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120a6ae012200eeabbbca4ee2aa8089f138e3b40344f883d78477762ef6ed645 | """Base class for all the objects in SymPy"""
from collections import defaultdict
from itertools import chain, zip_longest
from .assumptions import BasicMeta, ManagedProperties
from .cache import cacheit
from .sympify import _sympify, sympify, SympifyError
from .compatibility import iterable, ordered, 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(metaclass=ManagedProperties):
"""
Base class for all SymPy objects.
Notes and 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,)
3) By "SymPy object" we mean something that can be returned by
``sympify``. But not all objects one encounters using SymPy are
subclasses of Basic. For example, mutable objects are not:
>>> from sympy import Basic, Matrix, sympify
>>> A = Matrix([[1, 2], [3, 4]]).as_mutable()
>>> isinstance(A, Basic)
False
>>> B = sympify(A)
>>> isinstance(B, Basic)
True
"""
__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, 'extended_negative': False,
'extended_nonnegative': True, 'extended_nonpositive': False,
'extended_nonzero': True, 'extended_positive': True, 'extended_real':
True, 'finite': True, 'hermitian': True, 'imaginary': False,
'infinite': 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 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.xreplace({dummy: tmp}) == o.xreplace({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])
nodes = preorder_traversal(self)
if types:
result = {node for node in nodes if isinstance(node, types)}
else:
result = {node for node in nodes if not node.args}
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. When applied to a
symbol a new symbol having only the same commutativity will be
returned.
Examples
========
>>> from sympy import Integral, Symbol
>>> from sympy.abc import x
>>> r = Symbol('r', real=True)
>>> Integral(r, (r, x)).as_dummy()
Integral(_0, (_0, x))
>>> _.variables[0].is_real is None
True
>>> r.as_dummy()
_r
Notes
=====
Any object that has structurally bound variables should have
a property, `bound_symbols` that returns those symbols
appearing in the object.
"""
from sympy.core.symbol import Dummy, Symbol
def can(x):
# mask free that shadow bound
free = x.free_symbols
bound = set(x.bound_symbols)
d = {i: Dummy() for i in bound & free}
x = x.subs(d)
# replace bound with canonical names
x = x.xreplace(x.canonical_variables)
# return after undoing masking
return x.xreplace({v: k for k, v in d.items()})
if not self.has(Symbol):
return self
return self.replace(
lambda x: hasattr(x, 'bound_symbols'),
lambda x: can(x),
simultaneous=False)
@property
def canonical_variables(self):
"""Return a dictionary mapping any variable defined in
``self.bound_symbols`` to Symbols that do not clash
with any free symbols in the expression.
Examples
========
>>> from sympy import Lambda
>>> from sympy.abc import x
>>> Lambda(x, 2*x).canonical_variables
{x: _0}
"""
from sympy.utilities.iterables import numbered_symbols
if not hasattr(self, 'bound_symbols'):
return {}
dums = numbered_symbols('_')
reps = {}
# watch out for free symbol that are not in bound symbols;
# those that are in bound symbols are about to get changed
bound = self.bound_symbols
names = {i.name for i in self.free_symbols - set(bound)}
for b in bound:
d = next(dums)
if b.is_Symbol:
while d.name in names:
d = next(dums)
reps[b] = 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_extended_real = self.is_extended_real
if is_extended_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_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
sympy.core.evalf.EvalfMixin.evalf: calculates the given formula to a desired level of precision
"""
from sympy.core.compatibility import _nodes, default_sort_key
from sympy.core.containers import Dict
from sympy.core.symbol import Dummy, Symbol
from sympy.utilities.misc import filldedent
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):
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], str):
# when old is a string we prefer Symbol
s = Symbol(s[0]), s[1]
try:
s = [sympify(_, strict=not isinstance(_, str))
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)
# order so more complex items are first and items
# of identical complexity are ordered so
# f(x) < f(y) < x < y
# \___ 2 __/ \_1_/ <- number of nodes
#
# For more complex ordering use an unordered sequence.
k = list(ordered(sequence, default=False, keys=(
lambda x: -_nodes(x),
lambda x: default_sort_key(x),
)))
sequence = [(k, sequence[k]) for k in k]
if kwargs.pop('simultaneous', False): # XXX should this be the default for dict subs?
reps = {}
rv = self
kwargs['hack2'] = True
m = Dummy('subs_m')
for old, new in sequence:
com = new.is_commutative
if com is None:
com = True
d = Dummy('subs_d', commutative=com)
# 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 None
it will be set to True so the match will only succeed if all non-zero
values are received for each Wild that appears in the match pattern.
Setting this to False accepts a match of 0; while setting it True
accepts all matches that have a 0 in them. See example below for
cautions.
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)
When matching a single symbol, `exact` will default to True, but
this may or may not be the behavior that is desired:
Here, we want `exact=False`:
>>> from sympy import Function
>>> f = Function('f')
>>> e = f(1) + f(0)
>>> q = f(a), lambda a: f(a + 1)
>>> e.replace(*q, exact=False)
f(1) + f(2)
>>> e.replace(*q, exact=True)
f(0) + f(2)
But here, the nature of matching makes selecting
the right setting tricky:
>>> e = x**(1 + y)
>>> (x**(1 + y)).replace(x**(1 + a), lambda a: x**-a, exact=False)
x
>>> (x**(1 + y)).replace(x**(1 + a), lambda a: x**-a, exact=True)
x**(-x - y + 1)
>>> (x**y).replace(x**(1 + a), lambda a: x**-a, exact=False)
x
>>> (x**y).replace(x**(1 + a), lambda a: x**-a, exact=True)
x**(1 - y)
It is probably better to use a different form of the query
that describes the target expression more precisely:
>>> (1 + x**(1 + y)).replace(
... lambda x: x.is_Pow and x.exp.is_Add and x.exp.args[0] == 1,
... lambda x: x.base**(1 - (x.exp - 1)))
...
x**(1 - 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 Wild
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)
if exact is None:
exact = (len(query.atoms(Wild)) > 1)
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")
def walk(rv, F):
"""Apply ``F`` to args and then to result.
"""
args = getattr(rv, 'args', None)
if args is not None:
if args:
newargs = tuple([walk(a, F) for a in args])
if args != newargs:
rv = rv.func(*newargs)
if simultaneous:
# if rv is something that was already
# matched (that was changed) then skip
# applying F again
for i, e in enumerate(args):
if rv == e and e != newargs[i]:
return rv
rv = F(rv)
return rv
mapping = {} # changes that took place
def rec_replace(expr):
result = _query(expr)
if result or result == {}:
v = _value(expr, result)
if v is not None and v != expr:
if map:
mapping[expr] = v
expr = v
return expr
rv = walk(self, rec_replace)
return (rv, mapping) if map else rv
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}
"""
repl_dict = repl_dict.copy()
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, Sum
>>> 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
Structurally bound symbols are ignored during matching:
>>> Sum(x, (x, 1, 2)).match(Sum(y, (y, 1, p)))
{p_: 2}
But they can be identified if desired:
>>> Sum(x, (x, 1, 2)).match(Sum(q, (q, 1, p)))
{p_: 2, q_: x}
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}
"""
from sympy.core.symbol import Wild
from sympy.core.function import WildFunction
from sympy.utilities.misc import filldedent
pattern = sympify(pattern)
# match non-bound symbols
canonical = lambda x: x if x.is_Symbol else x.as_dummy()
m = canonical(pattern).matches(canonical(self), old=old)
if m is None:
return m
wild = pattern.atoms(Wild, WildFunction)
# sanity check
if set(m) - wild:
raise ValueError(filldedent('''
Some `matches` routine did not use a copy of repl_dict
and injected unexpected symbols. Report this as an
error at https://github.com/sympy/sympy/issues'''))
# now see if bound symbols were requested
bwild = wild - set(m)
if not bwild:
return m
# replace free-Wild symbols in pattern with match result
# so they will match but not be in the next match
wpat = pattern.xreplace(m)
# identify remaining bound wild
w = wpat.matches(self, old=old)
# add them to m
if w:
m.update(w)
# done
return m
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 simplify(self, **kwargs):
"""See the simplify function in sympy.simplify"""
from sympy.simplify import simplify
return simplify(self, **kwargs)
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], str):
rule = '_eval_rewrite_as_' + args[-1]
else:
# rewrite arg is usually a class but can also be a
# singleton (e.g. GoldenRatio) so we check
# __name__ or __class__.__name__
clsname = getattr(args[-1], "__name__", None)
if clsname is None:
clsname = args[-1].__class__.__name__
rule = '_eval_rewrite_as_' + clsname
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 = {} # type: ignore
@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.copy()
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, **kwargs):
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
========
In SymPy (as in Python) two numbers compare the same if they
have the same underlying base-2 representation even though
they may not be the same type:
>>> from sympy import S
>>> 2.0 == S(2)
True
>>> 0.5 == S.Half
True
This routine was written to provide a query for such cases that
would give false when the types do not match:
>>> from sympy.core.basic import _aresame
>>> _aresame(S(2.0), S(2))
False
"""
from .numbers import Number
from .function import AppliedUndef, UndefinedFunction as UndefFunc
if isinstance(a, Number) and isinstance(b, Number):
return a == b and a.__class__ == b.__class__
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:
"""
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:
yield from self._preorder_traversal(arg, keys)
elif iterable(node):
for item in node:
yield from self._preorder_traversal(item, keys)
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
|
413e12183975b51f0994b477448fbb03125695fd401b78be516bd170dec96f23 | 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, HAS_GMPY, gmpy
from .parameters import global_parameters
from sympy.utilities.iterables import sift
from sympy.utilities.exceptions import SymPyDeprecationWarning
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 < 0:
raise ValueError("n must be nonnegative")
n = int(n)
# Fast path: with IEEE 754 binary64 floats and a correctly-rounded
# math.sqrt, int(math.sqrt(n)) works for any integer n satisfying 0 <= n <
# 4503599761588224 = 2**52 + 2**27. But Python doesn't guarantee either
# IEEE 754 format floats *or* correct rounding of math.sqrt, so check the
# answer and fall back to the slow method if necessary.
if n < 4503599761588224:
s = int(_sqrt(n))
if 0 <= n - s*s <= 2*s:
return s
return integer_nthroot(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 HAS_GMPY and n < 2**63:
# Currently it works only for n < 2**63, else it produces TypeError
# sympy issue: https://github.com/sympy/sympy/issues/18374
# gmpy2 issue: https://github.com/aleaxit/gmpy/issues/257
if HAS_GMPY >= 2:
x, t = gmpy.iroot(y, n)
else:
x, t = gmpy.root(y, n)
return as_int(x), bool(t)
return _integer_nthroot_python(y, n)
def _integer_nthroot_python(y, n):
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):
r"""
Returns ``(e, bool)`` where e is the largest nonnegative integer
such that :math:`|y| \geq |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_parameters.evaluate
from sympy.functions.elementary.exponential import exp_polar
b = _sympify(b)
e = _sympify(e)
# XXX: This can be removed when non-Expr args are disallowed rather
# than deprecated.
from sympy.core.relational import Relational
if isinstance(b, Relational) or isinstance(e, Relational):
raise TypeError('Relational can not be used in Pow')
# XXX: This should raise TypeError once deprecation period is over:
if not (isinstance(b, Expr) and isinstance(e, Expr)):
SymPyDeprecationWarning(
feature="Pow with non-Expr args",
useinstead="Expr args",
issue=19445,
deprecated_since_version="1.7"
).warn()
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
elif e == -1 and not b:
return S.ComplexInfinity
# 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 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_extended_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_extended_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)
elif b.is_negative is False:
return Pow(b, -other)
elif e.is_even:
if b.is_extended_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_extended_nonnegative:
s = 1 # floor = 0
elif re(b).is_extended_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_extended_real and _n2(sign(s) - s) == 0:
s = sign(s)
else:
s = None
else:
# e.is_extended_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_extended_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):
r"""A dispatched function to compute `b^e \bmod q`, dispatched
by ``Mod``.
Notes
=====
Algorithms:
1. For unevaluated integer power, use built-in ``pow`` function
with 3 arguments, if powers are not too large wrt base.
2. 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.
3. For any unevaluated power found in `b` or `e`, the step 2
will be recursed down to the base and the exponent
such that the `b \bmod q` becomes the new base and
``\phi(q) + e \bmod \phi(q)`` becomes the new exponent, and then
the computation for the reduced expression can be done.
"""
from sympy.ntheory import totient
from .mod import Mod
base, exp = self.base, self.exp
if exp.is_integer and exp.is_positive:
if q.is_integer and base % q == 0:
return S.Zero
if base.is_Integer and exp.is_Integer and q.is_Integer:
b, e, m = int(base), int(exp), int(q)
mb = m.bit_length()
if mb <= 80 and e >= mb and e.bit_length()**4 >= m:
phi = totient(m)
return Integer(pow(b, phi + e%phi, m))
return Integer(pow(b, e, m))
if isinstance(base, Pow) and base.is_integer and base.is_number:
base = Mod(base, q)
return Mod(Pow(base, exp, evaluate=False), q)
if isinstance(exp, Pow) and exp.is_integer and exp.is_number:
bit_length = int(q).bit_length()
# XXX Mod-Pow actually attempts to do a hanging evaluation
# if this dispatched function returns None.
# May need some fixes in the dispatcher itself.
if bit_length <= 80:
phi = totient(q)
exp = phi + Mod(exp, phi)
return Mod(Pow(base, exp, evaluate=False), q)
def _eval_is_even(self):
if self.exp.is_integer and self.exp.is_positive:
return self.base.is_even
def _eval_is_negative(self):
ext_neg = Pow._eval_is_extended_negative(self)
if ext_neg is True:
return self.is_finite
return ext_neg
def _eval_is_positive(self):
ext_pos = Pow._eval_is_extended_positive(self)
if ext_pos is True:
return self.is_finite
return ext_pos
def _eval_is_extended_positive(self):
from sympy import log
if self.base == self.exp:
if self.base.is_extended_nonnegative:
return True
elif self.base.is_positive:
if self.exp.is_real:
return True
elif self.base.is_extended_negative:
if self.exp.is_even:
return True
if self.exp.is_odd:
return False
elif self.base.is_zero:
if self.exp.is_extended_real:
return self.exp.is_zero
elif self.base.is_extended_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_extended_negative(self):
if self.exp is S(1)/2:
if self.base.is_complex or self.base.is_extended_real:
return False
if self.base.is_extended_negative:
if self.exp.is_odd and self.base.is_finite:
return True
if self.exp.is_even:
return False
elif self.base.is_extended_positive:
if self.exp.is_extended_real:
return False
elif self.base.is_zero:
if self.exp.is_extended_real:
return False
elif self.base.is_extended_nonnegative:
if self.exp.is_extended_nonnegative:
return False
elif self.base.is_extended_nonpositive:
if self.exp.is_even:
return False
elif self.base.is_extended_real:
if self.exp.is_even:
return False
def _eval_is_zero(self):
if self.base.is_zero:
if self.exp.is_extended_positive:
return True
elif self.exp.is_extended_nonpositive:
return False
elif self.base.is_zero is False:
if self.base.is_finite and self.exp.is_finite:
return False
elif self.exp.is_negative:
return self.base.is_infinite
elif self.exp.is_nonnegative:
return False
elif self.exp.is_infinite and self.exp.is_extended_real:
if (1 - abs(self.base)).is_extended_positive:
return self.exp.is_extended_positive
elif (1 - abs(self.base)).is_extended_negative:
return self.exp.is_extended_negative
else: # when self.base.is_zero is None
if self.base.is_finite and self.exp.is_negative:
return False
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
if e.is_negative and b.is_positive and (b - 1).is_positive:
return False
if e.is_negative and b.is_negative and (b + 1).is_negative:
return False
def _eval_is_extended_real(self):
from sympy import arg, exp, log, Mul
real_b = self.base.is_extended_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_extended_real
if real_e is None:
return
if real_b and real_e:
if self.base.is_extended_positive:
return True
elif self.base.is_extended_nonnegative and self.exp.is_extended_nonnegative:
return True
elif self.exp.is_integer and self.base.is_extended_nonzero:
return True
elif self.exp.is_integer and self.exp.is_nonnegative:
return True
elif self.base.is_extended_negative:
if self.exp.is_Rational:
return False
if real_e and self.exp.is_extended_negative and self.base.is_zero is False:
return Pow(self.base, -self.exp).is_extended_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_extended_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:
if self.base.is_rational and c.is_rational:
if self.base.is_nonzero and (self.base - 1).is_nonzero and c.is_nonzero:
return False
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
if i.is_complex: # finite
return i.is_integer
def _eval_is_complex(self):
if all(a.is_complex for a in self.args) and self._eval_is_finite():
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_extended_real and self.exp.is_extended_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_extended_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 or self.base.is_nonzero:
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:
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_extended_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_extended_real:
return self
def _eval_transpose(self):
from sympy.functions.elementary.complexes import transpose
i, p = self.exp.is_integer, (self.base.is_complex or self.base.is_infinite)
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_extended_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_extended_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:
if e.is_Rational:
npow, cargs = sift(cargs, lambda x: x.is_Pow and
x.exp.is_Rational and x.base.is_number,
binary=True)
rv = Mul(*[self.func(b.func(*b.args), e) for b in npow])
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_e, im_e = self.base.as_real_imag(deep=deep)
if not im_e:
return self, S.Zero
a, b = symbols('a b', cls=Dummy)
if exp >= 0:
if re_e.is_Number and im_e.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_e**2 + im_e**2
re_e, im_e = re_e/mag, -im_e/mag
if re_e.is_Number and im_e.is_Number:
# We can be more efficient in this case
expr = expand_multinomial((re_e + im_e*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_e, b: S.ImaginaryUnit*im_e}),
im_part1.subs({a: re_e, b: im_e}) + im_part3.subs({a: re_e, b: -im_e}))
elif self.exp.is_Rational:
re_e, im_e = self.base.as_real_imag(deep=deep)
if im_e.is_zero and self.exp is S.Half:
if re_e.is_extended_nonnegative:
return self, S.Zero
if re_e.is_extended_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_e, 2) + self.func(im_e, 2), S.Half)
t = atan2(im_e, re_e)
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_extended_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
if self.base.is_zero is False:
if self.exp.is_nonzero:
return self.base.is_algebraic
elif self.base.is_algebraic:
return True
if self.exp.is_positive:
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_meromorphic(self, x, a):
# f**g is meromorphic if g is an integer and f is meromorphic.
# E**(log(f)*g) is meromorphic if log(f)*g is meromorphic
# and finite.
base_merom = self.base._eval_is_meromorphic(x, a)
exp_integer = self.exp.is_Integer
if exp_integer:
return base_merom
exp_merom = self.exp._eval_is_meromorphic(x, a)
if base_merom is False:
# f**g = E**(log(f)*g) may be meromorphic if the
# singularities of log(f) and g cancel each other,
# for example, if g = 1/log(f). Hence,
return False if exp_merom else None
elif base_merom is None:
return None
b = self.base.subs(x, a)
# b is extended complex as base is meromorphic.
# log(base) is finite and meromorphic when b != 0, zoo.
b_zero = b.is_zero
if b_zero:
log_defined = False
else:
log_defined = fuzzy_and((b.is_finite, fuzzy_not(b_zero)))
if log_defined is False: # zero or pole of base
return exp_integer # False or None
elif log_defined is None:
return None
if not exp_merom:
return exp_merom # False or None
return self.exp.subs(x, a).is_finite
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_extended_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)
repl_dict = repl_dict.copy()
# special case, pattern = 1 and expr.exp can match to 0
if expr is S.One:
d = self.exp.matches(S.Zero, repl_dict)
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, powdenest
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)
b = powdenest(b)
prefactor = b.as_leading_term(x)
# express "rest" as: rest = 1 + k*x**l + ... + O(x**n)
rest = expand_mul((b - prefactor)/prefactor)
rest = rest.simplify() #test_issue_6364
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:
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)
from sympy import AccumBounds
# Issue: #18795 -"XXX This can be removed and simply "z = (b - b0)/b0"
# would be enough when the operations on AccumBounds have been fixed."
if isinstance(b0, AccumBounds):
z = (b/b0 - 1)
else:
z = (b - b0)/b0
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
|
f41778e30fc1e8205db432ca309775ada3e23014d6cbb54ba780fc358c4049c6 | """Tools for manipulating of large commutative expressions. """
from sympy.core.add import Add
from sympy.core.compatibility import iterable, is_sequence, SYMPY_INTS
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
>>> 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_extended_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_extended_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_extended_nonpositive or s.is_extended_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_extended_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.One
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:
"""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 S.Zero) + factors[f]
factors[q] = (factors[q] if q in factors else S.Zero) - 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:
if isinstance(exp, Integer):
b, e = factor.as_base_exp()
e = _keep_coeff(exp, e)
args.append(b**e)
else:
args.append(factor**exp)
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:
"""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.One).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 = {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
>>> 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])
"""
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)
|
2d823e01c5e9b0bc2b7788412e5319a77aa44d89b716189932833d48524f6c8c | """Singleton mechanism"""
from typing import Any, Dict, Type
from .core import Registry
from .assumptions import ManagedProperties
from .sympify import sympify
class SingletonRegistry(Registry):
"""
The registry for the singleton classes (accessible as ``S``).
This class serves as two separate things.
The first thing it is is the ``SingletonRegistry``. Several classes in
SymPy appear so often that they are singletonized, that is, using some
metaprogramming they are made so that they can only be instantiated once
(see the :class:`sympy.core.singleton.Singleton` class for details). For
instance, every time you create ``Integer(0)``, this will return the same
instance, :class:`sympy.core.numbers.Zero`. All singleton instances are
attributes of the ``S`` object, so ``Integer(0)`` can also be accessed as
``S.Zero``.
Singletonization offers two advantages: it saves memory, and it allows
fast comparison. It saves memory because no matter how many times the
singletonized objects appear in expressions in memory, they all point to
the same single instance in memory. The fast comparison comes from the
fact that you can use ``is`` to compare exact instances in Python
(usually, you need to use ``==`` to compare things). ``is`` compares
objects by memory address, and is very fast. For instance
>>> from sympy import S, Integer
>>> a = Integer(0)
>>> a is S.Zero
True
For the most part, the fact that certain objects are singletonized is an
implementation detail that users shouldn't need to worry about. In SymPy
library code, ``is`` comparison is often used for performance purposes
The primary advantage of ``S`` for end users is the convenient access to
certain instances that are otherwise difficult to type, like ``S.Half``
(instead of ``Rational(1, 2)``).
When using ``is`` comparison, make sure the argument is sympified. For
instance,
>>> x = 0
>>> x is S.Zero
False
This problem is not an issue when using ``==``, which is recommended for
most use-cases:
>>> 0 == S.Zero
True
The second thing ``S`` is is a shortcut for
:func:`sympy.core.sympify.sympify`. :func:`sympy.core.sympify.sympify` is
the function that converts Python objects such as ``int(1)`` into SymPy
objects such as ``Integer(1)``. It also converts the string form of an
expression into a SymPy expression, like ``sympify("x**2")`` ->
``Symbol("x")**2``. ``S(1)`` is the same thing as ``sympify(1)``
(basically, ``S.__call__`` has been defined to call ``sympify``).
This is for convenience, since ``S`` is a single letter. It's mostly
useful for defining rational numbers. Consider an expression like ``x +
1/2``. If you enter this directly in Python, it will evaluate the ``1/2``
and give ``0.5`` (or just ``0`` in Python 2, because of integer division),
because both arguments are ints (see also
:ref:`tutorial-gotchas-final-notes`). However, in SymPy, you usually want
the quotient of two integers to give an exact rational number. The way
Python's evaluation works, at least one side of an operator needs to be a
SymPy object for the SymPy evaluation to take over. You could write this
as ``x + Rational(1, 2)``, but this is a lot more typing. A shorter
version is ``x + S(1)/2``. Since ``S(1)`` returns ``Integer(1)``, the
division will return a ``Rational`` type, since it will call
``Integer.__div__``, which knows how to return a ``Rational``.
"""
__slots__ = ()
# Also allow things like S(5)
__call__ = staticmethod(sympify)
def __init__(self):
self._classes_to_install = {}
# Dict of classes that have been registered, but that have not have been
# installed as an attribute of this SingletonRegistry.
# Installation automatically happens at the first attempt to access the
# attribute.
# The purpose of this is to allow registration during class
# initialization during import, but not trigger object creation until
# actual use (which should not happen until after all imports are
# finished).
def register(self, cls):
# Make sure a duplicate class overwrites the old one
if hasattr(self, cls.__name__):
delattr(self, cls.__name__)
self._classes_to_install[cls.__name__] = cls
def __getattr__(self, name):
"""Python calls __getattr__ if no attribute of that name was installed
yet.
This __getattr__ checks whether a class with the requested name was
already registered but not installed; if no, raises an AttributeError.
Otherwise, retrieves the class, calculates its singleton value, installs
it as an attribute of the given name, and unregisters the class."""
if name not in self._classes_to_install:
raise AttributeError(
"Attribute '%s' was not installed on SymPy registry %s" % (
name, self))
class_to_install = self._classes_to_install[name]
value_to_install = class_to_install()
self.__setattr__(name, value_to_install)
del self._classes_to_install[name]
return value_to_install
def __repr__(self):
return "S"
S = SingletonRegistry()
class Singleton(ManagedProperties):
"""
Metaclass for singleton classes.
A singleton class has only one instance which is returned every time the
class is instantiated. Additionally, this instance can be accessed through
the global registry object ``S`` as ``S.<class_name>``.
Examples
========
>>> from sympy import S, Basic
>>> from sympy.core.singleton import Singleton
>>> class MySingleton(Basic, metaclass=Singleton):
... pass
>>> Basic() is Basic()
False
>>> MySingleton() is MySingleton()
True
>>> S.MySingleton is MySingleton()
True
Notes
=====
Instance creation is delayed until the first time the value is accessed.
(SymPy versions before 1.0 would create the instance during class
creation time, which would be prone to import cycles.)
This metaclass is a subclass of ManagedProperties because that is the
metaclass of many classes that need to be Singletons (Python does not allow
subclasses to have a different metaclass than the superclass, except the
subclass may use a subclassed metaclass).
"""
_instances = {} # type: Dict[Type[Any], Any]
"Maps singleton classes to their instances."
def __new__(cls, *args, **kwargs):
result = super().__new__(cls, *args, **kwargs)
S.register(result)
return result
def __call__(self, *args, **kwargs):
# Called when application code says SomeClass(), where SomeClass is a
# class of which Singleton is the metaclas.
# __call__ is invoked first, before __new__() and __init__().
if self not in Singleton._instances:
Singleton._instances[self] = \
super().__call__(*args, **kwargs)
# Invokes the standard constructor of SomeClass.
return Singleton._instances[self]
# Inject pickling support.
def __getnewargs__(self):
return ()
self.__getnewargs__ = __getnewargs__
|
33012501090e27ecda8c939a03540d06f13124fa6e628c3fa7b9a28917053f9f | """
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 typing import Any, Dict as tDict, Optional, Set as tSet
from .add import Add
from .assumptions import ManagedProperties
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.parameters import global_parameters
from sympy.core.logic import fuzzy_and, fuzzy_or, fuzzy_not
from sympy.utilities import default_sort_key
from sympy.utilities.exceptions import SymPyDeprecationWarning
from sympy.utilities.iterables import has_dups, sift
from sympy.utilities.misc import filldedent
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_extended_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]))
class BadSignatureError(TypeError):
'''Raised when a Lambda is created with an invalid signature'''
pass
class BadArgumentsError(TypeError):
'''Raised when a Lambda is called with an incorrect number of arguments'''
pass
# 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)
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))
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)))
if nargs is None and 'nargs' not in cls.__dict__:
for supcls in cls.__mro__:
if hasattr(supcls, '_nargs'):
nargs = supcls._nargs
break
else:
continue
# 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().__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
>>> 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
FiniteSet(1)
>>> Function('f', nargs=(2, 1)).nargs
FiniteSet(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(Basic, metaclass=FunctionClass):
"""
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_parameters.evaluate)
# 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().__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_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, and if function is initialized with a
Symbol, the function inherits the name and assumptions associated with the Symbol:
>>> f_real = Function('f', real=True)
>>> f_real(x).is_real
True
>>> f_real_inherit = Function(Symbol('f', real=True))
>>> f_real_inherit(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_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_parameters.evaluate)
result = super().__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
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):
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_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_meromorphic(self, x, a):
if not self.args:
return True
if any(arg.has(x) for arg in self.args[1:]):
return False
arg = self.args[0]
if not arg._eval_is_meromorphic(x, a):
return None
return fuzzy_not(type(self).is_singular(arg.subs(x, a)))
_singularities = None # indeterminate
@classmethod
def is_singular(cls, a):
"""
Tests whether the argument is an essential singularity
or a branch point, or the functions is non-holomorphic.
"""
ss = cls._singularities
if ss in (True, None, False):
return ss
return fuzzy_or(a.is_infinite if s is S.ComplexInfinity
else (a - s).is_zero for s in ss)
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
if len(e.args) == 1:
# issue 14411
e = e.func(e.args[0].cancel())
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 = (n/cf).ceiling()
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 or not A.is_Symbol:
return Derivative(self, A)
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)
# 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))
u = [a.name for a in args if isinstance(a, UndefinedFunction)]
if u:
raise TypeError('Invalid argument: expecting an expression, not UndefinedFunction%s: %s' % (
's'*(len(u) > 1), ', '.join(u)))
obj = super().__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 UndefSageHelper:
"""
Helper to facilitate Sage conversion.
"""
def __get__(self, ins, typ):
import sage.all as sage
if ins is None:
return lambda: sage.function(typ.__name__)
else:
args = [arg._sage_() for arg in ins.args]
return lambda : sage.function(ins.__class__.__name__)(*args)
_undef_sage_helper = UndefSageHelper()
class UndefinedFunction(FunctionClass):
"""
The (meta)class of undefined functions.
"""
def __new__(mcl, name, bases=(AppliedUndef,), __dict__=None, **kwargs):
from .symbol import _filter_assumptions
# Allow Function('f', real=True)
# and/or Function(Symbol('f', real=True))
assumptions, kwargs = _filter_assumptions(kwargs)
if isinstance(name, Symbol):
assumptions = name._merge(assumptions)
name = name.name
elif not isinstance(name, str):
raise TypeError('expecting string or Symbol for name')
else:
commutative = assumptions.get('commutative', None)
assumptions = Symbol(name, **assumptions).assumptions0
if commutative is None:
assumptions.pop('commutative')
__dict__ = __dict__ or {}
# put the `is_*` for into __dict__
__dict__.update({'is_%s' % k: v for k, v in assumptions.items()})
# 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)
# add back the sanitized assumptions without the is_ prefix
kwargs.update(assumptions)
# Save these for __eq__
__dict__.update({'_kwargs': kwargs})
# do this for pickling
__dict__['__module__'] = None
obj = super().__new__(mcl, name, bases, __dict__)
obj.name = name
obj._sage_ = _undef_sage_helper
return obj
def __instancecheck__(cls, instance):
return cls in type(instance).__mro__
_kwargs = {} # type: tDict[str, Optional[bool]]
def __hash__(self):
return hash((self.class_key(), frozenset(self._kwargs.items())))
def __eq__(self, other):
return (isinstance(other, self.__class__) and
self.class_key() == other.class_key() and
self._kwargs == other._kwargs)
def __ne__(self, other):
return not self == other
@property
def _diff_wrt(self):
return False
# XXX: The type: ignore on WildFunction is because mypy complains:
#
# sympy/core/function.py:939: error: Cannot determine type of 'sort_key' in
# base class 'Expr'
#
# Somehow this is because of the @cacheit decorator but it is not clear how to
# fix it.
class WildFunction(Function, AtomicExpr): # type: ignore
"""
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
FiniteSet(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
FiniteSet(1, 2)
>>> f(x).match(F)
{F_: f(x)}
>>> f(x, y).match(F)
{F_: f(x, y)}
>>> f(x, y, 1).match(F)
"""
# XXX: What is this class attribute used for?
include = set() # type: tSet[Any]
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 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 explicitly 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
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 {} followed by number {}".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
elif isinstance(v, UndefinedFunction):
raise TypeError(
"cannot differentiate wrt "
"UndefinedFunction: %s" % v)
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 isinstance(expr, MatrixExpr):
from sympy import ZeroMatrix
return ZeroMatrix(*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
>>> 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):
ret = self.expr.free_symbols
# Add symbolic counts to free_symbols
for var, count in self.variable_count:
ret.update(count.free_symbols)
return ret
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 = {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)/...
To approximate ``Derivative`` around ``x0`` using a non-equidistant
spacing step, the algorithm supports assignment of undefined
functions to ``points``:
>>> dx = Function('dx')
>>> f(x).diff(x).as_finite_difference(points=dx(x), x0=x-h)
-f(-h + x - dx(-h + x)/2)/dx(-h + x) + f(-h + x + dx(-h + x)/2)/dx(-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).
Examples
========
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
It is also possible to unpack tuple arguments:
>>> f = Lambda( ((x, y), z) , x + y + z)
>>> f((1, 2), 3)
6
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, signature, expr):
if iterable(signature) and not isinstance(signature, (tuple, Tuple)):
SymPyDeprecationWarning(
feature="non tuple iterable of argument symbols to Lambda",
useinstead="tuple of argument symbols",
issue=17474,
deprecated_since_version="1.5").warn()
signature = tuple(signature)
sig = signature if iterable(signature) else (signature,)
sig = sympify(sig)
cls._check_signature(sig)
if len(sig) == 1 and sig[0] == expr:
return S.IdentityFunction
return Expr.__new__(cls, sig, sympify(expr))
@classmethod
def _check_signature(cls, sig):
syms = set()
def rcheck(args):
for a in args:
if a.is_symbol:
if a in syms:
raise BadSignatureError("Duplicate symbol %s" % a)
syms.add(a)
elif isinstance(a, Tuple):
rcheck(a)
else:
raise BadSignatureError("Lambda signature should be only tuples"
" and symbols, not %s" % a)
if not isinstance(sig, Tuple):
raise BadSignatureError("Lambda signature should be a tuple not %s" % sig)
# Recurse through the signature:
rcheck(sig)
@property
def signature(self):
"""The expected form of the arguments to be unpacked into variables"""
return self._args[0]
@property
def expr(self):
"""The return value of the function"""
return self._args[1]
@property
def variables(self):
"""The variables used in the internal representation of the function"""
def _variables(args):
if isinstance(args, Tuple):
for arg in args:
yield from _variables(arg)
else:
yield args
return tuple(_variables(self.signature))
@property
def nargs(self):
from sympy.sets.sets import FiniteSet
return FiniteSet(len(self.signature))
bound_symbols = variables
@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 BadArgumentsError(temp % {
'name': self,
'args': list(self.nargs)[0],
'plural': 's'*(list(self.nargs)[0] != 1),
'given': n})
d = self._match_signature(self.signature, args)
return self.expr.xreplace(d)
def _match_signature(self, sig, args):
symargmap = {}
def rmatch(pars, args):
for par, arg in zip(pars, args):
if par.is_symbol:
symargmap[par] = arg
elif isinstance(par, Tuple):
if not isinstance(arg, (tuple, Tuple)) or len(args) != len(pars):
raise BadArgumentsError("Can't match %s and %s" % (args, pars))
rmatch(par, arg)
rmatch(sig, args)
return symargmap
@property
def is_identity(self):
"""Return ``True`` if this ``Lambda`` is an identity function. """
return self.signature == self.expr
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 prepended _)
# 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-prepended 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().__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) == {new} and not any(
i.has(new) for i in self.args):
# the substitution is neutral
return self.xreplace({old: new})
# any occurrence 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
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, sympy.simplify.hyperexpand.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, factor=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)
"""
from sympy import Mul, log
if factor is False:
def _handle(x):
x1 = expand_mul(expand_log(x, deep=deep, force=force, factor=True))
if x1.count(log) <= x.count(log):
return x1
return x
expr = expr.replace(
lambda x: x.is_Mul and all(any(isinstance(i, log) and i.args[0].is_Rational
for i in Mul.make_args(j)) for j in x.as_numer_denom()),
lambda x: _handle(x))
return sympify(expr).expand(deep=deep, log=True, mul=False,
power_exp=False, power_base=False, multinomial=False,
basic=False, force=force, factor=factor)
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
========
sympy.core.expr.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, Sum, 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 isinstance(a, LatticeOp):
o = Symbol(a.func.__name__.upper())
# count the args
ops.append(o*(len(a.args) - 1))
elif a.args and (
a.is_Pow or
a.is_Function or
isinstance(a, Derivative) or
isinstance(a, Integral) or
isinstance(a, Sum)):
# if it's not in the list above we don't
# consider a.func something to count, e.g.
# Tuple, MatrixSymbol, etc...
o = Symbol(a.func.__name__.upper())
ops.append(o)
if not a.is_Symbol:
args.extend(a.args)
elif isinstance(expr, 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, dkeys=False):
"""Make all Rationals in expr Floats except those in exponents
(unless the exponents flag is set to True). When processing
dictionaries, don't modify the keys unless ``dkeys=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
Container types are not modified:
>>> type(nfloat((1, 2))) is tuple
True
"""
from sympy.core.power import Pow
from sympy.polys.rootoftools import RootOf
from sympy import MatrixBase
kw = dict(n=n, exponent=exponent, dkeys=dkeys)
if isinstance(expr, MatrixBase):
return expr.applyfunc(lambda e: nfloat(e, **kw))
# handling of iterable containers
if iterable(expr, exclude=str):
if isinstance(expr, (dict, Dict)):
if dkeys:
args = [tuple(map(lambda i: nfloat(i, **kw), a))
for a in expr.items()]
else:
args = [(k, nfloat(v, **kw)) for k, v in expr.items()]
if isinstance(expr, dict):
return type(expr)(args)
else:
return expr.func(*args)
elif isinstance(expr, Basic):
return expr.func(*[nfloat(a, **kw) for a in expr.args])
return type(expr)([nfloat(a, **kw) 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
elif rv.is_Atom:
return rv
elif rv.is_Relational:
args_nfloat = (nfloat(arg, **kw) for arg in rv.args)
return rv.func(*args_nfloat)
# 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
|
96a9ef85d547acac624be798cd43b8ec2695e0e69c9cf28f5b36391be8d901a2 | from collections import defaultdict
from functools import cmp_to_key
from .basic import Basic
from .compatibility import reduce, is_sequence
from .parameters import global_parameters
from .logic import _fuzzy_group, fuzzy_or, fuzzy_not
from .singleton import S
from .operations import AssocOp
from .cache import cacheit
from .numbers import ilcm, igcd
from .expr import Expr
# Key for sorting commutative args in canonical order
_args_sortkey = cmp_to_key(Basic.compare)
def _addsort(args):
# in-place sorting of args
args.sort(key=_args_sortkey)
def _unevaluated_Add(*args):
"""Return a well-formed unevaluated Add: Numbers are collected and
put in slot 0 and args are sorted. Use this when args have changed
but you still want to return an unevaluated Add.
Examples
========
>>> from sympy.core.add import _unevaluated_Add as uAdd
>>> from sympy import S, Add
>>> from sympy.abc import x, y
>>> a = uAdd(*[S(1.0), x, S(2)])
>>> a.args[0]
3.00000000000000
>>> a.args[1]
x
Beyond the Number being in slot 0, there is no other assurance of
order for the arguments since they are hash sorted. So, for testing
purposes, output produced by this in some other function can only
be tested against the output of this function or as one of several
options:
>>> opts = (Add(x, y, evaluated=False), Add(y, x, evaluated=False))
>>> a = uAdd(x, y)
>>> assert a in opts and a == uAdd(x, y)
>>> uAdd(x + 1, x + 2)
x + x + 3
"""
args = list(args)
newargs = []
co = S.Zero
while args:
a = args.pop()
if a.is_Add:
# this will keep nesting from building up
# so that x + (x + 1) -> x + x + 1 (3 args)
args.extend(a.args)
elif a.is_Number:
co += a
else:
newargs.append(a)
_addsort(newargs)
if co:
newargs.insert(0, co)
return Add._from_args(newargs)
class Add(Expr, AssocOp):
__slots__ = ()
is_Add = True
_args_type = Expr
@classmethod
def flatten(cls, seq):
"""
Takes the sequence "seq" of nested Adds and returns a flatten list.
Returns: (commutative_part, noncommutative_part, order_symbols)
Applies associativity, all terms are commutable with respect to
addition.
NB: the removal of 0 is already handled by AssocOp.__new__
See also
========
sympy.core.mul.Mul.flatten
"""
from sympy.calculus.util import AccumBounds
from sympy.matrices.expressions import MatrixExpr
from sympy.tensor.tensor import TensExpr
rv = None
if len(seq) == 2:
a, b = seq
if b.is_Rational:
a, b = b, a
if a.is_Rational:
if b.is_Mul:
rv = [a, b], [], None
if rv:
if all(s.is_commutative for s in rv[0]):
return rv
return [], rv[0], None
terms = {} # term -> coeff
# e.g. x**2 -> 5 for ... + 5*x**2 + ...
coeff = S.Zero # coefficient (Number or zoo) to always be in slot 0
# e.g. 3 + ...
order_factors = []
extra = []
for o in seq:
# O(x)
if o.is_Order:
if o.expr.is_zero:
continue
for o1 in order_factors:
if o1.contains(o):
o = None
break
if o is None:
continue
order_factors = [o] + [
o1 for o1 in order_factors if not o.contains(o1)]
continue
# 3 or NaN
elif o.is_Number:
if (o is S.NaN or coeff is S.ComplexInfinity and
o.is_finite is False) and not extra:
# we know for sure the result will be nan
return [S.NaN], [], None
if coeff.is_Number or isinstance(coeff, AccumBounds):
coeff += o
if coeff is S.NaN and not extra:
# we know for sure the result will be nan
return [S.NaN], [], None
continue
elif isinstance(o, AccumBounds):
coeff = o.__add__(coeff)
continue
elif isinstance(o, MatrixExpr):
# can't add 0 to Matrix so make sure coeff is not 0
extra.append(o)
continue
elif isinstance(o, TensExpr):
coeff = o.__add__(coeff) if coeff else o
continue
elif o is S.ComplexInfinity:
if coeff.is_finite is False and not extra:
# we know for sure the result will be nan
return [S.NaN], [], None
coeff = S.ComplexInfinity
continue
# Add([...])
elif o.is_Add:
# NB: here we assume Add is always commutative
seq.extend(o.args) # TODO zerocopy?
continue
# Mul([...])
elif o.is_Mul:
c, s = o.as_coeff_Mul()
# check for unevaluated Pow, e.g. 2**3 or 2**(-1/2)
elif o.is_Pow:
b, e = o.as_base_exp()
if b.is_Number and (e.is_Integer or
(e.is_Rational and e.is_negative)):
seq.append(b**e)
continue
c, s = S.One, o
else:
# everything else
c = S.One
s = o
# now we have:
# o = c*s, where
#
# c is a Number
# s is an expression with number factor extracted
# let's collect terms with the same s, so e.g.
# 2*x**2 + 3*x**2 -> 5*x**2
if s in terms:
terms[s] += c
if terms[s] is S.NaN and not extra:
# we know for sure the result will be nan
return [S.NaN], [], None
else:
terms[s] = c
# now let's construct new args:
# [2*x**2, x**3, 7*x**4, pi, ...]
newseq = []
noncommutative = False
for s, c in terms.items():
# 0*s
if c.is_zero:
continue
# 1*s
elif c is S.One:
newseq.append(s)
# c*s
else:
if s.is_Mul:
# Mul, already keeps its arguments in perfect order.
# so we can simply put c in slot0 and go the fast way.
cs = s._new_rawargs(*((c,) + s.args))
newseq.append(cs)
elif s.is_Add:
# we just re-create the unevaluated Mul
newseq.append(Mul(c, s, evaluate=False))
else:
# alternatively we have to call all Mul's machinery (slow)
newseq.append(Mul(c, s))
noncommutative = noncommutative or not s.is_commutative
# oo, -oo
if coeff is S.Infinity:
newseq = [f for f in newseq if not (f.is_extended_nonnegative or f.is_real)]
elif coeff is S.NegativeInfinity:
newseq = [f for f in newseq if not (f.is_extended_nonpositive or f.is_real)]
if coeff is S.ComplexInfinity:
# zoo might be
# infinite_real + finite_im
# finite_real + infinite_im
# infinite_real + infinite_im
# addition of a finite real or imaginary number won't be able to
# change the zoo nature; adding an infinite qualtity would result
# in a NaN condition if it had sign opposite of the infinite
# portion of zoo, e.g., infinite_real - infinite_real.
newseq = [c for c in newseq if not (c.is_finite and
c.is_extended_real is not None)]
# process O(x)
if order_factors:
newseq2 = []
for t in newseq:
for o in order_factors:
# x + O(x) -> O(x)
if o.contains(t):
t = None
break
# x + O(x**2) -> x + O(x**2)
if t is not None:
newseq2.append(t)
newseq = newseq2 + order_factors
# 1 + O(1) -> O(1)
for o in order_factors:
if o.contains(coeff):
coeff = S.Zero
break
# order args canonically
_addsort(newseq)
# current code expects coeff to be first
if coeff is not S.Zero:
newseq.insert(0, coeff)
if extra:
newseq += extra
noncommutative = True
# we are done
if noncommutative:
return [], newseq, None
else:
return newseq, [], None
@classmethod
def class_key(cls):
"""Nice order of classes"""
return 3, 1, cls.__name__
def as_coefficients_dict(a):
"""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}
"""
d = defaultdict(list)
for ai in a.args:
c, m = ai.as_coeff_Mul()
d[m].append(c)
for k, v in d.items():
if len(v) == 1:
d[k] = v[0]
else:
d[k] = Add(*v)
di = defaultdict(int)
di.update(d)
return di
@cacheit
def as_coeff_add(self, *deps):
"""
Returns a tuple (coeff, args) where self is treated as an Add and coeff
is the Number term and args is a tuple of all other terms.
Examples
========
>>> from sympy.abc import x
>>> (7 + 3*x).as_coeff_add()
(7, (3*x,))
>>> (7*x).as_coeff_add()
(0, (7*x,))
"""
if deps:
from sympy.utilities.iterables import sift
l1, l2 = sift(self.args, lambda x: x.has(*deps), binary=True)
return self._new_rawargs(*l2), tuple(l1)
coeff, notrat = self.args[0].as_coeff_add()
if coeff is not S.Zero:
return coeff, notrat + self.args[1:]
return S.Zero, self.args
def as_coeff_Add(self, rational=False, deps=None):
"""
Efficiently extract the coefficient of a summation.
"""
coeff, args = self.args[0], self.args[1:]
if coeff.is_Number and not rational or coeff.is_Rational:
return coeff, self._new_rawargs(*args)
return S.Zero, self
# Note, we intentionally do not implement Add.as_coeff_mul(). Rather, we
# let Expr.as_coeff_mul() just always return (S.One, self) for an Add. See
# issue 5524.
def _eval_power(self, e):
if e.is_Rational and self.is_number:
from sympy.core.evalf import pure_complex
from sympy.core.mul import _unevaluated_Mul
from sympy.core.exprtools import factor_terms
from sympy.core.function import expand_multinomial
from sympy.functions.elementary.complexes import sign
from sympy.functions.elementary.miscellaneous import sqrt
ri = pure_complex(self)
if ri:
r, i = ri
if e.q == 2:
D = sqrt(r**2 + i**2)
if D.is_Rational:
# (r, i, D) is a Pythagorean triple
root = sqrt(factor_terms((D - r)/2))**e.p
return root*expand_multinomial((
# principle value
(D + r)/abs(i) + sign(i)*S.ImaginaryUnit)**e.p)
elif e == -1:
return _unevaluated_Mul(
r - i*S.ImaginaryUnit,
1/(r**2 + i**2))
elif e.is_Number and abs(e) != 1:
# handle the Float case: (2.0 + 4*x)**e -> 4**e*(0.5 + x)**e
c, m = zip(*[i.as_coeff_Mul() for i in self.args])
if any(i.is_Float for i in c): # XXX should this always be done?
big = -1
for i in c:
if abs(i) >= big:
big = abs(i)
if big > 0 and big != 1:
from sympy.functions.elementary.complexes import sign
bigs = (big, -big)
c = [sign(i) if i in bigs else i/big for i in c]
addpow = Add(*[c*m for c, m in zip(c, m)])**e
return big**e*addpow
@cacheit
def _eval_derivative(self, s):
return self.func(*[a.diff(s) for a in self.args])
def _eval_nseries(self, x, n, logx):
terms = [t.nseries(x, n=n, logx=logx) for t in self.args]
return self.func(*terms)
def _matches_simple(self, expr, repl_dict):
# handle (w+3).matches('x+5') -> {w: x+2}
coeff, terms = self.as_coeff_add()
if len(terms) == 1:
return terms[0].matches(expr - coeff, repl_dict)
return
def matches(self, expr, repl_dict={}, old=False):
return self._matches_commutative(expr, repl_dict, old)
@staticmethod
def _combine_inverse(lhs, rhs):
"""
Returns lhs - rhs, but treats oo like a symbol so oo - oo
returns 0, instead of a nan.
"""
from sympy.simplify.simplify import signsimp
from sympy.core.symbol import Dummy
inf = (S.Infinity, S.NegativeInfinity)
if lhs.has(*inf) or rhs.has(*inf):
oo = Dummy('oo')
reps = {
S.Infinity: oo,
S.NegativeInfinity: -oo}
ireps = {v: k for k, v in reps.items()}
eq = signsimp(lhs.xreplace(reps) - rhs.xreplace(reps))
if eq.has(oo):
eq = eq.replace(
lambda x: x.is_Pow and x.base is oo,
lambda x: x.base)
return eq.xreplace(ireps)
else:
return signsimp(lhs - rhs)
@cacheit
def as_two_terms(self):
"""Return head and tail of self.
This is the most efficient way to get the head and tail of an
expression.
- if you want only the head, use self.args[0];
- if you want to process the arguments of the tail then use
self.as_coef_add() which gives the head and a tuple containing
the arguments of the tail when treated as an Add.
- if you want the coefficient when self is treated as a Mul
then use self.as_coeff_mul()[0]
>>> from sympy.abc import x, y
>>> (3*x - 2*y + 5).as_two_terms()
(5, 3*x - 2*y)
"""
return self.args[0], self._new_rawargs(*self.args[1:])
def as_numer_denom(self):
"""
Decomposes an expression to its numerator part and its
denominator part.
Examples
========
>>> from sympy.abc import x, y, z
>>> (x*y/z).as_numer_denom()
(x*y, z)
>>> (x*(y + 1)/y**7).as_numer_denom()
(x*(y + 1), y**7)
See Also
========
sympy.core.expr.Expr.as_numer_denom
"""
# clear rational denominator
content, expr = self.primitive()
ncon, dcon = content.as_numer_denom()
# collect numerators and denominators of the terms
nd = defaultdict(list)
for f in expr.args:
ni, di = f.as_numer_denom()
nd[di].append(ni)
# check for quick exit
if len(nd) == 1:
d, n = nd.popitem()
return self.func(
*[_keep_coeff(ncon, ni) for ni in n]), _keep_coeff(dcon, d)
# sum up the terms having a common denominator
for d, n in nd.items():
if len(n) == 1:
nd[d] = n[0]
else:
nd[d] = self.func(*n)
# assemble single numerator and denominator
denoms, numers = [list(i) for i in zip(*iter(nd.items()))]
n, d = self.func(*[Mul(*(denoms[:i] + [numers[i]] + denoms[i + 1:]))
for i in range(len(numers))]), Mul(*denoms)
return _keep_coeff(ncon, n), _keep_coeff(dcon, d)
def _eval_is_polynomial(self, syms):
return all(term._eval_is_polynomial(syms) for term in self.args)
def _eval_is_rational_function(self, syms):
return all(term._eval_is_rational_function(syms) for term in self.args)
def _eval_is_meromorphic(self, x, a):
return _fuzzy_group((arg.is_meromorphic(x, a) for arg in self.args),
quick_exit=True)
def _eval_is_algebraic_expr(self, syms):
return all(term._eval_is_algebraic_expr(syms) for term in self.args)
# assumption methods
_eval_is_real = lambda self: _fuzzy_group(
(a.is_real for a in self.args), quick_exit=True)
_eval_is_extended_real = lambda self: _fuzzy_group(
(a.is_extended_real for a in self.args), quick_exit=True)
_eval_is_complex = lambda self: _fuzzy_group(
(a.is_complex for a in self.args), quick_exit=True)
_eval_is_antihermitian = lambda self: _fuzzy_group(
(a.is_antihermitian for a in self.args), quick_exit=True)
_eval_is_finite = lambda self: _fuzzy_group(
(a.is_finite for a in self.args), quick_exit=True)
_eval_is_hermitian = lambda self: _fuzzy_group(
(a.is_hermitian for a in self.args), quick_exit=True)
_eval_is_integer = lambda self: _fuzzy_group(
(a.is_integer for a in self.args), quick_exit=True)
_eval_is_rational = lambda self: _fuzzy_group(
(a.is_rational for a in self.args), quick_exit=True)
_eval_is_algebraic = lambda self: _fuzzy_group(
(a.is_algebraic for a in self.args), quick_exit=True)
_eval_is_commutative = lambda self: _fuzzy_group(
a.is_commutative for a in self.args)
def _eval_is_infinite(self):
sawinf = False
for a in self.args:
ainf = a.is_infinite
if ainf is None:
return None
elif ainf is True:
# infinite+infinite might not be infinite
if sawinf is True:
return None
sawinf = True
return sawinf
def _eval_is_imaginary(self):
nz = []
im_I = []
for a in self.args:
if a.is_extended_real:
if a.is_zero:
pass
elif a.is_zero is False:
nz.append(a)
else:
return
elif a.is_imaginary:
im_I.append(a*S.ImaginaryUnit)
elif (S.ImaginaryUnit*a).is_extended_real:
im_I.append(a*S.ImaginaryUnit)
else:
return
b = self.func(*nz)
if b.is_zero:
return fuzzy_not(self.func(*im_I).is_zero)
elif b.is_zero is False:
return False
def _eval_is_zero(self):
if self.is_commutative is False:
# issue 10528: there is no way to know if a nc symbol
# is zero or not
return
nz = []
z = 0
im_or_z = False
im = False
for a in self.args:
if a.is_extended_real:
if a.is_zero:
z += 1
elif a.is_zero is False:
nz.append(a)
else:
return
elif a.is_imaginary:
im = True
elif (S.ImaginaryUnit*a).is_extended_real:
im_or_z = True
else:
return
if z == len(self.args):
return True
if len(nz) == 0 or len(nz) == len(self.args):
return None
b = self.func(*nz)
if b.is_zero:
if not im_or_z and not im:
return True
if im and not im_or_z:
return False
if b.is_zero is False:
return False
def _eval_is_odd(self):
l = [f for f in self.args if not (f.is_even is True)]
if not l:
return False
if l[0].is_odd:
return self._new_rawargs(*l[1:]).is_even
def _eval_is_irrational(self):
for t in self.args:
a = t.is_irrational
if a:
others = list(self.args)
others.remove(t)
if all(x.is_rational is True for x in others):
return True
return None
if a is None:
return
return False
def _eval_is_extended_positive(self):
from sympy.core.exprtools import _monotonic_sign
if self.is_number:
return super()._eval_is_extended_positive()
c, a = self.as_coeff_Add()
if not c.is_zero:
v = _monotonic_sign(a)
if v is not None:
s = v + c
if s != self and s.is_extended_positive and a.is_extended_nonnegative:
return True
if len(self.free_symbols) == 1:
v = _monotonic_sign(self)
if v is not None and v != self and v.is_extended_positive:
return True
pos = nonneg = nonpos = unknown_sign = False
saw_INF = set()
args = [a for a in self.args if not a.is_zero]
if not args:
return False
for a in args:
ispos = a.is_extended_positive
infinite = a.is_infinite
if infinite:
saw_INF.add(fuzzy_or((ispos, a.is_extended_nonnegative)))
if True in saw_INF and False in saw_INF:
return
if ispos:
pos = True
continue
elif a.is_extended_nonnegative:
nonneg = True
continue
elif a.is_extended_nonpositive:
nonpos = True
continue
if infinite is None:
return
unknown_sign = True
if saw_INF:
if len(saw_INF) > 1:
return
return saw_INF.pop()
elif unknown_sign:
return
elif not nonpos and not nonneg and pos:
return True
elif not nonpos and pos:
return True
elif not pos and not nonneg:
return False
def _eval_is_extended_nonnegative(self):
from sympy.core.exprtools import _monotonic_sign
if not self.is_number:
c, a = self.as_coeff_Add()
if not c.is_zero and a.is_extended_nonnegative:
v = _monotonic_sign(a)
if v is not None:
s = v + c
if s != self and s.is_extended_nonnegative:
return True
if len(self.free_symbols) == 1:
v = _monotonic_sign(self)
if v is not None and v != self and v.is_extended_nonnegative:
return True
def _eval_is_extended_nonpositive(self):
from sympy.core.exprtools import _monotonic_sign
if not self.is_number:
c, a = self.as_coeff_Add()
if not c.is_zero and a.is_extended_nonpositive:
v = _monotonic_sign(a)
if v is not None:
s = v + c
if s != self and s.is_extended_nonpositive:
return True
if len(self.free_symbols) == 1:
v = _monotonic_sign(self)
if v is not None and v != self and v.is_extended_nonpositive:
return True
def _eval_is_extended_negative(self):
from sympy.core.exprtools import _monotonic_sign
if self.is_number:
return super()._eval_is_extended_negative()
c, a = self.as_coeff_Add()
if not c.is_zero:
v = _monotonic_sign(a)
if v is not None:
s = v + c
if s != self and s.is_extended_negative and a.is_extended_nonpositive:
return True
if len(self.free_symbols) == 1:
v = _monotonic_sign(self)
if v is not None and v != self and v.is_extended_negative:
return True
neg = nonpos = nonneg = unknown_sign = False
saw_INF = set()
args = [a for a in self.args if not a.is_zero]
if not args:
return False
for a in args:
isneg = a.is_extended_negative
infinite = a.is_infinite
if infinite:
saw_INF.add(fuzzy_or((isneg, a.is_extended_nonpositive)))
if True in saw_INF and False in saw_INF:
return
if isneg:
neg = True
continue
elif a.is_extended_nonpositive:
nonpos = True
continue
elif a.is_extended_nonnegative:
nonneg = True
continue
if infinite is None:
return
unknown_sign = True
if saw_INF:
if len(saw_INF) > 1:
return
return saw_INF.pop()
elif unknown_sign:
return
elif not nonneg and not nonpos and neg:
return True
elif not nonneg and neg:
return True
elif not neg and not nonpos:
return False
def _eval_subs(self, old, new):
if not old.is_Add:
if old is S.Infinity and -old in self.args:
# foo - oo is foo + (-oo) internally
return self.xreplace({-old: -new})
return None
coeff_self, terms_self = self.as_coeff_Add()
coeff_old, terms_old = old.as_coeff_Add()
if coeff_self.is_Rational and coeff_old.is_Rational:
if terms_self == terms_old: # (2 + a).subs( 3 + a, y) -> -1 + y
return self.func(new, coeff_self, -coeff_old)
if terms_self == -terms_old: # (2 + a).subs(-3 - a, y) -> -1 - y
return self.func(-new, coeff_self, coeff_old)
if coeff_self.is_Rational and coeff_old.is_Rational \
or coeff_self == coeff_old:
args_old, args_self = self.func.make_args(
terms_old), self.func.make_args(terms_self)
if len(args_old) < len(args_self): # (a+b+c).subs(b+c,x) -> a+x
self_set = set(args_self)
old_set = set(args_old)
if old_set < self_set:
ret_set = self_set - old_set
return self.func(new, coeff_self, -coeff_old,
*[s._subs(old, new) for s in ret_set])
args_old = self.func.make_args(
-terms_old) # (a+b+c+d).subs(-b-c,x) -> a-x+d
old_set = set(args_old)
if old_set < self_set:
ret_set = self_set - old_set
return self.func(-new, coeff_self, coeff_old,
*[s._subs(old, new) for s in ret_set])
def removeO(self):
args = [a for a in self.args if not a.is_Order]
return self._new_rawargs(*args)
def getO(self):
args = [a for a in self.args if a.is_Order]
if args:
return self._new_rawargs(*args)
@cacheit
def extract_leading_order(self, symbols, point=None):
"""
Returns the leading term and its order.
Examples
========
>>> from sympy.abc import x
>>> (x + 1 + 1/x**5).extract_leading_order(x)
((x**(-5), O(x**(-5))),)
>>> (1 + x).extract_leading_order(x)
((1, O(1)),)
>>> (x + x**2).extract_leading_order(x)
((x, O(x)),)
"""
from sympy import Order
lst = []
symbols = list(symbols if is_sequence(symbols) else [symbols])
if not point:
point = [0]*len(symbols)
seq = [(f, Order(f, *zip(symbols, point))) for f in self.args]
for ef, of in seq:
for e, o in lst:
if o.contains(of) and o != of:
of = None
break
if of is None:
continue
new_lst = [(ef, of)]
for e, o in lst:
if of.contains(o) and o != of:
continue
new_lst.append((e, o))
lst = new_lst
return tuple(lst)
def as_real_imag(self, deep=True, **hints):
"""
returns a tuple representing a complex number
Examples
========
>>> from sympy import I
>>> (7 + 9*I).as_real_imag()
(7, 9)
>>> ((1 + I)/(1 - I)).as_real_imag()
(0, 1)
>>> ((1 + 2*I)*(1 + 3*I)).as_real_imag()
(-5, 5)
"""
sargs = self.args
re_part, im_part = [], []
for term in sargs:
re, im = term.as_real_imag(deep=deep)
re_part.append(re)
im_part.append(im)
return (self.func(*re_part), self.func(*im_part))
def _eval_as_leading_term(self, x):
from sympy import expand_mul, Order
old = self
expr = expand_mul(self)
if not expr.is_Add:
return expr.as_leading_term(x)
infinite = [t for t in expr.args if t.is_infinite]
leading_terms = [t.as_leading_term(x) for t in expr.args]
min, new_expr = Order(0), 0
try:
for term in leading_terms:
order = Order(term, x)
if not min or order not in min:
min = order
new_expr = term
elif min in order:
new_expr += term
except TypeError:
return expr
new_expr=new_expr.together()
if new_expr.is_Add:
new_expr = new_expr.simplify()
if not new_expr:
# simple leading term analysis gave us cancelled terms but we have to send
# back a term, so compute the leading term (via series)
return old.compute_leading_term(x)
elif new_expr is S.NaN:
return old.func._from_args(infinite)
else:
return new_expr
def _eval_adjoint(self):
return self.func(*[t.adjoint() for t in self.args])
def _eval_conjugate(self):
return self.func(*[t.conjugate() for t in self.args])
def _eval_transpose(self):
return self.func(*[t.transpose() for t in self.args])
def _sage_(self):
s = 0
for x in self.args:
s += x._sage_()
return s
def primitive(self):
"""
Return ``(R, self/R)`` where ``R``` is the Rational GCD of ``self```.
``R`` is collected only from the leading coefficient of each term.
Examples
========
>>> from sympy.abc import x, y
>>> (2*x + 4*y).primitive()
(2, x + 2*y)
>>> (2*x/3 + 4*y/9).primitive()
(2/9, 3*x + 2*y)
>>> (2*x/3 + 4.2*y).primitive()
(1/3, 2*x + 12.6*y)
No subprocessing of term factors is performed:
>>> ((2 + 2*x)*x + 2).primitive()
(1, x*(2*x + 2) + 2)
Recursive processing can be done with the ``as_content_primitive()``
method:
>>> ((2 + 2*x)*x + 2).as_content_primitive()
(2, x*(x + 1) + 1)
See also: primitive() function in polytools.py
"""
terms = []
inf = False
for a in self.args:
c, m = a.as_coeff_Mul()
if not c.is_Rational:
c = S.One
m = a
inf = inf or m is S.ComplexInfinity
terms.append((c.p, c.q, m))
if not inf:
ngcd = reduce(igcd, [t[0] for t in terms], 0)
dlcm = reduce(ilcm, [t[1] for t in terms], 1)
else:
ngcd = reduce(igcd, [t[0] for t in terms if t[1]], 0)
dlcm = reduce(ilcm, [t[1] for t in terms if t[1]], 1)
if ngcd == dlcm == 1:
return S.One, self
if not inf:
for i, (p, q, term) in enumerate(terms):
terms[i] = _keep_coeff(Rational((p//ngcd)*(dlcm//q)), term)
else:
for i, (p, q, term) in enumerate(terms):
if q:
terms[i] = _keep_coeff(Rational((p//ngcd)*(dlcm//q)), term)
else:
terms[i] = _keep_coeff(Rational(p, q), term)
# we don't need a complete re-flattening since no new terms will join
# so we just use the same sort as is used in Add.flatten. When the
# coefficient changes, the ordering of terms may change, e.g.
# (3*x, 6*y) -> (2*y, x)
#
# We do need to make sure that term[0] stays in position 0, however.
#
if terms[0].is_Number or terms[0] is S.ComplexInfinity:
c = terms.pop(0)
else:
c = None
_addsort(terms)
if c:
terms.insert(0, c)
return Rational(ngcd, dlcm), self._new_rawargs(*terms)
def as_content_primitive(self, radical=False, clear=True):
"""Return the tuple (R, self/R) where R is the positive Rational
extracted from self. If radical is True (default is False) then
common radicals will be removed and included as a factor of the
primitive expression.
Examples
========
>>> from sympy import sqrt
>>> (3 + 3*sqrt(2)).as_content_primitive()
(3, 1 + sqrt(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)))
See docstring of Expr.as_content_primitive for more examples.
"""
con, prim = self.func(*[_keep_coeff(*a.as_content_primitive(
radical=radical, clear=clear)) for a in self.args]).primitive()
if not clear and not con.is_Integer and prim.is_Add:
con, d = con.as_numer_denom()
_p = prim/d
if any(a.as_coeff_Mul()[0].is_Integer for a in _p.args):
prim = _p
else:
con /= d
if radical and prim.is_Add:
# look for common radicals that can be removed
args = prim.args
rads = []
common_q = None
for m in args:
term_rads = defaultdict(list)
for ai in Mul.make_args(m):
if ai.is_Pow:
b, e = ai.as_base_exp()
if e.is_Rational and b.is_Integer:
term_rads[e.q].append(abs(int(b))**e.p)
if not term_rads:
break
if common_q is None:
common_q = set(term_rads.keys())
else:
common_q = common_q & set(term_rads.keys())
if not common_q:
break
rads.append(term_rads)
else:
# process rads
# keep only those in common_q
for r in rads:
for q in list(r.keys()):
if q not in common_q:
r.pop(q)
for q in r:
r[q] = prod(r[q])
# find the gcd of bases for each q
G = []
for q in common_q:
g = reduce(igcd, [r[q] for r in rads], 0)
if g != 1:
G.append(g**Rational(1, q))
if G:
G = Mul(*G)
args = [ai/G for ai in args]
prim = G*prim.func(*args)
return con, prim
@property
def _sorted_args(self):
from sympy.core.compatibility import default_sort_key
return tuple(sorted(self.args, key=default_sort_key))
def _eval_difference_delta(self, n, step):
from sympy.series.limitseq import difference_delta as dd
return self.func(*[dd(a, n, step) for a in self.args])
@property
def _mpc_(self):
"""
Convert self to an mpmath mpc if possible
"""
from sympy.core.numbers import I, Float
re_part, rest = self.as_coeff_Add()
im_part, imag_unit = rest.as_coeff_Mul()
if not imag_unit == I:
# ValueError may seem more reasonable but since it's a @property,
# we need to use AttributeError to keep from confusing things like
# hasattr.
raise AttributeError("Cannot convert Add to mpc. Must be of the form Number + Number*I")
return (Float(re_part)._mpf_, Float(im_part)._mpf_)
def __neg__(self):
if not global_parameters.distribute:
return super().__neg__()
return Add(*[-i for i in self.args])
from .mul import Mul, _keep_coeff, prod
from sympy.core.numbers import Rational
|
34c1b0035ea9b9e8299783bbdb0598a74aa158e8b2e70f41b5e097a219afe9f0 | from typing import Tuple as tTuple
from .sympify import sympify, _sympify, SympifyError
from .basic import Basic, Atom
from .singleton import S
from .evalf import EvalfMixin, pure_complex
from .decorators import call_highest_priority, sympify_method_args, sympify_return
from .cache import cacheit
from .compatibility import reduce, as_int, default_sort_key, Iterable
from sympy.utilities.misc import func_name
from mpmath.libmp import mpf_log, prec_to_dps
from collections import defaultdict
@sympify_method_args
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__ = () # type: tTuple[str, ...]
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
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
def __eq__(self, other):
try:
other = _sympify(other)
if not isinstance(other, Expr):
return False
except (SympifyError, SyntaxError):
return False
# check for pure number expr
if not (self.is_Number and other.is_Number) and (
type(self) != type(other)):
return False
a, b = self._hashable_content(), other._hashable_content()
if a != b:
return False
# check number *in* an expression
for a, b in zip(a, b):
if not isinstance(a, Expr):
continue
if a.is_Number and type(a) != type(b):
return False
return True
# ***************
# * 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):
# Mul has its own __neg__ routine, so we just
# create a 2-args Mul with the -1 in the canonical
# slot 0.
c = self.is_commutative
return Mul._from_args((S.NegativeOne, self), c)
def __abs__(self):
from sympy import Abs
return Abs(self)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__radd__')
def __add__(self, other):
return Add(self, other)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__add__')
def __radd__(self, other):
return Add(other, self)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__rsub__')
def __sub__(self, other):
return Add(self, -other)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__sub__')
def __rsub__(self, other):
return Add(other, -self)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__rmul__')
def __mul__(self, other):
return Mul(self, other)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__mul__')
def __rmul__(self, other):
return Mul(other, self)
@sympify_return([('other', 'Expr')], 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
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__pow__')
def __rpow__(self, other):
return Pow(other, self)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__rdiv__')
def __div__(self, other):
denom = Pow(other, S.NegativeOne)
if self is S.One:
return denom
else:
return Mul(self, denom)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__div__')
def __rdiv__(self, other):
denom = Pow(self, S.NegativeOne)
if other is S.One:
return denom
else:
return Mul(other, denom)
__truediv__ = __div__
__rtruediv__ = __rdiv__
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__rmod__')
def __mod__(self, other):
return Mod(self, other)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__mod__')
def __rmod__(self, other):
return Mod(other, self)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__rfloordiv__')
def __floordiv__(self, other):
from sympy.functions.elementary.integers import floor
return floor(self / other)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__floordiv__')
def __rfloordiv__(self, other):
from sympy.functions.elementary.integers import floor
return floor(other / self)
@sympify_return([('other', 'Expr')], NotImplemented)
@call_highest_priority('__rdivmod__')
def __divmod__(self, other):
from sympy.functions.elementary.integers import floor
return floor(self / other), Mod(self, other)
@sympify_return([('other', 'Expr')], 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 _cmp(self, other, op, cls):
assert op in ("<", ">", "<=", ">=")
try:
other = _sympify(other)
except SympifyError:
return NotImplemented
if not isinstance(other, Expr):
return NotImplemented
for me in (self, other):
if me.is_extended_real is False:
raise TypeError("Invalid comparison of non-real %s" % me)
if me is S.NaN:
raise TypeError("Invalid NaN comparison")
n2 = _n2(self, other)
if n2 is not None:
# use float comparison for infinity.
# otherwise get stuck in infinite recursion
if n2 in (S.Infinity, S.NegativeInfinity):
n2 = float(n2)
if op == "<":
return _sympify(n2 < 0)
elif op == ">":
return _sympify(n2 > 0)
elif op == "<=":
return _sympify(n2 <= 0)
else: # >=
return _sympify(n2 >= 0)
if self.is_extended_real and other.is_extended_real:
if op in ("<=", ">") \
and ((self.is_infinite and self.is_extended_negative) \
or (other.is_infinite and other.is_extended_positive)):
return S.true if op == "<=" else S.false
if op in ("<", ">=") \
and ((self.is_infinite and self.is_extended_positive) \
or (other.is_infinite and other.is_extended_negative)):
return S.true if op == ">=" else S.false
diff = self - other
if diff is not S.NaN:
if op == "<":
test = diff.is_extended_negative
elif op == ">":
test = diff.is_extended_positive
elif op == "<=":
test = diff.is_extended_nonpositive
else: # >=
test = diff.is_extended_nonnegative
if test is not None:
return S.true if test == True else S.false
# return unevaluated comparison object
return cls(self, other, evaluate=False)
def __ge__(self, other):
from sympy import GreaterThan
return self._cmp(other, ">=", GreaterThan)
def __le__(self, other):
from sympy import LessThan
return self._cmp(other, "<=", LessThan)
def __gt__(self, other):
from sympy import StrictGreaterThan
return self._cmp(other, ">", StrictGreaterThan)
def __lt__(self, other):
from sympy import StrictLessThan
return self._cmp(other, "<", StrictLessThan)
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 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.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.testing.randtest.random_complex_number
"""
free = self.free_symbols
prec = 1
if free:
from sympy.testing.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, a few 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.
3) finding out zeros of denominator expression with free_symbols.
It won't be constant if there are zeros. It gives more negative
answers for expression that are not constant.
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
"""
def check_denominator_zeros(expression):
from sympy.solvers.solvers import denoms
retNone = False
for den in denoms(expression):
z = den.is_zero
if z is True:
return True
if z is None:
retNone = True
if retNone:
return None
return False
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
cd = check_denominator_zeros(self)
if cd is True:
return False
elif cd is None:
return None
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.solvers import solve
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 not diff.is_number:
if constant is None:
# 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:
# this gives a number whether there are free symbols or not
ndiff = diff._random()
# is_comparable will work whether the result is real
# or complex; it could be None, however.
if ndiff and ndiff.is_comparable:
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.
#
# removed
# ns = nsimplify(diff)
# if diff.is_number and (not ns or ns == diff):
#
# The thought was that if it nsimplifies to 0 that's a sure sign
# to try the following to prove it; or if it changed but wasn't
# zero that might be a sign that it's not going to be easy to
# prove. But tests seem to be working without that logic.
#
if diff.is_number:
# 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.
sol = solve(diff, s, simplify=False)
if sol:
if s in sol:
# the self-consistent result is present
return True
if all(si.is_Integer for si in sol):
# perfect powers are removed at instantiation
# so surd s cannot be an integer
return False
if all(i.is_algebraic is False for i in sol):
# a surd is algebraic
return False
if any(si in surds for si in sol):
# it wasn't equal to s but it is in surds
# and different surds are not equal
return False
if any(nsimplify(s - si) == 0 and
simplify(s - si) == 0 for si 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 (is_comparable) 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):
finite = self.is_finite
if finite is False:
return False
extended_positive = self.is_extended_positive
if finite is True:
return extended_positive
if extended_positive is False:
return False
def _eval_is_negative(self):
finite = self.is_finite
if finite is False:
return False
extended_negative = self.is_extended_negative
if finite is True:
return extended_negative
if extended_negative is False:
return False
def _eval_is_extended_positive_negative(self, positive):
from sympy.polys.numberfields import minimal_polynomial
from sympy.polys.polyerrors import NotAlgebraic
if self.is_number:
if self.is_extended_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 is S.NaN:
return None
r, i = self.evalf(2).as_real_imag()
if not i.is_Number or not r.is_Number:
return False
if r._prec != 1 and i._prec != 1:
return bool(not i and ((r > 0) if positive else (r < 0)))
elif r._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_extended_positive(self):
return self._eval_is_extended_positive_negative(positive=True)
def _eval_is_extended_negative(self):
return self._eval_is_extended_positive_negative(positive=False)
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.')
def _eval_endpoint(left):
c = a if left else b
if c is None:
return 0
else:
C = self.subs(x, c)
if C.has(S.NaN, S.Infinity, S.NegativeInfinity,
S.ComplexInfinity, AccumBounds):
if (a < b) != False:
C = limit(self, x, c, "+" if left else "-")
else:
C = limit(self, x, c, "-" if left else "+")
if isinstance(C, Limit):
raise NotImplementedError("Could not compute limit")
return C
if a == b:
return 0
A = _eval_endpoint(left=True)
if A is S.NaN:
return A
B = _eval_endpoint(left=False)
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_extended_real:
return self
elif self.is_imaginary:
return -self
def conjugate(self):
"""Returns the complex conjugate of '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 or self.is_infinite):
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_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_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_extended_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.Poly.coeff_monomial: efficiently find the single coefficient of a monomial in Poly
sympy.polys.polytools.Poly.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
one_c = self_c or x_c
xargs, nx = x.args_cnc(cset=True, warn=bool(not x_c))
# find the parts that pass the commutative terms
for a in args:
margs, nc = a.args_cnc(cset=True, warn=bool(not self_c))
if nc is None:
nc = []
if len(xargs) > len(margs):
continue
resid = margs.difference(xargs)
if len(resid) + len(xargs) == len(margs):
if one_c:
co.append(Mul(*(list(resid) + nc)))
else:
co.append((resid, nc))
if one_c:
if co == []:
return S.Zero
elif co:
return Add(*co)
else: # both 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.Poly.coeff_monomial: efficiently find the single coefficient of a monomial in Poly
sympy.polys.polytools.Poly.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), sympy.core.add.Add.as_two_terms(),
sympy.core.mul.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)
>>> ((x*(1 + y) + 0.4*x*(3 + 3*y))**2).as_content_primitive()
(1, 4.84*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
"""
from .add import _unevaluated_Add
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)
else:
return x
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)
if cs is not S.One:
args = [cs*t for t in newargs]
# args may be in different order
return _unevaluated_Add(*args)
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_zero:
return self
elif c == self:
return S.Zero
elif self == 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.Zero
res = S.One
args = Mul.make_args(self)
exps = []
for arg in args:
if isinstance(arg, exp_polar):
exps += [arg.exp]
else:
res *= arg
piimult = S.Zero
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.Half)*2
n += branchfact/2
c = coeff - branchfact
if allow_half:
nc = c.extract_additively(1)
if nc is not None:
n += S.Half
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.NegativeInfinity, 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_meromorphic(self, x, a):
# Default implementation, return True for constants.
return None if self.has(x) else True
def is_meromorphic(self, x, a):
"""
This tests whether an expression is meromorphic as
a function of the given symbol ``x`` at the point ``a``.
This method is intended as a quick test that will return
None if no decision can be made without simplification or
more detailed analysis.
Examples
========
>>> from sympy import zoo, log, sin, sqrt
>>> from sympy.abc import x
>>> f = 1/x**2 + 1 - 2*x**3
>>> f.is_meromorphic(x, 0)
True
>>> f.is_meromorphic(x, 1)
True
>>> f.is_meromorphic(x, zoo)
True
>>> g = x**log(3)
>>> g.is_meromorphic(x, 0)
False
>>> g.is_meromorphic(x, 1)
True
>>> g.is_meromorphic(x, zoo)
False
>>> h = sin(1/x)*x**2
>>> h.is_meromorphic(x, 0)
False
>>> h.is_meromorphic(x, 1)
True
>>> h.is_meromorphic(x, zoo)
True
Multivalued functions are considered meromorphic when their
branches are meromorphic. Thus most functions are meromorphic
everywhere except at essential singularities and branch points.
In particular, they will be meromorphic also on branch cuts
except at their endpoints.
>>> log(x).is_meromorphic(x, -1)
True
>>> log(x).is_meromorphic(x, 0)
False
>>> sqrt(x).is_meromorphic(x, -1)
True
>>> sqrt(x).is_meromorphic(x, 0)
False
"""
if not x.is_symbol:
raise TypeError("{} should be of symbol type".format(x))
a = sympify(a)
return self._eval_is_meromorphic(x, a)
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.
Parameters
==========
expr : Expression
The expression whose series is to be expanded.
x : Symbol
It is the variable of the expression to be calculated.
x0 : Value
The value around which ``x`` is calculated. Can be any value
from ``-oo`` to ``oo``.
n : Value
The number of terms upto which the series is to be expanded.
dir : String, optional
The series-expansion can be bi-directional. If ``dir="+"``,
then (x->x0+). If ``dir="-", then (x->x0-). For infinite
``x0`` (``oo`` or ``-oo``), the ``dir`` argument is determined
from the direction of the infinity (i.e., ``dir="-"`` for
``oo``).
logx : optional
It is used to replace any log(x) in the returned series with a
symbolic value rather than evaluating the actual value.
Examples
========
>>> from sympy import cos, exp, tan
>>> 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
>>> f = tan(x)
>>> f.series(x, 2, 6, "+")
tan(2) + (1 + tan(2)**2)*(x - 2) + (x - 2)**2*(tan(2)**3 + tan(2)) +
(x - 2)**3*(1/3 + 4*tan(2)**2/3 + tan(2)**4) + (x - 2)**4*(tan(2)**5 +
5*tan(2)**3/3 + 2*tan(2)/3) + (x - 2)**5*(2/15 + 17*tan(2)**2/15 +
2*tan(2)**4 + tan(2)**6) + O((x - 2)**6, (x, 2))
>>> f.series(x, 2, 3, "-")
tan(2) + (2 - x)*(-tan(2)**2 - 1) + (2 - x)**2*(tan(2)**3 + tan(2))
+ O((x - 2)**3, (x, 2))
Returns
=======
Expr : Expression
Series expansion of the expression about x0
Raises
======
TypeError
If "n" and "x0" are infinity objects
PoleError
If "x0" is an infinity object
"""
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 aseries(self, x=None, n=6, bound=0, hir=False):
"""Asymptotic Series expansion of self.
This is equivalent to ``self.series(x, oo, n)``.
Parameters
==========
self : Expression
The expression whose series is to be expanded.
x : Symbol
It is the variable of the expression to be calculated.
n : Value
The number of terms upto which the series is to be expanded.
hir : Boolean
Set this parameter to be True to produce hierarchical series.
It stops the recursion at an early level and may provide nicer
and more useful results.
bound : Value, Integer
Use the ``bound`` parameter to give limit on rewriting
coefficients in its normalised form.
Examples
========
>>> from sympy import sin, exp
>>> from sympy.abc import x
>>> e = sin(1/x + exp(-x)) - sin(1/x)
>>> e.aseries(x)
(1/(24*x**4) - 1/(2*x**2) + 1 + O(x**(-6), (x, oo)))*exp(-x)
>>> e.aseries(x, n=3, hir=True)
-exp(-2*x)*sin(1/x)/2 + exp(-x)*cos(1/x) + O(exp(-3*x), (x, oo))
>>> e = exp(exp(x)/(1 - 1/x))
>>> e.aseries(x)
exp(exp(x)/(1 - 1/x))
>>> e.aseries(x, bound=3)
exp(exp(x)/x**2)*exp(exp(x)/x)*exp(-exp(x) + exp(x)/(1 - 1/x) - exp(x)/x - exp(x)/x**2)*exp(exp(x))
Returns
=======
Expr
Asymptotic series expansion of the expression.
Notes
=====
This algorithm is directly induced from the limit computational algorithm provided by Gruntz.
It majorly uses the mrv and rewrite sub-routines. The overall idea of this algorithm is first
to look for the most rapidly varying subexpression w of a given expression f and then expands f
in a series in w. Then same thing is recursively done on the leading coefficient
till we get constant coefficients.
If the most rapidly varying subexpression of a given expression f is f itself,
the algorithm tries to find a normalised representation of the mrv set and rewrites f
using this normalised representation.
If the expansion contains an order term, it will be either ``O(x ** (-n))`` or ``O(w ** (-n))``
where ``w`` belongs to the most rapidly varying expression of ``self``.
References
==========
.. [1] A New Algorithm for Computing Asymptotic Series - Dominik Gruntz
.. [2] Gruntz thesis - p90
.. [3] http://en.wikipedia.org/wiki/Asymptotic_expansion
See Also
========
Expr.aseries: See the docstring of this function for complete details of this wrapper.
"""
from sympy import Order, Dummy
from sympy.functions import exp, log
from sympy.series.gruntz import mrv, rewrite
if x.is_positive is x.is_negative is None:
xpos = Dummy('x', positive=True)
return self.subs(x, xpos).aseries(xpos, n, bound, hir).subs(xpos, x)
om, exps = mrv(self, x)
# We move one level up by replacing `x` by `exp(x)`, and then
# computing the asymptotic series for f(exp(x)). Then asymptotic series
# can be obtained by moving one-step back, by replacing x by ln(x).
if x in om:
s = self.subs(x, exp(x)).aseries(x, n, bound, hir).subs(x, log(x))
if s.getO():
return s + Order(1/x**n, (x, S.Infinity))
return s
k = Dummy('k', positive=True)
# f is rewritten in terms of omega
func, logw = rewrite(exps, om, x, k)
if self in om:
if bound <= 0:
return self
s = (self.exp).aseries(x, n, bound=bound)
s = s.func(*[t.removeO() for t in s.args])
res = exp(s.subs(x, 1/x).as_leading_term(x).subs(x, 1/x))
func = exp(self.args[0] - res.args[0]) / k
logw = log(1/res)
s = func.series(k, 0, n)
# Hierarchical series
if hir:
return s.subs(k, exp(logw))
o = s.getO()
terms = sorted(Add.make_args(s.removeO()), key=lambda i: int(i.as_coeff_exponent(k)[1]))
s = S.Zero
has_ord = False
# Then we recursively expand these coefficients one by one into
# their asymptotic series in terms of their most rapidly varying subexpressions.
for t in terms:
coeff, expo = t.as_coeff_exponent(k)
if coeff.has(x):
# Recursive step
snew = coeff.aseries(x, n, bound=bound-1)
if has_ord and snew.getO():
break
elif snew.getO():
has_ord = True
s += (snew * k**expo)
else:
s += t
if not o or has_ord:
return s.subs(k, exp(logw))
return (s + o).subs(k, exp(logw))
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:
newseries = series.cancel()
if not newseries.is_Order:
if series.is_Add:
yield series.removeO()
else:
yield series
return
else:
series = newseries
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, Piecewise, piecewise_fold
from sympy.series.gruntz import calculate_series
if self.has(Piecewise):
expr = piecewise_fold(self)
else:
expr = self
if self.removeO() == 0:
return self
if logx is None:
d = Dummy('logx')
s = calculate_series(expr, x, d).subs(d, log(x))
else:
s = calculate_series(expr, 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 %s but got %s""" % (self, x, 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 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, 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 ``round`` function uses the SymPy ``round`` method so it
will always return a SymPy number (not a Python float or int):
>>> isinstance(round(S(123), -2), Number)
True
"""
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_extended_real:
r, i = x.as_real_imag()
return r.round(n) + S.ImaginaryUnit*i.round(n)
if not x:
return S.Zero if n is None else x
p = as_int(n or 0)
if x.is_Integer:
return Integer(round(int(x), p))
digits_to_decimal = _mag(x) # _mag(12) = 2, _mag(.012) = -1
allow = 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 = 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), dps) # keep same precision
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()._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_meromorphic(self, x, a):
from sympy.calculus.util import AccumBounds
return (not self.is_Number or self.is_finite) and not isinstance(self, AccumBounds)
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 x
>>> 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 import Piecewise, cos, pi
>>> from sympy.core.expr import unchanged
>>> from sympy.abc import x
>>> unchanged(cos, 1) # instead of assert cos(1) == cos(1)
True
>>> unchanged(cos, pi)
False
Comparison of args uses the builtin capabilities of the object's
arguments to test for equality so args can be defined loosely. Here,
the ExprCondPair arguments of Piecewise compare as equal to the
tuples that can be used to create the Piecewise:
>>> unchanged(Piecewise, (x, x > 1), (0, True))
True
"""
f = func(*args)
return f.func == func and f.args == args
class ExprBuilder:
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
|
0e7ec31942b69593e56301ebd13e25440d0c244b1336849c4e4e826ac1d5e9f1 | from typing import Dict, Type, Union
from sympy.utilities.exceptions import SymPyDeprecationWarning
from .add import _unevaluated_Add, Add
from .basic import S, Atom
from .compatibility import ordered
from .basic import Basic
from .expr import Expr
from .evalf import EvalfMixin
from .sympify import _sympify
from .parameters import global_parameters
from sympy.logic.boolalg import Boolean, BooleanAtom
__all__ = (
'Rel', 'Eq', 'Ne', 'Lt', 'Le', 'Gt', 'Ge',
'Relational', 'Equality', 'Unequality', 'StrictLessThan', 'LessThan',
'StrictGreaterThan', 'GreaterThan',
)
def _nontrivBool(side):
return isinstance(side, Boolean) and \
not isinstance(side, (BooleanAtom, Atom))
# Note, see issue 4986. Ideally, we wouldn't want to subclass both Boolean
# and Expr.
def _canonical(cond):
# return a condition in which all relationals are canonical
reps = {r: r.canonical for r in cond.atoms(Relational)}
return cond.xreplace(reps)
# XXX: AttributeError was being caught here but it wasn't triggered by any of
# the tests so I've removed it...
class Relational(Boolean, EvalfMixin):
"""Base class for all relation types.
Subclasses of Relational should generally be instantiated directly, but
Relational can be instantiated with a valid ``rop`` value to dispatch to
the appropriate subclass.
Parameters
==========
rop : str or None
Indicates what subclass to instantiate. Valid values can be found
in the keys of Relational.ValidRelationOperator.
Examples
========
>>> from sympy import Rel
>>> from sympy.abc import x, y
>>> Rel(y, x + x**2, '==')
Eq(y, x**2 + x)
"""
__slots__ = ()
ValidRelationOperator = {} # type: Dict[Union[str, None], Type[Relational]]
is_Relational = True
# ValidRelationOperator - Defined below, because the necessary classes
# have not yet been defined
def __new__(cls, lhs, rhs, rop=None, **assumptions):
# If called by a subclass, do nothing special and pass on to Basic.
if cls is not Relational:
return Basic.__new__(cls, lhs, rhs, **assumptions)
# XXX: Why do this? There should be a separate function to make a
# particular subclass of Relational from a string.
#
# If called directly with an operator, look up the subclass
# corresponding to that operator and delegate to it
cls = cls.ValidRelationOperator.get(rop, None)
if cls is None:
raise ValueError("Invalid relational operator symbol: %r" % rop)
if not issubclass(cls, (Eq, Ne)):
# validate that Booleans are not being used in a relational
# other than Eq/Ne;
# Note: Symbol is a subclass of Boolean but is considered
# acceptable here.
if any(map(_nontrivBool, (lhs, rhs))):
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.
'''))
return cls(lhs, rhs, **assumptions)
@property
def lhs(self):
"""The left-hand side of the relation."""
return self._args[0]
@property
def rhs(self):
"""The right-hand side of the relation."""
return self._args[1]
@property
def reversed(self):
"""Return the relationship with sides reversed.
Examples
========
>>> from sympy import Eq
>>> from sympy.abc import x
>>> Eq(x, 1)
Eq(x, 1)
>>> _.reversed
Eq(1, x)
>>> x < 1
x < 1
>>> _.reversed
1 > x
"""
ops = {Eq: Eq, Gt: Lt, Ge: Le, Lt: Gt, Le: Ge, Ne: Ne}
a, b = self.args
return Relational.__new__(ops.get(self.func, self.func), b, a)
@property
def reversedsign(self):
"""Return the relationship with signs reversed.
Examples
========
>>> from sympy import Eq
>>> from sympy.abc import x
>>> Eq(x, 1)
Eq(x, 1)
>>> _.reversedsign
Eq(-x, -1)
>>> x < 1
x < 1
>>> _.reversedsign
-x > -1
"""
a, b = self.args
if not (isinstance(a, BooleanAtom) or isinstance(b, BooleanAtom)):
ops = {Eq: Eq, Gt: Lt, Ge: Le, Lt: Gt, Le: Ge, Ne: Ne}
return Relational.__new__(ops.get(self.func, self.func), -a, -b)
else:
return self
@property
def negated(self):
"""Return the negated relationship.
Examples
========
>>> from sympy import Eq
>>> from sympy.abc import x
>>> Eq(x, 1)
Eq(x, 1)
>>> _.negated
Ne(x, 1)
>>> x < 1
x < 1
>>> _.negated
x >= 1
Notes
=====
This works more or less identical to ``~``/``Not``. The difference is
that ``negated`` returns the relationship even if ``evaluate=False``.
Hence, this is useful in code when checking for e.g. negated relations
to existing ones as it will not be affected by the `evaluate` flag.
"""
ops = {Eq: Ne, Ge: Lt, Gt: Le, Le: Gt, Lt: Ge, Ne: Eq}
# If there ever will be new Relational subclasses, the following line
# will work until it is properly sorted out
# return ops.get(self.func, lambda a, b, evaluate=False: ~(self.func(a,
# b, evaluate=evaluate)))(*self.args, evaluate=False)
return Relational.__new__(ops.get(self.func), *self.args)
def _eval_evalf(self, prec):
return self.func(*[s._evalf(prec) for s in self.args])
@property
def canonical(self):
"""Return a canonical form of the relational by putting a
number on the rhs, canonically removing a sign or else
ordering the args canonically. No other simplification is
attempted.
Examples
========
>>> from sympy.abc import x, y
>>> x < 2
x < 2
>>> _.reversed.canonical
x < 2
>>> (-y < x).canonical
x > -y
>>> (-y > x).canonical
x < -y
>>> (-y < -x).canonical
x < y
"""
args = self.args
r = self
if r.rhs.is_number:
if r.rhs.is_Number and r.lhs.is_Number and r.lhs > r.rhs:
r = r.reversed
elif r.lhs.is_number:
r = r.reversed
elif tuple(ordered(args)) != args:
r = r.reversed
LHS_CEMS = getattr(r.lhs, 'could_extract_minus_sign', None)
RHS_CEMS = getattr(r.rhs, 'could_extract_minus_sign', None)
if isinstance(r.lhs, BooleanAtom) or isinstance(r.rhs, BooleanAtom):
return r
# Check if first value has negative sign
if LHS_CEMS and LHS_CEMS():
return r.reversedsign
elif not r.rhs.is_number and RHS_CEMS and RHS_CEMS():
# Right hand side has a minus, but not lhs.
# How does the expression with reversed signs behave?
# This is so that expressions of the type
# Eq(x, -y) and Eq(-x, y)
# have the same canonical representation
expr1, _ = ordered([r.lhs, -r.rhs])
if expr1 != r.lhs:
return r.reversed.reversedsign
return r
def equals(self, other, failing_expression=False):
"""Return True if the sides of the relationship are mathematically
identical and the type of relationship is the same.
If failing_expression is True, return the expression whose truth value
was unknown."""
if isinstance(other, Relational):
if self == other or self.reversed == other:
return True
a, b = self, other
if a.func in (Eq, Ne) or b.func in (Eq, Ne):
if a.func != b.func:
return False
left, right = [i.equals(j,
failing_expression=failing_expression)
for i, j in zip(a.args, b.args)]
if left is True:
return right
if right is True:
return left
lr, rl = [i.equals(j, failing_expression=failing_expression)
for i, j in zip(a.args, b.reversed.args)]
if lr is True:
return rl
if rl is True:
return lr
e = (left, right, lr, rl)
if all(i is False for i in e):
return False
for i in e:
if i not in (True, False):
return i
else:
if b.func != a.func:
b = b.reversed
if a.func != b.func:
return False
left = a.lhs.equals(b.lhs,
failing_expression=failing_expression)
if left is False:
return False
right = a.rhs.equals(b.rhs,
failing_expression=failing_expression)
if right is False:
return False
if left is True:
return right
return left
def _eval_simplify(self, **kwargs):
r = self
r = r.func(*[i.simplify(**kwargs) for i in r.args])
if r.is_Relational:
dif = r.lhs - r.rhs
# replace dif with a valid Number that will
# allow a definitive comparison with 0
v = None
if dif.is_comparable:
v = dif.n(2)
elif dif.equals(0): # XXX this is expensive
v = S.Zero
if v is not None:
r = r.func._eval_relation(v, S.Zero)
r = r.canonical
# If there is only one symbol in the expression,
# try to write it on a simplified form
free = list(filter(lambda x: x.is_real is not False, r.free_symbols))
if len(free) == 1:
try:
from sympy.solvers.solveset import linear_coeffs
x = free.pop()
dif = r.lhs - r.rhs
m, b = linear_coeffs(dif, x)
if m.is_zero is False:
if m.is_negative:
# Dividing with a negative number, so change order of arguments
# canonical will put the symbol back on the lhs later
r = r.func(-b/m, x)
else:
r = r.func(x, -b/m)
else:
r = r.func(b, S.zero)
except ValueError:
# maybe not a linear function, try polynomial
from sympy.polys import Poly, poly, PolynomialError, gcd
try:
p = poly(dif, x)
c = p.all_coeffs()
constant = c[-1]
c[-1] = 0
scale = gcd(c)
c = [ctmp/scale for ctmp in c]
r = r.func(Poly.from_list(c, x).as_expr(), -constant/scale)
except PolynomialError:
pass
elif len(free) >= 2:
try:
from sympy.solvers.solveset import linear_coeffs
from sympy.polys import gcd
free = list(ordered(free))
dif = r.lhs - r.rhs
m = linear_coeffs(dif, *free)
constant = m[-1]
del m[-1]
scale = gcd(m)
m = [mtmp/scale for mtmp in m]
nzm = list(filter(lambda f: f[0] != 0, list(zip(m, free))))
if scale.is_zero is False:
if constant != 0:
# lhs: expression, rhs: constant
newexpr = Add(*[i*j for i, j in nzm])
r = r.func(newexpr, -constant/scale)
else:
# keep first term on lhs
lhsterm = nzm[0][0]*nzm[0][1]
del nzm[0]
newexpr = Add(*[i*j for i, j in nzm])
r = r.func(lhsterm, -newexpr)
else:
r = r.func(constant, S.zero)
except ValueError:
pass
# Did we get a simplified result?
r = r.canonical
measure = kwargs['measure']
if measure(r) < kwargs['ratio']*measure(self):
return r
else:
return self
def _eval_trigsimp(self, **opts):
from sympy.simplify import trigsimp
return self.func(trigsimp(self.lhs, **opts), trigsimp(self.rhs, **opts))
def expand(self, **kwargs):
args = (arg.expand(**kwargs) for arg in self.args)
return self.func(*args)
def __nonzero__(self):
raise TypeError("cannot determine truth value of Relational")
__bool__ = __nonzero__
def _eval_as_set(self):
# self is univariate and periodicity(self, x) in (0, None)
from sympy.solvers.inequalities import solve_univariate_inequality
from sympy.sets.conditionset import ConditionSet
syms = self.free_symbols
assert len(syms) == 1
x = syms.pop()
try:
xset = solve_univariate_inequality(self, x, relational=False)
except NotImplementedError:
# solve_univariate_inequality raises NotImplementedError for
# unsolvable equations/inequalities.
xset = ConditionSet(x, self, S.Reals)
return xset
@property
def binary_symbols(self):
# override where necessary
return set()
Rel = Relational
class Equality(Relational):
"""An equal relation between two objects.
Represents that two objects are equal. If they can be easily shown
to be definitively equal (or unequal), this will reduce to True (or
False). Otherwise, the relation is maintained as an unevaluated
Equality object. Use the ``simplify`` function on this object for
more nontrivial evaluation of the equality relation.
As usual, the keyword argument ``evaluate=False`` can be used to
prevent any evaluation.
Examples
========
>>> from sympy import Eq, simplify, exp, cos
>>> from sympy.abc import x, y
>>> Eq(y, x + x**2)
Eq(y, x**2 + x)
>>> Eq(2, 5)
False
>>> Eq(2, 5, evaluate=False)
Eq(2, 5)
>>> _.doit()
False
>>> Eq(exp(x), exp(x).rewrite(cos))
Eq(exp(x), sinh(x) + cosh(x))
>>> simplify(_)
True
See Also
========
sympy.logic.boolalg.Equivalent : for representing equality between two
boolean expressions
Notes
=====
Python treats 1 and True (and 0 and False) as being equal; SymPy
does not. And integer will always compare as unequal to a Boolean:
>>> Eq(True, 1), True == 1
(False, True)
This class is not the same as the == operator. The == operator tests
for exact structural equality between two expressions; this class
compares expressions mathematically.
If either object defines an `_eval_Eq` method, it can be used in place of
the default algorithm. If `lhs._eval_Eq(rhs)` or `rhs._eval_Eq(lhs)`
returns anything other than None, that return value will be substituted for
the Equality. If None is returned by `_eval_Eq`, an Equality object will
be created as usual.
Since this object is already an expression, it does not respond to
the method `as_expr` if one tries to create `x - y` from Eq(x, y).
This can be done with the `rewrite(Add)` method.
"""
rel_op = '=='
__slots__ = ()
is_Equality = True
def __new__(cls, lhs, rhs=None, **options):
from sympy.core.add import Add
from sympy.core.logic import fuzzy_bool, fuzzy_xor, fuzzy_and, fuzzy_not
from sympy.core.expr import _n2
from sympy.functions.elementary.complexes import arg
from sympy.simplify.simplify import clear_coefficients
from sympy.utilities.iterables import sift
if rhs is None:
SymPyDeprecationWarning(
feature="Eq(expr) with rhs default to 0",
useinstead="Eq(expr, 0)",
issue=16587,
deprecated_since_version="1.5"
).warn()
rhs = 0
lhs = _sympify(lhs)
rhs = _sympify(rhs)
evaluate = options.pop('evaluate', global_parameters.evaluate)
if evaluate:
if isinstance(lhs, Boolean) != isinstance(lhs, Boolean):
# e.g. 0/1 not recognized as Boolean in SymPy
return S.false
# If one expression has an _eval_Eq, return its results.
if hasattr(lhs, '_eval_Eq'):
r = lhs._eval_Eq(rhs)
if r is not None:
return r
if hasattr(rhs, '_eval_Eq'):
r = rhs._eval_Eq(lhs)
if r is not None:
return r
# If expressions have the same structure, they must be equal.
if lhs == rhs:
return S.true # e.g. True == True
elif all(isinstance(i, BooleanAtom) for i in (rhs, lhs)):
return S.false # True != False
elif not (lhs.is_Symbol or rhs.is_Symbol) and (
isinstance(lhs, Boolean) !=
isinstance(rhs, Boolean)):
return S.false # only Booleans can equal Booleans
if lhs.is_infinite or rhs.is_infinite:
if fuzzy_xor([lhs.is_infinite, rhs.is_infinite]):
return S.false
if fuzzy_xor([lhs.is_extended_real, rhs.is_extended_real]):
return S.false
if fuzzy_and([lhs.is_extended_real, rhs.is_extended_real]):
r = fuzzy_xor([lhs.is_extended_positive, fuzzy_not(rhs.is_extended_positive)])
return S(r)
# Try to split real/imaginary parts and equate them
I = S.ImaginaryUnit
def split_real_imag(expr):
real_imag = lambda t: (
'real' if t.is_extended_real else
'imag' if (I*t).is_extended_real else None)
return sift(Add.make_args(expr), real_imag)
lhs_ri = split_real_imag(lhs)
if not lhs_ri[None]:
rhs_ri = split_real_imag(rhs)
if not rhs_ri[None]:
eq_real = Eq(Add(*lhs_ri['real']), Add(*rhs_ri['real']))
eq_imag = Eq(I*Add(*lhs_ri['imag']), I*Add(*rhs_ri['imag']))
res = fuzzy_and(map(fuzzy_bool, [eq_real, eq_imag]))
if res is not None:
return S(res)
# Compare e.g. zoo with 1+I*oo by comparing args
arglhs = arg(lhs)
argrhs = arg(rhs)
# Guard against Eq(nan, nan) -> False
if not (arglhs == S.NaN and argrhs == S.NaN):
res = fuzzy_bool(Eq(arglhs, argrhs))
if res is not None:
return S(res)
return Relational.__new__(cls, lhs, rhs, **options)
if all(isinstance(i, Expr) for i in (lhs, rhs)):
# see if the difference evaluates
dif = lhs - rhs
z = dif.is_zero
if z is not None:
if z is False and dif.is_commutative: # issue 10728
return S.false
if z:
return S.true
# evaluate numerically if possible
n2 = _n2(lhs, rhs)
if n2 is not None:
return _sympify(n2 == 0)
# see if the ratio evaluates
n, d = dif.as_numer_denom()
rv = None
if n.is_zero:
rv = d.is_nonzero
elif n.is_finite:
if d.is_infinite:
rv = S.true
elif n.is_zero is False:
rv = d.is_infinite
if rv is None:
# if the condition that makes the denominator
# infinite does not make the original expression
# True then False can be returned
l, r = clear_coefficients(d, S.Infinity)
args = [_.subs(l, r) for _ in (lhs, rhs)]
if args != [lhs, rhs]:
rv = fuzzy_bool(Eq(*args))
if rv is True:
rv = None
elif any(a.is_infinite for a in Add.make_args(n)):
# (inf or nan)/x != 0
rv = S.false
if rv is not None:
return _sympify(rv)
return Relational.__new__(cls, lhs, rhs, **options)
@classmethod
def _eval_relation(cls, lhs, rhs):
return _sympify(lhs == rhs)
def _eval_rewrite_as_Add(self, *args, **kwargs):
"""return Eq(L, R) as L - R. To control the evaluation of
the result set pass `evaluate=True` to give L - R;
if `evaluate=None` then terms in L and R will not cancel
but they will be listed in canonical order; otherwise
non-canonical args will be returned.
Examples
========
>>> from sympy import Eq, Add
>>> from sympy.abc import b, x
>>> eq = Eq(x + b, x - b)
>>> eq.rewrite(Add)
2*b
>>> eq.rewrite(Add, evaluate=None).args
(b, b, x, -x)
>>> eq.rewrite(Add, evaluate=False).args
(b, x, b, -x)
"""
L, R = args
evaluate = kwargs.get('evaluate', True)
if evaluate:
# allow cancellation of args
return L - R
args = Add.make_args(L) + Add.make_args(-R)
if evaluate is None:
# no cancellation, but canonical
return _unevaluated_Add(*args)
# no cancellation, not canonical
return Add._from_args(args)
@property
def binary_symbols(self):
if S.true in self.args or S.false in self.args:
if self.lhs.is_Symbol:
return {self.lhs}
elif self.rhs.is_Symbol:
return {self.rhs}
return set()
def _eval_simplify(self, **kwargs):
from sympy.solvers.solveset import linear_coeffs
# standard simplify
e = super()._eval_simplify(**kwargs)
if not isinstance(e, Equality):
return e
free = self.free_symbols
if len(free) == 1:
try:
x = free.pop()
m, b = linear_coeffs(
e.rewrite(Add, evaluate=False), x)
if m.is_zero is False:
enew = e.func(x, -b/m)
else:
enew = e.func(m*x, -b)
measure = kwargs['measure']
if measure(enew) <= kwargs['ratio']*measure(e):
e = enew
except ValueError:
pass
return e.canonical
def integrate(self, *args, **kwargs):
"""See the integrate function in sympy.integrals"""
from sympy.integrals import integrate
return integrate(self, *args, **kwargs)
def as_poly(self, *gens, **kwargs):
'''Returns lhs-rhs as a Poly
Examples
========
>>> from sympy import Eq
>>> from sympy.abc import x
>>> Eq(x**2, 1).as_poly(x)
Poly(x**2 - 1, x, domain='ZZ')
'''
return (self.lhs - self.rhs).as_poly(*gens, **kwargs)
Eq = Equality
class Unequality(Relational):
"""An unequal relation between two objects.
Represents that two objects are not equal. If they can be shown to be
definitively equal, this will reduce to False; if definitively unequal,
this will reduce to True. Otherwise, the relation is maintained as an
Unequality object.
Examples
========
>>> from sympy import Ne
>>> from sympy.abc import x, y
>>> Ne(y, x+x**2)
Ne(y, x**2 + x)
See Also
========
Equality
Notes
=====
This class is not the same as the != operator. The != operator tests
for exact structural equality between two expressions; this class
compares expressions mathematically.
This class is effectively the inverse of Equality. As such, it uses the
same algorithms, including any available `_eval_Eq` methods.
"""
rel_op = '!='
__slots__ = ()
def __new__(cls, lhs, rhs, **options):
lhs = _sympify(lhs)
rhs = _sympify(rhs)
evaluate = options.pop('evaluate', global_parameters.evaluate)
if evaluate:
if isinstance(lhs, Boolean) != isinstance(lhs, Boolean):
# e.g. 0/1 not recognized as Boolean in SymPy
return S.true
is_equal = Equality(lhs, rhs)
if isinstance(is_equal, BooleanAtom):
return is_equal.negated
return Relational.__new__(cls, lhs, rhs, **options)
@classmethod
def _eval_relation(cls, lhs, rhs):
return _sympify(lhs != rhs)
@property
def binary_symbols(self):
if S.true in self.args or S.false in self.args:
if self.lhs.is_Symbol:
return {self.lhs}
elif self.rhs.is_Symbol:
return {self.rhs}
return set()
def _eval_simplify(self, **kwargs):
# simplify as an equality
eq = Equality(*self.args)._eval_simplify(**kwargs)
if isinstance(eq, Equality):
# send back Ne with the new args
return self.func(*eq.args)
return eq.negated # result of Ne is the negated Eq
Ne = Unequality
class _Inequality(Relational):
"""Internal base class for all *Than types.
Each subclass must implement _eval_relation to provide the method for
comparing two real numbers.
"""
__slots__ = ()
def __new__(cls, lhs, rhs, **options):
lhs = _sympify(lhs)
rhs = _sympify(rhs)
evaluate = options.pop('evaluate', global_parameters.evaluate)
if evaluate:
# First we invoke the appropriate inequality method of `lhs`
# (e.g., `lhs.__lt__`). That method will try to reduce to
# boolean or raise an exception. It may keep calling
# superclasses until it reaches `Expr` (e.g., `Expr.__lt__`).
# In some cases, `Expr` will just invoke us again (if neither it
# nor a subclass was able to reduce to boolean or raise an
# exception). In that case, it must call us with
# `evaluate=False` to prevent infinite recursion.
r = cls._eval_relation(lhs, rhs)
if r is not None:
return r
# Note: not sure r could be None, perhaps we never take this
# path? In principle, could use this to shortcut out if a
# class realizes the inequality cannot be evaluated further.
# make a "non-evaluated" Expr for the inequality
return Relational.__new__(cls, lhs, rhs, **options)
class _Greater(_Inequality):
"""Not intended for general use
_Greater is only used so that GreaterThan and StrictGreaterThan may
subclass it for the .gts and .lts properties.
"""
__slots__ = ()
@property
def gts(self):
return self._args[0]
@property
def lts(self):
return self._args[1]
class _Less(_Inequality):
"""Not intended for general use.
_Less is only used so that LessThan and StrictLessThan may subclass it for
the .gts and .lts properties.
"""
__slots__ = ()
@property
def gts(self):
return self._args[1]
@property
def lts(self):
return self._args[0]
class GreaterThan(_Greater):
"""Class representations of inequalities.
Extended Summary
================
The ``*Than`` classes represent inequal relationships, where the left-hand
side is generally bigger or smaller than the right-hand side. For example,
the GreaterThan class represents an inequal relationship where the
left-hand side is at least as big as the right side, if not bigger. In
mathematical notation:
lhs >= rhs
In total, there are four ``*Than`` classes, to represent the four
inequalities:
+-----------------+--------+
|Class Name | Symbol |
+=================+========+
|GreaterThan | (>=) |
+-----------------+--------+
|LessThan | (<=) |
+-----------------+--------+
|StrictGreaterThan| (>) |
+-----------------+--------+
|StrictLessThan | (<) |
+-----------------+--------+
All classes take two arguments, lhs and rhs.
+----------------------------+-----------------+
|Signature Example | Math equivalent |
+============================+=================+
|GreaterThan(lhs, rhs) | lhs >= rhs |
+----------------------------+-----------------+
|LessThan(lhs, rhs) | lhs <= rhs |
+----------------------------+-----------------+
|StrictGreaterThan(lhs, rhs) | lhs > rhs |
+----------------------------+-----------------+
|StrictLessThan(lhs, rhs) | lhs < rhs |
+----------------------------+-----------------+
In addition to the normal .lhs and .rhs of Relations, ``*Than`` inequality
objects also have the .lts and .gts properties, which represent the "less
than side" and "greater than side" of the operator. Use of .lts and .gts
in an algorithm rather than .lhs and .rhs as an assumption of inequality
direction will make more explicit the intent of a certain section of code,
and will make it similarly more robust to client code changes:
>>> from sympy import GreaterThan, StrictGreaterThan
>>> from sympy import LessThan, StrictLessThan
>>> from sympy import And, Ge, Gt, Le, Lt, Rel, S
>>> from sympy.abc import x, y, z
>>> from sympy.core.relational import Relational
>>> e = GreaterThan(x, 1)
>>> e
x >= 1
>>> '%s >= %s is the same as %s <= %s' % (e.gts, e.lts, e.lts, e.gts)
'x >= 1 is the same as 1 <= x'
Examples
========
One generally does not instantiate these classes directly, but uses various
convenience methods:
>>> for f in [Ge, Gt, Le, Lt]: # convenience wrappers
... print(f(x, 2))
x >= 2
x > 2
x <= 2
x < 2
Another option is to use the Python inequality operators (>=, >, <=, <)
directly. Their main advantage over the Ge, Gt, Le, and Lt counterparts,
is that one can write a more "mathematical looking" statement rather than
littering the math with oddball function calls. However there are certain
(minor) caveats of which to be aware (search for 'gotcha', below).
>>> x >= 2
x >= 2
>>> _ == Ge(x, 2)
True
However, it is also perfectly valid to instantiate a ``*Than`` class less
succinctly and less conveniently:
>>> Rel(x, 1, ">")
x > 1
>>> Relational(x, 1, ">")
x > 1
>>> StrictGreaterThan(x, 1)
x > 1
>>> GreaterThan(x, 1)
x >= 1
>>> LessThan(x, 1)
x <= 1
>>> StrictLessThan(x, 1)
x < 1
Notes
=====
There are a couple of "gotchas" to be aware of when using Python's
operators.
The first is that what your write is not always what you get:
>>> 1 < x
x > 1
Due to the order that Python parses a statement, it may
not immediately find two objects comparable. When "1 < x"
is evaluated, Python recognizes that the number 1 is a native
number and that x is *not*. Because a native Python number does
not know how to compare itself with a SymPy object
Python will try the reflective operation, "x > 1" and that is the
form that gets evaluated, hence returned.
If the order of the statement is important (for visual output to
the console, perhaps), one can work around this annoyance in a
couple ways:
(1) "sympify" the literal before comparison
>>> S(1) < x
1 < x
(2) use one of the wrappers or less succinct methods described
above
>>> Lt(1, x)
1 < x
>>> Relational(1, x, "<")
1 < x
The second gotcha involves writing equality tests between relationals
when one or both sides of the test involve a literal relational:
>>> e = x < 1; e
x < 1
>>> e == e # neither side is a literal
True
>>> e == x < 1 # expecting True, too
False
>>> e != x < 1 # expecting False
x < 1
>>> x < 1 != x < 1 # expecting False or the same thing as before
Traceback (most recent call last):
...
TypeError: cannot determine truth value of Relational
The solution for this case is to wrap literal relationals in
parentheses:
>>> e == (x < 1)
True
>>> e != (x < 1)
False
>>> (x < 1) != (x < 1)
False
The third gotcha involves chained inequalities not involving
'==' or '!='. Occasionally, one may be tempted to write:
>>> e = x < y < z
Traceback (most recent call last):
...
TypeError: symbolic boolean expression has no truth value.
Due to an implementation detail or decision of Python [1]_,
there is no way for SymPy to create a chained inequality with
that syntax so one must use And:
>>> e = And(x < y, y < z)
>>> type( e )
And
>>> e
(x < y) & (y < z)
Although this can also be done with the '&' operator, it cannot
be done with the 'and' operarator:
>>> (x < y) & (y < z)
(x < y) & (y < z)
>>> (x < y) and (y < z)
Traceback (most recent call last):
...
TypeError: cannot determine truth value of Relational
.. [1] This implementation detail is that Python provides no reliable
method to determine that a chained inequality is being built.
Chained comparison operators are evaluated pairwise, using "and"
logic (see
http://docs.python.org/2/reference/expressions.html#notin). This
is done in an efficient way, so that each object being compared
is only evaluated once and the comparison can short-circuit. For
example, ``1 > 2 > 3`` is evaluated by Python as ``(1 > 2) and (2
> 3)``. The ``and`` operator coerces each side into a bool,
returning the object itself when it short-circuits. The bool of
the --Than operators will raise TypeError on purpose, because
SymPy cannot determine the mathematical ordering of symbolic
expressions. Thus, if we were to compute ``x > y > z``, with
``x``, ``y``, and ``z`` being Symbols, Python converts the
statement (roughly) into these steps:
(1) x > y > z
(2) (x > y) and (y > z)
(3) (GreaterThanObject) and (y > z)
(4) (GreaterThanObject.__nonzero__()) and (y > z)
(5) TypeError
Because of the "and" added at step 2, the statement gets turned into a
weak ternary statement, and the first object's __nonzero__ method will
raise TypeError. Thus, creating a chained inequality is not possible.
In Python, there is no way to override the ``and`` operator, or to
control how it short circuits, so it is impossible to make something
like ``x > y > z`` work. There was a PEP to change this,
:pep:`335`, but it was officially closed in March, 2012.
"""
__slots__ = ()
rel_op = '>='
@classmethod
def _eval_relation(cls, lhs, rhs):
# We don't use the op symbol here: workaround issue #7951
return _sympify(lhs.__ge__(rhs))
Ge = GreaterThan
class LessThan(_Less):
__doc__ = GreaterThan.__doc__
__slots__ = ()
rel_op = '<='
@classmethod
def _eval_relation(cls, lhs, rhs):
# We don't use the op symbol here: workaround issue #7951
return _sympify(lhs.__le__(rhs))
Le = LessThan
class StrictGreaterThan(_Greater):
__doc__ = GreaterThan.__doc__
__slots__ = ()
rel_op = '>'
@classmethod
def _eval_relation(cls, lhs, rhs):
# We don't use the op symbol here: workaround issue #7951
return _sympify(lhs.__gt__(rhs))
Gt = StrictGreaterThan
class StrictLessThan(_Less):
__doc__ = GreaterThan.__doc__
__slots__ = ()
rel_op = '<'
@classmethod
def _eval_relation(cls, lhs, rhs):
# We don't use the op symbol here: workaround issue #7951
return _sympify(lhs.__lt__(rhs))
Lt = StrictLessThan
# A class-specific (not object-specific) data item used for a minor speedup.
# It is defined here, rather than directly in the class, because the classes
# that it references have not been defined until now (e.g. StrictLessThan).
Relational.ValidRelationOperator = {
None: Equality,
'==': Equality,
'eq': Equality,
'!=': Unequality,
'<>': Unequality,
'ne': Unequality,
'>=': GreaterThan,
'ge': GreaterThan,
'<=': LessThan,
'le': LessThan,
'>': StrictGreaterThan,
'gt': StrictGreaterThan,
'<': StrictLessThan,
'lt': StrictLessThan,
}
|
97c931b8f89a3d3a556440f9ec0be3e7022dd8a0a1d580f8e7d306d298f9b399 | import numbers
import decimal
import fractions
import math
import re as regex
from .containers import Tuple
from .sympify import (SympifyError, converter, sympify, _convert_numpy_types, _sympify,
_is_numpy_instance)
from .singleton import S, Singleton
from .expr import Expr, AtomicExpr
from .evalf import pure_complex
from .decorators import _sympifyit
from .cache import cacheit, clear_cache
from .logic import fuzzy_not
from sympy.core.compatibility import (as_int, HAS_GMPY, SYMPY_INTS,
int_info, gmpy)
from sympy.core.cache import lru_cache
import mpmath
import mpmath.libmp as mlib
from mpmath.libmp import bitcount
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, _normalize as mpf_normalize,
prec_to_dps)
from sympy.utilities.misc import debug, filldedent
from .parameters import global_parameters
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.
Examples
========
If ``tol`` is None then True will be returned if
``abs(z1 - z2)*10**p <= 5`` where ``p`` is minimum value of the
decimal precision of each value.
>>> from sympy.core.numbers import comp, pi
>>> pi4 = pi.n(4); pi4
3.142
>>> comp(_, 3.142)
True
>>> comp(pi4, 3.141)
False
>>> comp(pi4, 3.143)
False
A comparison of strings will be made
if ``z1`` is a Number and ``z2`` is a string or ``tol`` is ''.
>>> comp(pi4, 3.1415)
True
>>> comp(pi4, 3.1415, '')
False
When ``tol`` is provided and ``z2`` is non-zero and
``|z1| > 1`` the error is normalized by ``|z1|``:
>>> abs(pi4 - 3.14)/pi4
0.000509791731426756
>>> comp(pi4, 3.14, .001) # difference less than 0.1%
True
>>> comp(pi4, 3.14, .0005) # difference less than 0.1%
False
When ``|z1| <= 1`` the absolute error is used:
>>> 1/pi4
0.3183
>>> abs(1/pi4 - 0.3183)/(1/pi4)
3.07371499106316e-5
>>> abs(1/pi4 - 0.3183)
9.78393554684764e-6
>>> comp(1/pi4, 0.3183, 1e-5)
True
To see if the absolute error between ``z1`` and ``z2`` is less
than or equal to ``tol``, call this as ``comp(z1 - z2, 0, tol)``
or ``comp(z1 - z2, tol=tol)``:
>>> abs(pi4 - 3.14)
0.00160156249999988
>>> comp(pi4 - 3.14, 0, .002)
True
>>> comp(pi4 - 3.14, 0, .001)
False
"""
if type(z2) is str:
if not pure_complex(z1, or_real=True):
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:
a, b = z1, z2
if tol == '':
return str(a) == str(b)
if tol is None:
a, b = sympify(a), sympify(b)
if not all(i.is_number for i in (a, b)):
raise ValueError('expecting 2 numbers')
fa = a.atoms(Float)
fb = b.atoms(Float)
if not fa and not fb:
# no floats -- compare exactly
return a == b
# get a to be pure_complex
for do in range(2):
ca = pure_complex(a, or_real=True)
if not ca:
if fa:
a = a.n(prec_to_dps(min([i._prec for i in fa])))
ca = pure_complex(a, or_real=True)
break
else:
fa, fb = fb, fa
a, b = b, a
cb = pure_complex(b)
if not cb and fb:
b = b.n(prec_to_dps(min([i._prec for i in fb])))
cb = pure_complex(b, or_real=True)
if ca and cb and (ca[1] or cb[1]):
return all(comp(i, j) for i, j in zip(ca, cb))
tol = 10**prec_to_dps(min(a._prec, getattr(b, '_prec', a._prec)))
return int(abs(a - b)*tol) <= 5
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 fzero
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()
if HAS_GMPY: # Using gmpy if present to speed up.
for b in args_temp:
a = gmpy.gcd(a, b) if b else a
return as_int(a)
for b in args_temp:
a = igcd2(a, b) if b else a
return a
def _igcd2_python(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
try:
from math import gcd as igcd2
except ImportError:
igcd2 = _igcd2_python
# Use Lehmer's algorithm only for very large numbers.
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 returned 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, str):
_obj = obj.lower() # float('INF') == float('inf')
if _obj == 'nan':
return S.NaN
elif _obj == 'inf':
return S.Infinity
elif _obj == '+inf':
return S.Infinity
elif _obj == '-inf':
return S.NegativeInfinity
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
from sympy.functions.elementary.complexes import sign
try:
other = Number(other)
if self.is_infinite or S.NaN in (self, other):
return (S.NaN, S.NaN)
except TypeError:
return NotImplemented
if not other:
raise ZeroDivisionError('modulo by zero')
if self.is_Integer and other.is_Integer:
return Tuple(*divmod(self.p, other.p))
elif isinstance(other, Float):
rat = self/Rational(other)
else:
rat = self/other
if other.is_finite:
w = int(rat) if rat > 0 else int(rat) - 1
r = self - other*w
else:
w = 0 if not self or (sign(self) == sign(other)) else -1
r = other if w else self
return Tuple(w, r)
def __rdivmod__(self, other):
try:
other = Number(other)
except TypeError:
return NotImplemented
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 __floor__(self):
return self.floor()
def __ceil__(self):
return self.ceiling()
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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().__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.
In SymPy, a Float is a number that can be computed with arbitrary
precision. Although floating point 'inf' and 'nan' are not such
numbers, Float can create these numbers:
>>> Float('-inf')
-oo
>>> _.is_Float
False
"""
__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_extended_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, str):
# Float accepts spaces as digit separators
num = num.replace(' ', '').lower()
# in Py 3.6
# underscores are allowed. In anticipation of that, we ignore
# legally placed underscores
if '_' in num:
parts = num.split('_')
if not (all(parts) and
all(parts[i][-1].isdigit()
for i in range(0, len(parts), 2)) and
all(parts[i][0].isdigit()
for i in range(1, len(parts), 2))):
# copy Py 3.6 error
raise ValueError("could not convert string to float: '%s'" % num)
num = ''.join(parts)
if num.startswith('.') and len(num) > 1:
num = '0' + num
elif num.startswith('-.') and len(num) > 2:
num = '-0.' + num[2:]
elif num in ('inf', '+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, float) and num == float('nan'):
return S.NaN
elif isinstance(num, (SYMPY_INTS, Integer)):
num = str(num)
elif num is S.Infinity:
return num
elif num is S.NegativeInfinity:
return num
elif num is S.NaN:
return num
elif _is_numpy_instance(num): # 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, str) 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, str):
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, str):
_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
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:
if not all((
num[0] in (0, 1),
num[1] >= 0,
all(type(i) in (int, int) for i in num)
)):
raise ValueError('malformed mpf: %s' % (num,))
# don't compute number or else it may
# over/underflow
return Float._new(
(num[0], num[1], num[2], bitcount(num[1])),
precision)
else:
try:
_mpf_ = num._as_mpf_val(precision)
except (NotImplementedError, AttributeError):
_mpf_ = mpmath.mpf(num, prec=precision)._mpf_
return cls._new(_mpf_, precision, zero=False)
@classmethod
def _new(cls, _mpf_, _prec, zero=True):
# special cases
if zero and _mpf_ == fzero:
return S.Zero # Float(0) -> 0.0; Float._new((0,0,0,0)) -> 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)
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))))
def __floor__(self):
return self.floor()
def __ceil__(self):
return self.ceiling()
@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_ == fzero
def _eval_is_negative(self):
if self._mpf_ == _mpf_ninf or self._mpf_ == _mpf_inf:
return False
return self.num < 0
def _eval_is_positive(self):
if self._mpf_ == _mpf_ninf or self._mpf_ == _mpf_inf:
return False
return self.num > 0
def _eval_is_extended_negative(self):
if self._mpf_ == _mpf_ninf:
return True
if self._mpf_ == _mpf_inf:
return False
return self.num < 0
def _eval_is_extended_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_ == fzero
def __nonzero__(self):
return self._mpf_ != fzero
__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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
# calculate mod with Rationals, *then* round the result
return Float(Rational.__mod__(Rational(self), other),
precision=self._prec)
if isinstance(other, Float) and global_parameters.evaluate:
r = self/other
if r == int(r):
return Float(0, precision=max(self._prec, other._prec))
if isinstance(other, Number) and global_parameters.evaluate:
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_parameters.evaluate:
return other.__mod__(self)
if isinstance(other, Number) and global_parameters.evaluate:
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, fzero), (expt, fzero), 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_ == fzero:
return 0
return int(mlib.to_int(self._mpf_)) # uses round_fast = round_down
__long__ = __int__
def __eq__(self, other):
from sympy.logic.boolalg import Boolean
try:
other = _sympify(other)
except SympifyError:
return NotImplemented
if not self:
return not other
if isinstance(other, Boolean):
return False
if other.is_NumberSymbol:
if other.is_irrational:
return False
return other.__eq__(self)
if other.is_Float:
# comparison is exact
# so Float(.1, 3) != Float(.1, 33)
return self._mpf_ == other._mpf_
if other.is_Rational:
return other.__eq__(self)
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 _Frel(self, other, op):
from sympy.core.numbers import prec_to_dps
try:
other = _sympify(other)
except SympifyError:
return NotImplemented
if other.is_Rational:
# test self*other.q <?> other.p without losing precision
'''
>>> f = Float(.1,2)
>>> i = 1234567890
>>> (f*i)._mpf_
(0, 471, 18, 9)
>>> mlib.mpf_mul(f._mpf_, mlib.from_int(i))
(0, 505555550955, -12, 39)
'''
smpf = mlib.mpf_mul(self._mpf_, mlib.from_int(other.q))
ompf = mlib.from_int(other.p)
return _sympify(bool(op(smpf, ompf)))
elif other.is_Float:
return _sympify(bool(
op(self._mpf_, other._mpf_)))
elif other.is_comparable and other not in (
S.Infinity, S.NegativeInfinity):
other = other.evalf(prec_to_dps(self._prec))
if other._prec > 1:
if other.is_Number:
return _sympify(bool(
op(self._mpf_, other._as_mpf_val(self._prec))))
def __gt__(self, other):
if isinstance(other, NumberSymbol):
return other.__lt__(self)
rv = self._Frel(other, mlib.mpf_gt)
if rv is None:
return Expr.__gt__(self, other)
return rv
def __ge__(self, other):
if isinstance(other, NumberSymbol):
return other.__le__(self)
rv = self._Frel(other, mlib.mpf_ge)
if rv is None:
return Expr.__ge__(self, other)
return rv
def __lt__(self, other):
if isinstance(other, NumberSymbol):
return other.__gt__(self)
rv = self._Frel(other, mlib.mpf_lt)
if rv is None:
return Expr.__lt__(self, other)
return rv
def __le__(self, other):
if isinstance(other, NumberSymbol):
return other.__ge__(self)
rv = self._Frel(other, mlib.mpf_le)
if rv is None:
return Expr.__le__(self, other)
return rv
def __hash__(self):
return super().__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
========
sympy.core.sympify.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, str):
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_parameters.evaluate:
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_extended_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_extended_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 __floor__(self):
return self.floor()
def __ceil__(self):
return self.ceiling()
def __eq__(self, other):
from sympy.core.power import integer_log
try:
other = _sympify(other)
except SympifyError:
return NotImplemented
if not isinstance(other, Number):
# S(0) == S.false is False
# S(0) == False is True
return False
if not self:
return not other
if other.is_NumberSymbol:
if other.is_irrational:
return False
return other.__eq__(self)
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:
# all Floats have a denominator that is a power of 2
# so if self doesn't, it can't be equal to other
if self.q & (self.q - 1):
return False
s, m, t = other._mpf_[:3]
if s:
m = -m
if not t:
# other is an odd integer
if not self.is_Integer or self.is_even:
return False
return m == self.p
if t > 0:
# other is an even integer
if not self.is_Integer:
return False
# does m*2**t == self.p
return self.p and not self.p % m and \
integer_log(self.p//m, 2) == (t, True)
# does non-integer s*m/2**-t = p/q?
if self.is_Integer:
return False
return m == self.p and integer_log(self.q, 2) == (-t, True)
return False
def __ne__(self, other):
return not self == other
def _Rrel(self, other, attr):
# if you want self < other, pass self, other, __gt__
try:
other = _sympify(other)
except SympifyError:
return NotImplemented
if other.is_Number:
op = None
s, o = self, other
if other.is_NumberSymbol:
op = getattr(o, attr)
elif other.is_Float:
op = getattr(o, attr)
elif other.is_Rational:
s, o = Integer(s.p*o.q), Integer(s.q*o.p)
op = getattr(o, attr)
if op:
return op(s)
if o.is_number and o.is_extended_real:
return Integer(s.p), s.q*o
def __gt__(self, other):
rv = self._Rrel(other, '__lt__')
if rv is None:
rv = self, other
elif not type(rv) is tuple:
return rv
return Expr.__gt__(*rv)
def __ge__(self, other):
rv = self._Rrel(other, '__le__')
if rv is None:
rv = self, other
elif not type(rv) is tuple:
return rv
return Expr.__ge__(*rv)
def __lt__(self, other):
rv = self._Rrel(other, '__gt__')
if rv is None:
rv = self, other
elif not type(rv) is tuple:
return rv
return Expr.__lt__(*rv)
def __le__(self, other):
rv = self._Rrel(other, '__ge__')
if rv is None:
rv = self, other
elif not type(rv) is tuple:
return rv
return Expr.__le__(*rv)
def __hash__(self):
return super().__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()
def numerator(self):
return self.p
def denominator(self):
return self.q
@_sympifyit('other', NotImplemented)
def gcd(self, other):
if isinstance(other, Rational):
if other == 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, str):
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 __floor__(self):
return self.floor()
def __ceil__(self):
return self.ceiling()
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_parameters.evaluate:
return Tuple(*(divmod(self.p, other.p)))
else:
return Number.__divmod__(self, other)
def __rdivmod__(self, other):
from .containers import Tuple
if isinstance(other, int) and global_parameters.evaluate:
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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_parameters.evaluate:
if isinstance(other, int):
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, int):
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:
return NotImplemented
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:
return NotImplemented
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:
return NotImplemented
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:
return NotImplemented
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.ntheory.factor_ 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()._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
@_sympifyit('other', NotImplemented)
def __floordiv__(self, other):
if not isinstance(other, Expr):
return NotImplemented
if isinstance(other, Integer):
return Integer(self.p // other)
return Integer(divmod(self, other)[0])
def __rfloordiv__(self, other):
return Integer(Integer(other).p // self.p)
# Add sympify converters
converter[int] = 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().__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, **kwargs):
from sympy.polys import CRootOf, minpoly
measure, ratio = kwargs['measure'], kwargs['ratio']
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(IntegerConstant, metaclass=Singleton):
"""The number zero.
Zero is a singleton, and can be accessed by ``S.Zero``
Examples
========
>>> from sympy import S, Integer
>>> 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
is_comparable = True
__slots__ = ()
def __getnewargs__(self):
return ()
@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_extended_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(IntegerConstant, metaclass=Singleton):
"""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__ = ()
def __getnewargs__(self):
return ()
@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(IntegerConstant, metaclass=Singleton):
"""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__ = ()
def __getnewargs__(self):
return ()
@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(RationalConstant, metaclass=Singleton):
"""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__ = ()
def __getnewargs__(self):
return ()
@staticmethod
def __abs__():
return S.Half
class Infinity(Number, metaclass=Singleton):
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_number = True
is_complex = False
is_extended_real = True
is_infinite = True
is_comparable = True
is_extended_positive = 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
def _eval_evalf(self, prec=None):
return Float('inf')
def evalf(self, prec=None, **options):
return self._eval_evalf(prec)
@_sympifyit('other', NotImplemented)
def __add__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other is S.NegativeInfinity or other is S.NaN:
return S.NaN
return self
return Number.__add__(self, other)
__radd__ = __add__
@_sympifyit('other', NotImplemented)
def __sub__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other is S.Infinity or other is S.NaN:
return S.NaN
return self
return Number.__sub__(self, other)
@_sympifyit('other', NotImplemented)
def __rsub__(self, other):
return (-self).__add__(other)
@_sympifyit('other', NotImplemented)
def __mul__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other.is_zero or other is S.NaN:
return S.NaN
if other.is_extended_positive:
return self
return S.NegativeInfinity
return Number.__mul__(self, other)
__rmul__ = __mul__
@_sympifyit('other', NotImplemented)
def __div__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other is S.Infinity or \
other is S.NegativeInfinity or \
other is S.NaN:
return S.NaN
if other.is_extended_nonnegative:
return self
return S.NegativeInfinity
return Number.__div__(self, other)
__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_extended_positive:
return S.Infinity
if expt.is_extended_negative:
return S.Zero
if expt is S.NaN:
return S.NaN
if expt is S.ComplexInfinity:
return S.NaN
if expt.is_extended_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().__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')
__gt__ = Expr.__gt__
__ge__ = Expr.__ge__
__lt__ = Expr.__lt__
__le__ = Expr.__le__
@_sympifyit('other', NotImplemented)
def __mod__(self, other):
if not isinstance(other, Expr):
return NotImplemented
return S.NaN
__rmod__ = __mod__
def floor(self):
return self
def ceiling(self):
return self
oo = S.Infinity
class NegativeInfinity(Number, metaclass=Singleton):
"""Negative infinite quantity.
NegativeInfinity is a singleton, and can be accessed
by ``S.NegativeInfinity``.
See Also
========
Infinity
"""
is_extended_real = True
is_complex = False
is_commutative = True
is_infinite = True
is_comparable = True
is_extended_negative = 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
def _eval_evalf(self, prec=None):
return Float('-inf')
def evalf(self, prec=None, **options):
return self._eval_evalf(prec)
@_sympifyit('other', NotImplemented)
def __add__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other is S.Infinity or other is S.NaN:
return S.NaN
return self
return Number.__add__(self, other)
__radd__ = __add__
@_sympifyit('other', NotImplemented)
def __sub__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other is S.NegativeInfinity or other is S.NaN:
return S.NaN
return self
return Number.__sub__(self, other)
@_sympifyit('other', NotImplemented)
def __rsub__(self, other):
return (-self).__add__(other)
@_sympifyit('other', NotImplemented)
def __mul__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other.is_zero or other is S.NaN:
return S.NaN
if other.is_extended_positive:
return self
return S.Infinity
return Number.__mul__(self, other)
__rmul__ = __mul__
@_sympifyit('other', NotImplemented)
def __div__(self, other):
if isinstance(other, Number) and global_parameters.evaluate:
if other is S.Infinity or \
other is S.NegativeInfinity or \
other is S.NaN:
return S.NaN
if other.is_extended_nonnegative:
return self
return S.Infinity
return Number.__div__(self, other)
__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_extended_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().__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')
__gt__ = Expr.__gt__
__ge__ = Expr.__ge__
__lt__ = Expr.__lt__
__le__ = Expr.__le__
@_sympifyit('other', NotImplemented)
def __mod__(self, other):
if not isinstance(other, Expr):
return NotImplemented
return S.NaN
__rmod__ = __mod__
def floor(self):
return self
def ceiling(self):
return self
def as_powers_dict(self):
return {S.NegativeOne: 1, S.Infinity: 1}
class NaN(Number, metaclass=Singleton):
"""
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
contrast 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_extended_real = None
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}"
def __neg__(self):
return self
@_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().__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(AtomicExpr, metaclass=Singleton):
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
>>> 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 = False
is_extended_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_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().__hash__()
class Exp1(NumberSymbol, metaclass=Singleton):
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(NumberSymbol, metaclass=Singleton):
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(NumberSymbol, metaclass=Singleton):
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(NumberSymbol, metaclass=Singleton):
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(NumberSymbol, metaclass=Singleton):
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(NumberSymbol, metaclass=Singleton):
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 _eval_rewrite_as_Sum(self, k_sym=None, symbols=None):
from sympy import Sum, Dummy
if (k_sym is not None) or (symbols is not None):
return self
k = Dummy('k', integer=True, nonnegative=True)
return Sum((-1)**k / (2*k+1)**2, (k, 0, S.Infinity))
def _sage_(self):
import sage.all as sage
return sage.catalan
class ImaginaryUnit(AtomicExpr, metaclass=Singleton):
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
if HAS_GMPY:
def sympify_mpz(x):
return Integer(int(x))
# XXX: The sympify_mpq function here was never used because it is
# overridden by the other sympify_mpq function below. Maybe it should just
# be removed or maybe it should be used for something...
def sympify_mpq(x):
return Rational(int(x.numerator), int(x.denominator))
converter[type(gmpy.mpz(1))] = sympify_mpz
converter[type(gmpy.mpq(1, 2))] = sympify_mpq
def sympify_mpmath_mpq(x):
p, q = x._mpq_
return Rational(p, q, 1)
converter[type(mpmath.rational.mpq(1, 2))] = sympify_mpmath_mpq
def sympify_mpmath(x):
return Expr._from_mpmath(x, x.context.prec)
converter[mpnumeric] = sympify_mpmath
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()
def _register_classes():
numbers.Number.register(Number)
numbers.Real.register(Float)
numbers.Rational.register(Rational)
numbers.Rational.register(Integer)
_register_classes()
|
f4b44a49bf33d862d3f3c3766e4b6469dd85d98d5a36ba88f86838b1db49e173 | from typing import Tuple
from sympy.utilities.exceptions import SymPyDeprecationWarning
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
from sympy.core.logic import fuzzy_and
from sympy.core.parameters import global_parameters
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',) # type: Tuple[str, ...]
_args_type = None
@cacheit
def __new__(cls, *args, **options):
from sympy import Order
args = list(map(_sympify, args))
# Disallow non-Expr args in Add/Mul
typ = cls._args_type
if typ is not None:
from sympy.core.relational import Relational
if any(isinstance(arg, Relational) for arg in args):
raise TypeError("Relational can not be used in %s" % cls.__name__)
# This should raise TypeError once deprecation period is over:
if not all(isinstance(arg, typ) for arg in args):
SymPyDeprecationWarning(
feature="Add/Mul with non-Expr args",
useinstead="Expr args",
issue=19445,
deprecated_since_version="1.7"
).warn()
evaluate = options.get('evaluate')
if evaluate is None:
evaluate = global_parameters.evaluate
if not evaluate:
obj = cls._from_args(args)
obj = cls._exec_constructor_postprocessors(obj)
return obj
args = [a for a in args if a is not cls.identity]
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 the args are not in canonical order, then a non-canonical
result will be returned, so use with caution. The order of
args may change if the sign of the args is changed."""
if len(args) == 0:
return cls.identity
elif len(args) == 1:
return args[0]
obj = super().__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 they will show up in the result:
>>> m = (x*y)._new_rawargs(S.One, x); m
1*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
repl_dict = repl_dict.copy()
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))
if self.is_Add:
# in addition to normal ordered keys, impose
# sorting on Muls with leading Number to put
# them in order
wild_part = sorted(wild_part, key=lambda x:
x.args[0] if x.is_Mul and x.args[0].is_Number else
0)
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)
args = tuple(ordered(self.make_args(expr)))
if self.is_Add and expr.is_Add:
# in addition to normal ordered keys, impose
# sorting on Muls with leading Number to put
# them in order
args = tuple(sorted(args, key=lambda x:
x.args[0] if x.is_Mul and x.args[0].is_Number else
0))
expr_list = (self.identity,) + args
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. Numbers 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),)
def doit(self, **hints):
if hints.get('deep', True):
terms = [term.doit(**hints) for term in self.args]
else:
terms = self.args
return self.func(*terms, evaluate=True)
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:
yield from arg.args
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)])
# XXX: This should be cached on the object rather than using cacheit
# Maybe _argset can just be sorted in the constructor?
@property # type: ignore
@cacheit
def args(self):
return tuple(ordered(self._argset))
@staticmethod
def _compare_pretty(a, b):
return (str(a) > str(b)) - (str(a) < str(b))
|
b7336ee2828807388475ecec8e4e2f471f3347ce5102d06f6a0f7de7ca7bf47b | from sympy.core.assumptions import StdFactKB, _assume_defined
from sympy.core.compatibility import is_sequence, ordered
from .basic import Basic
from .sympify import sympify
from .singleton import S
from .expr import Expr, AtomicExpr
from .cache import cacheit
from .function import FunctionClass
from sympy.core.logic import fuzzy_bool
from sympy.logic.boolalg import Boolean
from sympy.utilities.iterables import cartes, sift
from sympy.core.containers import Tuple
import string
import re as _re
import random
def _filter_assumptions(kwargs):
"""Split the given dict into assumptions and non-assumptions.
Keys are taken as assumptions if they correspond to an
entry in ``_assume_defined``.
"""
assumptions, nonassumptions = map(dict, sift(kwargs.items(),
lambda i: i[0] in _assume_defined,
binary=True))
Symbol._sanitize(assumptions)
return assumptions, nonassumptions
def _symbol(s, matching_symbol=None, **assumptions):
"""Return s if s is a Symbol, else if s is a string, return either
the matching_symbol if the names are the same or else a new symbol
with the same assumptions as the matching symbol (or the
assumptions as provided).
Examples
========
>>> from sympy import Symbol
>>> from sympy.core.symbol import _symbol
>>> _symbol('y')
y
>>> _.is_real is None
True
>>> _symbol('y', real=True).is_real
True
>>> x = Symbol('x')
>>> _symbol(x, real=True)
x
>>> _.is_real is None # ignore attribute if s is a Symbol
True
Below, the variable sym has the name 'foo':
>>> sym = Symbol('foo', real=True)
Since 'x' is not the same as sym's name, a new symbol is created:
>>> _symbol('x', sym).name
'x'
It will acquire any assumptions give:
>>> _symbol('x', sym, real=False).is_real
False
Since 'foo' is the same as sym's name, sym is returned
>>> _symbol('foo', sym)
foo
Any assumptions given are ignored:
>>> _symbol('foo', sym, real=False).is_real
True
NB: the symbol here may not be the same as a symbol with the same
name defined elsewhere as a result of different assumptions.
See Also
========
sympy.core.symbol.Symbol
"""
if isinstance(s, str):
if matching_symbol and matching_symbol.name == s:
return matching_symbol
return Symbol(s, **assumptions)
elif isinstance(s, Symbol):
return s
else:
raise ValueError('symbol must be string for symbol name or Symbol')
def uniquely_named_symbol(xname, exprs=(), compare=str, modify=None, **assumptions):
"""Return a symbol which, when printed, will have a name unique
from any other already in the expressions given. The name is made
unique by appending numbers (default) but this can be
customized with the keyword 'modify'.
Parameters
==========
xname : a string or a Symbol (when symbol xname <- str(xname))
compare : a single arg function that takes a symbol and returns
a string to be compared with xname (the default is the str
function which indicates how the name will look when it
is printed, e.g. this includes underscores that appear on
Dummy symbols)
modify : a single arg function that changes its string argument
in some way (the default is to append numbers)
Examples
========
>>> from sympy.core.symbol import uniquely_named_symbol
>>> from sympy.abc import x
>>> uniquely_named_symbol('x', x)
x0
"""
from sympy.core.function import AppliedUndef
def numbered_string_incr(s, start=0):
if not s:
return str(start)
i = len(s) - 1
while i != -1:
if not s[i].isdigit():
break
i -= 1
n = str(int(s[i + 1:] or start - 1) + 1)
return s[:i + 1] + n
default = None
if is_sequence(xname):
xname, default = xname
x = str(xname)
if not exprs:
return _symbol(x, default, **assumptions)
if not is_sequence(exprs):
exprs = [exprs]
names = set().union((
[i.name for e in exprs for i in e.atoms(Symbol)] +
[i.func.name for e in exprs for i in e.atoms(AppliedUndef)]))
if modify is None:
modify = numbered_string_incr
while any(x == compare(s) for s in names):
x = modify(x)
return _symbol(x, default, **assumptions)
_uniquely_named_symbol = uniquely_named_symbol
class Symbol(AtomicExpr, Boolean):
"""
Assumptions:
commutative = True
You can override the default assumptions in the constructor:
>>> from sympy import symbols
>>> A,B = symbols('A,B', commutative = False)
>>> bool(A*B != B*A)
True
>>> bool(A*B*2 == 2*A*B) == True # multiplication by scalars is commutative
True
"""
is_comparable = False
__slots__ = ('name',)
is_Symbol = True
is_symbol = True
@property
def _diff_wrt(self):
"""Allow derivatives wrt Symbols.
Examples
========
>>> from sympy import Symbol
>>> x = Symbol('x')
>>> x._diff_wrt
True
"""
return True
@staticmethod
def _sanitize(assumptions, obj=None):
"""Remove None, covert values to bool, check commutativity *in place*.
"""
# be strict about commutativity: cannot be None
is_commutative = fuzzy_bool(assumptions.get('commutative', True))
if is_commutative is None:
whose = '%s ' % obj.__name__ if obj else ''
raise ValueError(
'%scommutativity must be True or False.' % whose)
# sanitize other assumptions so 1 -> True and 0 -> False
for key in list(assumptions.keys()):
v = assumptions[key]
if v is None:
assumptions.pop(key)
continue
assumptions[key] = bool(v)
def _merge(self, assumptions):
base = self.assumptions0
for k in set(assumptions) & set(base):
if assumptions[k] != base[k]:
from sympy.utilities.misc import filldedent
raise ValueError(filldedent('''
non-matching assumptions for %s: existing value
is %s and new value is %s''' % (
k, base[k], assumptions[k])))
base.update(assumptions)
return base
def __new__(cls, name, **assumptions):
"""Symbols are identified by name and assumptions::
>>> from sympy import Symbol
>>> Symbol("x") == Symbol("x")
True
>>> Symbol("x", real=True) == Symbol("x", real=False)
False
"""
cls._sanitize(assumptions, cls)
return Symbol.__xnew_cached_(cls, name, **assumptions)
def __new_stage2__(cls, name, **assumptions):
if not isinstance(name, str):
raise TypeError("name should be a string, not %s" % repr(type(name)))
obj = Expr.__new__(cls)
obj.name = name
# TODO: Issue #8873: Forcing the commutative assumption here means
# later code such as ``srepr()`` cannot tell whether the user
# specified ``commutative=True`` or omitted it. To workaround this,
# we keep a copy of the assumptions dict, then create the StdFactKB,
# and finally overwrite its ``._generator`` with the dict copy. This
# is a bit of a hack because we assume StdFactKB merely copies the
# given dict as ``._generator``, but future modification might, e.g.,
# compute a minimal equivalent assumption set.
tmp_asm_copy = assumptions.copy()
# be strict about commutativity
is_commutative = fuzzy_bool(assumptions.get('commutative', True))
assumptions['commutative'] = is_commutative
obj._assumptions = StdFactKB(assumptions)
obj._assumptions._generator = tmp_asm_copy # Issue #8873
return obj
__xnew__ = staticmethod(
__new_stage2__) # never cached (e.g. dummy)
__xnew_cached_ = staticmethod(
cacheit(__new_stage2__)) # symbols are always cached
def __getnewargs__(self):
return (self.name,)
def __getstate__(self):
return {'_assumptions': self._assumptions}
def _hashable_content(self):
# Note: user-specified assumptions not hashed, just derived ones
return (self.name,) + tuple(sorted(self.assumptions0.items()))
def _eval_subs(self, old, new):
from sympy.core.power import Pow
if old.is_Pow:
return Pow(self, S.One, evaluate=False)._eval_subs(old, new)
@property
def assumptions0(self):
return {key: value for key, value
in self._assumptions.items() if value is not None}
@cacheit
def sort_key(self, order=None):
return self.class_key(), (1, (self.name,)), S.One.sort_key(), S.One
def as_dummy(self):
# only put commutativity in explicitly if it is False
return Dummy(self.name) if self.is_commutative is not False \
else Dummy(self.name, commutative=self.is_commutative)
def as_real_imag(self, deep=True, **hints):
from sympy import im, re
if hints.get('ignore') == self:
return None
else:
return (re(self), im(self))
def _sage_(self):
import sage.all as sage
return sage.var(self.name)
def is_constant(self, *wrt, **flags):
if not wrt:
return False
return not self in wrt
@property
def free_symbols(self):
return {self}
binary_symbols = free_symbols # in this case, not always
def as_set(self):
return S.UniversalSet
class Dummy(Symbol):
"""Dummy symbols are each unique, even if they have the same name:
>>> from sympy import Dummy
>>> Dummy("x") == Dummy("x")
False
If a name is not supplied then a string value of an internal count will be
used. This is useful when a temporary variable is needed and the name
of the variable used in the expression is not important.
>>> Dummy() #doctest: +SKIP
_Dummy_10
"""
# In the rare event that a Dummy object needs to be recreated, both the
# `name` and `dummy_index` should be passed. This is used by `srepr` for
# example:
# >>> d1 = Dummy()
# >>> d2 = eval(srepr(d1))
# >>> d2 == d1
# True
#
# If a new session is started between `srepr` and `eval`, there is a very
# small chance that `d2` will be equal to a previously-created Dummy.
_count = 0
_prng = random.Random()
_base_dummy_index = _prng.randint(10**6, 9*10**6)
__slots__ = ('dummy_index',)
is_Dummy = True
def __new__(cls, name=None, dummy_index=None, **assumptions):
if dummy_index is not None:
assert name is not None, "If you specify a dummy_index, you must also provide a name"
if name is None:
name = "Dummy_" + str(Dummy._count)
if dummy_index is None:
dummy_index = Dummy._base_dummy_index + Dummy._count
Dummy._count += 1
cls._sanitize(assumptions, cls)
obj = Symbol.__xnew__(cls, name, **assumptions)
obj.dummy_index = dummy_index
return obj
def __getstate__(self):
return {'_assumptions': self._assumptions, 'dummy_index': self.dummy_index}
@cacheit
def sort_key(self, order=None):
return self.class_key(), (
2, (self.name, self.dummy_index)), S.One.sort_key(), S.One
def _hashable_content(self):
return Symbol._hashable_content(self) + (self.dummy_index,)
class Wild(Symbol):
"""
A Wild symbol matches anything, or anything
without whatever is explicitly excluded.
Parameters
==========
name : str
Name of the Wild instance.
exclude : iterable, optional
Instances in ``exclude`` will not be matched.
properties : iterable of functions, optional
Functions, each taking an expressions as input
and returns a ``bool``. All functions in ``properties``
need to return ``True`` in order for the Wild instance
to match the expression.
Examples
========
>>> from sympy import Wild, WildFunction, cos, pi
>>> from sympy.abc import x, y, z
>>> a = Wild('a')
>>> x.match(a)
{a_: x}
>>> pi.match(a)
{a_: pi}
>>> (3*x**2).match(a*x)
{a_: 3*x}
>>> cos(x).match(a)
{a_: cos(x)}
>>> b = Wild('b', exclude=[x])
>>> (3*x**2).match(b*x)
>>> b.match(a)
{a_: b_}
>>> A = WildFunction('A')
>>> A.match(a)
{a_: A_}
Tips
====
When using Wild, be sure to use the exclude
keyword to make the pattern more precise.
Without the exclude pattern, you may get matches
that are technically correct, but not what you
wanted. For example, using the above without
exclude:
>>> from sympy import symbols
>>> a, b = symbols('a b', cls=Wild)
>>> (2 + 3*y).match(a*x + b*y)
{a_: 2/x, b_: 3}
This is technically correct, because
(2/x)*x + 3*y == 2 + 3*y, but you probably
wanted it to not match at all. The issue is that
you really didn't want a and b to include x and y,
and the exclude parameter lets you specify exactly
this. With the exclude parameter, the pattern will
not match.
>>> a = Wild('a', exclude=[x, y])
>>> b = Wild('b', exclude=[x, y])
>>> (2 + 3*y).match(a*x + b*y)
Exclude also helps remove ambiguity from matches.
>>> E = 2*x**3*y*z
>>> a, b = symbols('a b', cls=Wild)
>>> E.match(a*b)
{a_: 2*y*z, b_: x**3}
>>> a = Wild('a', exclude=[x, y])
>>> E.match(a*b)
{a_: z, b_: 2*x**3*y}
>>> a = Wild('a', exclude=[x, y, z])
>>> E.match(a*b)
{a_: 2, b_: x**3*y*z}
Wild also accepts a ``properties`` parameter:
>>> a = Wild('a', properties=[lambda k: k.is_Integer])
>>> E.match(a*b)
{a_: 2, b_: x**3*y*z}
"""
is_Wild = True
__slots__ = ('exclude', 'properties')
def __new__(cls, name, exclude=(), properties=(), **assumptions):
exclude = tuple([sympify(x) for x in exclude])
properties = tuple(properties)
cls._sanitize(assumptions, cls)
return Wild.__xnew__(cls, name, exclude, properties, **assumptions)
def __getnewargs__(self):
return (self.name, self.exclude, self.properties)
@staticmethod
@cacheit
def __xnew__(cls, name, exclude, properties, **assumptions):
obj = Symbol.__xnew__(cls, name, **assumptions)
obj.exclude = exclude
obj.properties = properties
return obj
def _hashable_content(self):
return super()._hashable_content() + (self.exclude, self.properties)
# TODO add check against another Wild
def matches(self, expr, repl_dict={}, old=False):
if any(expr.has(x) for x in self.exclude):
return None
if any(not f(expr) for f in self.properties):
return None
repl_dict = repl_dict.copy()
repl_dict[self] = expr
return repl_dict
_range = _re.compile('([0-9]*:[0-9]+|[a-zA-Z]?:[a-zA-Z])')
def symbols(names, **args):
r"""
Transform strings into instances of :class:`Symbol` class.
:func:`symbols` function returns a sequence of symbols with names taken
from ``names`` argument, which can be a comma or whitespace delimited
string, or a sequence of strings::
>>> from sympy import symbols, Function
>>> x, y, z = symbols('x,y,z')
>>> a, b, c = symbols('a b c')
The type of output is dependent on the properties of input arguments::
>>> symbols('x')
x
>>> symbols('x,')
(x,)
>>> symbols('x,y')
(x, y)
>>> symbols(('a', 'b', 'c'))
(a, b, c)
>>> symbols(['a', 'b', 'c'])
[a, b, c]
>>> symbols({'a', 'b', 'c'})
{a, b, c}
If an iterable container is needed for a single symbol, set the ``seq``
argument to ``True`` or terminate the symbol name with a comma::
>>> symbols('x', seq=True)
(x,)
To reduce typing, range syntax is supported to create indexed symbols.
Ranges are indicated by a colon and the type of range is determined by
the character to the right of the colon. If the character is a digit
then all contiguous digits to the left are taken as the nonnegative
starting value (or 0 if there is no digit left of the colon) and all
contiguous digits to the right are taken as 1 greater than the ending
value::
>>> symbols('x:10')
(x0, x1, x2, x3, x4, x5, x6, x7, x8, x9)
>>> symbols('x5:10')
(x5, x6, x7, x8, x9)
>>> symbols('x5(:2)')
(x50, x51)
>>> symbols('x5:10,y:5')
(x5, x6, x7, x8, x9, y0, y1, y2, y3, y4)
>>> symbols(('x5:10', 'y:5'))
((x5, x6, x7, x8, x9), (y0, y1, y2, y3, y4))
If the character to the right of the colon is a letter, then the single
letter to the left (or 'a' if there is none) is taken as the start
and all characters in the lexicographic range *through* the letter to
the right are used as the range::
>>> symbols('x:z')
(x, y, z)
>>> symbols('x:c') # null range
()
>>> symbols('x(:c)')
(xa, xb, xc)
>>> symbols(':c')
(a, b, c)
>>> symbols('a:d, x:z')
(a, b, c, d, x, y, z)
>>> symbols(('a:d', 'x:z'))
((a, b, c, d), (x, y, z))
Multiple ranges are supported; contiguous numerical ranges should be
separated by parentheses to disambiguate the ending number of one
range from the starting number of the next::
>>> symbols('x:2(1:3)')
(x01, x02, x11, x12)
>>> symbols(':3:2') # parsing is from left to right
(00, 01, 10, 11, 20, 21)
Only one pair of parentheses surrounding ranges are removed, so to
include parentheses around ranges, double them. And to include spaces,
commas, or colons, escape them with a backslash::
>>> symbols('x((a:b))')
(x(a), x(b))
>>> symbols(r'x(:1\,:2)') # or r'x((:1)\,(:2))'
(x(0,0), x(0,1))
All newly created symbols have assumptions set according to ``args``::
>>> a = symbols('a', integer=True)
>>> a.is_integer
True
>>> x, y, z = symbols('x,y,z', real=True)
>>> x.is_real and y.is_real and z.is_real
True
Despite its name, :func:`symbols` can create symbol-like objects like
instances of Function or Wild classes. To achieve this, set ``cls``
keyword argument to the desired type::
>>> symbols('f,g,h', cls=Function)
(f, g, h)
>>> type(_[0])
<class 'sympy.core.function.UndefinedFunction'>
"""
result = []
if isinstance(names, str):
marker = 0
literals = [r'\,', r'\:', r'\ ']
for i in range(len(literals)):
lit = literals.pop(0)
if lit in names:
while chr(marker) in names:
marker += 1
lit_char = chr(marker)
marker += 1
names = names.replace(lit, lit_char)
literals.append((lit_char, lit[1:]))
def literal(s):
if literals:
for c, l in literals:
s = s.replace(c, l)
return s
names = names.strip()
as_seq = names.endswith(',')
if as_seq:
names = names[:-1].rstrip()
if not names:
raise ValueError('no symbols given')
# split on commas
names = [n.strip() for n in names.split(',')]
if not all(n for n in names):
raise ValueError('missing symbol between commas')
# split on spaces
for i in range(len(names) - 1, -1, -1):
names[i: i + 1] = names[i].split()
cls = args.pop('cls', Symbol)
seq = args.pop('seq', as_seq)
for name in names:
if not name:
raise ValueError('missing symbol')
if ':' not in name:
symbol = cls(literal(name), **args)
result.append(symbol)
continue
split = _range.split(name)
# remove 1 layer of bounding parentheses around ranges
for i in range(len(split) - 1):
if i and ':' in split[i] and split[i] != ':' and \
split[i - 1].endswith('(') and \
split[i + 1].startswith(')'):
split[i - 1] = split[i - 1][:-1]
split[i + 1] = split[i + 1][1:]
for i, s in enumerate(split):
if ':' in s:
if s[-1].endswith(':'):
raise ValueError('missing end range')
a, b = s.split(':')
if b[-1] in string.digits:
a = 0 if not a else int(a)
b = int(b)
split[i] = [str(c) for c in range(a, b)]
else:
a = a or 'a'
split[i] = [string.ascii_letters[c] for c in range(
string.ascii_letters.index(a),
string.ascii_letters.index(b) + 1)] # inclusive
if not split[i]:
break
else:
split[i] = [s]
else:
seq = True
if len(split) == 1:
names = split[0]
else:
names = [''.join(s) for s in cartes(*split)]
if literals:
result.extend([cls(literal(s), **args) for s in names])
else:
result.extend([cls(s, **args) for s in names])
if not seq and len(result) <= 1:
if not result:
return ()
return result[0]
return tuple(result)
else:
for name in names:
result.append(symbols(name, **args))
return type(names)(result)
def var(names, **args):
"""
Create symbols and inject them into the global namespace.
This calls :func:`symbols` with the same arguments and puts the results
into the *global* namespace. It's recommended not to use :func:`var` in
library code, where :func:`symbols` has to be used::
Examples
========
>>> from sympy import var
>>> var('x')
x
>>> x # noqa: F821
x
>>> var('a,ab,abc')
(a, ab, abc)
>>> abc # noqa: F821
abc
>>> var('x,y', real=True)
(x, y)
>>> x.is_real and y.is_real # noqa: F821
True
See :func:`symbols` documentation for more details on what kinds of
arguments can be passed to :func:`var`.
"""
def traverse(symbols, frame):
"""Recursively inject symbols to the global namespace. """
for symbol in symbols:
if isinstance(symbol, Basic):
frame.f_globals[symbol.name] = symbol
elif isinstance(symbol, FunctionClass):
frame.f_globals[symbol.__name__] = symbol
else:
traverse(symbol, frame)
from inspect import currentframe
frame = currentframe().f_back
try:
syms = symbols(names, **args)
if syms is not None:
if isinstance(syms, Basic):
frame.f_globals[syms.name] = syms
elif isinstance(syms, FunctionClass):
frame.f_globals[syms.__name__] = syms
else:
traverse(syms, frame)
finally:
del frame # break cyclic dependencies as stated in inspect docs
return syms
def disambiguate(*iter):
"""
Return a Tuple containing the passed expressions with symbols
that appear the same when printed replaced with numerically
subscripted symbols, and all Dummy symbols replaced with Symbols.
Parameters
==========
iter: list of symbols or expressions.
Examples
========
>>> from sympy.core.symbol import disambiguate
>>> from sympy import Dummy, Symbol, Tuple
>>> from sympy.abc import y
>>> tup = Symbol('_x'), Dummy('x'), Dummy('x')
>>> disambiguate(*tup)
(x_2, x, x_1)
>>> eqs = Tuple(Symbol('x')/y, Dummy('x')/y)
>>> disambiguate(*eqs)
(x_1/y, x/y)
>>> ix = Symbol('x', integer=True)
>>> vx = Symbol('x')
>>> disambiguate(vx + ix)
(x + x_1,)
To make your own mapping of symbols to use, pass only the free symbols
of the expressions and create a dictionary:
>>> free = eqs.free_symbols
>>> mapping = dict(zip(free, disambiguate(*free)))
>>> eqs.xreplace(mapping)
(x_1/y, x/y)
"""
new_iter = Tuple(*iter)
key = lambda x:tuple(sorted(x.assumptions0.items()))
syms = ordered(new_iter.free_symbols, keys=key)
mapping = {}
for s in syms:
mapping.setdefault(str(s).lstrip('_'), []).append(s)
reps = {}
for k in mapping:
# the first or only symbol doesn't get subscripted but make
# sure that it's a Symbol, not a Dummy
mapk0 = Symbol("%s" % (k), **mapping[k][0].assumptions0)
if mapping[k][0] != mapk0:
reps[mapping[k][0]] = mapk0
# the others get subscripts (and are made into Symbols)
skip = 0
for i in range(1, len(mapping[k])):
while True:
name = "%s_%i" % (k, i + skip)
if name not in mapping:
break
skip += 1
ki = mapping[k][i]
reps[ki] = Symbol(name, **ki.assumptions0)
return new_iter.xreplace(reps)
|
cf71309d4e5bea5c21891555d042d998c66d3aee5fc67560864fea559b4c231c | """
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 typing import Tuple, Type
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
* Use `u()` for escaped unicode sequences (e.g. u'\u2020' -> u('\u2020'))
* Use `u_decode()` to decode utf-8 formatted unicode strings
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 `__builtin__`, access with Python 3 name, `builtins`
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
"""
__all__ = [
'PY3', 'int_info', 'SYMPY_INTS', 'lru_cache', 'clock',
'unicode', 'u_decode', 'get_function_code', 'gmpy',
'get_function_globals', 'get_function_name', 'builtins', 'reduce',
'StringIO', 'cStringIO', 'exec_', 'Mapping', 'Callable',
'MutableMapping', 'MutableSet', 'Iterable', 'Hashable', 'unwrap',
'accumulate', 'with_metaclass', 'NotIterable', 'iterable', 'is_sequence',
'as_int', 'default_sort_key', 'ordered', 'GROUND_TYPES', 'HAS_GMPY',
]
import sys
PY3 = sys.version_info[0] > 2
if PY3:
int_info = sys.int_info
# String / unicode compatibility
unicode = str
def u_decode(x):
return x
# 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")
from collections.abc import (Mapping, Callable, MutableMapping,
MutableSet, Iterable, Hashable)
from inspect import unwrap
from itertools import accumulate
else:
int_info = sys.long_info
# String / unicode compatibility
unicode = unicode
def u_decode(x):
return x.decode('utf-8')
# 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_")
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=(str, 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))
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 True, this
uses `__index__ <https://docs.python.org/3/reference/datamodel.html#object.__index__>`_
and when it is False it uses ``int``.
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
"""
if strict:
try:
if type(n) is bool:
raise TypeError
return operator.index(n)
except TypeError:
raise ValueError('%s is not an integer' % (n,))
else:
try:
result = int(n)
except TypeError:
raise ValueError('%s is not an integer' % (n,))
if n != result:
raise ValueError('%s is not an integer' % (n,))
return result
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=str):
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, str):
try:
item = sympify(item, strict=True)
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
from .function import Derivative
if isinstance(e, Basic):
if isinstance(e, Derivative):
return _nodes(e.expr) + len(e.variables)
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)
yield from d[k]
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
else:
gmpy = None
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 = (int, ) # type: Tuple[Type, ...]
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 = {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)
if sys.version_info[:2] >= (3, 3):
# 3.2 has an lru_cache with an incompatible API
from functools import lru_cache
else:
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]
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
from time import perf_counter as clock
|
fddbf3e05cb7befcddf957ea82595df6e1a4b8e74036fd4962187a7b59cb25db | """sympify -- convert objects SymPy internal format"""
from typing import Dict, Type, Callable, Any
from inspect import getmro
from .compatibility import iterable
from .parameters import global_parameters
class SympifyError(ValueError):
def __init__(self, expr, base_exc=None):
self.expr = expr
self.base_exc = base_exc
def __str__(self):
if self.base_exc is None:
return "SympifyError: %r" % (self.expr,)
return ("Sympify of expression '%s' failed, because of exception being "
"raised:\n%s: %s" % (self.expr, self.base_exc.__class__.__name__,
str(self.base_exc)))
# See sympify docstring.
converter = {} # type: Dict[Type[Any], Callable[[Any], Basic]]
class CantSympify:
"""
Mix in this trait to a class to disallow sympification of its instances.
Examples
========
>>> from sympy.core.sympify import sympify, CantSympify
>>> class Something(dict):
... pass
...
>>> sympify(Something())
{}
>>> class Something(dict, CantSympify):
... pass
...
>>> sympify(Something())
Traceback (most recent call last):
...
SympifyError: SympifyError: {}
"""
pass
def _is_numpy_instance(a):
"""
Checks if an object is an instance of a type from the numpy module.
"""
# This check avoids unnecessarily importing NumPy. We check the whole
# __mro__ in case any base type is a numpy type.
return any(type_.__module__ == 'numpy'
for type_ in type(a).__mro__)
def _convert_numpy_types(a, **sympify_args):
"""
Converts a numpy datatype input to an appropriate SymPy type.
"""
import numpy as np
if not isinstance(a, np.floating):
if np.iscomplex(a):
return converter[complex](a.item())
else:
return sympify(a.item(), **sympify_args)
else:
try:
from sympy.core.numbers import Float
prec = np.finfo(a).nmant + 1
# E.g. double precision means prec=53 but nmant=52
# Leading bit of mantissa is always 1, so is not stored
a = str(list(np.reshape(np.asarray(a),
(1, np.size(a)))[0]))[1:-1]
return Float(a, precision=prec)
except NotImplementedError:
raise SympifyError('Translation for numpy float : %s '
'is not implemented' % a)
def sympify(a, locals=None, convert_xor=True, strict=False, rational=False,
evaluate=None):
"""Converts an arbitrary expression to a type that can be used inside SymPy.
For example, it will convert Python ints into instances of sympy.Integer,
floats into instances of sympy.Float, etc. It is also able to coerce symbolic
expressions which inherit from Basic. This can be useful in cooperation
with SAGE.
It currently accepts as arguments:
- any object defined in SymPy
- standard numeric python types: int, long, float, Decimal
- strings (like "0.09" or "2e-19")
- booleans, including ``None`` (will leave ``None`` unchanged)
- dict, lists, sets or tuples containing any of the above
.. warning::
Note that this function uses ``eval``, and thus shouldn't be used on
unsanitized input.
If the argument is already a type that SymPy understands, it will do
nothing but return that value. This can be used at the beginning of a
function to ensure you are working with the correct type.
>>> from sympy import sympify
>>> sympify(2).is_integer
True
>>> sympify(2).is_real
True
>>> sympify(2.0).is_real
True
>>> sympify("2.0").is_real
True
>>> sympify("2e-45").is_real
True
If the expression could not be converted, a SympifyError is raised.
>>> sympify("x***2")
Traceback (most recent call last):
...
SympifyError: SympifyError: "could not parse u'x***2'"
Locals
------
The sympification happens with access to everything that is loaded
by ``from sympy import *``; anything used in a string that is not
defined by that import will be converted to a symbol. In the following,
the ``bitcount`` function is treated as a symbol and the ``O`` is
interpreted as the Order object (used with series) and it raises
an error when used improperly:
>>> s = 'bitcount(42)'
>>> sympify(s)
bitcount(42)
>>> sympify("O(x)")
O(x)
>>> sympify("O + 1")
Traceback (most recent call last):
...
TypeError: unbound method...
In order to have ``bitcount`` be recognized it can be imported into a
namespace dictionary and passed as locals:
>>> from sympy.core.compatibility import exec_
>>> ns = {}
>>> exec_('from sympy.core.evalf import bitcount', ns)
>>> sympify(s, locals=ns)
6
In order to have the ``O`` interpreted as a Symbol, identify it as such
in the namespace dictionary. This can be done in a variety of ways; all
three of the following are possibilities:
>>> from sympy import Symbol
>>> ns["O"] = Symbol("O") # method 1
>>> exec_('from sympy.abc import O', ns) # method 2
>>> ns.update(dict(O=Symbol("O"))) # method 3
>>> sympify("O + 1", locals=ns)
O + 1
If you want *all* single-letter and Greek-letter variables to be symbols
then you can use the clashing-symbols dictionaries that have been defined
there as private variables: _clash1 (single-letter variables), _clash2
(the multi-letter Greek names) or _clash (both single and multi-letter
names that are defined in abc).
>>> from sympy.abc import _clash1
>>> _clash1
{'C': C, 'E': E, 'I': I, 'N': N, 'O': O, 'Q': Q, 'S': S}
>>> sympify('I & Q', _clash1)
I & Q
Strict
------
If the option ``strict`` is set to ``True``, only the types for which an
explicit conversion has been defined are converted. In the other
cases, a SympifyError is raised.
>>> print(sympify(None))
None
>>> sympify(None, strict=True)
Traceback (most recent call last):
...
SympifyError: SympifyError: None
Evaluation
----------
If the option ``evaluate`` is set to ``False``, then arithmetic and
operators will be converted into their SymPy equivalents and the
``evaluate=False`` option will be added. Nested ``Add`` or ``Mul`` will
be denested first. This is done via an AST transformation that replaces
operators with their SymPy equivalents, so if an operand redefines any
of those operations, the redefined operators will not be used.
>>> sympify('2**2 / 3 + 5')
19/3
>>> sympify('2**2 / 3 + 5', evaluate=False)
2**2/3 + 5
Extending
---------
To extend ``sympify`` to convert custom objects (not derived from ``Basic``),
just define a ``_sympy_`` method to your class. You can do that even to
classes that you do not own by subclassing or adding the method at runtime.
>>> from sympy import Matrix
>>> class MyList1(object):
... def __iter__(self):
... yield 1
... yield 2
... return
... def __getitem__(self, i): return list(self)[i]
... def _sympy_(self): return Matrix(self)
>>> sympify(MyList1())
Matrix([
[1],
[2]])
If you do not have control over the class definition you could also use the
``converter`` global dictionary. The key is the class and the value is a
function that takes a single argument and returns the desired SymPy
object, e.g. ``converter[MyList] = lambda x: Matrix(x)``.
>>> class MyList2(object): # XXX Do not do this if you control the class!
... def __iter__(self): # Use _sympy_!
... yield 1
... yield 2
... return
... def __getitem__(self, i): return list(self)[i]
>>> from sympy.core.sympify import converter
>>> converter[MyList2] = lambda x: Matrix(x)
>>> sympify(MyList2())
Matrix([
[1],
[2]])
Notes
=====
The keywords ``rational`` and ``convert_xor`` are only used
when the input is a string.
Sometimes autosimplification during sympification results in expressions
that are very different in structure than what was entered. Until such
autosimplification is no longer done, the ``kernS`` function might be of
some use. In the example below you can see how an expression reduces to
-1 by autosimplification, but does not do so when ``kernS`` is used.
>>> from sympy.core.sympify import kernS
>>> from sympy.abc import x
>>> -2*(-(-x + 1/x)/(x*(x - 1/x)**2) - 1/(x*(x - 1/x))) - 1
-1
>>> s = '-2*(-(-x + 1/x)/(x*(x - 1/x)**2) - 1/(x*(x - 1/x))) - 1'
>>> sympify(s)
-1
>>> kernS(s)
-2*(-(-x + 1/x)/(x*(x - 1/x)**2) - 1/(x*(x - 1/x))) - 1
"""
is_sympy = getattr(a, '__sympy__', None)
if is_sympy is not None:
return a
if isinstance(a, CantSympify):
raise SympifyError(a)
cls = getattr(a, "__class__", None)
if cls is None:
cls = type(a) # Probably an old-style class
conv = converter.get(cls, None)
if conv is not None:
return conv(a)
for superclass in getmro(cls):
try:
return converter[superclass](a)
except KeyError:
continue
if cls is type(None):
if strict:
raise SympifyError(a)
else:
return a
if evaluate is None:
evaluate = global_parameters.evaluate
# Support for basic numpy datatypes
if _is_numpy_instance(a):
import numpy as np
if np.isscalar(a):
return _convert_numpy_types(a, locals=locals,
convert_xor=convert_xor, strict=strict, rational=rational,
evaluate=evaluate)
_sympy_ = getattr(a, "_sympy_", None)
if _sympy_ is not None:
try:
return a._sympy_()
# XXX: Catches AttributeError: 'SympyConverter' object has no
# attribute 'tuple'
# This is probably a bug somewhere but for now we catch it here.
except AttributeError:
pass
if not strict:
# Put numpy array conversion _before_ float/int, see
# <https://github.com/sympy/sympy/issues/13924>.
flat = getattr(a, "flat", None)
if flat is not None:
shape = getattr(a, "shape", None)
if shape is not None:
from ..tensor.array import Array
return Array(a.flat, a.shape) # works with e.g. NumPy arrays
if not isinstance(a, str):
if _is_numpy_instance(a):
import numpy as np
assert not isinstance(a, np.number)
if isinstance(a, np.ndarray):
# Scalar arrays (those with zero dimensions) have sympify
# called on the scalar element.
if a.ndim == 0:
try:
return sympify(a.item(),
locals=locals,
convert_xor=convert_xor,
strict=strict,
rational=rational,
evaluate=evaluate)
except SympifyError:
pass
else:
# float and int can coerce size-one numpy arrays to their lone
# element. See issue https://github.com/numpy/numpy/issues/10404.
for coerce in (float, int):
try:
return sympify(coerce(a))
except (TypeError, ValueError, AttributeError, SympifyError):
continue
if strict:
raise SympifyError(a)
if iterable(a):
try:
return type(a)([sympify(x, locals=locals, convert_xor=convert_xor,
rational=rational) for x in a])
except TypeError:
# Not all iterables are rebuildable with their type.
pass
if isinstance(a, dict):
try:
return type(a)([sympify(x, locals=locals, convert_xor=convert_xor,
rational=rational) for x in a.items()])
except TypeError:
# Not all iterables are rebuildable with their type.
pass
if not isinstance(a, str):
try:
a = str(a)
except Exception as exc:
raise SympifyError(a, exc)
from sympy.utilities.exceptions import SymPyDeprecationWarning
SymPyDeprecationWarning(
feature="String fallback in sympify",
useinstead= \
'sympify(str(obj)) or ' + \
'sympy.core.sympify.converter or obj._sympy_',
issue=18066,
deprecated_since_version='1.6'
).warn()
from sympy.parsing.sympy_parser import (parse_expr, TokenError,
standard_transformations)
from sympy.parsing.sympy_parser import convert_xor as t_convert_xor
from sympy.parsing.sympy_parser import rationalize as t_rationalize
transformations = standard_transformations
if rational:
transformations += (t_rationalize,)
if convert_xor:
transformations += (t_convert_xor,)
try:
a = a.replace('\n', '')
expr = parse_expr(a, local_dict=locals, transformations=transformations, evaluate=evaluate)
except (TokenError, SyntaxError) as exc:
raise SympifyError('could not parse %r' % a, exc)
return expr
def _sympify(a):
"""
Short version of sympify for internal usage for __add__ and __eq__ methods
where it is ok to allow some things (like Python integers and floats) in
the expression. This excludes things (like strings) that are unwise to
allow into such an expression.
>>> from sympy import Integer
>>> Integer(1) == 1
True
>>> Integer(1) == '1'
False
>>> from sympy.abc import x
>>> x + 1
x + 1
>>> x + '1'
Traceback (most recent call last):
...
TypeError: unsupported operand type(s) for +: 'Symbol' and 'str'
see: sympify
"""
return sympify(a, strict=True)
def kernS(s):
"""Use a hack to try keep autosimplification from distributing a
a number into an Add; this modification doesn't
prevent the 2-arg Mul from becoming an Add, however.
Examples
========
>>> from sympy.core.sympify import kernS
>>> from sympy.abc import x, y
The 2-arg Mul distributes a number (or minus sign) across the terms
of an expression, but kernS will prevent that:
>>> 2*(x + y), -(x + 1)
(2*x + 2*y, -x - 1)
>>> kernS('2*(x + y)')
2*(x + y)
>>> kernS('-(x + 1)')
-(x + 1)
If use of the hack fails, the un-hacked string will be passed to sympify...
and you get what you get.
XXX This hack should not be necessary once issue 4596 has been resolved.
"""
import string
from random import choice
from sympy.core.symbol import Symbol
hit = False
quoted = '"' in s or "'" in s
if '(' in s and not quoted:
if s.count('(') != s.count(")"):
raise SympifyError('unmatched left parenthesis')
# strip all space from s
s = ''.join(s.split())
olds = s
# now use space to represent a symbol that
# will
# step 1. turn potential 2-arg Muls into 3-arg versions
# 1a. *( -> * *(
s = s.replace('*(', '* *(')
# 1b. close up exponentials
s = s.replace('** *', '**')
# 2. handle the implied multiplication of a negated
# parenthesized expression in two steps
# 2a: -(...) --> -( *(...)
target = '-( *('
s = s.replace('-(', target)
# 2b: double the matching closing parenthesis
# -( *(...) --> -( *(...))
i = nest = 0
assert target.endswith('(') # assumption below
while True:
j = s.find(target, i)
if j == -1:
break
j += len(target) - 1
for j in range(j, len(s)):
if s[j] == "(":
nest += 1
elif s[j] == ")":
nest -= 1
if nest == 0:
break
s = s[:j] + ")" + s[j:]
i = j + 2 # the first char after 2nd )
if ' ' in s:
# get a unique kern
kern = '_'
while kern in s:
kern += choice(string.ascii_letters + string.digits)
s = s.replace(' ', kern)
hit = kern in s
for i in range(2):
try:
expr = sympify(s)
break
except TypeError: # the kern might cause unknown errors...
if hit:
s = olds # maybe it didn't like the kern; use un-kerned s
hit = False
continue
expr = sympify(s) # let original error raise
if not hit:
return expr
rep = {Symbol(kern): 1}
def _clear(expr):
if isinstance(expr, (list, tuple, set)):
return type(expr)([_clear(e) for e in expr])
if hasattr(expr, 'subs'):
return expr.subs(rep, hack2=True)
return expr
expr = _clear(expr)
# hope that kern is not there anymore
return expr
# Avoid circular import
from .basic import Basic
|
65e5c077aa334548aab18a00f9ebbbb8305c5a1f0c0f758c29c15e8d10540de6 | """ Caching facility for SymPy """
from distutils.version import LooseVersion as V
class _cache(list):
""" List of cached functions """
def print_cache(self):
"""print cache info"""
for item in self:
name = item.__name__
myfunc = item
while hasattr(myfunc, '__wrapped__'):
if hasattr(myfunc, 'cache_info'):
info = myfunc.cache_info()
break
else:
myfunc = myfunc.__wrapped__
else:
info = None
print(name, info)
def clear_cache(self):
"""clear cache content"""
for item in self:
myfunc = item
while hasattr(myfunc, '__wrapped__'):
if hasattr(myfunc, 'cache_clear'):
myfunc.cache_clear()
break
else:
myfunc = myfunc.__wrapped__
# global cache registry:
CACHE = _cache()
# make clear and print methods available
print_cache = CACHE.print_cache
clear_cache = CACHE.clear_cache
try:
import fastcache
from warnings import warn
# the version attribute __version__ is not present for all versions
if not hasattr(fastcache, '__version__'):
warn("fastcache version >= 0.4.0 required", UserWarning)
raise ImportError
# ensure minimum required version of fastcache is present
if V(fastcache.__version__) < '0.4.0':
warn("fastcache version >= 0.4.0 required, detected {}"\
.format(fastcache.__version__), UserWarning)
raise ImportError
# Do not use fastcache if running under pypy
import platform
if platform.python_implementation() == 'PyPy':
raise ImportError
lru_cache = fastcache.clru_cache
except ImportError:
from sympy.core.compatibility import lru_cache
def __cacheit(maxsize):
"""caching decorator.
important: the result of cached function must be *immutable*
Examples
========
>>> from sympy.core.cache import cacheit
>>> @cacheit
... def f(a, b):
... return a+b
>>> @cacheit
... def f(a, b): # noqa: F811
... return [a, b] # <-- WRONG, returns mutable object
to force cacheit to check returned results mutability and consistency,
set environment variable SYMPY_USE_CACHE to 'debug'
"""
def func_wrapper(func):
from .decorators import wraps
cfunc = lru_cache(maxsize, typed=True)(func)
@wraps(func)
def wrapper(*args, **kwargs):
try:
retval = cfunc(*args, **kwargs)
except TypeError:
retval = func(*args, **kwargs)
return retval
wrapper.cache_info = cfunc.cache_info
wrapper.cache_clear = cfunc.cache_clear
CACHE.append(wrapper)
return wrapper
return func_wrapper
else:
def __cacheit(maxsize):
"""caching decorator.
important: the result of cached function must be *immutable*
Examples
========
>>> from sympy.core.cache import cacheit
>>> @cacheit
... def f(a, b):
... return a+b
>>> @cacheit
... def f(a, b): # noqa: F811
... return [a, b] # <-- WRONG, returns mutable object
to force cacheit to check returned results mutability and consistency,
set environment variable SYMPY_USE_CACHE to 'debug'
"""
def func_wrapper(func):
cfunc = fastcache.clru_cache(maxsize, typed=True, unhashable='ignore')(func)
CACHE.append(cfunc)
return cfunc
return func_wrapper
########################################
def __cacheit_nocache(func):
return func
def __cacheit_debug(maxsize):
"""cacheit + code to check cache consistency"""
def func_wrapper(func):
from .decorators import wraps
cfunc = __cacheit(maxsize)(func)
@wraps(func)
def wrapper(*args, **kw_args):
# always call function itself and compare it with cached version
r1 = func(*args, **kw_args)
r2 = cfunc(*args, **kw_args)
# try to see if the result is immutable
#
# this works because:
#
# hash([1,2,3]) -> raise TypeError
# hash({'a':1, 'b':2}) -> raise TypeError
# hash((1,[2,3])) -> raise TypeError
#
# hash((1,2,3)) -> just computes the hash
hash(r1), hash(r2)
# also see if returned values are the same
if r1 != r2:
raise RuntimeError("Returned values are not the same")
return r1
return wrapper
return func_wrapper
def _getenv(key, default=None):
from os import getenv
return getenv(key, default)
# SYMPY_USE_CACHE=yes/no/debug
USE_CACHE = _getenv('SYMPY_USE_CACHE', 'yes').lower()
# SYMPY_CACHE_SIZE=some_integer/None
# special cases :
# SYMPY_CACHE_SIZE=0 -> No caching
# SYMPY_CACHE_SIZE=None -> Unbounded caching
scs = _getenv('SYMPY_CACHE_SIZE', '1000')
if scs.lower() == 'none':
SYMPY_CACHE_SIZE = None
else:
try:
SYMPY_CACHE_SIZE = int(scs)
except ValueError:
raise RuntimeError(
'SYMPY_CACHE_SIZE must be a valid integer or None. ' + \
'Got: %s' % SYMPY_CACHE_SIZE)
if USE_CACHE == 'no':
cacheit = __cacheit_nocache
elif USE_CACHE == 'yes':
cacheit = __cacheit(SYMPY_CACHE_SIZE)
elif USE_CACHE == 'debug':
cacheit = __cacheit_debug(SYMPY_CACHE_SIZE) # a lot slower
else:
raise RuntimeError(
'unrecognized value for SYMPY_USE_CACHE: %s' % USE_CACHE)
|
c8f30022a3accc578fb357a1c3d7c8a84dc26753121209aefd27721b0eb236a3 | from collections import defaultdict
from functools import cmp_to_key
import operator
from .sympify import sympify
from .basic import Basic
from .singleton import S
from .operations import AssocOp
from .cache import cacheit
from .logic import fuzzy_not, _fuzzy_group, fuzzy_and
from .compatibility import reduce
from .expr import Expr
from .parameters import global_parameters
# internal marker to indicate:
# "there are still non-commutative objects -- don't forget to process them"
class NC_Marker:
is_Order = False
is_Mul = False
is_Number = False
is_Poly = False
is_commutative = False
# Key for sorting commutative args in canonical order
_args_sortkey = cmp_to_key(Basic.compare)
def _mulsort(args):
# in-place sorting of args
args.sort(key=_args_sortkey)
def _unevaluated_Mul(*args):
"""Return a well-formed unevaluated Mul: Numbers are collected and
put in slot 0, any arguments that are Muls will be flattened, and args
are sorted. Use this when args have changed but you still want to return
an unevaluated Mul.
Examples
========
>>> from sympy.core.mul import _unevaluated_Mul as uMul
>>> from sympy import S, sqrt, Mul
>>> from sympy.abc import x
>>> a = uMul(*[S(3.0), x, S(2)])
>>> a.args[0]
6.00000000000000
>>> a.args[1]
x
Two unevaluated Muls with the same arguments will
always compare as equal during testing:
>>> m = uMul(sqrt(2), sqrt(3))
>>> m == uMul(sqrt(3), sqrt(2))
True
>>> u = Mul(sqrt(3), sqrt(2), evaluate=False)
>>> m == uMul(u)
True
>>> m == Mul(*m.args)
False
"""
args = list(args)
newargs = []
ncargs = []
co = S.One
while args:
a = args.pop()
if a.is_Mul:
c, nc = a.args_cnc()
args.extend(c)
if nc:
ncargs.append(Mul._from_args(nc))
elif a.is_Number:
co *= a
else:
newargs.append(a)
_mulsort(newargs)
if co is not S.One:
newargs.insert(0, co)
if ncargs:
newargs.append(Mul._from_args(ncargs))
return Mul._from_args(newargs)
class Mul(Expr, AssocOp):
__slots__ = ()
is_Mul = True
_args_type = Expr
def __neg__(self):
c, args = self.as_coeff_mul()
c = -c
if c is not S.One:
if args[0].is_Number:
args = list(args)
if c is S.NegativeOne:
args[0] = -args[0]
else:
args[0] *= c
else:
args = (c,) + args
return self._from_args(args, self.is_commutative)
@classmethod
def flatten(cls, seq):
"""Return commutative, noncommutative and order arguments by
combining related terms.
Notes
=====
* In an expression like ``a*b*c``, python process this through sympy
as ``Mul(Mul(a, b), c)``. This can have undesirable consequences.
- Sometimes terms are not combined as one would like:
{c.f. https://github.com/sympy/sympy/issues/4596}
>>> from sympy import Mul, sqrt
>>> from sympy.abc import x, y, z
>>> 2*(x + 1) # this is the 2-arg Mul behavior
2*x + 2
>>> y*(x + 1)*2
2*y*(x + 1)
>>> 2*(x + 1)*y # 2-arg result will be obtained first
y*(2*x + 2)
>>> Mul(2, x + 1, y) # all 3 args simultaneously processed
2*y*(x + 1)
>>> 2*((x + 1)*y) # parentheses can control this behavior
2*y*(x + 1)
Powers with compound bases may not find a single base to
combine with unless all arguments are processed at once.
Post-processing may be necessary in such cases.
{c.f. https://github.com/sympy/sympy/issues/5728}
>>> a = sqrt(x*sqrt(y))
>>> a**3
(x*sqrt(y))**(3/2)
>>> Mul(a,a,a)
(x*sqrt(y))**(3/2)
>>> a*a*a
x*sqrt(y)*sqrt(x*sqrt(y))
>>> _.subs(a.base, z).subs(z, a.base)
(x*sqrt(y))**(3/2)
- If more than two terms are being multiplied then all the
previous terms will be re-processed for each new argument.
So if each of ``a``, ``b`` and ``c`` were :class:`Mul`
expression, then ``a*b*c`` (or building up the product
with ``*=``) will process all the arguments of ``a`` and
``b`` twice: once when ``a*b`` is computed and again when
``c`` is multiplied.
Using ``Mul(a, b, c)`` will process all arguments once.
* The results of Mul are cached according to arguments, so flatten
will only be called once for ``Mul(a, b, c)``. If you can
structure a calculation so the arguments are most likely to be
repeats then this can save time in computing the answer. For
example, say you had a Mul, M, that you wished to divide by ``d[i]``
and multiply by ``n[i]`` and you suspect there are many repeats
in ``n``. It would be better to compute ``M*n[i]/d[i]`` rather
than ``M/d[i]*n[i]`` since every time n[i] is a repeat, the
product, ``M*n[i]`` will be returned without flattening -- the
cached value will be returned. If you divide by the ``d[i]``
first (and those are more unique than the ``n[i]``) then that will
create a new Mul, ``M/d[i]`` the args of which will be traversed
again when it is multiplied by ``n[i]``.
{c.f. https://github.com/sympy/sympy/issues/5706}
This consideration is moot if the cache is turned off.
NB
--
The validity of the above notes depends on the implementation
details of Mul and flatten which may change at any time. Therefore,
you should only consider them when your code is highly performance
sensitive.
Removal of 1 from the sequence is already handled by AssocOp.__new__.
"""
from sympy.calculus.util import AccumBounds
from sympy.matrices.expressions import MatrixExpr
rv = None
if len(seq) == 2:
a, b = seq
if b.is_Rational:
a, b = b, a
seq = [a, b]
assert not a is S.One
if not a.is_zero and a.is_Rational:
r, b = b.as_coeff_Mul()
if b.is_Add:
if r is not S.One: # 2-arg hack
# leave the Mul as a Mul?
ar = a*r
if ar is S.One:
arb = b
else:
arb = cls(a*r, b, evaluate=False)
rv = [arb], [], None
elif global_parameters.distribute and b.is_commutative:
r, b = b.as_coeff_Add()
bargs = [_keep_coeff(a, bi) for bi in Add.make_args(b)]
_addsort(bargs)
ar = a*r
if ar:
bargs.insert(0, ar)
bargs = [Add._from_args(bargs)]
rv = bargs, [], None
if rv:
return rv
# apply associativity, separate commutative part of seq
c_part = [] # out: commutative factors
nc_part = [] # out: non-commutative factors
nc_seq = []
coeff = S.One # standalone term
# e.g. 3 * ...
c_powers = [] # (base,exp) n
# e.g. (x,n) for x
num_exp = [] # (num-base, exp) y
# e.g. (3, y) for ... * 3 * ...
neg1e = S.Zero # exponent on -1 extracted from Number-based Pow and I
pnum_rat = {} # (num-base, Rat-exp) 1/2
# e.g. (3, 1/2) for ... * 3 * ...
order_symbols = None
# --- PART 1 ---
#
# "collect powers and coeff":
#
# o coeff
# o c_powers
# o num_exp
# o neg1e
# o pnum_rat
#
# NOTE: this is optimized for all-objects-are-commutative case
for o in seq:
# O(x)
if o.is_Order:
o, order_symbols = o.as_expr_variables(order_symbols)
# Mul([...])
if o.is_Mul:
if o.is_commutative:
seq.extend(o.args) # XXX zerocopy?
else:
# NCMul can have commutative parts as well
for q in o.args:
if q.is_commutative:
seq.append(q)
else:
nc_seq.append(q)
# append non-commutative marker, so we don't forget to
# process scheduled non-commutative objects
seq.append(NC_Marker)
continue
# 3
elif o.is_Number:
if o is S.NaN or coeff is S.ComplexInfinity and o.is_zero:
# we know for sure the result will be nan
return [S.NaN], [], None
elif coeff.is_Number or isinstance(coeff, AccumBounds): # it could be zoo
coeff *= o
if coeff is S.NaN:
# we know for sure the result will be nan
return [S.NaN], [], None
continue
elif isinstance(o, AccumBounds):
coeff = o.__mul__(coeff)
continue
elif o is S.ComplexInfinity:
if not coeff:
# 0 * zoo = NaN
return [S.NaN], [], None
coeff = S.ComplexInfinity
continue
elif o is S.ImaginaryUnit:
neg1e += S.Half
continue
elif o.is_commutative:
# e
# o = b
b, e = o.as_base_exp()
# y
# 3
if o.is_Pow:
if b.is_Number:
# get all the factors with numeric base so they can be
# combined below, but don't combine negatives unless
# the exponent is an integer
if e.is_Rational:
if e.is_Integer:
coeff *= Pow(b, e) # it is an unevaluated power
continue
elif e.is_negative: # also a sign of an unevaluated power
seq.append(Pow(b, e))
continue
elif b.is_negative:
neg1e += e
b = -b
if b is not S.One:
pnum_rat.setdefault(b, []).append(e)
continue
elif b.is_positive or e.is_integer:
num_exp.append((b, e))
continue
c_powers.append((b, e))
# NON-COMMUTATIVE
# TODO: Make non-commutative exponents not combine automatically
else:
if o is not NC_Marker:
nc_seq.append(o)
# process nc_seq (if any)
while nc_seq:
o = nc_seq.pop(0)
if not nc_part:
nc_part.append(o)
continue
# b c b+c
# try to combine last terms: a * a -> a
o1 = nc_part.pop()
b1, e1 = o1.as_base_exp()
b2, e2 = o.as_base_exp()
new_exp = e1 + e2
# Only allow powers to combine if the new exponent is
# not an Add. This allow things like a**2*b**3 == a**5
# if a.is_commutative == False, but prohibits
# a**x*a**y and x**a*x**b from combining (x,y commute).
if b1 == b2 and (not new_exp.is_Add):
o12 = b1 ** new_exp
# now o12 could be a commutative object
if o12.is_commutative:
seq.append(o12)
continue
else:
nc_seq.insert(0, o12)
else:
nc_part.append(o1)
nc_part.append(o)
# We do want a combined exponent if it would not be an Add, such as
# y 2y 3y
# x * x -> x
# We determine if two exponents have the same term by using
# as_coeff_Mul.
#
# Unfortunately, this isn't smart enough to consider combining into
# exponents that might already be adds, so things like:
# z - y y
# x * x will be left alone. This is because checking every possible
# combination can slow things down.
# gather exponents of common bases...
def _gather(c_powers):
common_b = {} # b:e
for b, e in c_powers:
co = e.as_coeff_Mul()
common_b.setdefault(b, {}).setdefault(
co[1], []).append(co[0])
for b, d in common_b.items():
for di, li in d.items():
d[di] = Add(*li)
new_c_powers = []
for b, e in common_b.items():
new_c_powers.extend([(b, c*t) for t, c in e.items()])
return new_c_powers
# in c_powers
c_powers = _gather(c_powers)
# and in num_exp
num_exp = _gather(num_exp)
# --- PART 2 ---
#
# o process collected powers (x**0 -> 1; x**1 -> x; otherwise Pow)
# o combine collected powers (2**x * 3**x -> 6**x)
# with numeric base
# ................................
# now we have:
# - coeff:
# - c_powers: (b, e)
# - num_exp: (2, e)
# - pnum_rat: {(1/3, [1/3, 2/3, 1/4])}
# 0 1
# x -> 1 x -> x
# this should only need to run twice; if it fails because
# it needs to be run more times, perhaps this should be
# changed to a "while True" loop -- the only reason it
# isn't such now is to allow a less-than-perfect result to
# be obtained rather than raising an error or entering an
# infinite loop
for i in range(2):
new_c_powers = []
changed = False
for b, e in c_powers:
if e.is_zero:
# canceling out infinities yields NaN
if (b.is_Add or b.is_Mul) and any(infty in b.args
for infty in (S.ComplexInfinity, S.Infinity,
S.NegativeInfinity)):
return [S.NaN], [], None
continue
if e is S.One:
if b.is_Number:
coeff *= b
continue
p = b
if e is not S.One:
p = Pow(b, e)
# check to make sure that the base doesn't change
# after exponentiation; to allow for unevaluated
# Pow, we only do so if b is not already a Pow
if p.is_Pow and not b.is_Pow:
bi = b
b, e = p.as_base_exp()
if b != bi:
changed = True
c_part.append(p)
new_c_powers.append((b, e))
# there might have been a change, but unless the base
# matches some other base, there is nothing to do
if changed and len({
b for b, e in new_c_powers}) != len(new_c_powers):
# start over again
c_part = []
c_powers = _gather(new_c_powers)
else:
break
# x x x
# 2 * 3 -> 6
inv_exp_dict = {} # exp:Mul(num-bases) x x
# e.g. x:6 for ... * 2 * 3 * ...
for b, e in num_exp:
inv_exp_dict.setdefault(e, []).append(b)
for e, b in inv_exp_dict.items():
inv_exp_dict[e] = cls(*b)
c_part.extend([Pow(b, e) for e, b in inv_exp_dict.items() if e])
# b, e -> e' = sum(e), b
# {(1/5, [1/3]), (1/2, [1/12, 1/4]} -> {(1/3, [1/5, 1/2])}
comb_e = {}
for b, e in pnum_rat.items():
comb_e.setdefault(Add(*e), []).append(b)
del pnum_rat
# process them, reducing exponents to values less than 1
# and updating coeff if necessary else adding them to
# num_rat for further processing
num_rat = []
for e, b in comb_e.items():
b = cls(*b)
if e.q == 1:
coeff *= Pow(b, e)
continue
if e.p > e.q:
e_i, ep = divmod(e.p, e.q)
coeff *= Pow(b, e_i)
e = Rational(ep, e.q)
num_rat.append((b, e))
del comb_e
# extract gcd of bases in num_rat
# 2**(1/3)*6**(1/4) -> 2**(1/3+1/4)*3**(1/4)
pnew = defaultdict(list)
i = 0 # steps through num_rat which may grow
while i < len(num_rat):
bi, ei = num_rat[i]
grow = []
for j in range(i + 1, len(num_rat)):
bj, ej = num_rat[j]
g = bi.gcd(bj)
if g is not S.One:
# 4**r1*6**r2 -> 2**(r1+r2) * 2**r1 * 3**r2
# this might have a gcd with something else
e = ei + ej
if e.q == 1:
coeff *= Pow(g, e)
else:
if e.p > e.q:
e_i, ep = divmod(e.p, e.q) # change e in place
coeff *= Pow(g, e_i)
e = Rational(ep, e.q)
grow.append((g, e))
# update the jth item
num_rat[j] = (bj/g, ej)
# update bi that we are checking with
bi = bi/g
if bi is S.One:
break
if bi is not S.One:
obj = Pow(bi, ei)
if obj.is_Number:
coeff *= obj
else:
# changes like sqrt(12) -> 2*sqrt(3)
for obj in Mul.make_args(obj):
if obj.is_Number:
coeff *= obj
else:
assert obj.is_Pow
bi, ei = obj.args
pnew[ei].append(bi)
num_rat.extend(grow)
i += 1
# combine bases of the new powers
for e, b in pnew.items():
pnew[e] = cls(*b)
# handle -1 and I
if neg1e:
# treat I as (-1)**(1/2) and compute -1's total exponent
p, q = neg1e.as_numer_denom()
# if the integer part is odd, extract -1
n, p = divmod(p, q)
if n % 2:
coeff = -coeff
# if it's a multiple of 1/2 extract I
if q == 2:
c_part.append(S.ImaginaryUnit)
elif p:
# see if there is any positive base this power of
# -1 can join
neg1e = Rational(p, q)
for e, b in pnew.items():
if e == neg1e and b.is_positive:
pnew[e] = -b
break
else:
# keep it separate; we've already evaluated it as
# much as possible so evaluate=False
c_part.append(Pow(S.NegativeOne, neg1e, evaluate=False))
# add all the pnew powers
c_part.extend([Pow(b, e) for e, b in pnew.items()])
# oo, -oo
if (coeff is S.Infinity) or (coeff is S.NegativeInfinity):
def _handle_for_oo(c_part, coeff_sign):
new_c_part = []
for t in c_part:
if t.is_extended_positive:
continue
if t.is_extended_negative:
coeff_sign *= -1
continue
new_c_part.append(t)
return new_c_part, coeff_sign
c_part, coeff_sign = _handle_for_oo(c_part, 1)
nc_part, coeff_sign = _handle_for_oo(nc_part, coeff_sign)
coeff *= coeff_sign
# zoo
if coeff is S.ComplexInfinity:
# zoo might be
# infinite_real + bounded_im
# bounded_real + infinite_im
# infinite_real + infinite_im
# and non-zero real or imaginary will not change that status.
c_part = [c for c in c_part if not (fuzzy_not(c.is_zero) and
c.is_extended_real is not None)]
nc_part = [c for c in nc_part if not (fuzzy_not(c.is_zero) and
c.is_extended_real is not None)]
# 0
elif coeff.is_zero:
# we know for sure the result will be 0 except the multiplicand
# is infinity or a matrix
if any(isinstance(c, MatrixExpr) for c in nc_part):
return [coeff], nc_part, order_symbols
if any(c.is_finite == False for c in c_part):
return [S.NaN], [], order_symbols
return [coeff], [], order_symbols
# check for straggling Numbers that were produced
_new = []
for i in c_part:
if i.is_Number:
coeff *= i
else:
_new.append(i)
c_part = _new
# order commutative part canonically
_mulsort(c_part)
# current code expects coeff to be always in slot-0
if coeff is not S.One:
c_part.insert(0, coeff)
# we are done
if (global_parameters.distribute and not nc_part and len(c_part) == 2 and
c_part[0].is_Number and c_part[0].is_finite and c_part[1].is_Add):
# 2*(1+a) -> 2 + 2 * a
coeff = c_part[0]
c_part = [Add(*[coeff*f for f in c_part[1].args])]
return c_part, nc_part, order_symbols
def _eval_power(self, e):
# don't break up NC terms: (A*B)**3 != A**3*B**3, it is A*B*A*B*A*B
cargs, nc = self.args_cnc(split_1=False)
if e.is_Integer:
return Mul(*[Pow(b, e, evaluate=False) for b in cargs]) * \
Pow(Mul._from_args(nc), e, evaluate=False)
if e.is_Rational and e.q == 2:
from sympy.core.power import integer_nthroot
from sympy.functions.elementary.complexes import sign
if self.is_imaginary:
a = self.as_real_imag()[1]
if a.is_Rational:
n, d = abs(a/2).as_numer_denom()
n, t = integer_nthroot(n, 2)
if t:
d, t = integer_nthroot(d, 2)
if t:
r = sympify(n)/d
return _unevaluated_Mul(r**e.p, (1 + sign(a)*S.ImaginaryUnit)**e.p)
p = Pow(self, e, evaluate=False)
if e.is_Rational or e.is_Float:
return p._eval_expand_power_base()
return p
@classmethod
def class_key(cls):
return 3, 0, cls.__name__
def _eval_evalf(self, prec):
c, m = self.as_coeff_Mul()
if c is S.NegativeOne:
if m.is_Mul:
rv = -AssocOp._eval_evalf(m, prec)
else:
mnew = m._eval_evalf(prec)
if mnew is not None:
m = mnew
rv = -m
else:
rv = AssocOp._eval_evalf(self, prec)
if rv.is_number:
return rv.expand()
return rv
@property
def _mpc_(self):
"""
Convert self to an mpmath mpc if possible
"""
from sympy.core.numbers import I, Float
im_part, imag_unit = self.as_coeff_Mul()
if not imag_unit == I:
# ValueError may seem more reasonable but since it's a @property,
# we need to use AttributeError to keep from confusing things like
# hasattr.
raise AttributeError("Cannot convert Mul to mpc. Must be of the form Number*I")
return (Float(0)._mpf_, Float(im_part)._mpf_)
@cacheit
def as_two_terms(self):
"""Return head and tail of self.
This is the most efficient way to get the head and tail of an
expression.
- if you want only the head, use self.args[0];
- if you want to process the arguments of the tail then use
self.as_coef_mul() which gives the head and a tuple containing
the arguments of the tail when treated as a Mul.
- if you want the coefficient when self is treated as an Add
then use self.as_coeff_add()[0]
>>> from sympy.abc import x, y
>>> (3*x*y).as_two_terms()
(3, x*y)
"""
args = self.args
if len(args) == 1:
return S.One, self
elif len(args) == 2:
return args
else:
return args[0], self._new_rawargs(*args[1:])
@cacheit
def as_coefficients_dict(self):
"""Return a dictionary mapping terms to their coefficient.
Since the dictionary is a defaultdict, inquiries about terms which
were not present will return a coefficient of 0. The dictionary
is considered to have a single term.
Examples
========
>>> from sympy.abc import a, x
>>> (3*a*x).as_coefficients_dict()
{a*x: 3}
>>> _[a]
0
"""
d = defaultdict(int)
args = self.args
if len(args) == 1 or not args[0].is_Number:
d[self] = S.One
else:
d[self._new_rawargs(*args[1:])] = args[0]
return d
@cacheit
def as_coeff_mul(self, *deps, **kwargs):
if deps:
from sympy.utilities.iterables import sift
l1, l2 = sift(self.args, lambda x: x.has(*deps), binary=True)
return self._new_rawargs(*l2), tuple(l1)
rational = kwargs.pop('rational', True)
args = self.args
if args[0].is_Number:
if not rational or args[0].is_Rational:
return args[0], args[1:]
elif args[0].is_extended_negative:
return S.NegativeOne, (-args[0],) + args[1:]
return S.One, args
def as_coeff_Mul(self, rational=False):
"""
Efficiently extract the coefficient of a product.
"""
coeff, args = self.args[0], self.args[1:]
if coeff.is_Number:
if not rational or coeff.is_Rational:
if len(args) == 1:
return coeff, args[0]
else:
return coeff, self._new_rawargs(*args)
elif coeff.is_extended_negative:
return S.NegativeOne, self._new_rawargs(*((-coeff,) + args))
return S.One, self
def as_real_imag(self, deep=True, **hints):
from sympy import Abs, expand_mul, im, re
other = []
coeffr = []
coeffi = []
addterms = S.One
for a in self.args:
r, i = a.as_real_imag()
if i.is_zero:
coeffr.append(r)
elif r.is_zero:
coeffi.append(i*S.ImaginaryUnit)
elif a.is_commutative:
# search for complex conjugate pairs:
for i, x in enumerate(other):
if x == a.conjugate():
coeffr.append(Abs(x)**2)
del other[i]
break
else:
if a.is_Add:
addterms *= a
else:
other.append(a)
else:
other.append(a)
m = self.func(*other)
if hints.get('ignore') == m:
return
if len(coeffi) % 2:
imco = im(coeffi.pop(0))
# all other pairs make a real factor; they will be
# put into reco below
else:
imco = S.Zero
reco = self.func(*(coeffr + coeffi))
r, i = (reco*re(m), reco*im(m))
if addterms == 1:
if m == 1:
if imco.is_zero:
return (reco, S.Zero)
else:
return (S.Zero, reco*imco)
if imco is S.Zero:
return (r, i)
return (-imco*i, imco*r)
addre, addim = expand_mul(addterms, deep=False).as_real_imag()
if imco is S.Zero:
return (r*addre - i*addim, i*addre + r*addim)
else:
r, i = -imco*i, imco*r
return (r*addre - i*addim, r*addim + i*addre)
@staticmethod
def _expandsums(sums):
"""
Helper function for _eval_expand_mul.
sums must be a list of instances of Basic.
"""
L = len(sums)
if L == 1:
return sums[0].args
terms = []
left = Mul._expandsums(sums[:L//2])
right = Mul._expandsums(sums[L//2:])
terms = [Mul(a, b) for a in left for b in right]
added = Add(*terms)
return Add.make_args(added) # it may have collapsed down to one term
def _eval_expand_mul(self, **hints):
from sympy import fraction
# Handle things like 1/(x*(x + 1)), which are automatically converted
# to 1/x*1/(x + 1)
expr = self
n, d = fraction(expr)
if d.is_Mul:
n, d = [i._eval_expand_mul(**hints) if i.is_Mul else i
for i in (n, d)]
expr = n/d
if not expr.is_Mul:
return expr
plain, sums, rewrite = [], [], False
for factor in expr.args:
if factor.is_Add:
sums.append(factor)
rewrite = True
else:
if factor.is_commutative:
plain.append(factor)
else:
sums.append(Basic(factor)) # Wrapper
if not rewrite:
return expr
else:
plain = self.func(*plain)
if sums:
deep = hints.get("deep", False)
terms = self.func._expandsums(sums)
args = []
for term in terms:
t = self.func(plain, term)
if t.is_Mul and any(a.is_Add for a in t.args) and deep:
t = t._eval_expand_mul()
args.append(t)
return Add(*args)
else:
return plain
@cacheit
def _eval_derivative(self, s):
args = list(self.args)
terms = []
for i in range(len(args)):
d = args[i].diff(s)
if d:
# Note: reduce is used in step of Mul as Mul is unable to
# handle subtypes and operation priority:
terms.append(reduce(lambda x, y: x*y, (args[:i] + [d] + args[i + 1:]), S.One))
return Add.fromiter(terms)
@cacheit
def _eval_derivative_n_times(self, s, n):
from sympy import Integer, factorial, prod, Sum, Max
from sympy.ntheory.multinomial import multinomial_coefficients_iterator
from .function import AppliedUndef
from .symbol import Symbol, symbols, Dummy
if not isinstance(s, AppliedUndef) and not isinstance(s, Symbol):
# other types of s may not be well behaved, e.g.
# (cos(x)*sin(y)).diff([[x, y, z]])
return super()._eval_derivative_n_times(s, n)
args = self.args
m = len(args)
if isinstance(n, (int, Integer)):
# https://en.wikipedia.org/wiki/General_Leibniz_rule#More_than_two_factors
terms = []
for kvals, c in multinomial_coefficients_iterator(m, n):
p = prod([arg.diff((s, k)) for k, arg in zip(kvals, args)])
terms.append(c * p)
return Add(*terms)
kvals = symbols("k1:%i" % m, cls=Dummy)
klast = n - sum(kvals)
nfact = factorial(n)
e, l = (# better to use the multinomial?
nfact/prod(map(factorial, kvals))/factorial(klast)*\
prod([args[t].diff((s, kvals[t])) for t in range(m-1)])*\
args[-1].diff((s, Max(0, klast))),
[(k, 0, n) for k in kvals])
return Sum(e, *l)
def _eval_difference_delta(self, n, step):
from sympy.series.limitseq import difference_delta as dd
arg0 = self.args[0]
rest = Mul(*self.args[1:])
return (arg0.subs(n, n + step) * dd(rest, n, step) + dd(arg0, n, step) *
rest)
def _matches_simple(self, expr, repl_dict):
# handle (w*3).matches('x*5') -> {w: x*5/3}
coeff, terms = self.as_coeff_Mul()
terms = Mul.make_args(terms)
if len(terms) == 1:
newexpr = self.__class__._combine_inverse(expr, coeff)
return terms[0].matches(newexpr, repl_dict)
return
def matches(self, expr, repl_dict={}, old=False):
expr = sympify(expr)
repl_dict = repl_dict.copy()
if self.is_commutative and expr.is_commutative:
return self._matches_commutative(expr, repl_dict, old)
elif self.is_commutative is not expr.is_commutative:
return None
# Proceed only if both both expressions are non-commutative
c1, nc1 = self.args_cnc()
c2, nc2 = expr.args_cnc()
c1, c2 = [c or [1] for c in [c1, c2]]
# TODO: Should these be self.func?
comm_mul_self = Mul(*c1)
comm_mul_expr = Mul(*c2)
repl_dict = comm_mul_self.matches(comm_mul_expr, repl_dict, old)
# If the commutative arguments didn't match and aren't equal, then
# then the expression as a whole doesn't match
if repl_dict is None and c1 != c2:
return None
# Now match the non-commutative arguments, expanding powers to
# multiplications
nc1 = Mul._matches_expand_pows(nc1)
nc2 = Mul._matches_expand_pows(nc2)
repl_dict = Mul._matches_noncomm(nc1, nc2, repl_dict)
return repl_dict or None
@staticmethod
def _matches_expand_pows(arg_list):
new_args = []
for arg in arg_list:
if arg.is_Pow and arg.exp > 0:
new_args.extend([arg.base] * arg.exp)
else:
new_args.append(arg)
return new_args
@staticmethod
def _matches_noncomm(nodes, targets, repl_dict={}):
"""Non-commutative multiplication matcher.
`nodes` is a list of symbols within the matcher multiplication
expression, while `targets` is a list of arguments in the
multiplication expression being matched against.
"""
repl_dict = repl_dict.copy()
# List of possible future states to be considered
agenda = []
# The current matching state, storing index in nodes and targets
state = (0, 0)
node_ind, target_ind = state
# Mapping between wildcard indices and the index ranges they match
wildcard_dict = {}
repl_dict = repl_dict.copy()
while target_ind < len(targets) and node_ind < len(nodes):
node = nodes[node_ind]
if node.is_Wild:
Mul._matches_add_wildcard(wildcard_dict, state)
states_matches = Mul._matches_new_states(wildcard_dict, state,
nodes, targets)
if states_matches:
new_states, new_matches = states_matches
agenda.extend(new_states)
if new_matches:
for match in new_matches:
repl_dict[match] = new_matches[match]
if not agenda:
return None
else:
state = agenda.pop()
node_ind, target_ind = state
return repl_dict
@staticmethod
def _matches_add_wildcard(dictionary, state):
node_ind, target_ind = state
if node_ind in dictionary:
begin, end = dictionary[node_ind]
dictionary[node_ind] = (begin, target_ind)
else:
dictionary[node_ind] = (target_ind, target_ind)
@staticmethod
def _matches_new_states(dictionary, state, nodes, targets):
node_ind, target_ind = state
node = nodes[node_ind]
target = targets[target_ind]
# Don't advance at all if we've exhausted the targets but not the nodes
if target_ind >= len(targets) - 1 and node_ind < len(nodes) - 1:
return None
if node.is_Wild:
match_attempt = Mul._matches_match_wilds(dictionary, node_ind,
nodes, targets)
if match_attempt:
# If the same node has been matched before, don't return
# anything if the current match is diverging from the previous
# match
other_node_inds = Mul._matches_get_other_nodes(dictionary,
nodes, node_ind)
for ind in other_node_inds:
other_begin, other_end = dictionary[ind]
curr_begin, curr_end = dictionary[node_ind]
other_targets = targets[other_begin:other_end + 1]
current_targets = targets[curr_begin:curr_end + 1]
for curr, other in zip(current_targets, other_targets):
if curr != other:
return None
# A wildcard node can match more than one target, so only the
# target index is advanced
new_state = [(node_ind, target_ind + 1)]
# Only move on to the next node if there is one
if node_ind < len(nodes) - 1:
new_state.append((node_ind + 1, target_ind + 1))
return new_state, match_attempt
else:
# If we're not at a wildcard, then make sure we haven't exhausted
# nodes but not targets, since in this case one node can only match
# one target
if node_ind >= len(nodes) - 1 and target_ind < len(targets) - 1:
return None
match_attempt = node.matches(target)
if match_attempt:
return [(node_ind + 1, target_ind + 1)], match_attempt
elif node == target:
return [(node_ind + 1, target_ind + 1)], None
else:
return None
@staticmethod
def _matches_match_wilds(dictionary, wildcard_ind, nodes, targets):
"""Determine matches of a wildcard with sub-expression in `target`."""
wildcard = nodes[wildcard_ind]
begin, end = dictionary[wildcard_ind]
terms = targets[begin:end + 1]
# TODO: Should this be self.func?
mul = Mul(*terms) if len(terms) > 1 else terms[0]
return wildcard.matches(mul)
@staticmethod
def _matches_get_other_nodes(dictionary, nodes, node_ind):
"""Find other wildcards that may have already been matched."""
other_node_inds = []
for ind in dictionary:
if nodes[ind] == nodes[node_ind]:
other_node_inds.append(ind)
return other_node_inds
@staticmethod
def _combine_inverse(lhs, rhs):
"""
Returns lhs/rhs, but treats arguments like symbols, so things
like oo/oo return 1 (instead of a nan) and ``I`` behaves like
a symbol instead of sqrt(-1).
"""
from .symbol import Dummy
if lhs == rhs:
return S.One
def check(l, r):
if l.is_Float and r.is_comparable:
# if both objects are added to 0 they will share the same "normalization"
# and are more likely to compare the same. Since Add(foo, 0) will not allow
# the 0 to pass, we use __add__ directly.
return l.__add__(0) == r.evalf().__add__(0)
return False
if check(lhs, rhs) or check(rhs, lhs):
return S.One
if any(i.is_Pow or i.is_Mul for i in (lhs, rhs)):
# gruntz and limit wants a literal I to not combine
# with a power of -1
d = Dummy('I')
_i = {S.ImaginaryUnit: d}
i_ = {d: S.ImaginaryUnit}
a = lhs.xreplace(_i).as_powers_dict()
b = rhs.xreplace(_i).as_powers_dict()
blen = len(b)
for bi in tuple(b.keys()):
if bi in a:
a[bi] -= b.pop(bi)
if not a[bi]:
a.pop(bi)
if len(b) != blen:
lhs = Mul(*[k**v for k, v in a.items()]).xreplace(i_)
rhs = Mul(*[k**v for k, v in b.items()]).xreplace(i_)
return lhs/rhs
def as_powers_dict(self):
d = defaultdict(int)
for term in self.args:
for b, e in term.as_powers_dict().items():
d[b] += e
return d
def as_numer_denom(self):
# don't use _from_args to rebuild the numerators and denominators
# as the order is not guaranteed to be the same once they have
# been separated from each other
numers, denoms = list(zip(*[f.as_numer_denom() for f in self.args]))
return self.func(*numers), self.func(*denoms)
def as_base_exp(self):
e1 = None
bases = []
nc = 0
for m in self.args:
b, e = m.as_base_exp()
if not b.is_commutative:
nc += 1
if e1 is None:
e1 = e
elif e != e1 or nc > 1:
return self, S.One
bases.append(b)
return self.func(*bases), e1
def _eval_is_polynomial(self, syms):
return all(term._eval_is_polynomial(syms) for term in self.args)
def _eval_is_rational_function(self, syms):
return all(term._eval_is_rational_function(syms) for term in self.args)
def _eval_is_meromorphic(self, x, a):
return _fuzzy_group((arg.is_meromorphic(x, a) for arg in self.args),
quick_exit=True)
def _eval_is_algebraic_expr(self, syms):
return all(term._eval_is_algebraic_expr(syms) for term in self.args)
_eval_is_commutative = lambda self: _fuzzy_group(
a.is_commutative for a in self.args)
def _eval_is_complex(self):
comp = _fuzzy_group(a.is_complex for a in self.args)
if comp is False:
if any(a.is_infinite for a in self.args):
if any(a.is_zero is not False for a in self.args):
return None
return False
return comp
def _eval_is_finite(self):
if all(a.is_finite for a in self.args):
return True
if any(a.is_infinite for a in self.args):
if all(a.is_zero is False for a in self.args):
return False
def _eval_is_infinite(self):
if any(a.is_infinite for a in self.args):
if any(a.is_zero for a in self.args):
return S.NaN.is_infinite
if any(a.is_zero is None for a in self.args):
return None
return True
def _eval_is_rational(self):
r = _fuzzy_group((a.is_rational for a in self.args), quick_exit=True)
if r:
return r
elif r is False:
return self.is_zero
def _eval_is_algebraic(self):
r = _fuzzy_group((a.is_algebraic for a in self.args), quick_exit=True)
if r:
return r
elif r is False:
return self.is_zero
def _eval_is_zero(self):
zero = infinite = False
for a in self.args:
z = a.is_zero
if z:
if infinite:
return # 0*oo is nan and nan.is_zero is None
zero = True
else:
if not a.is_finite:
if zero:
return # 0*oo is nan and nan.is_zero is None
infinite = True
if zero is False and z is None: # trap None
zero = None
return zero
def _eval_is_integer(self):
from sympy import fraction
from sympy.core.numbers import Float
is_rational = self._eval_is_rational()
if is_rational is False:
return False
# use exact=True to avoid recomputing num or den
n, d = fraction(self, exact=True)
if is_rational:
if d is S.One:
return True
if d.is_even:
if d.is_prime: # literal or symbolic 2
return n.is_even
if n.is_odd:
return False # true even if d = 0
if n == d:
return fuzzy_and([not bool(self.atoms(Float)),
fuzzy_not(d.is_zero)])
def _eval_is_polar(self):
has_polar = any(arg.is_polar for arg in self.args)
return has_polar and \
all(arg.is_polar or arg.is_positive for arg in self.args)
def _eval_is_extended_real(self):
return self._eval_real_imag(True)
def _eval_real_imag(self, real):
zero = False
t_not_re_im = None
for t in self.args:
if (t.is_complex or t.is_infinite) is False and t.is_extended_real is False:
return False
elif t.is_imaginary: # I
real = not real
elif t.is_extended_real: # 2
if not zero:
z = t.is_zero
if not z and zero is False:
zero = z
elif z:
if all(a.is_finite for a in self.args):
return True
return
elif t.is_extended_real is False:
# symbolic or literal like `2 + I` or symbolic imaginary
if t_not_re_im:
return # complex terms might cancel
t_not_re_im = t
elif t.is_imaginary is False: # symbolic like `2` or `2 + I`
if t_not_re_im:
return # complex terms might cancel
t_not_re_im = t
else:
return
if t_not_re_im:
if t_not_re_im.is_extended_real is False:
if real: # like 3
return zero # 3*(smthng like 2 + I or i) is not real
if t_not_re_im.is_imaginary is False: # symbolic 2 or 2 + I
if not real: # like I
return zero # I*(smthng like 2 or 2 + I) is not real
elif zero is False:
return real # can't be trumped by 0
elif real:
return real # doesn't matter what zero is
def _eval_is_imaginary(self):
z = self.is_zero
if z:
return False
if self.is_finite is False:
return False
elif z is False and self.is_finite is True:
return self._eval_real_imag(False)
def _eval_is_hermitian(self):
return self._eval_herm_antiherm(True)
def _eval_herm_antiherm(self, real):
one_nc = zero = one_neither = False
for t in self.args:
if not t.is_commutative:
if one_nc:
return
one_nc = True
if t.is_antihermitian:
real = not real
elif t.is_hermitian:
if not zero:
z = t.is_zero
if not z and zero is False:
zero = z
elif z:
if all(a.is_finite for a in self.args):
return True
return
elif t.is_hermitian is False:
if one_neither:
return
one_neither = True
else:
return
if one_neither:
if real:
return zero
elif zero is False or real:
return real
def _eval_is_antihermitian(self):
z = self.is_zero
if z:
return False
elif z is False:
return self._eval_herm_antiherm(False)
def _eval_is_irrational(self):
for t in self.args:
a = t.is_irrational
if a:
others = list(self.args)
others.remove(t)
if all((x.is_rational and fuzzy_not(x.is_zero)) is True for x in others):
return True
return
if a is None:
return
if all(x.is_real for x in self.args):
return False
def _eval_is_extended_positive(self):
"""Return True if self is positive, False if not, and None if it
cannot be determined.
This algorithm is non-recursive and works by keeping track of the
sign which changes when a negative or nonpositive is encountered.
Whether a nonpositive or nonnegative is seen is also tracked since
the presence of these makes it impossible to return True, but
possible to return False if the end result is nonpositive. e.g.
pos * neg * nonpositive -> pos or zero -> None is returned
pos * neg * nonnegative -> neg or zero -> False is returned
"""
return self._eval_pos_neg(1)
def _eval_pos_neg(self, sign):
saw_NON = saw_NOT = False
for t in self.args:
if t.is_extended_positive:
continue
elif t.is_extended_negative:
sign = -sign
elif t.is_zero:
if all(a.is_finite for a in self.args):
return False
return
elif t.is_extended_nonpositive:
sign = -sign
saw_NON = True
elif t.is_extended_nonnegative:
saw_NON = True
# FIXME: is_positive/is_negative is False doesn't take account of
# Symbol('x', infinite=True, extended_real=True) which has
# e.g. is_positive is False but has uncertain sign.
elif t.is_positive is False:
sign = -sign
if saw_NOT:
return
saw_NOT = True
elif t.is_negative is False:
if saw_NOT:
return
saw_NOT = True
else:
return
if sign == 1 and saw_NON is False and saw_NOT is False:
return True
if sign < 0:
return False
def _eval_is_extended_negative(self):
return self._eval_pos_neg(-1)
def _eval_is_odd(self):
is_integer = self.is_integer
if is_integer:
r, acc = True, 1
for t in self.args:
if not t.is_integer:
return None
elif t.is_even:
r = False
elif t.is_integer:
if r is False:
pass
elif acc != 1 and (acc + t).is_odd:
r = False
elif t.is_odd is None:
r = None
acc = t
return r
# !integer -> !odd
elif is_integer is False:
return False
def _eval_is_even(self):
is_integer = self.is_integer
if is_integer:
return fuzzy_not(self.is_odd)
elif is_integer is False:
return False
def _eval_is_composite(self):
"""
Here we count the number of arguments that have a minimum value
greater than two.
If there are more than one of such a symbol then the result is composite.
Else, the result cannot be determined.
"""
number_of_args = 0 # count of symbols with minimum value greater than one
for arg in self.args:
if not (arg.is_integer and arg.is_positive):
return None
if (arg-1).is_positive:
number_of_args += 1
if number_of_args > 1:
return True
def _eval_subs(self, old, new):
from sympy.functions.elementary.complexes import sign
from sympy.ntheory.factor_ import multiplicity
from sympy.simplify.powsimp import powdenest
from sympy.simplify.radsimp import fraction
if not old.is_Mul:
return None
# try keep replacement literal so -2*x doesn't replace 4*x
if old.args[0].is_Number and old.args[0] < 0:
if self.args[0].is_Number:
if self.args[0] < 0:
return self._subs(-old, -new)
return None
def base_exp(a):
# if I and -1 are in a Mul, they get both end up with
# a -1 base (see issue 6421); all we want here are the
# true Pow or exp separated into base and exponent
from sympy import exp
if a.is_Pow or isinstance(a, exp):
return a.as_base_exp()
return a, S.One
def breakup(eq):
"""break up powers of eq when treated as a Mul:
b**(Rational*e) -> b**e, Rational
commutatives come back as a dictionary {b**e: Rational}
noncommutatives come back as a list [(b**e, Rational)]
"""
(c, nc) = (defaultdict(int), list())
for a in Mul.make_args(eq):
a = powdenest(a)
(b, e) = base_exp(a)
if e is not S.One:
(co, _) = e.as_coeff_mul()
b = Pow(b, e/co)
e = co
if a.is_commutative:
c[b] += e
else:
nc.append([b, e])
return (c, nc)
def rejoin(b, co):
"""
Put rational back with exponent; in general this is not ok, but
since we took it from the exponent for analysis, it's ok to put
it back.
"""
(b, e) = base_exp(b)
return Pow(b, e*co)
def ndiv(a, b):
"""if b divides a in an extractive way (like 1/4 divides 1/2
but not vice versa, and 2/5 does not divide 1/3) then return
the integer number of times it divides, else return 0.
"""
if not b.q % a.q or not a.q % b.q:
return int(a/b)
return 0
# give Muls in the denominator a chance to be changed (see issue 5651)
# rv will be the default return value
rv = None
n, d = fraction(self)
self2 = self
if d is not S.One:
self2 = n._subs(old, new)/d._subs(old, new)
if not self2.is_Mul:
return self2._subs(old, new)
if self2 != self:
rv = self2
# Now continue with regular substitution.
# handle the leading coefficient and use it to decide if anything
# should even be started; we always know where to find the Rational
# so it's a quick test
co_self = self2.args[0]
co_old = old.args[0]
co_xmul = None
if co_old.is_Rational and co_self.is_Rational:
# if coeffs are the same there will be no updating to do
# below after breakup() step; so skip (and keep co_xmul=None)
if co_old != co_self:
co_xmul = co_self.extract_multiplicatively(co_old)
elif co_old.is_Rational:
return rv
# break self and old into factors
(c, nc) = breakup(self2)
(old_c, old_nc) = breakup(old)
# update the coefficients if we had an extraction
# e.g. if co_self were 2*(3/35*x)**2 and co_old = 3/5
# then co_self in c is replaced by (3/5)**2 and co_residual
# is 2*(1/7)**2
if co_xmul and co_xmul.is_Rational and abs(co_old) != 1:
mult = S(multiplicity(abs(co_old), co_self))
c.pop(co_self)
if co_old in c:
c[co_old] += mult
else:
c[co_old] = mult
co_residual = co_self/co_old**mult
else:
co_residual = 1
# do quick tests to see if we can't succeed
ok = True
if len(old_nc) > len(nc):
# more non-commutative terms
ok = False
elif len(old_c) > len(c):
# more commutative terms
ok = False
elif {i[0] for i in old_nc}.difference({i[0] for i in nc}):
# unmatched non-commutative bases
ok = False
elif set(old_c).difference(set(c)):
# unmatched commutative terms
ok = False
elif any(sign(c[b]) != sign(old_c[b]) for b in old_c):
# differences in sign
ok = False
if not ok:
return rv
if not old_c:
cdid = None
else:
rat = []
for (b, old_e) in old_c.items():
c_e = c[b]
rat.append(ndiv(c_e, old_e))
if not rat[-1]:
return rv
cdid = min(rat)
if not old_nc:
ncdid = None
for i in range(len(nc)):
nc[i] = rejoin(*nc[i])
else:
ncdid = 0 # number of nc replacements we did
take = len(old_nc) # how much to look at each time
limit = cdid or S.Infinity # max number that we can take
failed = [] # failed terms will need subs if other terms pass
i = 0
while limit and i + take <= len(nc):
hit = False
# the bases must be equivalent in succession, and
# the powers must be extractively compatible on the
# first and last factor but equal in between.
rat = []
for j in range(take):
if nc[i + j][0] != old_nc[j][0]:
break
elif j == 0:
rat.append(ndiv(nc[i + j][1], old_nc[j][1]))
elif j == take - 1:
rat.append(ndiv(nc[i + j][1], old_nc[j][1]))
elif nc[i + j][1] != old_nc[j][1]:
break
else:
rat.append(1)
j += 1
else:
ndo = min(rat)
if ndo:
if take == 1:
if cdid:
ndo = min(cdid, ndo)
nc[i] = Pow(new, ndo)*rejoin(nc[i][0],
nc[i][1] - ndo*old_nc[0][1])
else:
ndo = 1
# the left residual
l = rejoin(nc[i][0], nc[i][1] - ndo*
old_nc[0][1])
# eliminate all middle terms
mid = new
# the right residual (which may be the same as the middle if take == 2)
ir = i + take - 1
r = (nc[ir][0], nc[ir][1] - ndo*
old_nc[-1][1])
if r[1]:
if i + take < len(nc):
nc[i:i + take] = [l*mid, r]
else:
r = rejoin(*r)
nc[i:i + take] = [l*mid*r]
else:
# there was nothing left on the right
nc[i:i + take] = [l*mid]
limit -= ndo
ncdid += ndo
hit = True
if not hit:
# do the subs on this failing factor
failed.append(i)
i += 1
else:
if not ncdid:
return rv
# although we didn't fail, certain nc terms may have
# failed so we rebuild them after attempting a partial
# subs on them
failed.extend(range(i, len(nc)))
for i in failed:
nc[i] = rejoin(*nc[i]).subs(old, new)
# rebuild the expression
if cdid is None:
do = ncdid
elif ncdid is None:
do = cdid
else:
do = min(ncdid, cdid)
margs = []
for b in c:
if b in old_c:
# calculate the new exponent
e = c[b] - old_c[b]*do
margs.append(rejoin(b, e))
else:
margs.append(rejoin(b.subs(old, new), c[b]))
if cdid and not ncdid:
# in case we are replacing commutative with non-commutative,
# we want the new term to come at the front just like the
# rest of this routine
margs = [Pow(new, cdid)] + margs
return co_residual*self2.func(*margs)*self2.func(*nc)
def _eval_nseries(self, x, n, logx):
from sympy import Integer, Mul, Order, ceiling, powsimp
from itertools import product
def coeff_exp(term, x):
coeff, exp = S.One, S.Zero
for factor in Mul.make_args(term):
if factor.has(x):
base, exp = factor.as_base_exp()
if base != x:
return term.leadterm(x)
else:
coeff *= factor
return coeff, exp
ords = []
try:
for t in self.args:
coeff, exp = t.leadterm(x)
if isinstance(coeff, Integer) or isinstance(coeff, Rational):
ords.append((t, exp))
else:
raise ValueError
n0 = sum(t[1] for t in ords)
facs = [t.series(x, 0, ceiling(n-n0+m)).removeO() for t, m in ords]
except (ValueError, NotImplementedError, TypeError, AttributeError):
facs = [t.nseries(x, n=n, logx=logx) for t in self.args]
res = powsimp(self.func(*facs).expand(), combine='exp', deep=True)
if res.has(Order):
res += Order(x**n, x)
return res
res = 0
ords2 = [Add.make_args(factor) for factor in facs]
for fac in product(*ords2):
ords3 = [coeff_exp(term, x) for term in fac]
coeffs, powers = zip(*ords3)
power = sum(powers)
if power < n:
res += Mul(*coeffs)*(x**power)
res += Order(x**n, x)
return res
def _eval_as_leading_term(self, x):
return self.func(*[t.as_leading_term(x) for t in self.args])
def _eval_conjugate(self):
return self.func(*[t.conjugate() for t in self.args])
def _eval_transpose(self):
return self.func(*[t.transpose() for t in self.args[::-1]])
def _eval_adjoint(self):
return self.func(*[t.adjoint() for t in self.args[::-1]])
def _sage_(self):
s = 1
for x in self.args:
s *= x._sage_()
return s
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
>>> (-3*sqrt(2)*(2 - 2*sqrt(2))).as_content_primitive()
(6, -sqrt(2)*(1 - sqrt(2)))
See docstring of Expr.as_content_primitive for more examples.
"""
coef = S.One
args = []
for i, a in enumerate(self.args):
c, p = a.as_content_primitive(radical=radical, clear=clear)
coef *= c
if p is not S.One:
args.append(p)
# don't use self._from_args here to reconstruct args
# since there may be identical args now that should be combined
# e.g. (2+2*x)*(3+3*x) should be (6, (1 + x)**2) not (6, (1+x)*(1+x))
return coef, self.func(*args)
def as_ordered_factors(self, order=None):
"""Transform an expression into an ordered list of factors.
Examples
========
>>> from sympy import sin, cos
>>> from sympy.abc import x, y
>>> (2*x*y*sin(x)*cos(x)).as_ordered_factors()
[2, x, y, sin(x), cos(x)]
"""
cpart, ncpart = self.args_cnc()
cpart.sort(key=lambda expr: expr.sort_key(order=order))
return cpart + ncpart
@property
def _sorted_args(self):
return tuple(self.as_ordered_factors())
def prod(a, start=1):
"""Return product of elements of a. Start with int 1 so if only
ints are included then an int result is returned.
Examples
========
>>> from sympy import prod, S
>>> prod(range(3))
0
>>> type(_) is int
True
>>> prod([S(2), 3])
6
>>> _.is_Integer
True
You can start the product at something other than 1:
>>> prod([1, 2], 3)
6
"""
return reduce(operator.mul, a, start)
def _keep_coeff(coeff, factors, clear=True, sign=False):
"""Return ``coeff*factors`` unevaluated if necessary.
If ``clear`` is False, do not keep the coefficient as a factor
if it can be distributed on a single factor such that one or
more terms will still have integer coefficients.
If ``sign`` is True, allow a coefficient of -1 to remain factored out.
Examples
========
>>> from sympy.core.mul import _keep_coeff
>>> from sympy.abc import x, y
>>> from sympy import S
>>> _keep_coeff(S.Half, x + 2)
(x + 2)/2
>>> _keep_coeff(S.Half, x + 2, clear=False)
x/2 + 1
>>> _keep_coeff(S.Half, (x + 2)*y, clear=False)
y*(x + 2)/2
>>> _keep_coeff(S(-1), x + y)
-x - y
>>> _keep_coeff(S(-1), x + y, sign=True)
-(x + y)
"""
if not coeff.is_Number:
if factors.is_Number:
factors, coeff = coeff, factors
else:
return coeff*factors
if coeff is S.One:
return factors
elif coeff is S.NegativeOne and not sign:
return -factors
elif factors.is_Add:
if not clear and coeff.is_Rational and coeff.q != 1:
q = S(coeff.q)
for i in factors.args:
c, t = i.as_coeff_Mul()
r = c/q
if r == int(r):
return coeff*factors
return Mul(coeff, factors, evaluate=False)
elif factors.is_Mul:
margs = list(factors.args)
if margs[0].is_Number:
margs[0] *= coeff
if margs[0] == 1:
margs.pop(0)
else:
margs.insert(0, coeff)
return Mul._from_args(margs)
else:
return coeff*factors
def expand_2arg(e):
from sympy.simplify.simplify import bottom_up
def do(e):
if e.is_Mul:
c, r = e.as_coeff_Mul()
if c.is_Number and r.is_Add:
return _unevaluated_Add(*[c*ri for ri in r.args])
return e
return bottom_up(e, do)
from .numbers import Rational
from .power import Pow
from .add import Add, _addsort, _unevaluated_Add
|
3a8b4f7f65ee1901104bcf0ac403f72c2db6228a7474e2afe58e3893259b8df3 | """Tools for setting up printing in interactive sessions. """
import sys
from distutils.version import LooseVersion as V
from io import BytesIO
from sympy import latex as default_latex
from sympy import preview
from sympy.utilities.misc import debug
def _init_python_printing(stringify_func, **settings):
"""Setup printing in Python interactive session. """
import sys
from sympy.core.compatibility import builtins
def _displayhook(arg):
"""Python's pretty-printer display hook.
This function was adapted from:
http://www.python.org/dev/peps/pep-0217/
"""
if arg is not None:
builtins._ = None
print(stringify_func(arg, **settings))
builtins._ = arg
sys.displayhook = _displayhook
def _init_ipython_printing(ip, stringify_func, use_latex, euler, forecolor,
backcolor, fontsize, latex_mode, print_builtin,
latex_printer, scale, **settings):
"""Setup printing in IPython interactive session. """
try:
from IPython.lib.latextools import latex_to_png
except ImportError:
pass
# Guess best font color if none was given based on the ip.colors string.
# From the IPython documentation:
# It has four case-insensitive values: 'nocolor', 'neutral', 'linux',
# 'lightbg'. The default is neutral, which should be legible on either
# dark or light terminal backgrounds. linux is optimised for dark
# backgrounds and lightbg for light ones.
if forecolor is None:
color = ip.colors.lower()
if color == 'lightbg':
forecolor = 'Black'
elif color == 'linux':
forecolor = 'White'
else:
# No idea, go with gray.
forecolor = 'Gray'
debug("init_printing: Automatic foreground color:", forecolor)
preamble = "\\documentclass[varwidth,%s]{standalone}\n" \
"\\usepackage{amsmath,amsfonts}%s\\begin{document}"
if euler:
addpackages = '\\usepackage{euler}'
else:
addpackages = ''
if use_latex == "svg":
addpackages = addpackages + "\n\\special{color %s}" % forecolor
preamble = preamble % (fontsize, addpackages)
imagesize = 'tight'
offset = "0cm,0cm"
resolution = round(150*scale)
dvi = r"-T %s -D %d -bg %s -fg %s -O %s" % (
imagesize, resolution, backcolor, forecolor, offset)
dvioptions = dvi.split()
svg_scale = 150/72*scale
dvioptions_svg = ["--no-fonts", "--scale={}".format(svg_scale)]
debug("init_printing: DVIOPTIONS:", dvioptions)
debug("init_printing: DVIOPTIONS_SVG:", dvioptions_svg)
debug("init_printing: PREAMBLE:", preamble)
latex = latex_printer or default_latex
def _print_plain(arg, p, cycle):
"""caller for pretty, for use in IPython 0.11"""
if _can_print_latex(arg):
p.text(stringify_func(arg))
else:
p.text(IPython.lib.pretty.pretty(arg))
def _preview_wrapper(o):
exprbuffer = BytesIO()
try:
preview(o, output='png', viewer='BytesIO',
outputbuffer=exprbuffer, preamble=preamble,
dvioptions=dvioptions)
except Exception as e:
# IPython swallows exceptions
debug("png printing:", "_preview_wrapper exception raised:",
repr(e))
raise
return exprbuffer.getvalue()
def _svg_wrapper(o):
exprbuffer = BytesIO()
try:
preview(o, output='svg', viewer='BytesIO',
outputbuffer=exprbuffer, preamble=preamble,
dvioptions=dvioptions_svg)
except Exception as e:
# IPython swallows exceptions
debug("svg printing:", "_preview_wrapper exception raised:",
repr(e))
raise
return exprbuffer.getvalue().decode('utf-8')
def _matplotlib_wrapper(o):
# mathtext does not understand certain latex flags, so we try to
# replace them with suitable subs
o = o.replace(r'\operatorname', '')
o = o.replace(r'\overline', r'\bar')
# mathtext can't render some LaTeX commands. For example, it can't
# render any LaTeX environments such as array or matrix. So here we
# ensure that if mathtext fails to render, we return None.
try:
try:
return latex_to_png(o, color=forecolor, scale=scale)
except TypeError: # Old IPython version without color and scale
return latex_to_png(o)
except ValueError as e:
debug('matplotlib exception caught:', repr(e))
return None
from sympy import Basic
from sympy.matrices import MatrixBase
from sympy.physics.vector import Vector, Dyadic
from sympy.tensor.array import NDimArray
# These should all have _repr_latex_ and _repr_latex_orig. If you update
# this also update printable_types below.
sympy_latex_types = (Basic, MatrixBase, Vector, Dyadic, NDimArray)
def _can_print_latex(o):
"""Return True if type o can be printed with LaTeX.
If o is a container type, this is True if and only if every element of
o can be printed with LaTeX.
"""
try:
# If you're adding another type, make sure you add it to printable_types
# later in this file as well
builtin_types = (list, tuple, set, frozenset)
if isinstance(o, builtin_types):
# If the object is a custom subclass with a custom str or
# repr, use that instead.
if (type(o).__str__ not in (i.__str__ for i in builtin_types) or
type(o).__repr__ not in (i.__repr__ for i in builtin_types)):
return False
return all(_can_print_latex(i) for i in o)
elif isinstance(o, dict):
return all(_can_print_latex(i) and _can_print_latex(o[i]) for i in o)
elif isinstance(o, bool):
return False
elif isinstance(o, sympy_latex_types):
# types known to the printer
return True
elif hasattr(o, '_latex'):
# types which add support themselves
return True
elif isinstance(o, (float, int)) and print_builtin:
return True
return False
except RuntimeError:
return False
# This is in case maximum recursion depth is reached.
# Since RecursionError is for versions of Python 3.5+
# so this is to guard against RecursionError for older versions.
def _print_latex_png(o):
"""
A function that returns a png rendered by an external latex
distribution, falling back to matplotlib rendering
"""
if _can_print_latex(o):
s = latex(o, mode=latex_mode, **settings)
if latex_mode == 'plain':
s = '$\\displaystyle %s$' % s
try:
return _preview_wrapper(s)
except RuntimeError as e:
debug('preview failed with:', repr(e),
' Falling back to matplotlib backend')
if latex_mode != 'inline':
s = latex(o, mode='inline', **settings)
return _matplotlib_wrapper(s)
def _print_latex_svg(o):
"""
A function that returns a svg rendered by an external latex
distribution, no fallback available.
"""
if _can_print_latex(o):
s = latex(o, mode=latex_mode, **settings)
if latex_mode == 'plain':
s = '$\\displaystyle %s$' % s
try:
return _svg_wrapper(s)
except RuntimeError as e:
debug('preview failed with:', repr(e),
' No fallback available.')
def _print_latex_matplotlib(o):
"""
A function that returns a png rendered by mathtext
"""
if _can_print_latex(o):
s = latex(o, mode='inline', **settings)
return _matplotlib_wrapper(s)
def _print_latex_text(o):
"""
A function to generate the latex representation of sympy expressions.
"""
if _can_print_latex(o):
s = latex(o, mode=latex_mode, **settings)
if latex_mode == 'plain':
return '$\\displaystyle %s$' % s
return s
def _result_display(self, arg):
"""IPython's pretty-printer display hook, for use in IPython 0.10
This function was adapted from:
ipython/IPython/hooks.py:155
"""
if self.rc.pprint:
out = stringify_func(arg)
if '\n' in out:
print
print(out)
else:
print(repr(arg))
import IPython
if V(IPython.__version__) >= '0.11':
from sympy.core.basic import Basic
from sympy.matrices.matrices import MatrixBase
from sympy.physics.vector import Vector, Dyadic
from sympy.tensor.array import NDimArray
printable_types = [Basic, MatrixBase, float, tuple, list, set,
frozenset, dict, Vector, Dyadic, NDimArray, int]
plaintext_formatter = ip.display_formatter.formatters['text/plain']
for cls in printable_types:
plaintext_formatter.for_type(cls, _print_plain)
svg_formatter = ip.display_formatter.formatters['image/svg+xml']
if use_latex in ('svg', ):
debug("init_printing: using svg formatter")
for cls in printable_types:
svg_formatter.for_type(cls, _print_latex_svg)
else:
debug("init_printing: not using any svg formatter")
for cls in printable_types:
# Better way to set this, but currently does not work in IPython
#png_formatter.for_type(cls, None)
if cls in svg_formatter.type_printers:
svg_formatter.type_printers.pop(cls)
png_formatter = ip.display_formatter.formatters['image/png']
if use_latex in (True, 'png'):
debug("init_printing: using png formatter")
for cls in printable_types:
png_formatter.for_type(cls, _print_latex_png)
elif use_latex == 'matplotlib':
debug("init_printing: using matplotlib formatter")
for cls in printable_types:
png_formatter.for_type(cls, _print_latex_matplotlib)
else:
debug("init_printing: not using any png formatter")
for cls in printable_types:
# Better way to set this, but currently does not work in IPython
#png_formatter.for_type(cls, None)
if cls in png_formatter.type_printers:
png_formatter.type_printers.pop(cls)
latex_formatter = ip.display_formatter.formatters['text/latex']
if use_latex in (True, 'mathjax'):
debug("init_printing: using mathjax formatter")
for cls in printable_types:
latex_formatter.for_type(cls, _print_latex_text)
for typ in sympy_latex_types:
typ._repr_latex_ = typ._repr_latex_orig
else:
debug("init_printing: not using text/latex formatter")
for cls in printable_types:
# Better way to set this, but currently does not work in IPython
#latex_formatter.for_type(cls, None)
if cls in latex_formatter.type_printers:
latex_formatter.type_printers.pop(cls)
for typ in sympy_latex_types:
typ._repr_latex_ = None
else:
ip.set_hook('result_display', _result_display)
def _is_ipython(shell):
"""Is a shell instance an IPython shell?"""
# shortcut, so we don't import IPython if we don't have to
if 'IPython' not in sys.modules:
return False
try:
from IPython.core.interactiveshell import InteractiveShell
except ImportError:
# IPython < 0.11
try:
from IPython.iplib import InteractiveShell
except ImportError:
# Reaching this points means IPython has changed in a backward-incompatible way
# that we don't know about. Warn?
return False
return isinstance(shell, InteractiveShell)
# Used by the doctester to override the default for no_global
NO_GLOBAL = False
def init_printing(pretty_print=True, order=None, use_unicode=None,
use_latex=None, wrap_line=None, num_columns=None,
no_global=False, ip=None, euler=False, forecolor=None,
backcolor='Transparent', fontsize='10pt',
latex_mode='plain', print_builtin=True,
str_printer=None, pretty_printer=None,
latex_printer=None, scale=1.0, **settings):
r"""
Initializes pretty-printer depending on the environment.
Parameters
==========
pretty_print : boolean, default=True
If True, use pretty_print to stringify or the provided pretty
printer; if False, use sstrrepr to stringify or the provided string
printer.
order : string or None, default='lex'
There are a few different settings for this parameter:
lex (default), which is lexographic order;
grlex, which is graded lexographic order;
grevlex, which is reversed graded lexographic order;
old, which is used for compatibility reasons and for long expressions;
None, which sets it to lex.
use_unicode : boolean or None, default=None
If True, use unicode characters;
if False, do not use unicode characters;
if None, make a guess based on the environment.
use_latex : string, boolean, or None, default=None
If True, use default LaTeX rendering in GUI interfaces (png and
mathjax);
if False, do not use LaTeX rendering;
if None, make a guess based on the environment;
if 'png', enable latex rendering with an external latex compiler,
falling back to matplotlib if external compilation fails;
if 'matplotlib', enable LaTeX rendering with matplotlib;
if 'mathjax', enable LaTeX text generation, for example MathJax
rendering in IPython notebook or text rendering in LaTeX documents;
if 'svg', enable LaTeX rendering with an external latex compiler,
no fallback
wrap_line : boolean
If True, lines will wrap at the end; if False, they will not wrap
but continue as one line. This is only relevant if ``pretty_print`` is
True.
num_columns : int or None, default=None
If int, number of columns before wrapping is set to num_columns; if
None, number of columns before wrapping is set to terminal width.
This is only relevant if ``pretty_print`` is True.
no_global : boolean, default=False
If True, the settings become system wide;
if False, use just for this console/session.
ip : An interactive console
This can either be an instance of IPython,
or a class that derives from code.InteractiveConsole.
euler : boolean, optional, default=False
Loads the euler package in the LaTeX preamble for handwritten style
fonts (http://www.ctan.org/pkg/euler).
forecolor : string or None, optional, default=None
DVI setting for foreground color. None means that either 'Black',
'White', or 'Gray' will be selected based on a guess of the IPython
terminal color setting. See notes.
backcolor : string, optional, default='Transparent'
DVI setting for background color. See notes.
fontsize : string, optional, default='10pt'
A font size to pass to the LaTeX documentclass function in the
preamble. Note that the options are limited by the documentclass.
Consider using scale instead.
latex_mode : string, optional, default='plain'
The mode used in the LaTeX printer. Can be one of:
{'inline'|'plain'|'equation'|'equation*'}.
print_builtin : boolean, optional, default=True
If ``True`` then floats and integers will be printed. If ``False`` the
printer will only print SymPy types.
str_printer : function, optional, default=None
A custom string printer function. This should mimic
sympy.printing.sstrrepr().
pretty_printer : function, optional, default=None
A custom pretty printer. This should mimic sympy.printing.pretty().
latex_printer : function, optional, default=None
A custom LaTeX printer. This should mimic sympy.printing.latex().
scale : float, optional, default=1.0
Scale the LaTeX output when using the ``png`` or ``svg`` backends.
Useful for high dpi screens.
settings :
Any additional settings for the ``latex`` and ``pretty`` commands can
be used to fine-tune the output.
Examples
========
>>> from sympy.interactive import init_printing
>>> from sympy import Symbol, sqrt
>>> from sympy.abc import x, y
>>> sqrt(5)
sqrt(5)
>>> init_printing(pretty_print=True) # doctest: +SKIP
>>> sqrt(5) # doctest: +SKIP
___
\/ 5
>>> theta = Symbol('theta') # doctest: +SKIP
>>> init_printing(use_unicode=True) # doctest: +SKIP
>>> theta # doctest: +SKIP
\u03b8
>>> init_printing(use_unicode=False) # doctest: +SKIP
>>> theta # doctest: +SKIP
theta
>>> init_printing(order='lex') # doctest: +SKIP
>>> str(y + x + y**2 + x**2) # doctest: +SKIP
x**2 + x + y**2 + y
>>> init_printing(order='grlex') # doctest: +SKIP
>>> str(y + x + y**2 + x**2) # doctest: +SKIP
x**2 + x + y**2 + y
>>> init_printing(order='grevlex') # doctest: +SKIP
>>> str(y * x**2 + x * y**2) # doctest: +SKIP
x**2*y + x*y**2
>>> init_printing(order='old') # doctest: +SKIP
>>> str(x**2 + y**2 + x + y) # doctest: +SKIP
x**2 + x + y**2 + y
>>> init_printing(num_columns=10) # doctest: +SKIP
>>> x**2 + x + y**2 + y # doctest: +SKIP
x + y +
x**2 + y**2
Notes
=====
The foreground and background colors can be selected when using 'png' or
'svg' LaTeX rendering. Note that before the ``init_printing`` command is
executed, the LaTeX rendering is handled by the IPython console and not SymPy.
The colors can be selected among the 68 standard colors known to ``dvips``,
for a list see [1]_. In addition, the background color can be
set to 'Transparent' (which is the default value).
When using the 'Auto' foreground color, the guess is based on the
``colors`` variable in the IPython console, see [2]_. Hence, if
that variable is set correctly in your IPython console, there is a high
chance that the output will be readable, although manual settings may be
needed.
References
==========
.. [1] https://en.wikibooks.org/wiki/LaTeX/Colors#The_68_standard_colors_known_to_dvips
.. [2] https://ipython.readthedocs.io/en/stable/config/details.html#terminal-colors
See Also
========
sympy.printing.latex
sympy.printing.pretty
"""
import sys
from sympy.printing.printer import Printer
if pretty_print:
if pretty_printer is not None:
stringify_func = pretty_printer
else:
from sympy.printing import pretty as stringify_func
else:
if str_printer is not None:
stringify_func = str_printer
else:
from sympy.printing import sstrrepr as stringify_func
# Even if ip is not passed, double check that not in IPython shell
in_ipython = False
if ip is None:
try:
ip = get_ipython()
except NameError:
pass
else:
in_ipython = (ip is not None)
if ip and not in_ipython:
in_ipython = _is_ipython(ip)
if in_ipython and pretty_print:
try:
import IPython
# IPython 1.0 deprecates the frontend module, so we import directly
# from the terminal module to prevent a deprecation message from being
# shown.
if V(IPython.__version__) >= '1.0':
from IPython.terminal.interactiveshell import TerminalInteractiveShell
else:
from IPython.frontend.terminal.interactiveshell import TerminalInteractiveShell
from code import InteractiveConsole
except ImportError:
pass
else:
# This will be True if we are in the qtconsole or notebook
if not isinstance(ip, (InteractiveConsole, TerminalInteractiveShell)) \
and 'ipython-console' not in ''.join(sys.argv):
if use_unicode is None:
debug("init_printing: Setting use_unicode to True")
use_unicode = True
if use_latex is None:
debug("init_printing: Setting use_latex to True")
use_latex = True
if not NO_GLOBAL and not no_global:
Printer.set_global_settings(order=order, use_unicode=use_unicode,
wrap_line=wrap_line, num_columns=num_columns)
else:
_stringify_func = stringify_func
if pretty_print:
stringify_func = lambda expr, **settings: \
_stringify_func(expr, order=order,
use_unicode=use_unicode,
wrap_line=wrap_line,
num_columns=num_columns,
**settings)
else:
stringify_func = \
lambda expr, **settings: _stringify_func(
expr, order=order, **settings)
if in_ipython:
mode_in_settings = settings.pop("mode", None)
if mode_in_settings:
debug("init_printing: Mode is not able to be set due to internals"
"of IPython printing")
_init_ipython_printing(ip, stringify_func, use_latex, euler,
forecolor, backcolor, fontsize, latex_mode,
print_builtin, latex_printer, scale,
**settings)
else:
_init_python_printing(stringify_func, **settings)
|
7111994b915b719ecdd1fe6ebd52eaee8ecddb24908f09e3449f61ee279c1141 | """Tools for setting up interactive sessions. """
from distutils.version import LooseVersion as V
from sympy.interactive.printing import init_printing
preexec_source = """\
from __future__ import division
from sympy import *
x, y, z, t = symbols('x y z t')
k, m, n = symbols('k m n', integer=True)
f, g, h = symbols('f g h', cls=Function)
init_printing()
"""
verbose_message = """\
These commands were executed:
%(source)s
Documentation can be found at https://docs.sympy.org/%(version)s
"""
no_ipython = """\
Couldn't locate IPython. Having IPython installed is greatly recommended.
See http://ipython.scipy.org for more details. If you use Debian/Ubuntu,
just install the 'ipython' package and start isympy again.
"""
def _make_message(ipython=True, quiet=False, source=None):
"""Create a banner for an interactive session. """
from sympy import __version__ as sympy_version
from sympy.polys.domains import GROUND_TYPES
from sympy.utilities.misc import ARCH
from sympy import SYMPY_DEBUG
import sys
import os
if quiet:
return ""
python_version = "%d.%d.%d" % sys.version_info[:3]
if ipython:
shell_name = "IPython"
else:
shell_name = "Python"
info = ['ground types: %s' % GROUND_TYPES]
cache = os.getenv('SYMPY_USE_CACHE')
if cache is not None and cache.lower() == 'no':
info.append('cache: off')
if SYMPY_DEBUG:
info.append('debugging: on')
args = shell_name, sympy_version, python_version, ARCH, ', '.join(info)
message = "%s console for SymPy %s (Python %s-%s) (%s)\n" % args
if source is None:
source = preexec_source
_source = ""
for line in source.split('\n')[:-1]:
if not line:
_source += '\n'
else:
_source += '>>> ' + line + '\n'
doc_version = sympy_version
if 'dev' in doc_version:
doc_version = "dev"
else:
doc_version = "%s/" % doc_version
message += '\n' + verbose_message % {'source': _source,
'version': doc_version}
return message
def int_to_Integer(s):
"""
Wrap integer literals with Integer.
This is based on the decistmt example from
http://docs.python.org/library/tokenize.html.
Only integer literals are converted. Float literals are left alone.
Examples
========
>>> from __future__ import division
>>> from sympy import Integer # noqa: F401
>>> from sympy.interactive.session import int_to_Integer
>>> s = '1.2 + 1/2 - 0x12 + a1'
>>> int_to_Integer(s)
'1.2 +Integer (1 )/Integer (2 )-Integer (0x12 )+a1 '
>>> s = 'print (1/2)'
>>> int_to_Integer(s)
'print (Integer (1 )/Integer (2 ))'
>>> exec(s)
0.5
>>> exec(int_to_Integer(s))
1/2
"""
from tokenize import generate_tokens, untokenize, NUMBER, NAME, OP
from sympy.core.compatibility import StringIO
def _is_int(num):
"""
Returns true if string value num (with token NUMBER) represents an integer.
"""
# XXX: Is there something in the standard library that will do this?
if '.' in num or 'j' in num.lower() or 'e' in num.lower():
return False
return True
result = []
g = generate_tokens(StringIO(s).readline) # tokenize the string
for toknum, tokval, _, _, _ in g:
if toknum == NUMBER and _is_int(tokval): # replace NUMBER tokens
result.extend([
(NAME, 'Integer'),
(OP, '('),
(NUMBER, tokval),
(OP, ')')
])
else:
result.append((toknum, tokval))
return untokenize(result)
def enable_automatic_int_sympification(shell):
"""
Allow IPython to automatically convert integer literals to Integer.
"""
import ast
old_run_cell = shell.run_cell
def my_run_cell(cell, *args, **kwargs):
try:
# Check the cell for syntax errors. This way, the syntax error
# will show the original input, not the transformed input. The
# downside here is that IPython magic like %timeit will not work
# with transformed input (but on the other hand, IPython magic
# that doesn't expect transformed input will continue to work).
ast.parse(cell)
except SyntaxError:
pass
else:
cell = int_to_Integer(cell)
old_run_cell(cell, *args, **kwargs)
shell.run_cell = my_run_cell
def enable_automatic_symbols(shell):
"""Allow IPython to automatically create symbols (``isympy -a``). """
# XXX: This should perhaps use tokenize, like int_to_Integer() above.
# This would avoid re-executing the code, which can lead to subtle
# issues. For example:
#
# In [1]: a = 1
#
# In [2]: for i in range(10):
# ...: a += 1
# ...:
#
# In [3]: a
# Out[3]: 11
#
# In [4]: a = 1
#
# In [5]: for i in range(10):
# ...: a += 1
# ...: print b
# ...:
# b
# b
# b
# b
# b
# b
# b
# b
# b
# b
#
# In [6]: a
# Out[6]: 12
#
# Note how the for loop is executed again because `b` was not defined, but `a`
# was already incremented once, so the result is that it is incremented
# multiple times.
import re
re_nameerror = re.compile(
"name '(?P<symbol>[A-Za-z_][A-Za-z0-9_]*)' is not defined")
def _handler(self, etype, value, tb, tb_offset=None):
"""Handle :exc:`NameError` exception and allow injection of missing symbols. """
if etype is NameError and tb.tb_next and not tb.tb_next.tb_next:
match = re_nameerror.match(str(value))
if match is not None:
# XXX: Make sure Symbol is in scope. Otherwise you'll get infinite recursion.
self.run_cell("%(symbol)s = Symbol('%(symbol)s')" %
{'symbol': match.group("symbol")}, store_history=False)
try:
code = self.user_ns['In'][-1]
except (KeyError, IndexError):
pass
else:
self.run_cell(code, store_history=False)
return None
finally:
self.run_cell("del %s" % match.group("symbol"),
store_history=False)
stb = self.InteractiveTB.structured_traceback(
etype, value, tb, tb_offset=tb_offset)
self._showtraceback(etype, value, stb)
shell.set_custom_exc((NameError,), _handler)
def init_ipython_session(shell=None, argv=[], auto_symbols=False, auto_int_to_Integer=False):
"""Construct new IPython session. """
import IPython
if V(IPython.__version__) >= '0.11':
if not shell:
# use an app to parse the command line, and init config
# IPython 1.0 deprecates the frontend module, so we import directly
# from the terminal module to prevent a deprecation message from being
# shown.
if V(IPython.__version__) >= '1.0':
from IPython.terminal import ipapp
else:
from IPython.frontend.terminal import ipapp
app = ipapp.TerminalIPythonApp()
# don't draw IPython banner during initialization:
app.display_banner = False
app.initialize(argv)
shell = app.shell
if auto_symbols:
enable_automatic_symbols(shell)
if auto_int_to_Integer:
enable_automatic_int_sympification(shell)
return shell
else:
from IPython.Shell import make_IPython
return make_IPython(argv)
def init_python_session():
"""Construct new Python session. """
from code import InteractiveConsole
class SymPyConsole(InteractiveConsole):
"""An interactive console with readline support. """
def __init__(self):
InteractiveConsole.__init__(self)
try:
import readline
except ImportError:
pass
else:
import os
import atexit
readline.parse_and_bind('tab: complete')
if hasattr(readline, 'read_history_file'):
history = os.path.expanduser('~/.sympy-history')
try:
readline.read_history_file(history)
except OSError:
pass
atexit.register(readline.write_history_file, history)
return SymPyConsole()
def init_session(ipython=None, pretty_print=True, order=None,
use_unicode=None, use_latex=None, quiet=False, auto_symbols=False,
auto_int_to_Integer=False, str_printer=None, pretty_printer=None,
latex_printer=None, argv=[]):
"""
Initialize an embedded IPython or Python session. The IPython session is
initiated with the --pylab option, without the numpy imports, so that
matplotlib plotting can be interactive.
Parameters
==========
pretty_print: boolean
If True, use pretty_print to stringify;
if False, use sstrrepr to stringify.
order: string or None
There are a few different settings for this parameter:
lex (default), which is lexographic order;
grlex, which is graded lexographic order;
grevlex, which is reversed graded lexographic order;
old, which is used for compatibility reasons and for long expressions;
None, which sets it to lex.
use_unicode: boolean or None
If True, use unicode characters;
if False, do not use unicode characters.
use_latex: boolean or None
If True, use latex rendering if IPython GUI's;
if False, do not use latex rendering.
quiet: boolean
If True, init_session will not print messages regarding its status;
if False, init_session will print messages regarding its status.
auto_symbols: boolean
If True, IPython will automatically create symbols for you.
If False, it will not.
The default is False.
auto_int_to_Integer: boolean
If True, IPython will automatically wrap int literals with Integer, so
that things like 1/2 give Rational(1, 2).
If False, it will not.
The default is False.
ipython: boolean or None
If True, printing will initialize for an IPython console;
if False, printing will initialize for a normal console;
The default is None, which automatically determines whether we are in
an ipython instance or not.
str_printer: function, optional, default=None
A custom string printer function. This should mimic
sympy.printing.sstrrepr().
pretty_printer: function, optional, default=None
A custom pretty printer. This should mimic sympy.printing.pretty().
latex_printer: function, optional, default=None
A custom LaTeX printer. This should mimic sympy.printing.latex()
This should mimic sympy.printing.latex().
argv: list of arguments for IPython
See sympy.bin.isympy for options that can be used to initialize IPython.
See Also
========
sympy.interactive.printing.init_printing: for examples and the rest of the parameters.
Examples
========
>>> from sympy import init_session, Symbol, sin, sqrt
>>> sin(x) #doctest: +SKIP
NameError: name 'x' is not defined
>>> init_session() #doctest: +SKIP
>>> sin(x) #doctest: +SKIP
sin(x)
>>> sqrt(5) #doctest: +SKIP
___
\\/ 5
>>> init_session(pretty_print=False) #doctest: +SKIP
>>> sqrt(5) #doctest: +SKIP
sqrt(5)
>>> y + x + y**2 + x**2 #doctest: +SKIP
x**2 + x + y**2 + y
>>> init_session(order='grlex') #doctest: +SKIP
>>> y + x + y**2 + x**2 #doctest: +SKIP
x**2 + y**2 + x + y
>>> init_session(order='grevlex') #doctest: +SKIP
>>> y * x**2 + x * y**2 #doctest: +SKIP
x**2*y + x*y**2
>>> init_session(order='old') #doctest: +SKIP
>>> x**2 + y**2 + x + y #doctest: +SKIP
x + y + x**2 + y**2
>>> theta = Symbol('theta') #doctest: +SKIP
>>> theta #doctest: +SKIP
theta
>>> init_session(use_unicode=True) #doctest: +SKIP
>>> theta # doctest: +SKIP
\u03b8
"""
import sys
in_ipython = False
if ipython is not False:
try:
import IPython
except ImportError:
if ipython is True:
raise RuntimeError("IPython is not available on this system")
ip = None
else:
try:
from IPython import get_ipython
ip = get_ipython()
except ImportError:
ip = None
in_ipython = bool(ip)
if ipython is None:
ipython = in_ipython
if ipython is False:
ip = init_python_session()
mainloop = ip.interact
else:
ip = init_ipython_session(ip, argv=argv, auto_symbols=auto_symbols,
auto_int_to_Integer=auto_int_to_Integer)
if V(IPython.__version__) >= '0.11':
# runsource is gone, use run_cell instead, which doesn't
# take a symbol arg. The second arg is `store_history`,
# and False means don't add the line to IPython's history.
ip.runsource = lambda src, symbol='exec': ip.run_cell(src, False)
#Enable interactive plotting using pylab.
try:
ip.enable_pylab(import_all=False)
except Exception:
# Causes an import error if matplotlib is not installed.
# Causes other errors (depending on the backend) if there
# is no display, or if there is some problem in the
# backend, so we have a bare "except Exception" here
pass
if not in_ipython:
mainloop = ip.mainloop
if auto_symbols and (not ipython or V(IPython.__version__) < '0.11'):
raise RuntimeError("automatic construction of symbols is possible only in IPython 0.11 or above")
if auto_int_to_Integer and (not ipython or V(IPython.__version__) < '0.11'):
raise RuntimeError("automatic int to Integer transformation is possible only in IPython 0.11 or above")
_preexec_source = preexec_source
ip.runsource(_preexec_source, symbol='exec')
init_printing(pretty_print=pretty_print, order=order,
use_unicode=use_unicode, use_latex=use_latex, ip=ip,
str_printer=str_printer, pretty_printer=pretty_printer,
latex_printer=latex_printer)
message = _make_message(ipython, quiet, _preexec_source)
if not in_ipython:
print(message)
mainloop()
sys.exit('Exiting ...')
else:
print(message)
import atexit
atexit.register(lambda: print("Exiting ...\n"))
|
81159a317c643b4b1d400e6f0a239fe4d7d6862cb0abf36e2c496b02e516755f | """Definitions of monomial orderings. """
from __future__ import print_function, division
from typing import Optional
__all__ = ["lex", "grlex", "grevlex", "ilex", "igrlex", "igrevlex"]
from sympy.core import Symbol
from sympy.core.compatibility import iterable
class MonomialOrder(object):
"""Base class for monomial orderings. """
alias = None # type: Optional[str]
is_global = None # type: Optional[bool]
is_default = False
def __repr__(self):
return self.__class__.__name__ + "()"
def __str__(self):
return self.alias
def __call__(self, monomial):
raise NotImplementedError
def __eq__(self, other):
return self.__class__ == other.__class__
def __hash__(self):
return hash(self.__class__)
def __ne__(self, other):
return not (self == other)
class LexOrder(MonomialOrder):
"""Lexicographic order of monomials. """
alias = 'lex'
is_global = True
is_default = True
def __call__(self, monomial):
return monomial
class GradedLexOrder(MonomialOrder):
"""Graded lexicographic order of monomials. """
alias = 'grlex'
is_global = True
def __call__(self, monomial):
return (sum(monomial), monomial)
class ReversedGradedLexOrder(MonomialOrder):
"""Reversed graded lexicographic order of monomials. """
alias = 'grevlex'
is_global = True
def __call__(self, monomial):
return (sum(monomial), tuple(reversed([-m for m in monomial])))
class ProductOrder(MonomialOrder):
"""
A product order built from other monomial orders.
Given (not necessarily total) orders O1, O2, ..., On, their product order
P is defined as M1 > M2 iff there exists i such that O1(M1) = O2(M2),
..., Oi(M1) = Oi(M2), O{i+1}(M1) > O{i+1}(M2).
Product orders are typically built from monomial orders on different sets
of variables.
ProductOrder is constructed by passing a list of pairs
[(O1, L1), (O2, L2), ...] where Oi are MonomialOrders and Li are callables.
Upon comparison, the Li are passed the total monomial, and should filter
out the part of the monomial to pass to Oi.
Examples
========
We can use a lexicographic order on x_1, x_2 and also on
y_1, y_2, y_3, and their product on {x_i, y_i} as follows:
>>> from sympy.polys.orderings import lex, grlex, ProductOrder
>>> P = ProductOrder(
... (lex, lambda m: m[:2]), # lex order on x_1 and x_2 of monomial
... (grlex, lambda m: m[2:]) # grlex on y_1, y_2, y_3
... )
>>> P((2, 1, 1, 0, 0)) > P((1, 10, 0, 2, 0))
True
Here the exponent `2` of `x_1` in the first monomial
(`x_1^2 x_2 y_1`) is bigger than the exponent `1` of `x_1` in the
second monomial (`x_1 x_2^10 y_2^2`), so the first monomial is greater
in the product ordering.
>>> P((2, 1, 1, 0, 0)) < P((2, 1, 0, 2, 0))
True
Here the exponents of `x_1` and `x_2` agree, so the grlex order on
`y_1, y_2, y_3` is used to decide the ordering. In this case the monomial
`y_2^2` is ordered larger than `y_1`, since for the grlex order the degree
of the monomial is most important.
"""
def __init__(self, *args):
self.args = args
def __call__(self, monomial):
return tuple(O(lamda(monomial)) for (O, lamda) in self.args)
def __repr__(self):
contents = [repr(x[0]) for x in self.args]
return self.__class__.__name__ + '(' + ", ".join(contents) + ')'
def __str__(self):
contents = [str(x[0]) for x in self.args]
return self.__class__.__name__ + '(' + ", ".join(contents) + ')'
def __eq__(self, other):
if not isinstance(other, ProductOrder):
return False
return self.args == other.args
def __hash__(self):
return hash((self.__class__, self.args))
@property
def is_global(self):
if all(o.is_global is True for o, _ in self.args):
return True
if all(o.is_global is False for o, _ in self.args):
return False
return None
class InverseOrder(MonomialOrder):
"""
The "inverse" of another monomial order.
If O is any monomial order, we can construct another monomial order iO
such that `A >_{iO} B` if and only if `B >_O A`. This is useful for
constructing local orders.
Note that many algorithms only work with *global* orders.
For example, in the inverse lexicographic order on a single variable `x`,
high powers of `x` count as small:
>>> from sympy.polys.orderings import lex, InverseOrder
>>> ilex = InverseOrder(lex)
>>> ilex((5,)) < ilex((0,))
True
"""
def __init__(self, O):
self.O = O
def __str__(self):
return "i" + str(self.O)
def __call__(self, monomial):
def inv(l):
if iterable(l):
return tuple(inv(x) for x in l)
return -l
return inv(self.O(monomial))
@property
def is_global(self):
if self.O.is_global is True:
return False
if self.O.is_global is False:
return True
return None
def __eq__(self, other):
return isinstance(other, InverseOrder) and other.O == self.O
def __hash__(self):
return hash((self.__class__, self.O))
lex = LexOrder()
grlex = GradedLexOrder()
grevlex = ReversedGradedLexOrder()
ilex = InverseOrder(lex)
igrlex = InverseOrder(grlex)
igrevlex = InverseOrder(grevlex)
_monomial_key = {
'lex': lex,
'grlex': grlex,
'grevlex': grevlex,
'ilex': ilex,
'igrlex': igrlex,
'igrevlex': igrevlex
}
def monomial_key(order=None, gens=None):
"""
Return a function defining admissible order on monomials.
The result of a call to :func:`monomial_key` is a function which should
be used as a key to :func:`sorted` built-in function, to provide order
in a set of monomials of the same length.
Currently supported monomial orderings are:
1. lex - lexicographic order (default)
2. grlex - graded lexicographic order
3. grevlex - reversed graded lexicographic order
4. ilex, igrlex, igrevlex - the corresponding inverse orders
If the ``order`` input argument is not a string but has ``__call__``
attribute, then it will pass through with an assumption that the
callable object defines an admissible order on monomials.
If the ``gens`` input argument contains a list of generators, the
resulting key function can be used to sort SymPy ``Expr`` objects.
"""
if order is None:
order = lex
if isinstance(order, Symbol):
order = str(order)
if isinstance(order, str):
try:
order = _monomial_key[order]
except KeyError:
raise ValueError("supported monomial orderings are 'lex', 'grlex' and 'grevlex', got %r" % order)
if hasattr(order, '__call__'):
if gens is not None:
def _order(expr):
return order(expr.as_poly(*gens).degree_list())
return _order
return order
else:
raise ValueError("monomial ordering specification must be a string or a callable, got %s" % order)
class _ItemGetter(object):
"""Helper class to return a subsequence of values."""
def __init__(self, seq):
self.seq = tuple(seq)
def __call__(self, m):
return tuple(m[idx] for idx in self.seq)
def __eq__(self, other):
if not isinstance(other, _ItemGetter):
return False
return self.seq == other.seq
def build_product_order(arg, gens):
"""
Build a monomial order on ``gens``.
``arg`` should be a tuple of iterables. The first element of each iterable
should be a string or monomial order (will be passed to monomial_key),
the others should be subsets of the generators. This function will build
the corresponding product order.
For example, build a product of two grlex orders:
>>> from sympy.polys.orderings import build_product_order
>>> from sympy.abc import x, y, z, t
>>> O = build_product_order((("grlex", x, y), ("grlex", z, t)), [x, y, z, t])
>>> O((1, 2, 3, 4))
((3, (1, 2)), (7, (3, 4)))
"""
gens2idx = {}
for i, g in enumerate(gens):
gens2idx[g] = i
order = []
for expr in arg:
name = expr[0]
var = expr[1:]
def makelambda(var):
return _ItemGetter(gens2idx[g] for g in var)
order.append((monomial_key(name), makelambda(var)))
return ProductOrder(*order)
|
c2d16b682a0d52cd159ddac2cb37fbfa283dbad99fee391c9c3f3fc85254b9c3 | """Implementation of RootOf class and related tools. """
from __future__ import print_function, division
from sympy.core import (S, Expr, Integer, Float, I, oo, Add, Lambda,
symbols, sympify, Rational, Dummy)
from sympy.core.cache import cacheit
from sympy.core.compatibility import ordered
from sympy.polys.domains import QQ
from sympy.polys.polyerrors import (
MultivariatePolynomialError,
GeneratorsNeeded,
PolynomialError,
DomainError)
from sympy.polys.polyfuncs import symmetrize, viete
from sympy.polys.polyroots import (
roots_linear, roots_quadratic, roots_binomial,
preprocess_roots, roots)
from sympy.polys.polytools import Poly, PurePoly, factor
from sympy.polys.rationaltools import together
from sympy.polys.rootisolation import (
dup_isolate_complex_roots_sqf,
dup_isolate_real_roots_sqf)
from sympy.utilities import lambdify, public, sift, numbered_symbols
from mpmath import mpf, mpc, findroot, workprec
from mpmath.libmp.libmpf import dps_to_prec, prec_to_dps
from itertools import chain
__all__ = ['CRootOf']
class _pure_key_dict(object):
"""A minimal dictionary that makes sure that the key is a
univariate PurePoly instance.
Examples
========
Only the following actions are guaranteed:
>>> from sympy.polys.rootoftools import _pure_key_dict
>>> from sympy import PurePoly
>>> from sympy.abc import x, y
1) creation
>>> P = _pure_key_dict()
2) assignment for a PurePoly or univariate polynomial
>>> P[x] = 1
>>> P[PurePoly(x - y, x)] = 2
3) retrieval based on PurePoly key comparison (use this
instead of the get method)
>>> P[y]
1
4) KeyError when trying to retrieve a nonexisting key
>>> P[y + 1]
Traceback (most recent call last):
...
