e7b6e45ebf8c0fcf75e80ecd3

from sympy import Order, S, log, limit, lcm_list, Abs, im, re, Dummy from sympy.core import Add, Mul, Pow from sympy.core.basic import Basic from sympy.core.compatibility import iterable from sympy.core.expr import AtomicExpr, Expr from sympy.core.numbers import _sympifyit, oo from sympy.core.sympify import _sympify from sympy.functions.elementary.miscellaneous import Min, Max from sympy.logic.boolalg import And from sympy.polys.rationaltools import together from sympy.sets.sets import (Interval, Intersection, FiniteSet, Union, Complement, EmptySet) from sympy.simplify.radsimp import denom from sympy.solvers.inequalities import solve_univariate_inequality from sympy.utilities import filldedent def continuous_domain(f, symbol, domain): """ Returns the intervals in the given domain for which the function is continuous. This method is limited by the ability to determine the various singularities and discontinuities of the given function. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for which the intervals are to be determined. domain : Interval The domain over which the continuity of the symbol has to be checked. Examples ======== >>> from sympy import Symbol, S, tan, log, pi, sqrt >>> from sympy.sets import Interval >>> from sympy.calculus.util import continuous_domain >>> x = Symbol('x') >>> continuous_domain(1/x, x, S.Reals) Union(Interval.open(-oo, 0), Interval.open(0, oo)) >>> continuous_domain(tan(x), x, Interval(0, pi)) Union(Interval.Ropen(0, pi/2), Interval.Lopen(pi/2, pi)) >>> continuous_domain(sqrt(x - 2), x, Interval(-5, 5)) Interval(2, 5) >>> continuous_domain(log(2*x - 1), x, S.Reals) Interval.open(1/2, oo) Returns ======= Interval Union of all intervals where the function is continuous. Raises ====== NotImplementedError If the method to determine continuity of such a function has not yet been developed. """ from sympy.solvers.inequalities import solve_univariate_inequality from sympy.solvers.solveset import solveset, _has_rational_power if domain.is_subset(S.Reals): constrained_interval = domain for atom in f.atoms(Pow): predicate, denomin = _has_rational_power(atom, symbol) if predicate and denomin == 2: constraint = solve_univariate_inequality(atom.base >= 0, symbol).as_set() constrained_interval = Intersection(constraint, constrained_interval) for atom in f.atoms(log): constraint = solve_univariate_inequality(atom.args[0] > 0, symbol).as_set() constrained_interval = Intersection(constraint, constrained_interval) domain = constrained_interval try: if f.has(Abs): sings = solveset(1/f, symbol, domain) + \ solveset(denom(together(f)), symbol, domain) else: for atom in f.atoms(Pow): predicate, denomin = _has_rational_power(atom, symbol) if predicate and denomin == 2: sings = solveset(1/f, symbol, domain) +\ solveset(denom(together(f)), symbol, domain) break else: sings = Intersection(solveset(1/f, symbol), domain) + \ solveset(denom(together(f)), symbol, domain) except NotImplementedError: raise NotImplementedError("Methods for determining the continuous domains" " of this function have not been developed.") return domain - sings def function_range(f, symbol, domain): """ Finds the range of a function in a given domain. This method is limited by the ability to determine the singularities and determine limits. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for which the range of function is to be determined. domain : Interval The domain under which the range of the function has to be found. Examples ======== >>> from sympy import Symbol, S, exp, log, pi, sqrt, sin, tan >>> from sympy.sets import Interval >>> from sympy.calculus.util import function_range >>> x = Symbol('x') >>> function_range(sin(x), x, Interval(0, 2*pi)) Interval(-1, 1) >>> function_range(tan(x), x, Interval(-pi/2, pi/2)) Interval(-oo, oo) >>> function_range(1/x, x, S.Reals) Union(Interval.open(-oo, 0), Interval.open(0, oo)) >>> function_range(exp(x), x, S.Reals) Interval.open(0, oo) >>> function_range(log(x), x, S.Reals) Interval(-oo, oo) >>> function_range(sqrt(x), x , Interval(-5, 9)) Interval(0, 3) Returns ======= Interval Union of all ranges for all intervals under domain where function is continuous. Raises ====== NotImplementedError If any of the intervals, in the given domain, for which function is continuous are not finite or real, OR if the critical points of the function on the domain can't be found. """ from sympy.solvers.solveset import solveset if isinstance(domain, EmptySet): return S.EmptySet period = periodicity(f, symbol) if period is S.Zero: # the expression is constant wrt symbol return FiniteSet(f.expand()) if period is not None: if isinstance(domain, Interval): if (domain.inf - domain.sup).is_infinite: domain = Interval(0, period) elif isinstance(domain, Union): for sub_dom in domain.args: if isinstance(sub_dom, Interval) and \ ((sub_dom.inf - sub_dom.sup).is_infinite): domain = Interval(0, period) intervals = continuous_domain(f, symbol, domain) range_int = S.EmptySet if isinstance(intervals,(Interval, FiniteSet)): interval_iter = (intervals,) elif isinstance(intervals, Union): interval_iter = intervals.args else: raise NotImplementedError(filldedent(''' Unable to find range for the given domain. ''')) for interval in interval_iter: if isinstance(interval, FiniteSet): for singleton in interval: if singleton in domain: range_int += FiniteSet(f.subs(symbol, singleton)) elif isinstance(interval, Interval): vals = S.EmptySet critical_points = S.EmptySet critical_values = S.EmptySet bounds = ((interval.left_open, interval.inf, '+'), (interval.right_open, interval.sup, '-')) for is_open, limit_point, direction in bounds: if is_open: critical_values += FiniteSet(limit(f, symbol, limit_point, direction)) vals += critical_values else: vals += FiniteSet(f.subs(symbol, limit_point)) solution = solveset(f.diff(symbol), symbol, interval) if not iterable(solution): raise NotImplementedError('Unable to find critical points for {}'.format(f)) critical_points += solution for critical_point in critical_points: vals += FiniteSet(f.subs(symbol, critical_point)) left_open, right_open = False, False if critical_values is not S.EmptySet: if critical_values.inf == vals.inf: left_open = True if critical_values.sup == vals.sup: right_open = True range_int += Interval(vals.inf, vals.sup, left_open, right_open) else: raise NotImplementedError(filldedent(''' Unable to find range for the given domain. ''')) return range_int def not_empty_in(finset_intersection, *syms): """ Finds the domain of the functions in `finite_set` in which the `finite_set` is not-empty Parameters ========== finset_intersection : The unevaluated intersection of FiniteSet containing real-valued functions with Union of Sets syms : Tuple of symbols Symbol for which domain is to be found Raises ====== NotImplementedError The algorithms to find the non-emptiness of the given FiniteSet are not yet implemented. ValueError The input is not valid. RuntimeError It is a bug, please report it to the github issue tracker (https://github.com/sympy/sympy/issues). Examples ======== >>> from sympy import FiniteSet, Interval, not_empty_in, oo >>> from sympy.abc import x >>> not_empty_in(FiniteSet(x/2).intersect(Interval(0, 1)), x) Interval(0, 2) >>> not_empty_in(FiniteSet(x, x**2).intersect(Interval(1, 2)), x) Union(Interval(-sqrt(2), -1), Interval(1, 2)) >>> not_empty_in(FiniteSet(x**2/(x + 2)).intersect(Interval(1, oo)), x) Union(Interval.Lopen(-2, -1), Interval(2, oo)) """ # TODO: handle piecewise defined functions # TODO: handle transcendental functions # TODO: handle multivariate functions if len(syms) == 0: raise ValueError("One or more symbols must be given in syms.") if finset_intersection.is_EmptySet: return EmptySet() if isinstance(finset_intersection, Union): elm_in_sets = finset_intersection.args[0] return Union(not_empty_in(finset_intersection.args[1], *syms), elm_in_sets) if isinstance(finset_intersection, FiniteSet): finite_set = finset_intersection _sets = S.Reals else: finite_set = finset_intersection.args[1] _sets = finset_intersection.args[0] if not isinstance(finite_set, FiniteSet): raise ValueError('A FiniteSet must be given, not %s: %s' % (type(finite_set), finite_set)) if len(syms) == 1: symb = syms[0] else: raise NotImplementedError('more than one variables %s not handled' % (syms,)) def elm_domain(expr, intrvl): """ Finds the domain of an expression in any given interval """ from sympy.solvers.solveset import solveset _start = intrvl.start _end = intrvl.end _singularities = solveset(expr.as_numer_denom()[1], symb, domain=S.Reals) if intrvl.right_open: if _end is S.Infinity: _domain1 = S.Reals else: _domain1 = solveset(expr < _end, symb, domain=S.Reals) else: _domain1 = solveset(expr <= _end, symb, domain=S.Reals) if intrvl.left_open: if _start is S.NegativeInfinity: _domain2 = S.Reals else: _domain2 = solveset(expr > _start, symb, domain=S.Reals) else: _domain2 = solveset(expr >= _start, symb, domain=S.Reals) # domain in the interval expr_with_sing = Intersection(_domain1, _domain2) expr_domain = Complement(expr_with_sing, _singularities) return expr_domain if isinstance(_sets, Interval): return Union(*[elm_domain(element, _sets) for element in finite_set]) if isinstance(_sets, Union): _domain = S.EmptySet for intrvl in _sets.args: _domain_element = Union(*[elm_domain(element, intrvl) for element in finite_set]) _domain = Union(_domain, _domain_element) return _domain def periodicity(f, symbol, check=False): """ Tests the given function for periodicity in the given symbol. Parameters ========== f : Expr. The concerned function. symbol : Symbol The variable for which the period is to be determined. check : Boolean, optional The flag to verify whether the value being returned is a period or not. Returns ======= period The period of the function is returned. `None` is returned when the function is aperiodic or has a complex period. The value of `0` is returned as the period of a constant function. Raises ====== NotImplementedError The value of the period computed cannot be verified. Notes ===== Currently, we do not support functions with a complex period. The period of functions having complex periodic values such as `exp`, `sinh` is evaluated to `None`. The value returned might not be the "fundamental" period of the given function i.e. it may not be the smallest periodic value of the function. The verification of the period through the `check` flag is not reliable due to internal simplification of the given expression. Hence, it is set to `False` by default. Examples ======== >>> from sympy import Symbol, sin, cos, tan, exp >>> from sympy.calculus.util import periodicity >>> x = Symbol('x') >>> f = sin(x) + sin(2*x) + sin(3*x) >>> periodicity(f, x) 2*pi >>> periodicity(sin(x)*cos(x), x) pi >>> periodicity(exp(tan(2*x) - 1), x) pi/2 >>> periodicity(sin(4*x)**cos(2*x), x) pi >>> periodicity(exp(x), x) """ from sympy.core.function import diff from sympy.core.mod import Mod from sympy.core.relational import Relational from sympy.functions.elementary.exponential import exp from sympy.functions.elementary.complexes import Abs from sympy.functions.elementary.trigonometric import ( TrigonometricFunction, sin, cos, csc, sec) from sympy.simplify.simplify import simplify from sympy.solvers.decompogen import decompogen from sympy.polys.polytools import degree, lcm_list temp = Dummy('x', real=True) f = f.subs(symbol, temp) symbol = temp def _check(orig_f, period): '''Return the checked period or raise an error.''' new_f = orig_f.subs(symbol, symbol + period) if new_f.equals(orig_f): return period else: raise NotImplementedError(filldedent(''' The period of the given function cannot be verified. When `%s` was replaced with `%s + %s` in `%s`, the result was `%s` which was not recognized as being the same as the original function. So either the period was wrong or the two forms were not recognized as being equal. Set check=False to obtain the value.''' % (symbol, symbol, period, orig_f, new_f))) orig_f = f period = None if isinstance(f, Relational): f = f.lhs - f.rhs f = simplify(f) if symbol not in f.free_symbols: return S.Zero if isinstance(f, TrigonometricFunction): try: period = f.period(symbol) except NotImplementedError: pass if isinstance(f, Abs): arg = f.args[0] if isinstance(arg, (sec, csc, cos)): # all but tan and cot might have a # a period that is half as large # so recast as sin arg = sin(arg.args[0]) period = periodicity(arg, symbol) if period is not None and isinstance(arg, sin): # the argument of Abs was a trigonometric other than # cot or tan; test to see if the half-period # is valid. Abs(arg) has behaviour equivalent to # orig_f, so use that for test: orig_f = Abs(arg) try: return _check(orig_f, period/2) except NotImplementedError as err: if check: raise NotImplementedError(err) # else let new orig_f and period be # checked below if isinstance(f, exp): if im(f) != 0: period_real = periodicity(re(f), symbol) period_imag = periodicity(im(f), symbol) if period_real is not None and period_imag is not None: period = lcim([period_real, period_imag]) if f.is_Pow: base, expo = f.args base_has_sym = base.has(symbol) expo_has_sym = expo.has(symbol) if base_has_sym and not expo_has_sym: period = periodicity(base, symbol) elif expo_has_sym and not base_has_sym: period = periodicity(expo, symbol) else: period = _periodicity(f.args, symbol) elif f.is_Mul: coeff, g = f.as_independent(symbol, as_Add=False) if isinstance(g, TrigonometricFunction) or coeff is not S.One: period = periodicity(g, symbol) else: period = _periodicity(g.args, symbol) elif f.is_Add: k, g = f.as_independent(symbol) if k is not S.Zero: return periodicity(g, symbol) period = _periodicity(g.args, symbol) elif isinstance(f, Mod): a, n = f.args if a == symbol: period = n elif isinstance(a, TrigonometricFunction): period = periodicity(a, symbol) #check if 'f' is linear in 'symbol' elif (a.is_polynomial(symbol) and degree(a, symbol) == 1 and symbol not in n.free_symbols): period = Abs(n / a.diff(symbol)) elif period is None: from sympy.solvers.decompogen import compogen g_s = decompogen(f, symbol) num_of_gs = len(g_s) if num_of_gs > 1: for index, g in enumerate(reversed(g_s)): start_index = num_of_gs - 1 - index g = compogen(g_s[start_index:], symbol) if g != orig_f and g != f: # Fix for issue 12620 period = periodicity(g, symbol) if period is not None: break if period is not None: if check: return _check(orig_f, period) return period return None def _periodicity(args, symbol): """ Helper for `periodicity` to find the period of a list of simpler functions. It uses the `lcim` method to find the least common period of all the functions. Parameters ========== args : Tuple of Symbol All the symbols present in a function. symbol : Symbol The symbol over which the function is to be evaluated. Returns ======= period The least common period of the function for all the symbols of the function. None if for at least one of the symbols the function is aperiodic """ periods = [] for f in args: period = periodicity(f, symbol) if period is None: return None if period is not S.Zero: periods.append(period) if len(periods) > 1: return lcim(periods) return periods[0] def lcim(numbers): """Returns the least common integral multiple of a list of numbers. The numbers can be rational or irrational or a mixture of both. `None` is returned for incommensurable numbers. Parameters ========== numbers : list Numbers (rational and/or irrational) for which lcim is to be found. Returns ======= number lcim if it exists, otherwise `None` for incommensurable numbers. Examples ======== >>> from sympy import S, pi >>> from sympy.calculus.util import lcim >>> lcim([S(1)/2, S(3)/4, S(5)/6]) 15/2 >>> lcim([2*pi, 3*pi, pi, pi/2]) 6*pi >>> lcim([S(1), 2*pi]) """ result = None if all(num.is_irrational for num in numbers): factorized_nums = list(map(lambda num: num.factor(), numbers)) factors_num = list( map(lambda num: num.as_coeff_Mul(), factorized_nums)) term = factors_num[0][1] if all(factor == term for coeff, factor in factors_num): common_term = term coeffs = [coeff for coeff, factor in factors_num] result = lcm_list(coeffs) * common_term elif all(num.is_rational for num in numbers): result = lcm_list(numbers) else: pass return result def is_convex(f, *syms, **kwargs): """Determines the convexity of the function passed in the argument. Parameters ========== f : Expr The concerned function. syms : Tuple of symbols The variables with respect to which the convexity is to be determined. domain : Interval, optional The domain over which the convexity of the function has to be checked. If unspecified, S.Reals will be the default domain. Returns ======= Boolean The method returns `True` if the function is convex otherwise it returns `False`. Raises ====== NotImplementedError The check for the convexity of multivariate functions is not implemented yet. Notes ===== To determine concavity of a function pass `-f` as the concerned function. To determine logarithmic convexity of a function pass log(f) as concerned function. To determine logartihmic concavity of a function pass -log(f) as concerned function. Currently, convexity check of multivariate functions is not handled. Examples ======== >>> from sympy import symbols, exp, oo, Interval >>> from sympy.calculus.util import is_convex >>> x = symbols('x') >>> is_convex(exp(x), x) True >>> is_convex(x**3, x, domain = Interval(-1, oo)) False References ========== .. [1] https://en.wikipedia.org/wiki/Convex_function .. [2] http://www.ifp.illinois.edu/~angelia/L3_convfunc.pdf .. [3] https://en.wikipedia.org/wiki/Logarithmically_convex_function .. [4] https://en.wikipedia.org/wiki/Logarithmically_concave_function .. [5] https://en.wikipedia.org/wiki/Concave_function """ if len(syms) > 1: raise NotImplementedError( "The check for the convexity of multivariate functions is not implemented yet.") f = _sympify(f) domain = kwargs.get('domain', S.Reals) var = syms[0] condition = f.diff(var, 2) < 0 if solve_univariate_inequality(condition, var, False, domain): return False return True def stationary_points(f, symbol, domain=S.Reals): """ Returns the stationary points of a function (where derivative of the function is 0) in the given domain. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for which the stationary points are to be determined. domain : Interval The domain over which the stationary points have to be checked. If unspecified, S.Reals will be the default domain. Examples ======== >>> from sympy import Symbol, S, sin, log, pi, pprint, stationary_points >>> from sympy.sets import Interval >>> x = Symbol('x') >>> stationary_points(1/x, x, S.Reals) EmptySet() >>> pprint(stationary_points(sin(x), x), use_unicode=False) pi 3*pi {2*n*pi + -- | n in Integers} U {2*n*pi + ---- | n in Integers} 2 2 >>> stationary_points(sin(x),x, Interval(0, 4*pi)) {pi/2, 3*pi/2, 5*pi/2, 7*pi/2} """ from sympy import solveset, diff if isinstance(domain, EmptySet): return S.EmptySet domain = continuous_domain(f, symbol, domain) set = solveset(diff(f, symbol), symbol, domain) return set def maximum(f, symbol, domain=S.Reals): """ Returns the maximum value of a function in the given domain. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for maximum value needs to be determined. domain : Interval The domain over which the maximum have to be checked. If unspecified, then Global maximum is returned. Examples ======== >>> from sympy import Symbol, S, sin, cos, pi, maximum >>> from sympy.sets import Interval >>> x = Symbol('x') >>> f = -x**2 + 2*x + 5 >>> maximum(f, x, S.Reals) 6 >>> maximum(sin(x), x, Interval(-pi, pi/4)) sqrt(2)/2 >>> maximum(sin(x)*cos(x), x) 1/2 """ from sympy import Symbol if isinstance(symbol, Symbol): if isinstance(domain, EmptySet): raise ValueError("Maximum value not defined for empty domain.") return function_range(f, symbol, domain).sup else: raise ValueError("%s is not a valid symbol." % symbol) def minimum(f, symbol, domain=S.Reals): """ Returns the minimum value of a function in the given domain. Parameters ========== f : Expr The concerned function. symbol : Symbol The variable for minimum value needs to be determined. domain : Interval The domain over which the minimum have to be checked. If unspecified, then Global minimum is returned. Examples ======== >>> from sympy import Symbol, S, sin, cos, minimum >>> from sympy.sets import Interval >>> x = Symbol('x') >>> f = x**2 + 2*x + 5 >>> minimum(f, x, S.Reals) 4 >>> minimum(sin(x), x, Interval(2, 3)) sin(3) >>> minimum(sin(x)*cos(x), x) -1/2 """ from sympy import Symbol if isinstance(symbol, Symbol): if isinstance(domain, EmptySet): raise ValueError("Minimum value not defined for empty domain.") return function_range(f, symbol, domain).inf else: raise ValueError("%s is not a valid symbol." % symbol) class AccumulationBounds(AtomicExpr): r""" # Note AccumulationBounds has an alias: AccumBounds AccumulationBounds represent an interval `[a, b]`, which is always closed at the ends. Here `a` and `b` can be any value from extended real numbers. The intended meaning of AccummulationBounds is to give an approximate location of the accumulation points of a real function at a limit point. Let `a` and `b` be reals such that a <= b. `\left\langle a, b\right\rangle = \{x \in \mathbb{R} \mid a \le x \le b\}` `\left\langle -\infty, b\right\rangle = \{x \in \mathbb{R} \mid x \le b\} \cup \{-\infty, \infty\}` `\left\langle a, \infty \right\rangle = \{x \in \mathbb{R} \mid a \le x\} \cup \{-\infty, \infty\}` `\left\langle -\infty, \infty \right\rangle = \mathbb{R} \cup \{-\infty, \infty\}` `oo` and `-oo` are added to the second and third definition respectively, since if either `-oo` or `oo` is an argument, then the other one should be included (though not as an end point). This is forced, since we have, for example, `1/AccumBounds(0, 1) = AccumBounds(1, oo)`, and the limit at `0` is not one-sided. As x tends to `0-`, then `1/x -> -oo`, so `-oo` should be interpreted as belonging to `AccumBounds(1, oo)` though it need not appear explicitly. In many cases it suffices to know that the limit set is bounded. However, in some other cases more exact information could be useful. For example, all accumulation values of cos(x) + 1 are non-negative. (AccumBounds(-1, 1) + 1 = AccumBounds(0, 2)) A AccumulationBounds object is defined to be real AccumulationBounds, if its end points are finite reals. Let `X`, `Y` be real AccumulationBounds, then their sum, difference, product are defined to be the following sets: `X + Y = \{ x+y \mid x \in X \cap y \in Y\}` `X - Y = \{ x-y \mid x \in X \cap y \in Y\}` `X * Y = \{ x*y \mid x \in X \cap y \in Y\}` There is, however, no consensus on Interval division. `X / Y = \{ z \mid \exists x \in X, y \in Y \mid y \neq 0, z = x/y\}` Note: According to this definition the quotient of two AccumulationBounds may not be a AccumulationBounds object but rather a union of AccumulationBounds. Note ==== The main focus in the interval arithmetic is on the simplest way to calculate upper and lower endpoints for the range of values of a function in one or more variables. These barriers are not necessarily the supremum or infimum, since the precise calculation of those values can be difficult or impossible. Examples ======== >>> from sympy import AccumBounds, sin, exp, log, pi, E, S, oo >>> from sympy.abc import x >>> AccumBounds(0, 1) + AccumBounds(1, 2) AccumBounds(1, 3) >>> AccumBounds(0, 1) - AccumBounds(0, 2) AccumBounds(-2, 1) >>> AccumBounds(-2, 3)*AccumBounds(-1, 1) AccumBounds(-3, 3) >>> AccumBounds(1, 2)*AccumBounds(3, 5) AccumBounds(3, 10) The exponentiation of AccumulationBounds is defined as follows: If 0 does not belong to `X` or `n > 0` then `X^n = \{ x^n \mid x \in X\}` otherwise `X^n = \{ x^n \mid x \neq 0, x \in X\} \cup \{-\infty, \infty\}` Here for fractional `n`, the part of `X` resulting in a complex AccumulationBounds object is neglected. >>> AccumBounds(-1, 4)**(S(1)/2) AccumBounds(0, 2) >>> AccumBounds(1, 2)**2 AccumBounds(1, 4) >>> AccumBounds(-1, oo)**(-1) AccumBounds(-oo, oo) Note: `<a, b>^2` is not same as `<a, b>*<a, b>` >>> AccumBounds(-1, 1)**2 AccumBounds(0, 1) >>> AccumBounds(1, 3) < 4 True >>> AccumBounds(1, 3) < -1 False Some elementary functions can also take AccumulationBounds as input. A function `f` evaluated for some real AccumulationBounds `<a, b>` is defined as `f(\left\langle a, b\right\rangle) = \{ f(x) \mid a \le x \le b \}` >>> sin(AccumBounds(pi/6, pi/3)) AccumBounds(1/2, sqrt(3)/2) >>> exp(AccumBounds(0, 1)) AccumBounds(1, E) >>> log(AccumBounds(1, E)) AccumBounds(0, 1) Some symbol in an expression can be substituted for a AccumulationBounds object. But it doesn't necessarily evaluate the AccumulationBounds for that expression. Same expression can be evaluated to different values depending upon the form it is used for substitution. For example: >>> (x**2 + 2*x + 1).subs(x, AccumBounds(-1, 1)) AccumBounds(-1, 4) >>> ((x + 1)**2).subs(x, AccumBounds(-1, 1)) AccumBounds(0, 4) References ========== .. [1] https://en.wikipedia.org/wiki/Interval_arithmetic .. [2] http://fab.cba.mit.edu/classes/S62.12/docs/Hickey_interval.pdf Notes ===== Do not use ``AccumulationBounds`` for floating point interval arithmetic calculations, use ``mpmath.iv`` instead. """ is_real = True def __new__(cls, min, max): min = _sympify(min) max = _sympify(max) inftys = [S.Infinity, S.NegativeInfinity] # Only allow real intervals (use symbols with 'is_real=True'). if not (min.is_real or min in inftys) \ or not (max.is_real or max in inftys): raise ValueError("Only real AccumulationBounds are supported") # Make sure that the created AccumBounds object will be valid. if max.is_comparable and min.is_comparable: if max < min: raise ValueError( "Lower limit should be smaller than upper limit") if max == min: return max return Basic.__new__(cls, min, max) # setting the operation priority _op_priority = 11.0 @property def min(self): """ Returns the minimum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).min 1 """ return self.args[0] @property def max(self): """ Returns the maximum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).max 3 """ return self.args[1] @property def delta(self): """ Returns the difference of maximum possible value attained by AccumulationBounds object and minimum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).delta 2 """ return self.max - self.min @property def mid(self): """ Returns the mean of maximum possible value attained by AccumulationBounds object and minimum possible value attained by AccumulationBounds object. Examples ======== >>> from sympy import AccumBounds >>> AccumBounds(1, 3).mid 2 """ return (self.min + self.max) / 2 @_sympifyit('other', NotImplemented) def _eval_power(self, other): return self.__pow__(other) @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): return AccumBounds( Add(self.min, other.min), Add(self.max, other.max)) if other is S.Infinity and self.min is S.NegativeInfinity or \ other is S.NegativeInfinity and self.max is S.Infinity: return AccumBounds(-oo, oo) elif other.is_real: return AccumBounds(Add(self.min, other), Add(self.max, other)) return Add(self, other, evaluate=False) return NotImplemented __radd__ = __add__ def __neg__(self): return AccumBounds(-self.max, -self.min) @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): return AccumBounds( Add(self.min, -other.max), Add(self.max, -other.min)) if other is S.NegativeInfinity and self.min is S.NegativeInfinity or \ other is S.Infinity and self.max is S.Infinity: return AccumBounds(-oo, oo) elif other.is_real: return AccumBounds( Add(self.min, -other), Add(self.max, -other)) return Add(self, -other, evaluate=False) return NotImplemented @_sympifyit('other', NotImplemented) def __rsub__(self, other): return self.__neg__() + other @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): return AccumBounds(Min(Mul(self.min, other.min), Mul(self.min, other.max), Mul(self.max, other.min), Mul(self.max, other.max)), Max(Mul(self.min, other.min), Mul(self.min, other.max), Mul(self.max, other.min), Mul(self.max, other.max))) if other is S.Infinity: if self.min.is_zero: return AccumBounds(0, oo) if self.max.is_zero: return AccumBounds(-oo, 0) if other is S.NegativeInfinity: if self.min.is_zero: return AccumBounds(-oo, 0) if self.max.is_zero: return AccumBounds(0, oo) if other.is_real: if other.is_zero: if self == AccumBounds(-oo, oo): return AccumBounds(-oo, oo) if self.max is S.Infinity: return AccumBounds(0, oo) if self.min is S.NegativeInfinity: return AccumBounds(-oo, 0) return S.Zero if other.is_positive: return AccumBounds( Mul(self.min, other), Mul(self.max, other)) elif other.is_negative: return AccumBounds( Mul(self.max, other), Mul(self.min, other)) if isinstance(other, Order): return other return Mul(self, other, evaluate=False) return NotImplemented __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Expr): if isinstance(other, AccumBounds): if S.Zero not in other: return self * AccumBounds(1/other.max, 1/other.min) if S.Zero in self and S.Zero in other: if self.min.is_zero and other.min.is_zero: return AccumBounds(0, oo) if self.max.is_zero and other.min.is_zero: return AccumBounds(-oo, 0) return AccumBounds(-oo, oo) if self.max.is_negative: if other.min.is_negative: if other.max.is_zero: return AccumBounds(self.max / other.min, oo) if other.max.is_positive: # the actual answer is a Union of AccumBounds, # Union(AccumBounds(-oo, self.max/other.max), # AccumBounds(self.max/other.min, oo)) return AccumBounds(-oo, oo) if other.min.is_zero and other.max.is_positive: return AccumBounds(-oo, self.max / other.max) if self.min.is_positive: if other.min.is_negative: if other.max.is_zero: return AccumBounds(-oo, self.min / other.min) if other.max.is_positive: # the actual answer is a Union of AccumBounds, # Union(AccumBounds(-oo, self.min/other.min), # AccumBounds(self.min/other.max, oo)) return AccumBounds(-oo, oo) if other.min.is_zero and other.max.is_positive: return AccumBounds(self.min / other.max, oo) elif other.is_real: if other is S.Infinity or other is S.NegativeInfinity: if self == AccumBounds(-oo, oo): return AccumBounds(-oo, oo) if self.max is S.Infinity: return AccumBounds(Min(0, other), Max(0, other)) if self.min is S.NegativeInfinity: return AccumBounds(Min(0, -other), Max(0, -other)) if other.is_positive: return AccumBounds(self.min / other, self.max / other) elif other.is_negative: return AccumBounds(self.max / other, self.min / other) return Mul(self, 1 / other, evaluate=False) return NotImplemented __truediv__ = __div__ @_sympifyit('other', NotImplemented) def __rdiv__(self, other): if isinstance(other, Expr): if other.is_real: if other.is_zero: return S.Zero if S.Zero in self: if self.min == S.Zero: if other.is_positive: return AccumBounds(Mul(other, 1 / self.max), oo) if other.is_negative: return AccumBounds(-oo, Mul(other, 1 / self.max)) if self.max == S.Zero: if other.is_positive: return AccumBounds(-oo, Mul(other, 1 / self.min)) if other.is_negative: return AccumBounds(Mul(other, 1 / self.min), oo) return AccumBounds(-oo, oo) else: return AccumBounds(Min(other / self.min, other / self.max), Max(other / self.min, other / self.max)) return Mul(other, 1 / self, evaluate=False) else: return NotImplemented __rtruediv__ = __rdiv__ @_sympifyit('other', NotImplemented) def __pow__(self, other): from sympy.functions.elementary.miscellaneous import real_root if isinstance(other, Expr): if other is S.Infinity: if self.min.is_nonnegative: if self.max < 1: return S.Zero if self.min > 1: return S.Infinity return AccumBounds(0, oo) elif self.max.is_negative: if self.min > -1: return S.Zero if self.max < -1: return FiniteSet(-oo, oo) return AccumBounds(-oo, oo) else: if self.min > -1: if self.max < 1: return S.Zero return AccumBounds(0, oo) return AccumBounds(-oo, oo) if other is S.NegativeInfinity: return (1 / self)**oo if other.is_real and other.is_number: if other.is_zero: return S.One if other.is_Integer: if self.min.is_positive: return AccumBounds( Min(self.min ** other, self.max ** other), Max(self.min ** other, self.max ** other)) elif self.max.is_negative: return AccumBounds( Min(self.max ** other, self.min ** other), Max(self.max ** other, self.min ** other)) if other % 2 == 0: if other.is_negative: if self.min.is_zero: return AccumBounds(self.max**other, oo) if self.max.is_zero: return AccumBounds(self.min**other, oo) return AccumBounds(0, oo) return AccumBounds( S.Zero, Max(self.min**other, self.max**other)) else: if other.is_negative: if self.min.is_zero: return AccumBounds(self.max**other, oo) if self.max.is_zero: return AccumBounds(-oo, self.min**other) return AccumBounds(-oo, oo) return AccumBounds(self.min**other, self.max**other) num, den = other.as_numer_denom() if num == S(1): if den % 2 == 0: if S.Zero in self: if self.min.is_negative: return AccumBounds(0, real_root(self.max, den)) return AccumBounds(real_root(self.min, den), real_root(self.max, den)) num_pow = self**num return num_pow**(1 / den) return Pow(self, other, evaluate=False) return NotImplemented def __abs__(self): if self.max.is_negative: return self.__neg__() elif self.min.is_negative: return AccumBounds(S.Zero, Max(abs(self.min), self.max)) else: return self def __lt__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is less than the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) < AccumBounds(4, oo) True >>> AccumBounds(1, 4) < AccumBounds(3, 4) AccumBounds(1, 4) < AccumBounds(3, 4) >>> AccumBounds(1, oo) < -1 False """ other = _sympify(other) if isinstance(other, AccumBounds): if self.max < other.min: return True if self.min >= other.max: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.max < other: return True if self.min >= other: return False return super(AccumulationBounds, self).__lt__(other) def __le__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is less than or equal to the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational. Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) <= AccumBounds(4, oo) True >>> AccumBounds(1, 4) <= AccumBounds(3, 4) AccumBounds(1, 4) <= AccumBounds(3, 4) >>> AccumBounds(1, 3) <= 0 False """ other = _sympify(other) if isinstance(other, AccumBounds): if self.max <= other.min: return True if self.min > other.max: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.max <= other: return True if self.min > other: return False return super(AccumulationBounds, self).__le__(other) def __gt__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is greater than the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational. Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) > AccumBounds(4, oo) False >>> AccumBounds(1, 4) > AccumBounds(3, 4) AccumBounds(1, 4) > AccumBounds(3, 4) >>> AccumBounds(1, oo) > -1 True """ other = _sympify(other) if isinstance(other, AccumBounds): if self.min > other.max: return True if self.max <= other.min: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.min > other: return True if self.max <= other: return False return super(AccumulationBounds, self).__gt__(other) def __ge__(self, other): """ Returns True if range of values attained by `self` AccumulationBounds object is less that the range of values attained by `other`, where other may be any value of type AccumulationBounds object or extended real number value, False if `other` satisfies the same property, else an unevaluated Relational. Examples ======== >>> from sympy import AccumBounds, oo >>> AccumBounds(1, 3) >= AccumBounds(4, oo) False >>> AccumBounds(1, 4) >= AccumBounds(3, 4) AccumBounds(1, 4) >= AccumBounds(3, 4) >>> AccumBounds(1, oo) >= 1 True """ other = _sympify(other) if isinstance(other, AccumBounds): if self.min >= other.max: return True if self.max < other.min: return False elif not(other.is_real or other is S.Infinity or other is S.NegativeInfinity): raise TypeError( "Invalid comparison of %s %s" % (type(other), other)) elif other.is_comparable: if self.min >= other: return True if self.max < other: return False return super(AccumulationBounds, self).__ge__(other) def __contains__(self, other): """ Returns True if other is contained in self, where other belongs to extended real numbers, False if not contained, otherwise TypeError is raised. Examples ======== >>> from sympy import AccumBounds, oo >>> 1 in AccumBounds(-1, 3) True -oo and oo go together as limits (in AccumulationBounds). >>> -oo in AccumBounds(1, oo) True >>> oo in AccumBounds(-oo, 0) True """ other = _sympify(other) if other is S.Infinity or other is S.NegativeInfinity: if self.min is S.NegativeInfinity or self.max is S.Infinity: return True return False rv = And(self.min <= other, self.max >= other) if rv not in (True, False): raise TypeError("input failed to evaluate") return rv def intersection(self, other): """ Returns the intersection of 'self' and 'other'. Here other can be an instance of FiniteSet or AccumulationBounds. Examples ======== >>> from sympy import AccumBounds, FiniteSet >>> AccumBounds(1, 3).intersection(AccumBounds(2, 4)) AccumBounds(2, 3) >>> AccumBounds(1, 3).intersection(AccumBounds(4, 6)) EmptySet() >>> AccumBounds(1, 4).intersection(FiniteSet(1, 2, 5)) {1, 2} """ if not isinstance(other, (AccumBounds, FiniteSet)): raise TypeError( "Input must be AccumulationBounds or FiniteSet object") if isinstance(other, FiniteSet): fin_set = S.EmptySet for i in other: if i in self: fin_set = fin_set + FiniteSet(i) return fin_set if self.max < other.min or self.min > other.max: return S.EmptySet if self.min <= other.min: if self.max <= other.max: return AccumBounds(other.min, self.max) if self.max > other.max: return other if other.min <= self.min: if other.max < self.max: return AccumBounds(self.min, other.max) if other.max > self.max: return self def union(self, other): # TODO : Devise a better method for Union of AccumBounds # this method is not actually correct and # can be made better if not isinstance(other, AccumBounds): raise TypeError( "Input must be AccumulationBounds or FiniteSet object") if self.min <= other.min and self.max >= other.min: return AccumBounds(self.min, Max(self.max, other.max)) if other.min <= self.min and other.max >= self.min: return AccumBounds(other.min, Max(self.max, other.max)) # setting an alias for AccumulationBounds AccumBounds = AccumulationBounds

c5e850695a053a34d55a1339298ed0a3c869e1620f1d3ae554a5fd270f65a24a

""" Generic SymPy-Independent Strategies """ from __future__ import print_function, division from sympy.core.compatibility import get_function_name identity = lambda x: x def exhaust(rule): """ Apply a rule repeatedly until it has no effect """ def exhaustive_rl(expr): new, old = rule(expr), expr while new != old: new, old = rule(new), new return new return exhaustive_rl def memoize(rule): """ Memoized version of a rule """ cache = {} def memoized_rl(expr): if expr in cache: return cache[expr] else: result = rule(expr) cache[expr] = result return result return memoized_rl def condition(cond, rule): """ Only apply rule if condition is true """ def conditioned_rl(expr): if cond(expr): return rule(expr) else: return expr return conditioned_rl def chain(*rules): """ Compose a sequence of rules so that they apply to the expr sequentially """ def chain_rl(expr): for rule in rules: expr = rule(expr) return expr return chain_rl def debug(rule, file=None): """ Print out before and after expressions each time rule is used """ if file is None: from sys import stdout file = stdout def debug_rl(*args, **kwargs): expr = args[0] result = rule(*args, **kwargs) if result != expr: file.write("Rule: %s\n" % get_function_name(rule)) file.write("In: %s\nOut: %s\n\n"%(expr, result)) return result return debug_rl def null_safe(rule): """ Return original expr if rule returns None """ def null_safe_rl(expr): result = rule(expr) if result is None: return expr else: return result return null_safe_rl def tryit(rule): """ Return original expr if rule raises exception """ def try_rl(expr): try: return rule(expr) except Exception: return expr return try_rl def do_one(*rules): """ Try each of the rules until one works. Then stop. """ def do_one_rl(expr): for rl in rules: result = rl(expr) if result != expr: return result return expr return do_one_rl def switch(key, ruledict): """ Select a rule based on the result of key called on the function """ def switch_rl(expr): rl = ruledict.get(key(expr), identity) return rl(expr) return switch_rl def minimize(*rules, **kwargs): """ Select result of rules that minimizes objective >>> from sympy.strategies import minimize >>> inc = lambda x: x + 1 >>> dec = lambda x: x - 1 >>> rl = minimize(inc, dec) >>> rl(4) 3 >>> rl = minimize(inc, dec, objective=lambda x: -x) # maximize >>> rl(4) 5 """ objective = kwargs.get('objective', identity) def minrule(expr): return min([rule(expr) for rule in rules], key=objective) return minrule

e940ef5d609e4969e6bea9db12538f9027af9fd3bc1ae524bb99da53ad2be4fd

""" module for generating C, C++, Fortran77, Fortran90, Julia, Rust and Octave/Matlab routines that evaluate sympy expressions. This module is work in progress. Only the milestones with a '+' character in the list below have been completed. --- How is sympy.utilities.codegen different from sympy.printing.ccode? --- We considered the idea to extend the printing routines for sympy functions in such a way that it prints complete compilable code, but this leads to a few unsurmountable issues that can only be tackled with dedicated code generator: - For C, one needs both a code and a header file, while the printing routines generate just one string. This code generator can be extended to support .pyf files for f2py. - SymPy functions are not concerned with programming-technical issues, such as input, output and input-output arguments. Other examples are contiguous or non-contiguous arrays, including headers of other libraries such as gsl or others. - It is highly interesting to evaluate several sympy functions in one C routine, eventually sharing common intermediate results with the help of the cse routine. This is more than just printing. - From the programming perspective, expressions with constants should be evaluated in the code generator as much as possible. This is different for printing. --- Basic assumptions --- * A generic Routine data structure describes the routine that must be translated into C/Fortran/... code. This data structure covers all features present in one or more of the supported languages. * Descendants from the CodeGen class transform multiple Routine instances into compilable code. Each derived class translates into a specific language. * In many cases, one wants a simple workflow. The friendly functions in the last part are a simple api on top of the Routine/CodeGen stuff. They are easier to use, but are less powerful. --- Milestones --- + First working version with scalar input arguments, generating C code, tests + Friendly functions that are easier to use than the rigorous Routine/CodeGen workflow. + Integer and Real numbers as input and output + Output arguments + InputOutput arguments + Sort input/output arguments properly + Contiguous array arguments (numpy matrices) + Also generate .pyf code for f2py (in autowrap module) + Isolate constants and evaluate them beforehand in double precision + Fortran 90 + Octave/Matlab - Common Subexpression Elimination - User defined comments in the generated code - Optional extra include lines for libraries/objects that can eval special functions - Test other C compilers and libraries: gcc, tcc, libtcc, gcc+gsl, ... - Contiguous array arguments (sympy matrices) - Non-contiguous array arguments (sympy matrices) - ccode must raise an error when it encounters something that can not be translated into c. ccode(integrate(sin(x)/x, x)) does not make sense. - Complex numbers as input and output - A default complex datatype - Include extra information in the header: date, user, hostname, sha1 hash, ... - Fortran 77 - C++ - Python - Julia - Rust - ... """ from __future__ import print_function, division import os import textwrap from sympy import __version__ as sympy_version from sympy.core import Symbol, S, Tuple, Equality, Function, Basic from sympy.core.compatibility import is_sequence, StringIO, string_types from sympy.printing.ccode import c_code_printers from sympy.printing.codeprinter import AssignmentError from sympy.printing.fcode import FCodePrinter from sympy.printing.julia import JuliaCodePrinter from sympy.printing.octave import OctaveCodePrinter from sympy.printing.rust import RustCodePrinter from sympy.tensor import Idx, Indexed, IndexedBase from sympy.matrices import (MatrixSymbol, ImmutableMatrix, MatrixBase, MatrixExpr, MatrixSlice) __all__ = [ # description of routines "Routine", "DataType", "default_datatypes", "get_default_datatype", "Argument", "InputArgument", "OutputArgument", "Result", # routines -> code "CodeGen", "CCodeGen", "FCodeGen", "JuliaCodeGen", "OctaveCodeGen", "RustCodeGen", # friendly functions "codegen", "make_routine", ] # # Description of routines # class Routine(object): """Generic description of evaluation routine for set of expressions. A CodeGen class can translate instances of this class into code in a particular language. The routine specification covers all the features present in these languages. The CodeGen part must raise an exception when certain features are not present in the target language. For example, multiple return values are possible in Python, but not in C or Fortran. Another example: Fortran and Python support complex numbers, while C does not. """ def __init__(self, name, arguments, results, local_vars, global_vars): """Initialize a Routine instance. Parameters ========== name : string Name of the routine. arguments : list of Arguments These are things that appear in arguments of a routine, often appearing on the right-hand side of a function call. These are commonly InputArguments but in some languages, they can also be OutputArguments or InOutArguments (e.g., pass-by-reference in C code). results : list of Results These are the return values of the routine, often appearing on the left-hand side of a function call. The difference between Results and OutputArguments and when you should use each is language-specific. local_vars : list of Results These are variables that will be defined at the beginning of the function. global_vars : list of Symbols Variables which will not be passed into the function. """ # extract all input symbols and all symbols appearing in an expression input_symbols = set([]) symbols = set([]) for arg in arguments: if isinstance(arg, OutputArgument): symbols.update(arg.expr.free_symbols - arg.expr.atoms(Indexed)) elif isinstance(arg, InputArgument): input_symbols.add(arg.name) elif isinstance(arg, InOutArgument): input_symbols.add(arg.name) symbols.update(arg.expr.free_symbols - arg.expr.atoms(Indexed)) else: raise ValueError("Unknown Routine argument: %s" % arg) for r in results: if not isinstance(r, Result): raise ValueError("Unknown Routine result: %s" % r) symbols.update(r.expr.free_symbols - r.expr.atoms(Indexed)) local_symbols = set() for r in local_vars: if isinstance(r, Result): symbols.update(r.expr.free_symbols - r.expr.atoms(Indexed)) local_symbols.add(r.name) else: local_symbols.add(r) symbols = set([s.label if isinstance(s, Idx) else s for s in symbols]) # Check that all symbols in the expressions are covered by # InputArguments/InOutArguments---subset because user could # specify additional (unused) InputArguments or local_vars. notcovered = symbols.difference( input_symbols.union(local_symbols).union(global_vars)) if notcovered != set([]): raise ValueError("Symbols needed for output are not in input " + ", ".join([str(x) for x in notcovered])) self.name = name self.arguments = arguments self.results = results self.local_vars = local_vars self.global_vars = global_vars def __str__(self): return self.__class__.__name__ + "({name!r}, {arguments}, {results}, {local_vars}, {global_vars})".format(**self.__dict__) __repr__ = __str__ @property def variables(self): """Returns a set of all variables possibly used in the routine. For routines with unnamed return values, the dummies that may or may not be used will be included in the set. """ v = set(self.local_vars) for arg in self.arguments: v.add(arg.name) for res in self.results: v.add(res.result_var) return v @property def result_variables(self): """Returns a list of OutputArgument, InOutArgument and Result. If return values are present, they are at the end ot the list. """ args = [arg for arg in self.arguments if isinstance( arg, (OutputArgument, InOutArgument))] args.extend(self.results) return args class DataType(object): """Holds strings for a certain datatype in different languages.""" def __init__(self, cname, fname, pyname, jlname, octname, rsname): self.cname = cname self.fname = fname self.pyname = pyname self.jlname = jlname self.octname = octname self.rsname = rsname default_datatypes = { "int": DataType("int", "INTEGER*4", "int", "", "", "i32"), "float": DataType("double", "REAL*8", "float", "", "", "f64"), "complex": DataType("double", "COMPLEX*16", "complex", "", "", "float") #FIXME: # complex is only supported in fortran, python, julia, and octave. # So to not break c or rust code generation, we stick with double or # float, respecitvely (but actually should raise an exeption for # explicitly complex variables (x.is_complex==True)) } COMPLEX_ALLOWED = False def get_default_datatype(expr, complex_allowed=None): """Derives an appropriate datatype based on the expression.""" if complex_allowed is None: complex_allowed = COMPLEX_ALLOWED if complex_allowed: final_dtype = "complex" else: final_dtype = "float" if expr.is_integer: return default_datatypes["int"] elif expr.is_real: return default_datatypes["float"] elif isinstance(expr, MatrixBase): #check all entries dt = "int" for element in expr: if dt is "int" and not element.is_integer: dt = "float" if dt is "float" and not element.is_real: return default_datatypes[final_dtype] return default_datatypes[dt] else: return default_datatypes[final_dtype] class Variable(object): """Represents a typed variable.""" def __init__(self, name, datatype=None, dimensions=None, precision=None): """Return a new variable. Parameters ========== name : Symbol or MatrixSymbol datatype : optional When not given, the data type will be guessed based on the assumptions on the symbol argument. dimension : sequence containing tupes, optional If present, the argument is interpreted as an array, where this sequence of tuples specifies (lower, upper) bounds for each index of the array. precision : int, optional Controls the precision of floating point constants. """ if not isinstance(name, (Symbol, MatrixSymbol)): raise TypeError("The first argument must be a sympy symbol.") if datatype is None: datatype = get_default_datatype(name) elif not isinstance(datatype, DataType): raise TypeError("The (optional) `datatype' argument must be an " "instance of the DataType class.") if dimensions and not isinstance(dimensions, (tuple, list)): raise TypeError( "The dimension argument must be a sequence of tuples") self._name = name self._datatype = { 'C': datatype.cname, 'FORTRAN': datatype.fname, 'JULIA': datatype.jlname, 'OCTAVE': datatype.octname, 'PYTHON': datatype.pyname, 'RUST': datatype.rsname, } self.dimensions = dimensions self.precision = precision def __str__(self): return "%s(%r)" % (self.__class__.__name__, self.name) __repr__ = __str__ @property def name(self): return self._name def get_datatype(self, language): """Returns the datatype string for the requested language. Examples ======== >>> from sympy import Symbol >>> from sympy.utilities.codegen import Variable >>> x = Variable(Symbol('x')) >>> x.get_datatype('c') 'double' >>> x.get_datatype('fortran') 'REAL*8' """ try: return self._datatype[language.upper()] except KeyError: raise CodeGenError("Has datatypes for languages: %s" % ", ".join(self._datatype)) class Argument(Variable): """An abstract Argument data structure: a name and a data type. This structure is refined in the descendants below. """ pass class InputArgument(Argument): pass class ResultBase(object): """Base class for all "outgoing" information from a routine. Objects of this class stores a sympy expression, and a sympy object representing a result variable that will be used in the generated code only if necessary. """ def __init__(self, expr, result_var): self.expr = expr self.result_var = result_var def __str__(self): return "%s(%r, %r)" % (self.__class__.__name__, self.expr, self.result_var) __repr__ = __str__ class OutputArgument(Argument, ResultBase): """OutputArgument are always initialized in the routine.""" def __init__(self, name, result_var, expr, datatype=None, dimensions=None, precision=None): """Return a new variable. Parameters ========== name : Symbol, MatrixSymbol The name of this variable. When used for code generation, this might appear, for example, in the prototype of function in the argument list. result_var : Symbol, Indexed Something that can be used to assign a value to this variable. Typically the same as `name` but for Indexed this should be e.g., "y[i]" whereas `name` should be the Symbol "y". expr : object The expression that should be output, typically a SymPy expression. datatype : optional When not given, the data type will be guessed based on the assumptions on the symbol argument. dimension : sequence containing tupes, optional If present, the argument is interpreted as an array, where this sequence of tuples specifies (lower, upper) bounds for each index of the array. precision : int, optional Controls the precision of floating point constants. """ Argument.__init__(self, name, datatype, dimensions, precision) ResultBase.__init__(self, expr, result_var) def __str__(self): return "%s(%r, %r, %r)" % (self.__class__.__name__, self.name, self.result_var, self.expr) __repr__ = __str__ class InOutArgument(Argument, ResultBase): """InOutArgument are never initialized in the routine.""" def __init__(self, name, result_var, expr, datatype=None, dimensions=None, precision=None): if not datatype: datatype = get_default_datatype(expr) Argument.__init__(self, name, datatype, dimensions, precision) ResultBase.__init__(self, expr, result_var) __init__.__doc__ = OutputArgument.__init__.__doc__ def __str__(self): return "%s(%r, %r, %r)" % (self.__class__.__name__, self.name, self.expr, self.result_var) __repr__ = __str__ class Result(Variable, ResultBase): """An expression for a return value. The name result is used to avoid conflicts with the reserved word "return" in the python language. It is also shorter than ReturnValue. These may or may not need a name in the destination (e.g., "return(x*y)" might return a value without ever naming it). """ def __init__(self, expr, name=None, result_var=None, datatype=None, dimensions=None, precision=None): """Initialize a return value. Parameters ========== expr : SymPy expression name : Symbol, MatrixSymbol, optional The name of this return variable. When used for code generation, this might appear, for example, in the prototype of function in a list of return values. A dummy name is generated if omitted. result_var : Symbol, Indexed, optional Something that can be used to assign a value to this variable. Typically the same as `name` but for Indexed this should be e.g., "y[i]" whereas `name` should be the Symbol "y". Defaults to `name` if omitted. datatype : optional When not given, the data type will be guessed based on the assumptions on the expr argument. dimension : sequence containing tupes, optional If present, this variable is interpreted as an array, where this sequence of tuples specifies (lower, upper) bounds for each index of the array. precision : int, optional Controls the precision of floating point constants. """ # Basic because it is the base class for all types of expressions if not isinstance(expr, (Basic, MatrixBase)): raise TypeError("The first argument must be a sympy expression.") if name is None: name = 'result_%d' % abs(hash(expr)) if datatype is None: #try to infer data type from the expression datatype = get_default_datatype(expr) if isinstance(name, string_types): if isinstance(expr, (MatrixBase, MatrixExpr)): name = MatrixSymbol(name, *expr.shape) else: name = Symbol(name) if result_var is None: result_var = name Variable.__init__(self, name, datatype=datatype, dimensions=dimensions, precision=precision) ResultBase.__init__(self, expr, result_var) def __str__(self): return "%s(%r, %r, %r)" % (self.__class__.__name__, self.expr, self.name, self.result_var) __repr__ = __str__ # # Transformation of routine objects into code # class CodeGen(object): """Abstract class for the code generators.""" printer = None # will be set to an instance of a CodePrinter subclass def _indent_code(self, codelines): return self.printer.indent_code(codelines) def _printer_method_with_settings(self, method, settings=None, *args, **kwargs): settings = settings or {} ori = {k: self.printer._settings[k] for k in settings} for k, v in settings.items(): self.printer._settings[k] = v result = getattr(self.printer, method)(*args, **kwargs) for k, v in ori.items(): self.printer._settings[k] = v return result def _get_symbol(self, s): """Returns the symbol as fcode prints it.""" if self.printer._settings['human']: expr_str = self.printer.doprint(s) else: constants, not_supported, expr_str = self.printer.doprint(s) if constants or not_supported: raise ValueError("Failed to print %s" % str(s)) return expr_str.strip() def __init__(self, project="project", cse=False): """Initialize a code generator. Derived classes will offer more options that affect the generated code. """ self.project = project self.cse = cse def routine(self, name, expr, argument_sequence=None, global_vars=None): """Creates an Routine object that is appropriate for this language. This implementation is appropriate for at least C/Fortran. Subclasses can override this if necessary. Here, we assume at most one return value (the l-value) which must be scalar. Additional outputs are OutputArguments (e.g., pointers on right-hand-side or pass-by-reference). Matrices are always returned via OutputArguments. If ``argument_sequence`` is None, arguments will be ordered alphabetically, but with all InputArguments first, and then OutputArgument and InOutArguments. """ if self.cse: from sympy.simplify.cse_main import cse if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") for e in expr: if not e.is_Equality: raise CodeGenError("Lists of expressions must all be Equalities. {} is not.".format(e)) # create a list of right hand sides and simplify them rhs = [e.rhs for e in expr] common, simplified = cse(rhs) # pack the simplified expressions back up with their left hand sides expr = [Equality(e.lhs, rhs) for e, rhs in zip(expr, simplified)] else: rhs = [expr] if isinstance(expr, Equality): common, simplified = cse(expr.rhs) #, ignore=in_out_args) expr = Equality(expr.lhs, simplified[0]) else: common, simplified = cse(expr) expr = simplified local_vars = [Result(b,a) for a,b in common] local_symbols = set([a for a,_ in common]) local_expressions = Tuple(*[b for _,b in common]) else: local_expressions = Tuple() if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(*expr) else: expressions = Tuple(expr) if self.cse: if {i.label for i in expressions.atoms(Idx)} != set(): raise CodeGenError("CSE and Indexed expressions do not play well together yet") else: # local variables for indexed expressions local_vars = {i.label for i in expressions.atoms(Idx)} local_symbols = local_vars # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments symbols = (expressions.free_symbols | local_expressions.free_symbols) - local_symbols - global_vars new_symbols = set([]) new_symbols.update(symbols) for symbol in symbols: if isinstance(symbol, Idx): new_symbols.remove(symbol) new_symbols.update(symbol.args[1].free_symbols) if isinstance(symbol, Indexed): new_symbols.remove(symbol) symbols = new_symbols # Decide whether to use output argument or return value return_val = [] output_args = [] for expr in expressions: if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs if isinstance(out_arg, Indexed): dims = tuple([ (S.Zero, dim - 1) for dim in out_arg.shape]) symbol = out_arg.base.label elif isinstance(out_arg, Symbol): dims = [] symbol = out_arg elif isinstance(out_arg, MatrixSymbol): dims = tuple([ (S.Zero, dim - 1) for dim in out_arg.shape]) symbol = out_arg else: raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") if expr.has(symbol): output_args.append( InOutArgument(symbol, out_arg, expr, dimensions=dims)) else: output_args.append( OutputArgument(symbol, out_arg, expr, dimensions=dims)) # remove duplicate arguments when they are not local variables if symbol not in local_vars: # avoid duplicate arguments symbols.remove(symbol) elif isinstance(expr, (ImmutableMatrix, MatrixSlice)): # Create a "dummy" MatrixSymbol to use as the Output arg out_arg = MatrixSymbol('out_%s' % abs(hash(expr)), *expr.shape) dims = tuple([(S.Zero, dim - 1) for dim in out_arg.shape]) output_args.append( OutputArgument(out_arg, out_arg, expr, dimensions=dims)) else: return_val.append(Result(expr)) arg_list = [] # setup input argument list array_symbols = {} for array in expressions.atoms(Indexed) | local_expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol) | local_expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): if symbol in array_symbols: dims = [] array = array_symbols[symbol] for dim in array.shape: dims.append((S.Zero, dim - 1)) metadata = {'dimensions': dims} else: metadata = {} arg_list.append(InputArgument(symbol, **metadata)) output_args.sort(key=lambda x: str(x.name)) arg_list.extend(output_args) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_val, local_vars, global_vars) def write(self, routines, prefix, to_files=False, header=True, empty=True): """Writes all the source code files for the given routines. The generated source is returned as a list of (filename, contents) tuples, or is written to files (see below). Each filename consists of the given prefix, appended with an appropriate extension. Parameters ========== routines : list A list of Routine instances to be written prefix : string The prefix for the output files to_files : bool, optional When True, the output is written to files. Otherwise, a list of (filename, contents) tuples is returned. [default: False] header : bool, optional When True, a header comment is included on top of each source file. [default: True] empty : bool, optional When True, empty lines are included to structure the source files. [default: True] """ if to_files: for dump_fn in self.dump_fns: filename = "%s.%s" % (prefix, dump_fn.extension) with open(filename, "w") as f: dump_fn(self, routines, f, prefix, header, empty) else: result = [] for dump_fn in self.dump_fns: filename = "%s.%s" % (prefix, dump_fn.extension) contents = StringIO() dump_fn(self, routines, contents, prefix, header, empty) result.append((filename, contents.getvalue())) return result def dump_code(self, routines, f, prefix, header=True, empty=True): """Write the code by calling language specific methods. The generated file contains all the definitions of the routines in low-level code and refers to the header file if appropriate. Parameters ========== routines : list A list of Routine instances. f : file-like Where to write the file. prefix : string The filename prefix, used to refer to the proper header file. Only the basename of the prefix is used. header : bool, optional When True, a header comment is included on top of each source file. [default : True] empty : bool, optional When True, empty lines are included to structure the source files. [default : True] """ code_lines = self._preprocessor_statements(prefix) for routine in routines: if empty: code_lines.append("\n") code_lines.extend(self._get_routine_opening(routine)) code_lines.extend(self._declare_arguments(routine)) code_lines.extend(self._declare_globals(routine)) code_lines.extend(self._declare_locals(routine)) if empty: code_lines.append("\n") code_lines.extend(self._call_printer(routine)) if empty: code_lines.append("\n") code_lines.extend(self._get_routine_ending(routine)) code_lines = self._indent_code(''.join(code_lines)) if header: code_lines = ''.join(self._get_header() + [code_lines]) if code_lines: f.write(code_lines) class CodeGenError(Exception): pass class CodeGenArgumentListError(Exception): @property def missing_args(self): return self.args[1] header_comment = """Code generated with sympy %(version)s See http://www.sympy.org/ for more information. This file is part of '%(project)s' """ class CCodeGen(CodeGen): """Generator for C code. The .write() method inherited from CodeGen will output a code file and an interface file, <prefix>.c and <prefix>.h respectively. """ code_extension = "c" interface_extension = "h" standard = 'c99' def __init__(self, project="project", printer=None, preprocessor_statements=None, cse=False): super(CCodeGen, self).__init__(project=project, cse=cse) self.printer = printer or c_code_printers[self.standard.lower()]() self.preprocessor_statements = preprocessor_statements if preprocessor_statements is None: self.preprocessor_statements = ['#include <math.h>'] def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] code_lines.append("/" + "*"*78 + '\n') tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): code_lines.append(" *%s*\n" % line.center(76)) code_lines.append(" " + "*"*78 + "/\n") return code_lines def get_prototype(self, routine): """Returns a string for the function prototype of the routine. If the routine has multiple result objects, an CodeGenError is raised. See: https://en.wikipedia.org/wiki/Function_prototype """ if len(routine.results) > 1: raise CodeGenError("C only supports a single or no return value.") elif len(routine.results) == 1: ctype = routine.results[0].get_datatype('C') else: ctype = "void" type_args = [] for arg in routine.arguments: name = self.printer.doprint(arg.name) if arg.dimensions or isinstance(arg, ResultBase): type_args.append((arg.get_datatype('C'), "*%s" % name)) else: type_args.append((arg.get_datatype('C'), name)) arguments = ", ".join([ "%s %s" % t for t in type_args]) return "%s %s(%s)" % (ctype, routine.name, arguments) def _preprocessor_statements(self, prefix): code_lines = [] code_lines.append('#include "{}.h"'.format(os.path.basename(prefix))) code_lines.extend(self.preprocessor_statements) code_lines = ['{}\n'.format(l) for l in code_lines] return code_lines def _get_routine_opening(self, routine): prototype = self.get_prototype(routine) return ["%s {\n" % prototype] def _declare_arguments(self, routine): # arguments are declared in prototype return [] def _declare_globals(self, routine): # global variables are not explicitly declared within C functions return [] def _declare_locals(self, routine): # Compose a list of symbols to be dereferenced in the function # body. These are the arguments that were passed by a reference # pointer, excluding arrays. dereference = [] for arg in routine.arguments: if isinstance(arg, ResultBase) and not arg.dimensions: dereference.append(arg.name) code_lines = [] for result in routine.local_vars: # local variables that are simple symbols such as those used as indices into # for loops are defined declared elsewhere. if not isinstance(result, Result): continue if result.name != result.result_var: raise CodeGen("Result variable and name should match: {}".format(result)) assign_to = result.name t = result.get_datatype('c') if isinstance(result.expr, (MatrixBase, MatrixExpr)): dims = result.expr.shape if dims[1] != 1: raise CodeGenError("Only column vectors are supported in local variabels. Local result {} has dimensions {}".format(result, dims)) code_lines.append("{0} {1}[{2}];\n".format(t, str(assign_to), dims[0])) prefix = "" else: prefix = "const {0} ".format(t) constants, not_c, c_expr = self._printer_method_with_settings( 'doprint', dict(human=False, dereference=dereference), result.expr, assign_to=assign_to) for name, value in sorted(constants, key=str): code_lines.append("double const %s = %s;\n" % (name, value)) code_lines.append("{}{}\n".format(prefix, c_expr)) return code_lines def _call_printer(self, routine): code_lines = [] # Compose a list of symbols to be dereferenced in the function # body. These are the arguments that were passed by a reference # pointer, excluding arrays. dereference = [] for arg in routine.arguments: if isinstance(arg, ResultBase) and not arg.dimensions: dereference.append(arg.name) return_val = None for result in routine.result_variables: if isinstance(result, Result): assign_to = routine.name + "_result" t = result.get_datatype('c') code_lines.append("{0} {1};\n".format(t, str(assign_to))) return_val = assign_to else: assign_to = result.result_var try: constants, not_c, c_expr = self._printer_method_with_settings( 'doprint', dict(human=False, dereference=dereference), result.expr, assign_to=assign_to) except AssignmentError: assign_to = result.result_var code_lines.append( "%s %s;\n" % (result.get_datatype('c'), str(assign_to))) constants, not_c, c_expr = self._printer_method_with_settings( 'doprint', dict(human=False, dereference=dereference), result.expr, assign_to=assign_to) for name, value in sorted(constants, key=str): code_lines.append("double const %s = %s;\n" % (name, value)) code_lines.append("%s\n" % c_expr) if return_val: code_lines.append(" return %s;\n" % return_val) return code_lines def _get_routine_ending(self, routine): return ["}\n"] def dump_c(self, routines, f, prefix, header=True, empty=True): self.dump_code(routines, f, prefix, header, empty) dump_c.extension = code_extension dump_c.__doc__ = CodeGen.dump_code.__doc__ def dump_h(self, routines, f, prefix, header=True, empty=True): """Writes the C header file. This file contains all the function declarations. Parameters ========== routines : list A list of Routine instances. f : file-like Where to write the file. prefix : string The filename prefix, used to construct the include guards. Only the basename of the prefix is used. header : bool, optional When True, a header comment is included on top of each source file. [default : True] empty : bool, optional When True, empty lines are included to structure the source files. [default : True] """ if header: print(''.join(self._get_header()), file=f) guard_name = "%s__%s__H" % (self.project.replace( " ", "_").upper(), prefix.replace("/", "_").upper()) # include guards if empty: print(file=f) print("#ifndef %s" % guard_name, file=f) print("#define %s" % guard_name, file=f) if empty: print(file=f) # declaration of the function prototypes for routine in routines: prototype = self.get_prototype(routine) print("%s;" % prototype, file=f) # end if include guards if empty: print(file=f) print("#endif", file=f) if empty: print(file=f) dump_h.extension = interface_extension # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_c, dump_h] class C89CodeGen(CCodeGen): standard = 'C89' class C99CodeGen(CCodeGen): standard = 'C99' class FCodeGen(CodeGen): """Generator for Fortran 95 code The .write() method inherited from CodeGen will output a code file and an interface file, <prefix>.f90 and <prefix>.h respectively. """ code_extension = "f90" interface_extension = "h" def __init__(self, project='project', printer=None): super(FCodeGen, self).__init__(project) self.printer = printer or FCodePrinter() def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] code_lines.append("!" + "*"*78 + '\n') tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): code_lines.append("!*%s*\n" % line.center(76)) code_lines.append("!" + "*"*78 + '\n') return code_lines def _preprocessor_statements(self, prefix): return [] def _get_routine_opening(self, routine): """Returns the opening statements of the fortran routine.""" code_list = [] if len(routine.results) > 1: raise CodeGenError( "Fortran only supports a single or no return value.") elif len(routine.results) == 1: result = routine.results[0] code_list.append(result.get_datatype('fortran')) code_list.append("function") else: code_list.append("subroutine") args = ", ".join("%s" % self._get_symbol(arg.name) for arg in routine.arguments) call_sig = "{0}({1})\n".format(routine.name, args) # Fortran 95 requires all lines be less than 132 characters, so wrap # this line before appending. call_sig = ' &\n'.join(textwrap.wrap(call_sig, width=60, break_long_words=False)) + '\n' code_list.append(call_sig) code_list = [' '.join(code_list)] code_list.append('implicit none\n') return code_list def _declare_arguments(self, routine): # argument type declarations code_list = [] array_list = [] scalar_list = [] for arg in routine.arguments: if isinstance(arg, InputArgument): typeinfo = "%s, intent(in)" % arg.get_datatype('fortran') elif isinstance(arg, InOutArgument): typeinfo = "%s, intent(inout)" % arg.get_datatype('fortran') elif isinstance(arg, OutputArgument): typeinfo = "%s, intent(out)" % arg.get_datatype('fortran') else: raise CodeGenError("Unknown Argument type: %s" % type(arg)) fprint = self._get_symbol if arg.dimensions: # fortran arrays start at 1 dimstr = ", ".join(["%s:%s" % ( fprint(dim[0] + 1), fprint(dim[1] + 1)) for dim in arg.dimensions]) typeinfo += ", dimension(%s)" % dimstr array_list.append("%s :: %s\n" % (typeinfo, fprint(arg.name))) else: scalar_list.append("%s :: %s\n" % (typeinfo, fprint(arg.name))) # scalars first, because they can be used in array declarations code_list.extend(scalar_list) code_list.extend(array_list) return code_list def _declare_globals(self, routine): # Global variables not explicitly declared within Fortran 90 functions. # Note: a future F77 mode may need to generate "common" blocks. return [] def _declare_locals(self, routine): code_list = [] for var in sorted(routine.local_vars, key=str): typeinfo = get_default_datatype(var) code_list.append("%s :: %s\n" % ( typeinfo.fname, self._get_symbol(var))) return code_list def _get_routine_ending(self, routine): """Returns the closing statements of the fortran routine.""" if len(routine.results) == 1: return ["end function\n"] else: return ["end subroutine\n"] def get_interface(self, routine): """Returns a string for the function interface. The routine should have a single result object, which can be None. If the routine has multiple result objects, a CodeGenError is raised. See: https://en.wikipedia.org/wiki/Function_prototype """ prototype = [ "interface\n" ] prototype.extend(self._get_routine_opening(routine)) prototype.extend(self._declare_arguments(routine)) prototype.extend(self._get_routine_ending(routine)) prototype.append("end interface\n") return "".join(prototype) def _call_printer(self, routine): declarations = [] code_lines = [] for result in routine.result_variables: if isinstance(result, Result): assign_to = routine.name elif isinstance(result, (OutputArgument, InOutArgument)): assign_to = result.result_var constants, not_fortran, f_expr = self._printer_method_with_settings( 'doprint', dict(human=False, source_format='free', standard=95), result.expr, assign_to=assign_to) for obj, v in sorted(constants, key=str): t = get_default_datatype(obj) declarations.append( "%s, parameter :: %s = %s\n" % (t.fname, obj, v)) for obj in sorted(not_fortran, key=str): t = get_default_datatype(obj) if isinstance(obj, Function): name = obj.func else: name = obj declarations.append("%s :: %s\n" % (t.fname, name)) code_lines.append("%s\n" % f_expr) return declarations + code_lines def _indent_code(self, codelines): return self._printer_method_with_settings( 'indent_code', dict(human=False, source_format='free'), codelines) def dump_f95(self, routines, f, prefix, header=True, empty=True): # check that symbols are unique with ignorecase for r in routines: lowercase = {str(x).lower() for x in r.variables} orig_case = {str(x) for x in r.variables} if len(lowercase) < len(orig_case): raise CodeGenError("Fortran ignores case. Got symbols: %s" % (", ".join([str(var) for var in r.variables]))) self.dump_code(routines, f, prefix, header, empty) dump_f95.extension = code_extension dump_f95.__doc__ = CodeGen.dump_code.__doc__ def dump_h(self, routines, f, prefix, header=True, empty=True): """Writes the interface to a header file. This file contains all the function declarations. Parameters ========== routines : list A list of Routine instances. f : file-like Where to write the file. prefix : string The filename prefix. header : bool, optional When True, a header comment is included on top of each source file. [default : True] empty : bool, optional When True, empty lines are included to structure the source files. [default : True] """ if header: print(''.join(self._get_header()), file=f) if empty: print(file=f) # declaration of the function prototypes for routine in routines: prototype = self.get_interface(routine) f.write(prototype) if empty: print(file=f) dump_h.extension = interface_extension # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_f95, dump_h] class JuliaCodeGen(CodeGen): """Generator for Julia code. The .write() method inherited from CodeGen will output a code file <prefix>.jl. """ code_extension = "jl" def __init__(self, project='project', printer=None): super(JuliaCodeGen, self).__init__(project) self.printer = printer or JuliaCodePrinter() def routine(self, name, expr, argument_sequence, global_vars): """Specialized Routine creation for Julia.""" if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(*expr) else: expressions = Tuple(expr) # local variables local_vars = {i.label for i in expressions.atoms(Idx)} # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments old_symbols = expressions.free_symbols - local_vars - global_vars symbols = set([]) for s in old_symbols: if isinstance(s, Idx): symbols.update(s.args[1].free_symbols) elif not isinstance(s, Indexed): symbols.add(s) # Julia supports multiple return values return_vals = [] output_args = [] for (i, expr) in enumerate(expressions): if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs symbol = out_arg if isinstance(out_arg, Indexed): dims = tuple([ (S.One, dim) for dim in out_arg.shape]) symbol = out_arg.base.label output_args.append(InOutArgument(symbol, out_arg, expr, dimensions=dims)) if not isinstance(out_arg, (Indexed, Symbol, MatrixSymbol)): raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") return_vals.append(Result(expr, name=symbol, result_var=out_arg)) if not expr.has(symbol): # this is a pure output: remove from the symbols list, so # it doesn't become an input. symbols.remove(symbol) else: # we have no name for this output return_vals.append(Result(expr, name='out%d' % (i+1))) # setup input argument list output_args.sort(key=lambda x: str(x.name)) arg_list = list(output_args) array_symbols = {} for array in expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): arg_list.append(InputArgument(symbol)) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_vals, local_vars, global_vars) def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): if line == '': code_lines.append("#\n") else: code_lines.append("# %s\n" % line) return code_lines def _preprocessor_statements(self, prefix): return [] def _get_routine_opening(self, routine): """Returns the opening statements of the routine.""" code_list = [] code_list.append("function ") # Inputs args = [] for i, arg in enumerate(routine.arguments): if isinstance(arg, OutputArgument): raise CodeGenError("Julia: invalid argument of type %s" % str(type(arg))) if isinstance(arg, (InputArgument, InOutArgument)): args.append("%s" % self._get_symbol(arg.name)) args = ", ".join(args) code_list.append("%s(%s)\n" % (routine.name, args)) code_list = [ "".join(code_list) ] return code_list def _declare_arguments(self, routine): return [] def _declare_globals(self, routine): return [] def _declare_locals(self, routine): return [] def _get_routine_ending(self, routine): outs = [] for result in routine.results: if isinstance(result, Result): # Note: name not result_var; want `y` not `y[i]` for Indexed s = self._get_symbol(result.name) else: raise CodeGenError("unexpected object in Routine results") outs.append(s) return ["return " + ", ".join(outs) + "\nend\n"] def _call_printer(self, routine): declarations = [] code_lines = [] for i, result in enumerate(routine.results): if isinstance(result, Result): assign_to = result.result_var else: raise CodeGenError("unexpected object in Routine results") constants, not_supported, jl_expr = self._printer_method_with_settings( 'doprint', dict(human=False), result.expr, assign_to=assign_to) for obj, v in sorted(constants, key=str): declarations.append( "%s = %s\n" % (obj, v)) for obj in sorted(not_supported, key=str): if isinstance(obj, Function): name = obj.func else: name = obj declarations.append( "# unsupported: %s\n" % (name)) code_lines.append("%s\n" % (jl_expr)) return declarations + code_lines def _indent_code(self, codelines): # Note that indenting seems to happen twice, first # statement-by-statement by JuliaPrinter then again here. p = JuliaCodePrinter({'human': False}) return p.indent_code(codelines) def dump_jl(self, routines, f, prefix, header=True, empty=True): self.dump_code(routines, f, prefix, header, empty) dump_jl.extension = code_extension dump_jl.__doc__ = CodeGen.dump_code.__doc__ # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_jl] class OctaveCodeGen(CodeGen): """Generator for Octave code. The .write() method inherited from CodeGen will output a code file <prefix>.m. Octave .m files usually contain one function. That function name should match the filename (``prefix``). If you pass multiple ``name_expr`` pairs, the latter ones are presumed to be private functions accessed by the primary function. You should only pass inputs to ``argument_sequence``: outputs are ordered according to their order in ``name_expr``. """ code_extension = "m" def __init__(self, project='project', printer=None): super(OctaveCodeGen, self).__init__(project) self.printer = printer or OctaveCodePrinter() def routine(self, name, expr, argument_sequence, global_vars): """Specialized Routine creation for Octave.""" # FIXME: this is probably general enough for other high-level # languages, perhaps its the C/Fortran one that is specialized! if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(*expr) else: expressions = Tuple(expr) # local variables local_vars = {i.label for i in expressions.atoms(Idx)} # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments old_symbols = expressions.free_symbols - local_vars - global_vars symbols = set([]) for s in old_symbols: if isinstance(s, Idx): symbols.update(s.args[1].free_symbols) elif not isinstance(s, Indexed): symbols.add(s) # Octave supports multiple return values return_vals = [] for (i, expr) in enumerate(expressions): if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs symbol = out_arg if isinstance(out_arg, Indexed): symbol = out_arg.base.label if not isinstance(out_arg, (Indexed, Symbol, MatrixSymbol)): raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") return_vals.append(Result(expr, name=symbol, result_var=out_arg)) if not expr.has(symbol): # this is a pure output: remove from the symbols list, so # it doesn't become an input. symbols.remove(symbol) else: # we have no name for this output return_vals.append(Result(expr, name='out%d' % (i+1))) # setup input argument list arg_list = [] array_symbols = {} for array in expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): arg_list.append(InputArgument(symbol)) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_vals, local_vars, global_vars) def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): if line == '': code_lines.append("%\n") else: code_lines.append("%% %s\n" % line) return code_lines def _preprocessor_statements(self, prefix): return [] def _get_routine_opening(self, routine): """Returns the opening statements of the routine.""" code_list = [] code_list.append("function ") # Outputs outs = [] for i, result in enumerate(routine.results): if isinstance(result, Result): # Note: name not result_var; want `y` not `y(i)` for Indexed s = self._get_symbol(result.name) else: raise CodeGenError("unexpected object in Routine results") outs.append(s) if len(outs) > 1: code_list.append("[" + (", ".join(outs)) + "]") else: code_list.append("".join(outs)) code_list.append(" = ") # Inputs args = [] for i, arg in enumerate(routine.arguments): if isinstance(arg, (OutputArgument, InOutArgument)): raise CodeGenError("Octave: invalid argument of type %s" % str(type(arg))) if isinstance(arg, InputArgument): args.append("%s" % self._get_symbol(arg.name)) args = ", ".join(args) code_list.append("%s(%s)\n" % (routine.name, args)) code_list = [ "".join(code_list) ] return code_list def _declare_arguments(self, routine): return [] def _declare_globals(self, routine): if not routine.global_vars: return [] s = " ".join(sorted([self._get_symbol(g) for g in routine.global_vars])) return ["global " + s + "\n"] def _declare_locals(self, routine): return [] def _get_routine_ending(self, routine): return ["end\n"] def _call_printer(self, routine): declarations = [] code_lines = [] for i, result in enumerate(routine.results): if isinstance(result, Result): assign_to = result.result_var else: raise CodeGenError("unexpected object in Routine results") constants, not_supported, oct_expr = self._printer_method_with_settings( 'doprint', dict(human=False), result.expr, assign_to=assign_to) for obj, v in sorted(constants, key=str): declarations.append( " %s = %s; %% constant\n" % (obj, v)) for obj in sorted(not_supported, key=str): if isinstance(obj, Function): name = obj.func else: name = obj declarations.append( " %% unsupported: %s\n" % (name)) code_lines.append("%s\n" % (oct_expr)) return declarations + code_lines def _indent_code(self, codelines): return self._printer_method_with_settings( 'indent_code', dict(human=False), codelines) def dump_m(self, routines, f, prefix, header=True, empty=True, inline=True): # Note used to call self.dump_code() but we need more control for header code_lines = self._preprocessor_statements(prefix) for i, routine in enumerate(routines): if i > 0: if empty: code_lines.append("\n") code_lines.extend(self._get_routine_opening(routine)) if i == 0: if routine.name != prefix: raise ValueError('Octave function name should match prefix') if header: code_lines.append("%" + prefix.upper() + " Autogenerated by sympy\n") code_lines.append(''.join(self._get_header())) code_lines.extend(self._declare_arguments(routine)) code_lines.extend(self._declare_globals(routine)) code_lines.extend(self._declare_locals(routine)) if empty: code_lines.append("\n") code_lines.extend(self._call_printer(routine)) if empty: code_lines.append("\n") code_lines.extend(self._get_routine_ending(routine)) code_lines = self._indent_code(''.join(code_lines)) if code_lines: f.write(code_lines) dump_m.extension = code_extension dump_m.__doc__ = CodeGen.dump_code.__doc__ # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_m] class RustCodeGen(CodeGen): """Generator for Rust code. The .write() method inherited from CodeGen will output a code file <prefix>.rs """ code_extension = "rs" def __init__(self, project="project", printer=None): super(RustCodeGen, self).__init__(project=project) self.printer = printer or RustCodePrinter() def routine(self, name, expr, argument_sequence, global_vars): """Specialized Routine creation for Rust.""" if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)): if not expr: raise ValueError("No expression given") expressions = Tuple(*expr) else: expressions = Tuple(expr) # local variables local_vars = set([i.label for i in expressions.atoms(Idx)]) # global variables global_vars = set() if global_vars is None else set(global_vars) # symbols that should be arguments symbols = expressions.free_symbols - local_vars - global_vars - expressions.atoms(Indexed) # Rust supports multiple return values return_vals = [] output_args = [] for (i, expr) in enumerate(expressions): if isinstance(expr, Equality): out_arg = expr.lhs expr = expr.rhs symbol = out_arg if isinstance(out_arg, Indexed): dims = tuple([ (S.One, dim) for dim in out_arg.shape]) symbol = out_arg.base.label output_args.append(InOutArgument(symbol, out_arg, expr, dimensions=dims)) if not isinstance(out_arg, (Indexed, Symbol, MatrixSymbol)): raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol " "can define output arguments.") return_vals.append(Result(expr, name=symbol, result_var=out_arg)) if not expr.has(symbol): # this is a pure output: remove from the symbols list, so # it doesn't become an input. symbols.remove(symbol) else: # we have no name for this output return_vals.append(Result(expr, name='out%d' % (i+1))) # setup input argument list output_args.sort(key=lambda x: str(x.name)) arg_list = list(output_args) array_symbols = {} for array in expressions.atoms(Indexed): array_symbols[array.base.label] = array for array in expressions.atoms(MatrixSymbol): array_symbols[array] = array for symbol in sorted(symbols, key=str): arg_list.append(InputArgument(symbol)) if argument_sequence is not None: # if the user has supplied IndexedBase instances, we'll accept that new_sequence = [] for arg in argument_sequence: if isinstance(arg, IndexedBase): new_sequence.append(arg.label) else: new_sequence.append(arg) argument_sequence = new_sequence missing = [x for x in arg_list if x.name not in argument_sequence] if missing: msg = "Argument list didn't specify: {0} " msg = msg.format(", ".join([str(m.name) for m in missing])) raise CodeGenArgumentListError(msg, missing) # create redundant arguments to produce the requested sequence name_arg_dict = {x.name: x for x in arg_list} new_args = [] for symbol in argument_sequence: try: new_args.append(name_arg_dict[symbol]) except KeyError: new_args.append(InputArgument(symbol)) arg_list = new_args return Routine(name, arg_list, return_vals, local_vars, global_vars) def _get_header(self): """Writes a common header for the generated files.""" code_lines = [] code_lines.append("/*\n") tmp = header_comment % {"version": sympy_version, "project": self.project} for line in tmp.splitlines(): code_lines.append((" *%s" % line.center(76)).rstrip() + "\n") code_lines.append(" */\n") return code_lines def get_prototype(self, routine): """Returns a string for the function prototype of the routine. If the routine has multiple result objects, an CodeGenError is raised. See: https://en.wikipedia.org/wiki/Function_prototype """ results = [i.get_datatype('Rust') for i in routine.results] if len(results) == 1: rstype = " -> " + results[0] elif len(routine.results) > 1: rstype = " -> (" + ", ".join(results) + ")" else: rstype = "" type_args = [] for arg in routine.arguments: name = self.printer.doprint(arg.name) if arg.dimensions or isinstance(arg, ResultBase): type_args.append(("*%s" % name, arg.get_datatype('Rust'))) else: type_args.append((name, arg.get_datatype('Rust'))) arguments = ", ".join([ "%s: %s" % t for t in type_args]) return "fn %s(%s)%s" % (routine.name, arguments, rstype) def _preprocessor_statements(self, prefix): code_lines = [] # code_lines.append("use std::f64::consts::*;\n") return code_lines def _get_routine_opening(self, routine): prototype = self.get_prototype(routine) return ["%s {\n" % prototype] def _declare_arguments(self, routine): # arguments are declared in prototype return [] def _declare_globals(self, routine): # global variables are not explicitly declared within C functions return [] def _declare_locals(self, routine): # loop variables are declared in loop statement return [] def _call_printer(self, routine): code_lines = [] declarations = [] returns = [] # Compose a list of symbols to be dereferenced in the function # body. These are the arguments that were passed by a reference # pointer, excluding arrays. dereference = [] for arg in routine.arguments: if isinstance(arg, ResultBase) and not arg.dimensions: dereference.append(arg.name) for i, result in enumerate(routine.results): if isinstance(result, Result): assign_to = result.result_var returns.append(str(result.result_var)) else: raise CodeGenError("unexpected object in Routine results") constants, not_supported, rs_expr = self._printer_method_with_settings( 'doprint', dict(human=False), result.expr, assign_to=assign_to) for name, value in sorted(constants, key=str): declarations.append("const %s: f64 = %s;\n" % (name, value)) for obj in sorted(not_supported, key=str): if isinstance(obj, Function): name = obj.func else: name = obj declarations.append("// unsupported: %s\n" % (name)) code_lines.append("let %s\n" % rs_expr); if len(returns) > 1: returns = ['(' + ', '.join(returns) + ')'] returns.append('\n') return declarations + code_lines + returns def _get_routine_ending(self, routine): return ["}\n"] def dump_rs(self, routines, f, prefix, header=True, empty=True): self.dump_code(routines, f, prefix, header, empty) dump_rs.extension = code_extension dump_rs.__doc__ = CodeGen.dump_code.__doc__ # This list of dump functions is used by CodeGen.write to know which dump # functions it has to call. dump_fns = [dump_rs] def get_code_generator(language, project=None, standard=None, printer = None): if language == 'C': if standard is None: pass elif standard.lower() == 'c89': language = 'C89' elif standard.lower() == 'c99': language = 'C99' CodeGenClass = {"C": CCodeGen, "C89": C89CodeGen, "C99": C99CodeGen, "F95": FCodeGen, "JULIA": JuliaCodeGen, "OCTAVE": OctaveCodeGen, "RUST": RustCodeGen}.get(language.upper()) if CodeGenClass is None: raise ValueError("Language '%s' is not supported." % language) return CodeGenClass(project, printer) # # Friendly functions # def codegen(name_expr, language=None, prefix=None, project="project", to_files=False, header=True, empty=True, argument_sequence=None, global_vars=None, standard=None, code_gen=None, printer = None): """Generate source code for expressions in a given language. Parameters ========== name_expr : tuple, or list of tuples A single (name, expression) tuple or a list of (name, expression) tuples. Each tuple corresponds to a routine. If the expression is an equality (an instance of class Equality) the left hand side is considered an output argument. If expression is an iterable, then the routine will have multiple outputs. language : string, A string that indicates the source code language. This is case insensitive. Currently, 'C', 'F95' and 'Octave' are supported. 'Octave' generates code compatible with both Octave and Matlab. prefix : string, optional A prefix for the names of the files that contain the source code. Language-dependent suffixes will be appended. If omitted, the name of the first name_expr tuple is used. project : string, optional A project name, used for making unique preprocessor instructions. [default: "project"] to_files : bool, optional When True, the code will be written to one or more files with the given prefix, otherwise strings with the names and contents of these files are returned. [default: False] header : bool, optional When True, a header is written on top of each source file. [default: True] empty : bool, optional When True, empty lines are used to structure the code. [default: True] argument_sequence : iterable, optional Sequence of arguments for the routine in a preferred order. A CodeGenError is raised if required arguments are missing. Redundant arguments are used without warning. If omitted, arguments will be ordered alphabetically, but with all input arguments first, and then output or in-out arguments. global_vars : iterable, optional Sequence of global variables used by the routine. Variables listed here will not show up as function arguments. standard : string code_gen : CodeGen instance An instance of a CodeGen subclass. Overrides ``language``. Examples ======== >>> from sympy.utilities.codegen import codegen >>> from sympy.abc import x, y, z >>> [(c_name, c_code), (h_name, c_header)] = codegen( ... ("f", x+y*z), "C89", "test", header=False, empty=False) >>> print(c_name) test.c >>> print(c_code) #include "test.h" #include <math.h> double f(double x, double y, double z) { double f_result; f_result = x + y*z; return f_result; } <BLANKLINE> >>> print(h_name) test.h >>> print(c_header) #ifndef PROJECT__TEST__H #define PROJECT__TEST__H double f(double x, double y, double z); #endif <BLANKLINE> Another example using Equality objects to give named outputs. Here the filename (prefix) is taken from the first (name, expr) pair. >>> from sympy.abc import f, g >>> from sympy import Eq >>> [(c_name, c_code), (h_name, c_header)] = codegen( ... [("myfcn", x + y), ("fcn2", [Eq(f, 2*x), Eq(g, y)])], ... "C99", header=False, empty=False) >>> print(c_name) myfcn.c >>> print(c_code) #include "myfcn.h" #include <math.h> double myfcn(double x, double y) { double myfcn_result; myfcn_result = x + y; return myfcn_result; } void fcn2(double x, double y, double *f, double *g) { (*f) = 2*x; (*g) = y; } <BLANKLINE> If the generated function(s) will be part of a larger project where various global variables have been defined, the 'global_vars' option can be used to remove the specified variables from the function signature >>> from sympy.utilities.codegen import codegen >>> from sympy.abc import x, y, z >>> [(f_name, f_code), header] = codegen( ... ("f", x+y*z), "F95", header=False, empty=False, ... argument_sequence=(x, y), global_vars=(z,)) >>> print(f_code) REAL*8 function f(x, y) implicit none REAL*8, intent(in) :: x REAL*8, intent(in) :: y f = x + y*z end function <BLANKLINE> """ # Initialize the code generator. if language is None: if code_gen is None: raise ValueError("Need either language or code_gen") else: if code_gen is not None: raise ValueError("You cannot specify both language and code_gen.") code_gen = get_code_generator(language, project, standard, printer) if isinstance(name_expr[0], string_types): # single tuple is given, turn it into a singleton list with a tuple. name_expr = [name_expr] if prefix is None: prefix = name_expr[0][0] # Construct Routines appropriate for this code_gen from (name, expr) pairs. routines = [] for name, expr in name_expr: routines.append(code_gen.routine(name, expr, argument_sequence, global_vars)) # Write the code. return code_gen.write(routines, prefix, to_files, header, empty) def make_routine(name, expr, argument_sequence=None, global_vars=None, language="F95"): """A factory that makes an appropriate Routine from an expression. Parameters ========== name : string The name of this routine in the generated code. expr : expression or list/tuple of expressions A SymPy expression that the Routine instance will represent. If given a list or tuple of expressions, the routine will be considered to have multiple return values and/or output arguments. argument_sequence : list or tuple, optional List arguments for the routine in a preferred order. If omitted, the results are language dependent, for example, alphabetical order or in the same order as the given expressions. global_vars : iterable, optional Sequence of global variables used by the routine. Variables listed here will not show up as function arguments. language : string, optional Specify a target language. The Routine itself should be language-agnostic but the precise way one is created, error checking, etc depend on the language. [default: "F95"]. A decision about whether to use output arguments or return values is made depending on both the language and the particular mathematical expressions. For an expression of type Equality, the left hand side is typically made into an OutputArgument (or perhaps an InOutArgument if appropriate). Otherwise, typically, the calculated expression is made a return values of the routine. Examples ======== >>> from sympy.utilities.codegen import make_routine >>> from sympy.abc import x, y, f, g >>> from sympy import Eq >>> r = make_routine('test', [Eq(f, 2*x), Eq(g, x + y)]) >>> [arg.result_var for arg in r.results] [] >>> [arg.name for arg in r.arguments] [x, y, f, g] >>> [arg.name for arg in r.result_variables] [f, g] >>> r.local_vars set() Another more complicated example with a mixture of specified and automatically-assigned names. Also has Matrix output. >>> from sympy import Matrix >>> r = make_routine('fcn', [x*y, Eq(f, 1), Eq(g, x + g), Matrix([[x, 2]])]) >>> [arg.result_var for arg in r.results] # doctest: +SKIP [result_5397460570204848505] >>> [arg.expr for arg in r.results] [x*y] >>> [arg.name for arg in r.arguments] # doctest: +SKIP [x, y, f, g, out_8598435338387848786] We can examine the various arguments more closely: >>> from sympy.utilities.codegen import (InputArgument, OutputArgument, ... InOutArgument) >>> [a.name for a in r.arguments if isinstance(a, InputArgument)] [x, y] >>> [a.name for a in r.arguments if isinstance(a, OutputArgument)] # doctest: +SKIP [f, out_8598435338387848786] >>> [a.expr for a in r.arguments if isinstance(a, OutputArgument)] [1, Matrix([[x, 2]])] >>> [a.name for a in r.arguments if isinstance(a, InOutArgument)] [g] >>> [a.expr for a in r.arguments if isinstance(a, InOutArgument)] [g + x] """ # initialize a new code generator code_gen = get_code_generator(language) return code_gen.routine(name, expr, argument_sequence, global_vars)

840546895b1011b9812ededbdfe36cb91b75cd9a024a358e3dbedf5960fd4b86

"""A module providing information about the necessity of brackets""" from __future__ import print_function, division from sympy.core.function import _coeff_isneg # Default precedence values for some basic types PRECEDENCE = { "Lambda": 1, "Xor": 10, "Or": 20, "And": 30, "Relational": 35, "Add": 40, "Mul": 50, "Pow": 60, "Func": 70, "Not": 100, "Atom": 1000, "BitwiseOr": 36, "BitwiseAnd": 38 } # A dictionary assigning precedence values to certain classes. These values are # treated like they were inherited, so not every single class has to be named # here. # Do not use this with printers other than StrPrinter PRECEDENCE_VALUES = { "Equivalent": PRECEDENCE["Xor"], "Xor": PRECEDENCE["Xor"], "Implies": PRECEDENCE["Xor"], "Or": PRECEDENCE["Or"], "And": PRECEDENCE["And"], "Add": PRECEDENCE["Add"], "Pow": PRECEDENCE["Pow"], "Relational": PRECEDENCE["Relational"], "Sub": PRECEDENCE["Add"], "Not": PRECEDENCE["Not"], "Function" : PRECEDENCE["Func"], "NegativeInfinity": PRECEDENCE["Add"], "MatAdd": PRECEDENCE["Add"], "MatPow": PRECEDENCE["Pow"], "TensAdd": PRECEDENCE["Add"], # As soon as `TensMul` is a subclass of `Mul`, remove this: "TensMul": PRECEDENCE["Mul"], "HadamardProduct": PRECEDENCE["Mul"], "HadamardPower": PRECEDENCE["Pow"], "KroneckerProduct": PRECEDENCE["Mul"], "Equality": PRECEDENCE["Mul"], "Unequality": PRECEDENCE["Mul"], } # Sometimes it's not enough to assign a fixed precedence value to a # class. Then a function can be inserted in this dictionary that takes # an instance of this class as argument and returns the appropriate # precedence value. # Precedence functions def precedence_Mul(item): if _coeff_isneg(item): return PRECEDENCE["Add"] return PRECEDENCE["Mul"] def precedence_Rational(item): if item.p < 0: return PRECEDENCE["Add"] return PRECEDENCE["Mul"] def precedence_Integer(item): if item.p < 0: return PRECEDENCE["Add"] return PRECEDENCE["Atom"] def precedence_Float(item): if item < 0: return PRECEDENCE["Add"] return PRECEDENCE["Atom"] def precedence_PolyElement(item): if item.is_generator: return PRECEDENCE["Atom"] elif item.is_ground: return precedence(item.coeff(1)) elif item.is_term: return PRECEDENCE["Mul"] else: return PRECEDENCE["Add"] def precedence_FracElement(item): if item.denom == 1: return precedence_PolyElement(item.numer) else: return PRECEDENCE["Mul"] def precedence_UnevaluatedExpr(item): return precedence(item.args[0]) PRECEDENCE_FUNCTIONS = { "Integer": precedence_Integer, "Mul": precedence_Mul, "Rational": precedence_Rational, "Float": precedence_Float, "PolyElement": precedence_PolyElement, "FracElement": precedence_FracElement, "UnevaluatedExpr": precedence_UnevaluatedExpr, } def precedence(item): """Returns the precedence of a given object. This is the precedence for StrPrinter. """ if hasattr(item, "precedence"): return item.precedence try: mro = item.__class__.__mro__ except AttributeError: return PRECEDENCE["Atom"] for i in mro: n = i.__name__ if n in PRECEDENCE_FUNCTIONS: return PRECEDENCE_FUNCTIONS[n](item) elif n in PRECEDENCE_VALUES: return PRECEDENCE_VALUES[n] return PRECEDENCE["Atom"] def precedence_traditional(item): """Returns the precedence of a given object according to the traditional rules of mathematics. This is the precedence for the LaTeX and pretty printer. """ # Integral, Sum, Product, Limit have the precedence of Mul in LaTeX, # the precedence of Atom for other printers: from sympy import Integral, Sum, Product, Limit, Derivative, Transpose, Adjoint from sympy.core.expr import UnevaluatedExpr from sympy.tensor.functions import TensorProduct if isinstance(item, (Integral, Sum, Product, Limit, Derivative, TensorProduct)): return PRECEDENCE["Mul"] elif isinstance(item, (Transpose, Adjoint)): return PRECEDENCE["Pow"] elif (item.__class__.__name__ in ("Dot", "Cross", "Gradient", "Divergence", "Curl", "Laplacian")): return PRECEDENCE["Mul"]-1 elif isinstance(item, UnevaluatedExpr): return precedence_traditional(item.args[0]) else: return precedence(item)

86cc27f1beac98e70baf14f01f19ec2b3b7798697709f6ce36e10d79ca578e77

""" A Printer for generating readable representation of most sympy classes. """ from __future__ import print_function, division from sympy.core import S, Rational, Pow, Basic, Mul from sympy.core.mul import _keep_coeff from sympy.core.compatibility import string_types from .printer import Printer from sympy.printing.precedence import precedence, PRECEDENCE from mpmath.libmp import prec_to_dps, to_str as mlib_to_str from sympy.utilities import default_sort_key class StrPrinter(Printer): printmethod = "_sympystr" _default_settings = { "order": None, "full_prec": "auto", "sympy_integers": False, "abbrev": False, } _relationals = dict() def parenthesize(self, item, level, strict=False): if (precedence(item) < level) or ((not strict) and precedence(item) <= level): return "(%s)" % self._print(item) else: return self._print(item) def stringify(self, args, sep, level=0): return sep.join([self.parenthesize(item, level) for item in args]) def emptyPrinter(self, expr): if isinstance(expr, string_types): return expr elif isinstance(expr, Basic): return repr(expr) else: return str(expr) def _print_Add(self, expr, order=None): if self.order == 'none': terms = list(expr.args) else: terms = self._as_ordered_terms(expr, order=order) PREC = precedence(expr) l = [] for term in terms: t = self._print(term) if t.startswith('-'): sign = "-" t = t[1:] else: sign = "+" if precedence(term) < PREC: l.extend([sign, "(%s)" % t]) else: l.extend([sign, t]) sign = l.pop(0) if sign == '+': sign = "" return sign + ' '.join(l) def _print_BooleanTrue(self, expr): return "True" def _print_BooleanFalse(self, expr): return "False" def _print_Not(self, expr): return '~%s' %(self.parenthesize(expr.args[0],PRECEDENCE["Not"])) def _print_And(self, expr): return self.stringify(expr.args, " & ", PRECEDENCE["BitwiseAnd"]) def _print_Or(self, expr): return self.stringify(expr.args, " | ", PRECEDENCE["BitwiseOr"]) def _print_AppliedPredicate(self, expr): return '%s(%s)' % (self._print(expr.func), self._print(expr.arg)) def _print_Basic(self, expr): l = [self._print(o) for o in expr.args] return expr.__class__.__name__ + "(%s)" % ", ".join(l) def _print_BlockMatrix(self, B): if B.blocks.shape == (1, 1): self._print(B.blocks[0, 0]) return self._print(B.blocks) def _print_Catalan(self, expr): return 'Catalan' def _print_ComplexInfinity(self, expr): return 'zoo' def _print_ConditionSet(self, s): args = tuple([self._print(i) for i in (s.sym, s.condition)]) if s.base_set is S.UniversalSet: return 'ConditionSet(%s, %s)' % args args += (self._print(s.base_set),) return 'ConditionSet(%s, %s, %s)' % args def _print_Derivative(self, expr): dexpr = expr.expr dvars = [i[0] if i[1] == 1 else i for i in expr.variable_count] return 'Derivative(%s)' % ", ".join(map(lambda arg: self._print(arg), [dexpr] + dvars)) def _print_dict(self, d): keys = sorted(d.keys(), key=default_sort_key) items = [] for key in keys: item = "%s: %s" % (self._print(key), self._print(d[key])) items.append(item) return "{%s}" % ", ".join(items) def _print_Dict(self, expr): return self._print_dict(expr) def _print_RandomDomain(self, d): if hasattr(d, 'as_boolean'): return 'Domain: ' + self._print(d.as_boolean()) elif hasattr(d, 'set'): return ('Domain: ' + self._print(d.symbols) + ' in ' + self._print(d.set)) else: return 'Domain on ' + self._print(d.symbols) def _print_Dummy(self, expr): return '_' + expr.name def _print_EulerGamma(self, expr): return 'EulerGamma' def _print_Exp1(self, expr): return 'E' def _print_ExprCondPair(self, expr): return '(%s, %s)' % (self._print(expr.expr), self._print(expr.cond)) def _print_FiniteSet(self, s): s = sorted(s, key=default_sort_key) if len(s) > 10: printset = s[:3] + ['...'] + s[-3:] else: printset = s return '{' + ', '.join(self._print(el) for el in printset) + '}' def _print_Function(self, expr): return expr.func.__name__ + "(%s)" % self.stringify(expr.args, ", ") def _print_GeometryEntity(self, expr): # GeometryEntity is special -- it's base is tuple return str(expr) def _print_GoldenRatio(self, expr): return 'GoldenRatio' def _print_TribonacciConstant(self, expr): return 'TribonacciConstant' def _print_ImaginaryUnit(self, expr): return 'I' def _print_Infinity(self, expr): return 'oo' def _print_Integral(self, expr): def _xab_tostr(xab): if len(xab) == 1: return self._print(xab[0]) else: return self._print((xab[0],) + tuple(xab[1:])) L = ', '.join([_xab_tostr(l) for l in expr.limits]) return 'Integral(%s, %s)' % (self._print(expr.function), L) def _print_Interval(self, i): fin = 'Interval{m}({a}, {b})' a, b, l, r = i.args if a.is_infinite and b.is_infinite: m = '' elif a.is_infinite and not r: m = '' elif b.is_infinite and not l: m = '' elif not l and not r: m = '' elif l and r: m = '.open' elif l: m = '.Lopen' else: m = '.Ropen' return fin.format(**{'a': a, 'b': b, 'm': m}) def _print_AccumulationBounds(self, i): return "AccumBounds(%s, %s)" % (self._print(i.min), self._print(i.max)) def _print_Inverse(self, I): return "%s**(-1)" % self.parenthesize(I.arg, PRECEDENCE["Pow"]) def _print_Lambda(self, obj): args, expr = obj.args if len(args) == 1: return "Lambda(%s, %s)" % (self._print(args.args[0]), self._print(expr)) else: arg_string = ", ".join(self._print(arg) for arg in args) return "Lambda((%s), %s)" % (arg_string, self._print(expr)) def _print_LatticeOp(self, expr): args = sorted(expr.args, key=default_sort_key) return expr.func.__name__ + "(%s)" % ", ".join(self._print(arg) for arg in args) def _print_Limit(self, expr): e, z, z0, dir = expr.args if str(dir) == "+": return "Limit(%s, %s, %s)" % tuple(map(self._print, (e, z, z0))) else: return "Limit(%s, %s, %s, dir='%s')" % tuple(map(self._print, (e, z, z0, dir))) def _print_list(self, expr): return "[%s]" % self.stringify(expr, ", ") def _print_MatrixBase(self, expr): return expr._format_str(self) _print_MutableSparseMatrix = \ _print_ImmutableSparseMatrix = \ _print_Matrix = \ _print_DenseMatrix = \ _print_MutableDenseMatrix = \ _print_ImmutableMatrix = \ _print_ImmutableDenseMatrix = \ _print_MatrixBase def _print_MatrixElement(self, expr): return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True) \ + '[%s, %s]' % (self._print(expr.i), self._print(expr.j)) def _print_MatrixSlice(self, expr): def strslice(x): x = list(x) if x[2] == 1: del x[2] if x[1] == x[0] + 1: del x[1] if x[0] == 0: x[0] = '' return ':'.join(map(lambda arg: self._print(arg), x)) return (self._print(expr.parent) + '[' + strslice(expr.rowslice) + ', ' + strslice(expr.colslice) + ']') def _print_DeferredVector(self, expr): return expr.name def _print_Mul(self, expr): prec = precedence(expr) c, e = expr.as_coeff_Mul() if c < 0: expr = _keep_coeff(-c, e) sign = "-" else: sign = "" a = [] # items in the numerator b = [] # items that are in the denominator (if any) pow_paren = [] # Will collect all pow with more than one base element and exp = -1 if self.order not in ('old', 'none'): args = expr.as_ordered_factors() else: # use make_args in case expr was something like -x -> x args = Mul.make_args(expr) # Gather args for numerator/denominator for item in args: if item.is_commutative and item.is_Pow and item.exp.is_Rational and item.exp.is_negative: if item.exp != -1: b.append(Pow(item.base, -item.exp, evaluate=False)) else: if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 pow_paren.append(item) b.append(Pow(item.base, -item.exp)) elif item.is_Rational and item is not S.Infinity: if item.p != 1: a.append(Rational(item.p)) if item.q != 1: b.append(Rational(item.q)) else: a.append(item) a = a or [S.One] a_str = [self.parenthesize(x, prec, strict=False) for x in a] b_str = [self.parenthesize(x, prec, strict=False) for x in b] # To parenthesize Pow with exp = -1 and having more than one Symbol for item in pow_paren: if item.base in b: b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] if not b: return sign + '*'.join(a_str) elif len(b) == 1: return sign + '*'.join(a_str) + "/" + b_str[0] else: return sign + '*'.join(a_str) + "/(%s)" % '*'.join(b_str) def _print_MatMul(self, expr): c, m = expr.as_coeff_mmul() if c.is_number and c < 0: expr = _keep_coeff(-c, m) sign = "-" else: sign = "" return sign + '*'.join( [self.parenthesize(arg, precedence(expr)) for arg in expr.args] ) def _print_HadamardProduct(self, expr): return '.*'.join([self.parenthesize(arg, precedence(expr)) for arg in expr.args]) def _print_HadamardPower(self, expr): PREC = precedence(expr) return '.**'.join([ self.parenthesize(expr.base, PREC), self.parenthesize(expr.exp, PREC) ]) def _print_ElementwiseApplyFunction(self, expr): return "{0}({1}...)".format( expr.function, self._print(expr.expr), ) def _print_NaN(self, expr): return 'nan' def _print_NegativeInfinity(self, expr): return '-oo' def _print_Order(self, expr): if not expr.variables or all(p is S.Zero for p in expr.point): if len(expr.variables) <= 1: return 'O(%s)' % self._print(expr.expr) else: return 'O(%s)' % self.stringify((expr.expr,) + expr.variables, ', ', 0) else: return 'O(%s)' % self.stringify(expr.args, ', ', 0) def _print_Ordinal(self, expr): return expr.__str__() def _print_Cycle(self, expr): return expr.__str__() def _print_Permutation(self, expr): from sympy.combinatorics.permutations import Permutation, Cycle if Permutation.print_cyclic: if not expr.size: return '()' # before taking Cycle notation, see if the last element is # a singleton and move it to the head of the string s = Cycle(expr)(expr.size - 1).__repr__()[len('Cycle'):] last = s.rfind('(') if not last == 0 and ',' not in s[last:]: s = s[last:] + s[:last] s = s.replace(',', '') return s else: s = expr.support() if not s: if expr.size < 5: return 'Permutation(%s)' % self._print(expr.array_form) return 'Permutation([], size=%s)' % self._print(expr.size) trim = self._print(expr.array_form[:s[-1] + 1]) + ', size=%s' % self._print(expr.size) use = full = self._print(expr.array_form) if len(trim) < len(full): use = trim return 'Permutation(%s)' % use def _print_Subs(self, obj): expr, old, new = obj.args if len(obj.point) == 1: old = old[0] new = new[0] return "Subs(%s, %s, %s)" % ( self._print(expr), self._print(old), self._print(new)) def _print_TensorIndex(self, expr): return expr._print() def _print_TensorHead(self, expr): return expr._print() def _print_Tensor(self, expr): return expr._print() def _print_TensMul(self, expr): # prints expressions like "A(a)", "3*A(a)", "(1+x)*A(a)" sign, args = expr._get_args_for_traditional_printer() return sign + "*".join( [self.parenthesize(arg, precedence(expr)) for arg in args] ) def _print_TensAdd(self, expr): return expr._print() def _print_PermutationGroup(self, expr): p = [' %s' % self._print(a) for a in expr.args] return 'PermutationGroup([\n%s])' % ',\n'.join(p) def _print_Pi(self, expr): return 'pi' def _print_PolyRing(self, ring): return "Polynomial ring in %s over %s with %s order" % \ (", ".join(map(lambda rs: self._print(rs), ring.symbols)), self._print(ring.domain), self._print(ring.order)) def _print_FracField(self, field): return "Rational function field in %s over %s with %s order" % \ (", ".join(map(lambda fs: self._print(fs), field.symbols)), self._print(field.domain), self._print(field.order)) def _print_FreeGroupElement(self, elm): return elm.__str__() def _print_PolyElement(self, poly): return poly.str(self, PRECEDENCE, "%s**%s", "*") def _print_FracElement(self, frac): if frac.denom == 1: return self._print(frac.numer) else: numer = self.parenthesize(frac.numer, PRECEDENCE["Mul"], strict=True) denom = self.parenthesize(frac.denom, PRECEDENCE["Atom"], strict=True) return numer + "/" + denom def _print_Poly(self, expr): ATOM_PREC = PRECEDENCE["Atom"] - 1 terms, gens = [], [ self.parenthesize(s, ATOM_PREC) for s in expr.gens ] for monom, coeff in expr.terms(): s_monom = [] for i, exp in enumerate(monom): if exp > 0: if exp == 1: s_monom.append(gens[i]) else: s_monom.append(gens[i] + "**%d" % exp) s_monom = "*".join(s_monom) if coeff.is_Add: if s_monom: s_coeff = "(" + self._print(coeff) + ")" else: s_coeff = self._print(coeff) else: if s_monom: if coeff is S.One: terms.extend(['+', s_monom]) continue if coeff is S.NegativeOne: terms.extend(['-', s_monom]) continue s_coeff = self._print(coeff) if not s_monom: s_term = s_coeff else: s_term = s_coeff + "*" + s_monom if s_term.startswith('-'): terms.extend(['-', s_term[1:]]) else: terms.extend(['+', s_term]) if terms[0] in ['-', '+']: modifier = terms.pop(0) if modifier == '-': terms[0] = '-' + terms[0] format = expr.__class__.__name__ + "(%s, %s" from sympy.polys.polyerrors import PolynomialError try: format += ", modulus=%s" % expr.get_modulus() except PolynomialError: format += ", domain='%s'" % expr.get_domain() format += ")" for index, item in enumerate(gens): if len(item) > 2 and (item[:1] == "(" and item[len(item) - 1:] == ")"): gens[index] = item[1:len(item) - 1] return format % (' '.join(terms), ', '.join(gens)) def _print_ProductSet(self, p): return ' x '.join(self._print(set) for set in p.sets) def _print_UniversalSet(self, p): return 'UniversalSet' def _print_AlgebraicNumber(self, expr): if expr.is_aliased: return self._print(expr.as_poly().as_expr()) else: return self._print(expr.as_expr()) def _print_Pow(self, expr, rational=False): PREC = precedence(expr) if expr.exp is S.Half and not rational: return "sqrt(%s)" % self._print(expr.base) if expr.is_commutative: if -expr.exp is S.Half and not rational: # Note: Don't test "expr.exp == -S.Half" here, because that will # match -0.5, which we don't want. return "%s/sqrt(%s)" % tuple(map(lambda arg: self._print(arg), (S.One, expr.base))) if expr.exp is -S.One: # Similarly to the S.Half case, don't test with "==" here. return '%s/%s' % (self._print(S.One), self.parenthesize(expr.base, PREC, strict=False)) e = self.parenthesize(expr.exp, PREC, strict=False) if self.printmethod == '_sympyrepr' and expr.exp.is_Rational and expr.exp.q != 1: # the parenthesized exp should be '(Rational(a, b))' so strip parens, # but just check to be sure. if e.startswith('(Rational'): return '%s**%s' % (self.parenthesize(expr.base, PREC, strict=False), e[1:-1]) return '%s**%s' % (self.parenthesize(expr.base, PREC, strict=False), e) def _print_UnevaluatedExpr(self, expr): return self._print(expr.args[0]) def _print_MatPow(self, expr): PREC = precedence(expr) return '%s**%s' % (self.parenthesize(expr.base, PREC, strict=False), self.parenthesize(expr.exp, PREC, strict=False)) def _print_ImmutableDenseNDimArray(self, expr): return str(expr) def _print_ImmutableSparseNDimArray(self, expr): return str(expr) def _print_Integer(self, expr): if self._settings.get("sympy_integers", False): return "S(%s)" % (expr) return str(expr.p) def _print_Integers(self, expr): return 'Integers' def _print_Naturals(self, expr): return 'Naturals' def _print_Naturals0(self, expr): return 'Naturals0' def _print_Reals(self, expr): return 'Reals' def _print_int(self, expr): return str(expr) def _print_mpz(self, expr): return str(expr) def _print_Rational(self, expr): if expr.q == 1: return str(expr.p) else: if self._settings.get("sympy_integers", False): return "S(%s)/%s" % (expr.p, expr.q) return "%s/%s" % (expr.p, expr.q) def _print_PythonRational(self, expr): if expr.q == 1: return str(expr.p) else: return "%d/%d" % (expr.p, expr.q) def _print_Fraction(self, expr): if expr.denominator == 1: return str(expr.numerator) else: return "%s/%s" % (expr.numerator, expr.denominator) def _print_mpq(self, expr): if expr.denominator == 1: return str(expr.numerator) else: return "%s/%s" % (expr.numerator, expr.denominator) def _print_Float(self, expr): prec = expr._prec if prec < 5: dps = 0 else: dps = prec_to_dps(expr._prec) if self._settings["full_prec"] is True: strip = False elif self._settings["full_prec"] is False: strip = True elif self._settings["full_prec"] == "auto": strip = self._print_level > 1 rv = mlib_to_str(expr._mpf_, dps, strip_zeros=strip) if rv.startswith('-.0'): rv = '-0.' + rv[3:] elif rv.startswith('.0'): rv = '0.' + rv[2:] if rv.startswith('+'): # e.g., +inf -> inf rv = rv[1:] return rv def _print_Relational(self, expr): charmap = { "==": "Eq", "!=": "Ne", ":=": "Assignment", '+=': "AddAugmentedAssignment", "-=": "SubAugmentedAssignment", "*=": "MulAugmentedAssignment", "/=": "DivAugmentedAssignment", "%=": "ModAugmentedAssignment", } if expr.rel_op in charmap: return '%s(%s, %s)' % (charmap[expr.rel_op], self._print(expr.lhs), self._print(expr.rhs)) return '%s %s %s' % (self.parenthesize(expr.lhs, precedence(expr)), self._relationals.get(expr.rel_op) or expr.rel_op, self.parenthesize(expr.rhs, precedence(expr))) def _print_ComplexRootOf(self, expr): return "CRootOf(%s, %d)" % (self._print_Add(expr.expr, order='lex'), expr.index) def _print_RootSum(self, expr): args = [self._print_Add(expr.expr, order='lex')] if expr.fun is not S.IdentityFunction: args.append(self._print(expr.fun)) return "RootSum(%s)" % ", ".join(args) def _print_GroebnerBasis(self, basis): cls = basis.__class__.__name__ exprs = [self._print_Add(arg, order=basis.order) for arg in basis.exprs] exprs = "[%s]" % ", ".join(exprs) gens = [ self._print(gen) for gen in basis.gens ] domain = "domain='%s'" % self._print(basis.domain) order = "order='%s'" % self._print(basis.order) args = [exprs] + gens + [domain, order] return "%s(%s)" % (cls, ", ".join(args)) def _print_set(self, s): items = sorted(s, key=default_sort_key) args = ', '.join(self._print(item) for item in items) if not args: return "set()" return '{%s}' % args def _print_frozenset(self, s): if not s: return "frozenset()" return "frozenset(%s)" % self._print_set(s) def _print_SparseMatrix(self, expr): from sympy.matrices import Matrix return self._print(Matrix(expr)) def _print_Sum(self, expr): def _xab_tostr(xab): if len(xab) == 1: return self._print(xab[0]) else: return self._print((xab[0],) + tuple(xab[1:])) L = ', '.join([_xab_tostr(l) for l in expr.limits]) return 'Sum(%s, %s)' % (self._print(expr.function), L) def _print_Symbol(self, expr): return expr.name _print_MatrixSymbol = _print_Symbol _print_RandomSymbol = _print_Symbol def _print_Identity(self, expr): return "I" def _print_ZeroMatrix(self, expr): return "0" def _print_Predicate(self, expr): return "Q.%s" % expr.name def _print_str(self, expr): return str(expr) def _print_tuple(self, expr): if len(expr) == 1: return "(%s,)" % self._print(expr[0]) else: return "(%s)" % self.stringify(expr, ", ") def _print_Tuple(self, expr): return self._print_tuple(expr) def _print_Transpose(self, T): return "%s.T" % self.parenthesize(T.arg, PRECEDENCE["Pow"]) def _print_Uniform(self, expr): return "Uniform(%s, %s)" % (self._print(expr.a), self._print(expr.b)) def _print_Union(self, expr): return 'Union(%s)' %(', '.join([self._print(a) for a in expr.args])) def _print_Complement(self, expr): return r' \ '.join(self._print(set_) for set_ in expr.args) def _print_Quantity(self, expr): if self._settings.get("abbrev", False): return "%s" % expr.abbrev return "%s" % expr.name def _print_Quaternion(self, expr): s = [self.parenthesize(i, PRECEDENCE["Mul"], strict=True) for i in expr.args] a = [s[0]] + [i+"*"+j for i, j in zip(s[1:], "ijk")] return " + ".join(a) def _print_Dimension(self, expr): return str(expr) def _print_Wild(self, expr): return expr.name + '_' def _print_WildFunction(self, expr): return expr.name + '_' def _print_Zero(self, expr): if self._settings.get("sympy_integers", False): return "S(0)" return "0" def _print_DMP(self, p): from sympy.core.sympify import SympifyError try: if p.ring is not None: # TODO incorporate order return self._print(p.ring.to_sympy(p)) except SympifyError: pass cls = p.__class__.__name__ rep = self._print(p.rep) dom = self._print(p.dom) ring = self._print(p.ring) return "%s(%s, %s, %s)" % (cls, rep, dom, ring) def _print_DMF(self, expr): return self._print_DMP(expr) def _print_Object(self, obj): return 'Object("%s")' % obj.name def _print_IdentityMorphism(self, morphism): return 'IdentityMorphism(%s)' % morphism.domain def _print_NamedMorphism(self, morphism): return 'NamedMorphism(%s, %s, "%s")' % \ (morphism.domain, morphism.codomain, morphism.name) def _print_Category(self, category): return 'Category("%s")' % category.name def _print_BaseScalarField(self, field): return field._coord_sys._names[field._index] def _print_BaseVectorField(self, field): return 'e_%s' % field._coord_sys._names[field._index] def _print_Differential(self, diff): field = diff._form_field if hasattr(field, '_coord_sys'): return 'd%s' % field._coord_sys._names[field._index] else: return 'd(%s)' % self._print(field) def _print_Tr(self, expr): #TODO : Handle indices return "%s(%s)" % ("Tr", self._print(expr.args[0])) def sstr(expr, **settings): """Returns the expression as a string. For large expressions where speed is a concern, use the setting order='none'. If abbrev=True setting is used then units are printed in abbreviated form. Examples ======== >>> from sympy import symbols, Eq, sstr >>> a, b = symbols('a b') >>> sstr(Eq(a + b, 0)) 'Eq(a + b, 0)' """ p = StrPrinter(settings) s = p.doprint(expr) return s class StrReprPrinter(StrPrinter): """(internal) -- see sstrrepr""" def _print_str(self, s): return repr(s) def sstrrepr(expr, **settings): """return expr in mixed str/repr form i.e. strings are returned in repr form with quotes, and everything else is returned in str form. This function could be useful for hooking into sys.displayhook """ p = StrReprPrinter(settings) s = p.doprint(expr) return s

e2bb497d83ce2485be0d9a2b068d6cf93e02bc99d758bb6ab5abee7025e96d69

from __future__ import print_function, division def pprint_nodes(subtrees): """ Prettyprints systems of nodes. Examples ======== >>> from sympy.printing.tree import pprint_nodes >>> print(pprint_nodes(["a", "b1\\nb2", "c"])) +-a +-b1 | b2 +-c """ def indent(s, type=1): x = s.split("\n") r = "+-%s\n" % x[0] for a in x[1:]: if a == "": continue if type == 1: r += "| %s\n" % a else: r += " %s\n" % a return r if not subtrees: return "" f = "" for a in subtrees[:-1]: f += indent(a) f += indent(subtrees[-1], 2) return f def print_node(node): """ Returns information about the "node". This includes class name, string representation and assumptions. """ s = "%s: %s\n" % (node.__class__.__name__, str(node)) d = node._assumptions if d: for a in sorted(d): v = d[a] if v is None: continue s += "%s: %s\n" % (a, v) return s def tree(node): """ Returns a tree representation of "node" as a string. It uses print_node() together with pprint_nodes() on node.args recursively. See Also ======== print_tree """ subtrees = [] for arg in node.args: subtrees.append(tree(arg)) s = print_node(node) + pprint_nodes(subtrees) return s def print_tree(node): """ Prints a tree representation of "node". Examples ======== >>> from sympy.printing import print_tree >>> from sympy import Symbol >>> x = Symbol('x', odd=True) >>> y = Symbol('y', even=True) >>> print_tree(y**x) Pow: y**x +-Symbol: y | algebraic: True | commutative: True | complex: True | even: True | finite: True | hermitian: True | imaginary: False | infinite: False | integer: True | irrational: False | noninteger: False | odd: False | rational: True | real: True | transcendental: False +-Symbol: x algebraic: True commutative: True complex: True even: False finite: True hermitian: True imaginary: False infinite: False integer: True irrational: False noninteger: False nonzero: True odd: True rational: True real: True transcendental: False zero: False See Also ======== tree """ print(tree(node))

a66182cb6debf5fae3986d438267dd0c85f50249b8add1bd8d1f38658b5f3a6b

""" A Printer which converts an expression into its LaTeX equivalent. """ from __future__ import print_function, division import itertools from sympy.core import S, Add, Symbol, Mod from sympy.core.alphabets import greeks from sympy.core.containers import Tuple from sympy.core.function import _coeff_isneg, AppliedUndef, Derivative from sympy.core.operations import AssocOp from sympy.core.sympify import SympifyError from sympy.logic.boolalg import true # sympy.printing imports from sympy.printing.precedence import precedence_traditional from sympy.printing.printer import Printer from sympy.printing.conventions import split_super_sub, requires_partial from sympy.printing.precedence import precedence, PRECEDENCE import mpmath.libmp as mlib from mpmath.libmp import prec_to_dps from sympy.core.compatibility import default_sort_key, range from sympy.utilities.iterables import has_variety import re # Hand-picked functions which can be used directly in both LaTeX and MathJax # Complete list at # https://docs.mathjax.org/en/latest/tex.html#supported-latex-commands # This variable only contains those functions which sympy uses. accepted_latex_functions = ['arcsin', 'arccos', 'arctan', 'sin', 'cos', 'tan', 'sinh', 'cosh', 'tanh', 'sqrt', 'ln', 'log', 'sec', 'csc', 'cot', 'coth', 're', 'im', 'frac', 'root', 'arg', ] tex_greek_dictionary = { 'Alpha': 'A', 'Beta': 'B', 'Gamma': r'\Gamma', 'Delta': r'\Delta', 'Epsilon': 'E', 'Zeta': 'Z', 'Eta': 'H', 'Theta': r'\Theta', 'Iota': 'I', 'Kappa': 'K', 'Lambda': r'\Lambda', 'Mu': 'M', 'Nu': 'N', 'Xi': r'\Xi', 'omicron': 'o', 'Omicron': 'O', 'Pi': r'\Pi', 'Rho': 'P', 'Sigma': r'\Sigma', 'Tau': 'T', 'Upsilon': r'\Upsilon', 'Phi': r'\Phi', 'Chi': 'X', 'Psi': r'\Psi', 'Omega': r'\Omega', 'lamda': r'\lambda', 'Lamda': r'\Lambda', 'khi': r'\chi', 'Khi': r'X', 'varepsilon': r'\varepsilon', 'varkappa': r'\varkappa', 'varphi': r'\varphi', 'varpi': r'\varpi', 'varrho': r'\varrho', 'varsigma': r'\varsigma', 'vartheta': r'\vartheta', } other_symbols = set(['aleph', 'beth', 'daleth', 'gimel', 'ell', 'eth', 'hbar', 'hslash', 'mho', 'wp', ]) # Variable name modifiers modifier_dict = { # Accents 'mathring': lambda s: r'\mathring{'+s+r'}', 'ddddot': lambda s: r'\ddddot{'+s+r'}', 'dddot': lambda s: r'\dddot{'+s+r'}', 'ddot': lambda s: r'\ddot{'+s+r'}', 'dot': lambda s: r'\dot{'+s+r'}', 'check': lambda s: r'\check{'+s+r'}', 'breve': lambda s: r'\breve{'+s+r'}', 'acute': lambda s: r'\acute{'+s+r'}', 'grave': lambda s: r'\grave{'+s+r'}', 'tilde': lambda s: r'\tilde{'+s+r'}', 'hat': lambda s: r'\hat{'+s+r'}', 'bar': lambda s: r'\bar{'+s+r'}', 'vec': lambda s: r'\vec{'+s+r'}', 'prime': lambda s: "{"+s+"}'", 'prm': lambda s: "{"+s+"}'", # Faces 'bold': lambda s: r'\boldsymbol{'+s+r'}', 'bm': lambda s: r'\boldsymbol{'+s+r'}', 'cal': lambda s: r'\mathcal{'+s+r'}', 'scr': lambda s: r'\mathscr{'+s+r'}', 'frak': lambda s: r'\mathfrak{'+s+r'}', # Brackets 'norm': lambda s: r'\left\|{'+s+r'}\right\|', 'avg': lambda s: r'\left\langle{'+s+r'}\right\rangle', 'abs': lambda s: r'\left|{'+s+r'}\right|', 'mag': lambda s: r'\left|{'+s+r'}\right|', } greek_letters_set = frozenset(greeks) _between_two_numbers_p = ( re.compile(r'[0-9][} ]*$'), # search re.compile(r'[{ ]*[-+0-9]'), # match ) class LatexPrinter(Printer): printmethod = "_latex" _default_settings = { "fold_frac_powers": False, "fold_func_brackets": False, "fold_short_frac": None, "inv_trig_style": "abbreviated", "itex": False, "ln_notation": False, "long_frac_ratio": None, "mat_delim": "[", "mat_str": None, "mode": "plain", "mul_symbol": None, "order": None, "symbol_names": {}, "root_notation": True, "mat_symbol_style": "plain", "imaginary_unit": "i", "gothic_re_im": False, } def __init__(self, settings=None): Printer.__init__(self, settings) if 'mode' in self._settings: valid_modes = ['inline', 'plain', 'equation', 'equation*'] if self._settings['mode'] not in valid_modes: raise ValueError("'mode' must be one of 'inline', 'plain', " "'equation' or 'equation*'") if self._settings['fold_short_frac'] is None and \ self._settings['mode'] == 'inline': self._settings['fold_short_frac'] = True mul_symbol_table = { None: r" ", "ldot": r" \,.\, ", "dot": r" \cdot ", "times": r" \times " } try: self._settings['mul_symbol_latex'] = \ mul_symbol_table[self._settings['mul_symbol']] except KeyError: self._settings['mul_symbol_latex'] = \ self._settings['mul_symbol'] try: self._settings['mul_symbol_latex_numbers'] = \ mul_symbol_table[self._settings['mul_symbol'] or 'dot'] except KeyError: if (self._settings['mul_symbol'].strip() in ['', ' ', '\\', '\\,', '\\:', '\\;', '\\quad']): self._settings['mul_symbol_latex_numbers'] = \ mul_symbol_table['dot'] else: self._settings['mul_symbol_latex_numbers'] = \ self._settings['mul_symbol'] self._delim_dict = {'(': ')', '[': ']'} imaginary_unit_table = { None: r"i", "i": r"i", "ri": r"\mathrm{i}", "ti": r"\text{i}", "j": r"j", "rj": r"\mathrm{j}", "tj": r"\text{j}", } try: self._settings['imaginary_unit_latex'] = \ imaginary_unit_table[self._settings['imaginary_unit']] except KeyError: self._settings['imaginary_unit_latex'] = \ self._settings['imaginary_unit'] def parenthesize(self, item, level, strict=False): prec_val = precedence_traditional(item) if (prec_val < level) or ((not strict) and prec_val <= level): return r"\left({}\right)".format(self._print(item)) else: return self._print(item) def doprint(self, expr): tex = Printer.doprint(self, expr) if self._settings['mode'] == 'plain': return tex elif self._settings['mode'] == 'inline': return r"$%s$" % tex elif self._settings['itex']: return r"$$%s$$" % tex else: env_str = self._settings['mode'] return r"\begin{%s}%s\end{%s}" % (env_str, tex, env_str) def _needs_brackets(self, expr): """ Returns True if the expression needs to be wrapped in brackets when printed, False otherwise. For example: a + b => True; a => False; 10 => False; -10 => True. """ return not ((expr.is_Integer and expr.is_nonnegative) or (expr.is_Atom and (expr is not S.NegativeOne and expr.is_Rational is False))) def _needs_function_brackets(self, expr): """ Returns True if the expression needs to be wrapped in brackets when passed as an argument to a function, False otherwise. This is a more liberal version of _needs_brackets, in that many expressions which need to be wrapped in brackets when added/subtracted/raised to a power do not need them when passed to a function. Such an example is a*b. """ if not self._needs_brackets(expr): return False else: # Muls of the form a*b*c... can be folded if expr.is_Mul and not self._mul_is_clean(expr): return True # Pows which don't need brackets can be folded elif expr.is_Pow and not self._pow_is_clean(expr): return True # Add and Function always need brackets elif expr.is_Add or expr.is_Function: return True else: return False def _needs_mul_brackets(self, expr, first=False, last=False): """ Returns True if the expression needs to be wrapped in brackets when printed as part of a Mul, False otherwise. This is True for Add, but also for some container objects that would not need brackets when appearing last in a Mul, e.g. an Integral. ``last=True`` specifies that this expr is the last to appear in a Mul. ``first=True`` specifies that this expr is the first to appear in a Mul. """ from sympy import Integral, Product, Sum if expr.is_Mul: if not first and _coeff_isneg(expr): return True elif precedence_traditional(expr) < PRECEDENCE["Mul"]: return True elif expr.is_Relational: return True if expr.is_Piecewise: return True if any([expr.has(x) for x in (Mod,)]): return True if (not last and any([expr.has(x) for x in (Integral, Product, Sum)])): return True return False def _needs_add_brackets(self, expr): """ Returns True if the expression needs to be wrapped in brackets when printed as part of an Add, False otherwise. This is False for most things. """ if expr.is_Relational: return True if any([expr.has(x) for x in (Mod,)]): return True if expr.is_Add: return True return False def _mul_is_clean(self, expr): for arg in expr.args: if arg.is_Function: return False return True def _pow_is_clean(self, expr): return not self._needs_brackets(expr.base) def _do_exponent(self, expr, exp): if exp is not None: return r"\left(%s\right)^{%s}" % (expr, exp) else: return expr def _print_Basic(self, expr): ls = [self._print(o) for o in expr.args] return self._deal_with_super_sub(expr.__class__.__name__) + \ r"\left(%s\right)" % ", ".join(ls) def _print_bool(self, e): return r"\text{%s}" % e _print_BooleanTrue = _print_bool _print_BooleanFalse = _print_bool def _print_NoneType(self, e): return r"\text{%s}" % e def _print_Add(self, expr, order=None): if self.order == 'none': terms = list(expr.args) else: terms = self._as_ordered_terms(expr, order=order) tex = "" for i, term in enumerate(terms): if i == 0: pass elif _coeff_isneg(term): tex += " - " term = -term else: tex += " + " term_tex = self._print(term) if self._needs_add_brackets(term): term_tex = r"\left(%s\right)" % term_tex tex += term_tex return tex def _print_Cycle(self, expr): from sympy.combinatorics.permutations import Permutation if expr.size == 0: return r"\left( \right)" expr = Permutation(expr) expr_perm = expr.cyclic_form siz = expr.size if expr.array_form[-1] == siz - 1: expr_perm = expr_perm + [[siz - 1]] term_tex = '' for i in expr_perm: term_tex += str(i).replace(',', r"\;") term_tex = term_tex.replace('[', r"\left( ") term_tex = term_tex.replace(']', r"\right)") return term_tex _print_Permutation = _print_Cycle def _print_Float(self, expr): # Based off of that in StrPrinter dps = prec_to_dps(expr._prec) str_real = mlib.to_str(expr._mpf_, dps, strip_zeros=True) # Must always have a mul symbol (as 2.5 10^{20} just looks odd) # thus we use the number separator separator = self._settings['mul_symbol_latex_numbers'] if 'e' in str_real: (mant, exp) = str_real.split('e') if exp[0] == '+': exp = exp[1:] return r"%s%s10^{%s}" % (mant, separator, exp) elif str_real == "+inf": return r"\infty" elif str_real == "-inf": return r"- \infty" else: return str_real def _print_Cross(self, expr): vec1 = expr._expr1 vec2 = expr._expr2 return r"%s \times %s" % (self.parenthesize(vec1, PRECEDENCE['Mul']), self.parenthesize(vec2, PRECEDENCE['Mul'])) def _print_Curl(self, expr): vec = expr._expr return r"\nabla\times %s" % self.parenthesize(vec, PRECEDENCE['Mul']) def _print_Divergence(self, expr): vec = expr._expr return r"\nabla\cdot %s" % self.parenthesize(vec, PRECEDENCE['Mul']) def _print_Dot(self, expr): vec1 = expr._expr1 vec2 = expr._expr2 return r"%s \cdot %s" % (self.parenthesize(vec1, PRECEDENCE['Mul']), self.parenthesize(vec2, PRECEDENCE['Mul'])) def _print_Gradient(self, expr): func = expr._expr return r"\nabla %s" % self.parenthesize(func, PRECEDENCE['Mul']) def _print_Laplacian(self, expr): func = expr._expr return r"\triangle %s" % self.parenthesize(func, PRECEDENCE['Mul']) def _print_Mul(self, expr): from sympy.core.power import Pow from sympy.physics.units import Quantity include_parens = False if _coeff_isneg(expr): expr = -expr tex = "- " if expr.is_Add: tex += "(" include_parens = True else: tex = "" from sympy.simplify import fraction numer, denom = fraction(expr, exact=True) separator = self._settings['mul_symbol_latex'] numbersep = self._settings['mul_symbol_latex_numbers'] def convert(expr): if not expr.is_Mul: return str(self._print(expr)) else: _tex = last_term_tex = "" if self.order not in ('old', 'none'): args = expr.as_ordered_factors() else: args = list(expr.args) # If quantities are present append them at the back args = sorted(args, key=lambda x: isinstance(x, Quantity) or (isinstance(x, Pow) and isinstance(x.base, Quantity))) for i, term in enumerate(args): term_tex = self._print(term) if self._needs_mul_brackets(term, first=(i == 0), last=(i == len(args) - 1)): term_tex = r"\left(%s\right)" % term_tex if _between_two_numbers_p[0].search(last_term_tex) and \ _between_two_numbers_p[1].match(term_tex): # between two numbers _tex += numbersep elif _tex: _tex += separator _tex += term_tex last_term_tex = term_tex return _tex if denom is S.One and Pow(1, -1, evaluate=False) not in expr.args: # use the original expression here, since fraction() may have # altered it when producing numer and denom tex += convert(expr) else: snumer = convert(numer) sdenom = convert(denom) ldenom = len(sdenom.split()) ratio = self._settings['long_frac_ratio'] if self._settings['fold_short_frac'] and ldenom <= 2 and \ "^" not in sdenom: # handle short fractions if self._needs_mul_brackets(numer, last=False): tex += r"\left(%s\right) / %s" % (snumer, sdenom) else: tex += r"%s / %s" % (snumer, sdenom) elif ratio is not None and \ len(snumer.split()) > ratio*ldenom: # handle long fractions if self._needs_mul_brackets(numer, last=True): tex += r"\frac{1}{%s}%s\left(%s\right)" \ % (sdenom, separator, snumer) elif numer.is_Mul: # split a long numerator a = S.One b = S.One for x in numer.args: if self._needs_mul_brackets(x, last=False) or \ len(convert(a*x).split()) > ratio*ldenom or \ (b.is_commutative is x.is_commutative is False): b *= x else: a *= x if self._needs_mul_brackets(b, last=True): tex += r"\frac{%s}{%s}%s\left(%s\right)" \ % (convert(a), sdenom, separator, convert(b)) else: tex += r"\frac{%s}{%s}%s%s" \ % (convert(a), sdenom, separator, convert(b)) else: tex += r"\frac{1}{%s}%s%s" % (sdenom, separator, snumer) else: tex += r"\frac{%s}{%s}" % (snumer, sdenom) if include_parens: tex += ")" return tex def _print_Pow(self, expr): # Treat x**Rational(1,n) as special case if expr.exp.is_Rational and abs(expr.exp.p) == 1 and expr.exp.q != 1 \ and self._settings['root_notation']: base = self._print(expr.base) expq = expr.exp.q if expq == 2: tex = r"\sqrt{%s}" % base elif self._settings['itex']: tex = r"\root{%d}{%s}" % (expq, base) else: tex = r"\sqrt[%d]{%s}" % (expq, base) if expr.exp.is_negative: return r"\frac{1}{%s}" % tex else: return tex elif self._settings['fold_frac_powers'] \ and expr.exp.is_Rational \ and expr.exp.q != 1: base = self.parenthesize(expr.base, PRECEDENCE['Pow']) p, q = expr.exp.p, expr.exp.q # issue #12886: add parentheses for superscripts raised to powers if '^' in base and expr.base.is_Symbol: base = r"\left(%s\right)" % base if expr.base.is_Function: return self._print(expr.base, exp="%s/%s" % (p, q)) return r"%s^{%s/%s}" % (base, p, q) elif expr.exp.is_Rational and expr.exp.is_negative and \ expr.base.is_commutative: # special case for 1^(-x), issue 9216 if expr.base == 1: return r"%s^{%s}" % (expr.base, expr.exp) # things like 1/x return self._print_Mul(expr) else: if expr.base.is_Function: return self._print(expr.base, exp=self._print(expr.exp)) else: tex = r"%s^{%s}" return self._helper_print_standard_power(expr, tex) def _helper_print_standard_power(self, expr, template): exp = self._print(expr.exp) # issue #12886: add parentheses around superscripts raised # to powers base = self.parenthesize(expr.base, PRECEDENCE['Pow']) if '^' in base and expr.base.is_Symbol: base = r"\left(%s\right)" % base elif (isinstance(expr.base, Derivative) and base.startswith(r'\left(') and re.match(r'\\left\(\\d?d?dot', base) and base.endswith(r'\right)')): # don't use parentheses around dotted derivative base = base[6: -7] # remove outermost added parens return template % (base, exp) def _print_UnevaluatedExpr(self, expr): return self._print(expr.args[0]) def _print_Sum(self, expr): if len(expr.limits) == 1: tex = r"\sum_{%s=%s}^{%s} " % \ tuple([self._print(i) for i in expr.limits[0]]) else: def _format_ineq(l): return r"%s \leq %s \leq %s" % \ tuple([self._print(s) for s in (l[1], l[0], l[2])]) tex = r"\sum_{\substack{%s}} " % \ str.join('\\\\', [_format_ineq(l) for l in expr.limits]) if isinstance(expr.function, Add): tex += r"\left(%s\right)" % self._print(expr.function) else: tex += self._print(expr.function) return tex def _print_Product(self, expr): if len(expr.limits) == 1: tex = r"\prod_{%s=%s}^{%s} " % \ tuple([self._print(i) for i in expr.limits[0]]) else: def _format_ineq(l): return r"%s \leq %s \leq %s" % \ tuple([self._print(s) for s in (l[1], l[0], l[2])]) tex = r"\prod_{\substack{%s}} " % \ str.join('\\\\', [_format_ineq(l) for l in expr.limits]) if isinstance(expr.function, Add): tex += r"\left(%s\right)" % self._print(expr.function) else: tex += self._print(expr.function) return tex def _print_BasisDependent(self, expr): from sympy.vector import Vector o1 = [] if expr == expr.zero: return expr.zero._latex_form if isinstance(expr, Vector): items = expr.separate().items() else: items = [(0, expr)] for system, vect in items: inneritems = list(vect.components.items()) inneritems.sort(key=lambda x: x[0].__str__()) for k, v in inneritems: if v == 1: o1.append(' + ' + k._latex_form) elif v == -1: o1.append(' - ' + k._latex_form) else: arg_str = '(' + LatexPrinter().doprint(v) + ')' o1.append(' + ' + arg_str + k._latex_form) outstr = (''.join(o1)) if outstr[1] != '-': outstr = outstr[3:] else: outstr = outstr[1:] return outstr def _print_Indexed(self, expr): tex_base = self._print(expr.base) tex = '{'+tex_base+'}'+'_{%s}' % ','.join( map(self._print, expr.indices)) return tex def _print_IndexedBase(self, expr): return self._print(expr.label) def _print_Derivative(self, expr): if requires_partial(expr): diff_symbol = r'\partial' else: diff_symbol = r'd' tex = "" dim = 0 for x, num in reversed(expr.variable_count): dim += num if num == 1: tex += r"%s %s" % (diff_symbol, self._print(x)) else: tex += r"%s %s^{%s}" % (diff_symbol, self._print(x), num) if dim == 1: tex = r"\frac{%s}{%s}" % (diff_symbol, tex) else: tex = r"\frac{%s^{%s}}{%s}" % (diff_symbol, dim, tex) return r"%s %s" % (tex, self.parenthesize(expr.expr, PRECEDENCE["Mul"], strict=True)) def _print_Subs(self, subs): expr, old, new = subs.args latex_expr = self._print(expr) latex_old = (self._print(e) for e in old) latex_new = (self._print(e) for e in new) latex_subs = r'\\ '.join( e[0] + '=' + e[1] for e in zip(latex_old, latex_new)) return r'\left. %s \right|_{\substack{ %s }}' % (latex_expr, latex_subs) def _print_Integral(self, expr): tex, symbols = "", [] # Only up to \iiiint exists if len(expr.limits) <= 4 and all(len(lim) == 1 for lim in expr.limits): # Use len(expr.limits)-1 so that syntax highlighters don't think # \" is an escaped quote tex = r"\i" + "i"*(len(expr.limits) - 1) + "nt" symbols = [r"\, d%s" % self._print(symbol[0]) for symbol in expr.limits] else: for lim in reversed(expr.limits): symbol = lim[0] tex += r"\int" if len(lim) > 1: if self._settings['mode'] != 'inline' \ and not self._settings['itex']: tex += r"\limits" if len(lim) == 3: tex += "_{%s}^{%s}" % (self._print(lim[1]), self._print(lim[2])) if len(lim) == 2: tex += "^{%s}" % (self._print(lim[1])) symbols.insert(0, r"\, d%s" % self._print(symbol)) return r"%s %s%s" % (tex, self.parenthesize(expr.function, PRECEDENCE["Mul"], strict=True), "".join(symbols)) def _print_Limit(self, expr): e, z, z0, dir = expr.args tex = r"\lim_{%s \to " % self._print(z) if str(dir) == '+-' or z0 in (S.Infinity, S.NegativeInfinity): tex += r"%s}" % self._print(z0) else: tex += r"%s^%s}" % (self._print(z0), self._print(dir)) if isinstance(e, AssocOp): return r"%s\left(%s\right)" % (tex, self._print(e)) else: return r"%s %s" % (tex, self._print(e)) def _hprint_Function(self, func): r''' Logic to decide how to render a function to latex - if it is a recognized latex name, use the appropriate latex command - if it is a single letter, just use that letter - if it is a longer name, then put \operatorname{} around it and be mindful of undercores in the name ''' func = self._deal_with_super_sub(func) if func in accepted_latex_functions: name = r"\%s" % func elif len(func) == 1 or func.startswith('\\'): name = func else: name = r"\operatorname{%s}" % func return name def _print_Function(self, expr, exp=None): r''' Render functions to LaTeX, handling functions that LaTeX knows about e.g., sin, cos, ... by using the proper LaTeX command (\sin, \cos, ...). For single-letter function names, render them as regular LaTeX math symbols. For multi-letter function names that LaTeX does not know about, (e.g., Li, sech) use \operatorname{} so that the function name is rendered in Roman font and LaTeX handles spacing properly. expr is the expression involving the function exp is an exponent ''' func = expr.func.__name__ if hasattr(self, '_print_' + func) and \ not isinstance(expr, AppliedUndef): return getattr(self, '_print_' + func)(expr, exp) else: args = [str(self._print(arg)) for arg in expr.args] # How inverse trig functions should be displayed, formats are: # abbreviated: asin, full: arcsin, power: sin^-1 inv_trig_style = self._settings['inv_trig_style'] # If we are dealing with a power-style inverse trig function inv_trig_power_case = False # If it is applicable to fold the argument brackets can_fold_brackets = self._settings['fold_func_brackets'] and \ len(args) == 1 and \ not self._needs_function_brackets(expr.args[0]) inv_trig_table = ["asin", "acos", "atan", "acsc", "asec", "acot"] # If the function is an inverse trig function, handle the style if func in inv_trig_table: if inv_trig_style == "abbreviated": pass elif inv_trig_style == "full": func = "arc" + func[1:] elif inv_trig_style == "power": func = func[1:] inv_trig_power_case = True # Can never fold brackets if we're raised to a power if exp is not None: can_fold_brackets = False if inv_trig_power_case: if func in accepted_latex_functions: name = r"\%s^{-1}" % func else: name = r"\operatorname{%s}^{-1}" % func elif exp is not None: name = r'%s^{%s}' % (self._hprint_Function(func), exp) else: name = self._hprint_Function(func) if can_fold_brackets: if func in accepted_latex_functions: # Wrap argument safely to avoid parse-time conflicts # with the function name itself name += r" {%s}" else: name += r"%s" else: name += r"{\left(%s \right)}" if inv_trig_power_case and exp is not None: name += r"^{%s}" % exp return name % ",".join(args) def _print_UndefinedFunction(self, expr): return self._hprint_Function(str(expr)) def _print_ElementwiseApplyFunction(self, expr): return r"%s\left({%s}\ldots\right)" % ( self._print(expr.function), self._print(expr.expr), ) @property def _special_function_classes(self): from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.functions.special.gamma_functions import gamma, lowergamma from sympy.functions.special.beta_functions import beta from sympy.functions.special.delta_functions import DiracDelta from sympy.functions.special.error_functions import Chi return {KroneckerDelta: r'\delta', gamma: r'\Gamma', lowergamma: r'\gamma', beta: r'\operatorname{B}', DiracDelta: r'\delta', Chi: r'\operatorname{Chi}'} def _print_FunctionClass(self, expr): for cls in self._special_function_classes: if issubclass(expr, cls) and expr.__name__ == cls.__name__: return self._special_function_classes[cls] return self._hprint_Function(str(expr)) def _print_Lambda(self, expr): symbols, expr = expr.args if len(symbols) == 1: symbols = self._print(symbols[0]) else: symbols = self._print(tuple(symbols)) tex = r"\left( %s \mapsto %s \right)" % (symbols, self._print(expr)) return tex def _hprint_variadic_function(self, expr, exp=None): args = sorted(expr.args, key=default_sort_key) texargs = [r"%s" % self._print(symbol) for symbol in args] tex = r"\%s\left(%s\right)" % (self._print((str(expr.func)).lower()), ", ".join(texargs)) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex _print_Min = _print_Max = _hprint_variadic_function def _print_floor(self, expr, exp=None): tex = r"\left\lfloor{%s}\right\rfloor" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_ceiling(self, expr, exp=None): tex = r"\left\lceil{%s}\right\rceil" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_log(self, expr, exp=None): if not self._settings["ln_notation"]: tex = r"\log{\left(%s \right)}" % self._print(expr.args[0]) else: tex = r"\ln{\left(%s \right)}" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_Abs(self, expr, exp=None): tex = r"\left|{%s}\right|" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex _print_Determinant = _print_Abs def _print_re(self, expr, exp=None): if self._settings['gothic_re_im']: tex = r"\Re{%s}" % self.parenthesize(expr.args[0], PRECEDENCE['Atom']) else: tex = r"\operatorname{{re}}{{{}}}".format(self.parenthesize(expr.args[0], PRECEDENCE['Atom'])) return self._do_exponent(tex, exp) def _print_im(self, expr, exp=None): if self._settings['gothic_re_im']: tex = r"\Im{%s}" % self.parenthesize(expr.args[0], PRECEDENCE['Atom']) else: tex = r"\operatorname{{im}}{{{}}}".format(self.parenthesize(expr.args[0], PRECEDENCE['Atom'])) return self._do_exponent(tex, exp) def _print_Not(self, e): from sympy import Equivalent, Implies if isinstance(e.args[0], Equivalent): return self._print_Equivalent(e.args[0], r"\not\Leftrightarrow") if isinstance(e.args[0], Implies): return self._print_Implies(e.args[0], r"\not\Rightarrow") if (e.args[0].is_Boolean): return r"\neg (%s)" % self._print(e.args[0]) else: return r"\neg %s" % self._print(e.args[0]) def _print_LogOp(self, args, char): arg = args[0] if arg.is_Boolean and not arg.is_Not: tex = r"\left(%s\right)" % self._print(arg) else: tex = r"%s" % self._print(arg) for arg in args[1:]: if arg.is_Boolean and not arg.is_Not: tex += r" %s \left(%s\right)" % (char, self._print(arg)) else: tex += r" %s %s" % (char, self._print(arg)) return tex def _print_And(self, e): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, r"\wedge") def _print_Or(self, e): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, r"\vee") def _print_Xor(self, e): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, r"\veebar") def _print_Implies(self, e, altchar=None): return self._print_LogOp(e.args, altchar or r"\Rightarrow") def _print_Equivalent(self, e, altchar=None): args = sorted(e.args, key=default_sort_key) return self._print_LogOp(args, altchar or r"\Leftrightarrow") def _print_conjugate(self, expr, exp=None): tex = r"\overline{%s}" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_polar_lift(self, expr, exp=None): func = r"\operatorname{polar\_lift}" arg = r"{\left(%s \right)}" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}%s" % (func, exp, arg) else: return r"%s%s" % (func, arg) def _print_ExpBase(self, expr, exp=None): # TODO should exp_polar be printed differently? # what about exp_polar(0), exp_polar(1)? tex = r"e^{%s}" % self._print(expr.args[0]) return self._do_exponent(tex, exp) def _print_elliptic_k(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"K^{%s}%s" % (exp, tex) else: return r"K%s" % tex def _print_elliptic_f(self, expr, exp=None): tex = r"\left(%s\middle| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"F^{%s}%s" % (exp, tex) else: return r"F%s" % tex def _print_elliptic_e(self, expr, exp=None): if len(expr.args) == 2: tex = r"\left(%s\middle| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1])) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"E^{%s}%s" % (exp, tex) else: return r"E%s" % tex def _print_elliptic_pi(self, expr, exp=None): if len(expr.args) == 3: tex = r"\left(%s; %s\middle| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1]), self._print(expr.args[2])) else: tex = r"\left(%s\middle| %s\right)" % \ (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\Pi^{%s}%s" % (exp, tex) else: return r"\Pi%s" % tex def _print_beta(self, expr, exp=None): tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\operatorname{B}^{%s}%s" % (exp, tex) else: return r"\operatorname{B}%s" % tex def _print_uppergamma(self, expr, exp=None): tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\Gamma^{%s}%s" % (exp, tex) else: return r"\Gamma%s" % tex def _print_lowergamma(self, expr, exp=None): tex = r"\left(%s, %s\right)" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"\gamma^{%s}%s" % (exp, tex) else: return r"\gamma%s" % tex def _hprint_one_arg_func(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}%s" % (self._print(expr.func), exp, tex) else: return r"%s%s" % (self._print(expr.func), tex) _print_gamma = _hprint_one_arg_func def _print_Chi(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\operatorname{Chi}^{%s}%s" % (exp, tex) else: return r"\operatorname{Chi}%s" % tex def _print_expint(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[1]) nu = self._print(expr.args[0]) if exp is not None: return r"\operatorname{E}_{%s}^{%s}%s" % (nu, exp, tex) else: return r"\operatorname{E}_{%s}%s" % (nu, tex) def _print_fresnels(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"S^{%s}%s" % (exp, tex) else: return r"S%s" % tex def _print_fresnelc(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"C^{%s}%s" % (exp, tex) else: return r"C%s" % tex def _print_subfactorial(self, expr, exp=None): tex = r"!%s" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) if exp is not None: return r"\left(%s\right)^{%s}" % (tex, exp) else: return tex def _print_factorial(self, expr, exp=None): tex = r"%s!" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_factorial2(self, expr, exp=None): tex = r"%s!!" % self.parenthesize(expr.args[0], PRECEDENCE["Func"]) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_binomial(self, expr, exp=None): tex = r"{\binom{%s}{%s}}" % (self._print(expr.args[0]), self._print(expr.args[1])) if exp is not None: return r"%s^{%s}" % (tex, exp) else: return tex def _print_RisingFactorial(self, expr, exp=None): n, k = expr.args base = r"%s" % self.parenthesize(n, PRECEDENCE['Func']) tex = r"{%s}^{\left(%s\right)}" % (base, self._print(k)) return self._do_exponent(tex, exp) def _print_FallingFactorial(self, expr, exp=None): n, k = expr.args sub = r"%s" % self.parenthesize(k, PRECEDENCE['Func']) tex = r"{\left(%s\right)}_{%s}" % (self._print(n), sub) return self._do_exponent(tex, exp) def _hprint_BesselBase(self, expr, exp, sym): tex = r"%s" % (sym) need_exp = False if exp is not None: if tex.find('^') == -1: tex = r"%s^{%s}" % (tex, self._print(exp)) else: need_exp = True tex = r"%s_{%s}\left(%s\right)" % (tex, self._print(expr.order), self._print(expr.argument)) if need_exp: tex = self._do_exponent(tex, exp) return tex def _hprint_vec(self, vec): if not vec: return "" s = "" for i in vec[:-1]: s += "%s, " % self._print(i) s += self._print(vec[-1]) return s def _print_besselj(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'J') def _print_besseli(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'I') def _print_besselk(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'K') def _print_bessely(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'Y') def _print_yn(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'y') def _print_jn(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'j') def _print_hankel1(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'H^{(1)}') def _print_hankel2(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'H^{(2)}') def _print_hn1(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'h^{(1)}') def _print_hn2(self, expr, exp=None): return self._hprint_BesselBase(expr, exp, 'h^{(2)}') def _hprint_airy(self, expr, exp=None, notation=""): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"%s^{%s}%s" % (notation, exp, tex) else: return r"%s%s" % (notation, tex) def _hprint_airy_prime(self, expr, exp=None, notation=""): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"{%s^\prime}^{%s}%s" % (notation, exp, tex) else: return r"%s^\prime%s" % (notation, tex) def _print_airyai(self, expr, exp=None): return self._hprint_airy(expr, exp, 'Ai') def _print_airybi(self, expr, exp=None): return self._hprint_airy(expr, exp, 'Bi') def _print_airyaiprime(self, expr, exp=None): return self._hprint_airy_prime(expr, exp, 'Ai') def _print_airybiprime(self, expr, exp=None): return self._hprint_airy_prime(expr, exp, 'Bi') def _print_hyper(self, expr, exp=None): tex = r"{{}_{%s}F_{%s}\left(\begin{matrix} %s \\ %s \end{matrix}" \ r"\middle| {%s} \right)}" % \ (self._print(len(expr.ap)), self._print(len(expr.bq)), self._hprint_vec(expr.ap), self._hprint_vec(expr.bq), self._print(expr.argument)) if exp is not None: tex = r"{%s}^{%s}" % (tex, self._print(exp)) return tex def _print_meijerg(self, expr, exp=None): tex = r"{G_{%s, %s}^{%s, %s}\left(\begin{matrix} %s & %s \\" \ r"%s & %s \end{matrix} \middle| {%s} \right)}" % \ (self._print(len(expr.ap)), self._print(len(expr.bq)), self._print(len(expr.bm)), self._print(len(expr.an)), self._hprint_vec(expr.an), self._hprint_vec(expr.aother), self._hprint_vec(expr.bm), self._hprint_vec(expr.bother), self._print(expr.argument)) if exp is not None: tex = r"{%s}^{%s}" % (tex, self._print(exp)) return tex def _print_dirichlet_eta(self, expr, exp=None): tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\eta^{%s}%s" % (self._print(exp), tex) return r"\eta%s" % tex def _print_zeta(self, expr, exp=None): if len(expr.args) == 2: tex = r"\left(%s, %s\right)" % tuple(map(self._print, expr.args)) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\zeta^{%s}%s" % (self._print(exp), tex) return r"\zeta%s" % tex def _print_lerchphi(self, expr, exp=None): tex = r"\left(%s, %s, %s\right)" % tuple(map(self._print, expr.args)) if exp is None: return r"\Phi%s" % tex return r"\Phi^{%s}%s" % (self._print(exp), tex) def _print_polylog(self, expr, exp=None): s, z = map(self._print, expr.args) tex = r"\left(%s\right)" % z if exp is None: return r"\operatorname{Li}_{%s}%s" % (s, tex) return r"\operatorname{Li}_{%s}^{%s}%s" % (s, self._print(exp), tex) def _print_jacobi(self, expr, exp=None): n, a, b, x = map(self._print, expr.args) tex = r"P_{%s}^{\left(%s,%s\right)}\left(%s\right)" % (n, a, b, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_gegenbauer(self, expr, exp=None): n, a, x = map(self._print, expr.args) tex = r"C_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_chebyshevt(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"T_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_chebyshevu(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"U_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_legendre(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"P_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_assoc_legendre(self, expr, exp=None): n, a, x = map(self._print, expr.args) tex = r"P_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_hermite(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"H_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_laguerre(self, expr, exp=None): n, x = map(self._print, expr.args) tex = r"L_{%s}\left(%s\right)" % (n, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_assoc_laguerre(self, expr, exp=None): n, a, x = map(self._print, expr.args) tex = r"L_{%s}^{\left(%s\right)}\left(%s\right)" % (n, a, x) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_Ynm(self, expr, exp=None): n, m, theta, phi = map(self._print, expr.args) tex = r"Y_{%s}^{%s}\left(%s,%s\right)" % (n, m, theta, phi) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_Znm(self, expr, exp=None): n, m, theta, phi = map(self._print, expr.args) tex = r"Z_{%s}^{%s}\left(%s,%s\right)" % (n, m, theta, phi) if exp is not None: tex = r"\left(" + tex + r"\right)^{%s}" % (self._print(exp)) return tex def _print_Rational(self, expr): if expr.q != 1: sign = "" p = expr.p if expr.p < 0: sign = "- " p = -p if self._settings['fold_short_frac']: return r"%s%d / %d" % (sign, p, expr.q) return r"%s\frac{%d}{%d}" % (sign, p, expr.q) else: return self._print(expr.p) def _print_Order(self, expr): s = self._print(expr.expr) if expr.point and any(p != S.Zero for p in expr.point) or \ len(expr.variables) > 1: s += '; ' if len(expr.variables) > 1: s += self._print(expr.variables) elif expr.variables: s += self._print(expr.variables[0]) s += r'\rightarrow ' if len(expr.point) > 1: s += self._print(expr.point) else: s += self._print(expr.point[0]) return r"O\left(%s\right)" % s def _print_Symbol(self, expr, style='plain'): if expr in self._settings['symbol_names']: return self._settings['symbol_names'][expr] result = self._deal_with_super_sub(expr.name) if \ '\\' not in expr.name else expr.name if style == 'bold': result = r"\mathbf{{{}}}".format(result) return result _print_RandomSymbol = _print_Symbol def _print_MatrixSymbol(self, expr): return self._print_Symbol(expr, style=self._settings['mat_symbol_style']) def _deal_with_super_sub(self, string): if '{' in string: return string name, supers, subs = split_super_sub(string) name = translate(name) supers = [translate(sup) for sup in supers] subs = [translate(sub) for sub in subs] # glue all items together: if supers: name += "^{%s}" % " ".join(supers) if subs: name += "_{%s}" % " ".join(subs) return name def _print_Relational(self, expr): if self._settings['itex']: gt = r"\gt" lt = r"\lt" else: gt = ">" lt = "<" charmap = { "==": "=", ">": gt, "<": lt, ">=": r"\geq", "<=": r"\leq", "!=": r"\neq", } return "%s %s %s" % (self._print(expr.lhs), charmap[expr.rel_op], self._print(expr.rhs)) def _print_Piecewise(self, expr): ecpairs = [r"%s & \text{for}\: %s" % (self._print(e), self._print(c)) for e, c in expr.args[:-1]] if expr.args[-1].cond == true: ecpairs.append(r"%s & \text{otherwise}" % self._print(expr.args[-1].expr)) else: ecpairs.append(r"%s & \text{for}\: %s" % (self._print(expr.args[-1].expr), self._print(expr.args[-1].cond))) tex = r"\begin{cases} %s \end{cases}" return tex % r" \\".join(ecpairs) def _print_MatrixBase(self, expr): lines = [] for line in range(expr.rows): # horrible, should be 'rows' lines.append(" & ".join([self._print(i) for i in expr[line, :]])) mat_str = self._settings['mat_str'] if mat_str is None: if self._settings['mode'] == 'inline': mat_str = 'smallmatrix' else: if (expr.cols <= 10) is True: mat_str = 'matrix' else: mat_str = 'array' out_str = r'\begin{%MATSTR%}%s\end{%MATSTR%}' out_str = out_str.replace('%MATSTR%', mat_str) if mat_str == 'array': out_str = out_str.replace('%s', '{' + 'c'*expr.cols + '}%s') if self._settings['mat_delim']: left_delim = self._settings['mat_delim'] right_delim = self._delim_dict[left_delim] out_str = r'\left' + left_delim + out_str + \ r'\right' + right_delim return out_str % r"\\".join(lines) _print_ImmutableMatrix = _print_ImmutableDenseMatrix \ = _print_Matrix \ = _print_MatrixBase def _print_MatrixElement(self, expr): return self.parenthesize(expr.parent, PRECEDENCE["Atom"], strict=True)\ + '_{%s, %s}' % (self._print(expr.i), self._print(expr.j)) def _print_MatrixSlice(self, expr): def latexslice(x): x = list(x) if x[2] == 1: del x[2] if x[1] == x[0] + 1: del x[1] if x[0] == 0: x[0] = '' return ':'.join(map(self._print, x)) return (self._print(expr.parent) + r'\left[' + latexslice(expr.rowslice) + ', ' + latexslice(expr.colslice) + r'\right]') def _print_BlockMatrix(self, expr): return self._print(expr.blocks) def _print_Transpose(self, expr): mat = expr.arg from sympy.matrices import MatrixSymbol if not isinstance(mat, MatrixSymbol): return r"\left(%s\right)^{T}" % self._print(mat) else: return "%s^{T}" % self.parenthesize(mat, precedence_traditional(expr), True) def _print_Trace(self, expr): mat = expr.arg return r"\operatorname{tr}\left(%s \right)" % self._print(mat) def _print_Adjoint(self, expr): mat = expr.arg from sympy.matrices import MatrixSymbol if not isinstance(mat, MatrixSymbol): return r"\left(%s\right)^{\dagger}" % self._print(mat) else: return r"%s^{\dagger}" % self._print(mat) def _print_MatMul(self, expr): from sympy import MatMul, Mul parens = lambda x: self.parenthesize(x, precedence_traditional(expr), False) args = expr.args if isinstance(args[0], Mul): args = args[0].as_ordered_factors() + list(args[1:]) else: args = list(args) if isinstance(expr, MatMul) and _coeff_isneg(expr): if args[0] == -1: args = args[1:] else: args[0] = -args[0] return '- ' + ' '.join(map(parens, args)) else: return ' '.join(map(parens, args)) def _print_Mod(self, expr, exp=None): if exp is not None: return r'\left(%s\bmod{%s}\right)^{%s}' % \ (self.parenthesize(expr.args[0], PRECEDENCE['Mul'], strict=True), self._print(expr.args[1]), self._print(exp)) return r'%s\bmod{%s}' % (self.parenthesize(expr.args[0], PRECEDENCE['Mul'], strict=True), self._print(expr.args[1])) def _print_HadamardProduct(self, expr): args = expr.args prec = PRECEDENCE['Pow'] parens = self.parenthesize return r' \circ '.join( map(lambda arg: parens(arg, prec, strict=True), args)) def _print_HadamardPower(self, expr): template = r"%s^{\circ {%s}}" return self._helper_print_standard_power(expr, template) def _print_KroneckerProduct(self, expr): args = expr.args prec = PRECEDENCE['Pow'] parens = self.parenthesize return r' \otimes '.join( map(lambda arg: parens(arg, prec, strict=True), args)) def _print_MatPow(self, expr): base, exp = expr.base, expr.exp from sympy.matrices import MatrixSymbol if not isinstance(base, MatrixSymbol): return "\\left(%s\\right)^{%s}" % (self._print(base), self._print(exp)) else: return "%s^{%s}" % (self._print(base), self._print(exp)) def _print_ZeroMatrix(self, Z): return r"\mathbb{0}" def _print_OneMatrix(self, O): return r"\mathbb{1}" def _print_Identity(self, I): return r"\mathbb{I}" def _print_NDimArray(self, expr): if expr.rank() == 0: return self._print(expr[()]) mat_str = self._settings['mat_str'] if mat_str is None: if self._settings['mode'] == 'inline': mat_str = 'smallmatrix' else: if (expr.rank() == 0) or (expr.shape[-1] <= 10): mat_str = 'matrix' else: mat_str = 'array' block_str = r'\begin{%MATSTR%}%s\end{%MATSTR%}' block_str = block_str.replace('%MATSTR%', mat_str) if self._settings['mat_delim']: left_delim = self._settings['mat_delim'] right_delim = self._delim_dict[left_delim] block_str = r'\left' + left_delim + block_str + \ r'\right' + right_delim if expr.rank() == 0: return block_str % "" level_str = [[]] + [[] for i in range(expr.rank())] shape_ranges = [list(range(i)) for i in expr.shape] for outer_i in itertools.product(*shape_ranges): level_str[-1].append(self._print(expr[outer_i])) even = True for back_outer_i in range(expr.rank()-1, -1, -1): if len(level_str[back_outer_i+1]) < expr.shape[back_outer_i]: break if even: level_str[back_outer_i].append( r" & ".join(level_str[back_outer_i+1])) else: level_str[back_outer_i].append( block_str % (r"\\".join(level_str[back_outer_i+1]))) if len(level_str[back_outer_i+1]) == 1: level_str[back_outer_i][-1] = r"\left[" + \ level_str[back_outer_i][-1] + r"\right]" even = not even level_str[back_outer_i+1] = [] out_str = level_str[0][0] if expr.rank() % 2 == 1: out_str = block_str % out_str return out_str _print_ImmutableDenseNDimArray = _print_NDimArray _print_ImmutableSparseNDimArray = _print_NDimArray _print_MutableDenseNDimArray = _print_NDimArray _print_MutableSparseNDimArray = _print_NDimArray def _printer_tensor_indices(self, name, indices, index_map={}): out_str = self._print(name) last_valence = None prev_map = None for index in indices: new_valence = index.is_up if ((index in index_map) or prev_map) and \ last_valence == new_valence: out_str += "," if last_valence != new_valence: if last_valence is not None: out_str += "}" if index.is_up: out_str += "{}^{" else: out_str += "{}_{" out_str += self._print(index.args[0]) if index in index_map: out_str += "=" out_str += self._print(index_map[index]) prev_map = True else: prev_map = False last_valence = new_valence if last_valence is not None: out_str += "}" return out_str def _print_Tensor(self, expr): name = expr.args[0].args[0] indices = expr.get_indices() return self._printer_tensor_indices(name, indices) def _print_TensorElement(self, expr): name = expr.expr.args[0].args[0] indices = expr.expr.get_indices() index_map = expr.index_map return self._printer_tensor_indices(name, indices, index_map) def _print_TensMul(self, expr): # prints expressions like "A(a)", "3*A(a)", "(1+x)*A(a)" sign, args = expr._get_args_for_traditional_printer() return sign + "".join( [self.parenthesize(arg, precedence(expr)) for arg in args] ) def _print_TensAdd(self, expr): a = [] args = expr.args for x in args: a.append(self.parenthesize(x, precedence(expr))) a.sort() s = ' + '.join(a) s = s.replace('+ -', '- ') return s def _print_TensorIndex(self, expr): return "{}%s{%s}" % ( "^" if expr.is_up else "_", self._print(expr.args[0]) ) def _print_UniversalSet(self, expr): return r"\mathbb{U}" def _print_tuple(self, expr): return r"\left( %s\right)" % \ r", \ ".join([self._print(i) for i in expr]) def _print_TensorProduct(self, expr): elements = [self._print(a) for a in expr.args] return r' \otimes '.join(elements) def _print_WedgeProduct(self, expr): elements = [self._print(a) for a in expr.args] return r' \wedge '.join(elements) def _print_Tuple(self, expr): return self._print_tuple(expr) def _print_list(self, expr): return r"\left[ %s\right]" % \ r", \ ".join([self._print(i) for i in expr]) def _print_dict(self, d): keys = sorted(d.keys(), key=default_sort_key) items = [] for key in keys: val = d[key] items.append("%s : %s" % (self._print(key), self._print(val))) return r"\left\{ %s\right\}" % r", \ ".join(items) def _print_Dict(self, expr): return self._print_dict(expr) def _print_DiracDelta(self, expr, exp=None): if len(expr.args) == 1 or expr.args[1] == 0: tex = r"\delta\left(%s\right)" % self._print(expr.args[0]) else: tex = r"\delta^{\left( %s \right)}\left( %s \right)" % ( self._print(expr.args[1]), self._print(expr.args[0])) if exp: tex = r"\left(%s\right)^{%s}" % (tex, exp) return tex def _print_SingularityFunction(self, expr): shift = self._print(expr.args[0] - expr.args[1]) power = self._print(expr.args[2]) tex = r"{\left\langle %s \right\rangle}^{%s}" % (shift, power) return tex def _print_Heaviside(self, expr, exp=None): tex = r"\theta\left(%s\right)" % self._print(expr.args[0]) if exp: tex = r"\left(%s\right)^{%s}" % (tex, exp) return tex def _print_KroneckerDelta(self, expr, exp=None): i = self._print(expr.args[0]) j = self._print(expr.args[1]) if expr.args[0].is_Atom and expr.args[1].is_Atom: tex = r'\delta_{%s %s}' % (i, j) else: tex = r'\delta_{%s, %s}' % (i, j) if exp is not None: tex = r'\left(%s\right)^{%s}' % (tex, exp) return tex def _print_LeviCivita(self, expr, exp=None): indices = map(self._print, expr.args) if all(x.is_Atom for x in expr.args): tex = r'\varepsilon_{%s}' % " ".join(indices) else: tex = r'\varepsilon_{%s}' % ", ".join(indices) if exp: tex = r'\left(%s\right)^{%s}' % (tex, exp) return tex def _print_ProductSet(self, p): if len(p.sets) > 1 and not has_variety(p.sets): return self._print(p.sets[0]) + "^{%d}" % len(p.sets) else: return r" \times ".join(self._print(set) for set in p.sets) def _print_RandomDomain(self, d): if hasattr(d, 'as_boolean'): return '\\text{Domain: }' + self._print(d.as_boolean()) elif hasattr(d, 'set'): return ('\\text{Domain: }' + self._print(d.symbols) + '\\text{ in }' + self._print(d.set)) elif hasattr(d, 'symbols'): return '\\text{Domain on }' + self._print(d.symbols) else: return self._print(None) def _print_FiniteSet(self, s): items = sorted(s.args, key=default_sort_key) return self._print_set(items) def _print_set(self, s): items = sorted(s, key=default_sort_key) items = ", ".join(map(self._print, items)) return r"\left\{%s\right\}" % items _print_frozenset = _print_set def _print_Range(self, s): dots = r'\ldots' if s.start.is_infinite: printset = dots, s[-1] - s.step, s[-1] elif s.stop.is_infinite: it = iter(s) printset = next(it), next(it), dots elif len(s) > 4: it = iter(s) printset = next(it), next(it), dots, s[-1] else: printset = tuple(s) return (r"\left\{" + r", ".join(self._print(el) for el in printset) + r"\right\}") def _print_bernoulli(self, expr, exp=None): tex = r"B_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex _print_bell = _print_bernoulli def _print_fibonacci(self, expr, exp=None): tex = r"F_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_lucas(self, expr, exp=None): tex = r"L_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_tribonacci(self, expr, exp=None): tex = r"T_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_SeqFormula(self, s): if len(s.start.free_symbols) > 0 or len(s.stop.free_symbols) > 0: return r"\left\{%s\right\}_{%s=%s}^{%s}" % ( self._print(s.formula), self._print(s.variables[0]), self._print(s.start), self._print(s.stop) ) if s.start is S.NegativeInfinity: stop = s.stop printset = (r'\ldots', s.coeff(stop - 3), s.coeff(stop - 2), s.coeff(stop - 1), s.coeff(stop)) elif s.stop is S.Infinity or s.length > 4: printset = s[:4] printset.append(r'\ldots') else: printset = tuple(s) return (r"\left[" + r", ".join(self._print(el) for el in printset) + r"\right]") _print_SeqPer = _print_SeqFormula _print_SeqAdd = _print_SeqFormula _print_SeqMul = _print_SeqFormula def _print_Interval(self, i): if i.start == i.end: return r"\left\{%s\right\}" % self._print(i.start) else: if i.left_open: left = '(' else: left = '[' if i.right_open: right = ')' else: right = ']' return r"\left%s%s, %s\right%s" % \ (left, self._print(i.start), self._print(i.end), right) def _print_AccumulationBounds(self, i): return r"\left\langle %s, %s\right\rangle" % \ (self._print(i.min), self._print(i.max)) def _print_Union(self, u): return r" \cup ".join([self._print(i) for i in u.args]) def _print_Complement(self, u): return r" \setminus ".join([self._print(i) for i in u.args]) def _print_Intersection(self, u): return r" \cap ".join([self._print(i) for i in u.args]) def _print_SymmetricDifference(self, u): return r" \triangle ".join([self._print(i) for i in u.args]) def _print_EmptySet(self, e): return r"\emptyset" def _print_Naturals(self, n): return r"\mathbb{N}" def _print_Naturals0(self, n): return r"\mathbb{N}_0" def _print_Integers(self, i): return r"\mathbb{Z}" def _print_Reals(self, i): return r"\mathbb{R}" def _print_Complexes(self, i): return r"\mathbb{C}" def _print_ImageSet(self, s): sets = s.args[1:] varsets = [r"%s \in %s" % (self._print(var), self._print(setv)) for var, setv in zip(s.lamda.variables, sets)] return r"\left\{%s\; |\; %s\right\}" % ( self._print(s.lamda.expr), ', '.join(varsets)) def _print_ConditionSet(self, s): vars_print = ', '.join([self._print(var) for var in Tuple(s.sym)]) if s.base_set is S.UniversalSet: return r"\left\{%s \mid %s \right\}" % \ (vars_print, self._print(s.condition.as_expr())) return r"\left\{%s \mid %s \in %s \wedge %s \right\}" % ( vars_print, vars_print, self._print(s.base_set), self._print(s.condition)) def _print_ComplexRegion(self, s): vars_print = ', '.join([self._print(var) for var in s.variables]) return r"\left\{%s\; |\; %s \in %s \right\}" % ( self._print(s.expr), vars_print, self._print(s.sets)) def _print_Contains(self, e): return r"%s \in %s" % tuple(self._print(a) for a in e.args) def _print_FourierSeries(self, s): return self._print_Add(s.truncate()) + self._print(r' + \ldots') def _print_FormalPowerSeries(self, s): return self._print_Add(s.infinite) def _print_FiniteField(self, expr): return r"\mathbb{F}_{%s}" % expr.mod def _print_IntegerRing(self, expr): return r"\mathbb{Z}" def _print_RationalField(self, expr): return r"\mathbb{Q}" def _print_RealField(self, expr): return r"\mathbb{R}" def _print_ComplexField(self, expr): return r"\mathbb{C}" def _print_PolynomialRing(self, expr): domain = self._print(expr.domain) symbols = ", ".join(map(self._print, expr.symbols)) return r"%s\left[%s\right]" % (domain, symbols) def _print_FractionField(self, expr): domain = self._print(expr.domain) symbols = ", ".join(map(self._print, expr.symbols)) return r"%s\left(%s\right)" % (domain, symbols) def _print_PolynomialRingBase(self, expr): domain = self._print(expr.domain) symbols = ", ".join(map(self._print, expr.symbols)) inv = "" if not expr.is_Poly: inv = r"S_<^{-1}" return r"%s%s\left[%s\right]" % (inv, domain, symbols) def _print_Poly(self, poly): cls = poly.__class__.__name__ terms = [] for monom, coeff in poly.terms(): s_monom = '' for i, exp in enumerate(monom): if exp > 0: if exp == 1: s_monom += self._print(poly.gens[i]) else: s_monom += self._print(pow(poly.gens[i], exp)) if coeff.is_Add: if s_monom: s_coeff = r"\left(%s\right)" % self._print(coeff) else: s_coeff = self._print(coeff) else: if s_monom: if coeff is S.One: terms.extend(['+', s_monom]) continue if coeff is S.NegativeOne: terms.extend(['-', s_monom]) continue s_coeff = self._print(coeff) if not s_monom: s_term = s_coeff else: s_term = s_coeff + " " + s_monom if s_term.startswith('-'): terms.extend(['-', s_term[1:]]) else: terms.extend(['+', s_term]) if terms[0] in ['-', '+']: modifier = terms.pop(0) if modifier == '-': terms[0] = '-' + terms[0] expr = ' '.join(terms) gens = list(map(self._print, poly.gens)) domain = "domain=%s" % self._print(poly.get_domain()) args = ", ".join([expr] + gens + [domain]) if cls in accepted_latex_functions: tex = r"\%s {\left(%s \right)}" % (cls, args) else: tex = r"\operatorname{%s}{\left( %s \right)}" % (cls, args) return tex def _print_ComplexRootOf(self, root): cls = root.__class__.__name__ if cls == "ComplexRootOf": cls = "CRootOf" expr = self._print(root.expr) index = root.index if cls in accepted_latex_functions: return r"\%s {\left(%s, %d\right)}" % (cls, expr, index) else: return r"\operatorname{%s} {\left(%s, %d\right)}" % (cls, expr, index) def _print_RootSum(self, expr): cls = expr.__class__.__name__ args = [self._print(expr.expr)] if expr.fun is not S.IdentityFunction: args.append(self._print(expr.fun)) if cls in accepted_latex_functions: return r"\%s {\left(%s\right)}" % (cls, ", ".join(args)) else: return r"\operatorname{%s} {\left(%s\right)}" % (cls, ", ".join(args)) def _print_PolyElement(self, poly): mul_symbol = self._settings['mul_symbol_latex'] return poly.str(self, PRECEDENCE, "{%s}^{%d}", mul_symbol) def _print_FracElement(self, frac): if frac.denom == 1: return self._print(frac.numer) else: numer = self._print(frac.numer) denom = self._print(frac.denom) return r"\frac{%s}{%s}" % (numer, denom) def _print_euler(self, expr, exp=None): m, x = (expr.args[0], None) if len(expr.args) == 1 else expr.args tex = r"E_{%s}" % self._print(m) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) if x is not None: tex = r"%s\left(%s\right)" % (tex, self._print(x)) return tex def _print_catalan(self, expr, exp=None): tex = r"C_{%s}" % self._print(expr.args[0]) if exp is not None: tex = r"%s^{%s}" % (tex, self._print(exp)) return tex def _print_UnifiedTransform(self, expr, s, inverse=False): return r"\mathcal{{{}}}{}_{{{}}}\left[{}\right]\left({}\right)".format(s, '^{-1}' if inverse else '', self._print(expr.args[1]), self._print(expr.args[0]), self._print(expr.args[2])) def _print_MellinTransform(self, expr): return self._print_UnifiedTransform(expr, 'M') def _print_InverseMellinTransform(self, expr): return self._print_UnifiedTransform(expr, 'M', True) def _print_LaplaceTransform(self, expr): return self._print_UnifiedTransform(expr, 'L') def _print_InverseLaplaceTransform(self, expr): return self._print_UnifiedTransform(expr, 'L', True) def _print_FourierTransform(self, expr): return self._print_UnifiedTransform(expr, 'F') def _print_InverseFourierTransform(self, expr): return self._print_UnifiedTransform(expr, 'F', True) def _print_SineTransform(self, expr): return self._print_UnifiedTransform(expr, 'SIN') def _print_InverseSineTransform(self, expr): return self._print_UnifiedTransform(expr, 'SIN', True) def _print_CosineTransform(self, expr): return self._print_UnifiedTransform(expr, 'COS') def _print_InverseCosineTransform(self, expr): return self._print_UnifiedTransform(expr, 'COS', True) def _print_DMP(self, p): try: if p.ring is not None: # TODO incorporate order return self._print(p.ring.to_sympy(p)) except SympifyError: pass return self._print(repr(p)) def _print_DMF(self, p): return self._print_DMP(p) def _print_Object(self, object): return self._print(Symbol(object.name)) def _print_Morphism(self, morphism): domain = self._print(morphism.domain) codomain = self._print(morphism.codomain) return "%s\\rightarrow %s" % (domain, codomain) def _print_NamedMorphism(self, morphism): pretty_name = self._print(Symbol(morphism.name)) pretty_morphism = self._print_Morphism(morphism) return "%s:%s" % (pretty_name, pretty_morphism) def _print_IdentityMorphism(self, morphism): from sympy.categories import NamedMorphism return self._print_NamedMorphism(NamedMorphism( morphism.domain, morphism.codomain, "id")) def _print_CompositeMorphism(self, morphism): # All components of the morphism have names and it is thus # possible to build the name of the composite. component_names_list = [self._print(Symbol(component.name)) for component in morphism.components] component_names_list.reverse() component_names = "\\circ ".join(component_names_list) + ":" pretty_morphism = self._print_Morphism(morphism) return component_names + pretty_morphism def _print_Category(self, morphism): return r"\mathbf{{{}}}".format(self._print(Symbol(morphism.name))) def _print_Diagram(self, diagram): if not diagram.premises: # This is an empty diagram. return self._print(S.EmptySet) latex_result = self._print(diagram.premises) if diagram.conclusions: latex_result += "\\Longrightarrow %s" % \ self._print(diagram.conclusions) return latex_result def _print_DiagramGrid(self, grid): latex_result = "\\begin{array}{%s}\n" % ("c" * grid.width) for i in range(grid.height): for j in range(grid.width): if grid[i, j]: latex_result += latex(grid[i, j]) latex_result += " " if j != grid.width - 1: latex_result += "& " if i != grid.height - 1: latex_result += "\\\\" latex_result += "\n" latex_result += "\\end{array}\n" return latex_result def _print_FreeModule(self, M): return '{{{}}}^{{{}}}'.format(self._print(M.ring), self._print(M.rank)) def _print_FreeModuleElement(self, m): # Print as row vector for convenience, for now. return r"\left[ {} \right]".format(",".join( '{' + self._print(x) + '}' for x in m)) def _print_SubModule(self, m): return r"\left\langle {} \right\rangle".format(",".join( '{' + self._print(x) + '}' for x in m.gens)) def _print_ModuleImplementedIdeal(self, m): return r"\left\langle {} \right\rangle".format(",".join( '{' + self._print(x) + '}' for [x] in m._module.gens)) def _print_Quaternion(self, expr): # TODO: This expression is potentially confusing, # shall we print it as `Quaternion( ... )`? s = [self.parenthesize(i, PRECEDENCE["Mul"], strict=True) for i in expr.args] a = [s[0]] + [i+" "+j for i, j in zip(s[1:], "ijk")] return " + ".join(a) def _print_QuotientRing(self, R): # TODO nicer fractions for few generators... return r"\frac{{{}}}{{{}}}".format(self._print(R.ring), self._print(R.base_ideal)) def _print_QuotientRingElement(self, x): return r"{{{}}} + {{{}}}".format(self._print(x.data), self._print(x.ring.base_ideal)) def _print_QuotientModuleElement(self, m): return r"{{{}}} + {{{}}}".format(self._print(m.data), self._print(m.module.killed_module)) def _print_QuotientModule(self, M): # TODO nicer fractions for few generators... return r"\frac{{{}}}{{{}}}".format(self._print(M.base), self._print(M.killed_module)) def _print_MatrixHomomorphism(self, h): return r"{{{}}} : {{{}}} \to {{{}}}".format(self._print(h._sympy_matrix()), self._print(h.domain), self._print(h.codomain)) def _print_BaseScalarField(self, field): string = field._coord_sys._names[field._index] return r'\mathbf{{{}}}'.format(self._print(Symbol(string))) def _print_BaseVectorField(self, field): string = field._coord_sys._names[field._index] return r'\partial_{{{}}}'.format(self._print(Symbol(string))) def _print_Differential(self, diff): field = diff._form_field if hasattr(field, '_coord_sys'): string = field._coord_sys._names[field._index] return r'\operatorname{{d}}{}'.format(self._print(Symbol(string))) else: string = self._print(field) return r'\operatorname{{d}}\left({}\right)'.format(string) def _print_Tr(self, p): # TODO: Handle indices contents = self._print(p.args[0]) return r'\operatorname{{tr}}\left({}\right)'.format(contents) def _print_totient(self, expr, exp=None): if exp is not None: return r'\left(\phi\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\phi\left(%s\right)' % self._print(expr.args[0]) def _print_reduced_totient(self, expr, exp=None): if exp is not None: return r'\left(\lambda\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\lambda\left(%s\right)' % self._print(expr.args[0]) def _print_divisor_sigma(self, expr, exp=None): if len(expr.args) == 2: tex = r"_%s\left(%s\right)" % tuple(map(self._print, (expr.args[1], expr.args[0]))) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\sigma^{%s}%s" % (self._print(exp), tex) return r"\sigma%s" % tex def _print_udivisor_sigma(self, expr, exp=None): if len(expr.args) == 2: tex = r"_%s\left(%s\right)" % tuple(map(self._print, (expr.args[1], expr.args[0]))) else: tex = r"\left(%s\right)" % self._print(expr.args[0]) if exp is not None: return r"\sigma^*^{%s}%s" % (self._print(exp), tex) return r"\sigma^*%s" % tex def _print_primenu(self, expr, exp=None): if exp is not None: return r'\left(\nu\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\nu\left(%s\right)' % self._print(expr.args[0]) def _print_primeomega(self, expr, exp=None): if exp is not None: return r'\left(\Omega\left(%s\right)\right)^{%s}' % \ (self._print(expr.args[0]), self._print(exp)) return r'\Omega\left(%s\right)' % self._print(expr.args[0]) def translate(s): r''' Check for a modifier ending the string. If present, convert the modifier to latex and translate the rest recursively. Given a description of a Greek letter or other special character, return the appropriate latex. Let everything else pass as given. >>> from sympy.printing.latex import translate >>> translate('alphahatdotprime') "{\\dot{\\hat{\\alpha}}}'" ''' # Process the rest tex = tex_greek_dictionary.get(s) if tex: return tex elif s.lower() in greek_letters_set: return "\\" + s.lower() elif s in other_symbols: return "\\" + s else: # Process modifiers, if any, and recurse for key in sorted(modifier_dict.keys(), key=lambda k:len(k), reverse=True): if s.lower().endswith(key) and len(s) > len(key): return modifier_dict[key](translate(s[:-len(key)])) return s def latex(expr, fold_frac_powers=False, fold_func_brackets=False, fold_short_frac=None, inv_trig_style="abbreviated", itex=False, ln_notation=False, long_frac_ratio=None, mat_delim="[", mat_str=None, mode="plain", mul_symbol=None, order=None, symbol_names=None, root_notation=True, mat_symbol_style="plain", imaginary_unit="i", gothic_re_im=False): r"""Convert the given expression to LaTeX string representation. Parameters ========== fold_frac_powers : boolean, optional Emit ``^{p/q}`` instead of ``^{\frac{p}{q}}`` for fractional powers. fold_func_brackets : boolean, optional Fold function brackets where applicable. fold_short_frac : boolean, optional Emit ``p / q`` instead of ``\frac{p}{q}`` when the denominator is simple enough (at most two terms and no powers). The default value is ``True`` for inline mode, ``False`` otherwise. inv_trig_style : string, optional How inverse trig functions should be displayed. Can be one of ``abbreviated``, ``full``, or ``power``. Defaults to ``abbreviated``. itex : boolean, optional Specifies if itex-specific syntax is used, including emitting ``$$...$$``. ln_notation : boolean, optional If set to ``True``, ``\ln`` is used instead of default ``\log``. long_frac_ratio : float or None, optional The allowed ratio of the width of the numerator to the width of the denominator before the printer breaks off long fractions. If ``None`` (the default value), long fractions are not broken up. mat_delim : string, optional The delimiter to wrap around matrices. Can be one of ``[``, ``(``, or the empty string. Defaults to ``[``. mat_str : string, optional Which matrix environment string to emit. ``smallmatrix``, ``matrix``, ``array``, etc. Defaults to ``smallmatrix`` for inline mode, ``matrix`` for matrices of no more than 10 columns, and ``array`` otherwise. mode: string, optional Specifies how the generated code will be delimited. ``mode`` can be one of ``plain``, ``inline``, ``equation`` or ``equation*``. If ``mode`` is set to ``plain``, then the resulting code will not be delimited at all (this is the default). If ``mode`` is set to ``inline`` then inline LaTeX ``$...$`` will be used. If ``mode`` is set to ``equation`` or ``equation*``, the resulting code will be enclosed in the ``equation`` or ``equation*`` environment (remember to import ``amsmath`` for ``equation*``), unless the ``itex`` option is set. In the latter case, the ``$$...$$`` syntax is used. mul_symbol : string or None, optional The symbol to use for multiplication. Can be one of ``None``, ``ldot``, ``dot``, or ``times``. order: string, optional Any of the supported monomial orderings (currently ``lex``, ``grlex``, or ``grevlex``), ``old``, and ``none``. This parameter does nothing for Mul objects. Setting order to ``old`` uses the compatibility ordering for Add defined in Printer. For very large expressions, set the ``order`` keyword to ``none`` if speed is a concern. symbol_names : dictionary of strings mapped to symbols, optional Dictionary of symbols and the custom strings they should be emitted as. root_notation : boolean, optional If set to ``False``, exponents of the form 1/n are printed in fractonal form. Default is ``True``, to print exponent in root form. mat_symbol_style : string, optional Can be either ``plain`` (default) or ``bold``. If set to ``bold``, a MatrixSymbol A will be printed as ``\mathbf{A}``, otherwise as ``A``. imaginary_unit : string, optional String to use for the imaginary unit. Defined options are "i" (default) and "j". Adding "r" or "t" in front gives ``\mathrm`` or ``\text``, so "ri" leads to ``\mathrm{i}`` which gives `\mathrm{i}`. gothic_re_im : boolean, optional If set to ``True``, `\Re` and `\Im` is used for ``re`` and ``im``, respectively. The default is ``False`` leading to `\operatorname{re}` and `\operatorname{im}`. Notes ===== Not using a print statement for printing, results in double backslashes for latex commands since that's the way Python escapes backslashes in strings. >>> from sympy import latex, Rational >>> from sympy.abc import tau >>> latex((2*tau)**Rational(7,2)) '8 \\sqrt{2} \\tau^{\\frac{7}{2}}' >>> print(latex((2*tau)**Rational(7,2))) 8 \sqrt{2} \tau^{\frac{7}{2}} Examples ======== >>> from sympy import latex, pi, sin, asin, Integral, Matrix, Rational, log >>> from sympy.abc import x, y, mu, r, tau Basic usage: >>> print(latex((2*tau)**Rational(7,2))) 8 \sqrt{2} \tau^{\frac{7}{2}} ``mode`` and ``itex`` options: >>> print(latex((2*mu)**Rational(7,2), mode='plain')) 8 \sqrt{2} \mu^{\frac{7}{2}} >>> print(latex((2*tau)**Rational(7,2), mode='inline')) $8 \sqrt{2} \tau^{7 / 2}$ >>> print(latex((2*mu)**Rational(7,2), mode='equation*')) \begin{equation*}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation*} >>> print(latex((2*mu)**Rational(7,2), mode='equation')) \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} >>> print(latex((2*mu)**Rational(7,2), mode='equation', itex=True)) $$8 \sqrt{2} \mu^{\frac{7}{2}}$$ >>> print(latex((2*mu)**Rational(7,2), mode='plain')) 8 \sqrt{2} \mu^{\frac{7}{2}} >>> print(latex((2*tau)**Rational(7,2), mode='inline')) $8 \sqrt{2} \tau^{7 / 2}$ >>> print(latex((2*mu)**Rational(7,2), mode='equation*')) \begin{equation*}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation*} >>> print(latex((2*mu)**Rational(7,2), mode='equation')) \begin{equation}8 \sqrt{2} \mu^{\frac{7}{2}}\end{equation} >>> print(latex((2*mu)**Rational(7,2), mode='equation', itex=True)) $$8 \sqrt{2} \mu^{\frac{7}{2}}$$ Fraction options: >>> print(latex((2*tau)**Rational(7,2), fold_frac_powers=True)) 8 \sqrt{2} \tau^{7/2} >>> print(latex((2*tau)**sin(Rational(7,2)))) \left(2 \tau\right)^{\sin{\left(\frac{7}{2} \right)}} >>> print(latex((2*tau)**sin(Rational(7,2)), fold_func_brackets=True)) \left(2 \tau\right)^{\sin {\frac{7}{2}}} >>> print(latex(3*x**2/y)) \frac{3 x^{2}}{y} >>> print(latex(3*x**2/y, fold_short_frac=True)) 3 x^{2} / y >>> print(latex(Integral(r, r)/2/pi, long_frac_ratio=2)) \frac{\int r\, dr}{2 \pi} >>> print(latex(Integral(r, r)/2/pi, long_frac_ratio=0)) \frac{1}{2 \pi} \int r\, dr Multiplication options: >>> print(latex((2*tau)**sin(Rational(7,2)), mul_symbol="times")) \left(2 \times \tau\right)^{\sin{\left(\frac{7}{2} \right)}} Trig options: >>> print(latex(asin(Rational(7,2)))) \operatorname{asin}{\left(\frac{7}{2} \right)} >>> print(latex(asin(Rational(7,2)), inv_trig_style="full")) \arcsin{\left(\frac{7}{2} \right)} >>> print(latex(asin(Rational(7,2)), inv_trig_style="power")) \sin^{-1}{\left(\frac{7}{2} \right)} Matrix options: >>> print(latex(Matrix(2, 1, [x, y]))) \left[\begin{matrix}x\\y\end{matrix}\right] >>> print(latex(Matrix(2, 1, [x, y]), mat_str = "array")) \left[\begin{array}{c}x\\y\end{array}\right] >>> print(latex(Matrix(2, 1, [x, y]), mat_delim="(")) \left(\begin{matrix}x\\y\end{matrix}\right) Custom printing of symbols: >>> print(latex(x**2, symbol_names={x: 'x_i'})) x_i^{2} Logarithms: >>> print(latex(log(10))) \log{\left(10 \right)} >>> print(latex(log(10), ln_notation=True)) \ln{\left(10 \right)} ``latex()`` also supports the builtin container types list, tuple, and dictionary. >>> print(latex([2/x, y], mode='inline')) $\left[ 2 / x, \ y\right]$ """ if symbol_names is None: symbol_names = {} settings = { 'fold_frac_powers': fold_frac_powers, 'fold_func_brackets': fold_func_brackets, 'fold_short_frac': fold_short_frac, 'inv_trig_style': inv_trig_style, 'itex': itex, 'ln_notation': ln_notation, 'long_frac_ratio': long_frac_ratio, 'mat_delim': mat_delim, 'mat_str': mat_str, 'mode': mode, 'mul_symbol': mul_symbol, 'order': order, 'symbol_names': symbol_names, 'root_notation': root_notation, 'mat_symbol_style': mat_symbol_style, 'imaginary_unit': imaginary_unit, 'gothic_re_im': gothic_re_im, } return LatexPrinter(settings).doprint(expr) def print_latex(expr, **settings): """Prints LaTeX representation of the given expression. Takes the same settings as ``latex()``.""" print(latex(expr, **settings))

bde93a64f132110274cad28a3f2979c7abddf091a147ee1a7e013c90946f8dc3

""" A MathML printer. """ from __future__ import print_function, division from sympy import sympify, S, Mul from sympy.core.compatibility import range, string_types, default_sort_key from sympy.core.function import _coeff_isneg from sympy.printing.conventions import split_super_sub, requires_partial from sympy.printing.precedence import precedence_traditional, PRECEDENCE from sympy.printing.pretty.pretty_symbology import greek_unicode from sympy.printing.printer import Printer import mpmath.libmp as mlib from mpmath.libmp import prec_to_dps class MathMLPrinterBase(Printer): """Contains common code required for MathMLContentPrinter and MathMLPresentationPrinter. """ _default_settings = { "order": None, "encoding": "utf-8", "fold_frac_powers": False, "fold_func_brackets": False, "fold_short_frac": None, "inv_trig_style": "abbreviated", "ln_notation": False, "long_frac_ratio": None, "mat_delim": "[", "mat_symbol_style": "plain", "mul_symbol": None, "root_notation": True, "symbol_names": {}, "mul_symbol_mathml_numbers": '·', } def __init__(self, settings=None): Printer.__init__(self, settings) from xml.dom.minidom import Document, Text self.dom = Document() # Workaround to allow strings to remain unescaped # Based on # https://stackoverflow.com/questions/38015864/python-xml-dom-minidom-\ # please-dont-escape-my-strings/38041194 class RawText(Text): def writexml(self, writer, indent='', addindent='', newl=''): if self.data: writer.write(u'{}{}{}'.format(indent, self.data, newl)) def createRawTextNode(data): r = RawText() r.data = data r.ownerDocument = self.dom return r self.dom.createTextNode = createRawTextNode def doprint(self, expr): """ Prints the expression as MathML. """ mathML = Printer._print(self, expr) unistr = mathML.toxml() xmlbstr = unistr.encode('ascii', 'xmlcharrefreplace') res = xmlbstr.decode() return res def apply_patch(self): # Applying the patch of xml.dom.minidom bug # Date: 2011-11-18 # Description: http://ronrothman.com/public/leftbraned/xml-dom-minidom\ # -toprettyxml-and-silly-whitespace/#best-solution # Issue: http://bugs.python.org/issue4147 # Patch: http://hg.python.org/cpython/rev/7262f8f276ff/ from xml.dom.minidom import Element, Text, Node, _write_data def writexml(self, writer, indent="", addindent="", newl=""): # indent = current indentation # addindent = indentation to add to higher levels # newl = newline string writer.write(indent + "<" + self.tagName) attrs = self._get_attributes() a_names = list(attrs.keys()) a_names.sort() for a_name in a_names: writer.write(" %s=\"" % a_name) _write_data(writer, attrs[a_name].value) writer.write("\"") if self.childNodes: writer.write(">") if (len(self.childNodes) == 1 and self.childNodes[0].nodeType == Node.TEXT_NODE): self.childNodes[0].writexml(writer, '', '', '') else: writer.write(newl) for node in self.childNodes: node.writexml( writer, indent + addindent, addindent, newl) writer.write(indent) writer.write("</%s>%s" % (self.tagName, newl)) else: writer.write("/>%s" % (newl)) self._Element_writexml_old = Element.writexml Element.writexml = writexml def writexml(self, writer, indent="", addindent="", newl=""): _write_data(writer, "%s%s%s" % (indent, self.data, newl)) self._Text_writexml_old = Text.writexml Text.writexml = writexml def restore_patch(self): from xml.dom.minidom import Element, Text Element.writexml = self._Element_writexml_old Text.writexml = self._Text_writexml_old class MathMLContentPrinter(MathMLPrinterBase): """Prints an expression to the Content MathML markup language. References: https://www.w3.org/TR/MathML2/chapter4.html """ printmethod = "_mathml_content" def mathml_tag(self, e): """Returns the MathML tag for an expression.""" translate = { 'Add': 'plus', 'Mul': 'times', 'Derivative': 'diff', 'Number': 'cn', 'int': 'cn', 'Pow': 'power', 'Symbol': 'ci', 'MatrixSymbol': 'ci', 'RandomSymbol': 'ci', 'Integral': 'int', 'Sum': 'sum', 'sin': 'sin', 'cos': 'cos', 'tan': 'tan', 'cot': 'cot', 'asin': 'arcsin', 'asinh': 'arcsinh', 'acos': 'arccos', 'acosh': 'arccosh', 'atan': 'arctan', 'atanh': 'arctanh', 'acot': 'arccot', 'atan2': 'arctan', 'log': 'ln', 'Equality': 'eq', 'Unequality': 'neq', 'GreaterThan': 'geq', 'LessThan': 'leq', 'StrictGreaterThan': 'gt', 'StrictLessThan': 'lt', } for cls in e.__class__.__mro__: n = cls.__name__ if n in translate: return translate[n] # Not found in the MRO set n = e.__class__.__name__ return n.lower() def _print_Mul(self, expr): if _coeff_isneg(expr): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('minus')) x.appendChild(self._print_Mul(-expr)) return x from sympy.simplify import fraction numer, denom = fraction(expr) if denom is not S.One: x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('divide')) x.appendChild(self._print(numer)) x.appendChild(self._print(denom)) return x coeff, terms = expr.as_coeff_mul() if coeff is S.One and len(terms) == 1: # XXX since the negative coefficient has been handled, I don't # think a coeff of 1 can remain return self._print(terms[0]) if self.order != 'old': terms = Mul._from_args(terms).as_ordered_factors() x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('times')) if coeff != 1: x.appendChild(self._print(coeff)) for term in terms: x.appendChild(self._print(term)) return x def _print_Add(self, expr, order=None): args = self._as_ordered_terms(expr, order=order) lastProcessed = self._print(args[0]) plusNodes = [] for arg in args[1:]: if _coeff_isneg(arg): # use minus x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('minus')) x.appendChild(lastProcessed) x.appendChild(self._print(-arg)) # invert expression since this is now minused lastProcessed = x if arg == args[-1]: plusNodes.append(lastProcessed) else: plusNodes.append(lastProcessed) lastProcessed = self._print(arg) if arg == args[-1]: plusNodes.append(self._print(arg)) if len(plusNodes) == 1: return lastProcessed x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('plus')) while plusNodes: x.appendChild(plusNodes.pop(0)) return x def _print_MatrixBase(self, m): x = self.dom.createElement('matrix') for i in range(m.rows): x_r = self.dom.createElement('matrixrow') for j in range(m.cols): x_r.appendChild(self._print(m[i, j])) x.appendChild(x_r) return x def _print_Rational(self, e): if e.q == 1: # don't divide x = self.dom.createElement('cn') x.appendChild(self.dom.createTextNode(str(e.p))) return x x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('divide')) # numerator xnum = self.dom.createElement('cn') xnum.appendChild(self.dom.createTextNode(str(e.p))) # denominator xdenom = self.dom.createElement('cn') xdenom.appendChild(self.dom.createTextNode(str(e.q))) x.appendChild(xnum) x.appendChild(xdenom) return x def _print_Limit(self, e): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement(self.mathml_tag(e))) x_1 = self.dom.createElement('bvar') x_2 = self.dom.createElement('lowlimit') x_1.appendChild(self._print(e.args[1])) x_2.appendChild(self._print(e.args[2])) x.appendChild(x_1) x.appendChild(x_2) x.appendChild(self._print(e.args[0])) return x def _print_ImaginaryUnit(self, e): return self.dom.createElement('imaginaryi') def _print_EulerGamma(self, e): return self.dom.createElement('eulergamma') def _print_GoldenRatio(self, e): """We use unicode #x3c6 for Greek letter phi as defined here http://www.w3.org/2003/entities/2007doc/isogrk1.html""" x = self.dom.createElement('cn') x.appendChild(self.dom.createTextNode(u"\N{GREEK SMALL LETTER PHI}")) return x def _print_Exp1(self, e): return self.dom.createElement('exponentiale') def _print_Pi(self, e): return self.dom.createElement('pi') def _print_Infinity(self, e): return self.dom.createElement('infinity') def _print_NegativeInfinity(self, e): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('minus')) x.appendChild(self.dom.createElement('infinity')) return x def _print_Integral(self, e): def lime_recur(limits): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement(self.mathml_tag(e))) bvar_elem = self.dom.createElement('bvar') bvar_elem.appendChild(self._print(limits[0][0])) x.appendChild(bvar_elem) if len(limits[0]) == 3: low_elem = self.dom.createElement('lowlimit') low_elem.appendChild(self._print(limits[0][1])) x.appendChild(low_elem) up_elem = self.dom.createElement('uplimit') up_elem.appendChild(self._print(limits[0][2])) x.appendChild(up_elem) if len(limits[0]) == 2: up_elem = self.dom.createElement('uplimit') up_elem.appendChild(self._print(limits[0][1])) x.appendChild(up_elem) if len(limits) == 1: x.appendChild(self._print(e.function)) else: x.appendChild(lime_recur(limits[1:])) return x limits = list(e.limits) limits.reverse() return lime_recur(limits) def _print_Sum(self, e): # Printer can be shared because Sum and Integral have the # same internal representation. return self._print_Integral(e) def _print_Symbol(self, sym): ci = self.dom.createElement(self.mathml_tag(sym)) def join(items): if len(items) > 1: mrow = self.dom.createElement('mml:mrow') for i, item in enumerate(items): if i > 0: mo = self.dom.createElement('mml:mo') mo.appendChild(self.dom.createTextNode(" ")) mrow.appendChild(mo) mi = self.dom.createElement('mml:mi') mi.appendChild(self.dom.createTextNode(item)) mrow.appendChild(mi) return mrow else: mi = self.dom.createElement('mml:mi') mi.appendChild(self.dom.createTextNode(items[0])) return mi # translate name, supers and subs to unicode characters def translate(s): if s in greek_unicode: return greek_unicode.get(s) else: return s name, supers, subs = split_super_sub(sym.name) name = translate(name) supers = [translate(sup) for sup in supers] subs = [translate(sub) for sub in subs] mname = self.dom.createElement('mml:mi') mname.appendChild(self.dom.createTextNode(name)) if not supers: if not subs: ci.appendChild(self.dom.createTextNode(name)) else: msub = self.dom.createElement('mml:msub') msub.appendChild(mname) msub.appendChild(join(subs)) ci.appendChild(msub) else: if not subs: msup = self.dom.createElement('mml:msup') msup.appendChild(mname) msup.appendChild(join(supers)) ci.appendChild(msup) else: msubsup = self.dom.createElement('mml:msubsup') msubsup.appendChild(mname) msubsup.appendChild(join(subs)) msubsup.appendChild(join(supers)) ci.appendChild(msubsup) return ci _print_MatrixSymbol = _print_Symbol _print_RandomSymbol = _print_Symbol def _print_Pow(self, e): # Here we use root instead of power if the exponent is the reciprocal # of an integer if (self._settings['root_notation'] and e.exp.is_Rational and e.exp.p == 1): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement('root')) if e.exp.q != 2: xmldeg = self.dom.createElement('degree') xmlci = self.dom.createElement('ci') xmlci.appendChild(self.dom.createTextNode(str(e.exp.q))) xmldeg.appendChild(xmlci) x.appendChild(xmldeg) x.appendChild(self._print(e.base)) return x x = self.dom.createElement('apply') x_1 = self.dom.createElement(self.mathml_tag(e)) x.appendChild(x_1) x.appendChild(self._print(e.base)) x.appendChild(self._print(e.exp)) return x def _print_Number(self, e): x = self.dom.createElement(self.mathml_tag(e)) x.appendChild(self.dom.createTextNode(str(e))) return x def _print_Derivative(self, e): x = self.dom.createElement('apply') diff_symbol = self.mathml_tag(e) if requires_partial(e): diff_symbol = 'partialdiff' x.appendChild(self.dom.createElement(diff_symbol)) x_1 = self.dom.createElement('bvar') for sym, times in reversed(e.variable_count): x_1.appendChild(self._print(sym)) if times > 1: degree = self.dom.createElement('degree') degree.appendChild(self._print(sympify(times))) x_1.appendChild(degree) x.appendChild(x_1) x.appendChild(self._print(e.expr)) return x def _print_Function(self, e): x = self.dom.createElement("apply") x.appendChild(self.dom.createElement(self.mathml_tag(e))) for arg in e.args: x.appendChild(self._print(arg)) return x def _print_Basic(self, e): x = self.dom.createElement(self.mathml_tag(e)) for arg in e.args: x.appendChild(self._print(arg)) return x def _print_AssocOp(self, e): x = self.dom.createElement('apply') x_1 = self.dom.createElement(self.mathml_tag(e)) x.appendChild(x_1) for arg in e.args: x.appendChild(self._print(arg)) return x def _print_Relational(self, e): x = self.dom.createElement('apply') x.appendChild(self.dom.createElement(self.mathml_tag(e))) x.appendChild(self._print(e.lhs)) x.appendChild(self._print(e.rhs)) return x def _print_list(self, seq): """MathML reference for the <list> element: http://www.w3.org/TR/MathML2/chapter4.html#contm.list""" dom_element = self.dom.createElement('list') for item in seq: dom_element.appendChild(self._print(item)) return dom_element def _print_int(self, p): dom_element = self.dom.createElement(self.mathml_tag(p)) dom_element.appendChild(self.dom.createTextNode(str(p))) return dom_element class MathMLPresentationPrinter(MathMLPrinterBase): """Prints an expression to the Presentation MathML markup language. References: https://www.w3.org/TR/MathML2/chapter3.html """ printmethod = "_mathml_presentation" def mathml_tag(self, e): """Returns the MathML tag for an expression.""" translate = { 'Number': 'mn', 'Limit': '→', 'Derivative': '&dd;', 'int': 'mn', 'Symbol': 'mi', 'Integral': '∫', 'Sum': '∑', 'sin': 'sin', 'cos': 'cos', 'tan': 'tan', 'cot': 'cot', 'asin': 'arcsin', 'asinh': 'arcsinh', 'acos': 'arccos', 'acosh': 'arccosh', 'atan': 'arctan', 'atanh': 'arctanh', 'acot': 'arccot', 'atan2': 'arctan', 'Equality': '=', 'Unequality': '≠', 'GreaterThan': '≥', 'LessThan': '≤', 'StrictGreaterThan': '>', 'StrictLessThan': '<', 'lerchphi': 'Φ', 'zeta': 'ζ', 'dirichlet_eta': 'η', 'elliptic_k': 'Κ', 'lowergamma': 'γ', 'uppergamma': 'Γ', 'gamma': 'Γ', 'totient': 'ϕ', 'reduced_totient': 'λ', 'primenu': 'ν', 'primeomega': 'Ω', 'fresnels': 'S', 'fresnelc': 'C', 'Heaviside': 'Θ', 'BooleanTrue': 'True', 'BooleanFalse': 'False', 'NoneType': 'None', } def mul_symbol_selection(): if (self._settings["mul_symbol"] is None or self._settings["mul_symbol"] == 'None'): return '⁢' elif self._settings["mul_symbol"] == 'times': return '×' elif self._settings["mul_symbol"] == 'dot': return '·' elif self._settings["mul_symbol"] == 'ldot': return '․' elif not isinstance(self._settings["mul_symbol"], string_types): raise TypeError else: return self._settings["mul_symbol"] for cls in e.__class__.__mro__: n = cls.__name__ if n in translate: return translate[n] # Not found in the MRO set if e.__class__.__name__ == "Mul": return mul_symbol_selection() n = e.__class__.__name__ return n.lower() def parenthesize(self, item, level, strict=False): prec_val = precedence_traditional(item) if (prec_val < level) or ((not strict) and prec_val <= level): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(item)) return brac else: return self._print(item) def _print_Mul(self, expr): def multiply(expr, mrow): from sympy.simplify import fraction numer, denom = fraction(expr) if denom is not S.One: frac = self.dom.createElement('mfrac') if self._settings["fold_short_frac"] and len(str(expr)) < 7: frac.setAttribute('bevelled', 'true') xnum = self._print(numer) xden = self._print(denom) frac.appendChild(xnum) frac.appendChild(xden) mrow.appendChild(frac) return mrow coeff, terms = expr.as_coeff_mul() if coeff is S.One and len(terms) == 1: mrow.appendChild(self._print(terms[0])) return mrow if self.order != 'old': terms = Mul._from_args(terms).as_ordered_factors() if coeff != 1: x = self._print(coeff) y = self.dom.createElement('mo') y.appendChild(self.dom.createTextNode(self.mathml_tag(expr))) mrow.appendChild(x) mrow.appendChild(y) for term in terms: x = self._print(term) mrow.appendChild(x) if not term == terms[-1]: y = self.dom.createElement('mo') y.appendChild(self.dom.createTextNode(self.mathml_tag(expr))) mrow.appendChild(y) return mrow mrow = self.dom.createElement('mrow') if _coeff_isneg(expr): x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('-')) mrow.appendChild(x) mrow = multiply(-expr, mrow) else: mrow = multiply(expr, mrow) return mrow def _print_Add(self, expr, order=None): mrow = self.dom.createElement('mrow') args = self._as_ordered_terms(expr, order=order) mrow.appendChild(self._print(args[0])) for arg in args[1:]: if _coeff_isneg(arg): # use minus x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('-')) y = self._print(-arg) # invert expression since this is now minused else: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('+')) y = self._print(arg) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_MatrixBase(self, m): table = self.dom.createElement('mtable') for i in range(m.rows): x = self.dom.createElement('mtr') for j in range(m.cols): y = self.dom.createElement('mtd') y.appendChild(self._print(m[i, j])) x.appendChild(y) table.appendChild(x) if self._settings["mat_delim"] == '': return table brac = self.dom.createElement('mfenced') if self._settings["mat_delim"] == "[": brac.setAttribute('open', '[') brac.setAttribute('close', ']') brac.appendChild(table) return brac def _get_printed_Rational(self, e, folded=None): if e.p < 0: p = -e.p else: p = e.p x = self.dom.createElement('mfrac') if folded or self._settings["fold_short_frac"]: x.setAttribute('bevelled', 'true') x.appendChild(self._print(p)) x.appendChild(self._print(e.q)) if e.p < 0: mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('-')) mrow.appendChild(mo) mrow.appendChild(x) return mrow else: return x def _print_Rational(self, e): if e.q == 1: # don't divide return self._print(e.p) return self._get_printed_Rational(e, self._settings["fold_short_frac"]) def _print_Limit(self, e): mrow = self.dom.createElement('mrow') munder = self.dom.createElement('munder') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('lim')) x = self.dom.createElement('mrow') x_1 = self._print(e.args[1]) arrow = self.dom.createElement('mo') arrow.appendChild(self.dom.createTextNode(self.mathml_tag(e))) x_2 = self._print(e.args[2]) x.appendChild(x_1) x.appendChild(arrow) x.appendChild(x_2) munder.appendChild(mi) munder.appendChild(x) mrow.appendChild(munder) mrow.appendChild(self._print(e.args[0])) return mrow def _print_ImaginaryUnit(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('&ImaginaryI;')) return x def _print_GoldenRatio(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('Φ')) return x def _print_Exp1(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('&ExponentialE;')) return x def _print_Pi(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('π')) return x def _print_Infinity(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('∞')) return x def _print_NegativeInfinity(self, e): mrow = self.dom.createElement('mrow') y = self.dom.createElement('mo') y.appendChild(self.dom.createTextNode('-')) x = self._print_Infinity(e) mrow.appendChild(y) mrow.appendChild(x) return mrow def _print_Integral(self, expr): intsymbols = {1: "∫", 2: "∬", 3: "∭"} mrow = self.dom.createElement('mrow') if len(expr.limits) <= 3 and all(len(lim) == 1 for lim in expr.limits): # Only up to three-integral signs exists mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(intsymbols[len(expr.limits)])) mrow.appendChild(mo) else: # Either more than three or limits provided for lim in reversed(expr.limits): mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(intsymbols[1])) if len(lim) == 1: mrow.appendChild(mo) if len(lim) == 2: msup = self.dom.createElement('msup') msup.appendChild(mo) msup.appendChild(self._print(lim[1])) mrow.appendChild(msup) if len(lim) == 3: msubsup = self.dom.createElement('msubsup') msubsup.appendChild(mo) msubsup.appendChild(self._print(lim[1])) msubsup.appendChild(self._print(lim[2])) mrow.appendChild(msubsup) # print function mrow.appendChild(self.parenthesize(expr.function, PRECEDENCE["Mul"], strict=True)) # print integration variables for lim in reversed(expr.limits): d = self.dom.createElement('mo') d.appendChild(self.dom.createTextNode('&dd;')) mrow.appendChild(d) mrow.appendChild(self._print(lim[0])) return mrow def _print_Sum(self, e): limits = list(e.limits) subsup = self.dom.createElement('munderover') low_elem = self._print(limits[0][1]) up_elem = self._print(limits[0][2]) summand = self.dom.createElement('mo') summand.appendChild(self.dom.createTextNode(self.mathml_tag(e))) low = self.dom.createElement('mrow') var = self._print(limits[0][0]) equal = self.dom.createElement('mo') equal.appendChild(self.dom.createTextNode('=')) low.appendChild(var) low.appendChild(equal) low.appendChild(low_elem) subsup.appendChild(summand) subsup.appendChild(low) subsup.appendChild(up_elem) mrow = self.dom.createElement('mrow') mrow.appendChild(subsup) if len(str(e.function)) == 1: mrow.appendChild(self._print(e.function)) else: fence = self.dom.createElement('mfenced') fence.appendChild(self._print(e.function)) mrow.appendChild(fence) return mrow def _print_Symbol(self, sym, style='plain'): def join(items): if len(items) > 1: mrow = self.dom.createElement('mrow') for i, item in enumerate(items): if i > 0: mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(" ")) mrow.appendChild(mo) mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(item)) mrow.appendChild(mi) return mrow else: mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(items[0])) return mi # translate name, supers and subs to unicode characters def translate(s): if s in greek_unicode: return greek_unicode.get(s) else: return s name, supers, subs = split_super_sub(sym.name) name = translate(name) supers = [translate(sup) for sup in supers] subs = [translate(sub) for sub in subs] mname = self.dom.createElement('mi') mname.appendChild(self.dom.createTextNode(name)) if len(supers) == 0: if len(subs) == 0: x = mname else: x = self.dom.createElement('msub') x.appendChild(mname) x.appendChild(join(subs)) else: if len(subs) == 0: x = self.dom.createElement('msup') x.appendChild(mname) x.appendChild(join(supers)) else: x = self.dom.createElement('msubsup') x.appendChild(mname) x.appendChild(join(subs)) x.appendChild(join(supers)) # Set bold font? if style == 'bold': x.setAttribute('mathvariant', 'bold') return x def _print_MatrixSymbol(self, sym): return self._print_Symbol(sym, style=self._settings['mat_symbol_style']) _print_RandomSymbol = _print_Symbol def _print_conjugate(self, expr): enc = self.dom.createElement('menclose') enc.setAttribute('notation', 'top') enc.appendChild(self._print(expr.args[0])) return enc def _print_operator_after(self, op, expr): row = self.dom.createElement('mrow') row.appendChild(self.parenthesize(expr, PRECEDENCE["Func"])) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(op)) row.appendChild(mo) return row def _print_factorial(self, expr): return self._print_operator_after('!', expr.args[0]) def _print_factorial2(self, expr): return self._print_operator_after('!!', expr.args[0]) def _print_binomial(self, expr): brac = self.dom.createElement('mfenced') frac = self.dom.createElement('mfrac') frac.setAttribute('linethickness', '0') frac.appendChild(self._print(expr.args[0])) frac.appendChild(self._print(expr.args[1])) brac.appendChild(frac) return brac def _print_Pow(self, e): # Here we use root instead of power if the exponent is the # reciprocal of an integer if (e.exp.is_Rational and abs(e.exp.p) == 1 and e.exp.q != 1 and self._settings['root_notation']): if e.exp.q == 2: x = self.dom.createElement('msqrt') x.appendChild(self._print(e.base)) if e.exp.q != 2: x = self.dom.createElement('mroot') x.appendChild(self._print(e.base)) x.appendChild(self._print(e.exp.q)) if e.exp.p == -1: frac = self.dom.createElement('mfrac') frac.appendChild(self._print(1)) frac.appendChild(x) return frac else: return x if e.exp.is_Rational and e.exp.q != 1: if e.exp.is_negative: top = self.dom.createElement('mfrac') top.appendChild(self._print(1)) x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._get_printed_Rational(-e.exp, self._settings['fold_frac_powers'])) top.appendChild(x) return top else: x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._get_printed_Rational(e.exp, self._settings['fold_frac_powers'])) return x if e.exp.is_negative: top = self.dom.createElement('mfrac') top.appendChild(self._print(1)) if e.exp == -1: top.appendChild(self._print(e.base)) else: x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._print(-e.exp)) top.appendChild(x) return top x = self.dom.createElement('msup') x.appendChild(self.parenthesize(e.base, PRECEDENCE['Pow'])) x.appendChild(self._print(e.exp)) return x def _print_Number(self, e): x = self.dom.createElement(self.mathml_tag(e)) x.appendChild(self.dom.createTextNode(str(e))) return x def _print_AccumulationBounds(self, i): brac = self.dom.createElement('mfenced') brac.setAttribute('open', u'\u27e8') brac.setAttribute('close', u'\u27e9') brac.appendChild(self._print(i.min)) brac.appendChild(self._print(i.max)) return brac def _print_Derivative(self, e): if requires_partial(e): d = '∂' else: d = self.mathml_tag(e) # Determine denominator m = self.dom.createElement('mrow') dim = 0 # Total diff dimension, for numerator for sym, num in reversed(e.variable_count): dim += num if num >= 2: x = self.dom.createElement('msup') xx = self.dom.createElement('mo') xx.appendChild(self.dom.createTextNode(d)) x.appendChild(xx) x.appendChild(self._print(num)) else: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(d)) m.appendChild(x) y = self._print(sym) m.appendChild(y) mnum = self.dom.createElement('mrow') if dim >= 2: x = self.dom.createElement('msup') xx = self.dom.createElement('mo') xx.appendChild(self.dom.createTextNode(d)) x.appendChild(xx) x.appendChild(self._print(dim)) else: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(d)) mnum.appendChild(x) mrow = self.dom.createElement('mrow') frac = self.dom.createElement('mfrac') frac.appendChild(mnum) frac.appendChild(m) mrow.appendChild(frac) # Print function mrow.appendChild(self._print(e.expr)) return mrow def _print_Function(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mi') if self.mathml_tag(e) == 'log' and self._settings["ln_notation"]: x.appendChild(self.dom.createTextNode('ln')) else: x.appendChild(self.dom.createTextNode(self.mathml_tag(e))) y = self.dom.createElement('mfenced') for arg in e.args: y.appendChild(self._print(arg)) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_Float(self, expr): # Based off of that in StrPrinter dps = prec_to_dps(expr._prec) str_real = mlib.to_str(expr._mpf_, dps, strip_zeros=True) # Must always have a mul symbol (as 2.5 10^{20} just looks odd) # thus we use the number separator separator = self._settings['mul_symbol_mathml_numbers'] mrow = self.dom.createElement('mrow') if 'e' in str_real: (mant, exp) = str_real.split('e') if exp[0] == '+': exp = exp[1:] mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode(mant)) mrow.appendChild(mn) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode(separator)) mrow.appendChild(mo) msup = self.dom.createElement('msup') mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode("10")) msup.appendChild(mn) mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode(exp)) msup.appendChild(mn) mrow.appendChild(msup) return mrow elif str_real == "+inf": return self._print_Infinity(None) elif str_real == "-inf": return self._print_NegativeInfinity(None) else: mn = self.dom.createElement('mn') mn.appendChild(self.dom.createTextNode(str_real)) return mn def _print_polylog(self, expr): mrow = self.dom.createElement('mrow') m = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('Li')) m.appendChild(mi) m.appendChild(self._print(expr.args[0])) mrow.appendChild(m) brac = self.dom.createElement('mfenced') brac.appendChild(self._print(expr.args[1])) mrow.appendChild(brac) return mrow def _print_Basic(self, e): mrow = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) mrow.appendChild(mi) brac = self.dom.createElement('mfenced') for arg in e.args: brac.appendChild(self._print(arg)) mrow.appendChild(brac) return mrow def _print_Tuple(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') for arg in e.args: x.appendChild(self._print(arg)) mrow.appendChild(x) return mrow def _print_Interval(self, i): mrow = self.dom.createElement('mrow') brac = self.dom.createElement('mfenced') if i.start == i.end: # Most often, this type of Interval is converted to a FiniteSet brac.setAttribute('open', '{') brac.setAttribute('close', '}') brac.appendChild(self._print(i.start)) else: if i.left_open: brac.setAttribute('open', '(') else: brac.setAttribute('open', '[') if i.right_open: brac.setAttribute('close', ')') else: brac.setAttribute('close', ']') brac.appendChild(self._print(i.start)) brac.appendChild(self._print(i.end)) mrow.appendChild(brac) return mrow def _print_Abs(self, expr, exp=None): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') x.setAttribute('open', '|') x.setAttribute('close', '|') x.appendChild(self._print(expr.args[0])) mrow.appendChild(x) return mrow _print_Determinant = _print_Abs def _print_re_im(self, c, expr): mrow = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'fraktur') mi.appendChild(self.dom.createTextNode(c)) mrow.appendChild(mi) brac = self.dom.createElement('mfenced') brac.appendChild(self._print(expr)) mrow.appendChild(brac) return mrow def _print_re(self, expr, exp=None): return self._print_re_im('R', expr.args[0]) def _print_im(self, expr, exp=None): return self._print_re_im('I', expr.args[0]) def _print_AssocOp(self, e): mrow = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) mrow.appendChild(mi) for arg in e.args: mrow.appendChild(self._print(arg)) return mrow def _print_SetOp(self, expr, symbol): mrow = self.dom.createElement('mrow') mrow.appendChild(self._print(expr.args[0])) for arg in expr.args[1:]: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(symbol)) y = self._print(arg) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_Union(self, expr): return self._print_SetOp(expr, '∪') def _print_Intersection(self, expr): return self._print_SetOp(expr, '∩') def _print_Complement(self, expr): return self._print_SetOp(expr, '∖') def _print_SymmetricDifference(self, expr): return self._print_SetOp(expr, '∆') def _print_FiniteSet(self, s): return self._print_set(s.args) def _print_set(self, s): items = sorted(s, key=default_sort_key) brac = self.dom.createElement('mfenced') brac.setAttribute('open', '{') brac.setAttribute('close', '}') for item in items: brac.appendChild(self._print(item)) return brac _print_frozenset = _print_set def _print_LogOp(self, args, symbol): mrow = self.dom.createElement('mrow') if args[0].is_Boolean and not args[0].is_Not: brac = self.dom.createElement('mfenced') brac.appendChild(self._print(args[0])) mrow.appendChild(brac) else: mrow.appendChild(self._print(args[0])) for arg in args[1:]: x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(symbol)) if arg.is_Boolean and not arg.is_Not: y = self.dom.createElement('mfenced') y.appendChild(self._print(arg)) else: y = self._print(arg) mrow.appendChild(x) mrow.appendChild(y) return mrow def _print_BasisDependent(self, expr): from sympy.vector import Vector if expr == expr.zero: # Not clear if this is ever called return self._print(expr.zero) if isinstance(expr, Vector): items = expr.separate().items() else: items = [(0, expr)] mrow = self.dom.createElement('mrow') for system, vect in items: inneritems = list(vect.components.items()) inneritems.sort(key = lambda x:x[0].__str__()) for i, (k, v) in enumerate(inneritems): if v == 1: if i: # No + for first item mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('+')) mrow.appendChild(mo) mrow.appendChild(self._print(k)) elif v == -1: mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('-')) mrow.appendChild(mo) mrow.appendChild(self._print(k)) else: if i: # No + for first item mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('+')) mrow.appendChild(mo) mbrac = self.dom.createElement('mfenced') mbrac.appendChild(self._print(v)) mrow.appendChild(mbrac) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('⁢')) mrow.appendChild(mo) mrow.appendChild(self._print(k)) return mrow def _print_And(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '∧') def _print_Or(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '∨') def _print_Xor(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '⊻') def _print_Implies(self, expr): return self._print_LogOp(expr.args, '⇒') def _print_Equivalent(self, expr): args = sorted(expr.args, key=default_sort_key) return self._print_LogOp(args, '⇔') def _print_Not(self, e): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('¬')) mrow.appendChild(mo) if (e.args[0].is_Boolean): x = self.dom.createElement('mfenced') x.appendChild(self._print(e.args[0])) else: x = self._print(e.args[0]) mrow.appendChild(x) return mrow def _print_bool(self, e): mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) return mi _print_BooleanTrue = _print_bool _print_BooleanFalse = _print_bool def _print_NoneType(self, e): mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(self.mathml_tag(e))) return mi def _print_Range(self, s): dots = u"\u2026" brac = self.dom.createElement('mfenced') brac.setAttribute('open', '{') brac.setAttribute('close', '}') if s.start.is_infinite: printset = dots, s[-1] - s.step, s[-1] elif s.stop.is_infinite: it = iter(s) printset = next(it), next(it), dots elif len(s) > 4: it = iter(s) printset = next(it), next(it), dots, s[-1] else: printset = tuple(s) for el in printset: if el == dots: mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode(dots)) brac.appendChild(mi) else: brac.appendChild(self._print(el)) return brac def _hprint_variadic_function(self, expr): args = sorted(expr.args, key=default_sort_key) mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode((str(expr.func)).lower())) mrow.appendChild(mo) brac = self.dom.createElement('mfenced') for symbol in args: brac.appendChild(self._print(symbol)) mrow.appendChild(brac) return mrow _print_Min = _print_Max = _hprint_variadic_function def _print_exp(self, expr): msup = self.dom.createElement('msup') msup.appendChild(self._print_Exp1(None)) msup.appendChild(self._print(expr.args[0])) return msup def _print_Relational(self, e): mrow = self.dom.createElement('mrow') mrow.appendChild(self._print(e.lhs)) x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode(self.mathml_tag(e))) mrow.appendChild(x) mrow.appendChild(self._print(e.rhs)) return mrow def _print_int(self, p): dom_element = self.dom.createElement(self.mathml_tag(p)) dom_element.appendChild(self.dom.createTextNode(str(p))) return dom_element def _print_BaseScalar(self, e): msub = self.dom.createElement('msub') index, system = e._id mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._variable_names[index])) msub.appendChild(mi) mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._name)) msub.appendChild(mi) return msub def _print_BaseVector(self, e): msub = self.dom.createElement('msub') index, system = e._id mover = self.dom.createElement('mover') mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._vector_names[index])) mover.appendChild(mi) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('^')) mover.appendChild(mo) msub.appendChild(mover) mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode(system._name)) msub.appendChild(mi) return msub def _print_VectorZero(self, e): mover = self.dom.createElement('mover') mi = self.dom.createElement('mi') mi.setAttribute('mathvariant', 'bold') mi.appendChild(self.dom.createTextNode("0")) mover.appendChild(mi) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('^')) mover.appendChild(mo) return mover def _print_Cross(self, expr): mrow = self.dom.createElement('mrow') vec1 = expr._expr1 vec2 = expr._expr2 mrow.appendChild(self.parenthesize(vec1, PRECEDENCE['Mul'])) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('×')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(vec2, PRECEDENCE['Mul'])) return mrow def _print_Curl(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∇')) mrow.appendChild(mo) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('×')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Divergence(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∇')) mrow.appendChild(mo) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('·')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Dot(self, expr): mrow = self.dom.createElement('mrow') vec1 = expr._expr1 vec2 = expr._expr2 mrow.appendChild(self.parenthesize(vec1, PRECEDENCE['Mul'])) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('·')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(vec2, PRECEDENCE['Mul'])) return mrow def _print_Gradient(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∇')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Laplacian(self, expr): mrow = self.dom.createElement('mrow') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∆')) mrow.appendChild(mo) mrow.appendChild(self.parenthesize(expr._expr, PRECEDENCE['Mul'])) return mrow def _print_Integers(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℤ')) return x def _print_Complexes(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℂ')) return x def _print_Reals(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℝ')) return x def _print_Naturals(self, e): x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℕ')) return x def _print_Naturals0(self, e): sub = self.dom.createElement('msub') x = self.dom.createElement('mi') x.setAttribute('mathvariant', 'normal') x.appendChild(self.dom.createTextNode('ℕ')) sub.appendChild(x) sub.appendChild(self._print(S.Zero)) return sub def _print_SingularityFunction(self, expr): shift = expr.args[0] - expr.args[1] power = expr.args[2] sup = self.dom.createElement('msup') brac = self.dom.createElement('mfenced') brac.setAttribute('open', u'\u27e8') brac.setAttribute('close', u'\u27e9') brac.appendChild(self._print(shift)) sup.appendChild(brac) sup.appendChild(self._print(power)) return sup def _print_NaN(self, e): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('NaN')) return x def _print_bernoulli(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('B')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub _print_bell = _print_bernoulli def _print_catalan(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('C')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_fibonacci(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('F')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_lucas(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('L')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_tribonacci(self, e): sub = self.dom.createElement('msub') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('T')) sub.appendChild(mi) sub.appendChild(self._print(e.args[0])) return sub def _print_ComplexInfinity(self, e): x = self.dom.createElement('mover') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∞')) x.appendChild(mo) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('~')) x.appendChild(mo) return x def _print_EmptySet(self, e): x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('∅')) return x def _print_UniversalSet(self, e): x = self.dom.createElement('mo') x.appendChild(self.dom.createTextNode('𝕌')) return x def _print_Adjoint(self, expr): from sympy.matrices import MatrixSymbol mat = expr.arg sup = self.dom.createElement('msup') if not isinstance(mat, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(mat)) sup.appendChild(brac) else: sup.appendChild(self._print(mat)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('†')) sup.appendChild(mo) return sup def _print_Transpose(self, expr): from sympy.matrices import MatrixSymbol mat = expr.arg sup = self.dom.createElement('msup') if not isinstance(mat, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(mat)) sup.appendChild(brac) else: sup.appendChild(self._print(mat)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('T')) sup.appendChild(mo) return sup def _print_Inverse(self, expr): from sympy.matrices import MatrixSymbol mat = expr.arg sup = self.dom.createElement('msup') if not isinstance(mat, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(mat)) sup.appendChild(brac) else: sup.appendChild(self._print(mat)) sup.appendChild(self._print(-1)) return sup def _print_MatMul(self, expr): from sympy import MatMul x = self.dom.createElement('mrow') args = expr.args if isinstance(args[0], Mul): args = args[0].as_ordered_factors() + list(args[1:]) else: args = list(args) if isinstance(expr, MatMul) and _coeff_isneg(expr): if args[0] == -1: args = args[1:] else: args[0] = -args[0] mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('-')) x.appendChild(mo) for arg in args[:-1]: x.appendChild(self.parenthesize(arg, precedence_traditional(expr), False)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('⁢')) x.appendChild(mo) x.appendChild(self.parenthesize(args[-1], precedence_traditional(expr), False)) return x def _print_MatPow(self, expr): from sympy.matrices import MatrixSymbol base, exp = expr.base, expr.exp sup = self.dom.createElement('msup') if not isinstance(base, MatrixSymbol): brac = self.dom.createElement('mfenced') brac.appendChild(self._print(base)) sup.appendChild(brac) else: sup.appendChild(self._print(base)) sup.appendChild(self._print(exp)) return sup def _print_HadamardProduct(self, expr): x = self.dom.createElement('mrow') args = expr.args for arg in args[:-1]: x.appendChild( self.parenthesize(arg, precedence_traditional(expr), False)) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('∘')) x.appendChild(mo) x.appendChild( self.parenthesize(args[-1], precedence_traditional(expr), False)) return x def _print_ZeroMatrix(self, Z): x = self.dom.createElement('mn') x.appendChild(self.dom.createTextNode('&#x1D7D8')) return x def _print_Identity(self, I): x = self.dom.createElement('mi') x.appendChild(self.dom.createTextNode('𝕀')) return x def _print_floor(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') x.setAttribute('open', u'\u230A') x.setAttribute('close', u'\u230B') x.appendChild(self._print(e.args[0])) mrow.appendChild(x) return mrow def _print_ceiling(self, e): mrow = self.dom.createElement('mrow') x = self.dom.createElement('mfenced') x.setAttribute('open', u'\u2308') x.setAttribute('close', u'\u2309') x.appendChild(self._print(e.args[0])) mrow.appendChild(x) return mrow def _print_Lambda(self, e): x = self.dom.createElement('mfenced') mrow = self.dom.createElement('mrow') symbols = e.args[0] if len(symbols) == 1: symbols = self._print(symbols[0]) else: symbols = self._print(symbols) mrow.appendChild(symbols) mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('↦')) mrow.appendChild(mo) mrow.appendChild(self._print(e.args[1])) x.appendChild(mrow) return x def _print_tuple(self, e): x = self.dom.createElement('mfenced') for i in e: x.appendChild(self._print(i)) return x def _print_IndexedBase(self, e): return self._print(e.label) def _print_Indexed(self, e): x = self.dom.createElement('msub') x.appendChild(self._print(e.base)) if len(e.indices) == 1: x.appendChild(self._print(e.indices[0])) return x x.appendChild(self._print(e.indices)) return x def _print_MatrixElement(self, e): x = self.dom.createElement('msub') x.appendChild(self.parenthesize(e.parent, PRECEDENCE["Atom"], strict = True)) brac = self.dom.createElement('mfenced') brac.setAttribute("open", "") brac.setAttribute("close", "") for i in e.indices: brac.appendChild(self._print(i)) x.appendChild(brac) return x def _print_elliptic_f(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('𝖥')) x.appendChild(mi) y = self.dom.createElement('mfenced') y.setAttribute("separators", "|") for i in e.args: y.appendChild(self._print(i)) x.appendChild(y) return x def _print_elliptic_e(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('𝖤')) x.appendChild(mi) y = self.dom.createElement('mfenced') y.setAttribute("separators", "|") for i in e.args: y.appendChild(self._print(i)) x.appendChild(y) return x def _print_elliptic_pi(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('𝛱')) x.appendChild(mi) y = self.dom.createElement('mfenced') if len(e.args) == 2: y.setAttribute("separators", "|") else: y.setAttribute("separators", ";|") for i in e.args: y.appendChild(self._print(i)) x.appendChild(y) return x def _print_Ei(self, e): x = self.dom.createElement('mrow') mi = self.dom.createElement('mi') mi.appendChild(self.dom.createTextNode('Ei')) x.appendChild(mi) x.appendChild(self._print(e.args)) return x def _print_expint(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('E')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_jacobi(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('P')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:3])) x.appendChild(y) x.appendChild(self._print(e.args[3:])) return x def _print_gegenbauer(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('C')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:2])) x.appendChild(y) x.appendChild(self._print(e.args[2:])) return x def _print_chebyshevt(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('T')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_chebyshevu(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('U')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_legendre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('P')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_assoc_legendre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('P')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:2])) x.appendChild(y) x.appendChild(self._print(e.args[2:])) return x def _print_laguerre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('L')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def _print_assoc_laguerre(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msubsup') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('L')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) y.appendChild(self._print(e.args[1:2])) x.appendChild(y) x.appendChild(self._print(e.args[2:])) return x def _print_hermite(self, e): x = self.dom.createElement('mrow') y = self.dom.createElement('msub') mo = self.dom.createElement('mo') mo.appendChild(self.dom.createTextNode('H')) y.appendChild(mo) y.appendChild(self._print(e.args[0])) x.appendChild(y) x.appendChild(self._print(e.args[1:])) return x def mathml(expr, printer='content', **settings): """Returns the MathML representation of expr. If printer is presentation then prints Presentation MathML else prints content MathML. """ if printer == 'presentation': return MathMLPresentationPrinter(settings).doprint(expr) else: return MathMLContentPrinter(settings).doprint(expr) def print_mathml(expr, printer='content', **settings): """ Prints a pretty representation of the MathML code for expr. If printer is presentation then prints Presentation MathML else prints content MathML. Examples ======== >>> ## >>> from sympy.printing.mathml import print_mathml >>> from sympy.abc import x >>> print_mathml(x+1) #doctest: +NORMALIZE_WHITESPACE <apply> <plus/> <ci>x</ci> <cn>1</cn> </apply> >>> print_mathml(x+1, printer='presentation') <mrow> <mi>x</mi> <mo>+</mo> <mn>1</mn> </mrow> """ if printer == 'presentation': s = MathMLPresentationPrinter(settings) else: s = MathMLContentPrinter(settings) xml = s._print(sympify(expr)) s.apply_patch() pretty_xml = xml.toprettyxml() s.restore_patch() print(pretty_xml) # For backward compatibility MathMLPrinter = MathMLContentPrinter

4a9c327ae46a20766719575a47f423463e88e9d4b4bb2e478e6063fa365db895

from __future__ import print_function, division from functools import wraps from sympy.core import Add, Mul, Pow, S, sympify, Float from sympy.core.basic import Basic from sympy.core.compatibility import default_sort_key, string_types from sympy.core.function import Lambda from sympy.core.mul import _keep_coeff from sympy.core.symbol import Symbol from sympy.printing.str import StrPrinter from sympy.printing.precedence import precedence # Backwards compatibility from sympy.codegen.ast import Assignment class requires(object): """ Decorator for registering requirements on print methods. """ def __init__(self, **kwargs): self._req = kwargs def __call__(self, method): def _method_wrapper(self_, *args, **kwargs): for k, v in self._req.items(): getattr(self_, k).update(v) return method(self_, *args, **kwargs) return wraps(method)(_method_wrapper) class AssignmentError(Exception): """ Raised if an assignment variable for a loop is missing. """ pass class CodePrinter(StrPrinter): """ The base class for code-printing subclasses. """ _operators = { 'and': '&&', 'or': '||', 'not': '!', } _default_settings = { 'order': None, 'full_prec': 'auto', 'error_on_reserved': False, 'reserved_word_suffix': '_', 'human': True, 'inline': False, 'allow_unknown_functions': False, } def __init__(self, settings=None): super(CodePrinter, self).__init__(settings=settings) if not hasattr(self, 'reserved_words'): self.reserved_words = set() def doprint(self, expr, assign_to=None): """ Print the expression as code. Parameters ---------- expr : Expression The expression to be printed. assign_to : Symbol, MatrixSymbol, or string (optional) If provided, the printed code will set the expression to a variable with name ``assign_to``. """ from sympy.matrices.expressions.matexpr import MatrixSymbol if isinstance(assign_to, string_types): if expr.is_Matrix: assign_to = MatrixSymbol(assign_to, *expr.shape) else: assign_to = Symbol(assign_to) elif not isinstance(assign_to, (Basic, type(None))): raise TypeError("{0} cannot assign to object of type {1}".format( type(self).__name__, type(assign_to))) if assign_to: expr = Assignment(assign_to, expr) else: # _sympify is not enough b/c it errors on iterables expr = sympify(expr) # keep a set of expressions that are not strictly translatable to Code # and number constants that must be declared and initialized self._not_supported = set() self._number_symbols = set() lines = self._print(expr).splitlines() # format the output if self._settings["human"]: frontlines = [] if self._not_supported: frontlines.append(self._get_comment( "Not supported in {0}:".format(self.language))) for expr in sorted(self._not_supported, key=str): frontlines.append(self._get_comment(type(expr).__name__)) for name, value in sorted(self._number_symbols, key=str): frontlines.append(self._declare_number_const(name, value)) lines = frontlines + lines lines = self._format_code(lines) result = "\n".join(lines) else: lines = self._format_code(lines) num_syms = set([(k, self._print(v)) for k, v in self._number_symbols]) result = (num_syms, self._not_supported, "\n".join(lines)) self._not_supported = set() self._number_symbols = set() return result def _doprint_loops(self, expr, assign_to=None): # Here we print an expression that contains Indexed objects, they # correspond to arrays in the generated code. The low-level implementation # involves looping over array elements and possibly storing results in temporary # variables or accumulate it in the assign_to object. if self._settings.get('contract', True): from sympy.tensor import get_contraction_structure # Setup loops over non-dummy indices -- all terms need these indices = self._get_expression_indices(expr, assign_to) # Setup loops over dummy indices -- each term needs separate treatment dummies = get_contraction_structure(expr) else: indices = [] dummies = {None: (expr,)} openloop, closeloop = self._get_loop_opening_ending(indices) # terms with no summations first if None in dummies: text = StrPrinter.doprint(self, Add(*dummies[None])) else: # If all terms have summations we must initialize array to Zero text = StrPrinter.doprint(self, 0) # skip redundant assignments (where lhs == rhs) lhs_printed = self._print(assign_to) lines = [] if text != lhs_printed: lines.extend(openloop) if assign_to is not None: text = self._get_statement("%s = %s" % (lhs_printed, text)) lines.append(text) lines.extend(closeloop) # then terms with summations for d in dummies: if isinstance(d, tuple): indices = self._sort_optimized(d, expr) openloop_d, closeloop_d = self._get_loop_opening_ending( indices) for term in dummies[d]: if term in dummies and not ([list(f.keys()) for f in dummies[term]] == [[None] for f in dummies[term]]): # If one factor in the term has it's own internal # contractions, those must be computed first. # (temporary variables?) raise NotImplementedError( "FIXME: no support for contractions in factor yet") else: # We need the lhs expression as an accumulator for # the loops, i.e # # for (int d=0; d < dim; d++){ # lhs[] = lhs[] + term[][d] # } ^.................. the accumulator # # We check if the expression already contains the # lhs, and raise an exception if it does, as that # syntax is currently undefined. FIXME: What would be # a good interpretation? if assign_to is None: raise AssignmentError( "need assignment variable for loops") if term.has(assign_to): raise ValueError("FIXME: lhs present in rhs,\ this is undefined in CodePrinter") lines.extend(openloop) lines.extend(openloop_d) text = "%s = %s" % (lhs_printed, StrPrinter.doprint( self, assign_to + term)) lines.append(self._get_statement(text)) lines.extend(closeloop_d) lines.extend(closeloop) return "\n".join(lines) def _get_expression_indices(self, expr, assign_to): from sympy.tensor import get_indices rinds, junk = get_indices(expr) linds, junk = get_indices(assign_to) # support broadcast of scalar if linds and not rinds: rinds = linds if rinds != linds: raise ValueError("lhs indices must match non-dummy" " rhs indices in %s" % expr) return self._sort_optimized(rinds, assign_to) def _sort_optimized(self, indices, expr): from sympy.tensor.indexed import Indexed if not indices: return [] # determine optimized loop order by giving a score to each index # the index with the highest score are put in the innermost loop. score_table = {} for i in indices: score_table[i] = 0 arrays = expr.atoms(Indexed) for arr in arrays: for p, ind in enumerate(arr.indices): try: score_table[ind] += self._rate_index_position(p) except KeyError: pass return sorted(indices, key=lambda x: score_table[x]) def _rate_index_position(self, p): """function to calculate score based on position among indices This method is used to sort loops in an optimized order, see CodePrinter._sort_optimized() """ raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _get_statement(self, codestring): """Formats a codestring with the proper line ending.""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _get_comment(self, text): """Formats a text string as a comment.""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _declare_number_const(self, name, value): """Declare a numeric constant at the top of a function""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _format_code(self, lines): """Take in a list of lines of code, and format them accordingly. This may include indenting, wrapping long lines, etc...""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _get_loop_opening_ending(self, indices): """Returns a tuple (open_lines, close_lines) containing lists of codelines""" raise NotImplementedError("This function must be implemented by " "subclass of CodePrinter.") def _print_Dummy(self, expr): if expr.name.startswith('Dummy_'): return '_' + expr.name else: return '%s_%d' % (expr.name, expr.dummy_index) def _print_CodeBlock(self, expr): return '\n'.join([self._print(i) for i in expr.args]) def _print_String(self, string): return str(string) def _print_QuotedString(self, arg): return '"%s"' % arg.text def _print_Comment(self, string): return self._get_comment(str(string)) def _print_Assignment(self, expr): from sympy.functions.elementary.piecewise import Piecewise from sympy.matrices.expressions.matexpr import MatrixSymbol from sympy.tensor.indexed import IndexedBase lhs = expr.lhs rhs = expr.rhs # We special case assignments that take multiple lines if isinstance(expr.rhs, Piecewise): # Here we modify Piecewise so each expression is now # an Assignment, and then continue on the print. expressions = [] conditions = [] for (e, c) in rhs.args: expressions.append(Assignment(lhs, e)) conditions.append(c) temp = Piecewise(*zip(expressions, conditions)) return self._print(temp) elif isinstance(lhs, MatrixSymbol): # Here we form an Assignment for each element in the array, # printing each one. lines = [] for (i, j) in self._traverse_matrix_indices(lhs): temp = Assignment(lhs[i, j], rhs[i, j]) code0 = self._print(temp) lines.append(code0) return "\n".join(lines) elif self._settings.get("contract", False) and (lhs.has(IndexedBase) or rhs.has(IndexedBase)): # Here we check if there is looping to be done, and if so # print the required loops. return self._doprint_loops(rhs, lhs) else: lhs_code = self._print(lhs) rhs_code = self._print(rhs) return self._get_statement("%s = %s" % (lhs_code, rhs_code)) def _print_AugmentedAssignment(self, expr): lhs_code = self._print(expr.lhs) rhs_code = self._print(expr.rhs) return self._get_statement("{0} {1} {2}".format( *map(lambda arg: self._print(arg), [lhs_code, expr.op, rhs_code]))) def _print_FunctionCall(self, expr): return '%s(%s)' % ( expr.name, ', '.join(map(lambda arg: self._print(arg), expr.function_args))) def _print_Variable(self, expr): return self._print(expr.symbol) def _print_Statement(self, expr): arg, = expr.args return self._get_statement(self._print(arg)) def _print_Symbol(self, expr): name = super(CodePrinter, self)._print_Symbol(expr) if name in self.reserved_words: if self._settings['error_on_reserved']: msg = ('This expression includes the symbol "{}" which is a ' 'reserved keyword in this language.') raise ValueError(msg.format(name)) return name + self._settings['reserved_word_suffix'] else: return name def _print_Function(self, expr): if expr.func.__name__ in self.known_functions: cond_func = self.known_functions[expr.func.__name__] func = None if isinstance(cond_func, string_types): func = cond_func else: for cond, func in cond_func: if cond(*expr.args): break if func is not None: try: return func(*[self.parenthesize(item, 0) for item in expr.args]) except TypeError: return "%s(%s)" % (func, self.stringify(expr.args, ", ")) elif hasattr(expr, '_imp_') and isinstance(expr._imp_, Lambda): # inlined function return self._print(expr._imp_(*expr.args)) elif expr.is_Function and self._settings.get('allow_unknown_functions', False): return '%s(%s)' % (self._print(expr.func), ', '.join(map(self._print, expr.args))) else: return self._print_not_supported(expr) _print_Expr = _print_Function def _print_NumberSymbol(self, expr): if self._settings.get("inline", False): return self._print(Float(expr.evalf(self._settings["precision"]))) else: # A Number symbol that is not implemented here or with _printmethod # is registered and evaluated self._number_symbols.add((expr, Float(expr.evalf(self._settings["precision"])))) return str(expr) def _print_Catalan(self, expr): return self._print_NumberSymbol(expr) def _print_EulerGamma(self, expr): return self._print_NumberSymbol(expr) def _print_GoldenRatio(self, expr): return self._print_NumberSymbol(expr) def _print_TribonacciConstant(self, expr): return self._print_NumberSymbol(expr) def _print_Exp1(self, expr): return self._print_NumberSymbol(expr) def _print_Pi(self, expr): return self._print_NumberSymbol(expr) def _print_And(self, expr): PREC = precedence(expr) return (" %s " % self._operators['and']).join(self.parenthesize(a, PREC) for a in sorted(expr.args, key=default_sort_key)) def _print_Or(self, expr): PREC = precedence(expr) return (" %s " % self._operators['or']).join(self.parenthesize(a, PREC) for a in sorted(expr.args, key=default_sort_key)) def _print_Xor(self, expr): if self._operators.get('xor') is None: return self._print_not_supported(expr) PREC = precedence(expr) return (" %s " % self._operators['xor']).join(self.parenthesize(a, PREC) for a in expr.args) def _print_Equivalent(self, expr): if self._operators.get('equivalent') is None: return self._print_not_supported(expr) PREC = precedence(expr) return (" %s " % self._operators['equivalent']).join(self.parenthesize(a, PREC) for a in expr.args) def _print_Not(self, expr): PREC = precedence(expr) return self._operators['not'] + self.parenthesize(expr.args[0], PREC) def _print_Mul(self, expr): prec = precedence(expr) c, e = expr.as_coeff_Mul() if c < 0: expr = _keep_coeff(-c, e) sign = "-" else: sign = "" a = [] # items in the numerator b = [] # items that are in the denominator (if any) pow_paren = [] # Will collect all pow with more than one base element and exp = -1 if self.order not in ('old', 'none'): args = expr.as_ordered_factors() else: # use make_args in case expr was something like -x -> x args = Mul.make_args(expr) # Gather args for numerator/denominator for item in args: if item.is_commutative and item.is_Pow and item.exp.is_Rational and item.exp.is_negative: if item.exp != -1: b.append(Pow(item.base, -item.exp, evaluate=False)) else: if len(item.args[0].args) != 1 and isinstance(item.base, Mul): # To avoid situations like #14160 pow_paren.append(item) b.append(Pow(item.base, -item.exp)) else: a.append(item) a = a or [S.One] a_str = [self.parenthesize(x, prec) for x in a] b_str = [self.parenthesize(x, prec) for x in b] # To parenthesize Pow with exp = -1 and having more than one Symbol for item in pow_paren: if item.base in b: b_str[b.index(item.base)] = "(%s)" % b_str[b.index(item.base)] if not b: return sign + '*'.join(a_str) elif len(b) == 1: return sign + '*'.join(a_str) + "/" + b_str[0] else: return sign + '*'.join(a_str) + "/(%s)" % '*'.join(b_str) def _print_not_supported(self, expr): self._not_supported.add(expr) return self.emptyPrinter(expr) # The following can not be simply translated into C or Fortran _print_Basic = _print_not_supported _print_ComplexInfinity = _print_not_supported _print_Derivative = _print_not_supported _print_ExprCondPair = _print_not_supported _print_GeometryEntity = _print_not_supported _print_Infinity = _print_not_supported _print_Integral = _print_not_supported _print_Interval = _print_not_supported _print_AccumulationBounds = _print_not_supported _print_Limit = _print_not_supported _print_Matrix = _print_not_supported _print_ImmutableMatrix = _print_not_supported _print_ImmutableDenseMatrix = _print_not_supported _print_MutableDenseMatrix = _print_not_supported _print_MatrixBase = _print_not_supported _print_DeferredVector = _print_not_supported _print_NaN = _print_not_supported _print_NegativeInfinity = _print_not_supported _print_Order = _print_not_supported _print_RootOf = _print_not_supported _print_RootsOf = _print_not_supported _print_RootSum = _print_not_supported _print_SparseMatrix = _print_not_supported _print_MutableSparseMatrix = _print_not_supported _print_ImmutableSparseMatrix = _print_not_supported _print_Uniform = _print_not_supported _print_Unit = _print_not_supported _print_Wild = _print_not_supported _print_WildFunction = _print_not_supported

84867b6d09f7a0b62c4ed4ecf063df960f5f1e5df9a6d7d1a3ad55ca8b81e9f9

from __future__ import print_function, division from sympy.core.compatibility import range, is_sequence from sympy.external import import_module from sympy.printing.printer import Printer import sympy from functools import partial theano = import_module('theano') if theano: ts = theano.scalar tt = theano.tensor from theano.sandbox import linalg as tlinalg mapping = { sympy.Add: tt.add, sympy.Mul: tt.mul, sympy.Abs: tt.abs_, sympy.sign: tt.sgn, sympy.ceiling: tt.ceil, sympy.floor: tt.floor, sympy.log: tt.log, sympy.exp: tt.exp, sympy.sqrt: tt.sqrt, sympy.cos: tt.cos, sympy.acos: tt.arccos, sympy.sin: tt.sin, sympy.asin: tt.arcsin, sympy.tan: tt.tan, sympy.atan: tt.arctan, sympy.atan2: tt.arctan2, sympy.cosh: tt.cosh, sympy.acosh: tt.arccosh, sympy.sinh: tt.sinh, sympy.asinh: tt.arcsinh, sympy.tanh: tt.tanh, sympy.atanh: tt.arctanh, sympy.re: tt.real, sympy.im: tt.imag, sympy.arg: tt.angle, sympy.erf: tt.erf, sympy.gamma: tt.gamma, sympy.loggamma: tt.gammaln, sympy.Pow: tt.pow, sympy.Eq: tt.eq, sympy.StrictGreaterThan: tt.gt, sympy.StrictLessThan: tt.lt, sympy.LessThan: tt.le, sympy.GreaterThan: tt.ge, sympy.And: tt.and_, sympy.Or: tt.or_, sympy.Max: tt.maximum, # Sympy accept >2 inputs, Theano only 2 sympy.Min: tt.minimum, # Sympy accept >2 inputs, Theano only 2 sympy.conjugate: tt.conj, sympy.numbers.ImaginaryUnit: lambda:tt.complex(0,1), # Matrices sympy.MatAdd: tt.Elemwise(ts.add), sympy.HadamardProduct: tt.Elemwise(ts.mul), sympy.Trace: tlinalg.trace, sympy.Determinant : tlinalg.det, sympy.Inverse: tlinalg.matrix_inverse, sympy.Transpose: tt.DimShuffle((False, False), [1, 0]), } class TheanoPrinter(Printer): """ Code printer which creates Theano symbolic expression graphs. Parameters ========== cache : dict Cache dictionary to use (see :attr:`cache`). If None (default) will use the global cache. To create a printer which does not depend on or alter global state pass an empty dictionary. Note: the dictionary is not copied on initialization of the printer and will be updated in-place, so using the same dict object when creating multiple printers or making multiple calls to :func:`.theano_code` or :func:`.theano_function` means the cache is shared between all these applications. Attributes ========== cache : dict A cache of Theano variables which have been created for Sympy symbol-like objects (e.g. :class:`sympy.core.symbol.Symbol` or :class:`sympy.matrices.expressions.MatrixSymbol`). This is used to ensure that all references to a given symbol in an expression (or multiple expressions) are printed as the same Theano variable, which is created only once. Symbols are differentiated only by name and type. The format of the cache's contents should be considered opaque to the user. """ printmethod = "_theano" def __init__(self, *args, **kwargs): self.cache = kwargs.pop('cache', dict()) super(TheanoPrinter, self).__init__(*args, **kwargs) def _get_key(self, s, name=None, dtype=None, broadcastable=None): """ Get the cache key for a Sympy object. Parameters ========== s : sympy.core.basic.Basic Sympy object to get key for. name : str Name of object, if it does not have a ``name`` attribute. """ if name is None: name = s.name return (name, type(s), s.args, dtype, broadcastable) def _get_or_create(self, s, name=None, dtype=None, broadcastable=None): """ Get the Theano variable for a Sympy symbol from the cache, or create it if it does not exist. """ # Defaults if name is None: name = s.name if dtype is None: dtype = 'floatX' if broadcastable is None: broadcastable = () key = self._get_key(s, name, dtype=dtype, broadcastable=broadcastable) if key in self.cache: return self.cache[key] value = tt.tensor(name=name, dtype=dtype, broadcastable=broadcastable) self.cache[key] = value return value def _print_Symbol(self, s, **kwargs): dtype = kwargs.get('dtypes', {}).get(s) bc = kwargs.get('broadcastables', {}).get(s) return self._get_or_create(s, dtype=dtype, broadcastable=bc) def _print_AppliedUndef(self, s, **kwargs): name = str(type(s)) + '_' + str(s.args[0]) dtype = kwargs.get('dtypes', {}).get(s) bc = kwargs.get('broadcastables', {}).get(s) return self._get_or_create(s, name=name, dtype=dtype, broadcastable=bc) def _print_Basic(self, expr, **kwargs): op = mapping[type(expr)] children = [self._print(arg, **kwargs) for arg in expr.args] return op(*children) def _print_Number(self, n, **kwargs): # Integers already taken care of below, interpret as float return float(n.evalf()) def _print_MatrixSymbol(self, X, **kwargs): dtype = kwargs.get('dtypes', {}).get(X) return self._get_or_create(X, dtype=dtype, broadcastable=(None, None)) def _print_DenseMatrix(self, X, **kwargs): if not hasattr(tt, 'stacklists'): raise NotImplementedError( "Matrix translation not yet supported in this version of Theano") return tt.stacklists([ [self._print(arg, **kwargs) for arg in L] for L in X.tolist() ]) _print_ImmutableMatrix = _print_ImmutableDenseMatrix = _print_DenseMatrix def _print_MatMul(self, expr, **kwargs): children = [self._print(arg, **kwargs) for arg in expr.args] result = children[0] for child in children[1:]: result = tt.dot(result, child) return result def _print_MatPow(self, expr, **kwargs): children = [self._print(arg, **kwargs) for arg in expr.args] result = 1 if isinstance(children[1], int) and children[1] > 0: for i in range(children[1]): result = tt.dot(result, children[0]) else: raise NotImplementedError('''Only non-negative integer powers of matrices can be handled by Theano at the moment''') return result def _print_MatrixSlice(self, expr, **kwargs): parent = self._print(expr.parent, **kwargs) rowslice = self._print(slice(*expr.rowslice), **kwargs) colslice = self._print(slice(*expr.colslice), **kwargs) return parent[rowslice, colslice] def _print_BlockMatrix(self, expr, **kwargs): nrows, ncols = expr.blocks.shape blocks = [[self._print(expr.blocks[r, c], **kwargs) for c in range(ncols)] for r in range(nrows)] return tt.join(0, *[tt.join(1, *row) for row in blocks]) def _print_slice(self, expr, **kwargs): return slice(*[self._print(i, **kwargs) if isinstance(i, sympy.Basic) else i for i in (expr.start, expr.stop, expr.step)]) def _print_Pi(self, expr, **kwargs): return 3.141592653589793 def _print_Piecewise(self, expr, **kwargs): import numpy as np e, cond = expr.args[0].args # First condition and corresponding value # Print conditional expression and value for first condition p_cond = self._print(cond, **kwargs) p_e = self._print(e, **kwargs) # One condition only if len(expr.args) == 1: # Return value if condition else NaN return tt.switch(p_cond, p_e, np.nan) # Return value_1 if condition_1 else evaluate remaining conditions p_remaining = self._print(sympy.Piecewise(*expr.args[1:]), **kwargs) return tt.switch(p_cond, p_e, p_remaining) def _print_Rational(self, expr, **kwargs): return tt.true_div(self._print(expr.p, **kwargs), self._print(expr.q, **kwargs)) def _print_Integer(self, expr, **kwargs): return expr.p def _print_factorial(self, expr, **kwargs): return self._print(sympy.gamma(expr.args[0] + 1), **kwargs) def _print_Derivative(self, deriv, **kwargs): rv = self._print(deriv.expr, **kwargs) for var in deriv.variables: var = self._print(var, **kwargs) rv = tt.Rop(rv, var, tt.ones_like(var)) return rv def emptyPrinter(self, expr): return expr def doprint(self, expr, dtypes=None, broadcastables=None): """ Convert a Sympy expression to a Theano graph variable. The ``dtypes`` and ``broadcastables`` arguments are used to specify the data type, dimension, and broadcasting behavior of the Theano variables corresponding to the free symbols in ``expr``. Each is a mapping from Sympy symbols to the value of the corresponding argument to :func:`theano.tensor.Tensor`. See the corresponding `documentation page`__ for more information on broadcasting in Theano. .. __: http://deeplearning.net/software/theano/tutorial/broadcasting.html Parameters ========== expr : sympy.core.expr.Expr Sympy expression to print. dtypes : dict Mapping from Sympy symbols to Theano datatypes to use when creating new Theano variables for those symbols. Corresponds to the ``dtype`` argument to :func:`theano.tensor.Tensor`. Defaults to ``'floatX'`` for symbols not included in the mapping. broadcastables : dict Mapping from Sympy symbols to the value of the ``broadcastable`` argument to :func:`theano.tensor.Tensor` to use when creating Theano variables for those symbols. Defaults to the empty tuple for symbols not included in the mapping (resulting in a scalar). Returns ======= theano.gof.graph.Variable A variable corresponding to the expression's value in a Theano symbolic expression graph. See Also ======== theano.tensor.Tensor """ if dtypes is None: dtypes = {} if broadcastables is None: broadcastables = {} return self._print(expr, dtypes=dtypes, broadcastables=broadcastables) global_cache = {} def theano_code(expr, cache=None, **kwargs): """ Convert a Sympy expression into a Theano graph variable. Parameters ========== expr : sympy.core.expr.Expr Sympy expression object to convert. cache : dict Cached Theano variables (see :attr:`.TheanoPrinter.cache`). Defaults to the module-level global cache. dtypes : dict Passed to :meth:`.TheanoPrinter.doprint`. broadcastables : dict Passed to :meth:`.TheanoPrinter.doprint`. Returns ======= theano.gof.graph.Variable A variable corresponding to the expression's value in a Theano symbolic expression graph. """ if not theano: raise ImportError("theano is required for theano_code") if cache is None: cache = global_cache return TheanoPrinter(cache=cache, settings={}).doprint(expr, **kwargs) def dim_handling(inputs, dim=None, dims=None, broadcastables=None): """ Get value of ``broadcastables`` argument to :func:`.theano_code` from keyword arguments to :func:`.theano_function`. Included for backwards compatibility. Parameters ========== inputs Sequence of input symbols. dim : int Common number of dimensions for all inputs. Overrides other arguments if given. dims : dict Mapping from input symbols to number of dimensions. Overrides ``broadcastables`` argument if given. broadcastables : dict Explicit value of ``broadcastables`` argument to :meth:`.TheanoPrinter.doprint`. If not None function will return this value unchanged. Returns ======= dict Dictionary mapping elements of ``inputs`` to their "broadcastable" values (tuple of ``bool``s). """ if dim is not None: return {s: (False,) * dim for s in inputs} if dims is not None: maxdim = max(dims.values()) return { s: (False,) * d + (True,) * (maxdim - d) for s, d in dims.items() } if broadcastables is not None: return broadcastables return {} def theano_function(inputs, outputs, scalar=False, **kwargs): """ Create a Theano function from SymPy expressions. The inputs and outputs are converted to Theano variables using :func:`.theano_code` and then passed to :func:`theano.function`. Parameters ========== inputs Sequence of symbols which constitute the inputs of the function. outputs Sequence of expressions which constitute the outputs(s) of the function. The free symbols of each expression must be a subset of ``inputs``. scalar : bool Convert 0-dimensional arrays in output to scalars. This will return a Python wrapper function around the Theano function object. cache : dict Cached Theano variables (see :attr:`.TheanoPrinter.cache`). Defaults to the module-level global cache. dtypes : dict Passed to :meth:`.TheanoPrinter.doprint`. broadcastables : dict Passed to :meth:`.TheanoPrinter.doprint`. dims : dict Alternative to ``broadcastables`` argument. Mapping from elements of ``inputs`` to integers indicating the dimension of their associated arrays/tensors. Overrides ``broadcastables`` argument if given. dim : int Another alternative to the ``broadcastables`` argument. Common number of dimensions to use for all arrays/tensors. ``theano_function([x, y], [...], dim=2)`` is equivalent to using ``broadcastables={x: (False, False), y: (False, False)}``. Returns ======= callable A callable object which takes values of ``inputs`` as positional arguments and returns an output array for each of the expressions in ``outputs``. If ``outputs`` is a single expression the function will return a Numpy array, if it is a list of multiple expressions the function will return a list of arrays. See description of the ``squeeze`` argument above for the behavior when a single output is passed in a list. The returned object will either be an instance of :class:`theano.compile.function_module.Function` or a Python wrapper function around one. In both cases, the returned value will have a ``theano_function`` attribute which points to the return value of :func:`theano.function`. Examples ======== >>> from sympy.abc import x, y, z >>> from sympy.printing.theanocode import theano_function A simple function with one input and one output: >>> f1 = theano_function([x], [x**2 - 1], scalar=True) >>> f1(3) 8.0 A function with multiple inputs and one output: >>> f2 = theano_function([x, y, z], [(x**z + y**z)**(1/z)], scalar=True) >>> f2(3, 4, 2) 5.0 A function with multiple inputs and multiple outputs: >>> f3 = theano_function([x, y], [x**2 + y**2, x**2 - y**2], scalar=True) >>> f3(2, 3) [13.0, -5.0] See also ======== theano.function dim_handling """ if not theano: raise ImportError("theano is required for theano_function") # Pop off non-theano keyword args cache = kwargs.pop('cache', {}) dtypes = kwargs.pop('dtypes', {}) broadcastables = dim_handling( inputs, dim=kwargs.pop('dim', None), dims=kwargs.pop('dims', None), broadcastables=kwargs.pop('broadcastables', None), ) # Print inputs/outputs code = partial(theano_code, cache=cache, dtypes=dtypes, broadcastables=broadcastables) tinputs = list(map(code, inputs)) toutputs = list(map(code, outputs)) #fix constant expressions as variables toutputs = [output if isinstance(output, theano.Variable) else tt.as_tensor_variable(output) for output in toutputs] if len(toutputs) == 1: toutputs = toutputs[0] # Compile theano func func = theano.function(tinputs, toutputs, **kwargs) is_0d = [len(o.variable.broadcastable) == 0 for o in func.outputs] # No wrapper required if not scalar or not any(is_0d): func.theano_function = func return func # Create wrapper to convert 0-dimensional outputs to scalars def wrapper(*args): out = func(*args) # out can be array(1.0) or [array(1.0), array(2.0)] if is_sequence(out): return [o[()] if is_0d[i] else o for i, o in enumerate(out)] else: return out[()] wrapper.__wrapped__ = func wrapper.__doc__ = func.__doc__ wrapper.theano_function = func return wrapper

40669f6e7e4759a0b1f825b8caee86c79f52809237f597fbd5bd2fcf562a0a5c

from __future__ import print_function, division from sympy.concrete.expr_with_limits import AddWithLimits from sympy.core.add import Add from sympy.core.basic import Basic from sympy.core.compatibility import is_sequence from sympy.core.containers import Tuple from sympy.core.expr import Expr from sympy.core.function import diff from sympy.core.mul import Mul from sympy.core.numbers import oo, pi from sympy.core.relational import Ne from sympy.core.singleton import S from sympy.core.symbol import (Dummy, Symbol, Wild) from sympy.core.sympify import sympify from sympy.functions import Piecewise, sqrt, piecewise_fold, tan, cot, atan from sympy.functions.elementary.exponential import log from sympy.functions.elementary.integers import floor from sympy.functions.elementary.complexes import Abs, sign from sympy.functions.elementary.miscellaneous import Min, Max from sympy.integrals.manualintegrate import manualintegrate from sympy.integrals.trigonometry import trigintegrate from sympy.integrals.meijerint import meijerint_definite, meijerint_indefinite from sympy.matrices import MatrixBase from sympy.polys import Poly, PolynomialError from sympy.series import limit from sympy.series.order import Order from sympy.series.formal import FormalPowerSeries from sympy.simplify.fu import sincos_to_sum from sympy.utilities.misc import filldedent class Integral(AddWithLimits): """Represents unevaluated integral.""" __slots__ = ['is_commutative'] def __new__(cls, function, *symbols, **assumptions): """Create an unevaluated integral. Arguments are an integrand followed by one or more limits. If no limits are given and there is only one free symbol in the expression, that symbol will be used, otherwise an error will be raised. >>> from sympy import Integral >>> from sympy.abc import x, y >>> Integral(x) Integral(x, x) >>> Integral(y) Integral(y, y) When limits are provided, they are interpreted as follows (using ``x`` as though it were the variable of integration): (x,) or x - indefinite integral (x, a) - "evaluate at" integral is an abstract antiderivative (x, a, b) - definite integral The ``as_dummy`` method can be used to see which symbols cannot be targeted by subs: those with a preppended underscore cannot be changed with ``subs``. (Also, the integration variables themselves -- the first element of a limit -- can never be changed by subs.) >>> i = Integral(x, x) >>> at = Integral(x, (x, x)) >>> i.as_dummy() Integral(x, x) >>> at.as_dummy() Integral(_0, (_0, x)) """ #This will help other classes define their own definitions #of behaviour with Integral. if hasattr(function, '_eval_Integral'): return function._eval_Integral(*symbols, **assumptions) obj = AddWithLimits.__new__(cls, function, *symbols, **assumptions) return obj def __getnewargs__(self): return (self.function,) + tuple([tuple(xab) for xab in self.limits]) @property def free_symbols(self): """ This method returns the symbols that will exist when the integral is evaluated. This is useful if one is trying to determine whether an integral depends on a certain symbol or not. Examples ======== >>> from sympy import Integral >>> from sympy.abc import x, y >>> Integral(x, (x, y, 1)).free_symbols {y} See Also ======== function, limits, variables """ return AddWithLimits.free_symbols.fget(self) def _eval_is_zero(self): # This is a very naive and quick test, not intended to do the integral to # answer whether it is zero or not, e.g. Integral(sin(x), (x, 0, 2*pi)) # is zero but this routine should return None for that case. But, like # Mul, there are trivial situations for which the integral will be # zero so we check for those. if self.function.is_zero: return True got_none = False for l in self.limits: if len(l) == 3: z = (l[1] == l[2]) or (l[1] - l[2]).is_zero if z: return True elif z is None: got_none = True free = self.function.free_symbols for xab in self.limits: if len(xab) == 1: free.add(xab[0]) continue if len(xab) == 2 and xab[0] not in free: if xab[1].is_zero: return True elif xab[1].is_zero is None: got_none = True # take integration symbol out of free since it will be replaced # with the free symbols in the limits free.discard(xab[0]) # add in the new symbols for i in xab[1:]: free.update(i.free_symbols) if self.function.is_zero is False and got_none is False: return False def transform(self, x, u): r""" Performs a change of variables from `x` to `u` using the relationship given by `x` and `u` which will define the transformations `f` and `F` (which are inverses of each other) as follows: 1) If `x` is a Symbol (which is a variable of integration) then `u` will be interpreted as some function, f(u), with inverse F(u). This, in effect, just makes the substitution of x with f(x). 2) If `u` is a Symbol then `x` will be interpreted as some function, F(x), with inverse f(u). This is commonly referred to as u-substitution. Once f and F have been identified, the transformation is made as follows: .. math:: \int_a^b x \mathrm{d}x \rightarrow \int_{F(a)}^{F(b)} f(x) \frac{\mathrm{d}}{\mathrm{d}x} where `F(x)` is the inverse of `f(x)` and the limits and integrand have been corrected so as to retain the same value after integration. Notes ===== The mappings, F(x) or f(u), must lead to a unique integral. Linear or rational linear expression, `2*x`, `1/x` and `sqrt(x)`, will always work; quadratic expressions like `x**2 - 1` are acceptable as long as the resulting integrand does not depend on the sign of the solutions (see examples). The integral will be returned unchanged if `x` is not a variable of integration. `x` must be (or contain) only one of of the integration variables. If `u` has more than one free symbol then it should be sent as a tuple (`u`, `uvar`) where `uvar` identifies which variable is replacing the integration variable. XXX can it contain another integration variable? Examples ======== >>> from sympy.abc import a, b, c, d, x, u, y >>> from sympy import Integral, S, cos, sqrt >>> i = Integral(x*cos(x**2 - 1), (x, 0, 1)) transform can change the variable of integration >>> i.transform(x, u) Integral(u*cos(u**2 - 1), (u, 0, 1)) transform can perform u-substitution as long as a unique integrand is obtained: >>> i.transform(x**2 - 1, u) Integral(cos(u)/2, (u, -1, 0)) This attempt fails because x = +/-sqrt(u + 1) and the sign does not cancel out of the integrand: >>> Integral(cos(x**2 - 1), (x, 0, 1)).transform(x**2 - 1, u) Traceback (most recent call last): ... ValueError: The mapping between F(x) and f(u) did not give a unique integrand. transform can do a substitution. Here, the previous result is transformed back into the original expression using "u-substitution": >>> ui = _ >>> _.transform(sqrt(u + 1), x) == i True We can accomplish the same with a regular substitution: >>> ui.transform(u, x**2 - 1) == i True If the `x` does not contain a symbol of integration then the integral will be returned unchanged. Integral `i` does not have an integration variable `a` so no change is made: >>> i.transform(a, x) == i True When `u` has more than one free symbol the symbol that is replacing `x` must be identified by passing `u` as a tuple: >>> Integral(x, (x, 0, 1)).transform(x, (u + a, u)) Integral(a + u, (u, -a, 1 - a)) >>> Integral(x, (x, 0, 1)).transform(x, (u + a, a)) Integral(a + u, (a, -u, 1 - u)) See Also ======== variables : Lists the integration variables as_dummy : Replace integration variables with dummy ones """ from sympy.solvers.solvers import solve, posify d = Dummy('d') xfree = x.free_symbols.intersection(self.variables) if len(xfree) > 1: raise ValueError( 'F(x) can only contain one of: %s' % self.variables) xvar = xfree.pop() if xfree else d if xvar not in self.variables: return self u = sympify(u) if isinstance(u, Expr): ufree = u.free_symbols if len(ufree) != 1: raise ValueError(filldedent(''' When f(u) has more than one free symbol, the one replacing x must be identified: pass f(u) as (f(u), u)''')) uvar = ufree.pop() else: u, uvar = u if uvar not in u.free_symbols: raise ValueError(filldedent(''' Expecting a tuple (expr, symbol) where symbol identified a free symbol in expr, but symbol is not in expr's free symbols.''')) if not isinstance(uvar, Symbol): raise ValueError(filldedent(''' Expecting a tuple (expr, symbol) but didn't get a symbol; got %s''' % uvar)) if x.is_Symbol and u.is_Symbol: return self.xreplace({x: u}) if not x.is_Symbol and not u.is_Symbol: raise ValueError('either x or u must be a symbol') if uvar == xvar: return self.transform(x, (u.subs(uvar, d), d)).xreplace({d: uvar}) if uvar in self.limits: raise ValueError(filldedent(''' u must contain the same variable as in x or a variable that is not already an integration variable''')) if not x.is_Symbol: F = [x.subs(xvar, d)] soln = solve(u - x, xvar, check=False) if not soln: raise ValueError('no solution for solve(F(x) - f(u), x)') f = [fi.subs(uvar, d) for fi in soln] else: f = [u.subs(uvar, d)] pdiff, reps = posify(u - x) puvar = uvar.subs([(v, k) for k, v in reps.items()]) soln = [s.subs(reps) for s in solve(pdiff, puvar)] if not soln: raise ValueError('no solution for solve(F(x) - f(u), u)') F = [fi.subs(xvar, d) for fi in soln] newfuncs = set([(self.function.subs(xvar, fi)*fi.diff(d) ).subs(d, uvar) for fi in f]) if len(newfuncs) > 1: raise ValueError(filldedent(''' The mapping between F(x) and f(u) did not give a unique integrand.''')) newfunc = newfuncs.pop() def _calc_limit_1(F, a, b): """ replace d with a, using subs if possible, otherwise limit where sign of b is considered """ wok = F.subs(d, a) if wok is S.NaN or wok.is_finite is False and a.is_finite: return limit(sign(b)*F, d, a) return wok def _calc_limit(a, b): """ replace d with a, using subs if possible, otherwise limit where sign of b is considered """ avals = list({_calc_limit_1(Fi, a, b) for Fi in F}) if len(avals) > 1: raise ValueError(filldedent(''' The mapping between F(x) and f(u) did not give a unique limit.''')) return avals[0] newlimits = [] for xab in self.limits: sym = xab[0] if sym == xvar: if len(xab) == 3: a, b = xab[1:] a, b = _calc_limit(a, b), _calc_limit(b, a) if a - b > 0: a, b = b, a newfunc = -newfunc newlimits.append((uvar, a, b)) elif len(xab) == 2: a = _calc_limit(xab[1], 1) newlimits.append((uvar, a)) else: newlimits.append(uvar) else: newlimits.append(xab) return self.func(newfunc, *newlimits) def doit(self, **hints): """ Perform the integration using any hints given. Examples ======== >>> from sympy import Integral >>> from sympy.abc import x, i >>> Integral(x**i, (i, 1, 3)).doit() Piecewise((x**3/log(x) - x/log(x), (x > 1) | ((x >= 0) & (x < 1))), (2, True)) See Also ======== sympy.integrals.trigonometry.trigintegrate sympy.integrals.risch.heurisch sympy.integrals.rationaltools.ratint as_sum : Approximate the integral using a sum """ if not hints.get('integrals', True): return self deep = hints.get('deep', True) meijerg = hints.get('meijerg', None) conds = hints.get('conds', 'piecewise') risch = hints.get('risch', None) heurisch = hints.get('heurisch', None) manual = hints.get('manual', None) if len(list(filter(None, (manual, meijerg, risch, heurisch)))) > 1: raise ValueError("At most one of manual, meijerg, risch, heurisch can be True") elif manual: meijerg = risch = heurisch = False elif meijerg: manual = risch = heurisch = False elif risch: manual = meijerg = heurisch = False elif heurisch: manual = meijerg = risch = False eval_kwargs = dict(meijerg=meijerg, risch=risch, manual=manual, heurisch=heurisch, conds=conds) if conds not in ['separate', 'piecewise', 'none']: raise ValueError('conds must be one of "separate", "piecewise", ' '"none", got: %s' % conds) if risch and any(len(xab) > 1 for xab in self.limits): raise ValueError('risch=True is only allowed for indefinite integrals.') # check for the trivial zero if self.is_zero: return S.Zero # now compute and check the function function = self.function if deep: function = function.doit(**hints) if function.is_zero: return S.Zero # hacks to handle special cases if isinstance(function, MatrixBase): return function.applyfunc( lambda f: self.func(f, self.limits).doit(**hints)) if isinstance(function, FormalPowerSeries): if len(self.limits) > 1: raise NotImplementedError xab = self.limits[0] if len(xab) > 1: return function.integrate(xab, **eval_kwargs) else: return function.integrate(xab[0], **eval_kwargs) # There is no trivial answer and special handling # is done so continue undone_limits = [] # ulj = free symbols of any undone limits' upper and lower limits ulj = set() for xab in self.limits: # compute uli, the free symbols in the # Upper and Lower limits of limit I if len(xab) == 1: uli = set(xab[:1]) elif len(xab) == 2: uli = xab[1].free_symbols elif len(xab) == 3: uli = xab[1].free_symbols.union(xab[2].free_symbols) # this integral can be done as long as there is no blocking # limit that has been undone. An undone limit is blocking if # it contains an integration variable that is in this limit's # upper or lower free symbols or vice versa if xab[0] in ulj or any(v[0] in uli for v in undone_limits): undone_limits.append(xab) ulj.update(uli) function = self.func(*([function] + [xab])) factored_function = function.factor() if not isinstance(factored_function, Integral): function = factored_function continue if function.has(Abs, sign) and ( (len(xab) < 3 and all(x.is_real for x in xab)) or (len(xab) == 3 and all(x.is_real and not x.is_infinite for x in xab[1:]))): # some improper integrals are better off with Abs xr = Dummy("xr", real=True) function = (function.xreplace({xab[0]: xr}) .rewrite(Piecewise).xreplace({xr: xab[0]})) elif function.has(Min, Max): function = function.rewrite(Piecewise) if (function.has(Piecewise) and not isinstance(function, Piecewise)): function = piecewise_fold(function) if isinstance(function, Piecewise): if len(xab) == 1: antideriv = function._eval_integral(xab[0], **eval_kwargs) else: antideriv = self._eval_integral( function, xab[0], **eval_kwargs) else: # There are a number of tradeoffs in using the # Meijer G method. It can sometimes be a lot faster # than other methods, and sometimes slower. And # there are certain types of integrals for which it # is more likely to work than others. These # heuristics are incorporated in deciding what # integration methods to try, in what order. See the # integrate() docstring for details. def try_meijerg(function, xab): ret = None if len(xab) == 3 and meijerg is not False: x, a, b = xab try: res = meijerint_definite(function, x, a, b) except NotImplementedError: from sympy.integrals.meijerint import _debug _debug('NotImplementedError ' 'from meijerint_definite') res = None if res is not None: f, cond = res if conds == 'piecewise': ret = Piecewise( (f, cond), (self.func( function, (x, a, b)), True)) elif conds == 'separate': if len(self.limits) != 1: raise ValueError(filldedent(''' conds=separate not supported in multiple integrals''')) ret = f, cond else: ret = f return ret meijerg1 = meijerg if (meijerg is not False and len(xab) == 3 and xab[1].is_real and xab[2].is_real and not function.is_Poly and (xab[1].has(oo, -oo) or xab[2].has(oo, -oo))): ret = try_meijerg(function, xab) if ret is not None: function = ret continue meijerg1 = False # If the special meijerg code did not succeed in # finding a definite integral, then the code using # meijerint_indefinite will not either (it might # find an antiderivative, but the answer is likely # to be nonsensical). Thus if we are requested to # only use Meijer G-function methods, we give up at # this stage. Otherwise we just disable G-function # methods. if meijerg1 is False and meijerg is True: antideriv = None else: antideriv = self._eval_integral( function, xab[0], **eval_kwargs) if antideriv is None and meijerg is True: ret = try_meijerg(function, xab) if ret is not None: function = ret continue if not isinstance(antideriv, Integral) and antideriv is not None: sym = xab[0] for atan_term in antideriv.atoms(atan): atan_arg = atan_term.args[0] # Checking `atan_arg` to be linear combination of `tan` or `cot` for tan_part in atan_arg.atoms(tan): x1 = Dummy('x1') tan_exp1 = atan_arg.subs(tan_part, x1) # The coefficient of `tan` should be constant coeff = tan_exp1.diff(x1) if x1 not in coeff.free_symbols: a = tan_part.args[0] antideriv = antideriv.subs(atan_term, Add(atan_term, sign(coeff)*pi*floor((a-pi/2)/pi))) for cot_part in atan_arg.atoms(cot): x1 = Dummy('x1') cot_exp1 = atan_arg.subs(cot_part, x1) # The coefficient of `cot` should be constant coeff = cot_exp1.diff(x1) if x1 not in coeff.free_symbols: a = cot_part.args[0] antideriv = antideriv.subs(atan_term, Add(atan_term, sign(coeff)*pi*floor((a)/pi))) if antideriv is None: undone_limits.append(xab) function = self.func(*([function] + [xab])).factor() factored_function = function.factor() if not isinstance(factored_function, Integral): function = factored_function continue else: if len(xab) == 1: function = antideriv else: if len(xab) == 3: x, a, b = xab elif len(xab) == 2: x, b = xab a = None else: raise NotImplementedError if deep: if isinstance(a, Basic): a = a.doit(**hints) if isinstance(b, Basic): b = b.doit(**hints) if antideriv.is_Poly: gens = list(antideriv.gens) gens.remove(x) antideriv = antideriv.as_expr() function = antideriv._eval_interval(x, a, b) function = Poly(function, *gens) else: def is_indef_int(g, x): return (isinstance(g, Integral) and any(i == (x,) for i in g.limits)) def eval_factored(f, x, a, b): # _eval_interval for integrals with # (constant) factors # a single indefinite integral is assumed args = [] for g in Mul.make_args(f): if is_indef_int(g, x): args.append(g._eval_interval(x, a, b)) else: args.append(g) return Mul(*args) integrals, others, piecewises = [], [], [] for f in Add.make_args(antideriv): if any(is_indef_int(g, x) for g in Mul.make_args(f)): integrals.append(f) elif any(isinstance(g, Piecewise) for g in Mul.make_args(f)): piecewises.append(piecewise_fold(f)) else: others.append(f) uneval = Add(*[eval_factored(f, x, a, b) for f in integrals]) try: evalued = Add(*others)._eval_interval(x, a, b) evalued_pw = piecewise_fold(Add(*piecewises))._eval_interval(x, a, b) function = uneval + evalued + evalued_pw except NotImplementedError: # This can happen if _eval_interval depends in a # complicated way on limits that cannot be computed undone_limits.append(xab) function = self.func(*([function] + [xab])) factored_function = function.factor() if not isinstance(factored_function, Integral): function = factored_function return function def _eval_derivative(self, sym): """Evaluate the derivative of the current Integral object by differentiating under the integral sign [1], using the Fundamental Theorem of Calculus [2] when possible. Whenever an Integral is encountered that is equivalent to zero or has an integrand that is independent of the variable of integration those integrals are performed. All others are returned as Integral instances which can be resolved with doit() (provided they are integrable). References: [1] https://en.wikipedia.org/wiki/Differentiation_under_the_integral_sign [2] https://en.wikipedia.org/wiki/Fundamental_theorem_of_calculus Examples ======== >>> from sympy import Integral >>> from sympy.abc import x, y >>> i = Integral(x + y, y, (y, 1, x)) >>> i.diff(x) Integral(x + y, (y, x)) + Integral(1, y, (y, 1, x)) >>> i.doit().diff(x) == i.diff(x).doit() True >>> i.diff(y) 0 The previous must be true since there is no y in the evaluated integral: >>> i.free_symbols {x} >>> i.doit() 2*x**3/3 - x/2 - 1/6 """ # differentiate under the integral sign; we do not # check for regularity conditions (TODO), see issue 4215 # get limits and the function f, limits = self.function, list(self.limits) # the order matters if variables of integration appear in the limits # so work our way in from the outside to the inside. limit = limits.pop(-1) if len(limit) == 3: x, a, b = limit elif len(limit) == 2: x, b = limit a = None else: a = b = None x = limit[0] if limits: # f is the argument to an integral f = self.func(f, *tuple(limits)) # assemble the pieces def _do(f, ab): dab_dsym = diff(ab, sym) if not dab_dsym: return S.Zero if isinstance(f, Integral): limits = [(x, x) if (len(l) == 1 and l[0] == x) else l for l in f.limits] f = self.func(f.function, *limits) return f.subs(x, ab)*dab_dsym rv = S.Zero if b is not None: rv += _do(f, b) if a is not None: rv -= _do(f, a) if len(limit) == 1 and sym == x: # the dummy variable *is* also the real-world variable arg = f rv += arg else: # the dummy variable might match sym but it's # only a dummy and the actual variable is determined # by the limits, so mask off the variable of integration # while differentiating u = Dummy('u') arg = f.subs(x, u).diff(sym).subs(u, x) if arg: rv += self.func(arg, Tuple(x, a, b)) return rv def _eval_integral(self, f, x, meijerg=None, risch=None, manual=None, heurisch=None, conds='piecewise'): """ Calculate the anti-derivative to the function f(x). The following algorithms are applied (roughly in this order): 1. Simple heuristics (based on pattern matching and integral table): - most frequently used functions (e.g. polynomials, products of trig functions) 2. Integration of rational functions: - A complete algorithm for integrating rational functions is implemented (the Lazard-Rioboo-Trager algorithm). The algorithm also uses the partial fraction decomposition algorithm implemented in apart() as a preprocessor to make this process faster. Note that the integral of a rational function is always elementary, but in general, it may include a RootSum. 3. Full Risch algorithm: - The Risch algorithm is a complete decision procedure for integrating elementary functions, which means that given any elementary function, it will either compute an elementary antiderivative, or else prove that none exists. Currently, part of transcendental case is implemented, meaning elementary integrals containing exponentials, logarithms, and (soon!) trigonometric functions can be computed. The algebraic case, e.g., functions containing roots, is much more difficult and is not implemented yet. - If the routine fails (because the integrand is not elementary, or because a case is not implemented yet), it continues on to the next algorithms below. If the routine proves that the integrals is nonelementary, it still moves on to the algorithms below, because we might be able to find a closed-form solution in terms of special functions. If risch=True, however, it will stop here. 4. The Meijer G-Function algorithm: - This algorithm works by first rewriting the integrand in terms of very general Meijer G-Function (meijerg in SymPy), integrating it, and then rewriting the result back, if possible. This algorithm is particularly powerful for definite integrals (which is actually part of a different method of Integral), since it can compute closed-form solutions of definite integrals even when no closed-form indefinite integral exists. But it also is capable of computing many indefinite integrals as well. - Another advantage of this method is that it can use some results about the Meijer G-Function to give a result in terms of a Piecewise expression, which allows to express conditionally convergent integrals. - Setting meijerg=True will cause integrate() to use only this method. 5. The "manual integration" algorithm: - This algorithm tries to mimic how a person would find an antiderivative by hand, for example by looking for a substitution or applying integration by parts. This algorithm does not handle as many integrands but can return results in a more familiar form. - Sometimes this algorithm can evaluate parts of an integral; in this case integrate() will try to evaluate the rest of the integrand using the other methods here. - Setting manual=True will cause integrate() to use only this method. 6. The Heuristic Risch algorithm: - This is a heuristic version of the Risch algorithm, meaning that it is not deterministic. This is tried as a last resort because it can be very slow. It is still used because not enough of the full Risch algorithm is implemented, so that there are still some integrals that can only be computed using this method. The goal is to implement enough of the Risch and Meijer G-function methods so that this can be deleted. Setting heurisch=True will cause integrate() to use only this method. Set heurisch=False to not use it. """ from sympy.integrals.deltafunctions import deltaintegrate from sympy.integrals.singularityfunctions import singularityintegrate from sympy.integrals.heurisch import heurisch as heurisch_, heurisch_wrapper from sympy.integrals.rationaltools import ratint from sympy.integrals.risch import risch_integrate if risch: try: return risch_integrate(f, x, conds=conds) except NotImplementedError: return None if manual: try: result = manualintegrate(f, x) if result is not None and result.func != Integral: return result except (ValueError, PolynomialError): pass eval_kwargs = dict(meijerg=meijerg, risch=risch, manual=manual, heurisch=heurisch, conds=conds) # if it is a poly(x) then let the polynomial integrate itself (fast) # # It is important to make this check first, otherwise the other code # will return a sympy expression instead of a Polynomial. # # see Polynomial for details. if isinstance(f, Poly) and not (manual or meijerg or risch): return f.integrate(x) # Piecewise antiderivatives need to call special integrate. if isinstance(f, Piecewise): return f.piecewise_integrate(x, **eval_kwargs) # let's cut it short if `f` does not depend on `x`; if # x is only a dummy, that will be handled below if not f.has(x): return f*x # try to convert to poly(x) and then integrate if successful (fast) poly = f.as_poly(x) if poly is not None and not (manual or meijerg or risch): return poly.integrate().as_expr() if risch is not False: try: result, i = risch_integrate(f, x, separate_integral=True, conds=conds) except NotImplementedError: pass else: if i: # There was a nonelementary integral. Try integrating it. # if no part of the NonElementaryIntegral is integrated by # the Risch algorithm, then use the original function to # integrate, instead of re-written one if result == 0: from sympy.integrals.risch import NonElementaryIntegral return NonElementaryIntegral(f, x).doit(risch=False) else: return result + i.doit(risch=False) else: return result # since Integral(f=g1+g2+...) == Integral(g1) + Integral(g2) + ... # we are going to handle Add terms separately, # if `f` is not Add -- we only have one term # Note that in general, this is a bad idea, because Integral(g1) + # Integral(g2) might not be computable, even if Integral(g1 + g2) is. # For example, Integral(x**x + x**x*log(x)). But many heuristics only # work term-wise. So we compute this step last, after trying # risch_integrate. We also try risch_integrate again in this loop, # because maybe the integral is a sum of an elementary part and a # nonelementary part (like erf(x) + exp(x)). risch_integrate() is # quite fast, so this is acceptable. parts = [] args = Add.make_args(f) for g in args: coeff, g = g.as_independent(x) # g(x) = const if g is S.One and not meijerg: parts.append(coeff*x) continue # g(x) = expr + O(x**n) order_term = g.getO() if order_term is not None: h = self._eval_integral(g.removeO(), x, **eval_kwargs) if h is not None: h_order_expr = self._eval_integral(order_term.expr, x, **eval_kwargs) if h_order_expr is not None: h_order_term = order_term.func( h_order_expr, *order_term.variables) parts.append(coeff*(h + h_order_term)) continue # NOTE: if there is O(x**n) and we fail to integrate then # there is no point in trying other methods because they # will fail, too. return None # c # g(x) = (a*x+b) if g.is_Pow and not g.exp.has(x) and not meijerg: a = Wild('a', exclude=[x]) b = Wild('b', exclude=[x]) M = g.base.match(a*x + b) if M is not None: if g.exp == -1: h = log(g.base) elif conds != 'piecewise': h = g.base**(g.exp + 1) / (g.exp + 1) else: h1 = log(g.base) h2 = g.base**(g.exp + 1) / (g.exp + 1) h = Piecewise((h2, Ne(g.exp, -1)), (h1, True)) parts.append(coeff * h / M[a]) continue # poly(x) # g(x) = ------- # poly(x) if g.is_rational_function(x) and not (manual or meijerg or risch): parts.append(coeff * ratint(g, x)) continue if not (manual or meijerg or risch): # g(x) = Mul(trig) h = trigintegrate(g, x, conds=conds) if h is not None: parts.append(coeff * h) continue # g(x) has at least a DiracDelta term h = deltaintegrate(g, x) if h is not None: parts.append(coeff * h) continue # g(x) has at least a Singularity Function term h = singularityintegrate(g, x) if h is not None: parts.append(coeff * h) continue # Try risch again. if risch is not False: try: h, i = risch_integrate(g, x, separate_integral=True, conds=conds) except NotImplementedError: h = None else: if i: h = h + i.doit(risch=False) parts.append(coeff*h) continue # fall back to heurisch if heurisch is not False: try: if conds == 'piecewise': h = heurisch_wrapper(g, x, hints=[]) else: h = heurisch_(g, x, hints=[]) except PolynomialError: # XXX: this exception means there is a bug in the # implementation of heuristic Risch integration # algorithm. h = None else: h = None if meijerg is not False and h is None: # rewrite using G functions try: h = meijerint_indefinite(g, x) except NotImplementedError: from sympy.integrals.meijerint import _debug _debug('NotImplementedError from meijerint_definite') res = None if h is not None: parts.append(coeff * h) continue if h is None and manual is not False: try: result = manualintegrate(g, x) if result is not None and not isinstance(result, Integral): if result.has(Integral) and not manual: # Try to have other algorithms do the integrals # manualintegrate can't handle, # unless we were asked to use manual only. # Keep the rest of eval_kwargs in case another # method was set to False already new_eval_kwargs = eval_kwargs new_eval_kwargs["manual"] = False result = result.func(*[ arg.doit(**new_eval_kwargs) if arg.has(Integral) else arg for arg in result.args ]).expand(multinomial=False, log=False, power_exp=False, power_base=False) if not result.has(Integral): parts.append(coeff * result) continue except (ValueError, PolynomialError): # can't handle some SymPy expressions pass # if we failed maybe it was because we had # a product that could have been expanded, # so let's try an expansion of the whole # thing before giving up; we don't try this # at the outset because there are things # that cannot be solved unless they are # NOT expanded e.g., x**x*(1+log(x)). There # should probably be a checker somewhere in this # routine to look for such cases and try to do # collection on the expressions if they are already # in an expanded form if not h and len(args) == 1: f = sincos_to_sum(f).expand(mul=True, deep=False) if f.is_Add: # Note: risch will be identical on the expanded # expression, but maybe it will be able to pick out parts, # like x*(exp(x) + erf(x)). return self._eval_integral(f, x, **eval_kwargs) if h is not None: parts.append(coeff * h) else: return None return Add(*parts) def _eval_lseries(self, x, logx): expr = self.as_dummy() symb = x for l in expr.limits: if x in l[1:]: symb = l[0] break for term in expr.function.lseries(symb, logx): yield integrate(term, *expr.limits) def _eval_nseries(self, x, n, logx): expr = self.as_dummy() symb = x for l in expr.limits: if x in l[1:]: symb = l[0] break terms, order = expr.function.nseries( x=symb, n=n, logx=logx).as_coeff_add(Order) order = [o.subs(symb, x) for o in order] return integrate(terms, *expr.limits) + Add(*order)*x def _eval_as_leading_term(self, x): series_gen = self.args[0].lseries(x) for leading_term in series_gen: if leading_term != 0: break return integrate(leading_term, *self.args[1:]) def _eval_simplify(self, ratio=1.7, measure=None, rational=False, inverse=False): from sympy.core.exprtools import factor_terms from sympy.simplify.simplify import simplify expr = factor_terms(self) kwargs = dict(ratio=ratio, measure=measure, rational=rational, inverse=inverse) if isinstance(expr, Integral): return expr.func(*[simplify(i, **kwargs) for i in expr.args]) return expr.simplify(**kwargs) def as_sum(self, n=None, method="midpoint", evaluate=True): """ Approximates a definite integral by a sum. Arguments --------- n The number of subintervals to use, optional. method One of: 'left', 'right', 'midpoint', 'trapezoid'. evaluate If False, returns an unevaluated Sum expression. The default is True, evaluate the sum. These methods of approximate integration are described in [1]. [1] https://en.wikipedia.org/wiki/Riemann_sum#Methods Examples ======== >>> from sympy import sin, sqrt >>> from sympy.abc import x, n >>> from sympy.integrals import Integral >>> e = Integral(sin(x), (x, 3, 7)) >>> e Integral(sin(x), (x, 3, 7)) For demonstration purposes, this interval will only be split into 2 regions, bounded by [3, 5] and [5, 7]. The left-hand rule uses function evaluations at the left of each interval: >>> e.as_sum(2, 'left') 2*sin(5) + 2*sin(3) The midpoint rule uses evaluations at the center of each interval: >>> e.as_sum(2, 'midpoint') 2*sin(4) + 2*sin(6) The right-hand rule uses function evaluations at the right of each interval: >>> e.as_sum(2, 'right') 2*sin(5) + 2*sin(7) The trapezoid rule uses function evaluations on both sides of the intervals. This is equivalent to taking the average of the left and right hand rule results: >>> e.as_sum(2, 'trapezoid') 2*sin(5) + sin(3) + sin(7) >>> (e.as_sum(2, 'left') + e.as_sum(2, 'right'))/2 == _ True Here, the discontinuity at x = 0 can be avoided by using the midpoint or right-hand method: >>> e = Integral(1/sqrt(x), (x, 0, 1)) >>> e.as_sum(5).n(4) 1.730 >>> e.as_sum(10).n(4) 1.809 >>> e.doit().n(4) # the actual value is 2 2.000 The left- or trapezoid method will encounter the discontinuity and return infinity: >>> e.as_sum(5, 'left') zoo The number of intervals can be symbolic. If omitted, a dummy symbol will be used for it. >>> e = Integral(x**2, (x, 0, 2)) >>> e.as_sum(n, 'right').expand() 8/3 + 4/n + 4/(3*n**2) This shows that the midpoint rule is more accurate, as its error term decays as the square of n: >>> e.as_sum(method='midpoint').expand() 8/3 - 2/(3*_n**2) A symbolic sum is returned with evaluate=False: >>> e.as_sum(n, 'midpoint', evaluate=False) 2*Sum((2*_k/n - 1/n)**2, (_k, 1, n))/n See Also ======== Integral.doit : Perform the integration using any hints """ from sympy.concrete.summations import Sum limits = self.limits if len(limits) > 1: raise NotImplementedError( "Multidimensional midpoint rule not implemented yet") else: limit = limits[0] if (len(limit) != 3 or limit[1].is_finite is False or limit[2].is_finite is False): raise ValueError("Expecting a definite integral over " "a finite interval.") if n is None: n = Dummy('n', integer=True, positive=True) else: n = sympify(n) if (n.is_positive is False or n.is_integer is False or n.is_finite is False): raise ValueError("n must be a positive integer, got %s" % n) x, a, b = limit dx = (b - a)/n k = Dummy('k', integer=True, positive=True) f = self.function if method == "left": result = dx*Sum(f.subs(x, a + (k-1)*dx), (k, 1, n)) elif method == "right": result = dx*Sum(f.subs(x, a + k*dx), (k, 1, n)) elif method == "midpoint": result = dx*Sum(f.subs(x, a + k*dx - dx/2), (k, 1, n)) elif method == "trapezoid": result = dx*((f.subs(x, a) + f.subs(x, b))/2 + Sum(f.subs(x, a + k*dx), (k, 1, n - 1))) else: raise ValueError("Unknown method %s" % method) return result.doit() if evaluate else result def _sage_(self): import sage.all as sage f, limits = self.function._sage_(), list(self.limits) for limit in limits: if len(limit) == 1: x = limit[0] f = sage.integral(f, x._sage_(), hold=True) elif len(limit) == 2: x, b = limit f = sage.integral(f, x._sage_(), b._sage_(), hold=True) else: x, a, b = limit f = sage.integral(f, (x._sage_(), a._sage_(), b._sage_()), hold=True) return f def principal_value(self, **kwargs): """ Compute the Cauchy Principal Value of the definite integral of a real function in the given interval on the real axis. In mathematics, the Cauchy principal value, is a method for assigning values to certain improper integrals which would otherwise be undefined. Examples ======== >>> from sympy import Dummy, symbols, integrate, limit, oo >>> from sympy.integrals.integrals import Integral >>> from sympy.calculus.singularities import singularities >>> x = symbols('x') >>> Integral(x+1, (x, -oo, oo)).principal_value() oo >>> f = 1 / (x**3) >>> Integral(f, (x, -oo, oo)).principal_value() 0 >>> Integral(f, (x, -10, 10)).principal_value() 0 >>> Integral(f, (x, -10, oo)).principal_value() + Integral(f, (x, -oo, 10)).principal_value() 0 References ========== .. [1] https://en.wikipedia.org/wiki/Cauchy_principal_value .. [2] http://mathworld.wolfram.com/CauchyPrincipalValue.html """ from sympy.calculus import singularities if len(self.limits) != 1 or len(list(self.limits[0])) != 3: raise ValueError("You need to insert a variable, lower_limit, and upper_limit correctly to calculate " "cauchy's principal value") x, a, b = self.limits[0] if not (a.is_comparable and b.is_comparable and a <= b): raise ValueError("The lower_limit must be smaller than or equal to the upper_limit to calculate " "cauchy's principal value. Also, a and b need to be comparable.") if a == b: return 0 r = Dummy('r') f = self.function singularities_list = [s for s in singularities(f, x) if s.is_comparable and a <= s <= b] for i in singularities_list: if (i == b) or (i == a): raise ValueError( 'The principal value is not defined in the given interval due to singularity at %d.' % (i)) F = integrate(f, x, **kwargs) if F.has(Integral): return self if a is -oo and b is oo: I = limit(F - F.subs(x, -x), x, oo) else: I = limit(F, x, b, '-') - limit(F, x, a, '+') for s in singularities_list: I += limit(((F.subs(x, s - r)) - F.subs(x, s + r)), r, 0, '+') return I def integrate(*args, **kwargs): """integrate(f, var, ...) Compute definite or indefinite integral of one or more variables using Risch-Norman algorithm and table lookup. This procedure is able to handle elementary algebraic and transcendental functions and also a huge class of special functions, including Airy, Bessel, Whittaker and Lambert. var can be: - a symbol -- indefinite integration - a tuple (symbol, a) -- indefinite integration with result given with `a` replacing `symbol` - a tuple (symbol, a, b) -- definite integration Several variables can be specified, in which case the result is multiple integration. (If var is omitted and the integrand is univariate, the indefinite integral in that variable will be performed.) Indefinite integrals are returned without terms that are independent of the integration variables. (see examples) Definite improper integrals often entail delicate convergence conditions. Pass conds='piecewise', 'separate' or 'none' to have these returned, respectively, as a Piecewise function, as a separate result (i.e. result will be a tuple), or not at all (default is 'piecewise'). **Strategy** SymPy uses various approaches to definite integration. One method is to find an antiderivative for the integrand, and then use the fundamental theorem of calculus. Various functions are implemented to integrate polynomial, rational and trigonometric functions, and integrands containing DiracDelta terms. SymPy also implements the part of the Risch algorithm, which is a decision procedure for integrating elementary functions, i.e., the algorithm can either find an elementary antiderivative, or prove that one does not exist. There is also a (very successful, albeit somewhat slow) general implementation of the heuristic Risch algorithm. This algorithm will eventually be phased out as more of the full Risch algorithm is implemented. See the docstring of Integral._eval_integral() for more details on computing the antiderivative using algebraic methods. The option risch=True can be used to use only the (full) Risch algorithm. This is useful if you want to know if an elementary function has an elementary antiderivative. If the indefinite Integral returned by this function is an instance of NonElementaryIntegral, that means that the Risch algorithm has proven that integral to be non-elementary. Note that by default, additional methods (such as the Meijer G method outlined below) are tried on these integrals, as they may be expressible in terms of special functions, so if you only care about elementary answers, use risch=True. Also note that an unevaluated Integral returned by this function is not necessarily a NonElementaryIntegral, even with risch=True, as it may just be an indication that the particular part of the Risch algorithm needed to integrate that function is not yet implemented. Another family of strategies comes from re-writing the integrand in terms of so-called Meijer G-functions. Indefinite integrals of a single G-function can always be computed, and the definite integral of a product of two G-functions can be computed from zero to infinity. Various strategies are implemented to rewrite integrands as G-functions, and use this information to compute integrals (see the ``meijerint`` module). The option manual=True can be used to use only an algorithm that tries to mimic integration by hand. This algorithm does not handle as many integrands as the other algorithms implemented but may return results in a more familiar form. The ``manualintegrate`` module has functions that return the steps used (see the module docstring for more information). In general, the algebraic methods work best for computing antiderivatives of (possibly complicated) combinations of elementary functions. The G-function methods work best for computing definite integrals from zero to infinity of moderately complicated combinations of special functions, or indefinite integrals of very simple combinations of special functions. The strategy employed by the integration code is as follows: - If computing a definite integral, and both limits are real, and at least one limit is +- oo, try the G-function method of definite integration first. - Try to find an antiderivative, using all available methods, ordered by performance (that is try fastest method first, slowest last; in particular polynomial integration is tried first, Meijer G-functions second to last, and heuristic Risch last). - If still not successful, try G-functions irrespective of the limits. The option meijerg=True, False, None can be used to, respectively: always use G-function methods and no others, never use G-function methods, or use all available methods (in order as described above). It defaults to None. Examples ======== >>> from sympy import integrate, log, exp, oo >>> from sympy.abc import a, x, y >>> integrate(x*y, x) x**2*y/2 >>> integrate(log(x), x) x*log(x) - x >>> integrate(log(x), (x, 1, a)) a*log(a) - a + 1 >>> integrate(x) x**2/2 Terms that are independent of x are dropped by indefinite integration: >>> from sympy import sqrt >>> integrate(sqrt(1 + x), (x, 0, x)) 2*(x + 1)**(3/2)/3 - 2/3 >>> integrate(sqrt(1 + x), x) 2*(x + 1)**(3/2)/3 >>> integrate(x*y) Traceback (most recent call last): ... ValueError: specify integration variables to integrate x*y Note that ``integrate(x)`` syntax is meant only for convenience in interactive sessions and should be avoided in library code. >>> integrate(x**a*exp(-x), (x, 0, oo)) # same as conds='piecewise' Piecewise((gamma(a + 1), re(a) > -1), (Integral(x**a*exp(-x), (x, 0, oo)), True)) >>> integrate(x**a*exp(-x), (x, 0, oo), conds='none') gamma(a + 1) >>> integrate(x**a*exp(-x), (x, 0, oo), conds='separate') (gamma(a + 1), -re(a) < 1) See Also ======== Integral, Integral.doit """ doit_flags = { 'deep': False, 'meijerg': kwargs.pop('meijerg', None), 'conds': kwargs.pop('conds', 'piecewise'), 'risch': kwargs.pop('risch', None), 'heurisch': kwargs.pop('heurisch', None), 'manual': kwargs.pop('manual', None) } integral = Integral(*args, **kwargs) if isinstance(integral, Integral): return integral.doit(**doit_flags) else: new_args = [a.doit(**doit_flags) if isinstance(a, Integral) else a for a in integral.args] return integral.func(*new_args) def line_integrate(field, curve, vars): """line_integrate(field, Curve, variables) Compute the line integral. Examples ======== >>> from sympy import Curve, line_integrate, E, ln >>> from sympy.abc import x, y, t >>> C = Curve([E**t + 1, E**t - 1], (t, 0, ln(2))) >>> line_integrate(x + y, C, [x, y]) 3*sqrt(2) See Also ======== integrate, Integral """ from sympy.geometry import Curve F = sympify(field) if not F: raise ValueError( "Expecting function specifying field as first argument.") if not isinstance(curve, Curve): raise ValueError("Expecting Curve entity as second argument.") if not is_sequence(vars): raise ValueError("Expecting ordered iterable for variables.") if len(curve.functions) != len(vars): raise ValueError("Field variable size does not match curve dimension.") if curve.parameter in vars: raise ValueError("Curve parameter clashes with field parameters.") # Calculate derivatives for line parameter functions # F(r) -> F(r(t)) and finally F(r(t)*r'(t)) Ft = F dldt = 0 for i, var in enumerate(vars): _f = curve.functions[i] _dn = diff(_f, curve.parameter) # ...arc length dldt = dldt + (_dn * _dn) Ft = Ft.subs(var, _f) Ft = Ft * sqrt(dldt) integral = Integral(Ft, curve.limits).doit(deep=False) return integral

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"""Base class for all the objects in SymPy""" from __future__ import print_function, division from collections import defaultdict from itertools import chain from .assumptions import BasicMeta, ManagedProperties from .cache import cacheit from .sympify import _sympify, sympify, SympifyError from .compatibility import (iterable, Iterator, ordered, string_types, with_metaclass, zip_longest, range, PY3, Mapping) from .singleton import S from inspect import getmro def as_Basic(expr): """Return expr as a Basic instance using strict sympify or raise a TypeError; this is just a wrapper to _sympify, raising a TypeError instead of a SympifyError.""" from sympy.utilities.misc import func_name try: return _sympify(expr) except SympifyError: raise TypeError( 'Argument must be a Basic object, not `%s`' % func_name( expr)) class Basic(with_metaclass(ManagedProperties)): """ Base class for all objects in SymPy. Conventions: 1) Always use ``.args``, when accessing parameters of some instance: >>> from sympy import cot >>> from sympy.abc import x, y >>> cot(x).args (x,) >>> cot(x).args[0] x >>> (x*y).args (x, y) >>> (x*y).args[1] y 2) Never use internal methods or variables (the ones prefixed with ``_``): >>> cot(x)._args # do not use this, use cot(x).args instead (x,) """ __slots__ = ['_mhash', # hash value '_args', # arguments '_assumptions' ] # To be overridden with True in the appropriate subclasses is_number = False is_Atom = False is_Symbol = False is_symbol = False is_Indexed = False is_Dummy = False is_Wild = False is_Function = False is_Add = False is_Mul = False is_Pow = False is_Number = False is_Float = False is_Rational = False is_Integer = False is_NumberSymbol = False is_Order = False is_Derivative = False is_Piecewise = False is_Poly = False is_AlgebraicNumber = False is_Relational = False is_Equality = False is_Boolean = False is_Not = False is_Matrix = False is_Vector = False is_Point = False is_MatAdd = False is_MatMul = False def __new__(cls, *args): obj = object.__new__(cls) obj._assumptions = cls.default_assumptions obj._mhash = None # will be set by __hash__ method. obj._args = args # all items in args must be Basic objects return obj def copy(self): return self.func(*self.args) def __reduce_ex__(self, proto): """ Pickling support.""" return type(self), self.__getnewargs__(), self.__getstate__() def __getnewargs__(self): return self.args def __getstate__(self): return {} def __setstate__(self, state): for k, v in state.items(): setattr(self, k, v) def __hash__(self): # hash cannot be cached using cache_it because infinite recurrence # occurs as hash is needed for setting cache dictionary keys h = self._mhash if h is None: h = hash((type(self).__name__,) + self._hashable_content()) self._mhash = h return h def _hashable_content(self): """Return a tuple of information about self that can be used to compute the hash. If a class defines additional attributes, like ``name`` in Symbol, then this method should be updated accordingly to return such relevant attributes. Defining more than _hashable_content is necessary if __eq__ has been defined by a class. See note about this in Basic.__eq__.""" return self._args @property def assumptions0(self): """ Return object `type` assumptions. For example: Symbol('x', real=True) Symbol('x', integer=True) are different objects. In other words, besides Python type (Symbol in this case), the initial assumptions are also forming their typeinfo. Examples ======== >>> from sympy import Symbol >>> from sympy.abc import x >>> x.assumptions0 {'commutative': True} >>> x = Symbol("x", positive=True) >>> x.assumptions0 {'commutative': True, 'complex': True, 'hermitian': True, 'imaginary': False, 'negative': False, 'nonnegative': True, 'nonpositive': False, 'nonzero': True, 'positive': True, 'real': True, 'zero': False} """ return {} def compare(self, other): """ Return -1, 0, 1 if the object is smaller, equal, or greater than other. Not in the mathematical sense. If the object is of a different type from the "other" then their classes are ordered according to the sorted_classes list. Examples ======== >>> from sympy.abc import x, y >>> x.compare(y) -1 >>> x.compare(x) 0 >>> y.compare(x) 1 """ # all redefinitions of __cmp__ method should start with the # following lines: if self is other: return 0 n1 = self.__class__ n2 = other.__class__ c = (n1 > n2) - (n1 < n2) if c: return c # st = self._hashable_content() ot = other._hashable_content() c = (len(st) > len(ot)) - (len(st) < len(ot)) if c: return c for l, r in zip(st, ot): l = Basic(*l) if isinstance(l, frozenset) else l r = Basic(*r) if isinstance(r, frozenset) else r if isinstance(l, Basic): c = l.compare(r) else: c = (l > r) - (l < r) if c: return c return 0 @staticmethod def _compare_pretty(a, b): from sympy.series.order import Order if isinstance(a, Order) and not isinstance(b, Order): return 1 if not isinstance(a, Order) and isinstance(b, Order): return -1 if a.is_Rational and b.is_Rational: l = a.p * b.q r = b.p * a.q return (l > r) - (l < r) else: from sympy.core.symbol import Wild p1, p2, p3 = Wild("p1"), Wild("p2"), Wild("p3") r_a = a.match(p1 * p2**p3) if r_a and p3 in r_a: a3 = r_a[p3] r_b = b.match(p1 * p2**p3) if r_b and p3 in r_b: b3 = r_b[p3] c = Basic.compare(a3, b3) if c != 0: return c return Basic.compare(a, b) @classmethod def fromiter(cls, args, **assumptions): """ Create a new object from an iterable. This is a convenience function that allows one to create objects from any iterable, without having to convert to a list or tuple first. Examples ======== >>> from sympy import Tuple >>> Tuple.fromiter(i for i in range(5)) (0, 1, 2, 3, 4) """ return cls(*tuple(args), **assumptions) @classmethod def class_key(cls): """Nice order of classes. """ return 5, 0, cls.__name__ @cacheit def sort_key(self, order=None): """ Return a sort key. Examples ======== >>> from sympy.core import S, I >>> sorted([S(1)/2, I, -I], key=lambda x: x.sort_key()) [1/2, -I, I] >>> S("[x, 1/x, 1/x**2, x**2, x**(1/2), x**(1/4), x**(3/2)]") [x, 1/x, x**(-2), x**2, sqrt(x), x**(1/4), x**(3/2)] >>> sorted(_, key=lambda x: x.sort_key()) [x**(-2), 1/x, x**(1/4), sqrt(x), x, x**(3/2), x**2] """ # XXX: remove this when issue 5169 is fixed def inner_key(arg): if isinstance(arg, Basic): return arg.sort_key(order) else: return arg args = self._sorted_args args = len(args), tuple([inner_key(arg) for arg in args]) return self.class_key(), args, S.One.sort_key(), S.One def __eq__(self, other): """Return a boolean indicating whether a == b on the basis of their symbolic trees. This is the same as a.compare(b) == 0 but faster. Notes ===== If a class that overrides __eq__() needs to retain the implementation of __hash__() from a parent class, the interpreter must be told this explicitly by setting __hash__ = <ParentClass>.__hash__. Otherwise the inheritance of __hash__() will be blocked, just as if __hash__ had been explicitly set to None. References ========== from http://docs.python.org/dev/reference/datamodel.html#object.__hash__ """ if self is other: return True tself = type(self) tother = type(other) if tself is not tother: try: other = _sympify(other) tother = type(other) except SympifyError: return NotImplemented # As long as we have the ordering of classes (sympy.core), # comparing types will be slow in Python 2, because it uses # __cmp__. Until we can remove it # (https://github.com/sympy/sympy/issues/4269), we only compare # types in Python 2 directly if they actually have __ne__. if PY3 or type(tself).__ne__ is not type.__ne__: if tself != tother: return False elif tself is not tother: return False return self._hashable_content() == other._hashable_content() def __ne__(self, other): """a != b -> Compare two symbolic trees and see whether they are different this is the same as: a.compare(b) != 0 but faster """ return not self == other def dummy_eq(self, other, symbol=None): """ Compare two expressions and handle dummy symbols. Examples ======== >>> from sympy import Dummy >>> from sympy.abc import x, y >>> u = Dummy('u') >>> (u**2 + 1).dummy_eq(x**2 + 1) True >>> (u**2 + 1) == (x**2 + 1) False >>> (u**2 + y).dummy_eq(x**2 + y, x) True >>> (u**2 + y).dummy_eq(x**2 + y, y) False """ s = self.as_dummy() o = _sympify(other) o = o.as_dummy() dummy_symbols = [i for i in s.free_symbols if i.is_Dummy] if len(dummy_symbols) == 1: dummy = dummy_symbols.pop() else: return s == o if symbol is None: symbols = o.free_symbols if len(symbols) == 1: symbol = symbols.pop() else: return s == o tmp = dummy.__class__() return s.subs(dummy, tmp) == o.subs(symbol, tmp) # Note, we always use the default ordering (lex) in __str__ and __repr__, # regardless of the global setting. See issue 5487. def __repr__(self): """Method to return the string representation. Return the expression as a string. """ from sympy.printing import sstr return sstr(self, order=None) def __str__(self): from sympy.printing import sstr return sstr(self, order=None) # We don't define _repr_png_ here because it would add a large amount of # data to any notebook containing SymPy expressions, without adding # anything useful to the notebook. It can still enabled manually, e.g., # for the qtconsole, with init_printing(). def _repr_latex_(self): """ IPython/Jupyter LaTeX printing To change the behavior of this (e.g., pass in some settings to LaTeX), use init_printing(). init_printing() will also enable LaTeX printing for built in numeric types like ints and container types that contain SymPy objects, like lists and dictionaries of expressions. """ from sympy.printing.latex import latex s = latex(self, mode='plain') return "$\\displaystyle %s$" % s _repr_latex_orig = _repr_latex_ def atoms(self, *types): """Returns the atoms that form the current object. By default, only objects that are truly atomic and can't be divided into smaller pieces are returned: symbols, numbers, and number symbols like I and pi. It is possible to request atoms of any type, however, as demonstrated below. Examples ======== >>> from sympy import I, pi, sin >>> from sympy.abc import x, y >>> (1 + x + 2*sin(y + I*pi)).atoms() {1, 2, I, pi, x, y} If one or more types are given, the results will contain only those types of atoms. >>> from sympy import Number, NumberSymbol, Symbol >>> (1 + x + 2*sin(y + I*pi)).atoms(Symbol) {x, y} >>> (1 + x + 2*sin(y + I*pi)).atoms(Number) {1, 2} >>> (1 + x + 2*sin(y + I*pi)).atoms(Number, NumberSymbol) {1, 2, pi} >>> (1 + x + 2*sin(y + I*pi)).atoms(Number, NumberSymbol, I) {1, 2, I, pi} Note that I (imaginary unit) and zoo (complex infinity) are special types of number symbols and are not part of the NumberSymbol class. The type can be given implicitly, too: >>> (1 + x + 2*sin(y + I*pi)).atoms(x) # x is a Symbol {x, y} Be careful to check your assumptions when using the implicit option since ``S(1).is_Integer = True`` but ``type(S(1))`` is ``One``, a special type of sympy atom, while ``type(S(2))`` is type ``Integer`` and will find all integers in an expression: >>> from sympy import S >>> (1 + x + 2*sin(y + I*pi)).atoms(S(1)) {1} >>> (1 + x + 2*sin(y + I*pi)).atoms(S(2)) {1, 2} Finally, arguments to atoms() can select more than atomic atoms: any sympy type (loaded in core/__init__.py) can be listed as an argument and those types of "atoms" as found in scanning the arguments of the expression recursively: >>> from sympy import Function, Mul >>> from sympy.core.function import AppliedUndef >>> f = Function('f') >>> (1 + f(x) + 2*sin(y + I*pi)).atoms(Function) {f(x), sin(y + I*pi)} >>> (1 + f(x) + 2*sin(y + I*pi)).atoms(AppliedUndef) {f(x)} >>> (1 + x + 2*sin(y + I*pi)).atoms(Mul) {I*pi, 2*sin(y + I*pi)} """ if types: types = tuple( [t if isinstance(t, type) else type(t) for t in types]) else: types = (Atom,) result = set() for expr in preorder_traversal(self): if isinstance(expr, types): result.add(expr) return result @property def free_symbols(self): """Return from the atoms of self those which are free symbols. For most expressions, all symbols are free symbols. For some classes this is not true. e.g. Integrals use Symbols for the dummy variables which are bound variables, so Integral has a method to return all symbols except those. Derivative keeps track of symbols with respect to which it will perform a derivative; those are bound variables, too, so it has its own free_symbols method. Any other method that uses bound variables should implement a free_symbols method.""" return set().union(*[a.free_symbols for a in self.args]) @property def expr_free_symbols(self): return set([]) def as_dummy(self): """Return the expression with any objects having structurally bound symbols replaced with unique, canonical symbols within the object in which they appear and having only the default assumption for commutativity being True. Examples ======== >>> from sympy import Integral, Symbol >>> from sympy.abc import x, y >>> r = Symbol('r', real=True) >>> Integral(r, (r, x)).as_dummy() Integral(_0, (_0, x)) >>> _.variables[0].is_real is None True Notes ===== Any object that has structural dummy variables should have a property, `bound_symbols` that returns a list of structural dummy symbols of the object itself. Lambda and Subs have bound symbols, but because of how they are cached, they already compare the same regardless of their bound symbols: >>> from sympy import Lambda >>> Lambda(x, x + 1) == Lambda(y, y + 1) True """ def can(x): d = {i: i.as_dummy() for i in x.bound_symbols} # mask free that shadow bound x = x.subs(d) c = x.canonical_variables # replace bound x = x.xreplace(c) # undo masking x = x.xreplace(dict((v, k) for k, v in d.items())) return x return self.replace( lambda x: hasattr(x, 'bound_symbols'), lambda x: can(x)) @property def canonical_variables(self): """Return a dictionary mapping any variable defined in ``self.bound_symbols`` to Symbols that do not clash with any existing symbol in the expression. Examples ======== >>> from sympy import Lambda >>> from sympy.abc import x >>> Lambda(x, 2*x).canonical_variables {x: _0} """ from sympy.core.symbol import Symbol from sympy.utilities.iterables import numbered_symbols if not hasattr(self, 'bound_symbols'): return {} dums = numbered_symbols('_') reps = {} v = self.bound_symbols # this free will include bound symbols that are not part of # self's bound symbols free = set([i.name for i in self.atoms(Symbol) - set(v)]) for v in v: d = next(dums) if v.is_Symbol: while v.name == d.name or d.name in free: d = next(dums) reps[v] = d return reps def rcall(self, *args): """Apply on the argument recursively through the expression tree. This method is used to simulate a common abuse of notation for operators. For instance in SymPy the the following will not work: ``(x+Lambda(y, 2*y))(z) == x+2*z``, however you can use >>> from sympy import Lambda >>> from sympy.abc import x, y, z >>> (x + Lambda(y, 2*y)).rcall(z) x + 2*z """ return Basic._recursive_call(self, args) @staticmethod def _recursive_call(expr_to_call, on_args): """Helper for rcall method. """ from sympy import Symbol def the_call_method_is_overridden(expr): for cls in getmro(type(expr)): if '__call__' in cls.__dict__: return cls != Basic if callable(expr_to_call) and the_call_method_is_overridden(expr_to_call): if isinstance(expr_to_call, Symbol): # XXX When you call a Symbol it is return expr_to_call # transformed into an UndefFunction else: return expr_to_call(*on_args) elif expr_to_call.args: args = [Basic._recursive_call( sub, on_args) for sub in expr_to_call.args] return type(expr_to_call)(*args) else: return expr_to_call def is_hypergeometric(self, k): from sympy.simplify import hypersimp return hypersimp(self, k) is not None @property def is_comparable(self): """Return True if self can be computed to a real number (or already is a real number) with precision, else False. Examples ======== >>> from sympy import exp_polar, pi, I >>> (I*exp_polar(I*pi/2)).is_comparable True >>> (I*exp_polar(I*pi*2)).is_comparable False A False result does not mean that `self` cannot be rewritten into a form that would be comparable. For example, the difference computed below is zero but without simplification it does not evaluate to a zero with precision: >>> e = 2**pi*(1 + 2**pi) >>> dif = e - e.expand() >>> dif.is_comparable False >>> dif.n(2)._prec 1 """ is_real = self.is_real if is_real is False: return False if not self.is_number: return False # don't re-eval numbers that are already evaluated since # this will create spurious precision n, i = [p.evalf(2) if not p.is_Number else p for p in self.as_real_imag()] if not (i.is_Number and n.is_Number): return False if i: # if _prec = 1 we can't decide and if not, # the answer is False because numbers with # imaginary parts can't be compared # so return False return False else: return n._prec != 1 @property def func(self): """ The top-level function in an expression. The following should hold for all objects:: >> x == x.func(*x.args) Examples ======== >>> from sympy.abc import x >>> a = 2*x >>> a.func <class 'sympy.core.mul.Mul'> >>> a.args (2, x) >>> a.func(*a.args) 2*x >>> a == a.func(*a.args) True """ return self.__class__ @property def args(self): """Returns a tuple of arguments of 'self'. Examples ======== >>> from sympy import cot >>> from sympy.abc import x, y >>> cot(x).args (x,) >>> cot(x).args[0] x >>> (x*y).args (x, y) >>> (x*y).args[1] y Notes ===== Never use self._args, always use self.args. Only use _args in __new__ when creating a new function. Don't override .args() from Basic (so that it's easy to change the interface in the future if needed). """ return self._args @property def _sorted_args(self): """ The same as ``args``. Derived classes which don't fix an order on their arguments should override this method to produce the sorted representation. """ return self.args def as_poly(self, *gens, **args): """Converts ``self`` to a polynomial or returns ``None``. >>> from sympy import sin >>> from sympy.abc import x, y >>> print((x**2 + x*y).as_poly()) Poly(x**2 + x*y, x, y, domain='ZZ') >>> print((x**2 + x*y).as_poly(x, y)) Poly(x**2 + x*y, x, y, domain='ZZ') >>> print((x**2 + sin(y)).as_poly(x, y)) None """ from sympy.polys import Poly, PolynomialError try: poly = Poly(self, *gens, **args) if not poly.is_Poly: return None else: return poly except PolynomialError: return None def as_content_primitive(self, radical=False, clear=True): """A stub to allow Basic args (like Tuple) to be skipped when computing the content and primitive components of an expression. See Also ======== sympy.core.expr.Expr.as_content_primitive """ return S.One, self def subs(self, *args, **kwargs): """ Substitutes old for new in an expression after sympifying args. `args` is either: - two arguments, e.g. foo.subs(old, new) - one iterable argument, e.g. foo.subs(iterable). The iterable may be o an iterable container with (old, new) pairs. In this case the replacements are processed in the order given with successive patterns possibly affecting replacements already made. o a dict or set whose key/value items correspond to old/new pairs. In this case the old/new pairs will be sorted by op count and in case of a tie, by number of args and the default_sort_key. The resulting sorted list is then processed as an iterable container (see previous). If the keyword ``simultaneous`` is True, the subexpressions will not be evaluated until all the substitutions have been made. Examples ======== >>> from sympy import pi, exp, limit, oo >>> from sympy.abc import x, y >>> (1 + x*y).subs(x, pi) pi*y + 1 >>> (1 + x*y).subs({x:pi, y:2}) 1 + 2*pi >>> (1 + x*y).subs([(x, pi), (y, 2)]) 1 + 2*pi >>> reps = [(y, x**2), (x, 2)] >>> (x + y).subs(reps) 6 >>> (x + y).subs(reversed(reps)) x**2 + 2 >>> (x**2 + x**4).subs(x**2, y) y**2 + y To replace only the x**2 but not the x**4, use xreplace: >>> (x**2 + x**4).xreplace({x**2: y}) x**4 + y To delay evaluation until all substitutions have been made, set the keyword ``simultaneous`` to True: >>> (x/y).subs([(x, 0), (y, 0)]) 0 >>> (x/y).subs([(x, 0), (y, 0)], simultaneous=True) nan This has the added feature of not allowing subsequent substitutions to affect those already made: >>> ((x + y)/y).subs({x + y: y, y: x + y}) 1 >>> ((x + y)/y).subs({x + y: y, y: x + y}, simultaneous=True) y/(x + y) In order to obtain a canonical result, unordered iterables are sorted by count_op length, number of arguments and by the default_sort_key to break any ties. All other iterables are left unsorted. >>> from sympy import sqrt, sin, cos >>> from sympy.abc import a, b, c, d, e >>> A = (sqrt(sin(2*x)), a) >>> B = (sin(2*x), b) >>> C = (cos(2*x), c) >>> D = (x, d) >>> E = (exp(x), e) >>> expr = sqrt(sin(2*x))*sin(exp(x)*x)*cos(2*x) + sin(2*x) >>> expr.subs(dict([A, B, C, D, E])) a*c*sin(d*e) + b The resulting expression represents a literal replacement of the old arguments with the new arguments. This may not reflect the limiting behavior of the expression: >>> (x**3 - 3*x).subs({x: oo}) nan >>> limit(x**3 - 3*x, x, oo) oo If the substitution will be followed by numerical evaluation, it is better to pass the substitution to evalf as >>> (1/x).evalf(subs={x: 3.0}, n=21) 0.333333333333333333333 rather than >>> (1/x).subs({x: 3.0}).evalf(21) 0.333333333333333314830 as the former will ensure that the desired level of precision is obtained. See Also ======== replace: replacement capable of doing wildcard-like matching, parsing of match, and conditional replacements xreplace: exact node replacement in expr tree; also capable of using matching rules evalf: calculates the given formula to a desired level of precision """ from sympy.core.containers import Dict from sympy.utilities import default_sort_key from sympy import Dummy, Symbol unordered = False if len(args) == 1: sequence = args[0] if isinstance(sequence, set): unordered = True elif isinstance(sequence, (Dict, Mapping)): unordered = True sequence = sequence.items() elif not iterable(sequence): from sympy.utilities.misc import filldedent raise ValueError(filldedent(""" When a single argument is passed to subs it should be a dictionary of old: new pairs or an iterable of (old, new) tuples.""")) elif len(args) == 2: sequence = [args] else: raise ValueError("subs accepts either 1 or 2 arguments") sequence = list(sequence) for i, s in enumerate(sequence): if isinstance(s[0], string_types): # when old is a string we prefer Symbol s = Symbol(s[0]), s[1] try: s = [sympify(_, strict=not isinstance(_, string_types)) for _ in s] except SympifyError: # if it can't be sympified, skip it sequence[i] = None continue # skip if there is no change sequence[i] = None if _aresame(*s) else tuple(s) sequence = list(filter(None, sequence)) if unordered: sequence = dict(sequence) if not all(k.is_Atom for k in sequence): d = {} for o, n in sequence.items(): try: ops = o.count_ops(), len(o.args) except TypeError: ops = (0, 0) d.setdefault(ops, []).append((o, n)) newseq = [] for k in sorted(d.keys(), reverse=True): newseq.extend( sorted([v[0] for v in d[k]], key=default_sort_key)) sequence = [(k, sequence[k]) for k in newseq] del newseq, d else: sequence = sorted([(k, v) for (k, v) in sequence.items()], key=default_sort_key) if kwargs.pop('simultaneous', False): # XXX should this be the default for dict subs? reps = {} rv = self kwargs['hack2'] = True m = Dummy() for old, new in sequence: d = Dummy(commutative=new.is_commutative) # using d*m so Subs will be used on dummy variables # in things like Derivative(f(x, y), x) in which x # is both free and bound rv = rv._subs(old, d*m, **kwargs) if not isinstance(rv, Basic): break reps[d] = new reps[m] = S.One # get rid of m return rv.xreplace(reps) else: rv = self for old, new in sequence: rv = rv._subs(old, new, **kwargs) if not isinstance(rv, Basic): break return rv @cacheit def _subs(self, old, new, **hints): """Substitutes an expression old -> new. If self is not equal to old then _eval_subs is called. If _eval_subs doesn't want to make any special replacement then a None is received which indicates that the fallback should be applied wherein a search for replacements is made amongst the arguments of self. >>> from sympy import Add >>> from sympy.abc import x, y, z Examples ======== Add's _eval_subs knows how to target x + y in the following so it makes the change: >>> (x + y + z).subs(x + y, 1) z + 1 Add's _eval_subs doesn't need to know how to find x + y in the following: >>> Add._eval_subs(z*(x + y) + 3, x + y, 1) is None True The returned None will cause the fallback routine to traverse the args and pass the z*(x + y) arg to Mul where the change will take place and the substitution will succeed: >>> (z*(x + y) + 3).subs(x + y, 1) z + 3 ** Developers Notes ** An _eval_subs routine for a class should be written if: 1) any arguments are not instances of Basic (e.g. bool, tuple); 2) some arguments should not be targeted (as in integration variables); 3) if there is something other than a literal replacement that should be attempted (as in Piecewise where the condition may be updated without doing a replacement). If it is overridden, here are some special cases that might arise: 1) If it turns out that no special change was made and all the original sub-arguments should be checked for replacements then None should be returned. 2) If it is necessary to do substitutions on a portion of the expression then _subs should be called. _subs will handle the case of any sub-expression being equal to old (which usually would not be the case) while its fallback will handle the recursion into the sub-arguments. For example, after Add's _eval_subs removes some matching terms it must process the remaining terms so it calls _subs on each of the un-matched terms and then adds them onto the terms previously obtained. 3) If the initial expression should remain unchanged then the original expression should be returned. (Whenever an expression is returned, modified or not, no further substitution of old -> new is attempted.) Sum's _eval_subs routine uses this strategy when a substitution is attempted on any of its summation variables. """ def fallback(self, old, new): """ Try to replace old with new in any of self's arguments. """ hit = False args = list(self.args) for i, arg in enumerate(args): if not hasattr(arg, '_eval_subs'): continue arg = arg._subs(old, new, **hints) if not _aresame(arg, args[i]): hit = True args[i] = arg if hit: rv = self.func(*args) hack2 = hints.get('hack2', False) if hack2 and self.is_Mul and not rv.is_Mul: # 2-arg hack coeff = S.One nonnumber = [] for i in args: if i.is_Number: coeff *= i else: nonnumber.append(i) nonnumber = self.func(*nonnumber) if coeff is S.One: return nonnumber else: return self.func(coeff, nonnumber, evaluate=False) return rv return self if _aresame(self, old): return new rv = self._eval_subs(old, new) if rv is None: rv = fallback(self, old, new) return rv def _eval_subs(self, old, new): """Override this stub if you want to do anything more than attempt a replacement of old with new in the arguments of self. See also: _subs """ return None def xreplace(self, rule): """ Replace occurrences of objects within the expression. Parameters ========== rule : dict-like Expresses a replacement rule Returns ======= xreplace : the result of the replacement Examples ======== >>> from sympy import symbols, pi, exp >>> x, y, z = symbols('x y z') >>> (1 + x*y).xreplace({x: pi}) pi*y + 1 >>> (1 + x*y).xreplace({x: pi, y: 2}) 1 + 2*pi Replacements occur only if an entire node in the expression tree is matched: >>> (x*y + z).xreplace({x*y: pi}) z + pi >>> (x*y*z).xreplace({x*y: pi}) x*y*z >>> (2*x).xreplace({2*x: y, x: z}) y >>> (2*2*x).xreplace({2*x: y, x: z}) 4*z >>> (x + y + 2).xreplace({x + y: 2}) x + y + 2 >>> (x + 2 + exp(x + 2)).xreplace({x + 2: y}) x + exp(y) + 2 xreplace doesn't differentiate between free and bound symbols. In the following, subs(x, y) would not change x since it is a bound symbol, but xreplace does: >>> from sympy import Integral >>> Integral(x, (x, 1, 2*x)).xreplace({x: y}) Integral(y, (y, 1, 2*y)) Trying to replace x with an expression raises an error: >>> Integral(x, (x, 1, 2*x)).xreplace({x: 2*y}) # doctest: +SKIP ValueError: Invalid limits given: ((2*y, 1, 4*y),) See Also ======== replace: replacement capable of doing wildcard-like matching, parsing of match, and conditional replacements subs: substitution of subexpressions as defined by the objects themselves. """ value, _ = self._xreplace(rule) return value def _xreplace(self, rule): """ Helper for xreplace. Tracks whether a replacement actually occurred. """ if self in rule: return rule[self], True elif rule: args = [] changed = False for a in self.args: _xreplace = getattr(a, '_xreplace', None) if _xreplace is not None: a_xr = _xreplace(rule) args.append(a_xr[0]) changed |= a_xr[1] else: args.append(a) args = tuple(args) if changed: return self.func(*args), True return self, False @cacheit def has(self, *patterns): """ Test whether any subexpression matches any of the patterns. Examples ======== >>> from sympy import sin >>> from sympy.abc import x, y, z >>> (x**2 + sin(x*y)).has(z) False >>> (x**2 + sin(x*y)).has(x, y, z) True >>> x.has(x) True Note ``has`` is a structural algorithm with no knowledge of mathematics. Consider the following half-open interval: >>> from sympy.sets import Interval >>> i = Interval.Lopen(0, 5); i Interval.Lopen(0, 5) >>> i.args (0, 5, True, False) >>> i.has(4) # there is no "4" in the arguments False >>> i.has(0) # there *is* a "0" in the arguments True Instead, use ``contains`` to determine whether a number is in the interval or not: >>> i.contains(4) True >>> i.contains(0) False Note that ``expr.has(*patterns)`` is exactly equivalent to ``any(expr.has(p) for p in patterns)``. In particular, ``False`` is returned when the list of patterns is empty. >>> x.has() False """ return any(self._has(pattern) for pattern in patterns) def _has(self, pattern): """Helper for .has()""" from sympy.core.function import UndefinedFunction, Function if isinstance(pattern, UndefinedFunction): return any(f.func == pattern or f == pattern for f in self.atoms(Function, UndefinedFunction)) pattern = sympify(pattern) if isinstance(pattern, BasicMeta): return any(isinstance(arg, pattern) for arg in preorder_traversal(self)) _has_matcher = getattr(pattern, '_has_matcher', None) if _has_matcher is not None: match = _has_matcher() return any(match(arg) for arg in preorder_traversal(self)) else: return any(arg == pattern for arg in preorder_traversal(self)) def _has_matcher(self): """Helper for .has()""" return lambda other: self == other def replace(self, query, value, map=False, simultaneous=True, exact=None): """ Replace matching subexpressions of ``self`` with ``value``. If ``map = True`` then also return the mapping {old: new} where ``old`` was a sub-expression found with query and ``new`` is the replacement value for it. If the expression itself doesn't match the query, then the returned value will be ``self.xreplace(map)`` otherwise it should be ``self.subs(ordered(map.items()))``. Traverses an expression tree and performs replacement of matching subexpressions from the bottom to the top of the tree. The default approach is to do the replacement in a simultaneous fashion so changes made are targeted only once. If this is not desired or causes problems, ``simultaneous`` can be set to False. In addition, if an expression containing more than one Wild symbol is being used to match subexpressions and the ``exact`` flag is True, then the match will only succeed if non-zero values are received for each Wild that appears in the match pattern. The list of possible combinations of queries and replacement values is listed below: Examples ======== Initial setup >>> from sympy import log, sin, cos, tan, Wild, Mul, Add >>> from sympy.abc import x, y >>> f = log(sin(x)) + tan(sin(x**2)) 1.1. type -> type obj.replace(type, newtype) When object of type ``type`` is found, replace it with the result of passing its argument(s) to ``newtype``. >>> f.replace(sin, cos) log(cos(x)) + tan(cos(x**2)) >>> sin(x).replace(sin, cos, map=True) (cos(x), {sin(x): cos(x)}) >>> (x*y).replace(Mul, Add) x + y 1.2. type -> func obj.replace(type, func) When object of type ``type`` is found, apply ``func`` to its argument(s). ``func`` must be written to handle the number of arguments of ``type``. >>> f.replace(sin, lambda arg: sin(2*arg)) log(sin(2*x)) + tan(sin(2*x**2)) >>> (x*y).replace(Mul, lambda *args: sin(2*Mul(*args))) sin(2*x*y) 2.1. pattern -> expr obj.replace(pattern(wild), expr(wild)) Replace subexpressions matching ``pattern`` with the expression written in terms of the Wild symbols in ``pattern``. >>> a, b = map(Wild, 'ab') >>> f.replace(sin(a), tan(a)) log(tan(x)) + tan(tan(x**2)) >>> f.replace(sin(a), tan(a/2)) log(tan(x/2)) + tan(tan(x**2/2)) >>> f.replace(sin(a), a) log(x) + tan(x**2) >>> (x*y).replace(a*x, a) y Matching is exact by default when more than one Wild symbol is used: matching fails unless the match gives non-zero values for all Wild symbols: >>> (2*x + y).replace(a*x + b, b - a) y - 2 >>> (2*x).replace(a*x + b, b - a) 2*x When set to False, the results may be non-intuitive: >>> (2*x).replace(a*x + b, b - a, exact=False) 2/x 2.2. pattern -> func obj.replace(pattern(wild), lambda wild: expr(wild)) All behavior is the same as in 2.1 but now a function in terms of pattern variables is used rather than an expression: >>> f.replace(sin(a), lambda a: sin(2*a)) log(sin(2*x)) + tan(sin(2*x**2)) 3.1. func -> func obj.replace(filter, func) Replace subexpression ``e`` with ``func(e)`` if ``filter(e)`` is True. >>> g = 2*sin(x**3) >>> g.replace(lambda expr: expr.is_Number, lambda expr: expr**2) 4*sin(x**9) The expression itself is also targeted by the query but is done in such a fashion that changes are not made twice. >>> e = x*(x*y + 1) >>> e.replace(lambda x: x.is_Mul, lambda x: 2*x) 2*x*(2*x*y + 1) See Also ======== subs: substitution of subexpressions as defined by the objects themselves. xreplace: exact node replacement in expr tree; also capable of using matching rules """ from sympy.core.symbol import Dummy, Wild from sympy.simplify.simplify import bottom_up try: query = _sympify(query) except SympifyError: pass try: value = _sympify(value) except SympifyError: pass if isinstance(query, type): _query = lambda expr: isinstance(expr, query) if isinstance(value, type): _value = lambda expr, result: value(*expr.args) elif callable(value): _value = lambda expr, result: value(*expr.args) else: raise TypeError( "given a type, replace() expects another " "type or a callable") elif isinstance(query, Basic): _query = lambda expr: expr.match(query) exact = len(query.atoms(Wild)) > 1 if exact is None else exact if isinstance(value, Basic): if exact: _value = lambda expr, result: (value.subs(result) if all(result.values()) else expr) else: _value = lambda expr, result: value.subs(result) elif callable(value): # match dictionary keys get the trailing underscore stripped # from them and are then passed as keywords to the callable; # if ``exact`` is True, only accept match if there are no null # values amongst those matched. if exact: _value = lambda expr, result: (value(** {str(k)[:-1]: v for k, v in result.items()}) if all(val for val in result.values()) else expr) else: _value = lambda expr, result: value(** {str(k)[:-1]: v for k, v in result.items()}) else: raise TypeError( "given an expression, replace() expects " "another expression or a callable") elif callable(query): _query = query if callable(value): _value = lambda expr, result: value(expr) else: raise TypeError( "given a callable, replace() expects " "another callable") else: raise TypeError( "first argument to replace() must be a " "type, an expression or a callable") mapping = {} # changes that took place mask = [] # the dummies that were used as change placeholders def rec_replace(expr): result = _query(expr) if result or result == {}: new = _value(expr, result) if new is not None and new != expr: mapping[expr] = new if simultaneous: # don't let this expression be changed during rebuilding com = getattr(new, 'is_commutative', True) if com is None: com = True d = Dummy(commutative=com) mask.append((d, new)) expr = d else: expr = new return expr rv = bottom_up(self, rec_replace, atoms=True) # restore original expressions for Dummy symbols if simultaneous: mask = list(reversed(mask)) for o, n in mask: r = {o: n} rv = rv.xreplace(r) if not map: return rv else: if simultaneous: # restore subexpressions in mapping for o, n in mask: r = {o: n} mapping = {k.xreplace(r): v.xreplace(r) for k, v in mapping.items()} return rv, mapping def find(self, query, group=False): """Find all subexpressions matching a query. """ query = _make_find_query(query) results = list(filter(query, preorder_traversal(self))) if not group: return set(results) else: groups = {} for result in results: if result in groups: groups[result] += 1 else: groups[result] = 1 return groups def count(self, query): """Count the number of matching subexpressions. """ query = _make_find_query(query) return sum(bool(query(sub)) for sub in preorder_traversal(self)) def matches(self, expr, repl_dict={}, old=False): """ Helper method for match() that looks for a match between Wild symbols in self and expressions in expr. Examples ======== >>> from sympy import symbols, Wild, Basic >>> a, b, c = symbols('a b c') >>> x = Wild('x') >>> Basic(a + x, x).matches(Basic(a + b, c)) is None True >>> Basic(a + x, x).matches(Basic(a + b + c, b + c)) {x_: b + c} """ expr = sympify(expr) if not isinstance(expr, self.__class__): return None if self == expr: return repl_dict if len(self.args) != len(expr.args): return None d = repl_dict.copy() for arg, other_arg in zip(self.args, expr.args): if arg == other_arg: continue d = arg.xreplace(d).matches(other_arg, d, old=old) if d is None: return None return d def match(self, pattern, old=False): """ Pattern matching. Wild symbols match all. Return ``None`` when expression (self) does not match with pattern. Otherwise return a dictionary such that:: pattern.xreplace(self.match(pattern)) == self Examples ======== >>> from sympy import Wild >>> from sympy.abc import x, y >>> p = Wild("p") >>> q = Wild("q") >>> r = Wild("r") >>> e = (x+y)**(x+y) >>> e.match(p**p) {p_: x + y} >>> e.match(p**q) {p_: x + y, q_: x + y} >>> e = (2*x)**2 >>> e.match(p*q**r) {p_: 4, q_: x, r_: 2} >>> (p*q**r).xreplace(e.match(p*q**r)) 4*x**2 The ``old`` flag will give the old-style pattern matching where expressions and patterns are essentially solved to give the match. Both of the following give None unless ``old=True``: >>> (x - 2).match(p - x, old=True) {p_: 2*x - 2} >>> (2/x).match(p*x, old=True) {p_: 2/x**2} """ pattern = sympify(pattern) return pattern.matches(self, old=old) def count_ops(self, visual=None): """wrapper for count_ops that returns the operation count.""" from sympy import count_ops return count_ops(self, visual) def doit(self, **hints): """Evaluate objects that are not evaluated by default like limits, integrals, sums and products. All objects of this kind will be evaluated recursively, unless some species were excluded via 'hints' or unless the 'deep' hint was set to 'False'. >>> from sympy import Integral >>> from sympy.abc import x >>> 2*Integral(x, x) 2*Integral(x, x) >>> (2*Integral(x, x)).doit() x**2 >>> (2*Integral(x, x)).doit(deep=False) 2*Integral(x, x) """ if hints.get('deep', True): terms = [term.doit(**hints) if isinstance(term, Basic) else term for term in self.args] return self.func(*terms) else: return self def _eval_rewrite(self, pattern, rule, **hints): if self.is_Atom: if hasattr(self, rule): return getattr(self, rule)() return self if hints.get('deep', True): args = [a._eval_rewrite(pattern, rule, **hints) if isinstance(a, Basic) else a for a in self.args] else: args = self.args if pattern is None or isinstance(self, pattern): if hasattr(self, rule): rewritten = getattr(self, rule)(*args, **hints) if rewritten is not None: return rewritten return self.func(*args) if hints.get('evaluate', True) else self def _accept_eval_derivative(self, s): # This method needs to be overridden by array-like objects return s._visit_eval_derivative_scalar(self) def _visit_eval_derivative_scalar(self, base): # Base is a scalar # Types are (base: scalar, self: scalar) return base._eval_derivative(self) def _visit_eval_derivative_array(self, base): # Types are (base: array/matrix, self: scalar) # Base is some kind of array/matrix, # it should have `.applyfunc(lambda x: x.diff(self)` implemented: return base._eval_derivative_array(self) def _eval_derivative_n_times(self, s, n): # This is the default evaluator for derivatives (as called by `diff` # and `Derivative`), it will attempt a loop to derive the expression # `n` times by calling the corresponding `_eval_derivative` method, # while leaving the derivative unevaluated if `n` is symbolic. This # method should be overridden if the object has a closed form for its # symbolic n-th derivative. from sympy import Integer if isinstance(n, (int, Integer)): obj = self for i in range(n): obj2 = obj._accept_eval_derivative(s) if obj == obj2 or obj2 is None: break obj = obj2 return obj2 else: return None def rewrite(self, *args, **hints): """ Rewrite functions in terms of other functions. Rewrites expression containing applications of functions of one kind in terms of functions of different kind. For example you can rewrite trigonometric functions as complex exponentials or combinatorial functions as gamma function. As a pattern this function accepts a list of functions to to rewrite (instances of DefinedFunction class). As rule you can use string or a destination function instance (in this case rewrite() will use the str() function). There is also the possibility to pass hints on how to rewrite the given expressions. For now there is only one such hint defined called 'deep'. When 'deep' is set to False it will forbid functions to rewrite their contents. Examples ======== >>> from sympy import sin, exp >>> from sympy.abc import x Unspecified pattern: >>> sin(x).rewrite(exp) -I*(exp(I*x) - exp(-I*x))/2 Pattern as a single function: >>> sin(x).rewrite(sin, exp) -I*(exp(I*x) - exp(-I*x))/2 Pattern as a list of functions: >>> sin(x).rewrite([sin, ], exp) -I*(exp(I*x) - exp(-I*x))/2 """ if not args: return self else: pattern = args[:-1] if isinstance(args[-1], string_types): rule = '_eval_rewrite_as_' + args[-1] else: try: rule = '_eval_rewrite_as_' + args[-1].__name__ except: rule = '_eval_rewrite_as_' + args[-1].__class__.__name__ if not pattern: return self._eval_rewrite(None, rule, **hints) else: if iterable(pattern[0]): pattern = pattern[0] pattern = [p for p in pattern if self.has(p)] if pattern: return self._eval_rewrite(tuple(pattern), rule, **hints) else: return self _constructor_postprocessor_mapping = {} @classmethod def _exec_constructor_postprocessors(cls, obj): # WARNING: This API is experimental. # This is an experimental API that introduces constructor # postprosessors for SymPy Core elements. If an argument of a SymPy # expression has a `_constructor_postprocessor_mapping` attribute, it will # be interpreted as a dictionary containing lists of postprocessing # functions for matching expression node names. clsname = obj.__class__.__name__ postprocessors = defaultdict(list) for i in obj.args: try: postprocessor_mappings = ( Basic._constructor_postprocessor_mapping[cls].items() for cls in type(i).mro() if cls in Basic._constructor_postprocessor_mapping ) for k, v in chain.from_iterable(postprocessor_mappings): postprocessors[k].extend([j for j in v if j not in postprocessors[k]]) except TypeError: pass for f in postprocessors.get(clsname, []): obj = f(obj) return obj class Atom(Basic): """ A parent class for atomic things. An atom is an expression with no subexpressions. Examples ======== Symbol, Number, Rational, Integer, ... But not: Add, Mul, Pow, ... """ is_Atom = True __slots__ = [] def matches(self, expr, repl_dict={}, old=False): if self == expr: return repl_dict def xreplace(self, rule, hack2=False): return rule.get(self, self) def doit(self, **hints): return self @classmethod def class_key(cls): return 2, 0, cls.__name__ @cacheit def sort_key(self, order=None): return self.class_key(), (1, (str(self),)), S.One.sort_key(), S.One def _eval_simplify(self, ratio, measure, rational, inverse): return self @property def _sorted_args(self): # this is here as a safeguard against accidentally using _sorted_args # on Atoms -- they cannot be rebuilt as atom.func(*atom._sorted_args) # since there are no args. So the calling routine should be checking # to see that this property is not called for Atoms. raise AttributeError('Atoms have no args. It might be necessary' ' to make a check for Atoms in the calling code.') def _aresame(a, b): """Return True if a and b are structurally the same, else False. Examples ======== To SymPy, 2.0 == 2: >>> from sympy import S >>> 2.0 == S(2) True Since a simple 'same or not' result is sometimes useful, this routine was written to provide that query: >>> from sympy.core.basic import _aresame >>> _aresame(S(2.0), S(2)) False """ from .function import AppliedUndef, UndefinedFunction as UndefFunc for i, j in zip_longest(preorder_traversal(a), preorder_traversal(b)): if i != j or type(i) != type(j): if ((isinstance(i, UndefFunc) and isinstance(j, UndefFunc)) or (isinstance(i, AppliedUndef) and isinstance(j, AppliedUndef))): if i.class_key() != j.class_key(): return False else: return False return True def _atomic(e, recursive=False): """Return atom-like quantities as far as substitution is concerned: Derivatives, Functions and Symbols. Don't return any 'atoms' that are inside such quantities unless they also appear outside, too, unless `recursive` is True. Examples ======== >>> from sympy import Derivative, Function, cos >>> from sympy.abc import x, y >>> from sympy.core.basic import _atomic >>> f = Function('f') >>> _atomic(x + y) {x, y} >>> _atomic(x + f(y)) {x, f(y)} >>> _atomic(Derivative(f(x), x) + cos(x) + y) {y, cos(x), Derivative(f(x), x)} """ from sympy import Derivative, Function, Symbol pot = preorder_traversal(e) seen = set() if isinstance(e, Basic): free = getattr(e, "free_symbols", None) if free is None: return {e} else: return set() atoms = set() for p in pot: if p in seen: pot.skip() continue seen.add(p) if isinstance(p, Symbol) and p in free: atoms.add(p) elif isinstance(p, (Derivative, Function)): if not recursive: pot.skip() atoms.add(p) return atoms class preorder_traversal(Iterator): """ Do a pre-order traversal of a tree. This iterator recursively yields nodes that it has visited in a pre-order fashion. That is, it yields the current node then descends through the tree breadth-first to yield all of a node's children's pre-order traversal. For an expression, the order of the traversal depends on the order of .args, which in many cases can be arbitrary. Parameters ========== node : sympy expression The expression to traverse. keys : (default None) sort key(s) The key(s) used to sort args of Basic objects. When None, args of Basic objects are processed in arbitrary order. If key is defined, it will be passed along to ordered() as the only key(s) to use to sort the arguments; if ``key`` is simply True then the default keys of ordered will be used. Yields ====== subtree : sympy expression All of the subtrees in the tree. Examples ======== >>> from sympy import symbols >>> from sympy.core.basic import preorder_traversal >>> x, y, z = symbols('x y z') The nodes are returned in the order that they are encountered unless key is given; simply passing key=True will guarantee that the traversal is unique. >>> list(preorder_traversal((x + y)*z, keys=None)) # doctest: +SKIP [z*(x + y), z, x + y, y, x] >>> list(preorder_traversal((x + y)*z, keys=True)) [z*(x + y), z, x + y, x, y] """ def __init__(self, node, keys=None): self._skip_flag = False self._pt = self._preorder_traversal(node, keys) def _preorder_traversal(self, node, keys): yield node if self._skip_flag: self._skip_flag = False return if isinstance(node, Basic): if not keys and hasattr(node, '_argset'): # LatticeOp keeps args as a set. We should use this if we # don't care about the order, to prevent unnecessary sorting. args = node._argset else: args = node.args if keys: if keys != True: args = ordered(args, keys, default=False) else: args = ordered(args) for arg in args: for subtree in self._preorder_traversal(arg, keys): yield subtree elif iterable(node): for item in node: for subtree in self._preorder_traversal(item, keys): yield subtree def skip(self): """ Skip yielding current node's (last yielded node's) subtrees. Examples ======== >>> from sympy.core import symbols >>> from sympy.core.basic import preorder_traversal >>> x, y, z = symbols('x y z') >>> pt = preorder_traversal((x+y*z)*z) >>> for i in pt: ... print(i) ... if i == x+y*z: ... pt.skip() z*(x + y*z) z x + y*z """ self._skip_flag = True def __next__(self): return next(self._pt) def __iter__(self): return self def _make_find_query(query): """Convert the argument of Basic.find() into a callable""" try: query = sympify(query) except SympifyError: pass if isinstance(query, type): return lambda expr: isinstance(expr, query) elif isinstance(query, Basic): return lambda expr: expr.match(query) is not None return query

5b80b2c6e01f5d665c9428266977c1c18bc7d2dfe6eb220b4ba50bfebab68d14

from __future__ import print_function, division from math import log as _log from .sympify import _sympify from .cache import cacheit from .singleton import S from .expr import Expr from .evalf import PrecisionExhausted from .function import (_coeff_isneg, expand_complex, expand_multinomial, expand_mul) from .logic import fuzzy_bool, fuzzy_not, fuzzy_and from .compatibility import as_int, range from .evaluate import global_evaluate from sympy.utilities.iterables import sift from mpmath.libmp import sqrtrem as mpmath_sqrtrem from math import sqrt as _sqrt def isqrt(n): """Return the largest integer less than or equal to sqrt(n).""" if n < 17984395633462800708566937239552: return int(_sqrt(n)) return integer_nthroot(int(n), 2)[0] def integer_nthroot(y, n): """ Return a tuple containing x = floor(y**(1/n)) and a boolean indicating whether the result is exact (that is, whether x**n == y). Examples ======== >>> from sympy import integer_nthroot >>> integer_nthroot(16, 2) (4, True) >>> integer_nthroot(26, 2) (5, False) To simply determine if a number is a perfect square, the is_square function should be used: >>> from sympy.ntheory.primetest import is_square >>> is_square(26) False See Also ======== sympy.ntheory.primetest.is_square integer_log """ y, n = as_int(y), as_int(n) if y < 0: raise ValueError("y must be nonnegative") if n < 1: raise ValueError("n must be positive") if y in (0, 1): return y, True if n == 1: return y, True if n == 2: x, rem = mpmath_sqrtrem(y) return int(x), not rem if n > y: return 1, False # Get initial estimate for Newton's method. Care must be taken to # avoid overflow try: guess = int(y**(1./n) + 0.5) except OverflowError: exp = _log(y, 2)/n if exp > 53: shift = int(exp - 53) guess = int(2.0**(exp - shift) + 1) << shift else: guess = int(2.0**exp) if guess > 2**50: # Newton iteration xprev, x = -1, guess while 1: t = x**(n - 1) xprev, x = x, ((n - 1)*x + y//t)//n if abs(x - xprev) < 2: break else: x = guess # Compensate t = x**n while t < y: x += 1 t = x**n while t > y: x -= 1 t = x**n return int(x), t == y # int converts long to int if possible def integer_log(y, x): """Returns (e, bool) where e is the largest nonnegative integer such that |y| >= |x**e| and bool is True if y == x**e Examples ======== >>> from sympy import integer_log >>> integer_log(125, 5) (3, True) >>> integer_log(17, 9) (1, False) >>> integer_log(4, -2) (2, True) >>> integer_log(-125,-5) (3, True) See Also ======== integer_nthroot sympy.ntheory.primetest.is_square sympy.ntheory.factor_.multiplicity sympy.ntheory.factor_.perfect_power """ if x == 1: raise ValueError('x cannot take value as 1') if y == 0: raise ValueError('y cannot take value as 0') if x in (-2, 2): x = int(x) y = as_int(y) e = y.bit_length() - 1 return e, x**e == y if x < 0: n, b = integer_log(y if y > 0 else -y, -x) return n, b and bool(n % 2 if y < 0 else not n % 2) x = as_int(x) y = as_int(y) r = e = 0 while y >= x: d = x m = 1 while y >= d: y, rem = divmod(y, d) r = r or rem e += m if y > d: d *= d m *= 2 return e, r == 0 and y == 1 class Pow(Expr): """ Defines the expression x**y as "x raised to a power y" Singleton definitions involving (0, 1, -1, oo, -oo, I, -I): +--------------+---------+-----------------------------------------------+ | expr | value | reason | +==============+=========+===============================================+ | z**0 | 1 | Although arguments over 0**0 exist, see [2]. | +--------------+---------+-----------------------------------------------+ | z**1 | z | | +--------------+---------+-----------------------------------------------+ | (-oo)**(-1) | 0 | | +--------------+---------+-----------------------------------------------+ | (-1)**-1 | -1 | | +--------------+---------+-----------------------------------------------+ | S.Zero**-1 | zoo | This is not strictly true, as 0**-1 may be | | | | undefined, but is convenient in some contexts | | | | where the base is assumed to be positive. | +--------------+---------+-----------------------------------------------+ | 1**-1 | 1 | | +--------------+---------+-----------------------------------------------+ | oo**-1 | 0 | | +--------------+---------+-----------------------------------------------+ | 0**oo | 0 | Because for all complex numbers z near | | | | 0, z**oo -> 0. | +--------------+---------+-----------------------------------------------+ | 0**-oo | zoo | This is not strictly true, as 0**oo may be | | | | oscillating between positive and negative | | | | values or rotating in the complex plane. | | | | It is convenient, however, when the base | | | | is positive. | +--------------+---------+-----------------------------------------------+ | 1**oo | nan | Because there are various cases where | | 1**-oo | | lim(x(t),t)=1, lim(y(t),t)=oo (or -oo), | | | | but lim( x(t)**y(t), t) != 1. See [3]. | +--------------+---------+-----------------------------------------------+ | b**zoo | nan | Because b**z has no limit as z -> zoo | +--------------+---------+-----------------------------------------------+ | (-1)**oo | nan | Because of oscillations in the limit. | | (-1)**(-oo) | | | +--------------+---------+-----------------------------------------------+ | oo**oo | oo | | +--------------+---------+-----------------------------------------------+ | oo**-oo | 0 | | +--------------+---------+-----------------------------------------------+ | (-oo)**oo | nan | | | (-oo)**-oo | | | +--------------+---------+-----------------------------------------------+ | oo**I | nan | oo**e could probably be best thought of as | | (-oo)**I | | the limit of x**e for real x as x tends to | | | | oo. If e is I, then the limit does not exist | | | | and nan is used to indicate that. | +--------------+---------+-----------------------------------------------+ | oo**(1+I) | zoo | If the real part of e is positive, then the | | (-oo)**(1+I) | | limit of abs(x**e) is oo. So the limit value | | | | is zoo. | +--------------+---------+-----------------------------------------------+ | oo**(-1+I) | 0 | If the real part of e is negative, then the | | -oo**(-1+I) | | limit is 0. | +--------------+---------+-----------------------------------------------+ Because symbolic computations are more flexible that floating point calculations and we prefer to never return an incorrect answer, we choose not to conform to all IEEE 754 conventions. This helps us avoid extra test-case code in the calculation of limits. See Also ======== sympy.core.numbers.Infinity sympy.core.numbers.NegativeInfinity sympy.core.numbers.NaN References ========== .. [1] https://en.wikipedia.org/wiki/Exponentiation .. [2] https://en.wikipedia.org/wiki/Exponentiation#Zero_to_the_power_of_zero .. [3] https://en.wikipedia.org/wiki/Indeterminate_forms """ is_Pow = True __slots__ = ['is_commutative'] @cacheit def __new__(cls, b, e, evaluate=None): if evaluate is None: evaluate = global_evaluate[0] from sympy.functions.elementary.exponential import exp_polar b = _sympify(b) e = _sympify(e) if evaluate: if e is S.ComplexInfinity: return S.NaN if e is S.Zero: return S.One elif e is S.One: return b # Only perform autosimplification if exponent or base is a Symbol or number elif (b.is_Symbol or b.is_number) and (e.is_Symbol or e.is_number) and\ e.is_integer and _coeff_isneg(b): if e.is_even: b = -b elif e.is_odd: return -Pow(-b, e) if S.NaN in (b, e): # XXX S.NaN**x -> S.NaN under assumption that x != 0 return S.NaN elif b is S.One: if abs(e).is_infinite: return S.NaN return S.One else: # recognize base as E if not e.is_Atom and b is not S.Exp1 and not isinstance(b, exp_polar): from sympy import numer, denom, log, sign, im, factor_terms c, ex = factor_terms(e, sign=False).as_coeff_Mul() den = denom(ex) if isinstance(den, log) and den.args[0] == b: return S.Exp1**(c*numer(ex)) elif den.is_Add: s = sign(im(b)) if s.is_Number and s and den == \ log(-factor_terms(b, sign=False)) + s*S.ImaginaryUnit*S.Pi: return S.Exp1**(c*numer(ex)) obj = b._eval_power(e) if obj is not None: return obj obj = Expr.__new__(cls, b, e) obj = cls._exec_constructor_postprocessors(obj) if not isinstance(obj, Pow): return obj obj.is_commutative = (b.is_commutative and e.is_commutative) return obj @property def base(self): return self._args[0] @property def exp(self): return self._args[1] @classmethod def class_key(cls): return 3, 2, cls.__name__ def _eval_refine(self, assumptions): from sympy.assumptions.ask import ask, Q b, e = self.as_base_exp() if ask(Q.integer(e), assumptions) and _coeff_isneg(b): if ask(Q.even(e), assumptions): return Pow(-b, e) elif ask(Q.odd(e), assumptions): return -Pow(-b, e) def _eval_power(self, other): from sympy import Abs, arg, exp, floor, im, log, re, sign b, e = self.as_base_exp() if b is S.NaN: return (b**e)**other # let __new__ handle it s = None if other.is_integer: s = 1 elif b.is_polar: # e.g. exp_polar, besselj, var('p', polar=True)... s = 1 elif e.is_real is not None: # helper functions =========================== def _half(e): """Return True if the exponent has a literal 2 as the denominator, else None.""" if getattr(e, 'q', None) == 2: return True n, d = e.as_numer_denom() if n.is_integer and d == 2: return True def _n2(e): """Return ``e`` evaluated to a Number with 2 significant digits, else None.""" try: rv = e.evalf(2, strict=True) if rv.is_Number: return rv except PrecisionExhausted: pass # =================================================== if e.is_real: # we need _half(other) with constant floor or # floor(S.Half - e*arg(b)/2/pi) == 0 # handle -1 as special case if e == -1: # floor arg. is 1/2 + arg(b)/2/pi if _half(other): if b.is_negative is True: return S.NegativeOne**other*Pow(-b, e*other) if b.is_real is False: return Pow(b.conjugate()/Abs(b)**2, other) elif e.is_even: if b.is_real: b = abs(b) if b.is_imaginary: b = abs(im(b))*S.ImaginaryUnit if (abs(e) < 1) == True or e == 1: s = 1 # floor = 0 elif b.is_nonnegative: s = 1 # floor = 0 elif re(b).is_nonnegative and (abs(e) < 2) == True: s = 1 # floor = 0 elif fuzzy_not(im(b).is_zero) and abs(e) == 2: s = 1 # floor = 0 elif _half(other): s = exp(2*S.Pi*S.ImaginaryUnit*other*floor( S.Half - e*arg(b)/(2*S.Pi))) if s.is_real and _n2(sign(s) - s) == 0: s = sign(s) else: s = None else: # e.is_real is False requires: # _half(other) with constant floor or # floor(S.Half - im(e*log(b))/2/pi) == 0 try: s = exp(2*S.ImaginaryUnit*S.Pi*other* floor(S.Half - im(e*log(b))/2/S.Pi)) # be careful to test that s is -1 or 1 b/c sign(I) == I: # so check that s is real if s.is_real and _n2(sign(s) - s) == 0: s = sign(s) else: s = None except PrecisionExhausted: s = None if s is not None: return s*Pow(b, e*other) def _eval_Mod(self, q): if self.exp.is_integer and self.exp.is_positive: if q.is_integer and self.base % q == 0: return S.Zero ''' For unevaluated Integer power, use built-in pow modular exponentiation, if powers are not too large wrt base. ''' if self.base.is_Integer and self.exp.is_Integer and q.is_Integer: b, e, m = int(self.base), int(self.exp), int(q) # For very large powers, use totient reduction if e >= lg(m). # Bound on m, is for safe factorization memory wise ie m^(1/4). # For pollard-rho to be faster than built-in pow lg(e) > m^(1/4) # check is added. mb = m.bit_length() if mb <= 80 and e >= mb and e.bit_length()**4 >= m: from sympy.ntheory import totient phi = totient(m) return pow(b, phi + e%phi, m) else: return pow(b, e, m) def _eval_is_even(self): if self.exp.is_integer and self.exp.is_positive: return self.base.is_even def _eval_is_positive(self): from sympy import log if self.base == self.exp: if self.base.is_nonnegative: return True elif self.base.is_positive: if self.exp.is_real: return True elif self.base.is_negative: if self.exp.is_even: return True if self.exp.is_odd: return False elif self.base.is_zero: if self.exp.is_real: return self.exp.is_zero elif self.base.is_nonpositive: if self.exp.is_odd: return False elif self.base.is_imaginary: if self.exp.is_integer: m = self.exp % 4 if m.is_zero: return True if m.is_integer and m.is_zero is False: return False if self.exp.is_imaginary: return log(self.base).is_imaginary def _eval_is_negative(self): if self.base.is_negative: if self.exp.is_odd: return True if self.exp.is_even: return False elif self.base.is_positive: if self.exp.is_real: return False elif self.base.is_zero: if self.exp.is_real: return False elif self.base.is_nonnegative: if self.exp.is_nonnegative: return False elif self.base.is_nonpositive: if self.exp.is_even: return False elif self.base.is_real: if self.exp.is_even: return False def _eval_is_zero(self): if self.base.is_zero: if self.exp.is_positive: return True elif self.exp.is_nonpositive: return False elif self.base.is_zero is False: if self.exp.is_finite: return False elif self.exp.is_infinite: if (1 - abs(self.base)).is_positive: return self.exp.is_positive elif (1 - abs(self.base)).is_negative: return self.exp.is_negative else: # when self.base.is_zero is None return None def _eval_is_integer(self): b, e = self.args if b.is_rational: if b.is_integer is False and e.is_positive: return False # rat**nonneg if b.is_integer and e.is_integer: if b is S.NegativeOne: return True if e.is_nonnegative or e.is_positive: return True if b.is_integer and e.is_negative and (e.is_finite or e.is_integer): if fuzzy_not((b - 1).is_zero) and fuzzy_not((b + 1).is_zero): return False if b.is_Number and e.is_Number: check = self.func(*self.args) return check.is_Integer def _eval_is_real(self): from sympy import arg, exp, log, Mul real_b = self.base.is_real if real_b is None: if self.base.func == exp and self.base.args[0].is_imaginary: return self.exp.is_imaginary return real_e = self.exp.is_real if real_e is None: return if real_b and real_e: if self.base.is_positive: return True elif self.base.is_nonnegative: if self.exp.is_nonnegative: return True else: if self.exp.is_integer: return True elif self.base.is_negative: if self.exp.is_Rational: return False if real_e and self.exp.is_negative: return Pow(self.base, -self.exp).is_real im_b = self.base.is_imaginary im_e = self.exp.is_imaginary if im_b: if self.exp.is_integer: if self.exp.is_even: return True elif self.exp.is_odd: return False elif im_e and log(self.base).is_imaginary: return True elif self.exp.is_Add: c, a = self.exp.as_coeff_Add() if c and c.is_Integer: return Mul( self.base**c, self.base**a, evaluate=False).is_real elif self.base in (-S.ImaginaryUnit, S.ImaginaryUnit): if (self.exp/2).is_integer is False: return False if real_b and im_e: if self.base is S.NegativeOne: return True c = self.exp.coeff(S.ImaginaryUnit) if c: ok = (c*log(self.base)/S.Pi).is_Integer if ok is not None: return ok if real_b is False: # we already know it's not imag i = arg(self.base)*self.exp/S.Pi return i.is_integer def _eval_is_complex(self): if all(a.is_complex for a in self.args): return True def _eval_is_imaginary(self): from sympy import arg, log if self.base.is_imaginary: if self.exp.is_integer: odd = self.exp.is_odd if odd is not None: return odd return if self.exp.is_imaginary: imlog = log(self.base).is_imaginary if imlog is not None: return False # I**i -> real; (2*I)**i -> complex ==> not imaginary if self.base.is_real and self.exp.is_real: if self.base.is_positive: return False else: rat = self.exp.is_rational if not rat: return rat if self.exp.is_integer: return False else: half = (2*self.exp).is_integer if half: return self.base.is_negative return half if self.base.is_real is False: # we already know it's not imag i = arg(self.base)*self.exp/S.Pi isodd = (2*i).is_odd if isodd is not None: return isodd if self.exp.is_negative: return (1/self).is_imaginary def _eval_is_odd(self): if self.exp.is_integer: if self.exp.is_positive: return self.base.is_odd elif self.exp.is_nonnegative and self.base.is_odd: return True elif self.base is S.NegativeOne: return True def _eval_is_finite(self): if self.exp.is_negative: if self.base.is_zero: return False if self.base.is_infinite: return True c1 = self.base.is_finite if c1 is None: return c2 = self.exp.is_finite if c2 is None: return if c1 and c2: if self.exp.is_nonnegative or fuzzy_not(self.base.is_zero): return True def _eval_is_prime(self): ''' An integer raised to the n(>=2)-th power cannot be a prime. ''' if self.base.is_integer and self.exp.is_integer and (self.exp - 1).is_positive: return False def _eval_is_composite(self): """ A power is composite if both base and exponent are greater than 1 """ if (self.base.is_integer and self.exp.is_integer and ((self.base - 1).is_positive and (self.exp - 1).is_positive or (self.base + 1).is_negative and self.exp.is_positive and self.exp.is_even)): return True def _eval_is_polar(self): return self.base.is_polar def _eval_subs(self, old, new): from sympy import exp, log, Symbol def _check(ct1, ct2, old): """Return (bool, pow, remainder_pow) where, if bool is True, then the exponent of Pow `old` will combine with `pow` so the substitution is valid, otherwise bool will be False. For noncommutative objects, `pow` will be an integer, and a factor `Pow(old.base, remainder_pow)` needs to be included. If there is no such factor, None is returned. For commutative objects, remainder_pow is always None. cti are the coefficient and terms of an exponent of self or old In this _eval_subs routine a change like (b**(2*x)).subs(b**x, y) will give y**2 since (b**x)**2 == b**(2*x); if that equality does not hold then the substitution should not occur so `bool` will be False. """ coeff1, terms1 = ct1 coeff2, terms2 = ct2 if terms1 == terms2: if old.is_commutative: # Allow fractional powers for commutative objects pow = coeff1/coeff2 try: pow = as_int(pow, strict=False) combines = True except ValueError: combines = isinstance(Pow._eval_power( Pow(*old.as_base_exp(), evaluate=False), pow), (Pow, exp, Symbol)) return combines, pow, None else: # With noncommutative symbols, substitute only integer powers if not isinstance(terms1, tuple): terms1 = (terms1,) if not all(term.is_integer for term in terms1): return False, None, None try: # Round pow toward zero pow, remainder = divmod(as_int(coeff1), as_int(coeff2)) if pow < 0 and remainder != 0: pow += 1 remainder -= as_int(coeff2) if remainder == 0: remainder_pow = None else: remainder_pow = Mul(remainder, *terms1) return True, pow, remainder_pow except ValueError: # Can't substitute pass return False, None, None if old == self.base: return new**self.exp._subs(old, new) # issue 10829: (4**x - 3*y + 2).subs(2**x, y) -> y**2 - 3*y + 2 if isinstance(old, self.func) and self.exp == old.exp: l = log(self.base, old.base) if l.is_Number: return Pow(new, l) if isinstance(old, self.func) and self.base == old.base: if self.exp.is_Add is False: ct1 = self.exp.as_independent(Symbol, as_Add=False) ct2 = old.exp.as_independent(Symbol, as_Add=False) ok, pow, remainder_pow = _check(ct1, ct2, old) if ok: # issue 5180: (x**(6*y)).subs(x**(3*y),z)->z**2 result = self.func(new, pow) if remainder_pow is not None: result = Mul(result, Pow(old.base, remainder_pow)) return result else: # b**(6*x + a).subs(b**(3*x), y) -> y**2 * b**a # exp(exp(x) + exp(x**2)).subs(exp(exp(x)), w) -> w * exp(exp(x**2)) oarg = old.exp new_l = [] o_al = [] ct2 = oarg.as_coeff_mul() for a in self.exp.args: newa = a._subs(old, new) ct1 = newa.as_coeff_mul() ok, pow, remainder_pow = _check(ct1, ct2, old) if ok: new_l.append(new**pow) if remainder_pow is not None: o_al.append(remainder_pow) continue elif not old.is_commutative and not newa.is_integer: # If any term in the exponent is non-integer, # we do not do any substitutions in the noncommutative case return o_al.append(newa) if new_l: expo = Add(*o_al) new_l.append(Pow(self.base, expo, evaluate=False) if expo != 1 else self.base) return Mul(*new_l) if isinstance(old, exp) and self.exp.is_real and self.base.is_positive: ct1 = old.args[0].as_independent(Symbol, as_Add=False) ct2 = (self.exp*log(self.base)).as_independent( Symbol, as_Add=False) ok, pow, remainder_pow = _check(ct1, ct2, old) if ok: result = self.func(new, pow) # (2**x).subs(exp(x*log(2)), z) -> z if remainder_pow is not None: result = Mul(result, Pow(old.base, remainder_pow)) return result def as_base_exp(self): """Return base and exp of self. If base is 1/Integer, then return Integer, -exp. If this extra processing is not needed, the base and exp properties will give the raw arguments Examples ======== >>> from sympy import Pow, S >>> p = Pow(S.Half, 2, evaluate=False) >>> p.as_base_exp() (2, -2) >>> p.args (1/2, 2) """ b, e = self.args if b.is_Rational and b.p == 1 and b.q != 1: return Integer(b.q), -e return b, e def _eval_adjoint(self): from sympy.functions.elementary.complexes import adjoint i, p = self.exp.is_integer, self.base.is_positive if i: return adjoint(self.base)**self.exp if p: return self.base**adjoint(self.exp) if i is False and p is False: expanded = expand_complex(self) if expanded != self: return adjoint(expanded) def _eval_conjugate(self): from sympy.functions.elementary.complexes import conjugate as c i, p = self.exp.is_integer, self.base.is_positive if i: return c(self.base)**self.exp if p: return self.base**c(self.exp) if i is False and p is False: expanded = expand_complex(self) if expanded != self: return c(expanded) if self.is_real: return self def _eval_transpose(self): from sympy.functions.elementary.complexes import transpose i, p = self.exp.is_integer, self.base.is_complex if p: return self.base**self.exp if i: return transpose(self.base)**self.exp if i is False and p is False: expanded = expand_complex(self) if expanded != self: return transpose(expanded) def _eval_expand_power_exp(self, **hints): """a**(n + m) -> a**n*a**m""" b = self.base e = self.exp if e.is_Add and e.is_commutative: expr = [] for x in e.args: expr.append(self.func(self.base, x)) return Mul(*expr) return self.func(b, e) def _eval_expand_power_base(self, **hints): """(a*b)**n -> a**n * b**n""" force = hints.get('force', False) b = self.base e = self.exp if not b.is_Mul: return self cargs, nc = b.args_cnc(split_1=False) # expand each term - this is top-level-only # expansion but we have to watch out for things # that don't have an _eval_expand method if nc: nc = [i._eval_expand_power_base(**hints) if hasattr(i, '_eval_expand_power_base') else i for i in nc] if e.is_Integer: if e.is_positive: rv = Mul(*nc*e) else: rv = Mul(*[i**-1 for i in nc[::-1]]*-e) if cargs: rv *= Mul(*cargs)**e return rv if not cargs: return self.func(Mul(*nc), e, evaluate=False) nc = [Mul(*nc)] # sift the commutative bases other, maybe_real = sift(cargs, lambda x: x.is_real is False, binary=True) def pred(x): if x is S.ImaginaryUnit: return S.ImaginaryUnit polar = x.is_polar if polar: return True if polar is None: return fuzzy_bool(x.is_nonnegative) sifted = sift(maybe_real, pred) nonneg = sifted[True] other += sifted[None] neg = sifted[False] imag = sifted[S.ImaginaryUnit] if imag: I = S.ImaginaryUnit i = len(imag) % 4 if i == 0: pass elif i == 1: other.append(I) elif i == 2: if neg: nonn = -neg.pop() if nonn is not S.One: nonneg.append(nonn) else: neg.append(S.NegativeOne) else: if neg: nonn = -neg.pop() if nonn is not S.One: nonneg.append(nonn) else: neg.append(S.NegativeOne) other.append(I) del imag # bring out the bases that can be separated from the base if force or e.is_integer: # treat all commutatives the same and put nc in other cargs = nonneg + neg + other other = nc else: # this is just like what is happening automatically, except # that now we are doing it for an arbitrary exponent for which # no automatic expansion is done assert not e.is_Integer # handle negatives by making them all positive and putting # the residual -1 in other if len(neg) > 1: o = S.One if not other and neg[0].is_Number: o *= neg.pop(0) if len(neg) % 2: o = -o for n in neg: nonneg.append(-n) if o is not S.One: other.append(o) elif neg and other: if neg[0].is_Number and neg[0] is not S.NegativeOne: other.append(S.NegativeOne) nonneg.append(-neg[0]) else: other.extend(neg) else: other.extend(neg) del neg cargs = nonneg other += nc rv = S.One if cargs: rv *= Mul(*[self.func(b, e, evaluate=False) for b in cargs]) if other: rv *= self.func(Mul(*other), e, evaluate=False) return rv def _eval_expand_multinomial(self, **hints): """(a + b + ..)**n -> a**n + n*a**(n-1)*b + .., n is nonzero integer""" base, exp = self.args result = self if exp.is_Rational and exp.p > 0 and base.is_Add: if not exp.is_Integer: n = Integer(exp.p // exp.q) if not n: return result else: radical, result = self.func(base, exp - n), [] expanded_base_n = self.func(base, n) if expanded_base_n.is_Pow: expanded_base_n = \ expanded_base_n._eval_expand_multinomial() for term in Add.make_args(expanded_base_n): result.append(term*radical) return Add(*result) n = int(exp) if base.is_commutative: order_terms, other_terms = [], [] for b in base.args: if b.is_Order: order_terms.append(b) else: other_terms.append(b) if order_terms: # (f(x) + O(x^n))^m -> f(x)^m + m*f(x)^{m-1} *O(x^n) f = Add(*other_terms) o = Add(*order_terms) if n == 2: return expand_multinomial(f**n, deep=False) + n*f*o else: g = expand_multinomial(f**(n - 1), deep=False) return expand_mul(f*g, deep=False) + n*g*o if base.is_number: # Efficiently expand expressions of the form (a + b*I)**n # where 'a' and 'b' are real numbers and 'n' is integer. a, b = base.as_real_imag() if a.is_Rational and b.is_Rational: if not a.is_Integer: if not b.is_Integer: k = self.func(a.q * b.q, n) a, b = a.p*b.q, a.q*b.p else: k = self.func(a.q, n) a, b = a.p, a.q*b elif not b.is_Integer: k = self.func(b.q, n) a, b = a*b.q, b.p else: k = 1 a, b, c, d = int(a), int(b), 1, 0 while n: if n & 1: c, d = a*c - b*d, b*c + a*d n -= 1 a, b = a*a - b*b, 2*a*b n //= 2 I = S.ImaginaryUnit if k == 1: return c + I*d else: return Integer(c)/k + I*d/k p = other_terms # (x + y)**3 -> x**3 + 3*x**2*y + 3*x*y**2 + y**3 # in this particular example: # p = [x,y]; n = 3 # so now it's easy to get the correct result -- we get the # coefficients first: from sympy import multinomial_coefficients from sympy.polys.polyutils import basic_from_dict expansion_dict = multinomial_coefficients(len(p), n) # in our example: {(3, 0): 1, (1, 2): 3, (0, 3): 1, (2, 1): 3} # and now construct the expression. return basic_from_dict(expansion_dict, *p) else: if n == 2: return Add(*[f*g for f in base.args for g in base.args]) else: multi = (base**(n - 1))._eval_expand_multinomial() if multi.is_Add: return Add(*[f*g for f in base.args for g in multi.args]) else: # XXX can this ever happen if base was an Add? return Add(*[f*multi for f in base.args]) elif (exp.is_Rational and exp.p < 0 and base.is_Add and abs(exp.p) > exp.q): return 1 / self.func(base, -exp)._eval_expand_multinomial() elif exp.is_Add and base.is_Number: # a + b a b # n --> n n , where n, a, b are Numbers coeff, tail = S.One, S.Zero for term in exp.args: if term.is_Number: coeff *= self.func(base, term) else: tail += term return coeff * self.func(base, tail) else: return result def as_real_imag(self, deep=True, **hints): from sympy import atan2, cos, im, re, sin from sympy.polys.polytools import poly if self.exp.is_Integer: exp = self.exp re, im = self.base.as_real_imag(deep=deep) if not im: return self, S.Zero a, b = symbols('a b', cls=Dummy) if exp >= 0: if re.is_Number and im.is_Number: # We can be more efficient in this case expr = expand_multinomial(self.base**exp) if expr != self: return expr.as_real_imag() expr = poly( (a + b)**exp) # a = re, b = im; expr = (a + b*I)**exp else: mag = re**2 + im**2 re, im = re/mag, -im/mag if re.is_Number and im.is_Number: # We can be more efficient in this case expr = expand_multinomial((re + im*S.ImaginaryUnit)**-exp) if expr != self: return expr.as_real_imag() expr = poly((a + b)**-exp) # Terms with even b powers will be real r = [i for i in expr.terms() if not i[0][1] % 2] re_part = Add(*[cc*a**aa*b**bb for (aa, bb), cc in r]) # Terms with odd b powers will be imaginary r = [i for i in expr.terms() if i[0][1] % 4 == 1] im_part1 = Add(*[cc*a**aa*b**bb for (aa, bb), cc in r]) r = [i for i in expr.terms() if i[0][1] % 4 == 3] im_part3 = Add(*[cc*a**aa*b**bb for (aa, bb), cc in r]) return (re_part.subs({a: re, b: S.ImaginaryUnit*im}), im_part1.subs({a: re, b: im}) + im_part3.subs({a: re, b: -im})) elif self.exp.is_Rational: re, im = self.base.as_real_imag(deep=deep) if im.is_zero and self.exp is S.Half: if re.is_nonnegative: return self, S.Zero if re.is_nonpositive: return S.Zero, (-self.base)**self.exp # XXX: This is not totally correct since for x**(p/q) with # x being imaginary there are actually q roots, but # only a single one is returned from here. r = self.func(self.func(re, 2) + self.func(im, 2), S.Half) t = atan2(im, re) rp, tp = self.func(r, self.exp), t*self.exp return (rp*cos(tp), rp*sin(tp)) else: if deep: hints['complex'] = False expanded = self.expand(deep, **hints) if hints.get('ignore') == expanded: return None else: return (re(expanded), im(expanded)) else: return (re(self), im(self)) def _eval_derivative(self, s): from sympy import log dbase = self.base.diff(s) dexp = self.exp.diff(s) return self * (dexp * log(self.base) + dbase * self.exp/self.base) def _eval_evalf(self, prec): base, exp = self.as_base_exp() base = base._evalf(prec) if not exp.is_Integer: exp = exp._evalf(prec) if exp.is_negative and base.is_number and base.is_real is False: base = base.conjugate() / (base * base.conjugate())._evalf(prec) exp = -exp return self.func(base, exp).expand() return self.func(base, exp) def _eval_is_polynomial(self, syms): if self.exp.has(*syms): return False if self.base.has(*syms): return bool(self.base._eval_is_polynomial(syms) and self.exp.is_Integer and (self.exp >= 0)) else: return True def _eval_is_rational(self): # The evaluation of self.func below can be very expensive in the case # of integer**integer if the exponent is large. We should try to exit # before that if possible: if (self.exp.is_integer and self.base.is_rational and fuzzy_not(fuzzy_and([self.exp.is_negative, self.base.is_zero]))): return True p = self.func(*self.as_base_exp()) # in case it's unevaluated if not p.is_Pow: return p.is_rational b, e = p.as_base_exp() if e.is_Rational and b.is_Rational: # we didn't check that e is not an Integer # because Rational**Integer autosimplifies return False if e.is_integer: if b.is_rational: if fuzzy_not(b.is_zero) or e.is_nonnegative: return True if b == e: # always rational, even for 0**0 return True elif b.is_irrational: return e.is_zero def _eval_is_algebraic(self): def _is_one(expr): try: return (expr - 1).is_zero except ValueError: # when the operation is not allowed return False if self.base.is_zero or _is_one(self.base): return True elif self.exp.is_rational: if self.base.is_algebraic is False: return self.exp.is_zero return self.base.is_algebraic elif self.base.is_algebraic and self.exp.is_algebraic: if ((fuzzy_not(self.base.is_zero) and fuzzy_not(_is_one(self.base))) or self.base.is_integer is False or self.base.is_irrational): return self.exp.is_rational def _eval_is_rational_function(self, syms): if self.exp.has(*syms): return False if self.base.has(*syms): return self.base._eval_is_rational_function(syms) and \ self.exp.is_Integer else: return True def _eval_is_algebraic_expr(self, syms): if self.exp.has(*syms): return False if self.base.has(*syms): return self.base._eval_is_algebraic_expr(syms) and \ self.exp.is_Rational else: return True def _eval_rewrite_as_exp(self, base, expo, **kwargs): from sympy import exp, log, I, arg if base.is_zero or base.has(exp) or expo.has(exp): return base**expo if base.has(Symbol): # delay evaluation if expo is non symbolic # (as exp(x*log(5)) automatically reduces to x**5) return exp(log(base)*expo, evaluate=expo.has(Symbol)) else: return exp((log(abs(base)) + I*arg(base))*expo) def as_numer_denom(self): if not self.is_commutative: return self, S.One base, exp = self.as_base_exp() n, d = base.as_numer_denom() # this should be the same as ExpBase.as_numer_denom wrt # exponent handling neg_exp = exp.is_negative if not neg_exp and not (-exp).is_negative: neg_exp = _coeff_isneg(exp) int_exp = exp.is_integer # the denominator cannot be separated from the numerator if # its sign is unknown unless the exponent is an integer, e.g. # sqrt(a/b) != sqrt(a)/sqrt(b) when a=1 and b=-1. But if the # denominator is negative the numerator and denominator can # be negated and the denominator (now positive) separated. if not (d.is_real or int_exp): n = base d = S.One dnonpos = d.is_nonpositive if dnonpos: n, d = -n, -d elif dnonpos is None and not int_exp: n = base d = S.One if neg_exp: n, d = d, n exp = -exp if exp.is_infinite: if n is S.One and d is not S.One: return n, self.func(d, exp) if n is not S.One and d is S.One: return self.func(n, exp), d return self.func(n, exp), self.func(d, exp) def matches(self, expr, repl_dict={}, old=False): expr = _sympify(expr) # special case, pattern = 1 and expr.exp can match to 0 if expr is S.One: d = repl_dict.copy() d = self.exp.matches(S.Zero, d) if d is not None: return d # make sure the expression to be matched is an Expr if not isinstance(expr, Expr): return None b, e = expr.as_base_exp() # special case number sb, se = self.as_base_exp() if sb.is_Symbol and se.is_Integer and expr: if e.is_rational: return sb.matches(b**(e/se), repl_dict) return sb.matches(expr**(1/se), repl_dict) d = repl_dict.copy() d = self.base.matches(b, d) if d is None: return None d = self.exp.xreplace(d).matches(e, d) if d is None: return Expr.matches(self, expr, repl_dict) return d def _eval_nseries(self, x, n, logx): # NOTE! This function is an important part of the gruntz algorithm # for computing limits. It has to return a generalized power # series with coefficients in C(log, log(x)). In more detail: # It has to return an expression # c_0*x**e_0 + c_1*x**e_1 + ... (finitely many terms) # where e_i are numbers (not necessarily integers) and c_i are # expressions involving only numbers, the log function, and log(x). from sympy import ceiling, collect, exp, log, O, Order, powsimp b, e = self.args if e.is_Integer: if e > 0: # positive integer powers are easy to expand, e.g.: # sin(x)**4 = (x - x**3/3 + ...)**4 = ... return expand_multinomial(self.func(b._eval_nseries(x, n=n, logx=logx), e), deep=False) elif e is S.NegativeOne: # this is also easy to expand using the formula: # 1/(1 + x) = 1 - x + x**2 - x**3 ... # so we need to rewrite base to the form "1 + x" nuse = n cf = 1 try: ord = b.as_leading_term(x) cf = Order(ord, x).getn() if cf and cf.is_Number: nuse = n + 2*ceiling(cf) else: cf = 1 except NotImplementedError: pass b_orig, prefactor = b, O(1, x) while prefactor.is_Order: nuse += 1 b = b_orig._eval_nseries(x, n=nuse, logx=logx) prefactor = b.as_leading_term(x) # express "rest" as: rest = 1 + k*x**l + ... + O(x**n) rest = expand_mul((b - prefactor)/prefactor) if rest.is_Order: return 1/prefactor + rest/prefactor + O(x**n, x) k, l = rest.leadterm(x) if l.is_Rational and l > 0: pass elif l.is_number and l > 0: l = l.evalf() elif l == 0: k = k.simplify() if k == 0: # if prefactor == w**4 + x**2*w**4 + 2*x*w**4, we need to # factor the w**4 out using collect: return 1/collect(prefactor, x) else: raise NotImplementedError() else: raise NotImplementedError() if cf < 0: cf = S.One/abs(cf) try: dn = Order(1/prefactor, x).getn() if dn and dn < 0: pass else: dn = 0 except NotImplementedError: dn = 0 terms = [1/prefactor] for m in range(1, ceiling((n - dn + 1)/l*cf)): new_term = terms[-1]*(-rest) if new_term.is_Pow: new_term = new_term._eval_expand_multinomial( deep=False) else: new_term = expand_mul(new_term, deep=False) terms.append(new_term) terms.append(O(x**n, x)) return powsimp(Add(*terms), deep=True, combine='exp') else: # negative powers are rewritten to the cases above, for # example: # sin(x)**(-4) = 1/(sin(x)**4) = ... # and expand the denominator: nuse, denominator = n, O(1, x) while denominator.is_Order: denominator = (b**(-e))._eval_nseries(x, n=nuse, logx=logx) nuse += 1 if 1/denominator == self: return self # now we have a type 1/f(x), that we know how to expand return (1/denominator)._eval_nseries(x, n=n, logx=logx) if e.has(Symbol): return exp(e*log(b))._eval_nseries(x, n=n, logx=logx) # see if the base is as simple as possible bx = b while bx.is_Pow and bx.exp.is_Rational: bx = bx.base if bx == x: return self # work for b(x)**e where e is not an Integer and does not contain x # and hopefully has no other symbols def e2int(e): """return the integer value (if possible) of e and a flag indicating whether it is bounded or not.""" n = e.limit(x, 0) infinite = n.is_infinite if not infinite: # XXX was int or floor intended? int used to behave like floor # so int(-Rational(1, 2)) returned -1 rather than int's 0 try: n = int(n) except TypeError: # well, the n is something more complicated (like 1 + log(2)) try: n = int(n.evalf()) + 1 # XXX why is 1 being added? except TypeError: pass # hope that base allows this to be resolved n = _sympify(n) return n, infinite order = O(x**n, x) ei, infinite = e2int(e) b0 = b.limit(x, 0) if infinite and (b0 is S.One or b0.has(Symbol)): # XXX what order if b0 is S.One: resid = (b - 1) if resid.is_positive: return S.Infinity elif resid.is_negative: return S.Zero raise ValueError('cannot determine sign of %s' % resid) return b0**ei if (b0 is S.Zero or b0.is_infinite): if infinite is not False: return b0**e # XXX what order if not ei.is_number: # if not, how will we proceed? raise ValueError( 'expecting numerical exponent but got %s' % ei) nuse = n - ei if e.is_real and e.is_positive: lt = b.as_leading_term(x) # Try to correct nuse (= m) guess from: # (lt + rest + O(x**m))**e = # lt**e*(1 + rest/lt + O(x**m)/lt)**e = # lt**e + ... + O(x**m)*lt**(e - 1) = ... + O(x**n) try: cf = Order(lt, x).getn() nuse = ceiling(n - cf*(e - 1)) except NotImplementedError: pass bs = b._eval_nseries(x, n=nuse, logx=logx) terms = bs.removeO() if terms.is_Add: bs = terms lt = terms.as_leading_term(x) # bs -> lt + rest -> lt*(1 + (bs/lt - 1)) return ((self.func(lt, e) * self.func((bs/lt).expand(), e).nseries( x, n=nuse, logx=logx)).expand() + order) if bs.is_Add: from sympy import O # So, bs + O() == terms c = Dummy('c') res = [] for arg in bs.args: if arg.is_Order: arg = c*arg.expr res.append(arg) bs = Add(*res) rv = (bs**e).series(x).subs(c, O(1, x)) rv += order return rv rv = bs**e if terms != bs: rv += order return rv # either b0 is bounded but neither 1 nor 0 or e is infinite # b -> b0 + (b - b0) -> b0 * (1 + (b/b0 - 1)) o2 = order*(b0**-e) z = (b/b0 - 1) o = O(z, x) if o is S.Zero or o2 is S.Zero: infinite = True else: if o.expr.is_number: e2 = log(o2.expr*x)/log(x) else: e2 = log(o2.expr)/log(o.expr) n, infinite = e2int(e2) if infinite: # requested accuracy gives infinite series, # order is probably non-polynomial e.g. O(exp(-1/x), x). r = 1 + z else: l = [] g = None for i in range(n + 2): g = self._taylor_term(i, z, g) g = g.nseries(x, n=n, logx=logx) l.append(g) r = Add(*l) return expand_mul(r*b0**e) + order def _eval_as_leading_term(self, x): from sympy import exp, log if not self.exp.has(x): return self.func(self.base.as_leading_term(x), self.exp) return exp(self.exp * log(self.base)).as_leading_term(x) @cacheit def _taylor_term(self, n, x, *previous_terms): # of (1 + x)**e from sympy import binomial return binomial(self.exp, n) * self.func(x, n) def _sage_(self): return self.args[0]._sage_()**self.args[1]._sage_() def as_content_primitive(self, radical=False, clear=True): """Return the tuple (R, self/R) where R is the positive Rational extracted from self. Examples ======== >>> from sympy import sqrt >>> sqrt(4 + 4*sqrt(2)).as_content_primitive() (2, sqrt(1 + sqrt(2))) >>> sqrt(3 + 3*sqrt(2)).as_content_primitive() (1, sqrt(3)*sqrt(1 + sqrt(2))) >>> from sympy import expand_power_base, powsimp, Mul >>> from sympy.abc import x, y >>> ((2*x + 2)**2).as_content_primitive() (4, (x + 1)**2) >>> (4**((1 + y)/2)).as_content_primitive() (2, 4**(y/2)) >>> (3**((1 + y)/2)).as_content_primitive() (1, 3**((y + 1)/2)) >>> (3**((5 + y)/2)).as_content_primitive() (9, 3**((y + 1)/2)) >>> eq = 3**(2 + 2*x) >>> powsimp(eq) == eq True >>> eq.as_content_primitive() (9, 3**(2*x)) >>> powsimp(Mul(*_)) 3**(2*x + 2) >>> eq = (2 + 2*x)**y >>> s = expand_power_base(eq); s.is_Mul, s (False, (2*x + 2)**y) >>> eq.as_content_primitive() (1, (2*(x + 1))**y) >>> s = expand_power_base(_[1]); s.is_Mul, s (True, 2**y*(x + 1)**y) See docstring of Expr.as_content_primitive for more examples. """ b, e = self.as_base_exp() b = _keep_coeff(*b.as_content_primitive(radical=radical, clear=clear)) ce, pe = e.as_content_primitive(radical=radical, clear=clear) if b.is_Rational: #e #= ce*pe #= ce*(h + t) #= ce*h + ce*t #=> self #= b**(ce*h)*b**(ce*t) #= b**(cehp/cehq)*b**(ce*t) #= b**(iceh + r/cehq)*b**(ce*t) #= b**(iceh)*b**(r/cehq)*b**(ce*t) #= b**(iceh)*b**(ce*t + r/cehq) h, t = pe.as_coeff_Add() if h.is_Rational: ceh = ce*h c = self.func(b, ceh) r = S.Zero if not c.is_Rational: iceh, r = divmod(ceh.p, ceh.q) c = self.func(b, iceh) return c, self.func(b, _keep_coeff(ce, t + r/ce/ceh.q)) e = _keep_coeff(ce, pe) # b**e = (h*t)**e = h**e*t**e = c*m*t**e if e.is_Rational and b.is_Mul: h, t = b.as_content_primitive(radical=radical, clear=clear) # h is positive c, m = self.func(h, e).as_coeff_Mul() # so c is positive m, me = m.as_base_exp() if m is S.One or me == e: # probably always true # return the following, not return c, m*Pow(t, e) # which would change Pow into Mul; we let sympy # decide what to do by using the unevaluated Mul, e.g # should it stay as sqrt(2 + 2*sqrt(5)) or become # sqrt(2)*sqrt(1 + sqrt(5)) return c, self.func(_keep_coeff(m, t), e) return S.One, self.func(b, e) def is_constant(self, *wrt, **flags): expr = self if flags.get('simplify', True): expr = expr.simplify() b, e = expr.as_base_exp() bz = b.equals(0) if bz: # recalculate with assumptions in case it's unevaluated new = b**e if new != expr: return new.is_constant() econ = e.is_constant(*wrt) bcon = b.is_constant(*wrt) if bcon: if econ: return True bz = b.equals(0) if bz is False: return False elif bcon is None: return None return e.equals(0) def _eval_difference_delta(self, n, step): b, e = self.args if e.has(n) and not b.has(n): new_e = e.subs(n, n + step) return (b**(new_e - e) - 1) * self from .add import Add from .numbers import Integer from .mul import Mul, _keep_coeff from .symbol import Symbol, Dummy, symbols