KeyError: PurePoly(y + 1, y, domain='ZZ')
5) ability to query with ``in``
>>> x + 1 in P
False
NOTE: this is a *not* a dictionary. It is a very basic object
for internal use that makes sure to always address its cache
via PurePoly instances. It does not, for example, implement
``get`` or ``setdefault``.
"""
def __init__(self):
self._dict = {}
def __getitem__(self, k):
if not isinstance(k, PurePoly):
if not (isinstance(k, Expr) and len(k.free_symbols) == 1):
raise KeyError
k = PurePoly(k, expand=False)
return self._dict[k]
def __setitem__(self, k, v):
if not isinstance(k, PurePoly):
if not (isinstance(k, Expr) and len(k.free_symbols) == 1):
raise ValueError('expecting univariate expression')
k = PurePoly(k, expand=False)
self._dict[k] = v
def __contains__(self, k):
try:
self[k]
return True
except KeyError:
return False
_reals_cache = _pure_key_dict()
_complexes_cache = _pure_key_dict()
def _pure_factors(poly):
_, factors = poly.factor_list()
return [(PurePoly(f, expand=False), m) for f, m in factors]
def _imag_count_of_factor(f):
"""Return the number of imaginary roots for irreducible
univariate polynomial ``f``.
"""
terms = [(i, j) for (i,), j in f.terms()]
if any(i % 2 for i, j in terms):
return 0
# update signs
even = [(i, I**i*j) for i, j in terms]
even = Poly.from_dict(dict(even), Dummy('x'))
return int(even.count_roots(-oo, oo))
@public
def rootof(f, x, index=None, radicals=True, expand=True):
"""An indexed root of a univariate polynomial.
Returns either a :obj:`ComplexRootOf` object or an explicit
expression involving radicals.
Parameters
==========
f : Expr
Univariate polynomial.
x : Symbol, optional
Generator for ``f``.
index : int or Integer
radicals : bool
Return a radical expression if possible.
expand : bool
Expand ``f``.
"""
return CRootOf(f, x, index=index, radicals=radicals, expand=expand)
@public
class RootOf(Expr):
"""Represents a root of a univariate polynomial.
Base class for roots of different kinds of polynomials.
Only complex roots are currently supported.
"""
__slots__ = ('poly',)
def __new__(cls, f, x, index=None, radicals=True, expand=True):
"""Construct a new ``CRootOf`` object for ``k``-th root of ``f``."""
return rootof(f, x, index=index, radicals=radicals, expand=expand)
@public
class ComplexRootOf(RootOf):
"""Represents an indexed complex root of a polynomial.
Roots of a univariate polynomial separated into disjoint
real or complex intervals and indexed in a fixed order.
Currently only rational coefficients are allowed.
Can be imported as ``CRootOf``. To avoid confusion, the
generator must be a Symbol.
Examples
========
>>> from sympy import CRootOf, rootof
>>> from sympy.abc import x
CRootOf is a way to reference a particular root of a
polynomial. If there is a rational root, it will be returned:
>>> CRootOf.clear_cache() # for doctest reproducibility
>>> CRootOf(x**2 - 4, 0)
-2
Whether roots involving radicals are returned or not
depends on whether the ``radicals`` flag is true (which is
set to True with rootof):
>>> CRootOf(x**2 - 3, 0)
CRootOf(x**2 - 3, 0)
>>> CRootOf(x**2 - 3, 0, radicals=True)
-sqrt(3)
>>> rootof(x**2 - 3, 0)
-sqrt(3)
The following cannot be expressed in terms of radicals:
>>> r = rootof(4*x**5 + 16*x**3 + 12*x**2 + 7, 0); r
CRootOf(4*x**5 + 16*x**3 + 12*x**2 + 7, 0)
The root bounds can be seen, however, and they are used by the
evaluation methods to get numerical approximations for the root.
>>> interval = r._get_interval(); interval
(-1, 0)
>>> r.evalf(2)
-0.98
The evalf method refines the width of the root bounds until it
guarantees that any decimal approximation within those bounds
will satisfy the desired precision. It then stores the refined
interval so subsequent requests at or below the requested
precision will not have to recompute the root bounds and will
return very quickly.
Before evaluation above, the interval was
>>> interval
(-1, 0)
After evaluation it is now
>>> r._get_interval() # doctest: +SKIP
(-165/169, -206/211)
To reset all intervals for a given polynomial, the :meth:`_reset` method
can be called from any CRootOf instance of the polynomial:
>>> r._reset()
>>> r._get_interval()
(-1, 0)
The :meth:`eval_approx` method will also find the root to a given
precision but the interval is not modified unless the search
for the root fails to converge within the root bounds. And
the secant method is used to find the root. (The ``evalf``
method uses bisection and will always update the interval.)
>>> r.eval_approx(2)
-0.98
The interval needed to be slightly updated to find that root:
>>> r._get_interval()
(-1, -1/2)
The ``evalf_rational`` will compute a rational approximation
of the root to the desired accuracy or precision.
>>> r.eval_rational(n=2)
-69629/71318
>>> t = CRootOf(x**3 + 10*x + 1, 1)
>>> t.eval_rational(1e-1)
15/256 - 805*I/256
>>> t.eval_rational(1e-1, 1e-4)
3275/65536 - 414645*I/131072
>>> t.eval_rational(1e-4, 1e-4)
6545/131072 - 414645*I/131072
>>> t.eval_rational(n=2)
104755/2097152 - 6634255*I/2097152
Notes
=====
Although a PurePoly can be constructed from a non-symbol generator
RootOf instances of non-symbols are disallowed to avoid confusion
over what root is being represented.
>>> from sympy import exp, PurePoly
>>> PurePoly(x) == PurePoly(exp(x))
True
>>> CRootOf(x - 1, 0)
1
>>> CRootOf(exp(x) - 1, 0) # would correspond to x == 0
Traceback (most recent call last):
...
sympy.polys.polyerrors.PolynomialError: generator must be a Symbol
See Also
========
eval_approx
eval_rational
"""
__slots__ = ('index',)
is_complex = True
is_number = True
is_finite = True
def __new__(cls, f, x, index=None, radicals=False, expand=True):
""" Construct an indexed complex root of a polynomial.
See ``rootof`` for the parameters.
The default value of ``radicals`` is ``False`` to satisfy
``eval(srepr(expr) == expr``.
"""
x = sympify(x)
if index is None and x.is_Integer:
x, index = None, x
else:
index = sympify(index)
if index is not None and index.is_Integer:
index = int(index)
else:
raise ValueError("expected an integer root index, got %s" % index)
poly = PurePoly(f, x, greedy=False, expand=expand)
if not poly.is_univariate:
raise PolynomialError("only univariate polynomials are allowed")
if not poly.gen.is_Symbol:
# PurePoly(sin(x) + 1) == PurePoly(x + 1) but the roots of
# x for each are not the same: issue 8617
raise PolynomialError("generator must be a Symbol")
degree = poly.degree()
if degree <= 0:
raise PolynomialError("can't construct CRootOf object for %s" % f)
if index < -degree or index >= degree:
raise IndexError("root index out of [%d, %d] range, got %d" %
(-degree, degree - 1, index))
elif index < 0:
index += degree
dom = poly.get_domain()
if not dom.is_Exact:
poly = poly.to_exact()
roots = cls._roots_trivial(poly, radicals)
if roots is not None:
return roots[index]
coeff, poly = preprocess_roots(poly)
dom = poly.get_domain()
if not dom.is_ZZ:
raise NotImplementedError("CRootOf is not supported over %s" % dom)
root = cls._indexed_root(poly, index)
return coeff * cls._postprocess_root(root, radicals)
@classmethod
def _new(cls, poly, index):
"""Construct new ``CRootOf`` object from raw data. """
obj = Expr.__new__(cls)
obj.poly = PurePoly(poly)
obj.index = index
try:
_reals_cache[obj.poly] = _reals_cache[poly]
_complexes_cache[obj.poly] = _complexes_cache[poly]
except KeyError:
pass
return obj
def _hashable_content(self):
return (self.poly, self.index)
@property
def expr(self):
return self.poly.as_expr()
@property
def args(self):
return (self.expr, Integer(self.index))
@property
def free_symbols(self):
# CRootOf currently only works with univariate expressions
# whose poly attribute should be a PurePoly with no free
# symbols
return set()
def _eval_is_real(self):
"""Return ``True`` if the root is real. """
return self.index < len(_reals_cache[self.poly])
def _eval_is_imaginary(self):
"""Return ``True`` if the root is imaginary. """
if self.index >= len(_reals_cache[self.poly]):
ivl = self._get_interval()
return ivl.ax*ivl.bx <= 0 # all others are on one side or the other
return False # XXX is this necessary?
@classmethod
def real_roots(cls, poly, radicals=True):
"""Get real roots of a polynomial. """
return cls._get_roots("_real_roots", poly, radicals)
@classmethod
def all_roots(cls, poly, radicals=True):
"""Get real and complex roots of a polynomial. """
return cls._get_roots("_all_roots", poly, radicals)
@classmethod
def _get_reals_sqf(cls, currentfactor, use_cache=True):
"""Get real root isolating intervals for a square-free factor."""
if use_cache and currentfactor in _reals_cache:
real_part = _reals_cache[currentfactor]
else:
_reals_cache[currentfactor] = real_part = \
dup_isolate_real_roots_sqf(
currentfactor.rep.rep, currentfactor.rep.dom, blackbox=True)
return real_part
@classmethod
def _get_complexes_sqf(cls, currentfactor, use_cache=True):
"""Get complex root isolating intervals for a square-free factor."""
if use_cache and currentfactor in _complexes_cache:
complex_part = _complexes_cache[currentfactor]
else:
_complexes_cache[currentfactor] = complex_part = \
dup_isolate_complex_roots_sqf(
currentfactor.rep.rep, currentfactor.rep.dom, blackbox=True)
return complex_part
@classmethod
def _get_reals(cls, factors, use_cache=True):
"""Compute real root isolating intervals for a list of factors. """
reals = []
for currentfactor, k in factors:
try:
if not use_cache:
raise KeyError
r = _reals_cache[currentfactor]
reals.extend([(i, currentfactor, k) for i in r])
except KeyError:
real_part = cls._get_reals_sqf(currentfactor, use_cache)
new = [(root, currentfactor, k) for root in real_part]
reals.extend(new)
reals = cls._reals_sorted(reals)
return reals
@classmethod
def _get_complexes(cls, factors, use_cache=True):
"""Compute complex root isolating intervals for a list of factors. """
complexes = []
for currentfactor, k in ordered(factors):
try:
if not use_cache:
raise KeyError
c = _complexes_cache[currentfactor]
complexes.extend([(i, currentfactor, k) for i in c])
except KeyError:
complex_part = cls._get_complexes_sqf(currentfactor, use_cache)
new = [(root, currentfactor, k) for root in complex_part]
complexes.extend(new)
complexes = cls._complexes_sorted(complexes)
return complexes
@classmethod
def _reals_sorted(cls, reals):
"""Make real isolating intervals disjoint and sort roots. """
cache = {}
for i, (u, f, k) in enumerate(reals):
for j, (v, g, m) in enumerate(reals[i + 1:]):
u, v = u.refine_disjoint(v)
reals[i + j + 1] = (v, g, m)
reals[i] = (u, f, k)
reals = sorted(reals, key=lambda r: r[0].a)
for root, currentfactor, _ in reals:
if currentfactor in cache:
cache[currentfactor].append(root)
else:
cache[currentfactor] = [root]
for currentfactor, root in cache.items():
_reals_cache[currentfactor] = root
return reals
@classmethod
def _refine_imaginary(cls, complexes):
sifted = sift(complexes, lambda c: c[1])
complexes = []
for f in ordered(sifted):
nimag = _imag_count_of_factor(f)
if nimag == 0:
# refine until xbounds are neg or pos
for u, f, k in sifted[f]:
while u.ax*u.bx <= 0:
u = u._inner_refine()
complexes.append((u, f, k))
else:
# refine until all but nimag xbounds are neg or pos
potential_imag = list(range(len(sifted[f])))
while True:
assert len(potential_imag) > 1
for i in list(potential_imag):
u, f, k = sifted[f][i]
if u.ax*u.bx > 0:
potential_imag.remove(i)
elif u.ax != u.bx:
u = u._inner_refine()
sifted[f][i] = u, f, k
if len(potential_imag) == nimag:
break
complexes.extend(sifted[f])
return complexes
@classmethod
def _refine_complexes(cls, complexes):
"""return complexes such that no bounding rectangles of non-conjugate
roots would intersect. In addition, assure that neither ay nor by is
0 to guarantee that non-real roots are distinct from real roots in
terms of the y-bounds.
"""
# get the intervals pairwise-disjoint.
# If rectangles were drawn around the coordinates of the bounding
# rectangles, no rectangles would intersect after this procedure.
for i, (u, f, k) in enumerate(complexes):
for j, (v, g, m) in enumerate(complexes[i + 1:]):
u, v = u.refine_disjoint(v)
complexes[i + j + 1] = (v, g, m)
complexes[i] = (u, f, k)
# refine until the x-bounds are unambiguously positive or negative
# for non-imaginary roots
complexes = cls._refine_imaginary(complexes)
# make sure that all y bounds are off the real axis
# and on the same side of the axis
for i, (u, f, k) in enumerate(complexes):
while u.ay*u.by <= 0:
u = u.refine()
complexes[i] = u, f, k
return complexes
@classmethod
def _complexes_sorted(cls, complexes):
"""Make complex isolating intervals disjoint and sort roots. """
complexes = cls._refine_complexes(complexes)
# XXX don't sort until you are sure that it is compatible
# with the indexing method but assert that the desired state
# is not broken
C, F = 0, 1 # location of ComplexInterval and factor
fs = set([i[F] for i in complexes])
for i in range(1, len(complexes)):
if complexes[i][F] != complexes[i - 1][F]:
# if this fails the factors of a root were not
# contiguous because a discontinuity should only
# happen once
fs.remove(complexes[i - 1][F])
for i in range(len(complexes)):
# negative im part (conj=True) comes before
# positive im part (conj=False)
assert complexes[i][C].conj is (i % 2 == 0)
# update cache
cache = {}
# -- collate
for root, currentfactor, _ in complexes:
cache.setdefault(currentfactor, []).append(root)
# -- store
for currentfactor, root in cache.items():
_complexes_cache[currentfactor] = root
return complexes
@classmethod
def _reals_index(cls, reals, index):
"""
Map initial real root index to an index in a factor where
the root belongs.
"""
i = 0
for j, (_, currentfactor, k) in enumerate(reals):
if index < i + k:
poly, index = currentfactor, 0
for _, currentfactor, _ in reals[:j]:
if currentfactor == poly:
index += 1
return poly, index
else:
i += k
@classmethod
def _complexes_index(cls, complexes, index):
"""
Map initial complex root index to an index in a factor where
the root belongs.
"""
i = 0
for j, (_, currentfactor, k) in enumerate(complexes):
if index < i + k:
poly, index = currentfactor, 0
for _, currentfactor, _ in complexes[:j]:
if currentfactor == poly:
index += 1
index += len(_reals_cache[poly])
return poly, index
else:
i += k
@classmethod
def _count_roots(cls, roots):
"""Count the number of real or complex roots with multiplicities."""
return sum([k for _, _, k in roots])
@classmethod
def _indexed_root(cls, poly, index):
"""Get a root of a composite polynomial by index. """
factors = _pure_factors(poly)
reals = cls._get_reals(factors)
reals_count = cls._count_roots(reals)
if index < reals_count:
return cls._reals_index(reals, index)
else:
complexes = cls._get_complexes(factors)
return cls._complexes_index(complexes, index - reals_count)
@classmethod
def _real_roots(cls, poly):
"""Get real roots of a composite polynomial. """
factors = _pure_factors(poly)
reals = cls._get_reals(factors)
reals_count = cls._count_roots(reals)
roots = []
for index in range(0, reals_count):
roots.append(cls._reals_index(reals, index))
return roots
def _reset(self):
"""
Reset all intervals
"""
self._all_roots(self.poly, use_cache=False)
@classmethod
def _all_roots(cls, poly, use_cache=True):
"""Get real and complex roots of a composite polynomial. """
factors = _pure_factors(poly)
reals = cls._get_reals(factors, use_cache=use_cache)
reals_count = cls._count_roots(reals)
roots = []
for index in range(0, reals_count):
roots.append(cls._reals_index(reals, index))
complexes = cls._get_complexes(factors, use_cache=use_cache)
complexes_count = cls._count_roots(complexes)
for index in range(0, complexes_count):
roots.append(cls._complexes_index(complexes, index))
return roots
@classmethod
@cacheit
def _roots_trivial(cls, poly, radicals):
"""Compute roots in linear, quadratic and binomial cases. """
if poly.degree() == 1:
return roots_linear(poly)
if not radicals:
return None
if poly.degree() == 2:
return roots_quadratic(poly)
elif poly.length() == 2 and poly.TC():
return roots_binomial(poly)
else:
return None
@classmethod
def _preprocess_roots(cls, poly):
"""Take heroic measures to make ``poly`` compatible with ``CRootOf``."""
dom = poly.get_domain()
if not dom.is_Exact:
poly = poly.to_exact()
coeff, poly = preprocess_roots(poly)
dom = poly.get_domain()
if not dom.is_ZZ:
raise NotImplementedError(
"sorted roots not supported over %s" % dom)
return coeff, poly
@classmethod
def _postprocess_root(cls, root, radicals):
"""Return the root if it is trivial or a ``CRootOf`` object. """
poly, index = root
roots = cls._roots_trivial(poly, radicals)
if roots is not None:
return roots[index]
else:
return cls._new(poly, index)
@classmethod
def _get_roots(cls, method, poly, radicals):
"""Return postprocessed roots of specified kind. """
if not poly.is_univariate:
raise PolynomialError("only univariate polynomials are allowed")
# get rid of gen and it's free symbol
d = Dummy()
poly = poly.subs(poly.gen, d)
x = symbols('x')
# see what others are left and select x or a numbered x
# that doesn't clash
free_names = {str(i) for i in poly.free_symbols}
for x in chain((symbols('x'),), numbered_symbols('x')):
if x.name not in free_names:
poly = poly.xreplace({d: x})
break
coeff, poly = cls._preprocess_roots(poly)
roots = []
for root in getattr(cls, method)(poly):
roots.append(coeff*cls._postprocess_root(root, radicals))
return roots
@classmethod
def clear_cache(cls):
"""Reset cache for reals and complexes.
The intervals used to approximate a root instance are updated
as needed. When a request is made to see the intervals, the
most current values are shown. `clear_cache` will reset all
CRootOf instances back to their original state.
See Also
========
_reset
"""
global _reals_cache, _complexes_cache
_reals_cache = _pure_key_dict()
_complexes_cache = _pure_key_dict()
def _get_interval(self):
"""Internal function for retrieving isolation interval from cache. """
if self.is_real:
return _reals_cache[self.poly][self.index]
else:
reals_count = len(_reals_cache[self.poly])
return _complexes_cache[self.poly][self.index - reals_count]
def _set_interval(self, interval):
"""Internal function for updating isolation interval in cache. """
if self.is_real:
_reals_cache[self.poly][self.index] = interval
else:
reals_count = len(_reals_cache[self.poly])
_complexes_cache[self.poly][self.index - reals_count] = interval
def _eval_subs(self, old, new):
# don't allow subs to change anything
return self
def _eval_conjugate(self):
if self.is_real:
return self
expr, i = self.args
return self.func(expr, i + (1 if self._get_interval().conj else -1))
def eval_approx(self, n):
"""Evaluate this complex root to the given precision.
This uses secant method and root bounds are used to both
generate an initial guess and to check that the root
returned is valid. If ever the method converges outside the
root bounds, the bounds will be made smaller and updated.
"""
prec = dps_to_prec(n)
with workprec(prec):
g = self.poly.gen
if not g.is_Symbol:
d = Dummy('x')
if self.is_imaginary:
d *= I
func = lambdify(d, self.expr.subs(g, d))
else:
expr = self.expr
if self.is_imaginary:
expr = self.expr.subs(g, I*g)
func = lambdify(g, expr)
interval = self._get_interval()
while True:
if self.is_real:
a = mpf(str(interval.a))
b = mpf(str(interval.b))
if a == b:
root = a
break
x0 = mpf(str(interval.center))
x1 = x0 + mpf(str(interval.dx))/4
elif self.is_imaginary:
a = mpf(str(interval.ay))
b = mpf(str(interval.by))
if a == b:
root = mpc(mpf('0'), a)
break
x0 = mpf(str(interval.center[1]))
x1 = x0 + mpf(str(interval.dy))/4
else:
ax = mpf(str(interval.ax))
bx = mpf(str(interval.bx))
ay = mpf(str(interval.ay))
by = mpf(str(interval.by))
if ax == bx and ay == by:
root = mpc(ax, ay)
break
x0 = mpc(*map(str, interval.center))
x1 = x0 + mpc(*map(str, (interval.dx, interval.dy)))/4
try:
# without a tolerance, this will return when (to within
# the given precision) x_i == x_{i-1}
root = findroot(func, (x0, x1))
# If the (real or complex) root is not in the 'interval',
# then keep refining the interval. This happens if findroot
# accidentally finds a different root outside of this
# interval because our initial estimate 'x0' was not close
# enough. It is also possible that the secant method will
# get trapped by a max/min in the interval; the root
# verification by findroot will raise a ValueError in this
# case and the interval will then be tightened -- and
# eventually the root will be found.
#
# It is also possible that findroot will not have any
# successful iterations to process (in which case it
# will fail to initialize a variable that is tested
# after the iterations and raise an UnboundLocalError).
if self.is_real or self.is_imaginary:
if not bool(root.imag) == self.is_real and (
a <= root <= b):
if self.is_imaginary:
root = mpc(mpf('0'), root.real)
break
elif (ax <= root.real <= bx and ay <= root.imag <= by):
break
except (UnboundLocalError, ValueError):
pass
interval = interval.refine()
# update the interval so we at least (for this precision or
# less) don't have much work to do to recompute the root
self._set_interval(interval)
return (Float._new(root.real._mpf_, prec) +
I*Float._new(root.imag._mpf_, prec))
def _eval_evalf(self, prec, **kwargs):
"""Evaluate this complex root to the given precision."""
# all kwargs are ignored
return self.eval_rational(n=prec_to_dps(prec))._evalf(prec)
def eval_rational(self, dx=None, dy=None, n=15):
"""
Return a Rational approximation of ``self`` that has real
and imaginary component approximations that are within ``dx``
and ``dy`` of the true values, respectively. Alternatively,
``n`` digits of precision can be specified.
The interval is refined with bisection and is sure to
converge. The root bounds are updated when the refinement
is complete so recalculation at the same or lesser precision
will not have to repeat the refinement and should be much
faster.
The following example first obtains Rational approximation to
1e-8 accuracy for all roots of the 4-th order Legendre
polynomial. Since the roots are all less than 1, this will
ensure the decimal representation of the approximation will be
correct (including rounding) to 6 digits:
>>> from sympy import legendre_poly, Symbol
>>> x = Symbol("x")
>>> p = legendre_poly(4, x, polys=True)
>>> r = p.real_roots()[-1]
>>> r.eval_rational(10**-8).n(6)
0.861136
It is not necessary to a two-step calculation, however: the
decimal representation can be computed directly:
>>> r.evalf(17)
0.86113631159405258
"""
dy = dy or dx
if dx:
rtol = None
dx = dx if isinstance(dx, Rational) else Rational(str(dx))
dy = dy if isinstance(dy, Rational) else Rational(str(dy))
else:
# 5 binary (or 2 decimal) digits are needed to ensure that
# a given digit is correctly rounded
# prec_to_dps(dps_to_prec(n) + 5) - n <= 2 (tested for
# n in range(1000000)
rtol = S(10)**-(n + 2) # +2 for guard digits
interval = self._get_interval()
while True:
if self.is_real:
if rtol:
dx = abs(interval.center*rtol)
interval = interval.refine_size(dx=dx)
c = interval.center
real = Rational(c)
imag = S.Zero
if not rtol or interval.dx < abs(c*rtol):
break
elif self.is_imaginary:
if rtol:
dy = abs(interval.center[1]*rtol)
dx = 1
interval = interval.refine_size(dx=dx, dy=dy)
c = interval.center[1]
imag = Rational(c)
real = S.Zero
if not rtol or interval.dy < abs(c*rtol):
break
else:
if rtol:
dx = abs(interval.center[0]*rtol)
dy = abs(interval.center[1]*rtol)
interval = interval.refine_size(dx, dy)
c = interval.center
real, imag = map(Rational, c)
if not rtol or (
interval.dx < abs(c[0]*rtol) and
interval.dy < abs(c[1]*rtol)):
break
# update the interval so we at least (for this precision or
# less) don't have much work to do to recompute the root
self._set_interval(interval)
return real + I*imag
def _eval_Eq(self, other):
# CRootOf represents a Root, so if other is that root, it should set
# the expression to zero *and* it should be in the interval of the
# CRootOf instance. It must also be a number that agrees with the
# is_real value of the CRootOf instance.
if type(self) == type(other):
return sympify(self == other)
if not other.is_number:
return None
if not other.is_finite:
return S.false
z = self.expr.subs(self.expr.free_symbols.pop(), other).is_zero
if z is False: # all roots will make z True but we don't know
# whether this is the right root if z is True
return S.false
o = other.is_real, other.is_imaginary
s = self.is_real, self.is_imaginary
assert None not in s # this is part of initial refinement
if o != s and None not in o:
return S.false
re, im = other.as_real_imag()
if self.is_real:
if im:
return S.false
i = self._get_interval()
a, b = [Rational(str(_)) for _ in (i.a, i.b)]
return sympify(a <= other and other <= b)
i = self._get_interval()
r1, r2, i1, i2 = [Rational(str(j)) for j in (
i.ax, i.bx, i.ay, i.by)]
return sympify((
r1 <= re and re <= r2) and (
i1 <= im and im <= i2))
CRootOf = ComplexRootOf
@public
class RootSum(Expr):
"""Represents a sum of all roots of a univariate polynomial. """
__slots__ = ('poly', 'fun', 'auto')
def __new__(cls, expr, func=None, x=None, auto=True, quadratic=False):
"""Construct a new ``RootSum`` instance of roots of a polynomial."""
coeff, poly = cls._transform(expr, x)
if not poly.is_univariate:
raise MultivariatePolynomialError(
"only univariate polynomials are allowed")
if func is None:
func = Lambda(poly.gen, poly.gen)
else:
is_func = getattr(func, 'is_Function', False)
if is_func and 1 in func.nargs:
if not isinstance(func, Lambda):
func = Lambda(poly.gen, func(poly.gen))
else:
raise ValueError(
"expected a univariate function, got %s" % func)
var, expr = func.variables[0], func.expr
if coeff is not S.One:
expr = expr.subs(var, coeff*var)
deg = poly.degree()
if not expr.has(var):
return deg*expr
if expr.is_Add:
add_const, expr = expr.as_independent(var)
else:
add_const = S.Zero
if expr.is_Mul:
mul_const, expr = expr.as_independent(var)
else:
mul_const = S.One
func = Lambda(var, expr)
rational = cls._is_func_rational(poly, func)
factors, terms = _pure_factors(poly), []
for poly, k in factors:
if poly.is_linear:
term = func(roots_linear(poly)[0])
elif quadratic and poly.is_quadratic:
term = sum(map(func, roots_quadratic(poly)))
else:
if not rational or not auto:
term = cls._new(poly, func, auto)
else:
term = cls._rational_case(poly, func)
terms.append(k*term)
return mul_const*Add(*terms) + deg*add_const
@classmethod
def _new(cls, poly, func, auto=True):
"""Construct new raw ``RootSum`` instance. """
obj = Expr.__new__(cls)
obj.poly = poly
obj.fun = func
obj.auto = auto
return obj
@classmethod
def new(cls, poly, func, auto=True):
"""Construct new ``RootSum`` instance. """
if not func.expr.has(*func.variables):
return func.expr
rational = cls._is_func_rational(poly, func)
if not rational or not auto:
return cls._new(poly, func, auto)
else:
return cls._rational_case(poly, func)
@classmethod
def _transform(cls, expr, x):
"""Transform an expression to a polynomial. """
poly = PurePoly(expr, x, greedy=False)
return preprocess_roots(poly)
@classmethod
def _is_func_rational(cls, poly, func):
"""Check if a lambda is a rational function. """
var, expr = func.variables[0], func.expr
return expr.is_rational_function(var)
@classmethod
def _rational_case(cls, poly, func):
"""Handle the rational function case. """
roots = symbols('r:%d' % poly.degree())
var, expr = func.variables[0], func.expr
f = sum(expr.subs(var, r) for r in roots)
p, q = together(f).as_numer_denom()
domain = QQ[roots]
p = p.expand()
q = q.expand()
try:
p = Poly(p, domain=domain, expand=False)
except GeneratorsNeeded:
p, p_coeff = None, (p,)
else:
p_monom, p_coeff = zip(*p.terms())
try:
q = Poly(q, domain=domain, expand=False)
except GeneratorsNeeded:
q, q_coeff = None, (q,)
else:
q_monom, q_coeff = zip(*q.terms())
coeffs, mapping = symmetrize(p_coeff + q_coeff, formal=True)
formulas, values = viete(poly, roots), []
for (sym, _), (_, val) in zip(mapping, formulas):
values.append((sym, val))
for i, (coeff, _) in enumerate(coeffs):
coeffs[i] = coeff.subs(values)
n = len(p_coeff)
p_coeff = coeffs[:n]
q_coeff = coeffs[n:]
if p is not None:
p = Poly(dict(zip(p_monom, p_coeff)), *p.gens).as_expr()
else:
(p,) = p_coeff
if q is not None:
q = Poly(dict(zip(q_monom, q_coeff)), *q.gens).as_expr()
else:
(q,) = q_coeff
return factor(p/q)
def _hashable_content(self):
return (self.poly, self.fun)
@property
def expr(self):
return self.poly.as_expr()
@property
def args(self):
return (self.expr, self.fun, self.poly.gen)
@property
def free_symbols(self):
return self.poly.free_symbols | self.fun.free_symbols
@property
def is_commutative(self):
return True
def doit(self, **hints):
if not hints.get('roots', True):
return self
_roots = roots(self.poly, multiple=True)
if len(_roots) < self.poly.degree():
return self
else:
return Add(*[self.fun(r) for r in _roots])
def _eval_evalf(self, prec):
try:
_roots = self.poly.nroots(n=prec_to_dps(prec))
except (DomainError, PolynomialError):
return self
else:
return Add(*[self.fun(r) for r in _roots])
def _eval_derivative(self, x):
var, expr = self.fun.args
func = Lambda(var, expr.diff(x))
return self.new(self.poly, func, self.auto)
|
808f388e850c4a779f6bbce056df54840e1387421ac6edd533154aaf99a4f2df | """Square-free decomposition algorithms and related tools. """
from __future__ import print_function, division
from sympy.polys.densearith import (
dup_neg, dmp_neg,
dup_sub, dmp_sub,
dup_mul,
dup_quo, dmp_quo,
dup_mul_ground, dmp_mul_ground)
from sympy.polys.densebasic import (
dup_strip,
dup_LC, dmp_ground_LC,
dmp_zero_p,
dmp_ground,
dup_degree, dmp_degree,
dmp_raise, dmp_inject,
dup_convert)
from sympy.polys.densetools import (
dup_diff, dmp_diff, dmp_diff_in,
dup_shift, dmp_compose,
dup_monic, dmp_ground_monic,
dup_primitive, dmp_ground_primitive)
from sympy.polys.euclidtools import (
dup_inner_gcd, dmp_inner_gcd,
dup_gcd, dmp_gcd,
dmp_resultant)
from sympy.polys.galoistools import (
gf_sqf_list, gf_sqf_part)
from sympy.polys.polyerrors import (
MultivariatePolynomialError,
DomainError)
def dup_sqf_p(f, K):
"""
Return ``True`` if ``f`` is a square-free polynomial in ``K[x]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> R.dup_sqf_p(x**2 - 2*x + 1)
False
>>> R.dup_sqf_p(x**2 - 1)
True
"""
if not f:
return True
else:
return not dup_degree(dup_gcd(f, dup_diff(f, 1, K), K))
def dmp_sqf_p(f, u, K):
"""
Return ``True`` if ``f`` is a square-free polynomial in ``K[X]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
>>> R.dmp_sqf_p(x**2 + 2*x*y + y**2)
False
>>> R.dmp_sqf_p(x**2 + y**2)
True
"""
if dmp_zero_p(f, u):
return True
else:
return not dmp_degree(dmp_gcd(f, dmp_diff(f, 1, u, K), u, K), u)
def dup_sqf_norm(f, K):
"""
Square-free norm of ``f`` in ``K[x]``, useful over algebraic domains.
Returns ``s``, ``f``, ``r``, such that ``g(x) = f(x-sa)`` and ``r(x) = Norm(g(x))``
is a square-free polynomial over K, where ``a`` is the algebraic extension of ``K``.
Examples
========
>>> from sympy.polys import ring, QQ
>>> from sympy import sqrt
>>> K = QQ.algebraic_field(sqrt(3))
>>> R, x = ring("x", K)
>>> _, X = ring("x", QQ)
>>> s, f, r = R.dup_sqf_norm(x**2 - 2)
>>> s == 1
True
>>> f == x**2 + K([QQ(-2), QQ(0)])*x + 1
True
>>> r == X**4 - 10*X**2 + 1
True
"""
if not K.is_Algebraic:
raise DomainError("ground domain must be algebraic")
s, g = 0, dmp_raise(K.mod.rep, 1, 0, K.dom)
while True:
h, _ = dmp_inject(f, 0, K, front=True)
r = dmp_resultant(g, h, 1, K.dom)
if dup_sqf_p(r, K.dom):
break
else:
f, s = dup_shift(f, -K.unit, K), s + 1
return s, f, r
def dmp_sqf_norm(f, u, K):
"""
Square-free norm of ``f`` in ``K[X]``, useful over algebraic domains.
Returns ``s``, ``f``, ``r``, such that ``g(x) = f(x-sa)`` and ``r(x) = Norm(g(x))``
is a square-free polynomial over K, where ``a`` is the algebraic extension of ``K``.
Examples
========
>>> from sympy.polys import ring, QQ
>>> from sympy import I
>>> K = QQ.algebraic_field(I)
>>> R, x, y = ring("x,y", K)
>>> _, X, Y = ring("x,y", QQ)
>>> s, f, r = R.dmp_sqf_norm(x*y + y**2)
>>> s == 1
True
>>> f == x*y + y**2 + K([QQ(-1), QQ(0)])*y
True
>>> r == X**2*Y**2 + 2*X*Y**3 + Y**4 + Y**2
True
"""
if not u:
return dup_sqf_norm(f, K)
if not K.is_Algebraic:
raise DomainError("ground domain must be algebraic")
g = dmp_raise(K.mod.rep, u + 1, 0, K.dom)
F = dmp_raise([K.one, -K.unit], u, 0, K)
s = 0
while True:
h, _ = dmp_inject(f, u, K, front=True)
r = dmp_resultant(g, h, u + 1, K.dom)
if dmp_sqf_p(r, u, K.dom):
break
else:
f, s = dmp_compose(f, F, u, K), s + 1
return s, f, r
def dmp_norm(f, u, K):
"""
Norm of ``f`` in ``K[X1, ..., Xn]``, often not square-free.
"""
if not K.is_Algebraic:
raise DomainError("ground domain must be algebraic")
g = dmp_raise(K.mod.rep, u + 1, 0, K.dom)
h, _ = dmp_inject(f, u, K, front=True)
return dmp_resultant(g, h, u + 1, K.dom)
def dup_gf_sqf_part(f, K):
"""Compute square-free part of ``f`` in ``GF(p)[x]``. """
f = dup_convert(f, K, K.dom)
g = gf_sqf_part(f, K.mod, K.dom)
return dup_convert(g, K.dom, K)
def dmp_gf_sqf_part(f, u, K):
"""Compute square-free part of ``f`` in ``GF(p)[X]``. """
raise NotImplementedError('multivariate polynomials over finite fields')
def dup_sqf_part(f, K):
"""
Returns square-free part of a polynomial in ``K[x]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> R.dup_sqf_part(x**3 - 3*x - 2)
x**2 - x - 2
"""
if K.is_FiniteField:
return dup_gf_sqf_part(f, K)
if not f:
return f
if K.is_negative(dup_LC(f, K)):
f = dup_neg(f, K)
gcd = dup_gcd(f, dup_diff(f, 1, K), K)
sqf = dup_quo(f, gcd, K)
if K.is_Field:
return dup_monic(sqf, K)
else:
return dup_primitive(sqf, K)[1]
def dmp_sqf_part(f, u, K):
"""
Returns square-free part of a polynomial in ``K[X]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
>>> R.dmp_sqf_part(x**3 + 2*x**2*y + x*y**2)
x**2 + x*y
"""
if not u:
return dup_sqf_part(f, K)
if K.is_FiniteField:
return dmp_gf_sqf_part(f, u, K)
if dmp_zero_p(f, u):
return f
if K.is_negative(dmp_ground_LC(f, u, K)):
f = dmp_neg(f, u, K)
gcd = f
for i in range(u+1):
gcd = dmp_gcd(gcd, dmp_diff_in(f, 1, i, u, K), u, K)
sqf = dmp_quo(f, gcd, u, K)
if K.is_Field:
return dmp_ground_monic(sqf, u, K)
else:
return dmp_ground_primitive(sqf, u, K)[1]
def dup_gf_sqf_list(f, K, all=False):
"""Compute square-free decomposition of ``f`` in ``GF(p)[x]``. """
f = dup_convert(f, K, K.dom)
coeff, factors = gf_sqf_list(f, K.mod, K.dom, all=all)
for i, (f, k) in enumerate(factors):
factors[i] = (dup_convert(f, K.dom, K), k)
return K.convert(coeff, K.dom), factors
def dmp_gf_sqf_list(f, u, K, all=False):
"""Compute square-free decomposition of ``f`` in ``GF(p)[X]``. """
raise NotImplementedError('multivariate polynomials over finite fields')
def dup_sqf_list(f, K, all=False):
"""
Return square-free decomposition of a polynomial in ``K[x]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> f = 2*x**5 + 16*x**4 + 50*x**3 + 76*x**2 + 56*x + 16
>>> R.dup_sqf_list(f)
(2, [(x + 1, 2), (x + 2, 3)])
>>> R.dup_sqf_list(f, all=True)
(2, [(1, 1), (x + 1, 2), (x + 2, 3)])
"""
if K.is_FiniteField:
return dup_gf_sqf_list(f, K, all=all)
if K.is_Field:
coeff = dup_LC(f, K)
f = dup_monic(f, K)
else:
coeff, f = dup_primitive(f, K)
if K.is_negative(dup_LC(f, K)):
f = dup_neg(f, K)
coeff = -coeff
if dup_degree(f) <= 0:
return coeff, []
result, i = [], 1
h = dup_diff(f, 1, K)
g, p, q = dup_inner_gcd(f, h, K)
while True:
d = dup_diff(p, 1, K)
h = dup_sub(q, d, K)
if not h:
result.append((p, i))
break
g, p, q = dup_inner_gcd(p, h, K)
if all or dup_degree(g) > 0:
result.append((g, i))
i += 1
return coeff, result
def dup_sqf_list_include(f, K, all=False):
"""
Return square-free decomposition of a polynomial in ``K[x]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> f = 2*x**5 + 16*x**4 + 50*x**3 + 76*x**2 + 56*x + 16
>>> R.dup_sqf_list_include(f)
[(2, 1), (x + 1, 2), (x + 2, 3)]
>>> R.dup_sqf_list_include(f, all=True)
[(2, 1), (x + 1, 2), (x + 2, 3)]
"""
coeff, factors = dup_sqf_list(f, K, all=all)
if factors and factors[0][1] == 1:
g = dup_mul_ground(factors[0][0], coeff, K)
return [(g, 1)] + factors[1:]
else:
g = dup_strip([coeff])
return [(g, 1)] + factors
def dmp_sqf_list(f, u, K, all=False):
"""
Return square-free decomposition of a polynomial in ``K[X]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
>>> f = x**5 + 2*x**4*y + x**3*y**2
>>> R.dmp_sqf_list(f)
(1, [(x + y, 2), (x, 3)])
>>> R.dmp_sqf_list(f, all=True)
(1, [(1, 1), (x + y, 2), (x, 3)])
"""
if not u:
return dup_sqf_list(f, K, all=all)
if K.is_FiniteField:
return dmp_gf_sqf_list(f, u, K, all=all)
if K.is_Field:
coeff = dmp_ground_LC(f, u, K)
f = dmp_ground_monic(f, u, K)
else:
coeff, f = dmp_ground_primitive(f, u, K)
if K.is_negative(dmp_ground_LC(f, u, K)):
f = dmp_neg(f, u, K)
coeff = -coeff
if dmp_degree(f, u) <= 0:
return coeff, []
result, i = [], 1
h = dmp_diff(f, 1, u, K)
g, p, q = dmp_inner_gcd(f, h, u, K)
while True:
d = dmp_diff(p, 1, u, K)
h = dmp_sub(q, d, u, K)
if dmp_zero_p(h, u):
result.append((p, i))
break
g, p, q = dmp_inner_gcd(p, h, u, K)
if all or dmp_degree(g, u) > 0:
result.append((g, i))
i += 1
return coeff, result
def dmp_sqf_list_include(f, u, K, all=False):
"""
Return square-free decomposition of a polynomial in ``K[x]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
>>> f = x**5 + 2*x**4*y + x**3*y**2
>>> R.dmp_sqf_list_include(f)
[(1, 1), (x + y, 2), (x, 3)]
>>> R.dmp_sqf_list_include(f, all=True)
[(1, 1), (x + y, 2), (x, 3)]
"""
if not u:
return dup_sqf_list_include(f, K, all=all)
coeff, factors = dmp_sqf_list(f, u, K, all=all)
if factors and factors[0][1] == 1:
g = dmp_mul_ground(factors[0][0], coeff, u, K)
return [(g, 1)] + factors[1:]
else:
g = dmp_ground(coeff, u)
return [(g, 1)] + factors
def dup_gff_list(f, K):
"""
Compute greatest factorial factorization of ``f`` in ``K[x]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> R.dup_gff_list(x**5 + 2*x**4 - x**3 - 2*x**2)
[(x, 1), (x + 2, 4)]
"""
if not f:
raise ValueError("greatest factorial factorization doesn't exist for a zero polynomial")
f = dup_monic(f, K)
if not dup_degree(f):
return []
else:
g = dup_gcd(f, dup_shift(f, K.one, K), K)
H = dup_gff_list(g, K)
for i, (h, k) in enumerate(H):
g = dup_mul(g, dup_shift(h, -K(k), K), K)
H[i] = (h, k + 1)
f = dup_quo(f, g, K)
if not dup_degree(f):
return H
else:
return [(f, 1)] + H
def dmp_gff_list(f, u, K):
"""
Compute greatest factorial factorization of ``f`` in ``K[X]``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
"""
if not u:
return dup_gff_list(f, K)
else:
raise MultivariatePolynomialError(f)
|
d02dce7e55806d165e0f977204e774c0e448f4f73187ad49da2995bee573f6ac | """User-friendly public interface to polynomial functions. """
from __future__ import print_function, division
from functools import wraps, reduce
from operator import mul
from sympy.core import (
S, Basic, Expr, I, Integer, Add, Mul, Dummy, Tuple
)
from sympy.core.basic import preorder_traversal
from sympy.core.compatibility import iterable, ordered
from sympy.core.decorators import _sympifyit
from sympy.core.function import Derivative
from sympy.core.mul import _keep_coeff
from sympy.core.relational import Relational
from sympy.core.symbol import Symbol
from sympy.core.sympify import sympify, _sympify
from sympy.logic.boolalg import BooleanAtom
from sympy.polys import polyoptions as options
from sympy.polys.constructor import construct_domain
from sympy.polys.domains import FF, QQ, ZZ
from sympy.polys.fglmtools import matrix_fglm
from sympy.polys.groebnertools import groebner as _groebner
from sympy.polys.monomials import Monomial
from sympy.polys.orderings import monomial_key
from sympy.polys.polyclasses import DMP
from sympy.polys.polyerrors import (
OperationNotSupported, DomainError,
CoercionFailed, UnificationFailed,
GeneratorsNeeded, PolynomialError,
MultivariatePolynomialError,
ExactQuotientFailed,
PolificationFailed,
ComputationFailed,
GeneratorsError,
)
from sympy.polys.polyutils import (
basic_from_dict,
_sort_gens,
_unify_gens,
_dict_reorder,
_dict_from_expr,
_parallel_dict_from_expr,
)
from sympy.polys.rationaltools import together
from sympy.polys.rootisolation import dup_isolate_real_roots_list
from sympy.utilities import group, sift, public, filldedent
from sympy.utilities.exceptions import SymPyDeprecationWarning
# Required to avoid errors
import sympy.polys
import mpmath
from mpmath.libmp.libhyper import NoConvergence
def _polifyit(func):
@wraps(func)
def wrapper(f, g):
g = _sympify(g)
if isinstance(g, Poly):
return func(f, g)
elif isinstance(g, Expr):
try:
g = f.from_expr(g, *f.gens)
except PolynomialError:
if g.is_Matrix:
return NotImplemented
expr_method = getattr(f.as_expr(), func.__name__)
result = expr_method(g)
if result is not NotImplemented:
SymPyDeprecationWarning(
feature="Mixing Poly with non-polynomial expressions in binary operations",
issue=18613,
deprecated_since_version="1.6",
useinstead="the as_expr or as_poly method to convert types").warn()
return result
else:
return func(f, g)
else:
return NotImplemented
return wrapper
@public
class Poly(Basic):
"""
Generic class for representing and operating on polynomial expressions.
Poly is a subclass of Basic rather than Expr but instances can be
converted to Expr with the ``as_expr`` method.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
Create a univariate polynomial:
>>> Poly(x*(x**2 + x - 1)**2)
Poly(x**5 + 2*x**4 - x**3 - 2*x**2 + x, x, domain='ZZ')
Create a univariate polynomial with specific domain:
>>> from sympy import sqrt
>>> Poly(x**2 + 2*x + sqrt(3), domain='R')
Poly(1.0*x**2 + 2.0*x + 1.73205080756888, x, domain='RR')
Create a multivariate polynomial:
>>> Poly(y*x**2 + x*y + 1)
Poly(x**2*y + x*y + 1, x, y, domain='ZZ')
Create a univariate polynomial, where y is a constant:
>>> Poly(y*x**2 + x*y + 1,x)
Poly(y*x**2 + y*x + 1, x, domain='ZZ[y]')
You can evaluate the above polynomial as a function of y:
>>> Poly(y*x**2 + x*y + 1,x).eval(2)
6*y + 1
See Also
========
sympy.core.expr.Expr
"""
__slots__ = ('rep', 'gens')
is_commutative = True
is_Poly = True
_op_priority = 10.001
def __new__(cls, rep, *gens, **args):
"""Create a new polynomial instance out of something useful. """
opt = options.build_options(gens, args)
if 'order' in opt:
raise NotImplementedError("'order' keyword is not implemented yet")
if iterable(rep, exclude=str):
if isinstance(rep, dict):
return cls._from_dict(rep, opt)
else:
return cls._from_list(list(rep), opt)
else:
rep = sympify(rep)
if rep.is_Poly:
return cls._from_poly(rep, opt)
else:
return cls._from_expr(rep, opt)
# Poly does not pass its args to Basic.__new__ to be stored in _args so we
# have to emulate them here with an args property that derives from rep
# and gens which are instance attributes. This also means we need to
# define _hashable_content. The _hashable_content is rep and gens but args
# uses expr instead of rep (expr is the Basic version of rep). Passing
# expr in args means that Basic methods like subs should work. Using rep
# otherwise means that Poly can remain more efficient than Basic by
# avoiding creating a Basic instance just to be hashable.
@classmethod
def new(cls, rep, *gens):
"""Construct :class:`Poly` instance from raw representation. """
if not isinstance(rep, DMP):
raise PolynomialError(
"invalid polynomial representation: %s" % rep)
elif rep.lev != len(gens) - 1:
raise PolynomialError("invalid arguments: %s, %s" % (rep, gens))
obj = Basic.__new__(cls)
obj.rep = rep
obj.gens = gens
return obj
@property
def expr(self):
return basic_from_dict(self.rep.to_sympy_dict(), *self.gens)
@property
def args(self):
return (self.expr,) + self.gens
def _hashable_content(self):
return (self.rep,) + self.gens
@classmethod
def from_dict(cls, rep, *gens, **args):
"""Construct a polynomial from a ``dict``. """
opt = options.build_options(gens, args)
return cls._from_dict(rep, opt)
@classmethod
def from_list(cls, rep, *gens, **args):
"""Construct a polynomial from a ``list``. """
opt = options.build_options(gens, args)
return cls._from_list(rep, opt)
@classmethod
def from_poly(cls, rep, *gens, **args):
"""Construct a polynomial from a polynomial. """
opt = options.build_options(gens, args)
return cls._from_poly(rep, opt)
@classmethod
def from_expr(cls, rep, *gens, **args):
"""Construct a polynomial from an expression. """
opt = options.build_options(gens, args)
return cls._from_expr(rep, opt)
@classmethod
def _from_dict(cls, rep, opt):
"""Construct a polynomial from a ``dict``. """
gens = opt.gens
if not gens:
raise GeneratorsNeeded(
"can't initialize from 'dict' without generators")
level = len(gens) - 1
domain = opt.domain
if domain is None:
domain, rep = construct_domain(rep, opt=opt)
else:
for monom, coeff in rep.items():
rep[monom] = domain.convert(coeff)
return cls.new(DMP.from_dict(rep, level, domain), *gens)
@classmethod
def _from_list(cls, rep, opt):
"""Construct a polynomial from a ``list``. """
gens = opt.gens
if not gens:
raise GeneratorsNeeded(
"can't initialize from 'list' without generators")
elif len(gens) != 1:
raise MultivariatePolynomialError(
"'list' representation not supported")
level = len(gens) - 1
domain = opt.domain
if domain is None:
domain, rep = construct_domain(rep, opt=opt)
else:
rep = list(map(domain.convert, rep))
return cls.new(DMP.from_list(rep, level, domain), *gens)
@classmethod
def _from_poly(cls, rep, opt):
"""Construct a polynomial from a polynomial. """
if cls != rep.__class__:
rep = cls.new(rep.rep, *rep.gens)
gens = opt.gens
field = opt.field
domain = opt.domain
if gens and rep.gens != gens:
if set(rep.gens) != set(gens):
return cls._from_expr(rep.as_expr(), opt)
else:
rep = rep.reorder(*gens)
if 'domain' in opt and domain:
rep = rep.set_domain(domain)
elif field is True:
rep = rep.to_field()
return rep
@classmethod
def _from_expr(cls, rep, opt):
"""Construct a polynomial from an expression. """
rep, opt = _dict_from_expr(rep, opt)
return cls._from_dict(rep, opt)
def __hash__(self):
return super(Poly, self).__hash__()
@property
def free_symbols(self):
"""
Free symbols of a polynomial expression.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y, z
>>> Poly(x**2 + 1).free_symbols
{x}
>>> Poly(x**2 + y).free_symbols
{x, y}
>>> Poly(x**2 + y, x).free_symbols
{x, y}
>>> Poly(x**2 + y, x, z).free_symbols
{x, y}
"""
symbols = set()
gens = self.gens
for i in range(len(gens)):
for monom in self.monoms():
if monom[i]:
symbols |= gens[i].free_symbols
break
return symbols | self.free_symbols_in_domain
@property
def free_symbols_in_domain(self):
"""
Free symbols of the domain of ``self``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 1).free_symbols_in_domain
set()
>>> Poly(x**2 + y).free_symbols_in_domain
set()
>>> Poly(x**2 + y, x).free_symbols_in_domain
{y}
"""
domain, symbols = self.rep.dom, set()
if domain.is_Composite:
for gen in domain.symbols:
symbols |= gen.free_symbols
elif domain.is_EX:
for coeff in self.coeffs():
symbols |= coeff.free_symbols
return symbols
@property
def gen(self):
"""
Return the principal generator.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).gen
x
"""
return self.gens[0]
@property
def domain(self):
"""Get the ground domain of ``self``. """
return self.get_domain()
@property
def zero(self):
"""Return zero polynomial with ``self``'s properties. """
return self.new(self.rep.zero(self.rep.lev, self.rep.dom), *self.gens)
@property
def one(self):
"""Return one polynomial with ``self``'s properties. """
return self.new(self.rep.one(self.rep.lev, self.rep.dom), *self.gens)
@property
def unit(self):
"""Return unit polynomial with ``self``'s properties. """
return self.new(self.rep.unit(self.rep.lev, self.rep.dom), *self.gens)
def unify(f, g):
"""
Make ``f`` and ``g`` belong to the same domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f, g = Poly(x/2 + 1), Poly(2*x + 1)
>>> f
Poly(1/2*x + 1, x, domain='QQ')
>>> g
Poly(2*x + 1, x, domain='ZZ')
>>> F, G = f.unify(g)
>>> F
Poly(1/2*x + 1, x, domain='QQ')
>>> G
Poly(2*x + 1, x, domain='QQ')
"""
_, per, F, G = f._unify(g)
return per(F), per(G)
def _unify(f, g):
g = sympify(g)
if not g.is_Poly:
try:
return f.rep.dom, f.per, f.rep, f.rep.per(f.rep.dom.from_sympy(g))
except CoercionFailed:
raise UnificationFailed("can't unify %s with %s" % (f, g))
if isinstance(f.rep, DMP) and isinstance(g.rep, DMP):
gens = _unify_gens(f.gens, g.gens)
dom, lev = f.rep.dom.unify(g.rep.dom, gens), len(gens) - 1
if f.gens != gens:
f_monoms, f_coeffs = _dict_reorder(
f.rep.to_dict(), f.gens, gens)
if f.rep.dom != dom:
f_coeffs = [dom.convert(c, f.rep.dom) for c in f_coeffs]
F = DMP(dict(list(zip(f_monoms, f_coeffs))), dom, lev)
else:
F = f.rep.convert(dom)
if g.gens != gens:
g_monoms, g_coeffs = _dict_reorder(
g.rep.to_dict(), g.gens, gens)
if g.rep.dom != dom:
g_coeffs = [dom.convert(c, g.rep.dom) for c in g_coeffs]
G = DMP(dict(list(zip(g_monoms, g_coeffs))), dom, lev)
else:
G = g.rep.convert(dom)
else:
raise UnificationFailed("can't unify %s with %s" % (f, g))
cls = f.__class__
def per(rep, dom=dom, gens=gens, remove=None):
if remove is not None:
gens = gens[:remove] + gens[remove + 1:]
if not gens:
return dom.to_sympy(rep)
return cls.new(rep, *gens)
return dom, per, F, G
def per(f, rep, gens=None, remove=None):
"""
Create a Poly out of the given representation.
Examples
========
>>> from sympy import Poly, ZZ
>>> from sympy.abc import x, y
>>> from sympy.polys.polyclasses import DMP
>>> a = Poly(x**2 + 1)
>>> a.per(DMP([ZZ(1), ZZ(1)], ZZ), gens=[y])
Poly(y + 1, y, domain='ZZ')
"""
if gens is None:
gens = f.gens
if remove is not None:
gens = gens[:remove] + gens[remove + 1:]
if not gens:
return f.rep.dom.to_sympy(rep)
return f.__class__.new(rep, *gens)
def set_domain(f, domain):
"""Set the ground domain of ``f``. """
opt = options.build_options(f.gens, {'domain': domain})
return f.per(f.rep.convert(opt.domain))
def get_domain(f):
"""Get the ground domain of ``f``. """
return f.rep.dom
def set_modulus(f, modulus):
"""
Set the modulus of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(5*x**2 + 2*x - 1, x).set_modulus(2)
Poly(x**2 + 1, x, modulus=2)
"""
modulus = options.Modulus.preprocess(modulus)
return f.set_domain(FF(modulus))
def get_modulus(f):
"""
Get the modulus of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, modulus=2).get_modulus()
2
"""
domain = f.get_domain()
if domain.is_FiniteField:
return Integer(domain.characteristic())
else:
raise PolynomialError("not a polynomial over a Galois field")
def _eval_subs(f, old, new):
"""Internal implementation of :func:`subs`. """
if old in f.gens:
if new.is_number:
return f.eval(old, new)
else:
try:
return f.replace(old, new)
except PolynomialError:
pass
return f.as_expr().subs(old, new)
def exclude(f):
"""
Remove unnecessary generators from ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import a, b, c, d, x
>>> Poly(a + x, a, b, c, d, x).exclude()
Poly(a + x, a, x, domain='ZZ')
"""
J, new = f.rep.exclude()
gens = []
for j in range(len(f.gens)):
if j not in J:
gens.append(f.gens[j])
return f.per(new, gens=gens)
def replace(f, x, y=None, *_ignore):
# XXX this does not match Basic's signature
"""
Replace ``x`` with ``y`` in generators list.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 1, x).replace(x, y)
Poly(y**2 + 1, y, domain='ZZ')
"""
if y is None:
if f.is_univariate:
x, y = f.gen, x
else:
raise PolynomialError(
"syntax supported only in univariate case")
if x == y or x not in f.gens:
return f
if x in f.gens and y not in f.gens:
dom = f.get_domain()
if not dom.is_Composite or y not in dom.symbols:
gens = list(f.gens)
gens[gens.index(x)] = y
return f.per(f.rep, gens=gens)
raise PolynomialError("can't replace %s with %s in %s" % (x, y, f))
def match(f, *args, **kwargs):
"""Match expression from Poly. See Basic.match()"""
return f.as_expr().match(*args, **kwargs)
def reorder(f, *gens, **args):
"""
Efficiently apply new order of generators.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + x*y**2, x, y).reorder(y, x)
Poly(y**2*x + x**2, y, x, domain='ZZ')
"""
opt = options.Options((), args)
if not gens:
gens = _sort_gens(f.gens, opt=opt)
elif set(f.gens) != set(gens):
raise PolynomialError(
"generators list can differ only up to order of elements")
rep = dict(list(zip(*_dict_reorder(f.rep.to_dict(), f.gens, gens))))
return f.per(DMP(rep, f.rep.dom, len(gens) - 1), gens=gens)
def ltrim(f, gen):
"""
Remove dummy generators from ``f`` that are to the left of
specified ``gen`` in the generators as ordered. When ``gen``
is an integer, it refers to the generator located at that
position within the tuple of generators of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y, z
>>> Poly(y**2 + y*z**2, x, y, z).ltrim(y)
Poly(y**2 + y*z**2, y, z, domain='ZZ')
>>> Poly(z, x, y, z).ltrim(-1)
Poly(z, z, domain='ZZ')
"""
rep = f.as_dict(native=True)
j = f._gen_to_level(gen)
terms = {}
for monom, coeff in rep.items():
if any(monom[:j]):
# some generator is used in the portion to be trimmed
raise PolynomialError("can't left trim %s" % f)
terms[monom[j:]] = coeff
gens = f.gens[j:]
return f.new(DMP.from_dict(terms, len(gens) - 1, f.rep.dom), *gens)
def has_only_gens(f, *gens):
"""
Return ``True`` if ``Poly(f, *gens)`` retains ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y, z
>>> Poly(x*y + 1, x, y, z).has_only_gens(x, y)
True
>>> Poly(x*y + z, x, y, z).has_only_gens(x, y)
False
"""
indices = set()
for gen in gens:
try:
index = f.gens.index(gen)
except ValueError:
raise GeneratorsError(
"%s doesn't have %s as generator" % (f, gen))
else:
indices.add(index)
for monom in f.monoms():
for i, elt in enumerate(monom):
if i not in indices and elt:
return False
return True
def to_ring(f):
"""
Make the ground domain a ring.
Examples
========
>>> from sympy import Poly, QQ
>>> from sympy.abc import x
>>> Poly(x**2 + 1, domain=QQ).to_ring()
Poly(x**2 + 1, x, domain='ZZ')
"""
if hasattr(f.rep, 'to_ring'):
result = f.rep.to_ring()
else: # pragma: no cover
raise OperationNotSupported(f, 'to_ring')
return f.per(result)
def to_field(f):
"""
Make the ground domain a field.
Examples
========
>>> from sympy import Poly, ZZ
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x, domain=ZZ).to_field()
Poly(x**2 + 1, x, domain='QQ')
"""
if hasattr(f.rep, 'to_field'):
result = f.rep.to_field()
else: # pragma: no cover
raise OperationNotSupported(f, 'to_field')
return f.per(result)
def to_exact(f):
"""
Make the ground domain exact.
Examples
========
>>> from sympy import Poly, RR
>>> from sympy.abc import x
>>> Poly(x**2 + 1.0, x, domain=RR).to_exact()
Poly(x**2 + 1, x, domain='QQ')
"""
if hasattr(f.rep, 'to_exact'):
result = f.rep.to_exact()
else: # pragma: no cover
raise OperationNotSupported(f, 'to_exact')
return f.per(result)
def retract(f, field=None):
"""
Recalculate the ground domain of a polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = Poly(x**2 + 1, x, domain='QQ[y]')
>>> f
Poly(x**2 + 1, x, domain='QQ[y]')
>>> f.retract()
Poly(x**2 + 1, x, domain='ZZ')
>>> f.retract(field=True)
Poly(x**2 + 1, x, domain='QQ')
"""
dom, rep = construct_domain(f.as_dict(zero=True),
field=field, composite=f.domain.is_Composite or None)
return f.from_dict(rep, f.gens, domain=dom)
def slice(f, x, m, n=None):
"""Take a continuous subsequence of terms of ``f``. """
if n is None:
j, m, n = 0, x, m
else:
j = f._gen_to_level(x)
m, n = int(m), int(n)
if hasattr(f.rep, 'slice'):
result = f.rep.slice(m, n, j)
else: # pragma: no cover
raise OperationNotSupported(f, 'slice')
return f.per(result)
def coeffs(f, order=None):
"""
Returns all non-zero coefficients from ``f`` in lex order.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 + 2*x + 3, x).coeffs()
[1, 2, 3]
See Also
========
all_coeffs
coeff_monomial
nth
"""
return [f.rep.dom.to_sympy(c) for c in f.rep.coeffs(order=order)]
def monoms(f, order=None):
"""
Returns all non-zero monomials from ``f`` in lex order.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 2*x*y**2 + x*y + 3*y, x, y).monoms()
[(2, 0), (1, 2), (1, 1), (0, 1)]
See Also
========
all_monoms
"""
return f.rep.monoms(order=order)
def terms(f, order=None):
"""
Returns all non-zero terms from ``f`` in lex order.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 2*x*y**2 + x*y + 3*y, x, y).terms()
[((2, 0), 1), ((1, 2), 2), ((1, 1), 1), ((0, 1), 3)]
See Also
========
all_terms
"""
return [(m, f.rep.dom.to_sympy(c)) for m, c in f.rep.terms(order=order)]
def all_coeffs(f):
"""
Returns all coefficients from a univariate polynomial ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 + 2*x - 1, x).all_coeffs()
[1, 0, 2, -1]
"""
return [f.rep.dom.to_sympy(c) for c in f.rep.all_coeffs()]
def all_monoms(f):
"""
Returns all monomials from a univariate polynomial ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 + 2*x - 1, x).all_monoms()
[(3,), (2,), (1,), (0,)]
See Also
========
all_terms
"""
return f.rep.all_monoms()
def all_terms(f):
"""
Returns all terms from a univariate polynomial ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 + 2*x - 1, x).all_terms()
[((3,), 1), ((2,), 0), ((1,), 2), ((0,), -1)]
"""
return [(m, f.rep.dom.to_sympy(c)) for m, c in f.rep.all_terms()]
def termwise(f, func, *gens, **args):
"""
Apply a function to all terms of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> def func(k, coeff):
... k = k[0]
... return coeff//10**(2-k)
>>> Poly(x**2 + 20*x + 400).termwise(func)
Poly(x**2 + 2*x + 4, x, domain='ZZ')
"""
terms = {}
for monom, coeff in f.terms():
result = func(monom, coeff)
if isinstance(result, tuple):
monom, coeff = result
else:
coeff = result
if coeff:
if monom not in terms:
terms[monom] = coeff
else:
raise PolynomialError(
"%s monomial was generated twice" % monom)
return f.from_dict(terms, *(gens or f.gens), **args)
def length(f):
"""
Returns the number of non-zero terms in ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 2*x - 1).length()
3
"""
return len(f.as_dict())
def as_dict(f, native=False, zero=False):
"""
Switch to a ``dict`` representation.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 2*x*y**2 - y, x, y).as_dict()
{(0, 1): -1, (1, 2): 2, (2, 0): 1}
"""
if native:
return f.rep.to_dict(zero=zero)
else:
return f.rep.to_sympy_dict(zero=zero)
def as_list(f, native=False):
"""Switch to a ``list`` representation. """
if native:
return f.rep.to_list()
else:
return f.rep.to_sympy_list()
def as_expr(f, *gens):
"""
Convert a Poly instance to an Expr instance.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = Poly(x**2 + 2*x*y**2 - y, x, y)
>>> f.as_expr()
x**2 + 2*x*y**2 - y
>>> f.as_expr({x: 5})
10*y**2 - y + 25
>>> f.as_expr(5, 6)
379
"""
if not gens:
return f.expr
if len(gens) == 1 and isinstance(gens[0], dict):
mapping = gens[0]
gens = list(f.gens)
for gen, value in mapping.items():
try:
index = gens.index(gen)
except ValueError:
raise GeneratorsError(
"%s doesn't have %s as generator" % (f, gen))
else:
gens[index] = value
return basic_from_dict(f.rep.to_sympy_dict(), *gens)
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
"""
try:
poly = Poly(self, *gens, **args)
if not poly.is_Poly:
return None
else:
return poly
except PolynomialError:
return None
def lift(f):
"""
Convert algebraic coefficients to rationals.
Examples
========
>>> from sympy import Poly, I
>>> from sympy.abc import x
>>> Poly(x**2 + I*x + 1, x, extension=I).lift()
Poly(x**4 + 3*x**2 + 1, x, domain='QQ')
"""
if hasattr(f.rep, 'lift'):
result = f.rep.lift()
else: # pragma: no cover
raise OperationNotSupported(f, 'lift')
return f.per(result)
def deflate(f):
"""
Reduce degree of ``f`` by mapping ``x_i**m`` to ``y_i``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**6*y**2 + x**3 + 1, x, y).deflate()
((3, 2), Poly(x**2*y + x + 1, x, y, domain='ZZ'))
"""
if hasattr(f.rep, 'deflate'):
J, result = f.rep.deflate()
else: # pragma: no cover
raise OperationNotSupported(f, 'deflate')
return J, f.per(result)
def inject(f, front=False):
"""
Inject ground domain generators into ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = Poly(x**2*y + x*y**3 + x*y + 1, x)
>>> f.inject()
Poly(x**2*y + x*y**3 + x*y + 1, x, y, domain='ZZ')
>>> f.inject(front=True)
Poly(y**3*x + y*x**2 + y*x + 1, y, x, domain='ZZ')
"""
dom = f.rep.dom
if dom.is_Numerical:
return f
elif not dom.is_Poly:
raise DomainError("can't inject generators over %s" % dom)
if hasattr(f.rep, 'inject'):
result = f.rep.inject(front=front)
else: # pragma: no cover
raise OperationNotSupported(f, 'inject')
if front:
gens = dom.symbols + f.gens
else:
gens = f.gens + dom.symbols
return f.new(result, *gens)
def eject(f, *gens):
"""
Eject selected generators into the ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = Poly(x**2*y + x*y**3 + x*y + 1, x, y)
>>> f.eject(x)
Poly(x*y**3 + (x**2 + x)*y + 1, y, domain='ZZ[x]')
>>> f.eject(y)
Poly(y*x**2 + (y**3 + y)*x + 1, x, domain='ZZ[y]')
"""
dom = f.rep.dom
if not dom.is_Numerical:
raise DomainError("can't eject generators over %s" % dom)
k = len(gens)
if f.gens[:k] == gens:
_gens, front = f.gens[k:], True
elif f.gens[-k:] == gens:
_gens, front = f.gens[:-k], False
else:
raise NotImplementedError(
"can only eject front or back generators")
dom = dom.inject(*gens)
if hasattr(f.rep, 'eject'):
result = f.rep.eject(dom, front=front)
else: # pragma: no cover
raise OperationNotSupported(f, 'eject')
return f.new(result, *_gens)
def terms_gcd(f):
"""
Remove GCD of terms from the polynomial ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**6*y**2 + x**3*y, x, y).terms_gcd()
((3, 1), Poly(x**3*y + 1, x, y, domain='ZZ'))
"""
if hasattr(f.rep, 'terms_gcd'):
J, result = f.rep.terms_gcd()
else: # pragma: no cover
raise OperationNotSupported(f, 'terms_gcd')
return J, f.per(result)
def add_ground(f, coeff):
"""
Add an element of the ground domain to ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x + 1).add_ground(2)
Poly(x + 3, x, domain='ZZ')
"""
if hasattr(f.rep, 'add_ground'):
result = f.rep.add_ground(coeff)
else: # pragma: no cover
raise OperationNotSupported(f, 'add_ground')
return f.per(result)
def sub_ground(f, coeff):
"""
Subtract an element of the ground domain from ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x + 1).sub_ground(2)
Poly(x - 1, x, domain='ZZ')
"""
if hasattr(f.rep, 'sub_ground'):
result = f.rep.sub_ground(coeff)
else: # pragma: no cover
raise OperationNotSupported(f, 'sub_ground')
return f.per(result)
def mul_ground(f, coeff):
"""
Multiply ``f`` by a an element of the ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x + 1).mul_ground(2)
Poly(2*x + 2, x, domain='ZZ')
"""
if hasattr(f.rep, 'mul_ground'):
result = f.rep.mul_ground(coeff)
else: # pragma: no cover
raise OperationNotSupported(f, 'mul_ground')
return f.per(result)
def quo_ground(f, coeff):
"""
Quotient of ``f`` by a an element of the ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x + 4).quo_ground(2)
Poly(x + 2, x, domain='ZZ')
>>> Poly(2*x + 3).quo_ground(2)
Poly(x + 1, x, domain='ZZ')
"""
if hasattr(f.rep, 'quo_ground'):
result = f.rep.quo_ground(coeff)
else: # pragma: no cover
raise OperationNotSupported(f, 'quo_ground')
return f.per(result)
def exquo_ground(f, coeff):
"""
Exact quotient of ``f`` by a an element of the ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x + 4).exquo_ground(2)
Poly(x + 2, x, domain='ZZ')
>>> Poly(2*x + 3).exquo_ground(2)
Traceback (most recent call last):
...
ExactQuotientFailed: 2 does not divide 3 in ZZ
"""
if hasattr(f.rep, 'exquo_ground'):
result = f.rep.exquo_ground(coeff)
else: # pragma: no cover
raise OperationNotSupported(f, 'exquo_ground')
return f.per(result)
def abs(f):
"""
Make all coefficients in ``f`` positive.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).abs()
Poly(x**2 + 1, x, domain='ZZ')
"""
if hasattr(f.rep, 'abs'):
result = f.rep.abs()
else: # pragma: no cover
raise OperationNotSupported(f, 'abs')
return f.per(result)
def neg(f):
"""
Negate all coefficients in ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).neg()
Poly(-x**2 + 1, x, domain='ZZ')
>>> -Poly(x**2 - 1, x)
Poly(-x**2 + 1, x, domain='ZZ')
"""
if hasattr(f.rep, 'neg'):
result = f.rep.neg()
else: # pragma: no cover
raise OperationNotSupported(f, 'neg')
return f.per(result)
def add(f, g):
"""
Add two polynomials ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).add(Poly(x - 2, x))
Poly(x**2 + x - 1, x, domain='ZZ')
>>> Poly(x**2 + 1, x) + Poly(x - 2, x)
Poly(x**2 + x - 1, x, domain='ZZ')
"""
g = sympify(g)
if not g.is_Poly:
return f.add_ground(g)
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'add'):
result = F.add(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'add')
return per(result)
def sub(f, g):
"""
Subtract two polynomials ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).sub(Poly(x - 2, x))
Poly(x**2 - x + 3, x, domain='ZZ')
>>> Poly(x**2 + 1, x) - Poly(x - 2, x)
Poly(x**2 - x + 3, x, domain='ZZ')
"""
g = sympify(g)
if not g.is_Poly:
return f.sub_ground(g)
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'sub'):
result = F.sub(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'sub')
return per(result)
def mul(f, g):
"""
Multiply two polynomials ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).mul(Poly(x - 2, x))
Poly(x**3 - 2*x**2 + x - 2, x, domain='ZZ')
>>> Poly(x**2 + 1, x)*Poly(x - 2, x)
Poly(x**3 - 2*x**2 + x - 2, x, domain='ZZ')
"""
g = sympify(g)
if not g.is_Poly:
return f.mul_ground(g)
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'mul'):
result = F.mul(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'mul')
return per(result)
def sqr(f):
"""
Square a polynomial ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x - 2, x).sqr()
Poly(x**2 - 4*x + 4, x, domain='ZZ')
>>> Poly(x - 2, x)**2
Poly(x**2 - 4*x + 4, x, domain='ZZ')
"""
if hasattr(f.rep, 'sqr'):
result = f.rep.sqr()
else: # pragma: no cover
raise OperationNotSupported(f, 'sqr')
return f.per(result)
def pow(f, n):
"""
Raise ``f`` to a non-negative power ``n``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x - 2, x).pow(3)
Poly(x**3 - 6*x**2 + 12*x - 8, x, domain='ZZ')
>>> Poly(x - 2, x)**3
Poly(x**3 - 6*x**2 + 12*x - 8, x, domain='ZZ')
"""
n = int(n)
if hasattr(f.rep, 'pow'):
result = f.rep.pow(n)
else: # pragma: no cover
raise OperationNotSupported(f, 'pow')
return f.per(result)
def pdiv(f, g):
"""
Polynomial pseudo-division of ``f`` by ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).pdiv(Poly(2*x - 4, x))
(Poly(2*x + 4, x, domain='ZZ'), Poly(20, x, domain='ZZ'))
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'pdiv'):
q, r = F.pdiv(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'pdiv')
return per(q), per(r)
def prem(f, g):
"""
Polynomial pseudo-remainder of ``f`` by ``g``.
Caveat: The function prem(f, g, x) can be safely used to compute
in Z[x] _only_ subresultant polynomial remainder sequences (prs's).
To safely compute Euclidean and Sturmian prs's in Z[x]
employ anyone of the corresponding functions found in
the module sympy.polys.subresultants_qq_zz. The functions
in the module with suffix _pg compute prs's in Z[x] employing
rem(f, g, x), whereas the functions with suffix _amv
compute prs's in Z[x] employing rem_z(f, g, x).
The function rem_z(f, g, x) differs from prem(f, g, x) in that
to compute the remainder polynomials in Z[x] it premultiplies
the divident times the absolute value of the leading coefficient
of the divisor raised to the power degree(f, x) - degree(g, x) + 1.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).prem(Poly(2*x - 4, x))
Poly(20, x, domain='ZZ')
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'prem'):
result = F.prem(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'prem')
return per(result)
def pquo(f, g):
"""
Polynomial pseudo-quotient of ``f`` by ``g``.
See the Caveat note in the function prem(f, g).
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).pquo(Poly(2*x - 4, x))
Poly(2*x + 4, x, domain='ZZ')
>>> Poly(x**2 - 1, x).pquo(Poly(2*x - 2, x))
Poly(2*x + 2, x, domain='ZZ')
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'pquo'):
result = F.pquo(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'pquo')
return per(result)
def pexquo(f, g):
"""
Polynomial exact pseudo-quotient of ``f`` by ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).pexquo(Poly(2*x - 2, x))
Poly(2*x + 2, x, domain='ZZ')
>>> Poly(x**2 + 1, x).pexquo(Poly(2*x - 4, x))
Traceback (most recent call last):
...
ExactQuotientFailed: 2*x - 4 does not divide x**2 + 1
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'pexquo'):
try:
result = F.pexquo(G)
except ExactQuotientFailed as exc:
raise exc.new(f.as_expr(), g.as_expr())
else: # pragma: no cover
raise OperationNotSupported(f, 'pexquo')
return per(result)
def div(f, g, auto=True):
"""
Polynomial division with remainder of ``f`` by ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).div(Poly(2*x - 4, x))
(Poly(1/2*x + 1, x, domain='QQ'), Poly(5, x, domain='QQ'))
>>> Poly(x**2 + 1, x).div(Poly(2*x - 4, x), auto=False)
(Poly(0, x, domain='ZZ'), Poly(x**2 + 1, x, domain='ZZ'))
"""
dom, per, F, G = f._unify(g)
retract = False
if auto and dom.is_Ring and not dom.is_Field:
F, G = F.to_field(), G.to_field()
retract = True
if hasattr(f.rep, 'div'):
q, r = F.div(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'div')
if retract:
try:
Q, R = q.to_ring(), r.to_ring()
except CoercionFailed:
pass
else:
q, r = Q, R
return per(q), per(r)
def rem(f, g, auto=True):
"""
Computes the polynomial remainder of ``f`` by ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).rem(Poly(2*x - 4, x))
Poly(5, x, domain='ZZ')
>>> Poly(x**2 + 1, x).rem(Poly(2*x - 4, x), auto=False)
Poly(x**2 + 1, x, domain='ZZ')
"""
dom, per, F, G = f._unify(g)
retract = False
if auto and dom.is_Ring and not dom.is_Field:
F, G = F.to_field(), G.to_field()
retract = True
if hasattr(f.rep, 'rem'):
r = F.rem(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'rem')
if retract:
try:
r = r.to_ring()
except CoercionFailed:
pass
return per(r)
def quo(f, g, auto=True):
"""
Computes polynomial quotient of ``f`` by ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).quo(Poly(2*x - 4, x))
Poly(1/2*x + 1, x, domain='QQ')
>>> Poly(x**2 - 1, x).quo(Poly(x - 1, x))
Poly(x + 1, x, domain='ZZ')
"""
dom, per, F, G = f._unify(g)
retract = False
if auto and dom.is_Ring and not dom.is_Field:
F, G = F.to_field(), G.to_field()
retract = True
if hasattr(f.rep, 'quo'):
q = F.quo(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'quo')
if retract:
try:
q = q.to_ring()
except CoercionFailed:
pass
return per(q)
def exquo(f, g, auto=True):
"""
Computes polynomial exact quotient of ``f`` by ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).exquo(Poly(x - 1, x))
Poly(x + 1, x, domain='ZZ')
>>> Poly(x**2 + 1, x).exquo(Poly(2*x - 4, x))
Traceback (most recent call last):
...
ExactQuotientFailed: 2*x - 4 does not divide x**2 + 1
"""
dom, per, F, G = f._unify(g)
retract = False
if auto and dom.is_Ring and not dom.is_Field:
F, G = F.to_field(), G.to_field()
retract = True
if hasattr(f.rep, 'exquo'):
try:
q = F.exquo(G)
except ExactQuotientFailed as exc:
raise exc.new(f.as_expr(), g.as_expr())
else: # pragma: no cover
raise OperationNotSupported(f, 'exquo')
if retract:
try:
q = q.to_ring()
except CoercionFailed:
pass
return per(q)
def _gen_to_level(f, gen):
"""Returns level associated with the given generator. """
if isinstance(gen, int):
length = len(f.gens)
if -length <= gen < length:
if gen < 0:
return length + gen
else:
return gen
else:
raise PolynomialError("-%s <= gen < %s expected, got %s" %
(length, length, gen))
else:
try:
return f.gens.index(sympify(gen))
except ValueError:
raise PolynomialError(
"a valid generator expected, got %s" % gen)
def degree(f, gen=0):
"""
Returns degree of ``f`` in ``x_j``.
The degree of 0 is negative infinity.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + y*x + 1, x, y).degree()
2
>>> Poly(x**2 + y*x + y, x, y).degree(y)
1
>>> Poly(0, x).degree()
-oo
"""
j = f._gen_to_level(gen)
if hasattr(f.rep, 'degree'):
return f.rep.degree(j)
else: # pragma: no cover
raise OperationNotSupported(f, 'degree')
def degree_list(f):
"""
Returns a list of degrees of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + y*x + 1, x, y).degree_list()
(2, 1)
"""
if hasattr(f.rep, 'degree_list'):
return f.rep.degree_list()
else: # pragma: no cover
raise OperationNotSupported(f, 'degree_list')
def total_degree(f):
"""
Returns the total degree of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + y*x + 1, x, y).total_degree()
2
>>> Poly(x + y**5, x, y).total_degree()
5
"""
if hasattr(f.rep, 'total_degree'):
return f.rep.total_degree()
else: # pragma: no cover
raise OperationNotSupported(f, 'total_degree')
def homogenize(f, s):
"""
Returns the homogeneous polynomial of ``f``.
A homogeneous polynomial is a polynomial whose all monomials with
non-zero coefficients have the same total degree. If you only
want to check if a polynomial is homogeneous, then use
:func:`Poly.is_homogeneous`. If you want not only to check if a
polynomial is homogeneous but also compute its homogeneous order,
then use :func:`Poly.homogeneous_order`.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y, z
>>> f = Poly(x**5 + 2*x**2*y**2 + 9*x*y**3)
>>> f.homogenize(z)
Poly(x**5 + 2*x**2*y**2*z + 9*x*y**3*z, x, y, z, domain='ZZ')
"""
if not isinstance(s, Symbol):
raise TypeError("``Symbol`` expected, got %s" % type(s))
if s in f.gens:
i = f.gens.index(s)
gens = f.gens
else:
i = len(f.gens)
gens = f.gens + (s,)
if hasattr(f.rep, 'homogenize'):
return f.per(f.rep.homogenize(i), gens=gens)
raise OperationNotSupported(f, 'homogeneous_order')
def homogeneous_order(f):
"""
Returns the homogeneous order of ``f``.
A homogeneous polynomial is a polynomial whose all monomials with
non-zero coefficients have the same total degree. This degree is
the homogeneous order of ``f``. If you only want to check if a
polynomial is homogeneous, then use :func:`Poly.is_homogeneous`.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = Poly(x**5 + 2*x**3*y**2 + 9*x*y**4)
>>> f.homogeneous_order()
5
"""
if hasattr(f.rep, 'homogeneous_order'):
return f.rep.homogeneous_order()
else: # pragma: no cover
raise OperationNotSupported(f, 'homogeneous_order')
def LC(f, order=None):
"""
Returns the leading coefficient of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(4*x**3 + 2*x**2 + 3*x, x).LC()
4
"""
if order is not None:
return f.coeffs(order)[0]
if hasattr(f.rep, 'LC'):
result = f.rep.LC()
else: # pragma: no cover
raise OperationNotSupported(f, 'LC')
return f.rep.dom.to_sympy(result)
def TC(f):
"""
Returns the trailing coefficient of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 + 2*x**2 + 3*x, x).TC()
0
"""
if hasattr(f.rep, 'TC'):
result = f.rep.TC()
else: # pragma: no cover
raise OperationNotSupported(f, 'TC')
return f.rep.dom.to_sympy(result)
def EC(f, order=None):
"""
Returns the last non-zero coefficient of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 + 2*x**2 + 3*x, x).EC()
3
"""
if hasattr(f.rep, 'coeffs'):
return f.coeffs(order)[-1]
else: # pragma: no cover
raise OperationNotSupported(f, 'EC')
def coeff_monomial(f, monom):
"""
Returns the coefficient of ``monom`` in ``f`` if there, else None.
Examples
========
>>> from sympy import Poly, exp
>>> from sympy.abc import x, y
>>> p = Poly(24*x*y*exp(8) + 23*x, x, y)
>>> p.coeff_monomial(x)
23
>>> p.coeff_monomial(y)
0
>>> p.coeff_monomial(x*y)
24*exp(8)
Note that ``Expr.coeff()`` behaves differently, collecting terms
if possible; the Poly must be converted to an Expr to use that
method, however:
>>> p.as_expr().coeff(x)
24*y*exp(8) + 23
>>> p.as_expr().coeff(y)
24*x*exp(8)
>>> p.as_expr().coeff(x*y)
24*exp(8)
See Also
========
nth: more efficient query using exponents of the monomial's generators
"""
return f.nth(*Monomial(monom, f.gens).exponents)
def nth(f, *N):
"""
Returns the ``n``-th coefficient of ``f`` where ``N`` are the
exponents of the generators in the term of interest.
Examples
========
>>> from sympy import Poly, sqrt
>>> from sympy.abc import x, y
>>> Poly(x**3 + 2*x**2 + 3*x, x).nth(2)
2
>>> Poly(x**3 + 2*x*y**2 + y**2, x, y).nth(1, 2)
2
>>> Poly(4*sqrt(x)*y)
Poly(4*y*(sqrt(x)), y, sqrt(x), domain='ZZ')
>>> _.nth(1, 1)
4
See Also
========
coeff_monomial
"""
if hasattr(f.rep, 'nth'):
if len(N) != len(f.gens):
raise ValueError('exponent of each generator must be specified')
result = f.rep.nth(*list(map(int, N)))
else: # pragma: no cover
raise OperationNotSupported(f, 'nth')
return f.rep.dom.to_sympy(result)
def coeff(f, x, n=1, right=False):
# the semantics of coeff_monomial and Expr.coeff are different;
# if someone is working with a Poly, they should be aware of the
# differences and chose the method best suited for the query.
# Alternatively, a pure-polys method could be written here but
# at this time the ``right`` keyword would be ignored because Poly
# doesn't work with non-commutatives.
raise NotImplementedError(
'Either convert to Expr with `as_expr` method '
'to use Expr\'s coeff method or else use the '
'`coeff_monomial` method of Polys.')
def LM(f, order=None):
"""
Returns the leading monomial of ``f``.
The Leading monomial signifies the monomial having
the highest power of the principal generator in the
expression f.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(4*x**2 + 2*x*y**2 + x*y + 3*y, x, y).LM()
x**2*y**0
"""
return Monomial(f.monoms(order)[0], f.gens)
def EM(f, order=None):
"""
Returns the last non-zero monomial of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(4*x**2 + 2*x*y**2 + x*y + 3*y, x, y).EM()
x**0*y**1
"""
return Monomial(f.monoms(order)[-1], f.gens)
def LT(f, order=None):
"""
Returns the leading term of ``f``.
The Leading term signifies the term having
the highest power of the principal generator in the
expression f along with its coefficient.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(4*x**2 + 2*x*y**2 + x*y + 3*y, x, y).LT()
(x**2*y**0, 4)
"""
monom, coeff = f.terms(order)[0]
return Monomial(monom, f.gens), coeff
def ET(f, order=None):
"""
Returns the last non-zero term of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(4*x**2 + 2*x*y**2 + x*y + 3*y, x, y).ET()
(x**0*y**1, 3)
"""
monom, coeff = f.terms(order)[-1]
return Monomial(monom, f.gens), coeff
def max_norm(f):
"""
Returns maximum norm of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(-x**2 + 2*x - 3, x).max_norm()
3
"""
if hasattr(f.rep, 'max_norm'):
result = f.rep.max_norm()
else: # pragma: no cover
raise OperationNotSupported(f, 'max_norm')
return f.rep.dom.to_sympy(result)
def l1_norm(f):
"""
Returns l1 norm of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(-x**2 + 2*x - 3, x).l1_norm()
6
"""
if hasattr(f.rep, 'l1_norm'):
result = f.rep.l1_norm()
else: # pragma: no cover
raise OperationNotSupported(f, 'l1_norm')
return f.rep.dom.to_sympy(result)
def clear_denoms(self, convert=False):
"""
Clear denominators, but keep the ground domain.
Examples
========
>>> from sympy import Poly, S, QQ
>>> from sympy.abc import x
>>> f = Poly(x/2 + S(1)/3, x, domain=QQ)
>>> f.clear_denoms()
(6, Poly(3*x + 2, x, domain='QQ'))
>>> f.clear_denoms(convert=True)
(6, Poly(3*x + 2, x, domain='ZZ'))
"""
f = self
if not f.rep.dom.is_Field:
return S.One, f
dom = f.get_domain()
if dom.has_assoc_Ring:
dom = f.rep.dom.get_ring()
if hasattr(f.rep, 'clear_denoms'):
coeff, result = f.rep.clear_denoms()
else: # pragma: no cover
raise OperationNotSupported(f, 'clear_denoms')
coeff, f = dom.to_sympy(coeff), f.per(result)
if not convert or not dom.has_assoc_Ring:
return coeff, f
else:
return coeff, f.to_ring()
def rat_clear_denoms(self, g):
"""
Clear denominators in a rational function ``f/g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = Poly(x**2/y + 1, x)
>>> g = Poly(x**3 + y, x)
>>> p, q = f.rat_clear_denoms(g)
>>> p
Poly(x**2 + y, x, domain='ZZ[y]')
>>> q
Poly(y*x**3 + y**2, x, domain='ZZ[y]')
"""
f = self
dom, per, f, g = f._unify(g)
f = per(f)
g = per(g)
if not (dom.is_Field and dom.has_assoc_Ring):
return f, g
a, f = f.clear_denoms(convert=True)
b, g = g.clear_denoms(convert=True)
f = f.mul_ground(b)
g = g.mul_ground(a)
return f, g
def integrate(self, *specs, **args):
"""
Computes indefinite integral of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 2*x + 1, x).integrate()
Poly(1/3*x**3 + x**2 + x, x, domain='QQ')
>>> Poly(x*y**2 + x, x, y).integrate((0, 1), (1, 0))
Poly(1/2*x**2*y**2 + 1/2*x**2, x, y, domain='QQ')
"""
f = self
if args.get('auto', True) and f.rep.dom.is_Ring:
f = f.to_field()
if hasattr(f.rep, 'integrate'):
if not specs:
return f.per(f.rep.integrate(m=1))
rep = f.rep
for spec in specs:
if type(spec) is tuple:
gen, m = spec
else:
gen, m = spec, 1
rep = rep.integrate(int(m), f._gen_to_level(gen))
return f.per(rep)
else: # pragma: no cover
raise OperationNotSupported(f, 'integrate')
def diff(f, *specs, **kwargs):
"""
Computes partial derivative of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + 2*x + 1, x).diff()
Poly(2*x + 2, x, domain='ZZ')
>>> Poly(x*y**2 + x, x, y).diff((0, 0), (1, 1))
Poly(2*x*y, x, y, domain='ZZ')
"""
if not kwargs.get('evaluate', True):
return Derivative(f, *specs, **kwargs)
if hasattr(f.rep, 'diff'):
if not specs:
return f.per(f.rep.diff(m=1))
rep = f.rep
for spec in specs:
if type(spec) is tuple:
gen, m = spec
else:
gen, m = spec, 1
rep = rep.diff(int(m), f._gen_to_level(gen))
return f.per(rep)
else: # pragma: no cover
raise OperationNotSupported(f, 'diff')
_eval_derivative = diff
def eval(self, x, a=None, auto=True):
"""
Evaluate ``f`` at ``a`` in the given variable.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y, z
>>> Poly(x**2 + 2*x + 3, x).eval(2)
11
>>> Poly(2*x*y + 3*x + y + 2, x, y).eval(x, 2)
Poly(5*y + 8, y, domain='ZZ')
>>> f = Poly(2*x*y + 3*x + y + 2*z, x, y, z)
>>> f.eval({x: 2})
Poly(5*y + 2*z + 6, y, z, domain='ZZ')
>>> f.eval({x: 2, y: 5})
Poly(2*z + 31, z, domain='ZZ')
>>> f.eval({x: 2, y: 5, z: 7})
45
>>> f.eval((2, 5))
Poly(2*z + 31, z, domain='ZZ')
>>> f(2, 5)
Poly(2*z + 31, z, domain='ZZ')
"""
f = self
if a is None:
if isinstance(x, dict):
mapping = x
for gen, value in mapping.items():
f = f.eval(gen, value)
return f
elif isinstance(x, (tuple, list)):
values = x
if len(values) > len(f.gens):
raise ValueError("too many values provided")
for gen, value in zip(f.gens, values):
f = f.eval(gen, value)
return f
else:
j, a = 0, x
else:
j = f._gen_to_level(x)
if not hasattr(f.rep, 'eval'): # pragma: no cover
raise OperationNotSupported(f, 'eval')
try:
result = f.rep.eval(a, j)
except CoercionFailed:
if not auto:
raise DomainError("can't evaluate at %s in %s" % (a, f.rep.dom))
else:
a_domain, [a] = construct_domain([a])
new_domain = f.get_domain().unify_with_symbols(a_domain, f.gens)
f = f.set_domain(new_domain)
a = new_domain.convert(a, a_domain)
result = f.rep.eval(a, j)
return f.per(result, remove=j)
def __call__(f, *values):
"""
Evaluate ``f`` at the give values.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y, z
>>> f = Poly(2*x*y + 3*x + y + 2*z, x, y, z)
>>> f(2)
Poly(5*y + 2*z + 6, y, z, domain='ZZ')
>>> f(2, 5)
Poly(2*z + 31, z, domain='ZZ')
>>> f(2, 5, 7)
45
"""
return f.eval(values)
def half_gcdex(f, g, auto=True):
"""
Half extended Euclidean algorithm of ``f`` and ``g``.
Returns ``(s, h)`` such that ``h = gcd(f, g)`` and ``s*f = h (mod g)``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = x**4 - 2*x**3 - 6*x**2 + 12*x + 15
>>> g = x**3 + x**2 - 4*x - 4
>>> Poly(f).half_gcdex(Poly(g))
(Poly(-1/5*x + 3/5, x, domain='QQ'), Poly(x + 1, x, domain='QQ'))
"""
dom, per, F, G = f._unify(g)
if auto and dom.is_Ring:
F, G = F.to_field(), G.to_field()
if hasattr(f.rep, 'half_gcdex'):
s, h = F.half_gcdex(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'half_gcdex')
return per(s), per(h)
def gcdex(f, g, auto=True):
"""
Extended Euclidean algorithm of ``f`` and ``g``.
Returns ``(s, t, h)`` such that ``h = gcd(f, g)`` and ``s*f + t*g = h``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = x**4 - 2*x**3 - 6*x**2 + 12*x + 15
>>> g = x**3 + x**2 - 4*x - 4
>>> Poly(f).gcdex(Poly(g))
(Poly(-1/5*x + 3/5, x, domain='QQ'),
Poly(1/5*x**2 - 6/5*x + 2, x, domain='QQ'),
Poly(x + 1, x, domain='QQ'))
"""
dom, per, F, G = f._unify(g)
if auto and dom.is_Ring:
F, G = F.to_field(), G.to_field()
if hasattr(f.rep, 'gcdex'):
s, t, h = F.gcdex(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'gcdex')
return per(s), per(t), per(h)
def invert(f, g, auto=True):
"""
Invert ``f`` modulo ``g`` when possible.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).invert(Poly(2*x - 1, x))
Poly(-4/3, x, domain='QQ')
>>> Poly(x**2 - 1, x).invert(Poly(x - 1, x))
Traceback (most recent call last):
...
NotInvertible: zero divisor
"""
dom, per, F, G = f._unify(g)
if auto and dom.is_Ring:
F, G = F.to_field(), G.to_field()
if hasattr(f.rep, 'invert'):
result = F.invert(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'invert')
return per(result)
def revert(f, n):
"""
Compute ``f**(-1)`` mod ``x**n``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(1, x).revert(2)
Poly(1, x, domain='ZZ')
>>> Poly(1 + x, x).revert(1)
Poly(1, x, domain='ZZ')
>>> Poly(x**2 - 1, x).revert(1)
Traceback (most recent call last):
...
NotReversible: only unity is reversible in a ring
>>> Poly(1/x, x).revert(1)
Traceback (most recent call last):
...
PolynomialError: 1/x contains an element of the generators set
"""
if hasattr(f.rep, 'revert'):
result = f.rep.revert(int(n))
else: # pragma: no cover
raise OperationNotSupported(f, 'revert')
return f.per(result)
def subresultants(f, g):
"""
Computes the subresultant PRS of ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 1, x).subresultants(Poly(x**2 - 1, x))
[Poly(x**2 + 1, x, domain='ZZ'),
Poly(x**2 - 1, x, domain='ZZ'),
Poly(-2, x, domain='ZZ')]
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'subresultants'):
result = F.subresultants(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'subresultants')
return list(map(per, result))
def resultant(f, g, includePRS=False):
"""
Computes the resultant of ``f`` and ``g`` via PRS.
If includePRS=True, it includes the subresultant PRS in the result.
Because the PRS is used to calculate the resultant, this is more
efficient than calling :func:`subresultants` separately.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = Poly(x**2 + 1, x)
>>> f.resultant(Poly(x**2 - 1, x))
4
>>> f.resultant(Poly(x**2 - 1, x), includePRS=True)
(4, [Poly(x**2 + 1, x, domain='ZZ'), Poly(x**2 - 1, x, domain='ZZ'),
Poly(-2, x, domain='ZZ')])
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'resultant'):
if includePRS:
result, R = F.resultant(G, includePRS=includePRS)
else:
result = F.resultant(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'resultant')
if includePRS:
return (per(result, remove=0), list(map(per, R)))
return per(result, remove=0)
def discriminant(f):
"""
Computes the discriminant of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + 2*x + 3, x).discriminant()
-8
"""
if hasattr(f.rep, 'discriminant'):
result = f.rep.discriminant()
else: # pragma: no cover
raise OperationNotSupported(f, 'discriminant')
return f.per(result, remove=0)
def dispersionset(f, g=None):
r"""Compute the *dispersion set* of two polynomials.
For two polynomials `f(x)` and `g(x)` with `\deg f > 0`
and `\deg g > 0` the dispersion set `\operatorname{J}(f, g)` is defined as:
.. math::
\operatorname{J}(f, g)
& := \{a \in \mathbb{N}_0 | \gcd(f(x), g(x+a)) \neq 1\} \\
& = \{a \in \mathbb{N}_0 | \deg \gcd(f(x), g(x+a)) \geq 1\}
For a single polynomial one defines `\operatorname{J}(f) := \operatorname{J}(f, f)`.
Examples
========
>>> from sympy import poly
>>> from sympy.polys.dispersion import dispersion, dispersionset
>>> from sympy.abc import x
Dispersion set and dispersion of a simple polynomial:
>>> fp = poly((x - 3)*(x + 3), x)
>>> sorted(dispersionset(fp))
[0, 6]
>>> dispersion(fp)
6
Note that the definition of the dispersion is not symmetric:
>>> fp = poly(x**4 - 3*x**2 + 1, x)
>>> gp = fp.shift(-3)
>>> sorted(dispersionset(fp, gp))
[2, 3, 4]
>>> dispersion(fp, gp)
4
>>> sorted(dispersionset(gp, fp))
[]
>>> dispersion(gp, fp)
-oo
Computing the dispersion also works over field extensions:
>>> from sympy import sqrt
>>> fp = poly(x**2 + sqrt(5)*x - 1, x, domain='QQ<sqrt(5)>')
>>> gp = poly(x**2 + (2 + sqrt(5))*x + sqrt(5), x, domain='QQ<sqrt(5)>')
>>> sorted(dispersionset(fp, gp))
[2]
>>> sorted(dispersionset(gp, fp))
[1, 4]
We can even perform the computations for polynomials
having symbolic coefficients:
>>> from sympy.abc import a
>>> fp = poly(4*x**4 + (4*a + 8)*x**3 + (a**2 + 6*a + 4)*x**2 + (a**2 + 2*a)*x, x)
>>> sorted(dispersionset(fp))
[0, 1]
See Also
========
dispersion
References
==========
1. [ManWright94]_
2. [Koepf98]_
3. [Abramov71]_
4. [Man93]_
"""
from sympy.polys.dispersion import dispersionset
return dispersionset(f, g)
def dispersion(f, g=None):
r"""Compute the *dispersion* of polynomials.
For two polynomials `f(x)` and `g(x)` with `\deg f > 0`
and `\deg g > 0` the dispersion `\operatorname{dis}(f, g)` is defined as:
.. math::
\operatorname{dis}(f, g)
& := \max\{ J(f,g) \cup \{0\} \} \\
& = \max\{ \{a \in \mathbb{N} | \gcd(f(x), g(x+a)) \neq 1\} \cup \{0\} \}
and for a single polynomial `\operatorname{dis}(f) := \operatorname{dis}(f, f)`.
Examples
========
>>> from sympy import poly
>>> from sympy.polys.dispersion import dispersion, dispersionset
>>> from sympy.abc import x
Dispersion set and dispersion of a simple polynomial:
>>> fp = poly((x - 3)*(x + 3), x)
>>> sorted(dispersionset(fp))
[0, 6]
>>> dispersion(fp)
6
Note that the definition of the dispersion is not symmetric:
>>> fp = poly(x**4 - 3*x**2 + 1, x)
>>> gp = fp.shift(-3)
>>> sorted(dispersionset(fp, gp))
[2, 3, 4]
>>> dispersion(fp, gp)
4
>>> sorted(dispersionset(gp, fp))
[]
>>> dispersion(gp, fp)
-oo
Computing the dispersion also works over field extensions:
>>> from sympy import sqrt
>>> fp = poly(x**2 + sqrt(5)*x - 1, x, domain='QQ<sqrt(5)>')
>>> gp = poly(x**2 + (2 + sqrt(5))*x + sqrt(5), x, domain='QQ<sqrt(5)>')
>>> sorted(dispersionset(fp, gp))
[2]
>>> sorted(dispersionset(gp, fp))
[1, 4]
We can even perform the computations for polynomials
having symbolic coefficients:
>>> from sympy.abc import a
>>> fp = poly(4*x**4 + (4*a + 8)*x**3 + (a**2 + 6*a + 4)*x**2 + (a**2 + 2*a)*x, x)
>>> sorted(dispersionset(fp))
[0, 1]
See Also
========
dispersionset
References
==========
1. [ManWright94]_
2. [Koepf98]_
3. [Abramov71]_
4. [Man93]_
"""
from sympy.polys.dispersion import dispersion
return dispersion(f, g)
def cofactors(f, g):
"""
Returns the GCD of ``f`` and ``g`` and their cofactors.
Returns polynomials ``(h, cff, cfg)`` such that ``h = gcd(f, g)``, and
``cff = quo(f, h)`` and ``cfg = quo(g, h)`` are, so called, cofactors
of ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).cofactors(Poly(x**2 - 3*x + 2, x))
(Poly(x - 1, x, domain='ZZ'),
Poly(x + 1, x, domain='ZZ'),
Poly(x - 2, x, domain='ZZ'))
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'cofactors'):
h, cff, cfg = F.cofactors(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'cofactors')
return per(h), per(cff), per(cfg)
def gcd(f, g):
"""
Returns the polynomial GCD of ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).gcd(Poly(x**2 - 3*x + 2, x))
Poly(x - 1, x, domain='ZZ')
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'gcd'):
result = F.gcd(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'gcd')
return per(result)
def lcm(f, g):
"""
Returns polynomial LCM of ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 1, x).lcm(Poly(x**2 - 3*x + 2, x))
Poly(x**3 - 2*x**2 - x + 2, x, domain='ZZ')
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'lcm'):
result = F.lcm(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'lcm')
return per(result)
def trunc(f, p):
"""
Reduce ``f`` modulo a constant ``p``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x**3 + 3*x**2 + 5*x + 7, x).trunc(3)
Poly(-x**3 - x + 1, x, domain='ZZ')
"""
p = f.rep.dom.convert(p)
if hasattr(f.rep, 'trunc'):
result = f.rep.trunc(p)
else: # pragma: no cover
raise OperationNotSupported(f, 'trunc')
return f.per(result)
def monic(self, auto=True):
"""
Divides all coefficients by ``LC(f)``.
Examples
========
>>> from sympy import Poly, ZZ
>>> from sympy.abc import x
>>> Poly(3*x**2 + 6*x + 9, x, domain=ZZ).monic()
Poly(x**2 + 2*x + 3, x, domain='QQ')
>>> Poly(3*x**2 + 4*x + 2, x, domain=ZZ).monic()
Poly(x**2 + 4/3*x + 2/3, x, domain='QQ')
"""
f = self
if auto and f.rep.dom.is_Ring:
f = f.to_field()
if hasattr(f.rep, 'monic'):
result = f.rep.monic()
else: # pragma: no cover
raise OperationNotSupported(f, 'monic')
return f.per(result)
def content(f):
"""
Returns the GCD of polynomial coefficients.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(6*x**2 + 8*x + 12, x).content()
2
"""
if hasattr(f.rep, 'content'):
result = f.rep.content()
else: # pragma: no cover
raise OperationNotSupported(f, 'content')
return f.rep.dom.to_sympy(result)
def primitive(f):
"""
Returns the content and a primitive form of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x**2 + 8*x + 12, x).primitive()
(2, Poly(x**2 + 4*x + 6, x, domain='ZZ'))
"""
if hasattr(f.rep, 'primitive'):
cont, result = f.rep.primitive()
else: # pragma: no cover
raise OperationNotSupported(f, 'primitive')
return f.rep.dom.to_sympy(cont), f.per(result)
def compose(f, g):
"""
Computes the functional composition of ``f`` and ``g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + x, x).compose(Poly(x - 1, x))
Poly(x**2 - x, x, domain='ZZ')
"""
_, per, F, G = f._unify(g)
if hasattr(f.rep, 'compose'):
result = F.compose(G)
else: # pragma: no cover
raise OperationNotSupported(f, 'compose')
return per(result)
def decompose(f):
"""
Computes a functional decomposition of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**4 + 2*x**3 - x - 1, x, domain='ZZ').decompose()
[Poly(x**2 - x - 1, x, domain='ZZ'), Poly(x**2 + x, x, domain='ZZ')]
"""
if hasattr(f.rep, 'decompose'):
result = f.rep.decompose()
else: # pragma: no cover
raise OperationNotSupported(f, 'decompose')
return list(map(f.per, result))
def shift(f, a):
"""
Efficiently compute Taylor shift ``f(x + a)``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 2*x + 1, x).shift(2)
Poly(x**2 + 2*x + 1, x, domain='ZZ')
"""
if hasattr(f.rep, 'shift'):
result = f.rep.shift(a)
else: # pragma: no cover
raise OperationNotSupported(f, 'shift')
return f.per(result)
def transform(f, p, q):
"""
Efficiently evaluate the functional transformation ``q**n * f(p/q)``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 2*x + 1, x).transform(Poly(x + 1, x), Poly(x - 1, x))
Poly(4, x, domain='ZZ')
"""
P, Q = p.unify(q)
F, P = f.unify(P)
F, Q = F.unify(Q)
if hasattr(F.rep, 'transform'):
result = F.rep.transform(P.rep, Q.rep)
else: # pragma: no cover
raise OperationNotSupported(F, 'transform')
return F.per(result)
def sturm(self, auto=True):
"""
Computes the Sturm sequence of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 - 2*x**2 + x - 3, x).sturm()
[Poly(x**3 - 2*x**2 + x - 3, x, domain='QQ'),
Poly(3*x**2 - 4*x + 1, x, domain='QQ'),
Poly(2/9*x + 25/9, x, domain='QQ'),
Poly(-2079/4, x, domain='QQ')]
"""
f = self
if auto and f.rep.dom.is_Ring:
f = f.to_field()
if hasattr(f.rep, 'sturm'):
result = f.rep.sturm()
else: # pragma: no cover
raise OperationNotSupported(f, 'sturm')
return list(map(f.per, result))
def gff_list(f):
"""
Computes greatest factorial factorization of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = x**5 + 2*x**4 - x**3 - 2*x**2
>>> Poly(f).gff_list()
[(Poly(x, x, domain='ZZ'), 1), (Poly(x + 2, x, domain='ZZ'), 4)]
"""
if hasattr(f.rep, 'gff_list'):
result = f.rep.gff_list()
else: # pragma: no cover
raise OperationNotSupported(f, 'gff_list')
return [(f.per(g), k) for g, k in result]
def norm(f):
"""
Computes the product, ``Norm(f)``, of the conjugates of
a polynomial ``f`` defined over a number field ``K``.
Examples
========
>>> from sympy import Poly, sqrt
>>> from sympy.abc import x
>>> a, b = sqrt(2), sqrt(3)
A polynomial over a quadratic extension.
Two conjugates x - a and x + a.
>>> f = Poly(x - a, x, extension=a)
>>> f.norm()
Poly(x**2 - 2, x, domain='QQ')
A polynomial over a quartic extension.
Four conjugates x - a, x - a, x + a and x + a.
>>> f = Poly(x - a, x, extension=(a, b))
>>> f.norm()
Poly(x**4 - 4*x**2 + 4, x, domain='QQ')
"""
if hasattr(f.rep, 'norm'):
r = f.rep.norm()
else: # pragma: no cover
raise OperationNotSupported(f, 'norm')
return f.per(r)
def sqf_norm(f):
"""
Computes square-free norm of ``f``.
Returns ``s``, ``f``, ``r``, such that ``g(x) = f(x-sa)`` and
``r(x) = Norm(g(x))`` is a square-free polynomial over ``K``,
where ``a`` is the algebraic extension of the ground domain.
Examples
========
>>> from sympy import Poly, sqrt
>>> from sympy.abc import x
>>> s, f, r = Poly(x**2 + 1, x, extension=[sqrt(3)]).sqf_norm()
>>> s
1
>>> f
Poly(x**2 - 2*sqrt(3)*x + 4, x, domain='QQ<sqrt(3)>')
>>> r
Poly(x**4 - 4*x**2 + 16, x, domain='QQ')
"""
if hasattr(f.rep, 'sqf_norm'):
s, g, r = f.rep.sqf_norm()
else: # pragma: no cover
raise OperationNotSupported(f, 'sqf_norm')
return s, f.per(g), f.per(r)
def sqf_part(f):
"""
Computes square-free part of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**3 - 3*x - 2, x).sqf_part()
Poly(x**2 - x - 2, x, domain='ZZ')
"""
if hasattr(f.rep, 'sqf_part'):
result = f.rep.sqf_part()
else: # pragma: no cover
raise OperationNotSupported(f, 'sqf_part')
return f.per(result)
def sqf_list(f, all=False):
"""
Returns a list of square-free factors of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = 2*x**5 + 16*x**4 + 50*x**3 + 76*x**2 + 56*x + 16
>>> Poly(f).sqf_list()
(2, [(Poly(x + 1, x, domain='ZZ'), 2),
(Poly(x + 2, x, domain='ZZ'), 3)])
>>> Poly(f).sqf_list(all=True)
(2, [(Poly(1, x, domain='ZZ'), 1),
(Poly(x + 1, x, domain='ZZ'), 2),
(Poly(x + 2, x, domain='ZZ'), 3)])
"""
if hasattr(f.rep, 'sqf_list'):
coeff, factors = f.rep.sqf_list(all)
else: # pragma: no cover
raise OperationNotSupported(f, 'sqf_list')
return f.rep.dom.to_sympy(coeff), [(f.per(g), k) for g, k in factors]
def sqf_list_include(f, all=False):
"""
Returns a list of square-free factors of ``f``.
Examples
========
>>> from sympy import Poly, expand
>>> from sympy.abc import x
>>> f = expand(2*(x + 1)**3*x**4)
>>> f
2*x**7 + 6*x**6 + 6*x**5 + 2*x**4
>>> Poly(f).sqf_list_include()
[(Poly(2, x, domain='ZZ'), 1),
(Poly(x + 1, x, domain='ZZ'), 3),
(Poly(x, x, domain='ZZ'), 4)]
>>> Poly(f).sqf_list_include(all=True)
[(Poly(2, x, domain='ZZ'), 1),
(Poly(1, x, domain='ZZ'), 2),
(Poly(x + 1, x, domain='ZZ'), 3),
(Poly(x, x, domain='ZZ'), 4)]
"""
if hasattr(f.rep, 'sqf_list_include'):
factors = f.rep.sqf_list_include(all)
else: # pragma: no cover
raise OperationNotSupported(f, 'sqf_list_include')
return [(f.per(g), k) for g, k in factors]
def factor_list(f):
"""
Returns a list of irreducible factors of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = 2*x**5 + 2*x**4*y + 4*x**3 + 4*x**2*y + 2*x + 2*y
>>> Poly(f).factor_list()
(2, [(Poly(x + y, x, y, domain='ZZ'), 1),
(Poly(x**2 + 1, x, y, domain='ZZ'), 2)])
"""
if hasattr(f.rep, 'factor_list'):
try:
coeff, factors = f.rep.factor_list()
except DomainError:
return S.One, [(f, 1)]
else: # pragma: no cover
raise OperationNotSupported(f, 'factor_list')
return f.rep.dom.to_sympy(coeff), [(f.per(g), k) for g, k in factors]
def factor_list_include(f):
"""
Returns a list of irreducible factors of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> f = 2*x**5 + 2*x**4*y + 4*x**3 + 4*x**2*y + 2*x + 2*y
>>> Poly(f).factor_list_include()
[(Poly(2*x + 2*y, x, y, domain='ZZ'), 1),
(Poly(x**2 + 1, x, y, domain='ZZ'), 2)]
"""
if hasattr(f.rep, 'factor_list_include'):
try:
factors = f.rep.factor_list_include()
except DomainError:
return [(f, 1)]
else: # pragma: no cover
raise OperationNotSupported(f, 'factor_list_include')
return [(f.per(g), k) for g, k in factors]
def intervals(f, all=False, eps=None, inf=None, sup=None, fast=False, sqf=False):
"""
Compute isolating intervals for roots of ``f``.
For real roots the Vincent-Akritas-Strzebonski (VAS) continued fractions method is used.
References
==========
.. [#] Alkiviadis G. Akritas and Adam W. Strzebonski: A Comparative Study of Two Real Root
Isolation Methods . Nonlinear Analysis: Modelling and Control, Vol. 10, No. 4, 297-304, 2005.
.. [#] Alkiviadis G. Akritas, Adam W. Strzebonski and Panagiotis S. Vigklas: Improving the
Performance of the Continued Fractions Method Using new Bounds of Positive Roots. Nonlinear
Analysis: Modelling and Control, Vol. 13, No. 3, 265-279, 2008.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 3, x).intervals()
[((-2, -1), 1), ((1, 2), 1)]
>>> Poly(x**2 - 3, x).intervals(eps=1e-2)
[((-26/15, -19/11), 1), ((19/11, 26/15), 1)]
"""
if eps is not None:
eps = QQ.convert(eps)
if eps <= 0:
raise ValueError("'eps' must be a positive rational")
if inf is not None:
inf = QQ.convert(inf)
if sup is not None:
sup = QQ.convert(sup)
if hasattr(f.rep, 'intervals'):
result = f.rep.intervals(
all=all, eps=eps, inf=inf, sup=sup, fast=fast, sqf=sqf)
else: # pragma: no cover
raise OperationNotSupported(f, 'intervals')
if sqf:
def _real(interval):
s, t = interval
return (QQ.to_sympy(s), QQ.to_sympy(t))
if not all:
return list(map(_real, result))
def _complex(rectangle):
(u, v), (s, t) = rectangle
return (QQ.to_sympy(u) + I*QQ.to_sympy(v),
QQ.to_sympy(s) + I*QQ.to_sympy(t))
real_part, complex_part = result
return list(map(_real, real_part)), list(map(_complex, complex_part))
else:
def _real(interval):
(s, t), k = interval
return ((QQ.to_sympy(s), QQ.to_sympy(t)), k)
if not all:
return list(map(_real, result))
def _complex(rectangle):
((u, v), (s, t)), k = rectangle
return ((QQ.to_sympy(u) + I*QQ.to_sympy(v),
QQ.to_sympy(s) + I*QQ.to_sympy(t)), k)
real_part, complex_part = result
return list(map(_real, real_part)), list(map(_complex, complex_part))
def refine_root(f, s, t, eps=None, steps=None, fast=False, check_sqf=False):
"""
Refine an isolating interval of a root to the given precision.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 3, x).refine_root(1, 2, eps=1e-2)
(19/11, 26/15)
"""
if check_sqf and not f.is_sqf:
raise PolynomialError("only square-free polynomials supported")
s, t = QQ.convert(s), QQ.convert(t)
if eps is not None:
eps = QQ.convert(eps)
if eps <= 0:
raise ValueError("'eps' must be a positive rational")
if steps is not None:
steps = int(steps)
elif eps is None:
steps = 1
if hasattr(f.rep, 'refine_root'):
S, T = f.rep.refine_root(s, t, eps=eps, steps=steps, fast=fast)
else: # pragma: no cover
raise OperationNotSupported(f, 'refine_root')
return QQ.to_sympy(S), QQ.to_sympy(T)
def count_roots(f, inf=None, sup=None):
"""
Return the number of roots of ``f`` in ``[inf, sup]`` interval.
Examples
========
>>> from sympy import Poly, I
>>> from sympy.abc import x
>>> Poly(x**4 - 4, x).count_roots(-3, 3)
2
>>> Poly(x**4 - 4, x).count_roots(0, 1 + 3*I)
1
"""
inf_real, sup_real = True, True
if inf is not None:
inf = sympify(inf)
if inf is S.NegativeInfinity:
inf = None
else:
re, im = inf.as_real_imag()
if not im:
inf = QQ.convert(inf)
else:
inf, inf_real = list(map(QQ.convert, (re, im))), False
if sup is not None:
sup = sympify(sup)
if sup is S.Infinity:
sup = None
else:
re, im = sup.as_real_imag()
if not im:
sup = QQ.convert(sup)
else:
sup, sup_real = list(map(QQ.convert, (re, im))), False
if inf_real and sup_real:
if hasattr(f.rep, 'count_real_roots'):
count = f.rep.count_real_roots(inf=inf, sup=sup)
else: # pragma: no cover
raise OperationNotSupported(f, 'count_real_roots')
else:
if inf_real and inf is not None:
inf = (inf, QQ.zero)
if sup_real and sup is not None:
sup = (sup, QQ.zero)
if hasattr(f.rep, 'count_complex_roots'):
count = f.rep.count_complex_roots(inf=inf, sup=sup)
else: # pragma: no cover
raise OperationNotSupported(f, 'count_complex_roots')
return Integer(count)
def root(f, index, radicals=True):
"""
Get an indexed root of a polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = Poly(2*x**3 - 7*x**2 + 4*x + 4)
>>> f.root(0)
-1/2
>>> f.root(1)
2
>>> f.root(2)
2
>>> f.root(3)
Traceback (most recent call last):
...
IndexError: root index out of [-3, 2] range, got 3
>>> Poly(x**5 + x + 1).root(0)
CRootOf(x**3 - x**2 + 1, 0)
"""
return sympy.polys.rootoftools.rootof(f, index, radicals=radicals)
def real_roots(f, multiple=True, radicals=True):
"""
Return a list of real roots with multiplicities.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x**3 - 7*x**2 + 4*x + 4).real_roots()
[-1/2, 2, 2]
>>> Poly(x**3 + x + 1).real_roots()
[CRootOf(x**3 + x + 1, 0)]
"""
reals = sympy.polys.rootoftools.CRootOf.real_roots(f, radicals=radicals)
if multiple:
return reals
else:
return group(reals, multiple=False)
def all_roots(f, multiple=True, radicals=True):
"""
Return a list of real and complex roots with multiplicities.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x**3 - 7*x**2 + 4*x + 4).all_roots()
[-1/2, 2, 2]
>>> Poly(x**3 + x + 1).all_roots()
[CRootOf(x**3 + x + 1, 0),
CRootOf(x**3 + x + 1, 1),
CRootOf(x**3 + x + 1, 2)]
"""
roots = sympy.polys.rootoftools.CRootOf.all_roots(f, radicals=radicals)
if multiple:
return roots
else:
return group(roots, multiple=False)
def nroots(f, n=15, maxsteps=50, cleanup=True):
"""
Compute numerical approximations of roots of ``f``.
Parameters
==========
n ... the number of digits to calculate
maxsteps ... the maximum number of iterations to do
If the accuracy `n` cannot be reached in `maxsteps`, it will raise an
exception. You need to rerun with higher maxsteps.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 3).nroots(n=15)
[-1.73205080756888, 1.73205080756888]
>>> Poly(x**2 - 3).nroots(n=30)
[-1.73205080756887729352744634151, 1.73205080756887729352744634151]
"""
from sympy.functions.elementary.complexes import sign
if f.is_multivariate:
raise MultivariatePolynomialError(
"can't compute numerical roots of %s" % f)
if f.degree() <= 0:
return []
# For integer and rational coefficients, convert them to integers only
# (for accuracy). Otherwise just try to convert the coefficients to
# mpmath.mpc and raise an exception if the conversion fails.
if f.rep.dom is ZZ:
coeffs = [int(coeff) for coeff in f.all_coeffs()]
elif f.rep.dom is QQ:
denoms = [coeff.q for coeff in f.all_coeffs()]
from sympy.core.numbers import ilcm
fac = ilcm(*denoms)
coeffs = [int(coeff*fac) for coeff in f.all_coeffs()]
else:
coeffs = [coeff.evalf(n=n).as_real_imag()
for coeff in f.all_coeffs()]
try:
coeffs = [mpmath.mpc(*coeff) for coeff in coeffs]
except TypeError:
raise DomainError("Numerical domain expected, got %s" % \
f.rep.dom)
dps = mpmath.mp.dps
mpmath.mp.dps = n
try:
# We need to add extra precision to guard against losing accuracy.
# 10 times the degree of the polynomial seems to work well.
roots = mpmath.polyroots(coeffs, maxsteps=maxsteps,
cleanup=cleanup, error=False, extraprec=f.degree()*10)
# Mpmath puts real roots first, then complex ones (as does all_roots)
# so we make sure this convention holds here, too.
roots = list(map(sympify,
sorted(roots, key=lambda r: (1 if r.imag else 0, r.real, abs(r.imag), sign(r.imag)))))
except NoConvergence:
raise NoConvergence(
'convergence to root failed; try n < %s or maxsteps > %s' % (
n, maxsteps))
finally:
mpmath.mp.dps = dps
return roots
def ground_roots(f):
"""
Compute roots of ``f`` by factorization in the ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**6 - 4*x**4 + 4*x**3 - x**2).ground_roots()
{0: 2, 1: 2}
"""
if f.is_multivariate:
raise MultivariatePolynomialError(
"can't compute ground roots of %s" % f)
roots = {}
for factor, k in f.factor_list()[1]:
if factor.is_linear:
a, b = factor.all_coeffs()
roots[-b/a] = k
return roots
def nth_power_roots_poly(f, n):
"""
Construct a polynomial with n-th powers of roots of ``f``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = Poly(x**4 - x**2 + 1)
>>> f.nth_power_roots_poly(2)
Poly(x**4 - 2*x**3 + 3*x**2 - 2*x + 1, x, domain='ZZ')
>>> f.nth_power_roots_poly(3)
Poly(x**4 + 2*x**2 + 1, x, domain='ZZ')
>>> f.nth_power_roots_poly(4)
Poly(x**4 + 2*x**3 + 3*x**2 + 2*x + 1, x, domain='ZZ')
>>> f.nth_power_roots_poly(12)
Poly(x**4 - 4*x**3 + 6*x**2 - 4*x + 1, x, domain='ZZ')
"""
if f.is_multivariate:
raise MultivariatePolynomialError(
"must be a univariate polynomial")
N = sympify(n)
if N.is_Integer and N >= 1:
n = int(N)
else:
raise ValueError("'n' must an integer and n >= 1, got %s" % n)
x = f.gen
t = Dummy('t')
r = f.resultant(f.__class__.from_expr(x**n - t, x, t))
return r.replace(t, x)
def cancel(f, g, include=False):
"""
Cancel common factors in a rational function ``f/g``.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x**2 - 2, x).cancel(Poly(x**2 - 2*x + 1, x))
(1, Poly(2*x + 2, x, domain='ZZ'), Poly(x - 1, x, domain='ZZ'))
>>> Poly(2*x**2 - 2, x).cancel(Poly(x**2 - 2*x + 1, x), include=True)
(Poly(2*x + 2, x, domain='ZZ'), Poly(x - 1, x, domain='ZZ'))
"""
dom, per, F, G = f._unify(g)
if hasattr(F, 'cancel'):
result = F.cancel(G, include=include)
else: # pragma: no cover
raise OperationNotSupported(f, 'cancel')
if not include:
if dom.has_assoc_Ring:
dom = dom.get_ring()
cp, cq, p, q = result
cp = dom.to_sympy(cp)
cq = dom.to_sympy(cq)
return cp/cq, per(p), per(q)
else:
return tuple(map(per, result))
@property
def is_zero(f):
"""
Returns ``True`` if ``f`` is a zero polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(0, x).is_zero
True
>>> Poly(1, x).is_zero
False
"""
return f.rep.is_zero
@property
def is_one(f):
"""
Returns ``True`` if ``f`` is a unit polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(0, x).is_one
False
>>> Poly(1, x).is_one
True
"""
return f.rep.is_one
@property
def is_sqf(f):
"""
Returns ``True`` if ``f`` is a square-free polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 - 2*x + 1, x).is_sqf
False
>>> Poly(x**2 - 1, x).is_sqf
True
"""
return f.rep.is_sqf
@property
def is_monic(f):
"""
Returns ``True`` if the leading coefficient of ``f`` is one.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x + 2, x).is_monic
True
>>> Poly(2*x + 2, x).is_monic
False
"""
return f.rep.is_monic
@property
def is_primitive(f):
"""
Returns ``True`` if GCD of the coefficients of ``f`` is one.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(2*x**2 + 6*x + 12, x).is_primitive
False
>>> Poly(x**2 + 3*x + 6, x).is_primitive
True
"""
return f.rep.is_primitive
@property
def is_ground(f):
"""
Returns ``True`` if ``f`` is an element of the ground domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x, x).is_ground
False
>>> Poly(2, x).is_ground
True
>>> Poly(y, x).is_ground
True
"""
return f.rep.is_ground
@property
def is_linear(f):
"""
Returns ``True`` if ``f`` is linear in all its variables.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x + y + 2, x, y).is_linear
True
>>> Poly(x*y + 2, x, y).is_linear
False
"""
return f.rep.is_linear
@property
def is_quadratic(f):
"""
Returns ``True`` if ``f`` is quadratic in all its variables.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x*y + 2, x, y).is_quadratic
True
>>> Poly(x*y**2 + 2, x, y).is_quadratic
False
"""
return f.rep.is_quadratic
@property
def is_monomial(f):
"""
Returns ``True`` if ``f`` is zero or has only one term.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(3*x**2, x).is_monomial
True
>>> Poly(3*x**2 + 1, x).is_monomial
False
"""
return f.rep.is_monomial
@property
def is_homogeneous(f):
"""
Returns ``True`` if ``f`` is a homogeneous polynomial.
A homogeneous polynomial is a polynomial whose all monomials with
non-zero coefficients have the same total degree. If you want not
only to check if a polynomial is homogeneous but also compute its
homogeneous order, then use :func:`Poly.homogeneous_order`.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + x*y, x, y).is_homogeneous
True
>>> Poly(x**3 + x*y, x, y).is_homogeneous
False
"""
return f.rep.is_homogeneous
@property
def is_irreducible(f):
"""
Returns ``True`` if ``f`` has no factors over its domain.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> Poly(x**2 + x + 1, x, modulus=2).is_irreducible
True
>>> Poly(x**2 + 1, x, modulus=2).is_irreducible
False
"""
return f.rep.is_irreducible
@property
def is_univariate(f):
"""
Returns ``True`` if ``f`` is a univariate polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + x + 1, x).is_univariate
True
>>> Poly(x*y**2 + x*y + 1, x, y).is_univariate
False
>>> Poly(x*y**2 + x*y + 1, x).is_univariate
True
>>> Poly(x**2 + x + 1, x, y).is_univariate
False
"""
return len(f.gens) == 1
@property
def is_multivariate(f):
"""
Returns ``True`` if ``f`` is a multivariate polynomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x, y
>>> Poly(x**2 + x + 1, x).is_multivariate
False
>>> Poly(x*y**2 + x*y + 1, x, y).is_multivariate
True
>>> Poly(x*y**2 + x*y + 1, x).is_multivariate
False
>>> Poly(x**2 + x + 1, x, y).is_multivariate
True
"""
return len(f.gens) != 1
@property
def is_cyclotomic(f):
"""
Returns ``True`` if ``f`` is a cyclotomic polnomial.
Examples
========
>>> from sympy import Poly
>>> from sympy.abc import x
>>> f = x**16 + x**14 - x**10 + x**8 - x**6 + x**2 + 1
>>> Poly(f).is_cyclotomic
False
>>> g = x**16 + x**14 - x**10 - x**8 - x**6 + x**2 + 1
>>> Poly(g).is_cyclotomic
True
"""
return f.rep.is_cyclotomic
def __abs__(f):
return f.abs()
def __neg__(f):
return f.neg()
@_polifyit
def __add__(f, g):
return f.add(g)
@_polifyit
def __radd__(f, g):
return g.add(f)
@_polifyit
def __sub__(f, g):
return f.sub(g)
@_polifyit
def __rsub__(f, g):
return g.sub(f)
@_polifyit
def __mul__(f, g):
return f.mul(g)
@_polifyit
def __rmul__(f, g):
return g.mul(f)
@_sympifyit('n', NotImplemented)
def __pow__(f, n):
if n.is_Integer and n >= 0:
return f.pow(n)
else:
return NotImplemented
@_polifyit
def __divmod__(f, g):
return f.div(g)
@_polifyit
def __rdivmod__(f, g):
return g.div(f)
@_polifyit
def __mod__(f, g):
return f.rem(g)
@_polifyit
def __rmod__(f, g):
return g.rem(f)
@_polifyit
def __floordiv__(f, g):
return f.quo(g)
@_polifyit
def __rfloordiv__(f, g):
return g.quo(f)
@_sympifyit('g', NotImplemented)
def __div__(f, g):
return f.as_expr()/g.as_expr()
@_sympifyit('g', NotImplemented)
def __rdiv__(f, g):
return g.as_expr()/f.as_expr()
__truediv__ = __div__
__rtruediv__ = __rdiv__
@_sympifyit('other', NotImplemented)
def __eq__(self, other):
f, g = self, other
if not g.is_Poly:
try:
g = f.__class__(g, f.gens, domain=f.get_domain())
except (PolynomialError, DomainError, CoercionFailed):
return False
if f.gens != g.gens:
return False
if f.rep.dom != g.rep.dom:
return False
return f.rep == g.rep
@_sympifyit('g', NotImplemented)
def __ne__(f, g):
return not f == g
def __nonzero__(f):
return not f.is_zero
__bool__ = __nonzero__
def eq(f, g, strict=False):
if not strict:
return f == g
else:
return f._strict_eq(sympify(g))
def ne(f, g, strict=False):
return not f.eq(g, strict=strict)
def _strict_eq(f, g):
return isinstance(g, f.__class__) and f.gens == g.gens and f.rep.eq(g.rep, strict=True)
@public
class PurePoly(Poly):
"""Class for representing pure polynomials. """
def _hashable_content(self):
"""Allow SymPy to hash Poly instances. """
return (self.rep,)
def __hash__(self):
return super(PurePoly, self).__hash__()
@property
def free_symbols(self):
"""
Free symbols of a polynomial.
Examples
========
>>> from sympy import PurePoly
>>> from sympy.abc import x, y
>>> PurePoly(x**2 + 1).free_symbols
set()
>>> PurePoly(x**2 + y).free_symbols
set()
>>> PurePoly(x**2 + y, x).free_symbols
{y}
"""
return self.free_symbols_in_domain
@_sympifyit('other', NotImplemented)
def __eq__(self, other):
f, g = self, other
if not g.is_Poly:
try:
g = f.__class__(g, f.gens, domain=f.get_domain())
except (PolynomialError, DomainError, CoercionFailed):
return False
if len(f.gens) != len(g.gens):
return False
if f.rep.dom != g.rep.dom:
try:
dom = f.rep.dom.unify(g.rep.dom, f.gens)
except UnificationFailed:
return False
f = f.set_domain(dom)
g = g.set_domain(dom)
return f.rep == g.rep
def _strict_eq(f, g):
return isinstance(g, f.__class__) and f.rep.eq(g.rep, strict=True)
def _unify(f, g):
g = sympify(g)
if not g.is_Poly:
try:
return f.rep.dom, f.per, f.rep, f.rep.per(f.rep.dom.from_sympy(g))
except CoercionFailed:
raise UnificationFailed("can't unify %s with %s" % (f, g))
if len(f.gens) != len(g.gens):
raise UnificationFailed("can't unify %s with %s" % (f, g))
if not (isinstance(f.rep, DMP) and isinstance(g.rep, DMP)):
raise UnificationFailed("can't unify %s with %s" % (f, g))
cls = f.__class__
gens = f.gens
dom = f.rep.dom.unify(g.rep.dom, gens)
F = f.rep.convert(dom)
G = g.rep.convert(dom)
def per(rep, dom=dom, gens=gens, remove=None):
if remove is not None:
gens = gens[:remove] + gens[remove + 1:]
if not gens:
return dom.to_sympy(rep)
return cls.new(rep, *gens)
return dom, per, F, G
@public
def poly_from_expr(expr, *gens, **args):
"""Construct a polynomial from an expression. """
opt = options.build_options(gens, args)
return _poly_from_expr(expr, opt)
def _poly_from_expr(expr, opt):
"""Construct a polynomial from an expression. """
orig, expr = expr, sympify(expr)
if not isinstance(expr, Basic):
raise PolificationFailed(opt, orig, expr)
elif expr.is_Poly:
poly = expr.__class__._from_poly(expr, opt)
opt.gens = poly.gens
opt.domain = poly.domain
if opt.polys is None:
opt.polys = True
return poly, opt
elif opt.expand:
expr = expr.expand()
rep, opt = _dict_from_expr(expr, opt)
if not opt.gens:
raise PolificationFailed(opt, orig, expr)
monoms, coeffs = list(zip(*list(rep.items())))
domain = opt.domain
if domain is None:
opt.domain, coeffs = construct_domain(coeffs, opt=opt)
else:
coeffs = list(map(domain.from_sympy, coeffs))
rep = dict(list(zip(monoms, coeffs)))
poly = Poly._from_dict(rep, opt)
if opt.polys is None:
opt.polys = False
return poly, opt
@public
def parallel_poly_from_expr(exprs, *gens, **args):
"""Construct polynomials from expressions. """
opt = options.build_options(gens, args)
return _parallel_poly_from_expr(exprs, opt)
def _parallel_poly_from_expr(exprs, opt):
"""Construct polynomials from expressions. """
from sympy.functions.elementary.piecewise import Piecewise
if len(exprs) == 2:
f, g = exprs
if isinstance(f, Poly) and isinstance(g, Poly):
f = f.__class__._from_poly(f, opt)
g = g.__class__._from_poly(g, opt)
f, g = f.unify(g)
opt.gens = f.gens
opt.domain = f.domain
if opt.polys is None:
opt.polys = True
return [f, g], opt
origs, exprs = list(exprs), []
_exprs, _polys = [], []
failed = False
for i, expr in enumerate(origs):
expr = sympify(expr)
if isinstance(expr, Basic):
if expr.is_Poly:
_polys.append(i)
else:
_exprs.append(i)
if opt.expand:
expr = expr.expand()
else:
failed = True
exprs.append(expr)
if failed:
raise PolificationFailed(opt, origs, exprs, True)
if _polys:
# XXX: this is a temporary solution
for i in _polys:
exprs[i] = exprs[i].as_expr()
reps, opt = _parallel_dict_from_expr(exprs, opt)
if not opt.gens:
raise PolificationFailed(opt, origs, exprs, True)
for k in opt.gens:
if isinstance(k, Piecewise):
raise PolynomialError("Piecewise generators do not make sense")
coeffs_list, lengths = [], []
all_monoms = []
all_coeffs = []
for rep in reps:
monoms, coeffs = list(zip(*list(rep.items())))
coeffs_list.extend(coeffs)
all_monoms.append(monoms)
lengths.append(len(coeffs))
domain = opt.domain
if domain is None:
opt.domain, coeffs_list = construct_domain(coeffs_list, opt=opt)
else:
coeffs_list = list(map(domain.from_sympy, coeffs_list))
for k in lengths:
all_coeffs.append(coeffs_list[:k])
coeffs_list = coeffs_list[k:]
polys = []
for monoms, coeffs in zip(all_monoms, all_coeffs):
rep = dict(list(zip(monoms, coeffs)))
poly = Poly._from_dict(rep, opt)
polys.append(poly)
if opt.polys is None:
opt.polys = bool(_polys)
return polys, opt
def _update_args(args, key, value):
"""Add a new ``(key, value)`` pair to arguments ``dict``. """
args = dict(args)
if key not in args:
args[key] = value
return args
@public
def degree(f, gen=0):
"""
Return the degree of ``f`` in the given variable.
The degree of 0 is negative infinity.
Examples
========
>>> from sympy import degree
>>> from sympy.abc import x, y
>>> degree(x**2 + y*x + 1, gen=x)
2
>>> degree(x**2 + y*x + 1, gen=y)
1
>>> degree(0, x)
-oo
See also
========
sympy.polys.polytools.Poly.total_degree
degree_list
"""
f = sympify(f, strict=True)
gen_is_Num = sympify(gen, strict=True).is_Number
if f.is_Poly:
p = f
isNum = p.as_expr().is_Number
else:
isNum = f.is_Number
if not isNum:
if gen_is_Num:
p, _ = poly_from_expr(f)
else:
p, _ = poly_from_expr(f, gen)
if isNum:
return S.Zero if f else S.NegativeInfinity
if not gen_is_Num:
if f.is_Poly and gen not in p.gens:
# try recast without explicit gens
p, _ = poly_from_expr(f.as_expr())
if gen not in p.gens:
return S.Zero
elif not f.is_Poly and len(f.free_symbols) > 1:
raise TypeError(filldedent('''
A symbolic generator of interest is required for a multivariate
expression like func = %s, e.g. degree(func, gen = %s) instead of
degree(func, gen = %s).
''' % (f, next(ordered(f.free_symbols)), gen)))
return Integer(p.degree(gen))
@public
def total_degree(f, *gens):
"""
Return the total_degree of ``f`` in the given variables.
Examples
========
>>> from sympy import total_degree, Poly
>>> from sympy.abc import x, y
>>> total_degree(1)
0
>>> total_degree(x + x*y)
2
>>> total_degree(x + x*y, x)
1
If the expression is a Poly and no variables are given
then the generators of the Poly will be used:
>>> p = Poly(x + x*y, y)
>>> total_degree(p)
1
To deal with the underlying expression of the Poly, convert
it to an Expr:
>>> total_degree(p.as_expr())
2
This is done automatically if any variables are given:
>>> total_degree(p, x)
1
See also
========
degree
"""
p = sympify(f)
if p.is_Poly:
p = p.as_expr()
if p.is_Number:
rv = 0
else:
if f.is_Poly:
gens = gens or f.gens
rv = Poly(p, gens).total_degree()
return Integer(rv)
@public
def degree_list(f, *gens, **args):
"""
Return a list of degrees of ``f`` in all variables.
Examples
========
>>> from sympy import degree_list
>>> from sympy.abc import x, y
>>> degree_list(x**2 + y*x + 1)
(2, 1)
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('degree_list', 1, exc)
degrees = F.degree_list()
return tuple(map(Integer, degrees))
@public
def LC(f, *gens, **args):
"""
Return the leading coefficient of ``f``.
Examples
========
>>> from sympy import LC
>>> from sympy.abc import x, y
>>> LC(4*x**2 + 2*x*y**2 + x*y + 3*y)
4
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('LC', 1, exc)
return F.LC(order=opt.order)
@public
def LM(f, *gens, **args):
"""
Return the leading monomial of ``f``.
Examples
========
>>> from sympy import LM
>>> from sympy.abc import x, y
>>> LM(4*x**2 + 2*x*y**2 + x*y + 3*y)
x**2
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('LM', 1, exc)
monom = F.LM(order=opt.order)
return monom.as_expr()
@public
def LT(f, *gens, **args):
"""
Return the leading term of ``f``.
Examples
========
>>> from sympy import LT
>>> from sympy.abc import x, y
>>> LT(4*x**2 + 2*x*y**2 + x*y + 3*y)
4*x**2
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('LT', 1, exc)
monom, coeff = F.LT(order=opt.order)
return coeff*monom.as_expr()
@public
def pdiv(f, g, *gens, **args):
"""
Compute polynomial pseudo-division of ``f`` and ``g``.
Examples
========
>>> from sympy import pdiv
>>> from sympy.abc import x
>>> pdiv(x**2 + 1, 2*x - 4)
(2*x + 4, 20)
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('pdiv', 2, exc)
q, r = F.pdiv(G)
if not opt.polys:
return q.as_expr(), r.as_expr()
else:
return q, r
@public
def prem(f, g, *gens, **args):
"""
Compute polynomial pseudo-remainder of ``f`` and ``g``.
Examples
========
>>> from sympy import prem
>>> from sympy.abc import x
>>> prem(x**2 + 1, 2*x - 4)
20
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('prem', 2, exc)
r = F.prem(G)
if not opt.polys:
return r.as_expr()
else:
return r
@public
def pquo(f, g, *gens, **args):
"""
Compute polynomial pseudo-quotient of ``f`` and ``g``.
Examples
========
>>> from sympy import pquo
>>> from sympy.abc import x
>>> pquo(x**2 + 1, 2*x - 4)
2*x + 4
>>> pquo(x**2 - 1, 2*x - 1)
2*x + 1
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('pquo', 2, exc)
try:
q = F.pquo(G)
except ExactQuotientFailed:
raise ExactQuotientFailed(f, g)
if not opt.polys:
return q.as_expr()
else:
return q
@public
def pexquo(f, g, *gens, **args):
"""
Compute polynomial exact pseudo-quotient of ``f`` and ``g``.
Examples
========
>>> from sympy import pexquo
>>> from sympy.abc import x
>>> pexquo(x**2 - 1, 2*x - 2)
2*x + 2
>>> pexquo(x**2 + 1, 2*x - 4)
Traceback (most recent call last):
...
ExactQuotientFailed: 2*x - 4 does not divide x**2 + 1
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('pexquo', 2, exc)
q = F.pexquo(G)
if not opt.polys:
return q.as_expr()
else:
return q
@public
def div(f, g, *gens, **args):
"""
Compute polynomial division of ``f`` and ``g``.
Examples
========
>>> from sympy import div, ZZ, QQ
>>> from sympy.abc import x
>>> div(x**2 + 1, 2*x - 4, domain=ZZ)
(0, x**2 + 1)
>>> div(x**2 + 1, 2*x - 4, domain=QQ)
(x/2 + 1, 5)
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('div', 2, exc)
q, r = F.div(G, auto=opt.auto)
if not opt.polys:
return q.as_expr(), r.as_expr()
else:
return q, r
@public
def rem(f, g, *gens, **args):
"""
Compute polynomial remainder of ``f`` and ``g``.
Examples
========
>>> from sympy import rem, ZZ, QQ
>>> from sympy.abc import x
>>> rem(x**2 + 1, 2*x - 4, domain=ZZ)
x**2 + 1
>>> rem(x**2 + 1, 2*x - 4, domain=QQ)
5
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('rem', 2, exc)
r = F.rem(G, auto=opt.auto)
if not opt.polys:
return r.as_expr()
else:
return r
@public
def quo(f, g, *gens, **args):
"""
Compute polynomial quotient of ``f`` and ``g``.
Examples
========
>>> from sympy import quo
>>> from sympy.abc import x
>>> quo(x**2 + 1, 2*x - 4)
x/2 + 1
>>> quo(x**2 - 1, x - 1)
x + 1
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('quo', 2, exc)
q = F.quo(G, auto=opt.auto)
if not opt.polys:
return q.as_expr()
else:
return q
@public
def exquo(f, g, *gens, **args):
"""
Compute polynomial exact quotient of ``f`` and ``g``.
Examples
========
>>> from sympy import exquo
>>> from sympy.abc import x
>>> exquo(x**2 - 1, x - 1)
x + 1
>>> exquo(x**2 + 1, 2*x - 4)
Traceback (most recent call last):
...
ExactQuotientFailed: 2*x - 4 does not divide x**2 + 1
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('exquo', 2, exc)
q = F.exquo(G, auto=opt.auto)
if not opt.polys:
return q.as_expr()
else:
return q
@public
def half_gcdex(f, g, *gens, **args):
"""
Half extended Euclidean algorithm of ``f`` and ``g``.
Returns ``(s, h)`` such that ``h = gcd(f, g)`` and ``s*f = h (mod g)``.
Examples
========
>>> from sympy import half_gcdex
>>> from sympy.abc import x
>>> half_gcdex(x**4 - 2*x**3 - 6*x**2 + 12*x + 15, x**3 + x**2 - 4*x - 4)
(3/5 - x/5, x + 1)
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
domain, (a, b) = construct_domain(exc.exprs)
try:
s, h = domain.half_gcdex(a, b)
except NotImplementedError:
raise ComputationFailed('half_gcdex', 2, exc)
else:
return domain.to_sympy(s), domain.to_sympy(h)
s, h = F.half_gcdex(G, auto=opt.auto)
if not opt.polys:
return s.as_expr(), h.as_expr()
else:
return s, h
@public
def gcdex(f, g, *gens, **args):
"""
Extended Euclidean algorithm of ``f`` and ``g``.
Returns ``(s, t, h)`` such that ``h = gcd(f, g)`` and ``s*f + t*g = h``.
Examples
========
>>> from sympy import gcdex
>>> from sympy.abc import x
>>> gcdex(x**4 - 2*x**3 - 6*x**2 + 12*x + 15, x**3 + x**2 - 4*x - 4)
(3/5 - x/5, x**2/5 - 6*x/5 + 2, x + 1)
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
domain, (a, b) = construct_domain(exc.exprs)
try:
s, t, h = domain.gcdex(a, b)
except NotImplementedError:
raise ComputationFailed('gcdex', 2, exc)
else:
return domain.to_sympy(s), domain.to_sympy(t), domain.to_sympy(h)
s, t, h = F.gcdex(G, auto=opt.auto)
if not opt.polys:
return s.as_expr(), t.as_expr(), h.as_expr()
else:
return s, t, h
@public
def invert(f, g, *gens, **args):
"""
Invert ``f`` modulo ``g`` when possible.
Examples
========
>>> from sympy import invert, S
>>> from sympy.core.numbers import mod_inverse
>>> from sympy.abc import x
>>> invert(x**2 - 1, 2*x - 1)
-4/3
>>> invert(x**2 - 1, x - 1)
Traceback (most recent call last):
...
NotInvertible: zero divisor
For more efficient inversion of Rationals,
use the :obj:`~.mod_inverse` function:
>>> mod_inverse(3, 5)
2
>>> (S(2)/5).invert(S(7)/3)
5/2
See Also
========
sympy.core.numbers.mod_inverse
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
domain, (a, b) = construct_domain(exc.exprs)
try:
return domain.to_sympy(domain.invert(a, b))
except NotImplementedError:
raise ComputationFailed('invert', 2, exc)
h = F.invert(G, auto=opt.auto)
if not opt.polys:
return h.as_expr()
else:
return h
@public
def subresultants(f, g, *gens, **args):
"""
Compute subresultant PRS of ``f`` and ``g``.
Examples
========
>>> from sympy import subresultants
>>> from sympy.abc import x
>>> subresultants(x**2 + 1, x**2 - 1)
[x**2 + 1, x**2 - 1, -2]
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('subresultants', 2, exc)
result = F.subresultants(G)
if not opt.polys:
return [r.as_expr() for r in result]
else:
return result
@public
def resultant(f, g, *gens, **args):
"""
Compute resultant of ``f`` and ``g``.
Examples
========
>>> from sympy import resultant
>>> from sympy.abc import x
>>> resultant(x**2 + 1, x**2 - 1)
4
"""
includePRS = args.pop('includePRS', False)
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('resultant', 2, exc)
if includePRS:
result, R = F.resultant(G, includePRS=includePRS)
else:
result = F.resultant(G)
if not opt.polys:
if includePRS:
return result.as_expr(), [r.as_expr() for r in R]
return result.as_expr()
else:
if includePRS:
return result, R
return result
@public
def discriminant(f, *gens, **args):
"""
Compute discriminant of ``f``.
Examples
========
>>> from sympy import discriminant
>>> from sympy.abc import x
>>> discriminant(x**2 + 2*x + 3)
-8
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('discriminant', 1, exc)
result = F.discriminant()
if not opt.polys:
return result.as_expr()
else:
return result
@public
def cofactors(f, g, *gens, **args):
"""
Compute GCD and cofactors of ``f`` and ``g``.
Returns polynomials ``(h, cff, cfg)`` such that ``h = gcd(f, g)``, and
``cff = quo(f, h)`` and ``cfg = quo(g, h)`` are, so called, cofactors
of ``f`` and ``g``.
Examples
========
>>> from sympy import cofactors
>>> from sympy.abc import x
>>> cofactors(x**2 - 1, x**2 - 3*x + 2)
(x - 1, x + 1, x - 2)
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
domain, (a, b) = construct_domain(exc.exprs)
try:
h, cff, cfg = domain.cofactors(a, b)
except NotImplementedError:
raise ComputationFailed('cofactors', 2, exc)
else:
return domain.to_sympy(h), domain.to_sympy(cff), domain.to_sympy(cfg)
h, cff, cfg = F.cofactors(G)
if not opt.polys:
return h.as_expr(), cff.as_expr(), cfg.as_expr()
else:
return h, cff, cfg
@public
def gcd_list(seq, *gens, **args):
"""
Compute GCD of a list of polynomials.
Examples
========
>>> from sympy import gcd_list
>>> from sympy.abc import x
>>> gcd_list([x**3 - 1, x**2 - 1, x**2 - 3*x + 2])
x - 1
"""
seq = sympify(seq)
def try_non_polynomial_gcd(seq):
if not gens and not args:
domain, numbers = construct_domain(seq)
if not numbers:
return domain.zero
elif domain.is_Numerical:
result, numbers = numbers[0], numbers[1:]
for number in numbers:
result = domain.gcd(result, number)
if domain.is_one(result):
break
return domain.to_sympy(result)
return None
result = try_non_polynomial_gcd(seq)
if result is not None:
return result
options.allowed_flags(args, ['polys'])
try:
polys, opt = parallel_poly_from_expr(seq, *gens, **args)
# gcd for domain Q[irrational] (purely algebraic irrational)
if len(seq) > 1 and all(elt.is_algebraic and elt.is_irrational for elt in seq):
a = seq[-1]
lst = [ (a/elt).ratsimp() for elt in seq[:-1] ]
if all(frc.is_rational for frc in lst):
lc = 1
for frc in lst:
lc = lcm(lc, frc.as_numer_denom()[0])
return a/lc
except PolificationFailed as exc:
result = try_non_polynomial_gcd(exc.exprs)
if result is not None:
return result
else:
raise ComputationFailed('gcd_list', len(seq), exc)
if not polys:
if not opt.polys:
return S.Zero
else:
return Poly(0, opt=opt)
result, polys = polys[0], polys[1:]
for poly in polys:
result = result.gcd(poly)
if result.is_one:
break
if not opt.polys:
return result.as_expr()
else:
return result
@public
def gcd(f, g=None, *gens, **args):
"""
Compute GCD of ``f`` and ``g``.
Examples
========
>>> from sympy import gcd
>>> from sympy.abc import x
>>> gcd(x**2 - 1, x**2 - 3*x + 2)
x - 1
"""
if hasattr(f, '__iter__'):
if g is not None:
gens = (g,) + gens
return gcd_list(f, *gens, **args)
elif g is None:
raise TypeError("gcd() takes 2 arguments or a sequence of arguments")
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
# gcd for domain Q[irrational] (purely algebraic irrational)
a, b = map(sympify, (f, g))
if a.is_algebraic and a.is_irrational and b.is_algebraic and b.is_irrational:
frc = (a/b).ratsimp()
if frc.is_rational:
return a/frc.as_numer_denom()[0]
except PolificationFailed as exc:
domain, (a, b) = construct_domain(exc.exprs)
try:
return domain.to_sympy(domain.gcd(a, b))
except NotImplementedError:
raise ComputationFailed('gcd', 2, exc)
result = F.gcd(G)
if not opt.polys:
return result.as_expr()
else:
return result
@public
def lcm_list(seq, *gens, **args):
"""
Compute LCM of a list of polynomials.
Examples
========
>>> from sympy import lcm_list
>>> from sympy.abc import x
>>> lcm_list([x**3 - 1, x**2 - 1, x**2 - 3*x + 2])
x**5 - x**4 - 2*x**3 - x**2 + x + 2
"""
seq = sympify(seq)
def try_non_polynomial_lcm(seq):
if not gens and not args:
domain, numbers = construct_domain(seq)
if not numbers:
return domain.one
elif domain.is_Numerical:
result, numbers = numbers[0], numbers[1:]
for number in numbers:
result = domain.lcm(result, number)
return domain.to_sympy(result)
return None
result = try_non_polynomial_lcm(seq)
if result is not None:
return result
options.allowed_flags(args, ['polys'])
try:
polys, opt = parallel_poly_from_expr(seq, *gens, **args)
# lcm for domain Q[irrational] (purely algebraic irrational)
if len(seq) > 1 and all(elt.is_algebraic and elt.is_irrational for elt in seq):
a = seq[-1]
lst = [ (a/elt).ratsimp() for elt in seq[:-1] ]
if all(frc.is_rational for frc in lst):
lc = 1
for frc in lst:
lc = lcm(lc, frc.as_numer_denom()[1])
return a*lc
except PolificationFailed as exc:
result = try_non_polynomial_lcm(exc.exprs)
if result is not None:
return result
else:
raise ComputationFailed('lcm_list', len(seq), exc)
if not polys:
if not opt.polys:
return S.One
else:
return Poly(1, opt=opt)
result, polys = polys[0], polys[1:]
for poly in polys:
result = result.lcm(poly)
if not opt.polys:
return result.as_expr()
else:
return result
@public
def lcm(f, g=None, *gens, **args):
"""
Compute LCM of ``f`` and ``g``.
Examples
========
>>> from sympy import lcm
>>> from sympy.abc import x
>>> lcm(x**2 - 1, x**2 - 3*x + 2)
x**3 - 2*x**2 - x + 2
"""
if hasattr(f, '__iter__'):
if g is not None:
gens = (g,) + gens
return lcm_list(f, *gens, **args)
elif g is None:
raise TypeError("lcm() takes 2 arguments or a sequence of arguments")
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
# lcm for domain Q[irrational] (purely algebraic irrational)
a, b = map(sympify, (f, g))
if a.is_algebraic and a.is_irrational and b.is_algebraic and b.is_irrational:
frc = (a/b).ratsimp()
if frc.is_rational:
return a*frc.as_numer_denom()[1]
except PolificationFailed as exc:
domain, (a, b) = construct_domain(exc.exprs)
try:
return domain.to_sympy(domain.lcm(a, b))
except NotImplementedError:
raise ComputationFailed('lcm', 2, exc)
result = F.lcm(G)
if not opt.polys:
return result.as_expr()
else:
return result
@public
def terms_gcd(f, *gens, **args):
"""
Remove GCD of terms from ``f``.
If the ``deep`` flag is True, then the arguments of ``f`` will have
terms_gcd applied to them.
If a fraction is factored out of ``f`` and ``f`` is an Add, then
an unevaluated Mul will be returned so that automatic simplification
does not redistribute it. The hint ``clear``, when set to False, can be
used to prevent such factoring when all coefficients are not fractions.
Examples
========
>>> from sympy import terms_gcd, cos
>>> from sympy.abc import x, y
>>> terms_gcd(x**6*y**2 + x**3*y, x, y)
x**3*y*(x**3*y + 1)
The default action of polys routines is to expand the expression
given to them. terms_gcd follows this behavior:
>>> terms_gcd((3+3*x)*(x+x*y))
3*x*(x*y + x + y + 1)
If this is not desired then the hint ``expand`` can be set to False.
In this case the expression will be treated as though it were comprised
of one or more terms:
>>> terms_gcd((3+3*x)*(x+x*y), expand=False)
(3*x + 3)*(x*y + x)
In order to traverse factors of a Mul or the arguments of other
functions, the ``deep`` hint can be used:
>>> terms_gcd((3 + 3*x)*(x + x*y), expand=False, deep=True)
3*x*(x + 1)*(y + 1)
>>> terms_gcd(cos(x + x*y), deep=True)
cos(x*(y + 1))
Rationals are factored out by default:
>>> terms_gcd(x + y/2)
(2*x + y)/2
Only the y-term had a coefficient that was a fraction; if one
does not want to factor out the 1/2 in cases like this, the
flag ``clear`` can be set to False:
>>> terms_gcd(x + y/2, clear=False)
x + y/2
>>> terms_gcd(x*y/2 + y**2, clear=False)
y*(x/2 + y)
The ``clear`` flag is ignored if all coefficients are fractions:
>>> terms_gcd(x/3 + y/2, clear=False)
(2*x + 3*y)/6
See Also
========
sympy.core.exprtools.gcd_terms, sympy.core.exprtools.factor_terms
"""
from sympy.core.relational import Equality
orig = sympify(f)
if isinstance(f, Equality):
return Equality(*(terms_gcd(s, *gens, **args) for s in [f.lhs, f.rhs]))
elif isinstance(f, Relational):
raise TypeError("Inequalities can not be used with terms_gcd. Found: %s" %(f,))
if not isinstance(f, Expr) or f.is_Atom:
return orig
if args.get('deep', False):
new = f.func(*[terms_gcd(a, *gens, **args) for a in f.args])
args.pop('deep')
args['expand'] = False
return terms_gcd(new, *gens, **args)
clear = args.pop('clear', True)
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
return exc.expr
J, f = F.terms_gcd()
if opt.domain.is_Ring:
if opt.domain.is_Field:
denom, f = f.clear_denoms(convert=True)
coeff, f = f.primitive()
if opt.domain.is_Field:
coeff /= denom
else:
coeff = S.One
term = Mul(*[x**j for x, j in zip(f.gens, J)])
if coeff == 1:
coeff = S.One
if term == 1:
return orig
if clear:
return _keep_coeff(coeff, term*f.as_expr())
# base the clearing on the form of the original expression, not
# the (perhaps) Mul that we have now
coeff, f = _keep_coeff(coeff, f.as_expr(), clear=False).as_coeff_Mul()
return _keep_coeff(coeff, term*f, clear=False)
@public
def trunc(f, p, *gens, **args):
"""
Reduce ``f`` modulo a constant ``p``.
Examples
========
>>> from sympy import trunc
>>> from sympy.abc import x
>>> trunc(2*x**3 + 3*x**2 + 5*x + 7, 3)
-x**3 - x + 1
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('trunc', 1, exc)
result = F.trunc(sympify(p))
if not opt.polys:
return result.as_expr()
else:
return result
@public
def monic(f, *gens, **args):
"""
Divide all coefficients of ``f`` by ``LC(f)``.
Examples
========
>>> from sympy import monic
>>> from sympy.abc import x
>>> monic(3*x**2 + 4*x + 2)
x**2 + 4*x/3 + 2/3
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('monic', 1, exc)
result = F.monic(auto=opt.auto)
if not opt.polys:
return result.as_expr()
else:
return result
@public
def content(f, *gens, **args):
"""
Compute GCD of coefficients of ``f``.
Examples
========
>>> from sympy import content
>>> from sympy.abc import x
>>> content(6*x**2 + 8*x + 12)
2
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('content', 1, exc)
return F.content()
@public
def primitive(f, *gens, **args):
"""
Compute content and the primitive form of ``f``.
Examples
========
>>> from sympy.polys.polytools import primitive
>>> from sympy.abc import x
>>> primitive(6*x**2 + 8*x + 12)
(2, 3*x**2 + 4*x + 6)
>>> eq = (2 + 2*x)*x + 2
Expansion is performed by default:
>>> primitive(eq)
(2, x**2 + x + 1)
Set ``expand`` to False to shut this off. Note that the
extraction will not be recursive; use the as_content_primitive method
for recursive, non-destructive Rational extraction.
>>> primitive(eq, expand=False)
(1, x*(2*x + 2) + 2)
>>> eq.as_content_primitive()
(2, x*(x + 1) + 1)
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('primitive', 1, exc)
cont, result = F.primitive()
if not opt.polys:
return cont, result.as_expr()
else:
return cont, result
@public
def compose(f, g, *gens, **args):
"""
Compute functional composition ``f(g)``.
Examples
========
>>> from sympy import compose
>>> from sympy.abc import x
>>> compose(x**2 + x, x - 1)
x**2 - x
"""
options.allowed_flags(args, ['polys'])
try:
(F, G), opt = parallel_poly_from_expr((f, g), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('compose', 2, exc)
result = F.compose(G)
if not opt.polys:
return result.as_expr()
else:
return result
@public
def decompose(f, *gens, **args):
"""
Compute functional decomposition of ``f``.
Examples
========
>>> from sympy import decompose
>>> from sympy.abc import x
>>> decompose(x**4 + 2*x**3 - x - 1)
[x**2 - x - 1, x**2 + x]
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('decompose', 1, exc)
result = F.decompose()
if not opt.polys:
return [r.as_expr() for r in result]
else:
return result
@public
def sturm(f, *gens, **args):
"""
Compute Sturm sequence of ``f``.
Examples
========
>>> from sympy import sturm
>>> from sympy.abc import x
>>> sturm(x**3 - 2*x**2 + x - 3)
[x**3 - 2*x**2 + x - 3, 3*x**2 - 4*x + 1, 2*x/9 + 25/9, -2079/4]
"""
options.allowed_flags(args, ['auto', 'polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('sturm', 1, exc)
result = F.sturm(auto=opt.auto)
if not opt.polys:
return [r.as_expr() for r in result]
else:
return result
@public
def gff_list(f, *gens, **args):
"""
Compute a list of greatest factorial factors of ``f``.
Note that the input to ff() and rf() should be Poly instances to use the
definitions here.
Examples
========
>>> from sympy import gff_list, ff, Poly
>>> from sympy.abc import x
>>> f = Poly(x**5 + 2*x**4 - x**3 - 2*x**2, x)
>>> gff_list(f)
[(Poly(x, x, domain='ZZ'), 1), (Poly(x + 2, x, domain='ZZ'), 4)]
>>> (ff(Poly(x), 1)*ff(Poly(x + 2), 4)) == f
True
>>> f = Poly(x**12 + 6*x**11 - 11*x**10 - 56*x**9 + 220*x**8 + 208*x**7 - \
1401*x**6 + 1090*x**5 + 2715*x**4 - 6720*x**3 - 1092*x**2 + 5040*x, x)
>>> gff_list(f)
[(Poly(x**3 + 7, x, domain='ZZ'), 2), (Poly(x**2 + 5*x, x, domain='ZZ'), 3)]
>>> ff(Poly(x**3 + 7, x), 2)*ff(Poly(x**2 + 5*x, x), 3) == f
True
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('gff_list', 1, exc)
factors = F.gff_list()
if not opt.polys:
return [(g.as_expr(), k) for g, k in factors]
else:
return factors
@public
def gff(f, *gens, **args):
"""Compute greatest factorial factorization of ``f``. """
raise NotImplementedError('symbolic falling factorial')
@public
def sqf_norm(f, *gens, **args):
"""
Compute square-free norm of ``f``.
Returns ``s``, ``f``, ``r``, such that ``g(x) = f(x-sa)`` and
``r(x) = Norm(g(x))`` is a square-free polynomial over ``K``,
where ``a`` is the algebraic extension of the ground domain.
Examples
========
>>> from sympy import sqf_norm, sqrt
>>> from sympy.abc import x
>>> sqf_norm(x**2 + 1, extension=[sqrt(3)])
(1, x**2 - 2*sqrt(3)*x + 4, x**4 - 4*x**2 + 16)
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('sqf_norm', 1, exc)
s, g, r = F.sqf_norm()
if not opt.polys:
return Integer(s), g.as_expr(), r.as_expr()
else:
return Integer(s), g, r
@public
def sqf_part(f, *gens, **args):
"""
Compute square-free part of ``f``.
Examples
========
>>> from sympy import sqf_part
>>> from sympy.abc import x
>>> sqf_part(x**3 - 3*x - 2)
x**2 - x - 2
"""
options.allowed_flags(args, ['polys'])
try:
F, opt = poly_from_expr(f, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('sqf_part', 1, exc)
result = F.sqf_part()
if not opt.polys:
return result.as_expr()
else:
return result
def _sorted_factors(factors, method):
"""Sort a list of ``(expr, exp)`` pairs. """
if method == 'sqf':
def key(obj):
poly, exp = obj
rep = poly.rep.rep
return (exp, len(rep), len(poly.gens), rep)
else:
def key(obj):
poly, exp = obj
rep = poly.rep.rep
return (len(rep), len(poly.gens), exp, rep)
return sorted(factors, key=key)
def _factors_product(factors):
"""Multiply a list of ``(expr, exp)`` pairs. """
return Mul(*[f.as_expr()**k for f, k in factors])
def _symbolic_factor_list(expr, opt, method):
"""Helper function for :func:`_symbolic_factor`. """
coeff, factors = S.One, []
args = [i._eval_factor() if hasattr(i, '_eval_factor') else i
for i in Mul.make_args(expr)]
for arg in args:
if arg.is_Number:
coeff *= arg
continue
elif arg.is_Pow:
base, exp = arg.args
if base.is_Number and exp.is_Number:
coeff *= arg
continue
if base.is_Number:
factors.append((base, exp))
continue
else:
base, exp = arg, S.One
try:
poly, _ = _poly_from_expr(base, opt)
except PolificationFailed as exc:
factors.append((exc.expr, exp))
else:
func = getattr(poly, method + '_list')
_coeff, _factors = func()
if _coeff is not S.One:
if exp.is_Integer:
coeff *= _coeff**exp
elif _coeff.is_positive:
factors.append((_coeff, exp))
else:
_factors.append((_coeff, S.One))
if exp is S.One:
factors.extend(_factors)
elif exp.is_integer:
factors.extend([(f, k*exp) for f, k in _factors])
else:
other = []
for f, k in _factors:
if f.as_expr().is_positive:
factors.append((f, k*exp))
else:
other.append((f, k))
factors.append((_factors_product(other), exp))
if method == 'sqf':
factors = [(reduce(mul, (f for f, _ in factors if _ == k)), k)
for k in set(i for _, i in factors)]
return coeff, factors
def _symbolic_factor(expr, opt, method):
"""Helper function for :func:`_factor`. """
if isinstance(expr, Expr):
if hasattr(expr,'_eval_factor'):
return expr._eval_factor()
coeff, factors = _symbolic_factor_list(together(expr, fraction=opt['fraction']), opt, method)
return _keep_coeff(coeff, _factors_product(factors))
elif hasattr(expr, 'args'):
return expr.func(*[_symbolic_factor(arg, opt, method) for arg in expr.args])
elif hasattr(expr, '__iter__'):
return expr.__class__([_symbolic_factor(arg, opt, method) for arg in expr])
else:
return expr
def _generic_factor_list(expr, gens, args, method):
"""Helper function for :func:`sqf_list` and :func:`factor_list`. """
options.allowed_flags(args, ['frac', 'polys'])
opt = options.build_options(gens, args)
expr = sympify(expr)
if isinstance(expr, (Expr, Poly)):
if isinstance(expr, Poly):
numer, denom = expr, 1
else:
numer, denom = together(expr).as_numer_denom()
cp, fp = _symbolic_factor_list(numer, opt, method)
cq, fq = _symbolic_factor_list(denom, opt, method)
if fq and not opt.frac:
raise PolynomialError("a polynomial expected, got %s" % expr)
_opt = opt.clone(dict(expand=True))
for factors in (fp, fq):
for i, (f, k) in enumerate(factors):
if not f.is_Poly:
f, _ = _poly_from_expr(f, _opt)
factors[i] = (f, k)
fp = _sorted_factors(fp, method)
fq = _sorted_factors(fq, method)
if not opt.polys:
fp = [(f.as_expr(), k) for f, k in fp]
fq = [(f.as_expr(), k) for f, k in fq]
coeff = cp/cq
if not opt.frac:
return coeff, fp
else:
return coeff, fp, fq
else:
raise PolynomialError("a polynomial expected, got %s" % expr)
def _generic_factor(expr, gens, args, method):
"""Helper function for :func:`sqf` and :func:`factor`. """
fraction = args.pop('fraction', True)
options.allowed_flags(args, [])
opt = options.build_options(gens, args)
opt['fraction'] = fraction
return _symbolic_factor(sympify(expr), opt, method)
def to_rational_coeffs(f):
"""
try to transform a polynomial to have rational coefficients
try to find a transformation ``x = alpha*y``
``f(x) = lc*alpha**n * g(y)`` where ``g`` is a polynomial with
rational coefficients, ``lc`` the leading coefficient.
If this fails, try ``x = y + beta``
``f(x) = g(y)``
Returns ``None`` if ``g`` not found;
``(lc, alpha, None, g)`` in case of rescaling
``(None, None, beta, g)`` in case of translation
Notes
=====
Currently it transforms only polynomials without roots larger than 2.
Examples
========
>>> from sympy import sqrt, Poly, simplify
>>> from sympy.polys.polytools import to_rational_coeffs
>>> from sympy.abc import x
>>> p = Poly(((x**2-1)*(x-2)).subs({x:x*(1 + sqrt(2))}), x, domain='EX')
>>> lc, r, _, g = to_rational_coeffs(p)
>>> lc, r
(7 + 5*sqrt(2), 2 - 2*sqrt(2))
>>> g
Poly(x**3 + x**2 - 1/4*x - 1/4, x, domain='QQ')
>>> r1 = simplify(1/r)
>>> Poly(lc*r**3*(g.as_expr()).subs({x:x*r1}), x, domain='EX') == p
True
"""
from sympy.simplify.simplify import simplify
def _try_rescale(f, f1=None):
"""
try rescaling ``x -> alpha*x`` to convert f to a polynomial
with rational coefficients.
Returns ``alpha, f``; if the rescaling is successful,
``alpha`` is the rescaling factor, and ``f`` is the rescaled
polynomial; else ``alpha`` is ``None``.
"""
from sympy.core.add import Add
if not len(f.gens) == 1 or not (f.gens[0]).is_Atom:
return None, f
n = f.degree()
lc = f.LC()
f1 = f1 or f1.monic()
coeffs = f1.all_coeffs()[1:]
coeffs = [simplify(coeffx) for coeffx in coeffs]
if coeffs[-2]:
rescale1_x = simplify(coeffs[-2]/coeffs[-1])
coeffs1 = []
for i in range(len(coeffs)):
coeffx = simplify(coeffs[i]*rescale1_x**(i + 1))
if not coeffx.is_rational:
break
coeffs1.append(coeffx)
else:
rescale_x = simplify(1/rescale1_x)
x = f.gens[0]
v = [x**n]
for i in range(1, n + 1):
v.append(coeffs1[i - 1]*x**(n - i))
f = Add(*v)
f = Poly(f)
return lc, rescale_x, f
return None
def _try_translate(f, f1=None):
"""
try translating ``x -> x + alpha`` to convert f to a polynomial
with rational coefficients.
Returns ``alpha, f``; if the translating is successful,
``alpha`` is the translating factor, and ``f`` is the shifted
polynomial; else ``alpha`` is ``None``.
"""
from sympy.core.add import Add
if not len(f.gens) == 1 or not (f.gens[0]).is_Atom:
return None, f
n = f.degree()
f1 = f1 or f1.monic()
coeffs = f1.all_coeffs()[1:]
c = simplify(coeffs[0])
if c and not c.is_rational:
func = Add
if c.is_Add:
args = c.args
func = c.func
else:
args = [c]
c1, c2 = sift(args, lambda z: z.is_rational, binary=True)
alpha = -func(*c2)/n
f2 = f1.shift(alpha)
return alpha, f2
return None
def _has_square_roots(p):
"""
Return True if ``f`` is a sum with square roots but no other root
"""
from sympy.core.exprtools import Factors
coeffs = p.coeffs()
has_sq = False
for y in coeffs:
for x in Add.make_args(y):
f = Factors(x).factors
r = [wx.q for b, wx in f.items() if
b.is_number and wx.is_Rational and wx.q >= 2]
if not r:
continue
if min(r) == 2:
has_sq = True
if max(r) > 2:
return False
return has_sq
if f.get_domain().is_EX and _has_square_roots(f):
f1 = f.monic()
r = _try_rescale(f, f1)
if r:
return r[0], r[1], None, r[2]
else:
r = _try_translate(f, f1)
if r:
return None, None, r[0], r[1]
return None
def _torational_factor_list(p, x):
"""
helper function to factor polynomial using to_rational_coeffs
Examples
========
>>> from sympy.polys.polytools import _torational_factor_list
>>> from sympy.abc import x
>>> from sympy import sqrt, expand, Mul
>>> p = expand(((x**2-1)*(x-2)).subs({x:x*(1 + sqrt(2))}))
>>> factors = _torational_factor_list(p, x); factors
(-2, [(-x*(1 + sqrt(2))/2 + 1, 1), (-x*(1 + sqrt(2)) - 1, 1), (-x*(1 + sqrt(2)) + 1, 1)])
>>> expand(factors[0]*Mul(*[z[0] for z in factors[1]])) == p
True
>>> p = expand(((x**2-1)*(x-2)).subs({x:x + sqrt(2)}))
>>> factors = _torational_factor_list(p, x); factors
(1, [(x - 2 + sqrt(2), 1), (x - 1 + sqrt(2), 1), (x + 1 + sqrt(2), 1)])
>>> expand(factors[0]*Mul(*[z[0] for z in factors[1]])) == p
True
"""
from sympy.simplify.simplify import simplify
p1 = Poly(p, x, domain='EX')
n = p1.degree()
res = to_rational_coeffs(p1)
if not res:
return None
lc, r, t, g = res
factors = factor_list(g.as_expr())
if lc:
c = simplify(factors[0]*lc*r**n)
r1 = simplify(1/r)
a = []
for z in factors[1:][0]:
a.append((simplify(z[0].subs({x: x*r1})), z[1]))
else:
c = factors[0]
a = []
for z in factors[1:][0]:
a.append((z[0].subs({x: x - t}), z[1]))
return (c, a)
@public
def sqf_list(f, *gens, **args):
"""
Compute a list of square-free factors of ``f``.
Examples
========
>>> from sympy import sqf_list
>>> from sympy.abc import x
>>> sqf_list(2*x**5 + 16*x**4 + 50*x**3 + 76*x**2 + 56*x + 16)
(2, [(x + 1, 2), (x + 2, 3)])
"""
return _generic_factor_list(f, gens, args, method='sqf')
@public
def sqf(f, *gens, **args):
"""
Compute square-free factorization of ``f``.
Examples
========
>>> from sympy import sqf
>>> from sympy.abc import x
>>> sqf(2*x**5 + 16*x**4 + 50*x**3 + 76*x**2 + 56*x + 16)
2*(x + 1)**2*(x + 2)**3
"""
return _generic_factor(f, gens, args, method='sqf')
@public
def factor_list(f, *gens, **args):
"""
Compute a list of irreducible factors of ``f``.
Examples
========
>>> from sympy import factor_list
>>> from sympy.abc import x, y
>>> factor_list(2*x**5 + 2*x**4*y + 4*x**3 + 4*x**2*y + 2*x + 2*y)
(2, [(x + y, 1), (x**2 + 1, 2)])
"""
return _generic_factor_list(f, gens, args, method='factor')
@public
def factor(f, *gens, **args):
"""
Compute the factorization of expression, ``f``, into irreducibles. (To
factor an integer into primes, use ``factorint``.)
There two modes implemented: symbolic and formal. If ``f`` is not an
instance of :class:`Poly` and generators are not specified, then the
former mode is used. Otherwise, the formal mode is used.
In symbolic mode, :func:`factor` will traverse the expression tree and
factor its components without any prior expansion, unless an instance
of :class:`~.Add` is encountered (in this case formal factorization is
used). This way :func:`factor` can handle large or symbolic exponents.
By default, the factorization is computed over the rationals. To factor
over other domain, e.g. an algebraic or finite field, use appropriate
options: ``extension``, ``modulus`` or ``domain``.
Examples
========
>>> from sympy import factor, sqrt, exp
>>> from sympy.abc import x, y
>>> factor(2*x**5 + 2*x**4*y + 4*x**3 + 4*x**2*y + 2*x + 2*y)
2*(x + y)*(x**2 + 1)**2
>>> factor(x**2 + 1)
x**2 + 1
>>> factor(x**2 + 1, modulus=2)
(x + 1)**2
>>> factor(x**2 + 1, gaussian=True)
(x - I)*(x + I)
>>> factor(x**2 - 2, extension=sqrt(2))
(x - sqrt(2))*(x + sqrt(2))
>>> factor((x**2 - 1)/(x**2 + 4*x + 4))
(x - 1)*(x + 1)/(x + 2)**2
>>> factor((x**2 + 4*x + 4)**10000000*(x**2 + 1))
(x + 2)**20000000*(x**2 + 1)
By default, factor deals with an expression as a whole:
>>> eq = 2**(x**2 + 2*x + 1)
>>> factor(eq)
2**(x**2 + 2*x + 1)
If the ``deep`` flag is True then subexpressions will
be factored:
>>> factor(eq, deep=True)
2**((x + 1)**2)
If the ``fraction`` flag is False then rational expressions
won't be combined. By default it is True.
>>> factor(5*x + 3*exp(2 - 7*x), deep=True)
(5*x*exp(7*x) + 3*exp(2))*exp(-7*x)
>>> factor(5*x + 3*exp(2 - 7*x), deep=True, fraction=False)
5*x + 3*exp(2)*exp(-7*x)
See Also
========
sympy.ntheory.factor_.factorint
"""
f = sympify(f)
if args.pop('deep', False):
from sympy.simplify.simplify import bottom_up
def _try_factor(expr):
"""
Factor, but avoid changing the expression when unable to.
"""
fac = factor(expr, *gens, **args)
if fac.is_Mul or fac.is_Pow:
return fac
return expr
f = bottom_up(f, _try_factor)
# clean up any subexpressions that may have been expanded
# while factoring out a larger expression
partials = {}
muladd = f.atoms(Mul, Add)
for p in muladd:
fac = factor(p, *gens, **args)
if (fac.is_Mul or fac.is_Pow) and fac != p:
partials[p] = fac
return f.xreplace(partials)
try:
return _generic_factor(f, gens, args, method='factor')
except PolynomialError as msg:
if not f.is_commutative:
from sympy.core.exprtools import factor_nc
return factor_nc(f)
else:
raise PolynomialError(msg)
@public
def intervals(F, all=False, eps=None, inf=None, sup=None, strict=False, fast=False, sqf=False):
"""
Compute isolating intervals for roots of ``f``.
Examples
========
>>> from sympy import intervals
>>> from sympy.abc import x
>>> intervals(x**2 - 3)
[((-2, -1), 1), ((1, 2), 1)]
>>> intervals(x**2 - 3, eps=1e-2)
[((-26/15, -19/11), 1), ((19/11, 26/15), 1)]
"""
if not hasattr(F, '__iter__'):
try:
F = Poly(F)
except GeneratorsNeeded:
return []
return F.intervals(all=all, eps=eps, inf=inf, sup=sup, fast=fast, sqf=sqf)
else:
polys, opt = parallel_poly_from_expr(F, domain='QQ')
if len(opt.gens) > 1:
raise MultivariatePolynomialError
for i, poly in enumerate(polys):
polys[i] = poly.rep.rep
if eps is not None:
eps = opt.domain.convert(eps)
if eps <= 0:
raise ValueError("'eps' must be a positive rational")
if inf is not None:
inf = opt.domain.convert(inf)
if sup is not None:
sup = opt.domain.convert(sup)
intervals = dup_isolate_real_roots_list(polys, opt.domain,
eps=eps, inf=inf, sup=sup, strict=strict, fast=fast)
result = []
for (s, t), indices in intervals:
s, t = opt.domain.to_sympy(s), opt.domain.to_sympy(t)
result.append(((s, t), indices))
return result
@public
def refine_root(f, s, t, eps=None, steps=None, fast=False, check_sqf=False):
"""
Refine an isolating interval of a root to the given precision.
Examples
========
>>> from sympy import refine_root
>>> from sympy.abc import x
>>> refine_root(x**2 - 3, 1, 2, eps=1e-2)
(19/11, 26/15)
"""
try:
F = Poly(f)
if not isinstance(f, Poly) and not F.gen.is_Symbol:
# root of sin(x) + 1 is -1 but when someone
# passes an Expr instead of Poly they may not expect
# that the generator will be sin(x), not x
raise PolynomialError("generator must be a Symbol")
except GeneratorsNeeded:
raise PolynomialError(
"can't refine a root of %s, not a polynomial" % f)
return F.refine_root(s, t, eps=eps, steps=steps, fast=fast, check_sqf=check_sqf)
@public
def count_roots(f, inf=None, sup=None):
"""
Return the number of roots of ``f`` in ``[inf, sup]`` interval.
If one of ``inf`` or ``sup`` is complex, it will return the number of roots
in the complex rectangle with corners at ``inf`` and ``sup``.
Examples
========
>>> from sympy import count_roots, I
>>> from sympy.abc import x
>>> count_roots(x**4 - 4, -3, 3)
2
>>> count_roots(x**4 - 4, 0, 1 + 3*I)
1
"""
try:
F = Poly(f, greedy=False)
if not isinstance(f, Poly) and not F.gen.is_Symbol:
# root of sin(x) + 1 is -1 but when someone
# passes an Expr instead of Poly they may not expect
# that the generator will be sin(x), not x
raise PolynomialError("generator must be a Symbol")
except GeneratorsNeeded:
raise PolynomialError("can't count roots of %s, not a polynomial" % f)
return F.count_roots(inf=inf, sup=sup)
@public
def real_roots(f, multiple=True):
"""
Return a list of real roots with multiplicities of ``f``.
Examples
========
>>> from sympy import real_roots
>>> from sympy.abc import x
>>> real_roots(2*x**3 - 7*x**2 + 4*x + 4)
[-1/2, 2, 2]
"""
try:
F = Poly(f, greedy=False)
if not isinstance(f, Poly) and not F.gen.is_Symbol:
# root of sin(x) + 1 is -1 but when someone
# passes an Expr instead of Poly they may not expect
# that the generator will be sin(x), not x
raise PolynomialError("generator must be a Symbol")
except GeneratorsNeeded:
raise PolynomialError(
"can't compute real roots of %s, not a polynomial" % f)
return F.real_roots(multiple=multiple)
@public
def nroots(f, n=15, maxsteps=50, cleanup=True):
"""
Compute numerical approximations of roots of ``f``.
Examples
========
>>> from sympy import nroots
>>> from sympy.abc import x
>>> nroots(x**2 - 3, n=15)
[-1.73205080756888, 1.73205080756888]
>>> nroots(x**2 - 3, n=30)
[-1.73205080756887729352744634151, 1.73205080756887729352744634151]
"""
try:
F = Poly(f, greedy=False)
if not isinstance(f, Poly) and not F.gen.is_Symbol:
# root of sin(x) + 1 is -1 but when someone
# passes an Expr instead of Poly they may not expect
# that the generator will be sin(x), not x
raise PolynomialError("generator must be a Symbol")
except GeneratorsNeeded:
raise PolynomialError(
"can't compute numerical roots of %s, not a polynomial" % f)
return F.nroots(n=n, maxsteps=maxsteps, cleanup=cleanup)
@public
def ground_roots(f, *gens, **args):
"""
Compute roots of ``f`` by factorization in the ground domain.
Examples
========
>>> from sympy import ground_roots
>>> from sympy.abc import x
>>> ground_roots(x**6 - 4*x**4 + 4*x**3 - x**2)
{0: 2, 1: 2}
"""
options.allowed_flags(args, [])
try:
F, opt = poly_from_expr(f, *gens, **args)
if not isinstance(f, Poly) and not F.gen.is_Symbol:
# root of sin(x) + 1 is -1 but when someone
# passes an Expr instead of Poly they may not expect
# that the generator will be sin(x), not x
raise PolynomialError("generator must be a Symbol")
except PolificationFailed as exc:
raise ComputationFailed('ground_roots', 1, exc)
return F.ground_roots()
@public
def nth_power_roots_poly(f, n, *gens, **args):
"""
Construct a polynomial with n-th powers of roots of ``f``.
Examples
========
>>> from sympy import nth_power_roots_poly, factor, roots
>>> from sympy.abc import x
>>> f = x**4 - x**2 + 1
>>> g = factor(nth_power_roots_poly(f, 2))
>>> g
(x**2 - x + 1)**2
>>> R_f = [ (r**2).expand() for r in roots(f) ]
>>> R_g = roots(g).keys()
>>> set(R_f) == set(R_g)
True
"""
options.allowed_flags(args, [])
try:
F, opt = poly_from_expr(f, *gens, **args)
if not isinstance(f, Poly) and not F.gen.is_Symbol:
# root of sin(x) + 1 is -1 but when someone
# passes an Expr instead of Poly they may not expect
# that the generator will be sin(x), not x
raise PolynomialError("generator must be a Symbol")
except PolificationFailed as exc:
raise ComputationFailed('nth_power_roots_poly', 1, exc)
result = F.nth_power_roots_poly(n)
if not opt.polys:
return result.as_expr()
else:
return result
@public
def cancel(f, *gens, **args):
"""
Cancel common factors in a rational function ``f``.
Examples
========
>>> from sympy import cancel, sqrt, Symbol, together
>>> from sympy.abc import x
>>> A = Symbol('A', commutative=False)
>>> cancel((2*x**2 - 2)/(x**2 - 2*x + 1))
(2*x + 2)/(x - 1)
>>> cancel((sqrt(3) + sqrt(15)*A)/(sqrt(2) + sqrt(10)*A))
sqrt(6)/2
Note: due to automatic distribution of Rationals, a sum divided by an integer
will appear as a sum. To recover a rational form use `together` on the result:
>>> cancel(x/2 + 1)
x/2 + 1
>>> together(_)
(x + 2)/2
"""
from sympy.core.exprtools import factor_terms
from sympy.functions.elementary.piecewise import Piecewise
options.allowed_flags(args, ['polys'])
f = sympify(f)
if not isinstance(f, (tuple, Tuple)):
if f.is_Number or isinstance(f, Relational) or not isinstance(f, Expr):
return f
f = factor_terms(f, radical=True)
p, q = f.as_numer_denom()
elif len(f) == 2:
p, q = f
elif isinstance(f, Tuple):
return factor_terms(f)
else:
raise ValueError('unexpected argument: %s' % f)
try:
(F, G), opt = parallel_poly_from_expr((p, q), *gens, **args)
except PolificationFailed:
if not isinstance(f, (tuple, Tuple)):
return f.expand()
else:
return S.One, p, q
except PolynomialError as msg:
if f.is_commutative and not f.has(Piecewise):
raise PolynomialError(msg)
# Handling of noncommutative and/or piecewise expressions
if f.is_Add or f.is_Mul:
c, nc = sift(f.args, lambda x:
x.is_commutative is True and not x.has(Piecewise),
binary=True)
nc = [cancel(i) for i in nc]
return f.func(cancel(f.func(*c)), *nc)
else:
reps = []
pot = preorder_traversal(f)
next(pot)
for e in pot:
# XXX: This should really skip anything that's not Expr.
if isinstance(e, (tuple, Tuple, BooleanAtom)):
continue
try:
reps.append((e, cancel(e)))
pot.skip() # this was handled successfully
except NotImplementedError:
pass
return f.xreplace(dict(reps))
c, P, Q = F.cancel(G)
if not isinstance(f, (tuple, Tuple)):
return c*(P.as_expr()/Q.as_expr())
else:
if not opt.polys:
return c, P.as_expr(), Q.as_expr()
else:
return c, P, Q
@public
def reduced(f, G, *gens, **args):
"""
Reduces a polynomial ``f`` modulo a set of polynomials ``G``.
Given a polynomial ``f`` and a set of polynomials ``G = (g_1, ..., g_n)``,
computes a set of quotients ``q = (q_1, ..., q_n)`` and the remainder ``r``
such that ``f = q_1*g_1 + ... + q_n*g_n + r``, where ``r`` vanishes or ``r``
is a completely reduced polynomial with respect to ``G``.
Examples
========
>>> from sympy import reduced
>>> from sympy.abc import x, y
>>> reduced(2*x**4 + y**2 - x**2 + y**3, [x**3 - x, y**3 - y])
([2*x, 1], x**2 + y**2 + y)
"""
options.allowed_flags(args, ['polys', 'auto'])
try:
polys, opt = parallel_poly_from_expr([f] + list(G), *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('reduced', 0, exc)
domain = opt.domain
retract = False
if opt.auto and domain.is_Ring and not domain.is_Field:
opt = opt.clone(dict(domain=domain.get_field()))
retract = True
from sympy.polys.rings import xring
_ring, _ = xring(opt.gens, opt.domain, opt.order)
for i, poly in enumerate(polys):
poly = poly.set_domain(opt.domain).rep.to_dict()
polys[i] = _ring.from_dict(poly)
Q, r = polys[0].div(polys[1:])
Q = [Poly._from_dict(dict(q), opt) for q in Q]
r = Poly._from_dict(dict(r), opt)
if retract:
try:
_Q, _r = [q.to_ring() for q in Q], r.to_ring()
except CoercionFailed:
pass
else:
Q, r = _Q, _r
if not opt.polys:
return [q.as_expr() for q in Q], r.as_expr()
else:
return Q, r
@public
def groebner(F, *gens, **args):
"""
Computes the reduced Groebner basis for a set of polynomials.
Use the ``order`` argument to set the monomial ordering that will be
used to compute the basis. Allowed orders are ``lex``, ``grlex`` and
``grevlex``. If no order is specified, it defaults to ``lex``.
For more information on Groebner bases, see the references and the docstring
of :func:`~.solve_poly_system`.
Examples
========
Example taken from [1].
>>> from sympy import groebner
>>> from sympy.abc import x, y
>>> F = [x*y - 2*y, 2*y**2 - x**2]
>>> groebner(F, x, y, order='lex')
GroebnerBasis([x**2 - 2*y**2, x*y - 2*y, y**3 - 2*y], x, y,
domain='ZZ', order='lex')
>>> groebner(F, x, y, order='grlex')
GroebnerBasis([y**3 - 2*y, x**2 - 2*y**2, x*y - 2*y], x, y,
domain='ZZ', order='grlex')
>>> groebner(F, x, y, order='grevlex')
GroebnerBasis([y**3 - 2*y, x**2 - 2*y**2, x*y - 2*y], x, y,
domain='ZZ', order='grevlex')
By default, an improved implementation of the Buchberger algorithm is
used. Optionally, an implementation of the F5B algorithm can be used. The
algorithm can be set using the ``method`` flag or with the
:func:`sympy.polys.polyconfig.setup` function.
>>> F = [x**2 - x - 1, (2*x - 1) * y - (x**10 - (1 - x)**10)]
>>> groebner(F, x, y, method='buchberger')
GroebnerBasis([x**2 - x - 1, y - 55], x, y, domain='ZZ', order='lex')
>>> groebner(F, x, y, method='f5b')
GroebnerBasis([x**2 - x - 1, y - 55], x, y, domain='ZZ', order='lex')
References
==========
1. [Buchberger01]_
2. [Cox97]_
"""
return GroebnerBasis(F, *gens, **args)
@public
def is_zero_dimensional(F, *gens, **args):
"""
Checks if the ideal generated by a Groebner basis is zero-dimensional.
The algorithm checks if the set of monomials not divisible by the
leading monomial of any element of ``F`` is bounded.
References
==========
David A. Cox, John B. Little, Donal O'Shea. Ideals, Varieties and
Algorithms, 3rd edition, p. 230
"""
return GroebnerBasis(F, *gens, **args).is_zero_dimensional
@public
class GroebnerBasis(Basic):
"""Represents a reduced Groebner basis. """
def __new__(cls, F, *gens, **args):
"""Compute a reduced Groebner basis for a system of polynomials. """
options.allowed_flags(args, ['polys', 'method'])
try:
polys, opt = parallel_poly_from_expr(F, *gens, **args)
except PolificationFailed as exc:
raise ComputationFailed('groebner', len(F), exc)
from sympy.polys.rings import PolyRing
ring = PolyRing(opt.gens, opt.domain, opt.order)
polys = [ring.from_dict(poly.rep.to_dict()) for poly in polys if poly]
G = _groebner(polys, ring, method=opt.method)
G = [Poly._from_dict(g, opt) for g in G]
return cls._new(G, opt)
@classmethod
def _new(cls, basis, options):
obj = Basic.__new__(cls)
obj._basis = tuple(basis)
obj._options = options
return obj
@property
def args(self):
basis = (p.as_expr() for p in self._basis)
return (Tuple(*basis), Tuple(*self._options.gens))
@property
def exprs(self):
return [poly.as_expr() for poly in self._basis]
@property
def polys(self):
return list(self._basis)
@property
def gens(self):
return self._options.gens
@property
def domain(self):
return self._options.domain
@property
def order(self):
return self._options.order
def __len__(self):
return len(self._basis)
def __iter__(self):
if self._options.polys:
return iter(self.polys)
else:
return iter(self.exprs)
def __getitem__(self, item):
if self._options.polys:
basis = self.polys
else:
basis = self.exprs
return basis[item]
def __hash__(self):
return hash((self._basis, tuple(self._options.items())))
def __eq__(self, other):
if isinstance(other, self.__class__):
return self._basis == other._basis and self._options == other._options
elif iterable(other):
return self.polys == list(other) or self.exprs == list(other)
else:
return False
def __ne__(self, other):
return not self == other
@property
def is_zero_dimensional(self):
"""
Checks if the ideal generated by a Groebner basis is zero-dimensional.
The algorithm checks if the set of monomials not divisible by the
leading monomial of any element of ``F`` is bounded.
References
==========
David A. Cox, John B. Little, Donal O'Shea. Ideals, Varieties and
Algorithms, 3rd edition, p. 230
"""
def single_var(monomial):
return sum(map(bool, monomial)) == 1
exponents = Monomial([0]*len(self.gens))
order = self._options.order
for poly in self.polys:
monomial = poly.LM(order=order)
if single_var(monomial):
exponents *= monomial
# If any element of the exponents vector is zero, then there's
# a variable for which there's no degree bound and the ideal
# generated by this Groebner basis isn't zero-dimensional.
return all(exponents)
def fglm(self, order):
"""
Convert a Groebner basis from one ordering to another.
The FGLM algorithm converts reduced Groebner bases of zero-dimensional
ideals from one ordering to another. This method is often used when it
is infeasible to compute a Groebner basis with respect to a particular
ordering directly.
Examples
========
>>> from sympy.abc import x, y
>>> from sympy import groebner
>>> F = [x**2 - 3*y - x + 1, y**2 - 2*x + y - 1]
>>> G = groebner(F, x, y, order='grlex')
>>> list(G.fglm('lex'))
[2*x - y**2 - y + 1, y**4 + 2*y**3 - 3*y**2 - 16*y + 7]
>>> list(groebner(F, x, y, order='lex'))
[2*x - y**2 - y + 1, y**4 + 2*y**3 - 3*y**2 - 16*y + 7]
References
==========
.. [1] J.C. Faugere, P. Gianni, D. Lazard, T. Mora (1994). Efficient
Computation of Zero-dimensional Groebner Bases by Change of
Ordering
"""
opt = self._options
src_order = opt.order
dst_order = monomial_key(order)
if src_order == dst_order:
return self
if not self.is_zero_dimensional:
raise NotImplementedError("can't convert Groebner bases of ideals with positive dimension")
polys = list(self._basis)
domain = opt.domain
opt = opt.clone(dict(
domain=domain.get_field(),
order=dst_order,
))
from sympy.polys.rings import xring
_ring, _ = xring(opt.gens, opt.domain, src_order)
for i, poly in enumerate(polys):
poly = poly.set_domain(opt.domain).rep.to_dict()
polys[i] = _ring.from_dict(poly)
G = matrix_fglm(polys, _ring, dst_order)
G = [Poly._from_dict(dict(g), opt) for g in G]
if not domain.is_Field:
G = [g.clear_denoms(convert=True)[1] for g in G]
opt.domain = domain
return self._new(G, opt)
def reduce(self, expr, auto=True):
"""
Reduces a polynomial modulo a Groebner basis.
Given a polynomial ``f`` and a set of polynomials ``G = (g_1, ..., g_n)``,
computes a set of quotients ``q = (q_1, ..., q_n)`` and the remainder ``r``
such that ``f = q_1*f_1 + ... + q_n*f_n + r``, where ``r`` vanishes or ``r``
is a completely reduced polynomial with respect to ``G``.
Examples
========
>>> from sympy import groebner, expand
>>> from sympy.abc import x, y
>>> f = 2*x**4 - x**2 + y**3 + y**2
>>> G = groebner([x**3 - x, y**3 - y])
>>> G.reduce(f)
([2*x, 1], x**2 + y**2 + y)
>>> Q, r = _
>>> expand(sum(q*g for q, g in zip(Q, G)) + r)
2*x**4 - x**2 + y**3 + y**2
>>> _ == f
True
"""
poly = Poly._from_expr(expr, self._options)
polys = [poly] + list(self._basis)
opt = self._options
domain = opt.domain
retract = False
if auto and domain.is_Ring and not domain.is_Field:
opt = opt.clone(dict(domain=domain.get_field()))
retract = True
from sympy.polys.rings import xring
_ring, _ = xring(opt.gens, opt.domain, opt.order)
for i, poly in enumerate(polys):
poly = poly.set_domain(opt.domain).rep.to_dict()
polys[i] = _ring.from_dict(poly)
Q, r = polys[0].div(polys[1:])
Q = [Poly._from_dict(dict(q), opt) for q in Q]
r = Poly._from_dict(dict(r), opt)
if retract:
try:
_Q, _r = [q.to_ring() for q in Q], r.to_ring()
except CoercionFailed:
pass
else:
Q, r = _Q, _r
if not opt.polys:
return [q.as_expr() for q in Q], r.as_expr()
else:
return Q, r
def contains(self, poly):
"""
Check if ``poly`` belongs the ideal generated by ``self``.
Examples
========
>>> from sympy import groebner
>>> from sympy.abc import x, y
>>> f = 2*x**3 + y**3 + 3*y
>>> G = groebner([x**2 + y**2 - 1, x*y - 2])
>>> G.contains(f)
True
>>> G.contains(f + 1)
False
"""
return self.reduce(poly)[1] == 0
@public
def poly(expr, *gens, **args):
"""
Efficiently transform an expression into a polynomial.
Examples
========
>>> from sympy import poly
>>> from sympy.abc import x
>>> poly(x*(x**2 + x - 1)**2)
Poly(x**5 + 2*x**4 - x**3 - 2*x**2 + x, x, domain='ZZ')
"""
options.allowed_flags(args, [])
def _poly(expr, opt):
terms, poly_terms = [], []
for term in Add.make_args(expr):
factors, poly_factors = [], []
for factor in Mul.make_args(term):
if factor.is_Add:
poly_factors.append(_poly(factor, opt))
elif factor.is_Pow and factor.base.is_Add and \
factor.exp.is_Integer and factor.exp >= 0:
poly_factors.append(
_poly(factor.base, opt).pow(factor.exp))
else:
factors.append(factor)
if not poly_factors:
terms.append(term)
else:
product = poly_factors[0]
for factor in poly_factors[1:]:
product = product.mul(factor)
if factors:
factor = Mul(*factors)
if factor.is_Number:
product = product.mul(factor)
else:
product = product.mul(Poly._from_expr(factor, opt))
poly_terms.append(product)
if not poly_terms:
result = Poly._from_expr(expr, opt)
else:
result = poly_terms[0]
for term in poly_terms[1:]:
result = result.add(term)
if terms:
term = Add(*terms)
if term.is_Number:
result = result.add(term)
else:
result = result.add(Poly._from_expr(term, opt))
return result.reorder(*opt.get('gens', ()), **args)
expr = sympify(expr)
if expr.is_Poly:
return Poly(expr, *gens, **args)
if 'expand' not in args:
args['expand'] = False
opt = options.build_options(gens, args)
return _poly(expr, opt)
|
15bcde60895bbc47721d8780a3a8947e9f9e17558690c80ba5a201fb3f449bb4 | """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, 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(q/p*sqrt(-3/p)*Rational(3, 2))/3 - k*pi*Rational(2, 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.One
u2 = Rational(-1, 2) + coeff
u3 = Rational(-1, 2) - 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*(Rational(-1, 2) + coeff)
u3 = u1*(Rational(-1, 2) - 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
>>> 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 = e*Rational(-5, 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 = e*Rational(-5, 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.expr == g.expr:
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
else:
return [] # fall back to normal solve
# 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 not isinstance(f, Poly) and not F.gen.is_Symbol:
raise PolynomialError("generator must be a Symbol")
else:
f = F
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.Zero]*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.Zero: 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
if filter not in [None, 'C']:
handlers = {
'Z': lambda r: r.is_Integer,
'Q': lambda r: r.is_Rational,
'R': lambda r: all(a.is_real for a in r.as_numer_denom()),
'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
# adding zero roots after non-trivial roots have been translated
result.update(zeros)
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
|
3fcbdfc8130651de06cdd6e427bab778ddb5369c40cb2f18ea9eb4d7f01565ac | """Dense univariate polynomials with coefficients in Galois fields. """
from __future__ import print_function, division
from random import uniform
from math import ceil as _ceil, sqrt as _sqrt
from sympy.core.compatibility import SYMPY_INTS
from sympy.core.mul import prod
from sympy.ntheory import factorint
from sympy.polys.polyconfig import query
from sympy.polys.polyerrors import ExactQuotientFailed
from sympy.polys.polyutils import _sort_factors
def gf_crt(U, M, K=None):
"""
Chinese Remainder Theorem.
Given a set of integer residues ``u_0,...,u_n`` and a set of
co-prime integer moduli ``m_0,...,m_n``, returns an integer
``u``, such that ``u = u_i mod m_i`` for ``i = ``0,...,n``.
Examples
========
Consider a set of residues ``U = [49, 76, 65]``
and a set of moduli ``M = [99, 97, 95]``. Then we have::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_crt
>>> gf_crt([49, 76, 65], [99, 97, 95], ZZ)
639985
This is the correct result because::
>>> [639985 % m for m in [99, 97, 95]]
[49, 76, 65]
Note: this is a low-level routine with no error checking.
See Also
========
sympy.ntheory.modular.crt : a higher level crt routine
sympy.ntheory.modular.solve_congruence
"""
p = prod(M, start=K.one)
v = K.zero
for u, m in zip(U, M):
e = p // m
s, _, _ = K.gcdex(e, m)
v += e*(u*s % m)
return v % p
def gf_crt1(M, K):
"""
First part of the Chinese Remainder Theorem.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_crt1
>>> gf_crt1([99, 97, 95], ZZ)
(912285, [9215, 9405, 9603], [62, 24, 12])
"""
E, S = [], []
p = prod(M, start=K.one)
for m in M:
E.append(p // m)
S.append(K.gcdex(E[-1], m)[0] % m)
return p, E, S
def gf_crt2(U, M, p, E, S, K):
"""
Second part of the Chinese Remainder Theorem.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_crt2
>>> U = [49, 76, 65]
>>> M = [99, 97, 95]
>>> p = 912285
>>> E = [9215, 9405, 9603]
>>> S = [62, 24, 12]
>>> gf_crt2(U, M, p, E, S, ZZ)
639985
"""
v = K.zero
for u, m, e, s in zip(U, M, E, S):
v += e*(u*s % m)
return v % p
def gf_int(a, p):
"""
Coerce ``a mod p`` to an integer in the range ``[-p/2, p/2]``.
Examples
========
>>> from sympy.polys.galoistools import gf_int
>>> gf_int(2, 7)
2
>>> gf_int(5, 7)
-2
"""
if a <= p // 2:
return a
else:
return a - p
def gf_degree(f):
"""
Return the leading degree of ``f``.
Examples
========
>>> from sympy.polys.galoistools import gf_degree
>>> gf_degree([1, 1, 2, 0])
3
>>> gf_degree([])
-1
"""
return len(f) - 1
def gf_LC(f, K):
"""
Return the leading coefficient of ``f``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_LC
>>> gf_LC([3, 0, 1], ZZ)
3
"""
if not f:
return K.zero
else:
return f[0]
def gf_TC(f, K):
"""
Return the trailing coefficient of ``f``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_TC
>>> gf_TC([3, 0, 1], ZZ)
1
"""
if not f:
return K.zero
else:
return f[-1]
def gf_strip(f):
"""
Remove leading zeros from ``f``.
Examples
========
>>> from sympy.polys.galoistools import gf_strip
>>> gf_strip([0, 0, 0, 3, 0, 1])
[3, 0, 1]
"""
if not f or f[0]:
return f
k = 0
for coeff in f:
if coeff:
break
else:
k += 1
return f[k:]
def gf_trunc(f, p):
"""
Reduce all coefficients modulo ``p``.
Examples
========
>>> from sympy.polys.galoistools import gf_trunc
>>> gf_trunc([7, -2, 3], 5)
[2, 3, 3]
"""
return gf_strip([ a % p for a in f ])
def gf_normal(f, p, K):
"""
Normalize all coefficients in ``K``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_normal
>>> gf_normal([5, 10, 21, -3], 5, ZZ)
[1, 2]
"""
return gf_trunc(list(map(K, f)), p)
def gf_from_dict(f, p, K):
"""
Create a ``GF(p)[x]`` polynomial from a dict.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_from_dict
>>> gf_from_dict({10: ZZ(4), 4: ZZ(33), 0: ZZ(-1)}, 5, ZZ)
[4, 0, 0, 0, 0, 0, 3, 0, 0, 0, 4]
"""
n, h = max(f.keys()), []
if isinstance(n, SYMPY_INTS):
for k in range(n, -1, -1):
h.append(f.get(k, K.zero) % p)
else:
(n,) = n
for k in range(n, -1, -1):
h.append(f.get((k,), K.zero) % p)
return gf_trunc(h, p)
def gf_to_dict(f, p, symmetric=True):
"""
Convert a ``GF(p)[x]`` polynomial to a dict.
Examples
========
>>> from sympy.polys.galoistools import gf_to_dict
>>> gf_to_dict([4, 0, 0, 0, 0, 0, 3, 0, 0, 0, 4], 5)
{0: -1, 4: -2, 10: -1}
>>> gf_to_dict([4, 0, 0, 0, 0, 0, 3, 0, 0, 0, 4], 5, symmetric=False)
{0: 4, 4: 3, 10: 4}
"""
n, result = gf_degree(f), {}
for k in range(0, n + 1):
if symmetric:
a = gf_int(f[n - k], p)
else:
a = f[n - k]
if a:
result[k] = a
return result
def gf_from_int_poly(f, p):
"""
Create a ``GF(p)[x]`` polynomial from ``Z[x]``.
Examples
========
>>> from sympy.polys.galoistools import gf_from_int_poly
>>> gf_from_int_poly([7, -2, 3], 5)
[2, 3, 3]
"""
return gf_trunc(f, p)
def gf_to_int_poly(f, p, symmetric=True):
"""
Convert a ``GF(p)[x]`` polynomial to ``Z[x]``.
Examples
========
>>> from sympy.polys.galoistools import gf_to_int_poly
>>> gf_to_int_poly([2, 3, 3], 5)
[2, -2, -2]
>>> gf_to_int_poly([2, 3, 3], 5, symmetric=False)
[2, 3, 3]
"""
if symmetric:
return [ gf_int(c, p) for c in f ]
else:
return f
def gf_neg(f, p, K):
"""
Negate a polynomial in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_neg
>>> gf_neg([3, 2, 1, 0], 5, ZZ)
[2, 3, 4, 0]
"""
return [ -coeff % p for coeff in f ]
def gf_add_ground(f, a, p, K):
"""
Compute ``f + a`` where ``f`` in ``GF(p)[x]`` and ``a`` in ``GF(p)``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_add_ground
>>> gf_add_ground([3, 2, 4], 2, 5, ZZ)
[3, 2, 1]
"""
if not f:
a = a % p
else:
a = (f[-1] + a) % p
if len(f) > 1:
return f[:-1] + [a]
if not a:
return []
else:
return [a]
def gf_sub_ground(f, a, p, K):
"""
Compute ``f - a`` where ``f`` in ``GF(p)[x]`` and ``a`` in ``GF(p)``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_sub_ground
>>> gf_sub_ground([3, 2, 4], 2, 5, ZZ)
[3, 2, 2]
"""
if not f:
a = -a % p
else:
a = (f[-1] - a) % p
if len(f) > 1:
return f[:-1] + [a]
if not a:
return []
else:
return [a]
def gf_mul_ground(f, a, p, K):
"""
Compute ``f * a`` where ``f`` in ``GF(p)[x]`` and ``a`` in ``GF(p)``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_mul_ground
>>> gf_mul_ground([3, 2, 4], 2, 5, ZZ)
[1, 4, 3]
"""
if not a:
return []
else:
return [ (a*b) % p for b in f ]
def gf_quo_ground(f, a, p, K):
"""
Compute ``f/a`` where ``f`` in ``GF(p)[x]`` and ``a`` in ``GF(p)``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_quo_ground
>>> gf_quo_ground(ZZ.map([3, 2, 4]), ZZ(2), 5, ZZ)
[4, 1, 2]
"""
return gf_mul_ground(f, K.invert(a, p), p, K)
def gf_add(f, g, p, K):
"""
Add polynomials in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_add
>>> gf_add([3, 2, 4], [2, 2, 2], 5, ZZ)
[4, 1]
"""
if not f:
return g
if not g:
return f
df = gf_degree(f)
dg = gf_degree(g)
if df == dg:
return gf_strip([ (a + b) % p 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) % p for a, b in zip(f, g) ]
def gf_sub(f, g, p, K):
"""
Subtract polynomials in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_sub
>>> gf_sub([3, 2, 4], [2, 2, 2], 5, ZZ)
[1, 0, 2]
"""
if not g:
return f
if not f:
return gf_neg(g, p, K)
df = gf_degree(f)
dg = gf_degree(g)
if df == dg:
return gf_strip([ (a - b) % p for a, b in zip(f, g) ])
else:
k = abs(df - dg)
if df > dg:
h, f = f[:k], f[k:]
else:
h, g = gf_neg(g[:k], p, K), g[k:]
return h + [ (a - b) % p for a, b in zip(f, g) ]
def gf_mul(f, g, p, K):
"""
Multiply polynomials in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_mul
>>> gf_mul([3, 2, 4], [2, 2, 2], 5, ZZ)
[1, 0, 3, 2, 3]
"""
df = gf_degree(f)
dg = gf_degree(g)
dh = df + dg
h = [0]*(dh + 1)
for i in range(0, dh + 1):
coeff = K.zero
for j in range(max(0, i - dg), min(i, df) + 1):
coeff += f[j]*g[i - j]
h[i] = coeff % p
return gf_strip(h)
def gf_sqr(f, p, K):
"""
Square polynomials in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_sqr
>>> gf_sqr([3, 2, 4], 5, ZZ)
[4, 2, 3, 1, 1]
"""
df = gf_degree(f)
dh = 2*df
h = [0]*(dh + 1)
for i in range(0, dh + 1):
coeff = 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):
coeff += f[j]*f[i - j]
coeff += coeff
if n & 1:
elem = f[jmax + 1]
coeff += elem**2
h[i] = coeff % p
return gf_strip(h)
def gf_add_mul(f, g, h, p, K):
"""
Returns ``f + g*h`` where ``f``, ``g``, ``h`` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_add_mul
>>> gf_add_mul([3, 2, 4], [2, 2, 2], [1, 4], 5, ZZ)
[2, 3, 2, 2]
"""
return gf_add(f, gf_mul(g, h, p, K), p, K)
def gf_sub_mul(f, g, h, p, K):
"""
Compute ``f - g*h`` where ``f``, ``g``, ``h`` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_sub_mul
>>> gf_sub_mul([3, 2, 4], [2, 2, 2], [1, 4], 5, ZZ)
[3, 3, 2, 1]
"""
return gf_sub(f, gf_mul(g, h, p, K), p, K)
def gf_expand(F, p, K):
"""
Expand results of :func:`~.factor` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_expand
>>> gf_expand([([3, 2, 4], 1), ([2, 2], 2), ([3, 1], 3)], 5, ZZ)
[4, 3, 0, 3, 0, 1, 4, 1]
"""
if type(F) is tuple:
lc, F = F
else:
lc = K.one
g = [lc]
for f, k in F:
f = gf_pow(f, k, p, K)
g = gf_mul(g, f, p, K)
return g
def gf_div(f, g, p, K):
"""
Division with remainder in ``GF(p)[x]``.
Given univariate polynomials ``f`` and ``g`` with coefficients in a
finite field with ``p`` elements, returns polynomials ``q`` and ``r``
(quotient and remainder) such that ``f = q*g + r``.
Consider polynomials ``x**3 + x + 1`` and ``x**2 + x`` in GF(2)::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_div, gf_add_mul
>>> gf_div(ZZ.map([1, 0, 1, 1]), ZZ.map([1, 1, 0]), 2, ZZ)
([1, 1], [1])
As result we obtained quotient ``x + 1`` and remainder ``1``, thus::
>>> gf_add_mul(ZZ.map([1]), ZZ.map([1, 1]), ZZ.map([1, 1, 0]), 2, ZZ)
[1, 0, 1, 1]
References
==========
.. [1] [Monagan93]_
.. [2] [Gathen99]_
"""
df = gf_degree(f)
dg = gf_degree(g)
if not g:
raise ZeroDivisionError("polynomial division")
elif df < dg:
return [], f
inv = K.invert(g[0], p)
h, dq, dr = list(f), df - dg, dg - 1
for i in range(0, df + 1):
coeff = h[i]
for j in range(max(0, dg - i), min(df - i, dr) + 1):
coeff -= h[i + j - dg] * g[dg - j]
if i <= dq:
coeff *= inv
h[i] = coeff % p
return h[:dq + 1], gf_strip(h[dq + 1:])
def gf_rem(f, g, p, K):
"""
Compute polynomial remainder in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_rem
>>> gf_rem(ZZ.map([1, 0, 1, 1]), ZZ.map([1, 1, 0]), 2, ZZ)
[1]
"""
return gf_div(f, g, p, K)[1]
def gf_quo(f, g, p, K):
"""
Compute exact quotient in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_quo
>>> gf_quo(ZZ.map([1, 0, 1, 1]), ZZ.map([1, 1, 0]), 2, ZZ)
[1, 1]
>>> gf_quo(ZZ.map([1, 0, 3, 2, 3]), ZZ.map([2, 2, 2]), 5, ZZ)
[3, 2, 4]
"""
df = gf_degree(f)
dg = gf_degree(g)
if not g:
raise ZeroDivisionError("polynomial division")
elif df < dg:
return []
inv = K.invert(g[0], p)
h, dq, dr = f[:], df - dg, dg - 1
for i in range(0, dq + 1):
coeff = h[i]
for j in range(max(0, dg - i), min(df - i, dr) + 1):
coeff -= h[i + j - dg] * g[dg - j]
h[i] = (coeff * inv) % p
return h[:dq + 1]
def gf_exquo(f, g, p, K):
"""
Compute polynomial quotient in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_exquo
>>> gf_exquo(ZZ.map([1, 0, 3, 2, 3]), ZZ.map([2, 2, 2]), 5, ZZ)
[3, 2, 4]
>>> gf_exquo(ZZ.map([1, 0, 1, 1]), ZZ.map([1, 1, 0]), 2, ZZ)
Traceback (most recent call last):
...
ExactQuotientFailed: [1, 1, 0] does not divide [1, 0, 1, 1]
"""
q, r = gf_div(f, g, p, K)
if not r:
return q
else:
raise ExactQuotientFailed(f, g)
def gf_lshift(f, n, K):
"""
Efficiently multiply ``f`` by ``x**n``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_lshift
>>> gf_lshift([3, 2, 4], 4, ZZ)
[3, 2, 4, 0, 0, 0, 0]
"""
if not f:
return f
else:
return f + [K.zero]*n
def gf_rshift(f, n, K):
"""
Efficiently divide ``f`` by ``x**n``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_rshift
>>> gf_rshift([1, 2, 3, 4, 0], 3, ZZ)
([1, 2], [3, 4, 0])
"""
if not n:
return f, []
else:
return f[:-n], f[-n:]
def gf_pow(f, n, p, K):
"""
Compute ``f**n`` in ``GF(p)[x]`` using repeated squaring.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_pow
>>> gf_pow([3, 2, 4], 3, 5, ZZ)
[2, 4, 4, 2, 2, 1, 4]
"""
if not n:
return [K.one]
elif n == 1:
return f
elif n == 2:
return gf_sqr(f, p, K)
h = [K.one]
while True:
if n & 1:
h = gf_mul(h, f, p, K)
n -= 1
n >>= 1
if not n:
break
f = gf_sqr(f, p, K)
return h
def gf_frobenius_monomial_base(g, p, K):
"""
return the list of ``x**(i*p) mod g in Z_p`` for ``i = 0, .., n - 1``
where ``n = gf_degree(g)``
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_frobenius_monomial_base
>>> g = ZZ.map([1, 0, 2, 1])
>>> gf_frobenius_monomial_base(g, 5, ZZ)
[[1], [4, 4, 2], [1, 2]]
"""
n = gf_degree(g)
if n == 0:
return []
b = [0]*n
b[0] = [1]
if p < n:
for i in range(1, n):
mon = gf_lshift(b[i - 1], p, K)
b[i] = gf_rem(mon, g, p, K)
elif n > 1:
b[1] = gf_pow_mod([K.one, K.zero], p, g, p, K)
for i in range(2, n):
b[i] = gf_mul(b[i - 1], b[1], p, K)
b[i] = gf_rem(b[i], g, p, K)
return b
def gf_frobenius_map(f, g, b, p, K):
"""
compute gf_pow_mod(f, p, g, p, K) using the Frobenius map
Parameters
==========
f, g : polynomials in ``GF(p)[x]``
b : frobenius monomial base
p : prime number
K : domain
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_frobenius_monomial_base, gf_frobenius_map
>>> f = ZZ.map([2, 1 , 0, 1])
>>> g = ZZ.map([1, 0, 2, 1])
>>> p = 5
>>> b = gf_frobenius_monomial_base(g, p, ZZ)
>>> r = gf_frobenius_map(f, g, b, p, ZZ)
>>> gf_frobenius_map(f, g, b, p, ZZ)
[4, 0, 3]
"""
m = gf_degree(g)
if gf_degree(f) >= m:
f = gf_rem(f, g, p, K)
if not f:
return []
n = gf_degree(f)
sf = [f[-1]]
for i in range(1, n + 1):
v = gf_mul_ground(b[i], f[n - i], p, K)
sf = gf_add(sf, v, p, K)
return sf
def _gf_pow_pnm1d2(f, n, g, b, p, K):
"""
utility function for ``gf_edf_zassenhaus``
Compute ``f**((p**n - 1) // 2)`` in ``GF(p)[x]/(g)``
``f**((p**n - 1) // 2) = (f*f**p*...*f**(p**n - 1))**((p - 1) // 2)``
"""
f = gf_rem(f, g, p, K)
h = f
r = f
for i in range(1, n):
h = gf_frobenius_map(h, g, b, p, K)
r = gf_mul(r, h, p, K)
r = gf_rem(r, g, p, K)
res = gf_pow_mod(r, (p - 1)//2, g, p, K)
return res
def gf_pow_mod(f, n, g, p, K):
"""
Compute ``f**n`` in ``GF(p)[x]/(g)`` using repeated squaring.
Given polynomials ``f`` and ``g`` in ``GF(p)[x]`` and a non-negative
integer ``n``, efficiently computes ``f**n (mod g)`` i.e. the remainder
of ``f**n`` from division by ``g``, using the repeated squaring algorithm.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_pow_mod
>>> gf_pow_mod(ZZ.map([3, 2, 4]), 3, ZZ.map([1, 1]), 5, ZZ)
[]
References
==========
.. [1] [Gathen99]_
"""
if not n:
return [K.one]
elif n == 1:
return gf_rem(f, g, p, K)
elif n == 2:
return gf_rem(gf_sqr(f, p, K), g, p, K)
h = [K.one]
while True:
if n & 1:
h = gf_mul(h, f, p, K)
h = gf_rem(h, g, p, K)
n -= 1
n >>= 1
if not n:
break
f = gf_sqr(f, p, K)
f = gf_rem(f, g, p, K)
return h
def gf_gcd(f, g, p, K):
"""
Euclidean Algorithm in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_gcd
>>> gf_gcd(ZZ.map([3, 2, 4]), ZZ.map([2, 2, 3]), 5, ZZ)
[1, 3]
"""
while g:
f, g = g, gf_rem(f, g, p, K)
return gf_monic(f, p, K)[1]
def gf_lcm(f, g, p, K):
"""
Compute polynomial LCM in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_lcm
>>> gf_lcm(ZZ.map([3, 2, 4]), ZZ.map([2, 2, 3]), 5, ZZ)
[1, 2, 0, 4]
"""
if not f or not g:
return []
h = gf_quo(gf_mul(f, g, p, K),
gf_gcd(f, g, p, K), p, K)
return gf_monic(h, p, K)[1]
def gf_cofactors(f, g, p, K):
"""
Compute polynomial GCD and cofactors in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_cofactors
>>> gf_cofactors(ZZ.map([3, 2, 4]), ZZ.map([2, 2, 3]), 5, ZZ)
([1, 3], [3, 3], [2, 1])
"""
if not f and not g:
return ([], [], [])
h = gf_gcd(f, g, p, K)
return (h, gf_quo(f, h, p, K),
gf_quo(g, h, p, K))
def gf_gcdex(f, g, p, K):
"""
Extended Euclidean Algorithm in ``GF(p)[x]``.
Given polynomials ``f`` and ``g`` in ``GF(p)[x]``, computes polynomials
``s``, ``t`` and ``h``, such that ``h = gcd(f, g)`` and ``s*f + t*g = h``.
The typical application of EEA is solving polynomial diophantine equations.
Consider polynomials ``f = (x + 7) (x + 1)``, ``g = (x + 7) (x**2 + 1)``
in ``GF(11)[x]``. Application of Extended Euclidean Algorithm gives::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_gcdex, gf_mul, gf_add
>>> s, t, g = gf_gcdex(ZZ.map([1, 8, 7]), ZZ.map([1, 7, 1, 7]), 11, ZZ)
>>> s, t, g
([5, 6], [6], [1, 7])
As result we obtained polynomials ``s = 5*x + 6`` and ``t = 6``, and
additionally ``gcd(f, g) = x + 7``. This is correct because::
>>> S = gf_mul(s, ZZ.map([1, 8, 7]), 11, ZZ)
>>> T = gf_mul(t, ZZ.map([1, 7, 1, 7]), 11, ZZ)
>>> gf_add(S, T, 11, ZZ) == [1, 7]
True
References
==========
.. [1] [Gathen99]_
"""
if not (f or g):
return [K.one], [], []
p0, r0 = gf_monic(f, p, K)
p1, r1 = gf_monic(g, p, K)
if not f:
return [], [K.invert(p1, p)], r1
if not g:
return [K.invert(p0, p)], [], r0
s0, s1 = [K.invert(p0, p)], []
t0, t1 = [], [K.invert(p1, p)]
while True:
Q, R = gf_div(r0, r1, p, K)
if not R:
break
(lc, r1), r0 = gf_monic(R, p, K), r1
inv = K.invert(lc, p)
s = gf_sub_mul(s0, s1, Q, p, K)
t = gf_sub_mul(t0, t1, Q, p, K)
s1, s0 = gf_mul_ground(s, inv, p, K), s1
t1, t0 = gf_mul_ground(t, inv, p, K), t1
return s1, t1, r1
def gf_monic(f, p, K):
"""
Compute LC and a monic polynomial in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_monic
>>> gf_monic(ZZ.map([3, 2, 4]), 5, ZZ)
(3, [1, 4, 3])
"""
if not f:
return K.zero, []
else:
lc = f[0]
if K.is_one(lc):
return lc, list(f)
else:
return lc, gf_quo_ground(f, lc, p, K)
def gf_diff(f, p, K):
"""
Differentiate polynomial in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_diff
>>> gf_diff([3, 2, 4], 5, ZZ)
[1, 2]
"""
df = gf_degree(f)
h, n = [K.zero]*df, df
for coeff in f[:-1]:
coeff *= K(n)
coeff %= p
if coeff:
h[df - n] = coeff
n -= 1
return gf_strip(h)
def gf_eval(f, a, p, K):
"""
Evaluate ``f(a)`` in ``GF(p)`` using Horner scheme.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_eval
>>> gf_eval([3, 2, 4], 2, 5, ZZ)
0
"""
result = K.zero
for c in f:
result *= a
result += c
result %= p
return result
def gf_multi_eval(f, A, p, K):
"""
Evaluate ``f(a)`` for ``a`` in ``[a_1, ..., a_n]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_multi_eval
>>> gf_multi_eval([3, 2, 4], [0, 1, 2, 3, 4], 5, ZZ)
[4, 4, 0, 2, 0]
"""
return [ gf_eval(f, a, p, K) for a in A ]
def gf_compose(f, g, p, K):
"""
Compute polynomial composition ``f(g)`` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_compose
>>> gf_compose([3, 2, 4], [2, 2, 2], 5, ZZ)
[2, 4, 0, 3, 0]
"""
if len(g) <= 1:
return gf_strip([gf_eval(f, gf_LC(g, K), p, K)])
if not f:
return []
h = [f[0]]
for c in f[1:]:
h = gf_mul(h, g, p, K)
h = gf_add_ground(h, c, p, K)
return h
def gf_compose_mod(g, h, f, p, K):
"""
Compute polynomial composition ``g(h)`` in ``GF(p)[x]/(f)``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_compose_mod
>>> gf_compose_mod(ZZ.map([3, 2, 4]), ZZ.map([2, 2, 2]), ZZ.map([4, 3]), 5, ZZ)
[4]
"""
if not g:
return []
comp = [g[0]]
for a in g[1:]:
comp = gf_mul(comp, h, p, K)
comp = gf_add_ground(comp, a, p, K)
comp = gf_rem(comp, f, p, K)
return comp
def gf_trace_map(a, b, c, n, f, p, K):
"""
Compute polynomial trace map in ``GF(p)[x]/(f)``.
Given a polynomial ``f`` in ``GF(p)[x]``, polynomials ``a``, ``b``,
``c`` in the quotient ring ``GF(p)[x]/(f)`` such that ``b = c**t
(mod f)`` for some positive power ``t`` of ``p``, and a positive
integer ``n``, returns a mapping::
a -> a**t**n, a + a**t + a**t**2 + ... + a**t**n (mod f)
In factorization context, ``b = x**p mod f`` and ``c = x mod f``.
This way we can efficiently compute trace polynomials in equal
degree factorization routine, much faster than with other methods,
like iterated Frobenius algorithm, for large degrees.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_trace_map
>>> gf_trace_map([1, 2], [4, 4], [1, 1], 4, [3, 2, 4], 5, ZZ)
([1, 3], [1, 3])
References
==========
.. [1] [Gathen92]_
"""
u = gf_compose_mod(a, b, f, p, K)
v = b
if n & 1:
U = gf_add(a, u, p, K)
V = b
else:
U = a
V = c
n >>= 1
while n:
u = gf_add(u, gf_compose_mod(u, v, f, p, K), p, K)
v = gf_compose_mod(v, v, f, p, K)
if n & 1:
U = gf_add(U, gf_compose_mod(u, V, f, p, K), p, K)
V = gf_compose_mod(v, V, f, p, K)
n >>= 1
return gf_compose_mod(a, V, f, p, K), U
def _gf_trace_map(f, n, g, b, p, K):
"""
utility for ``gf_edf_shoup``
"""
f = gf_rem(f, g, p, K)
h = f
r = f
for i in range(1, n):
h = gf_frobenius_map(h, g, b, p, K)
r = gf_add(r, h, p, K)
r = gf_rem(r, g, p, K)
return r
def gf_random(n, p, K):
"""
Generate a random polynomial in ``GF(p)[x]`` of degree ``n``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_random
>>> gf_random(10, 5, ZZ) #doctest: +SKIP
[1, 2, 3, 2, 1, 1, 1, 2, 0, 4, 2]
"""
return [K.one] + [ K(int(uniform(0, p))) for i in range(0, n) ]
def gf_irreducible(n, p, K):
"""
Generate random irreducible polynomial of degree ``n`` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_irreducible
>>> gf_irreducible(10, 5, ZZ) #doctest: +SKIP
[1, 4, 2, 2, 3, 2, 4, 1, 4, 0, 4]
"""
while True:
f = gf_random(n, p, K)
if gf_irreducible_p(f, p, K):
return f
def gf_irred_p_ben_or(f, p, K):
"""
Ben-Or's polynomial irreducibility test over finite fields.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_irred_p_ben_or
>>> gf_irred_p_ben_or(ZZ.map([1, 4, 2, 2, 3, 2, 4, 1, 4, 0, 4]), 5, ZZ)
True
>>> gf_irred_p_ben_or(ZZ.map([3, 2, 4]), 5, ZZ)
False
"""
n = gf_degree(f)
if n <= 1:
return True
_, f = gf_monic(f, p, K)
if n < 5:
H = h = gf_pow_mod([K.one, K.zero], p, f, p, K)
for i in range(0, n//2):
g = gf_sub(h, [K.one, K.zero], p, K)
if gf_gcd(f, g, p, K) == [K.one]:
h = gf_compose_mod(h, H, f, p, K)
else:
return False
else:
b = gf_frobenius_monomial_base(f, p, K)
H = h = gf_frobenius_map([K.one, K.zero], f, b, p, K)
for i in range(0, n//2):
g = gf_sub(h, [K.one, K.zero], p, K)
if gf_gcd(f, g, p, K) == [K.one]:
h = gf_frobenius_map(h, f, b, p, K)
else:
return False
return True
def gf_irred_p_rabin(f, p, K):
"""
Rabin's polynomial irreducibility test over finite fields.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_irred_p_rabin
>>> gf_irred_p_rabin(ZZ.map([1, 4, 2, 2, 3, 2, 4, 1, 4, 0, 4]), 5, ZZ)
True
>>> gf_irred_p_rabin(ZZ.map([3, 2, 4]), 5, ZZ)
False
"""
n = gf_degree(f)
if n <= 1:
return True
_, f = gf_monic(f, p, K)
x = [K.one, K.zero]
indices = { n//d for d in factorint(n) }
b = gf_frobenius_monomial_base(f, p, K)
h = b[1]
for i in range(1, n):
if i in indices:
g = gf_sub(h, x, p, K)
if gf_gcd(f, g, p, K) != [K.one]:
return False
h = gf_frobenius_map(h, f, b, p, K)
return h == x
_irred_methods = {
'ben-or': gf_irred_p_ben_or,
'rabin': gf_irred_p_rabin,
}
def gf_irreducible_p(f, p, K):
"""
Test irreducibility of a polynomial ``f`` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_irreducible_p
>>> gf_irreducible_p(ZZ.map([1, 4, 2, 2, 3, 2, 4, 1, 4, 0, 4]), 5, ZZ)
True
>>> gf_irreducible_p(ZZ.map([3, 2, 4]), 5, ZZ)
False
"""
method = query('GF_IRRED_METHOD')
if method is not None:
irred = _irred_methods[method](f, p, K)
else:
irred = gf_irred_p_rabin(f, p, K)
return irred
def gf_sqf_p(f, p, K):
"""
Return ``True`` if ``f`` is square-free in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_sqf_p
>>> gf_sqf_p(ZZ.map([3, 2, 4]), 5, ZZ)
True
>>> gf_sqf_p(ZZ.map([2, 4, 4, 2, 2, 1, 4]), 5, ZZ)
False
"""
_, f = gf_monic(f, p, K)
if not f:
return True
else:
return gf_gcd(f, gf_diff(f, p, K), p, K) == [K.one]
def gf_sqf_part(f, p, K):
"""
Return square-free part of a ``GF(p)[x]`` polynomial.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_sqf_part
>>> gf_sqf_part(ZZ.map([1, 1, 3, 0, 1, 0, 2, 2, 1]), 5, ZZ)
[1, 4, 3]
"""
_, sqf = gf_sqf_list(f, p, K)
g = [K.one]
for f, _ in sqf:
g = gf_mul(g, f, p, K)
return g
def gf_sqf_list(f, p, K, all=False):
"""
Return the square-free decomposition of a ``GF(p)[x]`` polynomial.
Given a polynomial ``f`` in ``GF(p)[x]``, returns the leading coefficient
of ``f`` and a square-free decomposition ``f_1**e_1 f_2**e_2 ... f_k**e_k``
such that all ``f_i`` are monic polynomials and ``(f_i, f_j)`` for ``i != j``
are co-prime and ``e_1 ... e_k`` are given in increasing order. All trivial
terms (i.e. ``f_i = 1``) aren't included in the output.
Consider polynomial ``f = x**11 + 1`` over ``GF(11)[x]``::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import (
... gf_from_dict, gf_diff, gf_sqf_list, gf_pow,
... )
... # doctest: +NORMALIZE_WHITESPACE
>>> f = gf_from_dict({11: ZZ(1), 0: ZZ(1)}, 11, ZZ)
Note that ``f'(x) = 0``::
>>> gf_diff(f, 11, ZZ)
[]
This phenomenon doesn't happen in characteristic zero. However we can
still compute square-free decomposition of ``f`` using ``gf_sqf()``::
>>> gf_sqf_list(f, 11, ZZ)
(1, [([1, 1], 11)])
We obtained factorization ``f = (x + 1)**11``. This is correct because::
>>> gf_pow([1, 1], 11, 11, ZZ) == f
True
References
==========
.. [1] [Geddes92]_
"""
n, sqf, factors, r = 1, False, [], int(p)
lc, f = gf_monic(f, p, K)
if gf_degree(f) < 1:
return lc, []
while True:
F = gf_diff(f, p, K)
if F != []:
g = gf_gcd(f, F, p, K)
h = gf_quo(f, g, p, K)
i = 1
while h != [K.one]:
G = gf_gcd(g, h, p, K)
H = gf_quo(h, G, p, K)
if gf_degree(H) > 0:
factors.append((H, i*n))
g, h, i = gf_quo(g, G, p, K), G, i + 1
if g == [K.one]:
sqf = True
else:
f = g
if not sqf:
d = gf_degree(f) // r
for i in range(0, d + 1):
f[i] = f[i*r]
f, n = f[:d + 1], n*r
else:
break
if all:
raise ValueError("'all=True' is not supported yet")
return lc, factors
def gf_Qmatrix(f, p, K):
"""
Calculate Berlekamp's ``Q`` matrix.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_Qmatrix
>>> gf_Qmatrix([3, 2, 4], 5, ZZ)
[[1, 0],
[3, 4]]
>>> gf_Qmatrix([1, 0, 0, 0, 1], 5, ZZ)
[[1, 0, 0, 0],
[0, 4, 0, 0],
[0, 0, 1, 0],
[0, 0, 0, 4]]
"""
n, r = gf_degree(f), int(p)
q = [K.one] + [K.zero]*(n - 1)
Q = [list(q)] + [[]]*(n - 1)
for i in range(1, (n - 1)*r + 1):
qq, c = [(-q[-1]*f[-1]) % p], q[-1]
for j in range(1, n):
qq.append((q[j - 1] - c*f[-j - 1]) % p)
if not (i % r):
Q[i//r] = list(qq)
q = qq
return Q
def gf_Qbasis(Q, p, K):
"""
Compute a basis of the kernel of ``Q``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_Qmatrix, gf_Qbasis
>>> gf_Qbasis(gf_Qmatrix([1, 0, 0, 0, 1], 5, ZZ), 5, ZZ)
[[1, 0, 0, 0], [0, 0, 1, 0]]
>>> gf_Qbasis(gf_Qmatrix([3, 2, 4], 5, ZZ), 5, ZZ)
[[1, 0]]
"""
Q, n = [ list(q) for q in Q ], len(Q)
for k in range(0, n):
Q[k][k] = (Q[k][k] - K.one) % p
for k in range(0, n):
for i in range(k, n):
if Q[k][i]:
break
else:
continue
inv = K.invert(Q[k][i], p)
for j in range(0, n):
Q[j][i] = (Q[j][i]*inv) % p
for j in range(0, n):
t = Q[j][k]
Q[j][k] = Q[j][i]
Q[j][i] = t
for i in range(0, n):
if i != k:
q = Q[k][i]
for j in range(0, n):
Q[j][i] = (Q[j][i] - Q[j][k]*q) % p
for i in range(0, n):
for j in range(0, n):
if i == j:
Q[i][j] = (K.one - Q[i][j]) % p
else:
Q[i][j] = (-Q[i][j]) % p
basis = []
for q in Q:
if any(q):
basis.append(q)
return basis
def gf_berlekamp(f, p, K):
"""
Factor a square-free ``f`` in ``GF(p)[x]`` for small ``p``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_berlekamp
>>> gf_berlekamp([1, 0, 0, 0, 1], 5, ZZ)
[[1, 0, 2], [1, 0, 3]]
"""
Q = gf_Qmatrix(f, p, K)
V = gf_Qbasis(Q, p, K)
for i, v in enumerate(V):
V[i] = gf_strip(list(reversed(v)))
factors = [f]
for k in range(1, len(V)):
for f in list(factors):
s = K.zero
while s < p:
g = gf_sub_ground(V[k], s, p, K)
h = gf_gcd(f, g, p, K)
if h != [K.one] and h != f:
factors.remove(f)
f = gf_quo(f, h, p, K)
factors.extend([f, h])
if len(factors) == len(V):
return _sort_factors(factors, multiple=False)
s += K.one
return _sort_factors(factors, multiple=False)
def gf_ddf_zassenhaus(f, p, K):
"""
Cantor-Zassenhaus: Deterministic Distinct Degree Factorization
Given a monic square-free polynomial ``f`` in ``GF(p)[x]``, computes
partial distinct degree factorization ``f_1 ... f_d`` of ``f`` where
``deg(f_i) != deg(f_j)`` for ``i != j``. The result is returned as a
list of pairs ``(f_i, e_i)`` where ``deg(f_i) > 0`` and ``e_i > 0``
is an argument to the equal degree factorization routine.
Consider the polynomial ``x**15 - 1`` in ``GF(11)[x]``::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_from_dict
>>> f = gf_from_dict({15: ZZ(1), 0: ZZ(-1)}, 11, ZZ)
Distinct degree factorization gives::
>>> from sympy.polys.galoistools import gf_ddf_zassenhaus
>>> gf_ddf_zassenhaus(f, 11, ZZ)
[([1, 0, 0, 0, 0, 10], 1), ([1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1], 2)]
which means ``x**15 - 1 = (x**5 - 1) (x**10 + x**5 + 1)``. To obtain
factorization into irreducibles, use equal degree factorization
procedure (EDF) with each of the factors.
References
==========
.. [1] [Gathen99]_
.. [2] [Geddes92]_
"""
i, g, factors = 1, [K.one, K.zero], []
b = gf_frobenius_monomial_base(f, p, K)
while 2*i <= gf_degree(f):
g = gf_frobenius_map(g, f, b, p, K)
h = gf_gcd(f, gf_sub(g, [K.one, K.zero], p, K), p, K)
if h != [K.one]:
factors.append((h, i))
f = gf_quo(f, h, p, K)
g = gf_rem(g, f, p, K)
b = gf_frobenius_monomial_base(f, p, K)
i += 1
if f != [K.one]:
return factors + [(f, gf_degree(f))]
else:
return factors
def gf_edf_zassenhaus(f, n, p, K):
"""
Cantor-Zassenhaus: Probabilistic Equal Degree Factorization
Given a monic square-free polynomial ``f`` in ``GF(p)[x]`` and
an integer ``n``, such that ``n`` divides ``deg(f)``, returns all
irreducible factors ``f_1,...,f_d`` of ``f``, each of degree ``n``.
EDF procedure gives complete factorization over Galois fields.
Consider the square-free polynomial ``f = x**3 + x**2 + x + 1`` in
``GF(5)[x]``. Let's compute its irreducible factors of degree one::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_edf_zassenhaus
>>> gf_edf_zassenhaus([1,1,1,1], 1, 5, ZZ)
[[1, 1], [1, 2], [1, 3]]
References
==========
.. [1] [Gathen99]_
.. [2] [Geddes92]_
"""
factors = [f]
if gf_degree(f) <= n:
return factors
N = gf_degree(f) // n
if p != 2:
b = gf_frobenius_monomial_base(f, p, K)
while len(factors) < N:
r = gf_random(2*n - 1, p, K)
if p == 2:
h = r
for i in range(0, 2**(n*N - 1)):
r = gf_pow_mod(r, 2, f, p, K)
h = gf_add(h, r, p, K)
g = gf_gcd(f, h, p, K)
else:
h = _gf_pow_pnm1d2(r, n, f, b, p, K)
g = gf_gcd(f, gf_sub_ground(h, K.one, p, K), p, K)
if g != [K.one] and g != f:
factors = gf_edf_zassenhaus(g, n, p, K) \
+ gf_edf_zassenhaus(gf_quo(f, g, p, K), n, p, K)
return _sort_factors(factors, multiple=False)
def gf_ddf_shoup(f, p, K):
"""
Kaltofen-Shoup: Deterministic Distinct Degree Factorization
Given a monic square-free polynomial ``f`` in ``GF(p)[x]``, computes
partial distinct degree factorization ``f_1,...,f_d`` of ``f`` where
``deg(f_i) != deg(f_j)`` for ``i != j``. The result is returned as a
list of pairs ``(f_i, e_i)`` where ``deg(f_i) > 0`` and ``e_i > 0``
is an argument to the equal degree factorization routine.
This algorithm is an improved version of Zassenhaus algorithm for
large ``deg(f)`` and modulus ``p`` (especially for ``deg(f) ~ lg(p)``).
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_ddf_shoup, gf_from_dict
>>> f = gf_from_dict({6: ZZ(1), 5: ZZ(-1), 4: ZZ(1), 3: ZZ(1), 1: ZZ(-1)}, 3, ZZ)
>>> gf_ddf_shoup(f, 3, ZZ)
[([1, 1, 0], 1), ([1, 1, 0, 1, 2], 2)]
References
==========
.. [1] [Kaltofen98]_
.. [2] [Shoup95]_
.. [3] [Gathen92]_
"""
n = gf_degree(f)
k = int(_ceil(_sqrt(n//2)))
b = gf_frobenius_monomial_base(f, p, K)
h = gf_frobenius_map([K.one, K.zero], f, b, p, K)
# U[i] = x**(p**i)
U = [[K.one, K.zero], h] + [K.zero]*(k - 1)
for i in range(2, k + 1):
U[i] = gf_frobenius_map(U[i-1], f, b, p, K)
h, U = U[k], U[:k]
# V[i] = x**(p**(k*(i+1)))
V = [h] + [K.zero]*(k - 1)
for i in range(1, k):
V[i] = gf_compose_mod(V[i - 1], h, f, p, K)
factors = []
for i, v in enumerate(V):
h, j = [K.one], k - 1
for u in U:
g = gf_sub(v, u, p, K)
h = gf_mul(h, g, p, K)
h = gf_rem(h, f, p, K)
g = gf_gcd(f, h, p, K)
f = gf_quo(f, g, p, K)
for u in reversed(U):
h = gf_sub(v, u, p, K)
F = gf_gcd(g, h, p, K)
if F != [K.one]:
factors.append((F, k*(i + 1) - j))
g, j = gf_quo(g, F, p, K), j - 1
if f != [K.one]:
factors.append((f, gf_degree(f)))
return factors
def gf_edf_shoup(f, n, p, K):
"""
Gathen-Shoup: Probabilistic Equal Degree Factorization
Given a monic square-free polynomial ``f`` in ``GF(p)[x]`` and integer
``n`` such that ``n`` divides ``deg(f)``, returns all irreducible factors
``f_1,...,f_d`` of ``f``, each of degree ``n``. This is a complete
factorization over Galois fields.
This algorithm is an improved version of Zassenhaus algorithm for
large ``deg(f)`` and modulus ``p`` (especially for ``deg(f) ~ lg(p)``).
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_edf_shoup
>>> gf_edf_shoup(ZZ.map([1, 2837, 2277]), 1, 2917, ZZ)
[[1, 852], [1, 1985]]
References
==========
.. [1] [Shoup91]_
.. [2] [Gathen92]_
"""
N, q = gf_degree(f), int(p)
if not N:
return []
if N <= n:
return [f]
factors, x = [f], [K.one, K.zero]
r = gf_random(N - 1, p, K)
if p == 2:
h = gf_pow_mod(x, q, f, p, K)
H = gf_trace_map(r, h, x, n - 1, f, p, K)[1]
h1 = gf_gcd(f, H, p, K)
h2 = gf_quo(f, h1, p, K)
factors = gf_edf_shoup(h1, n, p, K) \
+ gf_edf_shoup(h2, n, p, K)
else:
b = gf_frobenius_monomial_base(f, p, K)
H = _gf_trace_map(r, n, f, b, p, K)
h = gf_pow_mod(H, (q - 1)//2, f, p, K)
h1 = gf_gcd(f, h, p, K)
h2 = gf_gcd(f, gf_sub_ground(h, K.one, p, K), p, K)
h3 = gf_quo(f, gf_mul(h1, h2, p, K), p, K)
factors = gf_edf_shoup(h1, n, p, K) \
+ gf_edf_shoup(h2, n, p, K) \
+ gf_edf_shoup(h3, n, p, K)
return _sort_factors(factors, multiple=False)
def gf_zassenhaus(f, p, K):
"""
Factor a square-free ``f`` in ``GF(p)[x]`` for medium ``p``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_zassenhaus
>>> gf_zassenhaus(ZZ.map([1, 4, 3]), 5, ZZ)
[[1, 1], [1, 3]]
"""
factors = []
for factor, n in gf_ddf_zassenhaus(f, p, K):
factors += gf_edf_zassenhaus(factor, n, p, K)
return _sort_factors(factors, multiple=False)
def gf_shoup(f, p, K):
"""
Factor a square-free ``f`` in ``GF(p)[x]`` for large ``p``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_shoup
>>> gf_shoup(ZZ.map([1, 4, 3]), 5, ZZ)
[[1, 1], [1, 3]]
"""
factors = []
for factor, n in gf_ddf_shoup(f, p, K):
factors += gf_edf_shoup(factor, n, p, K)
return _sort_factors(factors, multiple=False)
_factor_methods = {
'berlekamp': gf_berlekamp, # ``p`` : small
'zassenhaus': gf_zassenhaus, # ``p`` : medium
'shoup': gf_shoup, # ``p`` : large
}
def gf_factor_sqf(f, p, K, method=None):
"""
Factor a square-free polynomial ``f`` in ``GF(p)[x]``.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_factor_sqf
>>> gf_factor_sqf(ZZ.map([3, 2, 4]), 5, ZZ)
(3, [[1, 1], [1, 3]])
"""
lc, f = gf_monic(f, p, K)
if gf_degree(f) < 1:
return lc, []
method = method or query('GF_FACTOR_METHOD')
if method is not None:
factors = _factor_methods[method](f, p, K)
else:
factors = gf_zassenhaus(f, p, K)
return lc, factors
def gf_factor(f, p, K):
"""
Factor (non square-free) polynomials in ``GF(p)[x]``.
Given a possibly non square-free polynomial ``f`` in ``GF(p)[x]``,
returns its complete factorization into irreducibles::
f_1(x)**e_1 f_2(x)**e_2 ... f_d(x)**e_d
where each ``f_i`` is a monic polynomial and ``gcd(f_i, f_j) == 1``,
for ``i != j``. The result is given as a tuple consisting of the
leading coefficient of ``f`` and a list of factors of ``f`` with
their multiplicities.
The algorithm proceeds by first computing square-free decomposition
of ``f`` and then iteratively factoring each of square-free factors.
Consider a non square-free polynomial ``f = (7*x + 1) (x + 2)**2`` in
``GF(11)[x]``. We obtain its factorization into irreducibles as follows::
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.galoistools import gf_factor
>>> gf_factor(ZZ.map([5, 2, 7, 2]), 11, ZZ)
(5, [([1, 2], 1), ([1, 8], 2)])
We arrived with factorization ``f = 5 (x + 2) (x + 8)**2``. We didn't
recover the exact form of the input polynomial because we requested to
get monic factors of ``f`` and its leading coefficient separately.
Square-free factors of ``f`` can be factored into irreducibles over
``GF(p)`` using three very different methods:
Berlekamp
efficient for very small values of ``p`` (usually ``p < 25``)
Cantor-Zassenhaus
efficient on average input and with "typical" ``p``
Shoup-Kaltofen-Gathen
efficient with very large inputs and modulus
If you want to use a specific factorization method, instead of the default
one, set ``GF_FACTOR_METHOD`` with one of ``berlekamp``, ``zassenhaus`` or
``shoup`` values.
References
==========
.. [1] [Gathen99]_
"""
lc, f = gf_monic(f, p, K)
if gf_degree(f) < 1:
return lc, []
factors = []
for g, n in gf_sqf_list(f, p, K)[1]:
for h in gf_factor_sqf(g, p, K)[1]:
factors.append((h, n))
return lc, _sort_factors(factors)
def gf_value(f, a):
"""
Value of polynomial 'f' at 'a' in field R.
Examples
========
>>> from sympy.polys.galoistools import gf_value
>>> gf_value([1, 7, 2, 4], 11)
2204
"""
result = 0
for c in f:
result *= a
result += c
return result
def linear_congruence(a, b, m):
"""
Returns the values of x satisfying a*x congruent b mod(m)
Here m is positive integer and a, b are natural numbers.
This function returns only those values of x which are distinct mod(m).
Examples
========
>>> from sympy.polys.galoistools import linear_congruence
>>> linear_congruence(3, 12, 15)
[4, 9, 14]
There are 3 solutions distinct mod(15) since gcd(a, m) = gcd(3, 15) = 3.
References
==========
.. [1] https://en.wikipedia.org/wiki/Linear_congruence_theorem
"""
from sympy.polys.polytools import gcdex
if a % m == 0:
if b % m == 0:
return list(range(m))
else:
return []
r, _, g = gcdex(a, m)
if b % g != 0:
return []
return [(r * b // g + t * m // g) % m for t in range(g)]
def _raise_mod_power(x, s, p, f):
"""
Used in gf_csolve to generate solutions of f(x) cong 0 mod(p**(s + 1))
from the solutions of f(x) cong 0 mod(p**s).
Examples
========
>>> from sympy.polys.galoistools import _raise_mod_power
>>> from sympy.polys.galoistools import csolve_prime
These is the solutions of f(x) = x**2 + x + 7 cong 0 mod(3)
>>> f = [1, 1, 7]
>>> csolve_prime(f, 3)
[1]
>>> [ i for i in range(3) if not (i**2 + i + 7) % 3]
[1]
The solutions of f(x) cong 0 mod(9) are constructed from the
values returned from _raise_mod_power:
>>> x, s, p = 1, 1, 3
>>> V = _raise_mod_power(x, s, p, f)
>>> [x + v * p**s for v in V]
[1, 4, 7]
And these are confirmed with the following:
>>> [ i for i in range(3**2) if not (i**2 + i + 7) % 3**2]
[1, 4, 7]
"""
from sympy.polys.domains import ZZ
f_f = gf_diff(f, p, ZZ)
alpha = gf_value(f_f, x)
beta = - gf_value(f, x) // p**s
return linear_congruence(alpha, beta, p)
def csolve_prime(f, p, e=1):
"""
Solutions of f(x) congruent 0 mod(p**e).
Examples
========
>>> from sympy.polys.galoistools import csolve_prime
>>> csolve_prime([1, 1, 7], 3, 1)
[1]
>>> csolve_prime([1, 1, 7], 3, 2)
[1, 4, 7]
Solutions [7, 4, 1] (mod 3**2) are generated by ``_raise_mod_power()``
from solution [1] (mod 3).
"""
from sympy.polys.domains import ZZ
X1 = [i for i in range(p) if gf_eval(f, i, p, ZZ) == 0]
if e == 1:
return X1
X = []
S = list(zip(X1, [1]*len(X1)))
while S:
x, s = S.pop()
if s == e:
X.append(x)
else:
s1 = s + 1
ps = p**s
S.extend([(x + v*ps, s1) for v in _raise_mod_power(x, s, p, f)])
return sorted(X)
def gf_csolve(f, n):
"""
To solve f(x) congruent 0 mod(n).
n is divided into canonical factors and f(x) cong 0 mod(p**e) will be
solved for each factor. Applying the Chinese Remainder Theorem to the
results returns the final answers.
Examples
========
Solve [1, 1, 7] congruent 0 mod(189):
>>> from sympy.polys.galoistools import gf_csolve
>>> gf_csolve([1, 1, 7], 189)
[13, 49, 76, 112, 139, 175]
References
==========
.. [1] 'An introduction to the Theory of Numbers' 5th Edition by Ivan Niven,
Zuckerman and Montgomery.
"""
from sympy.polys.domains import ZZ
P = factorint(n)
X = [csolve_prime(f, p, e) for p, e in P.items()]
pools = list(map(tuple, X))
perms = [[]]
for pool in pools:
perms = [x + [y] for x in perms for y in pool]
dist_factors = [pow(p, e) for p, e in P.items()]
return sorted([gf_crt(per, dist_factors, ZZ) for per in perms])
|
8e643a2061e5bc4c1c49a42d563194c8912a0fccbba07f0db70367580dc19011 | """Sparse polynomial rings. """
from __future__ import print_function, division
from typing import Any, Dict
from operator import add, mul, lt, le, gt, ge
from types import GeneratorType
from sympy.core.compatibility import is_sequence, reduce
from sympy.core.expr import Expr
from sympy.core.numbers import igcd, oo
from sympy.core.symbol import Symbol, symbols as _symbols
from sympy.core.sympify import CantSympify, sympify
from sympy.ntheory.multinomial import multinomial_coefficients
from sympy.polys.compatibility import IPolys
from sympy.polys.constructor import construct_domain
from sympy.polys.densebasic import dmp_to_dict, dmp_from_dict
from sympy.polys.domains.domainelement import DomainElement
from sympy.polys.domains.polynomialring import PolynomialRing
from sympy.polys.heuristicgcd import heugcd
from sympy.polys.monomials import MonomialOps
from sympy.polys.orderings import lex
from sympy.polys.polyerrors import (
CoercionFailed, GeneratorsError,
ExactQuotientFailed, MultivariatePolynomialError)
from sympy.polys.polyoptions import (Domain as DomainOpt,
Order as OrderOpt, build_options)
from sympy.polys.polyutils import (expr_from_dict, _dict_reorder,
_parallel_dict_from_expr)
from sympy.printing.defaults import DefaultPrinting
from sympy.utilities import public
from sympy.utilities.magic import pollute
@public
def ring(symbols, domain, order=lex):
"""Construct a polynomial ring returning ``(ring, x_1, ..., x_n)``.
Parameters
==========
symbols : str
Symbol/Expr or sequence of str, Symbol/Expr (non-empty)
domain : :class:`~.Domain` or coercible
order : :class:`~.MonomialOrder` or coercible, optional, defaults to ``lex``
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.orderings import lex
>>> R, x, y, z = ring("x,y,z", ZZ, lex)
>>> R
Polynomial ring in x, y, z over ZZ with lex order
>>> x + y + z
x + y + z
>>> type(_)
<class 'sympy.polys.rings.PolyElement'>
"""
_ring = PolyRing(symbols, domain, order)
return (_ring,) + _ring.gens
@public
def xring(symbols, domain, order=lex):
"""Construct a polynomial ring returning ``(ring, (x_1, ..., x_n))``.
Parameters
==========
symbols : str
Symbol/Expr or sequence of str, Symbol/Expr (non-empty)
domain : :class:`~.Domain` or coercible
order : :class:`~.MonomialOrder` or coercible, optional, defaults to ``lex``
Examples
========
>>> from sympy.polys.rings import xring
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.orderings import lex
>>> R, (x, y, z) = xring("x,y,z", ZZ, lex)
>>> R
Polynomial ring in x, y, z over ZZ with lex order
>>> x + y + z
x + y + z
>>> type(_)
<class 'sympy.polys.rings.PolyElement'>
"""
_ring = PolyRing(symbols, domain, order)
return (_ring, _ring.gens)
@public
def vring(symbols, domain, order=lex):
"""Construct a polynomial ring and inject ``x_1, ..., x_n`` into the global namespace.
Parameters
==========
symbols : str
Symbol/Expr or sequence of str, Symbol/Expr (non-empty)
domain : :class:`~.Domain` or coercible
order : :class:`~.MonomialOrder` or coercible, optional, defaults to ``lex``
Examples
========
>>> from sympy.polys.rings import vring
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.orderings import lex
>>> vring("x,y,z", ZZ, lex)
Polynomial ring in x, y, z over ZZ with lex order
>>> x + y + z # noqa:
x + y + z
>>> type(_)
<class 'sympy.polys.rings.PolyElement'>
"""
_ring = PolyRing(symbols, domain, order)
pollute([ sym.name for sym in _ring.symbols ], _ring.gens)
return _ring
@public
def sring(exprs, *symbols, **options):
"""Construct a ring deriving generators and domain from options and input expressions.
Parameters
==========
exprs : :class:`~.Expr` or sequence of :class:`~.Expr` (sympifiable)
symbols : sequence of :class:`~.Symbol`/:class:`~.Expr`
options : keyword arguments understood by :class:`~.Options`
Examples
========
>>> from sympy.core import symbols
>>> from sympy.polys.rings import sring
>>> x, y, z = symbols("x,y,z")
>>> R, f = sring(x + 2*y + 3*z)
>>> R
Polynomial ring in x, y, z over ZZ with lex order
>>> f
x + 2*y + 3*z
>>> type(_)
<class 'sympy.polys.rings.PolyElement'>
"""
single = False
if not is_sequence(exprs):
exprs, single = [exprs], True
exprs = list(map(sympify, exprs))
opt = build_options(symbols, options)
# TODO: rewrite this so that it doesn't use expand() (see poly()).
reps, opt = _parallel_dict_from_expr(exprs, opt)
if opt.domain is None:
# NOTE: this is inefficient because construct_domain() automatically
# performs conversion to the target domain. It shouldn't do this.
coeffs = sum([ list(rep.values()) for rep in reps ], [])
opt.domain, _ = construct_domain(coeffs, opt=opt)
_ring = PolyRing(opt.gens, opt.domain, opt.order)
polys = list(map(_ring.from_dict, reps))
if single:
return (_ring, polys[0])
else:
return (_ring, polys)
def _parse_symbols(symbols):
if isinstance(symbols, str):
return _symbols(symbols, seq=True) if symbols else ()
elif isinstance(symbols, Expr):
return (symbols,)
elif is_sequence(symbols):
if all(isinstance(s, str) for s in symbols):
return _symbols(symbols)
elif all(isinstance(s, Expr) for s in symbols):
return symbols
raise GeneratorsError("expected a string, Symbol or expression or a non-empty sequence of strings, Symbols or expressions")
_ring_cache = {} # type: Dict[Any, Any]
class PolyRing(DefaultPrinting, IPolys):
"""Multivariate distributed polynomial ring. """
def __new__(cls, symbols, domain, order=lex):
symbols = tuple(_parse_symbols(symbols))
ngens = len(symbols)
domain = DomainOpt.preprocess(domain)
order = OrderOpt.preprocess(order)
_hash_tuple = (cls.__name__, symbols, ngens, domain, order)
obj = _ring_cache.get(_hash_tuple)
if obj is None:
if domain.is_Composite and set(symbols) & set(domain.symbols):
raise GeneratorsError("polynomial ring and it's ground domain share generators")
obj = object.__new__(cls)
obj._hash_tuple = _hash_tuple
obj._hash = hash(_hash_tuple)
obj.dtype = type("PolyElement", (PolyElement,), {"ring": obj})
obj.symbols = symbols
obj.ngens = ngens
obj.domain = domain
obj.order = order
obj.zero_monom = (0,)*ngens
obj.gens = obj._gens()
obj._gens_set = set(obj.gens)
obj._one = [(obj.zero_monom, domain.one)]
if ngens:
# These expect monomials in at least one variable
codegen = MonomialOps(ngens)
obj.monomial_mul = codegen.mul()
obj.monomial_pow = codegen.pow()
obj.monomial_mulpow = codegen.mulpow()
obj.monomial_ldiv = codegen.ldiv()
obj.monomial_div = codegen.div()
obj.monomial_lcm = codegen.lcm()
obj.monomial_gcd = codegen.gcd()
else:
monunit = lambda a, b: ()
obj.monomial_mul = monunit
obj.monomial_pow = monunit
obj.monomial_mulpow = lambda a, b, c: ()
obj.monomial_ldiv = monunit
obj.monomial_div = monunit
obj.monomial_lcm = monunit
obj.monomial_gcd = monunit
if order is lex:
obj.leading_expv = lambda f: max(f)
else:
obj.leading_expv = lambda f: max(f, key=order)
for symbol, generator in zip(obj.symbols, obj.gens):
if isinstance(symbol, Symbol):
name = symbol.name
if not hasattr(obj, name):
setattr(obj, name, generator)
_ring_cache[_hash_tuple] = obj
return obj
def _gens(self):
"""Return a list of polynomial generators. """
one = self.domain.one
_gens = []
for i in range(self.ngens):
expv = self.monomial_basis(i)
poly = self.zero
poly[expv] = one
_gens.append(poly)
return tuple(_gens)
def __getnewargs__(self):
return (self.symbols, self.domain, self.order)
def __getstate__(self):
state = self.__dict__.copy()
del state["leading_expv"]
for key, value in state.items():
if key.startswith("monomial_"):
del state[key]
return state
def __hash__(self):
return self._hash
def __eq__(self, other):
return isinstance(other, PolyRing) and \
(self.symbols, self.domain, self.ngens, self.order) == \
(other.symbols, other.domain, other.ngens, other.order)
def __ne__(self, other):
return not self == other
def clone(self, symbols=None, domain=None, order=None):
return self.__class__(symbols or self.symbols, domain or self.domain, order or self.order)
def monomial_basis(self, i):
"""Return the ith-basis element. """
basis = [0]*self.ngens
basis[i] = 1
return tuple(basis)
@property
def zero(self):
return self.dtype()
@property
def one(self):
return self.dtype(self._one)
def domain_new(self, element, orig_domain=None):
return self.domain.convert(element, orig_domain)
def ground_new(self, coeff):
return self.term_new(self.zero_monom, coeff)
def term_new(self, monom, coeff):
coeff = self.domain_new(coeff)
poly = self.zero
if coeff:
poly[monom] = coeff
return poly
def ring_new(self, element):
if isinstance(element, PolyElement):
if self == element.ring:
return element
elif isinstance(self.domain, PolynomialRing) and self.domain.ring == element.ring:
return self.ground_new(element)
else:
raise NotImplementedError("conversion")
elif isinstance(element, str):
raise NotImplementedError("parsing")
elif isinstance(element, dict):
return self.from_dict(element)
elif isinstance(element, list):
try:
return self.from_terms(element)
except ValueError:
return self.from_list(element)
elif isinstance(element, Expr):
return self.from_expr(element)
else:
return self.ground_new(element)
__call__ = ring_new
def from_dict(self, element):
domain_new = self.domain_new
poly = self.zero
for monom, coeff in element.items():
coeff = domain_new(coeff)
if coeff:
poly[monom] = coeff
return poly
def from_terms(self, element):
return self.from_dict(dict(element))
def from_list(self, element):
return self.from_dict(dmp_to_dict(element, self.ngens-1, self.domain))
def _rebuild_expr(self, expr, mapping):
domain = self.domain
def _rebuild(expr):
generator = mapping.get(expr)
if generator is not None:
return generator
elif expr.is_Add:
return reduce(add, list(map(_rebuild, expr.args)))
elif expr.is_Mul:
return reduce(mul, list(map(_rebuild, expr.args)))
elif expr.is_Pow and expr.exp.is_Integer and expr.exp >= 0:
return _rebuild(expr.base)**int(expr.exp)
else:
return domain.convert(expr)
return _rebuild(sympify(expr))
def from_expr(self, expr):
mapping = dict(list(zip(self.symbols, self.gens)))
try:
poly = self._rebuild_expr(expr, mapping)
except CoercionFailed:
raise ValueError("expected an expression convertible to a polynomial in %s, got %s" % (self, expr))
else:
return self.ring_new(poly)
def index(self, gen):
"""Compute index of ``gen`` in ``self.gens``. """
if gen is None:
if self.ngens:
i = 0
else:
i = -1 # indicate impossible choice
elif isinstance(gen, int):
i = gen
if 0 <= i and i < self.ngens:
pass
elif -self.ngens <= i and i <= -1:
i = -i - 1
else:
raise ValueError("invalid generator index: %s" % gen)
elif isinstance(gen, self.dtype):
try:
i = self.gens.index(gen)
except ValueError:
raise ValueError("invalid generator: %s" % gen)
elif isinstance(gen, str):
try:
i = self.symbols.index(gen)
except ValueError:
raise ValueError("invalid generator: %s" % gen)
else:
raise ValueError("expected a polynomial generator, an integer, a string or None, got %s" % gen)
return i
def drop(self, *gens):
"""Remove specified generators from this ring. """
indices = set(map(self.index, gens))
symbols = [ s for i, s in enumerate(self.symbols) if i not in indices ]
if not symbols:
return self.domain
else:
return self.clone(symbols=symbols)
def __getitem__(self, key):
symbols = self.symbols[key]
if not symbols:
return self.domain
else:
return self.clone(symbols=symbols)
def to_ground(self):
# TODO: should AlgebraicField be a Composite domain?
if self.domain.is_Composite or hasattr(self.domain, 'domain'):
return self.clone(domain=self.domain.domain)
else:
raise ValueError("%s is not a composite domain" % self.domain)
def to_domain(self):
return PolynomialRing(self)
def to_field(self):
from sympy.polys.fields import FracField
return FracField(self.symbols, self.domain, self.order)
@property
def is_univariate(self):
return len(self.gens) == 1
@property
def is_multivariate(self):
return len(self.gens) > 1
def add(self, *objs):
"""
Add a sequence of polynomials or containers of polynomials.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> R, x = ring("x", ZZ)
>>> R.add([ x**2 + 2*i + 3 for i in range(4) ])
4*x**2 + 24
>>> _.factor_list()
(4, [(x**2 + 6, 1)])
"""
p = self.zero
for obj in objs:
if is_sequence(obj, include=GeneratorType):
p += self.add(*obj)
else:
p += obj
return p
def mul(self, *objs):
"""
Multiply a sequence of polynomials or containers of polynomials.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> R, x = ring("x", ZZ)
>>> R.mul([ x**2 + 2*i + 3 for i in range(4) ])
x**8 + 24*x**6 + 206*x**4 + 744*x**2 + 945
>>> _.factor_list()
(1, [(x**2 + 3, 1), (x**2 + 5, 1), (x**2 + 7, 1), (x**2 + 9, 1)])
"""
p = self.one
for obj in objs:
if is_sequence(obj, include=GeneratorType):
p *= self.mul(*obj)
else:
p *= obj
return p
def drop_to_ground(self, *gens):
r"""
Remove specified generators from the ring and inject them into
its domain.
"""
indices = set(map(self.index, gens))
symbols = [s for i, s in enumerate(self.symbols) if i not in indices]
gens = [gen for i, gen in enumerate(self.gens) if i not in indices]
if not symbols:
return self
else:
return self.clone(symbols=symbols, domain=self.drop(*gens))
def compose(self, other):
"""Add the generators of ``other`` to ``self``"""
if self != other:
syms = set(self.symbols).union(set(other.symbols))
return self.clone(symbols=list(syms))
else:
return self
def add_gens(self, symbols):
"""Add the elements of ``symbols`` as generators to ``self``"""
syms = set(self.symbols).union(set(symbols))
return self.clone(symbols=list(syms))
class PolyElement(DomainElement, DefaultPrinting, CantSympify, dict):
"""Element of multivariate distributed polynomial ring. """
def new(self, init):
return self.__class__(init)
def parent(self):
return self.ring.to_domain()
def __getnewargs__(self):
return (self.ring, list(self.iterterms()))
_hash = None
def __hash__(self):
# XXX: This computes a hash of a dictionary, but currently we don't
# protect dictionary from being changed so any use site modifications
# will make hashing go wrong. Use this feature with caution until we
# figure out how to make a safe API without compromising speed of this
# low-level class.
_hash = self._hash
if _hash is None:
self._hash = _hash = hash((self.ring, frozenset(self.items())))
return _hash
def copy(self):
"""Return a copy of polynomial self.
Polynomials are mutable; if one is interested in preserving
a polynomial, and one plans to use inplace operations, one
can copy the polynomial. This method makes a shallow copy.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> R, x, y = ring('x, y', ZZ)
>>> p = (x + y)**2
>>> p1 = p.copy()
>>> p2 = p
>>> p[R.zero_monom] = 3
>>> p
x**2 + 2*x*y + y**2 + 3
>>> p1
x**2 + 2*x*y + y**2
>>> p2
x**2 + 2*x*y + y**2 + 3
"""
return self.new(self)
def set_ring(self, new_ring):
if self.ring == new_ring:
return self
elif self.ring.symbols != new_ring.symbols:
terms = list(zip(*_dict_reorder(self, self.ring.symbols, new_ring.symbols)))
return new_ring.from_terms(terms)
else:
return new_ring.from_dict(self)
def as_expr(self, *symbols):
if symbols and len(symbols) != self.ring.ngens:
raise ValueError("not enough symbols, expected %s got %s" % (self.ring.ngens, len(symbols)))
else:
symbols = self.ring.symbols
return expr_from_dict(self.as_expr_dict(), *symbols)
def as_expr_dict(self):
to_sympy = self.ring.domain.to_sympy
return {monom: to_sympy(coeff) for monom, coeff in self.iterterms()}
def clear_denoms(self):
domain = self.ring.domain
if not domain.is_Field or not domain.has_assoc_Ring:
return domain.one, self
ground_ring = domain.get_ring()
common = ground_ring.one
lcm = ground_ring.lcm
denom = domain.denom
for coeff in self.values():
common = lcm(common, denom(coeff))
poly = self.new([ (k, v*common) for k, v in self.items() ])
return common, poly
def strip_zero(self):
"""Eliminate monomials with zero coefficient. """
for k, v in list(self.items()):
if not v:
del self[k]
def __eq__(p1, p2):
"""Equality test for polynomials.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', ZZ)
>>> p1 = (x + y)**2 + (x - y)**2
>>> p1 == 4*x*y
False
>>> p1 == 2*(x**2 + y**2)
True
"""
if not p2:
return not p1
elif isinstance(p2, PolyElement) and p2.ring == p1.ring:
return dict.__eq__(p1, p2)
elif len(p1) > 1:
return False
else:
return p1.get(p1.ring.zero_monom) == p2
def __ne__(p1, p2):
return not p1 == p2
def almosteq(p1, p2, tolerance=None):
"""Approximate equality test for polynomials. """
ring = p1.ring
if isinstance(p2, ring.dtype):
if set(p1.keys()) != set(p2.keys()):
return False
almosteq = ring.domain.almosteq
for k in p1.keys():
if not almosteq(p1[k], p2[k], tolerance):
return False
return True
elif len(p1) > 1:
return False
else:
try:
p2 = ring.domain.convert(p2)
except CoercionFailed:
return False
else:
return ring.domain.almosteq(p1.const(), p2, tolerance)
def sort_key(self):
return (len(self), self.terms())
def _cmp(p1, p2, op):
if isinstance(p2, p1.ring.dtype):
return op(p1.sort_key(), p2.sort_key())
else:
return NotImplemented
def __lt__(p1, p2):
return p1._cmp(p2, lt)
def __le__(p1, p2):
return p1._cmp(p2, le)
def __gt__(p1, p2):
return p1._cmp(p2, gt)
def __ge__(p1, p2):
return p1._cmp(p2, ge)
def _drop(self, gen):
ring = self.ring
i = ring.index(gen)
if ring.ngens == 1:
return i, ring.domain
else:
symbols = list(ring.symbols)
del symbols[i]
return i, ring.clone(symbols=symbols)
def drop(self, gen):
i, ring = self._drop(gen)
if self.ring.ngens == 1:
if self.is_ground:
return self.coeff(1)
else:
raise ValueError("can't drop %s" % gen)
else:
poly = ring.zero
for k, v in self.items():
if k[i] == 0:
K = list(k)
del K[i]
poly[tuple(K)] = v
else:
raise ValueError("can't drop %s" % gen)
return poly
def _drop_to_ground(self, gen):
ring = self.ring
i = ring.index(gen)
symbols = list(ring.symbols)
del symbols[i]
return i, ring.clone(symbols=symbols, domain=ring[i])
def drop_to_ground(self, gen):
if self.ring.ngens == 1:
raise ValueError("can't drop only generator to ground")
i, ring = self._drop_to_ground(gen)
poly = ring.zero
gen = ring.domain.gens[0]
for monom, coeff in self.iterterms():
mon = monom[:i] + monom[i+1:]
if not mon in poly:
poly[mon] = (gen**monom[i]).mul_ground(coeff)
else:
poly[mon] += (gen**monom[i]).mul_ground(coeff)
return poly
def to_dense(self):
return dmp_from_dict(self, self.ring.ngens-1, self.ring.domain)
def to_dict(self):
return dict(self)
def str(self, printer, precedence, exp_pattern, mul_symbol):
if not self:
return printer._print(self.ring.domain.zero)
prec_mul = precedence["Mul"]
prec_atom = precedence["Atom"]
ring = self.ring
symbols = ring.symbols
ngens = ring.ngens
zm = ring.zero_monom
sexpvs = []
for expv, coeff in self.terms():
positive = ring.domain.is_positive(coeff)
sign = " + " if positive else " - "
sexpvs.append(sign)
if expv == zm:
scoeff = printer._print(coeff)
if scoeff.startswith("-"):
scoeff = scoeff[1:]
else:
if not positive:
coeff = -coeff
if coeff != 1:
scoeff = printer.parenthesize(coeff, prec_mul, strict=True)
else:
scoeff = ''
sexpv = []
for i in range(ngens):
exp = expv[i]
if not exp:
continue
symbol = printer.parenthesize(symbols[i], prec_atom, strict=True)
if exp != 1:
if exp != int(exp) or exp < 0:
sexp = printer.parenthesize(exp, prec_atom, strict=False)
else:
sexp = exp
sexpv.append(exp_pattern % (symbol, sexp))
else:
sexpv.append('%s' % symbol)
if scoeff:
sexpv = [scoeff] + sexpv
sexpvs.append(mul_symbol.join(sexpv))
if sexpvs[0] in [" + ", " - "]:
head = sexpvs.pop(0)
if head == " - ":
sexpvs.insert(0, "-")
return "".join(sexpvs)
@property
def is_generator(self):
return self in self.ring._gens_set
@property
def is_ground(self):
return not self or (len(self) == 1 and self.ring.zero_monom in self)
@property
def is_monomial(self):
return not self or (len(self) == 1 and self.LC == 1)
@property
def is_term(self):
return len(self) <= 1
@property
def is_negative(self):
return self.ring.domain.is_negative(self.LC)
@property
def is_positive(self):
return self.ring.domain.is_positive(self.LC)
@property
def is_nonnegative(self):
return self.ring.domain.is_nonnegative(self.LC)
@property
def is_nonpositive(self):
return self.ring.domain.is_nonpositive(self.LC)
@property
def is_zero(f):
return not f
@property
def is_one(f):
return f == f.ring.one
@property
def is_monic(f):
return f.ring.domain.is_one(f.LC)
@property
def is_primitive(f):
return f.ring.domain.is_one(f.content())
@property
def is_linear(f):
return all(sum(monom) <= 1 for monom in f.itermonoms())
@property
def is_quadratic(f):
return all(sum(monom) <= 2 for monom in f.itermonoms())
@property
def is_squarefree(f):
if not f.ring.ngens:
return True
return f.ring.dmp_sqf_p(f)
@property
def is_irreducible(f):
if not f.ring.ngens:
return True
return f.ring.dmp_irreducible_p(f)
@property
def is_cyclotomic(f):
if f.ring.is_univariate:
return f.ring.dup_cyclotomic_p(f)
else:
raise MultivariatePolynomialError("cyclotomic polynomial")
def __neg__(self):
return self.new([ (monom, -coeff) for monom, coeff in self.iterterms() ])
def __pos__(self):
return self
def __add__(p1, p2):
"""Add two polynomials.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', ZZ)
>>> (x + y)**2 + (x - y)**2
2*x**2 + 2*y**2
"""
if not p2:
return p1.copy()
ring = p1.ring
if isinstance(p2, ring.dtype):
p = p1.copy()
get = p.get
zero = ring.domain.zero
for k, v in p2.items():
v = get(k, zero) + v
if v:
p[k] = v
else:
del p[k]
return p
elif isinstance(p2, PolyElement):
if isinstance(ring.domain, PolynomialRing) and ring.domain.ring == p2.ring:
pass
elif isinstance(p2.ring.domain, PolynomialRing) and p2.ring.domain.ring == ring:
return p2.__radd__(p1)
else:
return NotImplemented
try:
cp2 = ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
p = p1.copy()
if not cp2:
return p
zm = ring.zero_monom
if zm not in p1.keys():
p[zm] = cp2
else:
if p2 == -p[zm]:
del p[zm]
else:
p[zm] += cp2
return p
def __radd__(p1, n):
p = p1.copy()
if not n:
return p
ring = p1.ring
try:
n = ring.domain_new(n)
except CoercionFailed:
return NotImplemented
else:
zm = ring.zero_monom
if zm not in p1.keys():
p[zm] = n
else:
if n == -p[zm]:
del p[zm]
else:
p[zm] += n
return p
def __sub__(p1, p2):
"""Subtract polynomial p2 from p1.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', ZZ)
>>> p1 = x + y**2
>>> p2 = x*y + y**2
>>> p1 - p2
-x*y + x
"""
if not p2:
return p1.copy()
ring = p1.ring
if isinstance(p2, ring.dtype):
p = p1.copy()
get = p.get
zero = ring.domain.zero
for k, v in p2.items():
v = get(k, zero) - v
if v:
p[k] = v
else:
del p[k]
return p
elif isinstance(p2, PolyElement):
if isinstance(ring.domain, PolynomialRing) and ring.domain.ring == p2.ring:
pass
elif isinstance(p2.ring.domain, PolynomialRing) and p2.ring.domain.ring == ring:
return p2.__rsub__(p1)
else:
return NotImplemented
try:
p2 = ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
p = p1.copy()
zm = ring.zero_monom
if zm not in p1.keys():
p[zm] = -p2
else:
if p2 == p[zm]:
del p[zm]
else:
p[zm] -= p2
return p
def __rsub__(p1, n):
"""n - p1 with n convertible to the coefficient domain.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', ZZ)
>>> p = x + y
>>> 4 - p
-x - y + 4
"""
ring = p1.ring
try:
n = ring.domain_new(n)
except CoercionFailed:
return NotImplemented
else:
p = ring.zero
for expv in p1:
p[expv] = -p1[expv]
p += n
return p
def __mul__(p1, p2):
"""Multiply two polynomials.