946c4872925588ffcb23cffa550d91c9157e1b6025880efb62d914ff58b78701

"""Tools for manipulating of large commutative expressions. """ from __future__ import print_function, division from sympy.core.add import Add from sympy.core.compatibility import iterable, is_sequence, SYMPY_INTS, range from sympy.core.mul import Mul, _keep_coeff from sympy.core.power import Pow from sympy.core.basic import Basic, preorder_traversal from sympy.core.expr import Expr from sympy.core.sympify import sympify from sympy.core.numbers import Rational, Integer, Number, I from sympy.core.singleton import S from sympy.core.symbol import Dummy from sympy.core.coreerrors import NonCommutativeExpression from sympy.core.containers import Tuple, Dict from sympy.utilities import default_sort_key from sympy.utilities.iterables import (common_prefix, common_suffix, variations, ordered) from collections import defaultdict _eps = Dummy(positive=True) def _isnumber(i): return isinstance(i, (SYMPY_INTS, float)) or i.is_Number def _monotonic_sign(self): """Return the value closest to 0 that ``self`` may have if all symbols are signed and the result is uniformly the same sign for all values of symbols. If a symbol is only signed but not known to be an integer or the result is 0 then a symbol representative of the sign of self will be returned. Otherwise, None is returned if a) the sign could be positive or negative or b) self is not in one of the following forms: - L(x, y, ...) + A: a function linear in all symbols x, y, ... with an additive constant; if A is zero then the function can be a monomial whose sign is monotonic over the range of the variables, e.g. (x + 1)**3 if x is nonnegative. - A/L(x, y, ...) + B: the inverse of a function linear in all symbols x, y, ... that does not have a sign change from positive to negative for any set of values for the variables. - M(x, y, ...) + A: a monomial M whose factors are all signed and a constant, A. - A/M(x, y, ...) + B: the inverse of a monomial and constants A and B. - P(x): a univariate polynomial Examples ======== >>> from sympy.core.exprtools import _monotonic_sign as F >>> from sympy import Dummy, S >>> nn = Dummy(integer=True, nonnegative=True) >>> p = Dummy(integer=True, positive=True) >>> p2 = Dummy(integer=True, positive=True) >>> F(nn + 1) 1 >>> F(p - 1) _nneg >>> F(nn*p + 1) 1 >>> F(p2*p + 1) 2 >>> F(nn - 1) # could be negative, zero or positive """ if not self.is_real: return if (-self).is_Symbol: rv = _monotonic_sign(-self) return rv if rv is None else -rv if not self.is_Add and self.as_numer_denom()[1].is_number: s = self if s.is_prime: if s.is_odd: return S(3) else: return S(2) elif s.is_composite: if s.is_odd: return S(9) else: return S(4) elif s.is_positive: if s.is_even: if s.is_prime is False: return S(4) else: return S(2) elif s.is_integer: return S.One else: return _eps elif s.is_negative: if s.is_even: return S(-2) elif s.is_integer: return S.NegativeOne else: return -_eps if s.is_zero or s.is_nonpositive or s.is_nonnegative: return S.Zero return None # univariate polynomial free = self.free_symbols if len(free) == 1: if self.is_polynomial(): from sympy.polys.polytools import real_roots from sympy.polys.polyroots import roots from sympy.polys.polyerrors import PolynomialError x = free.pop() x0 = _monotonic_sign(x) if x0 == _eps or x0 == -_eps: x0 = S.Zero if x0 is not None: d = self.diff(x) if d.is_number: currentroots = [] else: try: currentroots = real_roots(d) except (PolynomialError, NotImplementedError): currentroots = [r for r in roots(d, x) if r.is_real] y = self.subs(x, x0) if x.is_nonnegative and all(r <= x0 for r in currentroots): if y.is_nonnegative and d.is_positive: if y: return y if y.is_positive else Dummy('pos', positive=True) else: return Dummy('nneg', nonnegative=True) if y.is_nonpositive and d.is_negative: if y: return y if y.is_negative else Dummy('neg', negative=True) else: return Dummy('npos', nonpositive=True) elif x.is_nonpositive and all(r >= x0 for r in currentroots): if y.is_nonnegative and d.is_negative: if y: return Dummy('pos', positive=True) else: return Dummy('nneg', nonnegative=True) if y.is_nonpositive and d.is_positive: if y: return Dummy('neg', negative=True) else: return Dummy('npos', nonpositive=True) else: n, d = self.as_numer_denom() den = None if n.is_number: den = _monotonic_sign(d) elif not d.is_number: if _monotonic_sign(n) is not None: den = _monotonic_sign(d) if den is not None and (den.is_positive or den.is_negative): v = n*den if v.is_positive: return Dummy('pos', positive=True) elif v.is_nonnegative: return Dummy('nneg', nonnegative=True) elif v.is_negative: return Dummy('neg', negative=True) elif v.is_nonpositive: return Dummy('npos', nonpositive=True) return None # multivariate c, a = self.as_coeff_Add() v = None if not a.is_polynomial(): # F/A or A/F where A is a number and F is a signed, rational monomial n, d = a.as_numer_denom() if not (n.is_number or d.is_number): return if ( a.is_Mul or a.is_Pow) and \ a.is_rational and \ all(p.exp.is_Integer for p in a.atoms(Pow) if p.is_Pow) and \ (a.is_positive or a.is_negative): v = S(1) for ai in Mul.make_args(a): if ai.is_number: v *= ai continue reps = {} for x in ai.free_symbols: reps[x] = _monotonic_sign(x) if reps[x] is None: return v *= ai.subs(reps) elif c: # signed linear expression if not any(p for p in a.atoms(Pow) if not p.is_number) and (a.is_nonpositive or a.is_nonnegative): free = list(a.free_symbols) p = {} for i in free: v = _monotonic_sign(i) if v is None: return p[i] = v or (_eps if i.is_nonnegative else -_eps) v = a.xreplace(p) if v is not None: rv = v + c if v.is_nonnegative and rv.is_positive: return rv.subs(_eps, 0) if v.is_nonpositive and rv.is_negative: return rv.subs(_eps, 0) def decompose_power(expr): """ Decompose power into symbolic base and integer exponent. This is strictly only valid if the exponent from which the integer is extracted is itself an integer or the base is positive. These conditions are assumed and not checked here. Examples ======== >>> from sympy.core.exprtools import decompose_power >>> from sympy.abc import x, y >>> decompose_power(x) (x, 1) >>> decompose_power(x**2) (x, 2) >>> decompose_power(x**(2*y)) (x**y, 2) >>> decompose_power(x**(2*y/3)) (x**(y/3), 2) """ base, exp = expr.as_base_exp() if exp.is_Number: if exp.is_Rational: if not exp.is_Integer: base = Pow(base, Rational(1, exp.q)) exp = exp.p else: base, exp = expr, 1 else: exp, tail = exp.as_coeff_Mul(rational=True) if exp is S.NegativeOne: base, exp = Pow(base, tail), -1 elif exp is not S.One: tail = _keep_coeff(Rational(1, exp.q), tail) base, exp = Pow(base, tail), exp.p else: base, exp = expr, 1 return base, exp def decompose_power_rat(expr): """ Decompose power into symbolic base and rational exponent. """ base, exp = expr.as_base_exp() if exp.is_Number: if not exp.is_Rational: base, exp = expr, 1 else: exp, tail = exp.as_coeff_Mul(rational=True) if exp is S.NegativeOne: base, exp = Pow(base, tail), -1 elif exp is not S.One: tail = _keep_coeff(Rational(1, exp.q), tail) base, exp = Pow(base, tail), exp.p else: base, exp = expr, 1 return base, exp class Factors(object): """Efficient representation of ``f_1*f_2*...*f_n``.""" __slots__ = ['factors', 'gens'] def __init__(self, factors=None): # Factors """Initialize Factors from dict or expr. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x >>> from sympy import I >>> e = 2*x**3 >>> Factors(e) Factors({2: 1, x: 3}) >>> Factors(e.as_powers_dict()) Factors({2: 1, x: 3}) >>> f = _ >>> f.factors # underlying dictionary {2: 1, x: 3} >>> f.gens # base of each factor frozenset({2, x}) >>> Factors(0) Factors({0: 1}) >>> Factors(I) Factors({I: 1}) Notes ===== Although a dictionary can be passed, only minimal checking is performed: powers of -1 and I are made canonical. """ if isinstance(factors, (SYMPY_INTS, float)): factors = S(factors) if isinstance(factors, Factors): factors = factors.factors.copy() elif factors is None or factors is S.One: factors = {} elif factors is S.Zero or factors == 0: factors = {S.Zero: S.One} elif isinstance(factors, Number): n = factors factors = {} if n < 0: factors[S.NegativeOne] = S.One n = -n if n is not S.One: if n.is_Float or n.is_Integer or n is S.Infinity: factors[n] = S.One elif n.is_Rational: # since we're processing Numbers, the denominator is # stored with a negative exponent; all other factors # are left . if n.p != 1: factors[Integer(n.p)] = S.One factors[Integer(n.q)] = S.NegativeOne else: raise ValueError('Expected Float|Rational|Integer, not %s' % n) elif isinstance(factors, Basic) and not factors.args: factors = {factors: S.One} elif isinstance(factors, Expr): c, nc = factors.args_cnc() i = c.count(I) for _ in range(i): c.remove(I) factors = dict(Mul._from_args(c).as_powers_dict()) # Handle all rational Coefficients for f in list(factors.keys()): if isinstance(f, Rational) and not isinstance(f, Integer): p, q = Integer(f.p), Integer(f.q) factors[p] = (factors[p] if p in factors else 0) + factors[f] factors[q] = (factors[q] if q in factors else 0) - factors[f] factors.pop(f) if i: factors[I] = S.One*i if nc: factors[Mul(*nc, evaluate=False)] = S.One else: factors = factors.copy() # /!\ should be dict-like # tidy up -/+1 and I exponents if Rational handle = [] for k in factors: if k is I or k in (-1, 1): handle.append(k) if handle: i1 = S.One for k in handle: if not _isnumber(factors[k]): continue i1 *= k**factors.pop(k) if i1 is not S.One: for a in i1.args if i1.is_Mul else [i1]: # at worst, -1.0*I*(-1)**e if a is S.NegativeOne: factors[a] = S.One elif a is I: factors[I] = S.One elif a.is_Pow: if S.NegativeOne not in factors: factors[S.NegativeOne] = S.Zero factors[S.NegativeOne] += a.exp elif a == 1: factors[a] = S.One elif a == -1: factors[-a] = S.One factors[S.NegativeOne] = S.One else: raise ValueError('unexpected factor in i1: %s' % a) self.factors = factors keys = getattr(factors, 'keys', None) if keys is None: raise TypeError('expecting Expr or dictionary') self.gens = frozenset(keys()) def __hash__(self): # Factors keys = tuple(ordered(self.factors.keys())) values = [self.factors[k] for k in keys] return hash((keys, values)) def __repr__(self): # Factors return "Factors({%s})" % ', '.join( ['%s: %s' % (k, v) for k, v in ordered(self.factors.items())]) @property def is_zero(self): # Factors """ >>> from sympy.core.exprtools import Factors >>> Factors(0).is_zero True """ f = self.factors return len(f) == 1 and S.Zero in f @property def is_one(self): # Factors """ >>> from sympy.core.exprtools import Factors >>> Factors(1).is_one True """ return not self.factors def as_expr(self): # Factors """Return the underlying expression. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y >>> Factors((x*y**2).as_powers_dict()).as_expr() x*y**2 """ args = [] for factor, exp in self.factors.items(): if exp != 1: b, e = factor.as_base_exp() if isinstance(exp, int): e = _keep_coeff(Integer(exp), e) elif isinstance(exp, Rational): e = _keep_coeff(exp, e) else: e *= exp args.append(b**e) else: args.append(factor) return Mul(*args) def mul(self, other): # Factors """Return Factors of ``self * other``. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((x*y**2).as_powers_dict()) >>> b = Factors((x*y/z).as_powers_dict()) >>> a.mul(b) Factors({x: 2, y: 3, z: -1}) >>> a*b Factors({x: 2, y: 3, z: -1}) """ if not isinstance(other, Factors): other = Factors(other) if any(f.is_zero for f in (self, other)): return Factors(S.Zero) factors = dict(self.factors) for factor, exp in other.factors.items(): if factor in factors: exp = factors[factor] + exp if not exp: del factors[factor] continue factors[factor] = exp return Factors(factors) def normal(self, other): """Return ``self`` and ``other`` with ``gcd`` removed from each. The only differences between this and method ``div`` is that this is 1) optimized for the case when there are few factors in common and 2) this does not raise an error if ``other`` is zero. See Also ======== div """ if not isinstance(other, Factors): other = Factors(other) if other.is_zero: return (Factors(), Factors(S.Zero)) if self.is_zero: return (Factors(S.Zero), Factors()) self_factors = dict(self.factors) other_factors = dict(other.factors) for factor, self_exp in self.factors.items(): try: other_exp = other.factors[factor] except KeyError: continue exp = self_exp - other_exp if not exp: del self_factors[factor] del other_factors[factor] elif _isnumber(exp): if exp > 0: self_factors[factor] = exp del other_factors[factor] else: del self_factors[factor] other_factors[factor] = -exp else: r = self_exp.extract_additively(other_exp) if r is not None: if r: self_factors[factor] = r del other_factors[factor] else: # should be handled already del self_factors[factor] del other_factors[factor] else: sc, sa = self_exp.as_coeff_Add() if sc: oc, oa = other_exp.as_coeff_Add() diff = sc - oc if diff > 0: self_factors[factor] -= oc other_exp = oa elif diff < 0: self_factors[factor] -= sc other_factors[factor] -= sc other_exp = oa - diff else: self_factors[factor] = sa other_exp = oa if other_exp: other_factors[factor] = other_exp else: del other_factors[factor] return Factors(self_factors), Factors(other_factors) def div(self, other): # Factors """Return ``self`` and ``other`` with ``gcd`` removed from each. This is optimized for the case when there are many factors in common. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> from sympy import S >>> a = Factors((x*y**2).as_powers_dict()) >>> a.div(a) (Factors({}), Factors({})) >>> a.div(x*z) (Factors({y: 2}), Factors({z: 1})) The ``/`` operator only gives ``quo``: >>> a/x Factors({y: 2}) Factors treats its factors as though they are all in the numerator, so if you violate this assumption the results will be correct but will not strictly correspond to the numerator and denominator of the ratio: >>> a.div(x/z) (Factors({y: 2}), Factors({z: -1})) Factors is also naive about bases: it does not attempt any denesting of Rational-base terms, for example the following does not become 2**(2*x)/2. >>> Factors(2**(2*x + 2)).div(S(8)) (Factors({2: 2*x + 2}), Factors({8: 1})) factor_terms can clean up such Rational-bases powers: >>> from sympy.core.exprtools import factor_terms >>> n, d = Factors(2**(2*x + 2)).div(S(8)) >>> n.as_expr()/d.as_expr() 2**(2*x + 2)/8 >>> factor_terms(_) 2**(2*x)/2 """ quo, rem = dict(self.factors), {} if not isinstance(other, Factors): other = Factors(other) if other.is_zero: raise ZeroDivisionError if self.is_zero: return (Factors(S.Zero), Factors()) for factor, exp in other.factors.items(): if factor in quo: d = quo[factor] - exp if _isnumber(d): if d <= 0: del quo[factor] if d >= 0: if d: quo[factor] = d continue exp = -d else: r = quo[factor].extract_additively(exp) if r is not None: if r: quo[factor] = r else: # should be handled already del quo[factor] else: other_exp = exp sc, sa = quo[factor].as_coeff_Add() if sc: oc, oa = other_exp.as_coeff_Add() diff = sc - oc if diff > 0: quo[factor] -= oc other_exp = oa elif diff < 0: quo[factor] -= sc other_exp = oa - diff else: quo[factor] = sa other_exp = oa if other_exp: rem[factor] = other_exp else: assert factor not in rem continue rem[factor] = exp return Factors(quo), Factors(rem) def quo(self, other): # Factors """Return numerator Factor of ``self / other``. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((x*y**2).as_powers_dict()) >>> b = Factors((x*y/z).as_powers_dict()) >>> a.quo(b) # same as a/b Factors({y: 1}) """ return self.div(other)[0] def rem(self, other): # Factors """Return denominator Factors of ``self / other``. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((x*y**2).as_powers_dict()) >>> b = Factors((x*y/z).as_powers_dict()) >>> a.rem(b) Factors({z: -1}) >>> a.rem(a) Factors({}) """ return self.div(other)[1] def pow(self, other): # Factors """Return self raised to a non-negative integer power. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y >>> a = Factors((x*y**2).as_powers_dict()) >>> a**2 Factors({x: 2, y: 4}) """ if isinstance(other, Factors): other = other.as_expr() if other.is_Integer: other = int(other) if isinstance(other, SYMPY_INTS) and other >= 0: factors = {} if other: for factor, exp in self.factors.items(): factors[factor] = exp*other return Factors(factors) else: raise ValueError("expected non-negative integer, got %s" % other) def gcd(self, other): # Factors """Return Factors of ``gcd(self, other)``. The keys are the intersection of factors with the minimum exponent for each factor. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((x*y**2).as_powers_dict()) >>> b = Factors((x*y/z).as_powers_dict()) >>> a.gcd(b) Factors({x: 1, y: 1}) """ if not isinstance(other, Factors): other = Factors(other) if other.is_zero: return Factors(self.factors) factors = {} for factor, exp in self.factors.items(): factor, exp = sympify(factor), sympify(exp) if factor in other.factors: lt = (exp - other.factors[factor]).is_negative if lt == True: factors[factor] = exp elif lt == False: factors[factor] = other.factors[factor] return Factors(factors) def lcm(self, other): # Factors """Return Factors of ``lcm(self, other)`` which are the union of factors with the maximum exponent for each factor. Examples ======== >>> from sympy.core.exprtools import Factors >>> from sympy.abc import x, y, z >>> a = Factors((x*y**2).as_powers_dict()) >>> b = Factors((x*y/z).as_powers_dict()) >>> a.lcm(b) Factors({x: 1, y: 2, z: -1}) """ if not isinstance(other, Factors): other = Factors(other) if any(f.is_zero for f in (self, other)): return Factors(S.Zero) factors = dict(self.factors) for factor, exp in other.factors.items(): if factor in factors: exp = max(exp, factors[factor]) factors[factor] = exp return Factors(factors) def __mul__(self, other): # Factors return self.mul(other) def __divmod__(self, other): # Factors return self.div(other) def __div__(self, other): # Factors return self.quo(other) __truediv__ = __div__ def __mod__(self, other): # Factors return self.rem(other) def __pow__(self, other): # Factors return self.pow(other) def __eq__(self, other): # Factors if not isinstance(other, Factors): other = Factors(other) return self.factors == other.factors def __ne__(self, other): # Factors return not self == other class Term(object): """Efficient representation of ``coeff*(numer/denom)``. """ __slots__ = ['coeff', 'numer', 'denom'] def __init__(self, term, numer=None, denom=None): # Term if numer is None and denom is None: if not term.is_commutative: raise NonCommutativeExpression( 'commutative expression expected') coeff, factors = term.as_coeff_mul() numer, denom = defaultdict(int), defaultdict(int) for factor in factors: base, exp = decompose_power(factor) if base.is_Add: cont, base = base.primitive() coeff *= cont**exp if exp > 0: numer[base] += exp else: denom[base] += -exp numer = Factors(numer) denom = Factors(denom) else: coeff = term if numer is None: numer = Factors() if denom is None: denom = Factors() self.coeff = coeff self.numer = numer self.denom = denom def __hash__(self): # Term return hash((self.coeff, self.numer, self.denom)) def __repr__(self): # Term return "Term(%s, %s, %s)" % (self.coeff, self.numer, self.denom) def as_expr(self): # Term return self.coeff*(self.numer.as_expr()/self.denom.as_expr()) def mul(self, other): # Term coeff = self.coeff*other.coeff numer = self.numer.mul(other.numer) denom = self.denom.mul(other.denom) numer, denom = numer.normal(denom) return Term(coeff, numer, denom) def inv(self): # Term return Term(1/self.coeff, self.denom, self.numer) def quo(self, other): # Term return self.mul(other.inv()) def pow(self, other): # Term if other < 0: return self.inv().pow(-other) else: return Term(self.coeff ** other, self.numer.pow(other), self.denom.pow(other)) def gcd(self, other): # Term return Term(self.coeff.gcd(other.coeff), self.numer.gcd(other.numer), self.denom.gcd(other.denom)) def lcm(self, other): # Term return Term(self.coeff.lcm(other.coeff), self.numer.lcm(other.numer), self.denom.lcm(other.denom)) def __mul__(self, other): # Term if isinstance(other, Term): return self.mul(other) else: return NotImplemented def __div__(self, other): # Term if isinstance(other, Term): return self.quo(other) else: return NotImplemented __truediv__ = __div__ def __pow__(self, other): # Term if isinstance(other, SYMPY_INTS): return self.pow(other) else: return NotImplemented def __eq__(self, other): # Term return (self.coeff == other.coeff and self.numer == other.numer and self.denom == other.denom) def __ne__(self, other): # Term return not self == other def _gcd_terms(terms, isprimitive=False, fraction=True): """Helper function for :func:`gcd_terms`. If ``isprimitive`` is True then the call to primitive for an Add will be skipped. This is useful when the content has already been extrated. If ``fraction`` is True then the expression will appear over a common denominator, the lcm of all term denominators. """ if isinstance(terms, Basic) and not isinstance(terms, Tuple): terms = Add.make_args(terms) terms = list(map(Term, [t for t in terms if t])) # there is some simplification that may happen if we leave this # here rather than duplicate it before the mapping of Term onto # the terms if len(terms) == 0: return S.Zero, S.Zero, S.One if len(terms) == 1: cont = terms[0].coeff numer = terms[0].numer.as_expr() denom = terms[0].denom.as_expr() else: cont = terms[0] for term in terms[1:]: cont = cont.gcd(term) for i, term in enumerate(terms): terms[i] = term.quo(cont) if fraction: denom = terms[0].denom for term in terms[1:]: denom = denom.lcm(term.denom) numers = [] for term in terms: numer = term.numer.mul(denom.quo(term.denom)) numers.append(term.coeff*numer.as_expr()) else: numers = [t.as_expr() for t in terms] denom = Term(S(1)).numer cont = cont.as_expr() numer = Add(*numers) denom = denom.as_expr() if not isprimitive and numer.is_Add: _cont, numer = numer.primitive() cont *= _cont return cont, numer, denom def gcd_terms(terms, isprimitive=False, clear=True, fraction=True): """Compute the GCD of ``terms`` and put them together. ``terms`` can be an expression or a non-Basic sequence of expressions which will be handled as though they are terms from a sum. If ``isprimitive`` is True the _gcd_terms will not run the primitive method on the terms. ``clear`` controls the removal of integers from the denominator of an Add expression. When True (default), all numerical denominator will be cleared; when False the denominators will be cleared only if all terms had numerical denominators other than 1. ``fraction``, when True (default), will put the expression over a common denominator. Examples ======== >>> from sympy.core import gcd_terms >>> from sympy.abc import x, y >>> gcd_terms((x + 1)**2*y + (x + 1)*y**2) y*(x + 1)*(x + y + 1) >>> gcd_terms(x/2 + 1) (x + 2)/2 >>> gcd_terms(x/2 + 1, clear=False) x/2 + 1 >>> gcd_terms(x/2 + y/2, clear=False) (x + y)/2 >>> gcd_terms(x/2 + 1/x) (x**2 + 2)/(2*x) >>> gcd_terms(x/2 + 1/x, fraction=False) (x + 2/x)/2 >>> gcd_terms(x/2 + 1/x, fraction=False, clear=False) x/2 + 1/x >>> gcd_terms(x/2/y + 1/x/y) (x**2 + 2)/(2*x*y) >>> gcd_terms(x/2/y + 1/x/y, clear=False) (x**2/2 + 1)/(x*y) >>> gcd_terms(x/2/y + 1/x/y, clear=False, fraction=False) (x/2 + 1/x)/y The ``clear`` flag was ignored in this case because the returned expression was a rational expression, not a simple sum. See Also ======== factor_terms, sympy.polys.polytools.terms_gcd """ def mask(terms): """replace nc portions of each term with a unique Dummy symbols and return the replacements to restore them""" args = [(a, []) if a.is_commutative else a.args_cnc() for a in terms] reps = [] for i, (c, nc) in enumerate(args): if nc: nc = Mul(*nc) d = Dummy() reps.append((d, nc)) c.append(d) args[i] = Mul(*c) else: args[i] = c return args, dict(reps) isadd = isinstance(terms, Add) addlike = isadd or not isinstance(terms, Basic) and \ is_sequence(terms, include=set) and \ not isinstance(terms, Dict) if addlike: if isadd: # i.e. an Add terms = list(terms.args) else: terms = sympify(terms) terms, reps = mask(terms) cont, numer, denom = _gcd_terms(terms, isprimitive, fraction) numer = numer.xreplace(reps) coeff, factors = cont.as_coeff_Mul() if not clear: c, _coeff = coeff.as_coeff_Mul() if not c.is_Integer and not clear and numer.is_Add: n, d = c.as_numer_denom() _numer = numer/d if any(a.as_coeff_Mul()[0].is_Integer for a in _numer.args): numer = _numer coeff = n*_coeff return _keep_coeff(coeff, factors*numer/denom, clear=clear) if not isinstance(terms, Basic): return terms if terms.is_Atom: return terms if terms.is_Mul: c, args = terms.as_coeff_mul() return _keep_coeff(c, Mul(*[gcd_terms(i, isprimitive, clear, fraction) for i in args]), clear=clear) def handle(a): # don't treat internal args like terms of an Add if not isinstance(a, Expr): if isinstance(a, Basic): return a.func(*[handle(i) for i in a.args]) return type(a)([handle(i) for i in a]) return gcd_terms(a, isprimitive, clear, fraction) if isinstance(terms, Dict): return Dict(*[(k, handle(v)) for k, v in terms.args]) return terms.func(*[handle(i) for i in terms.args]) def _factor_sum_int(expr, **kwargs): """Return Sum or Integral object with factors that are not in the wrt variables removed. In cases where there are additive terms in the function of the object that are independent, the object will be separated into two objects. Examples ======== >>> from sympy import Sum, factor_terms >>> from sympy.abc import x, y >>> factor_terms(Sum(x + y, (x, 1, 3))) y*Sum(1, (x, 1, 3)) + Sum(x, (x, 1, 3)) >>> factor_terms(Sum(x*y, (x, 1, 3))) y*Sum(x, (x, 1, 3)) Notes ===== If a function in the summand or integrand is replaced with a symbol, then this simplification should not be done or else an incorrect result will be obtained when the symbol is replaced with an expression that depends on the variables of summation/integration: >>> eq = Sum(y, (x, 1, 3)) >>> factor_terms(eq).subs(y, x).doit() 3*x >>> eq.subs(y, x).doit() 6 """ result = expr.function if result == 0: return S.Zero limits = expr.limits # get the wrt variables wrt = set([i.args[0] for i in limits]) # factor out any common terms that are independent of wrt f = factor_terms(result, **kwargs) i, d = f.as_independent(*wrt) if isinstance(f, Add): return i * expr.func(1, *limits) + expr.func(d, *limits) else: return i * expr.func(d, *limits) def factor_terms(expr, radical=False, clear=False, fraction=False, sign=True): """Remove common factors from terms in all arguments without changing the underlying structure of the expr. No expansion or simplification (and no processing of non-commutatives) is performed. If radical=True then a radical common to all terms will be factored out of any Add sub-expressions of the expr. If clear=False (default) then coefficients will not be separated from a single Add if they can be distributed to leave one or more terms with integer coefficients. If fraction=True (default is False) then a common denominator will be constructed for the expression. If sign=True (default) then even if the only factor in common is a -1, it will be factored out of the expression. Examples ======== >>> from sympy import factor_terms, Symbol >>> from sympy.abc import x, y >>> factor_terms(x + x*(2 + 4*y)**3) x*(8*(2*y + 1)**3 + 1) >>> A = Symbol('A', commutative=False) >>> factor_terms(x*A + x*A + x*y*A) x*(y*A + 2*A) When ``clear`` is False, a rational will only be factored out of an Add expression if all terms of the Add have coefficients that are fractions: >>> factor_terms(x/2 + 1, clear=False) x/2 + 1 >>> factor_terms(x/2 + 1, clear=True) (x + 2)/2 If a -1 is all that can be factored out, to *not* factor it out, the flag ``sign`` must be False: >>> factor_terms(-x - y) -(x + y) >>> factor_terms(-x - y, sign=False) -x - y >>> factor_terms(-2*x - 2*y, sign=False) -2*(x + y) See Also ======== gcd_terms, sympy.polys.polytools.terms_gcd """ def do(expr): from sympy.concrete.summations import Sum from sympy.integrals.integrals import Integral is_iterable = iterable(expr) if not isinstance(expr, Basic) or expr.is_Atom: if is_iterable: return type(expr)([do(i) for i in expr]) return expr if expr.is_Pow or expr.is_Function or \ is_iterable or not hasattr(expr, 'args_cnc'): args = expr.args newargs = tuple([do(i) for i in args]) if newargs == args: return expr return expr.func(*newargs) if isinstance(expr, (Sum, Integral)): return _factor_sum_int(expr, radical=radical, clear=clear, fraction=fraction, sign=sign) cont, p = expr.as_content_primitive(radical=radical, clear=clear) if p.is_Add: list_args = [do(a) for a in Add.make_args(p)] # get a common negative (if there) which gcd_terms does not remove if all(a.as_coeff_Mul()[0].extract_multiplicatively(-1) is not None for a in list_args): cont = -cont list_args = [-a for a in list_args] # watch out for exp(-(x+2)) which gcd_terms will change to exp(-x-2) special = {} for i, a in enumerate(list_args): b, e = a.as_base_exp() if e.is_Mul and e != Mul(*e.args): list_args[i] = Dummy() special[list_args[i]] = a # rebuild p not worrying about the order which gcd_terms will fix p = Add._from_args(list_args) p = gcd_terms(p, isprimitive=True, clear=clear, fraction=fraction).xreplace(special) elif p.args: p = p.func( *[do(a) for a in p.args]) rv = _keep_coeff(cont, p, clear=clear, sign=sign) return rv expr = sympify(expr) return do(expr) def _mask_nc(eq, name=None): """ Return ``eq`` with non-commutative objects replaced with Dummy symbols. A dictionary that can be used to restore the original values is returned: if it is None, the expression is noncommutative and cannot be made commutative. The third value returned is a list of any non-commutative symbols that appear in the returned equation. ``name``, if given, is the name that will be used with numbered Dummy variables that will replace the non-commutative objects and is mainly used for doctesting purposes. Notes ===== All non-commutative objects other than Symbols are replaced with a non-commutative Symbol. Identical objects will be identified by identical symbols. If there is only 1 non-commutative object in an expression it will be replaced with a commutative symbol. Otherwise, the non-commutative entities are retained and the calling routine should handle replacements in this case since some care must be taken to keep track of the ordering of symbols when they occur within Muls. Examples ======== >>> from sympy.physics.secondquant import Commutator, NO, F, Fd >>> from sympy import symbols, Mul >>> from sympy.core.exprtools import _mask_nc >>> from sympy.abc import x, y >>> A, B, C = symbols('A,B,C', commutative=False) One nc-symbol: >>> _mask_nc(A**2 - x**2, 'd') (_d0**2 - x**2, {_d0: A}, []) Multiple nc-symbols: >>> _mask_nc(A**2 - B**2, 'd') (A**2 - B**2, {}, [A, B]) An nc-object with nc-symbols but no others outside of it: >>> _mask_nc(1 + x*Commutator(A, B), 'd') (_d0*x + 1, {_d0: Commutator(A, B)}, []) >>> _mask_nc(NO(Fd(x)*F(y)), 'd') (_d0, {_d0: NO(CreateFermion(x)*AnnihilateFermion(y))}, []) Multiple nc-objects: >>> eq = x*Commutator(A, B) + x*Commutator(A, C)*Commutator(A, B) >>> _mask_nc(eq, 'd') (x*_d0 + x*_d1*_d0, {_d0: Commutator(A, B), _d1: Commutator(A, C)}, [_d0, _d1]) Multiple nc-objects and nc-symbols: >>> eq = A*Commutator(A, B) + B*Commutator(A, C) >>> _mask_nc(eq, 'd') (A*_d0 + B*_d1, {_d0: Commutator(A, B), _d1: Commutator(A, C)}, [_d0, _d1, A, B]) If there is an object that: - doesn't contain nc-symbols - but has arguments which derive from Basic, not Expr - and doesn't define an _eval_is_commutative routine then it will give False (or None?) for the is_commutative test. Such objects are also removed by this routine: >>> from sympy import Basic >>> eq = (1 + Mul(Basic(), Basic(), evaluate=False)) >>> eq.is_commutative False >>> _mask_nc(eq, 'd') (_d0**2 + 1, {_d0: Basic()}, []) """ name = name or 'mask' # Make Dummy() append sequential numbers to the name def numbered_names(): i = 0 while True: yield name + str(i) i += 1 names = numbered_names() def Dummy(*args, **kwargs): from sympy import Dummy return Dummy(next(names), *args, **kwargs) expr = eq if expr.is_commutative: return eq, {}, [] # identify nc-objects; symbols and other rep = [] nc_obj = set() nc_syms = set() pot = preorder_traversal(expr, keys=default_sort_key) for i, a in enumerate(pot): if any(a == r[0] for r in rep): pot.skip() elif not a.is_commutative: if a.is_symbol: nc_syms.add(a) pot.skip() elif not (a.is_Add or a.is_Mul or a.is_Pow): nc_obj.add(a) pot.skip() # If there is only one nc symbol or object, it can be factored regularly # but polys is going to complain, so replace it with a Dummy. if len(nc_obj) == 1 and not nc_syms: rep.append((nc_obj.pop(), Dummy())) elif len(nc_syms) == 1 and not nc_obj: rep.append((nc_syms.pop(), Dummy())) # Any remaining nc-objects will be replaced with an nc-Dummy and # identified as an nc-Symbol to watch out for nc_obj = sorted(nc_obj, key=default_sort_key) for n in nc_obj: nc = Dummy(commutative=False) rep.append((n, nc)) nc_syms.add(nc) expr = expr.subs(rep) nc_syms = list(nc_syms) nc_syms.sort(key=default_sort_key) return expr, {v: k for k, v in rep}, nc_syms def factor_nc(expr): """Return the factored form of ``expr`` while handling non-commutative expressions. Examples ======== >>> from sympy.core.exprtools import factor_nc >>> from sympy import Symbol >>> from sympy.abc import x >>> A = Symbol('A', commutative=False) >>> B = Symbol('B', commutative=False) >>> factor_nc((x**2 + 2*A*x + A**2).expand()) (x + A)**2 >>> factor_nc(((x + A)*(x + B)).expand()) (x + A)*(x + B) """ from sympy.simplify.simplify import powsimp from sympy.polys import gcd, factor def _pemexpand(expr): "Expand with the minimal set of hints necessary to check the result." return expr.expand(deep=True, mul=True, power_exp=True, power_base=False, basic=False, multinomial=True, log=False) expr = sympify(expr) if not isinstance(expr, Expr) or not expr.args: return expr if not expr.is_Add: return expr.func(*[factor_nc(a) for a in expr.args]) expr, rep, nc_symbols = _mask_nc(expr) if rep: return factor(expr).subs(rep) else: args = [a.args_cnc() for a in Add.make_args(expr)] c = g = l = r = S.One hit = False # find any commutative gcd term for i, a in enumerate(args): if i == 0: c = Mul._from_args(a[0]) elif a[0]: c = gcd(c, Mul._from_args(a[0])) else: c = S.One if c is not S.One: hit = True c, g = c.as_coeff_Mul() if g is not S.One: for i, (cc, _) in enumerate(args): cc = list(Mul.make_args(Mul._from_args(list(cc))/g)) args[i][0] = cc for i, (cc, _) in enumerate(args): cc[0] = cc[0]/c args[i][0] = cc # find any noncommutative common prefix for i, a in enumerate(args): if i == 0: n = a[1][:] else: n = common_prefix(n, a[1]) if not n: # is there a power that can be extracted? if not args[0][1]: break b, e = args[0][1][0].as_base_exp() ok = False if e.is_Integer: for t in args: if not t[1]: break bt, et = t[1][0].as_base_exp() if et.is_Integer and bt == b: e = min(e, et) else: break else: ok = hit = True l = b**e il = b**-e for _ in args: _[1][0] = il*_[1][0] break if not ok: break else: hit = True lenn = len(n) l = Mul(*n) for _ in args: _[1] = _[1][lenn:] # find any noncommutative common suffix for i, a in enumerate(args): if i == 0: n = a[1][:] else: n = common_suffix(n, a[1]) if not n: # is there a power that can be extracted? if not args[0][1]: break b, e = args[0][1][-1].as_base_exp() ok = False if e.is_Integer: for t in args: if not t[1]: break bt, et = t[1][-1].as_base_exp() if et.is_Integer and bt == b: e = min(e, et) else: break else: ok = hit = True r = b**e il = b**-e for _ in args: _[1][-1] = _[1][-1]*il break if not ok: break else: hit = True lenn = len(n) r = Mul(*n) for _ in args: _[1] = _[1][:len(_[1]) - lenn] if hit: mid = Add(*[Mul(*cc)*Mul(*nc) for cc, nc in args]) else: mid = expr # sort the symbols so the Dummys would appear in the same # order as the original symbols, otherwise you may introduce # a factor of -1, e.g. A**2 - B**2) -- {A:y, B:x} --> y**2 - x**2 # and the former factors into two terms, (A - B)*(A + B) while the # latter factors into 3 terms, (-1)*(x - y)*(x + y) rep1 = [(n, Dummy()) for n in sorted(nc_symbols, key=default_sort_key)] unrep1 = [(v, k) for k, v in rep1] unrep1.reverse() new_mid, r2, _ = _mask_nc(mid.subs(rep1)) new_mid = powsimp(factor(new_mid)) new_mid = new_mid.subs(r2).subs(unrep1) if new_mid.is_Pow: return _keep_coeff(c, g*l*new_mid*r) if new_mid.is_Mul: # XXX TODO there should be a way to inspect what order the terms # must be in and just select the plausible ordering without # checking permutations cfac = [] ncfac = [] for f in new_mid.args: if f.is_commutative: cfac.append(f) else: b, e = f.as_base_exp() if e.is_Integer: ncfac.extend([b]*e) else: ncfac.append(f) pre_mid = g*Mul(*cfac)*l target = _pemexpand(expr/c) for s in variations(ncfac, len(ncfac)): ok = pre_mid*Mul(*s)*r if _pemexpand(ok) == target: return _keep_coeff(c, ok) # mid was an Add that didn't factor successfully return _keep_coeff(c, g*l*mid*r)

010c9639af7a0f7514d10d245db6d14c323e8d584a075ef747e406661ec4a9a5

""" This module contains the machinery handling assumptions. All symbolic objects have assumption attributes that can be accessed via .is_<assumption name> attribute. Assumptions determine certain properties of symbolic objects and can have 3 possible values: True, False, None. True is returned if the object has the property and False is returned if it doesn't or can't (i.e. doesn't make sense): >>> from sympy import I >>> I.is_algebraic True >>> I.is_real False >>> I.is_prime False When the property cannot be determined (or when a method is not implemented) None will be returned, e.g. a generic symbol, x, may or may not be positive so a value of None is returned for x.is_positive. By default, all symbolic values are in the largest set in the given context without specifying the property. For example, a symbol that has a property being integer, is also real, complex, etc. Here follows a list of possible assumption names: .. glossary:: commutative object commutes with any other object with respect to multiplication operation. complex object can have only values from the set of complex numbers. imaginary object value is a number that can be written as a real number multiplied by the imaginary unit ``I``. See [3]_. Please note, that ``0`` is not considered to be an imaginary number, see `issue #7649 <https://github.com/sympy/sympy/issues/7649>`_. real object can have only values from the set of real numbers. integer object can have only values from the set of integers. odd even object can have only values from the set of odd (even) integers [2]_. prime object is a natural number greater than ``1`` that has no positive divisors other than ``1`` and itself. See [6]_. composite object is a positive integer that has at least one positive divisor other than ``1`` or the number itself. See [4]_. zero object has the value of ``0``. nonzero object is a real number that is not zero. rational object can have only values from the set of rationals. algebraic object can have only values from the set of algebraic numbers [11]_. transcendental object can have only values from the set of transcendental numbers [10]_. irrational object value cannot be represented exactly by Rational, see [5]_. finite infinite object absolute value is bounded (arbitrarily large). See [7]_, [8]_, [9]_. negative nonnegative object can have only negative (nonnegative) values [1]_. positive nonpositive object can have only positive (only nonpositive) values. hermitian antihermitian object belongs to the field of hermitian (antihermitian) operators. Examples ======== >>> from sympy import Symbol >>> x = Symbol('x', real=True); x x >>> x.is_real True >>> x.is_complex True See Also ======== .. seealso:: :py:class:`sympy.core.numbers.ImaginaryUnit` :py:class:`sympy.core.numbers.Zero` :py:class:`sympy.core.numbers.One` Notes ===== Assumption values are stored in obj._assumptions dictionary or are returned by getter methods (with property decorators) or are attributes of objects/classes. References ========== .. [1] https://en.wikipedia.org/wiki/Negative_number .. [2] https://en.wikipedia.org/wiki/Parity_%28mathematics%29 .. [3] https://en.wikipedia.org/wiki/Imaginary_number .. [4] https://en.wikipedia.org/wiki/Composite_number .. [5] https://en.wikipedia.org/wiki/Irrational_number .. [6] https://en.wikipedia.org/wiki/Prime_number .. [7] https://en.wikipedia.org/wiki/Finite .. [8] https://docs.python.org/3/library/math.html#math.isfinite .. [9] http://docs.scipy.org/doc/numpy/reference/generated/numpy.isfinite.html .. [10] https://en.wikipedia.org/wiki/Transcendental_number .. [11] https://en.wikipedia.org/wiki/Algebraic_number """ from __future__ import print_function, division from sympy.core.facts import FactRules, FactKB from sympy.core.core import BasicMeta from sympy.core.compatibility import integer_types from random import shuffle _assume_rules = FactRules([ 'integer -> rational', 'rational -> real & finite', 'rational -> algebraic', 'algebraic -> complex & finite', 'real -> complex', 'real -> hermitian', 'imaginary -> complex', 'imaginary -> antihermitian', 'complex -> commutative', 'odd == integer & !even', 'even == integer & !odd', 'real == negative | zero | positive', 'complex -> infinite | finite', 'transcendental == complex & !algebraic & finite', 'negative == nonpositive & nonzero', 'positive == nonnegative & nonzero', 'zero == nonnegative & nonpositive', 'nonpositive == real & !positive', 'nonnegative == real & !negative', 'zero -> even & finite', 'prime -> integer & positive', 'composite -> integer & positive & !prime', '!composite -> !positive | !even | prime', 'irrational == real & !rational & finite', 'imaginary -> !real', 'infinite -> !finite', 'noninteger == real & !integer', 'nonzero == real & !zero', ]) _assume_defined = _assume_rules.defined_facts.copy() _assume_defined.add('polar') _assume_defined = frozenset(_assume_defined) class StdFactKB(FactKB): """A FactKB specialised for the built-in rules This is the only kind of FactKB that Basic objects should use. """ def __init__(self, facts=None): super(StdFactKB, self).__init__(_assume_rules) # save a copy of the facts dict if not facts: self._generator = {} elif not isinstance(facts, FactKB): self._generator = facts.copy() else: self._generator = facts.generator if facts: self.deduce_all_facts(facts) def copy(self): return self.__class__(self) @property def generator(self): return self._generator.copy() def as_property(fact): """Convert a fact name to the name of the corresponding property""" return 'is_%s' % fact def make_property(fact): """Create the automagic property corresponding to a fact.""" def getit(self): try: return self._assumptions[fact] except KeyError: if self._assumptions is self.default_assumptions: self._assumptions = self.default_assumptions.copy() return _ask(fact, self) getit.func_name = as_property(fact) return property(getit) def _ask(fact, obj): """ Find the truth value for a property of an object. This function is called when a request is made to see what a fact value is. For this we use several techniques: First, the fact-evaluation function is tried, if it exists (for example _eval_is_integer). Then we try related facts. For example rational --> integer another example is joined rule: integer & !odd --> even so in the latter case if we are looking at what 'even' value is, 'integer' and 'odd' facts will be asked. In all cases, when we settle on some fact value, its implications are deduced, and the result is cached in ._assumptions. """ assumptions = obj._assumptions handler_map = obj._prop_handler # Store None into the assumptions so that recursive attempts at # evaluating the same fact don't trigger infinite recursion. assumptions._tell(fact, None) # First try the assumption evaluation function if it exists try: evaluate = handler_map[fact] except KeyError: pass else: a = evaluate(obj) if a is not None: assumptions.deduce_all_facts(((fact, a),)) return a # Try assumption's prerequisites prereq = list(_assume_rules.prereq[fact]) shuffle(prereq) for pk in prereq: if pk in assumptions: continue if pk in handler_map: _ask(pk, obj) # we might have found the value of fact ret_val = assumptions.get(fact) if ret_val is not None: return ret_val # Note: the result has already been cached return None class ManagedProperties(BasicMeta): """Metaclass for classes with old-style assumptions""" def __init__(cls, *args, **kws): BasicMeta.__init__(cls, *args, **kws) local_defs = {} for k in _assume_defined: attrname = as_property(k) v = cls.__dict__.get(attrname, '') if isinstance(v, (bool, integer_types, type(None))): if v is not None: v = bool(v) local_defs[k] = v defs = {} for base in reversed(cls.__bases__): assumptions = getattr(base, '_explicit_class_assumptions', None) if assumptions is not None: defs.update(assumptions) defs.update(local_defs) cls._explicit_class_assumptions = defs cls.default_assumptions = StdFactKB(defs) cls._prop_handler = {} for k in _assume_defined: eval_is_meth = getattr(cls, '_eval_is_%s' % k, None) if eval_is_meth is not None: cls._prop_handler[k] = eval_is_meth # Put definite results directly into the class dict, for speed for k, v in cls.default_assumptions.items(): setattr(cls, as_property(k), v) # protection e.g. for Integer.is_even=F <- (Rational.is_integer=F) derived_from_bases = set() for base in cls.__bases__: default_assumptions = getattr(base, 'default_assumptions', None) # is an assumption-aware class if default_assumptions is not None: derived_from_bases.update(default_assumptions) for fact in derived_from_bases - set(cls.default_assumptions): pname = as_property(fact) if pname not in cls.__dict__: setattr(cls, pname, make_property(fact)) # Finally, add any missing automagic property (e.g. for Basic) for fact in _assume_defined: pname = as_property(fact) if not hasattr(cls, pname): setattr(cls, pname, make_property(fact))

74a47e5114eafab3024b0d9e8cbf9ddd97821fe8905e9ed8c591e757c8f7921e

""" There are three types of functions implemented in SymPy: 1) defined functions (in the sense that they can be evaluated) like exp or sin; they have a name and a body: f = exp 2) undefined function which have a name but no body. Undefined functions can be defined using a Function class as follows: f = Function('f') (the result will be a Function instance) 3) anonymous function (or lambda function) which have a body (defined with dummy variables) but have no name: f = Lambda(x, exp(x)*x) f = Lambda((x, y), exp(x)*y) The fourth type of functions are composites, like (sin + cos)(x); these work in SymPy core, but are not yet part of SymPy. Examples ======== >>> import sympy >>> f = sympy.Function("f") >>> from sympy.abc import x >>> f(x) f(x) >>> print(sympy.srepr(f(x).func)) Function('f') >>> f(x).args (x,) """ from __future__ import print_function, division from .add import Add from .assumptions import ManagedProperties, _assume_defined from .basic import Basic, _atomic from .cache import cacheit from .compatibility import iterable, is_sequence, as_int, ordered, Iterable from .decorators import _sympifyit from .expr import Expr, AtomicExpr from .numbers import Rational, Float from .operations import LatticeOp from .rules import Transform from .singleton import S from .sympify import sympify from sympy.core.containers import Tuple, Dict from sympy.core.logic import fuzzy_and from sympy.core.compatibility import string_types, with_metaclass, PY3, range from sympy.utilities import default_sort_key from sympy.utilities.misc import filldedent from sympy.utilities.iterables import has_dups, sift from sympy.core.evaluate import global_evaluate import mpmath import mpmath.libmp as mlib import inspect from collections import Counter def _coeff_isneg(a): """Return True if the leading Number is negative. Examples ======== >>> from sympy.core.function import _coeff_isneg >>> from sympy import S, Symbol, oo, pi >>> _coeff_isneg(-3*pi) True >>> _coeff_isneg(S(3)) False >>> _coeff_isneg(-oo) True >>> _coeff_isneg(Symbol('n', negative=True)) # coeff is 1 False For matrix expressions: >>> from sympy import MatrixSymbol, sqrt >>> A = MatrixSymbol("A", 3, 3) >>> _coeff_isneg(-sqrt(2)*A) True >>> _coeff_isneg(sqrt(2)*A) False """ if a.is_MatMul: a = a.args[0] if a.is_Mul: a = a.args[0] return a.is_Number and a.is_negative class PoleError(Exception): pass class ArgumentIndexError(ValueError): def __str__(self): return ("Invalid operation with argument number %s for Function %s" % (self.args[1], self.args[0])) # Python 2/3 version that does not raise a Deprecation warning def arity(cls): """Return the arity of the function if it is known, else None. When default values are specified for some arguments, they are optional and the arity is reported as a tuple of possible values. Examples ======== >>> from sympy.core.function import arity >>> from sympy import log >>> arity(lambda x: x) 1 >>> arity(log) (1, 2) >>> arity(lambda *x: sum(x)) is None True """ eval_ = getattr(cls, 'eval', cls) if PY3: parameters = inspect.signature(eval_).parameters.items() if [p for _, p in parameters if p.kind == p.VAR_POSITIONAL]: return p_or_k = [p for _, p in parameters if p.kind == p.POSITIONAL_OR_KEYWORD] # how many have no default and how many have a default value no, yes = map(len, sift(p_or_k, lambda p:p.default == p.empty, binary=True)) return no if not yes else tuple(range(no, no + yes + 1)) else: cls_ = int(hasattr(cls, 'eval')) # correction for cls arguments evalargspec = inspect.getargspec(eval_) if evalargspec.varargs: return else: evalargs = len(evalargspec.args) - cls_ if evalargspec.defaults: # if there are default args then they are optional; the # fewest args will occur when all defaults are used and # the most when none are used (i.e. all args are given) fewest = evalargs - len(evalargspec.defaults) return tuple(range(fewest, evalargs + 1)) return evalargs class FunctionClass(ManagedProperties): """ Base class for function classes. FunctionClass is a subclass of type. Use Function('<function name>' [ , signature ]) to create undefined function classes. """ _new = type.__new__ def __init__(cls, *args, **kwargs): # honor kwarg value or class-defined value before using # the number of arguments in the eval function (if present) nargs = kwargs.pop('nargs', cls.__dict__.get('nargs', arity(cls))) # Canonicalize nargs here; change to set in nargs. if is_sequence(nargs): if not nargs: raise ValueError(filldedent(''' Incorrectly specified nargs as %s: if there are no arguments, it should be `nargs = 0`; if there are any number of arguments, it should be `nargs = None`''' % str(nargs))) nargs = tuple(ordered(set(nargs))) elif nargs is not None: nargs = (as_int(nargs),) cls._nargs = nargs super(FunctionClass, cls).__init__(*args, **kwargs) @property def __signature__(self): """ Allow Python 3's inspect.signature to give a useful signature for Function subclasses. """ # Python 3 only, but backports (like the one in IPython) still might # call this. try: from inspect import signature except ImportError: return None # TODO: Look at nargs return signature(self.eval) @property def free_symbols(self): return set() @property def xreplace(self): # Function needs args so we define a property that returns # a function that takes args...and then use that function # to return the right value return lambda rule, **_: rule.get(self, self) @property def nargs(self): """Return a set of the allowed number of arguments for the function. Examples ======== >>> from sympy.core.function import Function >>> from sympy.abc import x, y >>> f = Function('f') If the function can take any number of arguments, the set of whole numbers is returned: >>> Function('f').nargs Naturals0 If the function was initialized to accept one or more arguments, a corresponding set will be returned: >>> Function('f', nargs=1).nargs {1} >>> Function('f', nargs=(2, 1)).nargs {1, 2} The undefined function, after application, also has the nargs attribute; the actual number of arguments is always available by checking the ``args`` attribute: >>> f = Function('f') >>> f(1).nargs Naturals0 >>> len(f(1).args) 1 """ from sympy.sets.sets import FiniteSet # XXX it would be nice to handle this in __init__ but there are import # problems with trying to import FiniteSet there return FiniteSet(*self._nargs) if self._nargs else S.Naturals0 def __repr__(cls): return cls.__name__ class Application(with_metaclass(FunctionClass, Basic)): """ Base class for applied functions. Instances of Application represent the result of applying an application of any type to any object. """ is_Function = True @cacheit def __new__(cls, *args, **options): from sympy.sets.fancysets import Naturals0 from sympy.sets.sets import FiniteSet args = list(map(sympify, args)) evaluate = options.pop('evaluate', global_evaluate[0]) # WildFunction (and anything else like it) may have nargs defined # and we throw that value away here options.pop('nargs', None) if options: raise ValueError("Unknown options: %s" % options) if evaluate: evaluated = cls.eval(*args) if evaluated is not None: return evaluated obj = super(Application, cls).__new__(cls, *args, **options) # make nargs uniform here sentinel = object() objnargs = getattr(obj, "nargs", sentinel) if objnargs is not sentinel: # things passing through here: # - functions subclassed from Function (e.g. myfunc(1).nargs) # - functions like cos(1).nargs # - AppliedUndef with given nargs like Function('f', nargs=1)(1).nargs # Canonicalize nargs here if is_sequence(objnargs): nargs = tuple(ordered(set(objnargs))) elif objnargs is not None: nargs = (as_int(objnargs),) else: nargs = None else: # things passing through here: # - WildFunction('f').nargs # - AppliedUndef with no nargs like Function('f')(1).nargs nargs = obj._nargs # note the underscore here # convert to FiniteSet obj.nargs = FiniteSet(*nargs) if nargs else Naturals0() return obj @classmethod def eval(cls, *args): """ Returns a canonical form of cls applied to arguments args. The eval() method is called when the class cls is about to be instantiated and it should return either some simplified instance (possible of some other class), or if the class cls should be unmodified, return None. Examples of eval() for the function "sign" --------------------------------------------- .. code-block:: python @classmethod def eval(cls, arg): if arg is S.NaN: return S.NaN if arg is S.Zero: return S.Zero if arg.is_positive: return S.One if arg.is_negative: return S.NegativeOne if isinstance(arg, Mul): coeff, terms = arg.as_coeff_Mul(rational=True) if coeff is not S.One: return cls(coeff) * cls(terms) """ return @property def func(self): return self.__class__ def _eval_subs(self, old, new): if (old.is_Function and new.is_Function and callable(old) and callable(new) and old == self.func and len(self.args) in new.nargs): return new(*[i._subs(old, new) for i in self.args]) class Function(Application, Expr): """ Base class for applied mathematical functions. It also serves as a constructor for undefined function classes. Examples ======== First example shows how to use Function as a constructor for undefined function classes: >>> from sympy import Function, Symbol >>> x = Symbol('x') >>> f = Function('f') >>> g = Function('g')(x) >>> f f >>> f(x) f(x) >>> g g(x) >>> f(x).diff(x) Derivative(f(x), x) >>> g.diff(x) Derivative(g(x), x) Assumptions can be passed to Function. >>> f_real = Function('f', real=True) >>> f_real(x).is_real True Note that assumptions on a function are unrelated to the assumptions on the variable it is called on. If you want to add a relationship, subclass Function and define the appropriate ``_eval_is_assumption`` methods. In the following example Function is used as a base class for ``my_func`` that represents a mathematical function *my_func*. Suppose that it is well known, that *my_func(0)* is *1* and *my_func* at infinity goes to *0*, so we want those two simplifications to occur automatically. Suppose also that *my_func(x)* is real exactly when *x* is real. Here is an implementation that honours those requirements: >>> from sympy import Function, S, oo, I, sin >>> class my_func(Function): ... ... @classmethod ... def eval(cls, x): ... if x.is_Number: ... if x is S.Zero: ... return S.One ... elif x is S.Infinity: ... return S.Zero ... ... def _eval_is_real(self): ... return self.args[0].is_real ... >>> x = S('x') >>> my_func(0) + sin(0) 1 >>> my_func(oo) 0 >>> my_func(3.54).n() # Not yet implemented for my_func. my_func(3.54) >>> my_func(I).is_real False In order for ``my_func`` to become useful, several other methods would need to be implemented. See source code of some of the already implemented functions for more complete examples. Also, if the function can take more than one argument, then ``nargs`` must be defined, e.g. if ``my_func`` can take one or two arguments then, >>> class my_func(Function): ... nargs = (1, 2) ... >>> """ @property def _diff_wrt(self): return False @cacheit def __new__(cls, *args, **options): # Handle calls like Function('f') if cls is Function: return UndefinedFunction(*args, **options) n = len(args) if n not in cls.nargs: # XXX: exception message must be in exactly this format to # make it work with NumPy's functions like vectorize(). See, # for example, https://github.com/numpy/numpy/issues/1697. # The ideal solution would be just to attach metadata to # the exception and change NumPy to take advantage of this. temp = ('%(name)s takes %(qual)s %(args)s ' 'argument%(plural)s (%(given)s given)') raise TypeError(temp % { 'name': cls, 'qual': 'exactly' if len(cls.nargs) == 1 else 'at least', 'args': min(cls.nargs), 'plural': 's'*(min(cls.nargs) != 1), 'given': n}) evaluate = options.get('evaluate', global_evaluate[0]) result = super(Function, cls).__new__(cls, *args, **options) if evaluate and isinstance(result, cls) and result.args: pr2 = min(cls._should_evalf(a) for a in result.args) if pr2 > 0: pr = max(cls._should_evalf(a) for a in result.args) result = result.evalf(mlib.libmpf.prec_to_dps(pr)) return result @classmethod def _should_evalf(cls, arg): """ Decide if the function should automatically evalf(). By default (in this implementation), this happens if (and only if) the ARG is a floating point number. This function is used by __new__. Returns the precision to evalf to, or -1 if it shouldn't evalf. """ from sympy.core.evalf import pure_complex if arg.is_Float: return arg._prec if not arg.is_Add: return -1 m = pure_complex(arg) if m is None or not (m[0].is_Float or m[1].is_Float): return -1 l = [i._prec for i in m if i.is_Float] l.append(-1) return max(l) @classmethod def class_key(cls): from sympy.sets.fancysets import Naturals0 funcs = { 'exp': 10, 'log': 11, 'sin': 20, 'cos': 21, 'tan': 22, 'cot': 23, 'sinh': 30, 'cosh': 31, 'tanh': 32, 'coth': 33, 'conjugate': 40, 're': 41, 'im': 42, 'arg': 43, } name = cls.__name__ try: i = funcs[name] except KeyError: i = 0 if isinstance(cls.nargs, Naturals0) else 10000 return 4, i, name @property def is_commutative(self): """ Returns whether the function is commutative. """ if all(getattr(t, 'is_commutative') for t in self.args): return True else: return False def _eval_evalf(self, prec): def _get_mpmath_func(fname): """Lookup mpmath function based on name""" if isinstance(self, AppliedUndef): # Shouldn't lookup in mpmath but might have ._imp_ return None if not hasattr(mpmath, fname): from sympy.utilities.lambdify import MPMATH_TRANSLATIONS fname = MPMATH_TRANSLATIONS.get(fname, None) if fname is None: return None return getattr(mpmath, fname) func = _get_mpmath_func(self.func.__name__) # Fall-back evaluation if func is None: imp = getattr(self, '_imp_', None) if imp is None: return None try: return Float(imp(*[i.evalf(prec) for i in self.args]), prec) except (TypeError, ValueError) as e: return None # Convert all args to mpf or mpc # Convert the arguments to *higher* precision than requested for the # final result. # XXX + 5 is a guess, it is similar to what is used in evalf.py. Should # we be more intelligent about it? try: args = [arg._to_mpmath(prec + 5) for arg in self.args] def bad(m): from mpmath import mpf, mpc # the precision of an mpf value is the last element # if that is 1 (and m[1] is not 1 which would indicate a # power of 2), then the eval failed; so check that none of # the arguments failed to compute to a finite precision. # Note: An mpc value has two parts, the re and imag tuple; # check each of those parts, too. Anything else is allowed to # pass if isinstance(m, mpf): m = m._mpf_ return m[1] !=1 and m[-1] == 1 elif isinstance(m, mpc): m, n = m._mpc_ return m[1] !=1 and m[-1] == 1 and \ n[1] !=1 and n[-1] == 1 else: return False if any(bad(a) for a in args): raise ValueError # one or more args failed to compute with significance except ValueError: return with mpmath.workprec(prec): v = func(*args) return Expr._from_mpmath(v, prec) def _eval_derivative(self, s): # f(x).diff(s) -> x.diff(s) * f.fdiff(1)(s) i = 0 l = [] for a in self.args: i += 1 da = a.diff(s) if da is S.Zero: continue try: df = self.fdiff(i) except ArgumentIndexError: df = Function.fdiff(self, i) l.append(df * da) return Add(*l) def _eval_is_commutative(self): return fuzzy_and(a.is_commutative for a in self.args) def _eval_is_complex(self): return fuzzy_and(a.is_complex for a in self.args) def as_base_exp(self): """ Returns the method as the 2-tuple (base, exponent). """ return self, S.One def _eval_aseries(self, n, args0, x, logx): """ Compute an asymptotic expansion around args0, in terms of self.args. This function is only used internally by _eval_nseries and should not be called directly; derived classes can overwrite this to implement asymptotic expansions. """ from sympy.utilities.misc import filldedent raise PoleError(filldedent(''' Asymptotic expansion of %s around %s is not implemented.''' % (type(self), args0))) def _eval_nseries(self, x, n, logx): """ This function does compute series for multivariate functions, but the expansion is always in terms of *one* variable. Examples ======== >>> from sympy import atan2 >>> from sympy.abc import x, y >>> atan2(x, y).series(x, n=2) atan2(0, y) + x/y + O(x**2) >>> atan2(x, y).series(y, n=2) -y/x + atan2(x, 0) + O(y**2) This function also computes asymptotic expansions, if necessary and possible: >>> from sympy import loggamma >>> loggamma(1/x)._eval_nseries(x,0,None) -1/x - log(x)/x + log(x)/2 + O(1) """ from sympy import Order from sympy.sets.sets import FiniteSet args = self.args args0 = [t.limit(x, 0) for t in args] if any(t.is_finite is False for t in args0): from sympy import oo, zoo, nan # XXX could use t.as_leading_term(x) here but it's a little # slower a = [t.compute_leading_term(x, logx=logx) for t in args] a0 = [t.limit(x, 0) for t in a] if any([t.has(oo, -oo, zoo, nan) for t in a0]): return self._eval_aseries(n, args0, x, logx) # Careful: the argument goes to oo, but only logarithmically so. We # are supposed to do a power series expansion "around the # logarithmic term". e.g. # f(1+x+log(x)) # -> f(1+logx) + x*f'(1+logx) + O(x**2) # where 'logx' is given in the argument a = [t._eval_nseries(x, n, logx) for t in args] z = [r - r0 for (r, r0) in zip(a, a0)] p = [Dummy() for _ in z] q = [] v = None for ai, zi, pi in zip(a0, z, p): if zi.has(x): if v is not None: raise NotImplementedError q.append(ai + pi) v = pi else: q.append(ai) e1 = self.func(*q) if v is None: return e1 s = e1._eval_nseries(v, n, logx) o = s.getO() s = s.removeO() s = s.subs(v, zi).expand() + Order(o.expr.subs(v, zi), x) return s if (self.func.nargs is S.Naturals0 or (self.func.nargs == FiniteSet(1) and args0[0]) or any(c > 1 for c in self.func.nargs)): e = self e1 = e.expand() if e == e1: #for example when e = sin(x+1) or e = sin(cos(x)) #let's try the general algorithm term = e.subs(x, S.Zero) if term.is_finite is False or term is S.NaN: raise PoleError("Cannot expand %s around 0" % (self)) series = term fact = S.One _x = Dummy('x') e = e.subs(x, _x) for i in range(n - 1): i += 1 fact *= Rational(i) e = e.diff(_x) subs = e.subs(_x, S.Zero) if subs is S.NaN: # try to evaluate a limit if we have to subs = e.limit(_x, S.Zero) if subs.is_finite is False: raise PoleError("Cannot expand %s around 0" % (self)) term = subs*(x**i)/fact term = term.expand() series += term return series + Order(x**n, x) return e1.nseries(x, n=n, logx=logx) arg = self.args[0] l = [] g = None # try to predict a number of terms needed nterms = n + 2 cf = Order(arg.as_leading_term(x), x).getn() if cf != 0: nterms = int(nterms / cf) for i in range(nterms): g = self.taylor_term(i, arg, g) g = g.nseries(x, n=n, logx=logx) l.append(g) return Add(*l) + Order(x**n, x) def fdiff(self, argindex=1): """ Returns the first derivative of the function. """ if not (1 <= argindex <= len(self.args)): raise ArgumentIndexError(self, argindex) ix = argindex - 1 A = self.args[ix] if A._diff_wrt: if len(self.args) == 1: return Derivative(self, A) if A.is_Symbol: for i, v in enumerate(self.args): if i != ix and A in v.free_symbols: # it can't be in any other argument's free symbols # issue 8510 break else: return Derivative(self, A) else: free = A.free_symbols for i, a in enumerate(self.args): if ix != i and a.free_symbols & free: break else: # there is no possible interaction bewtween args return Derivative(self, A) # See issue 4624 and issue 4719, 5600 and 8510 D = Dummy('xi_%i' % argindex, dummy_index=hash(A)) args = self.args[:ix] + (D,) + self.args[ix + 1:] return Subs(Derivative(self.func(*args), D), D, A) def _eval_as_leading_term(self, x): """Stub that should be overridden by new Functions to return the first non-zero term in a series if ever an x-dependent argument whose leading term vanishes as x -> 0 might be encountered. See, for example, cos._eval_as_leading_term. """ from sympy import Order args = [a.as_leading_term(x) for a in self.args] o = Order(1, x) if any(x in a.free_symbols and o.contains(a) for a in args): # Whereas x and any finite number are contained in O(1, x), # expressions like 1/x are not. If any arg simplified to a # vanishing expression as x -> 0 (like x or x**2, but not # 3, 1/x, etc...) then the _eval_as_leading_term is needed # to supply the first non-zero term of the series, # # e.g. expression leading term # ---------- ------------ # cos(1/x) cos(1/x) # cos(cos(x)) cos(1) # cos(x) 1 <- _eval_as_leading_term needed # sin(x) x <- _eval_as_leading_term needed # raise NotImplementedError( '%s has no _eval_as_leading_term routine' % self.func) else: return self.func(*args) def _sage_(self): import sage.all as sage fname = self.func.__name__ func = getattr(sage, fname, None) args = [arg._sage_() for arg in self.args] # In the case the function is not known in sage: if func is None: import sympy if getattr(sympy, fname, None) is None: # abstract function return sage.function(fname)(*args) else: # the function defined in sympy is not known in sage # this exception is caught in sage raise AttributeError return func(*args) class AppliedUndef(Function): """ Base class for expressions resulting from the application of an undefined function. """ is_number = False def __new__(cls, *args, **options): args = list(map(sympify, args)) obj = super(AppliedUndef, cls).__new__(cls, *args, **options) return obj def _eval_as_leading_term(self, x): return self def _sage_(self): import sage.all as sage fname = str(self.func) args = [arg._sage_() for arg in self.args] func = sage.function(fname)(*args) return func @property def _diff_wrt(self): """ Allow derivatives wrt to undefined functions. Examples ======== >>> from sympy import Function, Symbol >>> f = Function('f') >>> x = Symbol('x') >>> f(x)._diff_wrt True >>> f(x).diff(x) Derivative(f(x), x) """ return True class UndefinedFunction(FunctionClass): """ The (meta)class of undefined functions. """ def __new__(mcl, name, bases=(AppliedUndef,), __dict__=None, **kwargs): __dict__ = __dict__ or {} # Allow Function('f', real=True) __dict__.update({'is_' + arg: val for arg, val in kwargs.items() if arg in _assume_defined}) # You can add other attributes, although they do have to be hashable # (but seriously, if you want to add anything other than assumptions, # just subclass Function) __dict__.update(kwargs) # Save these for __eq__ __dict__.update({'_extra_kwargs': kwargs}) __dict__['__module__'] = None # For pickling ret = super(UndefinedFunction, mcl).__new__(mcl, name, bases, __dict__) ret.name = name return ret def __instancecheck__(cls, instance): return cls in type(instance).__mro__ _extra_kwargs = {} def __hash__(self): return hash((self.class_key(), frozenset(self._extra_kwargs.items()))) def __eq__(self, other): return (isinstance(other, self.__class__) and self.class_key() == other.class_key() and self._extra_kwargs == other._extra_kwargs) def __ne__(self, other): return not self == other class WildFunction(Function, AtomicExpr): """ A WildFunction function matches any function (with its arguments). Examples ======== >>> from sympy import WildFunction, Function, cos >>> from sympy.abc import x, y >>> F = WildFunction('F') >>> f = Function('f') >>> F.nargs Naturals0 >>> x.match(F) >>> F.match(F) {F_: F_} >>> f(x).match(F) {F_: f(x)} >>> cos(x).match(F) {F_: cos(x)} >>> f(x, y).match(F) {F_: f(x, y)} To match functions with a given number of arguments, set ``nargs`` to the desired value at instantiation: >>> F = WildFunction('F', nargs=2) >>> F.nargs {2} >>> f(x).match(F) >>> f(x, y).match(F) {F_: f(x, y)} To match functions with a range of arguments, set ``nargs`` to a tuple containing the desired number of arguments, e.g. if ``nargs = (1, 2)`` then functions with 1 or 2 arguments will be matched. >>> F = WildFunction('F', nargs=(1, 2)) >>> F.nargs {1, 2} >>> f(x).match(F) {F_: f(x)} >>> f(x, y).match(F) {F_: f(x, y)} >>> f(x, y, 1).match(F) """ include = set() def __init__(cls, name, **assumptions): from sympy.sets.sets import Set, FiniteSet cls.name = name nargs = assumptions.pop('nargs', S.Naturals0) if not isinstance(nargs, Set): # Canonicalize nargs here. See also FunctionClass. if is_sequence(nargs): nargs = tuple(ordered(set(nargs))) elif nargs is not None: nargs = (as_int(nargs),) nargs = FiniteSet(*nargs) cls.nargs = nargs def matches(self, expr, repl_dict={}, old=False): if not isinstance(expr, (AppliedUndef, Function)): return None if len(expr.args) not in self.nargs: return None repl_dict = repl_dict.copy() repl_dict[self] = expr return repl_dict class Derivative(Expr): """ Carries out differentiation of the given expression with respect to symbols. Examples ======== >>> from sympy import Derivative, Function, symbols, Subs >>> from sympy.abc import x, y >>> f, g = symbols('f g', cls=Function) >>> Derivative(x**2, x, evaluate=True) 2*x Denesting of derivatives retains the ordering of variables: >>> Derivative(Derivative(f(x, y), y), x) Derivative(f(x, y), y, x) Contiguously identical symbols are merged into a tuple giving the symbol and the count: >>> Derivative(f(x), x, x, y, x) Derivative(f(x), (x, 2), y, x) If the derivative cannot be performed, and evaluate is True, the order of the variables of differentiation will be made canonical: >>> Derivative(f(x, y), y, x, evaluate=True) Derivative(f(x, y), x, y) Derivatives with respect to undefined functions can be calculated: >>> Derivative(f(x)**2, f(x), evaluate=True) 2*f(x) Such derivatives will show up when the chain rule is used to evalulate a derivative: >>> f(g(x)).diff(x) Derivative(f(g(x)), g(x))*Derivative(g(x), x) Substitution is used to represent derivatives of functions with arguments that are not symbols or functions: >>> f(2*x + 3).diff(x) == 2*Subs(f(y).diff(y), y, 2*x + 3) True Notes ===== Simplification of high-order derivatives: Because there can be a significant amount of simplification that can be done when multiple differentiations are performed, results will be automatically simplified in a fairly conservative fashion unless the keyword ``simplify`` is set to False. >>> from sympy import cos, sin, sqrt, diff, Function, symbols >>> from sympy.abc import x, y, z >>> f, g = symbols('f,g', cls=Function) >>> e = sqrt((x + 1)**2 + x) >>> diff(e, (x, 5), simplify=False).count_ops() 136 >>> diff(e, (x, 5)).count_ops() 30 Ordering of variables: If evaluate is set to True and the expression cannot be evaluated, the list of differentiation symbols will be sorted, that is, the expression is assumed to have continuous derivatives up to the order asked. Derivative wrt non-Symbols: For the most part, one may not differentiate wrt non-symbols. For example, we do not allow differentiation wrt `x*y` because there are multiple ways of structurally defining where x*y appears in an expression: a very strict definition would make (x*y*z).diff(x*y) == 0. Derivatives wrt defined functions (like cos(x)) are not allowed, either: >>> (x*y*z).diff(x*y) Traceback (most recent call last): ... ValueError: Can't calculate derivative wrt x*y. To make it easier to work with variational calculus, however, derivatives wrt AppliedUndef and Derivatives are allowed. For example, in the Euler-Lagrange method one may write F(t, u, v) where u = f(t) and v = f'(t). These variables can be written explicity as functions of time:: >>> from sympy.abc import t >>> F = Function('F') >>> U = f(t) >>> V = U.diff(t) The derivative wrt f(t) can be obtained directly: >>> direct = F(t, U, V).diff(U) When differentiation wrt a non-Symbol is attempted, the non-Symbol is temporarily converted to a Symbol while the differentiation is performed and the same answer is obtained: >>> indirect = F(t, U, V).subs(U, x).diff(x).subs(x, U) >>> assert direct == indirect The implication of this non-symbol replacement is that all functions are treated as independent of other functions and the symbols are independent of the functions that contain them:: >>> x.diff(f(x)) 0 >>> g(x).diff(f(x)) 0 It also means that derivatives are assumed to depend only on the variables of differentiation, not on anything contained within the expression being differentiated:: >>> F = f(x) >>> Fx = F.diff(x) >>> Fx.diff(F) # derivative depends on x, not F 0 >>> Fxx = Fx.diff(x) >>> Fxx.diff(Fx) # derivative depends on x, not Fx 0 The last example can be made explicit by showing the replacement of Fx in Fxx with y: >>> Fxx.subs(Fx, y) Derivative(y, x) Since that in itself will evaluate to zero, differentiating wrt Fx will also be zero: >>> _.doit() 0 Replacing undefined functions with concrete expressions One must be careful to replace undefined functions with expressions that contain variables consistent with the function definition and the variables of differentiation or else insconsistent result will be obtained. Consider the following example: >>> eq = f(x)*g(y) >>> eq.subs(f(x), x*y).diff(x, y).doit() y*Derivative(g(y), y) + g(y) >>> eq.diff(x, y).subs(f(x), x*y).doit() y*Derivative(g(y), y) The results differ because `f(x)` was replaced with an expression that involved both variables of differentiation. In the abstract case, differentiation of `f(x)` by `y` is 0; in the concrete case, the presence of `y` made that derivative nonvanishing and produced the extra `g(y)` term. Defining differentiation for an object An object must define ._eval_derivative(symbol) method that returns the differentiation result. This function only needs to consider the non-trivial case where expr contains symbol and it should call the diff() method internally (not _eval_derivative); Derivative should be the only one to call _eval_derivative. Any class can allow derivatives to be taken with respect to itself (while indicating its scalar nature). See the docstring of Expr._diff_wrt. See Also ======== _sort_variable_count """ is_Derivative = True @property def _diff_wrt(self): """An expression may be differentiated wrt a Derivative if it is in elementary form. Examples ======== >>> from sympy import Function, Derivative, cos >>> from sympy.abc import x >>> f = Function('f') >>> Derivative(f(x), x)._diff_wrt True >>> Derivative(cos(x), x)._diff_wrt False >>> Derivative(x + 1, x)._diff_wrt False A Derivative might be an unevaluated form of what will not be a valid variable of differentiation if evaluated. For example, >>> Derivative(f(f(x)), x).doit() Derivative(f(x), x)*Derivative(f(f(x)), f(x)) Such an expression will present the same ambiguities as arise when dealing with any other product, like `2*x`, so `_diff_wrt` is False: >>> Derivative(f(f(x)), x)._diff_wrt False """ return self.expr._diff_wrt and isinstance(self.doit(), Derivative) def __new__(cls, expr, *variables, **kwargs): from sympy.matrices.common import MatrixCommon from sympy import Integer, MatrixExpr from sympy.tensor.array import Array, NDimArray, derive_by_array from sympy.utilities.misc import filldedent expr = sympify(expr) symbols_or_none = getattr(expr, "free_symbols", None) has_symbol_set = isinstance(symbols_or_none, set) if not has_symbol_set: raise ValueError(filldedent(''' Since there are no variables in the expression %s, it cannot be differentiated.''' % expr)) # determine value for variables if it wasn't given if not variables: variables = expr.free_symbols if len(variables) != 1: if expr.is_number: return S.Zero if len(variables) == 0: raise ValueError(filldedent(''' Since there are no variables in the expression, the variable(s) of differentiation must be supplied to differentiate %s''' % expr)) else: raise ValueError(filldedent(''' Since there is more than one variable in the expression, the variable(s) of differentiation must be supplied to differentiate %s''' % expr)) # Standardize the variables by sympifying them: variables = list(sympify(variables)) # Split the list of variables into a list of the variables we are diff # wrt, where each element of the list has the form (s, count) where # s is the entity to diff wrt and count is the order of the # derivative. variable_count = [] array_likes = (tuple, list, Tuple) for i, v in enumerate(variables): if isinstance(v, Integer): if i == 0: raise ValueError("First variable cannot be a number: %i" % v) count = v prev, prevcount = variable_count[-1] if prevcount != 1: raise TypeError("tuple {0} followed by number {1}".format((prev, prevcount), v)) if count == 0: variable_count.pop() else: variable_count[-1] = Tuple(prev, count) else: if isinstance(v, array_likes): if len(v) == 0: # Ignore empty tuples: Derivative(expr, ... , (), ... ) continue if isinstance(v[0], array_likes): # Derive by array: Derivative(expr, ... , [[x, y, z]], ... ) if len(v) == 1: v = Array(v[0]) count = 1 else: v, count = v v = Array(v) else: v, count = v if count == 0: continue else: count = 1 variable_count.append(Tuple(v, count)) # light evaluation of contiguous, identical # items: (x, 1), (x, 1) -> (x, 2) merged = [] for t in variable_count: v, c = t if c.is_negative: raise ValueError( 'order of differentiation must be nonnegative') if merged and merged[-1][0] == v: c += merged[-1][1] if not c: merged.pop() else: merged[-1] = Tuple(v, c) else: merged.append(t) variable_count = merged # sanity check of variables of differentation; we waited # until the counts were computed since some variables may # have been removed because the count was 0 for v, c in variable_count: # v must have _diff_wrt True if not v._diff_wrt: __ = '' # filler to make error message neater raise ValueError(filldedent(''' Can't calculate derivative wrt %s.%s''' % (v, __))) # We make a special case for 0th derivative, because there is no # good way to unambiguously print this. if len(variable_count) == 0: return expr evaluate = kwargs.get('evaluate', False) if evaluate: if isinstance(expr, Derivative): expr = expr.canonical variable_count = [ (v.canonical if isinstance(v, Derivative) else v, c) for v, c in variable_count] # Look for a quick exit if there are symbols that don't appear in # expression at all. Note, this cannot check non-symbols like # Derivatives as those can be created by intermediate # derivatives. zero = False free = expr.free_symbols for v, c in variable_count: vfree = v.free_symbols if c.is_positive and vfree: if isinstance(v, AppliedUndef): # these match exactly since # x.diff(f(x)) == g(x).diff(f(x)) == 0 # and are not created by differentiation D = Dummy() if not expr.xreplace({v: D}).has(D): zero = True break elif isinstance(v, MatrixExpr): zero = False break elif isinstance(v, Symbol) and v not in free: zero = True break else: if not free & vfree: # e.g. v is IndexedBase or Matrix zero = True break if zero: if isinstance(expr, (MatrixCommon, NDimArray)): return expr.zeros(*expr.shape) elif expr.is_scalar: return S.Zero # make the order of symbols canonical #TODO: check if assumption of discontinuous derivatives exist variable_count = cls._sort_variable_count(variable_count) # denest if isinstance(expr, Derivative): variable_count = list(expr.variable_count) + variable_count expr = expr.expr return Derivative(expr, *variable_count, **kwargs) # we return here if evaluate is False or if there is no # _eval_derivative method if not evaluate or not hasattr(expr, '_eval_derivative'): # return an unevaluated Derivative if evaluate and variable_count == [(expr, 1)] and expr.is_scalar: # special hack providing evaluation for classes # that have defined is_scalar=True but have no # _eval_derivative defined return S.One return Expr.__new__(cls, expr, *variable_count) # evaluate the derivative by calling _eval_derivative method # of expr for each variable # ------------------------------------------------------------- nderivs = 0 # how many derivatives were performed unhandled = [] for i, (v, count) in enumerate(variable_count): old_expr = expr old_v = None is_symbol = v.is_symbol or isinstance(v, (Iterable, Tuple, MatrixCommon, NDimArray)) if not is_symbol: old_v = v v = Dummy('xi') expr = expr.xreplace({old_v: v}) # Derivatives and UndefinedFunctions are independent # of all others clashing = not (isinstance(old_v, Derivative) or \ isinstance(old_v, AppliedUndef)) if not v in expr.free_symbols and not clashing: return expr.diff(v) # expr's version of 0 if not old_v.is_scalar and not hasattr( old_v, '_eval_derivative'): # special hack providing evaluation for classes # that have defined is_scalar=True but have no # _eval_derivative defined expr *= old_v.diff(old_v) # Evaluate the derivative `n` times. If # `_eval_derivative_n_times` is not overridden by the current # object, the default in `Basic` will call a loop over # `_eval_derivative`: obj = expr._eval_derivative_n_times(v, count) if obj is not None and obj.is_zero: return obj nderivs += count if old_v is not None: if obj is not None: # remove the dummy that was used obj = obj.subs(v, old_v) # restore expr expr = old_expr if obj is None: # we've already checked for quick-exit conditions # that give 0 so the remaining variables # are contained in the expression but the expression # did not compute a derivative so we stop taking # derivatives unhandled = variable_count[i:] break expr = obj # what we have so far can be made canonical expr = expr.replace( lambda x: isinstance(x, Derivative), lambda x: x.canonical) if unhandled: if isinstance(expr, Derivative): unhandled = list(expr.variable_count) + unhandled expr = expr.expr expr = Expr.__new__(cls, expr, *unhandled) if (nderivs > 1) == True and kwargs.get('simplify', True): from sympy.core.exprtools import factor_terms from sympy.simplify.simplify import signsimp expr = factor_terms(signsimp(expr)) return expr @property def canonical(cls): return cls.func(cls.expr, *Derivative._sort_variable_count(cls.variable_count)) @classmethod def _sort_variable_count(cls, vc): """ Sort (variable, count) pairs into canonical order while retaining order of variables that do not commute during differentiation: * symbols and functions commute with each other * derivatives commute with each other * a derivative doesn't commute with anything it contains * any other object is not allowed to commute if it has free symbols in common with another object Examples ======== >>> from sympy import Derivative, Function, symbols, cos >>> vsort = Derivative._sort_variable_count >>> x, y, z = symbols('x y z') >>> f, g, h = symbols('f g h', cls=Function) Contiguous items are collapsed into one pair: >>> vsort([(x, 1), (x, 1)]) [(x, 2)] >>> vsort([(y, 1), (f(x), 1), (y, 1), (f(x), 1)]) [(y, 2), (f(x), 2)] Ordering is canonical. >>> def vsort0(*v): ... # docstring helper to ... # change vi -> (vi, 0), sort, and return vi vals ... return [i[0] for i in vsort([(i, 0) for i in v])] >>> vsort0(y, x) [x, y] >>> vsort0(g(y), g(x), f(y)) [f(y), g(x), g(y)] Symbols are sorted as far to the left as possible but never move to the left of a derivative having the same symbol in its variables; the same applies to AppliedUndef which are always sorted after Symbols: >>> dfx = f(x).diff(x) >>> assert vsort0(dfx, y) == [y, dfx] >>> assert vsort0(dfx, x) == [dfx, x] """ from sympy.utilities.iterables import uniq, topological_sort if not vc: return [] vc = list(vc) if len(vc) == 1: return [Tuple(*vc[0])] V = list(range(len(vc))) E = [] v = lambda i: vc[i][0] D = Dummy() def _block(d, v, wrt=False): # return True if v should not come before d else False if d == v: return wrt if d.is_Symbol: return False if isinstance(d, Derivative): # a derivative blocks if any of it's variables contain # v; the wrt flag will return True for an exact match # and will cause an AppliedUndef to block if v is in # the arguments if any(_block(k, v, wrt=True) for k in d._wrt_variables): return True return False if not wrt and isinstance(d, AppliedUndef): return False if v.is_Symbol: return v in d.free_symbols if isinstance(v, AppliedUndef): return _block(d.xreplace({v: D}), D) return d.free_symbols & v.free_symbols for i in range(len(vc)): for j in range(i): if _block(v(j), v(i)): E.append((j,i)) # this is the default ordering to use in case of ties O = dict(zip(ordered(uniq([i for i, c in vc])), range(len(vc)))) ix = topological_sort((V, E), key=lambda i: O[v(i)]) # merge counts of contiguously identical items merged = [] for v, c in [vc[i] for i in ix]: if merged and merged[-1][0] == v: merged[-1][1] += c else: merged.append([v, c]) return [Tuple(*i) for i in merged] def _eval_is_commutative(self): return self.expr.is_commutative def _eval_derivative(self, v): # If v (the variable of differentiation) is not in # self.variables, we might be able to take the derivative. if v not in self._wrt_variables: dedv = self.expr.diff(v) if isinstance(dedv, Derivative): return dedv.func(dedv.expr, *(self.variable_count + dedv.variable_count)) # dedv (d(self.expr)/dv) could have simplified things such that the # derivative wrt things in self.variables can now be done. Thus, # we set evaluate=True to see if there are any other derivatives # that can be done. The most common case is when dedv is a simple # number so that the derivative wrt anything else will vanish. return self.func(dedv, *self.variables, evaluate=True) # In this case v was in self.variables so the derivative wrt v has # already been attempted and was not computed, either because it # couldn't be or evaluate=False originally. variable_count = list(self.variable_count) variable_count.append((v, 1)) return self.func(self.expr, *variable_count, evaluate=False) def doit(self, **hints): expr = self.expr if hints.get('deep', True): expr = expr.doit(**hints) hints['evaluate'] = True rv = self.func(expr, *self.variable_count, **hints) if rv!= self and rv.has(Derivative): rv = rv.doit(**hints) return rv @_sympifyit('z0', NotImplementedError) def doit_numerically(self, z0): """ Evaluate the derivative at z numerically. When we can represent derivatives at a point, this should be folded into the normal evalf. For now, we need a special method. """ if len(self.free_symbols) != 1 or len(self.variables) != 1: raise NotImplementedError('partials and higher order derivatives') z = list(self.free_symbols)[0] def eval(x): f0 = self.expr.subs(z, Expr._from_mpmath(x, prec=mpmath.mp.prec)) f0 = f0.evalf(mlib.libmpf.prec_to_dps(mpmath.mp.prec)) return f0._to_mpmath(mpmath.mp.prec) return Expr._from_mpmath(mpmath.diff(eval, z0._to_mpmath(mpmath.mp.prec)), mpmath.mp.prec) @property def expr(self): return self._args[0] @property def _wrt_variables(self): # return the variables of differentiation without # respect to the type of count (int or symbolic) return [i[0] for i in self.variable_count] @property def variables(self): # TODO: deprecate? YES, make this 'enumerated_variables' and # name _wrt_variables as variables # TODO: support for `d^n`? rv = [] for v, count in self.variable_count: if not count.is_Integer: raise TypeError(filldedent(''' Cannot give expansion for symbolic count. If you just want a list of all variables of differentiation, use _wrt_variables.''')) rv.extend([v]*count) return tuple(rv) @property def variable_count(self): return self._args[1:] @property def derivative_count(self): return sum([count for var, count in self.variable_count], 0) @property def free_symbols(self): return self.expr.free_symbols def _eval_subs(self, old, new): # The substitution (old, new) cannot be done inside # Derivative(expr, vars) for a variety of reasons # as handled below. if old in self._wrt_variables: # first handle the counts expr = self.func(self.expr, *[(v, c.subs(old, new)) for v, c in self.variable_count]) if expr != self: return expr._eval_subs(old, new) # quick exit case if not getattr(new, '_diff_wrt', False): # case (0): new is not a valid variable of # differentiation if isinstance(old, Symbol): # don't introduce a new symbol if the old will do return Subs(self, old, new) else: xi = Dummy('xi') return Subs(self.xreplace({old: xi}), xi, new) # If both are Derivatives with the same expr, check if old is # equivalent to self or if old is a subderivative of self. if old.is_Derivative and old.expr == self.expr: if self.canonical == old.canonical: return new # collections.Counter doesn't have __le__ def _subset(a, b): return all((a[i] <= b[i]) == True for i in a) old_vars = Counter(dict(reversed(old.variable_count))) self_vars = Counter(dict(reversed(self.variable_count))) if _subset(old_vars, self_vars): return Derivative(new, *(self_vars - old_vars).items()).canonical args = list(self.args) newargs = list(x._subs(old, new) for x in args) if args[0] == old: # complete replacement of self.expr # we already checked that the new is valid so we know # it won't be a problem should it appear in variables return Derivative(*newargs) if newargs[0] != args[0]: # case (1) can't change expr by introducing something that is in # the _wrt_variables if it was already in the expr # e.g. # for Derivative(f(x, g(y)), y), x cannot be replaced with # anything that has y in it; for f(g(x), g(y)).diff(g(y)) # g(x) cannot be replaced with anything that has g(y) syms = {vi: Dummy() for vi in self._wrt_variables if not vi.is_Symbol} wrt = set(syms.get(vi, vi) for vi in self._wrt_variables) forbidden = args[0].xreplace(syms).free_symbols & wrt nfree = new.xreplace(syms).free_symbols ofree = old.xreplace(syms).free_symbols if (nfree - ofree) & forbidden: return Subs(self, old, new) viter = ((i, j) for ((i, _), (j, _)) in zip(newargs[1:], args[1:])) if any(i != j for i, j in viter): # a wrt-variable change # case (2) can't change vars by introducing a variable # that is contained in expr, e.g. # for Derivative(f(z, g(h(x), y)), y), y cannot be changed to # x, h(x), or g(h(x), y) for a in _atomic(self.expr, recursive=True): for i in range(1, len(newargs)): vi, _ = newargs[i] if a == vi and vi != args[i][0]: return Subs(self, old, new) # more arg-wise checks vc = newargs[1:] oldv = self._wrt_variables newe = self.expr subs = [] for i, (vi, ci) in enumerate(vc): if not vi._diff_wrt: # case (3) invalid differentiation expression so # create a replacement dummy xi = Dummy('xi_%i' % i) # replace the old valid variable with the dummy # in the expression newe = newe.xreplace({oldv[i]: xi}) # and replace the bad variable with the dummy vc[i] = (xi, ci) # and record the dummy with the new (invalid) # differentiation expression subs.append((xi, vi)) if subs: # handle any residual substitution in the expression newe = newe._subs(old, new) # return the Subs-wrapped derivative return Subs(Derivative(newe, *vc), *zip(*subs)) # everything was ok return Derivative(*newargs) def _eval_lseries(self, x, logx): dx = self.variables for term in self.expr.lseries(x, logx=logx): yield self.func(term, *dx) def _eval_nseries(self, x, n, logx): arg = self.expr.nseries(x, n=n, logx=logx) o = arg.getO() dx = self.variables rv = [self.func(a, *dx) for a in Add.make_args(arg.removeO())] if o: rv.append(o/x) return Add(*rv) def _eval_as_leading_term(self, x): series_gen = self.expr.lseries(x) d = S.Zero for leading_term in series_gen: d = diff(leading_term, *self.variables) if d != 0: break return d def _sage_(self): import sage.all as sage args = [arg._sage_() for arg in self.args] return sage.derivative(*args) def as_finite_difference(self, points=1, x0=None, wrt=None): """ Expresses a Derivative instance as a finite difference. Parameters ========== points : sequence or coefficient, optional If sequence: discrete values (length >= order+1) of the independent variable used for generating the finite difference weights. If it is a coefficient, it will be used as the step-size for generating an equidistant sequence of length order+1 centered around ``x0``. Default: 1 (step-size 1) x0 : number or Symbol, optional the value of the independent variable (``wrt``) at which the derivative is to be approximated. Default: same as ``wrt``. wrt : Symbol, optional "with respect to" the variable for which the (partial) derivative is to be approximated for. If not provided it is required that the derivative is ordinary. Default: ``None``. Examples ======== >>> from sympy import symbols, Function, exp, sqrt, Symbol >>> x, h = symbols('x h') >>> f = Function('f') >>> f(x).diff(x).as_finite_difference() -f(x - 1/2) + f(x + 1/2) The default step size and number of points are 1 and ``order + 1`` respectively. We can change the step size by passing a symbol as a parameter: >>> f(x).diff(x).as_finite_difference(h) -f(-h/2 + x)/h + f(h/2 + x)/h We can also specify the discretized values to be used in a sequence: >>> f(x).diff(x).as_finite_difference([x, x+h, x+2*h]) -3*f(x)/(2*h) + 2*f(h + x)/h - f(2*h + x)/(2*h) The algorithm is not restricted to use equidistant spacing, nor do we need to make the approximation around ``x0``, but we can get an expression estimating the derivative at an offset: >>> e, sq2 = exp(1), sqrt(2) >>> xl = [x-h, x+h, x+e*h] >>> f(x).diff(x, 1).as_finite_difference(xl, x+h*sq2) # doctest: +ELLIPSIS 2*h*((h + sqrt(2)*h)/(2*h) - (-sqrt(2)*h + h)/(2*h))*f(E*h + x)/... Partial derivatives are also supported: >>> y = Symbol('y') >>> d2fdxdy=f(x,y).diff(x,y) >>> d2fdxdy.as_finite_difference(wrt=x) -Derivative(f(x - 1/2, y), y) + Derivative(f(x + 1/2, y), y) We can apply ``as_finite_difference`` to ``Derivative`` instances in compound expressions using ``replace``: >>> (1 + 42**f(x).diff(x)).replace(lambda arg: arg.is_Derivative, ... lambda arg: arg.as_finite_difference()) 42**(-f(x - 1/2) + f(x + 1/2)) + 1 See also ======== sympy.calculus.finite_diff.apply_finite_diff sympy.calculus.finite_diff.differentiate_finite sympy.calculus.finite_diff.finite_diff_weights """ from ..calculus.finite_diff import _as_finite_diff return _as_finite_diff(self, points, x0, wrt) class Lambda(Expr): """ Lambda(x, expr) represents a lambda function similar to Python's 'lambda x: expr'. A function of several variables is written as Lambda((x, y, ...), expr). A simple example: >>> from sympy import Lambda >>> from sympy.abc import x >>> f = Lambda(x, x**2) >>> f(4) 16 For multivariate functions, use: >>> from sympy.abc import y, z, t >>> f2 = Lambda((x, y, z, t), x + y**z + t**z) >>> f2(1, 2, 3, 4) 73 A handy shortcut for lots of arguments: >>> p = x, y, z >>> f = Lambda(p, x + y*z) >>> f(*p) x + y*z """ is_Function = True def __new__(cls, variables, expr): from sympy.sets.sets import FiniteSet v = list(variables) if iterable(variables) else [variables] for i in v: if not getattr(i, 'is_symbol', False): raise TypeError('variable is not a symbol: %s' % i) if len(v) == 1 and v[0] == expr: return S.IdentityFunction obj = Expr.__new__(cls, Tuple(*v), sympify(expr)) obj.nargs = FiniteSet(len(v)) return obj @property def variables(self): """The variables used in the internal representation of the function""" return self._args[0] bound_symbols = variables @property def expr(self): """The return value of the function""" return self._args[1] @property def free_symbols(self): return self.expr.free_symbols - set(self.variables) def __call__(self, *args): n = len(args) if n not in self.nargs: # Lambda only ever has 1 value in nargs # XXX: exception message must be in exactly this format to # make it work with NumPy's functions like vectorize(). See, # for example, https://github.com/numpy/numpy/issues/1697. # The ideal solution would be just to attach metadata to # the exception and change NumPy to take advantage of this. ## XXX does this apply to Lambda? If not, remove this comment. temp = ('%(name)s takes exactly %(args)s ' 'argument%(plural)s (%(given)s given)') raise TypeError(temp % { 'name': self, 'args': list(self.nargs)[0], 'plural': 's'*(list(self.nargs)[0] != 1), 'given': n}) return self.expr.xreplace(dict(list(zip(self.variables, args)))) def __eq__(self, other): if not isinstance(other, Lambda): return False if self.nargs != other.nargs: return False selfexpr = self.args[1] otherexpr = other.args[1] otherexpr = otherexpr.xreplace(dict(list(zip(other.args[0], self.args[0])))) return selfexpr == otherexpr def __ne__(self, other): return not(self == other) def __hash__(self): return super(Lambda, self).__hash__() def _hashable_content(self): return (self.expr.xreplace(self.canonical_variables),) @property def is_identity(self): """Return ``True`` if this ``Lambda`` is an identity function. """ if len(self.args) == 2: return self.args[0] == self.args[1] else: return None class Subs(Expr): """ Represents unevaluated substitutions of an expression. ``Subs(expr, x, x0)`` receives 3 arguments: an expression, a variable or list of distinct variables and a point or list of evaluation points corresponding to those variables. ``Subs`` objects are generally useful to represent unevaluated derivatives calculated at a point. The variables may be expressions, but they are subjected to the limitations of subs(), so it is usually a good practice to use only symbols for variables, since in that case there can be no ambiguity. There's no automatic expansion - use the method .doit() to effect all possible substitutions of the object and also of objects inside the expression. When evaluating derivatives at a point that is not a symbol, a Subs object is returned. One is also able to calculate derivatives of Subs objects - in this case the expression is always expanded (for the unevaluated form, use Derivative()). Examples ======== >>> from sympy import Subs, Function, sin, cos >>> from sympy.abc import x, y, z >>> f = Function('f') Subs are created when a particular substitution cannot be made. The x in the derivative cannot be replaced with 0 because 0 is not a valid variables of differentiation: >>> f(x).diff(x).subs(x, 0) Subs(Derivative(f(x), x), x, 0) Once f is known, the derivative and evaluation at 0 can be done: >>> _.subs(f, sin).doit() == sin(x).diff(x).subs(x, 0) == cos(0) True Subs can also be created directly with one or more variables: >>> Subs(f(x)*sin(y) + z, (x, y), (0, 1)) Subs(z + f(x)*sin(y), (x, y), (0, 1)) >>> _.doit() z + f(0)*sin(1) Notes ===== In order to allow expressions to combine before doit is done, a representation of the Subs expression is used internally to make expressions that are superficially different compare the same: >>> a, b = Subs(x, x, 0), Subs(y, y, 0) >>> a + b 2*Subs(x, x, 0) This can lead to unexpected consequences when using methods like `has` that are cached: >>> s = Subs(x, x, 0) >>> s.has(x), s.has(y) (True, False) >>> ss = s.subs(x, y) >>> ss.has(x), ss.has(y) (True, False) >>> s, ss (Subs(x, x, 0), Subs(y, y, 0)) """ def __new__(cls, expr, variables, point, **assumptions): from sympy import Symbol if not is_sequence(variables, Tuple): variables = [variables] variables = Tuple(*variables) if has_dups(variables): repeated = [str(v) for v, i in Counter(variables).items() if i > 1] __ = ', '.join(repeated) raise ValueError(filldedent(''' The following expressions appear more than once: %s ''' % __)) point = Tuple(*(point if is_sequence(point, Tuple) else [point])) if len(point) != len(variables): raise ValueError('Number of point values must be the same as ' 'the number of variables.') if not point: return sympify(expr) # denest if isinstance(expr, Subs): variables = expr.variables + variables point = expr.point + point expr = expr.expr else: expr = sympify(expr) # use symbols with names equal to the point value (with preppended _) # to give a variable-independent expression pre = "_" pts = sorted(set(point), key=default_sort_key) from sympy.printing import StrPrinter class CustomStrPrinter(StrPrinter): def _print_Dummy(self, expr): return str(expr) + str(expr.dummy_index) def mystr(expr, **settings): p = CustomStrPrinter(settings) return p.doprint(expr) while 1: s_pts = {p: Symbol(pre + mystr(p)) for p in pts} reps = [(v, s_pts[p]) for v, p in zip(variables, point)] # if any underscore-preppended symbol is already a free symbol # and is a variable with a different point value, then there # is a clash, e.g. _0 clashes in Subs(_0 + _1, (_0, _1), (1, 0)) # because the new symbol that would be created is _1 but _1 # is already mapped to 0 so __0 and __1 are used for the new # symbols if any(r in expr.free_symbols and r in variables and Symbol(pre + mystr(point[variables.index(r)])) != r for _, r in reps): pre += "_" continue break obj = Expr.__new__(cls, expr, Tuple(*variables), point) obj._expr = expr.xreplace(dict(reps)) return obj def _eval_is_commutative(self): return self.expr.is_commutative def doit(self, **hints): e, v, p = self.args # remove self mappings for i, (vi, pi) in enumerate(zip(v, p)): if vi == pi: v = v[:i] + v[i + 1:] p = p[:i] + p[i + 1:] if not v: return self.expr if isinstance(e, Derivative): # apply functions first, e.g. f -> cos undone = [] for i, vi in enumerate(v): if isinstance(vi, FunctionClass): e = e.subs(vi, p[i]) else: undone.append((vi, p[i])) if not isinstance(e, Derivative): e = e.doit() if isinstance(e, Derivative): # do Subs that aren't related to differentiation undone2 = [] D = Dummy() for vi, pi in undone: if D not in e.xreplace({vi: D}).free_symbols: e = e.subs(vi, pi) else: undone2.append((vi, pi)) undone = undone2 # differentiate wrt variables that are present wrt = [] D = Dummy() expr = e.expr free = expr.free_symbols for vi, ci in e.variable_count: if isinstance(vi, Symbol) and vi in free: expr = expr.diff((vi, ci)) elif D in expr.subs(vi, D).free_symbols: expr = expr.diff((vi, ci)) else: wrt.append((vi, ci)) # inject remaining subs rv = expr.subs(undone) # do remaining differentiation *in order given* for vc in wrt: rv = rv.diff(vc) else: # inject remaining subs rv = e.subs(undone) else: rv = e.doit(**hints).subs(list(zip(v, p))) if hints.get('deep', True) and rv != self: rv = rv.doit(**hints) return rv def evalf(self, prec=None, **options): return self.doit().evalf(prec, **options) n = evalf @property def variables(self): """The variables to be evaluated""" return self._args[1] bound_symbols = variables @property def expr(self): """The expression on which the substitution operates""" return self._args[0] @property def point(self): """The values for which the variables are to be substituted""" return self._args[2] @property def free_symbols(self): return (self.expr.free_symbols - set(self.variables) | set(self.point.free_symbols)) @property def expr_free_symbols(self): return (self.expr.expr_free_symbols - set(self.variables) | set(self.point.expr_free_symbols)) def __eq__(self, other): if not isinstance(other, Subs): return False return self._hashable_content() == other._hashable_content() def __ne__(self, other): return not(self == other) def __hash__(self): return super(Subs, self).__hash__() def _hashable_content(self): return (self._expr.xreplace(self.canonical_variables), ) + tuple(ordered([(v, p) for v, p in zip(self.variables, self.point) if not self.expr.has(v)])) def _eval_subs(self, old, new): # Subs doit will do the variables in order; the semantics # of subs for Subs is have the following invariant for # Subs object foo: # foo.doit().subs(reps) == foo.subs(reps).doit() pt = list(self.point) if old in self.variables: if _atomic(new) == set([new]) and not any( i.has(new) for i in self.args): # the substitution is neutral return self.xreplace({old: new}) # any occurance of old before this point will get # handled by replacements from here on i = self.variables.index(old) for j in range(i, len(self.variables)): pt[j] = pt[j]._subs(old, new) return self.func(self.expr, self.variables, pt) v = [i._subs(old, new) for i in self.variables] if v != list(self.variables): return self.func(self.expr, self.variables + (old,), pt + [new]) expr = self.expr._subs(old, new) pt = [i._subs(old, new) for i in self.point] return self.func(expr, v, pt) def _eval_derivative(self, s): # Apply the chain rule of the derivative on the substitution variables: val = Add.fromiter(p.diff(s) * Subs(self.expr.diff(v), self.variables, self.point).doit() for v, p in zip(self.variables, self.point)) # Check if there are free symbols in `self.expr`: # First get the `expr_free_symbols`, which returns the free symbols # that are directly contained in an expression node (i.e. stop # searching if the node isn't an expression). At this point turn the # expressions into `free_symbols` and check if there are common free # symbols in `self.expr` and the deriving factor. fs1 = {j for i in self.expr_free_symbols for j in i.free_symbols} if len(fs1 & s.free_symbols) > 0: val += Subs(self.expr.diff(s), self.variables, self.point).doit() return val def _eval_nseries(self, x, n, logx): if x in self.point: # x is the variable being substituted into apos = self.point.index(x) other = self.variables[apos] else: other = x arg = self.expr.nseries(other, n=n, logx=logx) o = arg.getO() terms = Add.make_args(arg.removeO()) rv = Add(*[self.func(a, *self.args[1:]) for a in terms]) if o: rv += o.subs(other, x) return rv def _eval_as_leading_term(self, x): if x in self.point: ipos = self.point.index(x) xvar = self.variables[ipos] return self.expr.as_leading_term(xvar) if x in self.variables: # if `x` is a dummy variable, it means it won't exist after the # substitution has been performed: return self # The variable is independent of the substitution: return self.expr.as_leading_term(x) def diff(f, *symbols, **kwargs): """ Differentiate f with respect to symbols. This is just a wrapper to unify .diff() and the Derivative class; its interface is similar to that of integrate(). You can use the same shortcuts for multiple variables as with Derivative. For example, diff(f(x), x, x, x) and diff(f(x), x, 3) both return the third derivative of f(x). You can pass evaluate=False to get an unevaluated Derivative class. Note that if there are 0 symbols (such as diff(f(x), x, 0), then the result will be the function (the zeroth derivative), even if evaluate=False. Examples ======== >>> from sympy import sin, cos, Function, diff >>> from sympy.abc import x, y >>> f = Function('f') >>> diff(sin(x), x) cos(x) >>> diff(f(x), x, x, x) Derivative(f(x), (x, 3)) >>> diff(f(x), x, 3) Derivative(f(x), (x, 3)) >>> diff(sin(x)*cos(y), x, 2, y, 2) sin(x)*cos(y) >>> type(diff(sin(x), x)) cos >>> type(diff(sin(x), x, evaluate=False)) <class 'sympy.core.function.Derivative'> >>> type(diff(sin(x), x, 0)) sin >>> type(diff(sin(x), x, 0, evaluate=False)) sin >>> diff(sin(x)) cos(x) >>> diff(sin(x*y)) Traceback (most recent call last): ... ValueError: specify differentiation variables to differentiate sin(x*y) Note that ``diff(sin(x))`` syntax is meant only for convenience in interactive sessions and should be avoided in library code. References ========== http://reference.wolfram.com/legacy/v5_2/Built-inFunctions/AlgebraicComputation/Calculus/D.html See Also ======== Derivative sympy.geometry.util.idiff: computes the derivative implicitly """ if hasattr(f, 'diff'): return f.diff(*symbols, **kwargs) kwargs.setdefault('evaluate', True) return Derivative(f, *symbols, **kwargs) def expand(e, deep=True, modulus=None, power_base=True, power_exp=True, mul=True, log=True, multinomial=True, basic=True, **hints): r""" Expand an expression using methods given as hints. Hints evaluated unless explicitly set to False are: ``basic``, ``log``, ``multinomial``, ``mul``, ``power_base``, and ``power_exp`` The following hints are supported but not applied unless set to True: ``complex``, ``func``, and ``trig``. In addition, the following meta-hints are supported by some or all of the other hints: ``frac``, ``numer``, ``denom``, ``modulus``, and ``force``. ``deep`` is supported by all hints. Additionally, subclasses of Expr may define their own hints or meta-hints. The ``basic`` hint is used for any special rewriting of an object that should be done automatically (along with the other hints like ``mul``) when expand is called. This is a catch-all hint to handle any sort of expansion that may not be described by the existing hint names. To use this hint an object should override the ``_eval_expand_basic`` method. Objects may also define their own expand methods, which are not run by default. See the API section below. If ``deep`` is set to ``True`` (the default), things like arguments of functions are recursively expanded. Use ``deep=False`` to only expand on the top level. If the ``force`` hint is used, assumptions about variables will be ignored in making the expansion. Hints ===== These hints are run by default mul --- Distributes multiplication over addition: >>> from sympy import cos, exp, sin >>> from sympy.abc import x, y, z >>> (y*(x + z)).expand(mul=True) x*y + y*z multinomial ----------- Expand (x + y + ...)**n where n is a positive integer. >>> ((x + y + z)**2).expand(multinomial=True) x**2 + 2*x*y + 2*x*z + y**2 + 2*y*z + z**2 power_exp --------- Expand addition in exponents into multiplied bases. >>> exp(x + y).expand(power_exp=True) exp(x)*exp(y) >>> (2**(x + y)).expand(power_exp=True) 2**x*2**y power_base ---------- Split powers of multiplied bases. This only happens by default if assumptions allow, or if the ``force`` meta-hint is used: >>> ((x*y)**z).expand(power_base=True) (x*y)**z >>> ((x*y)**z).expand(power_base=True, force=True) x**z*y**z >>> ((2*y)**z).expand(power_base=True) 2**z*y**z Note that in some cases where this expansion always holds, SymPy performs it automatically: >>> (x*y)**2 x**2*y**2 log --- Pull out power of an argument as a coefficient and split logs products into sums of logs. Note that these only work if the arguments of the log function have the proper assumptions--the arguments must be positive and the exponents must be real--or else the ``force`` hint must be True: >>> from sympy import log, symbols >>> log(x**2*y).expand(log=True) log(x**2*y) >>> log(x**2*y).expand(log=True, force=True) 2*log(x) + log(y) >>> x, y = symbols('x,y', positive=True) >>> log(x**2*y).expand(log=True) 2*log(x) + log(y) basic ----- This hint is intended primarily as a way for custom subclasses to enable expansion by default. These hints are not run by default: complex ------- Split an expression into real and imaginary parts. >>> x, y = symbols('x,y') >>> (x + y).expand(complex=True) re(x) + re(y) + I*im(x) + I*im(y) >>> cos(x).expand(complex=True) -I*sin(re(x))*sinh(im(x)) + cos(re(x))*cosh(im(x)) Note that this is just a wrapper around ``as_real_imag()``. Most objects that wish to redefine ``_eval_expand_complex()`` should consider redefining ``as_real_imag()`` instead. func ---- Expand other functions. >>> from sympy import gamma >>> gamma(x + 1).expand(func=True) x*gamma(x) trig ---- Do trigonometric expansions. >>> cos(x + y).expand(trig=True) -sin(x)*sin(y) + cos(x)*cos(y) >>> sin(2*x).expand(trig=True) 2*sin(x)*cos(x) Note that the forms of ``sin(n*x)`` and ``cos(n*x)`` in terms of ``sin(x)`` and ``cos(x)`` are not unique, due to the identity `\sin^2(x) + \cos^2(x) = 1`. The current implementation uses the form obtained from Chebyshev polynomials, but this may change. See `this MathWorld article <http://mathworld.wolfram.com/Multiple-AngleFormulas.html>`_ for more information. Notes ===== - You can shut off unwanted methods:: >>> (exp(x + y)*(x + y)).expand() x*exp(x)*exp(y) + y*exp(x)*exp(y) >>> (exp(x + y)*(x + y)).expand(power_exp=False) x*exp(x + y) + y*exp(x + y) >>> (exp(x + y)*(x + y)).expand(mul=False) (x + y)*exp(x)*exp(y) - Use deep=False to only expand on the top level:: >>> exp(x + exp(x + y)).expand() exp(x)*exp(exp(x)*exp(y)) >>> exp(x + exp(x + y)).expand(deep=False) exp(x)*exp(exp(x + y)) - Hints are applied in an arbitrary, but consistent order (in the current implementation, they are applied in alphabetical order, except multinomial comes before mul, but this may change). Because of this, some hints may prevent expansion by other hints if they are applied first. For example, ``mul`` may distribute multiplications and prevent ``log`` and ``power_base`` from expanding them. Also, if ``mul`` is applied before ``multinomial`, the expression might not be fully distributed. The solution is to use the various ``expand_hint`` helper functions or to use ``hint=False`` to this function to finely control which hints are applied. Here are some examples:: >>> from sympy import expand, expand_mul, expand_power_base >>> x, y, z = symbols('x,y,z', positive=True) >>> expand(log(x*(y + z))) log(x) + log(y + z) Here, we see that ``log`` was applied before ``mul``. To get the mul expanded form, either of the following will work:: >>> expand_mul(log(x*(y + z))) log(x*y + x*z) >>> expand(log(x*(y + z)), log=False) log(x*y + x*z) A similar thing can happen with the ``power_base`` hint:: >>> expand((x*(y + z))**x) (x*y + x*z)**x To get the ``power_base`` expanded form, either of the following will work:: >>> expand((x*(y + z))**x, mul=False) x**x*(y + z)**x >>> expand_power_base((x*(y + z))**x) x**x*(y + z)**x >>> expand((x + y)*y/x) y + y**2/x The parts of a rational expression can be targeted:: >>> expand((x + y)*y/x/(x + 1), frac=True) (x*y + y**2)/(x**2 + x) >>> expand((x + y)*y/x/(x + 1), numer=True) (x*y + y**2)/(x*(x + 1)) >>> expand((x + y)*y/x/(x + 1), denom=True) y*(x + y)/(x**2 + x) - The ``modulus`` meta-hint can be used to reduce the coefficients of an expression post-expansion:: >>> expand((3*x + 1)**2) 9*x**2 + 6*x + 1 >>> expand((3*x + 1)**2, modulus=5) 4*x**2 + x + 1 - Either ``expand()`` the function or ``.expand()`` the method can be used. Both are equivalent:: >>> expand((x + 1)**2) x**2 + 2*x + 1 >>> ((x + 1)**2).expand() x**2 + 2*x + 1 API === Objects can define their own expand hints by defining ``_eval_expand_hint()``. The function should take the form:: def _eval_expand_hint(self, **hints): # Only apply the method to the top-level expression ... See also the example below. Objects should define ``_eval_expand_hint()`` methods only if ``hint`` applies to that specific object. The generic ``_eval_expand_hint()`` method defined in Expr will handle the no-op case. Each hint should be responsible for expanding that hint only. Furthermore, the expansion should be applied to the top-level expression only. ``expand()`` takes care of the recursion that happens when ``deep=True``. You should only call ``_eval_expand_hint()`` methods directly if you are 100% sure that the object has the method, as otherwise you are liable to get unexpected ``AttributeError``s. Note, again, that you do not need to recursively apply the hint to args of your object: this is handled automatically by ``expand()``. ``_eval_expand_hint()`` should generally not be used at all outside of an ``_eval_expand_hint()`` method. If you want to apply a specific expansion from within another method, use the public ``expand()`` function, method, or ``expand_hint()`` functions. In order for expand to work, objects must be rebuildable by their args, i.e., ``obj.func(*obj.args) == obj`` must hold. Expand methods are passed ``**hints`` so that expand hints may use 'metahints'--hints that control how different expand methods are applied. For example, the ``force=True`` hint described above that causes ``expand(log=True)`` to ignore assumptions is such a metahint. The ``deep`` meta-hint is handled exclusively by ``expand()`` and is not passed to ``_eval_expand_hint()`` methods. Note that expansion hints should generally be methods that perform some kind of 'expansion'. For hints that simply rewrite an expression, use the .rewrite() API. Examples ======== >>> from sympy import Expr, sympify >>> class MyClass(Expr): ... def __new__(cls, *args): ... args = sympify(args) ... return Expr.__new__(cls, *args) ... ... def _eval_expand_double(self, **hints): ... ''' ... Doubles the args of MyClass. ... ... If there more than four args, doubling is not performed, ... unless force=True is also used (False by default). ... ''' ... force = hints.pop('force', False) ... if not force and len(self.args) > 4: ... return self ... return self.func(*(self.args + self.args)) ... >>> a = MyClass(1, 2, MyClass(3, 4)) >>> a MyClass(1, 2, MyClass(3, 4)) >>> a.expand(double=True) MyClass(1, 2, MyClass(3, 4, 3, 4), 1, 2, MyClass(3, 4, 3, 4)) >>> a.expand(double=True, deep=False) MyClass(1, 2, MyClass(3, 4), 1, 2, MyClass(3, 4)) >>> b = MyClass(1, 2, 3, 4, 5) >>> b.expand(double=True) MyClass(1, 2, 3, 4, 5) >>> b.expand(double=True, force=True) MyClass(1, 2, 3, 4, 5, 1, 2, 3, 4, 5) See Also ======== expand_log, expand_mul, expand_multinomial, expand_complex, expand_trig, expand_power_base, expand_power_exp, expand_func, hyperexpand """ # don't modify this; modify the Expr.expand method hints['power_base'] = power_base hints['power_exp'] = power_exp hints['mul'] = mul hints['log'] = log hints['multinomial'] = multinomial hints['basic'] = basic return sympify(e).expand(deep=deep, modulus=modulus, **hints) # This is a special application of two hints def _mexpand(expr, recursive=False): # expand multinomials and then expand products; this may not always # be sufficient to give a fully expanded expression (see # test_issue_8247_8354 in test_arit) if expr is None: return was = None while was != expr: was, expr = expr, expand_mul(expand_multinomial(expr)) if not recursive: break return expr # These are simple wrappers around single hints. def expand_mul(expr, deep=True): """ Wrapper around expand that only uses the mul hint. See the expand docstring for more information. Examples ======== >>> from sympy import symbols, expand_mul, exp, log >>> x, y = symbols('x,y', positive=True) >>> expand_mul(exp(x+y)*(x+y)*log(x*y**2)) x*exp(x + y)*log(x*y**2) + y*exp(x + y)*log(x*y**2) """ return sympify(expr).expand(deep=deep, mul=True, power_exp=False, power_base=False, basic=False, multinomial=False, log=False) def expand_multinomial(expr, deep=True): """ Wrapper around expand that only uses the multinomial hint. See the expand docstring for more information. Examples ======== >>> from sympy import symbols, expand_multinomial, exp >>> x, y = symbols('x y', positive=True) >>> expand_multinomial((x + exp(x + 1))**2) x**2 + 2*x*exp(x + 1) + exp(2*x + 2) """ return sympify(expr).expand(deep=deep, mul=False, power_exp=False, power_base=False, basic=False, multinomial=True, log=False) def expand_log(expr, deep=True, force=False): """ Wrapper around expand that only uses the log hint. See the expand docstring for more information. Examples ======== >>> from sympy import symbols, expand_log, exp, log >>> x, y = symbols('x,y', positive=True) >>> expand_log(exp(x+y)*(x+y)*log(x*y**2)) (x + y)*(log(x) + 2*log(y))*exp(x + y) """ return sympify(expr).expand(deep=deep, log=True, mul=False, power_exp=False, power_base=False, multinomial=False, basic=False, force=force) def expand_func(expr, deep=True): """ Wrapper around expand that only uses the func hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_func, gamma >>> from sympy.abc import x >>> expand_func(gamma(x + 2)) x*(x + 1)*gamma(x) """ return sympify(expr).expand(deep=deep, func=True, basic=False, log=False, mul=False, power_exp=False, power_base=False, multinomial=False) def expand_trig(expr, deep=True): """ Wrapper around expand that only uses the trig hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_trig, sin >>> from sympy.abc import x, y >>> expand_trig(sin(x+y)*(x+y)) (x + y)*(sin(x)*cos(y) + sin(y)*cos(x)) """ return sympify(expr).expand(deep=deep, trig=True, basic=False, log=False, mul=False, power_exp=False, power_base=False, multinomial=False) def expand_complex(expr, deep=True): """ Wrapper around expand that only uses the complex hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_complex, exp, sqrt, I >>> from sympy.abc import z >>> expand_complex(exp(z)) I*exp(re(z))*sin(im(z)) + exp(re(z))*cos(im(z)) >>> expand_complex(sqrt(I)) sqrt(2)/2 + sqrt(2)*I/2 See Also ======== Expr.as_real_imag """ return sympify(expr).expand(deep=deep, complex=True, basic=False, log=False, mul=False, power_exp=False, power_base=False, multinomial=False) def expand_power_base(expr, deep=True, force=False): """ Wrapper around expand that only uses the power_base hint. See the expand docstring for more information. A wrapper to expand(power_base=True) which separates a power with a base that is a Mul into a product of powers, without performing any other expansions, provided that assumptions about the power's base and exponent allow. deep=False (default is True) will only apply to the top-level expression. force=True (default is False) will cause the expansion to ignore assumptions about the base and exponent. When False, the expansion will only happen if the base is non-negative or the exponent is an integer. >>> from sympy.abc import x, y, z >>> from sympy import expand_power_base, sin, cos, exp >>> (x*y)**2 x**2*y**2 >>> (2*x)**y (2*x)**y >>> expand_power_base(_) 2**y*x**y >>> expand_power_base((x*y)**z) (x*y)**z >>> expand_power_base((x*y)**z, force=True) x**z*y**z >>> expand_power_base(sin((x*y)**z), deep=False) sin((x*y)**z) >>> expand_power_base(sin((x*y)**z), force=True) sin(x**z*y**z) >>> expand_power_base((2*sin(x))**y + (2*cos(x))**y) 2**y*sin(x)**y + 2**y*cos(x)**y >>> expand_power_base((2*exp(y))**x) 2**x*exp(y)**x >>> expand_power_base((2*cos(x))**y) 2**y*cos(x)**y Notice that sums are left untouched. If this is not the desired behavior, apply full ``expand()`` to the expression: >>> expand_power_base(((x+y)*z)**2) z**2*(x + y)**2 >>> (((x+y)*z)**2).expand() x**2*z**2 + 2*x*y*z**2 + y**2*z**2 >>> expand_power_base((2*y)**(1+z)) 2**(z + 1)*y**(z + 1) >>> ((2*y)**(1+z)).expand() 2*2**z*y*y**z """ return sympify(expr).expand(deep=deep, log=False, mul=False, power_exp=False, power_base=True, multinomial=False, basic=False, force=force) def expand_power_exp(expr, deep=True): """ Wrapper around expand that only uses the power_exp hint. See the expand docstring for more information. Examples ======== >>> from sympy import expand_power_exp >>> from sympy.abc import x, y >>> expand_power_exp(x**(y + 2)) x**2*x**y """ return sympify(expr).expand(deep=deep, complex=False, basic=False, log=False, mul=False, power_exp=True, power_base=False, multinomial=False) def count_ops(expr, visual=False): """ Return a representation (integer or expression) of the operations in expr. If ``visual`` is ``False`` (default) then the sum of the coefficients of the visual expression will be returned. If ``visual`` is ``True`` then the number of each type of operation is shown with the core class types (or their virtual equivalent) multiplied by the number of times they occur. If expr is an iterable, the sum of the op counts of the items will be returned. Examples ======== >>> from sympy.abc import a, b, x, y >>> from sympy import sin, count_ops Although there isn't a SUB object, minus signs are interpreted as either negations or subtractions: >>> (x - y).count_ops(visual=True) SUB >>> (-x).count_ops(visual=True) NEG Here, there are two Adds and a Pow: >>> (1 + a + b**2).count_ops(visual=True) 2*ADD + POW In the following, an Add, Mul, Pow and two functions: >>> (sin(x)*x + sin(x)**2).count_ops(visual=True) ADD + MUL + POW + 2*SIN for a total of 5: >>> (sin(x)*x + sin(x)**2).count_ops(visual=False) 5 Note that "what you type" is not always what you get. The expression 1/x/y is translated by sympy into 1/(x*y) so it gives a DIV and MUL rather than two DIVs: >>> (1/x/y).count_ops(visual=True) DIV + MUL The visual option can be used to demonstrate the difference in operations for expressions in different forms. Here, the Horner representation is compared with the expanded form of a polynomial: >>> eq=x*(1 + x*(2 + x*(3 + x))) >>> count_ops(eq.expand(), visual=True) - count_ops(eq, visual=True) -MUL + 3*POW The count_ops function also handles iterables: >>> count_ops([x, sin(x), None, True, x + 2], visual=False) 2 >>> count_ops([x, sin(x), None, True, x + 2], visual=True) ADD + SIN >>> count_ops({x: sin(x), x + 2: y + 1}, visual=True) 2*ADD + SIN """ from sympy import Integral, Symbol from sympy.core.relational import Relational from sympy.simplify.radsimp import fraction from sympy.logic.boolalg import BooleanFunction from sympy.utilities.misc import func_name expr = sympify(expr) if isinstance(expr, Expr) and not expr.is_Relational: ops = [] args = [expr] NEG = Symbol('NEG') DIV = Symbol('DIV') SUB = Symbol('SUB') ADD = Symbol('ADD') while args: a = args.pop() if a.is_Rational: #-1/3 = NEG + DIV if a is not S.One: if a.p < 0: ops.append(NEG) if a.q != 1: ops.append(DIV) continue elif a.is_Mul or a.is_MatMul: if _coeff_isneg(a): ops.append(NEG) if a.args[0] is S.NegativeOne: a = a.as_two_terms()[1] else: a = -a n, d = fraction(a) if n.is_Integer: ops.append(DIV) if n < 0: ops.append(NEG) args.append(d) continue # won't be -Mul but could be Add elif d is not S.One: if not d.is_Integer: args.append(d) ops.append(DIV) args.append(n) continue # could be -Mul elif a.is_Add or a.is_MatAdd: aargs = list(a.args) negs = 0 for i, ai in enumerate(aargs): if _coeff_isneg(ai): negs += 1 args.append(-ai) if i > 0: ops.append(SUB) else: args.append(ai) if i > 0: ops.append(ADD) if negs == len(aargs): # -x - y = NEG + SUB ops.append(NEG) elif _coeff_isneg(aargs[0]): # -x + y = SUB, but already recorded ADD ops.append(SUB - ADD) continue if a.is_Pow and a.exp is S.NegativeOne: ops.append(DIV) args.append(a.base) # won't be -Mul but could be Add continue if (a.is_Mul or a.is_Pow or a.is_Function or isinstance(a, Derivative) or isinstance(a, Integral)): o = Symbol(a.func.__name__.upper()) # count the args if (a.is_Mul or isinstance(a, LatticeOp)): ops.append(o*(len(a.args) - 1)) else: ops.append(o) if not a.is_Symbol: args.extend(a.args) elif type(expr) is dict: ops = [count_ops(k, visual=visual) + count_ops(v, visual=visual) for k, v in expr.items()] elif iterable(expr): ops = [count_ops(i, visual=visual) for i in expr] elif isinstance(expr, (Relational, BooleanFunction)): ops = [] for arg in expr.args: ops.append(count_ops(arg, visual=True)) o = Symbol(func_name(expr, short=True).upper()) ops.append(o) elif not isinstance(expr, Basic): ops = [] else: # it's Basic not isinstance(expr, Expr): if not isinstance(expr, Basic): raise TypeError("Invalid type of expr") else: ops = [] args = [expr] while args: a = args.pop() if a.args: o = Symbol(a.func.__name__.upper()) if a.is_Boolean: ops.append(o*(len(a.args)-1)) else: ops.append(o) args.extend(a.args) if not ops: if visual: return S.Zero return 0 ops = Add(*ops) if visual: return ops if ops.is_Number: return int(ops) return sum(int((a.args or [1])[0]) for a in Add.make_args(ops)) def nfloat(expr, n=15, exponent=False): """Make all Rationals in expr Floats except those in exponents (unless the exponents flag is set to True). Examples ======== >>> from sympy.core.function import nfloat >>> from sympy.abc import x, y >>> from sympy import cos, pi, sqrt >>> nfloat(x**4 + x/2 + cos(pi/3) + 1 + sqrt(y)) x**4 + 0.5*x + sqrt(y) + 1.5 >>> nfloat(x**4 + sqrt(y), exponent=True) x**4.0 + y**0.5 """ from sympy.core.power import Pow from sympy.polys.rootoftools import RootOf if iterable(expr, exclude=string_types): if isinstance(expr, (dict, Dict)): return type(expr)([(k, nfloat(v, n, exponent)) for k, v in list(expr.items())]) return type(expr)([nfloat(a, n, exponent) for a in expr]) rv = sympify(expr) if rv.is_Number: return Float(rv, n) elif rv.is_number: # evalf doesn't always set the precision rv = rv.n(n) if rv.is_Number: rv = Float(rv.n(n), n) else: pass # pure_complex(rv) is likely True return rv # watch out for RootOf instances that don't like to have # their exponents replaced with Dummies and also sometimes have # problems with evaluating at low precision (issue 6393) rv = rv.xreplace({ro: ro.n(n) for ro in rv.atoms(RootOf)}) if not exponent: reps = [(p, Pow(p.base, Dummy())) for p in rv.atoms(Pow)] rv = rv.xreplace(dict(reps)) rv = rv.n(n) if not exponent: rv = rv.xreplace({d.exp: p.exp for p, d in reps}) else: # Pow._eval_evalf special cases Integer exponents so if # exponent is suppose to be handled we have to do so here rv = rv.xreplace(Transform( lambda x: Pow(x.base, Float(x.exp, n)), lambda x: x.is_Pow and x.exp.is_Integer)) return rv.xreplace(Transform( lambda x: x.func(*nfloat(x.args, n, exponent)), lambda x: isinstance(x, Function))) from sympy.core.symbol import Dummy, Symbol

759834573c11db3c55ec09e2d908ad08e484b9aec3605ce3696e13b1b1f46231

from __future__ import print_function, division from .sympify import sympify, _sympify, SympifyError from .basic import Basic, Atom from .singleton import S from .evalf import EvalfMixin, pure_complex from .decorators import _sympifyit, call_highest_priority from .cache import cacheit from .compatibility import reduce, as_int, default_sort_key, range, Iterable from sympy.utilities.misc import func_name from mpmath.libmp import mpf_log, prec_to_dps from collections import defaultdict class Expr(Basic, EvalfMixin): """ Base class for algebraic expressions. Everything that requires arithmetic operations to be defined should subclass this class, instead of Basic (which should be used only for argument storage and expression manipulation, i.e. pattern matching, substitutions, etc). See Also ======== sympy.core.basic.Basic """ __slots__ = [] is_scalar = True # self derivative is 1 @property def _diff_wrt(self): """Return True if one can differentiate with respect to this object, else False. Subclasses such as Symbol, Function and Derivative return True to enable derivatives wrt them. The implementation in Derivative separates the Symbol and non-Symbol (_diff_wrt=True) variables and temporarily converts the non-Symbols into Symbols when performing the differentiation. By default, any object deriving from Expr will behave like a scalar with self.diff(self) == 1. If this is not desired then the object must also set `is_scalar = False` or else define an _eval_derivative routine. Note, see the docstring of Derivative for how this should work mathematically. In particular, note that expr.subs(yourclass, Symbol) should be well-defined on a structural level, or this will lead to inconsistent results. Examples ======== >>> from sympy import Expr >>> e = Expr() >>> e._diff_wrt False >>> class MyScalar(Expr): ... _diff_wrt = True ... >>> MyScalar().diff(MyScalar()) 1 >>> class MySymbol(Expr): ... _diff_wrt = True ... is_scalar = False ... >>> MySymbol().diff(MySymbol()) Derivative(MySymbol(), MySymbol()) """ return False @cacheit def sort_key(self, order=None): coeff, expr = self.as_coeff_Mul() if expr.is_Pow: expr, exp = expr.args else: expr, exp = expr, S.One if expr.is_Dummy: args = (expr.sort_key(),) elif expr.is_Atom: args = (str(expr),) else: if expr.is_Add: args = expr.as_ordered_terms(order=order) elif expr.is_Mul: args = expr.as_ordered_factors(order=order) else: args = expr.args args = tuple( [ default_sort_key(arg, order=order) for arg in args ]) args = (len(args), tuple(args)) exp = exp.sort_key(order=order) return expr.class_key(), args, exp, coeff # *************** # * Arithmetics * # *************** # Expr and its sublcasses use _op_priority to determine which object # passed to a binary special method (__mul__, etc.) will handle the # operation. In general, the 'call_highest_priority' decorator will choose # the object with the highest _op_priority to handle the call. # Custom subclasses that want to define their own binary special methods # should set an _op_priority value that is higher than the default. # # **NOTE**: # This is a temporary fix, and will eventually be replaced with # something better and more powerful. See issue 5510. _op_priority = 10.0 def __pos__(self): return self def __neg__(self): return Mul(S.NegativeOne, self) def __abs__(self): from sympy import Abs return Abs(self) @_sympifyit('other', NotImplemented) @call_highest_priority('__radd__') def __add__(self, other): return Add(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__add__') def __radd__(self, other): return Add(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rsub__') def __sub__(self, other): return Add(self, -other) @_sympifyit('other', NotImplemented) @call_highest_priority('__sub__') def __rsub__(self, other): return Add(other, -self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rmul__') def __mul__(self, other): return Mul(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__mul__') def __rmul__(self, other): return Mul(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rpow__') def _pow(self, other): return Pow(self, other) def __pow__(self, other, mod=None): if mod is None: return self._pow(other) try: _self, other, mod = as_int(self), as_int(other), as_int(mod) if other >= 0: return pow(_self, other, mod) else: from sympy.core.numbers import mod_inverse return mod_inverse(pow(_self, -other, mod), mod) except ValueError: power = self._pow(other) try: return power%mod except TypeError: return NotImplemented @_sympifyit('other', NotImplemented) @call_highest_priority('__pow__') def __rpow__(self, other): return Pow(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rdiv__') def __div__(self, other): return Mul(self, Pow(other, S.NegativeOne)) @_sympifyit('other', NotImplemented) @call_highest_priority('__div__') def __rdiv__(self, other): return Mul(other, Pow(self, S.NegativeOne)) __truediv__ = __div__ __rtruediv__ = __rdiv__ @_sympifyit('other', NotImplemented) @call_highest_priority('__rmod__') def __mod__(self, other): return Mod(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__mod__') def __rmod__(self, other): return Mod(other, self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rfloordiv__') def __floordiv__(self, other): from sympy.functions.elementary.integers import floor return floor(self / other) @_sympifyit('other', NotImplemented) @call_highest_priority('__floordiv__') def __rfloordiv__(self, other): from sympy.functions.elementary.integers import floor return floor(other / self) @_sympifyit('other', NotImplemented) @call_highest_priority('__rdivmod__') def __divmod__(self, other): from sympy.functions.elementary.integers import floor return floor(self / other), Mod(self, other) @_sympifyit('other', NotImplemented) @call_highest_priority('__divmod__') def __rdivmod__(self, other): from sympy.functions.elementary.integers import floor return floor(other / self), Mod(other, self) def __int__(self): # Although we only need to round to the units position, we'll # get one more digit so the extra testing below can be avoided # unless the rounded value rounded to an integer, e.g. if an # expression were equal to 1.9 and we rounded to the unit position # we would get a 2 and would not know if this rounded up or not # without doing a test (as done below). But if we keep an extra # digit we know that 1.9 is not the same as 1 and there is no # need for further testing: our int value is correct. If the value # were 1.99, however, this would round to 2.0 and our int value is # off by one. So...if our round value is the same as the int value # (regardless of how much extra work we do to calculate extra decimal # places) we need to test whether we are off by one. from sympy import Dummy if not self.is_number: raise TypeError("can't convert symbols to int") r = self.round(2) if not r.is_Number: raise TypeError("can't convert complex to int") if r in (S.NaN, S.Infinity, S.NegativeInfinity): raise TypeError("can't convert %s to int" % r) i = int(r) if not i: return 0 # off-by-one check if i == r and not (self - i).equals(0): isign = 1 if i > 0 else -1 x = Dummy() # in the following (self - i).evalf(2) will not always work while # (self - r).evalf(2) and the use of subs does; if the test that # was added when this comment was added passes, it might be safe # to simply use sign to compute this rather than doing this by hand: diff_sign = 1 if (self - x).evalf(2, subs={x: i}) > 0 else -1 if diff_sign != isign: i -= isign return i __long__ = __int__ def __float__(self): # Don't bother testing if it's a number; if it's not this is going # to fail, and if it is we still need to check that it evalf'ed to # a number. result = self.evalf() if result.is_Number: return float(result) if result.is_number and result.as_real_imag()[1]: raise TypeError("can't convert complex to float") raise TypeError("can't convert expression to float") def __complex__(self): result = self.evalf() re, im = result.as_real_imag() return complex(float(re), float(im)) def __ge__(self, other): from sympy import GreaterThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 >= 0) if self.is_real or other.is_real: dif = self - other if dif.is_nonnegative is not None and \ dif.is_nonnegative is not dif.is_negative: return sympify(dif.is_nonnegative) return GreaterThan(self, other, evaluate=False) def __le__(self, other): from sympy import LessThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 <= 0) if self.is_real or other.is_real: dif = self - other if dif.is_nonpositive is not None and \ dif.is_nonpositive is not dif.is_positive: return sympify(dif.is_nonpositive) return LessThan(self, other, evaluate=False) def __gt__(self, other): from sympy import StrictGreaterThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 > 0) if self.is_real or other.is_real: dif = self - other if dif.is_positive is not None and \ dif.is_positive is not dif.is_nonpositive: return sympify(dif.is_positive) return StrictGreaterThan(self, other, evaluate=False) def __lt__(self, other): from sympy import StrictLessThan try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) for me in (self, other): if me.is_complex and me.is_real is False: raise TypeError("Invalid comparison of complex %s" % me) if me is S.NaN: raise TypeError("Invalid NaN comparison") n2 = _n2(self, other) if n2 is not None: return _sympify(n2 < 0) if self.is_real or other.is_real: dif = self - other if dif.is_negative is not None and \ dif.is_negative is not dif.is_nonnegative: return sympify(dif.is_negative) return StrictLessThan(self, other, evaluate=False) def __trunc__(self): if not self.is_number: raise TypeError("can't truncate symbols and expressions") else: return Integer(self) @staticmethod def _from_mpmath(x, prec): from sympy import Float if hasattr(x, "_mpf_"): return Float._new(x._mpf_, prec) elif hasattr(x, "_mpc_"): re, im = x._mpc_ re = Float._new(re, prec) im = Float._new(im, prec)*S.ImaginaryUnit return re + im else: raise TypeError("expected mpmath number (mpf or mpc)") @property def is_number(self): """Returns True if ``self`` has no free symbols and no undefined functions (AppliedUndef, to be precise). It will be faster than ``if not self.free_symbols``, however, since ``is_number`` will fail as soon as it hits a free symbol or undefined function. Examples ======== >>> from sympy import log, Integral, cos, sin, pi >>> from sympy.core.function import Function >>> from sympy.abc import x >>> f = Function('f') >>> x.is_number False >>> f(1).is_number False >>> (2*x).is_number False >>> (2 + Integral(2, x)).is_number False >>> (2 + Integral(2, (x, 1, 2))).is_number True Not all numbers are Numbers in the SymPy sense: >>> pi.is_number, pi.is_Number (True, False) If something is a number it should evaluate to a number with real and imaginary parts that are Numbers; the result may not be comparable, however, since the real and/or imaginary part of the result may not have precision. >>> cos(1).is_number and cos(1).is_comparable True >>> z = cos(1)**2 + sin(1)**2 - 1 >>> z.is_number True >>> z.is_comparable False See Also ======== sympy.core.basic.is_comparable """ return all(obj.is_number for obj in self.args) def _random(self, n=None, re_min=-1, im_min=-1, re_max=1, im_max=1): """Return self evaluated, if possible, replacing free symbols with random complex values, if necessary. The random complex value for each free symbol is generated by the random_complex_number routine giving real and imaginary parts in the range given by the re_min, re_max, im_min, and im_max values. The returned value is evaluated to a precision of n (if given) else the maximum of 15 and the precision needed to get more than 1 digit of precision. If the expression could not be evaluated to a number, or could not be evaluated to more than 1 digit of precision, then None is returned. Examples ======== >>> from sympy import sqrt >>> from sympy.abc import x, y >>> x._random() # doctest: +SKIP 0.0392918155679172 + 0.916050214307199*I >>> x._random(2) # doctest: +SKIP -0.77 - 0.87*I >>> (x + y/2)._random(2) # doctest: +SKIP -0.57 + 0.16*I >>> sqrt(2)._random(2) 1.4 See Also ======== sympy.utilities.randtest.random_complex_number """ free = self.free_symbols prec = 1 if free: from sympy.utilities.randtest import random_complex_number a, c, b, d = re_min, re_max, im_min, im_max reps = dict(list(zip(free, [random_complex_number(a, b, c, d, rational=True) for zi in free]))) try: nmag = abs(self.evalf(2, subs=reps)) except (ValueError, TypeError): # if an out of range value resulted in evalf problems # then return None -- XXX is there a way to know how to # select a good random number for a given expression? # e.g. when calculating n! negative values for n should not # be used return None else: reps = {} nmag = abs(self.evalf(2)) if not hasattr(nmag, '_prec'): # e.g. exp_polar(2*I*pi) doesn't evaluate but is_number is True return None if nmag._prec == 1: # increase the precision up to the default maximum # precision to see if we can get any significance from mpmath.libmp.libintmath import giant_steps from sympy.core.evalf import DEFAULT_MAXPREC as target # evaluate for prec in giant_steps(2, target): nmag = abs(self.evalf(prec, subs=reps)) if nmag._prec != 1: break if nmag._prec != 1: if n is None: n = max(prec, 15) return self.evalf(n, subs=reps) # never got any significance return None def is_constant(self, *wrt, **flags): """Return True if self is constant, False if not, or None if the constancy could not be determined conclusively. If an expression has no free symbols then it is a constant. If there are free symbols it is possible that the expression is a constant, perhaps (but not necessarily) zero. To test such expressions, two strategies are tried: 1) numerical evaluation at two random points. If two such evaluations give two different values and the values have a precision greater than 1 then self is not constant. If the evaluations agree or could not be obtained with any precision, no decision is made. The numerical testing is done only if ``wrt`` is different than the free symbols. 2) differentiation with respect to variables in 'wrt' (or all free symbols if omitted) to see if the expression is constant or not. This will not always lead to an expression that is zero even though an expression is constant (see added test in test_expr.py). If all derivatives are zero then self is constant with respect to the given symbols. If neither evaluation nor differentiation can prove the expression is constant, None is returned unless two numerical values happened to be the same and the flag ``failing_number`` is True -- in that case the numerical value will be returned. If flag simplify=False is passed, self will not be simplified; the default is True since self should be simplified before testing. Examples ======== >>> from sympy import cos, sin, Sum, S, pi >>> from sympy.abc import a, n, x, y >>> x.is_constant() False >>> S(2).is_constant() True >>> Sum(x, (x, 1, 10)).is_constant() True >>> Sum(x, (x, 1, n)).is_constant() False >>> Sum(x, (x, 1, n)).is_constant(y) True >>> Sum(x, (x, 1, n)).is_constant(n) False >>> Sum(x, (x, 1, n)).is_constant(x) True >>> eq = a*cos(x)**2 + a*sin(x)**2 - a >>> eq.is_constant() True >>> eq.subs({x: pi, a: 2}) == eq.subs({x: pi, a: 3}) == 0 True >>> (0**x).is_constant() False >>> x.is_constant() False >>> (x**x).is_constant() False >>> one = cos(x)**2 + sin(x)**2 >>> one.is_constant() True >>> ((one - 1)**(x + 1)).is_constant() in (True, False) # could be 0 or 1 True """ simplify = flags.get('simplify', True) if self.is_number: return True free = self.free_symbols if not free: return True # assume f(1) is some constant # if we are only interested in some symbols and they are not in the # free symbols then this expression is constant wrt those symbols wrt = set(wrt) if wrt and not wrt & free: return True wrt = wrt or free # simplify unless this has already been done expr = self if simplify: expr = expr.simplify() # is_zero should be a quick assumptions check; it can be wrong for # numbers (see test_is_not_constant test), giving False when it # shouldn't, but hopefully it will never give True unless it is sure. if expr.is_zero: return True # try numerical evaluation to see if we get two different values failing_number = None if wrt == free: # try 0 (for a) and 1 (for b) try: a = expr.subs(list(zip(free, [0]*len(free))), simultaneous=True) if a is S.NaN: # evaluation may succeed when substitution fails a = expr._random(None, 0, 0, 0, 0) except ZeroDivisionError: a = None if a is not None and a is not S.NaN: try: b = expr.subs(list(zip(free, [1]*len(free))), simultaneous=True) if b is S.NaN: # evaluation may succeed when substitution fails b = expr._random(None, 1, 0, 1, 0) except ZeroDivisionError: b = None if b is not None and b is not S.NaN and b.equals(a) is False: return False # try random real b = expr._random(None, -1, 0, 1, 0) if b is not None and b is not S.NaN and b.equals(a) is False: return False # try random complex b = expr._random() if b is not None and b is not S.NaN: if b.equals(a) is False: return False failing_number = a if a.is_number else b # now we will test each wrt symbol (or all free symbols) to see if the # expression depends on them or not using differentiation. This is # not sufficient for all expressions, however, so we don't return # False if we get a derivative other than 0 with free symbols. for w in wrt: deriv = expr.diff(w) if simplify: deriv = deriv.simplify() if deriv != 0: if not (pure_complex(deriv, or_real=True)): if flags.get('failing_number', False): return failing_number elif deriv.free_symbols: # dead line provided _random returns None in such cases return None return False return True def equals(self, other, failing_expression=False): """Return True if self == other, False if it doesn't, or None. If failing_expression is True then the expression which did not simplify to a 0 will be returned instead of None. If ``self`` is a Number (or complex number) that is not zero, then the result is False. If ``self`` is a number and has not evaluated to zero, evalf will be used to test whether the expression evaluates to zero. If it does so and the result has significance (i.e. the precision is either -1, for a Rational result, or is greater than 1) then the evalf value will be used to return True or False. """ from sympy.simplify.simplify import nsimplify, simplify from sympy.solvers.solveset import solveset from sympy.polys.polyerrors import NotAlgebraic from sympy.polys.numberfields import minimal_polynomial other = sympify(other) if self == other: return True # they aren't the same so see if we can make the difference 0; # don't worry about doing simplification steps one at a time # because if the expression ever goes to 0 then the subsequent # simplification steps that are done will be very fast. diff = factor_terms(simplify(self - other), radical=True) if not diff: return True if not diff.has(Add, Mod): # if there is no expanding to be done after simplifying # then this can't be a zero return False constant = diff.is_constant(simplify=False, failing_number=True) if constant is False: return False if constant is None and not diff.is_number: # e.g. unless the right simplification is done, a symbolic # zero is possible (see expression of issue 6829: without # simplification constant will be None). return if constant is True: ndiff = diff._random() if ndiff: return False # sometimes we can use a simplified result to give a clue as to # what the expression should be; if the expression is *not* zero # then we should have been able to compute that and so now # we can just consider the cases where the approximation appears # to be zero -- we try to prove it via minimal_polynomial. if diff.is_number: approx = diff.nsimplify() if not approx: # try to prove via self-consistency surds = [s for s in diff.atoms(Pow) if s.args[0].is_Integer] # it seems to work better to try big ones first surds.sort(key=lambda x: -x.args[0]) for s in surds: try: # simplify is False here -- this expression has already # been identified as being hard to identify as zero; # we will handle the checking ourselves using nsimplify # to see if we are in the right ballpark or not and if so # *then* the simplification will be attempted. if s.is_Symbol: sol = list(solveset(diff, s)) else: sol = [s] if sol: if s in sol: return True if s.is_real: if any(nsimplify(si, [s]) == s and simplify(si) == s for si in sol): return True except NotImplementedError: pass # try to prove with minimal_polynomial but know when # *not* to use this or else it can take a long time. e.g. issue 8354 if True: # change True to condition that assures non-hang try: mp = minimal_polynomial(diff) if mp.is_Symbol: return True return False except (NotAlgebraic, NotImplementedError): pass # diff has not simplified to zero; constant is either None, True # or the number with significance (prec != 1) that was randomly # calculated twice as the same value. if constant not in (True, None) and constant != 0: return False if failing_expression: return diff return None def _eval_is_positive(self): from sympy.polys.numberfields import minimal_polynomial from sympy.polys.polyerrors import NotAlgebraic if self.is_number: if self.is_real is False: return False # check to see that we can get a value try: n2 = self._eval_evalf(2) # XXX: This shouldn't be caught here # Catches ValueError: hypsum() failed to converge to the requested # 34 bits of accuracy except ValueError: return None if n2 is None: return None if getattr(n2, '_prec', 1) == 1: # no significance return None if n2 == S.NaN: return None n, i = self.evalf(2).as_real_imag() if not i.is_Number or not n.is_Number: return False if n._prec != 1 and i._prec != 1: return bool(not i and n > 0) elif n._prec == 1 and (not i or i._prec == 1) and \ self.is_algebraic and not self.has(Function): try: if minimal_polynomial(self).is_Symbol: return False except (NotAlgebraic, NotImplementedError): pass def _eval_is_negative(self): from sympy.polys.numberfields import minimal_polynomial from sympy.polys.polyerrors import NotAlgebraic if self.is_number: if self.is_real is False: return False # check to see that we can get a value try: n2 = self._eval_evalf(2) # XXX: This shouldn't be caught here # Catches ValueError: hypsum() failed to converge to the requested # 34 bits of accuracy except ValueError: return None if n2 is None: return None if getattr(n2, '_prec', 1) == 1: # no significance return None if n2 == S.NaN: return None n, i = self.evalf(2).as_real_imag() if not i.is_Number or not n.is_Number: return False if n._prec != 1 and i._prec != 1: return bool(not i and n < 0) elif n._prec == 1 and (not i or i._prec == 1) and \ self.is_algebraic and not self.has(Function): try: if minimal_polynomial(self).is_Symbol: return False except (NotAlgebraic, NotImplementedError): pass def _eval_interval(self, x, a, b): """ Returns evaluation over an interval. For most functions this is: self.subs(x, b) - self.subs(x, a), possibly using limit() if NaN is returned from subs, or if singularities are found between a and b. If b or a is None, it only evaluates -self.subs(x, a) or self.subs(b, x), respectively. """ from sympy.series import limit, Limit from sympy.solvers.solveset import solveset from sympy.sets.sets import Interval from sympy.functions.elementary.exponential import log from sympy.calculus.util import AccumBounds if (a is None and b is None): raise ValueError('Both interval ends cannot be None.') if a == b: return 0 if a is None: A = 0 else: A = self.subs(x, a) if A.has(S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity, AccumBounds): if (a < b) != False: A = limit(self, x, a,"+") else: A = limit(self, x, a,"-") if A is S.NaN: return A if isinstance(A, Limit): raise NotImplementedError("Could not compute limit") if b is None: B = 0 else: B = self.subs(x, b) if B.has(S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity, AccumBounds): if (a < b) != False: B = limit(self, x, b,"-") else: B = limit(self, x, b,"+") if isinstance(B, Limit): raise NotImplementedError("Could not compute limit") if (a and b) is None: return B - A value = B - A if a.is_comparable and b.is_comparable: if a < b: domain = Interval(a, b) else: domain = Interval(b, a) # check the singularities of self within the interval # if singularities is a ConditionSet (not iterable), catch the exception and pass singularities = solveset(self.cancel().as_numer_denom()[1], x, domain=domain) for logterm in self.atoms(log): singularities = singularities | solveset(logterm.args[0], x, domain=domain) try: for s in singularities: if value is S.NaN: # no need to keep adding, it will stay NaN break if not s.is_comparable: continue if (a < s) == (s < b) == True: value += -limit(self, x, s, "+") + limit(self, x, s, "-") elif (b < s) == (s < a) == True: value += limit(self, x, s, "+") - limit(self, x, s, "-") except TypeError: pass return value def _eval_power(self, other): # subclass to compute self**other for cases when # other is not NaN, 0, or 1 return None def _eval_conjugate(self): if self.is_real: return self elif self.is_imaginary: return -self def conjugate(self): from sympy.functions.elementary.complexes import conjugate as c return c(self) def _eval_transpose(self): from sympy.functions.elementary.complexes import conjugate if self.is_complex: return self elif self.is_hermitian: return conjugate(self) elif self.is_antihermitian: return -conjugate(self) def transpose(self): from sympy.functions.elementary.complexes import transpose return transpose(self) def _eval_adjoint(self): from sympy.functions.elementary.complexes import conjugate, transpose if self.is_hermitian: return self elif self.is_antihermitian: return -self obj = self._eval_conjugate() if obj is not None: return transpose(obj) obj = self._eval_transpose() if obj is not None: return conjugate(obj) def adjoint(self): from sympy.functions.elementary.complexes import adjoint return adjoint(self) @classmethod def _parse_order(cls, order): """Parse and configure the ordering of terms. """ from sympy.polys.orderings import monomial_key startswith = getattr(order, "startswith", None) if startswith is None: reverse = False else: reverse = startswith('rev-') if reverse: order = order[4:] monom_key = monomial_key(order) def neg(monom): result = [] for m in monom: if isinstance(m, tuple): result.append(neg(m)) else: result.append(-m) return tuple(result) def key(term): _, ((re, im), monom, ncpart) = term monom = neg(monom_key(monom)) ncpart = tuple([e.sort_key(order=order) for e in ncpart]) coeff = ((bool(im), im), (re, im)) return monom, ncpart, coeff return key, reverse def as_ordered_factors(self, order=None): """Return list of ordered factors (if Mul) else [self].""" return [self] def as_ordered_terms(self, order=None, data=False): """ Transform an expression to an ordered list of terms. Examples ======== >>> from sympy import sin, cos >>> from sympy.abc import x >>> (sin(x)**2*cos(x) + sin(x)**2 + 1).as_ordered_terms() [sin(x)**2*cos(x), sin(x)**2, 1] """ from .numbers import Number, NumberSymbol if order is None and self.is_Add: # Spot the special case of Add(Number, Mul(Number, expr)) with the # first number positive and thhe second number nagative key = lambda x:not isinstance(x, (Number, NumberSymbol)) add_args = sorted(Add.make_args(self), key=key) if (len(add_args) == 2 and isinstance(add_args[0], (Number, NumberSymbol)) and isinstance(add_args[1], Mul)): mul_args = sorted(Mul.make_args(add_args[1]), key=key) if (len(mul_args) == 2 and isinstance(mul_args[0], Number) and add_args[0].is_positive and mul_args[0].is_negative): return add_args key, reverse = self._parse_order(order) terms, gens = self.as_terms() if not any(term.is_Order for term, _ in terms): ordered = sorted(terms, key=key, reverse=reverse) else: _terms, _order = [], [] for term, repr in terms: if not term.is_Order: _terms.append((term, repr)) else: _order.append((term, repr)) ordered = sorted(_terms, key=key, reverse=True) \ + sorted(_order, key=key, reverse=True) if data: return ordered, gens else: return [term for term, _ in ordered] def as_terms(self): """Transform an expression to a list of terms. """ from .add import Add from .mul import Mul from .exprtools import decompose_power gens, terms = set([]), [] for term in Add.make_args(self): coeff, _term = term.as_coeff_Mul() coeff = complex(coeff) cpart, ncpart = {}, [] if _term is not S.One: for factor in Mul.make_args(_term): if factor.is_number: try: coeff *= complex(factor) except (TypeError, ValueError): pass else: continue if factor.is_commutative: base, exp = decompose_power(factor) cpart[base] = exp gens.add(base) else: ncpart.append(factor) coeff = coeff.real, coeff.imag ncpart = tuple(ncpart) terms.append((term, (coeff, cpart, ncpart))) gens = sorted(gens, key=default_sort_key) k, indices = len(gens), {} for i, g in enumerate(gens): indices[g] = i result = [] for term, (coeff, cpart, ncpart) in terms: monom = [0]*k for base, exp in cpart.items(): monom[indices[base]] = exp result.append((term, (coeff, tuple(monom), ncpart))) return result, gens def removeO(self): """Removes the additive O(..) symbol if there is one""" return self def getO(self): """Returns the additive O(..) symbol if there is one, else None.""" return None def getn(self): """ Returns the order of the expression. The order is determined either from the O(...) term. If there is no O(...) term, it returns None. Examples ======== >>> from sympy import O >>> from sympy.abc import x >>> (1 + x + O(x**2)).getn() 2 >>> (1 + x).getn() """ from sympy import Dummy, Symbol o = self.getO() if o is None: return None elif o.is_Order: o = o.expr if o is S.One: return S.Zero if o.is_Symbol: return S.One if o.is_Pow: return o.args[1] if o.is_Mul: # x**n*log(x)**n or x**n/log(x)**n for oi in o.args: if oi.is_Symbol: return S.One if oi.is_Pow: syms = oi.atoms(Symbol) if len(syms) == 1: x = syms.pop() oi = oi.subs(x, Dummy('x', positive=True)) if oi.base.is_Symbol and oi.exp.is_Rational: return abs(oi.exp) raise NotImplementedError('not sure of order of %s' % o) def count_ops(self, visual=None): """wrapper for count_ops that returns the operation count.""" from .function import count_ops return count_ops(self, visual) def args_cnc(self, cset=False, warn=True, split_1=True): """Return [commutative factors, non-commutative factors] of self. self is treated as a Mul and the ordering of the factors is maintained. If ``cset`` is True the commutative factors will be returned in a set. If there were repeated factors (as may happen with an unevaluated Mul) then an error will be raised unless it is explicitly suppressed by setting ``warn`` to False. Note: -1 is always separated from a Number unless split_1 is False. >>> from sympy import symbols, oo >>> A, B = symbols('A B', commutative=0) >>> x, y = symbols('x y') >>> (-2*x*y).args_cnc() [[-1, 2, x, y], []] >>> (-2.5*x).args_cnc() [[-1, 2.5, x], []] >>> (-2*x*A*B*y).args_cnc() [[-1, 2, x, y], [A, B]] >>> (-2*x*A*B*y).args_cnc(split_1=False) [[-2, x, y], [A, B]] >>> (-2*x*y).args_cnc(cset=True) [{-1, 2, x, y}, []] The arg is always treated as a Mul: >>> (-2 + x + A).args_cnc() [[], [x - 2 + A]] >>> (-oo).args_cnc() # -oo is a singleton [[-1, oo], []] """ if self.is_Mul: args = list(self.args) else: args = [self] for i, mi in enumerate(args): if not mi.is_commutative: c = args[:i] nc = args[i:] break else: c = args nc = [] if c and split_1 and ( c[0].is_Number and c[0].is_negative and c[0] is not S.NegativeOne): c[:1] = [S.NegativeOne, -c[0]] if cset: clen = len(c) c = set(c) if clen and warn and len(c) != clen: raise ValueError('repeated commutative arguments: %s' % [ci for ci in c if list(self.args).count(ci) > 1]) return [c, nc] def coeff(self, x, n=1, right=False): """ Returns the coefficient from the term(s) containing ``x**n``. If ``n`` is zero then all terms independent of ``x`` will be returned. When ``x`` is noncommutative, the coefficient to the left (default) or right of ``x`` can be returned. The keyword 'right' is ignored when ``x`` is commutative. See Also ======== as_coefficient: separate the expression into a coefficient and factor as_coeff_Add: separate the additive constant from an expression as_coeff_Mul: separate the multiplicative constant from an expression as_independent: separate x-dependent terms/factors from others sympy.polys.polytools.coeff_monomial: efficiently find the single coefficient of a monomial in Poly sympy.polys.polytools.nth: like coeff_monomial but powers of monomial terms are used Examples ======== >>> from sympy import symbols >>> from sympy.abc import x, y, z You can select terms that have an explicit negative in front of them: >>> (-x + 2*y).coeff(-1) x >>> (x - 2*y).coeff(-1) 2*y You can select terms with no Rational coefficient: >>> (x + 2*y).coeff(1) x >>> (3 + 2*x + 4*x**2).coeff(1) 0 You can select terms independent of x by making n=0; in this case expr.as_independent(x)[0] is returned (and 0 will be returned instead of None): >>> (3 + 2*x + 4*x**2).coeff(x, 0) 3 >>> eq = ((x + 1)**3).expand() + 1 >>> eq x**3 + 3*x**2 + 3*x + 2 >>> [eq.coeff(x, i) for i in reversed(range(4))] [1, 3, 3, 2] >>> eq -= 2 >>> [eq.coeff(x, i) for i in reversed(range(4))] [1, 3, 3, 0] You can select terms that have a numerical term in front of them: >>> (-x - 2*y).coeff(2) -y >>> from sympy import sqrt >>> (x + sqrt(2)*x).coeff(sqrt(2)) x The matching is exact: >>> (3 + 2*x + 4*x**2).coeff(x) 2 >>> (3 + 2*x + 4*x**2).coeff(x**2) 4 >>> (3 + 2*x + 4*x**2).coeff(x**3) 0 >>> (z*(x + y)**2).coeff((x + y)**2) z >>> (z*(x + y)**2).coeff(x + y) 0 In addition, no factoring is done, so 1 + z*(1 + y) is not obtained from the following: >>> (x + z*(x + x*y)).coeff(x) 1 If such factoring is desired, factor_terms can be used first: >>> from sympy import factor_terms >>> factor_terms(x + z*(x + x*y)).coeff(x) z*(y + 1) + 1 >>> n, m, o = symbols('n m o', commutative=False) >>> n.coeff(n) 1 >>> (3*n).coeff(n) 3 >>> (n*m + m*n*m).coeff(n) # = (1 + m)*n*m 1 + m >>> (n*m + m*n*m).coeff(n, right=True) # = (1 + m)*n*m m If there is more than one possible coefficient 0 is returned: >>> (n*m + m*n).coeff(n) 0 If there is only one possible coefficient, it is returned: >>> (n*m + x*m*n).coeff(m*n) x >>> (n*m + x*m*n).coeff(m*n, right=1) 1 """ x = sympify(x) if not isinstance(x, Basic): return S.Zero n = as_int(n) if not x: return S.Zero if x == self: if n == 1: return S.One return S.Zero if x is S.One: co = [a for a in Add.make_args(self) if a.as_coeff_Mul()[0] is S.One] if not co: return S.Zero return Add(*co) if n == 0: if x.is_Add and self.is_Add: c = self.coeff(x, right=right) if not c: return S.Zero if not right: return self - Add(*[a*x for a in Add.make_args(c)]) return self - Add(*[x*a for a in Add.make_args(c)]) return self.as_independent(x, as_Add=True)[0] # continue with the full method, looking for this power of x: x = x**n def incommon(l1, l2): if not l1 or not l2: return [] n = min(len(l1), len(l2)) for i in range(n): if l1[i] != l2[i]: return l1[:i] return l1[:] def find(l, sub, first=True): """ Find where list sub appears in list l. When ``first`` is True the first occurrence from the left is returned, else the last occurrence is returned. Return None if sub is not in l. >> l = range(5)*2 >> find(l, [2, 3]) 2 >> find(l, [2, 3], first=0) 7 >> find(l, [2, 4]) None """ if not sub or not l or len(sub) > len(l): return None n = len(sub) if not first: l.reverse() sub.reverse() for i in range(0, len(l) - n + 1): if all(l[i + j] == sub[j] for j in range(n)): break else: i = None if not first: l.reverse() sub.reverse() if i is not None and not first: i = len(l) - (i + n) return i co = [] args = Add.make_args(self) self_c = self.is_commutative x_c = x.is_commutative if self_c and not x_c: return S.Zero if self_c: xargs = x.args_cnc(cset=True, warn=False)[0] for a in args: margs = a.args_cnc(cset=True, warn=False)[0] if len(xargs) > len(margs): continue resid = margs.difference(xargs) if len(resid) + len(xargs) == len(margs): co.append(Mul(*resid)) if co == []: return S.Zero elif co: return Add(*co) elif x_c: xargs = x.args_cnc(cset=True, warn=False)[0] for a in args: margs, nc = a.args_cnc(cset=True) if len(xargs) > len(margs): continue resid = margs.difference(xargs) if len(resid) + len(xargs) == len(margs): co.append(Mul(*(list(resid) + nc))) if co == []: return S.Zero elif co: return Add(*co) else: # both nc xargs, nx = x.args_cnc(cset=True) # find the parts that pass the commutative terms for a in args: margs, nc = a.args_cnc(cset=True) if len(xargs) > len(margs): continue resid = margs.difference(xargs) if len(resid) + len(xargs) == len(margs): co.append((resid, nc)) # now check the non-comm parts if not co: return S.Zero if all(n == co[0][1] for r, n in co): ii = find(co[0][1], nx, right) if ii is not None: if not right: return Mul(Add(*[Mul(*r) for r, c in co]), Mul(*co[0][1][:ii])) else: return Mul(*co[0][1][ii + len(nx):]) beg = reduce(incommon, (n[1] for n in co)) if beg: ii = find(beg, nx, right) if ii is not None: if not right: gcdc = co[0][0] for i in range(1, len(co)): gcdc = gcdc.intersection(co[i][0]) if not gcdc: break return Mul(*(list(gcdc) + beg[:ii])) else: m = ii + len(nx) return Add(*[Mul(*(list(r) + n[m:])) for r, n in co]) end = list(reversed( reduce(incommon, (list(reversed(n[1])) for n in co)))) if end: ii = find(end, nx, right) if ii is not None: if not right: return Add(*[Mul(*(list(r) + n[:-len(end) + ii])) for r, n in co]) else: return Mul(*end[ii + len(nx):]) # look for single match hit = None for i, (r, n) in enumerate(co): ii = find(n, nx, right) if ii is not None: if not hit: hit = ii, r, n else: break else: if hit: ii, r, n = hit if not right: return Mul(*(list(r) + n[:ii])) else: return Mul(*n[ii + len(nx):]) return S.Zero def as_expr(self, *gens): """ Convert a polynomial to a SymPy expression. Examples ======== >>> from sympy import sin >>> from sympy.abc import x, y >>> f = (x**2 + x*y).as_poly(x, y) >>> f.as_expr() x**2 + x*y >>> sin(x).as_expr() sin(x) """ return self def as_coefficient(self, expr): """ Extracts symbolic coefficient at the given expression. In other words, this functions separates 'self' into the product of 'expr' and 'expr'-free coefficient. If such separation is not possible it will return None. Examples ======== >>> from sympy import E, pi, sin, I, Poly >>> from sympy.abc import x >>> E.as_coefficient(E) 1 >>> (2*E).as_coefficient(E) 2 >>> (2*sin(E)*E).as_coefficient(E) Two terms have E in them so a sum is returned. (If one were desiring the coefficient of the term exactly matching E then the constant from the returned expression could be selected. Or, for greater precision, a method of Poly can be used to indicate the desired term from which the coefficient is desired.) >>> (2*E + x*E).as_coefficient(E) x + 2 >>> _.args[0] # just want the exact match 2 >>> p = Poly(2*E + x*E); p Poly(x*E + 2*E, x, E, domain='ZZ') >>> p.coeff_monomial(E) 2 >>> p.nth(0, 1) 2 Since the following cannot be written as a product containing E as a factor, None is returned. (If the coefficient ``2*x`` is desired then the ``coeff`` method should be used.) >>> (2*E*x + x).as_coefficient(E) >>> (2*E*x + x).coeff(E) 2*x >>> (E*(x + 1) + x).as_coefficient(E) >>> (2*pi*I).as_coefficient(pi*I) 2 >>> (2*I).as_coefficient(pi*I) See Also ======== coeff: return sum of terms have a given factor as_coeff_Add: separate the additive constant from an expression as_coeff_Mul: separate the multiplicative constant from an expression as_independent: separate x-dependent terms/factors from others sympy.polys.polytools.coeff_monomial: efficiently find the single coefficient of a monomial in Poly sympy.polys.polytools.nth: like coeff_monomial but powers of monomial terms are used """ r = self.extract_multiplicatively(expr) if r and not r.has(expr): return r def as_independent(self, *deps, **hint): """ A mostly naive separation of a Mul or Add into arguments that are not are dependent on deps. To obtain as complete a separation of variables as possible, use a separation method first, e.g.: * separatevars() to change Mul, Add and Pow (including exp) into Mul * .expand(mul=True) to change Add or Mul into Add * .expand(log=True) to change log expr into an Add The only non-naive thing that is done here is to respect noncommutative ordering of variables and to always return (0, 0) for `self` of zero regardless of hints. For nonzero `self`, the returned tuple (i, d) has the following interpretation: * i will has no variable that appears in deps * d will either have terms that contain variables that are in deps, or be equal to 0 (when self is an Add) or 1 (when self is a Mul) * if self is an Add then self = i + d * if self is a Mul then self = i*d * otherwise (self, S.One) or (S.One, self) is returned. To force the expression to be treated as an Add, use the hint as_Add=True Examples ======== -- self is an Add >>> from sympy import sin, cos, exp >>> from sympy.abc import x, y, z >>> (x + x*y).as_independent(x) (0, x*y + x) >>> (x + x*y).as_independent(y) (x, x*y) >>> (2*x*sin(x) + y + x + z).as_independent(x) (y + z, 2*x*sin(x) + x) >>> (2*x*sin(x) + y + x + z).as_independent(x, y) (z, 2*x*sin(x) + x + y) -- self is a Mul >>> (x*sin(x)*cos(y)).as_independent(x) (cos(y), x*sin(x)) non-commutative terms cannot always be separated out when self is a Mul >>> from sympy import symbols >>> n1, n2, n3 = symbols('n1 n2 n3', commutative=False) >>> (n1 + n1*n2).as_independent(n2) (n1, n1*n2) >>> (n2*n1 + n1*n2).as_independent(n2) (0, n1*n2 + n2*n1) >>> (n1*n2*n3).as_independent(n1) (1, n1*n2*n3) >>> (n1*n2*n3).as_independent(n2) (n1, n2*n3) >>> ((x-n1)*(x-y)).as_independent(x) (1, (x - y)*(x - n1)) -- self is anything else: >>> (sin(x)).as_independent(x) (1, sin(x)) >>> (sin(x)).as_independent(y) (sin(x), 1) >>> exp(x+y).as_independent(x) (1, exp(x + y)) -- force self to be treated as an Add: >>> (3*x).as_independent(x, as_Add=True) (0, 3*x) -- force self to be treated as a Mul: >>> (3+x).as_independent(x, as_Add=False) (1, x + 3) >>> (-3+x).as_independent(x, as_Add=False) (1, x - 3) Note how the below differs from the above in making the constant on the dep term positive. >>> (y*(-3+x)).as_independent(x) (y, x - 3) -- use .as_independent() for true independence testing instead of .has(). The former considers only symbols in the free symbols while the latter considers all symbols >>> from sympy import Integral >>> I = Integral(x, (x, 1, 2)) >>> I.has(x) True >>> x in I.free_symbols False >>> I.as_independent(x) == (I, 1) True >>> (I + x).as_independent(x) == (I, x) True Note: when trying to get independent terms, a separation method might need to be used first. In this case, it is important to keep track of what you send to this routine so you know how to interpret the returned values >>> from sympy import separatevars, log >>> separatevars(exp(x+y)).as_independent(x) (exp(y), exp(x)) >>> (x + x*y).as_independent(y) (x, x*y) >>> separatevars(x + x*y).as_independent(y) (x, y + 1) >>> (x*(1 + y)).as_independent(y) (x, y + 1) >>> (x*(1 + y)).expand(mul=True).as_independent(y) (x, x*y) >>> a, b=symbols('a b', positive=True) >>> (log(a*b).expand(log=True)).as_independent(b) (log(a), log(b)) See Also ======== .separatevars(), .expand(log=True), Add.as_two_terms(), Mul.as_two_terms(), .as_coeff_add(), .as_coeff_mul() """ from .symbol import Symbol from .add import _unevaluated_Add from .mul import _unevaluated_Mul from sympy.utilities.iterables import sift if self.is_zero: return S.Zero, S.Zero func = self.func if hint.get('as_Add', isinstance(self, Add) ): want = Add else: want = Mul # sift out deps into symbolic and other and ignore # all symbols but those that are in the free symbols sym = set() other = [] for d in deps: if isinstance(d, Symbol): # Symbol.is_Symbol is True sym.add(d) else: other.append(d) def has(e): """return the standard has() if there are no literal symbols, else check to see that symbol-deps are in the free symbols.""" has_other = e.has(*other) if not sym: return has_other return has_other or e.has(*(e.free_symbols & sym)) if (want is not func or func is not Add and func is not Mul): if has(self): return (want.identity, self) else: return (self, want.identity) else: if func is Add: args = list(self.args) else: args, nc = self.args_cnc() d = sift(args, lambda x: has(x)) depend = d[True] indep = d[False] if func is Add: # all terms were treated as commutative return (Add(*indep), _unevaluated_Add(*depend)) else: # handle noncommutative by stopping at first dependent term for i, n in enumerate(nc): if has(n): depend.extend(nc[i:]) break indep.append(n) return Mul(*indep), ( Mul(*depend, evaluate=False) if nc else _unevaluated_Mul(*depend)) def as_real_imag(self, deep=True, **hints): """Performs complex expansion on 'self' and returns a tuple containing collected both real and imaginary parts. This method can't be confused with re() and im() functions, which does not perform complex expansion at evaluation. However it is possible to expand both re() and im() functions and get exactly the same results as with a single call to this function. >>> from sympy import symbols, I >>> x, y = symbols('x,y', real=True) >>> (x + y*I).as_real_imag() (x, y) >>> from sympy.abc import z, w >>> (z + w*I).as_real_imag() (re(z) - im(w), re(w) + im(z)) """ from sympy import im, re if hints.get('ignore') == self: return None else: return (re(self), im(self)) def as_powers_dict(self): """Return self as a dictionary of factors with each factor being treated as a power. The keys are the bases of the factors and the values, the corresponding exponents. The resulting dictionary should be used with caution if the expression is a Mul and contains non- commutative factors since the order that they appeared will be lost in the dictionary. See Also ======== as_ordered_factors: An alternative for noncommutative applications, returning an ordered list of factors. args_cnc: Similar to as_ordered_factors, but guarantees separation of commutative and noncommutative factors. """ d = defaultdict(int) d.update(dict([self.as_base_exp()])) return d def as_coefficients_dict(self): """Return a dictionary mapping terms to their Rational coefficient. Since the dictionary is a defaultdict, inquiries about terms which were not present will return a coefficient of 0. If an expression is not an Add it is considered to have a single term. Examples ======== >>> from sympy.abc import a, x >>> (3*x + a*x + 4).as_coefficients_dict() {1: 4, x: 3, a*x: 1} >>> _[a] 0 >>> (3*a*x).as_coefficients_dict() {a*x: 3} """ c, m = self.as_coeff_Mul() if not c.is_Rational: c = S.One m = self d = defaultdict(int) d.update({m: c}) return d def as_base_exp(self): # a -> b ** e return self, S.One def as_coeff_mul(self, *deps, **kwargs): """Return the tuple (c, args) where self is written as a Mul, ``m``. c should be a Rational multiplied by any factors of the Mul that are independent of deps. args should be a tuple of all other factors of m; args is empty if self is a Number or if self is independent of deps (when given). This should be used when you don't know if self is a Mul or not but you want to treat self as a Mul or if you want to process the individual arguments of the tail of self as a Mul. - if you know self is a Mul and want only the head, use self.args[0]; - if you don't want to process the arguments of the tail but need the tail then use self.as_two_terms() which gives the head and tail; - if you want to split self into an independent and dependent parts use ``self.as_independent(*deps)`` >>> from sympy import S >>> from sympy.abc import x, y >>> (S(3)).as_coeff_mul() (3, ()) >>> (3*x*y).as_coeff_mul() (3, (x, y)) >>> (3*x*y).as_coeff_mul(x) (3*y, (x,)) >>> (3*y).as_coeff_mul(x) (3*y, ()) """ if deps: if not self.has(*deps): return self, tuple() return S.One, (self,) def as_coeff_add(self, *deps): """Return the tuple (c, args) where self is written as an Add, ``a``. c should be a Rational added to any terms of the Add that are independent of deps. args should be a tuple of all other terms of ``a``; args is empty if self is a Number or if self is independent of deps (when given). This should be used when you don't know if self is an Add or not but you want to treat self as an Add or if you want to process the individual arguments of the tail of self as an Add. - if you know self is an Add and want only the head, use self.args[0]; - if you don't want to process the arguments of the tail but need the tail then use self.as_two_terms() which gives the head and tail. - if you want to split self into an independent and dependent parts use ``self.as_independent(*deps)`` >>> from sympy import S >>> from sympy.abc import x, y >>> (S(3)).as_coeff_add() (3, ()) >>> (3 + x).as_coeff_add() (3, (x,)) >>> (3 + x + y).as_coeff_add(x) (y + 3, (x,)) >>> (3 + y).as_coeff_add(x) (y + 3, ()) """ if deps: if not self.has(*deps): return self, tuple() return S.Zero, (self,) def primitive(self): """Return the positive Rational that can be extracted non-recursively from every term of self (i.e., self is treated like an Add). This is like the as_coeff_Mul() method but primitive always extracts a positive Rational (never a negative or a Float). Examples ======== >>> from sympy.abc import x >>> (3*(x + 1)**2).primitive() (3, (x + 1)**2) >>> a = (6*x + 2); a.primitive() (2, 3*x + 1) >>> b = (x/2 + 3); b.primitive() (1/2, x + 6) >>> (a*b).primitive() == (1, a*b) True """ if not self: return S.One, S.Zero c, r = self.as_coeff_Mul(rational=True) if c.is_negative: c, r = -c, -r return c, r def as_content_primitive(self, radical=False, clear=True): """This method should recursively remove a Rational from all arguments and return that (content) and the new self (primitive). The content should always be positive and ``Mul(*foo.as_content_primitive()) == foo``. The primitive need not be in canonical form and should try to preserve the underlying structure if possible (i.e. expand_mul should not be applied to self). Examples ======== >>> from sympy import sqrt >>> from sympy.abc import x, y, z >>> eq = 2 + 2*x + 2*y*(3 + 3*y) The as_content_primitive function is recursive and retains structure: >>> eq.as_content_primitive() (2, x + 3*y*(y + 1) + 1) Integer powers will have Rationals extracted from the base: >>> ((2 + 6*x)**2).as_content_primitive() (4, (3*x + 1)**2) >>> ((2 + 6*x)**(2*y)).as_content_primitive() (1, (2*(3*x + 1))**(2*y)) Terms may end up joining once their as_content_primitives are added: >>> ((5*(x*(1 + y)) + 2*x*(3 + 3*y))).as_content_primitive() (11, x*(y + 1)) >>> ((3*(x*(1 + y)) + 2*x*(3 + 3*y))).as_content_primitive() (9, x*(y + 1)) >>> ((3*(z*(1 + y)) + 2.0*x*(3 + 3*y))).as_content_primitive() (1, 6.0*x*(y + 1) + 3*z*(y + 1)) >>> ((5*(x*(1 + y)) + 2*x*(3 + 3*y))**2).as_content_primitive() (121, x**2*(y + 1)**2) >>> ((5*(x*(1 + y)) + 2.0*x*(3 + 3*y))**2).as_content_primitive() (1, 121.0*x**2*(y + 1)**2) Radical content can also be factored out of the primitive: >>> (2*sqrt(2) + 4*sqrt(10)).as_content_primitive(radical=True) (2, sqrt(2)*(1 + 2*sqrt(5))) If clear=False (default is True) then content will not be removed from an Add if it can be distributed to leave one or more terms with integer coefficients. >>> (x/2 + y).as_content_primitive() (1/2, x + 2*y) >>> (x/2 + y).as_content_primitive(clear=False) (1, x/2 + y) """ return S.One, self def as_numer_denom(self): """ expression -> a/b -> a, b This is just a stub that should be defined by an object's class methods to get anything else. See Also ======== normal: return a/b instead of a, b """ return self, S.One def normal(self): from .mul import _unevaluated_Mul n, d = self.as_numer_denom() if d is S.One: return n if d.is_Number: return _unevaluated_Mul(n, 1/d) else: return n/d def extract_multiplicatively(self, c): """Return None if it's not possible to make self in the form c * something in a nice way, i.e. preserving the properties of arguments of self. Examples ======== >>> from sympy import symbols, Rational >>> x, y = symbols('x,y', real=True) >>> ((x*y)**3).extract_multiplicatively(x**2 * y) x*y**2 >>> ((x*y)**3).extract_multiplicatively(x**4 * y) >>> (2*x).extract_multiplicatively(2) x >>> (2*x).extract_multiplicatively(3) >>> (Rational(1, 2)*x).extract_multiplicatively(3) x/6 """ c = sympify(c) if self is S.NaN: return None if c is S.One: return self elif c == self: return S.One if c.is_Add: cc, pc = c.primitive() if cc is not S.One: c = Mul(cc, pc, evaluate=False) if c.is_Mul: a, b = c.as_two_terms() x = self.extract_multiplicatively(a) if x is not None: return x.extract_multiplicatively(b) quotient = self / c if self.is_Number: if self is S.Infinity: if c.is_positive: return S.Infinity elif self is S.NegativeInfinity: if c.is_negative: return S.Infinity elif c.is_positive: return S.NegativeInfinity elif self is S.ComplexInfinity: if not c.is_zero: return S.ComplexInfinity elif self.is_Integer: if not quotient.is_Integer: return None elif self.is_positive and quotient.is_negative: return None else: return quotient elif self.is_Rational: if not quotient.is_Rational: return None elif self.is_positive and quotient.is_negative: return None else: return quotient elif self.is_Float: if not quotient.is_Float: return None elif self.is_positive and quotient.is_negative: return None else: return quotient elif self.is_NumberSymbol or self.is_Symbol or self is S.ImaginaryUnit: if quotient.is_Mul and len(quotient.args) == 2: if quotient.args[0].is_Integer and quotient.args[0].is_positive and quotient.args[1] == self: return quotient elif quotient.is_Integer and c.is_Number: return quotient elif self.is_Add: cs, ps = self.primitive() # assert cs >= 1 if c.is_Number and c is not S.NegativeOne: # assert c != 1 (handled at top) if cs is not S.One: if c.is_negative: xc = -(cs.extract_multiplicatively(-c)) else: xc = cs.extract_multiplicatively(c) if xc is not None: return xc*ps # rely on 2-arg Mul to restore Add return # |c| != 1 can only be extracted from cs if c == ps: return cs # check args of ps newargs = [] for arg in ps.args: newarg = arg.extract_multiplicatively(c) if newarg is None: return # all or nothing newargs.append(newarg) # args should be in same order so use unevaluated return if cs is not S.One: return Add._from_args([cs*t for t in newargs]) else: return Add._from_args(newargs) elif self.is_Mul: args = list(self.args) for i, arg in enumerate(args): newarg = arg.extract_multiplicatively(c) if newarg is not None: args[i] = newarg return Mul(*args) elif self.is_Pow: if c.is_Pow and c.base == self.base: new_exp = self.exp.extract_additively(c.exp) if new_exp is not None: return self.base ** (new_exp) elif c == self.base: new_exp = self.exp.extract_additively(1) if new_exp is not None: return self.base ** (new_exp) def extract_additively(self, c): """Return self - c if it's possible to subtract c from self and make all matching coefficients move towards zero, else return None. Examples ======== >>> from sympy.abc import x, y >>> e = 2*x + 3 >>> e.extract_additively(x + 1) x + 2 >>> e.extract_additively(3*x) >>> e.extract_additively(4) >>> (y*(x + 1)).extract_additively(x + 1) >>> ((x + 1)*(x + 2*y + 1) + 3).extract_additively(x + 1) (x + 1)*(x + 2*y) + 3 Sometimes auto-expansion will return a less simplified result than desired; gcd_terms might be used in such cases: >>> from sympy import gcd_terms >>> (4*x*(y + 1) + y).extract_additively(x) 4*x*(y + 1) + x*(4*y + 3) - x*(4*y + 4) + y >>> gcd_terms(_) x*(4*y + 3) + y See Also ======== extract_multiplicatively coeff as_coefficient """ c = sympify(c) if self is S.NaN: return None if c is S.Zero: return self elif c == self: return S.Zero elif self is S.Zero: return None if self.is_Number: if not c.is_Number: return None co = self diff = co - c # XXX should we match types? i.e should 3 - .1 succeed? if (co > 0 and diff > 0 and diff < co or co < 0 and diff < 0 and diff > co): return diff return None if c.is_Number: co, t = self.as_coeff_Add() xa = co.extract_additively(c) if xa is None: return None return xa + t # handle the args[0].is_Number case separately # since we will have trouble looking for the coeff of # a number. if c.is_Add and c.args[0].is_Number: # whole term as a term factor co = self.coeff(c) xa0 = (co.extract_additively(1) or 0)*c if xa0: diff = self - co*c return (xa0 + (diff.extract_additively(c) or diff)) or None # term-wise h, t = c.as_coeff_Add() sh, st = self.as_coeff_Add() xa = sh.extract_additively(h) if xa is None: return None xa2 = st.extract_additively(t) if xa2 is None: return None return xa + xa2 # whole term as a term factor co = self.coeff(c) xa0 = (co.extract_additively(1) or 0)*c if xa0: diff = self - co*c return (xa0 + (diff.extract_additively(c) or diff)) or None # term-wise coeffs = [] for a in Add.make_args(c): ac, at = a.as_coeff_Mul() co = self.coeff(at) if not co: return None coc, cot = co.as_coeff_Add() xa = coc.extract_additively(ac) if xa is None: return None self -= co*at coeffs.append((cot + xa)*at) coeffs.append(self) return Add(*coeffs) @property def expr_free_symbols(self): """ Like ``free_symbols``, but returns the free symbols only if they are contained in an expression node. Examples ======== >>> from sympy.abc import x, y >>> (x + y).expr_free_symbols {x, y} If the expression is contained in a non-expression object, don't return the free symbols. Compare: >>> from sympy import Tuple >>> t = Tuple(x + y) >>> t.expr_free_symbols set() >>> t.free_symbols {x, y} """ return {j for i in self.args for j in i.expr_free_symbols} def could_extract_minus_sign(self): """Return True if self is not in a canonical form with respect to its sign. For most expressions, e, there will be a difference in e and -e. When there is, True will be returned for one and False for the other; False will be returned if there is no difference. Examples ======== >>> from sympy.abc import x, y >>> e = x - y >>> {i.could_extract_minus_sign() for i in (e, -e)} {False, True} """ negative_self = -self if self == negative_self: return False # e.g. zoo*x == -zoo*x self_has_minus = (self.extract_multiplicatively(-1) is not None) negative_self_has_minus = ( (negative_self).extract_multiplicatively(-1) is not None) if self_has_minus != negative_self_has_minus: return self_has_minus else: if self.is_Add: # We choose the one with less arguments with minus signs all_args = len(self.args) negative_args = len([False for arg in self.args if arg.could_extract_minus_sign()]) positive_args = all_args - negative_args if positive_args > negative_args: return False elif positive_args < negative_args: return True elif self.is_Mul: # We choose the one with an odd number of minus signs num, den = self.as_numer_denom() args = Mul.make_args(num) + Mul.make_args(den) arg_signs = [arg.could_extract_minus_sign() for arg in args] negative_args = list(filter(None, arg_signs)) return len(negative_args) % 2 == 1 # As a last resort, we choose the one with greater value of .sort_key() return bool(self.sort_key() < negative_self.sort_key()) def extract_branch_factor(self, allow_half=False): """ Try to write self as ``exp_polar(2*pi*I*n)*z`` in a nice way. Return (z, n). >>> from sympy import exp_polar, I, pi >>> from sympy.abc import x, y >>> exp_polar(I*pi).extract_branch_factor() (exp_polar(I*pi), 0) >>> exp_polar(2*I*pi).extract_branch_factor() (1, 1) >>> exp_polar(-pi*I).extract_branch_factor() (exp_polar(I*pi), -1) >>> exp_polar(3*pi*I + x).extract_branch_factor() (exp_polar(x + I*pi), 1) >>> (y*exp_polar(-5*pi*I)*exp_polar(3*pi*I + 2*pi*x)).extract_branch_factor() (y*exp_polar(2*pi*x), -1) >>> exp_polar(-I*pi/2).extract_branch_factor() (exp_polar(-I*pi/2), 0) If allow_half is True, also extract exp_polar(I*pi): >>> exp_polar(I*pi).extract_branch_factor(allow_half=True) (1, 1/2) >>> exp_polar(2*I*pi).extract_branch_factor(allow_half=True) (1, 1) >>> exp_polar(3*I*pi).extract_branch_factor(allow_half=True) (1, 3/2) >>> exp_polar(-I*pi).extract_branch_factor(allow_half=True) (1, -1/2) """ from sympy import exp_polar, pi, I, ceiling, Add n = S(0) res = S(1) args = Mul.make_args(self) exps = [] for arg in args: if isinstance(arg, exp_polar): exps += [arg.exp] else: res *= arg piimult = S(0) extras = [] while exps: exp = exps.pop() if exp.is_Add: exps += exp.args continue if exp.is_Mul: coeff = exp.as_coefficient(pi*I) if coeff is not None: piimult += coeff continue extras += [exp] if piimult.is_number: coeff = piimult tail = () else: coeff, tail = piimult.as_coeff_add(*piimult.free_symbols) # round down to nearest multiple of 2 branchfact = ceiling(coeff/2 - S(1)/2)*2 n += branchfact/2 c = coeff - branchfact if allow_half: nc = c.extract_additively(1) if nc is not None: n += S(1)/2 c = nc newexp = pi*I*Add(*((c, ) + tail)) + Add(*extras) if newexp != 0: res *= exp_polar(newexp) return res, n def _eval_is_polynomial(self, syms): if self.free_symbols.intersection(syms) == set([]): return True return False def is_polynomial(self, *syms): r""" Return True if self is a polynomial in syms and False otherwise. This checks if self is an exact polynomial in syms. This function returns False for expressions that are "polynomials" with symbolic exponents. Thus, you should be able to apply polynomial algorithms to expressions for which this returns True, and Poly(expr, \*syms) should work if and only if expr.is_polynomial(\*syms) returns True. The polynomial does not have to be in expanded form. If no symbols are given, all free symbols in the expression will be used. This is not part of the assumptions system. You cannot do Symbol('z', polynomial=True). Examples ======== >>> from sympy import Symbol >>> x = Symbol('x') >>> ((x**2 + 1)**4).is_polynomial(x) True >>> ((x**2 + 1)**4).is_polynomial() True >>> (2**x + 1).is_polynomial(x) False >>> n = Symbol('n', nonnegative=True, integer=True) >>> (x**n + 1).is_polynomial(x) False This function does not attempt any nontrivial simplifications that may result in an expression that does not appear to be a polynomial to become one. >>> from sympy import sqrt, factor, cancel >>> y = Symbol('y', positive=True) >>> a = sqrt(y**2 + 2*y + 1) >>> a.is_polynomial(y) False >>> factor(a) y + 1 >>> factor(a).is_polynomial(y) True >>> b = (y**2 + 2*y + 1)/(y + 1) >>> b.is_polynomial(y) False >>> cancel(b) y + 1 >>> cancel(b).is_polynomial(y) True See also .is_rational_function() """ if syms: syms = set(map(sympify, syms)) else: syms = self.free_symbols if syms.intersection(self.free_symbols) == set([]): # constant polynomial return True else: return self._eval_is_polynomial(syms) def _eval_is_rational_function(self, syms): if self.free_symbols.intersection(syms) == set([]): return True return False def is_rational_function(self, *syms): """ Test whether function is a ratio of two polynomials in the given symbols, syms. When syms is not given, all free symbols will be used. The rational function does not have to be in expanded or in any kind of canonical form. This function returns False for expressions that are "rational functions" with symbolic exponents. Thus, you should be able to call .as_numer_denom() and apply polynomial algorithms to the result for expressions for which this returns True. This is not part of the assumptions system. You cannot do Symbol('z', rational_function=True). Examples ======== >>> from sympy import Symbol, sin >>> from sympy.abc import x, y >>> (x/y).is_rational_function() True >>> (x**2).is_rational_function() True >>> (x/sin(y)).is_rational_function(y) False >>> n = Symbol('n', integer=True) >>> (x**n + 1).is_rational_function(x) False This function does not attempt any nontrivial simplifications that may result in an expression that does not appear to be a rational function to become one. >>> from sympy import sqrt, factor >>> y = Symbol('y', positive=True) >>> a = sqrt(y**2 + 2*y + 1)/y >>> a.is_rational_function(y) False >>> factor(a) (y + 1)/y >>> factor(a).is_rational_function(y) True See also is_algebraic_expr(). """ if self in [S.NaN, S.Infinity, -S.Infinity, S.ComplexInfinity]: return False if syms: syms = set(map(sympify, syms)) else: syms = self.free_symbols if syms.intersection(self.free_symbols) == set([]): # constant rational function return True else: return self._eval_is_rational_function(syms) def _eval_is_algebraic_expr(self, syms): if self.free_symbols.intersection(syms) == set([]): return True return False def is_algebraic_expr(self, *syms): """ This tests whether a given expression is algebraic or not, in the given symbols, syms. When syms is not given, all free symbols will be used. The rational function does not have to be in expanded or in any kind of canonical form. This function returns False for expressions that are "algebraic expressions" with symbolic exponents. This is a simple extension to the is_rational_function, including rational exponentiation. Examples ======== >>> from sympy import Symbol, sqrt >>> x = Symbol('x', real=True) >>> sqrt(1 + x).is_rational_function() False >>> sqrt(1 + x).is_algebraic_expr() True This function does not attempt any nontrivial simplifications that may result in an expression that does not appear to be an algebraic expression to become one. >>> from sympy import exp, factor >>> a = sqrt(exp(x)**2 + 2*exp(x) + 1)/(exp(x) + 1) >>> a.is_algebraic_expr(x) False >>> factor(a).is_algebraic_expr() True See Also ======== is_rational_function() References ========== - https://en.wikipedia.org/wiki/Algebraic_expression """ if syms: syms = set(map(sympify, syms)) else: syms = self.free_symbols if syms.intersection(self.free_symbols) == set([]): # constant algebraic expression return True else: return self._eval_is_algebraic_expr(syms) ################################################################################### ##################### SERIES, LEADING TERM, LIMIT, ORDER METHODS ################## ################################################################################### def series(self, x=None, x0=0, n=6, dir="+", logx=None): """ Series expansion of "self" around ``x = x0`` yielding either terms of the series one by one (the lazy series given when n=None), else all the terms at once when n != None. Returns the series expansion of "self" around the point ``x = x0`` with respect to ``x`` up to ``O((x - x0)**n, x, x0)`` (default n is 6). If ``x=None`` and ``self`` is univariate, the univariate symbol will be supplied, otherwise an error will be raised. >>> from sympy import cos, exp >>> from sympy.abc import x, y >>> cos(x).series() 1 - x**2/2 + x**4/24 + O(x**6) >>> cos(x).series(n=4) 1 - x**2/2 + O(x**4) >>> cos(x).series(x, x0=1, n=2) cos(1) - (x - 1)*sin(1) + O((x - 1)**2, (x, 1)) >>> e = cos(x + exp(y)) >>> e.series(y, n=2) cos(x + 1) - y*sin(x + 1) + O(y**2) >>> e.series(x, n=2) cos(exp(y)) - x*sin(exp(y)) + O(x**2) If ``n=None`` then a generator of the series terms will be returned. >>> term=cos(x).series(n=None) >>> [next(term) for i in range(2)] [1, -x**2/2] For ``dir=+`` (default) the series is calculated from the right and for ``dir=-`` the series from the left. For smooth functions this flag will not alter the results. >>> abs(x).series(dir="+") x >>> abs(x).series(dir="-") -x """ from sympy import collect, Dummy, Order, Rational, Symbol, ceiling if x is None: syms = self.free_symbols if not syms: return self elif len(syms) > 1: raise ValueError('x must be given for multivariate functions.') x = syms.pop() if isinstance(x, Symbol): dep = x in self.free_symbols else: d = Dummy() dep = d in self.xreplace({x: d}).free_symbols if not dep: if n is None: return (s for s in [self]) else: return self if len(dir) != 1 or dir not in '+-': raise ValueError("Dir must be '+' or '-'") if x0 in [S.Infinity, S.NegativeInfinity]: sgn = 1 if x0 is S.Infinity else -1 s = self.subs(x, sgn/x).series(x, n=n, dir='+') if n is None: return (si.subs(x, sgn/x) for si in s) return s.subs(x, sgn/x) # use rep to shift origin to x0 and change sign (if dir is negative) # and undo the process with rep2 if x0 or dir == '-': if dir == '-': rep = -x + x0 rep2 = -x rep2b = x0 else: rep = x + x0 rep2 = x rep2b = -x0 s = self.subs(x, rep).series(x, x0=0, n=n, dir='+', logx=logx) if n is None: # lseries... return (si.subs(x, rep2 + rep2b) for si in s) return s.subs(x, rep2 + rep2b) # from here on it's x0=0 and dir='+' handling if x.is_positive is x.is_negative is None or x.is_Symbol is not True: # replace x with an x that has a positive assumption xpos = Dummy('x', positive=True, finite=True) rv = self.subs(x, xpos).series(xpos, x0, n, dir, logx=logx) if n is None: return (s.subs(xpos, x) for s in rv) else: return rv.subs(xpos, x) if n is not None: # nseries handling s1 = self._eval_nseries(x, n=n, logx=logx) o = s1.getO() or S.Zero if o: # make sure the requested order is returned ngot = o.getn() if ngot > n: # leave o in its current form (e.g. with x*log(x)) so # it eats terms properly, then replace it below if n != 0: s1 += o.subs(x, x**Rational(n, ngot)) else: s1 += Order(1, x) elif ngot < n: # increase the requested number of terms to get the desired # number keep increasing (up to 9) until the received order # is different than the original order and then predict how # many additional terms are needed for more in range(1, 9): s1 = self._eval_nseries(x, n=n + more, logx=logx) newn = s1.getn() if newn != ngot: ndo = n + ceiling((n - ngot)*more/(newn - ngot)) s1 = self._eval_nseries(x, n=ndo, logx=logx) while s1.getn() < n: s1 = self._eval_nseries(x, n=ndo, logx=logx) ndo += 1 break else: raise ValueError('Could not calculate %s terms for %s' % (str(n), self)) s1 += Order(x**n, x) o = s1.getO() s1 = s1.removeO() else: o = Order(x**n, x) s1done = s1.doit() if (s1done + o).removeO() == s1done: o = S.Zero try: return collect(s1, x) + o except NotImplementedError: return s1 + o else: # lseries handling def yield_lseries(s): """Return terms of lseries one at a time.""" for si in s: if not si.is_Add: yield si continue # yield terms 1 at a time if possible # by increasing order until all the # terms have been returned yielded = 0 o = Order(si, x)*x ndid = 0 ndo = len(si.args) while 1: do = (si - yielded + o).removeO() o *= x if not do or do.is_Order: continue if do.is_Add: ndid += len(do.args) else: ndid += 1 yield do if ndid == ndo: break yielded += do return yield_lseries(self.removeO()._eval_lseries(x, logx=logx)) def taylor_term(self, n, x, *previous_terms): """General method for the taylor term. This method is slow, because it differentiates n-times. Subclasses can redefine it to make it faster by using the "previous_terms". """ from sympy import Dummy, factorial x = sympify(x) _x = Dummy('x') return self.subs(x, _x).diff(_x, n).subs(_x, x).subs(x, 0) * x**n / factorial(n) def lseries(self, x=None, x0=0, dir='+', logx=None): """ Wrapper for series yielding an iterator of the terms of the series. Note: an infinite series will yield an infinite iterator. The following, for exaxmple, will never terminate. It will just keep printing terms of the sin(x) series:: for term in sin(x).lseries(x): print term The advantage of lseries() over nseries() is that many times you are just interested in the next term in the series (i.e. the first term for example), but you don't know how many you should ask for in nseries() using the "n" parameter. See also nseries(). """ return self.series(x, x0, n=None, dir=dir, logx=logx) def _eval_lseries(self, x, logx=None): # default implementation of lseries is using nseries(), and adaptively # increasing the "n". As you can see, it is not very efficient, because # we are calculating the series over and over again. Subclasses should # override this method and implement much more efficient yielding of # terms. n = 0 series = self._eval_nseries(x, n=n, logx=logx) if not series.is_Order: if series.is_Add: yield series.removeO() else: yield series return while series.is_Order: n += 1 series = self._eval_nseries(x, n=n, logx=logx) e = series.removeO() yield e while 1: while 1: n += 1 series = self._eval_nseries(x, n=n, logx=logx).removeO() if e != series: break yield series - e e = series def nseries(self, x=None, x0=0, n=6, dir='+', logx=None): """ Wrapper to _eval_nseries if assumptions allow, else to series. If x is given, x0 is 0, dir='+', and self has x, then _eval_nseries is called. This calculates "n" terms in the innermost expressions and then builds up the final series just by "cross-multiplying" everything out. The optional ``logx`` parameter can be used to replace any log(x) in the returned series with a symbolic value to avoid evaluating log(x) at 0. A symbol to use in place of log(x) should be provided. Advantage -- it's fast, because we don't have to determine how many terms we need to calculate in advance. Disadvantage -- you may end up with less terms than you may have expected, but the O(x**n) term appended will always be correct and so the result, though perhaps shorter, will also be correct. If any of those assumptions is not met, this is treated like a wrapper to series which will try harder to return the correct number of terms. See also lseries(). Examples ======== >>> from sympy import sin, log, Symbol >>> from sympy.abc import x, y >>> sin(x).nseries(x, 0, 6) x - x**3/6 + x**5/120 + O(x**6) >>> log(x+1).nseries(x, 0, 5) x - x**2/2 + x**3/3 - x**4/4 + O(x**5) Handling of the ``logx`` parameter --- in the following example the expansion fails since ``sin`` does not have an asymptotic expansion at -oo (the limit of log(x) as x approaches 0): >>> e = sin(log(x)) >>> e.nseries(x, 0, 6) Traceback (most recent call last): ... PoleError: ... ... >>> logx = Symbol('logx') >>> e.nseries(x, 0, 6, logx=logx) sin(logx) In the following example, the expansion works but gives only an Order term unless the ``logx`` parameter is used: >>> e = x**y >>> e.nseries(x, 0, 2) O(log(x)**2) >>> e.nseries(x, 0, 2, logx=logx) exp(logx*y) """ if x and not x in self.free_symbols: return self if x is None or x0 or dir != '+': # {see XPOS above} or (x.is_positive == x.is_negative == None): return self.series(x, x0, n, dir) else: return self._eval_nseries(x, n=n, logx=logx) def _eval_nseries(self, x, n, logx): """ Return terms of series for self up to O(x**n) at x=0 from the positive direction. This is a method that should be overridden in subclasses. Users should never call this method directly (use .nseries() instead), so you don't have to write docstrings for _eval_nseries(). """ from sympy.utilities.misc import filldedent raise NotImplementedError(filldedent(""" The _eval_nseries method should be added to %s to give terms up to O(x**n) at x=0 from the positive direction so it is available when nseries calls it.""" % self.func) ) def limit(self, x, xlim, dir='+'): """ Compute limit x->xlim. """ from sympy.series.limits import limit return limit(self, x, xlim, dir) def compute_leading_term(self, x, logx=None): """ as_leading_term is only allowed for results of .series() This is a wrapper to compute a series first. """ from sympy import Dummy, log from sympy.series.gruntz import calculate_series if self.removeO() == 0: return self if logx is None: d = Dummy('logx') s = calculate_series(self, x, d).subs(d, log(x)) else: s = calculate_series(self, x, logx) return s.as_leading_term(x) @cacheit def as_leading_term(self, *symbols): """ Returns the leading (nonzero) term of the series expansion of self. The _eval_as_leading_term routines are used to do this, and they must always return a non-zero value. Examples ======== >>> from sympy.abc import x >>> (1 + x + x**2).as_leading_term(x) 1 >>> (1/x**2 + x + x**2).as_leading_term(x) x**(-2) """ from sympy import powsimp if len(symbols) > 1: c = self for x in symbols: c = c.as_leading_term(x) return c elif not symbols: return self x = sympify(symbols[0]) if not x.is_symbol: raise ValueError('expecting a Symbol but got %s' % x) if x not in self.free_symbols: return self obj = self._eval_as_leading_term(x) if obj is not None: return powsimp(obj, deep=True, combine='exp') raise NotImplementedError('as_leading_term(%s, %s)' % (self, x)) def _eval_as_leading_term(self, x): return self def as_coeff_exponent(self, x): """ ``c*x**e -> c,e`` where x can be any symbolic expression. """ from sympy import collect s = collect(self, x) c, p = s.as_coeff_mul(x) if len(p) == 1: b, e = p[0].as_base_exp() if b == x: return c, e return s, S.Zero def leadterm(self, x): """ Returns the leading term a*x**b as a tuple (a, b). Examples ======== >>> from sympy.abc import x >>> (1+x+x**2).leadterm(x) (1, 0) >>> (1/x**2+x+x**2).leadterm(x) (1, -2) """ from sympy import Dummy, log l = self.as_leading_term(x) d = Dummy('logx') if l.has(log(x)): l = l.subs(log(x), d) c, e = l.as_coeff_exponent(x) if x in c.free_symbols: from sympy.utilities.misc import filldedent raise ValueError(filldedent(""" cannot compute leadterm(%s, %s). The coefficient should have been free of x but got %s""" % (self, x, c))) c = c.subs(d, log(x)) return c, e def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ return S.One, self def as_coeff_Add(self, rational=False): """Efficiently extract the coefficient of a summation. """ return S.Zero, self def fps(self, x=None, x0=0, dir=1, hyper=True, order=4, rational=True, full=False): """ Compute formal power power series of self. See the docstring of the :func:`fps` function in sympy.series.formal for more information. """ from sympy.series.formal import fps return fps(self, x, x0, dir, hyper, order, rational, full) def fourier_series(self, limits=None): """Compute fourier sine/cosine series of self. See the docstring of the :func:`fourier_series` in sympy.series.fourier for more information. """ from sympy.series.fourier import fourier_series return fourier_series(self, limits) ################################################################################### ##################### DERIVATIVE, INTEGRAL, FUNCTIONAL METHODS #################### ################################################################################### def diff(self, *symbols, **assumptions): assumptions.setdefault("evaluate", True) return Derivative(self, *symbols, **assumptions) ########################################################################### ###################### EXPRESSION EXPANSION METHODS ####################### ########################################################################### # Relevant subclasses should override _eval_expand_hint() methods. See # the docstring of expand() for more info. def _eval_expand_complex(self, **hints): real, imag = self.as_real_imag(**hints) return real + S.ImaginaryUnit*imag @staticmethod def _expand_hint(expr, hint, deep=True, **hints): """ Helper for ``expand()``. Recursively calls ``expr._eval_expand_hint()``. Returns ``(expr, hit)``, where expr is the (possibly) expanded ``expr`` and ``hit`` is ``True`` if ``expr`` was truly expanded and ``False`` otherwise. """ hit = False # XXX: Hack to support non-Basic args # | # V if deep and getattr(expr, 'args', ()) and not expr.is_Atom: sargs = [] for arg in expr.args: arg, arghit = Expr._expand_hint(arg, hint, **hints) hit |= arghit sargs.append(arg) if hit: expr = expr.func(*sargs) if hasattr(expr, hint): newexpr = getattr(expr, hint)(**hints) if newexpr != expr: return (newexpr, True) return (expr, hit) @cacheit def expand(self, deep=True, modulus=None, power_base=True, power_exp=True, mul=True, log=True, multinomial=True, basic=True, **hints): """ Expand an expression using hints. See the docstring of the expand() function in sympy.core.function for more information. """ from sympy.simplify.radsimp import fraction hints.update(power_base=power_base, power_exp=power_exp, mul=mul, log=log, multinomial=multinomial, basic=basic) expr = self if hints.pop('frac', False): n, d = [a.expand(deep=deep, modulus=modulus, **hints) for a in fraction(self)] return n/d elif hints.pop('denom', False): n, d = fraction(self) return n/d.expand(deep=deep, modulus=modulus, **hints) elif hints.pop('numer', False): n, d = fraction(self) return n.expand(deep=deep, modulus=modulus, **hints)/d # Although the hints are sorted here, an earlier hint may get applied # at a given node in the expression tree before another because of how # the hints are applied. e.g. expand(log(x*(y + z))) -> log(x*y + # x*z) because while applying log at the top level, log and mul are # applied at the deeper level in the tree so that when the log at the # upper level gets applied, the mul has already been applied at the # lower level. # Additionally, because hints are only applied once, the expression # may not be expanded all the way. For example, if mul is applied # before multinomial, x*(x + 1)**2 won't be expanded all the way. For # now, we just use a special case to make multinomial run before mul, # so that at least polynomials will be expanded all the way. In the # future, smarter heuristics should be applied. # TODO: Smarter heuristics def _expand_hint_key(hint): """Make multinomial come before mul""" if hint == 'mul': return 'mulz' return hint for hint in sorted(hints.keys(), key=_expand_hint_key): use_hint = hints[hint] if use_hint: hint = '_eval_expand_' + hint expr, hit = Expr._expand_hint(expr, hint, deep=deep, **hints) while True: was = expr if hints.get('multinomial', False): expr, _ = Expr._expand_hint( expr, '_eval_expand_multinomial', deep=deep, **hints) if hints.get('mul', False): expr, _ = Expr._expand_hint( expr, '_eval_expand_mul', deep=deep, **hints) if hints.get('log', False): expr, _ = Expr._expand_hint( expr, '_eval_expand_log', deep=deep, **hints) if expr == was: break if modulus is not None: modulus = sympify(modulus) if not modulus.is_Integer or modulus <= 0: raise ValueError( "modulus must be a positive integer, got %s" % modulus) terms = [] for term in Add.make_args(expr): coeff, tail = term.as_coeff_Mul(rational=True) coeff %= modulus if coeff: terms.append(coeff*tail) expr = Add(*terms) return expr ########################################################################### ################### GLOBAL ACTION VERB WRAPPER METHODS #################### ########################################################################### def integrate(self, *args, **kwargs): """See the integrate function in sympy.integrals""" from sympy.integrals import integrate return integrate(self, *args, **kwargs) def simplify(self, ratio=1.7, measure=None, rational=False, inverse=False): """See the simplify function in sympy.simplify""" from sympy.simplify import simplify from sympy.core.function import count_ops measure = measure or count_ops return simplify(self, ratio, measure) def nsimplify(self, constants=[], tolerance=None, full=False): """See the nsimplify function in sympy.simplify""" from sympy.simplify import nsimplify return nsimplify(self, constants, tolerance, full) def separate(self, deep=False, force=False): """See the separate function in sympy.simplify""" from sympy.core.function import expand_power_base return expand_power_base(self, deep=deep, force=force) def collect(self, syms, func=None, evaluate=True, exact=False, distribute_order_term=True): """See the collect function in sympy.simplify""" from sympy.simplify import collect return collect(self, syms, func, evaluate, exact, distribute_order_term) def together(self, *args, **kwargs): """See the together function in sympy.polys""" from sympy.polys import together return together(self, *args, **kwargs) def apart(self, x=None, **args): """See the apart function in sympy.polys""" from sympy.polys import apart return apart(self, x, **args) def ratsimp(self): """See the ratsimp function in sympy.simplify""" from sympy.simplify import ratsimp return ratsimp(self) def trigsimp(self, **args): """See the trigsimp function in sympy.simplify""" from sympy.simplify import trigsimp return trigsimp(self, **args) def radsimp(self, **kwargs): """See the radsimp function in sympy.simplify""" from sympy.simplify import radsimp return radsimp(self, **kwargs) def powsimp(self, *args, **kwargs): """See the powsimp function in sympy.simplify""" from sympy.simplify import powsimp return powsimp(self, *args, **kwargs) def combsimp(self): """See the combsimp function in sympy.simplify""" from sympy.simplify import combsimp return combsimp(self) def gammasimp(self): """See the gammasimp function in sympy.simplify""" from sympy.simplify import gammasimp return gammasimp(self) def factor(self, *gens, **args): """See the factor() function in sympy.polys.polytools""" from sympy.polys import factor return factor(self, *gens, **args) def refine(self, assumption=True): """See the refine function in sympy.assumptions""" from sympy.assumptions import refine return refine(self, assumption) def cancel(self, *gens, **args): """See the cancel function in sympy.polys""" from sympy.polys import cancel return cancel(self, *gens, **args) def invert(self, g, *gens, **args): """Return the multiplicative inverse of ``self`` mod ``g`` where ``self`` (and ``g``) may be symbolic expressions). See Also ======== sympy.core.numbers.mod_inverse, sympy.polys.polytools.invert """ from sympy.polys.polytools import invert from sympy.core.numbers import mod_inverse if self.is_number and getattr(g, 'is_number', True): return mod_inverse(self, g) return invert(self, g, *gens, **args) def round(self, n=None): """Return x rounded to the given decimal place. If a complex number would results, apply round to the real and imaginary components of the number. Examples ======== >>> from sympy import pi, E, I, S, Add, Mul, Number >>> pi.round() 3 >>> pi.round(2) 3.14 >>> (2*pi + E*I).round() 6 + 3*I The round method has a chopping effect: >>> (2*pi + I/10).round() 6 >>> (pi/10 + 2*I).round() 2*I >>> (pi/10 + E*I).round(2) 0.31 + 2.72*I Notes ===== The Python builtin function, round, always returns a float in Python 2 while the SymPy round method (and round with a Number argument in Python 3) returns a Number. >>> from sympy.core.compatibility import PY3 >>> isinstance(round(S(123), -2), Number if PY3 else float) True For a consistent behavior, and Python 3 rounding rules, import `round` from sympy.core.compatibility. >>> from sympy.core.compatibility import round >>> isinstance(round(S(123), -2), Number) True """ from sympy.core.power import integer_log from sympy.core.numbers import Float x = self if not x.is_number: raise TypeError("can't round symbolic expression") if not x.is_Atom: if not pure_complex(x.n(2), or_real=True): raise TypeError( 'Expected a number but got %s:' % func_name(x)) elif x in (S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity): return x if not x.is_real: i, r = x.as_real_imag() return i.round(n) + S.ImaginaryUnit*r.round(n) if not x: return S.Zero if n is None else x p = as_int(n or 0) if x.is_Integer: # XXX return Integer(round(int(x), p)) when Py2 is dropped if p >= 0: return x m = 10**-p i, r = divmod(abs(x), m) if i%2 and 2*r == m: i += 1 elif 2*r > m: i += 1 if x < 0: i *= -1 return i*m digits_to_decimal = _mag(x) allow = digits_needed = digits_to_decimal + p precs = [f._prec for f in x.atoms(Float)] dps = prec_to_dps(max(precs)) if precs else None if dps is None: # assume everything is exact so use the Python # float default or whatever was requested dps = max(15, allow) else: allow = min(allow, dps) # this will shift all digits to right of decimal # and give us dps to work with as an int shift = -digits_to_decimal + dps extra = 1 # how far we look past known digits # NOTE # mpmath will calculate the binary representation to # an arbitrary number of digits but we must base our # answer on a finite number of those digits, e.g. # .575 2589569785738035/2**52 in binary. # mpmath shows us that the first 18 digits are # >>> Float(.575).n(18) # 0.574999999999999956 # The default precision is 15 digits and if we ask # for 15 we get # >>> Float(.575).n(15) # 0.575000000000000 # mpmath handles rounding at the 15th digit. But we # need to be careful since the user might be asking # for rounding at the last digit and our semantics # are to round toward the even final digit when there # is a tie. So the extra digit will be used to make # that decision. In this case, the value is the same # to 15 digits: # >>> Float(.575).n(16) # 0.5750000000000000 # Now converting this to the 15 known digits gives # 575000000000000.0 # which rounds to integer # 5750000000000000 # And now we can round to the desired digt, e.g. at # the second from the left and we get # 5800000000000000 # and rescaling that gives # 0.58 # as the final result. # If the value is made slightly less than 0.575 we might # still obtain the same value: # >>> Float(.575-1e-16).n(16)*10**15 # 574999999999999.8 # What 15 digits best represents the known digits (which are # to the left of the decimal? 5750000000000000, the same as # before. The only way we will round down (in this case) is # if we declared that we had more than 15 digits of precision. # For example, if we use 16 digits of precision, the integer # we deal with is # >>> Float(.575-1e-16).n(17)*10**16 # 5749999999999998.4 # and this now rounds to 5749999999999998 and (if we round to # the 2nd digit from the left) we get 5700000000000000. # xf = x.n(dps + extra)*Pow(10, shift) xi = Integer(xf) # use the last digit to select the value of xi # nearest to x before rounding at the desired digit sign = 1 if x > 0 else -1 dif2 = sign*(xf - xi).n(extra) if dif2 < 0: raise NotImplementedError( 'not expecting int(x) to round away from 0') if dif2 > .5: xi += sign # round away from 0 elif dif2 == .5: xi += sign if xi%2 else -sign # round toward even # shift p to the new position ip = p - shift # let Python handle the int rounding then rescale xr = xi.round(ip) # when Py2 is drop make this round(xi.p, ip) # restore scale rv = Rational(xr, Pow(10, shift)) # return Float or Integer if rv.is_Integer: if n is None: # the single-arg case return rv # use str or else it won't be a float return Float(str(rv), digits_needed) else: if not allow and rv > self: allow += 1 return Float(rv, allow) __round__ = round def _eval_derivative_matrix_lines(self, x): from sympy.matrices.expressions.matexpr import _LeftRightArgs return [_LeftRightArgs([S.One, S.One], higher=self._eval_derivative(x))] class AtomicExpr(Atom, Expr): """ A parent class for object which are both atoms and Exprs. For example: Symbol, Number, Rational, Integer, ... But not: Add, Mul, Pow, ... """ is_number = False is_Atom = True __slots__ = [] def _eval_derivative(self, s): if self == s: return S.One return S.Zero def _eval_derivative_n_times(self, s, n): from sympy import Piecewise, Eq from sympy import Tuple, MatrixExpr from sympy.matrices.common import MatrixCommon if isinstance(s, (MatrixCommon, Tuple, Iterable, MatrixExpr)): return super(AtomicExpr, self)._eval_derivative_n_times(s, n) if self == s: return Piecewise((self, Eq(n, 0)), (1, Eq(n, 1)), (0, True)) else: return Piecewise((self, Eq(n, 0)), (0, True)) def _eval_is_polynomial(self, syms): return True def _eval_is_rational_function(self, syms): return True def _eval_is_algebraic_expr(self, syms): return True def _eval_nseries(self, x, n, logx): return self @property def expr_free_symbols(self): return {self} def _mag(x): """Return integer ``i`` such that .1 <= x/10**i < 1 Examples ======== >>> from sympy.core.expr import _mag >>> from sympy import Float >>> _mag(Float(.1)) 0 >>> _mag(Float(.01)) -1 >>> _mag(Float(1234)) 4 """ from math import log10, ceil, log from sympy import Float xpos = abs(x.n()) if not xpos: return S.Zero try: mag_first_dig = int(ceil(log10(xpos))) except (ValueError, OverflowError): mag_first_dig = int(ceil(Float(mpf_log(xpos._mpf_, 53))/log(10))) # check that we aren't off by 1 if (xpos/10**mag_first_dig) >= 1: assert 1 <= (xpos/10**mag_first_dig) < 10 mag_first_dig += 1 return mag_first_dig class UnevaluatedExpr(Expr): """ Expression that is not evaluated unless released. Examples ======== >>> from sympy import UnevaluatedExpr >>> from sympy.abc import a, b, x, y >>> x*(1/x) 1 >>> x*UnevaluatedExpr(1/x) x*1/x """ def __new__(cls, arg, **kwargs): arg = _sympify(arg) obj = Expr.__new__(cls, arg, **kwargs) return obj def doit(self, **kwargs): if kwargs.get("deep", True): return self.args[0].doit(**kwargs) else: return self.args[0] def _n2(a, b): """Return (a - b).evalf(2) if a and b are comparable, else None. This should only be used when a and b are already sympified. """ # /!\ it is very important (see issue 8245) not to # use a re-evaluated number in the calculation of dif if a.is_comparable and b.is_comparable: dif = (a - b).evalf(2) if dif.is_comparable: return dif def unchanged(func, *args): """Return True if `func` applied to the `args` is unchanged. Can be used instead of `assert foo == foo`. Examples ======== >>> from sympy.core.expr import unchanged >>> from sympy.functions.elementary.trigonometric import cos >>> from sympy.core.numbers import pi >>> unchanged(cos, 1) # instead of assert cos(1) == cos(1) True >>> unchanged(cos, pi) False """ f = func(*args) return f.func == func and f.args == tuple([sympify(a) for a in args]) class ExprBuilder(object): def __init__(self, op, args=[], validator=None, check=True): if not hasattr(op, "__call__"): raise TypeError("op {} needs to be callable".format(op)) self.op = op self.args = args self.validator = validator if (validator is not None) and check: self.validate() @staticmethod def _build_args(args): return [i.build() if isinstance(i, ExprBuilder) else i for i in args] def validate(self): if self.validator is None: return args = self._build_args(self.args) self.validator(*args) def build(self, check=True): args = self._build_args(self.args) if self.validator and check: self.validator(*args) return self.op(*args) def append_argument(self, arg, check=True): self.args.append(arg) if self.validator and check: self.validate(*self.args) def __getitem__(self, item): if item == 0: return self.op else: return self.args[item-1] def __repr__(self): return str(self.build()) def search_element(self, elem): for i, arg in enumerate(self.args): if isinstance(arg, ExprBuilder): ret = arg.search_index(elem) if ret is not None: return (i,) + ret elif id(arg) == id(elem): return (i,) return None from .mul import Mul from .add import Add from .power import Pow from .function import Derivative, Function from .mod import Mod from .exprtools import factor_terms from .numbers import Integer, Rational

4f40d9dfe729e1798baaac412c8466a10a6609fbfbb7d340a02371e0ba62cc96

from __future__ import print_function, division import decimal import fractions import math import re as regex from .containers import Tuple from .sympify import converter, sympify, _sympify, SympifyError, _convert_numpy_types from .singleton import S, Singleton from .expr import Expr, AtomicExpr from .decorators import _sympifyit from .cache import cacheit, clear_cache from .logic import fuzzy_not from sympy.core.compatibility import ( as_int, integer_types, long, string_types, with_metaclass, HAS_GMPY, SYMPY_INTS, int_info) from sympy.core.cache import lru_cache import mpmath import mpmath.libmp as mlib from mpmath.libmp.backend import MPZ from mpmath.libmp import mpf_pow, mpf_pi, mpf_e, phi_fixed from mpmath.ctx_mp import mpnumeric from mpmath.libmp.libmpf import ( finf as _mpf_inf, fninf as _mpf_ninf, fnan as _mpf_nan, fzero as _mpf_zero, _normalize as mpf_normalize, prec_to_dps) from sympy.utilities.misc import debug, filldedent from .evaluate import global_evaluate from sympy.utilities.exceptions import SymPyDeprecationWarning rnd = mlib.round_nearest _LOG2 = math.log(2) def comp(z1, z2, tol=None): """Return a bool indicating whether the error between z1 and z2 is <= tol. If ``tol`` is None then True will be returned if there is a significant difference between the numbers: ``abs(z1 - z2)*10**p <= 1/2`` where ``p`` is the lower of the precisions of the values. A comparison of strings will be made if ``z1`` is a Number and a) ``z2`` is a string or b) ``tol`` is '' and ``z2`` is a Number. When ``tol`` is a nonzero value, if z2 is non-zero and ``|z1| > 1`` the error is normalized by ``|z1|``, so if you want to see if the absolute error between ``z1`` and ``z2`` is <= ``tol`` then call this as ``comp(z1 - z2, 0, tol)``. """ if type(z2) is str: if not isinstance(z1, Number): raise ValueError('when z2 is a str z1 must be a Number') return str(z1) == z2 if not z1: z1, z2 = z2, z1 if not z1: return True if not tol: if tol is None: if type(z2) is str and getattr(z1, 'is_Number', False): return str(z1) == z2 a, b = Float(z1), Float(z2) return int(abs(a - b)*10**prec_to_dps( min(a._prec, b._prec)))*2 <= 1 elif all(getattr(i, 'is_Number', False) for i in (z1, z2)): return z1._prec == z2._prec and str(z1) == str(z2) raise ValueError('exact comparison requires two Numbers') diff = abs(z1 - z2) az1 = abs(z1) if z2 and az1 > 1: return diff/az1 <= tol else: return diff <= tol def mpf_norm(mpf, prec): """Return the mpf tuple normalized appropriately for the indicated precision after doing a check to see if zero should be returned or not when the mantissa is 0. ``mpf_normlize`` always assumes that this is zero, but it may not be since the mantissa for mpf's values "+inf", "-inf" and "nan" have a mantissa of zero, too. Note: this is not intended to validate a given mpf tuple, so sending mpf tuples that were not created by mpmath may produce bad results. This is only a wrapper to ``mpf_normalize`` which provides the check for non- zero mpfs that have a 0 for the mantissa. """ sign, man, expt, bc = mpf if not man: # hack for mpf_normalize which does not do this; # it assumes that if man is zero the result is 0 # (see issue 6639) if not bc: return _mpf_zero else: # don't change anything; this should already # be a well formed mpf tuple return mpf # Necessary if mpmath is using the gmpy backend from mpmath.libmp.backend import MPZ rv = mpf_normalize(sign, MPZ(man), expt, bc, prec, rnd) return rv # TODO: we should use the warnings module _errdict = {"divide": False} def seterr(divide=False): """ Should sympy raise an exception on 0/0 or return a nan? divide == True .... raise an exception divide == False ... return nan """ if _errdict["divide"] != divide: clear_cache() _errdict["divide"] = divide def _as_integer_ratio(p): neg_pow, man, expt, bc = getattr(p, '_mpf_', mpmath.mpf(p)._mpf_) p = [1, -1][neg_pow % 2]*man if expt < 0: q = 2**-expt else: q = 1 p *= 2**expt return int(p), int(q) def _decimal_to_Rational_prec(dec): """Convert an ordinary decimal instance to a Rational.""" if not dec.is_finite(): raise TypeError("dec must be finite, got %s." % dec) s, d, e = dec.as_tuple() prec = len(d) if e >= 0: # it's an integer rv = Integer(int(dec)) else: s = (-1)**s d = sum([di*10**i for i, di in enumerate(reversed(d))]) rv = Rational(s*d, 10**-e) return rv, prec _floatpat = regex.compile(r"[-+]?((\d*\.\d+)|(\d+\.?))") def _literal_float(f): """Return True if n starts like a floating point number.""" return bool(_floatpat.match(f)) # (a,b) -> gcd(a,b) # TODO caching with decorator, but not to degrade performance @lru_cache(1024) def igcd(*args): """Computes nonnegative integer greatest common divisor. The algorithm is based on the well known Euclid's algorithm. To improve speed, igcd() has its own caching mechanism implemented. Examples ======== >>> from sympy.core.numbers import igcd >>> igcd(2, 4) 2 >>> igcd(5, 10, 15) 5 """ if len(args) < 2: raise TypeError( 'igcd() takes at least 2 arguments (%s given)' % len(args)) args_temp = [abs(as_int(i)) for i in args] if 1 in args_temp: return 1 a = args_temp.pop() for b in args_temp: a = igcd2(a, b) if b else a return a try: from math import gcd as igcd2 except ImportError: def igcd2(a, b): """Compute gcd of two Python integers a and b.""" if (a.bit_length() > BIGBITS and b.bit_length() > BIGBITS): return igcd_lehmer(a, b) a, b = abs(a), abs(b) while b: a, b = b, a % b return a # Use Lehmer's algorithm only for very large numbers. # The limit could be different on Python 2.7 and 3.x. # If so, then this could be defined in compatibility.py. BIGBITS = 5000 def igcd_lehmer(a, b): """Computes greatest common divisor of two integers. Euclid's algorithm for the computation of the greatest common divisor gcd(a, b) of two (positive) integers a and b is based on the division identity a = q*b + r, where the quotient q and the remainder r are integers and 0 <= r < b. Then each common divisor of a and b divides r, and it follows that gcd(a, b) == gcd(b, r). The algorithm works by constructing the sequence r0, r1, r2, ..., where r0 = a, r1 = b, and each rn is the remainder from the division of the two preceding elements. In Python, q = a // b and r = a % b are obtained by the floor division and the remainder operations, respectively. These are the most expensive arithmetic operations, especially for large a and b. Lehmer's algorithm is based on the observation that the quotients qn = r(n-1) // rn are in general small integers even when a and b are very large. Hence the quotients can be usually determined from a relatively small number of most significant bits. The efficiency of the algorithm is further enhanced by not computing each long remainder in Euclid's sequence. The remainders are linear combinations of a and b with integer coefficients derived from the quotients. The coefficients can be computed as far as the quotients can be determined from the chosen most significant parts of a and b. Only then a new pair of consecutive remainders is computed and the algorithm starts anew with this pair. References ========== .. [1] https://en.wikipedia.org/wiki/Lehmer%27s_GCD_algorithm """ a, b = abs(as_int(a)), abs(as_int(b)) if a < b: a, b = b, a # The algorithm works by using one or two digit division # whenever possible. The outer loop will replace the # pair (a, b) with a pair of shorter consecutive elements # of the Euclidean gcd sequence until a and b # fit into two Python (long) int digits. nbits = 2*int_info.bits_per_digit while a.bit_length() > nbits and b != 0: # Quotients are mostly small integers that can # be determined from most significant bits. n = a.bit_length() - nbits x, y = int(a >> n), int(b >> n) # most significant bits # Elements of the Euclidean gcd sequence are linear # combinations of a and b with integer coefficients. # Compute the coefficients of consecutive pairs # a' = A*a + B*b, b' = C*a + D*b # using small integer arithmetic as far as possible. A, B, C, D = 1, 0, 0, 1 # initial values while True: # The coefficients alternate in sign while looping. # The inner loop combines two steps to keep track # of the signs. # At this point we have # A > 0, B <= 0, C <= 0, D > 0, # x' = x + B <= x < x" = x + A, # y' = y + C <= y < y" = y + D, # and # x'*N <= a' < x"*N, y'*N <= b' < y"*N, # where N = 2**n. # Now, if y' > 0, and x"//y' and x'//y" agree, # then their common value is equal to q = a'//b'. # In addition, # x'%y" = x' - q*y" < x" - q*y' = x"%y', # and # (x'%y")*N < a'%b' < (x"%y')*N. # On the other hand, we also have x//y == q, # and therefore # x'%y" = x + B - q*(y + D) = x%y + B', # x"%y' = x + A - q*(y + C) = x%y + A', # where # B' = B - q*D < 0, A' = A - q*C > 0. if y + C <= 0: break q = (x + A) // (y + C) # Now x'//y" <= q, and equality holds if # x' - q*y" = (x - q*y) + (B - q*D) >= 0. # This is a minor optimization to avoid division. x_qy, B_qD = x - q*y, B - q*D if x_qy + B_qD < 0: break # Next step in the Euclidean sequence. x, y = y, x_qy A, B, C, D = C, D, A - q*C, B_qD # At this point the signs of the coefficients # change and their roles are interchanged. # A <= 0, B > 0, C > 0, D < 0, # x' = x + A <= x < x" = x + B, # y' = y + D < y < y" = y + C. if y + D <= 0: break q = (x + B) // (y + D) x_qy, A_qC = x - q*y, A - q*C if x_qy + A_qC < 0: break x, y = y, x_qy A, B, C, D = C, D, A_qC, B - q*D # Now the conditions on top of the loop # are again satisfied. # A > 0, B < 0, C < 0, D > 0. if B == 0: # This can only happen when y == 0 in the beginning # and the inner loop does nothing. # Long division is forced. a, b = b, a % b continue # Compute new long arguments using the coefficients. a, b = A*a + B*b, C*a + D*b # Small divisors. Finish with the standard algorithm. while b: a, b = b, a % b return a def ilcm(*args): """Computes integer least common multiple. Examples ======== >>> from sympy.core.numbers import ilcm >>> ilcm(5, 10) 10 >>> ilcm(7, 3) 21 >>> ilcm(5, 10, 15) 30 """ if len(args) < 2: raise TypeError( 'ilcm() takes at least 2 arguments (%s given)' % len(args)) if 0 in args: return 0 a = args[0] for b in args[1:]: a = a // igcd(a, b) * b # since gcd(a,b) | a return a def igcdex(a, b): """Returns x, y, g such that g = x*a + y*b = gcd(a, b). >>> from sympy.core.numbers import igcdex >>> igcdex(2, 3) (-1, 1, 1) >>> igcdex(10, 12) (-1, 1, 2) >>> x, y, g = igcdex(100, 2004) >>> x, y, g (-20, 1, 4) >>> x*100 + y*2004 4 """ if (not a) and (not b): return (0, 1, 0) if not a: return (0, b//abs(b), abs(b)) if not b: return (a//abs(a), 0, abs(a)) if a < 0: a, x_sign = -a, -1 else: x_sign = 1 if b < 0: b, y_sign = -b, -1 else: y_sign = 1 x, y, r, s = 1, 0, 0, 1 while b: (c, q) = (a % b, a // b) (a, b, r, s, x, y) = (b, c, x - q*r, y - q*s, r, s) return (x*x_sign, y*y_sign, a) def mod_inverse(a, m): """ Return the number c such that, (a * c) = 1 (mod m) where c has the same sign as m. If no such value exists, a ValueError is raised. Examples ======== >>> from sympy import S >>> from sympy.core.numbers import mod_inverse Suppose we wish to find multiplicative inverse x of 3 modulo 11. This is the same as finding x such that 3 * x = 1 (mod 11). One value of x that satisfies this congruence is 4. Because 3 * 4 = 12 and 12 = 1 (mod 11). This is the value return by mod_inverse: >>> mod_inverse(3, 11) 4 >>> mod_inverse(-3, 11) 7 When there is a common factor between the numerators of ``a`` and ``m`` the inverse does not exist: >>> mod_inverse(2, 4) Traceback (most recent call last): ... ValueError: inverse of 2 mod 4 does not exist >>> mod_inverse(S(2)/7, S(5)/2) 7/2 References ========== - https://en.wikipedia.org/wiki/Modular_multiplicative_inverse - https://en.wikipedia.org/wiki/Extended_Euclidean_algorithm """ c = None try: a, m = as_int(a), as_int(m) if m != 1 and m != -1: x, y, g = igcdex(a, m) if g == 1: c = x % m except ValueError: a, m = sympify(a), sympify(m) if not (a.is_number and m.is_number): raise TypeError(filldedent(''' Expected numbers for arguments; symbolic `mod_inverse` is not implemented but symbolic expressions can be handled with the similar function, sympy.polys.polytools.invert''')) big = (m > 1) if not (big is S.true or big is S.false): raise ValueError('m > 1 did not evaluate; try to simplify %s' % m) elif big: c = 1/a if c is None: raise ValueError('inverse of %s (mod %s) does not exist' % (a, m)) return c class Number(AtomicExpr): """Represents atomic numbers in SymPy. Floating point numbers are represented by the Float class. Rational numbers (of any size) are represented by the Rational class. Integer numbers (of any size) are represented by the Integer class. Float and Rational are subclasses of Number; Integer is a subclass of Rational. For example, ``2/3`` is represented as ``Rational(2, 3)`` which is a different object from the floating point number obtained with Python division ``2/3``. Even for numbers that are exactly represented in binary, there is a difference between how two forms, such as ``Rational(1, 2)`` and ``Float(0.5)``, are used in SymPy. The rational form is to be preferred in symbolic computations. Other kinds of numbers, such as algebraic numbers ``sqrt(2)`` or complex numbers ``3 + 4*I``, are not instances of Number class as they are not atomic. See Also ======== Float, Integer, Rational """ is_commutative = True is_number = True is_Number = True __slots__ = [] # Used to make max(x._prec, y._prec) return x._prec when only x is a float _prec = -1 def __new__(cls, *obj): if len(obj) == 1: obj = obj[0] if isinstance(obj, Number): return obj if isinstance(obj, SYMPY_INTS): return Integer(obj) if isinstance(obj, tuple) and len(obj) == 2: return Rational(*obj) if isinstance(obj, (float, mpmath.mpf, decimal.Decimal)): return Float(obj) if isinstance(obj, string_types): val = sympify(obj) if isinstance(val, Number): return val else: raise ValueError('String "%s" does not denote a Number' % obj) msg = "expected str|int|long|float|Decimal|Number object but got %r" raise TypeError(msg % type(obj).__name__) def invert(self, other, *gens, **args): from sympy.polys.polytools import invert if getattr(other, 'is_number', True): return mod_inverse(self, other) return invert(self, other, *gens, **args) def __divmod__(self, other): from .containers import Tuple try: other = Number(other) except TypeError: msg = "unsupported operand type(s) for divmod(): '%s' and '%s'" raise TypeError(msg % (type(self).__name__, type(other).__name__)) if not other: raise ZeroDivisionError('modulo by zero') if self.is_Integer and other.is_Integer: return Tuple(*divmod(self.p, other.p)) else: rat = self/other w = int(rat) if rat > 0 else int(rat) - 1 r = self - other*w return Tuple(w, r) def __rdivmod__(self, other): try: other = Number(other) except TypeError: msg = "unsupported operand type(s) for divmod(): '%s' and '%s'" raise TypeError(msg % (type(other).__name__, type(self).__name__)) return divmod(other, self) def _as_mpf_val(self, prec): """Evaluation of mpf tuple accurate to at least prec bits.""" raise NotImplementedError('%s needs ._as_mpf_val() method' % (self.__class__.__name__)) def _eval_evalf(self, prec): return Float._new(self._as_mpf_val(prec), prec) def _as_mpf_op(self, prec): prec = max(prec, self._prec) return self._as_mpf_val(prec), prec def __float__(self): return mlib.to_float(self._as_mpf_val(53)) def floor(self): raise NotImplementedError('%s needs .floor() method' % (self.__class__.__name__)) def ceiling(self): raise NotImplementedError('%s needs .ceiling() method' % (self.__class__.__name__)) def _eval_conjugate(self): return self def _eval_order(self, *symbols): from sympy import Order # Order(5, x, y) -> Order(1,x,y) return Order(S.One, *symbols) def _eval_subs(self, old, new): if old == -self: return -new return self # there is no other possibility def _eval_is_finite(self): return True @classmethod def class_key(cls): return 1, 0, 'Number' @cacheit def sort_key(self, order=None): return self.class_key(), (0, ()), (), self @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity: return S.Infinity elif other is S.NegativeInfinity: return S.NegativeInfinity return AtomicExpr.__add__(self, other) @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity: return S.NegativeInfinity elif other is S.NegativeInfinity: return S.Infinity return AtomicExpr.__sub__(self, other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity: if self.is_zero: return S.NaN elif self.is_positive: return S.Infinity else: return S.NegativeInfinity elif other is S.NegativeInfinity: if self.is_zero: return S.NaN elif self.is_positive: return S.NegativeInfinity else: return S.Infinity elif isinstance(other, Tuple): return NotImplemented return AtomicExpr.__mul__(self, other) @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number) and global_evaluate[0]: if other is S.NaN: return S.NaN elif other is S.Infinity or other is S.NegativeInfinity: return S.Zero return AtomicExpr.__div__(self, other) __truediv__ = __div__ def __eq__(self, other): raise NotImplementedError('%s needs .__eq__() method' % (self.__class__.__name__)) def __ne__(self, other): raise NotImplementedError('%s needs .__ne__() method' % (self.__class__.__name__)) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) raise NotImplementedError('%s needs .__lt__() method' % (self.__class__.__name__)) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) raise NotImplementedError('%s needs .__le__() method' % (self.__class__.__name__)) def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) return _sympify(other).__lt__(self) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) return _sympify(other).__le__(self) def __hash__(self): return super(Number, self).__hash__() def is_constant(self, *wrt, **flags): return True def as_coeff_mul(self, *deps, **kwargs): # a -> c*t if self.is_Rational or not kwargs.pop('rational', True): return self, tuple() elif self.is_negative: return S.NegativeOne, (-self,) return S.One, (self,) def as_coeff_add(self, *deps): # a -> c + t if self.is_Rational: return self, tuple() return S.Zero, (self,) def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ if rational and not self.is_Rational: return S.One, self return (self, S.One) if self else (S.One, self) def as_coeff_Add(self, rational=False): """Efficiently extract the coefficient of a summation. """ if not rational: return self, S.Zero return S.Zero, self def gcd(self, other): """Compute GCD of `self` and `other`. """ from sympy.polys import gcd return gcd(self, other) def lcm(self, other): """Compute LCM of `self` and `other`. """ from sympy.polys import lcm return lcm(self, other) def cofactors(self, other): """Compute GCD and cofactors of `self` and `other`. """ from sympy.polys import cofactors return cofactors(self, other) class Float(Number): """Represent a floating-point number of arbitrary precision. Examples ======== >>> from sympy import Float >>> Float(3.5) 3.50000000000000 >>> Float(3) 3.00000000000000 Creating Floats from strings (and Python ``int`` and ``long`` types) will give a minimum precision of 15 digits, but the precision will automatically increase to capture all digits entered. >>> Float(1) 1.00000000000000 >>> Float(10**20) 100000000000000000000. >>> Float('1e20') 100000000000000000000. However, *floating-point* numbers (Python ``float`` types) retain only 15 digits of precision: >>> Float(1e20) 1.00000000000000e+20 >>> Float(1.23456789123456789) 1.23456789123457 It may be preferable to enter high-precision decimal numbers as strings: Float('1.23456789123456789') 1.23456789123456789 The desired number of digits can also be specified: >>> Float('1e-3', 3) 0.00100 >>> Float(100, 4) 100.0 Float can automatically count significant figures if a null string is sent for the precision; spaces or underscores are also allowed. (Auto- counting is only allowed for strings, ints and longs). >>> Float('123 456 789.123_456', '') 123456789.123456 >>> Float('12e-3', '') 0.012 >>> Float(3, '') 3. If a number is written in scientific notation, only the digits before the exponent are considered significant if a decimal appears, otherwise the "e" signifies only how to move the decimal: >>> Float('60.e2', '') # 2 digits significant 6.0e+3 >>> Float('60e2', '') # 4 digits significant 6000. >>> Float('600e-2', '') # 3 digits significant 6.00 Notes ===== Floats are inexact by their nature unless their value is a binary-exact value. >>> approx, exact = Float(.1, 1), Float(.125, 1) For calculation purposes, evalf needs to be able to change the precision but this will not increase the accuracy of the inexact value. The following is the most accurate 5-digit approximation of a value of 0.1 that had only 1 digit of precision: >>> approx.evalf(5) 0.099609 By contrast, 0.125 is exact in binary (as it is in base 10) and so it can be passed to Float or evalf to obtain an arbitrary precision with matching accuracy: >>> Float(exact, 5) 0.12500 >>> exact.evalf(20) 0.12500000000000000000 Trying to make a high-precision Float from a float is not disallowed, but one must keep in mind that the *underlying float* (not the apparent decimal value) is being obtained with high precision. For example, 0.3 does not have a finite binary representation. The closest rational is the fraction 5404319552844595/2**54. So if you try to obtain a Float of 0.3 to 20 digits of precision you will not see the same thing as 0.3 followed by 19 zeros: >>> Float(0.3, 20) 0.29999999999999998890 If you want a 20-digit value of the decimal 0.3 (not the floating point approximation of 0.3) you should send the 0.3 as a string. The underlying representation is still binary but a higher precision than Python's float is used: >>> Float('0.3', 20) 0.30000000000000000000 Although you can increase the precision of an existing Float using Float it will not increase the accuracy -- the underlying value is not changed: >>> def show(f): # binary rep of Float ... from sympy import Mul, Pow ... s, m, e, b = f._mpf_ ... v = Mul(int(m), Pow(2, int(e), evaluate=False), evaluate=False) ... print('%s at prec=%s' % (v, f._prec)) ... >>> t = Float('0.3', 3) >>> show(t) 4915/2**14 at prec=13 >>> show(Float(t, 20)) # higher prec, not higher accuracy 4915/2**14 at prec=70 >>> show(Float(t, 2)) # lower prec 307/2**10 at prec=10 The same thing happens when evalf is used on a Float: >>> show(t.evalf(20)) 4915/2**14 at prec=70 >>> show(t.evalf(2)) 307/2**10 at prec=10 Finally, Floats can be instantiated with an mpf tuple (n, c, p) to produce the number (-1)**n*c*2**p: >>> n, c, p = 1, 5, 0 >>> (-1)**n*c*2**p -5 >>> Float((1, 5, 0)) -5.00000000000000 An actual mpf tuple also contains the number of bits in c as the last element of the tuple: >>> _._mpf_ (1, 5, 0, 3) This is not needed for instantiation and is not the same thing as the precision. The mpf tuple and the precision are two separate quantities that Float tracks. """ __slots__ = ['_mpf_', '_prec'] # A Float represents many real numbers, # both rational and irrational. is_rational = None is_irrational = None is_number = True is_real = True is_Float = True def __new__(cls, num, dps=None, prec=None, precision=None): if prec is not None: SymPyDeprecationWarning( feature="Using 'prec=XX' to denote decimal precision", useinstead="'dps=XX' for decimal precision and 'precision=XX' "\ "for binary precision", issue=12820, deprecated_since_version="1.1").warn() dps = prec del prec # avoid using this deprecated kwarg if dps is not None and precision is not None: raise ValueError('Both decimal and binary precision supplied. ' 'Supply only one. ') if isinstance(num, string_types): # Float already accepts spaces as digit separators; in Py 3.6 # underscores are allowed. In anticipation of that, we ignore # legally placed underscores num = num.replace(' ', '') if '_' in num: if num.startswith('_') or num.endswith('_') or any( i in num for i in ('__', '_.', '._')): # copy Py 3.6 error raise ValueError("could not convert string to float: '%s'" % num) num = num.replace('_', '') if num.startswith('.') and len(num) > 1: num = '0' + num elif num.startswith('-.') and len(num) > 2: num = '-0.' + num[2:] elif num == 'inf' or num == '+inf': return S.Infinity elif num == '-inf': return S.NegativeInfinity elif isinstance(num, float) and num == 0: num = '0' elif isinstance(num, float) and num == float('inf'): return S.Infinity elif isinstance(num, float) and num == float('-inf'): return S.NegativeInfinity elif isinstance(num, (SYMPY_INTS, Integer)): num = str(num) # faster than mlib.from_int elif num is S.Infinity: return num elif num is S.NegativeInfinity: return num elif type(num).__module__ == 'numpy': # support for numpy datatypes num = _convert_numpy_types(num) elif isinstance(num, mpmath.mpf): if precision is None: if dps is None: precision = num.context.prec num = num._mpf_ if dps is None and precision is None: dps = 15 if isinstance(num, Float): return num if isinstance(num, string_types) and _literal_float(num): try: Num = decimal.Decimal(num) except decimal.InvalidOperation: pass else: isint = '.' not in num num, dps = _decimal_to_Rational_prec(Num) if num.is_Integer and isint: dps = max(dps, len(str(num).lstrip('-'))) dps = max(15, dps) precision = mlib.libmpf.dps_to_prec(dps) elif precision == '' and dps is None or precision is None and dps == '': if not isinstance(num, string_types): raise ValueError('The null string can only be used when ' 'the number to Float is passed as a string or an integer.') ok = None if _literal_float(num): try: Num = decimal.Decimal(num) except decimal.InvalidOperation: pass else: isint = '.' not in num num, dps = _decimal_to_Rational_prec(Num) if num.is_Integer and isint: dps = max(dps, len(str(num).lstrip('-'))) precision = mlib.libmpf.dps_to_prec(dps) ok = True if ok is None: raise ValueError('string-float not recognized: %s' % num) # decimal precision(dps) is set and maybe binary precision(precision) # as well.From here on binary precision is used to compute the Float. # Hence, if supplied use binary precision else translate from decimal # precision. if precision is None or precision == '': precision = mlib.libmpf.dps_to_prec(dps) precision = int(precision) if isinstance(num, float): _mpf_ = mlib.from_float(num, precision, rnd) elif isinstance(num, string_types): _mpf_ = mlib.from_str(num, precision, rnd) elif isinstance(num, decimal.Decimal): if num.is_finite(): _mpf_ = mlib.from_str(str(num), precision, rnd) elif num.is_nan(): return S.NaN elif num.is_infinite(): if num > 0: return S.Infinity else: return S.NegativeInfinity else: raise ValueError("unexpected decimal value %s" % str(num)) elif isinstance(num, tuple) and len(num) in (3, 4): if type(num[1]) is str: # it's a hexadecimal (coming from a pickled object) # assume that it is in standard form num = list(num) # If we're loading an object pickled in Python 2 into # Python 3, we may need to strip a tailing 'L' because # of a shim for int on Python 3, see issue #13470. if num[1].endswith('L'): num[1] = num[1][:-1] num[1] = MPZ(num[1], 16) _mpf_ = tuple(num) else: if len(num) == 4: # handle normalization hack return Float._new(num, precision) else: return (S.NegativeOne**num[0]*num[1]*S(2)**num[2]).evalf(precision) else: try: _mpf_ = num._as_mpf_val(precision) except (NotImplementedError, AttributeError): _mpf_ = mpmath.mpf(num, prec=precision)._mpf_ # special cases if _mpf_ == _mpf_zero: pass # we want a Float elif _mpf_ == _mpf_nan: return S.NaN elif _mpf_ == _mpf_inf: return S.Infinity elif _mpf_ == _mpf_ninf: return S.NegativeInfinity obj = Expr.__new__(cls) obj._mpf_ = _mpf_ obj._prec = precision return obj @classmethod def _new(cls, _mpf_, _prec): # special cases if _mpf_ == _mpf_zero: return S.Zero # XXX this is different from Float which gives 0.0 elif _mpf_ == _mpf_nan: return S.NaN elif _mpf_ == _mpf_inf: return S.Infinity elif _mpf_ == _mpf_ninf: return S.NegativeInfinity obj = Expr.__new__(cls) obj._mpf_ = mpf_norm(_mpf_, _prec) # XXX: Should this be obj._prec = obj._mpf_[3]? obj._prec = _prec return obj # mpz can't be pickled def __getnewargs__(self): return (mlib.to_pickable(self._mpf_),) def __getstate__(self): return {'_prec': self._prec} def _hashable_content(self): return (self._mpf_, self._prec) def floor(self): return Integer(int(mlib.to_int( mlib.mpf_floor(self._mpf_, self._prec)))) def ceiling(self): return Integer(int(mlib.to_int( mlib.mpf_ceil(self._mpf_, self._prec)))) @property def num(self): return mpmath.mpf(self._mpf_) def _as_mpf_val(self, prec): rv = mpf_norm(self._mpf_, prec) if rv != self._mpf_ and self._prec == prec: debug(self._mpf_, rv) return rv def _as_mpf_op(self, prec): return self._mpf_, max(prec, self._prec) def _eval_is_finite(self): if self._mpf_ in (_mpf_inf, _mpf_ninf): return False return True def _eval_is_infinite(self): if self._mpf_ in (_mpf_inf, _mpf_ninf): return True return False def _eval_is_integer(self): return self._mpf_ == _mpf_zero def _eval_is_negative(self): if self._mpf_ == _mpf_ninf: return True if self._mpf_ == _mpf_inf: return False return self.num < 0 def _eval_is_positive(self): if self._mpf_ == _mpf_inf: return True if self._mpf_ == _mpf_ninf: return False return self.num > 0 def _eval_is_zero(self): return self._mpf_ == _mpf_zero def __nonzero__(self): return self._mpf_ != _mpf_zero __bool__ = __nonzero__ def __neg__(self): return Float._new(mlib.mpf_neg(self._mpf_), self._prec) @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_add(self._mpf_, rhs, prec, rnd), prec) return Number.__add__(self, other) @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_sub(self._mpf_, rhs, prec, rnd), prec) return Number.__sub__(self, other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_mul(self._mpf_, rhs, prec, rnd), prec) return Number.__mul__(self, other) @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number) and other != 0 and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_div(self._mpf_, rhs, prec, rnd), prec) return Number.__div__(self, other) __truediv__ = __div__ @_sympifyit('other', NotImplemented) def __mod__(self, other): if isinstance(other, Rational) and other.q != 1 and global_evaluate[0]: # calculate mod with Rationals, *then* round the result return Float(Rational.__mod__(Rational(self), other), precision=self._prec) if isinstance(other, Float) and global_evaluate[0]: r = self/other if r == int(r): return Float(0, precision=max(self._prec, other._prec)) if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_mod(self._mpf_, rhs, prec, rnd), prec) return Number.__mod__(self, other) @_sympifyit('other', NotImplemented) def __rmod__(self, other): if isinstance(other, Float) and global_evaluate[0]: return other.__mod__(self) if isinstance(other, Number) and global_evaluate[0]: rhs, prec = other._as_mpf_op(self._prec) return Float._new(mlib.mpf_mod(rhs, self._mpf_, prec, rnd), prec) return Number.__rmod__(self, other) def _eval_power(self, expt): """ expt is symbolic object but not equal to 0, 1 (-p)**r -> exp(r*log(-p)) -> exp(r*(log(p) + I*Pi)) -> -> p**r*(sin(Pi*r) + cos(Pi*r)*I) """ if self == 0: if expt.is_positive: return S.Zero if expt.is_negative: return S.Infinity if isinstance(expt, Number): if isinstance(expt, Integer): prec = self._prec return Float._new( mlib.mpf_pow_int(self._mpf_, expt.p, prec, rnd), prec) elif isinstance(expt, Rational) and \ expt.p == 1 and expt.q % 2 and self.is_negative: return Pow(S.NegativeOne, expt, evaluate=False)*( -self)._eval_power(expt) expt, prec = expt._as_mpf_op(self._prec) mpfself = self._mpf_ try: y = mpf_pow(mpfself, expt, prec, rnd) return Float._new(y, prec) except mlib.ComplexResult: re, im = mlib.mpc_pow( (mpfself, _mpf_zero), (expt, _mpf_zero), prec, rnd) return Float._new(re, prec) + \ Float._new(im, prec)*S.ImaginaryUnit def __abs__(self): return Float._new(mlib.mpf_abs(self._mpf_), self._prec) def __int__(self): if self._mpf_ == _mpf_zero: return 0 return int(mlib.to_int(self._mpf_)) # uses round_fast = round_down __long__ = __int__ def __eq__(self, other): if isinstance(other, float): # coerce to Float at same precision o = Float(other) try: ompf = o._as_mpf_val(self._prec) except ValueError: return False return bool(mlib.mpf_eq(self._mpf_, ompf)) try: other = _sympify(other) except SympifyError: return NotImplemented if other.is_NumberSymbol: if other.is_irrational: return False return other.__eq__(self) if other.is_Float: return bool(mlib.mpf_eq(self._mpf_, other._mpf_)) if other.is_Number: # numbers should compare at the same precision; # all _as_mpf_val routines should be sure to abide # by the request to change the prec if necessary; if # they don't, the equality test will fail since it compares # the mpf tuples ompf = other._as_mpf_val(self._prec) return bool(mlib.mpf_eq(self._mpf_, ompf)) return False # Float != non-Number def __ne__(self, other): return not self == other def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_NumberSymbol: return other.__lt__(self) if other.is_Rational and not other.is_Integer: self *= other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_gt(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__gt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_NumberSymbol: return other.__le__(self) if other.is_Rational and not other.is_Integer: self *= other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_ge(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__ge__(self, other) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_NumberSymbol: return other.__gt__(self) if other.is_Rational and not other.is_Integer: self *= other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_lt(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__lt__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_NumberSymbol: return other.__ge__(self) if other.is_Rational and not other.is_Integer: self *= other.q other = _sympify(other.p) elif other.is_comparable: other = other.evalf() if other.is_Number and other is not S.NaN: return _sympify(bool( mlib.mpf_le(self._mpf_, other._as_mpf_val(self._prec)))) return Expr.__le__(self, other) def __hash__(self): return super(Float, self).__hash__() def epsilon_eq(self, other, epsilon="1e-15"): return abs(self - other) < Float(epsilon) def _sage_(self): import sage.all as sage return sage.RealNumber(str(self)) def __format__(self, format_spec): return format(decimal.Decimal(str(self)), format_spec) # Add sympify converters converter[float] = converter[decimal.Decimal] = Float # this is here to work nicely in Sage RealNumber = Float class Rational(Number): """Represents rational numbers (p/q) of any size. Examples ======== >>> from sympy import Rational, nsimplify, S, pi >>> Rational(1, 2) 1/2 Rational is unprejudiced in accepting input. If a float is passed, the underlying value of the binary representation will be returned: >>> Rational(.5) 1/2 >>> Rational(.2) 3602879701896397/18014398509481984 If the simpler representation of the float is desired then consider limiting the denominator to the desired value or convert the float to a string (which is roughly equivalent to limiting the denominator to 10**12): >>> Rational(str(.2)) 1/5 >>> Rational(.2).limit_denominator(10**12) 1/5 An arbitrarily precise Rational is obtained when a string literal is passed: >>> Rational("1.23") 123/100 >>> Rational('1e-2') 1/100 >>> Rational(".1") 1/10 >>> Rational('1e-2/3.2') 1/320 The conversion of other types of strings can be handled by the sympify() function, and conversion of floats to expressions or simple fractions can be handled with nsimplify: >>> S('.[3]') # repeating digits in brackets 1/3 >>> S('3**2/10') # general expressions 9/10 >>> nsimplify(.3) # numbers that have a simple form 3/10 But if the input does not reduce to a literal Rational, an error will be raised: >>> Rational(pi) Traceback (most recent call last): ... TypeError: invalid input: pi Low-level --------- Access numerator and denominator as .p and .q: >>> r = Rational(3, 4) >>> r 3/4 >>> r.p 3 >>> r.q 4 Note that p and q return integers (not SymPy Integers) so some care is needed when using them in expressions: >>> r.p/r.q 0.75 See Also ======== sympify, sympy.simplify.simplify.nsimplify """ is_real = True is_integer = False is_rational = True is_number = True __slots__ = ['p', 'q'] is_Rational = True @cacheit def __new__(cls, p, q=None, gcd=None): if q is None: if isinstance(p, Rational): return p if isinstance(p, SYMPY_INTS): pass else: if isinstance(p, (float, Float)): return Rational(*_as_integer_ratio(p)) if not isinstance(p, string_types): try: p = sympify(p) except (SympifyError, SyntaxError): pass # error will raise below else: if p.count('/') > 1: raise TypeError('invalid input: %s' % p) p = p.replace(' ', '') pq = p.rsplit('/', 1) if len(pq) == 2: p, q = pq fp = fractions.Fraction(p) fq = fractions.Fraction(q) p = fp/fq try: p = fractions.Fraction(p) except ValueError: pass # error will raise below else: return Rational(p.numerator, p.denominator, 1) if not isinstance(p, Rational): raise TypeError('invalid input: %s' % p) q = 1 gcd = 1 else: p = Rational(p) q = Rational(q) if isinstance(q, Rational): p *= q.q q = q.p if isinstance(p, Rational): q *= p.q p = p.p # p and q are now integers if q == 0: if p == 0: if _errdict["divide"]: raise ValueError("Indeterminate 0/0") else: return S.NaN return S.ComplexInfinity if q < 0: q = -q p = -p if not gcd: gcd = igcd(abs(p), q) if gcd > 1: p //= gcd q //= gcd if q == 1: return Integer(p) if p == 1 and q == 2: return S.Half obj = Expr.__new__(cls) obj.p = p obj.q = q return obj def limit_denominator(self, max_denominator=1000000): """Closest Rational to self with denominator at most max_denominator. >>> from sympy import Rational >>> Rational('3.141592653589793').limit_denominator(10) 22/7 >>> Rational('3.141592653589793').limit_denominator(100) 311/99 """ f = fractions.Fraction(self.p, self.q) return Rational(f.limit_denominator(fractions.Fraction(int(max_denominator)))) def __getnewargs__(self): return (self.p, self.q) def _hashable_content(self): return (self.p, self.q) def _eval_is_positive(self): return self.p > 0 def _eval_is_zero(self): return self.p == 0 def __neg__(self): return Rational(-self.p, self.q) @_sympifyit('other', NotImplemented) def __add__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.p + self.q*other.p, self.q, 1) elif isinstance(other, Rational): #TODO: this can probably be optimized more return Rational(self.p*other.q + self.q*other.p, self.q*other.q) elif isinstance(other, Float): return other + self else: return Number.__add__(self, other) return Number.__add__(self, other) __radd__ = __add__ @_sympifyit('other', NotImplemented) def __sub__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.p - self.q*other.p, self.q, 1) elif isinstance(other, Rational): return Rational(self.p*other.q - self.q*other.p, self.q*other.q) elif isinstance(other, Float): return -other + self else: return Number.__sub__(self, other) return Number.__sub__(self, other) @_sympifyit('other', NotImplemented) def __rsub__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.q*other.p - self.p, self.q, 1) elif isinstance(other, Rational): return Rational(self.q*other.p - self.p*other.q, self.q*other.q) elif isinstance(other, Float): return -self + other else: return Number.__rsub__(self, other) return Number.__rsub__(self, other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(self.p*other.p, self.q, igcd(other.p, self.q)) elif isinstance(other, Rational): return Rational(self.p*other.p, self.q*other.q, igcd(self.p, other.q)*igcd(self.q, other.p)) elif isinstance(other, Float): return other*self else: return Number.__mul__(self, other) return Number.__mul__(self, other) __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if global_evaluate[0]: if isinstance(other, Integer): if self.p and other.p == S.Zero: return S.ComplexInfinity else: return Rational(self.p, self.q*other.p, igcd(self.p, other.p)) elif isinstance(other, Rational): return Rational(self.p*other.q, self.q*other.p, igcd(self.p, other.p)*igcd(self.q, other.q)) elif isinstance(other, Float): return self*(1/other) else: return Number.__div__(self, other) return Number.__div__(self, other) @_sympifyit('other', NotImplemented) def __rdiv__(self, other): if global_evaluate[0]: if isinstance(other, Integer): return Rational(other.p*self.q, self.p, igcd(self.p, other.p)) elif isinstance(other, Rational): return Rational(other.p*self.q, other.q*self.p, igcd(self.p, other.p)*igcd(self.q, other.q)) elif isinstance(other, Float): return other*(1/self) else: return Number.__rdiv__(self, other) return Number.__rdiv__(self, other) __truediv__ = __div__ @_sympifyit('other', NotImplemented) def __mod__(self, other): if global_evaluate[0]: if isinstance(other, Rational): n = (self.p*other.q) // (other.p*self.q) return Rational(self.p*other.q - n*other.p*self.q, self.q*other.q) if isinstance(other, Float): # calculate mod with Rationals, *then* round the answer return Float(self.__mod__(Rational(other)), precision=other._prec) return Number.__mod__(self, other) return Number.__mod__(self, other) @_sympifyit('other', NotImplemented) def __rmod__(self, other): if isinstance(other, Rational): return Rational.__mod__(other, self) return Number.__rmod__(self, other) def _eval_power(self, expt): if isinstance(expt, Number): if isinstance(expt, Float): return self._eval_evalf(expt._prec)**expt if expt.is_negative: # (3/4)**-2 -> (4/3)**2 ne = -expt if (ne is S.One): return Rational(self.q, self.p) if self.is_negative: return S.NegativeOne**expt*Rational(self.q, -self.p)**ne else: return Rational(self.q, self.p)**ne if expt is S.Infinity: # -oo already caught by test for negative if self.p > self.q: # (3/2)**oo -> oo return S.Infinity if self.p < -self.q: # (-3/2)**oo -> oo + I*oo return S.Infinity + S.Infinity*S.ImaginaryUnit return S.Zero if isinstance(expt, Integer): # (4/3)**2 -> 4**2 / 3**2 return Rational(self.p**expt.p, self.q**expt.p, 1) if isinstance(expt, Rational): if self.p != 1: # (4/3)**(5/6) -> 4**(5/6)*3**(-5/6) return Integer(self.p)**expt*Integer(self.q)**(-expt) # as the above caught negative self.p, now self is positive return Integer(self.q)**Rational( expt.p*(expt.q - 1), expt.q) / \ Integer(self.q)**Integer(expt.p) if self.is_negative and expt.is_even: return (-self)**expt return def _as_mpf_val(self, prec): return mlib.from_rational(self.p, self.q, prec, rnd) def _mpmath_(self, prec, rnd): return mpmath.make_mpf(mlib.from_rational(self.p, self.q, prec, rnd)) def __abs__(self): return Rational(abs(self.p), self.q) def __int__(self): p, q = self.p, self.q if p < 0: return -int(-p//q) return int(p//q) __long__ = __int__ def floor(self): return Integer(self.p // self.q) def ceiling(self): return -Integer(-self.p // self.q) def __eq__(self, other): try: other = _sympify(other) except SympifyError: return NotImplemented if other.is_NumberSymbol: if other.is_irrational: return False return other.__eq__(self) if other.is_Number: if other.is_Rational: # a Rational is always in reduced form so will never be 2/4 # so we can just check equivalence of args return self.p == other.p and self.q == other.q if other.is_Float: return mlib.mpf_eq(self._as_mpf_val(other._prec), other._mpf_) return False def __ne__(self, other): return not self == other def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_NumberSymbol: return other.__lt__(self) expr = self if other.is_Number: if other.is_Rational: return _sympify(bool(self.p*other.q > self.q*other.p)) if other.is_Float: return _sympify(bool(mlib.mpf_gt( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.q*other return Expr.__gt__(expr, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_NumberSymbol: return other.__le__(self) expr = self if other.is_Number: if other.is_Rational: return _sympify(bool(self.p*other.q >= self.q*other.p)) if other.is_Float: return _sympify(bool(mlib.mpf_ge( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.q*other return Expr.__ge__(expr, other) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_NumberSymbol: return other.__gt__(self) expr = self if other.is_Number: if other.is_Rational: return _sympify(bool(self.p*other.q < self.q*other.p)) if other.is_Float: return _sympify(bool(mlib.mpf_lt( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.q*other return Expr.__lt__(expr, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) expr = self if other.is_NumberSymbol: return other.__ge__(self) elif other.is_Number: if other.is_Rational: return _sympify(bool(self.p*other.q <= self.q*other.p)) if other.is_Float: return _sympify(bool(mlib.mpf_le( self._as_mpf_val(other._prec), other._mpf_))) elif other.is_number and other.is_real: expr, other = Integer(self.p), self.q*other return Expr.__le__(expr, other) def __hash__(self): return super(Rational, self).__hash__() def factors(self, limit=None, use_trial=True, use_rho=False, use_pm1=False, verbose=False, visual=False): """A wrapper to factorint which return factors of self that are smaller than limit (or cheap to compute). Special methods of factoring are disabled by default so that only trial division is used. """ from sympy.ntheory import factorrat return factorrat(self, limit=limit, use_trial=use_trial, use_rho=use_rho, use_pm1=use_pm1, verbose=verbose).copy() @_sympifyit('other', NotImplemented) def gcd(self, other): if isinstance(other, Rational): if other is S.Zero: return other return Rational( Integer(igcd(self.p, other.p)), Integer(ilcm(self.q, other.q))) return Number.gcd(self, other) @_sympifyit('other', NotImplemented) def lcm(self, other): if isinstance(other, Rational): return Rational( self.p // igcd(self.p, other.p) * other.p, igcd(self.q, other.q)) return Number.lcm(self, other) def as_numer_denom(self): return Integer(self.p), Integer(self.q) def _sage_(self): import sage.all as sage return sage.Integer(self.p)/sage.Integer(self.q) def as_content_primitive(self, radical=False, clear=True): """Return the tuple (R, self/R) where R is the positive Rational extracted from self. Examples ======== >>> from sympy import S >>> (S(-3)/2).as_content_primitive() (3/2, -1) See docstring of Expr.as_content_primitive for more examples. """ if self: if self.is_positive: return self, S.One return -self, S.NegativeOne return S.One, self def as_coeff_Mul(self, rational=False): """Efficiently extract the coefficient of a product. """ return self, S.One def as_coeff_Add(self, rational=False): """Efficiently extract the coefficient of a summation. """ return self, S.Zero class Integer(Rational): """Represents integer numbers of any size. Examples ======== >>> from sympy import Integer >>> Integer(3) 3 If a float or a rational is passed to Integer, the fractional part will be discarded; the effect is of rounding toward zero. >>> Integer(3.8) 3 >>> Integer(-3.8) -3 A string is acceptable input if it can be parsed as an integer: >>> Integer("9" * 20) 99999999999999999999 It is rarely needed to explicitly instantiate an Integer, because Python integers are automatically converted to Integer when they are used in SymPy expressions. """ q = 1 is_integer = True is_number = True is_Integer = True __slots__ = ['p'] def _as_mpf_val(self, prec): return mlib.from_int(self.p, prec, rnd) def _mpmath_(self, prec, rnd): return mpmath.make_mpf(self._as_mpf_val(prec)) @cacheit def __new__(cls, i): if isinstance(i, string_types): i = i.replace(' ', '') # whereas we cannot, in general, make a Rational from an # arbitrary expression, we can make an Integer unambiguously # (except when a non-integer expression happens to round to # an integer). So we proceed by taking int() of the input and # let the int routines determine whether the expression can # be made into an int or whether an error should be raised. try: ival = int(i) except TypeError: raise TypeError( "Argument of Integer should be of numeric type, got %s." % i) # We only work with well-behaved integer types. This converts, for # example, numpy.int32 instances. if ival == 1: return S.One if ival == -1: return S.NegativeOne if ival == 0: return S.Zero obj = Expr.__new__(cls) obj.p = ival return obj def __getnewargs__(self): return (self.p,) # Arithmetic operations are here for efficiency def __int__(self): return self.p __long__ = __int__ def floor(self): return Integer(self.p) def ceiling(self): return Integer(self.p) def __neg__(self): return Integer(-self.p) def __abs__(self): if self.p >= 0: return self else: return Integer(-self.p) def __divmod__(self, other): from .containers import Tuple if isinstance(other, Integer) and global_evaluate[0]: return Tuple(*(divmod(self.p, other.p))) else: return Number.__divmod__(self, other) def __rdivmod__(self, other): from .containers import Tuple if isinstance(other, integer_types) and global_evaluate[0]: return Tuple(*(divmod(other, self.p))) else: try: other = Number(other) except TypeError: msg = "unsupported operand type(s) for divmod(): '%s' and '%s'" oname = type(other).__name__ sname = type(self).__name__ raise TypeError(msg % (oname, sname)) return Number.__divmod__(other, self) # TODO make it decorator + bytecodehacks? def __add__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p + other) elif isinstance(other, Integer): return Integer(self.p + other.p) elif isinstance(other, Rational): return Rational(self.p*other.q + other.p, other.q, 1) return Rational.__add__(self, other) else: return Add(self, other) def __radd__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other + self.p) elif isinstance(other, Rational): return Rational(other.p + self.p*other.q, other.q, 1) return Rational.__radd__(self, other) return Rational.__radd__(self, other) def __sub__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p - other) elif isinstance(other, Integer): return Integer(self.p - other.p) elif isinstance(other, Rational): return Rational(self.p*other.q - other.p, other.q, 1) return Rational.__sub__(self, other) return Rational.__sub__(self, other) def __rsub__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other - self.p) elif isinstance(other, Rational): return Rational(other.p - self.p*other.q, other.q, 1) return Rational.__rsub__(self, other) return Rational.__rsub__(self, other) def __mul__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p*other) elif isinstance(other, Integer): return Integer(self.p*other.p) elif isinstance(other, Rational): return Rational(self.p*other.p, other.q, igcd(self.p, other.q)) return Rational.__mul__(self, other) return Rational.__mul__(self, other) def __rmul__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other*self.p) elif isinstance(other, Rational): return Rational(other.p*self.p, other.q, igcd(self.p, other.q)) return Rational.__rmul__(self, other) return Rational.__rmul__(self, other) def __mod__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(self.p % other) elif isinstance(other, Integer): return Integer(self.p % other.p) return Rational.__mod__(self, other) return Rational.__mod__(self, other) def __rmod__(self, other): if global_evaluate[0]: if isinstance(other, integer_types): return Integer(other % self.p) elif isinstance(other, Integer): return Integer(other.p % self.p) return Rational.__rmod__(self, other) return Rational.__rmod__(self, other) def __eq__(self, other): if isinstance(other, integer_types): return (self.p == other) elif isinstance(other, Integer): return (self.p == other.p) return Rational.__eq__(self, other) def __ne__(self, other): return not self == other def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_Integer: return _sympify(self.p > other.p) return Rational.__gt__(self, other) def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_Integer: return _sympify(self.p < other.p) return Rational.__lt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_Integer: return _sympify(self.p >= other.p) return Rational.__ge__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_Integer: return _sympify(self.p <= other.p) return Rational.__le__(self, other) def __hash__(self): return hash(self.p) def __index__(self): return self.p ######################################## def _eval_is_odd(self): return bool(self.p % 2) def _eval_power(self, expt): """ Tries to do some simplifications on self**expt Returns None if no further simplifications can be done When exponent is a fraction (so we have for example a square root), we try to find a simpler representation by factoring the argument up to factors of 2**15, e.g. - sqrt(4) becomes 2 - sqrt(-4) becomes 2*I - (2**(3+7)*3**(6+7))**Rational(1,7) becomes 6*18**(3/7) Further simplification would require a special call to factorint on the argument which is not done here for sake of speed. """ from sympy import perfect_power if expt is S.Infinity: if self.p > S.One: return S.Infinity # cases -1, 0, 1 are done in their respective classes return S.Infinity + S.ImaginaryUnit*S.Infinity if expt is S.NegativeInfinity: return Rational(1, self)**S.Infinity if not isinstance(expt, Number): # simplify when expt is even # (-2)**k --> 2**k if self.is_negative and expt.is_even: return (-self)**expt if isinstance(expt, Float): # Rational knows how to exponentiate by a Float return super(Integer, self)._eval_power(expt) if not isinstance(expt, Rational): return if expt is S.Half and self.is_negative: # we extract I for this special case since everyone is doing so return S.ImaginaryUnit*Pow(-self, expt) if expt.is_negative: # invert base and change sign on exponent ne = -expt if self.is_negative: return S.NegativeOne**expt*Rational(1, -self)**ne else: return Rational(1, self.p)**ne # see if base is a perfect root, sqrt(4) --> 2 x, xexact = integer_nthroot(abs(self.p), expt.q) if xexact: # if it's a perfect root we've finished result = Integer(x**abs(expt.p)) if self.is_negative: result *= S.NegativeOne**expt return result # The following is an algorithm where we collect perfect roots # from the factors of base. # if it's not an nth root, it still might be a perfect power b_pos = int(abs(self.p)) p = perfect_power(b_pos) if p is not False: dict = {p[0]: p[1]} else: dict = Integer(b_pos).factors(limit=2**15) # now process the dict of factors out_int = 1 # integer part out_rad = 1 # extracted radicals sqr_int = 1 sqr_gcd = 0 sqr_dict = {} for prime, exponent in dict.items(): exponent *= expt.p # remove multiples of expt.q: (2**12)**(1/10) -> 2*(2**2)**(1/10) div_e, div_m = divmod(exponent, expt.q) if div_e > 0: out_int *= prime**div_e if div_m > 0: # see if the reduced exponent shares a gcd with e.q # (2**2)**(1/10) -> 2**(1/5) g = igcd(div_m, expt.q) if g != 1: out_rad *= Pow(prime, Rational(div_m//g, expt.q//g)) else: sqr_dict[prime] = div_m # identify gcd of remaining powers for p, ex in sqr_dict.items(): if sqr_gcd == 0: sqr_gcd = ex else: sqr_gcd = igcd(sqr_gcd, ex) if sqr_gcd == 1: break for k, v in sqr_dict.items(): sqr_int *= k**(v//sqr_gcd) if sqr_int == b_pos and out_int == 1 and out_rad == 1: result = None else: result = out_int*out_rad*Pow(sqr_int, Rational(sqr_gcd, expt.q)) if self.is_negative: result *= Pow(S.NegativeOne, expt) return result def _eval_is_prime(self): from sympy.ntheory import isprime return isprime(self) def _eval_is_composite(self): if self > 1: return fuzzy_not(self.is_prime) else: return False def as_numer_denom(self): return self, S.One def __floordiv__(self, other): return Integer(self.p // Integer(other).p) def __rfloordiv__(self, other): return Integer(Integer(other).p // self.p) # Add sympify converters for i_type in integer_types: converter[i_type] = Integer class AlgebraicNumber(Expr): """Class for representing algebraic numbers in SymPy. """ __slots__ = ['rep', 'root', 'alias', 'minpoly'] is_AlgebraicNumber = True is_algebraic = True is_number = True def __new__(cls, expr, coeffs=None, alias=None, **args): """Construct a new algebraic number. """ from sympy import Poly from sympy.polys.polyclasses import ANP, DMP from sympy.polys.numberfields import minimal_polynomial from sympy.core.symbol import Symbol expr = sympify(expr) if isinstance(expr, (tuple, Tuple)): minpoly, root = expr if not minpoly.is_Poly: minpoly = Poly(minpoly) elif expr.is_AlgebraicNumber: minpoly, root = expr.minpoly, expr.root else: minpoly, root = minimal_polynomial( expr, args.get('gen'), polys=True), expr dom = minpoly.get_domain() if coeffs is not None: if not isinstance(coeffs, ANP): rep = DMP.from_sympy_list(sympify(coeffs), 0, dom) scoeffs = Tuple(*coeffs) else: rep = DMP.from_list(coeffs.to_list(), 0, dom) scoeffs = Tuple(*coeffs.to_list()) if rep.degree() >= minpoly.degree(): rep = rep.rem(minpoly.rep) else: rep = DMP.from_list([1, 0], 0, dom) scoeffs = Tuple(1, 0) sargs = (root, scoeffs) if alias is not None: if not isinstance(alias, Symbol): alias = Symbol(alias) sargs = sargs + (alias,) obj = Expr.__new__(cls, *sargs) obj.rep = rep obj.root = root obj.alias = alias obj.minpoly = minpoly return obj def __hash__(self): return super(AlgebraicNumber, self).__hash__() def _eval_evalf(self, prec): return self.as_expr()._evalf(prec) @property def is_aliased(self): """Returns ``True`` if ``alias`` was set. """ return self.alias is not None def as_poly(self, x=None): """Create a Poly instance from ``self``. """ from sympy import Dummy, Poly, PurePoly if x is not None: return Poly.new(self.rep, x) else: if self.alias is not None: return Poly.new(self.rep, self.alias) else: return PurePoly.new(self.rep, Dummy('x')) def as_expr(self, x=None): """Create a Basic expression from ``self``. """ return self.as_poly(x or self.root).as_expr().expand() def coeffs(self): """Returns all SymPy coefficients of an algebraic number. """ return [ self.rep.dom.to_sympy(c) for c in self.rep.all_coeffs() ] def native_coeffs(self): """Returns all native coefficients of an algebraic number. """ return self.rep.all_coeffs() def to_algebraic_integer(self): """Convert ``self`` to an algebraic integer. """ from sympy import Poly f = self.minpoly if f.LC() == 1: return self coeff = f.LC()**(f.degree() - 1) poly = f.compose(Poly(f.gen/f.LC())) minpoly = poly*coeff root = f.LC()*self.root return AlgebraicNumber((minpoly, root), self.coeffs()) def _eval_simplify(self, ratio, measure, rational, inverse): from sympy.polys import CRootOf, minpoly for r in [r for r in self.minpoly.all_roots() if r.func != CRootOf]: if minpoly(self.root - r).is_Symbol: # use the matching root if it's simpler if measure(r) < ratio*measure(self.root): return AlgebraicNumber(r) return self class RationalConstant(Rational): """ Abstract base class for rationals with specific behaviors Derived classes must define class attributes p and q and should probably all be singletons. """ __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) class IntegerConstant(Integer): __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) class Zero(with_metaclass(Singleton, IntegerConstant)): """The number zero. Zero is a singleton, and can be accessed by ``S.Zero`` Examples ======== >>> from sympy import S, Integer, zoo >>> Integer(0) is S.Zero True >>> 1/S.Zero zoo References ========== .. [1] https://en.wikipedia.org/wiki/Zero """ p = 0 q = 1 is_positive = False is_negative = False is_zero = True is_number = True __slots__ = [] @staticmethod def __abs__(): return S.Zero @staticmethod def __neg__(): return S.Zero def _eval_power(self, expt): if expt.is_positive: return self if expt.is_negative: return S.ComplexInfinity if expt.is_real is False: return S.NaN # infinities are already handled with pos and neg # tests above; now throw away leading numbers on Mul # exponent coeff, terms = expt.as_coeff_Mul() if coeff.is_negative: return S.ComplexInfinity**terms if coeff is not S.One: # there is a Number to discard return self**terms def _eval_order(self, *symbols): # Order(0,x) -> 0 return self def __nonzero__(self): return False __bool__ = __nonzero__ def as_coeff_Mul(self, rational=False): # XXX this routine should be deleted """Efficiently extract the coefficient of a summation. """ return S.One, self class One(with_metaclass(Singleton, IntegerConstant)): """The number one. One is a singleton, and can be accessed by ``S.One``. Examples ======== >>> from sympy import S, Integer >>> Integer(1) is S.One True References ========== .. [1] https://en.wikipedia.org/wiki/1_%28number%29 """ is_number = True p = 1 q = 1 __slots__ = [] @staticmethod def __abs__(): return S.One @staticmethod def __neg__(): return S.NegativeOne def _eval_power(self, expt): return self def _eval_order(self, *symbols): return @staticmethod def factors(limit=None, use_trial=True, use_rho=False, use_pm1=False, verbose=False, visual=False): if visual: return S.One else: return {} class NegativeOne(with_metaclass(Singleton, IntegerConstant)): """The number negative one. NegativeOne is a singleton, and can be accessed by ``S.NegativeOne``. Examples ======== >>> from sympy import S, Integer >>> Integer(-1) is S.NegativeOne True See Also ======== One References ========== .. [1] https://en.wikipedia.org/wiki/%E2%88%921_%28number%29 """ is_number = True p = -1 q = 1 __slots__ = [] @staticmethod def __abs__(): return S.One @staticmethod def __neg__(): return S.One def _eval_power(self, expt): if expt.is_odd: return S.NegativeOne if expt.is_even: return S.One if isinstance(expt, Number): if isinstance(expt, Float): return Float(-1.0)**expt if expt is S.NaN: return S.NaN if expt is S.Infinity or expt is S.NegativeInfinity: return S.NaN if expt is S.Half: return S.ImaginaryUnit if isinstance(expt, Rational): if expt.q == 2: return S.ImaginaryUnit**Integer(expt.p) i, r = divmod(expt.p, expt.q) if i: return self**i*self**Rational(r, expt.q) return class Half(with_metaclass(Singleton, RationalConstant)): """The rational number 1/2. Half is a singleton, and can be accessed by ``S.Half``. Examples ======== >>> from sympy import S, Rational >>> Rational(1, 2) is S.Half True References ========== .. [1] https://en.wikipedia.org/wiki/One_half """ is_number = True p = 1 q = 2 __slots__ = [] @staticmethod def __abs__(): return S.Half class Infinity(with_metaclass(Singleton, Number)): r"""Positive infinite quantity. In real analysis the symbol `\infty` denotes an unbounded limit: `x\to\infty` means that `x` grows without bound. Infinity is often used not only to define a limit but as a value in the affinely extended real number system. Points labeled `+\infty` and `-\infty` can be added to the topological space of the real numbers, producing the two-point compactification of the real numbers. Adding algebraic properties to this gives us the extended real numbers. Infinity is a singleton, and can be accessed by ``S.Infinity``, or can be imported as ``oo``. Examples ======== >>> from sympy import oo, exp, limit, Symbol >>> 1 + oo oo >>> 42/oo 0 >>> x = Symbol('x') >>> limit(exp(x), x, oo) oo See Also ======== NegativeInfinity, NaN References ========== .. [1] https://en.wikipedia.org/wiki/Infinity """ is_commutative = True is_positive = True is_infinite = True is_number = True is_prime = False __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"\infty" def _eval_subs(self, old, new): if self == old: return new @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number): if other is S.NegativeInfinity or other is S.NaN: return S.NaN return self return NotImplemented __radd__ = __add__ @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number): if other is S.Infinity or other is S.NaN: return S.NaN return self return NotImplemented @_sympifyit('other', NotImplemented) def __rsub__(self, other): return (-self).__add__(other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number): if other.is_zero or other is S.NaN: return S.NaN if other.is_positive: return self return S.NegativeInfinity return NotImplemented __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number): if other is S.Infinity or \ other is S.NegativeInfinity or \ other is S.NaN: return S.NaN if other.is_nonnegative: return self return S.NegativeInfinity return NotImplemented __truediv__ = __div__ def __abs__(self): return S.Infinity def __neg__(self): return S.NegativeInfinity def _eval_power(self, expt): """ ``expt`` is symbolic object but not equal to 0 or 1. ================ ======= ============================== Expression Result Notes ================ ======= ============================== ``oo ** nan`` ``nan`` ``oo ** -p`` ``0`` ``p`` is number, ``oo`` ================ ======= ============================== See Also ======== Pow NaN NegativeInfinity """ from sympy.functions import re if expt.is_positive: return S.Infinity if expt.is_negative: return S.Zero if expt is S.NaN: return S.NaN if expt is S.ComplexInfinity: return S.NaN if expt.is_real is False and expt.is_number: expt_real = re(expt) if expt_real.is_positive: return S.ComplexInfinity if expt_real.is_negative: return S.Zero if expt_real.is_zero: return S.NaN return self**expt.evalf() def _as_mpf_val(self, prec): return mlib.finf def _sage_(self): import sage.all as sage return sage.oo def __hash__(self): return super(Infinity, self).__hash__() def __eq__(self, other): return other is S.Infinity or other == float('inf') def __ne__(self, other): return other is not S.Infinity and other != float('inf') def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_real: return S.false return Expr.__lt__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_real: if other.is_finite or other is S.NegativeInfinity: return S.false elif other.is_nonpositive: return S.false elif other.is_infinite and other.is_positive: return S.true return Expr.__le__(self, other) def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_real: if other.is_finite or other is S.NegativeInfinity: return S.true elif other.is_nonpositive: return S.true elif other.is_infinite and other.is_positive: return S.false return Expr.__gt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_real: return S.true return Expr.__ge__(self, other) def __mod__(self, other): return S.NaN __rmod__ = __mod__ def floor(self): return self def ceiling(self): return self oo = S.Infinity class NegativeInfinity(with_metaclass(Singleton, Number)): """Negative infinite quantity. NegativeInfinity is a singleton, and can be accessed by ``S.NegativeInfinity``. See Also ======== Infinity """ is_commutative = True is_negative = True is_infinite = True is_number = True __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"-\infty" def _eval_subs(self, old, new): if self == old: return new @_sympifyit('other', NotImplemented) def __add__(self, other): if isinstance(other, Number): if other is S.Infinity or other is S.NaN: return S.NaN return self return NotImplemented __radd__ = __add__ @_sympifyit('other', NotImplemented) def __sub__(self, other): if isinstance(other, Number): if other is S.NegativeInfinity or other is S.NaN: return S.NaN return self return NotImplemented @_sympifyit('other', NotImplemented) def __rsub__(self, other): return (-self).__add__(other) @_sympifyit('other', NotImplemented) def __mul__(self, other): if isinstance(other, Number): if other.is_zero or other is S.NaN: return S.NaN if other.is_positive: return self return S.Infinity return NotImplemented __rmul__ = __mul__ @_sympifyit('other', NotImplemented) def __div__(self, other): if isinstance(other, Number): if other is S.Infinity or \ other is S.NegativeInfinity or \ other is S.NaN: return S.NaN if other.is_nonnegative: return self return S.Infinity return NotImplemented __truediv__ = __div__ def __abs__(self): return S.Infinity def __neg__(self): return S.Infinity def _eval_power(self, expt): """ ``expt`` is symbolic object but not equal to 0 or 1. ================ ======= ============================== Expression Result Notes ================ ======= ============================== ``(-oo) ** nan`` ``nan`` ``(-oo) ** oo`` ``nan`` ``(-oo) ** -oo`` ``nan`` ``(-oo) ** e`` ``oo`` ``e`` is positive even integer ``(-oo) ** o`` ``-oo`` ``o`` is positive odd integer ================ ======= ============================== See Also ======== Infinity Pow NaN """ if expt.is_number: if expt is S.NaN or \ expt is S.Infinity or \ expt is S.NegativeInfinity: return S.NaN if isinstance(expt, Integer) and expt.is_positive: if expt.is_odd: return S.NegativeInfinity else: return S.Infinity return S.NegativeOne**expt*S.Infinity**expt def _as_mpf_val(self, prec): return mlib.fninf def _sage_(self): import sage.all as sage return -(sage.oo) def __hash__(self): return super(NegativeInfinity, self).__hash__() def __eq__(self, other): return other is S.NegativeInfinity or other == float('-inf') def __ne__(self, other): return other is not S.NegativeInfinity and other != float('-inf') def __lt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s < %s" % (self, other)) if other.is_real: if other.is_finite or other is S.Infinity: return S.true elif other.is_nonnegative: return S.true elif other.is_infinite and other.is_negative: return S.false return Expr.__lt__(self, other) def __le__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s <= %s" % (self, other)) if other.is_real: return S.true return Expr.__le__(self, other) def __gt__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s > %s" % (self, other)) if other.is_real: return S.false return Expr.__gt__(self, other) def __ge__(self, other): try: other = _sympify(other) except SympifyError: raise TypeError("Invalid comparison %s >= %s" % (self, other)) if other.is_real: if other.is_finite or other is S.Infinity: return S.false elif other.is_nonnegative: return S.false elif other.is_infinite and other.is_negative: return S.true return Expr.__ge__(self, other) def __mod__(self, other): return S.NaN __rmod__ = __mod__ def floor(self): return self def ceiling(self): return self class NaN(with_metaclass(Singleton, Number)): """ Not a Number. This serves as a place holder for numeric values that are indeterminate. Most operations on NaN, produce another NaN. Most indeterminate forms, such as ``0/0`` or ``oo - oo` produce NaN. Two exceptions are ``0**0`` and ``oo**0``, which all produce ``1`` (this is consistent with Python's float). NaN is loosely related to floating point nan, which is defined in the IEEE 754 floating point standard, and corresponds to the Python ``float('nan')``. Differences are noted below. NaN is mathematically not equal to anything else, even NaN itself. This explains the initially counter-intuitive results with ``Eq`` and ``==`` in the examples below. NaN is not comparable so inequalities raise a TypeError. This is in constrast with floating point nan where all inequalities are false. NaN is a singleton, and can be accessed by ``S.NaN``, or can be imported as ``nan``. Examples ======== >>> from sympy import nan, S, oo, Eq >>> nan is S.NaN True >>> oo - oo nan >>> nan + 1 nan >>> Eq(nan, nan) # mathematical equality False >>> nan == nan # structural equality True References ========== .. [1] https://en.wikipedia.org/wiki/NaN """ is_commutative = True is_real = None is_rational = None is_algebraic = None is_transcendental = None is_integer = None is_comparable = False is_finite = None is_zero = None is_prime = None is_positive = None is_negative = None is_number = True __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"\text{NaN}" @_sympifyit('other', NotImplemented) def __add__(self, other): return self @_sympifyit('other', NotImplemented) def __sub__(self, other): return self @_sympifyit('other', NotImplemented) def __mul__(self, other): return self @_sympifyit('other', NotImplemented) def __div__(self, other): return self __truediv__ = __div__ def floor(self): return self def ceiling(self): return self def _as_mpf_val(self, prec): return _mpf_nan def _sage_(self): import sage.all as sage return sage.NaN def __hash__(self): return super(NaN, self).__hash__() def __eq__(self, other): # NaN is structurally equal to another NaN return other is S.NaN def __ne__(self, other): return other is not S.NaN def _eval_Eq(self, other): # NaN is not mathematically equal to anything, even NaN return S.false # Expr will _sympify and raise TypeError __gt__ = Expr.__gt__ __ge__ = Expr.__ge__ __lt__ = Expr.__lt__ __le__ = Expr.__le__ nan = S.NaN class ComplexInfinity(with_metaclass(Singleton, AtomicExpr)): r"""Complex infinity. In complex analysis the symbol `\tilde\infty`, called "complex infinity", represents a quantity with infinite magnitude, but undetermined complex phase. ComplexInfinity is a singleton, and can be accessed by ``S.ComplexInfinity``, or can be imported as ``zoo``. Examples ======== >>> from sympy import zoo, oo >>> zoo + 42 zoo >>> 42/zoo 0 >>> zoo + zoo nan >>> zoo*zoo zoo See Also ======== Infinity """ is_commutative = True is_infinite = True is_number = True is_prime = False is_complex = True is_real = False __slots__ = [] def __new__(cls): return AtomicExpr.__new__(cls) def _latex(self, printer): return r"\tilde{\infty}" @staticmethod def __abs__(): return S.Infinity def floor(self): return self def ceiling(self): return self @staticmethod def __neg__(): return S.ComplexInfinity def _eval_power(self, expt): if expt is S.ComplexInfinity: return S.NaN if isinstance(expt, Number): if expt is S.Zero: return S.NaN else: if expt.is_positive: return S.ComplexInfinity else: return S.Zero def _sage_(self): import sage.all as sage return sage.UnsignedInfinityRing.gen() zoo = S.ComplexInfinity class NumberSymbol(AtomicExpr): is_commutative = True is_finite = True is_number = True __slots__ = [] is_NumberSymbol = True def __new__(cls): return AtomicExpr.__new__(cls) def approximation(self, number_cls): """ Return an interval with number_cls endpoints that contains the value of NumberSymbol. If not implemented, then return None. """ def _eval_evalf(self, prec): return Float._new(self._as_mpf_val(prec), prec) def __eq__(self, other): try: other = _sympify(other) except SympifyError: return NotImplemented if self is other: return True if other.is_Number and self.is_irrational: return False return False # NumberSymbol != non-(Number|self) def __ne__(self, other): return not self == other def __le__(self, other): if self is other: return S.true return Expr.__le__(self, other) def __ge__(self, other): if self is other: return S.true return Expr.__ge__(self, other) def __int__(self): # subclass with appropriate return value raise NotImplementedError def __long__(self): return self.__int__() def __hash__(self): return super(NumberSymbol, self).__hash__() class Exp1(with_metaclass(Singleton, NumberSymbol)): r"""The `e` constant. The transcendental number `e = 2.718281828\ldots` is the base of the natural logarithm and of the exponential function, `e = \exp(1)`. Sometimes called Euler's number or Napier's constant. Exp1 is a singleton, and can be accessed by ``S.Exp1``, or can be imported as ``E``. Examples ======== >>> from sympy import exp, log, E >>> E is exp(1) True >>> log(E) 1 References ========== .. [1] https://en.wikipedia.org/wiki/E_%28mathematical_constant%29 """ is_real = True is_positive = True is_negative = False # XXX Forces is_negative/is_nonnegative is_irrational = True is_number = True is_algebraic = False is_transcendental = True __slots__ = [] def _latex(self, printer): return r"e" @staticmethod def __abs__(): return S.Exp1 def __int__(self): return 2 def _as_mpf_val(self, prec): return mpf_e(prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (Integer(2), Integer(3)) elif issubclass(number_cls, Rational): pass def _eval_power(self, expt): from sympy import exp return exp(expt) def _eval_rewrite_as_sin(self, **kwargs): from sympy import sin I = S.ImaginaryUnit return sin(I + S.Pi/2) - I*sin(I) def _eval_rewrite_as_cos(self, **kwargs): from sympy import cos I = S.ImaginaryUnit return cos(I) + I*cos(I + S.Pi/2) def _sage_(self): import sage.all as sage return sage.e E = S.Exp1 class Pi(with_metaclass(Singleton, NumberSymbol)): r"""The `\pi` constant. The transcendental number `\pi = 3.141592654\ldots` represents the ratio of a circle's circumference to its diameter, the area of the unit circle, the half-period of trigonometric functions, and many other things in mathematics. Pi is a singleton, and can be accessed by ``S.Pi``, or can be imported as ``pi``. Examples ======== >>> from sympy import S, pi, oo, sin, exp, integrate, Symbol >>> S.Pi pi >>> pi > 3 True >>> pi.is_irrational True >>> x = Symbol('x') >>> sin(x + 2*pi) sin(x) >>> integrate(exp(-x**2), (x, -oo, oo)) sqrt(pi) References ========== .. [1] https://en.wikipedia.org/wiki/Pi """ is_real = True is_positive = True is_negative = False is_irrational = True is_number = True is_algebraic = False is_transcendental = True __slots__ = [] def _latex(self, printer): return r"\pi" @staticmethod def __abs__(): return S.Pi def __int__(self): return 3 def _as_mpf_val(self, prec): return mpf_pi(prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (Integer(3), Integer(4)) elif issubclass(number_cls, Rational): return (Rational(223, 71), Rational(22, 7)) def _sage_(self): import sage.all as sage return sage.pi pi = S.Pi class GoldenRatio(with_metaclass(Singleton, NumberSymbol)): r"""The golden ratio, `\phi`. `\phi = \frac{1 + \sqrt{5}}{2}` is algebraic number. Two quantities are in the golden ratio if their ratio is the same as the ratio of their sum to the larger of the two quantities, i.e. their maximum. GoldenRatio is a singleton, and can be accessed by ``S.GoldenRatio``. Examples ======== >>> from sympy import S >>> S.GoldenRatio > 1 True >>> S.GoldenRatio.expand(func=True) 1/2 + sqrt(5)/2 >>> S.GoldenRatio.is_irrational True References ========== .. [1] https://en.wikipedia.org/wiki/Golden_ratio """ is_real = True is_positive = True is_negative = False is_irrational = True is_number = True is_algebraic = True is_transcendental = False __slots__ = [] def _latex(self, printer): return r"\phi" def __int__(self): return 1 def _as_mpf_val(self, prec): # XXX track down why this has to be increased rv = mlib.from_man_exp(phi_fixed(prec + 10), -prec - 10) return mpf_norm(rv, prec) def _eval_expand_func(self, **hints): from sympy import sqrt return S.Half + S.Half*sqrt(5) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.One, Rational(2)) elif issubclass(number_cls, Rational): pass def _sage_(self): import sage.all as sage return sage.golden_ratio _eval_rewrite_as_sqrt = _eval_expand_func class TribonacciConstant(with_metaclass(Singleton, NumberSymbol)): r"""The tribonacci constant. The tribonacci numbers are like the Fibonacci numbers, but instead of starting with two predetermined terms, the sequence starts with three predetermined terms and each term afterwards is the sum of the preceding three terms. The tribonacci constant is the ratio toward which adjacent tribonacci numbers tend. It is a root of the polynomial `x^3 - x^2 - x - 1 = 0`, and also satisfies the equation `x + x^{-3} = 2`. TribonacciConstant is a singleton, and can be accessed by ``S.TribonacciConstant``. Examples ======== >>> from sympy import S >>> S.TribonacciConstant > 1 True >>> S.TribonacciConstant.expand(func=True) 1/3 + (19 - 3*sqrt(33))**(1/3)/3 + (3*sqrt(33) + 19)**(1/3)/3 >>> S.TribonacciConstant.is_irrational True >>> S.TribonacciConstant.n(20) 1.8392867552141611326 References ========== .. [1] https://en.wikipedia.org/wiki/Generalizations_of_Fibonacci_numbers#Tribonacci_numbers """ is_real = True is_positive = True is_negative = False is_irrational = True is_number = True is_algebraic = True is_transcendental = False __slots__ = [] def _latex(self, printer): return r"\text{TribonacciConstant}" def __int__(self): return 2 def _eval_evalf(self, prec): rv = self._eval_expand_func(function=True)._eval_evalf(prec + 4) return Float(rv, precision=prec) def _eval_expand_func(self, **hints): from sympy import sqrt, cbrt return (1 + cbrt(19 - 3*sqrt(33)) + cbrt(19 + 3*sqrt(33))) / 3 def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.One, Rational(2)) elif issubclass(number_cls, Rational): pass _eval_rewrite_as_sqrt = _eval_expand_func class EulerGamma(with_metaclass(Singleton, NumberSymbol)): r"""The Euler-Mascheroni constant. `\gamma = 0.5772157\ldots` (also called Euler's constant) is a mathematical constant recurring in analysis and number theory. It is defined as the limiting difference between the harmonic series and the natural logarithm: .. math:: \gamma = \lim\limits_{n\to\infty} \left(\sum\limits_{k=1}^n\frac{1}{k} - \ln n\right) EulerGamma is a singleton, and can be accessed by ``S.EulerGamma``. Examples ======== >>> from sympy import S >>> S.EulerGamma.is_irrational >>> S.EulerGamma > 0 True >>> S.EulerGamma > 1 False References ========== .. [1] https://en.wikipedia.org/wiki/Euler%E2%80%93Mascheroni_constant """ is_real = True is_positive = True is_negative = False is_irrational = None is_number = True __slots__ = [] def _latex(self, printer): return r"\gamma" def __int__(self): return 0 def _as_mpf_val(self, prec): # XXX track down why this has to be increased v = mlib.libhyper.euler_fixed(prec + 10) rv = mlib.from_man_exp(v, -prec - 10) return mpf_norm(rv, prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.Zero, S.One) elif issubclass(number_cls, Rational): return (S.Half, Rational(3, 5)) def _sage_(self): import sage.all as sage return sage.euler_gamma class Catalan(with_metaclass(Singleton, NumberSymbol)): r"""Catalan's constant. `K = 0.91596559\ldots` is given by the infinite series .. math:: K = \sum_{k=0}^{\infty} \frac{(-1)^k}{(2k+1)^2} Catalan is a singleton, and can be accessed by ``S.Catalan``. Examples ======== >>> from sympy import S >>> S.Catalan.is_irrational >>> S.Catalan > 0 True >>> S.Catalan > 1 False References ========== .. [1] https://en.wikipedia.org/wiki/Catalan%27s_constant """ is_real = True is_positive = True is_negative = False is_irrational = None is_number = True __slots__ = [] def __int__(self): return 0 def _as_mpf_val(self, prec): # XXX track down why this has to be increased v = mlib.catalan_fixed(prec + 10) rv = mlib.from_man_exp(v, -prec - 10) return mpf_norm(rv, prec) def approximation_interval(self, number_cls): if issubclass(number_cls, Integer): return (S.Zero, S.One) elif issubclass(number_cls, Rational): return (Rational(9, 10), S.One) def _sage_(self): import sage.all as sage return sage.catalan class ImaginaryUnit(with_metaclass(Singleton, AtomicExpr)): r"""The imaginary unit, `i = \sqrt{-1}`. I is a singleton, and can be accessed by ``S.I``, or can be imported as ``I``. Examples ======== >>> from sympy import I, sqrt >>> sqrt(-1) I >>> I*I -1 >>> 1/I -I References ========== .. [1] https://en.wikipedia.org/wiki/Imaginary_unit """ is_commutative = True is_imaginary = True is_finite = True is_number = True is_algebraic = True is_transcendental = False __slots__ = [] def _latex(self, printer): return printer._settings['imaginary_unit_latex'] @staticmethod def __abs__(): return S.One def _eval_evalf(self, prec): return self def _eval_conjugate(self): return -S.ImaginaryUnit def _eval_power(self, expt): """ b is I = sqrt(-1) e is symbolic object but not equal to 0, 1 I**r -> (-1)**(r/2) -> exp(r/2*Pi*I) -> sin(Pi*r/2) + cos(Pi*r/2)*I, r is decimal I**0 mod 4 -> 1 I**1 mod 4 -> I I**2 mod 4 -> -1 I**3 mod 4 -> -I """ if isinstance(expt, Number): if isinstance(expt, Integer): expt = expt.p % 4 if expt == 0: return S.One if expt == 1: return S.ImaginaryUnit if expt == 2: return -S.One return -S.ImaginaryUnit return def as_base_exp(self): return S.NegativeOne, S.Half def _sage_(self): import sage.all as sage return sage.I @property def _mpc_(self): return (Float(0)._mpf_, Float(1)._mpf_) I = S.ImaginaryUnit def sympify_fractions(f): return Rational(f.numerator, f.denominator, 1) converter[fractions.Fraction] = sympify_fractions try: if HAS_GMPY == 2: import gmpy2 as gmpy elif HAS_GMPY == 1: import gmpy else: raise ImportError def sympify_mpz(x): return Integer(long(x)) def sympify_mpq(x): return Rational(long(x.numerator), long(x.denominator)) converter[type(gmpy.mpz(1))] = sympify_mpz converter[type(gmpy.mpq(1, 2))] = sympify_mpq except ImportError: pass def sympify_mpmath(x): return Expr._from_mpmath(x, x.context.prec) converter[mpnumeric] = sympify_mpmath def sympify_mpq(x): p, q = x._mpq_ return Rational(p, q, 1) converter[type(mpmath.rational.mpq(1, 2))] = sympify_mpq def sympify_complex(a): real, imag = list(map(sympify, (a.real, a.imag))) return real + S.ImaginaryUnit*imag converter[complex] = sympify_complex from .power import Pow, integer_nthroot from .mul import Mul Mul.identity = One() from .add import Add Add.identity = Zero()

ecaf9178de4a8436b4d06de7f293265a82447e5f260be4139f31da36e8bf4470

from __future__ import print_function, division from sympy.core.sympify import _sympify, sympify from sympy.core.basic import Basic from sympy.core.cache import cacheit from sympy.core.compatibility import ordered, range from sympy.core.logic import fuzzy_and from sympy.core.evaluate import global_evaluate from sympy.utilities.iterables import sift class AssocOp(Basic): """ Associative operations, can separate noncommutative and commutative parts. (a op b) op c == a op (b op c) == a op b op c. Base class for Add and Mul. This is an abstract base class, concrete derived classes must define the attribute `identity`. """ # for performance reason, we don't let is_commutative go to assumptions, # and keep it right here __slots__ = ['is_commutative'] @cacheit def __new__(cls, *args, **options): from sympy import Order args = list(map(_sympify, args)) args = [a for a in args if a is not cls.identity] evaluate = options.get('evaluate') if evaluate is None: evaluate = global_evaluate[0] if not evaluate: obj = cls._from_args(args) obj = cls._exec_constructor_postprocessors(obj) return obj if len(args) == 0: return cls.identity if len(args) == 1: return args[0] c_part, nc_part, order_symbols = cls.flatten(args) is_commutative = not nc_part obj = cls._from_args(c_part + nc_part, is_commutative) obj = cls._exec_constructor_postprocessors(obj) if order_symbols is not None: return Order(obj, *order_symbols) return obj @classmethod def _from_args(cls, args, is_commutative=None): """Create new instance with already-processed args""" if len(args) == 0: return cls.identity elif len(args) == 1: return args[0] obj = super(AssocOp, cls).__new__(cls, *args) if is_commutative is None: is_commutative = fuzzy_and(a.is_commutative for a in args) obj.is_commutative = is_commutative return obj def _new_rawargs(self, *args, **kwargs): """Create new instance of own class with args exactly as provided by caller but returning the self class identity if args is empty. This is handy when we want to optimize things, e.g. >>> from sympy import Mul, S >>> from sympy.abc import x, y >>> e = Mul(3, x, y) >>> e.args (3, x, y) >>> Mul(*e.args[1:]) x*y >>> e._new_rawargs(*e.args[1:]) # the same as above, but faster x*y Note: use this with caution. There is no checking of arguments at all. This is best used when you are rebuilding an Add or Mul after simply removing one or more args. If, for example, modifications, result in extra 1s being inserted (as when collecting an expression's numerators and denominators) they will not show up in the result but a Mul will be returned nonetheless: >>> m = (x*y)._new_rawargs(S.One, x); m x >>> m == x False >>> m.is_Mul True Another issue to be aware of is that the commutativity of the result is based on the commutativity of self. If you are rebuilding the terms that came from a commutative object then there will be no problem, but if self was non-commutative then what you are rebuilding may now be commutative. Although this routine tries to do as little as possible with the input, getting the commutativity right is important, so this level of safety is enforced: commutativity will always be recomputed if self is non-commutative and kwarg `reeval=False` has not been passed. """ if kwargs.pop('reeval', True) and self.is_commutative is False: is_commutative = None else: is_commutative = self.is_commutative return self._from_args(args, is_commutative) @classmethod def flatten(cls, seq): """Return seq so that none of the elements are of type `cls`. This is the vanilla routine that will be used if a class derived from AssocOp does not define its own flatten routine.""" # apply associativity, no commutativity property is used new_seq = [] while seq: o = seq.pop() if o.__class__ is cls: # classes must match exactly seq.extend(o.args) else: new_seq.append(o) new_seq.reverse() # c_part, nc_part, order_symbols return [], new_seq, None def _matches_commutative(self, expr, repl_dict={}, old=False): """ Matches Add/Mul "pattern" to an expression "expr". repl_dict ... a dictionary of (wild: expression) pairs, that get returned with the results This function is the main workhorse for Add/Mul. For instance: >>> from sympy import symbols, Wild, sin >>> a = Wild("a") >>> b = Wild("b") >>> c = Wild("c") >>> x, y, z = symbols("x y z") >>> (a+sin(b)*c)._matches_commutative(x+sin(y)*z) {a_: x, b_: y, c_: z} In the example above, "a+sin(b)*c" is the pattern, and "x+sin(y)*z" is the expression. The repl_dict contains parts that were already matched. For example here: >>> (x+sin(b)*c)._matches_commutative(x+sin(y)*z, repl_dict={a: x}) {a_: x, b_: y, c_: z} the only function of the repl_dict is to return it in the result, e.g. if you omit it: >>> (x+sin(b)*c)._matches_commutative(x+sin(y)*z) {b_: y, c_: z} the "a: x" is not returned in the result, but otherwise it is equivalent. """ # make sure expr is Expr if pattern is Expr from .expr import Add, Expr from sympy import Mul if isinstance(self, Expr) and not isinstance(expr, Expr): return None # handle simple patterns if self == expr: return repl_dict d = self._matches_simple(expr, repl_dict) if d is not None: return d # eliminate exact part from pattern: (2+a+w1+w2).matches(expr) -> (w1+w2).matches(expr-a-2) from .function import WildFunction from .symbol import Wild wild_part, exact_part = sift(self.args, lambda p: p.has(Wild, WildFunction) and not expr.has(p), binary=True) if not exact_part: wild_part = list(ordered(wild_part)) else: exact = self._new_rawargs(*exact_part) free = expr.free_symbols if free and (exact.free_symbols - free): # there are symbols in the exact part that are not # in the expr; but if there are no free symbols, let # the matching continue return None newexpr = self._combine_inverse(expr, exact) if not old and (expr.is_Add or expr.is_Mul): if newexpr.count_ops() > expr.count_ops(): return None newpattern = self._new_rawargs(*wild_part) return newpattern.matches(newexpr, repl_dict) # now to real work ;) i = 0 saw = set() while expr not in saw: saw.add(expr) expr_list = (self.identity,) + tuple(ordered(self.make_args(expr))) for last_op in reversed(expr_list): for w in reversed(wild_part): d1 = w.matches(last_op, repl_dict) if d1 is not None: d2 = self.xreplace(d1).matches(expr, d1) if d2 is not None: return d2 if i == 0: if self.is_Mul: # make e**i look like Mul if expr.is_Pow and expr.exp.is_Integer: if expr.exp > 0: expr = Mul(*[expr.base, expr.base**(expr.exp - 1)], evaluate=False) else: expr = Mul(*[1/expr.base, expr.base**(expr.exp + 1)], evaluate=False) i += 1 continue elif self.is_Add: # make i*e look like Add c, e = expr.as_coeff_Mul() if abs(c) > 1: if c > 0: expr = Add(*[e, (c - 1)*e], evaluate=False) else: expr = Add(*[-e, (c + 1)*e], evaluate=False) i += 1 continue # try collection on non-Wild symbols from sympy.simplify.radsimp import collect was = expr did = set() for w in reversed(wild_part): c, w = w.as_coeff_mul(Wild) free = c.free_symbols - did if free: did.update(free) expr = collect(expr, free) if expr != was: i += 0 continue break # if we didn't continue, there is nothing more to do return def _has_matcher(self): """Helper for .has()""" def _ncsplit(expr): # this is not the same as args_cnc because here # we don't assume expr is a Mul -- hence deal with args -- # and always return a set. cpart, ncpart = sift(expr.args, lambda arg: arg.is_commutative is True, binary=True) return set(cpart), ncpart c, nc = _ncsplit(self) cls = self.__class__ def is_in(expr): if expr == self: return True elif not isinstance(expr, Basic): return False elif isinstance(expr, cls): _c, _nc = _ncsplit(expr) if (c & _c) == c: if not nc: return True elif len(nc) <= len(_nc): for i in range(len(_nc) - len(nc) + 1): if _nc[i:i + len(nc)] == nc: return True return False return is_in def _eval_evalf(self, prec): """ Evaluate the parts of self that are numbers; if the whole thing was a number with no functions it would have been evaluated, but it wasn't so we must judiciously extract the numbers and reconstruct the object. This is *not* simply replacing numbers with evaluated numbers. Nunmbers should be handled in the largest pure-number expression as possible. So the code below separates ``self`` into number and non-number parts and evaluates the number parts and walks the args of the non-number part recursively (doing the same thing). """ from .add import Add from .mul import Mul from .symbol import Symbol from .function import AppliedUndef if isinstance(self, (Mul, Add)): x, tail = self.as_independent(Symbol, AppliedUndef) # if x is an AssocOp Function then the _evalf below will # call _eval_evalf (here) so we must break the recursion if not (tail is self.identity or isinstance(x, AssocOp) and x.is_Function or x is self.identity and isinstance(tail, AssocOp)): # here, we have a number so we just call to _evalf with prec; # prec is not the same as n, it is the binary precision so # that's why we don't call to evalf. x = x._evalf(prec) if x is not self.identity else self.identity args = [] tail_args = tuple(self.func.make_args(tail)) for a in tail_args: # here we call to _eval_evalf since we don't know what we # are dealing with and all other _eval_evalf routines should # be doing the same thing (i.e. taking binary prec and # finding the evalf-able args) newa = a._eval_evalf(prec) if newa is None: args.append(a) else: args.append(newa) return self.func(x, *args) # this is the same as above, but there were no pure-number args to # deal with args = [] for a in self.args: newa = a._eval_evalf(prec) if newa is None: args.append(a) else: args.append(newa) return self.func(*args) @classmethod def make_args(cls, expr): """ Return a sequence of elements `args` such that cls(*args) == expr >>> from sympy import Symbol, Mul, Add >>> x, y = map(Symbol, 'xy') >>> Mul.make_args(x*y) (x, y) >>> Add.make_args(x*y) (x*y,) >>> set(Add.make_args(x*y + y)) == set([y, x*y]) True """ if isinstance(expr, cls): return expr.args else: return (sympify(expr),) class ShortCircuit(Exception): pass class LatticeOp(AssocOp): """ Join/meet operations of an algebraic lattice[1]. These binary operations are associative (op(op(a, b), c) = op(a, op(b, c))), commutative (op(a, b) = op(b, a)) and idempotent (op(a, a) = op(a) = a). Common examples are AND, OR, Union, Intersection, max or min. They have an identity element (op(identity, a) = a) and an absorbing element conventionally called zero (op(zero, a) = zero). This is an abstract base class, concrete derived classes must declare attributes zero and identity. All defining properties are then respected. >>> from sympy import Integer >>> from sympy.core.operations import LatticeOp >>> class my_join(LatticeOp): ... zero = Integer(0) ... identity = Integer(1) >>> my_join(2, 3) == my_join(3, 2) True >>> my_join(2, my_join(3, 4)) == my_join(2, 3, 4) True >>> my_join(0, 1, 4, 2, 3, 4) 0 >>> my_join(1, 2) 2 References: [1] - https://en.wikipedia.org/wiki/Lattice_%28order%29 """ is_commutative = True def __new__(cls, *args, **options): args = (_sympify(arg) for arg in args) try: # /!\ args is a generator and _new_args_filter # must be careful to handle as such; this # is done so short-circuiting can be done # without having to sympify all values _args = frozenset(cls._new_args_filter(args)) except ShortCircuit: return sympify(cls.zero) if not _args: return sympify(cls.identity) elif len(_args) == 1: return set(_args).pop() else: # XXX in almost every other case for __new__, *_args is # passed along, but the expectation here is for _args obj = super(AssocOp, cls).__new__(cls, _args) obj._argset = _args return obj @classmethod def _new_args_filter(cls, arg_sequence, call_cls=None): """Generator filtering args""" ncls = call_cls or cls for arg in arg_sequence: if arg == ncls.zero: raise ShortCircuit(arg) elif arg == ncls.identity: continue elif arg.func == ncls: for x in arg.args: yield x else: yield arg @classmethod def make_args(cls, expr): """ Return a set of args such that cls(*arg_set) == expr. """ if isinstance(expr, cls): return expr._argset else: return frozenset([sympify(expr)]) @property @cacheit def args(self): return tuple(ordered(self._argset)) @staticmethod def _compare_pretty(a, b): return (str(a) > str(b)) - (str(a) < str(b))

1bb672709eb717759fd695f5e22bf4a0d6cd82c8350b1dce51ac36d00039ec9d

""" Reimplementations of constructs introduced in later versions of Python than we support. Also some functions that are needed SymPy-wide and are located here for easy import. """ from __future__ import print_function, division import operator from collections import defaultdict from sympy.external import import_module """ Python 2 and Python 3 compatible imports String and Unicode compatible changes: * `unicode()` removed in Python 3, import `unicode` for Python 2/3 compatible function * `unichr()` removed in Python 3, import `unichr` for Python 2/3 compatible function * Use `u()` for escaped unicode sequences (e.g. u'\u2020' -> u('\u2020')) * Use `u_decode()` to decode utf-8 formatted unicode strings * `string_types` gives str in Python 3, unicode and str in Python 2, equivalent to basestring Integer related changes: * `long()` removed in Python 3, import `long` for Python 2/3 compatible function * `integer_types` gives int in Python 3, int and long in Python 2 Types related changes: * `class_types` gives type in Python 3, type and ClassType in Python 2 Renamed function attributes: * Python 2 `.func_code`, Python 3 `.__func__`, access with `get_function_code()` * Python 2 `.func_globals`, Python 3 `.__globals__`, access with `get_function_globals()` * Python 2 `.func_name`, Python 3 `.__name__`, access with `get_function_name()` Moved modules: * `reduce()` * `StringIO()` * `cStringIO()` (same as `StingIO()` in Python 3) * Python 2 `__builtins__`, access with Python 3 name, `builtins` Iterator/list changes: * `xrange` renamed as `range` in Python 3, import `range` for Python 2/3 compatible iterator version of range. exec: * Use `exec_()`, with parameters `exec_(code, globs=None, locs=None)` Metaclasses: * Use `with_metaclass()`, examples below * Define class `Foo` with metaclass `Meta`, and no parent: class Foo(with_metaclass(Meta)): pass * Define class `Foo` with metaclass `Meta` and parent class `Bar`: class Foo(with_metaclass(Meta, Bar)): pass """ import sys PY3 = sys.version_info[0] > 2 if PY3: class_types = type, integer_types = (int,) string_types = (str,) long = int int_info = sys.int_info # String / unicode compatibility unicode = str unichr = chr def u_decode(x): return x Iterator = object # Moved definitions get_function_code = operator.attrgetter("__code__") get_function_globals = operator.attrgetter("__globals__") get_function_name = operator.attrgetter("__name__") import builtins from functools import reduce from io import StringIO cStringIO = StringIO exec_ = getattr(builtins, "exec") range = range round = round from collections.abc import (Mapping, Callable, MutableMapping, MutableSet, Iterable, Hashable) from inspect import unwrap from itertools import accumulate else: import codecs import types class_types = (type, types.ClassType) integer_types = (int, long) string_types = (str, unicode) long = long int_info = sys.long_info # String / unicode compatibility unicode = unicode unichr = unichr def u_decode(x): return x.decode('utf-8') class Iterator(object): def next(self): return type(self).__next__(self) # Moved definitions get_function_code = operator.attrgetter("func_code") get_function_globals = operator.attrgetter("func_globals") get_function_name = operator.attrgetter("func_name") import __builtin__ as builtins reduce = reduce from StringIO import StringIO from cStringIO import StringIO as cStringIO def exec_(_code_, _globs_=None, _locs_=None): """Execute code in a namespace.""" if _globs_ is None: frame = sys._getframe(1) _globs_ = frame.f_globals if _locs_ is None: _locs_ = frame.f_locals del frame elif _locs_ is None: _locs_ = _globs_ exec("exec _code_ in _globs_, _locs_") range = xrange _round = round def round(x, *args): try: return x.__round__(*args) except (AttributeError, TypeError): return _round(x, *args) from collections import (Mapping, Callable, MutableMapping, MutableSet, Iterable, Hashable) def unwrap(func, stop=None): """Get the object wrapped by *func*. Follows the chain of :attr:`__wrapped__` attributes returning the last object in the chain. *stop* is an optional callback accepting an object in the wrapper chain as its sole argument that allows the unwrapping to be terminated early if the callback returns a true value. If the callback never returns a true value, the last object in the chain is returned as usual. For example, :func:`signature` uses this to stop unwrapping if any object in the chain has a ``__signature__`` attribute defined. :exc:`ValueError` is raised if a cycle is encountered. """ if stop is None: def _is_wrapper(f): return hasattr(f, '__wrapped__') else: def _is_wrapper(f): return hasattr(f, '__wrapped__') and not stop(f) f = func # remember the original func for error reporting memo = {id(f)} # Memoise by id to tolerate non-hashable objects while _is_wrapper(func): func = func.__wrapped__ id_func = id(func) if id_func in memo: raise ValueError('wrapper loop when unwrapping {!r}'.format(f)) memo.add(id_func) return func def accumulate(iterable, func=operator.add): state = iterable[0] yield state for i in iterable[1:]: state = func(state, i) yield state def with_metaclass(meta, *bases): """ Create a base class with a metaclass. For example, if you have the metaclass >>> class Meta(type): ... pass Use this as the metaclass by doing >>> from sympy.core.compatibility import with_metaclass >>> class MyClass(with_metaclass(Meta, object)): ... pass This is equivalent to the Python 2:: class MyClass(object): __metaclass__ = Meta or Python 3:: class MyClass(object, metaclass=Meta): pass That is, the first argument is the metaclass, and the remaining arguments are the base classes. Note that if the base class is just ``object``, you may omit it. >>> MyClass.__mro__ (<class '...MyClass'>, <... 'object'>) >>> type(MyClass) <class '...Meta'> """ # This requires a bit of explanation: the basic idea is to make a dummy # metaclass for one level of class instantiation that replaces itself with # the actual metaclass. # Code copied from the 'six' library. class metaclass(meta): def __new__(cls, name, this_bases, d): return meta(name, bases, d) return type.__new__(metaclass, "NewBase", (), {}) # These are in here because telling if something is an iterable just by calling # hasattr(obj, "__iter__") behaves differently in Python 2 and Python 3. In # particular, hasattr(str, "__iter__") is False in Python 2 and True in Python 3. # I think putting them here also makes it easier to use them in the core. class NotIterable: """ Use this as mixin when creating a class which is not supposed to return true when iterable() is called on its instances because calling list() on the instance, for example, would result in an infinite loop. """ pass def iterable(i, exclude=(string_types, dict, NotIterable)): """ Return a boolean indicating whether ``i`` is SymPy iterable. True also indicates that the iterator is finite, e.g. you can call list(...) on the instance. When SymPy is working with iterables, it is almost always assuming that the iterable is not a string or a mapping, so those are excluded by default. If you want a pure Python definition, make exclude=None. To exclude multiple items, pass them as a tuple. You can also set the _iterable attribute to True or False on your class, which will override the checks here, including the exclude test. As a rule of thumb, some SymPy functions use this to check if they should recursively map over an object. If an object is technically iterable in the Python sense but does not desire this behavior (e.g., because its iteration is not finite, or because iteration might induce an unwanted computation), it should disable it by setting the _iterable attribute to False. See also: is_sequence Examples ======== >>> from sympy.utilities.iterables import iterable >>> from sympy import Tuple >>> things = [[1], (1,), set([1]), Tuple(1), (j for j in [1, 2]), {1:2}, '1', 1] >>> for i in things: ... print('%s %s' % (iterable(i), type(i))) True <... 'list'> True <... 'tuple'> True <... 'set'> True <class 'sympy.core.containers.Tuple'> True <... 'generator'> False <... 'dict'> False <... 'str'> False <... 'int'> >>> iterable({}, exclude=None) True >>> iterable({}, exclude=str) True >>> iterable("no", exclude=str) False """ if hasattr(i, '_iterable'): return i._iterable try: iter(i) except TypeError: return False if exclude: return not isinstance(i, exclude) return True def is_sequence(i, include=None): """ Return a boolean indicating whether ``i`` is a sequence in the SymPy sense. If anything that fails the test below should be included as being a sequence for your application, set 'include' to that object's type; multiple types should be passed as a tuple of types. Note: although generators can generate a sequence, they often need special handling to make sure their elements are captured before the generator is exhausted, so these are not included by default in the definition of a sequence. See also: iterable Examples ======== >>> from sympy.utilities.iterables import is_sequence >>> from types import GeneratorType >>> is_sequence([]) True >>> is_sequence(set()) False >>> is_sequence('abc') False >>> is_sequence('abc', include=str) True >>> generator = (c for c in 'abc') >>> is_sequence(generator) False >>> is_sequence(generator, include=(str, GeneratorType)) True """ return (hasattr(i, '__getitem__') and iterable(i) or bool(include) and isinstance(i, include)) try: from itertools import zip_longest except ImportError: # Python 2.7 from itertools import izip_longest as zip_longest try: # Python 2.7 from string import maketrans except ImportError: maketrans = str.maketrans def as_int(n, strict=True): """ Convert the argument to a builtin integer. The return value is guaranteed to be equal to the input. ValueError is raised if the input has a non-integral value. When ``strict`` is False, non-integer input that compares equal to the integer value will not raise an error. Examples ======== >>> from sympy.core.compatibility import as_int >>> from sympy import sqrt, S The function is primarily concerned with sanitizing input for functions that need to work with builtin integers, so anything that is unambiguously an integer should be returned as an int: >>> as_int(S(3)) 3 Floats, being of limited precision, are not assumed to be exact and will raise an error unless the ``strict`` flag is False. This precision issue becomes apparent for large floating point numbers: >>> big = 1e23 >>> type(big) is float True >>> big == int(big) True >>> as_int(big) Traceback (most recent call last): ... ValueError: ... is not an integer >>> as_int(big, strict=False) 99999999999999991611392 Input that might be a complex representation of an integer value is also rejected by default: >>> one = sqrt(3 + 2*sqrt(2)) - sqrt(2) >>> int(one) == 1 True >>> as_int(one) Traceback (most recent call last): ... ValueError: ... is not an integer """ from sympy.core.numbers import Integer try: if strict and not isinstance(n, SYMPY_INTS + (Integer,)): raise TypeError result = int(n) if result != n: raise TypeError return result except TypeError: raise ValueError('%s is not an integer' % (n,)) def default_sort_key(item, order=None): """Return a key that can be used for sorting. The key has the structure: (class_key, (len(args), args), exponent.sort_key(), coefficient) This key is supplied by the sort_key routine of Basic objects when ``item`` is a Basic object or an object (other than a string) that sympifies to a Basic object. Otherwise, this function produces the key. The ``order`` argument is passed along to the sort_key routine and is used to determine how the terms *within* an expression are ordered. (See examples below) ``order`` options are: 'lex', 'grlex', 'grevlex', and reversed values of the same (e.g. 'rev-lex'). The default order value is None (which translates to 'lex'). Examples ======== >>> from sympy import S, I, default_sort_key, sin, cos, sqrt >>> from sympy.core.function import UndefinedFunction >>> from sympy.abc import x The following are equivalent ways of getting the key for an object: >>> x.sort_key() == default_sort_key(x) True Here are some examples of the key that is produced: >>> default_sort_key(UndefinedFunction('f')) ((0, 0, 'UndefinedFunction'), (1, ('f',)), ((1, 0, 'Number'), (0, ()), (), 1), 1) >>> default_sort_key('1') ((0, 0, 'str'), (1, ('1',)), ((1, 0, 'Number'), (0, ()), (), 1), 1) >>> default_sort_key(S.One) ((1, 0, 'Number'), (0, ()), (), 1) >>> default_sort_key(2) ((1, 0, 'Number'), (0, ()), (), 2) While sort_key is a method only defined for SymPy objects, default_sort_key will accept anything as an argument so it is more robust as a sorting key. For the following, using key= lambda i: i.sort_key() would fail because 2 doesn't have a sort_key method; that's why default_sort_key is used. Note, that it also handles sympification of non-string items likes ints: >>> a = [2, I, -I] >>> sorted(a, key=default_sort_key) [2, -I, I] The returned key can be used anywhere that a key can be specified for a function, e.g. sort, min, max, etc...: >>> a.sort(key=default_sort_key); a[0] 2 >>> min(a, key=default_sort_key) 2 Note ---- The key returned is useful for getting items into a canonical order that will be the same across platforms. It is not directly useful for sorting lists of expressions: >>> a, b = x, 1/x Since ``a`` has only 1 term, its value of sort_key is unaffected by ``order``: >>> a.sort_key() == a.sort_key('rev-lex') True If ``a`` and ``b`` are combined then the key will differ because there are terms that can be ordered: >>> eq = a + b >>> eq.sort_key() == eq.sort_key('rev-lex') False >>> eq.as_ordered_terms() [x, 1/x] >>> eq.as_ordered_terms('rev-lex') [1/x, x] But since the keys for each of these terms are independent of ``order``'s value, they don't sort differently when they appear separately in a list: >>> sorted(eq.args, key=default_sort_key) [1/x, x] >>> sorted(eq.args, key=lambda i: default_sort_key(i, order='rev-lex')) [1/x, x] The order of terms obtained when using these keys is the order that would be obtained if those terms were *factors* in a product. Although it is useful for quickly putting expressions in canonical order, it does not sort expressions based on their complexity defined by the number of operations, power of variables and others: >>> sorted([sin(x)*cos(x), sin(x)], key=default_sort_key) [sin(x)*cos(x), sin(x)] >>> sorted([x, x**2, sqrt(x), x**3], key=default_sort_key) [sqrt(x), x, x**2, x**3] See Also ======== ordered, sympy.core.expr.as_ordered_factors, sympy.core.expr.as_ordered_terms """ from .singleton import S from .basic import Basic from .sympify import sympify, SympifyError from .compatibility import iterable if isinstance(item, Basic): return item.sort_key(order=order) if iterable(item, exclude=string_types): if isinstance(item, dict): args = item.items() unordered = True elif isinstance(item, set): args = item unordered = True else: # e.g. tuple, list args = list(item) unordered = False args = [default_sort_key(arg, order=order) for arg in args] if unordered: # e.g. dict, set args = sorted(args) cls_index, args = 10, (len(args), tuple(args)) else: if not isinstance(item, string_types): try: item = sympify(item) except SympifyError: # e.g. lambda x: x pass else: if isinstance(item, Basic): # e.g int -> Integer return default_sort_key(item) # e.g. UndefinedFunction # e.g. str cls_index, args = 0, (1, (str(item),)) return (cls_index, 0, item.__class__.__name__ ), args, S.One.sort_key(), S.One def _nodes(e): """ A helper for ordered() which returns the node count of ``e`` which for Basic objects is the number of Basic nodes in the expression tree but for other objects is 1 (unless the object is an iterable or dict for which the sum of nodes is returned). """ from .basic import Basic if isinstance(e, Basic): return e.count(Basic) elif iterable(e): return 1 + sum(_nodes(ei) for ei in e) elif isinstance(e, dict): return 1 + sum(_nodes(k) + _nodes(v) for k, v in e.items()) else: return 1 def ordered(seq, keys=None, default=True, warn=False): """Return an iterator of the seq where keys are used to break ties in a conservative fashion: if, after applying a key, there are no ties then no other keys will be computed. Two default keys will be applied if 1) keys are not provided or 2) the given keys don't resolve all ties (but only if `default` is True). The two keys are `_nodes` (which places smaller expressions before large) and `default_sort_key` which (if the `sort_key` for an object is defined properly) should resolve any ties. If ``warn`` is True then an error will be raised if there were no keys remaining to break ties. This can be used if it was expected that there should be no ties between items that are not identical. Examples ======== >>> from sympy.utilities.iterables import ordered >>> from sympy import count_ops >>> from sympy.abc import x, y The count_ops is not sufficient to break ties in this list and the first two items appear in their original order (i.e. the sorting is stable): >>> list(ordered([y + 2, x + 2, x**2 + y + 3], ... count_ops, default=False, warn=False)) ... [y + 2, x + 2, x**2 + y + 3] The default_sort_key allows the tie to be broken: >>> list(ordered([y + 2, x + 2, x**2 + y + 3])) ... [x + 2, y + 2, x**2 + y + 3] Here, sequences are sorted by length, then sum: >>> seq, keys = [[[1, 2, 1], [0, 3, 1], [1, 1, 3], [2], [1]], [ ... lambda x: len(x), ... lambda x: sum(x)]] ... >>> list(ordered(seq, keys, default=False, warn=False)) [[1], [2], [1, 2, 1], [0, 3, 1], [1, 1, 3]] If ``warn`` is True, an error will be raised if there were not enough keys to break ties: >>> list(ordered(seq, keys, default=False, warn=True)) Traceback (most recent call last): ... ValueError: not enough keys to break ties Notes ===== The decorated sort is one of the fastest ways to sort a sequence for which special item comparison is desired: the sequence is decorated, sorted on the basis of the decoration (e.g. making all letters lower case) and then undecorated. If one wants to break ties for items that have the same decorated value, a second key can be used. But if the second key is expensive to compute then it is inefficient to decorate all items with both keys: only those items having identical first key values need to be decorated. This function applies keys successively only when needed to break ties. By yielding an iterator, use of the tie-breaker is delayed as long as possible. This function is best used in cases when use of the first key is expected to be a good hashing function; if there are no unique hashes from application of a key then that key should not have been used. The exception, however, is that even if there are many collisions, if the first group is small and one does not need to process all items in the list then time will not be wasted sorting what one was not interested in. For example, if one were looking for the minimum in a list and there were several criteria used to define the sort order, then this function would be good at returning that quickly if the first group of candidates is small relative to the number of items being processed. """ d = defaultdict(list) if keys: if not isinstance(keys, (list, tuple)): keys = [keys] keys = list(keys) f = keys.pop(0) for a in seq: d[f(a)].append(a) else: if not default: raise ValueError('if default=False then keys must be provided') d[None].extend(seq) for k in sorted(d.keys()): if len(d[k]) > 1: if keys: d[k] = ordered(d[k], keys, default, warn) elif default: d[k] = ordered(d[k], (_nodes, default_sort_key,), default=False, warn=warn) elif warn: from sympy.utilities.iterables import uniq u = list(uniq(d[k])) if len(u) > 1: raise ValueError( 'not enough keys to break ties: %s' % u) for v in d[k]: yield v d.pop(k) # If HAS_GMPY is 0, no supported version of gmpy is available. Otherwise, # HAS_GMPY contains the major version number of gmpy; i.e. 1 for gmpy, and # 2 for gmpy2. # Versions of gmpy prior to 1.03 do not work correctly with int(largempz) # For example, int(gmpy.mpz(2**256)) would raise OverflowError. # See issue 4980. # Minimum version of gmpy changed to 1.13 to allow a single code base to also # work with gmpy2. def _getenv(key, default=None): from os import getenv return getenv(key, default) GROUND_TYPES = _getenv('SYMPY_GROUND_TYPES', 'auto').lower() HAS_GMPY = 0 if GROUND_TYPES != 'python': # Don't try to import gmpy2 if ground types is set to gmpy1. This is # primarily intended for testing. if GROUND_TYPES != 'gmpy1': gmpy = import_module('gmpy2', min_module_version='2.0.0', module_version_attr='version', module_version_attr_call_args=()) if gmpy: HAS_GMPY = 2 else: GROUND_TYPES = 'gmpy' if not HAS_GMPY: gmpy = import_module('gmpy', min_module_version='1.13', module_version_attr='version', module_version_attr_call_args=()) if gmpy: HAS_GMPY = 1 if GROUND_TYPES == 'auto': if HAS_GMPY: GROUND_TYPES = 'gmpy' else: GROUND_TYPES = 'python' if GROUND_TYPES == 'gmpy' and not HAS_GMPY: from warnings import warn warn("gmpy library is not installed, switching to 'python' ground types") GROUND_TYPES = 'python' # SYMPY_INTS is a tuple containing the base types for valid integer types. SYMPY_INTS = integer_types if GROUND_TYPES == 'gmpy': SYMPY_INTS += (type(gmpy.mpz(0)),) # lru_cache compatible with py2.7 copied directly from # https://code.activestate.com/ # recipes/578078-py26-and-py30-backport-of-python-33s-lru-cache/ from collections import namedtuple from functools import update_wrapper from threading import RLock _CacheInfo = namedtuple("CacheInfo", ["hits", "misses", "maxsize", "currsize"]) class _HashedSeq(list): __slots__ = 'hashvalue' def __init__(self, tup, hash=hash): self[:] = tup self.hashvalue = hash(tup) def __hash__(self): return self.hashvalue def _make_key(args, kwds, typed, kwd_mark = (object(),), fasttypes = set((int, str, frozenset, type(None))), sorted=sorted, tuple=tuple, type=type, len=len): 'Make a cache key from optionally typed positional and keyword arguments' key = args if kwds: sorted_items = sorted(kwds.items()) key += kwd_mark for item in sorted_items: key += item if typed: key += tuple(type(v) for v in args) if kwds: key += tuple(type(v) for k, v in sorted_items) elif len(key) == 1 and type(key[0]) in fasttypes: return key[0] return _HashedSeq(key) def lru_cache(maxsize=100, typed=False): """Least-recently-used cache decorator. If *maxsize* is set to None, the LRU features are disabled and the cache can grow without bound. If *typed* is True, arguments of different types will be cached separately. For example, f(3.0) and f(3) will be treated as distinct calls with distinct results. Arguments to the cached function must be hashable. View the cache statistics named tuple (hits, misses, maxsize, currsize) with f.cache_info(). Clear the cache and statistics with f.cache_clear(). Access the underlying function with f.__wrapped__. See: https://en.wikipedia.org/wiki/Cache_algorithms#Least_Recently_Used """ # Users should only access the lru_cache through its public API: # cache_info, cache_clear, and f.__wrapped__ # The internals of the lru_cache are encapsulated for thread safety and # to allow the implementation to change (including a possible C version). def decorating_function(user_function): cache = dict() stats = [0, 0] # make statistics updateable non-locally HITS, MISSES = 0, 1 # names for the stats fields make_key = _make_key cache_get = cache.get # bound method to lookup key or return None _len = len # localize the global len() function lock = RLock() # because linkedlist updates aren't threadsafe root = [] # root of the circular doubly linked list root[:] = [root, root, None, None] # initialize by pointing to self nonlocal_root = [root] # make updateable non-locally PREV, NEXT, KEY, RESULT = 0, 1, 2, 3 # names for the link fields if maxsize == 0: def wrapper(*args, **kwds): # no caching, just do a statistics update after a successful call result = user_function(*args, **kwds) stats[MISSES] += 1 return result elif maxsize is None: def wrapper(*args, **kwds): # simple caching without ordering or size limit key = make_key(args, kwds, typed) result = cache_get(key, root) # root used here as a unique not-found sentinel if result is not root: stats[HITS] += 1 return result result = user_function(*args, **kwds) cache[key] = result stats[MISSES] += 1 return result else: def wrapper(*args, **kwds): # size limited caching that tracks accesses by recency try: key = make_key(args, kwds, typed) if kwds or typed else args except TypeError: stats[MISSES] += 1 return user_function(*args, **kwds) with lock: link = cache_get(key) if link is not None: # record recent use of the key by moving it to the front of the list root, = nonlocal_root link_prev, link_next, key, result = link link_prev[NEXT] = link_next link_next[PREV] = link_prev last = root[PREV] last[NEXT] = root[PREV] = link link[PREV] = last link[NEXT] = root stats[HITS] += 1 return result result = user_function(*args, **kwds) with lock: root, = nonlocal_root if key in cache: # getting here means that this same key was added to the # cache while the lock was released. since the link # update is already done, we need only return the # computed result and update the count of misses. pass elif _len(cache) >= maxsize: # use the old root to store the new key and result oldroot = root oldroot[KEY] = key oldroot[RESULT] = result # empty the oldest link and make it the new root root = nonlocal_root[0] = oldroot[NEXT] oldkey = root[KEY] oldvalue = root[RESULT] root[KEY] = root[RESULT] = None # now update the cache dictionary for the new links del cache[oldkey] cache[key] = oldroot else: # put result in a new link at the front of the list last = root[PREV] link = [last, root, key, result] last[NEXT] = root[PREV] = cache[key] = link stats[MISSES] += 1 return result def cache_info(): """Report cache statistics""" with lock: return _CacheInfo(stats[HITS], stats[MISSES], maxsize, len(cache)) def cache_clear(): """Clear the cache and cache statistics""" with lock: cache.clear() root = nonlocal_root[0] root[:] = [root, root, None, None] stats[:] = [0, 0] wrapper.__wrapped__ = user_function wrapper.cache_info = cache_info wrapper.cache_clear = cache_clear return update_wrapper(wrapper, user_function) return decorating_function ### End of backported lru_cache if sys.version_info[:2] >= (3, 3): # 3.2 has an lru_cache with an incompatible API from functools import lru_cache try: from itertools import filterfalse except ImportError: # Python 2.7 def filterfalse(pred, itr): return filter(lambda x: not pred(x), itr)

ffb64f545d86050727bec7569564f81851771f369b1675fa4095d87eb66604dc

"""Algorithms for computing symbolic roots of polynomials. """ from __future__ import print_function, division import math from sympy.core import S, I, pi from sympy.core.compatibility import ordered, range, reduce from sympy.core.exprtools import factor_terms from sympy.core.function import _mexpand from sympy.core.logic import fuzzy_not from sympy.core.mul import expand_2arg, Mul from sympy.core.numbers import Rational, igcd, comp from sympy.core.power import Pow from sympy.core.relational import Eq from sympy.core.symbol import Dummy, Symbol, symbols from sympy.core.sympify import sympify from sympy.functions import exp, sqrt, im, cos, acos, Piecewise from sympy.functions.elementary.miscellaneous import root from sympy.ntheory import divisors, isprime, nextprime from sympy.polys.polyerrors import (PolynomialError, GeneratorsNeeded, DomainError) from sympy.polys.polyquinticconst import PolyQuintic from sympy.polys.polytools import Poly, cancel, factor, gcd_list, discriminant from sympy.polys.rationaltools import together from sympy.polys.specialpolys import cyclotomic_poly from sympy.simplify import simplify, powsimp from sympy.utilities import public def roots_linear(f): """Returns a list of roots of a linear polynomial.""" r = -f.nth(0)/f.nth(1) dom = f.get_domain() if not dom.is_Numerical: if dom.is_Composite: r = factor(r) else: r = simplify(r) return [r] def roots_quadratic(f): """Returns a list of roots of a quadratic polynomial. If the domain is ZZ then the roots will be sorted with negatives coming before positives. The ordering will be the same for any numerical coefficients as long as the assumptions tested are correct, otherwise the ordering will not be sorted (but will be canonical). """ a, b, c = f.all_coeffs() dom = f.get_domain() def _sqrt(d): # remove squares from square root since both will be represented # in the results; a similar thing is happening in roots() but # must be duplicated here because not all quadratics are binomials co = [] other = [] for di in Mul.make_args(d): if di.is_Pow and di.exp.is_Integer and di.exp % 2 == 0: co.append(Pow(di.base, di.exp//2)) else: other.append(di) if co: d = Mul(*other) co = Mul(*co) return co*sqrt(d) return sqrt(d) def _simplify(expr): if dom.is_Composite: return factor(expr) else: return simplify(expr) if c is S.Zero: r0, r1 = S.Zero, -b/a if not dom.is_Numerical: r1 = _simplify(r1) elif r1.is_negative: r0, r1 = r1, r0 elif b is S.Zero: r = -c/a if not dom.is_Numerical: r = _simplify(r) R = _sqrt(r) r0 = -R r1 = R else: d = b**2 - 4*a*c A = 2*a B = -b/A if not dom.is_Numerical: d = _simplify(d) B = _simplify(B) D = factor_terms(_sqrt(d)/A) r0 = B - D r1 = B + D if a.is_negative: r0, r1 = r1, r0 elif not dom.is_Numerical: r0, r1 = [expand_2arg(i) for i in (r0, r1)] return [r0, r1] def roots_cubic(f, trig=False): """Returns a list of roots of a cubic polynomial. References ========== [1] https://en.wikipedia.org/wiki/Cubic_function, General formula for roots, (accessed November 17, 2014). """ if trig: a, b, c, d = f.all_coeffs() p = (3*a*c - b**2)/3/a**2 q = (2*b**3 - 9*a*b*c + 27*a**2*d)/(27*a**3) D = 18*a*b*c*d - 4*b**3*d + b**2*c**2 - 4*a*c**3 - 27*a**2*d**2 if (D > 0) == True: rv = [] for k in range(3): rv.append(2*sqrt(-p/3)*cos(acos(3*q/2/p*sqrt(-3/p))/3 - k*2*pi/3)) return [i - b/3/a for i in rv] _, a, b, c = f.monic().all_coeffs() if c is S.Zero: x1, x2 = roots([1, a, b], multiple=True) return [x1, S.Zero, x2] p = b - a**2/3 q = c - a*b/3 + 2*a**3/27 pon3 = p/3 aon3 = a/3 u1 = None if p is S.Zero: if q is S.Zero: return [-aon3]*3 if q.is_real: if q.is_positive: u1 = -root(q, 3) elif q.is_negative: u1 = root(-q, 3) elif q is S.Zero: y1, y2 = roots([1, 0, p], multiple=True) return [tmp - aon3 for tmp in [y1, S.Zero, y2]] elif q.is_real and q.is_negative: u1 = -root(-q/2 + sqrt(q**2/4 + pon3**3), 3) coeff = I*sqrt(3)/2 if u1 is None: u1 = S(1) u2 = -S.Half + coeff u3 = -S.Half - coeff a, b, c, d = S(1), a, b, c D0 = b**2 - 3*a*c D1 = 2*b**3 - 9*a*b*c + 27*a**2*d C = root((D1 + sqrt(D1**2 - 4*D0**3))/2, 3) return [-(b + uk*C + D0/C/uk)/3/a for uk in [u1, u2, u3]] u2 = u1*(-S.Half + coeff) u3 = u1*(-S.Half - coeff) if p is S.Zero: return [u1 - aon3, u2 - aon3, u3 - aon3] soln = [ -u1 + pon3/u1 - aon3, -u2 + pon3/u2 - aon3, -u3 + pon3/u3 - aon3 ] return soln def _roots_quartic_euler(p, q, r, a): """ Descartes-Euler solution of the quartic equation Parameters ========== p, q, r: coefficients of ``x**4 + p*x**2 + q*x + r`` a: shift of the roots Notes ===== This is a helper function for ``roots_quartic``. Look for solutions of the form :: ``x1 = sqrt(R) - sqrt(A + B*sqrt(R))`` ``x2 = -sqrt(R) - sqrt(A - B*sqrt(R))`` ``x3 = -sqrt(R) + sqrt(A - B*sqrt(R))`` ``x4 = sqrt(R) + sqrt(A + B*sqrt(R))`` To satisfy the quartic equation one must have ``p = -2*(R + A); q = -4*B*R; r = (R - A)**2 - B**2*R`` so that ``R`` must satisfy the Descartes-Euler resolvent equation ``64*R**3 + 32*p*R**2 + (4*p**2 - 16*r)*R - q**2 = 0`` If the resolvent does not have a rational solution, return None; in that case it is likely that the Ferrari method gives a simpler solution. Examples ======== >>> from sympy import S >>> from sympy.polys.polyroots import _roots_quartic_euler >>> p, q, r = -S(64)/5, -S(512)/125, -S(1024)/3125 >>> _roots_quartic_euler(p, q, r, S(0))[0] -sqrt(32*sqrt(5)/125 + 16/5) + 4*sqrt(5)/5 """ # solve the resolvent equation x = Dummy('x') eq = 64*x**3 + 32*p*x**2 + (4*p**2 - 16*r)*x - q**2 xsols = list(roots(Poly(eq, x), cubics=False).keys()) xsols = [sol for sol in xsols if sol.is_rational and sol.is_nonzero] if not xsols: return None R = max(xsols) c1 = sqrt(R) B = -q*c1/(4*R) A = -R - p/2 c2 = sqrt(A + B) c3 = sqrt(A - B) return [c1 - c2 - a, -c1 - c3 - a, -c1 + c3 - a, c1 + c2 - a] def roots_quartic(f): r""" Returns a list of roots of a quartic polynomial. There are many references for solving quartic expressions available [1-5]. This reviewer has found that many of them require one to select from among 2 or more possible sets of solutions and that some solutions work when one is searching for real roots but don't work when searching for complex roots (though this is not always stated clearly). The following routine has been tested and found to be correct for 0, 2 or 4 complex roots. The quasisymmetric case solution [6] looks for quartics that have the form `x**4 + A*x**3 + B*x**2 + C*x + D = 0` where `(C/A)**2 = D`. Although no general solution that is always applicable for all coefficients is known to this reviewer, certain conditions are tested to determine the simplest 4 expressions that can be returned: 1) `f = c + a*(a**2/8 - b/2) == 0` 2) `g = d - a*(a*(3*a**2/256 - b/16) + c/4) = 0` 3) if `f != 0` and `g != 0` and `p = -d + a*c/4 - b**2/12` then a) `p == 0` b) `p != 0` Examples ======== >>> from sympy import Poly, symbols, I >>> from sympy.polys.polyroots import roots_quartic >>> r = roots_quartic(Poly('x**4-6*x**3+17*x**2-26*x+20')) >>> # 4 complex roots: 1+-I*sqrt(3), 2+-I >>> sorted(str(tmp.evalf(n=2)) for tmp in r) ['1.0 + 1.7*I', '1.0 - 1.7*I', '2.0 + 1.0*I', '2.0 - 1.0*I'] References ========== 1. http://mathforum.org/dr.math/faq/faq.cubic.equations.html 2. https://en.wikipedia.org/wiki/Quartic_function#Summary_of_Ferrari.27s_method 3. http://planetmath.org/encyclopedia/GaloisTheoreticDerivationOfTheQuarticFormula.html 4. http://staff.bath.ac.uk/masjhd/JHD-CA.pdf 5. http://www.albmath.org/files/Math_5713.pdf 6. http://www.statemaster.com/encyclopedia/Quartic-equation 7. eqworld.ipmnet.ru/en/solutions/ae/ae0108.pdf """ _, a, b, c, d = f.monic().all_coeffs() if not d: return [S.Zero] + roots([1, a, b, c], multiple=True) elif (c/a)**2 == d: x, m = f.gen, c/a g = Poly(x**2 + a*x + b - 2*m, x) z1, z2 = roots_quadratic(g) h1 = Poly(x**2 - z1*x + m, x) h2 = Poly(x**2 - z2*x + m, x) r1 = roots_quadratic(h1) r2 = roots_quadratic(h2) return r1 + r2 else: a2 = a**2 e = b - 3*a2/8 f = _mexpand(c + a*(a2/8 - b/2)) g = _mexpand(d - a*(a*(3*a2/256 - b/16) + c/4)) aon4 = a/4 if f is S.Zero: y1, y2 = [sqrt(tmp) for tmp in roots([1, e, g], multiple=True)] return [tmp - aon4 for tmp in [-y1, -y2, y1, y2]] if g is S.Zero: y = [S.Zero] + roots([1, 0, e, f], multiple=True) return [tmp - aon4 for tmp in y] else: # Descartes-Euler method, see [7] sols = _roots_quartic_euler(e, f, g, aon4) if sols: return sols # Ferrari method, see [1, 2] a2 = a**2 e = b - 3*a2/8 f = c + a*(a2/8 - b/2) g = d - a*(a*(3*a2/256 - b/16) + c/4) p = -e**2/12 - g q = -e**3/108 + e*g/3 - f**2/8 TH = Rational(1, 3) def _ans(y): w = sqrt(e + 2*y) arg1 = 3*e + 2*y arg2 = 2*f/w ans = [] for s in [-1, 1]: root = sqrt(-(arg1 + s*arg2)) for t in [-1, 1]: ans.append((s*w - t*root)/2 - aon4) return ans # p == 0 case y1 = -5*e/6 - q**TH if p.is_zero: return _ans(y1) # if p != 0 then u below is not 0 root = sqrt(q**2/4 + p**3/27) r = -q/2 + root # or -q/2 - root u = r**TH # primary root of solve(x**3 - r, x) y2 = -5*e/6 + u - p/u/3 if fuzzy_not(p.is_zero): return _ans(y2) # sort it out once they know the values of the coefficients return [Piecewise((a1, Eq(p, 0)), (a2, True)) for a1, a2 in zip(_ans(y1), _ans(y2))] def roots_binomial(f): """Returns a list of roots of a binomial polynomial. If the domain is ZZ then the roots will be sorted with negatives coming before positives. The ordering will be the same for any numerical coefficients as long as the assumptions tested are correct, otherwise the ordering will not be sorted (but will be canonical). """ n = f.degree() a, b = f.nth(n), f.nth(0) base = -cancel(b/a) alpha = root(base, n) if alpha.is_number: alpha = alpha.expand(complex=True) # define some parameters that will allow us to order the roots. # If the domain is ZZ this is guaranteed to return roots sorted # with reals before non-real roots and non-real sorted according # to real part and imaginary part, e.g. -1, 1, -1 + I, 2 - I neg = base.is_negative even = n % 2 == 0 if neg: if even == True and (base + 1).is_positive: big = True else: big = False # get the indices in the right order so the computed # roots will be sorted when the domain is ZZ ks = [] imax = n//2 if even: ks.append(imax) imax -= 1 if not neg: ks.append(0) for i in range(imax, 0, -1): if neg: ks.extend([i, -i]) else: ks.extend([-i, i]) if neg: ks.append(0) if big: for i in range(0, len(ks), 2): pair = ks[i: i + 2] pair = list(reversed(pair)) # compute the roots roots, d = [], 2*I*pi/n for k in ks: zeta = exp(k*d).expand(complex=True) roots.append((alpha*zeta).expand(power_base=False)) return roots def _inv_totient_estimate(m): """ Find ``(L, U)`` such that ``L <= phi^-1(m) <= U``. Examples ======== >>> from sympy.polys.polyroots import _inv_totient_estimate >>> _inv_totient_estimate(192) (192, 840) >>> _inv_totient_estimate(400) (400, 1750) """ primes = [ d + 1 for d in divisors(m) if isprime(d + 1) ] a, b = 1, 1 for p in primes: a *= p b *= p - 1 L = m U = int(math.ceil(m*(float(a)/b))) P = p = 2 primes = [] while P <= U: p = nextprime(p) primes.append(p) P *= p P //= p b = 1 for p in primes[:-1]: b *= p - 1 U = int(math.ceil(m*(float(P)/b))) return L, U def roots_cyclotomic(f, factor=False): """Compute roots of cyclotomic polynomials. """ L, U = _inv_totient_estimate(f.degree()) for n in range(L, U + 1): g = cyclotomic_poly(n, f.gen, polys=True) if f == g: break else: # pragma: no cover raise RuntimeError("failed to find index of a cyclotomic polynomial") roots = [] if not factor: # get the indices in the right order so the computed # roots will be sorted h = n//2 ks = [i for i in range(1, n + 1) if igcd(i, n) == 1] ks.sort(key=lambda x: (x, -1) if x <= h else (abs(x - n), 1)) d = 2*I*pi/n for k in reversed(ks): roots.append(exp(k*d).expand(complex=True)) else: g = Poly(f, extension=root(-1, n)) for h, _ in ordered(g.factor_list()[1]): roots.append(-h.TC()) return roots def roots_quintic(f): """ Calculate exact roots of a solvable quintic """ result = [] coeff_5, coeff_4, p, q, r, s = f.all_coeffs() # Eqn must be of the form x^5 + px^3 + qx^2 + rx + s if coeff_4: return result if coeff_5 != 1: l = [p/coeff_5, q/coeff_5, r/coeff_5, s/coeff_5] if not all(coeff.is_Rational for coeff in l): return result f = Poly(f/coeff_5) quintic = PolyQuintic(f) # Eqn standardized. Algo for solving starts here if not f.is_irreducible: return result f20 = quintic.f20 # Check if f20 has linear factors over domain Z if f20.is_irreducible: return result # Now, we know that f is solvable for _factor in f20.factor_list()[1]: if _factor[0].is_linear: theta = _factor[0].root(0) break d = discriminant(f) delta = sqrt(d) # zeta = a fifth root of unity zeta1, zeta2, zeta3, zeta4 = quintic.zeta T = quintic.T(theta, d) tol = S(1e-10) alpha = T[1] + T[2]*delta alpha_bar = T[1] - T[2]*delta beta = T[3] + T[4]*delta beta_bar = T[3] - T[4]*delta disc = alpha**2 - 4*beta disc_bar = alpha_bar**2 - 4*beta_bar l0 = quintic.l0(theta) l1 = _quintic_simplify((-alpha + sqrt(disc)) / S(2)) l4 = _quintic_simplify((-alpha - sqrt(disc)) / S(2)) l2 = _quintic_simplify((-alpha_bar + sqrt(disc_bar)) / S(2)) l3 = _quintic_simplify((-alpha_bar - sqrt(disc_bar)) / S(2)) order = quintic.order(theta, d) test = (order*delta.n()) - ( (l1.n() - l4.n())*(l2.n() - l3.n()) ) # Comparing floats if not comp(test, 0, tol): l2, l3 = l3, l2 # Now we have correct order of l's R1 = l0 + l1*zeta1 + l2*zeta2 + l3*zeta3 + l4*zeta4 R2 = l0 + l3*zeta1 + l1*zeta2 + l4*zeta3 + l2*zeta4 R3 = l0 + l2*zeta1 + l4*zeta2 + l1*zeta3 + l3*zeta4 R4 = l0 + l4*zeta1 + l3*zeta2 + l2*zeta3 + l1*zeta4 Res = [None, [None]*5, [None]*5, [None]*5, [None]*5] Res_n = [None, [None]*5, [None]*5, [None]*5, [None]*5] sol = Symbol('sol') # Simplifying improves performance a lot for exact expressions R1 = _quintic_simplify(R1) R2 = _quintic_simplify(R2) R3 = _quintic_simplify(R3) R4 = _quintic_simplify(R4) # Solve imported here. Causing problems if imported as 'solve' # and hence the changed name from sympy.solvers.solvers import solve as _solve a, b = symbols('a b', cls=Dummy) _sol = _solve( sol**5 - a - I*b, sol) for i in range(5): _sol[i] = factor(_sol[i]) R1 = R1.as_real_imag() R2 = R2.as_real_imag() R3 = R3.as_real_imag() R4 = R4.as_real_imag() for i, currentroot in enumerate(_sol): Res[1][i] = _quintic_simplify(currentroot.subs({ a: R1[0], b: R1[1] })) Res[2][i] = _quintic_simplify(currentroot.subs({ a: R2[0], b: R2[1] })) Res[3][i] = _quintic_simplify(currentroot.subs({ a: R3[0], b: R3[1] })) Res[4][i] = _quintic_simplify(currentroot.subs({ a: R4[0], b: R4[1] })) for i in range(1, 5): for j in range(5): Res_n[i][j] = Res[i][j].n() Res[i][j] = _quintic_simplify(Res[i][j]) r1 = Res[1][0] r1_n = Res_n[1][0] for i in range(5): if comp(im(r1_n*Res_n[4][i]), 0, tol): r4 = Res[4][i] break # Now we have various Res values. Each will be a list of five # values. We have to pick one r value from those five for each Res u, v = quintic.uv(theta, d) testplus = (u + v*delta*sqrt(5)).n() testminus = (u - v*delta*sqrt(5)).n() # Evaluated numbers suffixed with _n # We will use evaluated numbers for calculation. Much faster. r4_n = r4.n() r2 = r3 = None for i in range(5): r2temp_n = Res_n[2][i] for j in range(5): # Again storing away the exact number and using # evaluated numbers in computations r3temp_n = Res_n[3][j] if (comp((r1_n*r2temp_n**2 + r4_n*r3temp_n**2 - testplus).n(), 0, tol) and comp((r3temp_n*r1_n**2 + r2temp_n*r4_n**2 - testminus).n(), 0, tol)): r2 = Res[2][i] r3 = Res[3][j] break if r2: break # Now, we have r's so we can get roots x1 = (r1 + r2 + r3 + r4)/5 x2 = (r1*zeta4 + r2*zeta3 + r3*zeta2 + r4*zeta1)/5 x3 = (r1*zeta3 + r2*zeta1 + r3*zeta4 + r4*zeta2)/5 x4 = (r1*zeta2 + r2*zeta4 + r3*zeta1 + r4*zeta3)/5 x5 = (r1*zeta1 + r2*zeta2 + r3*zeta3 + r4*zeta4)/5 result = [x1, x2, x3, x4, x5] # Now check if solutions are distinct saw = set() for r in result: r = r.n(2) if r in saw: # Roots were identical. Abort, return [] # and fall back to usual solve return [] saw.add(r) return result def _quintic_simplify(expr): expr = powsimp(expr) expr = cancel(expr) return together(expr) def _integer_basis(poly): """Compute coefficient basis for a polynomial over integers. Returns the integer ``div`` such that substituting ``x = div*y`` ``p(x) = m*q(y)`` where the coefficients of ``q`` are smaller than those of ``p``. For example ``x**5 + 512*x + 1024 = 0`` with ``div = 4`` becomes ``y**5 + 2*y + 1 = 0`` Returns the integer ``div`` or ``None`` if there is no possible scaling. Examples ======== >>> from sympy.polys import Poly >>> from sympy.abc import x >>> from sympy.polys.polyroots import _integer_basis >>> p = Poly(x**5 + 512*x + 1024, x, domain='ZZ') >>> _integer_basis(p) 4 """ monoms, coeffs = list(zip(*poly.terms())) monoms, = list(zip(*monoms)) coeffs = list(map(abs, coeffs)) if coeffs[0] < coeffs[-1]: coeffs = list(reversed(coeffs)) n = monoms[0] monoms = [n - i for i in reversed(monoms)] else: return None monoms = monoms[:-1] coeffs = coeffs[:-1] divs = reversed(divisors(gcd_list(coeffs))[1:]) try: div = next(divs) except StopIteration: return None while True: for monom, coeff in zip(monoms, coeffs): if coeff % div**monom != 0: try: div = next(divs) except StopIteration: return None else: break else: return div def preprocess_roots(poly): """Try to get rid of symbolic coefficients from ``poly``. """ coeff = S.One poly_func = poly.func try: _, poly = poly.clear_denoms(convert=True) except DomainError: return coeff, poly poly = poly.primitive()[1] poly = poly.retract() # TODO: This is fragile. Figure out how to make this independent of construct_domain(). if poly.get_domain().is_Poly and all(c.is_term for c in poly.rep.coeffs()): poly = poly.inject() strips = list(zip(*poly.monoms())) gens = list(poly.gens[1:]) base, strips = strips[0], strips[1:] for gen, strip in zip(list(gens), strips): reverse = False if strip[0] < strip[-1]: strip = reversed(strip) reverse = True ratio = None for a, b in zip(base, strip): if not a and not b: continue elif not a or not b: break elif b % a != 0: break else: _ratio = b // a if ratio is None: ratio = _ratio elif ratio != _ratio: break else: if reverse: ratio = -ratio poly = poly.eval(gen, 1) coeff *= gen**(-ratio) gens.remove(gen) if gens: poly = poly.eject(*gens) if poly.is_univariate and poly.get_domain().is_ZZ: basis = _integer_basis(poly) if basis is not None: n = poly.degree() def func(k, coeff): return coeff//basis**(n - k[0]) poly = poly.termwise(func) coeff *= basis if not isinstance(poly, poly_func): poly = poly_func(poly) return coeff, poly @public def roots(f, *gens, **flags): """ Computes symbolic roots of a univariate polynomial. Given a univariate polynomial f with symbolic coefficients (or a list of the polynomial's coefficients), returns a dictionary with its roots and their multiplicities. Only roots expressible via radicals will be returned. To get a complete set of roots use RootOf class or numerical methods instead. By default cubic and quartic formulas are used in the algorithm. To disable them because of unreadable output set ``cubics=False`` or ``quartics=False`` respectively. If cubic roots are real but are expressed in terms of complex numbers (casus irreducibilis [1]) the ``trig`` flag can be set to True to have the solutions returned in terms of cosine and inverse cosine functions. To get roots from a specific domain set the ``filter`` flag with one of the following specifiers: Z, Q, R, I, C. By default all roots are returned (this is equivalent to setting ``filter='C'``). By default a dictionary is returned giving a compact result in case of multiple roots. However to get a list containing all those roots set the ``multiple`` flag to True; the list will have identical roots appearing next to each other in the result. (For a given Poly, the all_roots method will give the roots in sorted numerical order.) Examples ======== >>> from sympy import Poly, roots >>> from sympy.abc import x, y >>> roots(x**2 - 1, x) {-1: 1, 1: 1} >>> p = Poly(x**2-1, x) >>> roots(p) {-1: 1, 1: 1} >>> p = Poly(x**2-y, x, y) >>> roots(Poly(p, x)) {-sqrt(y): 1, sqrt(y): 1} >>> roots(x**2 - y, x) {-sqrt(y): 1, sqrt(y): 1} >>> roots([1, 0, -1]) {-1: 1, 1: 1} References ========== .. [1] https://en.wikipedia.org/wiki/Cubic_function#Trigonometric_.28and_hyperbolic.29_method """ from sympy.polys.polytools import to_rational_coeffs flags = dict(flags) auto = flags.pop('auto', True) cubics = flags.pop('cubics', True) trig = flags.pop('trig', False) quartics = flags.pop('quartics', True) quintics = flags.pop('quintics', False) multiple = flags.pop('multiple', False) filter = flags.pop('filter', None) predicate = flags.pop('predicate', None) if isinstance(f, list): if gens: raise ValueError('redundant generators given') x = Dummy('x') poly, i = {}, len(f) - 1 for coeff in f: poly[i], i = sympify(coeff), i - 1 f = Poly(poly, x, field=True) else: try: f = Poly(f, *gens, **flags) if f.length == 2 and f.degree() != 1: # check for foo**n factors in the constant n = f.degree() npow_bases = [] others = [] expr = f.as_expr() con = expr.as_independent(*gens)[0] for p in Mul.make_args(con): if p.is_Pow and not p.exp % n: npow_bases.append(p.base**(p.exp/n)) else: others.append(p) if npow_bases: b = Mul(*npow_bases) B = Dummy() d = roots(Poly(expr - con + B**n*Mul(*others), *gens, **flags), *gens, **flags) rv = {} for k, v in d.items(): rv[k.subs(B, b)] = v return rv except GeneratorsNeeded: if multiple: return [] else: return {} if f.is_multivariate: raise PolynomialError('multivariate polynomials are not supported') def _update_dict(result, currentroot, k): if currentroot in result: result[currentroot] += k else: result[currentroot] = k def _try_decompose(f): """Find roots using functional decomposition. """ factors, roots = f.decompose(), [] for currentroot in _try_heuristics(factors[0]): roots.append(currentroot) for currentfactor in factors[1:]: previous, roots = list(roots), [] for currentroot in previous: g = currentfactor - Poly(currentroot, f.gen) for currentroot in _try_heuristics(g): roots.append(currentroot) return roots def _try_heuristics(f): """Find roots using formulas and some tricks. """ if f.is_ground: return [] if f.is_monomial: return [S(0)]*f.degree() if f.length() == 2: if f.degree() == 1: return list(map(cancel, roots_linear(f))) else: return roots_binomial(f) result = [] for i in [-1, 1]: if not f.eval(i): f = f.quo(Poly(f.gen - i, f.gen)) result.append(i) break n = f.degree() if n == 1: result += list(map(cancel, roots_linear(f))) elif n == 2: result += list(map(cancel, roots_quadratic(f))) elif f.is_cyclotomic: result += roots_cyclotomic(f) elif n == 3 and cubics: result += roots_cubic(f, trig=trig) elif n == 4 and quartics: result += roots_quartic(f) elif n == 5 and quintics: result += roots_quintic(f) return result (k,), f = f.terms_gcd() if not k: zeros = {} else: zeros = {S(0): k} coeff, f = preprocess_roots(f) if auto and f.get_domain().is_Ring: f = f.to_field() rescale_x = None translate_x = None result = {} if not f.is_ground: dom = f.get_domain() if not dom.is_Exact and dom.is_Numerical: for r in f.nroots(): _update_dict(result, r, 1) elif f.degree() == 1: result[roots_linear(f)[0]] = 1 elif f.length() == 2: roots_fun = roots_quadratic if f.degree() == 2 else roots_binomial for r in roots_fun(f): _update_dict(result, r, 1) else: _, factors = Poly(f.as_expr()).factor_list() if len(factors) == 1 and f.degree() == 2: for r in roots_quadratic(f): _update_dict(result, r, 1) else: if len(factors) == 1 and factors[0][1] == 1: if f.get_domain().is_EX: res = to_rational_coeffs(f) if res: if res[0] is None: translate_x, f = res[2:] else: rescale_x, f = res[1], res[-1] result = roots(f) if not result: for currentroot in _try_decompose(f): _update_dict(result, currentroot, 1) else: for r in _try_heuristics(f): _update_dict(result, r, 1) else: for currentroot in _try_decompose(f): _update_dict(result, currentroot, 1) else: for currentfactor, k in factors: for r in _try_heuristics(Poly(currentfactor, f.gen, field=True)): _update_dict(result, r, k) if coeff is not S.One: _result, result, = result, {} for currentroot, k in _result.items(): result[coeff*currentroot] = k result.update(zeros) if filter not in [None, 'C']: handlers = { 'Z': lambda r: r.is_Integer, 'Q': lambda r: r.is_Rational, 'R': lambda r: r.is_real, 'I': lambda r: r.is_imaginary, } try: query = handlers[filter] except KeyError: raise ValueError("Invalid filter: %s" % filter) for zero in dict(result).keys(): if not query(zero): del result[zero] if predicate is not None: for zero in dict(result).keys(): if not predicate(zero): del result[zero] if rescale_x: result1 = {} for k, v in result.items(): result1[k*rescale_x] = v result = result1 if translate_x: result1 = {} for k, v in result.items(): result1[k + translate_x] = v result = result1 if not multiple: return result else: zeros = [] for zero in ordered(result): zeros.extend([zero]*result[zero]) return zeros def root_factors(f, *gens, **args): """ Returns all factors of a univariate polynomial. Examples ======== >>> from sympy.abc import x, y >>> from sympy.polys.polyroots import root_factors >>> root_factors(x**2 - y, x) [x - sqrt(y), x + sqrt(y)] """ args = dict(args) filter = args.pop('filter', None) F = Poly(f, *gens, **args) if not F.is_Poly: return [f] if F.is_multivariate: raise ValueError('multivariate polynomials are not supported') x = F.gens[0] zeros = roots(F, filter=filter) if not zeros: factors = [F] else: factors, N = [], 0 for r, n in ordered(zeros.items()): factors, N = factors + [Poly(x - r, x)]*n, N + n if N < F.degree(): G = reduce(lambda p, q: p*q, factors) factors.append(F.quo(G)) if not isinstance(f, Poly): factors = [ f.as_expr() for f in factors ] return factors

9bd810abbe8c751da79198d97f58cb747ab6f45deb38a46b689e84eaba92792a

"""Arithmetics for dense recursive polynomials in ``K[x]`` or ``K[X]``. """ from __future__ import print_function, division from sympy.core.compatibility import range from sympy.polys.densebasic import ( dup_slice, dup_LC, dmp_LC, dup_degree, dmp_degree, dup_strip, dmp_strip, dmp_zero_p, dmp_zero, dmp_one_p, dmp_one, dmp_ground, dmp_zeros) from sympy.polys.polyerrors import (ExactQuotientFailed, PolynomialDivisionFailed) def dup_add_term(f, c, i, K): """ Add ``c*x**i`` to ``f`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add_term(x**2 - 1, ZZ(2), 4) 2*x**4 + x**2 - 1 """ if not c: return f n = len(f) m = n - i - 1 if i == n - 1: return dup_strip([f[0] + c] + f[1:]) else: if i >= n: return [c] + [K.zero]*(i - n) + f else: return f[:m] + [f[m] + c] + f[m + 1:] def dmp_add_term(f, c, i, u, K): """ Add ``c(x_2..x_u)*x_0**i`` to ``f`` in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add_term(x*y + 1, 2, 2) 2*x**2 + x*y + 1 """ if not u: return dup_add_term(f, c, i, K) v = u - 1 if dmp_zero_p(c, v): return f n = len(f) m = n - i - 1 if i == n - 1: return dmp_strip([dmp_add(f[0], c, v, K)] + f[1:], u) else: if i >= n: return [c] + dmp_zeros(i - n, v, K) + f else: return f[:m] + [dmp_add(f[m], c, v, K)] + f[m + 1:] def dup_sub_term(f, c, i, K): """ Subtract ``c*x**i`` from ``f`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub_term(2*x**4 + x**2 - 1, ZZ(2), 4) x**2 - 1 """ if not c: return f n = len(f) m = n - i - 1 if i == n - 1: return dup_strip([f[0] - c] + f[1:]) else: if i >= n: return [-c] + [K.zero]*(i - n) + f else: return f[:m] + [f[m] - c] + f[m + 1:] def dmp_sub_term(f, c, i, u, K): """ Subtract ``c(x_2..x_u)*x_0**i`` from ``f`` in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub_term(2*x**2 + x*y + 1, 2, 2) x*y + 1 """ if not u: return dup_add_term(f, -c, i, K) v = u - 1 if dmp_zero_p(c, v): return f n = len(f) m = n - i - 1 if i == n - 1: return dmp_strip([dmp_sub(f[0], c, v, K)] + f[1:], u) else: if i >= n: return [dmp_neg(c, v, K)] + dmp_zeros(i - n, v, K) + f else: return f[:m] + [dmp_sub(f[m], c, v, K)] + f[m + 1:] def dup_mul_term(f, c, i, K): """ Multiply ``f`` by ``c*x**i`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_mul_term(x**2 - 1, ZZ(3), 2) 3*x**4 - 3*x**2 """ if not c or not f: return [] else: return [ cf * c for cf in f ] + [K.zero]*i def dmp_mul_term(f, c, i, u, K): """ Multiply ``f`` by ``c(x_2..x_u)*x_0**i`` in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_mul_term(x**2*y + x, 3*y, 2) 3*x**4*y**2 + 3*x**3*y """ if not u: return dup_mul_term(f, c, i, K) v = u - 1 if dmp_zero_p(f, u): return f if dmp_zero_p(c, v): return dmp_zero(u) else: return [ dmp_mul(cf, c, v, K) for cf in f ] + dmp_zeros(i, v, K) def dup_add_ground(f, c, K): """ Add an element of the ground domain to ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add_ground(x**3 + 2*x**2 + 3*x + 4, ZZ(4)) x**3 + 2*x**2 + 3*x + 8 """ return dup_add_term(f, c, 0, K) def dmp_add_ground(f, c, u, K): """ Add an element of the ground domain to ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add_ground(x**3 + 2*x**2 + 3*x + 4, ZZ(4)) x**3 + 2*x**2 + 3*x + 8 """ return dmp_add_term(f, dmp_ground(c, u - 1), 0, u, K) def dup_sub_ground(f, c, K): """ Subtract an element of the ground domain from ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub_ground(x**3 + 2*x**2 + 3*x + 4, ZZ(4)) x**3 + 2*x**2 + 3*x """ return dup_sub_term(f, c, 0, K) def dmp_sub_ground(f, c, u, K): """ Subtract an element of the ground domain from ``f``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub_ground(x**3 + 2*x**2 + 3*x + 4, ZZ(4)) x**3 + 2*x**2 + 3*x """ return dmp_sub_term(f, dmp_ground(c, u - 1), 0, u, K) def dup_mul_ground(f, c, K): """ Multiply ``f`` by a constant value in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_mul_ground(x**2 + 2*x - 1, ZZ(3)) 3*x**2 + 6*x - 3 """ if not c or not f: return [] else: return [ cf * c for cf in f ] def dmp_mul_ground(f, c, u, K): """ Multiply ``f`` by a constant value in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_mul_ground(2*x + 2*y, ZZ(3)) 6*x + 6*y """ if not u: return dup_mul_ground(f, c, K) v = u - 1 return [ dmp_mul_ground(cf, c, v, K) for cf in f ] def dup_quo_ground(f, c, K): """ Quotient by a constant in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_quo_ground(3*x**2 + 2, ZZ(2)) x**2 + 1 >>> R, x = ring("x", QQ) >>> R.dup_quo_ground(3*x**2 + 2, QQ(2)) 3/2*x**2 + 1 """ if not c: raise ZeroDivisionError('polynomial division') if not f: return f if K.is_Field: return [ K.quo(cf, c) for cf in f ] else: return [ cf // c for cf in f ] def dmp_quo_ground(f, c, u, K): """ Quotient by a constant in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_quo_ground(2*x**2*y + 3*x, ZZ(2)) x**2*y + x >>> R, x,y = ring("x,y", QQ) >>> R.dmp_quo_ground(2*x**2*y + 3*x, QQ(2)) x**2*y + 3/2*x """ if not u: return dup_quo_ground(f, c, K) v = u - 1 return [ dmp_quo_ground(cf, c, v, K) for cf in f ] def dup_exquo_ground(f, c, K): """ Exact quotient by a constant in ``K[x]``. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x = ring("x", QQ) >>> R.dup_exquo_ground(x**2 + 2, QQ(2)) 1/2*x**2 + 1 """ if not c: raise ZeroDivisionError('polynomial division') if not f: return f return [ K.exquo(cf, c) for cf in f ] def dmp_exquo_ground(f, c, u, K): """ Exact quotient by a constant in ``K[X]``. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x,y = ring("x,y", QQ) >>> R.dmp_exquo_ground(x**2*y + 2*x, QQ(2)) 1/2*x**2*y + x """ if not u: return dup_exquo_ground(f, c, K) v = u - 1 return [ dmp_exquo_ground(cf, c, v, K) for cf in f ] def dup_lshift(f, n, K): """ Efficiently multiply ``f`` by ``x**n`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_lshift(x**2 + 1, 2) x**4 + x**2 """ if not f: return f else: return f + [K.zero]*n def dup_rshift(f, n, K): """ Efficiently divide ``f`` by ``x**n`` in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_rshift(x**4 + x**2, 2) x**2 + 1 >>> R.dup_rshift(x**4 + x**2 + 2, 2) x**2 + 1 """ return f[:-n] def dup_abs(f, K): """ Make all coefficients positive in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_abs(x**2 - 1) x**2 + 1 """ return [ K.abs(coeff) for coeff in f ] def dmp_abs(f, u, K): """ Make all coefficients positive in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_abs(x**2*y - x) x**2*y + x """ if not u: return dup_abs(f, K) v = u - 1 return [ dmp_abs(cf, v, K) for cf in f ] def dup_neg(f, K): """ Negate a polynomial in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_neg(x**2 - 1) -x**2 + 1 """ return [ -coeff for coeff in f ] def dmp_neg(f, u, K): """ Negate a polynomial in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_neg(x**2*y - x) -x**2*y + x """ if not u: return dup_neg(f, K) v = u - 1 return [ dmp_neg(cf, v, K) for cf in f ] def dup_add(f, g, K): """ Add dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add(x**2 - 1, x - 2) x**2 + x - 3 """ if not f: return g if not g: return f df = dup_degree(f) dg = dup_degree(g) if df == dg: return dup_strip([ a + b for a, b in zip(f, g) ]) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = g[:k], g[k:] return h + [ a + b for a, b in zip(f, g) ] def dmp_add(f, g, u, K): """ Add dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add(x**2 + y, x**2*y + x) x**2*y + x**2 + x + y """ if not u: return dup_add(f, g, K) df = dmp_degree(f, u) if df < 0: return g dg = dmp_degree(g, u) if dg < 0: return f v = u - 1 if df == dg: return dmp_strip([ dmp_add(a, b, v, K) for a, b in zip(f, g) ], u) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = g[:k], g[k:] return h + [ dmp_add(a, b, v, K) for a, b in zip(f, g) ] def dup_sub(f, g, K): """ Subtract dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub(x**2 - 1, x - 2) x**2 - x + 1 """ if not f: return dup_neg(g, K) if not g: return f df = dup_degree(f) dg = dup_degree(g) if df == dg: return dup_strip([ a - b for a, b in zip(f, g) ]) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = dup_neg(g[:k], K), g[k:] return h + [ a - b for a, b in zip(f, g) ] def dmp_sub(f, g, u, K): """ Subtract dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub(x**2 + y, x**2*y + x) -x**2*y + x**2 - x + y """ if not u: return dup_sub(f, g, K) df = dmp_degree(f, u) if df < 0: return dmp_neg(g, u, K) dg = dmp_degree(g, u) if dg < 0: return f v = u - 1 if df == dg: return dmp_strip([ dmp_sub(a, b, v, K) for a, b in zip(f, g) ], u) else: k = abs(df - dg) if df > dg: h, f = f[:k], f[k:] else: h, g = dmp_neg(g[:k], u, K), g[k:] return h + [ dmp_sub(a, b, v, K) for a, b in zip(f, g) ] def dup_add_mul(f, g, h, K): """ Returns ``f + g*h`` where ``f, g, h`` are in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_add_mul(x**2 - 1, x - 2, x + 2) 2*x**2 - 5 """ return dup_add(f, dup_mul(g, h, K), K) def dmp_add_mul(f, g, h, u, K): """ Returns ``f + g*h`` where ``f, g, h`` are in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_add_mul(x**2 + y, x, x + 2) 2*x**2 + 2*x + y """ return dmp_add(f, dmp_mul(g, h, u, K), u, K) def dup_sub_mul(f, g, h, K): """ Returns ``f - g*h`` where ``f, g, h`` are in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sub_mul(x**2 - 1, x - 2, x + 2) 3 """ return dup_sub(f, dup_mul(g, h, K), K) def dmp_sub_mul(f, g, h, u, K): """ Returns ``f - g*h`` where ``f, g, h`` are in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sub_mul(x**2 + y, x, x + 2) -2*x + y """ return dmp_sub(f, dmp_mul(g, h, u, K), u, K) def dup_mul(f, g, K): """ Multiply dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_mul(x - 2, x + 2) x**2 - 4 """ if f == g: return dup_sqr(f, K) if not (f and g): return [] df = dup_degree(f) dg = dup_degree(g) n = max(df, dg) + 1 if n < 100: h = [] for i in range(0, df + dg + 1): coeff = K.zero for j in range(max(0, i - dg), min(df, i) + 1): coeff += f[j]*g[i - j] h.append(coeff) return dup_strip(h) else: # Use Karatsuba's algorithm (divide and conquer), see e.g.: # Joris van der Hoeven, Relax But Don't Be Too Lazy, # J. Symbolic Computation, 11 (2002), section 3.1.1. n2 = n//2 fl, gl = dup_slice(f, 0, n2, K), dup_slice(g, 0, n2, K) fh = dup_rshift(dup_slice(f, n2, n, K), n2, K) gh = dup_rshift(dup_slice(g, n2, n, K), n2, K) lo, hi = dup_mul(fl, gl, K), dup_mul(fh, gh, K) mid = dup_mul(dup_add(fl, fh, K), dup_add(gl, gh, K), K) mid = dup_sub(mid, dup_add(lo, hi, K), K) return dup_add(dup_add(lo, dup_lshift(mid, n2, K), K), dup_lshift(hi, 2*n2, K), K) def dmp_mul(f, g, u, K): """ Multiply dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_mul(x*y + 1, x) x**2*y + x """ if not u: return dup_mul(f, g, K) if f == g: return dmp_sqr(f, u, K) df = dmp_degree(f, u) if df < 0: return f dg = dmp_degree(g, u) if dg < 0: return g h, v = [], u - 1 for i in range(0, df + dg + 1): coeff = dmp_zero(v) for j in range(max(0, i - dg), min(df, i) + 1): coeff = dmp_add(coeff, dmp_mul(f[j], g[i - j], v, K), v, K) h.append(coeff) return dmp_strip(h, u) def dup_sqr(f, K): """ Square dense polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_sqr(x**2 + 1) x**4 + 2*x**2 + 1 """ df, h = len(f) - 1, [] for i in range(0, 2*df + 1): c = K.zero jmin = max(0, i - df) jmax = min(i, df) n = jmax - jmin + 1 jmax = jmin + n // 2 - 1 for j in range(jmin, jmax + 1): c += f[j]*f[i - j] c += c if n & 1: elem = f[jmax + 1] c += elem**2 h.append(c) return dup_strip(h) def dmp_sqr(f, u, K): """ Square dense polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_sqr(x**2 + x*y + y**2) x**4 + 2*x**3*y + 3*x**2*y**2 + 2*x*y**3 + y**4 """ if not u: return dup_sqr(f, K) df = dmp_degree(f, u) if df < 0: return f h, v = [], u - 1 for i in range(0, 2*df + 1): c = dmp_zero(v) jmin = max(0, i - df) jmax = min(i, df) n = jmax - jmin + 1 jmax = jmin + n // 2 - 1 for j in range(jmin, jmax + 1): c = dmp_add(c, dmp_mul(f[j], f[i - j], v, K), v, K) c = dmp_mul_ground(c, K(2), v, K) if n & 1: elem = dmp_sqr(f[jmax + 1], v, K) c = dmp_add(c, elem, v, K) h.append(c) return dmp_strip(h, u) def dup_pow(f, n, K): """ Raise ``f`` to the ``n``-th power in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pow(x - 2, 3) x**3 - 6*x**2 + 12*x - 8 """ if not n: return [K.one] if n < 0: raise ValueError("can't raise polynomial to a negative power") if n == 1 or not f or f == [K.one]: return f g = [K.one] while True: n, m = n//2, n if m % 2: g = dup_mul(g, f, K) if not n: break f = dup_sqr(f, K) return g def dmp_pow(f, n, u, K): """ Raise ``f`` to the ``n``-th power in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_pow(x*y + 1, 3) x**3*y**3 + 3*x**2*y**2 + 3*x*y + 1 """ if not u: return dup_pow(f, n, K) if not n: return dmp_one(u, K) if n < 0: raise ValueError("can't raise polynomial to a negative power") if n == 1 or dmp_zero_p(f, u) or dmp_one_p(f, u, K): return f g = dmp_one(u, K) while True: n, m = n//2, n if m & 1: g = dmp_mul(g, f, u, K) if not n: break f = dmp_sqr(f, u, K) return g def dup_pdiv(f, g, K): """ Polynomial pseudo-division in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pdiv(x**2 + 1, 2*x - 4) (2*x + 4, 20) """ df = dup_degree(f) dg = dup_degree(g) q, r, dr = [], f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return q, r N = df - dg + 1 lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) j, N = dr - dg, N - 1 Q = dup_mul_ground(q, lc_g, K) q = dup_add_term(Q, lc_r, j, K) R = dup_mul_ground(r, lc_g, K) G = dup_mul_term(g, lc_r, j, K) r = dup_sub(R, G, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) c = lc_g**N q = dup_mul_ground(q, c, K) r = dup_mul_ground(r, c, K) return q, r def dup_prem(f, g, K): """ Polynomial pseudo-remainder in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_prem(x**2 + 1, 2*x - 4) 20 """ df = dup_degree(f) dg = dup_degree(g) r, dr = f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return r N = df - dg + 1 lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) j, N = dr - dg, N - 1 R = dup_mul_ground(r, lc_g, K) G = dup_mul_term(g, lc_r, j, K) r = dup_sub(R, G, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return dup_mul_ground(r, lc_g**N, K) def dup_pquo(f, g, K): """ Polynomial exact pseudo-quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pquo(x**2 - 1, 2*x - 2) 2*x + 2 >>> R.dup_pquo(x**2 + 1, 2*x - 4) 2*x + 4 """ return dup_pdiv(f, g, K)[0] def dup_pexquo(f, g, K): """ Polynomial pseudo-quotient in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_pexquo(x**2 - 1, 2*x - 2) 2*x + 2 >>> R.dup_pexquo(x**2 + 1, 2*x - 4) Traceback (most recent call last): ... ExactQuotientFailed: [2, -4] does not divide [1, 0, 1] """ q, r = dup_pdiv(f, g, K) if not r: return q else: raise ExactQuotientFailed(f, g) def dmp_pdiv(f, g, u, K): """ Polynomial pseudo-division in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_pdiv(x**2 + x*y, 2*x + 2) (2*x + 2*y - 2, -4*y + 4) """ if not u: return dup_pdiv(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") q, r, dr = dmp_zero(u), f, df if df < dg: return q, r N = df - dg + 1 lc_g = dmp_LC(g, K) while True: lc_r = dmp_LC(r, K) j, N = dr - dg, N - 1 Q = dmp_mul_term(q, lc_g, 0, u, K) q = dmp_add_term(Q, lc_r, j, u, K) R = dmp_mul_term(r, lc_g, 0, u, K) G = dmp_mul_term(g, lc_r, j, u, K) r = dmp_sub(R, G, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) c = dmp_pow(lc_g, N, u - 1, K) q = dmp_mul_term(q, c, 0, u, K) r = dmp_mul_term(r, c, 0, u, K) return q, r def dmp_prem(f, g, u, K): """ Polynomial pseudo-remainder in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_prem(x**2 + x*y, 2*x + 2) -4*y + 4 """ if not u: return dup_prem(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") r, dr = f, df if df < dg: return r N = df - dg + 1 lc_g = dmp_LC(g, K) while True: lc_r = dmp_LC(r, K) j, N = dr - dg, N - 1 R = dmp_mul_term(r, lc_g, 0, u, K) G = dmp_mul_term(g, lc_r, j, u, K) r = dmp_sub(R, G, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) c = dmp_pow(lc_g, N, u - 1, K) return dmp_mul_term(r, c, 0, u, K) def dmp_pquo(f, g, u, K): """ Polynomial exact pseudo-quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> f = x**2 + x*y >>> g = 2*x + 2*y >>> h = 2*x + 2 >>> R.dmp_pquo(f, g) 2*x >>> R.dmp_pquo(f, h) 2*x + 2*y - 2 """ return dmp_pdiv(f, g, u, K)[0] def dmp_pexquo(f, g, u, K): """ Polynomial pseudo-quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> f = x**2 + x*y >>> g = 2*x + 2*y >>> h = 2*x + 2 >>> R.dmp_pexquo(f, g) 2*x >>> R.dmp_pexquo(f, h) Traceback (most recent call last): ... ExactQuotientFailed: [[2], [2]] does not divide [[1], [1, 0], []] """ q, r = dmp_pdiv(f, g, u, K) if dmp_zero_p(r, u): return q else: raise ExactQuotientFailed(f, g) def dup_rr_div(f, g, K): """ Univariate division with remainder over a ring. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_rr_div(x**2 + 1, 2*x - 4) (0, x**2 + 1) """ df = dup_degree(f) dg = dup_degree(g) q, r, dr = [], f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return q, r lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) if lc_r % lc_g: break c = K.exquo(lc_r, lc_g) j = dr - dg q = dup_add_term(q, c, j, K) h = dup_mul_term(g, c, j, K) r = dup_sub(r, h, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dmp_rr_div(f, g, u, K): """ Multivariate division with remainder over a ring. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_rr_div(x**2 + x*y, 2*x + 2) (0, x**2 + x*y) """ if not u: return dup_rr_div(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") q, r, dr = dmp_zero(u), f, df if df < dg: return q, r lc_g, v = dmp_LC(g, K), u - 1 while True: lc_r = dmp_LC(r, K) c, R = dmp_rr_div(lc_r, lc_g, v, K) if not dmp_zero_p(R, v): break j = dr - dg q = dmp_add_term(q, c, j, u, K) h = dmp_mul_term(g, c, j, u, K) r = dmp_sub(r, h, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dup_ff_div(f, g, K): """ Polynomial division with remainder over a field. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x = ring("x", QQ) >>> R.dup_ff_div(x**2 + 1, 2*x - 4) (1/2*x + 1, 5) """ df = dup_degree(f) dg = dup_degree(g) q, r, dr = [], f, df if not g: raise ZeroDivisionError("polynomial division") elif df < dg: return q, r lc_g = dup_LC(g, K) while True: lc_r = dup_LC(r, K) c = K.exquo(lc_r, lc_g) j = dr - dg q = dup_add_term(q, c, j, K) h = dup_mul_term(g, c, j, K) r = dup_sub(r, h, K) _dr, dr = dr, dup_degree(r) if dr < dg: break elif dr == _dr and not K.is_Exact: # remove leading term created by rounding error r = dup_strip(r[1:]) dr = dup_degree(r) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dmp_ff_div(f, g, u, K): """ Polynomial division with remainder over a field. Examples ======== >>> from sympy.polys import ring, QQ >>> R, x,y = ring("x,y", QQ) >>> R.dmp_ff_div(x**2 + x*y, 2*x + 2) (1/2*x + 1/2*y - 1/2, -y + 1) """ if not u: return dup_ff_div(f, g, K) df = dmp_degree(f, u) dg = dmp_degree(g, u) if dg < 0: raise ZeroDivisionError("polynomial division") q, r, dr = dmp_zero(u), f, df if df < dg: return q, r lc_g, v = dmp_LC(g, K), u - 1 while True: lc_r = dmp_LC(r, K) c, R = dmp_ff_div(lc_r, lc_g, v, K) if not dmp_zero_p(R, v): break j = dr - dg q = dmp_add_term(q, c, j, u, K) h = dmp_mul_term(g, c, j, u, K) r = dmp_sub(r, h, u, K) _dr, dr = dr, dmp_degree(r, u) if dr < dg: break elif not (dr < _dr): raise PolynomialDivisionFailed(f, g, K) return q, r def dup_div(f, g, K): """ Polynomial division with remainder in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_div(x**2 + 1, 2*x - 4) (0, x**2 + 1) >>> R, x = ring("x", QQ) >>> R.dup_div(x**2 + 1, 2*x - 4) (1/2*x + 1, 5) """ if K.is_Field: return dup_ff_div(f, g, K) else: return dup_rr_div(f, g, K) def dup_rem(f, g, K): """ Returns polynomial remainder in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_rem(x**2 + 1, 2*x - 4) x**2 + 1 >>> R, x = ring("x", QQ) >>> R.dup_rem(x**2 + 1, 2*x - 4) 5 """ return dup_div(f, g, K)[1] def dup_quo(f, g, K): """ Returns exact polynomial quotient in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x = ring("x", ZZ) >>> R.dup_quo(x**2 + 1, 2*x - 4) 0 >>> R, x = ring("x", QQ) >>> R.dup_quo(x**2 + 1, 2*x - 4) 1/2*x + 1 """ return dup_div(f, g, K)[0] def dup_exquo(f, g, K): """ Returns polynomial quotient in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_exquo(x**2 - 1, x - 1) x + 1 >>> R.dup_exquo(x**2 + 1, 2*x - 4) Traceback (most recent call last): ... ExactQuotientFailed: [2, -4] does not divide [1, 0, 1] """ q, r = dup_div(f, g, K) if not r: return q else: raise ExactQuotientFailed(f, g) def dmp_div(f, g, u, K): """ Polynomial division with remainder in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_div(x**2 + x*y, 2*x + 2) (0, x**2 + x*y) >>> R, x,y = ring("x,y", QQ) >>> R.dmp_div(x**2 + x*y, 2*x + 2) (1/2*x + 1/2*y - 1/2, -y + 1) """ if K.is_Field: return dmp_ff_div(f, g, u, K) else: return dmp_rr_div(f, g, u, K) def dmp_rem(f, g, u, K): """ Returns polynomial remainder in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_rem(x**2 + x*y, 2*x + 2) x**2 + x*y >>> R, x,y = ring("x,y", QQ) >>> R.dmp_rem(x**2 + x*y, 2*x + 2) -y + 1 """ return dmp_div(f, g, u, K)[1] def dmp_quo(f, g, u, K): """ Returns exact polynomial quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ, QQ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_quo(x**2 + x*y, 2*x + 2) 0 >>> R, x,y = ring("x,y", QQ) >>> R.dmp_quo(x**2 + x*y, 2*x + 2) 1/2*x + 1/2*y - 1/2 """ return dmp_div(f, g, u, K)[0] def dmp_exquo(f, g, u, K): """ Returns polynomial quotient in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> f = x**2 + x*y >>> g = x + y >>> h = 2*x + 2 >>> R.dmp_exquo(f, g) x >>> R.dmp_exquo(f, h) Traceback (most recent call last): ... ExactQuotientFailed: [[2], [2]] does not divide [[1], [1, 0], []] """ q, r = dmp_div(f, g, u, K) if dmp_zero_p(r, u): return q else: raise ExactQuotientFailed(f, g) def dup_max_norm(f, K): """ Returns maximum norm of a polynomial in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_max_norm(-x**2 + 2*x - 3) 3 """ if not f: return K.zero else: return max(dup_abs(f, K)) def dmp_max_norm(f, u, K): """ Returns maximum norm of a polynomial in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_max_norm(2*x*y - x - 3) 3 """ if not u: return dup_max_norm(f, K) v = u - 1 return max([ dmp_max_norm(c, v, K) for c in f ]) def dup_l1_norm(f, K): """ Returns l1 norm of a polynomial in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_l1_norm(2*x**3 - 3*x**2 + 1) 6 """ if not f: return K.zero else: return sum(dup_abs(f, K)) def dmp_l1_norm(f, u, K): """ Returns l1 norm of a polynomial in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_l1_norm(2*x*y - x - 3) 6 """ if not u: return dup_l1_norm(f, K) v = u - 1 return sum([ dmp_l1_norm(c, v, K) for c in f ]) def dup_expand(polys, K): """ Multiply together several polynomials in ``K[x]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x = ring("x", ZZ) >>> R.dup_expand([x**2 - 1, x, 2]) 2*x**3 - 2*x """ if not polys: return [K.one] f = polys[0] for g in polys[1:]: f = dup_mul(f, g, K) return f def dmp_expand(polys, u, K): """ Multiply together several polynomials in ``K[X]``. Examples ======== >>> from sympy.polys import ring, ZZ >>> R, x,y = ring("x,y", ZZ) >>> R.dmp_expand([x**2 + y**2, x + 1]) x**3 + x**2 + x*y**2 + y**2 """ if not polys: return dmp_one(u, K) f = polys[0] for g in polys[1:]: f = dmp_mul(f, g, u, K) return f