Examples
========
>>> from sympy.polys.domains import QQ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', QQ)
>>> p1 = x + y
>>> p2 = x - y
>>> p1*p2
x**2 - y**2
"""
ring = p1.ring
p = ring.zero
if not p1 or not p2:
return p
elif isinstance(p2, ring.dtype):
get = p.get
zero = ring.domain.zero
monomial_mul = ring.monomial_mul
p2it = list(p2.items())
for exp1, v1 in p1.items():
for exp2, v2 in p2it:
exp = monomial_mul(exp1, exp2)
p[exp] = get(exp, zero) + v1*v2
p.strip_zero()
return p
elif isinstance(p2, PolyElement):
if isinstance(ring.domain, PolynomialRing) and ring.domain.ring == p2.ring:
pass
elif isinstance(p2.ring.domain, PolynomialRing) and p2.ring.domain.ring == ring:
return p2.__rmul__(p1)
else:
return NotImplemented
try:
p2 = ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
for exp1, v1 in p1.items():
v = v1*p2
if v:
p[exp1] = v
return p
def __rmul__(p1, p2):
"""p2 * p1 with p2 in the coefficient domain of p1.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', ZZ)
>>> p = x + y
>>> 4 * p
4*x + 4*y
"""
p = p1.ring.zero
if not p2:
return p
try:
p2 = p.ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
for exp1, v1 in p1.items():
v = p2*v1
if v:
p[exp1] = v
return p
def __pow__(self, n):
"""raise polynomial to power `n`
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.rings import ring
>>> _, x, y = ring('x, y', ZZ)
>>> p = x + y**2
>>> p**3
x**3 + 3*x**2*y**2 + 3*x*y**4 + y**6
"""
ring = self.ring
if not n:
if self:
return ring.one
else:
raise ValueError("0**0")
elif len(self) == 1:
monom, coeff = list(self.items())[0]
p = ring.zero
if coeff == 1:
p[ring.monomial_pow(monom, n)] = coeff
else:
p[ring.monomial_pow(monom, n)] = coeff**n
return p
# For ring series, we need negative and rational exponent support only
# with monomials.
n = int(n)
if n < 0:
raise ValueError("Negative exponent")
elif n == 1:
return self.copy()
elif n == 2:
return self.square()
elif n == 3:
return self*self.square()
elif len(self) <= 5: # TODO: use an actual density measure
return self._pow_multinomial(n)
else:
return self._pow_generic(n)
def _pow_generic(self, n):
p = self.ring.one
c = self
while True:
if n & 1:
p = p*c
n -= 1
if not n:
break
c = c.square()
n = n // 2
return p
def _pow_multinomial(self, n):
multinomials = list(multinomial_coefficients(len(self), n).items())
monomial_mulpow = self.ring.monomial_mulpow
zero_monom = self.ring.zero_monom
terms = list(self.iterterms())
zero = self.ring.domain.zero
poly = self.ring.zero
for multinomial, multinomial_coeff in multinomials:
product_monom = zero_monom
product_coeff = multinomial_coeff
for exp, (monom, coeff) in zip(multinomial, terms):
if exp:
product_monom = monomial_mulpow(product_monom, monom, exp)
product_coeff *= coeff**exp
monom = tuple(product_monom)
coeff = product_coeff
coeff = poly.get(monom, zero) + coeff
if coeff:
poly[monom] = coeff
else:
del poly[monom]
return poly
def square(self):
"""square of a polynomial
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring('x, y', ZZ)
>>> p = x + y**2
>>> p.square()
x**2 + 2*x*y**2 + y**4
"""
ring = self.ring
p = ring.zero
get = p.get
keys = list(self.keys())
zero = ring.domain.zero
monomial_mul = ring.monomial_mul
for i in range(len(keys)):
k1 = keys[i]
pk = self[k1]
for j in range(i):
k2 = keys[j]
exp = monomial_mul(k1, k2)
p[exp] = get(exp, zero) + pk*self[k2]
p = p.imul_num(2)
get = p.get
for k, v in self.items():
k2 = monomial_mul(k, k)
p[k2] = get(k2, zero) + v**2
p.strip_zero()
return p
def __divmod__(p1, p2):
ring = p1.ring
if not p2:
raise ZeroDivisionError("polynomial division")
elif isinstance(p2, ring.dtype):
return p1.div(p2)
elif isinstance(p2, PolyElement):
if isinstance(ring.domain, PolynomialRing) and ring.domain.ring == p2.ring:
pass
elif isinstance(p2.ring.domain, PolynomialRing) and p2.ring.domain.ring == ring:
return p2.__rdivmod__(p1)
else:
return NotImplemented
try:
p2 = ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
return (p1.quo_ground(p2), p1.rem_ground(p2))
def __rdivmod__(p1, p2):
return NotImplemented
def __mod__(p1, p2):
ring = p1.ring
if not p2:
raise ZeroDivisionError("polynomial division")
elif isinstance(p2, ring.dtype):
return p1.rem(p2)
elif isinstance(p2, PolyElement):
if isinstance(ring.domain, PolynomialRing) and ring.domain.ring == p2.ring:
pass
elif isinstance(p2.ring.domain, PolynomialRing) and p2.ring.domain.ring == ring:
return p2.__rmod__(p1)
else:
return NotImplemented
try:
p2 = ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
return p1.rem_ground(p2)
def __rmod__(p1, p2):
return NotImplemented
def __truediv__(p1, p2):
ring = p1.ring
if not p2:
raise ZeroDivisionError("polynomial division")
elif isinstance(p2, ring.dtype):
if p2.is_monomial:
return p1*(p2**(-1))
else:
return p1.quo(p2)
elif isinstance(p2, PolyElement):
if isinstance(ring.domain, PolynomialRing) and ring.domain.ring == p2.ring:
pass
elif isinstance(p2.ring.domain, PolynomialRing) and p2.ring.domain.ring == ring:
return p2.__rtruediv__(p1)
else:
return NotImplemented
try:
p2 = ring.domain_new(p2)
except CoercionFailed:
return NotImplemented
else:
return p1.quo_ground(p2)
def __rtruediv__(p1, p2):
return NotImplemented
__floordiv__ = __div__ = __truediv__
__rfloordiv__ = __rdiv__ = __rtruediv__
# TODO: use // (__floordiv__) for exquo()?
def _term_div(self):
zm = self.ring.zero_monom
domain = self.ring.domain
domain_quo = domain.quo
monomial_div = self.ring.monomial_div
if domain.is_Field:
def term_div(a_lm_a_lc, b_lm_b_lc):
a_lm, a_lc = a_lm_a_lc
b_lm, b_lc = b_lm_b_lc
if b_lm == zm: # apparently this is a very common case
monom = a_lm
else:
monom = monomial_div(a_lm, b_lm)
if monom is not None:
return monom, domain_quo(a_lc, b_lc)
else:
return None
else:
def term_div(a_lm_a_lc, b_lm_b_lc):
a_lm, a_lc = a_lm_a_lc
b_lm, b_lc = b_lm_b_lc
if b_lm == zm: # apparently this is a very common case
monom = a_lm
else:
monom = monomial_div(a_lm, b_lm)
if not (monom is None or a_lc % b_lc):
return monom, domain_quo(a_lc, b_lc)
else:
return None
return term_div
def div(self, fv):
"""Division algorithm, see [CLO] p64.
fv array of polynomials
return qv, r such that
self = sum(fv[i]*qv[i]) + r
All polynomials are required not to be Laurent polynomials.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring('x, y', ZZ)
>>> f = x**3
>>> f0 = x - y**2
>>> f1 = x - y
>>> qv, r = f.div((f0, f1))
>>> qv[0]
x**2 + x*y**2 + y**4
>>> qv[1]
0
>>> r
y**6
"""
ring = self.ring
ret_single = False
if isinstance(fv, PolyElement):
ret_single = True
fv = [fv]
if any(not f for f in fv):
raise ZeroDivisionError("polynomial division")
if not self:
if ret_single:
return ring.zero, ring.zero
else:
return [], ring.zero
for f in fv:
if f.ring != ring:
raise ValueError('self and f must have the same ring')
s = len(fv)
qv = [ring.zero for i in range(s)]
p = self.copy()
r = ring.zero
term_div = self._term_div()
expvs = [fx.leading_expv() for fx in fv]
while p:
i = 0
divoccurred = 0
while i < s and divoccurred == 0:
expv = p.leading_expv()
term = term_div((expv, p[expv]), (expvs[i], fv[i][expvs[i]]))
if term is not None:
expv1, c = term
qv[i] = qv[i]._iadd_monom((expv1, c))
p = p._iadd_poly_monom(fv[i], (expv1, -c))
divoccurred = 1
else:
i += 1
if not divoccurred:
expv = p.leading_expv()
r = r._iadd_monom((expv, p[expv]))
del p[expv]
if expv == ring.zero_monom:
r += p
if ret_single:
if not qv:
return ring.zero, r
else:
return qv[0], r
else:
return qv, r
def rem(self, G):
f = self
if isinstance(G, PolyElement):
G = [G]
if any(not g for g in G):
raise ZeroDivisionError("polynomial division")
ring = f.ring
domain = ring.domain
zero = domain.zero
monomial_mul = ring.monomial_mul
r = ring.zero
term_div = f._term_div()
ltf = f.LT
f = f.copy()
get = f.get
while f:
for g in G:
tq = term_div(ltf, g.LT)
if tq is not None:
m, c = tq
for mg, cg in g.iterterms():
m1 = monomial_mul(mg, m)
c1 = get(m1, zero) - c*cg
if not c1:
del f[m1]
else:
f[m1] = c1
ltm = f.leading_expv()
if ltm is not None:
ltf = ltm, f[ltm]
break
else:
ltm, ltc = ltf
if ltm in r:
r[ltm] += ltc
else:
r[ltm] = ltc
del f[ltm]
ltm = f.leading_expv()
if ltm is not None:
ltf = ltm, f[ltm]
return r
def quo(f, G):
return f.div(G)[0]
def exquo(f, G):
q, r = f.div(G)
if not r:
return q
else:
raise ExactQuotientFailed(f, G)
def _iadd_monom(self, mc):
"""add to self the monomial coeff*x0**i0*x1**i1*...
unless self is a generator -- then just return the sum of the two.
mc is a tuple, (monom, coeff), where monomial is (i0, i1, ...)
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring('x, y', ZZ)
>>> p = x**4 + 2*y
>>> m = (1, 2)
>>> p1 = p._iadd_monom((m, 5))
>>> p1
x**4 + 5*x*y**2 + 2*y
>>> p1 is p
True
>>> p = x
>>> p1 = p._iadd_monom((m, 5))
>>> p1
5*x*y**2 + x
>>> p1 is p
False
"""
if self in self.ring._gens_set:
cpself = self.copy()
else:
cpself = self
expv, coeff = mc
c = cpself.get(expv)
if c is None:
cpself[expv] = coeff
else:
c += coeff
if c:
cpself[expv] = c
else:
del cpself[expv]
return cpself
def _iadd_poly_monom(self, p2, mc):
"""add to self the product of (p)*(coeff*x0**i0*x1**i1*...)
unless self is a generator -- then just return the sum of the two.
mc is a tuple, (monom, coeff), where monomial is (i0, i1, ...)
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y, z = ring('x, y, z', ZZ)
>>> p1 = x**4 + 2*y
>>> p2 = y + z
>>> m = (1, 2, 3)
>>> p1 = p1._iadd_poly_monom(p2, (m, 3))
>>> p1
x**4 + 3*x*y**3*z**3 + 3*x*y**2*z**4 + 2*y
"""
p1 = self
if p1 in p1.ring._gens_set:
p1 = p1.copy()
(m, c) = mc
get = p1.get
zero = p1.ring.domain.zero
monomial_mul = p1.ring.monomial_mul
for k, v in p2.items():
ka = monomial_mul(k, m)
coeff = get(ka, zero) + v*c
if coeff:
p1[ka] = coeff
else:
del p1[ka]
return p1
def degree(f, x=None):
"""
The leading degree in ``x`` or the main variable.
Note that the degree of 0 is negative infinity (the SymPy object -oo).
"""
i = f.ring.index(x)
if not f:
return -oo
elif i < 0:
return 0
else:
return max([ monom[i] for monom in f.itermonoms() ])
def degrees(f):
"""
A tuple containing leading degrees in all variables.
Note that the degree of 0 is negative infinity (the SymPy object -oo)
"""
if not f:
return (-oo,)*f.ring.ngens
else:
return tuple(map(max, list(zip(*f.itermonoms()))))
def tail_degree(f, x=None):
"""
The tail degree in ``x`` or the main variable.
Note that the degree of 0 is negative infinity (the SymPy object -oo)
"""
i = f.ring.index(x)
if not f:
return -oo
elif i < 0:
return 0
else:
return min([ monom[i] for monom in f.itermonoms() ])
def tail_degrees(f):
"""
A tuple containing tail degrees in all variables.
Note that the degree of 0 is negative infinity (the SymPy object -oo)
"""
if not f:
return (-oo,)*f.ring.ngens
else:
return tuple(map(min, list(zip(*f.itermonoms()))))
def leading_expv(self):
"""Leading monomial tuple according to the monomial ordering.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y, z = ring('x, y, z', ZZ)
>>> p = x**4 + x**3*y + x**2*z**2 + z**7
>>> p.leading_expv()
(4, 0, 0)
"""
if self:
return self.ring.leading_expv(self)
else:
return None
def _get_coeff(self, expv):
return self.get(expv, self.ring.domain.zero)
def coeff(self, element):
"""
Returns the coefficient that stands next to the given monomial.
Parameters
==========
element : PolyElement (with ``is_monomial = True``) or 1
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y, z = ring("x,y,z", ZZ)
>>> f = 3*x**2*y - x*y*z + 7*z**3 + 23
>>> f.coeff(x**2*y)
3
>>> f.coeff(x*y)
0
>>> f.coeff(1)
23
"""
if element == 1:
return self._get_coeff(self.ring.zero_monom)
elif isinstance(element, self.ring.dtype):
terms = list(element.iterterms())
if len(terms) == 1:
monom, coeff = terms[0]
if coeff == self.ring.domain.one:
return self._get_coeff(monom)
raise ValueError("expected a monomial, got %s" % element)
def const(self):
"""Returns the constant coeffcient. """
return self._get_coeff(self.ring.zero_monom)
@property
def LC(self):
return self._get_coeff(self.leading_expv())
@property
def LM(self):
expv = self.leading_expv()
if expv is None:
return self.ring.zero_monom
else:
return expv
def leading_monom(self):
"""
Leading monomial as a polynomial element.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring('x, y', ZZ)
>>> (3*x*y + y**2).leading_monom()
x*y
"""
p = self.ring.zero
expv = self.leading_expv()
if expv:
p[expv] = self.ring.domain.one
return p
@property
def LT(self):
expv = self.leading_expv()
if expv is None:
return (self.ring.zero_monom, self.ring.domain.zero)
else:
return (expv, self._get_coeff(expv))
def leading_term(self):
"""Leading term as a polynomial element.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring('x, y', ZZ)
>>> (3*x*y + y**2).leading_term()
3*x*y
"""
p = self.ring.zero
expv = self.leading_expv()
if expv is not None:
p[expv] = self[expv]
return p
def _sorted(self, seq, order):
if order is None:
order = self.ring.order
else:
order = OrderOpt.preprocess(order)
if order is lex:
return sorted(seq, key=lambda monom: monom[0], reverse=True)
else:
return sorted(seq, key=lambda monom: order(monom[0]), reverse=True)
def coeffs(self, order=None):
"""Ordered list of polynomial coefficients.
Parameters
==========
order : :class:`~.MonomialOrder` or coercible, optional
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.orderings import lex, grlex
>>> _, x, y = ring("x, y", ZZ, lex)
>>> f = x*y**7 + 2*x**2*y**3
>>> f.coeffs()
[2, 1]
>>> f.coeffs(grlex)
[1, 2]
"""
return [ coeff for _, coeff in self.terms(order) ]
def monoms(self, order=None):
"""Ordered list of polynomial monomials.
Parameters
==========
order : :class:`~.MonomialOrder` or coercible, optional
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.orderings import lex, grlex
>>> _, x, y = ring("x, y", ZZ, lex)
>>> f = x*y**7 + 2*x**2*y**3
>>> f.monoms()
[(2, 3), (1, 7)]
>>> f.monoms(grlex)
[(1, 7), (2, 3)]
"""
return [ monom for monom, _ in self.terms(order) ]
def terms(self, order=None):
"""Ordered list of polynomial terms.
Parameters
==========
order : :class:`~.MonomialOrder` or coercible, optional
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> from sympy.polys.orderings import lex, grlex
>>> _, x, y = ring("x, y", ZZ, lex)
>>> f = x*y**7 + 2*x**2*y**3
>>> f.terms()
[((2, 3), 2), ((1, 7), 1)]
>>> f.terms(grlex)
[((1, 7), 1), ((2, 3), 2)]
"""
return self._sorted(list(self.items()), order)
def itercoeffs(self):
"""Iterator over coefficients of a polynomial. """
return iter(self.values())
def itermonoms(self):
"""Iterator over monomials of a polynomial. """
return iter(self.keys())
def iterterms(self):
"""Iterator over terms of a polynomial. """
return iter(self.items())
def listcoeffs(self):
"""Unordered list of polynomial coefficients. """
return list(self.values())
def listmonoms(self):
"""Unordered list of polynomial monomials. """
return list(self.keys())
def listterms(self):
"""Unordered list of polynomial terms. """
return list(self.items())
def imul_num(p, c):
"""multiply inplace the polynomial p by an element in the
coefficient ring, provided p is not one of the generators;
else multiply not inplace
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring('x, y', ZZ)
>>> p = x + y**2
>>> p1 = p.imul_num(3)
>>> p1
3*x + 3*y**2
>>> p1 is p
True
>>> p = x
>>> p1 = p.imul_num(3)
>>> p1
3*x
>>> p1 is p
False
"""
if p in p.ring._gens_set:
return p*c
if not c:
p.clear()
return
for exp in p:
p[exp] *= c
return p
def content(f):
"""Returns GCD of polynomial's coefficients. """
domain = f.ring.domain
cont = domain.zero
gcd = domain.gcd
for coeff in f.itercoeffs():
cont = gcd(cont, coeff)
return cont
def primitive(f):
"""Returns content and a primitive polynomial. """
cont = f.content()
return cont, f.quo_ground(cont)
def monic(f):
"""Divides all coefficients by the leading coefficient. """
if not f:
return f
else:
return f.quo_ground(f.LC)
def mul_ground(f, x):
if not x:
return f.ring.zero
terms = [ (monom, coeff*x) for monom, coeff in f.iterterms() ]
return f.new(terms)
def mul_monom(f, monom):
monomial_mul = f.ring.monomial_mul
terms = [ (monomial_mul(f_monom, monom), f_coeff) for f_monom, f_coeff in f.items() ]
return f.new(terms)
def mul_term(f, term):
monom, coeff = term
if not f or not coeff:
return f.ring.zero
elif monom == f.ring.zero_monom:
return f.mul_ground(coeff)
monomial_mul = f.ring.monomial_mul
terms = [ (monomial_mul(f_monom, monom), f_coeff*coeff) for f_monom, f_coeff in f.items() ]
return f.new(terms)
def quo_ground(f, x):
domain = f.ring.domain
if not x:
raise ZeroDivisionError('polynomial division')
if not f or x == domain.one:
return f
if domain.is_Field:
quo = domain.quo
terms = [ (monom, quo(coeff, x)) for monom, coeff in f.iterterms() ]
else:
terms = [ (monom, coeff // x) for monom, coeff in f.iterterms() if not (coeff % x) ]
return f.new(terms)
def quo_term(f, term):
monom, coeff = term
if not coeff:
raise ZeroDivisionError("polynomial division")
elif not f:
return f.ring.zero
elif monom == f.ring.zero_monom:
return f.quo_ground(coeff)
term_div = f._term_div()
terms = [ term_div(t, term) for t in f.iterterms() ]
return f.new([ t for t in terms if t is not None ])
def trunc_ground(f, p):
if f.ring.domain.is_ZZ:
terms = []
for monom, coeff in f.iterterms():
coeff = coeff % p
if coeff > p // 2:
coeff = coeff - p
terms.append((monom, coeff))
else:
terms = [ (monom, coeff % p) for monom, coeff in f.iterterms() ]
poly = f.new(terms)
poly.strip_zero()
return poly
rem_ground = trunc_ground
def extract_ground(self, g):
f = self
fc = f.content()
gc = g.content()
gcd = f.ring.domain.gcd(fc, gc)
f = f.quo_ground(gcd)
g = g.quo_ground(gcd)
return gcd, f, g
def _norm(f, norm_func):
if not f:
return f.ring.domain.zero
else:
ground_abs = f.ring.domain.abs
return norm_func([ ground_abs(coeff) for coeff in f.itercoeffs() ])
def max_norm(f):
return f._norm(max)
def l1_norm(f):
return f._norm(sum)
def deflate(f, *G):
ring = f.ring
polys = [f] + list(G)
J = [0]*ring.ngens
for p in polys:
for monom in p.itermonoms():
for i, m in enumerate(monom):
J[i] = igcd(J[i], m)
for i, b in enumerate(J):
if not b:
J[i] = 1
J = tuple(J)
if all(b == 1 for b in J):
return J, polys
H = []
for p in polys:
h = ring.zero
for I, coeff in p.iterterms():
N = [ i // j for i, j in zip(I, J) ]
h[tuple(N)] = coeff
H.append(h)
return J, H
def inflate(f, J):
poly = f.ring.zero
for I, coeff in f.iterterms():
N = [ i*j for i, j in zip(I, J) ]
poly[tuple(N)] = coeff
return poly
def lcm(self, g):
f = self
domain = f.ring.domain
if not domain.is_Field:
fc, f = f.primitive()
gc, g = g.primitive()
c = domain.lcm(fc, gc)
h = (f*g).quo(f.gcd(g))
if not domain.is_Field:
return h.mul_ground(c)
else:
return h.monic()
def gcd(f, g):
return f.cofactors(g)[0]
def cofactors(f, g):
if not f and not g:
zero = f.ring.zero
return zero, zero, zero
elif not f:
h, cff, cfg = f._gcd_zero(g)
return h, cff, cfg
elif not g:
h, cfg, cff = g._gcd_zero(f)
return h, cff, cfg
elif len(f) == 1:
h, cff, cfg = f._gcd_monom(g)
return h, cff, cfg
elif len(g) == 1:
h, cfg, cff = g._gcd_monom(f)
return h, cff, cfg
J, (f, g) = f.deflate(g)
h, cff, cfg = f._gcd(g)
return (h.inflate(J), cff.inflate(J), cfg.inflate(J))
def _gcd_zero(f, g):
one, zero = f.ring.one, f.ring.zero
if g.is_nonnegative:
return g, zero, one
else:
return -g, zero, -one
def _gcd_monom(f, g):
ring = f.ring
ground_gcd = ring.domain.gcd
ground_quo = ring.domain.quo
monomial_gcd = ring.monomial_gcd
monomial_ldiv = ring.monomial_ldiv
mf, cf = list(f.iterterms())[0]
_mgcd, _cgcd = mf, cf
for mg, cg in g.iterterms():
_mgcd = monomial_gcd(_mgcd, mg)
_cgcd = ground_gcd(_cgcd, cg)
h = f.new([(_mgcd, _cgcd)])
cff = f.new([(monomial_ldiv(mf, _mgcd), ground_quo(cf, _cgcd))])
cfg = f.new([(monomial_ldiv(mg, _mgcd), ground_quo(cg, _cgcd)) for mg, cg in g.iterterms()])
return h, cff, cfg
def _gcd(f, g):
ring = f.ring
if ring.domain.is_QQ:
return f._gcd_QQ(g)
elif ring.domain.is_ZZ:
return f._gcd_ZZ(g)
else: # TODO: don't use dense representation (port PRS algorithms)
return ring.dmp_inner_gcd(f, g)
def _gcd_ZZ(f, g):
return heugcd(f, g)
def _gcd_QQ(self, g):
f = self
ring = f.ring
new_ring = ring.clone(domain=ring.domain.get_ring())
cf, f = f.clear_denoms()
cg, g = g.clear_denoms()
f = f.set_ring(new_ring)
g = g.set_ring(new_ring)
h, cff, cfg = f._gcd_ZZ(g)
h = h.set_ring(ring)
c, h = h.LC, h.monic()
cff = cff.set_ring(ring).mul_ground(ring.domain.quo(c, cf))
cfg = cfg.set_ring(ring).mul_ground(ring.domain.quo(c, cg))
return h, cff, cfg
def cancel(self, g):
"""
Cancel common factors in a rational function ``f/g``.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
>>> (2*x**2 - 2).cancel(x**2 - 2*x + 1)
(2*x + 2, x - 1)
"""
f = self
ring = f.ring
if not f:
return f, ring.one
domain = ring.domain
if not (domain.is_Field and domain.has_assoc_Ring):
_, p, q = f.cofactors(g)
if q.is_negative:
p, q = -p, -q
else:
new_ring = ring.clone(domain=domain.get_ring())
cq, f = f.clear_denoms()
cp, g = g.clear_denoms()
f = f.set_ring(new_ring)
g = g.set_ring(new_ring)
_, p, q = f.cofactors(g)
_, cp, cq = new_ring.domain.cofactors(cp, cq)
p = p.set_ring(ring)
q = q.set_ring(ring)
p_neg = p.is_negative
q_neg = q.is_negative
if p_neg and q_neg:
p, q = -p, -q
elif p_neg:
cp, p = -cp, -p
elif q_neg:
cp, q = -cp, -q
p = p.mul_ground(cp)
q = q.mul_ground(cq)
return p, q
def diff(f, x):
"""Computes partial derivative in ``x``.
Examples
========
>>> from sympy.polys.rings import ring
>>> from sympy.polys.domains import ZZ
>>> _, x, y = ring("x,y", ZZ)
>>> p = x + x**2*y**3
>>> p.diff(x)
2*x*y**3 + 1
"""
ring = f.ring
i = ring.index(x)
m = ring.monomial_basis(i)
g = ring.zero
for expv, coeff in f.iterterms():
if expv[i]:
e = ring.monomial_ldiv(expv, m)
g[e] = ring.domain_new(coeff*expv[i])
return g
def __call__(f, *values):
if 0 < len(values) <= f.ring.ngens:
return f.evaluate(list(zip(f.ring.gens, values)))
else:
raise ValueError("expected at least 1 and at most %s values, got %s" % (f.ring.ngens, len(values)))
def evaluate(self, x, a=None):
f = self
if isinstance(x, list) and a is None:
(X, a), x = x[0], x[1:]
f = f.evaluate(X, a)
if not x:
return f
else:
x = [ (Y.drop(X), a) for (Y, a) in x ]
return f.evaluate(x)
ring = f.ring
i = ring.index(x)
a = ring.domain.convert(a)
if ring.ngens == 1:
result = ring.domain.zero
for (n,), coeff in f.iterterms():
result += coeff*a**n
return result
else:
poly = ring.drop(x).zero
for monom, coeff in f.iterterms():
n, monom = monom[i], monom[:i] + monom[i+1:]
coeff = coeff*a**n
if monom in poly:
coeff = coeff + poly[monom]
if coeff:
poly[monom] = coeff
else:
del poly[monom]
else:
if coeff:
poly[monom] = coeff
return poly
def subs(self, x, a=None):
f = self
if isinstance(x, list) and a is None:
for X, a in x:
f = f.subs(X, a)
return f
ring = f.ring
i = ring.index(x)
a = ring.domain.convert(a)
if ring.ngens == 1:
result = ring.domain.zero
for (n,), coeff in f.iterterms():
result += coeff*a**n
return ring.ground_new(result)
else:
poly = ring.zero
for monom, coeff in f.iterterms():
n, monom = monom[i], monom[:i] + (0,) + monom[i+1:]
coeff = coeff*a**n
if monom in poly:
coeff = coeff + poly[monom]
if coeff:
poly[monom] = coeff
else:
del poly[monom]
else:
if coeff:
poly[monom] = coeff
return poly
def compose(f, x, a=None):
ring = f.ring
poly = ring.zero
gens_map = dict(list(zip(ring.gens, list(range(ring.ngens)))))
if a is not None:
replacements = [(x, a)]
else:
if isinstance(x, list):
replacements = list(x)
elif isinstance(x, dict):
replacements = sorted(list(x.items()), key=lambda k: gens_map[k[0]])
else:
raise ValueError("expected a generator, value pair a sequence of such pairs")
for k, (x, g) in enumerate(replacements):
replacements[k] = (gens_map[x], ring.ring_new(g))
for monom, coeff in f.iterterms():
monom = list(monom)
subpoly = ring.one
for i, g in replacements:
n, monom[i] = monom[i], 0
if n:
subpoly *= g**n
subpoly = subpoly.mul_term((tuple(monom), coeff))
poly += subpoly
return poly
# TODO: following methods should point to polynomial
# representation independent algorithm implementations.
def pdiv(f, g):
return f.ring.dmp_pdiv(f, g)
def prem(f, g):
return f.ring.dmp_prem(f, g)
def pquo(f, g):
return f.ring.dmp_quo(f, g)
def pexquo(f, g):
return f.ring.dmp_exquo(f, g)
def half_gcdex(f, g):
return f.ring.dmp_half_gcdex(f, g)
def gcdex(f, g):
return f.ring.dmp_gcdex(f, g)
def subresultants(f, g):
return f.ring.dmp_subresultants(f, g)
def resultant(f, g):
return f.ring.dmp_resultant(f, g)
def discriminant(f):
return f.ring.dmp_discriminant(f)
def decompose(f):
if f.ring.is_univariate:
return f.ring.dup_decompose(f)
else:
raise MultivariatePolynomialError("polynomial decomposition")
def shift(f, a):
if f.ring.is_univariate:
return f.ring.dup_shift(f, a)
else:
raise MultivariatePolynomialError("polynomial shift")
def sturm(f):
if f.ring.is_univariate:
return f.ring.dup_sturm(f)
else:
raise MultivariatePolynomialError("sturm sequence")
def gff_list(f):
return f.ring.dmp_gff_list(f)
def sqf_norm(f):
return f.ring.dmp_sqf_norm(f)
def sqf_part(f):
return f.ring.dmp_sqf_part(f)
def sqf_list(f, all=False):
return f.ring.dmp_sqf_list(f, all=all)
def factor_list(f):
return f.ring.dmp_factor_list(f)
|
50f4d9aaf7322d13a350a033cc4ba1075ed29257aa4fba1422014205a06a85aa | """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
from sympy.polys.polyerrors import ExactQuotientFailed
from sympy.polys.polyutils import PicklableWithSlots, dict_from_expr
from sympy.utilities import public
from sympy.core.compatibility import is_sequence
@public
def itermonomials(variables, max_degrees, min_degrees=None):
r"""
`max_degrees` and `min_degrees` are either both integers or both lists.
Unless otherwise specified, `min_degrees` is either 0 or [0,...,0].
A generator of all monomials `monom` is returned, such that
either
min_degree <= total_degree(monom) <= max_degree,
or
min_degrees[i] <= degree_list(monom)[i] <= max_degrees[i], for all i.
Case I:: `max_degrees` and `min_degrees` are both integers.
===========================================================
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)
>>> set(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]
Case II:: `max_degrees` and `min_degrees` are both lists.
=========================================================
If max_degrees = [d_1, ..., d_n] and min_degrees = [e_1, ..., e_n],
the number of monomials generated is:
(d_1 - e_1 + 1) * ... * (d_n - e_n + 1)
Example
=======
Let us generate all monomials `monom` in variables `x`, and `y`
such that [1, 2][i] <= degree_list(monom)[i] <= [2, 4][i], i = 0, 1 ::
>>> 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, 4], [1, 2]), reverse=True, key=monomial_key('lex', [x, y]))
[x**2*y**4, x**2*y**3, x**2*y**2, x*y**4, x*y**3, x*y**2]
"""
n = len(variables)
if is_sequence(max_degrees):
if len(max_degrees) != n:
raise ValueError('Argument sizes do not match')
if min_degrees is None:
min_degrees = [0]*n
elif not is_sequence(min_degrees):
raise ValueError('min_degrees is not a list')
else:
if len(min_degrees) != n:
raise ValueError('Argument sizes do not match')
if any(i < 0 for i in min_degrees):
raise ValueError("min_degrees can't contain negative numbers")
total_degree = False
else:
max_degree = max_degrees
if max_degree < 0:
raise ValueError("max_degrees can't be negative")
if min_degrees is None:
min_degree = 0
else:
if min_degrees < 0:
raise ValueError("min_degrees can't be negative")
min_degree = min_degrees
total_degree = True
if total_degree:
if min_degree > max_degree:
return
if not variables or max_degree == 0:
yield S.One
return
# Force to list in case of passed tuple or other incompatible collection
variables = list(variables) + [S.One]
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 max(powers.values()) >= min_degree:
monomials_list_comm.append(Mul(*item))
for mon in set(monomials_list_comm):
yield mon
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 max(powers.values()) >= min_degree:
monomials_list_non_comm.append(Mul(*item))
for mon in set(monomials_list_non_comm):
yield mon
else:
if any(min_degrees[i] > max_degrees[i] for i in range(n)):
raise ValueError('min_degrees[i] must be <= max_degrees[i] for all i')
power_lists = []
for var, min_d, max_d in zip(variables, min_degrees, max_degrees):
power_lists.append([var**i for i in range(min_d, max_d + 1)])
for powers in product(*power_lists):
yield Mul(*powers)
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 = list(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))
|
ffcebbbfaca935c0d6286bd9775e7f2ba976d0eb0321c9914bba0ba32346629f | """Algorithms for partial fraction decomposition of rational functions. """
from __future__ import print_function, division
from sympy.core import S, Add, sympify, Function, Lambda, Dummy
from sympy.core.basic import preorder_traversal
from sympy.polys import Poly, RootSum, cancel, factor
from sympy.polys.polyerrors import PolynomialError
from sympy.polys.polyoptions import allowed_flags, set_defaults
from sympy.polys.polytools import parallel_poly_from_expr
from sympy.utilities import numbered_symbols, take, xthreaded, public
@xthreaded
@public
def apart(f, x=None, full=False, **options):
"""
Compute partial fraction decomposition of a rational function.
Given a rational function ``f``, computes the partial fraction
decomposition of ``f``. Two algorithms are available: One is based on the
undertermined coefficients method, the other is Bronstein's full partial
fraction decomposition algorithm.
The undetermined coefficients method (selected by ``full=False``) uses
polynomial factorization (and therefore accepts the same options as
factor) for the denominator. Per default it works over the rational
numbers, therefore decomposition of denominators with non-rational roots
(e.g. irrational, complex roots) is not supported by default (see options
of factor).
Bronstein's algorithm can be selected by using ``full=True`` and allows a
decomposition of denominators with non-rational roots. A human-readable
result can be obtained via ``doit()`` (see examples below).
Examples
========
>>> from sympy.polys.partfrac import apart
>>> from sympy.abc import x, y
By default, using the undetermined coefficients method:
>>> apart(y/(x + 2)/(x + 1), x)
-y/(x + 2) + y/(x + 1)
The undetermined coefficients method does not provide a result when the
denominators roots are not rational:
>>> apart(y/(x**2 + x + 1), x)
y/(x**2 + x + 1)
You can choose Bronstein's algorithm by setting ``full=True``:
>>> apart(y/(x**2 + x + 1), x, full=True)
RootSum(_w**2 + _w + 1, Lambda(_a, (-2*_a*y/3 - y/3)/(-_a + x)))
Calling ``doit()`` yields a human-readable result:
>>> apart(y/(x**2 + x + 1), x, full=True).doit()
(-y/3 - 2*y*(-1/2 - sqrt(3)*I/2)/3)/(x + 1/2 + sqrt(3)*I/2) + (-y/3 -
2*y*(-1/2 + sqrt(3)*I/2)/3)/(x + 1/2 - sqrt(3)*I/2)
See Also
========
apart_list, assemble_partfrac_list
"""
allowed_flags(options, [])
f = sympify(f)
if f.is_Atom:
return f
else:
P, Q = f.as_numer_denom()
_options = options.copy()
options = set_defaults(options, extension=True)
try:
(P, Q), opt = parallel_poly_from_expr((P, Q), x, **options)
except PolynomialError as msg:
if f.is_commutative:
raise PolynomialError(msg)
# non-commutative
if f.is_Mul:
c, nc = f.args_cnc(split_1=False)
nc = f.func(*nc)
if c:
c = apart(f.func._from_args(c), x=x, full=full, **_options)
return c*nc
else:
return nc
elif f.is_Add:
c = []
nc = []
for i in f.args:
if i.is_commutative:
c.append(i)
else:
try:
nc.append(apart(i, x=x, full=full, **_options))
except NotImplementedError:
nc.append(i)
return apart(f.func(*c), x=x, full=full, **_options) + f.func(*nc)
else:
reps = []
pot = preorder_traversal(f)
next(pot)
for e in pot:
try:
reps.append((e, apart(e, x=x, full=full, **_options)))
pot.skip() # this was handled successfully
except NotImplementedError:
pass
return f.xreplace(dict(reps))
if P.is_multivariate:
fc = f.cancel()
if fc != f:
return apart(fc, x=x, full=full, **_options)
raise NotImplementedError(
"multivariate partial fraction decomposition")
common, P, Q = P.cancel(Q)
poly, P = P.div(Q, auto=True)
P, Q = P.rat_clear_denoms(Q)
if Q.degree() <= 1:
partial = P/Q
else:
if not full:
partial = apart_undetermined_coeffs(P, Q)
else:
partial = apart_full_decomposition(P, Q)
terms = S.Zero
for term in Add.make_args(partial):
if term.has(RootSum):
terms += term
else:
terms += factor(term)
return common*(poly.as_expr() + terms)
def apart_undetermined_coeffs(P, Q):
"""Partial fractions via method of undetermined coefficients. """
X = numbered_symbols(cls=Dummy)
partial, symbols = [], []
_, factors = Q.factor_list()
for f, k in factors:
n, q = f.degree(), Q
for i in range(1, k + 1):
coeffs, q = take(X, n), q.quo(f)
partial.append((coeffs, q, f, i))
symbols.extend(coeffs)
dom = Q.get_domain().inject(*symbols)
F = Poly(0, Q.gen, domain=dom)
for i, (coeffs, q, f, k) in enumerate(partial):
h = Poly(coeffs, Q.gen, domain=dom)
partial[i] = (h, f, k)
q = q.set_domain(dom)
F += h*q
system, result = [], S.Zero
for (k,), coeff in F.terms():
system.append(coeff - P.nth(k))
from sympy.solvers import solve
solution = solve(system, symbols)
for h, f, k in partial:
h = h.as_expr().subs(solution)
result += h/f.as_expr()**k
return result
def apart_full_decomposition(P, Q):
"""
Bronstein's full partial fraction decomposition algorithm.
Given a univariate rational function ``f``, performing only GCD
operations over the algebraic closure of the initial ground domain
of definition, compute full partial fraction decomposition with
fractions having linear denominators.
Note that no factorization of the initial denominator of ``f`` is
performed. The final decomposition is formed in terms of a sum of
:class:`RootSum` instances.
References
==========
.. [1] [Bronstein93]_
"""
return assemble_partfrac_list(apart_list(P/Q, P.gens[0]))
@public
def apart_list(f, x=None, dummies=None, **options):
"""
Compute partial fraction decomposition of a rational function
and return the result in structured form.
Given a rational function ``f`` compute the partial fraction decomposition
of ``f``. Only Bronstein's full partial fraction decomposition algorithm
is supported by this method. The return value is highly structured and
perfectly suited for further algorithmic treatment rather than being
human-readable. The function returns a tuple holding three elements:
* The first item is the common coefficient, free of the variable `x` used
for decomposition. (It is an element of the base field `K`.)
* The second item is the polynomial part of the decomposition. This can be
the zero polynomial. (It is an element of `K[x]`.)
* The third part itself is a list of quadruples. Each quadruple
has the following elements in this order:
- The (not necessarily irreducible) polynomial `D` whose roots `w_i` appear
in the linear denominator of a bunch of related fraction terms. (This item
can also be a list of explicit roots. However, at the moment ``apart_list``
never returns a result this way, but the related ``assemble_partfrac_list``
function accepts this format as input.)
- The numerator of the fraction, written as a function of the root `w`
- The linear denominator of the fraction *excluding its power exponent*,
written as a function of the root `w`.
- The power to which the denominator has to be raised.
On can always rebuild a plain expression by using the function ``assemble_partfrac_list``.
Examples
========
A first example:
>>> from sympy.polys.partfrac import apart_list, assemble_partfrac_list
>>> from sympy.abc import x, t
>>> f = (2*x**3 - 2*x) / (x**2 - 2*x + 1)
>>> pfd = apart_list(f)
>>> pfd
(1,
Poly(2*x + 4, x, domain='ZZ'),
[(Poly(_w - 1, _w, domain='ZZ'), Lambda(_a, 4), Lambda(_a, -_a + x), 1)])
>>> assemble_partfrac_list(pfd)
2*x + 4 + 4/(x - 1)
Second example:
>>> f = (-2*x - 2*x**2) / (3*x**2 - 6*x)
>>> pfd = apart_list(f)
>>> pfd
(-1,
Poly(2/3, x, domain='QQ'),
[(Poly(_w - 2, _w, domain='ZZ'), Lambda(_a, 2), Lambda(_a, -_a + x), 1)])
>>> assemble_partfrac_list(pfd)
-2/3 - 2/(x - 2)
Another example, showing symbolic parameters:
>>> pfd = apart_list(t/(x**2 + x + t), x)
>>> pfd
(1,
Poly(0, x, domain='ZZ[t]'),
[(Poly(_w**2 + _w + t, _w, domain='ZZ[t]'),
Lambda(_a, -2*_a*t/(4*t - 1) - t/(4*t - 1)),
Lambda(_a, -_a + x),
1)])
>>> assemble_partfrac_list(pfd)
RootSum(_w**2 + _w + t, Lambda(_a, (-2*_a*t/(4*t - 1) - t/(4*t - 1))/(-_a + x)))
This example is taken from Bronstein's original paper:
>>> f = 36 / (x**5 - 2*x**4 - 2*x**3 + 4*x**2 + x - 2)
>>> pfd = apart_list(f)
>>> pfd
(1,
Poly(0, x, domain='ZZ'),
[(Poly(_w - 2, _w, domain='ZZ'), Lambda(_a, 4), Lambda(_a, -_a + x), 1),
(Poly(_w**2 - 1, _w, domain='ZZ'), Lambda(_a, -3*_a - 6), Lambda(_a, -_a + x), 2),
(Poly(_w + 1, _w, domain='ZZ'), Lambda(_a, -4), Lambda(_a, -_a + x), 1)])
>>> assemble_partfrac_list(pfd)
-4/(x + 1) - 3/(x + 1)**2 - 9/(x - 1)**2 + 4/(x - 2)
See also
========
apart, assemble_partfrac_list
References
==========
.. [1] [Bronstein93]_
"""
allowed_flags(options, [])
f = sympify(f)
if f.is_Atom:
return f
else:
P, Q = f.as_numer_denom()
options = set_defaults(options, extension=True)
(P, Q), opt = parallel_poly_from_expr((P, Q), x, **options)
if P.is_multivariate:
raise NotImplementedError(
"multivariate partial fraction decomposition")
common, P, Q = P.cancel(Q)
poly, P = P.div(Q, auto=True)
P, Q = P.rat_clear_denoms(Q)
polypart = poly
if dummies is None:
def dummies(name):
d = Dummy(name)
while True:
yield d
dummies = dummies("w")
rationalpart = apart_list_full_decomposition(P, Q, dummies)
return (common, polypart, rationalpart)
def apart_list_full_decomposition(P, Q, dummygen):
"""
Bronstein's full partial fraction decomposition algorithm.
Given a univariate rational function ``f``, performing only GCD
operations over the algebraic closure of the initial ground domain
of definition, compute full partial fraction decomposition with
fractions having linear denominators.
Note that no factorization of the initial denominator of ``f`` is
performed. The final decomposition is formed in terms of a sum of
:class:`RootSum` instances.
References
==========
.. [1] [Bronstein93]_
"""
f, x, U = P/Q, P.gen, []
u = Function('u')(x)
a = Dummy('a')
partial = []
for d, n in Q.sqf_list_include(all=True):
b = d.as_expr()
U += [ u.diff(x, n - 1) ]
h = cancel(f*b**n) / u**n
H, subs = [h], []
for j in range(1, n):
H += [ H[-1].diff(x) / j ]
for j in range(1, n + 1):
subs += [ (U[j - 1], b.diff(x, j) / j) ]
for j in range(0, n):
P, Q = cancel(H[j]).as_numer_denom()
for i in range(0, j + 1):
P = P.subs(*subs[j - i])
Q = Q.subs(*subs[0])
P = Poly(P, x)
Q = Poly(Q, x)
G = P.gcd(d)
D = d.quo(G)
B, g = Q.half_gcdex(D)
b = (P * B.quo(g)).rem(D)
Dw = D.subs(x, next(dummygen))
numer = Lambda(a, b.as_expr().subs(x, a))
denom = Lambda(a, (x - a))
exponent = n-j
partial.append((Dw, numer, denom, exponent))
return partial
@public
def assemble_partfrac_list(partial_list):
r"""Reassemble a full partial fraction decomposition
from a structured result obtained by the function ``apart_list``.
Examples
========
This example is taken from Bronstein's original paper:
>>> from sympy.polys.partfrac import apart_list, assemble_partfrac_list
>>> from sympy.abc import x
>>> f = 36 / (x**5 - 2*x**4 - 2*x**3 + 4*x**2 + x - 2)
>>> pfd = apart_list(f)
>>> pfd
(1,
Poly(0, x, domain='ZZ'),
[(Poly(_w - 2, _w, domain='ZZ'), Lambda(_a, 4), Lambda(_a, -_a + x), 1),
(Poly(_w**2 - 1, _w, domain='ZZ'), Lambda(_a, -3*_a - 6), Lambda(_a, -_a + x), 2),
(Poly(_w + 1, _w, domain='ZZ'), Lambda(_a, -4), Lambda(_a, -_a + x), 1)])
>>> assemble_partfrac_list(pfd)
-4/(x + 1) - 3/(x + 1)**2 - 9/(x - 1)**2 + 4/(x - 2)
If we happen to know some roots we can provide them easily inside the structure:
>>> pfd = apart_list(2/(x**2-2))
>>> pfd
(1,
Poly(0, x, domain='ZZ'),
[(Poly(_w**2 - 2, _w, domain='ZZ'),
Lambda(_a, _a/2),
Lambda(_a, -_a + x),
1)])
>>> pfda = assemble_partfrac_list(pfd)
>>> pfda
RootSum(_w**2 - 2, Lambda(_a, _a/(-_a + x)))/2
>>> pfda.doit()
-sqrt(2)/(2*(x + sqrt(2))) + sqrt(2)/(2*(x - sqrt(2)))
>>> from sympy import Dummy, Poly, Lambda, sqrt
>>> a = Dummy("a")
>>> pfd = (1, Poly(0, x, domain='ZZ'), [([sqrt(2),-sqrt(2)], Lambda(a, a/2), Lambda(a, -a + x), 1)])
>>> assemble_partfrac_list(pfd)
-sqrt(2)/(2*(x + sqrt(2))) + sqrt(2)/(2*(x - sqrt(2)))
See Also
========
apart, apart_list
"""
# Common factor
common = partial_list[0]
# Polynomial part
polypart = partial_list[1]
pfd = polypart.as_expr()
# Rational parts
for r, nf, df, ex in partial_list[2]:
if isinstance(r, Poly):
# Assemble in case the roots are given implicitly by a polynomials
an, nu = nf.variables, nf.expr
ad, de = df.variables, df.expr
# Hack to make dummies equal because Lambda created new Dummies
de = de.subs(ad[0], an[0])
func = Lambda(tuple(an), nu/de**ex)
pfd += RootSum(r, func, auto=False, quadratic=False)
else:
# Assemble in case the roots are given explicitly by a list of algebraic numbers
for root in r:
pfd += nf(root)/df(root)**ex
return common*pfd
|
46f31d015dead184a823018e322d67d3e9548fcf2f58bfd8a82df998d4fd4ab7 | """Real and complex root isolation and refinement algorithms. """
from __future__ import print_function, division
from sympy.polys.densearith import (
dup_neg, dup_rshift, dup_rem)
from sympy.polys.densebasic import (
dup_LC, dup_TC, dup_degree,
dup_strip, dup_reverse,
dup_convert,
dup_terms_gcd)
from sympy.polys.densetools import (
dup_clear_denoms,
dup_mirror, dup_scale, dup_shift,
dup_transform,
dup_diff,
dup_eval, dmp_eval_in,
dup_sign_variations,
dup_real_imag)
from sympy.polys.factortools import (
dup_factor_list)
from sympy.polys.polyerrors import (
RefinementFailed,
DomainError)
from sympy.polys.sqfreetools import (
dup_sqf_part, dup_sqf_list)
def dup_sturm(f, K):
"""
Computes the Sturm sequence of ``f`` in ``F[x]``.
Given a univariate, square-free polynomial ``f(x)`` returns the
associated Sturm sequence ``f_0(x), ..., f_n(x)`` defined by::
f_0(x), f_1(x) = f(x), f'(x)
f_n = -rem(f_{n-2}(x), f_{n-1}(x))
Examples
========
>>> from sympy.polys import ring, QQ
>>> R, x = ring("x", QQ)
>>> R.dup_sturm(x**3 - 2*x**2 + x - 3)
[x**3 - 2*x**2 + x - 3, 3*x**2 - 4*x + 1, 2/9*x + 25/9, -2079/4]
References
==========
.. [1] [Davenport88]_
"""
if not K.is_Field:
raise DomainError("can't compute Sturm sequence over %s" % K)
f = dup_sqf_part(f, K)
sturm = [f, dup_diff(f, 1, K)]
while sturm[-1]:
s = dup_rem(sturm[-2], sturm[-1], K)
sturm.append(dup_neg(s, K))
return sturm[:-1]
def dup_root_upper_bound(f, K):
"""Compute the LMQ upper bound for the positive roots of `f`;
LMQ (Local Max Quadratic) was developed by Akritas-Strzebonski-Vigklas.
References
==========
.. [1] Alkiviadis G. Akritas: "Linear and Quadratic Complexity Bounds on the
Values of the Positive Roots of Polynomials"
Journal of Universal Computer Science, Vol. 15, No. 3, 523-537, 2009.
"""
n, P = len(f), []
t = n * [K.one]
if dup_LC(f, K) < 0:
f = dup_neg(f, K)
f = list(reversed(f))
for i in range(0, n):
if f[i] >= 0:
continue
a, QL = K.log(-f[i], 2), []
for j in range(i + 1, n):
if f[j] <= 0:
continue
q = t[j] + a - K.log(f[j], 2)
QL.append([q // (j - i) , j])
if not QL:
continue
q = min(QL)
t[q[1]] = t[q[1]] + 1
P.append(q[0])
if not P:
return None
else:
return K.get_field()(2)**(max(P) + 1)
def dup_root_lower_bound(f, K):
"""Compute the LMQ lower bound for the positive roots of `f`;
LMQ (Local Max Quadratic) was developed by Akritas-Strzebonski-Vigklas.
References
==========
.. [1] Alkiviadis G. Akritas: "Linear and Quadratic Complexity Bounds on the
Values of the Positive Roots of Polynomials"
Journal of Universal Computer Science, Vol. 15, No. 3, 523-537, 2009.
"""
bound = dup_root_upper_bound(dup_reverse(f), K)
if bound is not None:
return 1/bound
else:
return None
def _mobius_from_interval(I, field):
"""Convert an open interval to a Mobius transform. """
s, t = I
a, c = field.numer(s), field.denom(s)
b, d = field.numer(t), field.denom(t)
return a, b, c, d
def _mobius_to_interval(M, field):
"""Convert a Mobius transform to an open interval. """
a, b, c, d = M
s, t = field(a, c), field(b, d)
if s <= t:
return (s, t)
else:
return (t, s)
def dup_step_refine_real_root(f, M, K, fast=False):
"""One step of positive real root refinement algorithm. """
a, b, c, d = M
if a == b and c == d:
return f, (a, b, c, d)
A = dup_root_lower_bound(f, K)
if A is not None:
A = K(int(A))
else:
A = K.zero
if fast and A > 16:
f = dup_scale(f, A, K)
a, c, A = A*a, A*c, K.one
if A >= K.one:
f = dup_shift(f, A, K)
b, d = A*a + b, A*c + d
if not dup_eval(f, K.zero, K):
return f, (b, b, d, d)
f, g = dup_shift(f, K.one, K), f
a1, b1, c1, d1 = a, a + b, c, c + d
if not dup_eval(f, K.zero, K):
return f, (b1, b1, d1, d1)
k = dup_sign_variations(f, K)
if k == 1:
a, b, c, d = a1, b1, c1, d1
else:
f = dup_shift(dup_reverse(g), K.one, K)
if not dup_eval(f, K.zero, K):
f = dup_rshift(f, 1, K)
a, b, c, d = b, a + b, d, c + d
return f, (a, b, c, d)
def dup_inner_refine_real_root(f, M, K, eps=None, steps=None, disjoint=None, fast=False, mobius=False):
"""Refine a positive root of `f` given a Mobius transform or an interval. """
F = K.get_field()
if len(M) == 2:
a, b, c, d = _mobius_from_interval(M, F)
else:
a, b, c, d = M
while not c:
f, (a, b, c, d) = dup_step_refine_real_root(f, (a, b, c,
d), K, fast=fast)
if eps is not None and steps is not None:
for i in range(0, steps):
if abs(F(a, c) - F(b, d)) >= eps:
f, (a, b, c, d) = dup_step_refine_real_root(f, (a, b, c, d), K, fast=fast)
else:
break
else:
if eps is not None:
while abs(F(a, c) - F(b, d)) >= eps:
f, (a, b, c, d) = dup_step_refine_real_root(f, (a, b, c, d), K, fast=fast)
if steps is not None:
for i in range(0, steps):
f, (a, b, c, d) = dup_step_refine_real_root(f, (a, b, c, d), K, fast=fast)
if disjoint is not None:
while True:
u, v = _mobius_to_interval((a, b, c, d), F)
if v <= disjoint or disjoint <= u:
break
else:
f, (a, b, c, d) = dup_step_refine_real_root(f, (a, b, c, d), K, fast=fast)
if not mobius:
return _mobius_to_interval((a, b, c, d), F)
else:
return f, (a, b, c, d)
def dup_outer_refine_real_root(f, s, t, K, eps=None, steps=None, disjoint=None, fast=False):
"""Refine a positive root of `f` given an interval `(s, t)`. """
a, b, c, d = _mobius_from_interval((s, t), K.get_field())
f = dup_transform(f, dup_strip([a, b]),
dup_strip([c, d]), K)
if dup_sign_variations(f, K) != 1:
raise RefinementFailed("there should be exactly one root in (%s, %s) interval" % (s, t))
return dup_inner_refine_real_root(f, (a, b, c, d), K, eps=eps, steps=steps, disjoint=disjoint, fast=fast)
def dup_refine_real_root(f, s, t, K, eps=None, steps=None, disjoint=None, fast=False):
"""Refine real root's approximating interval to the given precision. """
if K.is_QQ:
(_, f), K = dup_clear_denoms(f, K, convert=True), K.get_ring()
elif not K.is_ZZ:
raise DomainError("real root refinement not supported over %s" % K)
if s == t:
return (s, t)
if s > t:
s, t = t, s
negative = False
if s < 0:
if t <= 0:
f, s, t, negative = dup_mirror(f, K), -t, -s, True
else:
raise ValueError("can't refine a real root in (%s, %s)" % (s, t))
if negative and disjoint is not None:
if disjoint < 0:
disjoint = -disjoint
else:
disjoint = None
s, t = dup_outer_refine_real_root(
f, s, t, K, eps=eps, steps=steps, disjoint=disjoint, fast=fast)
if negative:
return (-t, -s)
else:
return ( s, t)
def dup_inner_isolate_real_roots(f, K, eps=None, fast=False):
"""Internal function for isolation positive roots up to given precision.
References
==========
1. Alkiviadis G. Akritas and Adam W. Strzebonski: A Comparative Study of Two Real Root
Isolation Methods . Nonlinear Analysis: Modelling and Control, Vol. 10, No. 4, 297-304, 2005.
2. Alkiviadis G. Akritas, Adam W. Strzebonski and Panagiotis S. Vigklas: Improving the
Performance of the Continued Fractions Method Using new Bounds of Positive Roots. Nonlinear
Analysis: Modelling and Control, Vol. 13, No. 3, 265-279, 2008.
"""
a, b, c, d = K.one, K.zero, K.zero, K.one
k = dup_sign_variations(f, K)
if k == 0:
return []
if k == 1:
roots = [dup_inner_refine_real_root(
f, (a, b, c, d), K, eps=eps, fast=fast, mobius=True)]
else:
roots, stack = [], [(a, b, c, d, f, k)]
while stack:
a, b, c, d, f, k = stack.pop()
A = dup_root_lower_bound(f, K)
if A is not None:
A = K(int(A))
else:
A = K.zero
if fast and A > 16:
f = dup_scale(f, A, K)
a, c, A = A*a, A*c, K.one
if A >= K.one:
f = dup_shift(f, A, K)
b, d = A*a + b, A*c + d
if not dup_TC(f, K):
roots.append((f, (b, b, d, d)))
f = dup_rshift(f, 1, K)
k = dup_sign_variations(f, K)
if k == 0:
continue
if k == 1:
roots.append(dup_inner_refine_real_root(
f, (a, b, c, d), K, eps=eps, fast=fast, mobius=True))
continue
f1 = dup_shift(f, K.one, K)
a1, b1, c1, d1, r = a, a + b, c, c + d, 0
if not dup_TC(f1, K):
roots.append((f1, (b1, b1, d1, d1)))
f1, r = dup_rshift(f1, 1, K), 1
k1 = dup_sign_variations(f1, K)
k2 = k - k1 - r
a2, b2, c2, d2 = b, a + b, d, c + d
if k2 > 1:
f2 = dup_shift(dup_reverse(f), K.one, K)
if not dup_TC(f2, K):
f2 = dup_rshift(f2, 1, K)
k2 = dup_sign_variations(f2, K)
else:
f2 = None
if k1 < k2:
a1, a2, b1, b2 = a2, a1, b2, b1
c1, c2, d1, d2 = c2, c1, d2, d1
f1, f2, k1, k2 = f2, f1, k2, k1
if not k1:
continue
if f1 is None:
f1 = dup_shift(dup_reverse(f), K.one, K)
if not dup_TC(f1, K):
f1 = dup_rshift(f1, 1, K)
if k1 == 1:
roots.append(dup_inner_refine_real_root(
f1, (a1, b1, c1, d1), K, eps=eps, fast=fast, mobius=True))
else:
stack.append((a1, b1, c1, d1, f1, k1))
if not k2:
continue
if f2 is None:
f2 = dup_shift(dup_reverse(f), K.one, K)
if not dup_TC(f2, K):
f2 = dup_rshift(f2, 1, K)
if k2 == 1:
roots.append(dup_inner_refine_real_root(
f2, (a2, b2, c2, d2), K, eps=eps, fast=fast, mobius=True))
else:
stack.append((a2, b2, c2, d2, f2, k2))
return roots
def _discard_if_outside_interval(f, M, inf, sup, K, negative, fast, mobius):
"""Discard an isolating interval if outside ``(inf, sup)``. """
F = K.get_field()
while True:
u, v = _mobius_to_interval(M, F)
if negative:
u, v = -v, -u
if (inf is None or u >= inf) and (sup is None or v <= sup):
if not mobius:
return u, v
else:
return f, M
elif (sup is not None and u > sup) or (inf is not None and v < inf):
return None
else:
f, M = dup_step_refine_real_root(f, M, K, fast=fast)
def dup_inner_isolate_positive_roots(f, K, eps=None, inf=None, sup=None, fast=False, mobius=False):
"""Iteratively compute disjoint positive root isolation intervals. """
if sup is not None and sup < 0:
return []
roots = dup_inner_isolate_real_roots(f, K, eps=eps, fast=fast)
F, results = K.get_field(), []
if inf is not None or sup is not None:
for f, M in roots:
result = _discard_if_outside_interval(f, M, inf, sup, K, False, fast, mobius)
if result is not None:
results.append(result)
elif not mobius:
for f, M in roots:
u, v = _mobius_to_interval(M, F)
results.append((u, v))
else:
results = roots
return results
def dup_inner_isolate_negative_roots(f, K, inf=None, sup=None, eps=None, fast=False, mobius=False):
"""Iteratively compute disjoint negative root isolation intervals. """
if inf is not None and inf >= 0:
return []
roots = dup_inner_isolate_real_roots(dup_mirror(f, K), K, eps=eps, fast=fast)
F, results = K.get_field(), []
if inf is not None or sup is not None:
for f, M in roots:
result = _discard_if_outside_interval(f, M, inf, sup, K, True, fast, mobius)
if result is not None:
results.append(result)
elif not mobius:
for f, M in roots:
u, v = _mobius_to_interval(M, F)
results.append((-v, -u))
else:
results = roots
return results
def _isolate_zero(f, K, inf, sup, basis=False, sqf=False):
"""Handle special case of CF algorithm when ``f`` is homogeneous. """
j, f = dup_terms_gcd(f, K)
if j > 0:
F = K.get_field()
if (inf is None or inf <= 0) and (sup is None or 0 <= sup):
if not sqf:
if not basis:
return [((F.zero, F.zero), j)], f
else:
return [((F.zero, F.zero), j, [K.one, K.zero])], f
else:
return [(F.zero, F.zero)], f
return [], f
def dup_isolate_real_roots_sqf(f, K, eps=None, inf=None, sup=None, fast=False, blackbox=False):
"""Isolate real roots of a square-free polynomial using the Vincent-Akritas-Strzebonski (VAS) CF approach.
References
==========
.. [1] Alkiviadis G. Akritas and Adam W. Strzebonski: A Comparative
Study of Two Real Root Isolation Methods. Nonlinear Analysis:
Modelling and Control, Vol. 10, No. 4, 297-304, 2005.
.. [2] Alkiviadis G. Akritas, Adam W. Strzebonski and Panagiotis S.
Vigklas: Improving the Performance of the Continued Fractions
Method Using New Bounds of Positive Roots. Nonlinear Analysis:
Modelling and Control, Vol. 13, No. 3, 265-279, 2008.
"""
if K.is_QQ:
(_, f), K = dup_clear_denoms(f, K, convert=True), K.get_ring()
elif not K.is_ZZ:
raise DomainError("isolation of real roots not supported over %s" % K)
if dup_degree(f) <= 0:
return []
I_zero, f = _isolate_zero(f, K, inf, sup, basis=False, sqf=True)
I_neg = dup_inner_isolate_negative_roots(f, K, eps=eps, inf=inf, sup=sup, fast=fast)
I_pos = dup_inner_isolate_positive_roots(f, K, eps=eps, inf=inf, sup=sup, fast=fast)
roots = sorted(I_neg + I_zero + I_pos)
if not blackbox:
return roots
else:
return [ RealInterval((a, b), f, K) for (a, b) in roots ]
def dup_isolate_real_roots(f, K, eps=None, inf=None, sup=None, basis=False, fast=False):
"""Isolate real roots using Vincent-Akritas-Strzebonski (VAS) continued fractions approach.
References
==========
.. [1] Alkiviadis G. Akritas and Adam W. Strzebonski: A Comparative
Study of Two Real Root Isolation Methods. Nonlinear Analysis:
Modelling and Control, Vol. 10, No. 4, 297-304, 2005.
.. [2] Alkiviadis G. Akritas, Adam W. Strzebonski and Panagiotis S.
Vigklas: Improving the Performance of the Continued Fractions
Method Using New Bounds of Positive Roots.
Nonlinear Analysis: Modelling and Control, Vol. 13, No. 3, 265-279, 2008.
"""
if K.is_QQ:
(_, f), K = dup_clear_denoms(f, K, convert=True), K.get_ring()
elif not K.is_ZZ:
raise DomainError("isolation of real roots not supported over %s" % K)
if dup_degree(f) <= 0:
return []
I_zero, f = _isolate_zero(f, K, inf, sup, basis=basis, sqf=False)
_, factors = dup_sqf_list(f, K)
if len(factors) == 1:
((f, k),) = factors
I_neg = dup_inner_isolate_negative_roots(f, K, eps=eps, inf=inf, sup=sup, fast=fast)
I_pos = dup_inner_isolate_positive_roots(f, K, eps=eps, inf=inf, sup=sup, fast=fast)
I_neg = [ ((u, v), k) for u, v in I_neg ]
I_pos = [ ((u, v), k) for u, v in I_pos ]
else:
I_neg, I_pos = _real_isolate_and_disjoin(factors, K,
eps=eps, inf=inf, sup=sup, basis=basis, fast=fast)
return sorted(I_neg + I_zero + I_pos)
def dup_isolate_real_roots_list(polys, K, eps=None, inf=None, sup=None, strict=False, basis=False, fast=False):
"""Isolate real roots of a list of square-free polynomial using Vincent-Akritas-Strzebonski (VAS) CF approach.
References
==========
.. [1] Alkiviadis G. Akritas and Adam W. Strzebonski: A Comparative
Study of Two Real Root Isolation Methods. Nonlinear Analysis:
Modelling and Control, Vol. 10, No. 4, 297-304, 2005.
.. [2] Alkiviadis G. Akritas, Adam W. Strzebonski and Panagiotis S.
Vigklas: Improving the Performance of the Continued Fractions
Method Using New Bounds of Positive Roots.
Nonlinear Analysis: Modelling and Control, Vol. 13, No. 3, 265-279, 2008.
"""
if K.is_QQ:
K, F, polys = K.get_ring(), K, polys[:]
for i, p in enumerate(polys):
polys[i] = dup_clear_denoms(p, F, K, convert=True)[1]
elif not K.is_ZZ:
raise DomainError("isolation of real roots not supported over %s" % K)
zeros, factors_dict = False, {}
if (inf is None or inf <= 0) and (sup is None or 0 <= sup):
zeros, zero_indices = True, {}
for i, p in enumerate(polys):
j, p = dup_terms_gcd(p, K)
if zeros and j > 0:
zero_indices[i] = j
for f, k in dup_factor_list(p, K)[1]:
f = tuple(f)
if f not in factors_dict:
factors_dict[f] = {i: k}
else:
factors_dict[f][i] = k
factors_list = []
for f, indices in factors_dict.items():
factors_list.append((list(f), indices))
I_neg, I_pos = _real_isolate_and_disjoin(factors_list, K, eps=eps,
inf=inf, sup=sup, strict=strict, basis=basis, fast=fast)
F = K.get_field()
if not zeros or not zero_indices:
I_zero = []
else:
if not basis:
I_zero = [((F.zero, F.zero), zero_indices)]
else:
I_zero = [((F.zero, F.zero), zero_indices, [K.one, K.zero])]
return sorted(I_neg + I_zero + I_pos)
def _disjoint_p(M, N, strict=False):
"""Check if Mobius transforms define disjoint intervals. """
a1, b1, c1, d1 = M
a2, b2, c2, d2 = N
a1d1, b1c1 = a1*d1, b1*c1
a2d2, b2c2 = a2*d2, b2*c2
if a1d1 == b1c1 and a2d2 == b2c2:
return True
if a1d1 > b1c1:
a1, c1, b1, d1 = b1, d1, a1, c1
if a2d2 > b2c2:
a2, c2, b2, d2 = b2, d2, a2, c2
if not strict:
return a2*d1 >= c2*b1 or b2*c1 <= d2*a1
else:
return a2*d1 > c2*b1 or b2*c1 < d2*a1
def _real_isolate_and_disjoin(factors, K, eps=None, inf=None, sup=None, strict=False, basis=False, fast=False):
"""Isolate real roots of a list of polynomials and disjoin intervals. """
I_pos, I_neg = [], []
for i, (f, k) in enumerate(factors):
for F, M in dup_inner_isolate_positive_roots(f, K, eps=eps, inf=inf, sup=sup, fast=fast, mobius=True):
I_pos.append((F, M, k, f))
for G, N in dup_inner_isolate_negative_roots(f, K, eps=eps, inf=inf, sup=sup, fast=fast, mobius=True):
I_neg.append((G, N, k, f))
for i, (f, M, k, F) in enumerate(I_pos):
for j, (g, N, m, G) in enumerate(I_pos[i + 1:]):
while not _disjoint_p(M, N, strict=strict):
f, M = dup_inner_refine_real_root(f, M, K, steps=1, fast=fast, mobius=True)
g, N = dup_inner_refine_real_root(g, N, K, steps=1, fast=fast, mobius=True)
I_pos[i + j + 1] = (g, N, m, G)
I_pos[i] = (f, M, k, F)
for i, (f, M, k, F) in enumerate(I_neg):
for j, (g, N, m, G) in enumerate(I_neg[i + 1:]):
while not _disjoint_p(M, N, strict=strict):
f, M = dup_inner_refine_real_root(f, M, K, steps=1, fast=fast, mobius=True)
g, N = dup_inner_refine_real_root(g, N, K, steps=1, fast=fast, mobius=True)
I_neg[i + j + 1] = (g, N, m, G)
I_neg[i] = (f, M, k, F)
if strict:
for i, (f, M, k, F) in enumerate(I_neg):
if not M[0]:
while not M[0]:
f, M = dup_inner_refine_real_root(f, M, K, steps=1, fast=fast, mobius=True)
I_neg[i] = (f, M, k, F)
break
for j, (g, N, m, G) in enumerate(I_pos):
if not N[0]:
while not N[0]:
g, N = dup_inner_refine_real_root(g, N, K, steps=1, fast=fast, mobius=True)
I_pos[j] = (g, N, m, G)
break
field = K.get_field()
I_neg = [ (_mobius_to_interval(M, field), k, f) for (_, M, k, f) in I_neg ]
I_pos = [ (_mobius_to_interval(M, field), k, f) for (_, M, k, f) in I_pos ]
if not basis:
I_neg = [ ((-v, -u), k) for ((u, v), k, _) in I_neg ]
I_pos = [ (( u, v), k) for ((u, v), k, _) in I_pos ]
else:
I_neg = [ ((-v, -u), k, f) for ((u, v), k, f) in I_neg ]
I_pos = [ (( u, v), k, f) for ((u, v), k, f) in I_pos ]
return I_neg, I_pos
def dup_count_real_roots(f, K, inf=None, sup=None):
"""Returns the number of distinct real roots of ``f`` in ``[inf, sup]``. """
if dup_degree(f) <= 0:
return 0
if not K.is_Field:
R, K = K, K.get_field()
f = dup_convert(f, R, K)
sturm = dup_sturm(f, K)
if inf is None:
signs_inf = dup_sign_variations([ dup_LC(s, K)*(-1)**dup_degree(s) for s in sturm ], K)
else:
signs_inf = dup_sign_variations([ dup_eval(s, inf, K) for s in sturm ], K)
if sup is None:
signs_sup = dup_sign_variations([ dup_LC(s, K) for s in sturm ], K)
else:
signs_sup = dup_sign_variations([ dup_eval(s, sup, K) for s in sturm ], K)
count = abs(signs_inf - signs_sup)
if inf is not None and not dup_eval(f, inf, K):
count += 1
return count
OO = 'OO' # Origin of (re, im) coordinate system
Q1 = 'Q1' # Quadrant #1 (++): re > 0 and im > 0
Q2 = 'Q2' # Quadrant #2 (-+): re < 0 and im > 0
Q3 = 'Q3' # Quadrant #3 (--): re < 0 and im < 0
Q4 = 'Q4' # Quadrant #4 (+-): re > 0 and im < 0
A1 = 'A1' # Axis #1 (+0): re > 0 and im = 0
A2 = 'A2' # Axis #2 (0+): re = 0 and im > 0
A3 = 'A3' # Axis #3 (-0): re < 0 and im = 0
A4 = 'A4' # Axis #4 (0-): re = 0 and im < 0
_rules_simple = {
# Q --> Q (same) => no change
(Q1, Q1): 0,
(Q2, Q2): 0,
(Q3, Q3): 0,
(Q4, Q4): 0,
# A -- CCW --> Q => +1/4 (CCW)
(A1, Q1): 1,
(A2, Q2): 1,
(A3, Q3): 1,
(A4, Q4): 1,
# A -- CW --> Q => -1/4 (CCW)
(A1, Q4): 2,
(A2, Q1): 2,
(A3, Q2): 2,
(A4, Q3): 2,
# Q -- CCW --> A => +1/4 (CCW)
(Q1, A2): 3,
(Q2, A3): 3,
(Q3, A4): 3,
(Q4, A1): 3,
# Q -- CW --> A => -1/4 (CCW)
(Q1, A1): 4,
(Q2, A2): 4,
(Q3, A3): 4,
(Q4, A4): 4,
# Q -- CCW --> Q => +1/2 (CCW)
(Q1, Q2): +5,
(Q2, Q3): +5,
(Q3, Q4): +5,
(Q4, Q1): +5,
# Q -- CW --> Q => -1/2 (CW)
(Q1, Q4): -5,
(Q2, Q1): -5,
(Q3, Q2): -5,
(Q4, Q3): -5,
}
_rules_ambiguous = {
# A -- CCW --> Q => { +1/4 (CCW), -9/4 (CW) }
(A1, OO, Q1): -1,
(A2, OO, Q2): -1,
(A3, OO, Q3): -1,
(A4, OO, Q4): -1,
# A -- CW --> Q => { -1/4 (CCW), +7/4 (CW) }
(A1, OO, Q4): -2,
(A2, OO, Q1): -2,
(A3, OO, Q2): -2,
(A4, OO, Q3): -2,
# Q -- CCW --> A => { +1/4 (CCW), -9/4 (CW) }
(Q1, OO, A2): -3,
(Q2, OO, A3): -3,
(Q3, OO, A4): -3,
(Q4, OO, A1): -3,
# Q -- CW --> A => { -1/4 (CCW), +7/4 (CW) }
(Q1, OO, A1): -4,
(Q2, OO, A2): -4,
(Q3, OO, A3): -4,
(Q4, OO, A4): -4,
# A -- OO --> A => { +1 (CCW), -1 (CW) }
(A1, A3): 7,
(A2, A4): 7,
(A3, A1): 7,
(A4, A2): 7,
(A1, OO, A3): 7,
(A2, OO, A4): 7,
(A3, OO, A1): 7,
(A4, OO, A2): 7,
# Q -- DIA --> Q => { +1 (CCW), -1 (CW) }
(Q1, Q3): 8,
(Q2, Q4): 8,
(Q3, Q1): 8,
(Q4, Q2): 8,
(Q1, OO, Q3): 8,
(Q2, OO, Q4): 8,
(Q3, OO, Q1): 8,
(Q4, OO, Q2): 8,
# A --- R ---> A => { +1/2 (CCW), -3/2 (CW) }
(A1, A2): 9,
(A2, A3): 9,
(A3, A4): 9,
(A4, A1): 9,
(A1, OO, A2): 9,
(A2, OO, A3): 9,
(A3, OO, A4): 9,
(A4, OO, A1): 9,
# A --- L ---> A => { +3/2 (CCW), -1/2 (CW) }
(A1, A4): 10,
(A2, A1): 10,
(A3, A2): 10,
(A4, A3): 10,
(A1, OO, A4): 10,
(A2, OO, A1): 10,
(A3, OO, A2): 10,
(A4, OO, A3): 10,
# Q --- 1 ---> A => { +3/4 (CCW), -5/4 (CW) }
(Q1, A3): 11,
(Q2, A4): 11,
(Q3, A1): 11,
(Q4, A2): 11,
(Q1, OO, A3): 11,
(Q2, OO, A4): 11,
(Q3, OO, A1): 11,
(Q4, OO, A2): 11,
# Q --- 2 ---> A => { +5/4 (CCW), -3/4 (CW) }
(Q1, A4): 12,
(Q2, A1): 12,
(Q3, A2): 12,
(Q4, A3): 12,
(Q1, OO, A4): 12,
(Q2, OO, A1): 12,
(Q3, OO, A2): 12,
(Q4, OO, A3): 12,
# A --- 1 ---> Q => { +5/4 (CCW), -3/4 (CW) }
(A1, Q3): 13,
(A2, Q4): 13,
(A3, Q1): 13,
(A4, Q2): 13,
(A1, OO, Q3): 13,
(A2, OO, Q4): 13,
(A3, OO, Q1): 13,
(A4, OO, Q2): 13,
# A --- 2 ---> Q => { +3/4 (CCW), -5/4 (CW) }
(A1, Q2): 14,
(A2, Q3): 14,
(A3, Q4): 14,
(A4, Q1): 14,
(A1, OO, Q2): 14,
(A2, OO, Q3): 14,
(A3, OO, Q4): 14,
(A4, OO, Q1): 14,
# Q --> OO --> Q => { +1/2 (CCW), -3/2 (CW) }
(Q1, OO, Q2): 15,
(Q2, OO, Q3): 15,
(Q3, OO, Q4): 15,
(Q4, OO, Q1): 15,
# Q --> OO --> Q => { +3/2 (CCW), -1/2 (CW) }
(Q1, OO, Q4): 16,
(Q2, OO, Q1): 16,
(Q3, OO, Q2): 16,
(Q4, OO, Q3): 16,
# A --> OO --> A => { +2 (CCW), 0 (CW) }
(A1, OO, A1): 17,
(A2, OO, A2): 17,
(A3, OO, A3): 17,
(A4, OO, A4): 17,
# Q --> OO --> Q => { +2 (CCW), 0 (CW) }
(Q1, OO, Q1): 18,
(Q2, OO, Q2): 18,
(Q3, OO, Q3): 18,
(Q4, OO, Q4): 18,
}
_values = {
0: [( 0, 1)],
1: [(+1, 4)],
2: [(-1, 4)],
3: [(+1, 4)],
4: [(-1, 4)],
-1: [(+9, 4), (+1, 4)],
-2: [(+7, 4), (-1, 4)],
-3: [(+9, 4), (+1, 4)],
-4: [(+7, 4), (-1, 4)],
+5: [(+1, 2)],
-5: [(-1, 2)],
7: [(+1, 1), (-1, 1)],
8: [(+1, 1), (-1, 1)],
9: [(+1, 2), (-3, 2)],
10: [(+3, 2), (-1, 2)],
11: [(+3, 4), (-5, 4)],
12: [(+5, 4), (-3, 4)],
13: [(+5, 4), (-3, 4)],
14: [(+3, 4), (-5, 4)],
15: [(+1, 2), (-3, 2)],
16: [(+3, 2), (-1, 2)],
17: [(+2, 1), ( 0, 1)],
18: [(+2, 1), ( 0, 1)],
}
def _classify_point(re, im):
"""Return the half-axis (or origin) on which (re, im) point is located. """
if not re and not im:
return OO
if not re:
if im > 0:
return A2
else:
return A4
elif not im:
if re > 0:
return A1
else:
return A3
def _intervals_to_quadrants(intervals, f1, f2, s, t, F):
"""Generate a sequence of extended quadrants from a list of critical points. """
if not intervals:
return []
Q = []
if not f1:
(a, b), _, _ = intervals[0]
if a == b == s:
if len(intervals) == 1:
if dup_eval(f2, t, F) > 0:
return [OO, A2]
else:
return [OO, A4]
else:
(a, _), _, _ = intervals[1]
if dup_eval(f2, (s + a)/2, F) > 0:
Q.extend([OO, A2])
f2_sgn = +1
else:
Q.extend([OO, A4])
f2_sgn = -1
intervals = intervals[1:]
else:
if dup_eval(f2, s, F) > 0:
Q.append(A2)
f2_sgn = +1
else:
Q.append(A4)
f2_sgn = -1
for (a, _), indices, _ in intervals:
Q.append(OO)
if indices[1] % 2 == 1:
f2_sgn = -f2_sgn
if a != t:
if f2_sgn > 0:
Q.append(A2)
else:
Q.append(A4)
return Q
if not f2:
(a, b), _, _ = intervals[0]
if a == b == s:
if len(intervals) == 1:
if dup_eval(f1, t, F) > 0:
return [OO, A1]
else:
return [OO, A3]
else:
(a, _), _, _ = intervals[1]
if dup_eval(f1, (s + a)/2, F) > 0:
Q.extend([OO, A1])
f1_sgn = +1
else:
Q.extend([OO, A3])
f1_sgn = -1
intervals = intervals[1:]
else:
if dup_eval(f1, s, F) > 0:
Q.append(A1)
f1_sgn = +1
else:
Q.append(A3)
f1_sgn = -1
for (a, _), indices, _ in intervals:
Q.append(OO)
if indices[0] % 2 == 1:
f1_sgn = -f1_sgn
if a != t:
if f1_sgn > 0:
Q.append(A1)
else:
Q.append(A3)
return Q
re = dup_eval(f1, s, F)
im = dup_eval(f2, s, F)
if not re or not im:
Q.append(_classify_point(re, im))
if len(intervals) == 1:
re = dup_eval(f1, t, F)
im = dup_eval(f2, t, F)
else:
(a, _), _, _ = intervals[1]
re = dup_eval(f1, (s + a)/2, F)
im = dup_eval(f2, (s + a)/2, F)
intervals = intervals[1:]
if re > 0:
f1_sgn = +1
else:
f1_sgn = -1
if im > 0:
f2_sgn = +1
else:
f2_sgn = -1
sgn = {
(+1, +1): Q1,
(-1, +1): Q2,
(-1, -1): Q3,
(+1, -1): Q4,
}
Q.append(sgn[(f1_sgn, f2_sgn)])
for (a, b), indices, _ in intervals:
if a == b:
re = dup_eval(f1, a, F)
im = dup_eval(f2, a, F)
cls = _classify_point(re, im)
if cls is not None:
Q.append(cls)
if 0 in indices:
if indices[0] % 2 == 1:
f1_sgn = -f1_sgn
if 1 in indices:
if indices[1] % 2 == 1:
f2_sgn = -f2_sgn
if not (a == b and b == t):
Q.append(sgn[(f1_sgn, f2_sgn)])
return Q
def _traverse_quadrants(Q_L1, Q_L2, Q_L3, Q_L4, exclude=None):
"""Transform sequences of quadrants to a sequence of rules. """
if exclude is True:
edges = [1, 1, 0, 0]
corners = {
(0, 1): 1,
(1, 2): 1,
(2, 3): 0,
(3, 0): 1,
}
else:
edges = [0, 0, 0, 0]
corners = {
(0, 1): 0,
(1, 2): 0,
(2, 3): 0,
(3, 0): 0,
}
if exclude is not None and exclude is not True:
exclude = set(exclude)
for i, edge in enumerate(['S', 'E', 'N', 'W']):
if edge in exclude:
edges[i] = 1
for i, corner in enumerate(['SW', 'SE', 'NE', 'NW']):
if corner in exclude:
corners[((i - 1) % 4, i)] = 1
QQ, rules = [Q_L1, Q_L2, Q_L3, Q_L4], []
for i, Q in enumerate(QQ):
if not Q:
continue
if Q[-1] == OO:
Q = Q[:-1]
if Q[0] == OO:
j, Q = (i - 1) % 4, Q[1:]
qq = (QQ[j][-2], OO, Q[0])
if qq in _rules_ambiguous:
rules.append((_rules_ambiguous[qq], corners[(j, i)]))
else:
raise NotImplementedError("3 element rule (corner): " + str(qq))
q1, k = Q[0], 1
while k < len(Q):
q2, k = Q[k], k + 1
if q2 != OO:
qq = (q1, q2)
if qq in _rules_simple:
rules.append((_rules_simple[qq], 0))
elif qq in _rules_ambiguous:
rules.append((_rules_ambiguous[qq], edges[i]))
else:
raise NotImplementedError("2 element rule (inside): " + str(qq))
else:
qq, k = (q1, q2, Q[k]), k + 1
if qq in _rules_ambiguous:
rules.append((_rules_ambiguous[qq], edges[i]))
else:
raise NotImplementedError("3 element rule (edge): " + str(qq))
q1 = qq[-1]
return rules
def _reverse_intervals(intervals):
"""Reverse intervals for traversal from right to left and from top to bottom. """
return [ ((b, a), indices, f) for (a, b), indices, f in reversed(intervals) ]
def _winding_number(T, field):
"""Compute the winding number of the input polynomial, i.e. the number of roots. """
return int(sum([ field(*_values[t][i]) for t, i in T ]) / field(2))
def dup_count_complex_roots(f, K, inf=None, sup=None, exclude=None):
"""Count all roots in [u + v*I, s + t*I] rectangle using Collins-Krandick algorithm. """
if not K.is_ZZ and not K.is_QQ:
raise DomainError("complex root counting is not supported over %s" % K)
if K.is_ZZ:
R, F = K, K.get_field()
else:
R, F = K.get_ring(), K
f = dup_convert(f, K, F)
if inf is None or sup is None:
_, lc = dup_degree(f), abs(dup_LC(f, F))
B = 2*max([ F.quo(abs(c), lc) for c in f ])
if inf is None:
(u, v) = (-B, -B)
else:
(u, v) = inf
if sup is None:
(s, t) = (+B, +B)
else:
(s, t) = sup
f1, f2 = dup_real_imag(f, F)
f1L1F = dmp_eval_in(f1, v, 1, 1, F)
f2L1F = dmp_eval_in(f2, v, 1, 1, F)
_, f1L1R = dup_clear_denoms(f1L1F, F, R, convert=True)
_, f2L1R = dup_clear_denoms(f2L1F, F, R, convert=True)
f1L2F = dmp_eval_in(f1, s, 0, 1, F)
f2L2F = dmp_eval_in(f2, s, 0, 1, F)
_, f1L2R = dup_clear_denoms(f1L2F, F, R, convert=True)
_, f2L2R = dup_clear_denoms(f2L2F, F, R, convert=True)
f1L3F = dmp_eval_in(f1, t, 1, 1, F)
f2L3F = dmp_eval_in(f2, t, 1, 1, F)
_, f1L3R = dup_clear_denoms(f1L3F, F, R, convert=True)
_, f2L3R = dup_clear_denoms(f2L3F, F, R, convert=True)
f1L4F = dmp_eval_in(f1, u, 0, 1, F)
f2L4F = dmp_eval_in(f2, u, 0, 1, F)
_, f1L4R = dup_clear_denoms(f1L4F, F, R, convert=True)
_, f2L4R = dup_clear_denoms(f2L4F, F, R, convert=True)
S_L1 = [f1L1R, f2L1R]
S_L2 = [f1L2R, f2L2R]
S_L3 = [f1L3R, f2L3R]
S_L4 = [f1L4R, f2L4R]
I_L1 = dup_isolate_real_roots_list(S_L1, R, inf=u, sup=s, fast=True, basis=True, strict=True)
I_L2 = dup_isolate_real_roots_list(S_L2, R, inf=v, sup=t, fast=True, basis=True, strict=True)
I_L3 = dup_isolate_real_roots_list(S_L3, R, inf=u, sup=s, fast=True, basis=True, strict=True)
I_L4 = dup_isolate_real_roots_list(S_L4, R, inf=v, sup=t, fast=True, basis=True, strict=True)
I_L3 = _reverse_intervals(I_L3)
I_L4 = _reverse_intervals(I_L4)
Q_L1 = _intervals_to_quadrants(I_L1, f1L1F, f2L1F, u, s, F)
Q_L2 = _intervals_to_quadrants(I_L2, f1L2F, f2L2F, v, t, F)
Q_L3 = _intervals_to_quadrants(I_L3, f1L3F, f2L3F, s, u, F)
Q_L4 = _intervals_to_quadrants(I_L4, f1L4F, f2L4F, t, v, F)
T = _traverse_quadrants(Q_L1, Q_L2, Q_L3, Q_L4, exclude=exclude)
return _winding_number(T, F)
def _vertical_bisection(N, a, b, I, Q, F1, F2, f1, f2, F):
"""Vertical bisection step in Collins-Krandick root isolation algorithm. """
(u, v), (s, t) = a, b
I_L1, I_L2, I_L3, I_L4 = I
Q_L1, Q_L2, Q_L3, Q_L4 = Q
f1L1F, f1L2F, f1L3F, f1L4F = F1
f2L1F, f2L2F, f2L3F, f2L4F = F2
x = (u + s) / 2
f1V = dmp_eval_in(f1, x, 0, 1, F)
f2V = dmp_eval_in(f2, x, 0, 1, F)
I_V = dup_isolate_real_roots_list([f1V, f2V], F, inf=v, sup=t, fast=True, strict=True, basis=True)
I_L1_L, I_L1_R = [], []
I_L2_L, I_L2_R = I_V, I_L2
I_L3_L, I_L3_R = [], []
I_L4_L, I_L4_R = I_L4, _reverse_intervals(I_V)
for I in I_L1:
(a, b), indices, h = I
if a == b:
if a == x:
I_L1_L.append(I)
I_L1_R.append(I)
elif a < x:
I_L1_L.append(I)
else:
I_L1_R.append(I)
else:
if b <= x:
I_L1_L.append(I)
elif a >= x:
I_L1_R.append(I)
else:
a, b = dup_refine_real_root(h, a, b, F.get_ring(), disjoint=x, fast=True)
if b <= x:
I_L1_L.append(((a, b), indices, h))
if a >= x:
I_L1_R.append(((a, b), indices, h))
for I in I_L3:
(b, a), indices, h = I
if a == b:
if a == x:
I_L3_L.append(I)
I_L3_R.append(I)
elif a < x:
I_L3_L.append(I)
else:
I_L3_R.append(I)
else:
if b <= x:
I_L3_L.append(I)
elif a >= x:
I_L3_R.append(I)
else:
a, b = dup_refine_real_root(h, a, b, F.get_ring(), disjoint=x, fast=True)
if b <= x:
I_L3_L.append(((b, a), indices, h))
if a >= x:
I_L3_R.append(((b, a), indices, h))
Q_L1_L = _intervals_to_quadrants(I_L1_L, f1L1F, f2L1F, u, x, F)
Q_L2_L = _intervals_to_quadrants(I_L2_L, f1V, f2V, v, t, F)
Q_L3_L = _intervals_to_quadrants(I_L3_L, f1L3F, f2L3F, x, u, F)
Q_L4_L = Q_L4
Q_L1_R = _intervals_to_quadrants(I_L1_R, f1L1F, f2L1F, x, s, F)
Q_L2_R = Q_L2
Q_L3_R = _intervals_to_quadrants(I_L3_R, f1L3F, f2L3F, s, x, F)
Q_L4_R = _intervals_to_quadrants(I_L4_R, f1V, f2V, t, v, F)
T_L = _traverse_quadrants(Q_L1_L, Q_L2_L, Q_L3_L, Q_L4_L, exclude=True)
T_R = _traverse_quadrants(Q_L1_R, Q_L2_R, Q_L3_R, Q_L4_R, exclude=True)
N_L = _winding_number(T_L, F)
N_R = _winding_number(T_R, F)
I_L = (I_L1_L, I_L2_L, I_L3_L, I_L4_L)
Q_L = (Q_L1_L, Q_L2_L, Q_L3_L, Q_L4_L)
I_R = (I_L1_R, I_L2_R, I_L3_R, I_L4_R)
Q_R = (Q_L1_R, Q_L2_R, Q_L3_R, Q_L4_R)
F1_L = (f1L1F, f1V, f1L3F, f1L4F)
F2_L = (f2L1F, f2V, f2L3F, f2L4F)
F1_R = (f1L1F, f1L2F, f1L3F, f1V)
F2_R = (f2L1F, f2L2F, f2L3F, f2V)
a, b = (u, v), (x, t)
c, d = (x, v), (s, t)
D_L = (N_L, a, b, I_L, Q_L, F1_L, F2_L)
D_R = (N_R, c, d, I_R, Q_R, F1_R, F2_R)
return D_L, D_R
def _horizontal_bisection(N, a, b, I, Q, F1, F2, f1, f2, F):
"""Horizontal bisection step in Collins-Krandick root isolation algorithm. """
(u, v), (s, t) = a, b
I_L1, I_L2, I_L3, I_L4 = I
Q_L1, Q_L2, Q_L3, Q_L4 = Q
f1L1F, f1L2F, f1L3F, f1L4F = F1
f2L1F, f2L2F, f2L3F, f2L4F = F2
y = (v + t) / 2
f1H = dmp_eval_in(f1, y, 1, 1, F)
f2H = dmp_eval_in(f2, y, 1, 1, F)
I_H = dup_isolate_real_roots_list([f1H, f2H], F, inf=u, sup=s, fast=True, strict=True, basis=True)
I_L1_B, I_L1_U = I_L1, I_H
I_L2_B, I_L2_U = [], []
I_L3_B, I_L3_U = _reverse_intervals(I_H), I_L3
I_L4_B, I_L4_U = [], []
for I in I_L2:
(a, b), indices, h = I
if a == b:
if a == y:
I_L2_B.append(I)
I_L2_U.append(I)
elif a < y:
I_L2_B.append(I)
else:
I_L2_U.append(I)
else:
if b <= y:
I_L2_B.append(I)
elif a >= y:
I_L2_U.append(I)
else:
a, b = dup_refine_real_root(h, a, b, F.get_ring(), disjoint=y, fast=True)
if b <= y:
I_L2_B.append(((a, b), indices, h))
if a >= y:
I_L2_U.append(((a, b), indices, h))
for I in I_L4:
(b, a), indices, h = I
if a == b:
if a == y:
I_L4_B.append(I)
I_L4_U.append(I)
elif a < y:
I_L4_B.append(I)
else:
I_L4_U.append(I)
else:
if b <= y:
I_L4_B.append(I)
elif a >= y:
I_L4_U.append(I)
else:
a, b = dup_refine_real_root(h, a, b, F.get_ring(), disjoint=y, fast=True)
if b <= y:
I_L4_B.append(((b, a), indices, h))
if a >= y:
I_L4_U.append(((b, a), indices, h))
Q_L1_B = Q_L1
Q_L2_B = _intervals_to_quadrants(I_L2_B, f1L2F, f2L2F, v, y, F)
Q_L3_B = _intervals_to_quadrants(I_L3_B, f1H, f2H, s, u, F)
Q_L4_B = _intervals_to_quadrants(I_L4_B, f1L4F, f2L4F, y, v, F)
Q_L1_U = _intervals_to_quadrants(I_L1_U, f1H, f2H, u, s, F)
Q_L2_U = _intervals_to_quadrants(I_L2_U, f1L2F, f2L2F, y, t, F)
Q_L3_U = Q_L3
Q_L4_U = _intervals_to_quadrants(I_L4_U, f1L4F, f2L4F, t, y, F)
T_B = _traverse_quadrants(Q_L1_B, Q_L2_B, Q_L3_B, Q_L4_B, exclude=True)
T_U = _traverse_quadrants(Q_L1_U, Q_L2_U, Q_L3_U, Q_L4_U, exclude=True)
N_B = _winding_number(T_B, F)
N_U = _winding_number(T_U, F)
I_B = (I_L1_B, I_L2_B, I_L3_B, I_L4_B)
Q_B = (Q_L1_B, Q_L2_B, Q_L3_B, Q_L4_B)
I_U = (I_L1_U, I_L2_U, I_L3_U, I_L4_U)
Q_U = (Q_L1_U, Q_L2_U, Q_L3_U, Q_L4_U)
F1_B = (f1L1F, f1L2F, f1H, f1L4F)
F2_B = (f2L1F, f2L2F, f2H, f2L4F)
F1_U = (f1H, f1L2F, f1L3F, f1L4F)
F2_U = (f2H, f2L2F, f2L3F, f2L4F)
a, b = (u, v), (s, y)
c, d = (u, y), (s, t)
D_B = (N_B, a, b, I_B, Q_B, F1_B, F2_B)
D_U = (N_U, c, d, I_U, Q_U, F1_U, F2_U)
return D_B, D_U
def _depth_first_select(rectangles):
"""Find a rectangle of minimum area for bisection. """
min_area, j = None, None
for i, (_, (u, v), (s, t), _, _, _, _) in enumerate(rectangles):
area = (s - u)*(t - v)
if min_area is None or area < min_area:
min_area, j = area, i
return rectangles.pop(j)
def _rectangle_small_p(a, b, eps):
"""Return ``True`` if the given rectangle is small enough. """
(u, v), (s, t) = a, b
if eps is not None:
return s - u < eps and t - v < eps
else:
return True
def dup_isolate_complex_roots_sqf(f, K, eps=None, inf=None, sup=None, blackbox=False):
"""Isolate complex roots of a square-free polynomial using Collins-Krandick algorithm. """
if not K.is_ZZ and not K.is_QQ:
raise DomainError("isolation of complex roots is not supported over %s" % K)
if dup_degree(f) <= 0:
return []
if K.is_ZZ:
F = K.get_field()
else:
F = K
f = dup_convert(f, K, F)
lc = abs(dup_LC(f, F))
B = 2*max([ F.quo(abs(c), lc) for c in f ])
(u, v), (s, t) = (-B, F.zero), (B, B)
if inf is not None:
u = inf
if sup is not None:
s = sup
if v < 0 or t <= v or s <= u:
raise ValueError("not a valid complex isolation rectangle")
f1, f2 = dup_real_imag(f, F)
f1L1 = dmp_eval_in(f1, v, 1, 1, F)
f2L1 = dmp_eval_in(f2, v, 1, 1, F)
f1L2 = dmp_eval_in(f1, s, 0, 1, F)
f2L2 = dmp_eval_in(f2, s, 0, 1, F)
f1L3 = dmp_eval_in(f1, t, 1, 1, F)
f2L3 = dmp_eval_in(f2, t, 1, 1, F)
f1L4 = dmp_eval_in(f1, u, 0, 1, F)
f2L4 = dmp_eval_in(f2, u, 0, 1, F)
S_L1 = [f1L1, f2L1]
S_L2 = [f1L2, f2L2]
S_L3 = [f1L3, f2L3]
S_L4 = [f1L4, f2L4]
I_L1 = dup_isolate_real_roots_list(S_L1, F, inf=u, sup=s, fast=True, strict=True, basis=True)
I_L2 = dup_isolate_real_roots_list(S_L2, F, inf=v, sup=t, fast=True, strict=True, basis=True)
I_L3 = dup_isolate_real_roots_list(S_L3, F, inf=u, sup=s, fast=True, strict=True, basis=True)
I_L4 = dup_isolate_real_roots_list(S_L4, F, inf=v, sup=t, fast=True, strict=True, basis=True)
I_L3 = _reverse_intervals(I_L3)
I_L4 = _reverse_intervals(I_L4)
Q_L1 = _intervals_to_quadrants(I_L1, f1L1, f2L1, u, s, F)
Q_L2 = _intervals_to_quadrants(I_L2, f1L2, f2L2, v, t, F)
Q_L3 = _intervals_to_quadrants(I_L3, f1L3, f2L3, s, u, F)
Q_L4 = _intervals_to_quadrants(I_L4, f1L4, f2L4, t, v, F)
T = _traverse_quadrants(Q_L1, Q_L2, Q_L3, Q_L4)
N = _winding_number(T, F)
if not N:
return []
I = (I_L1, I_L2, I_L3, I_L4)
Q = (Q_L1, Q_L2, Q_L3, Q_L4)
F1 = (f1L1, f1L2, f1L3, f1L4)
F2 = (f2L1, f2L2, f2L3, f2L4)
rectangles, roots = [(N, (u, v), (s, t), I, Q, F1, F2)], []
while rectangles:
N, (u, v), (s, t), I, Q, F1, F2 = _depth_first_select(rectangles)
if s - u > t - v:
D_L, D_R = _vertical_bisection(N, (u, v), (s, t), I, Q, F1, F2, f1, f2, F)
N_L, a, b, I_L, Q_L, F1_L, F2_L = D_L
N_R, c, d, I_R, Q_R, F1_R, F2_R = D_R
if N_L >= 1:
if N_L == 1 and _rectangle_small_p(a, b, eps):
roots.append(ComplexInterval(a, b, I_L, Q_L, F1_L, F2_L, f1, f2, F))
else:
rectangles.append(D_L)
if N_R >= 1:
if N_R == 1 and _rectangle_small_p(c, d, eps):
roots.append(ComplexInterval(c, d, I_R, Q_R, F1_R, F2_R, f1, f2, F))
else:
rectangles.append(D_R)
else:
D_B, D_U = _horizontal_bisection(N, (u, v), (s, t), I, Q, F1, F2, f1, f2, F)
N_B, a, b, I_B, Q_B, F1_B, F2_B = D_B
N_U, c, d, I_U, Q_U, F1_U, F2_U = D_U
if N_B >= 1:
if N_B == 1 and _rectangle_small_p(a, b, eps):
roots.append(ComplexInterval(
a, b, I_B, Q_B, F1_B, F2_B, f1, f2, F))
else:
rectangles.append(D_B)
if N_U >= 1:
if N_U == 1 and _rectangle_small_p(c, d, eps):
roots.append(ComplexInterval(
c, d, I_U, Q_U, F1_U, F2_U, f1, f2, F))
else:
rectangles.append(D_U)
_roots, roots = sorted(roots, key=lambda r: (r.ax, r.ay)), []
for root in _roots:
roots.extend([root.conjugate(), root])
if blackbox:
return roots
else:
return [ r.as_tuple() for r in roots ]
def dup_isolate_all_roots_sqf(f, K, eps=None, inf=None, sup=None, fast=False, blackbox=False):
"""Isolate real and complex roots of a square-free polynomial ``f``. """
return (
dup_isolate_real_roots_sqf( f, K, eps=eps, inf=inf, sup=sup, fast=fast, blackbox=blackbox),
dup_isolate_complex_roots_sqf(f, K, eps=eps, inf=inf, sup=sup, blackbox=blackbox))
def dup_isolate_all_roots(f, K, eps=None, inf=None, sup=None, fast=False):
"""Isolate real and complex roots of a non-square-free polynomial ``f``. """
if not K.is_ZZ and not K.is_QQ:
raise DomainError("isolation of real and complex roots is not supported over %s" % K)
_, factors = dup_sqf_list(f, K)
if len(factors) == 1:
((f, k),) = factors
real_part, complex_part = dup_isolate_all_roots_sqf(
f, K, eps=eps, inf=inf, sup=sup, fast=fast)
real_part = [ ((a, b), k) for (a, b) in real_part ]
complex_part = [ ((a, b), k) for (a, b) in complex_part ]
return real_part, complex_part
else:
raise NotImplementedError( "only trivial square-free polynomials are supported")
class RealInterval(object):
"""A fully qualified representation of a real isolation interval. """
def __init__(self, data, f, dom):
"""Initialize new real interval with complete information. """
if len(data) == 2:
s, t = data
self.neg = False
if s < 0:
if t <= 0:
f, s, t, self.neg = dup_mirror(f, dom), -t, -s, True
else:
raise ValueError("can't refine a real root in (%s, %s)" % (s, t))
a, b, c, d = _mobius_from_interval((s, t), dom.get_field())
f = dup_transform(f, dup_strip([a, b]),
dup_strip([c, d]), dom)
self.mobius = a, b, c, d
else:
self.mobius = data[:-1]
self.neg = data[-1]
self.f, self.dom = f, dom
@property
def func(self):
return RealInterval
@property
def args(self):
i = self
return (i.mobius + (i.neg,), i.f, i.dom)
def __eq__(self, other):
if type(other) != type(self):
return False
return self.args == other.args
@property
def a(self):
"""Return the position of the left end. """
field = self.dom.get_field()
a, b, c, d = self.mobius
if not self.neg:
if a*d < b*c:
return field(a, c)
return field(b, d)
else:
if a*d > b*c:
return -field(a, c)
return -field(b, d)
@property
def b(self):
"""Return the position of the right end. """
was = self.neg
self.neg = not was
rv = -self.a
self.neg = was
return rv
@property
def dx(self):
"""Return width of the real isolating interval. """
return self.b - self.a
@property
def center(self):
"""Return the center of the real isolating interval. """
return (self.a + self.b)/2
def as_tuple(self):
"""Return tuple representation of real isolating interval. """
return (self.a, self.b)
def __repr__(self):
return "(%s, %s)" % (self.a, self.b)
def is_disjoint(self, other):
"""Return ``True`` if two isolation intervals are disjoint. """
if isinstance(other, RealInterval):
return (self.b <= other.a or other.b <= self.a)
assert isinstance(other, ComplexInterval)
return (self.b <= other.ax or other.bx <= self.a
or other.ay*other.by > 0)
def _inner_refine(self):
"""Internal one step real root refinement procedure. """
if self.mobius is None:
return self
f, mobius = dup_inner_refine_real_root(
self.f, self.mobius, self.dom, steps=1, mobius=True)
return RealInterval(mobius + (self.neg,), f, self.dom)
def refine_disjoint(self, other):
"""Refine an isolating interval until it is disjoint with another one. """
expr = self
while not expr.is_disjoint(other):
expr, other = expr._inner_refine(), other._inner_refine()
return expr, other
def refine_size(self, dx):
"""Refine an isolating interval until it is of sufficiently small size. """
expr = self
while not (expr.dx < dx):
expr = expr._inner_refine()
return expr
def refine_step(self, steps=1):
"""Perform several steps of real root refinement algorithm. """
expr = self
for _ in range(steps):
expr = expr._inner_refine()
return expr
def refine(self):
"""Perform one step of real root refinement algorithm. """
return self._inner_refine()
class ComplexInterval(object):
"""A fully qualified representation of a complex isolation interval.
The printed form is shown as (ax, bx) x (ay, by) where (ax, ay)
and (bx, by) are the coordinates of the southwest and northeast
corners of the interval's rectangle, respectively.
Examples
========
>>> from sympy import CRootOf, S
>>> from sympy.abc import x
>>> CRootOf.clear_cache() # for doctest reproducibility
>>> root = CRootOf(x**10 - 2*x + 3, 9)
>>> i = root._get_interval(); i
(3/64, 3/32) x (9/8, 75/64)
The real part of the root lies within the range [0, 3/4] while
the imaginary part lies within the range [9/8, 3/2]:
>>> root.n(3)
0.0766 + 1.14*I
The width of the ranges in the x and y directions on the complex
plane are:
>>> i.dx, i.dy
(3/64, 3/64)
The center of the range is
>>> i.center
(9/128, 147/128)
The northeast coordinate of the rectangle bounding the root in the
complex plane is given by attribute b and the x and y components
are accessed by bx and by:
>>> i.b, i.bx, i.by
((3/32, 75/64), 3/32, 75/64)
The southwest coordinate is similarly given by i.a
>>> i.a, i.ax, i.ay
((3/64, 9/8), 3/64, 9/8)
Although the interval prints to show only the real and imaginary
range of the root, all the information of the underlying root
is contained as properties of the interval.
For example, an interval with a nonpositive imaginary range is
considered to be the conjugate. Since the y values of y are in the
range [0, 1/4] it is not the conjugate:
>>> i.conj
False
The conjugate's interval is
>>> ic = i.conjugate(); ic
(3/64, 3/32) x (-75/64, -9/8)
NOTE: the values printed still represent the x and y range
in which the root -- conjugate, in this case -- is located,
but the underlying a and b values of a root and its conjugate
are the same:
>>> assert i.a == ic.a and i.b == ic.b
What changes are the reported coordinates of the bounding rectangle:
>>> (i.ax, i.ay), (i.bx, i.by)
((3/64, 9/8), (3/32, 75/64))
>>> (ic.ax, ic.ay), (ic.bx, ic.by)
((3/64, -75/64), (3/32, -9/8))
The interval can be refined once:
>>> i # for reference, this is the current interval
(3/64, 3/32) x (9/8, 75/64)
>>> i.refine()
(3/64, 3/32) x (9/8, 147/128)
Several refinement steps can be taken:
>>> i.refine_step(2) # 2 steps
(9/128, 3/32) x (9/8, 147/128)
It is also possible to refine to a given tolerance:
>>> tol = min(i.dx, i.dy)/2
>>> i.refine_size(tol)
(9/128, 21/256) x (9/8, 291/256)
A disjoint interval is one whose bounding rectangle does not
overlap with another. An interval, necessarily, is not disjoint with
itself, but any interval is disjoint with a conjugate since the
conjugate rectangle will always be in the lower half of the complex
plane and the non-conjugate in the upper half:
>>> i.is_disjoint(i), i.is_disjoint(i.conjugate())
(False, True)
The following interval j is not disjoint from i:
>>> close = CRootOf(x**10 - 2*x + 300/S(101), 9)
>>> j = close._get_interval(); j
(75/1616, 75/808) x (225/202, 1875/1616)
>>> i.is_disjoint(j)
False
The two can be made disjoint, however:
>>> newi, newj = i.refine_disjoint(j)
>>> newi
(39/512, 159/2048) x (2325/2048, 4653/4096)
>>> newj
(3975/51712, 2025/25856) x (29325/25856, 117375/103424)
Even though the real ranges overlap, the imaginary do not, so
the roots have been resolved as distinct. Intervals are disjoint
when either the real or imaginary component of the intervals is
distinct. In the case above, the real components have not been
resolved (so we don't know, yet, which root has the smaller real
part) but the imaginary part of ``close`` is larger than ``root``:
>>> close.n(3)
0.0771 + 1.13*I
>>> root.n(3)
0.0766 + 1.14*I
"""
def __init__(self, a, b, I, Q, F1, F2, f1, f2, dom, conj=False):
"""Initialize new complex interval with complete information. """
# a and b are the SW and NE corner of the bounding interval,
# (ax, ay) and (bx, by), respectively, for the NON-CONJUGATE
# root (the one with the positive imaginary part); when working
# with the conjugate, the a and b value are still non-negative
# but the ay, by are reversed and have oppositite sign
self.a, self.b = a, b
self.I, self.Q = I, Q
self.f1, self.F1 = f1, F1
self.f2, self.F2 = f2, F2
self.dom = dom
self.conj = conj
@property
def func(self):
return ComplexInterval
@property
def args(self):
i = self
return (i.a, i.b, i.I, i.Q, i.F1, i.F2, i.f1, i.f2, i.dom, i.conj)
def __eq__(self, other):
if type(other) != type(self):
return False
return self.args == other.args
@property
def ax(self):
"""Return ``x`` coordinate of south-western corner. """
return self.a[0]
@property
def ay(self):
"""Return ``y`` coordinate of south-western corner. """
if not self.conj:
return self.a[1]
else:
return -self.b[1]
@property
def bx(self):
"""Return ``x`` coordinate of north-eastern corner. """
return self.b[0]
@property
def by(self):
"""Return ``y`` coordinate of north-eastern corner. """
if not self.conj:
return self.b[1]
else:
return -self.a[1]
@property
def dx(self):
"""Return width of the complex isolating interval. """
return self.b[0] - self.a[0]
@property
def dy(self):
"""Return height of the complex isolating interval. """
return self.b[1] - self.a[1]
@property
def center(self):
"""Return the center of the complex isolating interval. """
return ((self.ax + self.bx)/2, (self.ay + self.by)/2)
def as_tuple(self):
"""Return tuple representation of the complex isolating
interval's SW and NE corners, respectively. """
return ((self.ax, self.ay), (self.bx, self.by))
def __repr__(self):
return "(%s, %s) x (%s, %s)" % (self.ax, self.bx, self.ay, self.by)
def conjugate(self):
"""This complex interval really is located in lower half-plane. """
return ComplexInterval(self.a, self.b, self.I, self.Q,
self.F1, self.F2, self.f1, self.f2, self.dom, conj=True)
def is_disjoint(self, other):
"""Return ``True`` if two isolation intervals are disjoint. """
if isinstance(other, RealInterval):
return other.is_disjoint(self)
if self.conj != other.conj: # above and below real axis
return True
re_distinct = (self.bx <= other.ax or other.bx <= self.ax)
if re_distinct:
return True
im_distinct = (self.by <= other.ay or other.by <= self.ay)
return im_distinct
def _inner_refine(self):
"""Internal one step complex root refinement procedure. """
(u, v), (s, t) = self.a, self.b
I, Q = self.I, self.Q
f1, F1 = self.f1, self.F1
f2, F2 = self.f2, self.F2
dom = self.dom
if s - u > t - v:
D_L, D_R = _vertical_bisection(1, (u, v), (s, t), I, Q, F1, F2, f1, f2, dom)
if D_L[0] == 1:
_, a, b, I, Q, F1, F2 = D_L
else:
_, a, b, I, Q, F1, F2 = D_R
else:
D_B, D_U = _horizontal_bisection(1, (u, v), (s, t), I, Q, F1, F2, f1, f2, dom)
if D_B[0] == 1:
_, a, b, I, Q, F1, F2 = D_B
else:
_, a, b, I, Q, F1, F2 = D_U
return ComplexInterval(a, b, I, Q, F1, F2, f1, f2, dom, self.conj)
def refine_disjoint(self, other):
"""Refine an isolating interval until it is disjoint with another one. """
expr = self
while not expr.is_disjoint(other):
expr, other = expr._inner_refine(), other._inner_refine()
return expr, other
def refine_size(self, dx, dy=None):
"""Refine an isolating interval until it is of sufficiently small size. """
if dy is None:
dy = dx
expr = self
while not (expr.dx < dx and expr.dy < dy):
expr = expr._inner_refine()
return expr
def refine_step(self, steps=1):
"""Perform several steps of complex root refinement algorithm. """
expr = self
for _ in range(steps):
expr = expr._inner_refine()
return expr
def refine(self):
"""Perform one step of complex root refinement algorithm. """
return self._inner_refine()
|
f548a360d81464d44d682356933cc9a99c987cd4baa3cc9b3e6e2522de8731c6 | """Polynomial factorization routines in characteristic zero. """
from __future__ import print_function, division
from sympy.polys.galoistools import (
gf_from_int_poly, gf_to_int_poly,
gf_lshift, gf_add_mul, gf_mul,
gf_div, gf_rem,
gf_gcdex,
gf_sqf_p,
gf_factor_sqf, gf_factor)
from sympy.polys.densebasic import (
dup_LC, dmp_LC, dmp_ground_LC,
dup_TC,
dup_convert, dmp_convert,
dup_degree, dmp_degree,
dmp_degree_in, dmp_degree_list,
dmp_from_dict,
dmp_zero_p,
dmp_one,
dmp_nest, dmp_raise,
dup_strip,
dmp_ground,
dup_inflate,
dmp_exclude, dmp_include,
dmp_inject, dmp_eject,
dup_terms_gcd, dmp_terms_gcd)
from sympy.polys.densearith import (
dup_neg, dmp_neg,
dup_add, dmp_add,
dup_sub, dmp_sub,
dup_mul, dmp_mul,
dup_sqr,
dmp_pow,
dup_div, dmp_div,
dup_quo, dmp_quo,
dmp_expand,
dmp_add_mul,
dup_sub_mul, dmp_sub_mul,
dup_lshift,
dup_max_norm, dmp_max_norm,
dup_l1_norm,
dup_mul_ground, dmp_mul_ground,
dup_quo_ground, dmp_quo_ground)
from sympy.polys.densetools import (
dup_clear_denoms, dmp_clear_denoms,
dup_trunc, dmp_ground_trunc,
dup_content,
dup_monic, dmp_ground_monic,
dup_primitive, dmp_ground_primitive,
dmp_eval_tail,
dmp_eval_in, dmp_diff_eval_in,
dmp_compose,
dup_shift, dup_mirror)
from sympy.polys.euclidtools import (
dmp_primitive,
dup_inner_gcd, dmp_inner_gcd)
from sympy.polys.sqfreetools import (
dup_sqf_p,
dup_sqf_norm, dmp_sqf_norm,
dup_sqf_part, dmp_sqf_part)
from sympy.polys.polyutils import _sort_factors
from sympy.polys.polyconfig import query
from sympy.polys.polyerrors import (
ExtraneousFactors, DomainError, CoercionFailed, EvaluationFailed)
from sympy.ntheory import nextprime, isprime, factorint
from sympy.utilities import subsets
from math import ceil as _ceil, log as _log
def dup_trial_division(f, factors, K):
"""
Determine multiplicities of factors for a univariate polynomial
using trial division.
"""
result = []
for factor in factors:
k = 0
while True:
q, r = dup_div(f, factor, K)
if not r:
f, k = q, k + 1
else:
break
result.append((factor, k))
return _sort_factors(result)
def dmp_trial_division(f, factors, u, K):
"""
Determine multiplicities of factors for a multivariate polynomial
using trial division.
"""
result = []
for factor in factors:
k = 0
while True:
q, r = dmp_div(f, factor, u, K)
if dmp_zero_p(r, u):
f, k = q, k + 1
else:
break
result.append((factor, k))
return _sort_factors(result)
def dup_zz_mignotte_bound(f, K):
"""
The Knuth-Cohen variant of Mignotte bound for
univariate polynomials in `K[x]`.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> f = x**3 + 14*x**2 + 56*x + 64
>>> R.dup_zz_mignotte_bound(f)
152
By checking `factor(f)` we can see that max coeff is 8
Also consider a case that `f` is irreducible for example `f = 2*x**2 + 3*x + 4`
To avoid a bug for these cases, we return the bound plus the max coefficient of `f`
>>> f = 2*x**2 + 3*x + 4
>>> R.dup_zz_mignotte_bound(f)
6
Lastly,To see the difference between the new and the old Mignotte bound
consider the irreducible polynomial::
>>> f = 87*x**7 + 4*x**6 + 80*x**5 + 17*x**4 + 9*x**3 + 12*x**2 + 49*x + 26
>>> R.dup_zz_mignotte_bound(f)
744
The new Mignotte bound is 744 whereas the old one (SymPy 1.5.1) is 1937664.
References
==========
..[1] [Abbott2013]_
"""
from sympy import binomial
d = dup_degree(f)
delta = _ceil(d / 2)
delta2 = _ceil(delta / 2)
# euclidean-norm
eucl_norm = K.sqrt( sum( [cf**2 for cf in f] ) )
# biggest values of binomial coefficients (p. 538 of reference)
t1 = binomial(delta - 1, delta2)
t2 = binomial(delta - 1, delta2 - 1)
lc = K.abs(dup_LC(f, K)) # leading coefficient
bound = t1 * eucl_norm + t2 * lc # (p. 538 of reference)
bound += dup_max_norm(f, K) # add max coeff for irreducible polys
bound = _ceil(bound / 2) * 2 # round up to even integer
return bound
def dmp_zz_mignotte_bound(f, u, K):
"""Mignotte bound for multivariate polynomials in `K[X]`. """
a = dmp_max_norm(f, u, K)
b = abs(dmp_ground_LC(f, u, K))
n = sum(dmp_degree_list(f, u))
return K.sqrt(K(n + 1))*2**n*a*b
def dup_zz_hensel_step(m, f, g, h, s, t, K):
"""
One step in Hensel lifting in `Z[x]`.
Given positive integer `m` and `Z[x]` polynomials `f`, `g`, `h`, `s`
and `t` such that::
f = g*h (mod m)
s*g + t*h = 1 (mod m)
lc(f) is not a zero divisor (mod m)
lc(h) = 1
deg(f) = deg(g) + deg(h)
deg(s) < deg(h)
deg(t) < deg(g)
returns polynomials `G`, `H`, `S` and `T`, such that::
f = G*H (mod m**2)
S*G + T*H = 1 (mod m**2)
References
==========
.. [1] [Gathen99]_
"""
M = m**2
e = dup_sub_mul(f, g, h, K)
e = dup_trunc(e, M, K)
q, r = dup_div(dup_mul(s, e, K), h, K)
q = dup_trunc(q, M, K)
r = dup_trunc(r, M, K)
u = dup_add(dup_mul(t, e, K), dup_mul(q, g, K), K)
G = dup_trunc(dup_add(g, u, K), M, K)
H = dup_trunc(dup_add(h, r, K), M, K)
u = dup_add(dup_mul(s, G, K), dup_mul(t, H, K), K)
b = dup_trunc(dup_sub(u, [K.one], K), M, K)
c, d = dup_div(dup_mul(s, b, K), H, K)
c = dup_trunc(c, M, K)
d = dup_trunc(d, M, K)
u = dup_add(dup_mul(t, b, K), dup_mul(c, G, K), K)
S = dup_trunc(dup_sub(s, d, K), M, K)
T = dup_trunc(dup_sub(t, u, K), M, K)
return G, H, S, T
def dup_zz_hensel_lift(p, f, f_list, l, K):
"""
Multifactor Hensel lifting in `Z[x]`.
Given a prime `p`, polynomial `f` over `Z[x]` such that `lc(f)`
is a unit modulo `p`, monic pair-wise coprime polynomials `f_i`
over `Z[x]` satisfying::
f = lc(f) f_1 ... f_r (mod p)
and a positive integer `l`, returns a list of monic polynomials
`F_1`, `F_2`, ..., `F_r` satisfying::
f = lc(f) F_1 ... F_r (mod p**l)
F_i = f_i (mod p), i = 1..r
References
==========
.. [1] [Gathen99]_
"""
r = len(f_list)
lc = dup_LC(f, K)
if r == 1:
F = dup_mul_ground(f, K.gcdex(lc, p**l)[0], K)
return [ dup_trunc(F, p**l, K) ]
m = p
k = r // 2
d = int(_ceil(_log(l, 2)))
g = gf_from_int_poly([lc], p)
for f_i in f_list[:k]:
g = gf_mul(g, gf_from_int_poly(f_i, p), p, K)
h = gf_from_int_poly(f_list[k], p)
for f_i in f_list[k + 1:]:
h = gf_mul(h, gf_from_int_poly(f_i, p), p, K)
s, t, _ = gf_gcdex(g, h, p, K)
g = gf_to_int_poly(g, p)
h = gf_to_int_poly(h, p)
s = gf_to_int_poly(s, p)
t = gf_to_int_poly(t, p)
for _ in range(1, d + 1):
(g, h, s, t), m = dup_zz_hensel_step(m, f, g, h, s, t, K), m**2
return dup_zz_hensel_lift(p, g, f_list[:k], l, K) \
+ dup_zz_hensel_lift(p, h, f_list[k:], l, K)
def _test_pl(fc, q, pl):
if q > pl // 2:
q = q - pl
if not q:
return True
return fc % q == 0
def dup_zz_zassenhaus(f, K):
"""Factor primitive square-free polynomials in `Z[x]`. """
n = dup_degree(f)
if n == 1:
return [f]
fc = f[-1]
A = dup_max_norm(f, K)
b = dup_LC(f, K)
B = int(abs(K.sqrt(K(n + 1))*2**n*A*b))
C = int((n + 1)**(2*n)*A**(2*n - 1))
gamma = int(_ceil(2*_log(C, 2)))
bound = int(2*gamma*_log(gamma))
a = []
# choose a prime number `p` such that `f` be square free in Z_p
# if there are many factors in Z_p, choose among a few different `p`
# the one with fewer factors
for px in range(3, bound + 1):
if not isprime(px) or b % px == 0:
continue
px = K.convert(px)
F = gf_from_int_poly(f, px)
if not gf_sqf_p(F, px, K):
continue
fsqfx = gf_factor_sqf(F, px, K)[1]
a.append((px, fsqfx))
if len(fsqfx) < 15 or len(a) > 4:
break
p, fsqf = min(a, key=lambda x: len(x[1]))
l = int(_ceil(_log(2*B + 1, p)))
modular = [gf_to_int_poly(ff, p) for ff in fsqf]
g = dup_zz_hensel_lift(p, f, modular, l, K)
sorted_T = range(len(g))
T = set(sorted_T)
factors, s = [], 1
pl = p**l
while 2*s <= len(T):
for S in subsets(sorted_T, s):
# lift the constant coefficient of the product `G` of the factors
# in the subset `S`; if it is does not divide `fc`, `G` does
# not divide the input polynomial
if b == 1:
q = 1
for i in S:
q = q*g[i][-1]
q = q % pl
if not _test_pl(fc, q, pl):
continue
else:
G = [b]
for i in S:
G = dup_mul(G, g[i], K)
G = dup_trunc(G, pl, K)
G = dup_primitive(G, K)[1]
q = G[-1]
if q and fc % q != 0:
continue
H = [b]
S = set(S)
T_S = T - S
if b == 1:
G = [b]
for i in S:
G = dup_mul(G, g[i], K)
G = dup_trunc(G, pl, K)
for i in T_S:
H = dup_mul(H, g[i], K)
H = dup_trunc(H, pl, K)
G_norm = dup_l1_norm(G, K)
H_norm = dup_l1_norm(H, K)
if G_norm*H_norm <= B:
T = T_S
sorted_T = [i for i in sorted_T if i not in S]
G = dup_primitive(G, K)[1]
f = dup_primitive(H, K)[1]
factors.append(G)
b = dup_LC(f, K)
break
else:
s += 1
return factors + [f]
def dup_zz_irreducible_p(f, K):
"""Test irreducibility using Eisenstein's criterion. """
lc = dup_LC(f, K)
tc = dup_TC(f, K)
e_fc = dup_content(f[1:], K)
if e_fc:
e_ff = factorint(int(e_fc))
for p in e_ff.keys():
if (lc % p) and (tc % p**2):
return True
def dup_cyclotomic_p(f, K, irreducible=False):
"""
Efficiently test if ``f`` is a cyclotomic polynomial.
Examples
========
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> f = x**16 + x**14 - x**10 + x**8 - x**6 + x**2 + 1
>>> R.dup_cyclotomic_p(f)
False
>>> g = x**16 + x**14 - x**10 - x**8 - x**6 + x**2 + 1
>>> R.dup_cyclotomic_p(g)
True
"""
if K.is_QQ:
try:
K0, K = K, K.get_ring()
f = dup_convert(f, K0, K)
except CoercionFailed:
return False
elif not K.is_ZZ:
return False
lc = dup_LC(f, K)
tc = dup_TC(f, K)
if lc != 1 or (tc != -1 and tc != 1):
return False
if not irreducible:
coeff, factors = dup_factor_list(f, K)
if coeff != K.one or factors != [(f, 1)]:
return False
n = dup_degree(f)
g, h = [], []
for i in range(n, -1, -2):
g.insert(0, f[i])
for i in range(n - 1, -1, -2):
h.insert(0, f[i])
g = dup_sqr(dup_strip(g), K)
h = dup_sqr(dup_strip(h), K)
F = dup_sub(g, dup_lshift(h, 1, K), K)
if K.is_negative(dup_LC(F, K)):
F = dup_neg(F, K)
if F == f:
return True
g = dup_mirror(f, K)
if K.is_negative(dup_LC(g, K)):
g = dup_neg(g, K)
if F == g and dup_cyclotomic_p(g, K):
return True
G = dup_sqf_part(F, K)
if dup_sqr(G, K) == F and dup_cyclotomic_p(G, K):
return True
return False
def dup_zz_cyclotomic_poly(n, K):
"""Efficiently generate n-th cyclotomic polynomial. """
h = [K.one, -K.one]
for p, k in factorint(n).items():
h = dup_quo(dup_inflate(h, p, K), h, K)
h = dup_inflate(h, p**(k - 1), K)
return h
def _dup_cyclotomic_decompose(n, K):
H = [[K.one, -K.one]]
for p, k in factorint(n).items():
Q = [ dup_quo(dup_inflate(h, p, K), h, K) for h in H ]
H.extend(Q)
for i in range(1, k):
Q = [ dup_inflate(q, p, K) for q in Q ]
H.extend(Q)
return H
def dup_zz_cyclotomic_factor(f, K):
"""
Efficiently factor polynomials `x**n - 1` and `x**n + 1` in `Z[x]`.
Given a univariate polynomial `f` in `Z[x]` returns a list of factors
of `f`, provided that `f` is in the form `x**n - 1` or `x**n + 1` for
`n >= 1`. Otherwise returns None.
Factorization is performed using cyclotomic decomposition of `f`,
which makes this method much faster that any other direct factorization
approach (e.g. Zassenhaus's).
References
==========
.. [1] [Weisstein09]_
"""
lc_f, tc_f = dup_LC(f, K), dup_TC(f, K)
if dup_degree(f) <= 0:
return None
if lc_f != 1 or tc_f not in [-1, 1]:
return None
if any(bool(cf) for cf in f[1:-1]):
return None
n = dup_degree(f)
F = _dup_cyclotomic_decompose(n, K)
if not K.is_one(tc_f):
return F
else:
H = []
for h in _dup_cyclotomic_decompose(2*n, K):
if h not in F:
H.append(h)
return H
def dup_zz_factor_sqf(f, K):
"""Factor square-free (non-primitive) polynomials in `Z[x]`. """
cont, g = dup_primitive(f, K)
n = dup_degree(g)
if dup_LC(g, K) < 0:
cont, g = -cont, dup_neg(g, K)
if n <= 0:
return cont, []
elif n == 1:
return cont, [g]
if query('USE_IRREDUCIBLE_IN_FACTOR'):
if dup_zz_irreducible_p(g, K):
return cont, [g]
factors = None
if query('USE_CYCLOTOMIC_FACTOR'):
factors = dup_zz_cyclotomic_factor(g, K)
if factors is None:
factors = dup_zz_zassenhaus(g, K)
return cont, _sort_factors(factors, multiple=False)
def dup_zz_factor(f, K):
"""
Factor (non square-free) polynomials in `Z[x]`.
Given a univariate polynomial `f` in `Z[x]` computes its complete
factorization `f_1, ..., f_n` into irreducibles over integers::
f = content(f) f_1**k_1 ... f_n**k_n
The factorization is computed by reducing the input polynomial
into a primitive square-free polynomial and factoring it using
Zassenhaus algorithm. Trial division is used to recover the
multiplicities of factors.
The result is returned as a tuple consisting of::
(content(f), [(f_1, k_1), ..., (f_n, k_n))
Examples
========
Consider the polynomial `f = 2*x**4 - 2`::
>>> from sympy.polys import ring, ZZ
>>> R, x = ring("x", ZZ)
>>> R.dup_zz_factor(2*x**4 - 2)
(2, [(x - 1, 1), (x + 1, 1), (x**2 + 1, 1)])
In result we got the following factorization::
f = 2 (x - 1) (x + 1) (x**2 + 1)
Note that this is a complete factorization over integers,
however over Gaussian integers we can factor the last term.
By default, polynomials `x**n - 1` and `x**n + 1` are factored
using cyclotomic decomposition to speedup computations. To
disable this behaviour set cyclotomic=False.
References
==========
.. [1] [Gathen99]_
"""
cont, g = dup_primitive(f, K)
n = dup_degree(g)
if dup_LC(g, K) < 0:
cont, g = -cont, dup_neg(g, K)
if n <= 0:
return cont, []
elif n == 1:
return cont, [(g, 1)]
if query('USE_IRREDUCIBLE_IN_FACTOR'):
if dup_zz_irreducible_p(g, K):
return cont, [(g, 1)]
g = dup_sqf_part(g, K)
H = None
if query('USE_CYCLOTOMIC_FACTOR'):
H = dup_zz_cyclotomic_factor(g, K)
if H is None:
H = dup_zz_zassenhaus(g, K)
factors = dup_trial_division(f, H, K)
return cont, factors
def dmp_zz_wang_non_divisors(E, cs, ct, K):
"""Wang/EEZ: Compute a set of valid divisors. """
result = [ cs*ct ]
for q in E:
q = abs(q)
for r in reversed(result):
while r != 1:
r = K.gcd(r, q)
q = q // r
if K.is_one(q):
return None
result.append(q)
return result[1:]
def dmp_zz_wang_test_points(f, T, ct, A, u, K):
"""Wang/EEZ: Test evaluation points for suitability. """
if not dmp_eval_tail(dmp_LC(f, K), A, u - 1, K):
raise EvaluationFailed('no luck')
g = dmp_eval_tail(f, A, u, K)
if not dup_sqf_p(g, K):
raise EvaluationFailed('no luck')
c, h = dup_primitive(g, K)
if K.is_negative(dup_LC(h, K)):
c, h = -c, dup_neg(h, K)
v = u - 1
E = [ dmp_eval_tail(t, A, v, K) for t, _ in T ]
D = dmp_zz_wang_non_divisors(E, c, ct, K)
if D is not None:
return c, h, E
else:
raise EvaluationFailed('no luck')
def dmp_zz_wang_lead_coeffs(f, T, cs, E, H, A, u, K):
"""Wang/EEZ: Compute correct leading coefficients. """
C, J, v = [], [0]*len(E), u - 1
for h in H:
c = dmp_one(v, K)
d = dup_LC(h, K)*cs
for i in reversed(range(len(E))):
k, e, (t, _) = 0, E[i], T[i]
while not (d % e):
d, k = d//e, k + 1
if k != 0:
c, J[i] = dmp_mul(c, dmp_pow(t, k, v, K), v, K), 1
C.append(c)
if any(not j for j in J):
raise ExtraneousFactors # pragma: no cover
CC, HH = [], []
for c, h in zip(C, H):
d = dmp_eval_tail(c, A, v, K)
lc = dup_LC(h, K)
if K.is_one(cs):
cc = lc//d
else:
g = K.gcd(lc, d)
d, cc = d//g, lc//g
h, cs = dup_mul_ground(h, d, K), cs//d
c = dmp_mul_ground(c, cc, v, K)
CC.append(c)
HH.append(h)
if K.is_one(cs):
return f, HH, CC
CCC, HHH = [], []
for c, h in zip(CC, HH):
CCC.append(dmp_mul_ground(c, cs, v, K))
HHH.append(dmp_mul_ground(h, cs, 0, K))
f = dmp_mul_ground(f, cs**(len(H) - 1), u, K)
return f, HHH, CCC
def dup_zz_diophantine(F, m, p, K):
"""Wang/EEZ: Solve univariate Diophantine equations. """
if len(F) == 2:
a, b = F
f = gf_from_int_poly(a, p)
g = gf_from_int_poly(b, p)
s, t, G = gf_gcdex(g, f, p, K)
s = gf_lshift(s, m, K)
t = gf_lshift(t, m, K)
q, s = gf_div(s, f, p, K)
t = gf_add_mul(t, q, g, p, K)
s = gf_to_int_poly(s, p)
t = gf_to_int_poly(t, p)
result = [s, t]
else:
G = [F[-1]]
for f in reversed(F[1:-1]):
G.insert(0, dup_mul(f, G[0], K))
S, T = [], [[1]]
for f, g in zip(F, G):
t, s = dmp_zz_diophantine([g, f], T[-1], [], 0, p, 1, K)
T.append(t)
S.append(s)
result, S = [], S + [T[-1]]
for s, f in zip(S, F):
s = gf_from_int_poly(s, p)
f = gf_from_int_poly(f, p)
r = gf_rem(gf_lshift(s, m, K), f, p, K)
s = gf_to_int_poly(r, p)
result.append(s)
return result
def dmp_zz_diophantine(F, c, A, d, p, u, K):
"""Wang/EEZ: Solve multivariate Diophantine equations. """
if not A:
S = [ [] for _ in F ]
n = dup_degree(c)
for i, coeff in enumerate(c):
if not coeff:
continue
T = dup_zz_diophantine(F, n - i, p, K)
for j, (s, t) in enumerate(zip(S, T)):
t = dup_mul_ground(t, coeff, K)
S[j] = dup_trunc(dup_add(s, t, K), p, K)
else:
n = len(A)
e = dmp_expand(F, u, K)
a, A = A[-1], A[:-1]
B, G = [], []
for f in F:
B.append(dmp_quo(e, f, u, K))
G.append(dmp_eval_in(f, a, n, u, K))
C = dmp_eval_in(c, a, n, u, K)
v = u - 1
S = dmp_zz_diophantine(G, C, A, d, p, v, K)
S = [ dmp_raise(s, 1, v, K) for s in S ]
for s, b in zip(S, B):
c = dmp_sub_mul(c, s, b, u, K)
c = dmp_ground_trunc(c, p, u, K)
m = dmp_nest([K.one, -a], n, K)
M = dmp_one(n, K)
for k in K.map(range(0, d)):
if dmp_zero_p(c, u):
break
M = dmp_mul(M, m, u, K)
C = dmp_diff_eval_in(c, k + 1, a, n, u, K)
if not dmp_zero_p(C, v):
C = dmp_quo_ground(C, K.factorial(k + 1), v, K)
T = dmp_zz_diophantine(G, C, A, d, p, v, K)
for i, t in enumerate(T):
T[i] = dmp_mul(dmp_raise(t, 1, v, K), M, u, K)
for i, (s, t) in enumerate(zip(S, T)):
S[i] = dmp_add(s, t, u, K)
for t, b in zip(T, B):
c = dmp_sub_mul(c, t, b, u, K)
c = dmp_ground_trunc(c, p, u, K)
S = [ dmp_ground_trunc(s, p, u, K) for s in S ]
return S
def dmp_zz_wang_hensel_lifting(f, H, LC, A, p, u, K):
"""Wang/EEZ: Parallel Hensel lifting algorithm. """
S, n, v = [f], len(A), u - 1
H = list(H)
for i, a in enumerate(reversed(A[1:])):
s = dmp_eval_in(S[0], a, n - i, u - i, K)
S.insert(0, dmp_ground_trunc(s, p, v - i, K))
d = max(dmp_degree_list(f, u)[1:])
for j, s, a in zip(range(2, n + 2), S, A):
G, w = list(H), j - 1
I, J = A[:j - 2], A[j - 1:]
for i, (h, lc) in enumerate(zip(H, LC)):
lc = dmp_ground_trunc(dmp_eval_tail(lc, J, v, K), p, w - 1, K)
H[i] = [lc] + dmp_raise(h[1:], 1, w - 1, K)
m = dmp_nest([K.one, -a], w, K)
M = dmp_one(w, K)
c = dmp_sub(s, dmp_expand(H, w, K), w, K)
dj = dmp_degree_in(s, w, w)
for k in K.map(range(0, dj)):
if dmp_zero_p(c, w):
break
M = dmp_mul(M, m, w, K)
C = dmp_diff_eval_in(c, k + 1, a, w, w, K)
if not dmp_zero_p(C, w - 1):
C = dmp_quo_ground(C, K.factorial(k + 1), w - 1, K)
T = dmp_zz_diophantine(G, C, I, d, p, w - 1, K)
for i, (h, t) in enumerate(zip(H, T)):
h = dmp_add_mul(h, dmp_raise(t, 1, w - 1, K), M, w, K)
H[i] = dmp_ground_trunc(h, p, w, K)
h = dmp_sub(s, dmp_expand(H, w, K), w, K)
c = dmp_ground_trunc(h, p, w, K)
if dmp_expand(H, u, K) != f:
raise ExtraneousFactors # pragma: no cover
else:
return H
def dmp_zz_wang(f, u, K, mod=None, seed=None):
"""
Factor primitive square-free polynomials in `Z[X]`.
Given a multivariate polynomial `f` in `Z[x_1,...,x_n]`, which is
primitive and square-free in `x_1`, computes factorization of `f` into
irreducibles over integers.
The procedure is based on Wang's Enhanced Extended Zassenhaus
algorithm. The algorithm works by viewing `f` as a univariate polynomial
in `Z[x_2,...,x_n][x_1]`, for which an evaluation mapping is computed::
x_2 -> a_2, ..., x_n -> a_n
where `a_i`, for `i = 2, ..., n`, are carefully chosen integers. The
mapping is used to transform `f` into a univariate polynomial in `Z[x_1]`,
which can be factored efficiently using Zassenhaus algorithm. The last
step is to lift univariate factors to obtain true multivariate
factors. For this purpose a parallel Hensel lifting procedure is used.
The parameter ``seed`` is passed to _randint and can be used to seed randint
(when an integer) or (for testing purposes) can be a sequence of numbers.
References
==========
.. [1] [Wang78]_
.. [2] [Geddes92]_
"""
from sympy.testing.randtest import _randint
randint = _randint(seed)
ct, T = dmp_zz_factor(dmp_LC(f, K), u - 1, K)
b = dmp_zz_mignotte_bound(f, u, K)
p = K(nextprime(b))
if mod is None:
if u == 1:
mod = 2
else:
mod = 1
history, configs, A, r = set([]), [], [K.zero]*u, None
try:
cs, s, E = dmp_zz_wang_test_points(f, T, ct, A, u, K)
_, H = dup_zz_factor_sqf(s, K)
r = len(H)
if r == 1:
return [f]
configs = [(s, cs, E, H, A)]
except EvaluationFailed:
pass
eez_num_configs = query('EEZ_NUMBER_OF_CONFIGS')
eez_num_tries = query('EEZ_NUMBER_OF_TRIES')
eez_mod_step = query('EEZ_MODULUS_STEP')
while len(configs) < eez_num_configs:
for _ in range(eez_num_tries):
A = [ K(randint(-mod, mod)) for _ in range(u) ]
if tuple(A) not in history:
history.add(tuple(A))
else:
continue
try:
cs, s, E = dmp_zz_wang_test_points(f, T, ct, A, u, K)
except EvaluationFailed:
continue
_, H = dup_zz_factor_sqf(s, K)
rr = len(H)
if r is not None:
if rr != r: # pragma: no cover
if rr < r:
configs, r = [], rr
else:
continue
else:
r = rr
if r == 1:
return [f]
configs.append((s, cs, E, H, A))
if len(configs) == eez_num_configs:
break
else:
mod += eez_mod_step
s_norm, s_arg, i = None, 0, 0
for s, _, _, _, _ in configs:
_s_norm = dup_max_norm(s, K)
if s_norm is not None:
if _s_norm < s_norm:
s_norm = _s_norm
s_arg = i
else:
s_norm = _s_norm
i += 1
_, cs, E, H, A = configs[s_arg]
orig_f = f
try:
f, H, LC = dmp_zz_wang_lead_coeffs(f, T, cs, E, H, A, u, K)
factors = dmp_zz_wang_hensel_lifting(f, H, LC, A, p, u, K)
except ExtraneousFactors: # pragma: no cover
if query('EEZ_RESTART_IF_NEEDED'):
return dmp_zz_wang(orig_f, u, K, mod + 1)
else:
raise ExtraneousFactors(
"we need to restart algorithm with better parameters")
result = []
for f in factors:
_, f = dmp_ground_primitive(f, u, K)
if K.is_negative(dmp_ground_LC(f, u, K)):
f = dmp_neg(f, u, K)
result.append(f)
return result
def dmp_zz_factor(f, u, K):
"""
Factor (non square-free) polynomials in `Z[X]`.
Given a multivariate polynomial `f` in `Z[x]` computes its complete
factorization `f_1, ..., f_n` into irreducibles over integers::
f = content(f) f_1**k_1 ... f_n**k_n
The factorization is computed by reducing the input polynomial
into a primitive square-free polynomial and factoring it using
Enhanced Extended Zassenhaus (EEZ) algorithm. Trial division
is used to recover the multiplicities of factors.
The result is returned as a tuple consisting of::
(content(f), [(f_1, k_1), ..., (f_n, k_n))
Consider polynomial `f = 2*(x**2 - y**2)`::
>>> from sympy.polys import ring, ZZ
>>> R, x,y = ring("x,y", ZZ)
>>> R.dmp_zz_factor(2*x**2 - 2*y**2)
(2, [(x - y, 1), (x + y, 1)])
In result we got the following factorization::
f = 2 (x - y) (x + y)
References
==========
.. [1] [Gathen99]_
"""
if not u:
return dup_zz_factor(f, K)
if dmp_zero_p(f, u):
return K.zero, []
cont, g = dmp_ground_primitive(f, u, K)
if dmp_ground_LC(g, u, K) < 0:
cont, g = -cont, dmp_neg(g, u, K)
if all(d <= 0 for d in dmp_degree_list(g, u)):
return cont, []
G, g = dmp_primitive(g, u, K)
factors = []
if dmp_degree(g, u) > 0:
g = dmp_sqf_part(g, u, K)
H = dmp_zz_wang(g, u, K)
factors = dmp_trial_division(f, H, u, K)
for g, k in dmp_zz_factor(G, u - 1, K)[1]:
factors.insert(0, ([g], k))
return cont, _sort_factors(factors)
def dup_ext_factor(f, K):
"""Factor univariate polynomials over algebraic number fields. """
n, lc = dup_degree(f), dup_LC(f, K)
f = dup_monic(f, K)
if n <= 0:
return lc, []
if n == 1:
return lc, [(f, 1)]
f, F = dup_sqf_part(f, K), f
s, g, r = dup_sqf_norm(f, K)
factors = dup_factor_list_include(r, K.dom)
if len(factors) == 1:
return lc, [(f, n//dup_degree(f))]
H = s*K.unit
for i, (factor, _) in enumerate(factors):
h = dup_convert(factor, K.dom, K)
h, _, g = dup_inner_gcd(h, g, K)
h = dup_shift(h, H, K)
factors[i] = h
factors = dup_trial_division(F, factors, K)
return lc, factors
def dmp_ext_factor(f, u, K):
"""Factor multivariate polynomials over algebraic number fields. """
if not u:
return dup_ext_factor(f, K)
lc = dmp_ground_LC(f, u, K)
f = dmp_ground_monic(f, u, K)
if all(d <= 0 for d in dmp_degree_list(f, u)):
return lc, []
f, F = dmp_sqf_part(f, u, K), f
s, g, r = dmp_sqf_norm(f, u, K)
factors = dmp_factor_list_include(r, u, K.dom)
if len(factors) == 1:
factors = [f]
else:
H = dmp_raise([K.one, s*K.unit], u, 0, K)
for i, (factor, _) in enumerate(factors):
h = dmp_convert(factor, u, K.dom, K)
h, _, g = dmp_inner_gcd(h, g, u, K)
h = dmp_compose(h, H, u, K)
factors[i] = h
return lc, dmp_trial_division(F, factors, u, K)
def dup_gf_factor(f, K):
"""Factor univariate polynomials over finite fields. """
f = dup_convert(f, K, K.dom)
coeff, factors = gf_factor(f, K.mod, K.dom)
for i, (f, k) in enumerate(factors):
factors[i] = (dup_convert(f, K.dom, K), k)
return K.convert(coeff, K.dom), factors
def dmp_gf_factor(f, u, K):
"""Factor multivariate polynomials over finite fields. """
raise NotImplementedError('multivariate polynomials over finite fields')
def dup_factor_list(f, K0):
"""Factor univariate polynomials into irreducibles in `K[x]`. """
j, f = dup_terms_gcd(f, K0)
cont, f = dup_primitive(f, K0)
if K0.is_FiniteField:
coeff, factors = dup_gf_factor(f, K0)
elif K0.is_Algebraic:
coeff, factors = dup_ext_factor(f, K0)
else:
if not K0.is_Exact:
K0_inexact, K0 = K0, K0.get_exact()
f = dup_convert(f, K0_inexact, K0)
else:
K0_inexact = None
if K0.is_Field:
K = K0.get_ring()
denom, f = dup_clear_denoms(f, K0, K)
f = dup_convert(f, K0, K)
else:
K = K0
if K.is_ZZ:
coeff, factors = dup_zz_factor(f, K)
elif K.is_Poly:
f, u = dmp_inject(f, 0, K)
coeff, factors = dmp_factor_list(f, u, K.dom)
for i, (f, k) in enumerate(factors):
factors[i] = (dmp_eject(f, u, K), k)
coeff = K.convert(coeff, K.dom)
else: # pragma: no cover
raise DomainError('factorization not supported over %s' % K0)
if K0.is_Field:
for i, (f, k) in enumerate(factors):
factors[i] = (dup_convert(f, K, K0), k)
coeff = K0.convert(coeff, K)
coeff = K0.quo(coeff, denom)
if K0_inexact:
for i, (f, k) in enumerate(factors):
max_norm = dup_max_norm(f, K0)
f = dup_quo_ground(f, max_norm, K0)
f = dup_convert(f, K0, K0_inexact)
factors[i] = (f, k)
coeff = K0.mul(coeff, K0.pow(max_norm, k))
coeff = K0_inexact.convert(coeff, K0)
K0 = K0_inexact
if j:
factors.insert(0, ([K0.one, K0.zero], j))
return coeff*cont, _sort_factors(factors)
def dup_factor_list_include(f, K):
"""Factor univariate polynomials into irreducibles in `K[x]`. """
coeff, factors = dup_factor_list(f, K)
if not factors:
return [(dup_strip([coeff]), 1)]
else:
g = dup_mul_ground(factors[0][0], coeff, K)
return [(g, factors[0][1])] + factors[1:]
def dmp_factor_list(f, u, K0):
"""Factor multivariate polynomials into irreducibles in `K[X]`. """
if not u:
return dup_factor_list(f, K0)
J, f = dmp_terms_gcd(f, u, K0)
cont, f = dmp_ground_primitive(f, u, K0)
if K0.is_FiniteField: # pragma: no cover
coeff, factors = dmp_gf_factor(f, u, K0)
elif K0.is_Algebraic:
coeff, factors = dmp_ext_factor(f, u, K0)
else:
if not K0.is_Exact:
K0_inexact, K0 = K0, K0.get_exact()
f = dmp_convert(f, u, K0_inexact, K0)
else:
K0_inexact = None
if K0.is_Field:
K = K0.get_ring()
denom, f = dmp_clear_denoms(f, u, K0, K)
f = dmp_convert(f, u, K0, K)
else:
K = K0
if K.is_ZZ:
levels, f, v = dmp_exclude(f, u, K)
coeff, factors = dmp_zz_factor(f, v, K)
for i, (f, k) in enumerate(factors):
factors[i] = (dmp_include(f, levels, v, K), k)
elif K.is_Poly:
f, v = dmp_inject(f, u, K)
coeff, factors = dmp_factor_list(f, v, K.dom)
for i, (f, k) in enumerate(factors):
factors[i] = (dmp_eject(f, v, K), k)
coeff = K.convert(coeff, K.dom)
else: # pragma: no cover
raise DomainError('factorization not supported over %s' % K0)
if K0.is_Field:
for i, (f, k) in enumerate(factors):
factors[i] = (dmp_convert(f, u, K, K0), k)
coeff = K0.convert(coeff, K)
coeff = K0.quo(coeff, denom)
if K0_inexact:
for i, (f, k) in enumerate(factors):
max_norm = dmp_max_norm(f, u, K0)
f = dmp_quo_ground(f, max_norm, u, K0)
f = dmp_convert(f, u, K0, K0_inexact)
factors[i] = (f, k)
coeff = K0.mul(coeff, K0.pow(max_norm, k))
coeff = K0_inexact.convert(coeff, K0)
K0 = K0_inexact
for i, j in enumerate(reversed(J)):
if not j:
continue
term = {(0,)*(u - i) + (1,) + (0,)*i: K0.one}
factors.insert(0, (dmp_from_dict(term, u, K0), j))
return coeff*cont, _sort_factors(factors)
def dmp_factor_list_include(f, u, K):
"""Factor multivariate polynomials into irreducibles in `K[X]`. """
if not u:
return dup_factor_list_include(f, K)
coeff, factors = dmp_factor_list(f, u, K)
if not factors:
return [(dmp_ground(coeff, u), 1)]
else:
g = dmp_mul_ground(factors[0][0], coeff, u, K)
return [(g, factors[0][1])] + factors[1:]
def dup_irreducible_p(f, K):
"""
Returns ``True`` if a univariate polynomial ``f`` has no factors
over its domain.
"""
return dmp_irreducible_p(f, 0, K)
def dmp_irreducible_p(f, u, K):
"""
Returns ``True`` if a multivariate polynomial ``f`` has no factors
over its domain.
"""
_, factors = dmp_factor_list(f, u, K)
if not factors:
return True
elif len(factors) > 1:
return False
else:
_, k = factors[0]
return k == 1
|
493ba6e72f76bf4dccdd59c9b24fe5f08c0a5d1472432e85050dfc7c20625c9f | r"""
Sparse distributed elements of free modules over multivariate (generalized)
polynomial rings.
This code and its data structures are very much like the distributed
polynomials, except that the first "exponent" of the monomial is
a module generator index. That is, the multi-exponent ``(i, e_1, ..., e_n)``
represents the "monomial" `x_1^{e_1} \cdots x_n^{e_n} f_i` of the free module
`F` generated by `f_1, \ldots, f_r` over (a localization of) the ring
`K[x_1, \ldots, x_n]`. A module element is simply stored as a list of terms
ordered by the monomial order. Here a term is a pair of a multi-exponent and a
coefficient. In general, this coefficient should never be zero (since it can
then be omitted). The zero module element is stored as an empty list.
The main routines are ``sdm_nf_mora`` and ``sdm_groebner`` which can be used
to compute, respectively, weak normal forms and standard bases. They work with
arbitrary (not necessarily global) monomial orders.
In general, product orders have to be used to construct valid monomial orders
for modules. However, ``lex`` can be used as-is.
Note that the "level" (number of variables, i.e. parameter u+1 in
distributedpolys.py) is never needed in this code.
The main reference for this file is [SCA],
"A Singular Introduction to Commutative Algebra".
"""
from __future__ import print_function, division
from itertools import permutations
from sympy.polys.monomials import (
monomial_mul, monomial_lcm, monomial_div, monomial_deg
)
from sympy.polys.polytools import Poly
from sympy.polys.polyutils import parallel_dict_from_expr
from sympy import S, sympify
# Additional monomial tools.
def sdm_monomial_mul(M, X):
"""
Multiply tuple ``X`` representing a monomial of `K[X]` into the tuple
``M`` representing a monomial of `F`.
Examples
========
Multiplying `xy^3` into `x f_1` yields `x^2 y^3 f_1`:
>>> from sympy.polys.distributedmodules import sdm_monomial_mul
>>> sdm_monomial_mul((1, 1, 0), (1, 3))
(1, 2, 3)
"""
return (M[0],) + monomial_mul(X, M[1:])
def sdm_monomial_deg(M):
"""
Return the total degree of ``M``.
Examples
========
For example, the total degree of `x^2 y f_5` is 3:
>>> from sympy.polys.distributedmodules import sdm_monomial_deg
>>> sdm_monomial_deg((5, 2, 1))
3
"""
return monomial_deg(M[1:])
def sdm_monomial_lcm(A, B):
r"""
Return the "least common multiple" of ``A`` and ``B``.
IF `A = M e_j` and `B = N e_j`, where `M` and `N` are polynomial monomials,
this returns `\lcm(M, N) e_j`. Note that ``A`` and ``B`` involve distinct
monomials.
Otherwise the result is undefined.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_monomial_lcm
>>> sdm_monomial_lcm((1, 2, 3), (1, 0, 5))
(1, 2, 5)
"""
return (A[0],) + monomial_lcm(A[1:], B[1:])
def sdm_monomial_divides(A, B):
"""
Does there exist a (polynomial) monomial X such that XA = B?
Examples
========
Positive examples:
In the following examples, the monomial is given in terms of x, y and the
generator(s), f_1, f_2 etc. The tuple form of that monomial is used in
the call to sdm_monomial_divides.
Note: the generator appears last in the expression but first in the tuple
and other factors appear in the same order that they appear in the monomial
expression.
`A = f_1` divides `B = f_1`
>>> from sympy.polys.distributedmodules import sdm_monomial_divides
>>> sdm_monomial_divides((1, 0, 0), (1, 0, 0))
True
`A = f_1` divides `B = x^2 y f_1`
>>> sdm_monomial_divides((1, 0, 0), (1, 2, 1))
True
`A = xy f_5` divides `B = x^2 y f_5`
>>> sdm_monomial_divides((5, 1, 1), (5, 2, 1))
True
Negative examples:
`A = f_1` does not divide `B = f_2`
>>> sdm_monomial_divides((1, 0, 0), (2, 0, 0))
False
`A = x f_1` does not divide `B = f_1`
>>> sdm_monomial_divides((1, 1, 0), (1, 0, 0))
False
`A = xy^2 f_5` does not divide `B = y f_5`
>>> sdm_monomial_divides((5, 1, 2), (5, 0, 1))
False
"""
return A[0] == B[0] and all(a <= b for a, b in zip(A[1:], B[1:]))
# The actual distributed modules code.
def sdm_LC(f, K):
"""Returns the leading coeffcient of ``f``. """
if not f:
return K.zero
else:
return f[0][1]
def sdm_to_dict(f):
"""Make a dictionary from a distributed polynomial. """
return dict(f)
def sdm_from_dict(d, O):
"""
Create an sdm from a dictionary.
Here ``O`` is the monomial order to use.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_from_dict
>>> from sympy.polys import QQ, lex
>>> dic = {(1, 1, 0): QQ(1), (1, 0, 0): QQ(2), (0, 1, 0): QQ(0)}
>>> sdm_from_dict(dic, lex)
[((1, 1, 0), 1), ((1, 0, 0), 2)]
"""
return sdm_strip(sdm_sort(list(d.items()), O))
def sdm_sort(f, O):
"""Sort terms in ``f`` using the given monomial order ``O``. """
return sorted(f, key=lambda term: O(term[0]), reverse=True)
def sdm_strip(f):
"""Remove terms with zero coefficients from ``f`` in ``K[X]``. """
return [ (monom, coeff) for monom, coeff in f if coeff ]
def sdm_add(f, g, O, K):
"""
Add two module elements ``f``, ``g``.
Addition is done over the ground field ``K``, monomials are ordered
according to ``O``.
Examples
========
All examples use lexicographic order.
`(xy f_1) + (f_2) = f_2 + xy f_1`
>>> from sympy.polys.distributedmodules import sdm_add
>>> from sympy.polys import lex, QQ
>>> sdm_add([((1, 1, 1), QQ(1))], [((2, 0, 0), QQ(1))], lex, QQ)
[((2, 0, 0), 1), ((1, 1, 1), 1)]
`(xy f_1) + (-xy f_1)` = 0`
>>> sdm_add([((1, 1, 1), QQ(1))], [((1, 1, 1), QQ(-1))], lex, QQ)
[]
`(f_1) + (2f_1) = 3f_1`
>>> sdm_add([((1, 0, 0), QQ(1))], [((1, 0, 0), QQ(2))], lex, QQ)
[((1, 0, 0), 3)]
`(yf_1) + (xf_1) = xf_1 + yf_1`
>>> sdm_add([((1, 0, 1), QQ(1))], [((1, 1, 0), QQ(1))], lex, QQ)
[((1, 1, 0), 1), ((1, 0, 1), 1)]
"""
h = dict(f)
for monom, c in g:
if monom in h:
coeff = h[monom] + c
if not coeff:
del h[monom]
else:
h[monom] = coeff
else:
h[monom] = c
return sdm_from_dict(h, O)
def sdm_LM(f):
r"""
Returns the leading monomial of ``f``.
Only valid if `f \ne 0`.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_LM, sdm_from_dict
>>> from sympy.polys import QQ, lex
>>> dic = {(1, 2, 3): QQ(1), (4, 0, 0): QQ(1), (4, 0, 1): QQ(1)}
>>> sdm_LM(sdm_from_dict(dic, lex))
(4, 0, 1)
"""
return f[0][0]
def sdm_LT(f):
r"""
Returns the leading term of ``f``.
Only valid if `f \ne 0`.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_LT, sdm_from_dict
>>> from sympy.polys import QQ, lex
>>> dic = {(1, 2, 3): QQ(1), (4, 0, 0): QQ(2), (4, 0, 1): QQ(3)}
>>> sdm_LT(sdm_from_dict(dic, lex))
((4, 0, 1), 3)
"""
return f[0]
def sdm_mul_term(f, term, O, K):
"""
Multiply a distributed module element ``f`` by a (polynomial) term ``term``.
Multiplication of coefficients is done over the ground field ``K``, and
monomials are ordered according to ``O``.
Examples
========
`0 f_1 = 0`
>>> from sympy.polys.distributedmodules import sdm_mul_term
>>> from sympy.polys import lex, QQ
>>> sdm_mul_term([((1, 0, 0), QQ(1))], ((0, 0), QQ(0)), lex, QQ)
[]
`x 0 = 0`
>>> sdm_mul_term([], ((1, 0), QQ(1)), lex, QQ)
[]
`(x) (f_1) = xf_1`
>>> sdm_mul_term([((1, 0, 0), QQ(1))], ((1, 0), QQ(1)), lex, QQ)
[((1, 1, 0), 1)]
`(2xy) (3x f_1 + 4y f_2) = 8xy^2 f_2 + 6x^2y f_1`
>>> f = [((2, 0, 1), QQ(4)), ((1, 1, 0), QQ(3))]
>>> sdm_mul_term(f, ((1, 1), QQ(2)), lex, QQ)
[((2, 1, 2), 8), ((1, 2, 1), 6)]
"""
X, c = term
if not f or not c:
return []
else:
if K.is_one(c):
return [ (sdm_monomial_mul(f_M, X), f_c) for f_M, f_c in f ]
else:
return [ (sdm_monomial_mul(f_M, X), f_c * c) for f_M, f_c in f ]
def sdm_zero():
"""Return the zero module element."""
return []
def sdm_deg(f):
"""
Degree of ``f``.
This is the maximum of the degrees of all its monomials.
Invalid if ``f`` is zero.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_deg
>>> sdm_deg([((1, 2, 3), 1), ((10, 0, 1), 1), ((2, 3, 4), 4)])
7
"""
return max(sdm_monomial_deg(M[0]) for M in f)
# Conversion
def sdm_from_vector(vec, O, K, **opts):
"""
Create an sdm from an iterable of expressions.
Coefficients are created in the ground field ``K``, and terms are ordered
according to monomial order ``O``. Named arguments are passed on to the
polys conversion code and can be used to specify for example generators.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_from_vector
>>> from sympy.abc import x, y, z
>>> from sympy.polys import QQ, lex
>>> sdm_from_vector([x**2+y**2, 2*z], lex, QQ)
[((1, 0, 0, 1), 2), ((0, 2, 0, 0), 1), ((0, 0, 2, 0), 1)]
"""
dics, gens = parallel_dict_from_expr(sympify(vec), **opts)
dic = {}
for i, d in enumerate(dics):
for k, v in d.items():
dic[(i,) + k] = K.convert(v)
return sdm_from_dict(dic, O)
def sdm_to_vector(f, gens, K, n=None):
"""
Convert sdm ``f`` into a list of polynomial expressions.
The generators for the polynomial ring are specified via ``gens``. The rank
of the module is guessed, or passed via ``n``. The ground field is assumed
to be ``K``.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_to_vector
>>> from sympy.abc import x, y, z
>>> from sympy.polys import QQ
>>> f = [((1, 0, 0, 1), QQ(2)), ((0, 2, 0, 0), QQ(1)), ((0, 0, 2, 0), QQ(1))]
>>> sdm_to_vector(f, [x, y, z], QQ)
[x**2 + y**2, 2*z]
"""
dic = sdm_to_dict(f)
dics = {}
for k, v in dic.items():
dics.setdefault(k[0], []).append((k[1:], v))
n = n or len(dics)
res = []
for k in range(n):
if k in dics:
res.append(Poly(dict(dics[k]), gens=gens, domain=K).as_expr())
else:
res.append(S.Zero)
return res
# Algorithms.
def sdm_spoly(f, g, O, K, phantom=None):
"""
Compute the generalized s-polynomial of ``f`` and ``g``.
The ground field is assumed to be ``K``, and monomials ordered according to
``O``.
This is invalid if either of ``f`` or ``g`` is zero.
If the leading terms of `f` and `g` involve different basis elements of
`F`, their s-poly is defined to be zero. Otherwise it is a certain linear
combination of `f` and `g` in which the leading terms cancel.
See [SCA, defn 2.3.6] for details.
If ``phantom`` is not ``None``, it should be a pair of module elements on
which to perform the same operation(s) as on ``f`` and ``g``. The in this
case both results are returned.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_spoly
>>> from sympy.polys import QQ, lex
>>> f = [((2, 1, 1), QQ(1)), ((1, 0, 1), QQ(1))]
>>> g = [((2, 3, 0), QQ(1))]
>>> h = [((1, 2, 3), QQ(1))]
>>> sdm_spoly(f, h, lex, QQ)
[]
>>> sdm_spoly(f, g, lex, QQ)
[((1, 2, 1), 1)]
"""
if not f or not g:
return sdm_zero()
LM1 = sdm_LM(f)
LM2 = sdm_LM(g)
if LM1[0] != LM2[0]:
return sdm_zero()
LM1 = LM1[1:]
LM2 = LM2[1:]
lcm = monomial_lcm(LM1, LM2)
m1 = monomial_div(lcm, LM1)
m2 = monomial_div(lcm, LM2)
c = K.quo(-sdm_LC(f, K), sdm_LC(g, K))
r1 = sdm_add(sdm_mul_term(f, (m1, K.one), O, K),
sdm_mul_term(g, (m2, c), O, K), O, K)
if phantom is None:
return r1
r2 = sdm_add(sdm_mul_term(phantom[0], (m1, K.one), O, K),
sdm_mul_term(phantom[1], (m2, c), O, K), O, K)
return r1, r2
def sdm_ecart(f):
"""
Compute the ecart of ``f``.
This is defined to be the difference of the total degree of `f` and the
total degree of the leading monomial of `f` [SCA, defn 2.3.7].
Invalid if f is zero.
Examples
========
>>> from sympy.polys.distributedmodules import sdm_ecart
>>> sdm_ecart([((1, 2, 3), 1), ((1, 0, 1), 1)])
0
>>> sdm_ecart([((2, 2, 1), 1), ((1, 5, 1), 1)])
3
"""
return sdm_deg(f) - sdm_monomial_deg(sdm_LM(f))
def sdm_nf_mora(f, G, O, K, phantom=None):
r"""
Compute a weak normal form of ``f`` with respect to ``G`` and order ``O``.
The ground field is assumed to be ``K``, and monomials ordered according to
``O``.
Weak normal forms are defined in [SCA, defn 2.3.3]. They are not unique.
This function deterministically computes a weak normal form, depending on
the order of `G`.
The most important property of a weak normal form is the following: if
`R` is the ring associated with the monomial ordering (if the ordering is
global, we just have `R = K[x_1, \ldots, x_n]`, otherwise it is a certain
localization thereof), `I` any ideal of `R` and `G` a standard basis for
`I`, then for any `f \in R`, we have `f \in I` if and only if
`NF(f | G) = 0`.
This is the generalized Mora algorithm for computing weak normal forms with
respect to arbitrary monomial orders [SCA, algorithm 2.3.9].
If ``phantom`` is not ``None``, it should be a pair of "phantom" arguments
on which to perform the same computations as on ``f``, ``G``, both results
are then returned.
"""
from itertools import repeat
h = f
T = list(G)
if phantom is not None:
# "phantom" variables with suffix p
hp = phantom[0]
Tp = list(phantom[1])
phantom = True
else:
Tp = repeat([])
phantom = False
while h:
# TODO better data structure!!!
Th = [(g, sdm_ecart(g), gp) for g, gp in zip(T, Tp)
if sdm_monomial_divides(sdm_LM(g), sdm_LM(h))]
if not Th:
break
g, _, gp = min(Th, key=lambda x: x[1])
if sdm_ecart(g) > sdm_ecart(h):
T.append(h)
if phantom:
Tp.append(hp)
if phantom:
h, hp = sdm_spoly(h, g, O, K, phantom=(hp, gp))
else:
h = sdm_spoly(h, g, O, K)
if phantom:
return h, hp
return h
def sdm_nf_buchberger(f, G, O, K, phantom=None):
r"""
Compute a weak normal form of ``f`` with respect to ``G`` and order ``O``.
The ground field is assumed to be ``K``, and monomials ordered according to
``O``.
This is the standard Buchberger algorithm for computing weak normal forms with
respect to *global* monomial orders [SCA, algorithm 1.6.10].
If ``phantom`` is not ``None``, it should be a pair of "phantom" arguments
on which to perform the same computations as on ``f``, ``G``, both results
are then returned.
"""
from itertools import repeat
h = f
T = list(G)
if phantom is not None:
# "phantom" variables with suffix p
hp = phantom[0]
Tp = list(phantom[1])
phantom = True
else:
Tp = repeat([])
phantom = False
while h:
try:
g, gp = next((g, gp) for g, gp in zip(T, Tp)
if sdm_monomial_divides(sdm_LM(g), sdm_LM(h)))
except StopIteration:
break
if phantom:
h, hp = sdm_spoly(h, g, O, K, phantom=(hp, gp))
else:
h = sdm_spoly(h, g, O, K)
if phantom:
return h, hp
return h
def sdm_nf_buchberger_reduced(f, G, O, K):
r"""
Compute a reduced normal form of ``f`` with respect to ``G`` and order ``O``.
The ground field is assumed to be ``K``, and monomials ordered according to
``O``.
In contrast to weak normal forms, reduced normal forms *are* unique, but
their computation is more expensive.
This is the standard Buchberger algorithm for computing reduced normal forms
with respect to *global* monomial orders [SCA, algorithm 1.6.11].
The ``pantom`` option is not supported, so this normal form cannot be used
as a normal form for the "extended" groebner algorithm.
"""
h = sdm_zero()
g = f
while g:
g = sdm_nf_buchberger(g, G, O, K)
if g:
h = sdm_add(h, [sdm_LT(g)], O, K)
g = g[1:]
return h
def sdm_groebner(G, NF, O, K, extended=False):
"""
Compute a minimal standard basis of ``G`` with respect to order ``O``.
The algorithm uses a normal form ``NF``, for example ``sdm_nf_mora``.
The ground field is assumed to be ``K``, and monomials ordered according
to ``O``.
Let `N` denote the submodule generated by elements of `G`. A standard
basis for `N` is a subset `S` of `N`, such that `in(S) = in(N)`, where for
any subset `X` of `F`, `in(X)` denotes the submodule generated by the
initial forms of elements of `X`. [SCA, defn 2.3.2]
A standard basis is called minimal if no subset of it is a standard basis.
One may show that standard bases are always generating sets.
Minimal standard bases are not unique. This algorithm computes a
deterministic result, depending on the particular order of `G`.
If ``extended=True``, also compute the transition matrix from the initial
generators to the groebner basis. That is, return a list of coefficient
vectors, expressing the elements of the groebner basis in terms of the
elements of ``G``.
This functions implements the "sugar" strategy, see
Giovini et al: "One sugar cube, please" OR Selection strategies in
Buchberger algorithm.
"""
# The critical pair set.
# A critical pair is stored as (i, j, s, t) where (i, j) defines the pair
# (by indexing S), s is the sugar of the pair, and t is the lcm of their
# leading monomials.
P = []
# The eventual standard basis.
S = []
Sugars = []
def Ssugar(i, j):
"""Compute the sugar of the S-poly corresponding to (i, j)."""
LMi = sdm_LM(S[i])
LMj = sdm_LM(S[j])
return max(Sugars[i] - sdm_monomial_deg(LMi),
Sugars[j] - sdm_monomial_deg(LMj)) \
+ sdm_monomial_deg(sdm_monomial_lcm(LMi, LMj))
ourkey = lambda p: (p[2], O(p[3]), p[1])
def update(f, sugar, P):
"""Add f with sugar ``sugar`` to S, update P."""
if not f:
return P
k = len(S)
S.append(f)
Sugars.append(sugar)
LMf = sdm_LM(f)
def removethis(pair):
i, j, s, t = pair
if LMf[0] != t[0]:
return False
tik = sdm_monomial_lcm(LMf, sdm_LM(S[i]))
tjk = sdm_monomial_lcm(LMf, sdm_LM(S[j]))
return tik != t and tjk != t and sdm_monomial_divides(tik, t) and \
sdm_monomial_divides(tjk, t)
# apply the chain criterion
P = [p for p in P if not removethis(p)]
# new-pair set
N = [(i, k, Ssugar(i, k), sdm_monomial_lcm(LMf, sdm_LM(S[i])))
for i in range(k) if LMf[0] == sdm_LM(S[i])[0]]
# TODO apply the product criterion?
N.sort(key=ourkey)
remove = set()
for i, p in enumerate(N):
for j in range(i + 1, len(N)):
if sdm_monomial_divides(p[3], N[j][3]):
remove.add(j)
# TODO mergesort?
P.extend(reversed([p for i, p in enumerate(N) if not i in remove]))
P.sort(key=ourkey, reverse=True)
# NOTE reverse-sort, because we want to pop from the end
return P
# Figure out the number of generators in the ground ring.
try:
# NOTE: we look for the first non-zero vector, take its first monomial
# the number of generators in the ring is one less than the length
# (since the zeroth entry is for the module generators)
numgens = len(next(x[0] for x in G if x)[0]) - 1
except StopIteration:
# No non-zero elements in G ...
if extended:
return [], []
return []
# This list will store expressions of the elements of S in terms of the
# initial generators
coefficients = []
# First add all the elements of G to S
for i, f in enumerate(G):
P = update(f, sdm_deg(f), P)
if extended and f:
coefficients.append(sdm_from_dict({(i,) + (0,)*numgens: K(1)}, O))
# Now carry out the buchberger algorithm.
while P:
i, j, s, t = P.pop()
f, g = S[i], S[j]
if extended:
sp, coeff = sdm_spoly(f, g, O, K,
phantom=(coefficients[i], coefficients[j]))
h, hcoeff = NF(sp, S, O, K, phantom=(coeff, coefficients))
if h:
coefficients.append(hcoeff)
else:
h = NF(sdm_spoly(f, g, O, K), S, O, K)
P = update(h, Ssugar(i, j), P)
# Finally interreduce the standard basis.
# (TODO again, better data structures)
S = set((tuple(f), i) for i, f in enumerate(S))
for (a, ai), (b, bi) in permutations(S, 2):
A = sdm_LM(a)
B = sdm_LM(b)
if sdm_monomial_divides(A, B) and (b, bi) in S and (a, ai) in S:
S.remove((b, bi))
L = sorted(((list(f), i) for f, i in S), key=lambda p: O(sdm_LM(p[0])),
reverse=True)
res = [x[0] for x in L]
if extended:
return res, [coefficients[i] for _, i in L]
return res
|
10ba4867db043829ec0285fd1477ab3b4469e7ada5345e8c542d58b0a3b06b81 | """ SymPy interface to Unification engine
See sympy.unify for module level docstring
See sympy.unify.core for algorithmic docstring """
from __future__ import print_function, division
from sympy.core import Basic, Add, Mul, Pow
from sympy.core.operations import AssocOp, LatticeOp
from sympy.matrices import MatAdd, MatMul, MatrixExpr
from sympy.sets.sets import Union, Intersection, FiniteSet
from sympy.unify.core import Compound, Variable, CondVariable
from sympy.unify import core
basic_new_legal = [MatrixExpr]
eval_false_legal = [AssocOp, Pow, FiniteSet]
illegal = [LatticeOp]
def sympy_associative(op):
assoc_ops = (AssocOp, MatAdd, MatMul, Union, Intersection, FiniteSet)
return any(issubclass(op, aop) for aop in assoc_ops)
def sympy_commutative(op):
comm_ops = (Add, MatAdd, Union, Intersection, FiniteSet)
return any(issubclass(op, cop) for cop in comm_ops)
def is_associative(x):
return isinstance(x, Compound) and sympy_associative(x.op)
def is_commutative(x):
if not isinstance(x, Compound):
return False
if sympy_commutative(x.op):
return True
if issubclass(x.op, Mul):
return all(construct(arg).is_commutative for arg in x.args)
def mk_matchtype(typ):
def matchtype(x):
return (isinstance(x, typ) or
isinstance(x, Compound) and issubclass(x.op, typ))
return matchtype
def deconstruct(s, variables=()):
""" Turn a SymPy object into a Compound """
if s in variables:
return Variable(s)
if isinstance(s, (Variable, CondVariable)):
return s
if not isinstance(s, Basic) or s.is_Atom:
return s
return Compound(s.__class__,
tuple(deconstruct(arg, variables) for arg in s.args))
def construct(t):
""" Turn a Compound into a SymPy object """
if isinstance(t, (Variable, CondVariable)):
return t.arg
if not isinstance(t, Compound):
return t
if any(issubclass(t.op, cls) for cls in eval_false_legal):
return t.op(*map(construct, t.args), evaluate=False)
elif any(issubclass(t.op, cls) for cls in basic_new_legal):
return Basic.__new__(t.op, *map(construct, t.args))
else:
return t.op(*map(construct, t.args))
def rebuild(s):
""" Rebuild a SymPy expression
This removes harm caused by Expr-Rules interactions
"""
return construct(deconstruct(s))
def unify(x, y, s=None, variables=(), **kwargs):
""" Structural unification of two expressions/patterns
Examples
========
>>> from sympy.unify.usympy import unify
>>> from sympy import Basic
>>> from sympy.abc import x, y, z, p, q
>>> next(unify(Basic(1, 2), Basic(1, x), variables=[x]))
{x: 2}
>>> expr = 2*x + y + z
>>> pattern = 2*p + q
>>> next(unify(expr, pattern, {}, variables=(p, q)))
{p: x, q: y + z}
Unification supports commutative and associative matching
>>> expr = x + y + z
>>> pattern = p + q
>>> len(list(unify(expr, pattern, {}, variables=(p, q))))
12
Symbols not indicated to be variables are treated as literal,
else they are wild-like and match anything in a sub-expression.
>>> expr = x*y*z + 3
>>> pattern = x*y + 3
>>> next(unify(expr, pattern, {}, variables=[x, y]))
{x: y, y: x*z}
The x and y of the pattern above were in a Mul and matched factors
in the Mul of expr. Here, a single symbol matches an entire term:
>>> expr = x*y + 3
>>> pattern = p + 3
>>> next(unify(expr, pattern, {}, variables=[p]))
{p: x*y}
"""
decons = lambda x: deconstruct(x, variables)
s = s or {}
s = dict((decons(k), decons(v)) for k, v in s.items())
ds = core.unify(decons(x), decons(y), s,
is_associative=is_associative,
is_commutative=is_commutative,
**kwargs)
for d in ds:
yield dict((construct(k), construct(v)) for k, v in d.items())
|
18251f46aec8cda3094376ae0cc3d5ff945b44704a17836e7eafab9a77d63244 | """py.test hacks to support XFAIL/XPASS"""
from __future__ import print_function, division
import sys
import functools
import os
import contextlib
import warnings
from sympy.core.compatibility import get_function_name
from sympy.utilities.exceptions import SymPyDeprecationWarning
ON_TRAVIS = os.getenv('TRAVIS_BUILD_NUMBER', None)
try:
import pytest
USE_PYTEST = getattr(sys, '_running_pytest', False)
except ImportError:
USE_PYTEST = False
if USE_PYTEST:
raises = pytest.raises
warns = pytest.warns
skip = pytest.skip
XFAIL = pytest.mark.xfail
SKIP = pytest.mark.skip
slow = pytest.mark.slow
nocache_fail = pytest.mark.nocache_fail
from _pytest.outcomes import Failed
else:
# Not using pytest so define the things that would have been imported from
# there.
def raises(expectedException, code=None):
"""
Tests that ``code`` raises the exception ``expectedException``.
``code`` may be a callable, such as a lambda expression or function
name.
If ``code`` is not given or None, ``raises`` will return a context
manager for use in ``with`` statements; the code to execute then
comes from the scope of the ``with``.
``raises()`` does nothing if the callable raises the expected exception,
otherwise it raises an AssertionError.
Examples
========
>>> from sympy.testing.pytest import raises
>>> raises(ZeroDivisionError, lambda: 1/0)
>>> raises(ZeroDivisionError, lambda: 1/2)
Traceback (most recent call last):
...
Failed: DID NOT RAISE
>>> with raises(ZeroDivisionError):
... n = 1/0
>>> with raises(ZeroDivisionError):
... n = 1/2
Traceback (most recent call last):
...
Failed: DID NOT RAISE
Note that you cannot test multiple statements via
``with raises``:
>>> with raises(ZeroDivisionError):
... n = 1/0 # will execute and raise, aborting the ``with``
... n = 9999/0 # never executed
This is just what ``with`` is supposed to do: abort the
contained statement sequence at the first exception and let
the context manager deal with the exception.
To test multiple statements, you'll need a separate ``with``
for each:
>>> with raises(ZeroDivisionError):
... n = 1/0 # will execute and raise
>>> with raises(ZeroDivisionError):
... n = 9999/0 # will also execute and raise
"""
if code is None:
return RaisesContext(expectedException)
elif callable(code):
try:
code()
except expectedException:
return
raise Failed("DID NOT RAISE")
elif isinstance(code, str):
raise TypeError(
'\'raises(xxx, "code")\' has been phased out; '
'change \'raises(xxx, "expression")\' '
'to \'raises(xxx, lambda: expression)\', '
'\'raises(xxx, "statement")\' '
'to \'with raises(xxx): statement\'')
else:
raise TypeError(
'raises() expects a callable for the 2nd argument.')
class RaisesContext(object):
def __init__(self, expectedException):
self.expectedException = expectedException
def __enter__(self):
return None
def __exit__(self, exc_type, exc_value, traceback):
if exc_type is None:
raise Failed("DID NOT RAISE")
return issubclass(exc_type, self.expectedException)
class XFail(Exception):
pass
class XPass(Exception):
pass
class Skipped(Exception):
pass
class Failed(Exception):
pass
def XFAIL(func):
def wrapper():
try:
func()
except Exception as e:
message = str(e)
if message != "Timeout":
raise XFail(get_function_name(func))
else:
raise Skipped("Timeout")
raise XPass(get_function_name(func))
wrapper = functools.update_wrapper(wrapper, func)
return wrapper
def skip(str):
raise Skipped(str)
def SKIP(reason):
"""Similar to ``skip()``, but this is a decorator. """
def wrapper(func):
def func_wrapper():
raise Skipped(reason)
func_wrapper = functools.update_wrapper(func_wrapper, func)
return func_wrapper
return wrapper
def slow(func):
func._slow = True
def func_wrapper():
func()
func_wrapper = functools.update_wrapper(func_wrapper, func)
func_wrapper.__wrapped__ = func
return func_wrapper
def nocache_fail(func):
"Dummy decorator for marking tests that fail when cache is disabled"
return func
@contextlib.contextmanager
def warns(warningcls, **kwargs):
'''Like raises but tests that warnings are emitted.
>>> from sympy.testing.pytest import warns
>>> import warnings
>>> with warns(UserWarning):
... warnings.warn('deprecated', UserWarning)
>>> with warns(UserWarning):
... pass
Traceback (most recent call last):
...
Failed: DID NOT WARN. No warnings of type UserWarning\
was emitted. The list of emitted warnings is: [].
'''
match = kwargs.pop('match', '')
if kwargs:
raise TypeError('Invalid keyword arguments: %s' % kwargs)
# Absorbs all warnings in warnrec
with warnings.catch_warnings(record=True) as warnrec:
# Hide all warnings but make sure that our warning is emitted
warnings.simplefilter("ignore")
warnings.filterwarnings("always", match, warningcls)
# Now run the test
yield
# Raise if expected warning not found
if not any(issubclass(w.category, warningcls) for w in warnrec):
msg = ('Failed: DID NOT WARN.'
' No warnings of type %s was emitted.'
' The list of emitted warnings is: %s.'
) % (warningcls, [w.message for w in warnrec])
raise Failed(msg)
@contextlib.contextmanager
def warns_deprecated_sympy():
'''Shorthand for ``warns(SymPyDeprecationWarning)``
This is the recommended way to test that ``SymPyDeprecationWarning`` is
emitted for deprecated features in SymPy. To test for other warnings use
``warns``. To suppress warnings without asserting that they are emitted
use ``ignore_warnings``.
>>> from sympy.testing.pytest import warns_deprecated_sympy
>>> from sympy.utilities.exceptions import SymPyDeprecationWarning
>>> with warns_deprecated_sympy():
... SymPyDeprecationWarning("Don't use", feature="old thing",
... deprecated_since_version="1.0", issue=123).warn()
>>> with warns_deprecated_sympy():
... pass
Traceback (most recent call last):
...
Failed: DID NOT WARN. No warnings of type \
SymPyDeprecationWarning was emitted. The list of emitted warnings is: [].
'''
with warns(SymPyDeprecationWarning):
yield
@contextlib.contextmanager
def ignore_warnings(warningcls):
'''Context manager to suppress warnings during tests.
This function is useful for suppressing warnings during tests. The warns
function should be used to assert that a warning is raised. The
ignore_warnings function is useful in situation when the warning is not
guaranteed to be raised (e.g. on importing a module) or if the warning
comes from third-party code.
When the warning is coming (reliably) from SymPy the warns function should
be preferred to ignore_warnings.
>>> from sympy.testing.pytest import ignore_warnings
>>> import warnings
Here's a warning:
>>> with warnings.catch_warnings(): # reset warnings in doctest
... warnings.simplefilter('error')
... warnings.warn('deprecated', UserWarning)
Traceback (most recent call last):
...
UserWarning: deprecated
Let's suppress it with ignore_warnings:
>>> with warnings.catch_warnings(): # reset warnings in doctest
... warnings.simplefilter('error')
... with ignore_warnings(UserWarning):
... warnings.warn('deprecated', UserWarning)
(No warning emitted)
'''
# Absorbs all warnings in warnrec
with warnings.catch_warnings(record=True) as warnrec:
# Make sure our warning doesn't get filtered
warnings.simplefilter("always", warningcls)
# Now run the test
yield
# Reissue any warnings that we aren't testing for
for w in warnrec:
if not issubclass(w.category, warningcls):
warnings.warn_explicit(w.message, w.category, w.filename, w.lineno)
|
8831d14d364921b1c926c7e58eb05f719f0baad3e8ccb8ed58be4ce7b9ef469d | from typing import Type
from sympy.core.assumptions import StdFactKB
from sympy.core import S, Pow, sympify
from sympy.core.expr import AtomicExpr, Expr
from sympy.core.compatibility import default_sort_key
from sympy import sqrt, ImmutableMatrix as Matrix, Add
from sympy.vector.coordsysrect import CoordSys3D
from sympy.vector.basisdependent import (BasisDependent, BasisDependentAdd,
BasisDependentMul, BasisDependentZero)
from sympy.vector.dyadic import BaseDyadic, Dyadic, DyadicAdd
class Vector(BasisDependent):
"""
Super class for all Vector classes.
Ideally, neither this class nor any of its subclasses should be
instantiated by the user.
"""
is_Vector = True
_op_priority = 12.0
_expr_type = None # type: Type[Vector]
_mul_func = None # type: Type[Vector]
_add_func = None # type: Type[Vector]
_zero_func = None # type: Type[Vector]
_base_func = None # type: Type[Vector]
zero = None # type: VectorZero
@property
def components(self):
"""
Returns the components of this vector in the form of a
Python dictionary mapping BaseVector instances to the
corresponding measure numbers.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> C = CoordSys3D('C')
>>> v = 3*C.i + 4*C.j + 5*C.k
>>> v.components
{C.i: 3, C.j: 4, C.k: 5}
"""
# The '_components' attribute is defined according to the
# subclass of Vector the instance belongs to.
return self._components
def magnitude(self):
"""
Returns the magnitude of this vector.
"""
return sqrt(self & self)
def normalize(self):
"""
Returns the normalized version of this vector.
"""
return self / self.magnitude()
def dot(self, other):
"""
Returns the dot product of this Vector, either with another
Vector, or a Dyadic, or a Del operator.
If 'other' is a Vector, returns the dot product scalar (Sympy
expression).
If 'other' is a Dyadic, the dot product is returned as a Vector.
If 'other' is an instance of Del, returns the directional
derivative operator as a Python function. If this function is
applied to a scalar expression, it returns the directional
derivative of the scalar field wrt this Vector.
Parameters
==========
other: Vector/Dyadic/Del
The Vector or Dyadic we are dotting with, or a Del operator .
Examples
========
>>> from sympy.vector import CoordSys3D, Del
>>> C = CoordSys3D('C')
>>> delop = Del()
>>> C.i.dot(C.j)
0
>>> C.i & C.i
1
>>> v = 3*C.i + 4*C.j + 5*C.k
>>> v.dot(C.k)
5
>>> (C.i & delop)(C.x*C.y*C.z)
C.y*C.z
>>> d = C.i.outer(C.i)
>>> C.i.dot(d)
C.i
"""
# Check special cases
if isinstance(other, Dyadic):
if isinstance(self, VectorZero):
return Vector.zero
outvec = Vector.zero
for k, v in other.components.items():
vect_dot = k.args[0].dot(self)
outvec += vect_dot * v * k.args[1]
return outvec
from sympy.vector.deloperator import Del
if not isinstance(other, Vector) and not isinstance(other, Del):
raise TypeError(str(other) + " is not a vector, dyadic or " +
"del operator")
# Check if the other is a del operator
if isinstance(other, Del):
def directional_derivative(field):
from sympy.vector.functions import directional_derivative
return directional_derivative(field, self)
return directional_derivative
return dot(self, other)
def __and__(self, other):
return self.dot(other)
__and__.__doc__ = dot.__doc__
def cross(self, other):
"""
Returns the cross product of this Vector with another Vector or
Dyadic instance.
The cross product is a Vector, if 'other' is a Vector. If 'other'
is a Dyadic, this returns a Dyadic instance.
Parameters
==========
other: Vector/Dyadic
The Vector or Dyadic we are crossing with.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> C = CoordSys3D('C')
>>> C.i.cross(C.j)
C.k
>>> C.i ^ C.i
0
>>> v = 3*C.i + 4*C.j + 5*C.k
>>> v ^ C.i
5*C.j + (-4)*C.k
>>> d = C.i.outer(C.i)
>>> C.j.cross(d)
(-1)*(C.k|C.i)
"""
# Check special cases
if isinstance(other, Dyadic):
if isinstance(self, VectorZero):
return Dyadic.zero
outdyad = Dyadic.zero
for k, v in other.components.items():
cross_product = self.cross(k.args[0])
outer = cross_product.outer(k.args[1])
outdyad += v * outer
return outdyad
return cross(self, other)
def __xor__(self, other):
return self.cross(other)
__xor__.__doc__ = cross.__doc__
def outer(self, other):
"""
Returns the outer product of this vector with another, in the
form of a Dyadic instance.
Parameters
==========
other : Vector
The Vector with respect to which the outer product is to
be computed.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> N = CoordSys3D('N')
>>> N.i.outer(N.j)
(N.i|N.j)
"""
# Handle the special cases
if not isinstance(other, Vector):
raise TypeError("Invalid operand for outer product")
elif (isinstance(self, VectorZero) or
isinstance(other, VectorZero)):
return Dyadic.zero
# Iterate over components of both the vectors to generate
# the required Dyadic instance
args = []
for k1, v1 in self.components.items():
for k2, v2 in other.components.items():
args.append((v1 * v2) * BaseDyadic(k1, k2))
return DyadicAdd(*args)
def projection(self, other, scalar=False):
"""
Returns the vector or scalar projection of the 'other' on 'self'.
Examples
========
>>> from sympy.vector.coordsysrect import CoordSys3D
>>> C = CoordSys3D('C')
>>> i, j, k = C.base_vectors()
>>> v1 = i + j + k
>>> v2 = 3*i + 4*j
>>> v1.projection(v2)
7/3*C.i + 7/3*C.j + 7/3*C.k
>>> v1.projection(v2, scalar=True)
7/3
"""
if self.equals(Vector.zero):
return S.zero if scalar else Vector.zero
if scalar:
return self.dot(other) / self.dot(self)
else:
return self.dot(other) / self.dot(self) * self
@property
def _projections(self):
"""
Returns the components of this vector but the output includes
also zero values components.
Examples
========
>>> from sympy.vector import CoordSys3D, Vector
>>> C = CoordSys3D('C')
>>> v1 = 3*C.i + 4*C.j + 5*C.k
>>> v1._projections
(3, 4, 5)
>>> v2 = C.x*C.y*C.z*C.i
>>> v2._projections
(C.x*C.y*C.z, 0, 0)
>>> v3 = Vector.zero
>>> v3._projections
(0, 0, 0)
"""
from sympy.vector.operators import _get_coord_sys_from_expr
if isinstance(self, VectorZero):
return (S.Zero, S.Zero, S.Zero)
base_vec = next(iter(_get_coord_sys_from_expr(self))).base_vectors()
return tuple([self.dot(i) for i in base_vec])
def __or__(self, other):
return self.outer(other)
__or__.__doc__ = outer.__doc__
def to_matrix(self, system):
"""
Returns the matrix form of this vector with respect to the
specified coordinate system.
Parameters
==========
system : CoordSys3D
The system wrt which the matrix form is to be computed
Examples
========
>>> from sympy.vector import CoordSys3D
>>> C = CoordSys3D('C')
>>> from sympy.abc import a, b, c
>>> v = a*C.i + b*C.j + c*C.k
>>> v.to_matrix(C)
Matrix([
[a],
[b],
[c]])
"""
return Matrix([self.dot(unit_vec) for unit_vec in
system.base_vectors()])
def separate(self):
"""
The constituents of this vector in different coordinate systems,
as per its definition.
Returns a dict mapping each CoordSys3D to the corresponding
constituent Vector.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> R1 = CoordSys3D('R1')
>>> R2 = CoordSys3D('R2')
>>> v = R1.i + R2.i
>>> v.separate() == {R1: R1.i, R2: R2.i}
True
"""
parts = {}
for vect, measure in self.components.items():
parts[vect.system] = (parts.get(vect.system, Vector.zero) +
vect * measure)
return parts
def _div_helper(one, other):
""" Helper for division involving vectors. """
if isinstance(one, Vector) and isinstance(other, Vector):
raise TypeError("Cannot divide two vectors")
elif isinstance(one, Vector):
if other == S.Zero:
raise ValueError("Cannot divide a vector by zero")
return VectorMul(one, Pow(other, S.NegativeOne))
else:
raise TypeError("Invalid division involving a vector")
class BaseVector(Vector, AtomicExpr):
"""
Class to denote a base vector.
Unicode pretty forms in Python 2 should use the prefix ``u``.
"""
def __new__(cls, index, system, pretty_str=None, latex_str=None):
if pretty_str is None:
pretty_str = "x{}".format(index)
if latex_str is None:
latex_str = "x_{}".format(index)
pretty_str = str(pretty_str)
latex_str = str(latex_str)
# Verify arguments
if index not in range(0, 3):
raise ValueError("index must be 0, 1 or 2")
if not isinstance(system, CoordSys3D):
raise TypeError("system should be a CoordSys3D")
name = system._vector_names[index]
# Initialize an object
obj = super().__new__(cls, S(index), system)
# Assign important attributes
obj._base_instance = obj
obj._components = {obj: S.One}
obj._measure_number = S.One
obj._name = system._name + '.' + name
obj._pretty_form = '' + pretty_str
obj._latex_form = latex_str
obj._system = system
# The _id is used for printing purposes
obj._id = (index, system)
assumptions = {'commutative': True}
obj._assumptions = StdFactKB(assumptions)
# This attr is used for re-expression to one of the systems
# involved in the definition of the Vector. Applies to
# VectorMul and VectorAdd too.
obj._sys = system
return obj
@property
def system(self):
return self._system
def __str__(self, printer=None):
return self._name
@property
def free_symbols(self):
return {self}
__repr__ = __str__
_sympystr = __str__
class VectorAdd(BasisDependentAdd, Vector):
"""
Class to denote sum of Vector instances.
"""
def __new__(cls, *args, **options):
obj = BasisDependentAdd.__new__(cls, *args, **options)
return obj
def __str__(self, printer=None):
ret_str = ''
items = list(self.separate().items())
items.sort(key=lambda x: x[0].__str__())
for system, vect in items:
base_vects = system.base_vectors()
for x in base_vects:
if x in vect.components:
temp_vect = self.components[x] * x
ret_str += temp_vect.__str__(printer) + " + "
return ret_str[:-3]
__repr__ = __str__
_sympystr = __str__
class VectorMul(BasisDependentMul, Vector):
"""
Class to denote products of scalars and BaseVectors.
"""
def __new__(cls, *args, **options):
obj = BasisDependentMul.__new__(cls, *args, **options)
return obj
@property
def base_vector(self):
""" The BaseVector involved in the product. """
return self._base_instance
@property
def measure_number(self):
""" The scalar expression involved in the definition of
this VectorMul.
"""
return self._measure_number
class VectorZero(BasisDependentZero, Vector):
"""
Class to denote a zero vector
"""
_op_priority = 12.1
_pretty_form = '0'
_latex_form = r'\mathbf{\hat{0}}'
def __new__(cls):
obj = BasisDependentZero.__new__(cls)
return obj
class Cross(Vector):
"""
Represents unevaluated Cross product.
Examples
========
>>> from sympy.vector import CoordSys3D, Cross
>>> R = CoordSys3D('R')
>>> v1 = R.i + R.j + R.k
>>> v2 = R.x * R.i + R.y * R.j + R.z * R.k
>>> Cross(v1, v2)
Cross(R.i + R.j + R.k, R.x*R.i + R.y*R.j + R.z*R.k)
>>> Cross(v1, v2).doit()
(-R.y + R.z)*R.i + (R.x - R.z)*R.j + (-R.x + R.y)*R.k
"""
def __new__(cls, expr1, expr2):
expr1 = sympify(expr1)
expr2 = sympify(expr2)
if default_sort_key(expr1) > default_sort_key(expr2):
return -Cross(expr2, expr1)
obj = Expr.__new__(cls, expr1, expr2)
obj._expr1 = expr1
obj._expr2 = expr2
return obj
def doit(self, **kwargs):
return cross(self._expr1, self._expr2)
class Dot(Expr):
"""
Represents unevaluated Dot product.
Examples
========
>>> from sympy.vector import CoordSys3D, Dot
>>> from sympy import symbols
>>> R = CoordSys3D('R')
>>> a, b, c = symbols('a b c')
>>> v1 = R.i + R.j + R.k
>>> v2 = a * R.i + b * R.j + c * R.k
>>> Dot(v1, v2)
Dot(R.i + R.j + R.k, a*R.i + b*R.j + c*R.k)
>>> Dot(v1, v2).doit()
a + b + c
"""
def __new__(cls, expr1, expr2):
expr1 = sympify(expr1)
expr2 = sympify(expr2)
expr1, expr2 = sorted([expr1, expr2], key=default_sort_key)
obj = Expr.__new__(cls, expr1, expr2)
obj._expr1 = expr1
obj._expr2 = expr2
return obj
def doit(self, **kwargs):
return dot(self._expr1, self._expr2)
def cross(vect1, vect2):
"""
Returns cross product of two vectors.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy.vector.vector import cross
>>> R = CoordSys3D('R')
>>> v1 = R.i + R.j + R.k
>>> v2 = R.x * R.i + R.y * R.j + R.z * R.k
>>> cross(v1, v2)
(-R.y + R.z)*R.i + (R.x - R.z)*R.j + (-R.x + R.y)*R.k
"""
if isinstance(vect1, Add):
return VectorAdd.fromiter(cross(i, vect2) for i in vect1.args)
if isinstance(vect2, Add):
return VectorAdd.fromiter(cross(vect1, i) for i in vect2.args)
if isinstance(vect1, BaseVector) and isinstance(vect2, BaseVector):
if vect1._sys == vect2._sys:
n1 = vect1.args[0]
n2 = vect2.args[0]
if n1 == n2:
return Vector.zero
n3 = ({0,1,2}.difference({n1, n2})).pop()
sign = 1 if ((n1 + 1) % 3 == n2) else -1
return sign*vect1._sys.base_vectors()[n3]
from .functions import express
try:
v = express(vect1, vect2._sys)
except ValueError:
return Cross(vect1, vect2)
else:
return cross(v, vect2)
if isinstance(vect1, VectorZero) or isinstance(vect2, VectorZero):
return Vector.zero
if isinstance(vect1, VectorMul):
v1, m1 = next(iter(vect1.components.items()))
return m1*cross(v1, vect2)
if isinstance(vect2, VectorMul):
v2, m2 = next(iter(vect2.components.items()))
return m2*cross(vect1, v2)
return Cross(vect1, vect2)
def dot(vect1, vect2):
"""
Returns dot product of two vectors.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy.vector.vector import dot
>>> R = CoordSys3D('R')
>>> v1 = R.i + R.j + R.k
>>> v2 = R.x * R.i + R.y * R.j + R.z * R.k
>>> dot(v1, v2)
R.x + R.y + R.z
"""
if isinstance(vect1, Add):
return Add.fromiter(dot(i, vect2) for i in vect1.args)
if isinstance(vect2, Add):
return Add.fromiter(dot(vect1, i) for i in vect2.args)
if isinstance(vect1, BaseVector) and isinstance(vect2, BaseVector):
if vect1._sys == vect2._sys:
return S.One if vect1 == vect2 else S.Zero
from .functions import express
try:
v = express(vect2, vect1._sys)
except ValueError:
return Dot(vect1, vect2)
else:
return dot(vect1, v)
if isinstance(vect1, VectorZero) or isinstance(vect2, VectorZero):
return S.Zero
if isinstance(vect1, VectorMul):
v1, m1 = next(iter(vect1.components.items()))
return m1*dot(v1, vect2)
if isinstance(vect2, VectorMul):
v2, m2 = next(iter(vect2.components.items()))
return m2*dot(vect1, v2)
return Dot(vect1, vect2)
Vector._expr_type = Vector
Vector._mul_func = VectorMul
Vector._add_func = VectorAdd
Vector._zero_func = VectorZero
Vector._base_func = BaseVector
Vector.zero = VectorZero()
|
2e55a088440d88eb5720274280a657a0db36cc14307fabb2ffc1d40d2e497f87 | from sympy.core.basic import Basic
from sympy.vector.vector import Vector
from sympy.vector.coordsysrect import CoordSys3D
from sympy.vector.functions import _path
from sympy import Symbol
from sympy.core.cache import cacheit
class Point(Basic):
"""
Represents a point in 3-D space.
"""
def __new__(cls, name, position=Vector.zero, parent_point=None):
name = str(name)
# Check the args first
if not isinstance(position, Vector):
raise TypeError(
"position should be an instance of Vector, not %s" % type(
position))
if (not isinstance(parent_point, Point) and
parent_point is not None):
raise TypeError(
"parent_point should be an instance of Point, not %s" % type(
parent_point))
# Super class construction
if parent_point is None:
obj = super().__new__(cls, Symbol(name), position)
else:
obj = super().__new__(cls, Symbol(name), position, parent_point)
# Decide the object parameters
obj._name = name
obj._pos = position
if parent_point is None:
obj._parent = None
obj._root = obj
else:
obj._parent = parent_point
obj._root = parent_point._root
# Return object
return obj
@cacheit
def position_wrt(self, other):
"""
Returns the position vector of this Point with respect to
another Point/CoordSys3D.
Parameters
==========
other : Point/CoordSys3D
If other is a Point, the position of this Point wrt it is
returned. If its an instance of CoordSyRect, the position
wrt its origin is returned.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> N = CoordSys3D('N')
>>> p1 = N.origin.locate_new('p1', 10 * N.i)
>>> N.origin.position_wrt(p1)
(-10)*N.i
"""
if (not isinstance(other, Point) and
not isinstance(other, CoordSys3D)):
raise TypeError(str(other) +
"is not a Point or CoordSys3D")
if isinstance(other, CoordSys3D):
other = other.origin
# Handle special cases
if other == self:
return Vector.zero
elif other == self._parent:
return self._pos
elif other._parent == self:
return -1 * other._pos
# Else, use point tree to calculate position
rootindex, path = _path(self, other)
result = Vector.zero
i = -1
for i in range(rootindex):
result += path[i]._pos
i += 2
while i < len(path):
result -= path[i]._pos
i += 1
return result
def locate_new(self, name, position):
"""
Returns a new Point located at the given position wrt this
Point.
Thus, the position vector of the new Point wrt this one will
be equal to the given 'position' parameter.
Parameters
==========
name : str
Name of the new point
position : Vector
The position vector of the new Point wrt this one
Examples
========
>>> from sympy.vector import CoordSys3D
>>> N = CoordSys3D('N')
>>> p1 = N.origin.locate_new('p1', 10 * N.i)
>>> p1.position_wrt(N.origin)
10*N.i
"""
return Point(name, position, self)
def express_coordinates(self, coordinate_system):
"""
Returns the Cartesian/rectangular coordinates of this point
wrt the origin of the given CoordSys3D instance.
Parameters
==========
coordinate_system : CoordSys3D
The coordinate system to express the coordinates of this
Point in.
Examples
========
>>> from sympy.vector import CoordSys3D
>>> N = CoordSys3D('N')
>>> p1 = N.origin.locate_new('p1', 10 * N.i)
>>> p2 = p1.locate_new('p2', 5 * N.j)
>>> p2.express_coordinates(N)
(10, 5, 0)
"""
# Determine the position vector
pos_vect = self.position_wrt(coordinate_system.origin)
# Express it in the given coordinate system
return tuple(pos_vect.to_matrix(coordinate_system))
def __str__(self, printer=None):
return self._name
__repr__ = __str__
_sympystr = __str__
|
b050fc8d332c1c454106a1ca44ca7ea28e5902d97720fb7a1c62555c2f237b20 | from sympy.vector.coordsysrect import CoordSys3D
from sympy.vector.deloperator import Del
from sympy.vector.scalar import BaseScalar
from sympy.vector.vector import Vector, BaseVector
from sympy.vector.operators import gradient, curl, divergence
from sympy import diff, integrate, S, simplify
from sympy.core import sympify
from sympy.vector.dyadic import Dyadic
def express(expr, system, system2=None, variables=False):
"""
Global function for 'express' functionality.
Re-expresses a Vector, Dyadic or scalar(sympyfiable) in the given
coordinate system.
If 'variables' is True, then the coordinate variables (base scalars)
of other coordinate systems present in the vector/scalar field or
dyadic are also substituted in terms of the base scalars of the
given system.
Parameters
==========
expr : Vector/Dyadic/scalar(sympyfiable)
The expression to re-express in CoordSys3D 'system'
system: CoordSys3D
The coordinate system the expr is to be expressed in
system2: CoordSys3D
The other coordinate system required for re-expression
(only for a Dyadic Expr)
variables : boolean
Specifies whether to substitute the coordinate variables present
in expr, in terms of those of parameter system
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy import Symbol, cos, sin
>>> N = CoordSys3D('N')
>>> q = Symbol('q')
>>> B = N.orient_new_axis('B', q, N.k)
>>> from sympy.vector import express
>>> express(B.i, N)
(cos(q))*N.i + (sin(q))*N.j
>>> express(N.x, B, variables=True)
B.x*cos(q) - B.y*sin(q)
>>> d = N.i.outer(N.i)
>>> express(d, B, N) == (cos(q))*(B.i|N.i) + (-sin(q))*(B.j|N.i)
True
"""
if expr == 0 or expr == Vector.zero:
return expr
if not isinstance(system, CoordSys3D):
raise TypeError("system should be a CoordSys3D \
instance")
if isinstance(expr, Vector):
if system2 is not None:
raise ValueError("system2 should not be provided for \
Vectors")
# Given expr is a Vector
if variables:
# If variables attribute is True, substitute
# the coordinate variables in the Vector
system_list = []
for x in expr.atoms(BaseScalar, BaseVector):
if x.system != system:
system_list.append(x.system)
system_list = set(system_list)
subs_dict = {}
for f in system_list:
subs_dict.update(f.scalar_map(system))
expr = expr.subs(subs_dict)
# Re-express in this coordinate system
outvec = Vector.zero
parts = expr.separate()
for x in parts:
if x != system:
temp = system.rotation_matrix(x) * parts[x].to_matrix(x)
outvec += matrix_to_vector(temp, system)
else:
outvec += parts[x]
return outvec
elif isinstance(expr, Dyadic):
if system2 is None:
system2 = system
if not isinstance(system2, CoordSys3D):
raise TypeError("system2 should be a CoordSys3D \
instance")
outdyad = Dyadic.zero
var = variables
for k, v in expr.components.items():
outdyad += (express(v, system, variables=var) *
(express(k.args[0], system, variables=var) |
express(k.args[1], system2, variables=var)))
return outdyad
else:
if system2 is not None:
raise ValueError("system2 should not be provided for \
Vectors")
if variables:
# Given expr is a scalar field
system_set = set()
expr = sympify(expr)
# Substitute all the coordinate variables
for x in expr.atoms(BaseScalar):
if x.system != system:
system_set.add(x.system)
subs_dict = {}
for f in system_set:
subs_dict.update(f.scalar_map(system))
return expr.subs(subs_dict)
return expr
def directional_derivative(field, direction_vector):
"""
Returns the directional derivative of a scalar or vector field computed
along a given vector in coordinate system which parameters are expressed.
Parameters
==========
field : Vector or Scalar
The scalar or vector field to compute the directional derivative of
direction_vector : Vector
The vector to calculated directional derivative along them.
Examples
========
>>> from sympy.vector import CoordSys3D, directional_derivative
>>> R = CoordSys3D('R')
>>> f1 = R.x*R.y*R.z
>>> v1 = 3*R.i + 4*R.j + R.k
>>> directional_derivative(f1, v1)
R.x*R.y + 4*R.x*R.z + 3*R.y*R.z
>>> f2 = 5*R.x**2*R.z
>>> directional_derivative(f2, v1)
5*R.x**2 + 30*R.x*R.z
"""
from sympy.vector.operators import _get_coord_sys_from_expr
coord_sys = _get_coord_sys_from_expr(field)
if len(coord_sys) > 0:
# TODO: This gets a random coordinate system in case of multiple ones:
coord_sys = next(iter(coord_sys))
field = express(field, coord_sys, variables=True)
i, j, k = coord_sys.base_vectors()
x, y, z = coord_sys.base_scalars()
out = Vector.dot(direction_vector, i) * diff(field, x)
out += Vector.dot(direction_vector, j) * diff(field, y)
out += Vector.dot(direction_vector, k) * diff(field, z)
if out == 0 and isinstance(field, Vector):
out = Vector.zero
return out
elif isinstance(field, Vector):
return Vector.zero
else:
return S.Zero
def laplacian(expr):
"""
Return the laplacian of the given field computed in terms of
the base scalars of the given coordinate system.
Parameters
==========
expr : SymPy Expr or Vector
expr denotes a scalar or vector field.
Examples
========
>>> from sympy.vector import CoordSys3D, laplacian
>>> R = CoordSys3D('R')
>>> f = R.x**2*R.y**5*R.z
>>> laplacian(f)
20*R.x**2*R.y**3*R.z + 2*R.y**5*R.z
>>> f = R.x**2*R.i + R.y**3*R.j + R.z**4*R.k
>>> laplacian(f)
2*R.i + 6*R.y*R.j + 12*R.z**2*R.k
"""
delop = Del()
if expr.is_Vector:
return (gradient(divergence(expr)) - curl(curl(expr))).doit()
return delop.dot(delop(expr)).doit()
def is_conservative(field):
"""
Checks if a field is conservative.
Parameters
==========
field : Vector
The field to check for conservative property
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy.vector import is_conservative
>>> R = CoordSys3D('R')
>>> is_conservative(R.y*R.z*R.i + R.x*R.z*R.j + R.x*R.y*R.k)
True
>>> is_conservative(R.z*R.j)
False
"""
# Field is conservative irrespective of system
# Take the first coordinate system in the result of the
# separate method of Vector
if not isinstance(field, Vector):
raise TypeError("field should be a Vector")
if field == Vector.zero:
return True
return curl(field).simplify() == Vector.zero
def is_solenoidal(field):
"""
Checks if a field is solenoidal.
Parameters
==========
field : Vector
The field to check for solenoidal property
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy.vector import is_solenoidal
>>> R = CoordSys3D('R')
>>> is_solenoidal(R.y*R.z*R.i + R.x*R.z*R.j + R.x*R.y*R.k)
True
>>> is_solenoidal(R.y * R.j)
False
"""
# Field is solenoidal irrespective of system
# Take the first coordinate system in the result of the
# separate method in Vector
if not isinstance(field, Vector):
raise TypeError("field should be a Vector")
if field == Vector.zero:
return True
return divergence(field).simplify() is S.Zero
def scalar_potential(field, coord_sys):
"""
Returns the scalar potential function of a field in a given
coordinate system (without the added integration constant).
Parameters
==========
field : Vector
The vector field whose scalar potential function is to be
calculated
coord_sys : CoordSys3D
The coordinate system to do the calculation in
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy.vector import scalar_potential, gradient
>>> R = CoordSys3D('R')
>>> scalar_potential(R.k, R) == R.z
True
>>> scalar_field = 2*R.x**2*R.y*R.z
>>> grad_field = gradient(scalar_field)
>>> scalar_potential(grad_field, R)
2*R.x**2*R.y*R.z
"""
# Check whether field is conservative
if not is_conservative(field):
raise ValueError("Field is not conservative")
if field == Vector.zero:
return S.Zero
# Express the field exntirely in coord_sys
# Substitute coordinate variables also
if not isinstance(coord_sys, CoordSys3D):
raise TypeError("coord_sys must be a CoordSys3D")
field = express(field, coord_sys, variables=True)
dimensions = coord_sys.base_vectors()
scalars = coord_sys.base_scalars()
# Calculate scalar potential function
temp_function = integrate(field.dot(dimensions[0]), scalars[0])
for i, dim in enumerate(dimensions[1:]):
partial_diff = diff(temp_function, scalars[i + 1])
partial_diff = field.dot(dim) - partial_diff
temp_function += integrate(partial_diff, scalars[i + 1])
return temp_function
def scalar_potential_difference(field, coord_sys, point1, point2):
"""
Returns the scalar potential difference between two points in a
certain coordinate system, wrt a given field.
If a scalar field is provided, its values at the two points are
considered. If a conservative vector field is provided, the values
of its scalar potential function at the two points are used.
Returns (potential at point2) - (potential at point1)
The position vectors of the two Points are calculated wrt the
origin of the coordinate system provided.
Parameters
==========
field : Vector/Expr
The field to calculate wrt
coord_sys : CoordSys3D
The coordinate system to do the calculations in
point1 : Point
The initial Point in given coordinate system
position2 : Point
The second Point in the given coordinate system
Examples
========
>>> from sympy.vector import CoordSys3D
>>> from sympy.vector import scalar_potential_difference
>>> R = CoordSys3D('R')
>>> P = R.origin.locate_new('P', R.x*R.i + R.y*R.j + R.z*R.k)
>>> vectfield = 4*R.x*R.y*R.i + 2*R.x**2*R.j
>>> scalar_potential_difference(vectfield, R, R.origin, P)
2*R.x**2*R.y
>>> Q = R.origin.locate_new('O', 3*R.i + R.j + 2*R.k)
>>> scalar_potential_difference(vectfield, R, P, Q)
-2*R.x**2*R.y + 18
"""
if not isinstance(coord_sys, CoordSys3D):
raise TypeError("coord_sys must be a CoordSys3D")
if isinstance(field, Vector):
# Get the scalar potential function
scalar_fn = scalar_potential(field, coord_sys)
else:
# Field is a scalar
scalar_fn = field
# Express positions in required coordinate system
origin = coord_sys.origin
position1 = express(point1.position_wrt(origin), coord_sys,
variables=True)
position2 = express(point2.position_wrt(origin), coord_sys,
variables=True)
# Get the two positions as substitution dicts for coordinate variables
subs_dict1 = {}
subs_dict2 = {}
scalars = coord_sys.base_scalars()
for i, x in enumerate(coord_sys.base_vectors()):
subs_dict1[scalars[i]] = x.dot(position1)
subs_dict2[scalars[i]] = x.dot(position2)
return scalar_fn.subs(subs_dict2) - scalar_fn.subs(subs_dict1)
def matrix_to_vector(matrix, system):
"""
Converts a vector in matrix form to a Vector instance.
It is assumed that the elements of the Matrix represent the
measure numbers of the components of the vector along basis
vectors of 'system'.
Parameters
==========
matrix : SymPy Matrix, Dimensions: (3, 1)
The matrix to be converted to a vector
system : CoordSys3D
The coordinate system the vector is to be defined in
Examples
========
>>> from sympy import ImmutableMatrix as Matrix
>>> m = Matrix([1, 2, 3])
>>> from sympy.vector import CoordSys3D, matrix_to_vector
>>> C = CoordSys3D('C')
>>> v = matrix_to_vector(m, C)
>>> v
C.i + 2*C.j + 3*C.k
>>> v.to_matrix(C) == m
True
"""
outvec = Vector.zero
vects = system.base_vectors()
for i, x in enumerate(matrix):
outvec += x * vects[i]
return outvec
def _path(from_object, to_object):
"""
Calculates the 'path' of objects starting from 'from_object'
to 'to_object', along with the index of the first common
ancestor in the tree.
Returns (index, list) tuple.
"""
if from_object._root != to_object._root:
raise ValueError("No connecting path found between " +
str(from_object) + " and " + str(to_object))
other_path = []
obj = to_object
while obj._parent is not None:
other_path.append(obj)
obj = obj._parent
other_path.append(obj)
object_set = set(other_path)
from_path = []
obj = from_object
while obj not in object_set:
from_path.append(obj)
obj = obj._parent
index = len(from_path)
i = other_path.index(obj)
while i >= 0:
from_path.append(other_path[i])
i -= 1
return index, from_path
def orthogonalize(*vlist, **kwargs):
"""
Takes a sequence of independent vectors and orthogonalizes them
using the Gram - Schmidt process. Returns a list of
orthogonal or orthonormal vectors.
Parameters
==========
vlist : sequence of independent vectors to be made orthogonal.
orthonormal : Optional parameter
Set to True if the vectors returned should be
orthonormal.
Default: False
Examples
========
>>> from sympy.vector.coordsysrect import CoordSys3D
>>> from sympy.vector.functions import orthogonalize
>>> C = CoordSys3D('C')
>>> i, j, k = C.base_vectors()
>>> v1 = i + 2*j
>>> v2 = 2*i + 3*j
>>> orthogonalize(v1, v2)
[C.i + 2*C.j, 2/5*C.i + (-1/5)*C.j]
References
==========
.. [1] https://en.wikipedia.org/wiki/Gram-Schmidt_process
"""
orthonormal = kwargs.get('orthonormal', False)
if not all(isinstance(vec, Vector) for vec in vlist):
raise TypeError('Each element must be of Type Vector')
ortho_vlist = []
for i, term in enumerate(vlist):
for j in range(i):
term -= ortho_vlist[j].projection(vlist[i])
# TODO : The following line introduces a performance issue
# and needs to be changed once a good solution for issue #10279 is
# found.
if simplify(term).equals(Vector.zero):
raise ValueError("Vector set not linearly independent")
ortho_vlist.append(term)
if orthonormal:
ortho_vlist = [vec.normalize() for vec in ortho_vlist]
return ortho_vlist
|
a07d5c0bfad600839dcc887a6d60f537a8e54a8574fb66560c31be6d0ee53bc6 | """Curves in 2-dimensional Euclidean space.
Contains
========
Curve
"""
from sympy import sqrt
from sympy.core import sympify, diff
from sympy.core.compatibility import is_sequence
from sympy.core.containers import Tuple
from sympy.core.symbol import _symbol
from sympy.geometry.entity import GeometryEntity, GeometrySet
from sympy.geometry.point import Point
from sympy.integrals import integrate
class Curve(GeometrySet):
"""A curve in space.
A curve is defined by parametric functions for the coordinates, a
parameter and the lower and upper bounds for the parameter value.
Parameters
==========
function : list of functions
limits : 3-tuple
Function parameter and lower and upper bounds.
Attributes
==========
functions
parameter
limits
Raises
======
ValueError
When `functions` are specified incorrectly.
When `limits` are specified incorrectly.
Examples
========
>>> from sympy import sin, cos, interpolate
>>> from sympy.abc import t, a
>>> from sympy.geometry import Curve
>>> C = Curve((sin(t), cos(t)), (t, 0, 2))
>>> C.functions
(sin(t), cos(t))
>>> C.limits
(t, 0, 2)
>>> C.parameter
t
>>> C = Curve((t, interpolate([1, 4, 9, 16], t)), (t, 0, 1)); C
Curve((t, t**2), (t, 0, 1))
>>> C.subs(t, 4)
Point2D(4, 16)
>>> C.arbitrary_point(a)
Point2D(a, a**2)
See Also
========
sympy.core.function.Function
sympy.polys.polyfuncs.interpolate
"""
def __new__(cls, function, limits):
fun = sympify(function)
if not is_sequence(fun) or len(fun) != 2:
raise ValueError("Function argument should be (x(t), y(t)) "
"but got %s" % str(function))
if not is_sequence(limits) or len(limits) != 3:
raise ValueError("Limit argument should be (t, tmin, tmax) "
"but got %s" % str(limits))
return GeometryEntity.__new__(cls, Tuple(*fun), Tuple(*limits))
def __call__(self, f):
return self.subs(self.parameter, f)
def _eval_subs(self, old, new):
if old == self.parameter:
return Point(*[f.subs(old, new) for f in self.functions])
def arbitrary_point(self, parameter='t'):
"""A parameterized point on the curve.
Parameters
==========
parameter : str or Symbol, optional
Default value is 't'.
The Curve's parameter is selected with None or self.parameter
otherwise the provided symbol is used.
Returns
=======
Point :
Returns a point in parametric form.
Raises
======
ValueError
When `parameter` already appears in the functions.
Examples
========
>>> from sympy import Symbol
>>> from sympy.abc import s
>>> from sympy.geometry import Curve
>>> C = Curve([2*s, s**2], (s, 0, 2))
>>> C.arbitrary_point()
Point2D(2*t, t**2)
>>> C.arbitrary_point(C.parameter)
Point2D(2*s, s**2)
>>> C.arbitrary_point(None)
Point2D(2*s, s**2)
>>> C.arbitrary_point(Symbol('a'))
Point2D(2*a, a**2)
See Also
========
sympy.geometry.point.Point
"""
if parameter is None:
return Point(*self.functions)
tnew = _symbol(parameter, self.parameter, real=True)
t = self.parameter
if (tnew.name != t.name and
tnew.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.' % tnew.name)
return Point(*[w.subs(t, tnew) for w in self.functions])
@property
def free_symbols(self):
"""Return a set of symbols other than the bound symbols used to
parametrically define the Curve.
Returns
=======
set :
Set of all non-parameterized symbols.
Examples
========
>>> from sympy.abc import t, a
>>> from sympy.geometry import Curve
>>> Curve((t, t**2), (t, 0, 2)).free_symbols
set()
>>> Curve((t, t**2), (t, a, 2)).free_symbols
{a}
"""
free = set()
for a in self.functions + self.limits[1:]:
free |= a.free_symbols
free = free.difference({self.parameter})
return free
@property
def ambient_dimension(self):
"""The dimension of the curve.
Returns
=======
int :
the dimension of curve.
Examples
========
>>> from sympy.abc import t
>>> from sympy.geometry import Curve
>>> C = Curve((t, t**2), (t, 0, 2))
>>> C.ambient_dimension
2
"""
return len(self.args[0])
@property
def functions(self):
"""The functions specifying the curve.
Returns
=======
functions :
list of parameterized coordinate functions.
Examples
========
>>> from sympy.abc import t
>>> from sympy.geometry import Curve
>>> C = Curve((t, t**2), (t, 0, 2))
>>> C.functions
(t, t**2)
See Also
========
parameter
"""
return self.args[0]
@property
def limits(self):
"""The limits for the curve.
Returns
=======
limits : tuple
Contains parameter and lower and upper limits.
Examples
========
>>> from sympy.abc import t
>>> from sympy.geometry import Curve
>>> C = Curve([t, t**3], (t, -2, 2))
>>> C.limits
(t, -2, 2)
See Also
========
plot_interval
"""
return self.args[1]
@property
def parameter(self):
"""The curve function variable.
Returns
=======
Symbol :
returns a bound symbol.
Examples
========
>>> from sympy.abc import t
>>> from sympy.geometry import Curve
>>> C = Curve([t, t**2], (t, 0, 2))
>>> C.parameter
t
See Also
========
functions
"""
return self.args[1][0]
@property
def length(self):
"""The curve length.
Examples
========
>>> from sympy.geometry.curve import Curve
>>> from sympy.abc import t
>>> Curve((t, t), (t, 0, 1)).length
sqrt(2)
"""
integrand = sqrt(sum(diff(func, self.limits[0])**2 for func in self.functions))
return integrate(integrand, self.limits)
def plot_interval(self, parameter='t'):
"""The plot interval for the default geometric plot of the curve.
Parameters
==========
parameter : str or Symbol, optional
Default value is 't';
otherwise the provided symbol is used.
Returns
=======
List :
the plot interval as below:
[parameter, lower_bound, upper_bound]
Examples
========
>>> from sympy import Curve, sin
>>> from sympy.abc import x, s
>>> Curve((x, sin(x)), (x, 1, 2)).plot_interval()
[t, 1, 2]
>>> Curve((x, sin(x)), (x, 1, 2)).plot_interval(s)
[s, 1, 2]
See Also
========
limits : Returns limits of the parameter interval
"""
t = _symbol(parameter, self.parameter, real=True)
return [t] + list(self.limits[1:])
def rotate(self, angle=0, pt=None):
"""This function is used to rotate a curve along given point ``pt`` at given angle(in radian).
Parameters
==========
angle :
the angle at which the curve will be rotated(in radian) in counterclockwise direction.
default value of angle is 0.
pt : Point
the point along which the curve will be rotated.
If no point given, the curve will be rotated around origin.
Returns
=======
Curve :
returns a curve rotated at given angle along given point.
Examples
========
>>> from sympy.geometry.curve import Curve
>>> from sympy.abc import x
>>> from sympy import pi
>>> Curve((x, x), (x, 0, 1)).rotate(pi/2)
Curve((-x, x), (x, 0, 1))
"""
from sympy.matrices import Matrix, rot_axis3
if pt:
pt = -Point(pt, dim=2)
else:
pt = Point(0,0)
rv = self.translate(*pt.args)
f = list(rv.functions)
f.append(0)
f = Matrix(1, 3, f)
f *= rot_axis3(angle)
rv = self.func(f[0, :2].tolist()[0], self.limits)
if pt is not None:
pt = -pt
return rv.translate(*pt.args)
return rv
def scale(self, x=1, y=1, pt=None):
"""Override GeometryEntity.scale since Curve is not made up of Points.
Returns
=======
Curve :
returns scaled curve.
Examples
========
>>> from sympy.geometry.curve import Curve
>>> from sympy.abc import x
>>> Curve((x, x), (x, 0, 1)).scale(2)
Curve((2*x, x), (x, 0, 1))
"""
if pt:
pt = Point(pt, dim=2)
return self.translate(*(-pt).args).scale(x, y).translate(*pt.args)
fx, fy = self.functions
return self.func((fx*x, fy*y), self.limits)
def translate(self, x=0, y=0):
"""Translate the Curve by (x, y).
Returns
=======
Curve :
returns a translated curve.
Examples
========
>>> from sympy.geometry.curve import Curve
>>> from sympy.abc import x
>>> Curve((x, x), (x, 0, 1)).translate(1, 2)
Curve((x + 1, x + 2), (x, 0, 1))
"""
fx, fy = self.functions
return self.func((fx + x, fy + y), self.limits)
|
7dc1a6d39df3bec5f23d99767a7799acb99b9ee55c9ae79cf3c0f8a33e480e0a | """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
"""
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.parameters import global_parameters
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_parameters.evaluate)
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({
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 __rmul__(self, factor):
"""Multiply a factor by point's coordinates."""
return self.__mul__(factor)
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])
# XXX fragile -- what is a better way?
return m.rank(iszerofunc = lambda x:
abs(x.n(2)) < 1e-12 if x.is_number else x.is_zero)
@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 : GeometryEntity or sequence of coordinates
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].is_zero:
return Point([1] + (dim - 1)*[0])
if self[1].is_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
========
translate, 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
========
sympy.geometry.point.Point2D.rotate
sympy.geometry.point.Point2D.scale
sympy.geometry.point.Point2D.translate
"""
if not (matrix.is_Matrix and matrix.shape == (3, 3)):
raise ValueError("matrix must be a 3x3 matrix")
col, row = matrix.shape
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
========
sympy.geometry.point.Point2D.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 coordinates(self):
"""
Returns the two coordinates of the Point.
Examples
========
>>> from sympy import Point2D
>>> p = Point2D(0, 1)
>>> p.coordinates
(0, 1)
"""
return self.args
@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
>>> 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 GeometryEntity.
Parameters
==========
other : GeometryEntity or sequence of coordinates
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
========
sympy.geometry.point.Point3D.scale
sympy.geometry.point.Point3D.translate
"""
if not (matrix.is_Matrix and matrix.shape == (4, 4)):
raise ValueError("matrix must be a 4x4 matrix")
col, row = matrix.shape
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
========
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 coordinates(self):
"""
Returns the three coordinates of the Point.
Examples
========
>>> from sympy import Point3D
>>> p = Point3D(0, 1, 2)
>>> p.coordinates
(0, 1, 2)
"""
return self.args
@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]
|
35fc914ea49fad28e761493b28da70b9b70aeda86511264411c45893183912fa | """Geometrical Planes.
Contains
========
Plane
"""
from sympy import simplify # type:ignore
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
>>> 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 Point3D, 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
"""
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 Point3D, 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
>>> 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_matrix:
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_matrix:
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
>>> 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
>>> 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, 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, 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 pi
>>> from sympy.geometry import Plane
>>> 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.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
|
dc09e7fbfd9ed43490cd457693f5a58a3488f2ad2a3203ee4f8ea7fb0a8fb3d6 | """Elliptical geometrical entities.
Contains
* Ellipse
* Circle
"""
from sympy import Expr, Eq
from sympy.core import S, pi, sympify
from sympy.core.parameters import global_parameters
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().__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 "{}" 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
>>> 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):
hit = self.intersection(o)
if not hit:
return False
if len(hit) == 1:
return True
# might return None if it can't decide
return hit[0].equals(hit[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 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 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 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
>>> 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), modify=lambda s: '_' + s, 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().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
def polar_second_moment_of_area(self):
"""Returns the polar second moment of area of an Ellipse
It is a constituent of the second moment of area, linked through
the perpendicular axis theorem. While the planar second moment of
area describes an object's resistance to deflection (bending) when
subjected to a force applied to a plane parallel to the central
axis, the polar second moment of area describes an object's
resistance to deflection when subjected to a moment applied in a
plane perpendicular to the object's central axis (i.e. parallel to
the cross-section)
References
==========
https://en.wikipedia.org/wiki/Polar_moment_of_inertia
Examples
========
>>> from sympy import symbols, Circle, Ellipse
>>> c = Circle((5, 5), 4)
>>> c.polar_second_moment_of_area()
128*pi
>>> a, b = symbols('a, b')
>>> e = Ellipse((0, 0), a, b)
>>> e.polar_second_moment_of_area()
pi*a**3*b/4 + pi*a*b**3/4
"""
second_moment = self.second_moment_of_area()
return second_moment[0] + second_moment[1]
def section_modulus(self, point=None):
"""Returns a tuple with the section modulus of an ellipse
Section modulus is a geometric property of an ellipse defined as the
ratio of second moment of area to the distance of the extreme end of
the ellipse from the centroidal axis.
References
==========
https://en.wikipedia.org/wiki/Section_modulus
Parameters
==========
point : Point, two-tuple of sympifyable objects, or None(default=None)
point is the point at which section modulus is to be found.
If "point=None" section modulus will be calculated for the
point farthest from the centroidal axis of the ellipse.
Returns
=======
S_x, S_y: numbers or SymPy expressions
S_x is the section modulus with respect to the x-axis
S_y is the section modulus with respect to the y-axis
A negetive sign indicates that the section modulus is
determined for a point below the centroidal axis.
Examples
========
>>> from sympy import Symbol, Ellipse, Circle, Point2D
>>> d = Symbol('d', positive=True)
>>> c = Circle((0, 0), d/2)
>>> c.section_modulus()
(pi*d**3/32, pi*d**3/32)
>>> e = Ellipse(Point2D(0, 0), 2, 4)
>>> e.section_modulus()
(8*pi, 4*pi)
>>> e.section_modulus((2, 2))
(16*pi, 4*pi)
"""
x_c, y_c = self.center
if point is None:
# taking x and y as maximum distances from centroid
x_min, y_min, x_max, y_max = self.bounds
y = max(y_c - y_min, y_max - y_c)
x = max(x_c - x_min, x_max - x_c)
else:
# taking x and y as distances of the given point from the center
point = Point2D(point)
y = point.y - y_c
x = point.x - x_c
second_moment = self.second_moment_of_area()
S_x = second_moment[0]/y
S_y = second_moment[1]/x
return S_x, S_y
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_parameters.evaluate)
if len(args) == 1 and isinstance(args[0], (Expr, Eq)):
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 ValueError:
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
|
93584ac3f0a1bf38ed76e36c61a0393473b863bd56d58f7c8a125d51be139533 | """Utility functions for geometrical entities.
Contains
========
intersection
convex_hull
closest_points
farthest_points
are_coplanar
are_similar
"""
from sympy import Function, Symbol, solve, sqrt
from sympy.core.compatibility import (
is_sequence, ordered)
from sympy.core.containers import OrderedSet
from .point import Point, Point2D
def find(x, equation):
"""
Checks whether the parameter 'x' is present in 'equation' or not.
If it is present then it returns the passed parameter 'x' as a free
symbol, else, it returns a ValueError.
"""
free = equation.free_symbols
xs = [i for i in free if (i.name if isinstance(x, str) else i) == x]
if not xs:
raise ValueError('could not find %s' % x)
if len(xs) != 1:
raise ValueError('ambiguous %s' % x)
return xs[0]
def _ordered_points(p):
"""Return the tuple of points sorted numerically according to args"""
return tuple(sorted(p, key=lambda x: x.args))
def are_coplanar(*e):
""" Returns True if the given entities are coplanar otherwise False
Parameters
==========
e: entities to be checked for being coplanar
Returns
=======
Boolean
Examples
========
>>> from sympy import Point3D, Line3D
>>> from sympy.geometry.util import are_coplanar
>>> a = Line3D(Point3D(5, 0, 0), Point3D(1, -1, 1))
>>> b = Line3D(Point3D(0, -2, 0), Point3D(3, 1, 1))
>>> c = Line3D(Point3D(0, -1, 0), Point3D(5, -1, 9))
>>> are_coplanar(a, b, c)
False
"""
from sympy.geometry.line import LinearEntity3D
from sympy.geometry.entity import GeometryEntity
from sympy.geometry.point import Point3D
from sympy.geometry.plane import Plane
# XXX update tests for coverage
e = set(e)
# first work with a Plane if present
for i in list(e):
if isinstance(i, Plane):
e.remove(i)
return all(p.is_coplanar(i) for p in e)
if all(isinstance(i, Point3D) for i in e):
if len(e) < 3:
return False
# remove pts that are collinear with 2 pts
a, b = e.pop(), e.pop()
for i in list(e):
if Point3D.are_collinear(a, b, i):
e.remove(i)
if not e:
return False
else:
# define a plane
p = Plane(a, b, e.pop())
for i in e:
if i not in p:
return False
return True
else:
pt3d = []
for i in e:
if isinstance(i, Point3D):
pt3d.append(i)
elif isinstance(i, LinearEntity3D):
pt3d.extend(i.args)
elif isinstance(i, GeometryEntity): # XXX we should have a GeometryEntity3D class so we can tell the difference between 2D and 3D -- here we just want to deal with 2D objects; if new 3D objects are encountered that we didn't handle above, an error should be raised
# all 2D objects have some Point that defines them; so convert those points to 3D pts by making z=0
for p in i.args:
if isinstance(p, Point):
pt3d.append(Point3D(*(p.args + (0,))))
return are_coplanar(*pt3d)
def are_similar(e1, e2):
"""Are two geometrical entities similar.
Can one geometrical entity be uniformly scaled to the other?
Parameters
==========
e1 : GeometryEntity
e2 : GeometryEntity
Returns
=======
are_similar : boolean
Raises
======
GeometryError
When `e1` and `e2` cannot be compared.
Notes
=====
If the two objects are equal then they are similar.
See Also
========
sympy.geometry.entity.GeometryEntity.is_similar
Examples
========
>>> from sympy import Point, Circle, Triangle, are_similar
>>> c1, c2 = Circle(Point(0, 0), 4), Circle(Point(1, 4), 3)
>>> t1 = Triangle(Point(0, 0), Point(1, 0), Point(0, 1))
>>> t2 = Triangle(Point(0, 0), Point(2, 0), Point(0, 2))
>>> t3 = Triangle(Point(0, 0), Point(3, 0), Point(0, 1))
>>> are_similar(t1, t2)
True
>>> are_similar(t1, t3)
False
"""
from .exceptions import GeometryError
if e1 == e2:
return True
is_similar1 = getattr(e1, 'is_similar', None)
if is_similar1:
return is_similar1(e2)
is_similar2 = getattr(e2, 'is_similar', None)
if is_similar2:
return is_similar2(e1)
n1 = e1.__class__.__name__
n2 = e2.__class__.__name__
raise GeometryError(
"Cannot test similarity between %s and %s" % (n1, n2))
def centroid(*args):
"""Find the centroid (center of mass) of the collection containing only Points,
Segments or Polygons. The centroid is the weighted average of the individual centroid
where the weights are the lengths (of segments) or areas (of polygons).
Overlapping regions will add to the weight of that region.
If there are no objects (or a mixture of objects) then None is returned.
See Also
========
sympy.geometry.point.Point, sympy.geometry.line.Segment,
sympy.geometry.polygon.Polygon
Examples
========
>>> from sympy import Point, Segment, Polygon
>>> from sympy.geometry.util import centroid
>>> p = Polygon((0, 0), (10, 0), (10, 10))
>>> q = p.translate(0, 20)
>>> p.centroid, q.centroid
(Point2D(20/3, 10/3), Point2D(20/3, 70/3))
>>> centroid(p, q)
Point2D(20/3, 40/3)
>>> p, q = Segment((0, 0), (2, 0)), Segment((0, 0), (2, 2))
>>> centroid(p, q)
Point2D(1, 2 - sqrt(2))
>>> centroid(Point(0, 0), Point(2, 0))
Point2D(1, 0)
Stacking 3 polygons on top of each other effectively triples the
weight of that polygon:
>>> p = Polygon((0, 0), (1, 0), (1, 1), (0, 1))
>>> q = Polygon((1, 0), (3, 0), (3, 1), (1, 1))
>>> centroid(p, q)
Point2D(3/2, 1/2)
>>> centroid(p, p, p, q) # centroid x-coord shifts left
Point2D(11/10, 1/2)
Stacking the squares vertically above and below p has the same
effect:
>>> centroid(p, p.translate(0, 1), p.translate(0, -1), q)
Point2D(11/10, 1/2)
"""
from sympy.geometry import Polygon, Segment, Point
if args:
if all(isinstance(g, Point) for g in args):
c = Point(0, 0)
for g in args:
c += g
den = len(args)
elif all(isinstance(g, Segment) for g in args):
c = Point(0, 0)
L = 0
for g in args:
l = g.length
c += g.midpoint*l
L += l
den = L
elif all(isinstance(g, Polygon) for g in args):
c = Point(0, 0)
A = 0
for g in args:
a = g.area
c += g.centroid*a
A += a
den = A
c /= den
return c.func(*[i.simplify() for i in c.args])
def closest_points(*args):
"""Return the subset of points from a set of points that were
the closest to each other in the 2D plane.
Parameters
==========
args : a collection of Points on 2D plane.
Notes
=====
This can only be performed on a set of points whose coordinates can
be ordered on the number line. If there are no ties then a single
pair of Points will be in the set.
References
==========
[1] http://www.cs.mcgill.ca/~cs251/ClosestPair/ClosestPairPS.html
[2] Sweep line algorithm
https://en.wikipedia.org/wiki/Sweep_line_algorithm
Examples
========
>>> from sympy.geometry import closest_points, Triangle
>>> Triangle(sss=(3, 4, 5)).args
(Point2D(0, 0), Point2D(3, 0), Point2D(3, 4))
>>> closest_points(*_)
{(Point2D(0, 0), Point2D(3, 0))}
"""
from collections import deque
from math import sqrt as _sqrt
from sympy.functions.elementary.miscellaneous import sqrt
p = [Point2D(i) for i in set(args)]
if len(p) < 2:
raise ValueError('At least 2 distinct points must be given.')
try:
p.sort(key=lambda x: x.args)
except TypeError:
raise ValueError("The points could not be sorted.")
if any(not i.is_Rational for j in p for i in j.args):
def hypot(x, y):
arg = x*x + y*y
if arg.is_Rational:
return _sqrt(arg)
return sqrt(arg)
else:
from math import hypot
rv = [(0, 1)]
best_dist = hypot(p[1].x - p[0].x, p[1].y - p[0].y)
i = 2
left = 0
box = deque([0, 1])
while i < len(p):
while left < i and p[i][0] - p[left][0] > best_dist:
box.popleft()
left += 1
for j in box:
d = hypot(p[i].x - p[j].x, p[i].y - p[j].y)
if d < best_dist:
rv = [(j, i)]
elif d == best_dist:
rv.append((j, i))
else:
continue
best_dist = d
box.append(i)
i += 1
return {tuple([p[i] for i in pair]) for pair in rv}
def convex_hull(*args, polygon=True):
"""The convex hull surrounding the Points contained in the list of entities.
Parameters
==========
args : a collection of Points, Segments and/or Polygons
Optional parameters
===================
polygon : Boolean. If True, returns a Polygon, if false a tuple, see below.
Default is True.
Returns
=======
convex_hull : Polygon if ``polygon`` is True else as a tuple `(U, L)` where
``L`` and ``U`` are the lower and upper hulls, respectively.
Notes
=====
This can only be performed on a set of points whose coordinates can
be ordered on the number line.
References
==========
[1] https://en.wikipedia.org/wiki/Graham_scan
[2] Andrew's Monotone Chain Algorithm
(A.M. Andrew,
"Another Efficient Algorithm for Convex Hulls in Two Dimensions", 1979)
http://geomalgorithms.com/a10-_hull-1.html
See Also
========
sympy.geometry.point.Point, sympy.geometry.polygon.Polygon
Examples
========
>>> from sympy.geometry import convex_hull
>>> points = [(1, 1), (1, 2), (3, 1), (-5, 2), (15, 4)]
>>> convex_hull(*points)
Polygon(Point2D(-5, 2), Point2D(1, 1), Point2D(3, 1), Point2D(15, 4))
>>> convex_hull(*points, **dict(polygon=False))
([Point2D(-5, 2), Point2D(15, 4)],
[Point2D(-5, 2), Point2D(1, 1), Point2D(3, 1), Point2D(15, 4)])
"""
from .entity import GeometryEntity
from .point import Point
from .line import Segment
from .polygon import Polygon
p = OrderedSet()
for e in args:
if not isinstance(e, GeometryEntity):
try:
e = Point(e)
except NotImplementedError:
raise ValueError('%s is not a GeometryEntity and cannot be made into Point' % str(e))
if isinstance(e, Point):
p.add(e)
elif isinstance(e, Segment):
p.update(e.points)
elif isinstance(e, Polygon):
p.update(e.vertices)
else:
raise NotImplementedError(
'Convex hull for %s not implemented.' % type(e))
# make sure all our points are of the same dimension
if any(len(x) != 2 for x in p):
raise ValueError('Can only compute the convex hull in two dimensions')
p = list(p)
if len(p) == 1:
return p[0] if polygon else (p[0], None)
elif len(p) == 2:
s = Segment(p[0], p[1])
return s if polygon else (s, None)
def _orientation(p, q, r):
'''Return positive if p-q-r are clockwise, neg if ccw, zero if
collinear.'''
return (q.y - p.y)*(r.x - p.x) - (q.x - p.x)*(r.y - p.y)
# scan to find upper and lower convex hulls of a set of 2d points.
U = []
L = []
try:
p.sort(key=lambda x: x.args)
except TypeError:
raise ValueError("The points could not be sorted.")
for p_i in p:
while len(U) > 1 and _orientation(U[-2], U[-1], p_i) <= 0:
U.pop()
while len(L) > 1 and _orientation(L[-2], L[-1], p_i) >= 0:
L.pop()
U.append(p_i)
L.append(p_i)
U.reverse()
convexHull = tuple(L + U[1:-1])
if len(convexHull) == 2:
s = Segment(convexHull[0], convexHull[1])
return s if polygon else (s, None)
if polygon:
return Polygon(*convexHull)
else:
U.reverse()
return (U, L)
def farthest_points(*args):
"""Return the subset of points from a set of points that were
the furthest apart from each other in the 2D plane.
Parameters
==========
args : a collection of Points on 2D plane.
Notes
=====
This can only be performed on a set of points whose coordinates can
be ordered on the number line. If there are no ties then a single
pair of Points will be in the set.
References
==========
[1] http://code.activestate.com/recipes/117225-convex-hull-and-diameter-of-2d-point-sets/
[2] Rotating Callipers Technique
https://en.wikipedia.org/wiki/Rotating_calipers
Examples
========
>>> from sympy.geometry import farthest_points, Triangle
>>> Triangle(sss=(3, 4, 5)).args
(Point2D(0, 0), Point2D(3, 0), Point2D(3, 4))
>>> farthest_points(*_)
{(Point2D(0, 0), Point2D(3, 4))}
"""
from math import sqrt as _sqrt
def rotatingCalipers(Points):
U, L = convex_hull(*Points, **dict(polygon=False))
if L is None:
if isinstance(U, Point):
raise ValueError('At least two distinct points must be given.')
yield U.args
else:
i = 0
j = len(L) - 1
while i < len(U) - 1 or j > 0:
yield U[i], L[j]
# if all the way through one side of hull, advance the other side
if i == len(U) - 1:
j -= 1
elif j == 0:
i += 1
# still points left on both lists, compare slopes of next hull edges
# being careful to avoid divide-by-zero in slope calculation
elif (U[i+1].y - U[i].y) * (L[j].x - L[j-1].x) > \
(L[j].y - L[j-1].y) * (U[i+1].x - U[i].x):
i += 1
else:
j -= 1
p = [Point2D(i) for i in set(args)]
if any(not i.is_Rational for j in p for i in j.args):
def hypot(x, y):
arg = x*x + y*y
if arg.is_Rational:
return _sqrt(arg)
return sqrt(arg)
else:
from math import hypot
rv = []
diam = 0
for pair in rotatingCalipers(args):
h, q = _ordered_points(pair)
d = hypot(h.x - q.x, h.y - q.y)
if d > diam:
rv = [(h, q)]
elif d == diam:
rv.append((h, q))
else:
continue
diam = d
return set(rv)
def idiff(eq, y, x, n=1):
"""Return ``dy/dx`` assuming that ``eq == 0``.
Parameters
==========
y : the dependent variable or a list of dependent variables (with y first)
x : the variable that the derivative is being taken with respect to
n : the order of the derivative (default is 1)
Examples
========
>>> from sympy.abc import x, y, a
>>> from sympy.geometry.util import idiff
>>> circ = x**2 + y**2 - 4
>>> idiff(circ, y, x)
-x/y
>>> idiff(circ, y, x, 2).simplify()
-(x**2 + y**2)/y**3
Here, ``a`` is assumed to be independent of ``x``:
>>> idiff(x + a + y, y, x)
-1
Now the x-dependence of ``a`` is made explicit by listing ``a`` after
``y`` in a list.
>>> idiff(x + a + y, [y, a], x)
-Derivative(a, x) - 1
See Also
========
sympy.core.function.Derivative: represents unevaluated derivatives
sympy.core.function.diff: explicitly differentiates wrt symbols
"""
if is_sequence(y):
dep = set(y)
y = y[0]
elif isinstance(y, Symbol):
dep = {y}
elif isinstance(y, Function):
pass
else:
raise ValueError("expecting x-dependent symbol(s) or function(s) but got: %s" % y)
f = {s: Function(s.name)(x) for s in eq.free_symbols
if s != x and s in dep}
if isinstance(y, Symbol):
dydx = Function(y.name)(x).diff(x)
else:
dydx = y.diff(x)
eq = eq.subs(f)
derivs = {}
for i in range(n):
yp = solve(eq.diff(x), dydx)[0].subs(derivs)
if i == n - 1:
return yp.subs([(v, k) for k, v in f.items()])
derivs[dydx] = yp
eq = dydx - yp
dydx = dydx.diff(x)
def intersection(*entities, **kwargs):
"""The intersection of a collection of GeometryEntity instances.
Parameters
==========
entities : sequence of GeometryEntity
pairwise (keyword argument) : Can be either True or False
Returns
=======
intersection : list of GeometryEntity
Raises
======
NotImplementedError
When unable to calculate intersection.
Notes
=====
The intersection of any geometrical entity with itself should return
a list with one item: the entity in question.
An intersection requires two or more entities. If only a single
entity is given then the function will return an empty list.
It is possible for `intersection` to miss intersections that one
knows exists because the required quantities were not fully
simplified internally.
Reals should be converted to Rationals, e.g. Rational(str(real_num))
or else failures due to floating point issues may result.
Case 1: When the keyword argument 'pairwise' is False (default value):
In this case, the function returns a list of intersections common to
all entities.
Case 2: When the keyword argument 'pairwise' is True:
In this case, the functions returns a list intersections that occur
between any pair of entities.
See Also
========
sympy.geometry.entity.GeometryEntity.intersection
Examples
========
>>> from sympy.geometry import Ray, Circle, intersection
>>> c = Circle((0, 1), 1)
>>> intersection(c, c.center)
[]
>>> right = Ray((0, 0), (1, 0))
>>> up = Ray((0, 0), (0, 1))
>>> intersection(c, right, up)
[Point2D(0, 0)]
>>> intersection(c, right, up, pairwise=True)
[Point2D(0, 0), Point2D(0, 2)]
>>> left = Ray((1, 0), (0, 0))
>>> intersection(right, left)
[Segment2D(Point2D(0, 0), Point2D(1, 0))]
"""
from .entity import GeometryEntity
from .point import Point
pairwise = kwargs.pop('pairwise', False)
if len(entities) <= 1:
return []
# entities may be an immutable tuple
entities = list(entities)
for i, e in enumerate(entities):
if not isinstance(e, GeometryEntity):
entities[i] = Point(e)
if not pairwise:
# find the intersection common to all objects
res = entities[0].intersection(entities[1])
for entity in entities[2:]:
newres = []
for x in res:
newres.extend(x.intersection(entity))
res = newres
return res
# find all pairwise intersections
ans = []
for j in range(0, len(entities)):
for k in range(j + 1, len(entities)):
ans.extend(intersection(entities[j], entities[k]))
return list(ordered(set(ans)))
|
8d76770b8ff92e17ade859ef036fa443913023ab02c4814dd799876218e30715 | """Line-like geometrical entities.
Contains
========
LinearEntity
Line
Ray
Segment
LinearEntity2D
Line2D
Ray2D
Segment2D
LinearEntity3D
Line3D
Ray3D
Segment3D
"""
from sympy import Expr
from sympy.core import S, sympify
from sympy.core.compatibility import ordered
from sympy.core.containers import Tuple
from sympy.core.decorators import deprecated
from sympy.core.numbers import Rational, oo
from sympy.core.relational import Eq
from sympy.core.symbol import _symbol, Dummy
from sympy.functions.elementary.piecewise import Piecewise
from sympy.functions.elementary.trigonometric import (_pi_coeff as pi_coeff, acos, tan, atan2)
from sympy.geometry.exceptions import GeometryError
from sympy.geometry.util import intersection
from sympy.logic.boolalg import And
from sympy.matrices import Matrix
from sympy.sets import Intersection
from sympy.simplify.simplify import simplify
from sympy.solvers.solveset import linear_coeffs
from sympy.utilities.exceptions import SymPyDeprecationWarning
from sympy.utilities.misc import Undecidable, filldedent
from .entity import GeometryEntity, GeometrySet
from .point import Point, Point3D
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 Line
>>> 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
>>> 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
>>> 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
========
sympy.geometry.line.LinearEntity.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))
def bisectors(self, other):
"""Returns the perpendicular lines which pass through the intersections
of self and other that are in the same plane.
Parameters
==========
line : Line3D
Returns
=======
list: two Line instances
Examples
========
>>> from sympy.geometry import Point3D, Line3D
>>> r1 = Line3D(Point3D(0, 0, 0), Point3D(1, 0, 0))
>>> r2 = Line3D(Point3D(0, 0, 0), Point3D(0, 1, 0))
>>> r1.bisectors(r2)
[Line3D(Point3D(0, 0, 0), Point3D(1, 1, 0)), Line3D(Point3D(0, 0, 0), Point3D(1, -1, 0))]
"""
if not isinstance(other, LinearEntity):
raise GeometryError("Expecting LinearEntity, not %s" % other)
l1, l2 = self, other
# make sure dimensions match or else a warning will rise from
# intersection calculation
if l1.p1.ambient_dimension != l2.p1.ambient_dimension:
if isinstance(l1, Line2D):
l1, l2 = l2, l1
_, p1 = Point._normalize_dimension(l1.p1, l2.p1, on_morph='ignore')
_, p2 = Point._normalize_dimension(l1.p2, l2.p2, on_morph='ignore')
l2 = Line(p1, p2)
point = intersection(l1, l2)
# Three cases: Lines may intersect in a point, may be equal or may not intersect.
if not point:
raise GeometryError("The lines do not intersect")
else:
pt = point[0]
if isinstance(pt, Line):
# Intersection is a line because both lines are coincident
return [self]
d1 = l1.direction.unit
d2 = l2.direction.unit
bis1 = Line(pt, pt + d1 + d2)
bis2 = Line(pt, pt + d1 - d2)
return [bis1, bis2]
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, Eq)):
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, 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 = ["{},{}".format(p.x, p.y) for p in verts]
path = "M {} L {}".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
========
sympy.geometry.line.LinearEntity.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.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 = ["{},{}".format(p.x, p.y) for p in verts]
path = "M {} L {}".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.Line2D.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
========
sympy.geometry.line.Line2D.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 = ["{},{}".format(p.x, p.y) for p in verts]
path = "M {} L {}".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.Line3D.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.Line3D.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
>>> 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
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)
|
00b65f6c39f515324779dd0761659d71478d1edb3362fedb64aa07e70e61d493 | from sympy.core import Expr, S, Symbol, oo, pi, sympify
from sympy.core.compatibility import as_int, ordered
from sympy.core.symbol import _symbol, Dummy, symbols
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
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
Optional parameters
==========
n : If > 0, an n-sided RegularPolygon is created. See below.
Default value is 0.
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 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, n = 0, **kwargs):
if 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 sympifyable 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 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.vertices
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
def first_moment_of_area(self, point=None):
"""
Returns the first moment of area of a two-dimensional polygon with
respect to a certain point of interest.
First moment of area is a measure of the distribution of the area
of a polygon in relation to an axis. The first moment of area of
the entire polygon about its own centroid is always zero. Therefore,
here it is calculated for an area, above or below a certain point
of interest, that makes up a smaller portion of the polygon. This
area is bounded by the point of interest and the extreme end
(top or bottom) of the polygon. The first moment for this area is
is then determined about the centroidal axis of the initial polygon.
References
==========
https://skyciv.com/docs/tutorials/section-tutorials/calculating-the-statical-or-first-moment-of-area-of-beam-sections/?cc=BMD
https://mechanicalc.com/reference/cross-sections
Parameters
==========
point: Point, two-tuple of sympifyable objects, or None (default=None)
point is the point above or below which the area of interest lies
If ``point=None`` then the centroid acts as the point of interest.
Returns
=======
Q_x, Q_y: number or sympy expressions
Q_x is the first moment of area about the x-axis
Q_y is the first moment of area about the y-axis
A negative sign indicates that the section modulus is
determined for a section below (or left of) the centroidal axis
Examples
========
>>> from sympy import Point, Polygon
>>> a, b = 50, 10
>>> p1, p2, p3, p4 = [(0, b), (0, 0), (a, 0), (a, b)]
>>> p = Polygon(p1, p2, p3, p4)
>>> p.first_moment_of_area()
(625, 3125)
>>> p.first_moment_of_area(point=Point(30, 7))
(525, 3000)
"""
if point:
xc, yc = self.centroid
else:
point = self.centroid
xc, yc = point
h_line = Line(point, slope=0)
v_line = Line(point, slope=S.Infinity)
h_poly = self.cut_section(h_line)
v_poly = self.cut_section(v_line)
x_min, y_min, x_max, y_max = self.bounds
poly_1 = h_poly[0] if h_poly[0].area <= h_poly[1].area else h_poly[1]
poly_2 = v_poly[0] if v_poly[0].area <= v_poly[1].area else v_poly[1]
Q_x = (poly_1.centroid.y - yc)*poly_1.area
Q_y = (poly_2.centroid.x - xc)*poly_2.area
return Q_x, Q_y
def polar_second_moment_of_area(self):
"""Returns the polar modulus of a two-dimensional polygon
It is a constituent of the second moment of area, linked through
the perpendicular axis theorem. While the planar second moment of
area describes an object's resistance to deflection (bending) when
subjected to a force applied to a plane parallel to the central
axis, the polar second moment of area describes an object's
resistance to deflection when subjected to a moment applied in a
plane perpendicular to the object's central axis (i.e. parallel to
the cross-section)
References
==========
https://en.wikipedia.org/wiki/Polar_moment_of_inertia
Examples
========
>>> from sympy import Polygon, symbols
>>> a, b = symbols('a, b')
>>> rectangle = Polygon((0, 0), (a, 0), (a, b), (0, b))
>>> rectangle.polar_second_moment_of_area()
a**3*b/12 + a*b**3/12
"""
second_moment = self.second_moment_of_area()
return second_moment[0] + second_moment[1]
def section_modulus(self, point=None):
"""Returns a tuple with the section modulus of a two-dimensional
polygon.
Section modulus is a geometric property of a polygon defined as the
ratio of second moment of area to the distance of the extreme end of
the polygon from the centroidal axis.
References
==========
https://en.wikipedia.org/wiki/Section_modulus
Parameters
==========
point : Point, two-tuple of sympifyable objects, or None(default=None)
point is the point at which section modulus is to be found.
If "point=None" it will be calculated for the point farthest from the
centroidal axis of the polygon.
Returns
=======
S_x, S_y: numbers or SymPy expressions
S_x is the section modulus with respect to the x-axis
S_y is the section modulus with respect to the y-axis
A negative sign indicates that the section modulus is
determined for a point below the centroidal axis
Examples
========
>>> from sympy import symbols, Polygon, Point
>>> a, b = symbols('a, b', positive=True)
>>> rectangle = Polygon((0, 0), (a, 0), (a, b), (0, b))
>>> rectangle.section_modulus()
(a*b**2/6, a**2*b/6)
>>> rectangle.section_modulus(Point(a/4, b/4))
(-a*b**2/3, -a**2*b/3)
"""
x_c, y_c = self.centroid
if point is None:
# taking x and y as maximum distances from centroid
x_min, y_min, x_max, y_max = self.bounds
y = max(y_c - y_min, y_max - y_c)
x = max(x_c - x_min, x_max - x_c)
else:
# taking x and y as distances of the given point from the centroid
y = point.y - y_c
x = point.x - x_c
second_moment= self.second_moment_of_area()
S_x = second_moment[0]/y
S_y = second_moment[1]/x
return S_x, S_y
@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
>>> 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, 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 cut_section(self, line):
"""
Returns a tuple of two polygon segments that lie above and below
the intersecting line respectively.
Parameters
==========
line: Line object of geometry module
line which cuts the Polygon. The part of the Polygon that lies
above and below this line is returned.
Returns
=======
upper_polygon, lower_polygon: Polygon objects or None
upper_polygon is the polygon that lies above the given line.
lower_polygon is the polygon that lies below the given line.
upper_polygon and lower polygon are ``None`` when no polygon
exists above the line or below the line.
Raises
======
ValueError: When the line does not intersect the polygon
References
==========
https://github.com/sympy/sympy/wiki/A-method-to-return-a-cut-section-of-any-polygon-geometry
Examples
========
>>> from sympy import Polygon, Line
>>> a, b = 20, 10
>>> p1, p2, p3, p4 = [(0, b), (0, 0), (a, 0), (a, b)]
>>> rectangle = Polygon(p1, p2, p3, p4)
>>> t = rectangle.cut_section(Line((0, 5), slope=0))
>>> t
(Polygon(Point2D(0, 10), Point2D(0, 5), Point2D(20, 5), Point2D(20, 10)),
Polygon(Point2D(0, 5), Point2D(0, 0), Point2D(20, 0), Point2D(20, 5)))
>>> upper_segment, lower_segment = t
>>> upper_segment.area
100
>>> upper_segment.centroid
Point2D(10, 15/2)
>>> lower_segment.centroid
Point2D(10, 5/2)
"""
intersection_points = self.intersection(line)
if not intersection_points:
raise ValueError("This line does not intersect the polygon")
points = list(self.vertices)
points.append(points[0])
x, y = symbols('x, y', real=True, cls=Dummy)
eq = line.equation(x, y)
# considering equation of line to be `ax +by + c`
a = eq.coeff(x)
b = eq.coeff(y)
upper_vertices = []
lower_vertices = []
# prev is true when previous point is above the line
prev = True
prev_point = None
for point in points:
# when coefficient of y is 0, right side of the line is
# considered
compare = eq.subs({x: point.x, y: point.y})/b if b \
else eq.subs(x, point.x)/a
# if point lies above line
if compare > 0:
if not prev:
# if previous point lies below the line, the intersection
# point of the polygon egde and the line has to be included
edge = Line(point, prev_point)
new_point = edge.intersection(line)
upper_vertices.append(new_point[0])
lower_vertices.append(new_point[0])
upper_vertices.append(point)
prev = True
else:
if prev and prev_point:
edge = Line(point, prev_point)
new_point = edge.intersection(line)
upper_vertices.append(new_point[0])
lower_vertices.append(new_point[0])
lower_vertices.append(point)
prev = False
prev_point = point
upper_polygon, lower_polygon = None, None
if upper_vertices and isinstance(Polygon(*upper_vertices), Polygon):
upper_polygon = Polygon(*upper_vertices)
if lower_vertices and isinstance(Polygon(*lower_vertices), Polygon):
lower_polygon = Polygon(*lower_vertices)
return upper_polygon, lower_polygon
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 = ["{},{}".format(p.x, p.y) for p in verts]
path = "M {} L {} 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
def bisectors(p, prec=None):
"""Returns angle bisectors of a polygon. If prec is given
then approximate the point defining the ray to that precision.
The distance between the points defining the bisector ray is 1.
Examples
========
>>> from sympy import Polygon, Point
>>> p = Polygon(Point(0, 0), Point(2, 0), Point(1, 1), Point(0, 3))
>>> p.bisectors(2)
{Point2D(0, 0): Ray2D(Point2D(0, 0), Point2D(0.71, 0.71)),
Point2D(0, 3): Ray2D(Point2D(0, 3), Point2D(0.23, 2.0)),
Point2D(1, 1): Ray2D(Point2D(1, 1), Point2D(0.19, 0.42)),
Point2D(2, 0): Ray2D(Point2D(2, 0), Point2D(1.1, 0.38))}
"""
b = {}
pts = list(p.args)
pts.append(pts[0]) # close it
cw = Polygon._isright(*pts[:3])
if cw:
pts = list(reversed(pts))
for v, a in p.angles.items():
i = pts.index(v)
p1, p2 = Point._normalize_dimension(pts[i], pts[i + 1])
ray = Ray(p1, p2).rotate(a/2, v)
dir = ray.direction
ray = Ray(ray.p1, ray.p1 + dir/dir.distance((0, 0)))
if prec is not None:
ray = Ray(ray.p1, ray.p2.n(prec))
b[v] = ray
return b
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, 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().__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
>>> 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 excenters(self):
"""Excenters of the triangle.
An excenter is the center of a circle that is tangent to a side of the
triangle and the extensions of the other two sides.
Returns
=======
excenters : dict
Examples
========
The excenters are keyed to the side of the triangle to which their corresponding
excircle is tangent: The center is keyed, e.g. the excenter of a circle touching
side 0 is:
>>> from sympy.geometry import Point, Triangle
>>> p1, p2, p3 = Point(0, 0), Point(6, 0), Point(0, 2)
>>> t = Triangle(p1, p2, p3)
>>> t.excenters[t.sides[0]]
Point2D(12*sqrt(10), 2/3 + sqrt(10)/3)
See Also
========
sympy.geometry.polygon.Triangle.exradii
References
==========
.. [1] http://mathworld.wolfram.com/Excircles.html
"""
s = self.sides
v = self.vertices
a = s[0].length
b = s[1].length
c = s[2].length
x = [v[0].x, v[1].x, v[2].x]
y = [v[0].y, v[1].y, v[2].y]
exc_coords = {
"x1": simplify(-a*x[0]+b*x[1]+c*x[2]/(-a+b+c)),
"x2": simplify(a*x[0]-b*x[1]+c*x[2]/(a-b+c)),
"x3": simplify(a*x[0]+b*x[1]-c*x[2]/(a+b-c)),
"y1": simplify(-a*y[0]+b*y[1]+c*y[2]/(-a+b+c)),
"y2": simplify(a*y[0]-b*y[1]+c*y[2]/(a-b+c)),
"y3": simplify(a*y[0]+b*y[1]-c*y[2]/(a+b-c))
}
excenters = {
s[0]: Point(exc_coords["x1"], exc_coords["y1"]),
s[1]: Point(exc_coords["x2"], exc_coords["y2"]),
s[2]: Point(exc_coords["x3"], exc_coords["y3"])
}
return excenters
@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)
|
1a3e6fc6f0df92bdf0b983c36a6ba7a8a95352f7d2770606e8fccc339dba66f1 | """Recurrence Operators"""
from sympy import symbols, Symbol, S
from sympy.printing import sstr
from sympy.core.sympify import sympify
def RecurrenceOperators(base, generator):
"""
Returns an Algebra of Recurrence Operators and the operator for
shifting i.e. the `Sn` operator.
The first argument needs to be the base polynomial ring for the algebra
and the second argument must be a generator which can be either a
noncommutative Symbol or a string.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> from sympy.holonomic.recurrence import RecurrenceOperators
>>> n = symbols('n', integer=True)
>>> R, Sn = RecurrenceOperators(ZZ.old_poly_ring(n), 'Sn')
"""
ring = RecurrenceOperatorAlgebra(base, generator)
return (ring, ring.shift_operator)
class RecurrenceOperatorAlgebra:
"""
A Recurrence Operator Algebra is a set of noncommutative polynomials
in intermediate `Sn` and coefficients in a base ring A. It follows the
commutation rule:
Sn * a(n) = a(n + 1) * Sn
This class represents a Recurrence Operator Algebra and serves as the parent ring
for Recurrence Operators.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> from sympy.holonomic.recurrence import RecurrenceOperators
>>> n = symbols('n', integer=True)
>>> R, Sn = RecurrenceOperators(ZZ.old_poly_ring(n), 'Sn')
>>> R
Univariate Recurrence Operator Algebra in intermediate Sn over the base ring
ZZ[n]
See Also
========
RecurrenceOperator
"""
def __init__(self, base, generator):
# the base ring for the algebra
self.base = base
# the operator representing shift i.e. `Sn`
self.shift_operator = RecurrenceOperator(
[base.zero, base.one], self)
if generator is None:
self.gen_symbol = symbols('Sn', commutative=False)
else:
if isinstance(generator, str):
self.gen_symbol = symbols(generator, commutative=False)
elif isinstance(generator, Symbol):
self.gen_symbol = generator
def __str__(self):
string = 'Univariate Recurrence Operator Algebra in intermediate '\
+ sstr(self.gen_symbol) + ' over the base ring ' + \
(self.base).__str__()
return string
__repr__ = __str__
def __eq__(self, other):
if self.base == other.base and self.gen_symbol == other.gen_symbol:
return True
else:
return False
def _add_lists(list1, list2):
if len(list1) <= len(list2):
sol = [a + b for a, b in zip(list1, list2)] + list2[len(list1):]
else:
sol = [a + b for a, b in zip(list1, list2)] + list1[len(list2):]
return sol
class RecurrenceOperator:
"""
The Recurrence Operators are defined by a list of polynomials
in the base ring and the parent ring of the Operator.
Takes a list of polynomials for each power of Sn and the
parent ring which must be an instance of RecurrenceOperatorAlgebra.
A Recurrence Operator can be created easily using
the operator `Sn`. See examples below.
Examples
========
>>> from sympy.holonomic.recurrence import RecurrenceOperator, RecurrenceOperators
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> n = symbols('n', integer=True)
>>> R, Sn = RecurrenceOperators(ZZ.old_poly_ring(n),'Sn')
>>> RecurrenceOperator([0, 1, n**2], R)
(1)Sn + (n**2)Sn**2
>>> Sn*n
(n + 1)Sn
>>> n*Sn*n + 1 - Sn**2*n
(1) + (n**2 + n)Sn + (-n - 2)Sn**2
See Also
========
DifferentialOperatorAlgebra
"""
_op_priority = 20
def __init__(self, list_of_poly, parent):
# the parent ring for this operator
# must be an RecurrenceOperatorAlgebra object
self.parent = parent
# sequence of polynomials in n for each power of Sn
# represents the operator
# convert the expressions into ring elements using from_sympy
if isinstance(list_of_poly, list):
for i, j in enumerate(list_of_poly):
if isinstance(j, int):
list_of_poly[i] = self.parent.base.from_sympy(S(j))
elif not isinstance(j, self.parent.base.dtype):
list_of_poly[i] = self.parent.base.from_sympy(j)
self.listofpoly = list_of_poly
self.order = len(self.listofpoly) - 1
def __mul__(self, other):
"""
Multiplies two Operators and returns another
RecurrenceOperator instance using the commutation rule
Sn * a(n) = a(n + 1) * Sn
"""
listofself = self.listofpoly
base = self.parent.base
if not isinstance(other, RecurrenceOperator):
if not isinstance(other, self.parent.base.dtype):
listofother = [self.parent.base.from_sympy(sympify(other))]
else:
listofother = [other]
else:
listofother = other.listofpoly
# multiply a polynomial `b` with a list of polynomials
def _mul_dmp_diffop(b, listofother):
if isinstance(listofother, list):
sol = []
for i in listofother:
sol.append(i * b)
return sol
else:
return [b * listofother]
sol = _mul_dmp_diffop(listofself[0], listofother)
# compute Sn^i * b
def _mul_Sni_b(b):
sol = [base.zero]
if isinstance(b, list):
for i in b:
j = base.to_sympy(i).subs(base.gens[0], base.gens[0] + S.One)
sol.append(base.from_sympy(j))
else:
j = b.subs(base.gens[0], base.gens[0] + S.One)
sol.append(base.from_sympy(j))
return sol
for i in range(1, len(listofself)):
# find Sn^i * b in ith iteration
listofother = _mul_Sni_b(listofother)
# solution = solution + listofself[i] * (Sn^i * b)
sol = _add_lists(sol, _mul_dmp_diffop(listofself[i], listofother))
return RecurrenceOperator(sol, self.parent)
def __rmul__(self, other):
if not isinstance(other, RecurrenceOperator):
if isinstance(other, int):
other = S(other)
if not isinstance(other, self.parent.base.dtype):
other = (self.parent.base).from_sympy(other)
sol = []
for j in self.listofpoly:
sol.append(other * j)
return RecurrenceOperator(sol, self.parent)
def __add__(self, other):
if isinstance(other, RecurrenceOperator):
sol = _add_lists(self.listofpoly, other.listofpoly)
return RecurrenceOperator(sol, self.parent)
else:
if isinstance(other, int):
other = S(other)
list_self = self.listofpoly
if not isinstance(other, self.parent.base.dtype):
list_other = [((self.parent).base).from_sympy(other)]
else:
list_other = [other]
sol = []
sol.append(list_self[0] + list_other[0])
sol += list_self[1:]
return RecurrenceOperator(sol, self.parent)
__radd__ = __add__
def __sub__(self, other):
return self + (-1) * other
def __rsub__(self, other):
return (-1) * self + other
def __pow__(self, n):
if n == 1:
return self
if n == 0:
return RecurrenceOperator([self.parent.base.one], self.parent)
# if self is `Sn`
if self.listofpoly == self.parent.shift_operator.listofpoly:
sol = []
for i in range(0, n):
sol.append(self.parent.base.zero)
sol.append(self.parent.base.one)
return RecurrenceOperator(sol, self.parent)
else:
if n % 2 == 1:
powreduce = self**(n - 1)
return powreduce * self
elif n % 2 == 0:
powreduce = self**(n / 2)
return powreduce * powreduce
def __str__(self):
listofpoly = self.listofpoly
print_str = ''
for i, j in enumerate(listofpoly):
if j == self.parent.base.zero:
continue
if i == 0:
print_str += '(' + sstr(j) + ')'
continue
if print_str:
print_str += ' + '
if i == 1:
print_str += '(' + sstr(j) + ')Sn'
continue
print_str += '(' + sstr(j) + ')' + 'Sn**' + sstr(i)
return print_str
__repr__ = __str__
def __eq__(self, other):
if isinstance(other, RecurrenceOperator):
if self.listofpoly == other.listofpoly and self.parent == other.parent:
return True
else:
return False
else:
if self.listofpoly[0] == other:
for i in self.listofpoly[1:]:
if i is not self.parent.base.zero:
return False
return True
else:
return False
class HolonomicSequence:
"""
A Holonomic Sequence is a type of sequence satisfying a linear homogeneous
recurrence relation with Polynomial coefficients. Alternatively, A sequence
is Holonomic if and only if its generating function is a Holonomic Function.
"""
def __init__(self, recurrence, u0=[]):
self.recurrence = recurrence
if not isinstance(u0, list):
self.u0 = [u0]
else:
self.u0 = u0
if len(self.u0) == 0:
self._have_init_cond = False
else:
self._have_init_cond = True
self.n = recurrence.parent.base.gens[0]
def __repr__(self):
str_sol = 'HolonomicSequence(%s, %s)' % ((self.recurrence).__repr__(), sstr(self.n))
if not self._have_init_cond:
return str_sol
else:
cond_str = ''
seq_str = 0
for i in self.u0:
cond_str += ', u(%s) = %s' % (sstr(seq_str), sstr(i))
seq_str += 1
sol = str_sol + cond_str
return sol
__str__ = __repr__
def __eq__(self, other):
if self.recurrence == other.recurrence:
if self.n == other.n:
if self._have_init_cond and other._have_init_cond:
if self.u0 == other.u0:
return True
else:
return False
else:
return True
else:
return False
else:
return False
|
2c393651db5efc09a15397ff0c604a2aa40277d99156a69e040e21ac48e91b60 | """
This module implements Holonomic Functions and
various operations on them.
"""
from sympy import (Symbol, S, Dummy, Order, rf, I,
solve, limit, Float, nsimplify, gamma)
from sympy.core.compatibility import ordered
from sympy.core.numbers import NaN, Infinity, NegativeInfinity
from sympy.core.sympify import sympify
from sympy.functions.combinatorial.factorials import binomial, factorial
from sympy.functions.elementary.exponential import exp_polar, exp
from sympy.functions.special.hyper import hyper, meijerg
from sympy.integrals import meijerint
from sympy.matrices import Matrix
from sympy.polys.rings import PolyElement
from sympy.polys.fields import FracElement
from sympy.polys.domains import QQ, RR
from sympy.polys.polyclasses import DMF
from sympy.polys.polyroots import roots
from sympy.polys.polytools import Poly
from sympy.printing import sstr
from sympy.simplify.hyperexpand import hyperexpand
from .linearsolver import NewMatrix
from .recurrence import HolonomicSequence, RecurrenceOperator, RecurrenceOperators
from .holonomicerrors import (NotPowerSeriesError, NotHyperSeriesError,
SingularityError, NotHolonomicError)
def DifferentialOperators(base, generator):
r"""
This function is used to create annihilators using ``Dx``.
Returns an Algebra of Differential Operators also called Weyl Algebra
and the operator for differentiation i.e. the ``Dx`` operator.
Parameters
==========
base:
Base polynomial ring for the algebra.
The base polynomial ring is the ring of polynomials in :math:`x` that
will appear as coefficients in the operators.
generator:
Generator of the algebra which can
be either a noncommutative ``Symbol`` or a string. e.g. "Dx" or "D".
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy.abc import x
>>> from sympy.holonomic.holonomic import DifferentialOperators
>>> R, Dx = DifferentialOperators(ZZ.old_poly_ring(x), 'Dx')
>>> R
Univariate Differential Operator Algebra in intermediate Dx over the base ring ZZ[x]
>>> Dx*x
(1) + (x)*Dx
"""
ring = DifferentialOperatorAlgebra(base, generator)
return (ring, ring.derivative_operator)
class DifferentialOperatorAlgebra:
r"""
An Ore Algebra is a set of noncommutative polynomials in the
intermediate ``Dx`` and coefficients in a base polynomial ring :math:`A`.
It follows the commutation rule:
.. math ::
Dxa = \sigma(a)Dx + \delta(a)
for :math:`a \subset A`.
Where :math:`\sigma: A \Rightarrow A` is an endomorphism and :math:`\delta: A \rightarrow A`
is a skew-derivation i.e. :math:`\delta(ab) = \delta(a) b + \sigma(a) \delta(b)`.
If one takes the sigma as identity map and delta as the standard derivation
then it becomes the algebra of Differential Operators also called
a Weyl Algebra i.e. an algebra whose elements are Differential Operators.
This class represents a Weyl Algebra and serves as the parent ring for
Differential Operators.
Examples
========
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> from sympy.holonomic.holonomic import DifferentialOperators
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(ZZ.old_poly_ring(x), 'Dx')
>>> R
Univariate Differential Operator Algebra in intermediate Dx over the base ring
ZZ[x]
See Also
========
DifferentialOperator
"""
def __init__(self, base, generator):
# the base polynomial ring for the algebra
self.base = base
# the operator representing differentiation i.e. `Dx`
self.derivative_operator = DifferentialOperator(
[base.zero, base.one], self)
if generator is None:
self.gen_symbol = Symbol('Dx', commutative=False)
else:
if isinstance(generator, str):
self.gen_symbol = Symbol(generator, commutative=False)
elif isinstance(generator, Symbol):
self.gen_symbol = generator
def __str__(self):
string = 'Univariate Differential Operator Algebra in intermediate '\
+ sstr(self.gen_symbol) + ' over the base ring ' + \
(self.base).__str__()
return string
__repr__ = __str__
def __eq__(self, other):
if self.base == other.base and self.gen_symbol == other.gen_symbol:
return True
else:
return False
class DifferentialOperator:
"""
Differential Operators are elements of Weyl Algebra. The Operators
are defined by a list of polynomials in the base ring and the
parent ring of the Operator i.e. the algebra it belongs to.
Takes a list of polynomials for each power of ``Dx`` and the
parent ring which must be an instance of DifferentialOperatorAlgebra.
A Differential Operator can be created easily using
the operator ``Dx``. See examples below.
Examples
========
>>> from sympy.holonomic.holonomic import DifferentialOperator, DifferentialOperators
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(ZZ.old_poly_ring(x),'Dx')
>>> DifferentialOperator([0, 1, x**2], R)
(1)*Dx + (x**2)*Dx**2
>>> (x*Dx*x + 1 - Dx**2)**2
(2*x**2 + 2*x + 1) + (4*x**3 + 2*x**2 - 4)*Dx + (x**4 - 6*x - 2)*Dx**2 + (-2*x**2)*Dx**3 + (1)*Dx**4
See Also
========
DifferentialOperatorAlgebra
"""
_op_priority = 20
def __init__(self, list_of_poly, parent):
"""
Parameters
==========
list_of_poly:
List of polynomials belonging to the base ring of the algebra.
parent:
Parent algebra of the operator.
"""
# the parent ring for this operator
# must be an DifferentialOperatorAlgebra object
self.parent = parent
base = self.parent.base
self.x = base.gens[0] if isinstance(base.gens[0], Symbol) else base.gens[0][0]
# sequence of polynomials in x for each power of Dx
# the list should not have trailing zeroes
# represents the operator
# convert the expressions into ring elements using from_sympy
for i, j in enumerate(list_of_poly):
if not isinstance(j, base.dtype):
list_of_poly[i] = base.from_sympy(sympify(j))
else:
list_of_poly[i] = base.from_sympy(base.to_sympy(j))
self.listofpoly = list_of_poly
# highest power of `Dx`
self.order = len(self.listofpoly) - 1
def __mul__(self, other):
"""
Multiplies two DifferentialOperator and returns another
DifferentialOperator instance using the commutation rule
Dx*a = a*Dx + a'
"""
listofself = self.listofpoly
if not isinstance(other, DifferentialOperator):
if not isinstance(other, self.parent.base.dtype):
listofother = [self.parent.base.from_sympy(sympify(other))]
else:
listofother = [other]
else:
listofother = other.listofpoly
# multiplies a polynomial `b` with a list of polynomials
def _mul_dmp_diffop(b, listofother):
if isinstance(listofother, list):
sol = []
for i in listofother:
sol.append(i * b)
return sol
else:
return [b * listofother]
sol = _mul_dmp_diffop(listofself[0], listofother)
# compute Dx^i * b
def _mul_Dxi_b(b):
sol1 = [self.parent.base.zero]
sol2 = []
if isinstance(b, list):
for i in b:
sol1.append(i)
sol2.append(i.diff())
else:
sol1.append(self.parent.base.from_sympy(b))
sol2.append(self.parent.base.from_sympy(b).diff())
return _add_lists(sol1, sol2)
for i in range(1, len(listofself)):
# find Dx^i * b in ith iteration
listofother = _mul_Dxi_b(listofother)
# solution = solution + listofself[i] * (Dx^i * b)
sol = _add_lists(sol, _mul_dmp_diffop(listofself[i], listofother))
return DifferentialOperator(sol, self.parent)
def __rmul__(self, other):
if not isinstance(other, DifferentialOperator):
if not isinstance(other, self.parent.base.dtype):
other = (self.parent.base).from_sympy(sympify(other))
sol = []
for j in self.listofpoly:
sol.append(other * j)
return DifferentialOperator(sol, self.parent)
def __add__(self, other):
if isinstance(other, DifferentialOperator):
sol = _add_lists(self.listofpoly, other.listofpoly)
return DifferentialOperator(sol, self.parent)
else:
list_self = self.listofpoly
if not isinstance(other, self.parent.base.dtype):
list_other = [((self.parent).base).from_sympy(sympify(other))]
else:
list_other = [other]
sol = []
sol.append(list_self[0] + list_other[0])
sol += list_self[1:]
return DifferentialOperator(sol, self.parent)
__radd__ = __add__
def __sub__(self, other):
return self + (-1) * other
def __rsub__(self, other):
return (-1) * self + other
def __neg__(self):
return -1 * self
def __div__(self, other):
return self * (S.One / other)
def __truediv__(self, other):
return self.__div__(other)
def __pow__(self, n):
if n == 1:
return self
if n == 0:
return DifferentialOperator([self.parent.base.one], self.parent)
# if self is `Dx`
if self.listofpoly == self.parent.derivative_operator.listofpoly:
sol = []
for i in range(0, n):
sol.append(self.parent.base.zero)
sol.append(self.parent.base.one)
return DifferentialOperator(sol, self.parent)
# the general case
else:
if n % 2 == 1:
powreduce = self**(n - 1)
return powreduce * self
elif n % 2 == 0:
powreduce = self**(n / 2)
return powreduce * powreduce
def __str__(self):
listofpoly = self.listofpoly
print_str = ''
for i, j in enumerate(listofpoly):
if j == self.parent.base.zero:
continue
if i == 0:
print_str += '(' + sstr(j) + ')'
continue
if print_str:
print_str += ' + '
if i == 1:
print_str += '(' + sstr(j) + ')*%s' %(self.parent.gen_symbol)
continue
print_str += '(' + sstr(j) + ')' + '*%s**' %(self.parent.gen_symbol) + sstr(i)
return print_str
__repr__ = __str__
def __eq__(self, other):
if isinstance(other, DifferentialOperator):
if self.listofpoly == other.listofpoly and self.parent == other.parent:
return True
else:
return False
else:
if self.listofpoly[0] == other:
for i in self.listofpoly[1:]:
if i is not self.parent.base.zero:
return False
return True
else:
return False
def is_singular(self, x0):
"""
Checks if the differential equation is singular at x0.