18a862eb464006dde4cdb94e507af82d19b80083000146bbd42661f1747de57e

"""Tools and arithmetics for monomials of distributed polynomials. """ from __future__ import print_function, division from itertools import combinations_with_replacement, product from textwrap import dedent from sympy.core import Mul, S, Tuple, sympify from sympy.core.compatibility import exec_, iterable, range from sympy.polys.polyerrors import ExactQuotientFailed from sympy.polys.polyutils import PicklableWithSlots, dict_from_expr from sympy.utilities import public @public def itermonomials(variables, max_degree, min_degree = 0): r""" Generate a set of monomials of the degree greater than or equal to `min_degree` and less than or equal to `max_degree`. Given a set of variables `V` and a min_degree `N` and a max_degree `M` generate a set of monomials of degree less than or equal to `N` and greater than or equal to `M`. The total number of monomials in commutative variables is huge and is given by the following formula if `M = 0`: .. math:: \frac{(\#V + N)!}{\#V! N!} For example if we would like to generate a dense polynomial of a total degree `N = 50` and `M = 0`, which is the worst case, in 5 variables, assuming that exponents and all of coefficients are 32-bit long and stored in an array we would need almost 80 GiB of memory! Fortunately most polynomials, that we will encounter, are sparse. Examples ======== Consider monomials in commutative variables `x` and `y` and non-commutative variables `a` and `b`:: >>> from sympy import symbols >>> from sympy.polys.monomials import itermonomials >>> from sympy.polys.orderings import monomial_key >>> from sympy.abc import x, y >>> sorted(itermonomials([x, y], 2), key=monomial_key('grlex', [y, x])) [1, x, y, x**2, x*y, y**2] >>> sorted(itermonomials([x, y], 3), key=monomial_key('grlex', [y, x])) [1, x, y, x**2, x*y, y**2, x**3, x**2*y, x*y**2, y**3] >>> a, b = symbols('a, b', commutative=False) >>> itermonomials([a, b, x], 2) {1, a, a**2, b, b**2, x, x**2, a*b, b*a, x*a, x*b} >>> sorted(itermonomials([x, y], 2, 1), key=monomial_key('grlex', [y, x])) [x, y, x**2, x*y, y**2] """ if max_degree < 0 or min_degree > max_degree: return set() if not variables or max_degree == 0: return {S(1)} # Force to list in case of passed tuple or other incompatible collection variables = list(variables) + [S(1)] if all(variable.is_commutative for variable in variables): monomials_list_comm = [] for item in combinations_with_replacement(variables, max_degree): powers = dict() for variable in variables: powers[variable] = 0 for variable in item: if variable != 1: powers[variable] += 1 if sum(powers.values()) >= min_degree: monomials_list_comm.append(Mul(*item)) return set(monomials_list_comm) else: monomials_list_non_comm = [] for item in product(variables, repeat=max_degree): powers = dict() for variable in variables: powers[variable] = 0 for variable in item: if variable != 1: powers[variable] += 1 if sum(powers.values()) >= min_degree: monomials_list_non_comm.append(Mul(*item)) return set(monomials_list_non_comm) def monomial_count(V, N): r""" Computes the number of monomials. The number of monomials is given by the following formula: .. math:: \frac{(\#V + N)!}{\#V! N!} where `N` is a total degree and `V` is a set of variables. Examples ======== >>> from sympy.polys.monomials import itermonomials, monomial_count >>> from sympy.polys.orderings import monomial_key >>> from sympy.abc import x, y >>> monomial_count(2, 2) 6 >>> M = itermonomials([x, y], 2) >>> sorted(M, key=monomial_key('grlex', [y, x])) [1, x, y, x**2, x*y, y**2] >>> len(M) 6 """ from sympy import factorial return factorial(V + N) / factorial(V) / factorial(N) def monomial_mul(A, B): """ Multiplication of tuples representing monomials. Examples ======== Lets multiply `x**3*y**4*z` with `x*y**2`:: >>> from sympy.polys.monomials import monomial_mul >>> monomial_mul((3, 4, 1), (1, 2, 0)) (4, 6, 1) which gives `x**4*y**5*z`. """ return tuple([ a + b for a, b in zip(A, B) ]) def monomial_div(A, B): """ Division of tuples representing monomials. Examples ======== Lets divide `x**3*y**4*z` by `x*y**2`:: >>> from sympy.polys.monomials import monomial_div >>> monomial_div((3, 4, 1), (1, 2, 0)) (2, 2, 1) which gives `x**2*y**2*z`. However:: >>> monomial_div((3, 4, 1), (1, 2, 2)) is None True `x*y**2*z**2` does not divide `x**3*y**4*z`. """ C = monomial_ldiv(A, B) if all(c >= 0 for c in C): return tuple(C) else: return None def monomial_ldiv(A, B): """ Division of tuples representing monomials. Examples ======== Lets divide `x**3*y**4*z` by `x*y**2`:: >>> from sympy.polys.monomials import monomial_ldiv >>> monomial_ldiv((3, 4, 1), (1, 2, 0)) (2, 2, 1) which gives `x**2*y**2*z`. >>> monomial_ldiv((3, 4, 1), (1, 2, 2)) (2, 2, -1) which gives `x**2*y**2*z**-1`. """ return tuple([ a - b for a, b in zip(A, B) ]) def monomial_pow(A, n): """Return the n-th pow of the monomial. """ return tuple([ a*n for a in A ]) def monomial_gcd(A, B): """ Greatest common divisor of tuples representing monomials. Examples ======== Lets compute GCD of `x*y**4*z` and `x**3*y**2`:: >>> from sympy.polys.monomials import monomial_gcd >>> monomial_gcd((1, 4, 1), (3, 2, 0)) (1, 2, 0) which gives `x*y**2`. """ return tuple([ min(a, b) for a, b in zip(A, B) ]) def monomial_lcm(A, B): """ Least common multiple of tuples representing monomials. Examples ======== Lets compute LCM of `x*y**4*z` and `x**3*y**2`:: >>> from sympy.polys.monomials import monomial_lcm >>> monomial_lcm((1, 4, 1), (3, 2, 0)) (3, 4, 1) which gives `x**3*y**4*z`. """ return tuple([ max(a, b) for a, b in zip(A, B) ]) def monomial_divides(A, B): """ Does there exist a monomial X such that XA == B? Examples ======== >>> from sympy.polys.monomials import monomial_divides >>> monomial_divides((1, 2), (3, 4)) True >>> monomial_divides((1, 2), (0, 2)) False """ return all(a <= b for a, b in zip(A, B)) def monomial_max(*monoms): """ Returns maximal degree for each variable in a set of monomials. Examples ======== Consider monomials `x**3*y**4*z**5`, `y**5*z` and `x**6*y**3*z**9`. We wish to find out what is the maximal degree for each of `x`, `y` and `z` variables:: >>> from sympy.polys.monomials import monomial_max >>> monomial_max((3,4,5), (0,5,1), (6,3,9)) (6, 5, 9) """ M = list(monoms[0]) for N in monoms[1:]: for i, n in enumerate(N): M[i] = max(M[i], n) return tuple(M) def monomial_min(*monoms): """ Returns minimal degree for each variable in a set of monomials. Examples ======== Consider monomials `x**3*y**4*z**5`, `y**5*z` and `x**6*y**3*z**9`. We wish to find out what is the minimal degree for each of `x`, `y` and `z` variables:: >>> from sympy.polys.monomials import monomial_min >>> monomial_min((3,4,5), (0,5,1), (6,3,9)) (0, 3, 1) """ M = list(monoms[0]) for N in monoms[1:]: for i, n in enumerate(N): M[i] = min(M[i], n) return tuple(M) def monomial_deg(M): """ Returns the total degree of a monomial. Examples ======== The total degree of `xy^2` is 3: >>> from sympy.polys.monomials import monomial_deg >>> monomial_deg((1, 2)) 3 """ return sum(M) def term_div(a, b, domain): """Division of two terms in over a ring/field. """ a_lm, a_lc = a b_lm, b_lc = b monom = monomial_div(a_lm, b_lm) if domain.is_Field: if monom is not None: return monom, domain.quo(a_lc, b_lc) else: return None else: if not (monom is None or a_lc % b_lc): return monom, domain.quo(a_lc, b_lc) else: return None class MonomialOps(object): """Code generator of fast monomial arithmetic functions. """ def __init__(self, ngens): self.ngens = ngens def _build(self, code, name): ns = {} exec_(code, ns) return ns[name] def _vars(self, name): return [ "%s%s" % (name, i) for i in range(self.ngens) ] def mul(self): name = "monomial_mul" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s + %s" % (a, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) def pow(self): name = "monomial_pow" template = dedent("""\ def %(name)s(A, k): (%(A)s,) = A return (%(Ak)s,) """) A = self._vars("a") Ak = [ "%s*k" % a for a in A ] code = template % dict(name=name, A=", ".join(A), Ak=", ".join(Ak)) return self._build(code, name) def mulpow(self): name = "monomial_mulpow" template = dedent("""\ def %(name)s(A, B, k): (%(A)s,) = A (%(B)s,) = B return (%(ABk)s,) """) A = self._vars("a") B = self._vars("b") ABk = [ "%s + %s*k" % (a, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), ABk=", ".join(ABk)) return self._build(code, name) def ldiv(self): name = "monomial_ldiv" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s - %s" % (a, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) def div(self): name = "monomial_div" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B %(RAB)s return (%(R)s,) """) A = self._vars("a") B = self._vars("b") RAB = [ "r%(i)s = a%(i)s - b%(i)s\n if r%(i)s < 0: return None" % dict(i=i) for i in range(self.ngens) ] R = self._vars("r") code = template % dict(name=name, A=", ".join(A), B=", ".join(B), RAB="\n ".join(RAB), R=", ".join(R)) return self._build(code, name) def lcm(self): name = "monomial_lcm" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s if %s >= %s else %s" % (a, a, b, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) def gcd(self): name = "monomial_gcd" template = dedent("""\ def %(name)s(A, B): (%(A)s,) = A (%(B)s,) = B return (%(AB)s,) """) A = self._vars("a") B = self._vars("b") AB = [ "%s if %s <= %s else %s" % (a, a, b, b) for a, b in zip(A, B) ] code = template % dict(name=name, A=", ".join(A), B=", ".join(B), AB=", ".join(AB)) return self._build(code, name) @public class Monomial(PicklableWithSlots): """Class representing a monomial, i.e. a product of powers. """ __slots__ = ['exponents', 'gens'] def __init__(self, monom, gens=None): if not iterable(monom): rep, gens = dict_from_expr(sympify(monom), gens=gens) if len(rep) == 1 and list(rep.values())[0] == 1: monom = list(rep.keys())[0] else: raise ValueError("Expected a monomial got {}".format(monom)) self.exponents = tuple(map(int, monom)) self.gens = gens def rebuild(self, exponents, gens=None): return self.__class__(exponents, gens or self.gens) def __len__(self): return len(self.exponents) def __iter__(self): return iter(self.exponents) def __getitem__(self, item): return self.exponents[item] def __hash__(self): return hash((self.__class__.__name__, self.exponents, self.gens)) def __str__(self): if self.gens: return "*".join([ "%s**%s" % (gen, exp) for gen, exp in zip(self.gens, self.exponents) ]) else: return "%s(%s)" % (self.__class__.__name__, self.exponents) def as_expr(self, *gens): """Convert a monomial instance to a SymPy expression. """ gens = gens or self.gens if not gens: raise ValueError( "can't convert %s to an expression without generators" % self) return Mul(*[ gen**exp for gen, exp in zip(gens, self.exponents) ]) def __eq__(self, other): if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: return False return self.exponents == exponents def __ne__(self, other): return not self == other def __mul__(self, other): if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise NotImplementedError return self.rebuild(monomial_mul(self.exponents, exponents)) def __div__(self, other): if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise NotImplementedError result = monomial_div(self.exponents, exponents) if result is not None: return self.rebuild(result) else: raise ExactQuotientFailed(self, Monomial(other)) __floordiv__ = __truediv__ = __div__ def __pow__(self, other): n = int(other) if not n: return self.rebuild([0]*len(self)) elif n > 0: exponents = self.exponents for i in range(1, n): exponents = monomial_mul(exponents, self.exponents) return self.rebuild(exponents) else: raise ValueError("a non-negative integer expected, got %s" % other) def gcd(self, other): """Greatest common divisor of monomials. """ if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise TypeError( "an instance of Monomial class expected, got %s" % other) return self.rebuild(monomial_gcd(self.exponents, exponents)) def lcm(self, other): """Least common multiple of monomials. """ if isinstance(other, Monomial): exponents = other.exponents elif isinstance(other, (tuple, Tuple)): exponents = other else: raise TypeError( "an instance of Monomial class expected, got %s" % other) return self.rebuild(monomial_lcm(self.exponents, exponents))

722ca075ce43d16a949bf25d18ba72bb0cce112ff25a2d6b1c207810c696c7f1

"""Useful utilities for higher level polynomial classes. """ from __future__ import print_function, division from sympy.core import (S, Add, Mul, Pow, Expr, expand_mul, expand_multinomial) from sympy.core.compatibility import range from sympy.core.exprtools import decompose_power, decompose_power_rat from sympy.core.numbers import Float from sympy.polys.polyerrors import PolynomialError, GeneratorsError from sympy.polys.polyoptions import build_options import re _gens_order = { 'a': 301, 'b': 302, 'c': 303, 'd': 304, 'e': 305, 'f': 306, 'g': 307, 'h': 308, 'i': 309, 'j': 310, 'k': 311, 'l': 312, 'm': 313, 'n': 314, 'o': 315, 'p': 216, 'q': 217, 'r': 218, 's': 219, 't': 220, 'u': 221, 'v': 222, 'w': 223, 'x': 124, 'y': 125, 'z': 126, } _max_order = 1000 _re_gen = re.compile(r"^(.+?)(\d*)$") def _nsort(roots, separated=False): """Sort the numerical roots putting the real roots first, then sorting according to real and imaginary parts. If ``separated`` is True, then the real and imaginary roots will be returned in two lists, respectively. This routine tries to avoid issue 6137 by separating the roots into real and imaginary parts before evaluation. In addition, the sorting will raise an error if any computation cannot be done with precision. """ if not all(r.is_number for r in roots): raise NotImplementedError # see issue 6137: # get the real part of the evaluated real and imaginary parts of each root key = [[i.n(2).as_real_imag()[0] for i in r.as_real_imag()] for r in roots] # make sure the parts were computed with precision if any(i._prec == 1 for k in key for i in k): raise NotImplementedError("could not compute root with precision") # insert a key to indicate if the root has an imaginary part key = [(1 if i else 0, r, i) for r, i in key] key = sorted(zip(key, roots)) # return the real and imaginary roots separately if desired if separated: r = [] i = [] for (im, _, _), v in key: if im: i.append(v) else: r.append(v) return r, i _, roots = zip(*key) return list(roots) def _sort_gens(gens, **args): """Sort generators in a reasonably intelligent way. """ opt = build_options(args) gens_order, wrt = {}, None if opt is not None: gens_order, wrt = {}, opt.wrt for i, gen in enumerate(opt.sort): gens_order[gen] = i + 1 def order_key(gen): gen = str(gen) if wrt is not None: try: return (-len(wrt) + wrt.index(gen), gen, 0) except ValueError: pass name, index = _re_gen.match(gen).groups() if index: index = int(index) else: index = 0 try: return ( gens_order[name], name, index) except KeyError: pass try: return (_gens_order[name], name, index) except KeyError: pass return (_max_order, name, index) try: gens = sorted(gens, key=order_key) except TypeError: # pragma: no cover pass return tuple(gens) def _unify_gens(f_gens, g_gens): """Unify generators in a reasonably intelligent way. """ f_gens = list(f_gens) g_gens = list(g_gens) if f_gens == g_gens: return tuple(f_gens) gens, common, k = [], [], 0 for gen in f_gens: if gen in g_gens: common.append(gen) for i, gen in enumerate(g_gens): if gen in common: g_gens[i], k = common[k], k + 1 for gen in common: i = f_gens.index(gen) gens.extend(f_gens[:i]) f_gens = f_gens[i + 1:] i = g_gens.index(gen) gens.extend(g_gens[:i]) g_gens = g_gens[i + 1:] gens.append(gen) gens.extend(f_gens) gens.extend(g_gens) return tuple(gens) def _analyze_gens(gens): """Support for passing generators as `*gens` and `[gens]`. """ if len(gens) == 1 and hasattr(gens[0], '__iter__'): return tuple(gens[0]) else: return tuple(gens) def _sort_factors(factors, **args): """Sort low-level factors in increasing 'complexity' order. """ def order_if_multiple_key(factor): (f, n) = factor return (len(f), n, f) def order_no_multiple_key(f): return (len(f), f) if args.get('multiple', True): return sorted(factors, key=order_if_multiple_key) else: return sorted(factors, key=order_no_multiple_key) illegal = [S.NaN, S.Infinity, S.NegativeInfinity, S.ComplexInfinity] finf = [float(i) for i in illegal[1:3]] def _not_a_coeff(expr): """Do not treat NaN and infinities as valid polynomial coefficients. """ if expr in illegal or expr in finf: return True if type(expr) is float and float(expr) != expr: return True # nan return # could be def _parallel_dict_from_expr_if_gens(exprs, opt): """Transform expressions into a multinomial form given generators. """ k, indices = len(opt.gens), {} for i, g in enumerate(opt.gens): indices[g] = i polys = [] for expr in exprs: poly = {} if expr.is_Equality: expr = expr.lhs - expr.rhs for term in Add.make_args(expr): coeff, monom = [], [0]*k for factor in Mul.make_args(term): if not _not_a_coeff(factor) and factor.is_Number: coeff.append(factor) else: try: if opt.series is False: base, exp = decompose_power(factor) if exp < 0: exp, base = -exp, Pow(base, -S.One) else: base, exp = decompose_power_rat(factor) monom[indices[base]] = exp except KeyError: if not factor.free_symbols.intersection(opt.gens): coeff.append(factor) else: raise PolynomialError("%s contains an element of " "the set of generators." % factor) monom = tuple(monom) if monom in poly: poly[monom] += Mul(*coeff) else: poly[monom] = Mul(*coeff) polys.append(poly) return polys, opt.gens def _parallel_dict_from_expr_no_gens(exprs, opt): """Transform expressions into a multinomial form and figure out generators. """ if opt.domain is not None: def _is_coeff(factor): return factor in opt.domain elif opt.extension is True: def _is_coeff(factor): return factor.is_algebraic elif opt.greedy is not False: def _is_coeff(factor): return False else: def _is_coeff(factor): return factor.is_number gens, reprs = set([]), [] for expr in exprs: terms = [] if expr.is_Equality: expr = expr.lhs - expr.rhs for term in Add.make_args(expr): coeff, elements = [], {} for factor in Mul.make_args(term): if not _not_a_coeff(factor) and (factor.is_Number or _is_coeff(factor)): coeff.append(factor) else: if opt.series is False: base, exp = decompose_power(factor) if exp < 0: exp, base = -exp, Pow(base, -S.One) else: base, exp = decompose_power_rat(factor) elements[base] = elements.setdefault(base, 0) + exp gens.add(base) terms.append((coeff, elements)) reprs.append(terms) gens = _sort_gens(gens, opt=opt) k, indices = len(gens), {} for i, g in enumerate(gens): indices[g] = i polys = [] for terms in reprs: poly = {} for coeff, term in terms: monom = [0]*k for base, exp in term.items(): monom[indices[base]] = exp monom = tuple(monom) if monom in poly: poly[monom] += Mul(*coeff) else: poly[monom] = Mul(*coeff) polys.append(poly) return polys, tuple(gens) def _dict_from_expr_if_gens(expr, opt): """Transform an expression into a multinomial form given generators. """ (poly,), gens = _parallel_dict_from_expr_if_gens((expr,), opt) return poly, gens def _dict_from_expr_no_gens(expr, opt): """Transform an expression into a multinomial form and figure out generators. """ (poly,), gens = _parallel_dict_from_expr_no_gens((expr,), opt) return poly, gens def parallel_dict_from_expr(exprs, **args): """Transform expressions into a multinomial form. """ reps, opt = _parallel_dict_from_expr(exprs, build_options(args)) return reps, opt.gens def _parallel_dict_from_expr(exprs, opt): """Transform expressions into a multinomial form. """ if opt.expand is not False: exprs = [ expr.expand() for expr in exprs ] if any(expr.is_commutative is False for expr in exprs): raise PolynomialError('non-commutative expressions are not supported') if opt.gens: reps, gens = _parallel_dict_from_expr_if_gens(exprs, opt) else: reps, gens = _parallel_dict_from_expr_no_gens(exprs, opt) return reps, opt.clone({'gens': gens}) def dict_from_expr(expr, **args): """Transform an expression into a multinomial form. """ rep, opt = _dict_from_expr(expr, build_options(args)) return rep, opt.gens def _dict_from_expr(expr, opt): """Transform an expression into a multinomial form. """ if expr.is_commutative is False: raise PolynomialError('non-commutative expressions are not supported') def _is_expandable_pow(expr): return (expr.is_Pow and expr.exp.is_positive and expr.exp.is_Integer and expr.base.is_Add) if opt.expand is not False: if not isinstance(expr, Expr): raise PolynomialError('expression must be of type Expr') expr = expr.expand() # TODO: Integrate this into expand() itself while any(_is_expandable_pow(i) or i.is_Mul and any(_is_expandable_pow(j) for j in i.args) for i in Add.make_args(expr)): expr = expand_multinomial(expr) while any(i.is_Mul and any(j.is_Add for j in i.args) for i in Add.make_args(expr)): expr = expand_mul(expr) if opt.gens: rep, gens = _dict_from_expr_if_gens(expr, opt) else: rep, gens = _dict_from_expr_no_gens(expr, opt) return rep, opt.clone({'gens': gens}) def expr_from_dict(rep, *gens): """Convert a multinomial form into an expression. """ result = [] for monom, coeff in rep.items(): term = [coeff] for g, m in zip(gens, monom): if m: term.append(Pow(g, m)) result.append(Mul(*term)) return Add(*result) parallel_dict_from_basic = parallel_dict_from_expr dict_from_basic = dict_from_expr basic_from_dict = expr_from_dict def _dict_reorder(rep, gens, new_gens): """Reorder levels using dict representation. """ gens = list(gens) monoms = rep.keys() coeffs = rep.values() new_monoms = [ [] for _ in range(len(rep)) ] used_indices = set() for gen in new_gens: try: j = gens.index(gen) used_indices.add(j) for M, new_M in zip(monoms, new_monoms): new_M.append(M[j]) except ValueError: for new_M in new_monoms: new_M.append(0) for i, _ in enumerate(gens): if i not in used_indices: for monom in monoms: if monom[i]: raise GeneratorsError("unable to drop generators") return map(tuple, new_monoms), coeffs class PicklableWithSlots(object): """ Mixin class that allows to pickle objects with ``__slots__``. Examples ======== First define a class that mixes :class:`PicklableWithSlots` in:: >>> from sympy.polys.polyutils import PicklableWithSlots >>> class Some(PicklableWithSlots): ... __slots__ = ['foo', 'bar'] ... ... def __init__(self, foo, bar): ... self.foo = foo ... self.bar = bar To make :mod:`pickle` happy in doctest we have to use these hacks:: >>> from sympy.core.compatibility import builtins >>> builtins.Some = Some >>> from sympy.polys import polyutils >>> polyutils.Some = Some Next lets see if we can create an instance, pickle it and unpickle:: >>> some = Some('abc', 10) >>> some.foo, some.bar ('abc', 10) >>> from pickle import dumps, loads >>> some2 = loads(dumps(some)) >>> some2.foo, some2.bar ('abc', 10) """ __slots__ = [] def __getstate__(self, cls=None): if cls is None: # This is the case for the instance that gets pickled cls = self.__class__ d = {} # Get all data that should be stored from super classes for c in cls.__bases__: if hasattr(c, "__getstate__"): d.update(c.__getstate__(self, c)) # Get all information that should be stored from cls and return the dict for name in cls.__slots__: if hasattr(self, name): d[name] = getattr(self, name) return d def __setstate__(self, d): # All values that were pickled are now assigned to a fresh instance for name, value in d.items(): try: setattr(self, name, value) except AttributeError: # This is needed in cases like Rational :> Half pass

6dd7824f551a3469c07dce7410f0b1a99bc57245f959c305481670deca553bf3

"""Geometrical Points. Contains ======== Point Point2D Point3D When methods of Point require 1 or more points as arguments, they can be passed as a sequence of coordinates or Points: >>> from sympy.geometry.point import Point >>> Point(1, 1).is_collinear((2, 2), (3, 4)) False >>> Point(1, 1).is_collinear(Point(2, 2), Point(3, 4)) False """ from __future__ import division, print_function import warnings from sympy.core import S, sympify, Expr from sympy.core.compatibility import is_sequence from sympy.core.containers import Tuple from sympy.simplify import nsimplify, simplify from sympy.geometry.exceptions import GeometryError from sympy.functions.elementary.miscellaneous import sqrt from sympy.functions.elementary.complexes import im from sympy.matrices import Matrix from sympy.core.numbers import Float from sympy.core.evaluate import global_evaluate from sympy.core.add import Add from sympy.utilities.iterables import uniq from sympy.utilities.misc import filldedent, func_name, Undecidable from .entity import GeometryEntity class Point(GeometryEntity): """A point in a n-dimensional Euclidean space. Parameters ========== coords : sequence of n-coordinate values. In the special case where n=2 or 3, a Point2D or Point3D will be created as appropriate. evaluate : if `True` (default), all floats are turn into exact types. dim : number of coordinates the point should have. If coordinates are unspecified, they are padded with zeros. on_morph : indicates what should happen when the number of coordinates of a point need to be changed by adding or removing zeros. Possible values are `'warn'`, `'error'`, or `ignore` (default). No warning or error is given when `*args` is empty and `dim` is given. An error is always raised when trying to remove nonzero coordinates. Attributes ========== length origin: A `Point` representing the origin of the appropriately-dimensioned space. Raises ====== TypeError : When instantiating with anything but a Point or sequence ValueError : when instantiating with a sequence with length < 2 or when trying to reduce dimensions if keyword `on_morph='error'` is set. See Also ======== sympy.geometry.line.Segment : Connects two Points Examples ======== >>> from sympy.geometry import Point >>> from sympy.abc import x >>> Point(1, 2, 3) Point3D(1, 2, 3) >>> Point([1, 2]) Point2D(1, 2) >>> Point(0, x) Point2D(0, x) >>> Point(dim=4) Point(0, 0, 0, 0) Floats are automatically converted to Rational unless the evaluate flag is False: >>> Point(0.5, 0.25) Point2D(1/2, 1/4) >>> Point(0.5, 0.25, evaluate=False) Point2D(0.5, 0.25) """ is_Point = True def __new__(cls, *args, **kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) on_morph = kwargs.get('on_morph', 'ignore') # unpack into coords coords = args[0] if len(args) == 1 else args # check args and handle quickly handle Point instances if isinstance(coords, Point): # even if we're mutating the dimension of a point, we # don't reevaluate its coordinates evaluate = False if len(coords) == kwargs.get('dim', len(coords)): return coords if not is_sequence(coords): raise TypeError(filldedent(''' Expecting sequence of coordinates, not `{}`''' .format(func_name(coords)))) # A point where only `dim` is specified is initialized # to zeros. if len(coords) == 0 and kwargs.get('dim', None): coords = (S.Zero,)*kwargs.get('dim') coords = Tuple(*coords) dim = kwargs.get('dim', len(coords)) if len(coords) < 2: raise ValueError(filldedent(''' Point requires 2 or more coordinates or keyword `dim` > 1.''')) if len(coords) != dim: message = ("Dimension of {} needs to be changed " "from {} to {}.").format(coords, len(coords), dim) if on_morph == 'ignore': pass elif on_morph == "error": raise ValueError(message) elif on_morph == 'warn': warnings.warn(message) else: raise ValueError(filldedent(''' on_morph value should be 'error', 'warn' or 'ignore'.''')) if any(coords[dim:]): raise ValueError('Nonzero coordinates cannot be removed.') if any(a.is_number and im(a) for a in coords): raise ValueError('Imaginary coordinates are not permitted.') if not all(isinstance(a, Expr) for a in coords): raise TypeError('Coordinates must be valid SymPy expressions.') # pad with zeros appropriately coords = coords[:dim] + (S.Zero,)*(dim - len(coords)) # Turn any Floats into rationals and simplify # any expressions before we instantiate if evaluate: coords = coords.xreplace(dict( [(f, simplify(nsimplify(f, rational=True))) for f in coords.atoms(Float)])) # return 2D or 3D instances if len(coords) == 2: kwargs['_nocheck'] = True return Point2D(*coords, **kwargs) elif len(coords) == 3: kwargs['_nocheck'] = True return Point3D(*coords, **kwargs) # the general Point return GeometryEntity.__new__(cls, *coords) def __abs__(self): """Returns the distance between this point and the origin.""" origin = Point([0]*len(self)) return Point.distance(origin, self) def __add__(self, other): """Add other to self by incrementing self's coordinates by those of other. Notes ===== >>> from sympy.geometry.point import Point When sequences of coordinates are passed to Point methods, they are converted to a Point internally. This __add__ method does not do that so if floating point values are used, a floating point result (in terms of SymPy Floats) will be returned. >>> Point(1, 2) + (.1, .2) Point2D(1.1, 2.2) If this is not desired, the `translate` method can be used or another Point can be added: >>> Point(1, 2).translate(.1, .2) Point2D(11/10, 11/5) >>> Point(1, 2) + Point(.1, .2) Point2D(11/10, 11/5) See Also ======== sympy.geometry.point.Point.translate """ try: s, o = Point._normalize_dimension(self, Point(other, evaluate=False)) except TypeError: raise GeometryError("Don't know how to add {} and a Point object".format(other)) coords = [simplify(a + b) for a, b in zip(s, o)] return Point(coords, evaluate=False) def __contains__(self, item): return item in self.args def __div__(self, divisor): """Divide point's coordinates by a factor.""" divisor = sympify(divisor) coords = [simplify(x/divisor) for x in self.args] return Point(coords, evaluate=False) def __eq__(self, other): if not isinstance(other, Point) or len(self.args) != len(other.args): return False return self.args == other.args def __getitem__(self, key): return self.args[key] def __hash__(self): return hash(self.args) def __iter__(self): return self.args.__iter__() def __len__(self): return len(self.args) def __mul__(self, factor): """Multiply point's coordinates by a factor. Notes ===== >>> from sympy.geometry.point import Point When multiplying a Point by a floating point number, the coordinates of the Point will be changed to Floats: >>> Point(1, 2)*0.1 Point2D(0.1, 0.2) If this is not desired, the `scale` method can be used or else only multiply or divide by integers: >>> Point(1, 2).scale(1.1, 1.1) Point2D(11/10, 11/5) >>> Point(1, 2)*11/10 Point2D(11/10, 11/5) See Also ======== sympy.geometry.point.Point.scale """ factor = sympify(factor) coords = [simplify(x*factor) for x in self.args] return Point(coords, evaluate=False) def __neg__(self): """Negate the point.""" coords = [-x for x in self.args] return Point(coords, evaluate=False) def __sub__(self, other): """Subtract two points, or subtract a factor from this point's coordinates.""" return self + [-x for x in other] @classmethod def _normalize_dimension(cls, *points, **kwargs): """Ensure that points have the same dimension. By default `on_morph='warn'` is passed to the `Point` constructor.""" # if we have a built-in ambient dimension, use it dim = getattr(cls, '_ambient_dimension', None) # override if we specified it dim = kwargs.get('dim', dim) # if no dim was given, use the highest dimensional point if dim is None: dim = max(i.ambient_dimension for i in points) if all(i.ambient_dimension == dim for i in points): return list(points) kwargs['dim'] = dim kwargs['on_morph'] = kwargs.get('on_morph', 'warn') return [Point(i, **kwargs) for i in points] @staticmethod def affine_rank(*args): """The affine rank of a set of points is the dimension of the smallest affine space containing all the points. For example, if the points lie on a line (and are not all the same) their affine rank is 1. If the points lie on a plane but not a line, their affine rank is 2. By convention, the empty set has affine rank -1.""" if len(args) == 0: return -1 # make sure we're genuinely points # and translate every point to the origin points = Point._normalize_dimension(*[Point(i) for i in args]) origin = points[0] points = [i - origin for i in points[1:]] m = Matrix([i.args for i in points]) return m.rank() @property def ambient_dimension(self): """Number of components this point has.""" return getattr(self, '_ambient_dimension', len(self)) @classmethod def are_coplanar(cls, *points): """Return True if there exists a plane in which all the points lie. A trivial True value is returned if `len(points) < 3` or all Points are 2-dimensional. Parameters ========== A set of points Raises ====== ValueError : if less than 3 unique points are given Returns ======= boolean Examples ======== >>> from sympy import Point3D >>> p1 = Point3D(1, 2, 2) >>> p2 = Point3D(2, 7, 2) >>> p3 = Point3D(0, 0, 2) >>> p4 = Point3D(1, 1, 2) >>> Point3D.are_coplanar(p1, p2, p3, p4) True >>> p5 = Point3D(0, 1, 3) >>> Point3D.are_coplanar(p1, p2, p3, p5) False """ if len(points) <= 1: return True points = cls._normalize_dimension(*[Point(i) for i in points]) # quick exit if we are in 2D if points[0].ambient_dimension == 2: return True points = list(uniq(points)) return Point.affine_rank(*points) <= 2 def distance(self, other): """The Euclidean distance between self and another GeometricEntity. Returns ======= distance : number or symbolic expression. Raises ====== TypeError : if other is not recognized as a GeometricEntity or is a GeometricEntity for which distance is not defined. See Also ======== sympy.geometry.line.Segment.length sympy.geometry.point.Point.taxicab_distance Examples ======== >>> from sympy.geometry import Point, Line >>> p1, p2 = Point(1, 1), Point(4, 5) >>> l = Line((3, 1), (2, 2)) >>> p1.distance(p2) 5 >>> p1.distance(l) sqrt(2) The computed distance may be symbolic, too: >>> from sympy.abc import x, y >>> p3 = Point(x, y) >>> p3.distance((0, 0)) sqrt(x**2 + y**2) """ if not isinstance(other, GeometryEntity): try: other = Point(other, dim=self.ambient_dimension) except TypeError: raise TypeError("not recognized as a GeometricEntity: %s" % type(other)) if isinstance(other, Point): s, p = Point._normalize_dimension(self, Point(other)) return sqrt(Add(*((a - b)**2 for a, b in zip(s, p)))) distance = getattr(other, 'distance', None) if distance is None: raise TypeError("distance between Point and %s is not defined" % type(other)) return distance(self) def dot(self, p): """Return dot product of self with another Point.""" if not is_sequence(p): p = Point(p) # raise the error via Point return Add(*(a*b for a, b in zip(self, p))) def equals(self, other): """Returns whether the coordinates of self and other agree.""" # a point is equal to another point if all its components are equal if not isinstance(other, Point) or len(self) != len(other): return False return all(a.equals(b) for a, b in zip(self, other)) def evalf(self, prec=None, **options): """Evaluate the coordinates of the point. This method will, where possible, create and return a new Point where the coordinates are evaluated as floating point numbers to the precision indicated (default=15). Parameters ========== prec : int Returns ======= point : Point Examples ======== >>> from sympy import Point, Rational >>> p1 = Point(Rational(1, 2), Rational(3, 2)) >>> p1 Point2D(1/2, 3/2) >>> p1.evalf() Point2D(0.5, 1.5) """ coords = [x.evalf(prec, **options) for x in self.args] return Point(*coords, evaluate=False) def intersection(self, other): """The intersection between this point and another GeometryEntity. Parameters ========== other : Point Returns ======= intersection : list of Points Notes ===== The return value will either be an empty list if there is no intersection, otherwise it will contain this point. Examples ======== >>> from sympy import Point >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(0, 0) >>> p1.intersection(p2) [] >>> p1.intersection(p3) [Point2D(0, 0)] """ if not isinstance(other, GeometryEntity): other = Point(other) if isinstance(other, Point): if self == other: return [self] p1, p2 = Point._normalize_dimension(self, other) if p1 == self and p1 == p2: return [self] return [] return other.intersection(self) def is_collinear(self, *args): """Returns `True` if there exists a line that contains `self` and `points`. Returns `False` otherwise. A trivially True value is returned if no points are given. Parameters ========== args : sequence of Points Returns ======= is_collinear : boolean See Also ======== sympy.geometry.line.Line Examples ======== >>> from sympy import Point >>> from sympy.abc import x >>> p1, p2 = Point(0, 0), Point(1, 1) >>> p3, p4, p5 = Point(2, 2), Point(x, x), Point(1, 2) >>> Point.is_collinear(p1, p2, p3, p4) True >>> Point.is_collinear(p1, p2, p3, p5) False """ points = (self,) + args points = Point._normalize_dimension(*[Point(i) for i in points]) points = list(uniq(points)) return Point.affine_rank(*points) <= 1 def is_concyclic(self, *args): """Do `self` and the given sequence of points lie in a circle? Returns True if the set of points are concyclic and False otherwise. A trivial value of True is returned if there are fewer than 2 other points. Parameters ========== args : sequence of Points Returns ======= is_concyclic : boolean Examples ======== >>> from sympy import Point Define 4 points that are on the unit circle: >>> p1, p2, p3, p4 = Point(1, 0), (0, 1), (-1, 0), (0, -1) >>> p1.is_concyclic() == p1.is_concyclic(p2, p3, p4) == True True Define a point not on that circle: >>> p = Point(1, 1) >>> p.is_concyclic(p1, p2, p3) False """ points = (self,) + args points = Point._normalize_dimension(*[Point(i) for i in points]) points = list(uniq(points)) if not Point.affine_rank(*points) <= 2: return False origin = points[0] points = [p - origin for p in points] # points are concyclic if they are coplanar and # there is a point c so that ||p_i-c|| == ||p_j-c|| for all # i and j. Rearranging this equation gives us the following # condition: the matrix `mat` must not a pivot in the last # column. mat = Matrix([list(i) + [i.dot(i)] for i in points]) rref, pivots = mat.rref() if len(origin) not in pivots: return True return False @property def is_nonzero(self): """True if any coordinate is nonzero, False if every coordinate is zero, and None if it cannot be determined.""" is_zero = self.is_zero if is_zero is None: return None return not is_zero def is_scalar_multiple(self, p): """Returns whether each coordinate of `self` is a scalar multiple of the corresponding coordinate in point p. """ s, o = Point._normalize_dimension(self, Point(p)) # 2d points happen a lot, so optimize this function call if s.ambient_dimension == 2: (x1, y1), (x2, y2) = s.args, o.args rv = (x1*y2 - x2*y1).equals(0) if rv is None: raise Undecidable(filldedent( '''can't determine if %s is a scalar multiple of %s''' % (s, o))) # if the vectors p1 and p2 are linearly dependent, then they must # be scalar multiples of each other m = Matrix([s.args, o.args]) return m.rank() < 2 @property def is_zero(self): """True if every coordinate is zero, False if any coordinate is not zero, and None if it cannot be determined.""" nonzero = [x.is_nonzero for x in self.args] if any(nonzero): return False if any(x is None for x in nonzero): return None return True @property def length(self): """ Treating a Point as a Line, this returns 0 for the length of a Point. Examples ======== >>> from sympy import Point >>> p = Point(0, 1) >>> p.length 0 """ return S.Zero def midpoint(self, p): """The midpoint between self and point p. Parameters ========== p : Point Returns ======= midpoint : Point See Also ======== sympy.geometry.line.Segment.midpoint Examples ======== >>> from sympy.geometry import Point >>> p1, p2 = Point(1, 1), Point(13, 5) >>> p1.midpoint(p2) Point2D(7, 3) """ s, p = Point._normalize_dimension(self, Point(p)) return Point([simplify((a + b)*S.Half) for a, b in zip(s, p)]) @property def origin(self): """A point of all zeros of the same ambient dimension as the current point""" return Point([0]*len(self), evaluate=False) @property def orthogonal_direction(self): """Returns a non-zero point that is orthogonal to the line containing `self` and the origin. Examples ======== >>> from sympy.geometry import Line, Point >>> a = Point(1, 2, 3) >>> a.orthogonal_direction Point3D(-2, 1, 0) >>> b = _ >>> Line(b, b.origin).is_perpendicular(Line(a, a.origin)) True """ dim = self.ambient_dimension # if a coordinate is zero, we can put a 1 there and zeros elsewhere if self[0] == S.Zero: return Point([1] + (dim - 1)*[0]) if self[1] == S.Zero: return Point([0,1] + (dim - 2)*[0]) # if the first two coordinates aren't zero, we can create a non-zero # orthogonal vector by swapping them, negating one, and padding with zeros return Point([-self[1], self[0]] + (dim - 2)*[0]) @staticmethod def project(a, b): """Project the point `a` onto the line between the origin and point `b` along the normal direction. Parameters ========== a : Point b : Point Returns ======= p : Point See Also ======== sympy.geometry.line.LinearEntity.projection Examples ======== >>> from sympy.geometry import Line, Point >>> a = Point(1, 2) >>> b = Point(2, 5) >>> z = a.origin >>> p = Point.project(a, b) >>> Line(p, a).is_perpendicular(Line(p, b)) True >>> Point.is_collinear(z, p, b) True """ a, b = Point._normalize_dimension(Point(a), Point(b)) if b.is_zero: raise ValueError("Cannot project to the zero vector.") return b*(a.dot(b) / b.dot(b)) def taxicab_distance(self, p): """The Taxicab Distance from self to point p. Returns the sum of the horizontal and vertical distances to point p. Parameters ========== p : Point Returns ======= taxicab_distance : The sum of the horizontal and vertical distances to point p. See Also ======== sympy.geometry.point.Point.distance Examples ======== >>> from sympy.geometry import Point >>> p1, p2 = Point(1, 1), Point(4, 5) >>> p1.taxicab_distance(p2) 7 """ s, p = Point._normalize_dimension(self, Point(p)) return Add(*(abs(a - b) for a, b in zip(s, p))) def canberra_distance(self, p): """The Canberra Distance from self to point p. Returns the weighted sum of horizontal and vertical distances to point p. Parameters ========== p : Point Returns ======= canberra_distance : The weighted sum of horizontal and vertical distances to point p. The weight used is the sum of absolute values of the coordinates. Examples ======== >>> from sympy.geometry import Point >>> p1, p2 = Point(1, 1), Point(3, 3) >>> p1.canberra_distance(p2) 1 >>> p1, p2 = Point(0, 0), Point(3, 3) >>> p1.canberra_distance(p2) 2 Raises ====== ValueError when both vectors are zero. See Also ======== sympy.geometry.point.Point.distance """ s, p = Point._normalize_dimension(self, Point(p)) if self.is_zero and p.is_zero: raise ValueError("Cannot project to the zero vector.") return Add(*((abs(a - b)/(abs(a) + abs(b))) for a, b in zip(s, p))) @property def unit(self): """Return the Point that is in the same direction as `self` and a distance of 1 from the origin""" return self / abs(self) n = evalf __truediv__ = __div__ class Point2D(Point): """A point in a 2-dimensional Euclidean space. Parameters ========== coords : sequence of 2 coordinate values. Attributes ========== x y length Raises ====== TypeError When trying to add or subtract points with different dimensions. When trying to create a point with more than two dimensions. When `intersection` is called with object other than a Point. See Also ======== sympy.geometry.line.Segment : Connects two Points Examples ======== >>> from sympy.geometry import Point2D >>> from sympy.abc import x >>> Point2D(1, 2) Point2D(1, 2) >>> Point2D([1, 2]) Point2D(1, 2) >>> Point2D(0, x) Point2D(0, x) Floats are automatically converted to Rational unless the evaluate flag is False: >>> Point2D(0.5, 0.25) Point2D(1/2, 1/4) >>> Point2D(0.5, 0.25, evaluate=False) Point2D(0.5, 0.25) """ _ambient_dimension = 2 def __new__(cls, *args, **kwargs): if not kwargs.pop('_nocheck', False): kwargs['dim'] = 2 args = Point(*args, **kwargs) return GeometryEntity.__new__(cls, *args) def __contains__(self, item): return item == self @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ return (self.x, self.y, self.x, self.y) def rotate(self, angle, pt=None): """Rotate ``angle`` radians counterclockwise about Point ``pt``. See Also ======== rotate, scale Examples ======== >>> from sympy import Point2D, pi >>> t = Point2D(1, 0) >>> t.rotate(pi/2) Point2D(0, 1) >>> t.rotate(pi/2, (2, 0)) Point2D(2, -1) """ from sympy import cos, sin, Point c = cos(angle) s = sin(angle) rv = self if pt is not None: pt = Point(pt, dim=2) rv -= pt x, y = rv.args rv = Point(c*x - s*y, s*x + c*y) if pt is not None: rv += pt return rv def scale(self, x=1, y=1, pt=None): """Scale the coordinates of the Point by multiplying by ``x`` and ``y`` after subtracting ``pt`` -- default is (0, 0) -- and then adding ``pt`` back again (i.e. ``pt`` is the point of reference for the scaling). See Also ======== rotate, translate Examples ======== >>> from sympy import Point2D >>> t = Point2D(1, 1) >>> t.scale(2) Point2D(2, 1) >>> t.scale(2, 2) Point2D(2, 2) """ if pt: pt = Point(pt, dim=2) return self.translate(*(-pt).args).scale(x, y).translate(*pt.args) return Point(self.x*x, self.y*y) def transform(self, matrix): """Return the point after applying the transformation described by the 3x3 Matrix, ``matrix``. See Also ======== geometry.entity.rotate geometry.entity.scale geometry.entity.translate """ if not (matrix.is_Matrix and matrix.shape == (3, 3)): raise ValueError("matrix must be a 3x3 matrix") col, row = matrix.shape valid_matrix = matrix.is_square and col == 3 x, y = self.args return Point(*(Matrix(1, 3, [x, y, 1])*matrix).tolist()[0][:2]) def translate(self, x=0, y=0): """Shift the Point by adding x and y to the coordinates of the Point. See Also ======== rotate, scale Examples ======== >>> from sympy import Point2D >>> t = Point2D(0, 1) >>> t.translate(2) Point2D(2, 1) >>> t.translate(2, 2) Point2D(2, 3) >>> t + Point2D(2, 2) Point2D(2, 3) """ return Point(self.x + x, self.y + y) @property def x(self): """ Returns the X coordinate of the Point. Examples ======== >>> from sympy import Point2D >>> p = Point2D(0, 1) >>> p.x 0 """ return self.args[0] @property def y(self): """ Returns the Y coordinate of the Point. Examples ======== >>> from sympy import Point2D >>> p = Point2D(0, 1) >>> p.y 1 """ return self.args[1] class Point3D(Point): """A point in a 3-dimensional Euclidean space. Parameters ========== coords : sequence of 3 coordinate values. Attributes ========== x y z length Raises ====== TypeError When trying to add or subtract points with different dimensions. When `intersection` is called with object other than a Point. Examples ======== >>> from sympy import Point3D >>> from sympy.abc import x >>> Point3D(1, 2, 3) Point3D(1, 2, 3) >>> Point3D([1, 2, 3]) Point3D(1, 2, 3) >>> Point3D(0, x, 3) Point3D(0, x, 3) Floats are automatically converted to Rational unless the evaluate flag is False: >>> Point3D(0.5, 0.25, 2) Point3D(1/2, 1/4, 2) >>> Point3D(0.5, 0.25, 3, evaluate=False) Point3D(0.5, 0.25, 3) """ _ambient_dimension = 3 def __new__(cls, *args, **kwargs): if not kwargs.pop('_nocheck', False): kwargs['dim'] = 3 args = Point(*args, **kwargs) return GeometryEntity.__new__(cls, *args) def __contains__(self, item): return item == self @staticmethod def are_collinear(*points): """Is a sequence of points collinear? Test whether or not a set of points are collinear. Returns True if the set of points are collinear, or False otherwise. Parameters ========== points : sequence of Point Returns ======= are_collinear : boolean See Also ======== sympy.geometry.line.Line3D Examples ======== >>> from sympy import Point3D, Matrix >>> from sympy.abc import x >>> p1, p2 = Point3D(0, 0, 0), Point3D(1, 1, 1) >>> p3, p4, p5 = Point3D(2, 2, 2), Point3D(x, x, x), Point3D(1, 2, 6) >>> Point3D.are_collinear(p1, p2, p3, p4) True >>> Point3D.are_collinear(p1, p2, p3, p5) False """ return Point.is_collinear(*points) def direction_cosine(self, point): """ Gives the direction cosine between 2 points Parameters ========== p : Point3D Returns ======= list Examples ======== >>> from sympy import Point3D >>> p1 = Point3D(1, 2, 3) >>> p1.direction_cosine(Point3D(2, 3, 5)) [sqrt(6)/6, sqrt(6)/6, sqrt(6)/3] """ a = self.direction_ratio(point) b = sqrt(Add(*(i**2 for i in a))) return [(point.x - self.x) / b,(point.y - self.y) / b, (point.z - self.z) / b] def direction_ratio(self, point): """ Gives the direction ratio between 2 points Parameters ========== p : Point3D Returns ======= list Examples ======== >>> from sympy import Point3D >>> p1 = Point3D(1, 2, 3) >>> p1.direction_ratio(Point3D(2, 3, 5)) [1, 1, 2] """ return [(point.x - self.x),(point.y - self.y),(point.z - self.z)] def intersection(self, other): """The intersection between this point and another point. Parameters ========== other : Point Returns ======= intersection : list of Points Notes ===== The return value will either be an empty list if there is no intersection, otherwise it will contain this point. Examples ======== >>> from sympy import Point3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(0, 0, 0) >>> p1.intersection(p2) [] >>> p1.intersection(p3) [Point3D(0, 0, 0)] """ if not isinstance(other, GeometryEntity): other = Point(other, dim=3) if isinstance(other, Point3D): if self == other: return [self] return [] return other.intersection(self) def scale(self, x=1, y=1, z=1, pt=None): """Scale the coordinates of the Point by multiplying by ``x`` and ``y`` after subtracting ``pt`` -- default is (0, 0) -- and then adding ``pt`` back again (i.e. ``pt`` is the point of reference for the scaling). See Also ======== translate Examples ======== >>> from sympy import Point3D >>> t = Point3D(1, 1, 1) >>> t.scale(2) Point3D(2, 1, 1) >>> t.scale(2, 2) Point3D(2, 2, 1) """ if pt: pt = Point3D(pt) return self.translate(*(-pt).args).scale(x, y, z).translate(*pt.args) return Point3D(self.x*x, self.y*y, self.z*z) def transform(self, matrix): """Return the point after applying the transformation described by the 4x4 Matrix, ``matrix``. See Also ======== geometry.entity.rotate geometry.entity.scale geometry.entity.translate """ if not (matrix.is_Matrix and matrix.shape == (4, 4)): raise ValueError("matrix must be a 4x4 matrix") col, row = matrix.shape valid_matrix = matrix.is_square and col == 4 from sympy.matrices.expressions import Transpose x, y, z = self.args m = Transpose(matrix) return Point3D(*(Matrix(1, 4, [x, y, z, 1])*m).tolist()[0][:3]) def translate(self, x=0, y=0, z=0): """Shift the Point by adding x and y to the coordinates of the Point. See Also ======== rotate, scale Examples ======== >>> from sympy import Point3D >>> t = Point3D(0, 1, 1) >>> t.translate(2) Point3D(2, 1, 1) >>> t.translate(2, 2) Point3D(2, 3, 1) >>> t + Point3D(2, 2, 2) Point3D(2, 3, 3) """ return Point3D(self.x + x, self.y + y, self.z + z) @property def x(self): """ Returns the X coordinate of the Point. Examples ======== >>> from sympy import Point3D >>> p = Point3D(0, 1, 3) >>> p.x 0 """ return self.args[0] @property def y(self): """ Returns the Y coordinate of the Point. Examples ======== >>> from sympy import Point3D >>> p = Point3D(0, 1, 2) >>> p.y 1 """ return self.args[1] @property def z(self): """ Returns the Z coordinate of the Point. Examples ======== >>> from sympy import Point3D >>> p = Point3D(0, 1, 1) >>> p.z 1 """ return self.args[2]

7901b9adf9dd534ad7b27d1de84519b4b50bdc0ba70fb267c125e580b0b2282b

"""Geometrical Planes. Contains ======== Plane """ from __future__ import division, print_function from sympy import simplify from sympy.core import Dummy, Rational, S, Symbol from sympy.core.symbol import _symbol from sympy.core.compatibility import is_sequence from sympy.functions.elementary.trigonometric import cos, sin, acos, asin, sqrt from sympy.matrices import Matrix from sympy.polys.polytools import cancel from sympy.solvers import solve, linsolve from sympy.utilities.iterables import uniq from sympy.utilities.misc import filldedent, func_name, Undecidable from .entity import GeometryEntity from .point import Point, Point3D from .line import Line, Ray, Segment, Line3D, LinearEntity3D, Ray3D, Segment3D class Plane(GeometryEntity): """ A plane is a flat, two-dimensional surface. A plane is the two-dimensional analogue of a point (zero-dimensions), a line (one-dimension) and a solid (three-dimensions). A plane can generally be constructed by two types of inputs. They are three non-collinear points and a point and the plane's normal vector. Attributes ========== p1 normal_vector Examples ======== >>> from sympy import Plane, Point3D >>> from sympy.abc import x >>> Plane(Point3D(1, 1, 1), Point3D(2, 3, 4), Point3D(2, 2, 2)) Plane(Point3D(1, 1, 1), (-1, 2, -1)) >>> Plane((1, 1, 1), (2, 3, 4), (2, 2, 2)) Plane(Point3D(1, 1, 1), (-1, 2, -1)) >>> Plane(Point3D(1, 1, 1), normal_vector=(1,4,7)) Plane(Point3D(1, 1, 1), (1, 4, 7)) """ def __new__(cls, p1, a=None, b=None, **kwargs): p1 = Point3D(p1, dim=3) if a and b: p2 = Point(a, dim=3) p3 = Point(b, dim=3) if Point3D.are_collinear(p1, p2, p3): raise ValueError('Enter three non-collinear points') a = p1.direction_ratio(p2) b = p1.direction_ratio(p3) normal_vector = tuple(Matrix(a).cross(Matrix(b))) else: a = kwargs.pop('normal_vector', a) if is_sequence(a) and len(a) == 3: normal_vector = Point3D(a).args else: raise ValueError(filldedent(''' Either provide 3 3D points or a point with a normal vector expressed as a sequence of length 3''')) if all(coord.is_zero for coord in normal_vector): raise ValueError('Normal vector cannot be zero vector') return GeometryEntity.__new__(cls, p1, normal_vector, **kwargs) def __contains__(self, o): from sympy.geometry.line import LinearEntity, LinearEntity3D x, y, z = map(Dummy, 'xyz') k = self.equation(x, y, z) if isinstance(o, (LinearEntity, LinearEntity3D)): t = Dummy() d = Point3D(o.arbitrary_point(t)) e = k.subs([(x, d.x), (y, d.y), (z, d.z)]) return e.equals(0) try: o = Point(o, dim=3, strict=True) d = k.xreplace(dict(zip((x, y, z), o.args))) return d.equals(0) except TypeError: return False def angle_between(self, o): """Angle between the plane and other geometric entity. Parameters ========== LinearEntity3D, Plane. Returns ======= angle : angle in radians Notes ===== This method accepts only 3D entities as it's parameter, but if you want to calculate the angle between a 2D entity and a plane you should first convert to a 3D entity by projecting onto a desired plane and then proceed to calculate the angle. Examples ======== >>> from sympy import Point3D, Line3D, Plane >>> a = Plane(Point3D(1, 2, 2), normal_vector=(1, 2, 3)) >>> b = Line3D(Point3D(1, 3, 4), Point3D(2, 2, 2)) >>> a.angle_between(b) -asin(sqrt(21)/6) """ from sympy.geometry.line import LinearEntity3D if isinstance(o, LinearEntity3D): a = Matrix(self.normal_vector) b = Matrix(o.direction_ratio) c = a.dot(b) d = sqrt(sum([i**2 for i in self.normal_vector])) e = sqrt(sum([i**2 for i in o.direction_ratio])) return asin(c/(d*e)) if isinstance(o, Plane): a = Matrix(self.normal_vector) b = Matrix(o.normal_vector) c = a.dot(b) d = sqrt(sum([i**2 for i in self.normal_vector])) e = sqrt(sum([i**2 for i in o.normal_vector])) return acos(c/(d*e)) def arbitrary_point(self, u=None, v=None): """ Returns an arbitrary point on the Plane. If given two parameters, the point ranges over the entire plane. If given 1 or no parameters, returns a point with one parameter which, when varying from 0 to 2*pi, moves the point in a circle of radius 1 about p1 of the Plane. Examples ======== >>> from sympy.geometry import Plane, Ray >>> from sympy.abc import u, v, t, r >>> p = Plane((1, 1, 1), normal_vector=(1, 0, 0)) >>> p.arbitrary_point(u, v) Point3D(1, u + 1, v + 1) >>> p.arbitrary_point(t) Point3D(1, cos(t) + 1, sin(t) + 1) While arbitrary values of u and v can move the point anywhere in the plane, the single-parameter point can be used to construct a ray whose arbitrary point can be located at angle t and radius r from p.p1: >>> Ray(p.p1, _).arbitrary_point(r) Point3D(1, r*cos(t) + 1, r*sin(t) + 1) Returns ======= Point3D """ circle = v is None if circle: u = _symbol(u or 't', real=True) else: u = _symbol(u or 'u', real=True) v = _symbol(v or 'v', real=True) x, y, z = self.normal_vector a, b, c = self.p1.args # x1, y1, z1 is a nonzero vector parallel to the plane if x.is_zero and y.is_zero: x1, y1, z1 = S.One, S.Zero, S.Zero else: x1, y1, z1 = -y, x, S.Zero # x2, y2, z2 is also parallel to the plane, and orthogonal to x1, y1, z1 x2, y2, z2 = tuple(Matrix((x, y, z)).cross(Matrix((x1, y1, z1)))) if circle: x1, y1, z1 = (w/sqrt(x1**2 + y1**2 + z1**2) for w in (x1, y1, z1)) x2, y2, z2 = (w/sqrt(x2**2 + y2**2 + z2**2) for w in (x2, y2, z2)) p = Point3D(a + x1*cos(u) + x2*sin(u), \ b + y1*cos(u) + y2*sin(u), \ c + z1*cos(u) + z2*sin(u)) else: p = Point3D(a + x1*u + x2*v, b + y1*u + y2*v, c + z1*u + z2*v) return p @staticmethod def are_concurrent(*planes): """Is a sequence of Planes concurrent? Two or more Planes are concurrent if their intersections are a common line. Parameters ========== planes: list Returns ======= Boolean Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(5, 0, 0), normal_vector=(1, -1, 1)) >>> b = Plane(Point3D(0, -2, 0), normal_vector=(3, 1, 1)) >>> c = Plane(Point3D(0, -1, 0), normal_vector=(5, -1, 9)) >>> Plane.are_concurrent(a, b) True >>> Plane.are_concurrent(a, b, c) False """ planes = list(uniq(planes)) for i in planes: if not isinstance(i, Plane): raise ValueError('All objects should be Planes but got %s' % i.func) if len(planes) < 2: return False planes = list(planes) first = planes.pop(0) sol = first.intersection(planes[0]) if sol == []: return False else: line = sol[0] for i in planes[1:]: l = first.intersection(i) if not l or not l[0] in line: return False return True def distance(self, o): """Distance between the plane and another geometric entity. Parameters ========== Point3D, LinearEntity3D, Plane. Returns ======= distance Notes ===== This method accepts only 3D entities as it's parameter, but if you want to calculate the distance between a 2D entity and a plane you should first convert to a 3D entity by projecting onto a desired plane and then proceed to calculate the distance. Examples ======== >>> from sympy import Point, Point3D, Line, Line3D, Plane >>> a = Plane(Point3D(1, 1, 1), normal_vector=(1, 1, 1)) >>> b = Point3D(1, 2, 3) >>> a.distance(b) sqrt(3) >>> c = Line3D(Point3D(2, 3, 1), Point3D(1, 2, 2)) >>> a.distance(c) 0 """ from sympy.geometry.line import LinearEntity3D if self.intersection(o) != []: return S.Zero if isinstance(o, (Segment3D, Ray3D)): a, b = o.p1, o.p2 pi, = self.intersection(Line3D(a, b)) if pi in o: return self.distance(pi) elif a in Segment3D(pi, b): return self.distance(a) else: assert isinstance(o, Segment3D) is True return self.distance(b) # following code handles `Point3D`, `LinearEntity3D`, `Plane` a = o if isinstance(o, Point3D) else o.p1 n = Point3D(self.normal_vector).unit d = (a - self.p1).dot(n) return abs(d) def equals(self, o): """ Returns True if self and o are the same mathematical entities. Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1, 2, 3), normal_vector=(1, 1, 1)) >>> b = Plane(Point3D(1, 2, 3), normal_vector=(2, 2, 2)) >>> c = Plane(Point3D(1, 2, 3), normal_vector=(-1, 4, 6)) >>> a.equals(a) True >>> a.equals(b) True >>> a.equals(c) False """ if isinstance(o, Plane): a = self.equation() b = o.equation() return simplify(a / b).is_constant() else: return False def equation(self, x=None, y=None, z=None): """The equation of the Plane. Examples ======== >>> from sympy import Point3D, Plane >>> a = Plane(Point3D(1, 1, 2), Point3D(2, 4, 7), Point3D(3, 5, 1)) >>> a.equation() -23*x + 11*y - 2*z + 16 >>> a = Plane(Point3D(1, 4, 2), normal_vector=(6, 6, 6)) >>> a.equation() 6*x + 6*y + 6*z - 42 """ x, y, z = [i if i else Symbol(j, real=True) for i, j in zip((x, y, z), 'xyz')] a = Point3D(x, y, z) b = self.p1.direction_ratio(a) c = self.normal_vector return (sum(i*j for i, j in zip(b, c))) def intersection(self, o): """ The intersection with other geometrical entity. Parameters ========== Point, Point3D, LinearEntity, LinearEntity3D, Plane Returns ======= List Examples ======== >>> from sympy import Point, Point3D, Line, Line3D, Plane >>> a = Plane(Point3D(1, 2, 3), normal_vector=(1, 1, 1)) >>> b = Point3D(1, 2, 3) >>> a.intersection(b) [Point3D(1, 2, 3)] >>> c = Line3D(Point3D(1, 4, 7), Point3D(2, 2, 2)) >>> a.intersection(c) [Point3D(2, 2, 2)] >>> d = Plane(Point3D(6, 0, 0), normal_vector=(2, -5, 3)) >>> e = Plane(Point3D(2, 0, 0), normal_vector=(3, 4, -3)) >>> d.intersection(e) [Line3D(Point3D(78/23, -24/23, 0), Point3D(147/23, 321/23, 23))] """ from sympy.geometry.line import LinearEntity, LinearEntity3D if not isinstance(o, GeometryEntity): o = Point(o, dim=3) if isinstance(o, Point): if o in self: return [o] else: return [] if isinstance(o, (LinearEntity, LinearEntity3D)): # recast to 3D p1, p2 = o.p1, o.p2 if isinstance(o, Segment): o = Segment3D(p1, p2) elif isinstance(o, Ray): o = Ray3D(p1, p2) elif isinstance(o, Line): o = Line3D(p1, p2) else: raise ValueError('unhandled linear entity: %s' % o.func) if o in self: return [o] else: t = Dummy() # unnamed else it may clash with a symbol in o a = Point3D(o.arbitrary_point(t)) p1, n = self.p1, Point3D(self.normal_vector) # TODO: Replace solve with solveset, when this line is tested c = solve((a - p1).dot(n), t) if not c: return [] else: c = [i for i in c if i.is_real is not False] if len(c) > 1: c = [i for i in c if i.is_real] if len(c) != 1: raise Undecidable("not sure which point is real") p = a.subs(t, c[0]) if p not in o: return [] # e.g. a segment might not intersect a plane return [p] if isinstance(o, Plane): if self.equals(o): return [self] if self.is_parallel(o): return [] else: x, y, z = map(Dummy, 'xyz') a, b = Matrix([self.normal_vector]), Matrix([o.normal_vector]) c = list(a.cross(b)) d = self.equation(x, y, z) e = o.equation(x, y, z) result = list(linsolve([d, e], x, y, z))[0] for i in (x, y, z): result = result.subs(i, 0) return [Line3D(Point3D(result), direction_ratio=c)] def is_coplanar(self, o): """ Returns True if `o` is coplanar with self, else False. Examples ======== >>> from sympy import Plane, Point3D >>> o = (0, 0, 0) >>> p = Plane(o, (1, 1, 1)) >>> p2 = Plane(o, (2, 2, 2)) >>> p == p2 False >>> p.is_coplanar(p2) True """ if isinstance(o, Plane): x, y, z = map(Dummy, 'xyz') return not cancel(self.equation(x, y, z)/o.equation(x, y, z)).has(x, y, z) if isinstance(o, Point3D): return o in self elif isinstance(o, LinearEntity3D): return all(i in self for i in self) elif isinstance(o, GeometryEntity): # XXX should only be handling 2D objects now return all(i == 0 for i in self.normal_vector[:2]) def is_parallel(self, l): """Is the given geometric entity parallel to the plane? Parameters ========== LinearEntity3D or Plane Returns ======= Boolean Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1,4,6), normal_vector=(2, 4, 6)) >>> b = Plane(Point3D(3,1,3), normal_vector=(4, 8, 12)) >>> a.is_parallel(b) True """ from sympy.geometry.line import LinearEntity3D if isinstance(l, LinearEntity3D): a = l.direction_ratio b = self.normal_vector c = sum([i*j for i, j in zip(a, b)]) if c == 0: return True else: return False elif isinstance(l, Plane): a = Matrix(l.normal_vector) b = Matrix(self.normal_vector) if a.cross(b).is_zero: return True else: return False def is_perpendicular(self, l): """is the given geometric entity perpendicualar to the given plane? Parameters ========== LinearEntity3D or Plane Returns ======= Boolean Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1,4,6), normal_vector=(2, 4, 6)) >>> b = Plane(Point3D(2, 2, 2), normal_vector=(-1, 2, -1)) >>> a.is_perpendicular(b) True """ from sympy.geometry.line import LinearEntity3D if isinstance(l, LinearEntity3D): a = Matrix(l.direction_ratio) b = Matrix(self.normal_vector) if a.cross(b).is_zero: return True else: return False elif isinstance(l, Plane): a = Matrix(l.normal_vector) b = Matrix(self.normal_vector) if a.dot(b) == 0: return True else: return False else: return False @property def normal_vector(self): """Normal vector of the given plane. Examples ======== >>> from sympy import Point3D, Plane >>> a = Plane(Point3D(1, 1, 1), Point3D(2, 3, 4), Point3D(2, 2, 2)) >>> a.normal_vector (-1, 2, -1) >>> a = Plane(Point3D(1, 1, 1), normal_vector=(1, 4, 7)) >>> a.normal_vector (1, 4, 7) """ return self.args[1] @property def p1(self): """The only defining point of the plane. Others can be obtained from the arbitrary_point method. See Also ======== sympy.geometry.point.Point3D Examples ======== >>> from sympy import Point3D, Plane >>> a = Plane(Point3D(1, 1, 1), Point3D(2, 3, 4), Point3D(2, 2, 2)) >>> a.p1 Point3D(1, 1, 1) """ return self.args[0] def parallel_plane(self, pt): """ Plane parallel to the given plane and passing through the point pt. Parameters ========== pt: Point3D Returns ======= Plane Examples ======== >>> from sympy import Plane, Point3D >>> a = Plane(Point3D(1, 4, 6), normal_vector=(2, 4, 6)) >>> a.parallel_plane(Point3D(2, 3, 5)) Plane(Point3D(2, 3, 5), (2, 4, 6)) """ a = self.normal_vector return Plane(pt, normal_vector=a) def perpendicular_line(self, pt): """A line perpendicular to the given plane. Parameters ========== pt: Point3D Returns ======= Line3D Examples ======== >>> from sympy import Plane, Point3D, Line3D >>> a = Plane(Point3D(1,4,6), normal_vector=(2, 4, 6)) >>> a.perpendicular_line(Point3D(9, 8, 7)) Line3D(Point3D(9, 8, 7), Point3D(11, 12, 13)) """ a = self.normal_vector return Line3D(pt, direction_ratio=a) def perpendicular_plane(self, *pts): """ Return a perpendicular passing through the given points. If the direction ratio between the points is the same as the Plane's normal vector then, to select from the infinite number of possible planes, a third point will be chosen on the z-axis (or the y-axis if the normal vector is already parallel to the z-axis). If less than two points are given they will be supplied as follows: if no point is given then pt1 will be self.p1; if a second point is not given it will be a point through pt1 on a line parallel to the z-axis (if the normal is not already the z-axis, otherwise on the line parallel to the y-axis). Parameters ========== pts: 0, 1 or 2 Point3D Returns ======= Plane Examples ======== >>> from sympy import Plane, Point3D, Line3D >>> a, b = Point3D(0, 0, 0), Point3D(0, 1, 0) >>> Z = (0, 0, 1) >>> p = Plane(a, normal_vector=Z) >>> p.perpendicular_plane(a, b) Plane(Point3D(0, 0, 0), (1, 0, 0)) """ if len(pts) > 2: raise ValueError('No more than 2 pts should be provided.') pts = list(pts) if len(pts) == 0: pts.append(self.p1) if len(pts) == 1: x, y, z = self.normal_vector if x == y == 0: dir = (0, 1, 0) else: dir = (0, 0, 1) pts.append(pts[0] + Point3D(*dir)) p1, p2 = [Point(i, dim=3) for i in pts] l = Line3D(p1, p2) n = Line3D(p1, direction_ratio=self.normal_vector) if l in n: # XXX should an error be raised instead? # there are infinitely many perpendicular planes; x, y, z = self.normal_vector if x == y == 0: # the z axis is the normal so pick a pt on the y-axis p3 = Point3D(0, 1, 0) # case 1 else: # else pick a pt on the z axis p3 = Point3D(0, 0, 1) # case 2 # in case that point is already given, move it a bit if p3 in l: p3 *= 2 # case 3 else: p3 = p1 + Point3D(*self.normal_vector) # case 4 return Plane(p1, p2, p3) def projection_line(self, line): """Project the given line onto the plane through the normal plane containing the line. Parameters ========== LinearEntity or LinearEntity3D Returns ======= Point3D, Line3D, Ray3D or Segment3D Notes ===== For the interaction between 2D and 3D lines(segments, rays), you should convert the line to 3D by using this method. For example for finding the intersection between a 2D and a 3D line, convert the 2D line to a 3D line by projecting it on a required plane and then proceed to find the intersection between those lines. Examples ======== >>> from sympy import Plane, Line, Line3D, Point, Point3D >>> a = Plane(Point3D(1, 1, 1), normal_vector=(1, 1, 1)) >>> b = Line(Point3D(1, 1), Point3D(2, 2)) >>> a.projection_line(b) Line3D(Point3D(4/3, 4/3, 1/3), Point3D(5/3, 5/3, -1/3)) >>> c = Line3D(Point3D(1, 1, 1), Point3D(2, 2, 2)) >>> a.projection_line(c) Point3D(1, 1, 1) """ from sympy.geometry.line import LinearEntity, LinearEntity3D if not isinstance(line, (LinearEntity, LinearEntity3D)): raise NotImplementedError('Enter a linear entity only') a, b = self.projection(line.p1), self.projection(line.p2) if a == b: # projection does not imply intersection so for # this case (line parallel to plane's normal) we # return the projection point return a if isinstance(line, (Line, Line3D)): return Line3D(a, b) if isinstance(line, (Ray, Ray3D)): return Ray3D(a, b) if isinstance(line, (Segment, Segment3D)): return Segment3D(a, b) def projection(self, pt): """Project the given point onto the plane along the plane normal. Parameters ========== Point or Point3D Returns ======= Point3D Examples ======== >>> from sympy import Plane, Point, Point3D >>> A = Plane(Point3D(1, 1, 2), normal_vector=(1, 1, 1)) The projection is along the normal vector direction, not the z axis, so (1, 1) does not project to (1, 1, 2) on the plane A: >>> b = Point3D(1, 1) >>> A.projection(b) Point3D(5/3, 5/3, 2/3) >>> _ in A True But the point (1, 1, 2) projects to (1, 1) on the XY-plane: >>> XY = Plane((0, 0, 0), (0, 0, 1)) >>> XY.projection((1, 1, 2)) Point3D(1, 1, 0) """ rv = Point(pt, dim=3) if rv in self: return rv return self.intersection(Line3D(rv, rv + Point3D(self.normal_vector)))[0] def random_point(self, seed=None): """ Returns a random point on the Plane. Returns ======= Point3D Examples ======== >>> from sympy import Plane >>> p = Plane((1, 0, 0), normal_vector=(0, 1, 0)) >>> r = p.random_point(seed=42) # seed value is optional >>> r.n(3) Point3D(2.29, 0, -1.35) The random point can be moved to lie on the circle of radius 1 centered on p1: >>> c = p.p1 + (r - p.p1).unit >>> c.distance(p.p1).equals(1) True """ import random if seed is not None: rng = random.Random(seed) else: rng = random u, v = Dummy('u'), Dummy('v') params = { u: 2*Rational(rng.gauss(0, 1)) - 1, v: 2*Rational(rng.gauss(0, 1)) - 1} return self.arbitrary_point(u, v).subs(params) def parameter_value(self, other, u, v=None): """Return the parameter(s) corresponding to the given point. Examples ======== >>> from sympy import Plane, Point, pi >>> from sympy.abc import t, u, v >>> p = Plane((2, 0, 0), (0, 0, 1), (0, 1, 0)) By default, the parameter value returned defines a point that is a distance of 1 from the Plane's p1 value and in line with the given point: >>> on_circle = p.arbitrary_point(t).subs(t, pi/4) >>> on_circle.distance(p.p1) 1 >>> p.parameter_value(on_circle, t) {t: pi/4} Moving the point twice as far from p1 does not change the parameter value: >>> off_circle = p.p1 + (on_circle - p.p1)*2 >>> off_circle.distance(p.p1) 2 >>> p.parameter_value(off_circle, t) {t: pi/4} If the 2-value parameter is desired, supply the two parameter symbols and a replacement dictionary will be returned: >>> p.parameter_value(on_circle, u, v) {u: sqrt(10)/10, v: sqrt(10)/30} >>> p.parameter_value(off_circle, u, v) {u: sqrt(10)/5, v: sqrt(10)/15} """ from sympy.geometry.point import Point from sympy.core.symbol import Dummy from sympy.solvers.solvers import solve if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if not isinstance(other, Point): raise ValueError("other must be a point") if other == self.p1: return other if isinstance(u, Symbol) and v is None: delta = self.arbitrary_point(u) - self.p1 eq = delta - (other - self.p1).unit sol = solve(eq, u, dict=True) elif isinstance(u, Symbol) and isinstance(v, Symbol): pt = self.arbitrary_point(u, v) sol = solve(pt - other, (u, v), dict=True) else: raise ValueError('expecting 1 or 2 symbols') if not sol: raise ValueError("Given point is not on %s" % func_name(self)) return sol[0] # {t: tval} or {u: uval, v: vval} @property def ambient_dimension(self): return self.p1.ambient_dimension

7bc84cca939d5cd389b613042a1f033d9f898ad5c91b253e384f2b244acbc194

"""Elliptical geometrical entities. Contains * Ellipse * Circle """ from __future__ import division, print_function from sympy import Expr, Eq from sympy.core import S, pi, sympify from sympy.core.evaluate import global_evaluate from sympy.core.logic import fuzzy_bool from sympy.core.numbers import Rational, oo from sympy.core.compatibility import ordered from sympy.core.symbol import Dummy, _uniquely_named_symbol, _symbol from sympy.simplify import simplify, trigsimp from sympy.functions.elementary.miscellaneous import sqrt, Max from sympy.functions.elementary.trigonometric import cos, sin from sympy.functions.special.elliptic_integrals import elliptic_e from sympy.geometry.exceptions import GeometryError from sympy.geometry.line import Ray2D, Segment2D, Line2D, LinearEntity3D from sympy.polys import DomainError, Poly, PolynomialError from sympy.polys.polyutils import _not_a_coeff, _nsort from sympy.solvers import solve from sympy.solvers.solveset import linear_coeffs from sympy.utilities.misc import filldedent, func_name from .entity import GeometryEntity, GeometrySet from .point import Point, Point2D, Point3D from .line import Line, Segment from .util import idiff import random class Ellipse(GeometrySet): """An elliptical GeometryEntity. Parameters ========== center : Point, optional Default value is Point(0, 0) hradius : number or SymPy expression, optional vradius : number or SymPy expression, optional eccentricity : number or SymPy expression, optional Two of `hradius`, `vradius` and `eccentricity` must be supplied to create an Ellipse. The third is derived from the two supplied. Attributes ========== center hradius vradius area circumference eccentricity periapsis apoapsis focus_distance foci Raises ====== GeometryError When `hradius`, `vradius` and `eccentricity` are incorrectly supplied as parameters. TypeError When `center` is not a Point. See Also ======== Circle Notes ----- Constructed from a center and two radii, the first being the horizontal radius (along the x-axis) and the second being the vertical radius (along the y-axis). When symbolic value for hradius and vradius are used, any calculation that refers to the foci or the major or minor axis will assume that the ellipse has its major radius on the x-axis. If this is not true then a manual rotation is necessary. Examples ======== >>> from sympy import Ellipse, Point, Rational >>> e1 = Ellipse(Point(0, 0), 5, 1) >>> e1.hradius, e1.vradius (5, 1) >>> e2 = Ellipse(Point(3, 1), hradius=3, eccentricity=Rational(4, 5)) >>> e2 Ellipse(Point2D(3, 1), 3, 9/5) """ def __contains__(self, o): if isinstance(o, Point): x = Dummy('x', real=True) y = Dummy('y', real=True) res = self.equation(x, y).subs({x: o.x, y: o.y}) return trigsimp(simplify(res)) is S.Zero elif isinstance(o, Ellipse): return self == o return False def __eq__(self, o): """Is the other GeometryEntity the same as this ellipse?""" return isinstance(o, Ellipse) and (self.center == o.center and self.hradius == o.hradius and self.vradius == o.vradius) def __hash__(self): return super(Ellipse, self).__hash__() def __new__( cls, center=None, hradius=None, vradius=None, eccentricity=None, **kwargs): hradius = sympify(hradius) vradius = sympify(vradius) eccentricity = sympify(eccentricity) if center is None: center = Point(0, 0) else: center = Point(center, dim=2) if len(center) != 2: raise ValueError('The center of "{0}" must be a two dimensional point'.format(cls)) if len(list(filter(lambda x: x is not None, (hradius, vradius, eccentricity)))) != 2: raise ValueError(filldedent(''' Exactly two arguments of "hradius", "vradius", and "eccentricity" must not be None.''')) if eccentricity is not None: if hradius is None: hradius = vradius / sqrt(1 - eccentricity**2) elif vradius is None: vradius = hradius * sqrt(1 - eccentricity**2) if hradius == vradius: return Circle(center, hradius, **kwargs) if hradius == 0 or vradius == 0: return Segment(Point(center[0] - hradius, center[1] - vradius), Point(center[0] + hradius, center[1] + vradius)) return GeometryEntity.__new__(cls, center, hradius, vradius, **kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG ellipse element for the Ellipse. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N c = N(self.center) h, v = N(self.hradius), N(self.vradius) return ( '<ellipse fill="{1}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" cx="{2}" cy="{3}" rx="{4}" ry="{5}"/>' ).format(2. * scale_factor, fill_color, c.x, c.y, h, v) @property def ambient_dimension(self): return 2 @property def apoapsis(self): """The apoapsis of the ellipse. The greatest distance between the focus and the contour. Returns ======= apoapsis : number See Also ======== periapsis : Returns shortest distance between foci and contour Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.apoapsis 2*sqrt(2) + 3 """ return self.major * (1 + self.eccentricity) def arbitrary_point(self, parameter='t'): """A parameterized point on the ellipse. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= arbitrary_point : Point Raises ====== ValueError When `parameter` already appears in the functions. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.arbitrary_point() Point2D(3*cos(t), 2*sin(t)) """ t = _symbol(parameter, real=True) if t.name in (f.name for f in self.free_symbols): raise ValueError(filldedent('Symbol %s already appears in object ' 'and cannot be used as a parameter.' % t.name)) return Point(self.center.x + self.hradius*cos(t), self.center.y + self.vradius*sin(t)) @property def area(self): """The area of the ellipse. Returns ======= area : number Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.area 3*pi """ return simplify(S.Pi * self.hradius * self.vradius) @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ h, v = self.hradius, self.vradius return (self.center.x - h, self.center.y - v, self.center.x + h, self.center.y + v) @property def center(self): """The center of the ellipse. Returns ======= center : number See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.center Point2D(0, 0) """ return self.args[0] @property def circumference(self): """The circumference of the ellipse. Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.circumference 12*elliptic_e(8/9) """ if self.eccentricity == 1: # degenerate return 4*self.major elif self.eccentricity == 0: # circle return 2*pi*self.hradius else: return 4*self.major*elliptic_e(self.eccentricity**2) @property def eccentricity(self): """The eccentricity of the ellipse. Returns ======= eccentricity : number Examples ======== >>> from sympy import Point, Ellipse, sqrt >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, sqrt(2)) >>> e1.eccentricity sqrt(7)/3 """ return self.focus_distance / self.major def encloses_point(self, p): """ Return True if p is enclosed by (is inside of) self. Notes ----- Being on the border of self is considered False. Parameters ========== p : Point Returns ======= encloses_point : True, False or None See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Ellipse, S >>> from sympy.abc import t >>> e = Ellipse((0, 0), 3, 2) >>> e.encloses_point((0, 0)) True >>> e.encloses_point(e.arbitrary_point(t).subs(t, S.Half)) False >>> e.encloses_point((4, 0)) False """ p = Point(p, dim=2) if p in self: return False if len(self.foci) == 2: # if the combined distance from the foci to p (h1 + h2) is less # than the combined distance from the foci to the minor axis # (which is the same as the major axis length) then p is inside # the ellipse h1, h2 = [f.distance(p) for f in self.foci] test = 2*self.major - (h1 + h2) else: test = self.radius - self.center.distance(p) return fuzzy_bool(test.is_positive) def equation(self, x='x', y='y', _slope=None): """ Returns the equation of an ellipse aligned with the x and y axes; when slope is given, the equation returned corresponds to an ellipse with a major axis having that slope. Parameters ========== x : str, optional Label for the x-axis. Default value is 'x'. y : str, optional Label for the y-axis. Default value is 'y'. _slope : Expr, optional The slope of the major axis. Ignored when 'None'. Returns ======= equation : sympy expression See Also ======== arbitrary_point : Returns parameterized point on ellipse Examples ======== >>> from sympy import Point, Ellipse, pi >>> from sympy.abc import x, y >>> e1 = Ellipse(Point(1, 0), 3, 2) >>> eq1 = e1.equation(x, y); eq1 y**2/4 + (x/3 - 1/3)**2 - 1 >>> eq2 = e1.equation(x, y, _slope=1); eq2 (-x + y + 1)**2/8 + (x + y - 1)**2/18 - 1 A point on e1 satisfies eq1. Let's use one on the x-axis: >>> p1 = e1.center + Point(e1.major, 0) >>> assert eq1.subs(x, p1.x).subs(y, p1.y) == 0 When rotated the same as the rotated ellipse, about the center point of the ellipse, it will satisfy the rotated ellipse's equation, too: >>> r1 = p1.rotate(pi/4, e1.center) >>> assert eq2.subs(x, r1.x).subs(y, r1.y) == 0 References ========== .. [1] https://math.stackexchange.com/questions/108270/what-is-the-equation-of-an-ellipse-that-is-not-aligned-with-the-axis .. [2] https://en.wikipedia.org/wiki/Ellipse#Equation_of_a_shifted_ellipse """ x = _symbol(x, real=True) y = _symbol(y, real=True) dx = x - self.center.x dy = y - self.center.y if _slope is not None: L = (dy - _slope*dx)**2 l = (_slope*dy + dx)**2 h = 1 + _slope**2 b = h*self.major**2 a = h*self.minor**2 return l/b + L/a - 1 else: t1 = (dx/self.hradius)**2 t2 = (dy/self.vradius)**2 return t1 + t2 - 1 def evolute(self, x='x', y='y'): """The equation of evolute of the ellipse. Parameters ========== x : str, optional Label for the x-axis. Default value is 'x'. y : str, optional Label for the y-axis. Default value is 'y'. Returns ======= equation : sympy expression Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(1, 0), 3, 2) >>> e1.evolute() 2**(2/3)*y**(2/3) + (3*x - 3)**(2/3) - 5**(2/3) """ if len(self.args) != 3: raise NotImplementedError('Evolute of arbitrary Ellipse is not supported.') x = _symbol(x, real=True) y = _symbol(y, real=True) t1 = (self.hradius*(x - self.center.x))**Rational(2, 3) t2 = (self.vradius*(y - self.center.y))**Rational(2, 3) return t1 + t2 - (self.hradius**2 - self.vradius**2)**Rational(2, 3) @property def foci(self): """The foci of the ellipse. Notes ----- The foci can only be calculated if the major/minor axes are known. Raises ====== ValueError When the major and minor axis cannot be determined. See Also ======== sympy.geometry.point.Point focus_distance : Returns the distance between focus and center Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.foci (Point2D(-2*sqrt(2), 0), Point2D(2*sqrt(2), 0)) """ c = self.center hr, vr = self.hradius, self.vradius if hr == vr: return (c, c) # calculate focus distance manually, since focus_distance calls this # routine fd = sqrt(self.major**2 - self.minor**2) if hr == self.minor: # foci on the y-axis return (c + Point(0, -fd), c + Point(0, fd)) elif hr == self.major: # foci on the x-axis return (c + Point(-fd, 0), c + Point(fd, 0)) @property def focus_distance(self): """The focal distance of the ellipse. The distance between the center and one focus. Returns ======= focus_distance : number See Also ======== foci Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.focus_distance 2*sqrt(2) """ return Point.distance(self.center, self.foci[0]) @property def hradius(self): """The horizontal radius of the ellipse. Returns ======= hradius : number See Also ======== vradius, major, minor Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.hradius 3 """ return self.args[1] def intersection(self, o): """The intersection of this ellipse and another geometrical entity `o`. Parameters ========== o : GeometryEntity Returns ======= intersection : list of GeometryEntity objects Notes ----- Currently supports intersections with Point, Line, Segment, Ray, Circle and Ellipse types. See Also ======== sympy.geometry.entity.GeometryEntity Examples ======== >>> from sympy import Ellipse, Point, Line, sqrt >>> e = Ellipse(Point(0, 0), 5, 7) >>> e.intersection(Point(0, 0)) [] >>> e.intersection(Point(5, 0)) [Point2D(5, 0)] >>> e.intersection(Line(Point(0,0), Point(0, 1))) [Point2D(0, -7), Point2D(0, 7)] >>> e.intersection(Line(Point(5,0), Point(5, 1))) [Point2D(5, 0)] >>> e.intersection(Line(Point(6,0), Point(6, 1))) [] >>> e = Ellipse(Point(-1, 0), 4, 3) >>> e.intersection(Ellipse(Point(1, 0), 4, 3)) [Point2D(0, -3*sqrt(15)/4), Point2D(0, 3*sqrt(15)/4)] >>> e.intersection(Ellipse(Point(5, 0), 4, 3)) [Point2D(2, -3*sqrt(7)/4), Point2D(2, 3*sqrt(7)/4)] >>> e.intersection(Ellipse(Point(100500, 0), 4, 3)) [] >>> e.intersection(Ellipse(Point(0, 0), 3, 4)) [Point2D(3, 0), Point2D(-363/175, -48*sqrt(111)/175), Point2D(-363/175, 48*sqrt(111)/175)] >>> e.intersection(Ellipse(Point(-1, 0), 3, 4)) [Point2D(-17/5, -12/5), Point2D(-17/5, 12/5), Point2D(7/5, -12/5), Point2D(7/5, 12/5)] """ # TODO: Replace solve with nonlinsolve, when nonlinsolve will be able to solve in real domain x = Dummy('x', real=True) y = Dummy('y', real=True) if isinstance(o, Point): if o in self: return [o] else: return [] elif isinstance(o, (Segment2D, Ray2D)): ellipse_equation = self.equation(x, y) result = solve([ellipse_equation, Line(o.points[0], o.points[1]).equation(x, y)], [x, y]) return list(ordered([Point(i) for i in result if i in o])) elif isinstance(o, Polygon): return o.intersection(self) elif isinstance(o, (Ellipse, Line2D)): if o == self: return self else: ellipse_equation = self.equation(x, y) return list(ordered([Point(i) for i in solve([ellipse_equation, o.equation(x, y)], [x, y])])) elif isinstance(o, LinearEntity3D): raise TypeError('Entity must be two dimensional, not three dimensional') else: raise TypeError('Intersection not handled for %s' % func_name(o)) def is_tangent(self, o): """Is `o` tangent to the ellipse? Parameters ========== o : GeometryEntity An Ellipse, LinearEntity or Polygon Raises ====== NotImplementedError When the wrong type of argument is supplied. Returns ======= is_tangent: boolean True if o is tangent to the ellipse, False otherwise. See Also ======== tangent_lines Examples ======== >>> from sympy import Point, Ellipse, Line >>> p0, p1, p2 = Point(0, 0), Point(3, 0), Point(3, 3) >>> e1 = Ellipse(p0, 3, 2) >>> l1 = Line(p1, p2) >>> e1.is_tangent(l1) True """ if isinstance(o, Point2D): return False elif isinstance(o, Ellipse): intersect = self.intersection(o) if isinstance(intersect, Ellipse): return True elif intersect: return all((self.tangent_lines(i)[0]).equals((o.tangent_lines(i)[0])) for i in intersect) else: return False elif isinstance(o, Line2D): return len(self.intersection(o)) == 1 elif isinstance(o, Ray2D): intersect = self.intersection(o) if len(intersect) == 1: return intersect[0] != o.source and not self.encloses_point(o.source) else: return False elif isinstance(o, (Segment2D, Polygon)): all_tangents = False segments = o.sides if isinstance(o, Polygon) else [o] for segment in segments: intersect = self.intersection(segment) if len(intersect) == 1: if not any(intersect[0] in i for i in segment.points) \ and all(not self.encloses_point(i) for i in segment.points): all_tangents = True continue else: return False else: return all_tangents return all_tangents elif isinstance(o, (LinearEntity3D, Point3D)): raise TypeError('Entity must be two dimensional, not three dimensional') else: raise TypeError('Is_tangent not handled for %s' % func_name(o)) @property def major(self): """Longer axis of the ellipse (if it can be determined) else hradius. Returns ======= major : number or expression See Also ======== hradius, vradius, minor Examples ======== >>> from sympy import Point, Ellipse, Symbol >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.major 3 >>> a = Symbol('a') >>> b = Symbol('b') >>> Ellipse(p1, a, b).major a >>> Ellipse(p1, b, a).major b >>> m = Symbol('m') >>> M = m + 1 >>> Ellipse(p1, m, M).major m + 1 """ ab = self.args[1:3] if len(ab) == 1: return ab[0] a, b = ab o = b - a < 0 if o == True: return a elif o == False: return b return self.hradius @property def minor(self): """Shorter axis of the ellipse (if it can be determined) else vradius. Returns ======= minor : number or expression See Also ======== hradius, vradius, major Examples ======== >>> from sympy import Point, Ellipse, Symbol >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.minor 1 >>> a = Symbol('a') >>> b = Symbol('b') >>> Ellipse(p1, a, b).minor b >>> Ellipse(p1, b, a).minor a >>> m = Symbol('m') >>> M = m + 1 >>> Ellipse(p1, m, M).minor m """ ab = self.args[1:3] if len(ab) == 1: return ab[0] a, b = ab o = a - b < 0 if o == True: return a elif o == False: return b return self.vradius def normal_lines(self, p, prec=None): """Normal lines between `p` and the ellipse. Parameters ========== p : Point Returns ======= normal_lines : list with 1, 2 or 4 Lines Examples ======== >>> from sympy import Line, Point, Ellipse >>> e = Ellipse((0, 0), 2, 3) >>> c = e.center >>> e.normal_lines(c + Point(1, 0)) [Line2D(Point2D(0, 0), Point2D(1, 0))] >>> e.normal_lines(c) [Line2D(Point2D(0, 0), Point2D(0, 1)), Line2D(Point2D(0, 0), Point2D(1, 0))] Off-axis points require the solution of a quartic equation. This often leads to very large expressions that may be of little practical use. An approximate solution of `prec` digits can be obtained by passing in the desired value: >>> e.normal_lines((3, 3), prec=2) [Line2D(Point2D(-0.81, -2.7), Point2D(0.19, -1.2)), Line2D(Point2D(1.5, -2.0), Point2D(2.5, -2.7))] Whereas the above solution has an operation count of 12, the exact solution has an operation count of 2020. """ p = Point(p, dim=2) # XXX change True to something like self.angle == 0 if the arbitrarily # rotated ellipse is introduced. # https://github.com/sympy/sympy/issues/2815) if True: rv = [] if p.x == self.center.x: rv.append(Line(self.center, slope=oo)) if p.y == self.center.y: rv.append(Line(self.center, slope=0)) if rv: # at these special orientations of p either 1 or 2 normals # exist and we are done return rv # find the 4 normal points and construct lines through them with # the corresponding slope x, y = Dummy('x', real=True), Dummy('y', real=True) eq = self.equation(x, y) dydx = idiff(eq, y, x) norm = -1/dydx slope = Line(p, (x, y)).slope seq = slope - norm # TODO: Replace solve with solveset, when this line is tested yis = solve(seq, y)[0] xeq = eq.subs(y, yis).as_numer_denom()[0].expand() if len(xeq.free_symbols) == 1: try: # this is so much faster, it's worth a try xsol = Poly(xeq, x).real_roots() except (DomainError, PolynomialError, NotImplementedError): # TODO: Replace solve with solveset, when these lines are tested xsol = _nsort(solve(xeq, x), separated=True)[0] points = [Point(i, solve(eq.subs(x, i), y)[0]) for i in xsol] else: raise NotImplementedError( 'intersections for the general ellipse are not supported') slopes = [norm.subs(zip((x, y), pt.args)) for pt in points] if prec is not None: points = [pt.n(prec) for pt in points] slopes = [i if _not_a_coeff(i) else i.n(prec) for i in slopes] return [Line(pt, slope=s) for pt, s in zip(points, slopes)] @property def periapsis(self): """The periapsis of the ellipse. The shortest distance between the focus and the contour. Returns ======= periapsis : number See Also ======== apoapsis : Returns greatest distance between focus and contour Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.periapsis 3 - 2*sqrt(2) """ return self.major * (1 - self.eccentricity) @property def semilatus_rectum(self): """ Calculates the semi-latus rectum of the Ellipse. Semi-latus rectum is defined as one half of the the chord through a focus parallel to the conic section directrix of a conic section. Returns ======= semilatus_rectum : number See Also ======== apoapsis : Returns greatest distance between focus and contour periapsis : The shortest distance between the focus and the contour Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.semilatus_rectum 1/3 References ========== [1] http://mathworld.wolfram.com/SemilatusRectum.html [2] https://en.wikipedia.org/wiki/Ellipse#Semi-latus_rectum """ return self.major * (1 - self.eccentricity ** 2) def auxiliary_circle(self): """Returns a Circle whose diameter is the major axis of the ellipse. Examples ======== >>> from sympy import Circle, Ellipse, Point, symbols >>> c = Point(1, 2) >>> Ellipse(c, 8, 7).auxiliary_circle() Circle(Point2D(1, 2), 8) >>> a, b = symbols('a b') >>> Ellipse(c, a, b).auxiliary_circle() Circle(Point2D(1, 2), Max(a, b)) """ return Circle(self.center, Max(self.hradius, self.vradius)) def director_circle(self): """ Returns a Circle consisting of all points where two perpendicular tangent lines to the ellipse cross each other. Returns ======= Circle A director circle returned as a geometric object. Examples ======== >>> from sympy import Circle, Ellipse, Point, symbols >>> c = Point(3,8) >>> Ellipse(c, 7, 9).director_circle() Circle(Point2D(3, 8), sqrt(130)) >>> a, b = symbols('a b') >>> Ellipse(c, a, b).director_circle() Circle(Point2D(3, 8), sqrt(a**2 + b**2)) References ========== .. [1] https://en.wikipedia.org/wiki/Director_circle """ return Circle(self.center, sqrt(self.hradius**2 + self.vradius**2)) def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the Ellipse. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.plot_interval() [t, -pi, pi] """ t = _symbol(parameter, real=True) return [t, -S.Pi, S.Pi] def random_point(self, seed=None): """A random point on the ellipse. Returns ======= point : Point Examples ======== >>> from sympy import Point, Ellipse, Segment >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.random_point() # gives some random point Point2D(...) >>> p1 = e1.random_point(seed=0); p1.n(2) Point2D(2.1, 1.4) Notes ===== When creating a random point, one may simply replace the parameter with a random number. When doing so, however, the random number should be made a Rational or else the point may not test as being in the ellipse: >>> from sympy.abc import t >>> from sympy import Rational >>> arb = e1.arbitrary_point(t); arb Point2D(3*cos(t), 2*sin(t)) >>> arb.subs(t, .1) in e1 False >>> arb.subs(t, Rational(.1)) in e1 True >>> arb.subs(t, Rational('.1')) in e1 True See Also ======== sympy.geometry.point.Point arbitrary_point : Returns parameterized point on ellipse """ from sympy import sin, cos, Rational t = _symbol('t', real=True) x, y = self.arbitrary_point(t).args # get a random value in [-1, 1) corresponding to cos(t) # and confirm that it will test as being in the ellipse if seed is not None: rng = random.Random(seed) else: rng = random # simplify this now or else the Float will turn s into a Float r = Rational(rng.random()) c = 2*r - 1 s = sqrt(1 - c**2) return Point(x.subs(cos(t), c), y.subs(sin(t), s)) def reflect(self, line): """Override GeometryEntity.reflect since the radius is not a GeometryEntity. Examples ======== >>> from sympy import Circle, Line >>> Circle((0, 1), 1).reflect(Line((0, 0), (1, 1))) Circle(Point2D(1, 0), -1) >>> from sympy import Ellipse, Line, Point >>> Ellipse(Point(3, 4), 1, 3).reflect(Line(Point(0, -4), Point(5, 0))) Traceback (most recent call last): ... NotImplementedError: General Ellipse is not supported but the equation of the reflected Ellipse is given by the zeros of: f(x, y) = (9*x/41 + 40*y/41 + 37/41)**2 + (40*x/123 - 3*y/41 - 364/123)**2 - 1 Notes ===== Until the general ellipse (with no axis parallel to the x-axis) is supported a NotImplemented error is raised and the equation whose zeros define the rotated ellipse is given. """ if line.slope in (0, oo): c = self.center c = c.reflect(line) return self.func(c, -self.hradius, self.vradius) else: x, y = [_uniquely_named_symbol( name, (self, line), real=True) for name in 'xy'] expr = self.equation(x, y) p = Point(x, y).reflect(line) result = expr.subs(zip((x, y), p.args ), simultaneous=True) raise NotImplementedError(filldedent( 'General Ellipse is not supported but the equation ' 'of the reflected Ellipse is given by the zeros of: ' + "f(%s, %s) = %s" % (str(x), str(y), str(result)))) def rotate(self, angle=0, pt=None): """Rotate ``angle`` radians counterclockwise about Point ``pt``. Note: since the general ellipse is not supported, only rotations that are integer multiples of pi/2 are allowed. Examples ======== >>> from sympy import Ellipse, pi >>> Ellipse((1, 0), 2, 1).rotate(pi/2) Ellipse(Point2D(0, 1), 1, 2) >>> Ellipse((1, 0), 2, 1).rotate(pi) Ellipse(Point2D(-1, 0), 2, 1) """ if self.hradius == self.vradius: return self.func(self.center.rotate(angle, pt), self.hradius) if (angle/S.Pi).is_integer: return super(Ellipse, self).rotate(angle, pt) if (2*angle/S.Pi).is_integer: return self.func(self.center.rotate(angle, pt), self.vradius, self.hradius) # XXX see https://github.com/sympy/sympy/issues/2815 for general ellipes raise NotImplementedError('Only rotations of pi/2 are currently supported for Ellipse.') def scale(self, x=1, y=1, pt=None): """Override GeometryEntity.scale since it is the major and minor axes which must be scaled and they are not GeometryEntities. Examples ======== >>> from sympy import Ellipse >>> Ellipse((0, 0), 2, 1).scale(2, 4) Circle(Point2D(0, 0), 4) >>> Ellipse((0, 0), 2, 1).scale(2) Ellipse(Point2D(0, 0), 4, 1) """ c = self.center if pt: pt = Point(pt, dim=2) return self.translate(*(-pt).args).scale(x, y).translate(*pt.args) h = self.hradius v = self.vradius return self.func(c.scale(x, y), hradius=h*x, vradius=v*y) def tangent_lines(self, p): """Tangent lines between `p` and the ellipse. If `p` is on the ellipse, returns the tangent line through point `p`. Otherwise, returns the tangent line(s) from `p` to the ellipse, or None if no tangent line is possible (e.g., `p` inside ellipse). Parameters ========== p : Point Returns ======= tangent_lines : list with 1 or 2 Lines Raises ====== NotImplementedError Can only find tangent lines for a point, `p`, on the ellipse. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Line Examples ======== >>> from sympy import Point, Ellipse >>> e1 = Ellipse(Point(0, 0), 3, 2) >>> e1.tangent_lines(Point(3, 0)) [Line2D(Point2D(3, 0), Point2D(3, -12))] """ p = Point(p, dim=2) if self.encloses_point(p): return [] if p in self: delta = self.center - p rise = (self.vradius**2)*delta.x run = -(self.hradius**2)*delta.y p2 = Point(simplify(p.x + run), simplify(p.y + rise)) return [Line(p, p2)] else: if len(self.foci) == 2: f1, f2 = self.foci maj = self.hradius test = (2*maj - Point.distance(f1, p) - Point.distance(f2, p)) else: test = self.radius - Point.distance(self.center, p) if test.is_number and test.is_positive: return [] # else p is outside the ellipse or we can't tell. In case of the # latter, the solutions returned will only be valid if # the point is not inside the ellipse; if it is, nan will result. x, y = Dummy('x'), Dummy('y') eq = self.equation(x, y) dydx = idiff(eq, y, x) slope = Line(p, Point(x, y)).slope # TODO: Replace solve with solveset, when this line is tested tangent_points = solve([slope - dydx, eq], [x, y]) # handle horizontal and vertical tangent lines if len(tangent_points) == 1: assert tangent_points[0][ 0] == p.x or tangent_points[0][1] == p.y return [Line(p, p + Point(1, 0)), Line(p, p + Point(0, 1))] # others return [Line(p, tangent_points[0]), Line(p, tangent_points[1])] @property def vradius(self): """The vertical radius of the ellipse. Returns ======= vradius : number See Also ======== hradius, major, minor Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.vradius 1 """ return self.args[2] def second_moment_of_area(self, point=None): """Returns the second moment and product moment area of an ellipse. Parameters ========== point : Point, two-tuple of sympifiable objects, or None(default=None) point is the point about which second moment of area is to be found. If "point=None" it will be calculated about the axis passing through the centroid of the ellipse. Returns ======= I_xx, I_yy, I_xy : number or sympy expression I_xx, I_yy are second moment of area of an ellise. I_xy is product moment of area of an ellipse. Examples ======== >>> from sympy import Point, Ellipse >>> p1 = Point(0, 0) >>> e1 = Ellipse(p1, 3, 1) >>> e1.second_moment_of_area() (3*pi/4, 27*pi/4, 0) References ========== https://en.wikipedia.org/wiki/List_of_second_moments_of_area """ I_xx = (S.Pi*(self.hradius)*(self.vradius**3))/4 I_yy = (S.Pi*(self.hradius**3)*(self.vradius))/4 I_xy = 0 if point is None: return I_xx, I_yy, I_xy # parallel axis theorem I_xx = I_xx + self.area*((point[1] - self.center.y)**2) I_yy = I_yy + self.area*((point[0] - self.center.x)**2) I_xy = I_xy + self.area*(point[0] - self.center.x)*(point[1] - self.center.y) return I_xx, I_yy, I_xy class Circle(Ellipse): """A circle in space. Constructed simply from a center and a radius, from three non-collinear points, or the equation of a circle. Parameters ========== center : Point radius : number or sympy expression points : sequence of three Points equation : equation of a circle Attributes ========== radius (synonymous with hradius, vradius, major and minor) circumference equation Raises ====== GeometryError When the given equation is not that of a circle. When trying to construct circle from incorrect parameters. See Also ======== Ellipse, sympy.geometry.point.Point Examples ======== >>> from sympy import Eq >>> from sympy.geometry import Point, Circle >>> from sympy.abc import x, y, a, b A circle constructed from a center and radius: >>> c1 = Circle(Point(0, 0), 5) >>> c1.hradius, c1.vradius, c1.radius (5, 5, 5) A circle constructed from three points: >>> c2 = Circle(Point(0, 0), Point(1, 1), Point(1, 0)) >>> c2.hradius, c2.vradius, c2.radius, c2.center (sqrt(2)/2, sqrt(2)/2, sqrt(2)/2, Point2D(1/2, 1/2)) A circle can be constructed from an equation in the form `a*x**2 + by**2 + gx + hy + c = 0`, too: >>> Circle(x**2 + y**2 - 25) Circle(Point2D(0, 0), 5) If the variables corresponding to x and y are named something else, their name or symbol can be supplied: >>> Circle(Eq(a**2 + b**2, 25), x='a', y=b) Circle(Point2D(0, 0), 5) """ def __new__(cls, *args, **kwargs): from sympy.geometry.util import find from .polygon import Triangle evaluate = kwargs.get('evaluate', global_evaluate[0]) if len(args) == 1 and isinstance(args[0], Expr): x = kwargs.get('x', 'x') y = kwargs.get('y', 'y') equation = args[0] if isinstance(equation, Eq): equation = equation.lhs - equation.rhs x = find(x, equation) y = find(y, equation) try: a, b, c, d, e = linear_coeffs(equation, x**2, y**2, x, y) except ValueError: raise GeometryError("The given equation is not that of a circle.") if a == 0 or b == 0 or a != b: raise GeometryError("The given equation is not that of a circle.") center_x = -c/a/2 center_y = -d/b/2 r2 = (center_x**2) + (center_y**2) - e return Circle((center_x, center_y), sqrt(r2), evaluate=evaluate) else: c, r = None, None if len(args) == 3: args = [Point(a, dim=2, evaluate=evaluate) for a in args] t = Triangle(*args) if not isinstance(t, Triangle): return t c = t.circumcenter r = t.circumradius elif len(args) == 2: # Assume (center, radius) pair c = Point(args[0], dim=2, evaluate=evaluate) r = args[1] # this will prohibit imaginary radius try: r = Point(r, 0, evaluate=evaluate).x except: raise GeometryError("Circle with imaginary radius is not permitted") if not (c is None or r is None): if r == 0: return c return GeometryEntity.__new__(cls, c, r, **kwargs) raise GeometryError("Circle.__new__ received unknown arguments") @property def circumference(self): """The circumference of the circle. Returns ======= circumference : number or SymPy expression Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(3, 4), 6) >>> c1.circumference 12*pi """ return 2 * S.Pi * self.radius def equation(self, x='x', y='y'): """The equation of the circle. Parameters ========== x : str or Symbol, optional Default value is 'x'. y : str or Symbol, optional Default value is 'y'. Returns ======= equation : SymPy expression Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(0, 0), 5) >>> c1.equation() x**2 + y**2 - 25 """ x = _symbol(x, real=True) y = _symbol(y, real=True) t1 = (x - self.center.x)**2 t2 = (y - self.center.y)**2 return t1 + t2 - self.major**2 def intersection(self, o): """The intersection of this circle with another geometrical entity. Parameters ========== o : GeometryEntity Returns ======= intersection : list of GeometryEntities Examples ======== >>> from sympy import Point, Circle, Line, Ray >>> p1, p2, p3 = Point(0, 0), Point(5, 5), Point(6, 0) >>> p4 = Point(5, 0) >>> c1 = Circle(p1, 5) >>> c1.intersection(p2) [] >>> c1.intersection(p4) [Point2D(5, 0)] >>> c1.intersection(Ray(p1, p2)) [Point2D(5*sqrt(2)/2, 5*sqrt(2)/2)] >>> c1.intersection(Line(p2, p3)) [] """ return Ellipse.intersection(self, o) @property def radius(self): """The radius of the circle. Returns ======= radius : number or sympy expression See Also ======== Ellipse.major, Ellipse.minor, Ellipse.hradius, Ellipse.vradius Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(3, 4), 6) >>> c1.radius 6 """ return self.args[1] def reflect(self, line): """Override GeometryEntity.reflect since the radius is not a GeometryEntity. Examples ======== >>> from sympy import Circle, Line >>> Circle((0, 1), 1).reflect(Line((0, 0), (1, 1))) Circle(Point2D(1, 0), -1) """ c = self.center c = c.reflect(line) return self.func(c, -self.radius) def scale(self, x=1, y=1, pt=None): """Override GeometryEntity.scale since the radius is not a GeometryEntity. Examples ======== >>> from sympy import Circle >>> Circle((0, 0), 1).scale(2, 2) Circle(Point2D(0, 0), 2) >>> Circle((0, 0), 1).scale(2, 4) Ellipse(Point2D(0, 0), 2, 4) """ c = self.center if pt: pt = Point(pt, dim=2) return self.translate(*(-pt).args).scale(x, y).translate(*pt.args) c = c.scale(x, y) x, y = [abs(i) for i in (x, y)] if x == y: return self.func(c, x*self.radius) h = v = self.radius return Ellipse(c, hradius=h*x, vradius=v*y) @property def vradius(self): """ This Ellipse property is an alias for the Circle's radius. Whereas hradius, major and minor can use Ellipse's conventions, the vradius does not exist for a circle. It is always a positive value in order that the Circle, like Polygons, will have an area that can be positive or negative as determined by the sign of the hradius. Examples ======== >>> from sympy import Point, Circle >>> c1 = Circle(Point(3, 4), 6) >>> c1.vradius 6 """ return abs(self.radius) from .polygon import Polygon

dd799b8566be2c566de8940bdca1e0ad61f4d1fcc05df07c4e91baaacbc4d94c

"""Line-like geometrical entities. Contains ======== LinearEntity Line Ray Segment LinearEntity2D Line2D Ray2D Segment2D LinearEntity3D Line3D Ray3D Segment3D """ from __future__ import division, print_function from sympy import Expr from sympy.core import S, sympify from sympy.core.compatibility import ordered from sympy.core.numbers import Rational, oo from sympy.core.relational import Eq from sympy.core.symbol import _symbol, Dummy from sympy.functions.elementary.trigonometric import (_pi_coeff as pi_coeff, acos, tan, atan2) from sympy.functions.elementary.piecewise import Piecewise from sympy.logic.boolalg import And from sympy.simplify.simplify import simplify from sympy.geometry.exceptions import GeometryError from sympy.core.containers import Tuple from sympy.core.decorators import deprecated from sympy.sets import Intersection from sympy.matrices import Matrix from sympy.solvers.solveset import linear_coeffs from .entity import GeometryEntity, GeometrySet from .point import Point, Point3D from sympy.utilities.misc import Undecidable, filldedent from sympy.utilities.exceptions import SymPyDeprecationWarning class LinearEntity(GeometrySet): """A base class for all linear entities (Line, Ray and Segment) in n-dimensional Euclidean space. Attributes ========== ambient_dimension direction length p1 p2 points Notes ===== This is an abstract class and is not meant to be instantiated. See Also ======== sympy.geometry.entity.GeometryEntity """ def __new__(cls, p1, p2=None, **kwargs): p1, p2 = Point._normalize_dimension(p1, p2) if p1 == p2: # sometimes we return a single point if we are not given two unique # points. This is done in the specific subclass raise ValueError( "%s.__new__ requires two unique Points." % cls.__name__) if len(p1) != len(p2): raise ValueError( "%s.__new__ requires two Points of equal dimension." % cls.__name__) return GeometryEntity.__new__(cls, p1, p2, **kwargs) def __contains__(self, other): """Return a definitive answer or else raise an error if it cannot be determined that other is on the boundaries of self.""" result = self.contains(other) if result is not None: return result else: raise Undecidable( "can't decide whether '%s' contains '%s'" % (self, other)) def _span_test(self, other): """Test whether the point `other` lies in the positive span of `self`. A point x is 'in front' of a point y if x.dot(y) >= 0. Return -1 if `other` is behind `self.p1`, 0 if `other` is `self.p1` and and 1 if `other` is in front of `self.p1`.""" if self.p1 == other: return 0 rel_pos = other - self.p1 d = self.direction if d.dot(rel_pos) > 0: return 1 return -1 @property def ambient_dimension(self): """A property method that returns the dimension of LinearEntity object. Parameters ========== p1 : LinearEntity Returns ======= dimension : integer Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(1, 1) >>> l1 = Line(p1, p2) >>> l1.ambient_dimension 2 >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0, 0), Point(1, 1, 1) >>> l1 = Line(p1, p2) >>> l1.ambient_dimension 3 """ return len(self.p1) def angle_between(l1, l2): """Return the non-reflex angle formed by rays emanating from the origin with directions the same as the direction vectors of the linear entities. Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= angle : angle in radians Notes ===== From the dot product of vectors v1 and v2 it is known that: ``dot(v1, v2) = |v1|*|v2|*cos(A)`` where A is the angle formed between the two vectors. We can get the directional vectors of the two lines and readily find the angle between the two using the above formula. See Also ======== is_perpendicular, Ray2D.closing_angle Examples ======== >>> from sympy import Point, Line, pi >>> e = Line((0, 0), (1, 0)) >>> ne = Line((0, 0), (1, 1)) >>> sw = Line((1, 1), (0, 0)) >>> ne.angle_between(e) pi/4 >>> sw.angle_between(e) 3*pi/4 To obtain the non-obtuse angle at the intersection of lines, use the ``smallest_angle_between`` method: >>> sw.smallest_angle_between(e) pi/4 >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(-1, 2, 0) >>> l1, l2 = Line3D(p1, p2), Line3D(p2, p3) >>> l1.angle_between(l2) acos(-sqrt(2)/3) >>> l1.smallest_angle_between(l2) acos(sqrt(2)/3) """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') v1, v2 = l1.direction, l2.direction return acos(v1.dot(v2)/(abs(v1)*abs(v2))) def smallest_angle_between(l1, l2): """Return the smallest angle formed at the intersection of the lines containing the linear entities. Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= angle : angle in radians See Also ======== angle_between, is_perpendicular, Ray2D.closing_angle Examples ======== >>> from sympy import Point, Line, pi >>> p1, p2, p3 = Point(0, 0), Point(0, 4), Point(2, -2) >>> l1, l2 = Line(p1, p2), Line(p1, p3) >>> l1.smallest_angle_between(l2) pi/4 See Also ======== angle_between, Ray2D.closing_angle """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') v1, v2 = l1.direction, l2.direction return acos(abs(v1.dot(v2))/(abs(v1)*abs(v2))) def arbitrary_point(self, parameter='t'): """A parameterized point on the Line. Parameters ========== parameter : str, optional The name of the parameter which will be used for the parametric point. The default value is 't'. When this parameter is 0, the first point used to define the line will be returned, and when it is 1 the second point will be returned. Returns ======= point : Point Raises ====== ValueError When ``parameter`` already appears in the Line's definition. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(1, 0), Point(5, 3) >>> l1 = Line(p1, p2) >>> l1.arbitrary_point() Point2D(4*t + 1, 3*t) >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(1, 0, 0), Point3D(5, 3, 1) >>> l1 = Line3D(p1, p2) >>> l1.arbitrary_point() Point3D(4*t + 1, 3*t, t) """ t = _symbol(parameter, real=True) if t.name in (f.name for f in self.free_symbols): raise ValueError(filldedent(''' Symbol %s already appears in object and cannot be used as a parameter. ''' % t.name)) # multiply on the right so the variable gets # combined with the coordinates of the point return self.p1 + (self.p2 - self.p1)*t @staticmethod def are_concurrent(*lines): """Is a sequence of linear entities concurrent? Two or more linear entities are concurrent if they all intersect at a single point. Parameters ========== lines : a sequence of linear entities. Returns ======= True : if the set of linear entities intersect in one point False : otherwise. See Also ======== sympy.geometry.util.intersection Examples ======== >>> from sympy import Point, Line, Line3D >>> p1, p2 = Point(0, 0), Point(3, 5) >>> p3, p4 = Point(-2, -2), Point(0, 2) >>> l1, l2, l3 = Line(p1, p2), Line(p1, p3), Line(p1, p4) >>> Line.are_concurrent(l1, l2, l3) True >>> l4 = Line(p2, p3) >>> Line.are_concurrent(l2, l3, l4) False >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(3, 5, 2) >>> p3, p4 = Point3D(-2, -2, -2), Point3D(0, 2, 1) >>> l1, l2, l3 = Line3D(p1, p2), Line3D(p1, p3), Line3D(p1, p4) >>> Line3D.are_concurrent(l1, l2, l3) True >>> l4 = Line3D(p2, p3) >>> Line3D.are_concurrent(l2, l3, l4) False """ common_points = Intersection(*lines) if common_points.is_FiniteSet and len(common_points) == 1: return True return False def contains(self, other): """Subclasses should implement this method and should return True if other is on the boundaries of self; False if not on the boundaries of self; None if a determination cannot be made.""" raise NotImplementedError() @property def direction(self): """The direction vector of the LinearEntity. Returns ======= p : a Point; the ray from the origin to this point is the direction of `self` Examples ======== >>> from sympy.geometry import Line >>> a, b = (1, 1), (1, 3) >>> Line(a, b).direction Point2D(0, 2) >>> Line(b, a).direction Point2D(0, -2) This can be reported so the distance from the origin is 1: >>> Line(b, a).direction.unit Point2D(0, -1) See Also ======== sympy.geometry.point.Point.unit """ return self.p2 - self.p1 def intersection(self, other): """The intersection with another geometrical entity. Parameters ========== o : Point or LinearEntity Returns ======= intersection : list of geometrical entities See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line, Segment >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(7, 7) >>> l1 = Line(p1, p2) >>> l1.intersection(p3) [Point2D(7, 7)] >>> p4, p5 = Point(5, 0), Point(0, 3) >>> l2 = Line(p4, p5) >>> l1.intersection(l2) [Point2D(15/8, 15/8)] >>> p6, p7 = Point(0, 5), Point(2, 6) >>> s1 = Segment(p6, p7) >>> l1.intersection(s1) [] >>> from sympy import Point3D, Line3D, Segment3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(7, 7, 7) >>> l1 = Line3D(p1, p2) >>> l1.intersection(p3) [Point3D(7, 7, 7)] >>> l1 = Line3D(Point3D(4,19,12), Point3D(5,25,17)) >>> l2 = Line3D(Point3D(-3, -15, -19), direction_ratio=[2,8,8]) >>> l1.intersection(l2) [Point3D(1, 1, -3)] >>> p6, p7 = Point3D(0, 5, 2), Point3D(2, 6, 3) >>> s1 = Segment3D(p6, p7) >>> l1.intersection(s1) [] """ def intersect_parallel_rays(ray1, ray2): if ray1.direction.dot(ray2.direction) > 0: # rays point in the same direction # so return the one that is "in front" return [ray2] if ray1._span_test(ray2.p1) >= 0 else [ray1] else: # rays point in opposite directions st = ray1._span_test(ray2.p1) if st < 0: return [] elif st == 0: return [ray2.p1] return [Segment(ray1.p1, ray2.p1)] def intersect_parallel_ray_and_segment(ray, seg): st1, st2 = ray._span_test(seg.p1), ray._span_test(seg.p2) if st1 < 0 and st2 < 0: return [] elif st1 >= 0 and st2 >= 0: return [seg] elif st1 >= 0: # st2 < 0: return [Segment(ray.p1, seg.p1)] elif st2 > 0: # st1 <= 0 return [Segment(ray.p1, seg.p2)] def intersect_parallel_segments(seg1, seg2): if seg1.contains(seg2): return [seg2] if seg2.contains(seg1): return [seg1] # direct the segments so they're oriented the same way if seg1.direction.dot(seg2.direction) < 0: seg2 = Segment(seg2.p2, seg2.p1) # order the segments so seg1 is "behind" seg2 if seg1._span_test(seg2.p1) < 0: seg1, seg2 = seg2, seg1 if seg2._span_test(seg1.p2) < 0: return [] return [Segment(seg2.p1, seg1.p2)] if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if other.is_Point: if self.contains(other): return [other] else: return [] elif isinstance(other, LinearEntity): # break into cases based on whether # the lines are parallel, non-parallel intersecting, or skew pts = Point._normalize_dimension(self.p1, self.p2, other.p1, other.p2) rank = Point.affine_rank(*pts) if rank == 1: # we're collinear if isinstance(self, Line): return [other] if isinstance(other, Line): return [self] if isinstance(self, Ray) and isinstance(other, Ray): return intersect_parallel_rays(self, other) if isinstance(self, Ray) and isinstance(other, Segment): return intersect_parallel_ray_and_segment(self, other) if isinstance(self, Segment) and isinstance(other, Ray): return intersect_parallel_ray_and_segment(other, self) if isinstance(self, Segment) and isinstance(other, Segment): return intersect_parallel_segments(self, other) elif rank == 2: # we're in the same plane l1 = Line(*pts[:2]) l2 = Line(*pts[2:]) # check to see if we're parallel. If we are, we can't # be intersecting, since the collinear case was already # handled if l1.direction.is_scalar_multiple(l2.direction): return [] # find the intersection as if everything were lines # by solving the equation t*d + p1 == s*d' + p1' m = Matrix([l1.direction, -l2.direction]).transpose() v = Matrix([l2.p1 - l1.p1]).transpose() # we cannot use m.solve(v) because that only works for square matrices m_rref, pivots = m.col_insert(2, v).rref(simplify=True) # rank == 2 ensures we have 2 pivots, but let's check anyway if len(pivots) != 2: raise GeometryError("Failed when solving Mx=b when M={} and b={}".format(m, v)) coeff = m_rref[0, 2] line_intersection = l1.direction*coeff + self.p1 # if we're both lines, we can skip a containment check if isinstance(self, Line) and isinstance(other, Line): return [line_intersection] if ((isinstance(self, Line) or self.contains(line_intersection)) and other.contains(line_intersection)): return [line_intersection] return [] else: # we're skew return [] return other.intersection(self) def is_parallel(l1, l2): """Are two linear entities parallel? Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= True : if l1 and l2 are parallel, False : otherwise. See Also ======== coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(1, 1) >>> p3, p4 = Point(3, 4), Point(6, 7) >>> l1, l2 = Line(p1, p2), Line(p3, p4) >>> Line.is_parallel(l1, l2) True >>> p5 = Point(6, 6) >>> l3 = Line(p3, p5) >>> Line.is_parallel(l1, l3) False >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(3, 4, 5) >>> p3, p4 = Point3D(2, 1, 1), Point3D(8, 9, 11) >>> l1, l2 = Line3D(p1, p2), Line3D(p3, p4) >>> Line3D.is_parallel(l1, l2) True >>> p5 = Point3D(6, 6, 6) >>> l3 = Line3D(p3, p5) >>> Line3D.is_parallel(l1, l3) False """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') return l1.direction.is_scalar_multiple(l2.direction) def is_perpendicular(l1, l2): """Are two linear entities perpendicular? Parameters ========== l1 : LinearEntity l2 : LinearEntity Returns ======= True : if l1 and l2 are perpendicular, False : otherwise. See Also ======== coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(-1, 1) >>> l1, l2 = Line(p1, p2), Line(p1, p3) >>> l1.is_perpendicular(l2) True >>> p4 = Point(5, 3) >>> l3 = Line(p1, p4) >>> l1.is_perpendicular(l3) False >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(-1, 2, 0) >>> l1, l2 = Line3D(p1, p2), Line3D(p2, p3) >>> l1.is_perpendicular(l2) False >>> p4 = Point3D(5, 3, 7) >>> l3 = Line3D(p1, p4) >>> l1.is_perpendicular(l3) False """ if not isinstance(l1, LinearEntity) and not isinstance(l2, LinearEntity): raise TypeError('Must pass only LinearEntity objects') return S.Zero.equals(l1.direction.dot(l2.direction)) def is_similar(self, other): """ Return True if self and other are contained in the same line. Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 1), Point(3, 4), Point(2, 3) >>> l1 = Line(p1, p2) >>> l2 = Line(p1, p3) >>> l1.is_similar(l2) True """ l = Line(self.p1, self.p2) return l.contains(other) @property def length(self): """ The length of the line. Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(3, 5) >>> l1 = Line(p1, p2) >>> l1.length oo """ return S.Infinity @property def p1(self): """The first defining point of a linear entity. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l = Line(p1, p2) >>> l.p1 Point2D(0, 0) """ return self.args[0] @property def p2(self): """The second defining point of a linear entity. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l = Line(p1, p2) >>> l.p2 Point2D(5, 3) """ return self.args[1] def parallel_line(self, p): """Create a new Line parallel to this linear entity which passes through the point `p`. Parameters ========== p : Point Returns ======= line : Line See Also ======== is_parallel Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(2, 3), Point(-2, 2) >>> l1 = Line(p1, p2) >>> l2 = l1.parallel_line(p3) >>> p3 in l2 True >>> l1.is_parallel(l2) True >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(2, 3, 4), Point3D(-2, 2, 0) >>> l1 = Line3D(p1, p2) >>> l2 = l1.parallel_line(p3) >>> p3 in l2 True >>> l1.is_parallel(l2) True """ p = Point(p, dim=self.ambient_dimension) return Line(p, p + self.direction) def perpendicular_line(self, p): """Create a new Line perpendicular to this linear entity which passes through the point `p`. Parameters ========== p : Point Returns ======= line : Line See Also ======== is_perpendicular, perpendicular_segment Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(2, 3), Point(-2, 2) >>> l1 = Line(p1, p2) >>> l2 = l1.perpendicular_line(p3) >>> p3 in l2 True >>> l1.is_perpendicular(l2) True >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(2, 3, 4), Point3D(-2, 2, 0) >>> l1 = Line3D(p1, p2) >>> l2 = l1.perpendicular_line(p3) >>> p3 in l2 True >>> l1.is_perpendicular(l2) True """ p = Point(p, dim=self.ambient_dimension) if p in self: p = p + self.direction.orthogonal_direction return Line(p, self.projection(p)) def perpendicular_segment(self, p): """Create a perpendicular line segment from `p` to this line. The enpoints of the segment are ``p`` and the closest point in the line containing self. (If self is not a line, the point might not be in self.) Parameters ========== p : Point Returns ======= segment : Segment Notes ===== Returns `p` itself if `p` is on this linear entity. See Also ======== perpendicular_line Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(0, 2) >>> l1 = Line(p1, p2) >>> s1 = l1.perpendicular_segment(p3) >>> l1.is_perpendicular(s1) True >>> p3 in s1 True >>> l1.perpendicular_segment(Point(4, 0)) Segment2D(Point2D(4, 0), Point2D(2, 2)) >>> from sympy import Point3D, Line3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(0, 2, 0) >>> l1 = Line3D(p1, p2) >>> s1 = l1.perpendicular_segment(p3) >>> l1.is_perpendicular(s1) True >>> p3 in s1 True >>> l1.perpendicular_segment(Point3D(4, 0, 0)) Segment3D(Point3D(4, 0, 0), Point3D(4/3, 4/3, 4/3)) """ p = Point(p, dim=self.ambient_dimension) if p in self: return p l = self.perpendicular_line(p) # The intersection should be unique, so unpack the singleton p2, = Intersection(Line(self.p1, self.p2), l) return Segment(p, p2) @property def points(self): """The two points used to define this linear entity. Returns ======= points : tuple of Points See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 11) >>> l1 = Line(p1, p2) >>> l1.points (Point2D(0, 0), Point2D(5, 11)) """ return (self.p1, self.p2) def projection(self, other): """Project a point, line, ray, or segment onto this linear entity. Parameters ========== other : Point or LinearEntity (Line, Ray, Segment) Returns ======= projection : Point or LinearEntity (Line, Ray, Segment) The return type matches the type of the parameter ``other``. Raises ====== GeometryError When method is unable to perform projection. Notes ===== A projection involves taking the two points that define the linear entity and projecting those points onto a Line and then reforming the linear entity using these projections. A point P is projected onto a line L by finding the point on L that is closest to P. This point is the intersection of L and the line perpendicular to L that passes through P. See Also ======== sympy.geometry.point.Point, perpendicular_line Examples ======== >>> from sympy import Point, Line, Segment, Rational >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(Rational(1, 2), 0) >>> l1 = Line(p1, p2) >>> l1.projection(p3) Point2D(1/4, 1/4) >>> p4, p5 = Point(10, 0), Point(12, 1) >>> s1 = Segment(p4, p5) >>> l1.projection(s1) Segment2D(Point2D(5, 5), Point2D(13/2, 13/2)) >>> p1, p2, p3 = Point(0, 0, 1), Point(1, 1, 2), Point(2, 0, 1) >>> l1 = Line(p1, p2) >>> l1.projection(p3) Point3D(2/3, 2/3, 5/3) >>> p4, p5 = Point(10, 0, 1), Point(12, 1, 3) >>> s1 = Segment(p4, p5) >>> l1.projection(s1) Segment3D(Point3D(10/3, 10/3, 13/3), Point3D(5, 5, 6)) """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) def proj_point(p): return Point.project(p - self.p1, self.direction) + self.p1 if isinstance(other, Point): return proj_point(other) elif isinstance(other, LinearEntity): p1, p2 = proj_point(other.p1), proj_point(other.p2) # test to see if we're degenerate if p1 == p2: return p1 projected = other.__class__(p1, p2) projected = Intersection(self, projected) # if we happen to have intersected in only a point, return that if projected.is_FiniteSet and len(projected) == 1: # projected is a set of size 1, so unpack it in `a` a, = projected return a # order args so projection is in the same direction as self if self.direction.dot(projected.direction) < 0: p1, p2 = projected.args projected = projected.func(p2, p1) return projected raise GeometryError( "Do not know how to project %s onto %s" % (other, self)) def random_point(self, seed=None): """A random point on a LinearEntity. Returns ======= point : Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Line, Ray, Segment >>> p1, p2 = Point(0, 0), Point(5, 3) >>> line = Line(p1, p2) >>> r = line.random_point(seed=42) # seed value is optional >>> r.n(3) Point2D(-0.72, -0.432) >>> r in line True >>> Ray(p1, p2).random_point(seed=42).n(3) Point2D(0.72, 0.432) >>> Segment(p1, p2).random_point(seed=42).n(3) Point2D(3.2, 1.92) """ import random if seed is not None: rng = random.Random(seed) else: rng = random t = Dummy() pt = self.arbitrary_point(t) if isinstance(self, Ray): v = abs(rng.gauss(0, 1)) elif isinstance(self, Segment): v = rng.random() elif isinstance(self, Line): v = rng.gauss(0, 1) else: raise NotImplementedError('unhandled line type') return pt.subs(t, Rational(v)) class Line(LinearEntity): """An infinite line in space. A 2D line is declared with two distinct points, point and slope, or an equation. A 3D line may be defined with a point and a direction ratio. Parameters ========== p1 : Point p2 : Point slope : sympy expression direction_ratio : list equation : equation of a line Notes ===== `Line` will automatically subclass to `Line2D` or `Line3D` based on the dimension of `p1`. The `slope` argument is only relevant for `Line2D` and the `direction_ratio` argument is only relevant for `Line3D`. See Also ======== sympy.geometry.point.Point sympy.geometry.line.Line2D sympy.geometry.line.Line3D Examples ======== >>> from sympy import Point, Eq >>> from sympy.geometry import Line, Segment >>> from sympy.abc import x, y, a, b >>> L = Line(Point(2,3), Point(3,5)) >>> L Line2D(Point2D(2, 3), Point2D(3, 5)) >>> L.points (Point2D(2, 3), Point2D(3, 5)) >>> L.equation() -2*x + y + 1 >>> L.coefficients (-2, 1, 1) Instantiate with keyword ``slope``: >>> Line(Point(0, 0), slope=0) Line2D(Point2D(0, 0), Point2D(1, 0)) Instantiate with another linear object >>> s = Segment((0, 0), (0, 1)) >>> Line(s).equation() x The line corresponding to an equation in the for `ax + by + c = 0`, can be entered: >>> Line(3*x + y + 18) Line2D(Point2D(0, -18), Point2D(1, -21)) If `x` or `y` has a different name, then they can be specified, too, as a string (to match the name) or symbol: >>> Line(Eq(3*a + b, -18), x='a', y=b) Line2D(Point2D(0, -18), Point2D(1, -21)) """ def __new__(cls, *args, **kwargs): from sympy.geometry.util import find if len(args) == 1 and isinstance(args[0], Expr): x = kwargs.get('x', 'x') y = kwargs.get('y', 'y') equation = args[0] if isinstance(equation, Eq): equation = equation.lhs - equation.rhs xin, yin = x, y x = find(x, equation) or Dummy() y = find(y, equation) or Dummy() a, b, c = linear_coeffs(equation, x, y) if b: return Line((0, -c/b), slope=-a/b) if a: return Line((-c/a, 0), slope=oo) raise ValueError('neither %s nor %s were found in the equation' % (xin, yin)) else: if len(args) > 0: p1 = args[0] if len(args) > 1: p2 = args[1] else: p2=None if isinstance(p1, LinearEntity): if p2: raise ValueError('If p1 is a LinearEntity, p2 must be None.') dim = len(p1.p1) else: p1 = Point(p1) dim = len(p1) if p2 is not None or isinstance(p2, Point) and p2.ambient_dimension != dim: p2 = Point(p2) if dim == 2: return Line2D(p1, p2, **kwargs) elif dim == 3: return Line3D(p1, p2, **kwargs) return LinearEntity.__new__(cls, p1, p2, **kwargs) def contains(self, other): """ Return True if `other` is on this Line, or False otherwise. Examples ======== >>> from sympy import Line,Point >>> p1, p2 = Point(0, 1), Point(3, 4) >>> l = Line(p1, p2) >>> l.contains(p1) True >>> l.contains((0, 1)) True >>> l.contains((0, 0)) False >>> a = (0, 0, 0) >>> b = (1, 1, 1) >>> c = (2, 2, 2) >>> l1 = Line(a, b) >>> l2 = Line(b, a) >>> l1 == l2 False >>> l1 in l2 True """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): return Point.is_collinear(other, self.p1, self.p2) if isinstance(other, LinearEntity): return Point.is_collinear(self.p1, self.p2, other.p1, other.p2) return False def distance(self, other): """ Finds the shortest distance between a line and a point. Raises ====== NotImplementedError is raised if `other` is not a Point Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(1, 1) >>> s = Line(p1, p2) >>> s.distance(Point(-1, 1)) sqrt(2) >>> s.distance((-1, 2)) 3*sqrt(2)/2 >>> p1, p2 = Point(0, 0, 0), Point(1, 1, 1) >>> s = Line(p1, p2) >>> s.distance(Point(-1, 1, 1)) 2*sqrt(6)/3 >>> s.distance((-1, 1, 1)) 2*sqrt(6)/3 """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if self.contains(other): return S.Zero return self.perpendicular_segment(other).length @deprecated(useinstead="equals", issue=12860, deprecated_since_version="1.0") def equal(self, other): return self.equals(other) def equals(self, other): """Returns True if self and other are the same mathematical entities""" if not isinstance(other, Line): return False return Point.is_collinear(self.p1, other.p1, self.p2, other.p2) def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of line. Gives values that will produce a line that is +/- 5 units long (where a unit is the distance between the two points that define the line). Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list (plot interval) [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l1 = Line(p1, p2) >>> l1.plot_interval() [t, -5, 5] """ t = _symbol(parameter, real=True) return [t, -5, 5] class Ray(LinearEntity): """A Ray is a semi-line in the space with a source point and a direction. Parameters ========== p1 : Point The source of the Ray p2 : Point or radian value This point determines the direction in which the Ray propagates. If given as an angle it is interpreted in radians with the positive direction being ccw. Attributes ========== source See Also ======== sympy.geometry.line.Ray2D sympy.geometry.line.Ray3D sympy.geometry.point.Point sympy.geometry.line.Line Notes ===== `Ray` will automatically subclass to `Ray2D` or `Ray3D` based on the dimension of `p1`. Examples ======== >>> from sympy import Point, pi >>> from sympy.geometry import Ray >>> r = Ray(Point(2, 3), Point(3, 5)) >>> r Ray2D(Point2D(2, 3), Point2D(3, 5)) >>> r.points (Point2D(2, 3), Point2D(3, 5)) >>> r.source Point2D(2, 3) >>> r.xdirection oo >>> r.ydirection oo >>> r.slope 2 >>> Ray(Point(0, 0), angle=pi/4).slope 1 """ def __new__(cls, p1, p2=None, **kwargs): p1 = Point(p1) if p2 is not None: p1, p2 = Point._normalize_dimension(p1, Point(p2)) dim = len(p1) if dim == 2: return Ray2D(p1, p2, **kwargs) elif dim == 3: return Ray3D(p1, p2, **kwargs) return LinearEntity.__new__(cls, p1, *pts, **kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the LinearEntity. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = (N(self.p1), N(self.p2)) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1}".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" ' 'marker-start="url(#markerCircle)" marker-end="url(#markerArrow)"/>' ).format(2. * scale_factor, path, fill_color) def contains(self, other): """ Is other GeometryEntity contained in this Ray? Examples ======== >>> from sympy import Ray,Point,Segment >>> p1, p2 = Point(0, 0), Point(4, 4) >>> r = Ray(p1, p2) >>> r.contains(p1) True >>> r.contains((1, 1)) True >>> r.contains((1, 3)) False >>> s = Segment((1, 1), (2, 2)) >>> r.contains(s) True >>> s = Segment((1, 2), (2, 5)) >>> r.contains(s) False >>> r1 = Ray((2, 2), (3, 3)) >>> r.contains(r1) True >>> r1 = Ray((2, 2), (3, 5)) >>> r.contains(r1) False """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): if Point.is_collinear(self.p1, self.p2, other): # if we're in the direction of the ray, our # direction vector dot the ray's direction vector # should be non-negative return bool((self.p2 - self.p1).dot(other - self.p1) >= S.Zero) return False elif isinstance(other, Ray): if Point.is_collinear(self.p1, self.p2, other.p1, other.p2): return bool((self.p2 - self.p1).dot(other.p2 - other.p1) > S.Zero) return False elif isinstance(other, Segment): return other.p1 in self and other.p2 in self # No other known entity can be contained in a Ray return False def distance(self, other): """ Finds the shortest distance between the ray and a point. Raises ====== NotImplementedError is raised if `other` is not a Point Examples ======== >>> from sympy import Point, Ray >>> p1, p2 = Point(0, 0), Point(1, 1) >>> s = Ray(p1, p2) >>> s.distance(Point(-1, -1)) sqrt(2) >>> s.distance((-1, 2)) 3*sqrt(2)/2 >>> p1, p2 = Point(0, 0, 0), Point(1, 1, 2) >>> s = Ray(p1, p2) >>> s Ray3D(Point3D(0, 0, 0), Point3D(1, 1, 2)) >>> s.distance(Point(-1, -1, 2)) 4*sqrt(3)/3 >>> s.distance((-1, -1, 2)) 4*sqrt(3)/3 """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if self.contains(other): return S.Zero proj = Line(self.p1, self.p2).projection(other) if self.contains(proj): return abs(other - proj) else: return abs(other - self.source) def equals(self, other): """Returns True if self and other are the same mathematical entities""" if not isinstance(other, Ray): return False return self.source == other.source and other.p2 in self def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the Ray. Gives values that will produce a ray that is 10 units long (where a unit is the distance between the two points that define the ray). Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Ray, pi >>> r = Ray((0, 0), angle=pi/4) >>> r.plot_interval() [t, 0, 10] """ t = _symbol(parameter, real=True) return [t, 0, 10] @property def source(self): """The point from which the ray emanates. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Ray >>> p1, p2 = Point(0, 0), Point(4, 1) >>> r1 = Ray(p1, p2) >>> r1.source Point2D(0, 0) >>> p1, p2 = Point(0, 0, 0), Point(4, 1, 5) >>> r1 = Ray(p2, p1) >>> r1.source Point3D(4, 1, 5) """ return self.p1 class Segment(LinearEntity): """A line segment in space. Parameters ========== p1 : Point p2 : Point Attributes ========== length : number or sympy expression midpoint : Point See Also ======== sympy.geometry.line.Segment2D sympy.geometry.line.Segment3D sympy.geometry.point.Point sympy.geometry.line.Line Notes ===== If 2D or 3D points are used to define `Segment`, it will be automatically subclassed to `Segment2D` or `Segment3D`. Examples ======== >>> from sympy import Point >>> from sympy.geometry import Segment >>> Segment((1, 0), (1, 1)) # tuples are interpreted as pts Segment2D(Point2D(1, 0), Point2D(1, 1)) >>> s = Segment(Point(4, 3), Point(1, 1)) >>> s.points (Point2D(4, 3), Point2D(1, 1)) >>> s.slope 2/3 >>> s.length sqrt(13) >>> s.midpoint Point2D(5/2, 2) >>> Segment((1, 0, 0), (1, 1, 1)) # tuples are interpreted as pts Segment3D(Point3D(1, 0, 0), Point3D(1, 1, 1)) >>> s = Segment(Point(4, 3, 9), Point(1, 1, 7)); s Segment3D(Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.points (Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.length sqrt(17) >>> s.midpoint Point3D(5/2, 2, 8) """ def __new__(cls, p1, p2, **kwargs): p1, p2 = Point._normalize_dimension(Point(p1), Point(p2)) dim = len(p1) if dim == 2: return Segment2D(p1, p2, **kwargs) elif dim == 3: return Segment3D(p1, p2, **kwargs) return LinearEntity.__new__(cls, p1, p2, **kwargs) def contains(self, other): """ Is the other GeometryEntity contained within this Segment? Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 1), Point(3, 4) >>> s = Segment(p1, p2) >>> s2 = Segment(p2, p1) >>> s.contains(s2) True >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 1, 1), Point3D(3, 4, 5) >>> s = Segment3D(p1, p2) >>> s2 = Segment3D(p2, p1) >>> s.contains(s2) True >>> s.contains((p1 + p2) / 2) True """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): if Point.is_collinear(other, self.p1, self.p2): if isinstance(self, Segment2D): # if it is collinear and is in the bounding box of the # segment then it must be on the segment vert = (1/self.slope).equals(0) if vert is False: isin = (self.p1.x - other.x)*(self.p2.x - other.x) <= 0 if isin in (True, False): return isin if vert is True: isin = (self.p1.y - other.y)*(self.p2.y - other.y) <= 0 if isin in (True, False): return isin # use the triangle inequality d1, d2 = other - self.p1, other - self.p2 d = self.p2 - self.p1 # without the call to simplify, sympy cannot tell that an expression # like (a+b)*(a/2+b/2) is always non-negative. If it cannot be # determined, raise an Undecidable error try: # the triangle inequality says that |d1|+|d2| >= |d| and is strict # only if other lies in the line segment return bool(simplify(Eq(abs(d1) + abs(d2) - abs(d), 0))) except TypeError: raise Undecidable("Cannot determine if {} is in {}".format(other, self)) if isinstance(other, Segment): return other.p1 in self and other.p2 in self return False def equals(self, other): """Returns True if self and other are the same mathematical entities""" return isinstance(other, self.func) and list( ordered(self.args)) == list(ordered(other.args)) def distance(self, other): """ Finds the shortest distance between a line segment and a point. Raises ====== NotImplementedError is raised if `other` is not a Point Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 1), Point(3, 4) >>> s = Segment(p1, p2) >>> s.distance(Point(10, 15)) sqrt(170) >>> s.distance((0, 12)) sqrt(73) >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 0, 3), Point3D(1, 1, 4) >>> s = Segment3D(p1, p2) >>> s.distance(Point3D(10, 15, 12)) sqrt(341) >>> s.distance((10, 15, 12)) sqrt(341) """ if not isinstance(other, GeometryEntity): other = Point(other, dim=self.ambient_dimension) if isinstance(other, Point): vp1 = other - self.p1 vp2 = other - self.p2 dot_prod_sign_1 = self.direction.dot(vp1) >= 0 dot_prod_sign_2 = self.direction.dot(vp2) <= 0 if dot_prod_sign_1 and dot_prod_sign_2: return Line(self.p1, self.p2).distance(other) if dot_prod_sign_1 and not dot_prod_sign_2: return abs(vp2) if not dot_prod_sign_1 and dot_prod_sign_2: return abs(vp1) raise NotImplementedError() @property def length(self): """The length of the line segment. See Also ======== sympy.geometry.point.Point.distance Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 0), Point(4, 3) >>> s1 = Segment(p1, p2) >>> s1.length 5 >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(4, 3, 3) >>> s1 = Segment3D(p1, p2) >>> s1.length sqrt(34) """ return Point.distance(self.p1, self.p2) @property def midpoint(self): """The midpoint of the line segment. See Also ======== sympy.geometry.point.Point.midpoint Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 0), Point(4, 3) >>> s1 = Segment(p1, p2) >>> s1.midpoint Point2D(2, 3/2) >>> from sympy import Point3D, Segment3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(4, 3, 3) >>> s1 = Segment3D(p1, p2) >>> s1.midpoint Point3D(2, 3/2, 3/2) """ return Point.midpoint(self.p1, self.p2) def perpendicular_bisector(self, p=None): """The perpendicular bisector of this segment. If no point is specified or the point specified is not on the bisector then the bisector is returned as a Line. Otherwise a Segment is returned that joins the point specified and the intersection of the bisector and the segment. Parameters ========== p : Point Returns ======= bisector : Line or Segment See Also ======== LinearEntity.perpendicular_segment Examples ======== >>> from sympy import Point, Segment >>> p1, p2, p3 = Point(0, 0), Point(6, 6), Point(5, 1) >>> s1 = Segment(p1, p2) >>> s1.perpendicular_bisector() Line2D(Point2D(3, 3), Point2D(-3, 9)) >>> s1.perpendicular_bisector(p3) Segment2D(Point2D(5, 1), Point2D(3, 3)) """ l = self.perpendicular_line(self.midpoint) if p is not None: p2 = Point(p, dim=self.ambient_dimension) if p2 in l: return Segment(p2, self.midpoint) return l def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the Segment gives values that will produce the full segment in a plot. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Point, Segment >>> p1, p2 = Point(0, 0), Point(5, 3) >>> s1 = Segment(p1, p2) >>> s1.plot_interval() [t, 0, 1] """ t = _symbol(parameter, real=True) return [t, 0, 1] class LinearEntity2D(LinearEntity): """A base class for all linear entities (line, ray and segment) in a 2-dimensional Euclidean space. Attributes ========== p1 p2 coefficients slope points Notes ===== This is an abstract class and is not meant to be instantiated. See Also ======== sympy.geometry.entity.GeometryEntity """ @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ verts = self.points xs = [p.x for p in verts] ys = [p.y for p in verts] return (min(xs), min(ys), max(xs), max(ys)) def perpendicular_line(self, p): """Create a new Line perpendicular to this linear entity which passes through the point `p`. Parameters ========== p : Point Returns ======= line : Line See Also ======== is_perpendicular, perpendicular_segment Examples ======== >>> from sympy import Point, Line >>> p1, p2, p3 = Point(0, 0), Point(2, 3), Point(-2, 2) >>> l1 = Line(p1, p2) >>> l2 = l1.perpendicular_line(p3) >>> p3 in l2 True >>> l1.is_perpendicular(l2) True """ p = Point(p, dim=self.ambient_dimension) # any two lines in R^2 intersect, so blindly making # a line through p in an orthogonal direction will work return Line(p, p + self.direction.orthogonal_direction) @property def slope(self): """The slope of this linear entity, or infinity if vertical. Returns ======= slope : number or sympy expression See Also ======== coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(0, 0), Point(3, 5) >>> l1 = Line(p1, p2) >>> l1.slope 5/3 >>> p3 = Point(0, 4) >>> l2 = Line(p1, p3) >>> l2.slope oo """ d1, d2 = (self.p1 - self.p2).args if d1 == 0: return S.Infinity return simplify(d2/d1) class Line2D(LinearEntity2D, Line): """An infinite line in space 2D. A line is declared with two distinct points or a point and slope as defined using keyword `slope`. Parameters ========== p1 : Point pt : Point slope : sympy expression See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point >>> from sympy.abc import L >>> from sympy.geometry import Line, Segment >>> L = Line(Point(2,3), Point(3,5)) >>> L Line2D(Point2D(2, 3), Point2D(3, 5)) >>> L.points (Point2D(2, 3), Point2D(3, 5)) >>> L.equation() -2*x + y + 1 >>> L.coefficients (-2, 1, 1) Instantiate with keyword ``slope``: >>> Line(Point(0, 0), slope=0) Line2D(Point2D(0, 0), Point2D(1, 0)) Instantiate with another linear object >>> s = Segment((0, 0), (0, 1)) >>> Line(s).equation() x """ def __new__(cls, p1, pt=None, slope=None, **kwargs): if isinstance(p1, LinearEntity): if pt is not None: raise ValueError('When p1 is a LinearEntity, pt should be None') p1, pt = Point._normalize_dimension(*p1.args, dim=2) else: p1 = Point(p1, dim=2) if pt is not None and slope is None: try: p2 = Point(pt, dim=2) except (NotImplementedError, TypeError, ValueError): raise ValueError(filldedent(''' The 2nd argument was not a valid Point. If it was a slope, enter it with keyword "slope". ''')) elif slope is not None and pt is None: slope = sympify(slope) if slope.is_finite is False: # when infinite slope, don't change x dx = 0 dy = 1 else: # go over 1 up slope dx = 1 dy = slope # XXX avoiding simplification by adding to coords directly p2 = Point(p1.x + dx, p1.y + dy, evaluate=False) else: raise ValueError('A 2nd Point or keyword "slope" must be used.') return LinearEntity2D.__new__(cls, p1, p2, **kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the LinearEntity. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = (N(self.p1), N(self.p2)) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1}".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" ' 'marker-start="url(#markerReverseArrow)" marker-end="url(#markerArrow)"/>' ).format(2. * scale_factor, path, fill_color) @property def coefficients(self): """The coefficients (`a`, `b`, `c`) for `ax + by + c = 0`. See Also ======== sympy.geometry.line.Line.equation Examples ======== >>> from sympy import Point, Line >>> from sympy.abc import x, y >>> p1, p2 = Point(0, 0), Point(5, 3) >>> l = Line(p1, p2) >>> l.coefficients (-3, 5, 0) >>> p3 = Point(x, y) >>> l2 = Line(p1, p3) >>> l2.coefficients (-y, x, 0) """ p1, p2 = self.points if p1.x == p2.x: return (S.One, S.Zero, -p1.x) elif p1.y == p2.y: return (S.Zero, S.One, -p1.y) return tuple([simplify(i) for i in (self.p1.y - self.p2.y, self.p2.x - self.p1.x, self.p1.x*self.p2.y - self.p1.y*self.p2.x)]) def equation(self, x='x', y='y'): """The equation of the line: ax + by + c. Parameters ========== x : str, optional The name to use for the x-axis, default value is 'x'. y : str, optional The name to use for the y-axis, default value is 'y'. Returns ======= equation : sympy expression See Also ======== LinearEntity.coefficients Examples ======== >>> from sympy import Point, Line >>> p1, p2 = Point(1, 0), Point(5, 3) >>> l1 = Line(p1, p2) >>> l1.equation() -3*x + 4*y + 3 """ x = _symbol(x, real=True) y = _symbol(y, real=True) p1, p2 = self.points if p1.x == p2.x: return x - p1.x elif p1.y == p2.y: return y - p1.y a, b, c = self.coefficients return a*x + b*y + c class Ray2D(LinearEntity2D, Ray): """ A Ray is a semi-line in the space with a source point and a direction. Parameters ========== p1 : Point The source of the Ray p2 : Point or radian value This point determines the direction in which the Ray propagates. If given as an angle it is interpreted in radians with the positive direction being ccw. Attributes ========== source xdirection ydirection See Also ======== sympy.geometry.point.Point, Line Examples ======== >>> from sympy import Point, pi >>> from sympy.geometry import Ray >>> r = Ray(Point(2, 3), Point(3, 5)) >>> r Ray2D(Point2D(2, 3), Point2D(3, 5)) >>> r.points (Point2D(2, 3), Point2D(3, 5)) >>> r.source Point2D(2, 3) >>> r.xdirection oo >>> r.ydirection oo >>> r.slope 2 >>> Ray(Point(0, 0), angle=pi/4).slope 1 """ def __new__(cls, p1, pt=None, angle=None, **kwargs): p1 = Point(p1, dim=2) if pt is not None and angle is None: try: p2 = Point(pt, dim=2) except (NotImplementedError, TypeError, ValueError): from sympy.utilities.misc import filldedent raise ValueError(filldedent(''' The 2nd argument was not a valid Point; if it was meant to be an angle it should be given with keyword "angle".''')) if p1 == p2: raise ValueError('A Ray requires two distinct points.') elif angle is not None and pt is None: # we need to know if the angle is an odd multiple of pi/2 c = pi_coeff(sympify(angle)) p2 = None if c is not None: if c.is_Rational: if c.q == 2: if c.p == 1: p2 = p1 + Point(0, 1) elif c.p == 3: p2 = p1 + Point(0, -1) elif c.q == 1: if c.p == 0: p2 = p1 + Point(1, 0) elif c.p == 1: p2 = p1 + Point(-1, 0) if p2 is None: c *= S.Pi else: c = angle % (2*S.Pi) if not p2: m = 2*c/S.Pi left = And(1 < m, m < 3) # is it in quadrant 2 or 3? x = Piecewise((-1, left), (Piecewise((0, Eq(m % 1, 0)), (1, True)), True)) y = Piecewise((-tan(c), left), (Piecewise((1, Eq(m, 1)), (-1, Eq(m, 3)), (tan(c), True)), True)) p2 = p1 + Point(x, y) else: raise ValueError('A 2nd point or keyword "angle" must be used.') return LinearEntity2D.__new__(cls, p1, p2, **kwargs) @property def xdirection(self): """The x direction of the ray. Positive infinity if the ray points in the positive x direction, negative infinity if the ray points in the negative x direction, or 0 if the ray is vertical. See Also ======== ydirection Examples ======== >>> from sympy import Point, Ray >>> p1, p2, p3 = Point(0, 0), Point(1, 1), Point(0, -1) >>> r1, r2 = Ray(p1, p2), Ray(p1, p3) >>> r1.xdirection oo >>> r2.xdirection 0 """ if self.p1.x < self.p2.x: return S.Infinity elif self.p1.x == self.p2.x: return S.Zero else: return S.NegativeInfinity @property def ydirection(self): """The y direction of the ray. Positive infinity if the ray points in the positive y direction, negative infinity if the ray points in the negative y direction, or 0 if the ray is horizontal. See Also ======== xdirection Examples ======== >>> from sympy import Point, Ray >>> p1, p2, p3 = Point(0, 0), Point(-1, -1), Point(-1, 0) >>> r1, r2 = Ray(p1, p2), Ray(p1, p3) >>> r1.ydirection -oo >>> r2.ydirection 0 """ if self.p1.y < self.p2.y: return S.Infinity elif self.p1.y == self.p2.y: return S.Zero else: return S.NegativeInfinity def closing_angle(r1, r2): """Return the angle by which r2 must be rotated so it faces the same direction as r1. Parameters ========== r1 : Ray2D r2 : Ray2D Returns ======= angle : angle in radians (ccw angle is positive) See Also ======== LinearEntity.angle_between Examples ======== >>> from sympy import Ray, pi >>> r1 = Ray((0, 0), (1, 0)) >>> r2 = r1.rotate(-pi/2) >>> angle = r1.closing_angle(r2); angle pi/2 >>> r2.rotate(angle).direction.unit == r1.direction.unit True >>> r2.closing_angle(r1) -pi/2 """ if not all(isinstance(r, Ray2D) for r in (r1, r2)): # although the direction property is defined for # all linear entities, only the Ray is truly a # directed object raise TypeError('Both arguments must be Ray2D objects.') a1 = atan2(*list(reversed(r1.direction.args))) a2 = atan2(*list(reversed(r2.direction.args))) if a1*a2 < 0: a1 = 2*S.Pi + a1 if a1 < 0 else a1 a2 = 2*S.Pi + a2 if a2 < 0 else a2 return a1 - a2 class Segment2D(LinearEntity2D, Segment): """A line segment in 2D space. Parameters ========== p1 : Point p2 : Point Attributes ========== length : number or sympy expression midpoint : Point See Also ======== sympy.geometry.point.Point, Line Examples ======== >>> from sympy import Point >>> from sympy.geometry import Segment >>> Segment((1, 0), (1, 1)) # tuples are interpreted as pts Segment2D(Point2D(1, 0), Point2D(1, 1)) >>> s = Segment(Point(4, 3), Point(1, 1)); s Segment2D(Point2D(4, 3), Point2D(1, 1)) >>> s.points (Point2D(4, 3), Point2D(1, 1)) >>> s.slope 2/3 >>> s.length sqrt(13) >>> s.midpoint Point2D(5/2, 2) """ def __new__(cls, p1, p2, **kwargs): p1 = Point(p1, dim=2) p2 = Point(p2, dim=2) if p1 == p2: return p1 return LinearEntity2D.__new__(cls, p1, p2, **kwargs) def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the LinearEntity. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = (N(self.p1), N(self.p2)) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1}".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" />' ).format(2. * scale_factor, path, fill_color) class LinearEntity3D(LinearEntity): """An base class for all linear entities (line, ray and segment) in a 3-dimensional Euclidean space. Attributes ========== p1 p2 direction_ratio direction_cosine points Notes ===== This is a base class and is not meant to be instantiated. """ def __new__(cls, p1, p2, **kwargs): p1 = Point3D(p1, dim=3) p2 = Point3D(p2, dim=3) if p1 == p2: # if it makes sense to return a Point, handle in subclass raise ValueError( "%s.__new__ requires two unique Points." % cls.__name__) return GeometryEntity.__new__(cls, p1, p2, **kwargs) ambient_dimension = 3 @property def direction_ratio(self): """The direction ratio of a given line in 3D. See Also ======== sympy.geometry.line.Line.equation Examples ======== >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(5, 3, 1) >>> l = Line3D(p1, p2) >>> l.direction_ratio [5, 3, 1] """ p1, p2 = self.points return p1.direction_ratio(p2) @property def direction_cosine(self): """The normalized direction ratio of a given line in 3D. See Also ======== sympy.geometry.line.Line.equation Examples ======== >>> from sympy import Point3D, Line3D >>> p1, p2 = Point3D(0, 0, 0), Point3D(5, 3, 1) >>> l = Line3D(p1, p2) >>> l.direction_cosine [sqrt(35)/7, 3*sqrt(35)/35, sqrt(35)/35] >>> sum(i**2 for i in _) 1 """ p1, p2 = self.points return p1.direction_cosine(p2) class Line3D(LinearEntity3D, Line): """An infinite 3D line in space. A line is declared with two distinct points or a point and direction_ratio as defined using keyword `direction_ratio`. Parameters ========== p1 : Point3D pt : Point3D direction_ratio : list See Also ======== sympy.geometry.point.Point3D sympy.geometry.line.Line sympy.geometry.line.Line2D Examples ======== >>> from sympy import Point3D >>> from sympy.geometry import Line3D, Segment3D >>> L = Line3D(Point3D(2, 3, 4), Point3D(3, 5, 1)) >>> L Line3D(Point3D(2, 3, 4), Point3D(3, 5, 1)) >>> L.points (Point3D(2, 3, 4), Point3D(3, 5, 1)) """ def __new__(cls, p1, pt=None, direction_ratio=[], **kwargs): if isinstance(p1, LinearEntity3D): if pt is not None: raise ValueError('if p1 is a LinearEntity, pt must be None.') p1, pt = p1.args else: p1 = Point(p1, dim=3) if pt is not None and len(direction_ratio) == 0: pt = Point(pt, dim=3) elif len(direction_ratio) == 3 and pt is None: pt = Point3D(p1.x + direction_ratio[0], p1.y + direction_ratio[1], p1.z + direction_ratio[2]) else: raise ValueError('A 2nd Point or keyword "direction_ratio" must ' 'be used.') return LinearEntity3D.__new__(cls, p1, pt, **kwargs) def equation(self, x='x', y='y', z='z', k=None): """Return the equations that define the line in 3D. Parameters ========== x : str, optional The name to use for the x-axis, default value is 'x'. y : str, optional The name to use for the y-axis, default value is 'y'. z : str, optional The name to use for the z-axis, default value is 'z'. Returns ======= equation : Tuple of simultaneous equations Examples ======== >>> from sympy import Point3D, Line3D, solve >>> from sympy.abc import x, y, z >>> p1, p2 = Point3D(1, 0, 0), Point3D(5, 3, 0) >>> l1 = Line3D(p1, p2) >>> eq = l1.equation(x, y, z); eq (-3*x + 4*y + 3, z) >>> solve(eq.subs(z, 0), (x, y, z)) {x: 4*y/3 + 1} """ if k is not None: SymPyDeprecationWarning( feature="equation() no longer needs 'k'", issue=13742, deprecated_since_version="1.2").warn() from sympy import solve x, y, z, k = [_symbol(i, real=True) for i in (x, y, z, 'k')] p1, p2 = self.points d1, d2, d3 = p1.direction_ratio(p2) x1, y1, z1 = p1 v = (x, y, z) eqs = [-d1*k + x - x1, -d2*k + y - y1, -d3*k + z - z1] # eliminate k from equations by solving first eq with k for k for i, e in enumerate(eqs): if e.has(k): kk = solve(eqs[i], k)[0] eqs.pop(i) break return Tuple(*[i.subs(k, kk).as_numer_denom()[0] for i in eqs]) class Ray3D(LinearEntity3D, Ray): """ A Ray is a semi-line in the space with a source point and a direction. Parameters ========== p1 : Point3D The source of the Ray p2 : Point or a direction vector direction_ratio: Determines the direction in which the Ray propagates. Attributes ========== source xdirection ydirection zdirection See Also ======== sympy.geometry.point.Point3D, Line3D Examples ======== >>> from sympy import Point3D >>> from sympy.geometry import Ray3D >>> r = Ray3D(Point3D(2, 3, 4), Point3D(3, 5, 0)) >>> r Ray3D(Point3D(2, 3, 4), Point3D(3, 5, 0)) >>> r.points (Point3D(2, 3, 4), Point3D(3, 5, 0)) >>> r.source Point3D(2, 3, 4) >>> r.xdirection oo >>> r.ydirection oo >>> r.direction_ratio [1, 2, -4] """ def __new__(cls, p1, pt=None, direction_ratio=[], **kwargs): from sympy.utilities.misc import filldedent if isinstance(p1, LinearEntity3D): if pt is not None: raise ValueError('If p1 is a LinearEntity, pt must be None') p1, pt = p1.args else: p1 = Point(p1, dim=3) if pt is not None and len(direction_ratio) == 0: pt = Point(pt, dim=3) elif len(direction_ratio) == 3 and pt is None: pt = Point3D(p1.x + direction_ratio[0], p1.y + direction_ratio[1], p1.z + direction_ratio[2]) else: raise ValueError(filldedent(''' A 2nd Point or keyword "direction_ratio" must be used. ''')) return LinearEntity3D.__new__(cls, p1, pt, **kwargs) @property def xdirection(self): """The x direction of the ray. Positive infinity if the ray points in the positive x direction, negative infinity if the ray points in the negative x direction, or 0 if the ray is vertical. See Also ======== ydirection Examples ======== >>> from sympy import Point3D, Ray3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(1, 1, 1), Point3D(0, -1, 0) >>> r1, r2 = Ray3D(p1, p2), Ray3D(p1, p3) >>> r1.xdirection oo >>> r2.xdirection 0 """ if self.p1.x < self.p2.x: return S.Infinity elif self.p1.x == self.p2.x: return S.Zero else: return S.NegativeInfinity @property def ydirection(self): """The y direction of the ray. Positive infinity if the ray points in the positive y direction, negative infinity if the ray points in the negative y direction, or 0 if the ray is horizontal. See Also ======== xdirection Examples ======== >>> from sympy import Point3D, Ray3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(-1, -1, -1), Point3D(-1, 0, 0) >>> r1, r2 = Ray3D(p1, p2), Ray3D(p1, p3) >>> r1.ydirection -oo >>> r2.ydirection 0 """ if self.p1.y < self.p2.y: return S.Infinity elif self.p1.y == self.p2.y: return S.Zero else: return S.NegativeInfinity @property def zdirection(self): """The z direction of the ray. Positive infinity if the ray points in the positive z direction, negative infinity if the ray points in the negative z direction, or 0 if the ray is horizontal. See Also ======== xdirection Examples ======== >>> from sympy import Point3D, Ray3D >>> p1, p2, p3 = Point3D(0, 0, 0), Point3D(-1, -1, -1), Point3D(-1, 0, 0) >>> r1, r2 = Ray3D(p1, p2), Ray3D(p1, p3) >>> r1.ydirection -oo >>> r2.ydirection 0 >>> r2.zdirection 0 """ if self.p1.z < self.p2.z: return S.Infinity elif self.p1.z == self.p2.z: return S.Zero else: return S.NegativeInfinity class Segment3D(LinearEntity3D, Segment): """A line segment in a 3D space. Parameters ========== p1 : Point3D p2 : Point3D Attributes ========== length : number or sympy expression midpoint : Point3D See Also ======== sympy.geometry.point.Point3D, Line3D Examples ======== >>> from sympy import Point3D >>> from sympy.geometry import Segment3D >>> Segment3D((1, 0, 0), (1, 1, 1)) # tuples are interpreted as pts Segment3D(Point3D(1, 0, 0), Point3D(1, 1, 1)) >>> s = Segment3D(Point3D(4, 3, 9), Point3D(1, 1, 7)); s Segment3D(Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.points (Point3D(4, 3, 9), Point3D(1, 1, 7)) >>> s.length sqrt(17) >>> s.midpoint Point3D(5/2, 2, 8) """ def __new__(cls, p1, p2, **kwargs): p1 = Point(p1, dim=3) p2 = Point(p2, dim=3) if p1 == p2: return p1 return LinearEntity3D.__new__(cls, p1, p2, **kwargs)