"""
base = self.parent.base
return x0 in roots(base.to_sympy(self.listofpoly[-1]), self.x)
class HolonomicFunction:
r"""
A Holonomic Function is a solution to a linear homogeneous ordinary
differential equation with polynomial coefficients. This differential
equation can also be represented by an annihilator i.e. a Differential
Operator ``L`` such that :math:`L.f = 0`. For uniqueness of these functions,
initial conditions can also be provided along with the annihilator.
Holonomic functions have closure properties and thus forms a ring.
Given two Holonomic Functions f and g, their sum, product,
integral and derivative is also a Holonomic Function.
For ordinary points initial condition should be a vector of values of
the derivatives i.e. :math:`[y(x_0), y'(x_0), y''(x_0) ... ]`.
For regular singular points initial conditions can also be provided in this
format:
:math:`{s0: [C_0, C_1, ...], s1: [C^1_0, C^1_1, ...], ...}`
where s0, s1, ... are the roots of indicial equation and vectors
:math:`[C_0, C_1, ...], [C^0_0, C^0_1, ...], ...` are the corresponding initial
terms of the associated power series. See Examples below.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import QQ
>>> from sympy import symbols, S
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(QQ.old_poly_ring(x),'Dx')
>>> p = HolonomicFunction(Dx - 1, x, 0, [1]) # e^x
>>> q = HolonomicFunction(Dx**2 + 1, x, 0, [0, 1]) # sin(x)
>>> p + q # annihilator of e^x + sin(x)
HolonomicFunction((-1) + (1)*Dx + (-1)*Dx**2 + (1)*Dx**3, x, 0, [1, 2, 1])
>>> p * q # annihilator of e^x * sin(x)
HolonomicFunction((2) + (-2)*Dx + (1)*Dx**2, x, 0, [0, 1])
An example of initial conditions for regular singular points,
the indicial equation has only one root `1/2`.
>>> HolonomicFunction(-S(1)/2 + x*Dx, x, 0, {S(1)/2: [1]})
HolonomicFunction((-1/2) + (x)*Dx, x, 0, {1/2: [1]})
>>> HolonomicFunction(-S(1)/2 + x*Dx, x, 0, {S(1)/2: [1]}).to_expr()
sqrt(x)
To plot a Holonomic Function, one can use `.evalf()` for numerical
computation. Here's an example on `sin(x)**2/x` using numpy and matplotlib.
>>> import sympy.holonomic # doctest: +SKIP
>>> from sympy import var, sin # doctest: +SKIP
>>> import matplotlib.pyplot as plt # doctest: +SKIP
>>> import numpy as np # doctest: +SKIP
>>> var("x") # doctest: +SKIP
>>> r = np.linspace(1, 5, 100) # doctest: +SKIP
>>> y = sympy.holonomic.expr_to_holonomic(sin(x)**2/x, x0=1).evalf(r) # doctest: +SKIP
>>> plt.plot(r, y, label="holonomic function") # doctest: +SKIP
>>> plt.show() # doctest: +SKIP
"""
_op_priority = 20
def __init__(self, annihilator, x, x0=0, y0=None):
"""
Parameters
==========
annihilator:
Annihilator of the Holonomic Function, represented by a
`DifferentialOperator` object.
x:
Variable of the function.
x0:
The point at which initial conditions are stored.
Generally an integer.
y0:
The initial condition. The proper format for the initial condition
is described in class docstring. To make the function unique,
length of the vector `y0` should be equal to or greater than the
order of differential equation.
"""
# initial condition
self.y0 = y0
# the point for initial conditions, default is zero.
self.x0 = x0
# differential operator L such that L.f = 0
self.annihilator = annihilator
self.x = x
def __str__(self):
if self._have_init_cond():
str_sol = 'HolonomicFunction(%s, %s, %s, %s)' % (str(self.annihilator),\
sstr(self.x), sstr(self.x0), sstr(self.y0))
else:
str_sol = 'HolonomicFunction(%s, %s)' % (str(self.annihilator),\
sstr(self.x))
return str_sol
__repr__ = __str__
def unify(self, other):
"""
Unifies the base polynomial ring of a given two Holonomic
Functions.
"""
R1 = self.annihilator.parent.base
R2 = other.annihilator.parent.base
dom1 = R1.dom
dom2 = R2.dom
if R1 == R2:
return (self, other)
R = (dom1.unify(dom2)).old_poly_ring(self.x)
newparent, _ = DifferentialOperators(R, str(self.annihilator.parent.gen_symbol))
sol1 = [R1.to_sympy(i) for i in self.annihilator.listofpoly]
sol2 = [R2.to_sympy(i) for i in other.annihilator.listofpoly]
sol1 = DifferentialOperator(sol1, newparent)
sol2 = DifferentialOperator(sol2, newparent)
sol1 = HolonomicFunction(sol1, self.x, self.x0, self.y0)
sol2 = HolonomicFunction(sol2, other.x, other.x0, other.y0)
return (sol1, sol2)
def is_singularics(self):
"""
Returns True if the function have singular initial condition
in the dictionary format.
Returns False if the function have ordinary initial condition
in the list format.
Returns None for all other cases.
"""
if isinstance(self.y0, dict):
return True
elif isinstance(self.y0, list):
return False
def _have_init_cond(self):
"""
Checks if the function have initial condition.
"""
return bool(self.y0)
def _singularics_to_ord(self):
"""
Converts a singular initial condition to ordinary if possible.
"""
a = list(self.y0)[0]
b = self.y0[a]
if len(self.y0) == 1 and a == int(a) and a > 0:
y0 = []
a = int(a)
for i in range(a):
y0.append(S.Zero)
y0 += [j * factorial(a + i) for i, j in enumerate(b)]
return HolonomicFunction(self.annihilator, self.x, self.x0, y0)
def __add__(self, other):
# if the ground domains are different
if self.annihilator.parent.base != other.annihilator.parent.base:
a, b = self.unify(other)
return a + b
deg1 = self.annihilator.order
deg2 = other.annihilator.order
dim = max(deg1, deg2)
R = self.annihilator.parent.base
K = R.get_field()
rowsself = [self.annihilator]
rowsother = [other.annihilator]
gen = self.annihilator.parent.derivative_operator
# constructing annihilators up to order dim
for i in range(dim - deg1):
diff1 = (gen * rowsself[-1])
rowsself.append(diff1)
for i in range(dim - deg2):
diff2 = (gen * rowsother[-1])
rowsother.append(diff2)
row = rowsself + rowsother
# constructing the matrix of the ansatz
r = []
for expr in row:
p = []
for i in range(dim + 1):
if i >= len(expr.listofpoly):
p.append(0)
else:
p.append(K.new(expr.listofpoly[i].rep))
r.append(p)
r = NewMatrix(r).transpose()
homosys = [[S.Zero for q in range(dim + 1)]]
homosys = NewMatrix(homosys).transpose()
# solving the linear system using gauss jordan solver
solcomp = r.gauss_jordan_solve(homosys)
sol = solcomp[0]
# if a solution is not obtained then increasing the order by 1 in each
# iteration
while sol.is_zero_matrix:
dim += 1
diff1 = (gen * rowsself[-1])
rowsself.append(diff1)
diff2 = (gen * rowsother[-1])
rowsother.append(diff2)
row = rowsself + rowsother
r = []
for expr in row:
p = []
for i in range(dim + 1):
if i >= len(expr.listofpoly):
p.append(S.Zero)
else:
p.append(K.new(expr.listofpoly[i].rep))
r.append(p)
r = NewMatrix(r).transpose()
homosys = [[S.Zero for q in range(dim + 1)]]
homosys = NewMatrix(homosys).transpose()
solcomp = r.gauss_jordan_solve(homosys)
sol = solcomp[0]
# taking only the coefficients needed to multiply with `self`
# can be also be done the other way by taking R.H.S and multiplying with
# `other`
sol = sol[:dim + 1 - deg1]
sol1 = _normalize(sol, self.annihilator.parent)
# annihilator of the solution
sol = sol1 * (self.annihilator)
sol = _normalize(sol.listofpoly, self.annihilator.parent, negative=False)
if not (self._have_init_cond() and other._have_init_cond()):
return HolonomicFunction(sol, self.x)
# both the functions have ordinary initial conditions
if self.is_singularics() == False and other.is_singularics() == False:
# directly add the corresponding value
if self.x0 == other.x0:
# try to extended the initial conditions
# using the annihilator
y1 = _extend_y0(self, sol.order)
y2 = _extend_y0(other, sol.order)
y0 = [a + b for a, b in zip(y1, y2)]
return HolonomicFunction(sol, self.x, self.x0, y0)
else:
# change the intiial conditions to a same point
selfat0 = self.annihilator.is_singular(0)
otherat0 = other.annihilator.is_singular(0)
if self.x0 == 0 and not selfat0 and not otherat0:
return self + other.change_ics(0)
elif other.x0 == 0 and not selfat0 and not otherat0:
return self.change_ics(0) + other
else:
selfatx0 = self.annihilator.is_singular(self.x0)
otheratx0 = other.annihilator.is_singular(self.x0)
if not selfatx0 and not otheratx0:
return self + other.change_ics(self.x0)
else:
return self.change_ics(other.x0) + other
if self.x0 != other.x0:
return HolonomicFunction(sol, self.x)
# if the functions have singular_ics
y1 = None
y2 = None
if self.is_singularics() == False and other.is_singularics() == True:
# convert the ordinary initial condition to singular.
_y0 = [j / factorial(i) for i, j in enumerate(self.y0)]
y1 = {S.Zero: _y0}
y2 = other.y0
elif self.is_singularics() == True and other.is_singularics() == False:
_y0 = [j / factorial(i) for i, j in enumerate(other.y0)]
y1 = self.y0
y2 = {S.Zero: _y0}
elif self.is_singularics() == True and other.is_singularics() == True:
y1 = self.y0
y2 = other.y0
# computing singular initial condition for the result
# taking union of the series terms of both functions
y0 = {}
for i in y1:
# add corresponding initial terms if the power
# on `x` is same
if i in y2:
y0[i] = [a + b for a, b in zip(y1[i], y2[i])]
else:
y0[i] = y1[i]
for i in y2:
if not i in y1:
y0[i] = y2[i]
return HolonomicFunction(sol, self.x, self.x0, y0)
def integrate(self, limits, initcond=False):
"""
Integrates the given holonomic function.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import QQ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(QQ.old_poly_ring(x),'Dx')
>>> HolonomicFunction(Dx - 1, x, 0, [1]).integrate((x, 0, x)) # e^x - 1
HolonomicFunction((-1)*Dx + (1)*Dx**2, x, 0, [0, 1])
>>> HolonomicFunction(Dx**2 + 1, x, 0, [1, 0]).integrate((x, 0, x))
HolonomicFunction((1)*Dx + (1)*Dx**3, x, 0, [0, 1, 0])
"""
# to get the annihilator, just multiply by Dx from right
D = self.annihilator.parent.derivative_operator
# if the function have initial conditions of the series format
if self.is_singularics() == True:
r = self._singularics_to_ord()
if r:
return r.integrate(limits, initcond=initcond)
# computing singular initial condition for the function
# produced after integration.
y0 = {}
for i in self.y0:
c = self.y0[i]
c2 = []
for j in range(len(c)):
if c[j] == 0:
c2.append(S.Zero)
# if power on `x` is -1, the integration becomes log(x)
# TODO: Implement this case
elif i + j + 1 == 0:
raise NotImplementedError("logarithmic terms in the series are not supported")
else:
c2.append(c[j] / S(i + j + 1))
y0[i + 1] = c2
if hasattr(limits, "__iter__"):
raise NotImplementedError("Definite integration for singular initial conditions")
return HolonomicFunction(self.annihilator * D, self.x, self.x0, y0)
# if no initial conditions are available for the function
if not self._have_init_cond():
if initcond:
return HolonomicFunction(self.annihilator * D, self.x, self.x0, [S.Zero])
return HolonomicFunction(self.annihilator * D, self.x)
# definite integral
# initial conditions for the answer will be stored at point `a`,
# where `a` is the lower limit of the integrand
if hasattr(limits, "__iter__"):
if len(limits) == 3 and limits[0] == self.x:
x0 = self.x0
a = limits[1]
b = limits[2]
definite = True
else:
definite = False
y0 = [S.Zero]
y0 += self.y0
indefinite_integral = HolonomicFunction(self.annihilator * D, self.x, self.x0, y0)
if not definite:
return indefinite_integral
# use evalf to get the values at `a`
if x0 != a:
try:
indefinite_expr = indefinite_integral.to_expr()
except (NotHyperSeriesError, NotPowerSeriesError):
indefinite_expr = None
if indefinite_expr:
lower = indefinite_expr.subs(self.x, a)
if isinstance(lower, NaN):
lower = indefinite_expr.limit(self.x, a)
else:
lower = indefinite_integral.evalf(a)
if b == self.x:
y0[0] = y0[0] - lower
return HolonomicFunction(self.annihilator * D, self.x, x0, y0)
elif S(b).is_Number:
if indefinite_expr:
upper = indefinite_expr.subs(self.x, b)
if isinstance(upper, NaN):
upper = indefinite_expr.limit(self.x, b)
else:
upper = indefinite_integral.evalf(b)
return upper - lower
# if the upper limit is `x`, the answer will be a function
if b == self.x:
return HolonomicFunction(self.annihilator * D, self.x, a, y0)
# if the upper limits is a Number, a numerical value will be returned
elif S(b).is_Number:
try:
s = HolonomicFunction(self.annihilator * D, self.x, a,\
y0).to_expr()
indefinite = s.subs(self.x, b)
if not isinstance(indefinite, NaN):
return indefinite
else:
return s.limit(self.x, b)
except (NotHyperSeriesError, NotPowerSeriesError):
return HolonomicFunction(self.annihilator * D, self.x, a, y0).evalf(b)
return HolonomicFunction(self.annihilator * D, self.x)
def diff(self, *args, **kwargs):
r"""
Differentiation of the given Holonomic function.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(ZZ.old_poly_ring(x),'Dx')
>>> HolonomicFunction(Dx**2 + 1, x, 0, [0, 1]).diff().to_expr()
cos(x)
>>> HolonomicFunction(Dx - 2, x, 0, [1]).diff().to_expr()
2*exp(2*x)
See Also
========
.integrate()
"""
kwargs.setdefault('evaluate', True)
if args:
if args[0] != self.x:
return S.Zero
elif len(args) == 2:
sol = self
for i in range(args[1]):
sol = sol.diff(args[0])
return sol
ann = self.annihilator
# if the function is constant.
if ann.listofpoly[0] == ann.parent.base.zero and ann.order == 1:
return S.Zero
# if the coefficient of y in the differential equation is zero.
# a shifting is done to compute the answer in this case.
elif ann.listofpoly[0] == ann.parent.base.zero:
sol = DifferentialOperator(ann.listofpoly[1:], ann.parent)
if self._have_init_cond():
# if ordinary initial condition
if self.is_singularics() == False:
return HolonomicFunction(sol, self.x, self.x0, self.y0[1:])
# TODO: support for singular initial condition
return HolonomicFunction(sol, self.x)
else:
return HolonomicFunction(sol, self.x)
# the general algorithm
R = ann.parent.base
K = R.get_field()
seq_dmf = [K.new(i.rep) for i in ann.listofpoly]
# -y = a1*y'/a0 + a2*y''/a0 ... + an*y^n/a0
rhs = [i / seq_dmf[0] for i in seq_dmf[1:]]
rhs.insert(0, K.zero)
# differentiate both lhs and rhs
sol = _derivate_diff_eq(rhs)
# add the term y' in lhs to rhs
sol = _add_lists(sol, [K.zero, K.one])
sol = _normalize(sol[1:], self.annihilator.parent, negative=False)
if not self._have_init_cond() or self.is_singularics() == True:
return HolonomicFunction(sol, self.x)
y0 = _extend_y0(self, sol.order + 1)[1:]
return HolonomicFunction(sol, self.x, self.x0, y0)
def __eq__(self, other):
if self.annihilator == other.annihilator:
if self.x == other.x:
if self._have_init_cond() and other._have_init_cond():
if self.x0 == other.x0 and self.y0 == other.y0:
return True
else:
return False
else:
return True
else:
return False
else:
return False
def __mul__(self, other):
ann_self = self.annihilator
if not isinstance(other, HolonomicFunction):
other = sympify(other)
if other.has(self.x):
raise NotImplementedError(" Can't multiply a HolonomicFunction and expressions/functions.")
if not self._have_init_cond():
return self
else:
y0 = _extend_y0(self, ann_self.order)
y1 = []
for j in y0:
y1.append((Poly.new(j, self.x) * other).rep)
return HolonomicFunction(ann_self, self.x, self.x0, y1)
if self.annihilator.parent.base != other.annihilator.parent.base:
a, b = self.unify(other)
return a * b
ann_other = other.annihilator
list_self = []
list_other = []
a = ann_self.order
b = ann_other.order
R = ann_self.parent.base
K = R.get_field()
for j in ann_self.listofpoly:
list_self.append(K.new(j.rep))
for j in ann_other.listofpoly:
list_other.append(K.new(j.rep))
# will be used to reduce the degree
self_red = [-list_self[i] / list_self[a] for i in range(a)]
other_red = [-list_other[i] / list_other[b] for i in range(b)]
# coeff_mull[i][j] is the coefficient of Dx^i(f).Dx^j(g)
coeff_mul = [[S.Zero for i in range(b + 1)] for j in range(a + 1)]
coeff_mul[0][0] = S.One
# making the ansatz
lin_sys = [[coeff_mul[i][j] for i in range(a) for j in range(b)]]
homo_sys = [[S.Zero for q in range(a * b)]]
homo_sys = NewMatrix(homo_sys).transpose()
sol = (NewMatrix(lin_sys).transpose()).gauss_jordan_solve(homo_sys)
# until a non trivial solution is found
while sol[0].is_zero_matrix:
# updating the coefficients Dx^i(f).Dx^j(g) for next degree
for i in range(a - 1, -1, -1):
for j in range(b - 1, -1, -1):
coeff_mul[i][j + 1] += coeff_mul[i][j]
coeff_mul[i + 1][j] += coeff_mul[i][j]
if isinstance(coeff_mul[i][j], K.dtype):
coeff_mul[i][j] = DMFdiff(coeff_mul[i][j])
else:
coeff_mul[i][j] = coeff_mul[i][j].diff(self.x)
# reduce the terms to lower power using annihilators of f, g
for i in range(a + 1):
if not coeff_mul[i][b].is_zero:
for j in range(b):
coeff_mul[i][j] += other_red[j] * \
coeff_mul[i][b]
coeff_mul[i][b] = S.Zero
# not d2 + 1, as that is already covered in previous loop
for j in range(b):
if not coeff_mul[a][j] == 0:
for i in range(a):
coeff_mul[i][j] += self_red[i] * \
coeff_mul[a][j]
coeff_mul[a][j] = S.Zero
lin_sys.append([coeff_mul[i][j] for i in range(a)
for j in range(b)])
sol = (NewMatrix(lin_sys).transpose()).gauss_jordan_solve(homo_sys)
sol_ann = _normalize(sol[0][0:], self.annihilator.parent, negative=False)
if not (self._have_init_cond() and other._have_init_cond()):
return HolonomicFunction(sol_ann, self.x)
if self.is_singularics() == False and other.is_singularics() == False:
# if both the conditions are at same point
if self.x0 == other.x0:
# try to find more initial conditions
y0_self = _extend_y0(self, sol_ann.order)
y0_other = _extend_y0(other, sol_ann.order)
# h(x0) = f(x0) * g(x0)
y0 = [y0_self[0] * y0_other[0]]
# coefficient of Dx^j(f)*Dx^i(g) in Dx^i(fg)
for i in range(1, min(len(y0_self), len(y0_other))):
coeff = [[0 for i in range(i + 1)] for j in range(i + 1)]
for j in range(i + 1):
for k in range(i + 1):
if j + k == i:
coeff[j][k] = binomial(i, j)
sol = 0
for j in range(i + 1):
for k in range(i + 1):
sol += coeff[j][k]* y0_self[j] * y0_other[k]
y0.append(sol)
return HolonomicFunction(sol_ann, self.x, self.x0, y0)
# if the points are different, consider one
else:
selfat0 = self.annihilator.is_singular(0)
otherat0 = other.annihilator.is_singular(0)
if self.x0 == 0 and not selfat0 and not otherat0:
return self * other.change_ics(0)
elif other.x0 == 0 and not selfat0 and not otherat0:
return self.change_ics(0) * other
else:
selfatx0 = self.annihilator.is_singular(self.x0)
otheratx0 = other.annihilator.is_singular(self.x0)
if not selfatx0 and not otheratx0:
return self * other.change_ics(self.x0)
else:
return self.change_ics(other.x0) * other
if self.x0 != other.x0:
return HolonomicFunction(sol_ann, self.x)
# if the functions have singular_ics
y1 = None
y2 = None
if self.is_singularics() == False and other.is_singularics() == True:
_y0 = [j / factorial(i) for i, j in enumerate(self.y0)]
y1 = {S.Zero: _y0}
y2 = other.y0
elif self.is_singularics() == True and other.is_singularics() == False:
_y0 = [j / factorial(i) for i, j in enumerate(other.y0)]
y1 = self.y0
y2 = {S.Zero: _y0}
elif self.is_singularics() == True and other.is_singularics() == True:
y1 = self.y0
y2 = other.y0
y0 = {}
# multiply every possible pair of the series terms
for i in y1:
for j in y2:
k = min(len(y1[i]), len(y2[j]))
c = []
for a in range(k):
s = S.Zero
for b in range(a + 1):
s += y1[i][b] * y2[j][a - b]
c.append(s)
if not i + j in y0:
y0[i + j] = c
else:
y0[i + j] = [a + b for a, b in zip(c, y0[i + j])]
return HolonomicFunction(sol_ann, self.x, self.x0, y0)
__rmul__ = __mul__
def __sub__(self, other):
return self + other * -1
def __rsub__(self, other):
return self * -1 + other
def __neg__(self):
return -1 * self
def __div__(self, other):
return self * (S.One / other)
def __truediv__(self, other):
return self.__div__(other)
def __pow__(self, n):
if self.annihilator.order <= 1:
ann = self.annihilator
parent = ann.parent
if self.y0 is None:
y0 = None
else:
y0 = [list(self.y0)[0] ** n]
p0 = ann.listofpoly[0]
p1 = ann.listofpoly[1]
p0 = (Poly.new(p0, self.x) * n).rep
sol = [parent.base.to_sympy(i) for i in [p0, p1]]
dd = DifferentialOperator(sol, parent)
return HolonomicFunction(dd, self.x, self.x0, y0)
if n < 0:
raise NotHolonomicError("Negative Power on a Holonomic Function")
if n == 0:
Dx = self.annihilator.parent.derivative_operator
return HolonomicFunction(Dx, self.x, S.Zero, [S.One])
if n == 1:
return self
else:
if n % 2 == 1:
powreduce = self**(n - 1)
return powreduce * self
elif n % 2 == 0:
powreduce = self**(n / 2)
return powreduce * powreduce
def degree(self):
"""
Returns the highest power of `x` in the annihilator.
"""
sol = [i.degree() for i in self.annihilator.listofpoly]
return max(sol)
def composition(self, expr, *args, **kwargs):
"""
Returns function after composition of a holonomic
function with an algebraic function. The method can't compute
initial conditions for the result by itself, so they can be also be
provided.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import QQ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(QQ.old_poly_ring(x),'Dx')
>>> HolonomicFunction(Dx - 1, x).composition(x**2, 0, [1]) # e^(x**2)
HolonomicFunction((-2*x) + (1)*Dx, x, 0, [1])
>>> HolonomicFunction(Dx**2 + 1, x).composition(x**2 - 1, 1, [1, 0])
HolonomicFunction((4*x**3) + (-1)*Dx + (x)*Dx**2, x, 1, [1, 0])
See Also
========
from_hyper()
"""
R = self.annihilator.parent
a = self.annihilator.order
diff = expr.diff(self.x)
listofpoly = self.annihilator.listofpoly
for i, j in enumerate(listofpoly):
if isinstance(j, self.annihilator.parent.base.dtype):
listofpoly[i] = self.annihilator.parent.base.to_sympy(j)
r = listofpoly[a].subs({self.x:expr})
subs = [-listofpoly[i].subs({self.x:expr}) / r for i in range (a)]
coeffs = [S.Zero for i in range(a)] # coeffs[i] == coeff of (D^i f)(a) in D^k (f(a))
coeffs[0] = S.One
system = [coeffs]
homogeneous = Matrix([[S.Zero for i in range(a)]]).transpose()
sol = S.Zero
while True:
coeffs_next = [p.diff(self.x) for p in coeffs]
for i in range(a - 1):
coeffs_next[i + 1] += (coeffs[i] * diff)
for i in range(a):
coeffs_next[i] += (coeffs[-1] * subs[i] * diff)
coeffs = coeffs_next
# check for linear relations
system.append(coeffs)
sol, taus = (Matrix(system).transpose()
).gauss_jordan_solve(homogeneous)
if sol.is_zero_matrix is not True:
break
tau = list(taus)[0]
sol = sol.subs(tau, 1)
sol = _normalize(sol[0:], R, negative=False)
# if initial conditions are given for the resulting function
if args:
return HolonomicFunction(sol, self.x, args[0], args[1])
return HolonomicFunction(sol, self.x)
def to_sequence(self, lb=True):
r"""
Finds recurrence relation for the coefficients in the series expansion
of the function about :math:`x_0`, where :math:`x_0` is the point at
which the initial condition is stored.
If the point :math:`x_0` is ordinary, solution of the form :math:`[(R, n_0)]`
is returned. Where :math:`R` is the recurrence relation and :math:`n_0` is the
smallest ``n`` for which the recurrence holds true.
If the point :math:`x_0` is regular singular, a list of solutions in
the format :math:`(R, p, n_0)` is returned, i.e. `[(R, p, n_0), ... ]`.
Each tuple in this vector represents a recurrence relation :math:`R`
associated with a root of the indicial equation ``p``. Conditions of
a different format can also be provided in this case, see the
docstring of HolonomicFunction class.
If it's not possible to numerically compute a initial condition,
it is returned as a symbol :math:`C_j`, denoting the coefficient of
:math:`(x - x_0)^j` in the power series about :math:`x_0`.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import QQ
>>> from sympy import symbols, S
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(QQ.old_poly_ring(x),'Dx')
>>> HolonomicFunction(Dx - 1, x, 0, [1]).to_sequence()
[(HolonomicSequence((-1) + (n + 1)Sn, n), u(0) = 1, 0)]
>>> HolonomicFunction((1 + x)*Dx**2 + Dx, x, 0, [0, 1]).to_sequence()
[(HolonomicSequence((n**2) + (n**2 + n)Sn, n), u(0) = 0, u(1) = 1, u(2) = -1/2, 2)]
>>> HolonomicFunction(-S(1)/2 + x*Dx, x, 0, {S(1)/2: [1]}).to_sequence()
[(HolonomicSequence((n), n), u(0) = 1, 1/2, 1)]
See Also
========
HolonomicFunction.series()
References
==========
.. [1] https://hal.inria.fr/inria-00070025/document
.. [2] http://www.risc.jku.at/publications/download/risc_2244/DIPLFORM.pdf
"""
if self.x0 != 0:
return self.shift_x(self.x0).to_sequence()
# check whether a power series exists if the point is singular
if self.annihilator.is_singular(self.x0):
return self._frobenius(lb=lb)
dict1 = {}
n = Symbol('n', integer=True)
dom = self.annihilator.parent.base.dom
R, _ = RecurrenceOperators(dom.old_poly_ring(n), 'Sn')
# substituting each term of the form `x^k Dx^j` in the
# annihilator, according to the formula below:
# x^k Dx^j = Sum(rf(n + 1 - k, j) * a(n + j - k) * x^n, (n, k, oo))
# for explanation see [2].
for i, j in enumerate(self.annihilator.listofpoly):
listofdmp = j.all_coeffs()
degree = len(listofdmp) - 1
for k in range(degree + 1):
coeff = listofdmp[degree - k]
if coeff == 0:
continue
if (i - k, k) in dict1:
dict1[(i - k, k)] += (dom.to_sympy(coeff) * rf(n - k + 1, i))
else:
dict1[(i - k, k)] = (dom.to_sympy(coeff) * rf(n - k + 1, i))
sol = []
keylist = [i[0] for i in dict1]
lower = min(keylist)
upper = max(keylist)
degree = self.degree()
# the recurrence relation holds for all values of
# n greater than smallest_n, i.e. n >= smallest_n
smallest_n = lower + degree
dummys = {}
eqs = []
unknowns = []
# an appropriate shift of the recurrence
for j in range(lower, upper + 1):
if j in keylist:
temp = S.Zero
for k in dict1.keys():
if k[0] == j:
temp += dict1[k].subs(n, n - lower)
sol.append(temp)
else:
sol.append(S.Zero)
# the recurrence relation
sol = RecurrenceOperator(sol, R)
# computing the initial conditions for recurrence
order = sol.order
all_roots = roots(R.base.to_sympy(sol.listofpoly[-1]), n, filter='Z')
all_roots = all_roots.keys()
if all_roots:
max_root = max(all_roots) + 1
smallest_n = max(max_root, smallest_n)
order += smallest_n
y0 = _extend_y0(self, order)
u0 = []
# u(n) = y^n(0)/factorial(n)
for i, j in enumerate(y0):
u0.append(j / factorial(i))
# if sufficient conditions can't be computed then
# try to use the series method i.e.
# equate the coefficients of x^k in the equation formed by
# substituting the series in differential equation, to zero.
if len(u0) < order:
for i in range(degree):
eq = S.Zero
for j in dict1:
if i + j[0] < 0:
dummys[i + j[0]] = S.Zero
elif i + j[0] < len(u0):
dummys[i + j[0]] = u0[i + j[0]]
elif not i + j[0] in dummys:
dummys[i + j[0]] = Symbol('C_%s' %(i + j[0]))
unknowns.append(dummys[i + j[0]])
if j[1] <= i:
eq += dict1[j].subs(n, i) * dummys[i + j[0]]
eqs.append(eq)
# solve the system of equations formed
soleqs = solve(eqs, *unknowns)
if isinstance(soleqs, dict):
for i in range(len(u0), order):
if i not in dummys:
dummys[i] = Symbol('C_%s' %i)
if dummys[i] in soleqs:
u0.append(soleqs[dummys[i]])
else:
u0.append(dummys[i])
if lb:
return [(HolonomicSequence(sol, u0), smallest_n)]
return [HolonomicSequence(sol, u0)]
for i in range(len(u0), order):
if i not in dummys:
dummys[i] = Symbol('C_%s' %i)
s = False
for j in soleqs:
if dummys[i] in j:
u0.append(j[dummys[i]])
s = True
if not s:
u0.append(dummys[i])
if lb:
return [(HolonomicSequence(sol, u0), smallest_n)]
return [HolonomicSequence(sol, u0)]
def _frobenius(self, lb=True):
# compute the roots of indicial equation
indicialroots = self._indicial()
reals = []
compl = []
for i in ordered(indicialroots.keys()):
if i.is_real:
reals.extend([i] * indicialroots[i])
else:
a, b = i.as_real_imag()
compl.extend([(i, a, b)] * indicialroots[i])
# sort the roots for a fixed ordering of solution
compl.sort(key=lambda x : x[1])
compl.sort(key=lambda x : x[2])
reals.sort()
# grouping the roots, roots differ by an integer are put in the same group.
grp = []
for i in reals:
intdiff = False
if len(grp) == 0:
grp.append([i])
continue
for j in grp:
if int(j[0] - i) == j[0] - i:
j.append(i)
intdiff = True
break
if not intdiff:
grp.append([i])
# True if none of the roots differ by an integer i.e.
# each element in group have only one member
independent = True if all(len(i) == 1 for i in grp) else False
allpos = all(i >= 0 for i in reals)
allint = all(int(i) == i for i in reals)
# if initial conditions are provided
# then use them.
if self.is_singularics() == True:
rootstoconsider = []
for i in ordered(self.y0.keys()):
for j in ordered(indicialroots.keys()):
if j == i:
rootstoconsider.append(i)
elif allpos and allint:
rootstoconsider = [min(reals)]
elif independent:
rootstoconsider = [i[0] for i in grp] + [j[0] for j in compl]
elif not allint:
rootstoconsider = []
for i in reals:
if not int(i) == i:
rootstoconsider.append(i)
elif not allpos:
if not self._have_init_cond() or S(self.y0[0]).is_finite == False:
rootstoconsider = [min(reals)]
else:
posroots = []
for i in reals:
if i >= 0:
posroots.append(i)
rootstoconsider = [min(posroots)]
n = Symbol('n', integer=True)
dom = self.annihilator.parent.base.dom
R, _ = RecurrenceOperators(dom.old_poly_ring(n), 'Sn')
finalsol = []
char = ord('C')
for p in rootstoconsider:
dict1 = {}
for i, j in enumerate(self.annihilator.listofpoly):
listofdmp = j.all_coeffs()
degree = len(listofdmp) - 1
for k in range(degree + 1):
coeff = listofdmp[degree - k]
if coeff == 0:
continue
if (i - k, k - i) in dict1:
dict1[(i - k, k - i)] += (dom.to_sympy(coeff) * rf(n - k + 1 + p, i))
else:
dict1[(i - k, k - i)] = (dom.to_sympy(coeff) * rf(n - k + 1 + p, i))
sol = []
keylist = [i[0] for i in dict1]
lower = min(keylist)
upper = max(keylist)
degree = max([i[1] for i in dict1])
degree2 = min([i[1] for i in dict1])
smallest_n = lower + degree
dummys = {}
eqs = []
unknowns = []
for j in range(lower, upper + 1):
if j in keylist:
temp = S.Zero
for k in dict1.keys():
if k[0] == j:
temp += dict1[k].subs(n, n - lower)
sol.append(temp)
else:
sol.append(S.Zero)
# the recurrence relation
sol = RecurrenceOperator(sol, R)
# computing the initial conditions for recurrence
order = sol.order
all_roots = roots(R.base.to_sympy(sol.listofpoly[-1]), n, filter='Z')
all_roots = all_roots.keys()
if all_roots:
max_root = max(all_roots) + 1
smallest_n = max(max_root, smallest_n)
order += smallest_n
u0 = []
if self.is_singularics() == True:
u0 = self.y0[p]
elif self.is_singularics() == False and p >= 0 and int(p) == p and len(rootstoconsider) == 1:
y0 = _extend_y0(self, order + int(p))
# u(n) = y^n(0)/factorial(n)
if len(y0) > int(p):
for i in range(int(p), len(y0)):
u0.append(y0[i] / factorial(i))
if len(u0) < order:
for i in range(degree2, degree):
eq = S.Zero
for j in dict1:
if i + j[0] < 0:
dummys[i + j[0]] = S.Zero
elif i + j[0] < len(u0):
dummys[i + j[0]] = u0[i + j[0]]
elif not i + j[0] in dummys:
letter = chr(char) + '_%s' %(i + j[0])
dummys[i + j[0]] = Symbol(letter)
unknowns.append(dummys[i + j[0]])
if j[1] <= i:
eq += dict1[j].subs(n, i) * dummys[i + j[0]]
eqs.append(eq)
# solve the system of equations formed
soleqs = solve(eqs, *unknowns)
if isinstance(soleqs, dict):
for i in range(len(u0), order):
if i not in dummys:
letter = chr(char) + '_%s' %i
dummys[i] = Symbol(letter)
if dummys[i] in soleqs:
u0.append(soleqs[dummys[i]])
else:
u0.append(dummys[i])
if lb:
finalsol.append((HolonomicSequence(sol, u0), p, smallest_n))
continue
else:
finalsol.append((HolonomicSequence(sol, u0), p))
continue
for i in range(len(u0), order):
if i not in dummys:
letter = chr(char) + '_%s' %i
dummys[i] = Symbol(letter)
s = False
for j in soleqs:
if dummys[i] in j:
u0.append(j[dummys[i]])
s = True
if not s:
u0.append(dummys[i])
if lb:
finalsol.append((HolonomicSequence(sol, u0), p, smallest_n))
else:
finalsol.append((HolonomicSequence(sol, u0), p))
char += 1
return finalsol
def series(self, n=6, coefficient=False, order=True, _recur=None):
r"""
Finds the power series expansion of given holonomic function about :math:`x_0`.
A list of series might be returned if :math:`x_0` is a regular point with
multiple roots of the indicial equation.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import QQ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(QQ.old_poly_ring(x),'Dx')
>>> HolonomicFunction(Dx - 1, x, 0, [1]).series() # e^x
1 + x + x**2/2 + x**3/6 + x**4/24 + x**5/120 + O(x**6)
>>> HolonomicFunction(Dx**2 + 1, x, 0, [0, 1]).series(n=8) # sin(x)
x - x**3/6 + x**5/120 - x**7/5040 + O(x**8)
See Also
========
HolonomicFunction.to_sequence()
"""
if _recur is None:
recurrence = self.to_sequence()
else:
recurrence = _recur
if isinstance(recurrence, tuple) and len(recurrence) == 2:
recurrence = recurrence[0]
constantpower = 0
elif isinstance(recurrence, tuple) and len(recurrence) == 3:
constantpower = recurrence[1]
recurrence = recurrence[0]
elif len(recurrence) == 1 and len(recurrence[0]) == 2:
recurrence = recurrence[0][0]
constantpower = 0
elif len(recurrence) == 1 and len(recurrence[0]) == 3:
constantpower = recurrence[0][1]
recurrence = recurrence[0][0]
else:
sol = []
for i in recurrence:
sol.append(self.series(_recur=i))
return sol
n = n - int(constantpower)
l = len(recurrence.u0) - 1
k = recurrence.recurrence.order
x = self.x
x0 = self.x0
seq_dmp = recurrence.recurrence.listofpoly
R = recurrence.recurrence.parent.base
K = R.get_field()
seq = []
for i, j in enumerate(seq_dmp):
seq.append(K.new(j.rep))
sub = [-seq[i] / seq[k] for i in range(k)]
sol = [i for i in recurrence.u0]
if l + 1 >= n:
pass
else:
# use the initial conditions to find the next term
for i in range(l + 1 - k, n - k):
coeff = S.Zero
for j in range(k):
if i + j >= 0:
coeff += DMFsubs(sub[j], i) * sol[i + j]
sol.append(coeff)
if coefficient:
return sol
ser = S.Zero
for i, j in enumerate(sol):
ser += x**(i + constantpower) * j
if order:
ser += Order(x**(n + int(constantpower)), x)
if x0 != 0:
return ser.subs(x, x - x0)
return ser
def _indicial(self):
"""
Computes roots of the Indicial equation.
"""
if self.x0 != 0:
return self.shift_x(self.x0)._indicial()
list_coeff = self.annihilator.listofpoly
R = self.annihilator.parent.base
x = self.x
s = R.zero
y = R.one
def _pole_degree(poly):
root_all = roots(R.to_sympy(poly), x, filter='Z')
if 0 in root_all.keys():
return root_all[0]
else:
return 0
degree = [j.degree() for j in list_coeff]
degree = max(degree)
inf = 10 * (max(1, degree) + max(1, self.annihilator.order))
deg = lambda q: inf if q.is_zero else _pole_degree(q)
b = deg(list_coeff[0])
for j in range(1, len(list_coeff)):
b = min(b, deg(list_coeff[j]) - j)
for i, j in enumerate(list_coeff):
listofdmp = j.all_coeffs()
degree = len(listofdmp) - 1
if - i - b <= 0 and degree - i - b >= 0:
s = s + listofdmp[degree - i - b] * y
y *= x - i
return roots(R.to_sympy(s), x)
def evalf(self, points, method='RK4', h=0.05, derivatives=False):
r"""
Finds numerical value of a holonomic function using numerical methods.
(RK4 by default). A set of points (real or complex) must be provided
which will be the path for the numerical integration.
The path should be given as a list :math:`[x_1, x_2, ... x_n]`. The numerical
values will be computed at each point in this order
:math:`x_1 --> x_2 --> x_3 ... --> x_n`.
Returns values of the function at :math:`x_1, x_2, ... x_n` in a list.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import QQ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(QQ.old_poly_ring(x),'Dx')
A straight line on the real axis from (0 to 1)
>>> r = [0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1]
Runge-Kutta 4th order on e^x from 0.1 to 1.
Exact solution at 1 is 2.71828182845905
>>> HolonomicFunction(Dx - 1, x, 0, [1]).evalf(r)
[1.10517083333333, 1.22140257085069, 1.34985849706254, 1.49182424008069,
1.64872063859684, 1.82211796209193, 2.01375162659678, 2.22553956329232,
2.45960141378007, 2.71827974413517]
Euler's method for the same
>>> HolonomicFunction(Dx - 1, x, 0, [1]).evalf(r, method='Euler')
[1.1, 1.21, 1.331, 1.4641, 1.61051, 1.771561, 1.9487171, 2.14358881,
2.357947691, 2.5937424601]
One can also observe that the value obtained using Runge-Kutta 4th order
is much more accurate than Euler's method.
"""
from sympy.holonomic.numerical import _evalf
lp = False
# if a point `b` is given instead of a mesh
if not hasattr(points, "__iter__"):
lp = True
b = S(points)
if self.x0 == b:
return _evalf(self, [b], method=method, derivatives=derivatives)[-1]
if not b.is_Number:
raise NotImplementedError
a = self.x0
if a > b:
h = -h
n = int((b - a) / h)
points = [a + h]
for i in range(n - 1):
points.append(points[-1] + h)
for i in roots(self.annihilator.parent.base.to_sympy(self.annihilator.listofpoly[-1]), self.x):
if i == self.x0 or i in points:
raise SingularityError(self, i)
if lp:
return _evalf(self, points, method=method, derivatives=derivatives)[-1]
return _evalf(self, points, method=method, derivatives=derivatives)
def change_x(self, z):
"""
Changes only the variable of Holonomic Function, for internal
purposes. For composition use HolonomicFunction.composition()
"""
dom = self.annihilator.parent.base.dom
R = dom.old_poly_ring(z)
parent, _ = DifferentialOperators(R, 'Dx')
sol = []
for j in self.annihilator.listofpoly:
sol.append(R(j.rep))
sol = DifferentialOperator(sol, parent)
return HolonomicFunction(sol, z, self.x0, self.y0)
def shift_x(self, a):
"""
Substitute `x + a` for `x`.
"""
x = self.x
listaftershift = self.annihilator.listofpoly
base = self.annihilator.parent.base
sol = [base.from_sympy(base.to_sympy(i).subs(x, x + a)) for i in listaftershift]
sol = DifferentialOperator(sol, self.annihilator.parent)
x0 = self.x0 - a
if not self._have_init_cond():
return HolonomicFunction(sol, x)
return HolonomicFunction(sol, x, x0, self.y0)
def to_hyper(self, as_list=False, _recur=None):
r"""
Returns a hypergeometric function (or linear combination of them)
representing the given holonomic function.
Returns an answer of the form:
`a_1 \cdot x^{b_1} \cdot{hyper()} + a_2 \cdot x^{b_2} \cdot{hyper()} ...`
This is very useful as one can now use ``hyperexpand`` to find the
symbolic expressions/functions.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(ZZ.old_poly_ring(x),'Dx')
>>> # sin(x)
>>> HolonomicFunction(Dx**2 + 1, x, 0, [0, 1]).to_hyper()
x*hyper((), (3/2,), -x**2/4)
>>> # exp(x)
>>> HolonomicFunction(Dx - 1, x, 0, [1]).to_hyper()
hyper((), (), x)
See Also
========
from_hyper, from_meijerg
"""
if _recur is None:
recurrence = self.to_sequence()
else:
recurrence = _recur
if isinstance(recurrence, tuple) and len(recurrence) == 2:
smallest_n = recurrence[1]
recurrence = recurrence[0]
constantpower = 0
elif isinstance(recurrence, tuple) and len(recurrence) == 3:
smallest_n = recurrence[2]
constantpower = recurrence[1]
recurrence = recurrence[0]
elif len(recurrence) == 1 and len(recurrence[0]) == 2:
smallest_n = recurrence[0][1]
recurrence = recurrence[0][0]
constantpower = 0
elif len(recurrence) == 1 and len(recurrence[0]) == 3:
smallest_n = recurrence[0][2]
constantpower = recurrence[0][1]
recurrence = recurrence[0][0]
else:
sol = self.to_hyper(as_list=as_list, _recur=recurrence[0])
for i in recurrence[1:]:
sol += self.to_hyper(as_list=as_list, _recur=i)
return sol
u0 = recurrence.u0
r = recurrence.recurrence
x = self.x
x0 = self.x0
# order of the recurrence relation
m = r.order
# when no recurrence exists, and the power series have finite terms
if m == 0:
nonzeroterms = roots(r.parent.base.to_sympy(r.listofpoly[0]), recurrence.n, filter='R')
sol = S.Zero
for j, i in enumerate(nonzeroterms):
if i < 0 or int(i) != i:
continue
i = int(i)
if i < len(u0):
if isinstance(u0[i], (PolyElement, FracElement)):
u0[i] = u0[i].as_expr()
sol += u0[i] * x**i
else:
sol += Symbol('C_%s' %j) * x**i
if isinstance(sol, (PolyElement, FracElement)):
sol = sol.as_expr() * x**constantpower
else:
sol = sol * x**constantpower
if as_list:
if x0 != 0:
return [(sol.subs(x, x - x0), )]
return [(sol, )]
if x0 != 0:
return sol.subs(x, x - x0)
return sol
if smallest_n + m > len(u0):
raise NotImplementedError("Can't compute sufficient Initial Conditions")
# check if the recurrence represents a hypergeometric series
is_hyper = True
for i in range(1, len(r.listofpoly)-1):
if r.listofpoly[i] != r.parent.base.zero:
is_hyper = False
break
if not is_hyper:
raise NotHyperSeriesError(self, self.x0)
a = r.listofpoly[0]
b = r.listofpoly[-1]
# the constant multiple of argument of hypergeometric function
if isinstance(a.rep[0], (PolyElement, FracElement)):
c = - (S(a.rep[0].as_expr()) * m**(a.degree())) / (S(b.rep[0].as_expr()) * m**(b.degree()))
else:
c = - (S(a.rep[0]) * m**(a.degree())) / (S(b.rep[0]) * m**(b.degree()))
sol = 0
arg1 = roots(r.parent.base.to_sympy(a), recurrence.n)
arg2 = roots(r.parent.base.to_sympy(b), recurrence.n)
# iterate through the initial conditions to find
# the hypergeometric representation of the given
# function.
# The answer will be a linear combination
# of different hypergeometric series which satisfies
# the recurrence.
if as_list:
listofsol = []
for i in range(smallest_n + m):
# if the recurrence relation doesn't hold for `n = i`,
# then a Hypergeometric representation doesn't exist.
# add the algebraic term a * x**i to the solution,
# where a is u0[i]
if i < smallest_n:
if as_list:
listofsol.append(((S(u0[i]) * x**(i+constantpower)).subs(x, x-x0), ))
else:
sol += S(u0[i]) * x**i
continue
# if the coefficient u0[i] is zero, then the
# independent hypergeomtric series starting with
# x**i is not a part of the answer.
if S(u0[i]) == 0:
continue
ap = []
bq = []
# substitute m * n + i for n
for k in ordered(arg1.keys()):
ap.extend([nsimplify((i - k) / m)] * arg1[k])
for k in ordered(arg2.keys()):
bq.extend([nsimplify((i - k) / m)] * arg2[k])
# convention of (k + 1) in the denominator
if 1 in bq:
bq.remove(1)
else:
ap.append(1)
if as_list:
listofsol.append(((S(u0[i])*x**(i+constantpower)).subs(x, x-x0), (hyper(ap, bq, c*x**m)).subs(x, x-x0)))
else:
sol += S(u0[i]) * hyper(ap, bq, c * x**m) * x**i
if as_list:
return listofsol
sol = sol * x**constantpower
if x0 != 0:
return sol.subs(x, x - x0)
return sol
def to_expr(self):
"""
Converts a Holonomic Function back to elementary functions.
Examples
========
>>> from sympy.holonomic.holonomic import HolonomicFunction, DifferentialOperators
>>> from sympy.polys.domains import ZZ
>>> from sympy import symbols, S
>>> x = symbols('x')
>>> R, Dx = DifferentialOperators(ZZ.old_poly_ring(x),'Dx')
>>> HolonomicFunction(x**2*Dx**2 + x*Dx + (x**2 - 1), x, 0, [0, S(1)/2]).to_expr()
besselj(1, x)
>>> HolonomicFunction((1 + x)*Dx**3 + Dx**2, x, 0, [1, 1, 1]).to_expr()
x*log(x + 1) + log(x + 1) + 1
"""
return hyperexpand(self.to_hyper()).simplify()
def change_ics(self, b, lenics=None):
"""
Changes the point `x0` to `b` for initial conditions.
Examples
========
>>> from sympy.holonomic import expr_to_holonomic
>>> from sympy import symbols, sin, exp
>>> x = symbols('x')
>>> expr_to_holonomic(sin(x)).change_ics(1)
HolonomicFunction((1) + (1)*Dx**2, x, 1, [sin(1), cos(1)])
>>> expr_to_holonomic(exp(x)).change_ics(2)
HolonomicFunction((-1) + (1)*Dx, x, 2, [exp(2)])
"""
symbolic = True
if lenics is None and len(self.y0) > self.annihilator.order:
lenics = len(self.y0)
dom = self.annihilator.parent.base.domain
try:
sol = expr_to_holonomic(self.to_expr(), x=self.x, x0=b, lenics=lenics, domain=dom)
except (NotPowerSeriesError, NotHyperSeriesError):
symbolic = False
if symbolic and sol.x0 == b:
return sol
y0 = self.evalf(b, derivatives=True)
return HolonomicFunction(self.annihilator, self.x, b, y0)
def to_meijerg(self):
"""
Returns a linear combination of Meijer G-functions.
Examples
========
>>> from sympy.holonomic import expr_to_holonomic
>>> from sympy import sin, cos, hyperexpand, log, symbols
>>> x = symbols('x')
>>> hyperexpand(expr_to_holonomic(cos(x) + sin(x)).to_meijerg())
sin(x) + cos(x)
>>> hyperexpand(expr_to_holonomic(log(x)).to_meijerg()).simplify()
log(x)
See Also
========
to_hyper()
"""
# convert to hypergeometric first
rep = self.to_hyper(as_list=True)
sol = S.Zero
for i in rep:
if len(i) == 1:
sol += i[0]
elif len(i) == 2:
sol += i[0] * _hyper_to_meijerg(i[1])
return sol
def from_hyper(func, x0=0, evalf=False):
r"""
Converts a hypergeometric function to holonomic.
``func`` is the Hypergeometric Function and ``x0`` is the point at
which initial conditions are required.
Examples
========
>>> from sympy.holonomic.holonomic import from_hyper
>>> from sympy import symbols, hyper, S
>>> x = symbols('x')
>>> from_hyper(hyper([], [S(3)/2], x**2/4))
HolonomicFunction((-x) + (2)*Dx + (x)*Dx**2, x, 1, [sinh(1), -sinh(1) + cosh(1)])
"""
a = func.ap
b = func.bq
z = func.args[2]
x = z.atoms(Symbol).pop()
R, Dx = DifferentialOperators(QQ.old_poly_ring(x), 'Dx')
# generalized hypergeometric differential equation
r1 = 1
for i in range(len(a)):
r1 = r1 * (x * Dx + a[i])
r2 = Dx
for i in range(len(b)):
r2 = r2 * (x * Dx + b[i] - 1)
sol = r1 - r2
simp = hyperexpand(func)
if isinstance(simp, Infinity) or isinstance(simp, NegativeInfinity):
return HolonomicFunction(sol, x).composition(z)
def _find_conditions(simp, x, x0, order, evalf=False):
y0 = []
for i in range(order):
if evalf:
val = simp.subs(x, x0).evalf()
else:
val = simp.subs(x, x0)
# return None if it is Infinite or NaN
if val.is_finite is False or isinstance(val, NaN):
return None
y0.append(val)
simp = simp.diff(x)
return y0
# if the function is known symbolically
if not isinstance(simp, hyper):
y0 = _find_conditions(simp, x, x0, sol.order)
while not y0:
# if values don't exist at 0, then try to find initial
# conditions at 1. If it doesn't exist at 1 too then
# try 2 and so on.
x0 += 1
y0 = _find_conditions(simp, x, x0, sol.order)
return HolonomicFunction(sol, x).composition(z, x0, y0)
if isinstance(simp, hyper):
x0 = 1
# use evalf if the function can't be simplified
y0 = _find_conditions(simp, x, x0, sol.order, evalf)
while not y0:
x0 += 1
y0 = _find_conditions(simp, x, x0, sol.order, evalf)
return HolonomicFunction(sol, x).composition(z, x0, y0)
return HolonomicFunction(sol, x).composition(z)
def from_meijerg(func, x0=0, evalf=False, initcond=True, domain=QQ):
"""
Converts a Meijer G-function to Holonomic.
``func`` is the G-Function and ``x0`` is the point at
which initial conditions are required.
Examples
========
>>> from sympy.holonomic.holonomic import from_meijerg
>>> from sympy import symbols, meijerg, S
>>> x = symbols('x')
>>> from_meijerg(meijerg(([], []), ([S(1)/2], [0]), x**2/4))
HolonomicFunction((1) + (1)*Dx**2, x, 0, [0, 1/sqrt(pi)])
"""
a = func.ap
b = func.bq
n = len(func.an)
m = len(func.bm)
p = len(a)
z = func.args[2]
x = z.atoms(Symbol).pop()
R, Dx = DifferentialOperators(domain.old_poly_ring(x), 'Dx')
# compute the differential equation satisfied by the
# Meijer G-function.
mnp = (-1)**(m + n - p)
r1 = x * mnp
for i in range(len(a)):
r1 *= x * Dx + 1 - a[i]
r2 = 1
for i in range(len(b)):
r2 *= x * Dx - b[i]
sol = r1 - r2
if not initcond:
return HolonomicFunction(sol, x).composition(z)
simp = hyperexpand(func)
if isinstance(simp, Infinity) or isinstance(simp, NegativeInfinity):
return HolonomicFunction(sol, x).composition(z)
def _find_conditions(simp, x, x0, order, evalf=False):
y0 = []
for i in range(order):
if evalf:
val = simp.subs(x, x0).evalf()
else:
val = simp.subs(x, x0)
if val.is_finite is False or isinstance(val, NaN):
return None
y0.append(val)
simp = simp.diff(x)
return y0
# computing initial conditions
if not isinstance(simp, meijerg):
y0 = _find_conditions(simp, x, x0, sol.order)
while not y0:
x0 += 1
y0 = _find_conditions(simp, x, x0, sol.order)
return HolonomicFunction(sol, x).composition(z, x0, y0)
if isinstance(simp, meijerg):
x0 = 1
y0 = _find_conditions(simp, x, x0, sol.order, evalf)
while not y0:
x0 += 1
y0 = _find_conditions(simp, x, x0, sol.order, evalf)
return HolonomicFunction(sol, x).composition(z, x0, y0)
return HolonomicFunction(sol, x).composition(z)
x_1 = Dummy('x_1')
_lookup_table = None
domain_for_table = None
from sympy.integrals.meijerint import _mytype
def expr_to_holonomic(func, x=None, x0=0, y0=None, lenics=None, domain=None, initcond=True):
"""
Converts a function or an expression to a holonomic function.
Parameters
==========
func:
The expression to be converted.
x:
variable for the function.
x0:
point at which initial condition must be computed.
y0:
One can optionally provide initial condition if the method
isn't able to do it automatically.
lenics:
Number of terms in the initial condition. By default it is
equal to the order of the annihilator.
domain:
Ground domain for the polynomials in `x` appearing as coefficients
in the annihilator.
initcond:
Set it false if you don't want the initial conditions to be computed.
Examples
========
>>> from sympy.holonomic.holonomic import expr_to_holonomic
>>> from sympy import sin, exp, symbols
>>> x = symbols('x')
>>> expr_to_holonomic(sin(x))
HolonomicFunction((1) + (1)*Dx**2, x, 0, [0, 1])
>>> expr_to_holonomic(exp(x))
HolonomicFunction((-1) + (1)*Dx, x, 0, [1])
See Also
========
sympy.integrals.meijerint._rewrite1, _convert_poly_rat_alg, _create_table
"""
func = sympify(func)
syms = func.free_symbols
if not x:
if len(syms) == 1:
x= syms.pop()
else:
raise ValueError("Specify the variable for the function")
elif x in syms:
syms.remove(x)
extra_syms = list(syms)
if domain is None:
if func.has(Float):
domain = RR
else:
domain = QQ
if len(extra_syms) != 0:
domain = domain[extra_syms].get_field()
# try to convert if the function is polynomial or rational
solpoly = _convert_poly_rat_alg(func, x, x0=x0, y0=y0, lenics=lenics, domain=domain, initcond=initcond)
if solpoly:
return solpoly
# create the lookup table
global _lookup_table, domain_for_table
if not _lookup_table:
domain_for_table = domain
_lookup_table = {}
_create_table(_lookup_table, domain=domain)
elif domain != domain_for_table:
domain_for_table = domain
_lookup_table = {}
_create_table(_lookup_table, domain=domain)
# use the table directly to convert to Holonomic
if func.is_Function:
f = func.subs(x, x_1)
t = _mytype(f, x_1)
if t in _lookup_table:
l = _lookup_table[t]
sol = l[0][1].change_x(x)
else:
sol = _convert_meijerint(func, x, initcond=False, domain=domain)
if not sol:
raise NotImplementedError
if y0:
sol.y0 = y0
if y0 or not initcond:
sol.x0 = x0
return sol
if not lenics:
lenics = sol.annihilator.order
_y0 = _find_conditions(func, x, x0, lenics)
while not _y0:
x0 += 1
_y0 = _find_conditions(func, x, x0, lenics)
return HolonomicFunction(sol.annihilator, x, x0, _y0)
if y0 or not initcond:
sol = sol.composition(func.args[0])
if y0:
sol.y0 = y0
sol.x0 = x0
return sol
if not lenics:
lenics = sol.annihilator.order
_y0 = _find_conditions(func, x, x0, lenics)
while not _y0:
x0 += 1
_y0 = _find_conditions(func, x, x0, lenics)
return sol.composition(func.args[0], x0, _y0)
# iterate through the expression recursively
args = func.args
f = func.func
from sympy.core import Add, Mul, Pow
sol = expr_to_holonomic(args[0], x=x, initcond=False, domain=domain)
if f is Add:
for i in range(1, len(args)):
sol += expr_to_holonomic(args[i], x=x, initcond=False, domain=domain)
elif f is Mul:
for i in range(1, len(args)):
sol *= expr_to_holonomic(args[i], x=x, initcond=False, domain=domain)
elif f is Pow:
sol = sol**args[1]
sol.x0 = x0
if not sol:
raise NotImplementedError
if y0:
sol.y0 = y0
if y0 or not initcond:
return sol
if sol.y0:
return sol
if not lenics:
lenics = sol.annihilator.order
if sol.annihilator.is_singular(x0):
r = sol._indicial()
l = list(r)
if len(r) == 1 and r[l[0]] == S.One:
r = l[0]
g = func / (x - x0)**r
singular_ics = _find_conditions(g, x, x0, lenics)
singular_ics = [j / factorial(i) for i, j in enumerate(singular_ics)]
y0 = {r:singular_ics}
return HolonomicFunction(sol.annihilator, x, x0, y0)
_y0 = _find_conditions(func, x, x0, lenics)
while not _y0:
x0 += 1
_y0 = _find_conditions(func, x, x0, lenics)
return HolonomicFunction(sol.annihilator, x, x0, _y0)
## Some helper functions ##
def _normalize(list_of, parent, negative=True):
"""
Normalize a given annihilator
"""
num = []
denom = []
base = parent.base
K = base.get_field()
lcm_denom = base.from_sympy(S.One)
list_of_coeff = []
# convert polynomials to the elements of associated
# fraction field
for i, j in enumerate(list_of):
if isinstance(j, base.dtype):
list_of_coeff.append(K.new(j.rep))
elif not isinstance(j, K.dtype):
list_of_coeff.append(K.from_sympy(sympify(j)))
else:
list_of_coeff.append(j)
# corresponding numerators of the sequence of polynomials
num.append(list_of_coeff[i].numer())
# corresponding denominators
denom.append(list_of_coeff[i].denom())
# lcm of denominators in the coefficients
for i in denom:
lcm_denom = i.lcm(lcm_denom)
if negative:
lcm_denom = -lcm_denom
lcm_denom = K.new(lcm_denom.rep)
# multiply the coefficients with lcm
for i, j in enumerate(list_of_coeff):
list_of_coeff[i] = j * lcm_denom
gcd_numer = base((list_of_coeff[-1].numer() / list_of_coeff[-1].denom()).rep)
# gcd of numerators in the coefficients
for i in num:
gcd_numer = i.gcd(gcd_numer)
gcd_numer = K.new(gcd_numer.rep)
# divide all the coefficients by the gcd
for i, j in enumerate(list_of_coeff):
frac_ans = j / gcd_numer
list_of_coeff[i] = base((frac_ans.numer() / frac_ans.denom()).rep)
return DifferentialOperator(list_of_coeff, parent)
def _derivate_diff_eq(listofpoly):
"""
Let a differential equation a0(x)y(x) + a1(x)y'(x) + ... = 0
where a0, a1,... are polynomials or rational functions. The function
returns b0, b1, b2... such that the differential equation
b0(x)y(x) + b1(x)y'(x) +... = 0 is formed after differentiating the
former equation.
"""
sol = []
a = len(listofpoly) - 1
sol.append(DMFdiff(listofpoly[0]))
for i, j in enumerate(listofpoly[1:]):
sol.append(DMFdiff(j) + listofpoly[i])
sol.append(listofpoly[a])
return sol
def _hyper_to_meijerg(func):
"""
Converts a `hyper` to meijerg.
"""
ap = func.ap
bq = func.bq
ispoly = any(i <= 0 and int(i) == i for i in ap)
if ispoly:
return hyperexpand(func)
z = func.args[2]
# parameters of the `meijerg` function.
an = (1 - i for i in ap)
anp = ()
bm = (S.Zero, )
bmq = (1 - i for i in bq)
k = S.One
for i in bq:
k = k * gamma(i)
for i in ap:
k = k / gamma(i)
return k * meijerg(an, anp, bm, bmq, -z)
def _add_lists(list1, list2):
"""Takes polynomial sequences of two annihilators a and b and returns
the list of polynomials of sum of a and b.
"""
if len(list1) <= len(list2):
sol = [a + b for a, b in zip(list1, list2)] + list2[len(list1):]
else:
sol = [a + b for a, b in zip(list1, list2)] + list1[len(list2):]
return sol
def _extend_y0(Holonomic, n):
"""
Tries to find more initial conditions by substituting the initial
value point in the differential equation.
"""
if Holonomic.annihilator.is_singular(Holonomic.x0) or Holonomic.is_singularics() == True:
return Holonomic.y0
annihilator = Holonomic.annihilator
a = annihilator.order
listofpoly = []
y0 = Holonomic.y0
R = annihilator.parent.base
K = R.get_field()
for i, j in enumerate(annihilator.listofpoly):
if isinstance(j, annihilator.parent.base.dtype):
listofpoly.append(K.new(j.rep))
if len(y0) < a or n <= len(y0):
return y0
else:
list_red = [-listofpoly[i] / listofpoly[a]
for i in range(a)]
if len(y0) > a:
y1 = [y0[i] for i in range(a)]
else:
y1 = [i for i in y0]
for i in range(n - a):
sol = 0
for a, b in zip(y1, list_red):
r = DMFsubs(b, Holonomic.x0)
if not getattr(r, 'is_finite', True):
return y0
if isinstance(r, (PolyElement, FracElement)):
r = r.as_expr()
sol += a * r
y1.append(sol)
list_red = _derivate_diff_eq(list_red)
return y0 + y1[len(y0):]
def DMFdiff(frac):
# differentiate a DMF object represented as p/q
if not isinstance(frac, DMF):
return frac.diff()
K = frac.ring
p = K.numer(frac)
q = K.denom(frac)
sol_num = - p * q.diff() + q * p.diff()
sol_denom = q**2
return K((sol_num.rep, sol_denom.rep))
def DMFsubs(frac, x0, mpm=False):
# substitute the point x0 in DMF object of the form p/q
if not isinstance(frac, DMF):
return frac
p = frac.num
q = frac.den
sol_p = S.Zero
sol_q = S.Zero
if mpm:
from mpmath import mp
for i, j in enumerate(reversed(p)):
if mpm:
j = sympify(j)._to_mpmath(mp.prec)
sol_p += j * x0**i
for i, j in enumerate(reversed(q)):
if mpm:
j = sympify(j)._to_mpmath(mp.prec)
sol_q += j * x0**i
if isinstance(sol_p, (PolyElement, FracElement)):
sol_p = sol_p.as_expr()
if isinstance(sol_q, (PolyElement, FracElement)):
sol_q = sol_q.as_expr()
return sol_p / sol_q
def _convert_poly_rat_alg(func, x, x0=0, y0=None, lenics=None, domain=QQ, initcond=True):
"""
Converts polynomials, rationals and algebraic functions to holonomic.
"""
ispoly = func.is_polynomial()
if not ispoly:
israt = func.is_rational_function()
else:
israt = True
if not (ispoly or israt):
basepoly, ratexp = func.as_base_exp()
if basepoly.is_polynomial() and ratexp.is_Number:
if isinstance(ratexp, Float):
ratexp = nsimplify(ratexp)
m, n = ratexp.p, ratexp.q
is_alg = True
else:
is_alg = False
else:
is_alg = True
if not (ispoly or israt or is_alg):
return None
R = domain.old_poly_ring(x)
_, Dx = DifferentialOperators(R, 'Dx')
# if the function is constant
if not func.has(x):
return HolonomicFunction(Dx, x, 0, [func])
if ispoly:
# differential equation satisfied by polynomial
sol = func * Dx - func.diff(x)
sol = _normalize(sol.listofpoly, sol.parent, negative=False)
is_singular = sol.is_singular(x0)
# try to compute the conditions for singular points
if y0 is None and x0 == 0 and is_singular:
rep = R.from_sympy(func).rep
for i, j in enumerate(reversed(rep)):
if j == 0:
continue
else:
coeff = list(reversed(rep))[i:]
indicial = i
break
for i, j in enumerate(coeff):
if isinstance(j, (PolyElement, FracElement)):
coeff[i] = j.as_expr()
y0 = {indicial: S(coeff)}
elif israt:
p, q = func.as_numer_denom()
# differential equation satisfied by rational
sol = p * q * Dx + p * q.diff(x) - q * p.diff(x)
sol = _normalize(sol.listofpoly, sol.parent, negative=False)
elif is_alg:
sol = n * (x / m) * Dx - 1
sol = HolonomicFunction(sol, x).composition(basepoly).annihilator
is_singular = sol.is_singular(x0)
# try to compute the conditions for singular points
if y0 is None and x0 == 0 and is_singular and \
(lenics is None or lenics <= 1):
rep = R.from_sympy(basepoly).rep
for i, j in enumerate(reversed(rep)):
if j == 0:
continue
if isinstance(j, (PolyElement, FracElement)):
j = j.as_expr()
coeff = S(j)**ratexp
indicial = S(i) * ratexp
break
if isinstance(coeff, (PolyElement, FracElement)):
coeff = coeff.as_expr()
y0 = {indicial: S([coeff])}
if y0 or not initcond:
return HolonomicFunction(sol, x, x0, y0)
if not lenics:
lenics = sol.order
if sol.is_singular(x0):
r = HolonomicFunction(sol, x, x0)._indicial()
l = list(r)
if len(r) == 1 and r[l[0]] == S.One:
r = l[0]
g = func / (x - x0)**r
singular_ics = _find_conditions(g, x, x0, lenics)
singular_ics = [j / factorial(i) for i, j in enumerate(singular_ics)]
y0 = {r:singular_ics}
return HolonomicFunction(sol, x, x0, y0)
y0 = _find_conditions(func, x, x0, lenics)
while not y0:
x0 += 1
y0 = _find_conditions(func, x, x0, lenics)
return HolonomicFunction(sol, x, x0, y0)
def _convert_meijerint(func, x, initcond=True, domain=QQ):
args = meijerint._rewrite1(func, x)
if args:
fac, po, g, _ = args
else:
return None
# lists for sum of meijerg functions
fac_list = [fac * i[0] for i in g]
t = po.as_base_exp()
s = t[1] if t[0] == x else S.Zero
po_list = [s + i[1] for i in g]
G_list = [i[2] for i in g]
# finds meijerg representation of x**s * meijerg(a1 ... ap, b1 ... bq, z)
def _shift(func, s):
z = func.args[-1]
if z.has(I):
z = z.subs(exp_polar, exp)
d = z.collect(x, evaluate=False)
b = list(d)[0]
a = d[b]
t = b.as_base_exp()
b = t[1] if t[0] == x else S.Zero
r = s / b
an = (i + r for i in func.args[0][0])
ap = (i + r for i in func.args[0][1])
bm = (i + r for i in func.args[1][0])
bq = (i + r for i in func.args[1][1])
return a**-r, meijerg((an, ap), (bm, bq), z)
coeff, m = _shift(G_list[0], po_list[0])
sol = fac_list[0] * coeff * from_meijerg(m, initcond=initcond, domain=domain)
# add all the meijerg functions after converting to holonomic
for i in range(1, len(G_list)):
coeff, m = _shift(G_list[i], po_list[i])
sol += fac_list[i] * coeff * from_meijerg(m, initcond=initcond, domain=domain)
return sol
def _create_table(table, domain=QQ):
"""
Creates the look-up table. For a similar implementation
see meijerint._create_lookup_table.
"""
def add(formula, annihilator, arg, x0=0, y0=[]):
"""
Adds a formula in the dictionary
"""
table.setdefault(_mytype(formula, x_1), []).append((formula,
HolonomicFunction(annihilator, arg, x0, y0)))
R = domain.old_poly_ring(x_1)
_, Dx = DifferentialOperators(R, 'Dx')
from sympy import (sin, cos, exp, log, erf, sqrt, pi,
sinh, cosh, sinc, erfc, Si, Ci, Shi, erfi)
# add some basic functions
add(sin(x_1), Dx**2 + 1, x_1, 0, [0, 1])
add(cos(x_1), Dx**2 + 1, x_1, 0, [1, 0])
add(exp(x_1), Dx - 1, x_1, 0, 1)
add(log(x_1), Dx + x_1*Dx**2, x_1, 1, [0, 1])
add(erf(x_1), 2*x_1*Dx + Dx**2, x_1, 0, [0, 2/sqrt(pi)])
add(erfc(x_1), 2*x_1*Dx + Dx**2, x_1, 0, [1, -2/sqrt(pi)])
add(erfi(x_1), -2*x_1*Dx + Dx**2, x_1, 0, [0, 2/sqrt(pi)])
add(sinh(x_1), Dx**2 - 1, x_1, 0, [0, 1])
add(cosh(x_1), Dx**2 - 1, x_1, 0, [1, 0])
add(sinc(x_1), x_1 + 2*Dx + x_1*Dx**2, x_1)
add(Si(x_1), x_1*Dx + 2*Dx**2 + x_1*Dx**3, x_1)
add(Ci(x_1), x_1*Dx + 2*Dx**2 + x_1*Dx**3, x_1)
add(Shi(x_1), -x_1*Dx + 2*Dx**2 + x_1*Dx**3, x_1)
def _find_conditions(func, x, x0, order):
y0 = []
for i in range(order):
val = func.subs(x, x0)
if isinstance(val, NaN):
val = limit(func, x, x0)
if val.is_finite is False or isinstance(val, NaN):
return None
y0.append(val)
func = func.diff(x)
return y0
|
e7908c2f23060bbcacf7c3bc25ed0b9db46bf89f74a75ce47e7580ecf43cd280 | # -*- coding: utf-8 -*-
r"""
Wigner, Clebsch-Gordan, Racah, and Gaunt coefficients
Collection of functions for calculating Wigner 3j, 6j, 9j,
Clebsch-Gordan, Racah as well as Gaunt coefficients exactly, all
evaluating to a rational number times the square root of a rational
number [Rasch03]_.
Please see the description of the individual functions for further
details and examples.
References
~~~~~~~~~~
.. [Regge58] 'Symmetry Properties of Clebsch-Gordan Coefficients',
T. Regge, Nuovo Cimento, Volume 10, pp. 544 (1958)
.. [Regge59] 'Symmetry Properties of Racah Coefficients',
T. Regge, Nuovo Cimento, Volume 11, pp. 116 (1959)
.. [Edmonds74] A. R. Edmonds. Angular momentum in quantum mechanics.
Investigations in physics, 4.; Investigations in physics, no. 4.
Princeton, N.J., Princeton University Press, 1957.
.. [Rasch03] J. Rasch and A. C. H. Yu, 'Efficient Storage Scheme for
Pre-calculated Wigner 3j, 6j and Gaunt Coefficients', SIAM
J. Sci. Comput. Volume 25, Issue 4, pp. 1416-1428 (2003)
.. [Liberatodebrito82] 'FORTRAN program for the integral of three
spherical harmonics', A. Liberato de Brito,
Comput. Phys. Commun., Volume 25, pp. 81-85 (1982)
Credits and Copyright
~~~~~~~~~~~~~~~~~~~~~
This code was taken from Sage with the permission of all authors:
https://groups.google.com/forum/#!topic/sage-devel/M4NZdu-7O38
AUTHORS:
- Jens Rasch (2009-03-24): initial version for Sage
- Jens Rasch (2009-05-31): updated to sage-4.0
- Oscar Gerardo Lazo Arjona (2017-06-18): added Wigner D matrices
Copyright (C) 2008 Jens Rasch <[email protected]>
"""
from __future__ import print_function, division
from sympy import (Integer, pi, sqrt, sympify, Dummy, S, Sum, Ynm, zeros,
Function, sin, cos, exp, I, factorial, binomial,
Add, ImmutableMatrix)
# This list of precomputed factorials is needed to massively
# accelerate future calculations of the various coefficients
_Factlist = [1]
def _calc_factlist(nn):
r"""
Function calculates a list of precomputed factorials in order to
massively accelerate future calculations of the various
coefficients.
INPUT:
- ``nn`` - integer, highest factorial to be computed
OUTPUT:
list of integers -- the list of precomputed factorials
EXAMPLES:
Calculate list of factorials::
sage: from sage.functions.wigner import _calc_factlist
sage: _calc_factlist(10)
[1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800]
"""
if nn >= len(_Factlist):
for ii in range(len(_Factlist), int(nn + 1)):
_Factlist.append(_Factlist[ii - 1] * ii)
return _Factlist[:int(nn) + 1]
def wigner_3j(j_1, j_2, j_3, m_1, m_2, m_3):
r"""
Calculate the Wigner 3j symbol `\operatorname{Wigner3j}(j_1,j_2,j_3,m_1,m_2,m_3)`.
INPUT:
- ``j_1``, ``j_2``, ``j_3``, ``m_1``, ``m_2``, ``m_3`` - integer or half integer
OUTPUT:
Rational number times the square root of a rational number.
Examples
========
>>> from sympy.physics.wigner import wigner_3j
>>> wigner_3j(2, 6, 4, 0, 0, 0)
sqrt(715)/143
>>> wigner_3j(2, 6, 4, 0, 0, 1)
0
It is an error to have arguments that are not integer or half
integer values::
sage: wigner_3j(2.1, 6, 4, 0, 0, 0)
Traceback (most recent call last):
...
ValueError: j values must be integer or half integer
sage: wigner_3j(2, 6, 4, 1, 0, -1.1)
Traceback (most recent call last):
...
ValueError: m values must be integer or half integer
NOTES:
The Wigner 3j symbol obeys the following symmetry rules:
- invariant under any permutation of the columns (with the
exception of a sign change where `J:=j_1+j_2+j_3`):
.. math::
\begin{aligned}
\operatorname{Wigner3j}(j_1,j_2,j_3,m_1,m_2,m_3)
&=\operatorname{Wigner3j}(j_3,j_1,j_2,m_3,m_1,m_2) \\
&=\operatorname{Wigner3j}(j_2,j_3,j_1,m_2,m_3,m_1) \\
&=(-1)^J \operatorname{Wigner3j}(j_3,j_2,j_1,m_3,m_2,m_1) \\
&=(-1)^J \operatorname{Wigner3j}(j_1,j_3,j_2,m_1,m_3,m_2) \\
&=(-1)^J \operatorname{Wigner3j}(j_2,j_1,j_3,m_2,m_1,m_3)
\end{aligned}
- invariant under space inflection, i.e.
.. math::
\operatorname{Wigner3j}(j_1,j_2,j_3,m_1,m_2,m_3)
=(-1)^J \operatorname{Wigner3j}(j_1,j_2,j_3,-m_1,-m_2,-m_3)
- symmetric with respect to the 72 additional symmetries based on
the work by [Regge58]_
- zero for `j_1`, `j_2`, `j_3` not fulfilling triangle relation
- zero for `m_1 + m_2 + m_3 \neq 0`
- zero for violating any one of the conditions
`j_1 \ge |m_1|`, `j_2 \ge |m_2|`, `j_3 \ge |m_3|`
ALGORITHM:
This function uses the algorithm of [Edmonds74]_ to calculate the
value of the 3j symbol exactly. Note that the formula contains
alternating sums over large factorials and is therefore unsuitable
for finite precision arithmetic and only useful for a computer
algebra system [Rasch03]_.
AUTHORS:
- Jens Rasch (2009-03-24): initial version
"""
if int(j_1 * 2) != j_1 * 2 or int(j_2 * 2) != j_2 * 2 or \
int(j_3 * 2) != j_3 * 2:
raise ValueError("j values must be integer or half integer")
if int(m_1 * 2) != m_1 * 2 or int(m_2 * 2) != m_2 * 2 or \
int(m_3 * 2) != m_3 * 2:
raise ValueError("m values must be integer or half integer")
if m_1 + m_2 + m_3 != 0:
return 0
prefid = Integer((-1) ** int(j_1 - j_2 - m_3))
m_3 = -m_3
a1 = j_1 + j_2 - j_3
if a1 < 0:
return 0
a2 = j_1 - j_2 + j_3
if a2 < 0:
return 0
a3 = -j_1 + j_2 + j_3
if a3 < 0:
return 0
if (abs(m_1) > j_1) or (abs(m_2) > j_2) or (abs(m_3) > j_3):
return 0
maxfact = max(j_1 + j_2 + j_3 + 1, j_1 + abs(m_1), j_2 + abs(m_2),
j_3 + abs(m_3))
_calc_factlist(int(maxfact))
argsqrt = Integer(_Factlist[int(j_1 + j_2 - j_3)] *
_Factlist[int(j_1 - j_2 + j_3)] *
_Factlist[int(-j_1 + j_2 + j_3)] *
_Factlist[int(j_1 - m_1)] *
_Factlist[int(j_1 + m_1)] *
_Factlist[int(j_2 - m_2)] *
_Factlist[int(j_2 + m_2)] *
_Factlist[int(j_3 - m_3)] *
_Factlist[int(j_3 + m_3)]) / \
_Factlist[int(j_1 + j_2 + j_3 + 1)]
ressqrt = sqrt(argsqrt)
if ressqrt.is_complex or ressqrt.is_infinite:
ressqrt = ressqrt.as_real_imag()[0]
imin = max(-j_3 + j_1 + m_2, -j_3 + j_2 - m_1, 0)
imax = min(j_2 + m_2, j_1 - m_1, j_1 + j_2 - j_3)
sumres = 0
for ii in range(int(imin), int(imax) + 1):
den = _Factlist[ii] * \
_Factlist[int(ii + j_3 - j_1 - m_2)] * \
_Factlist[int(j_2 + m_2 - ii)] * \
_Factlist[int(j_1 - ii - m_1)] * \
_Factlist[int(ii + j_3 - j_2 + m_1)] * \
_Factlist[int(j_1 + j_2 - j_3 - ii)]
sumres = sumres + Integer((-1) ** ii) / den
res = ressqrt * sumres * prefid
return res
def clebsch_gordan(j_1, j_2, j_3, m_1, m_2, m_3):
r"""
Calculates the Clebsch-Gordan coefficient
`\left\langle j_1 m_1 \; j_2 m_2 | j_3 m_3 \right\rangle`.
The reference for this function is [Edmonds74]_.
INPUT:
- ``j_1``, ``j_2``, ``j_3``, ``m_1``, ``m_2``, ``m_3`` - integer or half integer
OUTPUT:
Rational number times the square root of a rational number.
EXAMPLES::
>>> from sympy import S
>>> from sympy.physics.wigner import clebsch_gordan
>>> clebsch_gordan(S(3)/2, S(1)/2, 2, S(3)/2, S(1)/2, 2)
1
>>> clebsch_gordan(S(3)/2, S(1)/2, 1, S(3)/2, -S(1)/2, 1)
sqrt(3)/2
>>> clebsch_gordan(S(3)/2, S(1)/2, 1, -S(1)/2, S(1)/2, 0)
-sqrt(2)/2
NOTES:
The Clebsch-Gordan coefficient will be evaluated via its relation
to Wigner 3j symbols:
.. math::
\left\langle j_1 m_1 \; j_2 m_2 | j_3 m_3 \right\rangle
=(-1)^{j_1-j_2+m_3} \sqrt{2j_3+1}
\operatorname{Wigner3j}(j_1,j_2,j_3,m_1,m_2,-m_3)
See also the documentation on Wigner 3j symbols which exhibit much
higher symmetry relations than the Clebsch-Gordan coefficient.
AUTHORS:
- Jens Rasch (2009-03-24): initial version
"""
res = (-1) ** sympify(j_1 - j_2 + m_3) * sqrt(2 * j_3 + 1) * \
wigner_3j(j_1, j_2, j_3, m_1, m_2, -m_3)
return res
def _big_delta_coeff(aa, bb, cc, prec=None):
r"""
Calculates the Delta coefficient of the 3 angular momenta for
Racah symbols. Also checks that the differences are of integer
value.
INPUT:
- ``aa`` - first angular momentum, integer or half integer
- ``bb`` - second angular momentum, integer or half integer
- ``cc`` - third angular momentum, integer or half integer
- ``prec`` - precision of the ``sqrt()`` calculation
OUTPUT:
double - Value of the Delta coefficient
EXAMPLES::
sage: from sage.functions.wigner import _big_delta_coeff
sage: _big_delta_coeff(1,1,1)
1/2*sqrt(1/6)
"""
if int(aa + bb - cc) != (aa + bb - cc):
raise ValueError("j values must be integer or half integer and fulfill the triangle relation")
if int(aa + cc - bb) != (aa + cc - bb):
raise ValueError("j values must be integer or half integer and fulfill the triangle relation")
if int(bb + cc - aa) != (bb + cc - aa):
raise ValueError("j values must be integer or half integer and fulfill the triangle relation")
if (aa + bb - cc) < 0:
return 0
if (aa + cc - bb) < 0:
return 0
if (bb + cc - aa) < 0:
return 0
maxfact = max(aa + bb - cc, aa + cc - bb, bb + cc - aa, aa + bb + cc + 1)
_calc_factlist(maxfact)
argsqrt = Integer(_Factlist[int(aa + bb - cc)] *
_Factlist[int(aa + cc - bb)] *
_Factlist[int(bb + cc - aa)]) / \
Integer(_Factlist[int(aa + bb + cc + 1)])
ressqrt = sqrt(argsqrt)
if prec:
ressqrt = ressqrt.evalf(prec).as_real_imag()[0]
return ressqrt
def racah(aa, bb, cc, dd, ee, ff, prec=None):
r"""
Calculate the Racah symbol `W(a,b,c,d;e,f)`.
INPUT:
- ``a``, ..., ``f`` - integer or half integer
- ``prec`` - precision, default: ``None``. Providing a precision can
drastically speed up the calculation.
OUTPUT:
Rational number times the square root of a rational number
(if ``prec=None``), or real number if a precision is given.
Examples
========
>>> from sympy.physics.wigner import racah
>>> racah(3,3,3,3,3,3)
-1/14
NOTES:
The Racah symbol is related to the Wigner 6j symbol:
.. math::
\operatorname{Wigner6j}(j_1,j_2,j_3,j_4,j_5,j_6)
=(-1)^{j_1+j_2+j_4+j_5} W(j_1,j_2,j_5,j_4,j_3,j_6)
Please see the 6j symbol for its much richer symmetries and for
additional properties.
ALGORITHM:
This function uses the algorithm of [Edmonds74]_ to calculate the
value of the 6j symbol exactly. Note that the formula contains
alternating sums over large factorials and is therefore unsuitable
for finite precision arithmetic and only useful for a computer
algebra system [Rasch03]_.
AUTHORS:
- Jens Rasch (2009-03-24): initial version
"""
prefac = _big_delta_coeff(aa, bb, ee, prec) * \
_big_delta_coeff(cc, dd, ee, prec) * \
_big_delta_coeff(aa, cc, ff, prec) * \
_big_delta_coeff(bb, dd, ff, prec)
if prefac == 0:
return 0
imin = max(aa + bb + ee, cc + dd + ee, aa + cc + ff, bb + dd + ff)
imax = min(aa + bb + cc + dd, aa + dd + ee + ff, bb + cc + ee + ff)
maxfact = max(imax + 1, aa + bb + cc + dd, aa + dd + ee + ff,
bb + cc + ee + ff)
_calc_factlist(maxfact)
sumres = 0
for kk in range(int(imin), int(imax) + 1):
den = _Factlist[int(kk - aa - bb - ee)] * \
_Factlist[int(kk - cc - dd - ee)] * \
_Factlist[int(kk - aa - cc - ff)] * \
_Factlist[int(kk - bb - dd - ff)] * \
_Factlist[int(aa + bb + cc + dd - kk)] * \
_Factlist[int(aa + dd + ee + ff - kk)] * \
_Factlist[int(bb + cc + ee + ff - kk)]
sumres = sumres + Integer((-1) ** kk * _Factlist[kk + 1]) / den
res = prefac * sumres * (-1) ** int(aa + bb + cc + dd)
return res
def wigner_6j(j_1, j_2, j_3, j_4, j_5, j_6, prec=None):
r"""
Calculate the Wigner 6j symbol `\operatorname{Wigner6j}(j_1,j_2,j_3,j_4,j_5,j_6)`.
INPUT:
- ``j_1``, ..., ``j_6`` - integer or half integer
- ``prec`` - precision, default: ``None``. Providing a precision can
drastically speed up the calculation.
OUTPUT:
Rational number times the square root of a rational number
(if ``prec=None``), or real number if a precision is given.
Examples
========
>>> from sympy.physics.wigner import wigner_6j
>>> wigner_6j(3,3,3,3,3,3)
-1/14
>>> wigner_6j(5,5,5,5,5,5)
1/52
It is an error to have arguments that are not integer or half
integer values or do not fulfill the triangle relation::
sage: wigner_6j(2.5,2.5,2.5,2.5,2.5,2.5)
Traceback (most recent call last):
...
ValueError: j values must be integer or half integer and fulfill the triangle relation
sage: wigner_6j(0.5,0.5,1.1,0.5,0.5,1.1)
Traceback (most recent call last):
...
ValueError: j values must be integer or half integer and fulfill the triangle relation
NOTES:
The Wigner 6j symbol is related to the Racah symbol but exhibits
more symmetries as detailed below.
.. math::
\operatorname{Wigner6j}(j_1,j_2,j_3,j_4,j_5,j_6)
=(-1)^{j_1+j_2+j_4+j_5} W(j_1,j_2,j_5,j_4,j_3,j_6)
The Wigner 6j symbol obeys the following symmetry rules:
- Wigner 6j symbols are left invariant under any permutation of
the columns:
.. math::
\begin{aligned}
\operatorname{Wigner6j}(j_1,j_2,j_3,j_4,j_5,j_6)
&=\operatorname{Wigner6j}(j_3,j_1,j_2,j_6,j_4,j_5) \\
&=\operatorname{Wigner6j}(j_2,j_3,j_1,j_5,j_6,j_4) \\
&=\operatorname{Wigner6j}(j_3,j_2,j_1,j_6,j_5,j_4) \\
&=\operatorname{Wigner6j}(j_1,j_3,j_2,j_4,j_6,j_5) \\
&=\operatorname{Wigner6j}(j_2,j_1,j_3,j_5,j_4,j_6)
\end{aligned}
- They are invariant under the exchange of the upper and lower
arguments in each of any two columns, i.e.
.. math::
\operatorname{Wigner6j}(j_1,j_2,j_3,j_4,j_5,j_6)
=\operatorname{Wigner6j}(j_1,j_5,j_6,j_4,j_2,j_3)
=\operatorname{Wigner6j}(j_4,j_2,j_6,j_1,j_5,j_3)
=\operatorname{Wigner6j}(j_4,j_5,j_3,j_1,j_2,j_6)
- additional 6 symmetries [Regge59]_ giving rise to 144 symmetries
in total
- only non-zero if any triple of `j`'s fulfill a triangle relation
ALGORITHM:
This function uses the algorithm of [Edmonds74]_ to calculate the
value of the 6j symbol exactly. Note that the formula contains
alternating sums over large factorials and is therefore unsuitable
for finite precision arithmetic and only useful for a computer
algebra system [Rasch03]_.
"""
res = (-1) ** int(j_1 + j_2 + j_4 + j_5) * \
racah(j_1, j_2, j_5, j_4, j_3, j_6, prec)
return res
def wigner_9j(j_1, j_2, j_3, j_4, j_5, j_6, j_7, j_8, j_9, prec=None):
r"""
Calculate the Wigner 9j symbol
`\operatorname{Wigner9j}(j_1,j_2,j_3,j_4,j_5,j_6,j_7,j_8,j_9)`.
INPUT:
- ``j_1``, ..., ``j_9`` - integer or half integer
- ``prec`` - precision, default: ``None``. Providing a precision can
drastically speed up the calculation.
OUTPUT:
Rational number times the square root of a rational number
(if ``prec=None``), or real number if a precision is given.
Examples
========
>>> from sympy.physics.wigner import wigner_9j
>>> wigner_9j(1,1,1, 1,1,1, 1,1,0 ,prec=64) # ==1/18
0.05555555...
>>> wigner_9j(1/2,1/2,0, 1/2,3/2,1, 0,1,1 ,prec=64) # ==1/6
0.1666666...
It is an error to have arguments that are not integer or half
integer values or do not fulfill the triangle relation::
sage: wigner_9j(0.5,0.5,0.5, 0.5,0.5,0.5, 0.5,0.5,0.5,prec=64)
Traceback (most recent call last):
...
ValueError: j values must be integer or half integer and fulfill the triangle relation
sage: wigner_9j(1,1,1, 0.5,1,1.5, 0.5,1,2.5,prec=64)
Traceback (most recent call last):
...
ValueError: j values must be integer or half integer and fulfill the triangle relation
ALGORITHM:
This function uses the algorithm of [Edmonds74]_ to calculate the
value of the 3j symbol exactly. Note that the formula contains
alternating sums over large factorials and is therefore unsuitable
for finite precision arithmetic and only useful for a computer
algebra system [Rasch03]_.
"""
imax = int(min(j_1 + j_9, j_2 + j_6, j_4 + j_8) * 2)
imin = imax % 2
sumres = 0
for kk in range(imin, int(imax) + 1, 2):
sumres = sumres + (kk + 1) * \
racah(j_1, j_2, j_9, j_6, j_3, kk / 2, prec) * \
racah(j_4, j_6, j_8, j_2, j_5, kk / 2, prec) * \
racah(j_1, j_4, j_9, j_8, j_7, kk / 2, prec)
return sumres
def gaunt(l_1, l_2, l_3, m_1, m_2, m_3, prec=None):
r"""
Calculate the Gaunt coefficient.
The Gaunt coefficient is defined as the integral over three
spherical harmonics:
.. math::
\begin{aligned}
\operatorname{Gaunt}(l_1,l_2,l_3,m_1,m_2,m_3)
&=\int Y_{l_1,m_1}(\Omega)
Y_{l_2,m_2}(\Omega) Y_{l_3,m_3}(\Omega) \,d\Omega \\
&=\sqrt{\frac{(2l_1+1)(2l_2+1)(2l_3+1)}{4\pi}}
\operatorname{Wigner3j}(l_1,l_2,l_3,0,0,0)
\operatorname{Wigner3j}(l_1,l_2,l_3,m_1,m_2,m_3)
\end{aligned}
INPUT:
- ``l_1``, ``l_2``, ``l_3``, ``m_1``, ``m_2``, ``m_3`` - integer
- ``prec`` - precision, default: ``None``. Providing a precision can
drastically speed up the calculation.
OUTPUT:
Rational number times the square root of a rational number
(if ``prec=None``), or real number if a precision is given.
Examples
========
>>> from sympy.physics.wigner import gaunt
>>> gaunt(1,0,1,1,0,-1)
-1/(2*sqrt(pi))
>>> gaunt(1000,1000,1200,9,3,-12).n(64)
0.00689500421922113448...
It is an error to use non-integer values for `l` and `m`::
sage: gaunt(1.2,0,1.2,0,0,0)
Traceback (most recent call last):
...
ValueError: l values must be integer
sage: gaunt(1,0,1,1.1,0,-1.1)
Traceback (most recent call last):
...
ValueError: m values must be integer
NOTES:
The Gaunt coefficient obeys the following symmetry rules:
- invariant under any permutation of the columns
.. math::
\begin{aligned}
Y(l_1,l_2,l_3,m_1,m_2,m_3)
&=Y(l_3,l_1,l_2,m_3,m_1,m_2) \\
&=Y(l_2,l_3,l_1,m_2,m_3,m_1) \\
&=Y(l_3,l_2,l_1,m_3,m_2,m_1) \\
&=Y(l_1,l_3,l_2,m_1,m_3,m_2) \\
&=Y(l_2,l_1,l_3,m_2,m_1,m_3)
\end{aligned}
- invariant under space inflection, i.e.
.. math::
Y(l_1,l_2,l_3,m_1,m_2,m_3)
=Y(l_1,l_2,l_3,-m_1,-m_2,-m_3)
- symmetric with respect to the 72 Regge symmetries as inherited
for the `3j` symbols [Regge58]_
- zero for `l_1`, `l_2`, `l_3` not fulfilling triangle relation
- zero for violating any one of the conditions: `l_1 \ge |m_1|`,
`l_2 \ge |m_2|`, `l_3 \ge |m_3|`
- non-zero only for an even sum of the `l_i`, i.e.
`L = l_1 + l_2 + l_3 = 2n` for `n` in `\mathbb{N}`
ALGORITHM:
This function uses the algorithm of [Liberatodebrito82]_ to
calculate the value of the Gaunt coefficient exactly. Note that
the formula contains alternating sums over large factorials and is
therefore unsuitable for finite precision arithmetic and only
useful for a computer algebra system [Rasch03]_.
AUTHORS:
- Jens Rasch (2009-03-24): initial version for Sage
"""
if int(l_1) != l_1 or int(l_2) != l_2 or int(l_3) != l_3:
raise ValueError("l values must be integer")
if int(m_1) != m_1 or int(m_2) != m_2 or int(m_3) != m_3:
raise ValueError("m values must be integer")
sumL = l_1 + l_2 + l_3
bigL = sumL // 2
a1 = l_1 + l_2 - l_3
if a1 < 0:
return 0
a2 = l_1 - l_2 + l_3
if a2 < 0:
return 0
a3 = -l_1 + l_2 + l_3
if a3 < 0:
return 0
if sumL % 2:
return 0
if (m_1 + m_2 + m_3) != 0:
return 0
if (abs(m_1) > l_1) or (abs(m_2) > l_2) or (abs(m_3) > l_3):
return 0
imin = max(-l_3 + l_1 + m_2, -l_3 + l_2 - m_1, 0)
imax = min(l_2 + m_2, l_1 - m_1, l_1 + l_2 - l_3)
maxfact = max(l_1 + l_2 + l_3 + 1, imax + 1)
_calc_factlist(maxfact)
argsqrt = (2 * l_1 + 1) * (2 * l_2 + 1) * (2 * l_3 + 1) * \
_Factlist[l_1 - m_1] * _Factlist[l_1 + m_1] * _Factlist[l_2 - m_2] * \
_Factlist[l_2 + m_2] * _Factlist[l_3 - m_3] * _Factlist[l_3 + m_3] / \
(4*pi)
ressqrt = sqrt(argsqrt)
prefac = Integer(_Factlist[bigL] * _Factlist[l_2 - l_1 + l_3] *
_Factlist[l_1 - l_2 + l_3] * _Factlist[l_1 + l_2 - l_3])/ \
_Factlist[2 * bigL + 1]/ \
(_Factlist[bigL - l_1] *
_Factlist[bigL - l_2] * _Factlist[bigL - l_3])
sumres = 0
for ii in range(int(imin), int(imax) + 1):
den = _Factlist[ii] * _Factlist[ii + l_3 - l_1 - m_2] * \
_Factlist[l_2 + m_2 - ii] * _Factlist[l_1 - ii - m_1] * \
_Factlist[ii + l_3 - l_2 + m_1] * _Factlist[l_1 + l_2 - l_3 - ii]
sumres = sumres + Integer((-1) ** ii) / den
res = ressqrt * prefac * sumres * Integer((-1) ** (bigL + l_3 + m_1 - m_2))
if prec is not None:
res = res.n(prec)
return res
class Wigner3j(Function):
def doit(self, **hints):
if all(obj.is_number for obj in self.args):
return wigner_3j(*self.args)
else:
return self
def dot_rot_grad_Ynm(j, p, l, m, theta, phi):
r"""
Returns dot product of rotational gradients of spherical harmonics.
This function returns the right hand side of the following expression:
.. math ::
\vec{R}Y{_j^{p}} \cdot \vec{R}Y{_l^{m}} = (-1)^{m+p}
\sum\limits_{k=|l-j|}^{l+j}Y{_k^{m+p}} * \alpha_{l,m,j,p,k} *
\frac{1}{2} (k^2-j^2-l^2+k-j-l)
Arguments
=========
j, p, l, m .... indices in spherical harmonics (expressions or integers)
theta, phi .... angle arguments in spherical harmonics
Example
=======
>>> from sympy import symbols
>>> from sympy.physics.wigner import dot_rot_grad_Ynm
>>> theta, phi = symbols("theta phi")
>>> dot_rot_grad_Ynm(3, 2, 2, 0, theta, phi).doit()
3*sqrt(55)*Ynm(5, 2, theta, phi)/(11*sqrt(pi))
"""
j = sympify(j)
p = sympify(p)
l = sympify(l)
m = sympify(m)
theta = sympify(theta)
phi = sympify(phi)
k = Dummy("k")
def alpha(l,m,j,p,k):
return sqrt((2*l+1)*(2*j+1)*(2*k+1)/(4*pi)) * \
Wigner3j(j, l, k, S.Zero, S.Zero, S.Zero) * \
Wigner3j(j, l, k, p, m, -m-p)
return (S.NegativeOne)**(m+p) * Sum(Ynm(k, m+p, theta, phi) * alpha(l,m,j,p,k) / 2 \
*(k**2-j**2-l**2+k-j-l), (k, abs(l-j), l+j))
def wigner_d_small(J, beta):
u"""Return the small Wigner d matrix for angular momentum J.
INPUT:
- ``J`` - An integer, half-integer, or sympy symbol for the total angular
momentum of the angular momentum space being rotated.
- ``beta`` - A real number representing the Euler angle of rotation about
the so-called line of nodes. See [Edmonds74]_.
OUTPUT:
A matrix representing the corresponding Euler angle rotation( in the basis
of eigenvectors of `J_z`).
.. math ::
\\mathcal{d}_{\\beta} = \\exp\\big( \\frac{i\\beta}{\\hbar} J_y\\big)
The components are calculated using the general form [Edmonds74]_,
equation 4.1.15.
Examples
========
>>> from sympy import Integer, symbols, pi, pprint
>>> from sympy.physics.wigner import wigner_d_small
>>> half = 1/Integer(2)
>>> beta = symbols("beta", real=True)
>>> pprint(wigner_d_small(half, beta), use_unicode=True)
⎡ ⎛β⎞ ⎛β⎞⎤
⎢cos⎜─⎟ sin⎜─⎟⎥
⎢ ⎝2⎠ ⎝2⎠⎥
⎢ ⎥
⎢ ⎛β⎞ ⎛β⎞⎥
⎢-sin⎜─⎟ cos⎜─⎟⎥
⎣ ⎝2⎠ ⎝2⎠⎦
>>> pprint(wigner_d_small(2*half, beta), use_unicode=True)
⎡ 2⎛β⎞ ⎛β⎞ ⎛β⎞ 2⎛β⎞ ⎤
⎢ cos ⎜─⎟ √2⋅sin⎜─⎟⋅cos⎜─⎟ sin ⎜─⎟ ⎥
⎢ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎥
⎢ ⎥
⎢ ⎛β⎞ ⎛β⎞ 2⎛β⎞ 2⎛β⎞ ⎛β⎞ ⎛β⎞⎥
⎢-√2⋅sin⎜─⎟⋅cos⎜─⎟ - sin ⎜─⎟ + cos ⎜─⎟ √2⋅sin⎜─⎟⋅cos⎜─⎟⎥
⎢ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎝2⎠⎥
⎢ ⎥
⎢ 2⎛β⎞ ⎛β⎞ ⎛β⎞ 2⎛β⎞ ⎥
⎢ sin ⎜─⎟ -√2⋅sin⎜─⎟⋅cos⎜─⎟ cos ⎜─⎟ ⎥
⎣ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎝2⎠ ⎦
From table 4 in [Edmonds74]_
>>> pprint(wigner_d_small(half, beta).subs({beta:pi/2}), use_unicode=True)
⎡ √2 √2⎤
⎢ ── ──⎥
⎢ 2 2 ⎥
⎢ ⎥
⎢-√2 √2⎥
⎢──── ──⎥
⎣ 2 2 ⎦
>>> pprint(wigner_d_small(2*half, beta).subs({beta:pi/2}),
... use_unicode=True)
⎡ √2 ⎤
⎢1/2 ── 1/2⎥
⎢ 2 ⎥
⎢ ⎥
⎢-√2 √2 ⎥
⎢──── 0 ── ⎥
⎢ 2 2 ⎥
⎢ ⎥
⎢ -√2 ⎥
⎢1/2 ──── 1/2⎥
⎣ 2 ⎦
>>> pprint(wigner_d_small(3*half, beta).subs({beta:pi/2}),
... use_unicode=True)
⎡ √2 √6 √6 √2⎤
⎢ ── ── ── ──⎥
⎢ 4 4 4 4 ⎥
⎢ ⎥
⎢-√6 -√2 √2 √6⎥
⎢──── ──── ── ──⎥
⎢ 4 4 4 4 ⎥
⎢ ⎥
⎢ √6 -√2 -√2 √6⎥
⎢ ── ──── ──── ──⎥
⎢ 4 4 4 4 ⎥
⎢ ⎥
⎢-√2 √6 -√6 √2⎥
⎢──── ── ──── ──⎥
⎣ 4 4 4 4 ⎦
>>> pprint(wigner_d_small(4*half, beta).subs({beta:pi/2}),
... use_unicode=True)
⎡ √6 ⎤
⎢1/4 1/2 ── 1/2 1/4⎥
⎢ 4 ⎥
⎢ ⎥
⎢-1/2 -1/2 0 1/2 1/2⎥
⎢ ⎥
⎢ √6 √6 ⎥
⎢ ── 0 -1/2 0 ── ⎥
⎢ 4 4 ⎥
⎢ ⎥
⎢-1/2 1/2 0 -1/2 1/2⎥
⎢ ⎥
⎢ √6 ⎥
⎢1/4 -1/2 ── -1/2 1/4⎥
⎣ 4 ⎦
"""
M = [J-i for i in range(2*J+1)]
d = zeros(2*J+1)
for i, Mi in enumerate(M):
for j, Mj in enumerate(M):
# We get the maximum and minimum value of sigma.
sigmamax = max([-Mi-Mj, J-Mj])
sigmamin = min([0, J-Mi])
dij = sqrt(factorial(J+Mi)*factorial(J-Mi) /
factorial(J+Mj)/factorial(J-Mj))
terms = [(-1)**(J-Mi-s) *
binomial(J+Mj, J-Mi-s) *
binomial(J-Mj, s) *
cos(beta/2)**(2*s+Mi+Mj) *
sin(beta/2)**(2*J-2*s-Mj-Mi)
for s in range(sigmamin, sigmamax+1)]
d[i, j] = dij*Add(*terms)
return ImmutableMatrix(d)
def wigner_d(J, alpha, beta, gamma):
u"""Return the Wigner D matrix for angular momentum J.
INPUT:
- ``J`` - An integer, half-integer, or sympy symbol for the total angular
momentum of the angular momentum space being rotated.
- ``alpha``, ``beta``, ``gamma`` - Real numbers representing the Euler
angles of rotation about the so-called vertical, line of nodes, and
figure axes. See [Edmonds74]_.
OUTPUT:
A matrix representing the corresponding Euler angle rotation( in the basis
of eigenvectors of `J_z`).
.. math ::
\\mathcal{D}_{\\alpha \\beta \\gamma} =
\\exp\\big( \\frac{i\\alpha}{\\hbar} J_z\\big)
\\exp\\big( \\frac{i\\beta}{\\hbar} J_y\\big)
\\exp\\big( \\frac{i\\gamma}{\\hbar} J_z\\big)
The components are calculated using the general form [Edmonds74]_,
equation 4.1.12.
Examples
========
The simplest possible example:
>>> from sympy.physics.wigner import wigner_d
>>> from sympy import Integer, symbols, pprint
>>> half = 1/Integer(2)
>>> alpha, beta, gamma = symbols("alpha, beta, gamma", real=True)
>>> pprint(wigner_d(half, alpha, beta, gamma), use_unicode=True)
⎡ ⅈ⋅α ⅈ⋅γ ⅈ⋅α -ⅈ⋅γ ⎤
⎢ ─── ─── ─── ───── ⎥
⎢ 2 2 ⎛β⎞ 2 2 ⎛β⎞ ⎥
⎢ ℯ ⋅ℯ ⋅cos⎜─⎟ ℯ ⋅ℯ ⋅sin⎜─⎟ ⎥
⎢ ⎝2⎠ ⎝2⎠ ⎥
⎢ ⎥
⎢ -ⅈ⋅α ⅈ⋅γ -ⅈ⋅α -ⅈ⋅γ ⎥
⎢ ───── ─── ───── ───── ⎥
⎢ 2 2 ⎛β⎞ 2 2 ⎛β⎞⎥
⎢-ℯ ⋅ℯ ⋅sin⎜─⎟ ℯ ⋅ℯ ⋅cos⎜─⎟⎥
⎣ ⎝2⎠ ⎝2⎠⎦
"""
d = wigner_d_small(J, beta)
M = [J-i for i in range(2*J+1)]
D = [[exp(I*Mi*alpha)*d[i, j]*exp(I*Mj*gamma)
for j, Mj in enumerate(M)] for i, Mi in enumerate(M)]
return ImmutableMatrix(D)
|
6ab5caaf21ddfdf6d6bd2aacd887bb20ab3e54f2b0c0224d29ba8743bb7092e5 | """
This module implements Pauli algebra by subclassing Symbol. Only algebraic
properties of Pauli matrices are used (we don't use the Matrix class).
See the documentation to the class Pauli for examples.
References
~~~~~~~~~~
.. [1] https://en.wikipedia.org/wiki/Pauli_matrices
"""
from __future__ import print_function, division
from sympy import Symbol, I, Mul, Pow, Add
from sympy.physics.quantum import TensorProduct
__all__ = ['evaluate_pauli_product']
def delta(i, j):
"""
Returns 1 if i == j, else 0.
This is used in the multiplication of Pauli matrices.
Examples
========
>>> from sympy.physics.paulialgebra import delta
>>> delta(1, 1)
1
>>> delta(2, 3)
0
"""
if i == j:
return 1
else:
return 0
def epsilon(i, j, k):
"""
Return 1 if i,j,k is equal to (1,2,3), (2,3,1), or (3,1,2);
-1 if i,j,k is equal to (1,3,2), (3,2,1), or (2,1,3);
else return 0.
This is used in the multiplication of Pauli matrices.
Examples
========
>>> from sympy.physics.paulialgebra import epsilon
>>> epsilon(1, 2, 3)
1
>>> epsilon(1, 3, 2)
-1
"""
if (i, j, k) in [(1, 2, 3), (2, 3, 1), (3, 1, 2)]:
return 1
elif (i, j, k) in [(1, 3, 2), (3, 2, 1), (2, 1, 3)]:
return -1
else:
return 0
class Pauli(Symbol):
"""
The class representing algebraic properties of Pauli matrices.
The symbol used to display the Pauli matrices can be changed with an
optional parameter ``label="sigma"``. Pauli matrices with different
``label`` attributes cannot multiply together.
If the left multiplication of symbol or number with Pauli matrix is needed,
please use parentheses to separate Pauli and symbolic multiplication
(for example: 2*I*(Pauli(3)*Pauli(2))).
Another variant is to use evaluate_pauli_product function to evaluate
the product of Pauli matrices and other symbols (with commutative
multiply rules).
See Also
========
evaluate_pauli_product
Examples
========
>>> from sympy.physics.paulialgebra import Pauli
>>> Pauli(1)
sigma1
>>> Pauli(1)*Pauli(2)
I*sigma3
>>> Pauli(1)*Pauli(1)
1
>>> Pauli(3)**4
1
>>> Pauli(1)*Pauli(2)*Pauli(3)
I
>>> from sympy.physics.paulialgebra import Pauli
>>> Pauli(1, label="tau")
tau1
>>> Pauli(1)*Pauli(2, label="tau")
sigma1*tau2
>>> Pauli(1, label="tau")*Pauli(2, label="tau")
I*tau3
>>> from sympy import I
>>> I*(Pauli(2)*Pauli(3))
-sigma1
>>> from sympy.physics.paulialgebra import evaluate_pauli_product
>>> f = I*Pauli(2)*Pauli(3)
>>> f
I*sigma2*sigma3
>>> evaluate_pauli_product(f)
-sigma1
"""
__slots__ = ("i", "label")
def __new__(cls, i, label="sigma"):
if not i in [1, 2, 3]:
raise IndexError("Invalid Pauli index")
obj = Symbol.__new__(cls, "%s%d" %(label,i), commutative=False, hermitian=True)
obj.i = i
obj.label = label
return obj
def __getnewargs__(self):
return (self.i,self.label,)
# FIXME don't work for -I*Pauli(2)*Pauli(3)
def __mul__(self, other):
if isinstance(other, Pauli):
j = self.i
k = other.i
jlab = self.label
klab = other.label
if jlab == klab:
return delta(j, k) \
+ I*epsilon(j, k, 1)*Pauli(1,jlab) \
+ I*epsilon(j, k, 2)*Pauli(2,jlab) \
+ I*epsilon(j, k, 3)*Pauli(3,jlab)
return super(Pauli, self).__mul__(other)
def _eval_power(b, e):
if e.is_Integer and e.is_positive:
return super(Pauli, b).__pow__(int(e) % 2)
def evaluate_pauli_product(arg):
'''Help function to evaluate Pauli matrices product
with symbolic objects
Parameters
==========
arg: symbolic expression that contains Paulimatrices
Examples
========
>>> from sympy.physics.paulialgebra import Pauli, evaluate_pauli_product
>>> from sympy import I
>>> evaluate_pauli_product(I*Pauli(1)*Pauli(2))
-sigma3
>>> from sympy.abc import x
>>> evaluate_pauli_product(x**2*Pauli(2)*Pauli(1))
-I*x**2*sigma3
'''
start = arg
end = arg
if isinstance(arg, Pow) and isinstance(arg.args[0], Pauli):
if arg.args[1].is_odd:
return arg.args[0]
else:
return 1
if isinstance(arg, Add):
return Add(*[evaluate_pauli_product(part) for part in arg.args])
if isinstance(arg, TensorProduct):
return TensorProduct(*[evaluate_pauli_product(part) for part in arg.args])
elif not(isinstance(arg, Mul)):
return arg
while ((not(start == end)) | ((start == arg) & (end == arg))):
start = end
tmp = start.as_coeff_mul()
sigma_product = 1
com_product = 1
keeper = 1
for el in tmp[1]:
if isinstance(el, Pauli):
sigma_product *= el
elif not(el.is_commutative):
if isinstance(el, Pow) and isinstance(el.args[0], Pauli):
if el.args[1].is_odd:
sigma_product *= el.args[0]
elif isinstance(el, TensorProduct):
keeper = keeper*sigma_product*\
TensorProduct(
*[evaluate_pauli_product(part) for part in el.args]
)
sigma_product = 1
else:
keeper = keeper*sigma_product*el
sigma_product = 1
else:
com_product *= el
end = (tmp[0]*keeper*sigma_product*com_product)
if end == arg: break
return end
|
809005f29410e40444aeadd7000e8430dc18e3be1f8a45fc6f041b68b5e479b5 | from __future__ import print_function, division
from sympy.core import S, pi, Rational
from sympy.functions import assoc_laguerre, sqrt, exp, factorial, factorial2
def R_nl(n, l, nu, r):
"""
Returns the radial wavefunction R_{nl} for a 3d isotropic harmonic
oscillator.
``n``
the "nodal" quantum number. Corresponds to the number of nodes in
the wavefunction. n >= 0
``l``
the quantum number for orbital angular momentum
``nu``
mass-scaled frequency: nu = m*omega/(2*hbar) where `m` is the mass
and `omega` the frequency of the oscillator.
(in atomic units nu == omega/2)
``r``
Radial coordinate
Examples
========
>>> from sympy.physics.sho import R_nl
>>> from sympy.abc import r, nu, l
>>> R_nl(0, 0, 1, r)
2*2**(3/4)*exp(-r**2)/pi**(1/4)
>>> R_nl(1, 0, 1, r)
4*2**(1/4)*sqrt(3)*(3/2 - 2*r**2)*exp(-r**2)/(3*pi**(1/4))
l, nu and r may be symbolic:
>>> R_nl(0, 0, nu, r)
2*2**(3/4)*sqrt(nu**(3/2))*exp(-nu*r**2)/pi**(1/4)
>>> R_nl(0, l, 1, r)
r**l*sqrt(2**(l + 3/2)*2**(l + 2)/factorial2(2*l + 1))*exp(-r**2)/pi**(1/4)
The normalization of the radial wavefunction is:
>>> from sympy import Integral, oo
>>> Integral(R_nl(0, 0, 1, r)**2*r**2, (r, 0, oo)).n()
1.00000000000000
>>> Integral(R_nl(1, 0, 1, r)**2*r**2, (r, 0, oo)).n()
1.00000000000000
>>> Integral(R_nl(1, 1, 1, r)**2*r**2, (r, 0, oo)).n()
1.00000000000000
"""
n, l, nu, r = map(S, [n, l, nu, r])
# formula uses n >= 1 (instead of nodal n >= 0)
n = n + 1
C = sqrt(
((2*nu)**(l + Rational(3, 2))*2**(n + l + 1)*factorial(n - 1))/
(sqrt(pi)*(factorial2(2*n + 2*l - 1)))
)
return C*r**(l)*exp(-nu*r**2)*assoc_laguerre(n - 1, l + S.Half, 2*nu*r**2)
def E_nl(n, l, hw):
"""
Returns the Energy of an isotropic harmonic oscillator
``n``
the "nodal" quantum number
``l``
the orbital angular momentum
``hw``
the harmonic oscillator parameter.
The unit of the returned value matches the unit of hw, since the energy is
calculated as:
E_nl = (2*n + l + 3/2)*hw
Examples
========
>>> from sympy.physics.sho import E_nl
>>> from sympy import symbols
>>> x, y, z = symbols('x, y, z')
>>> E_nl(x, y, z)
z*(2*x + y + 3/2)
"""
return (2*n + l + Rational(3, 2))*hw
|
1d22ef1c66e00b854ac36c6e11779b42016257a84c9030cced0a0c8fba2dbb57 | from __future__ import print_function, division
from sympy.core import S, pi, Rational
from sympy.functions import hermite, sqrt, exp, factorial, Abs
from sympy.physics.quantum.constants import hbar
def psi_n(n, x, m, omega):
"""
Returns the wavefunction psi_{n} for the One-dimensional harmonic oscillator.
``n``
the "nodal" quantum number. Corresponds to the number of nodes in the
wavefunction. n >= 0
``x``
x coordinate
``m``
mass of the particle
``omega``
angular frequency of the oscillator
Examples
========
>>> from sympy.physics.qho_1d import psi_n
>>> from sympy.abc import m, x, omega
>>> psi_n(0, x, m, omega)
(m*omega)**(1/4)*exp(-m*omega*x**2/(2*hbar))/(hbar**(1/4)*pi**(1/4))
"""
# sympify arguments
n, x, m, omega = map(S, [n, x, m, omega])
nu = m * omega / hbar
# normalization coefficient
C = (nu/pi)**Rational(1, 4) * sqrt(1/(2**n*factorial(n)))
return C * exp(-nu* x**2 /2) * hermite(n, sqrt(nu)*x)
def E_n(n, omega):
"""
Returns the Energy of the One-dimensional harmonic oscillator
``n``
the "nodal" quantum number
``omega``
the harmonic oscillator angular frequency
The unit of the returned value matches the unit of hw, since the energy is
calculated as:
E_n = hbar * omega*(n + 1/2)
Examples
========
>>> from sympy.physics.qho_1d import E_n
>>> from sympy.abc import x, omega
>>> E_n(x, omega)
hbar*omega*(x + 1/2)
"""
return hbar * omega * (n + S.Half)
def coherent_state(n, alpha):
"""
Returns <n|alpha> for the coherent states of 1D harmonic oscillator.
See https://en.wikipedia.org/wiki/Coherent_states
``n``
the "nodal" quantum number
``alpha``
the eigen value of annihilation operator
"""
return exp(- Abs(alpha)**2/2)*(alpha**n)/sqrt(factorial(n))
|
3071cabbff7837c57d5d95324d09d1b079260d25effc6ab44a3febd694d8f700 | from __future__ import print_function, division
from sympy import factorial, sqrt, exp, S, assoc_laguerre, Float
from sympy.functions.special.spherical_harmonics import Ynm
def R_nl(n, l, r, Z=1):
"""
Returns the Hydrogen radial wavefunction R_{nl}.
n, l
quantum numbers 'n' and 'l'
r
radial coordinate
Z
atomic number (1 for Hydrogen, 2 for Helium, ...)
Everything is in Hartree atomic units.
Examples
========
>>> from sympy.physics.hydrogen import R_nl
>>> from sympy.abc import r, Z
>>> R_nl(1, 0, r, Z)
2*sqrt(Z**3)*exp(-Z*r)
>>> R_nl(2, 0, r, Z)
sqrt(2)*(-Z*r + 2)*sqrt(Z**3)*exp(-Z*r/2)/4
>>> R_nl(2, 1, r, Z)
sqrt(6)*Z*r*sqrt(Z**3)*exp(-Z*r/2)/12
For Hydrogen atom, you can just use the default value of Z=1:
>>> R_nl(1, 0, r)
2*exp(-r)
>>> R_nl(2, 0, r)
sqrt(2)*(2 - r)*exp(-r/2)/4
>>> R_nl(3, 0, r)
2*sqrt(3)*(2*r**2/9 - 2*r + 3)*exp(-r/3)/27
For Silver atom, you would use Z=47:
>>> R_nl(1, 0, r, Z=47)
94*sqrt(47)*exp(-47*r)
>>> R_nl(2, 0, r, Z=47)
47*sqrt(94)*(2 - 47*r)*exp(-47*r/2)/4
>>> R_nl(3, 0, r, Z=47)
94*sqrt(141)*(4418*r**2/9 - 94*r + 3)*exp(-47*r/3)/27
The normalization of the radial wavefunction is:
>>> from sympy import integrate, oo
>>> integrate(R_nl(1, 0, r)**2 * r**2, (r, 0, oo))
1
>>> integrate(R_nl(2, 0, r)**2 * r**2, (r, 0, oo))
1
>>> integrate(R_nl(2, 1, r)**2 * r**2, (r, 0, oo))
1
It holds for any atomic number:
>>> integrate(R_nl(1, 0, r, Z=2)**2 * r**2, (r, 0, oo))
1
>>> integrate(R_nl(2, 0, r, Z=3)**2 * r**2, (r, 0, oo))
1
>>> integrate(R_nl(2, 1, r, Z=4)**2 * r**2, (r, 0, oo))
1
"""
# sympify arguments
n, l, r, Z = map(S, [n, l, r, Z])
# radial quantum number
n_r = n - l - 1
# rescaled "r"
a = 1/Z # Bohr radius
r0 = 2 * r / (n * a)
# normalization coefficient
C = sqrt((S(2)/(n*a))**3 * factorial(n_r) / (2*n*factorial(n + l)))
# This is an equivalent normalization coefficient, that can be found in
# some books. Both coefficients seem to be the same fast:
# C = S(2)/n**2 * sqrt(1/a**3 * factorial(n_r) / (factorial(n+l)))
return C * r0**l * assoc_laguerre(n_r, 2*l + 1, r0).expand() * exp(-r0/2)
def Psi_nlm(n, l, m, r, phi, theta, Z=1):
"""
Returns the Hydrogen wave function psi_{nlm}. It's the product of
the radial wavefunction R_{nl} and the spherical harmonic Y_{l}^{m}.
n, l, m
quantum numbers 'n', 'l' and 'm'
r
radial coordinate
phi
azimuthal angle
theta
polar angle
Z
atomic number (1 for Hydrogen, 2 for Helium, ...)
Everything is in Hartree atomic units.
Examples
========
>>> from sympy.physics.hydrogen import Psi_nlm
>>> from sympy import Symbol
>>> r=Symbol("r", real=True, positive=True)
>>> phi=Symbol("phi", real=True)
>>> theta=Symbol("theta", real=True)
>>> Z=Symbol("Z", positive=True, integer=True, nonzero=True)
>>> Psi_nlm(1,0,0,r,phi,theta,Z)
Z**(3/2)*exp(-Z*r)/sqrt(pi)
>>> Psi_nlm(2,1,1,r,phi,theta,Z)
-Z**(5/2)*r*exp(I*phi)*exp(-Z*r/2)*sin(theta)/(8*sqrt(pi))
Integrating the absolute square of a hydrogen wavefunction psi_{nlm}
over the whole space leads 1.
The normalization of the hydrogen wavefunctions Psi_nlm is:
>>> from sympy import integrate, conjugate, pi, oo, sin
>>> wf=Psi_nlm(2,1,1,r,phi,theta,Z)
>>> abs_sqrd=wf*conjugate(wf)
>>> jacobi=r**2*sin(theta)
>>> integrate(abs_sqrd*jacobi, (r,0,oo), (phi,0,2*pi), (theta,0,pi))
1
"""
# sympify arguments
n, l, m, r, phi, theta, Z = map(S, [n, l, m, r, phi, theta, Z])
# check if values for n,l,m make physically sense
if n.is_integer and n < 1:
raise ValueError("'n' must be positive integer")
if l.is_integer and not (n > l):
raise ValueError("'n' must be greater than 'l'")
if m.is_integer and not (abs(m) <= l):
raise ValueError("|'m'| must be less or equal 'l'")
# return the hydrogen wave function
return R_nl(n, l, r, Z)*Ynm(l, m, theta, phi).expand(func=True)
def E_nl(n, Z=1):
"""
Returns the energy of the state (n, l) in Hartree atomic units.
The energy doesn't depend on "l".
Examples
========
>>> from sympy.physics.hydrogen import E_nl
>>> from sympy.abc import n, Z
>>> E_nl(n, Z)
-Z**2/(2*n**2)
>>> E_nl(1)
-1/2
>>> E_nl(2)
-1/8
>>> E_nl(3)
-1/18
>>> E_nl(3, 47)
-2209/18
"""
n, Z = S(n), S(Z)
if n.is_integer and (n < 1):
raise ValueError("'n' must be positive integer")
return -Z**2/(2*n**2)
def E_nl_dirac(n, l, spin_up=True, Z=1, c=Float("137.035999037")):
"""
Returns the relativistic energy of the state (n, l, spin) in Hartree atomic
units.
The energy is calculated from the Dirac equation. The rest mass energy is
*not* included.
n, l
quantum numbers 'n' and 'l'
spin_up
True if the electron spin is up (default), otherwise down
Z
atomic number (1 for Hydrogen, 2 for Helium, ...)
c
speed of light in atomic units. Default value is 137.035999037,
taken from: http://arxiv.org/abs/1012.3627
Examples
========
>>> from sympy.physics.hydrogen import E_nl_dirac
>>> E_nl_dirac(1, 0)
-0.500006656595360
>>> E_nl_dirac(2, 0)
-0.125002080189006
>>> E_nl_dirac(2, 1)
-0.125000416028342
>>> E_nl_dirac(2, 1, False)
-0.125002080189006
>>> E_nl_dirac(3, 0)
-0.0555562951740285
>>> E_nl_dirac(3, 1)
-0.0555558020932949
>>> E_nl_dirac(3, 1, False)
-0.0555562951740285
>>> E_nl_dirac(3, 2)
-0.0555556377366884
>>> E_nl_dirac(3, 2, False)
-0.0555558020932949
"""
n, l, Z, c = map(S, [n, l, Z, c])
if not (l >= 0):
raise ValueError("'l' must be positive or zero")
if not (n > l):
raise ValueError("'n' must be greater than 'l'")
if (l == 0 and spin_up is False):
raise ValueError("Spin must be up for l==0.")
# skappa is sign*kappa, where sign contains the correct sign
if spin_up:
skappa = -l - 1
else:
skappa = -l
beta = sqrt(skappa**2 - Z**2/c**2)
return c**2/sqrt(1 + Z**2/(n + skappa + beta)**2/c**2) - c**2
|
0684613112462a902ff36014c45ccd8ece6c487b74e907682524e77e831ebdc6 | """
Second quantization operators and states for bosons.
This follow the formulation of Fetter and Welecka, "Quantum Theory
of Many-Particle Systems."
"""
from __future__ import print_function, division
from collections import defaultdict
from sympy import (Add, Basic, cacheit, Dummy, Expr, Function, I,
KroneckerDelta, Mul, Pow, S, sqrt, Symbol, sympify, Tuple,
zeros)
from sympy.printing.str import StrPrinter
from sympy.utilities.iterables import has_dups
from sympy.utilities import default_sort_key
__all__ = [
'Dagger',
'KroneckerDelta',
'BosonicOperator',
'AnnihilateBoson',
'CreateBoson',
'AnnihilateFermion',
'CreateFermion',
'FockState',
'FockStateBra',
'FockStateKet',
'FockStateBosonKet',
'FockStateBosonBra',
'FockStateFermionKet',
'FockStateFermionBra',
'BBra',
'BKet',
'FBra',
'FKet',
'F',
'Fd',
'B',
'Bd',
'apply_operators',
'InnerProduct',
'BosonicBasis',
'VarBosonicBasis',
'FixedBosonicBasis',
'Commutator',
'matrix_rep',
'contraction',
'wicks',
'NO',
'evaluate_deltas',
'AntiSymmetricTensor',
'substitute_dummies',
'PermutationOperator',
'simplify_index_permutations',
]
class SecondQuantizationError(Exception):
pass
class AppliesOnlyToSymbolicIndex(SecondQuantizationError):
pass
class ContractionAppliesOnlyToFermions(SecondQuantizationError):
pass
class ViolationOfPauliPrinciple(SecondQuantizationError):
pass
class SubstitutionOfAmbigousOperatorFailed(SecondQuantizationError):
pass
class WicksTheoremDoesNotApply(SecondQuantizationError):
pass
class Dagger(Expr):
"""
Hermitian conjugate of creation/annihilation operators.
Examples
========
>>> from sympy import I
>>> from sympy.physics.secondquant import Dagger, B, Bd
>>> Dagger(2*I)
-2*I
>>> Dagger(B(0))
CreateBoson(0)
>>> Dagger(Bd(0))
AnnihilateBoson(0)
"""
def __new__(cls, arg):
arg = sympify(arg)
r = cls.eval(arg)
if isinstance(r, Basic):
return r
obj = Basic.__new__(cls, arg)
return obj
@classmethod
def eval(cls, arg):
"""
Evaluates the Dagger instance.
Examples
========
>>> from sympy import I
>>> from sympy.physics.secondquant import Dagger, B, Bd
>>> Dagger(2*I)
-2*I
>>> Dagger(B(0))
CreateBoson(0)
>>> Dagger(Bd(0))
AnnihilateBoson(0)
The eval() method is called automatically.
"""
dagger = getattr(arg, '_dagger_', None)
if dagger is not None:
return dagger()
if isinstance(arg, Basic):
if arg.is_Add:
return Add(*tuple(map(Dagger, arg.args)))
if arg.is_Mul:
return Mul(*tuple(map(Dagger, reversed(arg.args))))
if arg.is_Number:
return arg
if arg.is_Pow:
return Pow(Dagger(arg.args[0]), arg.args[1])
if arg == I:
return -arg
else:
return None
def _dagger_(self):
return self.args[0]
class TensorSymbol(Expr):
is_commutative = True
class AntiSymmetricTensor(TensorSymbol):
"""Stores upper and lower indices in separate Tuple's.
Each group of indices is assumed to be antisymmetric.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import AntiSymmetricTensor
>>> i, j = symbols('i j', below_fermi=True)
>>> a, b = symbols('a b', above_fermi=True)
>>> AntiSymmetricTensor('v', (a, i), (b, j))
AntiSymmetricTensor(v, (a, i), (b, j))
>>> AntiSymmetricTensor('v', (i, a), (b, j))
-AntiSymmetricTensor(v, (a, i), (b, j))
As you can see, the indices are automatically sorted to a canonical form.
"""
def __new__(cls, symbol, upper, lower):
try:
upper, signu = _sort_anticommuting_fermions(
upper, key=cls._sortkey)
lower, signl = _sort_anticommuting_fermions(
lower, key=cls._sortkey)
except ViolationOfPauliPrinciple:
return S.Zero
symbol = sympify(symbol)
upper = Tuple(*upper)
lower = Tuple(*lower)
if (signu + signl) % 2:
return -TensorSymbol.__new__(cls, symbol, upper, lower)
else:
return TensorSymbol.__new__(cls, symbol, upper, lower)
@classmethod
def _sortkey(cls, index):
"""Key for sorting of indices.
particle < hole < general
FIXME: This is a bottle-neck, can we do it faster?
"""
h = hash(index)
label = str(index)
if isinstance(index, Dummy):
if index.assumptions0.get('above_fermi'):
return (20, label, h)
elif index.assumptions0.get('below_fermi'):
return (21, label, h)
else:
return (22, label, h)
if index.assumptions0.get('above_fermi'):
return (10, label, h)
elif index.assumptions0.get('below_fermi'):
return (11, label, h)
else:
return (12, label, h)
def _latex(self, printer):
return "%s^{%s}_{%s}" % (
self.symbol,
"".join([ i.name for i in self.args[1]]),
"".join([ i.name for i in self.args[2]])
)
@property
def symbol(self):
"""
Returns the symbol of the tensor.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import AntiSymmetricTensor
>>> i, j = symbols('i,j', below_fermi=True)
>>> a, b = symbols('a,b', above_fermi=True)
>>> AntiSymmetricTensor('v', (a, i), (b, j))
AntiSymmetricTensor(v, (a, i), (b, j))
>>> AntiSymmetricTensor('v', (a, i), (b, j)).symbol
v
"""
return self.args[0]
@property
def upper(self):
"""
Returns the upper indices.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import AntiSymmetricTensor
>>> i, j = symbols('i,j', below_fermi=True)
>>> a, b = symbols('a,b', above_fermi=True)
>>> AntiSymmetricTensor('v', (a, i), (b, j))
AntiSymmetricTensor(v, (a, i), (b, j))
>>> AntiSymmetricTensor('v', (a, i), (b, j)).upper
(a, i)
"""
return self.args[1]
@property
def lower(self):
"""
Returns the lower indices.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import AntiSymmetricTensor
>>> i, j = symbols('i,j', below_fermi=True)
>>> a, b = symbols('a,b', above_fermi=True)
>>> AntiSymmetricTensor('v', (a, i), (b, j))
AntiSymmetricTensor(v, (a, i), (b, j))
>>> AntiSymmetricTensor('v', (a, i), (b, j)).lower
(b, j)
"""
return self.args[2]
def __str__(self):
return "%s(%s,%s)" % self.args
def doit(self, **kw_args):
"""
Returns self.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import AntiSymmetricTensor
>>> i, j = symbols('i,j', below_fermi=True)
>>> a, b = symbols('a,b', above_fermi=True)
>>> AntiSymmetricTensor('v', (a, i), (b, j)).doit()
AntiSymmetricTensor(v, (a, i), (b, j))
"""
return self
class SqOperator(Expr):
"""
Base class for Second Quantization operators.
"""
op_symbol = 'sq'
is_commutative = False
def __new__(cls, k):
obj = Basic.__new__(cls, sympify(k))
return obj
@property
def state(self):
"""
Returns the state index related to this operator.
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F, Fd, B, Bd
>>> p = Symbol('p')
>>> F(p).state
p
>>> Fd(p).state
p
>>> B(p).state
p
>>> Bd(p).state
p
"""
return self.args[0]
@property
def is_symbolic(self):
"""
Returns True if the state is a symbol (as opposed to a number).
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> p = Symbol('p')
>>> F(p).is_symbolic
True
>>> F(1).is_symbolic
False
"""
if self.state.is_Integer:
return False
else:
return True
def doit(self, **kw_args):
"""
FIXME: hack to prevent crash further up...
"""
return self
def __repr__(self):
return NotImplemented
def __str__(self):
return "%s(%r)" % (self.op_symbol, self.state)
def apply_operator(self, state):
"""
Applies an operator to itself.
"""
raise NotImplementedError('implement apply_operator in a subclass')
class BosonicOperator(SqOperator):
pass
class Annihilator(SqOperator):
pass
class Creator(SqOperator):
pass
class AnnihilateBoson(BosonicOperator, Annihilator):
"""
Bosonic annihilation operator.
Examples
========
>>> from sympy.physics.secondquant import B
>>> from sympy.abc import x
>>> B(x)
AnnihilateBoson(x)
"""
op_symbol = 'b'
def _dagger_(self):
return CreateBoson(self.state)
def apply_operator(self, state):
"""
Apply state to self if self is not symbolic and state is a FockStateKet, else
multiply self by state.
Examples
========
>>> from sympy.physics.secondquant import B, BKet
>>> from sympy.abc import x, y, n
>>> B(x).apply_operator(y)
y*AnnihilateBoson(x)
>>> B(0).apply_operator(BKet((n,)))
sqrt(n)*FockStateBosonKet((n - 1,))
"""
if not self.is_symbolic and isinstance(state, FockStateKet):
element = self.state
amp = sqrt(state[element])
return amp*state.down(element)
else:
return Mul(self, state)
def __repr__(self):
return "AnnihilateBoson(%s)" % self.state
def _latex(self, printer):
return "b_{%s}" % self.state.name
class CreateBoson(BosonicOperator, Creator):
"""
Bosonic creation operator.
"""
op_symbol = 'b+'
def _dagger_(self):
return AnnihilateBoson(self.state)
def apply_operator(self, state):
"""
Apply state to self if self is not symbolic and state is a FockStateKet, else
multiply self by state.
Examples
========
>>> from sympy.physics.secondquant import B, Dagger, BKet
>>> from sympy.abc import x, y, n
>>> Dagger(B(x)).apply_operator(y)
y*CreateBoson(x)
>>> B(0).apply_operator(BKet((n,)))
sqrt(n)*FockStateBosonKet((n - 1,))
"""
if not self.is_symbolic and isinstance(state, FockStateKet):
element = self.state
amp = sqrt(state[element] + 1)
return amp*state.up(element)
else:
return Mul(self, state)
def __repr__(self):
return "CreateBoson(%s)" % self.state
def _latex(self, printer):
return "b^\\dagger_{%s}" % self.state.name
B = AnnihilateBoson
Bd = CreateBoson
class FermionicOperator(SqOperator):
@property
def is_restricted(self):
"""
Is this FermionicOperator restricted with respect to fermi level?
Return values:
1 : restricted to orbits above fermi
0 : no restriction
-1 : restricted to orbits below fermi
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F, Fd
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_restricted
1
>>> Fd(a).is_restricted
1
>>> F(i).is_restricted
-1
>>> Fd(i).is_restricted
-1
>>> F(p).is_restricted
0
>>> Fd(p).is_restricted
0
"""
ass = self.args[0].assumptions0
if ass.get("below_fermi"):
return -1
if ass.get("above_fermi"):
return 1
return 0
@property
def is_above_fermi(self):
"""
Does the index of this FermionicOperator allow values above fermi?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_above_fermi
True
>>> F(i).is_above_fermi
False
>>> F(p).is_above_fermi
True
The same applies to creation operators Fd
"""
return not self.args[0].assumptions0.get("below_fermi")
@property
def is_below_fermi(self):
"""
Does the index of this FermionicOperator allow values below fermi?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_below_fermi
False
>>> F(i).is_below_fermi
True
>>> F(p).is_below_fermi
True
The same applies to creation operators Fd
"""
return not self.args[0].assumptions0.get("above_fermi")
@property
def is_only_below_fermi(self):
"""
Is the index of this FermionicOperator restricted to values below fermi?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_only_below_fermi
False
>>> F(i).is_only_below_fermi
True
>>> F(p).is_only_below_fermi
False
The same applies to creation operators Fd
"""
return self.is_below_fermi and not self.is_above_fermi
@property
def is_only_above_fermi(self):
"""
Is the index of this FermionicOperator restricted to values above fermi?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_only_above_fermi
True
>>> F(i).is_only_above_fermi
False
>>> F(p).is_only_above_fermi
False
The same applies to creation operators Fd
"""
return self.is_above_fermi and not self.is_below_fermi
def _sortkey(self):
h = hash(self)
label = str(self.args[0])
if self.is_only_q_creator:
return 1, label, h
if self.is_only_q_annihilator:
return 4, label, h
if isinstance(self, Annihilator):
return 3, label, h
if isinstance(self, Creator):
return 2, label, h
class AnnihilateFermion(FermionicOperator, Annihilator):
"""
Fermionic annihilation operator.
"""
op_symbol = 'f'
def _dagger_(self):
return CreateFermion(self.state)
def apply_operator(self, state):
"""
Apply state to self if self is not symbolic and state is a FockStateKet, else
multiply self by state.
Examples
========
>>> from sympy.physics.secondquant import B, Dagger, BKet
>>> from sympy.abc import x, y, n
>>> Dagger(B(x)).apply_operator(y)
y*CreateBoson(x)
>>> B(0).apply_operator(BKet((n,)))
sqrt(n)*FockStateBosonKet((n - 1,))
"""
if isinstance(state, FockStateFermionKet):
element = self.state
return state.down(element)
elif isinstance(state, Mul):
c_part, nc_part = state.args_cnc()
if isinstance(nc_part[0], FockStateFermionKet):
element = self.state
return Mul(*(c_part + [nc_part[0].down(element)] + nc_part[1:]))
else:
return Mul(self, state)
else:
return Mul(self, state)
@property
def is_q_creator(self):
"""
Can we create a quasi-particle? (create hole or create particle)
If so, would that be above or below the fermi surface?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_q_creator
0
>>> F(i).is_q_creator
-1
>>> F(p).is_q_creator
-1
"""
if self.is_below_fermi:
return -1
return 0
@property
def is_q_annihilator(self):
"""
Can we destroy a quasi-particle? (annihilate hole or annihilate particle)
If so, would that be above or below the fermi surface?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=1)
>>> i = Symbol('i', below_fermi=1)
>>> p = Symbol('p')
>>> F(a).is_q_annihilator
1
>>> F(i).is_q_annihilator
0
>>> F(p).is_q_annihilator
1
"""
if self.is_above_fermi:
return 1
return 0
@property
def is_only_q_creator(self):
"""
Always create a quasi-particle? (create hole or create particle)
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_only_q_creator
False
>>> F(i).is_only_q_creator
True
>>> F(p).is_only_q_creator
False
"""
return self.is_only_below_fermi
@property
def is_only_q_annihilator(self):
"""
Always destroy a quasi-particle? (annihilate hole or annihilate particle)
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import F
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> F(a).is_only_q_annihilator
True
>>> F(i).is_only_q_annihilator
False
>>> F(p).is_only_q_annihilator
False
"""
return self.is_only_above_fermi
def __repr__(self):
return "AnnihilateFermion(%s)" % self.state
def _latex(self, printer):
return "a_{%s}" % self.state.name
class CreateFermion(FermionicOperator, Creator):
"""
Fermionic creation operator.
"""
op_symbol = 'f+'
def _dagger_(self):
return AnnihilateFermion(self.state)
def apply_operator(self, state):
"""
Apply state to self if self is not symbolic and state is a FockStateKet, else
multiply self by state.
Examples
========
>>> from sympy.physics.secondquant import B, Dagger, BKet
>>> from sympy.abc import x, y, n
>>> Dagger(B(x)).apply_operator(y)
y*CreateBoson(x)
>>> B(0).apply_operator(BKet((n,)))
sqrt(n)*FockStateBosonKet((n - 1,))
"""
if isinstance(state, FockStateFermionKet):
element = self.state
return state.up(element)
elif isinstance(state, Mul):
c_part, nc_part = state.args_cnc()
if isinstance(nc_part[0], FockStateFermionKet):
element = self.state
return Mul(*(c_part + [nc_part[0].up(element)] + nc_part[1:]))
return Mul(self, state)
@property
def is_q_creator(self):
"""
Can we create a quasi-particle? (create hole or create particle)
If so, would that be above or below the fermi surface?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import Fd
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> Fd(a).is_q_creator
1
>>> Fd(i).is_q_creator
0
>>> Fd(p).is_q_creator
1
"""
if self.is_above_fermi:
return 1
return 0
@property
def is_q_annihilator(self):
"""
Can we destroy a quasi-particle? (annihilate hole or annihilate particle)
If so, would that be above or below the fermi surface?
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import Fd
>>> a = Symbol('a', above_fermi=1)
>>> i = Symbol('i', below_fermi=1)
>>> p = Symbol('p')
>>> Fd(a).is_q_annihilator
0
>>> Fd(i).is_q_annihilator
-1
>>> Fd(p).is_q_annihilator
-1
"""
if self.is_below_fermi:
return -1
return 0
@property
def is_only_q_creator(self):
"""
Always create a quasi-particle? (create hole or create particle)
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import Fd
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> Fd(a).is_only_q_creator
True
>>> Fd(i).is_only_q_creator
False
>>> Fd(p).is_only_q_creator
False
"""
return self.is_only_above_fermi
@property
def is_only_q_annihilator(self):
"""
Always destroy a quasi-particle? (annihilate hole or annihilate particle)
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import Fd
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> Fd(a).is_only_q_annihilator
False
>>> Fd(i).is_only_q_annihilator
True
>>> Fd(p).is_only_q_annihilator
False
"""
return self.is_only_below_fermi
def __repr__(self):
return "CreateFermion(%s)" % self.state
def _latex(self, printer):
return "a^\\dagger_{%s}" % self.state.name
Fd = CreateFermion
F = AnnihilateFermion
class FockState(Expr):
"""
Many particle Fock state with a sequence of occupation numbers.
Anywhere you can have a FockState, you can also have S.Zero.
All code must check for this!
Base class to represent FockStates.
"""
is_commutative = False
def __new__(cls, occupations):
"""
occupations is a list with two possible meanings:
- For bosons it is a list of occupation numbers.
Element i is the number of particles in state i.
- For fermions it is a list of occupied orbits.
Element 0 is the state that was occupied first, element i
is the i'th occupied state.
"""
occupations = list(map(sympify, occupations))
obj = Basic.__new__(cls, Tuple(*occupations))
return obj
def __getitem__(self, i):
i = int(i)
return self.args[0][i]
def __repr__(self):
return ("FockState(%r)") % (self.args)
def __str__(self):
return "%s%r%s" % (self.lbracket, self._labels(), self.rbracket)
def _labels(self):
return self.args[0]
def __len__(self):
return len(self.args[0])
class BosonState(FockState):
"""
Base class for FockStateBoson(Ket/Bra).
"""
def up(self, i):
"""
Performs the action of a creation operator.
Examples
========
>>> from sympy.physics.secondquant import BBra
>>> b = BBra([1, 2])
>>> b
FockStateBosonBra((1, 2))
>>> b.up(1)
FockStateBosonBra((1, 3))
"""
i = int(i)
new_occs = list(self.args[0])
new_occs[i] = new_occs[i] + S.One
return self.__class__(new_occs)
def down(self, i):
"""
Performs the action of an annihilation operator.
Examples
========
>>> from sympy.physics.secondquant import BBra
>>> b = BBra([1, 2])
>>> b
FockStateBosonBra((1, 2))
>>> b.down(1)
FockStateBosonBra((1, 1))
"""
i = int(i)
new_occs = list(self.args[0])
if new_occs[i] == S.Zero:
return S.Zero
else:
new_occs[i] = new_occs[i] - S.One
return self.__class__(new_occs)
class FermionState(FockState):
"""
Base class for FockStateFermion(Ket/Bra).
"""
fermi_level = 0
def __new__(cls, occupations, fermi_level=0):
occupations = list(map(sympify, occupations))
if len(occupations) > 1:
try:
(occupations, sign) = _sort_anticommuting_fermions(
occupations, key=hash)
except ViolationOfPauliPrinciple:
return S.Zero
else:
sign = 0
cls.fermi_level = fermi_level
if cls._count_holes(occupations) > fermi_level:
return S.Zero
if sign % 2:
return S.NegativeOne*FockState.__new__(cls, occupations)
else:
return FockState.__new__(cls, occupations)
def up(self, i):
"""
Performs the action of a creation operator.
If below fermi we try to remove a hole,
if above fermi we try to create a particle.
if general index p we return Kronecker(p,i)*self
where i is a new symbol with restriction above or below.
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import FKet
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> FKet([]).up(a)
FockStateFermionKet((a,))
A creator acting on vacuum below fermi vanishes
>>> FKet([]).up(i)
0
"""
present = i in self.args[0]
if self._only_above_fermi(i):
if present:
return S.Zero
else:
return self._add_orbit(i)
elif self._only_below_fermi(i):
if present:
return self._remove_orbit(i)
else:
return S.Zero
else:
if present:
hole = Dummy("i", below_fermi=True)
return KroneckerDelta(i, hole)*self._remove_orbit(i)
else:
particle = Dummy("a", above_fermi=True)
return KroneckerDelta(i, particle)*self._add_orbit(i)
def down(self, i):
"""
Performs the action of an annihilation operator.
If below fermi we try to create a hole,
if above fermi we try to remove a particle.
if general index p we return Kronecker(p,i)*self
where i is a new symbol with restriction above or below.
>>> from sympy import Symbol
>>> from sympy.physics.secondquant import FKet
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
An annihilator acting on vacuum above fermi vanishes
>>> FKet([]).down(a)
0
Also below fermi, it vanishes, unless we specify a fermi level > 0
>>> FKet([]).down(i)
0
>>> FKet([],4).down(i)
FockStateFermionKet((i,))
"""
present = i in self.args[0]
if self._only_above_fermi(i):
if present:
return self._remove_orbit(i)
else:
return S.Zero
elif self._only_below_fermi(i):
if present:
return S.Zero
else:
return self._add_orbit(i)
else:
if present:
hole = Dummy("i", below_fermi=True)
return KroneckerDelta(i, hole)*self._add_orbit(i)
else:
particle = Dummy("a", above_fermi=True)
return KroneckerDelta(i, particle)*self._remove_orbit(i)
@classmethod
def _only_below_fermi(cls, i):
"""
Tests if given orbit is only below fermi surface.
If nothing can be concluded we return a conservative False.
"""
if i.is_number:
return i <= cls.fermi_level
if i.assumptions0.get('below_fermi'):
return True
return False
@classmethod
def _only_above_fermi(cls, i):
"""
Tests if given orbit is only above fermi surface.
If fermi level has not been set we return True.
If nothing can be concluded we return a conservative False.
"""
if i.is_number:
return i > cls.fermi_level
if i.assumptions0.get('above_fermi'):
return True
return not cls.fermi_level
def _remove_orbit(self, i):
"""
Removes particle/fills hole in orbit i. No input tests performed here.
"""
new_occs = list(self.args[0])
pos = new_occs.index(i)
del new_occs[pos]
if (pos) % 2:
return S.NegativeOne*self.__class__(new_occs, self.fermi_level)
else:
return self.__class__(new_occs, self.fermi_level)
def _add_orbit(self, i):
"""
Adds particle/creates hole in orbit i. No input tests performed here.
"""
return self.__class__((i,) + self.args[0], self.fermi_level)
@classmethod
def _count_holes(cls, list):
"""
returns number of identified hole states in list.
"""
return len([i for i in list if cls._only_below_fermi(i)])
def _negate_holes(self, list):
return tuple([-i if i <= self.fermi_level else i for i in list])
def __repr__(self):
if self.fermi_level:
return "FockStateKet(%r, fermi_level=%s)" % (self.args[0], self.fermi_level)
else:
return "FockStateKet(%r)" % (self.args[0],)
def _labels(self):
return self._negate_holes(self.args[0])
class FockStateKet(FockState):
"""
Representation of a ket.
"""
lbracket = '|'
rbracket = '>'
class FockStateBra(FockState):
"""
Representation of a bra.
"""
lbracket = '<'
rbracket = '|'
def __mul__(self, other):
if isinstance(other, FockStateKet):
return InnerProduct(self, other)
else:
return Expr.__mul__(self, other)
class FockStateBosonKet(BosonState, FockStateKet):
"""
Many particle Fock state with a sequence of occupation numbers.
Occupation numbers can be any integer >= 0.
Examples
========
>>> from sympy.physics.secondquant import BKet
>>> BKet([1, 2])
FockStateBosonKet((1, 2))
"""
def _dagger_(self):
return FockStateBosonBra(*self.args)
class FockStateBosonBra(BosonState, FockStateBra):
"""
Describes a collection of BosonBra particles.
Examples
========
>>> from sympy.physics.secondquant import BBra
>>> BBra([1, 2])
FockStateBosonBra((1, 2))
"""
def _dagger_(self):
return FockStateBosonKet(*self.args)
class FockStateFermionKet(FermionState, FockStateKet):
"""
Many-particle Fock state with a sequence of occupied orbits.
Each state can only have one particle, so we choose to store a list of
occupied orbits rather than a tuple with occupation numbers (zeros and ones).
states below fermi level are holes, and are represented by negative labels
in the occupation list.
For symbolic state labels, the fermi_level caps the number of allowed hole-
states.
Examples
========
>>> from sympy.physics.secondquant import FKet
>>> FKet([1, 2])
FockStateFermionKet((1, 2))
"""
def _dagger_(self):
return FockStateFermionBra(*self.args)
class FockStateFermionBra(FermionState, FockStateBra):
"""
See Also
========
FockStateFermionKet
Examples
========
>>> from sympy.physics.secondquant import FBra
>>> FBra([1, 2])
FockStateFermionBra((1, 2))
"""
def _dagger_(self):
return FockStateFermionKet(*self.args)
BBra = FockStateBosonBra
BKet = FockStateBosonKet
FBra = FockStateFermionBra
FKet = FockStateFermionKet
def _apply_Mul(m):
"""
Take a Mul instance with operators and apply them to states.
This method applies all operators with integer state labels
to the actual states. For symbolic state labels, nothing is done.
When inner products of FockStates are encountered (like <a|b>),
they are converted to instances of InnerProduct.
This does not currently work on double inner products like,
<a|b><c|d>.
If the argument is not a Mul, it is simply returned as is.
"""
if not isinstance(m, Mul):
return m
c_part, nc_part = m.args_cnc()
n_nc = len(nc_part)
if n_nc == 0 or n_nc == 1:
return m
else:
last = nc_part[-1]
next_to_last = nc_part[-2]
if isinstance(last, FockStateKet):
if isinstance(next_to_last, SqOperator):
if next_to_last.is_symbolic:
return m
else:
result = next_to_last.apply_operator(last)
if result == 0:
return S.Zero
else:
return _apply_Mul(Mul(*(c_part + nc_part[:-2] + [result])))
elif isinstance(next_to_last, Pow):
if isinstance(next_to_last.base, SqOperator) and \
next_to_last.exp.is_Integer:
if next_to_last.base.is_symbolic:
return m
else:
result = last
for i in range(next_to_last.exp):
result = next_to_last.base.apply_operator(result)
if result == 0:
break
if result == 0:
return S.Zero
else:
return _apply_Mul(Mul(*(c_part + nc_part[:-2] + [result])))
else:
return m
elif isinstance(next_to_last, FockStateBra):
result = InnerProduct(next_to_last, last)
if result == 0:
return S.Zero
else:
return _apply_Mul(Mul(*(c_part + nc_part[:-2] + [result])))
else:
return m
else:
return m
def apply_operators(e):
"""
Take a sympy expression with operators and states and apply the operators.
Examples
========
>>> from sympy.physics.secondquant import apply_operators
>>> from sympy import sympify
>>> apply_operators(sympify(3)+4)
7
"""
e = e.expand()
muls = e.atoms(Mul)
subs_list = [(m, _apply_Mul(m)) for m in iter(muls)]
return e.subs(subs_list)
class InnerProduct(Basic):
"""
An unevaluated inner product between a bra and ket.
Currently this class just reduces things to a product of
Kronecker Deltas. In the future, we could introduce abstract
states like ``|a>`` and ``|b>``, and leave the inner product unevaluated as
``<a|b>``.
"""
is_commutative = True
def __new__(cls, bra, ket):
if not isinstance(bra, FockStateBra):
raise TypeError("must be a bra")
if not isinstance(ket, FockStateKet):
raise TypeError("must be a key")
return cls.eval(bra, ket)
@classmethod
def eval(cls, bra, ket):
result = S.One
for i, j in zip(bra.args[0], ket.args[0]):
result *= KroneckerDelta(i, j)
if result == 0:
break
return result
@property
def bra(self):
"""Returns the bra part of the state"""
return self.args[0]
@property
def ket(self):
"""Returns the ket part of the state"""
return self.args[1]
def __repr__(self):
sbra = repr(self.bra)
sket = repr(self.ket)
return "%s|%s" % (sbra[:-1], sket[1:])
def __str__(self):
return self.__repr__()
def matrix_rep(op, basis):
"""
Find the representation of an operator in a basis.
Examples
========
>>> from sympy.physics.secondquant import VarBosonicBasis, B, matrix_rep
>>> b = VarBosonicBasis(5)
>>> o = B(0)
>>> matrix_rep(o, b)
Matrix([
[0, 1, 0, 0, 0],
[0, 0, sqrt(2), 0, 0],
[0, 0, 0, sqrt(3), 0],
[0, 0, 0, 0, 2],
[0, 0, 0, 0, 0]])
"""
a = zeros(len(basis))
for i in range(len(basis)):
for j in range(len(basis)):
a[i, j] = apply_operators(Dagger(basis[i])*op*basis[j])
return a
class BosonicBasis(object):
"""
Base class for a basis set of bosonic Fock states.
"""
pass
class VarBosonicBasis(object):
"""
A single state, variable particle number basis set.
Examples
========
>>> from sympy.physics.secondquant import VarBosonicBasis
>>> b = VarBosonicBasis(5)
>>> b
[FockState((0,)), FockState((1,)), FockState((2,)),
FockState((3,)), FockState((4,))]
"""
def __init__(self, n_max):
self.n_max = n_max
self._build_states()
def _build_states(self):
self.basis = []
for i in range(self.n_max):
self.basis.append(FockStateBosonKet([i]))
self.n_basis = len(self.basis)
def index(self, state):
"""
Returns the index of state in basis.
Examples
========
>>> from sympy.physics.secondquant import VarBosonicBasis
>>> b = VarBosonicBasis(3)
>>> state = b.state(1)
>>> b
[FockState((0,)), FockState((1,)), FockState((2,))]
>>> state
FockStateBosonKet((1,))
>>> b.index(state)
1
"""
return self.basis.index(state)
def state(self, i):
"""
The state of a single basis.
Examples
========
>>> from sympy.physics.secondquant import VarBosonicBasis
>>> b = VarBosonicBasis(5)
>>> b.state(3)
FockStateBosonKet((3,))
"""
return self.basis[i]
def __getitem__(self, i):
return self.state(i)
def __len__(self):
return len(self.basis)
def __repr__(self):
return repr(self.basis)
class FixedBosonicBasis(BosonicBasis):
"""
Fixed particle number basis set.
Examples
========
>>> from sympy.physics.secondquant import FixedBosonicBasis
>>> b = FixedBosonicBasis(2, 2)
>>> state = b.state(1)
>>> b
[FockState((2, 0)), FockState((1, 1)), FockState((0, 2))]
>>> state
FockStateBosonKet((1, 1))
>>> b.index(state)
1
"""
def __init__(self, n_particles, n_levels):
self.n_particles = n_particles
self.n_levels = n_levels
self._build_particle_locations()
self._build_states()
def _build_particle_locations(self):
tup = ["i%i" % i for i in range(self.n_particles)]
first_loop = "for i0 in range(%i)" % self.n_levels
other_loops = ''
for cur, prev in zip(tup[1:], tup):
temp = "for %s in range(%s + 1) " % (cur, prev)
other_loops = other_loops + temp
tup_string = "(%s)" % ", ".join(tup)
list_comp = "[%s %s %s]" % (tup_string, first_loop, other_loops)
result = eval(list_comp)
if self.n_particles == 1:
result = [(item,) for item in result]
self.particle_locations = result
def _build_states(self):
self.basis = []
for tuple_of_indices in self.particle_locations:
occ_numbers = self.n_levels*[0]
for level in tuple_of_indices:
occ_numbers[level] += 1
self.basis.append(FockStateBosonKet(occ_numbers))
self.n_basis = len(self.basis)
def index(self, state):
"""Returns the index of state in basis.
Examples
========
>>> from sympy.physics.secondquant import FixedBosonicBasis
>>> b = FixedBosonicBasis(2, 3)
>>> b.index(b.state(3))
3
"""
return self.basis.index(state)
def state(self, i):
"""Returns the state that lies at index i of the basis
Examples
========
>>> from sympy.physics.secondquant import FixedBosonicBasis
>>> b = FixedBosonicBasis(2, 3)
>>> b.state(3)
FockStateBosonKet((1, 0, 1))
"""
return self.basis[i]
def __getitem__(self, i):
return self.state(i)
def __len__(self):
return len(self.basis)
def __repr__(self):
return repr(self.basis)
class Commutator(Function):
"""
The Commutator: [A, B] = A*B - B*A
The arguments are ordered according to .__cmp__()
>>> from sympy import symbols
>>> from sympy.physics.secondquant import Commutator
>>> A, B = symbols('A,B', commutative=False)
>>> Commutator(B, A)
-Commutator(A, B)
Evaluate the commutator with .doit()
>>> comm = Commutator(A,B); comm
Commutator(A, B)
>>> comm.doit()
A*B - B*A
For two second quantization operators the commutator is evaluated
immediately:
>>> from sympy.physics.secondquant import Fd, F
>>> a = symbols('a', above_fermi=True)
>>> i = symbols('i', below_fermi=True)
>>> p,q = symbols('p,q')
>>> Commutator(Fd(a),Fd(i))
2*NO(CreateFermion(a)*CreateFermion(i))
But for more complicated expressions, the evaluation is triggered by
a call to .doit()
>>> comm = Commutator(Fd(p)*Fd(q),F(i)); comm
Commutator(CreateFermion(p)*CreateFermion(q), AnnihilateFermion(i))
>>> comm.doit(wicks=True)
-KroneckerDelta(i, p)*CreateFermion(q) +
KroneckerDelta(i, q)*CreateFermion(p)
"""
is_commutative = False
@classmethod
def eval(cls, a, b):
"""
The Commutator [A,B] is on canonical form if A < B.
Examples
========
>>> from sympy.physics.secondquant import Commutator, F, Fd
>>> from sympy.abc import x
>>> c1 = Commutator(F(x), Fd(x))
>>> c2 = Commutator(Fd(x), F(x))
>>> Commutator.eval(c1, c2)
0
"""
if not (a and b):
return S.Zero
if a == b:
return S.Zero
if a.is_commutative or b.is_commutative:
return S.Zero
#
# [A+B,C] -> [A,C] + [B,C]
#
a = a.expand()
if isinstance(a, Add):
return Add(*[cls(term, b) for term in a.args])
b = b.expand()
if isinstance(b, Add):
return Add(*[cls(a, term) for term in b.args])
#
# [xA,yB] -> xy*[A,B]
#
ca, nca = a.args_cnc()
cb, ncb = b.args_cnc()
c_part = list(ca) + list(cb)
if c_part:
return Mul(Mul(*c_part), cls(Mul._from_args(nca), Mul._from_args(ncb)))
#
# single second quantization operators
#
if isinstance(a, BosonicOperator) and isinstance(b, BosonicOperator):
if isinstance(b, CreateBoson) and isinstance(a, AnnihilateBoson):
return KroneckerDelta(a.state, b.state)
if isinstance(a, CreateBoson) and isinstance(b, AnnihilateBoson):
return S.NegativeOne*KroneckerDelta(a.state, b.state)
else:
return S.Zero
if isinstance(a, FermionicOperator) and isinstance(b, FermionicOperator):
return wicks(a*b) - wicks(b*a)
#
# Canonical ordering of arguments
#
if a.sort_key() > b.sort_key():
return S.NegativeOne*cls(b, a)
def doit(self, **hints):
"""
Enables the computation of complex expressions.
Examples
========
>>> from sympy.physics.secondquant import Commutator, F, Fd
>>> from sympy import symbols
>>> i, j = symbols('i,j', below_fermi=True)
>>> a, b = symbols('a,b', above_fermi=True)
>>> c = Commutator(Fd(a)*F(i),Fd(b)*F(j))
>>> c.doit(wicks=True)
0
"""
a = self.args[0]
b = self.args[1]
if hints.get("wicks"):
a = a.doit(**hints)
b = b.doit(**hints)
try:
return wicks(a*b) - wicks(b*a)
except ContractionAppliesOnlyToFermions:
pass
except WicksTheoremDoesNotApply:
pass
return (a*b - b*a).doit(**hints)
def __repr__(self):
return "Commutator(%s,%s)" % (self.args[0], self.args[1])
def __str__(self):
return "[%s,%s]" % (self.args[0], self.args[1])
def _latex(self, printer):
return "\\left[%s,%s\\right]" % tuple([
printer._print(arg) for arg in self.args])
class NO(Expr):
"""
This Object is used to represent normal ordering brackets.
i.e. {abcd} sometimes written :abcd:
Applying the function NO(arg) to an argument means that all operators in
the argument will be assumed to anticommute, and have vanishing
contractions. This allows an immediate reordering to canonical form
upon object creation.
>>> from sympy import symbols
>>> from sympy.physics.secondquant import NO, F, Fd
>>> p,q = symbols('p,q')
>>> NO(Fd(p)*F(q))
NO(CreateFermion(p)*AnnihilateFermion(q))
>>> NO(F(q)*Fd(p))
-NO(CreateFermion(p)*AnnihilateFermion(q))
Note:
If you want to generate a normal ordered equivalent of an expression, you
should use the function wicks(). This class only indicates that all
operators inside the brackets anticommute, and have vanishing contractions.
Nothing more, nothing less.
"""
is_commutative = False
def __new__(cls, arg):
"""
Use anticommutation to get canonical form of operators.
Employ associativity of normal ordered product: {ab{cd}} = {abcd}
but note that {ab}{cd} /= {abcd}.
We also employ distributivity: {ab + cd} = {ab} + {cd}.
Canonical form also implies expand() {ab(c+d)} = {abc} + {abd}.
"""
# {ab + cd} = {ab} + {cd}
arg = sympify(arg)
arg = arg.expand()
if arg.is_Add:
return Add(*[ cls(term) for term in arg.args])
if arg.is_Mul:
# take coefficient outside of normal ordering brackets
c_part, seq = arg.args_cnc()
if c_part:
coeff = Mul(*c_part)
if not seq:
return coeff
else:
coeff = S.One
# {ab{cd}} = {abcd}
newseq = []
foundit = False
for fac in seq:
if isinstance(fac, NO):
newseq.extend(fac.args)
foundit = True
else:
newseq.append(fac)
if foundit:
return coeff*cls(Mul(*newseq))
# We assume that the user don't mix B and F operators
if isinstance(seq[0], BosonicOperator):
raise NotImplementedError
try:
newseq, sign = _sort_anticommuting_fermions(seq)
except ViolationOfPauliPrinciple:
return S.Zero
if sign % 2:
return (S.NegativeOne*coeff)*cls(Mul(*newseq))
elif sign:
return coeff*cls(Mul(*newseq))
else:
pass # since sign==0, no permutations was necessary
# if we couldn't do anything with Mul object, we just
# mark it as normal ordered
if coeff != S.One:
return coeff*cls(Mul(*newseq))
return Expr.__new__(cls, Mul(*newseq))
if isinstance(arg, NO):
return arg
# if object was not Mul or Add, normal ordering does not apply
return arg
@property
def has_q_creators(self):
"""
Return 0 if the leftmost argument of the first argument is a not a
q_creator, else 1 if it is above fermi or -1 if it is below fermi.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import NO, F, Fd
>>> a = symbols('a', above_fermi=True)
>>> i = symbols('i', below_fermi=True)
>>> NO(Fd(a)*Fd(i)).has_q_creators
1
>>> NO(F(i)*F(a)).has_q_creators
-1
>>> NO(Fd(i)*F(a)).has_q_creators #doctest: +SKIP
0
"""
return self.args[0].args[0].is_q_creator
@property
def has_q_annihilators(self):
"""
Return 0 if the rightmost argument of the first argument is a not a
q_annihilator, else 1 if it is above fermi or -1 if it is below fermi.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import NO, F, Fd
>>> a = symbols('a', above_fermi=True)
>>> i = symbols('i', below_fermi=True)
>>> NO(Fd(a)*Fd(i)).has_q_annihilators
-1
>>> NO(F(i)*F(a)).has_q_annihilators
1
>>> NO(Fd(a)*F(i)).has_q_annihilators
0
"""
return self.args[0].args[-1].is_q_annihilator
def doit(self, **kw_args):
"""
Either removes the brackets or enables complex computations
in its arguments.
Examples
========
>>> from sympy.physics.secondquant import NO, Fd, F
>>> from textwrap import fill
>>> from sympy import symbols, Dummy
>>> p,q = symbols('p,q', cls=Dummy)
>>> print(fill(str(NO(Fd(p)*F(q)).doit())))
KroneckerDelta(_a, _p)*KroneckerDelta(_a,
_q)*CreateFermion(_a)*AnnihilateFermion(_a) + KroneckerDelta(_a,
_p)*KroneckerDelta(_i, _q)*CreateFermion(_a)*AnnihilateFermion(_i) -
KroneckerDelta(_a, _q)*KroneckerDelta(_i,
_p)*AnnihilateFermion(_a)*CreateFermion(_i) - KroneckerDelta(_i,
_p)*KroneckerDelta(_i, _q)*AnnihilateFermion(_i)*CreateFermion(_i)
"""
if kw_args.get("remove_brackets", True):
return self._remove_brackets()
else:
return self.__new__(type(self), self.args[0].doit(**kw_args))
def _remove_brackets(self):
"""
Returns the sorted string without normal order brackets.
The returned string have the property that no nonzero
contractions exist.
"""
# check if any creator is also an annihilator
subslist = []
for i in self.iter_q_creators():
if self[i].is_q_annihilator:
assume = self[i].state.assumptions0
# only operators with a dummy index can be split in two terms
if isinstance(self[i].state, Dummy):
# create indices with fermi restriction
assume.pop("above_fermi", None)
assume["below_fermi"] = True
below = Dummy('i', **assume)
assume.pop("below_fermi", None)
assume["above_fermi"] = True
above = Dummy('a', **assume)
cls = type(self[i])
split = (
self[i].__new__(cls, below)
* KroneckerDelta(below, self[i].state)
+ self[i].__new__(cls, above)
* KroneckerDelta(above, self[i].state)
)
subslist.append((self[i], split))
else:
raise SubstitutionOfAmbigousOperatorFailed(self[i])
if subslist:
result = NO(self.subs(subslist))
if isinstance(result, Add):
return Add(*[term.doit() for term in result.args])
else:
return self.args[0]
def _expand_operators(self):
"""
Returns a sum of NO objects that contain no ambiguous q-operators.
If an index q has range both above and below fermi, the operator F(q)
is ambiguous in the sense that it can be both a q-creator and a q-annihilator.
If q is dummy, it is assumed to be a summation variable and this method
rewrites it into a sum of NO terms with unambiguous operators:
{Fd(p)*F(q)} = {Fd(a)*F(b)} + {Fd(a)*F(i)} + {Fd(j)*F(b)} -{F(i)*Fd(j)}
where a,b are above and i,j are below fermi level.
"""
return NO(self._remove_brackets)
def __getitem__(self, i):
if isinstance(i, slice):
indices = i.indices(len(self))
return [self.args[0].args[i] for i in range(*indices)]
else:
return self.args[0].args[i]
def __len__(self):
return len(self.args[0].args)
def iter_q_annihilators(self):
"""
Iterates over the annihilation operators.
Examples
========
>>> from sympy import symbols
>>> i, j = symbols('i j', below_fermi=True)
>>> a, b = symbols('a b', above_fermi=True)
>>> from sympy.physics.secondquant import NO, F, Fd
>>> no = NO(Fd(a)*F(i)*F(b)*Fd(j))
>>> no.iter_q_creators()
<generator object... at 0x...>
>>> list(no.iter_q_creators())
[0, 1]
>>> list(no.iter_q_annihilators())
[3, 2]
"""
ops = self.args[0].args
iter = range(len(ops) - 1, -1, -1)
for i in iter:
if ops[i].is_q_annihilator:
yield i
else:
break
def iter_q_creators(self):
"""
Iterates over the creation operators.
Examples
========
>>> from sympy import symbols
>>> i, j = symbols('i j', below_fermi=True)
>>> a, b = symbols('a b', above_fermi=True)
>>> from sympy.physics.secondquant import NO, F, Fd
>>> no = NO(Fd(a)*F(i)*F(b)*Fd(j))
>>> no.iter_q_creators()
<generator object... at 0x...>
>>> list(no.iter_q_creators())
[0, 1]
>>> list(no.iter_q_annihilators())
[3, 2]
"""
ops = self.args[0].args
iter = range(0, len(ops))
for i in iter:
if ops[i].is_q_creator:
yield i
else:
break
def get_subNO(self, i):
"""
Returns a NO() without FermionicOperator at index i.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import F, NO
>>> p, q, r = symbols('p,q,r')
>>> NO(F(p)*F(q)*F(r)).get_subNO(1)
NO(AnnihilateFermion(p)*AnnihilateFermion(r))
"""
arg0 = self.args[0] # it's a Mul by definition of how it's created
mul = arg0._new_rawargs(*(arg0.args[:i] + arg0.args[i + 1:]))
return NO(mul)
def _latex(self, printer):
return "\\left\\{%s\\right\\}" % printer._print(self.args[0])
def __repr__(self):
return "NO(%s)" % self.args[0]
def __str__(self):
return ":%s:" % self.args[0]
def contraction(a, b):
"""
Calculates contraction of Fermionic operators a and b.
Examples
========
>>> from sympy import symbols
>>> from sympy.physics.secondquant import F, Fd, contraction
>>> p, q = symbols('p,q')
>>> a, b = symbols('a,b', above_fermi=True)
>>> i, j = symbols('i,j', below_fermi=True)
A contraction is non-zero only if a quasi-creator is to the right of a
quasi-annihilator:
>>> contraction(F(a),Fd(b))
KroneckerDelta(a, b)
>>> contraction(Fd(i),F(j))
KroneckerDelta(i, j)
For general indices a non-zero result restricts the indices to below/above
the fermi surface:
>>> contraction(Fd(p),F(q))
KroneckerDelta(_i, q)*KroneckerDelta(p, q)
>>> contraction(F(p),Fd(q))
KroneckerDelta(_a, q)*KroneckerDelta(p, q)
Two creators or two annihilators always vanishes:
>>> contraction(F(p),F(q))
0
>>> contraction(Fd(p),Fd(q))
0
"""
if isinstance(b, FermionicOperator) and isinstance(a, FermionicOperator):
if isinstance(a, AnnihilateFermion) and isinstance(b, CreateFermion):
if b.state.assumptions0.get("below_fermi"):
return S.Zero
if a.state.assumptions0.get("below_fermi"):
return S.Zero
if b.state.assumptions0.get("above_fermi"):
return KroneckerDelta(a.state, b.state)
if a.state.assumptions0.get("above_fermi"):
return KroneckerDelta(a.state, b.state)
return (KroneckerDelta(a.state, b.state)*
KroneckerDelta(b.state, Dummy('a', above_fermi=True)))
if isinstance(b, AnnihilateFermion) and isinstance(a, CreateFermion):
if b.state.assumptions0.get("above_fermi"):
return S.Zero
if a.state.assumptions0.get("above_fermi"):
return S.Zero
if b.state.assumptions0.get("below_fermi"):
return KroneckerDelta(a.state, b.state)
if a.state.assumptions0.get("below_fermi"):
return KroneckerDelta(a.state, b.state)
return (KroneckerDelta(a.state, b.state)*
KroneckerDelta(b.state, Dummy('i', below_fermi=True)))
# vanish if 2xAnnihilator or 2xCreator
return S.Zero
else:
#not fermion operators
t = ( isinstance(i, FermionicOperator) for i in (a, b) )
raise ContractionAppliesOnlyToFermions(*t)
def _sqkey(sq_operator):
"""Generates key for canonical sorting of SQ operators."""
return sq_operator._sortkey()
def _sort_anticommuting_fermions(string1, key=_sqkey):
"""Sort fermionic operators to canonical order, assuming all pairs anticommute.
Uses a bidirectional bubble sort. Items in string1 are not referenced
so in principle they may be any comparable objects. The sorting depends on the
operators '>' and '=='.
If the Pauli principle is violated, an exception is raised.
Returns
=======
tuple (sorted_str, sign)
sorted_str: list containing the sorted operators
sign: int telling how many times the sign should be changed
(if sign==0 the string was already sorted)
"""
verified = False
sign = 0
rng = list(range(len(string1) - 1))
rev = list(range(len(string1) - 3, -1, -1))
keys = list(map(key, string1))
key_val = dict(list(zip(keys, string1)))
while not verified:
verified = True
for i in rng:
left = keys[i]
right = keys[i + 1]
if left == right:
raise ViolationOfPauliPrinciple([left, right])
if left > right:
verified = False
keys[i:i + 2] = [right, left]
sign = sign + 1
if verified:
break
for i in rev:
left = keys[i]
right = keys[i + 1]
if left == right:
raise ViolationOfPauliPrinciple([left, right])
if left > right:
verified = False
keys[i:i + 2] = [right, left]
sign = sign + 1
string1 = [ key_val[k] for k in keys ]
return (string1, sign)
def evaluate_deltas(e):
"""
We evaluate KroneckerDelta symbols in the expression assuming Einstein summation.
If one index is repeated it is summed over and in effect substituted with
the other one. If both indices are repeated we substitute according to what
is the preferred index. this is determined by
KroneckerDelta.preferred_index and KroneckerDelta.killable_index.
In case there are no possible substitutions or if a substitution would
imply a loss of information, nothing is done.
In case an index appears in more than one KroneckerDelta, the resulting
substitution depends on the order of the factors. Since the ordering is platform
dependent, the literal expression resulting from this function may be hard to
predict.
Examples
========
We assume the following:
>>> from sympy import symbols, Function, Dummy, KroneckerDelta
>>> from sympy.physics.secondquant import evaluate_deltas
>>> i,j = symbols('i j', below_fermi=True, cls=Dummy)
>>> a,b = symbols('a b', above_fermi=True, cls=Dummy)
>>> p,q = symbols('p q', cls=Dummy)
>>> f = Function('f')
>>> t = Function('t')
The order of preference for these indices according to KroneckerDelta is
(a, b, i, j, p, q).
Trivial cases:
>>> evaluate_deltas(KroneckerDelta(i,j)*f(i)) # d_ij f(i) -> f(j)
f(_j)
>>> evaluate_deltas(KroneckerDelta(i,j)*f(j)) # d_ij f(j) -> f(i)
f(_i)
>>> evaluate_deltas(KroneckerDelta(i,p)*f(p)) # d_ip f(p) -> f(i)
f(_i)
>>> evaluate_deltas(KroneckerDelta(q,p)*f(p)) # d_qp f(p) -> f(q)
f(_q)
>>> evaluate_deltas(KroneckerDelta(q,p)*f(q)) # d_qp f(q) -> f(p)
f(_p)
More interesting cases:
>>> evaluate_deltas(KroneckerDelta(i,p)*t(a,i)*f(p,q))
f(_i, _q)*t(_a, _i)
>>> evaluate_deltas(KroneckerDelta(a,p)*t(a,i)*f(p,q))
f(_a, _q)*t(_a, _i)
>>> evaluate_deltas(KroneckerDelta(p,q)*f(p,q))
f(_p, _p)
Finally, here are some cases where nothing is done, because that would
imply a loss of information:
>>> evaluate_deltas(KroneckerDelta(i,p)*f(q))
f(_q)*KroneckerDelta(_i, _p)
>>> evaluate_deltas(KroneckerDelta(i,p)*f(i))
f(_i)*KroneckerDelta(_i, _p)
"""
# We treat Deltas only in mul objects
# for general function objects we don't evaluate KroneckerDeltas in arguments,
# but here we hard code exceptions to this rule
accepted_functions = (
Add,
)
if isinstance(e, accepted_functions):
return e.func(*[evaluate_deltas(arg) for arg in e.args])
elif isinstance(e, Mul):
# find all occurrences of delta function and count each index present in
# expression.
deltas = []
indices = {}
for i in e.args:
for s in i.free_symbols:
if s in indices:
indices[s] += 1
else:
indices[s] = 0 # geek counting simplifies logic below
if isinstance(i, KroneckerDelta):
deltas.append(i)
for d in deltas:
# If we do something, and there are more deltas, we should recurse
# to treat the resulting expression properly
if d.killable_index.is_Symbol and indices[d.killable_index]:
e = e.subs(d.killable_index, d.preferred_index)
if len(deltas) > 1:
return evaluate_deltas(e)
elif (d.preferred_index.is_Symbol and indices[d.preferred_index]
and d.indices_contain_equal_information):
e = e.subs(d.preferred_index, d.killable_index)
if len(deltas) > 1:
return evaluate_deltas(e)
else:
pass
return e
# nothing to do, maybe we hit a Symbol or a number
else:
return e
def substitute_dummies(expr, new_indices=False, pretty_indices={}):
"""
Collect terms by substitution of dummy variables.
This routine allows simplification of Add expressions containing terms
which differ only due to dummy variables.
The idea is to substitute all dummy variables consistently depending on
the structure of the term. For each term, we obtain a sequence of all
dummy variables, where the order is determined by the index range, what
factors the index belongs to and its position in each factor. See
_get_ordered_dummies() for more information about the sorting of dummies.
The index sequence is then substituted consistently in each term.
Examples
========
>>> from sympy import symbols, Function, Dummy
>>> from sympy.physics.secondquant import substitute_dummies
>>> a,b,c,d = symbols('a b c d', above_fermi=True, cls=Dummy)
>>> i,j = symbols('i j', below_fermi=True, cls=Dummy)
>>> f = Function('f')
>>> expr = f(a,b) + f(c,d); expr
f(_a, _b) + f(_c, _d)
Since a, b, c and d are equivalent summation indices, the expression can be
simplified to a single term (for which the dummy indices are still summed over)
>>> substitute_dummies(expr)
2*f(_a, _b)
Controlling output:
By default the dummy symbols that are already present in the expression
will be reused in a different permutation. However, if new_indices=True,
new dummies will be generated and inserted. The keyword 'pretty_indices'
can be used to control this generation of new symbols.
By default the new dummies will be generated on the form i_1, i_2, a_1,
etc. If you supply a dictionary with key:value pairs in the form:
{ index_group: string_of_letters }
The letters will be used as labels for the new dummy symbols. The
index_groups must be one of 'above', 'below' or 'general'.
>>> expr = f(a,b,i,j)
>>> my_dummies = { 'above':'st', 'below':'uv' }
>>> substitute_dummies(expr, new_indices=True, pretty_indices=my_dummies)
f(_s, _t, _u, _v)
If we run out of letters, or if there is no keyword for some index_group
the default dummy generator will be used as a fallback:
>>> p,q = symbols('p q', cls=Dummy) # general indices
>>> expr = f(p,q)
>>> substitute_dummies(expr, new_indices=True, pretty_indices=my_dummies)
f(_p_0, _p_1)
"""
# setup the replacing dummies
if new_indices:
letters_above = pretty_indices.get('above', "")
letters_below = pretty_indices.get('below', "")
letters_general = pretty_indices.get('general', "")
len_above = len(letters_above)
len_below = len(letters_below)
len_general = len(letters_general)
def _i(number):
try:
return letters_below[number]
except IndexError:
return 'i_' + str(number - len_below)
def _a(number):
try:
return letters_above[number]
except IndexError:
return 'a_' + str(number - len_above)
def _p(number):
try:
return letters_general[number]
except IndexError:
return 'p_' + str(number - len_general)
aboves = []
belows = []
generals = []
dummies = expr.atoms(Dummy)
if not new_indices:
dummies = sorted(dummies, key=default_sort_key)
# generate lists with the dummies we will insert
a = i = p = 0
for d in dummies:
assum = d.assumptions0
if assum.get("above_fermi"):
if new_indices:
sym = _a(a)
a += 1
l1 = aboves
elif assum.get("below_fermi"):
if new_indices:
sym = _i(i)
i += 1
l1 = belows
else:
if new_indices:
sym = _p(p)
p += 1
l1 = generals
if new_indices:
l1.append(Dummy(sym, **assum))
else:
l1.append(d)
expr = expr.expand()
terms = Add.make_args(expr)
new_terms = []
for term in terms:
i = iter(belows)
a = iter(aboves)
p = iter(generals)
ordered = _get_ordered_dummies(term)
subsdict = {}
for d in ordered:
if d.assumptions0.get('below_fermi'):
subsdict[d] = next(i)
elif d.assumptions0.get('above_fermi'):
subsdict[d] = next(a)
else:
subsdict[d] = next(p)
subslist = []
final_subs = []
for k, v in subsdict.items():
if k == v:
continue
if v in subsdict:
# We check if the sequence of substitutions end quickly. In
# that case, we can avoid temporary symbols if we ensure the
# correct substitution order.
if subsdict[v] in subsdict:
# (x, y) -> (y, x), we need a temporary variable
x = Dummy('x')
subslist.append((k, x))
final_subs.append((x, v))
else:
# (x, y) -> (y, a), x->y must be done last
# but before temporary variables are resolved
final_subs.insert(0, (k, v))
else:
subslist.append((k, v))
subslist.extend(final_subs)
new_terms.append(term.subs(subslist))
return Add(*new_terms)
class KeyPrinter(StrPrinter):
"""Printer for which only equal objects are equal in print"""
def _print_Dummy(self, expr):
return "(%s_%i)" % (expr.name, expr.dummy_index)
def __kprint(expr):
p = KeyPrinter()
return p.doprint(expr)
def _get_ordered_dummies(mul, verbose=False):
"""Returns all dummies in the mul sorted in canonical order
The purpose of the canonical ordering is that dummies can be substituted
consistently across terms with the result that equivalent terms can be
simplified.
It is not possible to determine if two terms are equivalent based solely on
the dummy order. However, a consistent substitution guided by the ordered
dummies should lead to trivially (non-)equivalent terms, thereby revealing
the equivalence. This also means that if two terms have identical sequences of
dummies, the (non-)equivalence should already be apparent.
Strategy
--------
The canoncial order is given by an arbitrary sorting rule. A sort key
is determined for each dummy as a tuple that depends on all factors where
the index is present. The dummies are thereby sorted according to the
contraction structure of the term, instead of sorting based solely on the
dummy symbol itself.
After all dummies in the term has been assigned a key, we check for identical
keys, i.e. unorderable dummies. If any are found, we call a specialized
method, _determine_ambiguous(), that will determine a unique order based
on recursive calls to _get_ordered_dummies().
Key description
---------------
A high level description of the sort key:
1. Range of the dummy index
2. Relation to external (non-dummy) indices
3. Position of the index in the first factor
4. Position of the index in the second factor
The sort key is a tuple with the following components:
1. A single character indicating the range of the dummy (above, below
or general.)
2. A list of strings with fully masked string representations of all
factors where the dummy is present. By masked, we mean that dummies
are represented by a symbol to indicate either below fermi, above or
general. No other information is displayed about the dummies at
this point. The list is sorted stringwise.
3. An integer number indicating the position of the index, in the first
factor as sorted in 2.
4. An integer number indicating the position of the index, in the second
factor as sorted in 2.
If a factor is either of type AntiSymmetricTensor or SqOperator, the index
position in items 3 and 4 is indicated as 'upper' or 'lower' only.
(Creation operators are considered upper and annihilation operators lower.)
If the masked factors are identical, the two factors cannot be ordered
unambiguously in item 2. In this case, items 3, 4 are left out. If several
indices are contracted between the unorderable factors, it will be handled by
_determine_ambiguous()
"""
# setup dicts to avoid repeated calculations in key()
args = Mul.make_args(mul)
fac_dum = dict([ (fac, fac.atoms(Dummy)) for fac in args] )
fac_repr = dict([ (fac, __kprint(fac)) for fac in args] )
all_dums = set().union(*fac_dum.values())
mask = {}
for d in all_dums:
if d.assumptions0.get('below_fermi'):
mask[d] = '0'
elif d.assumptions0.get('above_fermi'):
mask[d] = '1'
else:
mask[d] = '2'
dum_repr = {d: __kprint(d) for d in all_dums}
def _key(d):
dumstruct = [ fac for fac in fac_dum if d in fac_dum[fac] ]
other_dums = set().union(*[fac_dum[fac] for fac in dumstruct])
fac = dumstruct[-1]
if other_dums is fac_dum[fac]:
other_dums = fac_dum[fac].copy()
other_dums.remove(d)
masked_facs = [ fac_repr[fac] for fac in dumstruct ]
for d2 in other_dums:
masked_facs = [ fac.replace(dum_repr[d2], mask[d2])
for fac in masked_facs ]
all_masked = [ fac.replace(dum_repr[d], mask[d])
for fac in masked_facs ]
masked_facs = dict(list(zip(dumstruct, masked_facs)))
# dummies for which the ordering cannot be determined
if has_dups(all_masked):
all_masked.sort()
return mask[d], tuple(all_masked) # positions are ambiguous
# sort factors according to fully masked strings
keydict = dict(list(zip(dumstruct, all_masked)))
dumstruct.sort(key=lambda x: keydict[x])
all_masked.sort()
pos_val = []
for fac in dumstruct:
if isinstance(fac, AntiSymmetricTensor):
if d in fac.upper:
pos_val.append('u')
if d in fac.lower:
pos_val.append('l')
elif isinstance(fac, Creator):
pos_val.append('u')
elif isinstance(fac, Annihilator):
pos_val.append('l')
elif isinstance(fac, NO):
ops = [ op for op in fac if op.has(d) ]
for op in ops:
if isinstance(op, Creator):
pos_val.append('u')
else:
pos_val.append('l')
else:
# fallback to position in string representation
facpos = -1
while 1:
facpos = masked_facs[fac].find(dum_repr[d], facpos + 1)
if facpos == -1:
break
pos_val.append(facpos)
return (mask[d], tuple(all_masked), pos_val[0], pos_val[-1])
dumkey = dict(list(zip(all_dums, list(map(_key, all_dums)))))
result = sorted(all_dums, key=lambda x: dumkey[x])
if has_dups(iter(dumkey.values())):
# We have ambiguities
unordered = defaultdict(set)
for d, k in dumkey.items():
unordered[k].add(d)
for k in [ k for k in unordered if len(unordered[k]) < 2 ]:
del unordered[k]
unordered = [ unordered[k] for k in sorted(unordered) ]
result = _determine_ambiguous(mul, result, unordered)
return result
def _determine_ambiguous(term, ordered, ambiguous_groups):
# We encountered a term for which the dummy substitution is ambiguous.
# This happens for terms with 2 or more contractions between factors that
# cannot be uniquely ordered independent of summation indices. For
# example:
#
# Sum(p, q) v^{p, .}_{q, .}v^{q, .}_{p, .}
#
# Assuming that the indices represented by . are dummies with the
# same range, the factors cannot be ordered, and there is no
# way to determine a consistent ordering of p and q.
#
# The strategy employed here, is to relabel all unambiguous dummies with
# non-dummy symbols and call _get_ordered_dummies again. This procedure is
# applied to the entire term so there is a possibility that
# _determine_ambiguous() is called again from a deeper recursion level.
# break recursion if there are no ordered dummies
all_ambiguous = set()
for dummies in ambiguous_groups:
all_ambiguous |= dummies
all_ordered = set(ordered) - all_ambiguous
if not all_ordered:
# FIXME: If we arrive here, there are no ordered dummies. A method to
# handle this needs to be implemented. In order to return something
# useful nevertheless, we choose arbitrarily the first dummy and
# determine the rest from this one. This method is dependent on the
# actual dummy labels which violates an assumption for the
# canonicalization procedure. A better implementation is needed.
group = [ d for d in ordered if d in ambiguous_groups[0] ]
d = group[0]
all_ordered.add(d)
ambiguous_groups[0].remove(d)
stored_counter = _symbol_factory._counter
subslist = []
for d in [ d for d in ordered if d in all_ordered ]:
nondum = _symbol_factory._next()
subslist.append((d, nondum))
newterm = term.subs(subslist)
neworder = _get_ordered_dummies(newterm)
_symbol_factory._set_counter(stored_counter)
# update ordered list with new information
for group in ambiguous_groups:
ordered_group = [ d for d in neworder if d in group ]
ordered_group.reverse()
result = []
for d in ordered:
if d in group:
result.append(ordered_group.pop())
else:
result.append(d)
ordered = result
return ordered
class _SymbolFactory(object):
def __init__(self, label):
self._counterVar = 0
self._label = label
def _set_counter(self, value):
"""
Sets counter to value.
"""
self._counterVar = value
@property
def _counter(self):
"""
What counter is currently at.
"""
return self._counterVar
def _next(self):
"""
Generates the next symbols and increments counter by 1.
"""
s = Symbol("%s%i" % (self._label, self._counterVar))
self._counterVar += 1
return s
_symbol_factory = _SymbolFactory('_]"]_') # most certainly a unique label
@cacheit
def _get_contractions(string1, keep_only_fully_contracted=False):
"""
Returns Add-object with contracted terms.
Uses recursion to find all contractions. -- Internal helper function --
Will find nonzero contractions in string1 between indices given in
leftrange and rightrange.
"""
# Should we store current level of contraction?
if keep_only_fully_contracted and string1:
result = []
else:
result = [NO(Mul(*string1))]
for i in range(len(string1) - 1):
for j in range(i + 1, len(string1)):
c = contraction(string1[i], string1[j])
if c:
sign = (j - i + 1) % 2
if sign:
coeff = S.NegativeOne*c
else:
coeff = c
#
# Call next level of recursion
# ============================
#
# We now need to find more contractions among operators
#
# oplist = string1[:i]+ string1[i+1:j] + string1[j+1:]
#
# To prevent overcounting, we don't allow contractions
# we have already encountered. i.e. contractions between
# string1[:i] <---> string1[i+1:j]
# and string1[:i] <---> string1[j+1:].
#
# This leaves the case:
oplist = string1[i + 1:j] + string1[j + 1:]
if oplist:
result.append(coeff*NO(
Mul(*string1[:i])*_get_contractions( oplist,
keep_only_fully_contracted=keep_only_fully_contracted)))
else:
result.append(coeff*NO( Mul(*string1[:i])))
if keep_only_fully_contracted:
break # next iteration over i leaves leftmost operator string1[0] uncontracted
return Add(*result)
def wicks(e, **kw_args):
"""
Returns the normal ordered equivalent of an expression using Wicks Theorem.
Examples
========
>>> from sympy import symbols, Dummy
>>> from sympy.physics.secondquant import wicks, F, Fd
>>> p, q, r = symbols('p,q,r')
>>> wicks(Fd(p)*F(q))
KroneckerDelta(_i, q)*KroneckerDelta(p, q) + NO(CreateFermion(p)*AnnihilateFermion(q))
By default, the expression is expanded:
>>> wicks(F(p)*(F(q)+F(r)))
NO(AnnihilateFermion(p)*AnnihilateFermion(q)) + NO(AnnihilateFermion(p)*AnnihilateFermion(r))
With the keyword 'keep_only_fully_contracted=True', only fully contracted
terms are returned.
By request, the result can be simplified in the following order:
-- KroneckerDelta functions are evaluated
-- Dummy variables are substituted consistently across terms
>>> p, q, r = symbols('p q r', cls=Dummy)
>>> wicks(Fd(p)*(F(q)+F(r)), keep_only_fully_contracted=True)
KroneckerDelta(_i, _q)*KroneckerDelta(_p, _q) + KroneckerDelta(_i, _r)*KroneckerDelta(_p, _r)
"""
if not e:
return S.Zero
opts = {
'simplify_kronecker_deltas': False,
'expand': True,
'simplify_dummies': False,
'keep_only_fully_contracted': False
}
opts.update(kw_args)
# check if we are already normally ordered
if isinstance(e, NO):
if opts['keep_only_fully_contracted']:
return S.Zero
else:
return e
elif isinstance(e, FermionicOperator):
if opts['keep_only_fully_contracted']:
return S.Zero
else:
return e
# break up any NO-objects, and evaluate commutators
e = e.doit(wicks=True)
# make sure we have only one term to consider
e = e.expand()
if isinstance(e, Add):
if opts['simplify_dummies']:
return substitute_dummies(Add(*[ wicks(term, **kw_args) for term in e.args]))
else:
return Add(*[ wicks(term, **kw_args) for term in e.args])
# For Mul-objects we can actually do something
if isinstance(e, Mul):
# we don't want to mess around with commuting part of Mul
# so we factorize it out before starting recursion
c_part = []
string1 = []
for factor in e.args:
if factor.is_commutative:
c_part.append(factor)
else:
string1.append(factor)
n = len(string1)
# catch trivial cases
if n == 0:
result = e
elif n == 1:
if opts['keep_only_fully_contracted']:
return S.Zero
else:
result = e
else: # non-trivial
if isinstance(string1[0], BosonicOperator):
raise NotImplementedError
string1 = tuple(string1)
# recursion over higher order contractions
result = _get_contractions(string1,
keep_only_fully_contracted=opts['keep_only_fully_contracted'] )
result = Mul(*c_part)*result
if opts['expand']:
result = result.expand()
if opts['simplify_kronecker_deltas']:
result = evaluate_deltas(result)
return result
# there was nothing to do
return e
class PermutationOperator(Expr):
"""
Represents the index permutation operator P(ij).
P(ij)*f(i)*g(j) = f(i)*g(j) - f(j)*g(i)
"""
is_commutative = True
def __new__(cls, i, j):
i, j = sorted(map(sympify, (i, j)), key=default_sort_key)
obj = Basic.__new__(cls, i, j)
return obj
def get_permuted(self, expr):
"""
Returns -expr with permuted indices.
>>> from sympy import symbols, Function
>>> from sympy.physics.secondquant import PermutationOperator
>>> p,q = symbols('p,q')
>>> f = Function('f')
>>> PermutationOperator(p,q).get_permuted(f(p,q))
-f(q, p)
"""
i = self.args[0]
j = self.args[1]
if expr.has(i) and expr.has(j):
tmp = Dummy()
expr = expr.subs(i, tmp)
expr = expr.subs(j, i)
expr = expr.subs(tmp, j)
return S.NegativeOne*expr
else:
return expr
def _latex(self, printer):
return "P(%s%s)" % self.args
def simplify_index_permutations(expr, permutation_operators):
"""
Performs simplification by introducing PermutationOperators where appropriate.
Schematically:
[abij] - [abji] - [baij] + [baji] -> P(ab)*P(ij)*[abij]
permutation_operators is a list of PermutationOperators to consider.
If permutation_operators=[P(ab),P(ij)] we will try to introduce the
permutation operators P(ij) and P(ab) in the expression. If there are other
possible simplifications, we ignore them.
>>> from sympy import symbols, Function
>>> from sympy.physics.secondquant import simplify_index_permutations
>>> from sympy.physics.secondquant import PermutationOperator
>>> p,q,r,s = symbols('p,q,r,s')
>>> f = Function('f')
>>> g = Function('g')
>>> expr = f(p)*g(q) - f(q)*g(p); expr
f(p)*g(q) - f(q)*g(p)
>>> simplify_index_permutations(expr,[PermutationOperator(p,q)])
f(p)*g(q)*PermutationOperator(p, q)
>>> PermutList = [PermutationOperator(p,q),PermutationOperator(r,s)]
>>> expr = f(p,r)*g(q,s) - f(q,r)*g(p,s) + f(q,s)*g(p,r) - f(p,s)*g(q,r)
>>> simplify_index_permutations(expr,PermutList)
f(p, r)*g(q, s)*PermutationOperator(p, q)*PermutationOperator(r, s)
"""
def _get_indices(expr, ind):
"""
Collects indices recursively in predictable order.
"""
result = []
for arg in expr.args:
if arg in ind:
result.append(arg)
else:
if arg.args:
result.extend(_get_indices(arg, ind))
return result
def _choose_one_to_keep(a, b, ind):
# we keep the one where indices in ind are in order ind[0] < ind[1]
return min(a, b, key=lambda x: default_sort_key(_get_indices(x, ind)))
expr = expr.expand()
if isinstance(expr, Add):
terms = set(expr.args)
for P in permutation_operators:
new_terms = set([])
on_hold = set([])
while terms:
term = terms.pop()
permuted = P.get_permuted(term)
if permuted in terms | on_hold:
try:
terms.remove(permuted)
except KeyError:
on_hold.remove(permuted)
keep = _choose_one_to_keep(term, permuted, P.args)
new_terms.add(P*keep)
else:
# Some terms must get a second chance because the permuted
# term may already have canonical dummy ordering. Then
# substitute_dummies() does nothing. However, the other
# term, if it exists, will be able to match with us.
permuted1 = permuted
permuted = substitute_dummies(permuted)
if permuted1 == permuted:
on_hold.add(term)
elif permuted in terms | on_hold:
try:
terms.remove(permuted)
except KeyError:
on_hold.remove(permuted)
keep = _choose_one_to_keep(term, permuted, P.args)
new_terms.add(P*keep)
else:
new_terms.add(term)
terms = new_terms | on_hold
return Add(*terms)
return expr
|
26395d1af79d75b0888826ed402416f0d1fcb9e7c3837bf38fa89b9e14178305 | from __future__ import print_function, division
from sympy import sqrt, exp, S, pi, I
from sympy.physics.quantum.constants import hbar
def wavefunction(n, x):
"""
Returns the wavefunction for particle on ring.
n is the quantum number, x is the angle,
here n can be positive as well as negative
which can be used to describe the direction of motion of particle
Examples
========
>>> from sympy.physics.pring import wavefunction
>>> from sympy import Symbol, integrate, pi
>>> x=Symbol("x")
>>> wavefunction(1, x)
sqrt(2)*exp(I*x)/(2*sqrt(pi))
>>> wavefunction(2, x)
sqrt(2)*exp(2*I*x)/(2*sqrt(pi))
>>> wavefunction(3, x)
sqrt(2)*exp(3*I*x)/(2*sqrt(pi))
The normalization of the wavefunction is:
>>> integrate(wavefunction(2, x)*wavefunction(-2, x), (x, 0, 2*pi))
1
>>> integrate(wavefunction(4, x)*wavefunction(-4, x), (x, 0, 2*pi))
1
References
==========
.. [1] Atkins, Peter W.; Friedman, Ronald (2005). Molecular Quantum
Mechanics (4th ed.). Pages 71-73.
"""
# sympify arguments
n, x = S(n), S(x)
return exp(n * I * x) / sqrt(2 * pi)
def energy(n, m, r):
"""
Returns the energy of the state corresponding to quantum number n.
E=(n**2 * (hcross)**2) / (2 * m * r**2)
here n is the quantum number, m is the mass of the particle
and r is the radius of circle.
Examples
========
>>> from sympy.physics.pring import energy
>>> from sympy import Symbol
>>> m=Symbol("m")
>>> r=Symbol("r")
>>> energy(1, m, r)
hbar**2/(2*m*r**2)
>>> energy(2, m, r)
2*hbar**2/(m*r**2)
>>> energy(-2, 2.0, 3.0)
0.111111111111111*hbar**2
References
==========
.. [1] Atkins, Peter W.; Friedman, Ronald (2005). Molecular Quantum
Mechanics (4th ed.). Pages 71-73.
"""
n, m, r = S(n), S(m), S(r)
if n.is_integer:
return (n**2 * hbar**2) / (2 * m * r**2)
else:
raise ValueError("'n' must be integer")
|
d5973a6ae70fc8c6001a2c1cc3ff1151aaa7d0b6dfdefb83c3b8d4c0e7cb00ea | """Module with functions operating on IndexedBase, Indexed and Idx objects
- Check shape conformance
- Determine indices in resulting expression
etc.
Methods in this module could be implemented by calling methods on Expr
objects instead. When things stabilize this could be a useful
refactoring.
"""
from __future__ import print_function, division
from sympy.core.compatibility import reduce
from sympy.core.function import Function
from sympy.functions import exp, Piecewise
from sympy.tensor.indexed import Idx, Indexed
from sympy.utilities import sift
from collections import OrderedDict
class IndexConformanceException(Exception):
pass
def _unique_and_repeated(inds):
"""
Returns the unique and repeated indices. Also note, from the examples given below
that the order of indices is maintained as given in the input.
Examples
========
>>> from sympy.tensor.index_methods import _unique_and_repeated
>>> _unique_and_repeated([2, 3, 1, 3, 0, 4, 0])
([2, 1, 4], [3, 0])
"""
uniq = OrderedDict()
for i in inds:
if i in uniq:
uniq[i] = 0
else:
uniq[i] = 1
return sift(uniq, lambda x: uniq[x], binary=True)
def _remove_repeated(inds):
"""
Removes repeated objects from sequences
Returns a set of the unique objects and a tuple of all that have been
removed.
Examples
========
>>> from sympy.tensor.index_methods import _remove_repeated
>>> l1 = [1, 2, 3, 2]
>>> _remove_repeated(l1)
({1, 3}, (2,))
"""
u, r = _unique_and_repeated(inds)
return set(u), tuple(r)
def _get_indices_Mul(expr, return_dummies=False):
"""Determine the outer indices of a Mul object.
Examples
========
>>> from sympy.tensor.index_methods import _get_indices_Mul
>>> from sympy.tensor.indexed import IndexedBase, Idx
>>> i, j, k = map(Idx, ['i', 'j', 'k'])
>>> x = IndexedBase('x')
>>> y = IndexedBase('y')
>>> _get_indices_Mul(x[i, k]*y[j, k])
({i, j}, {})
>>> _get_indices_Mul(x[i, k]*y[j, k], return_dummies=True)
({i, j}, {}, (k,))
"""
inds = list(map(get_indices, expr.args))
inds, syms = list(zip(*inds))
inds = list(map(list, inds))
inds = list(reduce(lambda x, y: x + y, inds))
inds, dummies = _remove_repeated(inds)
symmetry = {}
for s in syms:
for pair in s:
if pair in symmetry:
symmetry[pair] *= s[pair]
else:
symmetry[pair] = s[pair]
if return_dummies:
return inds, symmetry, dummies
else:
return inds, symmetry
def _get_indices_Pow(expr):
"""Determine outer indices of a power or an exponential.
A power is considered a universal function, so that the indices of a Pow is
just the collection of indices present in the expression. This may be
viewed as a bit inconsistent in the special case:
x[i]**2 = x[i]*x[i] (1)
The above expression could have been interpreted as the contraction of x[i]
with itself, but we choose instead to interpret it as a function
lambda y: y**2
applied to each element of x (a universal function in numpy terms). In
order to allow an interpretation of (1) as a contraction, we need
contravariant and covariant Idx subclasses. (FIXME: this is not yet
implemented)
Expressions in the base or exponent are subject to contraction as usual,
but an index that is present in the exponent, will not be considered
contractable with its own base. Note however, that indices in the same
exponent can be contracted with each other.
Examples
========
>>> from sympy.tensor.index_methods import _get_indices_Pow
>>> from sympy import Pow, exp, IndexedBase, Idx
>>> A = IndexedBase('A')
>>> x = IndexedBase('x')
>>> i, j, k = map(Idx, ['i', 'j', 'k'])
>>> _get_indices_Pow(exp(A[i, j]*x[j]))
({i}, {})
>>> _get_indices_Pow(Pow(x[i], x[i]))
({i}, {})
>>> _get_indices_Pow(Pow(A[i, j]*x[j], x[i]))
({i}, {})
"""
base, exp = expr.as_base_exp()
binds, bsyms = get_indices(base)
einds, esyms = get_indices(exp)
inds = binds | einds
# FIXME: symmetries from power needs to check special cases, else nothing
symmetries = {}
return inds, symmetries
def _get_indices_Add(expr):
"""Determine outer indices of an Add object.
In a sum, each term must have the same set of outer indices. A valid
expression could be
x(i)*y(j) - x(j)*y(i)
But we do not allow expressions like:
x(i)*y(j) - z(j)*z(j)
FIXME: Add support for Numpy broadcasting
Examples
========
>>> from sympy.tensor.index_methods import _get_indices_Add
>>> from sympy.tensor.indexed import IndexedBase, Idx
>>> i, j, k = map(Idx, ['i', 'j', 'k'])
>>> x = IndexedBase('x')
>>> y = IndexedBase('y')
>>> _get_indices_Add(x[i] + x[k]*y[i, k])
({i}, {})
"""
inds = list(map(get_indices, expr.args))
inds, syms = list(zip(*inds))
# allow broadcast of scalars
non_scalars = [x for x in inds if x != set()]
if not non_scalars:
return set(), {}
if not all([x == non_scalars[0] for x in non_scalars[1:]]):
raise IndexConformanceException("Indices are not consistent: %s" % expr)
if not reduce(lambda x, y: x != y or y, syms):
symmetries = syms[0]
else:
# FIXME: search for symmetries
symmetries = {}
return non_scalars[0], symmetries
def get_indices(expr):
"""Determine the outer indices of expression ``expr``
By *outer* we mean indices that are not summation indices. Returns a set
and a dict. The set contains outer indices and the dict contains
information about index symmetries.
Examples
========
>>> from sympy.tensor.index_methods import get_indices
>>> from sympy import symbols
>>> from sympy.tensor import IndexedBase
>>> x, y, A = map(IndexedBase, ['x', 'y', 'A'])
>>> i, j, a, z = symbols('i j a z', integer=True)
The indices of the total expression is determined, Repeated indices imply a
summation, for instance the trace of a matrix A:
>>> get_indices(A[i, i])
(set(), {})
In the case of many terms, the terms are required to have identical
outer indices. Else an IndexConformanceException is raised.
>>> get_indices(x[i] + A[i, j]*y[j])
({i}, {})
:Exceptions:
An IndexConformanceException means that the terms ar not compatible, e.g.
>>> get_indices(x[i] + y[j]) #doctest: +SKIP
(...)
IndexConformanceException: Indices are not consistent: x(i) + y(j)
.. warning::
The concept of *outer* indices applies recursively, starting on the deepest
level. This implies that dummies inside parenthesis are assumed to be
summed first, so that the following expression is handled gracefully:
>>> get_indices((x[i] + A[i, j]*y[j])*x[j])
({i, j}, {})
This is correct and may appear convenient, but you need to be careful
with this as SymPy will happily .expand() the product, if requested. The
resulting expression would mix the outer ``j`` with the dummies inside
the parenthesis, which makes it a different expression. To be on the
safe side, it is best to avoid such ambiguities by using unique indices
for all contractions that should be held separate.
"""
# We call ourself recursively to determine indices of sub expressions.
# break recursion
if isinstance(expr, Indexed):
c = expr.indices
inds, dummies = _remove_repeated(c)
return inds, {}
elif expr is None:
return set(), {}
elif isinstance(expr, Idx):
return {expr}, {}
elif expr.is_Atom:
return set(), {}
# recurse via specialized functions
else:
if expr.is_Mul:
return _get_indices_Mul(expr)
elif expr.is_Add:
return _get_indices_Add(expr)
elif expr.is_Pow or isinstance(expr, exp):
return _get_indices_Pow(expr)
elif isinstance(expr, Piecewise):
# FIXME: No support for Piecewise yet
return set(), {}
elif isinstance(expr, Function):
# Support ufunc like behaviour by returning indices from arguments.
# Functions do not interpret repeated indices across argumnts
# as summation
ind0 = set()
for arg in expr.args:
ind, sym = get_indices(arg)
ind0 |= ind
return ind0, sym
# this test is expensive, so it should be at the end
elif not expr.has(Indexed):
return set(), {}
raise NotImplementedError(
"FIXME: No specialized handling of type %s" % type(expr))
def get_contraction_structure(expr):
"""Determine dummy indices of ``expr`` and describe its structure
By *dummy* we mean indices that are summation indices.
The structure of the expression is determined and described as follows:
1) A conforming summation of Indexed objects is described with a dict where
the keys are summation indices and the corresponding values are sets
containing all terms for which the summation applies. All Add objects
in the SymPy expression tree are described like this.
2) For all nodes in the SymPy expression tree that are *not* of type Add, the
following applies:
If a node discovers contractions in one of its arguments, the node
itself will be stored as a key in the dict. For that key, the
corresponding value is a list of dicts, each of which is the result of a
recursive call to get_contraction_structure(). The list contains only
dicts for the non-trivial deeper contractions, omitting dicts with None
as the one and only key.
.. Note:: The presence of expressions among the dictionary keys indicates
multiple levels of index contractions. A nested dict displays nested
contractions and may itself contain dicts from a deeper level. In
practical calculations the summation in the deepest nested level must be
calculated first so that the outer expression can access the resulting
indexed object.
Examples
========
>>> from sympy.tensor.index_methods import get_contraction_structure
>>> from sympy import default_sort_key
>>> from sympy.tensor import IndexedBase, Idx
>>> x, y, A = map(IndexedBase, ['x', 'y', 'A'])
>>> i, j, k, l = map(Idx, ['i', 'j', 'k', 'l'])
>>> get_contraction_structure(x[i]*y[i] + A[j, j])
{(i,): {x[i]*y[i]}, (j,): {A[j, j]}}
>>> get_contraction_structure(x[i]*y[j])
{None: {x[i]*y[j]}}
A multiplication of contracted factors results in nested dicts representing
the internal contractions.
>>> d = get_contraction_structure(x[i, i]*y[j, j])
>>> sorted(d.keys(), key=default_sort_key)
[None, x[i, i]*y[j, j]]
In this case, the product has no contractions:
>>> d[None]
{x[i, i]*y[j, j]}
Factors are contracted "first":
>>> sorted(d[x[i, i]*y[j, j]], key=default_sort_key)
[{(i,): {x[i, i]}}, {(j,): {y[j, j]}}]
A parenthesized Add object is also returned as a nested dictionary. The
term containing the parenthesis is a Mul with a contraction among the
arguments, so it will be found as a key in the result. It stores the
dictionary resulting from a recursive call on the Add expression.
>>> d = get_contraction_structure(x[i]*(y[i] + A[i, j]*x[j]))
>>> sorted(d.keys(), key=default_sort_key)
[(A[i, j]*x[j] + y[i])*x[i], (i,)]
>>> d[(i,)]
{(A[i, j]*x[j] + y[i])*x[i]}
>>> d[x[i]*(A[i, j]*x[j] + y[i])]
[{None: {y[i]}, (j,): {A[i, j]*x[j]}}]
Powers with contractions in either base or exponent will also be found as
keys in the dictionary, mapping to a list of results from recursive calls:
>>> d = get_contraction_structure(A[j, j]**A[i, i])
>>> d[None]
{A[j, j]**A[i, i]}
>>> nested_contractions = d[A[j, j]**A[i, i]]
>>> nested_contractions[0]
{(j,): {A[j, j]}}
>>> nested_contractions[1]
{(i,): {A[i, i]}}
The description of the contraction structure may appear complicated when
represented with a string in the above examples, but it is easy to iterate
over:
>>> from sympy import Expr
>>> for key in d:
... if isinstance(key, Expr):
... continue
... for term in d[key]:
... if term in d:
... # treat deepest contraction first
... pass
... # treat outermost contactions here
"""
# We call ourself recursively to inspect sub expressions.
if isinstance(expr, Indexed):
junk, key = _remove_repeated(expr.indices)
return {key or None: {expr}}
elif expr.is_Atom:
return {None: {expr}}
elif expr.is_Mul:
junk, junk, key = _get_indices_Mul(expr, return_dummies=True)
result = {key or None: {expr}}
# recurse on every factor
nested = []
for fac in expr.args:
facd = get_contraction_structure(fac)
if not (None in facd and len(facd) == 1):
nested.append(facd)
if nested:
result[expr] = nested
return result
elif expr.is_Pow or isinstance(expr, exp):
# recurse in base and exp separately. If either has internal
# contractions we must include ourselves as a key in the returned dict
b, e = expr.as_base_exp()
dbase = get_contraction_structure(b)
dexp = get_contraction_structure(e)
dicts = []
for d in dbase, dexp:
if not (None in d and len(d) == 1):
dicts.append(d)
result = {None: {expr}}
if dicts:
result[expr] = dicts
return result
elif expr.is_Add:
# Note: we just collect all terms with identical summation indices, We
# do nothing to identify equivalent terms here, as this would require
# substitutions or pattern matching in expressions of unknown
# complexity.
result = {}
for term in expr.args:
# recurse on every term
d = get_contraction_structure(term)
for key in d:
if key in result:
result[key] |= d[key]
else:
result[key] = d[key]
return result
elif isinstance(expr, Piecewise):
# FIXME: No support for Piecewise yet
return {None: expr}
elif isinstance(expr, Function):
# Collect non-trivial contraction structures in each argument
# We do not report repeated indices in separate arguments as a
# contraction
deeplist = []
for arg in expr.args:
deep = get_contraction_structure(arg)
if not (None in deep and len(deep) == 1):
deeplist.append(deep)
d = {None: {expr}}
if deeplist:
d[expr] = deeplist
return d
# this test is expensive, so it should be at the end
elif not expr.has(Indexed):
return {None: {expr}}
raise NotImplementedError(
"FIXME: No specialized handling of type %s" % type(expr))
|
c8755a23292855f1aacf0b681a85ee94b43f6d9ad1a7a64cc933cbfb434ff8cc | 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.assumptions import StdFactKB
from sympy.core import Expr, Tuple, sympify, S
from sympy.core.symbol import _filter_assumptions, Symbol
from sympy.core.compatibility import (is_sequence, NotIterable,
Iterable)
from sympy.core.logic import fuzzy_bool, fuzzy_not
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 by indexing ``IndexedBase``:
``IndexedBase('A')[i, j]`` instead of ``Indexed(IndexedBase('A'), i, j)``.
>>> A = IndexedBase('A')
>>> a_ij = A[i, j] # Prefer this,
>>> b_ij = Indexed(A, i, j) # over this.
>>> a_ij == b_ij
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, (str, Symbol)):
base = IndexedBase(base)
elif not hasattr(base, '__getitem__') and not isinstance(base, IndexedBase):
raise TypeError(filldedent("""
The base can only be replaced with a string, Symbol,
IndexedBase or an object with a method for getting
items (i.e. an object with a `__getitem__` method).
"""))
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]
obj = Expr.__new__(cls, base, *args, **kw_args)
try:
IndexedBase._set_assumptions(obj, base.assumptions0)
except AttributeError:
IndexedBase._set_assumptions(obj, {})
return obj
def _hashable_content(self):
return super(Indexed, self)._hashable_content() + tuple(sorted(self.assumptions0.items()))
@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 assumptions0(self):
return {k: v for k, v in self._assumptions.items() if v is not None}
@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)
Assumptions can be specified with keyword arguments the same way as for Symbol:
>>> A_real = IndexedBase('A', real=True)
>>> A_real.is_real
True
>>> A != A_real
True
Assumptions can also be inherited if a Symbol is used to initialize the IndexedBase:
>>> I = symbols('I', integer=True)
>>> C_inherit = IndexedBase(I)
>>> C_explicit = IndexedBase('I', integer=True)
>>> C_inherit == C_explicit
True
"""
is_commutative = True
is_symbol = True
is_Atom = True
@staticmethod
def _set_assumptions(obj, assumptions):
"""Set assumptions on obj, making sure to apply consistent values."""
tmp_asm_copy = assumptions.copy()
is_commutative = fuzzy_bool(assumptions.get('commutative', True))
assumptions['commutative'] = is_commutative
obj._assumptions = StdFactKB(assumptions)
obj._assumptions._generator = tmp_asm_copy # Issue #8873
def __new__(cls, label, shape=None, **kw_args):
from sympy import MatrixBase, NDimArray
assumptions, kw_args = _filter_assumptions(kw_args)
if isinstance(label, str):
label = Symbol(label, **assumptions)
elif isinstance(label, Symbol):
assumptions = label._merge(assumptions)
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)
IndexedBase._set_assumptions(obj, assumptions)
return obj
@property
def name(self):
return self._name
def _hashable_content(self):
return super(IndexedBase, self)._hashable_content() + tuple(sorted(self.assumptions0.items()))
@property
def assumptions0(self):
return {k: v for k, v in self._assumptions.items() if v is not None}
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
>>> 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 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, str):
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 range is not S.Infinity and fuzzy_not(range.is_integer):
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)
|
026ed521cedcfe06c6496f3635b246315c8847589d702ee70e6e97254b02c8f1 | from typing import Dict, Any
import inspect
from .dispatcher import Dispatcher, MethodDispatcher, ambiguity_warn
# XXX: This parameter to dispatch isn't documented and isn't used anywhere in
# sympy. Maybe it should just be removed.
global_namespace = dict() # type: Dict[str, Any]
def dispatch(*types, **kwargs):
""" Dispatch function on the types of the inputs
Supports dispatch on all non-keyword arguments.
Collects implementations based on the function name. Ignores namespaces.
If ambiguous type signatures occur a warning is raised when the function is
defined suggesting the additional method to break the ambiguity.
Examples
--------
>>> from sympy.multipledispatch import dispatch
>>> @dispatch(int)
... def f(x):
... return x + 1
>>> @dispatch(float)
... def f(x): # noqa: F811
... return x - 1
>>> f(3)
4
>>> f(3.0)
2.0
Specify an isolated namespace with the namespace keyword argument
>>> my_namespace = dict()
>>> @dispatch(int, namespace=my_namespace)
... def foo(x):
... return x + 1
Dispatch on instance methods within classes
>>> class MyClass(object):
... @dispatch(list)
... def __init__(self, data):
... self.data = data
... @dispatch(int)
... def __init__(self, datum): # noqa: F811
... self.data = [datum]
"""
namespace = kwargs.get('namespace', global_namespace)
on_ambiguity = kwargs.get('on_ambiguity', ambiguity_warn)
types = tuple(types)
def _(func):
name = func.__name__
if ismethod(func):
dispatcher = inspect.currentframe().f_back.f_locals.get(
name,
MethodDispatcher(name))
else:
if name not in namespace:
namespace[name] = Dispatcher(name)
dispatcher = namespace[name]
dispatcher.add(types, func, on_ambiguity=on_ambiguity)
return dispatcher
return _
def ismethod(func):
""" Is func a method?
Note that this has to work as the method is defined but before the class is
defined. At this stage methods look like functions.
"""
signature = inspect.signature(func)
return signature.parameters.get('self', None) is not None
|
6a3834d54f2777f68a1e3f8bd90d4b613ecda40a819e3600407ff8ad703c7da3 | from typing import Set
from warnings import warn
import inspect
from .conflict import ordering, ambiguities, super_signature, AmbiguityWarning
from .utils import expand_tuples
import itertools as itl
class MDNotImplementedError(NotImplementedError):
""" A NotImplementedError for multiple dispatch """
def ambiguity_warn(dispatcher, ambiguities):
""" Raise warning when ambiguity is detected
Parameters
----------
dispatcher : Dispatcher
The dispatcher on which the ambiguity was detected
ambiguities : set
Set of type signature pairs that are ambiguous within this dispatcher
See Also:
Dispatcher.add
warning_text
"""
warn(warning_text(dispatcher.name, ambiguities), AmbiguityWarning)
_unresolved_dispatchers = set() # type: Set[Dispatcher]
_resolve = [True]
def halt_ordering():
_resolve[0] = False
def restart_ordering(on_ambiguity=ambiguity_warn):
_resolve[0] = True
while _unresolved_dispatchers:
dispatcher = _unresolved_dispatchers.pop()
dispatcher.reorder(on_ambiguity=on_ambiguity)
class Dispatcher:
""" Dispatch methods based on type signature
Use ``dispatch`` to add implementations
Examples
--------
>>> from sympy.multipledispatch import dispatch
>>> @dispatch(int)
... def f(x):
... return x + 1
>>> @dispatch(float)
... def f(x): # noqa: F811
... return x - 1
>>> f(3)
4
>>> f(3.0)
2.0
"""
__slots__ = '__name__', 'name', 'funcs', 'ordering', '_cache', 'doc'
def __init__(self, name, doc=None):
self.name = self.__name__ = name
self.funcs = dict()
self._cache = dict()
self.ordering = []
self.doc = doc
def register(self, *types, **kwargs):
""" Register dispatcher with new implementation
>>> from sympy.multipledispatch.dispatcher import Dispatcher
>>> f = Dispatcher('f')
>>> @f.register(int)
... def inc(x):
... return x + 1
>>> @f.register(float)
... def dec(x):
... return x - 1
>>> @f.register(list)
... @f.register(tuple)
... def reverse(x):
... return x[::-1]
>>> f(1)
2
>>> f(1.0)
0.0
>>> f([1, 2, 3])
[3, 2, 1]
"""
def _(func):
self.add(types, func, **kwargs)
return func
return _
@classmethod
def get_func_params(cls, func):
if hasattr(inspect, "signature"):
sig = inspect.signature(func)
return sig.parameters.values()
@classmethod
def get_func_annotations(cls, func):
""" Get annotations of function positional parameters
"""
params = cls.get_func_params(func)
if params:
Parameter = inspect.Parameter
params = (param for param in params
if param.kind in
(Parameter.POSITIONAL_ONLY,
Parameter.POSITIONAL_OR_KEYWORD))
annotations = tuple(
param.annotation
for param in params)
if all(ann is not Parameter.empty for ann in annotations):
return annotations
def add(self, signature, func, on_ambiguity=ambiguity_warn):
""" Add new types/method pair to dispatcher
>>> from sympy.multipledispatch import Dispatcher
>>> D = Dispatcher('add')
>>> D.add((int, int), lambda x, y: x + y)
>>> D.add((float, float), lambda x, y: x + y)
>>> D(1, 2)
3
>>> D(1, 2.0)
Traceback (most recent call last):
...
NotImplementedError: Could not find signature for add: <int, float>
When ``add`` detects a warning it calls the ``on_ambiguity`` callback
with a dispatcher/itself, and a set of ambiguous type signature pairs
as inputs. See ``ambiguity_warn`` for an example.
"""
# Handle annotations
if not signature:
annotations = self.get_func_annotations(func)
if annotations:
signature = annotations
# Handle union types
if any(isinstance(typ, tuple) for typ in signature):
for typs in expand_tuples(signature):
self.add(typs, func, on_ambiguity)
return
for typ in signature:
if not isinstance(typ, type):
str_sig = ', '.join(c.__name__ if isinstance(c, type)
else str(c) for c in signature)
raise TypeError("Tried to dispatch on non-type: %s\n"
"In signature: <%s>\n"
"In function: %s" %
(typ, str_sig, self.name))
self.funcs[signature] = func
self.reorder(on_ambiguity=on_ambiguity)
self._cache.clear()
def reorder(self, on_ambiguity=ambiguity_warn):
if _resolve[0]:
self.ordering = ordering(self.funcs)
amb = ambiguities(self.funcs)
if amb:
on_ambiguity(self, amb)
else:
_unresolved_dispatchers.add(self)
def __call__(self, *args, **kwargs):
types = tuple([type(arg) for arg in args])
try:
func = self._cache[types]
except KeyError:
func = self.dispatch(*types)
if not func:
raise NotImplementedError(
'Could not find signature for %s: <%s>' %
(self.name, str_signature(types)))
self._cache[types] = func
try:
return func(*args, **kwargs)
except MDNotImplementedError:
funcs = self.dispatch_iter(*types)
next(funcs) # burn first
for func in funcs:
try:
return func(*args, **kwargs)
except MDNotImplementedError:
pass
raise NotImplementedError("Matching functions for "
"%s: <%s> found, but none completed successfully"
% (self.name, str_signature(types)))
def __str__(self):
return "<dispatched %s>" % self.name
__repr__ = __str__
def dispatch(self, *types):
""" Deterimine appropriate implementation for this type signature
This method is internal. Users should call this object as a function.
Implementation resolution occurs within the ``__call__`` method.
>>> from sympy.multipledispatch import dispatch
>>> @dispatch(int)
... def inc(x):
... return x + 1
>>> implementation = inc.dispatch(int)
>>> implementation(3)
4
>>> print(inc.dispatch(float))
None
See Also:
``sympy.multipledispatch.conflict`` - module to determine resolution order
"""
if types in self.funcs:
return self.funcs[types]
try:
return next(self.dispatch_iter(*types))
except StopIteration:
return None
def dispatch_iter(self, *types):
n = len(types)
for signature in self.ordering:
if len(signature) == n and all(map(issubclass, types, signature)):
result = self.funcs[signature]
yield result
def resolve(self, types):
""" Deterimine appropriate implementation for this type signature
.. deprecated:: 0.4.4
Use ``dispatch(*types)`` instead
"""
warn("resolve() is deprecated, use dispatch(*types)",
DeprecationWarning)
return self.dispatch(*types)
def __getstate__(self):
return {'name': self.name,
'funcs': self.funcs}
def __setstate__(self, d):
self.name = d['name']
self.funcs = d['funcs']
self.ordering = ordering(self.funcs)
self._cache = dict()
@property
def __doc__(self):
docs = ["Multiply dispatched method: %s" % self.name]
if self.doc:
docs.append(self.doc)
other = []
for sig in self.ordering[::-1]:
func = self.funcs[sig]
if func.__doc__:
s = 'Inputs: <%s>\n' % str_signature(sig)
s += '-' * len(s) + '\n'
s += func.__doc__.strip()
docs.append(s)
else:
other.append(str_signature(sig))
if other:
docs.append('Other signatures:\n ' + '\n '.join(other))
return '\n\n'.join(docs)
def _help(self, *args):
return self.dispatch(*map(type, args)).__doc__
def help(self, *args, **kwargs):
""" Print docstring for the function corresponding to inputs """
print(self._help(*args))
def _source(self, *args):
func = self.dispatch(*map(type, args))
if not func:
raise TypeError("No function found")
return source(func)
def source(self, *args, **kwargs):
""" Print source code for the function corresponding to inputs """
print(self._source(*args))
def source(func):
s = 'File: %s\n\n' % inspect.getsourcefile(func)
s = s + inspect.getsource(func)
return s
class MethodDispatcher(Dispatcher):
""" Dispatch methods based on type signature
See Also:
Dispatcher
"""
@classmethod
def get_func_params(cls, func):
if hasattr(inspect, "signature"):
sig = inspect.signature(func)
return itl.islice(sig.parameters.values(), 1, None)
def __get__(self, instance, owner):
self.obj = instance
self.cls = owner
return self
def __call__(self, *args, **kwargs):
types = tuple([type(arg) for arg in args])
func = self.dispatch(*types)
if not func:
raise NotImplementedError('Could not find signature for %s: <%s>' %
(self.name, str_signature(types)))
return func(self.obj, *args, **kwargs)
def str_signature(sig):
""" String representation of type signature
>>> from sympy.multipledispatch.dispatcher import str_signature
>>> str_signature((int, float))
'int, float'
"""
return ', '.join(cls.__name__ for cls in sig)
def warning_text(name, amb):
""" The text for ambiguity warnings """
text = "\nAmbiguities exist in dispatched function %s\n\n" % (name)
text += "The following signatures may result in ambiguous behavior:\n"
for pair in amb:
text += "\t" + \
', '.join('[' + str_signature(s) + ']' for s in pair) + "\n"
text += "\n\nConsider making the following additions:\n\n"
text += '\n\n'.join(['@dispatch(' + str_signature(super_signature(s))
+ ')\ndef %s(...)' % name for s in amb])
return text
|
8e33bb989e2bcdfb6fbe86291f90e6e9c610269b5f82831d16a76664d7fd4318 | """
Boolean algebra module for SymPy
"""
from collections import defaultdict
from itertools import chain, 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, as_int
from sympy.core.function import Application, Derivative
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(0) is false
True
>>> 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`.
>>> as_Boolean(nan)
Traceback (most recent call last):
...
TypeError: expecting bool or Boolean, not `nan`.
"""
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()
FiniteSet(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(BooleanAtom, metaclass=Singleton):
"""
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(BooleanAtom, metaclass=Singleton):
"""
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, **kwargs):
rv = self.func(*[
a._eval_simplify(**kwargs) for a in self.args])
return simplify_logic(rv)
def simplify(self, **kwargs):
from sympy.simplify.simplify import simplify
return simplify(self, **kwargs)
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)
def to_anf(self, deep=True):
return self._to_anf(*self.args, deep=deep)
@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)
@classmethod
def _to_anf(cls, *args, **kwargs):
deep = kwargs.get('deep', True)
argset = set()
for arg in args:
if deep:
if not is_literal(arg) or isinstance(arg, Not):
arg = arg.to_anf(deep=deep)
argset.add(arg)
else:
argset.add(arg)
return cls(*argset, remove_true=False)
# 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(Rel, 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.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):
args = BooleanFunction.binary_check_and_simplify(*args)
args = LatticeOp._new_args_filter(args, And)
newargs = []
rel = set()
for x in ordered(args):
if x.is_Relational:
c = x.canonical
if c in rel:
continue
elif c.negated.canonical in rel:
return [S.false]
else:
rel.add(c)
newargs.append(x)
return newargs
def _eval_subs(self, old, new):
args = []
bad = None
for i in self.args:
try:
i = i.subs(old, new)
except TypeError:
# store TypeError
if bad is None:
bad = i
continue
if i == False:
return S.false
elif i != True:
args.append(i)
if bad is not None:
# let it raise
bad.subs(old, new)
return self.func(*args)
def _eval_simplify(self, **kwargs):
from sympy.core.relational import Equality, Relational
from sympy.solvers.solveset import linear_coeffs
# standard simplify
rv = super()._eval_simplify(**kwargs)
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
measure, ratio = kwargs['measure'], kwargs['ratio']
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])
def _eval_rewrite_as_Nor(self, *args, **kwargs):
return Nor(*[Not(arg) for arg in self.args])
def to_anf(self, deep=True):
if deep:
result = And._to_anf(*self.args, deep=deep)
return distribute_xor_over_and(result)
return self
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.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_subs(self, old, new):
args = []
bad = None
for i in self.args:
try:
i = i.subs(old, new)
except TypeError:
# store TypeError
if bad is None:
bad = i
continue
if i == True:
return S.true
elif i != False:
args.append(i)
if bad is not None:
# let it raise
bad.subs(old, new)
return self.func(*args)
def _eval_as_set(self):
from sympy.sets.sets import Union
return Union(*[arg.as_set() for arg in self.args])
def _eval_rewrite_as_Nand(self, *args, **kwargs):
return Nand(*[Not(arg) for arg in self.args])
def _eval_simplify(self, **kwargs):
# standard simplify
rv = super()._eval_simplify(**kwargs)
if not isinstance(rv, Or):
return rv
patterns = simplify_patterns_or()
return self._apply_patternbased_simplification(rv, patterns,
kwargs['measure'], S.true)
def to_anf(self, deep=True):
args = range(1, len(self.args) + 1)
args = (combinations(self.args, j) for j in args)
args = chain.from_iterable(args) # powerset
args = (And(*arg) for arg in args)
args = map(lambda x: to_anf(x, deep=deep) if deep else x, args)
return Xor(*list(args), remove_true=False)
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)
def to_anf(self, deep=True):
return Xor._to_anf(true, self.args[0], deep=deep)
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
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()
remove_true = kwargs.pop('remove_true', True)
obj = super().__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 and remove_true:
argset.remove(True)
return Not(Xor(*argset))
else:
obj._args = tuple(ordered(argset))
obj._argset = frozenset(argset)
return obj
# XXX: This should be cached on the object rather than using cacheit
# Maybe it can be computed in __new__?
@property # type: ignore
@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_rewrite_as_Or(self, *args, **kwargs):
a = self.args
return Or(*[_convert_to_varsSOP(x, self.args)
for x in _get_odd_parity_terms(len(a))])
def _eval_rewrite_as_And(self, *args, **kwargs):
a = self.args
return And(*[_convert_to_varsPOS(x, self.args)
for x in _get_even_parity_terms(len(a))])
def _eval_simplify(self, **kwargs):
# 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(**kwargs) 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,
kwargs['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)
def to_anf(self, deep=True):
a, b = self.args
return Xor._to_anf(true, a, And(a, b), deep=deep)
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
>>> 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().__new__(cls, _args)
obj._argset = _args
return obj
# XXX: This should be cached on the object rather than using cacheit
# Maybe it can be computed in __new__?
@property # type: ignore
@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)
def to_anf(self, deep=True):
a = And(*self.args)
b = And(*[to_anf(Not(arg), deep=False) for arg in self.args])
b = distribute_xor_over_and(b)
return Xor._to_anf(a, b, deep=deep)
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_xor_over_and(expr):
"""
Given a sentence s consisting of conjunction and
exclusive disjunctions of literals, return an
equivalent exclusive disjunction.
Note that the output is NOT simplified.
Examples
========
>>> from sympy.logic.boolalg import distribute_xor_over_and, And, Xor, Not
>>> from sympy.abc import A, B, C
>>> distribute_xor_over_and(And(Xor(Not(A), B), C))
(B & C) ^ (C & ~A)
"""
return _distribute((expr, Xor, 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])), remove_true=False)
elif isinstance(info[0], info[1]):
return info[1](*list(map(_distribute,
[(x, info[1], info[2])
for x in info[0].args])),
remove_true=False)
else:
return info[0]
def to_anf(expr, deep=True):
r"""
Converts expr to Algebraic Normal Form (ANF).
ANF is a canonical normal form, which means that two
equivalent formulas will convert to the same ANF.
A logical expression is in ANF if it has the form
.. math:: 1 \oplus a \oplus b \oplus ab \oplus abc
i.e. it can be:
- purely true,
- purely false,
- conjunction of variables,
- exclusive disjunction.
The exclusive disjunction can only contain true, variables
or conjunction of variables. No negations are permitted.
If ``deep`` is ``False``, arguments of the boolean
expression are considered variables, i.e. only the
top-level expression is converted to ANF.
Examples
========
>>> from sympy.logic.boolalg import And, Or, Not, Implies, Equivalent
>>> from sympy.logic.boolalg import to_anf
>>> from sympy.abc import A, B, C
>>> to_anf(Not(A))
A ^ True
>>> to_anf(And(Or(A, B), Not(C)))
A ^ B ^ (A & B) ^ (A & C) ^ (B & C) ^ (A & B & C)
>>> to_anf(Implies(Not(A), Equivalent(B, C)), deep=False)
True ^ ~A ^ (~A & (Equivalent(B, C)))
"""
expr = sympify(expr)
if is_anf(expr):
return expr
return expr.to_anf(deep=deep)
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, force=False):
"""
Convert a propositional logical sentence s to conjunctive normal
form: ((A | ~B | ...) & (B | C | ...) & ...).
If simplify is True, the expr is evaluated to its simplest CNF
form using the Quine-McCluskey algorithm; this may take a long
time if there are more than 8 variables and requires that the
``force`` flag be set to True (default is False).
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:
if not force and len(_find_predicates(expr)) > 8:
raise ValueError(filldedent('''
To simplify a logical expression with more
than 8 variables may take a long time and requires
the use of `force=True`.'''))
return simplify_logic(expr, 'cnf', True, force=force)
# Don't convert unless we have to
if is_cnf(expr):
return expr
expr = eliminate_implications(expr)
res = distribute_and_over_or(expr)
return res
def to_dnf(expr, simplify=False, force=False):
"""
Convert a propositional logical sentence s to disjunctive normal
form: ((A & ~B & ...) | (B & C & ...) | ...).
If simplify is True, the expr is evaluated to its simplest DNF form using
the Quine-McCluskey algorithm; this may take a long
time if there are more than 8 variables and requires that the
``force`` flag be set to True (default is False).
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:
if not force and len(_find_predicates(expr)) > 8:
raise ValueError(filldedent('''
To simplify a logical expression with more
than 8 variables may take a long time and requires
the use of `force=True`.'''))
return simplify_logic(expr, 'dnf', True, force=force)
# 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_anf(expr):
r"""
Checks if expr is in Algebraic Normal Form (ANF).
A logical expression is in ANF if it has the form
.. math:: 1 \oplus a \oplus b \oplus ab \oplus abc
i.e. it is purely true, purely false, conjunction of
variables or exclusive disjunction. The exclusive
disjunction can only contain true, variables or
conjunction of variables. No negations are permitted.
Examples
========
>>> from sympy.logic.boolalg import And, Not, Xor, true, is_anf
>>> from sympy.abc import A, B, C
>>> is_anf(true)
True
>>> is_anf(A)
True
>>> is_anf(And(A, B, C))
True
>>> is_anf(Xor(A, Not(B)))
False
"""
expr = sympify(expr)
if is_literal(expr) and not isinstance(expr, Not):
return True
if isinstance(expr, And):
for arg in expr.args:
if not arg.is_Symbol:
return False
return True
elif isinstance(expr, Xor):
for arg in expr.args:
if isinstance(arg, And):
for a in arg.args:
if not a.is_Symbol:
return False
elif is_literal(arg):
if isinstance(arg, Not):
return False
else:
return False
return True
else:
return False
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 simplified 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)
vals = function1.make_args(expr) if isinstance(expr, function1) else [expr]
for lit in vals:
if isinstance(lit, function2):
vals2 = function2.make_args(lit) if isinstance(lit, function2) else [lit]
for l in vals2:
if is_literal(l) is False:
return False
elif is_literal(lit) is False:
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 is_literal(expr.args[0])
elif expr in (True, False) or expr.is_Atom:
return True
elif not isinstance(expr, BooleanFunction) and all(
a.is_Atom for a in expr.args):
return True
return False
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 [{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 _convert_to_varsANF(term, variables):
"""
Converts a term in the expansion of a function from binary to it's
variable form (for ANF).
Parameters
==========
term : list of 1's and 0's (complementation patter)
variables : list of variables
"""
temp = []
for i, m in enumerate(term):
if m == 1:
temp.append(variables[i])
else:
pass # ignore 0s
if temp == []:
return BooleanTrue()
return And(*temp)
def _get_odd_parity_terms(n):
"""
Returns a list of lists, with all possible combinations of n zeros and ones
with an odd number of ones.
"""
op = []
for i in range(1, 2**n):
e = ibin(i, n)
if sum(e) % 2 == 1:
op.append(e)
return op
def _get_even_parity_terms(n):
"""
Returns a list of lists, with all possible combinations of n zeros and ones
with an even number of ones.
"""
op = []
for i in range(2**n):
e = ibin(i, n)
if sum(e) % 2 == 0:
op.append(e)
return op
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] https://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] https://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 ANFform(variables, truthvalues):
"""
The ANFform function converts the list of truth values to
Algebraic Normal Form (ANF).
The variables must be given as the first argument.
Return True, False, logical And funciton (i.e., the
"Zhegalkin monomial") or logical Xor function (i.e.,
the "Zhegalkin polynomial"). When True and False
are represented by 1 and 0, respectively, then
And is multiplication and Xor is addition.
Formally a "Zhegalkin monomial" is the product (logical
And) of a finite set of distinct variables, including
the empty set whose product is denoted 1 (True).
A "Zhegalkin polynomial" is the sum (logical Xor) of a
set of Zhegalkin monomials, with the empty set denoted
by 0 (False).
Parameters
==========
variables : list of variables
truthvalues : list of 1's and 0's (result column of truth table)
Examples
========
>>> from sympy.logic.boolalg import ANFform
>>> from sympy.abc import x, y
>>> ANFform([x], [1, 0])
x ^ True
>>> ANFform([x, y], [0, 1, 1, 1])
x ^ y ^ (x & y)
References
==========
.. [2] https://en.wikipedia.org/wiki/Zhegalkin_polynomial
"""
n_vars = len(variables)
n_values = len(truthvalues)
if n_values != 2 ** n_vars:
raise ValueError("The number of truth values must be equal to 2^%d, "
"got %d" % (n_vars, n_values))
variables = [sympify(v) for v in variables]
coeffs = anf_coeffs(truthvalues)
terms = []
for i, t in enumerate(product([0, 1], repeat=n_vars)):
if coeffs[i] == 1:
terms.append(t)
return Xor(*[_convert_to_varsANF(x, variables) for x in terms],
remove_true=False)
def anf_coeffs(truthvalues):
"""
Convert a list of truth values of some boolean expression
to the list of coefficients of the polynomial mod 2 (exclusive
disjunction) representing the boolean expression in ANF
(i.e., the "Zhegalkin polynomial").
There are 2^n possible Zhegalkin monomials in n variables, since
each monomial is fully specified by the presence or absence of
each variable.
We can enumerate all the monomials. For example, boolean
function with four variables (a, b, c, d) can contain
up to 2^4 = 16 monomials. The 13-th monomial is the
product a & b & d, because 13 in binary is 1, 1, 0, 1.
A given monomial's presence or absence in a polynomial corresponds
to that monomial's coefficient being 1 or 0 respectively.
Examples
========
>>> from sympy.logic.boolalg import anf_coeffs, bool_monomial, Xor
>>> from sympy.abc import a, b, c
>>> truthvalues = [0, 1, 1, 0, 0, 1, 0, 1]
>>> coeffs = anf_coeffs(truthvalues)
>>> coeffs
[0, 1, 1, 0, 0, 0, 1, 0]
>>> polynomial = Xor(*[
... bool_monomial(k, [a, b, c])
... for k, coeff in enumerate(coeffs) if coeff == 1
... ])
>>> polynomial
b ^ c ^ (a & b)
"""
s = '{:b}'.format(len(truthvalues))
n = len(s) - 1
if len(truthvalues) != 2**n:
raise ValueError("The number of truth values must be a power of two, "
"got %d" % len(truthvalues))
coeffs = [[v] for v in truthvalues]
for i in range(n):
tmp = []
for j in range(2 ** (n-i-1)):
tmp.append(coeffs[2*j] +
list(map(lambda x, y: x^y, coeffs[2*j], coeffs[2*j+1])))
coeffs = tmp
return coeffs[0]
def bool_minterm(k, variables):
"""
Return the k-th minterm.
Minterms are numbered by a binary encoding of the complementation
pattern of the variables. This convention assigns the value 1 to
the direct form and 0 to the complemented form.
Parameters
==========
k : int or list of 1's and 0's (complementation patter)
variables : list of variables
Examples
========
>>> from sympy.logic.boolalg import bool_minterm
>>> from sympy.abc import x, y, z
>>> bool_minterm([1, 0, 1], [x, y, z])
x & z & ~y
>>> bool_minterm(6, [x, y, z])
x & y & ~z
References
==========
.. [3] https://en.wikipedia.org/wiki/Canonical_normal_form#Indexing_minterms
"""
if isinstance(k, int):
k = integer_to_term(k, len(variables))
variables = list(map(sympify, variables))
return _convert_to_varsSOP(k, variables)
def bool_maxterm(k, variables):
"""
Return the k-th maxterm.
Each maxterm is assigned an index based on the opposite
conventional binary encoding used for minterms. The maxterm
convention assigns the value 0 to the direct form and 1 to
the complemented form.
Parameters
==========
k : int or list of 1's and 0's (complementation pattern)
variables : list of variables
Examples
========
>>> from sympy.logic.boolalg import bool_maxterm
>>> from sympy.abc import x, y, z
>>> bool_maxterm([1, 0, 1], [x, y, z])
y | ~x | ~z
>>> bool_maxterm(6, [x, y, z])
z | ~x | ~y
References
==========
.. [4] https://en.wikipedia.org/wiki/Canonical_normal_form#Indexing_maxterms
"""
if isinstance(k, int):
k = integer_to_term(k, len(variables))
variables = list(map(sympify, variables))
return _convert_to_varsPOS(k, variables)
def bool_monomial(k, variables):
"""
Return the k-th monomial.
Monomials are numbered by a binary encoding of the presence and
absences of the variables. This convention assigns the value
1 to the presence of variable and 0 to the absence of variable.
Each boolean function can be uniquely represented by a
Zhegalkin Polynomial (Algebraic Normal Form). The Zhegalkin
Polynomial of the boolean function with n variables can contain
up to 2^n monomials. We can enumarate all the monomials.
Each monomial is fully specified by the presence or absence
of each variable.
For example, boolean function with four variables (a, b, c, d)
can contain up to 2^4 = 16 monomials. The 13-th monomial is the
product a & b & d, because 13 in binary is 1, 1, 0, 1.
Parameters
==========
k : int or list of 1's and 0's
variables : list of variables
Examples
========
>>> from sympy.logic.boolalg import bool_monomial
>>> from sympy.abc import x, y, z
>>> bool_monomial([1, 0, 1], [x, y, z])
x & z
>>> bool_monomial(6, [x, y, z])
x & y
"""
if isinstance(k, int):
k = integer_to_term(k, len(variables))
variables = list(map(sympify, variables))
return _convert_to_varsANF(k, variables)
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)
# check for quick exit: right form and all args are
# literal and do not involve Not
isc = is_cnf(expr)
isd = is_dnf(expr)
form_ok = (
isc and form == 'cnf' or
isd and form == 'dnf')
if form_ok and all(is_literal(a)
for a in expr.args):
return 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;
a sorted tuple of tuples, (i, j, k), where i is the number of arguments
in an And or Or with which it appeared as a Symbol, and j is
the number of arguments that were Not(Symbol); k is the number
of times that (i, j) was seen.
]
Examples
========
>>> from sympy.logic.boolalg import _finger as finger
>>> from sympy import And, Or, Not, Xor, to_cnf, symbols
>>> 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, 0, 1),)): [x],
(0, 0, 1, 0, ((2, 1, 1),)): [a, b],
(0, 0, 1, 2, ((2, 0, 1),)): [y]}
>>> dict(finger(x & ~y))
{(0, 1, 0, 0, ()): [y], (1, 0, 0, 0, ()): [x]}
In the following, the (5, 2, 6) means that there were 6 Or
functions in which a symbol appeared as itself amongst 5 arguments in
which there were also 2 negated symbols, e.g. ``(a0 | a1 | a2 | ~a3 | ~a4)``
is counted once for a0, a1 and a2.
>>> dict(finger(to_cnf(Xor(*symbols('a:5')))))
{(0, 0, 8, 8, ((5, 0, 1), (5, 2, 6), (5, 4, 1))): [a0, a1, a2, a3, a4]}
The equation must not have more than one level of nesting:
>>> dict(finger(And(Or(x, y), y)))
{(0, 0, 1, 0, ((2, 0, 1),)): [x], (1, 0, 1, 0, ((2, 0, 1),)): [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]*4 + [defaultdict(int)] 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] += 1
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())):
v[-1] = tuple(sorted([i + (j,) for i, j in v[-1].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.Zero), Eq(b, S.Zero))),
)
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
|
a0f7d986fc0f25aa6659223beca1f8baa794ff0e56b7822de497c6f63d6f360d | """Inference in propositional logic"""
from sympy.logic.boolalg import And, Not, conjuncts, to_cnf
from sympy.core.compatibility import ordered
from sympy.core.sympify import sympify
from sympy.external.importtools import import_module
def literal_symbol(literal):
"""
The symbol in this literal (without the negation).
Examples
========
>>> from sympy.abc import A
>>> from sympy.logic.inference import literal_symbol
>>> literal_symbol(A)
A
>>> literal_symbol(~A)
A
"""
if literal is True or literal is False:
return literal
try:
if literal.is_Symbol:
return literal
if literal.is_Not:
return literal_symbol(literal.args[0])
else:
raise ValueError
except (AttributeError, ValueError):
raise ValueError("Argument must be a boolean literal.")
def satisfiable(expr, algorithm=None, all_models=False):
"""
Check satisfiability of a propositional sentence.
Returns a model when it succeeds.
Returns {true: true} for trivially true expressions.
On setting all_models to True, if given expr is satisfiable then
returns a generator of models. However, if expr is unsatisfiable
then returns a generator containing the single element False.
Examples
========
>>> from sympy.abc import A, B
>>> from sympy.logic.inference import satisfiable
>>> satisfiable(A & ~B)
{A: True, B: False}
>>> satisfiable(A & ~A)
False
>>> satisfiable(True)
{True: True}
>>> next(satisfiable(A & ~A, all_models=True))
False
>>> models = satisfiable((A >> B) & B, all_models=True)
>>> next(models)
{A: False, B: True}
>>> next(models)
{A: True, B: True}
>>> def use_models(models):
... for model in models:
... if model:
... # Do something with the model.
... print(model)
... else:
... # Given expr is unsatisfiable.
... print("UNSAT")
>>> use_models(satisfiable(A >> ~A, all_models=True))
{A: False}
>>> use_models(satisfiable(A ^ A, all_models=True))
UNSAT
"""
if algorithm is None or algorithm == "pycosat":
pycosat = import_module('pycosat')
if pycosat is not None:
algorithm = "pycosat"
else:
if algorithm == "pycosat":
raise ImportError("pycosat module is not present")
# Silently fall back to dpll2 if pycosat
# is not installed
algorithm = "dpll2"
if algorithm == "dpll":
from sympy.logic.algorithms.dpll import dpll_satisfiable
return dpll_satisfiable(expr)
elif algorithm == "dpll2":
from sympy.logic.algorithms.dpll2 import dpll_satisfiable
return dpll_satisfiable(expr, all_models)
elif algorithm == "pycosat":
from sympy.logic.algorithms.pycosat_wrapper import pycosat_satisfiable
return pycosat_satisfiable(expr, all_models)
raise NotImplementedError
def valid(expr):
"""
Check validity of a propositional sentence.
A valid propositional sentence is True under every assignment.
Examples
========
>>> from sympy.abc import A, B
>>> from sympy.logic.inference import valid
>>> valid(A | ~A)
True
>>> valid(A | B)
False
References
==========
.. [1] https://en.wikipedia.org/wiki/Validity
"""
return not satisfiable(Not(expr))
def pl_true(expr, model={}, deep=False):
"""
Returns whether the given assignment is a model or not.
If the assignment does not specify the value for every proposition,
this may return None to indicate 'not obvious'.
Parameters
==========
model : dict, optional, default: {}
Mapping of symbols to boolean values to indicate assignment.
deep: boolean, optional, default: False
Gives the value of the expression under partial assignments
correctly. May still return None to indicate 'not obvious'.
Examples
========
>>> from sympy.abc import A, B
>>> from sympy.logic.inference import pl_true
>>> pl_true( A & B, {A: True, B: True})
True
>>> pl_true(A & B, {A: False})
False
>>> pl_true(A & B, {A: True})
>>> pl_true(A & B, {A: True}, deep=True)
>>> pl_true(A >> (B >> A))
>>> pl_true(A >> (B >> A), deep=True)
True
>>> pl_true(A & ~A)
>>> pl_true(A & ~A, deep=True)
False
>>> pl_true(A & B & (~A | ~B), {A: True})
>>> pl_true(A & B & (~A | ~B), {A: True}, deep=True)
False
"""
from sympy.core.symbol import Symbol
from sympy.logic.boolalg import BooleanFunction
boolean = (True, False)
def _validate(expr):
if isinstance(expr, Symbol) or expr in boolean:
return True
if not isinstance(expr, BooleanFunction):
return False
return all(_validate(arg) for arg in expr.args)
if expr in boolean:
return expr
expr = sympify(expr)
if not _validate(expr):
raise ValueError("%s is not a valid boolean expression" % expr)
model = {k: v for k, v in model.items() if v in boolean}
result = expr.subs(model)
if result in boolean:
return bool(result)
if deep:
model = {k: True for k in result.atoms()}
if pl_true(result, model):
if valid(result):
return True
else:
if not satisfiable(result):
return False
return None
def entails(expr, formula_set={}):
"""
Check whether the given expr_set entail an expr.
If formula_set is empty then it returns the validity of expr.
Examples
========
>>> from sympy.abc import A, B, C
>>> from sympy.logic.inference import entails
>>> entails(A, [A >> B, B >> C])
False
>>> entails(C, [A >> B, B >> C, A])
True
>>> entails(A >> B)
False
>>> entails(A >> (B >> A))
True
References
==========
.. [1] https://en.wikipedia.org/wiki/Logical_consequence
"""
formula_set = list(formula_set)
formula_set.append(Not(expr))
return not satisfiable(And(*formula_set))
class KB:
"""Base class for all knowledge bases"""
def __init__(self, sentence=None):
self.clauses_ = set()
if sentence:
self.tell(sentence)
def tell(self, sentence):
raise NotImplementedError
def ask(self, query):
raise NotImplementedError
def retract(self, sentence):
raise NotImplementedError
@property
def clauses(self):
return list(ordered(self.clauses_))
class PropKB(KB):
"""A KB for Propositional Logic. Inefficient, with no indexing."""
def tell(self, sentence):
"""Add the sentence's clauses to the KB
Examples
========
>>> from sympy.logic.inference import PropKB
>>> from sympy.abc import x, y
>>> l = PropKB()
>>> l.clauses
[]
>>> l.tell(x | y)
>>> l.clauses
[x | y]
>>> l.tell(y)
>>> l.clauses
[y, x | y]
"""
for c in conjuncts(to_cnf(sentence)):
self.clauses_.add(c)
def ask(self, query):
"""Checks if the query is true given the set of clauses.
Examples
========
>>> from sympy.logic.inference import PropKB
>>> from sympy.abc import x, y
>>> l = PropKB()
>>> l.tell(x & ~y)
>>> l.ask(x)
True
>>> l.ask(y)
False
"""
return entails(query, self.clauses_)
def retract(self, sentence):
"""Remove the sentence's clauses from the KB
Examples
========
>>> from sympy.logic.inference import PropKB
>>> from sympy.abc import x, y
>>> l = PropKB()
>>> l.clauses
[]
>>> l.tell(x | y)
>>> l.clauses
[x | y]
>>> l.retract(x | y)
>>> l.clauses
[]
"""
for c in conjuncts(to_cnf(sentence)):
self.clauses_.discard(c)
|
70cc62cea630574ee7e8a4de0df80ee6e2e61b28bda8c7b425f25e117fed0784 | import copy
from sympy.core.function import expand_mul
from sympy.functions.elementary.miscellaneous import Min, sqrt
from .common import NonSquareMatrixError, NonPositiveDefiniteMatrixError
from .utilities import _get_intermediate_simp, _iszero
from .determinant import _find_reasonable_pivot_naive
def _rank_decomposition(M, iszerofunc=_iszero, simplify=False):
r"""Returns a pair of matrices (`C`, `F`) with matching rank
such that `A = C F`.
Parameters
==========
iszerofunc : Function, optional
A function used for detecting whether an element can
act as a pivot. ``lambda x: x.is_zero`` is used by default.
simplify : Bool or Function, optional
A function used to simplify elements when looking for a
pivot. By default SymPy's ``simplify`` is used.
Returns
=======
(C, F) : Matrices
`C` and `F` are full-rank matrices with rank as same as `A`,
whose product gives `A`.
See Notes for additional mathematical details.
Examples
========
>>> from sympy.matrices import Matrix
>>> A = Matrix([
... [1, 3, 1, 4],
... [2, 7, 3, 9],
... [1, 5, 3, 1],
... [1, 2, 0, 8]
... ])
>>> C, F = A.rank_decomposition()
>>> C
Matrix([
[1, 3, 4],
[2, 7, 9],
[1, 5, 1],
[1, 2, 8]])
>>> F
Matrix([
[1, 0, -2, 0],
[0, 1, 1, 0],
[0, 0, 0, 1]])
>>> C * F == A
True
Notes
=====
Obtaining `F`, an RREF of `A`, is equivalent to creating a
product
.. math::
E_n E_{n-1} ... E_1 A = F
where `E_n, E_{n-1}, ... , E_1` are the elimination matrices or
permutation matrices equivalent to each row-reduction step.
The inverse of the same product of elimination matrices gives
`C`:
.. math::
C = (E_n E_{n-1} ... E_1)^{-1}
It is not necessary, however, to actually compute the inverse:
the columns of `C` are those from the original matrix with the
same column indices as the indices of the pivot columns of `F`.
References
==========
.. [1] https://en.wikipedia.org/wiki/Rank_factorization
.. [2] Piziak, R.; Odell, P. L. (1 June 1999).
"Full Rank Factorization of Matrices".
Mathematics Magazine. 72 (3): 193. doi:10.2307/2690882
See Also
========
rref
"""
F, pivot_cols = M.rref(simplify=simplify, iszerofunc=iszerofunc,
pivots=True)
rank = len(pivot_cols)
C = M.extract(range(M.rows), pivot_cols)
F = F[:rank, :]
return C, F
def _liupc(M):
"""Liu's algorithm, for pre-determination of the Elimination Tree of
the given matrix, used in row-based symbolic Cholesky factorization.
Examples
========
>>> from sympy.matrices import SparseMatrix
>>> S = SparseMatrix([
... [1, 0, 3, 2],
... [0, 0, 1, 0],
... [4, 0, 0, 5],
... [0, 6, 7, 0]])
>>> S.liupc()
([[0], [], [0], [1, 2]], [4, 3, 4, 4])
References
==========
Symbolic Sparse Cholesky Factorization using Elimination Trees,
Jeroen Van Grondelle (1999)
http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.39.7582
"""
# Algorithm 2.4, p 17 of reference
# get the indices of the elements that are non-zero on or below diag
R = [[] for r in range(M.rows)]
for r, c, _ in M.row_list():
if c <= r:
R[r].append(c)
inf = len(R) # nothing will be this large
parent = [inf]*M.rows
virtual = [inf]*M.rows
for r in range(M.rows):
for c in R[r][:-1]:
while virtual[c] < r:
t = virtual[c]
virtual[c] = r
c = t
if virtual[c] == inf:
parent[c] = virtual[c] = r
return R, parent
def _row_structure_symbolic_cholesky(M):
"""Symbolic cholesky factorization, for pre-determination of the
non-zero structure of the Cholesky factororization.
Examples
========
>>> from sympy.matrices import SparseMatrix
>>> S = SparseMatrix([
... [1, 0, 3, 2],
... [0, 0, 1, 0],
... [4, 0, 0, 5],
... [0, 6, 7, 0]])
>>> S.row_structure_symbolic_cholesky()
[[0], [], [0], [1, 2]]
References
==========
Symbolic Sparse Cholesky Factorization using Elimination Trees,
Jeroen Van Grondelle (1999)
http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.39.7582
"""
R, parent = M.liupc()
inf = len(R) # this acts as infinity
Lrow = copy.deepcopy(R)
for k in range(M.rows):
for j in R[k]:
while j != inf and j != k:
Lrow[k].append(j)
j = parent[j]
Lrow[k] = list(sorted(set(Lrow[k])))
return Lrow
def _cholesky(M, hermitian=True):
"""Returns the Cholesky-type decomposition L of a matrix A
such that L * L.H == A if hermitian flag is True,
or L * L.T == A if hermitian is False.
A must be a Hermitian positive-definite matrix if hermitian is True,
or a symmetric matrix if it is False.
Examples
========
>>> from sympy.matrices import Matrix
>>> A = Matrix(((25, 15, -5), (15, 18, 0), (-5, 0, 11)))
>>> A.cholesky()
Matrix([
[ 5, 0, 0],
[ 3, 3, 0],
[-1, 1, 3]])
>>> A.cholesky() * A.cholesky().T
Matrix([
[25, 15, -5],
[15, 18, 0],
[-5, 0, 11]])
The matrix can have complex entries:
>>> from sympy import I
>>> A = Matrix(((9, 3*I), (-3*I, 5)))
>>> A.cholesky()
Matrix([
[ 3, 0],
[-I, 2]])
>>> A.cholesky() * A.cholesky().H
Matrix([
[ 9, 3*I],
[-3*I, 5]])
Non-hermitian Cholesky-type decomposition may be useful when the
matrix is not positive-definite.
>>> A = Matrix([[1, 2], [2, 1]])
>>> L = A.cholesky(hermitian=False)
>>> L
Matrix([
[1, 0],
[2, sqrt(3)*I]])
>>> L*L.T == A
True
See Also
========
sympy.matrices.dense.DenseMatrix.LDLdecomposition
LUdecomposition
QRdecomposition
"""
from .dense import MutableDenseMatrix
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if hermitian and not M.is_hermitian:
raise ValueError("Matrix must be Hermitian.")
if not hermitian and not M.is_symmetric():
raise ValueError("Matrix must be symmetric.")
L = MutableDenseMatrix.zeros(M.rows, M.rows)
if hermitian:
for i in range(M.rows):
for j in range(i):
L[i, j] = ((1 / L[j, j])*(M[i, j] -
sum(L[i, k]*L[j, k].conjugate() for k in range(j))))
Lii2 = (M[i, i] -
sum(L[i, k]*L[i, k].conjugate() for k in range(i)))
if Lii2.is_positive is False:
raise NonPositiveDefiniteMatrixError(
"Matrix must be positive-definite")
L[i, i] = sqrt(Lii2)
else:
for i in range(M.rows):
for j in range(i):
L[i, j] = ((1 / L[j, j])*(M[i, j] -
sum(L[i, k]*L[j, k] for k in range(j))))
L[i, i] = sqrt(M[i, i] -
sum(L[i, k]**2 for k in range(i)))
return M._new(L)
def _cholesky_sparse(M, hermitian=True):
"""
Returns the Cholesky decomposition L of a matrix A
such that L * L.T = A
A must be a square, symmetric, positive-definite
and non-singular matrix
Examples
========
>>> from sympy.matrices import SparseMatrix
>>> A = SparseMatrix(((25,15,-5),(15,18,0),(-5,0,11)))
>>> A.cholesky()
Matrix([
[ 5, 0, 0],
[ 3, 3, 0],
[-1, 1, 3]])
>>> A.cholesky() * A.cholesky().T == A
True
The matrix can have complex entries:
>>> from sympy import I
>>> A = SparseMatrix(((9, 3*I), (-3*I, 5)))
>>> A.cholesky()
Matrix([
[ 3, 0],
[-I, 2]])
>>> A.cholesky() * A.cholesky().H
Matrix([
[ 9, 3*I],
[-3*I, 5]])
Non-hermitian Cholesky-type decomposition may be useful when the
matrix is not positive-definite.
>>> A = SparseMatrix([[1, 2], [2, 1]])
>>> L = A.cholesky(hermitian=False)
>>> L
Matrix([
[1, 0],
[2, sqrt(3)*I]])
>>> L*L.T == A
True
See Also
========
sympy.matrices.sparse.SparseMatrix.LDLdecomposition
LUdecomposition
QRdecomposition
"""
from .dense import MutableDenseMatrix
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if hermitian and not M.is_hermitian:
raise ValueError("Matrix must be Hermitian.")
if not hermitian and not M.is_symmetric():
raise ValueError("Matrix must be symmetric.")
dps = _get_intermediate_simp(expand_mul, expand_mul)
Crowstruc = M.row_structure_symbolic_cholesky()
C = MutableDenseMatrix.zeros(M.rows)
for i in range(len(Crowstruc)):
for j in Crowstruc[i]:
if i != j:
C[i, j] = M[i, j]
summ = 0
for p1 in Crowstruc[i]:
if p1 < j:
for p2 in Crowstruc[j]:
if p2 < j:
if p1 == p2:
if hermitian:
summ += C[i, p1]*C[j, p1].conjugate()
else:
summ += C[i, p1]*C[j, p1]
else:
break
else:
break
C[i, j] = dps((C[i, j] - summ) / C[j, j])
else: # i == j
C[j, j] = M[j, j]
summ = 0
for k in Crowstruc[j]:
if k < j:
if hermitian:
summ += C[j, k]*C[j, k].conjugate()
else:
summ += C[j, k]**2
else:
break
Cjj2 = dps(C[j, j] - summ)
if hermitian and Cjj2.is_positive is False:
raise NonPositiveDefiniteMatrixError(
"Matrix must be positive-definite")
C[j, j] = sqrt(Cjj2)
return M._new(C)
def _LDLdecomposition(M, hermitian=True):
"""Returns the LDL Decomposition (L, D) of matrix A,
such that L * D * L.H == A if hermitian flag is True, or
L * D * L.T == A if hermitian is False.
This method eliminates the use of square root.
Further this ensures that all the diagonal entries of L are 1.
A must be a Hermitian positive-definite matrix if hermitian is True,
or a symmetric matrix otherwise.
Examples
========
>>> from sympy.matrices import Matrix, eye
>>> A = Matrix(((25, 15, -5), (15, 18, 0), (-5, 0, 11)))
>>> L, D = A.LDLdecomposition()
>>> L
Matrix([
[ 1, 0, 0],
[ 3/5, 1, 0],
[-1/5, 1/3, 1]])
>>> D
Matrix([
[25, 0, 0],
[ 0, 9, 0],
[ 0, 0, 9]])
>>> L * D * L.T * A.inv() == eye(A.rows)
True
The matrix can have complex entries:
>>> from sympy import I
>>> A = Matrix(((9, 3*I), (-3*I, 5)))
>>> L, D = A.LDLdecomposition()
>>> L
Matrix([
[ 1, 0],
[-I/3, 1]])
>>> D
Matrix([
[9, 0],
[0, 4]])
>>> L*D*L.H == A
True
See Also
========
sympy.matrices.dense.DenseMatrix.cholesky
LUdecomposition
QRdecomposition
"""
from .dense import MutableDenseMatrix
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if hermitian and not M.is_hermitian:
raise ValueError("Matrix must be Hermitian.")
if not hermitian and not M.is_symmetric():
raise ValueError("Matrix must be symmetric.")
D = MutableDenseMatrix.zeros(M.rows, M.rows)
L = MutableDenseMatrix.eye(M.rows)
if hermitian:
for i in range(M.rows):
for j in range(i):
L[i, j] = (1 / D[j, j])*(M[i, j] - sum(
L[i, k]*L[j, k].conjugate()*D[k, k] for k in range(j)))
D[i, i] = (M[i, i] -
sum(L[i, k]*L[i, k].conjugate()*D[k, k] for k in range(i)))
if D[i, i].is_positive is False:
raise NonPositiveDefiniteMatrixError(
"Matrix must be positive-definite")
else:
for i in range(M.rows):
for j in range(i):
L[i, j] = (1 / D[j, j])*(M[i, j] - sum(
L[i, k]*L[j, k]*D[k, k] for k in range(j)))
D[i, i] = M[i, i] - sum(L[i, k]**2*D[k, k] for k in range(i))
return M._new(L), M._new(D)
def _LDLdecomposition_sparse(M, hermitian=True):
"""
Returns the LDL Decomposition (matrices ``L`` and ``D``) of matrix
``A``, such that ``L * D * L.T == A``. ``A`` must be a square,
symmetric, positive-definite and non-singular.
This method eliminates the use of square root and ensures that all
the diagonal entries of L are 1.
Examples
========
>>> from sympy.matrices import SparseMatrix
>>> A = SparseMatrix(((25, 15, -5), (15, 18, 0), (-5, 0, 11)))
>>> L, D = A.LDLdecomposition()
>>> L
Matrix([
[ 1, 0, 0],
[ 3/5, 1, 0],
[-1/5, 1/3, 1]])
>>> D
Matrix([
[25, 0, 0],
[ 0, 9, 0],
[ 0, 0, 9]])
>>> L * D * L.T == A
True
"""
from .dense import MutableDenseMatrix
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if hermitian and not M.is_hermitian:
raise ValueError("Matrix must be Hermitian.")
if not hermitian and not M.is_symmetric():
raise ValueError("Matrix must be symmetric.")
dps = _get_intermediate_simp(expand_mul, expand_mul)
Lrowstruc = M.row_structure_symbolic_cholesky()
L = MutableDenseMatrix.eye(M.rows)
D = MutableDenseMatrix.zeros(M.rows, M.cols)
for i in range(len(Lrowstruc)):
for j in Lrowstruc[i]:
if i != j:
L[i, j] = M[i, j]
summ = 0
for p1 in Lrowstruc[i]:
if p1 < j:
for p2 in Lrowstruc[j]:
if p2 < j:
if p1 == p2:
if hermitian:
summ += L[i, p1]*L[j, p1].conjugate()*D[p1, p1]
else:
summ += L[i, p1]*L[j, p1]*D[p1, p1]
else:
break
else:
break
L[i, j] = dps((L[i, j] - summ) / D[j, j])
else: # i == j
D[i, i] = M[i, i]
summ = 0
for k in Lrowstruc[i]:
if k < i:
if hermitian:
summ += L[i, k]*L[i, k].conjugate()*D[k, k]
else:
summ += L[i, k]**2*D[k, k]
else:
break
D[i, i] = dps(D[i, i] - summ)
if hermitian and D[i, i].is_positive is False:
raise NonPositiveDefiniteMatrixError(
"Matrix must be positive-definite")
return M._new(L), M._new(D)
def _LUdecomposition(M, iszerofunc=_iszero, simpfunc=None, rankcheck=False):
"""Returns (L, U, perm) where L is a lower triangular matrix with unit
diagonal, U is an upper triangular matrix, and perm is a list of row
swap index pairs. If A is the original matrix, then
A = (L*U).permuteBkwd(perm), and the row permutation matrix P such
that P*A = L*U can be computed by P=eye(A.row).permuteFwd(perm).
See documentation for LUCombined for details about the keyword argument
rankcheck, iszerofunc, and simpfunc.
Parameters
==========
rankcheck : bool, optional
Determines if this function should detect the rank
deficiency of the matrixis and should raise a
``ValueError``.
iszerofunc : function, optional
A function which determines if a given expression is zero.
The function should be a callable that takes a single
sympy expression and returns a 3-valued boolean value
``True``, ``False``, or ``None``.
It is internally used by the pivot searching algorithm.
See the notes section for a more information about the
pivot searching algorithm.
simpfunc : function or None, optional
A function that simplifies the input.
If this is specified as a function, this function should be
a callable that takes a single sympy expression and returns
an another sympy expression that is algebraically
equivalent.
If ``None``, it indicates that the pivot search algorithm
should not attempt to simplify any candidate pivots.
It is internally used by the pivot searching algorithm.
See the notes section for a more information about the
pivot searching algorithm.
Examples
========
>>> from sympy import Matrix
>>> a = Matrix([[4, 3], [6, 3]])
>>> L, U, _ = a.LUdecomposition()
>>> L
Matrix([
[ 1, 0],
[3/2, 1]])
>>> U
Matrix([
[4, 3],
[0, -3/2]])
See Also
========
sympy.matrices.dense.DenseMatrix.cholesky
sympy.matrices.dense.DenseMatrix.LDLdecomposition
QRdecomposition
LUdecomposition_Simple
LUdecompositionFF
LUsolve
"""
combined, p = M.LUdecomposition_Simple(iszerofunc=iszerofunc,
simpfunc=simpfunc, rankcheck=rankcheck)
# L is lower triangular ``M.rows x M.rows``
# U is upper triangular ``M.rows x M.cols``
# L has unit diagonal. For each column in combined, the subcolumn
# below the diagonal of combined is shared by L.
# If L has more columns than combined, then the remaining subcolumns
# below the diagonal of L are zero.
# The upper triangular portion of L and combined are equal.
def entry_L(i, j):
if i < j:
# Super diagonal entry
return M.zero
elif i == j:
return M.one
elif j < combined.cols:
return combined[i, j]
# Subdiagonal entry of L with no corresponding
# entry in combined
return M.zero
def entry_U(i, j):
return M.zero if i > j else combined[i, j]
L = M._new(combined.rows, combined.rows, entry_L)
U = M._new(combined.rows, combined.cols, entry_U)
return L, U, p
def _LUdecomposition_Simple(M, iszerofunc=_iszero, simpfunc=None,
rankcheck=False):
r"""Compute the PLU decomposition of the matrix.
Parameters
==========
rankcheck : bool, optional
Determines if this function should detect the rank
deficiency of the matrixis and should raise a
``ValueError``.
iszerofunc : function, optional
A function which determines if a given expression is zero.
The function should be a callable that takes a single
sympy expression and returns a 3-valued boolean value
``True``, ``False``, or ``None``.
It is internally used by the pivot searching algorithm.
See the notes section for a more information about the
pivot searching algorithm.
simpfunc : function or None, optional
A function that simplifies the input.
If this is specified as a function, this function should be
a callable that takes a single sympy expression and returns
an another sympy expression that is algebraically
equivalent.
If ``None``, it indicates that the pivot search algorithm
should not attempt to simplify any candidate pivots.
It is internally used by the pivot searching algorithm.
See the notes section for a more information about the
pivot searching algorithm.
Returns
=======
(lu, row_swaps) : (Matrix, list)
If the original matrix is a $m, n$ matrix:
*lu* is a $m, n$ matrix, which contains result of the
decomposition in a compresed form. See the notes section
to see how the matrix is compressed.
*row_swaps* is a $m$-element list where each element is a
pair of row exchange indices.
``A = (L*U).permute_backward(perm)``, and the row
permutation matrix $P$ from the formula $P A = L U$ can be
computed by ``P=eye(A.row).permute_forward(perm)``.
Raises
======
ValueError
Raised if ``rankcheck=True`` and the matrix is found to
be rank deficient during the computation.
Notes
=====
About the PLU decomposition:
PLU decomposition is a generalization of a LU decomposition
which can be extended for rank-deficient matrices.
It can further be generalized for non-square matrices, and this
is the notation that SymPy is using.
PLU decomposition is a decomposition of a $m, n$ matrix $A$ in
the form of $P A = L U$ where
* $L$ is a $m, m$ lower triangular matrix with unit diagonal
entries.
* $U$ is a $m, n$ upper triangular matrix.
* $P$ is a $m, m$ permutation matrix.
So, for a square matrix, the decomposition would look like:
.. math::
L = \begin{bmatrix}
1 & 0 & 0 & \cdots & 0 \\
L_{1, 0} & 1 & 0 & \cdots & 0 \\
L_{2, 0} & L_{2, 1} & 1 & \cdots & 0 \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots & 1
\end{bmatrix}
.. math::
U = \begin{bmatrix}
U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
0 & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
0 & 0 & U_{2, 2} & \cdots & U_{2, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
0 & 0 & 0 & \cdots & U_{n-1, n-1}
\end{bmatrix}
And for a matrix with more rows than the columns,
the decomposition would look like:
.. math::
L = \begin{bmatrix}
1 & 0 & 0 & \cdots & 0 & 0 & \cdots & 0 \\
L_{1, 0} & 1 & 0 & \cdots & 0 & 0 & \cdots & 0 \\
L_{2, 0} & L_{2, 1} & 1 & \cdots & 0 & 0 & \cdots & 0 \\
\vdots & \vdots & \vdots & \ddots & \vdots & \vdots & \ddots
& \vdots \\
L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots & 1 & 0
& \cdots & 0 \\
L_{n, 0} & L_{n, 1} & L_{n, 2} & \cdots & L_{n, n-1} & 1
& \cdots & 0 \\
\vdots & \vdots & \vdots & \ddots & \vdots & \vdots
& \ddots & \vdots \\
L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots & L_{m-1, n-1}
& 0 & \cdots & 1 \\
\end{bmatrix}
.. math::
U = \begin{bmatrix}
U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
0 & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
0 & 0 & U_{2, 2} & \cdots & U_{2, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
0 & 0 & 0 & \cdots & U_{n-1, n-1} \\
0 & 0 & 0 & \cdots & 0 \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
0 & 0 & 0 & \cdots & 0
\end{bmatrix}
Finally, for a matrix with more columns than the rows, the
decomposition would look like:
.. math::
L = \begin{bmatrix}
1 & 0 & 0 & \cdots & 0 \\
L_{1, 0} & 1 & 0 & \cdots & 0 \\
L_{2, 0} & L_{2, 1} & 1 & \cdots & 0 \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots & 1
\end{bmatrix}
.. math::
U = \begin{bmatrix}
U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, m-1}
& \cdots & U_{0, n-1} \\
0 & U_{1, 1} & U_{1, 2} & \cdots & U_{1, m-1}
& \cdots & U_{1, n-1} \\
0 & 0 & U_{2, 2} & \cdots & U_{2, m-1}
& \cdots & U_{2, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots
& \cdots & \vdots \\
0 & 0 & 0 & \cdots & U_{m-1, m-1}
& \cdots & U_{m-1, n-1} \\
\end{bmatrix}
About the compressed LU storage:
The results of the decomposition are often stored in compressed
forms rather than returning $L$ and $U$ matrices individually.
It may be less intiuitive, but it is commonly used for a lot of
numeric libraries because of the efficiency.
The storage matrix is defined as following for this specific
method:
* The subdiagonal elements of $L$ are stored in the subdiagonal
portion of $LU$, that is $LU_{i, j} = L_{i, j}$ whenever
$i > j$.
* The elements on the diagonal of $L$ are all 1, and are not
explicitly stored.
* $U$ is stored in the upper triangular portion of $LU$, that is
$LU_{i, j} = U_{i, j}$ whenever $i <= j$.
* For a case of $m > n$, the right side of the $L$ matrix is
trivial to store.
* For a case of $m < n$, the below side of the $U$ matrix is
trivial to store.
So, for a square matrix, the compressed output matrix would be:
.. math::
LU = \begin{bmatrix}
U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
L_{1, 0} & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
L_{2, 0} & L_{2, 1} & U_{2, 2} & \cdots & U_{2, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots & U_{n-1, n-1}
\end{bmatrix}
For a matrix with more rows than the columns, the compressed
output matrix would be:
.. math::
LU = \begin{bmatrix}
U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, n-1} \\
L_{1, 0} & U_{1, 1} & U_{1, 2} & \cdots & U_{1, n-1} \\
L_{2, 0} & L_{2, 1} & U_{2, 2} & \cdots & U_{2, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
L_{n-1, 0} & L_{n-1, 1} & L_{n-1, 2} & \cdots
& U_{n-1, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots \\
L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots
& L_{m-1, n-1} \\
\end{bmatrix}
For a matrix with more columns than the rows, the compressed
output matrix would be:
.. math::
LU = \begin{bmatrix}
U_{0, 0} & U_{0, 1} & U_{0, 2} & \cdots & U_{0, m-1}
& \cdots & U_{0, n-1} \\
L_{1, 0} & U_{1, 1} & U_{1, 2} & \cdots & U_{1, m-1}
& \cdots & U_{1, n-1} \\
L_{2, 0} & L_{2, 1} & U_{2, 2} & \cdots & U_{2, m-1}
& \cdots & U_{2, n-1} \\
\vdots & \vdots & \vdots & \ddots & \vdots
& \cdots & \vdots \\
L_{m-1, 0} & L_{m-1, 1} & L_{m-1, 2} & \cdots & U_{m-1, m-1}
& \cdots & U_{m-1, n-1} \\
\end{bmatrix}
About the pivot searching algorithm:
When a matrix contains symbolic entries, the pivot search algorithm
differs from the case where every entry can be categorized as zero or
nonzero.
The algorithm searches column by column through the submatrix whose
top left entry coincides with the pivot position.
If it exists, the pivot is the first entry in the current search
column that iszerofunc guarantees is nonzero.
If no such candidate exists, then each candidate pivot is simplified
if simpfunc is not None.
The search is repeated, with the difference that a candidate may be
the pivot if ``iszerofunc()`` cannot guarantee that it is nonzero.
In the second search the pivot is the first candidate that
iszerofunc can guarantee is nonzero.
If no such candidate exists, then the pivot is the first candidate
for which iszerofunc returns None.
If no such candidate exists, then the search is repeated in the next
column to the right.
The pivot search algorithm differs from the one in ``rref()``, which
relies on ``_find_reasonable_pivot()``.
Future versions of ``LUdecomposition_simple()`` may use
``_find_reasonable_pivot()``.
See Also
========
LUdecomposition
LUdecompositionFF
LUsolve
"""
if rankcheck:
# https://github.com/sympy/sympy/issues/9796
pass
if M.rows == 0 or M.cols == 0:
# Define LU decomposition of a matrix with no entries as a matrix
# of the same dimensions with all zero entries.
return M.zeros(M.rows, M.cols), []
dps = _get_intermediate_simp()
lu = M.as_mutable()
row_swaps = []
pivot_col = 0
for pivot_row in range(0, lu.rows - 1):
# Search for pivot. Prefer entry that iszeropivot determines
# is nonzero, over entry that iszeropivot cannot guarantee
# is zero.
# XXX ``_find_reasonable_pivot`` uses slow zero testing. Blocked by bug #10279
# Future versions of LUdecomposition_simple can pass iszerofunc and simpfunc
# to _find_reasonable_pivot().
# In pass 3 of _find_reasonable_pivot(), the predicate in ``if x.equals(S.Zero):``
# calls sympy.simplify(), and not the simplification function passed in via
# the keyword argument simpfunc.
iszeropivot = True
while pivot_col != M.cols and iszeropivot:
sub_col = (lu[r, pivot_col] for r in range(pivot_row, M.rows))
pivot_row_offset, pivot_value, is_assumed_non_zero, ind_simplified_pairs =\
_find_reasonable_pivot_naive(sub_col, iszerofunc, simpfunc)
iszeropivot = pivot_value is None
if iszeropivot:
# All candidate pivots in this column are zero.
# Proceed to next column.
pivot_col += 1
if rankcheck and pivot_col != pivot_row:
# All entries including and below the pivot position are
# zero, which indicates that the rank of the matrix is
# strictly less than min(num rows, num cols)
# Mimic behavior of previous implementation, by throwing a
# ValueError.
raise ValueError("Rank of matrix is strictly less than"
" number of rows or columns."
" Pass keyword argument"
" rankcheck=False to compute"
" the LU decomposition of this matrix.")
candidate_pivot_row = None if pivot_row_offset is None else pivot_row + pivot_row_offset
if candidate_pivot_row is None and iszeropivot:
# If candidate_pivot_row is None and iszeropivot is True
# after pivot search has completed, then the submatrix
# below and to the right of (pivot_row, pivot_col) is
# all zeros, indicating that Gaussian elimination is
# complete.
return lu, row_swaps
# Update entries simplified during pivot search.
for offset, val in ind_simplified_pairs:
lu[pivot_row + offset, pivot_col] = val
if pivot_row != candidate_pivot_row:
# Row swap book keeping:
# Record which rows were swapped.
# Update stored portion of L factor by multiplying L on the
# left and right with the current permutation.
# Swap rows of U.
row_swaps.append([pivot_row, candidate_pivot_row])
# Update L.
lu[pivot_row, 0:pivot_row], lu[candidate_pivot_row, 0:pivot_row] = \
lu[candidate_pivot_row, 0:pivot_row], lu[pivot_row, 0:pivot_row]
# Swap pivot row of U with candidate pivot row.
lu[pivot_row, pivot_col:lu.cols], lu[candidate_pivot_row, pivot_col:lu.cols] = \
lu[candidate_pivot_row, pivot_col:lu.cols], lu[pivot_row, pivot_col:lu.cols]
# Introduce zeros below the pivot by adding a multiple of the
# pivot row to a row under it, and store the result in the
# row under it.
# Only entries in the target row whose index is greater than
# start_col may be nonzero.
start_col = pivot_col + 1
for row in range(pivot_row + 1, lu.rows):
# Store factors of L in the subcolumn below
# (pivot_row, pivot_row).
lu[row, pivot_row] = \
dps(lu[row, pivot_col]/lu[pivot_row, pivot_col])
# Form the linear combination of the pivot row and the current
# row below the pivot row that zeros the entries below the pivot.
# Employing slicing instead of a loop here raises
# NotImplementedError: Cannot add Zero to MutableSparseMatrix
# in sympy/matrices/tests/test_sparse.py.
# c = pivot_row + 1 if pivot_row == pivot_col else pivot_col
for c in range(start_col, lu.cols):
lu[row, c] = dps(lu[row, c] - lu[row, pivot_row]*lu[pivot_row, c])
if pivot_row != pivot_col:
# matrix rank < min(num rows, num cols),
# so factors of L are not stored directly below the pivot.
# These entries are zero by construction, so don't bother
# computing them.
for row in range(pivot_row + 1, lu.rows):
lu[row, pivot_col] = M.zero
pivot_col += 1
if pivot_col == lu.cols:
# All candidate pivots are zero implies that Gaussian
# elimination is complete.
return lu, row_swaps
if rankcheck:
if iszerofunc(
lu[Min(lu.rows, lu.cols) - 1, Min(lu.rows, lu.cols) - 1]):
raise ValueError("Rank of matrix is strictly less than"
" number of rows or columns."
" Pass keyword argument"
" rankcheck=False to compute"
" the LU decomposition of this matrix.")
return lu, row_swaps
def _LUdecompositionFF(M):
"""Compute a fraction-free LU decomposition.
Returns 4 matrices P, L, D, U such that PA = L D**-1 U.
If the elements of the matrix belong to some integral domain I, then all
elements of L, D and U are guaranteed to belong to I.
See Also
========
LUdecomposition
LUdecomposition_Simple
LUsolve
References
==========
.. [1] W. Zhou & D.J. Jeffrey, "Fraction-free matrix factors: new forms
for LU and QR factors". Frontiers in Computer Science in China,
Vol 2, no. 1, pp. 67-80, 2008.
"""
from sympy.matrices import SparseMatrix
zeros = SparseMatrix.zeros
eye = SparseMatrix.eye
n, m = M.rows, M.cols
U, L, P = M.as_mutable(), eye(n), eye(n)
DD = zeros(n, n)
oldpivot = 1
for k in range(n - 1):
if U[k, k] == 0:
for kpivot in range(k + 1, n):
if U[kpivot, k]:
break
else:
raise ValueError("Matrix is not full rank")
U[k, k:], U[kpivot, k:] = U[kpivot, k:], U[k, k:]
L[k, :k], L[kpivot, :k] = L[kpivot, :k], L[k, :k]
P[k, :], P[kpivot, :] = P[kpivot, :], P[k, :]
L [k, k] = Ukk = U[k, k]
DD[k, k] = oldpivot * Ukk
for i in range(k + 1, n):
L[i, k] = Uik = U[i, k]
for j in range(k + 1, m):
U[i, j] = (Ukk * U[i, j] - U[k, j] * Uik) / oldpivot
U[i, k] = 0
oldpivot = Ukk
DD[n - 1, n - 1] = oldpivot
return P, L, DD, U
def _QRdecomposition(M):
r"""Returns a QR decomposition.
Explanation
===========
A QR decomposition is a decomposition in the form $A = Q R$
where
- $Q$ is a column orthogonal matrix.
- $R$ is a upper triangular (trapezoidal) matrix.
A column orthogonal matrix satisfies
$\mathbb{I} = Q^H Q$ while a full orthogonal matrix satisfies
relation $\mathbb{I} = Q Q^H = Q^H Q$ where $I$ is an identity
matrix with matching dimensions.
For matrices which are not square or are rank-deficient, it is
sufficient to return a column orthogonal matrix because augmenting
them may introduce redundant computations.
And an another advantage of this is that you can easily inspect the
matrix rank by counting the number of columns of $Q$.
If you want to augment the results to return a full orthogonal
decomposition, you should use the following procedures.
- Augment the $Q$ matrix with columns that are orthogonal to every
other columns and make it square.
- Augument the $R$ matrix with zero rows to make it have the same
shape as the original matrix.
The procedure will be illustrated in the examples section.
Examples
========
A full rank matrix example:
>>> from sympy import Matrix
>>> A = Matrix([[12, -51, 4], [6, 167, -68], [-4, 24, -41]])
>>> Q, R = A.QRdecomposition()
>>> Q
Matrix([
[ 6/7, -69/175, -58/175],
[ 3/7, 158/175, 6/175],
[-2/7, 6/35, -33/35]])
>>> R
Matrix([
[14, 21, -14],
[ 0, 175, -70],
[ 0, 0, 35]])
If the matrix is square and full rank, the $Q$ matrix becomes
orthogonal in both directions, and needs no augmentation.
>>> Q * Q.H
Matrix([
[1, 0, 0],
[0, 1, 0],
[0, 0, 1]])
>>> Q.H * Q
Matrix([
[1, 0, 0],
[0, 1, 0],
[0, 0, 1]])
>>> A == Q*R
True
A rank deficient matrix example:
>>> A = Matrix([[12, -51, 0], [6, 167, 0], [-4, 24, 0]])
>>> Q, R = A.QRdecomposition()
>>> Q
Matrix([
[ 6/7, -69/175],
[ 3/7, 158/175],
[-2/7, 6/35]])
>>> R
Matrix([
[14, 21, 0],
[ 0, 175, 0]])
QRdecomposition might return a matrix Q that is rectangular.
In this case the orthogonality condition might be satisfied as
$\mathbb{I} = Q.H*Q$ but not in the reversed product
$\mathbb{I} = Q * Q.H$.
>>> Q.H * Q
Matrix([
[1, 0],
[0, 1]])
>>> Q * Q.H
Matrix([
[27261/30625, 348/30625, -1914/6125],
[ 348/30625, 30589/30625, 198/6125],
[ -1914/6125, 198/6125, 136/1225]])
If you want to augment the results to be a full orthogonal
decomposition, you should augment $Q$ with an another orthogonal
column.
You are able to append an arbitrary standard basis that are linearly
independent to every other columns and you can run the Gram-Schmidt
process to make them augmented as orthogonal basis.
>>> Q_aug = Q.row_join(Matrix([0, 0, 1]))
>>> Q_aug = Q_aug.QRdecomposition()[0]
>>> Q_aug
Matrix([
[ 6/7, -69/175, 58/175],
[ 3/7, 158/175, -6/175],
[-2/7, 6/35, 33/35]])
>>> Q_aug.H * Q_aug
Matrix([
[1, 0, 0],
[0, 1, 0],
[0, 0, 1]])
>>> Q_aug * Q_aug.H
Matrix([
[1, 0, 0],
[0, 1, 0],
[0, 0, 1]])
Augmenting the $R$ matrix with zero row is straightforward.
>>> R_aug = R.col_join(Matrix([[0, 0, 0]]))
>>> R_aug
Matrix([
[14, 21, 0],
[ 0, 175, 0],
[ 0, 0, 0]])
>>> Q_aug * R_aug == A
True
A zero matrix example:
>>> from sympy import Matrix
>>> A = Matrix.zeros(3, 4)
>>> Q, R = A.QRdecomposition()
They may return matrices with zero rows and columns.
>>> Q
Matrix(3, 0, [])
>>> R
Matrix(0, 4, [])
>>> Q*R
Matrix([
[0, 0, 0, 0],
[0, 0, 0, 0],
[0, 0, 0, 0]])
As the same augmentation rule described above, $Q$ can be augmented
with columns of an identity matrix and $R$ can be augmented with
rows of a zero matrix.
>>> Q_aug = Q.row_join(Matrix.eye(3))
>>> R_aug = R.col_join(Matrix.zeros(3, 4))
>>> Q_aug * Q_aug.T
Matrix([
[1, 0, 0],
[0, 1, 0],
[0, 0, 1]])
>>> R_aug
Matrix([
[0, 0, 0, 0],
[0, 0, 0, 0],
[0, 0, 0, 0]])
>>> Q_aug * R_aug == A
True
See Also
========
sympy.matrices.dense.DenseMatrix.cholesky
sympy.matrices.dense.DenseMatrix.LDLdecomposition
LUdecomposition
QRsolve
"""
dps = _get_intermediate_simp(expand_mul, expand_mul)
mat = M.as_mutable()
n = mat.rows
m = mat.cols
ranked = list()
# Pad with additional rows to make wide matrices square
# nOrig keeps track of original size so zeros can be trimmed from Q
if n < m:
nOrig = n
n = m
mat = mat.col_join(mat.zeros(n - nOrig, m))
else:
nOrig = n
Q, R = mat.zeros(n, m), mat.zeros(m)
for j in range(m): # for each column vector
tmp = mat[:, j] # take original v
for i in range(j):
# subtract the project of mat on new vector
R[i, j] = dps(Q[:, i].dot(mat[:, j], hermitian=True))
tmp -= Q[:, i] * R[i, j]
tmp = dps(tmp)
# normalize it
R[j, j] = tmp.norm()
if not R[j, j].is_zero:
ranked.append(j)
Q[:, j] = tmp / R[j, j]
Q = Q.extract(range(nOrig), ranked)
R = R.extract(ranked, range(R.cols))
return M.__class__(Q), M.__class__(R)
|
1e9afc64769769b6352724bc9d77d5c8f1a640434840f9ee6c34d4ad0054e7c8 | from types import FunctionType
from sympy.core.numbers import Float, Integer
from sympy.core.singleton import S
from sympy.core.symbol import uniquely_named_symbol
from sympy.polys import PurePoly, cancel
from sympy.simplify.simplify import (simplify as _simplify,
dotprodsimp as _dotprodsimp)
from .common import MatrixError, NonSquareMatrixError
from .utilities import (
_get_intermediate_simp, _get_intermediate_simp_bool,
_iszero, _is_zero_after_expand_mul)
def _find_reasonable_pivot(col, iszerofunc=_iszero, simpfunc=_simplify):
""" Find the lowest index of an item in ``col`` that is
suitable for a pivot. If ``col`` consists only of
Floats, the pivot with the largest norm is returned.
Otherwise, the first element where ``iszerofunc`` returns
False is used. If ``iszerofunc`` doesn't return false,
items are simplified and retested until a suitable
pivot is found.
Returns a 4-tuple
(pivot_offset, pivot_val, assumed_nonzero, newly_determined)
where pivot_offset is the index of the pivot, pivot_val is
the (possibly simplified) value of the pivot, assumed_nonzero
is True if an assumption that the pivot was non-zero
was made without being proved, and newly_determined are
elements that were simplified during the process of pivot
finding."""
newly_determined = []
col = list(col)
# a column that contains a mix of floats and integers
# but at least one float is considered a numerical
# column, and so we do partial pivoting
if all(isinstance(x, (Float, Integer)) for x in col) and any(
isinstance(x, Float) for x in col):
col_abs = [abs(x) for x in col]
max_value = max(col_abs)
if iszerofunc(max_value):
# just because iszerofunc returned True, doesn't
# mean the value is numerically zero. Make sure
# to replace all entries with numerical zeros
if max_value != 0:
newly_determined = [(i, 0) for i, x in enumerate(col) if x != 0]
return (None, None, False, newly_determined)
index = col_abs.index(max_value)
return (index, col[index], False, newly_determined)
# PASS 1 (iszerofunc directly)
possible_zeros = []
for i, x in enumerate(col):
is_zero = iszerofunc(x)
# is someone wrote a custom iszerofunc, it may return
# BooleanFalse or BooleanTrue instead of True or False,
# so use == for comparison instead of `is`
if is_zero == False:
# we found something that is definitely not zero
return (i, x, False, newly_determined)
possible_zeros.append(is_zero)
# by this point, we've found no certain non-zeros
if all(possible_zeros):
# if everything is definitely zero, we have
# no pivot
return (None, None, False, newly_determined)
# PASS 2 (iszerofunc after simplify)
# we haven't found any for-sure non-zeros, so
# go through the elements iszerofunc couldn't
# make a determination about and opportunistically
# simplify to see if we find something
for i, x in enumerate(col):
if possible_zeros[i] is not None:
continue
simped = simpfunc(x)
is_zero = iszerofunc(simped)
if is_zero == True or is_zero == False:
newly_determined.append((i, simped))
if is_zero == False:
return (i, simped, False, newly_determined)
possible_zeros[i] = is_zero
# after simplifying, some things that were recognized
# as zeros might be zeros
if all(possible_zeros):
# if everything is definitely zero, we have
# no pivot
return (None, None, False, newly_determined)
# PASS 3 (.equals(0))
# some expressions fail to simplify to zero, but
# ``.equals(0)`` evaluates to True. As a last-ditch
# attempt, apply ``.equals`` to these expressions
for i, x in enumerate(col):
if possible_zeros[i] is not None:
continue
if x.equals(S.Zero):
# ``.iszero`` may return False with
# an implicit assumption (e.g., ``x.equals(0)``
# when ``x`` is a symbol), so only treat it
# as proved when ``.equals(0)`` returns True
possible_zeros[i] = True
newly_determined.append((i, S.Zero))
if all(possible_zeros):
return (None, None, False, newly_determined)
# at this point there is nothing that could definitely
# be a pivot. To maintain compatibility with existing
# behavior, we'll assume that an illdetermined thing is
# non-zero. We should probably raise a warning in this case
i = possible_zeros.index(None)
return (i, col[i], True, newly_determined)
def _find_reasonable_pivot_naive(col, iszerofunc=_iszero, simpfunc=None):
"""
Helper that computes the pivot value and location from a
sequence of contiguous matrix column elements. As a side effect
of the pivot search, this function may simplify some of the elements
of the input column. A list of these simplified entries and their
indices are also returned.
This function mimics the behavior of _find_reasonable_pivot(),
but does less work trying to determine if an indeterminate candidate
pivot simplifies to zero. This more naive approach can be much faster,
with the trade-off that it may erroneously return a pivot that is zero.
``col`` is a sequence of contiguous column entries to be searched for
a suitable pivot.
``iszerofunc`` is a callable that returns a Boolean that indicates
if its input is zero, or None if no such determination can be made.
``simpfunc`` is a callable that simplifies its input. It must return
its input if it does not simplify its input. Passing in
``simpfunc=None`` indicates that the pivot search should not attempt
to simplify any candidate pivots.
Returns a 4-tuple:
(pivot_offset, pivot_val, assumed_nonzero, newly_determined)
``pivot_offset`` is the sequence index of the pivot.
``pivot_val`` is the value of the pivot.
pivot_val and col[pivot_index] are equivalent, but will be different
when col[pivot_index] was simplified during the pivot search.
``assumed_nonzero`` is a boolean indicating if the pivot cannot be
guaranteed to be zero. If assumed_nonzero is true, then the pivot
may or may not be non-zero. If assumed_nonzero is false, then
the pivot is non-zero.
``newly_determined`` is a list of index-value pairs of pivot candidates
that were simplified during the pivot search.
"""
# indeterminates holds the index-value pairs of each pivot candidate
# that is neither zero or non-zero, as determined by iszerofunc().
# If iszerofunc() indicates that a candidate pivot is guaranteed
# non-zero, or that every candidate pivot is zero then the contents
# of indeterminates are unused.
# Otherwise, the only viable candidate pivots are symbolic.
# In this case, indeterminates will have at least one entry,
# and all but the first entry are ignored when simpfunc is None.
indeterminates = []
for i, col_val in enumerate(col):
col_val_is_zero = iszerofunc(col_val)
if col_val_is_zero == False:
# This pivot candidate is non-zero.
return i, col_val, False, []
elif col_val_is_zero is None:
# The candidate pivot's comparison with zero
# is indeterminate.
indeterminates.append((i, col_val))
if len(indeterminates) == 0:
# All candidate pivots are guaranteed to be zero, i.e. there is
# no pivot.
return None, None, False, []
if simpfunc is None:
# Caller did not pass in a simplification function that might
# determine if an indeterminate pivot candidate is guaranteed
# to be nonzero, so assume the first indeterminate candidate
# is non-zero.
return indeterminates[0][0], indeterminates[0][1], True, []
# newly_determined holds index-value pairs of candidate pivots
# that were simplified during the search for a non-zero pivot.
newly_determined = []
for i, col_val in indeterminates:
tmp_col_val = simpfunc(col_val)
if id(col_val) != id(tmp_col_val):
# simpfunc() simplified this candidate pivot.
newly_determined.append((i, tmp_col_val))
if iszerofunc(tmp_col_val) == False:
# Candidate pivot simplified to a guaranteed non-zero value.
return i, tmp_col_val, False, newly_determined
return indeterminates[0][0], indeterminates[0][1], True, newly_determined
# This functions is a candidate for caching if it gets implemented for matrices.
def _berkowitz_toeplitz_matrix(M):
"""Return (A,T) where T the Toeplitz matrix used in the Berkowitz algorithm
corresponding to ``M`` and A is the first principal submatrix.
"""
# the 0 x 0 case is trivial
if M.rows == 0 and M.cols == 0:
return M._new(1,1, [M.one])
#
# Partition M = [ a_11 R ]
# [ C A ]
#
a, R = M[0,0], M[0, 1:]
C, A = M[1:, 0], M[1:,1:]
#
# The Toeplitz matrix looks like
#
# [ 1 ]
# [ -a 1 ]
# [ -RC -a 1 ]
# [ -RAC -RC -a 1 ]
# [ -RA**2C -RAC -RC -a 1 ]
# etc.
# Compute the diagonal entries.
# Because multiplying matrix times vector is so much
# more efficient than matrix times matrix, recursively
# compute -R * A**n * C.
diags = [C]
for i in range(M.rows - 2):
diags.append(A.multiply(diags[i], dotprodsimp=True))
diags = [(-R).multiply(d, dotprodsimp=True)[0, 0] for d in diags]
diags = [M.one, -a] + diags
def entry(i,j):
if j > i:
return M.zero
return diags[i - j]
toeplitz = M._new(M.cols + 1, M.rows, entry)
return (A, toeplitz)
# This functions is a candidate for caching if it gets implemented for matrices.
def _berkowitz_vector(M):
""" Run the Berkowitz algorithm and return a vector whose entries
are the coefficients of the characteristic polynomial of ``M``.
Given N x N matrix, efficiently compute
coefficients of characteristic polynomials of ``M``
without division in the ground domain.
This method is particularly useful for computing determinant,
principal minors and characteristic polynomial when ``M``
has complicated coefficients e.g. polynomials. Semi-direct
usage of this algorithm is also important in computing
efficiently sub-resultant PRS.
Assuming that M is a square matrix of dimension N x N and
I is N x N identity matrix, then the Berkowitz vector is
an N x 1 vector whose entries are coefficients of the
polynomial
charpoly(M) = det(t*I - M)
As a consequence, all polynomials generated by Berkowitz
algorithm are monic.
For more information on the implemented algorithm refer to:
[1] S.J. Berkowitz, On computing the determinant in small
parallel time using a small number of processors, ACM,
Information Processing Letters 18, 1984, pp. 147-150
[2] M. Keber, Division-Free computation of sub-resultants
using Bezout matrices, Tech. Report MPI-I-2006-1-006,
Saarbrucken, 2006
"""
# handle the trivial cases
if M.rows == 0 and M.cols == 0:
return M._new(1, 1, [M.one])
elif M.rows == 1 and M.cols == 1:
return M._new(2, 1, [M.one, -M[0,0]])
submat, toeplitz = _berkowitz_toeplitz_matrix(M)
return toeplitz.multiply(_berkowitz_vector(submat), dotprodsimp=True)
def _adjugate(M, method="berkowitz"):
"""Returns the adjugate, or classical adjoint, of
a matrix. That is, the transpose of the matrix of cofactors.
https://en.wikipedia.org/wiki/Adjugate
Parameters
==========
method : string, optional
Method to use to find the cofactors, can be "bareiss", "berkowitz" or
"lu".
Examples
========
>>> from sympy import Matrix
>>> M = Matrix([[1, 2], [3, 4]])
>>> M.adjugate()
Matrix([
[ 4, -2],
[-3, 1]])
See Also
========
cofactor_matrix
sympy.matrices.common.MatrixCommon.transpose
"""
return M.cofactor_matrix(method=method).transpose()
# This functions is a candidate for caching if it gets implemented for matrices.
def _charpoly(M, x='lambda', simplify=_simplify):
"""Computes characteristic polynomial det(x*I - M) where I is
the identity matrix.
A PurePoly is returned, so using different variables for ``x`` does
not affect the comparison or the polynomials:
Parameters
==========
x : string, optional
Name for the "lambda" variable, defaults to "lambda".
simplify : function, optional
Simplification function to use on the characteristic polynomial
calculated. Defaults to ``simplify``.
Examples
========
>>> from sympy import Matrix
>>> from sympy.abc import x, y
>>> M = Matrix([[1, 3], [2, 0]])
>>> M.charpoly()
PurePoly(lambda**2 - lambda - 6, lambda, domain='ZZ')
>>> M.charpoly(x) == M.charpoly(y)
True
>>> M.charpoly(x) == M.charpoly(y)
True
Specifying ``x`` is optional; a symbol named ``lambda`` is used by
default (which looks good when pretty-printed in unicode):
>>> M.charpoly().as_expr()
lambda**2 - lambda - 6
And if ``x`` clashes with an existing symbol, underscores will
be prepended to the name to make it unique:
>>> M = Matrix([[1, 2], [x, 0]])
>>> M.charpoly(x).as_expr()
_x**2 - _x - 2*x
Whether you pass a symbol or not, the generator can be obtained
with the gen attribute since it may not be the same as the symbol
that was passed:
>>> M.charpoly(x).gen
_x
>>> M.charpoly(x).gen == x
False
Notes
=====
The Samuelson-Berkowitz algorithm is used to compute
the characteristic polynomial efficiently and without any
division operations. Thus the characteristic polynomial over any
commutative ring without zero divisors can be computed.
If the determinant det(x*I - M) can be found out easily as
in the case of an upper or a lower triangular matrix, then
instead of Samuelson-Berkowitz algorithm, eigenvalues are computed
and the characteristic polynomial with their help.
See Also
========
det
"""
if not M.is_square:
raise NonSquareMatrixError()
if M.is_lower or M.is_upper:
diagonal_elements = M.diagonal()
x = uniquely_named_symbol(x, diagonal_elements, modify=lambda s: '_' + s)
m = 1
for i in diagonal_elements:
m = m * (x - simplify(i))
return PurePoly(m, x)
berk_vector = _berkowitz_vector(M)
x = uniquely_named_symbol(x, berk_vector, modify=lambda s: '_' + s)
return PurePoly([simplify(a) for a in berk_vector], x)
def _cofactor(M, i, j, method="berkowitz"):
"""Calculate the cofactor of an element.
Parameters
==========
method : string, optional
Method to use to find the cofactors, can be "bareiss", "berkowitz" or
"lu".
Examples
========
>>> from sympy import Matrix
>>> M = Matrix([[1, 2], [3, 4]])
>>> M.cofactor(0, 1)
-3
See Also
========
cofactor_matrix
minor
minor_submatrix
"""
if not M.is_square or M.rows < 1:
raise NonSquareMatrixError()
return (-1)**((i + j) % 2) * M.minor(i, j, method)
def _cofactor_matrix(M, method="berkowitz"):
"""Return a matrix containing the cofactor of each element.
Parameters
==========
method : string, optional
Method to use to find the cofactors, can be "bareiss", "berkowitz" or
"lu".
Examples
========
>>> from sympy import Matrix
>>> M = Matrix([[1, 2], [3, 4]])
>>> M.cofactor_matrix()
Matrix([
[ 4, -3],
[-2, 1]])
See Also
========
cofactor
minor
minor_submatrix
"""
if not M.is_square or M.rows < 1:
raise NonSquareMatrixError()
return M._new(M.rows, M.cols,
lambda i, j: M.cofactor(i, j, method))
# This functions is a candidate for caching if it gets implemented for matrices.
def _det(M, method="bareiss", iszerofunc=None):
"""Computes the determinant of a matrix if ``M`` is a concrete matrix object
otherwise return an expressions ``Determinant(M)`` if ``M`` is a
``MatrixSymbol`` or other expression.
Parameters
==========
method : string, optional
Specifies the algorithm used for computing the matrix determinant.
If the matrix is at most 3x3, a hard-coded formula is used and the
specified method is ignored. Otherwise, it defaults to
``'bareiss'``.
Also, if the matrix is an upper or a lower triangular matrix, determinant
is computed by simple multiplication of diagonal elements, and the
specified method is ignored.
If it is set to ``'bareiss'``, Bareiss' fraction-free algorithm will
be used.
If it is set to ``'berkowitz'``, Berkowitz' algorithm will be used.
Otherwise, if it is set to ``'lu'``, LU decomposition will be used.
.. note::
For backward compatibility, legacy keys like "bareis" and
"det_lu" can still be used to indicate the corresponding
methods.
And the keys are also case-insensitive for now. However, it is
suggested to use the precise keys for specifying the method.
iszerofunc : FunctionType or None, optional
If it is set to ``None``, it will be defaulted to ``_iszero`` if the
method is set to ``'bareiss'``, and ``_is_zero_after_expand_mul`` if
the method is set to ``'lu'``.
It can also accept any user-specified zero testing function, if it
is formatted as a function which accepts a single symbolic argument
and returns ``True`` if it is tested as zero and ``False`` if it
tested as non-zero, and also ``None`` if it is undecidable.
Returns
=======
det : Basic
Result of determinant.
Raises
======
ValueError
If unrecognized keys are given for ``method`` or ``iszerofunc``.
NonSquareMatrixError
If attempted to calculate determinant from a non-square matrix.
Examples
========
>>> from sympy import Matrix, eye, det
>>> I3 = eye(3)
>>> det(I3)
1
>>> M = Matrix([[1, 2], [3, 4]])
>>> det(M)
-2
>>> det(M) == M.det()
True
"""
# sanitize `method`
method = method.lower()
if method == "bareis":
method = "bareiss"
elif method == "det_lu":
method = "lu"
if method not in ("bareiss", "berkowitz", "lu"):
raise ValueError("Determinant method '%s' unrecognized" % method)
if iszerofunc is None:
if method == "bareiss":
iszerofunc = _is_zero_after_expand_mul
elif method == "lu":
iszerofunc = _iszero
elif not isinstance(iszerofunc, FunctionType):
raise ValueError("Zero testing method '%s' unrecognized" % iszerofunc)
n = M.rows
if n == M.cols: # square check is done in individual method functions
if M.is_upper or M.is_lower:
m = 1
for i in range(n):
m = m * M[i, i]
return _get_intermediate_simp(_dotprodsimp)(m)
elif n == 0:
return M.one
elif n == 1:
return M[0,0]
elif n == 2:
m = M[0, 0] * M[1, 1] - M[0, 1] * M[1, 0]
return _get_intermediate_simp(_dotprodsimp)(m)
elif n == 3:
m = (M[0, 0] * M[1, 1] * M[2, 2]
+ M[0, 1] * M[1, 2] * M[2, 0]
+ M[0, 2] * M[1, 0] * M[2, 1]
- M[0, 2] * M[1, 1] * M[2, 0]
- M[0, 0] * M[1, 2] * M[2, 1]
- M[0, 1] * M[1, 0] * M[2, 2])
return _get_intermediate_simp(_dotprodsimp)(m)
if method == "bareiss":
return M._eval_det_bareiss(iszerofunc=iszerofunc)
elif method == "berkowitz":
return M._eval_det_berkowitz()
elif method == "lu":
return M._eval_det_lu(iszerofunc=iszerofunc)
else:
raise MatrixError('unknown method for calculating determinant')
# This functions is a candidate for caching if it gets implemented for matrices.
def _det_bareiss(M, iszerofunc=_is_zero_after_expand_mul):
"""Compute matrix determinant using Bareiss' fraction-free
algorithm which is an extension of the well known Gaussian
elimination method. This approach is best suited for dense
symbolic matrices and will result in a determinant with
minimal number of fractions. It means that less term
rewriting is needed on resulting formulae.
Parameters
==========
iszerofunc : function, optional
The function to use to determine zeros when doing an LU decomposition.
Defaults to ``lambda x: x.is_zero``.
TODO: Implement algorithm for sparse matrices (SFF),
http://www.eecis.udel.edu/~saunders/papers/sffge/it5.ps.
"""
# Recursively implemented Bareiss' algorithm as per Deanna Richelle Leggett's
# thesis http://www.math.usm.edu/perry/Research/Thesis_DRL.pdf
def bareiss(mat, cumm=1):
if mat.rows == 0:
return mat.one
elif mat.rows == 1:
return mat[0, 0]
# find a pivot and extract the remaining matrix
# With the default iszerofunc, _find_reasonable_pivot slows down
# the computation by the factor of 2.5 in one test.
# Relevant issues: #10279 and #13877.
pivot_pos, pivot_val, _, _ = _find_reasonable_pivot(mat[:, 0], iszerofunc=iszerofunc)
if pivot_pos is None:
return mat.zero
# if we have a valid pivot, we'll do a "row swap", so keep the
# sign of the det
sign = (-1) ** (pivot_pos % 2)
# we want every row but the pivot row and every column
rows = list(i for i in range(mat.rows) if i != pivot_pos)
cols = list(range(mat.cols))
tmp_mat = mat.extract(rows, cols)
def entry(i, j):
ret = (pivot_val*tmp_mat[i, j + 1] - mat[pivot_pos, j + 1]*tmp_mat[i, 0]) / cumm
if _get_intermediate_simp_bool(True):
return _dotprodsimp(ret)
elif not ret.is_Atom:
return cancel(ret)
return ret
return sign*bareiss(M._new(mat.rows - 1, mat.cols - 1, entry), pivot_val)
if not M.is_square:
raise NonSquareMatrixError()
if M.rows == 0:
return M.one
# sympy/matrices/tests/test_matrices.py contains a test that
# suggests that the determinant of a 0 x 0 matrix is one, by
# convention.
return bareiss(M)
def _det_berkowitz(M):
""" Use the Berkowitz algorithm to compute the determinant."""
if not M.is_square:
raise NonSquareMatrixError()
if M.rows == 0:
return M.one
# sympy/matrices/tests/test_matrices.py contains a test that
# suggests that the determinant of a 0 x 0 matrix is one, by
# convention.
berk_vector = _berkowitz_vector(M)
return (-1)**(len(berk_vector) - 1) * berk_vector[-1]
# This functions is a candidate for caching if it gets implemented for matrices.
def _det_LU(M, iszerofunc=_iszero, simpfunc=None):
""" Computes the determinant of a matrix from its LU decomposition.
This function uses the LU decomposition computed by
LUDecomposition_Simple().
The keyword arguments iszerofunc and simpfunc are passed to
LUDecomposition_Simple().
iszerofunc is a callable that returns a boolean indicating if its
input is zero, or None if it cannot make the determination.
simpfunc is a callable that simplifies its input.
The default is simpfunc=None, which indicate that the pivot search
algorithm should not attempt to simplify any candidate pivots.
If simpfunc fails to simplify its input, then it must return its input
instead of a copy.
Parameters
==========
iszerofunc : function, optional
The function to use to determine zeros when doing an LU decomposition.
Defaults to ``lambda x: x.is_zero``.
simpfunc : function, optional
The simplification function to use when looking for zeros for pivots.
"""
if not M.is_square:
raise NonSquareMatrixError()
if M.rows == 0:
return M.one
# sympy/matrices/tests/test_matrices.py contains a test that
# suggests that the determinant of a 0 x 0 matrix is one, by
# convention.
lu, row_swaps = M.LUdecomposition_Simple(iszerofunc=iszerofunc,
simpfunc=simpfunc)
# P*A = L*U => det(A) = det(L)*det(U)/det(P) = det(P)*det(U).
# Lower triangular factor L encoded in lu has unit diagonal => det(L) = 1.
# P is a permutation matrix => det(P) in {-1, 1} => 1/det(P) = det(P).
# LUdecomposition_Simple() returns a list of row exchange index pairs, rather
# than a permutation matrix, but det(P) = (-1)**len(row_swaps).
# Avoid forming the potentially time consuming product of U's diagonal entries
# if the product is zero.
# Bottom right entry of U is 0 => det(A) = 0.
# It may be impossible to determine if this entry of U is zero when it is symbolic.
if iszerofunc(lu[lu.rows-1, lu.rows-1]):
return M.zero
# Compute det(P)
det = -M.one if len(row_swaps)%2 else M.one
# Compute det(U) by calculating the product of U's diagonal entries.
# The upper triangular portion of lu is the upper triangular portion of the
# U factor in the LU decomposition.
for k in range(lu.rows):
det *= lu[k, k]
# return det(P)*det(U)
return det
def _minor(M, i, j, method="berkowitz"):
"""Return the (i,j) minor of ``M``. That is,
return the determinant of the matrix obtained by deleting
the `i`th row and `j`th column from ``M``.
Parameters
==========
i, j : int
The row and column to exclude to obtain the submatrix.
method : string, optional
Method to use to find the determinant of the submatrix, can be
"bareiss", "berkowitz" or "lu".
Examples
========
>>> from sympy import Matrix
>>> M = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]])
>>> M.minor(1, 1)
-12
See Also
========
minor_submatrix
cofactor
det
"""
if not M.is_square:
raise NonSquareMatrixError()
return M.minor_submatrix(i, j).det(method=method)
def _minor_submatrix(M, i, j):
"""Return the submatrix obtained by removing the `i`th row
and `j`th column from ``M`` (works with Pythonic negative indices).
Parameters
==========
i, j : int
The row and column to exclude to obtain the submatrix.
Examples
========
>>> from sympy import Matrix
>>> M = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]])
>>> M.minor_submatrix(1, 1)
Matrix([
[1, 3],
[7, 9]])
See Also
========
minor
cofactor
"""
if i < 0:
i += M.rows
if j < 0:
j += M.cols
if not 0 <= i < M.rows or not 0 <= j < M.cols:
raise ValueError("`i` and `j` must satisfy 0 <= i < ``M.rows`` "
"(%d)" % M.rows + "and 0 <= j < ``M.cols`` (%d)." % M.cols)
rows = [a for a in range(M.rows) if a != i]
cols = [a for a in range(M.cols) if a != j]
return M.extract(rows, cols)
|
d69f40ee54a3ed9dd80e929b05b77ae74025a61a3fe1f8f9631cd13849c380ac | """
Basic methods common to all matrices to be used
when creating more advanced matrices (e.g., matrices over rings,
etc.).
"""
from sympy.core.logic import FuzzyBool
from collections import defaultdict
from inspect import isfunction
from sympy.assumptions.refine import refine
from sympy.core import SympifyError, Add
from sympy.core.basic import Atom
from sympy.core.compatibility import (
Iterable, as_int, is_sequence, reduce)
from sympy.core.decorators import call_highest_priority
from sympy.core.logic import fuzzy_and
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.polys.polytools import Poly
from sympy.simplify import simplify as _simplify
from sympy.simplify.simplify import dotprodsimp as _dotprodsimp
from sympy.utilities.exceptions import SymPyDeprecationWarning
from sympy.utilities.iterables import flatten
from sympy.utilities.misc import filldedent
from .utilities import _get_intermediate_simp_bool
class MatrixError(Exception):
pass
class ShapeError(ValueError, MatrixError):
"""Wrong matrix shape"""
pass
class NonSquareMatrixError(ShapeError):
pass
class NonInvertibleMatrixError(ValueError, MatrixError):
"""The matrix in not invertible (division by multidimensional zero error)."""
pass
class NonPositiveDefiniteMatrixError(ValueError, MatrixError):
"""The matrix is not a positive-definite matrix."""
pass
class MatrixRequired:
"""All subclasses of matrix objects must implement the
required matrix properties listed here."""
rows = None # type: int
cols = None # type: int
_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.")
@property
def shape(self):
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):
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_todok(self):
dok = {}
rows, cols = self.shape
for i in range(rows):
for j in range(cols):
val = self[i, j]
if val != self.zero:
dok[i, j] = val
return dok
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
sympy.matrices.dense.MutableDenseMatrix.col_op
sympy.matrices.dense.MutableDenseMatrix.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
>>> 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
sympy.matrices.dense.MutableDenseMatrix.row_op
sympy.matrices.dense.MutableDenseMatrix.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 todok(self):
"""Return the matrix as dictionary of keys.
Examples
========
>>> from sympy import Matrix
>>> M = Matrix.eye(3)
>>> M.todok()
{(0, 0): 1, (1, 1): 1, (2, 2): 1}
"""
return self._eval_todok()
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 cls.one if i == j else cls.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 cls.one
return cls.zero
else:
def entry(i, j):
if i == j:
return eigenvalue
elif i + 1 == j:
return cls.one
return cls.zero
return cls._new(rows, cols, entry)
@classmethod
def _eval_ones(cls, rows, cols):
def entry(i, j):
return cls.one
return cls._new(rows, cols, entry)
@classmethod
def _eval_zeros(cls, rows, cols):
def entry(i, j):
return cls.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
matrices. 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
.sparsetools.banded - to create multi-diagonal matrices
"""
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)
@classmethod
def companion(kls, poly):
"""Returns a companion matrix of a polynomial.
Examples
========
>>> from sympy import Matrix, Poly, Symbol, symbols
>>> x = Symbol('x')
>>> c0, c1, c2, c3, c4 = symbols('c0:5')
>>> p = Poly(c0 + c1*x + c2*x**2 + c3*x**3 + c4*x**4 + x**5, x)
>>> Matrix.companion(p)
Matrix([
[0, 0, 0, 0, -c0],
[1, 0, 0, 0, -c1],
[0, 1, 0, 0, -c2],
[0, 0, 1, 0, -c3],
[0, 0, 0, 1, -c4]])
"""
poly = kls._sympify(poly)
if not isinstance(poly, Poly):
raise ValueError("{} must be a Poly instance.".format(poly))
if not poly.is_monic:
raise ValueError("{} must be a monic polynomial.".format(poly))
if not poly.is_univariate:
raise ValueError(
"{} must be a univariate polynomial.".format(poly))
size = poly.degree()
if not size >= 1:
raise ValueError(
"{} must have degree not less than 1.".format(poly))
coeffs = poly.all_coeffs()
def entry(i, j):
if j == size - 1:
return -coeffs[-1 - i]
elif i == j + 1:
return kls.one
return kls.zero
return kls._new(size, size, entry)
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_matrix
def _eval_is_Identity(self) -> FuzzyBool:
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_matrix
def _eval_is_zero_matrix(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 _has_positive_diagonals(self):
diagonal_entries = (self[i, i] for i in range(self.rows))
return fuzzy_and((x.is_positive for x in diagonal_entries))
def _has_nonnegative_diagonals(self):
diagonal_entries = (self[i, i] for i in range(self.rows))
return fuzzy_and((x.is_nonnegative for x in diagonal_entries))
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}
>>> Matrix([[x, y], [y, x]])
Matrix([
[x, y],
[y, x]])
>>> _.atoms()
{x, y}
"""
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
sympy.matrices.matrices.MatrixEigen.is_diagonalizable
diagonalize
"""
return self._eval_is_diagonal()
@property
def is_weakly_diagonally_dominant(self):
r"""Tests if the matrix is row weakly diagonally dominant.
Explanation
===========
A $n, n$ matrix $A$ is row weakly diagonally dominant if
.. math::
\left|A_{i, i}\right| \ge \sum_{j = 0, j \neq i}^{n-1}
\left|A_{i, j}\right| \quad {\text{for all }}
i \in \{ 0, ..., n-1 \}
Examples
========
>>> from sympy.matrices import Matrix
>>> A = Matrix([[3, -2, 1], [1, -3, 2], [-1, 2, 4]])
>>> A.is_weakly_diagonally_dominant
True
>>> A = Matrix([[-2, 2, 1], [1, 3, 2], [1, -2, 0]])
>>> A.is_weakly_diagonally_dominant
False
>>> A = Matrix([[-4, 2, 1], [1, 6, 2], [1, -2, 5]])
>>> A.is_weakly_diagonally_dominant
True
Notes
=====
If you want to test whether a matrix is column diagonally
dominant, you can apply the test after transposing the matrix.
"""
if not self.is_square:
return False
rows, cols = self.shape
def test_row(i):
summation = self.zero
for j in range(cols):
if i != j:
summation += Abs(self[i, j])
return (Abs(self[i, i]) - summation).is_nonnegative
return fuzzy_and((test_row(i) for i in range(rows)))
@property
def is_strongly_diagonally_dominant(self):
r"""Tests if the matrix is row strongly diagonally dominant.
Explanation
===========
A $n, n$ matrix $A$ is row strongly diagonally dominant if
.. math::
\left|A_{i, i}\right| > \sum_{j = 0, j \neq i}^{n-1}
\left|A_{i, j}\right| \quad {\text{for all }}
i \in \{ 0, ..., n-1 \}
Examples
========
>>> from sympy.matrices import Matrix
>>> A = Matrix([[3, -2, 1], [1, -3, 2], [-1, 2, 4]])
>>> A.is_strongly_diagonally_dominant
False
>>> A = Matrix([[-2, 2, 1], [1, 3, 2], [1, -2, 0]])
>>> A.is_strongly_diagonally_dominant
False
>>> A = Matrix([[-4, 2, 1], [1, 6, 2], [1, -2, 5]])
>>> A.is_strongly_diagonally_dominant
True
Notes
=====
If you want to test whether a matrix is column diagonally
dominant, you can apply the test after transposing the matrix.
"""
if not self.is_square:
return False
rows, cols = self.shape
def test_row(i):
summation = self.zero
for j in range(cols):
if i != j:
summation += Abs(self[i, j])
return (Abs(self[i, i]) - summation).is_positive
return fuzzy_and((test_row(i) for i in range(rows)))
@property
def is_hermitian(self):
"""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
return self._eval_is_matrix_hermitian(_simplify)
@property
def is_Identity(self) -> FuzzyBool:
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_matrix(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_matrix
True
>>> b.is_zero_matrix
True
>>> c.is_zero_matrix
False
>>> d.is_zero_matrix
True
>>> e.is_zero_matrix
"""
return self._eval_is_zero_matrix()
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): # type: ignore
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, deep=True, **hints):
"""Returns a tuple containing the (real, imaginary) part of matrix."""
# XXX: Ignoring deep and hints...
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
sympy.matrices.matrices.MatrixBase.D: Dirac conjugation
"""
return self._eval_conjugate()
def doit(self, **kwargs):
return self.applyfunc(lambda x: x.doit())
def evalf(self, n=15, subs=None, maxn=100, chop=False, strict=False, quad=None, verbose=False):
"""Apply evalf() to each element of self."""
options = {'subs':subs, 'maxn':maxn, 'chop':chop, 'strict':strict,
'quad':quad, 'verbose':verbose}
return self.applyfunc(lambda i: i.evalf(n, **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
sympy.matrices.matrices.MatrixBase.D: Dirac conjugation
"""
return self.T.C
def permute(self, perm, orientation='rows', direction='forward'):
r"""Permute the rows or columns of a matrix by the given list of
swaps.
Parameters
==========
perm : Permutation, list, or list of lists
A representation for the permutation.
If it is ``Permutation``, it is used directly with some
resizing with respect to the matrix size.
If it is specified as list of lists,
(e.g., ``[[0, 1], [0, 2]]``), then the permutation is formed
from applying the product of cycles. The direction how the
cyclic product is applied is described in below.
If it is specified as a list, the list should represent
an array form of a permutation. (e.g., ``[1, 2, 0]``) which
would would form the swapping function
`0 \mapsto 1, 1 \mapsto 2, 2\mapsto 0`.
orientation : 'rows', 'cols'
A flag to control whether to permute the rows or the columns
direction : 'forward', 'backward'
A flag to control whether to apply the permutations from
the start of the list first, or from the back of the list
first.
For example, if the permutation specification is
``[[0, 1], [0, 2]]``,
If the flag is set to ``'forward'``, the cycle would be
formed as `0 \mapsto 2, 2 \mapsto 1, 1 \mapsto 0`.
If the flag is set to ``'backward'``, the cycle would be
formed as `0 \mapsto 1, 1 \mapsto 2, 2 \mapsto 0`.
If the argument ``perm`` is not in a form of list of lists,
this flag takes no effect.
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]])
Notes
=====
If a bijective function
`\sigma : \mathbb{N}_0 \rightarrow \mathbb{N}_0` denotes the
permutation.
If the matrix `A` is the matrix to permute, represented as
a horizontal or a vertical stack of vectors:
.. math::
A =
\begin{bmatrix}
a_0 \\ a_1 \\ \vdots \\ a_{n-1}
\end{bmatrix} =
\begin{bmatrix}
\alpha_0 & \alpha_1 & \cdots & \alpha_{n-1}
\end{bmatrix}
If the matrix `B` is the result, the permutation of matrix rows
is defined as:
.. math::
B := \begin{bmatrix}
a_{\sigma(0)} \\ a_{\sigma(1)} \\ \vdots \\ a_{\sigma(n-1)}
\end{bmatrix}
And the permutation of matrix columns is defined as:
.. math::
B := \begin{bmatrix}
\alpha_{\sigma(0)} & \alpha_{\sigma(1)} &
\cdots & \alpha_{\sigma(n-1)}
\end{bmatrix}
"""
from sympy.combinatorics import Permutation
# 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))
if not isinstance(perm, (Permutation, Iterable)):
raise ValueError(
"{} must be a list, a list of lists, "
"or a SymPy permutation object.".format(perm))
# 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.")
if perm and not isinstance(perm, Permutation) and \
isinstance(perm[0], Iterable):
if direction == 'forward':
perm = list(reversed(perm))
perm = Permutation(perm, size=max_index+1)
else:
perm = Permutation(perm, size=max_index+1)
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, simultaneous=True, exact=None):
"""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=map, simultaneous=simultaneous, exact=exact))
def rot90(self, k=1):
"""Rotates Matrix by 90 degrees
Parameters
==========
k : int
Specifies how many times the matrix is rotated by 90 degrees
(clockwise when positive, counter-clockwise when negative).
Examples
========
>>> from sympy import Matrix, symbols
>>> A = Matrix(2, 2, symbols('a:d'))
>>> A
Matrix([
[a, b],
[c, d]])
Rotating the matrix clockwise one time:
>>> A.rot90(1)
Matrix([
[c, a],
[d, b]])
Rotating the matrix anticlockwise two times:
>>> A.rot90(-2)
Matrix([
[d, c],
[b, a]])
"""
mod = k%4
if mod == 0:
return self
if mod == 1:
return self[::-1, ::].T
if mod == 2:
return self[::-1, ::-1]
if mod == 3:
return self[::, ::-1].T
def simplify(self, **kwargs):
"""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(**kwargs))
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()
@property
def T(self):
'''Matrix transposition'''
return self.transpose()
@property
def C(self):
'''By-element conjugation'''
return self.conjugate()
def n(self, *args, **kwargs):
"""Apply evalf() to each element of self."""
return self.evalf(*args, **kwargs)
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))
def _eval_simplify(self, **kwargs):
# XXX: We can't use self.simplify here as mutable subclasses will
# override simplify and have it return None
return MatrixOperations.simplify(self, **kwargs)
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):
vec = [self[i,k]*other[k,j] for k in range(self.cols)]
try:
return Add(*vec)
except (TypeError, SympifyError):
# Some matrices don't work with `sum` or `Add`
# They don't work with `sum` because `sum` tries to add `0`
# Fall back to a safe way to multiply if the `Add` fails.
return reduce(lambda a, b: a + b, vec)
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:
a, b = self, self._eval_pow_by_recursion(num - 1)
else:
a = b = self._eval_pow_by_recursion(num // 2)
return a.multiply(b)
def _eval_pow_by_cayley(self, exp):
from sympy.discrete.recurrences import linrec_coeffs
row = self.shape[0]
p = self.charpoly()
coeffs = (-p).all_coeffs()[1:]
coeffs = linrec_coeffs(coeffs, exp)
new_mat = self.eye(row)
ans = self.zeros(row)
for i in range(row):
ans += coeffs[i]*new_mat
new_mat *= self
return ans
def _eval_pow_by_recursion_dotprodsimp(self, num, prevsimp=None):
if prevsimp is None:
prevsimp = [True]*len(self)
if num == 1:
return self
if num % 2 == 1:
a, b = self, self._eval_pow_by_recursion_dotprodsimp(num - 1,
prevsimp=prevsimp)
else:
a = b = self._eval_pow_by_recursion_dotprodsimp(num // 2,
prevsimp=prevsimp)
m = a.multiply(b, dotprodsimp=False)
lenm = len(m)
elems = [None]*lenm
for i in range(lenm):
if prevsimp[i]:
elems[i], prevsimp[i] = _dotprodsimp(m[i], withsimp=True)
else:
elems[i] = m[i]
return m._new(m.rows, m.cols, elems)
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 * (self.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
"""
return self.multiply(other)
def multiply(self, other, dotprodsimp=None):
"""Same as __mul__() but with optional simplification.
Parameters
==========
dotprodsimp : bool, optional
Specifies whether intermediate term algebraic simplification is used
during matrix multiplications to control expression blowup and thus
speed up calculation. Default is off.
"""
isimpbool = _get_intermediate_simp_bool(False, dotprodsimp)
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):
m = self._eval_matrix_mul(other)
if isimpbool:
return m._new(m.rows, m.cols, [_dotprodsimp(e) for e in m])
return m
# 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 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
========
sympy.matrices.matrices.MatrixBase.cross
sympy.matrices.matrices.MatrixBase.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)
def __neg__(self):
return self._eval_scalar_mul(-1)
@call_highest_priority('__rpow__')
def __pow__(self, exp):
"""Return self**exp a scalar or symbol."""
return self.pow(exp)
def pow(self, exp, method=None):
r"""Return self**exp a scalar or symbol.
Parameters
==========
method : multiply, mulsimp, jordan, cayley
If multiply then it returns exponentiation using recursion.
If jordan then Jordan form exponentiation will be used.
If cayley then the exponentiation is done using Cayley-Hamilton
theorem.
If mulsimp then the exponentiation is done using recursion
with dotprodsimp. This specifies whether intermediate term
algebraic simplification is used during naive matrix power to
control expression blowup and thus speed up calculation.
If None, then it heuristically decides which method to use.
"""
if method is not None and method not in ['multiply', 'mulsimp', 'jordan', 'cayley']:
raise TypeError('No such method')
if self.rows != self.cols:
raise NonSquareMatrixError()
a = self
jordan_pow = getattr(a, '_matrix_pow_by_jordan_blocks', None)
exp = sympify(exp)
if exp.is_zero:
return a._new(a.rows, a.cols, lambda i, j: int(i == j))
if exp == 1:
return a
diagonal = getattr(a, 'is_diagonal', None)
if diagonal is not None and diagonal():
return a._new(a.rows, a.cols, lambda i, j: a[i,j]**exp if i == j else 0)
if exp.is_Number and exp % 1 == 0:
if a.rows == 1:
return a._new([[a[0]**exp]])
if exp < 0:
exp = -exp
a = a.inv()
# When certain conditions are met,
# Jordan block algorithm is faster than
# computation by recursion.
if method == 'jordan':
try:
return jordan_pow(exp)
except MatrixError:
if method == 'jordan':
raise
elif method == 'cayley':
if not exp.is_Number or exp % 1 != 0:
raise ValueError("cayley method is only valid for integer powers")
return a._eval_pow_by_cayley(exp)
elif method == "mulsimp":
if not exp.is_Number or exp % 1 != 0:
raise ValueError("mulsimp method is only valid for integer powers")
return a._eval_pow_by_recursion_dotprodsimp(exp)
elif method == "multiply":
if not exp.is_Number or exp % 1 != 0:
raise ValueError("multiply method is only valid for integer powers")
return a._eval_pow_by_recursion(exp)
elif method is None and exp.is_Number and exp % 1 == 0:
# Decide heuristically which method to apply
if a.rows == 2 and exp > 100000:
return jordan_pow(exp)
elif _get_intermediate_simp_bool(True, None):
return a._eval_pow_by_recursion_dotprodsimp(exp)
elif exp > 10000:
return a._eval_pow_by_cayley(exp)
else:
return a._eval_pow_by_recursion(exp)
if jordan_pow:
try:
return jordan_pow(exp)
except NonInvertibleMatrixError:
# Raised by jordan_pow on zero determinant matrix unless exp is
# definitely known to be a non-negative integer.
# Here we raise if n is definitely not a non-negative integer
# but otherwise we can leave this as an unevaluated MatPow.
if exp.is_integer is False or exp.is_nonnegative is False:
raise
from sympy.matrices.expressions import MatPow
return MatPow(a, exp)
@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)
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 # type: bool
class _MinimalMatrix:
"""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
zero = S.Zero
one = S.One
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 _CastableMatrix: # this is needed here ONLY FOR TESTS.
def as_mutable(self):
return self
def as_immutable(self):
return self
class _MatrixWrapper:
"""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. This one is intended for
matrix-like objects which use the same indexing format as SymPy with respect
to returning matrix elements instead of rows for non-tuple indexes.
"""
is_Matrix = False # needs to be here because of __getattr__
is_MatrixLike = True
def __init__(self, mat, shape):
self.mat = mat
self.shape = shape
self.rows, self.cols = shape
def __getitem__(self, key):
if isinstance(key, tuple):
return sympify(self.mat.__getitem__(key))
return sympify(self.mat.__getitem__((key // self.rows, key % self.cols)))
def __iter__(self): # supports numpy.matrix and numpy.array
mat = self.mat
cols = self.cols
return iter(sympify(mat[r, c]) for r in range(self.rows) for c in range(cols))
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) or getattr(mat, 'is_MatrixLike', False):
return mat
shape = None
if hasattr(mat, 'shape'): # numpy, scipy.sparse
if len(mat.shape) == 2:
shape = mat.shape
elif hasattr(mat, 'rows') and hasattr(mat, 'cols'): # mpmath
shape = (mat.rows, mat.cols)
if shape:
return _MatrixWrapper(mat, shape)
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__))
|
d76095d6c84214b2b1815f6615f5a55ecb1fa9cf561e005920a0e19cbb416c99 | import random
from sympy.core import SympifyError, Add
from sympy.core.basic import Basic
from sympy.core.compatibility import is_sequence, reduce
from sympy.core.expr import Expr
from sympy.core.singleton import S
from sympy.core.symbol import Symbol
from sympy.core.sympify import sympify
from sympy.functions.elementary.trigonometric import cos, sin
from sympy.matrices.common import \
a2idx, classof, ShapeError
from sympy.matrices.matrices import MatrixBase
from sympy.simplify.simplify import simplify as _simplify
from sympy.utilities.decorator import doctest_depends_on
from sympy.utilities.misc import filldedent
from .decompositions import _cholesky, _LDLdecomposition
from .solvers import _lower_triangular_solve, _upper_triangular_solve
def _iszero(x):
"""Returns True if x is zero."""
return x.is_zero
def _compare_sequence(a, b):
"""Compares the elements of a list/tuple `a`
and a list/tuple `b`. `_compare_sequence((1,2), [1, 2])`
is True, whereas `(1,2) == [1, 2]` is False"""
if type(a) is type(b):
# if they are the same type, compare directly
return a == b
# there is no overhead for calling `tuple` on a
# tuple
return tuple(a) == tuple(b)
class DenseMatrix(MatrixBase):
is_MatrixExpr = False # type: bool
_op_priority = 10.01
_class_priority = 4
def __eq__(self, other):
other = sympify(other)
self_shape = getattr(self, 'shape', None)
other_shape = getattr(other, 'shape', None)
if None in (self_shape, other_shape):
return False
if self_shape != other_shape:
return False
if isinstance(other, Matrix):
return _compare_sequence(self._mat, other._mat)
elif isinstance(other, MatrixBase):
return _compare_sequence(self._mat, Matrix(other)._mat)
def __getitem__(self, key):
"""Return portion of self defined by key. If the key involves a slice
then a list will be returned (if key is a single slice) or a matrix
(if key was a tuple involving a slice).
Examples
========
>>> from sympy import Matrix, I
>>> m = Matrix([
... [1, 2 + I],
... [3, 4 ]])
If the key is a tuple that doesn't involve a slice then that element
is returned:
>>> m[1, 0]
3
When a tuple key involves a slice, a matrix is returned. Here, the
first column is selected (all rows, column 0):
>>> m[:, 0]
Matrix([
[1],
[3]])
If the slice is not a tuple then it selects from the underlying
list of elements that are arranged in row order and a list is
returned if a slice is involved:
>>> m[0]
1
>>> m[::2]
[1, 3]
"""
if isinstance(key, tuple):
i, j = key
try:
i, j = self.key2ij(key)
return self._mat[i*self.cols + j]
except (TypeError, IndexError):
if (isinstance(i, Expr) and not i.is_number) or (isinstance(j, Expr) and not j.is_number):
if ((j < 0) is True) or ((j >= self.shape[1]) is True) or\
((i < 0) is True) or ((i >= self.shape[0]) is True):
raise ValueError("index out of boundary")
from sympy.matrices.expressions.matexpr import MatrixElement
return MatrixElement(self, i, j)
if isinstance(i, slice):
i = range(self.rows)[i]
elif is_sequence(i):
pass
else:
i = [i]
if isinstance(j, slice):
j = range(self.cols)[j]
elif is_sequence(j):
pass
else:
j = [j]
return self.extract(i, j)
else:
# row-wise decomposition of matrix
if isinstance(key, slice):
return self._mat[key]
return self._mat[a2idx(key)]
def __setitem__(self, key, value):
raise NotImplementedError()
def _eval_add(self, other):
# we assume both arguments are dense matrices since
# sparse matrices have a higher priority
mat = [a + b for a,b in zip(self._mat, other._mat)]
return classof(self, other)._new(self.rows, self.cols, mat, copy=False)
def _eval_extract(self, rowsList, colsList):
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),
list(mat[i] for i in indices), copy=False)
def _eval_matrix_mul(self, other):
other_len = other.rows*other.cols
new_len = self.rows*other.cols
new_mat = [self.zero]*new_len
# if we multiply an n x 0 with a 0 x m, the
# expected behavior is to produce an n x m matrix of zeros
if self.cols != 0 and other.rows != 0:
self_cols = self.cols
mat = self._mat
other_mat = other._mat
for i in range(new_len):
row, col = i // other.cols, i % other.cols
row_indices = range(self_cols*row, self_cols*(row+1))
col_indices = range(col, other_len, other.cols)
vec = [mat[a]*other_mat[b] for a, b in zip(row_indices, col_indices)]
try:
new_mat[i] = Add(*vec)
except (TypeError, SympifyError):
# Some matrices don't work with `sum` or `Add`
# They don't work with `sum` because `sum` tries to add `0`
# Fall back to a safe way to multiply if the `Add` fails.
new_mat[i] = reduce(lambda a, b: a + b, vec)
return classof(self, other)._new(self.rows, other.cols, new_mat, copy=False)
def _eval_matrix_mul_elementwise(self, other):
mat = [a*b for a,b in zip(self._mat, other._mat)]
return classof(self, other)._new(self.rows, self.cols, mat, copy=False)
def _eval_inverse(self, **kwargs):
return self.inv(method=kwargs.get('method', 'GE'),
iszerofunc=kwargs.get('iszerofunc', _iszero),
try_block_diag=kwargs.get('try_block_diag', False))
def _eval_scalar_mul(self, other):
mat = [other*a for a in self._mat]
return self._new(self.rows, self.cols, mat, copy=False)
def _eval_scalar_rmul(self, other):
mat = [a*other for a in self._mat]
return self._new(self.rows, self.cols, mat, copy=False)
def _eval_tolist(self):
mat = list(self._mat)
cols = self.cols
return [mat[i*cols:(i + 1)*cols] for i in range(self.rows)]
def as_immutable(self):
"""Returns an Immutable version of this Matrix
"""
from .immutable import ImmutableDenseMatrix as cls
if self.rows and self.cols:
return cls._new(self.tolist())
return cls._new(self.rows, self.cols, [])
def as_mutable(self):
"""Returns a mutable version of this matrix
Examples
========
>>> from sympy import ImmutableMatrix
>>> X = ImmutableMatrix([[1, 2], [3, 4]])
>>> Y = X.as_mutable()
>>> Y[1, 1] = 5 # Can set values in Y
>>> Y
Matrix([
[1, 2],
[3, 5]])
"""
return Matrix(self)
def equals(self, other, failing_expression=False):
"""Applies ``equals`` to corresponding elements of the matrices,
trying to prove that the elements are equivalent, returning True
if they are, False if any pair is not, and None (or the first
failing expression if failing_expression is True) if it cannot
be decided if the expressions are equivalent or not. This is, in
general, an expensive operation.
Examples
========
>>> from sympy.matrices import Matrix
>>> from sympy.abc import x
>>> A = Matrix([x*(x - 1), 0])
>>> B = Matrix([x**2 - x, 0])
>>> A == B
False
>>> A.simplify() == B.simplify()
True
>>> A.equals(B)
True
>>> A.equals(2)
False
See Also
========
sympy.core.expr.Expr.equals
"""
self_shape = getattr(self, 'shape', None)
other_shape = getattr(other, 'shape', None)
if None in (self_shape, other_shape):
return False
if self_shape != other_shape:
return False
rv = True
for i in range(self.rows):
for j in range(self.cols):
ans = self[i, j].equals(other[i, j], failing_expression)
if ans is False:
return False
elif ans is not True and rv is True:
rv = ans
return rv
def cholesky(self, hermitian=True):
return _cholesky(self, hermitian=hermitian)
def LDLdecomposition(self, hermitian=True):
return _LDLdecomposition(self, hermitian=hermitian)
def lower_triangular_solve(self, rhs):
return _lower_triangular_solve(self, rhs)
def upper_triangular_solve(self, rhs):
return _upper_triangular_solve(self, rhs)
cholesky.__doc__ = _cholesky.__doc__
LDLdecomposition.__doc__ = _LDLdecomposition.__doc__
lower_triangular_solve.__doc__ = _lower_triangular_solve.__doc__
upper_triangular_solve.__doc__ = _upper_triangular_solve.__doc__
def _force_mutable(x):
"""Return a matrix as a Matrix, otherwise return x."""
if getattr(x, 'is_Matrix', False):
return x.as_mutable()
elif isinstance(x, Basic):
return x
elif hasattr(x, '__array__'):
a = x.__array__()
if len(a.shape) == 0:
return sympify(a)
return Matrix(x)
return x
class MutableDenseMatrix(DenseMatrix, MatrixBase):
__hash__ = None
def __new__(cls, *args, **kwargs):
return cls._new(*args, **kwargs)
@classmethod
def _new(cls, *args, **kwargs):
# if the `copy` flag is set to False, the input
# was rows, cols, [list]. It should be used directly
# without creating a copy.
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
self = object.__new__(cls)
self.rows = rows
self.cols = cols
self._mat = flat_list
return self
def __setitem__(self, key, value):
"""
Examples
========
>>> from sympy import Matrix, I, zeros, ones
>>> m = Matrix(((1, 2+I), (3, 4)))
>>> m
Matrix([
[1, 2 + I],
[3, 4]])
>>> m[1, 0] = 9
>>> m
Matrix([
[1, 2 + I],
[9, 4]])
>>> m[1, 0] = [[0, 1]]
To replace row r you assign to position r*m where m
is the number of columns:
>>> M = zeros(4)
>>> m = M.cols
>>> M[3*m] = ones(1, m)*2; M
Matrix([
[0, 0, 0, 0],
[0, 0, 0, 0],
[0, 0, 0, 0],
[2, 2, 2, 2]])
And to replace column c you can assign to position c:
>>> M[2] = ones(m, 1)*4; M
Matrix([
[0, 0, 4, 0],
[0, 0, 4, 0],
[0, 0, 4, 0],
[2, 2, 4, 2]])
"""
rv = self._setitem(key, value)
if rv is not None:
i, j, value = rv
self._mat[i*self.cols + j] = value
def as_mutable(self):
return self.copy()
def col_del(self, i):
"""Delete the given column.
Examples
========
>>> from sympy.matrices import eye
>>> M = eye(3)
>>> M.col_del(1)
>>> M
Matrix([
[1, 0],
[0, 0],
[0, 1]])
See Also
========
col
row_del
"""
if i < -self.cols or i >= self.cols:
raise IndexError("Index out of range: 'i=%s', valid -%s <= i < %s"
% (i, self.cols, self.cols))
for j in range(self.rows - 1, -1, -1):
del self._mat[i + j*self.cols]
self.cols -= 1
def col_op(self, j, f):
"""In-place operation on col j using two-arg functor whose args are
interpreted as (self[i, j], i).
Examples
========
>>> from sympy.matrices import eye
>>> M = eye(3)
>>> M.col_op(1, lambda v, i: v + 2*M[i, 0]); M
Matrix([
[1, 2, 0],
[0, 1, 0],
[0, 0, 1]])
See Also
========
col
row_op
"""
self._mat[j::self.cols] = [f(*t) for t in list(zip(self._mat[j::self.cols], list(range(self.rows))))]
def col_swap(self, i, j):
"""Swap the two given columns of the matrix in-place.
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix([[1, 0], [1, 0]])
>>> M
Matrix([
[1, 0],
[1, 0]])
>>> M.col_swap(0, 1)
>>> M
Matrix([
[0, 1],
[0, 1]])
See Also
========
col
row_swap
"""
for k in range(0, self.rows):
self[k, i], self[k, j] = self[k, j], self[k, i]
def copyin_list(self, key, value):
"""Copy in elements from a list.
Parameters
==========
key : slice
The section of this matrix to replace.
value : iterable
The iterable to copy values from.
Examples
========
>>> from sympy.matrices import eye
>>> I = eye(3)
>>> I[:2, 0] = [1, 2] # col
>>> I
Matrix([
[1, 0, 0],
[2, 1, 0],
[0, 0, 1]])
>>> I[1, :2] = [[3, 4]]
>>> I
Matrix([
[1, 0, 0],
[3, 4, 0],
[0, 0, 1]])
See Also
========
copyin_matrix
"""
if not is_sequence(value):
raise TypeError("`value` must be an ordered iterable, not %s." % type(value))
return self.copyin_matrix(key, Matrix(value))
def copyin_matrix(self, key, value):
"""Copy in values from a matrix into the given bounds.
Parameters
==========
key : slice
The section of this matrix to replace.
value : Matrix
The matrix to copy values from.
Examples
========
>>> from sympy.matrices import Matrix, eye
>>> M = Matrix([[0, 1], [2, 3], [4, 5]])
>>> I = eye(3)
>>> I[:3, :2] = M
>>> I
Matrix([
[0, 1, 0],
[2, 3, 0],
[4, 5, 1]])
>>> I[0, 1] = M
>>> I
Matrix([
[0, 0, 1],
[2, 2, 3],
[4, 4, 5]])
See Also
========
copyin_list
"""
rlo, rhi, clo, chi = self.key2bounds(key)
shape = value.shape
dr, dc = rhi - rlo, chi - clo
if shape != (dr, dc):
raise ShapeError(filldedent("The Matrix `value` doesn't have the "
"same dimensions "
"as the in sub-Matrix given by `key`."))
for i in range(value.rows):
for j in range(value.cols):
self[i + rlo, j + clo] = value[i, j]
def fill(self, value):
"""Fill the matrix with the scalar value.
See Also
========
zeros
ones
"""
self._mat = [value]*len(self)
def row_del(self, i):
"""Delete the given row.
Examples
========
>>> from sympy.matrices import eye
>>> M = eye(3)
>>> M.row_del(1)
>>> M
Matrix([
[1, 0, 0],
[0, 0, 1]])
See Also
========
row
col_del
"""
if i < -self.rows or i >= self.rows:
raise IndexError("Index out of range: 'i = %s', valid -%s <= i"
" < %s" % (i, self.rows, self.rows))
if i < 0:
i += self.rows
del self._mat[i*self.cols:(i+1)*self.cols]
self.rows -= 1
def row_op(self, i, f):
"""In-place operation on row ``i`` using two-arg functor whose args are
interpreted as ``(self[i, j], j)``.
Examples
========
>>> from sympy.matrices import eye
>>> M = eye(3)
>>> M.row_op(1, lambda v, j: v + 2*M[0, j]); M
Matrix([
[1, 0, 0],
[2, 1, 0],
[0, 0, 1]])
See Also
========
row
zip_row_op
col_op
"""
i0 = i*self.cols
ri = self._mat[i0: i0 + self.cols]
self._mat[i0: i0 + self.cols] = [f(x, j) for x, j in zip(ri, list(range(self.cols)))]
def row_swap(self, i, j):
"""Swap the two given rows of the matrix in-place.
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix([[0, 1], [1, 0]])
>>> M
Matrix([
[0, 1],
[1, 0]])
>>> M.row_swap(0, 1)
>>> M
Matrix([
[1, 0],
[0, 1]])
See Also
========
row
col_swap
"""
for k in range(0, self.cols):
self[i, k], self[j, k] = self[j, k], self[i, k]
def simplify(self, **kwargs):
"""Applies simplify to the elements of a matrix in place.
This is a shortcut for M.applyfunc(lambda x: simplify(x, ratio, measure))
See Also
========
sympy.simplify.simplify.simplify
"""
for i in range(len(self._mat)):
self._mat[i] = _simplify(self._mat[i], **kwargs)
def zip_row_op(self, i, k, f):
"""In-place operation on row ``i`` using two-arg functor whose args are
interpreted as ``(self[i, j], self[k, j])``.
Examples
========
>>> from sympy.matrices import eye
>>> M = eye(3)
>>> M.zip_row_op(1, 0, lambda v, u: v + 2*u); M
Matrix([
[1, 0, 0],
[2, 1, 0],
[0, 0, 1]])
See Also
========
row
row_op
col_op
"""
i0 = i*self.cols
k0 = k*self.cols
ri = self._mat[i0: i0 + self.cols]
rk = self._mat[k0: k0 + self.cols]
self._mat[i0: i0 + self.cols] = [f(x, y) for x, y in zip(ri, rk)]
is_zero = False
MutableMatrix = Matrix = MutableDenseMatrix
###########
# Numpy Utility Functions:
# list2numpy, matrix2numpy, symmarray, rot_axis[123]
###########
def list2numpy(l, dtype=object): # pragma: no cover
"""Converts python list of SymPy expressions to a NumPy array.
See Also
========
matrix2numpy
"""
from numpy import empty
a = empty(len(l), dtype)
for i, s in enumerate(l):
a[i] = s
return a
def matrix2numpy(m, dtype=object): # pragma: no cover
"""Converts SymPy's matrix to a NumPy array.
See Also
========
list2numpy
"""
from numpy import empty
a = empty(m.shape, dtype)
for i in range(m.rows):
for j in range(m.cols):
a[i, j] = m[i, j]
return a
def rot_axis3(theta):
"""Returns a rotation matrix for a rotation of theta (in radians) about
the 3-axis.
Examples
========
>>> from sympy import pi
>>> from sympy.matrices import rot_axis3
A rotation of pi/3 (60 degrees):
>>> theta = pi/3
>>> rot_axis3(theta)
Matrix([
[ 1/2, sqrt(3)/2, 0],
[-sqrt(3)/2, 1/2, 0],
[ 0, 0, 1]])
If we rotate by pi/2 (90 degrees):
>>> rot_axis3(pi/2)
Matrix([
[ 0, 1, 0],
[-1, 0, 0],
[ 0, 0, 1]])
See Also
========
rot_axis1: Returns a rotation matrix for a rotation of theta (in radians)
about the 1-axis
rot_axis2: Returns a rotation matrix for a rotation of theta (in radians)
about the 2-axis
"""
ct = cos(theta)
st = sin(theta)
lil = ((ct, st, 0),
(-st, ct, 0),
(0, 0, 1))
return Matrix(lil)
def rot_axis2(theta):
"""Returns a rotation matrix for a rotation of theta (in radians) about
the 2-axis.
Examples
========
>>> from sympy import pi
>>> from sympy.matrices import rot_axis2
A rotation of pi/3 (60 degrees):
>>> theta = pi/3
>>> rot_axis2(theta)
Matrix([
[ 1/2, 0, -sqrt(3)/2],
[ 0, 1, 0],
[sqrt(3)/2, 0, 1/2]])
If we rotate by pi/2 (90 degrees):
>>> rot_axis2(pi/2)
Matrix([
[0, 0, -1],
[0, 1, 0],
[1, 0, 0]])
See Also
========
rot_axis1: Returns a rotation matrix for a rotation of theta (in radians)
about the 1-axis
rot_axis3: Returns a rotation matrix for a rotation of theta (in radians)
about the 3-axis
"""
ct = cos(theta)
st = sin(theta)
lil = ((ct, 0, -st),
(0, 1, 0),
(st, 0, ct))
return Matrix(lil)
def rot_axis1(theta):
"""Returns a rotation matrix for a rotation of theta (in radians) about
the 1-axis.
Examples
========
>>> from sympy import pi
>>> from sympy.matrices import rot_axis1
A rotation of pi/3 (60 degrees):
>>> theta = pi/3
>>> rot_axis1(theta)
Matrix([
[1, 0, 0],
[0, 1/2, sqrt(3)/2],
[0, -sqrt(3)/2, 1/2]])
If we rotate by pi/2 (90 degrees):
>>> rot_axis1(pi/2)
Matrix([
[1, 0, 0],
[0, 0, 1],
[0, -1, 0]])
See Also
========
rot_axis2: Returns a rotation matrix for a rotation of theta (in radians)
about the 2-axis
rot_axis3: Returns a rotation matrix for a rotation of theta (in radians)
about the 3-axis
"""
ct = cos(theta)
st = sin(theta)
lil = ((1, 0, 0),
(0, ct, st),
(0, -st, ct))
return Matrix(lil)
@doctest_depends_on(modules=('numpy',))
def symarray(prefix, shape, **kwargs): # pragma: no cover
r"""Create a numpy ndarray of symbols (as an object array).
The created symbols are named ``prefix_i1_i2_``... You should thus provide a
non-empty prefix if you want your symbols to be unique for different output
arrays, as SymPy symbols with identical names are the same object.
Parameters
----------
prefix : string
A prefix prepended to the name of every symbol.
shape : int or tuple
Shape of the created array. If an int, the array is one-dimensional; for
more than one dimension the shape must be a tuple.
\*\*kwargs : dict
keyword arguments passed on to Symbol
Examples
========
These doctests require numpy.
>>> from sympy import symarray
>>> symarray('', 3)
[_0 _1 _2]
If you want multiple symarrays to contain distinct symbols, you *must*
provide unique prefixes:
>>> a = symarray('', 3)
>>> b = symarray('', 3)
>>> a[0] == b[0]
True
>>> a = symarray('a', 3)
>>> b = symarray('b', 3)
>>> a[0] == b[0]
False
Creating symarrays with a prefix:
>>> symarray('a', 3)
[a_0 a_1 a_2]
For more than one dimension, the shape must be given as a tuple:
>>> symarray('a', (2, 3))
[[a_0_0 a_0_1 a_0_2]
[a_1_0 a_1_1 a_1_2]]
>>> symarray('a', (2, 3, 2))
[[[a_0_0_0 a_0_0_1]
[a_0_1_0 a_0_1_1]
[a_0_2_0 a_0_2_1]]
<BLANKLINE>
[[a_1_0_0 a_1_0_1]
[a_1_1_0 a_1_1_1]
[a_1_2_0 a_1_2_1]]]
For setting assumptions of the underlying Symbols:
>>> [s.is_real for s in symarray('a', 2, real=True)]
[True, True]
"""
from numpy import empty, ndindex
arr = empty(shape, dtype=object)
for index in ndindex(shape):
arr[index] = Symbol('%s_%s' % (prefix, '_'.join(map(str, index))),
**kwargs)
return arr
###############
# Functions
###############
def casoratian(seqs, n, zero=True):
"""Given linear difference operator L of order 'k' and homogeneous
equation Ly = 0 we want to compute kernel of L, which is a set
of 'k' sequences: a(n), b(n), ... z(n).
Solutions of L are linearly independent iff their Casoratian,
denoted as C(a, b, ..., z), do not vanish for n = 0.
Casoratian is defined by k x k determinant::
+ a(n) b(n) . . . z(n) +
| a(n+1) b(n+1) . . . z(n+1) |
| . . . . |
| . . . . |
| . . . . |
+ a(n+k-1) b(n+k-1) . . . z(n+k-1) +
It proves very useful in rsolve_hyper() where it is applied
to a generating set of a recurrence to factor out linearly
dependent solutions and return a basis:
>>> from sympy import Symbol, casoratian, factorial
>>> n = Symbol('n', integer=True)
Exponential and factorial are linearly independent:
>>> casoratian([2**n, factorial(n)], n) != 0
True
"""
seqs = list(map(sympify, seqs))
if not zero:
f = lambda i, j: seqs[j].subs(n, n + i)
else:
f = lambda i, j: seqs[j].subs(n, i)
k = len(seqs)
return Matrix(k, k, f).det()
def eye(*args, **kwargs):
"""Create square identity matrix n x n
See Also
========
diag
zeros
ones
"""
return Matrix.eye(*args, **kwargs)
def diag(*values, **kwargs):
"""Returns a matrix with the provided values placed on the
diagonal. If non-square matrices are included, they will
produce a block-diagonal matrix.
Examples
========
This version of diag is a thin wrapper to Matrix.diag that differs
in that it treats all lists like matrices -- even when a single list
is given. If this is not desired, either put a `*` before the list or
set `unpack=True`.
>>> from sympy import diag
>>> diag([1, 2, 3], unpack=True) # = diag(1,2,3) or diag(*[1,2,3])
Matrix([
[1, 0, 0],
[0, 2, 0],
[0, 0, 3]])
>>> diag([1, 2, 3]) # a column vector
Matrix([
[1],
[2],
[3]])
See Also
========
.common.MatrixCommon.eye
.common.MatrixCommon.diagonal - to extract a diagonal
.common.MatrixCommon.diag
.expressions.blockmatrix.BlockMatrix
"""
# Extract any setting so we don't duplicate keywords sent
# as named parameters:
kw = kwargs.copy()
strict = kw.pop('strict', True) # lists will be converted to Matrices
unpack = kw.pop('unpack', False)
return Matrix.diag(*values, strict=strict, unpack=unpack, **kw)
def GramSchmidt(vlist, orthonormal=False):
"""Apply the Gram-Schmidt process to a set of vectors.
Parameters
==========
vlist : List of Matrix
Vectors to be orthogonalized for.
orthonormal : Bool, optional
If true, return an orthonormal basis.
Returns
=======
vlist : List of Matrix
Orthogonalized vectors
Notes
=====
This routine is mostly duplicate from ``Matrix.orthogonalize``,
except for some difference that this always raises error when
linearly dependent vectors are found, and the keyword ``normalize``
has been named as ``orthonormal`` in this function.
See Also
========
.matrices.MatrixSubspaces.orthogonalize
References
==========
.. [1] https://en.wikipedia.org/wiki/Gram%E2%80%93Schmidt_process
"""
return MutableDenseMatrix.orthogonalize(
*vlist, normalize=orthonormal, rankcheck=True
)
def hessian(f, varlist, constraints=[]):
"""Compute Hessian matrix for a function f wrt parameters in varlist
which may be given as a sequence or a row/column vector. A list of
constraints may optionally be given.
Examples
========
>>> from sympy import Function, hessian, pprint
>>> from sympy.abc import x, y
>>> f = Function('f')(x, y)
>>> g1 = Function('g')(x, y)
>>> g2 = x**2 + 3*y
>>> pprint(hessian(f, (x, y), [g1, g2]))
[ d d ]
[ 0 0 --(g(x, y)) --(g(x, y)) ]
[ dx dy ]
[ ]
[ 0 0 2*x 3 ]
[ ]
[ 2 2 ]
[d d d ]
[--(g(x, y)) 2*x ---(f(x, y)) -----(f(x, y))]
[dx 2 dy dx ]
[ dx ]
[ ]
[ 2 2 ]
[d d d ]
[--(g(x, y)) 3 -----(f(x, y)) ---(f(x, y)) ]
[dy dy dx 2 ]
[ dy ]
References
==========
https://en.wikipedia.org/wiki/Hessian_matrix
See Also
========
sympy.matrices.matrices.MatrixCalculus.jacobian
wronskian
"""
# f is the expression representing a function f, return regular matrix
if isinstance(varlist, MatrixBase):
if 1 not in varlist.shape:
raise ShapeError("`varlist` must be a column or row vector.")
if varlist.cols == 1:
varlist = varlist.T
varlist = varlist.tolist()[0]
if is_sequence(varlist):
n = len(varlist)
if not n:
raise ShapeError("`len(varlist)` must not be zero.")
else:
raise ValueError("Improper variable list in hessian function")
if not getattr(f, 'diff'):
# check differentiability
raise ValueError("Function `f` (%s) is not differentiable" % f)
m = len(constraints)
N = m + n
out = zeros(N)
for k, g in enumerate(constraints):
if not getattr(g, 'diff'):
# check differentiability
raise ValueError("Function `f` (%s) is not differentiable" % f)
for i in range(n):
out[k, i + m] = g.diff(varlist[i])
for i in range(n):
for j in range(i, n):
out[i + m, j + m] = f.diff(varlist[i]).diff(varlist[j])
for i in range(N):
for j in range(i + 1, N):
out[j, i] = out[i, j]
return out
def jordan_cell(eigenval, n):
"""
Create a Jordan block:
Examples
========
>>> from sympy.matrices import jordan_cell
>>> from sympy.abc import x
>>> jordan_cell(x, 4)
Matrix([
[x, 1, 0, 0],
[0, x, 1, 0],
[0, 0, x, 1],
[0, 0, 0, x]])
"""
return Matrix.jordan_block(size=n, eigenvalue=eigenval)
def matrix_multiply_elementwise(A, B):
"""Return the Hadamard product (elementwise product) of A and B
>>> from sympy.matrices import matrix_multiply_elementwise
>>> from sympy.matrices import Matrix
>>> A = Matrix([[0, 1, 2], [3, 4, 5]])
>>> B = Matrix([[1, 10, 100], [100, 10, 1]])
>>> matrix_multiply_elementwise(A, B)
Matrix([
[ 0, 10, 200],
[300, 40, 5]])
See Also
========
sympy.matrices.common.MatrixCommon.__mul__
"""
return A.multiply_elementwise(B)
def ones(*args, **kwargs):
"""Returns a matrix of ones with ``rows`` rows and ``cols`` columns;
if ``cols`` is omitted a square matrix will be returned.
See Also
========
zeros
eye
diag
"""
if 'c' in kwargs:
kwargs['cols'] = kwargs.pop('c')
return Matrix.ones(*args, **kwargs)
def randMatrix(r, c=None, min=0, max=99, seed=None, symmetric=False,
percent=100, prng=None):
"""Create random matrix with dimensions ``r`` x ``c``. If ``c`` is omitted
the matrix will be square. If ``symmetric`` is True the matrix must be
square. If ``percent`` is less than 100 then only approximately the given
percentage of elements will be non-zero.
The pseudo-random number generator used to generate matrix is chosen in the
following way.
* If ``prng`` is supplied, it will be used as random number generator.
It should be an instance of ``random.Random``, or at least have
``randint`` and ``shuffle`` methods with same signatures.
* if ``prng`` is not supplied but ``seed`` is supplied, then new
``random.Random`` with given ``seed`` will be created;
* otherwise, a new ``random.Random`` with default seed will be used.
Examples
========
>>> from sympy.matrices import randMatrix
>>> randMatrix(3) # doctest:+SKIP
[25, 45, 27]
[44, 54, 9]
[23, 96, 46]
>>> randMatrix(3, 2) # doctest:+SKIP
[87, 29]
[23, 37]
[90, 26]
>>> randMatrix(3, 3, 0, 2) # doctest:+SKIP
[0, 2, 0]
[2, 0, 1]
[0, 0, 1]
>>> randMatrix(3, symmetric=True) # doctest:+SKIP
[85, 26, 29]
[26, 71, 43]
[29, 43, 57]
>>> A = randMatrix(3, seed=1)
>>> B = randMatrix(3, seed=2)
>>> A == B
False
>>> A == randMatrix(3, seed=1)
True
>>> randMatrix(3, symmetric=True, percent=50) # doctest:+SKIP
[77, 70, 0],
[70, 0, 0],
[ 0, 0, 88]
"""
if c is None:
c = r
# Note that ``Random()`` is equivalent to ``Random(None)``
prng = prng or random.Random(seed)
if not symmetric:
m = Matrix._new(r, c, lambda i, j: prng.randint(min, max))
if percent == 100:
return m
z = int(r*c*(100 - percent) // 100)
m._mat[:z] = [S.Zero]*z
prng.shuffle(m._mat)
return m
# Symmetric case
if r != c:
raise ValueError('For symmetric matrices, r must equal c, but %i != %i' % (r, c))
m = zeros(r)
ij = [(i, j) for i in range(r) for j in range(i, r)]
if percent != 100:
ij = prng.sample(ij, int(len(ij)*percent // 100))
for i, j in ij:
value = prng.randint(min, max)
m[i, j] = m[j, i] = value
return m
def wronskian(functions, var, method='bareiss'):
"""
Compute Wronskian for [] of functions
::
| f1 f2 ... fn |
| f1' f2' ... fn' |
| . . . . |
W(f1, ..., fn) = | . . . . |
| . . . . |
| (n) (n) (n) |
| D (f1) D (f2) ... D (fn) |
see: https://en.wikipedia.org/wiki/Wronskian
See Also
========
sympy.matrices.matrices.MatrixCalculus.jacobian
hessian
"""
for index in range(0, len(functions)):
functions[index] = sympify(functions[index])
n = len(functions)
if n == 0:
return 1
W = Matrix(n, n, lambda i, j: functions[i].diff(var, j))
return W.det(method)
def zeros(*args, **kwargs):
"""Returns a matrix of zeros with ``rows`` rows and ``cols`` columns;
if ``cols`` is omitted a square matrix will be returned.
See Also
========
ones
eye
diag
"""
if 'c' in kwargs:
kwargs['cols'] = kwargs.pop('c')
return Matrix.zeros(*args, **kwargs)
|
465737bf59dc02d676a91c2442e0e51207186d171db2c6244e4f3afaf13f50e5 | from sympy.core.function import expand_mul
from sympy.core.symbol import Dummy, uniquely_named_symbol, symbols
from sympy.utilities.iterables import numbered_symbols
from .common import ShapeError, NonSquareMatrixError, NonInvertibleMatrixError
from .eigen import _fuzzy_positive_definite
from .utilities import _get_intermediate_simp, _iszero
def _diagonal_solve(M, rhs):
"""Solves ``Ax = B`` efficiently, where A is a diagonal Matrix,
with non-zero diagonal entries.
Examples
========
>>> from sympy.matrices import Matrix, eye
>>> A = eye(2)*2
>>> B = Matrix([[1, 2], [3, 4]])
>>> A.diagonal_solve(B) == B/2
True
See Also
========
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
gauss_jordan_solve
cholesky_solve
LDLsolve
LUsolve
QRsolve
pinv_solve
"""
if not M.is_diagonal():
raise TypeError("Matrix should be diagonal")
if rhs.rows != M.rows:
raise TypeError("Size mis-match")
return M._new(
rhs.rows, rhs.cols, lambda i, j: rhs[i, j] / M[i, i])
def _lower_triangular_solve(M, rhs):
"""Solves ``Ax = B``, where A is a lower triangular matrix.
See Also
========
upper_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv_solve
"""
from .dense import MutableDenseMatrix
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if rhs.rows != M.rows:
raise ShapeError("Matrices size mismatch.")
if not M.is_lower:
raise ValueError("Matrix must be lower triangular.")
dps = _get_intermediate_simp()
X = MutableDenseMatrix.zeros(M.rows, rhs.cols)
for j in range(rhs.cols):
for i in range(M.rows):
if M[i, i] == 0:
raise TypeError("Matrix must be non-singular.")
X[i, j] = dps((rhs[i, j] - sum(M[i, k]*X[k, j]
for k in range(i))) / M[i, i])
return M._new(X)
def _lower_triangular_solve_sparse(M, rhs):
"""Solves ``Ax = B``, where A is a lower triangular matrix.
See Also
========
upper_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv_solve
"""
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if rhs.rows != M.rows:
raise ShapeError("Matrices size mismatch.")
if not M.is_lower:
raise ValueError("Matrix must be lower triangular.")
dps = _get_intermediate_simp()
rows = [[] for i in range(M.rows)]
for i, j, v in M.row_list():
if i > j:
rows[i].append((j, v))
X = rhs.as_mutable()
for j in range(rhs.cols):
for i in range(rhs.rows):
for u, v in rows[i]:
X[i, j] -= v*X[u, j]
X[i, j] = dps(X[i, j] / M[i, i])
return M._new(X)
def _upper_triangular_solve(M, rhs):
"""Solves ``Ax = B``, where A is an upper triangular matrix.
See Also
========
lower_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv_solve
"""
from .dense import MutableDenseMatrix
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if rhs.rows != M.rows:
raise ShapeError("Matrix size mismatch.")
if not M.is_upper:
raise TypeError("Matrix is not upper triangular.")
dps = _get_intermediate_simp()
X = MutableDenseMatrix.zeros(M.rows, rhs.cols)
for j in range(rhs.cols):
for i in reversed(range(M.rows)):
if M[i, i] == 0:
raise ValueError("Matrix must be non-singular.")
X[i, j] = dps((rhs[i, j] - sum(M[i, k]*X[k, j]
for k in range(i + 1, M.rows))) / M[i, i])
return M._new(X)
def _upper_triangular_solve_sparse(M, rhs):
"""Solves ``Ax = B``, where A is an upper triangular matrix.
See Also
========
lower_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv_solve
"""
if not M.is_square:
raise NonSquareMatrixError("Matrix must be square.")
if rhs.rows != M.rows:
raise ShapeError("Matrix size mismatch.")
if not M.is_upper:
raise TypeError("Matrix is not upper triangular.")
dps = _get_intermediate_simp()
rows = [[] for i in range(M.rows)]
for i, j, v in M.row_list():
if i < j:
rows[i].append((j, v))
X = rhs.as_mutable()
for j in range(rhs.cols):
for i in reversed(range(rhs.rows)):
for u, v in reversed(rows[i]):
X[i, j] -= v*X[u, j]
X[i, j] = dps(X[i, j] / M[i, i])
return M._new(X)
def _cholesky_solve(M, rhs):
"""Solves ``Ax = B`` using Cholesky decomposition,
for a general square non-singular matrix.
For a non-square matrix with rows > cols,
the least squares solution is returned.
See Also
========
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
gauss_jordan_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv_solve
"""
if M.rows < M.cols:
raise NotImplementedError(
'Under-determined System. Try M.gauss_jordan_solve(rhs)')
hermitian = True
reform = False
if M.is_symmetric():
hermitian = False
elif not M.is_hermitian:
reform = True
if reform or _fuzzy_positive_definite(M) is False:
H = M.H
M = H.multiply(M)
rhs = H.multiply(rhs)
hermitian = not M.is_symmetric()
L = M.cholesky(hermitian=hermitian)
Y = L.lower_triangular_solve(rhs)
if hermitian:
return (L.H).upper_triangular_solve(Y)
else:
return (L.T).upper_triangular_solve(Y)
def _LDLsolve(M, rhs):
"""Solves ``Ax = B`` using LDL decomposition,
for a general square and non-singular matrix.
For a non-square matrix with rows > cols,
the least squares solution is returned.
Examples
========
>>> from sympy.matrices import Matrix, eye
>>> A = eye(2)*2
>>> B = Matrix([[1, 2], [3, 4]])
>>> A.LDLsolve(B) == B/2
True
See Also
========
sympy.matrices.dense.DenseMatrix.LDLdecomposition
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LUsolve
QRsolve
pinv_solve
"""
if M.rows < M.cols:
raise NotImplementedError(
'Under-determined System. Try M.gauss_jordan_solve(rhs)')
hermitian = True
reform = False
if M.is_symmetric():
hermitian = False
elif not M.is_hermitian:
reform = True
if reform or _fuzzy_positive_definite(M) is False:
H = M.H
M = H.multiply(M)
rhs = H.multiply(rhs)
hermitian = not M.is_symmetric()
L, D = M.LDLdecomposition(hermitian=hermitian)
Y = L.lower_triangular_solve(rhs)
Z = D.diagonal_solve(Y)
if hermitian:
return (L.H).upper_triangular_solve(Z)
else:
return (L.T).upper_triangular_solve(Z)
def _LUsolve(M, rhs, iszerofunc=_iszero):
"""Solve the linear system ``Ax = rhs`` for ``x`` where ``A = M``.
This is for symbolic matrices, for real or complex ones use
mpmath.lu_solve or mpmath.qr_solve.
See Also
========
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
QRsolve
pinv_solve
LUdecomposition
"""
if rhs.rows != M.rows:
raise ShapeError(
"``M`` and ``rhs`` must have the same number of rows.")
m = M.rows
n = M.cols
if m < n:
raise NotImplementedError("Underdetermined systems not supported.")
try:
A, perm = M.LUdecomposition_Simple(
iszerofunc=_iszero, rankcheck=True)
except ValueError:
raise NonInvertibleMatrixError("Matrix det == 0; not invertible.")
dps = _get_intermediate_simp()
b = rhs.permute_rows(perm).as_mutable()
# forward substitution, all diag entries are scaled to 1
for i in range(m):
for j in range(min(i, n)):
scale = A[i, j]
b.zip_row_op(i, j, lambda x, y: dps(x - y * scale))
# consistency check for overdetermined systems
if m > n:
for i in range(n, m):
for j in range(b.cols):
if not iszerofunc(b[i, j]):
raise ValueError("The system is inconsistent.")
b = b[0:n, :] # truncate zero rows if consistent
# backward substitution
for i in range(n - 1, -1, -1):
for j in range(i + 1, n):
scale = A[i, j]
b.zip_row_op(i, j, lambda x, y: dps(x - y * scale))
scale = A[i, i]
b.row_op(i, lambda x, _: dps(x / scale))
return rhs.__class__(b)
def _QRsolve(M, b):
"""Solve the linear system ``Ax = b``.
``M`` is the matrix ``A``, the method argument is the vector
``b``. The method returns the solution vector ``x``. If ``b`` is a
matrix, the system is solved for each column of ``b`` and the
return value is a matrix of the same shape as ``b``.
This method is slower (approximately by a factor of 2) but
more stable for floating-point arithmetic than the LUsolve method.
However, LUsolve usually uses an exact arithmetic, so you don't need
to use QRsolve.
This is mainly for educational purposes and symbolic matrices, for real
(or complex) matrices use mpmath.qr_solve.
See Also
========
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
pinv_solve
QRdecomposition
"""
dps = _get_intermediate_simp(expand_mul, expand_mul)
Q, R = M.QRdecomposition()
y = Q.T * b
# back substitution to solve R*x = y:
# We build up the result "backwards" in the vector 'x' and reverse it
# only in the end.
x = []
n = R.rows
for j in range(n - 1, -1, -1):
tmp = y[j, :]
for k in range(j + 1, n):
tmp -= R[j, k] * x[n - 1 - k]
tmp = dps(tmp)
x.append(tmp / R[j, j])
return M._new([row._mat for row in reversed(x)])
def _gauss_jordan_solve(M, B, freevar=False):
"""
Solves ``Ax = B`` using Gauss Jordan elimination.
There may be zero, one, or infinite solutions. If one solution
exists, it will be returned. If infinite solutions exist, it will
be returned parametrically. If no solutions exist, It will throw
ValueError.
Parameters
==========
B : Matrix
The right hand side of the equation to be solved for. Must have
the same number of rows as matrix A.
freevar : List
If the system is underdetermined (e.g. A has more columns than
rows), infinite solutions are possible, in terms of arbitrary
values of free variables. Then the index of the free variables
in the solutions (column Matrix) will be returned by freevar, if
the flag `freevar` is set to `True`.
Returns
=======
x : Matrix
The matrix that will satisfy ``Ax = B``. Will have as many rows as
matrix A has columns, and as many columns as matrix B.
params : Matrix
If the system is underdetermined (e.g. A has more columns than
rows), infinite solutions are possible, in terms of arbitrary
parameters. These arbitrary parameters are returned as params
Matrix.
Examples
========
>>> from sympy import Matrix
>>> A = Matrix([[1, 2, 1, 1], [1, 2, 2, -1], [2, 4, 0, 6]])
>>> B = Matrix([7, 12, 4])
>>> sol, params = A.gauss_jordan_solve(B)
>>> sol
Matrix([
[-2*tau0 - 3*tau1 + 2],
[ tau0],
[ 2*tau1 + 5],
[ tau1]])
>>> params
Matrix([
[tau0],
[tau1]])
>>> taus_zeroes = { tau:0 for tau in params }
>>> sol_unique = sol.xreplace(taus_zeroes)
>>> sol_unique
Matrix([
[2],
[0],
[5],
[0]])
>>> A = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 10]])
>>> B = Matrix([3, 6, 9])
>>> sol, params = A.gauss_jordan_solve(B)
>>> sol
Matrix([
[-1],
[ 2],
[ 0]])
>>> params
Matrix(0, 1, [])
>>> A = Matrix([[2, -7], [-1, 4]])
>>> B = Matrix([[-21, 3], [12, -2]])
>>> sol, params = A.gauss_jordan_solve(B)
>>> sol
Matrix([
[0, -2],
[3, -1]])
>>> params
Matrix(0, 2, [])
See Also
========
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv
References
==========
.. [1] https://en.wikipedia.org/wiki/Gaussian_elimination
"""
from sympy.matrices import Matrix, zeros
cls = M.__class__
aug = M.hstack(M.copy(), B.copy())
B_cols = B.cols
row, col = aug[:, :-B_cols].shape
# solve by reduced row echelon form
A, pivots = aug.rref(simplify=True)
A, v = A[:, :-B_cols], A[:, -B_cols:]
pivots = list(filter(lambda p: p < col, pivots))
rank = len(pivots)
# Bring to block form
permutation = Matrix(range(col)).T
for i, c in enumerate(pivots):
permutation.col_swap(i, c)
# check for existence of solutions
# rank of aug Matrix should be equal to rank of coefficient matrix
if not v[rank:, :].is_zero_matrix:
raise ValueError("Linear system has no solution")
# Get index of free symbols (free parameters)
# non-pivots columns are free variables
free_var_index = permutation[len(pivots):]
# Free parameters
# what are current unnumbered free symbol names?
name = uniquely_named_symbol('tau', aug,
compare=lambda i: str(i).rstrip('1234567890'),
modify=lambda s: '_' + s).name
gen = numbered_symbols(name)
tau = Matrix([next(gen) for k in range((col - rank)*B_cols)]).reshape(
col - rank, B_cols)
# Full parametric solution
V = A[:rank, [c for c in range(A.cols) if c not in pivots]]
vt = v[:rank, :]
free_sol = tau.vstack(vt - V * tau, tau)
# Undo permutation
sol = zeros(col, B_cols)
for k in range(col):
sol[permutation[k], :] = free_sol[k,:]
sol, tau = cls(sol), cls(tau)
if freevar:
return sol, tau, free_var_index
else:
return sol, tau
def _pinv_solve(M, B, arbitrary_matrix=None):
"""Solve ``Ax = B`` using the Moore-Penrose pseudoinverse.
There may be zero, one, or infinite solutions. If one solution
exists, it will be returned. If infinite solutions exist, one will
be returned based on the value of arbitrary_matrix. If no solutions
exist, the least-squares solution is returned.
Parameters
==========
B : Matrix
The right hand side of the equation to be solved for. Must have
the same number of rows as matrix A.
arbitrary_matrix : Matrix
If the system is underdetermined (e.g. A has more columns than
rows), infinite solutions are possible, in terms of an arbitrary
matrix. This parameter may be set to a specific matrix to use
for that purpose; if so, it must be the same shape as x, with as
many rows as matrix A has columns, and as many columns as matrix
B. If left as None, an appropriate matrix containing dummy
symbols in the form of ``wn_m`` will be used, with n and m being
row and column position of each symbol.
Returns
=======
x : Matrix
The matrix that will satisfy ``Ax = B``. Will have as many rows as
matrix A has columns, and as many columns as matrix B.
Examples
========
>>> from sympy import Matrix
>>> A = Matrix([[1, 2, 3], [4, 5, 6]])
>>> B = Matrix([7, 8])
>>> A.pinv_solve(B)
Matrix([
[ _w0_0/6 - _w1_0/3 + _w2_0/6 - 55/18],
[-_w0_0/3 + 2*_w1_0/3 - _w2_0/3 + 1/9],
[ _w0_0/6 - _w1_0/3 + _w2_0/6 + 59/18]])
>>> A.pinv_solve(B, arbitrary_matrix=Matrix([0, 0, 0]))
Matrix([
[-55/18],
[ 1/9],
[ 59/18]])
See Also
========
sympy.matrices.dense.DenseMatrix.lower_triangular_solve
sympy.matrices.dense.DenseMatrix.upper_triangular_solve
gauss_jordan_solve
cholesky_solve
diagonal_solve
LDLsolve
LUsolve
QRsolve
pinv
Notes
=====
This may return either exact solutions or least squares solutions.
To determine which, check ``A * A.pinv() * B == B``. It will be
True if exact solutions exist, and False if only a least-squares
solution exists. Be aware that the left hand side of that equation
may need to be simplified to correctly compare to the right hand
side.
References
==========
.. [1] https://en.wikipedia.org/wiki/Moore-Penrose_pseudoinverse#Obtaining_all_solutions_of_a_linear_system
"""
from sympy.matrices import eye
A = M
A_pinv = M.pinv()
if arbitrary_matrix is None:
rows, cols = A.cols, B.cols
w = symbols('w:{}_:{}'.format(rows, cols), cls=Dummy)
arbitrary_matrix = M.__class__(cols, rows, w).T
return A_pinv.multiply(B) + (eye(A.cols) -
A_pinv.multiply(A)).multiply(arbitrary_matrix)
def _solve(M, rhs, method='GJ'):
"""Solves linear equation where the unique solution exists.
Parameters
==========
rhs : Matrix
Vector representing the right hand side of the linear equation.
method : string, optional
If set to ``'GJ'`` or ``'GE'``, the Gauss-Jordan elimination will be
used, which is implemented in the routine ``gauss_jordan_solve``.
If set to ``'LU'``, ``LUsolve`` routine will be used.
If set to ``'QR'``, ``QRsolve`` routine will be used.
If set to ``'PINV'``, ``pinv_solve`` routine will be used.
It also supports the methods available for special linear systems
For positive definite systems:
If set to ``'CH'``, ``cholesky_solve`` routine will be used.
If set to ``'LDL'``, ``LDLsolve`` routine will be used.
To use a different method and to compute the solution via the
inverse, use a method defined in the .inv() docstring.
Returns
=======
solutions : Matrix
Vector representing the solution.
Raises
======
ValueError
If there is not a unique solution then a ``ValueError`` will be
raised.
If ``M`` is not square, a ``ValueError`` and a different routine
for solving the system will be suggested.
"""
if method == 'GJ' or method == 'GE':
try:
soln, param = M.gauss_jordan_solve(rhs)
if param:
raise NonInvertibleMatrixError("Matrix det == 0; not invertible. "
"Try ``M.gauss_jordan_solve(rhs)`` to obtain a parametric solution.")
except ValueError:
raise NonInvertibleMatrixError("Matrix det == 0; not invertible.")
return soln
elif method == 'LU':
return M.LUsolve(rhs)
elif method == 'CH':
return M.cholesky_solve(rhs)
elif method == 'QR':
return M.QRsolve(rhs)
elif method == 'LDL':
return M.LDLsolve(rhs)
elif method == 'PINV':
return M.pinv_solve(rhs)
else:
return M.inv(method=method).multiply(rhs)
def _solve_least_squares(M, rhs, method='CH'):
"""Return the least-square fit to the data.
Parameters
==========
rhs : Matrix
Vector representing the right hand side of the linear equation.
method : string or boolean, optional
If set to ``'CH'``, ``cholesky_solve`` routine will be used.
If set to ``'LDL'``, ``LDLsolve`` routine will be used.
If set to ``'QR'``, ``QRsolve`` routine will be used.
If set to ``'PINV'``, ``pinv_solve`` routine will be used.
Otherwise, the conjugate of ``M`` will be used to create a system
of equations that is passed to ``solve`` along with the hint
defined by ``method``.
Returns
=======
solutions : Matrix
Vector representing the solution.
Examples
========
>>> from sympy.matrices import Matrix, ones
>>> A = Matrix([1, 2, 3])
>>> B = Matrix([2, 3, 4])
>>> S = Matrix(A.row_join(B))
>>> S
Matrix([
[1, 2],
[2, 3],
[3, 4]])
If each line of S represent coefficients of Ax + By
and x and y are [2, 3] then S*xy is:
>>> r = S*Matrix([2, 3]); r
Matrix([
[ 8],
[13],
[18]])
But let's add 1 to the middle value and then solve for the
least-squares value of xy:
>>> xy = S.solve_least_squares(Matrix([8, 14, 18])); xy
Matrix([
[ 5/3],
[10/3]])
The error is given by S*xy - r:
>>> S*xy - r
Matrix([
[1/3],
[1/3],
[1/3]])
>>> _.norm().n(2)
0.58
If a different xy is used, the norm will be higher:
>>> xy += ones(2, 1)/10
>>> (S*xy - r).norm().n(2)
1.5
"""
if method == 'CH':
return M.cholesky_solve(rhs)
elif method == 'QR':
return M.QRsolve(rhs)
elif method == 'LDL':
return M.LDLsolve(rhs)
elif method == 'PINV':
return M.pinv_solve(rhs)
else:
t = M.H
return (t * M).solve(t * rhs, method=method)
|
b25952dd3a1000f33032fee29901dbce75ef27aa119e29b3f0b3b97b4b87fb89 | from typing import Any
import mpmath as mp
from sympy.core.add import Add
from sympy.core.basic import Basic
from sympy.core.compatibility import (
Callable, NotIterable, as_int, is_sequence)
from sympy.core.decorators import deprecated
from sympy.core.expr import Expr
from sympy.core.power import Pow
from sympy.core.singleton import S
from sympy.core.symbol import Dummy, Symbol, uniquely_named_symbol
from sympy.core.sympify import sympify
from sympy.functions import exp, factorial, log
from sympy.functions.elementary.miscellaneous import Max, Min, sqrt
from sympy.functions.special.tensor_functions import KroneckerDelta
from sympy.polys import cancel
from sympy.printing import sstr
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
from .common import (
MatrixCommon, MatrixError, NonSquareMatrixError, NonInvertibleMatrixError,
ShapeError)
from .utilities import _iszero, _is_zero_after_expand_mul
from .determinant import (
_find_reasonable_pivot, _find_reasonable_pivot_naive,
_adjugate, _charpoly, _cofactor, _cofactor_matrix,
_det, _det_bareiss, _det_berkowitz, _det_LU, _minor, _minor_submatrix)
from .reductions import _is_echelon, _echelon_form, _rank, _rref
from .subspaces import _columnspace, _nullspace, _rowspace, _orthogonalize
from .eigen import (
_eigenvals, _eigenvects,
_bidiagonalize, _bidiagonal_decomposition,
_is_diagonalizable, _diagonalize,
_is_positive_definite, _is_positive_semidefinite,
_is_negative_definite, _is_negative_semidefinite, _is_indefinite,
_jordan_form, _left_eigenvects, _singular_values)
from .decompositions import (
_rank_decomposition, _cholesky, _LDLdecomposition,
_LUdecomposition, _LUdecomposition_Simple, _LUdecompositionFF,
_QRdecomposition)
from .graph import _connected_components, _connected_components_decomposition
from .solvers import (
_diagonal_solve, _lower_triangular_solve, _upper_triangular_solve,
_cholesky_solve, _LDLsolve, _LUsolve, _QRsolve, _gauss_jordan_solve,
_pinv_solve, _solve, _solve_least_squares)
from .inverse import (
_pinv, _inv_mod, _inv_ADJ, _inv_GE, _inv_LU, _inv_CH, _inv_LDL, _inv_QR,
_inv, _inv_block)
class DeferredVector(Symbol, NotIterable):
"""A vector whose components are deferred (e.g. for use with lambdify)
Examples
========
>>> from sympy import DeferredVector, lambdify
>>> X = DeferredVector( 'X' )
>>> X
X
>>> expr = (X[0] + 2, X[2] + 3)
>>> func = lambdify( X, expr)
>>> func( [1, 2, 3] )
(3, 6)
"""
def __getitem__(self, i):
if i == -0:
i = 0
if i < 0:
raise IndexError('DeferredVector index out of range')
component_name = '%s[%d]' % (self.name, i)
return Symbol(component_name)
def __str__(self):
return sstr(self)
def __repr__(self):
return "DeferredVector('%s')" % self.name
class MatrixDeterminant(MatrixCommon):
"""Provides basic matrix determinant operations. Should not be instantiated
directly. See ``determinant.py`` for their implementations."""
def _eval_det_bareiss(self, iszerofunc=_is_zero_after_expand_mul):
return _det_bareiss(self, iszerofunc=iszerofunc)
def _eval_det_berkowitz(self):
return _det_berkowitz(self)
def _eval_det_lu(self, iszerofunc=_iszero, simpfunc=None):
return _det_LU(self, iszerofunc=iszerofunc, simpfunc=simpfunc)
def _eval_determinant(self): # for expressions.determinant.Determinant
return _det(self)
def adjugate(self, method="berkowitz"):
return _adjugate(self, method=method)
def charpoly(self, x='lambda', simplify=_simplify):
return _charpoly(self, x=x, simplify=simplify)
def cofactor(self, i, j, method="berkowitz"):
return _cofactor(self, i, j, method=method)
def cofactor_matrix(self, method="berkowitz"):
return _cofactor_matrix(self, method=method)
def det(self, method="bareiss", iszerofunc=None):
return _det(self, method=method, iszerofunc=iszerofunc)
def minor(self, i, j, method="berkowitz"):
return _minor(self, i, j, method=method)
def minor_submatrix(self, i, j):
return _minor_submatrix(self, i, j)
_find_reasonable_pivot.__doc__ = _find_reasonable_pivot.__doc__
_find_reasonable_pivot_naive.__doc__ = _find_reasonable_pivot_naive.__doc__
_eval_det_bareiss.__doc__ = _det_bareiss.__doc__
_eval_det_berkowitz.__doc__ = _det_berkowitz.__doc__
_eval_det_lu.__doc__ = _det_LU.__doc__
_eval_determinant.__doc__ = _det.__doc__
adjugate.__doc__ = _adjugate.__doc__
charpoly.__doc__ = _charpoly.__doc__
cofactor.__doc__ = _cofactor.__doc__
cofactor_matrix.__doc__ = _cofactor_matrix.__doc__
det.__doc__ = _det.__doc__
minor.__doc__ = _minor.__doc__
minor_submatrix.__doc__ = _minor_submatrix.__doc__
class MatrixReductions(MatrixDeterminant):
"""Provides basic matrix row/column operations. Should not be instantiated
directly. See ``reductions.py`` for some of their implementations."""
def echelon_form(self, iszerofunc=_iszero, simplify=False, with_pivots=False):
return _echelon_form(self, iszerofunc=iszerofunc, simplify=simplify,
with_pivots=with_pivots)
@property
def is_echelon(self):
return _is_echelon(self)
def rank(self, iszerofunc=_iszero, simplify=False):
return _rank(self, iszerofunc=iszerofunc, simplify=simplify)
def rref(self, iszerofunc=_iszero, simplify=False, pivots=True,
normalize_last=True):
return _rref(self, iszerofunc=iszerofunc, simplify=simplify,
pivots=pivots, normalize_last=normalize_last)
echelon_form.__doc__ = _echelon_form.__doc__
is_echelon.__doc__ = _is_echelon.__doc__
rank.__doc__ = _rank.__doc__
rref.__doc__ = _rref.__doc__
def _normalize_op_args(self, op, col, k, col1, col2, error_str="col"):
"""Validate the arguments for a row/column operation. ``error_str``
can be one of "row" or "col" depending on the arguments being parsed."""
if op not in ["n->kn", "n<->m", "n->n+km"]:
raise ValueError("Unknown {} operation '{}'. Valid col operations "
"are 'n->kn', 'n<->m', 'n->n+km'".format(error_str, op))
# define self_col according to error_str
self_cols = self.cols if error_str == 'col' else self.rows
# normalize and validate the arguments
if op == "n->kn":
col = col if col is not None else col1
if col is None or k is None:
raise ValueError("For a {0} operation 'n->kn' you must provide the "
"kwargs `{0}` and `k`".format(error_str))
if not 0 <= col < self_cols:
raise ValueError("This matrix doesn't have a {} '{}'".format(error_str, col))
elif op == "n<->m":
# we need two cols to swap. It doesn't matter
# how they were specified, so gather them together and
# remove `None`
cols = {col, k, col1, col2}.difference([None])
if len(cols) > 2:
# maybe the user left `k` by mistake?
cols = {col, col1, col2}.difference([None])
if len(cols) != 2:
raise ValueError("For a {0} operation 'n<->m' you must provide the "
"kwargs `{0}1` and `{0}2`".format(error_str))
col1, col2 = cols
if not 0 <= col1 < self_cols:
raise ValueError("This matrix doesn't have a {} '{}'".format(error_str, col1))
if not 0 <= col2 < self_cols:
raise ValueError("This matrix doesn't have a {} '{}'".format(error_str, col2))
elif op == "n->n+km":
col = col1 if col is None else col
col2 = col1 if col2 is None else col2
if col is None or col2 is None or k is None:
raise ValueError("For a {0} operation 'n->n+km' you must provide the "
"kwargs `{0}`, `k`, and `{0}2`".format(error_str))
if col == col2:
raise ValueError("For a {0} operation 'n->n+km' `{0}` and `{0}2` must "
"be different.".format(error_str))
if not 0 <= col < self_cols:
raise ValueError("This matrix doesn't have a {} '{}'".format(error_str, col))
if not 0 <= col2 < self_cols:
raise ValueError("This matrix doesn't have a {} '{}'".format(error_str, col2))
else:
raise ValueError('invalid operation %s' % repr(op))
return op, col, k, col1, col2
def _eval_col_op_multiply_col_by_const(self, col, k):
def entry(i, j):
if j == col:
return k * self[i, j]
return self[i, j]
return self._new(self.rows, self.cols, entry)
def _eval_col_op_swap(self, col1, col2):
def entry(i, j):
if j == col1:
return self[i, col2]
elif j == col2:
return self[i, col1]
return self[i, j]
return self._new(self.rows, self.cols, entry)
def _eval_col_op_add_multiple_to_other_col(self, col, k, col2):
def entry(i, j):
if j == col:
return self[i, j] + k * self[i, col2]
return self[i, j]
return self._new(self.rows, self.cols, entry)
def _eval_row_op_swap(self, row1, row2):
def entry(i, j):
if i == row1:
return self[row2, j]
elif i == row2:
return self[row1, j]
return self[i, j]
return self._new(self.rows, self.cols, entry)
def _eval_row_op_multiply_row_by_const(self, row, k):
def entry(i, j):
if i == row:
return k * self[i, j]
return self[i, j]
return self._new(self.rows, self.cols, entry)
def _eval_row_op_add_multiple_to_other_row(self, row, k, row2):
def entry(i, j):
if i == row:
return self[i, j] + k * self[row2, j]
return self[i, j]
return self._new(self.rows, self.cols, entry)
def elementary_col_op(self, op="n->kn", col=None, k=None, col1=None, col2=None):
"""Performs the elementary column operation `op`.
`op` may be one of
* "n->kn" (column n goes to k*n)
* "n<->m" (swap column n and column m)
* "n->n+km" (column n goes to column n + k*column m)
Parameters
==========
op : string; the elementary row operation
col : the column to apply the column operation
k : the multiple to apply in the column operation
col1 : one column of a column swap
col2 : second column of a column swap or column "m" in the column operation
"n->n+km"
"""
op, col, k, col1, col2 = self._normalize_op_args(op, col, k, col1, col2, "col")
# now that we've validated, we're all good to dispatch
if op == "n->kn":
return self._eval_col_op_multiply_col_by_const(col, k)
if op == "n<->m":
return self._eval_col_op_swap(col1, col2)
if op == "n->n+km":
return self._eval_col_op_add_multiple_to_other_col(col, k, col2)
def elementary_row_op(self, op="n->kn", row=None, k=None, row1=None, row2=None):
"""Performs the elementary row operation `op`.
`op` may be one of
* "n->kn" (row n goes to k*n)
* "n<->m" (swap row n and row m)
* "n->n+km" (row n goes to row n + k*row m)
Parameters
==========
op : string; the elementary row operation
row : the row to apply the row operation
k : the multiple to apply in the row operation
row1 : one row of a row swap
row2 : second row of a row swap or row "m" in the row operation
"n->n+km"
"""
op, row, k, row1, row2 = self._normalize_op_args(op, row, k, row1, row2, "row")
# now that we've validated, we're all good to dispatch
if op == "n->kn":
return self._eval_row_op_multiply_row_by_const(row, k)
if op == "n<->m":
return self._eval_row_op_swap(row1, row2)
if op == "n->n+km":
return self._eval_row_op_add_multiple_to_other_row(row, k, row2)
class MatrixSubspaces(MatrixReductions):
"""Provides methods relating to the fundamental subspaces of a matrix.
Should not be instantiated directly. See ``subspaces.py`` for their
implementations."""
def columnspace(self, simplify=False):
return _columnspace(self, simplify=simplify)
def nullspace(self, simplify=False, iszerofunc=_iszero):
return _nullspace(self, simplify=simplify, iszerofunc=iszerofunc)
def rowspace(self, simplify=False):
return _rowspace(self, simplify=simplify)
# This is a classmethod but is converted to such later in order to allow
# assignment of __doc__ since that does not work for already wrapped
# classmethods in Python 3.6.
def orthogonalize(cls, *vecs, **kwargs):
return _orthogonalize(cls, *vecs, **kwargs)
columnspace.__doc__ = _columnspace.__doc__
nullspace.__doc__ = _nullspace.__doc__
rowspace.__doc__ = _rowspace.__doc__
orthogonalize.__doc__ = _orthogonalize.__doc__
orthogonalize = classmethod(orthogonalize)
class MatrixEigen(MatrixSubspaces):
"""Provides basic matrix eigenvalue/vector operations.
Should not be instantiated directly. See ``eigen.py`` for their
implementations."""
def eigenvals(self, error_when_incomplete=True, **flags):
return _eigenvals(self, error_when_incomplete=error_when_incomplete, **flags)
def eigenvects(self, error_when_incomplete=True, iszerofunc=_iszero, **flags):
return _eigenvects(self, error_when_incomplete=error_when_incomplete,
iszerofunc=iszerofunc, **flags)
def is_diagonalizable(self, reals_only=False, **kwargs):
return _is_diagonalizable(self, reals_only=reals_only, **kwargs)
def diagonalize(self, reals_only=False, sort=False, normalize=False):
return _diagonalize(self, reals_only=reals_only, sort=sort,
normalize=normalize)
def bidiagonalize(self, upper=True):
return _bidiagonalize(self, upper=upper)
def bidiagonal_decomposition(self, upper=True):
return _bidiagonal_decomposition(self, upper=upper)
@property
def is_positive_definite(self):
return _is_positive_definite(self)
@property
def is_positive_semidefinite(self):
return _is_positive_semidefinite(self)
@property
def is_negative_definite(self):
return _is_negative_definite(self)
@property
def is_negative_semidefinite(self):
return _is_negative_semidefinite(self)
@property
def is_indefinite(self):
return _is_indefinite(self)
def jordan_form(self, calc_transform=True, **kwargs):
return _jordan_form(self, calc_transform=calc_transform, **kwargs)
def left_eigenvects(self, **flags):
return _left_eigenvects(self, **flags)
def singular_values(self):
return _singular_values(self)
eigenvals.__doc__ = _eigenvals.__doc__
eigenvects.__doc__ = _eigenvects.__doc__
is_diagonalizable.__doc__ = _is_diagonalizable.__doc__
diagonalize.__doc__ = _diagonalize.__doc__
is_positive_definite.__doc__ = _is_positive_definite.__doc__
is_positive_semidefinite.__doc__ = _is_positive_semidefinite.__doc__
is_negative_definite.__doc__ = _is_negative_definite.__doc__
is_negative_semidefinite.__doc__ = _is_negative_semidefinite.__doc__
is_indefinite.__doc__ = _is_indefinite.__doc__
jordan_form.__doc__ = _jordan_form.__doc__
left_eigenvects.__doc__ = _left_eigenvects.__doc__
singular_values.__doc__ = _singular_values.__doc__
bidiagonalize.__doc__ = _bidiagonalize.__doc__
bidiagonal_decomposition.__doc__ = _bidiagonal_decomposition.__doc__
class MatrixCalculus(MatrixCommon):
"""Provides calculus-related matrix operations."""
def diff(self, *args, **kwargs):
"""Calculate the derivative of each element in the matrix.
``args`` will be passed to the ``integrate`` function.
Examples
========
>>> from sympy.matrices import Matrix
>>> from sympy.abc import x, y
>>> M = Matrix([[x, y], [1, 0]])
>>> M.diff(x)
Matrix([
[1, 0],
[0, 0]])
See Also
========
integrate
limit
"""
# XXX this should be handled here rather than in Derivative
from sympy import Derivative
kwargs.setdefault('evaluate', True)
deriv = Derivative(self, *args, evaluate=True)
if not isinstance(self, Basic):
return deriv.as_mutable()
else:
return deriv
def _eval_derivative(self, arg):
return self.applyfunc(lambda x: x.diff(arg))
def _accept_eval_derivative(self, s):
return s._visit_eval_derivative_array(self)
def _visit_eval_derivative_scalar(self, base):
# Types are (base: scalar, self: matrix)
return self.applyfunc(lambda x: base.diff(x))
def _visit_eval_derivative_array(self, base):
# Types are (base: array/matrix, self: matrix)
from sympy import derive_by_array
return derive_by_array(base, self)
def integrate(self, *args, **kwargs):
"""Integrate each element of the matrix. ``args`` will
be passed to the ``integrate`` function.
Examples
========
>>> from sympy.matrices import Matrix
>>> from sympy.abc import x, y
>>> M = Matrix([[x, y], [1, 0]])
>>> M.integrate((x, ))
Matrix([
[x**2/2, x*y],
[ x, 0]])
>>> M.integrate((x, 0, 2))
Matrix([
[2, 2*y],
[2, 0]])
See Also
========
limit
diff
"""
return self.applyfunc(lambda x: x.integrate(*args, **kwargs))
def jacobian(self, X):
"""Calculates the Jacobian matrix (derivative of a vector-valued function).
Parameters
==========
``self`` : vector of expressions representing functions f_i(x_1, ..., x_n).
X : set of x_i's in order, it can be a list or a Matrix
Both ``self`` and X can be a row or a column matrix in any order
(i.e., jacobian() should always work).
Examples
========
>>> from sympy import sin, cos, Matrix
>>> from sympy.abc import rho, phi
>>> X = Matrix([rho*cos(phi), rho*sin(phi), rho**2])
>>> Y = Matrix([rho, phi])
>>> X.jacobian(Y)
Matrix([
[cos(phi), -rho*sin(phi)],
[sin(phi), rho*cos(phi)],
[ 2*rho, 0]])
>>> X = Matrix([rho*cos(phi), rho*sin(phi)])
>>> X.jacobian(Y)
Matrix([
[cos(phi), -rho*sin(phi)],
[sin(phi), rho*cos(phi)]])
See Also
========
hessian
wronskian
"""
if not isinstance(X, MatrixBase):
X = self._new(X)
# Both X and ``self`` can be a row or a column matrix, so we need to make
# sure all valid combinations work, but everything else fails:
if self.shape[0] == 1:
m = self.shape[1]
elif self.shape[1] == 1:
m = self.shape[0]
else:
raise TypeError("``self`` must be a row or a column matrix")
if X.shape[0] == 1:
n = X.shape[1]
elif X.shape[1] == 1:
n = X.shape[0]
else:
raise TypeError("X must be a row or a column matrix")
# m is the number of functions and n is the number of variables
# computing the Jacobian is now easy:
return self._new(m, n, lambda j, i: self[j].diff(X[i]))
def limit(self, *args):
"""Calculate the limit of each element in the matrix.
``args`` will be passed to the ``limit`` function.
Examples
========
>>> from sympy.matrices import Matrix
>>> from sympy.abc import x, y
>>> M = Matrix([[x, y], [1, 0]])
>>> M.limit(x, 2)
Matrix([
[2, y],
[1, 0]])
See Also
========
integrate
diff
"""
return self.applyfunc(lambda x: x.limit(*args))
# https://github.com/sympy/sympy/pull/12854
class MatrixDeprecated(MatrixCommon):
"""A class to house deprecated matrix methods."""
def _legacy_array_dot(self, b):
"""Compatibility function for deprecated behavior of ``matrix.dot(vector)``
"""
from .dense import Matrix
if not isinstance(b, MatrixBase):
if is_sequence(b):
if len(b) != self.cols and len(b) != self.rows:
raise ShapeError(
"Dimensions incorrect for dot product: %s, %s" % (
self.shape, len(b)))
return self.dot(Matrix(b))
else:
raise TypeError(
"`b` must be an ordered iterable or Matrix, not %s." %
type(b))
mat = self
if mat.cols == b.rows:
if b.cols != 1:
mat = mat.T
b = b.T
prod = flatten((mat * b).tolist())
return prod
if mat.cols == b.cols:
return mat.dot(b.T)
elif mat.rows == b.rows:
return mat.T.dot(b)
else:
raise ShapeError("Dimensions incorrect for dot product: %s, %s" % (
self.shape, b.shape))
def berkowitz_charpoly(self, x=Dummy('lambda'), simplify=_simplify):
return self.charpoly(x=x)
def berkowitz_det(self):
"""Computes determinant using Berkowitz method.
See Also
========
det
berkowitz
"""
return self.det(method='berkowitz')
def berkowitz_eigenvals(self, **flags):
"""Computes eigenvalues of a Matrix using Berkowitz method.
See Also
========
berkowitz
"""
return self.eigenvals(**flags)
def berkowitz_minors(self):
"""Computes principal minors using Berkowitz method.
See Also
========
berkowitz
"""
sign, minors = self.one, []
for poly in self.berkowitz():
minors.append(sign * poly[-1])
sign = -sign
return tuple(minors)
def berkowitz(self):
from sympy.matrices import zeros
berk = ((1,),)
if not self:
return berk
if not self.is_square:
raise NonSquareMatrixError()
A, N = self, self.rows
transforms = [0] * (N - 1)
for n in range(N, 1, -1):
T, k = zeros(n + 1, n), n - 1
R, C = -A[k, :k], A[:k, k]
A, a = A[:k, :k], -A[k, k]
items = [C]
for i in range(0, n - 2):
items.append(A * items[i])
for i, B in enumerate(items):
items[i] = (R * B)[0, 0]
items = [self.one, a] + items
for i in range(n):
T[i:, i] = items[:n - i + 1]
transforms[k - 1] = T
polys = [self._new([self.one, -A[0, 0]])]
for i, T in enumerate(transforms):
polys.append(T * polys[i])
return berk + tuple(map(tuple, polys))
def cofactorMatrix(self, method="berkowitz"):
return self.cofactor_matrix(method=method)
def det_bareis(self):
return _det_bareiss(self)
def det_LU_decomposition(self):
"""Compute matrix determinant using LU decomposition
Note that this method fails if the LU decomposition itself
fails. In particular, if the matrix has no inverse this method
will fail.
TODO: Implement algorithm for sparse matrices (SFF),
http://www.eecis.udel.edu/~saunders/papers/sffge/it5.ps.
See Also
========
det
det_bareiss
berkowitz_det
"""
return self.det(method='lu')
def jordan_cell(self, eigenval, n):
return self.jordan_block(size=n, eigenvalue=eigenval)
def jordan_cells(self, calc_transformation=True):
P, J = self.jordan_form()
return P, J.get_diag_blocks()
def minorEntry(self, i, j, method="berkowitz"):
return self.minor(i, j, method=method)
def minorMatrix(self, i, j):
return self.minor_submatrix(i, j)
def permuteBkwd(self, perm):
"""Permute the rows of the matrix with the given permutation in reverse."""
return self.permute_rows(perm, direction='backward')
def permuteFwd(self, perm):
"""Permute the rows of the matrix with the given permutation."""
return self.permute_rows(perm, direction='forward')
class MatrixBase(MatrixDeprecated,
MatrixCalculus,
MatrixEigen,
MatrixCommon):
"""Base class for matrix objects."""
# Added just for numpy compatibility
__array_priority__ = 11
is_Matrix = True
_class_priority = 3
_sympify = staticmethod(sympify)
zero = S.Zero
one = S.One
# Defined here the same as on Basic.
# 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_ # type: Any
def __array__(self, dtype=object):
from .dense import matrix2numpy
return matrix2numpy(self, dtype=dtype)
def __len__(self):
"""Return the number of elements of ``self``.
Implemented mainly so bool(Matrix()) == False.
"""
return self.rows * self.cols
def __mathml__(self):
mml = ""
for i in range(self.rows):
mml += "<matrixrow>"
for j in range(self.cols):
mml += self[i, j].__mathml__()
mml += "</matrixrow>"
return "<matrix>" + mml + "</matrix>"
def _matrix_pow_by_jordan_blocks(self, num):
from sympy.matrices import diag, MutableMatrix
from sympy import binomial
def jordan_cell_power(jc, n):
N = jc.shape[0]
l = jc[0,0]
if l.is_zero:
if N == 1 and n.is_nonnegative:
jc[0,0] = l**n
elif not (n.is_integer and n.is_nonnegative):
raise NonInvertibleMatrixError("Non-invertible matrix can only be raised to a nonnegative integer")
else:
for i in range(N):
jc[0,i] = KroneckerDelta(i, n)
else:
for i in range(N):
bn = binomial(n, i)
if isinstance(bn, binomial):
bn = bn._eval_expand_func()
jc[0,i] = l**(n-i)*bn
for i in range(N):
for j in range(1, N-i):
jc[j,i+j] = jc [j-1,i+j-1]
P, J = self.jordan_form()
jordan_cells = J.get_diag_blocks()
# Make sure jordan_cells matrices are mutable:
jordan_cells = [MutableMatrix(j) for j in jordan_cells]
for j in jordan_cells:
jordan_cell_power(j, num)
return self._new(P.multiply(diag(*jordan_cells))
.multiply(P.inv()))
def __repr__(self):
return sstr(self)
def __str__(self):
if self.rows == 0 or self.cols == 0:
return 'Matrix(%s, %s, [])' % (self.rows, self.cols)
return "Matrix(%s)" % str(self.tolist())
def _format_str(self, printer=None):
if not printer:
from sympy.printing.str import StrPrinter
printer = StrPrinter()
# Handle zero dimensions:
if self.rows == 0 or self.cols == 0:
return 'Matrix(%s, %s, [])' % (self.rows, self.cols)
if self.rows == 1:
return "Matrix([%s])" % self.table(printer, rowsep=',\n')
return "Matrix([\n%s])" % self.table(printer, rowsep=',\n')
@classmethod
def irregular(cls, ntop, *matrices, **kwargs):
"""Return a matrix filled by the given matrices which
are listed in order of appearance from left to right, top to
bottom as they first appear in the matrix. They must fill the
matrix completely.
Examples
========
>>> from sympy import ones, Matrix
>>> Matrix.irregular(3, ones(2,1), ones(3,3)*2, ones(2,2)*3,
... ones(1,1)*4, ones(2,2)*5, ones(1,2)*6, ones(1,2)*7)
Matrix([
[1, 2, 2, 2, 3, 3],
[1, 2, 2, 2, 3, 3],
[4, 2, 2, 2, 5, 5],
[6, 6, 7, 7, 5, 5]])
"""
from sympy.core.compatibility import as_int
ntop = as_int(ntop)
# make sure we are working with explicit matrices
b = [i.as_explicit() if hasattr(i, 'as_explicit') else i
for i in matrices]
q = list(range(len(b)))
dat = [i.rows for i in b]
active = [q.pop(0) for _ in range(ntop)]
cols = sum([b[i].cols for i in active])
rows = []
while any(dat):
r = []
for a, j in enumerate(active):
r.extend(b[j][-dat[j], :])
dat[j] -= 1
if dat[j] == 0 and q:
active[a] = q.pop(0)
if len(r) != cols:
raise ValueError(filldedent('''
Matrices provided do not appear to fill
the space completely.'''))
rows.append(r)
return cls._new(rows)
@classmethod
def _handle_ndarray(cls, arg):
# NumPy array or matrix or some other object that implements
# __array__. So let's first use this method to get a
# numpy.array() and then make a python list out of it.
arr = arg.__array__()
if len(arr.shape) == 2:
rows, cols = arr.shape[0], arr.shape[1]
flat_list = [cls._sympify(i) for i in arr.ravel()]
return rows, cols, flat_list
elif len(arr.shape) == 1:
flat_list = [cls._sympify(i) for i in arr]
return arr.shape[0], 1, flat_list
else:
raise NotImplementedError(
"SymPy supports just 1D and 2D matrices")
@classmethod
def _handle_creation_inputs(cls, *args, **kwargs):
"""Return the number of rows, cols and flat matrix elements.
Examples
========
>>> from sympy import Matrix, I
Matrix can be constructed as follows:
* from a nested list of iterables
>>> Matrix( ((1, 2+I), (3, 4)) )
Matrix([
[1, 2 + I],
[3, 4]])
* from un-nested iterable (interpreted as a column)
>>> Matrix( [1, 2] )
Matrix([
[1],
[2]])
* from un-nested iterable with dimensions
>>> Matrix(1, 2, [1, 2] )
Matrix([[1, 2]])
* from no arguments (a 0 x 0 matrix)
>>> Matrix()
Matrix(0, 0, [])
* from a rule
>>> Matrix(2, 2, lambda i, j: i/(j + 1) )
Matrix([
[0, 0],
[1, 1/2]])
See Also
========
irregular - filling a matrix with irregular blocks
"""
from sympy.matrices.sparse import SparseMatrix
from sympy.matrices.expressions.matexpr import MatrixSymbol
from sympy.matrices.expressions.blockmatrix import BlockMatrix
from sympy.utilities.iterables import reshape
flat_list = None
if len(args) == 1:
# Matrix(SparseMatrix(...))
if isinstance(args[0], SparseMatrix):
return args[0].rows, args[0].cols, flatten(args[0].tolist())
# Matrix(Matrix(...))
elif isinstance(args[0], MatrixBase):
return args[0].rows, args[0].cols, args[0]._mat
# Matrix(MatrixSymbol('X', 2, 2))
elif isinstance(args[0], Basic) and args[0].is_Matrix:
return args[0].rows, args[0].cols, args[0].as_explicit()._mat
elif isinstance(args[0], mp.matrix):
M = args[0]
flat_list = [cls._sympify(x) for x in M]
return M.rows, M.cols, flat_list
# Matrix(numpy.ones((2, 2)))
elif hasattr(args[0], "__array__"):
return cls._handle_ndarray(args[0])
# Matrix([1, 2, 3]) or Matrix([[1, 2], [3, 4]])
elif is_sequence(args[0]) \
and not isinstance(args[0], DeferredVector):
dat = list(args[0])
ismat = lambda i: isinstance(i, MatrixBase) and (
evaluate or
isinstance(i, BlockMatrix) or
isinstance(i, MatrixSymbol))
raw = lambda i: is_sequence(i) and not ismat(i)
evaluate = kwargs.get('evaluate', True)
if evaluate:
def do(x):
# make Block and Symbol explicit
if isinstance(x, (list, tuple)):
return type(x)([do(i) for i in x])
if isinstance(x, BlockMatrix) or \
isinstance(x, MatrixSymbol) and \
all(_.is_Integer for _ in x.shape):
return x.as_explicit()
return x
dat = do(dat)
if dat == [] or dat == [[]]:
rows = cols = 0
flat_list = []
elif not any(raw(i) or ismat(i) for i in dat):
# a column as a list of values
flat_list = [cls._sympify(i) for i in dat]
rows = len(flat_list)
cols = 1 if rows else 0
elif evaluate and all(ismat(i) for i in dat):
# a column as a list of matrices
ncol = {i.cols for i in dat if any(i.shape)}
if ncol:
if len(ncol) != 1:
raise ValueError('mismatched dimensions')
flat_list = [_ for i in dat for r in i.tolist() for _ in r]
cols = ncol.pop()
rows = len(flat_list)//cols
else:
rows = cols = 0
flat_list = []
elif evaluate and any(ismat(i) for i in dat):
ncol = set()
flat_list = []
for i in dat:
if ismat(i):
flat_list.extend(
[k for j in i.tolist() for k in j])
if any(i.shape):
ncol.add(i.cols)
elif raw(i):
if i:
ncol.add(len(i))
flat_list.extend(i)
else:
ncol.add(1)
flat_list.append(i)
if len(ncol) > 1:
raise ValueError('mismatched dimensions')
cols = ncol.pop()
rows = len(flat_list)//cols
else:
# list of lists; each sublist is a logical row
# which might consist of many rows if the values in
# the row are matrices
flat_list = []
ncol = set()
rows = cols = 0
for row in dat:
if not is_sequence(row) and \
not getattr(row, 'is_Matrix', False):
raise ValueError('expecting list of lists')
if hasattr(row, '__array__'):
if 0 in row.shape:
continue
elif not row:
continue
if evaluate and all(ismat(i) for i in row):
r, c, flatT = cls._handle_creation_inputs(
[i.T for i in row])
T = reshape(flatT, [c])
flat = \
[T[i][j] for j in range(c) for i in range(r)]
r, c = c, r
else:
r = 1
if getattr(row, 'is_Matrix', False):
c = 1
flat = [row]
else:
c = len(row)
flat = [cls._sympify(i) for i in row]
ncol.add(c)
if len(ncol) > 1:
raise ValueError('mismatched dimensions')
flat_list.extend(flat)
rows += r
cols = ncol.pop() if ncol else 0
elif len(args) == 3:
rows = as_int(args[0])
cols = as_int(args[1])
if rows < 0 or cols < 0:
raise ValueError("Cannot create a {} x {} matrix. "
"Both dimensions must be positive".format(rows, cols))
# Matrix(2, 2, lambda i, j: i+j)
if len(args) == 3 and isinstance(args[2], Callable):
op = args[2]
flat_list = []
for i in range(rows):
flat_list.extend(
[cls._sympify(op(cls._sympify(i), cls._sympify(j)))
for j in range(cols)])
# Matrix(2, 2, [1, 2, 3, 4])
elif len(args) == 3 and is_sequence(args[2]):
flat_list = args[2]
if len(flat_list) != rows * cols:
raise ValueError(
'List length should be equal to rows*columns')
flat_list = [cls._sympify(i) for i in flat_list]
# Matrix()
elif len(args) == 0:
# Empty Matrix
rows = cols = 0
flat_list = []
if flat_list is None:
raise TypeError(filldedent('''
Data type not understood; expecting list of lists
or lists of values.'''))
return rows, cols, flat_list
def _setitem(self, key, value):
"""Helper to set value at location given by key.
Examples
========
>>> from sympy import Matrix, I, zeros, ones
>>> m = Matrix(((1, 2+I), (3, 4)))
>>> m
Matrix([
[1, 2 + I],
[3, 4]])
>>> m[1, 0] = 9
>>> m
Matrix([
[1, 2 + I],
[9, 4]])
>>> m[1, 0] = [[0, 1]]
To replace row r you assign to position r*m where m
is the number of columns:
>>> M = zeros(4)
>>> m = M.cols
>>> M[3*m] = ones(1, m)*2; M
Matrix([
[0, 0, 0, 0],
[0, 0, 0, 0],
[0, 0, 0, 0],
[2, 2, 2, 2]])
And to replace column c you can assign to position c:
>>> M[2] = ones(m, 1)*4; M
Matrix([
[0, 0, 4, 0],
[0, 0, 4, 0],
[0, 0, 4, 0],
[2, 2, 4, 2]])
"""
from .dense import Matrix
is_slice = isinstance(key, slice)
i, j = key = self.key2ij(key)
is_mat = isinstance(value, MatrixBase)
if type(i) is slice or type(j) is slice:
if is_mat:
self.copyin_matrix(key, value)
return
if not isinstance(value, Expr) and is_sequence(value):
self.copyin_list(key, value)
return
raise ValueError('unexpected value: %s' % value)
else:
if (not is_mat and
not isinstance(value, Basic) and is_sequence(value)):
value = Matrix(value)
is_mat = True
if is_mat:
if is_slice:
key = (slice(*divmod(i, self.cols)),
slice(*divmod(j, self.cols)))
else:
key = (slice(i, i + value.rows),
slice(j, j + value.cols))
self.copyin_matrix(key, value)
else:
return i, j, self._sympify(value)
return
def add(self, b):
"""Return self + b """
return self + b
def condition_number(self):
"""Returns the condition number of a matrix.
This is the maximum singular value divided by the minimum singular value
Examples
========
>>> from sympy import Matrix, S
>>> A = Matrix([[1, 0, 0], [0, 10, 0], [0, 0, S.One/10]])
>>> A.condition_number()
100
See Also
========
singular_values
"""
if not self:
return self.zero
singularvalues = self.singular_values()
return Max(*singularvalues) / Min(*singularvalues)
def copy(self):
"""
Returns the copy of a matrix.
Examples
========
>>> from sympy import Matrix
>>> A = Matrix(2, 2, [1, 2, 3, 4])
>>> A.copy()
Matrix([
[1, 2],
[3, 4]])
"""
return self._new(self.rows, self.cols, self._mat)
def cross(self, b):
r"""
Return the cross product of ``self`` and ``b`` relaxing the condition
of compatible dimensions: if each has 3 elements, a matrix of the
same type and shape as ``self`` will be returned. If ``b`` has the same
shape as ``self`` then common identities for the cross product (like
`a \times b = - b \times a`) will hold.
Parameters
==========
b : 3x1 or 1x3 Matrix
See Also
========
dot
multiply
multiply_elementwise
"""
from sympy.matrices.expressions.matexpr import MatrixExpr
if not isinstance(b, MatrixBase) and not isinstance(b, MatrixExpr):
raise TypeError(
"{} must be a Matrix, not {}.".format(b, type(b)))
if not (self.rows * self.cols == b.rows * b.cols == 3):
raise ShapeError("Dimensions incorrect for cross product: %s x %s" %
((self.rows, self.cols), (b.rows, b.cols)))
else:
return self._new(self.rows, self.cols, (
(self[1] * b[2] - self[2] * b[1]),
(self[2] * b[0] - self[0] * b[2]),
(self[0] * b[1] - self[1] * b[0])))
@property
def D(self):
"""Return Dirac conjugate (if ``self.rows == 4``).
Examples
========
>>> from sympy import Matrix, I, eye
>>> m = Matrix((0, 1 + I, 2, 3))
>>> m.D
Matrix([[0, 1 - I, -2, -3]])
>>> m = (eye(4) + I*eye(4))
>>> m[0, 3] = 2
>>> m.D
Matrix([
[1 - I, 0, 0, 0],
[ 0, 1 - I, 0, 0],
[ 0, 0, -1 + I, 0],
[ 2, 0, 0, -1 + I]])
If the matrix does not have 4 rows an AttributeError will be raised
because this property is only defined for matrices with 4 rows.
>>> Matrix(eye(2)).D
Traceback (most recent call last):
...
AttributeError: Matrix has no attribute D.
See Also
========
sympy.matrices.common.MatrixCommon.conjugate: By-element conjugation
sympy.matrices.common.MatrixCommon.H: Hermite conjugation
"""
from sympy.physics.matrices import mgamma
if self.rows != 4:
# In Python 3.2, properties can only return an AttributeError
# so we can't raise a ShapeError -- see commit which added the
# first line of this inline comment. Also, there is no need
# for a message since MatrixBase will raise the AttributeError
raise AttributeError
return self.H * mgamma(0)
def dot(self, b, hermitian=None, conjugate_convention=None):
"""Return the dot or inner product of two vectors of equal length.
Here ``self`` must be a ``Matrix`` of size 1 x n or n x 1, and ``b``
must be either a matrix of size 1 x n, n x 1, or a list/tuple of length n.
A scalar is returned.
By default, ``dot`` does not conjugate ``self`` or ``b``, even if there are
complex entries. Set ``hermitian=True`` (and optionally a ``conjugate_convention``)
to compute the hermitian inner product.
Possible kwargs are ``hermitian`` and ``conjugate_convention``.
If ``conjugate_convention`` is ``"left"``, ``"math"`` or ``"maths"``,
the conjugate of the first vector (``self``) is used. If ``"right"``
or ``"physics"`` is specified, the conjugate of the second vector ``b`` is used.
Examples
========
>>> from sympy import Matrix
>>> M = Matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]])
>>> v = Matrix([1, 1, 1])
>>> M.row(0).dot(v)
6
>>> M.col(0).dot(v)
12
>>> v = [3, 2, 1]
>>> M.row(0).dot(v)
10
>>> from sympy import I
>>> q = Matrix([1*I, 1*I, 1*I])
>>> q.dot(q, hermitian=False)
-3
>>> q.dot(q, hermitian=True)
3
>>> q1 = Matrix([1, 1, 1*I])
>>> q.dot(q1, hermitian=True, conjugate_convention="maths")
1 - 2*I
>>> q.dot(q1, hermitian=True, conjugate_convention="physics")
1 + 2*I
See Also
========
cross
multiply
multiply_elementwise
"""
from .dense import Matrix
if not isinstance(b, MatrixBase):
if is_sequence(b):
if len(b) != self.cols and len(b) != self.rows:
raise ShapeError(
"Dimensions incorrect for dot product: %s, %s" % (
self.shape, len(b)))
return self.dot(Matrix(b))
else:
raise TypeError(
"`b` must be an ordered iterable or Matrix, not %s." %
type(b))
mat = self
if (1 not in mat.shape) or (1 not in b.shape) :
SymPyDeprecationWarning(
feature="Dot product of non row/column vectors",
issue=13815,
deprecated_since_version="1.2",
useinstead="* to take matrix products").warn()
return mat._legacy_array_dot(b)
if len(mat) != len(b):
raise ShapeError("Dimensions incorrect for dot product: %s, %s" % (self.shape, b.shape))
n = len(mat)
if mat.shape != (1, n):
mat = mat.reshape(1, n)
if b.shape != (n, 1):
b = b.reshape(n, 1)
# Now ``mat`` is a row vector and ``b`` is a column vector.
# If it so happens that only conjugate_convention is passed
# then automatically set hermitian to True. If only hermitian
# is true but no conjugate_convention is not passed then
# automatically set it to ``"maths"``
if conjugate_convention is not None and hermitian is None:
hermitian = True
if hermitian and conjugate_convention is None:
conjugate_convention = "maths"
if hermitian == True:
if conjugate_convention in ("maths", "left", "math"):
mat = mat.conjugate()
elif conjugate_convention in ("physics", "right"):
b = b.conjugate()
else:
raise ValueError("Unknown conjugate_convention was entered."
" conjugate_convention must be one of the"
" following: math, maths, left, physics or right.")
return (mat * b)[0]
def dual(self):
"""Returns the dual of a matrix, which is:
``(1/2)*levicivita(i, j, k, l)*M(k, l)`` summed over indices `k` and `l`
Since the levicivita method is anti_symmetric for any pairwise
exchange of indices, the dual of a symmetric matrix is the zero
matrix. Strictly speaking the dual defined here assumes that the
'matrix' `M` is a contravariant anti_symmetric second rank tensor,
so that the dual is a covariant second rank tensor.
"""
from sympy import LeviCivita
from sympy.matrices import zeros
M, n = self[:, :], self.rows
work = zeros(n)
if self.is_symmetric():
return work
for i in range(1, n):
for j in range(1, n):
acum = 0
for k in range(1, n):
acum += LeviCivita(i, j, 0, k) * M[0, k]
work[i, j] = acum
work[j, i] = -acum
for l in range(1, n):
acum = 0
for a in range(1, n):
for b in range(1, n):
acum += LeviCivita(0, l, a, b) * M[a, b]
acum /= 2
work[0, l] = -acum
work[l, 0] = acum
return work
def _eval_matrix_exp_jblock(self):
"""A helper function to compute an exponential of a Jordan block
matrix
Examples
========
>>> from sympy import Symbol, Matrix
>>> l = Symbol('lamda')
A trivial example of 1*1 Jordan block:
>>> m = Matrix.jordan_block(1, l)
>>> m._eval_matrix_exp_jblock()
Matrix([[exp(lamda)]])
An example of 3*3 Jordan block:
>>> m = Matrix.jordan_block(3, l)
>>> m._eval_matrix_exp_jblock()
Matrix([
[exp(lamda), exp(lamda), exp(lamda)/2],
[ 0, exp(lamda), exp(lamda)],
[ 0, 0, exp(lamda)]])
References
==========
.. [1] https://en.wikipedia.org/wiki/Matrix_function#Jordan_decomposition
"""
size = self.rows
l = self[0, 0]
exp_l = exp(l)
bands = {i: exp_l / factorial(i) for i in range(size)}
from .sparsetools import banded
return self.__class__(banded(size, bands))
def analytic_func(self, f, x):
"""
Computes f(A) where A is a Square Matrix
and f is an analytic function.
Examples
========
>>> from sympy import Symbol, Matrix, S, log
>>> x = Symbol('x')
>>> m = Matrix([[S(5)/4, S(3)/4], [S(3)/4, S(5)/4]])
>>> f = log(x)
>>> m.analytic_func(f, x)
Matrix([
[ 0, log(2)],
[log(2), 0]])
Parameters
==========
f : Expr
Analytic Function
x : Symbol
parameter of f
"""
from sympy import diff
if not self.is_square:
raise NonSquareMatrixError(
"Valid only for square matrices")
if not x.is_symbol:
raise ValueError("The parameter for f should be a symbol")
if x not in f.free_symbols:
raise ValueError("x should be a parameter in Function")
if x in self.free_symbols:
raise ValueError("x should be a parameter in Matrix")
eigen = self.eigenvals()
max_mul = max(eigen.values())
derivative = {}
dd = f
for i in range(max_mul - 1):
dd = diff(dd, x)
derivative[i + 1] = dd
n = self.shape[0]
r = self.zeros(n)
f_val = self.zeros(n, 1)
row = 0
for i in eigen:
mul = eigen[i]
f_val[row] = f.subs(x, i)
if not f.subs(x, i).free_symbols and not f.subs(x, i).is_complex:
raise ValueError("Cannot Evaluate the function is not"
" analytic at some eigen value")
val = 1
for a in range(n):
r[row, a] = val
val *= i
if mul > 1:
coe = [1 for ii in range(n)]
deri = 1
while mul > 1:
row = row + 1
mul -= 1
d_i = derivative[deri].subs(x, i)
if not d_i.free_symbols and not d_i.is_complex:
raise ValueError("Cannot Evaluate the function is not"
" analytic at some eigen value")
f_val[row] = d_i
for a in range(n):
if a - deri + 1 <= 0:
r[row, a] = 0
coe[a] = 0
continue
coe[a] = coe[a]*(a - deri + 1)
r[row, a] = coe[a]*pow(i, a - deri)
deri += 1
row += 1
c = r.solve(f_val)
ans = self.zeros(n)
pre = self.eye(n)
for i in range(n):
ans = ans + c[i]*pre
pre *= self
return ans
def exp(self):
"""Return the exponential of a square matrix
Examples
========
>>> from sympy import Symbol, Matrix
>>> t = Symbol('t')
>>> m = Matrix([[0, 1], [-1, 0]]) * t
>>> m.exp()
Matrix([
[ exp(I*t)/2 + exp(-I*t)/2, -I*exp(I*t)/2 + I*exp(-I*t)/2],
[I*exp(I*t)/2 - I*exp(-I*t)/2, exp(I*t)/2 + exp(-I*t)/2]])
"""
if not self.is_square:
raise NonSquareMatrixError(
"Exponentiation is valid only for square matrices")
try:
P, J = self.jordan_form()
cells = J.get_diag_blocks()
except MatrixError:
raise NotImplementedError(
"Exponentiation is implemented only for matrices for which the Jordan normal form can be computed")
blocks = [cell._eval_matrix_exp_jblock() for cell in cells]
from sympy.matrices import diag
from sympy import re
eJ = diag(*blocks)
# n = self.rows
ret = P.multiply(eJ, dotprodsimp=True).multiply(P.inv(), dotprodsimp=True)
if all(value.is_real for value in self.values()):
return type(self)(re(ret))
else:
return type(self)(ret)
def _eval_matrix_log_jblock(self):
"""Helper function to compute logarithm of a jordan block.
Examples
========
>>> from sympy import Symbol, Matrix
>>> l = Symbol('lamda')
A trivial example of 1*1 Jordan block:
>>> m = Matrix.jordan_block(1, l)
>>> m._eval_matrix_log_jblock()
Matrix([[log(lamda)]])
An example of 3*3 Jordan block:
>>> m = Matrix.jordan_block(3, l)
>>> m._eval_matrix_log_jblock()
Matrix([
[log(lamda), 1/lamda, -1/(2*lamda**2)],
[ 0, log(lamda), 1/lamda],
[ 0, 0, log(lamda)]])
"""
size = self.rows
l = self[0, 0]
if l.is_zero:
raise MatrixError(
'Could not take logarithm or reciprocal for the given '
'eigenvalue {}'.format(l))
bands = {0: log(l)}
for i in range(1, size):
bands[i] = -((-l) ** -i) / i
from .sparsetools import banded
return self.__class__(banded(size, bands))
def log(self, simplify=cancel):
"""Return the logarithm of a square matrix
Parameters
==========
simplify : function, bool
The function to simplify the result with.
Default is ``cancel``, which is effective to reduce the
expression growing for taking reciprocals and inverses for
symbolic matrices.
Examples
========
>>> from sympy import S, Matrix
Examples for positive-definite matrices:
>>> m = Matrix([[1, 1], [0, 1]])
>>> m.log()
Matrix([
[0, 1],
[0, 0]])
>>> m = Matrix([[S(5)/4, S(3)/4], [S(3)/4, S(5)/4]])
>>> m.log()
Matrix([
[ 0, log(2)],
[log(2), 0]])
Examples for non positive-definite matrices:
>>> m = Matrix([[S(3)/4, S(5)/4], [S(5)/4, S(3)/4]])
>>> m.log()
Matrix([
[ I*pi/2, log(2) - I*pi/2],
[log(2) - I*pi/2, I*pi/2]])
>>> m = Matrix(
... [[0, 0, 0, 1],
... [0, 0, 1, 0],
... [0, 1, 0, 0],
... [1, 0, 0, 0]])
>>> m.log()
Matrix([
[ I*pi/2, 0, 0, -I*pi/2],
[ 0, I*pi/2, -I*pi/2, 0],
[ 0, -I*pi/2, I*pi/2, 0],
[-I*pi/2, 0, 0, I*pi/2]])
"""
if not self.is_square:
raise NonSquareMatrixError(
"Logarithm is valid only for square matrices")
try:
if simplify:
P, J = simplify(self).jordan_form()
else:
P, J = self.jordan_form()
cells = J.get_diag_blocks()
except MatrixError:
raise NotImplementedError(
"Logarithm is implemented only for matrices for which "
"the Jordan normal form can be computed")
blocks = [
cell._eval_matrix_log_jblock()
for cell in cells]
from sympy.matrices import diag
eJ = diag(*blocks)
if simplify:
ret = simplify(P * eJ * simplify(P.inv()))
ret = self.__class__(ret)
else:
ret = P * eJ * P.inv()
return ret
def is_nilpotent(self):
"""Checks if a matrix is nilpotent.
A matrix B is nilpotent if for some integer k, B**k is
a zero matrix.
Examples
========
>>> from sympy import Matrix
>>> a = Matrix([[0, 0, 0], [1, 0, 0], [1, 1, 0]])
>>> a.is_nilpotent()
True
>>> a = Matrix([[1, 0, 1], [1, 0, 0], [1, 1, 0]])
>>> a.is_nilpotent()
False
"""
if not self:
return True
if not self.is_square:
raise NonSquareMatrixError(
"Nilpotency is valid only for square matrices")
x = uniquely_named_symbol('x', self, modify=lambda s: '_' + s)
p = self.charpoly(x)
if p.args[0] == x ** self.rows:
return True
return False
def key2bounds(self, keys):
"""Converts a key with potentially mixed types of keys (integer and slice)
into a tuple of ranges and raises an error if any index is out of ``self``'s
range.
See Also
========
key2ij
"""
from sympy.matrices.common import a2idx as a2idx_ # Remove this line after deprecation of a2idx from matrices.py
islice, jslice = [isinstance(k, slice) for k in keys]
if islice:
if not self.rows:
rlo = rhi = 0
else:
rlo, rhi = keys[0].indices(self.rows)[:2]
else:
rlo = a2idx_(keys[0], self.rows)
rhi = rlo + 1
if jslice:
if not self.cols:
clo = chi = 0
else:
clo, chi = keys[1].indices(self.cols)[:2]
else:
clo = a2idx_(keys[1], self.cols)
chi = clo + 1
return rlo, rhi, clo, chi
def key2ij(self, key):
"""Converts key into canonical form, converting integers or indexable
items into valid integers for ``self``'s range or returning slices
unchanged.
See Also
========
key2bounds
"""
from sympy.matrices.common import a2idx as a2idx_ # Remove this line after deprecation of a2idx from matrices.py
if is_sequence(key):
if not len(key) == 2:
raise TypeError('key must be a sequence of length 2')
return [a2idx_(i, n) if not isinstance(i, slice) else i
for i, n in zip(key, self.shape)]
elif isinstance(key, slice):
return key.indices(len(self))[:2]
else:
return divmod(a2idx_(key, len(self)), self.cols)
def normalized(self, iszerofunc=_iszero):
"""Return the normalized version of ``self``.
Parameters
==========
iszerofunc : Function, optional
A function to determine whether ``self`` is a zero vector.
The default ``_iszero`` tests to see if each element is
exactly zero.
Returns
=======
Matrix
Normalized vector form of ``self``.
It has the same length as a unit vector. However, a zero vector
will be returned for a vector with norm 0.
Raises
======
ShapeError
If the matrix is not in a vector form.
See Also
========
norm
"""
if self.rows != 1 and self.cols != 1:
raise ShapeError("A Matrix must be a vector to normalize.")
norm = self.norm()
if iszerofunc(norm):
out = self.zeros(self.rows, self.cols)
else:
out = self.applyfunc(lambda i: i / norm)
return out
def norm(self, ord=None):
"""Return the Norm of a Matrix or Vector.
In the simplest case this is the geometric size of the vector
Other norms can be specified by the ord parameter
===== ============================ ==========================
ord norm for matrices norm for vectors
===== ============================ ==========================
None Frobenius norm 2-norm
'fro' Frobenius norm - does not exist
inf maximum row sum max(abs(x))
-inf -- min(abs(x))
1 maximum column sum as below
-1 -- as below
2 2-norm (largest sing. value) as below
-2 smallest singular value as below
other - does not exist sum(abs(x)**ord)**(1./ord)
===== ============================ ==========================
Examples
========
>>> from sympy import Matrix, Symbol, trigsimp, cos, sin, oo
>>> x = Symbol('x', real=True)
>>> v = Matrix([cos(x), sin(x)])
>>> trigsimp( v.norm() )
1
>>> v.norm(10)
(sin(x)**10 + cos(x)**10)**(1/10)
>>> A = Matrix([[1, 1], [1, 1]])
>>> A.norm(1) # maximum sum of absolute values of A is 2
2
>>> A.norm(2) # Spectral norm (max of |Ax|/|x| under 2-vector-norm)
2
>>> A.norm(-2) # Inverse spectral norm (smallest singular value)
0
>>> A.norm() # Frobenius Norm
2
>>> A.norm(oo) # Infinity Norm
2
>>> Matrix([1, -2]).norm(oo)
2
>>> Matrix([-1, 2]).norm(-oo)
1
See Also
========
normalized
"""
# Row or Column Vector Norms
vals = list(self.values()) or [0]
if self.rows == 1 or self.cols == 1:
if ord == 2 or ord is None: # Common case sqrt(<x, x>)
return sqrt(Add(*(abs(i) ** 2 for i in vals)))
elif ord == 1: # sum(abs(x))
return Add(*(abs(i) for i in vals))
elif ord is S.Infinity: # max(abs(x))
return Max(*[abs(i) for i in vals])
elif ord is S.NegativeInfinity: # min(abs(x))
return Min(*[abs(i) for i in vals])
# Otherwise generalize the 2-norm, Sum(x_i**ord)**(1/ord)
# Note that while useful this is not mathematically a norm
try:
return Pow(Add(*(abs(i) ** ord for i in vals)), S.One / ord)
except (NotImplementedError, TypeError):
raise ValueError("Expected order to be Number, Symbol, oo")
# Matrix Norms
else:
if ord == 1: # Maximum column sum
m = self.applyfunc(abs)
return Max(*[sum(m.col(i)) for i in range(m.cols)])
elif ord == 2: # Spectral Norm
# Maximum singular value
return Max(*self.singular_values())
elif ord == -2:
# Minimum singular value
return Min(*self.singular_values())
elif ord is S.Infinity: # Infinity Norm - Maximum row sum
m = self.applyfunc(abs)
return Max(*[sum(m.row(i)) for i in range(m.rows)])
elif (ord is None or isinstance(ord,
str) and ord.lower() in
['f', 'fro', 'frobenius', 'vector']):
# Reshape as vector and send back to norm function
return self.vec().norm(ord=2)
else:
raise NotImplementedError("Matrix Norms under development")
def print_nonzero(self, symb="X"):
"""Shows location of non-zero entries for fast shape lookup.
Examples
========
>>> from sympy.matrices import Matrix, eye
>>> m = Matrix(2, 3, lambda i, j: i*3+j)
>>> m
Matrix([
[0, 1, 2],
[3, 4, 5]])
>>> m.print_nonzero()
[ XX]
[XXX]
>>> m = eye(4)
>>> m.print_nonzero("x")
[x ]
[ x ]
[ x ]
[ x]
"""
s = []
for i in range(self.rows):
line = []
for j in range(self.cols):
if self[i, j] == 0:
line.append(" ")
else:
line.append(str(symb))
s.append("[%s]" % ''.join(line))
print('\n'.join(s))
def project(self, v):
"""Return the projection of ``self`` onto the line containing ``v``.
Examples
========
>>> from sympy import Matrix, S, sqrt
>>> V = Matrix([sqrt(3)/2, S.Half])
>>> x = Matrix([[1, 0]])
>>> V.project(x)
Matrix([[sqrt(3)/2, 0]])
>>> V.project(-x)
Matrix([[sqrt(3)/2, 0]])
"""
return v * (self.dot(v) / v.dot(v))
def table(self, printer, rowstart='[', rowend=']', rowsep='\n',
colsep=', ', align='right'):
r"""
String form of Matrix as a table.
``printer`` is the printer to use for on the elements (generally
something like StrPrinter())
``rowstart`` is the string used to start each row (by default '[').
``rowend`` is the string used to end each row (by default ']').
``rowsep`` is the string used to separate rows (by default a newline).
``colsep`` is the string used to separate columns (by default ', ').
``align`` defines how the elements are aligned. Must be one of 'left',
'right', or 'center'. You can also use '<', '>', and '^' to mean the
same thing, respectively.
This is used by the string printer for Matrix.
Examples
========
>>> from sympy import Matrix
>>> from sympy.printing.str import StrPrinter
>>> M = Matrix([[1, 2], [-33, 4]])
>>> printer = StrPrinter()
>>> M.table(printer)
'[ 1, 2]\n[-33, 4]'
>>> print(M.table(printer))
[ 1, 2]
[-33, 4]
>>> print(M.table(printer, rowsep=',\n'))
[ 1, 2],
[-33, 4]
>>> print('[%s]' % M.table(printer, rowsep=',\n'))
[[ 1, 2],
[-33, 4]]
>>> print(M.table(printer, colsep=' '))
[ 1 2]
[-33 4]
>>> print(M.table(printer, align='center'))
[ 1 , 2]
[-33, 4]
>>> print(M.table(printer, rowstart='{', rowend='}'))
{ 1, 2}
{-33, 4}
"""
# Handle zero dimensions:
if self.rows == 0 or self.cols == 0:
return '[]'
# Build table of string representations of the elements
res = []
# Track per-column max lengths for pretty alignment
maxlen = [0] * self.cols
for i in range(self.rows):
res.append([])
for j in range(self.cols):
s = printer._print(self[i, j])
res[-1].append(s)
maxlen[j] = max(len(s), maxlen[j])
# Patch strings together
align = {
'left': 'ljust',
'right': 'rjust',
'center': 'center',
'<': 'ljust',
'>': 'rjust',
'^': 'center',
}[align]
for i, row in enumerate(res):
for j, elem in enumerate(row):
row[j] = getattr(elem, align)(maxlen[j])
res[i] = rowstart + colsep.join(row) + rowend
return rowsep.join(res)
def vech(self, diagonal=True, check_symmetry=True):
"""Return the unique elements of a symmetric Matrix as a one column matrix
by stacking the elements in the lower triangle.
Arguments:
diagonal -- include the diagonal cells of ``self`` or not
check_symmetry -- checks symmetry of ``self`` but not completely reliably
Examples
========
>>> from sympy import Matrix
>>> m=Matrix([[1, 2], [2, 3]])
>>> m
Matrix([
[1, 2],
[2, 3]])
>>> m.vech()
Matrix([
[1],
[2],
[3]])
>>> m.vech(diagonal=False)
Matrix([[2]])
See Also
========
vec
"""
from sympy.matrices import zeros
c = self.cols
if c != self.rows:
raise NonSquareMatrixError("Matrix must be square")
if check_symmetry:
self.simplify()
if self != self.transpose():
raise ValueError(
"Matrix appears to be asymmetric; consider check_symmetry=False")
count = 0
if diagonal:
v = zeros(c * (c + 1) // 2, 1)
for j in range(c):
for i in range(j, c):
v[count] = self[i, j]
count += 1
else:
v = zeros(c * (c - 1) // 2, 1)
for j in range(c):
for i in range(j + 1, c):
v[count] = self[i, j]
count += 1
return v
def rank_decomposition(self, iszerofunc=_iszero, simplify=False):
return _rank_decomposition(self, iszerofunc=iszerofunc,
simplify=simplify)
def cholesky(self, hermitian=True):
raise NotImplementedError('This function is implemented in DenseMatrix or SparseMatrix')
def LDLdecomposition(self, hermitian=True):
raise NotImplementedError('This function is implemented in DenseMatrix or SparseMatrix')
def LUdecomposition(self, iszerofunc=_iszero, simpfunc=None,
rankcheck=False):
return _LUdecomposition(self, iszerofunc=iszerofunc, simpfunc=simpfunc,
rankcheck=rankcheck)
def LUdecomposition_Simple(self, iszerofunc=_iszero, simpfunc=None,
rankcheck=False):
return _LUdecomposition_Simple(self, iszerofunc=iszerofunc,
simpfunc=simpfunc, rankcheck=rankcheck)
def LUdecompositionFF(self):
return _LUdecompositionFF(self)
def QRdecomposition(self):
return _QRdecomposition(self)
def diagonal_solve(self, rhs):
return _diagonal_solve(self, rhs)
def lower_triangular_solve(self, rhs):
raise NotImplementedError('This function is implemented in DenseMatrix or SparseMatrix')
def upper_triangular_solve(self, rhs):
raise NotImplementedError('This function is implemented in DenseMatrix or SparseMatrix')
def cholesky_solve(self, rhs):
return _cholesky_solve(self, rhs)
def LDLsolve(self, rhs):
return _LDLsolve(self, rhs)
def LUsolve(self, rhs, iszerofunc=_iszero):
return _LUsolve(self, rhs, iszerofunc=iszerofunc)
def QRsolve(self, b):
return _QRsolve(self, b)
def gauss_jordan_solve(self, B, freevar=False):
return _gauss_jordan_solve(self, B, freevar=freevar)
def pinv_solve(self, B, arbitrary_matrix=None):
return _pinv_solve(self, B, arbitrary_matrix=arbitrary_matrix)
def solve(self, rhs, method='GJ'):
return _solve(self, rhs, method=method)
def solve_least_squares(self, rhs, method='CH'):
return _solve_least_squares(self, rhs, method=method)
def pinv(self, method='RD'):
return _pinv(self, method=method)
def inv_mod(self, m):
return _inv_mod(self, m)
def inverse_ADJ(self, iszerofunc=_iszero):
return _inv_ADJ(self, iszerofunc=iszerofunc)
def inverse_BLOCK(self, iszerofunc=_iszero):
return _inv_block(self, iszerofunc=iszerofunc)
def inverse_GE(self, iszerofunc=_iszero):
return _inv_GE(self, iszerofunc=iszerofunc)
def inverse_LU(self, iszerofunc=_iszero):
return _inv_LU(self, iszerofunc=iszerofunc)
def inverse_CH(self, iszerofunc=_iszero):
return _inv_CH(self, iszerofunc=iszerofunc)
def inverse_LDL(self, iszerofunc=_iszero):
return _inv_LDL(self, iszerofunc=iszerofunc)
def inverse_QR(self, iszerofunc=_iszero):
return _inv_QR(self, iszerofunc=iszerofunc)
def inv(self, method=None, iszerofunc=_iszero, try_block_diag=False):
return _inv(self, method=method, iszerofunc=iszerofunc,
try_block_diag=try_block_diag)
def connected_components(self):
return _connected_components(self)
def connected_components_decomposition(self):
return _connected_components_decomposition(self)
rank_decomposition.__doc__ = _rank_decomposition.__doc__
cholesky.__doc__ = _cholesky.__doc__
LDLdecomposition.__doc__ = _LDLdecomposition.__doc__
LUdecomposition.__doc__ = _LUdecomposition.__doc__
LUdecomposition_Simple.__doc__ = _LUdecomposition_Simple.__doc__
LUdecompositionFF.__doc__ = _LUdecompositionFF.__doc__
QRdecomposition.__doc__ = _QRdecomposition.__doc__
diagonal_solve.__doc__ = _diagonal_solve.__doc__
lower_triangular_solve.__doc__ = _lower_triangular_solve.__doc__
upper_triangular_solve.__doc__ = _upper_triangular_solve.__doc__
cholesky_solve.__doc__ = _cholesky_solve.__doc__
LDLsolve.__doc__ = _LDLsolve.__doc__
LUsolve.__doc__ = _LUsolve.__doc__
QRsolve.__doc__ = _QRsolve.__doc__
gauss_jordan_solve.__doc__ = _gauss_jordan_solve.__doc__
pinv_solve.__doc__ = _pinv_solve.__doc__
solve.__doc__ = _solve.__doc__
solve_least_squares.__doc__ = _solve_least_squares.__doc__
pinv.__doc__ = _pinv.__doc__
inv_mod.__doc__ = _inv_mod.__doc__
inverse_ADJ.__doc__ = _inv_ADJ.__doc__
inverse_GE.__doc__ = _inv_GE.__doc__
inverse_LU.__doc__ = _inv_LU.__doc__
inverse_CH.__doc__ = _inv_CH.__doc__
inverse_LDL.__doc__ = _inv_LDL.__doc__
inverse_QR.__doc__ = _inv_QR.__doc__
inverse_BLOCK.__doc__ = _inv_block.__doc__
inv.__doc__ = _inv.__doc__
connected_components.__doc__ = _connected_components.__doc__
connected_components_decomposition.__doc__ = \
_connected_components_decomposition.__doc__
@deprecated(
issue=15109,
useinstead="from sympy.matrices.common import classof",
deprecated_since_version="1.3")
def classof(A, B):
from sympy.matrices.common import classof as classof_
return classof_(A, B)
@deprecated(
issue=15109,
deprecated_since_version="1.3",
useinstead="from sympy.matrices.common import a2idx")
def a2idx(j, n=None):
from sympy.matrices.common import a2idx as a2idx_
return a2idx_(j, n)
|
6d28800badbbbc81e9a49ba9b1f05caa0c48ed33a1cd2106ca2f2f908f401ad7 | from types import FunctionType
from collections import Counter
from mpmath import mp, workprec
from mpmath.libmp.libmpf import prec_to_dps
from sympy.core.compatibility import default_sort_key
from sympy.core.evalf import DEFAULT_MAXPREC, PrecisionExhausted
from sympy.core.logic import fuzzy_and, fuzzy_or
from sympy.core.numbers import Float
from sympy.core.sympify import _sympify
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.polys import roots
from sympy.simplify import nsimplify, simplify as _simplify
from sympy.utilities.exceptions import SymPyDeprecationWarning
from .common import MatrixError, NonSquareMatrixError
from .utilities import _iszero
def _eigenvals_triangular(M, multiple=False):
"""A fast decision for eigenvalues of an upper or a lower triangular
matrix.
"""
diagonal_entries = [M[i, i] for i in range(M.rows)]
if multiple:
return diagonal_entries
return dict(Counter(diagonal_entries))
def _eigenvals_eigenvects_mpmath(M):
norm2 = lambda v: mp.sqrt(sum(i**2 for i in v))
v1 = None
prec = max([x._prec for x in M.atoms(Float)])
eps = 2**-prec
while prec < DEFAULT_MAXPREC:
with workprec(prec):
A = mp.matrix(M.evalf(n=prec_to_dps(prec)))
E, ER = mp.eig(A)
v2 = norm2([i for e in E for i in (mp.re(e), mp.im(e))])
if v1 is not None and mp.fabs(v1 - v2) < eps:
return E, ER
v1 = v2
prec *= 2
# we get here because the next step would have taken us
# past MAXPREC or because we never took a step; in case
# of the latter, we refuse to send back a solution since
# it would not have been verified; we also resist taking
# a small step to arrive exactly at MAXPREC since then
# the two calculations might be artificially close.
raise PrecisionExhausted
def _eigenvals_mpmath(M, multiple=False):
"""Compute eigenvalues using mpmath"""
E, _ = _eigenvals_eigenvects_mpmath(M)
result = [_sympify(x) for x in E]
if multiple:
return result
return dict(Counter(result))
def _eigenvects_mpmath(M):
E, ER = _eigenvals_eigenvects_mpmath(M)
result = []
for i in range(M.rows):
eigenval = _sympify(E[i])
eigenvect = _sympify(ER[:, i])
result.append((eigenval, 1, [eigenvect]))
return result
# This functions is a candidate for caching if it gets implemented for matrices.
def _eigenvals(
M, error_when_incomplete=True, *, simplify=False, multiple=False,
rational=False, **flags):
r"""Return eigenvalues using the Berkowitz agorithm to compute
the characteristic polynomial.
Parameters
==========
error_when_incomplete : bool, optional
If it is set to ``True``, it will raise an error if not all
eigenvalues are computed. This is caused by ``roots`` not returning
a full list of eigenvalues.
simplify : bool or function, optional
If it is set to ``True``, it attempts to return the most
simplified form of expressions returned by applying default
simplification method in every routine.
If it is set to ``False``, it will skip simplification in this
particular routine to save computation resources.
If a function is passed to, it will attempt to apply
the particular function as simplification method.
rational : bool, optional
If it is set to ``True``, every floating point numbers would be
replaced with rationals before computation. It can solve some
issues of ``roots`` routine not working well with floats.
multiple : bool, optional
If it is set to ``True``, the result will be in the form of a
list.
If it is set to ``False``, the result will be in the form of a
dictionary.
Returns
=======
eigs : list or dict
Eigenvalues of a matrix. The return format would be specified by
the key ``multiple``.
Raises
======
MatrixError
If not enough roots had got computed.
NonSquareMatrixError
If attempted to compute eigenvalues from a non-square matrix.
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix(3, 3, [0, 1, 1, 1, 0, 0, 1, 1, 1])
>>> M.eigenvals()
{-1: 1, 0: 1, 2: 1}
See Also
========
MatrixDeterminant.charpoly
eigenvects
Notes
=====
Eigenvalues of a matrix `A` can be computed by solving a matrix
equation `\det(A - \lambda I) = 0`
"""
if not M:
if multiple:
return []
return {}
if not M.is_square:
raise NonSquareMatrixError("{} must be a square matrix.".format(M))
if M.is_upper or M.is_lower:
return _eigenvals_triangular(M, multiple=multiple)
if all(x.is_number for x in M) and M.has(Float):
return _eigenvals_mpmath(M, multiple=multiple)
if rational:
M = M.applyfunc(
lambda x: nsimplify(x, rational=True) if x.has(Float) else x)
if multiple:
return _eigenvals_list(
M, error_when_incomplete=error_when_incomplete, simplify=simplify,
**flags)
return _eigenvals_dict(
M, error_when_incomplete=error_when_incomplete, simplify=simplify,
**flags)
def _eigenvals_list(
M, error_when_incomplete=True, simplify=False, **flags):
iblocks = M.connected_components()
all_eigs = []
for b in iblocks:
block = M[b, b]
if isinstance(simplify, FunctionType):
charpoly = block.charpoly(simplify=simplify)
else:
charpoly = block.charpoly()
eigs = roots(charpoly, multiple=True, **flags)
if error_when_incomplete:
if len(eigs) != block.rows:
raise MatrixError(
"Could not compute eigenvalues for {}. if you see this "
"error, please report to SymPy issue tracker."
.format(block))
all_eigs += eigs
if not simplify:
return all_eigs
if not isinstance(simplify, FunctionType):
simplify = _simplify
return [simplify(value) for value in all_eigs]
def _eigenvals_dict(
M, error_when_incomplete=True, simplify=False, **flags):
iblocks = M.connected_components()
all_eigs = {}
for b in iblocks:
block = M[b, b]
if isinstance(simplify, FunctionType):
charpoly = block.charpoly(simplify=simplify)
else:
charpoly = block.charpoly()
eigs = roots(charpoly, multiple=False, **flags)
if error_when_incomplete:
if sum(eigs.values()) != block.rows:
raise MatrixError(
"Could not compute eigenvalues for {}. if you see this "
"error, please report to SymPy issue tracker."
.format(block))
for k, v in eigs.items():
if k in all_eigs:
all_eigs[k] += v
else:
all_eigs[k] = v
if not simplify:
return all_eigs
if not isinstance(simplify, FunctionType):
simplify = _simplify
return {simplify(key): value for key, value in all_eigs.items()}
def _eigenspace(M, eigenval, iszerofunc=_iszero, simplify=False):
"""Get a basis for the eigenspace for a particular eigenvalue"""
m = M - M.eye(M.rows) * eigenval
ret = m.nullspace(iszerofunc=iszerofunc)
# The nullspace for a real eigenvalue should be non-trivial.
# If we didn't find an eigenvector, try once more a little harder
if len(ret) == 0 and simplify:
ret = m.nullspace(iszerofunc=iszerofunc, simplify=True)
if len(ret) == 0:
raise NotImplementedError(
"Can't evaluate eigenvector for eigenvalue {}".format(eigenval))
return ret
# This functions is a candidate for caching if it gets implemented for matrices.
def _eigenvects(M, error_when_incomplete=True, iszerofunc=_iszero, **flags):
"""Return list of triples (eigenval, multiplicity, eigenspace).
Parameters
==========
error_when_incomplete : bool, optional
Raise an error when not all eigenvalues are computed. This is
caused by ``roots`` not returning a full list of eigenvalues.
iszerofunc : function, optional
Specifies a zero testing function to be used in ``rref``.
Default value is ``_iszero``, which uses SymPy's naive and fast
default assumption handler.
It can also accept any user-specified zero testing function, if it
is formatted as a function which accepts a single symbolic argument
and returns ``True`` if it is tested as zero and ``False`` if it
is tested as non-zero, and ``None`` if it is undecidable.
simplify : bool or function, optional
If ``True``, ``as_content_primitive()`` will be used to tidy up
normalization artifacts.
It will also be used by the ``nullspace`` routine.
chop : bool or positive number, optional
If the matrix contains any Floats, they will be changed to Rationals
for computation purposes, but the answers will be returned after
being evaluated with evalf. The ``chop`` flag is passed to ``evalf``.
When ``chop=True`` a default precision will be used; a number will
be interpreted as the desired level of precision.
Returns
=======
ret : [(eigenval, multiplicity, eigenspace), ...]
A ragged list containing tuples of data obtained by ``eigenvals``
and ``nullspace``.
``eigenspace`` is a list containing the ``eigenvector`` for each
eigenvalue.
``eigenvector`` is a vector in the form of a ``Matrix``. e.g.
a vector of length 3 is returned as ``Matrix([a_1, a_2, a_3])``.
Raises
======
NotImplementedError
If failed to compute nullspace.
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix(3, 3, [0, 1, 1, 1, 0, 0, 1, 1, 1])
>>> M.eigenvects()
[(-1, 1, [Matrix([
[-1],
[ 1],
[ 0]])]), (0, 1, [Matrix([
[ 0],
[-1],
[ 1]])]), (2, 1, [Matrix([
[2/3],
[1/3],
[ 1]])])]
See Also
========
eigenvals
MatrixSubspaces.nullspace
"""
simplify = flags.get('simplify', True)
primitive = flags.get('simplify', False)
chop = flags.pop('chop', False)
flags.pop('multiple', None) # remove this if it's there
if not isinstance(simplify, FunctionType):
simpfunc = _simplify if simplify else lambda x: x
has_floats = M.has(Float)
if has_floats:
if all(x.is_number for x in M):
return _eigenvects_mpmath(M)
M = M.applyfunc(lambda x: nsimplify(x, rational=True))
eigenvals = M.eigenvals(
rational=False, error_when_incomplete=error_when_incomplete,
**flags)
eigenvals = sorted(eigenvals.items(), key=default_sort_key)
ret = []
for val, mult in eigenvals:
vects = _eigenspace(M, val, iszerofunc=iszerofunc, simplify=simplify)
ret.append((val, mult, vects))
if primitive:
# if the primitive flag is set, get rid of any common
# integer denominators
def denom_clean(l):
from sympy import gcd
return [(v / gcd(list(v))).applyfunc(simpfunc) for v in l]
ret = [(val, mult, denom_clean(es)) for val, mult, es in ret]
if has_floats:
# if we had floats to start with, turn the eigenvectors to floats
ret = [(val.evalf(chop=chop), mult, [v.evalf(chop=chop) for v in es])
for val, mult, es in ret]
return ret
def _is_diagonalizable_with_eigen(M, reals_only=False):
"""See _is_diagonalizable. This function returns the bool along with the
eigenvectors to avoid calculating them again in functions like
``diagonalize``."""
if not M.is_square:
return False, []
eigenvecs = M.eigenvects(simplify=True)
for val, mult, basis in eigenvecs:
if reals_only and not val.is_real: # if we have a complex eigenvalue
return False, eigenvecs
if mult != len(basis): # if the geometric multiplicity doesn't equal the algebraic
return False, eigenvecs
return True, eigenvecs
def _is_diagonalizable(M, reals_only=False, **kwargs):
"""Returns ``True`` if a matrix is diagonalizable.
Parameters
==========
reals_only : bool, optional
If ``True``, it tests whether the matrix can be diagonalized
to contain only real numbers on the diagonal.
If ``False``, it tests whether the matrix can be diagonalized
at all, even with numbers that may not be real.
Examples
========
Example of a diagonalizable matrix:
>>> from sympy import Matrix
>>> M = Matrix([[1, 2, 0], [0, 3, 0], [2, -4, 2]])
>>> M.is_diagonalizable()
True
Example of a non-diagonalizable matrix:
>>> M = Matrix([[0, 1], [0, 0]])
>>> M.is_diagonalizable()
False
Example of a matrix that is diagonalized in terms of non-real entries:
>>> M = Matrix([[0, 1], [-1, 0]])
>>> M.is_diagonalizable(reals_only=False)
True
>>> M.is_diagonalizable(reals_only=True)
False
See Also
========
is_diagonal
diagonalize
"""
if 'clear_cache' in kwargs:
SymPyDeprecationWarning(
feature='clear_cache',
deprecated_since_version=1.4,
issue=15887
).warn()
if 'clear_subproducts' in kwargs:
SymPyDeprecationWarning(
feature='clear_subproducts',
deprecated_since_version=1.4,
issue=15887
).warn()
if not M.is_square:
return False
if all(e.is_real for e in M) and M.is_symmetric():
return True
if all(e.is_complex for e in M) and M.is_hermitian:
return True
return _is_diagonalizable_with_eigen(M, reals_only=reals_only)[0]
#G&VL, Matrix Computations, Algo 5.4.2
def _householder_vector(x):
if not x.cols == 1:
raise ValueError("Input must be a column matrix")
v = x.copy()
v_plus = x.copy()
v_minus = x.copy()
q = x[0, 0] / abs(x[0, 0])
norm_x = x.norm()
v_plus[0, 0] = x[0, 0] + q * norm_x
v_minus[0, 0] = x[0, 0] - q * norm_x
if x[1:, 0].norm() == 0:
bet = 0
v[0, 0] = 1
else:
if v_plus.norm() <= v_minus.norm():
v = v_plus
else:
v = v_minus
v = v / v[0]
bet = 2 / (v.norm() ** 2)
return v, bet
def _bidiagonal_decmp_hholder(M):
m = M.rows
n = M.cols
A = M.as_mutable()
U, V = A.eye(m), A.eye(n)
for i in range(min(m, n)):
v, bet = _householder_vector(A[i:, i])
hh_mat = A.eye(m - i) - bet * v * v.H
A[i:, i:] = hh_mat * A[i:, i:]
temp = A.eye(m)
temp[i:, i:] = hh_mat
U = U * temp
if i + 1 <= n - 2:
v, bet = _householder_vector(A[i, i+1:].T)
hh_mat = A.eye(n - i - 1) - bet * v * v.H
A[i:, i+1:] = A[i:, i+1:] * hh_mat
temp = A.eye(n)
temp[i+1:, i+1:] = hh_mat
V = temp * V
return U, A, V
def _eval_bidiag_hholder(M):
m = M.rows
n = M.cols
A = M.as_mutable()
for i in range(min(m, n)):
v, bet = _householder_vector(A[i:, i])
hh_mat = A.eye(m-i) - bet * v * v.H
A[i:, i:] = hh_mat * A[i:, i:]
if i + 1 <= n - 2:
v, bet = _householder_vector(A[i, i+1:].T)
hh_mat = A.eye(n - i - 1) - bet * v * v.H
A[i:, i+1:] = A[i:, i+1:] * hh_mat
return A
def _bidiagonal_decomposition(M, upper=True):
"""
Returns (U,B,V.H)
`A = UBV^{H}`
where A is the input matrix, and B is its Bidiagonalized form
Note: Bidiagonal Computation can hang for symbolic matrices.
Parameters
==========
upper : bool. Whether to do upper bidiagnalization or lower.
True for upper and False for lower.
References
==========
1. Algorith 5.4.2, Matrix computations by Golub and Van Loan, 4th edition
2. Complex Matrix Bidiagonalization : https://github.com/vslobody/Householder-Bidiagonalization
"""
if type(upper) is not bool:
raise ValueError("upper must be a boolean")
if not upper:
X = _bidiagonal_decmp_hholder(M.H)
return X[2].H, X[1].H, X[0].H
return _bidiagonal_decmp_hholder(M)
def _bidiagonalize(M, upper=True):
"""
Returns `B`
where B is the Bidiagonalized form of the input matrix.
Note: Bidiagonal Computation can hang for symbolic matrices.
Parameters
==========
upper : bool. Whether to do upper bidiagnalization or lower.
True for upper and False for lower.
References
==========
1. Algorith 5.4.2, Matrix computations by Golub and Van Loan, 4th edition
2. Complex Matrix Bidiagonalization : https://github.com/vslobody/Householder-Bidiagonalization
"""
if type(upper) is not bool:
raise ValueError("upper must be a boolean")
if not upper:
return _eval_bidiag_hholder(M.H).H
return _eval_bidiag_hholder(M)
def _diagonalize(M, reals_only=False, sort=False, normalize=False):
"""
Return (P, D), where D is diagonal and
D = P^-1 * M * P
where M is current matrix.
Parameters
==========
reals_only : bool. Whether to throw an error if complex numbers are need
to diagonalize. (Default: False)
sort : bool. Sort the eigenvalues along the diagonal. (Default: False)
normalize : bool. If True, normalize the columns of P. (Default: False)
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix(3, 3, [1, 2, 0, 0, 3, 0, 2, -4, 2])
>>> M
Matrix([
[1, 2, 0],
[0, 3, 0],
[2, -4, 2]])
>>> (P, D) = M.diagonalize()
>>> D
Matrix([
[1, 0, 0],
[0, 2, 0],
[0, 0, 3]])
>>> P
Matrix([
[-1, 0, -1],
[ 0, 0, -1],
[ 2, 1, 2]])
>>> P.inv() * M * P
Matrix([
[1, 0, 0],
[0, 2, 0],
[0, 0, 3]])
See Also
========
is_diagonal
is_diagonalizable
"""
if not M.is_square:
raise NonSquareMatrixError()
is_diagonalizable, eigenvecs = _is_diagonalizable_with_eigen(M,
reals_only=reals_only)
if not is_diagonalizable:
raise MatrixError("Matrix is not diagonalizable")
if sort:
eigenvecs = sorted(eigenvecs, key=default_sort_key)
p_cols, diag = [], []
for val, mult, basis in eigenvecs:
diag += [val] * mult
p_cols += basis
if normalize:
p_cols = [v / v.norm() for v in p_cols]
return M.hstack(*p_cols), M.diag(*diag)
def _fuzzy_positive_definite(M):
positive_diagonals = M._has_positive_diagonals()
if positive_diagonals is False:
return False
if positive_diagonals and M.is_strongly_diagonally_dominant:
return True
return None
def _is_positive_definite(M):
if not M.is_hermitian:
if not M.is_square:
return False
M = M + M.H
fuzzy = _fuzzy_positive_definite(M)
if fuzzy is not None:
return fuzzy
return _is_positive_definite_GE(M)
def _is_positive_semidefinite(M):
if not M.is_hermitian:
if not M.is_square:
return False
M = M + M.H
nonnegative_diagonals = M._has_nonnegative_diagonals()
if nonnegative_diagonals is False:
return False
if nonnegative_diagonals and M.is_weakly_diagonally_dominant:
return True
return _is_positive_semidefinite_minors(M)
def _is_negative_definite(M):
return _is_positive_definite(-M)
def _is_negative_semidefinite(M):
return _is_positive_semidefinite(-M)
def _is_indefinite(M):
if M.is_hermitian:
eigen = M.eigenvals()
args1 = [x.is_positive for x in eigen.keys()]
any_positive = fuzzy_or(args1)
args2 = [x.is_negative for x in eigen.keys()]
any_negative = fuzzy_or(args2)
return fuzzy_and([any_positive, any_negative])
elif M.is_square:
return (M + M.H).is_indefinite
return False
def _is_positive_definite_GE(M):
"""A division-free gaussian elimination method for testing
positive-definiteness."""
M = M.as_mutable()
size = M.rows
for i in range(size):
is_positive = M[i, i].is_positive
if is_positive is not True:
return is_positive
for j in range(i+1, size):
M[j, i+1:] = M[i, i] * M[j, i+1:] - M[j, i] * M[i, i+1:]
return True
def _is_positive_semidefinite_minors(M):
"""A method to evaluate all principal minors for testing
positive-semidefiniteness."""
size = M.rows
for i in range(size):
minor = M[:i+1, :i+1].det(method='berkowitz')
is_nonnegative = minor.is_nonnegative
if is_nonnegative is not True:
return is_nonnegative
return True
_doc_positive_definite = \
r"""Finds out the definiteness of a matrix.
Examples
========
An example of numeric positive definite matrix:
>>> from sympy import Matrix
>>> A = Matrix([[1, -2], [-2, 6]])
>>> A.is_positive_definite
True
>>> A.is_positive_semidefinite
True
>>> A.is_negative_definite
False
>>> A.is_negative_semidefinite
False
>>> A.is_indefinite
False
An example of numeric negative definite matrix:
>>> A = Matrix([[-1, 2], [2, -6]])
>>> A.is_positive_definite
False
>>> A.is_positive_semidefinite
False
>>> A.is_negative_definite
True
>>> A.is_negative_semidefinite
True
>>> A.is_indefinite
False
An example of numeric indefinite matrix:
>>> A = Matrix([[1, 2], [2, 1]])
>>> A.is_positive_definite
False
>>> A.is_positive_semidefinite
False
>>> A.is_negative_definite
False
>>> A.is_negative_semidefinite
False
>>> A.is_indefinite
True
Notes
=====
Definitiveness is not very commonly discussed for non-hermitian
matrices.
However, computing the definitiveness of a matrix can be
generalized over any real matrix by taking the symmetric part:
`A_S = 1/2 (A + A^{T})`
Or over any complex matrix by taking the hermitian part:
`A_H = 1/2 (A + A^{H})`
And computing the eigenvalues.
References
==========
.. [1] https://en.wikipedia.org/wiki/Definiteness_of_a_matrix#Eigenvalues
.. [2] http://mathworld.wolfram.com/PositiveDefiniteMatrix.html
.. [3] Johnson, C. R. "Positive Definite Matrices." Amer.
Math. Monthly 77, 259-264 1970.
"""
_is_positive_definite.__doc__ = _doc_positive_definite
_is_positive_semidefinite.__doc__ = _doc_positive_definite
_is_negative_definite.__doc__ = _doc_positive_definite
_is_negative_semidefinite.__doc__ = _doc_positive_definite
_is_indefinite.__doc__ = _doc_positive_definite
def _jordan_form(M, calc_transform=True, **kwargs):
"""Return ``(P, J)`` where `J` is a Jordan block
matrix and `P` is a matrix such that
``M == P*J*P**-1``
Parameters
==========
calc_transform : bool
If ``False``, then only `J` is returned.
chop : bool
All matrices are converted to exact types when computing
eigenvalues and eigenvectors. As a result, there may be
approximation errors. If ``chop==True``, these errors
will be truncated.
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix([[ 6, 5, -2, -3], [-3, -1, 3, 3], [ 2, 1, -2, -3], [-1, 1, 5, 5]])
>>> P, J = M.jordan_form()
>>> J
Matrix([
[2, 1, 0, 0],
[0, 2, 0, 0],
[0, 0, 2, 1],
[0, 0, 0, 2]])
See Also
========
jordan_block
"""
if not M.is_square:
raise NonSquareMatrixError("Only square matrices have Jordan forms")
chop = kwargs.pop('chop', False)
mat = M
has_floats = M.has(Float)
if has_floats:
try:
max_prec = max(term._prec for term in M._mat if isinstance(term, Float))
except ValueError:
# if no term in the matrix is explicitly a Float calling max()
# will throw a error so setting max_prec to default value of 53
max_prec = 53
# setting minimum max_dps to 15 to prevent loss of precision in
# matrix containing non evaluated expressions
max_dps = max(prec_to_dps(max_prec), 15)
def restore_floats(*args):
"""If ``has_floats`` is `True`, cast all ``args`` as
matrices of floats."""
if has_floats:
args = [m.evalf(n=max_dps, chop=chop) for m in args]
if len(args) == 1:
return args[0]
return args
# cache calculations for some speedup
mat_cache = {}
def eig_mat(val, pow):
"""Cache computations of ``(M - val*I)**pow`` for quick
retrieval"""
if (val, pow) in mat_cache:
return mat_cache[(val, pow)]
if (val, pow - 1) in mat_cache:
mat_cache[(val, pow)] = mat_cache[(val, pow - 1)].multiply(
mat_cache[(val, 1)], dotprodsimp=True)
else:
mat_cache[(val, pow)] = (mat - val*M.eye(M.rows)).pow(pow)
return mat_cache[(val, pow)]
# helper functions
def nullity_chain(val, algebraic_multiplicity):
"""Calculate the sequence [0, nullity(E), nullity(E**2), ...]
until it is constant where ``E = M - val*I``"""
# mat.rank() is faster than computing the null space,
# so use the rank-nullity theorem
cols = M.cols
ret = [0]
nullity = cols - eig_mat(val, 1).rank()
i = 2
while nullity != ret[-1]:
ret.append(nullity)
if nullity == algebraic_multiplicity:
break
nullity = cols - eig_mat(val, i).rank()
i += 1
# Due to issues like #7146 and #15872, SymPy sometimes
# gives the wrong rank. In this case, raise an error
# instead of returning an incorrect matrix
if nullity < ret[-1] or nullity > algebraic_multiplicity:
raise MatrixError(
"SymPy had encountered an inconsistent "
"result while computing Jordan block: "
"{}".format(M))
return ret
def blocks_from_nullity_chain(d):
"""Return a list of the size of each Jordan block.
If d_n is the nullity of E**n, then the number
of Jordan blocks of size n is
2*d_n - d_(n-1) - d_(n+1)"""
# d[0] is always the number of columns, so skip past it
mid = [2*d[n] - d[n - 1] - d[n + 1] for n in range(1, len(d) - 1)]
# d is assumed to plateau with "d[ len(d) ] == d[-1]", so
# 2*d_n - d_(n-1) - d_(n+1) == d_n - d_(n-1)
end = [d[-1] - d[-2]] if len(d) > 1 else [d[0]]
return mid + end
def pick_vec(small_basis, big_basis):
"""Picks a vector from big_basis that isn't in
the subspace spanned by small_basis"""
if len(small_basis) == 0:
return big_basis[0]
for v in big_basis:
_, pivots = M.hstack(*(small_basis + [v])).echelon_form(
with_pivots=True)
if pivots[-1] == len(small_basis):
return v
# roots doesn't like Floats, so replace them with Rationals
if has_floats:
mat = mat.applyfunc(lambda x: nsimplify(x, rational=True))
# first calculate the jordan block structure
eigs = mat.eigenvals()
# make sure that we found all the roots by counting
# the algebraic multiplicity
if sum(m for m in eigs.values()) != mat.cols:
raise MatrixError("Could not compute eigenvalues for {}".format(mat))
# most matrices have distinct eigenvalues
# and so are diagonalizable. In this case, don't
# do extra work!
if len(eigs.keys()) == mat.cols:
blocks = list(sorted(eigs.keys(), key=default_sort_key))
jordan_mat = mat.diag(*blocks)
if not calc_transform:
return restore_floats(jordan_mat)
jordan_basis = [eig_mat(eig, 1).nullspace()[0]
for eig in blocks]
basis_mat = mat.hstack(*jordan_basis)
return restore_floats(basis_mat, jordan_mat)
block_structure = []
for eig in sorted(eigs.keys(), key=default_sort_key):
algebraic_multiplicity = eigs[eig]
chain = nullity_chain(eig, algebraic_multiplicity)
block_sizes = blocks_from_nullity_chain(chain)
# if block_sizes = = [a, b, c, ...], then the number of
# Jordan blocks of size 1 is a, of size 2 is b, etc.
# create an array that has (eig, block_size) with one
# entry for each block
size_nums = [(i+1, num) for i, num in enumerate(block_sizes)]
# we expect larger Jordan blocks to come earlier
size_nums.reverse()
block_structure.extend(
(eig, size) for size, num in size_nums for _ in range(num))
jordan_form_size = sum(size for eig, size in block_structure)
if jordan_form_size != M.rows:
raise MatrixError(
"SymPy had encountered an inconsistent result while "
"computing Jordan block. : {}".format(M))
blocks = (mat.jordan_block(size=size, eigenvalue=eig) for eig, size in block_structure)
jordan_mat = mat.diag(*blocks)
if not calc_transform:
return restore_floats(jordan_mat)
# For each generalized eigenspace, calculate a basis.
# We start by looking for a vector in null( (A - eig*I)**n )
# which isn't in null( (A - eig*I)**(n-1) ) where n is
# the size of the Jordan block
#
# Ideally we'd just loop through block_structure and
# compute each generalized eigenspace. However, this
# causes a lot of unneeded computation. Instead, we
# go through the eigenvalues separately, since we know
# their generalized eigenspaces must have bases that
# are linearly independent.
jordan_basis = []
for eig in sorted(eigs.keys(), key=default_sort_key):
eig_basis = []
for block_eig, size in block_structure:
if block_eig != eig:
continue
null_big = (eig_mat(eig, size)).nullspace()
null_small = (eig_mat(eig, size - 1)).nullspace()
# we want to pick something that is in the big basis
# and not the small, but also something that is independent
# of any other generalized eigenvectors from a different
# generalized eigenspace sharing the same eigenvalue.
vec = pick_vec(null_small + eig_basis, null_big)
new_vecs = [eig_mat(eig, i).multiply(vec, dotprodsimp=True)
for i in range(size)]
eig_basis.extend(new_vecs)
jordan_basis.extend(reversed(new_vecs))
basis_mat = mat.hstack(*jordan_basis)
return restore_floats(basis_mat, jordan_mat)
def _left_eigenvects(M, **flags):
"""Returns left eigenvectors and eigenvalues.
This function returns the list of triples (eigenval, multiplicity,
basis) for the left eigenvectors. Options are the same as for
eigenvects(), i.e. the ``**flags`` arguments gets passed directly to
eigenvects().
Examples
========
>>> from sympy.matrices import Matrix
>>> M = Matrix([[0, 1, 1], [1, 0, 0], [1, 1, 1]])
>>> M.eigenvects()
[(-1, 1, [Matrix([
[-1],
[ 1],
[ 0]])]), (0, 1, [Matrix([
[ 0],
[-1],
[ 1]])]), (2, 1, [Matrix([
[2/3],
[1/3],
[ 1]])])]
>>> M.left_eigenvects()
[(-1, 1, [Matrix([[-2, 1, 1]])]), (0, 1, [Matrix([[-1, -1, 1]])]), (2,
1, [Matrix([[1, 1, 1]])])]
"""
eigs = M.transpose().eigenvects(**flags)
return [(val, mult, [l.transpose() for l in basis]) for val, mult, basis in eigs]
def _singular_values(M):
"""Compute the singular values of a Matrix
Examples
========
>>> from sympy import Matrix, Symbol
>>> x = Symbol('x', real=True)
>>> M = Matrix([[0, 1, 0], [0, x, 0], [-1, 0, 0]])
>>> M.singular_values()
[sqrt(x**2 + 1), 1, 0]
See Also
========
condition_number
"""
if M.rows >= M.cols:
valmultpairs = M.H.multiply(M).eigenvals()
else:
valmultpairs = M.multiply(M.H).eigenvals()
# Expands result from eigenvals into a simple list
vals = []
for k, v in valmultpairs.items():
vals += [sqrt(k)] * v # dangerous! same k in several spots!
# Pad with zeros if singular values are computed in reverse way,
# to give consistent format.
if len(vals) < M.cols:
vals += [M.zero] * (M.cols - len(vals))
# sort them in descending order
vals.sort(reverse=True, key=default_sort_key)
return vals
|
9bf599d4646c3d3f269edbcee8872e69447b6ab48fe35a92585d91e14ff43471 | from sympy.core import Basic, Integer
import operator
class OmegaPower(Basic):
"""
Represents ordinal exponential and multiplication terms one of the
building blocks of the Ordinal class.
In OmegaPower(a, b) a represents exponent and b represents multiplicity.
"""
def __new__(cls, a, b):
if isinstance(b, int):
b = Integer(b)
if not isinstance(b, Integer) or b <= 0:
raise TypeError("multiplicity must be a positive integer")
if not isinstance(a, Ordinal):
a = Ordinal.convert(a)
return Basic.__new__(cls, a, b)
@property
def exp(self):
return self.args[0]
@property
def mult(self):
return self.args[1]
def _compare_term(self, other, op):
if self.exp == other.exp:
return op(self.mult, other.mult)
else:
return op(self.exp, other.exp)
def __eq__(self, other):
if not isinstance(other, OmegaPower):
try:
other = OmegaPower(0, other)
except TypeError:
return NotImplemented
return self.args == other.args
def __hash__(self):
return Basic.__hash__(self)
def __lt__(self, other):
if not isinstance(other, OmegaPower):
try:
other = OmegaPower(0, other)
except TypeError:
return NotImplemented
return self._compare_term(other, operator.lt)
class Ordinal(Basic):
"""
Represents ordinals in Cantor normal form.
Internally, this class is just a list of instances of OmegaPower
Examples
========
>>> from sympy.sets import Ordinal, OmegaPower
>>> from sympy.sets.ordinals import omega
>>> w = omega
>>> w.is_limit_ordinal
True
>>> Ordinal(OmegaPower(w + 1 ,1), OmegaPower(3, 2))
w**(w + 1) + w**3*2
>>> 3 + w
w
>>> (w + 1) * w
w**2
References
==========
.. [1] https://en.wikipedia.org/wiki/Ordinal_arithmetic
"""
def __new__(cls, *terms):
obj = super(Ordinal, cls).__new__(cls, *terms)
powers = [i.exp for i in obj.args]
if not all(powers[i] >= powers[i+1] for i in range(len(powers) - 1)):
raise ValueError("powers must be in decreasing order")
return obj
@property
def terms(self):
return self.args
@property
def leading_term(self):
if self == ord0:
raise ValueError("ordinal zero has no leading term")
return self.terms[0]
@property
def trailing_term(self):
if self == ord0:
raise ValueError("ordinal zero has no trailing term")
return self.terms[-1]
@property
def is_successor_ordinal(self):
try:
return self.trailing_term.exp == ord0
except ValueError:
return False
@property
def is_limit_ordinal(self):
try:
return not self.trailing_term.exp == ord0
except ValueError:
return False
@property
def degree(self):
return self.leading_term.exp
@classmethod
def convert(cls, integer_value):
if integer_value == 0:
return ord0
return Ordinal(OmegaPower(0, integer_value))
def __eq__(self, other):
if not isinstance(other, Ordinal):
try:
other = Ordinal.convert(other)
except TypeError:
return NotImplemented
return self.terms == other.terms
def __hash__(self):
return hash(self.args)
def __lt__(self, other):
if not isinstance(other, Ordinal):
try:
other = Ordinal.convert(other)
except TypeError:
return NotImplemented
for term_self, term_other in zip(self.terms, other.terms):
if term_self != term_other:
return term_self < term_other
return len(self.terms) < len(other.terms)
def __le__(self, other):
return (self == other or self < other)
def __gt__(self, other):
return not self <= other
def __ge__(self, other):
return not self < other
def __str__(self):
net_str = ""
plus_count = 0
if self == ord0:
return 'ord0'
for i in self.terms:
if plus_count:
net_str += " + "
if i.exp == ord0:
net_str += str(i.mult)
elif i.exp == 1:
net_str += 'w'
elif len(i.exp.terms) > 1 or i.exp.is_limit_ordinal:
net_str += 'w**(%s)'%i.exp
else:
net_str += 'w**%s'%i.exp
if not i.mult == 1 and not i.exp == ord0:
net_str += '*%s'%i.mult
plus_count += 1
return(net_str)
__repr__ = __str__
def __add__(self, other):
if not isinstance(other, Ordinal):
try:
other = Ordinal.convert(other)
except TypeError:
return NotImplemented
if other == ord0:
return self
a_terms = list(self.terms)
b_terms = list(other.terms)
r = len(a_terms) - 1
b_exp = other.degree
while r >= 0 and a_terms[r].exp < b_exp:
r -= 1
if r < 0:
terms = b_terms
elif a_terms[r].exp == b_exp:
sum_term = OmegaPower(b_exp, a_terms[r].mult + other.leading_term.mult)
terms = a_terms[:r] + [sum_term] + b_terms[1:]
else:
terms = a_terms[:r+1] + b_terms
return Ordinal(*terms)
def __radd__(self, other):
if not isinstance(other, Ordinal):
try:
other = Ordinal.convert(other)
except TypeError:
return NotImplemented
return other + self
def __mul__(self, other):
if not isinstance(other, Ordinal):
try:
other = Ordinal.convert(other)
except TypeError:
return NotImplemented
if ord0 in (self, other):
return ord0
a_exp = self.degree
a_mult = self.leading_term.mult
sum = []
if other.is_limit_ordinal:
for arg in other.terms:
sum.append(OmegaPower(a_exp + arg.exp, arg.mult))
else:
for arg in other.terms[:-1]:
sum.append(OmegaPower(a_exp + arg.exp, arg.mult))
b_mult = other.trailing_term.mult
sum.append(OmegaPower(a_exp, a_mult*b_mult))
sum += list(self.terms[1:])
return Ordinal(*sum)
def __rmul__(self, other):
if not isinstance(other, Ordinal):
try:
other = Ordinal.convert(other)
except TypeError:
return NotImplemented
return other * self
def __pow__(self, other):
if not self == omega:
return NotImplemented
return Ordinal(OmegaPower(other, 1))
class OrdinalZero(Ordinal):
"""The ordinal zero.
OrdinalZero can be imported as ``ord0``.
"""
pass
class OrdinalOmega(Ordinal):
"""The ordinal omega which forms the base of all ordinals in cantor normal form.
OrdinalOmega can be imported as ``omega``.
Examples
========
>>> from sympy.sets.ordinals import omega
>>> omega + omega
w*2
"""
def __new__(cls):
return Ordinal.__new__(cls)
@property
def terms(self):
return (OmegaPower(1, 1),)
ord0 = OrdinalZero()
omega = OrdinalOmega()
|
b860d8d9042af9ba2511632bcb28ff5069ee32d92b67e64f969a8b10da4b18ee | from __future__ import print_function, division
from functools import reduce
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_not, fuzzy_or, fuzzy_and
from sympy.core.numbers import oo, Integer
from sympy.core.relational import Eq
from sympy.core.singleton import Singleton, S
from sympy.core.symbol import Dummy, symbols, Symbol
from sympy.core.sympify import _sympify, sympify, converter
from sympy.logic.boolalg import And
from sympy.sets.sets import (Set, Interval, Union, FiniteSet,
ProductSet)
from sympy.utilities.misc import filldedent
from sympy.utilities.iterables import cartes
class Rationals(Set, metaclass=Singleton):
"""
Represents the rational numbers. This set is also available as
the Singleton, S.Rationals.
Examples
========
>>> from sympy import S
>>> S.Half in S.Rationals
True
>>> iterable = iter(S.Rationals)
>>> [next(iterable) for i in range(12)]
[0, 1, -1, 1/2, 2, -1/2, -2, 1/3, 3, -1/3, -3, 2/3]
"""
is_iterable = True
_inf = S.NegativeInfinity
_sup = S.Infinity
is_empty = False
is_finite_set = False
def _contains(self, other):
if not isinstance(other, Expr):
return False
if other.is_Number:
return other.is_Rational
return other.is_rational
def __iter__(self):
from sympy.core.numbers import igcd, Rational
yield S.Zero
yield S.One
yield S.NegativeOne
d = 2
while True:
for n in range(d):
if igcd(n, d) == 1:
yield Rational(n, d)
yield Rational(d, n)
yield Rational(-n, d)
yield Rational(-d, n)
d += 1
@property
def _boundary(self):
return S.Reals
class Naturals(Set, metaclass=Singleton):
"""
Represents the natural numbers (or counting numbers) which are all
positive integers starting from 1. This set is also available as
the Singleton, S.Naturals.
Examples
========
>>> from sympy import S, Interval, pprint
>>> 5 in S.Naturals
True
>>> iterable = iter(S.Naturals)
>>> next(iterable)
1
>>> next(iterable)
2
>>> next(iterable)
3
>>> pprint(S.Naturals.intersect(Interval(0, 10)))
{1, 2, ..., 10}
See Also
========
Naturals0 : non-negative integers (i.e. includes 0, too)
Integers : also includes negative integers
"""
is_iterable = True
_inf = S.One
_sup = S.Infinity
is_empty = False
is_finite_set = False
def _contains(self, other):
if not isinstance(other, Expr):
return False
elif other.is_positive and other.is_integer:
return True
elif other.is_integer is False or other.is_positive is False:
return False
def _eval_is_subset(self, other):
return Range(1, oo).is_subset(other)
def _eval_is_superset(self, other):
return Range(1, oo).is_superset(other)
def __iter__(self):
i = self._inf
while True:
yield i
i = i + 1
@property
def _boundary(self):
return self
def as_relational(self, x):
from sympy.functions.elementary.integers import floor
return And(Eq(floor(x), x), x >= self.inf, x < oo)
class Naturals0(Naturals):
"""Represents the whole numbers which are all the non-negative integers,
inclusive of zero.
See Also
========
Naturals : positive integers; does not include 0
Integers : also includes the negative integers
"""
_inf = S.Zero
def _contains(self, other):
if not isinstance(other, Expr):
return S.false
elif other.is_integer and other.is_nonnegative:
return S.true
elif other.is_integer is False or other.is_nonnegative is False:
return S.false
def _eval_is_subset(self, other):
return Range(oo).is_subset(other)
def _eval_is_superset(self, other):
return Range(oo).is_superset(other)
class Integers(Set, metaclass=Singleton):
"""
Represents all integers: positive, negative and zero. This set is also
available as the Singleton, S.Integers.
Examples
========
>>> from sympy import S, Interval, pprint
>>> 5 in S.Naturals
True
>>> iterable = iter(S.Integers)
>>> next(iterable)
0
>>> next(iterable)
1
>>> next(iterable)
-1
>>> next(iterable)
2
>>> pprint(S.Integers.intersect(Interval(-4, 4)))
{-4, -3, ..., 4}
See Also
========
Naturals0 : non-negative integers
Integers : positive and negative integers and zero
"""
is_iterable = True
is_empty = False
is_finite_set = False
def _contains(self, other):
if not isinstance(other, Expr):
return S.false
return other.is_integer
def __iter__(self):
yield S.Zero
i = S.One
while True:
yield i
yield -i
i = i + 1
@property
def _inf(self):
return S.NegativeInfinity
@property
def _sup(self):
return S.Infinity
@property
def _boundary(self):
return self
def as_relational(self, x):
from sympy.functions.elementary.integers import floor
return And(Eq(floor(x), x), -oo < x, x < oo)
def _eval_is_subset(self, other):
return Range(-oo, oo).is_subset(other)
def _eval_is_superset(self, other):
return Range(-oo, oo).is_superset(other)
class Reals(Interval, metaclass=Singleton):
"""
Represents all real numbers
from negative infinity to positive infinity,
including all integer, rational and irrational numbers.
This set is also available as the Singleton, S.Reals.
Examples
========
>>> from sympy import S, Rational, pi, I
>>> 5 in S.Reals
True
>>> Rational(-1, 2) in S.Reals
True
>>> pi in S.Reals
True
>>> 3*I in S.Reals
False
>>> S.Reals.contains(pi)
True
See Also
========
ComplexRegion
"""
def __new__(cls):
return Interval.__new__(cls, S.NegativeInfinity, S.Infinity)
def __eq__(self, other):
return other == Interval(S.NegativeInfinity, S.Infinity)
def __hash__(self):
return hash(Interval(S.NegativeInfinity, S.Infinity))
class ImageSet(Set):
"""
Image of a set under a mathematical function. The transformation
must be given as a Lambda function which has as many arguments
as the elements of the set upon which it operates, e.g. 1 argument
when acting on the set of integers or 2 arguments when acting on
a complex region.
This function is not normally called directly, but is called
from `imageset`.
Examples
========
>>> from sympy import Symbol, S, pi, Dummy, Lambda
>>> from sympy.sets.sets import FiniteSet, Interval
>>> from sympy.sets.fancysets import ImageSet
>>> x = Symbol('x')
>>> N = S.Naturals
>>> squares = ImageSet(Lambda(x, x**2), N) # {x**2 for x in N}
>>> 4 in squares
True
>>> 5 in squares
False
>>> FiniteSet(0, 1, 2, 3, 4, 5, 6, 7, 9, 10).intersect(squares)
FiniteSet(1, 4, 9)
>>> square_iterable = iter(squares)
>>> for i in range(4):
... next(square_iterable)
1
4
9
16
If you want to get value for `x` = 2, 1/2 etc. (Please check whether the
`x` value is in `base_set` or not before passing it as args)
>>> squares.lamda(2)
4
>>> squares.lamda(S(1)/2)
1/4
>>> n = Dummy('n')
>>> solutions = ImageSet(Lambda(n, n*pi), S.Integers) # solutions of sin(x) = 0
>>> dom = Interval(-1, 1)
>>> dom.intersect(solutions)
FiniteSet(0)
See Also
========
sympy.sets.sets.imageset
"""
def __new__(cls, flambda, *sets):
if not isinstance(flambda, Lambda):
raise ValueError('First argument must be a Lambda')
signature = flambda.signature
if len(signature) != len(sets):
raise ValueError('Incompatible signature')
sets = [_sympify(s) for s in sets]
if not all(isinstance(s, Set) for s in sets):
raise TypeError("Set arguments to ImageSet should of type Set")
if not all(cls._check_sig(sg, st) for sg, st in zip(signature, sets)):
raise ValueError("Signature %s does not match sets %s" % (signature, sets))
if flambda is S.IdentityFunction and len(sets) == 1:
return sets[0]
if not set(flambda.variables) & flambda.expr.free_symbols:
is_empty = fuzzy_or(s.is_empty for s in sets)
if is_empty == True:
return S.EmptySet
elif is_empty == False:
return FiniteSet(flambda.expr)
return Basic.__new__(cls, flambda, *sets)
lamda = property(lambda self: self.args[0])
base_sets = property(lambda self: self.args[1:])
@property
def base_set(self):
# XXX: Maybe deprecate this? It is poorly defined in handling
# the multivariate case...
sets = self.base_sets
if len(sets) == 1:
return sets[0]
else:
return ProductSet(*sets).flatten()
@property
def base_pset(self):
return ProductSet(*self.base_sets)
@classmethod
def _check_sig(cls, sig_i, set_i):
if sig_i.is_symbol:
return True
elif isinstance(set_i, ProductSet):
sets = set_i.sets
if len(sig_i) != len(sets):
return False
# Recurse through the signature for nested tuples:
return all(cls._check_sig(ts, ps) for ts, ps in zip(sig_i, sets))
else:
# XXX: Need a better way of checking whether a set is a set of
# Tuples or not. For example a FiniteSet can contain Tuples
# but so can an ImageSet or a ConditionSet. Others like
# Integers, Reals etc can not contain Tuples. We could just
# list the possibilities here... Current code for e.g.
# _contains probably only works for ProductSet.
return True # Give the benefit of the doubt
def __iter__(self):
already_seen = set()
for i in self.base_pset:
val = self.lamda(*i)
if val in already_seen:
continue
else:
already_seen.add(val)
yield val
def _is_multivariate(self):
return len(self.lamda.variables) > 1
def _contains(self, other):
from sympy.solvers.solveset import _solveset_multi
def get_symsetmap(signature, base_sets):
'''Attempt to get a map of symbols to base_sets'''
queue = list(zip(signature, base_sets))
symsetmap = {}
for sig, base_set in queue:
if sig.is_symbol:
symsetmap[sig] = base_set
elif base_set.is_ProductSet:
sets = base_set.sets
if len(sig) != len(sets):
raise ValueError("Incompatible signature")
# Recurse
queue.extend(zip(sig, sets))
else:
# If we get here then we have something like sig = (x, y) and
# base_set = {(1, 2), (3, 4)}. For now we give up.
return None
return symsetmap
def get_equations(expr, candidate):
'''Find the equations relating symbols in expr and candidate.'''
queue = [(expr, candidate)]
for e, c in queue:
if not isinstance(e, Tuple):
yield Eq(e, c)
elif not isinstance(c, Tuple) or len(e) != len(c):
yield False
return
else:
queue.extend(zip(e, c))
# Get the basic objects together:
other = _sympify(other)
expr = self.lamda.expr
sig = self.lamda.signature
variables = self.lamda.variables
base_sets = self.base_sets
# Use dummy symbols for ImageSet parameters so they don't match
# anything in other
rep = {v: Dummy(v.name) for v in variables}
variables = [v.subs(rep) for v in variables]
sig = sig.subs(rep)
expr = expr.subs(rep)
# Map the parts of other to those in the Lambda expr
equations = []
for eq in get_equations(expr, other):
# Unsatisfiable equation?
if eq is False:
return False
equations.append(eq)
# Map the symbols in the signature to the corresponding domains
symsetmap = get_symsetmap(sig, base_sets)
if symsetmap is None:
# Can't factor the base sets to a ProductSet
return None
# Which of the variables in the Lambda signature need to be solved for?
symss = (eq.free_symbols for eq in equations)
variables = set(variables) & reduce(set.union, symss, set())
# Use internal multivariate solveset
variables = tuple(variables)
base_sets = [symsetmap[v] for v in variables]
solnset = _solveset_multi(equations, variables, base_sets)
if solnset is None:
return None
return fuzzy_not(solnset.is_empty)
@property
def is_iterable(self):
return all(s.is_iterable for s in self.base_sets)
def doit(self, **kwargs):
from sympy.sets.setexpr import SetExpr
f = self.lamda
sig = f.signature
if len(sig) == 1 and sig[0].is_symbol and isinstance(f.expr, Expr):
base_set = self.base_sets[0]
return SetExpr(base_set)._eval_func(f).set
if all(s.is_FiniteSet for s in self.base_sets):
return FiniteSet(*(f(*a) for a in cartes(*self.base_sets)))
return self
class Range(Set):
"""
Represents a range of integers. Can be called as Range(stop),
Range(start, stop), or Range(start, stop, step); when stop is
not given it defaults to 1.
`Range(stop)` is the same as `Range(0, stop, 1)` and the stop value
(juse as for Python ranges) is not included in the Range values.
>>> from sympy import Range
>>> list(Range(3))
[0, 1, 2]
The step can also be negative:
>>> list(Range(10, 0, -2))
[10, 8, 6, 4, 2]
The stop value is made canonical so equivalent ranges always
have the same args:
>>> Range(0, 10, 3)
Range(0, 12, 3)
Infinite ranges are allowed. ``oo`` and ``-oo`` are never included in the
set (``Range`` is always a subset of ``Integers``). If the starting point
is infinite, then the final value is ``stop - step``. To iterate such a
range, it needs to be reversed:
>>> from sympy import oo
>>> r = Range(-oo, 1)
>>> r[-1]
0
>>> next(iter(r))
Traceback (most recent call last):
...
TypeError: Cannot iterate over Range with infinite start
>>> next(iter(r.reversed))
0
Although Range is a set (and supports the normal set
operations) it maintains the order of the elements and can
be used in contexts where `range` would be used.
>>> from sympy import Interval
>>> Range(0, 10, 2).intersect(Interval(3, 7))
Range(4, 8, 2)
>>> list(_)
[4, 6]
Although slicing of a Range will always return a Range -- possibly
empty -- an empty set will be returned from any intersection that
is empty:
>>> Range(3)[:0]
Range(0, 0, 1)
>>> Range(3).intersect(Interval(4, oo))
EmptySet
>>> Range(3).intersect(Range(4, oo))
EmptySet
Range will accept symbolic arguments but has very limited support
for doing anything other than displaying the Range:
>>> from sympy import Symbol, pprint
>>> from sympy.abc import i, j, k
>>> Range(i, j, k).start
i
>>> Range(i, j, k).inf
Traceback (most recent call last):
...
ValueError: invalid method for symbolic range
Better success will be had when using integer symbols:
>>> n = Symbol('n', integer=True)
>>> r = Range(n, n + 20, 3)
>>> r.inf
n
>>> pprint(r)
{n, n + 3, ..., n + 17}
"""
is_iterable = True
def __new__(cls, *args):
from sympy.functions.elementary.integers import ceiling
if len(args) == 1:
if isinstance(args[0], range):
raise TypeError(
'use sympify(%s) to convert range to Range' % args[0])
# expand range
slc = slice(*args)
if slc.step == 0:
raise ValueError("step cannot be 0")
start, stop, step = slc.start or 0, slc.stop, slc.step or 1
try:
ok = []
for w in (start, stop, step):
w = sympify(w)
if w in [S.NegativeInfinity, S.Infinity] or (
w.has(Symbol) and w.is_integer != False):
ok.append(w)
elif not w.is_Integer:
raise ValueError
else:
ok.append(w)
except ValueError:
raise ValueError(filldedent('''
Finite arguments to Range must be integers; `imageset` can define
other cases, e.g. use `imageset(i, i/10, Range(3))` to give
[0, 1/10, 1/5].'''))
start, stop, step = ok
null = False
if any(i.has(Symbol) for i in (start, stop, step)):
if start == stop:
null = True
else:
end = stop
elif start.is_infinite:
span = step*(stop - start)
if span is S.NaN or span <= 0:
null = True
elif step.is_Integer and stop.is_infinite and abs(step) != 1:
raise ValueError(filldedent('''
Step size must be %s in this case.''' % (1 if step > 0 else -1)))
else:
end = stop
else:
oostep = step.is_infinite
if oostep:
step = S.One if step > 0 else S.NegativeOne
n = ceiling((stop - start)/step)
if n <= 0:
null = True
elif oostep:
end = start + 1
step = S.One # make it a canonical single step
else:
end = start + n*step
if null:
start = end = S.Zero
step = S.One
return Basic.__new__(cls, start, end, step)
start = property(lambda self: self.args[0])
stop = property(lambda self: self.args[1])
step = property(lambda self: self.args[2])
@property
def reversed(self):
"""Return an equivalent Range in the opposite order.
Examples
========
>>> from sympy import Range
>>> Range(10).reversed
Range(9, -1, -1)
"""
if self.has(Symbol):
_ = self.size # validate
if not self:
return self
return self.func(
self.stop - self.step, self.start - self.step, -self.step)
def _contains(self, other):
if not self:
return S.false
if other.is_infinite:
return S.false
if not other.is_integer:
return other.is_integer
if self.has(Symbol):
try:
_ = self.size # validate
except ValueError:
return
if self.start.is_finite:
ref = self.start
elif self.stop.is_finite:
ref = self.stop
else: # both infinite; step is +/- 1 (enforced by __new__)
return S.true
if self.size == 1:
return Eq(other, self[0])
res = (ref - other) % self.step
if res == S.Zero:
return And(other >= self.inf, other <= self.sup)
elif res.is_Integer: # off sequence
return S.false
else: # symbolic/unsimplified residue modulo step
return None
def __iter__(self):
if self.has(Symbol):
_ = self.size # validate
if self.start in [S.NegativeInfinity, S.Infinity]:
raise TypeError("Cannot iterate over Range with infinite start")
elif self:
i = self.start
step = self.step
while True:
if (step > 0 and not (self.start <= i < self.stop)) or \
(step < 0 and not (self.stop < i <= self.start)):
break
yield i
i += step
def __len__(self):
rv = self.size
if rv is S.Infinity:
raise ValueError('Use .size to get the length of an infinite Range')
return int(rv)
@property
def size(self):
if not self:
return S.Zero
dif = self.stop - self.start
if self.has(Symbol):
if dif.has(Symbol) or self.step.has(Symbol) or (
not self.start.is_integer and not self.stop.is_integer):
raise ValueError('invalid method for symbolic range')
if dif.is_infinite:
return S.Infinity
return Integer(abs(dif//self.step))
@property
def is_finite_set(self):
if self.start.is_integer and self.stop.is_integer:
return True
return self.size.is_finite
def __nonzero__(self):
return self.start != self.stop
__bool__ = __nonzero__
def __getitem__(self, i):
from sympy.functions.elementary.integers import ceiling
ooslice = "cannot slice from the end with an infinite value"
zerostep = "slice step cannot be zero"
infinite = "slicing not possible on range with infinite start"
# if we had to take every other element in the following
# oo, ..., 6, 4, 2, 0
# we might get oo, ..., 4, 0 or oo, ..., 6, 2
ambiguous = "cannot unambiguously re-stride from the end " + \
"with an infinite value"
if isinstance(i, slice):
if self.size.is_finite: # validates, too
start, stop, step = i.indices(self.size)
n = ceiling((stop - start)/step)
if n <= 0:
return Range(0)
canonical_stop = start + n*step
end = canonical_stop - step
ss = step*self.step
return Range(self[start], self[end] + ss, ss)
else: # infinite Range
start = i.start
stop = i.stop
if i.step == 0:
raise ValueError(zerostep)
step = i.step or 1
ss = step*self.step
#---------------------
# handle infinite Range
# i.e. Range(-oo, oo) or Range(oo, -oo, -1)
# --------------------
if self.start.is_infinite and self.stop.is_infinite:
raise ValueError(infinite)
#---------------------
# handle infinite on right
# e.g. Range(0, oo) or Range(0, -oo, -1)
# --------------------
if self.stop.is_infinite:
# start and stop are not interdependent --
# they only depend on step --so we use the
# equivalent reversed values
return self.reversed[
stop if stop is None else -stop + 1:
start if start is None else -start:
step].reversed
#---------------------
# handle infinite on the left
# e.g. Range(oo, 0, -1) or Range(-oo, 0)
# --------------------
# consider combinations of
# start/stop {== None, < 0, == 0, > 0} and
# step {< 0, > 0}
if start is None:
if stop is None:
if step < 0:
return Range(self[-1], self.start, ss)
elif step > 1:
raise ValueError(ambiguous)
else: # == 1
return self
elif stop < 0:
if step < 0:
return Range(self[-1], self[stop], ss)
else: # > 0
return Range(self.start, self[stop], ss)
elif stop == 0:
if step > 0:
return Range(0)
else: # < 0
raise ValueError(ooslice)
elif stop == 1:
if step > 0:
raise ValueError(ooslice) # infinite singleton
else: # < 0
raise ValueError(ooslice)
else: # > 1
raise ValueError(ooslice)
elif start < 0:
if stop is None:
if step < 0:
return Range(self[start], self.start, ss)
else: # > 0
return Range(self[start], self.stop, ss)
elif stop < 0:
return Range(self[start], self[stop], ss)
elif stop == 0:
if step < 0:
raise ValueError(ooslice)
else: # > 0
return Range(0)
elif stop > 0:
raise ValueError(ooslice)
elif start == 0:
if stop is None:
if step < 0:
raise ValueError(ooslice) # infinite singleton
elif step > 1:
raise ValueError(ambiguous)
else: # == 1
return self
elif stop < 0:
if step > 1:
raise ValueError(ambiguous)
elif step == 1:
return Range(self.start, self[stop], ss)
else: # < 0
return Range(0)
else: # >= 0
raise ValueError(ooslice)
elif start > 0:
raise ValueError(ooslice)
else:
if not self:
raise IndexError('Range index out of range')
if i == 0:
if self.start.is_infinite:
raise ValueError(ooslice)
if self.has(Symbol):
if (self.stop > self.start) == self.step.is_positive and self.step.is_positive is not None:
pass
else:
_ = self.size # validate
return self.start
if i == -1:
if self.stop.is_infinite:
raise ValueError(ooslice)
n = self.stop - self.step
if n.is_Integer or (
n.is_integer and (
(n - self.start).is_nonnegative ==
self.step.is_positive)):
return n
_ = self.size # validate
rv = (self.stop if i < 0 else self.start) + i*self.step
if rv.is_infinite:
raise ValueError(ooslice)
if rv < self.inf or rv > self.sup:
raise IndexError("Range index out of range")
return rv
@property
def _inf(self):
if not self:
raise NotImplementedError
if self.has(Symbol):
if self.step.is_positive:
return self[0]
elif self.step.is_negative:
return self[-1]
_ = self.size # validate
if self.step > 0:
return self.start
else:
return self.stop - self.step
@property
def _sup(self):
if not self:
raise NotImplementedError
if self.has(Symbol):
if self.step.is_positive:
return self[-1]
elif self.step.is_negative:
return self[0]
_ = self.size # validate
if self.step > 0:
return self.stop - self.step
else:
return self.start
@property
def _boundary(self):
return self
def as_relational(self, x):
"""Rewrite a Range in terms of equalities and logic operators. """
from sympy.functions.elementary.integers import floor
if self.size == 1:
return Eq(x, self[0])
else:
return And(
Eq(x, floor(x)),
x >= self.inf if self.inf in self else x > self.inf,
x <= self.sup if self.sup in self else x < self.sup)
converter[range] = lambda r: Range(r.start, r.stop, r.step)
def normalize_theta_set(theta):
"""
Normalize a Real Set `theta` in the Interval [0, 2*pi). It returns
a normalized value of theta in the Set. For Interval, a maximum of
one cycle [0, 2*pi], is returned i.e. for theta equal to [0, 10*pi],
returned normalized value would be [0, 2*pi). As of now intervals
with end points as non-multiples of `pi` is not supported.
Raises
======
NotImplementedError
The algorithms for Normalizing theta Set are not yet
implemented.
ValueError
The input is not valid, i.e. the input is not a real set.
RuntimeError
It is a bug, please report to the github issue tracker.
Examples
========
>>> from sympy.sets.fancysets import normalize_theta_set
>>> from sympy import Interval, FiniteSet, pi
>>> normalize_theta_set(Interval(9*pi/2, 5*pi))
Interval(pi/2, pi)
>>> normalize_theta_set(Interval(-3*pi/2, pi/2))
Interval.Ropen(0, 2*pi)
>>> normalize_theta_set(Interval(-pi/2, pi/2))
Union(Interval(0, pi/2), Interval.Ropen(3*pi/2, 2*pi))
>>> normalize_theta_set(Interval(-4*pi, 3*pi))
Interval.Ropen(0, 2*pi)
>>> normalize_theta_set(Interval(-3*pi/2, -pi/2))
Interval(pi/2, 3*pi/2)
>>> normalize_theta_set(FiniteSet(0, pi, 3*pi))
FiniteSet(0, pi)
"""
from sympy.functions.elementary.trigonometric import _pi_coeff as coeff
if theta.is_Interval:
interval_len = theta.measure
# one complete circle
if interval_len >= 2*S.Pi:
if interval_len == 2*S.Pi and theta.left_open and theta.right_open:
k = coeff(theta.start)
return Union(Interval(0, k*S.Pi, False, True),
Interval(k*S.Pi, 2*S.Pi, True, True))
return Interval(0, 2*S.Pi, False, True)
k_start, k_end = coeff(theta.start), coeff(theta.end)
if k_start is None or k_end is None:
raise NotImplementedError("Normalizing theta without pi as coefficient is "
"not yet implemented")
new_start = k_start*S.Pi
new_end = k_end*S.Pi
if new_start > new_end:
return Union(Interval(S.Zero, new_end, False, theta.right_open),
Interval(new_start, 2*S.Pi, theta.left_open, True))
else:
return Interval(new_start, new_end, theta.left_open, theta.right_open)
elif theta.is_FiniteSet:
new_theta = []
for element in theta:
k = coeff(element)
if k is None:
raise NotImplementedError('Normalizing theta without pi as '
'coefficient, is not Implemented.')
else:
new_theta.append(k*S.Pi)
return FiniteSet(*new_theta)
elif theta.is_Union:
return Union(*[normalize_theta_set(interval) for interval in theta.args])
elif theta.is_subset(S.Reals):
raise NotImplementedError("Normalizing theta when, it is of type %s is not "
"implemented" % type(theta))
else:
raise ValueError(" %s is not a real set" % (theta))
class ComplexRegion(Set):
"""
Represents the Set of all Complex Numbers. It can represent a
region of Complex Plane in both the standard forms Polar and
Rectangular coordinates.
* Polar Form
Input is in the form of the ProductSet or Union of ProductSets
of the intervals of r and theta, & use the flag polar=True.
Z = {z in C | z = r*[cos(theta) + I*sin(theta)], r in [r], theta in [theta]}
* Rectangular Form
Input is in the form of the ProductSet or Union of ProductSets
of interval of x and y the of the Complex numbers in a Plane.
Default input type is in rectangular form.
Z = {z in C | z = x + I*y, x in [Re(z)], y in [Im(z)]}
Examples
========
>>> from sympy.sets.fancysets import ComplexRegion
>>> from sympy.sets import Interval
>>> from sympy import S, I, Union
>>> a = Interval(2, 3)
>>> b = Interval(4, 6)
>>> c = Interval(1, 8)
>>> c1 = ComplexRegion(a*b) # Rectangular Form
>>> c1
CartesianComplexRegion(ProductSet(Interval(2, 3), Interval(4, 6)))
* c1 represents the rectangular region in complex plane
surrounded by the coordinates (2, 4), (3, 4), (3, 6) and
(2, 6), of the four vertices.
>>> c2 = ComplexRegion(Union(a*b, b*c))
>>> c2
CartesianComplexRegion(Union(ProductSet(Interval(2, 3), Interval(4, 6)), ProductSet(Interval(4, 6), Interval(1, 8))))
* c2 represents the Union of two rectangular regions in complex
plane. One of them surrounded by the coordinates of c1 and
other surrounded by the coordinates (4, 1), (6, 1), (6, 8) and
(4, 8).
>>> 2.5 + 4.5*I in c1
True
>>> 2.5 + 6.5*I in c1
False
>>> r = Interval(0, 1)
>>> theta = Interval(0, 2*S.Pi)
>>> c2 = ComplexRegion(r*theta, polar=True) # Polar Form
>>> c2 # unit Disk
PolarComplexRegion(ProductSet(Interval(0, 1), Interval.Ropen(0, 2*pi)))
* c2 represents the region in complex plane inside the
Unit Disk centered at the origin.
>>> 0.5 + 0.5*I in c2
True
>>> 1 + 2*I in c2
False
>>> unit_disk = ComplexRegion(Interval(0, 1)*Interval(0, 2*S.Pi), polar=True)
>>> upper_half_unit_disk = ComplexRegion(Interval(0, 1)*Interval(0, S.Pi), polar=True)
>>> intersection = unit_disk.intersect(upper_half_unit_disk)
>>> intersection
PolarComplexRegion(ProductSet(Interval(0, 1), Interval(0, pi)))
>>> intersection == upper_half_unit_disk
True
See Also
========
CartesianComplexRegion
PolarComplexRegion
Complexes
"""
is_ComplexRegion = True
def __new__(cls, sets, polar=False):
if polar is False:
return CartesianComplexRegion(sets)
elif polar is True:
return PolarComplexRegion(sets)
else:
raise ValueError("polar should be either True or False")
@property
def sets(self):
"""
Return raw input sets to the self.
Examples
========
>>> from sympy import Interval, ComplexRegion, Union
>>> a = Interval(2, 3)
>>> b = Interval(4, 5)
>>> c = Interval(1, 7)
>>> C1 = ComplexRegion(a*b)
>>> C1.sets
ProductSet(Interval(2, 3), Interval(4, 5))
>>> C2 = ComplexRegion(Union(a*b, b*c))
>>> C2.sets
Union(ProductSet(Interval(2, 3), Interval(4, 5)), ProductSet(Interval(4, 5), Interval(1, 7)))
"""
return self.args[0]
@property
def psets(self):
"""
Return a tuple of sets (ProductSets) input of the self.
Examples
========
>>> from sympy import Interval, ComplexRegion, Union
>>> a = Interval(2, 3)
>>> b = Interval(4, 5)
>>> c = Interval(1, 7)
>>> C1 = ComplexRegion(a*b)
>>> C1.psets
(ProductSet(Interval(2, 3), Interval(4, 5)),)
>>> C2 = ComplexRegion(Union(a*b, b*c))
>>> C2.psets
(ProductSet(Interval(2, 3), Interval(4, 5)), ProductSet(Interval(4, 5), Interval(1, 7)))
"""
if self.sets.is_ProductSet:
psets = ()
psets = psets + (self.sets, )
else:
psets = self.sets.args
return psets
@property
def a_interval(self):
"""
Return the union of intervals of `x` when, self is in
rectangular form, or the union of intervals of `r` when
self is in polar form.
Examples
========
>>> from sympy import Interval, ComplexRegion, Union
>>> a = Interval(2, 3)
>>> b = Interval(4, 5)
>>> c = Interval(1, 7)
>>> C1 = ComplexRegion(a*b)
>>> C1.a_interval
Interval(2, 3)
>>> C2 = ComplexRegion(Union(a*b, b*c))
>>> C2.a_interval
Union(Interval(2, 3), Interval(4, 5))
"""
a_interval = []
for element in self.psets:
a_interval.append(element.args[0])
a_interval = Union(*a_interval)
return a_interval
@property
def b_interval(self):
"""
Return the union of intervals of `y` when, self is in
rectangular form, or the union of intervals of `theta`
when self is in polar form.
Examples
========
>>> from sympy import Interval, ComplexRegion, Union
>>> a = Interval(2, 3)
>>> b = Interval(4, 5)
>>> c = Interval(1, 7)
>>> C1 = ComplexRegion(a*b)
>>> C1.b_interval
Interval(4, 5)
>>> C2 = ComplexRegion(Union(a*b, b*c))
>>> C2.b_interval
Interval(1, 7)
"""
b_interval = []
for element in self.psets:
b_interval.append(element.args[1])
b_interval = Union(*b_interval)
return b_interval
@property
def _measure(self):
"""
The measure of self.sets.
Examples
========
>>> from sympy import Interval, ComplexRegion, S
>>> a, b = Interval(2, 5), Interval(4, 8)
>>> c = Interval(0, 2*S.Pi)
>>> c1 = ComplexRegion(a*b)
>>> c1.measure
12
>>> c2 = ComplexRegion(a*c, polar=True)
>>> c2.measure
6*pi
"""
return self.sets._measure
@classmethod
def from_real(cls, sets):
"""
Converts given subset of real numbers to a complex region.
Examples
========
>>> from sympy import Interval, ComplexRegion
>>> unit = Interval(0,1)
>>> ComplexRegion.from_real(unit)
CartesianComplexRegion(ProductSet(Interval(0, 1), FiniteSet(0)))
"""
if not sets.is_subset(S.Reals):
raise ValueError("sets must be a subset of the real line")
return CartesianComplexRegion(sets * FiniteSet(0))
def _contains(self, other):
from sympy.functions import arg, Abs
from sympy.core.containers import Tuple
other = sympify(other)
isTuple = isinstance(other, Tuple)
if isTuple and len(other) != 2:
raise ValueError('expecting Tuple of length 2')
# If the other is not an Expression, and neither a Tuple
if not isinstance(other, Expr) and not isinstance(other, Tuple):
return S.false
# self in rectangular form
if not self.polar:
re, im = other if isTuple else other.as_real_imag()
return fuzzy_or(fuzzy_and([
pset.args[0]._contains(re),
pset.args[1]._contains(im)])
for pset in self.psets)
# self in polar form
elif self.polar:
if other.is_zero:
# ignore undefined complex argument
return fuzzy_or(pset.args[0]._contains(S.Zero)
for pset in self.psets)
if isTuple:
r, theta = other
else:
r, theta = Abs(other), arg(other)
if theta.is_real and theta.is_number:
# angles in psets are normalized to [0, 2pi)
theta %= 2*S.Pi
return fuzzy_or(fuzzy_and([
pset.args[0]._contains(r),
pset.args[1]._contains(theta)])
for pset in self.psets)
class CartesianComplexRegion(ComplexRegion):
"""
Set representing a square region of the complex plane.
Z = {z in C | z = x + I*y, x in [Re(z)], y in [Im(z)]}
Examples
========
>>> from sympy.sets.fancysets import ComplexRegion
>>> from sympy.sets.sets import Interval
>>> from sympy import I
>>> region = ComplexRegion(Interval(1, 3) * Interval(4, 6))
>>> 2 + 5*I in region
True
>>> 5*I in region
False
See also
========
ComplexRegion
PolarComplexRegion
Complexes
"""
polar = False
variables = symbols('x, y', cls=Dummy)
def __new__(cls, sets):
if sets == S.Reals*S.Reals:
return S.Complexes
if all(_a.is_FiniteSet for _a in sets.args) and (len(sets.args) == 2):
# ** ProductSet of FiniteSets in the Complex Plane. **
# For Cases like ComplexRegion({2, 4}*{3}), It
# would return {2 + 3*I, 4 + 3*I}
# FIXME: This should probably be handled with something like:
# return ImageSet(Lambda((x, y), x+I*y), sets).rewrite(FiniteSet)
complex_num = []
for x in sets.args[0]:
for y in sets.args[1]:
complex_num.append(x + S.ImaginaryUnit*y)
return FiniteSet(*complex_num)
else:
return Set.__new__(cls, sets)
@property
def expr(self):
x, y = self.variables
return x + S.ImaginaryUnit*y
class PolarComplexRegion(ComplexRegion):
"""
Set representing a polar region of the complex plane.
Z = {z in C | z = r*[cos(theta) + I*sin(theta)], r in [r], theta in [theta]}
Examples
========
>>> from sympy.sets.fancysets import ComplexRegion, Interval
>>> from sympy import oo, pi, I
>>> rset = Interval(0, oo)
>>> thetaset = Interval(0, pi)
>>> upper_half_plane = ComplexRegion(rset * thetaset, polar=True)
>>> 1 + I in upper_half_plane
True
>>> 1 - I in upper_half_plane
False
See also
========
ComplexRegion
CartesianComplexRegion
Complexes
"""
polar = True
variables = symbols('r, theta', cls=Dummy)
def __new__(cls, sets):
new_sets = []
# sets is Union of ProductSets
if not sets.is_ProductSet:
for k in sets.args:
new_sets.append(k)
# sets is ProductSets
else:
new_sets.append(sets)
# Normalize input theta
for k, v in enumerate(new_sets):
new_sets[k] = ProductSet(v.args[0],
normalize_theta_set(v.args[1]))
sets = Union(*new_sets)
return Set.__new__(cls, sets)
@property
def expr(self):
from sympy.functions.elementary.trigonometric import sin, cos
r, theta = self.variables
return r*(cos(theta) + S.ImaginaryUnit*sin(theta))
class Complexes(CartesianComplexRegion, metaclass=Singleton):
"""
The Set of all complex numbers
Examples
========
>>> from sympy import S, I
>>> S.Complexes
Complexes
>>> 1 + I in S.Complexes
True
See also
========
Reals
ComplexRegion
"""
is_empty = False
is_finite_set = False
# Override property from superclass since Complexes has no args
sets = ProductSet(S.Reals, S.Reals)
def __new__(cls):
return Set.__new__(cls)
def __str__(self):
return "S.Complexes"
def __repr__(self):
return "S.Complexes"
|
5940caa3d4a0fbb404a34d6e162abc76836e80c8c1a437dfd48a6d5958e6dd14 | from __future__ import print_function, division
from typing import Optional
from collections import defaultdict
import inspect
from sympy.core.basic import Basic
from sympy.core.compatibility import iterable, ordered, reduce
from sympy.core.containers import Tuple
from sympy.core.decorators import (deprecated, sympify_method_args,
sympify_return)
from sympy.core.evalf import EvalfMixin
from sympy.core.parameters import global_parameters
from sympy.core.expr import Expr
from sympy.core.logic import (FuzzyBool, fuzzy_bool, fuzzy_or, fuzzy_and,
fuzzy_not)
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, Xor, true, false
from sympy.sets.contains import Contains
from sympy.utilities import subsets
from sympy.utilities.exceptions import SymPyDeprecationWarning
from sympy.utilities.iterables import iproduct, sift, roundrobin
from sympy.utilities.misc import func_name, filldedent
from mpmath import mpi, mpf
tfn = defaultdict(lambda: None, {
True: S.true,
S.true: S.true,
False: S.false,
S.false: S.false})
@sympify_method_args
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 # type: Optional[bool]
is_UniversalSet = None # type: Optional[bool]
is_Complement = None # type: Optional[bool]
is_ComplexRegion = False
is_empty = None # type: FuzzyBool
is_finite_set = None # type: FuzzyBool
@property # type: ignore
@deprecated(useinstead="is S.EmptySet or is_empty",
issue=16946, deprecated_since_version="1.5")
def is_EmptySet(self):
return None
@staticmethod
def _infimum_key(expr):
"""
Return infimum (if possible) else S.Infinity.
"""
try:
infimum = expr.inf
assert infimum.is_comparable
infimum = infimum.evalf() # issue #18505
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(FiniteSet(3), Interval.Lopen(1, 2))
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)
Complement(UniversalSet, Interval(0, 1))
"""
return Complement(universe, self)
def _complement(self, other):
# this behaves as other - self
if isinstance(self, ProductSet) and isinstance(other, ProductSet):
# If self and other are disjoint then other - self == self
if len(self.sets) != len(other.sets):
return other
# There can be other ways to represent this but this gives:
# (A x B) - (C x D) = ((A - C) x B) U (A x (B - D))
overlaps = []
pairs = list(zip(self.sets, other.sets))
for n in range(len(pairs)):
sets = (o if i != n else o-s for i, (s, o) in enumerate(pairs))
overlaps.append(ProductSet(*sets))
return Union(*overlaps)
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 a SymPy value indicating whether ``other`` is contained
in ``self``: ``true`` if it is, ``false`` if it isn't, else
an unevaluated ``Contains`` expression (or, as in the case of
ConditionSet and a union of FiniteSet/Intervals, an expression
indicating the conditions for containment).
Examples
========
>>> from sympy import Interval, S
>>> from sympy.abc import x
>>> Interval(0, 1).contains(0.5)
True
As a shortcut it is possible to use the 'in' operator, but that
will raise an error unless an affirmative true or false is not
obtained.
>>> Interval(0, 1).contains(x)
(0 <= x) & (x <= 1)
>>> x in Interval(0, 1)
Traceback (most recent call last):
...
TypeError: did not evaluate to a bool: None
The result of 'in' is a bool, not a SymPy value
>>> 1 in Interval(0, 2)
True
>>> _ is S.true
False
"""
other = sympify(other, strict=True)
c = self._contains(other)
if c is None:
return Contains(other, self, evaluate=False)
b = tfn[c]
if b is None:
return c
return b
def _contains(self, other):
raise NotImplementedError(filldedent('''
(%s)._contains(%s) is not defined. This method, when
defined, will receive a sympified object. The method
should return True, False, None or something that
expresses what must be true for the containment of that
object in self to be evaluated. If None is returned
then a generic Contains object will be returned
by the ``contains`` method.''' % (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 not isinstance(other, Set):
raise ValueError("Unknown argument '%s'" % other)
# Handle the trivial cases
if self == other:
return True
is_empty = self.is_empty
if is_empty is True:
return True
elif fuzzy_not(is_empty) and other.is_empty:
return False
if self.is_finite_set is False and other.is_finite_set:
return False
# Dispatch on subclass rules
ret = self._eval_is_subset(other)
if ret is not None:
return ret
ret = other._eval_is_superset(self)
if ret is not None:
return ret
# Use pairwise rules from multiple dispatch
from sympy.sets.handlers.issubset import is_subset_sets
ret = is_subset_sets(self, other)
if ret is not None:
return ret
# Fall back on computing the intersection
# XXX: We shouldn't do this. A query like this should be handled
# without evaluating new Set objects. It should be the other way round
# so that the intersect method uses is_subset for evaluation.
if self.intersect(other) == self:
return True
def _eval_is_subset(self, other):
'''Returns a fuzzy bool for whether self is a subset of other.'''
return None
def _eval_is_superset(self, other):
'''Returns a fuzzy bool for whether self is a subset of other.'''
return None
# This should be deprecated:
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)
# This should be deprecated:
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):
from .powerset import PowerSet
return PowerSet(self)
def powerset(self):
"""
Find the Power set of 'self'.
Examples
========
>>> from sympy import EmptySet, FiniteSet, Interval
A power set of an empty set:
>>> A = EmptySet
>>> A.powerset()
FiniteSet(EmptySet)
A power set of a finite set:
>>> A = FiniteSet(1, 2)
>>> a, b, c = FiniteSet(1), FiniteSet(2), FiniteSet(1, 2)
>>> A.powerset() == FiniteSet(a, b, c, EmptySet)
True
A power set of an interval:
>>> Interval(1, 2).powerset()
PowerSet(Interval(1, 2))
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
FiniteSet(0, 1)
>>> Interval(0, 1, True, False).boundary
FiniteSet(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. In particular, a subset A of the reals is open if and only
if each one of its points is contained in an open interval that is a
subset of A.
Examples
========
>>> from sympy import S
>>> S.Reals.is_open
True
>>> S.Rationals.is_open
False
"""
return Intersection(self, self.boundary).is_empty
@property
def is_closed(self):
"""
A property method to check whether a set is closed.
A set is closed if its complement is an open set. The closedness of a
subset of the reals is determined with respect to R and its standard
topology.
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)
@sympify_return([('other', 'Set')], NotImplemented)
def __add__(self, other):
return self.union(other)
@sympify_return([('other', 'Set')], NotImplemented)
def __or__(self, other):
return self.union(other)
@sympify_return([('other', 'Set')], NotImplemented)
def __and__(self, other):
return self.intersect(other)
@sympify_return([('other', 'Set')], NotImplemented)
def __mul__(self, other):
return ProductSet(self, other)
@sympify_return([('other', 'Set')], NotImplemented)
def __xor__(self, other):
return SymmetricDifference(self, other)
@sympify_return([('exp', Expr)], NotImplemented)
def __pow__(self, exp):
if not (exp.is_Integer and exp >= 0):
raise ValueError("%s: Exponent must be a positive Integer" % exp)
return ProductSet(*[self]*exp)
@sympify_return([('other', 'Set')], NotImplemented)
def __sub__(self, other):
return Complement(self, other)
def __contains__(self, other):
other = _sympify(other)
c = self._contains(other)
b = tfn[c]
if b is None:
raise TypeError('did not evaluate to a bool: %r' % c)
return b
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)
ProductSet(Interval(0, 5), FiniteSet(1, 2, 3))
>>> (2, 2) in ProductSet(I, S)
True
>>> Interval(0, 1) * Interval(0, 1) # The unit square
ProductSet(Interval(0, 1), Interval(0, 1))
>>> coin = FiniteSet('H', 'T')
>>> set(coin**2)
{(H, H), (H, T), (T, H), (T, T)}
The Cartesian product is not commutative or associative e.g.:
>>> I*S == S*I
False
>>> (I*I)*I == I*(I*I)
False
Notes
=====
- Passes most operations down to the argument sets
References
==========
.. [1] https://en.wikipedia.org/wiki/Cartesian_product
"""
is_ProductSet = True
def __new__(cls, *sets, **assumptions):
if len(sets) == 1 and iterable(sets[0]) and not isinstance(sets[0], (Set, set)):
SymPyDeprecationWarning(
feature="ProductSet(iterable)",
useinstead="ProductSet(*iterable)",
issue=17557,
deprecated_since_version="1.5"
).warn()
sets = tuple(sets[0])
sets = [sympify(s) for s in sets]
if not all(isinstance(s, Set) for s in sets):
raise TypeError("Arguments to ProductSet should be of type Set")
# Nullary product of sets is *not* the empty set
if len(sets) == 0:
return FiniteSet(())
if S.EmptySet in sets:
return S.EmptySet
return Basic.__new__(cls, *sets, **assumptions)
@property
def sets(self):
return self.args
def flatten(self):
def _flatten(sets):
for s in sets:
if s.is_ProductSet:
for s2 in _flatten(s.sets):
yield s2
else:
yield s
return ProductSet(*_flatten(self.sets))
def _eval_Eq(self, other):
if not other.is_ProductSet:
return
if len(self.sets) != len(other.sets):
return false
eqs = (Eq(x, y) for x, y in zip(self.sets, other.sets))
return tfn[fuzzy_and(map(fuzzy_bool, eqs))]
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
"""
if element.is_Symbol:
return None
if not isinstance(element, Tuple) or len(element) != len(self.sets):
return False
return fuzzy_and(s._contains(e) for s, e in zip(self.sets, element))
def as_relational(self, *symbols):
symbols = [_sympify(s) for s in symbols]
if len(symbols) != len(self.sets) or not all(
i.is_Symbol for i in symbols):
raise ValueError(
'number of symbols must match the number of sets')
return And(*[s.as_relational(i) for s, i in zip(self.sets, symbols)])
@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
>>> 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.
"""
return iproduct(*self.sets)
@property
def is_empty(self):
return fuzzy_or(s.is_empty for s in self.sets)
@property
def is_finite_set(self):
all_finite = fuzzy_and(s.is_finite_set for s in self.sets)
return fuzzy_or([self.is_empty, all_finite])
@property
def _measure(self):
measure = 1
for s in self.sets:
measure *= s.measure
return measure
def __len__(self):
return reduce(lambda a, b: a*b, (len(s) for s in self.args))
def __bool__(self):
return all([bool(s) for s in self.sets])
__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))
# Only allow real intervals
if fuzzy_not(fuzzy_and(i.is_extended_real for i in (start, end, end-start))):
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 is S.Infinity or start is S.NegativeInfinity:
return S.EmptySet
return FiniteSet(end)
# Make sure infinite interval end points are open.
if start is S.NegativeInfinity:
left_open = true
if end is S.Infinity:
right_open = true
if start == S.Infinity or end == S.NegativeInfinity:
return S.EmptySet
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]
@property
def is_empty(self):
if self.left_open or self.right_open:
cond = self.start >= self.end # One/both bounds open
else:
cond = self.start > self.end # Both bounds closed
return fuzzy_bool(cond)
@property
def is_finite_set(self):
return self.measure.is_zero
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.NaN
or other.is_real is False):
return false
if self.start is S.NegativeInfinity and self.end is S.Infinity:
if other.is_real is not None:
return other.is_real
d = Dummy()
return self.as_relational(d).subs(d, other)
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)
@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._evalf(prec), self.right._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 _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_parameters.evaluate)
# 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
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])
@property
def is_empty(self):
return fuzzy_and(set.is_empty for set in self.args)
@property
def is_finite_set(self):
return fuzzy_and(set.is_finite_set 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 _contains(self, other):
return Or(*[s.contains(other) for s in self.args])
def is_subset(self, other):
return fuzzy_and(s.is_subset(other) for s in self.args)
def as_relational(self, symbol):
"""Rewrite a Union in terms of equalities and logic operators. """
if all(isinstance(i, (FiniteSet, Interval)) for i in self.args):
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])
raise NotImplementedError('relational of Union with non-Intervals')
@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):
return roundrobin(*(iter(arg) for arg in self.args))
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_parameters.evaluate)
# flatten inputs to merge intersections and iterables
args = list(ordered(set(_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
def args(self):
return self._args
@property
def is_iterable(self):
return any(arg.is_iterable for arg in self.args)
@property
def is_finite_set(self):
if fuzzy_or(arg.is_finite_set for arg in self.args):
return True
@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):
sets_sift = sift(self.args, lambda x: x.is_iterable)
completed = False
candidates = sets_sift[True] + sets_sift[None]
finite_candidates, others = [], []
for candidate in candidates:
length = None
try:
length = len(candidate)
except TypeError:
others.append(candidate)
if length is not None:
finite_candidates.append(candidate)
finite_candidates.sort(key=len)
for s in finite_candidates + others:
other_sets = set(self.args) - set((s,))
other = Intersection(*other_sets, evaluate=False)
completed = True
for x in s:
try:
if x in other:
yield x
except TypeError:
completed = False
if completed:
return
if not completed:
if not candidates:
raise TypeError("None of the constituent sets are iterable")
raise TypeError(
"The computation had not completed because of the "
"undecidable set membership is found in every candidates.")
@staticmethod
def _handle_finite_sets(args):
'''Simplify intersection of one or more FiniteSets and other sets'''
# First separate the FiniteSets from the others
fs_args, others = sift(args, lambda x: x.is_FiniteSet, binary=True)
# Let the caller handle intersection of non-FiniteSets
if not fs_args:
return
# Convert to Python sets and build the set of all elements
fs_sets = [set(fs) for fs in fs_args]
all_elements = reduce(lambda a, b: a | b, fs_sets, set())
# Extract elements that are definitely in or definitely not in the
# intersection. Here we check contains for all of args.
definite = set()
for e in all_elements:
inall = fuzzy_and(s.contains(e) for s in args)
if inall is True:
definite.add(e)
if inall is not None:
for s in fs_sets:
s.discard(e)
# At this point all elements in all of fs_sets are possibly in the
# intersection. In some cases this is because they are definitely in
# the intersection of the finite sets but it's not clear if they are
# members of others. We might have {m, n}, {m}, and Reals where we
# don't know if m or n is real. We want to remove n here but it is
# possibly in because it might be equal to m. So what we do now is
# extract the elements that are definitely in the remaining finite
# sets iteratively until we end up with {n}, {}. At that point if we
# get any empty set all remaining elements are discarded.
fs_elements = reduce(lambda a, b: a | b, fs_sets, set())
# Need fuzzy containment testing
fs_symsets = [FiniteSet(*s) for s in fs_sets]
while fs_elements:
for e in fs_elements:
infs = fuzzy_and(s.contains(e) for s in fs_symsets)
if infs is True:
definite.add(e)
if infs is not None:
for n, s in enumerate(fs_sets):
# Update Python set and FiniteSet
if e in s:
s.remove(e)
fs_symsets[n] = FiniteSet(*s)
fs_elements.remove(e)
break
# If we completed the for loop without removing anything we are
# done so quit the outer while loop
else:
break
# If any of the sets of remainder elements is empty then we discard
# all of them for the intersection.
if not all(fs_sets):
fs_sets = [set()]
# Here we fold back the definitely included elements into each fs.
# Since they are definitely included they must have been members of
# each FiniteSet to begin with. We could instead fold these in with a
# Union at the end to get e.g. {3}|({x}&{y}) rather than {3,x}&{3,y}.
if definite:
fs_sets = [fs | definite for fs in fs_sets]
if fs_sets == [set()]:
return S.EmptySet
sets = [FiniteSet(*s) for s in fs_sets]
# Any set in others is redundant if it contains all the elements that
# are in the finite sets so we don't need it in the Intersection
all_elements = reduce(lambda a, b: a | b, fs_sets, set())
is_redundant = lambda o: all(fuzzy_bool(o.contains(e)) for e in all_elements)
others = [o for o in others if not is_redundant(o)]
if others:
rest = Intersection(*others)
# XXX: Maybe this shortcut should be at the beginning. For large
# FiniteSets it could much more efficient to process the other
# sets first...
if rest is S.EmptySet:
return S.EmptySet
# Flatten the Intersection
if rest.is_Intersection:
sets.extend(rest.args)
else:
sets.append(rest)
if len(sets) == 1:
return sets[0]
else:
return Intersection(*sets, evaluate=False)
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 \mid x \notin B\}`
Examples
========
>>> from sympy import Complement, FiniteSet
>>> Complement(FiniteSet(0, 1, 2), FiniteSet(1))
FiniteSet(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 S.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)))
def as_relational(self, symbol):
"""Rewrite a complement in terms of equalities and logic
operators"""
A, B = self.args
A_rel = A.as_relational(symbol)
B_rel = Not(B.as_relational(symbol))
return And(A_rel, B_rel)
@property
def is_iterable(self):
if self.args[0].is_iterable:
return True
@property
def is_finite_set(self):
A, B = self.args
a_finite = A.is_finite_set
if a_finite is True:
return True
elif a_finite is False and B.is_finite_set:
return False
def __iter__(self):
A, B = self.args
for a in A:
if a not in B:
yield a
else:
continue
class EmptySet(Set, metaclass=Singleton):
"""
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_empty = True
is_finite_set = True
is_FiniteSet = True
@property # type: ignore
@deprecated(useinstead="is S.EmptySet or is_empty",
issue=16946, deprecated_since_version="1.5")
def is_EmptySet(self):
return 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(Set, metaclass=Singleton):
"""
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
is_empty = False
is_finite_set = False
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 S.EmptySet
class FiniteSet(Set, EvalfMixin):
"""
Represents a finite set of discrete numbers
Examples
========
>>> from sympy import FiniteSet
>>> FiniteSet(1, 2, 3, 4)
FiniteSet(1, 2, 3, 4)
>>> 3 in FiniteSet(1, 2, 3, 4)
True
>>> members = [1, 2, 3, 4]
>>> f = FiniteSet(*members)
>>> f
FiniteSet(1, 2, 3, 4)
>>> f - FiniteSet(2)
FiniteSet(1, 3, 4)
>>> f + FiniteSet(2, 5)
FiniteSet(1, 2, 3, 4, 5)
References
==========
.. [1] https://en.wikipedia.org/wiki/Finite_set
"""
is_FiniteSet = True
is_iterable = True
is_empty = False
is_finite_set = True
def __new__(cls, *args, **kwargs):
evaluate = kwargs.get('evaluate', global_parameters.evaluate)
if evaluate:
args = list(map(sympify, args))
if len(args) == 0:
return S.EmptySet
else:
args = list(map(sympify, args))
# keep the form of the first canonical arg
dargs = {}
for i in reversed(list(ordered(args))):
if i.is_Symbol:
dargs[i] = i
else:
try:
dargs[i.as_dummy()] = i
except TypeError:
# e.g. i = class without args like `Interval`
dargs[i] = i
_args_set = set(dargs.values())
args = list(ordered(_args_set, Set._infimum_key))
obj = Basic.__new__(cls, *args)
obj._args_set = _args_set
return obj
def _eval_Eq(self, other):
if not isinstance(other, FiniteSet):
# XXX: If Interval(x, x, evaluate=False) worked then the line
# below would mean that
# FiniteSet(x) & Interval(x, x, evaluate=False) -> false
if isinstance(other, Interval):
return false
elif isinstance(other, Set):
return None
return false
def all_in_both():
s_set = set(self.args)
o_set = set(other.args)
yield fuzzy_and(self._contains(e) for e in o_set - s_set)
yield fuzzy_and(other._contains(e) for e in s_set - o_set)
return tfn[fuzzy_and(all_in_both())]
def __iter__(self):
return iter(self.args)
def _complement(self, other):
if isinstance(other, Interval):
# Splitting in sub-intervals is only done for S.Reals;
# other cases that need splitting will first pass through
# Set._complement().
nums, syms = [], []
for m in self.args:
if m.is_number and m.is_real:
nums.append(m)
elif m.is_real == False:
pass # drop non-reals
else:
syms.append(m) # various symbolic expressions
if other == S.Reals and nums != []:
nums.sort()
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 == []: # no splitting necessary or possible:
if syms:
return Complement(other, FiniteSet(*syms), evaluate=False)
else:
return other
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.
The actual test is for mathematical equality (as opposed to
syntactical equality). In the worst case all elements of the
set must be checked.
Examples
========
>>> from sympy import FiniteSet
>>> 1 in FiniteSet(1, 2)
True
>>> 5 in FiniteSet(1, 2)
False
"""
if other in self._args_set:
return True
else:
# evaluate=True is needed to override evaluate=False context;
# we need Eq to do the evaluation
return fuzzy_or(fuzzy_bool(Eq(e, other, evaluate=True))
for e in self.args)
def _eval_is_subset(self, other):
return fuzzy_and(other._contains(e) for e in self.args)
@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._evalf(prec) for elem in self])
@property
def _sorted_args(self):
return self.args
def _eval_powerset(self):
return self.func(*[self.func(*s) for s in subsets(self.args)])
def _eval_rewrite_as_PowerSet(self, *args, **kwargs):
"""Rewriting method for a finite set to a power set."""
from .powerset import PowerSet
is2pow = lambda n: bool(n and not n & (n - 1))
if not is2pow(len(self)):
return None
fs_test = lambda arg: isinstance(arg, Set) and arg.is_FiniteSet
if not all((fs_test(arg) for arg in args)):
return None
biggest = max(args, key=len)
for arg in subsets(biggest.args):
arg_set = FiniteSet(*arg)
if arg_set not in args:
return None
return PowerSet(biggest)
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))
FiniteSet(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 as_relational(self, symbol):
"""Rewrite a symmetric_difference in terms of equalities and
logic operators"""
A, B = self.args
A_rel = A.as_relational(symbol)
B_rel = B.as_relational(symbol)
return Xor(A_rel, B_rel)
@property
def is_iterable(self):
if all(arg.is_iterable for arg in self.args):
return True
def __iter__(self):
args = self.args
union = roundrobin(*(iter(arg) for arg in args))
for item in union:
count = 0
for s in args:
if item in s:
count += 1
if count % 2 == 1:
yield item
class DisjointUnion(Set):
""" Represents the disjoint union (also known as the external disjoint union)
of a finite number of sets.
Examples
========
>>> from sympy import DisjointUnion, FiniteSet, Interval, Union, Symbol
>>> A = FiniteSet(1, 2, 3)
>>> B = Interval(0, 5)
>>> DisjointUnion(A, B)
DisjointUnion(FiniteSet(1, 2, 3), Interval(0, 5))
>>> DisjointUnion(A, B).rewrite(Union)
Union(ProductSet(FiniteSet(1, 2, 3), FiniteSet(0)), ProductSet(Interval(0, 5), FiniteSet(1)))
>>> C = FiniteSet(Symbol('x'), Symbol('y'), Symbol('z'))
>>> DisjointUnion(C, C)
DisjointUnion(FiniteSet(x, y, z), FiniteSet(x, y, z))
>>> DisjointUnion(C, C).rewrite(Union)
ProductSet(FiniteSet(x, y, z), FiniteSet(0, 1))
References
==========
https://en.wikipedia.org/wiki/Disjoint_union
"""
def __new__(cls, *sets):
dj_collection = []
for set_i in sets:
if isinstance(set_i, Set):
dj_collection.append(set_i)
else:
raise TypeError("Invalid input: '%s', input args \
to DisjointUnion must be Sets" % set_i)
obj = Basic.__new__(cls, *dj_collection)
return obj
@property
def sets(self):
return self.args
@property
def is_empty(self):
return fuzzy_and(s.is_empty for s in self.sets)
@property
def is_finite_set(self):
all_finite = fuzzy_and(s.is_finite_set for s in self.sets)
return fuzzy_or([self.is_empty, all_finite])
@property
def is_iterable(self):
if self.is_empty:
return False
iter_flag = True
for set_i in self.sets:
if not set_i.is_empty:
iter_flag = iter_flag and set_i.is_iterable
return iter_flag
def _eval_rewrite_as_Union(self, *sets):
"""
Rewrites the disjoint union as the union of (``set`` x {``i``})
where ``set`` is the element in ``sets`` at index = ``i``
"""
dj_union = EmptySet()
index = 0
for set_i in sets:
if isinstance(set_i, Set):
cross = ProductSet(set_i, FiniteSet(index))
dj_union = Union(dj_union, cross)
index = index + 1
return dj_union
def _contains(self, element):
"""
'in' operator for DisjointUnion
Examples
========
>>> from sympy import Interval, DisjointUnion
>>> D = DisjointUnion(Interval(0, 1), Interval(0, 2))
>>> (0.5, 0) in D
True
>>> (0.5, 1) in D
True
>>> (1.5, 0) in D
False
>>> (1.5, 1) in D
True
Passes operation on to constituent sets
"""
if not isinstance(element, Tuple) or len(element) != 2:
return False
if not element[1].is_Integer:
return False
if element[1] >= len(self.sets) or element[1] < 0:
return False
return element[0] in self.sets[element[1]]
def __iter__(self):
if self.is_iterable:
from sympy.core.numbers import Integer
iters = []
for i, s in enumerate(self.sets):
iters.append(iproduct(s, {Integer(i)}))
return iter(roundrobin(*iters))
else:
raise ValueError("'%s' is not iterable." % self)
def __len__(self):
"""
Returns the length of the disjoint union, i.e., the number of elements in the set.
Examples
========
>>> from sympy import FiniteSet, DisjointUnion, EmptySet
>>> D1 = DisjointUnion(FiniteSet(1, 2, 3, 4), EmptySet, FiniteSet(3, 4, 5))
>>> len(D1)
7
>>> D2 = DisjointUnion(FiniteSet(3, 5, 7), EmptySet, FiniteSet(3, 5, 7))
>>> len(D2)
6
>>> D3 = DisjointUnion(EmptySet, EmptySet)
>>> len(D3)
0
Adds up the lengths of the constituent sets.
"""
if self.is_finite_set:
size = 0
for set in self.sets:
size += len(set)
return size
else:
raise ValueError("'%s' is not a finite set." % self)
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) \mid x \in \mathrm{self} \}
Examples
========
>>> from sympy import S, Interval, imageset, sin, Lambda
>>> from sympy.abc import x
>>> 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(y, x + y), 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 callable(f):
nargs = getattr(f, 'nargs', {})
if nargs:
if len(nargs) != 1:
raise NotImplementedError(filldedent('''
This function can take more than 1 arg
but the potentially complicated set input
has not been analyzed at this point to
know its dimensions. TODO
'''))
N = nargs.args[0]
if N == 1:
s = 'x'
else:
s = [Symbol('x%i' % i) for i in range(1, N + 1)]
else:
s = inspect.signature(f).parameters
dexpr = _sympify(f(*[Dummy() for i in s]))
var = tuple(uniquely_named_symbol(
Symbol(i), dexpr) for i in s)
f = Lambda(var, f(*var))
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]
try:
# TypeError if arg count != set dimensions
r = set_function(f, set)
if r is None:
raise TypeError
if not r:
return r
except TypeError:
r = ImageSet(f, set)
if isinstance(r, ImageSet):
f, set = r.args
if f.variables[0] == f.expr:
return set
if isinstance(set, ImageSet):
# XXX: Maybe this should just be:
# f2 = set.lambda
# fun = Lambda(f2.signature, f(*f2.expr))
# return imageset(fun, *set.base_sets)
if len(set.lamda.variables) == 1 and len(f.variables) == 1:
x = set.lamda.variables[0]
y = f.variables[0]
return imageset(
Lambda(x, f.expr.subs(y, set.lamda.expr)), *set.base_sets)
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 S.EmptySet 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)
|
882551e475755dc2eadaa663d58ec333707c0502643ad56efb244db5b8929e64 | """Implicit plotting module for SymPy
The module implements a data series called ImplicitSeries which is used by
``Plot`` class to plot implicit plots for different backends. The module,
by default, implements plotting using interval arithmetic. It switches to a
fall back algorithm if the expression cannot be plotted using interval arithmetic.
It is also possible to specify to use the fall back algorithm for all plots.
Boolean combinations of expressions cannot be plotted by the fall back
algorithm.
See Also
========
sympy.plotting.plot
References
==========
- Jeffrey Allen Tupper. Reliable Two-Dimensional Graphing Methods for
Mathematical Formulae with Two Free Variables.
- Jeffrey Allen Tupper. Graphing Equations with Generalized Interval
Arithmetic. Master's thesis. University of Toronto, 1996
"""
from __future__ import print_function, division
from .plot import BaseSeries, Plot
from .experimental_lambdify import experimental_lambdify, vectorized_lambdify
from .intervalmath import interval
from sympy.core.relational import (Equality, GreaterThan, LessThan,
Relational, StrictLessThan, StrictGreaterThan)
from sympy import Eq, Tuple, sympify, Symbol, Dummy
from sympy.external import import_module
from sympy.logic.boolalg import BooleanFunction
from sympy.polys.polyutils import _sort_gens
from sympy.utilities.decorator import doctest_depends_on
from sympy.utilities.iterables import flatten
import warnings
class ImplicitSeries(BaseSeries):
""" Representation for Implicit plot """
is_implicit = True
def __init__(self, expr, var_start_end_x, var_start_end_y,
has_equality, use_interval_math, depth, nb_of_points,
line_color):
super(ImplicitSeries, self).__init__()
self.expr = sympify(expr)
self.var_x = sympify(var_start_end_x[0])
self.start_x = float(var_start_end_x[1])
self.end_x = float(var_start_end_x[2])
self.var_y = sympify(var_start_end_y[0])
self.start_y = float(var_start_end_y[1])
self.end_y = float(var_start_end_y[2])
self.get_points = self.get_raster
self.has_equality = has_equality # If the expression has equality, i.e.
#Eq, Greaterthan, LessThan.
self.nb_of_points = nb_of_points
self.use_interval_math = use_interval_math
self.depth = 4 + depth
self.line_color = line_color
def __str__(self):
return ('Implicit equation: %s for '
'%s over %s and %s over %s') % (
str(self.expr),
str(self.var_x),
str((self.start_x, self.end_x)),
str(self.var_y),
str((self.start_y, self.end_y)))
def get_raster(self):
func = experimental_lambdify((self.var_x, self.var_y), self.expr,
use_interval=True)
xinterval = interval(self.start_x, self.end_x)
yinterval = interval(self.start_y, self.end_y)
try:
func(xinterval, yinterval)
except AttributeError:
# XXX: AttributeError("'list' object has no attribute 'is_real'")
# That needs fixing somehow - we shouldn't be catching
# AttributeError here.
if self.use_interval_math:
warnings.warn("Adaptive meshing could not be applied to the"
" expression. Using uniform meshing.")
self.use_interval_math = False
if self.use_interval_math:
return self._get_raster_interval(func)
else:
return self._get_meshes_grid()
def _get_raster_interval(self, func):
""" Uses interval math to adaptively mesh and obtain the plot"""
k = self.depth
interval_list = []
#Create initial 32 divisions
np = import_module('numpy')
xsample = np.linspace(self.start_x, self.end_x, 33)
ysample = np.linspace(self.start_y, self.end_y, 33)
#Add a small jitter so that there are no false positives for equality.
# Ex: y==x becomes True for x interval(1, 2) and y interval(1, 2)
#which will draw a rectangle.
jitterx = (np.random.rand(
len(xsample)) * 2 - 1) * (self.end_x - self.start_x) / 2**20
jittery = (np.random.rand(
len(ysample)) * 2 - 1) * (self.end_y - self.start_y) / 2**20
xsample += jitterx
ysample += jittery
xinter = [interval(x1, x2) for x1, x2 in zip(xsample[:-1],
xsample[1:])]
yinter = [interval(y1, y2) for y1, y2 in zip(ysample[:-1],
ysample[1:])]
interval_list = [[x, y] for x in xinter for y in yinter]
plot_list = []
#recursive call refinepixels which subdivides the intervals which are
#neither True nor False according to the expression.
def refine_pixels(interval_list):
""" Evaluates the intervals and subdivides the interval if the
expression is partially satisfied."""
temp_interval_list = []
plot_list = []
for intervals in interval_list:
#Convert the array indices to x and y values
intervalx = intervals[0]
intervaly = intervals[1]
func_eval = func(intervalx, intervaly)
#The expression is valid in the interval. Change the contour
#array values to 1.
if func_eval[1] is False or func_eval[0] is False:
pass
elif func_eval == (True, True):
plot_list.append([intervalx, intervaly])
elif func_eval[1] is None or func_eval[0] is None:
#Subdivide
avgx = intervalx.mid
avgy = intervaly.mid
a = interval(intervalx.start, avgx)
b = interval(avgx, intervalx.end)
c = interval(intervaly.start, avgy)
d = interval(avgy, intervaly.end)
temp_interval_list.append([a, c])
temp_interval_list.append([a, d])
temp_interval_list.append([b, c])
temp_interval_list.append([b, d])
return temp_interval_list, plot_list
while k >= 0 and len(interval_list):
interval_list, plot_list_temp = refine_pixels(interval_list)
plot_list.extend(plot_list_temp)
k = k - 1
#Check whether the expression represents an equality
#If it represents an equality, then none of the intervals
#would have satisfied the expression due to floating point
#differences. Add all the undecided values to the plot.
if self.has_equality:
for intervals in interval_list:
intervalx = intervals[0]
intervaly = intervals[1]
func_eval = func(intervalx, intervaly)
if func_eval[1] and func_eval[0] is not False:
plot_list.append([intervalx, intervaly])
return plot_list, 'fill'
def _get_meshes_grid(self):
"""Generates the mesh for generating a contour.