e86ac40ab6a8cda9b2266decdd2d70b836a5e02ab9a89c637dc3a9bf85f94a11

from __future__ import division, print_function from sympy.core import Expr, S, Symbol, oo, pi, sympify from sympy.core.compatibility import as_int, range, ordered from sympy.core.symbol import _symbol, Dummy from sympy.functions.elementary.complexes import sign from sympy.functions.elementary.piecewise import Piecewise from sympy.functions.elementary.trigonometric import cos, sin, tan from sympy.geometry.exceptions import GeometryError from sympy.logic import And from sympy.matrices import Matrix from sympy.simplify import simplify from sympy.utilities import default_sort_key from sympy.utilities.iterables import has_dups, has_variety, uniq, rotate_left, least_rotation from sympy.utilities.misc import func_name from .entity import GeometryEntity, GeometrySet from .point import Point from .ellipse import Circle from .line import Line, Segment, Ray from sympy import sqrt import warnings class Polygon(GeometrySet): """A two-dimensional polygon. A simple polygon in space. Can be constructed from a sequence of points or from a center, radius, number of sides and rotation angle. Parameters ========== vertices : sequence of Points Attributes ========== area angles perimeter vertices centroid sides Raises ====== GeometryError If all parameters are not Points. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment, Triangle Notes ===== Polygons are treated as closed paths rather than 2D areas so some calculations can be be negative or positive (e.g., area) based on the orientation of the points. Any consecutive identical points are reduced to a single point and any points collinear and between two points will be removed unless they are needed to define an explicit intersection (see examples). A Triangle, Segment or Point will be returned when there are 3 or fewer points provided. Examples ======== >>> from sympy import Point, Polygon, pi >>> p1, p2, p3, p4, p5 = [(0, 0), (1, 0), (5, 1), (0, 1), (3, 0)] >>> Polygon(p1, p2, p3, p4) Polygon(Point2D(0, 0), Point2D(1, 0), Point2D(5, 1), Point2D(0, 1)) >>> Polygon(p1, p2) Segment2D(Point2D(0, 0), Point2D(1, 0)) >>> Polygon(p1, p2, p5) Segment2D(Point2D(0, 0), Point2D(3, 0)) The area of a polygon is calculated as positive when vertices are traversed in a ccw direction. When the sides of a polygon cross the area will have positive and negative contributions. The following defines a Z shape where the bottom right connects back to the top left. >>> Polygon((0, 2), (2, 2), (0, 0), (2, 0)).area 0 When the the keyword `n` is used to define the number of sides of the Polygon then a RegularPolygon is created and the other arguments are interpreted as center, radius and rotation. The unrotated RegularPolygon will always have a vertex at Point(r, 0) where `r` is the radius of the circle that circumscribes the RegularPolygon. Its method `spin` can be used to increment that angle. >>> p = Polygon((0,0), 1, n=3) >>> p RegularPolygon(Point2D(0, 0), 1, 3, 0) >>> p.vertices[0] Point2D(1, 0) >>> p.args[0] Point2D(0, 0) >>> p.spin(pi/2) >>> p.vertices[0] Point2D(0, 1) """ def __new__(cls, *args, **kwargs): if kwargs.get('n', 0): n = kwargs.pop('n') args = list(args) # return a virtual polygon with n sides if len(args) == 2: # center, radius args.append(n) elif len(args) == 3: # center, radius, rotation args.insert(2, n) return RegularPolygon(*args, **kwargs) vertices = [Point(a, dim=2, **kwargs) for a in args] # remove consecutive duplicates nodup = [] for p in vertices: if nodup and p == nodup[-1]: continue nodup.append(p) if len(nodup) > 1 and nodup[-1] == nodup[0]: nodup.pop() # last point was same as first # remove collinear points i = -3 while i < len(nodup) - 3 and len(nodup) > 2: a, b, c = nodup[i], nodup[i + 1], nodup[i + 2] if Point.is_collinear(a, b, c): nodup.pop(i + 1) if a == c: nodup.pop(i) else: i += 1 vertices = list(nodup) if len(vertices) > 3: return GeometryEntity.__new__(cls, *vertices, **kwargs) elif len(vertices) == 3: return Triangle(*vertices, **kwargs) elif len(vertices) == 2: return Segment(*vertices, **kwargs) else: return Point(*vertices, **kwargs) @property def area(self): """ The area of the polygon. Notes ===== The area calculation can be positive or negative based on the orientation of the points. If any side of the polygon crosses any other side, there will be areas having opposite signs. See Also ======== sympy.geometry.ellipse.Ellipse.area Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.area 3 In the Z shaped polygon (with the lower right connecting back to the upper left) the areas cancel out: >>> Z = Polygon((0, 1), (1, 1), (0, 0), (1, 0)) >>> Z.area 0 In the M shaped polygon, areas do not cancel because no side crosses any other (though there is a point of contact). >>> M = Polygon((0, 0), (0, 1), (2, 0), (3, 1), (3, 0)) >>> M.area -3/2 """ area = 0 args = self.args for i in range(len(args)): x1, y1 = args[i - 1].args x2, y2 = args[i].args area += x1*y2 - x2*y1 return simplify(area) / 2 @staticmethod def _isright(a, b, c): """Return True/False for cw/ccw orientation. Examples ======== >>> from sympy import Point, Polygon >>> a, b, c = [Point(i) for i in [(0, 0), (1, 1), (1, 0)]] >>> Polygon._isright(a, b, c) True >>> Polygon._isright(a, c, b) False """ ba = b - a ca = c - a t_area = simplify(ba.x*ca.y - ca.x*ba.y) res = t_area.is_nonpositive if res is None: raise ValueError("Can't determine orientation") return res @property def angles(self): """The internal angle at each vertex. Returns ======= angles : dict A dictionary where each key is a vertex and each value is the internal angle at that vertex. The vertices are represented as Points. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.LinearEntity.angle_between Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.angles[p1] pi/2 >>> poly.angles[p2] acos(-4*sqrt(17)/17) """ # Determine orientation of points args = self.vertices cw = self._isright(args[-1], args[0], args[1]) ret = {} for i in range(len(args)): a, b, c = args[i - 2], args[i - 1], args[i] ang = Ray(b, a).angle_between(Ray(b, c)) if cw ^ self._isright(a, b, c): ret[b] = 2*S.Pi - ang else: ret[b] = ang return ret @property def ambient_dimension(self): return self.vertices[0].ambient_dimension @property def perimeter(self): """The perimeter of the polygon. Returns ======= perimeter : number or Basic instance See Also ======== sympy.geometry.line.Segment.length Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.perimeter sqrt(17) + 7 """ p = 0 args = self.vertices for i in range(len(args)): p += args[i - 1].distance(args[i]) return simplify(p) @property def vertices(self): """The vertices of the polygon. Returns ======= vertices : list of Points Notes ===== When iterating over the vertices, it is more efficient to index self rather than to request the vertices and index them. Only use the vertices when you want to process all of them at once. This is even more important with RegularPolygons that calculate each vertex. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.vertices [Point2D(0, 0), Point2D(1, 0), Point2D(5, 1), Point2D(0, 1)] >>> poly.vertices[0] Point2D(0, 0) """ return list(self.args) @property def centroid(self): """The centroid of the polygon. Returns ======= centroid : Point See Also ======== sympy.geometry.point.Point, sympy.geometry.util.centroid Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.centroid Point2D(31/18, 11/18) """ A = 1/(6*self.area) cx, cy = 0, 0 args = self.args for i in range(len(args)): x1, y1 = args[i - 1].args x2, y2 = args[i].args v = x1*y2 - x2*y1 cx += v*(x1 + x2) cy += v*(y1 + y2) return Point(simplify(A*cx), simplify(A*cy)) def second_moment_of_area(self, point=None): """Returns the second moment and product moment of area of a two dimensional polygon. Parameters ========== point : Point, two-tuple of sympifiable objects, or None(default=None) point is the point about which second moment of area is to be found. If "point=None" it will be calculated about the axis passing through the centroid of the polygon. Returns ======= I_xx, I_yy, I_xy : number or sympy expression I_xx, I_yy are second moment of area of a two dimensional polygon. I_xy is product moment of area of a two dimensional polygon. Examples ======== >>> from sympy import Point, Polygon, symbols >>> a, b = symbols('a, b') >>> p1, p2, p3, p4, p5 = [(0, 0), (a, 0), (a, b), (0, b), (a/3, b/3)] >>> rectangle = Polygon(p1, p2, p3, p4) >>> rectangle.second_moment_of_area() (a*b**3/12, a**3*b/12, 0) >>> rectangle.second_moment_of_area(p5) (a*b**3/9, a**3*b/9, a**2*b**2/36) References ========== https://en.wikipedia.org/wiki/Second_moment_of_area """ I_xx, I_yy, I_xy = 0, 0, 0 args = self.args for i in range(len(args)): x1, y1 = args[i-1].args x2, y2 = args[i].args v = x1*y2 - x2*y1 I_xx += (y1**2 + y1*y2 + y2**2)*v I_yy += (x1**2 + x1*x2 + x2**2)*v I_xy += (x1*y2 + 2*x1*y1 + 2*x2*y2 + x2*y1)*v A = self.area c_x = self.centroid[0] c_y = self.centroid[1] # parallel axis theorem I_xx_c = (I_xx/12) - (A*(c_y**2)) I_yy_c = (I_yy/12) - (A*(c_x**2)) I_xy_c = (I_xy/24) - (A*(c_x*c_y)) if point is None: return I_xx_c, I_yy_c, I_xy_c I_xx = (I_xx_c + A*((point[1]-c_y)**2)) I_yy = (I_yy_c + A*((point[0]-c_x)**2)) I_xy = (I_xy_c + A*((point[0]-c_x)*(point[1]-c_y))) return I_xx, I_yy, I_xy @property def sides(self): """The directed line segments that form the sides of the polygon. Returns ======= sides : list of sides Each side is a directed Segment. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.sides [Segment2D(Point2D(0, 0), Point2D(1, 0)), Segment2D(Point2D(1, 0), Point2D(5, 1)), Segment2D(Point2D(5, 1), Point2D(0, 1)), Segment2D(Point2D(0, 1), Point2D(0, 0))] """ res = [] args = self.vertices for i in range(-len(args), 0): res.append(Segment(args[i], args[i + 1])) return res @property def bounds(self): """Return a tuple (xmin, ymin, xmax, ymax) representing the bounding rectangle for the geometric figure. """ verts = self.vertices xs = [p.x for p in verts] ys = [p.y for p in verts] return (min(xs), min(ys), max(xs), max(ys)) def is_convex(self): """Is the polygon convex? A polygon is convex if all its interior angles are less than 180 degrees and there are no intersections between sides. Returns ======= is_convex : boolean True if this polygon is convex, False otherwise. See Also ======== sympy.geometry.util.convex_hull Examples ======== >>> from sympy import Point, Polygon >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly = Polygon(p1, p2, p3, p4) >>> poly.is_convex() True """ # Determine orientation of points args = self.vertices cw = self._isright(args[-2], args[-1], args[0]) for i in range(1, len(args)): if cw ^ self._isright(args[i - 2], args[i - 1], args[i]): return False # check for intersecting sides sides = self.sides for i, si in enumerate(sides): pts = si.args # exclude the sides connected to si for j in range(1 if i == len(sides) - 1 else 0, i - 1): sj = sides[j] if sj.p1 not in pts and sj.p2 not in pts: hit = si.intersection(sj) if hit: return False return True def encloses_point(self, p): """ Return True if p is enclosed by (is inside of) self. Notes ===== Being on the border of self is considered False. Parameters ========== p : Point Returns ======= encloses_point : True, False or None See Also ======== sympy.geometry.point.Point, sympy.geometry.ellipse.Ellipse.encloses_point Examples ======== >>> from sympy import Polygon, Point >>> from sympy.abc import t >>> p = Polygon((0, 0), (4, 0), (4, 4)) >>> p.encloses_point(Point(2, 1)) True >>> p.encloses_point(Point(2, 2)) False >>> p.encloses_point(Point(5, 5)) False References ========== [1] http://paulbourke.net/geometry/polygonmesh/#insidepoly """ p = Point(p, dim=2) if p in self.vertices or any(p in s for s in self.sides): return False # move to p, checking that the result is numeric lit = [] for v in self.vertices: lit.append(v - p) # the difference is simplified if lit[-1].free_symbols: return None poly = Polygon(*lit) # polygon closure is assumed in the following test but Polygon removes duplicate pts so # the last point has to be added so all sides are computed. Using Polygon.sides is # not good since Segments are unordered. args = poly.args indices = list(range(-len(args), 1)) if poly.is_convex(): orientation = None for i in indices: a = args[i] b = args[i + 1] test = ((-a.y)*(b.x - a.x) - (-a.x)*(b.y - a.y)).is_negative if orientation is None: orientation = test elif test is not orientation: return False return True hit_odd = False p1x, p1y = args[0].args for i in indices[1:]: p2x, p2y = args[i].args if 0 > min(p1y, p2y): if 0 <= max(p1y, p2y): if 0 <= max(p1x, p2x): if p1y != p2y: xinters = (-p1y)*(p2x - p1x)/(p2y - p1y) + p1x if p1x == p2x or 0 <= xinters: hit_odd = not hit_odd p1x, p1y = p2x, p2y return hit_odd def arbitrary_point(self, parameter='t'): """A parameterized point on the polygon. The parameter, varying from 0 to 1, assigns points to the position on the perimeter that is that fraction of the total perimeter. So the point evaluated at t=1/2 would return the point from the first vertex that is 1/2 way around the polygon. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= arbitrary_point : Point Raises ====== ValueError When `parameter` already appears in the Polygon's definition. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy import Polygon, S, Symbol >>> t = Symbol('t', real=True) >>> tri = Polygon((0, 0), (1, 0), (1, 1)) >>> p = tri.arbitrary_point('t') >>> perimeter = tri.perimeter >>> s1, s2 = [s.length for s in tri.sides[:2]] >>> p.subs(t, (s1 + s2/2)/perimeter) Point2D(1, 1/2) """ t = _symbol(parameter, real=True) if t.name in (f.name for f in self.free_symbols): raise ValueError('Symbol %s already appears in object and cannot be used as a parameter.' % t.name) sides = [] perimeter = self.perimeter perim_fraction_start = 0 for s in self.sides: side_perim_fraction = s.length/perimeter perim_fraction_end = perim_fraction_start + side_perim_fraction pt = s.arbitrary_point(parameter).subs( t, (t - perim_fraction_start)/side_perim_fraction) sides.append( (pt, (And(perim_fraction_start <= t, t < perim_fraction_end)))) perim_fraction_start = perim_fraction_end return Piecewise(*sides) def parameter_value(self, other, t): from sympy.solvers.solvers import solve if not isinstance(other,GeometryEntity): other = Point(other, dim=self.ambient_dimension) if not isinstance(other,Point): raise ValueError("other must be a point") if other.free_symbols: raise NotImplementedError('non-numeric coordinates') unknown = False T = Dummy('t', real=True) p = self.arbitrary_point(T) for pt, cond in p.args: sol = solve(pt - other, T, dict=True) if not sol: continue value = sol[0][T] if simplify(cond.subs(T, value)) == True: return {t: value} unknown = True if unknown: raise ValueError("Given point may not be on %s" % func_name(self)) raise ValueError("Given point is not on %s" % func_name(self)) def plot_interval(self, parameter='t'): """The plot interval for the default geometric plot of the polygon. Parameters ========== parameter : str, optional Default value is 't'. Returns ======= plot_interval : list (plot interval) [parameter, lower_bound, upper_bound] Examples ======== >>> from sympy import Polygon >>> p = Polygon((0, 0), (1, 0), (1, 1)) >>> p.plot_interval() [t, 0, 1] """ t = Symbol(parameter, real=True) return [t, 0, 1] def intersection(self, o): """The intersection of polygon and geometry entity. The intersection may be empty and can contain individual Points and complete Line Segments. Parameters ========== other: GeometryEntity Returns ======= intersection : list The list of Segments and Points See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment Examples ======== >>> from sympy import Point, Polygon, Line >>> p1, p2, p3, p4 = map(Point, [(0, 0), (1, 0), (5, 1), (0, 1)]) >>> poly1 = Polygon(p1, p2, p3, p4) >>> p5, p6, p7 = map(Point, [(3, 2), (1, -1), (0, 2)]) >>> poly2 = Polygon(p5, p6, p7) >>> poly1.intersection(poly2) [Point2D(1/3, 1), Point2D(2/3, 0), Point2D(9/5, 1/5), Point2D(7/3, 1)] >>> poly1.intersection(Line(p1, p2)) [Segment2D(Point2D(0, 0), Point2D(1, 0))] >>> poly1.intersection(p1) [Point2D(0, 0)] """ intersection_result = [] k = o.sides if isinstance(o, Polygon) else [o] for side in self.sides: for side1 in k: intersection_result.extend(side.intersection(side1)) intersection_result = list(uniq(intersection_result)) points = [entity for entity in intersection_result if isinstance(entity, Point)] segments = [entity for entity in intersection_result if isinstance(entity, Segment)] if points and segments: points_in_segments = list(uniq([point for point in points for segment in segments if point in segment])) if points_in_segments: for i in points_in_segments: points.remove(i) return list(ordered(segments + points)) else: return list(ordered(intersection_result)) def distance(self, o): """ Returns the shortest distance between self and o. If o is a point, then self does not need to be convex. If o is another polygon self and o must be convex. Examples ======== >>> from sympy import Point, Polygon, RegularPolygon >>> p1, p2 = map(Point, [(0, 0), (7, 5)]) >>> poly = Polygon(*RegularPolygon(p1, 1, 3).vertices) >>> poly.distance(p2) sqrt(61) """ if isinstance(o, Point): dist = oo for side in self.sides: current = side.distance(o) if current == 0: return S.Zero elif current < dist: dist = current return dist elif isinstance(o, Polygon) and self.is_convex() and o.is_convex(): return self._do_poly_distance(o) raise NotImplementedError() def _do_poly_distance(self, e2): """ Calculates the least distance between the exteriors of two convex polygons e1 and e2. Does not check for the convexity of the polygons as this is checked by Polygon.distance. Notes ===== - Prints a warning if the two polygons possibly intersect as the return value will not be valid in such a case. For a more through test of intersection use intersection(). See Also ======== sympy.geometry.point.Point.distance Examples ======== >>> from sympy.geometry import Point, Polygon >>> square = Polygon(Point(0, 0), Point(0, 1), Point(1, 1), Point(1, 0)) >>> triangle = Polygon(Point(1, 2), Point(2, 2), Point(2, 1)) >>> square._do_poly_distance(triangle) sqrt(2)/2 Description of method used ========================== Method: [1] http://cgm.cs.mcgill.ca/~orm/mind2p.html Uses rotating calipers: [2] https://en.wikipedia.org/wiki/Rotating_calipers and antipodal points: [3] https://en.wikipedia.org/wiki/Antipodal_point """ e1 = self '''Tests for a possible intersection between the polygons and outputs a warning''' e1_center = e1.centroid e2_center = e2.centroid e1_max_radius = S.Zero e2_max_radius = S.Zero for vertex in e1.vertices: r = Point.distance(e1_center, vertex) if e1_max_radius < r: e1_max_radius = r for vertex in e2.vertices: r = Point.distance(e2_center, vertex) if e2_max_radius < r: e2_max_radius = r center_dist = Point.distance(e1_center, e2_center) if center_dist <= e1_max_radius + e2_max_radius: warnings.warn("Polygons may intersect producing erroneous output") ''' Find the upper rightmost vertex of e1 and the lowest leftmost vertex of e2 ''' e1_ymax = Point(0, -oo) e2_ymin = Point(0, oo) for vertex in e1.vertices: if vertex.y > e1_ymax.y or (vertex.y == e1_ymax.y and vertex.x > e1_ymax.x): e1_ymax = vertex for vertex in e2.vertices: if vertex.y < e2_ymin.y or (vertex.y == e2_ymin.y and vertex.x < e2_ymin.x): e2_ymin = vertex min_dist = Point.distance(e1_ymax, e2_ymin) ''' Produce a dictionary with vertices of e1 as the keys and, for each vertex, the points to which the vertex is connected as its value. The same is then done for e2. ''' e1_connections = {} e2_connections = {} for side in e1.sides: if side.p1 in e1_connections: e1_connections[side.p1].append(side.p2) else: e1_connections[side.p1] = [side.p2] if side.p2 in e1_connections: e1_connections[side.p2].append(side.p1) else: e1_connections[side.p2] = [side.p1] for side in e2.sides: if side.p1 in e2_connections: e2_connections[side.p1].append(side.p2) else: e2_connections[side.p1] = [side.p2] if side.p2 in e2_connections: e2_connections[side.p2].append(side.p1) else: e2_connections[side.p2] = [side.p1] e1_current = e1_ymax e2_current = e2_ymin support_line = Line(Point(S.Zero, S.Zero), Point(S.One, S.Zero)) ''' Determine which point in e1 and e2 will be selected after e2_ymin and e1_ymax, this information combined with the above produced dictionaries determines the path that will be taken around the polygons ''' point1 = e1_connections[e1_ymax][0] point2 = e1_connections[e1_ymax][1] angle1 = support_line.angle_between(Line(e1_ymax, point1)) angle2 = support_line.angle_between(Line(e1_ymax, point2)) if angle1 < angle2: e1_next = point1 elif angle2 < angle1: e1_next = point2 elif Point.distance(e1_ymax, point1) > Point.distance(e1_ymax, point2): e1_next = point2 else: e1_next = point1 point1 = e2_connections[e2_ymin][0] point2 = e2_connections[e2_ymin][1] angle1 = support_line.angle_between(Line(e2_ymin, point1)) angle2 = support_line.angle_between(Line(e2_ymin, point2)) if angle1 > angle2: e2_next = point1 elif angle2 > angle1: e2_next = point2 elif Point.distance(e2_ymin, point1) > Point.distance(e2_ymin, point2): e2_next = point2 else: e2_next = point1 ''' Loop which determines the distance between anti-podal pairs and updates the minimum distance accordingly. It repeats until it reaches the starting position. ''' while True: e1_angle = support_line.angle_between(Line(e1_current, e1_next)) e2_angle = pi - support_line.angle_between(Line( e2_current, e2_next)) if (e1_angle < e2_angle) is True: support_line = Line(e1_current, e1_next) e1_segment = Segment(e1_current, e1_next) min_dist_current = e1_segment.distance(e2_current) if min_dist_current.evalf() < min_dist.evalf(): min_dist = min_dist_current if e1_connections[e1_next][0] != e1_current: e1_current = e1_next e1_next = e1_connections[e1_next][0] else: e1_current = e1_next e1_next = e1_connections[e1_next][1] elif (e1_angle > e2_angle) is True: support_line = Line(e2_next, e2_current) e2_segment = Segment(e2_current, e2_next) min_dist_current = e2_segment.distance(e1_current) if min_dist_current.evalf() < min_dist.evalf(): min_dist = min_dist_current if e2_connections[e2_next][0] != e2_current: e2_current = e2_next e2_next = e2_connections[e2_next][0] else: e2_current = e2_next e2_next = e2_connections[e2_next][1] else: support_line = Line(e1_current, e1_next) e1_segment = Segment(e1_current, e1_next) e2_segment = Segment(e2_current, e2_next) min1 = e1_segment.distance(e2_next) min2 = e2_segment.distance(e1_next) min_dist_current = min(min1, min2) if min_dist_current.evalf() < min_dist.evalf(): min_dist = min_dist_current if e1_connections[e1_next][0] != e1_current: e1_current = e1_next e1_next = e1_connections[e1_next][0] else: e1_current = e1_next e1_next = e1_connections[e1_next][1] if e2_connections[e2_next][0] != e2_current: e2_current = e2_next e2_next = e2_connections[e2_next][0] else: e2_current = e2_next e2_next = e2_connections[e2_next][1] if e1_current == e1_ymax and e2_current == e2_ymin: break return min_dist def _svg(self, scale_factor=1., fill_color="#66cc99"): """Returns SVG path element for the Polygon. Parameters ========== scale_factor : float Multiplication factor for the SVG stroke-width. Default is 1. fill_color : str, optional Hex string for fill color. Default is "#66cc99". """ from sympy.core.evalf import N verts = map(N, self.vertices) coords = ["{0},{1}".format(p.x, p.y) for p in verts] path = "M {0} L {1} z".format(coords[0], " L ".join(coords[1:])) return ( '<path fill-rule="evenodd" fill="{2}" stroke="#555555" ' 'stroke-width="{0}" opacity="0.6" d="{1}" />' ).format(2. * scale_factor, path, fill_color) def _hashable_content(self): D = {} def ref_list(point_list): kee = {} for i, p in enumerate(ordered(set(point_list))): kee[p] = i D[i] = p return [kee[p] for p in point_list] S1 = ref_list(self.args) r_nor = rotate_left(S1, least_rotation(S1)) S2 = ref_list(list(reversed(self.args))) r_rev = rotate_left(S2, least_rotation(S2)) if r_nor < r_rev: r = r_nor else: r = r_rev canonical_args = [ D[order] for order in r ] return tuple(canonical_args) def __contains__(self, o): """ Return True if o is contained within the boundary lines of self.altitudes Parameters ========== other : GeometryEntity Returns ======= contained in : bool The points (and sides, if applicable) are contained in self. See Also ======== sympy.geometry.entity.GeometryEntity.encloses Examples ======== >>> from sympy import Line, Segment, Point >>> p = Point(0, 0) >>> q = Point(1, 1) >>> s = Segment(p, q*2) >>> l = Line(p, q) >>> p in q False >>> p in s True >>> q*3 in s False >>> s in l True """ if isinstance(o, Polygon): return self == o elif isinstance(o, Segment): return any(o in s for s in self.sides) elif isinstance(o, Point): if o in self.vertices: return True for side in self.sides: if o in side: return True return False class RegularPolygon(Polygon): """ A regular polygon. Such a polygon has all internal angles equal and all sides the same length. Parameters ========== center : Point radius : number or Basic instance The distance from the center to a vertex n : int The number of sides Attributes ========== vertices center radius rotation apothem interior_angle exterior_angle circumcircle incircle angles Raises ====== GeometryError If the `center` is not a Point, or the `radius` is not a number or Basic instance, or the number of sides, `n`, is less than three. Notes ===== A RegularPolygon can be instantiated with Polygon with the kwarg n. Regular polygons are instantiated with a center, radius, number of sides and a rotation angle. Whereas the arguments of a Polygon are vertices, the vertices of the RegularPolygon must be obtained with the vertices method. See Also ======== sympy.geometry.point.Point, Polygon Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> r = RegularPolygon(Point(0, 0), 5, 3) >>> r RegularPolygon(Point2D(0, 0), 5, 3, 0) >>> r.vertices[0] Point2D(5, 0) """ __slots__ = ['_n', '_center', '_radius', '_rot'] def __new__(self, c, r, n, rot=0, **kwargs): r, n, rot = map(sympify, (r, n, rot)) c = Point(c, dim=2, **kwargs) if not isinstance(r, Expr): raise GeometryError("r must be an Expr object, not %s" % r) if n.is_Number: as_int(n) # let an error raise if necessary if n < 3: raise GeometryError("n must be a >= 3, not %s" % n) obj = GeometryEntity.__new__(self, c, r, n, **kwargs) obj._n = n obj._center = c obj._radius = r obj._rot = rot % (2*S.Pi/n) if rot.is_number else rot return obj @property def args(self): """ Returns the center point, the radius, the number of sides, and the orientation angle. Examples ======== >>> from sympy import RegularPolygon, Point >>> r = RegularPolygon(Point(0, 0), 5, 3) >>> r.args (Point2D(0, 0), 5, 3, 0) """ return self._center, self._radius, self._n, self._rot def __str__(self): return 'RegularPolygon(%s, %s, %s, %s)' % tuple(self.args) def __repr__(self): return 'RegularPolygon(%s, %s, %s, %s)' % tuple(self.args) @property def area(self): """Returns the area. Examples ======== >>> from sympy.geometry import RegularPolygon >>> square = RegularPolygon((0, 0), 1, 4) >>> square.area 2 >>> _ == square.length**2 True """ c, r, n, rot = self.args return sign(r)*n*self.length**2/(4*tan(pi/n)) @property def length(self): """Returns the length of the sides. The half-length of the side and the apothem form two legs of a right triangle whose hypotenuse is the radius of the regular polygon. Examples ======== >>> from sympy.geometry import RegularPolygon >>> from sympy import sqrt >>> s = square_in_unit_circle = RegularPolygon((0, 0), 1, 4) >>> s.length sqrt(2) >>> sqrt((_/2)**2 + s.apothem**2) == s.radius True """ return self.radius*2*sin(pi/self._n) @property def center(self): """The center of the RegularPolygon This is also the center of the circumscribing circle. Returns ======= center : Point See Also ======== sympy.geometry.point.Point, sympy.geometry.ellipse.Ellipse.center Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 5, 4) >>> rp.center Point2D(0, 0) """ return self._center centroid = center @property def circumcenter(self): """ Alias for center. Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 5, 4) >>> rp.circumcenter Point2D(0, 0) """ return self.center @property def radius(self): """Radius of the RegularPolygon This is also the radius of the circumscribing circle. Returns ======= radius : number or instance of Basic See Also ======== sympy.geometry.line.Segment.length, sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.radius r """ return self._radius @property def circumradius(self): """ Alias for radius. Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.circumradius r """ return self.radius @property def rotation(self): """CCW angle by which the RegularPolygon is rotated Returns ======= rotation : number or instance of Basic Examples ======== >>> from sympy import pi >>> from sympy.abc import a >>> from sympy.geometry import RegularPolygon, Point >>> RegularPolygon(Point(0, 0), 3, 4, pi/4).rotation pi/4 Numerical rotation angles are made canonical: >>> RegularPolygon(Point(0, 0), 3, 4, a).rotation a >>> RegularPolygon(Point(0, 0), 3, 4, pi).rotation 0 """ return self._rot @property def apothem(self): """The inradius of the RegularPolygon. The apothem/inradius is the radius of the inscribed circle. Returns ======= apothem : number or instance of Basic See Also ======== sympy.geometry.line.Segment.length, sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.apothem sqrt(2)*r/2 """ return self.radius * cos(S.Pi/self._n) @property def inradius(self): """ Alias for apothem. Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import RegularPolygon, Point >>> radius = Symbol('r') >>> rp = RegularPolygon(Point(0, 0), radius, 4) >>> rp.inradius sqrt(2)*r/2 """ return self.apothem @property def interior_angle(self): """Measure of the interior angles. Returns ======= interior_angle : number See Also ======== sympy.geometry.line.LinearEntity.angle_between Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 8) >>> rp.interior_angle 3*pi/4 """ return (self._n - 2)*S.Pi/self._n @property def exterior_angle(self): """Measure of the exterior angles. Returns ======= exterior_angle : number See Also ======== sympy.geometry.line.LinearEntity.angle_between Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 8) >>> rp.exterior_angle pi/4 """ return 2*S.Pi/self._n @property def circumcircle(self): """The circumcircle of the RegularPolygon. Returns ======= circumcircle : Circle See Also ======== circumcenter, sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 8) >>> rp.circumcircle Circle(Point2D(0, 0), 4) """ return Circle(self.center, self.radius) @property def incircle(self): """The incircle of the RegularPolygon. Returns ======= incircle : Circle See Also ======== inradius, sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 4, 7) >>> rp.incircle Circle(Point2D(0, 0), 4*cos(pi/7)) """ return Circle(self.center, self.apothem) @property def angles(self): """ Returns a dictionary with keys, the vertices of the Polygon, and values, the interior angle at each vertex. Examples ======== >>> from sympy import RegularPolygon, Point >>> r = RegularPolygon(Point(0, 0), 5, 3) >>> r.angles {Point2D(-5/2, -5*sqrt(3)/2): pi/3, Point2D(-5/2, 5*sqrt(3)/2): pi/3, Point2D(5, 0): pi/3} """ ret = {} ang = self.interior_angle for v in self.vertices: ret[v] = ang return ret def encloses_point(self, p): """ Return True if p is enclosed by (is inside of) self. Notes ===== Being on the border of self is considered False. The general Polygon.encloses_point method is called only if a point is not within or beyond the incircle or circumcircle, respectively. Parameters ========== p : Point Returns ======= encloses_point : True, False or None See Also ======== sympy.geometry.ellipse.Ellipse.encloses_point Examples ======== >>> from sympy import RegularPolygon, S, Point, Symbol >>> p = RegularPolygon((0, 0), 3, 4) >>> p.encloses_point(Point(0, 0)) True >>> r, R = p.inradius, p.circumradius >>> p.encloses_point(Point((r + R)/2, 0)) True >>> p.encloses_point(Point(R/2, R/2 + (R - r)/10)) False >>> t = Symbol('t', real=True) >>> p.encloses_point(p.arbitrary_point().subs(t, S.Half)) False >>> p.encloses_point(Point(5, 5)) False """ c = self.center d = Segment(c, p).length if d >= self.radius: return False elif d < self.inradius: return True else: # now enumerate the RegularPolygon like a general polygon. return Polygon.encloses_point(self, p) def spin(self, angle): """Increment *in place* the virtual Polygon's rotation by ccw angle. See also: rotate method which moves the center. >>> from sympy import Polygon, Point, pi >>> r = Polygon(Point(0,0), 1, n=3) >>> r.vertices[0] Point2D(1, 0) >>> r.spin(pi/6) >>> r.vertices[0] Point2D(sqrt(3)/2, 1/2) See Also ======== rotation rotate : Creates a copy of the RegularPolygon rotated about a Point """ self._rot += angle def rotate(self, angle, pt=None): """Override GeometryEntity.rotate to first rotate the RegularPolygon about its center. >>> from sympy import Point, RegularPolygon, Polygon, pi >>> t = RegularPolygon(Point(1, 0), 1, 3) >>> t.vertices[0] # vertex on x-axis Point2D(2, 0) >>> t.rotate(pi/2).vertices[0] # vertex on y axis now Point2D(0, 2) See Also ======== rotation spin : Rotates a RegularPolygon in place """ r = type(self)(*self.args) # need a copy or else changes are in-place r._rot += angle return GeometryEntity.rotate(r, angle, pt) def scale(self, x=1, y=1, pt=None): """Override GeometryEntity.scale since it is the radius that must be scaled (if x == y) or else a new Polygon must be returned. >>> from sympy import RegularPolygon Symmetric scaling returns a RegularPolygon: >>> RegularPolygon((0, 0), 1, 4).scale(2, 2) RegularPolygon(Point2D(0, 0), 2, 4, 0) Asymmetric scaling returns a kite as a Polygon: >>> RegularPolygon((0, 0), 1, 4).scale(2, 1) Polygon(Point2D(2, 0), Point2D(0, 1), Point2D(-2, 0), Point2D(0, -1)) """ if pt: pt = Point(pt, dim=2) return self.translate(*(-pt).args).scale(x, y).translate(*pt.args) if x != y: return Polygon(*self.vertices).scale(x, y) c, r, n, rot = self.args r *= x return self.func(c, r, n, rot) def reflect(self, line): """Override GeometryEntity.reflect since this is not made of only points. Examples ======== >>> from sympy import RegularPolygon, Line >>> RegularPolygon((0, 0), 1, 4).reflect(Line((0, 1), slope=-2)) RegularPolygon(Point2D(4/5, 2/5), -1, 4, atan(4/3)) """ c, r, n, rot = self.args v = self.vertices[0] d = v - c cc = c.reflect(line) vv = v.reflect(line) dd = vv - cc # calculate rotation about the new center # which will align the vertices l1 = Ray((0, 0), dd) l2 = Ray((0, 0), d) ang = l1.closing_angle(l2) rot += ang # change sign of radius as point traversal is reversed return self.func(cc, -r, n, rot) @property def vertices(self): """The vertices of the RegularPolygon. Returns ======= vertices : list Each vertex is a Point. See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import RegularPolygon, Point >>> rp = RegularPolygon(Point(0, 0), 5, 4) >>> rp.vertices [Point2D(5, 0), Point2D(0, 5), Point2D(-5, 0), Point2D(0, -5)] """ c = self._center r = abs(self._radius) rot = self._rot v = 2*S.Pi/self._n return [Point(c.x + r*cos(k*v + rot), c.y + r*sin(k*v + rot)) for k in range(self._n)] def __eq__(self, o): if not isinstance(o, Polygon): return False elif not isinstance(o, RegularPolygon): return Polygon.__eq__(o, self) return self.args == o.args def __hash__(self): return super(RegularPolygon, self).__hash__() class Triangle(Polygon): """ A polygon with three vertices and three sides. Parameters ========== points : sequence of Points keyword: asa, sas, or sss to specify sides/angles of the triangle Attributes ========== vertices altitudes orthocenter circumcenter circumradius circumcircle inradius incircle exradii medians medial nine_point_circle Raises ====== GeometryError If the number of vertices is not equal to three, or one of the vertices is not a Point, or a valid keyword is not given. See Also ======== sympy.geometry.point.Point, Polygon Examples ======== >>> from sympy.geometry import Triangle, Point >>> Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) Triangle(Point2D(0, 0), Point2D(4, 0), Point2D(4, 3)) Keywords sss, sas, or asa can be used to give the desired side lengths (in order) and interior angles (in degrees) that define the triangle: >>> Triangle(sss=(3, 4, 5)) Triangle(Point2D(0, 0), Point2D(3, 0), Point2D(3, 4)) >>> Triangle(asa=(30, 1, 30)) Triangle(Point2D(0, 0), Point2D(1, 0), Point2D(1/2, sqrt(3)/6)) >>> Triangle(sas=(1, 45, 2)) Triangle(Point2D(0, 0), Point2D(2, 0), Point2D(sqrt(2)/2, sqrt(2)/2)) """ def __new__(cls, *args, **kwargs): if len(args) != 3: if 'sss' in kwargs: return _sss(*[simplify(a) for a in kwargs['sss']]) if 'asa' in kwargs: return _asa(*[simplify(a) for a in kwargs['asa']]) if 'sas' in kwargs: return _sas(*[simplify(a) for a in kwargs['sas']]) msg = "Triangle instantiates with three points or a valid keyword." raise GeometryError(msg) vertices = [Point(a, dim=2, **kwargs) for a in args] # remove consecutive duplicates nodup = [] for p in vertices: if nodup and p == nodup[-1]: continue nodup.append(p) if len(nodup) > 1 and nodup[-1] == nodup[0]: nodup.pop() # last point was same as first # remove collinear points i = -3 while i < len(nodup) - 3 and len(nodup) > 2: a, b, c = sorted( [nodup[i], nodup[i + 1], nodup[i + 2]], key=default_sort_key) if Point.is_collinear(a, b, c): nodup[i] = a nodup[i + 1] = None nodup.pop(i + 1) i += 1 vertices = list(filter(lambda x: x is not None, nodup)) if len(vertices) == 3: return GeometryEntity.__new__(cls, *vertices, **kwargs) elif len(vertices) == 2: return Segment(*vertices, **kwargs) else: return Point(*vertices, **kwargs) @property def vertices(self): """The triangle's vertices Returns ======= vertices : tuple Each element in the tuple is a Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Triangle, Point >>> t = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t.vertices (Point2D(0, 0), Point2D(4, 0), Point2D(4, 3)) """ return self.args def is_similar(t1, t2): """Is another triangle similar to this one. Two triangles are similar if one can be uniformly scaled to the other. Parameters ========== other: Triangle Returns ======= is_similar : boolean See Also ======== sympy.geometry.entity.GeometryEntity.is_similar Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t2 = Triangle(Point(0, 0), Point(-4, 0), Point(-4, -3)) >>> t1.is_similar(t2) True >>> t2 = Triangle(Point(0, 0), Point(-4, 0), Point(-4, -4)) >>> t1.is_similar(t2) False """ if not isinstance(t2, Polygon): return False s1_1, s1_2, s1_3 = [side.length for side in t1.sides] s2 = [side.length for side in t2.sides] def _are_similar(u1, u2, u3, v1, v2, v3): e1 = simplify(u1/v1) e2 = simplify(u2/v2) e3 = simplify(u3/v3) return bool(e1 == e2) and bool(e2 == e3) # There's only 6 permutations, so write them out return _are_similar(s1_1, s1_2, s1_3, *s2) or \ _are_similar(s1_1, s1_3, s1_2, *s2) or \ _are_similar(s1_2, s1_1, s1_3, *s2) or \ _are_similar(s1_2, s1_3, s1_1, *s2) or \ _are_similar(s1_3, s1_1, s1_2, *s2) or \ _are_similar(s1_3, s1_2, s1_1, *s2) def is_equilateral(self): """Are all the sides the same length? Returns ======= is_equilateral : boolean See Also ======== sympy.geometry.entity.GeometryEntity.is_similar, RegularPolygon is_isosceles, is_right, is_scalene Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t1.is_equilateral() False >>> from sympy import sqrt >>> t2 = Triangle(Point(0, 0), Point(10, 0), Point(5, 5*sqrt(3))) >>> t2.is_equilateral() True """ return not has_variety(s.length for s in self.sides) def is_isosceles(self): """Are two or more of the sides the same length? Returns ======= is_isosceles : boolean See Also ======== is_equilateral, is_right, is_scalene Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(2, 4)) >>> t1.is_isosceles() True """ return has_dups(s.length for s in self.sides) def is_scalene(self): """Are all the sides of the triangle of different lengths? Returns ======= is_scalene : boolean See Also ======== is_equilateral, is_isosceles, is_right Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(1, 4)) >>> t1.is_scalene() True """ return not has_dups(s.length for s in self.sides) def is_right(self): """Is the triangle right-angled. Returns ======= is_right : boolean See Also ======== sympy.geometry.line.LinearEntity.is_perpendicular is_equilateral, is_isosceles, is_scalene Examples ======== >>> from sympy.geometry import Triangle, Point >>> t1 = Triangle(Point(0, 0), Point(4, 0), Point(4, 3)) >>> t1.is_right() True """ s = self.sides return Segment.is_perpendicular(s[0], s[1]) or \ Segment.is_perpendicular(s[1], s[2]) or \ Segment.is_perpendicular(s[0], s[2]) @property def altitudes(self): """The altitudes of the triangle. An altitude of a triangle is a segment through a vertex, perpendicular to the opposite side, with length being the height of the vertex measured from the line containing the side. Returns ======= altitudes : dict The dictionary consists of keys which are vertices and values which are Segments. See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment.length Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.altitudes[p1] Segment2D(Point2D(0, 0), Point2D(1/2, 1/2)) """ s = self.sides v = self.vertices return {v[0]: s[1].perpendicular_segment(v[0]), v[1]: s[2].perpendicular_segment(v[1]), v[2]: s[0].perpendicular_segment(v[2])} @property def orthocenter(self): """The orthocenter of the triangle. The orthocenter is the intersection of the altitudes of a triangle. It may lie inside, outside or on the triangle. Returns ======= orthocenter : Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.orthocenter Point2D(0, 0) """ a = self.altitudes v = self.vertices return Line(a[v[0]]).intersection(Line(a[v[1]]))[0] @property def circumcenter(self): """The circumcenter of the triangle The circumcenter is the center of the circumcircle. Returns ======= circumcenter : Point See Also ======== sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.circumcenter Point2D(1/2, 1/2) """ a, b, c = [x.perpendicular_bisector() for x in self.sides] if not a.intersection(b): print(a,b,a.intersection(b)) return a.intersection(b)[0] @property def circumradius(self): """The radius of the circumcircle of the triangle. Returns ======= circumradius : number of Basic instance See Also ======== sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy import Symbol >>> from sympy.geometry import Point, Triangle >>> a = Symbol('a') >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, a) >>> t = Triangle(p1, p2, p3) >>> t.circumradius sqrt(a**2/4 + 1/4) """ return Point.distance(self.circumcenter, self.vertices[0]) @property def circumcircle(self): """The circle which passes through the three vertices of the triangle. Returns ======= circumcircle : Circle See Also ======== sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.circumcircle Circle(Point2D(1/2, 1/2), sqrt(2)/2) """ return Circle(self.circumcenter, self.circumradius) def bisectors(self): """The angle bisectors of the triangle. An angle bisector of a triangle is a straight line through a vertex which cuts the corresponding angle in half. Returns ======= bisectors : dict Each key is a vertex (Point) and each value is the corresponding bisector (Segment). See Also ======== sympy.geometry.point.Point, sympy.geometry.line.Segment Examples ======== >>> from sympy.geometry import Point, Triangle, Segment >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> from sympy import sqrt >>> t.bisectors()[p2] == Segment(Point(1, 0), Point(0, sqrt(2) - 1)) True """ # use lines containing sides so containment check during # intersection calculation can be avoided, thus reducing # the processing time for calculating the bisectors s = [Line(l) for l in self.sides] v = self.vertices c = self.incenter l1 = Segment(v[0], Line(v[0], c).intersection(s[1])[0]) l2 = Segment(v[1], Line(v[1], c).intersection(s[2])[0]) l3 = Segment(v[2], Line(v[2], c).intersection(s[0])[0]) return {v[0]: l1, v[1]: l2, v[2]: l3} @property def incenter(self): """The center of the incircle. The incircle is the circle which lies inside the triangle and touches all three sides. Returns ======= incenter : Point See Also ======== incircle, sympy.geometry.point.Point Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.incenter Point2D(1 - sqrt(2)/2, 1 - sqrt(2)/2) """ s = self.sides l = Matrix([s[i].length for i in [1, 2, 0]]) p = sum(l) v = self.vertices x = simplify(l.dot(Matrix([vi.x for vi in v]))/p) y = simplify(l.dot(Matrix([vi.y for vi in v]))/p) return Point(x, y) @property def inradius(self): """The radius of the incircle. Returns ======= inradius : number of Basic instance See Also ======== incircle, sympy.geometry.ellipse.Circle.radius Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(4, 0), Point(0, 3) >>> t = Triangle(p1, p2, p3) >>> t.inradius 1 """ return simplify(2 * self.area / self.perimeter) @property def incircle(self): """The incircle of the triangle. The incircle is the circle which lies inside the triangle and touches all three sides. Returns ======= incircle : Circle See Also ======== sympy.geometry.ellipse.Circle Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(2, 0), Point(0, 2) >>> t = Triangle(p1, p2, p3) >>> t.incircle Circle(Point2D(2 - sqrt(2), 2 - sqrt(2)), 2 - sqrt(2)) """ return Circle(self.incenter, self.inradius) @property def exradii(self): """The radius of excircles of a triangle. An excircle of the triangle is a circle lying outside the triangle, tangent to one of its sides and tangent to the extensions of the other two. Returns ======= exradii : dict See Also ======== sympy.geometry.polygon.Triangle.inradius Examples ======== The exradius touches the side of the triangle to which it is keyed, e.g. the exradius touching side 2 is: >>> from sympy.geometry import Point, Triangle, Segment2D, Point2D >>> p1, p2, p3 = Point(0, 0), Point(6, 0), Point(0, 2) >>> t = Triangle(p1, p2, p3) >>> t.exradii[t.sides[2]] -2 + sqrt(10) References ========== [1] http://mathworld.wolfram.com/Exradius.html [2] http://mathworld.wolfram.com/Excircles.html """ side = self.sides a = side[0].length b = side[1].length c = side[2].length s = (a+b+c)/2 area = self.area exradii = {self.sides[0]: simplify(area/(s-a)), self.sides[1]: simplify(area/(s-b)), self.sides[2]: simplify(area/(s-c))} return exradii @property def medians(self): """The medians of the triangle. A median of a triangle is a straight line through a vertex and the midpoint of the opposite side, and divides the triangle into two equal areas. Returns ======= medians : dict Each key is a vertex (Point) and each value is the median (Segment) at that point. See Also ======== sympy.geometry.point.Point.midpoint, sympy.geometry.line.Segment.midpoint Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.medians[p1] Segment2D(Point2D(0, 0), Point2D(1/2, 1/2)) """ s = self.sides v = self.vertices return {v[0]: Segment(v[0], s[1].midpoint), v[1]: Segment(v[1], s[2].midpoint), v[2]: Segment(v[2], s[0].midpoint)} @property def medial(self): """The medial triangle of the triangle. The triangle which is formed from the midpoints of the three sides. Returns ======= medial : Triangle See Also ======== sympy.geometry.line.Segment.midpoint Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.medial Triangle(Point2D(1/2, 0), Point2D(1/2, 1/2), Point2D(0, 1/2)) """ s = self.sides return Triangle(s[0].midpoint, s[1].midpoint, s[2].midpoint) @property def nine_point_circle(self): """The nine-point circle of the triangle. Nine-point circle is the circumcircle of the medial triangle, which passes through the feet of altitudes and the middle points of segments connecting the vertices and the orthocenter. Returns ======= nine_point_circle : Circle See also ======== sympy.geometry.line.Segment.midpoint sympy.geometry.polygon.Triangle.medial sympy.geometry.polygon.Triangle.orthocenter Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.nine_point_circle Circle(Point2D(1/4, 1/4), sqrt(2)/4) """ return Circle(*self.medial.vertices) @property def eulerline(self): """The Euler line of the triangle. The line which passes through circumcenter, centroid and orthocenter. Returns ======= eulerline : Line (or Point for equilateral triangles in which case all centers coincide) Examples ======== >>> from sympy.geometry import Point, Triangle >>> p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1) >>> t = Triangle(p1, p2, p3) >>> t.eulerline Line2D(Point2D(0, 0), Point2D(1/2, 1/2)) """ if self.is_equilateral(): return self.orthocenter return Line(self.orthocenter, self.circumcenter) def rad(d): """Return the radian value for the given degrees (pi = 180 degrees).""" return d*pi/180 def deg(r): """Return the degree value for the given radians (pi = 180 degrees).""" return r/pi*180 def _slope(d): rv = tan(rad(d)) return rv def _asa(d1, l, d2): """Return triangle having side with length l on the x-axis.""" xy = Line((0, 0), slope=_slope(d1)).intersection( Line((l, 0), slope=_slope(180 - d2)))[0] return Triangle((0, 0), (l, 0), xy) def _sss(l1, l2, l3): """Return triangle having side of length l1 on the x-axis.""" c1 = Circle((0, 0), l3) c2 = Circle((l1, 0), l2) inter = [a for a in c1.intersection(c2) if a.y.is_nonnegative] if not inter: return None pt = inter[0] return Triangle((0, 0), (l1, 0), pt) def _sas(l1, d, l2): """Return triangle having side with length l2 on the x-axis.""" p1 = Point(0, 0) p2 = Point(l2, 0) p3 = Point(cos(rad(d))*l1, sin(rad(d))*l1) return Triangle(p1, p2, p3)

c99424988fba32cb118bcfe4392c4113b978555a598b898acf45387c94e2c5b6

"""Transform a string with Python-like source code into SymPy expression. """ from __future__ import print_function, division from tokenize import (generate_tokens, untokenize, TokenError, NUMBER, STRING, NAME, OP, ENDMARKER, ERRORTOKEN, NEWLINE) from keyword import iskeyword import ast import unicodedata from sympy.core.compatibility import exec_, StringIO, iterable from sympy.core.basic import Basic from sympy.core import Symbol from sympy.core.function import arity from sympy.utilities.misc import filldedent, func_name def _token_splittable(token): """ Predicate for whether a token name can be split into multiple tokens. A token is splittable if it does not contain an underscore character and it is not the name of a Greek letter. This is used to implicitly convert expressions like 'xyz' into 'x*y*z'. """ if '_' in token: return False else: try: return not unicodedata.lookup('GREEK SMALL LETTER ' + token) except KeyError: pass if len(token) > 1: return True return False def _token_callable(token, local_dict, global_dict, nextToken=None): """ Predicate for whether a token name represents a callable function. Essentially wraps ``callable``, but looks up the token name in the locals and globals. """ func = local_dict.get(token[1]) if not func: func = global_dict.get(token[1]) return callable(func) and not isinstance(func, Symbol) def _add_factorial_tokens(name, result): if result == [] or result[-1][1] == '(': raise TokenError() beginning = [(NAME, name), (OP, '(')] end = [(OP, ')')] diff = 0 length = len(result) for index, token in enumerate(result[::-1]): toknum, tokval = token i = length - index - 1 if tokval == ')': diff += 1 elif tokval == '(': diff -= 1 if diff == 0: if i - 1 >= 0 and result[i - 1][0] == NAME: return result[:i - 1] + beginning + result[i - 1:] + end else: return result[:i] + beginning + result[i:] + end return result class AppliedFunction(object): """ A group of tokens representing a function and its arguments. `exponent` is for handling the shorthand sin^2, ln^2, etc. """ def __init__(self, function, args, exponent=None): if exponent is None: exponent = [] self.function = function self.args = args self.exponent = exponent self.items = ['function', 'args', 'exponent'] def expand(self): """Return a list of tokens representing the function""" result = [] result.append(self.function) result.extend(self.args) return result def __getitem__(self, index): return getattr(self, self.items[index]) def __repr__(self): return "AppliedFunction(%s, %s, %s)" % (self.function, self.args, self.exponent) class ParenthesisGroup(list): """List of tokens representing an expression in parentheses.""" pass def _flatten(result): result2 = [] for tok in result: if isinstance(tok, AppliedFunction): result2.extend(tok.expand()) else: result2.append(tok) return result2 def _group_parentheses(recursor): def _inner(tokens, local_dict, global_dict): """Group tokens between parentheses with ParenthesisGroup. Also processes those tokens recursively. """ result = [] stacks = [] stacklevel = 0 for token in tokens: if token[0] == OP: if token[1] == '(': stacks.append(ParenthesisGroup([])) stacklevel += 1 elif token[1] == ')': stacks[-1].append(token) stack = stacks.pop() if len(stacks) > 0: # We don't recurse here since the upper-level stack # would reprocess these tokens stacks[-1].extend(stack) else: # Recurse here to handle nested parentheses # Strip off the outer parentheses to avoid an infinite loop inner = stack[1:-1] inner = recursor(inner, local_dict, global_dict) parenGroup = [stack[0]] + inner + [stack[-1]] result.append(ParenthesisGroup(parenGroup)) stacklevel -= 1 continue if stacklevel: stacks[-1].append(token) else: result.append(token) if stacklevel: raise TokenError("Mismatched parentheses") return result return _inner def _apply_functions(tokens, local_dict, global_dict): """Convert a NAME token + ParenthesisGroup into an AppliedFunction. Note that ParenthesisGroups, if not applied to any function, are converted back into lists of tokens. """ result = [] symbol = None for tok in tokens: if tok[0] == NAME: symbol = tok result.append(tok) elif isinstance(tok, ParenthesisGroup): if symbol and _token_callable(symbol, local_dict, global_dict): result[-1] = AppliedFunction(symbol, tok) symbol = None else: result.extend(tok) else: symbol = None result.append(tok) return result def _implicit_multiplication(tokens, local_dict, global_dict): """Implicitly adds '*' tokens. Cases: - Two AppliedFunctions next to each other ("sin(x)cos(x)") - AppliedFunction next to an open parenthesis ("sin x (cos x + 1)") - A close parenthesis next to an AppliedFunction ("(x+2)sin x")\ - A close parenthesis next to an open parenthesis ("(x+2)(x+3)") - AppliedFunction next to an implicitly applied function ("sin(x)cos x") """ result = [] for tok, nextTok in zip(tokens, tokens[1:]): result.append(tok) if (isinstance(tok, AppliedFunction) and isinstance(nextTok, AppliedFunction)): result.append((OP, '*')) elif (isinstance(tok, AppliedFunction) and nextTok[0] == OP and nextTok[1] == '('): # Applied function followed by an open parenthesis if tok.function[1] == "Function": result[-1].function = (result[-1].function[0], 'Symbol') result.append((OP, '*')) elif (tok[0] == OP and tok[1] == ')' and isinstance(nextTok, AppliedFunction)): # Close parenthesis followed by an applied function result.append((OP, '*')) elif (tok[0] == OP and tok[1] == ')' and nextTok[0] == NAME): # Close parenthesis followed by an implicitly applied function result.append((OP, '*')) elif (tok[0] == nextTok[0] == OP and tok[1] == ')' and nextTok[1] == '('): # Close parenthesis followed by an open parenthesis result.append((OP, '*')) elif (isinstance(tok, AppliedFunction) and nextTok[0] == NAME): # Applied function followed by implicitly applied function result.append((OP, '*')) elif (tok[0] == NAME and not _token_callable(tok, local_dict, global_dict) and nextTok[0] == OP and nextTok[1] == '('): # Constant followed by parenthesis result.append((OP, '*')) elif (tok[0] == NAME and not _token_callable(tok, local_dict, global_dict) and nextTok[0] == NAME and not _token_callable(nextTok, local_dict, global_dict)): # Constant followed by constant result.append((OP, '*')) elif (tok[0] == NAME and not _token_callable(tok, local_dict, global_dict) and (isinstance(nextTok, AppliedFunction) or nextTok[0] == NAME)): # Constant followed by (implicitly applied) function result.append((OP, '*')) if tokens: result.append(tokens[-1]) return result def _implicit_application(tokens, local_dict, global_dict): """Adds parentheses as needed after functions.""" result = [] appendParen = 0 # number of closing parentheses to add skip = 0 # number of tokens to delay before adding a ')' (to # capture **, ^, etc.) exponentSkip = False # skipping tokens before inserting parentheses to # work with function exponentiation for tok, nextTok in zip(tokens, tokens[1:]): result.append(tok) if (tok[0] == NAME and nextTok[0] not in [OP, ENDMARKER, NEWLINE]): if _token_callable(tok, local_dict, global_dict, nextTok): result.append((OP, '(')) appendParen += 1 # name followed by exponent - function exponentiation elif (tok[0] == NAME and nextTok[0] == OP and nextTok[1] == '**'): if _token_callable(tok, local_dict, global_dict): exponentSkip = True elif exponentSkip: # if the last token added was an applied function (i.e. the # power of the function exponent) OR a multiplication (as # implicit multiplication would have added an extraneous # multiplication) if (isinstance(tok, AppliedFunction) or (tok[0] == OP and tok[1] == '*')): # don't add anything if the next token is a multiplication # or if there's already a parenthesis (if parenthesis, still # stop skipping tokens) if not (nextTok[0] == OP and nextTok[1] == '*'): if not(nextTok[0] == OP and nextTok[1] == '('): result.append((OP, '(')) appendParen += 1 exponentSkip = False elif appendParen: if nextTok[0] == OP and nextTok[1] in ('^', '**', '*'): skip = 1 continue if skip: skip -= 1 continue result.append((OP, ')')) appendParen -= 1 if tokens: result.append(tokens[-1]) if appendParen: result.extend([(OP, ')')] * appendParen) return result def function_exponentiation(tokens, local_dict, global_dict): """Allows functions to be exponentiated, e.g. ``cos**2(x)``. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, function_exponentiation) >>> transformations = standard_transformations + (function_exponentiation,) >>> parse_expr('sin**4(x)', transformations=transformations) sin(x)**4 """ result = [] exponent = [] consuming_exponent = False level = 0 for tok, nextTok in zip(tokens, tokens[1:]): if tok[0] == NAME and nextTok[0] == OP and nextTok[1] == '**': if _token_callable(tok, local_dict, global_dict): consuming_exponent = True elif consuming_exponent: if tok[0] == NAME and tok[1] == 'Function': tok = (NAME, 'Symbol') exponent.append(tok) # only want to stop after hitting ) if tok[0] == nextTok[0] == OP and tok[1] == ')' and nextTok[1] == '(': consuming_exponent = False # if implicit multiplication was used, we may have )*( instead if tok[0] == nextTok[0] == OP and tok[1] == '*' and nextTok[1] == '(': consuming_exponent = False del exponent[-1] continue elif exponent and not consuming_exponent: if tok[0] == OP: if tok[1] == '(': level += 1 elif tok[1] == ')': level -= 1 if level == 0: result.append(tok) result.extend(exponent) exponent = [] continue result.append(tok) if tokens: result.append(tokens[-1]) if exponent: result.extend(exponent) return result def split_symbols_custom(predicate): """Creates a transformation that splits symbol names. ``predicate`` should return True if the symbol name is to be split. For instance, to retain the default behavior but avoid splitting certain symbol names, a predicate like this would work: >>> from sympy.parsing.sympy_parser import (parse_expr, _token_splittable, ... standard_transformations, implicit_multiplication, ... split_symbols_custom) >>> def can_split(symbol): ... if symbol not in ('list', 'of', 'unsplittable', 'names'): ... return _token_splittable(symbol) ... return False ... >>> transformation = split_symbols_custom(can_split) >>> parse_expr('unsplittable', transformations=standard_transformations + ... (transformation, implicit_multiplication)) unsplittable """ def _split_symbols(tokens, local_dict, global_dict): result = [] split = False split_previous=False for tok in tokens: if split_previous: # throw out closing parenthesis of Symbol that was split split_previous=False continue split_previous=False if tok[0] == NAME and tok[1] in ['Symbol', 'Function']: split = True elif split and tok[0] == NAME: symbol = tok[1][1:-1] if predicate(symbol): tok_type = result[-2][1] # Symbol or Function del result[-2:] # Get rid of the call to Symbol i = 0 while i < len(symbol): char = symbol[i] if char in local_dict or char in global_dict: result.extend([(NAME, "%s" % char)]) elif char.isdigit(): char = [char] for i in range(i + 1, len(symbol)): if not symbol[i].isdigit(): i -= 1 break char.append(symbol[i]) char = ''.join(char) result.extend([(NAME, 'Number'), (OP, '('), (NAME, "'%s'" % char), (OP, ')')]) else: use = tok_type if i == len(symbol) else 'Symbol' result.extend([(NAME, use), (OP, '('), (NAME, "'%s'" % char), (OP, ')')]) i += 1 # Set split_previous=True so will skip # the closing parenthesis of the original Symbol split = False split_previous = True continue else: split = False result.append(tok) return result return _split_symbols #: Splits symbol names for implicit multiplication. #: #: Intended to let expressions like ``xyz`` be parsed as ``x*y*z``. Does not #: split Greek character names, so ``theta`` will *not* become #: ``t*h*e*t*a``. Generally this should be used with #: ``implicit_multiplication``. split_symbols = split_symbols_custom(_token_splittable) def implicit_multiplication(result, local_dict, global_dict): """Makes the multiplication operator optional in most cases. Use this before :func:`implicit_application`, otherwise expressions like ``sin 2x`` will be parsed as ``x * sin(2)`` rather than ``sin(2*x)``. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, implicit_multiplication) >>> transformations = standard_transformations + (implicit_multiplication,) >>> parse_expr('3 x y', transformations=transformations) 3*x*y """ # These are interdependent steps, so we don't expose them separately for step in (_group_parentheses(implicit_multiplication), _apply_functions, _implicit_multiplication): result = step(result, local_dict, global_dict) result = _flatten(result) return result def implicit_application(result, local_dict, global_dict): """Makes parentheses optional in some cases for function calls. Use this after :func:`implicit_multiplication`, otherwise expressions like ``sin 2x`` will be parsed as ``x * sin(2)`` rather than ``sin(2*x)``. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, implicit_application) >>> transformations = standard_transformations + (implicit_application,) >>> parse_expr('cot z + csc z', transformations=transformations) cot(z) + csc(z) """ for step in (_group_parentheses(implicit_application), _apply_functions, _implicit_application,): result = step(result, local_dict, global_dict) result = _flatten(result) return result def implicit_multiplication_application(result, local_dict, global_dict): """Allows a slightly relaxed syntax. - Parentheses for single-argument method calls are optional. - Multiplication is implicit. - Symbol names can be split (i.e. spaces are not needed between symbols). - Functions can be exponentiated. Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, implicit_multiplication_application) >>> parse_expr("10sin**2 x**2 + 3xyz + tan theta", ... transformations=(standard_transformations + ... (implicit_multiplication_application,))) 3*x*y*z + 10*sin(x**2)**2 + tan(theta) """ for step in (split_symbols, implicit_multiplication, implicit_application, function_exponentiation): result = step(result, local_dict, global_dict) return result def auto_symbol(tokens, local_dict, global_dict): """Inserts calls to ``Symbol``/``Function`` for undefined variables.""" result = [] prevTok = (None, None) tokens.append((None, None)) # so zip traverses all tokens for tok, nextTok in zip(tokens, tokens[1:]): tokNum, tokVal = tok nextTokNum, nextTokVal = nextTok if tokNum == NAME: name = tokVal if (name in ['True', 'False', 'None'] or iskeyword(name) # Don't convert attribute access or (prevTok[0] == OP and prevTok[1] == '.') # Don't convert keyword arguments or (prevTok[0] == OP and prevTok[1] in ('(', ',') and nextTokNum == OP and nextTokVal == '=')): result.append((NAME, name)) continue elif name in local_dict: if isinstance(local_dict[name], Symbol) and nextTokVal == '(': result.extend([(NAME, 'Function'), (OP, '('), (NAME, repr(str(local_dict[name]))), (OP, ')')]) else: result.append((NAME, name)) continue elif name in global_dict: obj = global_dict[name] if isinstance(obj, (Basic, type)) or callable(obj): result.append((NAME, name)) continue result.extend([ (NAME, 'Symbol' if nextTokVal != '(' else 'Function'), (OP, '('), (NAME, repr(str(name))), (OP, ')'), ]) else: result.append((tokNum, tokVal)) prevTok = (tokNum, tokVal) return result def lambda_notation(tokens, local_dict, global_dict): """Substitutes "lambda" with its Sympy equivalent Lambda(). However, the conversion doesn't take place if only "lambda" is passed because that is a syntax error. """ result = [] flag = False toknum, tokval = tokens[0] tokLen = len(tokens) if toknum == NAME and tokval == 'lambda': if tokLen == 2 or tokLen == 3 and tokens[1][0] == NEWLINE: # In Python 3.6.7+, inputs without a newline get NEWLINE added to # the tokens result.extend(tokens) elif tokLen > 2: result.extend([ (NAME, 'Lambda'), (OP, '('), (OP, '('), (OP, ')'), (OP, ')'), ]) for tokNum, tokVal in tokens[1:]: if tokNum == OP and tokVal == ':': tokVal = ',' flag = True if not flag and tokNum == OP and tokVal in ['*', '**']: raise TokenError("Starred arguments in lambda not supported") if flag: result.insert(-1, (tokNum, tokVal)) else: result.insert(-2, (tokNum, tokVal)) else: result.extend(tokens) return result def factorial_notation(tokens, local_dict, global_dict): """Allows standard notation for factorial.""" result = [] nfactorial = 0 for toknum, tokval in tokens: if toknum == ERRORTOKEN: op = tokval if op == '!': nfactorial += 1 else: nfactorial = 0 result.append((OP, op)) else: if nfactorial == 1: result = _add_factorial_tokens('factorial', result) elif nfactorial == 2: result = _add_factorial_tokens('factorial2', result) elif nfactorial > 2: raise TokenError nfactorial = 0 result.append((toknum, tokval)) return result def convert_xor(tokens, local_dict, global_dict): """Treats XOR, ``^``, as exponentiation, ``**``.""" result = [] for toknum, tokval in tokens: if toknum == OP: if tokval == '^': result.append((OP, '**')) else: result.append((toknum, tokval)) else: result.append((toknum, tokval)) return result def repeated_decimals(tokens, local_dict, global_dict): """ Allows 0.2[1] notation to represent the repeated decimal 0.2111... (19/90) Run this before auto_number. """ result = [] def is_digit(s): return all(i in '0123456789_' for i in s) # num will running match any DECIMAL [ INTEGER ] num = [] for toknum, tokval in tokens: if toknum == NUMBER: if (not num and '.' in tokval and 'e' not in tokval.lower() and 'j' not in tokval.lower()): num.append((toknum, tokval)) elif is_digit(tokval)and len(num) == 2: num.append((toknum, tokval)) elif is_digit(tokval) and len(num) == 3 and is_digit(num[-1][1]): # Python 2 tokenizes 00123 as '00', '123' # Python 3 tokenizes 01289 as '012', '89' num.append((toknum, tokval)) else: num = [] elif toknum == OP: if tokval == '[' and len(num) == 1: num.append((OP, tokval)) elif tokval == ']' and len(num) >= 3: num.append((OP, tokval)) elif tokval == '.' and not num: # handle .[1] num.append((NUMBER, '0.')) else: num = [] else: num = [] result.append((toknum, tokval)) if num and num[-1][1] == ']': # pre.post[repetend] = a + b/c + d/e where a = pre, b/c = post, # and d/e = repetend result = result[:-len(num)] pre, post = num[0][1].split('.') repetend = num[2][1] if len(num) == 5: repetend += num[3][1] pre = pre.replace('_', '') post = post.replace('_', '') repetend = repetend.replace('_', '') zeros = '0'*len(post) post, repetends = [w.lstrip('0') for w in [post, repetend]] # or else interpreted as octal a = pre or '0' b, c = post or '0', '1' + zeros d, e = repetends, ('9'*len(repetend)) + zeros seq = [ (OP, '('), (NAME, 'Integer'), (OP, '('), (NUMBER, a), (OP, ')'), (OP, '+'), (NAME, 'Rational'), (OP, '('), (NUMBER, b), (OP, ','), (NUMBER, c), (OP, ')'), (OP, '+'), (NAME, 'Rational'), (OP, '('), (NUMBER, d), (OP, ','), (NUMBER, e), (OP, ')'), (OP, ')'), ] result.extend(seq) num = [] return result def auto_number(tokens, local_dict, global_dict): """ Converts numeric literals to use SymPy equivalents. Complex numbers use ``I``, integer literals use ``Integer``, and float literals use ``Float``. """ result = [] for toknum, tokval in tokens: if toknum == NUMBER: number = tokval postfix = [] if number.endswith('j') or number.endswith('J'): number = number[:-1] postfix = [(OP, '*'), (NAME, 'I')] if '.' in number or (('e' in number or 'E' in number) and not (number.startswith('0x') or number.startswith('0X'))): seq = [(NAME, 'Float'), (OP, '('), (NUMBER, repr(str(number))), (OP, ')')] else: seq = [(NAME, 'Integer'), (OP, '('), ( NUMBER, number), (OP, ')')] result.extend(seq + postfix) else: result.append((toknum, tokval)) return result def rationalize(tokens, local_dict, global_dict): """Converts floats into ``Rational``. Run AFTER ``auto_number``.""" result = [] passed_float = False for toknum, tokval in tokens: if toknum == NAME: if tokval == 'Float': passed_float = True tokval = 'Rational' result.append((toknum, tokval)) elif passed_float == True and toknum == NUMBER: passed_float = False result.append((STRING, tokval)) else: result.append((toknum, tokval)) return result def _transform_equals_sign(tokens, local_dict, global_dict): """Transforms the equals sign ``=`` to instances of Eq. This is a helper function for `convert_equals_signs`. Works with expressions containing one equals sign and no nesting. Expressions like `(1=2)=False` won't work with this and should be used with `convert_equals_signs`. Examples: 1=2 to Eq(1,2) 1*2=x to Eq(1*2, x) This does not deal with function arguments yet. """ result = [] if (OP, "=") in tokens: result.append((NAME, "Eq")) result.append((OP, "(")) for index, token in enumerate(tokens): if token == (OP, "="): result.append((OP, ",")) continue result.append(token) result.append((OP, ")")) else: result = tokens return result def convert_equals_signs(result, local_dict, global_dict): """ Transforms all the equals signs ``=`` to instances of Eq. Parses the equals signs in the expression and replaces them with appropriate Eq instances.Also works with nested equals signs. Does not yet play well with function arguments. For example, the expression `(x=y)` is ambiguous and can be interpreted as x being an argument to a function and `convert_equals_signs` won't work for this. See also ======== convert_equality_operators Examples ======== >>> from sympy.parsing.sympy_parser import (parse_expr, ... standard_transformations, convert_equals_signs) >>> parse_expr("1*2=x", transformations=( ... standard_transformations + (convert_equals_signs,))) Eq(2, x) >>> parse_expr("(1*2=x)=False", transformations=( ... standard_transformations + (convert_equals_signs,))) Eq(Eq(2, x), False) """ for step in (_group_parentheses(convert_equals_signs), _apply_functions, _transform_equals_sign): result = step(result, local_dict, global_dict) result = _flatten(result) return result #: Standard transformations for :func:`parse_expr`. #: Inserts calls to :class:`Symbol`, :class:`Integer`, and other SymPy #: datatypes and allows the use of standard factorial notation (e.g. ``x!``). standard_transformations = (lambda_notation, auto_symbol, repeated_decimals, auto_number, factorial_notation) def stringify_expr(s, local_dict, global_dict, transformations): """ Converts the string ``s`` to Python code, in ``local_dict`` Generally, ``parse_expr`` should be used. """ tokens = [] input_code = StringIO(s.strip()) for toknum, tokval, _, _, _ in generate_tokens(input_code.readline): tokens.append((toknum, tokval)) for transform in transformations: tokens = transform(tokens, local_dict, global_dict) return untokenize(tokens) def eval_expr(code, local_dict, global_dict): """ Evaluate Python code generated by ``stringify_expr``. Generally, ``parse_expr`` should be used. """ expr = eval( code, global_dict, local_dict) # take local objects in preference return expr def parse_expr(s, local_dict=None, transformations=standard_transformations, global_dict=None, evaluate=True): """Converts the string ``s`` to a SymPy expression, in ``local_dict`` Parameters ========== s : str The string to parse. local_dict : dict, optional A dictionary of local variables to use when parsing. global_dict : dict, optional A dictionary of global variables. By default, this is initialized with ``from sympy import *``; provide this parameter to override this behavior (for instance, to parse ``"Q & S"``). transformations : tuple, optional A tuple of transformation functions used to modify the tokens of the parsed expression before evaluation. The default transformations convert numeric literals into their SymPy equivalents, convert undefined variables into SymPy symbols, and allow the use of standard mathematical factorial notation (e.g. ``x!``). evaluate : bool, optional When False, the order of the arguments will remain as they were in the string and automatic simplification that would normally occur is suppressed. (see examples) Examples ======== >>> from sympy.parsing.sympy_parser import parse_expr >>> parse_expr("1/2") 1/2 >>> type(_) <class 'sympy.core.numbers.Half'> >>> from sympy.parsing.sympy_parser import standard_transformations,\\ ... implicit_multiplication_application >>> transformations = (standard_transformations + ... (implicit_multiplication_application,)) >>> parse_expr("2x", transformations=transformations) 2*x When evaluate=False, some automatic simplifications will not occur: >>> parse_expr("2**3"), parse_expr("2**3", evaluate=False) (8, 2**3) In addition the order of the arguments will not be made canonical. This feature allows one to tell exactly how the expression was entered: >>> a = parse_expr('1 + x', evaluate=False) >>> b = parse_expr('x + 1', evaluate=0) >>> a == b False >>> a.args (1, x) >>> b.args (x, 1) See Also ======== stringify_expr, eval_expr, standard_transformations, implicit_multiplication_application """ if local_dict is None: local_dict = {} elif not isinstance(local_dict, dict): raise TypeError('expecting local_dict to be a dict') if global_dict is None: global_dict = {} exec_('from sympy import *', global_dict) elif not isinstance(global_dict, dict): raise TypeError('expecting global_dict to be a dict') transformations = transformations or () if transformations: if not iterable(transformations): raise TypeError( '`transformations` should be a list of functions.') for _ in transformations: if not callable(_): raise TypeError(filldedent(''' expected a function in `transformations`, not %s''' % func_name(_))) if arity(_) != 3: raise TypeError(filldedent(''' a transformation should be function that takes 3 arguments''')) code = stringify_expr(s, local_dict, global_dict, transformations) if not evaluate: code = compile(evaluateFalse(code), '<string>', 'eval') return eval_expr(code, local_dict, global_dict) def evaluateFalse(s): """ Replaces operators with the SymPy equivalent and sets evaluate=False. """ node = ast.parse(s) node = EvaluateFalseTransformer().visit(node) # node is a Module, we want an Expression node = ast.Expression(node.body[0].value) return ast.fix_missing_locations(node) class EvaluateFalseTransformer(ast.NodeTransformer): operators = { ast.Add: 'Add', ast.Mult: 'Mul', ast.Pow: 'Pow', ast.Sub: 'Add', ast.Div: 'Mul', ast.BitOr: 'Or', ast.BitAnd: 'And', ast.BitXor: 'Not', } def flatten(self, args, func): result = [] for arg in args: if isinstance(arg, ast.Call) and arg.func.id == func: result.extend(self.flatten(arg.args, func)) else: result.append(arg) return result def visit_BinOp(self, node): if node.op.__class__ in self.operators: sympy_class = self.operators[node.op.__class__] right = self.visit(node.right) left = self.visit(node.left) if isinstance(node.left, ast.UnaryOp) and (isinstance(node.right, ast.UnaryOp) == 0) and sympy_class in ('Mul',): left, right = right, left if isinstance(node.op, ast.Sub): right = ast.Call( func=ast.Name(id='Mul', ctx=ast.Load()), args=[ast.UnaryOp(op=ast.USub(), operand=ast.Num(1)), right], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) if isinstance(node.op, ast.Div): if isinstance(node.left, ast.UnaryOp): if isinstance(node.right,ast.UnaryOp): left, right = right, left left = ast.Call( func=ast.Name(id='Pow', ctx=ast.Load()), args=[left, ast.UnaryOp(op=ast.USub(), operand=ast.Num(1))], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) else: right = ast.Call( func=ast.Name(id='Pow', ctx=ast.Load()), args=[right, ast.UnaryOp(op=ast.USub(), operand=ast.Num(1))], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) new_node = ast.Call( func=ast.Name(id=sympy_class, ctx=ast.Load()), args=[left, right], keywords=[ast.keyword(arg='evaluate', value=ast.Name(id='False', ctx=ast.Load()))], starargs=None, kwargs=None ) if sympy_class in ('Add', 'Mul'): # Denest Add or Mul as appropriate new_node.args = self.flatten(new_node.args, sympy_class) return new_node return node

f774726144584e5c84d33d2262d34fe1d3924b84b7c906edc31bca6ac6a62107

r"""Module that defines indexed objects The classes ``IndexedBase``, ``Indexed``, and ``Idx`` represent a matrix element ``M[i, j]`` as in the following diagram:: 1) The Indexed class represents the entire indexed object. | ___|___ ' ' M[i, j] / \__\______ | | | | | 2) The Idx class represents indices; each Idx can | optionally contain information about its range. | 3) IndexedBase represents the 'stem' of an indexed object, here `M`. The stem used by itself is usually taken to represent the entire array. There can be any number of indices on an Indexed object. No transformation properties are implemented in these Base objects, but implicit contraction of repeated indices is supported. Note that the support for complicated (i.e. non-atomic) integer expressions as indices is limited. (This should be improved in future releases.) Examples ======== To express the above matrix element example you would write: >>> from sympy import symbols, IndexedBase, Idx >>> M = IndexedBase('M') >>> i, j = symbols('i j', cls=Idx) >>> M[i, j] M[i, j] Repeated indices in a product implies a summation, so to express a matrix-vector product in terms of Indexed objects: >>> x = IndexedBase('x') >>> M[i, j]*x[j] M[i, j]*x[j] If the indexed objects will be converted to component based arrays, e.g. with the code printers or the autowrap framework, you also need to provide (symbolic or numerical) dimensions. This can be done by passing an optional shape parameter to IndexedBase upon construction: >>> dim1, dim2 = symbols('dim1 dim2', integer=True) >>> A = IndexedBase('A', shape=(dim1, 2*dim1, dim2)) >>> A.shape (dim1, 2*dim1, dim2) >>> A[i, j, 3].shape (dim1, 2*dim1, dim2) If an IndexedBase object has no shape information, it is assumed that the array is as large as the ranges of its indices: >>> n, m = symbols('n m', integer=True) >>> i = Idx('i', m) >>> j = Idx('j', n) >>> M[i, j].shape (m, n) >>> M[i, j].ranges [(0, m - 1), (0, n - 1)] The above can be compared with the following: >>> A[i, 2, j].shape (dim1, 2*dim1, dim2) >>> A[i, 2, j].ranges [(0, m - 1), None, (0, n - 1)] To analyze the structure of indexed expressions, you can use the methods get_indices() and get_contraction_structure(): >>> from sympy.tensor import get_indices, get_contraction_structure >>> get_indices(A[i, j, j]) ({i}, {}) >>> get_contraction_structure(A[i, j, j]) {(j,): {A[i, j, j]}} See the appropriate docstrings for a detailed explanation of the output. """ # TODO: (some ideas for improvement) # # o test and guarantee numpy compatibility # - implement full support for broadcasting # - strided arrays # # o more functions to analyze indexed expressions # - identify standard constructs, e.g matrix-vector product in a subexpression # # o functions to generate component based arrays (numpy and sympy.Matrix) # - generate a single array directly from Indexed # - convert simple sub-expressions # # o sophisticated indexing (possibly in subclasses to preserve simplicity) # - Idx with range smaller than dimension of Indexed # - Idx with stepsize != 1 # - Idx with step determined by function call from __future__ import print_function, division from sympy.core import Expr, Tuple, Symbol, sympify, S from sympy.core.compatibility import (is_sequence, string_types, NotIterable, Iterable) from sympy.core.sympify import _sympify from sympy.functions.special.tensor_functions import KroneckerDelta class IndexException(Exception): pass class Indexed(Expr): """Represents a mathematical object with indices. >>> from sympy import Indexed, IndexedBase, Idx, symbols >>> i, j = symbols('i j', cls=Idx) >>> Indexed('A', i, j) A[i, j] It is recommended that ``Indexed`` objects be created via ``IndexedBase``: >>> A = IndexedBase('A') >>> Indexed('A', i, j) == A[i, j] True """ is_commutative = True is_Indexed = True is_symbol = True is_Atom = True def __new__(cls, base, *args, **kw_args): from sympy.utilities.misc import filldedent from sympy.tensor.array.ndim_array import NDimArray from sympy.matrices.matrices import MatrixBase if not args: raise IndexException("Indexed needs at least one index.") if isinstance(base, (string_types, Symbol)): base = IndexedBase(base) elif not hasattr(base, '__getitem__') and not isinstance(base, IndexedBase): raise TypeError(filldedent(""" Indexed expects string, Symbol, or IndexedBase as base.""")) args = list(map(sympify, args)) if isinstance(base, (NDimArray, Iterable, Tuple, MatrixBase)) and all([i.is_number for i in args]): if len(args) == 1: return base[args[0]] else: return base[args] return Expr.__new__(cls, base, *args, **kw_args) @property def name(self): return str(self) @property def _diff_wrt(self): """Allow derivatives with respect to an ``Indexed`` object.""" return True def _eval_derivative(self, wrt): from sympy.tensor.array.ndim_array import NDimArray if isinstance(wrt, Indexed) and wrt.base == self.base: if len(self.indices) != len(wrt.indices): msg = "Different # of indices: d({!s})/d({!s})".format(self, wrt) raise IndexException(msg) result = S.One for index1, index2 in zip(self.indices, wrt.indices): result *= KroneckerDelta(index1, index2) return result elif isinstance(self.base, NDimArray): from sympy.tensor.array import derive_by_array return Indexed(derive_by_array(self.base, wrt), *self.args[1:]) else: if Tuple(self.indices).has(wrt): return S.NaN return S.Zero @property def base(self): """Returns the ``IndexedBase`` of the ``Indexed`` object. Examples ======== >>> from sympy import Indexed, IndexedBase, Idx, symbols >>> i, j = symbols('i j', cls=Idx) >>> Indexed('A', i, j).base A >>> B = IndexedBase('B') >>> B == B[i, j].base True """ return self.args[0] @property def indices(self): """ Returns the indices of the ``Indexed`` object. Examples ======== >>> from sympy import Indexed, Idx, symbols >>> i, j = symbols('i j', cls=Idx) >>> Indexed('A', i, j).indices (i, j) """ return self.args[1:] @property def rank(self): """ Returns the rank of the ``Indexed`` object. Examples ======== >>> from sympy import Indexed, Idx, symbols >>> i, j, k, l, m = symbols('i:m', cls=Idx) >>> Indexed('A', i, j).rank 2 >>> q = Indexed('A', i, j, k, l, m) >>> q.rank 5 >>> q.rank == len(q.indices) True """ return len(self.args) - 1 @property def shape(self): """Returns a list with dimensions of each index. Dimensions is a property of the array, not of the indices. Still, if the ``IndexedBase`` does not define a shape attribute, it is assumed that the ranges of the indices correspond to the shape of the array. >>> from sympy import IndexedBase, Idx, symbols >>> n, m = symbols('n m', integer=True) >>> i = Idx('i', m) >>> j = Idx('j', m) >>> A = IndexedBase('A', shape=(n, n)) >>> B = IndexedBase('B') >>> A[i, j].shape (n, n) >>> B[i, j].shape (m, m) """ from sympy.utilities.misc import filldedent if self.base.shape: return self.base.shape sizes = [] for i in self.indices: upper = getattr(i, 'upper', None) lower = getattr(i, 'lower', None) if None in (upper, lower): raise IndexException(filldedent(""" Range is not defined for all indices in: %s""" % self)) try: size = upper - lower + 1 except TypeError: raise IndexException(filldedent(""" Shape cannot be inferred from Idx with undefined range: %s""" % self)) sizes.append(size) return Tuple(*sizes) @property def ranges(self): """Returns a list of tuples with lower and upper range of each index. If an index does not define the data members upper and lower, the corresponding slot in the list contains ``None`` instead of a tuple. Examples ======== >>> from sympy import Indexed,Idx, symbols >>> Indexed('A', Idx('i', 2), Idx('j', 4), Idx('k', 8)).ranges [(0, 1), (0, 3), (0, 7)] >>> Indexed('A', Idx('i', 3), Idx('j', 3), Idx('k', 3)).ranges [(0, 2), (0, 2), (0, 2)] >>> x, y, z = symbols('x y z', integer=True) >>> Indexed('A', x, y, z).ranges [None, None, None] """ ranges = [] for i in self.indices: sentinel = object() upper = getattr(i, 'upper', sentinel) lower = getattr(i, 'lower', sentinel) if sentinel not in (upper, lower): ranges.append(Tuple(lower, upper)) else: ranges.append(None) return ranges def _sympystr(self, p): indices = list(map(p.doprint, self.indices)) return "%s[%s]" % (p.doprint(self.base), ", ".join(indices)) @property def free_symbols(self): base_free_symbols = self.base.free_symbols indices_free_symbols = { fs for i in self.indices for fs in i.free_symbols} if base_free_symbols: return {self} | base_free_symbols | indices_free_symbols else: return indices_free_symbols @property def expr_free_symbols(self): return {self} class IndexedBase(Expr, NotIterable): """Represent the base or stem of an indexed object The IndexedBase class represent an array that contains elements. The main purpose of this class is to allow the convenient creation of objects of the Indexed class. The __getitem__ method of IndexedBase returns an instance of Indexed. Alone, without indices, the IndexedBase class can be used as a notation for e.g. matrix equations, resembling what you could do with the Symbol class. But, the IndexedBase class adds functionality that is not available for Symbol instances: - An IndexedBase object can optionally store shape information. This can be used in to check array conformance and conditions for numpy broadcasting. (TODO) - An IndexedBase object implements syntactic sugar that allows easy symbolic representation of array operations, using implicit summation of repeated indices. - The IndexedBase object symbolizes a mathematical structure equivalent to arrays, and is recognized as such for code generation and automatic compilation and wrapping. >>> from sympy.tensor import IndexedBase, Idx >>> from sympy import symbols >>> A = IndexedBase('A'); A A >>> type(A) <class 'sympy.tensor.indexed.IndexedBase'> When an IndexedBase object receives indices, it returns an array with named axes, represented by an Indexed object: >>> i, j = symbols('i j', integer=True) >>> A[i, j, 2] A[i, j, 2] >>> type(A[i, j, 2]) <class 'sympy.tensor.indexed.Indexed'> The IndexedBase constructor takes an optional shape argument. If given, it overrides any shape information in the indices. (But not the index ranges!) >>> m, n, o, p = symbols('m n o p', integer=True) >>> i = Idx('i', m) >>> j = Idx('j', n) >>> A[i, j].shape (m, n) >>> B = IndexedBase('B', shape=(o, p)) >>> B[i, j].shape (o, p) """ is_commutative = True is_symbol = True is_Atom = True def __new__(cls, label, shape=None, **kw_args): from sympy import MatrixBase, NDimArray if isinstance(label, string_types): label = Symbol(label) elif isinstance(label, Symbol): pass elif isinstance(label, (MatrixBase, NDimArray)): return label elif isinstance(label, Iterable): return _sympify(label) else: label = _sympify(label) if is_sequence(shape): shape = Tuple(*shape) elif shape is not None: shape = Tuple(shape) offset = kw_args.pop('offset', S.Zero) strides = kw_args.pop('strides', None) if shape is not None: obj = Expr.__new__(cls, label, shape) else: obj = Expr.__new__(cls, label) obj._shape = shape obj._offset = offset obj._strides = strides obj._name = str(label) return obj @property def name(self): return self._name def __getitem__(self, indices, **kw_args): if is_sequence(indices): # Special case needed because M[*my_tuple] is a syntax error. if self.shape and len(self.shape) != len(indices): raise IndexException("Rank mismatch.") return Indexed(self, *indices, **kw_args) else: if self.shape and len(self.shape) != 1: raise IndexException("Rank mismatch.") return Indexed(self, indices, **kw_args) @property def shape(self): """Returns the shape of the ``IndexedBase`` object. Examples ======== >>> from sympy import IndexedBase, Idx, Symbol >>> from sympy.abc import x, y >>> IndexedBase('A', shape=(x, y)).shape (x, y) Note: If the shape of the ``IndexedBase`` is specified, it will override any shape information given by the indices. >>> A = IndexedBase('A', shape=(x, y)) >>> B = IndexedBase('B') >>> i = Idx('i', 2) >>> j = Idx('j', 1) >>> A[i, j].shape (x, y) >>> B[i, j].shape (2, 1) """ return self._shape @property def strides(self): """Returns the strided scheme for the ``IndexedBase`` object. Normally this is a tuple denoting the number of steps to take in the respective dimension when traversing an array. For code generation purposes strides='C' and strides='F' can also be used. strides='C' would mean that code printer would unroll in row-major order and 'F' means unroll in column major order. """ return self._strides @property def offset(self): """Returns the offset for the ``IndexedBase`` object. This is the value added to the resulting index when the 2D Indexed object is unrolled to a 1D form. Used in code generation. Examples ========== >>> from sympy.printing import ccode >>> from sympy.tensor import IndexedBase, Idx >>> from sympy import symbols >>> l, m, n, o = symbols('l m n o', integer=True) >>> A = IndexedBase('A', strides=(l, m, n), offset=o) >>> i, j, k = map(Idx, 'ijk') >>> ccode(A[i, j, k]) 'A[l*i + m*j + n*k + o]' """ return self._offset @property def label(self): """Returns the label of the ``IndexedBase`` object. Examples ======== >>> from sympy import IndexedBase >>> from sympy.abc import x, y >>> IndexedBase('A', shape=(x, y)).label A """ return self.args[0] def _sympystr(self, p): return p.doprint(self.label) class Idx(Expr): """Represents an integer index as an ``Integer`` or integer expression. There are a number of ways to create an ``Idx`` object. The constructor takes two arguments: ``label`` An integer or a symbol that labels the index. ``range`` Optionally you can specify a range as either * ``Symbol`` or integer: This is interpreted as a dimension. Lower and upper bounds are set to ``0`` and ``range - 1``, respectively. * ``tuple``: The two elements are interpreted as the lower and upper bounds of the range, respectively. Note: bounds of the range are assumed to be either integer or infinite (oo and -oo are allowed to specify an unbounded range). If ``n`` is given as a bound, then ``n.is_integer`` must not return false. For convenience, if the label is given as a string it is automatically converted to an integer symbol. (Note: this conversion is not done for range or dimension arguments.) Examples ======== >>> from sympy import IndexedBase, Idx, symbols, oo >>> n, i, L, U = symbols('n i L U', integer=True) If a string is given for the label an integer ``Symbol`` is created and the bounds are both ``None``: >>> idx = Idx('qwerty'); idx qwerty >>> idx.lower, idx.upper (None, None) Both upper and lower bounds can be specified: >>> idx = Idx(i, (L, U)); idx i >>> idx.lower, idx.upper (L, U) When only a single bound is given it is interpreted as the dimension and the lower bound defaults to 0: >>> idx = Idx(i, n); idx.lower, idx.upper (0, n - 1) >>> idx = Idx(i, 4); idx.lower, idx.upper (0, 3) >>> idx = Idx(i, oo); idx.lower, idx.upper (0, oo) """ is_integer = True is_finite = True is_real = True is_symbol = True is_Atom = True _diff_wrt = True def __new__(cls, label, range=None, **kw_args): from sympy.utilities.misc import filldedent if isinstance(label, string_types): label = Symbol(label, integer=True) label, range = list(map(sympify, (label, range))) if label.is_Number: if not label.is_integer: raise TypeError("Index is not an integer number.") return label if not label.is_integer: raise TypeError("Idx object requires an integer label.") elif is_sequence(range): if len(range) != 2: raise ValueError(filldedent(""" Idx range tuple must have length 2, but got %s""" % len(range))) for bound in range: if (bound.is_integer is False and bound is not S.Infinity and bound is not S.NegativeInfinity): raise TypeError("Idx object requires integer bounds.") args = label, Tuple(*range) elif isinstance(range, Expr): if not (range.is_integer or range is S.Infinity): raise TypeError("Idx object requires an integer dimension.") args = label, Tuple(0, range - 1) elif range: raise TypeError(filldedent(""" The range must be an ordered iterable or integer SymPy expression.""")) else: args = label, obj = Expr.__new__(cls, *args, **kw_args) obj._assumptions["finite"] = True obj._assumptions["real"] = True return obj @property def label(self): """Returns the label (Integer or integer expression) of the Idx object. Examples ======== >>> from sympy import Idx, Symbol >>> x = Symbol('x', integer=True) >>> Idx(x).label x >>> j = Symbol('j', integer=True) >>> Idx(j).label j >>> Idx(j + 1).label j + 1 """ return self.args[0] @property def lower(self): """Returns the lower bound of the ``Idx``. Examples ======== >>> from sympy import Idx >>> Idx('j', 2).lower 0 >>> Idx('j', 5).lower 0 >>> Idx('j').lower is None True """ try: return self.args[1][0] except IndexError: return @property def upper(self): """Returns the upper bound of the ``Idx``. Examples ======== >>> from sympy import Idx >>> Idx('j', 2).upper 1 >>> Idx('j', 5).upper 4 >>> Idx('j').upper is None True """ try: return self.args[1][1] except IndexError: return def _sympystr(self, p): return p.doprint(self.label) @property def name(self): return self.label.name if self.label.is_Symbol else str(self.label) @property def free_symbols(self): return {self} def __le__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.upper is not None and (self.upper <= other_lower) == True: return True if self.lower is not None and (self.lower > other_upper) == True: return False return super(Idx, self).__le__(other) def __ge__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.lower is not None and (self.lower >= other_upper) == True: return True if self.upper is not None and (self.upper < other_lower) == True: return False return super(Idx, self).__ge__(other) def __lt__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.upper is not None and (self.upper < other_lower) == True: return True if self.lower is not None and (self.lower >= other_upper) == True: return False return super(Idx, self).__lt__(other) def __gt__(self, other): if isinstance(other, Idx): other_upper = other if other.upper is None else other.upper other_lower = other if other.lower is None else other.lower else: other_upper = other other_lower = other if self.lower is not None and (self.lower > other_upper) == True: return True if self.upper is not None and (self.upper <= other_lower) == True: return False return super(Idx, self).__gt__(other)

26ad2a5d12a59f6ffa9f9d0f43fadbfc9f721e05bc8003f619b806de203657ae

""" Boolean algebra module for SymPy """ from __future__ import print_function, division from collections import defaultdict from itertools import combinations, product from sympy.core.add import Add from sympy.core.basic import Basic from sympy.core.cache import cacheit from sympy.core.compatibility import (ordered, range, with_metaclass, as_int) from sympy.core.function import Application, Derivative, count_ops from sympy.core.numbers import Number from sympy.core.operations import LatticeOp from sympy.core.singleton import Singleton, S from sympy.core.sympify import converter, _sympify, sympify from sympy.utilities.iterables import sift, ibin from sympy.utilities.misc import filldedent def as_Boolean(e): """Like bool, return the Boolean value of an expression, e, which can be any instance of Boolean or bool. Examples ======== >>> from sympy import true, false, nan >>> from sympy.logic.boolalg import as_Boolean >>> from sympy.abc import x >>> as_Boolean(1) is true True >>> as_Boolean(x) x >>> as_Boolean(2) Traceback (most recent call last): ... TypeError: expecting bool or Boolean, not `2`. """ from sympy.core.symbol import Symbol if e == True: return S.true if e == False: return S.false if isinstance(e, Symbol): z = e.is_zero if z is None: return e return S.false if z else S.true if isinstance(e, Boolean): return e raise TypeError('expecting bool or Boolean, not `%s`.' % e) class Boolean(Basic): """A boolean object is an object for which logic operations make sense.""" __slots__ = [] def __and__(self, other): """Overloading for & operator""" return And(self, other) __rand__ = __and__ def __or__(self, other): """Overloading for |""" return Or(self, other) __ror__ = __or__ def __invert__(self): """Overloading for ~""" return Not(self) def __rshift__(self, other): """Overloading for >>""" return Implies(self, other) def __lshift__(self, other): """Overloading for <<""" return Implies(other, self) __rrshift__ = __lshift__ __rlshift__ = __rshift__ def __xor__(self, other): return Xor(self, other) __rxor__ = __xor__ def equals(self, other): """ Returns True if the given formulas have the same truth table. For two formulas to be equal they must have the same literals. Examples ======== >>> from sympy.abc import A, B, C >>> from sympy.logic.boolalg import And, Or, Not >>> (A >> B).equals(~B >> ~A) True >>> Not(And(A, B, C)).equals(And(Not(A), Not(B), Not(C))) False >>> Not(And(A, Not(A))).equals(Or(B, Not(B))) False """ from sympy.logic.inference import satisfiable from sympy.core.relational import Relational if self.has(Relational) or other.has(Relational): raise NotImplementedError('handling of relationals') return self.atoms() == other.atoms() and \ not satisfiable(Not(Equivalent(self, other))) def to_nnf(self, simplify=True): # override where necessary return self def as_set(self): """ Rewrites Boolean expression in terms of real sets. Examples ======== >>> from sympy import Symbol, Eq, Or, And >>> x = Symbol('x', real=True) >>> Eq(x, 0).as_set() {0} >>> (x > 0).as_set() Interval.open(0, oo) >>> And(-2 < x, x < 2).as_set() Interval.open(-2, 2) >>> Or(x < -2, 2 < x).as_set() Union(Interval.open(-oo, -2), Interval.open(2, oo)) """ from sympy.calculus.util import periodicity from sympy.core.relational import Relational free = self.free_symbols if len(free) == 1: x = free.pop() reps = {} for r in self.atoms(Relational): if periodicity(r, x) not in (0, None): s = r._eval_as_set() if s in (S.EmptySet, S.UniversalSet, S.Reals): reps[r] = s.as_relational(x) continue raise NotImplementedError(filldedent(''' as_set is not implemented for relationals with periodic solutions ''')) return self.subs(reps)._eval_as_set() else: raise NotImplementedError("Sorry, as_set has not yet been" " implemented for multivariate" " expressions") @property def binary_symbols(self): from sympy.core.relational import Eq, Ne return set().union(*[i.binary_symbols for i in self.args if i.is_Boolean or i.is_Symbol or isinstance(i, (Eq, Ne))]) class BooleanAtom(Boolean): """ Base class of BooleanTrue and BooleanFalse. """ is_Boolean = True is_Atom = True _op_priority = 11 # higher than Expr def simplify(self, *a, **kw): return self def expand(self, *a, **kw): return self @property def canonical(self): return self def _noop(self, other=None): raise TypeError('BooleanAtom not allowed in this context.') __add__ = _noop __radd__ = _noop __sub__ = _noop __rsub__ = _noop __mul__ = _noop __rmul__ = _noop __pow__ = _noop __rpow__ = _noop __rdiv__ = _noop __truediv__ = _noop __div__ = _noop __rtruediv__ = _noop __mod__ = _noop __rmod__ = _noop _eval_power = _noop # /// drop when Py2 is no longer supported def __lt__(self, other): from sympy.utilities.misc import filldedent raise TypeError(filldedent(''' A Boolean argument can only be used in Eq and Ne; all other relationals expect real expressions. ''')) __le__ = __lt__ __gt__ = __lt__ __ge__ = __lt__ # \\\ class BooleanTrue(with_metaclass(Singleton, BooleanAtom)): """ SymPy version of True, a singleton that can be accessed via S.true. This is the SymPy version of True, for use in the logic module. The primary advantage of using true instead of True is that shorthand boolean operations like ~ and >> will work as expected on this class, whereas with True they act bitwise on 1. Functions in the logic module will return this class when they evaluate to true. Notes ===== There is liable to be some confusion as to when ``True`` should be used and when ``S.true`` should be used in various contexts throughout SymPy. An important thing to remember is that ``sympify(True)`` returns ``S.true``. This means that for the most part, you can just use ``True`` and it will automatically be converted to ``S.true`` when necessary, similar to how you can generally use 1 instead of ``S.One``. The rule of thumb is: "If the boolean in question can be replaced by an arbitrary symbolic ``Boolean``, like ``Or(x, y)`` or ``x > 1``, use ``S.true``. Otherwise, use ``True``" In other words, use ``S.true`` only on those contexts where the boolean is being used as a symbolic representation of truth. For example, if the object ends up in the ``.args`` of any expression, then it must necessarily be ``S.true`` instead of ``True``, as elements of ``.args`` must be ``Basic``. On the other hand, ``==`` is not a symbolic operation in SymPy, since it always returns ``True`` or ``False``, and does so in terms of structural equality rather than mathematical, so it should return ``True``. The assumptions system should use ``True`` and ``False``. Aside from not satisfying the above rule of thumb, the assumptions system uses a three-valued logic (``True``, ``False``, ``None``), whereas ``S.true`` and ``S.false`` represent a two-valued logic. When in doubt, use ``True``. "``S.true == True is True``." While "``S.true is True``" is ``False``, "``S.true == True``" is ``True``, so if there is any doubt over whether a function or expression will return ``S.true`` or ``True``, just use ``==`` instead of ``is`` to do the comparison, and it will work in either case. Finally, for boolean flags, it's better to just use ``if x`` instead of ``if x is True``. To quote PEP 8: Don't compare boolean values to ``True`` or ``False`` using ``==``. * Yes: ``if greeting:`` * No: ``if greeting == True:`` * Worse: ``if greeting is True:`` Examples ======== >>> from sympy import sympify, true, false, Or >>> sympify(True) True >>> _ is True, _ is true (False, True) >>> Or(true, false) True >>> _ is true True Python operators give a boolean result for true but a bitwise result for True >>> ~true, ~True (False, -2) >>> true >> true, True >> True (True, 0) Python operators give a boolean result for true but a bitwise result for True >>> ~true, ~True (False, -2) >>> true >> true, True >> True (True, 0) See Also ======== sympy.logic.boolalg.BooleanFalse """ def __nonzero__(self): return True __bool__ = __nonzero__ def __hash__(self): return hash(True) @property def negated(self): return S.false def as_set(self): """ Rewrite logic operators and relationals in terms of real sets. Examples ======== >>> from sympy import true >>> true.as_set() UniversalSet """ return S.UniversalSet class BooleanFalse(with_metaclass(Singleton, BooleanAtom)): """ SymPy version of False, a singleton that can be accessed via S.false. This is the SymPy version of False, for use in the logic module. The primary advantage of using false instead of False is that shorthand boolean operations like ~ and >> will work as expected on this class, whereas with False they act bitwise on 0. Functions in the logic module will return this class when they evaluate to false. Notes ====== See note in :py:class`sympy.logic.boolalg.BooleanTrue` Examples ======== >>> from sympy import sympify, true, false, Or >>> sympify(False) False >>> _ is False, _ is false (False, True) >>> Or(true, false) True >>> _ is true True Python operators give a boolean result for false but a bitwise result for False >>> ~false, ~False (True, -1) >>> false >> false, False >> False (True, 0) See Also ======== sympy.logic.boolalg.BooleanTrue """ def __nonzero__(self): return False __bool__ = __nonzero__ def __hash__(self): return hash(False) @property def negated(self): return S.true def as_set(self): """ Rewrite logic operators and relationals in terms of real sets. Examples ======== >>> from sympy import false >>> false.as_set() EmptySet() """ return S.EmptySet true = BooleanTrue() false = BooleanFalse() # We want S.true and S.false to work, rather than S.BooleanTrue and # S.BooleanFalse, but making the class and instance names the same causes some # major issues (like the inability to import the class directly from this # file). S.true = true S.false = false converter[bool] = lambda x: S.true if x else S.false class BooleanFunction(Application, Boolean): """Boolean function is a function that lives in a boolean space It is used as base class for And, Or, Not, etc. """ is_Boolean = True def _eval_simplify(self, ratio, measure, rational, inverse): rv = self.func(*[a._eval_simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse) for a in self.args]) return simplify_logic(rv) def simplify(self, ratio=1.7, measure=count_ops, rational=False, inverse=False): return self._eval_simplify(ratio, measure, rational, inverse) # /// drop when Py2 is no longer supported def __lt__(self, other): from sympy.utilities.misc import filldedent raise TypeError(filldedent(''' A Boolean argument can only be used in Eq and Ne; all other relationals expect real expressions. ''')) __le__ = __lt__ __ge__ = __lt__ __gt__ = __lt__ # \\\ @classmethod def binary_check_and_simplify(self, *args): from sympy.core.relational import Relational, Eq, Ne args = [as_Boolean(i) for i in args] bin = set().union(*[i.binary_symbols for i in args]) rel = set().union(*[i.atoms(Relational) for i in args]) reps = {} for x in bin: for r in rel: if x in bin and x in r.free_symbols: if isinstance(r, (Eq, Ne)): if not ( S.true in r.args or S.false in r.args): reps[r] = S.false else: raise TypeError(filldedent(''' Incompatible use of binary symbol `%s` as a real variable in `%s` ''' % (x, r))) return [i.subs(reps) for i in args] def to_nnf(self, simplify=True): return self._to_nnf(*self.args, simplify=simplify) @classmethod def _to_nnf(cls, *args, **kwargs): simplify = kwargs.get('simplify', True) argset = set([]) for arg in args: if not is_literal(arg): arg = arg.to_nnf(simplify) if simplify: if isinstance(arg, cls): arg = arg.args else: arg = (arg,) for a in arg: if Not(a) in argset: return cls.zero argset.add(a) else: argset.add(arg) return cls(*argset) # the diff method below is copied from Expr class def diff(self, *symbols, **assumptions): assumptions.setdefault("evaluate", True) return Derivative(self, *symbols, **assumptions) def _eval_derivative(self, x): from sympy.core.relational import Eq from sympy.functions.elementary.piecewise import Piecewise if x in self.binary_symbols: return Piecewise( (0, Eq(self.subs(x, 0), self.subs(x, 1))), (1, True)) elif x in self.free_symbols: # not implemented, see https://www.encyclopediaofmath.org/ # index.php/Boolean_differential_calculus pass else: return S.Zero def _apply_patternbased_simplification(self, rv, patterns, measure, dominatingvalue, replacementvalue=None): """ Replace patterns of Relational Parameters ========== rv : Expr Boolean expression patterns : tuple Tuple of tuples, with (pattern to simplify, simplified pattern) measure : function Simplification measure dominatingvalue : boolean or None The dominating value for the function of consideration. For example, for And S.false is dominating. As soon as one expression is S.false in And, the whole expression is S.false. replacementvalue : boolean or None, optional The resulting value for the whole expression if one argument evaluates to dominatingvalue. For example, for Nand S.false is dominating, but in this case the resulting value is S.true. Default is None. If replacementvalue is None and dominatingvalue is not None, replacementvalue = dominatingvalue """ from sympy.core.relational import Relational, _canonical if replacementvalue is None and dominatingvalue is not None: replacementvalue = dominatingvalue # Use replacement patterns for Relationals changed = True Rel, nonRel = sift(rv.args, lambda i: isinstance(i, Relational), binary=True) if len(Rel) <= 1: return rv Rel, nonRealRel = sift(rv.args, lambda i: all(s.is_real is not False for s in i.free_symbols), binary=True) Rel = [i.canonical for i in Rel] while changed and len(Rel) >= 2: changed = False # Sort based on ordered Rel = list(ordered(Rel)) # Create a list of possible replacements results = [] # Try all combinations for ((i, pi), (j, pj)) in combinations(enumerate(Rel), 2): for k, (pattern, simp) in enumerate(patterns): res = [] # use SymPy matching oldexpr = rv.func(pi, pj) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) # Try reversing first relational # This and the rest should not be required with a better # canonical oldexpr = rv.func(pi.reversed, pj) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) # Try reversing second relational oldexpr = rv.func(pi, pj.reversed) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) # Try reversing both relationals oldexpr = rv.func(pi.reversed, pj.reversed) tmpres = oldexpr.match(pattern) if tmpres: res.append((tmpres, oldexpr)) if res: for tmpres, oldexpr in res: # we have a matching, compute replacement np = simp.subs(tmpres) if np == dominatingvalue: # if dominatingvalue, the whole expression # will be replacementvalue return replacementvalue # add replacement if not isinstance(np, ITE): # We only want to use ITE replacements if # they simplify to a relational costsaving = measure(oldexpr) - measure(np) if costsaving > 0: results.append((costsaving, (i, j, np))) if results: # Sort results based on complexity results = list(reversed(sorted(results, key=lambda pair: pair[0]))) # Replace the one providing most simplification cost, replacement = results[0] i, j, newrel = replacement # Remove the old relationals del Rel[j] del Rel[i] if dominatingvalue is None or newrel != ~dominatingvalue: # Insert the new one (no need to insert a value that will # not affect the result) Rel.append(newrel) # We did change something so try again changed = True rv = rv.func(*([_canonical(i) for i in ordered(Rel)] + nonRel + nonRealRel)) return rv class And(LatticeOp, BooleanFunction): """ Logical AND function. It evaluates its arguments in order, giving False immediately if any of them are False, and True if they are all True. Examples ======== >>> from sympy.core import symbols >>> from sympy.abc import x, y >>> from sympy.logic.boolalg import And >>> x & y x & y Notes ===== The ``&`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise and. Hence, ``And(a, b)`` and ``a & b`` will return different things if ``a`` and ``b`` are integers. >>> And(x, y).subs(x, 1) y """ zero = false identity = true nargs = None @classmethod def _new_args_filter(cls, args): newargs = [] rel = [] args = BooleanFunction.binary_check_and_simplify(*args) for x in reversed(args): if x.is_Relational: c = x.canonical if c in rel: continue nc = c.negated.canonical if any(r == nc for r in rel): return [S.false] rel.append(c) newargs.append(x) return LatticeOp._new_args_filter(newargs, And) def _eval_simplify(self, ratio, measure, rational, inverse): from sympy.core.relational import Equality, Relational from sympy.solvers.solveset import linear_coeffs # standard simplify rv = super(And, self)._eval_simplify( ratio, measure, rational, inverse) if not isinstance(rv, And): return rv # simplify args that are equalities involving # symbols so x == 0 & x == y -> x==0 & y == 0 Rel, nonRel = sift(rv.args, lambda i: isinstance(i, Relational), binary=True) if not Rel: return rv eqs, other = sift(Rel, lambda i: isinstance(i, Equality), binary=True) if not eqs: return rv reps = {} sifted = {} if eqs: # group by length of free symbols sifted = sift(ordered([ (i.free_symbols, i) for i in eqs]), lambda x: len(x[0])) eqs = [] while 1 in sifted: for free, e in sifted.pop(1): x = free.pop() if e.lhs != x or x in e.rhs.free_symbols: try: m, b = linear_coeffs( e.rewrite(Add, evaluate=False), x) enew = e.func(x, -b/m) if measure(enew) <= ratio*measure(e): e = enew else: eqs.append(e) continue except ValueError: pass if x in reps: eqs.append(e.func(e.rhs, reps[x])) else: reps[x] = e.rhs eqs.append(e) resifted = defaultdict(list) for k in sifted: for f, e in sifted[k]: e = e.subs(reps) f = e.free_symbols resifted[len(f)].append((f, e)) sifted = resifted for k in sifted: eqs.extend([e for f, e in sifted[k]]) other = [ei.subs(reps) for ei in other] rv = rv.func(*([i.canonical for i in (eqs + other)] + nonRel)) patterns = simplify_patterns_and() return self._apply_patternbased_simplification(rv, patterns, measure, False) def _eval_as_set(self): from sympy.sets.sets import Intersection return Intersection(*[arg.as_set() for arg in self.args]) class Or(LatticeOp, BooleanFunction): """ Logical OR function It evaluates its arguments in order, giving True immediately if any of them are True, and False if they are all False. Examples ======== >>> from sympy.core import symbols >>> from sympy.abc import x, y >>> from sympy.logic.boolalg import Or >>> x | y x | y Notes ===== The ``|`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise or. Hence, ``Or(a, b)`` and ``a | b`` will return different things if ``a`` and ``b`` are integers. >>> Or(x, y).subs(x, 0) y """ zero = true identity = false @classmethod def _new_args_filter(cls, args): newargs = [] rel = [] args = BooleanFunction.binary_check_and_simplify(*args) for x in args: if x.is_Relational: c = x.canonical if c in rel: continue nc = c.negated.canonical if any(r == nc for r in rel): return [S.true] rel.append(c) newargs.append(x) return LatticeOp._new_args_filter(newargs, Or) def _eval_as_set(self): from sympy.sets.sets import Union return Union(*[arg.as_set() for arg in self.args]) def _eval_simplify(self, ratio, measure, rational, inverse): # standard simplify rv = super(Or, self)._eval_simplify( ratio, measure, rational, inverse) if not isinstance(rv, Or): return rv patterns = simplify_patterns_or() return self._apply_patternbased_simplification(rv, patterns, measure, S.true) class Not(BooleanFunction): """ Logical Not function (negation) Returns True if the statement is False Returns False if the statement is True Examples ======== >>> from sympy.logic.boolalg import Not, And, Or >>> from sympy.abc import x, A, B >>> Not(True) False >>> Not(False) True >>> Not(And(True, False)) True >>> Not(Or(True, False)) False >>> Not(And(And(True, x), Or(x, False))) ~x >>> ~x ~x >>> Not(And(Or(A, B), Or(~A, ~B))) ~((A | B) & (~A | ~B)) Notes ===== - The ``~`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise not. In particular, ``~a`` and ``Not(a)`` will be different if ``a`` is an integer. Furthermore, since bools in Python subclass from ``int``, ``~True`` is the same as ``~1`` which is ``-2``, which has a boolean value of True. To avoid this issue, use the SymPy boolean types ``true`` and ``false``. >>> from sympy import true >>> ~True -2 >>> ~true False """ is_Not = True @classmethod def eval(cls, arg): from sympy import ( Equality, GreaterThan, LessThan, StrictGreaterThan, StrictLessThan, Unequality) if isinstance(arg, Number) or arg in (True, False): return false if arg else true if arg.is_Not: return arg.args[0] # Simplify Relational objects. if isinstance(arg, Equality): return Unequality(*arg.args) if isinstance(arg, Unequality): return Equality(*arg.args) if isinstance(arg, StrictLessThan): return GreaterThan(*arg.args) if isinstance(arg, StrictGreaterThan): return LessThan(*arg.args) if isinstance(arg, LessThan): return StrictGreaterThan(*arg.args) if isinstance(arg, GreaterThan): return StrictLessThan(*arg.args) def _eval_as_set(self): """ Rewrite logic operators and relationals in terms of real sets. Examples ======== >>> from sympy import Not, Symbol >>> x = Symbol('x') >>> Not(x > 0).as_set() Interval(-oo, 0) """ return self.args[0].as_set().complement(S.Reals) def to_nnf(self, simplify=True): if is_literal(self): return self expr = self.args[0] func, args = expr.func, expr.args if func == And: return Or._to_nnf(*[~arg for arg in args], simplify=simplify) if func == Or: return And._to_nnf(*[~arg for arg in args], simplify=simplify) if func == Implies: a, b = args return And._to_nnf(a, ~b, simplify=simplify) if func == Equivalent: return And._to_nnf(Or(*args), Or(*[~arg for arg in args]), simplify=simplify) if func == Xor: result = [] for i in range(1, len(args)+1, 2): for neg in combinations(args, i): clause = [~s if s in neg else s for s in args] result.append(Or(*clause)) return And._to_nnf(*result, simplify=simplify) if func == ITE: a, b, c = args return And._to_nnf(Or(a, ~c), Or(~a, ~b), simplify=simplify) raise ValueError("Illegal operator %s in expression" % func) class Xor(BooleanFunction): """ Logical XOR (exclusive OR) function. Returns True if an odd number of the arguments are True and the rest are False. Returns False if an even number of the arguments are True and the rest are False. Examples ======== >>> from sympy.logic.boolalg import Xor >>> from sympy import symbols >>> x, y = symbols('x y') >>> Xor(True, False) True >>> Xor(True, True) False >>> Xor(True, False, True, True, False) True >>> Xor(True, False, True, False) False >>> x ^ y Xor(x, y) Notes ===== The ``^`` operator is provided as a convenience, but note that its use here is different from its normal use in Python, which is bitwise xor. In particular, ``a ^ b`` and ``Xor(a, b)`` will be different if ``a`` and ``b`` are integers. >>> Xor(x, y).subs(y, 0) x """ def __new__(cls, *args, **kwargs): argset = set([]) obj = super(Xor, cls).__new__(cls, *args, **kwargs) for arg in obj._args: if isinstance(arg, Number) or arg in (True, False): if arg: arg = true else: continue if isinstance(arg, Xor): for a in arg.args: argset.remove(a) if a in argset else argset.add(a) elif arg in argset: argset.remove(arg) else: argset.add(arg) rel = [(r, r.canonical, r.negated.canonical) for r in argset if r.is_Relational] odd = False # is number of complimentary pairs odd? start 0 -> False remove = [] for i, (r, c, nc) in enumerate(rel): for j in range(i + 1, len(rel)): rj, cj = rel[j][:2] if cj == nc: odd = ~odd break elif cj == c: break else: continue remove.append((r, rj)) if odd: argset.remove(true) if true in argset else argset.add(true) for a, b in remove: argset.remove(a) argset.remove(b) if len(argset) == 0: return false elif len(argset) == 1: return argset.pop() elif True in argset: argset.remove(True) return Not(Xor(*argset)) else: obj._args = tuple(ordered(argset)) obj._argset = frozenset(argset) return obj @property @cacheit def args(self): return tuple(ordered(self._argset)) def to_nnf(self, simplify=True): args = [] for i in range(0, len(self.args)+1, 2): for neg in combinations(self.args, i): clause = [~s if s in neg else s for s in self.args] args.append(Or(*clause)) return And._to_nnf(*args, simplify=simplify) def _eval_simplify(self, ratio, measure, rational, inverse): # as standard simplify uses simplify_logic which writes things as # And and Or, we only simplify the partial expressions before using # patterns rv = self.func(*[a._eval_simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse) for a in self.args]) if not isinstance(rv, Xor): # This shouldn't really happen here return rv patterns = simplify_patterns_xor() return self._apply_patternbased_simplification(rv, patterns, measure, None) class Nand(BooleanFunction): """ Logical NAND function. It evaluates its arguments in order, giving True immediately if any of them are False, and False if they are all True. Returns True if any of the arguments are False Returns False if all arguments are True Examples ======== >>> from sympy.logic.boolalg import Nand >>> from sympy import symbols >>> x, y = symbols('x y') >>> Nand(False, True) True >>> Nand(True, True) False >>> Nand(x, y) ~(x & y) """ @classmethod def eval(cls, *args): return Not(And(*args)) class Nor(BooleanFunction): """ Logical NOR function. It evaluates its arguments in order, giving False immediately if any of them are True, and True if they are all False. Returns False if any argument is True Returns True if all arguments are False Examples ======== >>> from sympy.logic.boolalg import Nor >>> from sympy import symbols >>> x, y = symbols('x y') >>> Nor(True, False) False >>> Nor(True, True) False >>> Nor(False, True) False >>> Nor(False, False) True >>> Nor(x, y) ~(x | y) """ @classmethod def eval(cls, *args): return Not(Or(*args)) class Xnor(BooleanFunction): """ Logical XNOR function. Returns False if an odd number of the arguments are True and the rest are False. Returns True if an even number of the arguments are True and the rest are False. Examples ======== >>> from sympy.logic.boolalg import Xnor >>> from sympy import symbols >>> x, y = symbols('x y') >>> Xnor(True, False) False >>> Xnor(True, True) True >>> Xnor(True, False, True, True, False) False >>> Xnor(True, False, True, False) True """ @classmethod def eval(cls, *args): return Not(Xor(*args)) class Implies(BooleanFunction): """ Logical implication. A implies B is equivalent to !A v B Accepts two Boolean arguments; A and B. Returns False if A is True and B is False Returns True otherwise. Examples ======== >>> from sympy.logic.boolalg import Implies >>> from sympy import symbols >>> x, y = symbols('x y') >>> Implies(True, False) False >>> Implies(False, False) True >>> Implies(True, True) True >>> Implies(False, True) True >>> x >> y Implies(x, y) >>> y << x Implies(x, y) Notes ===== The ``>>`` and ``<<`` operators are provided as a convenience, but note that their use here is different from their normal use in Python, which is bit shifts. Hence, ``Implies(a, b)`` and ``a >> b`` will return different things if ``a`` and ``b`` are integers. In particular, since Python considers ``True`` and ``False`` to be integers, ``True >> True`` will be the same as ``1 >> 1``, i.e., 0, which has a truth value of False. To avoid this issue, use the SymPy objects ``true`` and ``false``. >>> from sympy import true, false >>> True >> False 1 >>> true >> false False """ @classmethod def eval(cls, *args): try: newargs = [] for x in args: if isinstance(x, Number) or x in (0, 1): newargs.append(True if x else False) else: newargs.append(x) A, B = newargs except ValueError: raise ValueError( "%d operand(s) used for an Implies " "(pairs are required): %s" % (len(args), str(args))) if A == True or A == False or B == True or B == False: return Or(Not(A), B) elif A == B: return S.true elif A.is_Relational and B.is_Relational: if A.canonical == B.canonical: return S.true if A.negated.canonical == B.canonical: return B else: return Basic.__new__(cls, *args) def to_nnf(self, simplify=True): a, b = self.args return Or._to_nnf(~a, b, simplify=simplify) class Equivalent(BooleanFunction): """ Equivalence relation. Equivalent(A, B) is True iff A and B are both True or both False Returns True if all of the arguments are logically equivalent. Returns False otherwise. Examples ======== >>> from sympy.logic.boolalg import Equivalent, And >>> from sympy.abc import x, y >>> Equivalent(False, False, False) True >>> Equivalent(True, False, False) False >>> Equivalent(x, And(x, True)) True """ def __new__(cls, *args, **options): from sympy.core.relational import Relational args = [_sympify(arg) for arg in args] argset = set(args) for x in args: if isinstance(x, Number) or x in [True, False]: # Includes 0, 1 argset.discard(x) argset.add(True if x else False) rel = [] for r in argset: if isinstance(r, Relational): rel.append((r, r.canonical, r.negated.canonical)) remove = [] for i, (r, c, nc) in enumerate(rel): for j in range(i + 1, len(rel)): rj, cj = rel[j][:2] if cj == nc: return false elif cj == c: remove.append((r, rj)) break for a, b in remove: argset.remove(a) argset.remove(b) argset.add(True) if len(argset) <= 1: return true if True in argset: argset.discard(True) return And(*argset) if False in argset: argset.discard(False) return And(*[~arg for arg in argset]) _args = frozenset(argset) obj = super(Equivalent, cls).__new__(cls, _args) obj._argset = _args return obj @property @cacheit def args(self): return tuple(ordered(self._argset)) def to_nnf(self, simplify=True): args = [] for a, b in zip(self.args, self.args[1:]): args.append(Or(~a, b)) args.append(Or(~self.args[-1], self.args[0])) return And._to_nnf(*args, simplify=simplify) class ITE(BooleanFunction): """ If then else clause. ITE(A, B, C) evaluates and returns the result of B if A is true else it returns the result of C. All args must be Booleans. Examples ======== >>> from sympy.logic.boolalg import ITE, And, Xor, Or >>> from sympy.abc import x, y, z >>> ITE(True, False, True) False >>> ITE(Or(True, False), And(True, True), Xor(True, True)) True >>> ITE(x, y, z) ITE(x, y, z) >>> ITE(True, x, y) x >>> ITE(False, x, y) y >>> ITE(x, y, y) y Trying to use non-Boolean args will generate a TypeError: >>> ITE(True, [], ()) Traceback (most recent call last): ... TypeError: expecting bool, Boolean or ITE, not `[]` """ def __new__(cls, *args, **kwargs): from sympy.core.relational import Eq, Ne if len(args) != 3: raise ValueError('expecting exactly 3 args') a, b, c = args # check use of binary symbols if isinstance(a, (Eq, Ne)): # in this context, we can evaluate the Eq/Ne # if one arg is a binary symbol and the other # is true/false b, c = map(as_Boolean, (b, c)) bin = set().union(*[i.binary_symbols for i in (b, c)]) if len(set(a.args) - bin) == 1: # one arg is a binary_symbols _a = a if a.lhs is S.true: a = a.rhs elif a.rhs is S.true: a = a.lhs elif a.lhs is S.false: a = ~a.rhs elif a.rhs is S.false: a = ~a.lhs else: # binary can only equal True or False a = S.false if isinstance(_a, Ne): a = ~a else: a, b, c = BooleanFunction.binary_check_and_simplify( a, b, c) rv = None if kwargs.get('evaluate', True): rv = cls.eval(a, b, c) if rv is None: rv = BooleanFunction.__new__(cls, a, b, c, evaluate=False) return rv @classmethod def eval(cls, *args): from sympy.core.relational import Eq, Ne # do the args give a singular result? a, b, c = args if isinstance(a, (Ne, Eq)): _a = a if S.true in a.args: a = a.lhs if a.rhs is S.true else a.rhs elif S.false in a.args: a = ~a.lhs if a.rhs is S.false else ~a.rhs else: _a = None if _a is not None and isinstance(_a, Ne): a = ~a if a is S.true: return b if a is S.false: return c if b == c: return b else: # or maybe the results allow the answer to be expressed # in terms of the condition if b is S.true and c is S.false: return a if b is S.false and c is S.true: return Not(a) if [a, b, c] != args: return cls(a, b, c, evaluate=False) def to_nnf(self, simplify=True): a, b, c = self.args return And._to_nnf(Or(~a, b), Or(a, c), simplify=simplify) def _eval_as_set(self): return self.to_nnf().as_set() def _eval_rewrite_as_Piecewise(self, *args, **kwargs): from sympy.functions import Piecewise return Piecewise((args[1], args[0]), (args[2], True)) # end class definitions. Some useful methods def conjuncts(expr): """Return a list of the conjuncts in the expr s. Examples ======== >>> from sympy.logic.boolalg import conjuncts >>> from sympy.abc import A, B >>> conjuncts(A & B) frozenset({A, B}) >>> conjuncts(A | B) frozenset({A | B}) """ return And.make_args(expr) def disjuncts(expr): """Return a list of the disjuncts in the sentence s. Examples ======== >>> from sympy.logic.boolalg import disjuncts >>> from sympy.abc import A, B >>> disjuncts(A | B) frozenset({A, B}) >>> disjuncts(A & B) frozenset({A & B}) """ return Or.make_args(expr) def distribute_and_over_or(expr): """ Given a sentence s consisting of conjunctions and disjunctions of literals, return an equivalent sentence in CNF. Examples ======== >>> from sympy.logic.boolalg import distribute_and_over_or, And, Or, Not >>> from sympy.abc import A, B, C >>> distribute_and_over_or(Or(A, And(Not(B), Not(C)))) (A | ~B) & (A | ~C) """ return _distribute((expr, And, Or)) def distribute_or_over_and(expr): """ Given a sentence s consisting of conjunctions and disjunctions of literals, return an equivalent sentence in DNF. Note that the output is NOT simplified. Examples ======== >>> from sympy.logic.boolalg import distribute_or_over_and, And, Or, Not >>> from sympy.abc import A, B, C >>> distribute_or_over_and(And(Or(Not(A), B), C)) (B & C) | (C & ~A) """ return _distribute((expr, Or, And)) def _distribute(info): """ Distributes info[1] over info[2] with respect to info[0]. """ if isinstance(info[0], info[2]): for arg in info[0].args: if isinstance(arg, info[1]): conj = arg break else: return info[0] rest = info[2](*[a for a in info[0].args if a is not conj]) return info[1](*list(map(_distribute, [(info[2](c, rest), info[1], info[2]) for c in conj.args]))) elif isinstance(info[0], info[1]): return info[1](*list(map(_distribute, [(x, info[1], info[2]) for x in info[0].args]))) else: return info[0] def to_nnf(expr, simplify=True): """ Converts expr to Negation Normal Form. A logical expression is in Negation Normal Form (NNF) if it contains only And, Or and Not, and Not is applied only to literals. If simplify is True, the result contains no redundant clauses. Examples ======== >>> from sympy.abc import A, B, C, D >>> from sympy.logic.boolalg import Not, Equivalent, to_nnf >>> to_nnf(Not((~A & ~B) | (C & D))) (A | B) & (~C | ~D) >>> to_nnf(Equivalent(A >> B, B >> A)) (A | ~B | (A & ~B)) & (B | ~A | (B & ~A)) """ if is_nnf(expr, simplify): return expr return expr.to_nnf(simplify) def to_cnf(expr, simplify=False): """ Convert a propositional logical sentence s to conjunctive normal form. That is, of the form ((A | ~B | ...) & (B | C | ...) & ...) If simplify is True, the expr is evaluated to its simplest CNF form using the Quine-McCluskey algorithm. Examples ======== >>> from sympy.logic.boolalg import to_cnf >>> from sympy.abc import A, B, D >>> to_cnf(~(A | B) | D) (D | ~A) & (D | ~B) >>> to_cnf((A | B) & (A | ~A), True) A | B """ expr = sympify(expr) if not isinstance(expr, BooleanFunction): return expr if simplify: return simplify_logic(expr, 'cnf', True) # Don't convert unless we have to if is_cnf(expr): return expr expr = eliminate_implications(expr) return distribute_and_over_or(expr) def to_dnf(expr, simplify=False): """ Convert a propositional logical sentence s to disjunctive normal form. That is, of the form ((A & ~B & ...) | (B & C & ...) | ...) If simplify is True, the expr is evaluated to its simplest DNF form using the Quine-McCluskey algorithm. Examples ======== >>> from sympy.logic.boolalg import to_dnf >>> from sympy.abc import A, B, C >>> to_dnf(B & (A | C)) (A & B) | (B & C) >>> to_dnf((A & B) | (A & ~B) | (B & C) | (~B & C), True) A | C """ expr = sympify(expr) if not isinstance(expr, BooleanFunction): return expr if simplify: return simplify_logic(expr, 'dnf', True) # Don't convert unless we have to if is_dnf(expr): return expr expr = eliminate_implications(expr) return distribute_or_over_and(expr) def is_nnf(expr, simplified=True): """ Checks if expr is in Negation Normal Form. A logical expression is in Negation Normal Form (NNF) if it contains only And, Or and Not, and Not is applied only to literals. If simpified is True, checks if result contains no redundant clauses. Examples ======== >>> from sympy.abc import A, B, C >>> from sympy.logic.boolalg import Not, is_nnf >>> is_nnf(A & B | ~C) True >>> is_nnf((A | ~A) & (B | C)) False >>> is_nnf((A | ~A) & (B | C), False) True >>> is_nnf(Not(A & B) | C) False >>> is_nnf((A >> B) & (B >> A)) False """ expr = sympify(expr) if is_literal(expr): return True stack = [expr] while stack: expr = stack.pop() if expr.func in (And, Or): if simplified: args = expr.args for arg in args: if Not(arg) in args: return False stack.extend(expr.args) elif not is_literal(expr): return False return True def is_cnf(expr): """ Test whether or not an expression is in conjunctive normal form. Examples ======== >>> from sympy.logic.boolalg import is_cnf >>> from sympy.abc import A, B, C >>> is_cnf(A | B | C) True >>> is_cnf(A & B & C) True >>> is_cnf((A & B) | C) False """ return _is_form(expr, And, Or) def is_dnf(expr): """ Test whether or not an expression is in disjunctive normal form. Examples ======== >>> from sympy.logic.boolalg import is_dnf >>> from sympy.abc import A, B, C >>> is_dnf(A | B | C) True >>> is_dnf(A & B & C) True >>> is_dnf((A & B) | C) True >>> is_dnf(A & (B | C)) False """ return _is_form(expr, Or, And) def _is_form(expr, function1, function2): """ Test whether or not an expression is of the required form. """ expr = sympify(expr) # Special case of an Atom if expr.is_Atom: return True # Special case of a single expression of function2 if isinstance(expr, function2): for lit in expr.args: if isinstance(lit, Not): if not lit.args[0].is_Atom: return False else: if not lit.is_Atom: return False return True # Special case of a single negation if isinstance(expr, Not): if not expr.args[0].is_Atom: return False if not isinstance(expr, function1): return False for cls in expr.args: if cls.is_Atom: continue if isinstance(cls, Not): if not cls.args[0].is_Atom: return False elif not isinstance(cls, function2): return False for lit in cls.args: if isinstance(lit, Not): if not lit.args[0].is_Atom: return False else: if not lit.is_Atom: return False return True def eliminate_implications(expr): """ Change >>, <<, and Equivalent into &, |, and ~. That is, return an expression that is equivalent to s, but has only &, |, and ~ as logical operators. Examples ======== >>> from sympy.logic.boolalg import Implies, Equivalent, \ eliminate_implications >>> from sympy.abc import A, B, C >>> eliminate_implications(Implies(A, B)) B | ~A >>> eliminate_implications(Equivalent(A, B)) (A | ~B) & (B | ~A) >>> eliminate_implications(Equivalent(A, B, C)) (A | ~C) & (B | ~A) & (C | ~B) """ return to_nnf(expr, simplify=False) def is_literal(expr): """ Returns True if expr is a literal, else False. Examples ======== >>> from sympy import Or, Q >>> from sympy.abc import A, B >>> from sympy.logic.boolalg import is_literal >>> is_literal(A) True >>> is_literal(~A) True >>> is_literal(Q.zero(A)) True >>> is_literal(A + B) True >>> is_literal(Or(A, B)) False """ if isinstance(expr, Not): return not isinstance(expr.args[0], BooleanFunction) else: return not isinstance(expr, BooleanFunction) def to_int_repr(clauses, symbols): """ Takes clauses in CNF format and puts them into an integer representation. Examples ======== >>> from sympy.logic.boolalg import to_int_repr >>> from sympy.abc import x, y >>> to_int_repr([x | y, y], [x, y]) == [{1, 2}, {2}] True """ # Convert the symbol list into a dict symbols = dict(list(zip(symbols, list(range(1, len(symbols) + 1))))) def append_symbol(arg, symbols): if isinstance(arg, Not): return -symbols[arg.args[0]] else: return symbols[arg] return [set(append_symbol(arg, symbols) for arg in Or.make_args(c)) for c in clauses] def term_to_integer(term): """ Return an integer corresponding to the base-2 digits given by ``term``. Parameters ========== term : a string or list of ones and zeros Examples ======== >>> from sympy.logic.boolalg import term_to_integer >>> term_to_integer([1, 0, 0]) 4 >>> term_to_integer('100') 4 """ return int(''.join(list(map(str, list(term)))), 2) def integer_to_term(k, n_bits=None): """ Return a list of the base-2 digits in the integer, ``k``. Parameters ========== k : int n_bits : int If ``n_bits`` is given and the number of digits in the binary representation of ``k`` is smaller than ``n_bits`` then left-pad the list with 0s. Examples ======== >>> from sympy.logic.boolalg import integer_to_term >>> integer_to_term(4) [1, 0, 0] >>> integer_to_term(4, 6) [0, 0, 0, 1, 0, 0] """ s = '{0:0{1}b}'.format(abs(as_int(k)), as_int(abs(n_bits or 0))) return list(map(int, s)) def truth_table(expr, variables, input=True): """ Return a generator of all possible configurations of the input variables, and the result of the boolean expression for those values. Parameters ========== expr : string or boolean expression variables : list of variables input : boolean (default True) indicates whether to return the input combinations. Examples ======== >>> from sympy.logic.boolalg import truth_table >>> from sympy.abc import x,y >>> table = truth_table(x >> y, [x, y]) >>> for t in table: ... print('{0} -> {1}'.format(*t)) [0, 0] -> True [0, 1] -> True [1, 0] -> False [1, 1] -> True >>> table = truth_table(x | y, [x, y]) >>> list(table) [([0, 0], False), ([0, 1], True), ([1, 0], True), ([1, 1], True)] If input is false, truth_table returns only a list of truth values. In this case, the corresponding input values of variables can be deduced from the index of a given output. >>> from sympy.logic.boolalg import integer_to_term >>> vars = [y, x] >>> values = truth_table(x >> y, vars, input=False) >>> values = list(values) >>> values [True, False, True, True] >>> for i, value in enumerate(values): ... print('{0} -> {1}'.format(list(zip( ... vars, integer_to_term(i, len(vars)))), value)) [(y, 0), (x, 0)] -> True [(y, 0), (x, 1)] -> False [(y, 1), (x, 0)] -> True [(y, 1), (x, 1)] -> True """ variables = [sympify(v) for v in variables] expr = sympify(expr) if not isinstance(expr, BooleanFunction) and not is_literal(expr): return table = product([0, 1], repeat=len(variables)) for term in table: term = list(term) value = expr.xreplace(dict(zip(variables, term))) if input: yield term, value else: yield value def _check_pair(minterm1, minterm2): """ Checks if a pair of minterms differs by only one bit. If yes, returns index, else returns -1. """ index = -1 for x, (i, j) in enumerate(zip(minterm1, minterm2)): if i != j: if index == -1: index = x else: return -1 return index def _convert_to_varsSOP(minterm, variables): """ Converts a term in the expansion of a function from binary to its variable form (for SOP). """ temp = [] for i, m in enumerate(minterm): if m == 0: temp.append(Not(variables[i])) elif m == 1: temp.append(variables[i]) else: pass # ignore the 3s return And(*temp) def _convert_to_varsPOS(maxterm, variables): """ Converts a term in the expansion of a function from binary to its variable form (for POS). """ temp = [] for i, m in enumerate(maxterm): if m == 1: temp.append(Not(variables[i])) elif m == 0: temp.append(variables[i]) else: pass # ignore the 3s return Or(*temp) def _simplified_pairs(terms): """ Reduces a set of minterms, if possible, to a simplified set of minterms with one less variable in the terms using QM method. """ simplified_terms = [] todo = list(range(len(terms))) for i, ti in enumerate(terms[:-1]): for j_i, tj in enumerate(terms[(i + 1):]): index = _check_pair(ti, tj) if index != -1: todo[i] = todo[j_i + i + 1] = None newterm = ti[:] newterm[index] = 3 if newterm not in simplified_terms: simplified_terms.append(newterm) simplified_terms.extend( [terms[i] for i in [_ for _ in todo if _ is not None]]) return simplified_terms def _compare_term(minterm, term): """ Return True if a binary term is satisfied by the given term. Used for recognizing prime implicants. """ for i, x in enumerate(term): if x != 3 and x != minterm[i]: return False return True def _rem_redundancy(l1, terms): """ After the truth table has been sufficiently simplified, use the prime implicant table method to recognize and eliminate redundant pairs, and return the essential arguments. """ if len(terms): # Create dominating matrix dommatrix = [[0]*len(l1) for n in range(len(terms))] for primei, prime in enumerate(l1): for termi, term in enumerate(terms): if _compare_term(term, prime): dommatrix[termi][primei] = 1 # Non-dominated prime implicants, dominated set to None ndprimeimplicants = list(range(len(l1))) # Non-dominated terms, dominated set to None ndterms = list(range(len(terms))) # Mark dominated rows and columns oldndterms = None oldndprimeimplicants = None while ndterms != oldndterms or \ ndprimeimplicants != oldndprimeimplicants: oldndterms = ndterms[:] oldndprimeimplicants = ndprimeimplicants[:] for rowi, row in enumerate(dommatrix): if ndterms[rowi] is not None: row = [row[i] for i in [_ for _ in ndprimeimplicants if _ is not None]] for row2i, row2 in enumerate(dommatrix): if rowi != row2i and ndterms[row2i] is not None: row2 = [row2[i] for i in [_ for _ in ndprimeimplicants if _ is not None]] if all(a >= b for (a, b) in zip(row2, row)): # row2 dominating row, keep row ndterms[row2i] = None for coli in range(len(l1)): if ndprimeimplicants[coli] is not None: col = [dommatrix[a][coli] for a in range(len(terms))] col = [col[i] for i in [_ for _ in oldndterms if _ is not None]] for col2i in range(len(l1)): if coli != col2i and \ ndprimeimplicants[col2i] is not None: col2 = [dommatrix[a][col2i] for a in range(len(terms))] col2 = [col2[i] for i in [_ for _ in oldndterms if _ is not None]] if all(a >= b for (a, b) in zip(col, col2)): # col dominating col2, keep col ndprimeimplicants[col2i] = None l1 = [l1[i] for i in [_ for _ in ndprimeimplicants if _ is not None]] return l1 else: return [] def _input_to_binlist(inputlist, variables): binlist = [] bits = len(variables) for val in inputlist: if isinstance(val, int): binlist.append(ibin(val, bits)) elif isinstance(val, dict): nonspecvars = list(variables) for key in val.keys(): nonspecvars.remove(key) for t in product([0, 1], repeat=len(nonspecvars)): d = dict(zip(nonspecvars, t)) d.update(val) binlist.append([d[v] for v in variables]) elif isinstance(val, (list, tuple)): if len(val) != bits: raise ValueError("Each term must contain {} bits as there are" "\n{} variables (or be an integer)." "".format(bits, bits)) binlist.append(list(val)) else: raise TypeError("A term list can only contain lists," " ints or dicts.") return binlist def SOPform(variables, minterms, dontcares=None): """ The SOPform function uses simplified_pairs and a redundant group- eliminating algorithm to convert the list of all input combos that generate '1' (the minterms) into the smallest Sum of Products form. The variables must be given as the first argument. Return a logical Or function (i.e., the "sum of products" or "SOP" form) that gives the desired outcome. If there are inputs that can be ignored, pass them as a list, too. The result will be one of the (perhaps many) functions that satisfy the conditions. Examples ======== >>> from sympy.logic import SOPform >>> from sympy import symbols >>> w, x, y, z = symbols('w x y z') >>> minterms = [[0, 0, 0, 1], [0, 0, 1, 1], ... [0, 1, 1, 1], [1, 0, 1, 1], [1, 1, 1, 1]] >>> dontcares = [[0, 0, 0, 0], [0, 0, 1, 0], [0, 1, 0, 1]] >>> SOPform([w, x, y, z], minterms, dontcares) (y & z) | (z & ~w) The terms can also be represented as integers: >>> minterms = [1, 3, 7, 11, 15] >>> dontcares = [0, 2, 5] >>> SOPform([w, x, y, z], minterms, dontcares) (y & z) | (z & ~w) They can also be specified using dicts, which does not have to be fully specified: >>> minterms = [{w: 0, x: 1}, {y: 1, z: 1, x: 0}] >>> SOPform([w, x, y, z], minterms) (x & ~w) | (y & z & ~x) Or a combination: >>> minterms = [4, 7, 11, [1, 1, 1, 1]] >>> dontcares = [{w : 0, x : 0, y: 0}, 5] >>> SOPform([w, x, y, z], minterms, dontcares) (w & y & z) | (x & y & z) | (~w & ~y) References ========== .. [1] en.wikipedia.org/wiki/Quine-McCluskey_algorithm """ variables = [sympify(v) for v in variables] if minterms == []: return false minterms = _input_to_binlist(minterms, variables) dontcares = _input_to_binlist((dontcares or []), variables) for d in dontcares: if d in minterms: raise ValueError('%s in minterms is also in dontcares' % d) old = None new = minterms + dontcares while new != old: old = new new = _simplified_pairs(old) essential = _rem_redundancy(new, minterms) return Or(*[_convert_to_varsSOP(x, variables) for x in essential]) def POSform(variables, minterms, dontcares=None): """ The POSform function uses simplified_pairs and a redundant-group eliminating algorithm to convert the list of all input combinations that generate '1' (the minterms) into the smallest Product of Sums form. The variables must be given as the first argument. Return a logical And function (i.e., the "product of sums" or "POS" form) that gives the desired outcome. If there are inputs that can be ignored, pass them as a list, too. The result will be one of the (perhaps many) functions that satisfy the conditions. Examples ======== >>> from sympy.logic import POSform >>> from sympy import symbols >>> w, x, y, z = symbols('w x y z') >>> minterms = [[0, 0, 0, 1], [0, 0, 1, 1], [0, 1, 1, 1], ... [1, 0, 1, 1], [1, 1, 1, 1]] >>> dontcares = [[0, 0, 0, 0], [0, 0, 1, 0], [0, 1, 0, 1]] >>> POSform([w, x, y, z], minterms, dontcares) z & (y | ~w) The terms can also be represented as integers: >>> minterms = [1, 3, 7, 11, 15] >>> dontcares = [0, 2, 5] >>> POSform([w, x, y, z], minterms, dontcares) z & (y | ~w) They can also be specified using dicts, which does not have to be fully specified: >>> minterms = [{w: 0, x: 1}, {y: 1, z: 1, x: 0}] >>> POSform([w, x, y, z], minterms) (x | y) & (x | z) & (~w | ~x) Or a combination: >>> minterms = [4, 7, 11, [1, 1, 1, 1]] >>> dontcares = [{w : 0, x : 0, y: 0}, 5] >>> POSform([w, x, y, z], minterms, dontcares) (w | x) & (y | ~w) & (z | ~y) References ========== .. [1] en.wikipedia.org/wiki/Quine-McCluskey_algorithm """ variables = [sympify(v) for v in variables] if minterms == []: return false minterms = _input_to_binlist(minterms, variables) dontcares = _input_to_binlist((dontcares or []), variables) for d in dontcares: if d in minterms: raise ValueError('%s in minterms is also in dontcares' % d) maxterms = [] for t in product([0, 1], repeat=len(variables)): t = list(t) if (t not in minterms) and (t not in dontcares): maxterms.append(t) old = None new = maxterms + dontcares while new != old: old = new new = _simplified_pairs(old) essential = _rem_redundancy(new, maxterms) return And(*[_convert_to_varsPOS(x, variables) for x in essential]) def _find_predicates(expr): """Helper to find logical predicates in BooleanFunctions. A logical predicate is defined here as anything within a BooleanFunction that is not a BooleanFunction itself. """ if not isinstance(expr, BooleanFunction): return {expr} return set().union(*(_find_predicates(i) for i in expr.args)) def simplify_logic(expr, form=None, deep=True, force=False): """ This function simplifies a boolean function to its simplified version in SOP or POS form. The return type is an Or or And object in SymPy. Parameters ========== expr : string or boolean expression form : string ('cnf' or 'dnf') or None (default). If 'cnf' or 'dnf', the simplest expression in the corresponding normal form is returned; if None, the answer is returned according to the form with fewest args (in CNF by default). deep : boolean (default True) Indicates whether to recursively simplify any non-boolean functions contained within the input. force : boolean (default False) As the simplifications require exponential time in the number of variables, there is by default a limit on expressions with 8 variables. When the expression has more than 8 variables only symbolical simplification (controlled by ``deep``) is made. By setting force to ``True``, this limit is removed. Be aware that this can lead to very long simplification times. Examples ======== >>> from sympy.logic import simplify_logic >>> from sympy.abc import x, y, z >>> from sympy import S >>> b = (~x & ~y & ~z) | ( ~x & ~y & z) >>> simplify_logic(b) ~x & ~y >>> S(b) (z & ~x & ~y) | (~x & ~y & ~z) >>> simplify_logic(_) ~x & ~y """ if form not in (None, 'cnf', 'dnf'): raise ValueError("form can be cnf or dnf only") expr = sympify(expr) if deep: variables = _find_predicates(expr) from sympy.simplify.simplify import simplify s = [simplify(v) for v in variables] expr = expr.xreplace(dict(zip(variables, s))) if not isinstance(expr, BooleanFunction): return expr # get variables in case not deep or after doing # deep simplification since they may have changed variables = _find_predicates(expr) if not force and len(variables) > 8: return expr # group into constants and variable values c, v = sift(variables, lambda x: x in (True, False), binary=True) variables = c + v truthtable = [] # standardize constants to be 1 or 0 in keeping with truthtable c = [1 if i == True else 0 for i in c] for t in product([0, 1], repeat=len(v)): if expr.xreplace(dict(zip(v, t))) == True: truthtable.append(c + list(t)) big = len(truthtable) >= (2 ** (len(variables) - 1)) if form == 'dnf' or form is None and big: return SOPform(variables, truthtable) return POSform(variables, truthtable) def _finger(eq): """ Assign a 5-item fingerprint to each symbol in the equation: [ # of times it appeared as a Symbol, # of times it appeared as a Not(symbol), # of times it appeared as a Symbol in an And or Or, # of times it appeared as a Not(Symbol) in an And or Or, sum of the number of arguments with which it appeared as a Symbol, counting Symbol as 1 and Not(Symbol) as 2 and counting self as 1 ] >>> from sympy.logic.boolalg import _finger as finger >>> from sympy import And, Or, Not >>> from sympy.abc import a, b, x, y >>> eq = Or(And(Not(y), a), And(Not(y), b), And(x, y)) >>> dict(finger(eq)) {(0, 0, 1, 0, 2): [x], (0, 0, 1, 0, 3): [a, b], (0, 0, 1, 2, 2): [y]} >>> dict(finger(x & ~y)) {(0, 1, 0, 0, 0): [y], (1, 0, 0, 0, 0): [x]} The equation must not have more than one level of nesting: >>> dict(finger(And(Or(x, y), y))) {(0, 0, 1, 0, 2): [x], (1, 0, 1, 0, 2): [y]} >>> dict(finger(And(Or(x, And(a, x)), y))) Traceback (most recent call last): ... NotImplementedError: unexpected level of nesting So y and x have unique fingerprints, but a and b do not. """ f = eq.free_symbols d = dict(list(zip(f, [[0] * 5 for fi in f]))) for a in eq.args: if a.is_Symbol: d[a][0] += 1 elif a.is_Not: d[a.args[0]][1] += 1 else: o = len(a.args) + sum(isinstance(ai, Not) for ai in a.args) for ai in a.args: if ai.is_Symbol: d[ai][2] += 1 d[ai][-1] += o elif ai.is_Not: d[ai.args[0]][3] += 1 else: raise NotImplementedError('unexpected level of nesting') inv = defaultdict(list) for k, v in ordered(iter(d.items())): inv[tuple(v)].append(k) return inv def bool_map(bool1, bool2): """ Return the simplified version of bool1, and the mapping of variables that makes the two expressions bool1 and bool2 represent the same logical behaviour for some correspondence between the variables of each. If more than one mappings of this sort exist, one of them is returned. For example, And(x, y) is logically equivalent to And(a, b) for the mapping {x: a, y:b} or {x: b, y:a}. If no such mapping exists, return False. Examples ======== >>> from sympy import SOPform, bool_map, Or, And, Not, Xor >>> from sympy.abc import w, x, y, z, a, b, c, d >>> function1 = SOPform([x, z, y],[[1, 0, 1], [0, 0, 1]]) >>> function2 = SOPform([a, b, c],[[1, 0, 1], [1, 0, 0]]) >>> bool_map(function1, function2) (y & ~z, {y: a, z: b}) The results are not necessarily unique, but they are canonical. Here, ``(w, z)`` could be ``(a, d)`` or ``(d, a)``: >>> eq = Or(And(Not(y), w), And(Not(y), z), And(x, y)) >>> eq2 = Or(And(Not(c), a), And(Not(c), d), And(b, c)) >>> bool_map(eq, eq2) ((x & y) | (w & ~y) | (z & ~y), {w: a, x: b, y: c, z: d}) >>> eq = And(Xor(a, b), c, And(c,d)) >>> bool_map(eq, eq.subs(c, x)) (c & d & (a | b) & (~a | ~b), {a: a, b: b, c: d, d: x}) """ def match(function1, function2): """Return the mapping that equates variables between two simplified boolean expressions if possible. By "simplified" we mean that a function has been denested and is either an And (or an Or) whose arguments are either symbols (x), negated symbols (Not(x)), or Or (or an And) whose arguments are only symbols or negated symbols. For example, And(x, Not(y), Or(w, Not(z))). Basic.match is not robust enough (see issue 4835) so this is a workaround that is valid for simplified boolean expressions """ # do some quick checks if function1.__class__ != function2.__class__: return None # maybe simplification makes them the same? if len(function1.args) != len(function2.args): return None # maybe simplification makes them the same? if function1.is_Symbol: return {function1: function2} # get the fingerprint dictionaries f1 = _finger(function1) f2 = _finger(function2) # more quick checks if len(f1) != len(f2): return False # assemble the match dictionary if possible matchdict = {} for k in f1.keys(): if k not in f2: return False if len(f1[k]) != len(f2[k]): return False for i, x in enumerate(f1[k]): matchdict[x] = f2[k][i] return matchdict a = simplify_logic(bool1) b = simplify_logic(bool2) m = match(a, b) if m: return a, m return m def simplify_patterns_and(): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.core import Wild from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt a = Wild('a') b = Wild('b') c = Wild('c') # With a better canonical fewer results are required _matchers_and = ((And(Eq(a, b), Ge(a, b)), Eq(a, b)), (And(Eq(a, b), Gt(a, b)), S.false), (And(Eq(a, b), Le(a, b)), Eq(a, b)), (And(Eq(a, b), Lt(a, b)), S.false), (And(Ge(a, b), Gt(a, b)), Gt(a, b)), (And(Ge(a, b), Le(a, b)), Eq(a, b)), (And(Ge(a, b), Lt(a, b)), S.false), (And(Ge(a, b), Ne(a, b)), Gt(a, b)), (And(Gt(a, b), Le(a, b)), S.false), (And(Gt(a, b), Lt(a, b)), S.false), (And(Gt(a, b), Ne(a, b)), Gt(a, b)), (And(Le(a, b), Lt(a, b)), Lt(a, b)), (And(Le(a, b), Ne(a, b)), Lt(a, b)), (And(Lt(a, b), Ne(a, b)), Lt(a, b)), # Min/max (And(Ge(a, b), Ge(a, c)), Ge(a, Max(b, c))), (And(Ge(a, b), Gt(a, c)), ITE(b > c, Ge(a, b), Gt(a, c))), (And(Gt(a, b), Gt(a, c)), Gt(a, Max(b, c))), (And(Le(a, b), Le(a, c)), Le(a, Min(b, c))), (And(Le(a, b), Lt(a, c)), ITE(b < c, Le(a, b), Lt(a, c))), (And(Lt(a, b), Lt(a, c)), Lt(a, Min(b, c))), # Sign (And(Eq(a, b), Eq(a, -b)), And(Eq(a, S(0)), Eq(b, S(0)))), ) return _matchers_and def simplify_patterns_or(): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.core import Wild from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt a = Wild('a') b = Wild('b') c = Wild('c') _matchers_or = ((Or(Eq(a, b), Ge(a, b)), Ge(a, b)), (Or(Eq(a, b), Gt(a, b)), Ge(a, b)), (Or(Eq(a, b), Le(a, b)), Le(a, b)), (Or(Eq(a, b), Lt(a, b)), Le(a, b)), (Or(Ge(a, b), Gt(a, b)), Ge(a, b)), (Or(Ge(a, b), Le(a, b)), S.true), (Or(Ge(a, b), Lt(a, b)), S.true), (Or(Ge(a, b), Ne(a, b)), S.true), (Or(Gt(a, b), Le(a, b)), S.true), (Or(Gt(a, b), Lt(a, b)), Ne(a, b)), (Or(Gt(a, b), Ne(a, b)), Ne(a, b)), (Or(Le(a, b), Lt(a, b)), Le(a, b)), (Or(Le(a, b), Ne(a, b)), S.true), (Or(Lt(a, b), Ne(a, b)), Ne(a, b)), # Min/max (Or(Ge(a, b), Ge(a, c)), Ge(a, Min(b, c))), (Or(Ge(a, b), Gt(a, c)), ITE(b > c, Gt(a, c), Ge(a, b))), (Or(Gt(a, b), Gt(a, c)), Gt(a, Min(b, c))), (Or(Le(a, b), Le(a, c)), Le(a, Max(b, c))), (Or(Le(a, b), Lt(a, c)), ITE(b >= c, Le(a, b), Lt(a, c))), (Or(Lt(a, b), Lt(a, c)), Lt(a, Max(b, c))), ) return _matchers_or def simplify_patterns_xor(): from sympy.functions.elementary.miscellaneous import Min, Max from sympy.core import Wild from sympy.core.relational import Eq, Ne, Ge, Gt, Le, Lt a = Wild('a') b = Wild('b') c = Wild('c') _matchers_xor = ((Xor(Eq(a, b), Ge(a, b)), Gt(a, b)), (Xor(Eq(a, b), Gt(a, b)), Ge(a, b)), (Xor(Eq(a, b), Le(a, b)), Lt(a, b)), (Xor(Eq(a, b), Lt(a, b)), Le(a, b)), (Xor(Ge(a, b), Gt(a, b)), Eq(a, b)), (Xor(Ge(a, b), Le(a, b)), Ne(a, b)), (Xor(Ge(a, b), Lt(a, b)), S.true), (Xor(Ge(a, b), Ne(a, b)), Le(a, b)), (Xor(Gt(a, b), Le(a, b)), S.true), (Xor(Gt(a, b), Lt(a, b)), Ne(a, b)), (Xor(Gt(a, b), Ne(a, b)), Lt(a, b)), (Xor(Le(a, b), Lt(a, b)), Eq(a, b)), (Xor(Le(a, b), Ne(a, b)), Ge(a, b)), (Xor(Lt(a, b), Ne(a, b)), Gt(a, b)), # Min/max (Xor(Ge(a, b), Ge(a, c)), And(Ge(a, Min(b, c)), Lt(a, Max(b, c)))), (Xor(Ge(a, b), Gt(a, c)), ITE(b > c, And(Gt(a, c), Lt(a, b)), And(Ge(a, b), Le(a, c)))), (Xor(Gt(a, b), Gt(a, c)), And(Gt(a, Min(b, c)), Le(a, Max(b, c)))), (Xor(Le(a, b), Le(a, c)), And(Le(a, Max(b, c)), Gt(a, Min(b, c)))), (Xor(Le(a, b), Lt(a, c)), ITE(b < c, And(Lt(a, c), Gt(a, b)), And(Le(a, b), Ge(a, c)))), (Xor(Lt(a, b), Lt(a, c)), And(Lt(a, Max(b, c)), Ge(a, Min(b, c)))), ) return _matchers_xor

0d59f01ba22fd456d418f95aac125480d0401fc712785c82a06f868c334400f7

"""A module that handles matrices. Includes functions for fast creating matrices like zero, one/eye, random matrix, etc. """ from .common import ShapeError, NonSquareMatrixError from .dense import ( GramSchmidt, casoratian, diag, eye, hessian, jordan_cell, list2numpy, matrix2numpy, matrix_multiply_elementwise, ones, randMatrix, rot_axis1, rot_axis2, rot_axis3, symarray, wronskian, zeros) from .dense import MutableDenseMatrix from .matrices import DeferredVector, MatrixBase Matrix = MutableMatrix = MutableDenseMatrix from .sparse import MutableSparseMatrix from .sparsetools import banded from .immutable import ImmutableDenseMatrix, ImmutableSparseMatrix ImmutableMatrix = ImmutableDenseMatrix SparseMatrix = MutableSparseMatrix from .expressions import ( MatrixSlice, BlockDiagMatrix, BlockMatrix, FunctionMatrix, Identity, Inverse, MatAdd, MatMul, MatPow, MatrixExpr, MatrixSymbol, Trace, Transpose, ZeroMatrix, OneMatrix, blockcut, block_collapse, matrix_symbols, Adjoint, hadamard_product, HadamardProduct, HadamardPower, Determinant, det, diagonalize_vector, DiagonalizeVector, DiagonalMatrix, DiagonalOf, trace, DotProduct, kronecker_product, KroneckerProduct)

cc38817355c3b993604076fed8493c435b24cd67fb03e5a86be119fad08b783f

from __future__ import division, print_function from sympy.core import Basic, Dict, Integer, S, Tuple, sympify from sympy.core.cache import cacheit from sympy.core.sympify import converter as sympify_converter from sympy.matrices.dense import DenseMatrix from sympy.matrices.expressions import MatrixExpr from sympy.matrices.matrices import MatrixBase from sympy.matrices.sparse import MutableSparseMatrix, SparseMatrix def sympify_matrix(arg): return arg.as_immutable() sympify_converter[MatrixBase] = sympify_matrix class ImmutableDenseMatrix(DenseMatrix, MatrixExpr): """Create an immutable version of a matrix. Examples ======== >>> from sympy import eye >>> from sympy.matrices import ImmutableMatrix >>> ImmutableMatrix(eye(3)) Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) >>> _[0, 0] = 42 Traceback (most recent call last): ... TypeError: Cannot set values of ImmutableDenseMatrix """ # MatrixExpr is set as NotIterable, but we want explicit matrices to be # iterable _iterable = True _class_priority = 8 _op_priority = 10.001 def __new__(cls, *args, **kwargs): return cls._new(*args, **kwargs) __hash__ = MatrixExpr.__hash__ @classmethod def _new(cls, *args, **kwargs): if len(args) == 1 and isinstance(args[0], ImmutableDenseMatrix): return args[0] if kwargs.get('copy', True) is False: if len(args) != 3: raise TypeError("'copy=False' requires a matrix be initialized as rows,cols,[list]") rows, cols, flat_list = args else: rows, cols, flat_list = cls._handle_creation_inputs(*args, **kwargs) flat_list = list(flat_list) # create a shallow copy rows = Integer(rows) cols = Integer(cols) if not isinstance(flat_list, Tuple): flat_list = Tuple(*flat_list) return Basic.__new__(cls, rows, cols, flat_list) @property def _mat(self): # self.args[2] is a Tuple. Access to the elements # of a tuple are significantly faster than Tuple, # so return the internal tuple. return self.args[2].args def _entry(self, i, j, **kwargs): return DenseMatrix.__getitem__(self, (i, j)) def __setitem__(self, *args): raise TypeError("Cannot set values of {}".format(self.__class__)) def _eval_Eq(self, other): """Helper method for Equality with matrices. Relational automatically converts matrices to ImmutableDenseMatrix instances, so this method only applies here. Returns True if the matrices are definitively the same, False if they are definitively different, and None if undetermined (e.g. if they contain Symbols). Returning None triggers default handling of Equalities. """ if not hasattr(other, 'shape') or self.shape != other.shape: return S.false if isinstance(other, MatrixExpr) and not isinstance( other, ImmutableDenseMatrix): return None diff = self - other return sympify(diff.is_zero) def _eval_extract(self, rowsList, colsList): # self._mat is a Tuple. It is slightly faster to index a # tuple over a Tuple, so grab the internal tuple directly mat = self._mat cols = self.cols indices = (i * cols + j for i in rowsList for j in colsList) return self._new(len(rowsList), len(colsList), Tuple(*(mat[i] for i in indices), sympify=False), copy=False) @property def cols(self): return int(self.args[1]) @property def rows(self): return int(self.args[0]) @property def shape(self): return tuple(int(i) for i in self.args[:2]) def is_diagonalizable(self, reals_only=False, **kwargs): return super(ImmutableDenseMatrix, self).is_diagonalizable( reals_only=reals_only, **kwargs) is_diagonalizable.__doc__ = DenseMatrix.is_diagonalizable.__doc__ is_diagonalizable = cacheit(is_diagonalizable) # This is included after the class definition as a workaround for issue 7213. # See https://github.com/sympy/sympy/issues/7213 # the object is non-zero # See https://github.com/sympy/sympy/issues/7213 ImmutableDenseMatrix.is_zero = DenseMatrix.is_zero # make sure ImmutableDenseMatrix is aliased as ImmutableMatrix ImmutableMatrix = ImmutableDenseMatrix class ImmutableSparseMatrix(SparseMatrix, Basic): """Create an immutable version of a sparse matrix. Examples ======== >>> from sympy import eye >>> from sympy.matrices.immutable import ImmutableSparseMatrix >>> ImmutableSparseMatrix(1, 1, {}) Matrix([[0]]) >>> ImmutableSparseMatrix(eye(3)) Matrix([ [1, 0, 0], [0, 1, 0], [0, 0, 1]]) >>> _[0, 0] = 42 Traceback (most recent call last): ... TypeError: Cannot set values of ImmutableSparseMatrix >>> _.shape (3, 3) """ is_Matrix = True _class_priority = 9 @classmethod def _new(cls, *args, **kwargs): s = MutableSparseMatrix(*args) rows = Integer(s.rows) cols = Integer(s.cols) mat = Dict(s._smat) obj = Basic.__new__(cls, rows, cols, mat) obj.rows = s.rows obj.cols = s.cols obj._smat = s._smat return obj def __new__(cls, *args, **kwargs): return cls._new(*args, **kwargs) def __setitem__(self, *args): raise TypeError("Cannot set values of ImmutableSparseMatrix") def __hash__(self): return hash((type(self).__name__,) + (self.shape, tuple(self._smat))) _eval_Eq = ImmutableDenseMatrix._eval_Eq def is_diagonalizable(self, reals_only=False, **kwargs): return super(ImmutableSparseMatrix, self).is_diagonalizable( reals_only=reals_only, **kwargs) is_diagonalizable.__doc__ = SparseMatrix.is_diagonalizable.__doc__ is_diagonalizable = cacheit(is_diagonalizable)

f51e19b96615d19960fd53c27d5c6008e50613ebc244255aaa674771982fc4a3

""" Basic methods common to all matrices to be used when creating more advanced matrices (e.g., matrices over rings, etc.). """ from __future__ import division, print_function from collections import defaultdict from inspect import isfunction from sympy.assumptions.refine import refine from sympy.core.basic import Atom from sympy.core.compatibility import ( Iterable, as_int, is_sequence, range, reduce) from sympy.core.decorators import call_highest_priority from sympy.core.expr import Expr from sympy.core.function import count_ops from sympy.core.singleton import S from sympy.core.symbol import Symbol from sympy.core.sympify import sympify from sympy.functions import Abs from sympy.simplify import simplify as _simplify from sympy.utilities.exceptions import SymPyDeprecationWarning from sympy.utilities.iterables import flatten from sympy.utilities.misc import filldedent class MatrixError(Exception): pass class ShapeError(ValueError, MatrixError): """Wrong matrix shape""" pass class NonSquareMatrixError(ShapeError): pass class MatrixRequired(object): """All subclasses of matrix objects must implement the required matrix properties listed here.""" rows = None cols = None shape = None _simplify = None @classmethod def _new(cls, *args, **kwargs): """`_new` must, at minimum, be callable as `_new(rows, cols, mat) where mat is a flat list of the elements of the matrix.""" raise NotImplementedError("Subclasses must implement this.") def __eq__(self, other): raise NotImplementedError("Subclasses must implement this.") def __getitem__(self, key): """Implementations of __getitem__ should accept ints, in which case the matrix is indexed as a flat list, tuples (i,j) in which case the (i,j) entry is returned, slices, or mixed tuples (a,b) where a and b are any combintion of slices and integers.""" raise NotImplementedError("Subclasses must implement this.") def __len__(self): """The total number of entries in the matrix.""" raise NotImplementedError("Subclasses must implement this.") class MatrixShaping(MatrixRequired): """Provides basic matrix shaping and extracting of submatrices""" def _eval_col_del(self, col): def entry(i, j): return self[i, j] if j < col else self[i, j + 1] return self._new(self.rows, self.cols - 1, entry) def _eval_col_insert(self, pos, other): cols = self.cols def entry(i, j): if j < pos: return self[i, j] elif pos <= j < pos + other.cols: return other[i, j - pos] return self[i, j - other.cols] return self._new(self.rows, self.cols + other.cols, lambda i, j: entry(i, j)) def _eval_col_join(self, other): rows = self.rows def entry(i, j): if i < rows: return self[i, j] return other[i - rows, j] return classof(self, other)._new(self.rows + other.rows, self.cols, lambda i, j: entry(i, j)) def _eval_extract(self, rowsList, colsList): mat = list(self) cols = self.cols indices = (i * cols + j for i in rowsList for j in colsList) return self._new(len(rowsList), len(colsList), list(mat[i] for i in indices)) def _eval_get_diag_blocks(self): sub_blocks = [] def recurse_sub_blocks(M): i = 1 while i <= M.shape[0]: if i == 1: to_the_right = M[0, i:] to_the_bottom = M[i:, 0] else: to_the_right = M[:i, i:] to_the_bottom = M[i:, :i] if any(to_the_right) or any(to_the_bottom): i += 1 continue else: sub_blocks.append(M[:i, :i]) if M.shape == M[:i, :i].shape: return else: recurse_sub_blocks(M[i:, i:]) return recurse_sub_blocks(self) return sub_blocks def _eval_row_del(self, row): def entry(i, j): return self[i, j] if i < row else self[i + 1, j] return self._new(self.rows - 1, self.cols, entry) def _eval_row_insert(self, pos, other): entries = list(self) insert_pos = pos * self.cols entries[insert_pos:insert_pos] = list(other) return self._new(self.rows + other.rows, self.cols, entries) def _eval_row_join(self, other): cols = self.cols def entry(i, j): if j < cols: return self[i, j] return other[i, j - cols] return classof(self, other)._new(self.rows, self.cols + other.cols, lambda i, j: entry(i, j)) def _eval_tolist(self): return [list(self[i,:]) for i in range(self.rows)] def _eval_vec(self): rows = self.rows def entry(n, _): # we want to read off the columns first j = n // rows i = n - j * rows return self[i, j] return self._new(len(self), 1, entry) def col_del(self, col): """Delete the specified column.""" if col < 0: col += self.cols if not 0 <= col < self.cols: raise ValueError("Column {} out of range.".format(col)) return self._eval_col_del(col) def col_insert(self, pos, other): """Insert one or more columns at the given column position. Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(3, 1) >>> M.col_insert(1, V) Matrix([ [0, 1, 0, 0], [0, 1, 0, 0], [0, 1, 0, 0]]) See Also ======== col row_insert """ # Allows you to build a matrix even if it is null matrix if not self: return type(self)(other) pos = as_int(pos) if pos < 0: pos = self.cols + pos if pos < 0: pos = 0 elif pos > self.cols: pos = self.cols if self.rows != other.rows: raise ShapeError( "`self` and `other` must have the same number of rows.") return self._eval_col_insert(pos, other) def col_join(self, other): """Concatenates two matrices along self's last and other's first row. Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(1, 3) >>> M.col_join(V) Matrix([ [0, 0, 0], [0, 0, 0], [0, 0, 0], [1, 1, 1]]) See Also ======== col row_join """ # A null matrix can always be stacked (see #10770) if self.rows == 0 and self.cols != other.cols: return self._new(0, other.cols, []).col_join(other) if self.cols != other.cols: raise ShapeError( "`self` and `other` must have the same number of columns.") return self._eval_col_join(other) def col(self, j): """Elementary column selector. Examples ======== >>> from sympy import eye >>> eye(2).col(0) Matrix([ [1], [0]]) See Also ======== row col_op col_swap col_del col_join col_insert """ return self[:, j] def extract(self, rowsList, colsList): """Return a submatrix by specifying a list of rows and columns. Negative indices can be given. All indices must be in the range -n <= i < n where n is the number of rows or columns. Examples ======== >>> from sympy import Matrix >>> m = Matrix(4, 3, range(12)) >>> m Matrix([ [0, 1, 2], [3, 4, 5], [6, 7, 8], [9, 10, 11]]) >>> m.extract([0, 1, 3], [0, 1]) Matrix([ [0, 1], [3, 4], [9, 10]]) Rows or columns can be repeated: >>> m.extract([0, 0, 1], [-1]) Matrix([ [2], [2], [5]]) Every other row can be taken by using range to provide the indices: >>> m.extract(range(0, m.rows, 2), [-1]) Matrix([ [2], [8]]) RowsList or colsList can also be a list of booleans, in which case the rows or columns corresponding to the True values will be selected: >>> m.extract([0, 1, 2, 3], [True, False, True]) Matrix([ [0, 2], [3, 5], [6, 8], [9, 11]]) """ if not is_sequence(rowsList) or not is_sequence(colsList): raise TypeError("rowsList and colsList must be iterable") # ensure rowsList and colsList are lists of integers if rowsList and all(isinstance(i, bool) for i in rowsList): rowsList = [index for index, item in enumerate(rowsList) if item] if colsList and all(isinstance(i, bool) for i in colsList): colsList = [index for index, item in enumerate(colsList) if item] # ensure everything is in range rowsList = [a2idx(k, self.rows) for k in rowsList] colsList = [a2idx(k, self.cols) for k in colsList] return self._eval_extract(rowsList, colsList) def get_diag_blocks(self): """Obtains the square sub-matrices on the main diagonal of a square matrix. Useful for inverting symbolic matrices or solving systems of linear equations which may be decoupled by having a block diagonal structure. Examples ======== >>> from sympy import Matrix >>> from sympy.abc import x, y, z >>> A = Matrix([[1, 3, 0, 0], [y, z*z, 0, 0], [0, 0, x, 0], [0, 0, 0, 0]]) >>> a1, a2, a3 = A.get_diag_blocks() >>> a1 Matrix([ [1, 3], [y, z**2]]) >>> a2 Matrix([[x]]) >>> a3 Matrix([[0]]) """ return self._eval_get_diag_blocks() @classmethod def hstack(cls, *args): """Return a matrix formed by joining args horizontally (i.e. by repeated application of row_join). Examples ======== >>> from sympy.matrices import Matrix, eye >>> Matrix.hstack(eye(2), 2*eye(2)) Matrix([ [1, 0, 2, 0], [0, 1, 0, 2]]) """ if len(args) == 0: return cls._new() kls = type(args[0]) return reduce(kls.row_join, args) def reshape(self, rows, cols): """Reshape the matrix. Total number of elements must remain the same. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 3, lambda i, j: 1) >>> m Matrix([ [1, 1, 1], [1, 1, 1]]) >>> m.reshape(1, 6) Matrix([[1, 1, 1, 1, 1, 1]]) >>> m.reshape(3, 2) Matrix([ [1, 1], [1, 1], [1, 1]]) """ if self.rows * self.cols != rows * cols: raise ValueError("Invalid reshape parameters %d %d" % (rows, cols)) return self._new(rows, cols, lambda i, j: self[i * cols + j]) def row_del(self, row): """Delete the specified row.""" if row < 0: row += self.rows if not 0 <= row < self.rows: raise ValueError("Row {} out of range.".format(row)) return self._eval_row_del(row) def row_insert(self, pos, other): """Insert one or more rows at the given row position. Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(1, 3) >>> M.row_insert(1, V) Matrix([ [0, 0, 0], [1, 1, 1], [0, 0, 0], [0, 0, 0]]) See Also ======== row col_insert """ # Allows you to build a matrix even if it is null matrix if not self: return self._new(other) pos = as_int(pos) if pos < 0: pos = self.rows + pos if pos < 0: pos = 0 elif pos > self.rows: pos = self.rows if self.cols != other.cols: raise ShapeError( "`self` and `other` must have the same number of columns.") return self._eval_row_insert(pos, other) def row_join(self, other): """Concatenates two matrices along self's last and rhs's first column Examples ======== >>> from sympy import zeros, ones >>> M = zeros(3) >>> V = ones(3, 1) >>> M.row_join(V) Matrix([ [0, 0, 0, 1], [0, 0, 0, 1], [0, 0, 0, 1]]) See Also ======== row col_join """ # A null matrix can always be stacked (see #10770) if self.cols == 0 and self.rows != other.rows: return self._new(other.rows, 0, []).row_join(other) if self.rows != other.rows: raise ShapeError( "`self` and `rhs` must have the same number of rows.") return self._eval_row_join(other) def diagonal(self, k=0): """Returns the kth diagonal of self. The main diagonal corresponds to `k=0`; diagonals above and below correspond to `k > 0` and `k < 0`, respectively. The values of `self[i, j]` for which `j - i = k`, are returned in order of increasing `i + j`, starting with `i + j = |k|`. Examples ======== >>> from sympy import Matrix, SparseMatrix >>> m = Matrix(3, 3, lambda i, j: j - i); m Matrix([ [ 0, 1, 2], [-1, 0, 1], [-2, -1, 0]]) >>> _.diagonal() Matrix([[0, 0, 0]]) >>> m.diagonal(1) Matrix([[1, 1]]) >>> m.diagonal(-2) Matrix([[-2]]) Even though the diagonal is returned as a Matrix, the element retrieval can be done with a single index: >>> Matrix.diag(1, 2, 3).diagonal()[1] # instead of [0, 1] 2 See Also ======== diag - to create a diagonal matrix """ rv = [] k = as_int(k) r = 0 if k > 0 else -k c = 0 if r else k while True: if r == self.rows or c == self.cols: break rv.append(self[r, c]) r += 1 c += 1 if not rv: raise ValueError(filldedent(''' The %s diagonal is out of range [%s, %s]''' % ( k, 1 - self.rows, self.cols - 1))) return self._new(1, len(rv), rv) def row(self, i): """Elementary row selector. Examples ======== >>> from sympy import eye >>> eye(2).row(0) Matrix([[1, 0]]) See Also ======== col row_op row_swap row_del row_join row_insert """ return self[i, :] @property def shape(self): """The shape (dimensions) of the matrix as the 2-tuple (rows, cols). Examples ======== >>> from sympy.matrices import zeros >>> M = zeros(2, 3) >>> M.shape (2, 3) >>> M.rows 2 >>> M.cols 3 """ return (self.rows, self.cols) def tolist(self): """Return the Matrix as a nested Python list. Examples ======== >>> from sympy import Matrix, ones >>> m = Matrix(3, 3, range(9)) >>> m Matrix([ [0, 1, 2], [3, 4, 5], [6, 7, 8]]) >>> m.tolist() [[0, 1, 2], [3, 4, 5], [6, 7, 8]] >>> ones(3, 0).tolist() [[], [], []] When there are no rows then it will not be possible to tell how many columns were in the original matrix: >>> ones(0, 3).tolist() [] """ if not self.rows: return [] if not self.cols: return [[] for i in range(self.rows)] return self._eval_tolist() def vec(self): """Return the Matrix converted into a one column matrix by stacking columns Examples ======== >>> from sympy import Matrix >>> m=Matrix([[1, 3], [2, 4]]) >>> m Matrix([ [1, 3], [2, 4]]) >>> m.vec() Matrix([ [1], [2], [3], [4]]) See Also ======== vech """ return self._eval_vec() @classmethod def vstack(cls, *args): """Return a matrix formed by joining args vertically (i.e. by repeated application of col_join). Examples ======== >>> from sympy.matrices import Matrix, eye >>> Matrix.vstack(eye(2), 2*eye(2)) Matrix([ [1, 0], [0, 1], [2, 0], [0, 2]]) """ if len(args) == 0: return cls._new() kls = type(args[0]) return reduce(kls.col_join, args) class MatrixSpecial(MatrixRequired): """Construction of special matrices""" @classmethod def _eval_diag(cls, rows, cols, diag_dict): """diag_dict is a defaultdict containing all the entries of the diagonal matrix.""" def entry(i, j): return diag_dict[(i, j)] return cls._new(rows, cols, entry) @classmethod def _eval_eye(cls, rows, cols): def entry(i, j): return S.One if i == j else S.Zero return cls._new(rows, cols, entry) @classmethod def _eval_jordan_block(cls, rows, cols, eigenvalue, band='upper'): if band == 'lower': def entry(i, j): if i == j: return eigenvalue elif j + 1 == i: return S.One return S.Zero else: def entry(i, j): if i == j: return eigenvalue elif i + 1 == j: return S.One return S.Zero return cls._new(rows, cols, entry) @classmethod def _eval_ones(cls, rows, cols): def entry(i, j): return S.One return cls._new(rows, cols, entry) @classmethod def _eval_zeros(cls, rows, cols): def entry(i, j): return S.Zero return cls._new(rows, cols, entry) @classmethod def diag(kls, *args, **kwargs): """Returns a matrix with the specified diagonal. If matrices are passed, a block-diagonal matrix is created (i.e. the "direct sum" of the matrices). kwargs ====== rows : rows of the resulting matrix; computed if not given. cols : columns of the resulting matrix; computed if not given. cls : class for the resulting matrix unpack : bool which, when True (default), unpacks a single sequence rather than interpreting it as a Matrix. strict : bool which, when False (default), allows Matrices to have variable-length rows. Examples ======== >>> from sympy.matrices import Matrix >>> Matrix.diag(1, 2, 3) Matrix([ [1, 0, 0], [0, 2, 0], [0, 0, 3]]) The current default is to unpack a single sequence. If this is not desired, set `unpack=False` and it will be interpreted as a matrix. >>> Matrix.diag([1, 2, 3]) == Matrix.diag(1, 2, 3) True When more than one element is passed, each is interpreted as something to put on the diagonal. Lists are converted to matricecs. Filling of the diagonal always continues from the bottom right hand corner of the previous item: this will create a block-diagonal matrix whether the matrices are square or not. >>> col = [1, 2, 3] >>> row = [[4, 5]] >>> Matrix.diag(col, row) Matrix([ [1, 0, 0], [2, 0, 0], [3, 0, 0], [0, 4, 5]]) When `unpack` is False, elements within a list need not all be of the same length. Setting `strict` to True would raise a ValueError for the following: >>> Matrix.diag([[1, 2, 3], [4, 5], [6]], unpack=False) Matrix([ [1, 2, 3], [4, 5, 0], [6, 0, 0]]) The type of the returned matrix can be set with the ``cls`` keyword. >>> from sympy.matrices import ImmutableMatrix >>> from sympy.utilities.misc import func_name >>> func_name(Matrix.diag(1, cls=ImmutableMatrix)) 'ImmutableDenseMatrix' A zero dimension matrix can be used to position the start of the filling at the start of an arbitrary row or column: >>> from sympy import ones >>> r2 = ones(0, 2) >>> Matrix.diag(r2, 1, 2) Matrix([ [0, 0, 1, 0], [0, 0, 0, 2]]) See Also ======== eye diagonal - to extract a diagonal .dense.diag .expressions.blockmatrix.BlockMatrix """ from sympy.matrices.matrices import MatrixBase from sympy.matrices.dense import Matrix from sympy.matrices.sparse import SparseMatrix klass = kwargs.get('cls', kls) strict = kwargs.get('strict', False) # lists -> Matrices unpack = kwargs.get('unpack', True) # unpack single sequence if unpack and len(args) == 1 and is_sequence(args[0]) and \ not isinstance(args[0], MatrixBase): args = args[0] # fill a default dict with the diagonal entries diag_entries = defaultdict(int) rmax = cmax = 0 # keep track of the biggest index seen for m in args: if isinstance(m, list): if strict: # if malformed, Matrix will raise an error _ = Matrix(m) r, c = _.shape m = _.tolist() else: m = SparseMatrix(m) for (i, j), _ in m._smat.items(): diag_entries[(i + rmax, j + cmax)] = _ r, c = m.shape m = [] # to skip process below elif hasattr(m, 'shape'): # a Matrix # convert to list of lists r, c = m.shape m = m.tolist() else: # in this case, we're a single value diag_entries[(rmax, cmax)] = m rmax += 1 cmax += 1 continue # process list of lists for i in range(len(m)): for j, _ in enumerate(m[i]): diag_entries[(i + rmax, j + cmax)] = _ rmax += r cmax += c rows = kwargs.get('rows', None) cols = kwargs.get('cols', None) if rows is None: rows, cols = cols, rows if rows is None: rows, cols = rmax, cmax else: cols = rows if cols is None else cols if rows < rmax or cols < cmax: raise ValueError(filldedent(''' The constructed matrix is {} x {} but a size of {} x {} was specified.'''.format(rmax, cmax, rows, cols))) return klass._eval_diag(rows, cols, diag_entries) @classmethod def eye(kls, rows, cols=None, **kwargs): """Returns an identity matrix. Args ==== rows : rows of the matrix cols : cols of the matrix (if None, cols=rows) kwargs ====== cls : class of the returned matrix """ if cols is None: cols = rows klass = kwargs.get('cls', kls) rows, cols = as_int(rows), as_int(cols) return klass._eval_eye(rows, cols) @classmethod def jordan_block(kls, size=None, eigenvalue=None, **kwargs): """Returns a Jordan block Parameters ========== size : Integer, optional Specifies the shape of the Jordan block matrix. eigenvalue : Number or Symbol Specifies the value for the main diagonal of the matrix. .. note:: The keyword ``eigenval`` is also specified as an alias of this keyword, but it is not recommended to use. We may deprecate the alias in later release. band : 'upper' or 'lower', optional Specifies the position of the off-diagonal to put `1` s on. cls : Matrix, optional Specifies the matrix class of the output form. If it is not specified, the class type where the method is being executed on will be returned. rows, cols : Integer, optional Specifies the shape of the Jordan block matrix. See Notes section for the details of how these key works. .. note:: This feature will be deprecated in the future. Returns ======= Matrix A Jordan block matrix. Raises ====== ValueError If insufficient arguments are given for matrix size specification, or no eigenvalue is given. Examples ======== Creating a default Jordan block: >>> from sympy import Matrix >>> from sympy.abc import x >>> Matrix.jordan_block(4, x) Matrix([ [x, 1, 0, 0], [0, x, 1, 0], [0, 0, x, 1], [0, 0, 0, x]]) Creating an alternative Jordan block matrix where `1` is on lower off-diagonal: >>> Matrix.jordan_block(4, x, band='lower') Matrix([ [x, 0, 0, 0], [1, x, 0, 0], [0, 1, x, 0], [0, 0, 1, x]]) Creating a Jordan block with keyword arguments >>> Matrix.jordan_block(size=4, eigenvalue=x) Matrix([ [x, 1, 0, 0], [0, x, 1, 0], [0, 0, x, 1], [0, 0, 0, x]]) Notes ===== .. note:: This feature will be deprecated in the future. The keyword arguments ``size``, ``rows``, ``cols`` relates to the Jordan block size specifications. If you want to create a square Jordan block, specify either one of the three arguments. If you want to create a rectangular Jordan block, specify ``rows`` and ``cols`` individually. +--------------------------------+---------------------+ | Arguments Given | Matrix Shape | +----------+----------+----------+----------+----------+ | size | rows | cols | rows | cols | +==========+==========+==========+==========+==========+ | size | Any | size | size | +----------+----------+----------+----------+----------+ | | None | ValueError | | +----------+----------+----------+----------+ | None | rows | None | rows | rows | | +----------+----------+----------+----------+ | | None | cols | cols | cols | + +----------+----------+----------+----------+ | | rows | cols | rows | cols | +----------+----------+----------+----------+----------+ References ========== .. [1] https://en.wikipedia.org/wiki/Jordan_matrix """ if 'rows' in kwargs or 'cols' in kwargs: SymPyDeprecationWarning( feature="Keyword arguments 'rows' or 'cols'", issue=16102, useinstead="a more generic banded matrix constructor", deprecated_since_version="1.4" ).warn() klass = kwargs.pop('cls', kls) band = kwargs.pop('band', 'upper') rows = kwargs.pop('rows', None) cols = kwargs.pop('cols', None) eigenval = kwargs.get('eigenval', None) if eigenvalue is None and eigenval is None: raise ValueError("Must supply an eigenvalue") elif eigenvalue != eigenval and None not in (eigenval, eigenvalue): raise ValueError( "Inconsistent values are given: 'eigenval'={}, " "'eigenvalue'={}".format(eigenval, eigenvalue)) else: if eigenval is not None: eigenvalue = eigenval if (size, rows, cols) == (None, None, None): raise ValueError("Must supply a matrix size") if size is not None: rows, cols = size, size elif rows is not None and cols is None: cols = rows elif cols is not None and rows is None: rows = cols rows, cols = as_int(rows), as_int(cols) return klass._eval_jordan_block(rows, cols, eigenvalue, band) @classmethod def ones(kls, rows, cols=None, **kwargs): """Returns a matrix of ones. Args ==== rows : rows of the matrix cols : cols of the matrix (if None, cols=rows) kwargs ====== cls : class of the returned matrix """ if cols is None: cols = rows klass = kwargs.get('cls', kls) rows, cols = as_int(rows), as_int(cols) return klass._eval_ones(rows, cols) @classmethod def zeros(kls, rows, cols=None, **kwargs): """Returns a matrix of zeros. Args ==== rows : rows of the matrix cols : cols of the matrix (if None, cols=rows) kwargs ====== cls : class of the returned matrix """ if cols is None: cols = rows klass = kwargs.get('cls', kls) rows, cols = as_int(rows), as_int(cols) return klass._eval_zeros(rows, cols) class MatrixProperties(MatrixRequired): """Provides basic properties of a matrix.""" def _eval_atoms(self, *types): result = set() for i in self: result.update(i.atoms(*types)) return result def _eval_free_symbols(self): return set().union(*(i.free_symbols for i in self)) def _eval_has(self, *patterns): return any(a.has(*patterns) for a in self) def _eval_is_anti_symmetric(self, simpfunc): if not all(simpfunc(self[i, j] + self[j, i]).is_zero for i in range(self.rows) for j in range(self.cols)): return False return True def _eval_is_diagonal(self): for i in range(self.rows): for j in range(self.cols): if i != j and self[i, j]: return False return True # _eval_is_hermitian is called by some general sympy # routines and has a different *args signature. Make # sure the names don't clash by adding `_matrix_` in name. def _eval_is_matrix_hermitian(self, simpfunc): mat = self._new(self.rows, self.cols, lambda i, j: simpfunc(self[i, j] - self[j, i].conjugate())) return mat.is_zero def _eval_is_Identity(self): def dirac(i, j): if i == j: return 1 return 0 return all(self[i, j] == dirac(i, j) for i in range(self.rows) for j in range(self.cols)) def _eval_is_lower_hessenberg(self): return all(self[i, j].is_zero for i in range(self.rows) for j in range(i + 2, self.cols)) def _eval_is_lower(self): return all(self[i, j].is_zero for i in range(self.rows) for j in range(i + 1, self.cols)) def _eval_is_symbolic(self): return self.has(Symbol) def _eval_is_symmetric(self, simpfunc): mat = self._new(self.rows, self.cols, lambda i, j: simpfunc(self[i, j] - self[j, i])) return mat.is_zero def _eval_is_zero(self): if any(i.is_zero == False for i in self): return False if any(i.is_zero is None for i in self): return None return True def _eval_is_upper_hessenberg(self): return all(self[i, j].is_zero for i in range(2, self.rows) for j in range(min(self.cols, (i - 1)))) def _eval_values(self): return [i for i in self if not i.is_zero] def atoms(self, *types): """Returns the atoms that form the current object. Examples ======== >>> from sympy.abc import x, y >>> from sympy.matrices import Matrix >>> Matrix([[x]]) Matrix([[x]]) >>> _.atoms() {x} """ types = tuple(t if isinstance(t, type) else type(t) for t in types) if not types: types = (Atom,) return self._eval_atoms(*types) @property def free_symbols(self): """Returns the free symbols within the matrix. Examples ======== >>> from sympy.abc import x >>> from sympy.matrices import Matrix >>> Matrix([[x], [1]]).free_symbols {x} """ return self._eval_free_symbols() def has(self, *patterns): """Test whether any subexpression matches any of the patterns. Examples ======== >>> from sympy import Matrix, SparseMatrix, Float >>> from sympy.abc import x, y >>> A = Matrix(((1, x), (0.2, 3))) >>> B = SparseMatrix(((1, x), (0.2, 3))) >>> A.has(x) True >>> A.has(y) False >>> A.has(Float) True >>> B.has(x) True >>> B.has(y) False >>> B.has(Float) True """ return self._eval_has(*patterns) def is_anti_symmetric(self, simplify=True): """Check if matrix M is an antisymmetric matrix, that is, M is a square matrix with all M[i, j] == -M[j, i]. When ``simplify=True`` (default), the sum M[i, j] + M[j, i] is simplified before testing to see if it is zero. By default, the SymPy simplify function is used. To use a custom function set simplify to a function that accepts a single argument which returns a simplified expression. To skip simplification, set simplify to False but note that although this will be faster, it may induce false negatives. Examples ======== >>> from sympy import Matrix, symbols >>> m = Matrix(2, 2, [0, 1, -1, 0]) >>> m Matrix([ [ 0, 1], [-1, 0]]) >>> m.is_anti_symmetric() True >>> x, y = symbols('x y') >>> m = Matrix(2, 3, [0, 0, x, -y, 0, 0]) >>> m Matrix([ [ 0, 0, x], [-y, 0, 0]]) >>> m.is_anti_symmetric() False >>> from sympy.abc import x, y >>> m = Matrix(3, 3, [0, x**2 + 2*x + 1, y, ... -(x + 1)**2 , 0, x*y, ... -y, -x*y, 0]) Simplification of matrix elements is done by default so even though two elements which should be equal and opposite wouldn't pass an equality test, the matrix is still reported as anti-symmetric: >>> m[0, 1] == -m[1, 0] False >>> m.is_anti_symmetric() True If 'simplify=False' is used for the case when a Matrix is already simplified, this will speed things up. Here, we see that without simplification the matrix does not appear anti-symmetric: >>> m.is_anti_symmetric(simplify=False) False But if the matrix were already expanded, then it would appear anti-symmetric and simplification in the is_anti_symmetric routine is not needed: >>> m = m.expand() >>> m.is_anti_symmetric(simplify=False) True """ # accept custom simplification simpfunc = simplify if not isfunction(simplify): simpfunc = _simplify if simplify else lambda x: x if not self.is_square: return False return self._eval_is_anti_symmetric(simpfunc) def is_diagonal(self): """Check if matrix is diagonal, that is matrix in which the entries outside the main diagonal are all zero. Examples ======== >>> from sympy import Matrix, diag >>> m = Matrix(2, 2, [1, 0, 0, 2]) >>> m Matrix([ [1, 0], [0, 2]]) >>> m.is_diagonal() True >>> m = Matrix(2, 2, [1, 1, 0, 2]) >>> m Matrix([ [1, 1], [0, 2]]) >>> m.is_diagonal() False >>> m = diag(1, 2, 3) >>> m Matrix([ [1, 0, 0], [0, 2, 0], [0, 0, 3]]) >>> m.is_diagonal() True See Also ======== is_lower is_upper is_diagonalizable diagonalize """ return self._eval_is_diagonal() @property def is_hermitian(self, simplify=True): """Checks if the matrix is Hermitian. In a Hermitian matrix element i,j is the complex conjugate of element j,i. Examples ======== >>> from sympy.matrices import Matrix >>> from sympy import I >>> from sympy.abc import x >>> a = Matrix([[1, I], [-I, 1]]) >>> a Matrix([ [ 1, I], [-I, 1]]) >>> a.is_hermitian True >>> a[0, 0] = 2*I >>> a.is_hermitian False >>> a[0, 0] = x >>> a.is_hermitian >>> a[0, 1] = a[1, 0]*I >>> a.is_hermitian False """ if not self.is_square: return False simpfunc = simplify if not isfunction(simplify): simpfunc = _simplify if simplify else lambda x: x return self._eval_is_matrix_hermitian(simpfunc) @property def is_Identity(self): if not self.is_square: return False return self._eval_is_Identity() @property def is_lower_hessenberg(self): r"""Checks if the matrix is in the lower-Hessenberg form. The lower hessenberg matrix has zero entries above the first superdiagonal. Examples ======== >>> from sympy.matrices import Matrix >>> a = Matrix([[1, 2, 0, 0], [5, 2, 3, 0], [3, 4, 3, 7], [5, 6, 1, 1]]) >>> a Matrix([ [1, 2, 0, 0], [5, 2, 3, 0], [3, 4, 3, 7], [5, 6, 1, 1]]) >>> a.is_lower_hessenberg True See Also ======== is_upper_hessenberg is_lower """ return self._eval_is_lower_hessenberg() @property def is_lower(self): """Check if matrix is a lower triangular matrix. True can be returned even if the matrix is not square. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, [1, 0, 0, 1]) >>> m Matrix([ [1, 0], [0, 1]]) >>> m.is_lower True >>> m = Matrix(4, 3, [0, 0, 0, 2, 0, 0, 1, 4 , 0, 6, 6, 5]) >>> m Matrix([ [0, 0, 0], [2, 0, 0], [1, 4, 0], [6, 6, 5]]) >>> m.is_lower True >>> from sympy.abc import x, y >>> m = Matrix(2, 2, [x**2 + y, y**2 + x, 0, x + y]) >>> m Matrix([ [x**2 + y, x + y**2], [ 0, x + y]]) >>> m.is_lower False See Also ======== is_upper is_diagonal is_lower_hessenberg """ return self._eval_is_lower() @property def is_square(self): """Checks if a matrix is square. A matrix is square if the number of rows equals the number of columns. The empty matrix is square by definition, since the number of rows and the number of columns are both zero. Examples ======== >>> from sympy import Matrix >>> a = Matrix([[1, 2, 3], [4, 5, 6]]) >>> b = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) >>> c = Matrix([]) >>> a.is_square False >>> b.is_square True >>> c.is_square True """ return self.rows == self.cols def is_symbolic(self): """Checks if any elements contain Symbols. Examples ======== >>> from sympy.matrices import Matrix >>> from sympy.abc import x, y >>> M = Matrix([[x, y], [1, 0]]) >>> M.is_symbolic() True """ return self._eval_is_symbolic() def is_symmetric(self, simplify=True): """Check if matrix is symmetric matrix, that is square matrix and is equal to its transpose. By default, simplifications occur before testing symmetry. They can be skipped using 'simplify=False'; while speeding things a bit, this may however induce false negatives. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, [0, 1, 1, 2]) >>> m Matrix([ [0, 1], [1, 2]]) >>> m.is_symmetric() True >>> m = Matrix(2, 2, [0, 1, 2, 0]) >>> m Matrix([ [0, 1], [2, 0]]) >>> m.is_symmetric() False >>> m = Matrix(2, 3, [0, 0, 0, 0, 0, 0]) >>> m Matrix([ [0, 0, 0], [0, 0, 0]]) >>> m.is_symmetric() False >>> from sympy.abc import x, y >>> m = Matrix(3, 3, [1, x**2 + 2*x + 1, y, (x + 1)**2 , 2, 0, y, 0, 3]) >>> m Matrix([ [ 1, x**2 + 2*x + 1, y], [(x + 1)**2, 2, 0], [ y, 0, 3]]) >>> m.is_symmetric() True If the matrix is already simplified, you may speed-up is_symmetric() test by using 'simplify=False'. >>> bool(m.is_symmetric(simplify=False)) False >>> m1 = m.expand() >>> m1.is_symmetric(simplify=False) True """ simpfunc = simplify if not isfunction(simplify): simpfunc = _simplify if simplify else lambda x: x if not self.is_square: return False return self._eval_is_symmetric(simpfunc) @property def is_upper_hessenberg(self): """Checks if the matrix is the upper-Hessenberg form. The upper hessenberg matrix has zero entries below the first subdiagonal. Examples ======== >>> from sympy.matrices import Matrix >>> a = Matrix([[1, 4, 2, 3], [3, 4, 1, 7], [0, 2, 3, 4], [0, 0, 1, 3]]) >>> a Matrix([ [1, 4, 2, 3], [3, 4, 1, 7], [0, 2, 3, 4], [0, 0, 1, 3]]) >>> a.is_upper_hessenberg True See Also ======== is_lower_hessenberg is_upper """ return self._eval_is_upper_hessenberg() @property def is_upper(self): """Check if matrix is an upper triangular matrix. True can be returned even if the matrix is not square. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, [1, 0, 0, 1]) >>> m Matrix([ [1, 0], [0, 1]]) >>> m.is_upper True >>> m = Matrix(4, 3, [5, 1, 9, 0, 4 , 6, 0, 0, 5, 0, 0, 0]) >>> m Matrix([ [5, 1, 9], [0, 4, 6], [0, 0, 5], [0, 0, 0]]) >>> m.is_upper True >>> m = Matrix(2, 3, [4, 2, 5, 6, 1, 1]) >>> m Matrix([ [4, 2, 5], [6, 1, 1]]) >>> m.is_upper False See Also ======== is_lower is_diagonal is_upper_hessenberg """ return all(self[i, j].is_zero for i in range(1, self.rows) for j in range(min(i, self.cols))) @property def is_zero(self): """Checks if a matrix is a zero matrix. A matrix is zero if every element is zero. A matrix need not be square to be considered zero. The empty matrix is zero by the principle of vacuous truth. For a matrix that may or may not be zero (e.g. contains a symbol), this will be None Examples ======== >>> from sympy import Matrix, zeros >>> from sympy.abc import x >>> a = Matrix([[0, 0], [0, 0]]) >>> b = zeros(3, 4) >>> c = Matrix([[0, 1], [0, 0]]) >>> d = Matrix([]) >>> e = Matrix([[x, 0], [0, 0]]) >>> a.is_zero True >>> b.is_zero True >>> c.is_zero False >>> d.is_zero True >>> e.is_zero """ return self._eval_is_zero() def values(self): """Return non-zero values of self.""" return self._eval_values() class MatrixOperations(MatrixRequired): """Provides basic matrix shape and elementwise operations. Should not be instantiated directly.""" def _eval_adjoint(self): return self.transpose().conjugate() def _eval_applyfunc(self, f): out = self._new(self.rows, self.cols, [f(x) for x in self]) return out def _eval_as_real_imag(self): from sympy.functions.elementary.complexes import re, im return (self.applyfunc(re), self.applyfunc(im)) def _eval_conjugate(self): return self.applyfunc(lambda x: x.conjugate()) def _eval_permute_cols(self, perm): # apply the permutation to a list mapping = list(perm) def entry(i, j): return self[i, mapping[j]] return self._new(self.rows, self.cols, entry) def _eval_permute_rows(self, perm): # apply the permutation to a list mapping = list(perm) def entry(i, j): return self[mapping[i], j] return self._new(self.rows, self.cols, entry) def _eval_trace(self): return sum(self[i, i] for i in range(self.rows)) def _eval_transpose(self): return self._new(self.cols, self.rows, lambda i, j: self[j, i]) def adjoint(self): """Conjugate transpose or Hermitian conjugation.""" return self._eval_adjoint() def applyfunc(self, f): """Apply a function to each element of the matrix. Examples ======== >>> from sympy import Matrix >>> m = Matrix(2, 2, lambda i, j: i*2+j) >>> m Matrix([ [0, 1], [2, 3]]) >>> m.applyfunc(lambda i: 2*i) Matrix([ [0, 2], [4, 6]]) """ if not callable(f): raise TypeError("`f` must be callable.") return self._eval_applyfunc(f) def as_real_imag(self): """Returns a tuple containing the (real, imaginary) part of matrix.""" return self._eval_as_real_imag() def conjugate(self): """Return the by-element conjugation. Examples ======== >>> from sympy.matrices import SparseMatrix >>> from sympy import I >>> a = SparseMatrix(((1, 2 + I), (3, 4), (I, -I))) >>> a Matrix([ [1, 2 + I], [3, 4], [I, -I]]) >>> a.C Matrix([ [ 1, 2 - I], [ 3, 4], [-I, I]]) See Also ======== transpose: Matrix transposition H: Hermite conjugation D: Dirac conjugation """ return self._eval_conjugate() def doit(self, **kwargs): return self.applyfunc(lambda x: x.doit()) def evalf(self, prec=None, **options): """Apply evalf() to each element of self.""" return self.applyfunc(lambda i: i.evalf(prec, **options)) def expand(self, deep=True, modulus=None, power_base=True, power_exp=True, mul=True, log=True, multinomial=True, basic=True, **hints): """Apply core.function.expand to each entry of the matrix. Examples ======== >>> from sympy.abc import x >>> from sympy.matrices import Matrix >>> Matrix(1, 1, [x*(x+1)]) Matrix([[x*(x + 1)]]) >>> _.expand() Matrix([[x**2 + x]]) """ return self.applyfunc(lambda x: x.expand( deep, modulus, power_base, power_exp, mul, log, multinomial, basic, **hints)) @property def H(self): """Return Hermite conjugate. Examples ======== >>> from sympy import Matrix, I >>> m = Matrix((0, 1 + I, 2, 3)) >>> m Matrix([ [ 0], [1 + I], [ 2], [ 3]]) >>> m.H Matrix([[0, 1 - I, 2, 3]]) See Also ======== conjugate: By-element conjugation D: Dirac conjugation """ return self.T.C def permute(self, perm, orientation='rows', direction='forward'): """Permute the rows or columns of a matrix by the given list of swaps. Parameters ========== perm : a permutation. This may be a list swaps (e.g., `[[1, 2], [0, 3]]`), or any valid input to the `Permutation` constructor, including a `Permutation()` itself. If `perm` is given explicitly as a list of indices or a `Permutation`, `direction` has no effect. orientation : ('rows' or 'cols') whether to permute the rows or the columns direction : ('forward', 'backward') whether to apply the permutations from the start of the list first, or from the back of the list first Examples ======== >>> from sympy.matrices import eye >>> M = eye(3) >>> M.permute([[0, 1], [0, 2]], orientation='rows', direction='forward') Matrix([ [0, 0, 1], [1, 0, 0], [0, 1, 0]]) >>> from sympy.matrices import eye >>> M = eye(3) >>> M.permute([[0, 1], [0, 2]], orientation='rows', direction='backward') Matrix([ [0, 1, 0], [0, 0, 1], [1, 0, 0]]) """ # allow british variants and `columns` if direction == 'forwards': direction = 'forward' if direction == 'backwards': direction = 'backward' if orientation == 'columns': orientation = 'cols' if direction not in ('forward', 'backward'): raise TypeError("direction='{}' is an invalid kwarg. " "Try 'forward' or 'backward'".format(direction)) if orientation not in ('rows', 'cols'): raise TypeError("orientation='{}' is an invalid kwarg. " "Try 'rows' or 'cols'".format(orientation)) # ensure all swaps are in range max_index = self.rows if orientation == 'rows' else self.cols if not all(0 <= t <= max_index for t in flatten(list(perm))): raise IndexError("`swap` indices out of range.") # see if we are a list of pairs try: assert len(perm[0]) == 2 # we are a list of swaps, so `direction` matters if direction == 'backward': perm = reversed(perm) # since Permutation doesn't let us have non-disjoint cycles, # we'll construct the explicit mapping ourselves XXX Bug #12479 mapping = list(range(max_index)) for (i, j) in perm: mapping[i], mapping[j] = mapping[j], mapping[i] perm = mapping except (TypeError, AssertionError, IndexError): pass from sympy.combinatorics import Permutation perm = Permutation(perm, size=max_index) if orientation == 'rows': return self._eval_permute_rows(perm) if orientation == 'cols': return self._eval_permute_cols(perm) def permute_cols(self, swaps, direction='forward'): """Alias for `self.permute(swaps, orientation='cols', direction=direction)` See Also ======== permute """ return self.permute(swaps, orientation='cols', direction=direction) def permute_rows(self, swaps, direction='forward'): """Alias for `self.permute(swaps, orientation='rows', direction=direction)` See Also ======== permute """ return self.permute(swaps, orientation='rows', direction=direction) def refine(self, assumptions=True): """Apply refine to each element of the matrix. Examples ======== >>> from sympy import Symbol, Matrix, Abs, sqrt, Q >>> x = Symbol('x') >>> Matrix([[Abs(x)**2, sqrt(x**2)],[sqrt(x**2), Abs(x)**2]]) Matrix([ [ Abs(x)**2, sqrt(x**2)], [sqrt(x**2), Abs(x)**2]]) >>> _.refine(Q.real(x)) Matrix([ [ x**2, Abs(x)], [Abs(x), x**2]]) """ return self.applyfunc(lambda x: refine(x, assumptions)) def replace(self, F, G, map=False): """Replaces Function F in Matrix entries with Function G. Examples ======== >>> from sympy import symbols, Function, Matrix >>> F, G = symbols('F, G', cls=Function) >>> M = Matrix(2, 2, lambda i, j: F(i+j)) ; M Matrix([ [F(0), F(1)], [F(1), F(2)]]) >>> N = M.replace(F,G) >>> N Matrix([ [G(0), G(1)], [G(1), G(2)]]) """ return self.applyfunc(lambda x: x.replace(F, G, map)) def simplify(self, ratio=1.7, measure=count_ops, rational=False, inverse=False): """Apply simplify to each element of the matrix. Examples ======== >>> from sympy.abc import x, y >>> from sympy import sin, cos >>> from sympy.matrices import SparseMatrix >>> SparseMatrix(1, 1, [x*sin(y)**2 + x*cos(y)**2]) Matrix([[x*sin(y)**2 + x*cos(y)**2]]) >>> _.simplify() Matrix([[x]]) """ return self.applyfunc(lambda x: x.simplify(ratio=ratio, measure=measure, rational=rational, inverse=inverse)) def subs(self, *args, **kwargs): # should mirror core.basic.subs """Return a new matrix with subs applied to each entry. Examples ======== >>> from sympy.abc import x, y >>> from sympy.matrices import SparseMatrix, Matrix >>> SparseMatrix(1, 1, [x]) Matrix([[x]]) >>> _.subs(x, y) Matrix([[y]]) >>> Matrix(_).subs(y, x) Matrix([[x]]) """ return self.applyfunc(lambda x: x.subs(*args, **kwargs)) def trace(self): """ Returns the trace of a square matrix i.e. the sum of the diagonal elements. Examples ======== >>> from sympy import Matrix >>> A = Matrix(2, 2, [1, 2, 3, 4]) >>> A.trace() 5 """ if self.rows != self.cols: raise NonSquareMatrixError() return self._eval_trace() def transpose(self): """ Returns the transpose of the matrix. Examples ======== >>> from sympy import Matrix >>> A = Matrix(2, 2, [1, 2, 3, 4]) >>> A.transpose() Matrix([ [1, 3], [2, 4]]) >>> from sympy import Matrix, I >>> m=Matrix(((1, 2+I), (3, 4))) >>> m Matrix([ [1, 2 + I], [3, 4]]) >>> m.transpose() Matrix([ [ 1, 3], [2 + I, 4]]) >>> m.T == m.transpose() True See Also ======== conjugate: By-element conjugation """ return self._eval_transpose() T = property(transpose, None, None, "Matrix transposition.") C = property(conjugate, None, None, "By-element conjugation.") n = evalf def xreplace(self, rule): # should mirror core.basic.xreplace """Return a new matrix with xreplace applied to each entry. Examples ======== >>> from sympy.abc import x, y >>> from sympy.matrices import SparseMatrix, Matrix >>> SparseMatrix(1, 1, [x]) Matrix([[x]]) >>> _.xreplace({x: y}) Matrix([[y]]) >>> Matrix(_).xreplace({y: x}) Matrix([[x]]) """ return self.applyfunc(lambda x: x.xreplace(rule)) _eval_simplify = simplify def _eval_trigsimp(self, **opts): from sympy.simplify import trigsimp return self.applyfunc(lambda x: trigsimp(x, **opts)) class MatrixArithmetic(MatrixRequired): """Provides basic matrix arithmetic operations. Should not be instantiated directly.""" _op_priority = 10.01 def _eval_Abs(self): return self._new(self.rows, self.cols, lambda i, j: Abs(self[i, j])) def _eval_add(self, other): return self._new(self.rows, self.cols, lambda i, j: self[i, j] + other[i, j]) def _eval_matrix_mul(self, other): def entry(i, j): try: return sum(self[i,k]*other[k,j] for k in range(self.cols)) except TypeError: # Block matrices don't work with `sum` or `Add` (ISSUE #11599) # They don't work with `sum` because `sum` tries to add `0` # initially, and for a matrix, that is a mix of a scalar and # a matrix, which raises a TypeError. Fall back to a # block-matrix-safe way to multiply if the `sum` fails. ret = self[i, 0]*other[0, j] for k in range(1, self.cols): ret += self[i, k]*other[k, j] return ret return self._new(self.rows, other.cols, entry) def _eval_matrix_mul_elementwise(self, other): return self._new(self.rows, self.cols, lambda i, j: self[i,j]*other[i,j]) def _eval_matrix_rmul(self, other): def entry(i, j): return sum(other[i,k]*self[k,j] for k in range(other.cols)) return self._new(other.rows, self.cols, entry) def _eval_pow_by_recursion(self, num): if num == 1: return self if num % 2 == 1: return self * self._eval_pow_by_recursion(num - 1) ret = self._eval_pow_by_recursion(num // 2) return ret * ret def _eval_scalar_mul(self, other): return self._new(self.rows, self.cols, lambda i, j: self[i,j]*other) def _eval_scalar_rmul(self, other): return self._new(self.rows, self.cols, lambda i, j: other*self[i,j]) def _eval_Mod(self, other): from sympy import Mod return self._new(self.rows, self.cols, lambda i, j: Mod(self[i, j], other)) # python arithmetic functions def __abs__(self): """Returns a new matrix with entry-wise absolute values.""" return self._eval_Abs() @call_highest_priority('__radd__') def __add__(self, other): """Return self + other, raising ShapeError if shapes don't match.""" other = _matrixify(other) # matrix-like objects can have shapes. This is # our first sanity check. if hasattr(other, 'shape'): if self.shape != other.shape: raise ShapeError("Matrix size mismatch: %s + %s" % ( self.shape, other.shape)) # honest sympy matrices defer to their class's routine if getattr(other, 'is_Matrix', False): # call the highest-priority class's _eval_add a, b = self, other if a.__class__ != classof(a, b): b, a = a, b return a._eval_add(b) # Matrix-like objects can be passed to CommonMatrix routines directly. if getattr(other, 'is_MatrixLike', False): return MatrixArithmetic._eval_add(self, other) raise TypeError('cannot add %s and %s' % (type(self), type(other))) @call_highest_priority('__rdiv__') def __div__(self, other): return self * (S.One / other) @call_highest_priority('__rmatmul__') def __matmul__(self, other): other = _matrixify(other) if not getattr(other, 'is_Matrix', False) and not getattr(other, 'is_MatrixLike', False): return NotImplemented return self.__mul__(other) def __mod__(self, other): return self.applyfunc(lambda x: x % other) @call_highest_priority('__rmul__') def __mul__(self, other): """Return self*other where other is either a scalar or a matrix of compatible dimensions. Examples ======== >>> from sympy.matrices import Matrix >>> A = Matrix([[1, 2, 3], [4, 5, 6]]) >>> 2*A == A*2 == Matrix([[2, 4, 6], [8, 10, 12]]) True >>> B = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) >>> A*B Matrix([ [30, 36, 42], [66, 81, 96]]) >>> B*A Traceback (most recent call last): ... ShapeError: Matrices size mismatch. >>> See Also ======== matrix_multiply_elementwise """ other = _matrixify(other) # matrix-like objects can have shapes. This is # our first sanity check. if hasattr(other, 'shape') and len(other.shape) == 2: if self.shape[1] != other.shape[0]: raise ShapeError("Matrix size mismatch: %s * %s." % ( self.shape, other.shape)) # honest sympy matrices defer to their class's routine if getattr(other, 'is_Matrix', False): return self._eval_matrix_mul(other) # Matrix-like objects can be passed to CommonMatrix routines directly. if getattr(other, 'is_MatrixLike', False): return MatrixArithmetic._eval_matrix_mul(self, other) # if 'other' is not iterable then scalar multiplication. if not isinstance(other, Iterable): try: return self._eval_scalar_mul(other) except TypeError: pass return NotImplemented def __neg__(self): return self._eval_scalar_mul(-1) @call_highest_priority('__rpow__') def __pow__(self, num): if self.rows != self.cols: raise NonSquareMatrixError() a = self jordan_pow = getattr(a, '_matrix_pow_by_jordan_blocks', None) num = sympify(num) if num.is_Number and num % 1 == 0: if a.rows == 1: return a._new([[a[0]**num]]) if num == 0: return self._new(self.rows, self.cols, lambda i, j: int(i == j)) if num < 0: num = -num a = a.inv() # When certain conditions are met, # Jordan block algorithm is faster than # computation by recursion. elif a.rows == 2 and num > 100000 and jordan_pow is not None: try: return jordan_pow(num) except MatrixError: pass return a._eval_pow_by_recursion(num) elif not num.is_Number and num.is_negative is None and a.det() == 0: from sympy.matrices.expressions import MatPow return MatPow(a, num) elif isinstance(num, (Expr, float)): return jordan_pow(num) else: raise TypeError( "Only SymPy expressions or integers are supported as exponent for matrices") @call_highest_priority('__add__') def __radd__(self, other): return self + other @call_highest_priority('__matmul__') def __rmatmul__(self, other): other = _matrixify(other) if not getattr(other, 'is_Matrix', False) and not getattr(other, 'is_MatrixLike', False): return NotImplemented return self.__rmul__(other) @call_highest_priority('__mul__') def __rmul__(self, other): other = _matrixify(other) # matrix-like objects can have shapes. This is # our first sanity check. if hasattr(other, 'shape') and len(other.shape) == 2: if self.shape[0] != other.shape[1]: raise ShapeError("Matrix size mismatch.") # honest sympy matrices defer to their class's routine if getattr(other, 'is_Matrix', False): return other._new(other.as_mutable() * self) # Matrix-like objects can be passed to CommonMatrix routines directly. if getattr(other, 'is_MatrixLike', False): return MatrixArithmetic._eval_matrix_rmul(self, other) # if 'other' is not iterable then scalar multiplication. if not isinstance(other, Iterable): try: return self._eval_scalar_rmul(other) except TypeError: pass return NotImplemented @call_highest_priority('__sub__') def __rsub__(self, a): return (-self) + a @call_highest_priority('__rsub__') def __sub__(self, a): return self + (-a) @call_highest_priority('__rtruediv__') def __truediv__(self, other): return self.__div__(other) def multiply_elementwise(self, other): """Return the Hadamard product (elementwise product) of A and B Examples ======== >>> from sympy.matrices import Matrix >>> A = Matrix([[0, 1, 2], [3, 4, 5]]) >>> B = Matrix([[1, 10, 100], [100, 10, 1]]) >>> A.multiply_elementwise(B) Matrix([ [ 0, 10, 200], [300, 40, 5]]) See Also ======== cross dot multiply """ if self.shape != other.shape: raise ShapeError("Matrix shapes must agree {} != {}".format(self.shape, other.shape)) return self._eval_matrix_mul_elementwise(other) class MatrixCommon(MatrixArithmetic, MatrixOperations, MatrixProperties, MatrixSpecial, MatrixShaping): """All common matrix operations including basic arithmetic, shaping, and special matrices like `zeros`, and `eye`.""" _diff_wrt = True class _MinimalMatrix(object): """Class providing the minimum functionality for a matrix-like object and implementing every method required for a `MatrixRequired`. This class does not have everything needed to become a full-fledged SymPy object, but it will satisfy the requirements of anything inheriting from `MatrixRequired`. If you wish to make a specialized matrix type, make sure to implement these methods and properties with the exception of `__init__` and `__repr__` which are included for convenience.""" is_MatrixLike = True _sympify = staticmethod(sympify) _class_priority = 3 is_Matrix = True is_MatrixExpr = False @classmethod def _new(cls, *args, **kwargs): return cls(*args, **kwargs) def __init__(self, rows, cols=None, mat=None): if isfunction(mat): # if we passed in a function, use that to populate the indices mat = list(mat(i, j) for i in range(rows) for j in range(cols)) if cols is None and mat is None: mat = rows rows, cols = getattr(mat, 'shape', (rows, cols)) try: # if we passed in a list of lists, flatten it and set the size if cols is None and mat is None: mat = rows cols = len(mat[0]) rows = len(mat) mat = [x for l in mat for x in l] except (IndexError, TypeError): pass self.mat = tuple(self._sympify(x) for x in mat) self.rows, self.cols = rows, cols if self.rows is None or self.cols is None: raise NotImplementedError("Cannot initialize matrix with given parameters") def __getitem__(self, key): def _normalize_slices(row_slice, col_slice): """Ensure that row_slice and col_slice don't have `None` in their arguments. Any integers are converted to slices of length 1""" if not isinstance(row_slice, slice): row_slice = slice(row_slice, row_slice + 1, None) row_slice = slice(*row_slice.indices(self.rows)) if not isinstance(col_slice, slice): col_slice = slice(col_slice, col_slice + 1, None) col_slice = slice(*col_slice.indices(self.cols)) return (row_slice, col_slice) def _coord_to_index(i, j): """Return the index in _mat corresponding to the (i,j) position in the matrix. """ return i * self.cols + j if isinstance(key, tuple): i, j = key if isinstance(i, slice) or isinstance(j, slice): # if the coordinates are not slices, make them so # and expand the slices so they don't contain `None` i, j = _normalize_slices(i, j) rowsList, colsList = list(range(self.rows))[i], \ list(range(self.cols))[j] indices = (i * self.cols + j for i in rowsList for j in colsList) return self._new(len(rowsList), len(colsList), list(self.mat[i] for i in indices)) # if the key is a tuple of ints, change # it to an array index key = _coord_to_index(i, j) return self.mat[key] def __eq__(self, other): try: classof(self, other) except TypeError: return False return ( self.shape == other.shape and list(self) == list(other)) def __len__(self): return self.rows*self.cols def __repr__(self): return "_MinimalMatrix({}, {}, {})".format(self.rows, self.cols, self.mat) @property def shape(self): return (self.rows, self.cols) class _MatrixWrapper(object): """Wrapper class providing the minimum functionality for a matrix-like object: .rows, .cols, .shape, indexability, and iterability. CommonMatrix math operations should work on matrix-like objects. For example, wrapping a numpy matrix in a MatrixWrapper allows it to be passed to CommonMatrix. """ is_MatrixLike = True def __init__(self, mat, shape=None): self.mat = mat self.rows, self.cols = mat.shape if shape is None else shape def __getattr__(self, attr): """Most attribute access is passed straight through to the stored matrix""" return getattr(self.mat, attr) def __getitem__(self, key): return self.mat.__getitem__(key) def _matrixify(mat): """If `mat` is a Matrix or is matrix-like, return a Matrix or MatrixWrapper object. Otherwise `mat` is passed through without modification.""" if getattr(mat, 'is_Matrix', False): return mat if hasattr(mat, 'shape'): if len(mat.shape) == 2: return _MatrixWrapper(mat) return mat def a2idx(j, n=None): """Return integer after making positive and validating against n.""" if type(j) is not int: jindex = getattr(j, '__index__', None) if jindex is not None: j = jindex() else: raise IndexError("Invalid index a[%r]" % (j,)) if n is not None: if j < 0: j += n if not (j >= 0 and j < n): raise IndexError("Index out of range: a[%s]" % (j,)) return int(j) def classof(A, B): """ Get the type of the result when combining matrices of different types. Currently the strategy is that immutability is contagious. Examples ======== >>> from sympy import Matrix, ImmutableMatrix >>> from sympy.matrices.common import classof >>> M = Matrix([[1, 2], [3, 4]]) # a Mutable Matrix >>> IM = ImmutableMatrix([[1, 2], [3, 4]]) >>> classof(M, IM) <class 'sympy.matrices.immutable.ImmutableDenseMatrix'> """ priority_A = getattr(A, '_class_priority', None) priority_B = getattr(B, '_class_priority', None) if None not in (priority_A, priority_B): if A._class_priority > B._class_priority: return A.__class__ else: return B.__class__ try: import numpy except ImportError: pass else: if isinstance(A, numpy.ndarray): return B.__class__ if isinstance(B, numpy.ndarray): return A.__class__ raise TypeError("Incompatible classes %s, %s" % (A.__class__, B.__class__))

da6102438d5d89f6e4040f9a679182a600cdaefa6c6e4724dbbda0f2f233cebb

from __future__ import print_function, division from itertools import product from sympy.core.basic import Basic from sympy.core.compatibility import (iterable, with_metaclass, ordered, range, PY3) from sympy.core.cache import cacheit from sympy.core.evalf import EvalfMixin from sympy.core.evaluate import global_evaluate from sympy.core.expr import Expr from sympy.core.function import FunctionClass from sympy.core.logic import fuzzy_bool from sympy.core.mul import Mul from sympy.core.numbers import Float from sympy.core.operations import LatticeOp from sympy.core.relational import Eq, Ne from sympy.core.singleton import Singleton, S from sympy.core.symbol import Symbol, Dummy, _uniquely_named_symbol from sympy.core.sympify import _sympify, sympify, converter from sympy.logic.boolalg import And, Or, Not, true, false from sympy.sets.contains import Contains from sympy.utilities import subsets from sympy.utilities.iterables import sift from sympy.utilities.misc import func_name, filldedent from mpmath import mpi, mpf class Set(Basic): """ The base class for any kind of set. This is not meant to be used directly as a container of items. It does not behave like the builtin ``set``; see :class:`FiniteSet` for that. Real intervals are represented by the :class:`Interval` class and unions of sets by the :class:`Union` class. The empty set is represented by the :class:`EmptySet` class and available as a singleton as ``S.EmptySet``. """ is_number = False is_iterable = False is_interval = False is_FiniteSet = False is_Interval = False is_ProductSet = False is_Union = False is_Intersection = None is_EmptySet = None is_UniversalSet = None is_Complement = None is_ComplexRegion = False @staticmethod def _infimum_key(expr): """ Return infimum (if possible) else S.Infinity. """ try: infimum = expr.inf assert infimum.is_comparable except (NotImplementedError, AttributeError, AssertionError, ValueError): infimum = S.Infinity return infimum def union(self, other): """ Returns the union of 'self' and 'other'. Examples ======== As a shortcut it is possible to use the '+' operator: >>> from sympy import Interval, FiniteSet >>> Interval(0, 1).union(Interval(2, 3)) Union(Interval(0, 1), Interval(2, 3)) >>> Interval(0, 1) + Interval(2, 3) Union(Interval(0, 1), Interval(2, 3)) >>> Interval(1, 2, True, True) + FiniteSet(2, 3) Union(Interval.Lopen(1, 2), {3}) Similarly it is possible to use the '-' operator for set differences: >>> Interval(0, 2) - Interval(0, 1) Interval.Lopen(1, 2) >>> Interval(1, 3) - FiniteSet(2) Union(Interval.Ropen(1, 2), Interval.Lopen(2, 3)) """ return Union(self, other) def intersect(self, other): """ Returns the intersection of 'self' and 'other'. >>> from sympy import Interval >>> Interval(1, 3).intersect(Interval(1, 2)) Interval(1, 2) >>> from sympy import imageset, Lambda, symbols, S >>> n, m = symbols('n m') >>> a = imageset(Lambda(n, 2*n), S.Integers) >>> a.intersect(imageset(Lambda(m, 2*m + 1), S.Integers)) EmptySet() """ return Intersection(self, other) def intersection(self, other): """ Alias for :meth:`intersect()` """ return self.intersect(other) def is_disjoint(self, other): """ Returns True if 'self' and 'other' are disjoint Examples ======== >>> from sympy import Interval >>> Interval(0, 2).is_disjoint(Interval(1, 2)) False >>> Interval(0, 2).is_disjoint(Interval(3, 4)) True References ========== .. [1] https://en.wikipedia.org/wiki/Disjoint_sets """ return self.intersect(other) == S.EmptySet def isdisjoint(self, other): """ Alias for :meth:`is_disjoint()` """ return self.is_disjoint(other) def complement(self, universe): r""" The complement of 'self' w.r.t the given universe. Examples ======== >>> from sympy import Interval, S >>> Interval(0, 1).complement(S.Reals) Union(Interval.open(-oo, 0), Interval.open(1, oo)) >>> Interval(0, 1).complement(S.UniversalSet) UniversalSet \ Interval(0, 1) """ return Complement(universe, self) def _complement(self, other): # this behaves as other - self if isinstance(other, ProductSet): # For each set consider it or it's complement # We need at least one of the sets to be complemented # Consider all 2^n combinations. # We can conveniently represent these options easily using a # ProductSet # XXX: this doesn't work if the dimensions of the sets isn't same. # A - B is essentially same as A if B has a different # dimensionality than A switch_sets = ProductSet(FiniteSet(o, o - s) for s, o in zip(self.sets, other.sets)) product_sets = (ProductSet(*set) for set in switch_sets) # Union of all combinations but this one return Union(*(p for p in product_sets if p != other)) elif isinstance(other, Interval): if isinstance(self, Interval) or isinstance(self, FiniteSet): return Intersection(other, self.complement(S.Reals)) elif isinstance(other, Union): return Union(*(o - self for o in other.args)) elif isinstance(other, Complement): return Complement(other.args[0], Union(other.args[1], self), evaluate=False) elif isinstance(other, EmptySet): return S.EmptySet elif isinstance(other, FiniteSet): from sympy.utilities.iterables import sift sifted = sift(other, lambda x: fuzzy_bool(self.contains(x))) # ignore those that are contained in self return Union(FiniteSet(*(sifted[False])), Complement(FiniteSet(*(sifted[None])), self, evaluate=False) if sifted[None] else S.EmptySet) def symmetric_difference(self, other): """ Returns symmetric difference of `self` and `other`. Examples ======== >>> from sympy import Interval, S >>> Interval(1, 3).symmetric_difference(S.Reals) Union(Interval.open(-oo, 1), Interval.open(3, oo)) >>> Interval(1, 10).symmetric_difference(S.Reals) Union(Interval.open(-oo, 1), Interval.open(10, oo)) >>> from sympy import S, EmptySet >>> S.Reals.symmetric_difference(EmptySet()) Reals References ========== .. [1] https://en.wikipedia.org/wiki/Symmetric_difference """ return SymmetricDifference(self, other) def _symmetric_difference(self, other): return Union(Complement(self, other), Complement(other, self)) @property def inf(self): """ The infimum of 'self' Examples ======== >>> from sympy import Interval, Union >>> Interval(0, 1).inf 0 >>> Union(Interval(0, 1), Interval(2, 3)).inf 0 """ return self._inf @property def _inf(self): raise NotImplementedError("(%s)._inf" % self) @property def sup(self): """ The supremum of 'self' Examples ======== >>> from sympy import Interval, Union >>> Interval(0, 1).sup 1 >>> Union(Interval(0, 1), Interval(2, 3)).sup 3 """ return self._sup @property def _sup(self): raise NotImplementedError("(%s)._sup" % self) def contains(self, other): """ Returns True if 'other' is contained in 'self' as an element. As a shortcut it is possible to use the 'in' operator: Examples ======== >>> from sympy import Interval >>> Interval(0, 1).contains(0.5) True >>> 0.5 in Interval(0, 1) True """ other = sympify(other, strict=True) ret = sympify(self._contains(other)) if ret is None: ret = Contains(other, self, evaluate=False) return ret def _contains(self, other): raise NotImplementedError("(%s)._contains(%s)" % (self, other)) def is_subset(self, other): """ Returns True if 'self' is a subset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 0.5).is_subset(Interval(0, 1)) True >>> Interval(0, 1).is_subset(Interval(0, 1, left_open=True)) False """ if isinstance(other, Set): return self.intersect(other) == self else: raise ValueError("Unknown argument '%s'" % other) def issubset(self, other): """ Alias for :meth:`is_subset()` """ return self.is_subset(other) def is_proper_subset(self, other): """ Returns True if 'self' is a proper subset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 0.5).is_proper_subset(Interval(0, 1)) True >>> Interval(0, 1).is_proper_subset(Interval(0, 1)) False """ if isinstance(other, Set): return self != other and self.is_subset(other) else: raise ValueError("Unknown argument '%s'" % other) def is_superset(self, other): """ Returns True if 'self' is a superset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 0.5).is_superset(Interval(0, 1)) False >>> Interval(0, 1).is_superset(Interval(0, 1, left_open=True)) True """ if isinstance(other, Set): return other.is_subset(self) else: raise ValueError("Unknown argument '%s'" % other) def issuperset(self, other): """ Alias for :meth:`is_superset()` """ return self.is_superset(other) def is_proper_superset(self, other): """ Returns True if 'self' is a proper superset of 'other'. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).is_proper_superset(Interval(0, 0.5)) True >>> Interval(0, 1).is_proper_superset(Interval(0, 1)) False """ if isinstance(other, Set): return self != other and self.is_superset(other) else: raise ValueError("Unknown argument '%s'" % other) def _eval_powerset(self): raise NotImplementedError('Power set not defined for: %s' % self.func) def powerset(self): """ Find the Power set of 'self'. Examples ======== >>> from sympy import FiniteSet, EmptySet >>> A = EmptySet() >>> A.powerset() {EmptySet()} >>> A = FiniteSet(1, 2) >>> a, b, c = FiniteSet(1), FiniteSet(2), FiniteSet(1, 2) >>> A.powerset() == FiniteSet(a, b, c, EmptySet()) True References ========== .. [1] https://en.wikipedia.org/wiki/Power_set """ return self._eval_powerset() @property def measure(self): """ The (Lebesgue) measure of 'self' Examples ======== >>> from sympy import Interval, Union >>> Interval(0, 1).measure 1 >>> Union(Interval(0, 1), Interval(2, 3)).measure 2 """ return self._measure @property def boundary(self): """ The boundary or frontier of a set A point x is on the boundary of a set S if 1. x is in the closure of S. I.e. Every neighborhood of x contains a point in S. 2. x is not in the interior of S. I.e. There does not exist an open set centered on x contained entirely within S. There are the points on the outer rim of S. If S is open then these points need not actually be contained within S. For example, the boundary of an interval is its start and end points. This is true regardless of whether or not the interval is open. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).boundary {0, 1} >>> Interval(0, 1, True, False).boundary {0, 1} """ return self._boundary @property def is_open(self): """ Property method to check whether a set is open. A set is open if and only if it has an empty intersection with its boundary. Examples ======== >>> from sympy import S >>> S.Reals.is_open True """ if not Intersection(self, self.boundary): return True # We can't confidently claim that an intersection exists return None @property def is_closed(self): """ A property method to check whether a set is closed. A set is closed if it's complement is an open set. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).is_closed True """ return self.boundary.is_subset(self) @property def closure(self): """ Property method which returns the closure of a set. The closure is defined as the union of the set itself and its boundary. Examples ======== >>> from sympy import S, Interval >>> S.Reals.closure Reals >>> Interval(0, 1).closure Interval(0, 1) """ return self + self.boundary @property def interior(self): """ Property method which returns the interior of a set. The interior of a set S consists all points of S that do not belong to the boundary of S. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).interior Interval.open(0, 1) >>> Interval(0, 1).boundary.interior EmptySet() """ return self - self.boundary @property def _boundary(self): raise NotImplementedError() @property def _measure(self): raise NotImplementedError("(%s)._measure" % self) def __add__(self, other): return self.union(other) def __or__(self, other): return self.union(other) def __and__(self, other): return self.intersect(other) def __mul__(self, other): return ProductSet(self, other) def __xor__(self, other): return SymmetricDifference(self, other) def __pow__(self, exp): if not sympify(exp).is_Integer and exp >= 0: raise ValueError("%s: Exponent must be a positive Integer" % exp) return ProductSet([self]*exp) def __sub__(self, other): return Complement(self, other) def __contains__(self, other): symb = sympify(self.contains(other)) if not (symb is S.true or symb is S.false): raise TypeError('contains did not evaluate to a bool: %r' % symb) return bool(symb) class ProductSet(Set): """ Represents a Cartesian Product of Sets. Returns a Cartesian product given several sets as either an iterable or individual arguments. Can use '*' operator on any sets for convenient shorthand. Examples ======== >>> from sympy import Interval, FiniteSet, ProductSet >>> I = Interval(0, 5); S = FiniteSet(1, 2, 3) >>> ProductSet(I, S) Interval(0, 5) x {1, 2, 3} >>> (2, 2) in ProductSet(I, S) True >>> Interval(0, 1) * Interval(0, 1) # The unit square Interval(0, 1) x Interval(0, 1) >>> coin = FiniteSet('H', 'T') >>> set(coin**2) {(H, H), (H, T), (T, H), (T, T)} Notes ===== - Passes most operations down to the argument sets - Flattens Products of ProductSets References ========== .. [1] https://en.wikipedia.org/wiki/Cartesian_product """ is_ProductSet = True def __new__(cls, *sets, **assumptions): def flatten(arg): if isinstance(arg, Set): if arg.is_ProductSet: return sum(map(flatten, arg.args), []) else: return [arg] elif iterable(arg): return sum(map(flatten, arg), []) raise TypeError("Input must be Sets or iterables of Sets") sets = flatten(list(sets)) if EmptySet() in sets or len(sets) == 0: return EmptySet() if len(sets) == 1: return sets[0] return Basic.__new__(cls, *sets, **assumptions) def _eval_Eq(self, other): if not other.is_ProductSet: return if len(self.args) != len(other.args): return false return And(*(Eq(x, y) for x, y in zip(self.args, other.args))) def _contains(self, element): """ 'in' operator for ProductSets Examples ======== >>> from sympy import Interval >>> (2, 3) in Interval(0, 5) * Interval(0, 5) True >>> (10, 10) in Interval(0, 5) * Interval(0, 5) False Passes operation on to constituent sets """ try: if len(element) != len(self.args): return false except TypeError: # maybe element isn't an iterable return false return And(* [set.contains(item) for set, item in zip(self.sets, element)]) @property def sets(self): return self.args @property def _boundary(self): return Union(*(ProductSet(b + b.boundary if i != j else b.boundary for j, b in enumerate(self.sets)) for i, a in enumerate(self.sets))) @property def is_iterable(self): """ A property method which tests whether a set is iterable or not. Returns True if set is iterable, otherwise returns False. Examples ======== >>> from sympy import FiniteSet, Interval, ProductSet >>> I = Interval(0, 1) >>> A = FiniteSet(1, 2, 3, 4, 5) >>> I.is_iterable False >>> A.is_iterable True """ return all(set.is_iterable for set in self.sets) def __iter__(self): """ A method which implements is_iterable property method. If self.is_iterable returns True (both constituent sets are iterable), then return the Cartesian Product. Otherwise, raise TypeError. """ if self.is_iterable: return product(*self.sets) else: raise TypeError("Not all constituent sets are iterable") @property def _measure(self): measure = 1 for set in self.sets: measure *= set.measure return measure def __len__(self): return Mul(*[len(s) for s in self.args]) def __bool__(self): return all([bool(s) for s in self.args]) __nonzero__ = __bool__ class Interval(Set, EvalfMixin): """ Represents a real interval as a Set. Usage: Returns an interval with end points "start" and "end". For left_open=True (default left_open is False) the interval will be open on the left. Similarly, for right_open=True the interval will be open on the right. Examples ======== >>> from sympy import Symbol, Interval >>> Interval(0, 1) Interval(0, 1) >>> Interval.Ropen(0, 1) Interval.Ropen(0, 1) >>> Interval.Ropen(0, 1) Interval.Ropen(0, 1) >>> Interval.Lopen(0, 1) Interval.Lopen(0, 1) >>> Interval.open(0, 1) Interval.open(0, 1) >>> a = Symbol('a', real=True) >>> Interval(0, a) Interval(0, a) Notes ===== - Only real end points are supported - Interval(a, b) with a > b will return the empty set - Use the evalf() method to turn an Interval into an mpmath 'mpi' interval instance References ========== .. [1] https://en.wikipedia.org/wiki/Interval_%28mathematics%29 """ is_Interval = True def __new__(cls, start, end, left_open=False, right_open=False): start = _sympify(start) end = _sympify(end) left_open = _sympify(left_open) right_open = _sympify(right_open) if not all(isinstance(a, (type(true), type(false))) for a in [left_open, right_open]): raise NotImplementedError( "left_open and right_open can have only true/false values, " "got %s and %s" % (left_open, right_open)) inftys = [S.Infinity, S.NegativeInfinity] # Only allow real intervals (use symbols with 'is_real=True'). if not all(i.is_real is not False or i in inftys for i in (start, end)): raise ValueError("Non-real intervals are not supported") # evaluate if possible if (end < start) == True: return S.EmptySet elif (end - start).is_negative: return S.EmptySet if end == start and (left_open or right_open): return S.EmptySet if end == start and not (left_open or right_open): if start == S.Infinity or start == S.NegativeInfinity: return S.EmptySet return FiniteSet(end) # Make sure infinite interval end points are open. if start == S.NegativeInfinity: left_open = true if end == S.Infinity: right_open = true return Basic.__new__(cls, start, end, left_open, right_open) @property def start(self): """ The left end point of 'self'. This property takes the same value as the 'inf' property. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).start 0 """ return self._args[0] _inf = left = start @classmethod def open(cls, a, b): """Return an interval including neither boundary.""" return cls(a, b, True, True) @classmethod def Lopen(cls, a, b): """Return an interval not including the left boundary.""" return cls(a, b, True, False) @classmethod def Ropen(cls, a, b): """Return an interval not including the right boundary.""" return cls(a, b, False, True) @property def end(self): """ The right end point of 'self'. This property takes the same value as the 'sup' property. Examples ======== >>> from sympy import Interval >>> Interval(0, 1).end 1 """ return self._args[1] _sup = right = end @property def left_open(self): """ True if 'self' is left-open. Examples ======== >>> from sympy import Interval >>> Interval(0, 1, left_open=True).left_open True >>> Interval(0, 1, left_open=False).left_open False """ return self._args[2] @property def right_open(self): """ True if 'self' is right-open. Examples ======== >>> from sympy import Interval >>> Interval(0, 1, right_open=True).right_open True >>> Interval(0, 1, right_open=False).right_open False """ return self._args[3] def _complement(self, other): if other == S.Reals: a = Interval(S.NegativeInfinity, self.start, True, not self.left_open) b = Interval(self.end, S.Infinity, not self.right_open, True) return Union(a, b) if isinstance(other, FiniteSet): nums = [m for m in other.args if m.is_number] if nums == []: return None return Set._complement(self, other) @property def _boundary(self): finite_points = [p for p in (self.start, self.end) if abs(p) != S.Infinity] return FiniteSet(*finite_points) def _contains(self, other): if not isinstance(other, Expr) or ( other is S.Infinity or other is S.NegativeInfinity or other is S.NaN or other is S.ComplexInfinity) or other.is_real is False: return false if self.start is S.NegativeInfinity and self.end is S.Infinity: if not other.is_real is None: return other.is_real if self.left_open: expr = other > self.start else: expr = other >= self.start if self.right_open: expr = And(expr, other < self.end) else: expr = And(expr, other <= self.end) return _sympify(expr) @property def _measure(self): return self.end - self.start def to_mpi(self, prec=53): return mpi(mpf(self.start._eval_evalf(prec)), mpf(self.end._eval_evalf(prec))) def _eval_evalf(self, prec): return Interval(self.left._eval_evalf(prec), self.right._eval_evalf(prec), left_open=self.left_open, right_open=self.right_open) def _is_comparable(self, other): is_comparable = self.start.is_comparable is_comparable &= self.end.is_comparable is_comparable &= other.start.is_comparable is_comparable &= other.end.is_comparable return is_comparable @property def is_left_unbounded(self): """Return ``True`` if the left endpoint is negative infinity. """ return self.left is S.NegativeInfinity or self.left == Float("-inf") @property def is_right_unbounded(self): """Return ``True`` if the right endpoint is positive infinity. """ return self.right is S.Infinity or self.right == Float("+inf") def as_relational(self, x): """Rewrite an interval in terms of inequalities and logic operators.""" x = sympify(x) if self.right_open: right = x < self.end else: right = x <= self.end if self.left_open: left = self.start < x else: left = self.start <= x return And(left, right) def _eval_Eq(self, other): if not isinstance(other, Interval): if isinstance(other, FiniteSet): return false elif isinstance(other, Set): return None return false return And(Eq(self.left, other.left), Eq(self.right, other.right), self.left_open == other.left_open, self.right_open == other.right_open) class Union(Set, LatticeOp, EvalfMixin): """ Represents a union of sets as a :class:`Set`. Examples ======== >>> from sympy import Union, Interval >>> Union(Interval(1, 2), Interval(3, 4)) Union(Interval(1, 2), Interval(3, 4)) The Union constructor will always try to merge overlapping intervals, if possible. For example: >>> Union(Interval(1, 2), Interval(2, 3)) Interval(1, 3) See Also ======== Intersection References ========== .. [1] https://en.wikipedia.org/wiki/Union_%28set_theory%29 """ is_Union = True @property def identity(self): return S.EmptySet @property def zero(self): return S.UniversalSet def __new__(cls, *args, **kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) # flatten inputs to merge intersections and iterables args = _sympify(args) # Reduce sets using known rules if evaluate: args = list(cls._new_args_filter(args)) return simplify_union(args) args = list(ordered(args, Set._infimum_key)) obj = Basic.__new__(cls, *args) obj._argset = frozenset(args) return obj @property @cacheit def args(self): return self._args def _complement(self, universe): # DeMorgan's Law return Intersection(s.complement(universe) for s in self.args) @property def _inf(self): # We use Min so that sup is meaningful in combination with symbolic # interval end points. from sympy.functions.elementary.miscellaneous import Min return Min(*[set.inf for set in self.args]) @property def _sup(self): # We use Max so that sup is meaningful in combination with symbolic # end points. from sympy.functions.elementary.miscellaneous import Max return Max(*[set.sup for set in self.args]) def _contains(self, other): return Or(*[set.contains(other) for set in self.args]) @property def _measure(self): # Measure of a union is the sum of the measures of the sets minus # the sum of their pairwise intersections plus the sum of their # triple-wise intersections minus ... etc... # Sets is a collection of intersections and a set of elementary # sets which made up those intersections (called "sos" for set of sets) # An example element might of this list might be: # ( {A,B,C}, A.intersect(B).intersect(C) ) # Start with just elementary sets ( ({A}, A), ({B}, B), ... ) # Then get and subtract ( ({A,B}, (A int B), ... ) while non-zero sets = [(FiniteSet(s), s) for s in self.args] measure = 0 parity = 1 while sets: # Add up the measure of these sets and add or subtract it to total measure += parity * sum(inter.measure for sos, inter in sets) # For each intersection in sets, compute the intersection with every # other set not already part of the intersection. sets = ((sos + FiniteSet(newset), newset.intersect(intersection)) for sos, intersection in sets for newset in self.args if newset not in sos) # Clear out sets with no measure sets = [(sos, inter) for sos, inter in sets if inter.measure != 0] # Clear out duplicates sos_list = [] sets_list = [] for set in sets: if set[0] in sos_list: continue else: sos_list.append(set[0]) sets_list.append(set) sets = sets_list # Flip Parity - next time subtract/add if we added/subtracted here parity *= -1 return measure @property def _boundary(self): def boundary_of_set(i): """ The boundary of set i minus interior of all other sets """ b = self.args[i].boundary for j, a in enumerate(self.args): if j != i: b = b - a.interior return b return Union(*map(boundary_of_set, range(len(self.args)))) def as_relational(self, symbol): """Rewrite a Union in terms of equalities and logic operators. """ if len(self.args) == 2: a, b = self.args if (a.sup == b.inf and a.inf is S.NegativeInfinity and b.sup is S.Infinity): return And(Ne(symbol, a.sup), symbol < b.sup, symbol > a.inf) return Or(*[set.as_relational(symbol) for set in self.args]) @property def is_iterable(self): return all(arg.is_iterable for arg in self.args) def _eval_evalf(self, prec): try: return Union(*(set._eval_evalf(prec) for set in self.args)) except (TypeError, ValueError, NotImplementedError): import sys raise (TypeError("Not all sets are evalf-able"), None, sys.exc_info()[2]) def __iter__(self): import itertools # roundrobin recipe taken from itertools documentation: # https://docs.python.org/2/library/itertools.html#recipes def roundrobin(*iterables): "roundrobin('ABC', 'D', 'EF') --> A D E B F C" # Recipe credited to George Sakkis pending = len(iterables) if PY3: nexts = itertools.cycle(iter(it).__next__ for it in iterables) else: nexts = itertools.cycle(iter(it).next for it in iterables) while pending: try: for next in nexts: yield next() except StopIteration: pending -= 1 nexts = itertools.cycle(itertools.islice(nexts, pending)) if all(set.is_iterable for set in self.args): return roundrobin(*(iter(arg) for arg in self.args)) else: raise TypeError("Not all constituent sets are iterable") class Intersection(Set, LatticeOp): """ Represents an intersection of sets as a :class:`Set`. Examples ======== >>> from sympy import Intersection, Interval >>> Intersection(Interval(1, 3), Interval(2, 4)) Interval(2, 3) We often use the .intersect method >>> Interval(1,3).intersect(Interval(2,4)) Interval(2, 3) See Also ======== Union References ========== .. [1] https://en.wikipedia.org/wiki/Intersection_%28set_theory%29 """ is_Intersection = True @property def identity(self): return S.UniversalSet @property def zero(self): return S.EmptySet def __new__(cls, *args, **kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) # flatten inputs to merge intersections and iterables args = _sympify(args) # Reduce sets using known rules if evaluate: args = list(cls._new_args_filter(args)) return simplify_intersection(args) args = list(ordered(args, Set._infimum_key)) obj = Basic.__new__(cls, *args) obj._argset = frozenset(args) return obj @property @cacheit def args(self): return self._args @property def is_iterable(self): return any(arg.is_iterable for arg in self.args) @property def _inf(self): raise NotImplementedError() @property def _sup(self): raise NotImplementedError() def _contains(self, other): return And(*[set.contains(other) for set in self.args]) def __iter__(self): no_iter = True for s in self.args: if s.is_iterable: no_iter = False other_sets = set(self.args) - set((s,)) other = Intersection(*other_sets, evaluate=False) for x in s: c = sympify(other.contains(x)) if c is S.true: yield x elif c is S.false: pass else: yield c if no_iter: raise ValueError("None of the constituent sets are iterable") @staticmethod def _handle_finite_sets(args): from sympy.core.logic import fuzzy_and, fuzzy_bool from sympy.core.compatibility import zip_longest fs_args, other = sift(args, lambda x: x.is_FiniteSet, binary=True) if not fs_args: return fs_args.sort(key=len) s = fs_args[0] fs_args = fs_args[1:] res = [] unk = [] for x in s: c = fuzzy_and(fuzzy_bool(o.contains(x)) for o in fs_args + other) if c: res.append(x) elif c is None: unk.append(x) else: pass # drop arg res = FiniteSet( *res, evaluate=False) if res else S.EmptySet if unk: symbolic_s_list = [x for x in s if x.has(Symbol)] non_symbolic_s = s - FiniteSet( *symbolic_s_list, evaluate=False) while fs_args: v = fs_args.pop() if all(i == j for i, j in zip_longest( symbolic_s_list, (x for x in v if x.has(Symbol)))): # all the symbolic elements of `v` are the same # as in `s` so remove the non-symbol containing # expressions from `unk`, since they cannot be # contained for x in non_symbolic_s: if x in unk: unk.remove(x) else: # if only a subset of elements in `s` are # contained in `v` then remove them from `v` # and add this as a new arg contained = [x for x in symbolic_s_list if sympify(v.contains(x)) is S.true] if contained != symbolic_s_list: other.append( v - FiniteSet( *contained, evaluate=False)) else: pass # for coverage other_sets = Intersection(*other) if not other_sets: return S.EmptySet # b/c we use evaluate=False below elif other_sets == S.UniversalSet: res += FiniteSet(*unk) else: res += Intersection( FiniteSet(*unk), other_sets, evaluate=False) return res def as_relational(self, symbol): """Rewrite an Intersection in terms of equalities and logic operators""" return And(*[set.as_relational(symbol) for set in self.args]) class Complement(Set, EvalfMixin): r"""Represents the set difference or relative complement of a set with another set. `A - B = \{x \in A| x \\notin B\}` Examples ======== >>> from sympy import Complement, FiniteSet >>> Complement(FiniteSet(0, 1, 2), FiniteSet(1)) {0, 2} See Also ========= Intersection, Union References ========== .. [1] http://mathworld.wolfram.com/ComplementSet.html """ is_Complement = True def __new__(cls, a, b, evaluate=True): if evaluate: return Complement.reduce(a, b) return Basic.__new__(cls, a, b) @staticmethod def reduce(A, B): """ Simplify a :class:`Complement`. """ if B == S.UniversalSet or A.is_subset(B): return EmptySet() if isinstance(B, Union): return Intersection(*(s.complement(A) for s in B.args)) result = B._complement(A) if result is not None: return result else: return Complement(A, B, evaluate=False) def _contains(self, other): A = self.args[0] B = self.args[1] return And(A.contains(other), Not(B.contains(other))) class EmptySet(with_metaclass(Singleton, Set)): """ Represents the empty set. The empty set is available as a singleton as S.EmptySet. Examples ======== >>> from sympy import S, Interval >>> S.EmptySet EmptySet() >>> Interval(1, 2).intersect(S.EmptySet) EmptySet() See Also ======== UniversalSet References ========== .. [1] https://en.wikipedia.org/wiki/Empty_set """ is_EmptySet = True is_FiniteSet = True @property def _measure(self): return 0 def _contains(self, other): return false def as_relational(self, symbol): return false def __len__(self): return 0 def __iter__(self): return iter([]) def _eval_powerset(self): return FiniteSet(self) @property def _boundary(self): return self def _complement(self, other): return other def _symmetric_difference(self, other): return other class UniversalSet(with_metaclass(Singleton, Set)): """ Represents the set of all things. The universal set is available as a singleton as S.UniversalSet Examples ======== >>> from sympy import S, Interval >>> S.UniversalSet UniversalSet >>> Interval(1, 2).intersect(S.UniversalSet) Interval(1, 2) See Also ======== EmptySet References ========== .. [1] https://en.wikipedia.org/wiki/Universal_set """ is_UniversalSet = True def _complement(self, other): return S.EmptySet def _symmetric_difference(self, other): return other @property def _measure(self): return S.Infinity def _contains(self, other): return true def as_relational(self, symbol): return true @property def _boundary(self): return EmptySet() class FiniteSet(Set, EvalfMixin): """ Represents a finite set of discrete numbers Examples ======== >>> from sympy import FiniteSet >>> FiniteSet(1, 2, 3, 4) {1, 2, 3, 4} >>> 3 in FiniteSet(1, 2, 3, 4) True >>> members = [1, 2, 3, 4] >>> f = FiniteSet(*members) >>> f {1, 2, 3, 4} >>> f - FiniteSet(2) {1, 3, 4} >>> f + FiniteSet(2, 5) {1, 2, 3, 4, 5} References ========== .. [1] https://en.wikipedia.org/wiki/Finite_set """ is_FiniteSet = True is_iterable = True def __new__(cls, *args, **kwargs): evaluate = kwargs.get('evaluate', global_evaluate[0]) if evaluate: args = list(map(sympify, args)) if len(args) == 0: return EmptySet() else: args = list(map(sympify, args)) args = list(ordered(frozenset(tuple(args)), Set._infimum_key)) obj = Basic.__new__(cls, *args) obj._elements = frozenset(args) return obj def _eval_Eq(self, other): if not isinstance(other, FiniteSet): if isinstance(other, Interval): return false elif isinstance(other, Set): return None return false if len(self) != len(other): return false return And(*(Eq(x, y) for x, y in zip(self.args, other.args))) def __iter__(self): return iter(self.args) def _complement(self, other): if isinstance(other, Interval): nums = sorted(m for m in self.args if m.is_number) if other == S.Reals and nums != []: syms = [m for m in self.args if m.is_Symbol] # Reals cannot contain elements other than numbers and symbols. intervals = [] # Build up a list of intervals between the elements intervals += [Interval(S.NegativeInfinity, nums[0], True, True)] for a, b in zip(nums[:-1], nums[1:]): intervals.append(Interval(a, b, True, True)) # both open intervals.append(Interval(nums[-1], S.Infinity, True, True)) if syms != []: return Complement(Union(*intervals, evaluate=False), FiniteSet(*syms), evaluate=False) else: return Union(*intervals, evaluate=False) elif nums == []: return None elif isinstance(other, FiniteSet): unk = [] for i in self: c = sympify(other.contains(i)) if c is not S.true and c is not S.false: unk.append(i) unk = FiniteSet(*unk) if unk == self: return not_true = [] for i in other: c = sympify(self.contains(i)) if c is not S.true: not_true.append(i) return Complement(FiniteSet(*not_true), unk) return Set._complement(self, other) def _contains(self, other): """ Tests whether an element, other, is in the set. Relies on Python's set class. This tests for object equality All inputs are sympified Examples ======== >>> from sympy import FiniteSet >>> 1 in FiniteSet(1, 2) True >>> 5 in FiniteSet(1, 2) False """ r = false for e in self._elements: # override global evaluation so we can use Eq to do # do the evaluation t = Eq(e, other, evaluate=True) if t is true: return t elif t is not false: r = None return r @property def _boundary(self): return self @property def _inf(self): from sympy.functions.elementary.miscellaneous import Min return Min(*self) @property def _sup(self): from sympy.functions.elementary.miscellaneous import Max return Max(*self) @property def measure(self): return 0 def __len__(self): return len(self.args) def as_relational(self, symbol): """Rewrite a FiniteSet in terms of equalities and logic operators. """ from sympy.core.relational import Eq return Or(*[Eq(symbol, elem) for elem in self]) def compare(self, other): return (hash(self) - hash(other)) def _eval_evalf(self, prec): return FiniteSet(*[elem._eval_evalf(prec) for elem in self]) def _hashable_content(self): return (self._elements,) @property def _sorted_args(self): return tuple(ordered(self.args, Set._infimum_key)) def _eval_powerset(self): return self.func(*[self.func(*s) for s in subsets(self.args)]) def __ge__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return other.is_subset(self) def __gt__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return self.is_proper_superset(other) def __le__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return self.is_subset(other) def __lt__(self, other): if not isinstance(other, Set): raise TypeError("Invalid comparison of set with %s" % func_name(other)) return self.is_proper_subset(other) converter[set] = lambda x: FiniteSet(*x) converter[frozenset] = lambda x: FiniteSet(*x) class SymmetricDifference(Set): """Represents the set of elements which are in either of the sets and not in their intersection. Examples ======== >>> from sympy import SymmetricDifference, FiniteSet >>> SymmetricDifference(FiniteSet(1, 2, 3), FiniteSet(3, 4, 5)) {1, 2, 4, 5} See Also ======== Complement, Union References ========== .. [1] https://en.wikipedia.org/wiki/Symmetric_difference """ is_SymmetricDifference = True def __new__(cls, a, b, evaluate=True): if evaluate: return SymmetricDifference.reduce(a, b) return Basic.__new__(cls, a, b) @staticmethod def reduce(A, B): result = B._symmetric_difference(A) if result is not None: return result else: return SymmetricDifference(A, B, evaluate=False) def imageset(*args): r""" Return an image of the set under transformation ``f``. If this function can't compute the image, it returns an unevaluated ImageSet object. .. math:: { f(x) | x \in self } Examples ======== >>> from sympy import S, Interval, Symbol, imageset, sin, Lambda >>> from sympy.abc import x, y >>> imageset(x, 2*x, Interval(0, 2)) Interval(0, 4) >>> imageset(lambda x: 2*x, Interval(0, 2)) Interval(0, 4) >>> imageset(Lambda(x, sin(x)), Interval(-2, 1)) ImageSet(Lambda(x, sin(x)), Interval(-2, 1)) >>> imageset(sin, Interval(-2, 1)) ImageSet(Lambda(x, sin(x)), Interval(-2, 1)) >>> imageset(lambda y: x + y, Interval(-2, 1)) ImageSet(Lambda(_x, _x + x), Interval(-2, 1)) Expressions applied to the set of Integers are simplified to show as few negatives as possible and linear expressions are converted to a canonical form. If this is not desirable then the unevaluated ImageSet should be used. >>> imageset(x, -2*x + 5, S.Integers) ImageSet(Lambda(x, 2*x + 1), Integers) See Also ======== sympy.sets.fancysets.ImageSet """ from sympy.core import Lambda from sympy.sets.fancysets import ImageSet from sympy.sets.setexpr import set_function if len(args) < 2: raise ValueError('imageset expects at least 2 args, got: %s' % len(args)) if isinstance(args[0], (Symbol, tuple)) and len(args) > 2: f = Lambda(args[0], args[1]) set_list = args[2:] else: f = args[0] set_list = args[1:] if isinstance(f, Lambda): pass elif ( isinstance(f, FunctionClass) # like cos or func_name(f) == '<lambda>' ): # TODO: should we support a way to sympify `lambda`? if len(set_list) == 1: var = _uniquely_named_symbol(Symbol('x'), f(Dummy())) expr = f(var) else: var = [Symbol('x%i' % (i+1)) for i in range(len(set_list))] expr = f(*var) f = Lambda(var, expr) else: raise TypeError(filldedent(''' expecting lambda, Lambda, or FunctionClass, not \'%s\'.''' % func_name(f))) if any(not isinstance(s, Set) for s in set_list): name = [func_name(s) for s in set_list] raise ValueError( 'arguments after mapping should be sets, not %s' % name) if len(set_list) == 1: set = set_list[0] r = set_function(f, set) if r is None: r = ImageSet(f, set) if isinstance(r, ImageSet): f, set = r.args if f.variables[0] == f.expr: return set if isinstance(set, ImageSet): if len(set.lamda.variables) == 1 and len(f.variables) == 1: return imageset(Lambda(set.lamda.variables[0], f.expr.subs(f.variables[0], set.lamda.expr)), set.base_set) if r is not None: return r return ImageSet(f, *set_list) def is_function_invertible_in_set(func, setv): """ Checks whether function ``func`` is invertible when the domain is restricted to set ``setv``. """ from sympy import exp, log # Functions known to always be invertible: if func in (exp, log): return True u = Dummy("u") fdiff = func(u).diff(u) # monotonous functions: # TODO: check subsets (`func` in `setv`) if (fdiff > 0) == True or (fdiff < 0) == True: return True # TODO: support more return None def simplify_union(args): """ Simplify a :class:`Union` using known rules We first start with global rules like 'Merge all FiniteSets' Then we iterate through all pairs and ask the constituent sets if they can simplify themselves with any other constituent. This process depends on ``union_sets(a, b)`` functions. """ from sympy.sets.handlers.union import union_sets # ===== Global Rules ===== if not args: return S.EmptySet for arg in args: if not isinstance(arg, Set): raise TypeError("Input args to Union must be Sets") # Merge all finite sets finite_sets = [x for x in args if x.is_FiniteSet] if len(finite_sets) > 1: a = (x for set in finite_sets for x in set) finite_set = FiniteSet(*a) args = [finite_set] + [x for x in args if not x.is_FiniteSet] # ===== Pair-wise Rules ===== # Here we depend on rules built into the constituent sets args = set(args) new_args = True while new_args: for s in args: new_args = False for t in args - set((s,)): new_set = union_sets(s, t) # This returns None if s does not know how to intersect # with t. Returns the newly intersected set otherwise if new_set is not None: if not isinstance(new_set, set): new_set = set((new_set, )) new_args = (args - set((s, t))).union(new_set) break if new_args: args = new_args break if len(args) == 1: return args.pop() else: return Union(*args, evaluate=False) def simplify_intersection(args): """ Simplify an intersection using known rules We first start with global rules like 'if any empty sets return empty set' and 'distribute any unions' Then we iterate through all pairs and ask the constituent sets if they can simplify themselves with any other constituent """ # ===== Global Rules ===== if not args: return S.UniversalSet for arg in args: if not isinstance(arg, Set): raise TypeError("Input args to Union must be Sets") # If any EmptySets return EmptySet if any(s.is_EmptySet for s in args): return S.EmptySet # Handle Finite sets rv = Intersection._handle_finite_sets(args) if rv is not None: return rv # If any of the sets are unions, return a Union of Intersections for s in args: if s.is_Union: other_sets = set(args) - set((s,)) if len(other_sets) > 0: other = Intersection(*other_sets) return Union(*(Intersection(arg, other) for arg in s.args)) else: return Union(*[arg for arg in s.args]) for s in args: if s.is_Complement: args.remove(s) other_sets = args + [s.args[0]] return Complement(Intersection(*other_sets), s.args[1]) from sympy.sets.handlers.intersection import intersection_sets # At this stage we are guaranteed not to have any # EmptySets, FiniteSets, or Unions in the intersection # ===== Pair-wise Rules ===== # Here we depend on rules built into the constituent sets args = set(args) new_args = True while new_args: for s in args: new_args = False for t in args - set((s,)): new_set = intersection_sets(s, t) # This returns None if s does not know how to intersect # with t. Returns the newly intersected set otherwise if new_set is not None: new_args = (args - set((s, t))).union(set((new_set, ))) break if new_args: args = new_args break if len(args) == 1: return args.pop() else: return Intersection(*args, evaluate=False) def _handle_finite_sets(op, x, y, commutative): # Handle finite sets: fs_args, other = sift([x, y], lambda x: isinstance(x, FiniteSet), binary=True) if len(fs_args) == 2: return FiniteSet(*[op(i, j) for i in fs_args[0] for j in fs_args[1]]) elif len(fs_args) == 1: sets = [_apply_operation(op, other[0], i, commutative) for i in fs_args[0]] return Union(*sets) else: return None def _apply_operation(op, x, y, commutative): from sympy.sets import ImageSet from sympy import symbols,Lambda d = Dummy('d') out = _handle_finite_sets(op, x, y, commutative) if out is None: out = op(x, y) if out is None and commutative: out = op(y, x) if out is None: _x, _y = symbols("x y") if isinstance(x, Set) and not isinstance(y, Set): out = ImageSet(Lambda(d, op(d, y)), x).doit() elif not isinstance(x, Set) and isinstance(y, Set): out = ImageSet(Lambda(d, op(x, d)), y).doit() else: out = ImageSet(Lambda((_x, _y), op(_x, _y)), x, y) return out def set_add(x, y): from sympy.sets.handlers.add import _set_add return _apply_operation(_set_add, x, y, commutative=True) def set_sub(x, y): from sympy.sets.handlers.add import _set_sub return _apply_operation(_set_sub, x, y, commutative=False) def set_mul(x, y): from sympy.sets.handlers.mul import _set_mul return _apply_operation(_set_mul, x, y, commutative=True) def set_div(x, y): from sympy.sets.handlers.mul import _set_div return _apply_operation(_set_div, x, y, commutative=False) def set_pow(x, y): from sympy.sets.handlers.power import _set_pow return _apply_operation(_set_pow, x, y, commutative=False) def set_function(f, x): from sympy.sets.handlers.functions import _set_function return _set_function(f, x)

9545dc4118ecfc8c261c6fae70b89ed3dcd3761a3b9346d4cca8d77290f61e30

from __future__ import print_function, division from sympy import S from sympy.core.basic import Basic from sympy.core.containers import Tuple from sympy.core.expr import Expr from sympy.core.function import Lambda from sympy.core.logic import fuzzy_bool from sympy.core.symbol import Symbol, Dummy from sympy.logic.boolalg import And, as_Boolean from sympy.sets.contains import Contains from sympy.sets.sets import Set, EmptySet, Union, FiniteSet from sympy.utilities.iterables import sift from sympy.utilities.misc import filldedent class ConditionSet(Set): """ Set of elements which satisfies a given condition. {x | condition(x) is True for x in S} Examples ======== >>> from sympy import Symbol, S, ConditionSet, pi, Eq, sin, Interval >>> from sympy.abc import x, y, z >>> sin_sols = ConditionSet(x, Eq(sin(x), 0), Interval(0, 2*pi)) >>> 2*pi in sin_sols True >>> pi/2 in sin_sols False >>> 3*pi in sin_sols False >>> 5 in ConditionSet(x, x**2 > 4, S.Reals) True If the value is not in the base set, the result is false: >>> 5 in ConditionSet(x, x**2 > 4, Interval(2, 4)) False Notes ===== Symbols with assumptions should be avoided or else the condition may evaluate without consideration of the set: >>> n = Symbol('n', negative=True) >>> cond = (n > 0); cond False >>> ConditionSet(n, cond, S.Integers) EmptySet() In addition, substitution of a dummy symbol can only be done with a generic symbol with matching commutativity or else a symbol that has identical assumptions. If the base set contains the dummy symbol it is logically distinct and will be the target of substitution. >>> c = ConditionSet(x, x < 1, {x, z}) >>> c.subs(x, y) ConditionSet(x, x < 1, {y, z}) A second substitution is needed to change the dummy symbol, too: >>> _.subs(x, y) ConditionSet(y, y < 1, {y, z}) And trying to replace the dummy symbol with anything but a symbol is ignored: the only change possible will be in the base set: >>> ConditionSet(y, y < 1, {y, z}).subs(y, 1) ConditionSet(y, y < 1, {z}) >>> _.subs(y, 1) ConditionSet(y, y < 1, {z}) Notes ===== If no base set is specified, the universal set is implied: >>> ConditionSet(x, x < 1).base_set UniversalSet Although expressions other than symbols may be used, this is discouraged and will raise an error if the expression is not found in the condition: >>> ConditionSet(x + 1, x + 1 < 1, S.Integers) ConditionSet(x + 1, x + 1 < 1, Integers) >>> ConditionSet(x + 1, x < 1, S.Integers) Traceback (most recent call last): ... ValueError: non-symbol dummy not recognized in condition Although the name is usually respected, it must be replaced if the base set is another ConditionSet and the dummy symbol and appears as a free symbol in the base set and the dummy symbol of the base set appears as a free symbol in the condition: >>> ConditionSet(x, x < y, ConditionSet(y, x + y < 2, S.Integers)) ConditionSet(lambda, (lambda < y) & (lambda + x < 2), Integers) The best way to do anything with the dummy symbol is to access it with the sym property. >>> _.subs(_.sym, Symbol('_x')) ConditionSet(_x, (_x < y) & (_x + x < 2), Integers) """ def __new__(cls, sym, condition, base_set=S.UniversalSet): # nonlinsolve uses ConditionSet to return an unsolved system # of equations (see _return_conditionset in solveset) so until # that is changed we do minimal checking of the args if isinstance(sym, (Tuple, tuple)): # unsolved eqns syntax sym = Tuple(*sym) condition = FiniteSet(*condition) return Basic.__new__(cls, sym, condition, base_set) condition = as_Boolean(condition) if isinstance(base_set, set): base_set = FiniteSet(*base_set) elif not isinstance(base_set, Set): raise TypeError('expecting set for base_set') if condition is S.false: return S.EmptySet if condition is S.true: return base_set if isinstance(base_set, EmptySet): return base_set know = None if isinstance(base_set, FiniteSet): sifted = sift( base_set, lambda _: fuzzy_bool( condition.subs(sym, _))) if sifted[None]: know = FiniteSet(*sifted[True]) base_set = FiniteSet(*sifted[None]) else: return FiniteSet(*sifted[True]) if isinstance(base_set, cls): s, c, base_set = base_set.args if sym == s: condition = And(condition, c) elif sym not in c.free_symbols: condition = And(condition, c.xreplace({s: sym})) elif s not in condition.free_symbols: condition = And(condition.xreplace({sym: s}), c) sym = s else: # user will have to use cls.sym to get symbol dum = Symbol('lambda') if dum in condition.free_symbols or \ dum in c.free_symbols: dum = Dummy(str(dum)) condition = And( condition.xreplace({sym: dum}), c.xreplace({s: dum})) sym = dum if not isinstance(sym, Symbol): s = Dummy('lambda') if s not in condition.xreplace({sym: s}).free_symbols: raise ValueError( 'non-symbol dummy not recognized in condition') rv = Basic.__new__(cls, sym, condition, base_set) return rv if know is None else Union(know, rv) sym = property(lambda self: self.args[0]) condition = property(lambda self: self.args[1]) base_set = property(lambda self: self.args[2]) @property def free_symbols(self): s, c, b = self.args return (c.free_symbols - s.free_symbols) | b.free_symbols def contains(self, other): return And(Lambda(self.sym, self.condition)( other), self.base_set.contains(other)) def _eval_subs(self, old, new): if not isinstance(self.sym, Expr): # Don't do anything with the equation set syntax; # that should go away, eventually. return self sym, cond, base = self.args if old == sym: # we try to be as lenient as possible to allow # the dummy symbol to be changed base = base.subs(old, new) if isinstance(new, Symbol): # if the assumptions don't match, the cond # might evaluate or change if (new.assumptions0 == old.assumptions0 or len(new.assumptions0) == 1 and old.is_commutative == new.is_commutative): if base != self.base_set: # it will be aggravating to have the dummy # symbol change if you are trying to target # the base set so if the base set is changed # leave the dummy symbol alone -- a second # subs will be needed to change the dummy return self.func(sym, cond, base) else: return self.func(new, cond.subs(old, new), base) raise ValueError(filldedent(''' A dummy symbol can only be replaced with a symbol having the same assumptions or one having a single assumption having the same commutativity. ''')) # don't target cond: it is there to tell how # the base set should be filtered and if new is not in # the base set then this substitution is ignored return self.func(sym, cond, base) cond = self.condition.subs(old, new) base = self.base_set.subs(old, new) if cond is S.true: return ConditionSet(new, Contains(new, base), base) return self.func(self.sym, cond, base) def dummy_eq(self, other, symbol=None): if not isinstance(other, self.func): return False if isinstance(self.sym, Symbol) != isinstance(other.sym, Symbol): # this test won't be necessary when unsolved equations # syntax is removed return False if symbol: raise ValueError('symbol arg not supported for ConditionSet') o = other if isinstance(self.sym, Symbol) and isinstance(other.sym, Symbol): # this code will not need to be in an if-block when # the unsolved equations syntax is removed o = other.func(self.sym, other.condition.subs(other.sym, self.sym), other.base_set) return self == o

f0a2fb02dddc9c3ac40edcb3a22ec781fadc6b87c7baae62418e0181b3241605

from __future__ import unicode_literals from sympy import (EmptySet, FiniteSet, S, Symbol, Interval, exp, erf, sqrt, symbols, simplify, Eq, cos, And, Tuple, integrate, oo, sin, Sum, Basic, DiracDelta, Lambda, log, pi) from sympy.stats import (Die, Normal, Exponential, FiniteRV, P, E, H, variance, covariance, skewness, density, given, independent, dependent, where, pspace, random_symbols, sample, Geometric) from sympy.stats.rv import (IndependentProductPSpace, rs_swap, Density, NamedArgsMixin, RandomSymbol, PSpace) from sympy.utilities.pytest import raises, XFAIL from sympy.core.compatibility import range from sympy.abc import x def test_where(): X, Y = Die('X'), Die('Y') Z = Normal('Z', 0, 1) assert where(Z**2 <= 1).set == Interval(-1, 1) assert where( Z**2 <= 1).as_boolean() == Interval(-1, 1).as_relational(Z.symbol) assert where(And(X > Y, Y > 4)).as_boolean() == And( Eq(X.symbol, 6), Eq(Y.symbol, 5)) assert len(where(X < 3).set) == 2 assert 1 in where(X < 3).set X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) assert where(And(X**2 <= 1, X >= 0)).set == Interval(0, 1) XX = given(X, And(X**2 <= 1, X >= 0)) assert XX.pspace.domain.set == Interval(0, 1) assert XX.pspace.domain.as_boolean() == \ And(0 <= X.symbol, X.symbol**2 <= 1, -oo < X.symbol, X.symbol < oo) with raises(TypeError): XX = given(X, X + 3) def test_random_symbols(): X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) assert set(random_symbols(2*X + 1)) == set((X,)) assert set(random_symbols(2*X + Y)) == set((X, Y)) assert set(random_symbols(2*X + Y.symbol)) == set((X,)) assert set(random_symbols(2)) == set() def test_pspace(): X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) raises(ValueError, lambda: pspace(5 + 3)) raises(ValueError, lambda: pspace(x < 1)) assert pspace(X) == X.pspace assert pspace(2*X + 1) == X.pspace assert pspace(2*X + Y) == IndependentProductPSpace(Y.pspace, X.pspace) def test_rs_swap(): X = Normal('x', 0, 1) Y = Exponential('y', 1) XX = Normal('x', 0, 2) YY = Normal('y', 0, 3) expr = 2*X + Y assert expr.subs(rs_swap((X, Y), (YY, XX))) == 2*XX + YY def test_RandomSymbol(): X = Normal('x', 0, 1) Y = Normal('x', 0, 2) assert X.symbol == Y.symbol assert X != Y assert X.name == X.symbol.name X = Normal('lambda', 0, 1) # make sure we can use protected terms X = Normal('Lambda', 0, 1) # make sure we can use SymPy terms def test_RandomSymbol_diff(): X = Normal('x', 0, 1) assert (2*X).diff(X) def test_random_symbol_no_pspace(): x = RandomSymbol(Symbol('x')) assert x.pspace == PSpace() def test_overlap(): X = Normal('x', 0, 1) Y = Normal('x', 0, 2) raises(ValueError, lambda: P(X > Y)) def test_IndependentProductPSpace(): X = Normal('X', 0, 1) Y = Normal('Y', 0, 1) px = X.pspace py = Y.pspace assert pspace(X + Y) == IndependentProductPSpace(px, py) assert pspace(X + Y) == IndependentProductPSpace(py, px) def test_E(): assert E(5) == 5 def test_H(): X = Normal('X', 0, 1) D = Die('D', sides = 4) G = Geometric('G', 0.5) assert H(X, X > 0) == -log(2)/2 + S(1)/2 + log(pi)/2 assert H(D, D > 2) == log(2) assert H(G).evalf().round(2) == 1.39 def test_Sample(): X = Die('X', 6) Y = Normal('Y', 0, 1) z = Symbol('z') assert sample(X) in [1, 2, 3, 4, 5, 6] assert sample(X + Y).is_Float P(X + Y > 0, Y < 0, numsamples=10).is_number assert E(X + Y, numsamples=10).is_number assert variance(X + Y, numsamples=10).is_number raises(ValueError, lambda: P(Y > z, numsamples=5)) assert P(sin(Y) <= 1, numsamples=10) == 1 assert P(sin(Y) <= 1, cos(Y) < 1, numsamples=10) == 1 # Make sure this doesn't raise an error E(Sum(1/z**Y, (z, 1, oo)), Y > 2, numsamples=3) assert all(i in range(1, 7) for i in density(X, numsamples=10)) assert all(i in range(4, 7) for i in density(X, X>3, numsamples=10)) def test_given(): X = Normal('X', 0, 1) Y = Normal('Y', 0, 1) A = given(X, True) B = given(X, Y > 2) assert X == A == B def test_dependence(): X, Y = Die('X'), Die('Y') assert independent(X, 2*Y) assert not dependent(X, 2*Y) X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) assert independent(X, Y) assert dependent(X, 2*X) # Create a dependency XX, YY = given(Tuple(X, Y), Eq(X + Y, 3)) assert dependent(XX, YY) @XFAIL def test_dependent_finite(): X, Y = Die('X'), Die('Y') # Dependence testing requires symbolic conditions which currently break # finite random variables assert dependent(X, Y + X) XX, YY = given(Tuple(X, Y), X + Y > 5) # Create a dependency assert dependent(XX, YY) def test_normality(): X, Y = Normal('X', 0, 1), Normal('Y', 0, 1) x, z = symbols('x, z', real=True, finite=True) dens = density(X - Y, Eq(X + Y, z)) assert integrate(dens(x), (x, -oo, oo)) == 1 def test_Density(): X = Die('X', 6) d = Density(X) assert d.doit() == density(X) def test_NamedArgsMixin(): class Foo(Basic, NamedArgsMixin): _argnames = 'foo', 'bar' a = Foo(1, 2) assert a.foo == 1 assert a.bar == 2 raises(AttributeError, lambda: a.baz) class Bar(Basic, NamedArgsMixin): pass raises(AttributeError, lambda: Bar(1, 2).foo) def test_density_constant(): assert density(3)(2) == 0 assert density(3)(3) == DiracDelta(0) def test_real(): x = Normal('x', 0, 1) assert x.is_real def test_issue_10052(): X = Exponential('X', 3) assert P(X < oo) == 1 assert P(X > oo) == 0 assert P(X < 2, X > oo) == 0 assert P(X < oo, X > oo) == 0 assert P(X < oo, X > 2) == 1 assert P(X < 3, X == 2) == 0 raises(ValueError, lambda: P(1)) raises(ValueError, lambda: P(X < 1, 2)) def test_issue_11934(): density = {0: .5, 1: .5} X = FiniteRV('X', density) assert E(X) == 0.5 assert P( X>= 2) == 0 def test_issue_8129(): X = Exponential('X', 4) assert P(X >= X) == 1 assert P(X > X) == 0 assert P(X > X+1) == 0

2b3e01dc76479f9dc2f962e24fe8254652027eee160efd66559c7d45cb7228af

import sympy import tempfile import os from sympy import symbols, Eq, Mod from sympy.external import import_module from sympy.tensor import IndexedBase, Idx from sympy.utilities.autowrap import autowrap, ufuncify, CodeWrapError from sympy.utilities.pytest import skip numpy = import_module('numpy', min_module_version='1.6.1') Cython = import_module('Cython', min_module_version='0.15.1') f2py = import_module('numpy.f2py', __import__kwargs={'fromlist': ['f2py']}) f2pyworks = False if f2py: try: autowrap(symbols('x'), 'f95', 'f2py') except (CodeWrapError, ImportError, OSError): f2pyworks = False else: f2pyworks = True a, b, c = symbols('a b c') n, m, d = symbols('n m d', integer=True) A, B, C = symbols('A B C', cls=IndexedBase) i = Idx('i', m) j = Idx('j', n) k = Idx('k', d) def has_module(module): """ Return True if module exists, otherwise run skip(). module should be a string. """ # To give a string of the module name to skip(), this function takes a # string. So we don't waste time running import_module() more than once, # just map the three modules tested here in this dict. modnames = {'numpy': numpy, 'Cython': Cython, 'f2py': f2py} if modnames[module]: if module == 'f2py' and not f2pyworks: skip("Couldn't run f2py.") return True skip("Couldn't import %s." % module) # # test runners used by several language-backend combinations # def runtest_autowrap_twice(language, backend): f = autowrap((((a + b)/c)**5).expand(), language, backend) g = autowrap((((a + b)/c)**4).expand(), language, backend) # check that autowrap updates the module name. Else, g gives the same as f assert f(1, -2, 1) == -1.0 assert g(1, -2, 1) == 1.0 def runtest_autowrap_trace(language, backend): has_module('numpy') trace = autowrap(A[i, i], language, backend) assert trace(numpy.eye(100)) == 100 def runtest_autowrap_matrix_vector(language, backend): has_module('numpy') x, y = symbols('x y', cls=IndexedBase) expr = Eq(y[i], A[i, j]*x[j]) mv = autowrap(expr, language, backend) # compare with numpy's dot product M = numpy.random.rand(10, 20) x = numpy.random.rand(20) y = numpy.dot(M, x) assert numpy.sum(numpy.abs(y - mv(M, x))) < 1e-13 def runtest_autowrap_matrix_matrix(language, backend): has_module('numpy') expr = Eq(C[i, j], A[i, k]*B[k, j]) matmat = autowrap(expr, language, backend) # compare with numpy's dot product M1 = numpy.random.rand(10, 20) M2 = numpy.random.rand(20, 15) M3 = numpy.dot(M1, M2) assert numpy.sum(numpy.abs(M3 - matmat(M1, M2))) < 1e-13 def runtest_ufuncify(language, backend): has_module('numpy') a, b, c = symbols('a b c') fabc = ufuncify([a, b, c], a*b + c, backend=backend) facb = ufuncify([a, c, b], a*b + c, backend=backend) grid = numpy.linspace(-2, 2, 50) b = numpy.linspace(-5, 4, 50) c = numpy.linspace(-1, 1, 50) expected = grid*b + c numpy.testing.assert_allclose(fabc(grid, b, c), expected) numpy.testing.assert_allclose(facb(grid, c, b), expected) def runtest_issue_10274(language, backend): expr = (a - b + c)**(13) tmp = tempfile.mkdtemp() f = autowrap(expr, language, backend, tempdir=tmp, helpers=('helper', a - b + c, (a, b, c))) assert f(1, 1, 1) == 1 for file in os.listdir(tmp): if file.startswith("wrapped_code_") and file.endswith(".c"): fil = open(tmp + '/' + file) lines = fil.readlines() assert lines[0] == "/******************************************************************************\n" assert "Code generated with sympy " + sympy.__version__ in lines[1] assert lines[2:] == [ " * *\n", " * See http://www.sympy.org/ for more information. *\n", " * *\n", " * This file is part of 'autowrap' *\n", " ******************************************************************************/\n", "#include " + '"' + file[:-1]+ 'h"' + "\n", "#include <math.h>\n", "\n", "double helper(double a, double b, double c) {\n", "\n", " double helper_result;\n", " helper_result = a - b + c;\n", " return helper_result;\n", "\n", "}\n", "\n", "double autofunc(double a, double b, double c) {\n", "\n", " double autofunc_result;\n", " autofunc_result = pow(helper(a, b, c), 13);\n", " return autofunc_result;\n", "\n", "}\n", ] def runtest_issue_15337(language, backend): has_module('numpy') # NOTE : autowrap was originally designed to only accept an iterable for # the kwarg "helpers", but in issue 10274 the user mistakenly thought that # if there was only a single helper it did not need to be passed via an # iterable that wrapped the helper tuple. There were no tests for this # behavior so when the code was changed to accept a single tuple it broke # the original behavior. These tests below ensure that both now work. a, b, c, d, e = symbols('a, b, c, d, e') expr = (a - b + c - d + e)**13 exp_res = (1. - 2. + 3. - 4. + 5.)**13 f = autowrap(expr, language, backend, args=(a, b, c, d, e), helpers=('f1', a - b + c, (a, b, c))) numpy.testing.assert_allclose(f(1, 2, 3, 4, 5), exp_res) f = autowrap(expr, language, backend, args=(a, b, c, d, e), helpers=(('f1', a - b, (a, b)), ('f2', c - d, (c, d)))) numpy.testing.assert_allclose(f(1, 2, 3, 4, 5), exp_res) def test_issue_15230(): has_module('f2py') x, y = symbols('x, y') expr = Mod(x, 3.0) - Mod(y, -2.0) f = autowrap(expr, args=[x, y], language='F95') exp_res = float(expr.xreplace({x: 3.5, y: 2.7}).evalf()) assert abs(f(3.5, 2.7) - exp_res) < 1e-14 x, y = symbols('x, y', integer=True) expr = Mod(x, 3) - Mod(y, -2) f = autowrap(expr, args=[x, y], language='F95') assert f(3, 2) == expr.xreplace({x: 3, y: 2}) # # tests of language-backend combinations # # f2py def test_wrap_twice_f95_f2py(): has_module('f2py') runtest_autowrap_twice('f95', 'f2py') def test_autowrap_trace_f95_f2py(): has_module('f2py') runtest_autowrap_trace('f95', 'f2py') def test_autowrap_matrix_vector_f95_f2py(): has_module('f2py') runtest_autowrap_matrix_vector('f95', 'f2py') def test_autowrap_matrix_matrix_f95_f2py(): has_module('f2py') runtest_autowrap_matrix_matrix('f95', 'f2py') def test_ufuncify_f95_f2py(): has_module('f2py') runtest_ufuncify('f95', 'f2py') def test_issue_15337_f95_f2py(): has_module('f2py') runtest_issue_15337('f95', 'f2py') # Cython def test_wrap_twice_c_cython(): has_module('Cython') runtest_autowrap_twice('C', 'cython') def test_autowrap_trace_C_Cython(): has_module('Cython') runtest_autowrap_trace('C99', 'cython') def test_autowrap_matrix_vector_C_cython(): has_module('Cython') runtest_autowrap_matrix_vector('C99', 'cython') def test_autowrap_matrix_matrix_C_cython(): has_module('Cython') runtest_autowrap_matrix_matrix('C99', 'cython') def test_ufuncify_C_Cython(): has_module('Cython') runtest_ufuncify('C99', 'cython') def test_issue_10274_C_cython(): has_module('Cython') runtest_issue_10274('C89', 'cython') def test_issue_15337_C_cython(): has_module('Cython') runtest_issue_15337('C89', 'cython') def test_autowrap_custom_printer(): has_module('Cython') from sympy import pi from sympy.utilities.codegen import C99CodeGen from sympy.printing.ccode import C99CodePrinter from sympy.functions.elementary.exponential import exp class PiPrinter(C99CodePrinter): def _print_Pi(self, expr): return "S_PI" printer = PiPrinter() gen = C99CodeGen(printer=printer) gen.preprocessor_statements.append('#include "shortpi.h"') expr = pi * a expected = ( '#include "%s"\n' '#include <math.h>\n' '#include "shortpi.h"\n' '\n' 'double autofunc(double a) {\n' '\n' ' double autofunc_result;\n' ' autofunc_result = S_PI*a;\n' ' return autofunc_result;\n' '\n' '}\n' ) tmpdir = tempfile.mkdtemp() # write a trivial header file to use in the generated code open(os.path.join(tmpdir, 'shortpi.h'), 'w').write('#define S_PI 3.14') func = autowrap(expr, backend='cython', tempdir=tmpdir, code_gen=gen) assert func(4.2) == 3.14 * 4.2 # check that the generated code is correct for filename in os.listdir(tmpdir): if filename.startswith('wrapped_code') and filename.endswith('.c'): with open(os.path.join(tmpdir, filename)) as f: lines = f.readlines() expected = expected % filename.replace('.c', '.h') assert ''.join(lines[7:]) == expected # Numpy def test_ufuncify_numpy(): # This test doesn't use Cython, but if Cython works, then there is a valid # C compiler, which is needed. has_module('Cython') runtest_ufuncify('C99', 'numpy')

6f77352982e364f266138e1dbbe97b8b2c872ff354ce0a208ee976e61a2eafd0

from sympy import ( sqrt, Derivative, symbols, collect, Function, factor, Wild, S, collect_const, log, fraction, I, cos, Add, O,sin, rcollect, Mul, radsimp, diff, root, Symbol, Rational, exp) from sympy.core.mul import _unevaluated_Mul as umul from sympy.simplify.radsimp import _unevaluated_Add, collect_sqrt, fraction_expand from sympy.utilities.pytest import XFAIL, raises from sympy.abc import x, y, z, a, b, c, d def test_radsimp(): r2 = sqrt(2) r3 = sqrt(3) r5 = sqrt(5) r7 = sqrt(7) assert fraction(radsimp(1/r2)) == (sqrt(2), 2) assert radsimp(1/(1 + r2)) == \ -1 + sqrt(2) assert radsimp(1/(r2 + r3)) == \ -sqrt(2) + sqrt(3) assert fraction(radsimp(1/(1 + r2 + r3))) == \ (-sqrt(6) + sqrt(2) + 2, 4) assert fraction(radsimp(1/(r2 + r3 + r5))) == \ (-sqrt(30) + 2*sqrt(3) + 3*sqrt(2), 12) assert fraction(radsimp(1/(1 + r2 + r3 + r5))) == ( (-34*sqrt(10) - 26*sqrt(15) - 55*sqrt(3) - 61*sqrt(2) + 14*sqrt(30) + 93 + 46*sqrt(6) + 53*sqrt(5), 71)) assert fraction(radsimp(1/(r2 + r3 + r5 + r7))) == ( (-50*sqrt(42) - 133*sqrt(5) - 34*sqrt(70) - 145*sqrt(3) + 22*sqrt(105) + 185*sqrt(2) + 62*sqrt(30) + 135*sqrt(7), 215)) z = radsimp(1/(1 + r2/3 + r3/5 + r5 + r7)) assert len((3616791619821680643598*z).args) == 16 assert radsimp(1/z) == 1/z assert radsimp(1/z, max_terms=20).expand() == 1 + r2/3 + r3/5 + r5 + r7 assert radsimp(1/(r2*3)) == \ sqrt(2)/6 assert radsimp(1/(r2*a + r3 + r5 + r7)) == ( (8*sqrt(2)*a**7 - 8*sqrt(7)*a**6 - 8*sqrt(5)*a**6 - 8*sqrt(3)*a**6 - 180*sqrt(2)*a**5 + 8*sqrt(30)*a**5 + 8*sqrt(42)*a**5 + 8*sqrt(70)*a**5 - 24*sqrt(105)*a**4 + 84*sqrt(3)*a**4 + 100*sqrt(5)*a**4 + 116*sqrt(7)*a**4 - 72*sqrt(70)*a**3 - 40*sqrt(42)*a**3 - 8*sqrt(30)*a**3 + 782*sqrt(2)*a**3 - 462*sqrt(3)*a**2 - 302*sqrt(7)*a**2 - 254*sqrt(5)*a**2 + 120*sqrt(105)*a**2 - 795*sqrt(2)*a - 62*sqrt(30)*a + 82*sqrt(42)*a + 98*sqrt(70)*a - 118*sqrt(105) + 59*sqrt(7) + 295*sqrt(5) + 531*sqrt(3))/(16*a**8 - 480*a**6 + 3128*a**4 - 6360*a**2 + 3481)) assert radsimp(1/(r2*a + r2*b + r3 + r7)) == ( (sqrt(2)*a*(a + b)**2 - 5*sqrt(2)*a + sqrt(42)*a + sqrt(2)*b*(a + b)**2 - 5*sqrt(2)*b + sqrt(42)*b - sqrt(7)*(a + b)**2 - sqrt(3)*(a + b)**2 - 2*sqrt(3) + 2*sqrt(7))/(2*a**4 + 8*a**3*b + 12*a**2*b**2 - 20*a**2 + 8*a*b**3 - 40*a*b + 2*b**4 - 20*b**2 + 8)) assert radsimp(1/(r2*a + r2*b + r2*c + r2*d)) == \ sqrt(2)/(2*a + 2*b + 2*c + 2*d) assert radsimp(1/(1 + r2*a + r2*b + r2*c + r2*d)) == ( (sqrt(2)*a + sqrt(2)*b + sqrt(2)*c + sqrt(2)*d - 1)/(2*a**2 + 4*a*b + 4*a*c + 4*a*d + 2*b**2 + 4*b*c + 4*b*d + 2*c**2 + 4*c*d + 2*d**2 - 1)) assert radsimp((y**2 - x)/(y - sqrt(x))) == \ sqrt(x) + y assert radsimp(-(y**2 - x)/(y - sqrt(x))) == \ -(sqrt(x) + y) assert radsimp(1/(1 - I + a*I)) == \ (-I*a + 1 + I)/(a**2 - 2*a + 2) assert radsimp(1/((-x + y)*(x - sqrt(y)))) == \ (-x - sqrt(y))/((x - y)*(x**2 - y)) e = (3 + 3*sqrt(2))*x*(3*x - 3*sqrt(y)) assert radsimp(e) == x*(3 + 3*sqrt(2))*(3*x - 3*sqrt(y)) assert radsimp(1/e) == ( (-9*x + 9*sqrt(2)*x - 9*sqrt(y) + 9*sqrt(2)*sqrt(y))/(9*x*(9*x**2 - 9*y))) assert radsimp(1 + 1/(1 + sqrt(3))) == \ Mul(S.Half, -1 + sqrt(3), evaluate=False) + 1 A = symbols("A", commutative=False) assert radsimp(x**2 + sqrt(2)*x**2 - sqrt(2)*x*A) == \ x**2 + sqrt(2)*x**2 - sqrt(2)*x*A assert radsimp(1/sqrt(5 + 2 * sqrt(6))) == -sqrt(2) + sqrt(3) assert radsimp(1/sqrt(5 + 2 * sqrt(6))**3) == -(-sqrt(3) + sqrt(2))**3 # issue 6532 assert fraction(radsimp(1/sqrt(x))) == (sqrt(x), x) assert fraction(radsimp(1/sqrt(2*x + 3))) == (sqrt(2*x + 3), 2*x + 3) assert fraction(radsimp(1/sqrt(2*(x + 3)))) == (sqrt(2*x + 6), 2*x + 6) # issue 5994 e = S('-(2 + 2*sqrt(2) + 4*2**(1/4))/' '(1 + 2**(3/4) + 3*2**(1/4) + 3*sqrt(2))') assert radsimp(e).expand() == -2*2**(S(3)/4) - 2*2**(S(1)/4) + 2 + 2*sqrt(2) # issue 5986 (modifications to radimp didn't initially recognize this so # the test is included here) assert radsimp(1/(-sqrt(5)/2 - S(1)/2 + (-sqrt(5)/2 - S(1)/2)**2)) == 1 # from issue 5934 eq = ( (-240*sqrt(2)*sqrt(sqrt(5) + 5)*sqrt(8*sqrt(5) + 40) - 360*sqrt(2)*sqrt(-8*sqrt(5) + 40)*sqrt(-sqrt(5) + 5) - 120*sqrt(10)*sqrt(-8*sqrt(5) + 40)*sqrt(-sqrt(5) + 5) + 120*sqrt(2)*sqrt(-sqrt(5) + 5)*sqrt(8*sqrt(5) + 40) + 120*sqrt(2)*sqrt(-8*sqrt(5) + 40)*sqrt(sqrt(5) + 5) + 120*sqrt(10)*sqrt(-sqrt(5) + 5)*sqrt(8*sqrt(5) + 40) + 120*sqrt(10)*sqrt(-8*sqrt(5) + 40)*sqrt(sqrt(5) + 5))/(-36000 - 7200*sqrt(5) + (12*sqrt(10)*sqrt(sqrt(5) + 5) + 24*sqrt(10)*sqrt(-sqrt(5) + 5))**2)) assert radsimp(eq) is S.NaN # it's 0/0 # work with normal form e = 1/sqrt(sqrt(7)/7 + 2*sqrt(2) + 3*sqrt(3) + 5*sqrt(5)) + 3 assert radsimp(e) == ( -sqrt(sqrt(7) + 14*sqrt(2) + 21*sqrt(3) + 35*sqrt(5))*(-11654899*sqrt(35) - 1577436*sqrt(210) - 1278438*sqrt(15) - 1346996*sqrt(10) + 1635060*sqrt(6) + 5709765 + 7539830*sqrt(14) + 8291415*sqrt(21))/1300423175 + 3) # obey power rules base = sqrt(3) - sqrt(2) assert radsimp(1/base**3) == (sqrt(3) + sqrt(2))**3 assert radsimp(1/(-base)**3) == -(sqrt(2) + sqrt(3))**3 assert radsimp(1/(-base)**x) == (-base)**(-x) assert radsimp(1/base**x) == (sqrt(2) + sqrt(3))**x assert radsimp(root(1/(-1 - sqrt(2)), -x)) == (-1)**(-1/x)*(1 + sqrt(2))**(1/x) # recurse e = cos(1/(1 + sqrt(2))) assert radsimp(e) == cos(-sqrt(2) + 1) assert radsimp(e/2) == cos(-sqrt(2) + 1)/2 assert radsimp(1/e) == 1/cos(-sqrt(2) + 1) assert radsimp(2/e) == 2/cos(-sqrt(2) + 1) assert fraction(radsimp(e/sqrt(x))) == (sqrt(x)*cos(-sqrt(2)+1), x) # test that symbolic denominators are not processed r = 1 + sqrt(2) assert radsimp(x/r, symbolic=False) == -x*(-sqrt(2) + 1) assert radsimp(x/(y + r), symbolic=False) == x/(y + 1 + sqrt(2)) assert radsimp(x/(y + r)/r, symbolic=False) == \ -x*(-sqrt(2) + 1)/(y + 1 + sqrt(2)) # issue 7408 eq = sqrt(x)/sqrt(y) assert radsimp(eq) == umul(sqrt(x), sqrt(y), 1/y) assert radsimp(eq, symbolic=False) == eq # issue 7498 assert radsimp(sqrt(x)/sqrt(y)**3) == umul(sqrt(x), sqrt(y**3), 1/y**3) # for coverage eq = sqrt(x)/y**2 assert radsimp(eq) == eq def test_radsimp_issue_3214(): c, p = symbols('c p', positive=True) s = sqrt(c**2 - p**2) b = (c + I*p - s)/(c + I*p + s) assert radsimp(b) == -I*(c + I*p - sqrt(c**2 - p**2))**2/(2*c*p) def test_collect_1(): """Collect with respect to a Symbol""" x, y, z, n = symbols('x,y,z,n') assert collect(1, x) == 1 assert collect( x + y*x, x ) == x * (1 + y) assert collect( x + x**2, x ) == x + x**2 assert collect( x**2 + y*x**2, x ) == (x**2)*(1 + y) assert collect( x**2 + y*x, x ) == x*y + x**2 assert collect( 2*x**2 + y*x**2 + 3*x*y, [x] ) == x**2*(2 + y) + 3*x*y assert collect( 2*x**2 + y*x**2 + 3*x*y, [y] ) == 2*x**2 + y*(x**2 + 3*x) assert collect( ((1 + y + x)**4).expand(), x) == ((1 + y)**4).expand() + \ x*(4*(1 + y)**3).expand() + x**2*(6*(1 + y)**2).expand() + \ x**3*(4*(1 + y)).expand() + x**4 # symbols can be given as any iterable expr = x + y assert collect(expr, expr.free_symbols) == expr def test_collect_2(): """Collect with respect to a sum""" a, b, x = symbols('a,b,x') assert collect(a*(cos(x) + sin(x)) + b*(cos(x) + sin(x)), sin(x) + cos(x)) == (a + b)*(cos(x) + sin(x)) def test_collect_3(): """Collect with respect to a product""" a, b, c = symbols('a,b,c') f = Function('f') x, y, z, n = symbols('x,y,z,n') assert collect(-x/8 + x*y, -x) == x*(y - S(1)/8) assert collect( 1 + x*(y**2), x*y ) == 1 + x*(y**2) assert collect( x*y + a*x*y, x*y) == x*y*(1 + a) assert collect( 1 + x*y + a*x*y, x*y) == 1 + x*y*(1 + a) assert collect(a*x*f(x) + b*(x*f(x)), x*f(x)) == x*(a + b)*f(x) assert collect(a*x*log(x) + b*(x*log(x)), x*log(x)) == x*(a + b)*log(x) assert collect(a*x**2*log(x)**2 + b*(x*log(x))**2, x*log(x)) == \ x**2*log(x)**2*(a + b) # with respect to a product of three symbols assert collect(y*x*z + a*x*y*z, x*y*z) == (1 + a)*x*y*z def test_collect_4(): """Collect with respect to a power""" a, b, c, x = symbols('a,b,c,x') assert collect(a*x**c + b*x**c, x**c) == x**c*(a + b) # issue 6096: 2 stays with c (unless c is integer or x is positive0 assert collect(a*x**(2*c) + b*x**(2*c), x**c) == x**(2*c)*(a + b) def test_collect_5(): """Collect with respect to a tuple""" a, x, y, z, n = symbols('a,x,y,z,n') assert collect(x**2*y**4 + z*(x*y**2)**2 + z + a*z, [x*y**2, z]) in [ z*(1 + a + x**2*y**4) + x**2*y**4, z*(1 + a) + x**2*y**4*(1 + z) ] assert collect((1 + (x + y) + (x + y)**2).expand(), [x, y]) == 1 + y + x*(1 + 2*y) + x**2 + y**2 def test_collect_D(): D = Derivative f = Function('f') x, a, b = symbols('x,a,b') fx = D(f(x), x) fxx = D(f(x), x, x) assert collect(a*fx + b*fx, fx) == (a + b)*fx assert collect(a*D(fx, x) + b*D(fx, x), fx) == (a + b)*D(fx, x) assert collect(a*fxx + b*fxx, fx) == (a + b)*D(fx, x) # issue 4784 assert collect(5*f(x) + 3*fx, fx) == 5*f(x) + 3*fx assert collect(f(x) + f(x)*diff(f(x), x) + x*diff(f(x), x)*f(x), f(x).diff(x)) == \ (x*f(x) + f(x))*D(f(x), x) + f(x) assert collect(f(x) + f(x)*diff(f(x), x) + x*diff(f(x), x)*f(x), f(x).diff(x), exact=True) == \ (x*f(x) + f(x))*D(f(x), x) + f(x) assert collect(1/f(x) + 1/f(x)*diff(f(x), x) + x*diff(f(x), x)/f(x), f(x).diff(x), exact=True) == \ (1/f(x) + x/f(x))*D(f(x), x) + 1/f(x) e = (1 + x*fx + fx)/f(x) assert collect(e.expand(), fx) == fx*(x/f(x) + 1/f(x)) + 1/f(x) def test_collect_func(): f = ((x + a + 1)**3).expand() assert collect(f, x) == a**3 + 3*a**2 + 3*a + x**3 + x**2*(3*a + 3) + \ x*(3*a**2 + 6*a + 3) + 1 assert collect(f, x, factor) == x**3 + 3*x**2*(a + 1) + 3*x*(a + 1)**2 + \ (a + 1)**3 assert collect(f, x, evaluate=False) == { S.One: a**3 + 3*a**2 + 3*a + 1, x: 3*a**2 + 6*a + 3, x**2: 3*a + 3, x**3: 1 } assert collect(f, x, factor, evaluate=False) == { S.One: (a + 1)**3, x: 3*(a + 1)**2, x**2: umul(S(3), a + 1), x**3: 1} def test_collect_order(): a, b, x, t = symbols('a,b,x,t') assert collect(t + t*x + t*x**2 + O(x**3), t) == t*(1 + x + x**2 + O(x**3)) assert collect(t + t*x + x**2 + O(x**3), t) == \ t*(1 + x + O(x**3)) + x**2 + O(x**3) f = a*x + b*x + c*x**2 + d*x**2 + O(x**3) g = x*(a + b) + x**2*(c + d) + O(x**3) assert collect(f, x) == g assert collect(f, x, distribute_order_term=False) == g f = sin(a + b).series(b, 0, 10) assert collect(f, [sin(a), cos(a)]) == \ sin(a)*cos(b).series(b, 0, 10) + cos(a)*sin(b).series(b, 0, 10) assert collect(f, [sin(a), cos(a)], distribute_order_term=False) == \ sin(a)*cos(b).series(b, 0, 10).removeO() + \ cos(a)*sin(b).series(b, 0, 10).removeO() + O(b**10) def test_rcollect(): assert rcollect((x**2*y + x*y + x + y)/(x + y), y) == \ (x + y*(1 + x + x**2))/(x + y) assert rcollect(sqrt(-((x + 1)*(y + 1))), z) == sqrt(-((x + 1)*(y + 1))) def test_collect_D_0(): D = Derivative f = Function('f') x, a, b = symbols('x,a,b') fxx = D(f(x), x, x) assert collect(a*fxx + b*fxx, fxx) == (a + b)*fxx def test_collect_Wild(): """Collect with respect to functions with Wild argument""" a, b, x, y = symbols('a b x y') f = Function('f') w1 = Wild('.1') w2 = Wild('.2') assert collect(f(x) + a*f(x), f(w1)) == (1 + a)*f(x) assert collect(f(x, y) + a*f(x, y), f(w1)) == f(x, y) + a*f(x, y) assert collect(f(x, y) + a*f(x, y), f(w1, w2)) == (1 + a)*f(x, y) assert collect(f(x, y) + a*f(x, y), f(w1, w1)) == f(x, y) + a*f(x, y) assert collect(f(x, x) + a*f(x, x), f(w1, w1)) == (1 + a)*f(x, x) assert collect(a*(x + 1)**y + (x + 1)**y, w1**y) == (1 + a)*(x + 1)**y assert collect(a*(x + 1)**y + (x + 1)**y, w1**b) == \ a*(x + 1)**y + (x + 1)**y assert collect(a*(x + 1)**y + (x + 1)**y, (x + 1)**w2) == \ (1 + a)*(x + 1)**y assert collect(a*(x + 1)**y + (x + 1)**y, w1**w2) == (1 + a)*(x + 1)**y def test_collect_const(): # coverage not provided by above tests assert collect_const(2*sqrt(3) + 4*a*sqrt(5)) == \ 2*(2*sqrt(5)*a + sqrt(3)) # let the primitive reabsorb assert collect_const(2*sqrt(3) + 4*a*sqrt(5), sqrt(3)) == \ 2*sqrt(3) + 4*a*sqrt(5) assert collect_const(sqrt(2)*(1 + sqrt(2)) + sqrt(3) + x*sqrt(2)) == \ sqrt(2)*(x + 1 + sqrt(2)) + sqrt(3) # issue 5290 assert collect_const(2*x + 2*y + 1, 2) == \ collect_const(2*x + 2*y + 1) == \ Add(S(1), Mul(2, x + y, evaluate=False), evaluate=False) assert collect_const(-y - z) == Mul(-1, y + z, evaluate=False) assert collect_const(2*x - 2*y - 2*z, 2) == \ Mul(2, x - y - z, evaluate=False) assert collect_const(2*x - 2*y - 2*z, -2) == \ _unevaluated_Add(2*x, Mul(-2, y + z, evaluate=False)) # this is why the content_primitive is used eq = (sqrt(15 + 5*sqrt(2))*x + sqrt(3 + sqrt(2))*y)*2 assert collect_sqrt(eq + 2) == \ 2*sqrt(sqrt(2) + 3)*(sqrt(5)*x + y) + 2 # issue 16296 assert collect_const(a + b + x/2 + y/2) == a + b + Mul(S.Half, x + y, evaluate=False) def test_issue_13143(): f = Function('f') fx = f(x).diff(x) e = f(x) + fx + f(x)*fx # collect function before derivative assert collect(e, Wild('w')) == f(x)*(fx + 1) + fx e = f(x) + f(x)*fx + x*fx*f(x) assert collect(e, fx) == (x*f(x) + f(x))*fx + f(x) assert collect(e, f(x)) == (x*fx + fx + 1)*f(x) e = f(x) + fx + f(x)*fx assert collect(e, [f(x), fx]) == f(x)*(1 + fx) + fx assert collect(e, [fx, f(x)]) == fx*(1 + f(x)) + f(x) def test_issue_6097(): assert collect(a*y**(2.0*x) + b*y**(2.0*x), y**x) == y**(2.0*x)*(a + b) assert collect(a*2**(2.0*x) + b*2**(2.0*x), 2**x) == 2**(2.0*x)*(a + b) def test_fraction_expand(): eq = (x + y)*y/x assert eq.expand(frac=True) == fraction_expand(eq) == (x*y + y**2)/x assert eq.expand() == y + y**2/x def test_fraction(): x, y, z = map(Symbol, 'xyz') A = Symbol('A', commutative=False) assert fraction(Rational(1, 2)) == (1, 2) assert fraction(x) == (x, 1) assert fraction(1/x) == (1, x) assert fraction(x/y) == (x, y) assert fraction(x/2) == (x, 2) assert fraction(x*y/z) == (x*y, z) assert fraction(x/(y*z)) == (x, y*z) assert fraction(1/y**2) == (1, y**2) assert fraction(x/y**2) == (x, y**2) assert fraction((x**2 + 1)/y) == (x**2 + 1, y) assert fraction(x*(y + 1)/y**7) == (x*(y + 1), y**7) assert fraction(exp(-x), exact=True) == (exp(-x), 1) assert fraction((1/(x + y))/2, exact=True) == (1, Mul(2,(x + y), evaluate=False)) assert fraction(x*A/y) == (x*A, y) assert fraction(x*A**-1/y) == (x*A**-1, y) n = symbols('n', negative=True) assert fraction(exp(n)) == (1, exp(-n)) assert fraction(exp(-n)) == (exp(-n), 1) p = symbols('p', positive=True) assert fraction(exp(-p)*log(p), exact=True) == (exp(-p)*log(p), 1) def test_issue_5615(): aA, Re, a, b, D = symbols('aA Re a b D') e = ((D**3*a + b*aA**3)/Re).expand() assert collect(e, [aA**3/Re, a]) == e def test_issue_5933(): from sympy import Polygon, RegularPolygon, denom x = Polygon(*RegularPolygon((0, 0), 1, 5).vertices).centroid.x assert abs(denom(x).n()) > 1e-12 assert abs(denom(radsimp(x))) > 1e-12 # in case simplify didn't handle it def test_issue_14608(): a, b = symbols('a b', commutative=False) x, y = symbols('x y') raises(AttributeError, lambda: collect(a*b + b*a, a)) assert collect(x*y + y*(x+1), a) == x*y + y*(x+1) assert collect(x*y + y*(x+1) + a*b + b*a, y) == y*(2*x + 1) + a*b + b*a

9d804d08d03e9a109d247f8cefaf29a7343bc415c3719308b0e59b52cf31dced

from sympy import ( Abs, acos, Add, asin, atan, Basic, binomial, besselsimp, collect,cos, cosh, cot, coth, count_ops, csch, Derivative, diff, E, Eq, erf, exp, exp_polar, expand, expand_multinomial, factor, factorial, Float, fraction, Function, gamma, GoldenRatio, hyper, hypersimp, I, Integral, integrate, log, logcombine, Lt, Matrix, MatrixSymbol, Mul, nsimplify, O, oo, pi, Piecewise, posify, rad, Rational, root, S, separatevars, signsimp, simplify, sign, sin, sinc, sinh, solve, sqrt, Sum, Symbol, symbols, sympify, tan, tanh, zoo) from sympy.core.mul import _keep_coeff from sympy.simplify.simplify import nthroot, inversecombine from sympy.utilities.pytest import XFAIL, slow from sympy.core.compatibility import range from sympy.abc import x, y, z, t, a, b, c, d, e, f, g, h, i, k def test_issue_7263(): assert abs((simplify(30.8**2 - 82.5**2 * sin(rad(11.6))**2)).evalf() - \ 673.447451402970) < 1e-12 @XFAIL def test_factorial_simplify(): # There are more tests in test_factorials.py. These are just to # ensure that simplify() calls factorial_simplify correctly from sympy.specfun.factorials import factorial x = Symbol('x') assert simplify(factorial(x)/x) == factorial(x - 1) assert simplify(factorial(factorial(x))) == factorial(factorial(x)) def test_simplify_expr(): x, y, z, k, n, m, w, s, A = symbols('x,y,z,k,n,m,w,s,A') f = Function('f') assert all(simplify(tmp) == tmp for tmp in [I, E, oo, x, -x, -oo, -E, -I]) e = 1/x + 1/y assert e != (x + y)/(x*y) assert simplify(e) == (x + y)/(x*y) e = A**2*s**4/(4*pi*k*m**3) assert simplify(e) == e e = (4 + 4*x - 2*(2 + 2*x))/(2 + 2*x) assert simplify(e) == 0 e = (-4*x*y**2 - 2*y**3 - 2*x**2*y)/(x + y)**2 assert simplify(e) == -2*y e = -x - y - (x + y)**(-1)*y**2 + (x + y)**(-1)*x**2 assert simplify(e) == -2*y e = (x + x*y)/x assert simplify(e) == 1 + y e = (f(x) + y*f(x))/f(x) assert simplify(e) == 1 + y e = (2 * (1/n - cos(n * pi)/n))/pi assert simplify(e) == (-cos(pi*n) + 1)/(pi*n)*2 e = integrate(1/(x**3 + 1), x).diff(x) assert simplify(e) == 1/(x**3 + 1) e = integrate(x/(x**2 + 3*x + 1), x).diff(x) assert simplify(e) == x/(x**2 + 3*x + 1) f = Symbol('f') A = Matrix([[2*k - m*w**2, -k], [-k, k - m*w**2]]).inv() assert simplify((A*Matrix([0, f]))[1]) == \ -f*(2*k - m*w**2)/(k**2 - (k - m*w**2)*(2*k - m*w**2)) f = -x + y/(z + t) + z*x/(z + t) + z*a/(z + t) + t*x/(z + t) assert simplify(f) == (y + a*z)/(z + t) # issue 10347 expr = -x*(y**2 - 1)*(2*y**2*(x**2 - 1)/(a*(x**2 - y**2)**2) + (x**2 - 1) /(a*(x**2 - y**2)))/(a*(x**2 - y**2)) + x*(-2*x**2*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(a*(x**2 - y**2)**2) - x**2*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(a*(x**2 - 1)*(x**2 - y**2)) + (x**2*sqrt((-x**2 + 1)* (y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(x**2 - 1) + sqrt( (-x**2 + 1)*(y**2 - 1))*(x*(-x*y**2 + x)/sqrt(-x**2*y**2 + x**2 + y**2 - 1) + sqrt(-x**2*y**2 + x**2 + y**2 - 1))*sin(z))/(a*sqrt((-x**2 + 1)*( y**2 - 1))*(x**2 - y**2)))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(a* (x**2 - y**2)) + x*(-2*x**2*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a* (x**2 - y**2)**2) - x**2*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a* (x**2 - 1)*(x**2 - y**2)) + (x**2*sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2 *y**2 + x**2 + y**2 - 1)*cos(z)/(x**2 - 1) + x*sqrt((-x**2 + 1)*(y**2 - 1))*(-x*y**2 + x)*cos(z)/sqrt(-x**2*y**2 + x**2 + y**2 - 1) + sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z))/(a*sqrt((-x**2 + 1)*(y**2 - 1))*(x**2 - y**2)))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos( z)/(a*(x**2 - y**2)) - y*sqrt((-x**2 + 1)*(y**2 - 1))*(-x*y*sqrt(-x**2* y**2 + x**2 + y**2 - 1)*sin(z)/(a*(x**2 - y**2)*(y**2 - 1)) + 2*x*y*sqrt( -x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(a*(x**2 - y**2)**2) + (x*y*sqrt(( -x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(y**2 - 1) + x*sqrt((-x**2 + 1)*(y**2 - 1))*(-x**2*y + y)*sin(z)/sqrt(-x**2*y**2 + x**2 + y**2 - 1))/(a*sqrt((-x**2 + 1)*(y**2 - 1))*(x**2 - y**2)))*sin( z)/(a*(x**2 - y**2)) + y*(x**2 - 1)*(-2*x*y*(x**2 - 1)/(a*(x**2 - y**2) **2) + 2*x*y/(a*(x**2 - y**2)))/(a*(x**2 - y**2)) + y*(x**2 - 1)*(y**2 - 1)*(-x*y*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a*(x**2 - y**2)*(y**2 - 1)) + 2*x*y*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a*(x**2 - y**2) **2) + (x*y*sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(y**2 - 1) + x*sqrt((-x**2 + 1)*(y**2 - 1))*(-x**2*y + y)*cos( z)/sqrt(-x**2*y**2 + x**2 + y**2 - 1))/(a*sqrt((-x**2 + 1)*(y**2 - 1) )*(x**2 - y**2)))*cos(z)/(a*sqrt((-x**2 + 1)*(y**2 - 1))*(x**2 - y**2) ) - x*sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin( z)**2/(a**2*(x**2 - 1)*(x**2 - y**2)*(y**2 - 1)) - x*sqrt((-x**2 + 1)*( y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)**2/(a**2*(x**2 - 1)*( x**2 - y**2)*(y**2 - 1)) assert simplify(expr) == 2*x/(a**2*(x**2 - y**2)) A, B = symbols('A,B', commutative=False) assert simplify(A*B - B*A) == A*B - B*A assert simplify(A/(1 + y/x)) == x*A/(x + y) assert simplify(A*(1/x + 1/y)) == A/x + A/y #(x + y)*A/(x*y) assert simplify(log(2) + log(3)) == log(6) assert simplify(log(2*x) - log(2)) == log(x) assert simplify(hyper([], [], x)) == exp(x) def test_issue_3557(): f_1 = x*a + y*b + z*c - 1 f_2 = x*d + y*e + z*f - 1 f_3 = x*g + y*h + z*i - 1 solutions = solve([f_1, f_2, f_3], x, y, z, simplify=False) assert simplify(solutions[y]) == \ (a*i + c*d + f*g - a*f - c*g - d*i)/ \ (a*e*i + b*f*g + c*d*h - a*f*h - b*d*i - c*e*g) def test_simplify_other(): assert simplify(sin(x)**2 + cos(x)**2) == 1 assert simplify(gamma(x + 1)/gamma(x)) == x assert simplify(sin(x)**2 + cos(x)**2 + factorial(x)/gamma(x)) == 1 + x assert simplify( Eq(sin(x)**2 + cos(x)**2, factorial(x)/gamma(x))) == Eq(x, 1) nc = symbols('nc', commutative=False) assert simplify(x + x*nc) == x*(1 + nc) # issue 6123 # f = exp(-I*(k*sqrt(t) + x/(2*sqrt(t)))**2) # ans = integrate(f, (k, -oo, oo), conds='none') ans = I*(-pi*x*exp(-3*I*pi/4 + I*x**2/(4*t))*erf(x*exp(-3*I*pi/4)/ (2*sqrt(t)))/(2*sqrt(t)) + pi*x*exp(-3*I*pi/4 + I*x**2/(4*t))/ (2*sqrt(t)))*exp(-I*x**2/(4*t))/(sqrt(pi)*x) - I*sqrt(pi) * \ (-erf(x*exp(I*pi/4)/(2*sqrt(t))) + 1)*exp(I*pi/4)/(2*sqrt(t)) assert simplify(ans) == -(-1)**(S(3)/4)*sqrt(pi)/sqrt(t) # issue 6370 assert simplify(2**(2 + x)/4) == 2**x def test_simplify_complex(): cosAsExp = cos(x)._eval_rewrite_as_exp(x) tanAsExp = tan(x)._eval_rewrite_as_exp(x) assert simplify(cosAsExp*tanAsExp) == sin(x) # issue 4341 # issue 10124 assert simplify(exp(Matrix([[0, -1], [1, 0]]))) == Matrix([[cos(1), -sin(1)], [sin(1), cos(1)]]) def test_simplify_ratio(): # roots of x**3-3*x+5 roots = ['(1/2 - sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3) + 1/((1/2 - ' 'sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3))', '1/((1/2 + sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3)) + ' '(1/2 + sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3)', '-(sqrt(21)/2 + 5/2)**(1/3) - 1/(sqrt(21)/2 + 5/2)**(1/3)'] for r in roots: r = S(r) assert count_ops(simplify(r, ratio=1)) <= count_ops(r) # If ratio=oo, simplify() is always applied: assert simplify(r, ratio=oo) is not r def test_simplify_measure(): measure1 = lambda expr: len(str(expr)) measure2 = lambda expr: -count_ops(expr) # Return the most complicated result expr = (x + 1)/(x + sin(x)**2 + cos(x)**2) assert measure1(simplify(expr, measure=measure1)) <= measure1(expr) assert measure2(simplify(expr, measure=measure2)) <= measure2(expr) expr2 = Eq(sin(x)**2 + cos(x)**2, 1) assert measure1(simplify(expr2, measure=measure1)) <= measure1(expr2) assert measure2(simplify(expr2, measure=measure2)) <= measure2(expr2) def test_simplify_rational(): expr = 2**x*2.**y assert simplify(expr, rational = True) == 2**(x+y) assert simplify(expr, rational = None) == 2.0**(x+y) assert simplify(expr, rational = False) == expr def test_simplify_issue_1308(): assert simplify(exp(-Rational(1, 2)) + exp(-Rational(3, 2))) == \ (1 + E)*exp(-Rational(3, 2)) def test_issue_5652(): assert simplify(E + exp(-E)) == exp(-E) + E n = symbols('n', commutative=False) assert simplify(n + n**(-n)) == n + n**(-n) def test_simplify_fail1(): x = Symbol('x') y = Symbol('y') e = (x + y)**2/(-4*x*y**2 - 2*y**3 - 2*x**2*y) assert simplify(e) == 1 / (-2*y) def test_nthroot(): assert nthroot(90 + 34*sqrt(7), 3) == sqrt(7) + 3 q = 1 + sqrt(2) - 2*sqrt(3) + sqrt(6) + sqrt(7) assert nthroot(expand_multinomial(q**3), 3) == q assert nthroot(41 + 29*sqrt(2), 5) == 1 + sqrt(2) assert nthroot(-41 - 29*sqrt(2), 5) == -1 - sqrt(2) expr = 1320*sqrt(10) + 4216 + 2576*sqrt(6) + 1640*sqrt(15) assert nthroot(expr, 5) == 1 + sqrt(6) + sqrt(15) q = 1 + sqrt(2) + sqrt(3) + sqrt(5) assert expand_multinomial(nthroot(expand_multinomial(q**5), 5)) == q q = 1 + sqrt(2) + 7*sqrt(6) + 2*sqrt(10) assert nthroot(expand_multinomial(q**5), 5, 8) == q q = 1 + sqrt(2) - 2*sqrt(3) + 1171*sqrt(6) assert nthroot(expand_multinomial(q**3), 3) == q assert nthroot(expand_multinomial(q**6), 6) == q def test_nthroot1(): q = 1 + sqrt(2) + sqrt(3) + S(1)/10**20 p = expand_multinomial(q**5) assert nthroot(p, 5) == q q = 1 + sqrt(2) + sqrt(3) + S(1)/10**30 p = expand_multinomial(q**5) assert nthroot(p, 5) == q def test_separatevars(): x, y, z, n = symbols('x,y,z,n') assert separatevars(2*n*x*z + 2*x*y*z) == 2*x*z*(n + y) assert separatevars(x*z + x*y*z) == x*z*(1 + y) assert separatevars(pi*x*z + pi*x*y*z) == pi*x*z*(1 + y) assert separatevars(x*y**2*sin(x) + x*sin(x)*sin(y)) == \ x*(sin(y) + y**2)*sin(x) assert separatevars(x*exp(x + y) + x*exp(x)) == x*(1 + exp(y))*exp(x) assert separatevars((x*(y + 1))**z).is_Pow # != x**z*(1 + y)**z assert separatevars(1 + x + y + x*y) == (x + 1)*(y + 1) assert separatevars(y/pi*exp(-(z - x)/cos(n))) == \ y*exp(x/cos(n))*exp(-z/cos(n))/pi assert separatevars((x + y)*(x - y) + y**2 + 2*x + 1) == (x + 1)**2 # issue 4858 p = Symbol('p', positive=True) assert separatevars(sqrt(p**2 + x*p**2)) == p*sqrt(1 + x) assert separatevars(sqrt(y*(p**2 + x*p**2))) == p*sqrt(y*(1 + x)) assert separatevars(sqrt(y*(p**2 + x*p**2)), force=True) == \ p*sqrt(y)*sqrt(1 + x) # issue 4865 assert separatevars(sqrt(x*y)).is_Pow assert separatevars(sqrt(x*y), force=True) == sqrt(x)*sqrt(y) # issue 4957 # any type sequence for symbols is fine assert separatevars(((2*x + 2)*y), dict=True, symbols=()) == \ {'coeff': 1, x: 2*x + 2, y: y} # separable assert separatevars(((2*x + 2)*y), dict=True, symbols=[x]) == \ {'coeff': y, x: 2*x + 2} assert separatevars(((2*x + 2)*y), dict=True, symbols=[]) == \ {'coeff': 1, x: 2*x + 2, y: y} assert separatevars(((2*x + 2)*y), dict=True) == \ {'coeff': 1, x: 2*x + 2, y: y} assert separatevars(((2*x + 2)*y), dict=True, symbols=None) == \ {'coeff': y*(2*x + 2)} # not separable assert separatevars(3, dict=True) is None assert separatevars(2*x + y, dict=True, symbols=()) is None assert separatevars(2*x + y, dict=True) is None assert separatevars(2*x + y, dict=True, symbols=None) == {'coeff': 2*x + y} # issue 4808 n, m = symbols('n,m', commutative=False) assert separatevars(m + n*m) == (1 + n)*m assert separatevars(x + x*n) == x*(1 + n) # issue 4910 f = Function('f') assert separatevars(f(x) + x*f(x)) == f(x) + x*f(x) # a noncommutable object present eq = x*(1 + hyper((), (), y*z)) assert separatevars(eq) == eq def test_separatevars_advanced_factor(): x, y, z = symbols('x,y,z') assert separatevars(1 + log(x)*log(y) + log(x) + log(y)) == \ (log(x) + 1)*(log(y) + 1) assert separatevars(1 + x - log(z) - x*log(z) - exp(y)*log(z) - x*exp(y)*log(z) + x*exp(y) + exp(y)) == \ -((x + 1)*(log(z) - 1)*(exp(y) + 1)) x, y = symbols('x,y', positive=True) assert separatevars(1 + log(x**log(y)) + log(x*y)) == \ (log(x) + 1)*(log(y) + 1) def test_hypersimp(): n, k = symbols('n,k', integer=True) assert hypersimp(factorial(k), k) == k + 1 assert hypersimp(factorial(k**2), k) is None assert hypersimp(1/factorial(k), k) == 1/(k + 1) assert hypersimp(2**k/factorial(k)**2, k) == 2/(k + 1)**2 assert hypersimp(binomial(n, k), k) == (n - k)/(k + 1) assert hypersimp(binomial(n + 1, k), k) == (n - k + 1)/(k + 1) term = (4*k + 1)*factorial(k)/factorial(2*k + 1) assert hypersimp(term, k) == (S(1)/2)*((4*k + 5)/(3 + 14*k + 8*k**2)) term = 1/((2*k - 1)*factorial(2*k + 1)) assert hypersimp(term, k) == (k - S(1)/2)/((k + 1)*(2*k + 1)*(2*k + 3)) term = binomial(n, k)*(-1)**k/factorial(k) assert hypersimp(term, k) == (k - n)/(k + 1)**2 def test_nsimplify(): x = Symbol("x") assert nsimplify(0) == 0 assert nsimplify(-1) == -1 assert nsimplify(1) == 1 assert nsimplify(1 + x) == 1 + x assert nsimplify(2.7) == Rational(27, 10) assert nsimplify(1 - GoldenRatio) == (1 - sqrt(5))/2 assert nsimplify((1 + sqrt(5))/4, [GoldenRatio]) == GoldenRatio/2 assert nsimplify(2/GoldenRatio, [GoldenRatio]) == 2*GoldenRatio - 2 assert nsimplify(exp(5*pi*I/3, evaluate=False)) == \ sympify('1/2 - sqrt(3)*I/2') assert nsimplify(sin(3*pi/5, evaluate=False)) == \ sympify('sqrt(sqrt(5)/8 + 5/8)') assert nsimplify(sqrt(atan('1', evaluate=False))*(2 + I), [pi]) == \ sqrt(pi) + sqrt(pi)/2*I assert nsimplify(2 + exp(2*atan('1/4')*I)) == sympify('49/17 + 8*I/17') assert nsimplify(pi, tolerance=0.01) == Rational(22, 7) assert nsimplify(pi, tolerance=0.001) == Rational(355, 113) assert nsimplify(0.33333, tolerance=1e-4) == Rational(1, 3) assert nsimplify(2.0**(1/3.), tolerance=0.001) == Rational(635, 504) assert nsimplify(2.0**(1/3.), tolerance=0.001, full=True) == \ 2**Rational(1, 3) assert nsimplify(x + .5, rational=True) == Rational(1, 2) + x assert nsimplify(1/.3 + x, rational=True) == Rational(10, 3) + x assert nsimplify(log(3).n(), rational=True) == \ sympify('109861228866811/100000000000000') assert nsimplify(Float(0.272198261287950), [pi, log(2)]) == pi*log(2)/8 assert nsimplify(Float(0.272198261287950).n(3), [pi, log(2)]) == \ -pi/4 - log(2) + S(7)/4 assert nsimplify(x/7.0) == x/7 assert nsimplify(pi/1e2) == pi/100 assert nsimplify(pi/1e2, rational=False) == pi/100.0 assert nsimplify(pi/1e-7) == 10000000*pi assert not nsimplify( factor(-3.0*z**2*(z**2)**(-2.5) + 3*(z**2)**(-1.5))).atoms(Float) e = x**0.0 assert e.is_Pow and nsimplify(x**0.0) == 1 assert nsimplify(3.333333, tolerance=0.1, rational=True) == Rational(10, 3) assert nsimplify(3.333333, tolerance=0.01, rational=True) == Rational(10, 3) assert nsimplify(3.666666, tolerance=0.1, rational=True) == Rational(11, 3) assert nsimplify(3.666666, tolerance=0.01, rational=True) == Rational(11, 3) assert nsimplify(33, tolerance=10, rational=True) == Rational(33) assert nsimplify(33.33, tolerance=10, rational=True) == Rational(30) assert nsimplify(37.76, tolerance=10, rational=True) == Rational(40) assert nsimplify(-203.1) == -S(2031)/10 assert nsimplify(.2, tolerance=0) == S.One/5 assert nsimplify(-.2, tolerance=0) == -S.One/5 assert nsimplify(.2222, tolerance=0) == S(1111)/5000 assert nsimplify(-.2222, tolerance=0) == -S(1111)/5000 # issue 7211, PR 4112 assert nsimplify(S(2e-8)) == S(1)/50000000 # issue 7322 direct test assert nsimplify(1e-42, rational=True) != 0 # issue 10336 inf = Float('inf') infs = (-oo, oo, inf, -inf) for i in infs: ans = sign(i)*oo assert nsimplify(i) == ans assert nsimplify(i + x) == x + ans assert nsimplify(0.33333333, rational=True, rational_conversion='exact') == Rational(0.33333333) # Make sure nsimplify on expressions uses full precision assert nsimplify(pi.evalf(100)*x, rational_conversion='exact').evalf(100) == pi.evalf(100)*x def test_issue_9448(): tmp = sympify("1/(1 - (-1)**(2/3) - (-1)**(1/3)) + 1/(1 + (-1)**(2/3) + (-1)**(1/3))") assert nsimplify(tmp) == S(1)/2 def test_extract_minus_sign(): x = Symbol("x") y = Symbol("y") a = Symbol("a") b = Symbol("b") assert simplify(-x/-y) == x/y assert simplify(-x/y) == -x/y assert simplify(x/y) == x/y assert simplify(x/-y) == -x/y assert simplify(-x/0) == zoo*x assert simplify(S(-5)/0) == zoo assert simplify(-a*x/(-y - b)) == a*x/(b + y) def test_diff(): x = Symbol("x") y = Symbol("y") f = Function("f") g = Function("g") assert simplify(g(x).diff(x)*f(x).diff(x) - f(x).diff(x)*g(x).diff(x)) == 0 assert simplify(2*f(x)*f(x).diff(x) - diff(f(x)**2, x)) == 0 assert simplify(diff(1/f(x), x) + f(x).diff(x)/f(x)**2) == 0 assert simplify(f(x).diff(x, y) - f(x).diff(y, x)) == 0 def test_logcombine_1(): x, y = symbols("x,y") a = Symbol("a") z, w = symbols("z,w", positive=True) b = Symbol("b", real=True) assert logcombine(log(x) + 2*log(y)) == log(x) + 2*log(y) assert logcombine(log(x) + 2*log(y), force=True) == log(x*y**2) assert logcombine(a*log(w) + log(z)) == a*log(w) + log(z) assert logcombine(b*log(z) + b*log(x)) == log(z**b) + b*log(x) assert logcombine(b*log(z) - log(w)) == log(z**b/w) assert logcombine(log(x)*log(z)) == log(x)*log(z) assert logcombine(log(w)*log(x)) == log(w)*log(x) assert logcombine(cos(-2*log(z) + b*log(w))) in [cos(log(w**b/z**2)), cos(log(z**2/w**b))] assert logcombine(log(log(x) - log(y)) - log(z), force=True) == \ log(log(x/y)/z) assert logcombine((2 + I)*log(x), force=True) == (2 + I)*log(x) assert logcombine((x**2 + log(x) - log(y))/(x*y), force=True) == \ (x**2 + log(x/y))/(x*y) # the following could also give log(z*x**log(y**2)), what we # are testing is that a canonical result is obtained assert logcombine(log(x)*2*log(y) + log(z), force=True) == \ log(z*y**log(x**2)) assert logcombine((x*y + sqrt(x**4 + y**4) + log(x) - log(y))/(pi*x**Rational(2, 3)* sqrt(y)**3), force=True) == ( x*y + sqrt(x**4 + y**4) + log(x/y))/(pi*x**(S(2)/3)*y**(S(3)/2)) assert logcombine(gamma(-log(x/y))*acos(-log(x/y)), force=True) == \ acos(-log(x/y))*gamma(-log(x/y)) assert logcombine(2*log(z)*log(w)*log(x) + log(z) + log(w)) == \ log(z**log(w**2))*log(x) + log(w*z) assert logcombine(3*log(w) + 3*log(z)) == log(w**3*z**3) assert logcombine(x*(y + 1) + log(2) + log(3)) == x*(y + 1) + log(6) assert logcombine((x + y)*log(w) + (-x - y)*log(3)) == (x + y)*log(w/3) # a single unknown can combine assert logcombine(log(x) + log(2)) == log(2*x) eq = log(abs(x)) + log(abs(y)) assert logcombine(eq) == eq reps = {x: 0, y: 0} assert log(abs(x)*abs(y)).subs(reps) != eq.subs(reps) def test_logcombine_complex_coeff(): i = Integral((sin(x**2) + cos(x**3))/x, x) assert logcombine(i, force=True) == i assert logcombine(i + 2*log(x), force=True) == \ i + log(x**2) def test_issue_5950(): x, y = symbols("x,y", positive=True) assert logcombine(log(3) - log(2)) == log(Rational(3,2), evaluate=False) assert logcombine(log(x) - log(y)) == log(x/y) assert logcombine(log(Rational(3,2), evaluate=False) - log(2)) == \ log(Rational(3,4), evaluate=False) def test_posify(): from sympy.abc import x assert str(posify( x + Symbol('p', positive=True) + Symbol('n', negative=True))) == '(_x + n + p, {_x: x})' eq, rep = posify(1/x) assert log(eq).expand().subs(rep) == -log(x) assert str(posify([x, 1 + x])) == '([_x, _x + 1], {_x: x})' x = symbols('x') p = symbols('p', positive=True) n = symbols('n', negative=True) orig = [x, n, p] modified, reps = posify(orig) assert str(modified) == '[_x, n, p]' assert [w.subs(reps) for w in modified] == orig assert str(Integral(posify(1/x + y)[0], (y, 1, 3)).expand()) == \ 'Integral(1/_x, (y, 1, 3)) + Integral(_y, (y, 1, 3))' assert str(Sum(posify(1/x**n)[0], (n,1,3)).expand()) == \ 'Sum(_x**(-n), (n, 1, 3))' # issue 16438 k = Symbol('k', finite=True) eq, rep = posify(k) assert eq.assumptions0 == {'positive': True, 'zero': False, 'imaginary': False, 'nonpositive': False, 'commutative': True, 'hermitian': True, 'real': True, 'nonzero': True, 'nonnegative': True, 'negative': False, 'complex': True, 'finite': True, 'infinite': False} def test_issue_4194(): # simplify should call cancel from sympy.abc import x, y f = Function('f') assert simplify((4*x + 6*f(y))/(2*x + 3*f(y))) == 2 @XFAIL def test_simplify_float_vs_integer(): # Test for issue 4473: # https://github.com/sympy/sympy/issues/4473 assert simplify(x**2.0 - x**2) == 0 assert simplify(x**2 - x**2.0) == 0 def test_as_content_primitive(): assert (x/2 + y).as_content_primitive() == (S.Half, x + 2*y) assert (x/2 + y).as_content_primitive(clear=False) == (S.One, x/2 + y) assert (y*(x/2 + y)).as_content_primitive() == (S.Half, y*(x + 2*y)) assert (y*(x/2 + y)).as_content_primitive(clear=False) == (S.One, y*(x/2 + y)) # although the _as_content_primitive methods do not alter the underlying structure, # the as_content_primitive function will touch up the expression and join # bases that would otherwise have not been joined. assert ((x*(2 + 2*x)*(3*x + 3)**2)).as_content_primitive() == \ (18, x*(x + 1)**3) assert (2 + 2*x + 2*y*(3 + 3*y)).as_content_primitive() == \ (2, x + 3*y*(y + 1) + 1) assert ((2 + 6*x)**2).as_content_primitive() == \ (4, (3*x + 1)**2) assert ((2 + 6*x)**(2*y)).as_content_primitive() == \ (1, (_keep_coeff(S(2), (3*x + 1)))**(2*y)) assert (5 + 10*x + 2*y*(3 + 3*y)).as_content_primitive() == \ (1, 10*x + 6*y*(y + 1) + 5) assert ((5*(x*(1 + y)) + 2*x*(3 + 3*y))).as_content_primitive() == \ (11, x*(y + 1)) assert ((5*(x*(1 + y)) + 2*x*(3 + 3*y))**2).as_content_primitive() == \ (121, x**2*(y + 1)**2) assert (y**2).as_content_primitive() == \ (1, y**2) assert (S.Infinity).as_content_primitive() == (1, oo) eq = x**(2 + y) assert (eq).as_content_primitive() == (1, eq) assert (S.Half**(2 + x)).as_content_primitive() == (S(1)/4, 2**-x) assert ((-S.Half)**(2 + x)).as_content_primitive() == \ (S(1)/4, (-S.Half)**x) assert ((-S.Half)**(2 + x)).as_content_primitive() == \ (S(1)/4, (-S.Half)**x) assert (4**((1 + y)/2)).as_content_primitive() == (2, 4**(y/2)) assert (3**((1 + y)/2)).as_content_primitive() == \ (1, 3**(Mul(S(1)/2, 1 + y, evaluate=False))) assert (5**(S(3)/4)).as_content_primitive() == (1, 5**(S(3)/4)) assert (5**(S(7)/4)).as_content_primitive() == (5, 5**(S(3)/4)) assert Add(5*z/7, 0.5*x, 3*y/2, evaluate=False).as_content_primitive() == \ (S(1)/14, 7.0*x + 21*y + 10*z) assert (2**(S(3)/4) + 2**(S(1)/4)*sqrt(3)).as_content_primitive(radical=True) == \ (1, 2**(S(1)/4)*(sqrt(2) + sqrt(3))) def test_signsimp(): e = x*(-x + 1) + x*(x - 1) assert signsimp(Eq(e, 0)) is S.true assert Abs(x - 1) == Abs(1 - x) assert signsimp(y - x) == y - x assert signsimp(y - x, evaluate=False) == Mul(-1, x - y, evaluate=False) def test_besselsimp(): from sympy import besselj, besseli, exp_polar, cosh, cosine_transform assert besselsimp(exp(-I*pi*y/2)*besseli(y, z*exp_polar(I*pi/2))) == \ besselj(y, z) assert besselsimp(exp(-I*pi*a/2)*besseli(a, 2*sqrt(x)*exp_polar(I*pi/2))) == \ besselj(a, 2*sqrt(x)) assert besselsimp(sqrt(2)*sqrt(pi)*x**(S(1)/4)*exp(I*pi/4)*exp(-I*pi*a/2) * besseli(-S(1)/2, sqrt(x)*exp_polar(I*pi/2)) * besseli(a, sqrt(x)*exp_polar(I*pi/2))/2) == \ besselj(a, sqrt(x)) * cos(sqrt(x)) assert besselsimp(besseli(S(-1)/2, z)) == \ sqrt(2)*cosh(z)/(sqrt(pi)*sqrt(z)) assert besselsimp(besseli(a, z*exp_polar(-I*pi/2))) == \ exp(-I*pi*a/2)*besselj(a, z) assert cosine_transform(1/t*sin(a/t), t, y) == \ sqrt(2)*sqrt(pi)*besselj(0, 2*sqrt(a)*sqrt(y))/2 def test_Piecewise(): e1 = x*(x + y) - y*(x + y) e2 = sin(x)**2 + cos(x)**2 e3 = expand((x + y)*y/x) s1 = simplify(e1) s2 = simplify(e2) s3 = simplify(e3) assert simplify(Piecewise((e1, x < e2), (e3, True))) == \ Piecewise((s1, x < s2), (s3, True)) def test_polymorphism(): class A(Basic): def _eval_simplify(x, **kwargs): return 1 a = A(5, 2) assert simplify(a) == 1 def test_issue_from_PR1599(): n1, n2, n3, n4 = symbols('n1 n2 n3 n4', negative=True) assert simplify(I*sqrt(n1)) == -sqrt(-n1) def test_issue_6811(): eq = (x + 2*y)*(2*x + 2) assert simplify(eq) == (x + 1)*(x + 2*y)*2 # reject the 2-arg Mul -- these are a headache for test writing assert simplify(eq.expand()) == \ 2*x**2 + 4*x*y + 2*x + 4*y def test_issue_6920(): e = [cos(x) + I*sin(x), cos(x) - I*sin(x), cosh(x) - sinh(x), cosh(x) + sinh(x)] ok = [exp(I*x), exp(-I*x), exp(-x), exp(x)] # wrap in f to show that the change happens wherever ei occurs f = Function('f') assert [simplify(f(ei)).args[0] for ei in e] == ok def test_issue_7001(): from sympy.abc import r, R assert simplify(-(r*Piecewise((4*pi/3, r <= R), (-8*pi*R**3/(3*r**3), True)) + 2*Piecewise((4*pi*r/3, r <= R), (4*pi*R**3/(3*r**2), True)))/(4*pi*r)) == \ Piecewise((-1, r <= R), (0, True)) def test_inequality_no_auto_simplify(): # no simplify on creation but can be simplified lhs = cos(x)**2 + sin(x)**2 rhs = 2 e = Lt(lhs, rhs, evaluate=False) assert e is not S.true assert simplify(e) def test_issue_9398(): from sympy import Number, cancel assert cancel(1e-14) != 0 assert cancel(1e-14*I) != 0 assert simplify(1e-14) != 0 assert simplify(1e-14*I) != 0 assert (I*Number(1.)*Number(10)**Number(-14)).simplify() != 0 assert cancel(1e-20) != 0 assert cancel(1e-20*I) != 0 assert simplify(1e-20) != 0 assert simplify(1e-20*I) != 0 assert cancel(1e-100) != 0 assert cancel(1e-100*I) != 0 assert simplify(1e-100) != 0 assert simplify(1e-100*I) != 0 f = Float("1e-1000") assert cancel(f) != 0 assert cancel(f*I) != 0 assert simplify(f) != 0 assert simplify(f*I) != 0 def test_issue_9324_simplify(): M = MatrixSymbol('M', 10, 10) e = M[0, 0] + M[5, 4] + 1304 assert simplify(e) == e def test_issue_13474(): x = Symbol('x') assert simplify(x + csch(sinc(1))) == x + csch(sinc(1)) def test_simplify_function_inverse(): # "inverse" attribute does not guarantee that f(g(x)) is x # so this simplification should not happen automatically. # See issue #12140 x, y = symbols('x, y') g = Function('g') class f(Function): def inverse(self, argindex=1): return g assert simplify(f(g(x))) == f(g(x)) assert inversecombine(f(g(x))) == x assert simplify(f(g(x)), inverse=True) == x assert simplify(f(g(sin(x)**2 + cos(x)**2)), inverse=True) == 1 assert simplify(f(g(x, y)), inverse=True) == f(g(x, y)) assert simplify(2*asin(sin(3*x)), inverse=True) == 6*x assert simplify(log(exp(x))) == log(exp(x)) assert simplify(log(exp(x)), inverse=True) == x assert simplify(log(exp(x), 2), inverse=True) == x/log(2) assert simplify(log(exp(x), 2, evaluate=False), inverse=True) == x/log(2) def test_clear_coefficients(): from sympy.simplify.simplify import clear_coefficients assert clear_coefficients(4*y*(6*x + 3)) == (y*(2*x + 1), 0) assert clear_coefficients(4*y*(6*x + 3) - 2) == (y*(2*x + 1), S(1)/6) assert clear_coefficients(4*y*(6*x + 3) - 2, x) == (y*(2*x + 1), x/12 + S(1)/6) assert clear_coefficients(sqrt(2) - 2) == (sqrt(2), 2) assert clear_coefficients(4*sqrt(2) - 2) == (sqrt(2), S.Half) assert clear_coefficients(S(3), x) == (0, x - 3) assert clear_coefficients(S.Infinity, x) == (S.Infinity, x) assert clear_coefficients(-S.Pi, x) == (S.Pi, -x) assert clear_coefficients(2 - S.Pi/3, x) == (pi, -3*x + 6) def test_nc_simplify(): from sympy.simplify.simplify import nc_simplify from sympy.matrices.expressions import (MatrixExpr, MatAdd, MatMul, MatPow, Identity) from sympy.core import Pow from functools import reduce a, b, c, d = symbols('a b c d', commutative = False) x = Symbol('x') A = MatrixSymbol("A", x, x) B = MatrixSymbol("B", x, x) C = MatrixSymbol("C", x, x) D = MatrixSymbol("D", x, x) subst = {a: A, b: B, c: C, d:D} funcs = {Add: lambda x,y: x+y, Mul: lambda x,y: x*y } def _to_matrix(expr): if expr in subst: return subst[expr] if isinstance(expr, Pow): return MatPow(_to_matrix(expr.args[0]), expr.args[1]) elif isinstance(expr, (Add, Mul)): return reduce(funcs[expr.func],[_to_matrix(a) for a in expr.args]) else: return expr*Identity(x) def _check(expr, simplified, deep=True, matrix=True): assert nc_simplify(expr, deep=deep) == simplified assert expand(expr) == expand(simplified) if matrix: m_simp = _to_matrix(simplified).doit(inv_expand=False) assert nc_simplify(_to_matrix(expr), deep=deep) == m_simp _check(a*b*a*b*a*b*c*(a*b)**3*c, ((a*b)**3*c)**2) _check(a*b*(a*b)**-2*a*b, 1) _check(a**2*b*a*b*a*b*(a*b)**-1, a*(a*b)**2, matrix=False) _check(b*a*b**2*a*b**2*a*b**2, b*(a*b**2)**3) _check(a*b*a**2*b*a**2*b*a**3, (a*b*a)**3*a**2) _check(a**2*b*a**4*b*a**4*b*a**2, (a**2*b*a**2)**3) _check(a**3*b*a**4*b*a**4*b*a, a**3*(b*a**4)**3*a**-3) _check(a*b*a*b + a*b*c*x*a*b*c, (a*b)**2 + x*(a*b*c)**2) _check(a*b*a*b*c*a*b*a*b*c, ((a*b)**2*c)**2) _check(b**-1*a**-1*(a*b)**2, a*b) _check(a**-1*b*c**-1, (c*b**-1*a)**-1) expr = a**3*b*a**4*b*a**4*b*a**2*b*a**2*(b*a**2)**2*b*a**2*b*a**2 for i in range(10): expr *= a*b _check(expr, a**3*(b*a**4)**2*(b*a**2)**6*(a*b)**10) _check((a*b*a*b)**2, (a*b*a*b)**2, deep=False) _check(a*b*(c*d)**2, a*b*(c*d)**2) expr = b**-1*(a**-1*b**-1 - a**-1*c*b**-1)**-1*a**-1 assert nc_simplify(expr) == (1-c)**-1 # commutative expressions should be returned without an error assert nc_simplify(2*x**2) == 2*x**2 def test_issue_15965(): A = Sum(z*x**y, (x, 1, a)) anew = z*Sum(x**y, (x, 1, a)) B = Integral(x*y, x) bnew = y*Integral(x, x) assert simplify(A + B) == anew + bnew assert simplify(A) == anew assert simplify(B) == bnew

b3ec13913f031deccef286a8bfb6aeb84e973e68e5a9d4429d6dca6858a23228

import math from sympy import ( Float, Idx, IndexedBase, Integer, Matrix, MatrixSymbol, Range, sin, symbols, Symbol, Tuple, Lt, nan, oo ) from sympy.core.relational import StrictLessThan from sympy.utilities.pytest import raises, XFAIL from sympy.codegen.ast import ( Assignment, Attribute, aug_assign, CodeBlock, For, Type, Variable, Pointer, Declaration, AddAugmentedAssignment, SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment, value_const, pointer_const, integer, real, complex_, int8, uint8, float16 as f16, float32 as f32, float64 as f64, float80 as f80, float128 as f128, complex64 as c64, complex128 as c128, While, Scope, String, Print, QuotedString, FunctionPrototype, FunctionDefinition, Return, FunctionCall, untyped, IntBaseType, intc, Node, none, NoneToken, Token, Comment ) x, y, z, t, x0, x1, x2, a, b = symbols("x, y, z, t, x0, x1, x2, a, b") n = symbols("n", integer=True) A = MatrixSymbol('A', 3, 1) mat = Matrix([1, 2, 3]) B = IndexedBase('B') i = Idx("i", n) A22 = MatrixSymbol('A22',2,2) B22 = MatrixSymbol('B22',2,2) def test_Assignment(): # Here we just do things to show they don't error Assignment(x, y) Assignment(x, 0) Assignment(A, mat) Assignment(A[1,0], 0) Assignment(A[1,0], x) Assignment(B[i], x) Assignment(B[i], 0) a = Assignment(x, y) assert a.func(*a.args) == a assert a.op == ':=' # Here we test things to show that they error # Matrix to scalar raises(ValueError, lambda: Assignment(B[i], A)) raises(ValueError, lambda: Assignment(B[i], mat)) raises(ValueError, lambda: Assignment(x, mat)) raises(ValueError, lambda: Assignment(x, A)) raises(ValueError, lambda: Assignment(A[1,0], mat)) # Scalar to matrix raises(ValueError, lambda: Assignment(A, x)) raises(ValueError, lambda: Assignment(A, 0)) # Non-atomic lhs raises(TypeError, lambda: Assignment(mat, A)) raises(TypeError, lambda: Assignment(0, x)) raises(TypeError, lambda: Assignment(x*x, 1)) raises(TypeError, lambda: Assignment(A + A, mat)) raises(TypeError, lambda: Assignment(B, 0)) def test_AugAssign(): # Here we just do things to show they don't error aug_assign(x, '+', y) aug_assign(x, '+', 0) aug_assign(A, '+', mat) aug_assign(A[1, 0], '+', 0) aug_assign(A[1, 0], '+', x) aug_assign(B[i], '+', x) aug_assign(B[i], '+', 0) # Check creation via aug_assign vs constructor for binop, cls in [ ('+', AddAugmentedAssignment), ('-', SubAugmentedAssignment), ('*', MulAugmentedAssignment), ('/', DivAugmentedAssignment), ('%', ModAugmentedAssignment), ]: a = aug_assign(x, binop, y) b = cls(x, y) assert a.func(*a.args) == a == b assert a.binop == binop assert a.op == binop + '=' # Here we test things to show that they error # Matrix to scalar raises(ValueError, lambda: aug_assign(B[i], '+', A)) raises(ValueError, lambda: aug_assign(B[i], '+', mat)) raises(ValueError, lambda: aug_assign(x, '+', mat)) raises(ValueError, lambda: aug_assign(x, '+', A)) raises(ValueError, lambda: aug_assign(A[1, 0], '+', mat)) # Scalar to matrix raises(ValueError, lambda: aug_assign(A, '+', x)) raises(ValueError, lambda: aug_assign(A, '+', 0)) # Non-atomic lhs raises(TypeError, lambda: aug_assign(mat, '+', A)) raises(TypeError, lambda: aug_assign(0, '+', x)) raises(TypeError, lambda: aug_assign(x * x, '+', 1)) raises(TypeError, lambda: aug_assign(A + A, '+', mat)) raises(TypeError, lambda: aug_assign(B, '+', 0)) def test_Assignment_printing(): assignment_classes = [ Assignment, AddAugmentedAssignment, SubAugmentedAssignment, MulAugmentedAssignment, DivAugmentedAssignment, ModAugmentedAssignment, ] pairs = [ (x, 2 * y + 2), (B[i], x), (A22, B22), (A[0, 0], x), ] for cls in assignment_classes: for lhs, rhs in pairs: a = cls(lhs, rhs) assert repr(a) == '%s(%s, %s)' % (cls.__name__, repr(lhs), repr(rhs)) def test_CodeBlock(): c = CodeBlock(Assignment(x, 1), Assignment(y, x + 1)) assert c.func(*c.args) == c assert c.left_hand_sides == Tuple(x, y) assert c.right_hand_sides == Tuple(1, x + 1) def test_CodeBlock_topological_sort(): assignments = [ Assignment(x, y + z), Assignment(z, 1), Assignment(t, x), Assignment(y, 2), ] ordered_assignments = [ # Note that the unrelated z=1 and y=2 are kept in that order Assignment(z, 1), Assignment(y, 2), Assignment(x, y + z), Assignment(t, x), ] c1 = CodeBlock.topological_sort(assignments) assert c1 == CodeBlock(*ordered_assignments) # Cycle invalid_assignments = [ Assignment(x, y + z), Assignment(z, 1), Assignment(y, x), Assignment(y, 2), ] raises(ValueError, lambda: CodeBlock.topological_sort(invalid_assignments)) # Free symbols free_assignments = [ Assignment(x, y + z), Assignment(z, a * b), Assignment(t, x), Assignment(y, b + 3), ] free_assignments_ordered = [ Assignment(z, a * b), Assignment(y, b + 3), Assignment(x, y + z), Assignment(t, x), ] c2 = CodeBlock.topological_sort(free_assignments) assert c2 == CodeBlock(*free_assignments_ordered) def test_CodeBlock_free_symbols(): c1 = CodeBlock( Assignment(x, y + z), Assignment(z, 1), Assignment(t, x), Assignment(y, 2), ) assert c1.free_symbols == set() c2 = CodeBlock( Assignment(x, y + z), Assignment(z, a * b), Assignment(t, x), Assignment(y, b + 3), ) assert c2.free_symbols == {a, b} def test_CodeBlock_cse(): c1 = CodeBlock( Assignment(y, 1), Assignment(x, sin(y)), Assignment(z, sin(y)), Assignment(t, x*z), ) assert c1.cse() == CodeBlock( Assignment(y, 1), Assignment(x0, sin(y)), Assignment(x, x0), Assignment(z, x0), Assignment(t, x*z), ) # Multiple assignments to same symbol not supported raises(NotImplementedError, lambda: CodeBlock( Assignment(x, 1), Assignment(y, 1), Assignment(y, 2) ).cse()) # Check auto-generated symbols do not collide with existing ones c2 = CodeBlock( Assignment(x0, sin(y) + 1), Assignment(x1, 2 * sin(y)), Assignment(z, x * y), ) assert c2.cse() == CodeBlock( Assignment(x2, sin(y)), Assignment(x0, x2 + 1), Assignment(x1, 2 * x2), Assignment(z, x * y), ) def test_CodeBlock_cse__issue_14118(): # see https://github.com/sympy/sympy/issues/14118 c = CodeBlock( Assignment(A22, Matrix([[x, sin(y)],[3, 4]])), Assignment(B22, Matrix([[sin(y), 2*sin(y)], [sin(y)**2, 7]])) ) assert c.cse() == CodeBlock( Assignment(x0, sin(y)), Assignment(A22, Matrix([[x, x0],[3, 4]])), Assignment(B22, Matrix([[x0, 2*x0], [x0**2, 7]])) ) def test_For(): f = For(n, Range(0, 3), (Assignment(A[n, 0], x + n), aug_assign(x, '+', y))) f = For(n, (1, 2, 3, 4, 5), (Assignment(A[n, 0], x + n),)) assert f.func(*f.args) == f raises(TypeError, lambda: For(n, x, (x + y,))) def test_none(): assert none.is_Atom assert none == none class Foo(Token): pass foo = Foo() assert foo != none assert none == None assert none == NoneToken() assert none.func(*none.args) == none def test_String(): st = String('foobar') assert st.is_Atom assert st == String('foobar') assert st.text == 'foobar' assert st.func(**st.kwargs()) == st class Signifier(String): pass si = Signifier('foobar') assert si != st assert si.text == st.text s = String('foo') assert str(s) == 'foo' assert repr(s) == "String('foo')" def test_Comment(): c = Comment('foobar') assert c.text == 'foobar' assert str(c) == 'foobar' def test_Node(): n = Node() assert n == Node() assert n.func(*n.args) == n def test_Type(): t = Type('MyType') assert len(t.args) == 1 assert t.name == String('MyType') assert str(t) == 'MyType' assert repr(t) == "Type(String('MyType'))" assert Type(t) == t assert t.func(*t.args) == t t1 = Type('t1') t2 = Type('t2') assert t1 != t2 assert t1 == t1 and t2 == t2 t1b = Type('t1') assert t1 == t1b assert t2 != t1b def test_Type__from_expr(): assert Type.from_expr(i) == integer u = symbols('u', real=True) assert Type.from_expr(u) == real assert Type.from_expr(n) == integer assert Type.from_expr(3) == integer assert Type.from_expr(3.0) == real assert Type.from_expr(3+1j) == complex_ raises(ValueError, lambda: Type.from_expr(sum)) def test_Type__cast_check__integers(): # Rounding raises(ValueError, lambda: integer.cast_check(3.5)) assert integer.cast_check('3') == 3 assert integer.cast_check(Float('3.0000000000000000000')) == 3 assert integer.cast_check(Float('3.0000000000000000001')) == 3 # unintuitive maybe? # Range assert int8.cast_check(127.0) == 127 raises(ValueError, lambda: int8.cast_check(128)) assert int8.cast_check(-128) == -128 raises(ValueError, lambda: int8.cast_check(-129)) assert uint8.cast_check(0) == 0 assert uint8.cast_check(128) == 128 raises(ValueError, lambda: uint8.cast_check(256.0)) raises(ValueError, lambda: uint8.cast_check(-1)) def test_Attribute(): noexcept = Attribute('noexcept') assert noexcept == Attribute('noexcept') alignas16 = Attribute('alignas', [16]) alignas32 = Attribute('alignas', [32]) assert alignas16 != alignas32 assert alignas16.func(*alignas16.args) == alignas16 def test_Variable(): v = Variable(x, type=real) assert v == Variable(v) assert v == Variable('x', type=real) assert v.symbol == x assert v.type == real assert value_const not in v.attrs assert v.func(*v.args) == v assert str(v) == 'Variable(x, type=real)' w = Variable(y, f32, attrs={value_const}) assert w.symbol == y assert w.type == f32 assert value_const in w.attrs assert w.func(*w.args) == w v_n = Variable(n, type=Type.from_expr(n)) assert v_n.type == integer assert v_n.func(*v_n.args) == v_n v_i = Variable(i, type=Type.from_expr(n)) assert v_i.type == integer assert v_i != v_n a_i = Variable.deduced(i) assert a_i.type == integer assert Variable.deduced(Symbol('x', real=True)).type == real assert a_i.func(*a_i.args) == a_i v_n2 = Variable.deduced(n, value=3.5, cast_check=False) assert v_n2.func(*v_n2.args) == v_n2 assert abs(v_n2.value - 3.5) < 1e-15 raises(ValueError, lambda: Variable.deduced(n, value=3.5, cast_check=True)) v_n3 = Variable.deduced(n) assert v_n3.type == integer assert str(v_n3) == 'Variable(n, type=integer)' assert Variable.deduced(z, value=3).type == integer assert Variable.deduced(z, value=3.0).type == real assert Variable.deduced(z, value=3.0+1j).type == complex_ def test_Pointer(): p = Pointer(x) assert p.symbol == x assert p.type == untyped assert value_const not in p.attrs assert pointer_const not in p.attrs assert p.func(*p.args) == p u = symbols('u', real=True) pu = Pointer(u, type=Type.from_expr(u), attrs={value_const, pointer_const}) assert pu.symbol is u assert pu.type == real assert value_const in pu.attrs assert pointer_const in pu.attrs assert pu.func(*pu.args) == pu i = symbols('i', integer=True) deref = pu[i] assert deref.indices == (i,) def test_Declaration(): u = symbols('u', real=True) vu = Variable(u, type=Type.from_expr(u)) assert Declaration(vu).variable.type == real vn = Variable(n, type=Type.from_expr(n)) assert Declaration(vn).variable.type == integer lt = StrictLessThan(vu, vn) assert isinstance(lt, StrictLessThan) vuc = Variable(u, Type.from_expr(u), value=3.0, attrs={value_const}) assert value_const in vuc.attrs assert pointer_const not in vuc.attrs decl = Declaration(vuc) assert decl.variable == vuc assert isinstance(decl.variable.value, Float) assert decl.variable.value == 3.0 assert decl.func(*decl.args) == decl assert vuc.as_Declaration() == decl assert vuc.as_Declaration(value=None, attrs=None) == Declaration(vu) vy = Variable(y, type=integer, value=3) decl2 = Declaration(vy) assert decl2.variable == vy assert decl2.variable.value == Integer(3) vi = Variable(i, type=Type.from_expr(i), value=3.0) decl3 = Declaration(vi) assert decl3.variable.type == integer assert decl3.variable.value == 3.0 raises(ValueError, lambda: Declaration(vi, 42)) def test_IntBaseType(): assert intc.name == String('intc') assert intc.args == (intc.name,) assert str(IntBaseType('a').name) == 'a' def test_FloatType(): assert f16.dig == 3 assert f32.dig == 6 assert f64.dig == 15 assert f80.dig == 18 assert f128.dig == 33 assert f16.decimal_dig == 5 assert f32.decimal_dig == 9 assert f64.decimal_dig == 17 assert f80.decimal_dig == 21 assert f128.decimal_dig == 36 assert f16.max_exponent == 16 assert f32.max_exponent == 128 assert f64.max_exponent == 1024 assert f80.max_exponent == 16384 assert f128.max_exponent == 16384 assert f16.min_exponent == -13 assert f32.min_exponent == -125 assert f64.min_exponent == -1021 assert f80.min_exponent == -16381 assert f128.min_exponent == -16381 assert abs(f16.eps / Float('0.00097656', precision=16) - 1) < 0.1*10**-f16.dig assert abs(f32.eps / Float('1.1920929e-07', precision=32) - 1) < 0.1*10**-f32.dig assert abs(f64.eps / Float('2.2204460492503131e-16', precision=64) - 1) < 0.1*10**-f64.dig assert abs(f80.eps / Float('1.08420217248550443401e-19', precision=80) - 1) < 0.1*10**-f80.dig assert abs(f128.eps / Float(' 1.92592994438723585305597794258492732e-34', precision=128) - 1) < 0.1*10**-f128.dig assert abs(f16.max / Float('65504', precision=16) - 1) < .1*10**-f16.dig assert abs(f32.max / Float('3.40282347e+38', precision=32) - 1) < 0.1*10**-f32.dig assert abs(f64.max / Float('1.79769313486231571e+308', precision=64) - 1) < 0.1*10**-f64.dig # cf. np.finfo(np.float64).max assert abs(f80.max / Float('1.18973149535723176502e+4932', precision=80) - 1) < 0.1*10**-f80.dig assert abs(f128.max / Float('1.18973149535723176508575932662800702e+4932', precision=128) - 1) < 0.1*10**-f128.dig # cf. np.finfo(np.float32).tiny assert abs(f16.tiny / Float('6.1035e-05', precision=16) - 1) < 0.1*10**-f16.dig assert abs(f32.tiny / Float('1.17549435e-38', precision=32) - 1) < 0.1*10**-f32.dig assert abs(f64.tiny / Float('2.22507385850720138e-308', precision=64) - 1) < 0.1*10**-f64.dig assert abs(f80.tiny / Float('3.36210314311209350626e-4932', precision=80) - 1) < 0.1*10**-f80.dig assert abs(f128.tiny / Float('3.3621031431120935062626778173217526e-4932', precision=128) - 1) < 0.1*10**-f128.dig assert f64.cast_check(0.5) == 0.5 assert abs(f64.cast_check(3.7) - 3.7) < 3e-17 assert isinstance(f64.cast_check(3), (Float, float)) assert f64.cast_nocheck(oo) == float('inf') assert f64.cast_nocheck(-oo) == float('-inf') assert f64.cast_nocheck(float(oo)) == float('inf') assert f64.cast_nocheck(float(-oo)) == float('-inf') assert math.isnan(f64.cast_nocheck(nan)) assert f32 != f64 assert f64 == f64.func(*f64.args) def test_Type__cast_check__floating_point(): raises(ValueError, lambda: f32.cast_check(123.45678949)) raises(ValueError, lambda: f32.cast_check(12.345678949)) raises(ValueError, lambda: f32.cast_check(1.2345678949)) raises(ValueError, lambda: f32.cast_check(.12345678949)) assert abs(123.456789049 - f32.cast_check(123.456789049) - 4.9e-8) < 1e-8 assert abs(0.12345678904 - f32.cast_check(0.12345678904) - 4e-11) < 1e-11 dcm21 = Float('0.123456789012345670499') # 21 decimals assert abs(dcm21 - f64.cast_check(dcm21) - 4.99e-19) < 1e-19 f80.cast_check(Float('0.12345678901234567890103', precision=88)) raises(ValueError, lambda: f80.cast_check(Float('0.12345678901234567890149', precision=88))) v10 = 12345.67894 raises(ValueError, lambda: f32.cast_check(v10)) assert abs(Float(str(v10), precision=64+8) - f64.cast_check(v10)) < v10*1e-16 assert abs(f32.cast_check(2147483647) - 2147483650) < 1 def test_Type__cast_check__complex_floating_point(): val9_11 = 123.456789049 + 0.123456789049j raises(ValueError, lambda: c64.cast_check(.12345678949 + .12345678949j)) assert abs(val9_11 - c64.cast_check(val9_11) - 4.9e-8) < 1e-8 dcm21 = Float('0.123456789012345670499') + 1e-20j # 21 decimals assert abs(dcm21 - c128.cast_check(dcm21) - 4.99e-19) < 1e-19 v19 = Float('0.1234567890123456749') + 1j*Float('0.1234567890123456749') raises(ValueError, lambda: c128.cast_check(v19)) def test_While(): xpp = AddAugmentedAssignment(x, 1) whl1 = While(x < 2, [xpp]) assert whl1.condition.args[0] == x assert whl1.condition.args[1] == 2 assert whl1.condition == Lt(x, 2, evaluate=False) assert whl1.body.args == (xpp,) assert whl1.func(*whl1.args) == whl1 cblk = CodeBlock(AddAugmentedAssignment(x, 1)) whl2 = While(x < 2, cblk) assert whl1 == whl2 assert whl1 != While(x < 3, [xpp]) def test_Scope(): assign = Assignment(x, y) incr = AddAugmentedAssignment(x, 1) scp = Scope([assign, incr]) cblk = CodeBlock(assign, incr) assert scp.body == cblk assert scp == Scope(cblk) assert scp != Scope([incr, assign]) assert scp.func(*scp.args) == scp def test_Print(): fmt = "%d %.3f" ps = Print([n, x], fmt) assert str(ps.format_string) == fmt assert ps.print_args == Tuple(n, x) assert ps.args == (Tuple(n, x), QuotedString(fmt), none) assert ps == Print((n, x), fmt) assert ps != Print([x, n], fmt) assert ps.func(*ps.args) == ps ps2 = Print([n, x]) assert ps2 == Print([n, x]) assert ps2 != ps assert ps2.format_string == None def test_FunctionPrototype_and_FunctionDefinition(): vx = Variable(x, type=real) vn = Variable(n, type=integer) fp1 = FunctionPrototype(real, 'power', [vx, vn]) assert fp1.return_type == real assert fp1.name == String('power') assert fp1.parameters == Tuple(vx, vn) assert fp1 == FunctionPrototype(real, 'power', [vx, vn]) assert fp1 != FunctionPrototype(real, 'power', [vn, vx]) assert fp1.func(*fp1.args) == fp1 body = [Assignment(x, x**n), Return(x)] fd1 = FunctionDefinition(real, 'power', [vx, vn], body) assert fd1.return_type == real assert str(fd1.name) == 'power' assert fd1.parameters == Tuple(vx, vn) assert fd1.body == CodeBlock(*body) assert fd1 == FunctionDefinition(real, 'power', [vx, vn], body) assert fd1 != FunctionDefinition(real, 'power', [vx, vn], body[::-1]) assert fd1.func(*fd1.args) == fd1 fp2 = FunctionPrototype.from_FunctionDefinition(fd1) assert fp2 == fp1 fd2 = FunctionDefinition.from_FunctionPrototype(fp1, body) assert fd2 == fd1 def test_Return(): rs = Return(x) assert rs.args == (x,) assert rs == Return(x) assert rs != Return(y) assert rs.func(*rs.args) == rs def test_FunctionCall(): fc = FunctionCall('power', (x, 3)) assert fc.function_args[0] == x assert fc.function_args[1] == 3 assert isinstance(fc.function_args[1], Integer) assert fc == FunctionCall('power', (x, 3)) assert fc != FunctionCall('power', (3, x)) assert fc != FunctionCall('Power', (x, 3)) assert fc.func(*fc.args) == fc def test_ast_replace(): x = Variable('x', real) y = Variable('y', real) n = Variable('n', integer) pwer = FunctionDefinition(real, 'pwer', [x, n], [pow(x.symbol, n.symbol)]) pname = pwer.name pcall = FunctionCall('pwer', [y, 3]) tree1 = CodeBlock(pwer, pcall) assert str(tree1.args[0].name) == 'pwer' assert str(tree1.args[1].name) == 'pwer' for a, b in zip(tree1, [pwer, pcall]): assert a == b tree2 = tree1.replace(pname, String('power')) assert str(tree1.args[0].name) == 'pwer' assert str(tree1.args[1].name) == 'pwer' assert str(tree2.args[0].name) == 'power' assert str(tree2.args[1].name) == 'power'

95e45597dd5f69e2d5a6d9c9d1e70fe2fe00c2158cbb78364ec8e8ef0ebe33d2

from __future__ import (absolute_import, print_function) from sympy import log, exp, Symbol, Pow, sin from sympy.printing.ccode import ccode from sympy.codegen.cfunctions import log2, exp2, expm1, log1p from sympy.codegen.rewriting import ( optimize, log2_opt, exp2_opt, expm1_opt, log1p_opt, optims_c99, create_expand_pow_optimization ) from sympy.utilities.pytest import XFAIL def test_log2_opt(): x = Symbol('x') expr1 = 7*log(3*x + 5)/(log(2)) opt1 = optimize(expr1, [log2_opt]) assert opt1 == 7*log2(3*x + 5) assert opt1.rewrite(log) == expr1 expr2 = 3*log(5*x + 7)/(13*log(2)) opt2 = optimize(expr2, [log2_opt]) assert opt2 == 3*log2(5*x + 7)/13 assert opt2.rewrite(log) == expr2 expr3 = log(x)/log(2) opt3 = optimize(expr3, [log2_opt]) assert opt3 == log2(x) assert opt3.rewrite(log) == expr3 expr4 = log(x)/log(2) + log(x+1) opt4 = optimize(expr4, [log2_opt]) assert opt4 == log2(x) + log(2)*log2(x+1) assert opt4.rewrite(log) == expr4 expr5 = log(17) opt5 = optimize(expr5, [log2_opt]) assert opt5 == expr5 expr6 = log(x + 3)/log(2) opt6 = optimize(expr6, [log2_opt]) assert str(opt6) == 'log2(x + 3)' assert opt6.rewrite(log) == expr6 def test_exp2_opt(): x = Symbol('x') expr1 = 1 + 2**x opt1 = optimize(expr1, [exp2_opt]) assert opt1 == 1 + exp2(x) assert opt1.rewrite(Pow) == expr1 expr2 = 1 + 3**x assert expr2 == optimize(expr2, [exp2_opt]) def test_expm1_opt(): x = Symbol('x') expr1 = exp(x) - 1 opt1 = optimize(expr1, [expm1_opt]) assert expm1(x) - opt1 == 0 assert opt1.rewrite(exp) == expr1 expr2 = 3*exp(x) - 3 opt2 = optimize(expr2, [expm1_opt]) assert 3*expm1(x) == opt2 assert opt2.rewrite(exp) == expr2 expr3 = 3*exp(x) - 5 assert expr3 == optimize(expr3, [expm1_opt]) expr4 = 3*exp(x) + log(x) - 3 opt4 = optimize(expr4, [expm1_opt]) assert 3*expm1(x) + log(x) == opt4 assert opt4.rewrite(exp) == expr4 expr5 = 3*exp(2*x) - 3 opt5 = optimize(expr5, [expm1_opt]) assert 3*expm1(2*x) == opt5 assert opt5.rewrite(exp) == expr5 @XFAIL def test_expm1_two_exp_terms(): x, y = map(Symbol, 'x y'.split()) expr1 = exp(x) + exp(y) - 2 opt1 = optimize(expr1, [expm1_opt]) assert opt1 == expm1(x) + expm1(y) def test_log1p_opt(): x = Symbol('x') expr1 = log(x + 1) opt1 = optimize(expr1, [log1p_opt]) assert log1p(x) - opt1 == 0 assert opt1.rewrite(log) == expr1 expr2 = log(3*x + 3) opt2 = optimize(expr2, [log1p_opt]) assert log1p(x) + log(3) == opt2 assert (opt2.rewrite(log) - expr2).simplify() == 0 expr3 = log(2*x + 1) opt3 = optimize(expr3, [log1p_opt]) assert log1p(2*x) - opt3 == 0 assert opt3.rewrite(log) == expr3 expr4 = log(x+3) opt4 = optimize(expr4, [log1p_opt]) assert str(opt4) == 'log(x + 3)' def test_optims_c99(): x = Symbol('x') expr1 = 2**x + log(x)/log(2) + log(x + 1) + exp(x) - 1 opt1 = optimize(expr1, optims_c99).simplify() assert opt1 == exp2(x) + log2(x) + log1p(x) + expm1(x) assert opt1.rewrite(exp).rewrite(log).rewrite(Pow) == expr1 expr2 = log(x)/log(2) + log(x + 1) opt2 = optimize(expr2, optims_c99) assert opt2 == log2(x) + log1p(x) assert opt2.rewrite(log) == expr2 expr3 = log(x)/log(2) + log(17*x + 17) opt3 = optimize(expr3, optims_c99) delta3 = opt3 - (log2(x) + log(17) + log1p(x)) assert delta3 == 0 assert (opt3.rewrite(log) - expr3).simplify() == 0 expr4 = 2**x + 3*log(5*x + 7)/(13*log(2)) + 11*exp(x) - 11 + log(17*x + 17) opt4 = optimize(expr4, optims_c99).simplify() delta4 = opt4 - (exp2(x) + 3*log2(5*x + 7)/13 + 11*expm1(x) + log(17) + log1p(x)) assert delta4 == 0 assert (opt4.rewrite(exp).rewrite(log).rewrite(Pow) - expr4).simplify() == 0 expr5 = 3*exp(2*x) - 3 opt5 = optimize(expr5, optims_c99) delta5 = opt5 - 3*expm1(2*x) assert delta5 == 0 assert opt5.rewrite(exp) == expr5 expr6 = exp(2*x) - 3 opt6 = optimize(expr6, optims_c99) delta6 = opt6 - (exp(2*x) - 3) assert delta6 == 0 expr7 = log(3*x + 3) opt7 = optimize(expr7, optims_c99) delta7 = opt7 - (log(3) + log1p(x)) assert delta7 == 0 assert (opt7.rewrite(log) - expr7).simplify() == 0 expr8 = log(2*x + 3) opt8 = optimize(expr8, optims_c99) assert opt8 == expr8 def test_create_expand_pow_optimization(): cc = lambda x: ccode( optimize(x, [create_expand_pow_optimization(4)])) x = Symbol('x') assert cc(x**4) == 'x*x*x*x' assert cc(x**4 + x**2) == 'x*x + x*x*x*x' assert cc(x**5 + x**4) == 'pow(x, 5) + x*x*x*x' assert cc(sin(x)**4) == 'pow(sin(x), 4)' # gh issue 15335 assert cc(x**(-4)) == '1.0/(x*x*x*x)' assert cc(x**(-5)) == 'pow(x, -5)' assert cc(-x**4) == '-x*x*x*x' assert cc(x**4 - x**2) == '-x*x + x*x*x*x' i = Symbol('i', integer=True) assert cc(x**i - x**2) == 'pow(x, i) - x*x'

22ef1ea32dafbf71fcba5417cba310ae6ce6bad9d408c25e6c088e5278c58f5c

from sympy import symbols, IndexedBase, HadamardProduct, Identity, cos from sympy.codegen.array_utils import (CodegenArrayContraction, CodegenArrayTensorProduct, CodegenArrayDiagonal, CodegenArrayPermuteDims, CodegenArrayElementwiseAdd, _codegen_array_parse, _recognize_matrix_expression, _RecognizeMatOp, _RecognizeMatMulLines, _unfold_recognized_expr, parse_indexed_expression, recognize_matrix_expression, _parse_matrix_expression) from sympy import (MatrixSymbol, Sum) from sympy.combinatorics import Permutation from sympy.functions.special.tensor_functions import KroneckerDelta from sympy.matrices.expressions.diagonal import DiagonalizeVector from sympy.matrices.expressions.matexpr import MatrixElement from sympy.matrices import (Trace, MatAdd, MatMul, Transpose) from sympy.utilities.pytest import raises, XFAIL A, B = symbols("A B", cls=IndexedBase) i, j, k, l, m, n = symbols("i j k l m n") M = MatrixSymbol("M", k, k) N = MatrixSymbol("N", k, k) P = MatrixSymbol("P", k, k) Q = MatrixSymbol("Q", k, k) def test_codegen_array_contraction_construction(): cg = CodegenArrayContraction(A) assert cg == A s = Sum(A[i]*B[i], (i, 0, 3)) cg = parse_indexed_expression(s) assert cg == CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (0, 1)) cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (1, 0)) assert cg == CodegenArrayContraction(CodegenArrayTensorProduct(A, B), (0, 1)) expr = M*N result = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) assert CodegenArrayContraction.from_MatMul(expr) == result elem = expr[i, j] assert parse_indexed_expression(elem) == result expr = M*N*M result = CodegenArrayContraction(CodegenArrayTensorProduct(M, N, M), (1, 2), (3, 4)) assert CodegenArrayContraction.from_MatMul(expr) == result elem = expr[i, j] result = CodegenArrayContraction(CodegenArrayTensorProduct(M, M, N), (1, 4), (2, 5)) cg = parse_indexed_expression(elem) cg = cg.sort_args_by_name() assert cg == result def test_codegen_array_contraction_indices_types(): cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 1)) indtup = cg._get_contraction_tuples() assert indtup == [[(0, 0), (0, 1)]] assert cg._contraction_tuples_to_contraction_indices(cg.expr, indtup) == [(0, 1)] cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) indtup = cg._get_contraction_tuples() assert indtup == [[(0, 1), (1, 0)]] assert cg._contraction_tuples_to_contraction_indices(cg.expr, indtup) == [(1, 2)] cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, M, N), (1, 4), (2, 5)) indtup = cg._get_contraction_tuples() assert indtup == [[(0, 1), (2, 0)], [(1, 0), (2, 1)]] assert cg._contraction_tuples_to_contraction_indices(cg.expr, indtup) == [(1, 4), (2, 5)] def test_codegen_array_recognize_matrix_mul_lines(): cg = CodegenArrayContraction(CodegenArrayTensorProduct(M), (0, 1)) assert recognize_matrix_expression(cg) == Trace(M) cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 1), (2, 3)) assert recognize_matrix_expression(cg) == Trace(M)*Trace(N) cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 3), (1, 2)) assert recognize_matrix_expression(cg) == Trace(M*N) cg = CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 2), (1, 3)) assert recognize_matrix_expression(cg) == Trace(M*N.T) cg = parse_indexed_expression((M*N*P)[i,j]) assert recognize_matrix_expression(cg) == M*N*P cg = CodegenArrayContraction.from_MatMul(M*N*P) assert recognize_matrix_expression(cg) == M*N*P cg = parse_indexed_expression((M*N.T*P)[i,j]) assert recognize_matrix_expression(cg) == M*N.T*P cg = CodegenArrayContraction.from_MatMul(M*N.T*P) assert recognize_matrix_expression(cg) == M*N.T*P cg = CodegenArrayContraction(CodegenArrayTensorProduct(M,N,P,Q), (1, 2), (5, 6)) assert recognize_matrix_expression(cg) == [M*N, P*Q] expr = -2*M*N elem = expr[i, j] cg = parse_indexed_expression(elem) assert recognize_matrix_expression(cg) == -2*M*N def test_codegen_array_flatten(): # Flatten nested CodegenArrayTensorProduct objects: expr1 = CodegenArrayTensorProduct(M, N) expr2 = CodegenArrayTensorProduct(P, Q) expr = CodegenArrayTensorProduct(expr1, expr2) assert expr == CodegenArrayTensorProduct(M, N, P, Q) assert expr.args == (M, N, P, Q) # Flatten mixed CodegenArrayTensorProduct and CodegenArrayContraction objects: cg1 = CodegenArrayContraction(expr1, (1, 2)) cg2 = CodegenArrayContraction(expr2, (0, 3)) expr = CodegenArrayTensorProduct(cg1, cg2) assert expr == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (1, 2), (4, 7)) expr = CodegenArrayTensorProduct(M, cg1) assert expr == CodegenArrayContraction(CodegenArrayTensorProduct(M, M, N), (3, 4)) # Flatten nested CodegenArrayContraction objects: cgnested = CodegenArrayContraction(cg1, (0, 1)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (0, 3), (1, 2)) cgnested = CodegenArrayContraction(CodegenArrayTensorProduct(cg1, cg2), (0, 3)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 6), (1, 2), (4, 7)) cg3 = CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (1, 3), (2, 4)) cgnested = CodegenArrayContraction(cg3, (0, 1)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 5), (1, 3), (2, 4)) cgnested = CodegenArrayContraction(cg3, (0, 3), (1, 2)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 7), (1, 3), (2, 4), (5, 6)) cg4 = CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (1, 5), (3, 7)) cgnested = CodegenArrayContraction(cg4, (0, 1)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 2), (1, 5), (3, 7)) cgnested = CodegenArrayContraction(cg4, (0, 1), (2, 3)) assert cgnested == CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P, Q), (0, 2), (1, 5), (3, 7), (4, 6)) cg = CodegenArrayDiagonal(cg4) assert cg == cg4 assert isinstance(cg, type(cg4)) # Flatten nested CodegenArrayDiagonal objects: cg1 = CodegenArrayDiagonal(expr1, (1, 2)) cg2 = CodegenArrayDiagonal(expr2, (0, 3)) cg3 = CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 3), (2, 4)) cg4 = CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 5), (3, 7)) cgnested = CodegenArrayDiagonal(cg1, (0, 1)) assert cgnested == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N), (1, 2), (0, 3)) cgnested = CodegenArrayDiagonal(cg3, (1, 2)) assert cgnested == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 3), (2, 4), (5, 6)) cgnested = CodegenArrayDiagonal(cg4, (1, 2)) assert cgnested == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P, Q), (1, 5), (3, 7), (2, 4)) def test_codegen_array_parse(): expr = M[i, j] assert _codegen_array_parse(expr) == (M, (i, j)) expr = M[i, j]*N[k, l] assert _codegen_array_parse(expr) == (CodegenArrayTensorProduct(M, N), (i, j, k, l)) expr = M[i, j]*N[j, k] assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N), (1, 2)), (i, k, j)) expr = Sum(M[i, j]*N[j, k], (j, 0, k-1)) assert _codegen_array_parse(expr) == (CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)), (i, k)) expr = M[i, j] + N[i, j] assert _codegen_array_parse(expr) == (CodegenArrayElementwiseAdd(M, N), (i, j)) expr = M[i, j] + N[j, i] assert _codegen_array_parse(expr) == (CodegenArrayElementwiseAdd(M, CodegenArrayPermuteDims(N, Permutation([1,0]))), (i, j)) expr = M[i, j] + M[j, i] assert _codegen_array_parse(expr) == (CodegenArrayElementwiseAdd(M, CodegenArrayPermuteDims(M, Permutation([1,0]))), (i, j)) expr = (M*N*P)[i, j] assert _codegen_array_parse(expr) == (CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P), (1, 2), (3, 4)), (i, j)) expr = expr.function # Disregard summation in previous expression ret1, ret2 = _codegen_array_parse(expr) assert ret1 == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P), (1, 2), (3, 4)) assert str(ret2) == "(i, j, _i_1, _i_2)" expr = KroneckerDelta(i, j)*M[i, k] assert _codegen_array_parse(expr) == (M, ({i, j}, k)) expr = KroneckerDelta(i, j)*KroneckerDelta(j, k)*M[i, l] assert _codegen_array_parse(expr) == (M, ({i, j, k}, l)) expr = KroneckerDelta(j, k)*(M[i, j]*N[k, l] + N[i, j]*M[k, l]) assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(CodegenArrayElementwiseAdd( CodegenArrayTensorProduct(M, N), CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), Permutation(0, 2)(1, 3)) ), (1, 2)), (i, l, frozenset({j, k}))) expr = KroneckerDelta(j, m)*KroneckerDelta(m, k)*(M[i, j]*N[k, l] + N[i, j]*M[k, l]) assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(CodegenArrayElementwiseAdd( CodegenArrayTensorProduct(M, N), CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), Permutation(0, 2)(1, 3)) ), (1, 2)), (i, l, frozenset({j, m, k}))) expr = KroneckerDelta(i, j)*KroneckerDelta(j, k)*KroneckerDelta(k,m)*M[i, 0]*KroneckerDelta(m, n) assert _codegen_array_parse(expr) == (M, ({i,j,k,m,n}, 0)) expr = M[i, i] assert _codegen_array_parse(expr) == (CodegenArrayDiagonal(M, (0, 1)), (i,)) def test_codegen_array_diagonal(): cg = CodegenArrayDiagonal(M, (1, 0)) assert cg == CodegenArrayDiagonal(M, (0, 1)) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P), (4, 1), (2, 0)) assert cg == CodegenArrayDiagonal(CodegenArrayTensorProduct(M, N, P), (1, 4), (0, 2)) def test_codegen_recognize_matrix_expression(): expr = CodegenArrayElementwiseAdd(M, CodegenArrayPermuteDims(M, [1, 0])) rec = _recognize_matrix_expression(expr) assert rec == _RecognizeMatOp(MatAdd, [M, _RecognizeMatOp(Transpose, [M])]) assert _unfold_recognized_expr(rec) == M + Transpose(M) expr = M[i,j] + N[i,j] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [M, N]) assert _unfold_recognized_expr(rec) == M + N expr = M[i,j] + N[j,i] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [M, _RecognizeMatOp(Transpose, [N])]) assert _unfold_recognized_expr(rec) == M + N.T expr = M[i,j]*N[k,l] + N[i,j]*M[k,l] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [_RecognizeMatMulLines([M, N]), _RecognizeMatMulLines([N, M])]) #assert _unfold_recognized_expr(rec) == TensorProduct(M, N) + TensorProduct(N, M) maybe? expr = (M*N*P)[i, j] p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatMulLines([_RecognizeMatOp(MatMul, [M, N, P])]) assert _unfold_recognized_expr(rec) == M*N*P expr = Sum(M[i,j]*(N*P)[j,m], (j, 0, k-1)) p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatMul, [M, N, P]) assert _unfold_recognized_expr(rec) == M*N*P expr = Sum((P[j, m] + P[m, j])*(M[i,j]*N[m,n] + N[i,j]*M[m,n]), (j, 0, k-1), (m, 0, k-1)) p1, p2 = _codegen_array_parse(expr) rec = _recognize_matrix_expression(p1) assert rec == _RecognizeMatOp(MatAdd, [ _RecognizeMatOp(MatMul, [M, _RecognizeMatOp(MatAdd, [P, _RecognizeMatOp(Transpose, [P])]), N]), _RecognizeMatOp(MatMul, [N, _RecognizeMatOp(MatAdd, [P, _RecognizeMatOp(Transpose, [P])]), M]) ]) assert _unfold_recognized_expr(rec) == M*(P + P.T)*N + N*(P + P.T)*M def test_codegen_array_shape(): expr = CodegenArrayTensorProduct(M, N, P, Q) assert expr.shape == (k, k, k, k, k, k, k, k) Z = MatrixSymbol("Z", m, n) expr = CodegenArrayTensorProduct(M, Z) assert expr.shape == (k, k, m, n) expr2 = CodegenArrayContraction(expr, (0, 1)) assert expr2.shape == (m, n) expr2 = CodegenArrayDiagonal(expr, (0, 1)) assert expr2.shape == (m, n, k) exprp = CodegenArrayPermuteDims(expr, [2, 1, 3, 0]) assert exprp.shape == (m, k, n, k) expr3 = CodegenArrayTensorProduct(N, Z) expr2 = CodegenArrayElementwiseAdd(expr, expr3) assert expr2.shape == (k, k, m, n) # Contraction along axes with discordant dimensions: raises(ValueError, lambda: CodegenArrayContraction(expr, (1, 2))) # Also diagonal needs the same dimensions: raises(ValueError, lambda: CodegenArrayDiagonal(expr, (1, 2))) def test_codegen_array_parse_out_of_bounds(): expr = Sum(M[i, i], (i, 0, 4)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, i], (i, 0, k)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, i], (i, 1, k-1)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, j]*N[j,m], (j, 0, 4)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, j]*N[j,m], (j, 0, k)) raises(ValueError, lambda: parse_indexed_expression(expr)) expr = Sum(M[i, j]*N[j,m], (j, 1, k-1)) raises(ValueError, lambda: parse_indexed_expression(expr)) def test_codegen_permutedims_sink(): cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [0, 1, 3, 2]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(M, CodegenArrayPermuteDims(N, [1, 0])) assert recognize_matrix_expression(sunk) == [M, N.T] cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [1, 0, 3, 2]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(CodegenArrayPermuteDims(M, [1, 0]), CodegenArrayPermuteDims(N, [1, 0])) assert recognize_matrix_expression(sunk) == [M.T, N.T] cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [3, 2, 1, 0]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(CodegenArrayPermuteDims(N, [1, 0]), CodegenArrayPermuteDims(M, [1, 0])) assert recognize_matrix_expression(sunk) == [N.T, M.T] cg = CodegenArrayPermuteDims(CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)), [1, 0]) sunk = cg.nest_permutation() assert sunk == CodegenArrayContraction(CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [[0, 3]]), (1, 2)) cg = CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N), [1, 0, 3, 2]) sunk = cg.nest_permutation() assert sunk == CodegenArrayTensorProduct(CodegenArrayPermuteDims(M, [1, 0]), CodegenArrayPermuteDims(N, [1, 0])) cg = CodegenArrayPermuteDims(CodegenArrayContraction(CodegenArrayTensorProduct(M, N, P), (1, 2), (3, 4)), [1, 0]) sunk = cg.nest_permutation() assert sunk == CodegenArrayContraction(CodegenArrayPermuteDims(CodegenArrayTensorProduct(M, N, P), [[0, 5]]), (1, 2), (3, 4)) sunk2 = sunk.expr.nest_permutation() def test_parsing_of_matrix_expressions(): expr = M*N assert _parse_matrix_expression(expr) == CodegenArrayContraction(CodegenArrayTensorProduct(M, N), (1, 2)) expr = Transpose(M) assert _parse_matrix_expression(expr) == CodegenArrayPermuteDims(M, [1, 0]) expr = M*Transpose(N) assert _parse_matrix_expression(expr) == CodegenArrayContraction(CodegenArrayTensorProduct(M, CodegenArrayPermuteDims(N, [1, 0])), (1, 2)) def test_special_matrices(): a = MatrixSymbol("a", k, 1) b = MatrixSymbol("b", k, 1) expr = a.T*b elem = expr[0, 0] cg = parse_indexed_expression(elem) assert cg == CodegenArrayContraction(CodegenArrayTensorProduct(a, b), (0, 2)) assert recognize_matrix_expression(cg) == a.T*b def test_push_indices_up_and_down(): indices = list(range(10)) contraction_indices = [(0, 6), (2, 8)] assert CodegenArrayContraction._push_indices_down(contraction_indices, indices) == (1, 3, 4, 5, 7, 9, 10, 11, 12, 13) assert CodegenArrayContraction._push_indices_up(contraction_indices, indices) == (None, 0, None, 1, 2, 3, None, 4, None, 5) assert CodegenArrayDiagonal._push_indices_down(contraction_indices, indices) == (0, 1, 2, 3, 4, 5, 7, 9, 10, 11) assert CodegenArrayDiagonal._push_indices_up(contraction_indices, indices) == (0, 1, 2, 3, 4, 5, None, 6, None, 7) contraction_indices = [(1, 2), (7, 8)] assert CodegenArrayContraction._push_indices_down(contraction_indices, indices) == (0, 3, 4, 5, 6, 9, 10, 11, 12, 13) assert CodegenArrayContraction._push_indices_up(contraction_indices, indices) == (0, None, None, 1, 2, 3, 4, None, None, 5) assert CodegenArrayContraction._push_indices_down(contraction_indices, indices) == (0, 3, 4, 5, 6, 9, 10, 11, 12, 13) assert CodegenArrayDiagonal._push_indices_up(contraction_indices, indices) == (0, 1, None, 2, 3, 4, 5, 6, None, 7) def test_recognize_diagonalized_vectors(): a = MatrixSymbol("a", k, 1) b = MatrixSymbol("b", k, 1) A = MatrixSymbol("A", k, k) B = MatrixSymbol("B", k, k) C = MatrixSymbol("C", k, k) X = MatrixSymbol("X", k, k) x = MatrixSymbol("x", k, 1) I1 = Identity(1) I = Identity(k) # Check matrix recognition over trivial dimensions: cg = CodegenArrayTensorProduct(a, b) assert recognize_matrix_expression(cg) == a*b.T cg = CodegenArrayTensorProduct(I1, a, b) assert recognize_matrix_expression(cg) == a*I1*b.T # Recognize trace inside a tensor product: cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, B, C), (0, 3), (1, 2)) assert recognize_matrix_expression(cg) == Trace(A*B)*C # Transform diagonal operator to contraction: cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(A, a), (1, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a)), (1, 2)) assert recognize_matrix_expression(cg) == A*DiagonalizeVector(a) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(a, b), (0, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(DiagonalizeVector(a), b), (0, 2)) assert recognize_matrix_expression(cg).doit() == DiagonalizeVector(a)*b cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(A, a), (0, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a)), (0, 2)) assert recognize_matrix_expression(cg) == A.T*DiagonalizeVector(a) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(I, x, I1), (0, 2), (3, 5)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(I, DiagonalizeVector(x), I1), (0, 2)) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(I, x, A, B), (1, 2), (5, 6)) assert cg.transform_to_product() == CodegenArrayDiagonal(CodegenArrayContraction(CodegenArrayTensorProduct(I, DiagonalizeVector(x), A, B), (1, 2)), (3, 4)) cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(x, I1), (1, 2)) assert isinstance(cg, CodegenArrayDiagonal) assert cg.diagonal_indices == ((1, 2),) assert recognize_matrix_expression(cg) == x cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(x, I), (0, 2)) assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(DiagonalizeVector(x), I), (0, 2)) assert recognize_matrix_expression(cg).doit() == DiagonalizeVector(x) cg = CodegenArrayDiagonal(x, (1,)) assert cg == x # Ignore identity matrices with contractions: cg = CodegenArrayContraction(CodegenArrayTensorProduct(I, A, I, I), (0, 2), (1, 3), (5, 7)) assert cg.split_multiple_contractions() == cg assert recognize_matrix_expression(cg) == Trace(A)*I cg = CodegenArrayContraction(CodegenArrayTensorProduct(Trace(A) * I, I, I), (1, 5), (3, 4)) assert cg.split_multiple_contractions() == cg assert recognize_matrix_expression(cg).doit() == Trace(A)*I # Add DiagonalizeVector when required: cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a), (1, 2)) assert cg.split_multiple_contractions() == cg assert recognize_matrix_expression(cg) == A*a cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, B), (1, 2, 4)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), B), (1, 2), (3, 4)) assert recognize_matrix_expression(cg) == A*DiagonalizeVector(a)*B cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, B), (0, 2, 4)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), B), (0, 2), (3, 4)) assert recognize_matrix_expression(cg) == A.T*DiagonalizeVector(a)*B cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, b, a.T, B), (0, 2, 4, 7, 9)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), DiagonalizeVector(b), DiagonalizeVector(a), B), (0, 2), (3, 4), (5, 7), (6, 9)) assert recognize_matrix_expression(cg).doit() == A.T*DiagonalizeVector(a)*DiagonalizeVector(b)*DiagonalizeVector(a)*B.T cg = CodegenArrayContraction(CodegenArrayTensorProduct(I1, I1, I1), (1, 2, 4)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(I1, I1, I1), (1, 2), (3, 4)) assert recognize_matrix_expression(cg).doit() == Identity(1) cg = CodegenArrayContraction(CodegenArrayTensorProduct(I, I, I, I, A), (1, 2, 8), (5, 6, 9)) assert recognize_matrix_expression(cg.split_multiple_contractions()).doit() == A cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, C, a, B), (1, 2, 4), (5, 6, 8)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagonalizeVector(a), C, DiagonalizeVector(a), B), (1, 2), (3, 4), (5, 6), (7, 8)) assert recognize_matrix_expression(cg) == A*DiagonalizeVector(a)*C*DiagonalizeVector(a)*B cg = CodegenArrayContraction(CodegenArrayTensorProduct(a, I1, b, I1, (a.T*b).applyfunc(cos)), (1, 2, 8), (5, 6, 9)) assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(a, I1, b, I1, (a.T*b).applyfunc(cos)), (1, 2), (3, 8), (5, 6), (7, 9)) assert recognize_matrix_expression(cg) == MatMul(a, I1, (a.T*b).applyfunc(cos), Transpose(I1), b.T) cg = CodegenArrayContraction(CodegenArrayTensorProduct(A.T, a, b, b.T, (A*X*b).applyfunc(cos)), (1, 2, 8), (5, 6, 9)) assert cg.split_multiple_contractions() == CodegenArrayContraction( CodegenArrayTensorProduct(A.T, DiagonalizeVector(a), b, b.T, (A*X*b).applyfunc(cos)), (1, 2), (3, 8), (5, 6, 9)) # assert recognize_matrix_expression(cg) # Check no overlap of lines: cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, C, a, B), (1, 2, 4), (5, 6, 8), (3, 7)) assert cg.split_multiple_contractions() == cg cg = CodegenArrayContraction(CodegenArrayTensorProduct(a, b, A), (0, 2, 4), (1, 3)) assert cg.split_multiple_contractions() == cg

b71efa4d81948a7e1a186be0703fe6278d06fb5878b9ddd96b3938ebe6b915b6

import itertools as it from sympy.core.function import Function from sympy.core.numbers import I, oo, Rational from sympy.core.power import Pow from sympy.core.singleton import S from sympy.core.symbol import Symbol from sympy.functions.elementary.miscellaneous import (sqrt, cbrt, root, Min, Max, real_root) from sympy.functions.elementary.trigonometric import cos, sin from sympy.functions.elementary.exponential import log from sympy.functions.elementary.integers import floor, ceiling from sympy.functions.special.delta_functions import Heaviside from sympy.utilities.lambdify import lambdify from sympy.utilities.pytest import raises, skip, ignore_warnings from sympy.external import import_module def test_Min(): from sympy.abc import x, y, z n = Symbol('n', negative=True) n_ = Symbol('n_', negative=True) nn = Symbol('nn', nonnegative=True) nn_ = Symbol('nn_', nonnegative=True) p = Symbol('p', positive=True) p_ = Symbol('p_', positive=True) np = Symbol('np', nonpositive=True) np_ = Symbol('np_', nonpositive=True) r = Symbol('r', real=True) assert Min(5, 4) == 4 assert Min(-oo, -oo) == -oo assert Min(-oo, n) == -oo assert Min(n, -oo) == -oo assert Min(-oo, np) == -oo assert Min(np, -oo) == -oo assert Min(-oo, 0) == -oo assert Min(0, -oo) == -oo assert Min(-oo, nn) == -oo assert Min(nn, -oo) == -oo assert Min(-oo, p) == -oo assert Min(p, -oo) == -oo assert Min(-oo, oo) == -oo assert Min(oo, -oo) == -oo assert Min(n, n) == n assert Min(n, np) == Min(n, np) assert Min(np, n) == Min(np, n) assert Min(n, 0) == n assert Min(0, n) == n assert Min(n, nn) == n assert Min(nn, n) == n assert Min(n, p) == n assert Min(p, n) == n assert Min(n, oo) == n assert Min(oo, n) == n assert Min(np, np) == np assert Min(np, 0) == np assert Min(0, np) == np assert Min(np, nn) == np assert Min(nn, np) == np assert Min(np, p) == np assert Min(p, np) == np assert Min(np, oo) == np assert Min(oo, np) == np assert Min(0, 0) == 0 assert Min(0, nn) == 0 assert Min(nn, 0) == 0 assert Min(0, p) == 0 assert Min(p, 0) == 0 assert Min(0, oo) == 0 assert Min(oo, 0) == 0 assert Min(nn, nn) == nn assert Min(nn, p) == Min(nn, p) assert Min(p, nn) == Min(p, nn) assert Min(nn, oo) == nn assert Min(oo, nn) == nn assert Min(p, p) == p assert Min(p, oo) == p assert Min(oo, p) == p assert Min(oo, oo) == oo assert Min(n, n_).func is Min assert Min(nn, nn_).func is Min assert Min(np, np_).func is Min assert Min(p, p_).func is Min # lists assert Min() == S.Infinity assert Min(x) == x assert Min(x, y) == Min(y, x) assert Min(x, y, z) == Min(z, y, x) assert Min(x, Min(y, z)) == Min(z, y, x) assert Min(x, Max(y, -oo)) == Min(x, y) assert Min(p, oo, n, p, p, p_) == n assert Min(p_, n_, p) == n_ assert Min(n, oo, -7, p, p, 2) == Min(n, -7) assert Min(2, x, p, n, oo, n_, p, 2, -2, -2) == Min(-2, x, n, n_) assert Min(0, x, 1, y) == Min(0, x, y) assert Min(1000, 100, -100, x, p, n) == Min(n, x, -100) assert Min(cos(x), sin(x)) == Min(cos(x), sin(x)) assert Min(cos(x), sin(x)).subs(x, 1) == cos(1) assert Min(cos(x), sin(x)).subs(x, S(1)/2) == sin(S(1)/2) raises(ValueError, lambda: Min(cos(x), sin(x)).subs(x, I)) raises(ValueError, lambda: Min(I)) raises(ValueError, lambda: Min(I, x)) raises(ValueError, lambda: Min(S.ComplexInfinity, x)) assert Min(1, x).diff(x) == Heaviside(1 - x) assert Min(x, 1).diff(x) == Heaviside(1 - x) assert Min(0, -x, 1 - 2*x).diff(x) == -Heaviside(x + Min(0, -2*x + 1)) \ - 2*Heaviside(2*x + Min(0, -x) - 1) # issue 7619 f = Function('f') assert Min(1, 2*Min(f(1), 2)) # doesn't fail # issue 7233 e = Min(0, x) assert e.evalf == e.n assert e.n().args == (0, x) # issue 8643 m = Min(n, p_, n_, r) assert m.is_positive is False assert m.is_nonnegative is False assert m.is_negative is True m = Min(p, p_) assert m.is_positive is True assert m.is_nonnegative is True assert m.is_negative is False m = Min(p, nn_, p_) assert m.is_positive is None assert m.is_nonnegative is True assert m.is_negative is False m = Min(nn, p, r) assert m.is_positive is None assert m.is_nonnegative is None assert m.is_negative is None def test_Max(): from sympy.abc import x, y, z n = Symbol('n', negative=True) n_ = Symbol('n_', negative=True) nn = Symbol('nn', nonnegative=True) nn_ = Symbol('nn_', nonnegative=True) p = Symbol('p', positive=True) p_ = Symbol('p_', positive=True) np = Symbol('np', nonpositive=True) np_ = Symbol('np_', nonpositive=True) r = Symbol('r', real=True) assert Max(5, 4) == 5 # lists assert Max() == S.NegativeInfinity assert Max(x) == x assert Max(x, y) == Max(y, x) assert Max(x, y, z) == Max(z, y, x) assert Max(x, Max(y, z)) == Max(z, y, x) assert Max(x, Min(y, oo)) == Max(x, y) assert Max(n, -oo, n_, p, 2) == Max(p, 2) assert Max(n, -oo, n_, p) == p assert Max(2, x, p, n, -oo, S.NegativeInfinity, n_, p, 2) == Max(2, x, p) assert Max(0, x, 1, y) == Max(1, x, y) assert Max(r, r + 1, r - 1) == 1 + r assert Max(1000, 100, -100, x, p, n) == Max(p, x, 1000) assert Max(cos(x), sin(x)) == Max(sin(x), cos(x)) assert Max(cos(x), sin(x)).subs(x, 1) == sin(1) assert Max(cos(x), sin(x)).subs(x, S(1)/2) == cos(S(1)/2) raises(ValueError, lambda: Max(cos(x), sin(x)).subs(x, I)) raises(ValueError, lambda: Max(I)) raises(ValueError, lambda: Max(I, x)) raises(ValueError, lambda: Max(S.ComplexInfinity, 1)) assert Max(n, -oo, n_, p, 2) == Max(p, 2) assert Max(n, -oo, n_, p, 1000) == Max(p, 1000) assert Max(1, x).diff(x) == Heaviside(x - 1) assert Max(x, 1).diff(x) == Heaviside(x - 1) assert Max(x**2, 1 + x, 1).diff(x) == \ 2*x*Heaviside(x**2 - Max(1, x + 1)) \ + Heaviside(x - Max(1, x**2) + 1) e = Max(0, x) assert e.evalf == e.n assert e.n().args == (0, x) # issue 8643 m = Max(p, p_, n, r) assert m.is_positive is True assert m.is_nonnegative is True assert m.is_negative is False m = Max(n, n_) assert m.is_positive is False assert m.is_nonnegative is False assert m.is_negative is True m = Max(n, n_, r) assert m.is_positive is None assert m.is_nonnegative is None assert m.is_negative is None m = Max(n, nn, r) assert m.is_positive is None assert m.is_nonnegative is True assert m.is_negative is False def test_minmax_assumptions(): r = Symbol('r', real=True) a = Symbol('a', real=True, algebraic=True) t = Symbol('t', real=True, transcendental=True) q = Symbol('q', rational=True) p = Symbol('p', irrational=True) n = Symbol('n', rational=True, integer=False) i = Symbol('i', integer=True) o = Symbol('o', odd=True) e = Symbol('e', even=True) k = Symbol('k', prime=True) reals = [r, a, t, q, p, n, i, o, e, k] for ext in (Max, Min): for x, y in it.product(reals, repeat=2): # Must be real assert ext(x, y).is_real # Algebraic? if x.is_algebraic and y.is_algebraic: assert ext(x, y).is_algebraic elif x.is_transcendental and y.is_transcendental: assert ext(x, y).is_transcendental else: assert ext(x, y).is_algebraic is None # Rational? if x.is_rational and y.is_rational: assert ext(x, y).is_rational elif x.is_irrational and y.is_irrational: assert ext(x, y).is_irrational else: assert ext(x, y).is_rational is None # Integer? if x.is_integer and y.is_integer: assert ext(x, y).is_integer elif x.is_noninteger and y.is_noninteger: assert ext(x, y).is_noninteger else: assert ext(x, y).is_integer is None # Odd? if x.is_odd and y.is_odd: assert ext(x, y).is_odd elif x.is_odd is False and y.is_odd is False: assert ext(x, y).is_odd is False else: assert ext(x, y).is_odd is None # Even? if x.is_even and y.is_even: assert ext(x, y).is_even elif x.is_even is False and y.is_even is False: assert ext(x, y).is_even is False else: assert ext(x, y).is_even is None # Prime? if x.is_prime and y.is_prime: assert ext(x, y).is_prime elif x.is_prime is False and y.is_prime is False: assert ext(x, y).is_prime is False else: assert ext(x, y).is_prime is None def test_issue_8413(): x = Symbol('x', real=True) # we can't evaluate in general because non-reals are not # comparable: Min(floor(3.2 + I), 3.2 + I) -> ValueError assert Min(floor(x), x) == floor(x) assert Min(ceiling(x), x) == x assert Max(floor(x), x) == x assert Max(ceiling(x), x) == ceiling(x) def test_root(): from sympy.abc import x n = Symbol('n', integer=True) k = Symbol('k', integer=True) assert root(2, 2) == sqrt(2) assert root(2, 1) == 2 assert root(2, 3) == 2**Rational(1, 3) assert root(2, 3) == cbrt(2) assert root(2, -5) == 2**Rational(4, 5)/2 assert root(-2, 1) == -2 assert root(-2, 2) == sqrt(2)*I assert root(-2, 1) == -2 assert root(x, 2) == sqrt(x) assert root(x, 1) == x assert root(x, 3) == x**Rational(1, 3) assert root(x, 3) == cbrt(x) assert root(x, -5) == x**Rational(-1, 5) assert root(x, n) == x**(1/n) assert root(x, -n) == x**(-1/n) assert root(x, n, k) == (-1)**(2*k/n)*x**(1/n) def test_real_root(): assert real_root(-8, 3) == -2 assert real_root(-16, 4) == root(-16, 4) r = root(-7, 4) assert real_root(r) == r r1 = root(-1, 3) r2 = r1**2 r3 = root(-1, 4) assert real_root(r1 + r2 + r3) == -1 + r2 + r3 assert real_root(root(-2, 3)) == -root(2, 3) assert real_root(-8., 3) == -2 x = Symbol('x') n = Symbol('n') g = real_root(x, n) assert g.subs(dict(x=-8, n=3)) == -2 assert g.subs(dict(x=8, n=3)) == 2 # give principle root if there is no real root -- if this is not desired # then maybe a Root class is needed to raise an error instead assert g.subs(dict(x=I, n=3)) == cbrt(I) assert g.subs(dict(x=-8, n=2)) == sqrt(-8) assert g.subs(dict(x=I, n=2)) == sqrt(I) def test_issue_11463(): numpy = import_module('numpy') if not numpy: skip("numpy not installed.") x = Symbol('x') f = lambdify(x, real_root((log(x/(x-2))), 3), 'numpy') # numpy.select evaluates all options before considering conditions, # so it raises a warning about root of negative number which does # not affect the outcome. This warning is suppressed here with ignore_warnings(RuntimeWarning): assert f(numpy.array(-1)) < -1 def test_rewrite_MaxMin_as_Heaviside(): from sympy.abc import x assert Max(0, x).rewrite(Heaviside) == x*Heaviside(x) assert Max(3, x).rewrite(Heaviside) == x*Heaviside(x - 3) + \ 3*Heaviside(-x + 3) assert Max(0, x+2, 2*x).rewrite(Heaviside) == \ 2*x*Heaviside(2*x)*Heaviside(x - 2) + \ (x + 2)*Heaviside(-x + 2)*Heaviside(x + 2) assert Min(0, x).rewrite(Heaviside) == x*Heaviside(-x) assert Min(3, x).rewrite(Heaviside) == x*Heaviside(-x + 3) + \ 3*Heaviside(x - 3) assert Min(x, -x, -2).rewrite(Heaviside) == \ x*Heaviside(-2*x)*Heaviside(-x - 2) - \ x*Heaviside(2*x)*Heaviside(x - 2) \ - 2*Heaviside(-x + 2)*Heaviside(x + 2) def test_rewrite_MaxMin_as_Piecewise(): from sympy import symbols, Piecewise x, y, z, a, b = symbols('x y z a b', real=True) vx, vy, va = symbols('vx vy va') assert Max(a, b).rewrite(Piecewise) == Piecewise((a, a >= b), (b, True)) assert Max(x, y, z).rewrite(Piecewise) == Piecewise((x, (x >= y) & (x >= z)), (y, y >= z), (z, True)) assert Max(x, y, a, b).rewrite(Piecewise) == Piecewise((a, (a >= b) & (a >= x) & (a >= y)), (b, (b >= x) & (b >= y)), (x, x >= y), (y, True)) assert Min(a, b).rewrite(Piecewise) == Piecewise((a, a <= b), (b, True)) assert Min(x, y, z).rewrite(Piecewise) == Piecewise((x, (x <= y) & (x <= z)), (y, y <= z), (z, True)) assert Min(x, y, a, b).rewrite(Piecewise) == Piecewise((a, (a <= b) & (a <= x) & (a <= y)), (b, (b <= x) & (b <= y)), (x, x <= y), (y, True)) # Piecewise rewriting of Min/Max does also takes place for not explicitly real arguments assert Max(vx, vy).rewrite(Piecewise) == Piecewise((vx, vx >= vy), (vy, True)) assert Min(va, vx, vy).rewrite(Piecewise) == Piecewise((va, (va <= vx) & (va <= vy)), (vx, vx <= vy), (vy, True)) def test_issue_11099(): from sympy.abc import x, y # some fixed value tests fixed_test_data = {x: -2, y: 3} assert Min(x, y).evalf(subs=fixed_test_data) == \ Min(x, y).subs(fixed_test_data).evalf() assert Max(x, y).evalf(subs=fixed_test_data) == \ Max(x, y).subs(fixed_test_data).evalf() # randomly generate some test data from random import randint for i in range(20): random_test_data = {x: randint(-100, 100), y: randint(-100, 100)} assert Min(x, y).evalf(subs=random_test_data) == \ Min(x, y).subs(random_test_data).evalf() assert Max(x, y).evalf(subs=random_test_data) == \ Max(x, y).subs(random_test_data).evalf() def test_issue_12638(): from sympy.abc import a, b, c, d assert Min(a, b, c, Max(a, b)) == Min(a, b, c) assert Min(a, b, Max(a, b, c)) == Min(a, b) assert Min(a, b, Max(a, c)) == Min(a, b) def test_instantiation_evaluation(): from sympy.abc import v, w, x, y, z assert Min(1, Max(2, x)) == 1 assert Max(3, Min(2, x)) == 3 assert Min(Max(x, y), Max(x, z)) == Max(x, Min(y, z)) assert set(Min(Max(w, x), Max(y, z)).args) == set( [Max(w, x), Max(y, z)]) assert Min(Max(x, y), Max(x, z), w) == Min( w, Max(x, Min(y, z))) A, B = Min, Max for i in range(2): assert A(x, B(x, y)) == x assert A(x, B(y, A(x, w, z))) == A(x, B(y, A(w, z))) A, B = B, A assert Min(w, Max(x, y), Max(v, x, z)) == Min( w, Max(x, Min(y, Max(v, z)))) def test_rewrite_as_Abs(): from itertools import permutations from sympy.functions.elementary.complexes import Abs from sympy.abc import x, y, z, w def test(e): free = e.free_symbols a = e.rewrite(Abs) assert not a.has(Min, Max) for i in permutations(range(len(free))): reps = dict(zip(free, i)) assert a.xreplace(reps) == e.xreplace(reps) test(Min(x, y)) test(Max(x, y)) test(Min(x, y, z)) test(Min(Max(w, x), Max(y, z))) def test_issue_14000(): assert isinstance(sqrt(4, evaluate=False), Pow) == True assert isinstance(cbrt(3.5, evaluate=False), Pow) == True assert isinstance(root(16, 4, evaluate=False), Pow) == True assert sqrt(4, evaluate=False) == Pow(4, S.Half, evaluate=False) assert cbrt(3.5, evaluate=False) == Pow(3.5, Rational(1, 3), evaluate=False) assert root(4, 2, evaluate=False) == Pow(4, Rational(1, 2), evaluate=False) assert root(16, 4, 2, evaluate=False).has(Pow) == True assert real_root(-8, 3, evaluate=False).has(Pow) == True