In the case of equality, ``contour`` function of matplotlib can
be used. In other cases, matplotlib's ``contourf`` is used.
"""
equal = False
if isinstance(self.expr, Equality):
expr = self.expr.lhs - self.expr.rhs
equal = True
elif isinstance(self.expr, (GreaterThan, StrictGreaterThan)):
expr = self.expr.lhs - self.expr.rhs
elif isinstance(self.expr, (LessThan, StrictLessThan)):
expr = self.expr.rhs - self.expr.lhs
else:
raise NotImplementedError("The expression is not supported for "
"plotting in uniform meshed plot.")
np = import_module('numpy')
xarray = np.linspace(self.start_x, self.end_x, self.nb_of_points)
yarray = np.linspace(self.start_y, self.end_y, self.nb_of_points)
x_grid, y_grid = np.meshgrid(xarray, yarray)
func = vectorized_lambdify((self.var_x, self.var_y), expr)
z_grid = func(x_grid, y_grid)
z_grid[np.ma.where(z_grid < 0)] = -1
z_grid[np.ma.where(z_grid > 0)] = 1
if equal:
return xarray, yarray, z_grid, 'contour'
else:
return xarray, yarray, z_grid, 'contourf'
@doctest_depends_on(modules=('matplotlib',))
def plot_implicit(expr, x_var=None, y_var=None, adaptive=True, depth=0,
points=300, line_color="blue", show=True, **kwargs):
"""A plot function to plot implicit equations / inequalities.
Arguments
=========
- ``expr`` : The equation / inequality that is to be plotted.
- ``x_var`` (optional) : symbol to plot on x-axis or tuple giving symbol
and range as ``(symbol, xmin, xmax)``
- ``y_var`` (optional) : symbol to plot on y-axis or tuple giving symbol
and range as ``(symbol, ymin, ymax)``
If neither ``x_var`` nor ``y_var`` are given then the free symbols in the
expression will be assigned in the order they are sorted.
The following keyword arguments can also be used:
- ``adaptive`` Boolean. The default value is set to True. It has to be
set to False if you want to use a mesh grid.
- ``depth`` integer. The depth of recursion for adaptive mesh grid.
Default value is 0. Takes value in the range (0, 4).
- ``points`` integer. The number of points if adaptive mesh grid is not
used. Default value is 300.
- ``show`` Boolean. Default value is True. If set to False, the plot will
not be shown. See ``Plot`` for further information.
- ``title`` string. The title for the plot.
- ``xlabel`` string. The label for the x-axis
- ``ylabel`` string. The label for the y-axis
Aesthetics options:
- ``line_color``: float or string. Specifies the color for the plot.
See ``Plot`` to see how to set color for the plots.
Default value is "Blue"
plot_implicit, by default, uses interval arithmetic to plot functions. If
the expression cannot be plotted using interval arithmetic, it defaults to
a generating a contour using a mesh grid of fixed number of points. By
setting adaptive to False, you can force plot_implicit to use the mesh
grid. The mesh grid method can be effective when adaptive plotting using
interval arithmetic, fails to plot with small line width.
Examples
========
Plot expressions:
.. plot::
:context: reset
:format: doctest
:include-source: True
>>> from sympy import plot_implicit, symbols, Eq, And
>>> x, y = symbols('x y')
Without any ranges for the symbols in the expression:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p1 = plot_implicit(Eq(x**2 + y**2, 5))
With the range for the symbols:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p2 = plot_implicit(
... Eq(x**2 + y**2, 3), (x, -3, 3), (y, -3, 3))
With depth of recursion as argument:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p3 = plot_implicit(
... Eq(x**2 + y**2, 5), (x, -4, 4), (y, -4, 4), depth = 2)
Using mesh grid and not using adaptive meshing:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p4 = plot_implicit(
... Eq(x**2 + y**2, 5), (x, -5, 5), (y, -2, 2),
... adaptive=False)
Using mesh grid without using adaptive meshing with number of points
specified:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p5 = plot_implicit(
... Eq(x**2 + y**2, 5), (x, -5, 5), (y, -2, 2),
... adaptive=False, points=400)
Plotting regions:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p6 = plot_implicit(y > x**2)
Plotting Using boolean conjunctions:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p7 = plot_implicit(And(y > x, y > -x))
When plotting an expression with a single variable (y - 1, for example),
specify the x or the y variable explicitly:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p8 = plot_implicit(y - 1, y_var=y)
>>> p9 = plot_implicit(x - 1, x_var=x)
"""
has_equality = False # Represents whether the expression contains an Equality,
#GreaterThan or LessThan
def arg_expand(bool_expr):
"""
Recursively expands the arguments of an Boolean Function
"""
for arg in bool_expr.args:
if isinstance(arg, BooleanFunction):
arg_expand(arg)
elif isinstance(arg, Relational):
arg_list.append(arg)
arg_list = []
if isinstance(expr, BooleanFunction):
arg_expand(expr)
#Check whether there is an equality in the expression provided.
if any(isinstance(e, (Equality, GreaterThan, LessThan))
for e in arg_list):
has_equality = True
elif not isinstance(expr, Relational):
expr = Eq(expr, 0)
has_equality = True
elif isinstance(expr, (Equality, GreaterThan, LessThan)):
has_equality = True
xyvar = [i for i in (x_var, y_var) if i is not None]
free_symbols = expr.free_symbols
range_symbols = Tuple(*flatten(xyvar)).free_symbols
undeclared = free_symbols - range_symbols
if len(free_symbols & range_symbols) > 2:
raise NotImplementedError("Implicit plotting is not implemented for "
"more than 2 variables")
#Create default ranges if the range is not provided.
default_range = Tuple(-5, 5)
def _range_tuple(s):
if isinstance(s, Symbol):
return Tuple(s) + default_range
if len(s) == 3:
return Tuple(*s)
raise ValueError('symbol or `(symbol, min, max)` expected but got %s' % s)
if len(xyvar) == 0:
xyvar = list(_sort_gens(free_symbols))
var_start_end_x = _range_tuple(xyvar[0])
x = var_start_end_x[0]
if len(xyvar) != 2:
if x in undeclared or not undeclared:
xyvar.append(Dummy('f(%s)' % x.name))
else:
xyvar.append(undeclared.pop())
var_start_end_y = _range_tuple(xyvar[1])
#Check whether the depth is greater than 4 or less than 0.
if depth > 4:
depth = 4
elif depth < 0:
depth = 0
series_argument = ImplicitSeries(expr, var_start_end_x, var_start_end_y,
has_equality, adaptive, depth,
points, line_color)
#set the x and y limits
kwargs['xlim'] = tuple(float(x) for x in var_start_end_x[1:])
kwargs['ylim'] = tuple(float(y) for y in var_start_end_y[1:])
# set the x and y labels
kwargs.setdefault('xlabel', var_start_end_x[0].name)
kwargs.setdefault('ylabel', var_start_end_y[0].name)
p = Plot(series_argument, **kwargs)
if show:
p.show()
return p
|
10a2e3680c19b3c1fdce205a063246b40f9fdb833e9f2659721e21298dc560a2 | """Plotting module for Sympy.
A plot is represented by the ``Plot`` class that contains a reference to the
backend and a list of the data series to be plotted. The data series are
instances of classes meant to simplify getting points and meshes from sympy
expressions. ``plot_backends`` is a dictionary with all the backends.
This module gives only the essential. For all the fancy stuff use directly
the backend. You can get the backend wrapper for every plot from the
``_backend`` attribute. Moreover the data series classes have various useful
methods like ``get_points``, ``get_segments``, ``get_meshes``, etc, that may
be useful if you wish to use another plotting library.
Especially if you need publication ready graphs and this module is not enough
for you - just get the ``_backend`` attribute and add whatever you want
directly to it. In the case of matplotlib (the common way to graph data in
python) just copy ``_backend.fig`` which is the figure and ``_backend.ax``
which is the axis and work on them as you would on any other matplotlib object.
Simplicity of code takes much greater importance than performance. Don't use it
if you care at all about performance. A new backend instance is initialized
every time you call ``show()`` and the old one is left to the garbage collector.
"""
from __future__ import print_function, division
import warnings
from sympy import sympify, Expr, Tuple, Dummy, Symbol
from sympy.external import import_module
from sympy.core.function import arity
from sympy.core.compatibility import Callable
from sympy.utilities.iterables import is_sequence
from .experimental_lambdify import (vectorized_lambdify, lambdify)
# N.B.
# When changing the minimum module version for matplotlib, please change
# the same in the `SymPyDocTestFinder`` in `sympy/testing/runtests.py`
# Backend specific imports - textplot
from sympy.plotting.textplot import textplot
# Global variable
# Set to False when running tests / doctests so that the plots don't show.
_show = True
def unset_show():
"""
Disable show(). For use in the tests.
"""
global _show
_show = False
##############################################################################
# The public interface
##############################################################################
class Plot(object):
"""The central class of the plotting module.
For interactive work the function ``plot`` is better suited.
This class permits the plotting of sympy expressions using numerous
backends (matplotlib, textplot, the old pyglet module for sympy, Google
charts api, etc).
The figure can contain an arbitrary number of plots of sympy expressions,
lists of coordinates of points, etc. Plot has a private attribute _series that
contains all data series to be plotted (expressions for lines or surfaces,
lists of points, etc (all subclasses of BaseSeries)). Those data series are
instances of classes not imported by ``from sympy import *``.
The customization of the figure is on two levels. Global options that
concern the figure as a whole (eg title, xlabel, scale, etc) and
per-data series options (eg name) and aesthetics (eg. color, point shape,
line type, etc.).
The difference between options and aesthetics is that an aesthetic can be
a function of the coordinates (or parameters in a parametric plot). The
supported values for an aesthetic are:
- None (the backend uses default values)
- a constant
- a function of one variable (the first coordinate or parameter)
- a function of two variables (the first and second coordinate or
parameters)
- a function of three variables (only in nonparametric 3D plots)
Their implementation depends on the backend so they may not work in some
backends.
If the plot is parametric and the arity of the aesthetic function permits
it the aesthetic is calculated over parameters and not over coordinates.
If the arity does not permit calculation over parameters the calculation is
done over coordinates.
Only cartesian coordinates are supported for the moment, but you can use
the parametric plots to plot in polar, spherical and cylindrical
coordinates.
The arguments for the constructor Plot must be subclasses of BaseSeries.
Any global option can be specified as a keyword argument.
The global options for a figure are:
- title : str
- xlabel : str
- ylabel : str
- legend : bool
- xscale : {'linear', 'log'}
- yscale : {'linear', 'log'}
- axis : bool
- axis_center : tuple of two floats or {'center', 'auto'}
- xlim : tuple of two floats
- ylim : tuple of two floats
- aspect_ratio : tuple of two floats or {'auto'}
- autoscale : bool
- margin : float in [0, 1]
- backend : {'default', 'matplotlib', 'text'}
The per data series options and aesthetics are:
There are none in the base series. See below for options for subclasses.
Some data series support additional aesthetics or options:
ListSeries, LineOver1DRangeSeries, Parametric2DLineSeries,
Parametric3DLineSeries support the following:
Aesthetics:
- line_color : function which returns a float.
options:
- label : str
- steps : bool
- integers_only : bool
SurfaceOver2DRangeSeries, ParametricSurfaceSeries support the following:
aesthetics:
- surface_color : function which returns a float.
"""
def __init__(self, *args,
title=None, xlabel=None, ylabel=None, aspect_ratio='auto',
xlim=None, ylim=None, axis_center='auto', axis=True,
xscale='linear', yscale='linear', legend=False, autoscale=True,
margin=0, annotations=None, markers=None, rectangles=None,
fill=None, backend='default', **kwargs):
super(Plot, self).__init__()
# Options for the graph as a whole.
# The possible values for each option are described in the docstring of
# Plot. They are based purely on convention, no checking is done.
self.title = title
self.xlabel = xlabel
self.ylabel = ylabel
self.aspect_ratio = aspect_ratio
self.axis_center = axis_center
self.axis = axis
self.xscale = xscale
self.yscale = yscale
self.legend = legend
self.autoscale = autoscale
self.margin = margin
self.annotations = annotations
self.markers = markers
self.rectangles = rectangles
self.fill = fill
# Contains the data objects to be plotted. The backend should be smart
# enough to iterate over this list.
self._series = []
self._series.extend(args)
# The backend type. On every show() a new backend instance is created
# in self._backend which is tightly coupled to the Plot instance
# (thanks to the parent attribute of the backend).
self.backend = plot_backends[backend]
is_real = \
lambda lim: all(getattr(i, 'is_real', True) for i in lim)
is_finite = \
lambda lim: all(getattr(i, 'is_finite', True) for i in lim)
self.xlim = None
self.ylim = None
if xlim:
if not is_real(xlim):
raise ValueError(
"All numbers from xlim={} must be real".format(xlim))
if not is_finite(xlim):
raise ValueError(
"All numbers from xlim={} must be finite".format(xlim))
self.xlim = (float(xlim[0]), float(xlim[1]))
if ylim:
if not is_real(ylim):
raise ValueError(
"All numbers from ylim={} must be real".format(ylim))
if not is_finite(ylim):
raise ValueError(
"All numbers from ylim={} must be finite".format(ylim))
self.ylim = (float(ylim[0]), float(ylim[1]))
def show(self):
# TODO move this to the backend (also for save)
if hasattr(self, '_backend'):
self._backend.close()
self._backend = self.backend(self)
self._backend.show()
def save(self, path):
if hasattr(self, '_backend'):
self._backend.close()
self._backend = self.backend(self)
self._backend.save(path)
def __str__(self):
series_strs = [('[%d]: ' % i) + str(s)
for i, s in enumerate(self._series)]
return 'Plot object containing:\n' + '\n'.join(series_strs)
def __getitem__(self, index):
return self._series[index]
def __setitem__(self, index, *args):
if len(args) == 1 and isinstance(args[0], BaseSeries):
self._series[index] = args
def __delitem__(self, index):
del self._series[index]
def append(self, arg):
"""Adds an element from a plot's series to an existing plot.
Examples
========
Consider two ``Plot`` objects, ``p1`` and ``p2``. To add the
second plot's first series object to the first, use the
``append`` method, like so:
.. plot::
:format: doctest
:include-source: True
>>> from sympy import symbols
>>> from sympy.plotting import plot
>>> x = symbols('x')
>>> p1 = plot(x*x, show=False)
>>> p2 = plot(x, show=False)
>>> p1.append(p2[0])
>>> p1
Plot object containing:
[0]: cartesian line: x**2 for x over (-10.0, 10.0)
[1]: cartesian line: x for x over (-10.0, 10.0)
>>> p1.show()
See Also
========
extend
"""
if isinstance(arg, BaseSeries):
self._series.append(arg)
else:
raise TypeError('Must specify element of plot to append.')
def extend(self, arg):
"""Adds all series from another plot.
Examples
========
Consider two ``Plot`` objects, ``p1`` and ``p2``. To add the
second plot to the first, use the ``extend`` method, like so:
.. plot::
:format: doctest
:include-source: True
>>> from sympy import symbols
>>> from sympy.plotting import plot
>>> x = symbols('x')
>>> p1 = plot(x**2, show=False)
>>> p2 = plot(x, -x, show=False)
>>> p1.extend(p2)
>>> p1
Plot object containing:
[0]: cartesian line: x**2 for x over (-10.0, 10.0)
[1]: cartesian line: x for x over (-10.0, 10.0)
[2]: cartesian line: -x for x over (-10.0, 10.0)
>>> p1.show()
"""
if isinstance(arg, Plot):
self._series.extend(arg._series)
elif is_sequence(arg):
self._series.extend(arg)
else:
raise TypeError('Expecting Plot or sequence of BaseSeries')
class PlotGrid(object):
"""This class helps to plot subplots from already created sympy plots
in a single figure.
Examples
========
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> from sympy import symbols
>>> from sympy.plotting import plot, plot3d, PlotGrid
>>> x, y = symbols('x, y')
>>> p1 = plot(x, x**2, x**3, (x, -5, 5))
>>> p2 = plot((x**2, (x, -6, 6)), (x, (x, -5, 5)))
>>> p3 = plot(x**3, (x, -5, 5))
>>> p4 = plot3d(x*y, (x, -5, 5), (y, -5, 5))
Plotting vertically in a single line:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> PlotGrid(2, 1 , p1, p2)
PlotGrid object containing:
Plot[0]:Plot object containing:
[0]: cartesian line: x for x over (-5.0, 5.0)
[1]: cartesian line: x**2 for x over (-5.0, 5.0)
[2]: cartesian line: x**3 for x over (-5.0, 5.0)
Plot[1]:Plot object containing:
[0]: cartesian line: x**2 for x over (-6.0, 6.0)
[1]: cartesian line: x for x over (-5.0, 5.0)
Plotting horizontally in a single line:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> PlotGrid(1, 3 , p2, p3, p4)
PlotGrid object containing:
Plot[0]:Plot object containing:
[0]: cartesian line: x**2 for x over (-6.0, 6.0)
[1]: cartesian line: x for x over (-5.0, 5.0)
Plot[1]:Plot object containing:
[0]: cartesian line: x**3 for x over (-5.0, 5.0)
Plot[2]:Plot object containing:
[0]: cartesian surface: x*y for x over (-5.0, 5.0) and y over (-5.0, 5.0)
Plotting in a grid form:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> PlotGrid(2, 2, p1, p2 ,p3, p4)
PlotGrid object containing:
Plot[0]:Plot object containing:
[0]: cartesian line: x for x over (-5.0, 5.0)
[1]: cartesian line: x**2 for x over (-5.0, 5.0)
[2]: cartesian line: x**3 for x over (-5.0, 5.0)
Plot[1]:Plot object containing:
[0]: cartesian line: x**2 for x over (-6.0, 6.0)
[1]: cartesian line: x for x over (-5.0, 5.0)
Plot[2]:Plot object containing:
[0]: cartesian line: x**3 for x over (-5.0, 5.0)
Plot[3]:Plot object containing:
[0]: cartesian surface: x*y for x over (-5.0, 5.0) and y over (-5.0, 5.0)
"""
def __init__(self, nrows, ncolumns, *args, **kwargs):
"""
Parameters
==========
nrows : The number of rows that should be in the grid of the
required subplot
ncolumns : The number of columns that should be in the grid
of the required subplot
nrows and ncolumns together define the required grid
Arguments
=========
A list of predefined plot objects entered in a row-wise sequence
i.e. plot objects which are to be in the top row of the required
grid are written first, then the second row objects and so on
Keyword arguments
=================
show : Boolean
The default value is set to ``True``. Set show to ``False`` and
the function will not display the subplot. The returned instance
of the ``PlotGrid`` class can then be used to save or display the
plot by calling the ``save()`` and ``show()`` methods
respectively.
"""
self.nrows = nrows
self.ncolumns = ncolumns
self._series = []
self.args = args
for arg in args:
self._series.append(arg._series)
self.backend = DefaultBackend
show = kwargs.pop('show', True)
if show:
self.show()
def show(self):
if hasattr(self, '_backend'):
self._backend.close()
self._backend = self.backend(self)
self._backend.show()
def save(self, path):
if hasattr(self, '_backend'):
self._backend.close()
self._backend = self.backend(self)
self._backend.save(path)
def __str__(self):
plot_strs = [('Plot[%d]:' % i) + str(plot)
for i, plot in enumerate(self.args)]
return 'PlotGrid object containing:\n' + '\n'.join(plot_strs)
##############################################################################
# Data Series
##############################################################################
#TODO more general way to calculate aesthetics (see get_color_array)
### The base class for all series
class BaseSeries(object):
"""Base class for the data objects containing stuff to be plotted.
The backend should check if it supports the data series that it's given.
(eg TextBackend supports only LineOver1DRange).
It's the backend responsibility to know how to use the class of
data series that it's given.
Some data series classes are grouped (using a class attribute like is_2Dline)
according to the api they present (based only on convention). The backend is
not obliged to use that api (eg. The LineOver1DRange belongs to the
is_2Dline group and presents the get_points method, but the
TextBackend does not use the get_points method).
"""
# Some flags follow. The rationale for using flags instead of checking base
# classes is that setting multiple flags is simpler than multiple
# inheritance.
is_2Dline = False
# Some of the backends expect:
# - get_points returning 1D np.arrays list_x, list_y
# - get_segments returning np.array (done in Line2DBaseSeries)
# - get_color_array returning 1D np.array (done in Line2DBaseSeries)
# with the colors calculated at the points from get_points
is_3Dline = False
# Some of the backends expect:
# - get_points returning 1D np.arrays list_x, list_y, list_y
# - get_segments returning np.array (done in Line2DBaseSeries)
# - get_color_array returning 1D np.array (done in Line2DBaseSeries)
# with the colors calculated at the points from get_points
is_3Dsurface = False
# Some of the backends expect:
# - get_meshes returning mesh_x, mesh_y, mesh_z (2D np.arrays)
# - get_points an alias for get_meshes
is_contour = False
# Some of the backends expect:
# - get_meshes returning mesh_x, mesh_y, mesh_z (2D np.arrays)
# - get_points an alias for get_meshes
is_implicit = False
# Some of the backends expect:
# - get_meshes returning mesh_x (1D array), mesh_y(1D array,
# mesh_z (2D np.arrays)
# - get_points an alias for get_meshes
# Different from is_contour as the colormap in backend will be
# different
is_parametric = False
# The calculation of aesthetics expects:
# - get_parameter_points returning one or two np.arrays (1D or 2D)
# used for calculation aesthetics
def __init__(self):
super(BaseSeries, self).__init__()
@property
def is_3D(self):
flags3D = [
self.is_3Dline,
self.is_3Dsurface
]
return any(flags3D)
@property
def is_line(self):
flagslines = [
self.is_2Dline,
self.is_3Dline
]
return any(flagslines)
### 2D lines
class Line2DBaseSeries(BaseSeries):
"""A base class for 2D lines.
- adding the label, steps and only_integers options
- making is_2Dline true
- defining get_segments and get_color_array
"""
is_2Dline = True
_dim = 2
def __init__(self):
super(Line2DBaseSeries, self).__init__()
self.label = None
self.steps = False
self.only_integers = False
self.line_color = None
def get_segments(self):
np = import_module('numpy')
points = self.get_points()
if self.steps is True:
x = np.array((points[0], points[0])).T.flatten()[1:]
y = np.array((points[1], points[1])).T.flatten()[:-1]
points = (x, y)
points = np.ma.array(points).T.reshape(-1, 1, self._dim)
return np.ma.concatenate([points[:-1], points[1:]], axis=1)
def get_color_array(self):
np = import_module('numpy')
c = self.line_color
if hasattr(c, '__call__'):
f = np.vectorize(c)
nargs = arity(c)
if nargs == 1 and self.is_parametric:
x = self.get_parameter_points()
return f(centers_of_segments(x))
else:
variables = list(map(centers_of_segments, self.get_points()))
if nargs == 1:
return f(variables[0])
elif nargs == 2:
return f(*variables[:2])
else: # only if the line is 3D (otherwise raises an error)
return f(*variables)
else:
return c*np.ones(self.nb_of_points)
class List2DSeries(Line2DBaseSeries):
"""Representation for a line consisting of list of points."""
def __init__(self, list_x, list_y):
np = import_module('numpy')
super(List2DSeries, self).__init__()
self.list_x = np.array(list_x)
self.list_y = np.array(list_y)
self.label = 'list'
def __str__(self):
return 'list plot'
def get_points(self):
return (self.list_x, self.list_y)
class LineOver1DRangeSeries(Line2DBaseSeries):
"""Representation for a line consisting of a SymPy expression over a range."""
def __init__(self, expr, var_start_end, **kwargs):
super(LineOver1DRangeSeries, self).__init__()
self.expr = sympify(expr)
self.label = kwargs.get('label', None) or str(self.expr)
self.var = sympify(var_start_end[0])
self.start = float(var_start_end[1])
self.end = float(var_start_end[2])
self.nb_of_points = kwargs.get('nb_of_points', 300)
self.adaptive = kwargs.get('adaptive', True)
self.depth = kwargs.get('depth', 12)
self.line_color = kwargs.get('line_color', None)
self.xscale = kwargs.get('xscale', 'linear')
def __str__(self):
return 'cartesian line: %s for %s over %s' % (
str(self.expr), str(self.var), str((self.start, self.end)))
def get_segments(self):
"""
Adaptively gets segments for plotting.
The adaptive sampling is done by recursively checking if three
points are almost collinear. If they are not collinear, then more
points are added between those points.
References
==========
.. [1] Adaptive polygonal approximation of parametric curves,
Luiz Henrique de Figueiredo.
"""
if self.only_integers or not self.adaptive:
return super(LineOver1DRangeSeries, self).get_segments()
else:
f = lambdify([self.var], self.expr)
list_segments = []
np = import_module('numpy')
def sample(p, q, depth):
""" Samples recursively if three points are almost collinear.
For depth < 6, points are added irrespective of whether they
satisfy the collinearity condition or not. The maximum depth
allowed is 12.
"""
# Randomly sample to avoid aliasing.
random = 0.45 + np.random.rand() * 0.1
if self.xscale == 'log':
xnew = 10**(np.log10(p[0]) + random * (np.log10(q[0]) -
np.log10(p[0])))
else:
xnew = p[0] + random * (q[0] - p[0])
ynew = f(xnew)
new_point = np.array([xnew, ynew])
# Maximum depth
if depth > self.depth:
list_segments.append([p, q])
# Sample irrespective of whether the line is flat till the
# depth of 6. We are not using linspace to avoid aliasing.
elif depth < 6:
sample(p, new_point, depth + 1)
sample(new_point, q, depth + 1)
# Sample ten points if complex values are encountered
# at both ends. If there is a real value in between, then
# sample those points further.
elif p[1] is None and q[1] is None:
if self.xscale == 'log':
xarray = np.logspace(p[0], q[0], 10)
else:
xarray = np.linspace(p[0], q[0], 10)
yarray = list(map(f, xarray))
if any(y is not None for y in yarray):
for i in range(len(yarray) - 1):
if yarray[i] is not None or yarray[i + 1] is not None:
sample([xarray[i], yarray[i]],
[xarray[i + 1], yarray[i + 1]], depth + 1)
# Sample further if one of the end points in None (i.e. a
# complex value) or the three points are not almost collinear.
elif (p[1] is None or q[1] is None or new_point[1] is None
or not flat(p, new_point, q)):
sample(p, new_point, depth + 1)
sample(new_point, q, depth + 1)
else:
list_segments.append([p, q])
f_start = f(self.start)
f_end = f(self.end)
sample(np.array([self.start, f_start]),
np.array([self.end, f_end]), 0)
return list_segments
def get_points(self):
np = import_module('numpy')
if self.only_integers is True:
if self.xscale == 'log':
list_x = np.logspace(int(self.start), int(self.end),
num=int(self.end) - int(self.start) + 1)
else:
list_x = np.linspace(int(self.start), int(self.end),
num=int(self.end) - int(self.start) + 1)
else:
if self.xscale == 'log':
list_x = np.logspace(self.start, self.end, num=self.nb_of_points)
else:
list_x = np.linspace(self.start, self.end, num=self.nb_of_points)
f = vectorized_lambdify([self.var], self.expr)
list_y = f(list_x)
return (list_x, list_y)
class Parametric2DLineSeries(Line2DBaseSeries):
"""Representation for a line consisting of two parametric sympy expressions
over a range."""
is_parametric = True
def __init__(self, expr_x, expr_y, var_start_end, **kwargs):
super(Parametric2DLineSeries, self).__init__()
self.expr_x = sympify(expr_x)
self.expr_y = sympify(expr_y)
self.label = kwargs.get('label', None) or \
"(%s, %s)" % (str(self.expr_x), str(self.expr_y))
self.var = sympify(var_start_end[0])
self.start = float(var_start_end[1])
self.end = float(var_start_end[2])
self.nb_of_points = kwargs.get('nb_of_points', 300)
self.adaptive = kwargs.get('adaptive', True)
self.depth = kwargs.get('depth', 12)
self.line_color = kwargs.get('line_color', None)
def __str__(self):
return 'parametric cartesian line: (%s, %s) for %s over %s' % (
str(self.expr_x), str(self.expr_y), str(self.var),
str((self.start, self.end)))
def get_parameter_points(self):
np = import_module('numpy')
return np.linspace(self.start, self.end, num=self.nb_of_points)
def get_points(self):
param = self.get_parameter_points()
fx = vectorized_lambdify([self.var], self.expr_x)
fy = vectorized_lambdify([self.var], self.expr_y)
list_x = fx(param)
list_y = fy(param)
return (list_x, list_y)
def get_segments(self):
"""
Adaptively gets segments for plotting.
The adaptive sampling is done by recursively checking if three
points are almost collinear. If they are not collinear, then more
points are added between those points.
References
==========
[1] Adaptive polygonal approximation of parametric curves,
Luiz Henrique de Figueiredo.
"""
if not self.adaptive:
return super(Parametric2DLineSeries, self).get_segments()
f_x = lambdify([self.var], self.expr_x)
f_y = lambdify([self.var], self.expr_y)
list_segments = []
def sample(param_p, param_q, p, q, depth):
""" Samples recursively if three points are almost collinear.
For depth < 6, points are added irrespective of whether they
satisfy the collinearity condition or not. The maximum depth
allowed is 12.
"""
# Randomly sample to avoid aliasing.
np = import_module('numpy')
random = 0.45 + np.random.rand() * 0.1
param_new = param_p + random * (param_q - param_p)
xnew = f_x(param_new)
ynew = f_y(param_new)
new_point = np.array([xnew, ynew])
# Maximum depth
if depth > self.depth:
list_segments.append([p, q])
# Sample irrespective of whether the line is flat till the
# depth of 6. We are not using linspace to avoid aliasing.
elif depth < 6:
sample(param_p, param_new, p, new_point, depth + 1)
sample(param_new, param_q, new_point, q, depth + 1)
# Sample ten points if complex values are encountered
# at both ends. If there is a real value in between, then
# sample those points further.
elif ((p[0] is None and q[1] is None) or
(p[1] is None and q[1] is None)):
param_array = np.linspace(param_p, param_q, 10)
x_array = list(map(f_x, param_array))
y_array = list(map(f_y, param_array))
if any(x is not None and y is not None
for x, y in zip(x_array, y_array)):
for i in range(len(y_array) - 1):
if ((x_array[i] is not None and y_array[i] is not None) or
(x_array[i + 1] is not None and y_array[i + 1] is not None)):
point_a = [x_array[i], y_array[i]]
point_b = [x_array[i + 1], y_array[i + 1]]
sample(param_array[i], param_array[i], point_a,
point_b, depth + 1)
# Sample further if one of the end points in None (i.e. a complex
# value) or the three points are not almost collinear.
elif (p[0] is None or p[1] is None
or q[1] is None or q[0] is None
or not flat(p, new_point, q)):
sample(param_p, param_new, p, new_point, depth + 1)
sample(param_new, param_q, new_point, q, depth + 1)
else:
list_segments.append([p, q])
f_start_x = f_x(self.start)
f_start_y = f_y(self.start)
start = [f_start_x, f_start_y]
f_end_x = f_x(self.end)
f_end_y = f_y(self.end)
end = [f_end_x, f_end_y]
sample(self.start, self.end, start, end, 0)
return list_segments
### 3D lines
class Line3DBaseSeries(Line2DBaseSeries):
"""A base class for 3D lines.
Most of the stuff is derived from Line2DBaseSeries."""
is_2Dline = False
is_3Dline = True
_dim = 3
def __init__(self):
super(Line3DBaseSeries, self).__init__()
class Parametric3DLineSeries(Line3DBaseSeries):
"""Representation for a 3D line consisting of two parametric sympy
expressions and a range."""
def __init__(self, expr_x, expr_y, expr_z, var_start_end, **kwargs):
super(Parametric3DLineSeries, self).__init__()
self.expr_x = sympify(expr_x)
self.expr_y = sympify(expr_y)
self.expr_z = sympify(expr_z)
self.label = kwargs.get('label', None) or \
"(%s, %s)" % (str(self.expr_x), str(self.expr_y))
self.var = sympify(var_start_end[0])
self.start = float(var_start_end[1])
self.end = float(var_start_end[2])
self.nb_of_points = kwargs.get('nb_of_points', 300)
self.line_color = kwargs.get('line_color', None)
def __str__(self):
return '3D parametric cartesian line: (%s, %s, %s) for %s over %s' % (
str(self.expr_x), str(self.expr_y), str(self.expr_z),
str(self.var), str((self.start, self.end)))
def get_parameter_points(self):
np = import_module('numpy')
return np.linspace(self.start, self.end, num=self.nb_of_points)
def get_points(self):
np = import_module('numpy')
param = self.get_parameter_points()
fx = vectorized_lambdify([self.var], self.expr_x)
fy = vectorized_lambdify([self.var], self.expr_y)
fz = vectorized_lambdify([self.var], self.expr_z)
list_x = fx(param)
list_y = fy(param)
list_z = fz(param)
list_x = np.array(list_x, dtype=np.float64)
list_y = np.array(list_y, dtype=np.float64)
list_z = np.array(list_z, dtype=np.float64)
list_x = np.ma.masked_invalid(list_x)
list_y = np.ma.masked_invalid(list_y)
list_z = np.ma.masked_invalid(list_z)
self._xlim = (np.amin(list_x), np.amax(list_x))
self._ylim = (np.amin(list_y), np.amax(list_y))
self._zlim = (np.amin(list_z), np.amax(list_z))
return list_x, list_y, list_z
### Surfaces
class SurfaceBaseSeries(BaseSeries):
"""A base class for 3D surfaces."""
is_3Dsurface = True
def __init__(self):
super(SurfaceBaseSeries, self).__init__()
self.surface_color = None
def get_color_array(self):
np = import_module('numpy')
c = self.surface_color
if isinstance(c, Callable):
f = np.vectorize(c)
nargs = arity(c)
if self.is_parametric:
variables = list(map(centers_of_faces, self.get_parameter_meshes()))
if nargs == 1:
return f(variables[0])
elif nargs == 2:
return f(*variables)
variables = list(map(centers_of_faces, self.get_meshes()))
if nargs == 1:
return f(variables[0])
elif nargs == 2:
return f(*variables[:2])
else:
return f(*variables)
else:
return c*np.ones(self.nb_of_points)
class SurfaceOver2DRangeSeries(SurfaceBaseSeries):
"""Representation for a 3D surface consisting of a sympy expression and 2D
range."""
def __init__(self, expr, var_start_end_x, var_start_end_y, **kwargs):
super(SurfaceOver2DRangeSeries, self).__init__()
self.expr = sympify(expr)
self.var_x = sympify(var_start_end_x[0])
self.start_x = float(var_start_end_x[1])
self.end_x = float(var_start_end_x[2])
self.var_y = sympify(var_start_end_y[0])
self.start_y = float(var_start_end_y[1])
self.end_y = float(var_start_end_y[2])
self.nb_of_points_x = kwargs.get('nb_of_points_x', 50)
self.nb_of_points_y = kwargs.get('nb_of_points_y', 50)
self.surface_color = kwargs.get('surface_color', None)
self._xlim = (self.start_x, self.end_x)
self._ylim = (self.start_y, self.end_y)
def __str__(self):
return ('cartesian surface: %s for'
' %s over %s and %s over %s') % (
str(self.expr),
str(self.var_x),
str((self.start_x, self.end_x)),
str(self.var_y),
str((self.start_y, self.end_y)))
def get_meshes(self):
np = import_module('numpy')
mesh_x, mesh_y = np.meshgrid(np.linspace(self.start_x, self.end_x,
num=self.nb_of_points_x),
np.linspace(self.start_y, self.end_y,
num=self.nb_of_points_y))
f = vectorized_lambdify((self.var_x, self.var_y), self.expr)
mesh_z = f(mesh_x, mesh_y)
mesh_z = np.array(mesh_z, dtype=np.float64)
mesh_z = np.ma.masked_invalid(mesh_z)
self._zlim = (np.amin(mesh_z), np.amax(mesh_z))
return mesh_x, mesh_y, mesh_z
class ParametricSurfaceSeries(SurfaceBaseSeries):
"""Representation for a 3D surface consisting of three parametric sympy
expressions and a range."""
is_parametric = True
def __init__(
self, expr_x, expr_y, expr_z, var_start_end_u, var_start_end_v,
**kwargs):
super(ParametricSurfaceSeries, self).__init__()
self.expr_x = sympify(expr_x)
self.expr_y = sympify(expr_y)
self.expr_z = sympify(expr_z)
self.var_u = sympify(var_start_end_u[0])
self.start_u = float(var_start_end_u[1])
self.end_u = float(var_start_end_u[2])
self.var_v = sympify(var_start_end_v[0])
self.start_v = float(var_start_end_v[1])
self.end_v = float(var_start_end_v[2])
self.nb_of_points_u = kwargs.get('nb_of_points_u', 50)
self.nb_of_points_v = kwargs.get('nb_of_points_v', 50)
self.surface_color = kwargs.get('surface_color', None)
def __str__(self):
return ('parametric cartesian surface: (%s, %s, %s) for'
' %s over %s and %s over %s') % (
str(self.expr_x),
str(self.expr_y),
str(self.expr_z),
str(self.var_u),
str((self.start_u, self.end_u)),
str(self.var_v),
str((self.start_v, self.end_v)))
def get_parameter_meshes(self):
np = import_module('numpy')
return np.meshgrid(np.linspace(self.start_u, self.end_u,
num=self.nb_of_points_u),
np.linspace(self.start_v, self.end_v,
num=self.nb_of_points_v))
def get_meshes(self):
np = import_module('numpy')
mesh_u, mesh_v = self.get_parameter_meshes()
fx = vectorized_lambdify((self.var_u, self.var_v), self.expr_x)
fy = vectorized_lambdify((self.var_u, self.var_v), self.expr_y)
fz = vectorized_lambdify((self.var_u, self.var_v), self.expr_z)
mesh_x = fx(mesh_u, mesh_v)
mesh_y = fy(mesh_u, mesh_v)
mesh_z = fz(mesh_u, mesh_v)
mesh_x = np.array(mesh_x, dtype=np.float64)
mesh_y = np.array(mesh_y, dtype=np.float64)
mesh_z = np.array(mesh_z, dtype=np.float64)
mesh_x = np.ma.masked_invalid(mesh_x)
mesh_y = np.ma.masked_invalid(mesh_y)
mesh_z = np.ma.masked_invalid(mesh_z)
self._xlim = (np.amin(mesh_x), np.amax(mesh_x))
self._ylim = (np.amin(mesh_y), np.amax(mesh_y))
self._zlim = (np.amin(mesh_z), np.amax(mesh_z))
return mesh_x, mesh_y, mesh_z
### Contours
class ContourSeries(BaseSeries):
"""Representation for a contour plot."""
# The code is mostly repetition of SurfaceOver2DRange.
# Presently used in contour_plot function
is_contour = True
def __init__(self, expr, var_start_end_x, var_start_end_y):
super(ContourSeries, self).__init__()
self.nb_of_points_x = 50
self.nb_of_points_y = 50
self.expr = sympify(expr)
self.var_x = sympify(var_start_end_x[0])
self.start_x = float(var_start_end_x[1])
self.end_x = float(var_start_end_x[2])
self.var_y = sympify(var_start_end_y[0])
self.start_y = float(var_start_end_y[1])
self.end_y = float(var_start_end_y[2])
self.get_points = self.get_meshes
self._xlim = (self.start_x, self.end_x)
self._ylim = (self.start_y, self.end_y)
def __str__(self):
return ('contour: %s for '
'%s over %s and %s over %s') % (
str(self.expr),
str(self.var_x),
str((self.start_x, self.end_x)),
str(self.var_y),
str((self.start_y, self.end_y)))
def get_meshes(self):
np = import_module('numpy')
mesh_x, mesh_y = np.meshgrid(np.linspace(self.start_x, self.end_x,
num=self.nb_of_points_x),
np.linspace(self.start_y, self.end_y,
num=self.nb_of_points_y))
f = vectorized_lambdify((self.var_x, self.var_y), self.expr)
return (mesh_x, mesh_y, f(mesh_x, mesh_y))
##############################################################################
# Backends
##############################################################################
class BaseBackend(object):
def __init__(self, parent):
super(BaseBackend, self).__init__()
self.parent = parent
# Don't have to check for the success of importing matplotlib in each case;
# we will only be using this backend if we can successfully import matploblib
class MatplotlibBackend(BaseBackend):
def __init__(self, parent):
super(MatplotlibBackend, self).__init__(parent)
self.matplotlib = import_module('matplotlib',
import_kwargs={'fromlist': ['pyplot', 'cm', 'collections']},
min_module_version='1.1.0', catch=(RuntimeError,))
self.plt = self.matplotlib.pyplot
self.cm = self.matplotlib.cm
self.LineCollection = self.matplotlib.collections.LineCollection
aspect = getattr(self.parent, 'aspect_ratio', 'auto')
if aspect != 'auto':
aspect = float(aspect[1]) / aspect[0]
if isinstance(self.parent, Plot):
nrows, ncolumns = 1, 1
series_list = [self.parent._series]
elif isinstance(self.parent, PlotGrid):
nrows, ncolumns = self.parent.nrows, self.parent.ncolumns
series_list = self.parent._series
self.ax = []
self.fig = self.plt.figure()
for i, series in enumerate(series_list):
are_3D = [s.is_3D for s in series]
if any(are_3D) and not all(are_3D):
raise ValueError('The matplotlib backend can not mix 2D and 3D.')
elif all(are_3D):
# mpl_toolkits.mplot3d is necessary for
# projection='3d'
mpl_toolkits = import_module('mpl_toolkits', # noqa
import_kwargs={'fromlist': ['mplot3d']})
self.ax.append(self.fig.add_subplot(nrows, ncolumns, i + 1, projection='3d', aspect=aspect))
elif not any(are_3D):
self.ax.append(self.fig.add_subplot(nrows, ncolumns, i + 1, aspect=aspect))
self.ax[i].spines['left'].set_position('zero')
self.ax[i].spines['right'].set_color('none')
self.ax[i].spines['bottom'].set_position('zero')
self.ax[i].spines['top'].set_color('none')
self.ax[i].xaxis.set_ticks_position('bottom')
self.ax[i].yaxis.set_ticks_position('left')
def _process_series(self, series, ax, parent):
np = import_module('numpy')
mpl_toolkits = import_module(
'mpl_toolkits', import_kwargs={'fromlist': ['mplot3d']})
# XXX Workaround for matplotlib issue
# https://github.com/matplotlib/matplotlib/issues/17130
xlims, ylims, zlims = [], [], []
for s in series:
# Create the collections
if s.is_2Dline:
collection = self.LineCollection(s.get_segments())
ax.add_collection(collection)
elif s.is_contour:
ax.contour(*s.get_meshes())
elif s.is_3Dline:
# TODO too complicated, I blame matplotlib
art3d = mpl_toolkits.mplot3d.art3d
collection = art3d.Line3DCollection(s.get_segments())
ax.add_collection(collection)
x, y, z = s.get_points()
xlims.append(s._xlim)
ylims.append(s._ylim)
zlims.append(s._zlim)
elif s.is_3Dsurface:
x, y, z = s.get_meshes()
collection = ax.plot_surface(x, y, z,
cmap=getattr(self.cm, 'viridis', self.cm.jet),
rstride=1, cstride=1, linewidth=0.1)
xlims.append(s._xlim)
ylims.append(s._ylim)
zlims.append(s._zlim)
elif s.is_implicit:
points = s.get_raster()
if len(points) == 2:
# interval math plotting
x, y = _matplotlib_list(points[0])
ax.fill(x, y, facecolor=s.line_color, edgecolor='None')
else:
# use contourf or contour depending on whether it is
# an inequality or equality.
# XXX: ``contour`` plots multiple lines. Should be fixed.
ListedColormap = self.matplotlib.colors.ListedColormap
colormap = ListedColormap(["white", s.line_color])
xarray, yarray, zarray, plot_type = points
if plot_type == 'contour':
ax.contour(xarray, yarray, zarray, cmap=colormap)
else:
ax.contourf(xarray, yarray, zarray, cmap=colormap)
else:
raise NotImplementedError(
'{} is not supported in the sympy plotting module '
'with matplotlib backend. Please report this issue.'
.format(ax))
# Customise the collections with the corresponding per-series
# options.
if hasattr(s, 'label'):
collection.set_label(s.label)
if s.is_line and s.line_color:
if isinstance(s.line_color, (float, int)) or isinstance(s.line_color, Callable):
color_array = s.get_color_array()
collection.set_array(color_array)
else:
collection.set_color(s.line_color)
if s.is_3Dsurface and s.surface_color:
if self.matplotlib.__version__ < "1.2.0": # TODO in the distant future remove this check
warnings.warn('The version of matplotlib is too old to use surface coloring.')
elif isinstance(s.surface_color, (float, int)) or isinstance(s.surface_color, Callable):
color_array = s.get_color_array()
color_array = color_array.reshape(color_array.size)
collection.set_array(color_array)
else:
collection.set_color(s.surface_color)
Axes3D = mpl_toolkits.mplot3d.Axes3D
if not isinstance(ax, Axes3D):
ax.autoscale_view(
scalex=ax.get_autoscalex_on(),
scaley=ax.get_autoscaley_on())
else:
# XXX Workaround for matplotlib issue
# https://github.com/matplotlib/matplotlib/issues/17130
if xlims:
xlims = np.array(xlims)
xlim = (np.amin(xlims[:, 0]), np.amax(xlims[:, 1]))
ax.set_xlim(xlim)
else:
ax.set_xlim([0, 1])
if ylims:
ylims = np.array(ylims)
ylim = (np.amin(ylims[:, 0]), np.amax(ylims[:, 1]))
ax.set_ylim(ylim)
else:
ax.set_ylim([0, 1])
if zlims:
zlims = np.array(zlims)
zlim = (np.amin(zlims[:, 0]), np.amax(zlims[:, 1]))
ax.set_zlim(zlim)
else:
ax.set_zlim([0, 1])
# Set global options.
# TODO The 3D stuff
# XXX The order of those is important.
if parent.xscale and not isinstance(ax, Axes3D):
ax.set_xscale(parent.xscale)
if parent.yscale and not isinstance(ax, Axes3D):
ax.set_yscale(parent.yscale)
if not isinstance(ax, Axes3D) or self.matplotlib.__version__ >= '1.2.0': # XXX in the distant future remove this check
ax.set_autoscale_on(parent.autoscale)
if parent.axis_center:
val = parent.axis_center
if isinstance(ax, Axes3D):
pass
elif val == 'center':
ax.spines['left'].set_position('center')
ax.spines['bottom'].set_position('center')
elif val == 'auto':
xl, xh = ax.get_xlim()
yl, yh = ax.get_ylim()
pos_left = ('data', 0) if xl*xh <= 0 else 'center'
pos_bottom = ('data', 0) if yl*yh <= 0 else 'center'
ax.spines['left'].set_position(pos_left)
ax.spines['bottom'].set_position(pos_bottom)
else:
ax.spines['left'].set_position(('data', val[0]))
ax.spines['bottom'].set_position(('data', val[1]))
if not parent.axis:
ax.set_axis_off()
if parent.legend:
if ax.legend():
ax.legend_.set_visible(parent.legend)
if parent.margin:
ax.set_xmargin(parent.margin)
ax.set_ymargin(parent.margin)
if parent.title:
ax.set_title(parent.title)
if parent.xlabel:
ax.set_xlabel(parent.xlabel, position=(1, 0))
if parent.ylabel:
ax.set_ylabel(parent.ylabel, position=(0, 1))
if parent.annotations:
for a in parent.annotations:
ax.annotate(**a)
if parent.markers:
for marker in parent.markers:
# make a copy of the marker dictionary
# so that it doesn't get altered
m = marker.copy()
args = m.pop('args')
ax.plot(*args, **m)
if parent.rectangles:
for r in parent.rectangles:
rect = self.matplotlib.patches.Rectangle(**r)
ax.add_patch(rect)
if parent.fill:
ax.fill_between(**parent.fill)
# xlim and ylim shoulld always be set at last so that plot limits
# doesn't get altered during the process.
if parent.xlim:
ax.set_xlim(parent.xlim)
if parent.ylim:
ax.set_ylim(parent.ylim)
def process_series(self):
"""
Iterates over every ``Plot`` object and further calls
_process_series()
"""
parent = self.parent
if isinstance(parent, Plot):
series_list = [parent._series]
else:
series_list = parent._series
for i, (series, ax) in enumerate(zip(series_list, self.ax)):
if isinstance(self.parent, PlotGrid):
parent = self.parent.args[i]
self._process_series(series, ax, parent)
def show(self):
self.process_series()
#TODO after fixing https://github.com/ipython/ipython/issues/1255
# you can uncomment the next line and remove the pyplot.show() call
#self.fig.show()
if _show:
self.fig.tight_layout()
self.plt.show()
else:
self.close()
def save(self, path):
self.process_series()
self.fig.savefig(path)
def close(self):
self.plt.close(self.fig)
class TextBackend(BaseBackend):
def __init__(self, parent):
super(TextBackend, self).__init__(parent)
def show(self):
if not _show:
return
if len(self.parent._series) != 1:
raise ValueError(
'The TextBackend supports only one graph per Plot.')
elif not isinstance(self.parent._series[0], LineOver1DRangeSeries):
raise ValueError(
'The TextBackend supports only expressions over a 1D range')
else:
ser = self.parent._series[0]
textplot(ser.expr, ser.start, ser.end)
def close(self):
pass
class DefaultBackend(BaseBackend):
def __new__(cls, parent):
matplotlib = import_module('matplotlib', min_module_version='1.1.0', catch=(RuntimeError,))
if matplotlib:
return MatplotlibBackend(parent)
else:
return TextBackend(parent)
plot_backends = {
'matplotlib': MatplotlibBackend,
'text': TextBackend,
'default': DefaultBackend
}
##############################################################################
# Finding the centers of line segments or mesh faces
##############################################################################
def centers_of_segments(array):
np = import_module('numpy')
return np.mean(np.vstack((array[:-1], array[1:])), 0)
def centers_of_faces(array):
np = import_module('numpy')
return np.mean(np.dstack((array[:-1, :-1],
array[1:, :-1],
array[:-1, 1:],
array[:-1, :-1],
)), 2)
def flat(x, y, z, eps=1e-3):
"""Checks whether three points are almost collinear"""
np = import_module('numpy')
# Workaround plotting piecewise (#8577):
# workaround for `lambdify` in `.experimental_lambdify` fails
# to return numerical values in some cases. Lower-level fix
# in `lambdify` is possible.
vector_a = (x - y).astype(np.float)
vector_b = (z - y).astype(np.float)
dot_product = np.dot(vector_a, vector_b)
vector_a_norm = np.linalg.norm(vector_a)
vector_b_norm = np.linalg.norm(vector_b)
cos_theta = dot_product / (vector_a_norm * vector_b_norm)
return abs(cos_theta + 1) < eps
def _matplotlib_list(interval_list):
"""
Returns lists for matplotlib ``fill`` command from a list of bounding
rectangular intervals
"""
xlist = []
ylist = []
if len(interval_list):
for intervals in interval_list:
intervalx = intervals[0]
intervaly = intervals[1]
xlist.extend([intervalx.start, intervalx.start,
intervalx.end, intervalx.end, None])
ylist.extend([intervaly.start, intervaly.end,
intervaly.end, intervaly.start, None])
else:
#XXX Ugly hack. Matplotlib does not accept empty lists for ``fill``
xlist.extend([None, None, None, None])
ylist.extend([None, None, None, None])
return xlist, ylist
####New API for plotting module ####
# TODO: Add color arrays for plots.
# TODO: Add more plotting options for 3d plots.
# TODO: Adaptive sampling for 3D plots.
def plot(*args, **kwargs):
"""Plots a function of a single variable as a curve.
Parameters
==========
args
The first argument is the expression representing the function
of single variable to be plotted.
The last argument is a 3-tuple denoting the range of the free
variable. e.g. ``(x, 0, 5)``
Typical usage examples are in the followings:
- Plotting a single expression with a single range.
``plot(expr, range, **kwargs)``
- Plotting a single expression with the default range (-10, 10).
``plot(expr, **kwargs)``
- Plotting multiple expressions with a single range.
``plot(expr1, expr2, ..., range, **kwargs)``
- Plotting multiple expressions with multiple ranges.
``plot((expr1, range1), (expr2, range2), ..., **kwargs)``
It is best practice to specify range explicitly because default
range may change in the future if a more advanced default range
detection algorithm is implemented.
show : bool, optional
The default value is set to ``True``. Set show to ``False`` and
the function will not display the plot. The returned instance of
the ``Plot`` class can then be used to save or display the plot
by calling the ``save()`` and ``show()`` methods respectively.
line_color : float, optional
Specifies the color for the plot.
See ``Plot`` to see how to set color for the plots.
If there are multiple plots, then the same series series are
applied to all the plots. If you want to set these options
separately, you can index the ``Plot`` object returned and set
it.
title : str, optional
Title of the plot. It is set to the latex representation of
the expression, if the plot has only one expression.
label : str, optional
The label of the expression in the plot. It will be used when
called with ``legend``. Default is the name of the expression.
e.g. ``sin(x)``
xlabel : str, optional
Label for the x-axis.
ylabel : str, optional
Label for the y-axis.
xscale : 'linear' or 'log', optional
Sets the scaling of the x-axis.
yscale : 'linear' or 'log', optional
Sets the scaling of the y-axis.
axis_center : (float, float), optional
Tuple of two floats denoting the coordinates of the center or
{'center', 'auto'}
xlim : (float, float), optional
Denotes the x-axis limits, ``(min, max)```.
ylim : (float, float), optional
Denotes the y-axis limits, ``(min, max)```.
annotations : list, optional
A list of dictionaries specifying the type of annotation
required. The keys in the dictionary should be equivalent
to the arguments of the matplotlib's annotate() function.
markers : list, optional
A list of dictionaries specifying the type the markers required.
The keys in the dictionary should be equivalent to the arguments
of the matplotlib's plot() function along with the marker
related keyworded arguments.
rectangles : list, optional
A list of dictionaries specifying the dimensions of the
rectangles to be plotted. The keys in the dictionary should be
equivalent to the arguments of the matplotlib's
patches.Rectangle class.
fill : dict, optional
A dictionary specifying the type of color filling required in
the plot. The keys in the dictionary should be equivalent to the
arguments of the matplotlib's fill_between() function.
adaptive : bool, optional
The default value is set to ``True``. Set adaptive to ``False``
and specify ``nb_of_points`` if uniform sampling is required.
The plotting uses an adaptive algorithm which samples
recursively to accurately plot. The adaptive algorithm uses a
random point near the midpoint of two points that has to be
further sampled. Hence the same plots can appear slightly
different.
depth : int, optional
Recursion depth of the adaptive algorithm. A depth of value
``n`` samples a maximum of `2^{n}` points.
If the ``adaptive`` flag is set to ``False``, this will be
ignored.
nb_of_points : int, optional
Used when the ``adaptive`` is set to ``False``. The function
is uniformly sampled at ``nb_of_points`` number of points.
If the ``adaptive`` flag is set to ``True``, this will be
ignored.
Examples
========
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> from sympy import symbols
>>> from sympy.plotting import plot
>>> x = symbols('x')
Single Plot
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot(x**2, (x, -5, 5))
Plot object containing:
[0]: cartesian line: x**2 for x over (-5.0, 5.0)
Multiple plots with single range.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot(x, x**2, x**3, (x, -5, 5))
Plot object containing:
[0]: cartesian line: x for x over (-5.0, 5.0)
[1]: cartesian line: x**2 for x over (-5.0, 5.0)
[2]: cartesian line: x**3 for x over (-5.0, 5.0)
Multiple plots with different ranges.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot((x**2, (x, -6, 6)), (x, (x, -5, 5)))
Plot object containing:
[0]: cartesian line: x**2 for x over (-6.0, 6.0)
[1]: cartesian line: x for x over (-5.0, 5.0)
No adaptive sampling.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot(x**2, adaptive=False, nb_of_points=400)
Plot object containing:
[0]: cartesian line: x**2 for x over (-10.0, 10.0)
See Also
========
Plot, LineOver1DRangeSeries
"""
args = list(map(sympify, args))
free = set()
for a in args:
if isinstance(a, Expr):
free |= a.free_symbols
if len(free) > 1:
raise ValueError(
'The same variable should be used in all '
'univariate expressions being plotted.')
x = free.pop() if free else Symbol('x')
kwargs.setdefault('xlabel', x.name)
kwargs.setdefault('ylabel', 'f(%s)' % x.name)
show = kwargs.pop('show', True)
series = []
plot_expr = check_arguments(args, 1, 1)
series = [LineOver1DRangeSeries(*arg, **kwargs) for arg in plot_expr]
plots = Plot(*series, **kwargs)
if show:
plots.show()
return plots
def plot_parametric(*args, **kwargs):
"""
Plots a 2D parametric curve.
Parameters
==========
args
Common specifications are:
- Plotting a single parametric curve with a range
``plot_parametric((expr_x, expr_y), range)``
- Plotting multiple parametric curves with the same range
``plot_parametric((expr_x, expr_y), ..., range)``
- Plotting multiple parametric curves with different ranges
``plot_parametric((expr_x, expr_y, range), ...)``
``expr_x`` is the expression representing $x$ component of the
parametric function.
``expr_y`` is the expression representing $y$ component of the
parametric function.
``range`` is a 3-tuple denoting the parameter symbol, start and
stop. For example, ``(u, 0, 5)``.
If the range is not specified, then a default range of (-10, 10)
is used.
However, if the arguments are specified as
``(expr_x, expr_y, range), ...``, you must specify the ranges
for each expressions manually.
Default range may change in the future if a more advanced
algorithm is implemented.
adaptive : bool, optional
Specifies whether to use the adaptive sampling or not.
The default value is set to ``True``. Set adaptive to ``False``
and specify ``nb_of_points`` if uniform sampling is required.
depth : int, optional
The recursion depth of the adaptive algorithm. A depth of
value $n$ samples a maximum of $2^n$ points.
nb_of_points : int, optional
Used when the ``adaptive`` flag is set to ``False``.
Specifies the number of the points used for the uniform
sampling.
line_color : function
A function which returns a float.
Specifies the color of the plot.
See :class:`Plot` for more details.
label : str, optional
The label of the expression in the plot. It will be used when
called with ``legend``. Default is the name of the expression.
e.g. ``sin(x)``
xlabel : str, optional
Label for the x-axis.
ylabel : str, optional
Label for the y-axis.
xscale : 'linear' or 'log', optional
Sets the scaling of the x-axis.
yscale : 'linear' or 'log', optional
Sets the scaling of the y-axis.
axis_center : (float, float), optional
Tuple of two floats denoting the coordinates of the center or
{'center', 'auto'}
xlim : (float, float), optional
Denotes the x-axis limits, ``(min, max)```.
ylim : (float, float), optional
Denotes the y-axis limits, ``(min, max)```.
Examples
========
.. plot::
:context: reset
:format: doctest
:include-source: True
>>> from sympy import symbols, cos, sin
>>> from sympy.plotting import plot_parametric
>>> u = symbols('u')
A parametric plot with a single expression:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot_parametric((cos(u), sin(u)), (u, -5, 5))
Plot object containing:
[0]: parametric cartesian line: (cos(u), sin(u)) for u over (-5.0, 5.0)
A parametric plot with multiple expressions with the same range:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot_parametric((cos(u), sin(u)), (u, cos(u)), (u, -10, 10))
Plot object containing:
[0]: parametric cartesian line: (cos(u), sin(u)) for u over (-10.0, 10.0)
[1]: parametric cartesian line: (u, cos(u)) for u over (-10.0, 10.0)
A parametric plot with multiple expressions with different ranges
for each curve:
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot_parametric((cos(u), sin(u), (u, -5, 5)),
... (cos(u), u, (u, -5, 5)))
Plot object containing:
[0]: parametric cartesian line: (cos(u), sin(u)) for u over (-5.0, 5.0)
[1]: parametric cartesian line: (cos(u), u) for u over (-5.0, 5.0)
Notes
=====
The plotting uses an adaptive algorithm which samples recursively to
accurately plot the curve. The adaptive algorithm uses a random point
near the midpoint of two points that has to be further sampled.
Hence, repeating the same plot command can give slightly different
results because of the random sampling.
If there are multiple plots, then the same optional arguments are
applied to all the plots drawn in the same canvas. If you want to
set these options separately, you can index the returned ``Plot``
object and set it.
For example, when you specify ``line_color`` once, it would be
applied simultaneously to both series.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> from sympy import pi
>>> expr1 = (u, cos(2*pi*u)/2 + 1/2)
>>> expr2 = (u, sin(2*pi*u)/2 + 1/2)
>>> p = plot_parametric(expr1, expr2, (u, 0, 1), line_color='blue')
If you want to specify the line color for the specific series, you
should index each item and apply the property manually.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> p[0].line_color = 'red'
>>> p.show()
See Also
========
Plot, Parametric2DLineSeries
"""
args = list(map(sympify, args))
show = kwargs.pop('show', True)
series = []
plot_expr = check_arguments(args, 2, 1)
series = [Parametric2DLineSeries(*arg, **kwargs) for arg in plot_expr]
plots = Plot(*series, **kwargs)
if show:
plots.show()
return plots
def plot3d_parametric_line(*args, **kwargs):
"""
Plots a 3D parametric line plot.
Usage
=====
Single plot:
``plot3d_parametric_line(expr_x, expr_y, expr_z, range, **kwargs)``
If the range is not specified, then a default range of (-10, 10) is used.
Multiple plots.
``plot3d_parametric_line((expr_x, expr_y, expr_z, range), ..., **kwargs)``
Ranges have to be specified for every expression.
Default range may change in the future if a more advanced default range
detection algorithm is implemented.
Arguments
=========
``expr_x`` : Expression representing the function along x.
``expr_y`` : Expression representing the function along y.
``expr_z`` : Expression representing the function along z.
``range``: ``(u, 0, 5)``, A 3-tuple denoting the range of the parameter
variable.
Keyword Arguments
=================
Arguments for ``Parametric3DLineSeries`` class.
``nb_of_points``: The range is uniformly sampled at ``nb_of_points``
number of points.
Aesthetics:
``line_color``: function which returns a float. Specifies the color for the
plot. See ``sympy.plotting.Plot`` for more details.
``label``: str
The label to the plot. It will be used when called with ``legend=True``
to denote the function with the given label in the plot.
If there are multiple plots, then the same series arguments are applied to
all the plots. If you want to set these options separately, you can index
the returned ``Plot`` object and set it.
Arguments for ``Plot`` class.
``title`` : str. Title of the plot.
Examples
========
.. plot::
:context: reset
:format: doctest
:include-source: True
>>> from sympy import symbols, cos, sin
>>> from sympy.plotting import plot3d_parametric_line
>>> u = symbols('u')
Single plot.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot3d_parametric_line(cos(u), sin(u), u, (u, -5, 5))
Plot object containing:
[0]: 3D parametric cartesian line: (cos(u), sin(u), u) for u over (-5.0, 5.0)
Multiple plots.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot3d_parametric_line((cos(u), sin(u), u, (u, -5, 5)),
... (sin(u), u**2, u, (u, -5, 5)))
Plot object containing:
[0]: 3D parametric cartesian line: (cos(u), sin(u), u) for u over (-5.0, 5.0)
[1]: 3D parametric cartesian line: (sin(u), u**2, u) for u over (-5.0, 5.0)
See Also
========
Plot, Parametric3DLineSeries
"""
args = list(map(sympify, args))
show = kwargs.pop('show', True)
series = []
plot_expr = check_arguments(args, 3, 1)
series = [Parametric3DLineSeries(*arg, **kwargs) for arg in plot_expr]
plots = Plot(*series, **kwargs)
if show:
plots.show()
return plots
def plot3d(*args, **kwargs):
"""
Plots a 3D surface plot.
Usage
=====
Single plot
``plot3d(expr, range_x, range_y, **kwargs)``
If the ranges are not specified, then a default range of (-10, 10) is used.
Multiple plot with the same range.
``plot3d(expr1, expr2, range_x, range_y, **kwargs)``
If the ranges are not specified, then a default range of (-10, 10) is used.
Multiple plots with different ranges.
``plot3d((expr1, range_x, range_y), (expr2, range_x, range_y), ..., **kwargs)``
Ranges have to be specified for every expression.
Default range may change in the future if a more advanced default range
detection algorithm is implemented.
Arguments
=========
``expr`` : Expression representing the function along x.
``range_x``: (x, 0, 5), A 3-tuple denoting the range of the x
variable.
``range_y``: (y, 0, 5), A 3-tuple denoting the range of the y
variable.
Keyword Arguments
=================
Arguments for ``SurfaceOver2DRangeSeries`` class:
``nb_of_points_x``: int. The x range is sampled uniformly at
``nb_of_points_x`` of points.
``nb_of_points_y``: int. The y range is sampled uniformly at
``nb_of_points_y`` of points.
Aesthetics:
``surface_color``: Function which returns a float. Specifies the color for
the surface of the plot. See ``sympy.plotting.Plot`` for more details.
If there are multiple plots, then the same series arguments are applied to
all the plots. If you want to set these options separately, you can index
the returned ``Plot`` object and set it.
Arguments for ``Plot`` class:
``title`` : str. Title of the plot.
Examples
========
.. plot::
:context: reset
:format: doctest
:include-source: True
>>> from sympy import symbols
>>> from sympy.plotting import plot3d
>>> x, y = symbols('x y')
Single plot
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot3d(x*y, (x, -5, 5), (y, -5, 5))
Plot object containing:
[0]: cartesian surface: x*y for x over (-5.0, 5.0) and y over (-5.0, 5.0)
Multiple plots with same range
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot3d(x*y, -x*y, (x, -5, 5), (y, -5, 5))
Plot object containing:
[0]: cartesian surface: x*y for x over (-5.0, 5.0) and y over (-5.0, 5.0)
[1]: cartesian surface: -x*y for x over (-5.0, 5.0) and y over (-5.0, 5.0)
Multiple plots with different ranges.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot3d((x**2 + y**2, (x, -5, 5), (y, -5, 5)),
... (x*y, (x, -3, 3), (y, -3, 3)))
Plot object containing:
[0]: cartesian surface: x**2 + y**2 for x over (-5.0, 5.0) and y over (-5.0, 5.0)
[1]: cartesian surface: x*y for x over (-3.0, 3.0) and y over (-3.0, 3.0)
See Also
========
Plot, SurfaceOver2DRangeSeries
"""
args = list(map(sympify, args))
show = kwargs.pop('show', True)
series = []
plot_expr = check_arguments(args, 1, 2)
series = [SurfaceOver2DRangeSeries(*arg, **kwargs) for arg in plot_expr]
plots = Plot(*series, **kwargs)
if show:
plots.show()
return plots
def plot3d_parametric_surface(*args, **kwargs):
"""
Plots a 3D parametric surface plot.
Usage
=====
Single plot.
``plot3d_parametric_surface(expr_x, expr_y, expr_z, range_u, range_v, **kwargs)``
If the ranges is not specified, then a default range of (-10, 10) is used.
Multiple plots.
``plot3d_parametric_surface((expr_x, expr_y, expr_z, range_u, range_v), ..., **kwargs)``
Ranges have to be specified for every expression.
Default range may change in the future if a more advanced default range
detection algorithm is implemented.
Arguments
=========
``expr_x``: Expression representing the function along ``x``.
``expr_y``: Expression representing the function along ``y``.
``expr_z``: Expression representing the function along ``z``.
``range_u``: ``(u, 0, 5)``, A 3-tuple denoting the range of the ``u``
variable.
``range_v``: ``(v, 0, 5)``, A 3-tuple denoting the range of the v
variable.
Keyword Arguments
=================
Arguments for ``ParametricSurfaceSeries`` class:
``nb_of_points_u``: int. The ``u`` range is sampled uniformly at
``nb_of_points_v`` of points
``nb_of_points_y``: int. The ``v`` range is sampled uniformly at
``nb_of_points_y`` of points
Aesthetics:
``surface_color``: Function which returns a float. Specifies the color for
the surface of the plot. See ``sympy.plotting.Plot`` for more details.
If there are multiple plots, then the same series arguments are applied for
all the plots. If you want to set these options separately, you can index
the returned ``Plot`` object and set it.
Arguments for ``Plot`` class:
``title`` : str. Title of the plot.
Examples
========
.. plot::
:context: reset
:format: doctest
:include-source: True
>>> from sympy import symbols, cos, sin
>>> from sympy.plotting import plot3d_parametric_surface
>>> u, v = symbols('u v')
Single plot.
.. plot::
:context: close-figs
:format: doctest
:include-source: True
>>> plot3d_parametric_surface(cos(u + v), sin(u - v), u - v,
... (u, -5, 5), (v, -5, 5))
Plot object containing:
[0]: parametric cartesian surface: (cos(u + v), sin(u - v), u - v) for u over (-5.0, 5.0) and v over (-5.0, 5.0)
See Also
========
Plot, ParametricSurfaceSeries
"""
args = list(map(sympify, args))
show = kwargs.pop('show', True)
series = []
plot_expr = check_arguments(args, 3, 2)
series = [ParametricSurfaceSeries(*arg, **kwargs) for arg in plot_expr]
plots = Plot(*series, **kwargs)
if show:
plots.show()
return plots
def plot_contour(*args, **kwargs):
"""
Draws contour plot of a function
Usage
=====
Single plot
``plot_contour(expr, range_x, range_y, **kwargs)``
If the ranges are not specified, then a default range of (-10, 10) is used.
Multiple plot with the same range.
``plot_contour(expr1, expr2, range_x, range_y, **kwargs)``
If the ranges are not specified, then a default range of (-10, 10) is used.
Multiple plots with different ranges.
``plot_contour((expr1, range_x, range_y), (expr2, range_x, range_y), ..., **kwargs)``
Ranges have to be specified for every expression.
Default range may change in the future if a more advanced default range
detection algorithm is implemented.
Arguments
=========
``expr`` : Expression representing the function along x.
``range_x``: (x, 0, 5), A 3-tuple denoting the range of the x
variable.
``range_y``: (y, 0, 5), A 3-tuple denoting the range of the y
variable.
Keyword Arguments
=================
Arguments for ``ContourSeries`` class:
``nb_of_points_x``: int. The x range is sampled uniformly at
``nb_of_points_x`` of points.
``nb_of_points_y``: int. The y range is sampled uniformly at
``nb_of_points_y`` of points.
Aesthetics:
``surface_color``: Function which returns a float. Specifies the color for
the surface of the plot. See ``sympy.plotting.Plot`` for more details.
If there are multiple plots, then the same series arguments are applied to
all the plots. If you want to set these options separately, you can index
the returned ``Plot`` object and set it.
Arguments for ``Plot`` class:
``title`` : str. Title of the plot.
See Also
========
Plot, ContourSeries
"""
args = list(map(sympify, args))
show = kwargs.pop('show', True)
plot_expr = check_arguments(args, 1, 2)
series = [ContourSeries(*arg) for arg in plot_expr]
plot_contours = Plot(*series, **kwargs)
if len(plot_expr[0].free_symbols) > 2:
raise ValueError('Contour Plot cannot Plot for more than two variables.')
if show:
plot_contours.show()
return plot_contours
def check_arguments(args, expr_len, nb_of_free_symbols):
"""
Checks the arguments and converts into tuples of the
form (exprs, ranges)
Examples
========
.. plot::
:context: reset
:format: doctest
:include-source: True
>>> from sympy import cos, sin, symbols
>>> from sympy.plotting.plot import check_arguments
>>> x = symbols('x')
>>> check_arguments([cos(x), sin(x)], 2, 1)
[(cos(x), sin(x), (x, -10, 10))]
>>> check_arguments([x, x**2], 1, 1)
[(x, (x, -10, 10)), (x**2, (x, -10, 10))]
"""
if not args:
return []
if expr_len > 1 and isinstance(args[0], Expr):
# Multiple expressions same range.
# The arguments are tuples when the expression length is
# greater than 1.
if len(args) < expr_len:
raise ValueError("len(args) should not be less than expr_len")
for i in range(len(args)):
if isinstance(args[i], Tuple):
break
else:
i = len(args) + 1
exprs = Tuple(*args[:i])
free_symbols = list(set().union(*[e.free_symbols for e in exprs]))
if len(args) == expr_len + nb_of_free_symbols:
#Ranges given
plots = [exprs + Tuple(*args[expr_len:])]
else:
default_range = Tuple(-10, 10)
ranges = []
for symbol in free_symbols:
ranges.append(Tuple(symbol) + default_range)
for i in range(len(free_symbols) - nb_of_free_symbols):
ranges.append(Tuple(Dummy()) + default_range)
plots = [exprs + Tuple(*ranges)]
return plots
if isinstance(args[0], Expr) or (isinstance(args[0], Tuple) and
len(args[0]) == expr_len and
expr_len != 3):
# Cannot handle expressions with number of expression = 3. It is
# not possible to differentiate between expressions and ranges.
#Series of plots with same range
for i in range(len(args)):
if isinstance(args[i], Tuple) and len(args[i]) != expr_len:
break
if not isinstance(args[i], Tuple):
args[i] = Tuple(args[i])
else:
i = len(args) + 1
exprs = args[:i]
assert all(isinstance(e, Expr) for expr in exprs for e in expr)
free_symbols = list(set().union(*[e.free_symbols for expr in exprs
for e in expr]))
if len(free_symbols) > nb_of_free_symbols:
raise ValueError("The number of free_symbols in the expression "
"is greater than %d" % nb_of_free_symbols)
if len(args) == i + nb_of_free_symbols and isinstance(args[i], Tuple):
ranges = Tuple(*[range_expr for range_expr in args[
i:i + nb_of_free_symbols]])
plots = [expr + ranges for expr in exprs]
return plots
else:
# Use default ranges.
default_range = Tuple(-10, 10)
ranges = []
for symbol in free_symbols:
ranges.append(Tuple(symbol) + default_range)
for i in range(nb_of_free_symbols - len(free_symbols)):
ranges.append(Tuple(Dummy()) + default_range)
ranges = Tuple(*ranges)
plots = [expr + ranges for expr in exprs]
return plots
elif isinstance(args[0], Tuple) and len(args[0]) == expr_len + nb_of_free_symbols:
# Multiple plots with different ranges.
for arg in args:
for i in range(expr_len):
if not isinstance(arg[i], Expr):
raise ValueError("Expected an expression, given %s" %
str(arg[i]))
for i in range(nb_of_free_symbols):
if not len(arg[i + expr_len]) == 3:
raise ValueError("The ranges should be a tuple of "
"length 3, got %s" % str(arg[i + expr_len]))
return args
|
63e166c33bcd5582bf9aa383a094a8592a359fc0a50384950e93c5f2c5980d0a | """ rewrite of lambdify - This stuff is not stable at all.
It is for internal use in the new plotting module.
It may (will! see the Q'n'A in the source) be rewritten.
It's completely self contained. Especially it does not use lambdarepr.
It does not aim to replace the current lambdify. Most importantly it will never
ever support anything else than sympy expressions (no Matrices, dictionaries
and so on).
"""
from __future__ import print_function, division
import re
from sympy import Symbol, NumberSymbol, I, zoo, oo
from sympy.core.compatibility import exec_
from sympy.utilities.iterables import numbered_symbols
# We parse the expression string into a tree that identifies functions. Then
# we translate the names of the functions and we translate also some strings
# that are not names of functions (all this according to translation
# dictionaries).
# If the translation goes to another module (like numpy) the
# module is imported and 'func' is translated to 'module.func'.
# If a function can not be translated, the inner nodes of that part of the
# tree are not translated. So if we have Integral(sqrt(x)), sqrt is not
# translated to np.sqrt and the Integral does not crash.
# A namespace for all this is generated by crawling the (func, args) tree of
# the expression. The creation of this namespace involves many ugly
# workarounds.
# The namespace consists of all the names needed for the sympy expression and
# all the name of modules used for translation. Those modules are imported only
# as a name (import numpy as np) in order to keep the namespace small and
# manageable.
# Please, if there is a bug, do not try to fix it here! Rewrite this by using
# the method proposed in the last Q'n'A below. That way the new function will
# work just as well, be just as simple, but it wont need any new workarounds.
# If you insist on fixing it here, look at the workarounds in the function
# sympy_expression_namespace and in lambdify.
# Q: Why are you not using python abstract syntax tree?
# A: Because it is more complicated and not much more powerful in this case.
# Q: What if I have Symbol('sin') or g=Function('f')?
# A: You will break the algorithm. We should use srepr to defend against this?
# The problem with Symbol('sin') is that it will be printed as 'sin'. The
# parser will distinguish it from the function 'sin' because functions are
# detected thanks to the opening parenthesis, but the lambda expression won't
# understand the difference if we have also the sin function.
# The solution (complicated) is to use srepr and maybe ast.
# The problem with the g=Function('f') is that it will be printed as 'f' but in
# the global namespace we have only 'g'. But as the same printer is used in the
# constructor of the namespace there will be no problem.
# Q: What if some of the printers are not printing as expected?
# A: The algorithm wont work. You must use srepr for those cases. But even
# srepr may not print well. All problems with printers should be considered
# bugs.
# Q: What about _imp_ functions?
# A: Those are taken care for by evalf. A special case treatment will work
# faster but it's not worth the code complexity.
# Q: Will ast fix all possible problems?
# A: No. You will always have to use some printer. Even srepr may not work in
# some cases. But if the printer does not work, that should be considered a
# bug.
# Q: Is there same way to fix all possible problems?
# A: Probably by constructing our strings ourself by traversing the (func,
# args) tree and creating the namespace at the same time. That actually sounds
# good.
from sympy.external import import_module
import warnings
#TODO debugging output
class vectorized_lambdify(object):
""" Return a sufficiently smart, vectorized and lambdified function.
Returns only reals.
This function uses experimental_lambdify to created a lambdified
expression ready to be used with numpy. Many of the functions in sympy
are not implemented in numpy so in some cases we resort to python cmath or
even to evalf.
The following translations are tried:
only numpy complex
- on errors raised by sympy trying to work with ndarray:
only python cmath and then vectorize complex128
When using python cmath there is no need for evalf or float/complex
because python cmath calls those.
This function never tries to mix numpy directly with evalf because numpy
does not understand sympy Float. If this is needed one can use the
float_wrap_evalf/complex_wrap_evalf options of experimental_lambdify or
better one can be explicit about the dtypes that numpy works with.
Check numpy bug http://projects.scipy.org/numpy/ticket/1013 to know what
types of errors to expect.
"""
def __init__(self, args, expr):
self.args = args
self.expr = expr
self.lambda_func = experimental_lambdify(args, expr, use_np=True)
self.vector_func = self.lambda_func
self.failure = False
def __call__(self, *args):
np = import_module('numpy')
np_old_err = np.seterr(invalid='raise')
try:
temp_args = (np.array(a, dtype=np.complex) for a in args)
results = self.vector_func(*temp_args)
results = np.ma.masked_where(
np.abs(results.imag) > 1e-7 * np.abs(results),
results.real, copy=False)
except Exception as e:
#DEBUG: print 'Error', type(e), e
if ((isinstance(e, TypeError)
and 'unhashable type: \'numpy.ndarray\'' in str(e))
or
(isinstance(e, ValueError)
and ('Invalid limits given:' in str(e)
or 'negative dimensions are not allowed' in str(e) # XXX
or 'sequence too large; must be smaller than 32' in str(e)))): # XXX
# Almost all functions were translated to numpy, but some were
# left as sympy functions. They received an ndarray as an
# argument and failed.
# sin(ndarray(...)) raises "unhashable type"
# Integral(x, (x, 0, ndarray(...))) raises "Invalid limits"
# other ugly exceptions that are not well understood (marked with XXX)
# TODO: Cleanup the ugly special cases marked with xxx above.
# Solution: use cmath and vectorize the final lambda.
self.lambda_func = experimental_lambdify(
self.args, self.expr, use_python_cmath=True)
self.vector_func = np.vectorize(
self.lambda_func, otypes=[np.complex])
results = self.vector_func(*args)
results = np.ma.masked_where(
np.abs(results.imag) > 1e-7 * np.abs(results),
results.real, copy=False)
else:
# Complete failure. One last try with no translations, only
# wrapping in complex((...).evalf()) and returning the real
# part.
if self.failure:
raise e
else:
self.failure = True
self.lambda_func = experimental_lambdify(
self.args, self.expr, use_evalf=True,
complex_wrap_evalf=True)
self.vector_func = np.vectorize(
self.lambda_func, otypes=[np.complex])
results = self.vector_func(*args)
results = np.ma.masked_where(
np.abs(results.imag) > 1e-7 * np.abs(results),
results.real, copy=False)
warnings.warn('The evaluation of the expression is'
' problematic. We are trying a failback method'
' that may still work. Please report this as a bug.')
finally:
np.seterr(**np_old_err)
return results
class lambdify(object):
"""Returns the lambdified function.
This function uses experimental_lambdify to create a lambdified
expression. It uses cmath to lambdify the expression. If the function
is not implemented in python cmath, python cmath calls evalf on those
functions.
"""
def __init__(self, args, expr):
self.args = args
self.expr = expr
self.lambda_func = experimental_lambdify(args, expr, use_evalf=True,
use_python_cmath=True)
self.failure = False
def __call__(self, args, kwargs = {}):
if not self.lambda_func.use_python_math:
args = complex(args)
try:
#The result can be sympy.Float. Hence wrap it with complex type.
result = complex(self.lambda_func(args))
if abs(result.imag) > 1e-7 * abs(result):
return None
else:
return result.real
except Exception as e:
# The exceptions raised by sympy, cmath are not consistent and
# hence it is not possible to specify all the exceptions that
# are to be caught. Presently there are no cases for which the code
# reaches this block other than ZeroDivisionError and complex
# comparison. Also the exception is caught only once. If the
# exception repeats itself,
# then it is not caught and the corresponding error is raised.
# XXX: Remove catching all exceptions once the plotting module
# is heavily tested.
if isinstance(e, ZeroDivisionError):
return None
elif isinstance(e, TypeError) and ('no ordering relation is'
' defined for complex numbers'
in str(e) or 'unorderable '
'types' in str(e) or "not "
"supported between instances of"
in str(e)):
self.lambda_func = experimental_lambdify(self.args, self.expr,
use_evalf=True,
use_python_math=True)
result = self.lambda_func(args.real)
return result
else:
if self.failure:
raise e
#Failure
#Try wrapping it with complex(..).evalf()
self.failure = True
self.lambda_func = experimental_lambdify(self.args, self.expr,
use_evalf=True,
complex_wrap_evalf=True)
result = self.lambda_func(args)
warnings.warn('The evaluation of the expression is'
' problematic. We are trying a failback method'
' that may still work. Please report this as a bug.')
if abs(result.imag) > 1e-7 * abs(result):
return None
else:
return result.real
def experimental_lambdify(*args, **kwargs):
l = Lambdifier(*args, **kwargs)
return l
class Lambdifier(object):
def __init__(self, args, expr, print_lambda=False, use_evalf=False,
float_wrap_evalf=False, complex_wrap_evalf=False,
use_np=False, use_python_math=False, use_python_cmath=False,
use_interval=False):
self.print_lambda = print_lambda
self.use_evalf = use_evalf
self.float_wrap_evalf = float_wrap_evalf
self.complex_wrap_evalf = complex_wrap_evalf
self.use_np = use_np
self.use_python_math = use_python_math
self.use_python_cmath = use_python_cmath
self.use_interval = use_interval
# Constructing the argument string
# - check
if not all([isinstance(a, Symbol) for a in args]):
raise ValueError('The arguments must be Symbols.')
# - use numbered symbols
syms = numbered_symbols(exclude=expr.free_symbols)
newargs = [next(syms) for _ in args]
expr = expr.xreplace(dict(zip(args, newargs)))
argstr = ', '.join([str(a) for a in newargs])
del syms, newargs, args
# Constructing the translation dictionaries and making the translation
self.dict_str = self.get_dict_str()
self.dict_fun = self.get_dict_fun()
exprstr = str(expr)
newexpr = self.tree2str_translate(self.str2tree(exprstr))
# Constructing the namespaces
namespace = {}
namespace.update(self.sympy_atoms_namespace(expr))
namespace.update(self.sympy_expression_namespace(expr))
# XXX Workaround
# Ugly workaround because Pow(a,Half) prints as sqrt(a)
# and sympy_expression_namespace can not catch it.
from sympy import sqrt
namespace.update({'sqrt': sqrt})
namespace.update({'Eq': lambda x, y: x == y})
namespace.update({'Ne': lambda x, y: x != y})
# End workaround.
if use_python_math:
namespace.update({'math': __import__('math')})
if use_python_cmath:
namespace.update({'cmath': __import__('cmath')})
if use_np:
try:
namespace.update({'np': __import__('numpy')})
except ImportError:
raise ImportError(
'experimental_lambdify failed to import numpy.')
if use_interval:
namespace.update({'imath': __import__(
'sympy.plotting.intervalmath', fromlist=['intervalmath'])})
namespace.update({'math': __import__('math')})
# Construct the lambda
if self.print_lambda:
print(newexpr)
eval_str = 'lambda %s : ( %s )' % (argstr, newexpr)
self.eval_str = eval_str
exec_("from __future__ import division; MYNEWLAMBDA = %s" % eval_str, namespace)
self.lambda_func = namespace['MYNEWLAMBDA']
def __call__(self, *args, **kwargs):
return self.lambda_func(*args, **kwargs)
##############################################################################
# Dicts for translating from sympy to other modules
##############################################################################
###
# builtins
###
# Functions with different names in builtins
builtin_functions_different = {
'Min': 'min',
'Max': 'max',
'Abs': 'abs',
}
# Strings that should be translated
builtin_not_functions = {
'I': '1j',
# 'oo': '1e400',
}
###
# numpy
###
# Functions that are the same in numpy
numpy_functions_same = [
'sin', 'cos', 'tan', 'sinh', 'cosh', 'tanh', 'exp', 'log',
'sqrt', 'floor', 'conjugate',
]
# Functions with different names in numpy
numpy_functions_different = {
"acos": "arccos",
"acosh": "arccosh",
"arg": "angle",
"asin": "arcsin",
"asinh": "arcsinh",
"atan": "arctan",
"atan2": "arctan2",
"atanh": "arctanh",
"ceiling": "ceil",
"im": "imag",
"ln": "log",
"Max": "amax",
"Min": "amin",
"re": "real",
"Abs": "abs",
}
# Strings that should be translated
numpy_not_functions = {
'pi': 'np.pi',
'oo': 'np.inf',
'E': 'np.e',
}
###
# python math
###
# Functions that are the same in math
math_functions_same = [
'sin', 'cos', 'tan', 'asin', 'acos', 'atan', 'atan2',
'sinh', 'cosh', 'tanh', 'asinh', 'acosh', 'atanh',
'exp', 'log', 'erf', 'sqrt', 'floor', 'factorial', 'gamma',
]
# Functions with different names in math
math_functions_different = {
'ceiling': 'ceil',
'ln': 'log',
'loggamma': 'lgamma'
}
# Strings that should be translated
math_not_functions = {
'pi': 'math.pi',
'E': 'math.e',
}
###
# python cmath
###
# Functions that are the same in cmath
cmath_functions_same = [
'sin', 'cos', 'tan', 'asin', 'acos', 'atan',
'sinh', 'cosh', 'tanh', 'asinh', 'acosh', 'atanh',
'exp', 'log', 'sqrt',
]
# Functions with different names in cmath
cmath_functions_different = {
'ln': 'log',
'arg': 'phase',
}
# Strings that should be translated
cmath_not_functions = {
'pi': 'cmath.pi',
'E': 'cmath.e',
}
###
# intervalmath
###
interval_not_functions = {
'pi': 'math.pi',
'E': 'math.e'
}
interval_functions_same = [
'sin', 'cos', 'exp', 'tan', 'atan', 'log',
'sqrt', 'cosh', 'sinh', 'tanh', 'floor',
'acos', 'asin', 'acosh', 'asinh', 'atanh',
'Abs', 'And', 'Or'
]
interval_functions_different = {
'Min': 'imin',
'Max': 'imax',
'ceiling': 'ceil',
}
###
# mpmath, etc
###
#TODO
###
# Create the final ordered tuples of dictionaries
###
# For strings
def get_dict_str(self):
dict_str = dict(self.builtin_not_functions)
if self.use_np:
dict_str.update(self.numpy_not_functions)
if self.use_python_math:
dict_str.update(self.math_not_functions)
if self.use_python_cmath:
dict_str.update(self.cmath_not_functions)
if self.use_interval:
dict_str.update(self.interval_not_functions)
return dict_str
# For functions
def get_dict_fun(self):
dict_fun = dict(self.builtin_functions_different)
if self.use_np:
for s in self.numpy_functions_same:
dict_fun[s] = 'np.' + s
for k, v in self.numpy_functions_different.items():
dict_fun[k] = 'np.' + v
if self.use_python_math:
for s in self.math_functions_same:
dict_fun[s] = 'math.' + s
for k, v in self.math_functions_different.items():
dict_fun[k] = 'math.' + v
if self.use_python_cmath:
for s in self.cmath_functions_same:
dict_fun[s] = 'cmath.' + s
for k, v in self.cmath_functions_different.items():
dict_fun[k] = 'cmath.' + v
if self.use_interval:
for s in self.interval_functions_same:
dict_fun[s] = 'imath.' + s
for k, v in self.interval_functions_different.items():
dict_fun[k] = 'imath.' + v
return dict_fun
##############################################################################
# The translator functions, tree parsers, etc.
##############################################################################
def str2tree(self, exprstr):
"""Converts an expression string to a tree.
Functions are represented by ('func_name(', tree_of_arguments).
Other expressions are (head_string, mid_tree, tail_str).
Expressions that do not contain functions are directly returned.
Examples
========
>>> from sympy.abc import x, y, z
>>> from sympy import Integral, sin
>>> from sympy.plotting.experimental_lambdify import Lambdifier
>>> str2tree = Lambdifier([x], x).str2tree
>>> str2tree(str(Integral(x, (x, 1, y))))
('', ('Integral(', 'x, (x, 1, y)'), ')')
>>> str2tree(str(x+y))
'x + y'
>>> str2tree(str(x+y*sin(z)+1))
('x + y*', ('sin(', 'z'), ') + 1')
>>> str2tree('sin(y*(y + 1.1) + (sin(y)))')
('', ('sin(', ('y*(y + 1.1) + (', ('sin(', 'y'), '))')), ')')
"""
#matches the first 'function_name('
first_par = re.search(r'(\w+\()', exprstr)
if first_par is None:
return exprstr
else:
start = first_par.start()
end = first_par.end()
head = exprstr[:start]
func = exprstr[start:end]
tail = exprstr[end:]
count = 0
for i, c in enumerate(tail):
if c == '(':
count += 1
elif c == ')':
count -= 1
if count == -1:
break
func_tail = self.str2tree(tail[:i])
tail = self.str2tree(tail[i:])
return (head, (func, func_tail), tail)
@classmethod
def tree2str(cls, tree):
"""Converts a tree to string without translations.
Examples
========
>>> from sympy.abc import x, y, z
>>> from sympy import sin
>>> from sympy.plotting.experimental_lambdify import Lambdifier
>>> str2tree = Lambdifier([x], x).str2tree
>>> tree2str = Lambdifier([x], x).tree2str
>>> tree2str(str2tree(str(x+y*sin(z)+1)))
'x + y*sin(z) + 1'
"""
if isinstance(tree, str):
return tree
else:
return ''.join(map(cls.tree2str, tree))
def tree2str_translate(self, tree):
"""Converts a tree to string with translations.
Function names are translated by translate_func.
Other strings are translated by translate_str.
"""
if isinstance(tree, str):
return self.translate_str(tree)
elif isinstance(tree, tuple) and len(tree) == 2:
return self.translate_func(tree[0][:-1], tree[1])
else:
return ''.join([self.tree2str_translate(t) for t in tree])
def translate_str(self, estr):
"""Translate substrings of estr using in order the dictionaries in
dict_tuple_str."""
for pattern, repl in self.dict_str.items():
estr = re.sub(pattern, repl, estr)
return estr
def translate_func(self, func_name, argtree):
"""Translate function names and the tree of arguments.
If the function name is not in the dictionaries of dict_tuple_fun then the
function is surrounded by a float((...).evalf()).
The use of float is necessary as np.<function>(sympy.Float(..)) raises an
error."""
if func_name in self.dict_fun:
new_name = self.dict_fun[func_name]
argstr = self.tree2str_translate(argtree)
return new_name + '(' + argstr
elif func_name in ['Eq', 'Ne']:
op = {'Eq': '==', 'Ne': '!='}
return "(lambda x, y: x {} y)({}".format(op[func_name], self.tree2str_translate(argtree))
else:
template = '(%s(%s)).evalf(' if self.use_evalf else '%s(%s'
if self.float_wrap_evalf:
template = 'float(%s)' % template
elif self.complex_wrap_evalf:
template = 'complex(%s)' % template
# Wrapping should only happen on the outermost expression, which
# is the only thing we know will be a number.
float_wrap_evalf = self.float_wrap_evalf
complex_wrap_evalf = self.complex_wrap_evalf
self.float_wrap_evalf = False
self.complex_wrap_evalf = False
ret = template % (func_name, self.tree2str_translate(argtree))
self.float_wrap_evalf = float_wrap_evalf
self.complex_wrap_evalf = complex_wrap_evalf
return ret
##############################################################################
# The namespace constructors
##############################################################################
@classmethod
def sympy_expression_namespace(cls, expr):
"""Traverses the (func, args) tree of an expression and creates a sympy
namespace. All other modules are imported only as a module name. That way
the namespace is not polluted and rests quite small. It probably causes much
more variable lookups and so it takes more time, but there are no tests on
that for the moment."""
if expr is None:
return {}
else:
funcname = str(expr.func)
# XXX Workaround
# Here we add an ugly workaround because str(func(x))
# is not always the same as str(func). Eg
# >>> str(Integral(x))
# "Integral(x)"
# >>> str(Integral)
# "<class 'sympy.integrals.integrals.Integral'>"
# >>> str(sqrt(x))
# "sqrt(x)"
# >>> str(sqrt)
# "<function sqrt at 0x3d92de8>"
# >>> str(sin(x))
# "sin(x)"
# >>> str(sin)
# "sin"
# Either one of those can be used but not all at the same time.
# The code considers the sin example as the right one.
regexlist = [
r'<class \'sympy[\w.]*?.([\w]*)\'>$',
# the example Integral
r'<function ([\w]*) at 0x[\w]*>$', # the example sqrt
]
for r in regexlist:
m = re.match(r, funcname)
if m is not None:
funcname = m.groups()[0]
# End of the workaround
# XXX debug: print funcname
args_dict = {}
for a in expr.args:
if (isinstance(a, Symbol) or
isinstance(a, NumberSymbol) or
a in [I, zoo, oo]):
continue
else:
args_dict.update(cls.sympy_expression_namespace(a))
args_dict.update({funcname: expr.func})
return args_dict
@staticmethod
def sympy_atoms_namespace(expr):
"""For no real reason this function is separated from
sympy_expression_namespace. It can be moved to it."""
atoms = expr.atoms(Symbol, NumberSymbol, I, zoo, oo)
d = {}
for a in atoms:
# XXX debug: print 'atom:' + str(a)
d[str(a)] = a
return d
|
a76157c28a1cb5aa0bccadf81dabef72050fe3b1d3222655a2fc706aad450cb8 | from __future__ import unicode_literals
from sympy import (S, Symbol, Interval, exp, Or,
symbols, Eq, cos, And, Tuple, integrate, oo, sin, Sum, Basic, Indexed,
DiracDelta, Lambda, log, pi, FallingFactorial, Rational, Matrix)
from sympy.stats import (Die, Normal, Exponential, FiniteRV, P, E, H, variance,
density, given, independent, dependent, where, pspace, GaussianUnitaryEnsemble,
random_symbols, sample, Geometric, factorial_moment, Binomial, Hypergeometric,
DiscreteUniform, Poisson, characteristic_function, moment_generating_function,
BernoulliProcess, Variance, Expectation, Probability, Covariance, covariance)
from sympy.stats.rv import (IndependentProductPSpace, rs_swap, Density, NamedArgsMixin,
RandomSymbol, sample_iter, PSpace, is_random, RandomIndexedSymbol, RandomMatrixSymbol)
from sympy.testing.pytest import raises, skip, XFAIL, ignore_warnings
from sympy.external import import_module
from sympy.core.numbers import comp
from sympy.stats.frv_types import BernoulliDistribution
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_characteristic_function():
# Imports I from sympy
from sympy import I
X = Normal('X',0,1)
Y = DiscreteUniform('Y', [1,2,7])
Z = Poisson('Z', 2)
t = symbols('_t')
P = Lambda(t, exp(-t**2/2))
Q = Lambda(t, exp(7*t*I)/3 + exp(2*t*I)/3 + exp(t*I)/3)
R = Lambda(t, exp(2 * exp(t*I) - 2))
assert characteristic_function(X).dummy_eq(P)
assert characteristic_function(Y).dummy_eq(Q)
assert characteristic_function(Z).dummy_eq(R)
def test_moment_generating_function():
X = Normal('X',0,1)
Y = DiscreteUniform('Y', [1,2,7])
Z = Poisson('Z', 2)
t = symbols('_t')
P = Lambda(t, exp(t**2/2))
Q = Lambda(t, (exp(7*t)/3 + exp(2*t)/3 + exp(t)/3))
R = Lambda(t, exp(2 * exp(t) - 2))
assert moment_generating_function(X).dummy_eq(P)
assert moment_generating_function(Y).dummy_eq(Q)
assert moment_generating_function(Z).dummy_eq(R)
def test_sample_iter():
X = Normal('X',0,1)
Y = DiscreteUniform('Y', [1, 2, 7])
Z = Poisson('Z', 2)
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
expr = X**2 + 3
iterator = sample_iter(expr)
expr2 = Y**2 + 5*Y + 4
iterator2 = sample_iter(expr2)
expr3 = Z**3 + 4
iterator3 = sample_iter(expr3)
def is_iterator(obj):
if (
hasattr(obj, '__iter__') and
(hasattr(obj, 'next') or
hasattr(obj, '__next__')) and
callable(obj.__iter__) and
obj.__iter__() is obj
):
return True
else:
return False
assert is_iterator(iterator)
assert is_iterator(iterator2)
assert is_iterator(iterator3)
def test_pspace():
X, Y = Normal('X', 0, 1), Normal('Y', 0, 1)
x = Symbol('x')
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.Half + log(pi)/2
assert H(D, D > 2) == log(2)
assert comp(H(G).evalf().round(2), 1.39)
def test_Sample():
X = Die('X', 6)
Y = Normal('Y', 0, 1)
z = Symbol('z', integer=True)
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
with ignore_warnings(UserWarning):
assert next(sample(X)) in [1, 2, 3, 4, 5, 6]
assert isinstance(next(sample(X + Y)), float)
assert P(X + Y > 0, Y < 0, numsamples=10).is_number
assert E(X + Y, numsamples=10).is_number
assert E(X**2 + Y, numsamples=10).is_number
assert E((X + Y)**2, numsamples=10).is_number
assert variance(X + Y, numsamples=10).is_number
raises(TypeError, 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
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))
@XFAIL
def test_samplingE():
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
Y = Normal('Y', 0, 1)
z = Symbol('z', integer=True)
assert E(Sum(1/z**Y, (z, 1, oo)), Y > 2, numsamples=3).is_number
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_factorial_moment():
X = Poisson('X', 2)
Y = Binomial('Y', 2, S.Half)
Z = Hypergeometric('Z', 4, 2, 2)
assert factorial_moment(X, 2) == 4
assert factorial_moment(Y, 2) == S.Half
assert factorial_moment(Z, 2) == Rational(1, 3)
x, y, z, l = symbols('x y z l')
Y = Binomial('Y', 2, y)
Z = Hypergeometric('Z', 10, 2, 3)
assert factorial_moment(Y, l) == y**2*FallingFactorial(
2, l) + 2*y*(1 - y)*FallingFactorial(1, l) + (1 - y)**2*\
FallingFactorial(0, l)
assert factorial_moment(Z, l) == 7*FallingFactorial(0, l)/\
15 + 7*FallingFactorial(1, l)/15 + FallingFactorial(2, l)/15
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)
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 = Symbol('x', real=True, finite=True)
z = Symbol('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
def test_issue_12237():
X = Normal('X', 0, 1)
Y = Normal('Y', 0, 1)
U = P(X > 0, X)
V = P(Y < 0, X)
W = P(X + Y > 0, X)
assert W == P(X + Y > 0, X)
assert U == BernoulliDistribution(S.Half, S.Zero, S.One)
assert V == S.Half
def test_is_random():
X = Normal('X', 0, 1)
Y = Normal('Y', 0, 1)
a, b = symbols('a, b')
G = GaussianUnitaryEnsemble('U', 2)
B = BernoulliProcess('B', 0.9)
assert not is_random(a)
assert not is_random(a + b)
assert not is_random(a * b)
assert not is_random(Matrix([a**2, b**2]))
assert is_random(X)
assert is_random(X**2 + Y)
assert is_random(Y + b**2)
assert is_random(Y > 5)
assert is_random(B[3] < 1)
assert is_random(G)
assert is_random(X * Y * B[1])
assert is_random(Matrix([[X, B[2]], [G, Y]]))
assert is_random(Eq(X, 4))
def test_issue_12283():
x = symbols('x')
X = RandomSymbol(x)
Y = RandomSymbol('Y')
Z = RandomMatrixSymbol('Z', 2, 3)
RI = RandomIndexedSymbol(Indexed('RI', 3))
assert pspace(Z) == PSpace()
assert pspace(RI) == PSpace()
assert pspace(X) == PSpace()
assert E(X) == Expectation(X)
assert P(Y > 3) == Probability(Y > 3)
assert variance(X) == Variance(X)
assert variance(RI) == Variance(RI)
assert covariance(X, Y) == Covariance(X, Y)
assert covariance(X, Z) == Covariance(X, Z)
def test_issue_6810():
X = Die('X', 6)
Y = Normal('Y', 0, 1)
assert P(Eq(X, 2)) == S(1)/6
assert P(Eq(Y, 0)) == 0
assert P(Or(X > 2, X < 3)) == 1
assert P(And(X > 3, X > 2)) == S(1)/2
|
9d7aed36ec0b609a8f080239224a9eb28a8dc8a7b563e4ef296eac4f8e9d1875 | from sympy import (FiniteSet, S, Symbol, sqrt, nan, beta, Rational, symbols,
simplify, Eq, cos, And, Tuple, Or, Dict, sympify, binomial,
cancel, exp, I, Piecewise, Sum, Dummy)
from sympy.external import import_module
from sympy.matrices import Matrix
from sympy.stats import (DiscreteUniform, Die, Bernoulli, Coin, Binomial, BetaBinomial,
Hypergeometric, Rademacher, P, E, variance, covariance, skewness,
sample, density, where, FiniteRV, pspace, cdf, correlation, moment,
cmoment, smoment, characteristic_function, moment_generating_function,
quantile, kurtosis, median, coskewness)
from sympy.stats.frv_types import DieDistribution, BinomialDistribution, \
HypergeometricDistribution
from sympy.stats.rv import Density
from sympy.testing.pytest import raises, skip, ignore_warnings
def BayesTest(A, B):
assert P(A, B) == P(And(A, B)) / P(B)
assert P(A, B) == P(B, A) * P(A) / P(B)
def test_discreteuniform():
# Symbolic
a, b, c, t = symbols('a b c t')
X = DiscreteUniform('X', [a, b, c])
assert E(X) == (a + b + c)/3
assert simplify(variance(X)
- ((a**2 + b**2 + c**2)/3 - (a/3 + b/3 + c/3)**2)) == 0
assert P(Eq(X, a)) == P(Eq(X, b)) == P(Eq(X, c)) == S('1/3')
Y = DiscreteUniform('Y', range(-5, 5))
# Numeric
assert E(Y) == S('-1/2')
assert variance(Y) == S('33/4')
assert median(Y) == FiniteSet(-1, 0)
for x in range(-5, 5):
assert P(Eq(Y, x)) == S('1/10')
assert P(Y <= x) == S(x + 6)/10
assert P(Y >= x) == S(5 - x)/10
assert dict(density(Die('D', 6)).items()) == \
dict(density(DiscreteUniform('U', range(1, 7))).items())
assert characteristic_function(X)(t) == exp(I*a*t)/3 + exp(I*b*t)/3 + exp(I*c*t)/3
assert moment_generating_function(X)(t) == exp(a*t)/3 + exp(b*t)/3 + exp(c*t)/3
# issue 18611
raises(ValueError, lambda: DiscreteUniform('Z', [a, a, a, b, b, c]))
def test_dice():
# TODO: Make iid method!
X, Y, Z = Die('X', 6), Die('Y', 6), Die('Z', 6)
a, b, t, p = symbols('a b t p')
assert E(X) == 3 + S.Half
assert variance(X) == Rational(35, 12)
assert E(X + Y) == 7
assert E(X + X) == 7
assert E(a*X + b) == a*E(X) + b
assert variance(X + Y) == variance(X) + variance(Y) == cmoment(X + Y, 2)
assert variance(X + X) == 4 * variance(X) == cmoment(X + X, 2)
assert cmoment(X, 0) == 1
assert cmoment(4*X, 3) == 64*cmoment(X, 3)
assert covariance(X, Y) is S.Zero
assert covariance(X, X + Y) == variance(X)
assert density(Eq(cos(X*S.Pi), 1))[True] == S.Half
assert correlation(X, Y) == 0
assert correlation(X, Y) == correlation(Y, X)
assert smoment(X + Y, 3) == skewness(X + Y)
assert smoment(X + Y, 4) == kurtosis(X + Y)
assert smoment(X, 0) == 1
assert P(X > 3) == S.Half
assert P(2*X > 6) == S.Half
assert P(X > Y) == Rational(5, 12)
assert P(Eq(X, Y)) == P(Eq(X, 1))
assert E(X, X > 3) == 5 == moment(X, 1, 0, X > 3)
assert E(X, Y > 3) == E(X) == moment(X, 1, 0, Y > 3)
assert E(X + Y, Eq(X, Y)) == E(2*X)
assert moment(X, 0) == 1
assert moment(5*X, 2) == 25*moment(X, 2)
assert quantile(X)(p) == Piecewise((nan, (p > 1) | (p < 0)),\
(S.One, p <= Rational(1, 6)), (S(2), p <= Rational(1, 3)), (S(3), p <= S.Half),\
(S(4), p <= Rational(2, 3)), (S(5), p <= Rational(5, 6)), (S(6), p <= 1))
assert P(X > 3, X > 3) is S.One
assert P(X > Y, Eq(Y, 6)) is S.Zero
assert P(Eq(X + Y, 12)) == Rational(1, 36)
assert P(Eq(X + Y, 12), Eq(X, 6)) == Rational(1, 6)
assert density(X + Y) == density(Y + Z) != density(X + X)
d = density(2*X + Y**Z)
assert d[S(22)] == Rational(1, 108) and d[S(4100)] == Rational(1, 216) and S(3130) not in d
assert pspace(X).domain.as_boolean() == Or(
*[Eq(X.symbol, i) for i in [1, 2, 3, 4, 5, 6]])
assert where(X > 3).set == FiniteSet(4, 5, 6)
assert characteristic_function(X)(t) == exp(6*I*t)/6 + exp(5*I*t)/6 + exp(4*I*t)/6 + exp(3*I*t)/6 + exp(2*I*t)/6 + exp(I*t)/6
assert moment_generating_function(X)(t) == exp(6*t)/6 + exp(5*t)/6 + exp(4*t)/6 + exp(3*t)/6 + exp(2*t)/6 + exp(t)/6
assert median(X) == FiniteSet(3, 4)
D = Die('D', 7)
assert median(D) == FiniteSet(4)
# Bayes test for die
BayesTest(X > 3, X + Y < 5)
BayesTest(Eq(X - Y, Z), Z > Y)
BayesTest(X > 3, X > 2)
# arg test for die
raises(ValueError, lambda: Die('X', -1)) # issue 8105: negative sides.
raises(ValueError, lambda: Die('X', 0))
raises(ValueError, lambda: Die('X', 1.5)) # issue 8103: non integer sides.
# symbolic test for die
n, k = symbols('n, k', positive=True)
D = Die('D', n)
dens = density(D).dict
assert dens == Density(DieDistribution(n))
assert set(dens.subs(n, 4).doit().keys()) == set([1, 2, 3, 4])
assert set(dens.subs(n, 4).doit().values()) == set([Rational(1, 4)])
k = Dummy('k', integer=True)
assert E(D).dummy_eq(
Sum(Piecewise((k/n, k <= n), (0, True)), (k, 1, n)))
assert variance(D).subs(n, 6).doit() == Rational(35, 12)
ki = Dummy('ki')
cumuf = cdf(D)(k)
assert cumuf.dummy_eq(
Sum(Piecewise((1/n, (ki >= 1) & (ki <= n)), (0, True)), (ki, 1, k)))
assert cumuf.subs({n: 6, k: 2}).doit() == Rational(1, 3)
t = Dummy('t')
cf = characteristic_function(D)(t)
assert cf.dummy_eq(
Sum(Piecewise((exp(ki*I*t)/n, (ki >= 1) & (ki <= n)), (0, True)), (ki, 1, n)))
assert cf.subs(n, 3).doit() == exp(3*I*t)/3 + exp(2*I*t)/3 + exp(I*t)/3
mgf = moment_generating_function(D)(t)
assert mgf.dummy_eq(
Sum(Piecewise((exp(ki*t)/n, (ki >= 1) & (ki <= n)), (0, True)), (ki, 1, n)))
assert mgf.subs(n, 3).doit() == exp(3*t)/3 + exp(2*t)/3 + exp(t)/3
def test_given():
X = Die('X', 6)
assert density(X, X > 5) == {S(6): S.One}
assert where(X > 2, X > 5).as_boolean() == Eq(X.symbol, 6)
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
with ignore_warnings(UserWarning):
assert next(sample(X, X > 5)) == 6
def test_domains():
X, Y = Die('x', 6), Die('y', 6)
x, y = X.symbol, Y.symbol
# Domains
d = where(X > Y)
assert d.condition == (x > y)
d = where(And(X > Y, Y > 3))
assert d.as_boolean() == Or(And(Eq(x, 5), Eq(y, 4)), And(Eq(x, 6),
Eq(y, 5)), And(Eq(x, 6), Eq(y, 4)))
assert len(d.elements) == 3
assert len(pspace(X + Y).domain.elements) == 36
Z = Die('x', 4)
raises(ValueError, lambda: P(X > Z)) # Two domains with same internal symbol
assert pspace(X + Y).domain.set == FiniteSet(1, 2, 3, 4, 5, 6)**2
assert where(X > 3).set == FiniteSet(4, 5, 6)
assert X.pspace.domain.dict == FiniteSet(
*[Dict({X.symbol: i}) for i in range(1, 7)])
assert where(X > Y).dict == FiniteSet(*[Dict({X.symbol: i, Y.symbol: j})
for i in range(1, 7) for j in range(1, 7) if i > j])
def test_bernoulli():
p, a, b, t = symbols('p a b t')
X = Bernoulli('B', p, a, b)
assert E(X) == a*p + b*(-p + 1)
assert density(X)[a] == p
assert density(X)[b] == 1 - p
assert characteristic_function(X)(t) == p * exp(I * a * t) + (-p + 1) * exp(I * b * t)
assert moment_generating_function(X)(t) == p * exp(a * t) + (-p + 1) * exp(b * t)
X = Bernoulli('B', p, 1, 0)
z = Symbol("z")
assert E(X) == p
assert simplify(variance(X)) == p*(1 - p)
assert E(a*X + b) == a*E(X) + b
assert simplify(variance(a*X + b)) == simplify(a**2 * variance(X))
assert quantile(X)(z) == Piecewise((nan, (z > 1) | (z < 0)), (0, z <= 1 - p), (1, z <= 1))
Y = Bernoulli('Y', Rational(1, 2))
assert median(Y) == FiniteSet(0, 1)
Z = Bernoulli('Z', Rational(2, 3))
assert median(Z) == FiniteSet(1)
raises(ValueError, lambda: Bernoulli('B', 1.5))
raises(ValueError, lambda: Bernoulli('B', -0.5))
#issue 8248
assert X.pspace.compute_expectation(1) == 1
p = Rational(1, 5)
X = Binomial('X', 5, p)
Y = Binomial('Y', 7, 2*p)
Z = Binomial('Z', 9, 3*p)
assert coskewness(Y + Z, X + Y, X + Z).simplify() == 0
assert coskewness(Y + 2*X + Z, X + 2*Y + Z, X + 2*Z + Y).simplify() == \
sqrt(1529)*Rational(12, 16819)
assert coskewness(Y + 2*X + Z, X + 2*Y + Z, X + 2*Z + Y, X < 2).simplify() \
== -sqrt(357451121)*Rational(2812, 4646864573)
def test_cdf():
D = Die('D', 6)
o = S.One
assert cdf(
D) == sympify({1: o/6, 2: o/3, 3: o/2, 4: 2*o/3, 5: 5*o/6, 6: o})
def test_coins():
C, D = Coin('C'), Coin('D')
H, T = symbols('H, T')
assert P(Eq(C, D)) == S.Half
assert density(Tuple(C, D)) == {(H, H): Rational(1, 4), (H, T): Rational(1, 4),
(T, H): Rational(1, 4), (T, T): Rational(1, 4)}
assert dict(density(C).items()) == {H: S.Half, T: S.Half}
F = Coin('F', Rational(1, 10))
assert P(Eq(F, H)) == Rational(1, 10)
d = pspace(C).domain
assert d.as_boolean() == Or(Eq(C.symbol, H), Eq(C.symbol, T))
raises(ValueError, lambda: P(C > D)) # Can't intelligently compare H to T
def test_binomial_verify_parameters():
raises(ValueError, lambda: Binomial('b', .2, .5))
raises(ValueError, lambda: Binomial('b', 3, 1.5))
def test_binomial_numeric():
nvals = range(5)
pvals = [0, Rational(1, 4), S.Half, Rational(3, 4), 1]
for n in nvals:
for p in pvals:
X = Binomial('X', n, p)
assert E(X) == n*p
assert variance(X) == n*p*(1 - p)
if n > 0 and 0 < p < 1:
assert skewness(X) == (1 - 2*p)/sqrt(n*p*(1 - p))
assert kurtosis(X) == 3 + (1 - 6*p*(1 - p))/(n*p*(1 - p))
for k in range(n + 1):
assert P(Eq(X, k)) == binomial(n, k)*p**k*(1 - p)**(n - k)
def test_binomial_quantile():
X = Binomial('X', 50, S.Half)
assert quantile(X)(0.95) == S(31)
assert median(X) == FiniteSet(25)
X = Binomial('X', 5, S.Half)
p = Symbol("p", positive=True)
assert quantile(X)(p) == Piecewise((nan, p > S.One), (S.Zero, p <= Rational(1, 32)),\
(S.One, p <= Rational(3, 16)), (S(2), p <= S.Half), (S(3), p <= Rational(13, 16)),\
(S(4), p <= Rational(31, 32)), (S(5), p <= S.One))
assert median(X) == FiniteSet(2, 3)
def test_binomial_symbolic():
n = 2
p = symbols('p', positive=True)
X = Binomial('X', n, p)
t = Symbol('t')
assert simplify(E(X)) == n*p == simplify(moment(X, 1))
assert simplify(variance(X)) == n*p*(1 - p) == simplify(cmoment(X, 2))
assert cancel((skewness(X) - (1 - 2*p)/sqrt(n*p*(1 - p)))) == 0
assert cancel((kurtosis(X)) - (3 + (1 - 6*p*(1 - p))/(n*p*(1 - p)))) == 0
assert characteristic_function(X)(t) == p ** 2 * exp(2 * I * t) + 2 * p * (-p + 1) * exp(I * t) + (-p + 1) ** 2
assert moment_generating_function(X)(t) == p ** 2 * exp(2 * t) + 2 * p * (-p + 1) * exp(t) + (-p + 1) ** 2
# Test ability to change success/failure winnings
H, T = symbols('H T')
Y = Binomial('Y', n, p, succ=H, fail=T)
assert simplify(E(Y) - (n*(H*p + T*(1 - p)))) == 0
# test symbolic dimensions
n = symbols('n')
B = Binomial('B', n, p)
raises(NotImplementedError, lambda: P(B > 2))
assert density(B).dict == Density(BinomialDistribution(n, p, 1, 0))
assert set(density(B).dict.subs(n, 4).doit().keys()) == \
set([S.Zero, S.One, S(2), S(3), S(4)])
assert set(density(B).dict.subs(n, 4).doit().values()) == \
set([(1 - p)**4, 4*p*(1 - p)**3, 6*p**2*(1 - p)**2, 4*p**3*(1 - p), p**4])
k = Dummy('k', integer=True)
assert E(B > 2).dummy_eq(
Sum(Piecewise((k*p**k*(1 - p)**(-k + n)*binomial(n, k), (k >= 0)
& (k <= n) & (k > 2)), (0, True)), (k, 0, n)))
def test_beta_binomial():
# verify parameters
raises(ValueError, lambda: BetaBinomial('b', .2, 1, 2))
raises(ValueError, lambda: BetaBinomial('b', 2, -1, 2))
raises(ValueError, lambda: BetaBinomial('b', 2, 1, -2))
assert BetaBinomial('b', 2, 1, 1)
# test numeric values
nvals = range(1,5)
alphavals = [Rational(1, 4), S.Half, Rational(3, 4), 1, 10]
betavals = [Rational(1, 4), S.Half, Rational(3, 4), 1, 10]
for n in nvals:
for a in alphavals:
for b in betavals:
X = BetaBinomial('X', n, a, b)
assert E(X) == moment(X, 1)
assert variance(X) == cmoment(X, 2)
# test symbolic
n, a, b = symbols('a b n')
assert BetaBinomial('x', n, a, b)
n = 2 # Because we're using for loops, can't do symbolic n
a, b = symbols('a b', positive=True)
X = BetaBinomial('X', n, a, b)
t = Symbol('t')
assert E(X).expand() == moment(X, 1).expand()
assert variance(X).expand() == cmoment(X, 2).expand()
assert skewness(X) == smoment(X, 3)
assert characteristic_function(X)(t) == exp(2*I*t)*beta(a + 2, b)/beta(a, b) +\
2*exp(I*t)*beta(a + 1, b + 1)/beta(a, b) + beta(a, b + 2)/beta(a, b)
assert moment_generating_function(X)(t) == exp(2*t)*beta(a + 2, b)/beta(a, b) +\
2*exp(t)*beta(a + 1, b + 1)/beta(a, b) + beta(a, b + 2)/beta(a, b)
def test_hypergeometric_numeric():
for N in range(1, 5):
for m in range(0, N + 1):
for n in range(1, N + 1):
X = Hypergeometric('X', N, m, n)
N, m, n = map(sympify, (N, m, n))
assert sum(density(X).values()) == 1
assert E(X) == n * m / N
if N > 1:
assert variance(X) == n*(m/N)*(N - m)/N*(N - n)/(N - 1)
# Only test for skewness when defined
if N > 2 and 0 < m < N and n < N:
assert skewness(X) == simplify((N - 2*m)*sqrt(N - 1)*(N - 2*n)
/ (sqrt(n*m*(N - m)*(N - n))*(N - 2)))
def test_hypergeometric_symbolic():
N, m, n = symbols('N, m, n')
H = Hypergeometric('H', N, m, n)
dens = density(H).dict
expec = E(H > 2)
assert dens == Density(HypergeometricDistribution(N, m, n))
assert dens.subs(N, 5).doit() == Density(HypergeometricDistribution(5, m, n))
assert set(dens.subs({N: 3, m: 2, n: 1}).doit().keys()) == set([S.Zero, S.One])
assert set(dens.subs({N: 3, m: 2, n: 1}).doit().values()) == set([Rational(1, 3), Rational(2, 3)])
k = Dummy('k', integer=True)
assert expec.dummy_eq(
Sum(Piecewise((k*binomial(m, k)*binomial(N - m, -k + n)
/binomial(N, n), k > 2), (0, True)), (k, 0, n)))
def test_rademacher():
X = Rademacher('X')
t = Symbol('t')
assert E(X) == 0
assert variance(X) == 1
assert density(X)[-1] == S.Half
assert density(X)[1] == S.Half
assert characteristic_function(X)(t) == exp(I*t)/2 + exp(-I*t)/2
assert moment_generating_function(X)(t) == exp(t) / 2 + exp(-t) / 2
def test_FiniteRV():
F = FiniteRV('F', {1: S.Half, 2: Rational(1, 4), 3: Rational(1, 4)})
p = Symbol("p", positive=True)
assert dict(density(F).items()) == {S.One: S.Half, S(2): Rational(1, 4), S(3): Rational(1, 4)}
assert P(F >= 2) == S.Half
assert quantile(F)(p) == Piecewise((nan, p > S.One), (S.One, p <= S.Half),\
(S(2), p <= Rational(3, 4)),(S(3), True))
assert pspace(F).domain.as_boolean() == Or(
*[Eq(F.symbol, i) for i in [1, 2, 3]])
assert F.pspace.domain.set == FiniteSet(1, 2, 3)
raises(ValueError, lambda: FiniteRV('F', {1: S.Half, 2: S.Half, 3: S.Half}))
raises(ValueError, lambda: FiniteRV('F', {1: S.Half, 2: Rational(-1, 2), 3: S.One}))
raises(ValueError, lambda: FiniteRV('F', {1: S.One, 2: Rational(3, 2), 3: S.Zero,\
4: Rational(-1, 2), 5: Rational(-3, 4), 6: Rational(-1, 4)}))
def test_density_call():
from sympy.abc import p
x = Bernoulli('x', p)
d = density(x)
assert d(0) == 1 - p
assert d(S.Zero) == 1 - p
assert d(5) == 0
assert 0 in d
assert 5 not in d
assert d(S.Zero) == d[S.Zero]
def test_DieDistribution():
from sympy.abc import x
X = DieDistribution(6)
assert X.pmf(S.Half) is S.Zero
assert X.pmf(x).subs({x: 1}).doit() == Rational(1, 6)
assert X.pmf(x).subs({x: 7}).doit() == 0
assert X.pmf(x).subs({x: -1}).doit() == 0
assert X.pmf(x).subs({x: Rational(1, 3)}).doit() == 0
raises(ValueError, lambda: X.pmf(Matrix([0, 0])))
raises(ValueError, lambda: X.pmf(x**2 - 1))
def test_FinitePSpace():
X = Die('X', 6)
space = pspace(X)
assert space.density == DieDistribution(6)
def test_symbolic_conditions():
B = Bernoulli('B', Rational(1, 4))
D = Die('D', 4)
b, n = symbols('b, n')
Y = P(Eq(B, b))
Z = E(D > n)
assert Y == \
Piecewise((Rational(1, 4), Eq(b, 1)), (0, True)) + \
Piecewise((Rational(3, 4), Eq(b, 0)), (0, True))
assert Z == \
Piecewise((Rational(1, 4), n < 1), (0, True)) + Piecewise((S.Half, n < 2), (0, True)) + \
Piecewise((Rational(3, 4), n < 3), (0, True)) + Piecewise((S.One, n < 4), (0, True))
def test_sample_numpy():
distribs_numpy = [
Binomial("B", 5, 0.4),
]
size = 3
numpy = import_module('numpy')
if not numpy:
skip('Numpy is not installed. Abort tests for _sample_numpy.')
else:
with ignore_warnings(UserWarning):
for X in distribs_numpy:
samps = next(sample(X, size=size, library='numpy'))
for sam in samps:
assert sam in X.pspace.domain.set
raises(NotImplementedError,
lambda: next(sample(Die("D"), library='numpy')))
raises(NotImplementedError,
lambda: Die("D").pspace.sample(library='tensorflow'))
def test_sample_scipy():
distribs_scipy = [
FiniteRV('F', {1: S.Half, 2: Rational(1, 4), 3: Rational(1, 4)}),
DiscreteUniform("Y", list(range(5))),
Die("D"),
Bernoulli("Be", 0.3),
Binomial("Bi", 5, 0.4),
BetaBinomial("Bb", 2, 1, 1),
Hypergeometric("H", 1, 1, 1),
Rademacher("R")
]
size = 3
numsamples = 5
scipy = import_module('scipy')
if not scipy:
skip('Scipy not installed. Abort tests for _sample_scipy.')
else:
with ignore_warnings(UserWarning):
h_sample = list(sample(Hypergeometric("H", 1, 1, 1), size=size, numsamples=numsamples))
assert len(h_sample) == numsamples
for X in distribs_scipy:
samps = next(sample(X, size=size))
samps2 = next(sample(X, size=(2, 2)))
for sam in samps:
assert sam in X.pspace.domain.set
for i in range(2):
for j in range(2):
assert samps2[i][j] in X.pspace.domain.set
def test_sample_pymc3():
distribs_pymc3 = [
Bernoulli('B', 0.2),
Binomial('N', 5, 0.4)
]
size = 3
pymc3 = import_module('pymc3')
if not pymc3:
skip('PyMC3 is not installed. Abort tests for _sample_pymc3.')
else:
with ignore_warnings(UserWarning):
for X in distribs_pymc3:
samps = next(sample(X, size=size, library='pymc3'))
for sam in samps:
assert sam in X.pspace.domain.set
raises(NotImplementedError,
lambda: next(sample(Die("D"), library='pymc3')))
|
39d0ad4cf90ebc904f43c9837d946f23ad82d72d7089026945c3daad01af9e05 | from sympy import symbols, Mul, sin, Integral, oo, Eq, Sum
from sympy.core.expr import unchanged
from sympy.stats import (Normal, Poisson, variance, Covariance, Variance,
Probability, Expectation)
from sympy.stats.rv import probability, expectation
def test_literal_probability():
X = Normal('X', 2, 3)
Y = Normal('Y', 3, 4)
Z = Poisson('Z', 4)
W = Poisson('W', 3)
x = symbols('x', real=True)
y, w, z = symbols('y, w, z')
assert Probability(X > 0).evaluate_integral() == probability(X > 0)
assert Probability(X > x).evaluate_integral() == probability(X > x)
assert Probability(X > 0).rewrite(Integral).doit() == probability(X > 0)
assert Probability(X > x).rewrite(Integral).doit() == probability(X > x)
assert Expectation(X).evaluate_integral() == expectation(X)
assert Expectation(X).rewrite(Integral).doit() == expectation(X)
assert Expectation(X**2).evaluate_integral() == expectation(X**2)
assert Expectation(x*X).args == (x*X,)
assert Expectation(x*X).expand() == x*Expectation(X)
assert Expectation(2*X + 3*Y + z*X*Y).expand() == 2*Expectation(X) + 3*Expectation(Y) + z*Expectation(X*Y)
assert Expectation(2*X + 3*Y + z*X*Y).args == (2*X + 3*Y + z*X*Y,)
assert Expectation(sin(X)) == Expectation(sin(X)).expand()
assert Expectation(2*x*sin(X)*Y + y*X**2 + z*X*Y).expand() == 2*x*Expectation(sin(X)*Y) \
+ y*Expectation(X**2) + z*Expectation(X*Y)
assert Expectation(X + Y).expand() == Expectation(X) + Expectation(Y)
assert Expectation((X + Y)*(X - Y)).expand() == Expectation(X**2) - Expectation(Y**2)
assert Expectation((X + Y)*(X - Y)).expand().doit() == -12
assert Expectation(X + Y, evaluate=True).doit() == 5
assert Expectation(X + Expectation(Y)).doit() == 5
assert Expectation(X + Expectation(Y)).doit(deep=False) == 2 + Expectation(Expectation(Y))
assert Expectation(X + Expectation(Y + Expectation(2*X))).doit(deep=False) == 2 \
+ Expectation(Expectation(Y + Expectation(2*X)))
assert Expectation(X + Expectation(Y + Expectation(2*X))).doit() == 9
assert Expectation(Expectation(2*X)).doit() == 4
assert Expectation(Expectation(2*X)).doit(deep=False) == Expectation(2*X)
assert Expectation(4*Expectation(2*X)).doit(deep=False) == 4*Expectation(2*X)
assert Variance(w).args == (w,)
assert Variance(w).expand() == 0
assert Variance(X).evaluate_integral() == Variance(X).rewrite(Integral).doit() == variance(X)
assert Variance(X + z).args == (X + z,)
assert Variance(X + z).expand() == Variance(X)
assert Variance(X*Y).args == (Mul(X, Y),)
assert type(Variance(X*Y)) == Variance
assert Variance(z*X).expand() == z**2*Variance(X)
assert Variance(X + Y).expand() == Variance(X) + Variance(Y) + 2*Covariance(X, Y)
assert Variance(X + Y + Z + W).expand() == (Variance(X) + Variance(Y) + Variance(Z) + Variance(W) +
2 * Covariance(X, Y) + 2 * Covariance(X, Z) + 2 * Covariance(X, W) +
2 * Covariance(Y, Z) + 2 * Covariance(Y, W) + 2 * Covariance(W, Z))
assert Variance(X**2).evaluate_integral() == variance(X**2)
assert unchanged(Variance, X**2)
assert Variance(x*X**2).expand() == x**2*Variance(X**2)
assert Variance(sin(X)).args == (sin(X),)
assert Variance(sin(X)).expand() == Variance(sin(X))
assert Variance(x*sin(X)).expand() == x**2*Variance(sin(X))
assert Covariance(w, z).args == (w, z)
assert Covariance(w, z).expand() == 0
assert Covariance(X, w).expand() == 0
assert Covariance(w, X).expand() == 0
assert Covariance(X, Y).args == (X, Y)
assert type(Covariance(X, Y)) == Covariance
assert Covariance(z*X + 3, Y).expand() == z*Covariance(X, Y)
assert Covariance(X, X).args == (X, X)
assert Covariance(X, X).expand() == Variance(X)
assert Covariance(z*X + 3, w*Y + 4).expand() == w*z*Covariance(X,Y)
assert Covariance(X, Y) == Covariance(Y, X)
assert Covariance(X + Y, Z + W).expand() == Covariance(W, X) + Covariance(W, Y) + Covariance(X, Z) + Covariance(Y, Z)
assert Covariance(x*X + y*Y, z*Z + w*W).expand() == (x*w*Covariance(W, X) + w*y*Covariance(W, Y) +
x*z*Covariance(X, Z) + y*z*Covariance(Y, Z))
assert Covariance(x*X**2 + y*sin(Y), z*Y*Z**2 + w*W).expand() == (w*x*Covariance(W, X**2) + w*y*Covariance(sin(Y), W) +
x*z*Covariance(Y*Z**2, X**2) + y*z*Covariance(Y*Z**2, sin(Y)))
assert Covariance(X, X**2).expand() == Covariance(X, X**2)
assert Covariance(X, sin(X)).expand() == Covariance(sin(X), X)
assert Covariance(X**2, sin(X)*Y).expand() == Covariance(sin(X)*Y, X**2)
assert Covariance(w, X).evaluate_integral() == 0
def test_probability_rewrite():
X = Normal('X', 2, 3)
Y = Normal('Y', 3, 4)
Z = Poisson('Z', 4)
W = Poisson('W', 3)
x, y, w, z = symbols('x, y, w, z')
assert Variance(w).rewrite(Expectation) == 0
assert Variance(X).rewrite(Expectation) == Expectation(X ** 2) - Expectation(X) ** 2
assert Variance(X, condition=Y).rewrite(Expectation) == Expectation(X ** 2, Y) - Expectation(X, Y) ** 2
assert Variance(X, Y) != Expectation(X**2) - Expectation(X)**2
assert Variance(X + z).rewrite(Expectation) == Expectation((X + z) ** 2) - Expectation(X + z) ** 2
assert Variance(X * Y).rewrite(Expectation) == Expectation(X ** 2 * Y ** 2) - Expectation(X * Y) ** 2
assert Covariance(w, X).rewrite(Expectation) == -w*Expectation(X) + Expectation(w*X)
assert Covariance(X, Y).rewrite(Expectation) == Expectation(X*Y) - Expectation(X)*Expectation(Y)
assert Covariance(X, Y, condition=W).rewrite(Expectation) == Expectation(X * Y, W) - Expectation(X, W) * Expectation(Y, W)
w, x, z = symbols("W, x, z")
px = Probability(Eq(X, x))
pz = Probability(Eq(Z, z))
assert Expectation(X).rewrite(Probability) == Integral(x*px, (x, -oo, oo))
assert Expectation(Z).rewrite(Probability) == Sum(z*pz, (z, 0, oo))
assert Variance(X).rewrite(Probability) == Integral(x**2*px, (x, -oo, oo)) - Integral(x*px, (x, -oo, oo))**2
assert Variance(Z).rewrite(Probability) == Sum(z**2*pz, (z, 0, oo)) - Sum(z*pz, (z, 0, oo))**2
assert Covariance(w, X).rewrite(Probability) == \
-w*Integral(x*Probability(Eq(X, x)), (x, -oo, oo)) + Integral(w*x*Probability(Eq(X, x)), (x, -oo, oo))
# To test rewrite as sum function
assert Variance(X).rewrite(Sum) == Variance(X).rewrite(Integral)
assert Expectation(X).rewrite(Sum) == Expectation(X).rewrite(Integral)
assert Covariance(w, X).rewrite(Sum) == 0
assert Covariance(w, X).rewrite(Integral) == 0
assert Variance(X, condition=Y).rewrite(Probability) == Integral(x**2*Probability(Eq(X, x), Y), (x, -oo, oo)) - \
Integral(x*Probability(Eq(X, x), Y), (x, -oo, oo))**2
|
f5ebcad0ebacdeb3f578e36d9f7df0759ece9745a010e95bb53d0eb1fece08b5 | from sympy import (S, symbols, FiniteSet, Eq, Matrix, MatrixSymbol, Float, And,
ImmutableMatrix, Ne, Lt, Gt, exp, Not, Rational, Lambda, Sum,
Piecewise)
from sympy.stats import (DiscreteMarkovChain, P, TransitionMatrixOf, E,
StochasticStateSpaceOf, variance, ContinuousMarkovChain,
BernoulliProcess)
from sympy.stats.joint_rv import JointDistribution, JointDistributionHandmade
from sympy.stats.rv import RandomIndexedSymbol
from sympy.stats.symbolic_probability import Probability, Expectation
from sympy.testing.pytest import raises
from sympy.stats.frv_types import BernoulliDistribution
def test_DiscreteMarkovChain():
# pass only the name
X = DiscreteMarkovChain("X")
assert X.state_space == S.Reals
assert X.index_set == S.Naturals0
assert X.transition_probabilities == None
t = symbols('t', positive=True, integer=True)
assert isinstance(X[t], RandomIndexedSymbol)
assert E(X[0]) == Expectation(X[0])
raises(TypeError, lambda: DiscreteMarkovChain(1))
raises(NotImplementedError, lambda: X(t))
# pass name and state_space
Y = DiscreteMarkovChain("Y", [1, 2, 3])
assert Y.transition_probabilities == None
assert Y.state_space == FiniteSet(1, 2, 3)
assert P(Eq(Y[2], 1), Eq(Y[0], 2)) == Probability(Eq(Y[2], 1), Eq(Y[0], 2))
assert E(X[0]) == Expectation(X[0])
raises(TypeError, lambda: DiscreteMarkovChain("Y", dict((1, 1))))
# pass name, state_space and transition_probabilities
T = Matrix([[0.5, 0.2, 0.3],[0.2, 0.5, 0.3],[0.2, 0.3, 0.5]])
TS = MatrixSymbol('T', 3, 3)
Y = DiscreteMarkovChain("Y", [0, 1, 2], T)
YS = DiscreteMarkovChain("Y", [0, 1, 2], TS)
assert YS._transient2transient() == None
assert YS._transient2absorbing() == None
assert Y.joint_distribution(1, Y[2], 3) == JointDistribution(Y[1], Y[2], Y[3])
raises(ValueError, lambda: Y.joint_distribution(Y[1].symbol, Y[2].symbol))
assert P(Eq(Y[3], 2), Eq(Y[1], 1)).round(2) == Float(0.36, 2)
assert str(P(Eq(YS[3], 2), Eq(YS[1], 1))) == \
"T[0, 2]*T[1, 0] + T[1, 1]*T[1, 2] + T[1, 2]*T[2, 2]"
assert P(Eq(YS[1], 1), Eq(YS[2], 2)) == Probability(Eq(YS[1], 1))
assert P(Eq(YS[3], 3), Eq(YS[1], 1)) is S.Zero
TO = Matrix([[0.25, 0.75, 0],[0, 0.25, 0.75],[0.75, 0, 0.25]])
assert P(Eq(Y[3], 2), Eq(Y[1], 1) & TransitionMatrixOf(Y, TO)).round(3) == Float(0.375, 3)
assert E(Y[3], evaluate=False) == Expectation(Y[3])
assert E(Y[3], Eq(Y[2], 1)).round(2) == Float(1.1, 3)
TSO = MatrixSymbol('T', 4, 4)
raises(ValueError, lambda: str(P(Eq(YS[3], 2), Eq(YS[1], 1) & TransitionMatrixOf(YS, TSO))))
raises(TypeError, lambda: DiscreteMarkovChain("Z", [0, 1, 2], symbols('M')))
raises(ValueError, lambda: DiscreteMarkovChain("Z", [0, 1, 2], MatrixSymbol('T', 3, 4)))
raises(ValueError, lambda: E(Y[3], Eq(Y[2], 6)))
raises(ValueError, lambda: E(Y[2], Eq(Y[3], 1)))
# extended tests for probability queries
TO1 = Matrix([[Rational(1, 4), Rational(3, 4), 0],[Rational(1, 3), Rational(1, 3), Rational(1, 3)],[0, Rational(1, 4), Rational(3, 4)]])
assert P(And(Eq(Y[2], 1), Eq(Y[1], 1), Eq(Y[0], 0)),
Eq(Probability(Eq(Y[0], 0)), Rational(1, 4)) & TransitionMatrixOf(Y, TO1)) == Rational(1, 16)
assert P(And(Eq(Y[2], 1), Eq(Y[1], 1), Eq(Y[0], 0)), TransitionMatrixOf(Y, TO1)) == \
Probability(Eq(Y[0], 0))/4
assert P(Lt(X[1], 2) & Gt(X[1], 0), Eq(X[0], 2) &
StochasticStateSpaceOf(X, [0, 1, 2]) & TransitionMatrixOf(X, TO1)) == Rational(1, 4)
assert P(Ne(X[1], 2) & Ne(X[1], 1), Eq(X[0], 2) &
StochasticStateSpaceOf(X, [0, 1, 2]) & TransitionMatrixOf(X, TO1)) is S.Zero
assert P(And(Eq(Y[2], 1), Eq(Y[1], 1), Eq(Y[0], 0)), Eq(Y[1], 1)) == 0.1*Probability(Eq(Y[0], 0))
# testing properties of Markov chain
TO2 = Matrix([[S.One, 0, 0],[Rational(1, 3), Rational(1, 3), Rational(1, 3)],[0, Rational(1, 4), Rational(3, 4)]])
TO3 = Matrix([[Rational(1, 4), Rational(3, 4), 0],[Rational(1, 3), Rational(1, 3), Rational(1, 3)],[0, Rational(1, 4), Rational(3, 4)]])
Y2 = DiscreteMarkovChain('Y', trans_probs=TO2)
Y3 = DiscreteMarkovChain('Y', trans_probs=TO3)
assert Y3._transient2absorbing() == None
raises (ValueError, lambda: Y3.fundamental_matrix())
assert Y2.is_absorbing_chain() == True
assert Y3.is_absorbing_chain() == False
TO4 = Matrix([[Rational(1, 5), Rational(2, 5), Rational(2, 5)], [Rational(1, 10), S.Half, Rational(2, 5)], [Rational(3, 5), Rational(3, 10), Rational(1, 10)]])
Y4 = DiscreteMarkovChain('Y', trans_probs=TO4)
w = ImmutableMatrix([[Rational(11, 39), Rational(16, 39), Rational(4, 13)]])
assert Y4.limiting_distribution == w
assert Y4.is_regular() == True
TS1 = MatrixSymbol('T', 3, 3)
Y5 = DiscreteMarkovChain('Y', trans_probs=TS1)
assert Y5.limiting_distribution(w, TO4).doit() == True
TO6 = Matrix([[S.One, 0, 0, 0, 0],[S.Half, 0, S.Half, 0, 0],[0, S.Half, 0, S.Half, 0], [0, 0, S.Half, 0, S.Half], [0, 0, 0, 0, 1]])
Y6 = DiscreteMarkovChain('Y', trans_probs=TO6)
assert Y6._transient2absorbing() == ImmutableMatrix([[S.Half, 0], [0, 0], [0, S.Half]])
assert Y6._transient2transient() == ImmutableMatrix([[0, S.Half, 0], [S.Half, 0, S.Half], [0, S.Half, 0]])
assert Y6.fundamental_matrix() == ImmutableMatrix([[Rational(3, 2), S.One, S.Half], [S.One, S(2), S.One], [S.Half, S.One, Rational(3, 2)]])
assert Y6.absorbing_probabilites() == ImmutableMatrix([[Rational(3, 4), Rational(1, 4)], [S.Half, S.Half], [Rational(1, 4), Rational(3, 4)]])
# testing miscellaneous queries
T = Matrix([[S.Half, Rational(1, 4), Rational(1, 4)],
[Rational(1, 3), 0, Rational(2, 3)],
[S.Half, S.Half, 0]])
X = DiscreteMarkovChain('X', [0, 1, 2], T)
assert P(Eq(X[1], 2) & Eq(X[2], 1) & Eq(X[3], 0),
Eq(P(Eq(X[1], 0)), Rational(1, 4)) & Eq(P(Eq(X[1], 1)), Rational(1, 4))) == Rational(1, 12)
assert P(Eq(X[2], 1) | Eq(X[2], 2), Eq(X[1], 1)) == Rational(2, 3)
assert P(Eq(X[2], 1) & Eq(X[2], 2), Eq(X[1], 1)) is S.Zero
assert P(Ne(X[2], 2), Eq(X[1], 1)) == Rational(1, 3)
assert E(X[1]**2, Eq(X[0], 1)) == Rational(8, 3)
assert variance(X[1], Eq(X[0], 1)) == Rational(8, 9)
raises(ValueError, lambda: E(X[1], Eq(X[2], 1)))
def test_ContinuousMarkovChain():
T1 = Matrix([[S(-2), S(2), S.Zero],
[S.Zero, S.NegativeOne, S.One],
[Rational(3, 2), Rational(3, 2), S(-3)]])
C1 = ContinuousMarkovChain('C', [0, 1, 2], T1)
assert C1.limiting_distribution() == ImmutableMatrix([[Rational(3, 19), Rational(12, 19), Rational(4, 19)]])
T2 = Matrix([[-S.One, S.One, S.Zero], [S.One, -S.One, S.Zero], [S.Zero, S.One, -S.One]])
C2 = ContinuousMarkovChain('C', [0, 1, 2], T2)
A, t = C2.generator_matrix, symbols('t', positive=True)
assert C2.transition_probabilities(A)(t) == Matrix([[S.Half + exp(-2*t)/2, S.Half - exp(-2*t)/2, 0],
[S.Half - exp(-2*t)/2, S.Half + exp(-2*t)/2, 0],
[S.Half - exp(-t) + exp(-2*t)/2, S.Half - exp(-2*t)/2, exp(-t)]])
assert P(Eq(C2(1), 1), Eq(C2(0), 1), evaluate=False) == Probability(Eq(C2(1), 1))
assert P(Eq(C2(1), 1), Eq(C2(0), 1)) == exp(-2)/2 + S.Half
assert P(Eq(C2(1), 0) & Eq(C2(2), 1) & Eq(C2(3), 1),
Eq(P(Eq(C2(1), 0)), S.Half)) == (Rational(1, 4) - exp(-2)/4)*(exp(-2)/2 + S.Half)
assert P(Not(Eq(C2(1), 0) & Eq(C2(2), 1) & Eq(C2(3), 2)) |
(Eq(C2(1), 0) & Eq(C2(2), 1) & Eq(C2(3), 2)),
Eq(P(Eq(C2(1), 0)), Rational(1, 4)) & Eq(P(Eq(C2(1), 1)), Rational(1, 4))) is S.One
assert E(C2(Rational(3, 2)), Eq(C2(0), 2)) == -exp(-3)/2 + 2*exp(Rational(-3, 2)) + S.Half
assert variance(C2(Rational(3, 2)), Eq(C2(0), 1)) == ((S.Half - exp(-3)/2)**2*(exp(-3)/2 + S.Half)
+ (Rational(-1, 2) - exp(-3)/2)**2*(S.Half - exp(-3)/2))
raises(KeyError, lambda: P(Eq(C2(1), 0), Eq(P(Eq(C2(1), 1)), S.Half)))
assert P(Eq(C2(1), 0), Eq(P(Eq(C2(5), 1)), S.Half)) == Probability(Eq(C2(1), 0))
TS1 = MatrixSymbol('G', 3, 3)
CS1 = ContinuousMarkovChain('C', [0, 1, 2], TS1)
A = CS1.generator_matrix
assert CS1.transition_probabilities(A)(t) == exp(t*A)
def test_BernoulliProcess():
B = BernoulliProcess("B", p=0.6, success=1, failure=0)
assert B.state_space == FiniteSet(0, 1)
assert B.index_set == S.Naturals0
assert B.success == 1
assert B.failure == 0
X = BernoulliProcess("X", p=Rational(1,3), success='H', failure='T')
assert X.state_space == FiniteSet('H', 'T')
H, T = symbols("H,T")
assert E(X[1]+X[2]*X[3]) == H**2/9 + 4*H*T/9 + H/3 + 4*T**2/9 + 2*T/3
t, x = symbols('t, x', positive=True, integer=True)
assert isinstance(B[t], RandomIndexedSymbol)
raises(ValueError, lambda: BernoulliProcess("X", p=1.1, success=1, failure=0))
raises(NotImplementedError, lambda: B(t))
raises(IndexError, lambda: B[-3])
assert B.joint_distribution(B[3], B[9]) == JointDistributionHandmade(Lambda((B[3], B[9]),
Piecewise((0.6, Eq(B[3], 1)), (0.4, Eq(B[3], 0)), (0, True))
*Piecewise((0.6, Eq(B[9], 1)), (0.4, Eq(B[9], 0)), (0, True))))
assert B.joint_distribution(2, B[4]) == JointDistributionHandmade(Lambda((B[2], B[4]),
Piecewise((0.6, Eq(B[2], 1)), (0.4, Eq(B[2], 0)), (0, True))
*Piecewise((0.6, Eq(B[4], 1)), (0.4, Eq(B[4], 0)), (0, True))))
# Test for the sum distribution of Bernoulli Process RVs
Y = B[1] + B[2] + B[3]
assert P(Eq(Y, 0)).round(2) == Float(0.06, 1)
assert P(Eq(Y, 2)).round(2) == Float(0.43, 2)
assert P(Eq(Y, 4)).round(2) == 0
assert P(Gt(Y, 1)).round(2) == Float(0.65, 2)
# Test for independency of each Random Indexed variable
assert P(Eq(B[1], 0) & Eq(B[2], 1) & Eq(B[3], 0) & Eq(B[4], 1)).round(2) == Float(0.06, 1)
assert E(2 * B[1] + B[2]).round(2) == Float(1.80, 3)
assert E(2 * B[1] + B[2] + 5).round(2) == Float(6.80, 3)
assert E(B[2] * B[4] + B[10]).round(2) == Float(0.96, 2)
assert E(B[2] > 0, Eq(B[1],1) & Eq(B[2],1)).round(2) == Float(0.60,2)
assert E(B[1]) == 0.6
assert P(B[1] > 0).round(2) == Float(0.60, 2)
assert P(B[1] < 1).round(2) == Float(0.40, 2)
assert P(B[1] > 0, B[2] <= 1).round(2) == Float(0.60, 2)
assert P(B[12] * B[5] > 0).round(2) == Float(0.36, 2)
assert P(B[12] * B[5] > 0, B[4] < 1).round(2) == Float(0.36, 2)
assert P(Eq(B[2], 1), B[2] > 0) == 1
assert P(Eq(B[5], 3)) == 0
assert P(Eq(B[1], 1), B[1] < 0) == 0
assert P(B[2] > 0, Eq(B[2], 1)) == 1
assert P(B[2] < 0, Eq(B[2], 1)) == 0
assert P(B[2] > 0, B[2]==7) == 0
assert P(B[5] > 0, B[5]) == BernoulliDistribution(0.6, 0, 1)
raises(ValueError, lambda: P(3))
raises(ValueError, lambda: P(B[3] > 0, 3))
# test issue 19456
expr = Sum(B[t], (t, 0, 4))
expr2 = Sum(B[t], (t, 1, 3))
expr3 = Sum(B[t]**2, (t, 1, 3))
assert expr.doit() == B[0] + B[1] + B[2] + B[3] + B[4]
assert expr2.doit() == Y
assert expr3.doit() == B[1]**2 + B[2]**2 + B[3]**2
assert B[2*t].free_symbols == {B[2*t], t}
assert B[4].free_symbols == {B[4]}
assert B[x*t].free_symbols == {B[x*t], x, t}
|
75a582059ee8fe03823dee50b87087bb6cc47a0874264f4c05af4baa7b122341 | from sympy import (S, Symbol, Sum, I, lambdify, re, im, log, simplify, sqrt,
zeta, pi, besseli, Dummy, oo, Piecewise, Rational, beta,
floor, FiniteSet)
from sympy.core.relational import Eq, Ne
from sympy.functions.elementary.exponential import exp
from sympy.logic.boolalg import Or
from sympy.sets.fancysets import Range
from sympy.stats import (P, E, variance, density, characteristic_function,
where, moment_generating_function, skewness, cdf,
kurtosis, coskewness)
from sympy.stats.drv_types import (PoissonDistribution, GeometricDistribution,
Poisson, Geometric, Hermite, Logarithmic,
NegativeBinomial, Skellam, YuleSimon, Zeta,
DiscreteRV)
from sympy.stats.rv import sample
from sympy.testing.pytest import slow, nocache_fail, raises, skip, ignore_warnings
from sympy.external import import_module
x = Symbol('x')
def test_PoissonDistribution():
l = 3
p = PoissonDistribution(l)
assert abs(p.cdf(10).evalf() - 1) < .001
assert p.expectation(x, x) == l
assert p.expectation(x**2, x) - p.expectation(x, x)**2 == l
def test_Poisson():
l = 3
x = Poisson('x', l)
assert E(x) == l
assert variance(x) == l
assert density(x) == PoissonDistribution(l)
assert isinstance(E(x, evaluate=False), Sum)
assert isinstance(E(2*x, evaluate=False), Sum)
# issue 8248
assert x.pspace.compute_expectation(1) == 1
@slow
def test_GeometricDistribution():
p = S.One / 5
d = GeometricDistribution(p)
assert d.expectation(x, x) == 1/p
assert d.expectation(x**2, x) - d.expectation(x, x)**2 == (1-p)/p**2
assert abs(d.cdf(20000).evalf() - 1) < .001
X = Geometric('X', Rational(1, 5))
Y = Geometric('Y', Rational(3, 10))
assert coskewness(X, X + Y, X + 2*Y).simplify() == sqrt(230)*Rational(81, 1150)
def test_Hermite():
a1 = Symbol("a1", positive=True)
a2 = Symbol("a2", negative=True)
raises(ValueError, lambda: Hermite("H", a1, a2))
a1 = Symbol("a1", negative=True)
a2 = Symbol("a2", positive=True)
raises(ValueError, lambda: Hermite("H", a1, a2))
a1 = Symbol("a1", positive=True)
x = Symbol("x")
H = Hermite("H", a1, a2)
assert moment_generating_function(H)(x) == exp(a1*(exp(x) - 1)
+ a2*(exp(2*x) - 1))
assert characteristic_function(H)(x) == exp(a1*(exp(I*x) - 1)
+ a2*(exp(2*I*x) - 1))
assert E(H) == a1 + 2*a2
H = Hermite("H", a1=5, a2=4)
assert density(H)(2) == 33*exp(-9)/2
assert E(H) == 13
assert variance(H) == 21
assert kurtosis(H) == Rational(464,147)
assert skewness(H) == 37*sqrt(21)/441
def test_Logarithmic():
p = S.Half
x = Logarithmic('x', p)
assert E(x) == -p / ((1 - p) * log(1 - p))
assert variance(x) == -1/log(2)**2 + 2/log(2)
assert E(2*x**2 + 3*x + 4) == 4 + 7 / log(2)
assert isinstance(E(x, evaluate=False), Sum)
@nocache_fail
def test_negative_binomial():
r = 5
p = S.One / 3
x = NegativeBinomial('x', r, p)
assert E(x) == p*r / (1-p)
# This hangs when run with the cache disabled:
assert variance(x) == p*r / (1-p)**2
assert E(x**5 + 2*x + 3) == Rational(9207, 4)
assert isinstance(E(x, evaluate=False), Sum)
def test_skellam():
mu1 = Symbol('mu1')
mu2 = Symbol('mu2')
z = Symbol('z')
X = Skellam('x', mu1, mu2)
assert density(X)(z) == (mu1/mu2)**(z/2) * \
exp(-mu1 - mu2)*besseli(z, 2*sqrt(mu1*mu2))
assert skewness(X).expand() == mu1/(mu1*sqrt(mu1 + mu2) + mu2 *
sqrt(mu1 + mu2)) - mu2/(mu1*sqrt(mu1 + mu2) + mu2*sqrt(mu1 + mu2))
assert variance(X).expand() == mu1 + mu2
assert E(X) == mu1 - mu2
assert characteristic_function(X)(z) == exp(
mu1*exp(I*z) - mu1 - mu2 + mu2*exp(-I*z))
assert moment_generating_function(X)(z) == exp(
mu1*exp(z) - mu1 - mu2 + mu2*exp(-z))
def test_yule_simon():
from sympy import S
rho = S(3)
x = YuleSimon('x', rho)
assert simplify(E(x)) == rho / (rho - 1)
assert simplify(variance(x)) == rho**2 / ((rho - 1)**2 * (rho - 2))
assert isinstance(E(x, evaluate=False), Sum)
# To test the cdf function
assert cdf(x)(x) == Piecewise((-beta(floor(x), 4)*floor(x) + 1, x >= 1), (0, True))
def test_zeta():
s = S(5)
x = Zeta('x', s)
assert E(x) == zeta(s-1) / zeta(s)
assert simplify(variance(x)) == (
zeta(s) * zeta(s-2) - zeta(s-1)**2) / zeta(s)**2
@slow
def test_sample_discrete():
X = Geometric('X', S.Half)
scipy = import_module('scipy')
if not scipy:
skip('Scipy not installed. Abort tests')
with ignore_warnings(UserWarning):
assert next(sample(X)) in X.pspace.domain.set
samps = next(sample(X, size=2)) # This takes long time if ran without scipy
for samp in samps:
assert samp in X.pspace.domain.set
def test_discrete_probability():
X = Geometric('X', Rational(1, 5))
Y = Poisson('Y', 4)
G = Geometric('e', x)
assert P(Eq(X, 3)) == Rational(16, 125)
assert P(X < 3) == Rational(9, 25)
assert P(X > 3) == Rational(64, 125)
assert P(X >= 3) == Rational(16, 25)
assert P(X <= 3) == Rational(61, 125)
assert P(Ne(X, 3)) == Rational(109, 125)
assert P(Eq(Y, 3)) == 32*exp(-4)/3
assert P(Y < 3) == 13*exp(-4)
assert P(Y > 3).equals(32*(Rational(-71, 32) + 3*exp(4)/32)*exp(-4)/3)
assert P(Y >= 3).equals(32*(Rational(-39, 32) + 3*exp(4)/32)*exp(-4)/3)
assert P(Y <= 3) == 71*exp(-4)/3
assert P(Ne(Y, 3)).equals(
13*exp(-4) + 32*(Rational(-71, 32) + 3*exp(4)/32)*exp(-4)/3)
assert P(X < S.Infinity) is S.One
assert P(X > S.Infinity) is S.Zero
assert P(G < 3) == x*(2-x)
assert P(Eq(G, 3)) == x*(-x + 1)**2
def test_DiscreteRV():
p = S(1)/2
x = Symbol('x', integer=True, positive=True)
pdf = p*(1 - p)**(x - 1) # pdf of Geometric Distribution
D = DiscreteRV(x, pdf, set=S.Naturals)
assert E(D) == E(Geometric('G', S(1)/2)) == 2
assert P(D > 3) == S(1)/8
assert D.pspace.domain.set == S.Naturals
raises(ValueError, lambda: DiscreteRV(x, x, FiniteSet(*range(4))))
def test_precomputed_characteristic_functions():
import mpmath
def test_cf(dist, support_lower_limit, support_upper_limit):
pdf = density(dist)
t = S('t')
x = S('x')
# first function is the hardcoded CF of the distribution
cf1 = lambdify([t], characteristic_function(dist)(t), 'mpmath')
# second function is the Fourier transform of the density function
f = lambdify([x, t], pdf(x)*exp(I*x*t), 'mpmath')
cf2 = lambda t: mpmath.nsum(lambda x: f(x, t), [
support_lower_limit, support_upper_limit], maxdegree=10)
# compare the two functions at various points
for test_point in [2, 5, 8, 11]:
n1 = cf1(test_point)
n2 = cf2(test_point)
assert abs(re(n1) - re(n2)) < 1e-12
assert abs(im(n1) - im(n2)) < 1e-12
test_cf(Geometric('g', Rational(1, 3)), 1, mpmath.inf)
test_cf(Logarithmic('l', Rational(1, 5)), 1, mpmath.inf)
test_cf(NegativeBinomial('n', 5, Rational(1, 7)), 0, mpmath.inf)
test_cf(Poisson('p', 5), 0, mpmath.inf)
test_cf(YuleSimon('y', 5), 1, mpmath.inf)
test_cf(Zeta('z', 5), 1, mpmath.inf)
def test_moment_generating_functions():
t = S('t')
geometric_mgf = moment_generating_function(Geometric('g', S.Half))(t)
assert geometric_mgf.diff(t).subs(t, 0) == 2
logarithmic_mgf = moment_generating_function(Logarithmic('l', S.Half))(t)
assert logarithmic_mgf.diff(t).subs(t, 0) == 1/log(2)
negative_binomial_mgf = moment_generating_function(
NegativeBinomial('n', 5, Rational(1, 3)))(t)
assert negative_binomial_mgf.diff(t).subs(t, 0) == Rational(5, 2)
poisson_mgf = moment_generating_function(Poisson('p', 5))(t)
assert poisson_mgf.diff(t).subs(t, 0) == 5
skellam_mgf = moment_generating_function(Skellam('s', 1, 1))(t)
assert skellam_mgf.diff(t).subs(
t, 2) == (-exp(-2) + exp(2))*exp(-2 + exp(-2) + exp(2))
yule_simon_mgf = moment_generating_function(YuleSimon('y', 3))(t)
assert simplify(yule_simon_mgf.diff(t).subs(t, 0)) == Rational(3, 2)
zeta_mgf = moment_generating_function(Zeta('z', 5))(t)
assert zeta_mgf.diff(t).subs(t, 0) == pi**4/(90*zeta(5))
def test_Or():
X = Geometric('X', S.Half)
P(Or(X < 3, X > 4)) == Rational(13, 16)
P(Or(X > 2, X > 1)) == P(X > 1)
P(Or(X >= 3, X < 3)) == 1
def test_where():
X = Geometric('X', Rational(1, 5))
Y = Poisson('Y', 4)
assert where(X**2 > 4).set == Range(3, S.Infinity, 1)
assert where(X**2 >= 4).set == Range(2, S.Infinity, 1)
assert where(Y**2 < 9).set == Range(0, 3, 1)
assert where(Y**2 <= 9).set == Range(0, 4, 1)
def test_conditional():
X = Geometric('X', Rational(2, 3))
Y = Poisson('Y', 3)
assert P(X > 2, X > 3) == 1
assert P(X > 3, X > 2) == Rational(1, 3)
assert P(Y > 2, Y < 2) == 0
assert P(Eq(Y, 3), Y >= 0) == 9*exp(-3)/2
assert P(Eq(Y, 3), Eq(Y, 2)) == 0
assert P(X < 2, Eq(X, 2)) == 0
assert P(X > 2, Eq(X, 3)) == 1
def test_product_spaces():
X1 = Geometric('X1', S.Half)
X2 = Geometric('X2', Rational(1, 3))
#assert str(P(X1 + X2 < 3, evaluate=False)) == """Sum(Piecewise((2**(X2 - n - 2)*(2/3)**(X2 - 1)/6, """\
# + """(-X2 + n + 3 >= 1) & (-X2 + n + 3 < oo)), (0, True)), (X2, 1, oo), (n, -oo, -1))"""
n = Dummy('n')
assert P(X1 + X2 < 3, evaluate=False).dummy_eq(Sum(Piecewise((2**(-n)/4,
n + 2 >= 1), (0, True)), (n, -oo, -1))/3)
#assert str(P(X1 + X2 > 3)) == """Sum(Piecewise((2**(X2 - n - 2)*(2/3)**(X2 - 1)/6, """ +\
# """(-X2 + n + 3 >= 1) & (-X2 + n + 3 < oo)), (0, True)), (X2, 1, oo), (n, 1, oo))"""
assert P(X1 + X2 > 3).dummy_eq(Sum(Piecewise((2**(X2 - n - 2)*(Rational(2, 3))**(X2 - 1)/6,
-X2 + n + 3 >= 1), (0, True)),
(X2, 1, oo), (n, 1, oo)))
# assert str(P(Eq(X1 + X2, 3))) == """Sum(Piecewise((2**(X2 - 2)*(2/3)**(X2 - 1)/6, """ +\
# """X2 <= 2), (0, True)), (X2, 1, oo))"""
assert P(Eq(X1 + X2, 3)) == Rational(1, 12)
def test_sample_numpy():
distribs_numpy = [
Geometric('G', 0.5),
Poisson('P', 1),
Zeta('Z', 2)
]
size = 3
numpy = import_module('numpy')
if not numpy:
skip('Numpy is not installed. Abort tests for _sample_numpy.')
else:
with ignore_warnings(UserWarning):
for X in distribs_numpy:
samps = next(sample(X, size=size, library='numpy'))
for sam in samps:
assert sam in X.pspace.domain.set
raises(NotImplementedError,
lambda: next(sample(Skellam('S', 1, 1), library='numpy')))
raises(NotImplementedError,
lambda: Skellam('S', 1, 1).pspace.distribution.sample(library='tensorflow'))
def test_sample_scipy():
p = S(2)/3
x = Symbol('x', integer=True, positive=True)
pdf = p*(1 - p)**(x - 1) # pdf of Geometric Distribution
distribs_scipy = [
DiscreteRV(x, pdf, set=S.Naturals),
Geometric('G', 0.5),
Logarithmic('L', 0.5),
NegativeBinomial('N', 5, 0.4),
Poisson('P', 1),
Skellam('S', 1, 1),
YuleSimon('Y', 1),
Zeta('Z', 2)
]
size = 3
numsamples = 5
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests for _sample_scipy.')
else:
with ignore_warnings(UserWarning):
z_sample = list(sample(Zeta("G", 7), size=size, numsamples=numsamples))
assert len(z_sample) == numsamples
for X in distribs_scipy:
samps = next(sample(X, size=size, library='scipy'))
samps2 = next(sample(X, size=(2, 2), library='scipy'))
for sam in samps:
assert sam in X.pspace.domain.set
for i in range(2):
for j in range(2):
assert samps2[i][j] in X.pspace.domain.set
def test_sample_pymc3():
distribs_pymc3 = [
Geometric('G', 0.5),
Poisson('P', 1),
NegativeBinomial('N', 5, 0.4)
]
size = 3
pymc3 = import_module('pymc3')
if not pymc3:
skip('PyMC3 is not installed. Abort tests for _sample_pymc3.')
else:
with ignore_warnings(UserWarning):
for X in distribs_pymc3:
samps = next(sample(X, size=size, library='pymc3'))
for sam in samps:
assert sam in X.pspace.domain.set
raises(NotImplementedError,
lambda: next(sample(Skellam('S', 1, 1), library='pymc3')))
|
3469c685e38bd564efca5bac4166c7c8f075d40206f2e506ba94e6e2b48c2002 | from sympy import E as e
from sympy import (Symbol, Abs, exp, expint, S, pi, simplify, Interval, erf, erfc, Ne,
EulerGamma, Eq, log, lowergamma, uppergamma, symbols, sqrt, And,
gamma, beta, Piecewise, Integral, sin, cos, tan, sinh, cosh,
besseli, floor, expand_func, Rational, I, re, Lambda, asin,
im, lambdify, hyper, diff, Or, Mul, sign, Dummy, Sum,
factorial, binomial, erfi, besselj, besselk)
from sympy.external import import_module
from sympy.functions.special.error_functions import erfinv
from sympy.functions.special.hyper import meijerg
from sympy.sets.sets import Intersection, FiniteSet
from sympy.stats import (P, E, where, density, variance, covariance, skewness, kurtosis, median,
given, pspace, cdf, characteristic_function, moment_generating_function,
ContinuousRV, sample, Arcsin, Benini, Beta, BetaNoncentral, BetaPrime,
Cauchy, Chi, ChiSquared, ChiNoncentral, Dagum, Erlang, ExGaussian,
Exponential, ExponentialPower, FDistribution, FisherZ, Frechet, Gamma,
GammaInverse, Gompertz, Gumbel, Kumaraswamy, Laplace, Levy, Logistic,
LogLogistic, LogNormal, Maxwell, Moyal, Nakagami, Normal, GaussianInverse,
Pareto, PowerFunction, QuadraticU, RaisedCosine, Rayleigh, Reciprocal, ShiftedGompertz, StudentT,
Trapezoidal, Triangular, Uniform, UniformSum, VonMises, Weibull, coskewness,
WignerSemicircle, Wald, correlation, moment, cmoment, smoment, quantile,
Lomax, BoundedPareto)
from sympy.stats.crv_types import NormalDistribution, ExponentialDistribution, ContinuousDistributionHandmade
from sympy.stats.joint_rv_types import MultivariateLaplaceDistribution, MultivariateNormalDistribution
from sympy.stats.crv import SingleContinuousPSpace, SingleContinuousDomain
from sympy.stats.joint_rv import JointPSpace
from sympy.testing.pytest import raises, XFAIL, slow, skip, ignore_warnings
from sympy.testing.randtest import verify_numerically as tn
oo = S.Infinity
x, y, z = map(Symbol, 'xyz')
def test_single_normal():
mu = Symbol('mu', real=True)
sigma = Symbol('sigma', positive=True)
X = Normal('x', 0, 1)
Y = X*sigma + mu
assert E(Y) == mu
assert variance(Y) == sigma**2
pdf = density(Y)
x = Symbol('x', real=True)
assert (pdf(x) ==
2**S.Half*exp(-(x - mu)**2/(2*sigma**2))/(2*pi**S.Half*sigma))
assert P(X**2 < 1) == erf(2**S.Half/2)
assert quantile(Y)(x) == Intersection(S.Reals, FiniteSet(sqrt(2)*sigma*(sqrt(2)*mu/(2*sigma) + erfinv(2*x - 1))))
assert E(X, Eq(X, mu)) == mu
assert median(X) == FiniteSet(0)
# issue 8248
assert X.pspace.compute_expectation(1).doit() == 1
def test_conditional_1d():
X = Normal('x', 0, 1)
Y = given(X, X >= 0)
z = Symbol('z')
assert density(Y)(z) == 2 * density(X)(z)
assert Y.pspace.domain.set == Interval(0, oo)
assert E(Y) == sqrt(2) / sqrt(pi)
assert E(X**2) == E(Y**2)
def test_ContinuousDomain():
X = Normal('x', 0, 1)
assert where(X**2 <= 1).set == Interval(-1, 1)
assert where(X**2 <= 1).symbol == X.symbol
where(And(X**2 <= 1, X >= 0)).set == Interval(0, 1)
raises(ValueError, lambda: where(sin(X) > 1))
Y = given(X, X >= 0)
assert Y.pspace.domain.set == Interval(0, oo)
@slow
def test_multiple_normal():
X, Y = Normal('x', 0, 1), Normal('y', 0, 1)
p = Symbol("p", positive=True)
assert E(X + Y) == 0
assert variance(X + Y) == 2
assert variance(X + X) == 4
assert covariance(X, Y) == 0
assert covariance(2*X + Y, -X) == -2*variance(X)
assert skewness(X) == 0
assert skewness(X + Y) == 0
assert kurtosis(X) == 3
assert kurtosis(X+Y) == 3
assert correlation(X, Y) == 0
assert correlation(X, X + Y) == correlation(X, X - Y)
assert moment(X, 2) == 1
assert cmoment(X, 3) == 0
assert moment(X + Y, 4) == 12
assert cmoment(X, 2) == variance(X)
assert smoment(X*X, 2) == 1
assert smoment(X + Y, 3) == skewness(X + Y)
assert smoment(X + Y, 4) == kurtosis(X + Y)
assert E(X, Eq(X + Y, 0)) == 0
assert variance(X, Eq(X + Y, 0)) == S.Half
assert quantile(X)(p) == sqrt(2)*erfinv(2*p - S.One)
def test_symbolic():
mu1, mu2 = symbols('mu1 mu2', real=True)
s1, s2 = symbols('sigma1 sigma2', positive=True)
rate = Symbol('lambda', positive=True)
X = Normal('x', mu1, s1)
Y = Normal('y', mu2, s2)
Z = Exponential('z', rate)
a, b, c = symbols('a b c', real=True)
assert E(X) == mu1
assert E(X + Y) == mu1 + mu2
assert E(a*X + b) == a*E(X) + b
assert variance(X) == s1**2
assert variance(X + a*Y + b) == variance(X) + a**2*variance(Y)
assert E(Z) == 1/rate
assert E(a*Z + b) == a*E(Z) + b
assert E(X + a*Z + b) == mu1 + a/rate + b
assert median(X) == FiniteSet(mu1)
def test_cdf():
X = Normal('x', 0, 1)
d = cdf(X)
assert P(X < 1) == d(1).rewrite(erfc)
assert d(0) == S.Half
d = cdf(X, X > 0) # given X>0
assert d(0) == 0
Y = Exponential('y', 10)
d = cdf(Y)
assert d(-5) == 0
assert P(Y > 3) == 1 - d(3)
raises(ValueError, lambda: cdf(X + Y))
Z = Exponential('z', 1)
f = cdf(Z)
assert f(z) == Piecewise((1 - exp(-z), z >= 0), (0, True))
def test_characteristic_function():
X = Uniform('x', 0, 1)
cf = characteristic_function(X)
assert cf(1) == -I*(-1 + exp(I))
Y = Normal('y', 1, 1)
cf = characteristic_function(Y)
assert cf(0) == 1
assert cf(1) == exp(I - S.Half)
Z = Exponential('z', 5)
cf = characteristic_function(Z)
assert cf(0) == 1
assert cf(1).expand() == Rational(25, 26) + I*Rational(5, 26)
X = GaussianInverse('x', 1, 1)
cf = characteristic_function(X)
assert cf(0) == 1
assert cf(1) == exp(1 - sqrt(1 - 2*I))
X = ExGaussian('x', 0, 1, 1)
cf = characteristic_function(X)
assert cf(0) == 1
assert cf(1) == (1 + I)*exp(Rational(-1, 2))/2
L = Levy('x', 0, 1)
cf = characteristic_function(L)
assert cf(0) == 1
assert cf(1) == exp(-sqrt(2)*sqrt(-I))
def test_moment_generating_function():
t = symbols('t', positive=True)
# Symbolic tests
a, b, c = symbols('a b c')
mgf = moment_generating_function(Beta('x', a, b))(t)
assert mgf == hyper((a,), (a + b,), t)
mgf = moment_generating_function(Chi('x', a))(t)
assert mgf == sqrt(2)*t*gamma(a/2 + S.Half)*\
hyper((a/2 + S.Half,), (Rational(3, 2),), t**2/2)/gamma(a/2) +\
hyper((a/2,), (S.Half,), t**2/2)
mgf = moment_generating_function(ChiSquared('x', a))(t)
assert mgf == (1 - 2*t)**(-a/2)
mgf = moment_generating_function(Erlang('x', a, b))(t)
assert mgf == (1 - t/b)**(-a)
mgf = moment_generating_function(ExGaussian("x", a, b, c))(t)
assert mgf == exp(a*t + b**2*t**2/2)/(1 - t/c)
mgf = moment_generating_function(Exponential('x', a))(t)
assert mgf == a/(a - t)
mgf = moment_generating_function(Gamma('x', a, b))(t)
assert mgf == (-b*t + 1)**(-a)
mgf = moment_generating_function(Gumbel('x', a, b))(t)
assert mgf == exp(b*t)*gamma(-a*t + 1)
mgf = moment_generating_function(Gompertz('x', a, b))(t)
assert mgf == b*exp(b)*expint(t/a, b)
mgf = moment_generating_function(Laplace('x', a, b))(t)
assert mgf == exp(a*t)/(-b**2*t**2 + 1)
mgf = moment_generating_function(Logistic('x', a, b))(t)
assert mgf == exp(a*t)*beta(-b*t + 1, b*t + 1)
mgf = moment_generating_function(Normal('x', a, b))(t)
assert mgf == exp(a*t + b**2*t**2/2)
mgf = moment_generating_function(Pareto('x', a, b))(t)
assert mgf == b*(-a*t)**b*uppergamma(-b, -a*t)
mgf = moment_generating_function(QuadraticU('x', a, b))(t)
assert str(mgf) == ("(3*(t*(-4*b + (a + b)**2) + 4)*exp(b*t) - "
"3*(t*(a**2 + 2*a*(b - 2) + b**2) + 4)*exp(a*t))/(t**2*(a - b)**3)")
mgf = moment_generating_function(RaisedCosine('x', a, b))(t)
assert mgf == pi**2*exp(a*t)*sinh(b*t)/(b*t*(b**2*t**2 + pi**2))
mgf = moment_generating_function(Rayleigh('x', a))(t)
assert mgf == sqrt(2)*sqrt(pi)*a*t*(erf(sqrt(2)*a*t/2) + 1)\
*exp(a**2*t**2/2)/2 + 1
mgf = moment_generating_function(Triangular('x', a, b, c))(t)
assert str(mgf) == ("(-2*(-a + b)*exp(c*t) + 2*(-a + c)*exp(b*t) + "
"2*(b - c)*exp(a*t))/(t**2*(-a + b)*(-a + c)*(b - c))")
mgf = moment_generating_function(Uniform('x', a, b))(t)
assert mgf == (-exp(a*t) + exp(b*t))/(t*(-a + b))
mgf = moment_generating_function(UniformSum('x', a))(t)
assert mgf == ((exp(t) - 1)/t)**a
mgf = moment_generating_function(WignerSemicircle('x', a))(t)
assert mgf == 2*besseli(1, a*t)/(a*t)
# Numeric tests
mgf = moment_generating_function(Beta('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 1) == hyper((2,), (3,), 1)/2
mgf = moment_generating_function(Chi('x', 1))(t)
assert mgf.diff(t).subs(t, 1) == sqrt(2)*hyper((1,), (Rational(3, 2),), S.Half
)/sqrt(pi) + hyper((Rational(3, 2),), (Rational(3, 2),), S.Half) + 2*sqrt(2)*hyper((2,),
(Rational(5, 2),), S.Half)/(3*sqrt(pi))
mgf = moment_generating_function(ChiSquared('x', 1))(t)
assert mgf.diff(t).subs(t, 1) == I
mgf = moment_generating_function(Erlang('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 0) == 1
mgf = moment_generating_function(ExGaussian("x", 0, 1, 1))(t)
assert mgf.diff(t).subs(t, 2) == -exp(2)
mgf = moment_generating_function(Exponential('x', 1))(t)
assert mgf.diff(t).subs(t, 0) == 1
mgf = moment_generating_function(Gamma('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 0) == 1
mgf = moment_generating_function(Gumbel('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 0) == EulerGamma + 1
mgf = moment_generating_function(Gompertz('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 1) == -e*meijerg(((), (1, 1)),
((0, 0, 0), ()), 1)
mgf = moment_generating_function(Laplace('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 0) == 1
mgf = moment_generating_function(Logistic('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 0) == beta(1, 1)
mgf = moment_generating_function(Normal('x', 0, 1))(t)
assert mgf.diff(t).subs(t, 1) == exp(S.Half)
mgf = moment_generating_function(Pareto('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 0) == expint(1, 0)
mgf = moment_generating_function(QuadraticU('x', 1, 2))(t)
assert mgf.diff(t).subs(t, 1) == -12*e - 3*exp(2)
mgf = moment_generating_function(RaisedCosine('x', 1, 1))(t)
assert mgf.diff(t).subs(t, 1) == -2*e*pi**2*sinh(1)/\
(1 + pi**2)**2 + e*pi**2*cosh(1)/(1 + pi**2)
mgf = moment_generating_function(Rayleigh('x', 1))(t)
assert mgf.diff(t).subs(t, 0) == sqrt(2)*sqrt(pi)/2
mgf = moment_generating_function(Triangular('x', 1, 3, 2))(t)
assert mgf.diff(t).subs(t, 1) == -e + exp(3)
mgf = moment_generating_function(Uniform('x', 0, 1))(t)
assert mgf.diff(t).subs(t, 1) == 1
mgf = moment_generating_function(UniformSum('x', 1))(t)
assert mgf.diff(t).subs(t, 1) == 1
mgf = moment_generating_function(WignerSemicircle('x', 1))(t)
assert mgf.diff(t).subs(t, 1) == -2*besseli(1, 1) + besseli(2, 1) +\
besseli(0, 1)
def test_sample_continuous():
Z = ContinuousRV(z, exp(-z), set=Interval(0, oo))
assert density(Z)(-1) == 0
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
with ignore_warnings(UserWarning):
assert next(sample(Z)) in Z.pspace.domain.set
sym, val = list(Z.pspace.sample().items())[0]
assert sym == Z and val in Interval(0, oo)
def test_ContinuousRV():
pdf = sqrt(2)*exp(-x**2/2)/(2*sqrt(pi)) # Normal distribution
# X and Y should be equivalent
X = ContinuousRV(x, pdf)
Y = Normal('y', 0, 1)
assert variance(X) == variance(Y)
assert P(X > 0) == P(Y > 0)
Z = ContinuousRV(z, exp(-z), set=Interval(0, oo))
assert Z.pspace.domain.set == Interval(0, oo)
assert E(Z) == 1
assert P(Z > 5) == exp(-5)
raises(ValueError, lambda: ContinuousRV(z, exp(-z), set=Interval(0, 10)))
def test_arcsin():
a = Symbol("a", real=True)
b = Symbol("b", real=True)
X = Arcsin('x', a, b)
assert density(X)(x) == 1/(pi*sqrt((-x + b)*(x - a)))
assert cdf(X)(x) == Piecewise((0, a > x),
(2*asin(sqrt((-a + x)/(-a + b)))/pi, b >= x),
(1, True))
assert pspace(X).domain.set == Interval(a, b)
def test_benini():
alpha = Symbol("alpha", positive=True)
beta = Symbol("beta", positive=True)
sigma = Symbol("sigma", positive=True)
X = Benini('x', alpha, beta, sigma)
assert density(X)(x) == ((alpha/x + 2*beta*log(x/sigma)/x)
*exp(-alpha*log(x/sigma) - beta*log(x/sigma)**2))
assert pspace(X).domain.set == Interval(sigma, oo)
raises(NotImplementedError, lambda: moment_generating_function(X))
alpha = Symbol("alpha", nonpositive=True)
raises(ValueError, lambda: Benini('x', alpha, beta, sigma))
beta = Symbol("beta", nonpositive=True)
raises(ValueError, lambda: Benini('x', alpha, beta, sigma))
alpha = Symbol("alpha", positive=True)
raises(ValueError, lambda: Benini('x', alpha, beta, sigma))
beta = Symbol("beta", positive=True)
sigma = Symbol("sigma", nonpositive=True)
raises(ValueError, lambda: Benini('x', alpha, beta, sigma))
def test_beta():
a, b = symbols('alpha beta', positive=True)
B = Beta('x', a, b)
assert pspace(B).domain.set == Interval(0, 1)
assert characteristic_function(B)(x) == hyper((a,), (a + b,), I*x)
assert density(B)(x) == x**(a - 1)*(1 - x)**(b - 1)/beta(a, b)
assert simplify(E(B)) == a / (a + b)
assert simplify(variance(B)) == a*b / (a**3 + 3*a**2*b + a**2 + 3*a*b**2 + 2*a*b + b**3 + b**2)
# Full symbolic solution is too much, test with numeric version
a, b = 1, 2
B = Beta('x', a, b)
assert expand_func(E(B)) == a / S(a + b)
assert expand_func(variance(B)) == (a*b) / S((a + b)**2 * (a + b + 1))
assert median(B) == FiniteSet(1 - 1/sqrt(2))
def test_beta_noncentral():
a, b = symbols('a b', positive=True)
c = Symbol('c', nonnegative=True)
_k = Dummy('k')
X = BetaNoncentral('x', a, b, c)
assert pspace(X).domain.set == Interval(0, 1)
dens = density(X)
z = Symbol('z')
res = Sum( z**(_k + a - 1)*(c/2)**_k*(1 - z)**(b - 1)*exp(-c/2)/
(beta(_k + a, b)*factorial(_k)), (_k, 0, oo))
assert dens(z).dummy_eq(res)
# BetaCentral should not raise if the assumptions
# on the symbols can not be determined
a, b, c = symbols('a b c')
assert BetaNoncentral('x', a, b, c)
a = Symbol('a', positive=False, real=True)
raises(ValueError, lambda: BetaNoncentral('x', a, b, c))
a = Symbol('a', positive=True)
b = Symbol('b', positive=False, real=True)
raises(ValueError, lambda: BetaNoncentral('x', a, b, c))
a = Symbol('a', positive=True)
b = Symbol('b', positive=True)
c = Symbol('c', nonnegative=False, real=True)
raises(ValueError, lambda: BetaNoncentral('x', a, b, c))
def test_betaprime():
alpha = Symbol("alpha", positive=True)
betap = Symbol("beta", positive=True)
X = BetaPrime('x', alpha, betap)
assert density(X)(x) == x**(alpha - 1)*(x + 1)**(-alpha - betap)/beta(alpha, betap)
alpha = Symbol("alpha", nonpositive=True)
raises(ValueError, lambda: BetaPrime('x', alpha, betap))
alpha = Symbol("alpha", positive=True)
betap = Symbol("beta", nonpositive=True)
raises(ValueError, lambda: BetaPrime('x', alpha, betap))
X = BetaPrime('x', 1, 1)
assert median(X) == FiniteSet(1)
def test_BoundedPareto():
L, H = symbols('L, H', negative=True)
raises(ValueError, lambda: BoundedPareto('X', 1, L, H))
L, H = symbols('L, H', real=False)
raises(ValueError, lambda: BoundedPareto('X', 1, L, H))
L, H = symbols('L, H', positive=True)
raises(ValueError, lambda: BoundedPareto('X', -1, L, H))
X = BoundedPareto('X', 2, L, H)
assert X.pspace.domain.set == Interval(L, H)
assert density(X)(x) == 2*L**2/(x**3*(1 - L**2/H**2))
assert cdf(X)(x) == Piecewise((-H**2*L**2/(x**2*(H**2 - L**2)) \
+ H**2/(H**2 - L**2), L <= x), (0, True))
assert E(X).simplify() == 2*H*L/(H + L)
X = BoundedPareto('X', 1, 2, 4)
assert E(X).simplify() == log(16)
assert median(X) == FiniteSet(Rational(8, 3))
assert variance(X).simplify() == 8 - 16*log(2)**2
def test_cauchy():
x0 = Symbol("x0", real=True)
gamma = Symbol("gamma", positive=True)
p = Symbol("p", positive=True)
X = Cauchy('x', x0, gamma)
# Tests the characteristic function
assert characteristic_function(X)(x) == exp(-gamma*Abs(x) + I*x*x0)
raises(NotImplementedError, lambda: moment_generating_function(X))
assert density(X)(x) == 1/(pi*gamma*(1 + (x - x0)**2/gamma**2))
assert diff(cdf(X)(x), x) == density(X)(x)
assert quantile(X)(p) == gamma*tan(pi*(p - S.Half)) + x0
x1 = Symbol("x1", real=False)
raises(ValueError, lambda: Cauchy('x', x1, gamma))
gamma = Symbol("gamma", nonpositive=True)
raises(ValueError, lambda: Cauchy('x', x0, gamma))
assert median(X) == FiniteSet(x0)
def test_chi():
from sympy import I
k = Symbol("k", integer=True)
X = Chi('x', k)
assert density(X)(x) == 2**(-k/2 + 1)*x**(k - 1)*exp(-x**2/2)/gamma(k/2)
# Tests the characteristic function
assert characteristic_function(X)(x) == sqrt(2)*I*x*gamma(k/2 + S(1)/2)*hyper((k/2 + S(1)/2,),
(S(3)/2,), -x**2/2)/gamma(k/2) + hyper((k/2,), (S(1)/2,), -x**2/2)
# Tests the moment generating function
assert moment_generating_function(X)(x) == sqrt(2)*x*gamma(k/2 + S(1)/2)*hyper((k/2 + S(1)/2,),
(S(3)/2,), x**2/2)/gamma(k/2) + hyper((k/2,), (S(1)/2,), x**2/2)
k = Symbol("k", integer=True, positive=False)
raises(ValueError, lambda: Chi('x', k))
k = Symbol("k", integer=False, positive=True)
raises(ValueError, lambda: Chi('x', k))
def test_chi_noncentral():
k = Symbol("k", integer=True)
l = Symbol("l")
X = ChiNoncentral("x", k, l)
assert density(X)(x) == (x**k*l*(x*l)**(-k/2)*
exp(-x**2/2 - l**2/2)*besseli(k/2 - 1, x*l))
k = Symbol("k", integer=True, positive=False)
raises(ValueError, lambda: ChiNoncentral('x', k, l))
k = Symbol("k", integer=True, positive=True)
l = Symbol("l", nonpositive=True)
raises(ValueError, lambda: ChiNoncentral('x', k, l))
k = Symbol("k", integer=False)
l = Symbol("l", positive=True)
raises(ValueError, lambda: ChiNoncentral('x', k, l))
def test_chi_squared():
k = Symbol("k", integer=True)
X = ChiSquared('x', k)
# Tests the characteristic function
assert characteristic_function(X)(x) == ((-2*I*x + 1)**(-k/2))
assert density(X)(x) == 2**(-k/2)*x**(k/2 - 1)*exp(-x/2)/gamma(k/2)
assert cdf(X)(x) == Piecewise((lowergamma(k/2, x/2)/gamma(k/2), x >= 0), (0, True))
assert E(X) == k
assert variance(X) == 2*k
X = ChiSquared('x', 15)
assert cdf(X)(3) == -14873*sqrt(6)*exp(Rational(-3, 2))/(5005*sqrt(pi)) + erf(sqrt(6)/2)
k = Symbol("k", integer=True, positive=False)
raises(ValueError, lambda: ChiSquared('x', k))
k = Symbol("k", integer=False, positive=True)
raises(ValueError, lambda: ChiSquared('x', k))
def test_dagum():
p = Symbol("p", positive=True)
b = Symbol("b", positive=True)
a = Symbol("a", positive=True)
X = Dagum('x', p, a, b)
assert density(X)(x) == a*p*(x/b)**(a*p)*((x/b)**a + 1)**(-p - 1)/x
assert cdf(X)(x) == Piecewise(((1 + (x/b)**(-a))**(-p), x >= 0),
(0, True))
p = Symbol("p", nonpositive=True)
raises(ValueError, lambda: Dagum('x', p, a, b))
p = Symbol("p", positive=True)
b = Symbol("b", nonpositive=True)
raises(ValueError, lambda: Dagum('x', p, a, b))
b = Symbol("b", positive=True)
a = Symbol("a", nonpositive=True)
raises(ValueError, lambda: Dagum('x', p, a, b))
X = Dagum('x', 1 , 1, 1)
assert median(X) == FiniteSet(1)
def test_erlang():
k = Symbol("k", integer=True, positive=True)
l = Symbol("l", positive=True)
X = Erlang("x", k, l)
assert density(X)(x) == x**(k - 1)*l**k*exp(-x*l)/gamma(k)
assert cdf(X)(x) == Piecewise((lowergamma(k, l*x)/gamma(k), x > 0),
(0, True))
def test_exgaussian():
m, z = symbols("m, z")
s, l = symbols("s, l", positive=True)
X = ExGaussian("x", m, s, l)
assert density(X)(z) == l*exp(l*(l*s**2 + 2*m - 2*z)/2) *\
erfc(sqrt(2)*(l*s**2 + m - z)/(2*s))/2
# Note: actual_output simplifies to expected_output.
# Ideally cdf(X)(z) would return expected_output
# expected_output = (erf(sqrt(2)*(l*s**2 + m - z)/(2*s)) - 1)*exp(l*(l*s**2 + 2*m - 2*z)/2)/2 - erf(sqrt(2)*(m - z)/(2*s))/2 + S.Half
u = l*(z - m)
v = l*s
GaussianCDF1 = cdf(Normal('x', 0, v))(u)
GaussianCDF2 = cdf(Normal('x', v**2, v))(u)
actual_output = GaussianCDF1 - exp(-u + (v**2/2) + log(GaussianCDF2))
assert cdf(X)(z) == actual_output
# assert simplify(actual_output) == expected_output
assert variance(X).expand() == s**2 + l**(-2)
assert skewness(X).expand() == 2/(l**3*s**2*sqrt(s**2 + l**(-2)) + l *
sqrt(s**2 + l**(-2)))
def test_exponential():
rate = Symbol('lambda', positive=True)
X = Exponential('x', rate)
p = Symbol("p", positive=True, real=True, finite=True)
assert E(X) == 1/rate
assert variance(X) == 1/rate**2
assert skewness(X) == 2
assert skewness(X) == smoment(X, 3)
assert kurtosis(X) == 9
assert kurtosis(X) == smoment(X, 4)
assert smoment(2*X, 4) == smoment(X, 4)
assert moment(X, 3) == 3*2*1/rate**3
assert P(X > 0) is S.One
assert P(X > 1) == exp(-rate)
assert P(X > 10) == exp(-10*rate)
assert quantile(X)(p) == -log(1-p)/rate
assert where(X <= 1).set == Interval(0, 1)
Y = Exponential('y', 1)
assert median(Y) == FiniteSet(log(2))
#Test issue 9970
z = Dummy('z')
assert P(X > z) == exp(-z*rate)
assert P(X < z) == 0
#Test issue 10076 (Distribution with interval(0,oo))
x = Symbol('x')
_z = Dummy('_z')
b = SingleContinuousPSpace(x, ExponentialDistribution(2))
expected1 = Integral(2*exp(-2*_z), (_z, 3, oo))
assert b.probability(x > 3, evaluate=False).dummy_eq(expected1) is True
expected2 = Integral(2*exp(-2*_z), (_z, 0, 4))
assert b.probability(x < 4, evaluate=False).dummy_eq(expected2) is True
Y = Exponential('y', 2*rate)
assert coskewness(X, X, X) == skewness(X)
assert coskewness(X, Y + rate*X, Y + 2*rate*X) == \
4/(sqrt(1 + 1/(4*rate**2))*sqrt(4 + 1/(4*rate**2)))
assert coskewness(X + 2*Y, Y + X, Y + 2*X, X > 3) == \
sqrt(170)*Rational(9, 85)
def test_exponential_power():
mu = Symbol('mu')
z = Symbol('z')
alpha = Symbol('alpha', positive=True)
beta = Symbol('beta', positive=True)
X = ExponentialPower('x', mu, alpha, beta)
assert density(X)(z) == beta*exp(-(Abs(mu - z)/alpha)
** beta)/(2*alpha*gamma(1/beta))
assert cdf(X)(z) == S.Half + lowergamma(1/beta,
(Abs(mu - z)/alpha)**beta)*sign(-mu + z)/\
(2*gamma(1/beta))
def test_f_distribution():
d1 = Symbol("d1", positive=True)
d2 = Symbol("d2", positive=True)
X = FDistribution("x", d1, d2)
assert density(X)(x) == (d2**(d2/2)*sqrt((d1*x)**d1*(d1*x + d2)**(-d1 - d2))
/(x*beta(d1/2, d2/2)))
raises(NotImplementedError, lambda: moment_generating_function(X))
d1 = Symbol("d1", nonpositive=True)
raises(ValueError, lambda: FDistribution('x', d1, d1))
d1 = Symbol("d1", positive=True, integer=False)
raises(ValueError, lambda: FDistribution('x', d1, d1))
d1 = Symbol("d1", positive=True)
d2 = Symbol("d2", nonpositive=True)
raises(ValueError, lambda: FDistribution('x', d1, d2))
d2 = Symbol("d2", positive=True, integer=False)
raises(ValueError, lambda: FDistribution('x', d1, d2))
def test_fisher_z():
d1 = Symbol("d1", positive=True)
d2 = Symbol("d2", positive=True)
X = FisherZ("x", d1, d2)
assert density(X)(x) == (2*d1**(d1/2)*d2**(d2/2)*(d1*exp(2*x) + d2)
**(-d1/2 - d2/2)*exp(d1*x)/beta(d1/2, d2/2))
def test_frechet():
a = Symbol("a", positive=True)
s = Symbol("s", positive=True)
m = Symbol("m", real=True)
X = Frechet("x", a, s=s, m=m)
assert density(X)(x) == a*((x - m)/s)**(-a - 1)*exp(-((x - m)/s)**(-a))/s
assert cdf(X)(x) == Piecewise((exp(-((-m + x)/s)**(-a)), m <= x), (0, True))
@slow
def test_gamma():
k = Symbol("k", positive=True)
theta = Symbol("theta", positive=True)
X = Gamma('x', k, theta)
# Tests characteristic function
assert characteristic_function(X)(x) == ((-I*theta*x + 1)**(-k))
assert density(X)(x) == x**(k - 1)*theta**(-k)*exp(-x/theta)/gamma(k)
assert cdf(X, meijerg=True)(z) == Piecewise(
(-k*lowergamma(k, 0)/gamma(k + 1) +
k*lowergamma(k, z/theta)/gamma(k + 1), z >= 0),
(0, True))
# assert simplify(variance(X)) == k*theta**2 # handled numerically below
assert E(X) == moment(X, 1)
k, theta = symbols('k theta', positive=True)
X = Gamma('x', k, theta)
assert E(X) == k*theta
assert variance(X) == k*theta**2
assert skewness(X).expand() == 2/sqrt(k)
assert kurtosis(X).expand() == 3 + 6/k
Y = Gamma('y', 2*k, 3*theta)
assert coskewness(X, theta*X + Y, k*X + Y).simplify() == \
2*531441**(-k)*sqrt(k)*theta*(3*3**(12*k) - 2*531441**k) \
/(sqrt(k**2 + 18)*sqrt(theta**2 + 18))
def test_gamma_inverse():
a = Symbol("a", positive=True)
b = Symbol("b", positive=True)
X = GammaInverse("x", a, b)
assert density(X)(x) == x**(-a - 1)*b**a*exp(-b/x)/gamma(a)
assert cdf(X)(x) == Piecewise((uppergamma(a, b/x)/gamma(a), x > 0), (0, True))
assert characteristic_function(X)(x) == 2 * (-I*b*x)**(a/2) \
* besselk(a, 2*sqrt(b)*sqrt(-I*x))/gamma(a)
raises(NotImplementedError, lambda: moment_generating_function(X))
def test_sampling_gamma_inverse():
scipy = import_module('scipy')
if not scipy:
skip('Scipy not installed. Abort tests for sampling of gamma inverse.')
X = GammaInverse("x", 1, 1)
with ignore_warnings(UserWarning):
assert next(sample(X)) in X.pspace.domain.set
def test_gompertz():
b = Symbol("b", positive=True)
eta = Symbol("eta", positive=True)
X = Gompertz("x", b, eta)
assert density(X)(x) == b*eta*exp(eta)*exp(b*x)*exp(-eta*exp(b*x))
assert cdf(X)(x) == 1 - exp(eta)*exp(-eta*exp(b*x))
assert diff(cdf(X)(x), x) == density(X)(x)
def test_gumbel():
beta = Symbol("beta", positive=True)
mu = Symbol("mu")
x = Symbol("x")
y = Symbol("y")
X = Gumbel("x", beta, mu)
Y = Gumbel("y", beta, mu, minimum=True)
assert density(X)(x).expand() == \
exp(mu/beta)*exp(-x/beta)*exp(-exp(mu/beta)*exp(-x/beta))/beta
assert density(Y)(y).expand() == \
exp(-mu/beta)*exp(y/beta)*exp(-exp(-mu/beta)*exp(y/beta))/beta
assert cdf(X)(x).expand() == \
exp(-exp(mu/beta)*exp(-x/beta))
assert characteristic_function(X)(x) == exp(I*mu*x)*gamma(-I*beta*x + 1)
def test_kumaraswamy():
a = Symbol("a", positive=True)
b = Symbol("b", positive=True)
X = Kumaraswamy("x", a, b)
assert density(X)(x) == x**(a - 1)*a*b*(-x**a + 1)**(b - 1)
assert cdf(X)(x) == Piecewise((0, x < 0),
(-(-x**a + 1)**b + 1, x <= 1),
(1, True))
def test_laplace():
mu = Symbol("mu")
b = Symbol("b", positive=True)
X = Laplace('x', mu, b)
#Tests characteristic_function
assert characteristic_function(X)(x) == (exp(I*mu*x)/(b**2*x**2 + 1))
assert density(X)(x) == exp(-Abs(x - mu)/b)/(2*b)
assert cdf(X)(x) == Piecewise((exp((-mu + x)/b)/2, mu > x),
(-exp((mu - x)/b)/2 + 1, True))
X = Laplace('x', [1, 2], [[1, 0], [0, 1]])
assert isinstance(pspace(X).distribution, MultivariateLaplaceDistribution)
def test_levy():
mu = Symbol("mu", real=True)
c = Symbol("c", positive=True)
X = Levy('x', mu, c)
assert X.pspace.domain.set == Interval(mu, oo)
assert density(X)(x) == sqrt(c/(2*pi))*exp(-c/(2*(x - mu)))/((x - mu)**(S.One + S.Half))
assert cdf(X)(x) == erfc(sqrt(c/(2*(x - mu))))
raises(NotImplementedError, lambda: moment_generating_function(X))
mu = Symbol("mu", real=False)
raises(ValueError, lambda: Levy('x',mu,c))
c = Symbol("c", nonpositive=True)
raises(ValueError, lambda: Levy('x',mu,c))
mu = Symbol("mu", real=True)
raises(ValueError, lambda: Levy('x',mu,c))
def test_logistic():
mu = Symbol("mu", real=True)
s = Symbol("s", positive=True)
p = Symbol("p", positive=True)
X = Logistic('x', mu, s)
#Tests characteristics_function
assert characteristic_function(X)(x) == \
(Piecewise((pi*s*x*exp(I*mu*x)/sinh(pi*s*x), Ne(x, 0)), (1, True)))
assert density(X)(x) == exp((-x + mu)/s)/(s*(exp((-x + mu)/s) + 1)**2)
assert cdf(X)(x) == 1/(exp((mu - x)/s) + 1)
assert quantile(X)(p) == mu - s*log(-S.One + 1/p)
def test_loglogistic():
a, b = symbols('a b')
assert LogLogistic('x', a, b)
a = Symbol('a', negative=True)
b = Symbol('b', positive=True)
raises(ValueError, lambda: LogLogistic('x', a, b))
a = Symbol('a', positive=True)
b = Symbol('b', negative=True)
raises(ValueError, lambda: LogLogistic('x', a, b))
a, b, z, p = symbols('a b z p', positive=True)
X = LogLogistic('x', a, b)
assert density(X)(z) == b*(z/a)**(b - 1)/(a*((z/a)**b + 1)**2)
assert cdf(X)(z) == 1/(1 + (z/a)**(-b))
assert quantile(X)(p) == a*(p/(1 - p))**(1/b)
# Expectation
assert E(X) == Piecewise((S.NaN, b <= 1), (pi*a/(b*sin(pi/b)), True))
b = symbols('b', prime=True) # b > 1
X = LogLogistic('x', a, b)
assert E(X) == pi*a/(b*sin(pi/b))
X = LogLogistic('x', 1, 2)
assert median(X) == FiniteSet(1)
def test_lognormal():
mean = Symbol('mu', real=True)
std = Symbol('sigma', positive=True)
X = LogNormal('x', mean, std)
# The sympy integrator can't do this too well
#assert E(X) == exp(mean+std**2/2)
#assert variance(X) == (exp(std**2)-1) * exp(2*mean + std**2)
# Right now, only density function and sampling works
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
with ignore_warnings(UserWarning):
for i in range(3):
X = LogNormal('x', i, 1)
assert next(sample(X)) in X.pspace.domain.set
size = 5
with ignore_warnings(UserWarning):
samps = next(sample(X, size=size))
for samp in samps:
assert samp in X.pspace.domain.set
# The sympy integrator can't do this too well
#assert E(X) ==
raises(NotImplementedError, lambda: moment_generating_function(X))
mu = Symbol("mu", real=True)
sigma = Symbol("sigma", positive=True)
X = LogNormal('x', mu, sigma)
assert density(X)(x) == (sqrt(2)*exp(-(-mu + log(x))**2
/(2*sigma**2))/(2*x*sqrt(pi)*sigma))
# Tests cdf
assert cdf(X)(x) == Piecewise(
(erf(sqrt(2)*(-mu + log(x))/(2*sigma))/2
+ S(1)/2, x > 0), (0, True))
X = LogNormal('x', 0, 1) # Mean 0, standard deviation 1
assert density(X)(x) == sqrt(2)*exp(-log(x)**2/2)/(2*x*sqrt(pi))
def test_Lomax():
a, l = symbols('a, l', negative=True)
raises(ValueError, lambda: Lomax('X', a , l))
a, l = symbols('a, l', real=False)
raises(ValueError, lambda: Lomax('X', a , l))
a, l = symbols('a, l', positive=True)
X = Lomax('X', a, l)
assert X.pspace.domain.set == Interval(0, oo)
assert density(X)(x) == a*(1 + x/l)**(-a - 1)/l
assert cdf(X)(x) == Piecewise((1 - (1 + x/l)**(-a), x >= 0), (0, True))
a = 3
X = Lomax('X', a, l)
assert E(X) == l/2
assert median(X) == FiniteSet(l*(-1 + 2**Rational(1, 3)))
assert variance(X) == 3*l**2/4
def test_maxwell():
a = Symbol("a", positive=True)
X = Maxwell('x', a)
assert density(X)(x) == (sqrt(2)*x**2*exp(-x**2/(2*a**2))/
(sqrt(pi)*a**3))
assert E(X) == 2*sqrt(2)*a/sqrt(pi)
assert variance(X) == -8*a**2/pi + 3*a**2
assert cdf(X)(x) == erf(sqrt(2)*x/(2*a)) - sqrt(2)*x*exp(-x**2/(2*a**2))/(sqrt(pi)*a)
assert diff(cdf(X)(x), x) == density(X)(x)
def test_Moyal():
mu = Symbol('mu',real=False)
sigma = Symbol('sigma', real=True, positive=True)
raises(ValueError, lambda: Moyal('M',mu, sigma))
mu = Symbol('mu', real=True)
sigma = Symbol('sigma', real=True, negative=True)
raises(ValueError, lambda: Moyal('M',mu, sigma))
sigma = Symbol('sigma', real=True, positive=True)
M = Moyal('M', mu, sigma)
assert density(M)(z) == sqrt(2)*exp(-exp((mu - z)/sigma)/2
- (-mu + z)/(2*sigma))/(2*sqrt(pi)*sigma)
assert cdf(M)(z).simplify() == 1 - erf(sqrt(2)*exp((mu - z)/(2*sigma))/2)
assert characteristic_function(M)(z) == 2**(-I*sigma*z)*exp(I*mu*z) \
*gamma(-I*sigma*z + Rational(1, 2))/sqrt(pi)
assert E(M) == mu + EulerGamma*sigma + sigma*log(2)
assert moment_generating_function(M)(z) == 2**(-sigma*z)*exp(mu*z) \
*gamma(-sigma*z + Rational(1, 2))/sqrt(pi)
def test_nakagami():
mu = Symbol("mu", positive=True)
omega = Symbol("omega", positive=True)
X = Nakagami('x', mu, omega)
assert density(X)(x) == (2*x**(2*mu - 1)*mu**mu*omega**(-mu)
*exp(-x**2*mu/omega)/gamma(mu))
assert simplify(E(X)) == (sqrt(mu)*sqrt(omega)
*gamma(mu + S.Half)/gamma(mu + 1))
assert simplify(variance(X)) == (
omega - omega*gamma(mu + S.Half)**2/(gamma(mu)*gamma(mu + 1)))
assert cdf(X)(x) == Piecewise(
(lowergamma(mu, mu*x**2/omega)/gamma(mu), x > 0),
(0, True))
X = Nakagami('x',1 ,1)
assert median(X) == FiniteSet(sqrt(log(2)))
def test_gaussian_inverse():
# test for symbolic parameters
a, b = symbols('a b')
assert GaussianInverse('x', a, b)
# Inverse Gaussian distribution is also known as Wald distribution
# `GaussianInverse` can also be referred by the name `Wald`
a, b, z = symbols('a b z')
X = Wald('x', a, b)
assert density(X)(z) == sqrt(2)*sqrt(b/z**3)*exp(-b*(-a + z)**2/(2*a**2*z))/(2*sqrt(pi))
a, b = symbols('a b', positive=True)
z = Symbol('z', positive=True)
X = GaussianInverse('x', a, b)
assert density(X)(z) == sqrt(2)*sqrt(b)*sqrt(z**(-3))*exp(-b*(-a + z)**2/(2*a**2*z))/(2*sqrt(pi))
assert E(X) == a
assert variance(X).expand() == a**3/b
assert cdf(X)(z) == (S.Half - erf(sqrt(2)*sqrt(b)*(1 + z/a)/(2*sqrt(z)))/2)*exp(2*b/a) +\
erf(sqrt(2)*sqrt(b)*(-1 + z/a)/(2*sqrt(z)))/2 + S.Half
a = symbols('a', nonpositive=True)
raises(ValueError, lambda: GaussianInverse('x', a, b))
a = symbols('a', positive=True)
b = symbols('b', nonpositive=True)
raises(ValueError, lambda: GaussianInverse('x', a, b))
def test_sampling_gaussian_inverse():
scipy = import_module('scipy')
if not scipy:
skip('Scipy not installed. Abort tests for sampling of Gaussian inverse.')
X = GaussianInverse("x", 1, 1)
with ignore_warnings(UserWarning):
assert next(sample(X, library='scipy')) in X.pspace.domain.set
def test_pareto():
xm, beta = symbols('xm beta', positive=True)
alpha = beta + 5
X = Pareto('x', xm, alpha)
dens = density(X)
#Tests cdf function
assert cdf(X)(x) == \
Piecewise((-x**(-beta - 5)*xm**(beta + 5) + 1, x >= xm), (0, True))
#Tests characteristic_function
assert characteristic_function(X)(x) == \
((-I*x*xm)**(beta + 5)*(beta + 5)*uppergamma(-beta - 5, -I*x*xm))
assert dens(x) == x**(-(alpha + 1))*xm**(alpha)*(alpha)
assert simplify(E(X)) == alpha*xm/(alpha-1)
# computation of taylor series for MGF still too slow
#assert simplify(variance(X)) == xm**2*alpha / ((alpha-1)**2*(alpha-2))
def test_pareto_numeric():
xm, beta = 3, 2
alpha = beta + 5
X = Pareto('x', xm, alpha)
assert E(X) == alpha*xm/S(alpha - 1)
assert variance(X) == xm**2*alpha / S(((alpha - 1)**2*(alpha - 2)))
assert median(X) == FiniteSet(3*2**Rational(1, 7))
# Skewness tests too slow. Try shortcutting function?
def test_PowerFunction():
alpha = Symbol("alpha", nonpositive=True)
a, b = symbols('a, b', real=True)
raises (ValueError, lambda: PowerFunction('x', alpha, a, b))
a, b = symbols('a, b', real=False)
raises (ValueError, lambda: PowerFunction('x', alpha, a, b))
alpha = Symbol("alpha", positive=True)
a, b = symbols('a, b', real=True)
raises (ValueError, lambda: PowerFunction('x', alpha, 5, 2))
X = PowerFunction('X', 2, a, b)
assert density(X)(z) == (-2*a + 2*z)/(-a + b)**2
assert cdf(X)(z) == Piecewise((a**2/(a**2 - 2*a*b + b**2) -
2*a*z/(a**2 - 2*a*b + b**2) + z**2/(a**2 - 2*a*b + b**2), a <= z), (0, True))
X = PowerFunction('X', 2, 0, 1)
assert density(X)(z) == 2*z
assert cdf(X)(z) == Piecewise((z**2, z >= 0), (0,True))
assert E(X) == Rational(2,3)
assert P(X < 0) == 0
assert P(X < 1) == 1
assert median(X) == FiniteSet(1/sqrt(2))
def test_raised_cosine():
mu = Symbol("mu", real=True)
s = Symbol("s", positive=True)
X = RaisedCosine("x", mu, s)
assert pspace(X).domain.set == Interval(mu - s, mu + s)
#Tests characteristics_function
assert characteristic_function(X)(x) == \
Piecewise((exp(-I*pi*mu/s)/2, Eq(x, -pi/s)), (exp(I*pi*mu/s)/2, Eq(x, pi/s)), (pi**2*exp(I*mu*x)*sin(s*x)/(s*x*(-s**2*x**2 + pi**2)), True))
assert density(X)(x) == (Piecewise(((cos(pi*(x - mu)/s) + 1)/(2*s),
And(x <= mu + s, mu - s <= x)), (0, True)))
def test_rayleigh():
sigma = Symbol("sigma", positive=True)
X = Rayleigh('x', sigma)
#Tests characteristic_function
assert characteristic_function(X)(x) == (-sqrt(2)*sqrt(pi)*sigma*x*(erfi(sqrt(2)*sigma*x/2) - I)*exp(-sigma**2*x**2/2)/2 + 1)
assert density(X)(x) == x*exp(-x**2/(2*sigma**2))/sigma**2
assert E(X) == sqrt(2)*sqrt(pi)*sigma/2
assert variance(X) == -pi*sigma**2/2 + 2*sigma**2
assert cdf(X)(x) == 1 - exp(-x**2/(2*sigma**2))
assert diff(cdf(X)(x), x) == density(X)(x)
def test_reciprocal():
a = Symbol("a", real=True)
b = Symbol("b", real=True)
X = Reciprocal('x', a, b)
assert density(X)(x) == 1/(x*(-log(a) + log(b)))
assert cdf(X)(x) == Piecewise((log(a)/(log(a) - log(b)) - log(x)/(log(a) - log(b)), a <= x), (0, True))
X = Reciprocal('x', 5, 30)
assert E(X) == 25/(log(30) - log(5))
assert P(X < 4) == S.Zero
assert P(X < 20) == log(20) / (log(30) - log(5)) - log(5) / (log(30) - log(5))
assert cdf(X)(10) == log(10) / (log(30) - log(5)) - log(5) / (log(30) - log(5))
a = symbols('a', nonpositive=True)
raises(ValueError, lambda: Reciprocal('x', a, b))
a = symbols('a', positive=True)
b = symbols('b', positive=True)
raises(ValueError, lambda: Reciprocal('x', a + b, a))
def test_shiftedgompertz():
b = Symbol("b", positive=True)
eta = Symbol("eta", positive=True)
X = ShiftedGompertz("x", b, eta)
assert density(X)(x) == b*(eta*(1 - exp(-b*x)) + 1)*exp(-b*x)*exp(-eta*exp(-b*x))
def test_studentt():
nu = Symbol("nu", positive=True)
X = StudentT('x', nu)
assert density(X)(x) == (1 + x**2/nu)**(-nu/2 - S.Half)/(sqrt(nu)*beta(S.Half, nu/2))
assert cdf(X)(x) == S.Half + x*gamma(nu/2 + S.Half)*hyper((S.Half, nu/2 + S.Half),
(Rational(3, 2),), -x**2/nu)/(sqrt(pi)*sqrt(nu)*gamma(nu/2))
raises(NotImplementedError, lambda: moment_generating_function(X))
def test_trapezoidal():
a = Symbol("a", real=True)
b = Symbol("b", real=True)
c = Symbol("c", real=True)
d = Symbol("d", real=True)
X = Trapezoidal('x', a, b, c, d)
assert density(X)(x) == Piecewise(((-2*a + 2*x)/((-a + b)*(-a - b + c + d)), (a <= x) & (x < b)),
(2/(-a - b + c + d), (b <= x) & (x < c)),
((2*d - 2*x)/((-c + d)*(-a - b + c + d)), (c <= x) & (x <= d)),
(0, True))
X = Trapezoidal('x', 0, 1, 2, 3)
assert E(X) == Rational(3, 2)
assert variance(X) == Rational(5, 12)
assert P(X < 2) == Rational(3, 4)
assert median(X) == FiniteSet(Rational(3, 2))
def test_triangular():
a = Symbol("a")
b = Symbol("b")
c = Symbol("c")
X = Triangular('x', a, b, c)
assert pspace(X).domain.set == Interval(a, b)
assert str(density(X)(x)) == ("Piecewise(((-2*a + 2*x)/((-a + b)*(-a + c)), (a <= x) & (c > x)), "
"(2/(-a + b), Eq(c, x)), ((2*b - 2*x)/((-a + b)*(b - c)), (b >= x) & (c < x)), (0, True))")
#Tests moment_generating_function
assert moment_generating_function(X)(x).expand() == \
((-2*(-a + b)*exp(c*x) + 2*(-a + c)*exp(b*x) + 2*(b - c)*exp(a*x))/(x**2*(-a + b)*(-a + c)*(b - c))).expand()
assert str(characteristic_function(X)(x)) == \
'(2*(-a + b)*exp(I*c*x) - 2*(-a + c)*exp(I*b*x) - 2*(b - c)*exp(I*a*x))/(x**2*(-a + b)*(-a + c)*(b - c))'
def test_quadratic_u():
a = Symbol("a", real=True)
b = Symbol("b", real=True)
X = QuadraticU("x", a, b)
Y = QuadraticU("x", 1, 2)
assert pspace(X).domain.set == Interval(a, b)
# Tests _moment_generating_function
assert moment_generating_function(Y)(1) == -15*exp(2) + 27*exp(1)
assert moment_generating_function(Y)(2) == -9*exp(4)/2 + 21*exp(2)/2
assert characteristic_function(Y)(1) == 3*I*(-1 + 4*I)*exp(I*exp(2*I))
assert density(X)(x) == (Piecewise((12*(x - a/2 - b/2)**2/(-a + b)**3,
And(x <= b, a <= x)), (0, True)))
def test_uniform():
l = Symbol('l', real=True)
w = Symbol('w', positive=True)
X = Uniform('x', l, l + w)
assert E(X) == l + w/2
assert variance(X).expand() == w**2/12
# With numbers all is well
X = Uniform('x', 3, 5)
assert P(X < 3) == 0 and P(X > 5) == 0
assert P(X < 4) == P(X > 4) == S.Half
assert median(X) == FiniteSet(4)
z = Symbol('z')
p = density(X)(z)
assert p.subs(z, 3.7) == S.Half
assert p.subs(z, -1) == 0
assert p.subs(z, 6) == 0
c = cdf(X)
assert c(2) == 0 and c(3) == 0
assert c(Rational(7, 2)) == Rational(1, 4)
assert c(5) == 1 and c(6) == 1
@XFAIL
def test_uniform_P():
""" This stopped working because SingleContinuousPSpace.compute_density no
longer calls integrate on a DiracDelta but rather just solves directly.
integrate used to call UniformDistribution.expectation which special-cased
subsed out the Min and Max terms that Uniform produces
I decided to regress on this class for general cleanliness (and I suspect
speed) of the algorithm.
"""
l = Symbol('l', real=True)
w = Symbol('w', positive=True)
X = Uniform('x', l, l + w)
assert P(X < l) == 0 and P(X > l + w) == 0
def test_uniformsum():
n = Symbol("n", integer=True)
_k = Dummy("k")
x = Symbol("x")
X = UniformSum('x', n)
res = Sum((-1)**_k*(-_k + x)**(n - 1)*binomial(n, _k), (_k, 0, floor(x)))/factorial(n - 1)
assert density(X)(x).dummy_eq(res)
#Tests set functions
assert X.pspace.domain.set == Interval(0, n)
#Tests the characteristic_function
assert characteristic_function(X)(x) == (-I*(exp(I*x) - 1)/x)**n
#Tests the moment_generating_function
assert moment_generating_function(X)(x) == ((exp(x) - 1)/x)**n
def test_von_mises():
mu = Symbol("mu")
k = Symbol("k", positive=True)
X = VonMises("x", mu, k)
assert density(X)(x) == exp(k*cos(x - mu))/(2*pi*besseli(0, k))
def test_weibull():
a, b = symbols('a b', positive=True)
# FIXME: simplify(E(X)) seems to hang without extended_positive=True
# On a Linux machine this had a rapid memory leak...
# a, b = symbols('a b', positive=True)
X = Weibull('x', a, b)
assert E(X).expand() == a * gamma(1 + 1/b)
assert variance(X).expand() == (a**2 * gamma(1 + 2/b) - E(X)**2).expand()
assert simplify(skewness(X)) == (2*gamma(1 + 1/b)**3 - 3*gamma(1 + 1/b)*gamma(1 + 2/b) + gamma(1 + 3/b))/(-gamma(1 + 1/b)**2 + gamma(1 + 2/b))**Rational(3, 2)
assert simplify(kurtosis(X)) == (-3*gamma(1 + 1/b)**4 +\
6*gamma(1 + 1/b)**2*gamma(1 + 2/b) - 4*gamma(1 + 1/b)*gamma(1 + 3/b) + gamma(1 + 4/b))/(gamma(1 + 1/b)**2 - gamma(1 + 2/b))**2
def test_weibull_numeric():
# Test for integers and rationals
a = 1
bvals = [S.Half, 1, Rational(3, 2), 5]
for b in bvals:
X = Weibull('x', a, b)
assert simplify(E(X)) == expand_func(a * gamma(1 + 1/S(b)))
assert simplify(variance(X)) == simplify(
a**2 * gamma(1 + 2/S(b)) - E(X)**2)
# Not testing Skew... it's slow with int/frac values > 3/2
def test_wignersemicircle():
R = Symbol("R", positive=True)
X = WignerSemicircle('x', R)
assert pspace(X).domain.set == Interval(-R, R)
assert density(X)(x) == 2*sqrt(-x**2 + R**2)/(pi*R**2)
assert E(X) == 0
#Tests ChiNoncentralDistribution
assert characteristic_function(X)(x) == \
Piecewise((2*besselj(1, R*x)/(R*x), Ne(x, 0)), (1, True))
def test_prefab_sampling():
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests')
N = Normal('X', 0, 1)
L = LogNormal('L', 0, 1)
E = Exponential('Ex', 1)
P = Pareto('P', 1, 3)
W = Weibull('W', 1, 1)
U = Uniform('U', 0, 1)
B = Beta('B', 2, 5)
G = Gamma('G', 1, 3)
variables = [N, L, E, P, W, U, B, G]
niter = 10
size = 5
with ignore_warnings(UserWarning):
for var in variables:
for i in range(niter):
assert next(sample(var)) in var.pspace.domain.set
samps = next(sample(var, size=size))
for samp in samps:
assert samp in var.pspace.domain.set
def test_input_value_assertions():
a, b = symbols('a b')
p, q = symbols('p q', positive=True)
m, n = symbols('m n', positive=False, real=True)
raises(ValueError, lambda: Normal('x', 3, 0))
raises(ValueError, lambda: Normal('x', m, n))
Normal('X', a, p) # No error raised
raises(ValueError, lambda: Exponential('x', m))
Exponential('Ex', p) # No error raised
for fn in [Pareto, Weibull, Beta, Gamma]:
raises(ValueError, lambda: fn('x', m, p))
raises(ValueError, lambda: fn('x', p, n))
fn('x', p, q) # No error raised
def test_unevaluated():
X = Normal('x', 0, 1)
assert str(E(X, evaluate=False)) == ("Integral(sqrt(2)*x*exp(-x**2/2)/"
"(2*sqrt(pi)), (x, -oo, oo))")
assert str(E(X + 1, evaluate=False)) == ("Integral(sqrt(2)*x*exp(-x**2/2)/"
"(2*sqrt(pi)), (x, -oo, oo)) + 1")
assert str(P(X > 0, evaluate=False)) == ("Integral(sqrt(2)*exp(-_z**2/2)/"
"(2*sqrt(pi)), (_z, 0, oo))")
assert P(X > 0, X**2 < 1, evaluate=False) == S.Half
def test_probability_unevaluated():
T = Normal('T', 30, 3)
assert type(P(T > 33, evaluate=False)) == Integral
def test_density_unevaluated():
X = Normal('X', 0, 1)
Y = Normal('Y', 0, 2)
assert isinstance(density(X+Y, evaluate=False)(z), Integral)
def test_NormalDistribution():
nd = NormalDistribution(0, 1)
x = Symbol('x')
assert nd.cdf(x) == erf(sqrt(2)*x/2)/2 + S.Half
assert nd.expectation(1, x) == 1
assert nd.expectation(x, x) == 0
assert nd.expectation(x**2, x) == 1
#Test issue 10076
a = SingleContinuousPSpace(x, NormalDistribution(2, 4))
_z = Dummy('_z')
expected1 = Integral(sqrt(2)*exp(-(_z - 2)**2/32)/(8*sqrt(pi)),(_z, -oo, 1))
assert a.probability(x < 1, evaluate=False).dummy_eq(expected1) is True
expected2 = Integral(sqrt(2)*exp(-(_z - 2)**2/32)/(8*sqrt(pi)),(_z, 1, oo))
assert a.probability(x > 1, evaluate=False).dummy_eq(expected2) is True
b = SingleContinuousPSpace(x, NormalDistribution(1, 9))
expected3 = Integral(sqrt(2)*exp(-(_z - 1)**2/162)/(18*sqrt(pi)),(_z, 6, oo))
assert b.probability(x > 6, evaluate=False).dummy_eq(expected3) is True
expected4 = Integral(sqrt(2)*exp(-(_z - 1)**2/162)/(18*sqrt(pi)),(_z, -oo, 6))
assert b.probability(x < 6, evaluate=False).dummy_eq(expected4) is True
def test_random_parameters():
mu = Normal('mu', 2, 3)
meas = Normal('T', mu, 1)
assert density(meas, evaluate=False)(z)
assert isinstance(pspace(meas), JointPSpace)
X = Normal('x', [1, 2], [[1, 0], [0, 1]])
assert isinstance(pspace(X).distribution, MultivariateNormalDistribution)
#assert density(meas, evaluate=False)(z) == Integral(mu.pspace.pdf *
# meas.pspace.pdf, (mu.symbol, -oo, oo)).subs(meas.symbol, z)
def test_random_parameters_given():
mu = Normal('mu', 2, 3)
meas = Normal('T', mu, 1)
assert given(meas, Eq(mu, 5)) == Normal('T', 5, 1)
def test_conjugate_priors():
mu = Normal('mu', 2, 3)
x = Normal('x', mu, 1)
assert isinstance(simplify(density(mu, Eq(x, y), evaluate=False)(z)),
Mul)
def test_difficult_univariate():
""" Since using solve in place of deltaintegrate we're able to perform
substantially more complex density computations on single continuous random
variables """
x = Normal('x', 0, 1)
assert density(x**3)
assert density(exp(x**2))
assert density(log(x))
def test_issue_10003():
X = Exponential('x', 3)
G = Gamma('g', 1, 2)
assert P(X < -1) is S.Zero
assert P(G < -1) is S.Zero
@slow
def test_precomputed_cdf():
x = symbols("x", real=True)
mu = symbols("mu", real=True)
sigma, xm, alpha = symbols("sigma xm alpha", positive=True)
n = symbols("n", integer=True, positive=True)
distribs = [
Normal("X", mu, sigma),
Pareto("P", xm, alpha),
ChiSquared("C", n),
Exponential("E", sigma),
# LogNormal("L", mu, sigma),
]
for X in distribs:
compdiff = cdf(X)(x) - simplify(X.pspace.density.compute_cdf()(x))
compdiff = simplify(compdiff.rewrite(erfc))
assert compdiff == 0
@slow
def test_precomputed_characteristic_functions():
import mpmath
def test_cf(dist, support_lower_limit, support_upper_limit):
pdf = density(dist)
t = Symbol('t')
# first function is the hardcoded CF of the distribution
cf1 = lambdify([t], characteristic_function(dist)(t), 'mpmath')
# second function is the Fourier transform of the density function
f = lambdify([x, t], pdf(x)*exp(I*x*t), 'mpmath')
cf2 = lambda t: mpmath.quad(lambda x: f(x, t), [support_lower_limit, support_upper_limit], maxdegree=10)
# compare the two functions at various points
for test_point in [2, 5, 8, 11]:
n1 = cf1(test_point)
n2 = cf2(test_point)
assert abs(re(n1) - re(n2)) < 1e-12
assert abs(im(n1) - im(n2)) < 1e-12
test_cf(Beta('b', 1, 2), 0, 1)
test_cf(Chi('c', 3), 0, mpmath.inf)
test_cf(ChiSquared('c', 2), 0, mpmath.inf)
test_cf(Exponential('e', 6), 0, mpmath.inf)
test_cf(Logistic('l', 1, 2), -mpmath.inf, mpmath.inf)
test_cf(Normal('n', -1, 5), -mpmath.inf, mpmath.inf)
test_cf(RaisedCosine('r', 3, 1), 2, 4)
test_cf(Rayleigh('r', 0.5), 0, mpmath.inf)
test_cf(Uniform('u', -1, 1), -1, 1)
test_cf(WignerSemicircle('w', 3), -3, 3)
def test_long_precomputed_cdf():
x = symbols("x", real=True)
distribs = [
Arcsin("A", -5, 9),
Dagum("D", 4, 10, 3),
Erlang("E", 14, 5),
Frechet("F", 2, 6, -3),
Gamma("G", 2, 7),
GammaInverse("GI", 3, 5),
Kumaraswamy("K", 6, 8),
Laplace("LA", -5, 4),
Logistic("L", -6, 7),
Nakagami("N", 2, 7),
StudentT("S", 4)
]
for distr in distribs:
for _ in range(5):
assert tn(diff(cdf(distr)(x), x), density(distr)(x), x, a=0, b=0, c=1, d=0)
US = UniformSum("US", 5)
pdf01 = density(US)(x).subs(floor(x), 0).doit() # pdf on (0, 1)
cdf01 = cdf(US, evaluate=False)(x).subs(floor(x), 0).doit() # cdf on (0, 1)
assert tn(diff(cdf01, x), pdf01, x, a=0, b=0, c=1, d=0)
def test_issue_13324():
X = Uniform('X', 0, 1)
assert E(X, X > S.Half) == Rational(3, 4)
assert E(X, X > 0) == S.Half
def test_FiniteSet_prob():
E = Exponential('E', 3)
N = Normal('N', 5, 7)
assert P(Eq(E, 1)) is S.Zero
assert P(Eq(N, 2)) is S.Zero
assert P(Eq(N, x)) is S.Zero
def test_prob_neq():
E = Exponential('E', 4)
X = ChiSquared('X', 4)
assert P(Ne(E, 2)) == 1
assert P(Ne(X, 4)) == 1
assert P(Ne(X, 4)) == 1
assert P(Ne(X, 5)) == 1
assert P(Ne(E, x)) == 1
def test_union():
N = Normal('N', 3, 2)
assert simplify(P(N**2 - N > 2)) == \
-erf(sqrt(2))/2 - erfc(sqrt(2)/4)/2 + Rational(3, 2)
assert simplify(P(N**2 - 4 > 0)) == \
-erf(5*sqrt(2)/4)/2 - erfc(sqrt(2)/4)/2 + Rational(3, 2)
def test_Or():
N = Normal('N', 0, 1)
assert simplify(P(Or(N > 2, N < 1))) == \
-erf(sqrt(2))/2 - erfc(sqrt(2)/2)/2 + Rational(3, 2)
assert P(Or(N < 0, N < 1)) == P(N < 1)
assert P(Or(N > 0, N < 0)) == 1
def test_conditional_eq():
E = Exponential('E', 1)
assert P(Eq(E, 1), Eq(E, 1)) == 1
assert P(Eq(E, 1), Eq(E, 2)) == 0
assert P(E > 1, Eq(E, 2)) == 1
assert P(E < 1, Eq(E, 2)) == 0
def test_ContinuousDistributionHandmade():
x = Symbol('x')
z = Dummy('z')
dens = Lambda(x, Piecewise((S.Half, (0<=x)&(x<1)), (0, (x>=1)&(x<2)),
(S.Half, (x>=2)&(x<3)), (0, True)))
dens = ContinuousDistributionHandmade(dens, set=Interval(0, 3))
space = SingleContinuousPSpace(z, dens)
assert dens.pdf == Lambda(x, Piecewise((1/2, (x >= 0) & (x < 1)),
(0, (x >= 1) & (x < 2)), (1/2, (x >= 2) & (x < 3)), (0, True)))
assert median(space.value) == Interval(1, 2)
assert E(space.value) == Rational(3, 2)
assert variance(space.value) == Rational(13, 12)
def test_sample_numpy():
distribs_numpy = [
Beta("B", 1, 1),
Normal("N", 0, 1),
Gamma("G", 2, 7),
Exponential("E", 2),
LogNormal("LN", 0, 1),
Pareto("P", 1, 1),
ChiSquared("CS", 2),
Uniform("U", 0, 1)
]
size = 3
numpy = import_module('numpy')
if not numpy:
skip('Numpy is not installed. Abort tests for _sample_numpy.')
else:
with ignore_warnings(UserWarning):
for X in distribs_numpy:
samps = next(sample(X, size=size, library='numpy'))
for sam in samps:
assert sam in X.pspace.domain.set
raises(NotImplementedError,
lambda: next(sample(Chi("C", 1), library='numpy')))
raises(NotImplementedError,
lambda: Chi("C", 1).pspace.distribution.sample(library='tensorflow'))
def test_sample_scipy():
distribs_scipy = [
Beta("B", 1, 1),
BetaPrime("BP", 1, 1),
Cauchy("C", 1, 1),
Chi("C", 1),
Normal("N", 0, 1),
Gamma("G", 2, 7),
GammaInverse("GI", 1, 1),
GaussianInverse("GUI", 1, 1),
Exponential("E", 2),
LogNormal("LN", 0, 1),
Pareto("P", 1, 1),
StudentT("S", 2),
ChiSquared("CS", 2),
Uniform("U", 0, 1)
]
size = 3
numsamples = 5
scipy = import_module('scipy')
if not scipy:
skip('Scipy is not installed. Abort tests for _sample_scipy.')
else:
with ignore_warnings(UserWarning):
g_sample = list(sample(Gamma("G", 2, 7), size=size, numsamples=numsamples))
assert len(g_sample) == numsamples
for X in distribs_scipy:
samps = next(sample(X, size=size, library='scipy'))
samps2 = next(sample(X, size=(2, 2), library='scipy'))
for sam in samps:
assert sam in X.pspace.domain.set
for i in range(2):
for j in range(2):
assert samps2[i][j] in X.pspace.domain.set
def test_sample_pymc3():
distribs_pymc3 = [
Beta("B", 1, 1),
Cauchy("C", 1, 1),
Normal("N", 0, 1),
Gamma("G", 2, 7),
GaussianInverse("GI", 1, 1),
Exponential("E", 2),
LogNormal("LN", 0, 1),
Pareto("P", 1, 1),
ChiSquared("CS", 2),
Uniform("U", 0, 1)
]
size = 3
pymc3 = import_module('pymc3')
if not pymc3:
skip('PyMC3 is not installed. Abort tests for _sample_pymc3.')
else:
with ignore_warnings(UserWarning):
for X in distribs_pymc3:
samps = next(sample(X, size=size, library='pymc3'))
for sam in samps:
assert sam in X.pspace.domain.set
raises(NotImplementedError,
lambda: next(sample(Chi("C", 1), library='pymc3')))
def test_issue_16318():
#test compute_expectation function of the SingleContinuousDomain
N = SingleContinuousDomain(x, Interval(0, 1))
raises (ValueError, lambda: SingleContinuousDomain.compute_expectation(N, x+1, {x, y}))
|
b94e4ca4e9ff4b3c995d8ac98d92f682ae47a778cdaf6afda169628f6ea4aaed | from sympy import sin, cos, exp, E, series, oo, S, Derivative, O, Integral, \
Function, log, sqrt, Symbol, Subs, pi, symbols, atan, LambertW, Rational
from sympy.abc import x, y, n, k
from sympy.testing.pytest import raises
from sympy.series.gruntz import calculate_series
def test_sin():
e1 = sin(x).series(x, 0)
e2 = series(sin(x), x, 0)
assert e1 == e2
def test_cos():
e1 = cos(x).series(x, 0)
e2 = series(cos(x), x, 0)
assert e1 == e2
def test_exp():
e1 = exp(x).series(x, 0)
e2 = series(exp(x), x, 0)
assert e1 == e2
def test_exp2():
e1 = exp(cos(x)).series(x, 0)
e2 = series(exp(cos(x)), x, 0)
assert e1 == e2
def test_issue_5223():
assert series(1, x) == 1
assert next(S.Zero.lseries(x)) == 0
assert cos(x).series() == cos(x).series(x)
raises(ValueError, lambda: cos(x + y).series())
raises(ValueError, lambda: x.series(dir=""))
assert (cos(x).series(x, 1) -
cos(x + 1).series(x).subs(x, x - 1)).removeO() == 0
e = cos(x).series(x, 1, n=None)
assert [next(e) for i in range(2)] == [cos(1), -((x - 1)*sin(1))]
e = cos(x).series(x, 1, n=None, dir='-')
assert [next(e) for i in range(2)] == [cos(1), (1 - x)*sin(1)]
# the following test is exact so no need for x -> x - 1 replacement
assert abs(x).series(x, 1, dir='-') == x
assert exp(x).series(x, 1, dir='-', n=3).removeO() == \
E - E*(-x + 1) + E*(-x + 1)**2/2
D = Derivative
assert D(x**2 + x**3*y**2, x, 2, y, 1).series(x).doit() == 12*x*y
assert next(D(cos(x), x).lseries()) == D(1, x)
assert D(
exp(x), x).series(n=3) == D(1, x) + D(x, x) + D(x**2/2, x) + D(x**3/6, x) + O(x**3)
assert Integral(x, (x, 1, 3), (y, 1, x)).series(x) == -4 + 4*x
assert (1 + x + O(x**2)).getn() == 2
assert (1 + x).getn() is None
assert ((1/sin(x))**oo).series() is oo
logx = Symbol('logx')
assert ((sin(x))**y).nseries(x, n=1, logx=logx) == \
exp(y*logx) + O(x*exp(y*logx), x)
assert sin(1/x).series(x, oo, n=5) == 1/x - 1/(6*x**3) + O(x**(-5), (x, oo))
assert abs(x).series(x, oo, n=5, dir='+') == x
assert abs(x).series(x, -oo, n=5, dir='-') == -x
assert abs(-x).series(x, oo, n=5, dir='+') == x
assert abs(-x).series(x, -oo, n=5, dir='-') == -x
assert exp(x*log(x)).series(n=3) == \
1 + x*log(x) + x**2*log(x)**2/2 + O(x**3*log(x)**3)
# XXX is this right? If not, fix "ngot > n" handling in expr.
p = Symbol('p', positive=True)
assert exp(sqrt(p)**3*log(p)).series(n=3) == \
1 + p**S('3/2')*log(p) + O(p**3*log(p)**3)
assert exp(sin(x)*log(x)).series(n=2) == 1 + x*log(x) + O(x**2*log(x)**2)
def test_issue_11313():
assert Integral(cos(x), x).series(x) == sin(x).series(x)
assert Derivative(sin(x), x).series(x, n=3).doit() == cos(x).series(x, n=3)
assert Derivative(x**3, x).as_leading_term(x) == 3*x**2
assert Derivative(x**3, y).as_leading_term(x) == 0
assert Derivative(sin(x), x).as_leading_term(x) == 1
assert Derivative(cos(x), x).as_leading_term(x) == -x
# This result is equivalent to zero, zero is not return because
# `Expr.series` doesn't currently detect an `x` in its `free_symbol`s.
assert Derivative(1, x).as_leading_term(x) == Derivative(1, x)
assert Derivative(exp(x), x).series(x).doit() == exp(x).series(x)
assert 1 + Integral(exp(x), x).series(x) == exp(x).series(x)
assert Derivative(log(x), x).series(x).doit() == (1/x).series(x)
assert Integral(log(x), x).series(x) == Integral(log(x), x).doit().series(x).removeO()
def test_series_of_Subs():
from sympy.abc import x, y, z
subs1 = Subs(sin(x), x, y)
subs2 = Subs(sin(x) * cos(z), x, y)
subs3 = Subs(sin(x * z), (x, z), (y, x))
assert subs1.series(x) == subs1
subs1_series = (Subs(x, x, y) + Subs(-x**3/6, x, y) +
Subs(x**5/120, x, y) + O(y**6))
assert subs1.series() == subs1_series
assert subs1.series(y) == subs1_series
assert subs1.series(z) == subs1
assert subs2.series(z) == (Subs(z**4*sin(x)/24, x, y) +
Subs(-z**2*sin(x)/2, x, y) + Subs(sin(x), x, y) + O(z**6))
assert subs3.series(x).doit() == subs3.doit().series(x)
assert subs3.series(z).doit() == sin(x*y)
raises(ValueError, lambda: Subs(x + 2*y, y, z).series())
assert Subs(x + y, y, z).series(x).doit() == x + z
def test_issue_3978():
f = Function('f')
assert f(x).series(x, 0, 3, dir='-') == \
f(0) + x*Subs(Derivative(f(x), x), x, 0) + \
x**2*Subs(Derivative(f(x), x, x), x, 0)/2 + O(x**3)
assert f(x).series(x, 0, 3) == \
f(0) + x*Subs(Derivative(f(x), x), x, 0) + \
x**2*Subs(Derivative(f(x), x, x), x, 0)/2 + O(x**3)
assert f(x**2).series(x, 0, 3) == \
f(0) + x**2*Subs(Derivative(f(x), x), x, 0) + O(x**3)
assert f(x**2+1).series(x, 0, 3) == \
f(1) + x**2*Subs(Derivative(f(x), x), x, 1) + O(x**3)
class TestF(Function):
pass
assert TestF(x).series(x, 0, 3) == TestF(0) + \
x*Subs(Derivative(TestF(x), x), x, 0) + \
x**2*Subs(Derivative(TestF(x), x, x), x, 0)/2 + O(x**3)
from sympy.series.acceleration import richardson, shanks
from sympy import Sum, Integer
def test_acceleration():
e = (1 + 1/n)**n
assert round(richardson(e, n, 10, 20).evalf(), 10) == round(E.evalf(), 10)
A = Sum(Integer(-1)**(k + 1) / k, (k, 1, n))
assert round(shanks(A, n, 25).evalf(), 4) == round(log(2).evalf(), 4)
assert round(shanks(A, n, 25, 5).evalf(), 10) == round(log(2).evalf(), 10)
def test_issue_5852():
assert series(1/cos(x/log(x)), x, 0) == 1 + x**2/(2*log(x)**2) + \
5*x**4/(24*log(x)**4) + O(x**6)
def test_issue_4583():
assert cos(1 + x + x**2).series(x, 0, 5) == cos(1) - x*sin(1) + \
x**2*(-sin(1) - cos(1)/2) + x**3*(-cos(1) + sin(1)/6) + \
x**4*(-11*cos(1)/24 + sin(1)/2) + O(x**5)
def test_issue_6318():
eq = (1/x)**Rational(2, 3)
assert (eq + 1).as_leading_term(x) == eq
def test_x_is_base_detection():
eq = (x**2)**Rational(2, 3)
assert eq.series() == x**Rational(4, 3)
def test_sin_power():
e = sin(x)**1.2
assert calculate_series(e, x) == x**1.2
def test_issue_7203():
assert series(cos(x), x, pi, 3) == \
-1 + (x - pi)**2/2 + O((x - pi)**3, (x, pi))
def test_exp_product_positive_factors():
a, b = symbols('a, b', positive=True)
x = a * b
assert series(exp(x), x, n=8) == 1 + a*b + a**2*b**2/2 + \
a**3*b**3/6 + a**4*b**4/24 + a**5*b**5/120 + a**6*b**6/720 + \
a**7*b**7/5040 + O(a**8*b**8, a, b)
def test_issue_8805():
assert series(1, n=8) == 1
def test_issue_10761():
assert series(1/(x**-2 + x**-3), x, 0) == x**3 - x**4 + x**5 + O(x**6)
def test_issue_14885():
assert series(x**Rational(-3, 2)*exp(x), x, 0) == (x**Rational(-3, 2) + 1/sqrt(x) +
sqrt(x)/2 + x**Rational(3, 2)/6 + x**Rational(5, 2)/24 + x**Rational(7, 2)/120 +
x**Rational(9, 2)/720 + x**Rational(11, 2)/5040 + O(x**6))
def test_issue_15539():
assert series(atan(x), x, -oo) == (-1/(5*x**5) + 1/(3*x**3) - 1/x - pi/2
+ O(x**(-6), (x, -oo)))
assert series(atan(x), x, oo) == (-1/(5*x**5) + 1/(3*x**3) - 1/x + pi/2
+ O(x**(-6), (x, oo)))
def test_issue_7259():
assert series(LambertW(x), x) == x - x**2 + 3*x**3/2 - 8*x**4/3 + 125*x**5/24 + O(x**6)
assert series(LambertW(x**2), x, n=8) == x**2 - x**4 + 3*x**6/2 + O(x**8)
assert series(LambertW(sin(x)), x, n=4) == x - x**2 + 4*x**3/3 + O(x**4)
def test_issue_11884():
assert cos(x).series(x, 1, n=1) == cos(1) + O(x - 1, (x, 1))
|
cd3e7c7a9fabb224a1a21a071f379c5f147206f0e786a325068e8359ae86c8ca | from sympy import (symbols, pi, Piecewise, sin, cos, sinc, Rational, S,
oo, fourier_series, Add, log, exp, tan)
from sympy.series.fourier import FourierSeries
from sympy.testing.pytest import raises
from sympy.core.cache import lru_cache
x, y, z = symbols('x y z')
# Don't declare these during import because they are slow
@lru_cache()
def _get_examples():
fo = fourier_series(x, (x, -pi, pi))
fe = fourier_series(x**2, (-pi, pi))
fp = fourier_series(Piecewise((0, x < 0), (pi, True)), (x, -pi, pi))
return fo, fe, fp
def test_FourierSeries():
fo, fe, fp = _get_examples()
assert fourier_series(1, (-pi, pi)) == 1
assert (Piecewise((0, x < 0), (pi, True)).
fourier_series((x, -pi, pi)).truncate()) == fp.truncate()
assert isinstance(fo, FourierSeries)
assert fo.function == x
assert fo.x == x
assert fo.period == (-pi, pi)
assert fo.term(3) == 2*sin(3*x) / 3
assert fe.term(3) == -4*cos(3*x) / 9
assert fp.term(3) == 2*sin(3*x) / 3
assert fo.as_leading_term(x) == 2*sin(x)
assert fe.as_leading_term(x) == pi**2 / 3
assert fp.as_leading_term(x) == pi / 2
assert fo.truncate() == 2*sin(x) - sin(2*x) + (2*sin(3*x) / 3)
assert fe.truncate() == -4*cos(x) + cos(2*x) + pi**2 / 3
assert fp.truncate() == 2*sin(x) + (2*sin(3*x) / 3) + pi / 2
fot = fo.truncate(n=None)
s = [0, 2*sin(x), -sin(2*x)]
for i, t in enumerate(fot):
if i == 3:
break
assert s[i] == t
def _check_iter(f, i):
for ind, t in enumerate(f):
assert t == f[ind]
if ind == i:
break
_check_iter(fo, 3)
_check_iter(fe, 3)
_check_iter(fp, 3)
assert fo.subs(x, x**2) == fo
raises(ValueError, lambda: fourier_series(x, (0, 1, 2)))
raises(ValueError, lambda: fourier_series(x, (x, 0, oo)))
raises(ValueError, lambda: fourier_series(x*y, (0, oo)))
def test_FourierSeries_2():
p = Piecewise((0, x < 0), (x, True))
f = fourier_series(p, (x, -2, 2))
assert f.term(3) == (2*sin(3*pi*x / 2) / (3*pi) -
4*cos(3*pi*x / 2) / (9*pi**2))
assert f.truncate() == (2*sin(pi*x / 2) / pi - sin(pi*x) / pi -
4*cos(pi*x / 2) / pi**2 + S.Half)
def test_square_wave():
"""Test if fourier_series approximates discontinuous function correctly."""
square_wave = Piecewise((1, x < pi), (-1, True))
s = fourier_series(square_wave, (x, 0, 2*pi))
assert s.truncate(3) == 4 / pi * sin(x) + 4 / (3 * pi) * sin(3 * x) + \
4 / (5 * pi) * sin(5 * x)
assert s.sigma_approximation(4) == 4 / pi * sin(x) * sinc(pi / 4) + \
4 / (3 * pi) * sin(3 * x) * sinc(3 * pi / 4)
def test_sawtooth_wave():
s = fourier_series(x, (x, 0, pi))
assert s.truncate(4) == \
pi/2 - sin(2*x) - sin(4*x)/2 - sin(6*x)/3
s = fourier_series(x, (x, 0, 1))
assert s.truncate(4) == \
S.Half - sin(2*pi*x)/pi - sin(4*pi*x)/(2*pi) - sin(6*pi*x)/(3*pi)
def test_FourierSeries__operations():
fo, fe, fp = _get_examples()
fes = fe.scale(-1).shift(pi**2)
assert fes.truncate() == 4*cos(x) - cos(2*x) + 2*pi**2 / 3
assert fp.shift(-pi/2).truncate() == (2*sin(x) + (2*sin(3*x) / 3) +
(2*sin(5*x) / 5))
fos = fo.scale(3)
assert fos.truncate() == 6*sin(x) - 3*sin(2*x) + 2*sin(3*x)
fx = fe.scalex(2).shiftx(1)
assert fx.truncate() == -4*cos(2*x + 2) + cos(4*x + 4) + pi**2 / 3
fl = fe.scalex(3).shift(-pi).scalex(2).shiftx(1).scale(4)
assert fl.truncate() == (-16*cos(6*x + 6) + 4*cos(12*x + 12) -
4*pi + 4*pi**2 / 3)
raises(ValueError, lambda: fo.shift(x))
raises(ValueError, lambda: fo.shiftx(sin(x)))
raises(ValueError, lambda: fo.scale(x*y))
raises(ValueError, lambda: fo.scalex(x**2))
def test_FourierSeries__neg():
fo, fe, fp = _get_examples()
assert (-fo).truncate() == -2*sin(x) + sin(2*x) - (2*sin(3*x) / 3)
assert (-fe).truncate() == +4*cos(x) - cos(2*x) - pi**2 / 3
def test_FourierSeries__add__sub():
fo, fe, fp = _get_examples()
assert fo + fo == fo.scale(2)
assert fo - fo == 0
assert -fe - fe == fe.scale(-2)
assert (fo + fe).truncate() == 2*sin(x) - sin(2*x) - 4*cos(x) + cos(2*x) \
+ pi**2 / 3
assert (fo - fe).truncate() == 2*sin(x) - sin(2*x) + 4*cos(x) - cos(2*x) \
- pi**2 / 3
assert isinstance(fo + 1, Add)
raises(ValueError, lambda: fo + fourier_series(x, (x, 0, 2)))
def test_FourierSeries_finite():
assert fourier_series(sin(x)).truncate(1) == sin(x)
# assert type(fourier_series(sin(x)*log(x))).truncate() == FourierSeries
# assert type(fourier_series(sin(x**2+6))).truncate() == FourierSeries
assert fourier_series(sin(x)*log(y)*exp(z),(x,pi,-pi)).truncate() == sin(x)*log(y)*exp(z)
assert fourier_series(sin(x)**6).truncate(oo) == -15*cos(2*x)/32 + 3*cos(4*x)/16 - cos(6*x)/32 \
+ Rational(5, 16)
assert fourier_series(sin(x) ** 6).truncate() == -15 * cos(2 * x) / 32 + 3 * cos(4 * x) / 16 \
+ Rational(5, 16)
assert fourier_series(sin(4*x+3) + cos(3*x+4)).truncate(oo) == -sin(4)*sin(3*x) + sin(4*x)*cos(3) \
+ cos(4)*cos(3*x) + sin(3)*cos(4*x)
assert fourier_series(sin(x)+cos(x)*tan(x)).truncate(oo) == 2*sin(x)
assert fourier_series(cos(pi*x), (x, -1, 1)).truncate(oo) == cos(pi*x)
assert fourier_series(cos(3*pi*x + 4) - sin(4*pi*x)*log(pi*y) , (x, -1, 1)).truncate(oo) == -log(pi*y)*sin(4*pi*x)\
- sin(4)*sin(3*pi*x) + cos(4)*cos(3*pi*x)
|
d4c902ac8fabb00d0a67e17f042b9f2d421aaef705e977a19094a53a982173ec | from itertools import product as cartes
from sympy import (
limit, exp, oo, log, sqrt, Limit, sin, floor, cos, ceiling,
atan, Abs, gamma, Symbol, S, pi, Integral, Rational, I,
tan, cot, integrate, Sum, sign, Function, subfactorial, symbols,
binomial, simplify, frac, Float, sec, zoo, fresnelc, fresnels,
acos, erfi, LambertW, factorial, Ei, EulerGamma)
from sympy.calculus.util import AccumBounds
from sympy.core.add import Add
from sympy.core.mul import Mul
from sympy.series.limits import heuristics
from sympy.series.order import Order
from sympy.testing.pytest import XFAIL, raises, nocache_fail
from sympy.abc import x, y, z, k
n = Symbol('n', integer=True, positive=True)
def test_basic1():
assert limit(x, x, oo) is oo
assert limit(x, x, -oo) is -oo
assert limit(-x, x, oo) is -oo
assert limit(x**2, x, -oo) is oo
assert limit(-x**2, x, oo) is -oo
assert limit(x*log(x), x, 0, dir="+") == 0
assert limit(1/x, x, oo) == 0
assert limit(exp(x), x, oo) is oo
assert limit(-exp(x), x, oo) is -oo
assert limit(exp(x)/x, x, oo) is oo
assert limit(1/x - exp(-x), x, oo) == 0
assert limit(x + 1/x, x, oo) is oo
assert limit(x - x**2, x, oo) is -oo
assert limit((1 + x)**(1 + sqrt(2)), x, 0) == 1
assert limit((1 + x)**oo, x, 0) is oo
assert limit((1 + x)**oo, x, 0, dir='-') == 0
assert limit((1 + x + y)**oo, x, 0, dir='-') == (1 + y)**(oo)
assert limit(y/x/log(x), x, 0) == -oo*sign(y)
assert limit(cos(x + y)/x, x, 0) == sign(cos(y))*oo
assert limit(gamma(1/x + 3), x, oo) == 2
assert limit(S.NaN, x, -oo) is S.NaN
assert limit(Order(2)*x, x, S.NaN) is S.NaN
assert limit(1/(x - 1), x, 1, dir="+") is oo
assert limit(1/(x - 1), x, 1, dir="-") is -oo
assert limit(1/(5 - x)**3, x, 5, dir="+") is -oo
assert limit(1/(5 - x)**3, x, 5, dir="-") is oo
assert limit(1/sin(x), x, pi, dir="+") is -oo
assert limit(1/sin(x), x, pi, dir="-") is oo
assert limit(1/cos(x), x, pi/2, dir="+") is -oo
assert limit(1/cos(x), x, pi/2, dir="-") is oo
assert limit(1/tan(x**3), x, (2*pi)**Rational(1, 3), dir="+") is oo
assert limit(1/tan(x**3), x, (2*pi)**Rational(1, 3), dir="-") is -oo
assert limit(1/cot(x)**3, x, (pi*Rational(3, 2)), dir="+") is -oo
assert limit(1/cot(x)**3, x, (pi*Rational(3, 2)), dir="-") is oo
# test bi-directional limits
assert limit(sin(x)/x, x, 0, dir="+-") == 1
assert limit(x**2, x, 0, dir="+-") == 0
assert limit(1/x**2, x, 0, dir="+-") is oo
# test failing bi-directional limits
assert limit(1/x, x, 0, dir="+-") is zoo
# approaching 0
# from dir="+"
assert limit(1 + 1/x, x, 0) is oo
# from dir='-'
# Add
assert limit(1 + 1/x, x, 0, dir='-') is -oo
# Pow
assert limit(x**(-2), x, 0, dir='-') is oo
assert limit(x**(-3), x, 0, dir='-') is -oo
assert limit(1/sqrt(x), x, 0, dir='-') == (-oo)*I
assert limit(x**2, x, 0, dir='-') == 0
assert limit(sqrt(x), x, 0, dir='-') == 0
assert limit(x**-pi, x, 0, dir='-') == oo*sign((-1)**(-pi))
assert limit((1 + cos(x))**oo, x, 0) is oo
def test_basic2():
assert limit(x**x, x, 0, dir="+") == 1
assert limit((exp(x) - 1)/x, x, 0) == 1
assert limit(1 + 1/x, x, oo) == 1
assert limit(-exp(1/x), x, oo) == -1
assert limit(x + exp(-x), x, oo) is oo
assert limit(x + exp(-x**2), x, oo) is oo
assert limit(x + exp(-exp(x)), x, oo) is oo
assert limit(13 + 1/x - exp(-x), x, oo) == 13
def test_basic3():
assert limit(1/x, x, 0, dir="+") is oo
assert limit(1/x, x, 0, dir="-") is -oo
def test_basic4():
assert limit(2*x + y*x, x, 0) == 0
assert limit(2*x + y*x, x, 1) == 2 + y
assert limit(2*x**8 + y*x**(-3), x, -2) == 512 - y/8
assert limit(sqrt(x + 1) - sqrt(x), x, oo) == 0
assert integrate(1/(x**3 + 1), (x, 0, oo)) == 2*pi*sqrt(3)/9
def test_basic5():
class my(Function):
@classmethod
def eval(cls, arg):
if arg is S.Infinity:
return S.NaN
assert limit(my(x), x, oo) == Limit(my(x), x, oo)
def test_issue_3885():
assert limit(x*y + x*z, z, 2) == x*(y + 2)
def test_Limit():
assert Limit(sin(x)/x, x, 0) != 1
assert Limit(sin(x)/x, x, 0).doit() == 1
assert Limit(x, x, 0, dir='+-').args == (x, x, 0, Symbol('+-'))
def test_floor():
assert limit(floor(x), x, -2, "+") == -2
assert limit(floor(x), x, -2, "-") == -3
assert limit(floor(x), x, -1, "+") == -1
assert limit(floor(x), x, -1, "-") == -2
assert limit(floor(x), x, 0, "+") == 0
assert limit(floor(x), x, 0, "-") == -1
assert limit(floor(x), x, 1, "+") == 1
assert limit(floor(x), x, 1, "-") == 0
assert limit(floor(x), x, 2, "+") == 2
assert limit(floor(x), x, 2, "-") == 1
assert limit(floor(x), x, 248, "+") == 248
assert limit(floor(x), x, 248, "-") == 247
def test_floor_requires_robust_assumptions():
assert limit(floor(sin(x)), x, 0, "+") == 0
assert limit(floor(sin(x)), x, 0, "-") == -1
assert limit(floor(cos(x)), x, 0, "+") == 0
assert limit(floor(cos(x)), x, 0, "-") == 0
assert limit(floor(5 + sin(x)), x, 0, "+") == 5
assert limit(floor(5 + sin(x)), x, 0, "-") == 4
assert limit(floor(5 + cos(x)), x, 0, "+") == 5
assert limit(floor(5 + cos(x)), x, 0, "-") == 5
def test_ceiling():
assert limit(ceiling(x), x, -2, "+") == -1
assert limit(ceiling(x), x, -2, "-") == -2
assert limit(ceiling(x), x, -1, "+") == 0
assert limit(ceiling(x), x, -1, "-") == -1
assert limit(ceiling(x), x, 0, "+") == 1
assert limit(ceiling(x), x, 0, "-") == 0
assert limit(ceiling(x), x, 1, "+") == 2
assert limit(ceiling(x), x, 1, "-") == 1
assert limit(ceiling(x), x, 2, "+") == 3
assert limit(ceiling(x), x, 2, "-") == 2
assert limit(ceiling(x), x, 248, "+") == 249
assert limit(ceiling(x), x, 248, "-") == 248
def test_ceiling_requires_robust_assumptions():
assert limit(ceiling(sin(x)), x, 0, "+") == 1
assert limit(ceiling(sin(x)), x, 0, "-") == 0
assert limit(ceiling(cos(x)), x, 0, "+") == 1
assert limit(ceiling(cos(x)), x, 0, "-") == 1
assert limit(ceiling(5 + sin(x)), x, 0, "+") == 6
assert limit(ceiling(5 + sin(x)), x, 0, "-") == 5
assert limit(ceiling(5 + cos(x)), x, 0, "+") == 6
assert limit(ceiling(5 + cos(x)), x, 0, "-") == 6
def test_atan():
x = Symbol("x", real=True)
assert limit(atan(x)*sin(1/x), x, 0) == 0
assert limit(atan(x) + sqrt(x + 1) - sqrt(x), x, oo) == pi/2
def test_abs():
assert limit(abs(x), x, 0) == 0
assert limit(abs(sin(x)), x, 0) == 0
assert limit(abs(cos(x)), x, 0) == 1
assert limit(abs(sin(x + 1)), x, 0) == sin(1)
def test_heuristic():
x = Symbol("x", real=True)
assert heuristics(sin(1/x) + atan(x), x, 0, '+') == AccumBounds(-1, 1)
assert limit(log(2 + sqrt(atan(x))*sqrt(sin(1/x))), x, 0) == log(2)
def test_issue_3871():
z = Symbol("z", positive=True)
f = -1/z*exp(-z*x)
assert limit(f, x, oo) == 0
assert f.limit(x, oo) == 0
def test_exponential():
n = Symbol('n')
x = Symbol('x', real=True)
assert limit((1 + x/n)**n, n, oo) == exp(x)
assert limit((1 + x/(2*n))**n, n, oo) == exp(x/2)
assert limit((1 + x/(2*n + 1))**n, n, oo) == exp(x/2)
assert limit(((x - 1)/(x + 1))**x, x, oo) == exp(-2)
assert limit(1 + (1 + 1/x)**x, x, oo) == 1 + S.Exp1
assert limit((2 + 6*x)**x/(6*x)**x, x, oo) == exp(S('1/3'))
@XFAIL
def test_exponential2():
n = Symbol('n')
assert limit((1 + x/(n + sin(n)))**n, n, oo) == exp(x)
def test_doit():
f = Integral(2 * x, x)
l = Limit(f, x, oo)
assert l.doit() is oo
def test_AccumBounds():
assert limit(sin(k) - sin(k + 1), k, oo) == AccumBounds(-2, 2)
assert limit(cos(k) - cos(k + 1) + 1, k, oo) == AccumBounds(-1, 3)
# not the exact bound
assert limit(sin(k) - sin(k)*cos(k), k, oo) == AccumBounds(-2, 2)
# test for issue #9934
t1 = Mul(S.Half, 1/(-1 + cos(1)), Add(AccumBounds(-3, 1), cos(1)))
assert limit(simplify(Sum(cos(n).rewrite(exp), (n, 0, k)).doit().rewrite(sin)), k, oo) == t1
t2 = Mul(S.Half, Add(AccumBounds(-2, 2), sin(1)), 1/(-cos(1) + 1))
assert limit(simplify(Sum(sin(n).rewrite(exp), (n, 0, k)).doit().rewrite(sin)), k, oo) == t2
assert limit(frac(x)**x, x, oo) == AccumBounds(0, oo)
assert limit(((sin(x) + 1)/2)**x, x, oo) == AccumBounds(0, oo)
# Possible improvement: AccumBounds(0, 1)
@XFAIL
def test_doit2():
f = Integral(2 * x, x)
l = Limit(f, x, oo)
# limit() breaks on the contained Integral.
assert l.doit(deep=False) == l
def test_issue_2929():
assert limit((x * exp(x))/(exp(x) - 1), x, -oo) == 0
def test_issue_3792():
assert limit((1 - cos(x))/x**2, x, S.Half) == 4 - 4*cos(S.Half)
assert limit(sin(sin(x + 1) + 1), x, 0) == sin(1 + sin(1))
assert limit(abs(sin(x + 1) + 1), x, 0) == 1 + sin(1)
def test_issue_4090():
assert limit(1/(x + 3), x, 2) == Rational(1, 5)
assert limit(1/(x + pi), x, 2) == S.One/(2 + pi)
assert limit(log(x)/(x**2 + 3), x, 2) == log(2)/7
assert limit(log(x)/(x**2 + pi), x, 2) == log(2)/(4 + pi)
def test_issue_4547():
assert limit(cot(x), x, 0, dir='+') is oo
assert limit(cot(x), x, pi/2, dir='+') == 0
def test_issue_5164():
assert limit(x**0.5, x, oo) == oo**0.5 is oo
assert limit(x**0.5, x, 16) == S(16)**0.5
assert limit(x**0.5, x, 0) == 0
assert limit(x**(-0.5), x, oo) == 0
assert limit(x**(-0.5), x, 4) == S(4)**(-0.5)
def test_issue_5183():
# using list(...) so py.test can recalculate values
tests = list(cartes([x, -x],
[-1, 1],
[2, 3, S.Half, Rational(2, 3)],
['-', '+']))
results = (oo, oo, -oo, oo, -oo*I, oo, -oo*(-1)**Rational(1, 3), oo,
0, 0, 0, 0, 0, 0, 0, 0,
oo, oo, oo, -oo, oo, -oo*I, oo, -oo*(-1)**Rational(1, 3),
0, 0, 0, 0, 0, 0, 0, 0)
assert len(tests) == len(results)
for i, (args, res) in enumerate(zip(tests, results)):
y, s, e, d = args
eq = y**(s*e)
try:
assert limit(eq, x, 0, dir=d) == res
except AssertionError:
if 0: # change to 1 if you want to see the failing tests
print()
print(i, res, eq, d, limit(eq, x, 0, dir=d))
else:
assert None
def test_issue_5184():
assert limit(sin(x)/x, x, oo) == 0
assert limit(atan(x), x, oo) == pi/2
assert limit(gamma(x), x, oo) is oo
assert limit(cos(x)/x, x, oo) == 0
assert limit(gamma(x), x, S.Half) == sqrt(pi)
r = Symbol('r', real=True)
assert limit(r*sin(1/r), r, 0) == 0
def test_issue_5229():
assert limit((1 + y)**(1/y) - S.Exp1, y, 0) == 0
def test_issue_4546():
# using list(...) so py.test can recalculate values
tests = list(cartes([cot, tan],
[-pi/2, 0, pi/2, pi, pi*Rational(3, 2)],
['-', '+']))
results = (0, 0, -oo, oo, 0, 0, -oo, oo, 0, 0,
oo, -oo, 0, 0, oo, -oo, 0, 0, oo, -oo)
assert len(tests) == len(results)
for i, (args, res) in enumerate(zip(tests, results)):
f, l, d = args
eq = f(x)
try:
assert limit(eq, x, l, dir=d) == res
except AssertionError:
if 0: # change to 1 if you want to see the failing tests
print()
print(i, res, eq, l, d, limit(eq, x, l, dir=d))
else:
assert None
def test_issue_3934():
assert limit((1 + x**log(3))**(1/x), x, 0) == 1
assert limit((5**(1/x) + 3**(1/x))**x, x, 0) == 5
def test_calculate_series():
# needs gruntz calculate_series to go to n = 32
assert limit(x**Rational(77, 3)/(1 + x**Rational(77, 3)), x, oo) == 1
# needs gruntz calculate_series to go to n = 128
assert limit(x**101.1/(1 + x**101.1), x, oo) == 1
def test_issue_5955():
assert limit((x**16)/(1 + x**16), x, oo) == 1
assert limit((x**100)/(1 + x**100), x, oo) == 1
assert limit((x**1885)/(1 + x**1885), x, oo) == 1
assert limit((x**1000/((x + 1)**1000 + exp(-x))), x, oo) == 1
def test_newissue():
assert limit(exp(1/sin(x))/exp(cot(x)), x, 0) == 1
def test_extended_real_line():
assert limit(x - oo, x, oo) is -oo
assert limit(oo - x, x, -oo) is oo
assert limit(x**2/(x - 5) - oo, x, oo) is -oo
assert limit(1/(x + sin(x)) - oo, x, 0) is -oo
assert limit(oo/x, x, oo) is oo
assert limit(x - oo + 1/x, x, oo) is -oo
assert limit(x - oo + 1/x, x, 0) is -oo
@XFAIL
def test_order_oo():
x = Symbol('x', positive=True)
assert Order(x)*oo != Order(1, x)
assert limit(oo/(x**2 - 4), x, oo) is oo
def test_issue_5436():
raises(NotImplementedError, lambda: limit(exp(x*y), x, oo))
raises(NotImplementedError, lambda: limit(exp(-x*y), x, oo))
def test_Limit_dir():
raises(TypeError, lambda: Limit(x, x, 0, dir=0))
raises(ValueError, lambda: Limit(x, x, 0, dir='0'))
def test_polynomial():
assert limit((x + 1)**1000/((x + 1)**1000 + 1), x, oo) == 1
assert limit((x + 1)**1000/((x + 1)**1000 + 1), x, -oo) == 1
def test_rational():
assert limit(1/y - (1/(y + x) + x/(y + x)/y)/z, x, oo) == (z - 1)/(y*z)
assert limit(1/y - (1/(y + x) + x/(y + x)/y)/z, x, -oo) == (z - 1)/(y*z)
def test_issue_5740():
assert limit(log(x)*z - log(2*x)*y, x, 0) == oo*sign(y - z)
def test_issue_6366():
n = Symbol('n', integer=True, positive=True)
r = (n + 1)*x**(n + 1)/(x**(n + 1) - 1) - x/(x - 1)
assert limit(r, x, 1) == n/2
def test_factorial():
from sympy import factorial, E
f = factorial(x)
assert limit(f, x, oo) is oo
assert limit(x/f, x, oo) == 0
# see Stirling's approximation:
# https://en.wikipedia.org/wiki/Stirling's_approximation
assert limit(f/(sqrt(2*pi*x)*(x/E)**x), x, oo) == 1
assert limit(f, x, -oo) == factorial(-oo)
assert limit(f, x, x**2) == factorial(x**2)
assert limit(f, x, -x**2) == factorial(-x**2)
def test_issue_6560():
e = (5*x**3/4 - x*Rational(3, 4) + (y*(3*x**2/2 - S.Half) +
35*x**4/8 - 15*x**2/4 + Rational(3, 8))/(2*(y + 1)))
assert limit(e, y, oo) == (5*x**3 + 3*x**2 - 3*x - 1)/4
@XFAIL
def test_issue_5172():
n = Symbol('n')
r = Symbol('r', positive=True)
c = Symbol('c')
p = Symbol('p', positive=True)
m = Symbol('m', negative=True)
expr = ((2*n*(n - r + 1)/(n + r*(n - r + 1)))**c +
(r - 1)*(n*(n - r + 2)/(n + r*(n - r + 1)))**c - n)/(n**c - n)
expr = expr.subs(c, c + 1)
raises(NotImplementedError, lambda: limit(expr, n, oo))
assert limit(expr.subs(c, m), n, oo) == 1
assert limit(expr.subs(c, p), n, oo).simplify() == \
(2**(p + 1) + r - 1)/(r + 1)**(p + 1)
def test_issue_7088():
a = Symbol('a')
assert limit(sqrt(x/(x + a)), x, oo) == 1
def test_issue_6364():
a = Symbol('a')
e = z/(1 - sqrt(1 + z)*sin(a)**2 - sqrt(1 - z)*cos(a)**2)
assert limit(e, z, 0).simplify() == 2/cos(2*a)
def test_issue_4099():
a = Symbol('a')
assert limit(a/x, x, 0) == oo*sign(a)
assert limit(-a/x, x, 0) == -oo*sign(a)
assert limit(-a*x, x, oo) == -oo*sign(a)
assert limit(a*x, x, oo) == oo*sign(a)
def test_issue_4503():
dx = Symbol('dx')
assert limit((sqrt(1 + exp(x + dx)) - sqrt(1 + exp(x)))/dx, dx, 0) == \
exp(x)/(2*sqrt(exp(x) + 1))
def test_issue_8481():
k = Symbol('k', integer=True, nonnegative=True)
lamda = Symbol('lamda', real=True, positive=True)
limit(lamda**k * exp(-lamda) / factorial(k), k, oo) == 0
def test_issue_8730():
assert limit(subfactorial(x), x, oo) is oo
def test_issue_9558():
assert limit(sin(x)**15, x, 0, '-') == 0
def test_issue_10801():
# make sure limits work with binomial
assert limit(16**k / (k * binomial(2*k, k)**2), k, oo) == pi
def test_issue_9041():
assert limit(factorial(n) / ((n/exp(1))**n * sqrt(2*pi*n)), n, oo) == 1
def test_issue_9205():
x, y, a = symbols('x, y, a')
assert Limit(x, x, a).free_symbols == {a}
assert Limit(x, x, a, '-').free_symbols == {a}
assert Limit(x + y, x + y, a).free_symbols == {a}
assert Limit(-x**2 + y, x**2, a).free_symbols == {y, a}
def test_issue_9471():
assert limit((((27**(log(n,3))))/n**3),n,oo) == 1
assert limit((((27**(log(n,3)+1)))/n**3),n,oo) == 27
def test_issue_11879():
assert simplify(limit(((x+y)**n-x**n)/y, y, 0)) == n*x**(n-1)
def test_limit_with_Float():
k = symbols("k")
assert limit(1.0 ** k, k, oo) == 1
assert limit(0.3*1.0**k, k, oo) == Float(0.3)
def test_issue_10610():
assert limit(3**x*3**(-x - 1)*(x + 1)**2/x**2, x, oo) == Rational(1, 3)
def test_issue_6599():
assert limit((n + cos(n))/n, n, oo) == 1
def test_issue_12555():
assert limit((3**x + 2* x**10) / (x**10 + exp(x)), x, -oo) == 2
assert limit((3**x + 2* x**10) / (x**10 + exp(x)), x, oo) is oo
def test_issue_13332():
assert limit(sqrt(30)*5**(-5*x - 1)*(46656*x)**x*(5*x + 2)**(5*x + 5*S.Half) *
(6*x + 2)**(-6*x - 5*S.Half), x, oo) == Rational(25, 36)
def test_issue_12564():
assert limit(x**2 + x*sin(x) + cos(x), x, -oo) is oo
assert limit(x**2 + x*sin(x) + cos(x), x, oo) is oo
assert limit(((x + cos(x))**2).expand(), x, oo) is oo
assert limit(((x + sin(x))**2).expand(), x, oo) is oo
assert limit(((x + cos(x))**2).expand(), x, -oo) is oo
assert limit(((x + sin(x))**2).expand(), x, -oo) is oo
def test_issue_14456():
raises(NotImplementedError, lambda: Limit(exp(x), x, zoo).doit())
raises(NotImplementedError, lambda: Limit(x**2/(x+1), x, zoo).doit())
def test_issue_14411():
assert limit(3*sec(4*pi*x - x/3), x, 3*pi/(24*pi - 2)) is -oo
def test_issue_13382():
assert limit(x*(((x + 1)**2 + 1)/(x**2 + 1) - 1), x, oo) == 2
def test_issue_13403():
assert limit(x*(-1 + (x + log(x + 1) + 1)/(x + log(x))), x ,oo) == 1
def test_issue_13416():
assert limit((-x**3*log(x)**3 + (x - 1)*(x + 1)**2*log(x + 1)**3)/(x**2*log(x)**3), x ,oo) == 1
def test_issue_13462():
assert limit(n**2*(2*n*(-(1 - 1/(2*n))**x + 1) - x - (-x**2/4 + x/4)/n), n, oo) == x*(x**2 - 3*x + 2)/24
def test_issue_14574():
assert limit(sqrt(x)*cos(x - x**2) / (x + 1), x, oo) == 0
def test_issue_10102():
assert limit(fresnels(x), x, oo) == S.Half
assert limit(3 + fresnels(x), x, oo) == 3 + S.Half
assert limit(5*fresnels(x), x, oo) == Rational(5, 2)
assert limit(fresnelc(x), x, oo) == S.Half
assert limit(fresnels(x), x, -oo) == Rational(-1, 2)
assert limit(4*fresnelc(x), x, -oo) == -2
def test_issue_14377():
raises(NotImplementedError, lambda: limit(exp(I*x)*sin(pi*x), x, oo))
def test_issue_15984():
assert limit((-x + log(exp(x) + 1))/x, x, oo, dir='-').doit() == 0
@nocache_fail
def test_issue_13575():
# This fails with infinite recursion when run without the cache:
result = limit(acos(erfi(x)), x, 1)
assert isinstance(result, Add)
re, im = result.evalf().as_real_imag()
assert abs(re) < 1e-12
assert abs(im - 1.08633774961570) < 1e-12
def test_issue_17325():
assert Limit(sin(x)/x, x, 0, dir="+-").doit() == 1
assert Limit(x**2, x, 0, dir="+-").doit() == 0
assert Limit(1/x**2, x, 0, dir="+-").doit() is oo
assert Limit(1/x, x, 0, dir="+-").doit() is zoo
def test_issue_10978():
assert LambertW(x).limit(x, 0) == 0
@XFAIL
def test_issue_14313_comment():
assert limit(floor(n/2), n, oo) is oo
@XFAIL
def test_issue_15323():
d = ((1 - 1/x)**x).diff(x)
assert limit(d, x, 1, dir='+') == 1
def test_issue_12571():
assert limit(-LambertW(-log(x))/log(x), x, 1) == 1
def test_issue_14590():
assert limit((x**3*((x + 1)/x)**x)/((x + 1)*(x + 2)*(x + 3)), x, oo) == exp(1)
def test_issue_14393():
a, b = symbols('a b')
assert limit((x**b - y**b)/(x**a - y**a), x, y) == b*y**(-a)*y**b/a
def test_issue_14556():
assert limit(factorial(n + 1)**(1/(n + 1)) - factorial(n)**(1/n), n, oo) == exp(-1)
def test_issue_14811():
assert limit(((1 + ((S(2)/3)**(x + 1)))**(2**x))/(2**((S(4)/3)**(x - 1))), x, oo) == oo
def test_issue_16722():
z = symbols('z', positive=True)
assert limit(binomial(n + z, n)*n**-z, n, oo) == 1/gamma(z + 1)
z = symbols('z', positive=True, integer=True)
assert limit(binomial(n + z, n)*n**-z, n, oo) == 1/gamma(z + 1)
def test_issue_17431():
assert limit(((n + 1) + 1) / (((n + 1) + 2) * factorial(n + 1)) *
(n + 2) * factorial(n) / (n + 1), n, oo) == 0
assert limit((n + 2)**2*factorial(n)/((n + 1)*(n + 3)*factorial(n + 1))
, n, oo) == 0
assert limit((n + 1) * factorial(n) / (n * factorial(n + 1)), n, oo) == 0
def test_issue_17671():
assert limit(Ei(-log(x)) - log(log(x))/x, x, 1) == EulerGamma
def test_issue_17792():
assert limit(factorial(n)/sqrt(n)*(exp(1)/n)**n, n, oo) == sqrt(2)*sqrt(pi)
def test_issue_18306():
assert limit(sin(sqrt(x))/sqrt(sin(x)), x, 0, '+') == 1
def test_issue_18378():
assert limit(log(exp(3*x) + x)/log(exp(x) + x**100), x, oo) == 3
def test_issue_18442():
assert limit(tan(x)**(2**(sqrt(pi))), x, oo, dir='-') == AccumBounds(-oo, oo)
def test_issue_18482():
assert limit((2*exp(3*x)/(exp(2*x) + 1))**(1/x), x, oo) == exp(1)
def test_issue_18501():
assert limit(Abs(log(x - 1)**3 - 1), x, 1, '+') == oo
def test_issue_18508():
assert limit(sin(x)/sqrt(1-cos(x)), x, 0) == sqrt(2)
assert limit(sin(x)/sqrt(1-cos(x)), x, 0, dir='+') == sqrt(2)
assert limit(sin(x)/sqrt(1-cos(x)), x, 0, dir='-') == -sqrt(2)
def test_issue_18992():
assert limit(n/(factorial(n)**(1/n)), n, oo) == exp(1)
def test_issue_18997():
assert limit(Abs(log(x)), x, 0) == oo
assert limit(Abs(log(Abs(x))), x, 0) == oo
def test_issue_19026():
x = Symbol('x', positive=True)
assert limit(Abs(log(x) + 1)/log(x), x, oo) == 1
def test_issue_19067():
x = Symbol('x')
assert limit(gamma(x)/(gamma(x - 1)*gamma(x + 2)), x, 0) == -1
def test_issue_13715():
n = Symbol('n')
p = Symbol('p', zero=True)
assert limit(n + p, n, 0) == p
def test_issue_15055():
assert limit(n**3*((-n - 1)*sin(1/n) + (n + 2)*sin(1/(n + 1)))/(-n + 1), n, oo) == 1
|
84f5ecfe6e8cbacc3e35a5999482ec45cef0a3efb07b242054c1526af4f0711b | from sympy import (Symbol, Rational, ln, exp, log, sqrt, E, O, pi, I, sinh,
sin, cosh, cos, tanh, coth, asinh, acosh, atanh, acoth, tan, cot, Integer,
PoleError, floor, ceiling, asin, symbols, limit, Piecewise, Eq, sign,
Derivative, S)
from sympy.abc import x, y, z
from sympy.testing.pytest import raises, XFAIL
def test_simple_1():
assert x.nseries(x, n=5) == x
assert y.nseries(x, n=5) == y
assert (1/(x*y)).nseries(y, n=5) == 1/(x*y)
assert Rational(3, 4).nseries(x, n=5) == Rational(3, 4)
assert x.nseries() == x
def test_mul_0():
assert (x*ln(x)).nseries(x, n=5) == x*ln(x)
def test_mul_1():
assert (x*ln(2 + x)).nseries(x, n=5) == x*log(2) + x**2/2 - x**3/8 + \
x**4/24 + O(x**5)
assert (x*ln(1 + x)).nseries(
x, n=5) == x**2 - x**3/2 + x**4/3 + O(x**5)
def test_pow_0():
assert (x**2).nseries(x, n=5) == x**2
assert (1/x).nseries(x, n=5) == 1/x
assert (1/x**2).nseries(x, n=5) == 1/x**2
assert (x**Rational(2, 3)).nseries(x, n=5) == (x**Rational(2, 3))
assert (sqrt(x)**3).nseries(x, n=5) == (sqrt(x)**3)
def test_pow_1():
assert ((1 + x)**2).nseries(x, n=5) == 1 + 2*x + x**2
def test_geometric_1():
assert (1/(1 - x)).nseries(x, n=5) == 1 + x + x**2 + x**3 + x**4 + O(x**5)
assert (x/(1 - x)).nseries(x, n=6) == x + x**2 + x**3 + x**4 + x**5 + O(x**6)
assert (x**3/(1 - x)).nseries(x, n=8) == x**3 + x**4 + x**5 + x**6 + \
x**7 + O(x**8)
def test_sqrt_1():
assert sqrt(1 + x).nseries(x, n=5) == 1 + x/2 - x**2/8 + x**3/16 - 5*x**4/128 + O(x**5)
def test_exp_1():
assert exp(x).nseries(x, n=5) == 1 + x + x**2/2 + x**3/6 + x**4/24 + O(x**5)
assert exp(x).nseries(x, n=12) == 1 + x + x**2/2 + x**3/6 + x**4/24 + x**5/120 + \
x**6/720 + x**7/5040 + x**8/40320 + x**9/362880 + x**10/3628800 + \
x**11/39916800 + O(x**12)
assert exp(1/x).nseries(x, n=5) == exp(1/x)
assert exp(1/(1 + x)).nseries(x, n=4) == \
(E*(1 - x - 13*x**3/6 + 3*x**2/2)).expand() + O(x**4)
assert exp(2 + x).nseries(x, n=5) == \
(exp(2)*(1 + x + x**2/2 + x**3/6 + x**4/24)).expand() + O(x**5)
def test_exp_sqrt_1():
assert exp(1 + sqrt(x)).nseries(x, n=3) == \
(exp(1)*(1 + sqrt(x) + x/2 + sqrt(x)*x/6)).expand() + O(sqrt(x)**3)
def test_power_x_x1():
assert (exp(x*ln(x))).nseries(x, n=4) == \
1 + x*log(x) + x**2*log(x)**2/2 + x**3*log(x)**3/6 + O(x**4*log(x)**4)
def test_power_x_x2():
assert (x**x).nseries(x, n=4) == \
1 + x*log(x) + x**2*log(x)**2/2 + x**3*log(x)**3/6 + O(x**4*log(x)**4)
def test_log_singular1():
assert log(1 + 1/x).nseries(x, n=5) == x - log(x) - x**2/2 + x**3/3 - \
x**4/4 + O(x**5)
def test_log_power1():
e = 1 / (1/x + x ** (log(3)/log(2)))
assert e.nseries(x, n=5) == x - x**(2 + log(3)/log(2)) + O(x**5)
def test_log_series():
l = Symbol('l')
e = 1/(1 - log(x))
assert e.nseries(x, n=5, logx=l) == 1/(1 - l)
def test_log2():
e = log(-1/x)
assert e.nseries(x, n=5) == -log(x) + log(-1)
def test_log3():
l = Symbol('l')
e = 1/log(-1/x)
assert e.nseries(x, n=4, logx=l) == 1/(-l + log(-1))
def test_series1():
e = sin(x)
assert e.nseries(x, 0, 0) != 0
assert e.nseries(x, 0, 0) == O(1, x)
assert e.nseries(x, 0, 1) == O(x, x)
assert e.nseries(x, 0, 2) == x + O(x**2, x)
assert e.nseries(x, 0, 3) == x + O(x**3, x)
assert e.nseries(x, 0, 4) == x - x**3/6 + O(x**4, x)
e = (exp(x) - 1)/x
assert e.nseries(x, 0, 3) == 1 + x/2 + x**2/6 + O(x**3)
assert x.nseries(x, 0, 2) == x
@XFAIL
def test_series1_failing():
assert x.nseries(x, 0, 0) == O(1, x)
assert x.nseries(x, 0, 1) == O(x, x)
def test_seriesbug1():
assert (1/x).nseries(x, 0, 3) == 1/x
assert (x + 1/x).nseries(x, 0, 3) == x + 1/x
def test_series2x():
assert ((x + 1)**(-2)).nseries(x, 0, 4) == 1 - 2*x + 3*x**2 - 4*x**3 + O(x**4, x)
assert ((x + 1)**(-1)).nseries(x, 0, 4) == 1 - x + x**2 - x**3 + O(x**4, x)
assert ((x + 1)**0).nseries(x, 0, 3) == 1
assert ((x + 1)**1).nseries(x, 0, 3) == 1 + x
assert ((x + 1)**2).nseries(x, 0, 3) == 1 + 2*x + x**2
assert ((x + 1)**3).nseries(
x, 0, 3) == 1 + 3*x + 3*x**2 + x**3 # 1+3*x+3*x**2+O(x**3)
assert (1/(1 + x)).nseries(x, 0, 4) == 1 - x + x**2 - x**3 + O(x**4, x)
assert (x + 3/(1 + 2*x)).nseries(x, 0, 4) == 3 - 5*x + 12*x**2 - 24*x**3 + O(x**4, x)
assert ((1/x + 1)**3).nseries(x, 0, 3) == 1 + x**(-3) + 3*x**(-2) + 3/x
assert (1/(1 + 1/x)).nseries(x, 0, 4) == x - x**2 + x**3 - O(x**4, x)
assert (1/(1 + 1/x**2)).nseries(x, 0, 6) == x**2 - x**4 + O(x**6, x)
def test_bug2(): # 1/log(0)*log(0) problem
w = Symbol("w")
e = (w**(-1) + w**(
-log(3)*log(2)**(-1)))**(-1)*(3*w**(-log(3)*log(2)**(-1)) + 2*w**(-1))
e = e.expand()
assert e.nseries(w, 0, 4).subs(w, 0) == 3
def test_exp():
e = (1 + x)**(1/x)
assert e.nseries(x, n=3) == exp(1) - x*exp(1)/2 + 11*exp(1)*x**2/24 + O(x**3)
def test_exp2():
w = Symbol("w")
e = w**(1 - log(x)/(log(2) + log(x)))
logw = Symbol("logw")
assert e.nseries(
w, 0, 1, logx=logw) == exp(logw - logw*log(x)/(log(2) + log(x)))
def test_bug3():
e = (2/x + 3/x**2)/(1/x + 1/x**2)
assert e.nseries(x, n=3) == 3 - x + x**2 + O(x**3)
def test_generalexponent():
p = 2
e = (2/x + 3/x**p)/(1/x + 1/x**p)
assert e.nseries(x, 0, 3) == 3 - x + x**2 + O(x**3)
p = S.Half
e = (2/x + 3/x**p)/(1/x + 1/x**p)
assert e.nseries(x, 0, 2) == 2 - x + sqrt(x) + x**(S(3)/2) + O(x**2)
e = 1 + sqrt(x)
assert e.nseries(x, 0, 4) == 1 + sqrt(x)
# more complicated example
def test_genexp_x():
e = 1/(1 + sqrt(x))
assert e.nseries(x, 0, 2) == \
1 + x - sqrt(x) - sqrt(x)**3 + O(x**2, x)
# more complicated example
def test_genexp_x2():
p = Rational(3, 2)
e = (2/x + 3/x**p)/(1/x + 1/x**p)
assert e.nseries(x, 0, 3) == 3 + x + x**2 - sqrt(x) - x**(S(3)/2) - x**(S(5)/2) + O(x**3)
def test_seriesbug2():
w = Symbol("w")
#simple case (1):
e = ((2*w)/w)**(1 + w)
assert e.nseries(w, 0, 1) == 2 + O(w, w)
assert e.nseries(w, 0, 1).subs(w, 0) == 2
def test_seriesbug2b():
w = Symbol("w")
#test sin
e = sin(2*w)/w
assert e.nseries(w, 0, 3) == 2 - 4*w**2/3 + O(w**3)
def test_seriesbug2d():
w = Symbol("w", real=True)
e = log(sin(2*w)/w)
assert e.series(w, n=5) == log(2) - 2*w**2/3 - 4*w**4/45 + O(w**5)
def test_seriesbug2c():
w = Symbol("w", real=True)
#more complicated case, but sin(x)~x, so the result is the same as in (1)
e = (sin(2*w)/w)**(1 + w)
assert e.series(w, 0, 1) == 2 + O(w)
assert e.series(w, 0, 3) == 2 + 2*w*log(2) + \
w**2*(Rational(-4, 3) + log(2)**2) + O(w**3)
assert e.series(w, 0, 2).subs(w, 0) == 2
def test_expbug4():
x = Symbol("x", real=True)
assert (log(
sin(2*x)/x)*(1 + x)).series(x, 0, 2) == log(2) + x*log(2) + O(x**2, x)
assert exp(
log(sin(2*x)/x)*(1 + x)).series(x, 0, 2) == 2 + 2*x*log(2) + O(x**2)
assert exp(log(2) + O(x)).nseries(x, 0, 2) == 2 + O(x)
assert ((2 + O(x))**(1 + x)).nseries(x, 0, 2) == 2 + O(x)
def test_logbug4():
assert log(2 + O(x)).nseries(x, 0, 2) == log(2) + O(x, x)
def test_expbug5():
assert exp(log(1 + x)/x).nseries(x, n=3) == exp(1) + -exp(1)*x/2 + 11*exp(1)*x**2/24 + O(x**3)
assert exp(O(x)).nseries(x, 0, 2) == 1 + O(x)
def test_sinsinbug():
assert sin(sin(x)).nseries(x, 0, 8) == x - x**3/3 + x**5/10 - 8*x**7/315 + O(x**8)
def test_issue_3258():
a = x/(exp(x) - 1)
assert a.nseries(x, 0, 5) == 1 - x/2 - x**4/720 + x**2/12 + O(x**5)
@XFAIL
def test_issue_3204():
x = Symbol("x", nonnegative=True)
f = sin(x**3)**Rational(1, 3)
assert f.nseries(x, 0, 17) == x - x**7/18 - x**13/3240 + O(x**17)
def test_issue_3224():
f = sqrt(1 - sqrt(y))
assert f.nseries(y, 0, 2) == 1 - sqrt(y)/2 - y/8 - sqrt(y)**3/16 + O(y**2)
def test_issue_3463():
from sympy import symbols
w, i = symbols('w,i')
r = log(5)/log(3)
p = w**(-1 + r)
e = 1/x*(-log(w**(1 + r)) + log(w + w**r))
e_ser = -r*log(w)/x + p/x - p**2/(2*x) + O(p**3)
assert e.nseries(w, n=3) == e_ser
def test_sin():
assert sin(8*x).nseries(x, n=4) == 8*x - 256*x**3/3 + O(x**4)
assert sin(x + y).nseries(x, n=1) == sin(y) + O(x)
assert sin(x + y).nseries(x, n=2) == sin(y) + cos(y)*x + O(x**2)
assert sin(x + y).nseries(x, n=5) == sin(y) + cos(y)*x - sin(y)*x**2/2 - \
cos(y)*x**3/6 + sin(y)*x**4/24 + O(x**5)
def test_issue_3515():
e = sin(8*x)/x
assert e.nseries(x, n=6) == 8 - 256*x**2/3 + 4096*x**4/15 + O(x**6)
def test_issue_3505():
e = sin(x)**(-4)*(sqrt(cos(x))*sin(x)**2 -
cos(x)**Rational(1, 3)*sin(x)**2)
assert e.nseries(x, n=9) == Rational(-1, 12) - 7*x**2/288 - \
43*x**4/10368 - 1123*x**6/2488320 + 377*x**8/29859840 + O(x**9)
def test_issue_3501():
a = Symbol("a")
e = x**(-2)*(x*sin(a + x) - x*sin(a))
assert e.nseries(x, n=6) == cos(a) - sin(a)*x/2 - cos(a)*x**2/6 + \
sin(a)*x**3/24 + O(x**4)
e = x**(-2)*(x*cos(a + x) - x*cos(a))
assert e.nseries(x, n=6) == -sin(a) - cos(a)*x/2 + sin(a)*x**2/6 + \
cos(a)*x**3/24 + O(x**4)
def test_issue_3502():
e = sin(5*x)/sin(2*x)
assert e.nseries(x, n=2) == Rational(5, 2) + O(x**2)
assert e.nseries(x, n=6) == \
Rational(5, 2) - 35*x**2/4 + 329*x**4/48 + O(x**6)
def test_issue_3503():
e = sin(2 + x)/(2 + x)
assert e.nseries(x, n=2) == sin(2)/2 + x*cos(2)/2 - x*sin(2)/4 + O(x**2)
def test_issue_3506():
e = (x + sin(3*x))**(-2)*(x*(x + sin(3*x)) - (x + sin(3*x))*sin(2*x))
assert e.nseries(x, n=7) == \
Rational(-1, 4) + 5*x**2/96 + 91*x**4/768 + 11117*x**6/129024 + O(x**7)
def test_issue_3508():
x = Symbol("x", real=True)
assert log(sin(x)).series(x, n=5) == log(x) - x**2/6 - x**4/180 + O(x**5)
e = -log(x) + x*(-log(x) + log(sin(2*x))) + log(sin(2*x))
assert e.series(x, n=5) == \
log(2) + log(2)*x - 2*x**2/3 - 2*x**3/3 - 4*x**4/45 + O(x**5)
def test_issue_3507():
e = x**(-4)*(x**2 - x**2*sqrt(cos(x)))
assert e.nseries(x, n=9) == \
Rational(1, 4) + x**2/96 + 19*x**4/5760 + 559*x**6/645120 + 29161*x**8/116121600 + O(x**9)
def test_issue_3639():
assert sin(cos(x)).nseries(x, n=5) == \
sin(1) - x**2*cos(1)/2 - x**4*sin(1)/8 + x**4*cos(1)/24 + O(x**5)
def test_hyperbolic():
assert sinh(x).nseries(x, n=6) == x + x**3/6 + x**5/120 + O(x**6)
assert cosh(x).nseries(x, n=5) == 1 + x**2/2 + x**4/24 + O(x**5)
assert tanh(x).nseries(x, n=6) == x - x**3/3 + 2*x**5/15 + O(x**6)
assert coth(x).nseries(x, n=6) == \
1/x - x**3/45 + x/3 + 2*x**5/945 + O(x**6)
assert asinh(x).nseries(x, n=6) == x - x**3/6 + 3*x**5/40 + O(x**6)
assert acosh(x).nseries(x, n=6) == \
pi*I/2 - I*x - 3*I*x**5/40 - I*x**3/6 + O(x**6)
assert atanh(x).nseries(x, n=6) == x + x**3/3 + x**5/5 + O(x**6)
assert acoth(x).nseries(x, n=6) == x + x**3/3 + x**5/5 + pi*I/2 + O(x**6)
def test_series2():
w = Symbol("w", real=True)
x = Symbol("x", real=True)
e = w**(-2)*(w*exp(1/x - w) - w*exp(1/x))
assert e.nseries(w, n=4) == -exp(1/x) + w*exp(1/x) / 2 + O(w**2)
def test_series3():
w = Symbol("w", real=True)
e = w**(-6)*(w**3*tan(w) - w**3*sin(w))
assert e.nseries(w, n=8) == Integer(1)/2 + w**2/8 + 13*w**4/240 + 529*w**6/24192 + O(w**8)
def test_bug4():
w = Symbol("w")
e = x/(w**4 + x**2*w**4 + 2*x*w**4)*w**4
assert e.nseries(w, n=2) in [x/(1 + 2*x + x**2),
1/(1 + x/2 + 1/x/2)/2, 1/x/(1 + 2/x + x**(-2))]
def test_bug5():
w = Symbol("w")
l = Symbol('l')
e = (-log(w) + log(1 + w*log(x)))**(-2)*w**(-2)*((-log(w) +
log(1 + x*w))*(-log(w) + log(1 + w*log(x)))*w - x*(-log(w) +
log(1 + w*log(x)))*w)
assert e.nseries(w, n=2, logx=l) == x/w/l + 1/w + O(1, w)
assert e.nseries(w, n=3, logx=l) == x/w/l + 1/w - x/l + 1/l*log(x) \
+ x*log(x)/l**2 + O(w)
def test_issue_4115():
assert (sin(x)/(1 - cos(x))).nseries(x, n=1) == 2/x + O(x)
assert (sin(x)**2/(1 - cos(x))).nseries(x, n=1) == 2 + O(x)
def test_pole():
raises(PoleError, lambda: sin(1/x).series(x, 0, 5))
raises(PoleError, lambda: sin(1 + 1/x).series(x, 0, 5))
raises(PoleError, lambda: (x*sin(1/x)).series(x, 0, 5))
def test_expsinbug():
assert exp(sin(x)).series(x, 0, 0) == O(1, x)
assert exp(sin(x)).series(x, 0, 1) == 1 + O(x)
assert exp(sin(x)).series(x, 0, 2) == 1 + x + O(x**2)
assert exp(sin(x)).series(x, 0, 3) == 1 + x + x**2/2 + O(x**3)
assert exp(sin(x)).series(x, 0, 4) == 1 + x + x**2/2 + O(x**4)
assert exp(sin(x)).series(x, 0, 5) == 1 + x + x**2/2 - x**4/8 + O(x**5)
def test_floor():
x = Symbol('x')
assert floor(x).series(x) == 0
assert floor(-x).series(x) == -1
assert floor(sin(x)).series(x) == 0
assert floor(sin(-x)).series(x) == -1
assert floor(x**3).series(x) == 0
assert floor(-x**3).series(x) == -1
assert floor(cos(x)).series(x) == 0
assert floor(cos(-x)).series(x) == 0
assert floor(5 + sin(x)).series(x) == 5
assert floor(5 + sin(-x)).series(x) == 4
assert floor(x).series(x, 2) == 2
assert floor(-x).series(x, 2) == -3
x = Symbol('x', negative=True)
assert floor(x + 1.5).series(x) == 1
def test_ceiling():
assert ceiling(x).series(x) == 1
assert ceiling(-x).series(x) == 0
assert ceiling(sin(x)).series(x) == 1
assert ceiling(sin(-x)).series(x) == 0
assert ceiling(1 - cos(x)).series(x) == 1
assert ceiling(1 - cos(-x)).series(x) == 1
assert ceiling(x).series(x, 2) == 3
assert ceiling(-x).series(x, 2) == -2
def test_abs():
a = Symbol('a')
assert abs(x).nseries(x, n=4) == x
assert abs(-x).nseries(x, n=4) == x
assert abs(x + 1).nseries(x, n=4) == x + 1
assert abs(sin(x)).nseries(x, n=4) == x - Rational(1, 6)*x**3 + O(x**4)
assert abs(sin(-x)).nseries(x, n=4) == x - Rational(1, 6)*x**3 + O(x**4)
assert abs(x - a).nseries(x, 1) == Piecewise((x - 1, Eq(1 - a, 0)),
((x - a)*sign(1 - a), True))
def test_dir():
assert abs(x).series(x, 0, dir="+") == x
assert abs(x).series(x, 0, dir="-") == -x
assert floor(x + 2).series(x, 0, dir='+') == 2
assert floor(x + 2).series(x, 0, dir='-') == 1
assert floor(x + 2.2).series(x, 0, dir='-') == 2
assert ceiling(x + 2.2).series(x, 0, dir='-') == 3
assert sin(x + y).series(x, 0, dir='-') == sin(x + y).series(x, 0, dir='+')
def test_issue_3504():
a = Symbol("a")
e = asin(a*x)/x
assert e.series(x, 4, n=2).removeO() == \
(x - 4)*(a/(4*sqrt(-16*a**2 + 1)) - asin(4*a)/16) + asin(4*a)/4
def test_issue_4441():
a, b = symbols('a,b')
f = 1/(1 + a*x)
assert f.series(x, 0, 5) == 1 - a*x + a**2*x**2 - a**3*x**3 + \
a**4*x**4 + O(x**5)
f = 1/(1 + (a + b)*x)
assert f.series(x, 0, 3) == 1 + x*(-a - b) + \
x**2*(a**2 + 2*a*b + b**2) + O(x**3)
def test_issue_4329():
assert tan(x).series(x, pi/2, n=3).removeO() == \
-pi/6 + x/3 - 1/(x - pi/2)
assert cot(x).series(x, pi, n=3).removeO() == \
-x/3 + pi/3 + 1/(x - pi)
assert limit(tan(x)**tan(2*x), x, pi/4) == exp(-1)
def test_issue_5183():
assert abs(x + x**2).series(n=1) == O(x)
assert abs(x + x**2).series(n=2) == x + O(x**2)
assert ((1 + x)**2).series(x, n=6) == 1 + 2*x + x**2
assert (1 + 1/x).series() == 1 + 1/x
assert Derivative(exp(x).series(), x).doit() == \
1 + x + x**2/2 + x**3/6 + x**4/24 + O(x**5)
def test_issue_5654():
a = Symbol('a')
assert (1/(x**2+a**2)**2).nseries(x, x0=I*a, n=0) == \
-I/(4*a**3*(-I*a + x)) - 1/(4*a**2*(-I*a + x)**2) + O(1, (x, I*a))
assert (1/(x**2+a**2)**2).nseries(x, x0=I*a, n=1) == 3/(16*a**4) \
-I/(4*a**3*(-I*a + x)) - 1/(4*a**2*(-I*a + x)**2) + O(-I*a + x, (x, I*a))
def test_issue_5925():
sx = sqrt(x + z).series(z, 0, 1)
sxy = sqrt(x + y + z).series(z, 0, 1)
s1, s2 = sx.subs(x, x + y), sxy
assert (s1 - s2).expand().removeO().simplify() == 0
sx = sqrt(x + z).series(z, 0, 1)
sxy = sqrt(x + y + z).series(z, 0, 1)
assert sxy.subs({x:1, y:2}) == sx.subs(x, 3)
def test_exp_2():
assert exp(x**3).nseries(x, 0, 14) == 1 + x**3 + x**6/2 + x**9/6 + x**12/24 + O(x**14)
|
84b313ec6a27c0039a9f0478995f4948f274ab20e39be81ead544224a2e0351d | from sympy import (
sqrt, Derivative, symbols, collect, Function, factor, Wild, S,
collect_const, log, fraction, I, cos, Add, O,sin, rcollect,
Mul, Pow, radsimp, diff, root, Symbol, Rational, exp, Abs)
from sympy.core.expr import unchanged
from sympy.core.mul import _unevaluated_Mul as umul
from sympy.simplify.radsimp import (_unevaluated_Add,
collect_sqrt, fraction_expand, collect_abs)
from sympy.testing.pytest import 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**Rational(3, 4) - 2*2**Rational(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.Half + (-sqrt(5)/2 - S.Half)**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 - Rational(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_pr19431():
"""Unevaluated collect with respect to a product"""
a = symbols('a')
assert collect(a**2*(a**2 + 1), a**2, evaluate=False)[a**2] == (a**2 + 1)
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.One, 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) == (a + b)*(y**x)**2.0
assert collect(a*2**(2.0*x) + b*2**(2.0*x), 2**x) == (a + b)*(2**x)**2.0
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(S.Half) == (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)
m = Mul(1, 1, S.Half, evaluate=False)
assert fraction(m) == (1, 2)
assert fraction(m, exact=True) == (Mul(1, 1, evaluate=False), 2)
m = Mul(1, 1, S.Half, S.Half, Pow(1, -1, evaluate=False), evaluate=False)
assert fraction(m) == (1, 4)
assert fraction(m, exact=True) == \
(Mul(1, 1, evaluate=False), Mul(2, 2, 1, evaluate=False))
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
def test_collect_abs():
s = abs(x) + abs(y)
assert collect_abs(s) == s
assert unchanged(Mul, abs(x), abs(y))
ans = Abs(x*y)
assert isinstance(ans, Abs)
assert collect_abs(abs(x)*abs(y)) == ans
assert collect_abs(1 + exp(abs(x)*abs(y))) == 1 + exp(ans)
# See https://github.com/sympy/sympy/issues/12910
p = Symbol('p', positive=True)
assert collect_abs(p/abs(1-p)).is_commutative is True
def test_issue_19149():
eq = exp(3*x/4)
assert collect(eq, exp(x)) == eq
|
4a582e1b29a2a105cdc433dd6f9a11835b555c8fa4d653fd6a005cbb4d6dcece | from sympy import ratsimpmodprime, ratsimp, Rational, sqrt, pi, log, erf, GF
from sympy.abc import x, y, z, t, a, b, c, d, e
def test_ratsimp():
f, g = 1/x + 1/y, (x + y)/(x*y)
assert f != g and ratsimp(f) == g
f, g = 1/(1 + 1/x), 1 - 1/(x + 1)
assert f != g and ratsimp(f) == g
f, g = x/(x + y) + y/(x + y), 1
assert f != g and ratsimp(f) == g
f, g = -x - y - y**2/(x + y) + x**2/(x + y), -2*y
assert f != g and ratsimp(f) == g
f = (a*c*x*y + a*c*z - b*d*x*y - b*d*z - b*t*x*y - b*t*x - b*t*z +
e*x)/(x*y + z)
G = [a*c - b*d - b*t + (-b*t*x + e*x)/(x*y + z),
a*c - b*d - b*t - ( b*t*x - e*x)/(x*y + z)]
assert f != g and ratsimp(f) in G
A = sqrt(pi)
B = log(erf(x) - 1)
C = log(erf(x) + 1)
D = 8 - 8*erf(x)
f = A*B/D - A*C/D + A*C*erf(x)/D - A*B*erf(x)/D + 2*A/D
assert ratsimp(f) == A*B/8 - A*C/8 - A/(4*erf(x) - 4)
def test_ratsimpmodprime():
a = y**5 + x + y
b = x - y
F = [x*y**5 - x - y]
assert ratsimpmodprime(a/b, F, x, y, order='lex') == \
(-x**2 - x*y - x - y) / (-x**2 + x*y)
a = x + y**2 - 2
b = x + y**2 - y - 1
F = [x*y - 1]
assert ratsimpmodprime(a/b, F, x, y, order='lex') == \
(1 + y - x)/(y - x)
a = 5*x**3 + 21*x**2 + 4*x*y + 23*x + 12*y + 15
b = 7*x**3 - y*x**2 + 31*x**2 + 2*x*y + 15*y + 37*x + 21
F = [x**2 + y**2 - 1]
assert ratsimpmodprime(a/b, F, x, y, order='lex') == \
(1 + 5*y - 5*x)/(8*y - 6*x)
a = x*y - x - 2*y + 4
b = x + y**2 - 2*y
F = [x - 2, y - 3]
assert ratsimpmodprime(a/b, F, x, y, order='lex') == \
Rational(2, 5)
# Test a bug where denominators would be dropped
assert ratsimpmodprime(x, [y - 2*x], order='lex') == \
y/2
a = (x**5 + 2*x**4 + 2*x**3 + 2*x**2 + x + 2/x + x**(-2))
assert ratsimpmodprime(a, [x + 1], domain=GF(2)) == 1
assert ratsimpmodprime(a, [x + 1], domain=GF(3)) == -1
|
6000449bda4177926661caaad00f25e9397fba5e0ce6fbd7cb17abd5e8aff8e4 | from sympy import symbols, IndexedBase, Identity, cos, Inverse
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 DiagMatrix
from sympy.matrices import Trace, MatAdd, MatMul, Transpose
from sympy.testing.pytest import raises
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 parse_matrix_expression(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 parse_matrix_expression(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 = parse_matrix_expression(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 = parse_matrix_expression(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))
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))
expr = 3*M*N
res = parse_matrix_expression(expr)
rexpr = recognize_matrix_expression(res)
assert expr == rexpr
expr = 3*M + N*M.T*M + 4*k*N
res = parse_matrix_expression(expr)
rexpr = recognize_matrix_expression(res)
assert expr == rexpr
expr = Inverse(M)*N
rexpr = recognize_matrix_expression(parse_matrix_expression(expr))
assert expr == rexpr
expr = M**2
rexpr = recognize_matrix_expression(parse_matrix_expression(expr))
assert expr == rexpr
expr = M*(2*N + 3*M)
res = parse_matrix_expression(expr)
rexpr = recognize_matrix_expression(res)
assert expr.expand() == rexpr.doit()
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, DiagMatrix(a)), (1, 2))
assert recognize_matrix_expression(cg) == A*DiagMatrix(a)
cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(a, b), (0, 2))
assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(DiagMatrix(a), b), (0, 2))
assert recognize_matrix_expression(cg).doit() == DiagMatrix(a)*b
cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(A, a), (0, 2))
assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagMatrix(a)), (0, 2))
assert recognize_matrix_expression(cg) == A.T*DiagMatrix(a)
cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(I, x, I1), (0, 2), (3, 5))
assert cg.transform_to_product() == CodegenArrayContraction(CodegenArrayTensorProduct(I, DiagMatrix(x), I1), (0, 2))
cg = CodegenArrayDiagonal(CodegenArrayTensorProduct(I, x, A, B), (1, 2), (5, 6))
assert cg.transform_to_product() == CodegenArrayDiagonal(CodegenArrayContraction(CodegenArrayTensorProduct(I, DiagMatrix(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(DiagMatrix(x), I), (0, 2))
assert recognize_matrix_expression(cg).doit() == DiagMatrix(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 DiagMatrix 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, DiagMatrix(a), B), (1, 2), (3, 4))
assert recognize_matrix_expression(cg) == A*DiagMatrix(a)*B
cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, B), (0, 2, 4))
assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagMatrix(a), B), (0, 2), (3, 4))
assert recognize_matrix_expression(cg) == A.T*DiagMatrix(a)*B
cg = CodegenArrayContraction(CodegenArrayTensorProduct(A, a, b, a.T, B), (0, 2, 4, 7, 9))
assert cg.split_multiple_contractions() == CodegenArrayContraction(CodegenArrayTensorProduct(A, DiagMatrix(a), DiagMatrix(b),
DiagMatrix(a), B),
(0, 2), (3, 4), (5, 7), (6, 9))
assert recognize_matrix_expression(cg).doit() == A.T*DiagMatrix(a)*DiagMatrix(b)*DiagMatrix(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, DiagMatrix(a), C, DiagMatrix(a), B), (1, 2), (3, 4), (5, 6), (7, 8))
assert recognize_matrix_expression(cg) == A*DiagMatrix(a)*C*DiagMatrix(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().dummy_eq(CodegenArrayContraction(CodegenArrayTensorProduct(a, I1, b, I1, (a.T*b).applyfunc(cos)), (1, 2), (3, 8), (5, 6), (7, 9)))
assert recognize_matrix_expression(cg).dummy_eq(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().dummy_eq(CodegenArrayContraction(
CodegenArrayTensorProduct(A.T, DiagMatrix(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
|
553e676b0548b8f12eeab943da643c6fa5ae12b8c50dcba4abe170639df41178 | """
This module contains query handlers responsible for calculus queries:
infinitesimal, finite, etc.
"""
from sympy.logic.boolalg import conjuncts
from sympy.assumptions import Q, ask
from sympy.assumptions.handlers import CommonHandler
class AskFiniteHandler(CommonHandler):
"""
Handler for key 'finite'.
Test that an expression is bounded respect to all its variables.
Examples of usage:
>>> from sympy import Q
>>> from sympy.assumptions.handlers.calculus import AskFiniteHandler
>>> from sympy.abc import x
>>> a = AskFiniteHandler()
>>> a.Symbol(x, Q.positive(x)) is None
True
>>> a.Symbol(x, Q.finite(x))
True
"""
@staticmethod
def Symbol(expr, assumptions):
"""
Handles Symbol.
Examples
========
>>> from sympy import Q
>>> from sympy.assumptions.handlers.calculus import AskFiniteHandler
>>> from sympy.abc import x
>>> a = AskFiniteHandler()
>>> a.Symbol(x, Q.positive(x)) is None
True
>>> a.Symbol(x, Q.finite(x))
True
"""
if expr.is_finite is not None:
return expr.is_finite
if Q.finite(expr) in conjuncts(assumptions):
return True
return None
@staticmethod
def Add(expr, assumptions):
"""
Return True if expr is bounded, False if not and None if unknown.
Truth Table:
+-------+-----+-----------+-----------+
| | | | |
| | B | U | ? |
| | | | |
+-------+-----+---+---+---+---+---+---+
| | | | | | | | |
| | |'+'|'-'|'x'|'+'|'-'|'x'|
| | | | | | | | |
+-------+-----+---+---+---+---+---+---+
| | | | |
| B | B | U | ? |
| | | | |
+---+---+-----+---+---+---+---+---+---+
| | | | | | | | | |
| |'+'| | U | ? | ? | U | ? | ? |
| | | | | | | | | |
| +---+-----+---+---+---+---+---+---+
| | | | | | | | | |
| U |'-'| | ? | U | ? | ? | U | ? |
| | | | | | | | | |
| +---+-----+---+---+---+---+---+---+
| | | | | |
| |'x'| | ? | ? |
| | | | | |
+---+---+-----+---+---+---+---+---+---+
| | | | |
| ? | | | ? |
| | | | |
+-------+-----+-----------+---+---+---+
* 'B' = Bounded
* 'U' = Unbounded
* '?' = unknown boundedness
* '+' = positive sign
* '-' = negative sign
* 'x' = sign unknown
|
* All Bounded -> True
* 1 Unbounded and the rest Bounded -> False
* >1 Unbounded, all with same known sign -> False
* Any Unknown and unknown sign -> None
* Else -> None
When the signs are not the same you can have an undefined
result as in oo - oo, hence 'bounded' is also undefined.
"""
sign = -1 # sign of unknown or infinite
result = True
for arg in expr.args:
_bounded = ask(Q.finite(arg), assumptions)
if _bounded:
continue
s = ask(Q.positive(arg), assumptions)
# if there has been more than one sign or if the sign of this arg
# is None and Bounded is None or there was already
# an unknown sign, return None
if sign != -1 and s != sign or \
s is None and (s == _bounded or s == sign):
return None
else:
sign = s
# once False, do not change
if result is not False:
result = _bounded
return result
@staticmethod
def Mul(expr, assumptions):
"""
Return True if expr is bounded, False if not and None if unknown.
Truth Table:
+---+---+---+--------+
| | | | |
| | B | U | ? |
| | | | |
+---+---+---+---+----+
| | | | | |
| | | | s | /s |
| | | | | |
+---+---+---+---+----+
| | | | |
| B | B | U | ? |
| | | | |
+---+---+---+---+----+
| | | | | |
| U | | U | U | ? |
| | | | | |
+---+---+---+---+----+
| | | | |
| ? | | | ? |
| | | | |
+---+---+---+---+----+
* B = Bounded
* U = Unbounded
* ? = unknown boundedness
* s = signed (hence nonzero)
* /s = not signed
"""
result = True
for arg in expr.args:
_bounded = ask(Q.finite(arg), assumptions)
if _bounded:
continue
elif _bounded is None:
if result is None:
return None
if ask(Q.nonzero(arg), assumptions) is None:
return None
if result is not False:
result = None
else:
result = False
return result
@staticmethod
def Pow(expr, assumptions):
"""
Unbounded ** NonZero -> Unbounded
Bounded ** Bounded -> Bounded
Abs()<=1 ** Positive -> Bounded
Abs()>=1 ** Negative -> Bounded
Otherwise unknown
"""
base_bounded = ask(Q.finite(expr.base), assumptions)
exp_bounded = ask(Q.finite(expr.exp), assumptions)
if base_bounded is None and exp_bounded is None: # Common Case
return None
if base_bounded is False and ask(Q.nonzero(expr.exp), assumptions):
return False
if base_bounded and exp_bounded:
return True
if (abs(expr.base) <= 1) == True and ask(Q.positive(expr.exp), assumptions):
return True
if (abs(expr.base) >= 1) == True and ask(Q.negative(expr.exp), assumptions):
return True
if (abs(expr.base) >= 1) == True and exp_bounded is False:
return False
return None
@staticmethod
def log(expr, assumptions):
return ask(Q.finite(expr.args[0]), assumptions)
exp = log
cos, sin, Number, Pi, Exp1, GoldenRatio, TribonacciConstant, ImaginaryUnit, sign = \
[staticmethod(CommonHandler.AlwaysTrue)]*9
Infinity, NegativeInfinity = [staticmethod(CommonHandler.AlwaysFalse)]*2
|
f19b35c993aca83cc94d743197f3ee71ae82007c1113dc9cd0378ea8eb18b321 | """
This module implements some special functions that commonly appear in
combinatorial contexts (e.g. in power series); in particular,
sequences of rational numbers such as Bernoulli and Fibonacci numbers.
Factorials, binomial coefficients and related functions are located in
the separate 'factorials' module.
"""
from typing import Callable, Dict
from sympy.core import S, Symbol, Rational, Integer, Add, Dummy
from sympy.core.cache import cacheit
from sympy.core.compatibility import as_int, SYMPY_INTS
from sympy.core.function import Function, expand_mul
from sympy.core.logic import fuzzy_not
from sympy.core.numbers import E, pi
from sympy.core.relational import LessThan, StrictGreaterThan
from sympy.functions.combinatorial.factorials import binomial, factorial
from sympy.functions.elementary.exponential import log
from sympy.functions.elementary.integers import floor
from sympy.functions.elementary.miscellaneous import sqrt, cbrt
from sympy.functions.elementary.trigonometric import sin, cos, cot
from sympy.ntheory import isprime
from sympy.ntheory.primetest import is_square
from sympy.utilities.memoization import recurrence_memo
from mpmath import bernfrac, workprec
from mpmath.libmp import ifib as _ifib
def _product(a, b):
p = 1
for k in range(a, b + 1):
p *= k
return p
# Dummy symbol used for computing polynomial sequences
_sym = Symbol('x')
#----------------------------------------------------------------------------#
# #
# Carmichael numbers #
# #
#----------------------------------------------------------------------------#
class carmichael(Function):
"""
Carmichael Numbers:
Certain cryptographic algorithms make use of big prime numbers.
However, checking whether a big number is prime is not so easy.
Randomized prime number checking tests exist that offer a high degree of confidence of
accurate determination at low cost, such as the Fermat test.
Let 'a' be a random number between 2 and n - 1, where n is the number whose primality we are testing.
Then, n is probably prime if it satisfies the modular arithmetic congruence relation :
a^(n-1) = 1(mod n).
(where mod refers to the modulo operation)
If a number passes the Fermat test several times, then it is prime with a
high probability.
Unfortunately, certain composite numbers (non-primes) still pass the Fermat test
with every number smaller than themselves.
These numbers are called Carmichael numbers.
A Carmichael number will pass a Fermat primality test to every base b relatively prime to the number,
even though it is not actually prime. This makes tests based on Fermat's Little Theorem less effective than
strong probable prime tests such as the Baillie-PSW primality test and the Miller-Rabin primality test.
mr functions given in sympy/sympy/ntheory/primetest.py will produce wrong results for each and every
carmichael number.
Examples
========
>>> from sympy import carmichael
>>> carmichael.find_first_n_carmichaels(5)
[561, 1105, 1729, 2465, 2821]
>>> carmichael.is_prime(2465)
False
>>> carmichael.is_prime(1729)
False
>>> carmichael.find_carmichael_numbers_in_range(0, 562)
[561]
>>> carmichael.find_carmichael_numbers_in_range(0,1000)
[561]
>>> carmichael.find_carmichael_numbers_in_range(0,2000)
[561, 1105, 1729]
References
==========
.. [1] https://en.wikipedia.org/wiki/Carmichael_number
.. [2] https://en.wikipedia.org/wiki/Fermat_primality_test
.. [3] https://www.jstor.org/stable/23248683?seq=1#metadata_info_tab_contents
"""
@staticmethod
def is_perfect_square(n):
return is_square(n)
@staticmethod
def divides(p, n):
return n % p == 0
@staticmethod
def is_prime(n):
return isprime(n)
@staticmethod
def is_carmichael(n):
if n >= 0:
if (n == 1) or (carmichael.is_prime(n)) or (n % 2 == 0):
return False
divisors = list([1, n])
# get divisors
for i in range(3, n // 2 + 1, 2):
if n % i == 0:
divisors.append(i)
for i in divisors:
if carmichael.is_perfect_square(i) and i != 1:
return False
if carmichael.is_prime(i):
if not carmichael.divides(i - 1, n - 1):
return False
return True
else:
raise ValueError('The provided number must be greater than or equal to 0')
@staticmethod
def find_carmichael_numbers_in_range(x, y):
if 0 <= x <= y:
if x % 2 == 0:
return list([i for i in range(x + 1, y, 2) if carmichael.is_carmichael(i)])
else:
return list([i for i in range(x, y, 2) if carmichael.is_carmichael(i)])
else:
raise ValueError('The provided range is not valid. x and y must be non-negative integers and x <= y')
@staticmethod
def find_first_n_carmichaels(n):
i = 1
carmichaels = list()
while len(carmichaels) < n:
if carmichael.is_carmichael(i):
carmichaels.append(i)
i += 2
return carmichaels
#----------------------------------------------------------------------------#
# #
# Fibonacci numbers #
# #
#----------------------------------------------------------------------------#
class fibonacci(Function):
r"""
Fibonacci numbers / Fibonacci polynomials
The Fibonacci numbers are the integer sequence defined by the
initial terms `F_0 = 0`, `F_1 = 1` and the two-term recurrence
relation `F_n = F_{n-1} + F_{n-2}`. This definition
extended to arbitrary real and complex arguments using
the formula
.. math :: F_z = \frac{\phi^z - \cos(\pi z) \phi^{-z}}{\sqrt 5}
The Fibonacci polynomials are defined by `F_1(x) = 1`,
`F_2(x) = x`, and `F_n(x) = x*F_{n-1}(x) + F_{n-2}(x)` for `n > 2`.
For all positive integers `n`, `F_n(1) = F_n`.
* ``fibonacci(n)`` gives the `n^{th}` Fibonacci number, `F_n`
* ``fibonacci(n, x)`` gives the `n^{th}` Fibonacci polynomial in `x`, `F_n(x)`
Examples
========
>>> from sympy import fibonacci, Symbol
>>> [fibonacci(x) for x in range(11)]
[0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55]
>>> fibonacci(5, Symbol('t'))
t**4 + 3*t**2 + 1
See Also
========
bell, bernoulli, catalan, euler, harmonic, lucas, genocchi, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Fibonacci_number
.. [2] http://mathworld.wolfram.com/FibonacciNumber.html
"""
@staticmethod
def _fib(n):
return _ifib(n)
@staticmethod
@recurrence_memo([None, S.One, _sym])
def _fibpoly(n, prev):
return (prev[-2] + _sym*prev[-1]).expand()
@classmethod
def eval(cls, n, sym=None):
if n is S.Infinity:
return S.Infinity
if n.is_Integer:
if sym is None:
n = int(n)
if n < 0:
return S.NegativeOne**(n + 1) * fibonacci(-n)
else:
return Integer(cls._fib(n))
else:
if n < 1:
raise ValueError("Fibonacci polynomials are defined "
"only for positive integer indices.")
return cls._fibpoly(n).subs(_sym, sym)
def _eval_rewrite_as_sqrt(self, n, **kwargs):
return 2**(-n)*sqrt(5)*((1 + sqrt(5))**n - (-sqrt(5) + 1)**n) / 5
def _eval_rewrite_as_GoldenRatio(self,n, **kwargs):
return (S.GoldenRatio**n - 1/(-S.GoldenRatio)**n)/(2*S.GoldenRatio-1)
#----------------------------------------------------------------------------#
# #
# Lucas numbers #
# #
#----------------------------------------------------------------------------#
class lucas(Function):
"""
Lucas numbers
Lucas numbers satisfy a recurrence relation similar to that of
the Fibonacci sequence, in which each term is the sum of the
preceding two. They are generated by choosing the initial
values `L_0 = 2` and `L_1 = 1`.
* ``lucas(n)`` gives the `n^{th}` Lucas number
Examples
========
>>> from sympy import lucas
>>> [lucas(x) for x in range(11)]
[2, 1, 3, 4, 7, 11, 18, 29, 47, 76, 123]
See Also
========
bell, bernoulli, catalan, euler, fibonacci, harmonic, genocchi, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Lucas_number
.. [2] http://mathworld.wolfram.com/LucasNumber.html
"""
@classmethod
def eval(cls, n):
if n is S.Infinity:
return S.Infinity
if n.is_Integer:
return fibonacci(n + 1) + fibonacci(n - 1)
def _eval_rewrite_as_sqrt(self, n, **kwargs):
return 2**(-n)*((1 + sqrt(5))**n + (-sqrt(5) + 1)**n)
#----------------------------------------------------------------------------#
# #
# Tribonacci numbers #
# #
#----------------------------------------------------------------------------#
class tribonacci(Function):
r"""
Tribonacci numbers / Tribonacci polynomials
The Tribonacci numbers are the integer sequence defined by the
initial terms `T_0 = 0`, `T_1 = 1`, `T_2 = 1` and the three-term
recurrence relation `T_n = T_{n-1} + T_{n-2} + T_{n-3}`.
The Tribonacci polynomials are defined by `T_0(x) = 0`, `T_1(x) = 1`,
`T_2(x) = x^2`, and `T_n(x) = x^2 T_{n-1}(x) + x T_{n-2}(x) + T_{n-3}(x)`
for `n > 2`. For all positive integers `n`, `T_n(1) = T_n`.
* ``tribonacci(n)`` gives the `n^{th}` Tribonacci number, `T_n`
* ``tribonacci(n, x)`` gives the `n^{th}` Tribonacci polynomial in `x`, `T_n(x)`
Examples
========
>>> from sympy import tribonacci, Symbol
>>> [tribonacci(x) for x in range(11)]
[0, 1, 1, 2, 4, 7, 13, 24, 44, 81, 149]
>>> tribonacci(5, Symbol('t'))
t**8 + 3*t**5 + 3*t**2
See Also
========
bell, bernoulli, catalan, euler, fibonacci, harmonic, lucas, genocchi, partition
References
==========
.. [1] https://en.wikipedia.org/wiki/Generalizations_of_Fibonacci_numbers#Tribonacci_numbers
.. [2] http://mathworld.wolfram.com/TribonacciNumber.html
.. [3] https://oeis.org/A000073
"""
@staticmethod
@recurrence_memo([S.Zero, S.One, S.One])
def _trib(n, prev):
return (prev[-3] + prev[-2] + prev[-1])
@staticmethod
@recurrence_memo([S.Zero, S.One, _sym**2])
def _tribpoly(n, prev):
return (prev[-3] + _sym*prev[-2] + _sym**2*prev[-1]).expand()
@classmethod
def eval(cls, n, sym=None):
if n is S.Infinity:
return S.Infinity
if n.is_Integer:
n = int(n)
if n < 0:
raise ValueError("Tribonacci polynomials are defined "
"only for non-negative integer indices.")
if sym is None:
return Integer(cls._trib(n))
else:
return cls._tribpoly(n).subs(_sym, sym)
def _eval_rewrite_as_sqrt(self, n, **kwargs):
w = (-1 + S.ImaginaryUnit * sqrt(3)) / 2
a = (1 + cbrt(19 + 3*sqrt(33)) + cbrt(19 - 3*sqrt(33))) / 3
b = (1 + w*cbrt(19 + 3*sqrt(33)) + w**2*cbrt(19 - 3*sqrt(33))) / 3
c = (1 + w**2*cbrt(19 + 3*sqrt(33)) + w*cbrt(19 - 3*sqrt(33))) / 3
Tn = (a**(n + 1)/((a - b)*(a - c))
+ b**(n + 1)/((b - a)*(b - c))
+ c**(n + 1)/((c - a)*(c - b)))
return Tn
def _eval_rewrite_as_TribonacciConstant(self, n, **kwargs):
b = cbrt(586 + 102*sqrt(33))
Tn = 3 * b * S.TribonacciConstant**n / (b**2 - 2*b + 4)
return floor(Tn + S.Half)
#----------------------------------------------------------------------------#
# #
# Bernoulli numbers #
# #
#----------------------------------------------------------------------------#
class bernoulli(Function):
r"""
Bernoulli numbers / Bernoulli polynomials
The Bernoulli numbers are a sequence of rational numbers
defined by `B_0 = 1` and the recursive relation (`n > 0`):
.. math :: 0 = \sum_{k=0}^n \binom{n+1}{k} B_k
They are also commonly defined by their exponential generating
function, which is `\frac{x}{e^x - 1}`. For odd indices > 1, the
Bernoulli numbers are zero.
The Bernoulli polynomials satisfy the analogous formula:
.. math :: B_n(x) = \sum_{k=0}^n \binom{n}{k} B_k x^{n-k}
Bernoulli numbers and Bernoulli polynomials are related as
`B_n(0) = B_n`.
We compute Bernoulli numbers using Ramanujan's formula:
.. math :: B_n = \frac{A(n) - S(n)}{\binom{n+3}{n}}
where:
.. math :: A(n) = \begin{cases} \frac{n+3}{3} &
n \equiv 0\ \text{or}\ 2 \pmod{6} \\
-\frac{n+3}{6} & n \equiv 4 \pmod{6} \end{cases}
and:
.. math :: S(n) = \sum_{k=1}^{[n/6]} \binom{n+3}{n-6k} B_{n-6k}
This formula is similar to the sum given in the definition, but
cuts 2/3 of the terms. For Bernoulli polynomials, we use the
formula in the definition.
* ``bernoulli(n)`` gives the nth Bernoulli number, `B_n`
* ``bernoulli(n, x)`` gives the nth Bernoulli polynomial in `x`, `B_n(x)`
Examples
========
>>> from sympy import bernoulli
>>> [bernoulli(n) for n in range(11)]
[1, -1/2, 1/6, 0, -1/30, 0, 1/42, 0, -1/30, 0, 5/66]
>>> bernoulli(1000001)
0
See Also
========
bell, catalan, euler, fibonacci, harmonic, lucas, genocchi, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Bernoulli_number
.. [2] https://en.wikipedia.org/wiki/Bernoulli_polynomial
.. [3] http://mathworld.wolfram.com/BernoulliNumber.html
.. [4] http://mathworld.wolfram.com/BernoulliPolynomial.html
"""
# Calculates B_n for positive even n
@staticmethod
def _calc_bernoulli(n):
s = 0
a = int(binomial(n + 3, n - 6))
for j in range(1, n//6 + 1):
s += a * bernoulli(n - 6*j)
# Avoid computing each binomial coefficient from scratch
a *= _product(n - 6 - 6*j + 1, n - 6*j)
a //= _product(6*j + 4, 6*j + 9)
if n % 6 == 4:
s = -Rational(n + 3, 6) - s
else:
s = Rational(n + 3, 3) - s
return s / binomial(n + 3, n)
# We implement a specialized memoization scheme to handle each
# case modulo 6 separately
_cache = {0: S.One, 2: Rational(1, 6), 4: Rational(-1, 30)}
_highest = {0: 0, 2: 2, 4: 4}
@classmethod
def eval(cls, n, sym=None):
if n.is_Number:
if n.is_Integer and n.is_nonnegative:
if n.is_zero:
return S.One
elif n is S.One:
if sym is None:
return Rational(-1, 2)
else:
return sym - S.Half
# Bernoulli numbers
elif sym is None:
if n.is_odd:
return S.Zero
n = int(n)
# Use mpmath for enormous Bernoulli numbers
if n > 500:
p, q = bernfrac(n)
return Rational(int(p), int(q))
case = n % 6
highest_cached = cls._highest[case]
if n <= highest_cached:
return cls._cache[n]
# To avoid excessive recursion when, say, bernoulli(1000) is
# requested, calculate and cache the entire sequence ... B_988,
# B_994, B_1000 in increasing order
for i in range(highest_cached + 6, n + 6, 6):
b = cls._calc_bernoulli(i)
cls._cache[i] = b
cls._highest[case] = i
return b
# Bernoulli polynomials
else:
n, result = int(n), []
for k in range(n + 1):
result.append(binomial(n, k)*cls(k)*sym**(n - k))
return Add(*result)
else:
raise ValueError("Bernoulli numbers are defined only"
" for nonnegative integer indices.")
if sym is None:
if n.is_odd and (n - 1).is_positive:
return S.Zero
#----------------------------------------------------------------------------#
# #
# Bell numbers #
# #
#----------------------------------------------------------------------------#
class bell(Function):
r"""
Bell numbers / Bell polynomials
The Bell numbers satisfy `B_0 = 1` and
.. math:: B_n = \sum_{k=0}^{n-1} \binom{n-1}{k} B_k.
They are also given by:
.. math:: B_n = \frac{1}{e} \sum_{k=0}^{\infty} \frac{k^n}{k!}.
The Bell polynomials are given by `B_0(x) = 1` and
.. math:: B_n(x) = x \sum_{k=1}^{n-1} \binom{n-1}{k-1} B_{k-1}(x).
The second kind of Bell polynomials (are sometimes called "partial" Bell
polynomials or incomplete Bell polynomials) are defined as
.. math:: B_{n,k}(x_1, x_2,\dotsc x_{n-k+1}) =
\sum_{j_1+j_2+j_2+\dotsb=k \atop j_1+2j_2+3j_2+\dotsb=n}
\frac{n!}{j_1!j_2!\dotsb j_{n-k+1}!}
\left(\frac{x_1}{1!} \right)^{j_1}
\left(\frac{x_2}{2!} \right)^{j_2} \dotsb
\left(\frac{x_{n-k+1}}{(n-k+1)!} \right) ^{j_{n-k+1}}.
* ``bell(n)`` gives the `n^{th}` Bell number, `B_n`.
* ``bell(n, x)`` gives the `n^{th}` Bell polynomial, `B_n(x)`.
* ``bell(n, k, (x1, x2, ...))`` gives Bell polynomials of the second kind,
`B_{n,k}(x_1, x_2, \dotsc, x_{n-k+1})`.
Notes
=====
Not to be confused with Bernoulli numbers and Bernoulli polynomials,
which use the same notation.
Examples
========
>>> from sympy import bell, Symbol, symbols
>>> [bell(n) for n in range(11)]
[1, 1, 2, 5, 15, 52, 203, 877, 4140, 21147, 115975]
>>> bell(30)
846749014511809332450147
>>> bell(4, Symbol('t'))
t**4 + 6*t**3 + 7*t**2 + t
>>> bell(6, 2, symbols('x:6')[1:])
6*x1*x5 + 15*x2*x4 + 10*x3**2
See Also
========
bernoulli, catalan, euler, fibonacci, harmonic, lucas, genocchi, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Bell_number
.. [2] http://mathworld.wolfram.com/BellNumber.html
.. [3] http://mathworld.wolfram.com/BellPolynomial.html
"""
@staticmethod
@recurrence_memo([1, 1])
def _bell(n, prev):
s = 1
a = 1
for k in range(1, n):
a = a * (n - k) // k
s += a * prev[k]
return s
@staticmethod
@recurrence_memo([S.One, _sym])
def _bell_poly(n, prev):
s = 1
a = 1
for k in range(2, n + 1):
a = a * (n - k + 1) // (k - 1)
s += a * prev[k - 1]
return expand_mul(_sym * s)
@staticmethod
def _bell_incomplete_poly(n, k, symbols):
r"""
The second kind of Bell polynomials (incomplete Bell polynomials).
Calculated by recurrence formula:
.. math:: B_{n,k}(x_1, x_2, \dotsc, x_{n-k+1}) =
\sum_{m=1}^{n-k+1}
\x_m \binom{n-1}{m-1} B_{n-m,k-1}(x_1, x_2, \dotsc, x_{n-m-k})
where
`B_{0,0} = 1;`
`B_{n,0} = 0; for n \ge 1`
`B_{0,k} = 0; for k \ge 1`
"""
if (n == 0) and (k == 0):
return S.One
elif (n == 0) or (k == 0):
return S.Zero
s = S.Zero
a = S.One
for m in range(1, n - k + 2):
s += a * bell._bell_incomplete_poly(
n - m, k - 1, symbols) * symbols[m - 1]
a = a * (n - m) / m
return expand_mul(s)
@classmethod
def eval(cls, n, k_sym=None, symbols=None):
if n is S.Infinity:
if k_sym is None:
return S.Infinity
else:
raise ValueError("Bell polynomial is not defined")
if n.is_negative or n.is_integer is False:
raise ValueError("a non-negative integer expected")
if n.is_Integer and n.is_nonnegative:
if k_sym is None:
return Integer(cls._bell(int(n)))
elif symbols is None:
return cls._bell_poly(int(n)).subs(_sym, k_sym)
else:
r = cls._bell_incomplete_poly(int(n), int(k_sym), symbols)
return r
def _eval_rewrite_as_Sum(self, n, k_sym=None, symbols=None, **kwargs):
from sympy import Sum
if (k_sym is not None) or (symbols is not None):
return self
# Dobinski's formula
if not n.is_nonnegative:
return self
k = Dummy('k', integer=True, nonnegative=True)
return 1 / E * Sum(k**n / factorial(k), (k, 0, S.Infinity))
#----------------------------------------------------------------------------#
# #
# Harmonic numbers #
# #
#----------------------------------------------------------------------------#
class harmonic(Function):
r"""
Harmonic numbers
The nth harmonic number is given by `\operatorname{H}_{n} =
1 + \frac{1}{2} + \frac{1}{3} + \ldots + \frac{1}{n}`.
More generally:
.. math:: \operatorname{H}_{n,m} = \sum_{k=1}^{n} \frac{1}{k^m}
As `n \rightarrow \infty`, `\operatorname{H}_{n,m} \rightarrow \zeta(m)`,
the Riemann zeta function.
* ``harmonic(n)`` gives the nth harmonic number, `\operatorname{H}_n`
* ``harmonic(n, m)`` gives the nth generalized harmonic number
of order `m`, `\operatorname{H}_{n,m}`, where
``harmonic(n) == harmonic(n, 1)``
Examples
========
>>> from sympy import harmonic, oo
>>> [harmonic(n) for n in range(6)]
[0, 1, 3/2, 11/6, 25/12, 137/60]
>>> [harmonic(n, 2) for n in range(6)]
[0, 1, 5/4, 49/36, 205/144, 5269/3600]
>>> harmonic(oo, 2)
pi**2/6
>>> from sympy import Symbol, Sum
>>> n = Symbol("n")
>>> harmonic(n).rewrite(Sum)
Sum(1/_k, (_k, 1, n))
We can evaluate harmonic numbers for all integral and positive
rational arguments:
>>> from sympy import S, expand_func, simplify
>>> harmonic(8)
761/280
>>> harmonic(11)
83711/27720
>>> H = harmonic(1/S(3))
>>> H
harmonic(1/3)
>>> He = expand_func(H)
>>> He
-log(6) - sqrt(3)*pi/6 + 2*Sum(log(sin(_k*pi/3))*cos(2*_k*pi/3), (_k, 1, 1))
+ 3*Sum(1/(3*_k + 1), (_k, 0, 0))
>>> He.doit()
-log(6) - sqrt(3)*pi/6 - log(sqrt(3)/2) + 3
>>> H = harmonic(25/S(7))
>>> He = simplify(expand_func(H).doit())
>>> He
log(sin(pi/7)**(-2*cos(pi/7))*sin(2*pi/7)**(2*cos(16*pi/7))*cos(pi/14)**(-2*sin(pi/14))/14)
+ pi*tan(pi/14)/2 + 30247/9900
>>> He.n(40)
1.983697455232980674869851942390639915940
>>> harmonic(25/S(7)).n(40)
1.983697455232980674869851942390639915940
We can rewrite harmonic numbers in terms of polygamma functions:
>>> from sympy import digamma, polygamma
>>> m = Symbol("m")
>>> harmonic(n).rewrite(digamma)
polygamma(0, n + 1) + EulerGamma
>>> harmonic(n).rewrite(polygamma)
polygamma(0, n + 1) + EulerGamma
>>> harmonic(n,3).rewrite(polygamma)
polygamma(2, n + 1)/2 - polygamma(2, 1)/2
>>> harmonic(n,m).rewrite(polygamma)
(-1)**m*(polygamma(m - 1, 1) - polygamma(m - 1, n + 1))/factorial(m - 1)
Integer offsets in the argument can be pulled out:
>>> from sympy import expand_func
>>> expand_func(harmonic(n+4))
harmonic(n) + 1/(n + 4) + 1/(n + 3) + 1/(n + 2) + 1/(n + 1)
>>> expand_func(harmonic(n-4))
harmonic(n) - 1/(n - 1) - 1/(n - 2) - 1/(n - 3) - 1/n
Some limits can be computed as well:
>>> from sympy import limit, oo
>>> limit(harmonic(n), n, oo)
oo
>>> limit(harmonic(n, 2), n, oo)
pi**2/6
>>> limit(harmonic(n, 3), n, oo)
-polygamma(2, 1)/2
However we can not compute the general relation yet:
>>> limit(harmonic(n, m), n, oo)
harmonic(oo, m)
which equals ``zeta(m)`` for ``m > 1``.
See Also
========
bell, bernoulli, catalan, euler, fibonacci, lucas, genocchi, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Harmonic_number
.. [2] http://functions.wolfram.com/GammaBetaErf/HarmonicNumber/
.. [3] http://functions.wolfram.com/GammaBetaErf/HarmonicNumber2/
"""
# Generate one memoized Harmonic number-generating function for each
# order and store it in a dictionary
_functions = {} # type: Dict[Integer, Callable[[int], Rational]]
@classmethod
def eval(cls, n, m=None):
from sympy import zeta
if m is S.One:
return cls(n)
if m is None:
m = S.One
if m.is_zero:
return n
if n is S.Infinity and m.is_Number:
# TODO: Fix for symbolic values of m
if m.is_negative:
return S.NaN
elif LessThan(m, S.One):
return S.Infinity
elif StrictGreaterThan(m, S.One):
return zeta(m)
else:
return cls
if n == 0:
return S.Zero
if n.is_Integer and n.is_nonnegative and m.is_Integer:
if not m in cls._functions:
@recurrence_memo([0])
def f(n, prev):
return prev[-1] + S.One / n**m
cls._functions[m] = f
return cls._functions[m](int(n))
def _eval_rewrite_as_polygamma(self, n, m=1, **kwargs):
from sympy.functions.special.gamma_functions import polygamma
return S.NegativeOne**m/factorial(m - 1) * (polygamma(m - 1, 1) - polygamma(m - 1, n + 1))
def _eval_rewrite_as_digamma(self, n, m=1, **kwargs):
from sympy.functions.special.gamma_functions import polygamma
return self.rewrite(polygamma)
def _eval_rewrite_as_trigamma(self, n, m=1, **kwargs):
from sympy.functions.special.gamma_functions import polygamma
return self.rewrite(polygamma)
def _eval_rewrite_as_Sum(self, n, m=None, **kwargs):
from sympy import Sum
k = Dummy("k", integer=True)
if m is None:
m = S.One
return Sum(k**(-m), (k, 1, n))
def _eval_expand_func(self, **hints):
from sympy import Sum
n = self.args[0]
m = self.args[1] if len(self.args) == 2 else 1
if m == S.One:
if n.is_Add:
off = n.args[0]
nnew = n - off
if off.is_Integer and off.is_positive:
result = [S.One/(nnew + i) for i in range(off, 0, -1)] + [harmonic(nnew)]
return Add(*result)
elif off.is_Integer and off.is_negative:
result = [-S.One/(nnew + i) for i in range(0, off, -1)] + [harmonic(nnew)]
return Add(*result)
if n.is_Rational:
# Expansions for harmonic numbers at general rational arguments (u + p/q)
# Split n as u + p/q with p < q
p, q = n.as_numer_denom()
u = p // q
p = p - u * q
if u.is_nonnegative and p.is_positive and q.is_positive and p < q:
k = Dummy("k")
t1 = q * Sum(1 / (q * k + p), (k, 0, u))
t2 = 2 * Sum(cos((2 * pi * p * k) / S(q)) *
log(sin((pi * k) / S(q))),
(k, 1, floor((q - 1) / S(2))))
t3 = (pi / 2) * cot((pi * p) / q) + log(2 * q)
return t1 + t2 - t3
return self
def _eval_rewrite_as_tractable(self, n, m=1, **kwargs):
from sympy import polygamma
return self.rewrite(polygamma).rewrite("tractable", deep=True)
def _eval_evalf(self, prec):
from sympy import polygamma
if all(i.is_number for i in self.args):
return self.rewrite(polygamma)._eval_evalf(prec)
#----------------------------------------------------------------------------#
# #
# Euler numbers #
# #
#----------------------------------------------------------------------------#
class euler(Function):
r"""
Euler numbers / Euler polynomials
The Euler numbers are given by:
.. math:: E_{2n} = I \sum_{k=1}^{2n+1} \sum_{j=0}^k \binom{k}{j}
\frac{(-1)^j (k-2j)^{2n+1}}{2^k I^k k}
.. math:: E_{2n+1} = 0
Euler numbers and Euler polynomials are related by
.. math:: E_n = 2^n E_n\left(\frac{1}{2}\right).
We compute symbolic Euler polynomials using [5]_
.. math:: E_n(x) = \sum_{k=0}^n \binom{n}{k} \frac{E_k}{2^k}
\left(x - \frac{1}{2}\right)^{n-k}.
However, numerical evaluation of the Euler polynomial is computed
more efficiently (and more accurately) using the mpmath library.
* ``euler(n)`` gives the `n^{th}` Euler number, `E_n`.
* ``euler(n, x)`` gives the `n^{th}` Euler polynomial, `E_n(x)`.
Examples
========
>>> from sympy import Symbol, S
>>> from sympy.functions import euler
>>> [euler(n) for n in range(10)]
[1, 0, -1, 0, 5, 0, -61, 0, 1385, 0]
>>> n = Symbol("n")
>>> euler(n + 2*n)
euler(3*n)
>>> x = Symbol("x")
>>> euler(n, x)
euler(n, x)
>>> euler(0, x)
1
>>> euler(1, x)
x - 1/2
>>> euler(2, x)
x**2 - x
>>> euler(3, x)
x**3 - 3*x**2/2 + 1/4
>>> euler(4, x)
x**4 - 2*x**3 + x
>>> euler(12, S.Half)
2702765/4096
>>> euler(12)
2702765
See Also
========
bell, bernoulli, catalan, fibonacci, harmonic, lucas, genocchi, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Euler_numbers
.. [2] http://mathworld.wolfram.com/EulerNumber.html
.. [3] https://en.wikipedia.org/wiki/Alternating_permutation
.. [4] http://mathworld.wolfram.com/AlternatingPermutation.html
.. [5] http://dlmf.nist.gov/24.2#ii
"""
@classmethod
def eval(cls, m, sym=None):
if m.is_Number:
if m.is_Integer and m.is_nonnegative:
# Euler numbers
if sym is None:
if m.is_odd:
return S.Zero
from mpmath import mp
m = m._to_mpmath(mp.prec)
res = mp.eulernum(m, exact=True)
return Integer(res)
# Euler polynomial
else:
from sympy.core.evalf import pure_complex
reim = pure_complex(sym, or_real=True)
# Evaluate polynomial numerically using mpmath
if reim and all(a.is_Float or a.is_Integer for a in reim) \
and any(a.is_Float for a in reim):
from mpmath import mp
from sympy import Expr
m = int(m)
# XXX ComplexFloat (#12192) would be nice here, above
prec = min([a._prec for a in reim if a.is_Float])
with workprec(prec):
res = mp.eulerpoly(m, sym)
return Expr._from_mpmath(res, prec)
# Construct polynomial symbolically from definition
m, result = int(m), []
for k in range(m + 1):
result.append(binomial(m, k)*cls(k)/(2**k)*(sym - S.Half)**(m - k))
return Add(*result).expand()
else:
raise ValueError("Euler numbers are defined only"
" for nonnegative integer indices.")
if sym is None:
if m.is_odd and m.is_positive:
return S.Zero
def _eval_rewrite_as_Sum(self, n, x=None, **kwargs):
from sympy import Sum
if x is None and n.is_even:
k = Dummy("k", integer=True)
j = Dummy("j", integer=True)
n = n / 2
Em = (S.ImaginaryUnit * Sum(Sum(binomial(k, j) * ((-1)**j * (k - 2*j)**(2*n + 1)) /
(2**k*S.ImaginaryUnit**k * k), (j, 0, k)), (k, 1, 2*n + 1)))
return Em
if x:
k = Dummy("k", integer=True)
return Sum(binomial(n, k)*euler(k)/2**k*(x - S.Half)**(n - k), (k, 0, n))
def _eval_evalf(self, prec):
m, x = (self.args[0], None) if len(self.args) == 1 else self.args
if x is None and m.is_Integer and m.is_nonnegative:
from mpmath import mp
from sympy import Expr
m = m._to_mpmath(prec)
with workprec(prec):
res = mp.eulernum(m)
return Expr._from_mpmath(res, prec)
if x and x.is_number and m.is_Integer and m.is_nonnegative:
from mpmath import mp
from sympy import Expr
m = int(m)
x = x._to_mpmath(prec)
with workprec(prec):
res = mp.eulerpoly(m, x)
return Expr._from_mpmath(res, prec)
#----------------------------------------------------------------------------#
# #
# Catalan numbers #
# #
#----------------------------------------------------------------------------#
class catalan(Function):
r"""
Catalan numbers
The `n^{th}` catalan number is given by:
.. math :: C_n = \frac{1}{n+1} \binom{2n}{n}
* ``catalan(n)`` gives the `n^{th}` Catalan number, `C_n`
Examples
========
>>> from sympy import (Symbol, binomial, gamma, hyper, catalan,
... diff, combsimp, Rational, I)
>>> [catalan(i) for i in range(1,10)]
[1, 2, 5, 14, 42, 132, 429, 1430, 4862]
>>> n = Symbol("n", integer=True)
>>> catalan(n)
catalan(n)
Catalan numbers can be transformed into several other, identical
expressions involving other mathematical functions
>>> catalan(n).rewrite(binomial)
binomial(2*n, n)/(n + 1)
>>> catalan(n).rewrite(gamma)
4**n*gamma(n + 1/2)/(sqrt(pi)*gamma(n + 2))
>>> catalan(n).rewrite(hyper)
hyper((1 - n, -n), (2,), 1)
For some non-integer values of n we can get closed form
expressions by rewriting in terms of gamma functions:
>>> catalan(Rational(1, 2)).rewrite(gamma)
8/(3*pi)
We can differentiate the Catalan numbers C(n) interpreted as a
continuous real function in n:
>>> diff(catalan(n), n)
(polygamma(0, n + 1/2) - polygamma(0, n + 2) + log(4))*catalan(n)
As a more advanced example consider the following ratio
between consecutive numbers:
>>> combsimp((catalan(n + 1)/catalan(n)).rewrite(binomial))
2*(2*n + 1)/(n + 2)
The Catalan numbers can be generalized to complex numbers:
>>> catalan(I).rewrite(gamma)
4**I*gamma(1/2 + I)/(sqrt(pi)*gamma(2 + I))
and evaluated with arbitrary precision:
>>> catalan(I).evalf(20)
0.39764993382373624267 - 0.020884341620842555705*I
See Also
========
bell, bernoulli, euler, fibonacci, harmonic, lucas, genocchi, partition, tribonacci
sympy.functions.combinatorial.factorials.binomial
References
==========
.. [1] https://en.wikipedia.org/wiki/Catalan_number
.. [2] http://mathworld.wolfram.com/CatalanNumber.html
.. [3] http://functions.wolfram.com/GammaBetaErf/CatalanNumber/
.. [4] http://geometer.org/mathcircles/catalan.pdf
"""
@classmethod
def eval(cls, n):
from sympy import gamma
if (n.is_Integer and n.is_nonnegative) or \
(n.is_noninteger and n.is_negative):
return 4**n*gamma(n + S.Half)/(gamma(S.Half)*gamma(n + 2))
if (n.is_integer and n.is_negative):
if (n + 1).is_negative:
return S.Zero
if (n + 1).is_zero:
return Rational(-1, 2)
def fdiff(self, argindex=1):
from sympy import polygamma, log
n = self.args[0]
return catalan(n)*(polygamma(0, n + S.Half) - polygamma(0, n + 2) + log(4))
def _eval_rewrite_as_binomial(self, n, **kwargs):
return binomial(2*n, n)/(n + 1)
def _eval_rewrite_as_factorial(self, n, **kwargs):
return factorial(2*n) / (factorial(n+1) * factorial(n))
def _eval_rewrite_as_gamma(self, n, **kwargs):
from sympy import gamma
# The gamma function allows to generalize Catalan numbers to complex n
return 4**n*gamma(n + S.Half)/(gamma(S.Half)*gamma(n + 2))
def _eval_rewrite_as_hyper(self, n, **kwargs):
from sympy import hyper
return hyper([1 - n, -n], [2], 1)
def _eval_rewrite_as_Product(self, n, **kwargs):
from sympy import Product
if not (n.is_integer and n.is_nonnegative):
return self
k = Dummy('k', integer=True, positive=True)
return Product((n + k) / k, (k, 2, n))
def _eval_is_integer(self):
if self.args[0].is_integer and self.args[0].is_nonnegative:
return True
def _eval_is_positive(self):
if self.args[0].is_nonnegative:
return True
def _eval_is_composite(self):
if self.args[0].is_integer and (self.args[0] - 3).is_positive:
return True
def _eval_evalf(self, prec):
from sympy import gamma
if self.args[0].is_number:
return self.rewrite(gamma)._eval_evalf(prec)
#----------------------------------------------------------------------------#
# #
# Genocchi numbers #
# #
#----------------------------------------------------------------------------#
class genocchi(Function):
r"""
Genocchi numbers
The Genocchi numbers are a sequence of integers `G_n` that satisfy the
relation:
.. math:: \frac{2t}{e^t + 1} = \sum_{n=1}^\infty \frac{G_n t^n}{n!}
Examples
========
>>> from sympy import Symbol
>>> from sympy.functions import genocchi
>>> [genocchi(n) for n in range(1, 9)]
[1, -1, 0, 1, 0, -3, 0, 17]
>>> n = Symbol('n', integer=True, positive=True)
>>> genocchi(2*n + 1)
0
See Also
========
bell, bernoulli, catalan, euler, fibonacci, harmonic, lucas, partition, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Genocchi_number
.. [2] http://mathworld.wolfram.com/GenocchiNumber.html
"""
@classmethod
def eval(cls, n):
if n.is_Number:
if (not n.is_Integer) or n.is_nonpositive:
raise ValueError("Genocchi numbers are defined only for " +
"positive integers")
return 2 * (1 - S(2) ** n) * bernoulli(n)
if n.is_odd and (n - 1).is_positive:
return S.Zero
if (n - 1).is_zero:
return S.One
def _eval_rewrite_as_bernoulli(self, n, **kwargs):
if n.is_integer and n.is_nonnegative:
return (1 - S(2) ** n) * bernoulli(n) * 2
def _eval_is_integer(self):
if self.args[0].is_integer and self.args[0].is_positive:
return True
def _eval_is_negative(self):
n = self.args[0]
if n.is_integer and n.is_positive:
if n.is_odd:
return False
return (n / 2).is_odd
def _eval_is_positive(self):
n = self.args[0]
if n.is_integer and n.is_positive:
if n.is_odd:
return fuzzy_not((n - 1).is_positive)
return (n / 2).is_even
def _eval_is_even(self):
n = self.args[0]
if n.is_integer and n.is_positive:
if n.is_even:
return False
return (n - 1).is_positive
def _eval_is_odd(self):
n = self.args[0]
if n.is_integer and n.is_positive:
if n.is_even:
return True
return fuzzy_not((n - 1).is_positive)
def _eval_is_prime(self):
n = self.args[0]
# only G_6 = -3 and G_8 = 17 are prime,
# but SymPy does not consider negatives as prime
# so only n=8 is tested
return (n - 8).is_zero
#----------------------------------------------------------------------------#
# #
# Partition numbers #
# #
#----------------------------------------------------------------------------#
_npartition = [1, 1]
class partition(Function):
r"""
Partition numbers
The Partition numbers are a sequence of integers `p_n` that represent the
number of distinct ways of representing `n` as a sum of natural numbers
(with order irrelevant). The generating function for `p_n` is given by:
.. math:: \sum_{n=0}^\infty p_n x^n = \prod_{k=1}^\infty (1 - x^k)^{-1}
Examples
========
>>> from sympy import Symbol
>>> from sympy.functions import partition
>>> [partition(n) for n in range(9)]
[1, 1, 2, 3, 5, 7, 11, 15, 22]
>>> n = Symbol('n', integer=True, negative=True)
>>> partition(n)
0
See Also
========
bell, bernoulli, catalan, euler, fibonacci, harmonic, lucas, genocchi, tribonacci
References
==========
.. [1] https://en.wikipedia.org/wiki/Partition_(number_theory%29
.. [2] https://en.wikipedia.org/wiki/Pentagonal_number_theorem
"""
@staticmethod
def _partition(n):
L = len(_npartition)
if n < L:
return _npartition[n]
# lengthen cache
for _n in range(L, n + 1):
v, p, i = 0, 0, 0
while 1:
s = 0
p += 3*i + 1 # p = pentagonal number: 1, 5, 12, ...
if _n >= p:
s += _npartition[_n - p]
i += 1
gp = p + i # gp = generalized pentagonal: 2, 7, 15, ...
if _n >= gp:
s += _npartition[_n - gp]
if s == 0:
break
else:
v += s if i%2 == 1 else -s
_npartition.append(v)
return v
@classmethod
def eval(cls, n):
is_int = n.is_integer
if is_int == False:
raise ValueError("Partition numbers are defined only for "
"integers")
elif is_int:
if n.is_negative:
return S.Zero
if n.is_zero or (n - 1).is_zero:
return S.One
if n.is_Integer:
return Integer(cls._partition(n))
def _eval_is_integer(self):
if self.args[0].is_integer:
return True
def _eval_is_negative(self):
if self.args[0].is_integer:
return False
def _eval_is_positive(self):
n = self.args[0]
if n.is_nonnegative and n.is_integer:
return True
#######################################################################
###
### Functions for enumerating partitions, permutations and combinations
###
#######################################################################
class _MultisetHistogram(tuple):
pass
_N = -1
_ITEMS = -2
_M = slice(None, _ITEMS)
def _multiset_histogram(n):
"""Return tuple used in permutation and combination counting. Input
is a dictionary giving items with counts as values or a sequence of
items (which need not be sorted).
The data is stored in a class deriving from tuple so it is easily
recognized and so it can be converted easily to a list.
"""
if isinstance(n, dict): # item: count
if not all(isinstance(v, int) and v >= 0 for v in n.values()):
raise ValueError
tot = sum(n.values())
items = sum(1 for k in n if n[k] > 0)
return _MultisetHistogram([n[k] for k in n if n[k] > 0] + [items, tot])
else:
n = list(n)
s = set(n)
if len(s) == len(n):
n = [1]*len(n)
n.extend([len(n), len(n)])
return _MultisetHistogram(n)
m = dict(zip(s, range(len(s))))
d = dict(zip(range(len(s)), [0]*len(s)))
for i in n:
d[m[i]] += 1
return _multiset_histogram(d)
def nP(n, k=None, replacement=False):
"""Return the number of permutations of ``n`` items taken ``k`` at a time.
Possible values for ``n``:
integer - set of length ``n``
sequence - converted to a multiset internally
multiset - {element: multiplicity}
If ``k`` is None then the total of all permutations of length 0
through the number of items represented by ``n`` will be returned.
If ``replacement`` is True then a given item can appear more than once
in the ``k`` items. (For example, for 'ab' permutations of 2 would
include 'aa', 'ab', 'ba' and 'bb'.) The multiplicity of elements in
``n`` is ignored when ``replacement`` is True but the total number
of elements is considered since no element can appear more times than
the number of elements in ``n``.
Examples
========
>>> from sympy.functions.combinatorial.numbers import nP
>>> from sympy.utilities.iterables import multiset_permutations, multiset
>>> nP(3, 2)
6
>>> nP('abc', 2) == nP(multiset('abc'), 2) == 6
True
>>> nP('aab', 2)
3
>>> nP([1, 2, 2], 2)
3
>>> [nP(3, i) for i in range(4)]
[1, 3, 6, 6]
>>> nP(3) == sum(_)
True
When ``replacement`` is True, each item can have multiplicity
equal to the length represented by ``n``:
>>> nP('aabc', replacement=True)
121
>>> [len(list(multiset_permutations('aaaabbbbcccc', i))) for i in range(5)]
[1, 3, 9, 27, 81]
>>> sum(_)
121
See Also
========
sympy.utilities.iterables.multiset_permutations
References
==========
.. [1] https://en.wikipedia.org/wiki/Permutation
"""
try:
n = as_int(n)
except ValueError:
return Integer(_nP(_multiset_histogram(n), k, replacement))
return Integer(_nP(n, k, replacement))
@cacheit
def _nP(n, k=None, replacement=False):
from sympy.functions.combinatorial.factorials import factorial
from sympy.core.mul import prod
if k == 0:
return 1
if isinstance(n, SYMPY_INTS): # n different items
# assert n >= 0
if k is None:
return sum(_nP(n, i, replacement) for i in range(n + 1))
elif replacement:
return n**k
elif k > n:
return 0
elif k == n:
return factorial(k)
elif k == 1:
return n
else:
# assert k >= 0
return _product(n - k + 1, n)
elif isinstance(n, _MultisetHistogram):
if k is None:
return sum(_nP(n, i, replacement) for i in range(n[_N] + 1))
elif replacement:
return n[_ITEMS]**k
elif k == n[_N]:
return factorial(k)/prod([factorial(i) for i in n[_M] if i > 1])
elif k > n[_N]:
return 0
elif k == 1:
return n[_ITEMS]
else:
# assert k >= 0
tot = 0
n = list(n)
for i in range(len(n[_M])):
if not n[i]:
continue
n[_N] -= 1
if n[i] == 1:
n[i] = 0
n[_ITEMS] -= 1
tot += _nP(_MultisetHistogram(n), k - 1)
n[_ITEMS] += 1
n[i] = 1
else:
n[i] -= 1
tot += _nP(_MultisetHistogram(n), k - 1)
n[i] += 1
n[_N] += 1
return tot
@cacheit
def _AOP_product(n):
"""for n = (m1, m2, .., mk) return the coefficients of the polynomial,
prod(sum(x**i for i in range(nj + 1)) for nj in n); i.e. the coefficients
of the product of AOPs (all-one polynomials) or order given in n. The
resulting coefficient corresponding to x**r is the number of r-length
combinations of sum(n) elements with multiplicities given in n.
The coefficients are given as a default dictionary (so if a query is made
for a key that is not present, 0 will be returned).
Examples
========
>>> from sympy.functions.combinatorial.numbers import _AOP_product
>>> from sympy.abc import x
>>> n = (2, 2, 3) # e.g. aabbccc
>>> prod = ((x**2 + x + 1)*(x**2 + x + 1)*(x**3 + x**2 + x + 1)).expand()
>>> c = _AOP_product(n); dict(c)
{0: 1, 1: 3, 2: 6, 3: 8, 4: 8, 5: 6, 6: 3, 7: 1}
>>> [c[i] for i in range(8)] == [prod.coeff(x, i) for i in range(8)]
True
The generating poly used here is the same as that listed in
http://tinyurl.com/cep849r, but in a refactored form.
"""
from collections import defaultdict
n = list(n)
ord = sum(n)
need = (ord + 2)//2
rv = [1]*(n.pop() + 1)
rv.extend([0]*(need - len(rv)))
rv = rv[:need]
while n:
ni = n.pop()
N = ni + 1
was = rv[:]
for i in range(1, min(N, len(rv))):
rv[i] += rv[i - 1]
for i in range(N, need):
rv[i] += rv[i - 1] - was[i - N]
rev = list(reversed(rv))
if ord % 2:
rv = rv + rev
else:
rv[-1:] = rev
d = defaultdict(int)
for i in range(len(rv)):
d[i] = rv[i]
return d
def nC(n, k=None, replacement=False):
"""Return the number of combinations of ``n`` items taken ``k`` at a time.
Possible values for ``n``:
integer - set of length ``n``
sequence - converted to a multiset internally
multiset - {element: multiplicity}
If ``k`` is None then the total of all combinations of length 0
through the number of items represented in ``n`` will be returned.
If ``replacement`` is True then a given item can appear more than once
in the ``k`` items. (For example, for 'ab' sets of 2 would include 'aa',
'ab', and 'bb'.) The multiplicity of elements in ``n`` is ignored when
``replacement`` is True but the total number of elements is considered
since no element can appear more times than the number of elements in
``n``.
Examples
========
>>> from sympy.functions.combinatorial.numbers import nC
>>> from sympy.utilities.iterables import multiset_combinations
>>> nC(3, 2)
3
>>> nC('abc', 2)
3
>>> nC('aab', 2)
2
When ``replacement`` is True, each item can have multiplicity
equal to the length represented by ``n``:
>>> nC('aabc', replacement=True)
35
>>> [len(list(multiset_combinations('aaaabbbbcccc', i))) for i in range(5)]
[1, 3, 6, 10, 15]
>>> sum(_)
35
If there are ``k`` items with multiplicities ``m_1, m_2, ..., m_k``
then the total of all combinations of length 0 through ``k`` is the
product, ``(m_1 + 1)*(m_2 + 1)*...*(m_k + 1)``. When the multiplicity
of each item is 1 (i.e., k unique items) then there are 2**k
combinations. For example, if there are 4 unique items, the total number
of combinations is 16:
>>> sum(nC(4, i) for i in range(5))
16
See Also
========
sympy.utilities.iterables.multiset_combinations
References
==========
.. [1] https://en.wikipedia.org/wiki/Combination
.. [2] http://tinyurl.com/cep849r
"""
from sympy.functions.combinatorial.factorials import binomial
from sympy.core.mul import prod
if isinstance(n, SYMPY_INTS):
if k is None:
if not replacement:
return 2**n
return sum(nC(n, i, replacement) for i in range(n + 1))
if k < 0:
raise ValueError("k cannot be negative")
if replacement:
return binomial(n + k - 1, k)
return binomial(n, k)
if isinstance(n, _MultisetHistogram):
N = n[_N]
if k is None:
if not replacement:
return prod(m + 1 for m in n[_M])
return sum(nC(n, i, replacement) for i in range(N + 1))
elif replacement:
return nC(n[_ITEMS], k, replacement)
# assert k >= 0
elif k in (1, N - 1):
return n[_ITEMS]
elif k in (0, N):
return 1
return _AOP_product(tuple(n[_M]))[k]
else:
return nC(_multiset_histogram(n), k, replacement)
def _eval_stirling1(n, k):
if n == k == 0:
return S.One
if 0 in (n, k):
return S.Zero
# some special values
if n == k:
return S.One
elif k == n - 1:
return binomial(n, 2)
elif k == n - 2:
return (3*n - 1)*binomial(n, 3)/4
elif k == n - 3:
return binomial(n, 2)*binomial(n, 4)
return _stirling1(n, k)
@cacheit
def _stirling1(n, k):
row = [0, 1]+[0]*(k-1) # for n = 1
for i in range(2, n+1):
for j in range(min(k,i), 0, -1):
row[j] = (i-1) * row[j] + row[j-1]
return Integer(row[k])
def _eval_stirling2(n, k):
if n == k == 0:
return S.One
if 0 in (n, k):
return S.Zero
# some special values
if n == k:
return S.One
elif k == n - 1:
return binomial(n, 2)
elif k == 1:
return S.One
elif k == 2:
return Integer(2**(n - 1) - 1)
return _stirling2(n, k)
@cacheit
def _stirling2(n, k):
row = [0, 1]+[0]*(k-1) # for n = 1
for i in range(2, n+1):
for j in range(min(k,i), 0, -1):
row[j] = j * row[j] + row[j-1]
return Integer(row[k])
def stirling(n, k, d=None, kind=2, signed=False):
r"""Return Stirling number $S(n, k)$ of the first or second (default) kind.
The sum of all Stirling numbers of the second kind for $k = 1$
through $n$ is ``bell(n)``. The recurrence relationship for these numbers
is:
.. math :: {0 \brace 0} = 1; {n \brace 0} = {0 \brace k} = 0;
.. math :: {{n+1} \brace k} = j {n \brace k} + {n \brace {k-1}}
where $j$ is:
$n$ for Stirling numbers of the first kind,
$-n$ for signed Stirling numbers of the first kind,
$k$ for Stirling numbers of the second kind.
The first kind of Stirling number counts the number of permutations of
``n`` distinct items that have ``k`` cycles; the second kind counts the
ways in which ``n`` distinct items can be partitioned into ``k`` parts.
If ``d`` is given, the "reduced Stirling number of the second kind" is
returned: $S^{d}(n, k) = S(n - d + 1, k - d + 1)$ with $n \ge k \ge d$.
(This counts the ways to partition $n$ consecutive integers into $k$
groups with no pairwise difference less than $d$. See example below.)
To obtain the signed Stirling numbers of the first kind, use keyword
``signed=True``. Using this keyword automatically sets ``kind`` to 1.
Examples
========
>>> from sympy.functions.combinatorial.numbers import stirling, bell
>>> from sympy.combinatorics import Permutation
>>> from sympy.utilities.iterables import multiset_partitions, permutations
First kind (unsigned by default):
>>> [stirling(6, i, kind=1) for i in range(7)]
[0, 120, 274, 225, 85, 15, 1]
>>> perms = list(permutations(range(4)))
>>> [sum(Permutation(p).cycles == i for p in perms) for i in range(5)]
[0, 6, 11, 6, 1]
>>> [stirling(4, i, kind=1) for i in range(5)]
[0, 6, 11, 6, 1]
First kind (signed):
>>> [stirling(4, i, signed=True) for i in range(5)]
[0, -6, 11, -6, 1]
Second kind:
>>> [stirling(10, i) for i in range(12)]
[0, 1, 511, 9330, 34105, 42525, 22827, 5880, 750, 45, 1, 0]
>>> sum(_) == bell(10)
True
>>> len(list(multiset_partitions(range(4), 2))) == stirling(4, 2)
True
Reduced second kind:
>>> from sympy import subsets, oo
>>> def delta(p):
... if len(p) == 1:
... return oo
... return min(abs(i[0] - i[1]) for i in subsets(p, 2))
>>> parts = multiset_partitions(range(5), 3)
>>> d = 2
>>> sum(1 for p in parts if all(delta(i) >= d for i in p))
7
>>> stirling(5, 3, 2)
7
See Also
========
sympy.utilities.iterables.multiset_partitions
References
==========
.. [1] https://en.wikipedia.org/wiki/Stirling_numbers_of_the_first_kind
.. [2] https://en.wikipedia.org/wiki/Stirling_numbers_of_the_second_kind
"""
# TODO: make this a class like bell()
n = as_int(n)
k = as_int(k)
if n < 0:
raise ValueError('n must be nonnegative')
if k > n:
return S.Zero
if d:
# assert k >= d
# kind is ignored -- only kind=2 is supported
return _eval_stirling2(n - d + 1, k - d + 1)
elif signed:
# kind is ignored -- only kind=1 is supported
return (-1)**(n - k)*_eval_stirling1(n, k)
if kind == 1:
return _eval_stirling1(n, k)
elif kind == 2:
return _eval_stirling2(n, k)
else:
raise ValueError('kind must be 1 or 2, not %s' % k)
@cacheit
def _nT(n, k):
"""Return the partitions of ``n`` items into ``k`` parts. This
is used by ``nT`` for the case when ``n`` is an integer."""
# really quick exits
if k > n or k < 0:
return 0
if k == n or k == 1:
return 1
if k == 0:
return 0
# exits that could be done below but this is quicker
if k == 2:
return n//2
d = n - k
if d <= 3:
return d
# quick exit
if 3*k >= n: # or, equivalently, 2*k >= d
# all the information needed in this case
# will be in the cache needed to calculate
# partition(d), so...
# update cache
tot = partition._partition(d)
# and correct for values not needed
if d - k > 0:
tot -= sum(_npartition[:d - k])
return tot
# regular exit
# nT(n, k) = Sum(nT(n - k, m), (m, 1, k));
# calculate needed nT(i, j) values
p = [1]*d
for i in range(2, k + 1):
for m in range(i + 1, d):
p[m] += p[m - i]
d -= 1
# if p[0] were appended to the end of p then the last
# k values of p are the nT(n, j) values for 0 < j < k in reverse
# order p[-1] = nT(n, 1), p[-2] = nT(n, 2), etc.... Instead of
# putting the 1 from p[0] there, however, it is simply added to
# the sum below which is valid for 1 < k <= n//2
return (1 + sum(p[1 - k:]))
def nT(n, k=None):
"""Return the number of ``k``-sized partitions of ``n`` items.
Possible values for ``n``:
integer - ``n`` identical items
sequence - converted to a multiset internally
multiset - {element: multiplicity}
Note: the convention for ``nT`` is different than that of ``nC`` and
``nP`` in that
here an integer indicates ``n`` *identical* items instead of a set of
length ``n``; this is in keeping with the ``partitions`` function which
treats its integer-``n`` input like a list of ``n`` 1s. One can use
``range(n)`` for ``n`` to indicate ``n`` distinct items.
If ``k`` is None then the total number of ways to partition the elements
represented in ``n`` will be returned.
Examples
========
>>> from sympy.functions.combinatorial.numbers import nT
Partitions of the given multiset:
>>> [nT('aabbc', i) for i in range(1, 7)]
[1, 8, 11, 5, 1, 0]
>>> nT('aabbc') == sum(_)
True
>>> [nT("mississippi", i) for i in range(1, 12)]
[1, 74, 609, 1521, 1768, 1224, 579, 197, 50, 9, 1]
Partitions when all items are identical:
>>> [nT(5, i) for i in range(1, 6)]
[1, 2, 2, 1, 1]
>>> nT('1'*5) == sum(_)
True
When all items are different:
>>> [nT(range(5), i) for i in range(1, 6)]
[1, 15, 25, 10, 1]
>>> nT(range(5)) == sum(_)
True
Partitions of an integer expressed as a sum of positive integers:
>>> from sympy.functions.combinatorial.numbers import partition
>>> partition(4)
5
>>> nT(4, 1) + nT(4, 2) + nT(4, 3) + nT(4, 4)
5
>>> nT('1'*4)
5
See Also
========
sympy.utilities.iterables.partitions
sympy.utilities.iterables.multiset_partitions
sympy.functions.combinatorial.numbers.partition
References
==========
.. [1] http://undergraduate.csse.uwa.edu.au/units/CITS7209/partition.pdf
"""
from sympy.utilities.enumerative import MultisetPartitionTraverser
if isinstance(n, SYMPY_INTS):
# n identical items
if k is None:
return partition(n)
if isinstance(k, SYMPY_INTS):
n = as_int(n)
k = as_int(k)
return Integer(_nT(n, k))
if not isinstance(n, _MultisetHistogram):
try:
# if n contains hashable items there is some
# quick handling that can be done
u = len(set(n))
if u <= 1:
return nT(len(n), k)
elif u == len(n):
n = range(u)
raise TypeError
except TypeError:
n = _multiset_histogram(n)
N = n[_N]
if k is None and N == 1:
return 1
if k in (1, N):
return 1
if k == 2 or N == 2 and k is None:
m, r = divmod(N, 2)
rv = sum(nC(n, i) for i in range(1, m + 1))
if not r:
rv -= nC(n, m)//2
if k is None:
rv += 1 # for k == 1
return rv
if N == n[_ITEMS]:
# all distinct
if k is None:
return bell(N)
return stirling(N, k)
m = MultisetPartitionTraverser()
if k is None:
return m.count_partitions(n[_M])
# MultisetPartitionTraverser does not have a range-limited count
# method, so need to enumerate and count
tot = 0
for discard in m.enum_range(n[_M], k-1, k):
tot += 1
return tot
|
d76d819d1aeecb8c0c753e926ca89b47624b6fe263277ed6021cc13acc7cc8c9 | from typing import List
from sympy.core import S, sympify, Dummy, Mod
from sympy.core.cache import cacheit
from sympy.core.compatibility import reduce, HAS_GMPY
from sympy.core.function import Function, ArgumentIndexError
from sympy.core.logic import fuzzy_and
from sympy.core.numbers import Integer, pi
from sympy.core.relational import Eq
from sympy.ntheory import sieve
from sympy.polys.polytools import Poly
from math import sqrt as _sqrt
class CombinatorialFunction(Function):
"""Base class for combinatorial functions. """
def _eval_simplify(self, **kwargs):
from sympy.simplify.combsimp import combsimp
# combinatorial function with non-integer arguments is
# automatically passed to gammasimp
expr = combsimp(self)
measure = kwargs['measure']
if measure(expr) <= kwargs['ratio']*measure(self):
return expr
return self
###############################################################################
######################## FACTORIAL and MULTI-FACTORIAL ########################
###############################################################################
class factorial(CombinatorialFunction):
r"""Implementation of factorial function over nonnegative integers.
By convention (consistent with the gamma function and the binomial
coefficients), factorial of a negative integer is complex infinity.
The factorial is very important in combinatorics where it gives
the number of ways in which `n` objects can be permuted. It also
arises in calculus, probability, number theory, etc.
There is strict relation of factorial with gamma function. In
fact `n! = gamma(n+1)` for nonnegative integers. Rewrite of this
kind is very useful in case of combinatorial simplification.
Computation of the factorial is done using two algorithms. For
small arguments a precomputed look up table is used. However for bigger
input algorithm Prime-Swing is used. It is the fastest algorithm
known and computes `n!` via prime factorization of special class
of numbers, called here the 'Swing Numbers'.
Examples
========
>>> from sympy import Symbol, factorial, S
>>> n = Symbol('n', integer=True)
>>> factorial(0)
1
>>> factorial(7)
5040
>>> factorial(-2)
zoo
>>> factorial(n)
factorial(n)
>>> factorial(2*n)
factorial(2*n)
>>> factorial(S(1)/2)
factorial(1/2)
See Also
========
factorial2, RisingFactorial, FallingFactorial
"""
def fdiff(self, argindex=1):
from sympy import gamma, polygamma
if argindex == 1:
return gamma(self.args[0] + 1)*polygamma(0, self.args[0] + 1)
else:
raise ArgumentIndexError(self, argindex)
_small_swing = [
1, 1, 1, 3, 3, 15, 5, 35, 35, 315, 63, 693, 231, 3003, 429, 6435, 6435, 109395,
12155, 230945, 46189, 969969, 88179, 2028117, 676039, 16900975, 1300075,
35102025, 5014575, 145422675, 9694845, 300540195, 300540195
]
_small_factorials = [] # type: List[int]
@classmethod
def _swing(cls, n):
if n < 33:
return cls._small_swing[n]
else:
N, primes = int(_sqrt(n)), []
for prime in sieve.primerange(3, N + 1):
p, q = 1, n
while True:
q //= prime
if q > 0:
if q & 1 == 1:
p *= prime
else:
break
if p > 1:
primes.append(p)
for prime in sieve.primerange(N + 1, n//3 + 1):
if (n // prime) & 1 == 1:
primes.append(prime)
L_product = R_product = 1
for prime in sieve.primerange(n//2 + 1, n + 1):
L_product *= prime
for prime in primes:
R_product *= prime
return L_product*R_product
@classmethod
def _recursive(cls, n):
if n < 2:
return 1
else:
return (cls._recursive(n//2)**2)*cls._swing(n)
@classmethod
def eval(cls, n):
n = sympify(n)
if n.is_Number:
if n.is_zero:
return S.One
elif n is S.Infinity:
return S.Infinity
elif n.is_Integer:
if n.is_negative:
return S.ComplexInfinity
else:
n = n.p
if n < 20:
if not cls._small_factorials:
result = 1
for i in range(1, 20):
result *= i
cls._small_factorials.append(result)
result = cls._small_factorials[n-1]
# GMPY factorial is faster, use it when available
elif HAS_GMPY:
from sympy.core.compatibility import gmpy
result = gmpy.fac(n)
else:
bits = bin(n).count('1')
result = cls._recursive(n)*2**(n - bits)
return Integer(result)
def _facmod(self, n, q):
res, N = 1, int(_sqrt(n))
# Exponent of prime p in n! is e_p(n) = [n/p] + [n/p**2] + ...
# for p > sqrt(n), e_p(n) < sqrt(n), the primes with [n/p] = m,
# occur consecutively and are grouped together in pw[m] for
# simultaneous exponentiation at a later stage
pw = [1]*N
m = 2 # to initialize the if condition below
for prime in sieve.primerange(2, n + 1):
if m > 1:
m, y = 0, n // prime
while y:
m += y
y //= prime
if m < N:
pw[m] = pw[m]*prime % q
else:
res = res*pow(prime, m, q) % q
for ex, bs in enumerate(pw):
if ex == 0 or bs == 1:
continue
if bs == 0:
return 0
res = res*pow(bs, ex, q) % q
return res
def _eval_Mod(self, q):
n = self.args[0]
if n.is_integer and n.is_nonnegative and q.is_integer:
aq = abs(q)
d = aq - n
if d.is_nonpositive:
return S.Zero
else:
isprime = aq.is_prime
if d == 1:
# Apply Wilson's theorem (if a natural number n > 1
# is a prime number, then (n-1)! = -1 mod n) and
# its inverse (if n > 4 is a composite number, then
# (n-1)! = 0 mod n)
if isprime:
return S(-1 % q)
elif isprime is False and (aq - 6).is_nonnegative:
return S.Zero
elif n.is_Integer and q.is_Integer:
n, d, aq = map(int, (n, d, aq))
if isprime and (d - 1 < n):
fc = self._facmod(d - 1, aq)
fc = pow(fc, aq - 2, aq)
if d%2:
fc = -fc
else:
fc = self._facmod(n, aq)
return S(fc % q)
def _eval_rewrite_as_gamma(self, n, **kwargs):
from sympy import gamma
return gamma(n + 1)
def _eval_rewrite_as_Product(self, n, **kwargs):
from sympy import Product
if n.is_nonnegative and n.is_integer:
i = Dummy('i', integer=True)
return Product(i, (i, 1, n))
def _eval_is_integer(self):
if self.args[0].is_integer and self.args[0].is_nonnegative:
return True
def _eval_is_positive(self):
if self.args[0].is_integer and self.args[0].is_nonnegative:
return True
def _eval_is_even(self):
x = self.args[0]
if x.is_integer and x.is_nonnegative:
return (x - 2).is_nonnegative
def _eval_is_composite(self):
x = self.args[0]
if x.is_integer and x.is_nonnegative:
return (x - 3).is_nonnegative
def _eval_is_real(self):
x = self.args[0]
if x.is_nonnegative or x.is_noninteger:
return True
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0]
arg_1 = arg.as_leading_term(x)
if Order(x, x).contains(arg_1):
return S.One
if Order(1, x).contains(arg_1):
return self.func(arg_1)
####################################################
# The correct result here should be 'None'. #
# Indeed arg in not bounded as x tends to 0. #
# Consequently the series expansion does not admit #
# the leading term. #
# For compatibility reasons, the return value here #
# is the original function, i.e. factorial(arg), #
# instead of None. #
####################################################
return self.func(arg)
class MultiFactorial(CombinatorialFunction):
pass
class subfactorial(CombinatorialFunction):
r"""The subfactorial counts the derangements of n items and is
defined for non-negative integers as:
.. math:: !n = \begin{cases} 1 & n = 0 \\ 0 & n = 1 \\
(n-1)(!(n-1) + !(n-2)) & n > 1 \end{cases}
It can also be written as ``int(round(n!/exp(1)))`` but the
recursive definition with caching is implemented for this function.
An interesting analytic expression is the following [2]_
.. math:: !x = \Gamma(x + 1, -1)/e
which is valid for non-negative integers `x`. The above formula
is not very useful incase of non-integers. :math:`\Gamma(x + 1, -1)` is
single-valued only for integral arguments `x`, elsewhere on the positive
real axis it has an infinite number of branches none of which are real.
References
==========
.. [1] https://en.wikipedia.org/wiki/Subfactorial
.. [2] http://mathworld.wolfram.com/Subfactorial.html
Examples
========
>>> from sympy import subfactorial
>>> from sympy.abc import n
>>> subfactorial(n + 1)
subfactorial(n + 1)
>>> subfactorial(5)
44
See Also
========
sympy.functions.combinatorial.factorials.factorial,
sympy.utilities.iterables.generate_derangements,
sympy.functions.special.gamma_functions.uppergamma
"""
@classmethod
@cacheit
def _eval(self, n):
if not n:
return S.One
elif n == 1:
return S.Zero
else:
z1, z2 = 1, 0
for i in range(2, n + 1):
z1, z2 = z2, (i - 1)*(z2 + z1)
return z2
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg.is_Integer and arg.is_nonnegative:
return cls._eval(arg)
elif arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Infinity
def _eval_is_even(self):
if self.args[0].is_odd and self.args[0].is_nonnegative:
return True
def _eval_is_integer(self):
if self.args[0].is_integer and self.args[0].is_nonnegative:
return True
def _eval_rewrite_as_uppergamma(self, arg, **kwargs):
from sympy import uppergamma
return uppergamma(arg + 1, -1)/S.Exp1
def _eval_is_nonnegative(self):
if self.args[0].is_integer and self.args[0].is_nonnegative:
return True
def _eval_is_odd(self):
if self.args[0].is_even and self.args[0].is_nonnegative:
return True
class factorial2(CombinatorialFunction):
r"""The double factorial `n!!`, not to be confused with `(n!)!`
The double factorial is defined for nonnegative integers and for odd
negative integers as:
.. math:: n!! = \begin{cases} 1 & n = 0 \\
n(n-2)(n-4) \cdots 1 & n\ \text{positive odd} \\
n(n-2)(n-4) \cdots 2 & n\ \text{positive even} \\
(n+2)!!/(n+2) & n\ \text{negative odd} \end{cases}
References
==========
.. [1] https://en.wikipedia.org/wiki/Double_factorial
Examples
========
>>> from sympy import factorial2, var
>>> n = var('n')
>>> n
n
>>> factorial2(n + 1)
factorial2(n + 1)
>>> factorial2(5)
15
>>> factorial2(-1)
1
>>> factorial2(-5)
1/3
See Also
========
factorial, RisingFactorial, FallingFactorial
"""
@classmethod
def eval(cls, arg):
# TODO: extend this to complex numbers?
if arg.is_Number:
if not arg.is_Integer:
raise ValueError("argument must be nonnegative integer "
"or negative odd integer")
# This implementation is faster than the recursive one
# It also avoids "maximum recursion depth exceeded" runtime error
if arg.is_nonnegative:
if arg.is_even:
k = arg / 2
return 2**k * factorial(k)
return factorial(arg) / factorial2(arg - 1)
if arg.is_odd:
return arg*(S.NegativeOne)**((1 - arg)/2) / factorial2(-arg)
raise ValueError("argument must be nonnegative integer "
"or negative odd integer")
def _eval_is_even(self):
# Double factorial is even for every positive even input
n = self.args[0]
if n.is_integer:
if n.is_odd:
return False
if n.is_even:
if n.is_positive:
return True
if n.is_zero:
return False
def _eval_is_integer(self):
# Double factorial is an integer for every nonnegative input, and for
# -1 and -3
n = self.args[0]
if n.is_integer:
if (n + 1).is_nonnegative:
return True
if n.is_odd:
return (n + 3).is_nonnegative
def _eval_is_odd(self):
# Double factorial is odd for every odd input not smaller than -3, and
# for 0
n = self.args[0]
if n.is_odd:
return (n + 3).is_nonnegative
if n.is_even:
if n.is_positive:
return False
if n.is_zero:
return True
def _eval_is_positive(self):
# Double factorial is positive for every nonnegative input, and for
# every odd negative input which is of the form -1-4k for an
# nonnegative integer k
n = self.args[0]
if n.is_integer:
if (n + 1).is_nonnegative:
return True
if n.is_odd:
return ((n + 1) / 2).is_even
def _eval_rewrite_as_gamma(self, n, **kwargs):
from sympy import gamma, Piecewise, sqrt
return 2**(n/2)*gamma(n/2 + 1) * Piecewise((1, Eq(Mod(n, 2), 0)),
(sqrt(2/pi), Eq(Mod(n, 2), 1)))
###############################################################################
######################## RISING and FALLING FACTORIALS ########################
###############################################################################
class RisingFactorial(CombinatorialFunction):
r"""
Rising factorial (also called Pochhammer symbol) is a double valued
function arising in concrete mathematics, hypergeometric functions
and series expansions. It is defined by:
.. math:: rf(x,k) = x \cdot (x+1) \cdots (x+k-1)
where `x` can be arbitrary expression and `k` is an integer. For
more information check "Concrete mathematics" by Graham, pp. 66
or visit http://mathworld.wolfram.com/RisingFactorial.html page.
When `x` is a Poly instance of degree >= 1 with a single variable,
`rf(x,k) = x(y) \cdot x(y+1) \cdots x(y+k-1)`, where `y` is the
variable of `x`. This is as described in Peter Paule, "Greatest
Factorial Factorization and Symbolic Summation", Journal of
Symbolic Computation, vol. 20, pp. 235-268, 1995.
Examples
========
>>> from sympy import rf, symbols, factorial, ff, binomial, Poly
>>> from sympy.abc import x
>>> n, k = symbols('n k', integer=True)
>>> rf(x, 0)
1
>>> rf(1, 5)
120
>>> rf(x, 5) == x*(1 + x)*(2 + x)*(3 + x)*(4 + x)
True
>>> rf(Poly(x**3, x), 2)
Poly(x**6 + 3*x**5 + 3*x**4 + x**3, x, domain='ZZ')
Rewrite
>>> rf(x, k).rewrite(ff)
FallingFactorial(k + x - 1, k)
>>> rf(x, k).rewrite(binomial)
binomial(k + x - 1, k)*factorial(k)
>>> rf(n, k).rewrite(factorial)
factorial(k + n - 1)/factorial(n - 1)
See Also
========
factorial, factorial2, FallingFactorial
References
==========
.. [1] https://en.wikipedia.org/wiki/Pochhammer_symbol
"""
@classmethod
def eval(cls, x, k):
x = sympify(x)
k = sympify(k)
if x is S.NaN or k is S.NaN:
return S.NaN
elif x is S.One:
return factorial(k)
elif k.is_Integer:
if k.is_zero:
return S.One
else:
if k.is_positive:
if x is S.Infinity:
return S.Infinity
elif x is S.NegativeInfinity:
if k.is_odd:
return S.NegativeInfinity
else:
return S.Infinity
else:
if isinstance(x, Poly):
gens = x.gens
if len(gens)!= 1:
raise ValueError("rf only defined for "
"polynomials on one generator")
else:
return reduce(lambda r, i:
r*(x.shift(i)),
range(0, int(k)), 1)
else:
return reduce(lambda r, i: r*(x + i),
range(0, int(k)), 1)
else:
if x is S.Infinity:
return S.Infinity
elif x is S.NegativeInfinity:
return S.Infinity
else:
if isinstance(x, Poly):
gens = x.gens
if len(gens)!= 1:
raise ValueError("rf only defined for "
"polynomials on one generator")
else:
return 1/reduce(lambda r, i:
r*(x.shift(-i)),
range(1, abs(int(k)) + 1), 1)
else:
return 1/reduce(lambda r, i:
r*(x - i),
range(1, abs(int(k)) + 1), 1)
if k.is_integer == False:
if x.is_integer and x.is_negative:
return S.Zero
def _eval_rewrite_as_gamma(self, x, k, **kwargs):
from sympy import gamma
return gamma(x + k) / gamma(x)
def _eval_rewrite_as_FallingFactorial(self, x, k, **kwargs):
return FallingFactorial(x + k - 1, k)
def _eval_rewrite_as_factorial(self, x, k, **kwargs):
if x.is_integer and k.is_integer:
return factorial(k + x - 1) / factorial(x - 1)
def _eval_rewrite_as_binomial(self, x, k, **kwargs):
if k.is_integer:
return factorial(k) * binomial(x + k - 1, k)
def _eval_is_integer(self):
return fuzzy_and((self.args[0].is_integer, self.args[1].is_integer,
self.args[1].is_nonnegative))
def _sage_(self):
import sage.all as sage
return sage.rising_factorial(self.args[0]._sage_(),
self.args[1]._sage_())
class FallingFactorial(CombinatorialFunction):
r"""
Falling factorial (related to rising factorial) is a double valued
function arising in concrete mathematics, hypergeometric functions
and series expansions. It is defined by
.. math:: ff(x,k) = x \cdot (x-1) \cdots (x-k+1)
where `x` can be arbitrary expression and `k` is an integer. For
more information check "Concrete mathematics" by Graham, pp. 66
or visit http://mathworld.wolfram.com/FallingFactorial.html page.
When `x` is a Poly instance of degree >= 1 with single variable,
`ff(x,k) = x(y) \cdot x(y-1) \cdots x(y-k+1)`, where `y` is the
variable of `x`. This is as described in Peter Paule, "Greatest
Factorial Factorization and Symbolic Summation", Journal of
Symbolic Computation, vol. 20, pp. 235-268, 1995.
>>> from sympy import ff, factorial, rf, gamma, binomial, symbols, Poly
>>> from sympy.abc import x, k
>>> n, m = symbols('n m', integer=True)
>>> ff(x, 0)
1
>>> ff(5, 5)
120
>>> ff(x, 5) == x*(x-1)*(x-2)*(x-3)*(x-4)
True
>>> ff(Poly(x**2, x), 2)
Poly(x**4 - 2*x**3 + x**2, x, domain='ZZ')
>>> ff(n, n)
factorial(n)
Rewrite
>>> ff(x, k).rewrite(gamma)
(-1)**k*gamma(k - x)/gamma(-x)
>>> ff(x, k).rewrite(rf)
RisingFactorial(-k + x + 1, k)
>>> ff(x, m).rewrite(binomial)
binomial(x, m)*factorial(m)
>>> ff(n, m).rewrite(factorial)
factorial(n)/factorial(-m + n)
See Also
========
factorial, factorial2, RisingFactorial
References
==========
.. [1] http://mathworld.wolfram.com/FallingFactorial.html
"""
@classmethod
def eval(cls, x, k):
x = sympify(x)
k = sympify(k)
if x is S.NaN or k is S.NaN:
return S.NaN
elif k.is_integer and x == k:
return factorial(x)
elif k.is_Integer:
if k.is_zero:
return S.One
else:
if k.is_positive:
if x is S.Infinity:
return S.Infinity
elif x is S.NegativeInfinity:
if k.is_odd:
return S.NegativeInfinity
else:
return S.Infinity
else:
if isinstance(x, Poly):
gens = x.gens
if len(gens)!= 1:
raise ValueError("ff only defined for "
"polynomials on one generator")
else:
return reduce(lambda r, i:
r*(x.shift(-i)),
range(0, int(k)), 1)
else:
return reduce(lambda r, i: r*(x - i),
range(0, int(k)), 1)
else:
if x is S.Infinity:
return S.Infinity
elif x is S.NegativeInfinity:
return S.Infinity
else:
if isinstance(x, Poly):
gens = x.gens
if len(gens)!= 1:
raise ValueError("rf only defined for "
"polynomials on one generator")
else:
return 1/reduce(lambda r, i:
r*(x.shift(i)),
range(1, abs(int(k)) + 1), 1)
else:
return 1/reduce(lambda r, i: r*(x + i),
range(1, abs(int(k)) + 1), 1)
def _eval_rewrite_as_gamma(self, x, k, **kwargs):
from sympy import gamma
return (-1)**k*gamma(k - x) / gamma(-x)
def _eval_rewrite_as_RisingFactorial(self, x, k, **kwargs):
return rf(x - k + 1, k)
def _eval_rewrite_as_binomial(self, x, k, **kwargs):
if k.is_integer:
return factorial(k) * binomial(x, k)
def _eval_rewrite_as_factorial(self, x, k, **kwargs):
if x.is_integer and k.is_integer:
return factorial(x) / factorial(x - k)
def _eval_is_integer(self):
return fuzzy_and((self.args[0].is_integer, self.args[1].is_integer,
self.args[1].is_nonnegative))
def _sage_(self):
import sage.all as sage
return sage.falling_factorial(self.args[0]._sage_(),
self.args[1]._sage_())
rf = RisingFactorial
ff = FallingFactorial
###############################################################################
########################### BINOMIAL COEFFICIENTS #############################
###############################################################################
class binomial(CombinatorialFunction):
r"""Implementation of the binomial coefficient. It can be defined
in two ways depending on its desired interpretation:
.. math:: \binom{n}{k} = \frac{n!}{k!(n-k)!}\ \text{or}\
\binom{n}{k} = \frac{ff(n, k)}{k!}
First, in a strict combinatorial sense it defines the
number of ways we can choose `k` elements from a set of
`n` elements. In this case both arguments are nonnegative
integers and binomial is computed using an efficient
algorithm based on prime factorization.
The other definition is generalization for arbitrary `n`,
however `k` must also be nonnegative. This case is very
useful when evaluating summations.
For the sake of convenience for negative integer `k` this function
will return zero no matter what valued is the other argument.
To expand the binomial when `n` is a symbol, use either
``expand_func()`` or ``expand(func=True)``. The former will keep
the polynomial in factored form while the latter will expand the
polynomial itself. See examples for details.
Examples
========
>>> from sympy import Symbol, Rational, binomial, expand_func
>>> n = Symbol('n', integer=True, positive=True)
>>> binomial(15, 8)
6435
>>> binomial(n, -1)
0
Rows of Pascal's triangle can be generated with the binomial function:
>>> for N in range(8):
... print([binomial(N, i) for i in range(N + 1)])
...
[1]
[1, 1]
[1, 2, 1]
[1, 3, 3, 1]
[1, 4, 6, 4, 1]
[1, 5, 10, 10, 5, 1]
[1, 6, 15, 20, 15, 6, 1]
[1, 7, 21, 35, 35, 21, 7, 1]
As can a given diagonal, e.g. the 4th diagonal:
>>> N = -4
>>> [binomial(N, i) for i in range(1 - N)]
[1, -4, 10, -20, 35]
>>> binomial(Rational(5, 4), 3)
-5/128
>>> binomial(Rational(-5, 4), 3)
-195/128
>>> binomial(n, 3)
binomial(n, 3)
>>> binomial(n, 3).expand(func=True)
n**3/6 - n**2/2 + n/3
>>> expand_func(binomial(n, 3))
n*(n - 2)*(n - 1)/6
References
==========
.. [1] https://www.johndcook.com/blog/binomial_coefficients/
"""
def fdiff(self, argindex=1):
from sympy import polygamma
if argindex == 1:
# http://functions.wolfram.com/GammaBetaErf/Binomial/20/01/01/
n, k = self.args
return binomial(n, k)*(polygamma(0, n + 1) - \
polygamma(0, n - k + 1))
elif argindex == 2:
# http://functions.wolfram.com/GammaBetaErf/Binomial/20/01/02/
n, k = self.args
return binomial(n, k)*(polygamma(0, n - k + 1) - \
polygamma(0, k + 1))
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def _eval(self, n, k):
# n.is_Number and k.is_Integer and k != 1 and n != k
if k.is_Integer:
if n.is_Integer and n >= 0:
n, k = int(n), int(k)
if k > n:
return S.Zero
elif k > n // 2:
k = n - k
if HAS_GMPY:
from sympy.core.compatibility import gmpy
return Integer(gmpy.bincoef(n, k))
d, result = n - k, 1
for i in range(1, k + 1):
d += 1
result = result * d // i
return Integer(result)
else:
d, result = n - k, 1
for i in range(1, k + 1):
d += 1
result *= d
result /= i
return result
@classmethod
def eval(cls, n, k):
n, k = map(sympify, (n, k))
d = n - k
n_nonneg, n_isint = n.is_nonnegative, n.is_integer
if k.is_zero or ((n_nonneg or n_isint is False)
and d.is_zero):
return S.One
if (k - 1).is_zero or ((n_nonneg or n_isint is False)
and (d - 1).is_zero):
return n
if k.is_integer:
if k.is_negative or (n_nonneg and n_isint and d.is_negative):
return S.Zero
elif n.is_number:
res = cls._eval(n, k)
return res.expand(basic=True) if res else res
elif n_nonneg is False and n_isint:
# a special case when binomial evaluates to complex infinity
return S.ComplexInfinity
elif k.is_number:
from sympy import gamma
return gamma(n + 1)/(gamma(k + 1)*gamma(n - k + 1))
def _eval_Mod(self, q):
n, k = self.args
if any(x.is_integer is False for x in (n, k, q)):
raise ValueError("Integers expected for binomial Mod")
if all(x.is_Integer for x in (n, k, q)):
n, k = map(int, (n, k))
aq, res = abs(q), 1
# handle negative integers k or n
if k < 0:
return S.Zero
if n < 0:
n = -n + k - 1
res = -1 if k%2 else 1
# non negative integers k and n
if k > n:
return S.Zero
isprime = aq.is_prime
aq = int(aq)
if isprime:
if aq < n:
# use Lucas Theorem
N, K = n, k
while N or K:
res = res*binomial(N % aq, K % aq) % aq
N, K = N // aq, K // aq
else:
# use Factorial Modulo
d = n - k
if k > d:
k, d = d, k
kf = 1
for i in range(2, k + 1):
kf = kf*i % aq
df = kf
for i in range(k + 1, d + 1):
df = df*i % aq
res *= df
for i in range(d + 1, n + 1):
res = res*i % aq
res *= pow(kf*df % aq, aq - 2, aq)
res %= aq
else:
# Binomial Factorization is performed by calculating the
# exponents of primes <= n in `n! /(k! (n - k)!)`,
# for non-negative integers n and k. As the exponent of
# prime in n! is e_p(n) = [n/p] + [n/p**2] + ...
# the exponent of prime in binomial(n, k) would be
# e_p(n) - e_p(k) - e_p(n - k)
M = int(_sqrt(n))
for prime in sieve.primerange(2, n + 1):
if prime > n - k:
res = res*prime % aq
elif prime > n // 2:
continue
elif prime > M:
if n % prime < k % prime:
res = res*prime % aq
else:
N, K = n, k
exp = a = 0
while N > 0:
a = int((N % prime) < (K % prime + a))
N, K = N // prime, K // prime
exp += a
if exp > 0:
res *= pow(prime, exp, aq)
res %= aq
return S(res % q)
def _eval_expand_func(self, **hints):
"""
Function to expand binomial(n, k) when m is positive integer
Also,
n is self.args[0] and k is self.args[1] while using binomial(n, k)
"""
n = self.args[0]
if n.is_Number:
return binomial(*self.args)
k = self.args[1]
if (n-k).is_Integer:
k = n - k
if k.is_Integer:
if k.is_zero:
return S.One
elif k.is_negative:
return S.Zero
else:
n, result = self.args[0], 1
for i in range(1, k + 1):
result *= n - k + i
result /= i
return result
else:
return binomial(*self.args)
def _eval_rewrite_as_factorial(self, n, k, **kwargs):
return factorial(n)/(factorial(k)*factorial(n - k))
def _eval_rewrite_as_gamma(self, n, k, **kwargs):
from sympy import gamma
return gamma(n + 1)/(gamma(k + 1)*gamma(n - k + 1))
def _eval_rewrite_as_tractable(self, n, k, **kwargs):
return self._eval_rewrite_as_gamma(n, k).rewrite('tractable')
def _eval_rewrite_as_FallingFactorial(self, n, k, **kwargs):
if k.is_integer:
return ff(n, k) / factorial(k)
def _eval_is_integer(self):
n, k = self.args
if n.is_integer and k.is_integer:
return True
elif k.is_integer is False:
return False
def _eval_is_nonnegative(self):
n, k = self.args
if n.is_integer and k.is_integer:
if n.is_nonnegative or k.is_negative or k.is_even:
return True
elif k.is_even is False:
return False
|
7898e85b7ba2246b434e7302eb6b9b23e3a1230e059d12db943db8b4b0c374fa | from sympy.core.add import Add
from sympy.core.basic import sympify, cacheit
from sympy.core.function import Function, ArgumentIndexError, expand_mul
from sympy.core.logic import fuzzy_not, fuzzy_or, FuzzyBool
from sympy.core.numbers import igcdex, Rational, pi
from sympy.core.relational import Ne
from sympy.core.singleton import S
from sympy.core.symbol import Symbol
from sympy.functions.combinatorial.factorials import factorial, RisingFactorial
from sympy.functions.elementary.exponential import log, exp
from sympy.functions.elementary.integers import floor
from sympy.functions.elementary.hyperbolic import (acoth, asinh, atanh, cosh,
coth, HyperbolicFunction, sinh, tanh)
from sympy.functions.elementary.miscellaneous import sqrt, Min, Max
from sympy.functions.elementary.piecewise import Piecewise
from sympy.sets.sets import FiniteSet
from sympy.utilities.iterables import numbered_symbols
###############################################################################
########################## TRIGONOMETRIC FUNCTIONS ############################
###############################################################################
class TrigonometricFunction(Function):
"""Base class for trigonometric functions. """
unbranched = True
_singularities = (S.ComplexInfinity,)
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
if s.args[0].is_rational and fuzzy_not(s.args[0].is_zero):
return False
else:
return s.is_rational
def _eval_is_algebraic(self):
s = self.func(*self.args)
if s.func == self.func:
if fuzzy_not(self.args[0].is_zero) and self.args[0].is_algebraic:
return False
pi_coeff = _pi_coeff(self.args[0])
if pi_coeff is not None and pi_coeff.is_rational:
return True
else:
return s.is_algebraic
def _eval_expand_complex(self, deep=True, **hints):
re_part, im_part = self.as_real_imag(deep=deep, **hints)
return re_part + im_part*S.ImaginaryUnit
def _as_real_imag(self, deep=True, **hints):
if self.args[0].is_extended_real:
if deep:
hints['complex'] = False
return (self.args[0].expand(deep, **hints), S.Zero)
else:
return (self.args[0], S.Zero)
if deep:
re, im = self.args[0].expand(deep, **hints).as_real_imag()
else:
re, im = self.args[0].as_real_imag()
return (re, im)
def _period(self, general_period, symbol=None):
f = expand_mul(self.args[0])
if symbol is None:
symbol = tuple(f.free_symbols)[0]
if not f.has(symbol):
return S.Zero
if f == symbol:
return general_period
if symbol in f.free_symbols:
if f.is_Mul:
g, h = f.as_independent(symbol)
if h == symbol:
return general_period/abs(g)
if f.is_Add:
a, h = f.as_independent(symbol)
g, h = h.as_independent(symbol, as_Add=False)
if h == symbol:
return general_period/abs(g)
raise NotImplementedError("Use the periodicity function instead.")
def _peeloff_pi(arg):
"""
Split ARG into two parts, a "rest" and a multiple of pi/2.
This assumes ARG to be an Add.
The multiple of pi returned in the second position is always a Rational.
Examples
========
>>> from sympy.functions.elementary.trigonometric import _peeloff_pi as peel
>>> from sympy import pi
>>> from sympy.abc import x, y
>>> peel(x + pi/2)
(x, pi/2)
>>> peel(x + 2*pi/3 + pi*y)
(x + pi*y + pi/6, pi/2)
"""
for a in Add.make_args(arg):
if a is S.Pi:
K = S.One
break
elif a.is_Mul:
K, p = a.as_two_terms()
if p is S.Pi and K.is_Rational:
break
else:
return arg, S.Zero
m1 = (K % S.Half)*S.Pi
m2 = K*S.Pi - m1
return arg - m2, m2
def _pi_coeff(arg, cycles=1):
"""
When arg is a Number times pi (e.g. 3*pi/2) then return the Number
normalized to be in the range [0, 2], else None.
When an even multiple of pi is encountered, if it is multiplying
something with known parity then the multiple is returned as 0 otherwise
as 2.
Examples
========
>>> from sympy.functions.elementary.trigonometric import _pi_coeff as coeff
>>> from sympy import pi, Dummy
>>> from sympy.abc import x
>>> coeff(3*x*pi)
3*x
>>> coeff(11*pi/7)
11/7
>>> coeff(-11*pi/7)
3/7
>>> coeff(4*pi)
0
>>> coeff(5*pi)
1
>>> coeff(5.0*pi)
1
>>> coeff(5.5*pi)
3/2
>>> coeff(2 + pi)
>>> coeff(2*Dummy(integer=True)*pi)
2
>>> coeff(2*Dummy(even=True)*pi)
0
"""
arg = sympify(arg)
if arg is S.Pi:
return S.One
elif not arg:
return S.Zero
elif arg.is_Mul:
cx = arg.coeff(S.Pi)
if cx:
c, x = cx.as_coeff_Mul() # pi is not included as coeff
if c.is_Float:
# recast exact binary fractions to Rationals
f = abs(c) % 1
if f != 0:
p = -int(round(log(f, 2).evalf()))
m = 2**p
cm = c*m
i = int(cm)
if i == cm:
c = Rational(i, m)
cx = c*x
else:
c = Rational(int(c))
cx = c*x
if x.is_integer:
c2 = c % 2
if c2 == 1:
return x
elif not c2:
if x.is_even is not None: # known parity
return S.Zero
return S(2)
else:
return c2*x
return cx
elif arg.is_zero:
return S.Zero
class sin(TrigonometricFunction):
"""
The sine function.
Returns the sine of x (measured in radians).
Notes
=====
This function will evaluate automatically in the
case x/pi is some rational number [4]_. For example,
if x is a multiple of pi, pi/2, pi/3, pi/4 and pi/6.
Examples
========
>>> from sympy import sin, pi
>>> from sympy.abc import x
>>> sin(x**2).diff(x)
2*x*cos(x**2)
>>> sin(1).diff(x)
0
>>> sin(pi)
0
>>> sin(pi/2)
1
>>> sin(pi/6)
1/2
>>> sin(pi/12)
-sqrt(2)/4 + sqrt(6)/4
See Also
========
csc, cos, sec, tan, cot
asin, acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_functions
.. [2] http://dlmf.nist.gov/4.14
.. [3] http://functions.wolfram.com/ElementaryFunctions/Sin
.. [4] http://mathworld.wolfram.com/TrigonometryAngles.html
"""
def period(self, symbol=None):
return self._period(2*pi, symbol)
def fdiff(self, argindex=1):
if argindex == 1:
return cos(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, arg):
from sympy.calculus import AccumBounds
from sympy.sets.setexpr import SetExpr
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg.is_zero:
return S.Zero
elif arg is S.Infinity or arg is S.NegativeInfinity:
return AccumBounds(-1, 1)
if arg is S.ComplexInfinity:
return S.NaN
if isinstance(arg, AccumBounds):
min, max = arg.min, arg.max
d = floor(min/(2*S.Pi))
if min is not S.NegativeInfinity:
min = min - d*2*S.Pi
if max is not S.Infinity:
max = max - d*2*S.Pi
if AccumBounds(min, max).intersection(FiniteSet(S.Pi/2, S.Pi*Rational(5, 2))) \
is not S.EmptySet and \
AccumBounds(min, max).intersection(FiniteSet(S.Pi*Rational(3, 2),
S.Pi*Rational(7, 2))) is not S.EmptySet:
return AccumBounds(-1, 1)
elif AccumBounds(min, max).intersection(FiniteSet(S.Pi/2, S.Pi*Rational(5, 2))) \
is not S.EmptySet:
return AccumBounds(Min(sin(min), sin(max)), 1)
elif AccumBounds(min, max).intersection(FiniteSet(S.Pi*Rational(3, 2), S.Pi*Rational(8, 2))) \
is not S.EmptySet:
return AccumBounds(-1, Max(sin(min), sin(max)))
else:
return AccumBounds(Min(sin(min), sin(max)),
Max(sin(min), sin(max)))
elif isinstance(arg, SetExpr):
return arg._eval_func(cls)
if arg.could_extract_minus_sign():
return -cls(-arg)
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return S.ImaginaryUnit*sinh(i_coeff)
pi_coeff = _pi_coeff(arg)
if pi_coeff is not None:
if pi_coeff.is_integer:
return S.Zero
if (2*pi_coeff).is_integer:
# is_even-case handled above as then pi_coeff.is_integer,
# so check if known to be not even
if pi_coeff.is_even is False:
return S.NegativeOne**(pi_coeff - S.Half)
if not pi_coeff.is_Rational:
narg = pi_coeff*S.Pi
if narg != arg:
return cls(narg)
return None
# https://github.com/sympy/sympy/issues/6048
# transform a sine to a cosine, to avoid redundant code
if pi_coeff.is_Rational:
x = pi_coeff % 2
if x > 1:
return -cls((x % 1)*S.Pi)
if 2*x > 1:
return cls((1 - x)*S.Pi)
narg = ((pi_coeff + Rational(3, 2)) % 2)*S.Pi
result = cos(narg)
if not isinstance(result, cos):
return result
if pi_coeff*S.Pi != arg:
return cls(pi_coeff*S.Pi)
return None
if arg.is_Add:
x, m = _peeloff_pi(arg)
if m:
return sin(m)*cos(x) + cos(m)*sin(x)
if arg.is_zero:
return S.Zero
if isinstance(arg, asin):
return arg.args[0]
if isinstance(arg, atan):
x = arg.args[0]
return x/sqrt(1 + x**2)
if isinstance(arg, atan2):
y, x = arg.args
return y/sqrt(x**2 + y**2)
if isinstance(arg, acos):
x = arg.args[0]
return sqrt(1 - x**2)
if isinstance(arg, acot):
x = arg.args[0]
return 1/(sqrt(1 + 1/x**2)*x)
if isinstance(arg, acsc):
x = arg.args[0]
return 1/x
if isinstance(arg, asec):
x = arg.args[0]
return sqrt(1 - 1/x**2)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) > 2:
p = previous_terms[-2]
return -p*x**2/(n*(n - 1))
else:
return (-1)**(n//2)*x**(n)/factorial(n)
def _eval_rewrite_as_exp(self, arg, **kwargs):
I = S.ImaginaryUnit
if isinstance(arg, TrigonometricFunction) or isinstance(arg, HyperbolicFunction):
arg = arg.func(arg.args[0]).rewrite(exp)
return (exp(arg*I) - exp(-arg*I))/(2*I)
def _eval_rewrite_as_Pow(self, arg, **kwargs):
if isinstance(arg, log):
I = S.ImaginaryUnit
x = arg.args[0]
return I*x**-I/2 - I*x**I /2
def _eval_rewrite_as_cos(self, arg, **kwargs):
return cos(arg - S.Pi/2, evaluate=False)
def _eval_rewrite_as_tan(self, arg, **kwargs):
tan_half = tan(S.Half*arg)
return 2*tan_half/(1 + tan_half**2)
def _eval_rewrite_as_sincos(self, arg, **kwargs):
return sin(arg)*cos(arg)/cos(arg)
def _eval_rewrite_as_cot(self, arg, **kwargs):
cot_half = cot(S.Half*arg)
return 2*cot_half/(1 + cot_half**2)
def _eval_rewrite_as_pow(self, arg, **kwargs):
return self.rewrite(cos).rewrite(pow)
def _eval_rewrite_as_sqrt(self, arg, **kwargs):
return self.rewrite(cos).rewrite(sqrt)
def _eval_rewrite_as_csc(self, arg, **kwargs):
return 1/csc(arg)
def _eval_rewrite_as_sec(self, arg, **kwargs):
return 1/sec(arg - S.Pi/2, evaluate=False)
def _eval_rewrite_as_sinc(self, arg, **kwargs):
return arg*sinc(arg)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def as_real_imag(self, deep=True, **hints):
re, im = self._as_real_imag(deep=deep, **hints)
return (sin(re)*cosh(im), cos(re)*sinh(im))
def _eval_expand_trig(self, **hints):
from sympy import expand_mul
from sympy.functions.special.polynomials import chebyshevt, chebyshevu
arg = self.args[0]
x = None
if arg.is_Add: # TODO, implement more if deep stuff here
# TODO: Do this more efficiently for more than two terms
x, y = arg.as_two_terms()
sx = sin(x, evaluate=False)._eval_expand_trig()
sy = sin(y, evaluate=False)._eval_expand_trig()
cx = cos(x, evaluate=False)._eval_expand_trig()
cy = cos(y, evaluate=False)._eval_expand_trig()
return sx*cy + sy*cx
else:
n, x = arg.as_coeff_Mul(rational=True)
if n.is_Integer: # n will be positive because of .eval
# canonicalization
# See http://mathworld.wolfram.com/Multiple-AngleFormulas.html
if n.is_odd:
return (-1)**((n - 1)/2)*chebyshevt(n, sin(x))
else:
return expand_mul((-1)**(n/2 - 1)*cos(x)*chebyshevu(n -
1, sin(x)), deep=False)
pi_coeff = _pi_coeff(arg)
if pi_coeff is not None:
if pi_coeff.is_Rational:
return self.rewrite(sqrt)
return sin(arg)
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return arg
else:
if not arg.subs(x, 0).is_finite:
return self
else:
return self.func(arg)
def _eval_is_extended_real(self):
if self.args[0].is_extended_real:
return True
def _eval_is_finite(self):
arg = self.args[0]
if arg.is_extended_real:
return True
def _eval_is_zero(self):
arg = self.args[0]
if arg.is_zero:
return True
def _eval_is_complex(self):
if self.args[0].is_extended_real \
or self.args[0].is_complex:
return True
class cos(TrigonometricFunction):
"""
The cosine function.
Returns the cosine of x (measured in radians).
Notes
=====
See :func:`sin` for notes about automatic evaluation.
Examples
========
>>> from sympy import cos, pi
>>> from sympy.abc import x
>>> cos(x**2).diff(x)
-2*x*sin(x**2)
>>> cos(1).diff(x)
0
>>> cos(pi)
-1
>>> cos(pi/2)
0
>>> cos(2*pi/3)
-1/2
>>> cos(pi/12)
sqrt(2)/4 + sqrt(6)/4
See Also
========
sin, csc, sec, tan, cot
asin, acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_functions
.. [2] http://dlmf.nist.gov/4.14
.. [3] http://functions.wolfram.com/ElementaryFunctions/Cos
"""
def period(self, symbol=None):
return self._period(2*pi, symbol)
def fdiff(self, argindex=1):
if argindex == 1:
return -sin(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, arg):
from sympy.functions.special.polynomials import chebyshevt
from sympy.calculus.util import AccumBounds
from sympy.sets.setexpr import SetExpr
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg.is_zero:
return S.One
elif arg is S.Infinity or arg is S.NegativeInfinity:
# In this case it is better to return AccumBounds(-1, 1)
# rather than returning S.NaN, since AccumBounds(-1, 1)
# preserves the information that sin(oo) is between
# -1 and 1, where S.NaN does not do that.
return AccumBounds(-1, 1)
if arg is S.ComplexInfinity:
return S.NaN
if isinstance(arg, AccumBounds):
return sin(arg + S.Pi/2)
elif isinstance(arg, SetExpr):
return arg._eval_func(cls)
if arg.could_extract_minus_sign():
return cls(-arg)
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return cosh(i_coeff)
pi_coeff = _pi_coeff(arg)
if pi_coeff is not None:
if pi_coeff.is_integer:
return (S.NegativeOne)**pi_coeff
if (2*pi_coeff).is_integer:
# is_even-case handled above as then pi_coeff.is_integer,
# so check if known to be not even
if pi_coeff.is_even is False:
return S.Zero
if not pi_coeff.is_Rational:
narg = pi_coeff*S.Pi
if narg != arg:
return cls(narg)
return None
# cosine formula #####################
# https://github.com/sympy/sympy/issues/6048
# explicit calculations are performed for
# cos(k pi/n) for n = 8,10,12,15,20,24,30,40,60,120
# Some other exact values like cos(k pi/240) can be
# calculated using a partial-fraction decomposition
# by calling cos( X ).rewrite(sqrt)
cst_table_some = {
3: S.Half,
5: (sqrt(5) + 1)/4,
}
if pi_coeff.is_Rational:
q = pi_coeff.q
p = pi_coeff.p % (2*q)
if p > q:
narg = (pi_coeff - 1)*S.Pi
return -cls(narg)
if 2*p > q:
narg = (1 - pi_coeff)*S.Pi
return -cls(narg)
# If nested sqrt's are worse than un-evaluation
# you can require q to be in (1, 2, 3, 4, 6, 12)
# q <= 12, q=15, q=20, q=24, q=30, q=40, q=60, q=120 return
# expressions with 2 or fewer sqrt nestings.
table2 = {
12: (3, 4),
20: (4, 5),
30: (5, 6),
15: (6, 10),
24: (6, 8),
40: (8, 10),
60: (20, 30),
120: (40, 60)
}
if q in table2:
a, b = p*S.Pi/table2[q][0], p*S.Pi/table2[q][1]
nvala, nvalb = cls(a), cls(b)
if None == nvala or None == nvalb:
return None
return nvala*nvalb + cls(S.Pi/2 - a)*cls(S.Pi/2 - b)
if q > 12:
return None
if q in cst_table_some:
cts = cst_table_some[pi_coeff.q]
return chebyshevt(pi_coeff.p, cts).expand()
if 0 == q % 2:
narg = (pi_coeff*2)*S.Pi
nval = cls(narg)
if None == nval:
return None
x = (2*pi_coeff + 1)/2
sign_cos = (-1)**((-1 if x < 0 else 1)*int(abs(x)))
return sign_cos*sqrt( (1 + nval)/2 )
return None
if arg.is_Add:
x, m = _peeloff_pi(arg)
if m:
return cos(m)*cos(x) - sin(m)*sin(x)
if arg.is_zero:
return S.One
if isinstance(arg, acos):
return arg.args[0]
if isinstance(arg, atan):
x = arg.args[0]
return 1/sqrt(1 + x**2)
if isinstance(arg, atan2):
y, x = arg.args
return x/sqrt(x**2 + y**2)
if isinstance(arg, asin):
x = arg.args[0]
return sqrt(1 - x ** 2)
if isinstance(arg, acot):
x = arg.args[0]
return 1/sqrt(1 + 1/x**2)
if isinstance(arg, acsc):
x = arg.args[0]
return sqrt(1 - 1/x**2)
if isinstance(arg, asec):
x = arg.args[0]
return 1/x
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0 or n % 2 == 1:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) > 2:
p = previous_terms[-2]
return -p*x**2/(n*(n - 1))
else:
return (-1)**(n//2)*x**(n)/factorial(n)
def _eval_rewrite_as_exp(self, arg, **kwargs):
I = S.ImaginaryUnit
if isinstance(arg, TrigonometricFunction) or isinstance(arg, HyperbolicFunction):
arg = arg.func(arg.args[0]).rewrite(exp)
return (exp(arg*I) + exp(-arg*I))/2
def _eval_rewrite_as_Pow(self, arg, **kwargs):
if isinstance(arg, log):
I = S.ImaginaryUnit
x = arg.args[0]
return x**I/2 + x**-I/2
def _eval_rewrite_as_sin(self, arg, **kwargs):
return sin(arg + S.Pi/2, evaluate=False)
def _eval_rewrite_as_tan(self, arg, **kwargs):
tan_half = tan(S.Half*arg)**2
return (1 - tan_half)/(1 + tan_half)
def _eval_rewrite_as_sincos(self, arg, **kwargs):
return sin(arg)*cos(arg)/sin(arg)
def _eval_rewrite_as_cot(self, arg, **kwargs):
cot_half = cot(S.Half*arg)**2
return (cot_half - 1)/(cot_half + 1)
def _eval_rewrite_as_pow(self, arg, **kwargs):
return self._eval_rewrite_as_sqrt(arg)
def _eval_rewrite_as_sqrt(self, arg, **kwargs):
from sympy.functions.special.polynomials import chebyshevt
def migcdex(x):
# recursive calcuation of gcd and linear combination
# for a sequence of integers.
# Given (x1, x2, x3)
# Returns (y1, y1, y3, g)
# such that g is the gcd and x1*y1+x2*y2+x3*y3 - g = 0
# Note, that this is only one such linear combination.
if len(x) == 1:
return (1, x[0])
if len(x) == 2:
return igcdex(x[0], x[-1])
g = migcdex(x[1:])
u, v, h = igcdex(x[0], g[-1])
return tuple([u] + [v*i for i in g[0:-1] ] + [h])
def ipartfrac(r, factors=None):
from sympy.ntheory import factorint
if isinstance(r, int):
return r
if not isinstance(r, Rational):
raise TypeError("r is not rational")
n = r.q
if 2 > r.q*r.q:
return r.q
if None == factors:
a = [n//x**y for x, y in factorint(r.q).items()]
else:
a = [n//x for x in factors]
if len(a) == 1:
return [ r ]
h = migcdex(a)
ans = [ r.p*Rational(i*j, r.q) for i, j in zip(h[:-1], a) ]
assert r == sum(ans)
return ans
pi_coeff = _pi_coeff(arg)
if pi_coeff is None:
return None
if pi_coeff.is_integer:
# it was unevaluated
return self.func(pi_coeff*S.Pi)
if not pi_coeff.is_Rational:
return None
def _cospi257():
""" Express cos(pi/257) explicitly as a function of radicals
Based upon the equations in
http://math.stackexchange.com/questions/516142/how-does-cos2-pi-257-look-like-in-real-radicals
See also http://www.susqu.edu/brakke/constructions/257-gon.m.txt
"""
def f1(a, b):
return (a + sqrt(a**2 + b))/2, (a - sqrt(a**2 + b))/2
def f2(a, b):
return (a - sqrt(a**2 + b))/2
t1, t2 = f1(-1, 256)
z1, z3 = f1(t1, 64)
z2, z4 = f1(t2, 64)
y1, y5 = f1(z1, 4*(5 + t1 + 2*z1))
y6, y2 = f1(z2, 4*(5 + t2 + 2*z2))
y3, y7 = f1(z3, 4*(5 + t1 + 2*z3))
y8, y4 = f1(z4, 4*(5 + t2 + 2*z4))
x1, x9 = f1(y1, -4*(t1 + y1 + y3 + 2*y6))
x2, x10 = f1(y2, -4*(t2 + y2 + y4 + 2*y7))
x3, x11 = f1(y3, -4*(t1 + y3 + y5 + 2*y8))
x4, x12 = f1(y4, -4*(t2 + y4 + y6 + 2*y1))
x5, x13 = f1(y5, -4*(t1 + y5 + y7 + 2*y2))
x6, x14 = f1(y6, -4*(t2 + y6 + y8 + 2*y3))
x15, x7 = f1(y7, -4*(t1 + y7 + y1 + 2*y4))
x8, x16 = f1(y8, -4*(t2 + y8 + y2 + 2*y5))
v1 = f2(x1, -4*(x1 + x2 + x3 + x6))
v2 = f2(x2, -4*(x2 + x3 + x4 + x7))
v3 = f2(x8, -4*(x8 + x9 + x10 + x13))
v4 = f2(x9, -4*(x9 + x10 + x11 + x14))
v5 = f2(x10, -4*(x10 + x11 + x12 + x15))
v6 = f2(x16, -4*(x16 + x1 + x2 + x5))
u1 = -f2(-v1, -4*(v2 + v3))
u2 = -f2(-v4, -4*(v5 + v6))
w1 = -2*f2(-u1, -4*u2)
return sqrt(sqrt(2)*sqrt(w1 + 4)/8 + S.Half)
cst_table_some = {
3: S.Half,
5: (sqrt(5) + 1)/4,
17: sqrt((15 + sqrt(17))/32 + sqrt(2)*(sqrt(17 - sqrt(17)) +
sqrt(sqrt(2)*(-8*sqrt(17 + sqrt(17)) - (1 - sqrt(17))
*sqrt(17 - sqrt(17))) + 6*sqrt(17) + 34))/32),
257: _cospi257()
# 65537 is the only other known Fermat prime and the very
# large expression is intentionally omitted from SymPy; see
# http://www.susqu.edu/brakke/constructions/65537-gon.m.txt
}
def _fermatCoords(n):
# if n can be factored in terms of Fermat primes with
# multiplicity of each being 1, return those primes, else
# False
primes = []
for p_i in cst_table_some:
quotient, remainder = divmod(n, p_i)
if remainder == 0:
n = quotient
primes.append(p_i)
if n == 1:
return tuple(primes)
return False
if pi_coeff.q in cst_table_some:
rv = chebyshevt(pi_coeff.p, cst_table_some[pi_coeff.q])
if pi_coeff.q < 257:
rv = rv.expand()
return rv
if not pi_coeff.q % 2: # recursively remove factors of 2
pico2 = pi_coeff*2
nval = cos(pico2*S.Pi).rewrite(sqrt)
x = (pico2 + 1)/2
sign_cos = -1 if int(x) % 2 else 1
return sign_cos*sqrt( (1 + nval)/2 )
FC = _fermatCoords(pi_coeff.q)
if FC:
decomp = ipartfrac(pi_coeff, FC)
X = [(x[1], x[0]*S.Pi) for x in zip(decomp, numbered_symbols('z'))]
pcls = cos(sum([x[0] for x in X]))._eval_expand_trig().subs(X)
return pcls.rewrite(sqrt)
else:
decomp = ipartfrac(pi_coeff)
X = [(x[1], x[0]*S.Pi) for x in zip(decomp, numbered_symbols('z'))]
pcls = cos(sum([x[0] for x in X]))._eval_expand_trig().subs(X)
return pcls
def _eval_rewrite_as_sec(self, arg, **kwargs):
return 1/sec(arg)
def _eval_rewrite_as_csc(self, arg, **kwargs):
return 1/sec(arg).rewrite(csc)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def as_real_imag(self, deep=True, **hints):
re, im = self._as_real_imag(deep=deep, **hints)
return (cos(re)*cosh(im), -sin(re)*sinh(im))
def _eval_expand_trig(self, **hints):
from sympy.functions.special.polynomials import chebyshevt
arg = self.args[0]
x = None
if arg.is_Add: # TODO: Do this more efficiently for more than two terms
x, y = arg.as_two_terms()
sx = sin(x, evaluate=False)._eval_expand_trig()
sy = sin(y, evaluate=False)._eval_expand_trig()
cx = cos(x, evaluate=False)._eval_expand_trig()
cy = cos(y, evaluate=False)._eval_expand_trig()
return cx*cy - sx*sy
else:
coeff, terms = arg.as_coeff_Mul(rational=True)
if coeff.is_Integer:
return chebyshevt(coeff, cos(terms))
pi_coeff = _pi_coeff(arg)
if pi_coeff is not None:
if pi_coeff.is_Rational:
return self.rewrite(sqrt)
return cos(arg)
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return S.One
else:
if not arg.subs(x, 0).is_finite:
return self
else:
return self.func(arg)
def _eval_is_extended_real(self):
if self.args[0].is_extended_real:
return True
def _eval_is_finite(self):
arg = self.args[0]
if arg.is_extended_real:
return True
def _eval_is_complex(self):
if self.args[0].is_extended_real \
or self.args[0].is_complex:
return True
class tan(TrigonometricFunction):
"""
The tangent function.
Returns the tangent of x (measured in radians).
Notes
=====
See :func:`sin` for notes about automatic evaluation.
Examples
========
>>> from sympy import tan, pi
>>> from sympy.abc import x
>>> tan(x**2).diff(x)
2*x*(tan(x**2)**2 + 1)
>>> tan(1).diff(x)
0
>>> tan(pi/8).expand()
-1 + sqrt(2)
See Also
========
sin, csc, cos, sec, cot
asin, acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_functions
.. [2] http://dlmf.nist.gov/4.14
.. [3] http://functions.wolfram.com/ElementaryFunctions/Tan
"""
def period(self, symbol=None):
return self._period(pi, symbol)
def fdiff(self, argindex=1):
if argindex == 1:
return S.One + self**2
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return atan
@classmethod
def eval(cls, arg):
from sympy.calculus.util import AccumBounds
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg.is_zero:
return S.Zero
elif arg is S.Infinity or arg is S.NegativeInfinity:
return AccumBounds(S.NegativeInfinity, S.Infinity)
if arg is S.ComplexInfinity:
return S.NaN
if isinstance(arg, AccumBounds):
min, max = arg.min, arg.max
d = floor(min/S.Pi)
if min is not S.NegativeInfinity:
min = min - d*S.Pi
if max is not S.Infinity:
max = max - d*S.Pi
if AccumBounds(min, max).intersection(FiniteSet(S.Pi/2, S.Pi*Rational(3, 2))):
return AccumBounds(S.NegativeInfinity, S.Infinity)
else:
return AccumBounds(tan(min), tan(max))
if arg.could_extract_minus_sign():
return -cls(-arg)
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return S.ImaginaryUnit*tanh(i_coeff)
pi_coeff = _pi_coeff(arg, 2)
if pi_coeff is not None:
if pi_coeff.is_integer:
return S.Zero
if not pi_coeff.is_Rational:
narg = pi_coeff*S.Pi
if narg != arg:
return cls(narg)
return None
if pi_coeff.is_Rational:
q = pi_coeff.q
p = pi_coeff.p % q
# ensure simplified results are returned for n*pi/5, n*pi/10
table10 = {
1: sqrt(1 - 2*sqrt(5)/5),
2: sqrt(5 - 2*sqrt(5)),
3: sqrt(1 + 2*sqrt(5)/5),
4: sqrt(5 + 2*sqrt(5))
}
if q == 5 or q == 10:
n = 10*p/q
if n > 5:
n = 10 - n
return -table10[n]
else:
return table10[n]
if not pi_coeff.q % 2:
narg = pi_coeff*S.Pi*2
cresult, sresult = cos(narg), cos(narg - S.Pi/2)
if not isinstance(cresult, cos) \
and not isinstance(sresult, cos):
if sresult == 0:
return S.ComplexInfinity
return 1/sresult - cresult/sresult
table2 = {
12: (3, 4),
20: (4, 5),
30: (5, 6),
15: (6, 10),
24: (6, 8),
40: (8, 10),
60: (20, 30),
120: (40, 60)
}
if q in table2:
nvala, nvalb = cls(p*S.Pi/table2[q][0]), cls(p*S.Pi/table2[q][1])
if None == nvala or None == nvalb:
return None
return (nvala - nvalb)/(1 + nvala*nvalb)
narg = ((pi_coeff + S.Half) % 1 - S.Half)*S.Pi
# see cos() to specify which expressions should be
# expanded automatically in terms of radicals
cresult, sresult = cos(narg), cos(narg - S.Pi/2)
if not isinstance(cresult, cos) \
and not isinstance(sresult, cos):
if cresult == 0:
return S.ComplexInfinity
return (sresult/cresult)
if narg != arg:
return cls(narg)
if arg.is_Add:
x, m = _peeloff_pi(arg)
if m:
tanm = tan(m)
if tanm is S.ComplexInfinity:
return -cot(x)
else: # tanm == 0
return tan(x)
if arg.is_zero:
return S.Zero
if isinstance(arg, atan):
return arg.args[0]
if isinstance(arg, atan2):
y, x = arg.args
return y/x
if isinstance(arg, asin):
x = arg.args[0]
return x/sqrt(1 - x**2)
if isinstance(arg, acos):
x = arg.args[0]
return sqrt(1 - x**2)/x
if isinstance(arg, acot):
x = arg.args[0]
return 1/x
if isinstance(arg, acsc):
x = arg.args[0]
return 1/(sqrt(1 - 1/x**2)*x)
if isinstance(arg, asec):
x = arg.args[0]
return sqrt(1 - 1/x**2)*x
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
from sympy import bernoulli
if n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
a, b = ((n - 1)//2), 2**(n + 1)
B = bernoulli(n + 1)
F = factorial(n + 1)
return (-1)**a*b*(b - 1)*B/F*x**n
def _eval_nseries(self, x, n, logx):
i = self.args[0].limit(x, 0)*2/S.Pi
if i and i.is_Integer:
return self.rewrite(cos)._eval_nseries(x, n=n, logx=logx)
return Function._eval_nseries(self, x, n=n, logx=logx)
def _eval_rewrite_as_Pow(self, arg, **kwargs):
if isinstance(arg, log):
I = S.ImaginaryUnit
x = arg.args[0]
return I*(x**-I - x**I)/(x**-I + x**I)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def as_real_imag(self, deep=True, **hints):
re, im = self._as_real_imag(deep=deep, **hints)
if im:
denom = cos(2*re) + cosh(2*im)
return (sin(2*re)/denom, sinh(2*im)/denom)
else:
return (self.func(re), S.Zero)
def _eval_expand_trig(self, **hints):
from sympy import im, re
arg = self.args[0]
x = None
if arg.is_Add:
from sympy import symmetric_poly
n = len(arg.args)
TX = []
for x in arg.args:
tx = tan(x, evaluate=False)._eval_expand_trig()
TX.append(tx)
Yg = numbered_symbols('Y')
Y = [ next(Yg) for i in range(n) ]
p = [0, 0]
for i in range(n + 1):
p[1 - i % 2] += symmetric_poly(i, Y)*(-1)**((i % 4)//2)
return (p[0]/p[1]).subs(list(zip(Y, TX)))
else:
coeff, terms = arg.as_coeff_Mul(rational=True)
if coeff.is_Integer and coeff > 1:
I = S.ImaginaryUnit
z = Symbol('dummy', real=True)
P = ((1 + I*z)**coeff).expand()
return (im(P)/re(P)).subs([(z, tan(terms))])
return tan(arg)
def _eval_rewrite_as_exp(self, arg, **kwargs):
I = S.ImaginaryUnit
if isinstance(arg, TrigonometricFunction) or isinstance(arg, HyperbolicFunction):
arg = arg.func(arg.args[0]).rewrite(exp)
neg_exp, pos_exp = exp(-arg*I), exp(arg*I)
return I*(neg_exp - pos_exp)/(neg_exp + pos_exp)
def _eval_rewrite_as_sin(self, x, **kwargs):
return 2*sin(x)**2/sin(2*x)
def _eval_rewrite_as_cos(self, x, **kwargs):
return cos(x - S.Pi/2, evaluate=False)/cos(x)
def _eval_rewrite_as_sincos(self, arg, **kwargs):
return sin(arg)/cos(arg)
def _eval_rewrite_as_cot(self, arg, **kwargs):
return 1/cot(arg)
def _eval_rewrite_as_sec(self, arg, **kwargs):
sin_in_sec_form = sin(arg).rewrite(sec)
cos_in_sec_form = cos(arg).rewrite(sec)
return sin_in_sec_form/cos_in_sec_form
def _eval_rewrite_as_csc(self, arg, **kwargs):
sin_in_csc_form = sin(arg).rewrite(csc)
cos_in_csc_form = cos(arg).rewrite(csc)
return sin_in_csc_form/cos_in_csc_form
def _eval_rewrite_as_pow(self, arg, **kwargs):
y = self.rewrite(cos).rewrite(pow)
if y.has(cos):
return None
return y
def _eval_rewrite_as_sqrt(self, arg, **kwargs):
y = self.rewrite(cos).rewrite(sqrt)
if y.has(cos):
return None
return y
def _eval_as_leading_term(self, x):
arg = self.args[0]
x0 = arg.subs(x, 0)
n = x0/S.Pi
if n.is_integer:
lt = (arg - n*S.Pi).as_leading_term(x)
return lt if n.is_even else -1/lt
return self.func(arg)
def _eval_is_extended_real(self):
# FIXME: currently tan(pi/2) return zoo
return self.args[0].is_extended_real
def _eval_is_real(self):
arg = self.args[0]
if arg.is_real and (arg/pi - S.Half).is_integer is False:
return True
def _eval_is_finite(self):
arg = self.args[0]
if arg.is_real and (arg/pi - S.Half).is_integer is False:
return True
if arg.is_imaginary:
return True
def _eval_is_zero(self):
arg = self.args[0]
if arg.is_zero:
return True
def _eval_is_complex(self):
arg = self.args[0]
if arg.is_real and (arg/pi - S.Half).is_integer is False:
return True
class cot(TrigonometricFunction):
"""
The cotangent function.
Returns the cotangent of x (measured in radians).
Notes
=====
See :func:`sin` for notes about automatic evaluation.
Examples
========
>>> from sympy import cot, pi
>>> from sympy.abc import x
>>> cot(x**2).diff(x)
2*x*(-cot(x**2)**2 - 1)
>>> cot(1).diff(x)
0
>>> cot(pi/12)
sqrt(3) + 2
See Also
========
sin, csc, cos, sec, tan
asin, acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_functions
.. [2] http://dlmf.nist.gov/4.14
.. [3] http://functions.wolfram.com/ElementaryFunctions/Cot
"""
def period(self, symbol=None):
return self._period(pi, symbol)
def fdiff(self, argindex=1):
if argindex == 1:
return S.NegativeOne - self**2
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return acot
@classmethod
def eval(cls, arg):
from sympy.calculus.util import AccumBounds
if arg.is_Number:
if arg is S.NaN:
return S.NaN
if arg.is_zero:
return S.ComplexInfinity
if arg is S.ComplexInfinity:
return S.NaN
if isinstance(arg, AccumBounds):
return -tan(arg + S.Pi/2)
if arg.could_extract_minus_sign():
return -cls(-arg)
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return -S.ImaginaryUnit*coth(i_coeff)
pi_coeff = _pi_coeff(arg, 2)
if pi_coeff is not None:
if pi_coeff.is_integer:
return S.ComplexInfinity
if not pi_coeff.is_Rational:
narg = pi_coeff*S.Pi
if narg != arg:
return cls(narg)
return None
if pi_coeff.is_Rational:
if pi_coeff.q == 5 or pi_coeff.q == 10:
return tan(S.Pi/2 - arg)
if pi_coeff.q > 2 and not pi_coeff.q % 2:
narg = pi_coeff*S.Pi*2
cresult, sresult = cos(narg), cos(narg - S.Pi/2)
if not isinstance(cresult, cos) \
and not isinstance(sresult, cos):
return 1/sresult + cresult/sresult
table2 = {
12: (3, 4),
20: (4, 5),
30: (5, 6),
15: (6, 10),
24: (6, 8),
40: (8, 10),
60: (20, 30),
120: (40, 60)
}
q = pi_coeff.q
p = pi_coeff.p % q
if q in table2:
nvala, nvalb = cls(p*S.Pi/table2[q][0]), cls(p*S.Pi/table2[q][1])
if None == nvala or None == nvalb:
return None
return (1 + nvala*nvalb)/(nvalb - nvala)
narg = (((pi_coeff + S.Half) % 1) - S.Half)*S.Pi
# see cos() to specify which expressions should be
# expanded automatically in terms of radicals
cresult, sresult = cos(narg), cos(narg - S.Pi/2)
if not isinstance(cresult, cos) \
and not isinstance(sresult, cos):
if sresult == 0:
return S.ComplexInfinity
return cresult/sresult
if narg != arg:
return cls(narg)
if arg.is_Add:
x, m = _peeloff_pi(arg)
if m:
cotm = cot(m)
if cotm is S.ComplexInfinity:
return cot(x)
else: # cotm == 0
return -tan(x)
if arg.is_zero:
return S.ComplexInfinity
if isinstance(arg, acot):
return arg.args[0]
if isinstance(arg, atan):
x = arg.args[0]
return 1/x
if isinstance(arg, atan2):
y, x = arg.args
return x/y
if isinstance(arg, asin):
x = arg.args[0]
return sqrt(1 - x**2)/x
if isinstance(arg, acos):
x = arg.args[0]
return x/sqrt(1 - x**2)
if isinstance(arg, acsc):
x = arg.args[0]
return sqrt(1 - 1/x**2)*x
if isinstance(arg, asec):
x = arg.args[0]
return 1/(sqrt(1 - 1/x**2)*x)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
from sympy import bernoulli
if n == 0:
return 1/sympify(x)
elif n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
B = bernoulli(n + 1)
F = factorial(n + 1)
return (-1)**((n + 1)//2)*2**(n + 1)*B/F*x**n
def _eval_nseries(self, x, n, logx):
i = self.args[0].limit(x, 0)/S.Pi
if i and i.is_Integer:
return self.rewrite(cos)._eval_nseries(x, n=n, logx=logx)
return self.rewrite(tan)._eval_nseries(x, n=n, logx=logx)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def as_real_imag(self, deep=True, **hints):
re, im = self._as_real_imag(deep=deep, **hints)
if im:
denom = cos(2*re) - cosh(2*im)
return (-sin(2*re)/denom, sinh(2*im)/denom)
else:
return (self.func(re), S.Zero)
def _eval_rewrite_as_exp(self, arg, **kwargs):
I = S.ImaginaryUnit
if isinstance(arg, TrigonometricFunction) or isinstance(arg, HyperbolicFunction):
arg = arg.func(arg.args[0]).rewrite(exp)
neg_exp, pos_exp = exp(-arg*I), exp(arg*I)
return I*(pos_exp + neg_exp)/(pos_exp - neg_exp)
def _eval_rewrite_as_Pow(self, arg, **kwargs):
if isinstance(arg, log):
I = S.ImaginaryUnit
x = arg.args[0]
return -I*(x**-I + x**I)/(x**-I - x**I)
def _eval_rewrite_as_sin(self, x, **kwargs):
return sin(2*x)/(2*(sin(x)**2))
def _eval_rewrite_as_cos(self, x, **kwargs):
return cos(x)/cos(x - S.Pi/2, evaluate=False)
def _eval_rewrite_as_sincos(self, arg, **kwargs):
return cos(arg)/sin(arg)
def _eval_rewrite_as_tan(self, arg, **kwargs):
return 1/tan(arg)
def _eval_rewrite_as_sec(self, arg, **kwargs):
cos_in_sec_form = cos(arg).rewrite(sec)
sin_in_sec_form = sin(arg).rewrite(sec)
return cos_in_sec_form/sin_in_sec_form
def _eval_rewrite_as_csc(self, arg, **kwargs):
cos_in_csc_form = cos(arg).rewrite(csc)
sin_in_csc_form = sin(arg).rewrite(csc)
return cos_in_csc_form/sin_in_csc_form
def _eval_rewrite_as_pow(self, arg, **kwargs):
y = self.rewrite(cos).rewrite(pow)
if y.has(cos):
return None
return y
def _eval_rewrite_as_sqrt(self, arg, **kwargs):
y = self.rewrite(cos).rewrite(sqrt)
if y.has(cos):
return None
return y
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return 1/arg
else:
return self.func(arg)
def _eval_is_extended_real(self):
return self.args[0].is_extended_real
def _eval_expand_trig(self, **hints):
from sympy import im, re
arg = self.args[0]
x = None
if arg.is_Add:
from sympy import symmetric_poly
n = len(arg.args)
CX = []
for x in arg.args:
cx = cot(x, evaluate=False)._eval_expand_trig()
CX.append(cx)
Yg = numbered_symbols('Y')
Y = [ next(Yg) for i in range(n) ]
p = [0, 0]
for i in range(n, -1, -1):
p[(n - i) % 2] += symmetric_poly(i, Y)*(-1)**(((n - i) % 4)//2)
return (p[0]/p[1]).subs(list(zip(Y, CX)))
else:
coeff, terms = arg.as_coeff_Mul(rational=True)
if coeff.is_Integer and coeff > 1:
I = S.ImaginaryUnit
z = Symbol('dummy', real=True)
P = ((z + I)**coeff).expand()
return (re(P)/im(P)).subs([(z, cot(terms))])
return cot(arg)
def _eval_is_finite(self):
arg = self.args[0]
if arg.is_real and (arg/pi).is_integer is False:
return True
if arg.is_imaginary:
return True
def _eval_is_real(self):
arg = self.args[0]
if arg.is_real and (arg/pi).is_integer is False:
return True
def _eval_is_complex(self):
arg = self.args[0]
if arg.is_real and (arg/pi).is_integer is False:
return True
def _eval_subs(self, old, new):
arg = self.args[0]
argnew = arg.subs(old, new)
if arg != argnew and (argnew/S.Pi).is_integer:
return S.ComplexInfinity
return cot(argnew)
class ReciprocalTrigonometricFunction(TrigonometricFunction):
"""Base class for reciprocal functions of trigonometric functions. """
_reciprocal_of = None # mandatory, to be defined in subclass
_singularities = (S.ComplexInfinity,)
# _is_even and _is_odd are used for correct evaluation of csc(-x), sec(-x)
# TODO refactor into TrigonometricFunction common parts of
# trigonometric functions eval() like even/odd, func(x+2*k*pi), etc.
# optional, to be defined in subclasses:
_is_even = None # type: FuzzyBool
_is_odd = None # type: FuzzyBool
@classmethod
def eval(cls, arg):
if arg.could_extract_minus_sign():
if cls._is_even:
return cls(-arg)
if cls._is_odd:
return -cls(-arg)
pi_coeff = _pi_coeff(arg)
if (pi_coeff is not None
and not (2*pi_coeff).is_integer
and pi_coeff.is_Rational):
q = pi_coeff.q
p = pi_coeff.p % (2*q)
if p > q:
narg = (pi_coeff - 1)*S.Pi
return -cls(narg)
if 2*p > q:
narg = (1 - pi_coeff)*S.Pi
if cls._is_odd:
return cls(narg)
elif cls._is_even:
return -cls(narg)
if hasattr(arg, 'inverse') and arg.inverse() == cls:
return arg.args[0]
t = cls._reciprocal_of.eval(arg)
if t is None:
return t
elif any(isinstance(i, cos) for i in (t, -t)):
return (1/t).rewrite(sec)
elif any(isinstance(i, sin) for i in (t, -t)):
return (1/t).rewrite(csc)
else:
return 1/t
def _call_reciprocal(self, method_name, *args, **kwargs):
# Calls method_name on _reciprocal_of
o = self._reciprocal_of(self.args[0])
return getattr(o, method_name)(*args, **kwargs)
def _calculate_reciprocal(self, method_name, *args, **kwargs):
# If calling method_name on _reciprocal_of returns a value != None
# then return the reciprocal of that value
t = self._call_reciprocal(method_name, *args, **kwargs)
return 1/t if t is not None else t
def _rewrite_reciprocal(self, method_name, arg):
# Special handling for rewrite functions. If reciprocal rewrite returns
# unmodified expression, then return None
t = self._call_reciprocal(method_name, arg)
if t is not None and t != self._reciprocal_of(arg):
return 1/t
def _period(self, symbol):
f = expand_mul(self.args[0])
return self._reciprocal_of(f).period(symbol)
def fdiff(self, argindex=1):
return -self._calculate_reciprocal("fdiff", argindex)/self**2
def _eval_rewrite_as_exp(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_exp", arg)
def _eval_rewrite_as_Pow(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_Pow", arg)
def _eval_rewrite_as_sin(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_sin", arg)
def _eval_rewrite_as_cos(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_cos", arg)
def _eval_rewrite_as_tan(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_tan", arg)
def _eval_rewrite_as_pow(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_pow", arg)
def _eval_rewrite_as_sqrt(self, arg, **kwargs):
return self._rewrite_reciprocal("_eval_rewrite_as_sqrt", arg)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def as_real_imag(self, deep=True, **hints):
return (1/self._reciprocal_of(self.args[0])).as_real_imag(deep,
**hints)
def _eval_expand_trig(self, **hints):
return self._calculate_reciprocal("_eval_expand_trig", **hints)
def _eval_is_extended_real(self):
return self._reciprocal_of(self.args[0])._eval_is_extended_real()
def _eval_as_leading_term(self, x):
return (1/self._reciprocal_of(self.args[0]))._eval_as_leading_term(x)
def _eval_is_finite(self):
return (1/self._reciprocal_of(self.args[0])).is_finite
def _eval_nseries(self, x, n, logx):
return (1/self._reciprocal_of(self.args[0]))._eval_nseries(x, n, logx)
class sec(ReciprocalTrigonometricFunction):
"""
The secant function.
Returns the secant of x (measured in radians).
Notes
=====
See :func:`sin` for notes about automatic evaluation.
Examples
========
>>> from sympy import sec
>>> from sympy.abc import x
>>> sec(x**2).diff(x)
2*x*tan(x**2)*sec(x**2)
>>> sec(1).diff(x)
0
See Also
========
sin, csc, cos, tan, cot
asin, acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_functions
.. [2] http://dlmf.nist.gov/4.14
.. [3] http://functions.wolfram.com/ElementaryFunctions/Sec
"""
_reciprocal_of = cos
_is_even = True
def period(self, symbol=None):
return self._period(symbol)
def _eval_rewrite_as_cot(self, arg, **kwargs):
cot_half_sq = cot(arg/2)**2
return (cot_half_sq + 1)/(cot_half_sq - 1)
def _eval_rewrite_as_cos(self, arg, **kwargs):
return (1/cos(arg))
def _eval_rewrite_as_sincos(self, arg, **kwargs):
return sin(arg)/(cos(arg)*sin(arg))
def _eval_rewrite_as_sin(self, arg, **kwargs):
return (1/cos(arg).rewrite(sin))
def _eval_rewrite_as_tan(self, arg, **kwargs):
return (1/cos(arg).rewrite(tan))
def _eval_rewrite_as_csc(self, arg, **kwargs):
return csc(pi/2 - arg, evaluate=False)
def fdiff(self, argindex=1):
if argindex == 1:
return tan(self.args[0])*sec(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_complex(self):
arg = self.args[0]
if arg.is_complex and (arg/pi - S.Half).is_integer is False:
return True
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
# Reference Formula:
# http://functions.wolfram.com/ElementaryFunctions/Sec/06/01/02/01/
from sympy.functions.combinatorial.numbers import euler
if n < 0 or n % 2 == 1:
return S.Zero
else:
x = sympify(x)
k = n//2
return (-1)**k*euler(2*k)/factorial(2*k)*x**(2*k)
def _eval_as_leading_term(self, x):
arg = self.args[0]
x0 = arg.subs(x, 0).cancel()
n = (x0 + S.Pi/2)/S.Pi
if n.is_integer:
lt = (arg - n*S.Pi + S.Pi/2).as_leading_term(x)
return ((-1)**n)/lt
return self.func(x0)
class csc(ReciprocalTrigonometricFunction):
"""
The cosecant function.
Returns the cosecant of x (measured in radians).
Notes
=====
See :func:`sin` for notes about automatic evaluation.
Examples
========
>>> from sympy import csc
>>> from sympy.abc import x
>>> csc(x**2).diff(x)
-2*x*cot(x**2)*csc(x**2)
>>> csc(1).diff(x)
0
See Also
========
sin, cos, sec, tan, cot
asin, acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_functions
.. [2] http://dlmf.nist.gov/4.14
.. [3] http://functions.wolfram.com/ElementaryFunctions/Csc
"""
_reciprocal_of = sin
_is_odd = True
def period(self, symbol=None):
return self._period(symbol)
def _eval_rewrite_as_sin(self, arg, **kwargs):
return (1/sin(arg))
def _eval_rewrite_as_sincos(self, arg, **kwargs):
return cos(arg)/(sin(arg)*cos(arg))
def _eval_rewrite_as_cot(self, arg, **kwargs):
cot_half = cot(arg/2)
return (1 + cot_half**2)/(2*cot_half)
def _eval_rewrite_as_cos(self, arg, **kwargs):
return 1/sin(arg).rewrite(cos)
def _eval_rewrite_as_sec(self, arg, **kwargs):
return sec(pi/2 - arg, evaluate=False)
def _eval_rewrite_as_tan(self, arg, **kwargs):
return (1/sin(arg).rewrite(tan))
def fdiff(self, argindex=1):
if argindex == 1:
return -cot(self.args[0])*csc(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_complex(self):
arg = self.args[0]
if arg.is_real and (arg/pi).is_integer is False:
return True
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
from sympy import bernoulli
if n == 0:
return 1/sympify(x)
elif n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
k = n//2 + 1
return ((-1)**(k - 1)*2*(2**(2*k - 1) - 1)*
bernoulli(2*k)*x**(2*k - 1)/factorial(2*k))
class sinc(Function):
r"""
Represents an unnormalized sinc function:
.. math::
\operatorname{sinc}(x) =
\begin{cases}
\frac{\sin x}{x} & \qquad x \neq 0 \\
1 & \qquad x = 0
\end{cases}
Examples
========
>>> from sympy import sinc, oo, jn
>>> from sympy.abc import x
>>> sinc(x)
sinc(x)
* Automated Evaluation
>>> sinc(0)
1
>>> sinc(oo)
0
* Differentiation
>>> sinc(x).diff()
Piecewise(((x*cos(x) - sin(x))/x**2, Ne(x, 0)), (0, True))
* Series Expansion
>>> sinc(x).series()
1 - x**2/6 + x**4/120 + O(x**6)
* As zero'th order spherical Bessel Function
>>> sinc(x).rewrite(jn)
jn(0, x)
References
==========
.. [1] https://en.wikipedia.org/wiki/Sinc_function
"""
_singularities = (S.ComplexInfinity,)
def fdiff(self, argindex=1):
x = self.args[0]
if argindex == 1:
return Piecewise(((x*cos(x) - sin(x))/x**2, Ne(x, S.Zero)), (S.Zero, S.true))
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, arg):
if arg.is_zero:
return S.One
if arg.is_Number:
if arg in [S.Infinity, S.NegativeInfinity]:
return S.Zero
elif arg is S.NaN:
return S.NaN
if arg is S.ComplexInfinity:
return S.NaN
if arg.could_extract_minus_sign():
return cls(-arg)
pi_coeff = _pi_coeff(arg)
if pi_coeff is not None:
if pi_coeff.is_integer:
if fuzzy_not(arg.is_zero):
return S.Zero
elif (2*pi_coeff).is_integer:
return S.NegativeOne**(pi_coeff - S.Half)/arg
def _eval_nseries(self, x, n, logx):
x = self.args[0]
return (sin(x)/x)._eval_nseries(x, n, logx)
def _eval_rewrite_as_jn(self, arg, **kwargs):
from sympy.functions.special.bessel import jn
return jn(0, arg)
def _eval_rewrite_as_sin(self, arg, **kwargs):
return Piecewise((sin(arg)/arg, Ne(arg, S.Zero)), (S.One, S.true))
###############################################################################
########################### TRIGONOMETRIC INVERSES ############################
###############################################################################
class InverseTrigonometricFunction(Function):
"""Base class for inverse trigonometric functions."""
_singularities = (1, -1, 0, S.ComplexInfinity)
@staticmethod
def _asin_table():
# Only keys with could_extract_minus_sign() == False
# are actually needed.
return {
sqrt(3)/2: S.Pi/3,
sqrt(2)/2: S.Pi/4,
1/sqrt(2): S.Pi/4,
sqrt((5 - sqrt(5))/8): S.Pi/5,
sqrt(2)*sqrt(5 - sqrt(5))/4: S.Pi/5,
sqrt((5 + sqrt(5))/8): S.Pi*Rational(2, 5),
sqrt(2)*sqrt(5 + sqrt(5))/4: S.Pi*Rational(2, 5),
S.Half: S.Pi/6,
sqrt(2 - sqrt(2))/2: S.Pi/8,
sqrt(S.Half - sqrt(2)/4): S.Pi/8,
sqrt(2 + sqrt(2))/2: S.Pi*Rational(3, 8),
sqrt(S.Half + sqrt(2)/4): S.Pi*Rational(3, 8),
(sqrt(5) - 1)/4: S.Pi/10,
(1 - sqrt(5))/4: -S.Pi/10,
(sqrt(5) + 1)/4: S.Pi*Rational(3, 10),
sqrt(6)/4 - sqrt(2)/4: S.Pi/12,
-sqrt(6)/4 + sqrt(2)/4: -S.Pi/12,
(sqrt(3) - 1)/sqrt(8): S.Pi/12,
(1 - sqrt(3))/sqrt(8): -S.Pi/12,
sqrt(6)/4 + sqrt(2)/4: S.Pi*Rational(5, 12),
(1 + sqrt(3))/sqrt(8): S.Pi*Rational(5, 12)
}
@staticmethod
def _atan_table():
# Only keys with could_extract_minus_sign() == False
# are actually needed.
return {
sqrt(3)/3: S.Pi/6,
1/sqrt(3): S.Pi/6,
sqrt(3): S.Pi/3,
sqrt(2) - 1: S.Pi/8,
1 - sqrt(2): -S.Pi/8,
1 + sqrt(2): S.Pi*Rational(3, 8),
sqrt(5 - 2*sqrt(5)): S.Pi/5,
sqrt(5 + 2*sqrt(5)): S.Pi*Rational(2, 5),
sqrt(1 - 2*sqrt(5)/5): S.Pi/10,
sqrt(1 + 2*sqrt(5)/5): S.Pi*Rational(3, 10),
2 - sqrt(3): S.Pi/12,
-2 + sqrt(3): -S.Pi/12,
2 + sqrt(3): S.Pi*Rational(5, 12)
}
@staticmethod
def _acsc_table():
# Keys for which could_extract_minus_sign()
# will obviously return True are omitted.
return {
2*sqrt(3)/3: S.Pi/3,
sqrt(2): S.Pi/4,
sqrt(2 + 2*sqrt(5)/5): S.Pi/5,
1/sqrt(Rational(5, 8) - sqrt(5)/8): S.Pi/5,
sqrt(2 - 2*sqrt(5)/5): S.Pi*Rational(2, 5),
1/sqrt(Rational(5, 8) + sqrt(5)/8): S.Pi*Rational(2, 5),
2: S.Pi/6,
sqrt(4 + 2*sqrt(2)): S.Pi/8,
2/sqrt(2 - sqrt(2)): S.Pi/8,
sqrt(4 - 2*sqrt(2)): S.Pi*Rational(3, 8),
2/sqrt(2 + sqrt(2)): S.Pi*Rational(3, 8),
1 + sqrt(5): S.Pi/10,
sqrt(5) - 1: S.Pi*Rational(3, 10),
-(sqrt(5) - 1): S.Pi*Rational(-3, 10),
sqrt(6) + sqrt(2): S.Pi/12,
sqrt(6) - sqrt(2): S.Pi*Rational(5, 12),
-(sqrt(6) - sqrt(2)): S.Pi*Rational(-5, 12)
}
class asin(InverseTrigonometricFunction):
"""
The inverse sine function.
Returns the arcsine of x in radians.
Notes
=====
``asin(x)`` will evaluate automatically in the cases ``oo``, ``-oo``,
``0``, ``1``, ``-1`` and for some instances when the result is a rational
multiple of pi (see the eval class method).
A purely imaginary argument will lead to an asinh expression.
Examples
========
>>> from sympy import asin, oo
>>> asin(1)
pi/2
>>> asin(-1)
-pi/2
>>> asin(-oo)
oo*I
>>> asin(oo)
-oo*I
See Also
========
sin, csc, cos, sec, tan, cot
acsc, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions
.. [2] http://dlmf.nist.gov/4.23
.. [3] http://functions.wolfram.com/ElementaryFunctions/ArcSin
"""
def fdiff(self, argindex=1):
if argindex == 1:
return 1/sqrt(1 - self.args[0]**2)
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
if s.args[0].is_rational:
return False
else:
return s.is_rational
def _eval_is_positive(self):
return self._eval_is_extended_real() and self.args[0].is_positive
def _eval_is_negative(self):
return self._eval_is_extended_real() and self.args[0].is_negative
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.NegativeInfinity*S.ImaginaryUnit
elif arg is S.NegativeInfinity:
return S.Infinity*S.ImaginaryUnit
elif arg.is_zero:
return S.Zero
elif arg is S.One:
return S.Pi/2
elif arg is S.NegativeOne:
return -S.Pi/2
if arg is S.ComplexInfinity:
return S.ComplexInfinity
if arg.could_extract_minus_sign():
return -cls(-arg)
if arg.is_number:
asin_table = cls._asin_table()
if arg in asin_table:
return asin_table[arg]
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return S.ImaginaryUnit*asinh(i_coeff)
if arg.is_zero:
return S.Zero
if isinstance(arg, sin):
ang = arg.args[0]
if ang.is_comparable:
ang %= 2*pi # restrict to [0,2*pi)
if ang > pi: # restrict to (-pi,pi]
ang = pi - ang
# restrict to [-pi/2,pi/2]
if ang > pi/2:
ang = pi - ang
if ang < -pi/2:
ang = -pi - ang
return ang
if isinstance(arg, cos): # acos(x) + asin(x) = pi/2
ang = arg.args[0]
if ang.is_comparable:
return pi/2 - acos(arg)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) >= 2 and n > 2:
p = previous_terms[-2]
return p*(n - 2)**2/(n*(n - 1))*x**2
else:
k = (n - 1) // 2
R = RisingFactorial(S.Half, k)
F = factorial(k)
return R/F*x**n/n
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return arg
else:
return self.func(arg)
def _eval_rewrite_as_acos(self, x, **kwargs):
return S.Pi/2 - acos(x)
def _eval_rewrite_as_atan(self, x, **kwargs):
return 2*atan(x/(1 + sqrt(1 - x**2)))
def _eval_rewrite_as_log(self, x, **kwargs):
return -S.ImaginaryUnit*log(S.ImaginaryUnit*x + sqrt(1 - x**2))
def _eval_rewrite_as_acot(self, arg, **kwargs):
return 2*acot((1 + sqrt(1 - arg**2))/arg)
def _eval_rewrite_as_asec(self, arg, **kwargs):
return S.Pi/2 - asec(1/arg)
def _eval_rewrite_as_acsc(self, arg, **kwargs):
return acsc(1/arg)
def _eval_is_extended_real(self):
x = self.args[0]
return x.is_extended_real and (1 - abs(x)).is_nonnegative
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return sin
class acos(InverseTrigonometricFunction):
"""
The inverse cosine function.
Returns the arc cosine of x (measured in radians).
Notes
=====
``acos(x)`` will evaluate automatically in the cases
``oo``, ``-oo``, ``0``, ``1``, ``-1`` and for some instances when
the result is a rational multiple of pi (see the eval class method).
``acos(zoo)`` evaluates to ``zoo``
(see note in :class:`sympy.functions.elementary.trigonometric.asec`)
A purely imaginary argument will be rewritten to asinh.
Examples
========
>>> from sympy import acos, oo
>>> acos(1)
0
>>> acos(0)
pi/2
>>> acos(oo)
oo*I
See Also
========
sin, csc, cos, sec, tan, cot
asin, acsc, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions
.. [2] http://dlmf.nist.gov/4.23
.. [3] http://functions.wolfram.com/ElementaryFunctions/ArcCos
"""
def fdiff(self, argindex=1):
if argindex == 1:
return -1/sqrt(1 - self.args[0]**2)
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
if s.args[0].is_rational:
return False
else:
return s.is_rational
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Infinity*S.ImaginaryUnit
elif arg is S.NegativeInfinity:
return S.NegativeInfinity*S.ImaginaryUnit
elif arg.is_zero:
return S.Pi/2
elif arg is S.One:
return S.Zero
elif arg is S.NegativeOne:
return S.Pi
if arg is S.ComplexInfinity:
return S.ComplexInfinity
if arg.is_number:
asin_table = cls._asin_table()
if arg in asin_table:
return pi/2 - asin_table[arg]
elif -arg in asin_table:
return pi/2 + asin_table[-arg]
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return pi/2 - asin(arg)
if isinstance(arg, cos):
ang = arg.args[0]
if ang.is_comparable:
ang %= 2*pi # restrict to [0,2*pi)
if ang > pi: # restrict to [0,pi]
ang = 2*pi - ang
return ang
if isinstance(arg, sin): # acos(x) + asin(x) = pi/2
ang = arg.args[0]
if ang.is_comparable:
return pi/2 - asin(arg)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n == 0:
return S.Pi/2
elif n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) >= 2 and n > 2:
p = previous_terms[-2]
return p*(n - 2)**2/(n*(n - 1))*x**2
else:
k = (n - 1) // 2
R = RisingFactorial(S.Half, k)
F = factorial(k)
return -R/F*x**n/n
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return arg
else:
return self.func(arg)
def _eval_is_extended_real(self):
x = self.args[0]
return x.is_extended_real and (1 - abs(x)).is_nonnegative
def _eval_is_nonnegative(self):
return self._eval_is_extended_real()
def _eval_nseries(self, x, n, logx):
return self._eval_rewrite_as_log(self.args[0])._eval_nseries(x, n, logx)
def _eval_rewrite_as_log(self, x, **kwargs):
return S.Pi/2 + S.ImaginaryUnit*\
log(S.ImaginaryUnit*x + sqrt(1 - x**2))
def _eval_rewrite_as_asin(self, x, **kwargs):
return S.Pi/2 - asin(x)
def _eval_rewrite_as_atan(self, x, **kwargs):
return atan(sqrt(1 - x**2)/x) + (S.Pi/2)*(1 - x*sqrt(1/x**2))
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return cos
def _eval_rewrite_as_acot(self, arg, **kwargs):
return S.Pi/2 - 2*acot((1 + sqrt(1 - arg**2))/arg)
def _eval_rewrite_as_asec(self, arg, **kwargs):
return asec(1/arg)
def _eval_rewrite_as_acsc(self, arg, **kwargs):
return S.Pi/2 - acsc(1/arg)
def _eval_conjugate(self):
z = self.args[0]
r = self.func(self.args[0].conjugate())
if z.is_extended_real is False:
return r
elif z.is_extended_real and (z + 1).is_nonnegative and (z - 1).is_nonpositive:
return r
class atan(InverseTrigonometricFunction):
"""
The inverse tangent function.
Returns the arc tangent of x (measured in radians).
Notes
=====
``atan(x)`` will evaluate automatically in the cases
``oo``, ``-oo``, ``0``, ``1``, ``-1`` and for some instances when the
result is a rational multiple of pi (see the eval class method).
Examples
========
>>> from sympy import atan, oo
>>> atan(0)
0
>>> atan(1)
pi/4
>>> atan(oo)
pi/2
See Also
========
sin, csc, cos, sec, tan, cot
asin, acsc, acos, asec, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions
.. [2] http://dlmf.nist.gov/4.23
.. [3] http://functions.wolfram.com/ElementaryFunctions/ArcTan
"""
_singularities = (S.ImaginaryUnit, -S.ImaginaryUnit)
def fdiff(self, argindex=1):
if argindex == 1:
return 1/(1 + self.args[0]**2)
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
if s.args[0].is_rational:
return False
else:
return s.is_rational
def _eval_is_positive(self):
return self.args[0].is_extended_positive
def _eval_is_nonnegative(self):
return self.args[0].is_extended_nonnegative
def _eval_is_zero(self):
return self.args[0].is_zero
def _eval_is_real(self):
return self.args[0].is_extended_real
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Pi/2
elif arg is S.NegativeInfinity:
return -S.Pi/2
elif arg.is_zero:
return S.Zero
elif arg is S.One:
return S.Pi/4
elif arg is S.NegativeOne:
return -S.Pi/4
if arg is S.ComplexInfinity:
from sympy.calculus.util import AccumBounds
return AccumBounds(-S.Pi/2, S.Pi/2)
if arg.could_extract_minus_sign():
return -cls(-arg)
if arg.is_number:
atan_table = cls._atan_table()
if arg in atan_table:
return atan_table[arg]
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return S.ImaginaryUnit*atanh(i_coeff)
if arg.is_zero:
return S.Zero
if isinstance(arg, tan):
ang = arg.args[0]
if ang.is_comparable:
ang %= pi # restrict to [0,pi)
if ang > pi/2: # restrict to [-pi/2,pi/2]
ang -= pi
return ang
if isinstance(arg, cot): # atan(x) + acot(x) = pi/2
ang = arg.args[0]
if ang.is_comparable:
ang = pi/2 - acot(arg)
if ang > pi/2: # restrict to [-pi/2,pi/2]
ang -= pi
return ang
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
return (-1)**((n - 1)//2)*x**n/n
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return arg
else:
return self.func(arg)
def _eval_rewrite_as_log(self, x, **kwargs):
return S.ImaginaryUnit/2*(log(S.One - S.ImaginaryUnit*x)
- log(S.One + S.ImaginaryUnit*x))
def _eval_aseries(self, n, args0, x, logx):
if args0[0] is S.Infinity:
return (S.Pi/2 - atan(1/self.args[0]))._eval_nseries(x, n, logx)
elif args0[0] is S.NegativeInfinity:
return (-S.Pi/2 - atan(1/self.args[0]))._eval_nseries(x, n, logx)
else:
return super()._eval_aseries(n, args0, x, logx)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return tan
def _eval_rewrite_as_asin(self, arg, **kwargs):
return sqrt(arg**2)/arg*(S.Pi/2 - asin(1/sqrt(1 + arg**2)))
def _eval_rewrite_as_acos(self, arg, **kwargs):
return sqrt(arg**2)/arg*acos(1/sqrt(1 + arg**2))
def _eval_rewrite_as_acot(self, arg, **kwargs):
return acot(1/arg)
def _eval_rewrite_as_asec(self, arg, **kwargs):
return sqrt(arg**2)/arg*asec(sqrt(1 + arg**2))
def _eval_rewrite_as_acsc(self, arg, **kwargs):
return sqrt(arg**2)/arg*(S.Pi/2 - acsc(sqrt(1 + arg**2)))
class acot(InverseTrigonometricFunction):
r"""
The inverse cotangent function.
Returns the arc cotangent of x (measured in radians).
Notes
=====
``acot(x)`` will evaluate automatically in the cases ``oo``, ``-oo``,
``zoo``, ``0``, ``1``, ``-1`` and for some instances when the result is a
rational multiple of pi (see the eval class method).
A purely imaginary argument will lead to an ``acoth`` expression.
``acot(x)`` has a branch cut along `(-i, i)`, hence it is discontinuous
at 0. Its range for real ``x`` is `(-\frac{\pi}{2}, \frac{\pi}{2}]`.
Examples
========
>>> from sympy import acot, sqrt
>>> acot(0)
pi/2
>>> acot(1)
pi/4
>>> acot(sqrt(3) - 2)
-5*pi/12
See Also
========
sin, csc, cos, sec, tan, cot
asin, acsc, acos, asec, atan, atan2
References
==========
.. [1] http://dlmf.nist.gov/4.23
.. [2] http://functions.wolfram.com/ElementaryFunctions/ArcCot
"""
_singularities = (S.ImaginaryUnit, -S.ImaginaryUnit)
def fdiff(self, argindex=1):
if argindex == 1:
return -1/(1 + self.args[0]**2)
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
if s.args[0].is_rational:
return False
else:
return s.is_rational
def _eval_is_positive(self):
return self.args[0].is_nonnegative
def _eval_is_negative(self):
return self.args[0].is_negative
def _eval_is_extended_real(self):
return self.args[0].is_extended_real
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Zero
elif arg is S.NegativeInfinity:
return S.Zero
elif arg.is_zero:
return S.Pi/ 2
elif arg is S.One:
return S.Pi/4
elif arg is S.NegativeOne:
return -S.Pi/4
if arg is S.ComplexInfinity:
return S.Zero
if arg.could_extract_minus_sign():
return -cls(-arg)
if arg.is_number:
atan_table = cls._atan_table()
if arg in atan_table:
ang = pi/2 - atan_table[arg]
if ang > pi/2: # restrict to (-pi/2,pi/2]
ang -= pi
return ang
i_coeff = arg.as_coefficient(S.ImaginaryUnit)
if i_coeff is not None:
return -S.ImaginaryUnit*acoth(i_coeff)
if arg.is_zero:
return S.Pi*S.Half
if isinstance(arg, cot):
ang = arg.args[0]
if ang.is_comparable:
ang %= pi # restrict to [0,pi)
if ang > pi/2: # restrict to (-pi/2,pi/2]
ang -= pi;
return ang
if isinstance(arg, tan): # atan(x) + acot(x) = pi/2
ang = arg.args[0]
if ang.is_comparable:
ang = pi/2 - atan(arg)
if ang > pi/2: # restrict to (-pi/2,pi/2]
ang -= pi
return ang
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n == 0:
return S.Pi/2 # FIX THIS
elif n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
return (-1)**((n + 1)//2)*x**n/n
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return arg
else:
return self.func(arg)
def _eval_aseries(self, n, args0, x, logx):
if args0[0] is S.Infinity:
return (S.Pi/2 - acot(1/self.args[0]))._eval_nseries(x, n, logx)
elif args0[0] is S.NegativeInfinity:
return (S.Pi*Rational(3, 2) - acot(1/self.args[0]))._eval_nseries(x, n, logx)
else:
return super(atan, self)._eval_aseries(n, args0, x, logx)
def _eval_rewrite_as_log(self, x, **kwargs):
return S.ImaginaryUnit/2*(log(1 - S.ImaginaryUnit/x)
- log(1 + S.ImaginaryUnit/x))
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return cot
def _eval_rewrite_as_asin(self, arg, **kwargs):
return (arg*sqrt(1/arg**2)*
(S.Pi/2 - asin(sqrt(-arg**2)/sqrt(-arg**2 - 1))))
def _eval_rewrite_as_acos(self, arg, **kwargs):
return arg*sqrt(1/arg**2)*acos(sqrt(-arg**2)/sqrt(-arg**2 - 1))
def _eval_rewrite_as_atan(self, arg, **kwargs):
return atan(1/arg)
def _eval_rewrite_as_asec(self, arg, **kwargs):
return arg*sqrt(1/arg**2)*asec(sqrt((1 + arg**2)/arg**2))
def _eval_rewrite_as_acsc(self, arg, **kwargs):
return arg*sqrt(1/arg**2)*(S.Pi/2 - acsc(sqrt((1 + arg**2)/arg**2)))
class asec(InverseTrigonometricFunction):
r"""
The inverse secant function.
Returns the arc secant of x (measured in radians).
Notes
=====
``asec(x)`` will evaluate automatically in the cases ``oo``, ``-oo``,
``0``, ``1``, ``-1`` and for some instances when the result is a rational
multiple of pi (see the eval class method).
``asec(x)`` has branch cut in the interval [-1, 1]. For complex arguments,
it can be defined [4]_ as
.. math::
\operatorname{sec^{-1}}(z) = -i\frac{\log\left(\sqrt{1 - z^2} + 1\right)}{z}
At ``x = 0``, for positive branch cut, the limit evaluates to ``zoo``. For
negative branch cut, the limit
.. math::
\lim_{z \to 0}-i\frac{\log\left(-\sqrt{1 - z^2} + 1\right)}{z}
simplifies to :math:`-i\log\left(z/2 + O\left(z^3\right)\right)` which
ultimately evaluates to ``zoo``.
As ``acos(x)`` = ``asec(1/x)``, a similar argument can be given for
``acos(x)``.
Examples
========
>>> from sympy import asec, oo
>>> asec(1)
0
>>> asec(-1)
pi
>>> asec(0)
zoo
>>> asec(-oo)
pi/2
See Also
========
sin, csc, cos, sec, tan, cot
asin, acsc, acos, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions
.. [2] http://dlmf.nist.gov/4.23
.. [3] http://functions.wolfram.com/ElementaryFunctions/ArcSec
.. [4] http://reference.wolfram.com/language/ref/ArcSec.html
"""
@classmethod
def eval(cls, arg):
if arg.is_zero:
return S.ComplexInfinity
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.One:
return S.Zero
elif arg is S.NegativeOne:
return S.Pi
if arg in [S.Infinity, S.NegativeInfinity, S.ComplexInfinity]:
return S.Pi/2
if arg.is_number:
acsc_table = cls._acsc_table()
if arg in acsc_table:
return pi/2 - acsc_table[arg]
elif -arg in acsc_table:
return pi/2 + acsc_table[-arg]
if isinstance(arg, sec):
ang = arg.args[0]
if ang.is_comparable:
ang %= 2*pi # restrict to [0,2*pi)
if ang > pi: # restrict to [0,pi]
ang = 2*pi - ang
return ang
if isinstance(arg, csc): # asec(x) + acsc(x) = pi/2
ang = arg.args[0]
if ang.is_comparable:
return pi/2 - acsc(arg)
def fdiff(self, argindex=1):
if argindex == 1:
return 1/(self.args[0]**2*sqrt(1 - 1/self.args[0]**2))
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return sec
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if Order(1,x).contains(arg):
return log(arg)
else:
return self.func(arg)
def _eval_is_extended_real(self):
x = self.args[0]
if x.is_extended_real is False:
return False
return fuzzy_or(((x - 1).is_nonnegative, (-x - 1).is_nonnegative))
def _eval_rewrite_as_log(self, arg, **kwargs):
return S.Pi/2 + S.ImaginaryUnit*log(S.ImaginaryUnit/arg + sqrt(1 - 1/arg**2))
def _eval_rewrite_as_asin(self, arg, **kwargs):
return S.Pi/2 - asin(1/arg)
def _eval_rewrite_as_acos(self, arg, **kwargs):
return acos(1/arg)
def _eval_rewrite_as_atan(self, arg, **kwargs):
return sqrt(arg**2)/arg*(-S.Pi/2 + 2*atan(arg + sqrt(arg**2 - 1)))
def _eval_rewrite_as_acot(self, arg, **kwargs):
return sqrt(arg**2)/arg*(-S.Pi/2 + 2*acot(arg - sqrt(arg**2 - 1)))
def _eval_rewrite_as_acsc(self, arg, **kwargs):
return S.Pi/2 - acsc(arg)
class acsc(InverseTrigonometricFunction):
"""
The inverse cosecant function.
Returns the arc cosecant of x (measured in radians).
Notes
=====
``acsc(x)`` will evaluate automatically in the cases ``oo``, ``-oo``,
``0``, ``1``, ``-1`` and for some instances when the result is a rational
multiple of pi (see the eval class method).
Examples
========
>>> from sympy import acsc, oo
>>> acsc(1)
pi/2
>>> acsc(-1)
-pi/2
>>> acsc(oo)
0
>>> acsc(-oo) == acsc(oo)
True
>>> acsc(0)
zoo
See Also
========
sin, csc, cos, sec, tan, cot
asin, acos, asec, atan, acot, atan2
References
==========
.. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions
.. [2] http://dlmf.nist.gov/4.23
.. [3] http://functions.wolfram.com/ElementaryFunctions/ArcCsc
"""
@classmethod
def eval(cls, arg):
if arg.is_zero:
return S.ComplexInfinity
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.One:
return S.Pi/2
elif arg is S.NegativeOne:
return -S.Pi/2
if arg in [S.Infinity, S.NegativeInfinity, S.ComplexInfinity]:
return S.Zero
if arg.could_extract_minus_sign():
return -cls(-arg)
if arg.is_number:
acsc_table = cls._acsc_table()
if arg in acsc_table:
return acsc_table[arg]
if isinstance(arg, csc):
ang = arg.args[0]
if ang.is_comparable:
ang %= 2*pi # restrict to [0,2*pi)
if ang > pi: # restrict to (-pi,pi]
ang = pi - ang
# restrict to [-pi/2,pi/2]
if ang > pi/2:
ang = pi - ang
if ang < -pi/2:
ang = -pi - ang
return ang
if isinstance(arg, sec): # asec(x) + acsc(x) = pi/2
ang = arg.args[0]
if ang.is_comparable:
return pi/2 - asec(arg)
def fdiff(self, argindex=1):
if argindex == 1:
return -1/(self.args[0]**2*sqrt(1 - 1/self.args[0]**2))
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return csc
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if Order(1,x).contains(arg):
return log(arg)
else:
return self.func(arg)
def _eval_rewrite_as_log(self, arg, **kwargs):
return -S.ImaginaryUnit*log(S.ImaginaryUnit/arg + sqrt(1 - 1/arg**2))
def _eval_rewrite_as_asin(self, arg, **kwargs):
return asin(1/arg)
def _eval_rewrite_as_acos(self, arg, **kwargs):
return S.Pi/2 - acos(1/arg)
def _eval_rewrite_as_atan(self, arg, **kwargs):
return sqrt(arg**2)/arg*(S.Pi/2 - atan(sqrt(arg**2 - 1)))
def _eval_rewrite_as_acot(self, arg, **kwargs):
return sqrt(arg**2)/arg*(S.Pi/2 - acot(1/sqrt(arg**2 - 1)))
def _eval_rewrite_as_asec(self, arg, **kwargs):
return S.Pi/2 - asec(arg)
class atan2(InverseTrigonometricFunction):
r"""
The function ``atan2(y, x)`` computes `\operatorname{atan}(y/x)` taking
two arguments `y` and `x`. Signs of both `y` and `x` are considered to
determine the appropriate quadrant of `\operatorname{atan}(y/x)`.
The range is `(-\pi, \pi]`. The complete definition reads as follows:
.. math::
\operatorname{atan2}(y, x) =
\begin{cases}
\arctan\left(\frac y x\right) & \qquad x > 0 \\
\arctan\left(\frac y x\right) + \pi& \qquad y \ge 0 , x < 0 \\
\arctan\left(\frac y x\right) - \pi& \qquad y < 0 , x < 0 \\
+\frac{\pi}{2} & \qquad y > 0 , x = 0 \\
-\frac{\pi}{2} & \qquad y < 0 , x = 0 \\
\text{undefined} & \qquad y = 0, x = 0
\end{cases}
Attention: Note the role reversal of both arguments. The `y`-coordinate
is the first argument and the `x`-coordinate the second.
If either `x` or `y` is complex:
.. math::
\operatorname{atan2}(y, x) =
-i\log\left(\frac{x + iy}{\sqrt{x**2 + y**2}}\right)
Examples
========
Going counter-clock wise around the origin we find the
following angles:
>>> from sympy import atan2
>>> atan2(0, 1)
0
>>> atan2(1, 1)
pi/4
>>> atan2(1, 0)
pi/2
>>> atan2(1, -1)
3*pi/4
>>> atan2(0, -1)
pi
>>> atan2(-1, -1)
-3*pi/4
>>> atan2(-1, 0)
-pi/2
>>> atan2(-1, 1)
-pi/4
which are all correct. Compare this to the results of the ordinary
`\operatorname{atan}` function for the point `(x, y) = (-1, 1)`
>>> from sympy import atan, S
>>> atan(S(1)/-1)
-pi/4
>>> atan2(1, -1)
3*pi/4
where only the `\operatorname{atan2}` function reurns what we expect.
We can differentiate the function with respect to both arguments:
>>> from sympy import diff
>>> from sympy.abc import x, y
>>> diff(atan2(y, x), x)
-y/(x**2 + y**2)
>>> diff(atan2(y, x), y)
x/(x**2 + y**2)
We can express the `\operatorname{atan2}` function in terms of
complex logarithms:
>>> from sympy import log
>>> atan2(y, x).rewrite(log)
-I*log((x + I*y)/sqrt(x**2 + y**2))
and in terms of `\operatorname(atan)`:
>>> from sympy import atan
>>> atan2(y, x).rewrite(atan)
Piecewise((2*atan(y/(x + sqrt(x**2 + y**2))), Ne(y, 0)), (pi, re(x) < 0), (0, Ne(x, 0)), (nan, True))
but note that this form is undefined on the negative real axis.
See Also
========
sin, csc, cos, sec, tan, cot
asin, acsc, acos, asec, atan, acot
References
==========
.. [1] https://en.wikipedia.org/wiki/Inverse_trigonometric_functions
.. [2] https://en.wikipedia.org/wiki/Atan2
.. [3] http://functions.wolfram.com/ElementaryFunctions/ArcTan2
"""
@classmethod
def eval(cls, y, x):
from sympy import Heaviside, im, re
if x is S.NegativeInfinity:
if y.is_zero:
# Special case y = 0 because we define Heaviside(0) = 1/2
return S.Pi
return 2*S.Pi*(Heaviside(re(y))) - S.Pi
elif x is S.Infinity:
return S.Zero
elif x.is_imaginary and y.is_imaginary and x.is_number and y.is_number:
x = im(x)
y = im(y)
if x.is_extended_real and y.is_extended_real:
if x.is_positive:
return atan(y/x)
elif x.is_negative:
if y.is_negative:
return atan(y/x) - S.Pi
elif y.is_nonnegative:
return atan(y/x) + S.Pi
elif x.is_zero:
if y.is_positive:
return S.Pi/2
elif y.is_negative:
return -S.Pi/2
elif y.is_zero:
return S.NaN
if y.is_zero:
if x.is_extended_nonzero:
return S.Pi*(S.One - Heaviside(x))
if x.is_number:
return Piecewise((S.Pi, re(x) < 0),
(0, Ne(x, 0)),
(S.NaN, True))
if x.is_number and y.is_number:
return -S.ImaginaryUnit*log(
(x + S.ImaginaryUnit*y)/sqrt(x**2 + y**2))
def _eval_rewrite_as_log(self, y, x, **kwargs):
return -S.ImaginaryUnit*log((x + S.ImaginaryUnit*y)/sqrt(x**2 + y**2))
def _eval_rewrite_as_atan(self, y, x, **kwargs):
from sympy import re
return Piecewise((2*atan(y/(x + sqrt(x**2 + y**2))), Ne(y, 0)),
(pi, re(x) < 0),
(0, Ne(x, 0)),
(S.NaN, True))
def _eval_rewrite_as_arg(self, y, x, **kwargs):
from sympy import arg
if x.is_extended_real and y.is_extended_real:
return arg(x + y*S.ImaginaryUnit)
n = x + S.ImaginaryUnit*y
d = x**2 + y**2
return arg(n/sqrt(d)) - S.ImaginaryUnit*log(abs(n)/sqrt(abs(d)))
def _eval_is_extended_real(self):
return self.args[0].is_extended_real and self.args[1].is_extended_real
def _eval_conjugate(self):
return self.func(self.args[0].conjugate(), self.args[1].conjugate())
def fdiff(self, argindex):
y, x = self.args
if argindex == 1:
# Diff wrt y
return x/(x**2 + y**2)
elif argindex == 2:
# Diff wrt x
return -y/(x**2 + y**2)
else:
raise ArgumentIndexError(self, argindex)
def _eval_evalf(self, prec):
y, x = self.args
if x.is_extended_real and y.is_extended_real:
return super()._eval_evalf(prec)
|
7cf3a8eb00bd83ea66bb00e7a35cbdc2b352cb0d0dd19c21366ea595addaf7d4 | from sympy.core import Function, S, sympify
from sympy.core.add import Add
from sympy.core.containers import Tuple
from sympy.core.operations import LatticeOp, ShortCircuit
from sympy.core.function import (Application, Lambda,
ArgumentIndexError)
from sympy.core.expr import Expr
from sympy.core.mod import Mod
from sympy.core.mul import Mul
from sympy.core.numbers import Rational
from sympy.core.power import Pow
from sympy.core.relational import Eq, Relational
from sympy.core.singleton import Singleton
from sympy.core.symbol import Dummy
from sympy.core.rules import Transform
from sympy.core.logic import fuzzy_and, fuzzy_or, _torf
from sympy.logic.boolalg import And, Or
def _minmax_as_Piecewise(op, *args):
# helper for Min/Max rewrite as Piecewise
from sympy.functions.elementary.piecewise import Piecewise
ec = []
for i, a in enumerate(args):
c = []
for j in range(i + 1, len(args)):
c.append(Relational(a, args[j], op))
ec.append((a, And(*c)))
return Piecewise(*ec)
class IdentityFunction(Lambda, metaclass=Singleton):
"""
The identity function
Examples
========
>>> from sympy import Id, Symbol
>>> x = Symbol('x')
>>> Id(x)
x
"""
def __new__(cls):
x = Dummy('x')
#construct "by hand" to avoid infinite loop
return Expr.__new__(cls, Tuple(x), x)
@property
def args(self):
return ()
def __getnewargs__(self):
return ()
Id = S.IdentityFunction
###############################################################################
############################# ROOT and SQUARE ROOT FUNCTION ###################
###############################################################################
def sqrt(arg, evaluate=None):
"""Returns the principal square root.
Parameters
==========
evaluate : bool, optional
The parameter determines if the expression should be evaluated.
If ``None``, its value is taken from
``global_parameters.evaluate``.
Examples
========
>>> from sympy import sqrt, Symbol, S
>>> x = Symbol('x')
>>> sqrt(x)
sqrt(x)
>>> sqrt(x)**2
x
Note that sqrt(x**2) does not simplify to x.
>>> sqrt(x**2)
sqrt(x**2)
This is because the two are not equal to each other in general.
For example, consider x == -1:
>>> from sympy import Eq
>>> Eq(sqrt(x**2), x).subs(x, -1)
False
This is because sqrt computes the principal square root, so the square may
put the argument in a different branch. This identity does hold if x is
positive:
>>> y = Symbol('y', positive=True)
>>> sqrt(y**2)
y
You can force this simplification by using the powdenest() function with
the force option set to True:
>>> from sympy import powdenest
>>> sqrt(x**2)
sqrt(x**2)
>>> powdenest(sqrt(x**2), force=True)
x
To get both branches of the square root you can use the rootof function:
>>> from sympy import rootof
>>> [rootof(x**2-3,i) for i in (0,1)]
[-sqrt(3), sqrt(3)]
Although ``sqrt`` is printed, there is no ``sqrt`` function so looking for
``sqrt`` in an expression will fail:
>>> from sympy.utilities.misc import func_name
>>> func_name(sqrt(x))
'Pow'
>>> sqrt(x).has(sqrt)
Traceback (most recent call last):
...
sympy.core.sympify.SympifyError: SympifyError: <function sqrt at 0x10e8900d0>
To find ``sqrt`` look for ``Pow`` with an exponent of ``1/2``:
>>> (x + 1/sqrt(x)).find(lambda i: i.is_Pow and abs(i.exp) is S.Half)
{1/sqrt(x)}
See Also
========
sympy.polys.rootoftools.rootof, root, real_root
References
==========
.. [1] https://en.wikipedia.org/wiki/Square_root
.. [2] https://en.wikipedia.org/wiki/Principal_value
"""
# arg = sympify(arg) is handled by Pow
return Pow(arg, S.Half, evaluate=evaluate)
def cbrt(arg, evaluate=None):
"""Returns the principal cube root.
Parameters
==========
evaluate : bool, optional
The parameter determines if the expression should be evaluated.
If ``None``, its value is taken from
``global_parameters.evaluate``.
Examples
========
>>> from sympy import cbrt, Symbol
>>> x = Symbol('x')
>>> cbrt(x)
x**(1/3)
>>> cbrt(x)**3
x
Note that cbrt(x**3) does not simplify to x.
>>> cbrt(x**3)
(x**3)**(1/3)
This is because the two are not equal to each other in general.
For example, consider `x == -1`:
>>> from sympy import Eq
>>> Eq(cbrt(x**3), x).subs(x, -1)
False
This is because cbrt computes the principal cube root, this
identity does hold if `x` is positive:
>>> y = Symbol('y', positive=True)
>>> cbrt(y**3)
y
See Also
========
sympy.polys.rootoftools.rootof, root, real_root
References
==========
* https://en.wikipedia.org/wiki/Cube_root
* https://en.wikipedia.org/wiki/Principal_value
"""
return Pow(arg, Rational(1, 3), evaluate=evaluate)
def root(arg, n, k=0, evaluate=None):
r"""Returns the *k*-th *n*-th root of ``arg``.
Parameters
==========
k : int, optional
Should be an integer in $\{0, 1, ..., n-1\}$.
Defaults to the principal root if $0$.
evaluate : bool, optional
The parameter determines if the expression should be evaluated.
If ``None``, its value is taken from
``global_parameters.evaluate``.
Examples
========
>>> from sympy import root, Rational
>>> from sympy.abc import x, n
>>> root(x, 2)
sqrt(x)
>>> root(x, 3)
x**(1/3)
>>> root(x, n)
x**(1/n)
>>> root(x, -Rational(2, 3))
x**(-3/2)
To get the k-th n-th root, specify k:
>>> root(-2, 3, 2)
-(-1)**(2/3)*2**(1/3)
To get all n n-th roots you can use the rootof function.
The following examples show the roots of unity for n
equal 2, 3 and 4:
>>> from sympy import rootof
>>> [rootof(x**2 - 1, i) for i in range(2)]
[-1, 1]
>>> [rootof(x**3 - 1,i) for i in range(3)]
[1, -1/2 - sqrt(3)*I/2, -1/2 + sqrt(3)*I/2]
>>> [rootof(x**4 - 1,i) for i in range(4)]
[-1, 1, -I, I]
SymPy, like other symbolic algebra systems, returns the
complex root of negative numbers. This is the principal
root and differs from the text-book result that one might
be expecting. For example, the cube root of -8 does not
come back as -2:
>>> root(-8, 3)
2*(-1)**(1/3)
The real_root function can be used to either make the principal
result real (or simply to return the real root directly):
>>> from sympy import real_root
>>> real_root(_)
-2
>>> real_root(-32, 5)
-2
Alternatively, the n//2-th n-th root of a negative number can be
computed with root:
>>> root(-32, 5, 5//2)
-2
See Also
========
sympy.polys.rootoftools.rootof
sympy.core.power.integer_nthroot
sqrt, real_root
References
==========
* https://en.wikipedia.org/wiki/Square_root
* https://en.wikipedia.org/wiki/Real_root
* https://en.wikipedia.org/wiki/Root_of_unity
* https://en.wikipedia.org/wiki/Principal_value
* http://mathworld.wolfram.com/CubeRoot.html
"""
n = sympify(n)
if k:
return Mul(Pow(arg, S.One/n, evaluate=evaluate), S.NegativeOne**(2*k/n), evaluate=evaluate)
return Pow(arg, 1/n, evaluate=evaluate)
def real_root(arg, n=None, evaluate=None):
"""Return the real *n*'th-root of *arg* if possible.
Parameters
==========
n : int or None, optional
If *n* is ``None``, then all instances of
``(-n)**(1/odd)`` will be changed to ``-n**(1/odd)``.
This will only create a real root of a principal root.
The presence of other factors may cause the result to not be
real.
evaluate : bool, optional
The parameter determines if the expression should be evaluated.
If ``None``, its value is taken from
``global_parameters.evaluate``.
Examples
========
>>> from sympy import root, real_root
>>> real_root(-8, 3)
-2
>>> root(-8, 3)
2*(-1)**(1/3)
>>> real_root(_)
-2
If one creates a non-principal root and applies real_root, the
result will not be real (so use with caution):
>>> root(-8, 3, 2)
-2*(-1)**(2/3)
>>> real_root(_)
-2*(-1)**(2/3)
See Also
========
sympy.polys.rootoftools.rootof
sympy.core.power.integer_nthroot
root, sqrt
"""
from sympy.functions.elementary.complexes import Abs, im, sign
from sympy.functions.elementary.piecewise import Piecewise
if n is not None:
return Piecewise(
(root(arg, n, evaluate=evaluate), Or(Eq(n, S.One), Eq(n, S.NegativeOne))),
(Mul(sign(arg), root(Abs(arg), n, evaluate=evaluate), evaluate=evaluate),
And(Eq(im(arg), S.Zero), Eq(Mod(n, 2), S.One))),
(root(arg, n, evaluate=evaluate), True))
rv = sympify(arg)
n1pow = Transform(lambda x: -(-x.base)**x.exp,
lambda x:
x.is_Pow and
x.base.is_negative and
x.exp.is_Rational and
x.exp.p == 1 and x.exp.q % 2)
return rv.xreplace(n1pow)
###############################################################################
############################# MINIMUM and MAXIMUM #############################
###############################################################################
class MinMaxBase(Expr, LatticeOp):
def __new__(cls, *args, **assumptions):
evaluate = assumptions.pop('evaluate', True)
args = (sympify(arg) for arg in args)
# first standard filter, for cls.zero and cls.identity
# also reshape Max(a, Max(b, c)) to Max(a, b, c)
if evaluate:
try:
args = frozenset(cls._new_args_filter(args))
except ShortCircuit:
return cls.zero
else:
args = frozenset(args)
if evaluate:
# remove redundant args that are easily identified
args = cls._collapse_arguments(args, **assumptions)
# find local zeros
args = cls._find_localzeros(args, **assumptions)
if not args:
return cls.identity
if len(args) == 1:
return list(args).pop()
# base creation
_args = frozenset(args)
obj = Expr.__new__(cls, _args, **assumptions)
obj._argset = _args
return obj
@classmethod
def _collapse_arguments(cls, args, **assumptions):
"""Remove redundant args.
Examples
========
>>> from sympy import Min, Max
>>> from sympy.abc import a, b, c, d, e
Any arg in parent that appears in any
parent-like function in any of the flat args
of parent can be removed from that sub-arg:
>>> Min(a, Max(b, Min(a, c, d)))
Min(a, Max(b, Min(c, d)))
If the arg of parent appears in an opposite-than parent
function in any of the flat args of parent that function
can be replaced with the arg:
>>> Min(a, Max(b, Min(c, d, Max(a, e))))
Min(a, Max(b, Min(a, c, d)))
"""
from sympy.utilities.iterables import ordered
from sympy.simplify.simplify import walk
if not args:
return args
args = list(ordered(args))
if cls == Min:
other = Max
else:
other = Min
# find global comparable max of Max and min of Min if a new
# value is being introduced in these args at position 0 of
# the ordered args
if args[0].is_number:
sifted = mins, maxs = [], []
for i in args:
for v in walk(i, Min, Max):
if v.args[0].is_comparable:
sifted[isinstance(v, Max)].append(v)
small = Min.identity
for i in mins:
v = i.args[0]
if v.is_number and (v < small) == True:
small = v
big = Max.identity
for i in maxs:
v = i.args[0]
if v.is_number and (v > big) == True:
big = v
# at the point when this function is called from __new__,
# there may be more than one numeric arg present since
# local zeros have not been handled yet, so look through
# more than the first arg
if cls == Min:
for i in range(len(args)):
if not args[i].is_number:
break
if (args[i] < small) == True:
small = args[i]
elif cls == Max:
for i in range(len(args)):
if not args[i].is_number:
break
if (args[i] > big) == True:
big = args[i]
T = None
if cls == Min:
if small != Min.identity:
other = Max
T = small
elif big != Max.identity:
other = Min
T = big
if T is not None:
# remove numerical redundancy
for i in range(len(args)):
a = args[i]
if isinstance(a, other):
a0 = a.args[0]
if ((a0 > T) if other == Max else (a0 < T)) == True:
args[i] = cls.identity
# remove redundant symbolic args
def do(ai, a):
if not isinstance(ai, (Min, Max)):
return ai
cond = a in ai.args
if not cond:
return ai.func(*[do(i, a) for i in ai.args],
evaluate=False)
if isinstance(ai, cls):
return ai.func(*[do(i, a) for i in ai.args if i != a],
evaluate=False)
return a
for i, a in enumerate(args):
args[i + 1:] = [do(ai, a) for ai in args[i + 1:]]
# factor out common elements as for
# Min(Max(x, y), Max(x, z)) -> Max(x, Min(y, z))
# and vice versa when swapping Min/Max -- do this only for the
# easy case where all functions contain something in common;
# trying to find some optimal subset of args to modify takes
# too long
if len(args) > 1:
common = None
remove = []
sets = []
for i in range(len(args)):
a = args[i]
if not isinstance(a, other):
continue
s = set(a.args)
common = s if common is None else (common & s)
if not common:
break
sets.append(s)
remove.append(i)
if common:
sets = filter(None, [s - common for s in sets])
sets = [other(*s, evaluate=False) for s in sets]
for i in reversed(remove):
args.pop(i)
oargs = [cls(*sets)] if sets else []
oargs.extend(common)
args.append(other(*oargs, evaluate=False))
return args
@classmethod
def _new_args_filter(cls, arg_sequence):
"""
Generator filtering args.
first standard filter, for cls.zero and cls.identity.
Also reshape Max(a, Max(b, c)) to Max(a, b, c),
and check arguments for comparability
"""
for arg in arg_sequence:
# pre-filter, checking comparability of arguments
if not isinstance(arg, Expr) or arg.is_extended_real is False or (
arg.is_number and
not arg.is_comparable):
raise ValueError("The argument '%s' is not comparable." % arg)
if arg == cls.zero:
raise ShortCircuit(arg)
elif arg == cls.identity:
continue
elif arg.func == cls:
yield from arg.args
else:
yield arg
@classmethod
def _find_localzeros(cls, values, **options):
"""
Sequentially allocate values to localzeros.
When a value is identified as being more extreme than another member it
replaces that member; if this is never true, then the value is simply
appended to the localzeros.
"""
localzeros = set()
for v in values:
is_newzero = True
localzeros_ = list(localzeros)
for z in localzeros_:
if id(v) == id(z):
is_newzero = False
else:
con = cls._is_connected(v, z)
if con:
is_newzero = False
if con is True or con == cls:
localzeros.remove(z)
localzeros.update([v])
if is_newzero:
localzeros.update([v])
return localzeros
@classmethod
def _is_connected(cls, x, y):
"""
Check if x and y are connected somehow.
"""
from sympy.core.exprtools import factor_terms
def hit(v, t, f):
if not v.is_Relational:
return t if v else f
for i in range(2):
if x == y:
return True
r = hit(x >= y, Max, Min)
if r is not None:
return r
r = hit(y <= x, Max, Min)
if r is not None:
return r
r = hit(x <= y, Min, Max)
if r is not None:
return r
r = hit(y >= x, Min, Max)
if r is not None:
return r
# simplification can be expensive, so be conservative
# in what is attempted
x = factor_terms(x - y)
y = S.Zero
return False
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_zero:
continue
try:
df = self.fdiff(i)
except ArgumentIndexError:
df = Function.fdiff(self, i)
l.append(df * da)
return Add(*l)
def _eval_rewrite_as_Abs(self, *args, **kwargs):
from sympy.functions.elementary.complexes import Abs
s = (args[0] + self.func(*args[1:]))/2
d = abs(args[0] - self.func(*args[1:]))/2
return (s + d if isinstance(self, Max) else s - d).rewrite(Abs)
def evalf(self, n=15, **options):
return self.func(*[a.evalf(n, **options) for a in self.args])
def n(self, *args, **kwargs):
return self.evalf(*args, **kwargs)
_eval_is_algebraic = lambda s: _torf(i.is_algebraic for i in s.args)
_eval_is_antihermitian = lambda s: _torf(i.is_antihermitian for i in s.args)
_eval_is_commutative = lambda s: _torf(i.is_commutative for i in s.args)
_eval_is_complex = lambda s: _torf(i.is_complex for i in s.args)
_eval_is_composite = lambda s: _torf(i.is_composite for i in s.args)
_eval_is_even = lambda s: _torf(i.is_even for i in s.args)
_eval_is_finite = lambda s: _torf(i.is_finite for i in s.args)
_eval_is_hermitian = lambda s: _torf(i.is_hermitian for i in s.args)
_eval_is_imaginary = lambda s: _torf(i.is_imaginary for i in s.args)
_eval_is_infinite = lambda s: _torf(i.is_infinite for i in s.args)
_eval_is_integer = lambda s: _torf(i.is_integer for i in s.args)
_eval_is_irrational = lambda s: _torf(i.is_irrational for i in s.args)
_eval_is_negative = lambda s: _torf(i.is_negative for i in s.args)
_eval_is_noninteger = lambda s: _torf(i.is_noninteger for i in s.args)
_eval_is_nonnegative = lambda s: _torf(i.is_nonnegative for i in s.args)
_eval_is_nonpositive = lambda s: _torf(i.is_nonpositive for i in s.args)
_eval_is_nonzero = lambda s: _torf(i.is_nonzero for i in s.args)
_eval_is_odd = lambda s: _torf(i.is_odd for i in s.args)
_eval_is_polar = lambda s: _torf(i.is_polar for i in s.args)
_eval_is_positive = lambda s: _torf(i.is_positive for i in s.args)
_eval_is_prime = lambda s: _torf(i.is_prime for i in s.args)
_eval_is_rational = lambda s: _torf(i.is_rational for i in s.args)
_eval_is_real = lambda s: _torf(i.is_real for i in s.args)
_eval_is_extended_real = lambda s: _torf(i.is_extended_real for i in s.args)
_eval_is_transcendental = lambda s: _torf(i.is_transcendental for i in s.args)
_eval_is_zero = lambda s: _torf(i.is_zero for i in s.args)
class Max(MinMaxBase, Application):
"""
Return, if possible, the maximum value of the list.
When number of arguments is equal one, then
return this argument.
When number of arguments is equal two, then
return, if possible, the value from (a, b) that is >= the other.
In common case, when the length of list greater than 2, the task
is more complicated. Return only the arguments, which are greater
than others, if it is possible to determine directional relation.
If is not possible to determine such a relation, return a partially
evaluated result.
Assumptions are used to make the decision too.
Also, only comparable arguments are permitted.
It is named ``Max`` and not ``max`` to avoid conflicts
with the built-in function ``max``.
Examples
========
>>> from sympy import Max, Symbol, oo
>>> from sympy.abc import x, y, z
>>> p = Symbol('p', positive=True)
>>> n = Symbol('n', negative=True)
>>> Max(x, -2)
Max(-2, x)
>>> Max(x, -2).subs(x, 3)
3
>>> Max(p, -2)
p
>>> Max(x, y)
Max(x, y)
>>> Max(x, y) == Max(y, x)
True
>>> Max(x, Max(y, z))
Max(x, y, z)
>>> Max(n, 8, p, 7, -oo)
Max(8, p)
>>> Max (1, x, oo)
oo
* Algorithm
The task can be considered as searching of supremums in the
directed complete partial orders [1]_.
The source values are sequentially allocated by the isolated subsets
in which supremums are searched and result as Max arguments.
If the resulted supremum is single, then it is returned.
The isolated subsets are the sets of values which are only the comparable
with each other in the current set. E.g. natural numbers are comparable with
each other, but not comparable with the `x` symbol. Another example: the
symbol `x` with negative assumption is comparable with a natural number.
Also there are "least" elements, which are comparable with all others,
and have a zero property (maximum or minimum for all elements). E.g. `oo`.
In case of it the allocation operation is terminated and only this value is
returned.
Assumption:
- if A > B > C then A > C
- if A == B then B can be removed
References
==========
.. [1] https://en.wikipedia.org/wiki/Directed_complete_partial_order
.. [2] https://en.wikipedia.org/wiki/Lattice_%28order%29
See Also
========
Min : find minimum values
"""
zero = S.Infinity
identity = S.NegativeInfinity
def fdiff( self, argindex ):
from sympy import Heaviside
n = len(self.args)
if 0 < argindex and argindex <= n:
argindex -= 1
if n == 2:
return Heaviside(self.args[argindex] - self.args[1 - argindex])
newargs = tuple([self.args[i] for i in range(n) if i != argindex])
return Heaviside(self.args[argindex] - Max(*newargs))
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_Heaviside(self, *args, **kwargs):
from sympy import Heaviside
return Add(*[j*Mul(*[Heaviside(j - i) for i in args if i!=j]) \
for j in args])
def _eval_rewrite_as_Piecewise(self, *args, **kwargs):
return _minmax_as_Piecewise('>=', *args)
def _eval_is_positive(self):
return fuzzy_or(a.is_positive for a in self.args)
def _eval_is_nonnegative(self):
return fuzzy_or(a.is_nonnegative for a in self.args)
def _eval_is_negative(self):
return fuzzy_and(a.is_negative for a in self.args)
class Min(MinMaxBase, Application):
"""
Return, if possible, the minimum value of the list.
It is named ``Min`` and not ``min`` to avoid conflicts
with the built-in function ``min``.
Examples
========
>>> from sympy import Min, Symbol, oo
>>> from sympy.abc import x, y
>>> p = Symbol('p', positive=True)
>>> n = Symbol('n', negative=True)
>>> Min(x, -2)
Min(-2, x)
>>> Min(x, -2).subs(x, 3)
-2
>>> Min(p, -3)
-3
>>> Min(x, y)
Min(x, y)
>>> Min(n, 8, p, -7, p, oo)
Min(-7, n)
See Also
========
Max : find maximum values
"""
zero = S.NegativeInfinity
identity = S.Infinity
def fdiff( self, argindex ):
from sympy import Heaviside
n = len(self.args)
if 0 < argindex and argindex <= n:
argindex -= 1
if n == 2:
return Heaviside( self.args[1-argindex] - self.args[argindex] )
newargs = tuple([ self.args[i] for i in range(n) if i != argindex])
return Heaviside( Min(*newargs) - self.args[argindex] )
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_Heaviside(self, *args, **kwargs):
from sympy import Heaviside
return Add(*[j*Mul(*[Heaviside(i-j) for i in args if i!=j]) \
for j in args])
def _eval_rewrite_as_Piecewise(self, *args, **kwargs):
return _minmax_as_Piecewise('<=', *args)
def _eval_is_positive(self):
return fuzzy_and(a.is_positive for a in self.args)
def _eval_is_nonnegative(self):
return fuzzy_and(a.is_nonnegative for a in self.args)
def _eval_is_negative(self):
return fuzzy_or(a.is_negative for a in self.args)
|
75089ab3c1e8b96b90312bbfe1a979dd2228ef4aadc4faf21d2e7a987664560d | from sympy.core import Basic, S, Function, diff, Tuple, Dummy
from sympy.core.basic import as_Basic
from sympy.core.numbers import Rational, NumberSymbol
from sympy.core.relational import (Equality, Unequality, Relational,
_canonical)
from sympy.functions.elementary.miscellaneous import Max, Min
from sympy.logic.boolalg import (And, Boolean, distribute_and_over_or,
true, false, Or, ITE, simplify_logic)
from sympy.utilities.iterables import uniq, ordered, product, sift
from sympy.utilities.misc import filldedent, func_name
Undefined = S.NaN # Piecewise()
class ExprCondPair(Tuple):
"""Represents an expression, condition pair."""
def __new__(cls, expr, cond):
expr = as_Basic(expr)
if cond == True:
return Tuple.__new__(cls, expr, true)
elif cond == False:
return Tuple.__new__(cls, expr, false)
elif isinstance(cond, Basic) and cond.has(Piecewise):
cond = piecewise_fold(cond)
if isinstance(cond, Piecewise):
cond = cond.rewrite(ITE)
if not isinstance(cond, Boolean):
raise TypeError(filldedent('''
Second argument must be a Boolean,
not `%s`''' % func_name(cond)))
return Tuple.__new__(cls, expr, cond)
@property
def expr(self):
"""
Returns the expression of this pair.
"""
return self.args[0]
@property
def cond(self):
"""
Returns the condition of this pair.
"""
return self.args[1]
@property
def is_commutative(self):
return self.expr.is_commutative
def __iter__(self):
yield self.expr
yield self.cond
def _eval_simplify(self, **kwargs):
return self.func(*[a.simplify(**kwargs) for a in self.args])
class Piecewise(Function):
"""
Represents a piecewise function.
Usage:
Piecewise( (expr,cond), (expr,cond), ... )
- Each argument is a 2-tuple defining an expression and condition
- The conds are evaluated in turn returning the first that is True.
If any of the evaluated conds are not determined explicitly False,
e.g. x < 1, the function is returned in symbolic form.
- If the function is evaluated at a place where all conditions are False,
nan will be returned.
- Pairs where the cond is explicitly False, will be removed.
Examples
========
>>> from sympy import Piecewise, log, piecewise_fold
>>> from sympy.abc import x, y
>>> f = x**2
>>> g = log(x)
>>> p = Piecewise((0, x < -1), (f, x <= 1), (g, True))
>>> p.subs(x,1)
1
>>> p.subs(x,5)
log(5)
Booleans can contain Piecewise elements:
>>> cond = (x < y).subs(x, Piecewise((2, x < 0), (3, True))); cond
Piecewise((2, x < 0), (3, True)) < y
The folded version of this results in a Piecewise whose
expressions are Booleans:
>>> folded_cond = piecewise_fold(cond); folded_cond
Piecewise((2 < y, x < 0), (3 < y, True))
When a Boolean containing Piecewise (like cond) or a Piecewise
with Boolean expressions (like folded_cond) is used as a condition,
it is converted to an equivalent ITE object:
>>> Piecewise((1, folded_cond))
Piecewise((1, ITE(x < 0, y > 2, y > 3)))
When a condition is an ITE, it will be converted to a simplified
Boolean expression:
>>> piecewise_fold(_)
Piecewise((1, ((x >= 0) | (y > 2)) & ((y > 3) | (x < 0))))
See Also
========
piecewise_fold, ITE
"""
nargs = None
is_Piecewise = True
def __new__(cls, *args, **options):
if len(args) == 0:
raise TypeError("At least one (expr, cond) pair expected.")
# (Try to) sympify args first
newargs = []
for ec in args:
# ec could be a ExprCondPair or a tuple
pair = ExprCondPair(*getattr(ec, 'args', ec))
cond = pair.cond
if cond is false:
continue
newargs.append(pair)
if cond is true:
break
if options.pop('evaluate', True):
r = cls.eval(*newargs)
else:
r = None
if r is None:
return Basic.__new__(cls, *newargs, **options)
else:
return r
@classmethod
def eval(cls, *_args):
"""Either return a modified version of the args or, if no
modifications were made, return None.
Modifications that are made here:
1) relationals are made canonical
2) any False conditions are dropped
3) any repeat of a previous condition is ignored
3) any args past one with a true condition are dropped
If there are no args left, nan will be returned.
If there is a single arg with a True condition, its
corresponding expression will be returned.
"""
from sympy.functions.elementary.complexes import im, re
if not _args:
return Undefined
if len(_args) == 1 and _args[0][-1] == True:
return _args[0][0]
newargs = [] # the unevaluated conditions
current_cond = set() # the conditions up to a given e, c pair
# make conditions canonical
args = []
for e, c in _args:
if (not c.is_Atom and not isinstance(c, Relational) and
not c.has(im, re)):
free = c.free_symbols
if len(free) == 1:
funcs = [i for i in c.atoms(Function)
if not isinstance(i, Boolean)]
if len(funcs) == 1 and len(
c.xreplace({list(funcs)[0]: Dummy()}
).free_symbols) == 1:
# we can treat function like a symbol
free = funcs
_c = c
x = free.pop()
try:
c = c.as_set().as_relational(x)
except NotImplementedError:
pass
else:
reps = {}
for i in c.atoms(Relational):
ic = i.canonical
if ic.rhs in (S.Infinity, S.NegativeInfinity):
if not _c.has(ic.rhs):
# don't accept introduction of
# new Relationals with +/-oo
reps[i] = S.true
elif ('=' not in ic.rel_op and
c.xreplace({x: i.rhs}) !=
_c.xreplace({x: i.rhs})):
reps[i] = Relational(
i.lhs, i.rhs, i.rel_op + '=')
c = c.xreplace(reps)
args.append((e, _canonical(c)))
for expr, cond in args:
# Check here if expr is a Piecewise and collapse if one of
# the conds in expr matches cond. This allows the collapsing
# of Piecewise((Piecewise((x,x<0)),x<0)) to Piecewise((x,x<0)).
# This is important when using piecewise_fold to simplify
# multiple Piecewise instances having the same conds.
# Eventually, this code should be able to collapse Piecewise's
# having different intervals, but this will probably require
# using the new assumptions.
if isinstance(expr, Piecewise):
unmatching = []
for i, (e, c) in enumerate(expr.args):
if c in current_cond:
# this would already have triggered
continue
if c == cond:
if c != True:
# nothing past this condition will ever
# trigger and only those args before this
# that didn't match a previous condition
# could possibly trigger
if unmatching:
expr = Piecewise(*(
unmatching + [(e, c)]))
else:
expr = e
break
else:
unmatching.append((e, c))
# check for condition repeats
got = False
# -- if an And contains a condition that was
# already encountered, then the And will be
# False: if the previous condition was False
# then the And will be False and if the previous
# condition is True then then we wouldn't get to
# this point. In either case, we can skip this condition.
for i in ([cond] +
(list(cond.args) if isinstance(cond, And) else
[])):
if i in current_cond:
got = True
break
if got:
continue
# -- if not(c) is already in current_cond then c is
# a redundant condition in an And. This does not
# apply to Or, however: (e1, c), (e2, Or(~c, d))
# is not (e1, c), (e2, d) because if c and d are
# both False this would give no results when the
# true answer should be (e2, True)
if isinstance(cond, And):
nonredundant = []
for c in cond.args:
if (isinstance(c, Relational) and
c.negated.canonical in current_cond):
continue
nonredundant.append(c)
cond = cond.func(*nonredundant)
elif isinstance(cond, Relational):
if cond.negated.canonical in current_cond:
cond = S.true
current_cond.add(cond)
# collect successive e,c pairs when exprs or cond match
if newargs:
if newargs[-1].expr == expr:
orcond = Or(cond, newargs[-1].cond)
if isinstance(orcond, (And, Or)):
orcond = distribute_and_over_or(orcond)
newargs[-1] = ExprCondPair(expr, orcond)
continue
elif newargs[-1].cond == cond:
newargs[-1] = ExprCondPair(expr, cond)
continue
newargs.append(ExprCondPair(expr, cond))
# some conditions may have been redundant
missing = len(newargs) != len(_args)
# some conditions may have changed
same = all(a == b for a, b in zip(newargs, _args))
# if either change happened we return the expr with the
# updated args
if not newargs:
raise ValueError(filldedent('''
There are no conditions (or none that
are not trivially false) to define an
expression.'''))
if missing or not same:
return cls(*newargs)
def doit(self, **hints):
"""
Evaluate this piecewise function.
"""
newargs = []
for e, c in self.args:
if hints.get('deep', True):
if isinstance(e, Basic):
newe = e.doit(**hints)
if newe != self:
e = newe
if isinstance(c, Basic):
c = c.doit(**hints)
newargs.append((e, c))
return self.func(*newargs)
def _eval_simplify(self, **kwargs):
return piecewise_simplify(self, **kwargs)
def _eval_as_leading_term(self, x):
for e, c in self.args:
if c == True or c.subs(x, 0) == True:
return e.as_leading_term(x)
def _eval_adjoint(self):
return self.func(*[(e.adjoint(), c) for e, c in self.args])
def _eval_conjugate(self):
return self.func(*[(e.conjugate(), c) for e, c in self.args])
def _eval_derivative(self, x):
return self.func(*[(diff(e, x), c) for e, c in self.args])
def _eval_evalf(self, prec):
return self.func(*[(e._evalf(prec), c) for e, c in self.args])
def piecewise_integrate(self, x, **kwargs):
"""Return the Piecewise with each expression being
replaced with its antiderivative. To obtain a continuous
antiderivative, use the `integrate` function or method.
Examples
========
>>> from sympy import Piecewise
>>> from sympy.abc import x
>>> p = Piecewise((0, x < 0), (1, x < 1), (2, True))
>>> p.piecewise_integrate(x)
Piecewise((0, x < 0), (x, x < 1), (2*x, True))
Note that this does not give a continuous function, e.g.
at x = 1 the 3rd condition applies and the antiderivative
there is 2*x so the value of the antiderivative is 2:
>>> anti = _
>>> anti.subs(x, 1)
2
The continuous derivative accounts for the integral *up to*
the point of interest, however:
>>> p.integrate(x)
Piecewise((0, x < 0), (x, x < 1), (2*x - 1, True))
>>> _.subs(x, 1)
1
See Also
========
Piecewise._eval_integral
"""
from sympy.integrals import integrate
return self.func(*[(integrate(e, x, **kwargs), c) for e, c in self.args])
def _handle_irel(self, x, handler):
"""Return either None (if the conditions of self depend only on x) else
a Piecewise expression whose expressions (handled by the handler that
was passed) are paired with the governing x-independent relationals,
e.g. Piecewise((A, a(x) & b(y)), (B, c(x) | c(y)) ->
Piecewise(
(handler(Piecewise((A, a(x) & True), (B, c(x) | True)), b(y) & c(y)),
(handler(Piecewise((A, a(x) & True), (B, c(x) | False)), b(y)),
(handler(Piecewise((A, a(x) & False), (B, c(x) | True)), c(y)),
(handler(Piecewise((A, a(x) & False), (B, c(x) | False)), True))
"""
# identify governing relationals
rel = self.atoms(Relational)
irel = list(ordered([r for r in rel if x not in r.free_symbols
and r not in (S.true, S.false)]))
if irel:
args = {}
exprinorder = []
for truth in product((1, 0), repeat=len(irel)):
reps = dict(zip(irel, truth))
# only store the true conditions since the false are implied
# when they appear lower in the Piecewise args
if 1 not in truth:
cond = None # flag this one so it doesn't get combined
else:
andargs = Tuple(*[i for i in reps if reps[i]])
free = list(andargs.free_symbols)
if len(free) == 1:
from sympy.solvers.inequalities import (
reduce_inequalities, _solve_inequality)
try:
t = reduce_inequalities(andargs, free[0])
# ValueError when there are potentially
# nonvanishing imaginary parts
except (ValueError, NotImplementedError):
# at least isolate free symbol on left
t = And(*[_solve_inequality(
a, free[0], linear=True)
for a in andargs])
else:
t = And(*andargs)
if t is S.false:
continue # an impossible combination
cond = t
expr = handler(self.xreplace(reps))
if isinstance(expr, self.func) and len(expr.args) == 1:
expr, econd = expr.args[0]
cond = And(econd, True if cond is None else cond)
# the ec pairs are being collected since all possibilities
# are being enumerated, but don't put the last one in since
# its expr might match a previous expression and it
# must appear last in the args
if cond is not None:
args.setdefault(expr, []).append(cond)
# but since we only store the true conditions we must maintain
# the order so that the expression with the most true values
# comes first
exprinorder.append(expr)
# convert collected conditions as args of Or
for k in args:
args[k] = Or(*args[k])
# take them in the order obtained
args = [(e, args[e]) for e in uniq(exprinorder)]
# add in the last arg
args.append((expr, True))
# if any condition reduced to True, it needs to go last
# and there should only be one of them or else the exprs
# should agree
trues = [i for i in range(len(args)) if args[i][1] is S.true]
if not trues:
# make the last one True since all cases were enumerated
e, c = args[-1]
args[-1] = (e, S.true)
else:
assert len({e for e, c in [args[i] for i in trues]}) == 1
args.append(args.pop(trues.pop()))
while trues:
args.pop(trues.pop())
return Piecewise(*args)
def _eval_integral(self, x, _first=True, **kwargs):
"""Return the indefinite integral of the
Piecewise such that subsequent substitution of x with a
value will give the value of the integral (not including
the constant of integration) up to that point. To only
integrate the individual parts of Piecewise, use the
`piecewise_integrate` method.
Examples
========
>>> from sympy import Piecewise
>>> from sympy.abc import x
>>> p = Piecewise((0, x < 0), (1, x < 1), (2, True))
>>> p.integrate(x)
Piecewise((0, x < 0), (x, x < 1), (2*x - 1, True))
>>> p.piecewise_integrate(x)
Piecewise((0, x < 0), (x, x < 1), (2*x, True))
See Also
========
Piecewise.piecewise_integrate
"""
from sympy.integrals.integrals import integrate
if _first:
def handler(ipw):
if isinstance(ipw, self.func):
return ipw._eval_integral(x, _first=False, **kwargs)
else:
return ipw.integrate(x, **kwargs)
irv = self._handle_irel(x, handler)
if irv is not None:
return irv
# handle a Piecewise from -oo to oo with and no x-independent relationals
# -----------------------------------------------------------------------
try:
abei = self._intervals(x)
except NotImplementedError:
from sympy import Integral
return Integral(self, x) # unevaluated
pieces = [(a, b) for a, b, _, _ in abei]
oo = S.Infinity
done = [(-oo, oo, -1)]
for k, p in enumerate(pieces):
if p == (-oo, oo):
# all undone intervals will get this key
for j, (a, b, i) in enumerate(done):
if i == -1:
done[j] = a, b, k
break # nothing else to consider
N = len(done) - 1
for j, (a, b, i) in enumerate(reversed(done)):
if i == -1:
j = N - j
done[j: j + 1] = _clip(p, (a, b), k)
done = [(a, b, i) for a, b, i in done if a != b]
# append an arg if there is a hole so a reference to
# argument -1 will give Undefined
if any(i == -1 for (a, b, i) in done):
abei.append((-oo, oo, Undefined, -1))
# return the sum of the intervals
args = []
sum = None
for a, b, i in done:
anti = integrate(abei[i][-2], x, **kwargs)
if sum is None:
sum = anti
else:
sum = sum.subs(x, a)
if sum == Undefined:
sum = 0
sum += anti._eval_interval(x, a, x)
# see if we know whether b is contained in original
# condition
if b is S.Infinity:
cond = True
elif self.args[abei[i][-1]].cond.subs(x, b) == False:
cond = (x < b)
else:
cond = (x <= b)
args.append((sum, cond))
return Piecewise(*args)
def _eval_interval(self, sym, a, b, _first=True):
"""Evaluates the function along the sym in a given interval [a, b]"""
# FIXME: Currently complex intervals are not supported. A possible
# replacement algorithm, discussed in issue 5227, can be found in the
# following papers;
# http://portal.acm.org/citation.cfm?id=281649
# http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.70.4127&rep=rep1&type=pdf
from sympy.core.symbol import Dummy
if a is None or b is None:
# In this case, it is just simple substitution
return super()._eval_interval(sym, a, b)
else:
x, lo, hi = map(as_Basic, (sym, a, b))
if _first: # get only x-dependent relationals
def handler(ipw):
if isinstance(ipw, self.func):
return ipw._eval_interval(x, lo, hi, _first=None)
else:
return ipw._eval_interval(x, lo, hi)
irv = self._handle_irel(x, handler)
if irv is not None:
return irv
if (lo < hi) is S.false or (
lo is S.Infinity or hi is S.NegativeInfinity):
rv = self._eval_interval(x, hi, lo, _first=False)
if isinstance(rv, Piecewise):
rv = Piecewise(*[(-e, c) for e, c in rv.args])
else:
rv = -rv
return rv
if (lo < hi) is S.true or (
hi is S.Infinity or lo is S.NegativeInfinity):
pass
else:
_a = Dummy('lo')
_b = Dummy('hi')
a = lo if lo.is_comparable else _a
b = hi if hi.is_comparable else _b
pos = self._eval_interval(x, a, b, _first=False)
if a == _a and b == _b:
# it's purely symbolic so just swap lo and hi and
# change the sign to get the value for when lo > hi
neg, pos = (-pos.xreplace({_a: hi, _b: lo}),
pos.xreplace({_a: lo, _b: hi}))
else:
# at least one of the bounds was comparable, so allow
# _eval_interval to use that information when computing
# the interval with lo and hi reversed
neg, pos = (-self._eval_interval(x, hi, lo, _first=False),
pos.xreplace({_a: lo, _b: hi}))
# allow simplification based on ordering of lo and hi
p = Dummy('', positive=True)
if lo.is_Symbol:
pos = pos.xreplace({lo: hi - p}).xreplace({p: hi - lo})
neg = neg.xreplace({lo: hi + p}).xreplace({p: lo - hi})
elif hi.is_Symbol:
pos = pos.xreplace({hi: lo + p}).xreplace({p: hi - lo})
neg = neg.xreplace({hi: lo - p}).xreplace({p: lo - hi})
# assemble return expression; make the first condition be Lt
# b/c then the first expression will look the same whether
# the lo or hi limit is symbolic
if a == _a: # the lower limit was symbolic
rv = Piecewise(
(pos,
lo < hi),
(neg,
True))
else:
rv = Piecewise(
(neg,
hi < lo),
(pos,
True))
if rv == Undefined:
raise ValueError("Can't integrate across undefined region.")
if any(isinstance(i, Piecewise) for i in (pos, neg)):
rv = piecewise_fold(rv)
return rv
# handle a Piecewise with lo <= hi and no x-independent relationals
# -----------------------------------------------------------------
try:
abei = self._intervals(x)
except NotImplementedError:
from sympy import Integral
# not being able to do the interval of f(x) can
# be stated as not being able to do the integral
# of f'(x) over the same range
return Integral(self.diff(x), (x, lo, hi)) # unevaluated
pieces = [(a, b) for a, b, _, _ in abei]
done = [(lo, hi, -1)]
oo = S.Infinity
for k, p in enumerate(pieces):
if p[:2] == (-oo, oo):
# all undone intervals will get this key
for j, (a, b, i) in enumerate(done):
if i == -1:
done[j] = a, b, k
break # nothing else to consider
N = len(done) - 1
for j, (a, b, i) in enumerate(reversed(done)):
if i == -1:
j = N - j
done[j: j + 1] = _clip(p, (a, b), k)
done = [(a, b, i) for a, b, i in done if a != b]
# return the sum of the intervals
sum = S.Zero
upto = None
for a, b, i in done:
if i == -1:
if upto is None:
return Undefined
# TODO simplify hi <= upto
return Piecewise((sum, hi <= upto), (Undefined, True))
sum += abei[i][-2]._eval_interval(x, a, b)
upto = b
return sum
def _intervals(self, sym):
"""Return a list of unique tuples, (a, b, e, i), where a and b
are the lower and upper bounds in which the expression e of
argument i in self is defined and a < b (when involving
numbers) or a <= b when involving symbols.
If there are any relationals not involving sym, or any
relational cannot be solved for sym, NotImplementedError is
raised. The calling routine should have removed such
relationals before calling this routine.
The evaluated conditions will be returned as ranges.
Discontinuous ranges will be returned separately with
identical expressions. The first condition that evaluates to
True will be returned as the last tuple with a, b = -oo, oo.
"""
from sympy.solvers.inequalities import _solve_inequality
from sympy.logic.boolalg import to_cnf, distribute_or_over_and
assert isinstance(self, Piecewise)
def _solve_relational(r):
if sym not in r.free_symbols:
nonsymfail(r)
rv = _solve_inequality(r, sym)
if isinstance(rv, Relational):
free = rv.args[1].free_symbols
if rv.args[0] != sym or sym in free:
raise NotImplementedError(filldedent('''
Unable to solve relational
%s for %s.''' % (r, sym)))
if rv.rel_op == '==':
# this equality has been affirmed to have the form
# Eq(sym, rhs) where rhs is sym-free; it represents
# a zero-width interval which will be ignored
# whether it is an isolated condition or contained
# within an And or an Or
rv = S.false
elif rv.rel_op == '!=':
try:
rv = Or(sym < rv.rhs, sym > rv.rhs)
except TypeError:
# e.g. x != I ==> all real x satisfy
rv = S.true
elif rv == (S.NegativeInfinity < sym) & (sym < S.Infinity):
rv = S.true
return rv
def nonsymfail(cond):
raise NotImplementedError(filldedent('''
A condition not involving
%s appeared: %s''' % (sym, cond)))
# make self canonical wrt Relationals
reps = {
r: _solve_relational(r) for r in self.atoms(Relational)}
# process args individually so if any evaluate, their position
# in the original Piecewise will be known
args = [i.xreplace(reps) for i in self.args]
# precondition args
expr_cond = []
default = idefault = None
for i, (expr, cond) in enumerate(args):
if cond is S.false:
continue
elif cond is S.true:
default = expr
idefault = i
break
cond = to_cnf(cond)
if isinstance(cond, And):
cond = distribute_or_over_and(cond)
if isinstance(cond, Or):
expr_cond.extend(
[(i, expr, o) for o in cond.args
if not isinstance(o, Equality)])
elif cond is not S.false:
expr_cond.append((i, expr, cond))
# determine intervals represented by conditions
int_expr = []
for iarg, expr, cond in expr_cond:
if isinstance(cond, And):
lower = S.NegativeInfinity
upper = S.Infinity
for cond2 in cond.args:
if isinstance(cond2, Equality):
lower = upper # ignore
break
elif cond2.lts == sym:
upper = Min(cond2.gts, upper)
elif cond2.gts == sym:
lower = Max(cond2.lts, lower)
else:
nonsymfail(cond2) # should never get here
elif isinstance(cond, Relational):
lower, upper = cond.lts, cond.gts # part 1: initialize with givens
if cond.lts == sym: # part 1a: expand the side ...
lower = S.NegativeInfinity # e.g. x <= 0 ---> -oo <= 0
elif cond.gts == sym: # part 1a: ... that can be expanded
upper = S.Infinity # e.g. x >= 0 ---> oo >= 0
else:
nonsymfail(cond)
else:
raise NotImplementedError(
'unrecognized condition: %s' % cond)
lower, upper = lower, Max(lower, upper)
if (lower >= upper) is not S.true:
int_expr.append((lower, upper, expr, iarg))
if default is not None:
int_expr.append(
(S.NegativeInfinity, S.Infinity, default, idefault))
return list(uniq(int_expr))
def _eval_nseries(self, x, n, logx):
args = [(ec.expr._eval_nseries(x, n, logx), ec.cond) for ec in self.args]
return self.func(*args)
def _eval_power(self, s):
return self.func(*[(e**s, c) for e, c in self.args])
def _eval_subs(self, old, new):
# this is strictly not necessary, but we can keep track
# of whether True or False conditions arise and be
# somewhat more efficient by avoiding other substitutions
# and avoiding invalid conditions that appear after a
# True condition
args = list(self.args)
args_exist = False
for i, (e, c) in enumerate(args):
c = c._subs(old, new)
if c != False:
args_exist = True
e = e._subs(old, new)
args[i] = (e, c)
if c == True:
break
if not args_exist:
args = ((Undefined, True),)
return self.func(*args)
def _eval_transpose(self):
return self.func(*[(e.transpose(), c) for e, c in self.args])
def _eval_template_is_attr(self, is_attr):
b = None
for expr, _ in self.args:
a = getattr(expr, is_attr)
if a is None:
return
if b is None:
b = a
elif b is not a:
return
return b
_eval_is_finite = lambda self: self._eval_template_is_attr(
'is_finite')
_eval_is_complex = lambda self: self._eval_template_is_attr('is_complex')
_eval_is_even = lambda self: self._eval_template_is_attr('is_even')
_eval_is_imaginary = lambda self: self._eval_template_is_attr(
'is_imaginary')
_eval_is_integer = lambda self: self._eval_template_is_attr('is_integer')
_eval_is_irrational = lambda self: self._eval_template_is_attr(
'is_irrational')
_eval_is_negative = lambda self: self._eval_template_is_attr('is_negative')
_eval_is_nonnegative = lambda self: self._eval_template_is_attr(
'is_nonnegative')
_eval_is_nonpositive = lambda self: self._eval_template_is_attr(
'is_nonpositive')
_eval_is_nonzero = lambda self: self._eval_template_is_attr(
'is_nonzero')
_eval_is_odd = lambda self: self._eval_template_is_attr('is_odd')
_eval_is_polar = lambda self: self._eval_template_is_attr('is_polar')
_eval_is_positive = lambda self: self._eval_template_is_attr('is_positive')
_eval_is_extended_real = lambda self: self._eval_template_is_attr(
'is_extended_real')
_eval_is_extended_positive = lambda self: self._eval_template_is_attr(
'is_extended_positive')
_eval_is_extended_negative = lambda self: self._eval_template_is_attr(
'is_extended_negative')
_eval_is_extended_nonzero = lambda self: self._eval_template_is_attr(
'is_extended_nonzero')
_eval_is_extended_nonpositive = lambda self: self._eval_template_is_attr(
'is_extended_nonpositive')
_eval_is_extended_nonnegative = lambda self: self._eval_template_is_attr(
'is_extended_nonnegative')
_eval_is_real = lambda self: self._eval_template_is_attr('is_real')
_eval_is_zero = lambda self: self._eval_template_is_attr(
'is_zero')
@classmethod
def __eval_cond(cls, cond):
"""Return the truth value of the condition."""
if cond == True:
return True
if isinstance(cond, Equality):
try:
diff = cond.lhs - cond.rhs
if diff.is_commutative:
return diff.is_zero
except TypeError:
pass
def as_expr_set_pairs(self, domain=S.Reals):
"""Return tuples for each argument of self that give
the expression and the interval in which it is valid
which is contained within the given domain.
If a condition cannot be converted to a set, an error
will be raised. The variable of the conditions is
assumed to be real; sets of real values are returned.
Examples
========
>>> from sympy import Piecewise, Interval
>>> from sympy.abc import x
>>> p = Piecewise(
... (1, x < 2),
... (2,(x > 0) & (x < 4)),
... (3, True))
>>> p.as_expr_set_pairs()
[(1, Interval.open(-oo, 2)),
(2, Interval.Ropen(2, 4)),
(3, Interval(4, oo))]
>>> p.as_expr_set_pairs(Interval(0, 3))
[(1, Interval.Ropen(0, 2)),
(2, Interval(2, 3)), (3, EmptySet)]
"""
exp_sets = []
U = domain
complex = not domain.is_subset(S.Reals)
cond_free = set()
for expr, cond in self.args:
cond_free |= cond.free_symbols
if len(cond_free) > 1:
raise NotImplementedError(filldedent('''
multivariate conditions are not handled.'''))
if complex:
for i in cond.atoms(Relational):
if not isinstance(i, (Equality, Unequality)):
raise ValueError(filldedent('''
Inequalities in the complex domain are
not supported. Try the real domain by
setting domain=S.Reals'''))
cond_int = U.intersect(cond.as_set())
U = U - cond_int
exp_sets.append((expr, cond_int))
return exp_sets
def _eval_rewrite_as_ITE(self, *args, **kwargs):
byfree = {}
args = list(args)
default = any(c == True for b, c in args)
for i, (b, c) in enumerate(args):
if not isinstance(b, Boolean) and b != True:
raise TypeError(filldedent('''
Expecting Boolean or bool but got `%s`
''' % func_name(b)))
if c == True:
break
# loop over independent conditions for this b
for c in c.args if isinstance(c, Or) else [c]:
free = c.free_symbols
x = free.pop()
try:
byfree[x] = byfree.setdefault(
x, S.EmptySet).union(c.as_set())
except NotImplementedError:
if not default:
raise NotImplementedError(filldedent('''
A method to determine whether a multivariate
conditional is consistent with a complete coverage
of all variables has not been implemented so the
rewrite is being stopped after encountering `%s`.
This error would not occur if a default expression
like `(foo, True)` were given.
''' % c))
if byfree[x] in (S.UniversalSet, S.Reals):
# collapse the ith condition to True and break
args[i] = list(args[i])
c = args[i][1] = True
break
if c == True:
break
if c != True:
raise ValueError(filldedent('''
Conditions must cover all reals or a final default
condition `(foo, True)` must be given.
'''))
last, _ = args[i] # ignore all past ith arg
for a, c in reversed(args[:i]):
last = ITE(c, a, last)
return _canonical(last)
def _eval_rewrite_as_KroneckerDelta(self, *args):
from sympy import Ne, Eq, Not, KroneckerDelta
rules = {
And: [False, False],
Or: [True, True],
Not: [True, False],
Eq: [None, None],
Ne: [None, None]
}
class UnrecognizedCondition(Exception):
pass
def rewrite(cond):
if isinstance(cond, Eq):
return KroneckerDelta(*cond.args)
if isinstance(cond, Ne):
return 1 - KroneckerDelta(*cond.args)
cls, args = type(cond), cond.args
if cls not in rules:
raise UnrecognizedCondition(cls)
b1, b2 = rules[cls]
k = 1
for c in args:
if b1:
k *= 1 - rewrite(c)
else:
k *= rewrite(c)
if b2:
return 1 - k
return k
conditions = []
true_value = None
for value, cond in args:
if type(cond) in rules:
conditions.append((value, cond))
elif cond is S.true:
if true_value is None:
true_value = value
else:
return
if true_value is not None:
result = true_value
for value, cond in conditions[::-1]:
try:
k = rewrite(cond)
result = k * value + (1 - k) * result
except UnrecognizedCondition:
return
return result
def piecewise_fold(expr):
"""
Takes an expression containing a piecewise function and returns the
expression in piecewise form. In addition, any ITE conditions are
rewritten in negation normal form and simplified.
Examples
========
>>> from sympy import Piecewise, piecewise_fold, sympify as S
>>> from sympy.abc import x
>>> p = Piecewise((x, x < 1), (1, S(1) <= x))
>>> piecewise_fold(x*p)
Piecewise((x**2, x < 1), (x, True))
See Also
========
Piecewise
"""
if not isinstance(expr, Basic) or not expr.has(Piecewise):
return expr
new_args = []
if isinstance(expr, (ExprCondPair, Piecewise)):
for e, c in expr.args:
if not isinstance(e, Piecewise):
e = piecewise_fold(e)
# we don't keep Piecewise in condition because
# it has to be checked to see that it's complete
# and we convert it to ITE at that time
assert not c.has(Piecewise) # pragma: no cover
if isinstance(c, ITE):
c = c.to_nnf()
c = simplify_logic(c, form='cnf')
if isinstance(e, Piecewise):
new_args.extend([(piecewise_fold(ei), And(ci, c))
for ei, ci in e.args])
else:
new_args.append((e, c))
else:
from sympy.utilities.iterables import cartes, sift, common_prefix
# Given
# P1 = Piecewise((e11, c1), (e12, c2), A)
# P2 = Piecewise((e21, c1), (e22, c2), B)
# ...
# the folding of f(P1, P2) is trivially
# Piecewise(
# (f(e11, e21), c1),
# (f(e12, e22), c2),
# (f(Piecewise(A), Piecewise(B)), True))
# Certain objects end up rewriting themselves as thus, so
# we do that grouping before the more generic folding.
# The following applies this idea when f = Add or f = Mul
# (and the expression is commutative).
if expr.is_Add or expr.is_Mul and expr.is_commutative:
p, args = sift(expr.args, lambda x: x.is_Piecewise, binary=True)
pc = sift(p, lambda x: tuple([c for e,c in x.args]))
for c in list(ordered(pc)):
if len(pc[c]) > 1:
pargs = [list(i.args) for i in pc[c]]
# the first one is the same; there may be more
com = common_prefix(*[
[i.cond for i in j] for j in pargs])
n = len(com)
collected = []
for i in range(n):
collected.append((
expr.func(*[ai[i].expr for ai in pargs]),
com[i]))
remains = []
for a in pargs:
if n == len(a): # no more args
continue
if a[n].cond == True: # no longer Piecewise
remains.append(a[n].expr)
else: # restore the remaining Piecewise
remains.append(
Piecewise(*a[n:], evaluate=False))
if remains:
collected.append((expr.func(*remains), True))
args.append(Piecewise(*collected, evaluate=False))
continue
args.extend(pc[c])
else:
args = expr.args
# fold
folded = list(map(piecewise_fold, args))
for ec in cartes(*[
(i.args if isinstance(i, Piecewise) else
[(i, true)]) for i in folded]):
e, c = zip(*ec)
new_args.append((expr.func(*e), And(*c)))
return Piecewise(*new_args)
def _clip(A, B, k):
"""Return interval B as intervals that are covered by A (keyed
to k) and all other intervals of B not covered by A keyed to -1.
The reference point of each interval is the rhs; if the lhs is
greater than the rhs then an interval of zero width interval will
result, e.g. (4, 1) is treated like (1, 1).
Examples
========
>>> from sympy.functions.elementary.piecewise import _clip
>>> from sympy import Tuple
>>> A = Tuple(1, 3)
>>> B = Tuple(2, 4)
>>> _clip(A, B, 0)
[(2, 3, 0), (3, 4, -1)]
Interpretation: interval portion (2, 3) of interval (2, 4) is
covered by interval (1, 3) and is keyed to 0 as requested;
interval (3, 4) was not covered by (1, 3) and is keyed to -1.
"""
a, b = B
c, d = A
c, d = Min(Max(c, a), b), Min(Max(d, a), b)
a, b = Min(a, b), b
p = []
if a != c:
p.append((a, c, -1))
else:
pass
if c != d:
p.append((c, d, k))
else:
pass
if b != d:
if d == c and p and p[-1][-1] == -1:
p[-1] = p[-1][0], b, -1
else:
p.append((d, b, -1))
else:
pass
return p
def piecewise_simplify_arguments(expr, **kwargs):
from sympy import simplify
args = []
for e, c in expr.args:
if isinstance(e, Basic):
doit = kwargs.pop('doit', None)
# Skip doit to avoid growth at every call for some integrals
# and sums, see sympy/sympy#17165
newe = simplify(e, doit=False, **kwargs)
if newe != expr:
e = newe
if isinstance(c, Basic):
c = simplify(c, doit=doit, **kwargs)
args.append((e, c))
return Piecewise(*args)
def piecewise_simplify(expr, **kwargs):
expr = piecewise_simplify_arguments(expr, **kwargs)
if not isinstance(expr, Piecewise):
return expr
args = list(expr.args)
_blessed = lambda e: getattr(e.lhs, '_diff_wrt', False) and (
getattr(e.rhs, '_diff_wrt', None) or
isinstance(e.rhs, (Rational, NumberSymbol)))
for i, (expr, cond) in enumerate(args):
# try to simplify conditions and the expression for
# equalities that are part of the condition, e.g.
# Piecewise((n, And(Eq(n,0), Eq(n + m, 0))), (1, True))
# -> Piecewise((0, And(Eq(n, 0), Eq(m, 0))), (1, True))
if isinstance(cond, And):
eqs, other = sift(cond.args,
lambda i: isinstance(i, Equality), binary=True)
elif isinstance(cond, Equality):
eqs, other = [cond], []
else:
eqs = other = []
if eqs:
eqs = list(ordered(eqs))
for j, e in enumerate(eqs):
# these blessed lhs objects behave like Symbols
# and the rhs are simple replacements for the "symbols"
if _blessed(e):
expr = expr.subs(*e.args)
eqs[j + 1:] = [ei.subs(*e.args) for ei in eqs[j + 1:]]
other = [ei.subs(*e.args) for ei in other]
cond = And(*(eqs + other))
args[i] = args[i].func(expr, cond)
# See if expressions valid for an Equal expression happens to evaluate
# to the same function as in the next piecewise segment, see:
# https://github.com/sympy/sympy/issues/8458
prevexpr = None
for i, (expr, cond) in reversed(list(enumerate(args))):
if prevexpr is not None:
if isinstance(cond, And):
eqs, other = sift(cond.args,
lambda i: isinstance(i, Equality), binary=True)
elif isinstance(cond, Equality):
eqs, other = [cond], []
else:
eqs = other = []
_prevexpr = prevexpr
_expr = expr
if eqs and not other:
eqs = list(ordered(eqs))
for e in eqs:
# these blessed lhs objects behave like Symbols
# and the rhs are simple replacements for the "symbols"
if _blessed(e):
_prevexpr = _prevexpr.subs(*e.args)
_expr = _expr.subs(*e.args)
# Did it evaluate to the same?
if _prevexpr == _expr:
# Set the expression for the Not equal section to the same
# as the next. These will be merged when creating the new
# Piecewise
args[i] = args[i].func(args[i+1][0], cond)
else:
# Update the expression that we compare against
prevexpr = expr
else:
prevexpr = expr
return Piecewise(*args)
|
c955d1053444c6c9876a227ee94ff644c948c3f2c7d2ae709d1af73fbb19d88b | from sympy.core import Add, S
from sympy.core.evalf import get_integer_part, PrecisionExhausted
from sympy.core.function import Function
from sympy.core.logic import fuzzy_or
from sympy.core.numbers import Integer
from sympy.core.relational import Gt, Lt, Ge, Le, Relational
from sympy.core.symbol import Symbol
from sympy.core.sympify import _sympify
###############################################################################
######################### FLOOR and CEILING FUNCTIONS #########################
###############################################################################
class RoundFunction(Function):
"""The base class for rounding functions."""
@classmethod
def eval(cls, arg):
from sympy import im
v = cls._eval_number(arg)
if v is not None:
return v
if arg.is_integer or arg.is_finite is False:
return arg
if arg.is_imaginary or (S.ImaginaryUnit*arg).is_real:
i = im(arg)
if not i.has(S.ImaginaryUnit):
return cls(i)*S.ImaginaryUnit
return cls(arg, evaluate=False)
# Integral, numerical, symbolic part
ipart = npart = spart = S.Zero
# Extract integral (or complex integral) terms
terms = Add.make_args(arg)
for t in terms:
if t.is_integer or (t.is_imaginary and im(t).is_integer):
ipart += t
elif t.has(Symbol):
spart += t
else:
npart += t
if not (npart or spart):
return ipart
# Evaluate npart numerically if independent of spart
if npart and (
not spart or
npart.is_real and (spart.is_imaginary or (S.ImaginaryUnit*spart).is_real) or
npart.is_imaginary and spart.is_real):
try:
r, i = get_integer_part(
npart, cls._dir, {}, return_ints=True)
ipart += Integer(r) + Integer(i)*S.ImaginaryUnit
npart = S.Zero
except (PrecisionExhausted, NotImplementedError):
pass
spart += npart
if not spart:
return ipart
elif spart.is_imaginary or (S.ImaginaryUnit*spart).is_real:
return ipart + cls(im(spart), evaluate=False)*S.ImaginaryUnit
elif isinstance(spart, (floor, ceiling)):
return ipart + spart
else:
return ipart + cls(spart, evaluate=False)
def _eval_is_finite(self):
return self.args[0].is_finite
def _eval_is_real(self):
return self.args[0].is_real
def _eval_is_integer(self):
return self.args[0].is_real
class floor(RoundFunction):
"""
Floor is a univariate function which returns the largest integer
value not greater than its argument. This implementation
generalizes floor to complex numbers by taking the floor of the
real and imaginary parts separately.
Examples
========
>>> from sympy import floor, E, I, S, Float, Rational
>>> floor(17)
17
>>> floor(Rational(23, 10))
2
>>> floor(2*E)
5
>>> floor(-Float(0.567))
-1
>>> floor(-I/2)
-I
>>> floor(S(5)/2 + 5*I/2)
2 + 2*I
See Also
========
sympy.functions.elementary.integers.ceiling
References
==========
.. [1] "Concrete mathematics" by Graham, pp. 87
.. [2] http://mathworld.wolfram.com/FloorFunction.html
"""
_dir = -1
@classmethod
def _eval_number(cls, arg):
if arg.is_Number:
return arg.floor()
elif any(isinstance(i, j)
for i in (arg, -arg) for j in (floor, ceiling)):
return arg
if arg.is_NumberSymbol:
return arg.approximation_interval(Integer)[0]
def _eval_nseries(self, x, n, logx):
r = self.subs(x, 0)
args = self.args[0]
args0 = args.subs(x, 0)
if args0 == r:
direction = (args - args0).leadterm(x)[0]
if direction.is_positive:
return r
else:
return r - 1
else:
return r
def _eval_is_negative(self):
return self.args[0].is_negative
def _eval_is_nonnegative(self):
return self.args[0].is_nonnegative
def _eval_rewrite_as_ceiling(self, arg, **kwargs):
return -ceiling(-arg)
def _eval_rewrite_as_frac(self, arg, **kwargs):
return arg - frac(arg)
def _eval_Eq(self, other):
if isinstance(self, floor):
if (self.rewrite(ceiling) == other) or \
(self.rewrite(frac) == other):
return S.true
def __le__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] < other + 1
if other.is_number and other.is_real:
return self.args[0] < ceiling(other)
if self.args[0] == other and other.is_real:
return S.true
if other is S.Infinity and self.is_finite:
return S.true
return Le(self, other, evaluate=False)
def __ge__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] >= other
if other.is_number and other.is_real:
return self.args[0] >= ceiling(other)
if self.args[0] == other and other.is_real:
return S.false
if other is S.NegativeInfinity and self.is_finite:
return S.true
return Ge(self, other, evaluate=False)
def __gt__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] >= other + 1
if other.is_number and other.is_real:
return self.args[0] >= ceiling(other)
if self.args[0] == other and other.is_real:
return S.false
if other is S.NegativeInfinity and self.is_finite:
return S.true
return Gt(self, other, evaluate=False)
def __lt__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] < other
if other.is_number and other.is_real:
return self.args[0] < ceiling(other)
if self.args[0] == other and other.is_real:
return S.false
if other is S.Infinity and self.is_finite:
return S.true
return Lt(self, other, evaluate=False)
class ceiling(RoundFunction):
"""
Ceiling is a univariate function which returns the smallest integer
value not less than its argument. This implementation
generalizes ceiling to complex numbers by taking the ceiling of the
real and imaginary parts separately.
Examples
========
>>> from sympy import ceiling, E, I, S, Float, Rational
>>> ceiling(17)
17
>>> ceiling(Rational(23, 10))
3
>>> ceiling(2*E)
6
>>> ceiling(-Float(0.567))
0
>>> ceiling(I/2)
I
>>> ceiling(S(5)/2 + 5*I/2)
3 + 3*I
See Also
========
sympy.functions.elementary.integers.floor
References
==========
.. [1] "Concrete mathematics" by Graham, pp. 87
.. [2] http://mathworld.wolfram.com/CeilingFunction.html
"""
_dir = 1
@classmethod
def _eval_number(cls, arg):
if arg.is_Number:
return arg.ceiling()
elif any(isinstance(i, j)
for i in (arg, -arg) for j in (floor, ceiling)):
return arg
if arg.is_NumberSymbol:
return arg.approximation_interval(Integer)[1]
def _eval_nseries(self, x, n, logx):
r = self.subs(x, 0)
args = self.args[0]
args0 = args.subs(x, 0)
if args0 == r:
direction = (args - args0).leadterm(x)[0]
if direction.is_positive:
return r + 1
else:
return r
else:
return r
def _eval_rewrite_as_floor(self, arg, **kwargs):
return -floor(-arg)
def _eval_rewrite_as_frac(self, arg, **kwargs):
return arg + frac(-arg)
def _eval_is_positive(self):
return self.args[0].is_positive
def _eval_is_nonpositive(self):
return self.args[0].is_nonpositive
def _eval_Eq(self, other):
if isinstance(self, ceiling):
if (self.rewrite(floor) == other) or \
(self.rewrite(frac) == other):
return S.true
def __lt__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] <= other - 1
if other.is_number and other.is_real:
return self.args[0] <= floor(other)
if self.args[0] == other and other.is_real:
return S.false
if other is S.Infinity and self.is_finite:
return S.true
return Lt(self, other, evaluate=False)
def __gt__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] > other
if other.is_number and other.is_real:
return self.args[0] > floor(other)
if self.args[0] == other and other.is_real:
return S.false
if other is S.NegativeInfinity and self.is_finite:
return S.true
return Gt(self, other, evaluate=False)
def __ge__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] > other - 1
if other.is_number and other.is_real:
return self.args[0] > floor(other)
if self.args[0] == other and other.is_real:
return S.true
if other is S.NegativeInfinity and self.is_finite:
return S.true
return Ge(self, other, evaluate=False)
def __le__(self, other):
other = S(other)
if self.args[0].is_real:
if other.is_integer:
return self.args[0] <= other
if other.is_number and other.is_real:
return self.args[0] <= floor(other)
if self.args[0] == other and other.is_real:
return S.false
if other is S.Infinity and self.is_finite:
return S.true
return Le(self, other, evaluate=False)
class frac(Function):
r"""Represents the fractional part of x
For real numbers it is defined [1]_ as
.. math::
x - \left\lfloor{x}\right\rfloor
Examples
========
>>> from sympy import Symbol, frac, Rational, floor, I
>>> frac(Rational(4, 3))
1/3
>>> frac(-Rational(4, 3))
2/3
returns zero for integer arguments
>>> n = Symbol('n', integer=True)
>>> frac(n)
0
rewrite as floor
>>> x = Symbol('x')
>>> frac(x).rewrite(floor)
x - floor(x)
for complex arguments
>>> r = Symbol('r', real=True)
>>> t = Symbol('t', real=True)
>>> frac(t + I*r)
I*frac(r) + frac(t)
See Also
========
sympy.functions.elementary.integers.floor
sympy.functions.elementary.integers.ceiling
References
===========
.. [1] https://en.wikipedia.org/wiki/Fractional_part
.. [2] http://mathworld.wolfram.com/FractionalPart.html
"""
@classmethod
def eval(cls, arg):
from sympy import AccumBounds, im
def _eval(arg):
if arg is S.Infinity or arg is S.NegativeInfinity:
return AccumBounds(0, 1)
if arg.is_integer:
return S.Zero
if arg.is_number:
if arg is S.NaN:
return S.NaN
elif arg is S.ComplexInfinity:
return S.NaN
else:
return arg - floor(arg)
return cls(arg, evaluate=False)
terms = Add.make_args(arg)
real, imag = S.Zero, S.Zero
for t in terms:
# Two checks are needed for complex arguments
# see issue-7649 for details
if t.is_imaginary or (S.ImaginaryUnit*t).is_real:
i = im(t)
if not i.has(S.ImaginaryUnit):
imag += i
else:
real += t
else:
real += t
real = _eval(real)
imag = _eval(imag)
return real + S.ImaginaryUnit*imag
def _eval_rewrite_as_floor(self, arg, **kwargs):
return arg - floor(arg)
def _eval_rewrite_as_ceiling(self, arg, **kwargs):
return arg + ceiling(-arg)
def _eval_Eq(self, other):
if isinstance(self, frac):
if (self.rewrite(floor) == other) or \
(self.rewrite(ceiling) == other):
return S.true
# Check if other < 0
if other.is_extended_negative:
return S.false
# Check if other >= 1
res = self._value_one_or_more(other)
if res is not None:
return S.false
def _eval_is_finite(self):
return True
def _eval_is_real(self):
return self.args[0].is_extended_real
def _eval_is_imaginary(self):
return self.args[0].is_imaginary
def _eval_is_integer(self):
return self.args[0].is_integer
def _eval_is_zero(self):
return fuzzy_or([self.args[0].is_zero, self.args[0].is_integer])
def _eval_is_negative(self):
return False
def __ge__(self, other):
if self.is_extended_real:
other = _sympify(other)
# Check if other <= 0
if other.is_extended_nonpositive:
return S.true
# Check if other >= 1
res = self._value_one_or_more(other)
if res is not None:
return not(res)
return Ge(self, other, evaluate=False)
def __gt__(self, other):
if self.is_extended_real:
other = _sympify(other)
# Check if other < 0
res = self._value_one_or_more(other)
if res is not None:
return not(res)
# Check if other >= 1
if other.is_extended_negative:
return S.true
return Gt(self, other, evaluate=False)
def __le__(self, other):
if self.is_extended_real:
other = _sympify(other)
# Check if other < 0
if other.is_extended_negative:
return S.false
# Check if other >= 1
res = self._value_one_or_more(other)
if res is not None:
return res
return Le(self, other, evaluate=False)
def __lt__(self, other):
if self.is_extended_real:
other = _sympify(other)
# Check if other <= 0
if other.is_extended_nonpositive:
return S.false
# Check if other >= 1
res = self._value_one_or_more(other)
if res is not None:
return res
return Lt(self, other, evaluate=False)
def _value_one_or_more(self, other):
if other.is_extended_real:
if other.is_number:
res = other >= 1
if res and not isinstance(res, Relational):
return S.true
if other.is_integer and other.is_positive:
return S.true
|
d74586235167fcbaad2e731dc21e42c30946e070e4a556a6b3d7fb89eb897593 | from sympy.core import sympify
from sympy.core.add import Add
from sympy.core.cache import cacheit
from sympy.core.function import (Function, ArgumentIndexError, _coeff_isneg,
expand_mul)
from sympy.core.logic import fuzzy_and, fuzzy_not, fuzzy_or
from sympy.core.mul import Mul
from sympy.core.numbers import Integer, Rational
from sympy.core.power import Pow
from sympy.core.singleton import S
from sympy.core.symbol import Wild, Dummy
from sympy.functions.combinatorial.factorials import factorial
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.ntheory import multiplicity, perfect_power
# NOTE IMPORTANT
# The series expansion code in this file is an important part of the gruntz
# algorithm for determining limits. _eval_nseries has to return a generalized
# power series with coefficients in C(log(x), log).
# In more detail, the result of _eval_nseries(self, x, n) must be
# c_0*x**e_0 + ... (finitely many terms)
# where e_i are numbers (not necessarily integers) and c_i involve only
# numbers, the function log, and log(x). [This also means it must not contain
# log(x(1+p)), this *has* to be expanded to log(x)+log(1+p) if x.is_positive and
# p.is_positive.]
class ExpBase(Function):
unbranched = True
_singularities = (S.ComplexInfinity,)
def inverse(self, argindex=1):
"""
Returns the inverse function of ``exp(x)``.