9a011ca80e9acf7b40eccb65204d76bd363cbb4cda696f6dba2f5fabf145c41f

from sympy import (acos, acosh, asinh, atan, cos, Derivative, diff, dsolve, Dummy, Eq, Ne, erf, erfi, exp, Function, I, Integral, LambertW, log, O, pi, Rational, rootof, S, simplify, sin, sqrt, Subs, Symbol, tan, asin, sinh, Piecewise, symbols, Poly, sec, Ei, re, im) from sympy.solvers.ode import (_undetermined_coefficients_match, checkodesol, classify_ode, classify_sysode, constant_renumber, constantsimp, homogeneous_order, infinitesimals, checkinfsol, checksysodesol, solve_ics, dsolve, get_numbered_constants) from sympy.solvers.deutils import ode_order from sympy.utilities.pytest import XFAIL, skip, raises, slow, ON_TRAVIS C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, C10 = symbols('C0:11') u, x, y, z = symbols('u,x:z', real=True) f = Function('f') g = Function('g') h = Function('h') # Note: the tests below may fail (but still be correct) if ODE solver, # the integral engine, solve(), or even simplify() changes. Also, in # differently formatted solutions, the arbitrary constants might not be # equal. Using specific hints in tests can help to avoid this. # Tests of order higher than 1 should run the solutions through # constant_renumber because it will normalize it (constant_renumber causes # dsolve() to return different results on different machines) def test_linear_2eq_order1(): x, y, z = symbols('x, y, z', cls=Function) k, l, m, n = symbols('k, l, m, n', Integer=True) t = Symbol('t') x0, y0 = symbols('x0, y0', cls=Function) eq1 = (Eq(diff(x(t),t), 9*y(t)), Eq(diff(y(t),t), 12*x(t))) sol1 = [Eq(x(t), 9*C1*exp(6*sqrt(3)*t) + 9*C2*exp(-6*sqrt(3)*t)), \ Eq(y(t), 6*sqrt(3)*C1*exp(6*sqrt(3)*t) - 6*sqrt(3)*C2*exp(-6*sqrt(3)*t))] assert checksysodesol(eq1, sol1) == (True, [0, 0]) eq2 = (Eq(diff(x(t),t), 2*x(t) + 4*y(t)), Eq(diff(y(t),t), 12*x(t) + 41*y(t))) sol2 = [Eq(x(t), 4*C1*exp(t*(sqrt(1713)/2 + S(43)/2)) + 4*C2*exp(t*(-sqrt(1713)/2 + S(43)/2))), \ Eq(y(t), C1*(S(39)/2 + sqrt(1713)/2)*exp(t*(sqrt(1713)/2 + S(43)/2)) + \ C2*(-sqrt(1713)/2 + S(39)/2)*exp(t*(-sqrt(1713)/2 + S(43)/2)))] assert checksysodesol(eq2, sol2) == (True, [0, 0]) eq3 = (Eq(diff(x(t),t), x(t) + y(t)), Eq(diff(y(t),t), -2*x(t) + 2*y(t))) sol3 = [Eq(x(t), (C1*cos(sqrt(7)*t/2) + C2*sin(sqrt(7)*t/2))*exp(3*t/2)), \ Eq(y(t), (C1*(-sqrt(7)*sin(sqrt(7)*t/2)/2 + cos(sqrt(7)*t/2)/2) + \ C2*(sin(sqrt(7)*t/2)/2 + sqrt(7)*cos(sqrt(7)*t/2)/2))*exp(3*t/2))] assert checksysodesol(eq3, sol3) == (True, [0, 0]) eq4 = (Eq(diff(x(t),t), x(t) + y(t) + 9), Eq(diff(y(t),t), 2*x(t) + 5*y(t) + 23)) sol4 = [Eq(x(t), C1*exp(t*(sqrt(6) + 3)) + C2*exp(t*(-sqrt(6) + 3)) - S(22)/3), \ Eq(y(t), C1*(2 + sqrt(6))*exp(t*(sqrt(6) + 3)) + C2*(-sqrt(6) + 2)*exp(t*(-sqrt(6) + 3)) - S(5)/3)] assert checksysodesol(eq4, sol4) == (True, [0, 0]) eq5 = (Eq(diff(x(t),t), x(t) + y(t) + 81), Eq(diff(y(t),t), -2*x(t) + y(t) + 23)) sol5 = [Eq(x(t), (C1*cos(sqrt(2)*t) + C2*sin(sqrt(2)*t))*exp(t) - S(58)/3), \ Eq(y(t), (-sqrt(2)*C1*sin(sqrt(2)*t) + sqrt(2)*C2*cos(sqrt(2)*t))*exp(t) - S(185)/3)] assert checksysodesol(eq5, sol5) == (True, [0, 0]) eq6 = (Eq(diff(x(t),t), 5*t*x(t) + 2*y(t)), Eq(diff(y(t),t), 2*x(t) + 5*t*y(t))) sol6 = [Eq(x(t), (C1*exp(2*t) + C2*exp(-2*t))*exp(S(5)/2*t**2)), \ Eq(y(t), (C1*exp(2*t) - C2*exp(-2*t))*exp(S(5)/2*t**2))] s = dsolve(eq6) assert checksysodesol(eq6, sol6) == (True, [0, 0]) eq7 = (Eq(diff(x(t),t), 5*t*x(t) + t**2*y(t)), Eq(diff(y(t),t), -t**2*x(t) + 5*t*y(t))) sol7 = [Eq(x(t), (C1*cos((t**3)/3) + C2*sin((t**3)/3))*exp(S(5)/2*t**2)), \ Eq(y(t), (-C1*sin((t**3)/3) + C2*cos((t**3)/3))*exp(S(5)/2*t**2))] assert checksysodesol(eq7, sol7) == (True, [0, 0]) eq8 = (Eq(diff(x(t),t), 5*t*x(t) + t**2*y(t)), Eq(diff(y(t),t), -t**2*x(t) + (5*t+9*t**2)*y(t))) sol8 = [Eq(x(t), (C1*exp((sqrt(77)/2 + S(9)/2)*(t**3)/3) + \ C2*exp((-sqrt(77)/2 + S(9)/2)*(t**3)/3))*exp(S(5)/2*t**2)), \ Eq(y(t), (C1*(sqrt(77)/2 + S(9)/2)*exp((sqrt(77)/2 + S(9)/2)*(t**3)/3) + \ C2*(-sqrt(77)/2 + S(9)/2)*exp((-sqrt(77)/2 + S(9)/2)*(t**3)/3))*exp(S(5)/2*t**2))] assert checksysodesol(eq8, sol8) == (True, [0, 0]) eq10 = (Eq(diff(x(t),t), 5*t*x(t) + t**2*y(t)), Eq(diff(y(t),t), (1-t**2)*x(t) + (5*t+9*t**2)*y(t))) sol10 = [Eq(x(t), C1*x0(t) + C2*x0(t)*Integral(t**2*exp(Integral(5*t, t))*exp(Integral(9*t**2 + 5*t, t))/x0(t)**2, t)), \ Eq(y(t), C1*y0(t) + C2*(y0(t)*Integral(t**2*exp(Integral(5*t, t))*exp(Integral(9*t**2 + 5*t, t))/x0(t)**2, t) + \ exp(Integral(5*t, t))*exp(Integral(9*t**2 + 5*t, t))/x0(t)))] s = dsolve(eq10) assert s == sol10 # too complicated to test with subs and simplify # assert checksysodesol(eq10, sol10) == (True, [0, 0]) # this one fails def test_linear_2eq_order1_nonhomog_linear(): e = [Eq(diff(f(x), x), f(x) + g(x) + 5*x), Eq(diff(g(x), x), f(x) - g(x))] raises(NotImplementedError, lambda: dsolve(e)) def test_linear_2eq_order1_nonhomog(): # Note: once implemented, add some tests esp. with resonance e = [Eq(diff(f(x), x), f(x) + exp(x)), Eq(diff(g(x), x), f(x) + g(x) + x*exp(x))] raises(NotImplementedError, lambda: dsolve(e)) def test_linear_2eq_order1_type2_degen(): e = [Eq(diff(f(x), x), f(x) + 5), Eq(diff(g(x), x), f(x) + 7)] s1 = [Eq(f(x), C1*exp(x) - 5), Eq(g(x), C1*exp(x) - C2 + 2*x - 5)] assert checksysodesol(e, s1) == (True, [0, 0]) def test_dsolve_linear_2eq_order1_diag_triangular(): e = [Eq(diff(f(x), x), f(x)), Eq(diff(g(x), x), g(x))] s1 = [Eq(f(x), C1*exp(x)), Eq(g(x), C2*exp(x))] assert checksysodesol(e, s1) == (True, [0, 0]) e = [Eq(diff(f(x), x), 2*f(x)), Eq(diff(g(x), x), 3*f(x) + 7*g(x))] s1 = [Eq(f(x), -5*C2*exp(2*x)), Eq(g(x), 5*C1*exp(7*x) + 3*C2*exp(2*x))] assert checksysodesol(e, s1) == (True, [0, 0]) def test_sysode_linear_2eq_order1_type1_D_lt_0(): e = [Eq(diff(f(x), x), -9*I*f(x) - 4*g(x)), Eq(diff(g(x), x), -4*I*g(x))] s1 = [Eq(f(x), -4*C1*exp(-4*I*x) - 4*C2*exp(-9*I*x)), \ Eq(g(x), 5*I*C1*exp(-4*I*x))] assert checksysodesol(e, s1) == (True, [0, 0]) def test_sysode_linear_2eq_order1_type1_D_lt_0_b_eq_0(): e = [Eq(diff(f(x), x), -9*I*f(x)), Eq(diff(g(x), x), -4*I*g(x))] s1 = [Eq(f(x), -5*I*C2*exp(-9*I*x)), Eq(g(x), 5*I*C1*exp(-4*I*x))] assert checksysodesol(e, s1) == (True, [0, 0]) def test_sysode_linear_2eq_order1_many_zeros(): t = Symbol('t') corner_cases = [(0, 0, 0, 0), (1, 0, 0, 0), (0, 1, 0, 0), (0, 0, 1, 0), (0, 0, 0, 1), (1, 0, 0, I), (I, 0, 0, -I), (0, I, 0, 0), (0, I, I, 0)] s1 = [[Eq(f(t), C1), Eq(g(t), C2)], [Eq(f(t), C1*exp(t)), Eq(g(t), -C2)], [Eq(f(t), C1 + C2*t), Eq(g(t), C2)], [Eq(f(t), C2), Eq(g(t), C1 + C2*t)], [Eq(f(t), -C2), Eq(g(t), C1*exp(t))], [Eq(f(t), C1*(1 - I)*exp(t)), Eq(g(t), C2*(-1 + I)*exp(I*t))], [Eq(f(t), 2*I*C1*exp(I*t)), Eq(g(t), -2*I*C2*exp(-I*t))], [Eq(f(t), I*C1 + I*C2*t), Eq(g(t), C2)], [Eq(f(t), I*C1*exp(I*t) + I*C2*exp(-I*t)), \ Eq(g(t), I*C1*exp(I*t) - I*C2*exp(-I*t))] ] for r, sol in zip(corner_cases, s1): eq = [Eq(diff(f(t), t), r[0]*f(t) + r[1]*g(t)), Eq(diff(g(t), t), r[2]*f(t) + r[3]*g(t))] assert checksysodesol(eq, sol) == (True, [0, 0]) def test_dsolve_linsystem_symbol_piecewise(): u = Symbol('u') # XXX it's more complicated with real u eq = (Eq(diff(f(x), x), 2*f(x) + g(x)), Eq(diff(g(x), x), u*f(x))) s1 = [Eq(f(x), Piecewise((C1*exp(x*(sqrt(4*u + 4)/2 + 1)) + C2*exp(x*(-sqrt(4*u + 4)/2 + 1)), Ne(4*u + 4, 0)), ((C1 + C2*(x + Piecewise((0, Eq(sqrt(4*u + 4)/2 + 1, 2)), (1/(-sqrt(4*u + 4)/2 + 1), True))))*exp(x*(sqrt(4*u + 4)/2 + 1)), True))), Eq(g(x), Piecewise((C1*(sqrt(4*u + 4)/2 - 1)*exp(x*(sqrt(4*u + 4)/2 + 1)) + C2*(-sqrt(4*u + 4)/2 - 1)*exp(x*(-sqrt(4*u + 4)/2 + 1)), Ne(4*u + 4, 0)), ((C1*(sqrt(4*u + 4)/2 - 1) + C2*(x*(sqrt(4*u + 4)/2 - 1) + Piecewise((1, Eq(sqrt(4*u + 4)/2 + 1, 2)), (0, True))))*exp(x*(sqrt(4*u + 4)/2 + 1)), True)))] assert dsolve(eq) == s1 # FIXME: assert checksysodesol(eq, s) == (True, [0, 0]) # Remove lines below when checksysodesol works s = [(l.lhs, l.rhs) for l in s1] for v in [0, 7, -42, 5*I, 3 + 4*I]: assert eq[0].subs(s).subs(u, v).doit().simplify() assert eq[1].subs(s).subs(u, v).doit().simplify() # example from https://groups.google.com/d/msg/sympy/xmzoqW6tWaE/sf0bgQrlCgAJ i, r1, c1, r2, c2, t = symbols('i, r1, c1, r2, c2, t') x1 = Function('x1') x2 = Function('x2') eq1 = r1*c1*Derivative(x1(t), t) + x1(t) - x2(t) - r1*i eq2 = r2*c1*Derivative(x1(t), t) + r2*c2*Derivative(x2(t), t) + x2(t) - r2*i sol = dsolve((eq1, eq2)) # FIXME: assert checksysodesol(eq, sol) == (True, [0, 0]) # Remove line below when checksysodesol works assert all(s.has(Piecewise) for s in sol) @slow def test_linear_2eq_order2(): x, y, z = symbols('x, y, z', cls=Function) k, l, m, n = symbols('k, l, m, n', Integer=True) t, l = symbols('t, l') x0, y0 = symbols('x0, y0', cls=Function) eq1 = (Eq(diff(x(t),t,t), 5*x(t) + 43*y(t)), Eq(diff(y(t),t,t), x(t) + 9*y(t))) sol1 = [Eq(x(t), 43*C1*exp(t*rootof(l**4 - 14*l**2 + 2, 0)) + 43*C2*exp(t*rootof(l**4 - 14*l**2 + 2, 1)) + \ 43*C3*exp(t*rootof(l**4 - 14*l**2 + 2, 2)) + 43*C4*exp(t*rootof(l**4 - 14*l**2 + 2, 3))), \ Eq(y(t), C1*(rootof(l**4 - 14*l**2 + 2, 0)**2 - 5)*exp(t*rootof(l**4 - 14*l**2 + 2, 0)) + \ C2*(rootof(l**4 - 14*l**2 + 2, 1)**2 - 5)*exp(t*rootof(l**4 - 14*l**2 + 2, 1)) + \ C3*(rootof(l**4 - 14*l**2 + 2, 2)**2 - 5)*exp(t*rootof(l**4 - 14*l**2 + 2, 2)) + \ C4*(rootof(l**4 - 14*l**2 + 2, 3)**2 - 5)*exp(t*rootof(l**4 - 14*l**2 + 2, 3)))] assert dsolve(eq1) == sol1 # FIXME: assert checksysodesol(eq1, sol1) == (True, [0, 0]) # this one fails eq2 = (Eq(diff(x(t),t,t), 8*x(t)+3*y(t)+31), Eq(diff(y(t),t,t), 9*x(t)+7*y(t)+12)) sol2 = [Eq(x(t), 3*C1*exp(t*rootof(l**4 - 15*l**2 + 29, 0)) + 3*C2*exp(t*rootof(l**4 - 15*l**2 + 29, 1)) + \ 3*C3*exp(t*rootof(l**4 - 15*l**2 + 29, 2)) + 3*C4*exp(t*rootof(l**4 - 15*l**2 + 29, 3)) - S(181)/29), \ Eq(y(t), C1*(rootof(l**4 - 15*l**2 + 29, 0)**2 - 8)*exp(t*rootof(l**4 - 15*l**2 + 29, 0)) + \ C2*(rootof(l**4 - 15*l**2 + 29, 1)**2 - 8)*exp(t*rootof(l**4 - 15*l**2 + 29, 1)) + \ C3*(rootof(l**4 - 15*l**2 + 29, 2)**2 - 8)*exp(t*rootof(l**4 - 15*l**2 + 29, 2)) + \ C4*(rootof(l**4 - 15*l**2 + 29, 3)**2 - 8)*exp(t*rootof(l**4 - 15*l**2 + 29, 3)) + S(183)/29)] assert dsolve(eq2) == sol2 # FIXME: assert checksysodesol(eq2, sol2) == (True, [0, 0]) # this one fails eq3 = (Eq(diff(x(t),t,t) - 9*diff(y(t),t) + 7*x(t),0), Eq(diff(y(t),t,t) + 9*diff(x(t),t) + 7*y(t),0)) sol3 = [Eq(x(t), C1*cos(t*(S(9)/2 + sqrt(109)/2)) + C2*sin(t*(S(9)/2 + sqrt(109)/2)) + C3*cos(t*(-sqrt(109)/2 + S(9)/2)) + \ C4*sin(t*(-sqrt(109)/2 + S(9)/2))), Eq(y(t), -C1*sin(t*(S(9)/2 + sqrt(109)/2)) + C2*cos(t*(S(9)/2 + sqrt(109)/2)) - \ C3*sin(t*(-sqrt(109)/2 + S(9)/2)) + C4*cos(t*(-sqrt(109)/2 + S(9)/2)))] assert dsolve(eq3) == sol3 assert checksysodesol(eq3, sol3) == (True, [0, 0]) eq4 = (Eq(diff(x(t),t,t), 9*t*diff(y(t),t)-9*y(t)), Eq(diff(y(t),t,t),7*t*diff(x(t),t)-7*x(t))) sol4 = [Eq(x(t), C3*t + t*Integral((9*C1*exp(3*sqrt(7)*t**2/2) + 9*C2*exp(-3*sqrt(7)*t**2/2))/t**2, t)), \ Eq(y(t), C4*t + t*Integral((3*sqrt(7)*C1*exp(3*sqrt(7)*t**2/2) - 3*sqrt(7)*C2*exp(-3*sqrt(7)*t**2/2))/t**2, t))] assert dsolve(eq4) == sol4 assert checksysodesol(eq4, sol4) == (True, [0, 0]) eq5 = (Eq(diff(x(t),t,t), (log(t)+t**2)*diff(x(t),t)+(log(t)+t**2)*3*diff(y(t),t)), Eq(diff(y(t),t,t), \ (log(t)+t**2)*2*diff(x(t),t)+(log(t)+t**2)*9*diff(y(t),t))) sol5 = [Eq(x(t), -sqrt(22)*(C1*Integral(exp((-sqrt(22) + 5)*Integral(t**2 + log(t), t)), t) + C2 - \ C3*Integral(exp((sqrt(22) + 5)*Integral(t**2 + log(t), t)), t) - C4 - \ (sqrt(22) + 5)*(C1*Integral(exp((-sqrt(22) + 5)*Integral(t**2 + log(t), t)), t) + C2) + \ (-sqrt(22) + 5)*(C3*Integral(exp((sqrt(22) + 5)*Integral(t**2 + log(t), t)), t) + C4))/88), \ Eq(y(t), -sqrt(22)*(C1*Integral(exp((-sqrt(22) + 5)*Integral(t**2 + log(t), t)), t) + \ C2 - C3*Integral(exp((sqrt(22) + 5)*Integral(t**2 + log(t), t)), t) - C4)/44)] assert dsolve(eq5) == sol5 assert checksysodesol(eq5, sol5) == (True, [0, 0]) eq6 = (Eq(diff(x(t),t,t), log(t)*t*diff(y(t),t) - log(t)*y(t)), Eq(diff(y(t),t,t), log(t)*t*diff(x(t),t) - log(t)*x(t))) sol6 = [Eq(x(t), C3*t + t*Integral((C1*exp(Integral(t*log(t), t)) + \ C2*exp(-Integral(t*log(t), t)))/t**2, t)), Eq(y(t), C4*t + t*Integral((C1*exp(Integral(t*log(t), t)) - \ C2*exp(-Integral(t*log(t), t)))/t**2, t))] assert dsolve(eq6) == sol6 assert checksysodesol(eq6, sol6) == (True, [0, 0]) eq7 = (Eq(diff(x(t),t,t), log(t)*(t*diff(x(t),t) - x(t)) + exp(t)*(t*diff(y(t),t) - y(t))), \ Eq(diff(y(t),t,t), (t**2)*(t*diff(x(t),t) - x(t)) + (t)*(t*diff(y(t),t) - y(t)))) sol7 = [Eq(x(t), C3*t + t*Integral((C1*x0(t) + C2*x0(t)*Integral(t*exp(t)*exp(Integral(t**2, t))*\ exp(Integral(t*log(t), t))/x0(t)**2, t))/t**2, t)), Eq(y(t), C4*t + t*Integral((C1*y0(t) + \ C2*(y0(t)*Integral(t*exp(t)*exp(Integral(t**2, t))*exp(Integral(t*log(t), t))/x0(t)**2, t) + \ exp(Integral(t**2, t))*exp(Integral(t*log(t), t))/x0(t)))/t**2, t))] assert dsolve(eq7) == sol7 # FIXME: assert checksysodesol(eq7, sol7) == (True, [0, 0]) eq8 = (Eq(diff(x(t),t,t), t*(4*x(t) + 9*y(t))), Eq(diff(y(t),t,t), t*(12*x(t) - 6*y(t)))) sol8 = ("[Eq(x(t), -sqrt(133)*((-sqrt(133) - 1)*(C2*(133*t**8/24 - t**3/6 + sqrt(133)*t**3/2 + 1) + " "C1*t*(sqrt(133)*t**4/6 - t**3/12 + 1) + O(t**6)) - (-1 + sqrt(133))*(C2*(-sqrt(133)*t**3/6 - t**3/6 + 1) + " "C1*t*(-sqrt(133)*t**3/12 - t**3/12 + 1) + O(t**6)) - 4*C2*(133*t**8/24 - t**3/6 + sqrt(133)*t**3/2 + 1) + " "4*C2*(-sqrt(133)*t**3/6 - t**3/6 + 1) - 4*C1*t*(sqrt(133)*t**4/6 - t**3/12 + 1) + " "4*C1*t*(-sqrt(133)*t**3/12 - t**3/12 + 1) + O(t**6))/3192), Eq(y(t), -sqrt(133)*(-C2*(133*t**8/24 - t**3/6 + " "sqrt(133)*t**3/2 + 1) + C2*(-sqrt(133)*t**3/6 - t**3/6 + 1) - C1*t*(sqrt(133)*t**4/6 - t**3/12 + 1) + " "C1*t*(-sqrt(133)*t**3/12 - t**3/12 + 1) + O(t**6))/266)]") assert str(dsolve(eq8)) == sol8 # FIXME: assert checksysodesol(eq8, sol8) == (True, [0, 0]) eq9 = (Eq(diff(x(t),t,t), t*(4*diff(x(t),t) + 9*diff(y(t),t))), Eq(diff(y(t),t,t), t*(12*diff(x(t),t) - 6*diff(y(t),t)))) sol9 = [Eq(x(t), -sqrt(133)*(4*C1*Integral(exp((-sqrt(133) - 1)*Integral(t, t)), t) + 4*C2 - \ 4*C3*Integral(exp((-1 + sqrt(133))*Integral(t, t)), t) - 4*C4 - (-1 + sqrt(133))*(C1*Integral(exp((-sqrt(133) - \ 1)*Integral(t, t)), t) + C2) + (-sqrt(133) - 1)*(C3*Integral(exp((-1 + sqrt(133))*Integral(t, t)), t) + \ C4))/3192), Eq(y(t), -sqrt(133)*(C1*Integral(exp((-sqrt(133) - 1)*Integral(t, t)), t) + C2 - \ C3*Integral(exp((-1 + sqrt(133))*Integral(t, t)), t) - C4)/266)] assert dsolve(eq9) == sol9 assert checksysodesol(eq9, sol9) == (True, [0, 0]) eq10 = (t**2*diff(x(t),t,t) + 3*t*diff(x(t),t) + 4*t*diff(y(t),t) + 12*x(t) + 9*y(t), \ t**2*diff(y(t),t,t) + 2*t*diff(x(t),t) - 5*t*diff(y(t),t) + 15*x(t) + 8*y(t)) sol10 = [Eq(x(t), -C1*(-2*sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 13 + 2*sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + \ 346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))))*exp((-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2 + 1 + sqrt(-284/sqrt(-346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)))/2)*log(t)) - \ C2*(-2*sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 13 - 2*sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))))*exp((-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2 + 1 - sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)*log(t)) - C3*t**(1 + sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2 + sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)*(2*sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 13 + 2*sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))) - C4*t**(-sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2 + 1 + sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))/2)*(-2*sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))) + 2*sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 13)), Eq(y(t), C1*(-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 14 + (-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2 + 1 + sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)**2 + sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))))*exp((-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))/2 + 1 + sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)*log(t)) + C2*(-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 14 - sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))) + (-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))/2 + 1 - sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)**2)*exp((-sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))/2 + 1 - sqrt(-284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) - 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)*log(t)) + C3*t**(1 + sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + \ 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2 + sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)*(sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))) + 14 + (1 + sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3))/2 + sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + 346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)))/2)**2) + C4*t**(-sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + \ 346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)))/2 + 1 + sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2)*(-sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + \ 8 + 346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))) + (-sqrt(-2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3) + 8 + \ 346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 284/sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)))/2 + 1 + sqrt(-346/(3*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + \ 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3))/2)**2 + sqrt(-346/(3*(S(4333)/4 + \ 5*sqrt(70771857)/36)**(S(1)/3)) + 4 + 2*(S(4333)/4 + 5*sqrt(70771857)/36)**(S(1)/3)) + 14))] assert dsolve(eq10) == sol10 # FIXME: assert checksysodesol(eq10, sol10) == (True, [0, 0]) # this hangs or at least takes a while... def test_linear_3eq_order1(): x, y, z = symbols('x, y, z', cls=Function) t = Symbol('t') eq1 = (Eq(diff(x(t),t), 21*x(t)), Eq(diff(y(t),t), 17*x(t)+3*y(t)), Eq(diff(z(t),t), 5*x(t)+7*y(t)+9*z(t))) sol1 = [Eq(x(t), C1*exp(21*t)), Eq(y(t), 17*C1*exp(21*t)/18 + C2*exp(3*t)), \ Eq(z(t), 209*C1*exp(21*t)/216 - 7*C2*exp(3*t)/6 + C3*exp(9*t))] assert checksysodesol(eq1, sol1) == (True, [0, 0, 0]) eq2 = (Eq(diff(x(t),t),3*y(t)-11*z(t)),Eq(diff(y(t),t),7*z(t)-3*x(t)),Eq(diff(z(t),t),11*x(t)-7*y(t))) sol2 = [Eq(x(t), 7*C0 + sqrt(179)*C1*cos(sqrt(179)*t) + (77*C1/3 + 130*C2/3)*sin(sqrt(179)*t)), \ Eq(y(t), 11*C0 + sqrt(179)*C2*cos(sqrt(179)*t) + (-58*C1/3 - 77*C2/3)*sin(sqrt(179)*t)), \ Eq(z(t), 3*C0 + sqrt(179)*(-7*C1/3 - 11*C2/3)*cos(sqrt(179)*t) + (11*C1 - 7*C2)*sin(sqrt(179)*t))] assert checksysodesol(eq2, sol2) == (True, [0, 0, 0]) eq3 = (Eq(3*diff(x(t),t),4*5*(y(t)-z(t))),Eq(4*diff(y(t),t),3*5*(z(t)-x(t))),Eq(5*diff(z(t),t),3*4*(x(t)-y(t)))) sol3 = [Eq(x(t), C0 + 5*sqrt(2)*C1*cos(5*sqrt(2)*t) + (12*C1/5 + 164*C2/15)*sin(5*sqrt(2)*t)), \ Eq(y(t), C0 + 5*sqrt(2)*C2*cos(5*sqrt(2)*t) + (-51*C1/10 - 12*C2/5)*sin(5*sqrt(2)*t)), \ Eq(z(t), C0 + 5*sqrt(2)*(-9*C1/25 - 16*C2/25)*cos(5*sqrt(2)*t) + (12*C1/5 - 12*C2/5)*sin(5*sqrt(2)*t))] assert checksysodesol(eq3, sol3) == (True, [0, 0, 0]) f = t**3 + log(t) g = t**2 + sin(t) eq4 = (Eq(diff(x(t),t),(4*f+g)*x(t)-f*y(t)-2*f*z(t)), Eq(diff(y(t),t),2*f*x(t)+(f+g)*y(t)-2*f*z(t)), Eq(diff(z(t),t),5*f*x(t)+f*y(t)+(-3*f+g)*z(t))) sol4 = [Eq(x(t), (C1*exp(-2*Integral(t**3 + log(t), t)) + C2*(sqrt(3)*sin(sqrt(3)*Integral(t**3 + log(t), t))/6 \ + cos(sqrt(3)*Integral(t**3 + log(t), t))/2) + C3*(sin(sqrt(3)*Integral(t**3 + log(t), t))/2 - \ sqrt(3)*cos(sqrt(3)*Integral(t**3 + log(t), t))/6))*exp(Integral(-t**2 - sin(t), t))), Eq(y(t), \ (C2*(sqrt(3)*sin(sqrt(3)*Integral(t**3 + log(t), t))/6 + cos(sqrt(3)*Integral(t**3 + log(t), t))/2) + \ C3*(sin(sqrt(3)*Integral(t**3 + log(t), t))/2 - sqrt(3)*cos(sqrt(3)*Integral(t**3 + log(t), t))/6))*\ exp(Integral(-t**2 - sin(t), t))), Eq(z(t), (C1*exp(-2*Integral(t**3 + log(t), t)) + C2*cos(sqrt(3)*\ Integral(t**3 + log(t), t)) + C3*sin(sqrt(3)*Integral(t**3 + log(t), t)))*exp(Integral(-t**2 - sin(t), t)))] assert dsolve(eq4) == sol4 # FIXME: assert checksysodesol(eq4, sol4) == (True, [0, 0, 0]) # this one fails eq5 = (Eq(diff(x(t),t),4*x(t) - z(t)),Eq(diff(y(t),t),2*x(t)+2*y(t)-z(t)),Eq(diff(z(t),t),3*x(t)+y(t))) sol5 = [Eq(x(t), C1*exp(2*t) + C2*t*exp(2*t) + C2*exp(2*t) + C3*t**2*exp(2*t)/2 + C3*t*exp(2*t) + C3*exp(2*t)), \ Eq(y(t), C1*exp(2*t) + C2*t*exp(2*t) + C2*exp(2*t) + C3*t**2*exp(2*t)/2 + C3*t*exp(2*t)), \ Eq(z(t), 2*C1*exp(2*t) + 2*C2*t*exp(2*t) + C2*exp(2*t) + C3*t**2*exp(2*t) + C3*t*exp(2*t) + C3*exp(2*t))] assert checksysodesol(eq5, sol5) == (True, [0, 0, 0]) eq6 = (Eq(diff(x(t),t),4*x(t) - y(t) - 2*z(t)),Eq(diff(y(t),t),2*x(t) + y(t)- 2*z(t)),Eq(diff(z(t),t),5*x(t)-3*z(t))) sol6 = [Eq(x(t), C1*exp(2*t) + C2*(-sin(t)/5 + 3*cos(t)/5) + C3*(3*sin(t)/5 + cos(t)/5)), Eq(y(t), C2*(-sin(t)/5 + 3*cos(t)/5) + C3*(3*sin(t)/5 + cos(t)/5)), Eq(z(t), C1*exp(2*t) + C2*cos(t) + C3*sin(t))] assert checksysodesol(eq5, sol5) == (True, [0, 0, 0]) def test_linear_3eq_order1_nonhomog(): e = [Eq(diff(f(x), x), -9*f(x) - 4*g(x)), Eq(diff(g(x), x), -4*g(x)), Eq(diff(h(x), x), h(x) + exp(x))] raises(NotImplementedError, lambda: dsolve(e)) @XFAIL def test_linear_3eq_order1_diagonal(): # code makes assumptions about coefficients being nonzero, breaks when assumptions are not true e = [Eq(diff(f(x), x), f(x)), Eq(diff(g(x), x), g(x)), Eq(diff(h(x), x), h(x))] s1 = [Eq(f(x), C1*exp(x)), Eq(g(x), C2*exp(x)), Eq(h(x), C3*exp(x))] s = dsolve(e) assert s == s1 assert checksysodesol(e, s1) == (True, [0, 0, 0]) def test_nonlinear_2eq_order1(): x, y, z = symbols('x, y, z', cls=Function) t = Symbol('t') eq1 = (Eq(diff(x(t),t),x(t)*y(t)**3), Eq(diff(y(t),t),y(t)**5)) sol1 = [ Eq(x(t), C1*exp((-1/(4*C2 + 4*t))**(-S(1)/4))), Eq(y(t), -(-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), C1*exp(-1/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), (-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), C1*exp(-I/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), -I*(-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), C1*exp(I/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), I*(-1/(4*C2 + 4*t))**(S(1)/4))] assert dsolve(eq1) == sol1 assert checksysodesol(eq1, sol1) == (True, [0, 0]) eq2 = (Eq(diff(x(t),t), exp(3*x(t))*y(t)**3),Eq(diff(y(t),t), y(t)**5)) sol2 = [ Eq(x(t), -log(C1 - 3/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), -(-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), -log(C1 + 3/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), (-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), -log(C1 + 3*I/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), -I*(-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), -log(C1 - 3*I/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), I*(-1/(4*C2 + 4*t))**(S(1)/4))] assert dsolve(eq2) == sol2 assert checksysodesol(eq2, sol2) == (True, [0, 0]) eq3 = (Eq(diff(x(t),t), y(t)*x(t)), Eq(diff(y(t),t), x(t)**3)) tt = S(2)/3 sol3 = [ Eq(x(t), 6**tt/(6*(-sinh(sqrt(C1)*(C2 + t)/2)/sqrt(C1))**tt)), Eq(y(t), sqrt(C1 + C1/sinh(sqrt(C1)*(C2 + t)/2)**2)/3)] assert dsolve(eq3) == sol3 # FIXME: assert checksysodesol(eq3, sol3) == (True, [0, 0]) eq4 = (Eq(diff(x(t),t),x(t)*y(t)*sin(t)**2), Eq(diff(y(t),t),y(t)**2*sin(t)**2)) sol4 = set([Eq(x(t), -2*exp(C1)/(C2*exp(C1) + t - sin(2*t)/2)), Eq(y(t), -2/(C1 + t - sin(2*t)/2))]) assert dsolve(eq4) == sol4 # FIXME: assert checksysodesol(eq4, sol4) == (True, [0, 0]) eq5 = (Eq(x(t),t*diff(x(t),t)+diff(x(t),t)*diff(y(t),t)), Eq(y(t),t*diff(y(t),t)+diff(y(t),t)**2)) sol5 = set([Eq(x(t), C1*C2 + C1*t), Eq(y(t), C2**2 + C2*t)]) assert dsolve(eq5) == sol5 assert checksysodesol(eq5, sol5) == (True, [0, 0]) eq6 = (Eq(diff(x(t),t),x(t)**2*y(t)**3), Eq(diff(y(t),t),y(t)**5)) sol6 = [ Eq(x(t), 1/(C1 - 1/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), -(-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), 1/(C1 + (-1/(4*C2 + 4*t))**(-S(1)/4))), Eq(y(t), (-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), 1/(C1 + I/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), -I*(-1/(4*C2 + 4*t))**(S(1)/4)), Eq(x(t), 1/(C1 - I/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), I*(-1/(4*C2 + 4*t))**(S(1)/4))] assert dsolve(eq6) == sol6 assert checksysodesol(eq6, sol6) == (True, [0, 0]) def test_checksysodesol(): x, y, z = symbols('x, y, z', cls=Function) t = Symbol('t') eq = (Eq(diff(x(t),t), 9*y(t)), Eq(diff(y(t),t), 12*x(t))) sol = [Eq(x(t), 9*C1*exp(-6*sqrt(3)*t) + 9*C2*exp(6*sqrt(3)*t)), \ Eq(y(t), -6*sqrt(3)*C1*exp(-6*sqrt(3)*t) + 6*sqrt(3)*C2*exp(6*sqrt(3)*t))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 2*x(t) + 4*y(t)), Eq(diff(y(t),t), 12*x(t) + 41*y(t))) sol = [Eq(x(t), 4*C1*exp(t*(-sqrt(1713)/2 + S(43)/2)) + 4*C2*exp(t*(sqrt(1713)/2 + \ S(43)/2))), Eq(y(t), C1*(-sqrt(1713)/2 + S(39)/2)*exp(t*(-sqrt(1713)/2 + \ S(43)/2)) + C2*(S(39)/2 + sqrt(1713)/2)*exp(t*(sqrt(1713)/2 + S(43)/2)))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), x(t) + y(t)), Eq(diff(y(t),t), -2*x(t) + 2*y(t))) sol = [Eq(x(t), (C1*sin(sqrt(7)*t/2) + C2*cos(sqrt(7)*t/2))*exp(3*t/2)), \ Eq(y(t), ((C1/2 - sqrt(7)*C2/2)*sin(sqrt(7)*t/2) + (sqrt(7)*C1/2 + \ C2/2)*cos(sqrt(7)*t/2))*exp(3*t/2))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), x(t) + y(t) + 9), Eq(diff(y(t),t), 2*x(t) + 5*y(t) + 23)) sol = [Eq(x(t), C1*exp(t*(-sqrt(6) + 3)) + C2*exp(t*(sqrt(6) + 3)) - \ S(22)/3), Eq(y(t), C1*(-sqrt(6) + 2)*exp(t*(-sqrt(6) + 3)) + C2*(2 + \ sqrt(6))*exp(t*(sqrt(6) + 3)) - S(5)/3)] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), x(t) + y(t) + 81), Eq(diff(y(t),t), -2*x(t) + y(t) + 23)) sol = [Eq(x(t), (C1*sin(sqrt(2)*t) + C2*cos(sqrt(2)*t))*exp(t) - S(58)/3), \ Eq(y(t), (sqrt(2)*C1*cos(sqrt(2)*t) - sqrt(2)*C2*sin(sqrt(2)*t))*exp(t) - S(185)/3)] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 5*t*x(t) + 2*y(t)), Eq(diff(y(t),t), 2*x(t) + 5*t*y(t))) sol = [Eq(x(t), (C1*exp((Integral(2, t).doit())) + C2*exp(-(Integral(2, t)).doit()))*\ exp((Integral(5*t, t)).doit())), Eq(y(t), (C1*exp((Integral(2, t)).doit()) - \ C2*exp(-(Integral(2, t)).doit()))*exp((Integral(5*t, t)).doit()))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 5*t*x(t) + t**2*y(t)), Eq(diff(y(t),t), -t**2*x(t) + 5*t*y(t))) sol = [Eq(x(t), (C1*cos((Integral(t**2, t)).doit()) + C2*sin((Integral(t**2, t)).doit()))*\ exp((Integral(5*t, t)).doit())), Eq(y(t), (-C1*sin((Integral(t**2, t)).doit()) + \ C2*cos((Integral(t**2, t)).doit()))*exp((Integral(5*t, t)).doit()))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 5*t*x(t) + t**2*y(t)), Eq(diff(y(t),t), -t**2*x(t) + (5*t+9*t**2)*y(t))) sol = [Eq(x(t), (C1*exp((-sqrt(77)/2 + S(9)/2)*(Integral(t**2, t)).doit()) + \ C2*exp((sqrt(77)/2 + S(9)/2)*(Integral(t**2, t)).doit()))*exp((Integral(5*t, t)).doit())), \ Eq(y(t), (C1*(-sqrt(77)/2 + S(9)/2)*exp((-sqrt(77)/2 + S(9)/2)*(Integral(t**2, t)).doit()) + \ C2*(sqrt(77)/2 + S(9)/2)*exp((sqrt(77)/2 + S(9)/2)*(Integral(t**2, t)).doit()))*exp((Integral(5*t, t)).doit()))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t), 5*x(t) + 43*y(t)), Eq(diff(y(t),t,t), x(t) + 9*y(t))) root0 = -sqrt(-sqrt(47) + 7) root1 = sqrt(-sqrt(47) + 7) root2 = -sqrt(sqrt(47) + 7) root3 = sqrt(sqrt(47) + 7) sol = [Eq(x(t), 43*C1*exp(t*root0) + 43*C2*exp(t*root1) + 43*C3*exp(t*root2) + 43*C4*exp(t*root3)), \ Eq(y(t), C1*(root0**2 - 5)*exp(t*root0) + C2*(root1**2 - 5)*exp(t*root1) + \ C3*(root2**2 - 5)*exp(t*root2) + C4*(root3**2 - 5)*exp(t*root3))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t), 8*x(t)+3*y(t)+31), Eq(diff(y(t),t,t), 9*x(t)+7*y(t)+12)) root0 = -sqrt(-sqrt(109)/2 + S(15)/2) root1 = sqrt(-sqrt(109)/2 + S(15)/2) root2 = -sqrt(sqrt(109)/2 + S(15)/2) root3 = sqrt(sqrt(109)/2 + S(15)/2) sol = [Eq(x(t), 3*C1*exp(t*root0) + 3*C2*exp(t*root1) + 3*C3*exp(t*root2) + 3*C4*exp(t*root3) - S(181)/29), \ Eq(y(t), C1*(root0**2 - 8)*exp(t*root0) + C2*(root1**2 - 8)*exp(t*root1) + \ C3*(root2**2 - 8)*exp(t*root2) + C4*(root3**2 - 8)*exp(t*root3) + S(183)/29)] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t) - 9*diff(y(t),t) + 7*x(t),0), Eq(diff(y(t),t,t) + 9*diff(x(t),t) + 7*y(t),0)) sol = [Eq(x(t), C1*cos(t*(S(9)/2 + sqrt(109)/2)) + C2*sin(t*(S(9)/2 + sqrt(109)/2)) + \ C3*cos(t*(-sqrt(109)/2 + S(9)/2)) + C4*sin(t*(-sqrt(109)/2 + S(9)/2))), Eq(y(t), -C1*sin(t*(S(9)/2 + sqrt(109)/2)) \ + C2*cos(t*(S(9)/2 + sqrt(109)/2)) - C3*sin(t*(-sqrt(109)/2 + S(9)/2)) + C4*cos(t*(-sqrt(109)/2 + S(9)/2)))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t,t), 9*t*diff(y(t),t)-9*y(t)), Eq(diff(y(t),t,t),7*t*diff(x(t),t)-7*x(t))) I1 = sqrt(6)*7**(S(1)/4)*sqrt(pi)*erfi(sqrt(6)*7**(S(1)/4)*t/2)/2 - exp(3*sqrt(7)*t**2/2)/t I2 = -sqrt(6)*7**(S(1)/4)*sqrt(pi)*erf(sqrt(6)*7**(S(1)/4)*t/2)/2 - exp(-3*sqrt(7)*t**2/2)/t sol = [Eq(x(t), C3*t + t*(9*C1*I1 + 9*C2*I2)), Eq(y(t), C4*t + t*(3*sqrt(7)*C1*I1 - 3*sqrt(7)*C2*I2))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), 21*x(t)), Eq(diff(y(t),t), 17*x(t)+3*y(t)), Eq(diff(z(t),t), 5*x(t)+7*y(t)+9*z(t))) sol = [Eq(x(t), C1*exp(21*t)), Eq(y(t), 17*C1*exp(21*t)/18 + C2*exp(3*t)), \ Eq(z(t), 209*C1*exp(21*t)/216 - 7*C2*exp(3*t)/6 + C3*exp(9*t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),3*y(t)-11*z(t)),Eq(diff(y(t),t),7*z(t)-3*x(t)),Eq(diff(z(t),t),11*x(t)-7*y(t))) sol = [Eq(x(t), 7*C0 + sqrt(179)*C1*cos(sqrt(179)*t) + (77*C1/3 + 130*C2/3)*sin(sqrt(179)*t)), \ Eq(y(t), 11*C0 + sqrt(179)*C2*cos(sqrt(179)*t) + (-58*C1/3 - 77*C2/3)*sin(sqrt(179)*t)), \ Eq(z(t), 3*C0 + sqrt(179)*(-7*C1/3 - 11*C2/3)*cos(sqrt(179)*t) + (11*C1 - 7*C2)*sin(sqrt(179)*t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(3*diff(x(t),t),4*5*(y(t)-z(t))),Eq(4*diff(y(t),t),3*5*(z(t)-x(t))),Eq(5*diff(z(t),t),3*4*(x(t)-y(t)))) sol = [Eq(x(t), C0 + 5*sqrt(2)*C1*cos(5*sqrt(2)*t) + (12*C1/5 + 164*C2/15)*sin(5*sqrt(2)*t)), \ Eq(y(t), C0 + 5*sqrt(2)*C2*cos(5*sqrt(2)*t) + (-51*C1/10 - 12*C2/5)*sin(5*sqrt(2)*t)), \ Eq(z(t), C0 + 5*sqrt(2)*(-9*C1/25 - 16*C2/25)*cos(5*sqrt(2)*t) + (12*C1/5 - 12*C2/5)*sin(5*sqrt(2)*t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),4*x(t) - z(t)),Eq(diff(y(t),t),2*x(t)+2*y(t)-z(t)),Eq(diff(z(t),t),3*x(t)+y(t))) sol = [Eq(x(t), C1*exp(2*t) + C2*t*exp(2*t) + C2*exp(2*t) + C3*t**2*exp(2*t)/2 + C3*t*exp(2*t) + C3*exp(2*t)), \ Eq(y(t), C1*exp(2*t) + C2*t*exp(2*t) + C2*exp(2*t) + C3*t**2*exp(2*t)/2 + C3*t*exp(2*t)), \ Eq(z(t), 2*C1*exp(2*t) + 2*C2*t*exp(2*t) + C2*exp(2*t) + C3*t**2*exp(2*t) + C3*t*exp(2*t) + C3*exp(2*t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),4*x(t) - y(t) - 2*z(t)),Eq(diff(y(t),t),2*x(t) + y(t)- 2*z(t)),Eq(diff(z(t),t),5*x(t)-3*z(t))) sol = [Eq(x(t), C1*exp(2*t) + C2*(-sin(t) + 3*cos(t)) + C3*(3*sin(t) + cos(t))), \ Eq(y(t), C2*(-sin(t) + 3*cos(t)) + C3*(3*sin(t) + cos(t))), Eq(z(t), C1*exp(2*t) + 5*C2*cos(t) + 5*C3*sin(t))] assert checksysodesol(eq, sol) == (True, [0, 0, 0]) eq = (Eq(diff(x(t),t),x(t)*y(t)**3), Eq(diff(y(t),t),y(t)**5)) sol = [Eq(x(t), C1*exp((-1/(4*C2 + 4*t))**(-S(1)/4))), Eq(y(t), -(-1/(4*C2 + 4*t))**(S(1)/4)), \ Eq(x(t), C1*exp(-1/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), (-1/(4*C2 + 4*t))**(S(1)/4)), \ Eq(x(t), C1*exp(-I/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), -I*(-1/(4*C2 + 4*t))**(S(1)/4)), \ Eq(x(t), C1*exp(I/(-1/(4*C2 + 4*t))**(S(1)/4))), Eq(y(t), I*(-1/(4*C2 + 4*t))**(S(1)/4))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(diff(x(t),t), exp(3*x(t))*y(t)**3),Eq(diff(y(t),t), y(t)**5)) sol = [Eq(x(t), -log(C1 - 3/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), -(-1/(4*C2 + 4*t))**(S(1)/4)), \ Eq(x(t), -log(C1 + 3/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), (-1/(4*C2 + 4*t))**(S(1)/4)), \ Eq(x(t), -log(C1 + 3*I/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), -I*(-1/(4*C2 + 4*t))**(S(1)/4)), \ Eq(x(t), -log(C1 - 3*I/(-1/(4*C2 + 4*t))**(S(1)/4))/3), Eq(y(t), I*(-1/(4*C2 + 4*t))**(S(1)/4))] assert checksysodesol(eq, sol) == (True, [0, 0]) eq = (Eq(x(t),t*diff(x(t),t)+diff(x(t),t)*diff(y(t),t)), Eq(y(t),t*diff(y(t),t)+diff(y(t),t)**2)) sol = set([Eq(x(t), C1*C2 + C1*t), Eq(y(t), C2**2 + C2*t)]) assert checksysodesol(eq, sol) == (True, [0, 0]) @slow def test_nonlinear_3eq_order1(): x, y, z = symbols('x, y, z', cls=Function) t, u = symbols('t u') eq1 = (4*diff(x(t),t) + 2*y(t)*z(t), 3*diff(y(t),t) - z(t)*x(t), 5*diff(z(t),t) - x(t)*y(t)) sol1 = [Eq(4*Integral(1/(sqrt(-4*u**2 - 3*C1 + C2)*sqrt(-4*u**2 + 5*C1 - C2)), (u, x(t))), C3 - sqrt(15)*t/15), Eq(3*Integral(1/(sqrt(-6*u**2 - C1 + 5*C2)*sqrt(3*u**2 + C1 - 4*C2)), (u, y(t))), C3 + sqrt(5)*t/10), Eq(5*Integral(1/(sqrt(-10*u**2 - 3*C1 + C2)* sqrt(5*u**2 + 4*C1 - C2)), (u, z(t))), C3 + sqrt(3)*t/6)] assert [i.dummy_eq(j) for i, j in zip(dsolve(eq1), sol1)] # FIXME: assert checksysodesol(eq1, sol1) == (True, [0, 0, 0]) eq2 = (4*diff(x(t),t) + 2*y(t)*z(t)*sin(t), 3*diff(y(t),t) - z(t)*x(t)*sin(t), 5*diff(z(t),t) - x(t)*y(t)*sin(t)) sol2 = [Eq(3*Integral(1/(sqrt(-6*u**2 - C1 + 5*C2)*sqrt(3*u**2 + C1 - 4*C2)), (u, x(t))), C3 + sqrt(5)*cos(t)/10), Eq(4*Integral(1/(sqrt(-4*u**2 - 3*C1 + C2)*sqrt(-4*u**2 + 5*C1 - C2)), (u, y(t))), C3 - sqrt(15)*cos(t)/15), Eq(5*Integral(1/(sqrt(-10*u**2 - 3*C1 + C2)* sqrt(5*u**2 + 4*C1 - C2)), (u, z(t))), C3 + sqrt(3)*cos(t)/6)] assert [i.dummy_eq(j) for i, j in zip(dsolve(eq2), sol2)] # FIXME: assert checksysodesol(eq2, sol2) == (True, [0, 0, 0]) @slow def test_checkodesol(): from sympy import Ei # For the most part, checkodesol is well tested in the tests below. # These tests only handle cases not checked below. raises(ValueError, lambda: checkodesol(f(x, y).diff(x), Eq(f(x, y), x))) raises(ValueError, lambda: checkodesol(f(x).diff(x), Eq(f(x, y), x), f(x, y))) assert checkodesol(f(x).diff(x), Eq(f(x, y), x)) == \ (False, -f(x).diff(x) + f(x, y).diff(x) - 1) assert checkodesol(f(x).diff(x), Eq(f(x), x)) is not True assert checkodesol(f(x).diff(x), Eq(f(x), x)) == (False, 1) sol1 = Eq(f(x)**5 + 11*f(x) - 2*f(x) + x, 0) assert checkodesol(diff(sol1.lhs, x), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x)*exp(f(x)), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 2), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 2)*exp(f(x)), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 3), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 3)*exp(f(x)), sol1) == (True, 0) assert checkodesol(diff(sol1.lhs, x, 3), Eq(f(x), x*log(x))) == \ (False, 60*x**4*((log(x) + 1)**2 + log(x))*( log(x) + 1)*log(x)**2 - 5*x**4*log(x)**4 - 9) assert checkodesol(diff(exp(f(x)) + x, x)*x, Eq(exp(f(x)) + x, 0)) == \ (True, 0) assert checkodesol(diff(exp(f(x)) + x, x)*x, Eq(exp(f(x)) + x, 0), solve_for_func=False) == (True, 0) assert checkodesol(f(x).diff(x, 2), [Eq(f(x), C1 + C2*x), Eq(f(x), C2 + C1*x), Eq(f(x), C1*x + C2*x**2)]) == \ [(True, 0), (True, 0), (False, C2)] assert checkodesol(f(x).diff(x, 2), set([Eq(f(x), C1 + C2*x), Eq(f(x), C2 + C1*x), Eq(f(x), C1*x + C2*x**2)])) == \ set([(True, 0), (True, 0), (False, C2)]) assert checkodesol(f(x).diff(x) - 1/f(x)/2, Eq(f(x)**2, x)) == \ [(True, 0), (True, 0)] assert checkodesol(f(x).diff(x) - f(x), Eq(C1*exp(x), f(x))) == (True, 0) # Based on test_1st_homogeneous_coeff_ode2_eq3sol. Make sure that # checkodesol tries back substituting f(x) when it can. eq3 = x*exp(f(x)/x) + f(x) - x*f(x).diff(x) sol3 = Eq(f(x), log(log(C1/x)**(-x))) assert not checkodesol(eq3, sol3)[1].has(f(x)) # This case was failing intermittently depending on hash-seed: eqn = Eq(Derivative(x*Derivative(f(x), x), x)/x, exp(x)) sol = Eq(f(x), C1 + C2*log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] @slow def test_dsolve_options(): eq = x*f(x).diff(x) + f(x) a = dsolve(eq, hint='all') b = dsolve(eq, hint='all', simplify=False) c = dsolve(eq, hint='all_Integral') keys = ['1st_exact', '1st_exact_Integral', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_homogeneous_coeff_subs_dep_div_indep_Integral', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_linear', '1st_linear_Integral', 'almost_linear', 'almost_linear_Integral', 'best', 'best_hint', 'default', 'lie_group', 'nth_linear_euler_eq_homogeneous', 'order', 'separable', 'separable_Integral'] Integral_keys = ['1st_exact_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_linear_Integral', 'almost_linear_Integral', 'best', 'best_hint', 'default', 'nth_linear_euler_eq_homogeneous', 'order', 'separable_Integral'] assert sorted(a.keys()) == keys assert a['order'] == ode_order(eq, f(x)) assert a['best'] == Eq(f(x), C1/x) assert dsolve(eq, hint='best') == Eq(f(x), C1/x) assert a['default'] == 'separable' assert a['best_hint'] == 'separable' assert not a['1st_exact'].has(Integral) assert not a['separable'].has(Integral) assert not a['1st_homogeneous_coeff_best'].has(Integral) assert not a['1st_homogeneous_coeff_subs_dep_div_indep'].has(Integral) assert not a['1st_homogeneous_coeff_subs_indep_div_dep'].has(Integral) assert not a['1st_linear'].has(Integral) assert a['1st_linear_Integral'].has(Integral) assert a['1st_exact_Integral'].has(Integral) assert a['1st_homogeneous_coeff_subs_dep_div_indep_Integral'].has(Integral) assert a['1st_homogeneous_coeff_subs_indep_div_dep_Integral'].has(Integral) assert a['separable_Integral'].has(Integral) assert sorted(b.keys()) == keys assert b['order'] == ode_order(eq, f(x)) assert b['best'] == Eq(f(x), C1/x) assert dsolve(eq, hint='best', simplify=False) == Eq(f(x), C1/x) assert b['default'] == 'separable' assert b['best_hint'] == '1st_linear' assert a['separable'] != b['separable'] assert a['1st_homogeneous_coeff_subs_dep_div_indep'] != \ b['1st_homogeneous_coeff_subs_dep_div_indep'] assert a['1st_homogeneous_coeff_subs_indep_div_dep'] != \ b['1st_homogeneous_coeff_subs_indep_div_dep'] assert not b['1st_exact'].has(Integral) assert not b['separable'].has(Integral) assert not b['1st_homogeneous_coeff_best'].has(Integral) assert not b['1st_homogeneous_coeff_subs_dep_div_indep'].has(Integral) assert not b['1st_homogeneous_coeff_subs_indep_div_dep'].has(Integral) assert not b['1st_linear'].has(Integral) assert b['1st_linear_Integral'].has(Integral) assert b['1st_exact_Integral'].has(Integral) assert b['1st_homogeneous_coeff_subs_dep_div_indep_Integral'].has(Integral) assert b['1st_homogeneous_coeff_subs_indep_div_dep_Integral'].has(Integral) assert b['separable_Integral'].has(Integral) assert sorted(c.keys()) == Integral_keys raises(ValueError, lambda: dsolve(eq, hint='notarealhint')) raises(ValueError, lambda: dsolve(eq, hint='Liouville')) assert dsolve(f(x).diff(x) - 1/f(x)**2, hint='all')['best'] == \ dsolve(f(x).diff(x) - 1/f(x)**2, hint='best') assert dsolve(f(x) + f(x).diff(x) + sin(x).diff(x) + 1, f(x), hint="1st_linear_Integral") == \ Eq(f(x), (C1 + Integral((-sin(x).diff(x) - 1)* exp(Integral(1, x)), x))*exp(-Integral(1, x))) def test_classify_ode(): assert classify_ode(f(x).diff(x, 2), f(x)) == \ ( 'nth_algebraic', 'nth_linear_constant_coeff_homogeneous', 'nth_linear_euler_eq_homogeneous', 'Liouville', '2nd_power_series_ordinary', 'nth_algebraic_Integral', 'Liouville_Integral', ) assert classify_ode(f(x), f(x)) == () assert classify_ode(Eq(f(x).diff(x), 0), f(x)) == ( 'nth_algebraic', 'separable', '1st_linear', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_homogeneous', 'nth_linear_euler_eq_homogeneous', 'nth_algebraic_Integral', 'separable_Integral', '1st_linear_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral') assert classify_ode(f(x).diff(x)**2, f(x)) == ( 'nth_algebraic', 'lie_group', 'nth_algebraic_Integral') # issue 4749: f(x) should be cleared from highest derivative before classifying a = classify_ode(Eq(f(x).diff(x) + f(x), x), f(x)) b = classify_ode(f(x).diff(x)*f(x) + f(x)*f(x) - x*f(x), f(x)) c = classify_ode(f(x).diff(x)/f(x) + f(x)/f(x) - x/f(x), f(x)) assert a == ('1st_linear', 'Bernoulli', 'almost_linear', '1st_power_series', "lie_group", 'nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', '1st_linear_Integral', 'Bernoulli_Integral', 'almost_linear_Integral', 'nth_linear_constant_coeff_variation_of_parameters_Integral') assert b == c != () assert classify_ode( 2*x*f(x)*f(x).diff(x) + (1 + x)*f(x)**2 - exp(x), f(x) ) == ('Bernoulli', 'almost_linear', 'lie_group', 'Bernoulli_Integral', 'almost_linear_Integral') assert 'Riccati_special_minus2' in \ classify_ode(2*f(x).diff(x) + f(x)**2 - f(x)/x + 3*x**(-2), f(x)) raises(ValueError, lambda: classify_ode(x + f(x, y).diff(x).diff( y), f(x, y))) # issue 5176 k = Symbol('k') assert classify_ode(f(x).diff(x)/(k*f(x) + k*x*f(x)) + 2*f(x)/(k*f(x) + k*x*f(x)) + x*f(x).diff(x)/(k*f(x) + k*x*f(x)) + z, f(x)) == \ ('separable', '1st_exact', '1st_power_series', 'lie_group', 'separable_Integral', '1st_exact_Integral') # preprocessing ans = ('nth_algebraic', 'separable', '1st_exact', '1st_linear', 'Bernoulli', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', 'nth_linear_euler_eq_nonhomogeneous_variation_of_parameters', 'nth_algebraic_Integral', 'separable_Integral', '1st_exact_Integral', '1st_linear_Integral', 'Bernoulli_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral', 'nth_linear_constant_coeff_variation_of_parameters_Integral', 'nth_linear_euler_eq_nonhomogeneous_variation_of_parameters_Integral') # w/o f(x) given assert classify_ode(diff(f(x) + x, x) + diff(f(x), x)) == ans # w/ f(x) and prep=True assert classify_ode(diff(f(x) + x, x) + diff(f(x), x), f(x), prep=True) == ans assert classify_ode(Eq(2*x**3*f(x).diff(x), 0), f(x)) == \ ('nth_algebraic', 'separable', '1st_linear', '1st_power_series', 'lie_group', 'nth_linear_euler_eq_homogeneous', 'nth_algebraic_Integral', 'separable_Integral', '1st_linear_Integral') assert classify_ode(Eq(2*f(x)**3*f(x).diff(x), 0), f(x)) == \ ('nth_algebraic', 'separable', '1st_power_series', 'lie_group', 'nth_algebraic_Integral', 'separable_Integral') # test issue 13864 assert classify_ode(Eq(diff(f(x), x) - f(x)**x, 0), f(x)) == \ ('1st_power_series', 'lie_group') assert isinstance(classify_ode(Eq(f(x), 5), f(x), dict=True), dict) def test_classify_ode_ics(): # Dummy eq = f(x).diff(x, x) - f(x) # Not f(0) or f'(0) ics = {x: 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) ############################ # f(0) type (AppliedUndef) # ############################ # Wrong function ics = {g(0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Contains x ics = {f(x): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Too many args ics = {f(0, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # point contains f # XXX: Should be NotImplementedError ics = {f(0): f(1)} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Does not raise ics = {f(0): 1} classify_ode(eq, f(x), ics=ics) ##################### # f'(0) type (Subs) # ##################### # Wrong function ics = {g(x).diff(x).subs(x, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Contains x ics = {f(y).diff(y).subs(y, x): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Wrong variable ics = {f(y).diff(y).subs(y, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Too many args ics = {f(x, y).diff(x).subs(x, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Derivative wrt wrong vars ics = {Derivative(f(x), x, y).subs(x, 0): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # point contains f # XXX: Should be NotImplementedError ics = {f(x).diff(x).subs(x, 0): f(0)} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Does not raise ics = {f(x).diff(x).subs(x, 0): 1} classify_ode(eq, f(x), ics=ics) ########################### # f'(y) type (Derivative) # ########################### # Wrong function ics = {g(x).diff(x).subs(x, y): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Contains x ics = {f(y).diff(y).subs(y, x): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Too many args ics = {f(x, y).diff(x).subs(x, y): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Derivative wrt wrong vars ics = {Derivative(f(x), x, z).subs(x, y): 1} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # point contains f # XXX: Should be NotImplementedError ics = {f(x).diff(x).subs(x, y): f(0)} raises(ValueError, lambda: classify_ode(eq, f(x), ics=ics)) # Does not raise ics = {f(x).diff(x).subs(x, y): 1} classify_ode(eq, f(x), ics=ics) def test_classify_sysode(): # Here x is assumed to be x(t) and y as y(t) for simplicity. # Similarly diff(x,t) and diff(y,y) is assumed to be x1 and y1 respectively. k, l, m, n = symbols('k, l, m, n', Integer=True) k1, k2, k3, l1, l2, l3, m1, m2, m3 = symbols('k1, k2, k3, l1, l2, l3, m1, m2, m3', Integer=True) P, Q, R, p, q, r = symbols('P, Q, R, p, q, r', cls=Function) P1, P2, P3, Q1, Q2, R1, R2 = symbols('P1, P2, P3, Q1, Q2, R1, R2', cls=Function) x, y, z = symbols('x, y, z', cls=Function) t = symbols('t') x1 = diff(x(t),t) ; y1 = diff(y(t),t) ; z1 = diff(z(t),t) x2 = diff(x(t),t,t) ; y2 = diff(y(t),t,t) ; z2 = diff(z(t),t,t) eq1 = (Eq(diff(x(t),t), 5*t*x(t) + 2*y(t)), Eq(diff(y(t),t), 2*x(t) + 5*t*y(t))) sol1 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -5*t, (1, x(t), 1): 0, (0, x(t), 1): 1, \ (1, y(t), 0): -5*t, (1, x(t), 0): -2, (0, y(t), 1): 0, (0, y(t), 0): -2, (1, y(t), 1): 1}, \ 'type_of_equation': 'type3', 'func': [x(t), y(t)], 'is_linear': True, 'eq': [-5*t*x(t) - 2*y(t) + \ Derivative(x(t), t), -5*t*y(t) - 2*x(t) + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq1) == sol1 eq2 = (Eq(x2, k*x(t) - l*y1), Eq(y2, l*x1 + k*y(t))) sol2 = {'order': {y(t): 2, x(t): 2}, 'type_of_equation': 'type3', 'is_linear': True, 'eq': \ [-k*x(t) + l*Derivative(y(t), t) + Derivative(x(t), t, t), -k*y(t) - l*Derivative(x(t), t) + \ Derivative(y(t), t, t)], 'no_of_equation': 2, 'func_coeff': {(0, y(t), 0): 0, (0, x(t), 2): 1, \ (1, y(t), 1): 0, (1, y(t), 2): 1, (1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): -k, (1, x(t), 1): \ -l, (0, x(t), 1): 0, (0, y(t), 1): l, (1, x(t), 0): 0, (1, y(t), 0): -k}, 'func': [x(t), y(t)]} assert classify_sysode(eq2) == sol2 eq3 = (Eq(x2+4*x1+3*y1+9*x(t)+7*y(t), 11*exp(I*t)), Eq(y2+5*x1+8*y1+3*x(t)+12*y(t), 2*exp(I*t))) sol3 = {'no_of_equation': 2, 'func_coeff': {(1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): 9, \ (1, x(t), 1): 5, (0, x(t), 1): 4, (0, y(t), 1): 3, (1, x(t), 0): 3, (1, y(t), 0): 12, (0, y(t), 0): 7, \ (0, x(t), 2): 1, (1, y(t), 2): 1, (1, y(t), 1): 8}, 'type_of_equation': 'type4', 'func': [x(t), y(t)], \ 'is_linear': True, 'eq': [9*x(t) + 7*y(t) - 11*exp(I*t) + 4*Derivative(x(t), t) + 3*Derivative(y(t), t) + \ Derivative(x(t), t, t), 3*x(t) + 12*y(t) - 2*exp(I*t) + 5*Derivative(x(t), t) + 8*Derivative(y(t), t) + \ Derivative(y(t), t, t)], 'order': {y(t): 2, x(t): 2}} assert classify_sysode(eq3) == sol3 eq4 = (Eq((4*t**2 + 7*t + 1)**2*x2, 5*x(t) + 35*y(t)), Eq((4*t**2 + 7*t + 1)**2*y2, x(t) + 9*y(t))) sol4 = {'no_of_equation': 2, 'func_coeff': {(1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): -5, \ (1, x(t), 1): 0, (0, x(t), 1): 0, (0, y(t), 1): 0, (1, x(t), 0): -1, (1, y(t), 0): -9, (0, y(t), 0): -35, \ (0, x(t), 2): 16*t**4 + 56*t**3 + 57*t**2 + 14*t + 1, (1, y(t), 2): 16*t**4 + 56*t**3 + 57*t**2 + 14*t + 1, \ (1, y(t), 1): 0}, 'type_of_equation': 'type10', 'func': [x(t), y(t)], 'is_linear': True, \ 'eq': [(4*t**2 + 7*t + 1)**2*Derivative(x(t), t, t) - 5*x(t) - 35*y(t), (4*t**2 + 7*t + 1)**2*Derivative(y(t), t, t)\ - x(t) - 9*y(t)], 'order': {y(t): 2, x(t): 2}} assert classify_sysode(eq4) == sol4 eq5 = (Eq(diff(x(t),t), x(t) + y(t) + 9), Eq(diff(y(t),t), 2*x(t) + 5*y(t) + 23)) sol5 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -1, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): -5, \ (1, x(t), 0): -2, (0, y(t), 1): 0, (0, y(t), 0): -1, (1, y(t), 1): 1}, 'type_of_equation': 'type2', \ 'func': [x(t), y(t)], 'is_linear': True, 'eq': [-x(t) - y(t) + Derivative(x(t), t) - 9, -2*x(t) - 5*y(t) + \ Derivative(y(t), t) - 23], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq5) == sol5 eq6 = (Eq(x1, exp(k*x(t))*P(x(t),y(t))), Eq(y1,r(y(t))*P(x(t),y(t)))) sol6 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): 0, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): 0, \ (1, x(t), 0): 0, (0, y(t), 1): 0, (0, y(t), 0): 0, (1, y(t), 1): 1}, 'type_of_equation': 'type2', 'func': \ [x(t), y(t)], 'is_linear': False, 'eq': [-P(x(t), y(t))*exp(k*x(t)) + Derivative(x(t), t), -P(x(t), \ y(t))*r(y(t)) + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq6) == sol6 eq7 = (Eq(x1, x(t)**2+y(t)/x(t)), Eq(y1, x(t)/y(t))) sol7 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): 0, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): 0, \ (1, x(t), 0): -1/y(t), (0, y(t), 1): 0, (0, y(t), 0): -1/x(t), (1, y(t), 1): 1}, 'type_of_equation': 'type3', \ 'func': [x(t), y(t)], 'is_linear': False, 'eq': [-x(t)**2 + Derivative(x(t), t) - y(t)/x(t), -x(t)/y(t) + \ Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq7) == sol7 eq8 = (Eq(x1, P1(x(t))*Q1(y(t))*R(x(t),y(t),t)), Eq(y1, P1(x(t))*Q1(y(t))*R(x(t),y(t),t))) sol8 = {'func': [x(t), y(t)], 'is_linear': False, 'type_of_equation': 'type4', 'eq': \ [-P1(x(t))*Q1(y(t))*R(x(t), y(t), t) + Derivative(x(t), t), -P1(x(t))*Q1(y(t))*R(x(t), y(t), t) + \ Derivative(y(t), t)], 'func_coeff': {(0, y(t), 1): 0, (1, y(t), 1): 1, (1, x(t), 1): 0, (0, y(t), 0): 0, \ (1, x(t), 0): 0, (0, x(t), 0): 0, (1, y(t), 0): 0, (0, x(t), 1): 1}, 'order': {y(t): 1, x(t): 1}, 'no_of_equation': 2} assert classify_sysode(eq8) == sol8 eq9 = (Eq(x1,3*y(t)-11*z(t)),Eq(y1,7*z(t)-3*x(t)),Eq(z1,11*x(t)-7*y(t))) sol9 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): 0, (2, y(t), 1): 0, (2, z(t), 1): 1, \ (0, x(t), 0): 0, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): 7, (0, x(t), 1): 1, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): 3, (0, z(t), 0): 11, (0, y(t), 0): -3, (1, z(t), 0): -7, (0, z(t), 1): 0, \ (2, x(t), 0): -11, (2, z(t), 0): 0, (1, y(t), 1): 1}, 'type_of_equation': 'type2', 'func': [x(t), y(t), z(t)], \ 'is_linear': True, 'eq': [-3*y(t) + 11*z(t) + Derivative(x(t), t), 3*x(t) - 7*z(t) + Derivative(y(t), t), \ -11*x(t) + 7*y(t) + Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq9) == sol9 eq10 = (x2 + log(t)*(t*x1 - x(t)) + exp(t)*(t*y1 - y(t)), y2 + (t**2)*(t*x1 - x(t)) + (t)*(t*y1 - y(t))) sol10 = {'no_of_equation': 2, 'func_coeff': {(1, x(t), 2): 0, (0, y(t), 2): 0, (0, x(t), 0): -log(t), \ (1, x(t), 1): t**3, (0, x(t), 1): t*log(t), (0, y(t), 1): t*exp(t), (1, x(t), 0): -t**2, (1, y(t), 0): -t, \ (0, y(t), 0): -exp(t), (0, x(t), 2): 1, (1, y(t), 2): 1, (1, y(t), 1): t**2}, 'type_of_equation': 'type11', \ 'func': [x(t), y(t)], 'is_linear': True, 'eq': [(t*Derivative(x(t), t) - x(t))*log(t) + (t*Derivative(y(t), t) - \ y(t))*exp(t) + Derivative(x(t), t, t), t**2*(t*Derivative(x(t), t) - x(t)) + t*(t*Derivative(y(t), t) - y(t)) \ + Derivative(y(t), t, t)], 'order': {y(t): 2, x(t): 2}} assert classify_sysode(eq10) == sol10 eq11 = (Eq(x1,x(t)*y(t)**3), Eq(y1,y(t)**5)) sol11 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -y(t)**3, (1, x(t), 1): 0, (0, x(t), 1): 1, \ (1, y(t), 0): 0, (1, x(t), 0): 0, (0, y(t), 1): 0, (0, y(t), 0): 0, (1, y(t), 1): 1}, 'type_of_equation': \ 'type1', 'func': [x(t), y(t)], 'is_linear': False, 'eq': [-x(t)*y(t)**3 + Derivative(x(t), t), \ -y(t)**5 + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq11) == sol11 eq12 = (Eq(x1, y(t)), Eq(y1, x(t))) sol12 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): 0, (1, x(t), 1): 0, (0, x(t), 1): 1, (1, y(t), 0): 0, \ (1, x(t), 0): -1, (0, y(t), 1): 0, (0, y(t), 0): -1, (1, y(t), 1): 1}, 'type_of_equation': 'type1', 'func': \ [x(t), y(t)], 'is_linear': True, 'eq': [-y(t) + Derivative(x(t), t), -x(t) + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq12) == sol12 eq13 = (Eq(x1,x(t)*y(t)*sin(t)**2), Eq(y1,y(t)**2*sin(t)**2)) sol13 = {'no_of_equation': 2, 'func_coeff': {(0, x(t), 0): -y(t)*sin(t)**2, (1, x(t), 1): 0, (0, x(t), 1): 1, \ (1, y(t), 0): 0, (1, x(t), 0): 0, (0, y(t), 1): 0, (0, y(t), 0): -x(t)*sin(t)**2, (1, y(t), 1): 1}, \ 'type_of_equation': 'type4', 'func': [x(t), y(t)], 'is_linear': False, 'eq': [-x(t)*y(t)*sin(t)**2 + \ Derivative(x(t), t), -y(t)**2*sin(t)**2 + Derivative(y(t), t)], 'order': {y(t): 1, x(t): 1}} assert classify_sysode(eq13) == sol13 eq14 = (Eq(x1, 21*x(t)), Eq(y1, 17*x(t)+3*y(t)), Eq(z1, 5*x(t)+7*y(t)+9*z(t))) sol14 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): -3, (2, y(t), 1): 0, (2, z(t), 1): 1, \ (0, x(t), 0): -21, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): -7, (0, x(t), 1): 1, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): -17, (0, z(t), 0): 0, (0, y(t), 0): 0, (1, z(t), 0): 0, (0, z(t), 1): 0, \ (2, x(t), 0): -5, (2, z(t), 0): -9, (1, y(t), 1): 1}, 'type_of_equation': 'type1', 'func': [x(t), y(t), z(t)], \ 'is_linear': True, 'eq': [-21*x(t) + Derivative(x(t), t), -17*x(t) - 3*y(t) + Derivative(y(t), t), -5*x(t) - \ 7*y(t) - 9*z(t) + Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq14) == sol14 eq15 = (Eq(x1,4*x(t)+5*y(t)+2*z(t)),Eq(y1,x(t)+13*y(t)+9*z(t)),Eq(z1,32*x(t)+41*y(t)+11*z(t))) sol15 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): -13, (2, y(t), 1): 0, (2, z(t), 1): 1, \ (0, x(t), 0): -4, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): -41, (0, x(t), 1): 1, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): -1, (0, z(t), 0): -2, (0, y(t), 0): -5, (1, z(t), 0): -9, (0, z(t), 1): 0, \ (2, x(t), 0): -32, (2, z(t), 0): -11, (1, y(t), 1): 1}, 'type_of_equation': 'type6', 'func': \ [x(t), y(t), z(t)], 'is_linear': True, 'eq': [-4*x(t) - 5*y(t) - 2*z(t) + Derivative(x(t), t), -x(t) - 13*y(t) - \ 9*z(t) + Derivative(y(t), t), -32*x(t) - 41*y(t) - 11*z(t) + Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq15) == sol15 eq16 = (Eq(3*x1,4*5*(y(t)-z(t))),Eq(4*y1,3*5*(z(t)-x(t))),Eq(5*z1,3*4*(x(t)-y(t)))) sol16 = {'no_of_equation': 3, 'func_coeff': {(1, y(t), 0): 0, (2, y(t), 1): 0, (2, z(t), 1): 5, \ (0, x(t), 0): 0, (2, x(t), 1): 0, (1, x(t), 1): 0, (2, y(t), 0): 12, (0, x(t), 1): 3, (1, z(t), 1): 0, \ (0, y(t), 1): 0, (1, x(t), 0): 15, (0, z(t), 0): 20, (0, y(t), 0): -20, (1, z(t), 0): -15, (0, z(t), 1): 0, \ (2, x(t), 0): -12, (2, z(t), 0): 0, (1, y(t), 1): 4}, 'type_of_equation': 'type3', 'func': [x(t), y(t), z(t)], \ 'is_linear': True, 'eq': [-20*y(t) + 20*z(t) + 3*Derivative(x(t), t), 15*x(t) - 15*z(t) + 4*Derivative(y(t), t), \ -12*x(t) + 12*y(t) + 5*Derivative(z(t), t)], 'order': {z(t): 1, y(t): 1, x(t): 1}} assert classify_sysode(eq16) == sol16 # issue 8193: funcs parameter for classify_sysode has to actually work assert classify_sysode(eq1, funcs=[x(t), y(t)]) == sol1 def test_solve_ics(): # Basic tests that things work from dsolve. assert dsolve(f(x).diff(x) - 1/f(x), f(x), ics={f(1): 2}) == \ Eq(f(x), sqrt(2 * x + 2)) assert dsolve(f(x).diff(x) - f(x), f(x), ics={f(0): 1}) == Eq(f(x), exp(x)) assert dsolve(f(x).diff(x) - f(x), f(x), ics={f(x).diff(x).subs(x, 0): 1}) == Eq(f(x), exp(x)) assert dsolve(f(x).diff(x, x) + f(x), f(x), ics={f(0): 1, f(x).diff(x).subs(x, 0): 1}) == Eq(f(x), sin(x) + cos(x)) assert dsolve([f(x).diff(x) - f(x) + g(x), g(x).diff(x) - g(x) - f(x)], [f(x), g(x)], ics={f(0): 1, g(0): 0}) == [Eq(f(x), exp(x)*cos(x)), Eq(g(x), exp(x)*sin(x))] # Test cases where dsolve returns two solutions. eq = (x**2*f(x)**2 - x).diff(x) assert dsolve(eq, f(x), ics={f(1): 0}) == [Eq(f(x), -sqrt(x - 1)/x), Eq(f(x), sqrt(x - 1)/x)] assert dsolve(eq, f(x), ics={f(x).diff(x).subs(x, 1): 0}) == [Eq(f(x), -sqrt(x - S(1)/2)/x), Eq(f(x), sqrt(x - S(1)/2)/x)] eq = cos(f(x)) - (x*sin(f(x)) - f(x)**2)*f(x).diff(x) assert dsolve(eq, f(x), ics={f(0):1}, hint='1st_exact', simplify=False) == Eq(x*cos(f(x)) + f(x)**3/3, S(1)/3) assert dsolve(eq, f(x), ics={f(0):1}, hint='1st_exact', simplify=True) == Eq(x*cos(f(x)) + f(x)**3/3, S(1)/3) assert solve_ics([Eq(f(x), C1*exp(x))], [f(x)], [C1], {f(0): 1}) == {C1: 1} assert solve_ics([Eq(f(x), C1*sin(x) + C2*cos(x))], [f(x)], [C1, C2], {f(0): 1, f(pi/2): 1}) == {C1: 1, C2: 1} assert solve_ics([Eq(f(x), C1*sin(x) + C2*cos(x))], [f(x)], [C1, C2], {f(0): 1, f(x).diff(x).subs(x, 0): 1}) == {C1: 1, C2: 1} assert solve_ics([Eq(f(x), C1*sin(x) + C2*cos(x))], [f(x)], [C1, C2], {f(0): 1}) == \ {C2: 1} # Some more complicated tests Refer to PR #16098 assert dsolve(f(x).diff(x)*(f(x).diff(x, 2)-x), ics={f(0):0, f(x).diff(x).subs(x, 1):0}) == \ [Eq(f(x), 0), Eq(f(x), x ** 3 / 6 - x / 2)] assert dsolve(f(x).diff(x)*(f(x).diff(x, 2)-x), ics={f(0):0}) == \ [Eq(f(x), 0), Eq(f(x), C2*x + x**3/6)] K, r, f0 = symbols('K r f0') sol = Eq(f(x), -K*f0*exp(r*x)/((K - f0)*(-f0*exp(r*x)/(K - f0) - 1))) assert (dsolve(Eq(f(x).diff(x), r * f(x) * (1 - f(x) / K)), f(x), ics={f(0): f0})) == sol #Order dependent issues Refer to PR #16098 assert dsolve(f(x).diff(x)*(f(x).diff(x, 2)-x), ics={f(x).diff(x).subs(x,0):0, f(0):0}) == \ [Eq(f(x), 0), Eq(f(x), x ** 3 / 6)] assert dsolve(f(x).diff(x)*(f(x).diff(x, 2)-x), ics={f(0):0, f(x).diff(x).subs(x,0):0}) == \ [Eq(f(x), 0), Eq(f(x), x ** 3 / 6)] # XXX: Ought to be ValueError raises(ValueError, lambda: solve_ics([Eq(f(x), C1*sin(x) + C2*cos(x))], [f(x)], [C1, C2], {f(0): 1, f(pi): 1})) # Degenerate case. f'(0) is identically 0. raises(ValueError, lambda: solve_ics([Eq(f(x), sqrt(C1 - x**2))], [f(x)], [C1], {f(x).diff(x).subs(x, 0): 0})) EI, q, L = symbols('EI q L') # eq = Eq(EI*diff(f(x), x, 4), q) sols = [Eq(f(x), C1 + C2*x + C3*x**2 + C4*x**3 + q*x**4/(24*EI))] funcs = [f(x)] constants = [C1, C2, C3, C4] # Test both cases, Derivative (the default from f(x).diff(x).subs(x, L)), # and Subs ics1 = {f(0): 0, f(x).diff(x).subs(x, 0): 0, f(L).diff(L, 2): 0, f(L).diff(L, 3): 0} ics2 = {f(0): 0, f(x).diff(x).subs(x, 0): 0, Subs(f(x).diff(x, 2), x, L): 0, Subs(f(x).diff(x, 3), x, L): 0} solved_constants1 = solve_ics(sols, funcs, constants, ics1) solved_constants2 = solve_ics(sols, funcs, constants, ics2) assert solved_constants1 == solved_constants2 == { C1: 0, C2: 0, C3: L**2*q/(4*EI), C4: -L*q/(6*EI)} def test_ode_order(): f = Function('f') g = Function('g') x = Symbol('x') assert ode_order(3*x*exp(f(x)), f(x)) == 0 assert ode_order(x*diff(f(x), x) + 3*x*f(x) - sin(x)/x, f(x)) == 1 assert ode_order(x**2*f(x).diff(x, x) + x*diff(f(x), x) - f(x), f(x)) == 2 assert ode_order(diff(x*exp(f(x)), x, x), f(x)) == 2 assert ode_order(diff(x*diff(x*exp(f(x)), x, x), x), f(x)) == 3 assert ode_order(diff(f(x), x, x), g(x)) == 0 assert ode_order(diff(f(x), x, x)*diff(g(x), x), f(x)) == 2 assert ode_order(diff(f(x), x, x)*diff(g(x), x), g(x)) == 1 assert ode_order(diff(x*diff(x*exp(f(x)), x, x), x), g(x)) == 0 # issue 5835: ode_order has to also work for unevaluated derivatives # (ie, without using doit()). assert ode_order(Derivative(x*f(x), x), f(x)) == 1 assert ode_order(x*sin(Derivative(x*f(x)**2, x, x)), f(x)) == 2 assert ode_order(Derivative(x*Derivative(x*exp(f(x)), x, x), x), g(x)) == 0 assert ode_order(Derivative(f(x), x, x), g(x)) == 0 assert ode_order(Derivative(x*exp(f(x)), x, x), f(x)) == 2 assert ode_order(Derivative(f(x), x, x)*Derivative(g(x), x), g(x)) == 1 assert ode_order(Derivative(x*Derivative(f(x), x, x), x), f(x)) == 3 assert ode_order( x*sin(Derivative(x*Derivative(f(x), x)**2, x, x)), f(x)) == 3 # In all tests below, checkodesol has the order option set to prevent # superfluous calls to ode_order(), and the solve_for_func flag set to False # because dsolve() already tries to solve for the function, unless the # simplify=False option is set. def test_old_ode_tests(): # These are simple tests from the old ode module eq1 = Eq(f(x).diff(x), 0) eq2 = Eq(3*f(x).diff(x) - 5, 0) eq3 = Eq(3*f(x).diff(x), 5) eq4 = Eq(9*f(x).diff(x, x) + f(x), 0) eq5 = Eq(9*f(x).diff(x, x), f(x)) # Type: a(x)f'(x)+b(x)*f(x)+c(x)=0 eq6 = Eq(x**2*f(x).diff(x) + 3*x*f(x) - sin(x)/x, 0) eq7 = Eq(f(x).diff(x, x) - 3*diff(f(x), x) + 2*f(x), 0) # Type: 2nd order, constant coefficients (two real different roots) eq8 = Eq(f(x).diff(x, x) - 4*diff(f(x), x) + 4*f(x), 0) # Type: 2nd order, constant coefficients (two real equal roots) eq9 = Eq(f(x).diff(x, x) + 2*diff(f(x), x) + 3*f(x), 0) # Type: 2nd order, constant coefficients (two complex roots) eq10 = Eq(3*f(x).diff(x) - 1, 0) eq11 = Eq(x*f(x).diff(x) - 1, 0) sol1 = Eq(f(x), C1) sol2 = Eq(f(x), C1 + 5*x/3) sol3 = Eq(f(x), C1 + 5*x/3) sol4 = Eq(f(x), C1*sin(x/3) + C2*cos(x/3)) sol5 = Eq(f(x), C1*exp(-x/3) + C2*exp(x/3)) sol6 = Eq(f(x), (C1 - cos(x))/x**3) sol7 = Eq(f(x), (C1 + C2*exp(x))*exp(x)) sol8 = Eq(f(x), (C1 + C2*x)*exp(2*x)) sol9 = Eq(f(x), (C1*sin(x*sqrt(2)) + C2*cos(x*sqrt(2)))*exp(-x)) sol10 = Eq(f(x), C1 + x/3) sol11 = Eq(f(x), C1 + log(x)) assert dsolve(eq1) == sol1 assert dsolve(eq1.lhs) == sol1 assert dsolve(eq2) == sol2 assert dsolve(eq3) == sol3 assert dsolve(eq4) == sol4 assert dsolve(eq5) == sol5 assert dsolve(eq6) == sol6 assert dsolve(eq7) == sol7 assert dsolve(eq8) == sol8 assert dsolve(eq9) == sol9 assert dsolve(eq10) == sol10 assert dsolve(eq11) == sol11 assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=2, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=2, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=2, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=2, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=1, solve_for_func=False)[0] assert checkodesol(eq11, sol11, order=1, solve_for_func=False)[0] def test_1st_linear(): # Type: first order linear form f'(x)+p(x)f(x)=q(x) eq = Eq(f(x).diff(x) + x*f(x), x**2) sol = Eq(f(x), (C1 + x*exp(x**2/2) - sqrt(2)*sqrt(pi)*erfi(sqrt(2)*x/2)/2)*exp(-x**2/2)) assert dsolve(eq, hint='1st_linear') == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_Bernoulli(): # Type: Bernoulli, f'(x) + p(x)*f(x) == q(x)*f(x)**n eq = Eq(x*f(x).diff(x) + f(x) - f(x)**2, 0) sol = dsolve(eq, f(x), hint='Bernoulli') assert sol == Eq(f(x), 1/(x*(C1 + 1/x))) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_Riccati_special_minus2(): # Type: Riccati special alpha = -2, a*dy/dx + b*y**2 + c*y/x +d/x**2 eq = 2*f(x).diff(x) + f(x)**2 - f(x)/x + 3*x**(-2) sol = dsolve(eq, f(x), hint='Riccati_special_minus2') assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] @slow def test_1st_exact1(): # Type: Exact differential equation, p(x,f) + q(x,f)*f' == 0, # where dp/df == dq/dx eq1 = sin(x)*cos(f(x)) + cos(x)*sin(f(x))*f(x).diff(x) eq2 = (2*x*f(x) + 1)/f(x) + (f(x) - x)/f(x)**2*f(x).diff(x) eq3 = 2*x + f(x)*cos(x) + (2*f(x) + sin(x) - sin(f(x)))*f(x).diff(x) eq4 = cos(f(x)) - (x*sin(f(x)) - f(x)**2)*f(x).diff(x) eq5 = 2*x*f(x) + (x**2 + f(x)**2)*f(x).diff(x) sol1 = [Eq(f(x), -acos(C1/cos(x)) + 2*pi), Eq(f(x), acos(C1/cos(x)))] sol2 = Eq(f(x), exp(C1 - x**2 + LambertW(-x*exp(-C1 + x**2)))) sol2b = Eq(log(f(x)) + x/f(x) + x**2, C1) sol3 = Eq(f(x)*sin(x) + cos(f(x)) + x**2 + f(x)**2, C1) sol4 = Eq(x*cos(f(x)) + f(x)**3/3, C1) sol5 = Eq(x**2*f(x) + f(x)**3/3, C1) assert dsolve(eq1, f(x), hint='1st_exact') == sol1 assert dsolve(eq2, f(x), hint='1st_exact') == sol2 assert dsolve(eq3, f(x), hint='1st_exact') == sol3 assert dsolve(eq4, hint='1st_exact') == sol4 assert dsolve(eq5, hint='1st_exact', simplify=False) == sol5 assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] # issue 5080 blocks the testing of this solution # FIXME: assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2b, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=1, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=1, solve_for_func=False)[0] @slow @XFAIL def test_1st_exact2(): """ This is an exact equation that fails under the exact engine. It is caught by first order homogeneous albeit with a much contorted solution. The exact engine fails because of a poorly simplified integral of q(0,y)dy, where q is the function multiplying f'. The solutions should be Eq(sqrt(x**2+f(x)**2)**3+y**3, C1). The equation below is equivalent, but it is so complex that checkodesol fails, and takes a long time to do so. """ if ON_TRAVIS: skip("Too slow for travis.") eq = (x*sqrt(x**2 + f(x)**2) - (x**2*f(x)/(f(x) - sqrt(x**2 + f(x)**2)))*f(x).diff(x)) sol = dsolve(eq) assert sol == Eq(log(x), C1 - 9*sqrt(1 + f(x)**2/x**2)*asinh(f(x)/x)/(-27*f(x)/x + 27*sqrt(1 + f(x)**2/x**2)) - 9*sqrt(1 + f(x)**2/x**2)* log(1 - sqrt(1 + f(x)**2/x**2)*f(x)/x + 2*f(x)**2/x**2)/ (-27*f(x)/x + 27*sqrt(1 + f(x)**2/x**2)) + 9*asinh(f(x)/x)*f(x)/(x*(-27*f(x)/x + 27*sqrt(1 + f(x)**2/x**2))) + 9*f(x)*log(1 - sqrt(1 + f(x)**2/x**2)*f(x)/x + 2*f(x)**2/x**2)/ (x*(-27*f(x)/x + 27*sqrt(1 + f(x)**2/x**2)))) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_separable1(): # test_separable1-5 are from Ordinary Differential Equations, Tenenbaum and # Pollard, pg. 55 eq1 = f(x).diff(x) - f(x) eq2 = x*f(x).diff(x) - f(x) eq3 = f(x).diff(x) + sin(x) eq4 = f(x)**2 + 1 - (x**2 + 1)*f(x).diff(x) eq5 = f(x).diff(x)/tan(x) - f(x) - 2 eq6 = f(x).diff(x) * (1 - sin(f(x))) - 1 sol1 = Eq(f(x), C1*exp(x)) sol2 = Eq(f(x), C1*x) sol3 = Eq(f(x), C1 + cos(x)) sol4 = Eq(f(x), tan(C1 + atan(x))) sol5 = Eq(f(x), C1/cos(x) - 2) sol6 = Eq(-x + f(x) + cos(f(x)), C1) assert dsolve(eq1, hint='separable') == sol1 assert dsolve(eq2, hint='separable') == sol2 assert dsolve(eq3, hint='separable') == sol3 assert dsolve(eq4, hint='separable') == sol4 assert dsolve(eq5, hint='separable') == sol5 assert dsolve(eq6, hint='separable') == sol6 assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=1, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=1, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] @slow def test_separable2(): a = Symbol('a') eq6 = f(x)*x**2*f(x).diff(x) - f(x)**3 - 2*x**2*f(x).diff(x) eq7 = f(x)**2 - 1 - (2*f(x) + x*f(x))*f(x).diff(x) eq8 = x*log(x)*f(x).diff(x) + sqrt(1 + f(x)**2) eq9 = exp(x + 1)*tan(f(x)) + cos(f(x))*f(x).diff(x) eq10 = (x*cos(f(x)) + x**2*sin(f(x))*f(x).diff(x) - a**2*sin(f(x))*f(x).diff(x)) sol6 = Eq(Integral((u - 2)/u**3, (u, f(x))), C1 + Integral(x**(-2), x)) sol7 = Eq(-log(-1 + f(x)**2)/2, C1 - log(2 + x)) sol8 = Eq(asinh(f(x)), C1 - log(log(x))) # integrate cannot handle the integral on the lhs (cos/tan) sol9 = Eq(Integral(cos(u)/tan(u), (u, f(x))), C1 + Integral(-exp(1)*exp(x), x)) sol10 = Eq(-log(cos(f(x))), C1 - log(- a**2 + x**2)/2) assert dsolve(eq6, hint='separable_Integral').dummy_eq(sol6) assert dsolve(eq7, hint='separable', simplify=False) == sol7 assert dsolve(eq8, hint='separable', simplify=False) == sol8 assert dsolve(eq9, hint='separable_Integral').dummy_eq(sol9) assert dsolve(eq10, hint='separable', simplify=False) == sol10 assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=1, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=1, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=1, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=1, solve_for_func=False)[0] def test_separable3(): eq11 = f(x).diff(x) - f(x)*tan(x) eq12 = (x - 1)*cos(f(x))*f(x).diff(x) - 2*x*sin(f(x)) eq13 = f(x).diff(x) - f(x)*log(f(x))/tan(x) sol11 = Eq(f(x), C1/cos(x)) sol12 = Eq(log(sin(f(x))), C1 + 2*x + 2*log(x - 1)) sol13 = Eq(log(log(f(x))), C1 + log(sin(x))) assert dsolve(eq11, hint='separable') == sol11 assert dsolve(eq12, hint='separable', simplify=False) == sol12 assert dsolve(eq13, hint='separable', simplify=False) == sol13 assert checkodesol(eq11, sol11, order=1, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=1, solve_for_func=False)[0] assert checkodesol(eq13, sol13, order=1, solve_for_func=False)[0] def test_separable4(): # This has a slow integral (1/((1 + y**2)*atan(y))), so we isolate it. eq14 = x*f(x).diff(x) + (1 + f(x)**2)*atan(f(x)) sol14 = Eq(log(atan(f(x))), C1 - log(x)) assert dsolve(eq14, hint='separable', simplify=False) == sol14 assert checkodesol(eq14, sol14, order=1, solve_for_func=False)[0] def test_separable5(): eq15 = f(x).diff(x) + x*(f(x) + 1) eq16 = exp(f(x)**2)*(x**2 + 2*x + 1) + (x*f(x) + f(x))*f(x).diff(x) eq17 = f(x).diff(x) + f(x) eq18 = sin(x)*cos(2*f(x)) + cos(x)*sin(2*f(x))*f(x).diff(x) eq19 = (1 - x)*f(x).diff(x) - x*(f(x) + 1) eq20 = f(x)*diff(f(x), x) + x - 3*x*f(x)**2 eq21 = f(x).diff(x) - exp(x + f(x)) sol15 = Eq(f(x), -1 + C1*exp(-x**2/2)) sol16 = Eq(-exp(-f(x)**2)/2, C1 - x - x**2/2) sol17 = Eq(f(x), C1*exp(-x)) sol18 = Eq(-log(cos(2*f(x)))/2, C1 + log(cos(x))) sol19 = Eq(f(x), (C1*exp(-x) - x + 1)/(x - 1)) sol20 = Eq(log(-1 + 3*f(x)**2)/6, C1 + x**2/2) sol21 = Eq(-exp(-f(x)), C1 + exp(x)) assert dsolve(eq15, hint='separable') == sol15 assert dsolve(eq16, hint='separable', simplify=False) == sol16 assert dsolve(eq17, hint='separable') == sol17 assert dsolve(eq18, hint='separable', simplify=False) == sol18 assert dsolve(eq19, hint='separable') == sol19 assert dsolve(eq20, hint='separable', simplify=False) == sol20 assert dsolve(eq21, hint='separable', simplify=False) == sol21 assert checkodesol(eq15, sol15, order=1, solve_for_func=False)[0] assert checkodesol(eq16, sol16, order=1, solve_for_func=False)[0] assert checkodesol(eq17, sol17, order=1, solve_for_func=False)[0] assert checkodesol(eq18, sol18, order=1, solve_for_func=False)[0] assert checkodesol(eq19, sol19, order=1, solve_for_func=False)[0] assert checkodesol(eq20, sol20, order=1, solve_for_func=False)[0] assert checkodesol(eq21, sol21, order=1, solve_for_func=False)[0] def test_separable_1_5_checkodesol(): eq12 = (x - 1)*cos(f(x))*f(x).diff(x) - 2*x*sin(f(x)) sol12 = Eq(-log(1 - cos(f(x))**2)/2, C1 - 2*x - 2*log(1 - x)) assert checkodesol(eq12, sol12, order=1, solve_for_func=False)[0] def test_homogeneous_order(): assert homogeneous_order(exp(y/x) + tan(y/x), x, y) == 0 assert homogeneous_order(x**2 + sin(x)*cos(y), x, y) is None assert homogeneous_order(x - y - x*sin(y/x), x, y) == 1 assert homogeneous_order((x*y + sqrt(x**4 + y**4) + x**2*(log(x) - log(y)))/ (pi*x**Rational(2, 3)*sqrt(y)**3), x, y) == Rational(-1, 6) assert homogeneous_order(y/x*cos(y/x) - x/y*sin(y/x) + cos(y/x), x, y) == 0 assert homogeneous_order(f(x), x, f(x)) == 1 assert homogeneous_order(f(x)**2, x, f(x)) == 2 assert homogeneous_order(x*y*z, x, y) == 2 assert homogeneous_order(x*y*z, x, y, z) == 3 assert homogeneous_order(x**2*f(x)/sqrt(x**2 + f(x)**2), f(x)) is None assert homogeneous_order(f(x, y)**2, x, f(x, y), y) == 2 assert homogeneous_order(f(x, y)**2, x, f(x), y) is None assert homogeneous_order(f(x, y)**2, x, f(x, y)) is None assert homogeneous_order(f(y, x)**2, x, y, f(x, y)) is None assert homogeneous_order(f(y), f(x), x) is None assert homogeneous_order(-f(x)/x + 1/sin(f(x)/ x), f(x), x) == 0 assert homogeneous_order(log(1/y) + log(x**2), x, y) is None assert homogeneous_order(log(1/y) + log(x), x, y) == 0 assert homogeneous_order(log(x/y), x, y) == 0 assert homogeneous_order(2*log(1/y) + 2*log(x), x, y) == 0 a = Symbol('a') assert homogeneous_order(a*log(1/y) + a*log(x), x, y) == 0 assert homogeneous_order(f(x).diff(x), x, y) is None assert homogeneous_order(-f(x).diff(x) + x, x, y) is None assert homogeneous_order(O(x), x, y) is None assert homogeneous_order(x + O(x**2), x, y) is None assert homogeneous_order(x**pi, x) == pi assert homogeneous_order(x**x, x) is None raises(ValueError, lambda: homogeneous_order(x*y)) @slow def test_1st_homogeneous_coeff_ode(): # Type: First order homogeneous, y'=f(y/x) eq1 = f(x)/x*cos(f(x)/x) - (x/f(x)*sin(f(x)/x) + cos(f(x)/x))*f(x).diff(x) eq2 = x*f(x).diff(x) - f(x) - x*sin(f(x)/x) eq3 = f(x) + (x*log(f(x)/x) - 2*x)*diff(f(x), x) eq4 = 2*f(x)*exp(x/f(x)) + f(x)*f(x).diff(x) - 2*x*exp(x/f(x))*f(x).diff(x) eq5 = 2*x**2*f(x) + f(x)**3 + (x*f(x)**2 - 2*x**3)*f(x).diff(x) eq6 = x*exp(f(x)/x) - f(x)*sin(f(x)/x) + x*sin(f(x)/x)*f(x).diff(x) eq7 = (x + sqrt(f(x)**2 - x*f(x)))*f(x).diff(x) - f(x) eq8 = x + f(x) - (x - f(x))*f(x).diff(x) sol1 = Eq(log(x), C1 - log(f(x)*sin(f(x)/x)/x)) sol2 = Eq(log(x), log(C1) + log(cos(f(x)/x) - 1)/2 - log(cos(f(x)/x) + 1)/2) sol3 = Eq(f(x), -exp(C1)*LambertW(-x*exp(-C1 + 1))) sol4 = Eq(log(f(x)), C1 - 2*exp(x/f(x))) sol5 = Eq(f(x), exp(2*C1 + LambertW(-2*x**4*exp(-4*C1))/2)/x) sol6 = Eq(log(x), C1 + exp(-f(x)/x)*sin(f(x)/x)/2 + exp(-f(x)/x)*cos(f(x)/x)/2) sol7 = Eq(log(f(x)), C1 - 2*sqrt(-x/f(x) + 1)) sol8 = Eq(log(x), C1 - log(sqrt(1 + f(x)**2/x**2)) + atan(f(x)/x)) # indep_div_dep actually has a simpler solution for eq2, # but it runs too slow assert dsolve(eq1, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol1 assert dsolve(eq2, hint='1st_homogeneous_coeff_subs_dep_div_indep', simplify=False) == sol2 assert dsolve(eq3, hint='1st_homogeneous_coeff_best') == sol3 assert dsolve(eq4, hint='1st_homogeneous_coeff_best') == sol4 assert dsolve(eq5, hint='1st_homogeneous_coeff_best') == sol5 assert dsolve(eq6, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol6 assert dsolve(eq7, hint='1st_homogeneous_coeff_best') == sol7 assert dsolve(eq8, hint='1st_homogeneous_coeff_best') == sol8 # FIXME: sol3 and sol5 don't work with checkodesol (because of LambertW?) # previous code was testing with these other solutions: sol3b = Eq(-f(x)/(1 + log(x/f(x))), C1) sol5b = Eq(log(C1*x*sqrt(1/x)*sqrt(f(x))) + x**2/(2*f(x)**2), 0) assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3b, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=1, solve_for_func=False)[0] assert checkodesol(eq5, sol5b, order=1, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=1, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode_check2(): eq2 = x*f(x).diff(x) - f(x) - x*sin(f(x)/x) sol2 = Eq(x/tan(f(x)/(2*x)), C1) assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] @XFAIL def test_1st_homogeneous_coeff_ode_check3(): skip('This is a known issue.') # checker cannot determine that the following expression is zero: # (False, # x*(log(exp(-LambertW(C1*x))) + # LambertW(C1*x))*exp(-LambertW(C1*x) + 1)) # This is blocked by issue 5080. eq3 = f(x) + (x*log(f(x)/x) - 2*x)*diff(f(x), x) sol3a = Eq(f(x), x*exp(1 - LambertW(C1*x))) assert checkodesol(eq3, sol3a, solve_for_func=True)[0] # Checker can't verify this form either # (False, # C1*(log(C1*LambertW(C2*x)/x) + LambertW(C2*x) - 1)*LambertW(C2*x)) # It is because a = W(a)*exp(W(a)), so log(a) == log(W(a)) + W(a) and C2 = # -E/C1 (which can be verified by solving with simplify=False). sol3b = Eq(f(x), C1*LambertW(C2*x)) assert checkodesol(eq3, sol3b, solve_for_func=True)[0] def test_1st_homogeneous_coeff_ode_check7(): eq7 = (x + sqrt(f(x)**2 - x*f(x)))*f(x).diff(x) - f(x) sol7 = Eq(log(C1*f(x)) + 2*sqrt(1 - x/f(x)), 0) assert checkodesol(eq7, sol7, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode2(): eq1 = f(x).diff(x) - f(x)/x + 1/sin(f(x)/x) eq2 = x**2 + f(x)**2 - 2*x*f(x)*f(x).diff(x) eq3 = x*exp(f(x)/x) + f(x) - x*f(x).diff(x) sol1 = [Eq(f(x), x*(-acos(C1 + log(x)) + 2*pi)), Eq(f(x), x*acos(C1 + log(x)))] sol2 = Eq(log(f(x)), log(C1) + log(x/f(x)) - log(x**2/f(x)**2 - 1)) sol3 = Eq(f(x), log((1/(C1 - log(x)))**x)) # specific hints are applied for speed reasons assert dsolve(eq1, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol1 assert dsolve(eq2, hint='1st_homogeneous_coeff_best', simplify=False) == sol2 assert dsolve(eq3, hint='1st_homogeneous_coeff_subs_dep_div_indep') == sol3 # FIXME: sol3 doesn't work with checkodesol (because of **x?) # previous code was testing with this other solution: sol3b = Eq(f(x), log(log(C1/x)**(-x))) assert checkodesol(eq1, sol1, order=1, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=1, solve_for_func=False)[0] assert checkodesol(eq3, sol3b, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode_check9(): _u2 = Dummy('u2') __a = Dummy('a') eq9 = f(x)**2 + (x*sqrt(f(x)**2 - x**2) - x*f(x))*f(x).diff(x) sol9 = Eq(-Integral(-1/(-(1 - sqrt(1 - _u2**2))*_u2 + _u2), (_u2, __a, x/f(x))) + log(C1*f(x)), 0) assert checkodesol(eq9, sol9, order=1, solve_for_func=False)[0] def test_1st_homogeneous_coeff_ode3(): # The standard integration engine cannot handle one of the integrals # involved (see issue 4551). meijerg code comes up with an answer, but in # unconventional form. # checkodesol fails for this equation, so its test is in # test_1st_homogeneous_coeff_ode_check9 above. It has to compare string # expressions because u2 is a dummy variable. eq = f(x)**2 + (x*sqrt(f(x)**2 - x**2) - x*f(x))*f(x).diff(x) sol = Eq(log(f(x)), C1 + Piecewise( (acosh(f(x)/x), abs(f(x)**2)/x**2 > 1), (-I*asin(f(x)/x), True))) assert dsolve(eq, hint='1st_homogeneous_coeff_subs_indep_div_dep') == sol def test_1st_homogeneous_coeff_corner_case(): eq1 = f(x).diff(x) - f(x)/x c1 = classify_ode(eq1, f(x)) eq2 = x*f(x).diff(x) - f(x) c2 = classify_ode(eq2, f(x)) sdi = "1st_homogeneous_coeff_subs_dep_div_indep" sid = "1st_homogeneous_coeff_subs_indep_div_dep" assert sid not in c1 and sdi not in c1 assert sid not in c2 and sdi not in c2 @slow def test_nth_linear_constant_coeff_homogeneous(): # From Exercise 20, in Ordinary Differential Equations, # Tenenbaum and Pollard, pg. 220 a = Symbol('a', positive=True) k = Symbol('k', real=True) eq1 = f(x).diff(x, 2) + 2*f(x).diff(x) eq2 = f(x).diff(x, 2) - 3*f(x).diff(x) + 2*f(x) eq3 = f(x).diff(x, 2) - f(x) eq4 = f(x).diff(x, 3) + f(x).diff(x, 2) - 6*f(x).diff(x) eq5 = 6*f(x).diff(x, 2) - 11*f(x).diff(x) + 4*f(x) eq6 = Eq(f(x).diff(x, 2) + 2*f(x).diff(x) - f(x), 0) eq7 = diff(f(x), x, 3) + diff(f(x), x, 2) - 10*diff(f(x), x) - 6*f(x) eq8 = f(x).diff(x, 4) - f(x).diff(x, 3) - 4*f(x).diff(x, 2) + \ 4*f(x).diff(x) eq9 = f(x).diff(x, 4) + 4*f(x).diff(x, 3) + f(x).diff(x, 2) - \ 4*f(x).diff(x) - 2*f(x) eq10 = f(x).diff(x, 4) - a**2*f(x) eq11 = f(x).diff(x, 2) - 2*k*f(x).diff(x) - 2*f(x) eq12 = f(x).diff(x, 2) + 4*k*f(x).diff(x) - 12*k**2*f(x) eq13 = f(x).diff(x, 4) eq14 = f(x).diff(x, 2) + 4*f(x).diff(x) + 4*f(x) eq15 = 3*f(x).diff(x, 3) + 5*f(x).diff(x, 2) + f(x).diff(x) - f(x) eq16 = f(x).diff(x, 3) - 6*f(x).diff(x, 2) + 12*f(x).diff(x) - 8*f(x) eq17 = f(x).diff(x, 2) - 2*a*f(x).diff(x) + a**2*f(x) eq18 = f(x).diff(x, 4) + 3*f(x).diff(x, 3) eq19 = f(x).diff(x, 4) - 2*f(x).diff(x, 2) eq20 = f(x).diff(x, 4) + 2*f(x).diff(x, 3) - 11*f(x).diff(x, 2) - \ 12*f(x).diff(x) + 36*f(x) eq21 = 36*f(x).diff(x, 4) - 37*f(x).diff(x, 2) + 4*f(x).diff(x) + 5*f(x) eq22 = f(x).diff(x, 4) - 8*f(x).diff(x, 2) + 16*f(x) eq23 = f(x).diff(x, 2) - 2*f(x).diff(x) + 5*f(x) eq24 = f(x).diff(x, 2) - f(x).diff(x) + f(x) eq25 = f(x).diff(x, 4) + 5*f(x).diff(x, 2) + 6*f(x) eq26 = f(x).diff(x, 2) - 4*f(x).diff(x) + 20*f(x) eq27 = f(x).diff(x, 4) + 4*f(x).diff(x, 2) + 4*f(x) eq28 = f(x).diff(x, 3) + 8*f(x) eq29 = f(x).diff(x, 4) + 4*f(x).diff(x, 2) eq30 = f(x).diff(x, 5) + 2*f(x).diff(x, 3) + f(x).diff(x) eq31 = f(x).diff(x, 4) + f(x).diff(x, 2) + f(x) eq32 = f(x).diff(x, 4) + 4*f(x).diff(x, 2) + f(x) sol1 = Eq(f(x), C1 + C2*exp(-2*x)) sol2 = Eq(f(x), (C1 + C2*exp(x))*exp(x)) sol3 = Eq(f(x), C1*exp(x) + C2*exp(-x)) sol4 = Eq(f(x), C1 + C2*exp(-3*x) + C3*exp(2*x)) sol5 = Eq(f(x), C1*exp(x/2) + C2*exp(4*x/3)) sol6 = Eq(f(x), C1*exp(x*(-1 + sqrt(2))) + C2*exp(x*(-sqrt(2) - 1))) sol7 = Eq(f(x), C1*exp(3*x) + C2*exp(x*(-2 - sqrt(2))) + C3*exp(x*(-2 + sqrt(2)))) sol8 = Eq(f(x), C1 + C2*exp(x) + C3*exp(-2*x) + C4*exp(2*x)) sol9 = Eq(f(x), C1*exp(x) + C2*exp(-x) + C3*exp(x*(-2 + sqrt(2))) + C4*exp(x*(-2 - sqrt(2)))) sol10 = Eq(f(x), C1*sin(x*sqrt(a)) + C2*cos(x*sqrt(a)) + C3*exp(x*sqrt(a)) + C4*exp(-x*sqrt(a))) sol11 = Eq(f(x), C1*exp(x*(k - sqrt(k**2 + 2))) + C2*exp(x*(k + sqrt(k**2 + 2)))) sol12 = Eq(f(x), C1*exp(-6*k*x) + C2*exp(2*k*x)) sol13 = Eq(f(x), C1 + C2*x + C3*x**2 + C4*x**3) sol14 = Eq(f(x), (C1 + C2*x)*exp(-2*x)) sol15 = Eq(f(x), (C1 + C2*x)*exp(-x) + C3*exp(x/3)) sol16 = Eq(f(x), (C1 + C2*x + C3*x**2)*exp(2*x)) sol17 = Eq(f(x), (C1 + C2*x)*exp(a*x)) sol18 = Eq(f(x), C1 + C2*x + C3*x**2 + C4*exp(-3*x)) sol19 = Eq(f(x), C1 + C2*x + C3*exp(x*sqrt(2)) + C4*exp(-x*sqrt(2))) sol20 = Eq(f(x), (C1 + C2*x)*exp(-3*x) + (C3 + C4*x)*exp(2*x)) sol21 = Eq(f(x), C1*exp(x/2) + C2*exp(-x) + C3*exp(-x/3) + C4*exp(5*x/6)) sol22 = Eq(f(x), (C1 + C2*x)*exp(-2*x) + (C3 + C4*x)*exp(2*x)) sol23 = Eq(f(x), (C1*sin(2*x) + C2*cos(2*x))*exp(x)) sol24 = Eq(f(x), (C1*sin(x*sqrt(3)/2) + C2*cos(x*sqrt(3)/2))*exp(x/2)) sol25 = Eq(f(x), C1*cos(x*sqrt(3)) + C2*sin(x*sqrt(3)) + C3*sin(x*sqrt(2)) + C4*cos(x*sqrt(2))) sol26 = Eq(f(x), (C1*sin(4*x) + C2*cos(4*x))*exp(2*x)) sol27 = Eq(f(x), (C1 + C2*x)*sin(x*sqrt(2)) + (C3 + C4*x)*cos(x*sqrt(2))) sol28 = Eq(f(x), (C1*sin(x*sqrt(3)) + C2*cos(x*sqrt(3)))*exp(x) + C3*exp(-2*x)) sol29 = Eq(f(x), C1 + C2*sin(2*x) + C3*cos(2*x) + C4*x) sol30 = Eq(f(x), C1 + (C2 + C3*x)*sin(x) + (C4 + C5*x)*cos(x)) sol31 = Eq(f(x), (C1*sin(sqrt(3)*x/2) + C2*cos(sqrt(3)*x/2))/sqrt(exp(x)) + (C3*sin(sqrt(3)*x/2) + C4*cos(sqrt(3)*x/2))*sqrt(exp(x))) sol32 = Eq(f(x), C1*sin(x*sqrt(-sqrt(3) + 2)) + C2*sin(x*sqrt(sqrt(3) + 2)) + C3*cos(x*sqrt(-sqrt(3) + 2)) + C4*cos(x*sqrt(sqrt(3) + 2))) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) sol6s = constant_renumber(sol6) sol7s = constant_renumber(sol7) sol8s = constant_renumber(sol8) sol9s = constant_renumber(sol9) sol10s = constant_renumber(sol10) sol11s = constant_renumber(sol11) sol12s = constant_renumber(sol12) sol13s = constant_renumber(sol13) sol14s = constant_renumber(sol14) sol15s = constant_renumber(sol15) sol16s = constant_renumber(sol16) sol17s = constant_renumber(sol17) sol18s = constant_renumber(sol18) sol19s = constant_renumber(sol19) sol20s = constant_renumber(sol20) sol21s = constant_renumber(sol21) sol22s = constant_renumber(sol22) sol23s = constant_renumber(sol23) sol24s = constant_renumber(sol24) sol25s = constant_renumber(sol25) sol26s = constant_renumber(sol26) sol27s = constant_renumber(sol27) sol28s = constant_renumber(sol28) sol29s = constant_renumber(sol29) sol30s = constant_renumber(sol30) assert dsolve(eq1) in (sol1, sol1s) assert dsolve(eq2) in (sol2, sol2s) assert dsolve(eq3) in (sol3, sol3s) assert dsolve(eq4) in (sol4, sol4s) assert dsolve(eq5) in (sol5, sol5s) assert dsolve(eq6) in (sol6, sol6s) assert dsolve(eq7) in (sol7, sol7s) assert dsolve(eq8) in (sol8, sol8s) assert dsolve(eq9) in (sol9, sol9s) assert dsolve(eq10) in (sol10, sol10s) assert dsolve(eq11) in (sol11, sol11s) assert dsolve(eq12) in (sol12, sol12s) assert dsolve(eq13) in (sol13, sol13s) assert dsolve(eq14) in (sol14, sol14s) assert dsolve(eq15) in (sol15, sol15s) assert dsolve(eq16) in (sol16, sol16s) assert dsolve(eq17) in (sol17, sol17s) assert dsolve(eq18) in (sol18, sol18s) assert dsolve(eq19) in (sol19, sol19s) assert dsolve(eq20) in (sol20, sol20s) assert dsolve(eq21) in (sol21, sol21s) assert dsolve(eq22) in (sol22, sol22s) assert dsolve(eq23) in (sol23, sol23s) assert dsolve(eq24) in (sol24, sol24s) assert dsolve(eq25) in (sol25, sol25s) assert dsolve(eq26) in (sol26, sol26s) assert dsolve(eq27) in (sol27, sol27s) assert dsolve(eq28) in (sol28, sol28s) assert dsolve(eq29) in (sol29, sol29s) assert dsolve(eq30) in (sol30, sol30s) assert dsolve(eq31) in (sol31,) assert dsolve(eq32) in (sol32,) assert checkodesol(eq1, sol1, order=2, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=2, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=2, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=3, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=2, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=3, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=4, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=4, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=4, solve_for_func=False)[0] assert checkodesol(eq11, sol11, order=2, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=2, solve_for_func=False)[0] assert checkodesol(eq13, sol13, order=4, solve_for_func=False)[0] assert checkodesol(eq14, sol14, order=2, solve_for_func=False)[0] assert checkodesol(eq15, sol15, order=3, solve_for_func=False)[0] assert checkodesol(eq16, sol16, order=3, solve_for_func=False)[0] assert checkodesol(eq17, sol17, order=2, solve_for_func=False)[0] assert checkodesol(eq18, sol18, order=4, solve_for_func=False)[0] assert checkodesol(eq19, sol19, order=4, solve_for_func=False)[0] assert checkodesol(eq20, sol20, order=4, solve_for_func=False)[0] assert checkodesol(eq21, sol21, order=4, solve_for_func=False)[0] assert checkodesol(eq22, sol22, order=4, solve_for_func=False)[0] assert checkodesol(eq23, sol23, order=2, solve_for_func=False)[0] assert checkodesol(eq24, sol24, order=2, solve_for_func=False)[0] assert checkodesol(eq25, sol25, order=4, solve_for_func=False)[0] assert checkodesol(eq26, sol26, order=2, solve_for_func=False)[0] assert checkodesol(eq27, sol27, order=4, solve_for_func=False)[0] assert checkodesol(eq28, sol28, order=3, solve_for_func=False)[0] assert checkodesol(eq29, sol29, order=4, solve_for_func=False)[0] assert checkodesol(eq30, sol30, order=5, solve_for_func=False)[0] assert checkodesol(eq31, sol31, order=4, solve_for_func=False)[0] assert checkodesol(eq32, sol32, order=4, solve_for_func=False)[0] # Issue #15237 eqn = Derivative(x*f(x), x, x, x) hint = 'nth_linear_constant_coeff_homogeneous' raises(ValueError, lambda: dsolve(eqn, f(x), hint, prep=True)) raises(ValueError, lambda: dsolve(eqn, f(x), hint, prep=False)) def test_nth_linear_constant_coeff_homogeneous_rootof(): # One real root, two complex conjugate pairs eq = f(x).diff(x, 5) + 11*f(x).diff(x) - 2*f(x) r1, r2, r3, r4, r5 = [rootof(x**5 + 11*x - 2, n) for n in range(5)] sol = Eq(f(x), C5*exp(r1*x) + exp(re(r2)*x) * (C1*sin(im(r2)*x) + C2*cos(im(r2)*x)) + exp(re(r4)*x) * (C3*sin(im(r4)*x) + C4*cos(im(r4)*x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Three real roots, one complex conjugate pair eq = f(x).diff(x,5) - 3*f(x).diff(x) + f(x) r1, r2, r3, r4, r5 = [rootof(x**5 - 3*x + 1, n) for n in range(5)] sol = Eq(f(x), C3*exp(r1*x) + C4*exp(r2*x) + C5*exp(r3*x) + exp(re(r4)*x) * (C1*sin(im(r4)*x) + C2*cos(im(r4)*x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Five distinct real roots eq = f(x).diff(x,5) - 100*f(x).diff(x,3) + 1000*f(x).diff(x) + f(x) r1, r2, r3, r4, r5 = [rootof(x**5 - 100*x**3 + 1000*x + 1, n) for n in range(5)] sol = Eq(f(x), C1*exp(r1*x) + C2*exp(r2*x) + C3*exp(r3*x) + C4*exp(r4*x) + C5*exp(r5*x)) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Rational root and unsolvable quintic eq = f(x).diff(x, 6) - 6*f(x).diff(x, 5) + 5*f(x).diff(x, 4) + 10*f(x).diff(x) - 50 * f(x) r2, r3, r4, r5, r6 = [rootof(x**5 - x**4 + 10, n) for n in range(5)] sol = Eq(f(x), C5*exp(5*x) + C6*exp(x*r2) + exp(re(r3)*x) * (C1*sin(im(r3)*x) + C2*cos(im(r3)*x)) + exp(re(r5)*x) * (C3*sin(im(r5)*x) + C4*cos(im(r5)*x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... # Five double roots (this is (x**5 - x + 1)**2) eq = f(x).diff(x, 10) - 2*f(x).diff(x, 6) + 2*f(x).diff(x, 5) + f(x).diff(x, 2) - 2*f(x).diff(x, 1) + f(x) r1, r2, r3, r4, r5 = [rootof(x**5 - x + 1, n) for n in range(5)] sol = Eq(f(x), (C1 + C2 *x)*exp(r1*x) + exp(re(r2)*x) * ((C3 + C4*x)*sin(im(r2)*x) + (C5 + C6 *x)*cos(im(r2)*x)) + exp(re(r4)*x) * ((C7 + C8*x)*sin(im(r4)*x) + (C9 + C10*x)*cos(im(r4)*x)) ) assert dsolve(eq) == sol # FIXME: assert checkodesol(eq, sol) == (True, [0]) # Hangs... def test_nth_linear_constant_coeff_homogeneous_irrational(): our_hint='nth_linear_constant_coeff_homogeneous' eq = Eq(sqrt(2) * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2*sin(2**(S(3)/4)*x/2) + C3*cos(2**(S(3)/4)*x/2)) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] E = exp(1) eq = Eq(E * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2*sin(x/sqrt(E)) + C3*cos(x/sqrt(E))) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] eq = Eq(pi * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2*sin(x/sqrt(pi)) + C3*cos(x/sqrt(pi))) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] eq = Eq(I * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2*exp(-sqrt(I)*x) + C3*exp(sqrt(I)*x)) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=3, solve_for_func=False)[0] @XFAIL @slow def test_nth_linear_constant_coeff_homogeneous_rootof_sol(): if ON_TRAVIS: skip("Too slow for travis.") eq = f(x).diff(x, 5) + 11*f(x).diff(x) - 2*f(x) sol = Eq(f(x), C1*exp(x*rootof(x**5 + 11*x - 2, 0)) + C2*exp(x*rootof(x**5 + 11*x - 2, 1)) + C3*exp(x*rootof(x**5 + 11*x - 2, 2)) + C4*exp(x*rootof(x**5 + 11*x - 2, 3)) + C5*exp(x*rootof(x**5 + 11*x - 2, 4))) assert checkodesol(eq, sol, order=5, solve_for_func=False)[0] @XFAIL def test_noncircularized_real_imaginary_parts(): # If this passes, lines numbered 3878-3882 (at the time of this commit) # of sympy/solvers/ode.py for nth_linear_constant_coeff_homogeneous # should be removed. y = sqrt(1+x) i, r = im(y), re(y) assert not (i.has(atan2) and r.has(atan2)) @XFAIL def test_collect_respecting_exponentials(): # If this test passes, lines 1306-1311 (at the time of this commit) # of sympy/solvers/ode.py should be removed. sol = 1 + exp(x/2) assert sol == collect( sol, exp(x/3)) def test_undetermined_coefficients_match(): assert _undetermined_coefficients_match(g(x), x) == {'test': False} assert _undetermined_coefficients_match(sin(2*x + sqrt(5)), x) == \ {'test': True, 'trialset': set([cos(2*x + sqrt(5)), sin(2*x + sqrt(5))])} assert _undetermined_coefficients_match(sin(x)*cos(x), x) == \ {'test': False} s = set([cos(x), x*cos(x), x**2*cos(x), x**2*sin(x), x*sin(x), sin(x)]) assert _undetermined_coefficients_match(sin(x)*(x**2 + x + 1), x) == \ {'test': True, 'trialset': s} assert _undetermined_coefficients_match( sin(x)*x**2 + sin(x)*x + sin(x), x) == {'test': True, 'trialset': s} assert _undetermined_coefficients_match( exp(2*x)*sin(x)*(x**2 + x + 1), x ) == { 'test': True, 'trialset': set([exp(2*x)*sin(x), x**2*exp(2*x)*sin(x), cos(x)*exp(2*x), x**2*cos(x)*exp(2*x), x*cos(x)*exp(2*x), x*exp(2*x)*sin(x)])} assert _undetermined_coefficients_match(1/sin(x), x) == {'test': False} assert _undetermined_coefficients_match(log(x), x) == {'test': False} assert _undetermined_coefficients_match(2**(x)*(x**2 + x + 1), x) == \ {'test': True, 'trialset': set([2**x, x*2**x, x**2*2**x])} assert _undetermined_coefficients_match(x**y, x) == {'test': False} assert _undetermined_coefficients_match(exp(x)*exp(2*x + 1), x) == \ {'test': True, 'trialset': set([exp(1 + 3*x)])} assert _undetermined_coefficients_match(sin(x)*(x**2 + x + 1), x) == \ {'test': True, 'trialset': set([x*cos(x), x*sin(x), x**2*cos(x), x**2*sin(x), cos(x), sin(x)])} assert _undetermined_coefficients_match(sin(x)*(x + sin(x)), x) == \ {'test': False} assert _undetermined_coefficients_match(sin(x)*(x + sin(2*x)), x) == \ {'test': False} assert _undetermined_coefficients_match(sin(x)*tan(x), x) == \ {'test': False} assert _undetermined_coefficients_match( x**2*sin(x)*exp(x) + x*sin(x) + x, x ) == { 'test': True, 'trialset': set([x**2*cos(x)*exp(x), x, cos(x), S(1), exp(x)*sin(x), sin(x), x*exp(x)*sin(x), x*cos(x), x*cos(x)*exp(x), x*sin(x), cos(x)*exp(x), x**2*exp(x)*sin(x)])} assert _undetermined_coefficients_match(4*x*sin(x - 2), x) == { 'trialset': set([x*cos(x - 2), x*sin(x - 2), cos(x - 2), sin(x - 2)]), 'test': True, } assert _undetermined_coefficients_match(2**x*x, x) == \ {'test': True, 'trialset': set([2**x, x*2**x])} assert _undetermined_coefficients_match(2**x*exp(2*x), x) == \ {'test': True, 'trialset': set([2**x*exp(2*x)])} assert _undetermined_coefficients_match(exp(-x)/x, x) == \ {'test': False} # Below are from Ordinary Differential Equations, # Tenenbaum and Pollard, pg. 231 assert _undetermined_coefficients_match(S(4), x) == \ {'test': True, 'trialset': set([S(1)])} assert _undetermined_coefficients_match(12*exp(x), x) == \ {'test': True, 'trialset': set([exp(x)])} assert _undetermined_coefficients_match(exp(I*x), x) == \ {'test': True, 'trialset': set([exp(I*x)])} assert _undetermined_coefficients_match(sin(x), x) == \ {'test': True, 'trialset': set([cos(x), sin(x)])} assert _undetermined_coefficients_match(cos(x), x) == \ {'test': True, 'trialset': set([cos(x), sin(x)])} assert _undetermined_coefficients_match(8 + 6*exp(x) + 2*sin(x), x) == \ {'test': True, 'trialset': set([S(1), cos(x), sin(x), exp(x)])} assert _undetermined_coefficients_match(x**2, x) == \ {'test': True, 'trialset': set([S(1), x, x**2])} assert _undetermined_coefficients_match(9*x*exp(x) + exp(-x), x) == \ {'test': True, 'trialset': set([x*exp(x), exp(x), exp(-x)])} assert _undetermined_coefficients_match(2*exp(2*x)*sin(x), x) == \ {'test': True, 'trialset': set([exp(2*x)*sin(x), cos(x)*exp(2*x)])} assert _undetermined_coefficients_match(x - sin(x), x) == \ {'test': True, 'trialset': set([S(1), x, cos(x), sin(x)])} assert _undetermined_coefficients_match(x**2 + 2*x, x) == \ {'test': True, 'trialset': set([S(1), x, x**2])} assert _undetermined_coefficients_match(4*x*sin(x), x) == \ {'test': True, 'trialset': set([x*cos(x), x*sin(x), cos(x), sin(x)])} assert _undetermined_coefficients_match(x*sin(2*x), x) == \ {'test': True, 'trialset': set([x*cos(2*x), x*sin(2*x), cos(2*x), sin(2*x)])} assert _undetermined_coefficients_match(x**2*exp(-x), x) == \ {'test': True, 'trialset': set([x*exp(-x), x**2*exp(-x), exp(-x)])} assert _undetermined_coefficients_match(2*exp(-x) - x**2*exp(-x), x) == \ {'test': True, 'trialset': set([x*exp(-x), x**2*exp(-x), exp(-x)])} assert _undetermined_coefficients_match(exp(-2*x) + x**2, x) == \ {'test': True, 'trialset': set([S(1), x, x**2, exp(-2*x)])} assert _undetermined_coefficients_match(x*exp(-x), x) == \ {'test': True, 'trialset': set([x*exp(-x), exp(-x)])} assert _undetermined_coefficients_match(x + exp(2*x), x) == \ {'test': True, 'trialset': set([S(1), x, exp(2*x)])} assert _undetermined_coefficients_match(sin(x) + exp(-x), x) == \ {'test': True, 'trialset': set([cos(x), sin(x), exp(-x)])} assert _undetermined_coefficients_match(exp(x), x) == \ {'test': True, 'trialset': set([exp(x)])} # converted from sin(x)**2 assert _undetermined_coefficients_match(S(1)/2 - cos(2*x)/2, x) == \ {'test': True, 'trialset': set([S(1), cos(2*x), sin(2*x)])} # converted from exp(2*x)*sin(x)**2 assert _undetermined_coefficients_match( exp(2*x)*(S(1)/2 + cos(2*x)/2), x ) == { 'test': True, 'trialset': set([exp(2*x)*sin(2*x), cos(2*x)*exp(2*x), exp(2*x)])} assert _undetermined_coefficients_match(2*x + sin(x) + cos(x), x) == \ {'test': True, 'trialset': set([S(1), x, cos(x), sin(x)])} # converted from sin(2*x)*sin(x) assert _undetermined_coefficients_match(cos(x)/2 - cos(3*x)/2, x) == \ {'test': True, 'trialset': set([cos(x), cos(3*x), sin(x), sin(3*x)])} assert _undetermined_coefficients_match(cos(x**2), x) == {'test': False} assert _undetermined_coefficients_match(2**(x**2), x) == {'test': False} @slow def test_nth_linear_constant_coeff_undetermined_coefficients(): hint = 'nth_linear_constant_coeff_undetermined_coefficients' g = exp(-x) f2 = f(x).diff(x, 2) c = 3*f(x).diff(x, 3) + 5*f2 + f(x).diff(x) - f(x) - x eq1 = c - x*g eq2 = c - g # 3-27 below are from Ordinary Differential Equations, # Tenenbaum and Pollard, pg. 231 eq3 = f2 + 3*f(x).diff(x) + 2*f(x) - 4 eq4 = f2 + 3*f(x).diff(x) + 2*f(x) - 12*exp(x) eq5 = f2 + 3*f(x).diff(x) + 2*f(x) - exp(I*x) eq6 = f2 + 3*f(x).diff(x) + 2*f(x) - sin(x) eq7 = f2 + 3*f(x).diff(x) + 2*f(x) - cos(x) eq8 = f2 + 3*f(x).diff(x) + 2*f(x) - (8 + 6*exp(x) + 2*sin(x)) eq9 = f2 + f(x).diff(x) + f(x) - x**2 eq10 = f2 - 2*f(x).diff(x) - 8*f(x) - 9*x*exp(x) - 10*exp(-x) eq11 = f2 - 3*f(x).diff(x) - 2*exp(2*x)*sin(x) eq12 = f(x).diff(x, 4) - 2*f2 + f(x) - x + sin(x) eq13 = f2 + f(x).diff(x) - x**2 - 2*x eq14 = f2 + f(x).diff(x) - x - sin(2*x) eq15 = f2 + f(x) - 4*x*sin(x) eq16 = f2 + 4*f(x) - x*sin(2*x) eq17 = f2 + 2*f(x).diff(x) + f(x) - x**2*exp(-x) eq18 = f(x).diff(x, 3) + 3*f2 + 3*f(x).diff(x) + f(x) - 2*exp(-x) + \ x**2*exp(-x) eq19 = f2 + 3*f(x).diff(x) + 2*f(x) - exp(-2*x) - x**2 eq20 = f2 - 3*f(x).diff(x) + 2*f(x) - x*exp(-x) eq21 = f2 + f(x).diff(x) - 6*f(x) - x - exp(2*x) eq22 = f2 + f(x) - sin(x) - exp(-x) eq23 = f(x).diff(x, 3) - 3*f2 + 3*f(x).diff(x) - f(x) - exp(x) # sin(x)**2 eq24 = f2 + f(x) - S(1)/2 - cos(2*x)/2 # exp(2*x)*sin(x)**2 eq25 = f(x).diff(x, 3) - f(x).diff(x) - exp(2*x)*(S(1)/2 - cos(2*x)/2) eq26 = (f(x).diff(x, 5) + 2*f(x).diff(x, 3) + f(x).diff(x) - 2*x - sin(x) - cos(x)) # sin(2*x)*sin(x), skip 3127 for now, match bug eq27 = f2 + f(x) - cos(x)/2 + cos(3*x)/2 eq28 = f(x).diff(x) - 1 sol1 = Eq(f(x), -1 - x + (C1 + C2*x - 3*x**2/32 - x**3/24)*exp(-x) + C3*exp(x/3)) sol2 = Eq(f(x), -1 - x + (C1 + C2*x - x**2/8)*exp(-x) + C3*exp(x/3)) sol3 = Eq(f(x), 2 + C1*exp(-x) + C2*exp(-2*x)) sol4 = Eq(f(x), 2*exp(x) + C1*exp(-x) + C2*exp(-2*x)) sol5 = Eq(f(x), C1*exp(-2*x) + C2*exp(-x) + exp(I*x)/10 - 3*I*exp(I*x)/10) sol6 = Eq(f(x), -3*cos(x)/10 + sin(x)/10 + C1*exp(-x) + C2*exp(-2*x)) sol7 = Eq(f(x), cos(x)/10 + 3*sin(x)/10 + C1*exp(-x) + C2*exp(-2*x)) sol8 = Eq(f(x), 4 - 3*cos(x)/5 + sin(x)/5 + exp(x) + C1*exp(-x) + C2*exp(-2*x)) sol9 = Eq(f(x), -2*x + x**2 + (C1*sin(x*sqrt(3)/2) + C2*cos(x*sqrt(3)/2))*exp(-x/2)) sol10 = Eq(f(x), -x*exp(x) - 2*exp(-x) + C1*exp(-2*x) + C2*exp(4*x)) sol11 = Eq(f(x), C1 + C2*exp(3*x) + (-3*sin(x) - cos(x))*exp(2*x)/5) sol12 = Eq(f(x), x - sin(x)/4 + (C1 + C2*x)*exp(-x) + (C3 + C4*x)*exp(x)) sol13 = Eq(f(x), C1 + x**3/3 + C2*exp(-x)) sol14 = Eq(f(x), C1 - x - sin(2*x)/5 - cos(2*x)/10 + x**2/2 + C2*exp(-x)) sol15 = Eq(f(x), (C1 + x)*sin(x) + (C2 - x**2)*cos(x)) sol16 = Eq(f(x), (C1 + x/16)*sin(2*x) + (C2 - x**2/8)*cos(2*x)) sol17 = Eq(f(x), (C1 + C2*x + x**4/12)*exp(-x)) sol18 = Eq(f(x), (C1 + C2*x + C3*x**2 - x**5/60 + x**3/3)*exp(-x)) sol19 = Eq(f(x), S(7)/4 - 3*x/2 + x**2/2 + C1*exp(-x) + (C2 - x)*exp(-2*x)) sol20 = Eq(f(x), C1*exp(x) + C2*exp(2*x) + (6*x + 5)*exp(-x)/36) sol21 = Eq(f(x), -S(1)/36 - x/6 + C1*exp(-3*x) + (C2 + x/5)*exp(2*x)) sol22 = Eq(f(x), C1*sin(x) + (C2 - x/2)*cos(x) + exp(-x)/2) sol23 = Eq(f(x), (C1 + C2*x + C3*x**2 + x**3/6)*exp(x)) sol24 = Eq(f(x), S(1)/2 - cos(2*x)/6 + C1*sin(x) + C2*cos(x)) sol25 = Eq(f(x), C1 + C2*exp(-x) + C3*exp(x) + (-21*sin(2*x) + 27*cos(2*x) + 130)*exp(2*x)/1560) sol26 = Eq(f(x), C1 + (C2 + C3*x - x**2/8)*sin(x) + (C4 + C5*x + x**2/8)*cos(x) + x**2) sol27 = Eq(f(x), cos(3*x)/16 + C1*cos(x) + (C2 + x/4)*sin(x)) sol28 = Eq(f(x), C1 + x) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) sol6s = constant_renumber(sol6) sol7s = constant_renumber(sol7) sol8s = constant_renumber(sol8) sol9s = constant_renumber(sol9) sol10s = constant_renumber(sol10) sol11s = constant_renumber(sol11) sol12s = constant_renumber(sol12) sol13s = constant_renumber(sol13) sol14s = constant_renumber(sol14) sol15s = constant_renumber(sol15) sol16s = constant_renumber(sol16) sol17s = constant_renumber(sol17) sol18s = constant_renumber(sol18) sol19s = constant_renumber(sol19) sol20s = constant_renumber(sol20) sol21s = constant_renumber(sol21) sol22s = constant_renumber(sol22) sol23s = constant_renumber(sol23) sol24s = constant_renumber(sol24) sol25s = constant_renumber(sol25) sol26s = constant_renumber(sol26) sol27s = constant_renumber(sol27) assert dsolve(eq1, hint=hint) in (sol1, sol1s) assert dsolve(eq2, hint=hint) in (sol2, sol2s) assert dsolve(eq3, hint=hint) in (sol3, sol3s) assert dsolve(eq4, hint=hint) in (sol4, sol4s) assert dsolve(eq5, hint=hint) in (sol5, sol5s) assert dsolve(eq6, hint=hint) in (sol6, sol6s) assert dsolve(eq7, hint=hint) in (sol7, sol7s) assert dsolve(eq8, hint=hint) in (sol8, sol8s) assert dsolve(eq9, hint=hint) in (sol9, sol9s) assert dsolve(eq10, hint=hint) in (sol10, sol10s) assert dsolve(eq11, hint=hint) in (sol11, sol11s) assert dsolve(eq12, hint=hint) in (sol12, sol12s) assert dsolve(eq13, hint=hint) in (sol13, sol13s) assert dsolve(eq14, hint=hint) in (sol14, sol14s) assert dsolve(eq15, hint=hint) in (sol15, sol15s) assert dsolve(eq16, hint=hint) in (sol16, sol16s) assert dsolve(eq17, hint=hint) in (sol17, sol17s) assert dsolve(eq18, hint=hint) in (sol18, sol18s) assert dsolve(eq19, hint=hint) in (sol19, sol19s) assert dsolve(eq20, hint=hint) in (sol20, sol20s) assert dsolve(eq21, hint=hint) in (sol21, sol21s) assert dsolve(eq22, hint=hint) in (sol22, sol22s) assert dsolve(eq23, hint=hint) in (sol23, sol23s) assert dsolve(eq24, hint=hint) in (sol24, sol24s) assert dsolve(eq25, hint=hint) in (sol25, sol25s) assert dsolve(eq26, hint=hint) in (sol26, sol26s) assert dsolve(eq27, hint=hint) in (sol27, sol27s) assert dsolve(eq28, hint=hint) == sol28 assert checkodesol(eq1, sol1, order=3, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=3, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=2, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=2, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=2, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=2, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=2, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=2, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=2, solve_for_func=False)[0] assert checkodesol(eq11, sol11, order=2, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=4, solve_for_func=False)[0] assert checkodesol(eq13, sol13, order=2, solve_for_func=False)[0] assert checkodesol(eq14, sol14, order=2, solve_for_func=False)[0] assert checkodesol(eq15, sol15, order=2, solve_for_func=False)[0] assert checkodesol(eq16, sol16, order=2, solve_for_func=False)[0] assert checkodesol(eq17, sol17, order=2, solve_for_func=False)[0] assert checkodesol(eq18, sol18, order=3, solve_for_func=False)[0] assert checkodesol(eq19, sol19, order=2, solve_for_func=False)[0] assert checkodesol(eq20, sol20, order=2, solve_for_func=False)[0] assert checkodesol(eq21, sol21, order=2, solve_for_func=False)[0] assert checkodesol(eq22, sol22, order=2, solve_for_func=False)[0] assert checkodesol(eq23, sol23, order=3, solve_for_func=False)[0] assert checkodesol(eq24, sol24, order=2, solve_for_func=False)[0] assert checkodesol(eq25, sol25, order=3, solve_for_func=False)[0] assert checkodesol(eq26, sol26, order=5, solve_for_func=False)[0] assert checkodesol(eq27, sol27, order=2, solve_for_func=False)[0] assert checkodesol(eq28, sol28, order=1, solve_for_func=False)[0] def test_issue_5787(): # This test case is to show the classification of imaginary constants under # nth_linear_constant_coeff_undetermined_coefficients eq = Eq(diff(f(x), x), I*f(x) + S(1)/2 - I) our_hint = 'nth_linear_constant_coeff_undetermined_coefficients' assert our_hint in classify_ode(eq) @XFAIL def test_nth_linear_constant_coeff_undetermined_coefficients_imaginary_exp(): # Equivalent to eq26 in # test_nth_linear_constant_coeff_undetermined_coefficients above. # This fails because the algorithm for undetermined coefficients # doesn't know to multiply exp(I*x) by sufficient x because it is linearly # dependent on sin(x) and cos(x). hint = 'nth_linear_constant_coeff_undetermined_coefficients' eq26a = f(x).diff(x, 5) + 2*f(x).diff(x, 3) + f(x).diff(x) - 2*x - exp(I*x) sol26 = Eq(f(x), C1 + (C2 + C3*x - x**2/8)*sin(x) + (C4 + C5*x + x**2/8)*cos(x) + x**2) assert dsolve(eq26a, hint=hint) == sol26 assert checkodesol(eq26a, sol26, order=5, solve_for_func=False)[0] @slow def test_nth_linear_constant_coeff_variation_of_parameters(): hint = 'nth_linear_constant_coeff_variation_of_parameters' g = exp(-x) f2 = f(x).diff(x, 2) c = 3*f(x).diff(x, 3) + 5*f2 + f(x).diff(x) - f(x) - x eq1 = c - x*g eq2 = c - g eq3 = f(x).diff(x) - 1 eq4 = f2 + 3*f(x).diff(x) + 2*f(x) - 4 eq5 = f2 + 3*f(x).diff(x) + 2*f(x) - 12*exp(x) eq6 = f2 - 2*f(x).diff(x) - 8*f(x) - 9*x*exp(x) - 10*exp(-x) eq7 = f2 + 2*f(x).diff(x) + f(x) - x**2*exp(-x) eq8 = f2 - 3*f(x).diff(x) + 2*f(x) - x*exp(-x) eq9 = f(x).diff(x, 3) - 3*f2 + 3*f(x).diff(x) - f(x) - exp(x) eq10 = f2 + 2*f(x).diff(x) + f(x) - exp(-x)/x eq11 = f2 + f(x) - 1/sin(x)*1/cos(x) eq12 = f(x).diff(x, 4) - 1/x sol1 = Eq(f(x), -1 - x + (C1 + C2*x - 3*x**2/32 - x**3/24)*exp(-x) + C3*exp(x/3)) sol2 = Eq(f(x), -1 - x + (C1 + C2*x - x**2/8)*exp(-x) + C3*exp(x/3)) sol3 = Eq(f(x), C1 + x) sol4 = Eq(f(x), 2 + C1*exp(-x) + C2*exp(-2*x)) sol5 = Eq(f(x), 2*exp(x) + C1*exp(-x) + C2*exp(-2*x)) sol6 = Eq(f(x), -x*exp(x) - 2*exp(-x) + C1*exp(-2*x) + C2*exp(4*x)) sol7 = Eq(f(x), (C1 + C2*x + x**4/12)*exp(-x)) sol8 = Eq(f(x), C1*exp(x) + C2*exp(2*x) + (6*x + 5)*exp(-x)/36) sol9 = Eq(f(x), (C1 + C2*x + C3*x**2 + x**3/6)*exp(x)) sol10 = Eq(f(x), (C1 + x*(C2 + log(x)))*exp(-x)) sol11 = Eq(f(x), cos(x)*(C2 - Integral(1/cos(x), x)) + sin(x)*(C1 + Integral(1/sin(x), x))) sol12 = Eq(f(x), C1 + C2*x + x**3*(C3 + log(x)/6) + C4*x**2) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) sol6s = constant_renumber(sol6) sol7s = constant_renumber(sol7) sol8s = constant_renumber(sol8) sol9s = constant_renumber(sol9) sol10s = constant_renumber(sol10) sol11s = constant_renumber(sol11) sol12s = constant_renumber(sol12) assert dsolve(eq1, hint=hint) in (sol1, sol1s) assert dsolve(eq2, hint=hint) in (sol2, sol2s) assert dsolve(eq3, hint=hint) in (sol3, sol3s) assert dsolve(eq4, hint=hint) in (sol4, sol4s) assert dsolve(eq5, hint=hint) in (sol5, sol5s) assert dsolve(eq6, hint=hint) in (sol6, sol6s) assert dsolve(eq7, hint=hint) in (sol7, sol7s) assert dsolve(eq8, hint=hint) in (sol8, sol8s) assert dsolve(eq9, hint=hint) in (sol9, sol9s) assert dsolve(eq10, hint=hint) in (sol10, sol10s) assert dsolve(eq11, hint=hint + '_Integral') in (sol11, sol11s) assert dsolve(eq12, hint=hint) in (sol12, sol12s) assert checkodesol(eq1, sol1, order=3, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=3, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=1, solve_for_func=False)[0] assert checkodesol(eq4, sol4, order=2, solve_for_func=False)[0] assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] assert checkodesol(eq6, sol6, order=2, solve_for_func=False)[0] assert checkodesol(eq7, sol7, order=2, solve_for_func=False)[0] assert checkodesol(eq8, sol8, order=2, solve_for_func=False)[0] assert checkodesol(eq9, sol9, order=3, solve_for_func=False)[0] assert checkodesol(eq10, sol10, order=2, solve_for_func=False)[0] assert checkodesol(eq12, sol12, order=4, solve_for_func=False)[0] @slow def test_nth_linear_constant_coeff_variation_of_parameters_simplify_False(): # solve_variation_of_parameters shouldn't attempt to simplify the # Wronskian if simplify=False. If wronskian() ever gets good enough # to simplify the result itself, this test might fail. our_hint = 'nth_linear_constant_coeff_variation_of_parameters_Integral' eq = f(x).diff(x, 5) + 2*f(x).diff(x, 3) + f(x).diff(x) - 2*x - exp(I*x) sol_simp = dsolve(eq, f(x), hint=our_hint, simplify=True) sol_nsimp = dsolve(eq, f(x), hint=our_hint, simplify=False) assert sol_simp != sol_nsimp assert checkodesol(eq, sol_simp, order=5, solve_for_func=False)[0] assert checkodesol(eq, sol_nsimp, order=5, solve_for_func=False)[0] def test_Liouville_ODE(): hint = 'Liouville' # The first part here used to be test_ODE_1() from test_solvers.py eq1 = diff(f(x), x)/x + diff(f(x), x, x)/2 - diff(f(x), x)**2/2 eq1a = diff(x*exp(-f(x)), x, x) # compare to test_unexpanded_Liouville_ODE() below eq2 = (eq1*exp(-f(x))/exp(f(x))).expand() eq3 = diff(f(x), x, x) + 1/f(x)*(diff(f(x), x))**2 + 1/x*diff(f(x), x) eq4 = x*diff(f(x), x, x) + x/f(x)*diff(f(x), x)**2 + x*diff(f(x), x) eq5 = Eq((x*exp(f(x))).diff(x, x), 0) sol1 = Eq(f(x), log(x/(C1 + C2*x))) sol1a = Eq(C1 + C2/x - exp(-f(x)), 0) sol2 = sol1 sol3 = set( [Eq(f(x), -sqrt(C1 + C2*log(x))), Eq(f(x), sqrt(C1 + C2*log(x)))]) sol4 = set([Eq(f(x), sqrt(C1 + C2*exp(x))*exp(-x/2)), Eq(f(x), -sqrt(C1 + C2*exp(x))*exp(-x/2))]) sol5 = Eq(f(x), log(C1 + C2/x)) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) sol3s = constant_renumber(sol3) sol4s = constant_renumber(sol4) sol5s = constant_renumber(sol5) assert dsolve(eq1, hint=hint) in (sol1, sol1s) assert dsolve(eq1a, hint=hint) in (sol1, sol1s) assert dsolve(eq2, hint=hint) in (sol2, sol2s) assert set(dsolve(eq3, hint=hint)) in (sol3, sol3s) assert set(dsolve(eq4, hint=hint)) in (sol4, sol4s) assert dsolve(eq5, hint=hint) in (sol5, sol5s) assert checkodesol(eq1, sol1, order=2, solve_for_func=False)[0] assert checkodesol(eq1a, sol1a, order=2, solve_for_func=False)[0] assert checkodesol(eq2, sol2, order=2, solve_for_func=False)[0] assert checkodesol(eq3, sol3, order=2, solve_for_func=False) == {(True, 0)} assert checkodesol(eq4, sol4, order=2, solve_for_func=False) == {(True, 0)} assert checkodesol(eq5, sol5, order=2, solve_for_func=False)[0] not_Liouville1 = classify_ode(diff(f(x), x)/x + f(x)*diff(f(x), x, x)/2 - diff(f(x), x)**2/2, f(x)) not_Liouville2 = classify_ode(diff(f(x), x)/x + diff(f(x), x, x)/2 - x*diff(f(x), x)**2/2, f(x)) assert hint not in not_Liouville1 assert hint not in not_Liouville2 assert hint + '_Integral' not in not_Liouville1 assert hint + '_Integral' not in not_Liouville2 def test_unexpanded_Liouville_ODE(): # This is the same as eq1 from test_Liouville_ODE() above. eq1 = diff(f(x), x)/x + diff(f(x), x, x)/2 - diff(f(x), x)**2/2 eq2 = eq1*exp(-f(x))/exp(f(x)) sol2 = Eq(f(x), log(x/(C1 + C2*x))) sol2s = constant_renumber(sol2) assert dsolve(eq2) in (sol2, sol2s) assert checkodesol(eq2, sol2, order=2, solve_for_func=False)[0] def test_issue_4785(): from sympy.abc import A eq = x + A*(x + diff(f(x), x) + f(x)) + diff(f(x), x) + f(x) + 2 assert classify_ode(eq, f(x)) == ('1st_linear', 'almost_linear', '1st_power_series', 'lie_group', 'nth_linear_constant_coeff_undetermined_coefficients', 'nth_linear_constant_coeff_variation_of_parameters', '1st_linear_Integral', 'almost_linear_Integral', 'nth_linear_constant_coeff_variation_of_parameters_Integral') # issue 4864 eq = (x**2 + f(x)**2)*f(x).diff(x) - 2*x*f(x) assert classify_ode(eq, f(x)) == ('1st_exact', '1st_homogeneous_coeff_best', '1st_homogeneous_coeff_subs_indep_div_dep', '1st_homogeneous_coeff_subs_dep_div_indep', '1st_power_series', 'lie_group', '1st_exact_Integral', '1st_homogeneous_coeff_subs_indep_div_dep_Integral', '1st_homogeneous_coeff_subs_dep_div_indep_Integral') def test_issue_4825(): raises(ValueError, lambda: dsolve(f(x, y).diff(x) - y*f(x, y), f(x))) assert classify_ode(f(x, y).diff(x) - y*f(x, y), f(x), dict=True) == \ {'default': None, 'order': 0} # See also issue 3793, test Z13. raises(ValueError, lambda: dsolve(f(x).diff(x), f(y))) assert classify_ode(f(x).diff(x), f(y), dict=True) == \ {'default': None, 'order': 0} def test_constant_renumber_order_issue_5308(): from sympy.utilities.iterables import variations eq = f(x).diff(x) - y - x assert constant_renumber(C1*x + C2*y) == \ constant_renumber(C1*y + C2*x) == \ C1*x + C2*y e = C1*(C2 + x)*(C3 + y) for a, b, c in variations([C1, C2, C3], 3): assert constant_renumber(a*(b + x)*(c + y)) == e def test_issue_5770(): k = Symbol("k", real=True) t = Symbol('t') w = Function('w') sol = dsolve(w(t).diff(t, 6) - k**6*w(t), w(t)) assert len([s for s in sol.free_symbols if s.name.startswith('C')]) == 6 assert constantsimp((C1*cos(x) + C2*cos(x))*exp(x), set([C1, C2])) == \ C1*cos(x)*exp(x) assert constantsimp(C1*cos(x) + C2*cos(x) + C3*sin(x), set([C1, C2, C3])) == \ C1*cos(x) + C3*sin(x) assert constantsimp(exp(C1 + x), set([C1])) == C1*exp(x) assert constantsimp(x + C1 + y, set([C1, y])) == C1 + x assert constantsimp(x + C1 + Integral(x, (x, 1, 2)), set([C1])) == C1 + x def test_issue_5112_5430(): assert homogeneous_order(-log(x) + acosh(x), x) is None assert homogeneous_order(y - log(x), x, y) is None def test_nth_order_linear_euler_eq_homogeneous(): x, t, a, b, c = symbols('x t a b c') y = Function('y') our_hint = "nth_linear_euler_eq_homogeneous" eq = diff(f(t), t, 4)*t**4 - 13*diff(f(t), t, 2)*t**2 + 36*f(t) assert our_hint in classify_ode(eq) eq = a*y(t) + b*t*diff(y(t), t) + c*t**2*diff(y(t), t, 2) assert our_hint in classify_ode(eq) eq = Eq(-3*diff(f(x), x)*x + 2*x**2*diff(f(x), x, x), 0) sol = C1 + C2*x**Rational(5, 2) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(3*f(x) - 5*diff(f(x), x)*x + 2*x**2*diff(f(x), x, x), 0) sol = C1*sqrt(x) + C2*x**3 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(4*f(x) + 5*diff(f(x), x)*x + x**2*diff(f(x), x, x), 0) sol = (C1 + C2*log(x))/x**2 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(6*f(x) - 6*diff(f(x), x)*x + 1*x**2*diff(f(x), x, x) + x**3*diff(f(x), x, x, x), 0) sol = dsolve(eq, f(x), hint=our_hint) sol = C1/x**2 + C2*x + C3*x**3 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(-125*f(x) + 61*diff(f(x), x)*x - 12*x**2*diff(f(x), x, x) + x**3*diff(f(x), x, x, x), 0) sol = x**5*(C1 + C2*log(x) + C3*log(x)**2) sols = [sol, constant_renumber(sol)] sols += [sols[-1].expand()] assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in sols assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = t**2*diff(y(t), t, 2) + t*diff(y(t), t) - 9*y(t) sol = C1*t**3 + C2*t**-3 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, y(t), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = sin(x)*x**2*f(x).diff(x, 2) + sin(x)*x*f(x).diff(x) + sin(x)*f(x) sol = C1*sin(log(x)) + C2*cos(log(x)) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] def test_nth_order_linear_euler_eq_nonhomogeneous_undetermined_coefficients(): x, t = symbols('x t') a, b, c, d = symbols('a b c d', integer=True) our_hint = "nth_linear_euler_eq_nonhomogeneous_undetermined_coefficients" eq = x**4*diff(f(x), x, 4) - 13*x**2*diff(f(x), x, 2) + 36*f(x) + x assert our_hint in classify_ode(eq, f(x)) eq = a*x**2*diff(f(x), x, 2) + b*x*diff(f(x), x) + c*f(x) + d*log(x) assert our_hint in classify_ode(eq, f(x)) eq = Eq(x**2*diff(f(x), x, x) + x*diff(f(x), x), 1) sol = C1 + C2*log(x) + log(x)**2/2 sols = constant_renumber(sol) assert our_hint in classify_ode(eq, f(x)) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x**2*diff(f(x), x, x) - 2*x*diff(f(x), x) + 2*f(x), x**3) sol = x*(C1 + C2*x + Rational(1, 2)*x**2) sols = constant_renumber(sol) assert our_hint in classify_ode(eq, f(x)) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x**2*diff(f(x), x, x) - x*diff(f(x), x) - 3*f(x), log(x)/x) sol = C1/x + C2*x**3 - Rational(1, 16)*log(x)/x - Rational(1, 8)*log(x)**2/x sols = constant_renumber(sol) assert our_hint in classify_ode(eq, f(x)) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x**2*diff(f(x), x, x) + 3*x*diff(f(x), x) - 8*f(x), log(x)**3 - log(x)) sol = C1/x**4 + C2*x**2 - Rational(1,8)*log(x)**3 - Rational(3,32)*log(x)**2 - Rational(1,64)*log(x) - Rational(7, 256) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x**3*diff(f(x), x, x, x) - 3*x**2*diff(f(x), x, x) + 6*x*diff(f(x), x) - 6*f(x), log(x)) sol = C1*x + C2*x**2 + C3*x**3 - Rational(1, 6)*log(x) - Rational(11, 36) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] def test_nth_order_linear_euler_eq_nonhomogeneous_variation_of_parameters(): x, t = symbols('x, t') a, b, c, d = symbols('a, b, c, d', integer=True) our_hint = "nth_linear_euler_eq_nonhomogeneous_variation_of_parameters" eq = Eq(x**2*diff(f(x),x,2) - 8*x*diff(f(x),x) + 12*f(x), x**2) assert our_hint in classify_ode(eq, f(x)) eq = Eq(a*x**3*diff(f(x),x,3) + b*x**2*diff(f(x),x,2) + c*x*diff(f(x),x) + d*f(x), x*log(x)) assert our_hint in classify_ode(eq, f(x)) eq = Eq(x**2*Derivative(f(x), x, x) - 2*x*Derivative(f(x), x) + 2*f(x), x**4) sol = C1*x + C2*x**2 + x**4/6 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(3*x**2*diff(f(x), x, x) + 6*x*diff(f(x), x) - 6*f(x), x**3*exp(x)) sol = C1/x**2 + C2*x + x*exp(x)/3 - 4*exp(x)/3 + 8*exp(x)/(3*x) - 8*exp(x)/(3*x**2) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = Eq(x**2*Derivative(f(x), x, x) - 2*x*Derivative(f(x), x) + 2*f(x), x**4*exp(x)) sol = C1*x + C2*x**2 + x**2*exp(x) - 2*x*exp(x) sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs.expand() in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = x**2*Derivative(f(x), x, x) - 2*x*Derivative(f(x), x) + 2*f(x) - log(x) sol = C1*x + C2*x**2 + log(x)/2 + S(3)/4 sols = constant_renumber(sol) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint).rhs in (sol, sols) assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] eq = -exp(x) + (x*Derivative(f(x), (x, 2)) + Derivative(f(x), x))/x sol = Eq(f(x), C1 + C2*log(x) + exp(x) - Ei(x)) assert our_hint in classify_ode(eq) assert dsolve(eq, f(x), hint=our_hint) == sol assert checkodesol(eq, sol, order=2, solve_for_func=False)[0] def test_issue_5095(): f = Function('f') raises(ValueError, lambda: dsolve(f(x).diff(x)**2, f(x), 'separable')) raises(ValueError, lambda: dsolve(f(x).diff(x)**2, f(x), 'fdsjf')) def test_almost_linear(): from sympy import Ei A = Symbol('A', positive=True) our_hint = 'almost_linear' f = Function('f') d = f(x).diff(x) eq = x**2*f(x)**2*d + f(x)**3 + 1 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol[0].rhs == (C1*exp(3/x) - 1)**(S(1)/3) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = x*f(x)*d + 2*x*f(x)**2 + 1 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol[0].rhs == -sqrt(C1 - 2*Ei(4*x))*exp(-2*x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = x*d + x*f(x) + 1 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol.rhs == (C1 - Ei(x))*exp(-x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] assert our_hint in classify_ode(eq, f(x)) eq = x*exp(f(x))*d + exp(f(x)) + 3*x sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol.rhs == log(C1/x - 3*x/2) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = x + A*(x + diff(f(x), x) + f(x)) + diff(f(x), x) + f(x) + 2 sol = dsolve(eq, f(x), hint = 'almost_linear') assert sol.rhs == (C1 + Piecewise( (x, Eq(A + 1, 0)), ((-A*x + A - x - 1)*exp(x)/(A + 1), True)))*exp(-x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_exact_enhancement(): f = Function('f')(x) df = Derivative(f, x) eq = f/x**2 + ((f*x - 1)/x)*df sol = [Eq(f, (i*sqrt(C1*x**2 + 1) + 1)/x) for i in (-1, 1)] assert set(dsolve(eq, f)) == set(sol) assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0), (True, 0)] eq = (x*f - 1) + df*(x**2 - x*f) sol = [Eq(f, x - sqrt(C1 + x**2 - 2*log(x))), Eq(f, x + sqrt(C1 + x**2 - 2*log(x)))] assert set(dsolve(eq, f)) == set(sol) assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0), (True, 0)] eq = (x + 2)*sin(f) + df*x*cos(f) sol = [Eq(f, -asin(C1*exp(-x)/x**2) + pi), Eq(f, asin(C1*exp(-x)/x**2))] assert set(dsolve(eq, f)) == set(sol) assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0), (True, 0)] @slow def test_separable_reduced(): f = Function('f') x = Symbol('x') df = f(x).diff(x) eq = (x / f(x))*df + tan(x**2*f(x) / (x**2*f(x) - 1)) assert classify_ode(eq) == ('separable_reduced', 'lie_group', 'separable_reduced_Integral') eq = x* df + f(x)* (1 / (x**2*f(x) - 1)) assert classify_ode(eq) == ('separable_reduced', 'lie_group', 'separable_reduced_Integral') sol = dsolve(eq, hint = 'separable_reduced', simplify=False) assert sol.lhs == log(x**2*f(x))/3 + log(x**2*f(x) - S(3)/2)/6 assert sol.rhs == C1 + log(x) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = f(x).diff(x) + (f(x) / (x**4*f(x) - x)) assert classify_ode(eq) == ('separable_reduced', 'lie_group', 'separable_reduced_Integral') sol = dsolve(eq, hint = 'separable_reduced') # FIXME: This one hangs #assert checkodesol(eq, sol, order=1, solve_for_func=False) == [(True, 0)] * 4 assert len(sol) == 4 eq = x*df + f(x)*(x**2*f(x)) sol = dsolve(eq, hint = 'separable_reduced', simplify=False) assert sol == Eq(log(x**2*f(x))/2 - log(x**2*f(x) - 2)/2, C1 + log(x)) assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_homogeneous_function(): f = Function('f') eq1 = tan(x + f(x)) eq2 = sin((3*x)/(4*f(x))) eq3 = cos(3*x/4*f(x)) eq4 = log((3*x + 4*f(x))/(5*f(x) + 7*x)) eq5 = exp((2*x**2)/(3*f(x)**2)) eq6 = log((3*x + 4*f(x))/(5*f(x) + 7*x) + exp((2*x**2)/(3*f(x)**2))) eq7 = sin((3*x)/(5*f(x) + x**2)) assert homogeneous_order(eq1, x, f(x)) == None assert homogeneous_order(eq2, x, f(x)) == 0 assert homogeneous_order(eq3, x, f(x)) == None assert homogeneous_order(eq4, x, f(x)) == 0 assert homogeneous_order(eq5, x, f(x)) == 0 assert homogeneous_order(eq6, x, f(x)) == 0 assert homogeneous_order(eq7, x, f(x)) == None def test_linear_coeff_match(): from sympy.solvers.ode import _linear_coeff_match n, d = z*(2*x + 3*f(x) + 5), z*(7*x + 9*f(x) + 11) rat = n/d eq1 = sin(rat) + cos(rat.expand()) eq2 = rat eq3 = log(sin(rat)) ans = (4, -S(13)/3) assert _linear_coeff_match(eq1, f(x)) == ans assert _linear_coeff_match(eq2, f(x)) == ans assert _linear_coeff_match(eq3, f(x)) == ans # no c eq4 = (3*x)/f(x) # not x and f(x) eq5 = (3*x + 2)/x # denom will be zero eq6 = (3*x + 2*f(x) + 1)/(3*x + 2*f(x) + 5) # not rational coefficient eq7 = (3*x + 2*f(x) + sqrt(2))/(3*x + 2*f(x) + 5) assert _linear_coeff_match(eq4, f(x)) is None assert _linear_coeff_match(eq5, f(x)) is None assert _linear_coeff_match(eq6, f(x)) is None assert _linear_coeff_match(eq7, f(x)) is None def test_linear_coefficients(): f = Function('f') sol = Eq(f(x), C1/(x**2 + 6*x + 9) - S(3)/2) eq = f(x).diff(x) + (3 + 2*f(x))/(x + 3) assert dsolve(eq, hint='linear_coefficients') == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_constantsimp_take_problem(): c = exp(C1) + 2 assert len(Poly(constantsimp(exp(C1) + c + c*x, [C1])).gens) == 2 def test_issue_6879(): f = Function('f') eq = Eq(Derivative(f(x), x, 2) - 2*Derivative(f(x), x) + f(x), sin(x)) sol = (C1 + C2*x)*exp(x) + cos(x)/2 assert dsolve(eq).rhs == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_issue_6989(): f = Function('f') k = Symbol('k') eq = f(x).diff(x) - x*exp(-k*x) sol = Eq(f(x), C1 + Piecewise( ((-k*x - 1)*exp(-k*x)/k**2, Ne(k**2, 0)), (x**2/2, True) )) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] eq = -f(x).diff(x) + x*exp(-k*x) sol = Eq(f(x), C1 + Piecewise( ((-k*x - 1)*exp(-k*x)/k**2, Ne(k**2, 0)), (+x**2/2, True) )) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False)[0] def test_heuristic1(): y, a, b, c, a4, a3, a2, a1, a0 = symbols("y a b c a4 a3 a2 a1 a0") y = Symbol('y') f = Function('f') xi = Function('xi') eta = Function('eta') df = f(x).diff(x) eq = Eq(df, x**2*f(x)) eq1 = f(x).diff(x) + a*f(x) - c*exp(b*x) eq2 = f(x).diff(x) + 2*x*f(x) - x*exp(-x**2) eq3 = (1 + 2*x)*df + 2 - 4*exp(-f(x)) eq4 = f(x).diff(x) - (a4*x**4 + a3*x**3 + a2*x**2 + a1*x + a0)**(S(-1)/2) eq5 = x**2*df - f(x) + x**2*exp(x - (1/x)) eqlist = [eq, eq1, eq2, eq3, eq4, eq5] i = infinitesimals(eq, hint='abaco1_simple') assert i == [{eta(x, f(x)): exp(x**3/3), xi(x, f(x)): 0}, {eta(x, f(x)): f(x), xi(x, f(x)): 0}, {eta(x, f(x)): 0, xi(x, f(x)): x**(-2)}] i1 = infinitesimals(eq1, hint='abaco1_simple') assert i1 == [{eta(x, f(x)): exp(-a*x), xi(x, f(x)): 0}] i2 = infinitesimals(eq2, hint='abaco1_simple') assert i2 == [{eta(x, f(x)): exp(-x**2), xi(x, f(x)): 0}] i3 = infinitesimals(eq3, hint='abaco1_simple') assert i3 == [{eta(x, f(x)): 0, xi(x, f(x)): 2*x + 1}, {eta(x, f(x)): 0, xi(x, f(x)): 1/(exp(f(x)) - 2)}] i4 = infinitesimals(eq4, hint='abaco1_simple') assert i4 == [{eta(x, f(x)): 1, xi(x, f(x)): 0}, {eta(x, f(x)): 0, xi(x, f(x)): sqrt(a0 + a1*x + a2*x**2 + a3*x**3 + a4*x**4)}] i5 = infinitesimals(eq5, hint='abaco1_simple') assert i5 == [{xi(x, f(x)): 0, eta(x, f(x)): exp(-1/x)}] ilist = [i, i1, i2, i3, i4, i5] for eq, i in (zip(eqlist, ilist)): check = checkinfsol(eq, i) assert check[0] def test_issue_6247(): eq = x**2*f(x)**2 + x*Derivative(f(x), x) sol = Eq(f(x), 2*C1/(C1*x**2 - 1)) assert dsolve(eq, hint = 'separable_reduced') == sol assert checkodesol(eq, sol, order=1)[0] eq = f(x).diff(x, x) + 4*f(x) sol = Eq(f(x), C1*sin(2*x) + C2*cos(2*x)) assert dsolve(eq) == sol assert checkodesol(eq, sol, order=1)[0] def test_heuristic2(): y = Symbol('y') xi = Function('xi') eta = Function('eta') df = f(x).diff(x) # This ODE can be solved by the Lie Group method, when there are # better assumptions eq = df - (f(x)/x)*(x*log(x**2/f(x)) + 2) i = infinitesimals(eq, hint='abaco1_product') assert i == [{eta(x, f(x)): f(x)*exp(-x), xi(x, f(x)): 0}] assert checkinfsol(eq, i)[0] @slow def test_heuristic3(): y = Symbol('y') xi = Function('xi') eta = Function('eta') a, b = symbols("a b") df = f(x).diff(x) eq = x**2*df + x*f(x) + f(x)**2 + x**2 i = infinitesimals(eq, hint='bivariate') assert i == [{eta(x, f(x)): f(x), xi(x, f(x)): x}] assert checkinfsol(eq, i)[0] eq = x**2*(-f(x)**2 + df)- a*x**2*f(x) + 2 - a*x i = infinitesimals(eq, hint='bivariate') assert checkinfsol(eq, i)[0] def test_heuristic_4(): y, a = symbols("y a") xi = Function('xi') eta = Function('eta') eq = x*(f(x).diff(x)) + 1 - f(x)**2 i = infinitesimals(eq, hint='chi') assert checkinfsol(eq, i)[0] def test_heuristic_function_sum(): xi = Function('xi') eta = Function('eta') eq = f(x).diff(x) - (3*(1 + x**2/f(x)**2)*atan(f(x)/x) + (1 - 2*f(x))/x + (1 - 3*f(x))*(x/f(x)**2)) i = infinitesimals(eq, hint='function_sum') assert i == [{eta(x, f(x)): f(x)**(-2) + x**(-2), xi(x, f(x)): 0}] assert checkinfsol(eq, i)[0] def test_heuristic_abaco2_similar(): xi = Function('xi') eta = Function('eta') F = Function('F') a, b = symbols("a b") eq = f(x).diff(x) - F(a*x + b*f(x)) i = infinitesimals(eq, hint='abaco2_similar') assert i == [{eta(x, f(x)): -a/b, xi(x, f(x)): 1}] assert checkinfsol(eq, i)[0] eq = f(x).diff(x) - (f(x)**2 / (sin(f(x) - x) - x**2 + 2*x*f(x))) i = infinitesimals(eq, hint='abaco2_similar') assert i == [{eta(x, f(x)): f(x)**2, xi(x, f(x)): f(x)**2}] assert checkinfsol(eq, i)[0] def test_heuristic_abaco2_unique_unknown(): xi = Function('xi') eta = Function('eta') F = Function('F') a, b = symbols("a b") x = Symbol("x", positive=True) eq = f(x).diff(x) - x**(a - 1)*(f(x)**(1 - b))*F(x**a/a + f(x)**b/b) i = infinitesimals(eq, hint='abaco2_unique_unknown') assert i == [{eta(x, f(x)): -f(x)*f(x)**(-b), xi(x, f(x)): x*x**(-a)}] assert checkinfsol(eq, i)[0] eq = f(x).diff(x) + tan(F(x**2 + f(x)**2) + atan(x/f(x))) i = infinitesimals(eq, hint='abaco2_unique_unknown') assert i == [{eta(x, f(x)): x, xi(x, f(x)): -f(x)}] assert checkinfsol(eq, i)[0] eq = (x*f(x).diff(x) + f(x) + 2*x)**2 -4*x*f(x) -4*x**2 -4*a i = infinitesimals(eq, hint='abaco2_unique_unknown') assert checkinfsol(eq, i)[0] def test_heuristic_linear(): xi = Function('xi') eta = Function('eta') F = Function('F') a, b, m, n = symbols("a b m n") eq = x**(n*(m + 1) - m)*(f(x).diff(x)) - a*f(x)**n -b*x**(n*(m + 1)) i = infinitesimals(eq, hint='linear') assert checkinfsol(eq, i)[0] @XFAIL def test_kamke(): a, b, alpha, c = symbols("a b alpha c") eq = x**2*(a*f(x)**2+(f(x).diff(x))) + b*x**alpha + c i = infinitesimals(eq, hint='sum_function') assert checkinfsol(eq, i)[0] def test_series(): # FIXME: Maybe there should be a way to check series solutions # checkodesol doesn't work with them. C1 = Symbol("C1") eq = f(x).diff(x) - f(x) assert dsolve(eq, hint='1st_power_series') == Eq(f(x), C1 + C1*x + C1*x**2/2 + C1*x**3/6 + C1*x**4/24 + C1*x**5/120 + O(x**6)) eq = f(x).diff(x) - x*f(x) assert dsolve(eq, hint='1st_power_series') == Eq(f(x), C1*x**4/8 + C1*x**2/2 + C1 + O(x**6)) eq = f(x).diff(x) - sin(x*f(x)) sol = Eq(f(x), (x - 2)**2*(1+ sin(4))*cos(4) + (x - 2)*sin(4) + 2 + O(x**3)) assert dsolve(eq, hint='1st_power_series', ics={f(2): 2}, n=3) == sol @slow def test_lie_group(): C1 = Symbol("C1") x = Symbol("x") # assuming x is real generates an error! a, b, c = symbols("a b c") eq = f(x).diff(x)**2 sol = dsolve(eq, f(x), hint='lie_group') assert checkodesol(eq, sol)[0] eq = Eq(f(x).diff(x), x**2*f(x)) sol = dsolve(eq, f(x), hint='lie_group') assert sol == Eq(f(x), C1*exp(x**3)**(S(1)/3)) assert checkodesol(eq, sol)[0] eq = f(x).diff(x) + a*f(x) - c*exp(b*x) sol = dsolve(eq, f(x), hint='lie_group') assert checkodesol(eq, sol)[0] eq = f(x).diff(x) + 2*x*f(x) - x*exp(-x**2) sol = dsolve(eq, f(x), hint='lie_group') actual_sol = Eq(f(x), (C1 + x**2/2)*exp(-x**2)) errstr = str(eq)+' : '+str(sol)+' == '+str(actual_sol) assert sol == actual_sol, errstr assert checkodesol(eq, sol)[0] eq = (1 + 2*x)*(f(x).diff(x)) + 2 - 4*exp(-f(x)) sol = dsolve(eq, f(x), hint='lie_group') assert sol == Eq(f(x), log(C1/(2*x + 1) + 2)) assert checkodesol(eq, sol)[0] eq = x**2*(f(x).diff(x)) - f(x) + x**2*exp(x - (1/x)) sol = dsolve(eq, f(x), hint='lie_group') assert checkodesol(eq, sol)[0] eq = x**2*f(x)**2 + x*Derivative(f(x), x) sol = dsolve(eq, f(x), hint='lie_group') assert sol == Eq(f(x), 2/(C1 + x**2)) assert checkodesol(eq, sol)[0] @XFAIL def test_lie_group_issue15219(): eqn = exp(f(x).diff(x)-f(x)) assert 'lie_group' not in classify_ode(eqn, f(x)) def test_user_infinitesimals(): x = Symbol("x") # assuming x is real generates an error eq = x*(f(x).diff(x)) + 1 - f(x)**2 sol = Eq(f(x), (C1 + x**2)/(C1 - x**2)) infinitesimals = {'xi':sqrt(f(x) - 1)/sqrt(f(x) + 1), 'eta':0} assert dsolve(eq, hint='lie_group', **infinitesimals) == sol assert checkodesol(eq, sol) == (True, 0) raises(ValueError, lambda: dsolve(eq, hint='lie_group', xi=0, eta=f(x))) def test_issue_7081(): eq = x*(f(x).diff(x)) + 1 - f(x)**2 s = Eq(f(x), -1/(-C1 + x**2)*(C1 + x**2)) assert dsolve(eq) == s assert checkodesol(eq, s) == (True, 0) @slow def test_2nd_power_series_ordinary(): # FIXME: Maybe there should be a way to check series solutions # checkodesol doesn't work with them. C1, C2 = symbols("C1 C2") eq = f(x).diff(x, 2) - x*f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2*(x**3/6 + 1) + C1*x*(x**3/12 + 1) + O(x**6)) assert dsolve(eq, x0=-2) == Eq(f(x), C2*((x + 2)**4/6 + (x + 2)**3/6 - (x + 2)**2 + 1) + C1*(x + (x + 2)**4/12 - (x + 2)**3/3 + S(2)) + O(x**6)) assert dsolve(eq, n=2) == Eq(f(x), C2*x + C1 + O(x**2)) eq = (1 + x**2)*(f(x).diff(x, 2)) + 2*x*(f(x).diff(x)) -2*f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2*(-x**4/3 + x**2 + 1) + C1*x + O(x**6)) eq = f(x).diff(x, 2) + x*(f(x).diff(x)) + f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2*( x**4/8 - x**2/2 + 1) + C1*x*(-x**2/3 + 1) + O(x**6)) eq = f(x).diff(x, 2) + f(x).diff(x) - x*f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq) == Eq(f(x), C2*( -x**4/24 + x**3/6 + 1) + C1*x*(x**3/24 + x**2/6 - x/2 + 1) + O(x**6)) eq = f(x).diff(x, 2) + x*f(x) assert classify_ode(eq) == ('2nd_power_series_ordinary',) assert dsolve(eq, n=7) == Eq(f(x), C2*( x**6/180 - x**3/6 + 1) + C1*x*(-x**3/12 + 1) + O(x**7)) def test_2nd_power_series_regular(): # FIXME: Maybe there should be a way to check series solutions # checkodesol doesn't work with them. C1, C2 = symbols("C1 C2") eq = x**2*(f(x).diff(x, 2)) - 3*x*(f(x).diff(x)) + (4*x + 4)*f(x) assert dsolve(eq) == Eq(f(x), C1*x**2*(-16*x**3/9 + 4*x**2 - 4*x + 1) + O(x**6)) eq = 4*x**2*(f(x).diff(x, 2)) -8*x**2*(f(x).diff(x)) + (4*x**2 + 1)*f(x) assert dsolve(eq) == Eq(f(x), C1*sqrt(x)*( x**4/24 + x**3/6 + x**2/2 + x + 1) + O(x**6)) eq = x**2*(f(x).diff(x, 2)) - x**2*(f(x).diff(x)) + ( x**2 - 2)*f(x) assert dsolve(eq) == Eq(f(x), C1*(-x**6/720 - 3*x**5/80 - x**4/8 + x**2/2 + x/2 + 1)/x + C2*x**2*(-x**3/60 + x**2/20 + x/2 + 1) + O(x**6)) eq = x**2*(f(x).diff(x, 2)) + x*(f(x).diff(x)) + (x**2 - S(1)/4)*f(x) assert dsolve(eq) == Eq(f(x), C1*(x**4/24 - x**2/2 + 1)/sqrt(x) + C2*sqrt(x)*(x**4/120 - x**2/6 + 1) + O(x**6)) eq = x*(f(x).diff(x, 2)) - f(x).diff(x) + 4*x**3*f(x) assert dsolve(eq) == Eq(f(x), C2*(-x**4/2 + 1) + C1*x**2 + O(x**6)) def test_issue_7093(): x = Symbol("x") # assuming x is real leads to an error sol = [Eq(f(x), C1 - 2*x*sqrt(x**3)/5), Eq(f(x), C1 + 2*x*sqrt(x**3)/5)] eq = Derivative(f(x), x)**2 - x**3 assert set(dsolve(eq)) == set(sol) assert checkodesol(eq, sol) == [(True, 0)] * 2 def test_dsolve_linsystem_symbol(): eps = Symbol('epsilon', positive=True) eq1 = (Eq(diff(f(x), x), -eps*g(x)), Eq(diff(g(x), x), eps*f(x))) sol1 = [Eq(f(x), -C1*eps*cos(eps*x) - C2*eps*sin(eps*x)), Eq(g(x), -C1*eps*sin(eps*x) + C2*eps*cos(eps*x))] assert checksysodesol(eq1, sol1) == (True, [0, 0]) def test_C1_function_9239(): t = Symbol('t') C1 = Function('C1') C2 = Function('C2') C3 = Symbol('C3') C4 = Symbol('C4') eq = (Eq(diff(C1(t), t), 9*C2(t)), Eq(diff(C2(t), t), 12*C1(t))) sol = [Eq(C1(t), 9*C3*exp(6*sqrt(3)*t) + 9*C4*exp(-6*sqrt(3)*t)), Eq(C2(t), 6*sqrt(3)*C3*exp(6*sqrt(3)*t) - 6*sqrt(3)*C4*exp(-6*sqrt(3)*t))] assert checksysodesol(eq, sol) == (True, [0, 0]) def test_issue_15056(): t = Symbol('t') C3 = Symbol('C3') assert get_numbered_constants(Symbol('C1') * Function('C2')(t)) == C3 def test_issue_10379(): t,y = symbols('t,y') eq = f(t).diff(t)-(1-51.05*y*f(t)) sol = Eq(f(t), (0.019588638589618*exp(y*(C1 - 51.05*t)) + 0.019588638589618)/y) dsolve_sol = dsolve(eq, rational=False) assert str(dsolve_sol) == str(sol) assert checkodesol(eq, dsolve_sol)[0] def test_issue_10867(): x = Symbol('x') eq = Eq(g(x).diff(x).diff(x), (x-2)**2 + (x-3)**3) sol = Eq(g(x), C1 + C2*x + x**5/20 - 2*x**4/3 + 23*x**3/6 - 23*x**2/2) assert dsolve(eq, g(x)) == sol assert checkodesol(eq, sol, order=2, solve_for_func=False) == (True, 0) def test_issue_11290(): eq = cos(f(x)) - (x*sin(f(x)) - f(x)**2)*f(x).diff(x) sol_1 = dsolve(eq, f(x), simplify=False, hint='1st_exact_Integral') sol_0 = dsolve(eq, f(x), simplify=False, hint='1st_exact') assert sol_1.dummy_eq(Eq(Subs( Integral(u**2 - x*sin(u) - Integral(-sin(u), x), u) + Integral(cos(u), x), u, f(x)), C1)) assert sol_1.doit() == sol_0 assert checkodesol(eq, sol_0, order=1, solve_for_func=False) assert checkodesol(eq, sol_1, order=1, solve_for_func=False) def test_issue_4838(): # Issue #15999 eq = f(x).diff(x) - C1*f(x) sol = Eq(f(x), C2*exp(C1*x)) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False) == (True, 0) # Issue #13691 eq = f(x).diff(x) - C1*g(x).diff(x) sol = Eq(f(x), C2 + C1*g(x)) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, f(x), order=1, solve_for_func=False) == (True, 0) # Issue #4838 eq = f(x).diff(x) - 3*C1 - 3*x**2 sol = Eq(f(x), C2 + 3*C1*x + x**3) assert dsolve(eq, f(x)) == sol assert checkodesol(eq, sol, order=1, solve_for_func=False) == (True, 0) @slow def test_issue_14395(): eq = Derivative(f(x), x, x) + 9*f(x) - sec(x) sol = Eq(f(x), (C1 - x/3 + sin(2*x)/3)*sin(3*x) + (C2 + log(cos(x)) - 2*log(cos(x)**2)/3 + 2*cos(x)**2/3)*cos(3*x)) assert dsolve(eq, f(x)) == sol # FIXME: assert checkodesol(eq, sol, order=2, solve_for_func=False) == (True, 0) def test_sysode_linear_neq_order1(): from sympy.abc import t Z0 = Function('Z0') Z1 = Function('Z1') Z2 = Function('Z2') Z3 = Function('Z3') k01, k10, k20, k21, k23, k30 = symbols('k01 k10 k20 k21 k23 k30') eq = (Eq(Derivative(Z0(t), t), -k01*Z0(t) + k10*Z1(t) + k20*Z2(t) + k30*Z3(t)), Eq(Derivative(Z1(t), t), k01*Z0(t) - k10*Z1(t) + k21*Z2(t)), Eq(Derivative(Z2(t), t), -(k20 + k21 + k23)*Z2(t)), Eq(Derivative(Z3(t), t), k23*Z2(t) - k30*Z3(t))) sols_eq = [Eq(Z0(t), C1*k10/k01 + C2*(-k10 + k30)*exp(-k30*t)/(k01 + k10 - k30) - C3*exp(t*(- k01 - k10)) + C4*(k10*k20 + k10*k21 - k10*k30 - k20**2 - k20*k21 - k20*k23 + k20*k30 + k23*k30)*exp(t*(-k20 - k21 - k23))/(k23*(k01 + k10 - k20 - k21 - k23))), Eq(Z1(t), C1 - C2*k01*exp(-k30*t)/(k01 + k10 - k30) + C3*exp(t*(-k01 - k10)) + C4*(k01*k20 + k01*k21 - k01*k30 - k20*k21 - k21**2 - k21*k23 + k21*k30)*exp(t*(-k20 - k21 - k23))/(k23*(k01 + k10 - k20 - k21 - k23))), Eq(Z2(t), C4*(-k20 - k21 - k23 + k30)*exp(t*(-k20 - k21 - k23))/k23), Eq(Z3(t), C2*exp(-k30*t) + C4*exp(t*(-k20 - k21 - k23)))] assert dsolve(eq, simplify=False) == sols_eq assert checksysodesol(eq, sols_eq) == (True, [0, 0, 0, 0]) def test_nth_order_reducible(): from sympy.solvers.ode import _nth_order_reducible_match eqn = Eq(x*Derivative(f(x), x)**2 + Derivative(f(x), x, 2), 0) sol = Eq(f(x), C1 - sqrt(-1/C2)*log(-C2*sqrt(-1/C2) + x) + sqrt(-1/C2)*log(C2*sqrt(-1/C2) + x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert sol == dsolve(eqn, f(x), hint='nth_order_reducible') assert sol == dsolve(eqn, f(x)) F = lambda eq: _nth_order_reducible_match(eq, f(x)) D = Derivative assert F(D(y*f(x), x, y) + D(f(x), x)) is None assert F(D(y*f(y), y, y) + D(f(y), y)) is None assert F(f(x)*D(f(x), x) + D(f(x), x, 2)) is None assert F(D(x*f(y), y, 2) + D(u*y*f(x), x, 3)) is None # no simplification by design assert F(D(f(y), y, 2) + D(f(y), y, 3) + D(f(x), x, 4)) is None assert F(D(f(x), x, 2) + D(f(x), x, 3)) == dict(n=2) eqn = -exp(x) + (x*Derivative(f(x), (x, 2)) + Derivative(f(x), x))/x sol = Eq(f(x), C1 + C2*log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert sol == dsolve(eqn, f(x)) assert sol == dsolve(eqn, f(x), hint='nth_order_reducible') eqn = Eq(sqrt(2) * f(x).diff(x,x,x) + f(x).diff(x), 0) sol = Eq(f(x), C1 + C2*sin(2**(S(3)/4)*x/2) + C3*cos(2**(S(3)/4)*x/2)) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert sol == dsolve(eqn, f(x)) assert sol == dsolve(eqn, f(x), hint='nth_order_reducible') eqn = f(x).diff(x, 2) + 2*f(x).diff(x) sol = Eq(f(x), C1 + C2*exp(-2*x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 3) + f(x).diff(x, 2) - 6*f(x).diff(x) sol = Eq(f(x), C1 + C2*exp(-3*x) + C3*exp(2*x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) - f(x).diff(x, 3) - 4*f(x).diff(x, 2) + \ 4*f(x).diff(x) sol = Eq(f(x), C1 + C2*exp(x) + C3*exp(-2*x) + C4*exp(2*x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) + 3*f(x).diff(x, 3) sol = Eq(f(x), C1 + C2*x + C3*x**2 + C4*exp(-3*x)) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) - 2*f(x).diff(x, 2) sol = Eq(f(x), C1 + C2*x + C3*exp(x*sqrt(2)) + C4*exp(-x*sqrt(2))) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 4) + 4*f(x).diff(x, 2) sol = Eq(f(x), C1 + C2*sin(2*x) + C3*cos(2*x) + C4*x) sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) eqn = f(x).diff(x, 5) + 2*f(x).diff(x, 3) + f(x).diff(x) # These are equivalent: sol1 = Eq(f(x), C1 + (C2 + C3*x)*sin(x) + (C4 + C5*x)*cos(x)) sol2 = Eq(f(x), C1 + C2*(x*sin(x) + cos(x)) + C3*(-x*cos(x) + sin(x)) + C4*sin(x) + C5*cos(x)) sol1s = constant_renumber(sol1) sol2s = constant_renumber(sol2) assert checkodesol(eqn, sol1, order=2, solve_for_func=False) == (True, 0) assert checkodesol(eqn, sol2, order=2, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x)) in (sol1, sol1s) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol2, sol2s) # In this case the reduced ODE has two distinct solutions eqn = f(x).diff(x, 2) - f(x).diff(x)**3 sol = [Eq(f(x), C2 - sqrt(2)*I*(C1 + x)*sqrt(1/(C1 + x))), Eq(f(x), C2 + sqrt(2)*I*(C1 + x)*sqrt(1/(C1 + x)))] sols = constant_renumber(sol) assert checkodesol(eqn, sol, order=2, solve_for_func=False) == [(True, 0), (True, 0)] assert dsolve(eqn, f(x)) in (sol, sols) assert dsolve(eqn, f(x), hint='nth_order_reducible') in (sol, sols) def test_nth_algebraic(): eqn = Eq(Derivative(f(x), x), Derivative(g(x), x)) sol = Eq(f(x), C1 + g(x)) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = (diff(f(x)) - x)*(diff(f(x)) + x) sol = [Eq(f(x), C1 - x**2/2), Eq(f(x), C1 + x**2/2)] assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = (1 - sin(f(x))) * f(x).diff(x) sol = Eq(f(x), C1) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) M, m, r, t = symbols('M m r t') phi = Function('phi') eqn = Eq(-M * phi(t).diff(t), Rational(3, 2) * m * r**2 * phi(t).diff(t) * phi(t).diff(t,t)) solns = [Eq(phi(t), C1), Eq(phi(t), C1 + C2*t - M*t**2/(3*m*r**2))] assert checkodesol(eqn, solns[0], order=2, solve_for_func=False)[0] assert checkodesol(eqn, solns[1], order=2, solve_for_func=False)[0] assert set(solns) == set(dsolve(eqn, phi(t), hint='nth_algebraic')) assert set(solns) == set(dsolve(eqn, phi(t))) eqn = f(x) * f(x).diff(x) * f(x).diff(x, x) sol = Eq(f(x), C1 + C2*x) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = f(x) * f(x).diff(x) * f(x).diff(x, x) * (f(x) - 1) sol = Eq(f(x), C1 + C2*x) assert checkodesol(eqn, sol, order=1, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) eqn = f(x) * f(x).diff(x) * f(x).diff(x, x) * (f(x) - 1) * (f(x).diff(x) - x) solns = [Eq(f(x), C1 + x**2/2), Eq(f(x), C1 + C2*x)] assert checkodesol(eqn, solns[0], order=2, solve_for_func=False)[0] assert checkodesol(eqn, solns[1], order=2, solve_for_func=False)[0] assert set(solns) == set(dsolve(eqn, f(x), hint='nth_algebraic')) assert set(solns) == set(dsolve(eqn, f(x))) def test_nth_algebraic_issue15999(): eqn = f(x).diff(x) - C1 sol = Eq(f(x), C1*x + C2) # Correct solution assert checkodesol(eqn, sol, order=1, solve_for_func=False) == (True, 0) assert dsolve(eqn, f(x), hint='nth_algebraic') == sol assert dsolve(eqn, f(x)) == sol def test_nth_algebraic_redundant_solutions(): # This one has a redundant solution that should be removed eqn = f(x)*f(x).diff(x) soln = Eq(f(x), C1) assert checkodesol(eqn, soln, order=1, solve_for_func=False)[0] assert soln == dsolve(eqn, f(x), hint='nth_algebraic') assert soln == dsolve(eqn, f(x)) # This has two integral solutions and no algebraic solutions eqn = (diff(f(x)) - x)*(diff(f(x)) + x) sol = [Eq(f(x), C1 - x**2/2), Eq(f(x), C1 + x**2/2)] assert all(c[0] for c in checkodesol(eqn, sol, order=1, solve_for_func=False)) assert set(sol) == set(dsolve(eqn, f(x), hint='nth_algebraic')) assert set(sol) == set(dsolve(eqn, f(x))) # This one doesn't work with dsolve at the time of writing but the # redundancy checking code should not remove the algebraic solution. from sympy.solvers.ode import _nth_algebraic_remove_redundant_solutions eqn = f(x) + f(x)*f(x).diff(x) solns = [Eq(f(x), 0), Eq(f(x), C1 - x)] solns_final = _nth_algebraic_remove_redundant_solutions(eqn, solns, 1, x) assert all(c[0] for c in checkodesol(eqn, solns, order=1, solve_for_func=False)) assert set(solns) == set(solns_final) solns = [Eq(f(x), exp(x)), Eq(f(x), C1*exp(C2*x))] solns_final = _nth_algebraic_remove_redundant_solutions(eqn, solns, 2, x) assert solns_final == [Eq(f(x), C1*exp(C2*x))] # This one needs a substitution f' = g. eqn = -exp(x) + (x*Derivative(f(x), (x, 2)) + Derivative(f(x), x))/x sol = Eq(f(x), C1 + C2*log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x)) # # These tests can be combined with the above test if they get fixed # so that dsolve actually works in all these cases. # # Fails due to division by f(x) eliminating the solution before nth_algebraic # is called. @XFAIL def test_nth_algebraic_find_multiple1(): eqn = f(x) + f(x)*f(x).diff(x) solns = [Eq(f(x), 0), Eq(f(x), C1 - x)] assert all(c[0] for c in checkodesol(eqn, solns, order=1, solve_for_func=False)) assert set(solns) == set(dsolve(eqn, f(x))) # prep = True breaks this def test_nth_algebraic_noprep1(): eqn = Derivative(x*f(x), x, x, x) sol = Eq(f(x), (C1 + C2*x + C3*x**2) / x) assert checkodesol(eqn, sol, order=3, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=False, hint='nth_algebraic') @XFAIL def test_nth_algebraic_prep1(): eqn = Derivative(x*f(x), x, x, x) sol = Eq(f(x), (C1 + C2*x + C3*x**2) / x) assert checkodesol(eqn, sol, order=3, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=True, hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) # prep = True breaks this def test_nth_algebraic_noprep2(): eqn = Eq(Derivative(x*Derivative(f(x), x), x)/x, exp(x)) sol = Eq(f(x), C1 + C2*log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=False, hint='nth_algebraic') @XFAIL def test_nth_algebraic_prep2(): eqn = Eq(Derivative(x*Derivative(f(x), x), x)/x, exp(x)) sol = Eq(f(x), C1 + C2*log(x) + exp(x) - Ei(x)) assert checkodesol(eqn, sol, order=2, solve_for_func=False)[0] assert sol == dsolve(eqn, f(x), prep=True, hint='nth_algebraic') assert sol == dsolve(eqn, f(x)) # This needs a combination of solutions from nth_algebraic and some other # method from dsolve @XFAIL def test_nth_algebraic_find_multiple2(): eqn = f(x)**2 + f(x)*f(x).diff(x) solns = [Eq(f(x), 0), Eq(f(x), C1*exp(-x))] assert all(c[0] for c in checkodesol(eqn, solns, order=1, solve_for_func=False)) assert set(solns) == dsolve(eqn, f(x)) # Needs to be a way to know how to combine derivatives in the expression @XFAIL def test_factoring_ode(): eqn = Derivative(x*f(x), x, x, x) + Derivative(f(x), x, x, x) soln = Eq(f(x), (C1*x**2/2 + C2*x + C3 - x)/(1 + x)) assert checkodesol(eqn, soln, order=2, solve_for_func=False)[0] assert soln == dsolve(eqn, f(x)) def test_issue_11542(): m = 96 g = 9.8 k = .2 f1 = g * m t = Symbol('t') v = Function('v') v_equation = dsolve(f1 - k * (v(t) ** 2) - m * Derivative(v(t)), 0) assert str(v_equation) == \ 'Eq(v(t), -68.585712797929/tanh(C1 - 0.142886901662352*t))' def test_issue_15913(): eq = -C1/x - 2*x*f(x) - f(x) + Derivative(f(x), x) sol = C2*exp(x**2 + x) + exp(x**2 + x)*Integral(C1*exp(-x**2 - x)/x, x) assert checkodesol(eq, sol) == (True, 0) sol = C1 + C2*exp(-x*y) eq = Derivative(y*f(x), x) + f(x).diff(x, 2) assert checkodesol(eq, sol, f(x)) == (True, 0) def test_issue_16146(): raises(ValueError, lambda: dsolve([f(x).diff(x), g(x).diff(x)], [f(x), g(x), h(x)])) raises(ValueError, lambda: dsolve([f(x).diff(x), g(x).diff(x)], [f(x)]))