"""
return log
def as_numer_denom(self):
"""
Returns this with a positive exponent as a 2-tuple (a fraction).
Examples
========
>>> from sympy.functions import exp
>>> from sympy.abc import x
>>> exp(-x).as_numer_denom()
(1, exp(x))
>>> exp(x).as_numer_denom()
(exp(x), 1)
"""
# this should be the same as Pow.as_numer_denom wrt
# exponent handling
exp = self.exp
neg_exp = exp.is_negative
if not neg_exp and not (-exp).is_negative:
neg_exp = _coeff_isneg(exp)
if neg_exp:
return S.One, self.func(-exp)
return self, S.One
@property
def exp(self):
"""
Returns the exponent of the function.
"""
return self.args[0]
def as_base_exp(self):
"""
Returns the 2-tuple (base, exponent).
"""
return self.func(1), Mul(*self.args)
def _eval_adjoint(self):
return self.func(self.args[0].adjoint())
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def _eval_transpose(self):
return self.func(self.args[0].transpose())
def _eval_is_finite(self):
arg = self.args[0]
if arg.is_infinite:
if arg.is_extended_negative:
return True
if arg.is_extended_positive:
return False
if arg.is_finite:
return True
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
z = s.exp.is_zero
if z:
return True
elif s.exp.is_rational and fuzzy_not(z):
return False
else:
return s.is_rational
def _eval_is_zero(self):
return (self.args[0] is S.NegativeInfinity)
def _eval_power(self, other):
"""exp(arg)**e -> exp(arg*e) if assumptions allow it.
"""
b, e = self.as_base_exp()
return Pow._eval_power(Pow(b, e, evaluate=False), other)
def _eval_expand_power_exp(self, **hints):
from sympy import Sum, Product
arg = self.args[0]
if arg.is_Add and arg.is_commutative:
return Mul.fromiter(self.func(x) for x in arg.args)
elif isinstance(arg, Sum) and arg.is_commutative:
return Product(self.func(arg.function), *arg.limits)
return self.func(arg)
class exp_polar(ExpBase):
r"""
Represent a 'polar number' (see g-function Sphinx documentation).
``exp_polar`` represents the function
`Exp: \mathbb{C} \rightarrow \mathcal{S}`, sending the complex number
`z = a + bi` to the polar number `r = exp(a), \theta = b`. It is one of
the main functions to construct polar numbers.
>>> from sympy import exp_polar, pi, I, exp
The main difference is that polar numbers don't "wrap around" at `2 \pi`:
>>> exp(2*pi*I)
1
>>> exp_polar(2*pi*I)
exp_polar(2*I*pi)
apart from that they behave mostly like classical complex numbers:
>>> exp_polar(2)*exp_polar(3)
exp_polar(5)
See Also
========
sympy.simplify.powsimp.powsimp
polar_lift
periodic_argument
principal_branch
"""
is_polar = True
is_comparable = False # cannot be evalf'd
def _eval_Abs(self): # Abs is never a polar number
from sympy.functions.elementary.complexes import re
return exp(re(self.args[0]))
def _eval_evalf(self, prec):
""" Careful! any evalf of polar numbers is flaky """
from sympy import im, pi, re
i = im(self.args[0])
try:
bad = (i <= -pi or i > pi)
except TypeError:
bad = True
if bad:
return self # cannot evalf for this argument
res = exp(self.args[0])._eval_evalf(prec)
if i > 0 and im(res) < 0:
# i ~ pi, but exp(I*i) evaluated to argument slightly bigger than pi
return re(res)
return res
def _eval_power(self, other):
return self.func(self.args[0]*other)
def _eval_is_extended_real(self):
if self.args[0].is_extended_real:
return True
def as_base_exp(self):
# XXX exp_polar(0) is special!
if self.args[0] == 0:
return self, S.One
return ExpBase.as_base_exp(self)
class exp(ExpBase):
"""
The exponential function, :math:`e^x`.
See Also
========
log
"""
def fdiff(self, argindex=1):
"""
Returns the first derivative of this function.
"""
if argindex == 1:
return self
else:
raise ArgumentIndexError(self, argindex)
def _eval_refine(self, assumptions):
from sympy.assumptions import ask, Q
arg = self.args[0]
if arg.is_Mul:
Ioo = S.ImaginaryUnit*S.Infinity
if arg in [Ioo, -Ioo]:
return S.NaN
coeff = arg.as_coefficient(S.Pi*S.ImaginaryUnit)
if coeff:
if ask(Q.integer(2*coeff)):
if ask(Q.even(coeff)):
return S.One
elif ask(Q.odd(coeff)):
return S.NegativeOne
elif ask(Q.even(coeff + S.Half)):
return -S.ImaginaryUnit
elif ask(Q.odd(coeff + S.Half)):
return S.ImaginaryUnit
@classmethod
def eval(cls, arg):
from sympy.calculus import AccumBounds
from sympy.sets.setexpr import SetExpr
from sympy.matrices.matrices import MatrixBase
from sympy import logcombine
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg.is_zero:
return S.One
elif arg is S.One:
return S.Exp1
elif arg is S.Infinity:
return S.Infinity
elif arg is S.NegativeInfinity:
return S.Zero
elif arg is S.ComplexInfinity:
return S.NaN
elif isinstance(arg, log):
return arg.args[0]
elif isinstance(arg, AccumBounds):
return AccumBounds(exp(arg.min), exp(arg.max))
elif isinstance(arg, SetExpr):
return arg._eval_func(cls)
elif arg.is_Mul:
coeff = arg.as_coefficient(S.Pi*S.ImaginaryUnit)
if coeff:
if (2*coeff).is_integer:
if coeff.is_even:
return S.One
elif coeff.is_odd:
return S.NegativeOne
elif (coeff + S.Half).is_even:
return -S.ImaginaryUnit
elif (coeff + S.Half).is_odd:
return S.ImaginaryUnit
elif coeff.is_Rational:
ncoeff = coeff % 2 # restrict to [0, 2pi)
if ncoeff > 1: # restrict to (-pi, pi]
ncoeff -= 2
if ncoeff != coeff:
return cls(ncoeff*S.Pi*S.ImaginaryUnit)
# Warning: code in risch.py will be very sensitive to changes
# in this (see DifferentialExtension).
# look for a single log factor
coeff, terms = arg.as_coeff_Mul()
# but it can't be multiplied by oo
if coeff in [S.NegativeInfinity, S.Infinity]:
return None
coeffs, log_term = [coeff], None
for term in Mul.make_args(terms):
term_ = logcombine(term)
if isinstance(term_, log):
if log_term is None:
log_term = term_.args[0]
else:
return None
elif term.is_comparable:
coeffs.append(term)
else:
return None
return log_term**Mul(*coeffs) if log_term else None
elif arg.is_Add:
out = []
add = []
argchanged = False
for a in arg.args:
if a is S.One:
add.append(a)
continue
newa = cls(a)
if isinstance(newa, cls):
if newa.args[0] != a:
add.append(newa.args[0])
argchanged = True
else:
add.append(a)
else:
out.append(newa)
if out or argchanged:
return Mul(*out)*cls(Add(*add), evaluate=False)
elif isinstance(arg, MatrixBase):
return arg.exp()
if arg.is_zero:
return S.One
@property
def base(self):
"""
Returns the base of the exponential function.
"""
return S.Exp1
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
"""
Calculates the next term in the Taylor series expansion.
"""
if n < 0:
return S.Zero
if n == 0:
return S.One
x = sympify(x)
if previous_terms:
p = previous_terms[-1]
if p is not None:
return p * x / n
return x**n/factorial(n)
def as_real_imag(self, deep=True, **hints):
"""
Returns this function as a 2-tuple representing a complex number.
Examples
========
>>> from sympy import I
>>> from sympy.abc import x
>>> from sympy.functions import exp
>>> exp(x).as_real_imag()
(exp(re(x))*cos(im(x)), exp(re(x))*sin(im(x)))
>>> exp(1).as_real_imag()
(E, 0)
>>> exp(I).as_real_imag()
(cos(1), sin(1))
>>> exp(1+I).as_real_imag()
(E*cos(1), E*sin(1))
See Also
========
sympy.functions.elementary.complexes.re
sympy.functions.elementary.complexes.im
"""
import sympy
re, im = self.args[0].as_real_imag()
if deep:
re = re.expand(deep, **hints)
im = im.expand(deep, **hints)
cos, sin = sympy.cos(im), sympy.sin(im)
return (exp(re)*cos, exp(re)*sin)
def _eval_subs(self, old, new):
# keep processing of power-like args centralized in Pow
if old.is_Pow: # handle (exp(3*log(x))).subs(x**2, z) -> z**(3/2)
old = exp(old.exp*log(old.base))
elif old is S.Exp1 and new.is_Function:
old = exp
if isinstance(old, exp) or old is S.Exp1:
f = lambda a: Pow(*a.as_base_exp(), evaluate=False) if (
a.is_Pow or isinstance(a, exp)) else a
return Pow._eval_subs(f(self), f(old), new)
if old is exp and not new.is_Function:
return new**self.exp._subs(old, new)
return Function._eval_subs(self, old, new)
def _eval_is_extended_real(self):
if self.args[0].is_extended_real:
return True
elif self.args[0].is_imaginary:
arg2 = -S(2) * S.ImaginaryUnit * self.args[0] / S.Pi
return arg2.is_even
def _eval_is_complex(self):
def complex_extended_negative(arg):
yield arg.is_complex
yield arg.is_extended_negative
return fuzzy_or(complex_extended_negative(self.args[0]))
def _eval_is_algebraic(self):
s = self.func(*self.args)
if s.func == self.func:
if fuzzy_not(self.exp.is_zero):
if self.exp.is_algebraic:
return False
elif (self.exp/S.Pi).is_rational:
return False
else:
return s.is_algebraic
def _eval_is_extended_positive(self):
if self.args[0].is_extended_real:
return not self.args[0] is S.NegativeInfinity
elif self.args[0].is_imaginary:
arg2 = -S.ImaginaryUnit * self.args[0] / S.Pi
return arg2.is_even
def _eval_nseries(self, x, n, logx):
# NOTE Please see the comment at the beginning of this file, labelled
# IMPORTANT.
from sympy import ceiling, limit, oo, Order, powsimp, Wild, expand_complex
arg = self.args[0]
arg_series = arg._eval_nseries(x, n=n, logx=logx)
if arg_series.is_Order:
return 1 + arg_series
arg0 = limit(arg_series.removeO(), x, 0)
if arg0 in [-oo, oo]:
return self
t = Dummy("t")
nterms = n
try:
cf = Order(arg.as_leading_term(x), x).getn()
except NotImplementedError:
cf = 0
if cf and cf > 0:
nterms = ceiling(n/cf)
exp_series = exp(t)._taylor(t, nterms)
r = exp(arg0)*exp_series.subs(t, arg_series - arg0)
if cf and cf > 1:
r += Order((arg_series - arg0)**n, x)/x**((cf-1)*n)
else:
r += Order((arg_series - arg0)**n, x)
r = r.expand()
r = powsimp(r, deep=True, combine='exp')
# powsimp may introduce unexpanded (-1)**Rational; see PR #17201
simplerat = lambda x: x.is_Rational and x.q in [3, 4, 6]
w = Wild('w', properties=[simplerat])
r = r.replace((-1)**w, expand_complex((-1)**w))
return r
def _taylor(self, x, n):
l = []
g = None
for i in range(n):
g = self.taylor_term(i, self.args[0], g)
g = g.nseries(x, n=n)
l.append(g.removeO())
return Add(*l)
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0]
if arg.is_Add:
return Mul(*[exp(f).as_leading_term(x) for f in arg.args])
arg_1 = arg.as_leading_term(x)
if Order(x, x).contains(arg_1):
return S.One
if Order(1, x).contains(arg_1):
return exp(arg_1)
####################################################
# The correct result here should be 'None'. #
# Indeed arg in not bounded as x tends to 0. #
# Consequently the series expansion does not admit #
# the leading term. #
# For compatibility reasons, the return value here #
# is the original function, i.e. exp(arg), #
# instead of None. #
####################################################
return exp(arg)
def _eval_rewrite_as_sin(self, arg, **kwargs):
from sympy import sin
I = S.ImaginaryUnit
return sin(I*arg + S.Pi/2) - I*sin(I*arg)
def _eval_rewrite_as_cos(self, arg, **kwargs):
from sympy import cos
I = S.ImaginaryUnit
return cos(I*arg) + I*cos(I*arg + S.Pi/2)
def _eval_rewrite_as_tanh(self, arg, **kwargs):
from sympy import tanh
return (1 + tanh(arg/2))/(1 - tanh(arg/2))
def _eval_rewrite_as_sqrt(self, arg, **kwargs):
from sympy.functions.elementary.trigonometric import sin, cos
if arg.is_Mul:
coeff = arg.coeff(S.Pi*S.ImaginaryUnit)
if coeff and coeff.is_number:
cosine, sine = cos(S.Pi*coeff), sin(S.Pi*coeff)
if not isinstance(cosine, cos) and not isinstance (sine, sin):
return cosine + S.ImaginaryUnit*sine
def _eval_rewrite_as_Pow(self, arg, **kwargs):
if arg.is_Mul:
logs = [a for a in arg.args if isinstance(a, log) and len(a.args) == 1]
if logs:
return Pow(logs[0].args[0], arg.coeff(logs[0]))
def match_real_imag(expr):
"""
Try to match expr with a + b*I for real a and b.
``match_real_imag`` returns a tuple containing the real and imaginary
parts of expr or (None, None) if direct matching is not possible. Contrary
to ``re()``, ``im()``, ``as_real_imag()``, this helper won't force things
by returning expressions themselves containing ``re()`` or ``im()`` and it
doesn't expand its argument either.
"""
r_, i_ = expr.as_independent(S.ImaginaryUnit, as_Add=True)
if i_ == 0 and r_.is_real:
return (r_, i_)
i_ = i_.as_coefficient(S.ImaginaryUnit)
if i_ and i_.is_real and r_.is_real:
return (r_, i_)
else:
return (None, None) # simpler to check for than None
class log(Function):
r"""
The natural logarithm function `\ln(x)` or `\log(x)`.
Logarithms are taken with the natural base, `e`. To get
a logarithm of a different base ``b``, use ``log(x, b)``,
which is essentially short-hand for ``log(x)/log(b)``.
``log`` represents the principal branch of the natural
logarithm. As such it has a branch cut along the negative
real axis and returns values having a complex argument in
`(-\pi, \pi]`.
Examples
========
>>> from sympy import log, sqrt, S, I
>>> log(8, 2)
3
>>> log(S(8)/3, 2)
-log(3)/log(2) + 3
>>> log(-1 + I*sqrt(3))
log(2) + 2*I*pi/3
See Also
========
exp
"""
_singularities = (S.Zero, S.ComplexInfinity)
def fdiff(self, argindex=1):
"""
Returns the first derivative of the function.
"""
if argindex == 1:
return 1/self.args[0]
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
r"""
Returns `e^x`, the inverse function of `\log(x)`.
"""
return exp
@classmethod
def eval(cls, arg, base=None):
from sympy import unpolarify
from sympy.calculus import AccumBounds
from sympy.sets.setexpr import SetExpr
from sympy.functions.elementary.complexes import Abs
arg = sympify(arg)
if base is not None:
base = sympify(base)
if base == 1:
if arg == 1:
return S.NaN
else:
return S.ComplexInfinity
try:
# handle extraction of powers of the base now
# or else expand_log in Mul would have to handle this
n = multiplicity(base, arg)
if n:
return n + log(arg / base**n) / log(base)
else:
return log(arg)/log(base)
except ValueError:
pass
if base is not S.Exp1:
return cls(arg)/cls(base)
else:
return cls(arg)
if arg.is_Number:
if arg.is_zero:
return S.ComplexInfinity
elif arg is S.One:
return S.Zero
elif arg is S.Infinity:
return S.Infinity
elif arg is S.NegativeInfinity:
return S.Infinity
elif arg is S.NaN:
return S.NaN
elif arg.is_Rational and arg.p == 1:
return -cls(arg.q)
I = S.ImaginaryUnit
if isinstance(arg, exp) and arg.args[0].is_extended_real:
return arg.args[0]
elif isinstance(arg, exp) and arg.args[0].is_number:
r_, i_ = match_real_imag(arg.args[0])
if i_ and i_.is_comparable:
i_ %= 2*S.Pi
if i_ > S.Pi:
i_ -= 2*S.Pi
return r_ + expand_mul(i_ * I, deep=False)
elif isinstance(arg, exp_polar):
return unpolarify(arg.exp)
elif isinstance(arg, AccumBounds):
if arg.min.is_positive:
return AccumBounds(log(arg.min), log(arg.max))
else:
return
elif isinstance(arg, SetExpr):
return arg._eval_func(cls)
if arg.is_number:
if arg.is_negative:
return S.Pi * I + cls(-arg)
elif arg is S.ComplexInfinity:
return S.ComplexInfinity
elif arg is S.Exp1:
return S.One
if arg.is_zero:
return S.ComplexInfinity
# don't autoexpand Pow or Mul (see the issue 3351):
if not arg.is_Add:
coeff = arg.as_coefficient(I)
if coeff is not None:
if coeff is S.Infinity:
return S.Infinity
elif coeff is S.NegativeInfinity:
return S.Infinity
elif coeff.is_Rational:
if coeff.is_nonnegative:
return S.Pi * I * S.Half + cls(coeff)
else:
return -S.Pi * I * S.Half + cls(-coeff)
if arg.is_number and arg.is_algebraic:
# Match arg = coeff*(r_ + i_*I) with coeff>0, r_ and i_ real.
coeff, arg_ = arg.as_independent(I, as_Add=False)
if coeff.is_negative:
coeff *= -1
arg_ *= -1
arg_ = expand_mul(arg_, deep=False)
r_, i_ = arg_.as_independent(I, as_Add=True)
i_ = i_.as_coefficient(I)
if coeff.is_real and i_ and i_.is_real and r_.is_real:
if r_.is_zero:
if i_.is_positive:
return S.Pi * I * S.Half + cls(coeff * i_)
elif i_.is_negative:
return -S.Pi * I * S.Half + cls(coeff * -i_)
else:
from sympy.simplify import ratsimp
# Check for arguments involving rational multiples of pi
t = (i_/r_).cancel()
atan_table = {
# first quadrant only
sqrt(3): S.Pi/3,
1: S.Pi/4,
sqrt(5 - 2*sqrt(5)): S.Pi/5,
sqrt(2)*sqrt(5 - sqrt(5))/(1 + sqrt(5)): S.Pi/5,
sqrt(5 + 2*sqrt(5)): S.Pi*Rational(2, 5),
sqrt(2)*sqrt(sqrt(5) + 5)/(-1 + sqrt(5)): S.Pi*Rational(2, 5),
sqrt(3)/3: S.Pi/6,
sqrt(2) - 1: S.Pi/8,
sqrt(2 - sqrt(2))/sqrt(sqrt(2) + 2): S.Pi/8,
sqrt(2) + 1: S.Pi*Rational(3, 8),
sqrt(sqrt(2) + 2)/sqrt(2 - sqrt(2)): S.Pi*Rational(3, 8),
sqrt(1 - 2*sqrt(5)/5): S.Pi/10,
(-sqrt(2) + sqrt(10))/(2*sqrt(sqrt(5) + 5)): S.Pi/10,
sqrt(1 + 2*sqrt(5)/5): S.Pi*Rational(3, 10),
(sqrt(2) + sqrt(10))/(2*sqrt(5 - sqrt(5))): S.Pi*Rational(3, 10),
2 - sqrt(3): S.Pi/12,
(-1 + sqrt(3))/(1 + sqrt(3)): S.Pi/12,
2 + sqrt(3): S.Pi*Rational(5, 12),
(1 + sqrt(3))/(-1 + sqrt(3)): S.Pi*Rational(5, 12)
}
if t in atan_table:
modulus = ratsimp(coeff * Abs(arg_))
if r_.is_positive:
return cls(modulus) + I * atan_table[t]
else:
return cls(modulus) + I * (atan_table[t] - S.Pi)
elif -t in atan_table:
modulus = ratsimp(coeff * Abs(arg_))
if r_.is_positive:
return cls(modulus) + I * (-atan_table[-t])
else:
return cls(modulus) + I * (S.Pi - atan_table[-t])
def as_base_exp(self):
"""
Returns this function in the form (base, exponent).
"""
return self, S.One
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms): # of log(1+x)
r"""
Returns the next term in the Taylor series expansion of `\log(1+x)`.
"""
from sympy import powsimp
if n < 0:
return S.Zero
x = sympify(x)
if n == 0:
return x
if previous_terms:
p = previous_terms[-1]
if p is not None:
return powsimp((-n) * p * x / (n + 1), deep=True, combine='exp')
return (1 - 2*(n % 2)) * x**(n + 1)/(n + 1)
def _eval_expand_log(self, deep=True, **hints):
from sympy import unpolarify, expand_log, factorint
from sympy.concrete import Sum, Product
force = hints.get('force', False)
factor = hints.get('factor', False)
if (len(self.args) == 2):
return expand_log(self.func(*self.args), deep=deep, force=force)
arg = self.args[0]
if arg.is_Integer:
# remove perfect powers
p = perfect_power(arg)
logarg = None
coeff = 1
if p is not False:
arg, coeff = p
logarg = self.func(arg)
# expand as product of its prime factors if factor=True
if factor:
p = factorint(arg)
if arg not in p.keys():
logarg = sum(n*log(val) for val, n in p.items())
if logarg is not None:
return coeff*logarg
elif arg.is_Rational:
return log(arg.p) - log(arg.q)
elif arg.is_Mul:
expr = []
nonpos = []
for x in arg.args:
if force or x.is_positive or x.is_polar:
a = self.func(x)
if isinstance(a, log):
expr.append(self.func(x)._eval_expand_log(**hints))
else:
expr.append(a)
elif x.is_negative:
a = self.func(-x)
expr.append(a)
nonpos.append(S.NegativeOne)
else:
nonpos.append(x)
return Add(*expr) + log(Mul(*nonpos))
elif arg.is_Pow or isinstance(arg, exp):
if force or (arg.exp.is_extended_real and (arg.base.is_positive or ((arg.exp+1)
.is_positive and (arg.exp-1).is_nonpositive))) or arg.base.is_polar:
b = arg.base
e = arg.exp
a = self.func(b)
if isinstance(a, log):
return unpolarify(e) * a._eval_expand_log(**hints)
else:
return unpolarify(e) * a
elif isinstance(arg, Product):
if force or arg.function.is_positive:
return Sum(log(arg.function), *arg.limits)
return self.func(arg)
def _eval_simplify(self, **kwargs):
from sympy.simplify.simplify import expand_log, simplify, inversecombine
if len(self.args) == 2: # it's unevaluated
return simplify(self.func(*self.args), **kwargs)
expr = self.func(simplify(self.args[0], **kwargs))
if kwargs['inverse']:
expr = inversecombine(expr)
expr = expand_log(expr, deep=True)
return min([expr, self], key=kwargs['measure'])
def as_real_imag(self, deep=True, **hints):
"""
Returns this function as a complex coordinate.
Examples
========
>>> from sympy import I
>>> from sympy.abc import x
>>> from sympy.functions import log
>>> log(x).as_real_imag()
(log(Abs(x)), arg(x))
>>> log(I).as_real_imag()
(0, pi/2)
>>> log(1 + I).as_real_imag()
(log(sqrt(2)), pi/4)
>>> log(I*x).as_real_imag()
(log(Abs(x)), arg(I*x))
"""
from sympy import Abs, arg
sarg = self.args[0]
if deep:
sarg = self.args[0].expand(deep, **hints)
abs = Abs(sarg)
if abs == sarg:
return self, S.Zero
arg = arg(sarg)
if hints.get('log', False): # Expand the log
hints['complex'] = False
return (log(abs).expand(deep, **hints), arg)
else:
return log(abs), arg
def _eval_is_rational(self):
s = self.func(*self.args)
if s.func == self.func:
if (self.args[0] - 1).is_zero:
return True
if s.args[0].is_rational and fuzzy_not((self.args[0] - 1).is_zero):
return False
else:
return s.is_rational
def _eval_is_algebraic(self):
s = self.func(*self.args)
if s.func == self.func:
if (self.args[0] - 1).is_zero:
return True
elif fuzzy_not((self.args[0] - 1).is_zero):
if self.args[0].is_algebraic:
return False
else:
return s.is_algebraic
def _eval_is_extended_real(self):
return self.args[0].is_extended_positive
def _eval_is_complex(self):
z = self.args[0]
return fuzzy_and([z.is_complex, fuzzy_not(z.is_zero)])
def _eval_is_finite(self):
arg = self.args[0]
if arg.is_zero:
return False
return arg.is_finite
def _eval_is_extended_positive(self):
return (self.args[0] - 1).is_extended_positive
def _eval_is_zero(self):
return (self.args[0] - 1).is_zero
def _eval_is_extended_nonnegative(self):
return (self.args[0] - 1).is_extended_nonnegative
def _eval_nseries(self, x, n, logx):
# NOTE Please see the comment at the beginning of this file, labelled
# IMPORTANT.
from sympy import cancel, Order, logcombine
if not logx:
logx = log(x)
if self.args[0] == x:
return logx
arg = self.args[0]
k, l = Wild("k"), Wild("l")
r = arg.match(k*x**l)
if r is not None:
k, l = r[k], r[l]
if l != 0 and not l.has(x) and not k.has(x):
r = log(k) + l*logx # XXX true regardless of assumptions?
return r
# TODO new and probably slow
s = self.args[0].nseries(x, n=n, logx=logx)
while s.is_Order:
n += 1
s = self.args[0].nseries(x, n=n, logx=logx)
a, b = s.leadterm(x)
p = cancel(s/(a*x**b) - 1)
if p.has(exp):
p = logcombine(p)
g = None
l = []
for i in range(n + 2):
g = log.taylor_term(i, p, g)
g = g.nseries(x, n=n, logx=logx)
l.append(g)
return log(a) + b*logx + Add(*l) + Order(p**n, x)
def _eval_as_leading_term(self, x):
arg = self.args[0].as_leading_term(x)
if arg is S.One:
return (self.args[0] - 1).as_leading_term(x)
return self.func(arg)
class LambertW(Function):
r"""
The Lambert W function `W(z)` is defined as the inverse
function of `w \exp(w)` [1]_.
In other words, the value of `W(z)` is such that `z = W(z) \exp(W(z))`
for any complex number `z`. The Lambert W function is a multivalued
function with infinitely many branches `W_k(z)`, indexed by
`k \in \mathbb{Z}`. Each branch gives a different solution `w`
of the equation `z = w \exp(w)`.
The Lambert W function has two partially real branches: the
principal branch (`k = 0`) is real for real `z > -1/e`, and the
`k = -1` branch is real for `-1/e < z < 0`. All branches except
`k = 0` have a logarithmic singularity at `z = 0`.
Examples
========
>>> from sympy import LambertW
>>> LambertW(1.2)
0.635564016364870
>>> LambertW(1.2, -1).n()
-1.34747534407696 - 4.41624341514535*I
>>> LambertW(-1).is_real
False
References
==========
.. [1] https://en.wikipedia.org/wiki/Lambert_W_function
"""
@classmethod
def eval(cls, x, k=None):
if k == S.Zero:
return cls(x)
elif k is None:
k = S.Zero
if k.is_zero:
if x.is_zero:
return S.Zero
if x is S.Exp1:
return S.One
if x == -1/S.Exp1:
return S.NegativeOne
if x == -log(2)/2:
return -log(2)
if x == 2*log(2):
return log(2)
if x == -S.Pi/2:
return S.ImaginaryUnit*S.Pi/2
if x == exp(1 + S.Exp1):
return S.Exp1
if x is S.Infinity:
return S.Infinity
if x.is_zero:
return S.Zero
if fuzzy_not(k.is_zero):
if x.is_zero:
return S.NegativeInfinity
if k is S.NegativeOne:
if x == -S.Pi/2:
return -S.ImaginaryUnit*S.Pi/2
elif x == -1/S.Exp1:
return S.NegativeOne
elif x == -2*exp(-2):
return -Integer(2)
def fdiff(self, argindex=1):
"""
Return the first derivative of this function.
"""
x = self.args[0]
if len(self.args) == 1:
if argindex == 1:
return LambertW(x)/(x*(1 + LambertW(x)))
else:
k = self.args[1]
if argindex == 1:
return LambertW(x, k)/(x*(1 + LambertW(x, k)))
raise ArgumentIndexError(self, argindex)
def _eval_is_extended_real(self):
x = self.args[0]
if len(self.args) == 1:
k = S.Zero
else:
k = self.args[1]
if k.is_zero:
if (x + 1/S.Exp1).is_positive:
return True
elif (x + 1/S.Exp1).is_nonpositive:
return False
elif (k + 1).is_zero:
if x.is_negative and (x + 1/S.Exp1).is_positive:
return True
elif x.is_nonpositive or (x + 1/S.Exp1).is_nonnegative:
return False
elif fuzzy_not(k.is_zero) and fuzzy_not((k + 1).is_zero):
if x.is_extended_real:
return False
def _eval_is_finite(self):
return self.args[0].is_finite
def _eval_is_algebraic(self):
s = self.func(*self.args)
if s.func == self.func:
if fuzzy_not(self.args[0].is_zero) and self.args[0].is_algebraic:
return False
else:
return s.is_algebraic
def _eval_nseries(self, x, n, logx):
if len(self.args) == 1:
from sympy import Order, ceiling, expand_multinomial
arg = self.args[0].nseries(x, n=n, logx=logx)
lt = arg.compute_leading_term(x, logx=logx)
lte = 1
if lt.is_Pow:
lte = lt.exp
if ceiling(n/lte) >= 1:
s = Add(*[(-S.One)**(k - 1)*Integer(k)**(k - 2)/
factorial(k - 1)*arg**k for k in range(1, ceiling(n/lte))])
s = expand_multinomial(s)
else:
s = S.Zero
return s + Order(x**n, x)
return super()._eval_nseries(x, n, logx)
def _eval_is_zero(self):
x = self.args[0]
if len(self.args) == 1:
k = S.Zero
else:
k = self.args[1]
if x.is_zero and k.is_zero:
return True
|
f73271cafe0a5fbd526bfbbc125537149749a5f14d0c438e391465d200d8d2b6 | from sympy.core import S, Add, Mul, sympify, Symbol, Dummy, Basic
from sympy.core.expr import Expr
from sympy.core.exprtools import factor_terms
from sympy.core.function import (Function, Derivative, ArgumentIndexError,
AppliedUndef)
from sympy.core.logic import fuzzy_not, fuzzy_or
from sympy.core.numbers import pi, I, oo
from sympy.core.relational import Eq
from sympy.functions.elementary.exponential import exp, exp_polar, log
from sympy.functions.elementary.integers import ceiling
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.functions.elementary.piecewise import Piecewise
from sympy.functions.elementary.trigonometric import atan, atan2
###############################################################################
######################### REAL and IMAGINARY PARTS ############################
###############################################################################
class re(Function):
"""
Returns real part of expression. This function performs only
elementary analysis and so it will fail to decompose properly
more complicated expressions. If completely simplified result
is needed then use Basic.as_real_imag() or perform complex
expansion on instance of this function.
Examples
========
>>> from sympy import re, im, I, E
>>> from sympy.abc import x
>>> re(2*E)
2*E
>>> re(2*I + 17)
17
>>> re(2*I)
0
>>> re(im(x) + x*I + 2)
2
See Also
========
im
"""
is_extended_real = True
unbranched = True # implicitly works on the projection to C
_singularities = True # non-holomorphic
@classmethod
def eval(cls, arg):
if arg is S.NaN:
return S.NaN
elif arg is S.ComplexInfinity:
return S.NaN
elif arg.is_extended_real:
return arg
elif arg.is_imaginary or (S.ImaginaryUnit*arg).is_extended_real:
return S.Zero
elif arg.is_Matrix:
return arg.as_real_imag()[0]
elif arg.is_Function and isinstance(arg, conjugate):
return re(arg.args[0])
else:
included, reverted, excluded = [], [], []
args = Add.make_args(arg)
for term in args:
coeff = term.as_coefficient(S.ImaginaryUnit)
if coeff is not None:
if not coeff.is_extended_real:
reverted.append(coeff)
elif not term.has(S.ImaginaryUnit) and term.is_extended_real:
excluded.append(term)
else:
# Try to do some advanced expansion. If
# impossible, don't try to do re(arg) again
# (because this is what we are trying to do now).
real_imag = term.as_real_imag(ignore=arg)
if real_imag:
excluded.append(real_imag[0])
else:
included.append(term)
if len(args) != len(included):
a, b, c = (Add(*xs) for xs in [included, reverted, excluded])
return cls(a) - im(b) + c
def as_real_imag(self, deep=True, **hints):
"""
Returns the real number with a zero imaginary part.
"""
return (self, S.Zero)
def _eval_derivative(self, x):
if x.is_extended_real or self.args[0].is_extended_real:
return re(Derivative(self.args[0], x, evaluate=True))
if x.is_imaginary or self.args[0].is_imaginary:
return -S.ImaginaryUnit \
* im(Derivative(self.args[0], x, evaluate=True))
def _eval_rewrite_as_im(self, arg, **kwargs):
return self.args[0] - S.ImaginaryUnit*im(self.args[0])
def _eval_is_algebraic(self):
return self.args[0].is_algebraic
def _eval_is_zero(self):
# is_imaginary implies nonzero
return fuzzy_or([self.args[0].is_imaginary, self.args[0].is_zero])
def _eval_is_finite(self):
if self.args[0].is_finite:
return True
def _eval_is_complex(self):
if self.args[0].is_finite:
return True
def _sage_(self):
import sage.all as sage
return sage.real_part(self.args[0]._sage_())
class im(Function):
"""
Returns imaginary part of expression. This function performs only
elementary analysis and so it will fail to decompose properly more
complicated expressions. If completely simplified result is needed then
use Basic.as_real_imag() or perform complex expansion on instance of
this function.
Examples
========
>>> from sympy import re, im, E, I
>>> from sympy.abc import x, y
>>> im(2*E)
0
>>> re(2*I + 17)
17
>>> im(x*I)
re(x)
>>> im(re(x) + y)
im(y)
See Also
========
re
"""
is_extended_real = True
unbranched = True # implicitly works on the projection to C
_singularities = True # non-holomorphic
@classmethod
def eval(cls, arg):
if arg is S.NaN:
return S.NaN
elif arg is S.ComplexInfinity:
return S.NaN
elif arg.is_extended_real:
return S.Zero
elif arg.is_imaginary or (S.ImaginaryUnit*arg).is_extended_real:
return -S.ImaginaryUnit * arg
elif arg.is_Matrix:
return arg.as_real_imag()[1]
elif arg.is_Function and isinstance(arg, conjugate):
return -im(arg.args[0])
else:
included, reverted, excluded = [], [], []
args = Add.make_args(arg)
for term in args:
coeff = term.as_coefficient(S.ImaginaryUnit)
if coeff is not None:
if not coeff.is_extended_real:
reverted.append(coeff)
else:
excluded.append(coeff)
elif term.has(S.ImaginaryUnit) or not term.is_extended_real:
# Try to do some advanced expansion. If
# impossible, don't try to do im(arg) again
# (because this is what we are trying to do now).
real_imag = term.as_real_imag(ignore=arg)
if real_imag:
excluded.append(real_imag[1])
else:
included.append(term)
if len(args) != len(included):
a, b, c = (Add(*xs) for xs in [included, reverted, excluded])
return cls(a) + re(b) + c
def as_real_imag(self, deep=True, **hints):
"""
Return the imaginary part with a zero real part.
Examples
========
>>> from sympy.functions import im
>>> from sympy import I
>>> im(2 + 3*I).as_real_imag()
(3, 0)
"""
return (self, S.Zero)
def _eval_derivative(self, x):
if x.is_extended_real or self.args[0].is_extended_real:
return im(Derivative(self.args[0], x, evaluate=True))
if x.is_imaginary or self.args[0].is_imaginary:
return -S.ImaginaryUnit \
* re(Derivative(self.args[0], x, evaluate=True))
def _sage_(self):
import sage.all as sage
return sage.imag_part(self.args[0]._sage_())
def _eval_rewrite_as_re(self, arg, **kwargs):
return -S.ImaginaryUnit*(self.args[0] - re(self.args[0]))
def _eval_is_algebraic(self):
return self.args[0].is_algebraic
def _eval_is_zero(self):
return self.args[0].is_extended_real
def _eval_is_finite(self):
if self.args[0].is_finite:
return True
def _eval_is_complex(self):
if self.args[0].is_finite:
return True
###############################################################################
############### SIGN, ABSOLUTE VALUE, ARGUMENT and CONJUGATION ################
###############################################################################
class sign(Function):
"""
Returns the complex sign of an expression:
If the expression is real the sign will be:
* 1 if expression is positive
* 0 if expression is equal to zero
* -1 if expression is negative
If the expression is imaginary the sign will be:
* I if im(expression) is positive
* -I if im(expression) is negative
Otherwise an unevaluated expression will be returned. When evaluated, the
result (in general) will be ``cos(arg(expr)) + I*sin(arg(expr))``.
Examples
========
>>> from sympy.functions import sign
>>> from sympy.core.numbers import I
>>> sign(-1)
-1
>>> sign(0)
0
>>> sign(-3*I)
-I
>>> sign(1 + I)
sign(1 + I)
>>> _.evalf()
0.707106781186548 + 0.707106781186548*I
See Also
========
Abs, conjugate
"""
is_complex = True
_singularities = True
def doit(self, **hints):
if self.args[0].is_zero is False:
return self.args[0] / Abs(self.args[0])
return self
@classmethod
def eval(cls, arg):
# handle what we can
if arg.is_Mul:
c, args = arg.as_coeff_mul()
unk = []
s = sign(c)
for a in args:
if a.is_extended_negative:
s = -s
elif a.is_extended_positive:
pass
else:
ai = im(a)
if a.is_imaginary and ai.is_comparable: # i.e. a = I*real
s *= S.ImaginaryUnit
if ai.is_extended_negative:
# can't use sign(ai) here since ai might not be
# a Number
s = -s
else:
unk.append(a)
if c is S.One and len(unk) == len(args):
return None
return s * cls(arg._new_rawargs(*unk))
if arg is S.NaN:
return S.NaN
if arg.is_zero: # it may be an Expr that is zero
return S.Zero
if arg.is_extended_positive:
return S.One
if arg.is_extended_negative:
return S.NegativeOne
if arg.is_Function:
if isinstance(arg, sign):
return arg
if arg.is_imaginary:
if arg.is_Pow and arg.exp is S.Half:
# we catch this because non-trivial sqrt args are not expanded
# e.g. sqrt(1-sqrt(2)) --x--> to I*sqrt(sqrt(2) - 1)
return S.ImaginaryUnit
arg2 = -S.ImaginaryUnit * arg
if arg2.is_extended_positive:
return S.ImaginaryUnit
if arg2.is_extended_negative:
return -S.ImaginaryUnit
def _eval_Abs(self):
if fuzzy_not(self.args[0].is_zero):
return S.One
def _eval_conjugate(self):
return sign(conjugate(self.args[0]))
def _eval_derivative(self, x):
if self.args[0].is_extended_real:
from sympy.functions.special.delta_functions import DiracDelta
return 2 * Derivative(self.args[0], x, evaluate=True) \
* DiracDelta(self.args[0])
elif self.args[0].is_imaginary:
from sympy.functions.special.delta_functions import DiracDelta
return 2 * Derivative(self.args[0], x, evaluate=True) \
* DiracDelta(-S.ImaginaryUnit * self.args[0])
def _eval_is_nonnegative(self):
if self.args[0].is_nonnegative:
return True
def _eval_is_nonpositive(self):
if self.args[0].is_nonpositive:
return True
def _eval_is_imaginary(self):
return self.args[0].is_imaginary
def _eval_is_integer(self):
return self.args[0].is_extended_real
def _eval_is_zero(self):
return self.args[0].is_zero
def _eval_power(self, other):
if (
fuzzy_not(self.args[0].is_zero) and
other.is_integer and
other.is_even
):
return S.One
def _sage_(self):
import sage.all as sage
return sage.sgn(self.args[0]._sage_())
def _eval_rewrite_as_Piecewise(self, arg, **kwargs):
if arg.is_extended_real:
return Piecewise((1, arg > 0), (-1, arg < 0), (0, True))
def _eval_rewrite_as_Heaviside(self, arg, **kwargs):
from sympy.functions.special.delta_functions import Heaviside
if arg.is_extended_real:
return Heaviside(arg, H0=S(1)/2) * 2 - 1
def _eval_simplify(self, **kwargs):
return self.func(self.args[0].factor()) # XXX include doit?
class Abs(Function):
"""
Return the absolute value of the argument.
This is an extension of the built-in function abs() to accept symbolic
values. If you pass a SymPy expression to the built-in abs(), it will
pass it automatically to Abs().
Examples
========
>>> from sympy import Abs, Symbol, S
>>> Abs(-1)
1
>>> x = Symbol('x', real=True)
>>> Abs(-x)
Abs(x)
>>> Abs(x**2)
x**2
>>> abs(-x) # The Python built-in
Abs(x)
Note that the Python built-in will return either an Expr or int depending on
the argument::
>>> type(abs(-1))
<... 'int'>
>>> type(abs(S.NegativeOne))
<class 'sympy.core.numbers.One'>
Abs will always return a sympy object.
See Also
========
sign, conjugate
"""
is_extended_real = True
is_extended_negative = False
is_extended_nonnegative = True
unbranched = True
_singularities = True # non-holomorphic
def fdiff(self, argindex=1):
"""
Get the first derivative of the argument to Abs().
Examples
========
>>> from sympy.abc import x
>>> from sympy.functions import Abs
>>> Abs(-x).fdiff()
sign(x)
"""
if argindex == 1:
return sign(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, arg):
from sympy.simplify.simplify import signsimp
from sympy.core.function import expand_mul
from sympy.core.power import Pow
if hasattr(arg, '_eval_Abs'):
obj = arg._eval_Abs()
if obj is not None:
return obj
if not isinstance(arg, Expr):
raise TypeError("Bad argument type for Abs(): %s" % type(arg))
# handle what we can
arg = signsimp(arg, evaluate=False)
n, d = arg.as_numer_denom()
if d.free_symbols and not n.free_symbols:
return cls(n)/cls(d)
if arg.is_Mul:
known = []
unk = []
for t in arg.args:
if t.is_Pow and t.exp.is_integer and t.exp.is_negative:
bnew = cls(t.base)
if isinstance(bnew, cls):
unk.append(t)
else:
known.append(Pow(bnew, t.exp))
else:
tnew = cls(t)
if isinstance(tnew, cls):
unk.append(t)
else:
known.append(tnew)
known = Mul(*known)
unk = cls(Mul(*unk), evaluate=False) if unk else S.One
return known*unk
if arg is S.NaN:
return S.NaN
if arg is S.ComplexInfinity:
return S.Infinity
if arg.is_Pow:
base, exponent = arg.as_base_exp()
if base.is_extended_real:
if exponent.is_integer:
if exponent.is_even:
return arg
if base is S.NegativeOne:
return S.One
return Abs(base)**exponent
if base.is_extended_nonnegative:
return base**re(exponent)
if base.is_extended_negative:
return (-base)**re(exponent)*exp(-S.Pi*im(exponent))
return
elif not base.has(Symbol): # complex base
# express base**exponent as exp(exponent*log(base))
a, b = log(base).as_real_imag()
z = a + I*b
return exp(re(exponent*z))
if isinstance(arg, exp):
return exp(re(arg.args[0]))
if isinstance(arg, AppliedUndef):
return
if arg.is_Add and arg.has(S.Infinity, S.NegativeInfinity):
if any(a.is_infinite for a in arg.as_real_imag()):
return S.Infinity
if arg.is_zero:
return S.Zero
if arg.is_extended_nonnegative:
return arg
if arg.is_extended_nonpositive:
return -arg
if arg.is_imaginary:
arg2 = -S.ImaginaryUnit * arg
if arg2.is_extended_nonnegative:
return arg2
# reject result if all new conjugates are just wrappers around
# an expression that was already in the arg
conj = signsimp(arg.conjugate(), evaluate=False)
new_conj = conj.atoms(conjugate) - arg.atoms(conjugate)
if new_conj and all(arg.has(i.args[0]) for i in new_conj):
return
if arg != conj and arg != -conj:
ignore = arg.atoms(Abs)
abs_free_arg = arg.xreplace({i: Dummy(real=True) for i in ignore})
unk = [a for a in abs_free_arg.free_symbols if a.is_extended_real is None]
if not unk or not all(conj.has(conjugate(u)) for u in unk):
return sqrt(expand_mul(arg*conj))
def _eval_is_real(self):
if self.args[0].is_finite:
return True
def _eval_is_integer(self):
if self.args[0].is_extended_real:
return self.args[0].is_integer
def _eval_is_extended_nonzero(self):
return fuzzy_not(self._args[0].is_zero)
def _eval_is_zero(self):
return self._args[0].is_zero
def _eval_is_extended_positive(self):
is_z = self.is_zero
if is_z is not None:
return not is_z
def _eval_is_rational(self):
if self.args[0].is_extended_real:
return self.args[0].is_rational
def _eval_is_even(self):
if self.args[0].is_extended_real:
return self.args[0].is_even
def _eval_is_odd(self):
if self.args[0].is_extended_real:
return self.args[0].is_odd
def _eval_is_algebraic(self):
return self.args[0].is_algebraic
def _eval_power(self, exponent):
if self.args[0].is_extended_real and exponent.is_integer:
if exponent.is_even:
return self.args[0]**exponent
elif exponent is not S.NegativeOne and exponent.is_Integer:
return self.args[0]**(exponent - 1)*self
return
def _eval_nseries(self, x, n, logx):
direction = self.args[0].leadterm(x)[0]
if direction.has(log(x)):
direction = direction.subs(log(x), logx)
s = self.args[0]._eval_nseries(x, n=n, logx=logx)
when = Eq(direction, 0)
return Piecewise(
((s.subs(direction, 0)), when),
(sign(direction)*s, True),
)
def _sage_(self):
import sage.all as sage
return sage.abs_symbolic(self.args[0]._sage_())
def _eval_derivative(self, x):
if self.args[0].is_extended_real or self.args[0].is_imaginary:
return Derivative(self.args[0], x, evaluate=True) \
* sign(conjugate(self.args[0]))
rv = (re(self.args[0]) * Derivative(re(self.args[0]), x,
evaluate=True) + im(self.args[0]) * Derivative(im(self.args[0]),
x, evaluate=True)) / Abs(self.args[0])
return rv.rewrite(sign)
def _eval_rewrite_as_Heaviside(self, arg, **kwargs):
# Note this only holds for real arg (since Heaviside is not defined
# for complex arguments).
from sympy.functions.special.delta_functions import Heaviside
if arg.is_extended_real:
return arg*(Heaviside(arg) - Heaviside(-arg))
def _eval_rewrite_as_Piecewise(self, arg, **kwargs):
if arg.is_extended_real:
return Piecewise((arg, arg >= 0), (-arg, True))
elif arg.is_imaginary:
return Piecewise((I*arg, I*arg >= 0), (-I*arg, True))
def _eval_rewrite_as_sign(self, arg, **kwargs):
return arg/sign(arg)
def _eval_rewrite_as_conjugate(self, arg, **kwargs):
return (arg*conjugate(arg))**S.Half
class arg(Function):
"""
Returns the argument (in radians) of a complex number. For a positive
number, the argument is always 0.
Examples
========
>>> from sympy.functions import arg
>>> from sympy import I, sqrt
>>> arg(2.0)
0
>>> arg(I)
pi/2
>>> arg(sqrt(2) + I*sqrt(2))
pi/4
"""
is_extended_real = True
is_real = True
is_finite = True
_singularities = True # non-holomorphic
@classmethod
def eval(cls, arg):
if isinstance(arg, exp_polar):
return periodic_argument(arg, oo)
if not arg.is_Atom:
c, arg_ = factor_terms(arg).as_coeff_Mul()
if arg_.is_Mul:
arg_ = Mul(*[a if (sign(a) not in (-1, 1)) else
sign(a) for a in arg_.args])
arg_ = sign(c)*arg_
else:
arg_ = arg
if arg_.atoms(AppliedUndef):
return
x, y = arg_.as_real_imag()
rv = atan2(y, x)
if rv.is_number:
return rv
if arg_ != arg:
return cls(arg_, evaluate=False)
def _eval_derivative(self, t):
x, y = self.args[0].as_real_imag()
return (x * Derivative(y, t, evaluate=True) - y *
Derivative(x, t, evaluate=True)) / (x**2 + y**2)
def _eval_rewrite_as_atan2(self, arg, **kwargs):
x, y = self.args[0].as_real_imag()
return atan2(y, x)
class conjugate(Function):
"""
Returns the `complex conjugate` Ref[1] of an argument.
In mathematics, the complex conjugate of a complex number
is given by changing the sign of the imaginary part.
Thus, the conjugate of the complex number
:math:`a + ib` (where a and b are real numbers) is :math:`a - ib`
Examples
========
>>> from sympy import conjugate, I
>>> conjugate(2)
2
>>> conjugate(I)
-I
See Also
========
sign, Abs
References
==========
.. [1] https://en.wikipedia.org/wiki/Complex_conjugation
"""
_singularities = True # non-holomorphic
@classmethod
def eval(cls, arg):
obj = arg._eval_conjugate()
if obj is not None:
return obj
def _eval_Abs(self):
return Abs(self.args[0], evaluate=True)
def _eval_adjoint(self):
return transpose(self.args[0])
def _eval_conjugate(self):
return self.args[0]
def _eval_derivative(self, x):
if x.is_real:
return conjugate(Derivative(self.args[0], x, evaluate=True))
elif x.is_imaginary:
return -conjugate(Derivative(self.args[0], x, evaluate=True))
def _eval_transpose(self):
return adjoint(self.args[0])
def _eval_is_algebraic(self):
return self.args[0].is_algebraic
class transpose(Function):
"""
Linear map transposition.
"""
@classmethod
def eval(cls, arg):
obj = arg._eval_transpose()
if obj is not None:
return obj
def _eval_adjoint(self):
return conjugate(self.args[0])
def _eval_conjugate(self):
return adjoint(self.args[0])
def _eval_transpose(self):
return self.args[0]
class adjoint(Function):
"""
Conjugate transpose or Hermite conjugation.
"""
@classmethod
def eval(cls, arg):
obj = arg._eval_adjoint()
if obj is not None:
return obj
obj = arg._eval_transpose()
if obj is not None:
return conjugate(obj)
def _eval_adjoint(self):
return self.args[0]
def _eval_conjugate(self):
return transpose(self.args[0])
def _eval_transpose(self):
return conjugate(self.args[0])
def _latex(self, printer, exp=None, *args):
arg = printer._print(self.args[0])
tex = r'%s^{\dagger}' % arg
if exp:
tex = r'\left(%s\right)^{%s}' % (tex, printer._print(exp))
return tex
def _pretty(self, printer, *args):
from sympy.printing.pretty.stringpict import prettyForm
pform = printer._print(self.args[0], *args)
if printer._use_unicode:
pform = pform**prettyForm('\N{DAGGER}')
else:
pform = pform**prettyForm('+')
return pform
###############################################################################
############### HANDLING OF POLAR NUMBERS #####################################
###############################################################################
class polar_lift(Function):
"""
Lift argument to the Riemann surface of the logarithm, using the
standard branch.
>>> from sympy import Symbol, polar_lift, I
>>> p = Symbol('p', polar=True)
>>> x = Symbol('x')
>>> polar_lift(4)
4*exp_polar(0)
>>> polar_lift(-4)
4*exp_polar(I*pi)
>>> polar_lift(-I)
exp_polar(-I*pi/2)
>>> polar_lift(I + 2)
polar_lift(2 + I)
>>> polar_lift(4*x)
4*polar_lift(x)
>>> polar_lift(4*p)
4*p
See Also
========
sympy.functions.elementary.exponential.exp_polar
periodic_argument
"""
is_polar = True
is_comparable = False # Cannot be evalf'd.
@classmethod
def eval(cls, arg):
from sympy.functions.elementary.complexes import arg as argument
if arg.is_number:
ar = argument(arg)
# In general we want to affirm that something is known,
# e.g. `not ar.has(argument) and not ar.has(atan)`
# but for now we will just be more restrictive and
# see that it has evaluated to one of the known values.
if ar in (0, pi/2, -pi/2, pi):
return exp_polar(I*ar)*abs(arg)
if arg.is_Mul:
args = arg.args
else:
args = [arg]
included = []
excluded = []
positive = []
for arg in args:
if arg.is_polar:
included += [arg]
elif arg.is_positive:
positive += [arg]
else:
excluded += [arg]
if len(excluded) < len(args):
if excluded:
return Mul(*(included + positive))*polar_lift(Mul(*excluded))
elif included:
return Mul(*(included + positive))
else:
return Mul(*positive)*exp_polar(0)
def _eval_evalf(self, prec):
""" Careful! any evalf of polar numbers is flaky """
return self.args[0]._eval_evalf(prec)
def _eval_Abs(self):
return Abs(self.args[0], evaluate=True)
class periodic_argument(Function):
"""
Represent the argument on a quotient of the Riemann surface of the
logarithm. That is, given a period P, always return a value in
(-P/2, P/2], by using exp(P*I) == 1.
>>> from sympy import exp, exp_polar, periodic_argument, unbranched_argument
>>> from sympy import I, pi
>>> unbranched_argument(exp(5*I*pi))
pi
>>> unbranched_argument(exp_polar(5*I*pi))
5*pi
>>> periodic_argument(exp_polar(5*I*pi), 2*pi)
pi
>>> periodic_argument(exp_polar(5*I*pi), 3*pi)
-pi
>>> periodic_argument(exp_polar(5*I*pi), pi)
0
See Also
========
sympy.functions.elementary.exponential.exp_polar
polar_lift : Lift argument to the Riemann surface of the logarithm
principal_branch
"""
@classmethod
def _getunbranched(cls, ar):
if ar.is_Mul:
args = ar.args
else:
args = [ar]
unbranched = 0
for a in args:
if not a.is_polar:
unbranched += arg(a)
elif isinstance(a, exp_polar):
unbranched += a.exp.as_real_imag()[1]
elif a.is_Pow:
re, im = a.exp.as_real_imag()
unbranched += re*unbranched_argument(
a.base) + im*log(abs(a.base))
elif isinstance(a, polar_lift):
unbranched += arg(a.args[0])
else:
return None
return unbranched
@classmethod
def eval(cls, ar, period):
# Our strategy is to evaluate the argument on the Riemann surface of the
# logarithm, and then reduce.
# NOTE evidently this means it is a rather bad idea to use this with
# period != 2*pi and non-polar numbers.
if not period.is_extended_positive:
return None
if period == oo and isinstance(ar, principal_branch):
return periodic_argument(*ar.args)
if isinstance(ar, polar_lift) and period >= 2*pi:
return periodic_argument(ar.args[0], period)
if ar.is_Mul:
newargs = [x for x in ar.args if not x.is_positive]
if len(newargs) != len(ar.args):
return periodic_argument(Mul(*newargs), period)
unbranched = cls._getunbranched(ar)
if unbranched is None:
return None
if unbranched.has(periodic_argument, atan2, atan):
return None
if period == oo:
return unbranched
if period != oo:
n = ceiling(unbranched/period - S.Half)*period
if not n.has(ceiling):
return unbranched - n
def _eval_evalf(self, prec):
z, period = self.args
if period == oo:
unbranched = periodic_argument._getunbranched(z)
if unbranched is None:
return self
return unbranched._eval_evalf(prec)
ub = periodic_argument(z, oo)._eval_evalf(prec)
return (ub - ceiling(ub/period - S.Half)*period)._eval_evalf(prec)
def unbranched_argument(arg):
return periodic_argument(arg, oo)
class principal_branch(Function):
"""
Represent a polar number reduced to its principal branch on a quotient
of the Riemann surface of the logarithm.
This is a function of two arguments. The first argument is a polar
number `z`, and the second one a positive real number of infinity, `p`.
The result is "z mod exp_polar(I*p)".
>>> from sympy import exp_polar, principal_branch, oo, I, pi
>>> from sympy.abc import z
>>> principal_branch(z, oo)
z
>>> principal_branch(exp_polar(2*pi*I)*3, 2*pi)
3*exp_polar(0)
>>> principal_branch(exp_polar(2*pi*I)*3*z, 2*pi)
3*principal_branch(z, 2*pi)
See Also
========
sympy.functions.elementary.exponential.exp_polar
polar_lift : Lift argument to the Riemann surface of the logarithm
periodic_argument
"""
is_polar = True
is_comparable = False # cannot always be evalf'd
@classmethod
def eval(self, x, period):
from sympy import oo, exp_polar, I, Mul, polar_lift, Symbol
if isinstance(x, polar_lift):
return principal_branch(x.args[0], period)
if period == oo:
return x
ub = periodic_argument(x, oo)
barg = periodic_argument(x, period)
if ub != barg and not ub.has(periodic_argument) \
and not barg.has(periodic_argument):
pl = polar_lift(x)
def mr(expr):
if not isinstance(expr, Symbol):
return polar_lift(expr)
return expr
pl = pl.replace(polar_lift, mr)
# Recompute unbranched argument
ub = periodic_argument(pl, oo)
if not pl.has(polar_lift):
if ub != barg:
res = exp_polar(I*(barg - ub))*pl
else:
res = pl
if not res.is_polar and not res.has(exp_polar):
res *= exp_polar(0)
return res
if not x.free_symbols:
c, m = x, ()
else:
c, m = x.as_coeff_mul(*x.free_symbols)
others = []
for y in m:
if y.is_positive:
c *= y
else:
others += [y]
m = tuple(others)
arg = periodic_argument(c, period)
if arg.has(periodic_argument):
return None
if arg.is_number and (unbranched_argument(c) != arg or
(arg == 0 and m != () and c != 1)):
if arg == 0:
return abs(c)*principal_branch(Mul(*m), period)
return principal_branch(exp_polar(I*arg)*Mul(*m), period)*abs(c)
if arg.is_number and ((abs(arg) < period/2) == True or arg == period/2) \
and m == ():
return exp_polar(arg*I)*abs(c)
def _eval_evalf(self, prec):
from sympy import exp, pi, I
z, period = self.args
p = periodic_argument(z, period)._eval_evalf(prec)
if abs(p) > pi or p == -pi:
return self # Cannot evalf for this argument.
return (abs(z)*exp(I*p))._eval_evalf(prec)
def _polarify(eq, lift, pause=False):
from sympy import Integral
if eq.is_polar:
return eq
if eq.is_number and not pause:
return polar_lift(eq)
if isinstance(eq, Symbol) and not pause and lift:
return polar_lift(eq)
elif eq.is_Atom:
return eq
elif eq.is_Add:
r = eq.func(*[_polarify(arg, lift, pause=True) for arg in eq.args])
if lift:
return polar_lift(r)
return r
elif eq.is_Function:
return eq.func(*[_polarify(arg, lift, pause=False) for arg in eq.args])
elif isinstance(eq, Integral):
# Don't lift the integration variable
func = _polarify(eq.function, lift, pause=pause)
limits = []
for limit in eq.args[1:]:
var = _polarify(limit[0], lift=False, pause=pause)
rest = _polarify(limit[1:], lift=lift, pause=pause)
limits.append((var,) + rest)
return Integral(*((func,) + tuple(limits)))
else:
return eq.func(*[_polarify(arg, lift, pause=pause)
if isinstance(arg, Expr) else arg for arg in eq.args])
def polarify(eq, subs=True, lift=False):
"""
Turn all numbers in eq into their polar equivalents (under the standard
choice of argument).
Note that no attempt is made to guess a formal convention of adding
polar numbers, expressions like 1 + x will generally not be altered.
Note also that this function does not promote exp(x) to exp_polar(x).
If ``subs`` is True, all symbols which are not already polar will be
substituted for polar dummies; in this case the function behaves much
like posify.
If ``lift`` is True, both addition statements and non-polar symbols are
changed to their polar_lift()ed versions.
Note that lift=True implies subs=False.
>>> from sympy import polarify, sin, I
>>> from sympy.abc import x, y
>>> expr = (-x)**y
>>> expr.expand()
(-x)**y
>>> polarify(expr)
((_x*exp_polar(I*pi))**_y, {_x: x, _y: y})
>>> polarify(expr)[0].expand()
_x**_y*exp_polar(_y*I*pi)
>>> polarify(x, lift=True)
polar_lift(x)
>>> polarify(x*(1+y), lift=True)
polar_lift(x)*polar_lift(y + 1)
Adds are treated carefully:
>>> polarify(1 + sin((1 + I)*x))
(sin(_x*polar_lift(1 + I)) + 1, {_x: x})
"""
if lift:
subs = False
eq = _polarify(sympify(eq), lift)
if not subs:
return eq
reps = {s: Dummy(s.name, polar=True) for s in eq.free_symbols}
eq = eq.subs(reps)
return eq, {r: s for s, r in reps.items()}
def _unpolarify(eq, exponents_only, pause=False):
if not isinstance(eq, Basic) or eq.is_Atom:
return eq
if not pause:
if isinstance(eq, exp_polar):
return exp(_unpolarify(eq.exp, exponents_only))
if isinstance(eq, principal_branch) and eq.args[1] == 2*pi:
return _unpolarify(eq.args[0], exponents_only)
if (
eq.is_Add or eq.is_Mul or eq.is_Boolean or
eq.is_Relational and (
eq.rel_op in ('==', '!=') and 0 in eq.args or
eq.rel_op not in ('==', '!='))
):
return eq.func(*[_unpolarify(x, exponents_only) for x in eq.args])
if isinstance(eq, polar_lift):
return _unpolarify(eq.args[0], exponents_only)
if eq.is_Pow:
expo = _unpolarify(eq.exp, exponents_only)
base = _unpolarify(eq.base, exponents_only,
not (expo.is_integer and not pause))
return base**expo
if eq.is_Function and getattr(eq.func, 'unbranched', False):
return eq.func(*[_unpolarify(x, exponents_only, exponents_only)
for x in eq.args])
return eq.func(*[_unpolarify(x, exponents_only, True) for x in eq.args])
def unpolarify(eq, subs={}, exponents_only=False):
"""
If p denotes the projection from the Riemann surface of the logarithm to
the complex line, return a simplified version eq' of `eq` such that
p(eq') == p(eq).
Also apply the substitution subs in the end. (This is a convenience, since
``unpolarify``, in a certain sense, undoes polarify.)
>>> from sympy import unpolarify, polar_lift, sin, I
>>> unpolarify(polar_lift(I + 2))
2 + I
>>> unpolarify(sin(polar_lift(I + 7)))
sin(7 + I)
"""
if isinstance(eq, bool):
return eq
eq = sympify(eq)
if subs != {}:
return unpolarify(eq.subs(subs))
changed = True
pause = False
if exponents_only:
pause = True
while changed:
changed = False
res = _unpolarify(eq, exponents_only, pause)
if res != eq:
changed = True
eq = res
if isinstance(res, bool):
return res
# Finally, replacing Exp(0) by 1 is always correct.
# So is polar_lift(0) -> 0.
return res.subs({exp_polar(0): 1, polar_lift(0): 0})
|
01eb1f44839f11ec047b93fb7ec14d844e42c0ca1514dcef862c411735a652d1 | from sympy.core import Add, S, sympify, oo, pi, Dummy, expand_func
from sympy.core.compatibility import as_int
from sympy.core.function import Function, ArgumentIndexError
from sympy.core.logic import fuzzy_and, fuzzy_not
from sympy.core.numbers import Rational
from sympy.core.power import Pow
from sympy.functions.special.zeta_functions import zeta
from sympy.functions.special.error_functions import erf, erfc, Ei
from sympy.functions.elementary.complexes import re
from sympy.functions.elementary.exponential import exp, log
from sympy.functions.elementary.integers import ceiling, floor
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.functions.elementary.trigonometric import sin, cos, cot
from sympy.functions.combinatorial.numbers import bernoulli, harmonic
from sympy.functions.combinatorial.factorials import factorial, rf, RisingFactorial
def intlike(n):
try:
as_int(n, strict=False)
return True
except ValueError:
return False
###############################################################################
############################ COMPLETE GAMMA FUNCTION ##########################
###############################################################################
class gamma(Function):
r"""
The gamma function
.. math::
\Gamma(x) := \int^{\infty}_{0} t^{x-1} e^{-t} \mathrm{d}t.
Explanation
===========
The ``gamma`` function implements the function which passes through the
values of the factorial function (i.e., $\Gamma(n) = (n - 1)!$ when n is
an integer). More generally, $\Gamma(z)$ is defined in the whole complex
plane except at the negative integers where there are simple poles.
Examples
========
>>> from sympy import S, I, pi, gamma
>>> from sympy.abc import x
Several special values are known:
>>> gamma(1)
1
>>> gamma(4)
6
>>> gamma(S(3)/2)
sqrt(pi)/2
The ``gamma`` function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(gamma(x))
gamma(conjugate(x))
Differentiation with respect to $x$ is supported:
>>> from sympy import diff
>>> diff(gamma(x), x)
gamma(x)*polygamma(0, x)
Series expansion is also supported:
>>> from sympy import series
>>> series(gamma(x), x, 0, 3)
1/x - EulerGamma + x*(EulerGamma**2/2 + pi**2/12) + x**2*(-EulerGamma*pi**2/12 + polygamma(2, 1)/6 - EulerGamma**3/6) + O(x**3)
We can numerically evaluate the ``gamma`` function to arbitrary precision
on the whole complex plane:
>>> gamma(pi).evalf(40)
2.288037795340032417959588909060233922890
>>> gamma(1+I).evalf(20)
0.49801566811835604271 - 0.15494982830181068512*I
See Also
========
lowergamma: Lower incomplete gamma function.
uppergamma: Upper incomplete gamma function.
polygamma: Polygamma function.
loggamma: Log Gamma function.
digamma: Digamma function.
trigamma: Trigamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Gamma_function
.. [2] http://dlmf.nist.gov/5
.. [3] http://mathworld.wolfram.com/GammaFunction.html
.. [4] http://functions.wolfram.com/GammaBetaErf/Gamma/
"""
unbranched = True
_singularities = (S.ComplexInfinity,)
def fdiff(self, argindex=1):
if argindex == 1:
return self.func(self.args[0])*polygamma(0, self.args[0])
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Infinity
elif intlike(arg):
if arg.is_positive:
return factorial(arg - 1)
else:
return S.ComplexInfinity
elif arg.is_Rational:
if arg.q == 2:
n = abs(arg.p) // arg.q
if arg.is_positive:
k, coeff = n, S.One
else:
n = k = n + 1
if n & 1 == 0:
coeff = S.One
else:
coeff = S.NegativeOne
for i in range(3, 2*k, 2):
coeff *= i
if arg.is_positive:
return coeff*sqrt(S.Pi) / 2**n
else:
return 2**n*sqrt(S.Pi) / coeff
def _eval_expand_func(self, **hints):
arg = self.args[0]
if arg.is_Rational:
if abs(arg.p) > arg.q:
x = Dummy('x')
n = arg.p // arg.q
p = arg.p - n*arg.q
return self.func(x + n)._eval_expand_func().subs(x, Rational(p, arg.q))
if arg.is_Add:
coeff, tail = arg.as_coeff_add()
if coeff and coeff.q != 1:
intpart = floor(coeff)
tail = (coeff - intpart,) + tail
coeff = intpart
tail = arg._new_rawargs(*tail, reeval=False)
return self.func(tail)*RisingFactorial(tail, coeff)
return self.func(*self.args)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def _eval_is_real(self):
x = self.args[0]
if x.is_nonpositive and x.is_integer:
return False
if intlike(x) and x <= 0:
return False
if x.is_positive or x.is_noninteger:
return True
def _eval_is_positive(self):
x = self.args[0]
if x.is_positive:
return True
elif x.is_noninteger:
return floor(x).is_even
def _eval_rewrite_as_tractable(self, z, **kwargs):
return exp(loggamma(z))
def _eval_rewrite_as_factorial(self, z, **kwargs):
return factorial(z - 1)
def _eval_nseries(self, x, n, logx):
x0 = self.args[0].limit(x, 0)
if not (x0.is_Integer and x0 <= 0):
return super()._eval_nseries(x, n, logx)
t = self.args[0] - x0
return (self.func(t + 1)/rf(self.args[0], -x0 + 1))._eval_nseries(x, n, logx)
def _sage_(self):
import sage.all as sage
return sage.gamma(self.args[0]._sage_())
def _eval_as_leading_term(self, x):
arg = self.args[0]
x0 = arg.subs(x, 0)
if x0.is_integer and x0.is_nonpositive:
n = -x0
res = (-1)**n/self.func(n + 1)
return res/(arg + n).as_leading_term(x)
elif x0.is_finite:
return self.func(x0)
####################################################
# The correct result here should be 'None'. #
# Indeed arg in not bounded as x tends to 0. #
# Consequently the series expansion does not admit #
# the leading term. #
# For compatibility reasons, the return value here #
# is the original function, i.e. gamma(arg), #
# instead of None. #
####################################################
return self.func(arg)
###############################################################################
################## LOWER and UPPER INCOMPLETE GAMMA FUNCTIONS #################
###############################################################################
class lowergamma(Function):
r"""
The lower incomplete gamma function.
Explanation
===========
It can be defined as the meromorphic continuation of
.. math::
\gamma(s, x) := \int_0^x t^{s-1} e^{-t} \mathrm{d}t = \Gamma(s) - \Gamma(s, x).
This can be shown to be the same as
.. math::
\gamma(s, x) = \frac{x^s}{s} {}_1F_1\left({s \atop s+1} \middle| -x\right),
where ${}_1F_1$ is the (confluent) hypergeometric function.
Examples
========
>>> from sympy import lowergamma, S
>>> from sympy.abc import s, x
>>> lowergamma(s, x)
lowergamma(s, x)
>>> lowergamma(3, x)
-2*(x**2/2 + x + 1)*exp(-x) + 2
>>> lowergamma(-S(1)/2, x)
-2*sqrt(pi)*erf(sqrt(x)) - 2*exp(-x)/sqrt(x)
See Also
========
gamma: Gamma function.
uppergamma: Upper incomplete gamma function.
polygamma: Polygamma function.
loggamma: Log Gamma function.
digamma: Digamma function.
trigamma: Trigamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Incomplete_gamma_function#Lower_incomplete_Gamma_function
.. [2] Abramowitz, Milton; Stegun, Irene A., eds. (1965), Chapter 6,
Section 5, Handbook of Mathematical Functions with Formulas, Graphs,
and Mathematical Tables
.. [3] http://dlmf.nist.gov/8
.. [4] http://functions.wolfram.com/GammaBetaErf/Gamma2/
.. [5] http://functions.wolfram.com/GammaBetaErf/Gamma3/
"""
def fdiff(self, argindex=2):
from sympy import meijerg, unpolarify
if argindex == 2:
a, z = self.args
return exp(-unpolarify(z))*z**(a - 1)
elif argindex == 1:
a, z = self.args
return gamma(a)*digamma(a) - log(z)*uppergamma(a, z) \
- meijerg([], [1, 1], [0, 0, a], [], z)
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, a, x):
# For lack of a better place, we use this one to extract branching
# information. The following can be
# found in the literature (c/f references given above), albeit scattered:
# 1) For fixed x != 0, lowergamma(s, x) is an entire function of s
# 2) For fixed positive integers s, lowergamma(s, x) is an entire
# function of x.
# 3) For fixed non-positive integers s,
# lowergamma(s, exp(I*2*pi*n)*x) =
# 2*pi*I*n*(-1)**(-s)/factorial(-s) + lowergamma(s, x)
# (this follows from lowergamma(s, x).diff(x) = x**(s-1)*exp(-x)).
# 4) For fixed non-integral s,
# lowergamma(s, x) = x**s*gamma(s)*lowergamma_unbranched(s, x),
# where lowergamma_unbranched(s, x) is an entire function (in fact
# of both s and x), i.e.
# lowergamma(s, exp(2*I*pi*n)*x) = exp(2*pi*I*n*a)*lowergamma(a, x)
from sympy import unpolarify, I
if x is S.Zero:
return S.Zero
nx, n = x.extract_branch_factor()
if a.is_integer and a.is_positive:
nx = unpolarify(x)
if nx != x:
return lowergamma(a, nx)
elif a.is_integer and a.is_nonpositive:
if n != 0:
return 2*pi*I*n*(-1)**(-a)/factorial(-a) + lowergamma(a, nx)
elif n != 0:
return exp(2*pi*I*n*a)*lowergamma(a, nx)
# Special values.
if a.is_Number:
if a is S.One:
return S.One - exp(-x)
elif a is S.Half:
return sqrt(pi)*erf(sqrt(x))
elif a.is_Integer or (2*a).is_Integer:
b = a - 1
if b.is_positive:
if a.is_integer:
return factorial(b) - exp(-x) * factorial(b) * Add(*[x ** k / factorial(k) for k in range(a)])
else:
return gamma(a)*(lowergamma(S.Half, x)/sqrt(pi) - exp(-x)*Add(*[x**(k - S.Half)/gamma(S.Half + k) for k in range(1, a + S.Half)]))
if not a.is_Integer:
return (-1)**(S.Half - a)*pi*erf(sqrt(x))/gamma(1 - a) + exp(-x)*Add(*[x**(k + a - 1)*gamma(a)/gamma(a + k) for k in range(1, Rational(3, 2) - a)])
if x.is_zero:
return S.Zero
def _eval_evalf(self, prec):
from mpmath import mp, workprec
from sympy import Expr
if all(x.is_number for x in self.args):
a = self.args[0]._to_mpmath(prec)
z = self.args[1]._to_mpmath(prec)
with workprec(prec):
res = mp.gammainc(a, 0, z)
return Expr._from_mpmath(res, prec)
else:
return self
def _eval_conjugate(self):
x = self.args[1]
if x not in (S.Zero, S.NegativeInfinity):
return self.func(self.args[0].conjugate(), x.conjugate())
def _eval_rewrite_as_uppergamma(self, s, x, **kwargs):
return gamma(s) - uppergamma(s, x)
def _eval_rewrite_as_expint(self, s, x, **kwargs):
from sympy import expint
if s.is_integer and s.is_nonpositive:
return self
return self.rewrite(uppergamma).rewrite(expint)
def _eval_is_zero(self):
x = self.args[1]
if x.is_zero:
return True
class uppergamma(Function):
r"""
The upper incomplete gamma function.
Explanation
===========
It can be defined as the meromorphic continuation of
.. math::
\Gamma(s, x) := \int_x^\infty t^{s-1} e^{-t} \mathrm{d}t = \Gamma(s) - \gamma(s, x).
where $\gamma(s, x)$ is the lower incomplete gamma function,
:class:`lowergamma`. This can be shown to be the same as
.. math::
\Gamma(s, x) = \Gamma(s) - \frac{x^s}{s} {}_1F_1\left({s \atop s+1} \middle| -x\right),
where ${}_1F_1$ is the (confluent) hypergeometric function.
The upper incomplete gamma function is also essentially equivalent to the
generalized exponential integral:
.. math::
\operatorname{E}_{n}(x) = \int_{1}^{\infty}{\frac{e^{-xt}}{t^n} \, dt} = x^{n-1}\Gamma(1-n,x).
Examples
========
>>> from sympy import uppergamma, S
>>> from sympy.abc import s, x
>>> uppergamma(s, x)
uppergamma(s, x)
>>> uppergamma(3, x)
2*(x**2/2 + x + 1)*exp(-x)
>>> uppergamma(-S(1)/2, x)
-2*sqrt(pi)*erfc(sqrt(x)) + 2*exp(-x)/sqrt(x)
>>> uppergamma(-2, x)
expint(3, x)/x**2
See Also
========
gamma: Gamma function.
lowergamma: Lower incomplete gamma function.
polygamma: Polygamma function.
loggamma: Log Gamma function.
digamma: Digamma function.
trigamma: Trigamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Incomplete_gamma_function#Upper_incomplete_Gamma_function
.. [2] Abramowitz, Milton; Stegun, Irene A., eds. (1965), Chapter 6,
Section 5, Handbook of Mathematical Functions with Formulas, Graphs,
and Mathematical Tables
.. [3] http://dlmf.nist.gov/8
.. [4] http://functions.wolfram.com/GammaBetaErf/Gamma2/
.. [5] http://functions.wolfram.com/GammaBetaErf/Gamma3/
.. [6] https://en.wikipedia.org/wiki/Exponential_integral#Relation_with_other_functions
"""
def fdiff(self, argindex=2):
from sympy import meijerg, unpolarify
if argindex == 2:
a, z = self.args
return -exp(-unpolarify(z))*z**(a - 1)
elif argindex == 1:
a, z = self.args
return uppergamma(a, z)*log(z) + meijerg([], [1, 1], [0, 0, a], [], z)
else:
raise ArgumentIndexError(self, argindex)
def _eval_evalf(self, prec):
from mpmath import mp, workprec
from sympy import Expr
if all(x.is_number for x in self.args):
a = self.args[0]._to_mpmath(prec)
z = self.args[1]._to_mpmath(prec)
with workprec(prec):
res = mp.gammainc(a, z, mp.inf)
return Expr._from_mpmath(res, prec)
return self
@classmethod
def eval(cls, a, z):
from sympy import unpolarify, I, expint
if z.is_Number:
if z is S.NaN:
return S.NaN
elif z is S.Infinity:
return S.Zero
elif z.is_zero:
if re(a).is_positive:
return gamma(a)
# We extract branching information here. C/f lowergamma.
nx, n = z.extract_branch_factor()
if a.is_integer and a.is_positive:
nx = unpolarify(z)
if z != nx:
return uppergamma(a, nx)
elif a.is_integer and a.is_nonpositive:
if n != 0:
return -2*pi*I*n*(-1)**(-a)/factorial(-a) + uppergamma(a, nx)
elif n != 0:
return gamma(a)*(1 - exp(2*pi*I*n*a)) + exp(2*pi*I*n*a)*uppergamma(a, nx)
# Special values.
if a.is_Number:
if a is S.Zero and z.is_positive:
return -Ei(-z)
elif a is S.One:
return exp(-z)
elif a is S.Half:
return sqrt(pi)*erfc(sqrt(z))
elif a.is_Integer or (2*a).is_Integer:
b = a - 1
if b.is_positive:
if a.is_integer:
return exp(-z) * factorial(b) * Add(*[z**k / factorial(k) for k in range(a)])
else:
return gamma(a) * erfc(sqrt(z)) + (-1)**(a - S(3)/2) * exp(-z) * sqrt(z) * Add(*[gamma(-S.Half - k) * (-z)**k / gamma(1-a) for k in range(a - S.Half)])
elif b.is_Integer:
return expint(-b, z)*unpolarify(z)**(b + 1)
if not a.is_Integer:
return (-1)**(S.Half - a) * pi*erfc(sqrt(z))/gamma(1-a) - z**a * exp(-z) * Add(*[z**k * gamma(a) / gamma(a+k+1) for k in range(S.Half - a)])
if a.is_zero and z.is_positive:
return -Ei(-z)
if z.is_zero and re(a).is_positive:
return gamma(a)
def _eval_conjugate(self):
z = self.args[1]
if not z in (S.Zero, S.NegativeInfinity):
return self.func(self.args[0].conjugate(), z.conjugate())
def _eval_rewrite_as_lowergamma(self, s, x, **kwargs):
return gamma(s) - lowergamma(s, x)
def _eval_rewrite_as_expint(self, s, x, **kwargs):
from sympy import expint
return expint(1 - s, x)*x**s
def _sage_(self):
import sage.all as sage
return sage.gamma(self.args[0]._sage_(), self.args[1]._sage_())
###############################################################################
###################### POLYGAMMA and LOGGAMMA FUNCTIONS #######################
###############################################################################
class polygamma(Function):
r"""
The function ``polygamma(n, z)`` returns ``log(gamma(z)).diff(n + 1)``.
Explanation
===========
It is a meromorphic function on $\mathbb{C}$ and defined as the $(n+1)$-th
derivative of the logarithm of the gamma function:
.. math::
\psi^{(n)} (z) := \frac{\mathrm{d}^{n+1}}{\mathrm{d} z^{n+1}} \log\Gamma(z).
Examples
========
Several special values are known:
>>> from sympy import S, polygamma
>>> polygamma(0, 1)
-EulerGamma
>>> polygamma(0, 1/S(2))
-2*log(2) - EulerGamma
>>> polygamma(0, 1/S(3))
-log(3) - sqrt(3)*pi/6 - EulerGamma - log(sqrt(3))
>>> polygamma(0, 1/S(4))
-pi/2 - log(4) - log(2) - EulerGamma
>>> polygamma(0, 2)
1 - EulerGamma
>>> polygamma(0, 23)
19093197/5173168 - EulerGamma
>>> from sympy import oo, I
>>> polygamma(0, oo)
oo
>>> polygamma(0, -oo)
oo
>>> polygamma(0, I*oo)
oo
>>> polygamma(0, -I*oo)
oo
Differentiation with respect to $x$ is supported:
>>> from sympy import Symbol, diff
>>> x = Symbol("x")
>>> diff(polygamma(0, x), x)
polygamma(1, x)
>>> diff(polygamma(0, x), x, 2)
polygamma(2, x)
>>> diff(polygamma(0, x), x, 3)
polygamma(3, x)
>>> diff(polygamma(1, x), x)
polygamma(2, x)
>>> diff(polygamma(1, x), x, 2)
polygamma(3, x)
>>> diff(polygamma(2, x), x)
polygamma(3, x)
>>> diff(polygamma(2, x), x, 2)
polygamma(4, x)
>>> n = Symbol("n")
>>> diff(polygamma(n, x), x)
polygamma(n + 1, x)
>>> diff(polygamma(n, x), x, 2)
polygamma(n + 2, x)
We can rewrite ``polygamma`` functions in terms of harmonic numbers:
>>> from sympy import harmonic
>>> polygamma(0, x).rewrite(harmonic)
harmonic(x - 1) - EulerGamma
>>> polygamma(2, x).rewrite(harmonic)
2*harmonic(x - 1, 3) - 2*zeta(3)
>>> ni = Symbol("n", integer=True)
>>> polygamma(ni, x).rewrite(harmonic)
(-1)**(n + 1)*(-harmonic(x - 1, n + 1) + zeta(n + 1))*factorial(n)
See Also
========
gamma: Gamma function.
lowergamma: Lower incomplete gamma function.
uppergamma: Upper incomplete gamma function.
loggamma: Log Gamma function.
digamma: Digamma function.
trigamma: Trigamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Polygamma_function
.. [2] http://mathworld.wolfram.com/PolygammaFunction.html
.. [3] http://functions.wolfram.com/GammaBetaErf/PolyGamma/
.. [4] http://functions.wolfram.com/GammaBetaErf/PolyGamma2/
"""
def _eval_evalf(self, prec):
n = self.args[0]
# the mpmath polygamma implementation valid only for nonnegative integers
if n.is_number and n.is_real:
if (n.is_integer or n == int(n)) and n.is_nonnegative:
return super()._eval_evalf(prec)
def fdiff(self, argindex=2):
if argindex == 2:
n, z = self.args[:2]
return polygamma(n + 1, z)
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_real(self):
if self.args[0].is_positive and self.args[1].is_positive:
return True
def _eval_is_complex(self):
z = self.args[1]
is_negative_integer = fuzzy_and([z.is_negative, z.is_integer])
return fuzzy_and([z.is_complex, fuzzy_not(is_negative_integer)])
def _eval_is_positive(self):
if self.args[0].is_positive and self.args[1].is_positive:
return self.args[0].is_odd
def _eval_is_negative(self):
if self.args[0].is_positive and self.args[1].is_positive:
return self.args[0].is_even
def _eval_aseries(self, n, args0, x, logx):
from sympy import Order
if args0[1] != oo or not \
(self.args[0].is_Integer and self.args[0].is_nonnegative):
return super()._eval_aseries(n, args0, x, logx)
z = self.args[1]
N = self.args[0]
if N == 0:
# digamma function series
# Abramowitz & Stegun, p. 259, 6.3.18
r = log(z) - 1/(2*z)
o = None
if n < 2:
o = Order(1/z, x)
else:
m = ceiling((n + 1)//2)
l = [bernoulli(2*k) / (2*k*z**(2*k)) for k in range(1, m)]
r -= Add(*l)
o = Order(1/z**(2*m), x)
return r._eval_nseries(x, n, logx) + o
else:
# proper polygamma function
# Abramowitz & Stegun, p. 260, 6.4.10
# We return terms to order higher than O(x**n) on purpose
# -- otherwise we would not be able to return any terms for
# quite a long time!
fac = gamma(N)
e0 = fac + N*fac/(2*z)
m = ceiling((n + 1)//2)
for k in range(1, m):
fac = fac*(2*k + N - 1)*(2*k + N - 2) / ((2*k)*(2*k - 1))
e0 += bernoulli(2*k)*fac/z**(2*k)
o = Order(1/z**(2*m), x)
if n == 0:
o = Order(1/z, x)
elif n == 1:
o = Order(1/z**2, x)
r = e0._eval_nseries(z, n, logx) + o
return (-1 * (-1/z)**N * r)._eval_nseries(x, n, logx)
@classmethod
def eval(cls, n, z):
n, z = map(sympify, (n, z))
from sympy import unpolarify
if n.is_integer:
if n.is_nonnegative:
nz = unpolarify(z)
if z != nz:
return polygamma(n, nz)
if n.is_positive:
if z is S.Half:
return (-1)**(n + 1)*factorial(n)*(2**(n + 1) - 1)*zeta(n + 1)
if n is S.NegativeOne:
return loggamma(z)
else:
if z.is_Number:
if z is S.NaN:
return S.NaN
elif z is S.Infinity:
if n.is_Number:
if n.is_zero:
return S.Infinity
else:
return S.Zero
if n.is_zero:
return S.Infinity
elif z.is_Integer:
if z.is_nonpositive:
return S.ComplexInfinity
else:
if n.is_zero:
return -S.EulerGamma + harmonic(z - 1, 1)
elif n.is_odd:
return (-1)**(n + 1)*factorial(n)*zeta(n + 1, z)
if n.is_zero:
if z is S.NaN:
return S.NaN
elif z.is_Rational:
p, q = z.as_numer_denom()
# only expand for small denominators to avoid creating long expressions
if q <= 5:
return expand_func(polygamma(S.Zero, z, evaluate=False))
elif z in (S.Infinity, S.NegativeInfinity):
return S.Infinity
else:
t = z.extract_multiplicatively(S.ImaginaryUnit)
if t in (S.Infinity, S.NegativeInfinity):
return S.Infinity
# TODO n == 1 also can do some rational z
def _eval_expand_func(self, **hints):
n, z = self.args
if n.is_Integer and n.is_nonnegative:
if z.is_Add:
coeff = z.args[0]
if coeff.is_Integer:
e = -(n + 1)
if coeff > 0:
tail = Add(*[Pow(
z - i, e) for i in range(1, int(coeff) + 1)])
else:
tail = -Add(*[Pow(
z + i, e) for i in range(0, int(-coeff))])
return polygamma(n, z - coeff) + (-1)**n*factorial(n)*tail
elif z.is_Mul:
coeff, z = z.as_two_terms()
if coeff.is_Integer and coeff.is_positive:
tail = [ polygamma(n, z + Rational(
i, coeff)) for i in range(0, int(coeff)) ]
if n == 0:
return Add(*tail)/coeff + log(coeff)
else:
return Add(*tail)/coeff**(n + 1)
z *= coeff
if n == 0 and z.is_Rational:
p, q = z.as_numer_denom()
# Reference:
# Values of the polygamma functions at rational arguments, J. Choi, 2007
part_1 = -S.EulerGamma - pi * cot(p * pi / q) / 2 - log(q) + Add(
*[cos(2 * k * pi * p / q) * log(2 * sin(k * pi / q)) for k in range(1, q)])
if z > 0:
n = floor(z)
z0 = z - n
return part_1 + Add(*[1 / (z0 + k) for k in range(n)])
elif z < 0:
n = floor(1 - z)
z0 = z + n
return part_1 - Add(*[1 / (z0 - 1 - k) for k in range(n)])
return polygamma(n, z)
def _eval_rewrite_as_zeta(self, n, z, **kwargs):
if n.is_integer:
if (n - S.One).is_nonnegative:
return (-1)**(n + 1)*factorial(n)*zeta(n + 1, z)
def _eval_rewrite_as_harmonic(self, n, z, **kwargs):
if n.is_integer:
if n.is_zero:
return harmonic(z - 1) - S.EulerGamma
else:
return S.NegativeOne**(n+1) * factorial(n) * (zeta(n+1) - harmonic(z-1, n+1))
def _eval_as_leading_term(self, x):
from sympy import Order
n, z = [a.as_leading_term(x) for a in self.args]
o = Order(z, x)
if n == 0 and o.contains(1/x):
return o.getn() * log(x)
else:
return self.func(n, z)
class loggamma(Function):
r"""
The ``loggamma`` function implements the logarithm of the
gamma function (i.e., $\log\Gamma(x)$).
Examples
========
Several special values are known. For numerical integral
arguments we have:
>>> from sympy import loggamma
>>> loggamma(-2)
oo
>>> loggamma(0)
oo
>>> loggamma(1)
0
>>> loggamma(2)
0
>>> loggamma(3)
log(2)
And for symbolic values:
>>> from sympy import Symbol
>>> n = Symbol("n", integer=True, positive=True)
>>> loggamma(n)
log(gamma(n))
>>> loggamma(-n)
oo
For half-integral values:
>>> from sympy import S
>>> loggamma(S(5)/2)
log(3*sqrt(pi)/4)
>>> loggamma(n/2)
log(2**(1 - n)*sqrt(pi)*gamma(n)/gamma(n/2 + 1/2))
And general rational arguments:
>>> from sympy import expand_func
>>> L = loggamma(S(16)/3)
>>> expand_func(L).doit()
-5*log(3) + loggamma(1/3) + log(4) + log(7) + log(10) + log(13)
>>> L = loggamma(S(19)/4)
>>> expand_func(L).doit()
-4*log(4) + loggamma(3/4) + log(3) + log(7) + log(11) + log(15)
>>> L = loggamma(S(23)/7)
>>> expand_func(L).doit()
-3*log(7) + log(2) + loggamma(2/7) + log(9) + log(16)
The ``loggamma`` function has the following limits towards infinity:
>>> from sympy import oo
>>> loggamma(oo)
oo
>>> loggamma(-oo)
zoo
The ``loggamma`` function obeys the mirror symmetry
if $x \in \mathbb{C} \setminus \{-\infty, 0\}$:
>>> from sympy.abc import x
>>> from sympy import conjugate
>>> conjugate(loggamma(x))
loggamma(conjugate(x))
Differentiation with respect to $x$ is supported:
>>> from sympy import diff
>>> diff(loggamma(x), x)
polygamma(0, x)
Series expansion is also supported:
>>> from sympy import series
>>> series(loggamma(x), x, 0, 4)
-log(x) - EulerGamma*x + pi**2*x**2/12 + x**3*polygamma(2, 1)/6 + O(x**4)
We can numerically evaluate the ``gamma`` function to arbitrary precision
on the whole complex plane:
>>> from sympy import I
>>> loggamma(5).evalf(30)
3.17805383034794561964694160130
>>> loggamma(I).evalf(20)
-0.65092319930185633889 - 1.8724366472624298171*I
See Also
========
gamma: Gamma function.
lowergamma: Lower incomplete gamma function.
uppergamma: Upper incomplete gamma function.
polygamma: Polygamma function.
digamma: Digamma function.
trigamma: Trigamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Gamma_function
.. [2] http://dlmf.nist.gov/5
.. [3] http://mathworld.wolfram.com/LogGammaFunction.html
.. [4] http://functions.wolfram.com/GammaBetaErf/LogGamma/
"""
@classmethod
def eval(cls, z):
z = sympify(z)
if z.is_integer:
if z.is_nonpositive:
return S.Infinity
elif z.is_positive:
return log(gamma(z))
elif z.is_rational:
p, q = z.as_numer_denom()
# Half-integral values:
if p.is_positive and q == 2:
return log(sqrt(S.Pi) * 2**(1 - p) * gamma(p) / gamma((p + 1)*S.Half))
if z is S.Infinity:
return S.Infinity
elif abs(z) is S.Infinity:
return S.ComplexInfinity
if z is S.NaN:
return S.NaN
def _eval_expand_func(self, **hints):
from sympy import Sum
z = self.args[0]
if z.is_Rational:
p, q = z.as_numer_denom()
# General rational arguments (u + p/q)
# Split z as n + p/q with p < q
n = p // q
p = p - n*q
if p.is_positive and q.is_positive and p < q:
k = Dummy("k")
if n.is_positive:
return loggamma(p / q) - n*log(q) + Sum(log((k - 1)*q + p), (k, 1, n))
elif n.is_negative:
return loggamma(p / q) - n*log(q) + S.Pi*S.ImaginaryUnit*n - Sum(log(k*q - p), (k, 1, -n))
elif n.is_zero:
return loggamma(p / q)
return self
def _eval_nseries(self, x, n, logx=None):
x0 = self.args[0].limit(x, 0)
if x0.is_zero:
f = self._eval_rewrite_as_intractable(*self.args)
return f._eval_nseries(x, n, logx)
return super()._eval_nseries(x, n, logx)
def _eval_aseries(self, n, args0, x, logx):
from sympy import Order
if args0[0] != oo:
return super()._eval_aseries(n, args0, x, logx)
z = self.args[0]
m = min(n, ceiling((n + S.One)/2))
r = log(z)*(z - S.Half) - z + log(2*pi)/2
l = [bernoulli(2*k) / (2*k*(2*k - 1)*z**(2*k - 1)) for k in range(1, m)]
o = None
if m == 0:
o = Order(1, x)
else:
o = Order(1/z**(2*m - 1), x)
# It is very inefficient to first add the order and then do the nseries
return (r + Add(*l))._eval_nseries(x, n, logx) + o
def _eval_rewrite_as_intractable(self, z, **kwargs):
return log(gamma(z))
def _eval_is_real(self):
z = self.args[0]
if z.is_positive:
return True
elif z.is_nonpositive:
return False
def _eval_conjugate(self):
z = self.args[0]
if not z in (S.Zero, S.NegativeInfinity):
return self.func(z.conjugate())
def fdiff(self, argindex=1):
if argindex == 1:
return polygamma(0, self.args[0])
else:
raise ArgumentIndexError(self, argindex)
def _sage_(self):
import sage.all as sage
return sage.log_gamma(self.args[0]._sage_())
class digamma(Function):
r"""
The ``digamma`` function is the first derivative of the ``loggamma``
function
.. math::
\psi(x) := \frac{\mathrm{d}}{\mathrm{d} z} \log\Gamma(z)
= \frac{\Gamma'(z)}{\Gamma(z) }.
In this case, ``digamma(z) = polygamma(0, z)``.
Examples
========
>>> from sympy import digamma
>>> digamma(0)
zoo
>>> from sympy import Symbol
>>> z = Symbol('z')
>>> digamma(z)
polygamma(0, z)
To retain ``digamma`` as it is:
>>> digamma(0, evaluate=False)
digamma(0)
>>> digamma(z, evaluate=False)
digamma(z)
See Also
========
gamma: Gamma function.
lowergamma: Lower incomplete gamma function.
uppergamma: Upper incomplete gamma function.
polygamma: Polygamma function.
loggamma: Log Gamma function.
trigamma: Trigamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Digamma_function
.. [2] http://mathworld.wolfram.com/DigammaFunction.html
.. [3] http://functions.wolfram.com/GammaBetaErf/PolyGamma2/
"""
def _eval_evalf(self, prec):
z = self.args[0]
return polygamma(0, z).evalf(prec)
def fdiff(self, argindex=1):
z = self.args[0]
return polygamma(0, z).fdiff()
def _eval_is_real(self):
z = self.args[0]
return polygamma(0, z).is_real
def _eval_is_positive(self):
z = self.args[0]
return polygamma(0, z).is_positive
def _eval_is_negative(self):
z = self.args[0]
return polygamma(0, z).is_negative
def _eval_aseries(self, n, args0, x, logx):
as_polygamma = self.rewrite(polygamma)
args0 = [S.Zero,] + args0
return as_polygamma._eval_aseries(n, args0, x, logx)
@classmethod
def eval(cls, z):
return polygamma(0, z)
def _eval_expand_func(self, **hints):
z = self.args[0]
return polygamma(0, z).expand(func=True)
def _eval_rewrite_as_harmonic(self, z, **kwargs):
return harmonic(z - 1) - S.EulerGamma
def _eval_rewrite_as_polygamma(self, z, **kwargs):
return polygamma(0, z)
def _eval_as_leading_term(self, x):
z = self.args[0]
return polygamma(0, z).as_leading_term(x)
class trigamma(Function):
r"""
The ``trigamma`` function is the second derivative of the ``loggamma``
function
.. math::
\psi^{(1)}(z) := \frac{\mathrm{d}^{2}}{\mathrm{d} z^{2}} \log\Gamma(z).
In this case, ``trigamma(z) = polygamma(1, z)``.
Examples
========
>>> from sympy import trigamma
>>> trigamma(0)
zoo
>>> from sympy import Symbol
>>> z = Symbol('z')
>>> trigamma(z)
polygamma(1, z)
To retain ``trigamma`` as it is:
>>> trigamma(0, evaluate=False)
trigamma(0)
>>> trigamma(z, evaluate=False)
trigamma(z)
See Also
========
gamma: Gamma function.
lowergamma: Lower incomplete gamma function.
uppergamma: Upper incomplete gamma function.
polygamma: Polygamma function.
loggamma: Log Gamma function.
digamma: Digamma function.
beta: Euler Beta function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigamma_function
.. [2] http://mathworld.wolfram.com/TrigammaFunction.html
.. [3] http://functions.wolfram.com/GammaBetaErf/PolyGamma2/
"""
def _eval_evalf(self, prec):
z = self.args[0]
return polygamma(1, z).evalf(prec)
def fdiff(self, argindex=1):
z = self.args[0]
return polygamma(1, z).fdiff()
def _eval_is_real(self):
z = self.args[0]
return polygamma(1, z).is_real
def _eval_is_positive(self):
z = self.args[0]
return polygamma(1, z).is_positive
def _eval_is_negative(self):
z = self.args[0]
return polygamma(1, z).is_negative
def _eval_aseries(self, n, args0, x, logx):
as_polygamma = self.rewrite(polygamma)
args0 = [S.One,] + args0
return as_polygamma._eval_aseries(n, args0, x, logx)
@classmethod
def eval(cls, z):
return polygamma(1, z)
def _eval_expand_func(self, **hints):
z = self.args[0]
return polygamma(1, z).expand(func=True)
def _eval_rewrite_as_zeta(self, z, **kwargs):
return zeta(2, z)
def _eval_rewrite_as_polygamma(self, z, **kwargs):
return polygamma(1, z)
def _eval_rewrite_as_harmonic(self, z, **kwargs):
return -harmonic(z - 1, 2) + S.Pi**2 / 6
def _eval_as_leading_term(self, x):
z = self.args[0]
return polygamma(1, z).as_leading_term(x)
###############################################################################
##################### COMPLETE MULTIVARIATE GAMMA FUNCTION ####################
###############################################################################
class multigamma(Function):
r"""
The multivariate gamma function is a generalization of the gamma function
.. math::
\Gamma_p(z) = \pi^{p(p-1)/4}\prod_{k=1}^p \Gamma[z + (1 - k)/2].
In a special case, ``multigamma(x, 1) = gamma(x)``.
Examples
========
>>> from sympy import S, multigamma
>>> from sympy import Symbol
>>> x = Symbol('x')
>>> p = Symbol('p', positive=True, integer=True)
>>> multigamma(x, p)
pi**(p*(p - 1)/4)*Product(gamma(-_k/2 + x + 1/2), (_k, 1, p))
Several special values are known:
>>> multigamma(1, 1)
1
>>> multigamma(4, 1)
6
>>> multigamma(S(3)/2, 1)
sqrt(pi)/2
Writing ``multigamma`` in terms of the ``gamma`` function:
>>> multigamma(x, 1)
gamma(x)
>>> multigamma(x, 2)
sqrt(pi)*gamma(x)*gamma(x - 1/2)
>>> multigamma(x, 3)
pi**(3/2)*gamma(x)*gamma(x - 1)*gamma(x - 1/2)
Parameters
==========
p : order or dimension of the multivariate gamma function
See Also
========
gamma, lowergamma, uppergamma, polygamma, loggamma, digamma, trigamma,
beta
References
==========
.. [1] https://en.wikipedia.org/wiki/Multivariate_gamma_function
"""
unbranched = True
def fdiff(self, argindex=2):
from sympy import Sum
if argindex == 2:
x, p = self.args
k = Dummy("k")
return self.func(x, p)*Sum(polygamma(0, x + (1 - k)/2), (k, 1, p))
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, x, p):
from sympy import Product
x, p = map(sympify, (x, p))
if p.is_positive is False or p.is_integer is False:
raise ValueError('Order parameter p must be positive integer.')
k = Dummy("k")
return (pi**(p*(p - 1)/4)*Product(gamma(x + (1 - k)/2),
(k, 1, p))).doit()
def _eval_conjugate(self):
x, p = self.args
return self.func(x.conjugate(), p)
def _eval_is_real(self):
x, p = self.args
y = 2*x
if y.is_integer and (y <= (p - 1)) is True:
return False
if intlike(y) and (y <= (p - 1)):
return False
if y > (p - 1) or y.is_noninteger:
return True
|
fc1d4df566d639518827ede391a7c25aacfe25a7c24a98597151d1842e134dfc | from sympy.core import S, sympify, diff
from sympy.core.decorators import deprecated
from sympy.core.function import Function, ArgumentIndexError
from sympy.core.logic import fuzzy_not
from sympy.core.relational import Eq, Ne
from sympy.functions.elementary.complexes import im, sign
from sympy.functions.elementary.piecewise import Piecewise
from sympy.polys.polyerrors import PolynomialError
from sympy.utilities import filldedent
###############################################################################
################################ DELTA FUNCTION ###############################
###############################################################################
class DiracDelta(Function):
r"""
The DiracDelta function and its derivatives.
Explanation
===========
DiracDelta is not an ordinary function. It can be rigorously defined either
as a distribution or as a measure.
DiracDelta only makes sense in definite integrals, and in particular,
integrals of the form ``Integral(f(x)*DiracDelta(x - x0), (x, a, b))``,
where it equals ``f(x0)`` if ``a <= x0 <= b`` and ``0`` otherwise. Formally,
DiracDelta acts in some ways like a function that is ``0`` everywhere except
at ``0``, but in many ways it also does not. It can often be useful to treat
DiracDelta in formal ways, building up and manipulating expressions with
delta functions (which may eventually be integrated), but care must be taken
to not treat it as a real function. SymPy's ``oo`` is similar. It only
truly makes sense formally in certain contexts (such as integration limits),
but SymPy allows its use everywhere, and it tries to be consistent with
operations on it (like ``1/oo``), but it is easy to get into trouble and get
wrong results if ``oo`` is treated too much like a number. Similarly, if
DiracDelta is treated too much like a function, it is easy to get wrong or
nonsensical results.
DiracDelta function has the following properties:
1) $\frac{d}{d x} \theta(x) = \delta(x)$
2) $\int_{-\infty}^\infty \delta(x - a)f(x)\, dx = f(a)$ and $\int_{a-
\epsilon}^{a+\epsilon} \delta(x - a)f(x)\, dx = f(a)$
3) $\delta(x) = 0$ for all $x \neq 0$
4) $\delta(g(x)) = \sum_i \frac{\delta(x - x_i)}{\|g'(x_i)\|}$ where $x_i$
are the roots of $g$
5) $\delta(-x) = \delta(x)$
Derivatives of ``k``-th order of DiracDelta have the following properties:
6) $\delta(x, k) = 0$ for all $x \neq 0$
7) $\delta(-x, k) = -\delta(x, k)$ for odd $k$
8) $\delta(-x, k) = \delta(x, k)$ for even $k$
Examples
========
>>> from sympy import DiracDelta, diff, pi
>>> from sympy.abc import x, y
>>> DiracDelta(x)
DiracDelta(x)
>>> DiracDelta(1)
0
>>> DiracDelta(-1)
0
>>> DiracDelta(pi)
0
>>> DiracDelta(x - 4).subs(x, 4)
DiracDelta(0)
>>> diff(DiracDelta(x))
DiracDelta(x, 1)
>>> diff(DiracDelta(x - 1),x,2)
DiracDelta(x - 1, 2)
>>> diff(DiracDelta(x**2 - 1),x,2)
2*(2*x**2*DiracDelta(x**2 - 1, 2) + DiracDelta(x**2 - 1, 1))
>>> DiracDelta(3*x).is_simple(x)
True
>>> DiracDelta(x**2).is_simple(x)
False
>>> DiracDelta((x**2 - 1)*y).expand(diracdelta=True, wrt=x)
DiracDelta(x - 1)/(2*Abs(y)) + DiracDelta(x + 1)/(2*Abs(y))
See Also
========
Heaviside
sympy.simplify.simplify.simplify, is_simple
sympy.functions.special.tensor_functions.KroneckerDelta
References
==========
.. [1] http://mathworld.wolfram.com/DeltaFunction.html
"""
is_real = True
def fdiff(self, argindex=1):
"""
Returns the first derivative of a DiracDelta Function.
Explanation
===========
The difference between ``diff()`` and ``fdiff()`` is: ``diff()`` is the
user-level function and ``fdiff()`` is an object method. ``fdiff()`` is
a convenience method available in the ``Function`` class. It returns
the derivative of the function without considering the chain rule.
``diff(function, x)`` calls ``Function._eval_derivative`` which in turn
calls ``fdiff()`` internally to compute the derivative of the function.
Examples
========
>>> from sympy import DiracDelta, diff
>>> from sympy.abc import x
>>> DiracDelta(x).fdiff()
DiracDelta(x, 1)
>>> DiracDelta(x, 1).fdiff()
DiracDelta(x, 2)
>>> DiracDelta(x**2 - 1).fdiff()
DiracDelta(x**2 - 1, 1)
>>> diff(DiracDelta(x, 1)).fdiff()
DiracDelta(x, 3)
"""
if argindex == 1:
#I didn't know if there is a better way to handle default arguments
k = 0
if len(self.args) > 1:
k = self.args[1]
return self.func(self.args[0], k + 1)
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, arg, k=0):
"""
Returns a simplified form or a value of DiracDelta depending on the
argument passed by the DiracDelta object.
Explanation
===========
The ``eval()`` method is automatically called when the ``DiracDelta``
class is about to be instantiated and it returns either some simplified
instance or the unevaluated instance depending on the argument passed.
In other words, ``eval()`` method is not needed to be called explicitly,
it is being called and evaluated once the object is called.
Examples
========
>>> from sympy import DiracDelta, S
>>> from sympy.abc import x
>>> DiracDelta(x)
DiracDelta(x)
>>> DiracDelta(-x, 1)
-DiracDelta(x, 1)
>>> DiracDelta(1)
0
>>> DiracDelta(5, 1)
0
>>> DiracDelta(0)
DiracDelta(0)
>>> DiracDelta(-1)
0
>>> DiracDelta(S.NaN)
nan
>>> DiracDelta(x).eval(1)
0
>>> DiracDelta(x - 100).subs(x, 5)
0
>>> DiracDelta(x - 100).subs(x, 100)
DiracDelta(0)
"""
k = sympify(k)
if not k.is_Integer or k.is_negative:
raise ValueError("Error: the second argument of DiracDelta must be \
a non-negative integer, %s given instead." % (k,))
arg = sympify(arg)
if arg is S.NaN:
return S.NaN
if arg.is_nonzero:
return S.Zero
if fuzzy_not(im(arg).is_zero):
raise ValueError(filldedent('''
Function defined only for Real Values.
Complex part: %s found in %s .''' % (
repr(im(arg)), repr(arg))))
c, nc = arg.args_cnc()
if c and c[0] is S.NegativeOne:
# keep this fast and simple instead of using
# could_extract_minus_sign
if k.is_odd:
return -cls(-arg, k)
elif k.is_even:
return cls(-arg, k) if k else cls(-arg)
@deprecated(useinstead="expand(diracdelta=True, wrt=x)", issue=12859, deprecated_since_version="1.1")
def simplify(self, x, **kwargs):
return self.expand(diracdelta=True, wrt=x)
def _eval_expand_diracdelta(self, **hints):
"""
Compute a simplified representation of the function using
property number 4. Pass ``wrt`` as a hint to expand the expression
with respect to a particular variable.
Explanation
===========
``wrt`` is:
- a variable with respect to which a DiracDelta expression will
get expanded.
Examples
========
>>> from sympy import DiracDelta
>>> from sympy.abc import x, y
>>> DiracDelta(x*y).expand(diracdelta=True, wrt=x)
DiracDelta(x)/Abs(y)
>>> DiracDelta(x*y).expand(diracdelta=True, wrt=y)
DiracDelta(y)/Abs(x)
>>> DiracDelta(x**2 + x - 2).expand(diracdelta=True, wrt=x)
DiracDelta(x - 1)/3 + DiracDelta(x + 2)/3
See Also
========
is_simple, Diracdelta
"""
from sympy.polys.polyroots import roots
wrt = hints.get('wrt', None)
if wrt is None:
free = self.free_symbols
if len(free) == 1:
wrt = free.pop()
else:
raise TypeError(filldedent('''
When there is more than 1 free symbol or variable in the expression,
the 'wrt' keyword is required as a hint to expand when using the
DiracDelta hint.'''))
if not self.args[0].has(wrt) or (len(self.args) > 1 and self.args[1] != 0 ):
return self
try:
argroots = roots(self.args[0], wrt)
result = 0
valid = True
darg = abs(diff(self.args[0], wrt))
for r, m in argroots.items():
if r.is_real is not False and m == 1:
result += self.func(wrt - r)/darg.subs(wrt, r)
else:
# don't handle non-real and if m != 1 then
# a polynomial will have a zero in the derivative (darg)
# at r
valid = False
break
if valid:
return result
except PolynomialError:
pass
return self
def is_simple(self, x):
"""
Tells whether the argument(args[0]) of DiracDelta is a linear
expression in *x*.
Examples
========
>>> from sympy import DiracDelta, cos
>>> from sympy.abc import x, y
>>> DiracDelta(x*y).is_simple(x)
True
>>> DiracDelta(x*y).is_simple(y)
True
>>> DiracDelta(x**2 + x - 2).is_simple(x)
False
>>> DiracDelta(cos(x)).is_simple(x)
False
Parameters
==========
x : can be a symbol
See Also
========
sympy.simplify.simplify.simplify, DiracDelta
"""
p = self.args[0].as_poly(x)
if p:
return p.degree() == 1
return False
def _eval_rewrite_as_Piecewise(self, *args, **kwargs):
"""
Represents DiracDelta in a piecewise form.
Examples
========
>>> from sympy import DiracDelta, Piecewise, Symbol
>>> x = Symbol('x')
>>> DiracDelta(x).rewrite(Piecewise)
Piecewise((DiracDelta(0), Eq(x, 0)), (0, True))
>>> DiracDelta(x - 5).rewrite(Piecewise)
Piecewise((DiracDelta(0), Eq(x - 5, 0)), (0, True))
>>> DiracDelta(x**2 - 5).rewrite(Piecewise)
Piecewise((DiracDelta(0), Eq(x**2 - 5, 0)), (0, True))
>>> DiracDelta(x - 5, 4).rewrite(Piecewise)
DiracDelta(x - 5, 4)
"""
if len(args) == 1:
return Piecewise((DiracDelta(0), Eq(args[0], 0)), (0, True))
def _eval_rewrite_as_SingularityFunction(self, *args, **kwargs):
"""
Returns the DiracDelta expression written in the form of Singularity
Functions.
"""
from sympy.solvers import solve
from sympy.functions import SingularityFunction
if self == DiracDelta(0):
return SingularityFunction(0, 0, -1)
if self == DiracDelta(0, 1):
return SingularityFunction(0, 0, -2)
free = self.free_symbols
if len(free) == 1:
x = (free.pop())
if len(args) == 1:
return SingularityFunction(x, solve(args[0], x)[0], -1)
return SingularityFunction(x, solve(args[0], x)[0], -args[1] - 1)
else:
# I don't know how to handle the case for DiracDelta expressions
# having arguments with more than one variable.
raise TypeError(filldedent('''
rewrite(SingularityFunction) doesn't support
arguments with more that 1 variable.'''))
def _sage_(self):
import sage.all as sage
return sage.dirac_delta(self.args[0]._sage_())
###############################################################################
############################## HEAVISIDE FUNCTION #############################
###############################################################################
class Heaviside(Function):
r"""
Heaviside Piecewise function.
Explanation
===========
Heaviside function has the following properties:
1) $\frac{d}{d x} \theta(x) = \delta(x)$
2) $\theta(x) = \begin{cases} 0 & \text{for}\: x < 0 \\ \text{undefined} &
\text{for}\: x = 0 \\1 & \text{for}\: x > 0 \end{cases}$
3) $\frac{d}{d x} \max(x, 0) = \theta(x)$
Heaviside(x) is printed as $\theta(x)$ with the SymPy LaTeX printer.
Regarding to the value at 0, Mathematica defines $\theta(0)=1$, but Maple
uses $\theta(0) = \text{undefined}$. Different application areas may have
specific conventions. For example, in control theory, it is common practice
to assume $\theta(0) = 0$ to match the Laplace transform of a DiracDelta
distribution.
To specify the value of Heaviside at ``x=0``, a second argument can be
given. Omit this 2nd argument or pass ``None`` to recover the default
behavior.
Examples
========
>>> from sympy import Heaviside, S
>>> from sympy.abc import x
>>> Heaviside(9)
1
>>> Heaviside(-9)
0
>>> Heaviside(0)
Heaviside(0)
>>> Heaviside(0, S.Half)
1/2
>>> (Heaviside(x) + 1).replace(Heaviside(x), Heaviside(x, 1))
Heaviside(x, 1) + 1
See Also
========
DiracDelta
References
==========
.. [1] http://mathworld.wolfram.com/HeavisideStepFunction.html
.. [2] http://dlmf.nist.gov/1.16#iv
"""
is_real = True
def fdiff(self, argindex=1):
"""
Returns the first derivative of a Heaviside Function.
Examples
========
>>> from sympy import Heaviside, diff
>>> from sympy.abc import x
>>> Heaviside(x).fdiff()
DiracDelta(x)
>>> Heaviside(x**2 - 1).fdiff()
DiracDelta(x**2 - 1)
>>> diff(Heaviside(x)).fdiff()
DiracDelta(x, 1)
"""
if argindex == 1:
# property number 1
return DiracDelta(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
def __new__(cls, arg, H0=None, **options):
if isinstance(H0, Heaviside) and len(H0.args) == 1:
H0 = None
if H0 is None:
return super(cls, cls).__new__(cls, arg, **options)
return super(cls, cls).__new__(cls, arg, H0, **options)
@classmethod
def eval(cls, arg, H0=None):
"""
Returns a simplified form or a value of Heaviside depending on the
argument passed by the Heaviside object.
Explanation
===========
The ``eval()`` method is automatically called when the ``Heaviside``
class is about to be instantiated and it returns either some simplified
instance or the unevaluated instance depending on the argument passed.
In other words, ``eval()`` method is not needed to be called explicitly,
it is being called and evaluated once the object is called.
Examples
========
>>> from sympy import Heaviside, S
>>> from sympy.abc import x
>>> Heaviside(x)
Heaviside(x)
>>> Heaviside(19)
1
>>> Heaviside(0)
Heaviside(0)
>>> Heaviside(0, 1)
1
>>> Heaviside(-5)
0
>>> Heaviside(S.NaN)
nan
>>> Heaviside(x).eval(100)
1
>>> Heaviside(x - 100).subs(x, 5)
0
>>> Heaviside(x - 100).subs(x, 105)
1
"""
H0 = sympify(H0)
arg = sympify(arg)
if arg.is_extended_negative:
return S.Zero
elif arg.is_extended_positive:
return S.One
elif arg.is_zero:
return H0
elif arg is S.NaN:
return S.NaN
elif fuzzy_not(im(arg).is_zero):
raise ValueError("Function defined only for Real Values. Complex part: %s found in %s ." % (repr(im(arg)), repr(arg)) )
def _eval_rewrite_as_Piecewise(self, arg, H0=None, **kwargs):
"""
Represents Heaviside in a Piecewise form.
Examples
========
>>> from sympy import Heaviside, Piecewise, Symbol
>>> x = Symbol('x')
>>> Heaviside(x).rewrite(Piecewise)
Piecewise((0, x < 0), (Heaviside(0), Eq(x, 0)), (1, x > 0))
>>> Heaviside(x - 5).rewrite(Piecewise)
Piecewise((0, x - 5 < 0), (Heaviside(0), Eq(x - 5, 0)), (1, x - 5 > 0))
>>> Heaviside(x**2 - 1).rewrite(Piecewise)
Piecewise((0, x**2 - 1 < 0), (Heaviside(0), Eq(x**2 - 1, 0)), (1, x**2 - 1 > 0))
"""
if H0 is None:
return Piecewise((0, arg < 0), (Heaviside(0), Eq(arg, 0)), (1, arg > 0))
if H0 == 0:
return Piecewise((0, arg <= 0), (1, arg > 0))
if H0 == 1:
return Piecewise((0, arg < 0), (1, arg >= 0))
return Piecewise((0, arg < 0), (H0, Eq(arg, 0)), (1, arg > 0))
def _eval_rewrite_as_sign(self, arg, H0=None, **kwargs):
"""
Represents the Heaviside function in the form of sign function.
Explanation
===========
The value of the second argument of Heaviside must specify Heaviside(0)
= 1/2 for rewritting as sign to be strictly equivalent. For easier
usage, we also allow this rewriting when Heaviside(0) is undefined.
Examples
========
>>> from sympy import Heaviside, Symbol, sign, S
>>> x = Symbol('x', real=True)
>>> Heaviside(x, H0=S.Half).rewrite(sign)
sign(x)/2 + 1/2
>>> Heaviside(x, 0).rewrite(sign)
Piecewise((sign(x)/2 + 1/2, Ne(x, 0)), (0, True))
>>> Heaviside(x - 2, H0=S.Half).rewrite(sign)
sign(x - 2)/2 + 1/2
>>> Heaviside(x**2 - 2*x + 1, H0=S.Half).rewrite(sign)
sign(x**2 - 2*x + 1)/2 + 1/2
>>> y = Symbol('y')
>>> Heaviside(y).rewrite(sign)
Heaviside(y)
>>> Heaviside(y**2 - 2*y + 1).rewrite(sign)
Heaviside(y**2 - 2*y + 1)
See Also
========
sign
"""
if arg.is_extended_real:
pw1 = Piecewise(
((sign(arg) + 1)/2, Ne(arg, 0)),
(Heaviside(0, H0=H0), True))
pw2 = Piecewise(
((sign(arg) + 1)/2, Eq(Heaviside(0, H0=H0), S(1)/2)),
(pw1, True))
return pw2
def _eval_rewrite_as_SingularityFunction(self, args, **kwargs):
"""
Returns the Heaviside expression written in the form of Singularity
Functions.
"""
from sympy.solvers import solve
from sympy.functions import SingularityFunction
if self == Heaviside(0):
return SingularityFunction(0, 0, 0)
free = self.free_symbols
if len(free) == 1:
x = (free.pop())
return SingularityFunction(x, solve(args, x)[0], 0)
# TODO
# ((x - 5)**3*Heaviside(x - 5)).rewrite(SingularityFunction) should output
# SingularityFunction(x, 5, 0) instead of (x - 5)**3*SingularityFunction(x, 5, 0)
else:
# I don't know how to handle the case for Heaviside expressions
# having arguments with more than one variable.
raise TypeError(filldedent('''
rewrite(SingularityFunction) doesn't
support arguments with more that 1 variable.'''))
def _sage_(self):
import sage.all as sage
return sage.heaviside(self.args[0]._sage_())
|
1d6c516bdc9bdb340b7a8b47cbcff746eae4c17b1e3568e0a598a48642d0ff7d | from functools import wraps
from sympy import S, pi, I, Rational, Wild, cacheit, sympify
from sympy.core.function import Function, ArgumentIndexError
from sympy.core.power import Pow
from sympy.functions.combinatorial.factorials import factorial
from sympy.functions.elementary.trigonometric import sin, cos, csc, cot
from sympy.functions.elementary.complexes import Abs
from sympy.functions.elementary.miscellaneous import sqrt, root
from sympy.functions.elementary.complexes import re, im
from sympy.functions.special.gamma_functions import gamma
from sympy.functions.special.hyper import hyper
from sympy.polys.orthopolys import spherical_bessel_fn as fn
# TODO
# o Scorer functions G1 and G2
# o Asymptotic expansions
# These are possible, e.g. for fixed order, but since the bessel type
# functions are oscillatory they are not actually tractable at
# infinity, so this is not particularly useful right now.
# o Series Expansions for functions of the second kind about zero
# o Nicer series expansions.
# o More rewriting.
# o Add solvers to ode.py (or rather add solvers for the hypergeometric equation).
class BesselBase(Function):
"""
Abstract base class for Bessel-type functions.
This class is meant to reduce code duplication.
All Bessel-type functions can 1) be differentiated, with the derivatives
expressed in terms of similar functions, and 2) be rewritten in terms
of other Bessel-type functions.
Here, Bessel-type functions are assumed to have one complex parameter.
To use this base class, define class attributes ``_a`` and ``_b`` such that
``2*F_n' = -_a*F_{n+1} + b*F_{n-1}``.
"""
@property
def order(self):
""" The order of the Bessel-type function. """
return self.args[0]
@property
def argument(self):
""" The argument of the Bessel-type function. """
return self.args[1]
@classmethod
def eval(cls, nu, z):
return
def fdiff(self, argindex=2):
if argindex != 2:
raise ArgumentIndexError(self, argindex)
return (self._b/2 * self.__class__(self.order - 1, self.argument) -
self._a/2 * self.__class__(self.order + 1, self.argument))
def _eval_conjugate(self):
z = self.argument
if z.is_extended_negative is False:
return self.__class__(self.order.conjugate(), z.conjugate())
def _eval_expand_func(self, **hints):
nu, z, f = self.order, self.argument, self.__class__
if nu.is_extended_real:
if (nu - 1).is_extended_positive:
return (-self._a*self._b*f(nu - 2, z)._eval_expand_func() +
2*self._a*(nu - 1)*f(nu - 1, z)._eval_expand_func()/z)
elif (nu + 1).is_extended_negative:
return (2*self._b*(nu + 1)*f(nu + 1, z)._eval_expand_func()/z -
self._a*self._b*f(nu + 2, z)._eval_expand_func())
return self
def _eval_simplify(self, **kwargs):
from sympy.simplify.simplify import besselsimp
return besselsimp(self)
class besselj(BesselBase):
r"""
Bessel function of the first kind.
Explanation
===========
The Bessel $J$ function of order $\nu$ is defined to be the function
satisfying Bessel's differential equation
.. math ::
z^2 \frac{\mathrm{d}^2 w}{\mathrm{d}z^2}
+ z \frac{\mathrm{d}w}{\mathrm{d}z} + (z^2 - \nu^2) w = 0,
with Laurent expansion
.. math ::
J_\nu(z) = z^\nu \left(\frac{1}{\Gamma(\nu + 1) 2^\nu} + O(z^2) \right),
if $\nu$ is not a negative integer. If $\nu=-n \in \mathbb{Z}_{<0}$
*is* a negative integer, then the definition is
.. math ::
J_{-n}(z) = (-1)^n J_n(z).
Examples
========
Create a Bessel function object:
>>> from sympy import besselj, jn
>>> from sympy.abc import z, n
>>> b = besselj(n, z)
Differentiate it:
>>> b.diff(z)
besselj(n - 1, z)/2 - besselj(n + 1, z)/2
Rewrite in terms of spherical Bessel functions:
>>> b.rewrite(jn)
sqrt(2)*sqrt(z)*jn(n - 1/2, z)/sqrt(pi)
Access the parameter and argument:
>>> b.order
n
>>> b.argument
z
See Also
========
bessely, besseli, besselk
References
==========
.. [1] Abramowitz, Milton; Stegun, Irene A., eds. (1965), "Chapter 9",
Handbook of Mathematical Functions with Formulas, Graphs, and
Mathematical Tables
.. [2] Luke, Y. L. (1969), The Special Functions and Their
Approximations, Volume 1
.. [3] https://en.wikipedia.org/wiki/Bessel_function
.. [4] http://functions.wolfram.com/Bessel-TypeFunctions/BesselJ/
"""
_a = S.One
_b = S.One
@classmethod
def eval(cls, nu, z):
if z.is_zero:
if nu.is_zero:
return S.One
elif (nu.is_integer and nu.is_zero is False) or re(nu).is_positive:
return S.Zero
elif re(nu).is_negative and not (nu.is_integer is True):
return S.ComplexInfinity
elif nu.is_imaginary:
return S.NaN
if z is S.Infinity or (z is S.NegativeInfinity):
return S.Zero
if z.could_extract_minus_sign():
return (z)**nu*(-z)**(-nu)*besselj(nu, -z)
if nu.is_integer:
if nu.could_extract_minus_sign():
return S.NegativeOne**(-nu)*besselj(-nu, z)
newz = z.extract_multiplicatively(I)
if newz: # NOTE we don't want to change the function if z==0
return I**(nu)*besseli(nu, newz)
# branch handling:
from sympy import unpolarify, exp
if nu.is_integer:
newz = unpolarify(z)
if newz != z:
return besselj(nu, newz)
else:
newz, n = z.extract_branch_factor()
if n != 0:
return exp(2*n*pi*nu*I)*besselj(nu, newz)
nnu = unpolarify(nu)
if nu != nnu:
return besselj(nnu, z)
def _eval_rewrite_as_besseli(self, nu, z, **kwargs):
from sympy import polar_lift, exp
return exp(I*pi*nu/2)*besseli(nu, polar_lift(-I)*z)
def _eval_rewrite_as_bessely(self, nu, z, **kwargs):
if nu.is_integer is False:
return csc(pi*nu)*bessely(-nu, z) - cot(pi*nu)*bessely(nu, z)
def _eval_rewrite_as_jn(self, nu, z, **kwargs):
return sqrt(2*z/pi)*jn(nu - S.Half, self.argument)
def _eval_is_extended_real(self):
nu, z = self.args
if nu.is_integer and z.is_extended_real:
return True
def _sage_(self):
import sage.all as sage
return sage.bessel_J(self.args[0]._sage_(), self.args[1]._sage_())
class bessely(BesselBase):
r"""
Bessel function of the second kind.
Explanation
===========
The Bessel $Y$ function of order $\nu$ is defined as
.. math ::
Y_\nu(z) = \lim_{\mu \to \nu} \frac{J_\mu(z) \cos(\pi \mu)
- J_{-\mu}(z)}{\sin(\pi \mu)},
where $J_\mu(z)$ is the Bessel function of the first kind.
It is a solution to Bessel's equation, and linearly independent from
$J_\nu$.
Examples
========
>>> from sympy import bessely, yn
>>> from sympy.abc import z, n
>>> b = bessely(n, z)
>>> b.diff(z)
bessely(n - 1, z)/2 - bessely(n + 1, z)/2
>>> b.rewrite(yn)
sqrt(2)*sqrt(z)*yn(n - 1/2, z)/sqrt(pi)
See Also
========
besselj, besseli, besselk
References
==========
.. [1] http://functions.wolfram.com/Bessel-TypeFunctions/BesselY/
"""
_a = S.One
_b = S.One
@classmethod
def eval(cls, nu, z):
if z.is_zero:
if nu.is_zero:
return S.NegativeInfinity
elif re(nu).is_zero is False:
return S.ComplexInfinity
elif re(nu).is_zero:
return S.NaN
if z is S.Infinity or z is S.NegativeInfinity:
return S.Zero
if nu.is_integer:
if nu.could_extract_minus_sign():
return S.NegativeOne**(-nu)*bessely(-nu, z)
def _eval_rewrite_as_besselj(self, nu, z, **kwargs):
if nu.is_integer is False:
return csc(pi*nu)*(cos(pi*nu)*besselj(nu, z) - besselj(-nu, z))
def _eval_rewrite_as_besseli(self, nu, z, **kwargs):
aj = self._eval_rewrite_as_besselj(*self.args)
if aj:
return aj.rewrite(besseli)
def _eval_rewrite_as_yn(self, nu, z, **kwargs):
return sqrt(2*z/pi) * yn(nu - S.Half, self.argument)
def _eval_is_extended_real(self):
nu, z = self.args
if nu.is_integer and z.is_positive:
return True
def _sage_(self):
import sage.all as sage
return sage.bessel_Y(self.args[0]._sage_(), self.args[1]._sage_())
class besseli(BesselBase):
r"""
Modified Bessel function of the first kind.
Explanation
===========
The Bessel $I$ function is a solution to the modified Bessel equation
.. math ::
z^2 \frac{\mathrm{d}^2 w}{\mathrm{d}z^2}
+ z \frac{\mathrm{d}w}{\mathrm{d}z} + (z^2 + \nu^2)^2 w = 0.
It can be defined as
.. math ::
I_\nu(z) = i^{-\nu} J_\nu(iz),
where $J_\nu(z)$ is the Bessel function of the first kind.
Examples
========
>>> from sympy import besseli
>>> from sympy.abc import z, n
>>> besseli(n, z).diff(z)
besseli(n - 1, z)/2 + besseli(n + 1, z)/2
See Also
========
besselj, bessely, besselk
References
==========
.. [1] http://functions.wolfram.com/Bessel-TypeFunctions/BesselI/
"""
_a = -S.One
_b = S.One
@classmethod
def eval(cls, nu, z):
if z.is_zero:
if nu.is_zero:
return S.One
elif (nu.is_integer and nu.is_zero is False) or re(nu).is_positive:
return S.Zero
elif re(nu).is_negative and not (nu.is_integer is True):
return S.ComplexInfinity
elif nu.is_imaginary:
return S.NaN
if im(z) is S.Infinity or im(z) is S.NegativeInfinity:
return S.Zero
if z.could_extract_minus_sign():
return (z)**nu*(-z)**(-nu)*besseli(nu, -z)
if nu.is_integer:
if nu.could_extract_minus_sign():
return besseli(-nu, z)
newz = z.extract_multiplicatively(I)
if newz: # NOTE we don't want to change the function if z==0
return I**(-nu)*besselj(nu, -newz)
# branch handling:
from sympy import unpolarify, exp
if nu.is_integer:
newz = unpolarify(z)
if newz != z:
return besseli(nu, newz)
else:
newz, n = z.extract_branch_factor()
if n != 0:
return exp(2*n*pi*nu*I)*besseli(nu, newz)
nnu = unpolarify(nu)
if nu != nnu:
return besseli(nnu, z)
def _eval_rewrite_as_besselj(self, nu, z, **kwargs):
from sympy import polar_lift, exp
return exp(-I*pi*nu/2)*besselj(nu, polar_lift(I)*z)
def _eval_rewrite_as_bessely(self, nu, z, **kwargs):
aj = self._eval_rewrite_as_besselj(*self.args)
if aj:
return aj.rewrite(bessely)
def _eval_rewrite_as_jn(self, nu, z, **kwargs):
return self._eval_rewrite_as_besselj(*self.args).rewrite(jn)
def _eval_is_extended_real(self):
nu, z = self.args
if nu.is_integer and z.is_extended_real:
return True
def _sage_(self):
import sage.all as sage
return sage.bessel_I(self.args[0]._sage_(), self.args[1]._sage_())
class besselk(BesselBase):
r"""
Modified Bessel function of the second kind.
Explanation
===========
The Bessel $K$ function of order $\nu$ is defined as
.. math ::
K_\nu(z) = \lim_{\mu \to \nu} \frac{\pi}{2}
\frac{I_{-\mu}(z) -I_\mu(z)}{\sin(\pi \mu)},
where $I_\mu(z)$ is the modified Bessel function of the first kind.
It is a solution of the modified Bessel equation, and linearly independent
from $Y_\nu$.
Examples
========
>>> from sympy import besselk
>>> from sympy.abc import z, n
>>> besselk(n, z).diff(z)
-besselk(n - 1, z)/2 - besselk(n + 1, z)/2
See Also
========
besselj, besseli, bessely
References
==========
.. [1] http://functions.wolfram.com/Bessel-TypeFunctions/BesselK/
"""
_a = S.One
_b = -S.One
@classmethod
def eval(cls, nu, z):
if z.is_zero:
if nu.is_zero:
return S.Infinity
elif re(nu).is_zero is False:
return S.ComplexInfinity
elif re(nu).is_zero:
return S.NaN
if im(z) is S.Infinity or im(z) is S.NegativeInfinity:
return S.Zero
if nu.is_integer:
if nu.could_extract_minus_sign():
return besselk(-nu, z)
def _eval_rewrite_as_besseli(self, nu, z, **kwargs):
if nu.is_integer is False:
return pi*csc(pi*nu)*(besseli(-nu, z) - besseli(nu, z))/2
def _eval_rewrite_as_besselj(self, nu, z, **kwargs):
ai = self._eval_rewrite_as_besseli(*self.args)
if ai:
return ai.rewrite(besselj)
def _eval_rewrite_as_bessely(self, nu, z, **kwargs):
aj = self._eval_rewrite_as_besselj(*self.args)
if aj:
return aj.rewrite(bessely)
def _eval_rewrite_as_yn(self, nu, z, **kwargs):
ay = self._eval_rewrite_as_bessely(*self.args)
if ay:
return ay.rewrite(yn)
def _eval_is_extended_real(self):
nu, z = self.args
if nu.is_integer and z.is_positive:
return True
def _sage_(self):
import sage.all as sage
return sage.bessel_K(self.args[0]._sage_(), self.args[1]._sage_())
class hankel1(BesselBase):
r"""
Hankel function of the first kind.
Explanation
===========
This function is defined as
.. math ::
H_\nu^{(1)} = J_\nu(z) + iY_\nu(z),
where $J_\nu(z)$ is the Bessel function of the first kind, and
$Y_\nu(z)$ is the Bessel function of the second kind.
It is a solution to Bessel's equation.
Examples
========
>>> from sympy import hankel1
>>> from sympy.abc import z, n
>>> hankel1(n, z).diff(z)
hankel1(n - 1, z)/2 - hankel1(n + 1, z)/2
See Also
========
hankel2, besselj, bessely
References
==========
.. [1] http://functions.wolfram.com/Bessel-TypeFunctions/HankelH1/
"""
_a = S.One
_b = S.One
def _eval_conjugate(self):
z = self.argument
if z.is_extended_negative is False:
return hankel2(self.order.conjugate(), z.conjugate())
class hankel2(BesselBase):
r"""
Hankel function of the second kind.
Explanation
===========
This function is defined as
.. math ::
H_\nu^{(2)} = J_\nu(z) - iY_\nu(z),
where $J_\nu(z)$ is the Bessel function of the first kind, and
$Y_\nu(z)$ is the Bessel function of the second kind.
It is a solution to Bessel's equation, and linearly independent from
$H_\nu^{(1)}$.
Examples
========
>>> from sympy import hankel2
>>> from sympy.abc import z, n
>>> hankel2(n, z).diff(z)
hankel2(n - 1, z)/2 - hankel2(n + 1, z)/2
See Also
========
hankel1, besselj, bessely
References
==========
.. [1] http://functions.wolfram.com/Bessel-TypeFunctions/HankelH2/
"""
_a = S.One
_b = S.One
def _eval_conjugate(self):
z = self.argument
if z.is_extended_negative is False:
return hankel1(self.order.conjugate(), z.conjugate())
def assume_integer_order(fn):
@wraps(fn)
def g(self, nu, z):
if nu.is_integer:
return fn(self, nu, z)
return g
class SphericalBesselBase(BesselBase):
"""
Base class for spherical Bessel functions.
These are thin wrappers around ordinary Bessel functions,
since spherical Bessel functions differ from the ordinary
ones just by a slight change in order.
To use this class, define the ``_rewrite()`` and ``_expand()`` methods.
"""
def _expand(self, **hints):
""" Expand self into a polynomial. Nu is guaranteed to be Integer. """
raise NotImplementedError('expansion')
def _rewrite(self):
""" Rewrite self in terms of ordinary Bessel functions. """
raise NotImplementedError('rewriting')
def _eval_expand_func(self, **hints):
if self.order.is_Integer:
return self._expand(**hints)
return self
def _eval_evalf(self, prec):
if self.order.is_Integer:
return self._rewrite()._eval_evalf(prec)
def fdiff(self, argindex=2):
if argindex != 2:
raise ArgumentIndexError(self, argindex)
return self.__class__(self.order - 1, self.argument) - \
self * (self.order + 1)/self.argument
def _jn(n, z):
return fn(n, z)*sin(z) + (-1)**(n + 1)*fn(-n - 1, z)*cos(z)
def _yn(n, z):
# (-1)**(n + 1) * _jn(-n - 1, z)
return (-1)**(n + 1) * fn(-n - 1, z)*sin(z) - fn(n, z)*cos(z)
class jn(SphericalBesselBase):
r"""
Spherical Bessel function of the first kind.
Explanation
===========
This function is a solution to the spherical Bessel equation
.. math ::
z^2 \frac{\mathrm{d}^2 w}{\mathrm{d}z^2}
+ 2z \frac{\mathrm{d}w}{\mathrm{d}z} + (z^2 - \nu(\nu + 1)) w = 0.
It can be defined as
.. math ::
j_\nu(z) = \sqrt{\frac{\pi}{2z}} J_{\nu + \frac{1}{2}}(z),
where $J_\nu(z)$ is the Bessel function of the first kind.
The spherical Bessel functions of integral order are
calculated using the formula:
.. math:: j_n(z) = f_n(z) \sin{z} + (-1)^{n+1} f_{-n-1}(z) \cos{z},
where the coefficients $f_n(z)$ are available as
:func:`sympy.polys.orthopolys.spherical_bessel_fn`.
Examples
========
>>> from sympy import Symbol, jn, sin, cos, expand_func, besselj, bessely
>>> z = Symbol("z")
>>> nu = Symbol("nu", integer=True)
>>> print(expand_func(jn(0, z)))
sin(z)/z
>>> expand_func(jn(1, z)) == sin(z)/z**2 - cos(z)/z
True
>>> expand_func(jn(3, z))
(-6/z**2 + 15/z**4)*sin(z) + (1/z - 15/z**3)*cos(z)
>>> jn(nu, z).rewrite(besselj)
sqrt(2)*sqrt(pi)*sqrt(1/z)*besselj(nu + 1/2, z)/2
>>> jn(nu, z).rewrite(bessely)
(-1)**nu*sqrt(2)*sqrt(pi)*sqrt(1/z)*bessely(-nu - 1/2, z)/2
>>> jn(2, 5.2+0.3j).evalf(20)
0.099419756723640344491 - 0.054525080242173562897*I
See Also
========
besselj, bessely, besselk, yn
References
==========
.. [1] http://dlmf.nist.gov/10.47
"""
@classmethod
def eval(cls, nu, z):
if z.is_zero:
if nu.is_zero:
return S.One
elif nu.is_integer:
if nu.is_positive:
return S.Zero
else:
return S.ComplexInfinity
if z in (S.NegativeInfinity, S.Infinity):
return S.Zero
def _rewrite(self):
return self._eval_rewrite_as_besselj(self.order, self.argument)
def _eval_rewrite_as_besselj(self, nu, z, **kwargs):
return sqrt(pi/(2*z)) * besselj(nu + S.Half, z)
def _eval_rewrite_as_bessely(self, nu, z, **kwargs):
return (-1)**nu * sqrt(pi/(2*z)) * bessely(-nu - S.Half, z)
def _eval_rewrite_as_yn(self, nu, z, **kwargs):
return (-1)**(nu) * yn(-nu - 1, z)
def _expand(self, **hints):
return _jn(self.order, self.argument)
class yn(SphericalBesselBase):
r"""
Spherical Bessel function of the second kind.
Explanation
===========
This function is another solution to the spherical Bessel equation, and
linearly independent from $j_n$. It can be defined as
.. math ::
y_\nu(z) = \sqrt{\frac{\pi}{2z}} Y_{\nu + \frac{1}{2}}(z),
where $Y_\nu(z)$ is the Bessel function of the second kind.
For integral orders $n$, $y_n$ is calculated using the formula:
.. math:: y_n(z) = (-1)^{n+1} j_{-n-1}(z)
Examples
========
>>> from sympy import Symbol, yn, sin, cos, expand_func, besselj, bessely
>>> z = Symbol("z")
>>> nu = Symbol("nu", integer=True)
>>> print(expand_func(yn(0, z)))
-cos(z)/z
>>> expand_func(yn(1, z)) == -cos(z)/z**2-sin(z)/z
True
>>> yn(nu, z).rewrite(besselj)
(-1)**(nu + 1)*sqrt(2)*sqrt(pi)*sqrt(1/z)*besselj(-nu - 1/2, z)/2
>>> yn(nu, z).rewrite(bessely)
sqrt(2)*sqrt(pi)*sqrt(1/z)*bessely(nu + 1/2, z)/2
>>> yn(2, 5.2+0.3j).evalf(20)
0.18525034196069722536 + 0.014895573969924817587*I
See Also
========
besselj, bessely, besselk, jn
References
==========
.. [1] http://dlmf.nist.gov/10.47
"""
def _rewrite(self):
return self._eval_rewrite_as_bessely(self.order, self.argument)
@assume_integer_order
def _eval_rewrite_as_besselj(self, nu, z, **kwargs):
return (-1)**(nu+1) * sqrt(pi/(2*z)) * besselj(-nu - S.Half, z)
@assume_integer_order
def _eval_rewrite_as_bessely(self, nu, z, **kwargs):
return sqrt(pi/(2*z)) * bessely(nu + S.Half, z)
def _eval_rewrite_as_jn(self, nu, z, **kwargs):
return (-1)**(nu + 1) * jn(-nu - 1, z)
def _expand(self, **hints):
return _yn(self.order, self.argument)
class SphericalHankelBase(SphericalBesselBase):
def _rewrite(self):
return self._eval_rewrite_as_besselj(self.order, self.argument)
@assume_integer_order
def _eval_rewrite_as_besselj(self, nu, z, **kwargs):
# jn +- I*yn
# jn as beeselj: sqrt(pi/(2*z)) * besselj(nu + S.Half, z)
# yn as besselj: (-1)**(nu+1) * sqrt(pi/(2*z)) * besselj(-nu - S.Half, z)
hks = self._hankel_kind_sign
return sqrt(pi/(2*z))*(besselj(nu + S.Half, z) +
hks*I*(-1)**(nu+1)*besselj(-nu - S.Half, z))
@assume_integer_order
def _eval_rewrite_as_bessely(self, nu, z, **kwargs):
# jn +- I*yn
# jn as bessely: (-1)**nu * sqrt(pi/(2*z)) * bessely(-nu - S.Half, z)
# yn as bessely: sqrt(pi/(2*z)) * bessely(nu + S.Half, z)
hks = self._hankel_kind_sign
return sqrt(pi/(2*z))*((-1)**nu*bessely(-nu - S.Half, z) +
hks*I*bessely(nu + S.Half, z))
def _eval_rewrite_as_yn(self, nu, z, **kwargs):
hks = self._hankel_kind_sign
return jn(nu, z).rewrite(yn) + hks*I*yn(nu, z)
def _eval_rewrite_as_jn(self, nu, z, **kwargs):
hks = self._hankel_kind_sign
return jn(nu, z) + hks*I*yn(nu, z).rewrite(jn)
def _eval_expand_func(self, **hints):
if self.order.is_Integer:
return self._expand(**hints)
else:
nu = self.order
z = self.argument
hks = self._hankel_kind_sign
return jn(nu, z) + hks*I*yn(nu, z)
def _expand(self, **hints):
n = self.order
z = self.argument
hks = self._hankel_kind_sign
# fully expanded version
# return ((fn(n, z) * sin(z) +
# (-1)**(n + 1) * fn(-n - 1, z) * cos(z)) + # jn
# (hks * I * (-1)**(n + 1) *
# (fn(-n - 1, z) * hk * I * sin(z) +
# (-1)**(-n) * fn(n, z) * I * cos(z))) # +-I*yn
# )
return (_jn(n, z) + hks*I*_yn(n, z)).expand()
class hn1(SphericalHankelBase):
r"""
Spherical Hankel function of the first kind.
Explanation
===========
This function is defined as
.. math:: h_\nu^(1)(z) = j_\nu(z) + i y_\nu(z),
where $j_\nu(z)$ and $y_\nu(z)$ are the spherical
Bessel function of the first and second kinds.
For integral orders $n$, $h_n^(1)$ is calculated using the formula:
.. math:: h_n^(1)(z) = j_{n}(z) + i (-1)^{n+1} j_{-n-1}(z)
Examples
========
>>> from sympy import Symbol, hn1, hankel1, expand_func, yn, jn
>>> z = Symbol("z")
>>> nu = Symbol("nu", integer=True)
>>> print(expand_func(hn1(nu, z)))
jn(nu, z) + I*yn(nu, z)
>>> print(expand_func(hn1(0, z)))
sin(z)/z - I*cos(z)/z
>>> print(expand_func(hn1(1, z)))
-I*sin(z)/z - cos(z)/z + sin(z)/z**2 - I*cos(z)/z**2
>>> hn1(nu, z).rewrite(jn)
(-1)**(nu + 1)*I*jn(-nu - 1, z) + jn(nu, z)
>>> hn1(nu, z).rewrite(yn)
(-1)**nu*yn(-nu - 1, z) + I*yn(nu, z)
>>> hn1(nu, z).rewrite(hankel1)
sqrt(2)*sqrt(pi)*sqrt(1/z)*hankel1(nu, z)/2
See Also
========
hn2, jn, yn, hankel1, hankel2
References
==========
.. [1] http://dlmf.nist.gov/10.47
"""
_hankel_kind_sign = S.One
@assume_integer_order
def _eval_rewrite_as_hankel1(self, nu, z, **kwargs):
return sqrt(pi/(2*z))*hankel1(nu, z)
class hn2(SphericalHankelBase):
r"""
Spherical Hankel function of the second kind.
Explanation
===========
This function is defined as
.. math:: h_\nu^(2)(z) = j_\nu(z) - i y_\nu(z),
where $j_\nu(z)$ and $y_\nu(z)$ are the spherical
Bessel function of the first and second kinds.
For integral orders $n$, $h_n^(2)$ is calculated using the formula:
.. math:: h_n^(2)(z) = j_{n} - i (-1)^{n+1} j_{-n-1}(z)
Examples
========
>>> from sympy import Symbol, hn2, hankel2, expand_func, jn, yn
>>> z = Symbol("z")
>>> nu = Symbol("nu", integer=True)
>>> print(expand_func(hn2(nu, z)))
jn(nu, z) - I*yn(nu, z)
>>> print(expand_func(hn2(0, z)))
sin(z)/z + I*cos(z)/z
>>> print(expand_func(hn2(1, z)))
I*sin(z)/z - cos(z)/z + sin(z)/z**2 + I*cos(z)/z**2
>>> hn2(nu, z).rewrite(hankel2)
sqrt(2)*sqrt(pi)*sqrt(1/z)*hankel2(nu, z)/2
>>> hn2(nu, z).rewrite(jn)
-(-1)**(nu + 1)*I*jn(-nu - 1, z) + jn(nu, z)
>>> hn2(nu, z).rewrite(yn)
(-1)**nu*yn(-nu - 1, z) - I*yn(nu, z)
See Also
========
hn1, jn, yn, hankel1, hankel2
References
==========
.. [1] http://dlmf.nist.gov/10.47
"""
_hankel_kind_sign = -S.One
@assume_integer_order
def _eval_rewrite_as_hankel2(self, nu, z, **kwargs):
return sqrt(pi/(2*z))*hankel2(nu, z)
def jn_zeros(n, k, method="sympy", dps=15):
"""
Zeros of the spherical Bessel function of the first kind.
Explanation
===========
This returns an array of zeros of $jn$ up to the $k$-th zero.
* method = "sympy": uses `mpmath.besseljzero
<http://mpmath.org/doc/current/functions/bessel.html#mpmath.besseljzero>`_
* method = "scipy": uses the
`SciPy's sph_jn <http://docs.scipy.org/doc/scipy/reference/generated/scipy.special.jn_zeros.html>`_
and
`newton <http://docs.scipy.org/doc/scipy/reference/generated/scipy.optimize.newton.html>`_
to find all
roots, which is faster than computing the zeros using a general
numerical solver, but it requires SciPy and only works with low
precision floating point numbers. (The function used with
method="sympy" is a recent addition to mpmath; before that a general
solver was used.)
Examples
========
>>> from sympy import jn_zeros
>>> jn_zeros(2, 4, dps=5)
[5.7635, 9.095, 12.323, 15.515]
See Also
========
jn, yn, besselj, besselk, bessely
"""
from math import pi
if method == "sympy":
from mpmath import besseljzero
from mpmath.libmp.libmpf import dps_to_prec
from sympy import Expr
prec = dps_to_prec(dps)
return [Expr._from_mpmath(besseljzero(S(n + 0.5)._to_mpmath(prec),
int(l)), prec)
for l in range(1, k + 1)]
elif method == "scipy":
from scipy.optimize import newton
try:
from scipy.special import spherical_jn
f = lambda x: spherical_jn(n, x)
except ImportError:
from scipy.special import sph_jn
f = lambda x: sph_jn(n, x)[0][-1]
else:
raise NotImplementedError("Unknown method.")
def solver(f, x):
if method == "scipy":
root = newton(f, x)
else:
raise NotImplementedError("Unknown method.")
return root
# we need to approximate the position of the first root:
root = n + pi
# determine the first root exactly:
root = solver(f, root)
roots = [root]
for i in range(k - 1):
# estimate the position of the next root using the last root + pi:
root = solver(f, root + pi)
roots.append(root)
return roots
class AiryBase(Function):
"""
Abstract base class for Airy functions.
This class is meant to reduce code duplication.
"""
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def _eval_is_extended_real(self):
return self.args[0].is_extended_real
def as_real_imag(self, deep=True, **hints):
z = self.args[0]
zc = z.conjugate()
f = self.func
u = (f(z)+f(zc))/2
v = I*(f(zc)-f(z))/2
return u, v
def _eval_expand_complex(self, deep=True, **hints):
re_part, im_part = self.as_real_imag(deep=deep, **hints)
return re_part + im_part*S.ImaginaryUnit
class airyai(AiryBase):
r"""
The Airy function $\operatorname{Ai}$ of the first kind.
Explanation
===========
The Airy function $\operatorname{Ai}(z)$ is defined to be the function
satisfying Airy's differential equation
.. math::
\frac{\mathrm{d}^2 w(z)}{\mathrm{d}z^2} - z w(z) = 0.
Equivalently, for real $z$
.. math::
\operatorname{Ai}(z) := \frac{1}{\pi}
\int_0^\infty \cos\left(\frac{t^3}{3} + z t\right) \mathrm{d}t.
Examples
========
Create an Airy function object:
>>> from sympy import airyai
>>> from sympy.abc import z
>>> airyai(z)
airyai(z)
Several special values are known:
>>> airyai(0)
3**(1/3)/(3*gamma(2/3))
>>> from sympy import oo
>>> airyai(oo)
0
>>> airyai(-oo)
0
The Airy function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(airyai(z))
airyai(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(airyai(z), z)
airyaiprime(z)
>>> diff(airyai(z), z, 2)
z*airyai(z)
Series expansion is also supported:
>>> from sympy import series
>>> series(airyai(z), z, 0, 3)
3**(5/6)*gamma(1/3)/(6*pi) - 3**(1/6)*z*gamma(2/3)/(2*pi) + O(z**3)
We can numerically evaluate the Airy function to arbitrary precision
on the whole complex plane:
>>> airyai(-2).evalf(50)
0.22740742820168557599192443603787379946077222541710
Rewrite $\operatorname{Ai}(z)$ in terms of hypergeometric functions:
>>> from sympy import hyper
>>> airyai(z).rewrite(hyper)
-3**(2/3)*z*hyper((), (4/3,), z**3/9)/(3*gamma(1/3)) + 3**(1/3)*hyper((), (2/3,), z**3/9)/(3*gamma(2/3))
See Also
========
airybi: Airy function of the second kind.
airyaiprime: Derivative of the Airy function of the first kind.
airybiprime: Derivative of the Airy function of the second kind.
References
==========
.. [1] https://en.wikipedia.org/wiki/Airy_function
.. [2] http://dlmf.nist.gov/9
.. [3] http://www.encyclopediaofmath.org/index.php/Airy_functions
.. [4] http://mathworld.wolfram.com/AiryFunctions.html
"""
nargs = 1
unbranched = True
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Zero
elif arg is S.NegativeInfinity:
return S.Zero
elif arg.is_zero:
return S.One / (3**Rational(2, 3) * gamma(Rational(2, 3)))
if arg.is_zero:
return S.One / (3**Rational(2, 3) * gamma(Rational(2, 3)))
def fdiff(self, argindex=1):
if argindex == 1:
return airyaiprime(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) > 1:
p = previous_terms[-1]
return ((3**Rational(1, 3)*x)**(-n)*(3**Rational(1, 3)*x)**(n + 1)*sin(pi*(n*Rational(2, 3) + Rational(4, 3)))*factorial(n) *
gamma(n/3 + Rational(2, 3))/(sin(pi*(n*Rational(2, 3) + Rational(2, 3)))*factorial(n + 1)*gamma(n/3 + Rational(1, 3))) * p)
else:
return (S.One/(3**Rational(2, 3)*pi) * gamma((n+S.One)/S(3)) * sin(2*pi*(n+S.One)/S(3)) /
factorial(n) * (root(3, 3)*x)**n)
def _eval_rewrite_as_besselj(self, z, **kwargs):
ot = Rational(1, 3)
tt = Rational(2, 3)
a = Pow(-z, Rational(3, 2))
if re(z).is_negative:
return ot*sqrt(-z) * (besselj(-ot, tt*a) + besselj(ot, tt*a))
def _eval_rewrite_as_besseli(self, z, **kwargs):
ot = Rational(1, 3)
tt = Rational(2, 3)
a = Pow(z, Rational(3, 2))
if re(z).is_positive:
return ot*sqrt(z) * (besseli(-ot, tt*a) - besseli(ot, tt*a))
else:
return ot*(Pow(a, ot)*besseli(-ot, tt*a) - z*Pow(a, -ot)*besseli(ot, tt*a))
def _eval_rewrite_as_hyper(self, z, **kwargs):
pf1 = S.One / (3**Rational(2, 3)*gamma(Rational(2, 3)))
pf2 = z / (root(3, 3)*gamma(Rational(1, 3)))
return pf1 * hyper([], [Rational(2, 3)], z**3/9) - pf2 * hyper([], [Rational(4, 3)], z**3/9)
def _eval_expand_func(self, **hints):
arg = self.args[0]
symbs = arg.free_symbols
if len(symbs) == 1:
z = symbs.pop()
c = Wild("c", exclude=[z])
d = Wild("d", exclude=[z])
m = Wild("m", exclude=[z])
n = Wild("n", exclude=[z])
M = arg.match(c*(d*z**n)**m)
if M is not None:
m = M[m]
# The transformation is given by 03.05.16.0001.01
# http://functions.wolfram.com/Bessel-TypeFunctions/AiryAi/16/01/01/0001/
if (3*m).is_integer:
c = M[c]
d = M[d]
n = M[n]
pf = (d * z**n)**m / (d**m * z**(m*n))
newarg = c * d**m * z**(m*n)
return S.Half * ((pf + S.One)*airyai(newarg) - (pf - S.One)/sqrt(3)*airybi(newarg))
class airybi(AiryBase):
r"""
The Airy function $\operatorname{Bi}$ of the second kind.
Explanation
===========
The Airy function $\operatorname{Bi}(z)$ is defined to be the function
satisfying Airy's differential equation
.. math::
\frac{\mathrm{d}^2 w(z)}{\mathrm{d}z^2} - z w(z) = 0.
Equivalently, for real $z$
.. math::
\operatorname{Bi}(z) := \frac{1}{\pi}
\int_0^\infty
\exp\left(-\frac{t^3}{3} + z t\right)
+ \sin\left(\frac{t^3}{3} + z t\right) \mathrm{d}t.
Examples
========
Create an Airy function object:
>>> from sympy import airybi
>>> from sympy.abc import z
>>> airybi(z)
airybi(z)
Several special values are known:
>>> airybi(0)
3**(5/6)/(3*gamma(2/3))
>>> from sympy import oo
>>> airybi(oo)
oo
>>> airybi(-oo)
0
The Airy function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(airybi(z))
airybi(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(airybi(z), z)
airybiprime(z)
>>> diff(airybi(z), z, 2)
z*airybi(z)
Series expansion is also supported:
>>> from sympy import series
>>> series(airybi(z), z, 0, 3)
3**(1/3)*gamma(1/3)/(2*pi) + 3**(2/3)*z*gamma(2/3)/(2*pi) + O(z**3)
We can numerically evaluate the Airy function to arbitrary precision
on the whole complex plane:
>>> airybi(-2).evalf(50)
-0.41230258795639848808323405461146104203453483447240
Rewrite $\operatorname{Bi}(z)$ in terms of hypergeometric functions:
>>> from sympy import hyper
>>> airybi(z).rewrite(hyper)
3**(1/6)*z*hyper((), (4/3,), z**3/9)/gamma(1/3) + 3**(5/6)*hyper((), (2/3,), z**3/9)/(3*gamma(2/3))
See Also
========
airyai: Airy function of the first kind.
airyaiprime: Derivative of the Airy function of the first kind.
airybiprime: Derivative of the Airy function of the second kind.
References
==========
.. [1] https://en.wikipedia.org/wiki/Airy_function
.. [2] http://dlmf.nist.gov/9
.. [3] http://www.encyclopediaofmath.org/index.php/Airy_functions
.. [4] http://mathworld.wolfram.com/AiryFunctions.html
"""
nargs = 1
unbranched = True
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Infinity
elif arg is S.NegativeInfinity:
return S.Zero
elif arg.is_zero:
return S.One / (3**Rational(1, 6) * gamma(Rational(2, 3)))
if arg.is_zero:
return S.One / (3**Rational(1, 6) * gamma(Rational(2, 3)))
def fdiff(self, argindex=1):
if argindex == 1:
return airybiprime(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) > 1:
p = previous_terms[-1]
return (3**Rational(1, 3)*x * Abs(sin(2*pi*(n + S.One)/S(3))) * factorial((n - S.One)/S(3)) /
((n + S.One) * Abs(cos(2*pi*(n + S.Half)/S(3))) * factorial((n - 2)/S(3))) * p)
else:
return (S.One/(root(3, 6)*pi) * gamma((n + S.One)/S(3)) * Abs(sin(2*pi*(n + S.One)/S(3))) /
factorial(n) * (root(3, 3)*x)**n)
def _eval_rewrite_as_besselj(self, z, **kwargs):
ot = Rational(1, 3)
tt = Rational(2, 3)
a = Pow(-z, Rational(3, 2))
if re(z).is_negative:
return sqrt(-z/3) * (besselj(-ot, tt*a) - besselj(ot, tt*a))
def _eval_rewrite_as_besseli(self, z, **kwargs):
ot = Rational(1, 3)
tt = Rational(2, 3)
a = Pow(z, Rational(3, 2))
if re(z).is_positive:
return sqrt(z)/sqrt(3) * (besseli(-ot, tt*a) + besseli(ot, tt*a))
else:
b = Pow(a, ot)
c = Pow(a, -ot)
return sqrt(ot)*(b*besseli(-ot, tt*a) + z*c*besseli(ot, tt*a))
def _eval_rewrite_as_hyper(self, z, **kwargs):
pf1 = S.One / (root(3, 6)*gamma(Rational(2, 3)))
pf2 = z*root(3, 6) / gamma(Rational(1, 3))
return pf1 * hyper([], [Rational(2, 3)], z**3/9) + pf2 * hyper([], [Rational(4, 3)], z**3/9)
def _eval_expand_func(self, **hints):
arg = self.args[0]
symbs = arg.free_symbols
if len(symbs) == 1:
z = symbs.pop()
c = Wild("c", exclude=[z])
d = Wild("d", exclude=[z])
m = Wild("m", exclude=[z])
n = Wild("n", exclude=[z])
M = arg.match(c*(d*z**n)**m)
if M is not None:
m = M[m]
# The transformation is given by 03.06.16.0001.01
# http://functions.wolfram.com/Bessel-TypeFunctions/AiryBi/16/01/01/0001/
if (3*m).is_integer:
c = M[c]
d = M[d]
n = M[n]
pf = (d * z**n)**m / (d**m * z**(m*n))
newarg = c * d**m * z**(m*n)
return S.Half * (sqrt(3)*(S.One - pf)*airyai(newarg) + (S.One + pf)*airybi(newarg))
class airyaiprime(AiryBase):
r"""
The derivative $\operatorname{Ai}^\prime$ of the Airy function of the first
kind.
Explanation
===========
The Airy function $\operatorname{Ai}^\prime(z)$ is defined to be the
function
.. math::
\operatorname{Ai}^\prime(z) := \frac{\mathrm{d} \operatorname{Ai}(z)}{\mathrm{d} z}.
Examples
========
Create an Airy function object:
>>> from sympy import airyaiprime
>>> from sympy.abc import z
>>> airyaiprime(z)
airyaiprime(z)
Several special values are known:
>>> airyaiprime(0)
-3**(2/3)/(3*gamma(1/3))
>>> from sympy import oo
>>> airyaiprime(oo)
0
The Airy function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(airyaiprime(z))
airyaiprime(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(airyaiprime(z), z)
z*airyai(z)
>>> diff(airyaiprime(z), z, 2)
z*airyaiprime(z) + airyai(z)
Series expansion is also supported:
>>> from sympy import series
>>> series(airyaiprime(z), z, 0, 3)
-3**(2/3)/(3*gamma(1/3)) + 3**(1/3)*z**2/(6*gamma(2/3)) + O(z**3)
We can numerically evaluate the Airy function to arbitrary precision
on the whole complex plane:
>>> airyaiprime(-2).evalf(50)
0.61825902074169104140626429133247528291577794512415
Rewrite $\operatorname{Ai}^\prime(z)$ in terms of hypergeometric functions:
>>> from sympy import hyper
>>> airyaiprime(z).rewrite(hyper)
3**(1/3)*z**2*hyper((), (5/3,), z**3/9)/(6*gamma(2/3)) - 3**(2/3)*hyper((), (1/3,), z**3/9)/(3*gamma(1/3))
See Also
========
airyai: Airy function of the first kind.
airybi: Airy function of the second kind.
airybiprime: Derivative of the Airy function of the second kind.
References
==========
.. [1] https://en.wikipedia.org/wiki/Airy_function
.. [2] http://dlmf.nist.gov/9
.. [3] http://www.encyclopediaofmath.org/index.php/Airy_functions
.. [4] http://mathworld.wolfram.com/AiryFunctions.html
"""
nargs = 1
unbranched = True
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Zero
if arg.is_zero:
return S.NegativeOne / (3**Rational(1, 3) * gamma(Rational(1, 3)))
def fdiff(self, argindex=1):
if argindex == 1:
return self.args[0]*airyai(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
def _eval_evalf(self, prec):
from mpmath import mp, workprec
from sympy import Expr
z = self.args[0]._to_mpmath(prec)
with workprec(prec):
res = mp.airyai(z, derivative=1)
return Expr._from_mpmath(res, prec)
def _eval_rewrite_as_besselj(self, z, **kwargs):
tt = Rational(2, 3)
a = Pow(-z, Rational(3, 2))
if re(z).is_negative:
return z/3 * (besselj(-tt, tt*a) - besselj(tt, tt*a))
def _eval_rewrite_as_besseli(self, z, **kwargs):
ot = Rational(1, 3)
tt = Rational(2, 3)
a = tt * Pow(z, Rational(3, 2))
if re(z).is_positive:
return z/3 * (besseli(tt, a) - besseli(-tt, a))
else:
a = Pow(z, Rational(3, 2))
b = Pow(a, tt)
c = Pow(a, -tt)
return ot * (z**2*c*besseli(tt, tt*a) - b*besseli(-ot, tt*a))
def _eval_rewrite_as_hyper(self, z, **kwargs):
pf1 = z**2 / (2*3**Rational(2, 3)*gamma(Rational(2, 3)))
pf2 = 1 / (root(3, 3)*gamma(Rational(1, 3)))
return pf1 * hyper([], [Rational(5, 3)], z**3/9) - pf2 * hyper([], [Rational(1, 3)], z**3/9)
def _eval_expand_func(self, **hints):
arg = self.args[0]
symbs = arg.free_symbols
if len(symbs) == 1:
z = symbs.pop()
c = Wild("c", exclude=[z])
d = Wild("d", exclude=[z])
m = Wild("m", exclude=[z])
n = Wild("n", exclude=[z])
M = arg.match(c*(d*z**n)**m)
if M is not None:
m = M[m]
# The transformation is in principle
# given by 03.07.16.0001.01 but note
# that there is an error in this formula.
# http://functions.wolfram.com/Bessel-TypeFunctions/AiryAiPrime/16/01/01/0001/
if (3*m).is_integer:
c = M[c]
d = M[d]
n = M[n]
pf = (d**m * z**(n*m)) / (d * z**n)**m
newarg = c * d**m * z**(n*m)
return S.Half * ((pf + S.One)*airyaiprime(newarg) + (pf - S.One)/sqrt(3)*airybiprime(newarg))
class airybiprime(AiryBase):
r"""
The derivative $\operatorname{Bi}^\prime$ of the Airy function of the first
kind.
Explanation
===========
The Airy function $\operatorname{Bi}^\prime(z)$ is defined to be the
function
.. math::
\operatorname{Bi}^\prime(z) := \frac{\mathrm{d} \operatorname{Bi}(z)}{\mathrm{d} z}.
Examples
========
Create an Airy function object:
>>> from sympy import airybiprime
>>> from sympy.abc import z
>>> airybiprime(z)
airybiprime(z)
Several special values are known:
>>> airybiprime(0)
3**(1/6)/gamma(1/3)
>>> from sympy import oo
>>> airybiprime(oo)
oo
>>> airybiprime(-oo)
0
The Airy function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(airybiprime(z))
airybiprime(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(airybiprime(z), z)
z*airybi(z)
>>> diff(airybiprime(z), z, 2)
z*airybiprime(z) + airybi(z)
Series expansion is also supported:
>>> from sympy import series
>>> series(airybiprime(z), z, 0, 3)
3**(1/6)/gamma(1/3) + 3**(5/6)*z**2/(6*gamma(2/3)) + O(z**3)
We can numerically evaluate the Airy function to arbitrary precision
on the whole complex plane:
>>> airybiprime(-2).evalf(50)
0.27879516692116952268509756941098324140300059345163
Rewrite $\operatorname{Bi}^\prime(z)$ in terms of hypergeometric functions:
>>> from sympy import hyper
>>> airybiprime(z).rewrite(hyper)
3**(5/6)*z**2*hyper((), (5/3,), z**3/9)/(6*gamma(2/3)) + 3**(1/6)*hyper((), (1/3,), z**3/9)/gamma(1/3)
See Also
========
airyai: Airy function of the first kind.
airybi: Airy function of the second kind.
airyaiprime: Derivative of the Airy function of the first kind.
References
==========
.. [1] https://en.wikipedia.org/wiki/Airy_function
.. [2] http://dlmf.nist.gov/9
.. [3] http://www.encyclopediaofmath.org/index.php/Airy_functions
.. [4] http://mathworld.wolfram.com/AiryFunctions.html
"""
nargs = 1
unbranched = True
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Infinity
elif arg is S.NegativeInfinity:
return S.Zero
elif arg.is_zero:
return 3**Rational(1, 6) / gamma(Rational(1, 3))
if arg.is_zero:
return 3**Rational(1, 6) / gamma(Rational(1, 3))
def fdiff(self, argindex=1):
if argindex == 1:
return self.args[0]*airybi(self.args[0])
else:
raise ArgumentIndexError(self, argindex)
def _eval_evalf(self, prec):
from mpmath import mp, workprec
from sympy import Expr
z = self.args[0]._to_mpmath(prec)
with workprec(prec):
res = mp.airybi(z, derivative=1)
return Expr._from_mpmath(res, prec)
def _eval_rewrite_as_besselj(self, z, **kwargs):
tt = Rational(2, 3)
a = tt * Pow(-z, Rational(3, 2))
if re(z).is_negative:
return -z/sqrt(3) * (besselj(-tt, a) + besselj(tt, a))
def _eval_rewrite_as_besseli(self, z, **kwargs):
ot = Rational(1, 3)
tt = Rational(2, 3)
a = tt * Pow(z, Rational(3, 2))
if re(z).is_positive:
return z/sqrt(3) * (besseli(-tt, a) + besseli(tt, a))
else:
a = Pow(z, Rational(3, 2))
b = Pow(a, tt)
c = Pow(a, -tt)
return sqrt(ot) * (b*besseli(-tt, tt*a) + z**2*c*besseli(tt, tt*a))
def _eval_rewrite_as_hyper(self, z, **kwargs):
pf1 = z**2 / (2*root(3, 6)*gamma(Rational(2, 3)))
pf2 = root(3, 6) / gamma(Rational(1, 3))
return pf1 * hyper([], [Rational(5, 3)], z**3/9) + pf2 * hyper([], [Rational(1, 3)], z**3/9)
def _eval_expand_func(self, **hints):
arg = self.args[0]
symbs = arg.free_symbols
if len(symbs) == 1:
z = symbs.pop()
c = Wild("c", exclude=[z])
d = Wild("d", exclude=[z])
m = Wild("m", exclude=[z])
n = Wild("n", exclude=[z])
M = arg.match(c*(d*z**n)**m)
if M is not None:
m = M[m]
# The transformation is in principle
# given by 03.08.16.0001.01 but note
# that there is an error in this formula.
# http://functions.wolfram.com/Bessel-TypeFunctions/AiryBiPrime/16/01/01/0001/
if (3*m).is_integer:
c = M[c]
d = M[d]
n = M[n]
pf = (d**m * z**(n*m)) / (d * z**n)**m
newarg = c * d**m * z**(n*m)
return S.Half * (sqrt(3)*(pf - S.One)*airyaiprime(newarg) + (pf + S.One)*airybiprime(newarg))
class marcumq(Function):
r"""
The Marcum Q-function.
Explanation
===========
The Marcum Q-function is defined by the meromorphic continuation of
.. math::
Q_m(a, b) = a^{- m + 1} \int_{b}^{\infty} x^{m} e^{- \frac{a^{2}}{2} - \frac{x^{2}}{2}} I_{m - 1}\left(a x\right)\, dx
Examples
========
>>> from sympy import marcumq
>>> from sympy.abc import m, a, b
>>> marcumq(m, a, b)
marcumq(m, a, b)
Special values:
>>> marcumq(m, 0, b)
uppergamma(m, b**2/2)/gamma(m)
>>> marcumq(0, 0, 0)
0
>>> marcumq(0, a, 0)
1 - exp(-a**2/2)
>>> marcumq(1, a, a)
1/2 + exp(-a**2)*besseli(0, a**2)/2
>>> marcumq(2, a, a)
1/2 + exp(-a**2)*besseli(0, a**2)/2 + exp(-a**2)*besseli(1, a**2)
Differentiation with respect to $a$ and $b$ is supported:
>>> from sympy import diff
>>> diff(marcumq(m, a, b), a)
a*(-marcumq(m, a, b) + marcumq(m + 1, a, b))
>>> diff(marcumq(m, a, b), b)
-a**(1 - m)*b**m*exp(-a**2/2 - b**2/2)*besseli(m - 1, a*b)
References
==========
.. [1] https://en.wikipedia.org/wiki/Marcum_Q-function
.. [2] http://mathworld.wolfram.com/MarcumQ-Function.html
"""
@classmethod
def eval(cls, m, a, b):
from sympy import exp, uppergamma
if a is S.Zero:
if m is S.Zero and b is S.Zero:
return S.Zero
return uppergamma(m, b**2 * S.Half) / gamma(m)
if m is S.Zero and b is S.Zero:
return 1 - 1 / exp(a**2 * S.Half)
if a == b:
if m is S.One:
return (1 + exp(-a**2) * besseli(0, a**2))*S.Half
if m == 2:
return S.Half + S.Half * exp(-a**2) * besseli(0, a**2) + exp(-a**2) * besseli(1, a**2)
if a.is_zero:
if m.is_zero and b.is_zero:
return S.Zero
return uppergamma(m, b**2*S.Half) / gamma(m)
if m.is_zero and b.is_zero:
return 1 - 1 / exp(a**2*S.Half)
def fdiff(self, argindex=2):
from sympy import exp
m, a, b = self.args
if argindex == 2:
return a * (-marcumq(m, a, b) + marcumq(1+m, a, b))
elif argindex == 3:
return (-b**m / a**(m-1)) * exp(-(a**2 + b**2)/2) * besseli(m-1, a*b)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_Integral(self, m, a, b, **kwargs):
from sympy import Integral, exp, Dummy, oo
x = kwargs.get('x', Dummy('x'))
return a ** (1 - m) * \
Integral(x**m * exp(-(x**2 + a**2)/2) * besseli(m-1, a*x), [x, b, oo])
def _eval_rewrite_as_Sum(self, m, a, b, **kwargs):
from sympy import Sum, exp, Dummy, oo
k = kwargs.get('k', Dummy('k'))
return exp(-(a**2 + b**2) / 2) * Sum((a/b)**k * besseli(k, a*b), [k, 1-m, oo])
def _eval_rewrite_as_besseli(self, m, a, b, **kwargs):
if a == b:
from sympy import exp
if m == 1:
return (1 + exp(-a**2) * besseli(0, a**2)) / 2
if m.is_Integer and m >= 2:
s = sum([besseli(i, a**2) for i in range(1, m)])
return S.Half + exp(-a**2) * besseli(0, a**2) / 2 + exp(-a**2) * s
def _eval_is_zero(self):
if all(arg.is_zero for arg in self.args):
return True
|
4dfd1c2be0a376f480aa81fdbcffacf51266d3a016b1c7ead0f113305b0402d8 | from sympy.core import S, Integer
from sympy.core.compatibility import SYMPY_INTS
from sympy.core.function import Function
from sympy.core.logic import fuzzy_not
from sympy.core.mul import prod
from sympy.utilities.iterables import (has_dups, default_sort_key)
###############################################################################
###################### Kronecker Delta, Levi-Civita etc. ######################
###############################################################################
def Eijk(*args, **kwargs):
"""
Represent the Levi-Civita symbol.
This is a compatibility wrapper to ``LeviCivita()``.
See Also
========
LeviCivita
"""
return LeviCivita(*args, **kwargs)
def eval_levicivita(*args):
"""Evaluate Levi-Civita symbol."""
from sympy import factorial
n = len(args)
return prod(
prod(args[j] - args[i] for j in range(i + 1, n))
/ factorial(i) for i in range(n))
# converting factorial(i) to int is slightly faster
class LeviCivita(Function):
"""
Represent the Levi-Civita symbol.
Explanation
===========
For even permutations of indices it returns 1, for odd permutations -1, and
for everything else (a repeated index) it returns 0.
Thus it represents an alternating pseudotensor.
Examples
========
>>> from sympy import LeviCivita
>>> from sympy.abc import i, j, k
>>> LeviCivita(1, 2, 3)
1
>>> LeviCivita(1, 3, 2)
-1
>>> LeviCivita(1, 2, 2)
0
>>> LeviCivita(i, j, k)
LeviCivita(i, j, k)
>>> LeviCivita(i, j, i)
0
See Also
========
Eijk
"""
is_integer = True
@classmethod
def eval(cls, *args):
if all(isinstance(a, (SYMPY_INTS, Integer)) for a in args):
return eval_levicivita(*args)
if has_dups(args):
return S.Zero
def doit(self):
return eval_levicivita(*self.args)
class KroneckerDelta(Function):
"""
The discrete, or Kronecker, delta function.
Explanation
===========
A function that takes in two integers $i$ and $j$. It returns $0$ if $i$
and $j$ are not equal, or it returns $1$ if $i$ and $j$ are equal.
Examples
========
An example with integer indices:
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> KroneckerDelta(1, 2)
0
>>> KroneckerDelta(3, 3)
1
Symbolic indices:
>>> from sympy.abc import i, j, k
>>> KroneckerDelta(i, j)
KroneckerDelta(i, j)
>>> KroneckerDelta(i, i)
1
>>> KroneckerDelta(i, i + 1)
0
>>> KroneckerDelta(i, i + 1 + k)
KroneckerDelta(i, i + k + 1)
Parameters
==========
i : Number, Symbol
The first index of the delta function.
j : Number, Symbol
The second index of the delta function.
See Also
========
eval
DiracDelta
References
==========
.. [1] https://en.wikipedia.org/wiki/Kronecker_delta
"""
is_integer = True
@classmethod
def eval(cls, i, j, delta_range=None):
"""
Evaluates the discrete delta function.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy.abc import i, j, k
>>> KroneckerDelta(i, j)
KroneckerDelta(i, j)
>>> KroneckerDelta(i, i)
1
>>> KroneckerDelta(i, i + 1)
0
>>> KroneckerDelta(i, i + 1 + k)
KroneckerDelta(i, i + k + 1)
# indirect doctest
"""
if delta_range is not None:
dinf, dsup = delta_range
if (dinf - i > 0) == True:
return S.Zero
if (dinf - j > 0) == True:
return S.Zero
if (dsup - i < 0) == True:
return S.Zero
if (dsup - j < 0) == True:
return S.Zero
diff = i - j
if diff.is_zero:
return S.One
elif fuzzy_not(diff.is_zero):
return S.Zero
if i.assumptions0.get("below_fermi") and \
j.assumptions0.get("above_fermi"):
return S.Zero
if j.assumptions0.get("below_fermi") and \
i.assumptions0.get("above_fermi"):
return S.Zero
# to make KroneckerDelta canonical
# following lines will check if inputs are in order
# if not, will return KroneckerDelta with correct order
if i != min(i, j, key=default_sort_key):
if delta_range:
return cls(j, i, delta_range)
else:
return cls(j, i)
@property
def delta_range(self):
if len(self.args) > 2:
return self.args[2]
def _eval_power(self, expt):
if expt.is_positive:
return self
if expt.is_negative and not -expt is S.One:
return 1/self
@property
def is_above_fermi(self):
"""
True if Delta can be non-zero above fermi.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> q = Symbol('q')
>>> KroneckerDelta(p, a).is_above_fermi
True
>>> KroneckerDelta(p, i).is_above_fermi
False
>>> KroneckerDelta(p, q).is_above_fermi
True
See Also
========
is_below_fermi, is_only_below_fermi, is_only_above_fermi
"""
if self.args[0].assumptions0.get("below_fermi"):
return False
if self.args[1].assumptions0.get("below_fermi"):
return False
return True
@property
def is_below_fermi(self):
"""
True if Delta can be non-zero below fermi.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> q = Symbol('q')
>>> KroneckerDelta(p, a).is_below_fermi
False
>>> KroneckerDelta(p, i).is_below_fermi
True
>>> KroneckerDelta(p, q).is_below_fermi
True
See Also
========
is_above_fermi, is_only_above_fermi, is_only_below_fermi
"""
if self.args[0].assumptions0.get("above_fermi"):
return False
if self.args[1].assumptions0.get("above_fermi"):
return False
return True
@property
def is_only_above_fermi(self):
"""
True if Delta is restricted to above fermi.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> q = Symbol('q')
>>> KroneckerDelta(p, a).is_only_above_fermi
True
>>> KroneckerDelta(p, q).is_only_above_fermi
False
>>> KroneckerDelta(p, i).is_only_above_fermi
False
See Also
========
is_above_fermi, is_below_fermi, is_only_below_fermi
"""
return ( self.args[0].assumptions0.get("above_fermi")
or
self.args[1].assumptions0.get("above_fermi")
) or False
@property
def is_only_below_fermi(self):
"""
True if Delta is restricted to below fermi.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> q = Symbol('q')
>>> KroneckerDelta(p, i).is_only_below_fermi
True
>>> KroneckerDelta(p, q).is_only_below_fermi
False
>>> KroneckerDelta(p, a).is_only_below_fermi
False
See Also
========
is_above_fermi, is_below_fermi, is_only_above_fermi
"""
return ( self.args[0].assumptions0.get("below_fermi")
or
self.args[1].assumptions0.get("below_fermi")
) or False
@property
def indices_contain_equal_information(self):
"""
Returns True if indices are either both above or below fermi.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> p = Symbol('p')
>>> q = Symbol('q')
>>> KroneckerDelta(p, q).indices_contain_equal_information
True
>>> KroneckerDelta(p, q+1).indices_contain_equal_information
True
>>> KroneckerDelta(i, p).indices_contain_equal_information
False
"""
if (self.args[0].assumptions0.get("below_fermi") and
self.args[1].assumptions0.get("below_fermi")):
return True
if (self.args[0].assumptions0.get("above_fermi")
and self.args[1].assumptions0.get("above_fermi")):
return True
# if both indices are general we are True, else false
return self.is_below_fermi and self.is_above_fermi
@property
def preferred_index(self):
"""
Returns the index which is preferred to keep in the final expression.
Explanation
===========
The preferred index is the index with more information regarding fermi
level. If indices contain the same information, 'a' is preferred before
'b'.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> j = Symbol('j', below_fermi=True)
>>> p = Symbol('p')
>>> KroneckerDelta(p, i).preferred_index
i
>>> KroneckerDelta(p, a).preferred_index
a
>>> KroneckerDelta(i, j).preferred_index
i
See Also
========
killable_index
"""
if self._get_preferred_index():
return self.args[1]
else:
return self.args[0]
@property
def killable_index(self):
"""
Returns the index which is preferred to substitute in the final
expression.
Explanation
===========
The index to substitute is the index with less information regarding
fermi level. If indices contain the same information, 'a' is preferred
before 'b'.
Examples
========
>>> from sympy.functions.special.tensor_functions import KroneckerDelta
>>> from sympy import Symbol
>>> a = Symbol('a', above_fermi=True)
>>> i = Symbol('i', below_fermi=True)
>>> j = Symbol('j', below_fermi=True)
>>> p = Symbol('p')
>>> KroneckerDelta(p, i).killable_index
p
>>> KroneckerDelta(p, a).killable_index
p
>>> KroneckerDelta(i, j).killable_index
j
See Also
========
preferred_index
"""
if self._get_preferred_index():
return self.args[0]
else:
return self.args[1]
def _get_preferred_index(self):
"""
Returns the index which is preferred to keep in the final expression.
The preferred index is the index with more information regarding fermi
level. If indices contain the same information, index 0 is returned.
"""
if not self.is_above_fermi:
if self.args[0].assumptions0.get("below_fermi"):
return 0
else:
return 1
elif not self.is_below_fermi:
if self.args[0].assumptions0.get("above_fermi"):
return 0
else:
return 1
else:
return 0
@property
def indices(self):
return self.args[0:2]
def _sage_(self):
import sage.all as sage
return sage.kronecker_delta(self.args[0]._sage_(), self.args[1]._sage_())
def _eval_rewrite_as_Piecewise(self, *args, **kwargs):
from sympy.functions.elementary.piecewise import Piecewise
from sympy.core.relational import Ne
i, j = args
return Piecewise((0, Ne(i, j)), (1, True))
|
2840df2f6dfe81eb774468b8543a7e3482860cef930a990156d73bfae616f664 | """ Elliptic Integrals. """
from sympy.core import S, pi, I, Rational
from sympy.core.function import Function, ArgumentIndexError
from sympy.functions.elementary.complexes import sign
from sympy.functions.elementary.hyperbolic import atanh
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.functions.elementary.trigonometric import sin, tan
from sympy.functions.special.gamma_functions import gamma
from sympy.functions.special.hyper import hyper, meijerg
class elliptic_k(Function):
r"""
The complete elliptic integral of the first kind, defined by
.. math:: K(m) = F\left(\tfrac{\pi}{2}\middle| m\right)
where $F\left(z\middle| m\right)$ is the Legendre incomplete
elliptic integral of the first kind.
Explanation
===========
The function $K(m)$ is a single-valued function on the complex
plane with branch cut along the interval $(1, \infty)$.
Note that our notation defines the incomplete elliptic integral
in terms of the parameter $m$ instead of the elliptic modulus
(eccentricity) $k$.
In this case, the parameter $m$ is defined as $m=k^2$.
Examples
========
>>> from sympy import elliptic_k, I
>>> from sympy.abc import m
>>> elliptic_k(0)
pi/2
>>> elliptic_k(1.0 + I)
1.50923695405127 + 0.625146415202697*I
>>> elliptic_k(m).series(n=3)
pi/2 + pi*m/8 + 9*pi*m**2/128 + O(m**3)
See Also
========
elliptic_f
References
==========
.. [1] https://en.wikipedia.org/wiki/Elliptic_integrals
.. [2] http://functions.wolfram.com/EllipticIntegrals/EllipticK
"""
@classmethod
def eval(cls, m):
if m.is_zero:
return pi/2
elif m is S.Half:
return 8*pi**Rational(3, 2)/gamma(Rational(-1, 4))**2
elif m is S.One:
return S.ComplexInfinity
elif m is S.NegativeOne:
return gamma(Rational(1, 4))**2/(4*sqrt(2*pi))
elif m in (S.Infinity, S.NegativeInfinity, I*S.Infinity,
I*S.NegativeInfinity, S.ComplexInfinity):
return S.Zero
if m.is_zero:
return pi*S.Half
def fdiff(self, argindex=1):
m = self.args[0]
return (elliptic_e(m) - (1 - m)*elliptic_k(m))/(2*m*(1 - m))
def _eval_conjugate(self):
m = self.args[0]
if (m.is_real and (m - 1).is_positive) is False:
return self.func(m.conjugate())
def _eval_nseries(self, x, n, logx):
from sympy.simplify import hyperexpand
return hyperexpand(self.rewrite(hyper)._eval_nseries(x, n=n, logx=logx))
def _eval_rewrite_as_hyper(self, m, **kwargs):
return pi*S.Half*hyper((S.Half, S.Half), (S.One,), m)
def _eval_rewrite_as_meijerg(self, m, **kwargs):
return meijerg(((S.Half, S.Half), []), ((S.Zero,), (S.Zero,)), -m)/2
def _eval_is_zero(self):
m = self.args[0]
if m.is_infinite:
return True
def _eval_rewrite_as_Integral(self, *args):
from sympy import Integral, Dummy
t = Dummy('t')
m = self.args[0]
return Integral(1/sqrt(1 - m*sin(t)**2), (t, 0, pi/2))
def _sage_(self):
import sage.all as sage
return sage.elliptic_kc(self.args[0]._sage_())
class elliptic_f(Function):
r"""
The Legendre incomplete elliptic integral of the first
kind, defined by
.. math:: F\left(z\middle| m\right) =
\int_0^z \frac{dt}{\sqrt{1 - m \sin^2 t}}
Explanation
===========
This function reduces to a complete elliptic integral of
the first kind, $K(m)$, when $z = \pi/2$.
Note that our notation defines the incomplete elliptic integral
in terms of the parameter $m$ instead of the elliptic modulus
(eccentricity) $k$.
In this case, the parameter $m$ is defined as $m=k^2$.
Examples
========
>>> from sympy import elliptic_f, I
>>> from sympy.abc import z, m
>>> elliptic_f(z, m).series(z)
z + z**5*(3*m**2/40 - m/30) + m*z**3/6 + O(z**6)
>>> elliptic_f(3.0 + I/2, 1.0 + I)
2.909449841483 + 1.74720545502474*I
See Also
========
elliptic_k
References
==========
.. [1] https://en.wikipedia.org/wiki/Elliptic_integrals
.. [2] http://functions.wolfram.com/EllipticIntegrals/EllipticF
"""
@classmethod
def eval(cls, z, m):
if z.is_zero:
return S.Zero
if m.is_zero:
return z
k = 2*z/pi
if k.is_integer:
return k*elliptic_k(m)
elif m in (S.Infinity, S.NegativeInfinity):
return S.Zero
elif z.could_extract_minus_sign():
return -elliptic_f(-z, m)
def fdiff(self, argindex=1):
z, m = self.args
fm = sqrt(1 - m*sin(z)**2)
if argindex == 1:
return 1/fm
elif argindex == 2:
return (elliptic_e(z, m)/(2*m*(1 - m)) - elliptic_f(z, m)/(2*m) -
sin(2*z)/(4*(1 - m)*fm))
raise ArgumentIndexError(self, argindex)
def _eval_conjugate(self):
z, m = self.args
if (m.is_real and (m - 1).is_positive) is False:
return self.func(z.conjugate(), m.conjugate())
def _eval_rewrite_as_Integral(self, *args):
from sympy import Integral, Dummy
t = Dummy('t')
z, m = self.args[0], self.args[1]
return Integral(1/(sqrt(1 - m*sin(t)**2)), (t, 0, z))
def _eval_is_zero(self):
z, m = self.args
if z.is_zero:
return True
if m.is_extended_real and m.is_infinite:
return True
class elliptic_e(Function):
r"""
Called with two arguments $z$ and $m$, evaluates the
incomplete elliptic integral of the second kind, defined by
.. math:: E\left(z\middle| m\right) = \int_0^z \sqrt{1 - m \sin^2 t} dt
Called with a single argument $m$, evaluates the Legendre complete
elliptic integral of the second kind
.. math:: E(m) = E\left(\tfrac{\pi}{2}\middle| m\right)
Explanation
===========
The function $E(m)$ is a single-valued function on the complex
plane with branch cut along the interval $(1, \infty)$.
Note that our notation defines the incomplete elliptic integral
in terms of the parameter $m$ instead of the elliptic modulus
(eccentricity) $k$.
In this case, the parameter $m$ is defined as $m=k^2$.
Examples
========
>>> from sympy import elliptic_e, I
>>> from sympy.abc import z, m
>>> elliptic_e(z, m).series(z)
z + z**5*(-m**2/40 + m/30) - m*z**3/6 + O(z**6)
>>> elliptic_e(m).series(n=4)
pi/2 - pi*m/8 - 3*pi*m**2/128 - 5*pi*m**3/512 + O(m**4)
>>> elliptic_e(1 + I, 2 - I/2).n()
1.55203744279187 + 0.290764986058437*I
>>> elliptic_e(0)
pi/2
>>> elliptic_e(2.0 - I)
0.991052601328069 + 0.81879421395609*I
References
==========
.. [1] https://en.wikipedia.org/wiki/Elliptic_integrals
.. [2] http://functions.wolfram.com/EllipticIntegrals/EllipticE2
.. [3] http://functions.wolfram.com/EllipticIntegrals/EllipticE
"""
@classmethod
def eval(cls, m, z=None):
if z is not None:
z, m = m, z
k = 2*z/pi
if m.is_zero:
return z
if z.is_zero:
return S.Zero
elif k.is_integer:
return k*elliptic_e(m)
elif m in (S.Infinity, S.NegativeInfinity):
return S.ComplexInfinity
elif z.could_extract_minus_sign():
return -elliptic_e(-z, m)
else:
if m.is_zero:
return pi/2
elif m is S.One:
return S.One
elif m is S.Infinity:
return I*S.Infinity
elif m is S.NegativeInfinity:
return S.Infinity
elif m is S.ComplexInfinity:
return S.ComplexInfinity
def fdiff(self, argindex=1):
if len(self.args) == 2:
z, m = self.args
if argindex == 1:
return sqrt(1 - m*sin(z)**2)
elif argindex == 2:
return (elliptic_e(z, m) - elliptic_f(z, m))/(2*m)
else:
m = self.args[0]
if argindex == 1:
return (elliptic_e(m) - elliptic_k(m))/(2*m)
raise ArgumentIndexError(self, argindex)
def _eval_conjugate(self):
if len(self.args) == 2:
z, m = self.args
if (m.is_real and (m - 1).is_positive) is False:
return self.func(z.conjugate(), m.conjugate())
else:
m = self.args[0]
if (m.is_real and (m - 1).is_positive) is False:
return self.func(m.conjugate())
def _eval_nseries(self, x, n, logx):
from sympy.simplify import hyperexpand
if len(self.args) == 1:
return hyperexpand(self.rewrite(hyper)._eval_nseries(x, n=n, logx=logx))
return super()._eval_nseries(x, n=n, logx=logx)
def _eval_rewrite_as_hyper(self, *args, **kwargs):
if len(args) == 1:
m = args[0]
return (pi/2)*hyper((Rational(-1, 2), S.Half), (S.One,), m)
def _eval_rewrite_as_meijerg(self, *args, **kwargs):
if len(args) == 1:
m = args[0]
return -meijerg(((S.Half, Rational(3, 2)), []), \
((S.Zero,), (S.Zero,)), -m)/4
def _eval_rewrite_as_Integral(self, *args):
from sympy import Integral, Dummy
z, m = (pi/2, self.args[0]) if len(self.args) == 1 else self.args
t = Dummy('t')
return Integral(sqrt(1 - m*sin(t)**2), (t, 0, z))
class elliptic_pi(Function):
r"""
Called with three arguments $n$, $z$ and $m$, evaluates the
Legendre incomplete elliptic integral of the third kind, defined by
.. math:: \Pi\left(n; z\middle| m\right) = \int_0^z \frac{dt}
{\left(1 - n \sin^2 t\right) \sqrt{1 - m \sin^2 t}}
Called with two arguments $n$ and $m$, evaluates the complete
elliptic integral of the third kind:
.. math:: \Pi\left(n\middle| m\right) =
\Pi\left(n; \tfrac{\pi}{2}\middle| m\right)
Explanation
===========
Note that our notation defines the incomplete elliptic integral
in terms of the parameter $m$ instead of the elliptic modulus
(eccentricity) $k$.
In this case, the parameter $m$ is defined as $m=k^2$.
Examples
========
>>> from sympy import elliptic_pi, I
>>> from sympy.abc import z, n, m
>>> elliptic_pi(n, z, m).series(z, n=4)
z + z**3*(m/6 + n/3) + O(z**4)
>>> elliptic_pi(0.5 + I, 1.0 - I, 1.2)
2.50232379629182 - 0.760939574180767*I
>>> elliptic_pi(0, 0)
pi/2
>>> elliptic_pi(1.0 - I/3, 2.0 + I)
3.29136443417283 + 0.32555634906645*I
References
==========
.. [1] https://en.wikipedia.org/wiki/Elliptic_integrals
.. [2] http://functions.wolfram.com/EllipticIntegrals/EllipticPi3
.. [3] http://functions.wolfram.com/EllipticIntegrals/EllipticPi
"""
@classmethod
def eval(cls, n, m, z=None):
if z is not None:
n, z, m = n, m, z
if n.is_zero:
return elliptic_f(z, m)
elif n is S.One:
return (elliptic_f(z, m) +
(sqrt(1 - m*sin(z)**2)*tan(z) -
elliptic_e(z, m))/(1 - m))
k = 2*z/pi
if k.is_integer:
return k*elliptic_pi(n, m)
elif m.is_zero:
return atanh(sqrt(n - 1)*tan(z))/sqrt(n - 1)
elif n == m:
return (elliptic_f(z, n) - elliptic_pi(1, z, n) +
tan(z)/sqrt(1 - n*sin(z)**2))
elif n in (S.Infinity, S.NegativeInfinity):
return S.Zero
elif m in (S.Infinity, S.NegativeInfinity):
return S.Zero
elif z.could_extract_minus_sign():
return -elliptic_pi(n, -z, m)
if n.is_zero:
return elliptic_f(z, m)
if m.is_extended_real and m.is_infinite or \
n.is_extended_real and n.is_infinite:
return S.Zero
else:
if n.is_zero:
return elliptic_k(m)
elif n is S.One:
return S.ComplexInfinity
elif m.is_zero:
return pi/(2*sqrt(1 - n))
elif m == S.One:
return S.NegativeInfinity/sign(n - 1)
elif n == m:
return elliptic_e(n)/(1 - n)
elif n in (S.Infinity, S.NegativeInfinity):
return S.Zero
elif m in (S.Infinity, S.NegativeInfinity):
return S.Zero
if n.is_zero:
return elliptic_k(m)
if m.is_extended_real and m.is_infinite or \
n.is_extended_real and n.is_infinite:
return S.Zero
def _eval_conjugate(self):
if len(self.args) == 3:
n, z, m = self.args
if (n.is_real and (n - 1).is_positive) is False and \
(m.is_real and (m - 1).is_positive) is False:
return self.func(n.conjugate(), z.conjugate(), m.conjugate())
else:
n, m = self.args
return self.func(n.conjugate(), m.conjugate())
def fdiff(self, argindex=1):
if len(self.args) == 3:
n, z, m = self.args
fm, fn = sqrt(1 - m*sin(z)**2), 1 - n*sin(z)**2
if argindex == 1:
return (elliptic_e(z, m) + (m - n)*elliptic_f(z, m)/n +
(n**2 - m)*elliptic_pi(n, z, m)/n -
n*fm*sin(2*z)/(2*fn))/(2*(m - n)*(n - 1))
elif argindex == 2:
return 1/(fm*fn)
elif argindex == 3:
return (elliptic_e(z, m)/(m - 1) +
elliptic_pi(n, z, m) -
m*sin(2*z)/(2*(m - 1)*fm))/(2*(n - m))
else:
n, m = self.args
if argindex == 1:
return (elliptic_e(m) + (m - n)*elliptic_k(m)/n +
(n**2 - m)*elliptic_pi(n, m)/n)/(2*(m - n)*(n - 1))
elif argindex == 2:
return (elliptic_e(m)/(m - 1) + elliptic_pi(n, m))/(2*(n - m))
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_Integral(self, *args):
from sympy import Integral, Dummy
if len(self.args) == 2:
n, m, z = self.args[0], self.args[1], pi/2
else:
n, z, m = self.args
t = Dummy('t')
return Integral(1/((1 - n*sin(t)**2)*sqrt(1 - m*sin(t)**2)), (t, 0, z))
|
1ff9d87a1464b051331aae06226360adfe3e75cc1bdf4b908bb7faf295b9c91c | """ This module contains various functions that are special cases
of incomplete gamma functions. It should probably be renamed. """
from sympy.core import Add, S, sympify, cacheit, pi, I, Rational
from sympy.core.function import Function, ArgumentIndexError
from sympy.core.symbol import Symbol
from sympy.functions.combinatorial.factorials import factorial
from sympy.functions.elementary.integers import floor
from sympy.functions.elementary.miscellaneous import sqrt, root
from sympy.functions.elementary.exponential import exp, log
from sympy.functions.elementary.complexes import polar_lift
from sympy.functions.elementary.hyperbolic import cosh, sinh
from sympy.functions.elementary.trigonometric import cos, sin, sinc
from sympy.functions.special.hyper import hyper, meijerg
# TODO series expansions
# TODO see the "Note:" in Ei
# Helper function
def real_to_real_as_real_imag(self, deep=True, **hints):
if self.args[0].is_extended_real:
if deep:
hints['complex'] = False
return (self.expand(deep, **hints), S.Zero)
else:
return (self, S.Zero)
if deep:
x, y = self.args[0].expand(deep, **hints).as_real_imag()
else:
x, y = self.args[0].as_real_imag()
re = (self.func(x + I*y) + self.func(x - I*y))/2
im = (self.func(x + I*y) - self.func(x - I*y))/(2*I)
return (re, im)
###############################################################################
################################ ERROR FUNCTION ###############################
###############################################################################
class erf(Function):
r"""
The Gauss error function.
Explanation
===========
This function is defined as:
.. math ::
\mathrm{erf}(x) = \frac{2}{\sqrt{\pi}} \int_0^x e^{-t^2} \mathrm{d}t.
Examples
========
>>> from sympy import I, oo, erf
>>> from sympy.abc import z
Several special values are known:
>>> erf(0)
0
>>> erf(oo)
1
>>> erf(-oo)
-1
>>> erf(I*oo)
oo*I
>>> erf(-I*oo)
-oo*I
In general one can pull out factors of -1 and $I$ from the argument:
>>> erf(-z)
-erf(z)
The error function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(erf(z))
erf(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(erf(z), z)
2*exp(-z**2)/sqrt(pi)
We can numerically evaluate the error function to arbitrary precision
on the whole complex plane:
>>> erf(4).evalf(30)
0.999999984582742099719981147840
>>> erf(-4*I).evalf(30)
-1296959.73071763923152794095062*I
See Also
========
erfc: Complementary error function.
erfi: Imaginary error function.
erf2: Two-argument error function.
erfinv: Inverse error function.
erfcinv: Inverse Complementary error function.
erf2inv: Inverse two-argument error function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Error_function
.. [2] http://dlmf.nist.gov/7
.. [3] http://mathworld.wolfram.com/Erf.html
.. [4] http://functions.wolfram.com/GammaBetaErf/Erf
"""
unbranched = True
def fdiff(self, argindex=1):
if argindex == 1:
return 2*exp(-self.args[0]**2)/sqrt(S.Pi)
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return erfinv
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.One
elif arg is S.NegativeInfinity:
return S.NegativeOne
elif arg.is_zero:
return S.Zero
if isinstance(arg, erfinv):
return arg.args[0]
if isinstance(arg, erfcinv):
return S.One - arg.args[0]
if arg.is_zero:
return S.Zero
# Only happens with unevaluated erf2inv
if isinstance(arg, erf2inv) and arg.args[0].is_zero:
return arg.args[1]
# Try to pull out factors of I
t = arg.extract_multiplicatively(S.ImaginaryUnit)
if t is S.Infinity or t is S.NegativeInfinity:
return arg
# Try to pull out factors of -1
if arg.could_extract_minus_sign():
return -cls(-arg)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
k = floor((n - 1)/S(2))
if len(previous_terms) > 2:
return -previous_terms[-2] * x**2 * (n - 2)/(n*k)
else:
return 2*(-1)**k * x**n/(n*factorial(k)*sqrt(S.Pi))
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def _eval_is_real(self):
return self.args[0].is_extended_real
def _eval_is_finite(self):
if self.args[0].is_finite:
return True
else:
return self.args[0].is_extended_real
def _eval_is_zero(self):
if self.args[0].is_zero:
return True
def _eval_rewrite_as_uppergamma(self, z, **kwargs):
from sympy import uppergamma
return sqrt(z**2)/z*(S.One - uppergamma(S.Half, z**2)/sqrt(S.Pi))
def _eval_rewrite_as_fresnels(self, z, **kwargs):
arg = (S.One - S.ImaginaryUnit)*z/sqrt(pi)
return (S.One + S.ImaginaryUnit)*(fresnelc(arg) - I*fresnels(arg))
def _eval_rewrite_as_fresnelc(self, z, **kwargs):
arg = (S.One - S.ImaginaryUnit)*z/sqrt(pi)
return (S.One + S.ImaginaryUnit)*(fresnelc(arg) - I*fresnels(arg))
def _eval_rewrite_as_meijerg(self, z, **kwargs):
return z/sqrt(pi)*meijerg([S.Half], [], [0], [Rational(-1, 2)], z**2)
def _eval_rewrite_as_hyper(self, z, **kwargs):
return 2*z/sqrt(pi)*hyper([S.Half], [3*S.Half], -z**2)
def _eval_rewrite_as_expint(self, z, **kwargs):
return sqrt(z**2)/z - z*expint(S.Half, z**2)/sqrt(S.Pi)
def _eval_rewrite_as_tractable(self, z, **kwargs):
return S.One - _erfs(z)*exp(-z**2)
def _eval_rewrite_as_erfc(self, z, **kwargs):
return S.One - erfc(z)
def _eval_rewrite_as_erfi(self, z, **kwargs):
return -I*erfi(I*z)
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return 2*x/sqrt(pi)
else:
return self.func(arg)
as_real_imag = real_to_real_as_real_imag
class erfc(Function):
r"""
Complementary Error Function.
Explanation
===========
The function is defined as:
.. math ::
\mathrm{erfc}(x) = \frac{2}{\sqrt{\pi}} \int_x^\infty e^{-t^2} \mathrm{d}t
Examples
========
>>> from sympy import I, oo, erfc
>>> from sympy.abc import z
Several special values are known:
>>> erfc(0)
1
>>> erfc(oo)
0
>>> erfc(-oo)
2
>>> erfc(I*oo)
-oo*I
>>> erfc(-I*oo)
oo*I
The error function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(erfc(z))
erfc(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(erfc(z), z)
-2*exp(-z**2)/sqrt(pi)
It also follows
>>> erfc(-z)
2 - erfc(z)
We can numerically evaluate the complementary error function to arbitrary
precision on the whole complex plane:
>>> erfc(4).evalf(30)
0.0000000154172579002800188521596734869
>>> erfc(4*I).evalf(30)
1.0 - 1296959.73071763923152794095062*I
See Also
========
erf: Gaussian error function.
erfi: Imaginary error function.
erf2: Two-argument error function.
erfinv: Inverse error function.
erfcinv: Inverse Complementary error function.
erf2inv: Inverse two-argument error function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Error_function
.. [2] http://dlmf.nist.gov/7
.. [3] http://mathworld.wolfram.com/Erfc.html
.. [4] http://functions.wolfram.com/GammaBetaErf/Erfc
"""
unbranched = True
def fdiff(self, argindex=1):
if argindex == 1:
return -2*exp(-self.args[0]**2)/sqrt(S.Pi)
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return erfcinv
@classmethod
def eval(cls, arg):
if arg.is_Number:
if arg is S.NaN:
return S.NaN
elif arg is S.Infinity:
return S.Zero
elif arg.is_zero:
return S.One
if isinstance(arg, erfinv):
return S.One - arg.args[0]
if isinstance(arg, erfcinv):
return arg.args[0]
if arg.is_zero:
return S.One
# Try to pull out factors of I
t = arg.extract_multiplicatively(S.ImaginaryUnit)
if t is S.Infinity or t is S.NegativeInfinity:
return -arg
# Try to pull out factors of -1
if arg.could_extract_minus_sign():
return S(2) - cls(-arg)
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n == 0:
return S.One
elif n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
k = floor((n - 1)/S(2))
if len(previous_terms) > 2:
return -previous_terms[-2] * x**2 * (n - 2)/(n*k)
else:
return -2*(-1)**k * x**n/(n*factorial(k)*sqrt(S.Pi))
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def _eval_is_real(self):
return self.args[0].is_extended_real
def _eval_rewrite_as_tractable(self, z, **kwargs):
return self.rewrite(erf).rewrite("tractable", deep=True)
def _eval_rewrite_as_erf(self, z, **kwargs):
return S.One - erf(z)
def _eval_rewrite_as_erfi(self, z, **kwargs):
return S.One + I*erfi(I*z)
def _eval_rewrite_as_fresnels(self, z, **kwargs):
arg = (S.One - S.ImaginaryUnit)*z/sqrt(pi)
return S.One - (S.One + S.ImaginaryUnit)*(fresnelc(arg) - I*fresnels(arg))
def _eval_rewrite_as_fresnelc(self, z, **kwargs):
arg = (S.One-S.ImaginaryUnit)*z/sqrt(pi)
return S.One - (S.One + S.ImaginaryUnit)*(fresnelc(arg) - I*fresnels(arg))
def _eval_rewrite_as_meijerg(self, z, **kwargs):
return S.One - z/sqrt(pi)*meijerg([S.Half], [], [0], [Rational(-1, 2)], z**2)
def _eval_rewrite_as_hyper(self, z, **kwargs):
return S.One - 2*z/sqrt(pi)*hyper([S.Half], [3*S.Half], -z**2)
def _eval_rewrite_as_uppergamma(self, z, **kwargs):
from sympy import uppergamma
return S.One - sqrt(z**2)/z*(S.One - uppergamma(S.Half, z**2)/sqrt(S.Pi))
def _eval_rewrite_as_expint(self, z, **kwargs):
return S.One - sqrt(z**2)/z + z*expint(S.Half, z**2)/sqrt(S.Pi)
def _eval_expand_func(self, **hints):
return self.rewrite(erf)
def _eval_as_leading_term(self, x):
from sympy import Order
arg = self.args[0].as_leading_term(x)
if x in arg.free_symbols and Order(1, x).contains(arg):
return S.One
else:
return self.func(arg)
as_real_imag = real_to_real_as_real_imag
class erfi(Function):
r"""
Imaginary error function.
Explanation
===========
The function erfi is defined as:
.. math ::
\mathrm{erfi}(x) = \frac{2}{\sqrt{\pi}} \int_0^x e^{t^2} \mathrm{d}t
Examples
========
>>> from sympy import I, oo, erfi
>>> from sympy.abc import z
Several special values are known:
>>> erfi(0)
0
>>> erfi(oo)
oo
>>> erfi(-oo)
-oo
>>> erfi(I*oo)
I
>>> erfi(-I*oo)
-I
In general one can pull out factors of -1 and $I$ from the argument:
>>> erfi(-z)
-erfi(z)
>>> from sympy import conjugate
>>> conjugate(erfi(z))
erfi(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(erfi(z), z)
2*exp(z**2)/sqrt(pi)
We can numerically evaluate the imaginary error function to arbitrary
precision on the whole complex plane:
>>> erfi(2).evalf(30)
18.5648024145755525987042919132
>>> erfi(-2*I).evalf(30)
-0.995322265018952734162069256367*I
See Also
========
erf: Gaussian error function.
erfc: Complementary error function.
erf2: Two-argument error function.
erfinv: Inverse error function.
erfcinv: Inverse Complementary error function.
erf2inv: Inverse two-argument error function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Error_function
.. [2] http://mathworld.wolfram.com/Erfi.html
.. [3] http://functions.wolfram.com/GammaBetaErf/Erfi
"""
unbranched = True
def fdiff(self, argindex=1):
if argindex == 1:
return 2*exp(self.args[0]**2)/sqrt(S.Pi)
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, z):
if z.is_Number:
if z is S.NaN:
return S.NaN
elif z.is_zero:
return S.Zero
elif z is S.Infinity:
return S.Infinity
if z.is_zero:
return S.Zero
# Try to pull out factors of -1
if z.could_extract_minus_sign():
return -cls(-z)
# Try to pull out factors of I
nz = z.extract_multiplicatively(I)
if nz is not None:
if nz is S.Infinity:
return I
if isinstance(nz, erfinv):
return I*nz.args[0]
if isinstance(nz, erfcinv):
return I*(S.One - nz.args[0])
# Only happens with unevaluated erf2inv
if isinstance(nz, erf2inv) and nz.args[0].is_zero:
return I*nz.args[1]
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0 or n % 2 == 0:
return S.Zero
else:
x = sympify(x)
k = floor((n - 1)/S(2))
if len(previous_terms) > 2:
return previous_terms[-2] * x**2 * (n - 2)/(n*k)
else:
return 2 * x**n/(n*factorial(k)*sqrt(S.Pi))
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
def _eval_is_extended_real(self):
return self.args[0].is_extended_real
def _eval_is_zero(self):
if self.args[0].is_zero:
return True
def _eval_rewrite_as_tractable(self, z, **kwargs):
return self.rewrite(erf).rewrite("tractable", deep=True)
def _eval_rewrite_as_erf(self, z, **kwargs):
return -I*erf(I*z)
def _eval_rewrite_as_erfc(self, z, **kwargs):
return I*erfc(I*z) - I
def _eval_rewrite_as_fresnels(self, z, **kwargs):
arg = (S.One + S.ImaginaryUnit)*z/sqrt(pi)
return (S.One - S.ImaginaryUnit)*(fresnelc(arg) - I*fresnels(arg))
def _eval_rewrite_as_fresnelc(self, z, **kwargs):
arg = (S.One + S.ImaginaryUnit)*z/sqrt(pi)
return (S.One - S.ImaginaryUnit)*(fresnelc(arg) - I*fresnels(arg))
def _eval_rewrite_as_meijerg(self, z, **kwargs):
return z/sqrt(pi)*meijerg([S.Half], [], [0], [Rational(-1, 2)], -z**2)
def _eval_rewrite_as_hyper(self, z, **kwargs):
return 2*z/sqrt(pi)*hyper([S.Half], [3*S.Half], z**2)
def _eval_rewrite_as_uppergamma(self, z, **kwargs):
from sympy import uppergamma
return sqrt(-z**2)/z*(uppergamma(S.Half, -z**2)/sqrt(S.Pi) - S.One)
def _eval_rewrite_as_expint(self, z, **kwargs):
return sqrt(-z**2)/z - z*expint(S.Half, -z**2)/sqrt(S.Pi)
def _eval_expand_func(self, **hints):
return self.rewrite(erf)
as_real_imag = real_to_real_as_real_imag
class erf2(Function):
r"""
Two-argument error function.
Explanation
===========
This function is defined as:
.. math ::
\mathrm{erf2}(x, y) = \frac{2}{\sqrt{\pi}} \int_x^y e^{-t^2} \mathrm{d}t
Examples
========
>>> from sympy import oo, erf2
>>> from sympy.abc import x, y
Several special values are known:
>>> erf2(0, 0)
0
>>> erf2(x, x)
0
>>> erf2(x, oo)
1 - erf(x)
>>> erf2(x, -oo)
-erf(x) - 1
>>> erf2(oo, y)
erf(y) - 1
>>> erf2(-oo, y)
erf(y) + 1
In general one can pull out factors of -1:
>>> erf2(-x, -y)
-erf2(x, y)
The error function obeys the mirror symmetry:
>>> from sympy import conjugate
>>> conjugate(erf2(x, y))
erf2(conjugate(x), conjugate(y))
Differentiation with respect to $x$, $y$ is supported:
>>> from sympy import diff
>>> diff(erf2(x, y), x)
-2*exp(-x**2)/sqrt(pi)
>>> diff(erf2(x, y), y)
2*exp(-y**2)/sqrt(pi)
See Also
========
erf: Gaussian error function.
erfc: Complementary error function.
erfi: Imaginary error function.
erfinv: Inverse error function.
erfcinv: Inverse Complementary error function.
erf2inv: Inverse two-argument error function.
References
==========
.. [1] http://functions.wolfram.com/GammaBetaErf/Erf2/
"""
def fdiff(self, argindex):
x, y = self.args
if argindex == 1:
return -2*exp(-x**2)/sqrt(S.Pi)
elif argindex == 2:
return 2*exp(-y**2)/sqrt(S.Pi)
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, x, y):
I = S.Infinity
N = S.NegativeInfinity
O = S.Zero
if x is S.NaN or y is S.NaN:
return S.NaN
elif x == y:
return S.Zero
elif (x is I or x is N or x is O) or (y is I or y is N or y is O):
return erf(y) - erf(x)
if isinstance(y, erf2inv) and y.args[0] == x:
return y.args[1]
if x.is_zero or y.is_zero or x.is_extended_real and x.is_infinite or \
y.is_extended_real and y.is_infinite:
return erf(y) - erf(x)
#Try to pull out -1 factor
sign_x = x.could_extract_minus_sign()
sign_y = y.could_extract_minus_sign()
if (sign_x and sign_y):
return -cls(-x, -y)
elif (sign_x or sign_y):
return erf(y)-erf(x)
def _eval_conjugate(self):
return self.func(self.args[0].conjugate(), self.args[1].conjugate())
def _eval_is_extended_real(self):
return self.args[0].is_extended_real and self.args[1].is_extended_real
def _eval_rewrite_as_erf(self, x, y, **kwargs):
return erf(y) - erf(x)
def _eval_rewrite_as_erfc(self, x, y, **kwargs):
return erfc(x) - erfc(y)
def _eval_rewrite_as_erfi(self, x, y, **kwargs):
return I*(erfi(I*x)-erfi(I*y))
def _eval_rewrite_as_fresnels(self, x, y, **kwargs):
return erf(y).rewrite(fresnels) - erf(x).rewrite(fresnels)
def _eval_rewrite_as_fresnelc(self, x, y, **kwargs):
return erf(y).rewrite(fresnelc) - erf(x).rewrite(fresnelc)
def _eval_rewrite_as_meijerg(self, x, y, **kwargs):
return erf(y).rewrite(meijerg) - erf(x).rewrite(meijerg)
def _eval_rewrite_as_hyper(self, x, y, **kwargs):
return erf(y).rewrite(hyper) - erf(x).rewrite(hyper)
def _eval_rewrite_as_uppergamma(self, x, y, **kwargs):
from sympy import uppergamma
return (sqrt(y**2)/y*(S.One - uppergamma(S.Half, y**2)/sqrt(S.Pi)) -
sqrt(x**2)/x*(S.One - uppergamma(S.Half, x**2)/sqrt(S.Pi)))
def _eval_rewrite_as_expint(self, x, y, **kwargs):
return erf(y).rewrite(expint) - erf(x).rewrite(expint)
def _eval_expand_func(self, **hints):
return self.rewrite(erf)
class erfinv(Function):
r"""
Inverse Error Function. The erfinv function is defined as:
.. math ::
\mathrm{erf}(x) = y \quad \Rightarrow \quad \mathrm{erfinv}(y) = x
Examples
========
>>> from sympy import erfinv
>>> from sympy.abc import x
Several special values are known:
>>> erfinv(0)
0
>>> erfinv(1)
oo
Differentiation with respect to $x$ is supported:
>>> from sympy import diff
>>> diff(erfinv(x), x)
sqrt(pi)*exp(erfinv(x)**2)/2
We can numerically evaluate the inverse error function to arbitrary
precision on [-1, 1]:
>>> erfinv(0.2).evalf(30)
0.179143454621291692285822705344
See Also
========
erf: Gaussian error function.
erfc: Complementary error function.
erfi: Imaginary error function.
erf2: Two-argument error function.
erfcinv: Inverse Complementary error function.
erf2inv: Inverse two-argument error function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Error_function#Inverse_functions
.. [2] http://functions.wolfram.com/GammaBetaErf/InverseErf/
"""
def fdiff(self, argindex =1):
if argindex == 1:
return sqrt(S.Pi)*exp(self.func(self.args[0])**2)*S.Half
else :
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return erf
@classmethod
def eval(cls, z):
if z is S.NaN:
return S.NaN
elif z is S.NegativeOne:
return S.NegativeInfinity
elif z.is_zero:
return S.Zero
elif z is S.One:
return S.Infinity
if isinstance(z, erf) and z.args[0].is_extended_real:
return z.args[0]
if z.is_zero:
return S.Zero
# Try to pull out factors of -1
nz = z.extract_multiplicatively(-1)
if nz is not None and (isinstance(nz, erf) and (nz.args[0]).is_extended_real):
return -nz.args[0]
def _eval_rewrite_as_erfcinv(self, z, **kwargs):
return erfcinv(1-z)
def _eval_is_zero(self):
if self.args[0].is_zero:
return True
class erfcinv (Function):
r"""
Inverse Complementary Error Function. The erfcinv function is defined as:
.. math ::
\mathrm{erfc}(x) = y \quad \Rightarrow \quad \mathrm{erfcinv}(y) = x
Examples
========
>>> from sympy import erfcinv
>>> from sympy.abc import x
Several special values are known:
>>> erfcinv(1)
0
>>> erfcinv(0)
oo
Differentiation with respect to $x$ is supported:
>>> from sympy import diff
>>> diff(erfcinv(x), x)
-sqrt(pi)*exp(erfcinv(x)**2)/2
See Also
========
erf: Gaussian error function.
erfc: Complementary error function.
erfi: Imaginary error function.
erf2: Two-argument error function.
erfinv: Inverse error function.
erf2inv: Inverse two-argument error function.
References
==========
.. [1] https://en.wikipedia.org/wiki/Error_function#Inverse_functions
.. [2] http://functions.wolfram.com/GammaBetaErf/InverseErfc/
"""
def fdiff(self, argindex =1):
if argindex == 1:
return -sqrt(S.Pi)*exp(self.func(self.args[0])**2)*S.Half
else:
raise ArgumentIndexError(self, argindex)
def inverse(self, argindex=1):
"""
Returns the inverse of this function.
"""
return erfc
@classmethod
def eval(cls, z):
if z is S.NaN:
return S.NaN
elif z.is_zero:
return S.Infinity
elif z is S.One:
return S.Zero
elif z == 2:
return S.NegativeInfinity
if z.is_zero:
return S.Infinity
def _eval_rewrite_as_erfinv(self, z, **kwargs):
return erfinv(1-z)
class erf2inv(Function):
r"""
Two-argument Inverse error function. The erf2inv function is defined as:
.. math ::
\mathrm{erf2}(x, w) = y \quad \Rightarrow \quad \mathrm{erf2inv}(x, y) = w
Examples
========
>>> from sympy import erf2inv, oo
>>> from sympy.abc import x, y
Several special values are known:
>>> erf2inv(0, 0)
0
>>> erf2inv(1, 0)
1
>>> erf2inv(0, 1)
oo
>>> erf2inv(0, y)
erfinv(y)
>>> erf2inv(oo, y)
erfcinv(-y)
Differentiation with respect to $x$ and $y$ is supported:
>>> from sympy import diff
>>> diff(erf2inv(x, y), x)
exp(-x**2 + erf2inv(x, y)**2)
>>> diff(erf2inv(x, y), y)
sqrt(pi)*exp(erf2inv(x, y)**2)/2
See Also
========
erf: Gaussian error function.
erfc: Complementary error function.
erfi: Imaginary error function.
erf2: Two-argument error function.
erfinv: Inverse error function.
erfcinv: Inverse complementary error function.
References
==========
.. [1] http://functions.wolfram.com/GammaBetaErf/InverseErf2/
"""
def fdiff(self, argindex):
x, y = self.args
if argindex == 1:
return exp(self.func(x,y)**2-x**2)
elif argindex == 2:
return sqrt(S.Pi)*S.Half*exp(self.func(x,y)**2)
else:
raise ArgumentIndexError(self, argindex)
@classmethod
def eval(cls, x, y):
if x is S.NaN or y is S.NaN:
return S.NaN
elif x.is_zero and y.is_zero:
return S.Zero
elif x.is_zero and y is S.One:
return S.Infinity
elif x is S.One and y.is_zero:
return S.One
elif x.is_zero:
return erfinv(y)
elif x is S.Infinity:
return erfcinv(-y)
elif y.is_zero:
return x
elif y is S.Infinity:
return erfinv(x)
if x.is_zero:
if y.is_zero:
return S.Zero
else:
return erfinv(y)
if y.is_zero:
return x
def _eval_is_zero(self):
x, y = self.args
if x.is_zero and y.is_zero:
return True
###############################################################################
#################### EXPONENTIAL INTEGRALS ####################################
###############################################################################
class Ei(Function):
r"""
The classical exponential integral.
Explanation
===========
For use in SymPy, this function is defined as
.. math:: \operatorname{Ei}(x) = \sum_{n=1}^\infty \frac{x^n}{n\, n!}
+ \log(x) + \gamma,
where $\gamma$ is the Euler-Mascheroni constant.
If $x$ is a polar number, this defines an analytic function on the
Riemann surface of the logarithm. Otherwise this defines an analytic
function in the cut plane $\mathbb{C} \setminus (-\infty, 0]$.
**Background**
The name exponential integral comes from the following statement:
.. math:: \operatorname{Ei}(x) = \int_{-\infty}^x \frac{e^t}{t} \mathrm{d}t
If the integral is interpreted as a Cauchy principal value, this statement
holds for $x > 0$ and $\operatorname{Ei}(x)$ as defined above.
Examples
========
>>> from sympy import Ei, polar_lift, exp_polar, I, pi
>>> from sympy.abc import x
>>> Ei(-1)
Ei(-1)
This yields a real value:
>>> Ei(-1).n(chop=True)
-0.219383934395520
On the other hand the analytic continuation is not real:
>>> Ei(polar_lift(-1)).n(chop=True)
-0.21938393439552 + 3.14159265358979*I
The exponential integral has a logarithmic branch point at the origin:
>>> Ei(x*exp_polar(2*I*pi))
Ei(x) + 2*I*pi
Differentiation is supported:
>>> Ei(x).diff(x)
exp(x)/x
The exponential integral is related to many other special functions.
For example:
>>> from sympy import expint, Shi
>>> Ei(x).rewrite(expint)
-expint(1, x*exp_polar(I*pi)) - I*pi
>>> Ei(x).rewrite(Shi)
Chi(x) + Shi(x)
See Also
========
expint: Generalised exponential integral.
E1: Special case of the generalised exponential integral.
li: Logarithmic integral.
Li: Offset logarithmic integral.
Si: Sine integral.
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
uppergamma: Upper incomplete gamma function.
References
==========
.. [1] http://dlmf.nist.gov/6.6
.. [2] https://en.wikipedia.org/wiki/Exponential_integral
.. [3] Abramowitz & Stegun, section 5: http://people.math.sfu.ca/~cbm/aands/page_228.htm
"""
@classmethod
def eval(cls, z):
if z.is_zero:
return S.NegativeInfinity
elif z is S.Infinity:
return S.Infinity
elif z is S.NegativeInfinity:
return S.Zero
if z.is_zero:
return S.NegativeInfinity
nz, n = z.extract_branch_factor()
if n:
return Ei(nz) + 2*I*pi*n
def fdiff(self, argindex=1):
from sympy import unpolarify
arg = unpolarify(self.args[0])
if argindex == 1:
return exp(arg)/arg
else:
raise ArgumentIndexError(self, argindex)
def _eval_evalf(self, prec):
if (self.args[0]/polar_lift(-1)).is_positive:
return Function._eval_evalf(self, prec) + (I*pi)._eval_evalf(prec)
return Function._eval_evalf(self, prec)
def _eval_rewrite_as_uppergamma(self, z, **kwargs):
from sympy import uppergamma
# XXX this does not currently work usefully because uppergamma
# immediately turns into expint
return -uppergamma(0, polar_lift(-1)*z) - I*pi
def _eval_rewrite_as_expint(self, z, **kwargs):
return -expint(1, polar_lift(-1)*z) - I*pi
def _eval_rewrite_as_li(self, z, **kwargs):
if isinstance(z, log):
return li(z.args[0])
# TODO:
# Actually it only holds that:
# Ei(z) = li(exp(z))
# for -pi < imag(z) <= pi
return li(exp(z))
def _eval_rewrite_as_Si(self, z, **kwargs):
if z.is_negative:
return Shi(z) + Chi(z) - I*pi
else:
return Shi(z) + Chi(z)
_eval_rewrite_as_Ci = _eval_rewrite_as_Si
_eval_rewrite_as_Chi = _eval_rewrite_as_Si
_eval_rewrite_as_Shi = _eval_rewrite_as_Si
def _eval_rewrite_as_tractable(self, z, **kwargs):
return exp(z) * _eis(z)
def _eval_nseries(self, x, n, logx):
x0 = self.args[0].limit(x, 0)
if x0.is_zero:
f = self._eval_rewrite_as_Si(*self.args)
return f._eval_nseries(x, n, logx)
return super()._eval_nseries(x, n, logx)
class expint(Function):
r"""
Generalized exponential integral.
Explanation
===========
This function is defined as
.. math:: \operatorname{E}_\nu(z) = z^{\nu - 1} \Gamma(1 - \nu, z),
where $\Gamma(1 - \nu, z)$ is the upper incomplete gamma function
(``uppergamma``).
Hence for $z$ with positive real part we have
.. math:: \operatorname{E}_\nu(z)
= \int_1^\infty \frac{e^{-zt}}{t^\nu} \mathrm{d}t,
which explains the name.
The representation as an incomplete gamma function provides an analytic
continuation for $\operatorname{E}_\nu(z)$. If $\nu$ is a
non-positive integer, the exponential integral is thus an unbranched
function of $z$, otherwise there is a branch point at the origin.
Refer to the incomplete gamma function documentation for details of the
branching behavior.
Examples
========
>>> from sympy import expint, S
>>> from sympy.abc import nu, z
Differentiation is supported. Differentiation with respect to $z$ further
explains the name: for integral orders, the exponential integral is an
iterated integral of the exponential function.
>>> expint(nu, z).diff(z)
-expint(nu - 1, z)
Differentiation with respect to $\nu$ has no classical expression:
>>> expint(nu, z).diff(nu)
-z**(nu - 1)*meijerg(((), (1, 1)), ((0, 0, 1 - nu), ()), z)
At non-postive integer orders, the exponential integral reduces to the
exponential function:
>>> expint(0, z)
exp(-z)/z
>>> expint(-1, z)
exp(-z)/z + exp(-z)/z**2
At half-integers it reduces to error functions:
>>> expint(S(1)/2, z)
sqrt(pi)*erfc(sqrt(z))/sqrt(z)
At positive integer orders it can be rewritten in terms of exponentials
and ``expint(1, z)``. Use ``expand_func()`` to do this:
>>> from sympy import expand_func
>>> expand_func(expint(5, z))
z**4*expint(1, z)/24 + (-z**3 + z**2 - 2*z + 6)*exp(-z)/24
The generalised exponential integral is essentially equivalent to the
incomplete gamma function:
>>> from sympy import uppergamma
>>> expint(nu, z).rewrite(uppergamma)
z**(nu - 1)*uppergamma(1 - nu, z)
As such it is branched at the origin:
>>> from sympy import exp_polar, pi, I
>>> expint(4, z*exp_polar(2*pi*I))
I*pi*z**3/3 + expint(4, z)
>>> expint(nu, z*exp_polar(2*pi*I))
z**(nu - 1)*(exp(2*I*pi*nu) - 1)*gamma(1 - nu) + expint(nu, z)
See Also
========
Ei: Another related function called exponential integral.
E1: The classical case, returns expint(1, z).
li: Logarithmic integral.
Li: Offset logarithmic integral.
Si: Sine integral.
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
uppergamma
References
==========
.. [1] http://dlmf.nist.gov/8.19
.. [2] http://functions.wolfram.com/GammaBetaErf/ExpIntegralE/
.. [3] https://en.wikipedia.org/wiki/Exponential_integral
"""
@classmethod
def eval(cls, nu, z):
from sympy import (unpolarify, expand_mul, uppergamma, exp, gamma,
factorial)
nu2 = unpolarify(nu)
if nu != nu2:
return expint(nu2, z)
if nu.is_Integer and nu <= 0 or (not nu.is_Integer and (2*nu).is_Integer):
return unpolarify(expand_mul(z**(nu - 1)*uppergamma(1 - nu, z)))
# Extract branching information. This can be deduced from what is
# explained in lowergamma.eval().
z, n = z.extract_branch_factor()
if n is S.Zero:
return
if nu.is_integer:
if not nu > 0:
return
return expint(nu, z) \
- 2*pi*I*n*(-1)**(nu - 1)/factorial(nu - 1)*unpolarify(z)**(nu - 1)
else:
return (exp(2*I*pi*nu*n) - 1)*z**(nu - 1)*gamma(1 - nu) + expint(nu, z)
def fdiff(self, argindex):
from sympy import meijerg
nu, z = self.args
if argindex == 1:
return -z**(nu - 1)*meijerg([], [1, 1], [0, 0, 1 - nu], [], z)
elif argindex == 2:
return -expint(nu - 1, z)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_uppergamma(self, nu, z, **kwargs):
from sympy import uppergamma
return z**(nu - 1)*uppergamma(1 - nu, z)
def _eval_rewrite_as_Ei(self, nu, z, **kwargs):
from sympy import exp_polar, unpolarify, exp, factorial
if nu == 1:
return -Ei(z*exp_polar(-I*pi)) - I*pi
elif nu.is_Integer and nu > 1:
# DLMF, 8.19.7
x = -unpolarify(z)
return x**(nu - 1)/factorial(nu - 1)*E1(z).rewrite(Ei) + \
exp(x)/factorial(nu - 1) * \
Add(*[factorial(nu - k - 2)*x**k for k in range(nu - 1)])
else:
return self
def _eval_expand_func(self, **hints):
return self.rewrite(Ei).rewrite(expint, **hints)
def _eval_rewrite_as_Si(self, nu, z, **kwargs):
if nu != 1:
return self
return Shi(z) - Chi(z)
_eval_rewrite_as_Ci = _eval_rewrite_as_Si
_eval_rewrite_as_Chi = _eval_rewrite_as_Si
_eval_rewrite_as_Shi = _eval_rewrite_as_Si
def _eval_nseries(self, x, n, logx):
if not self.args[0].has(x):
nu = self.args[0]
if nu == 1:
f = self._eval_rewrite_as_Si(*self.args)
return f._eval_nseries(x, n, logx)
elif nu.is_Integer and nu > 1:
f = self._eval_rewrite_as_Ei(*self.args)
return f._eval_nseries(x, n, logx)
return super()._eval_nseries(x, n, logx)
def _sage_(self):
import sage.all as sage
return sage.exp_integral_e(self.args[0]._sage_(), self.args[1]._sage_())
def E1(z):
"""
Classical case of the generalized exponential integral.
Explanation
===========
This is equivalent to ``expint(1, z)``.
See Also
========
Ei: Exponential integral.
expint: Generalised exponential integral.
li: Logarithmic integral.
Li: Offset logarithmic integral.
Si: Sine integral.
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
"""
return expint(1, z)
class li(Function):
r"""
The classical logarithmic integral.
Explanation
===========
For use in SymPy, this function is defined as
.. math:: \operatorname{li}(x) = \int_0^x \frac{1}{\log(t)} \mathrm{d}t \,.
Examples
========
>>> from sympy import I, oo, li
>>> from sympy.abc import z
Several special values are known:
>>> li(0)
0
>>> li(1)
-oo
>>> li(oo)
oo
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(li(z), z)
1/log(z)
Defining the ``li`` function via an integral:
The logarithmic integral can also be defined in terms of ``Ei``:
>>> from sympy import Ei
>>> li(z).rewrite(Ei)
Ei(log(z))
>>> diff(li(z).rewrite(Ei), z)
1/log(z)
We can numerically evaluate the logarithmic integral to arbitrary precision
on the whole complex plane (except the singular points):
>>> li(2).evalf(30)
1.04516378011749278484458888919
>>> li(2*I).evalf(30)
1.0652795784357498247001125598 + 3.08346052231061726610939702133*I
We can even compute Soldner's constant by the help of mpmath:
>>> from mpmath import findroot
>>> findroot(li, 2)
1.45136923488338
Further transformations include rewriting ``li`` in terms of
the trigonometric integrals ``Si``, ``Ci``, ``Shi`` and ``Chi``:
>>> from sympy import Si, Ci, Shi, Chi
>>> li(z).rewrite(Si)
-log(I*log(z)) - log(1/log(z))/2 + log(log(z))/2 + Ci(I*log(z)) + Shi(log(z))
>>> li(z).rewrite(Ci)
-log(I*log(z)) - log(1/log(z))/2 + log(log(z))/2 + Ci(I*log(z)) + Shi(log(z))
>>> li(z).rewrite(Shi)
-log(1/log(z))/2 + log(log(z))/2 + Chi(log(z)) - Shi(log(z))
>>> li(z).rewrite(Chi)
-log(1/log(z))/2 + log(log(z))/2 + Chi(log(z)) - Shi(log(z))
See Also
========
Li: Offset logarithmic integral.
Ei: Exponential integral.
expint: Generalised exponential integral.
E1: Special case of the generalised exponential integral.
Si: Sine integral.
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Logarithmic_integral
.. [2] http://mathworld.wolfram.com/LogarithmicIntegral.html
.. [3] http://dlmf.nist.gov/6
.. [4] http://mathworld.wolfram.com/SoldnersConstant.html
"""
@classmethod
def eval(cls, z):
if z.is_zero:
return S.Zero
elif z is S.One:
return S.NegativeInfinity
elif z is S.Infinity:
return S.Infinity
if z.is_zero:
return S.Zero
def fdiff(self, argindex=1):
arg = self.args[0]
if argindex == 1:
return S.One / log(arg)
else:
raise ArgumentIndexError(self, argindex)
def _eval_conjugate(self):
z = self.args[0]
# Exclude values on the branch cut (-oo, 0)
if not z.is_extended_negative:
return self.func(z.conjugate())
def _eval_rewrite_as_Li(self, z, **kwargs):
return Li(z) + li(2)
def _eval_rewrite_as_Ei(self, z, **kwargs):
return Ei(log(z))
def _eval_rewrite_as_uppergamma(self, z, **kwargs):
from sympy import uppergamma
return (-uppergamma(0, -log(z)) +
S.Half*(log(log(z)) - log(S.One/log(z))) - log(-log(z)))
def _eval_rewrite_as_Si(self, z, **kwargs):
return (Ci(I*log(z)) - I*Si(I*log(z)) -
S.Half*(log(S.One/log(z)) - log(log(z))) - log(I*log(z)))
_eval_rewrite_as_Ci = _eval_rewrite_as_Si
def _eval_rewrite_as_Shi(self, z, **kwargs):
return (Chi(log(z)) - Shi(log(z)) - S.Half*(log(S.One/log(z)) - log(log(z))))
_eval_rewrite_as_Chi = _eval_rewrite_as_Shi
def _eval_rewrite_as_hyper(self, z, **kwargs):
return (log(z)*hyper((1, 1), (2, 2), log(z)) +
S.Half*(log(log(z)) - log(S.One/log(z))) + S.EulerGamma)
def _eval_rewrite_as_meijerg(self, z, **kwargs):
return (-log(-log(z)) - S.Half*(log(S.One/log(z)) - log(log(z)))
- meijerg(((), (1,)), ((0, 0), ()), -log(z)))
def _eval_rewrite_as_tractable(self, z, **kwargs):
return z * _eis(log(z))
def _eval_is_zero(self):
z = self.args[0]
if z.is_zero:
return True
class Li(Function):
r"""
The offset logarithmic integral.
Explanation
===========
For use in SymPy, this function is defined as
.. math:: \operatorname{Li}(x) = \operatorname{li}(x) - \operatorname{li}(2)
Examples
========
>>> from sympy import Li
>>> from sympy.abc import z
The following special value is known:
>>> Li(2)
0
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(Li(z), z)
1/log(z)
The shifted logarithmic integral can be written in terms of $li(z)$:
>>> from sympy import li
>>> Li(z).rewrite(li)
li(z) - li(2)
We can numerically evaluate the logarithmic integral to arbitrary precision
on the whole complex plane (except the singular points):
>>> Li(2).evalf(30)
0
>>> Li(4).evalf(30)
1.92242131492155809316615998938
See Also
========
li: Logarithmic integral.
Ei: Exponential integral.
expint: Generalised exponential integral.
E1: Special case of the generalised exponential integral.
Si: Sine integral.
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Logarithmic_integral
.. [2] http://mathworld.wolfram.com/LogarithmicIntegral.html
.. [3] http://dlmf.nist.gov/6
"""
@classmethod
def eval(cls, z):
if z is S.Infinity:
return S.Infinity
elif z == S(2):
return S.Zero
def fdiff(self, argindex=1):
arg = self.args[0]
if argindex == 1:
return S.One / log(arg)
else:
raise ArgumentIndexError(self, argindex)
def _eval_evalf(self, prec):
return self.rewrite(li).evalf(prec)
def _eval_rewrite_as_li(self, z, **kwargs):
return li(z) - li(2)
def _eval_rewrite_as_tractable(self, z, **kwargs):
return self.rewrite(li).rewrite("tractable", deep=True)
###############################################################################
#################### TRIGONOMETRIC INTEGRALS ##################################
###############################################################################
class TrigonometricIntegral(Function):
""" Base class for trigonometric integrals. """
@classmethod
def eval(cls, z):
if z is S.Zero:
return cls._atzero
elif z is S.Infinity:
return cls._atinf()
elif z is S.NegativeInfinity:
return cls._atneginf()
if z.is_zero:
return cls._atzero
nz = z.extract_multiplicatively(polar_lift(I))
if nz is None and cls._trigfunc(0) == 0:
nz = z.extract_multiplicatively(I)
if nz is not None:
return cls._Ifactor(nz, 1)
nz = z.extract_multiplicatively(polar_lift(-I))
if nz is not None:
return cls._Ifactor(nz, -1)
nz = z.extract_multiplicatively(polar_lift(-1))
if nz is None and cls._trigfunc(0) == 0:
nz = z.extract_multiplicatively(-1)
if nz is not None:
return cls._minusfactor(nz)
nz, n = z.extract_branch_factor()
if n == 0 and nz == z:
return
return 2*pi*I*n*cls._trigfunc(0) + cls(nz)
def fdiff(self, argindex=1):
from sympy import unpolarify
arg = unpolarify(self.args[0])
if argindex == 1:
return self._trigfunc(arg)/arg
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_Ei(self, z, **kwargs):
return self._eval_rewrite_as_expint(z).rewrite(Ei)
def _eval_rewrite_as_uppergamma(self, z, **kwargs):
from sympy import uppergamma
return self._eval_rewrite_as_expint(z).rewrite(uppergamma)
def _eval_nseries(self, x, n, logx):
# NOTE this is fairly inefficient
from sympy import log, EulerGamma, Pow
n += 1
if self.args[0].subs(x, 0) != 0:
return super()._eval_nseries(x, n, logx)
baseseries = self._trigfunc(x)._eval_nseries(x, n, logx)
if self._trigfunc(0) != 0:
baseseries -= 1
baseseries = baseseries.replace(Pow, lambda t, n: t**n/n, simultaneous=False)
if self._trigfunc(0) != 0:
baseseries += EulerGamma + log(x)
return baseseries.subs(x, self.args[0])._eval_nseries(x, n, logx)
class Si(TrigonometricIntegral):
r"""
Sine integral.
Explanation
===========
This function is defined by
.. math:: \operatorname{Si}(z) = \int_0^z \frac{\sin{t}}{t} \mathrm{d}t.
It is an entire function.
Examples
========
>>> from sympy import Si
>>> from sympy.abc import z
The sine integral is an antiderivative of $sin(z)/z$:
>>> Si(z).diff(z)
sin(z)/z
It is unbranched:
>>> from sympy import exp_polar, I, pi
>>> Si(z*exp_polar(2*I*pi))
Si(z)
Sine integral behaves much like ordinary sine under multiplication by ``I``:
>>> Si(I*z)
I*Shi(z)
>>> Si(-z)
-Si(z)
It can also be expressed in terms of exponential integrals, but beware
that the latter is branched:
>>> from sympy import expint
>>> Si(z).rewrite(expint)
-I*(-expint(1, z*exp_polar(-I*pi/2))/2 +
expint(1, z*exp_polar(I*pi/2))/2) + pi/2
It can be rewritten in the form of sinc function (by definition):
>>> from sympy import sinc
>>> Si(z).rewrite(sinc)
Integral(sinc(t), (t, 0, z))
See Also
========
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
Ei: Exponential integral.
expint: Generalised exponential integral.
sinc: unnormalized sinc function
E1: Special case of the generalised exponential integral.
li: Logarithmic integral.
Li: Offset logarithmic integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_integral
"""
_trigfunc = sin
_atzero = S.Zero
@classmethod
def _atinf(cls):
return pi*S.Half
@classmethod
def _atneginf(cls):
return -pi*S.Half
@classmethod
def _minusfactor(cls, z):
return -Si(z)
@classmethod
def _Ifactor(cls, z, sign):
return I*Shi(z)*sign
def _eval_rewrite_as_expint(self, z, **kwargs):
# XXX should we polarify z?
return pi/2 + (E1(polar_lift(I)*z) - E1(polar_lift(-I)*z))/2/I
def _eval_rewrite_as_sinc(self, z, **kwargs):
from sympy import Integral
t = Symbol('t', Dummy=True)
return Integral(sinc(t), (t, 0, z))
def _eval_is_zero(self):
z = self.args[0]
if z.is_zero:
return True
def _sage_(self):
import sage.all as sage
return sage.sin_integral(self.args[0]._sage_())
class Ci(TrigonometricIntegral):
r"""
Cosine integral.
Explanation
===========
This function is defined for positive $x$ by
.. math:: \operatorname{Ci}(x) = \gamma + \log{x}
+ \int_0^x \frac{\cos{t} - 1}{t} \mathrm{d}t
= -\int_x^\infty \frac{\cos{t}}{t} \mathrm{d}t,
where $\gamma$ is the Euler-Mascheroni constant.
We have
.. math:: \operatorname{Ci}(z) =
-\frac{\operatorname{E}_1\left(e^{i\pi/2} z\right)
+ \operatorname{E}_1\left(e^{-i \pi/2} z\right)}{2}
which holds for all polar $z$ and thus provides an analytic
continuation to the Riemann surface of the logarithm.
The formula also holds as stated
for $z \in \mathbb{C}$ with $\Re(z) > 0$.
By lifting to the principal branch, we obtain an analytic function on the
cut complex plane.
Examples
========
>>> from sympy import Ci
>>> from sympy.abc import z
The cosine integral is a primitive of $\cos(z)/z$:
>>> Ci(z).diff(z)
cos(z)/z
It has a logarithmic branch point at the origin:
>>> from sympy import exp_polar, I, pi
>>> Ci(z*exp_polar(2*I*pi))
Ci(z) + 2*I*pi
The cosine integral behaves somewhat like ordinary $\cos$ under
multiplication by $i$:
>>> from sympy import polar_lift
>>> Ci(polar_lift(I)*z)
Chi(z) + I*pi/2
>>> Ci(polar_lift(-1)*z)
Ci(z) + I*pi
It can also be expressed in terms of exponential integrals:
>>> from sympy import expint
>>> Ci(z).rewrite(expint)
-expint(1, z*exp_polar(-I*pi/2))/2 - expint(1, z*exp_polar(I*pi/2))/2
See Also
========
Si: Sine integral.
Shi: Hyperbolic sine integral.
Chi: Hyperbolic cosine integral.
Ei: Exponential integral.
expint: Generalised exponential integral.
E1: Special case of the generalised exponential integral.
li: Logarithmic integral.
Li: Offset logarithmic integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_integral
"""
_trigfunc = cos
_atzero = S.ComplexInfinity
@classmethod
def _atinf(cls):
return S.Zero
@classmethod
def _atneginf(cls):
return I*pi
@classmethod
def _minusfactor(cls, z):
return Ci(z) + I*pi
@classmethod
def _Ifactor(cls, z, sign):
return Chi(z) + I*pi/2*sign
def _eval_rewrite_as_expint(self, z, **kwargs):
return -(E1(polar_lift(I)*z) + E1(polar_lift(-I)*z))/2
def _sage_(self):
import sage.all as sage
return sage.cos_integral(self.args[0]._sage_())
class Shi(TrigonometricIntegral):
r"""
Sinh integral.
Explanation
===========
This function is defined by
.. math:: \operatorname{Shi}(z) = \int_0^z \frac{\sinh{t}}{t} \mathrm{d}t.
It is an entire function.
Examples
========
>>> from sympy import Shi
>>> from sympy.abc import z
The Sinh integral is a primitive of $\sinh(z)/z$:
>>> Shi(z).diff(z)
sinh(z)/z
It is unbranched:
>>> from sympy import exp_polar, I, pi
>>> Shi(z*exp_polar(2*I*pi))
Shi(z)
The $\sinh$ integral behaves much like ordinary $\sinh$ under
multiplication by $i$:
>>> Shi(I*z)
I*Si(z)
>>> Shi(-z)
-Shi(z)
It can also be expressed in terms of exponential integrals, but beware
that the latter is branched:
>>> from sympy import expint
>>> Shi(z).rewrite(expint)
expint(1, z)/2 - expint(1, z*exp_polar(I*pi))/2 - I*pi/2
See Also
========
Si: Sine integral.
Ci: Cosine integral.
Chi: Hyperbolic cosine integral.
Ei: Exponential integral.
expint: Generalised exponential integral.
E1: Special case of the generalised exponential integral.
li: Logarithmic integral.
Li: Offset logarithmic integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_integral
"""
_trigfunc = sinh
_atzero = S.Zero
@classmethod
def _atinf(cls):
return S.Infinity
@classmethod
def _atneginf(cls):
return S.NegativeInfinity
@classmethod
def _minusfactor(cls, z):
return -Shi(z)
@classmethod
def _Ifactor(cls, z, sign):
return I*Si(z)*sign
def _eval_rewrite_as_expint(self, z, **kwargs):
from sympy import exp_polar
# XXX should we polarify z?
return (E1(z) - E1(exp_polar(I*pi)*z))/2 - I*pi/2
def _eval_is_zero(self):
z = self.args[0]
if z.is_zero:
return True
def _sage_(self):
import sage.all as sage
return sage.sinh_integral(self.args[0]._sage_())
class Chi(TrigonometricIntegral):
r"""
Cosh integral.
Explanation
===========
This function is defined for positive $x$ by
.. math:: \operatorname{Chi}(x) = \gamma + \log{x}
+ \int_0^x \frac{\cosh{t} - 1}{t} \mathrm{d}t,
where $\gamma$ is the Euler-Mascheroni constant.
We have
.. math:: \operatorname{Chi}(z) = \operatorname{Ci}\left(e^{i \pi/2}z\right)
- i\frac{\pi}{2},
which holds for all polar $z$ and thus provides an analytic
continuation to the Riemann surface of the logarithm.
By lifting to the principal branch we obtain an analytic function on the
cut complex plane.
Examples
========
>>> from sympy import Chi
>>> from sympy.abc import z
The $\cosh$ integral is a primitive of $\cosh(z)/z$:
>>> Chi(z).diff(z)
cosh(z)/z
It has a logarithmic branch point at the origin:
>>> from sympy import exp_polar, I, pi
>>> Chi(z*exp_polar(2*I*pi))
Chi(z) + 2*I*pi
The $\cosh$ integral behaves somewhat like ordinary $\cosh$ under
multiplication by $i$:
>>> from sympy import polar_lift
>>> Chi(polar_lift(I)*z)
Ci(z) + I*pi/2
>>> Chi(polar_lift(-1)*z)
Chi(z) + I*pi
It can also be expressed in terms of exponential integrals:
>>> from sympy import expint
>>> Chi(z).rewrite(expint)
-expint(1, z)/2 - expint(1, z*exp_polar(I*pi))/2 - I*pi/2
See Also
========
Si: Sine integral.
Ci: Cosine integral.
Shi: Hyperbolic sine integral.
Ei: Exponential integral.
expint: Generalised exponential integral.
E1: Special case of the generalised exponential integral.
li: Logarithmic integral.
Li: Offset logarithmic integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Trigonometric_integral
"""
_trigfunc = cosh
_atzero = S.ComplexInfinity
@classmethod
def _atinf(cls):
return S.Infinity
@classmethod
def _atneginf(cls):
return S.Infinity
@classmethod
def _minusfactor(cls, z):
return Chi(z) + I*pi
@classmethod
def _Ifactor(cls, z, sign):
return Ci(z) + I*pi/2*sign
def _eval_rewrite_as_expint(self, z, **kwargs):
from sympy import exp_polar
return -I*pi/2 - (E1(z) + E1(exp_polar(I*pi)*z))/2
def _sage_(self):
import sage.all as sage
return sage.cosh_integral(self.args[0]._sage_())
###############################################################################
#################### FRESNEL INTEGRALS ########################################
###############################################################################
class FresnelIntegral(Function):
""" Base class for the Fresnel integrals."""
unbranched = True
@classmethod
def eval(cls, z):
# Values at positive infinities signs
# if any were extracted automatically
if z is S.Infinity:
return S.Half
# Value at zero
if z.is_zero:
return S.Zero
# Try to pull out factors of -1 and I
prefact = S.One
newarg = z
changed = False
nz = newarg.extract_multiplicatively(-1)
if nz is not None:
prefact = -prefact
newarg = nz
changed = True
nz = newarg.extract_multiplicatively(I)
if nz is not None:
prefact = cls._sign*I*prefact
newarg = nz
changed = True
if changed:
return prefact*cls(newarg)
def fdiff(self, argindex=1):
if argindex == 1:
return self._trigfunc(S.Half*pi*self.args[0]**2)
else:
raise ArgumentIndexError(self, argindex)
def _eval_is_extended_real(self):
return self.args[0].is_extended_real
_eval_is_finite = _eval_is_extended_real
def _eval_is_zero(self):
z = self.args[0]
if z.is_zero:
return True
def _eval_conjugate(self):
return self.func(self.args[0].conjugate())
as_real_imag = real_to_real_as_real_imag
class fresnels(FresnelIntegral):
r"""
Fresnel integral S.
Explanation
===========
This function is defined by
.. math:: \operatorname{S}(z) = \int_0^z \sin{\frac{\pi}{2} t^2} \mathrm{d}t.
It is an entire function.
Examples
========
>>> from sympy import I, oo, fresnels
>>> from sympy.abc import z
Several special values are known:
>>> fresnels(0)
0
>>> fresnels(oo)
1/2
>>> fresnels(-oo)
-1/2
>>> fresnels(I*oo)
-I/2
>>> fresnels(-I*oo)
I/2
In general one can pull out factors of -1 and $i$ from the argument:
>>> fresnels(-z)
-fresnels(z)
>>> fresnels(I*z)
-I*fresnels(z)
The Fresnel S integral obeys the mirror symmetry
$\overline{S(z)} = S(\bar{z})$:
>>> from sympy import conjugate
>>> conjugate(fresnels(z))
fresnels(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(fresnels(z), z)
sin(pi*z**2/2)
Defining the Fresnel functions via an integral:
>>> from sympy import integrate, pi, sin, expand_func
>>> integrate(sin(pi*z**2/2), z)
3*fresnels(z)*gamma(3/4)/(4*gamma(7/4))
>>> expand_func(integrate(sin(pi*z**2/2), z))
fresnels(z)
We can numerically evaluate the Fresnel integral to arbitrary precision
on the whole complex plane:
>>> fresnels(2).evalf(30)
0.343415678363698242195300815958
>>> fresnels(-2*I).evalf(30)
0.343415678363698242195300815958*I
See Also
========
fresnelc: Fresnel cosine integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Fresnel_integral
.. [2] http://dlmf.nist.gov/7
.. [3] http://mathworld.wolfram.com/FresnelIntegrals.html
.. [4] http://functions.wolfram.com/GammaBetaErf/FresnelS
.. [5] The converging factors for the fresnel integrals
by John W. Wrench Jr. and Vicki Alley
"""
_trigfunc = sin
_sign = -S.One
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) > 1:
p = previous_terms[-1]
return (-pi**2*x**4*(4*n - 1)/(8*n*(2*n + 1)*(4*n + 3))) * p
else:
return x**3 * (-x**4)**n * (S(2)**(-2*n - 1)*pi**(2*n + 1)) / ((4*n + 3)*factorial(2*n + 1))
def _eval_rewrite_as_erf(self, z, **kwargs):
return (S.One + I)/4 * (erf((S.One + I)/2*sqrt(pi)*z) - I*erf((S.One - I)/2*sqrt(pi)*z))
def _eval_rewrite_as_hyper(self, z, **kwargs):
return pi*z**3/6 * hyper([Rational(3, 4)], [Rational(3, 2), Rational(7, 4)], -pi**2*z**4/16)
def _eval_rewrite_as_meijerg(self, z, **kwargs):
return (pi*z**Rational(9, 4) / (sqrt(2)*(z**2)**Rational(3, 4)*(-z)**Rational(3, 4))
* meijerg([], [1], [Rational(3, 4)], [Rational(1, 4), 0], -pi**2*z**4/16))
def _eval_aseries(self, n, args0, x, logx):
from sympy import Order
point = args0[0]
# Expansion at oo and -oo
if point in [S.Infinity, -S.Infinity]:
z = self.args[0]
# expansion of S(x) = S1(x*sqrt(pi/2)), see reference[5] page 1-8
# as only real infinities are dealt with, sin and cos are O(1)
p = [(-1)**k * factorial(4*k + 1) /
(2**(2*k + 2) * z**(4*k + 3) * 2**(2*k)*factorial(2*k))
for k in range(0, n) if 4*k + 3 < n]
q = [1/(2*z)] + [(-1)**k * factorial(4*k - 1) /
(2**(2*k + 1) * z**(4*k + 1) * 2**(2*k - 1)*factorial(2*k - 1))
for k in range(1, n) if 4*k + 1 < n]
p = [-sqrt(2/pi)*t for t in p]
q = [-sqrt(2/pi)*t for t in q]
s = 1 if point is S.Infinity else -1
# The expansion at oo is 1/2 + some odd powers of z
# To get the expansion at -oo, replace z by -z and flip the sign
# The result -1/2 + the same odd powers of z as before.
return s*S.Half + (sin(z**2)*Add(*p) + cos(z**2)*Add(*q)
).subs(x, sqrt(2/pi)*x) + Order(1/z**n, x)
# All other points are not handled
return super()._eval_aseries(n, args0, x, logx)
class fresnelc(FresnelIntegral):
r"""
Fresnel integral C.
Explanation
===========
This function is defined by
.. math:: \operatorname{C}(z) = \int_0^z \cos{\frac{\pi}{2} t^2} \mathrm{d}t.
It is an entire function.
Examples
========
>>> from sympy import I, oo, fresnelc
>>> from sympy.abc import z
Several special values are known:
>>> fresnelc(0)
0
>>> fresnelc(oo)
1/2
>>> fresnelc(-oo)
-1/2
>>> fresnelc(I*oo)
I/2
>>> fresnelc(-I*oo)
-I/2
In general one can pull out factors of -1 and $i$ from the argument:
>>> fresnelc(-z)
-fresnelc(z)
>>> fresnelc(I*z)
I*fresnelc(z)
The Fresnel C integral obeys the mirror symmetry
$\overline{C(z)} = C(\bar{z})$:
>>> from sympy import conjugate
>>> conjugate(fresnelc(z))
fresnelc(conjugate(z))
Differentiation with respect to $z$ is supported:
>>> from sympy import diff
>>> diff(fresnelc(z), z)
cos(pi*z**2/2)
Defining the Fresnel functions via an integral:
>>> from sympy import integrate, pi, cos, expand_func
>>> integrate(cos(pi*z**2/2), z)
fresnelc(z)*gamma(1/4)/(4*gamma(5/4))
>>> expand_func(integrate(cos(pi*z**2/2), z))
fresnelc(z)
We can numerically evaluate the Fresnel integral to arbitrary precision
on the whole complex plane:
>>> fresnelc(2).evalf(30)
0.488253406075340754500223503357
>>> fresnelc(-2*I).evalf(30)
-0.488253406075340754500223503357*I
See Also
========
fresnels: Fresnel sine integral.
References
==========
.. [1] https://en.wikipedia.org/wiki/Fresnel_integral
.. [2] http://dlmf.nist.gov/7
.. [3] http://mathworld.wolfram.com/FresnelIntegrals.html
.. [4] http://functions.wolfram.com/GammaBetaErf/FresnelC
.. [5] The converging factors for the fresnel integrals
by John W. Wrench Jr. and Vicki Alley
"""
_trigfunc = cos
_sign = S.One
@staticmethod
@cacheit
def taylor_term(n, x, *previous_terms):
if n < 0:
return S.Zero
else:
x = sympify(x)
if len(previous_terms) > 1:
p = previous_terms[-1]
return (-pi**2*x**4*(4*n - 3)/(8*n*(2*n - 1)*(4*n + 1))) * p
else:
return x * (-x**4)**n * (S(2)**(-2*n)*pi**(2*n)) / ((4*n + 1)*factorial(2*n))
def _eval_rewrite_as_erf(self, z, **kwargs):
return (S.One - I)/4 * (erf((S.One + I)/2*sqrt(pi)*z) + I*erf((S.One - I)/2*sqrt(pi)*z))
def _eval_rewrite_as_hyper(self, z, **kwargs):
return z * hyper([Rational(1, 4)], [S.Half, Rational(5, 4)], -pi**2*z**4/16)
def _eval_rewrite_as_meijerg(self, z, **kwargs):
return (pi*z**Rational(3, 4) / (sqrt(2)*root(z**2, 4)*root(-z, 4))
* meijerg([], [1], [Rational(1, 4)], [Rational(3, 4), 0], -pi**2*z**4/16))
def _eval_aseries(self, n, args0, x, logx):
from sympy import Order
point = args0[0]
# Expansion at oo
if point in [S.Infinity, -S.Infinity]:
z = self.args[0]
# expansion of C(x) = C1(x*sqrt(pi/2)), see reference[5] page 1-8
# as only real infinities are dealt with, sin and cos are O(1)
p = [(-1)**k * factorial(4*k + 1) /
(2**(2*k + 2) * z**(4*k + 3) * 2**(2*k)*factorial(2*k))
for k in range(0, n) if 4*k + 3 < n]
q = [1/(2*z)] + [(-1)**k * factorial(4*k - 1) /
(2**(2*k + 1) * z**(4*k + 1) * 2**(2*k - 1)*factorial(2*k - 1))
for k in range(1, n) if 4*k + 1 < n]
p = [-sqrt(2/pi)*t for t in p]
q = [ sqrt(2/pi)*t for t in q]
s = 1 if point is S.Infinity else -1
# The expansion at oo is 1/2 + some odd powers of z
# To get the expansion at -oo, replace z by -z and flip the sign
# The result -1/2 + the same odd powers of z as before.
return s*S.Half + (cos(z**2)*Add(*p) + sin(z**2)*Add(*q)
).subs(x, sqrt(2/pi)*x) + Order(1/z**n, x)
# All other points are not handled
return super()._eval_aseries(n, args0, x, logx)
###############################################################################
#################### HELPER FUNCTIONS #########################################
###############################################################################
class _erfs(Function):
"""
Helper function to make the $\\mathrm{erf}(z)$ function
tractable for the Gruntz algorithm.
"""
def _eval_aseries(self, n, args0, x, logx):
from sympy import Order
point = args0[0]
# Expansion at oo
if point is S.Infinity:
z = self.args[0]
l = [ 1/sqrt(S.Pi) * factorial(2*k)*(-S(
4))**(-k)/factorial(k) * (1/z)**(2*k + 1) for k in range(0, n) ]
o = Order(1/z**(2*n + 1), x)
# It is very inefficient to first add the order and then do the nseries
return (Add(*l))._eval_nseries(x, n, logx) + o
# Expansion at I*oo
t = point.extract_multiplicatively(S.ImaginaryUnit)
if t is S.Infinity:
z = self.args[0]
# TODO: is the series really correct?
l = [ 1/sqrt(S.Pi) * factorial(2*k)*(-S(
4))**(-k)/factorial(k) * (1/z)**(2*k + 1) for k in range(0, n) ]
o = Order(1/z**(2*n + 1), x)
# It is very inefficient to first add the order and then do the nseries
return (Add(*l))._eval_nseries(x, n, logx) + o
# All other points are not handled
return super()._eval_aseries(n, args0, x, logx)
def fdiff(self, argindex=1):
if argindex == 1:
z = self.args[0]
return -2/sqrt(S.Pi) + 2*z*_erfs(z)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_intractable(self, z, **kwargs):
return (S.One - erf(z))*exp(z**2)
class _eis(Function):
"""
Helper function to make the $\\mathrm{Ei}(z)$ and $\\mathrm{li}(z)$
functions tractable for the Gruntz algorithm.
"""
def _eval_aseries(self, n, args0, x, logx):
from sympy import Order
if args0[0] != S.Infinity:
return super(_erfs, self)._eval_aseries(n, args0, x, logx)
z = self.args[0]
l = [ factorial(k) * (1/z)**(k + 1) for k in range(0, n) ]
o = Order(1/z**(n + 1), x)
# It is very inefficient to first add the order and then do the nseries
return (Add(*l))._eval_nseries(x, n, logx) + o
def fdiff(self, argindex=1):
if argindex == 1:
z = self.args[0]
return S.One / z - _eis(z)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_intractable(self, z, **kwargs):
return exp(-z)*Ei(z)
def _eval_nseries(self, x, n, logx):
x0 = self.args[0].limit(x, 0)
if x0.is_zero:
f = self._eval_rewrite_as_intractable(*self.args)
return f._eval_nseries(x, n, logx)
return super()._eval_nseries(x, n, logx)
|
f9ff6144a0e926dccb352d25bf22971e513c00bf0098e1bd1e02158a367f5347 | """
This module mainly implements special orthogonal polynomials.
See also functions.combinatorial.numbers which contains some
combinatorial polynomials.
"""
from sympy.core import Rational
from sympy.core.function import Function, ArgumentIndexError
from sympy.core.singleton import S
from sympy.core.symbol import Dummy
from sympy.functions.combinatorial.factorials import binomial, factorial, RisingFactorial
from sympy.functions.elementary.complexes import re
from sympy.functions.elementary.exponential import exp
from sympy.functions.elementary.integers import floor
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.functions.elementary.trigonometric import cos, sec
from sympy.functions.special.gamma_functions import gamma
from sympy.functions.special.hyper import hyper
from sympy.polys.orthopolys import (
jacobi_poly,
gegenbauer_poly,
chebyshevt_poly,
chebyshevu_poly,
laguerre_poly,
hermite_poly,
legendre_poly
)
_x = Dummy('x')
class OrthogonalPolynomial(Function):
"""Base class for orthogonal polynomials.
"""
@classmethod
def _eval_at_order(cls, n, x):
if n.is_integer and n >= 0:
return cls._ortho_poly(int(n), _x).subs(_x, x)
def _eval_conjugate(self):
return self.func(self.args[0], self.args[1].conjugate())
#----------------------------------------------------------------------------
# Jacobi polynomials
#
class jacobi(OrthogonalPolynomial):
r"""
Jacobi polynomial $P_n^{\left(\alpha, \beta\right)}(x)$.
Explanation
===========
``jacobi(n, alpha, beta, x)`` gives the nth Jacobi polynomial
in x, $P_n^{\left(\alpha, \beta\right)}(x)$.
The Jacobi polynomials are orthogonal on $[-1, 1]$ with respect
to the weight $\left(1-x\right)^\alpha \left(1+x\right)^\beta$.
Examples
========
>>> from sympy import jacobi, S, conjugate, diff
>>> from sympy.abc import a, b, n, x
>>> jacobi(0, a, b, x)
1
>>> jacobi(1, a, b, x)
a/2 - b/2 + x*(a/2 + b/2 + 1)
>>> jacobi(2, a, b, x)
a**2/8 - a*b/4 - a/8 + b**2/8 - b/8 + x**2*(a**2/8 + a*b/4 + 7*a/8 + b**2/8 + 7*b/8 + 3/2) + x*(a**2/4 + 3*a/4 - b**2/4 - 3*b/4) - 1/2
>>> jacobi(n, a, b, x)
jacobi(n, a, b, x)
>>> jacobi(n, a, a, x)
RisingFactorial(a + 1, n)*gegenbauer(n,
a + 1/2, x)/RisingFactorial(2*a + 1, n)
>>> jacobi(n, 0, 0, x)
legendre(n, x)
>>> jacobi(n, S(1)/2, S(1)/2, x)
RisingFactorial(3/2, n)*chebyshevu(n, x)/factorial(n + 1)
>>> jacobi(n, -S(1)/2, -S(1)/2, x)
RisingFactorial(1/2, n)*chebyshevt(n, x)/factorial(n)
>>> jacobi(n, a, b, -x)
(-1)**n*jacobi(n, b, a, x)
>>> jacobi(n, a, b, 0)
2**(-n)*gamma(a + n + 1)*hyper((-b - n, -n), (a + 1,), -1)/(factorial(n)*gamma(a + 1))
>>> jacobi(n, a, b, 1)
RisingFactorial(a + 1, n)/factorial(n)
>>> conjugate(jacobi(n, a, b, x))
jacobi(n, conjugate(a), conjugate(b), conjugate(x))
>>> diff(jacobi(n,a,b,x), x)
(a/2 + b/2 + n/2 + 1/2)*jacobi(n - 1, a + 1, b + 1, x)
See Also
========
gegenbauer,
chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly,
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Jacobi_polynomials
.. [2] http://mathworld.wolfram.com/JacobiPolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/JacobiP/
"""
@classmethod
def eval(cls, n, a, b, x):
# Simplify to other polynomials
# P^{a, a}_n(x)
if a == b:
if a == Rational(-1, 2):
return RisingFactorial(S.Half, n) / factorial(n) * chebyshevt(n, x)
elif a.is_zero:
return legendre(n, x)
elif a == S.Half:
return RisingFactorial(3*S.Half, n) / factorial(n + 1) * chebyshevu(n, x)
else:
return RisingFactorial(a + 1, n) / RisingFactorial(2*a + 1, n) * gegenbauer(n, a + S.Half, x)
elif b == -a:
# P^{a, -a}_n(x)
return gamma(n + a + 1) / gamma(n + 1) * (1 + x)**(a/2) / (1 - x)**(a/2) * assoc_legendre(n, -a, x)
if not n.is_Number:
# Symbolic result P^{a,b}_n(x)
# P^{a,b}_n(-x) ---> (-1)**n * P^{b,a}_n(-x)
if x.could_extract_minus_sign():
return S.NegativeOne**n * jacobi(n, b, a, -x)
# We can evaluate for some special values of x
if x.is_zero:
return (2**(-n) * gamma(a + n + 1) / (gamma(a + 1) * factorial(n)) *
hyper([-b - n, -n], [a + 1], -1))
if x == S.One:
return RisingFactorial(a + 1, n) / factorial(n)
elif x is S.Infinity:
if n.is_positive:
# Make sure a+b+2*n \notin Z
if (a + b + 2*n).is_integer:
raise ValueError("Error. a + b + 2*n should not be an integer.")
return RisingFactorial(a + b + n + 1, n) * S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial
return jacobi_poly(n, a, b, x)
def fdiff(self, argindex=4):
from sympy import Sum
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt a
n, a, b, x = self.args
k = Dummy("k")
f1 = 1 / (a + b + n + k + 1)
f2 = ((a + b + 2*k + 1) * RisingFactorial(b + k + 1, n - k) /
((n - k) * RisingFactorial(a + b + k + 1, n - k)))
return Sum(f1 * (jacobi(n, a, b, x) + f2*jacobi(k, a, b, x)), (k, 0, n - 1))
elif argindex == 3:
# Diff wrt b
n, a, b, x = self.args
k = Dummy("k")
f1 = 1 / (a + b + n + k + 1)
f2 = (-1)**(n - k) * ((a + b + 2*k + 1) * RisingFactorial(a + k + 1, n - k) /
((n - k) * RisingFactorial(a + b + k + 1, n - k)))
return Sum(f1 * (jacobi(n, a, b, x) + f2*jacobi(k, a, b, x)), (k, 0, n - 1))
elif argindex == 4:
# Diff wrt x
n, a, b, x = self.args
return S.Half * (a + b + n + 1) * jacobi(n - 1, a + 1, b + 1, x)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, a, b, x, **kwargs):
from sympy import Sum
# Make sure n \in N
if n.is_negative or n.is_integer is False:
raise ValueError("Error: n should be a non-negative integer.")
k = Dummy("k")
kern = (RisingFactorial(-n, k) * RisingFactorial(a + b + n + 1, k) * RisingFactorial(a + k + 1, n - k) /
factorial(k) * ((1 - x)/2)**k)
return 1 / factorial(n) * Sum(kern, (k, 0, n))
def _eval_conjugate(self):
n, a, b, x = self.args
return self.func(n, a.conjugate(), b.conjugate(), x.conjugate())
def jacobi_normalized(n, a, b, x):
r"""
Jacobi polynomial $P_n^{\left(\alpha, \beta\right)}(x)$.
Explanation
===========
``jacobi_normalized(n, alpha, beta, x)`` gives the nth
Jacobi polynomial in *x*, $P_n^{\left(\alpha, \beta\right)}(x)$.
The Jacobi polynomials are orthogonal on $[-1, 1]$ with respect
to the weight $\left(1-x\right)^\alpha \left(1+x\right)^\beta$.
This functions returns the polynomials normilzed:
.. math::
\int_{-1}^{1}
P_m^{\left(\alpha, \beta\right)}(x)
P_n^{\left(\alpha, \beta\right)}(x)
(1-x)^{\alpha} (1+x)^{\beta} \mathrm{d}x
= \delta_{m,n}
Examples
========
>>> from sympy import jacobi_normalized
>>> from sympy.abc import n,a,b,x
>>> jacobi_normalized(n, a, b, x)
jacobi(n, a, b, x)/sqrt(2**(a + b + 1)*gamma(a + n + 1)*gamma(b + n + 1)/((a + b + 2*n + 1)*factorial(n)*gamma(a + b + n + 1)))
See Also
========
gegenbauer,
chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly,
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Jacobi_polynomials
.. [2] http://mathworld.wolfram.com/JacobiPolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/JacobiP/
"""
nfactor = (S(2)**(a + b + 1) * (gamma(n + a + 1) * gamma(n + b + 1))
/ (2*n + a + b + 1) / (factorial(n) * gamma(n + a + b + 1)))
return jacobi(n, a, b, x) / sqrt(nfactor)
#----------------------------------------------------------------------------
# Gegenbauer polynomials
#
class gegenbauer(OrthogonalPolynomial):
r"""
Gegenbauer polynomial $C_n^{\left(\alpha\right)}(x)$.
Explanation
===========
``gegenbauer(n, alpha, x)`` gives the nth Gegenbauer polynomial
in x, $C_n^{\left(\alpha\right)}(x)$.
The Gegenbauer polynomials are orthogonal on $[-1, 1]$ with
respect to the weight $\left(1-x^2\right)^{\alpha-\frac{1}{2}}$.
Examples
========
>>> from sympy import gegenbauer, conjugate, diff
>>> from sympy.abc import n,a,x
>>> gegenbauer(0, a, x)
1
>>> gegenbauer(1, a, x)
2*a*x
>>> gegenbauer(2, a, x)
-a + x**2*(2*a**2 + 2*a)
>>> gegenbauer(3, a, x)
x**3*(4*a**3/3 + 4*a**2 + 8*a/3) + x*(-2*a**2 - 2*a)
>>> gegenbauer(n, a, x)
gegenbauer(n, a, x)
>>> gegenbauer(n, a, -x)
(-1)**n*gegenbauer(n, a, x)
>>> gegenbauer(n, a, 0)
2**n*sqrt(pi)*gamma(a + n/2)/(gamma(a)*gamma(1/2 - n/2)*gamma(n + 1))
>>> gegenbauer(n, a, 1)
gamma(2*a + n)/(gamma(2*a)*gamma(n + 1))
>>> conjugate(gegenbauer(n, a, x))
gegenbauer(n, conjugate(a), conjugate(x))
>>> diff(gegenbauer(n, a, x), x)
2*a*gegenbauer(n - 1, a + 1, x)
See Also
========
jacobi,
chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Gegenbauer_polynomials
.. [2] http://mathworld.wolfram.com/GegenbauerPolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/GegenbauerC3/
"""
@classmethod
def eval(cls, n, a, x):
# For negative n the polynomials vanish
# See http://functions.wolfram.com/Polynomials/GegenbauerC3/03/01/03/0012/
if n.is_negative:
return S.Zero
# Some special values for fixed a
if a == S.Half:
return legendre(n, x)
elif a == S.One:
return chebyshevu(n, x)
elif a == S.NegativeOne:
return S.Zero
if not n.is_Number:
# Handle this before the general sign extraction rule
if x == S.NegativeOne:
if (re(a) > S.Half) == True:
return S.ComplexInfinity
else:
return (cos(S.Pi*(a+n)) * sec(S.Pi*a) * gamma(2*a+n) /
(gamma(2*a) * gamma(n+1)))
# Symbolic result C^a_n(x)
# C^a_n(-x) ---> (-1)**n * C^a_n(x)
if x.could_extract_minus_sign():
return S.NegativeOne**n * gegenbauer(n, a, -x)
# We can evaluate for some special values of x
if x.is_zero:
return (2**n * sqrt(S.Pi) * gamma(a + S.Half*n) /
(gamma((1 - n)/2) * gamma(n + 1) * gamma(a)) )
if x == S.One:
return gamma(2*a + n) / (gamma(2*a) * gamma(n + 1))
elif x is S.Infinity:
if n.is_positive:
return RisingFactorial(a, n) * S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial
return gegenbauer_poly(n, a, x)
def fdiff(self, argindex=3):
from sympy import Sum
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt a
n, a, x = self.args
k = Dummy("k")
factor1 = 2 * (1 + (-1)**(n - k)) * (k + a) / ((k +
n + 2*a) * (n - k))
factor2 = 2*(k + 1) / ((k + 2*a) * (2*k + 2*a + 1)) + \
2 / (k + n + 2*a)
kern = factor1*gegenbauer(k, a, x) + factor2*gegenbauer(n, a, x)
return Sum(kern, (k, 0, n - 1))
elif argindex == 3:
# Diff wrt x
n, a, x = self.args
return 2*a*gegenbauer(n - 1, a + 1, x)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, a, x, **kwargs):
from sympy import Sum
k = Dummy("k")
kern = ((-1)**k * RisingFactorial(a, n - k) * (2*x)**(n - 2*k) /
(factorial(k) * factorial(n - 2*k)))
return Sum(kern, (k, 0, floor(n/2)))
def _eval_conjugate(self):
n, a, x = self.args
return self.func(n, a.conjugate(), x.conjugate())
#----------------------------------------------------------------------------
# Chebyshev polynomials of first and second kind
#
class chebyshevt(OrthogonalPolynomial):
r"""
Chebyshev polynomial of the first kind, $T_n(x)$.
Explanation
===========
``chebyshevt(n, x)`` gives the nth Chebyshev polynomial (of the first
kind) in x, $T_n(x)$.
The Chebyshev polynomials of the first kind are orthogonal on
$[-1, 1]$ with respect to the weight $\frac{1}{\sqrt{1-x^2}}$.
Examples
========
>>> from sympy import chebyshevt, diff
>>> from sympy.abc import n,x
>>> chebyshevt(0, x)
1
>>> chebyshevt(1, x)
x
>>> chebyshevt(2, x)
2*x**2 - 1
>>> chebyshevt(n, x)
chebyshevt(n, x)
>>> chebyshevt(n, -x)
(-1)**n*chebyshevt(n, x)
>>> chebyshevt(-n, x)
chebyshevt(n, x)
>>> chebyshevt(n, 0)
cos(pi*n/2)
>>> chebyshevt(n, -1)
(-1)**n
>>> diff(chebyshevt(n, x), x)
n*chebyshevu(n - 1, x)
See Also
========
jacobi, gegenbauer,
chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Chebyshev_polynomial
.. [2] http://mathworld.wolfram.com/ChebyshevPolynomialoftheFirstKind.html
.. [3] http://mathworld.wolfram.com/ChebyshevPolynomialoftheSecondKind.html
.. [4] http://functions.wolfram.com/Polynomials/ChebyshevT/
.. [5] http://functions.wolfram.com/Polynomials/ChebyshevU/
"""
_ortho_poly = staticmethod(chebyshevt_poly)
@classmethod
def eval(cls, n, x):
if not n.is_Number:
# Symbolic result T_n(x)
# T_n(-x) ---> (-1)**n * T_n(x)
if x.could_extract_minus_sign():
return S.NegativeOne**n * chebyshevt(n, -x)
# T_{-n}(x) ---> T_n(x)
if n.could_extract_minus_sign():
return chebyshevt(-n, x)
# We can evaluate for some special values of x
if x.is_zero:
return cos(S.Half * S.Pi * n)
if x == S.One:
return S.One
elif x is S.Infinity:
return S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial
if n.is_negative:
# T_{-n}(x) == T_n(x)
return cls._eval_at_order(-n, x)
else:
return cls._eval_at_order(n, x)
def fdiff(self, argindex=2):
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt x
n, x = self.args
return n * chebyshevu(n - 1, x)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, x, **kwargs):
from sympy import Sum
k = Dummy("k")
kern = binomial(n, 2*k) * (x**2 - 1)**k * x**(n - 2*k)
return Sum(kern, (k, 0, floor(n/2)))
class chebyshevu(OrthogonalPolynomial):
r"""
Chebyshev polynomial of the second kind, $U_n(x)$.
Explanation
===========
``chebyshevu(n, x)`` gives the nth Chebyshev polynomial of the second
kind in x, $U_n(x)$.
The Chebyshev polynomials of the second kind are orthogonal on
$[-1, 1]$ with respect to the weight $\sqrt{1-x^2}$.
Examples
========
>>> from sympy import chebyshevu, diff
>>> from sympy.abc import n,x
>>> chebyshevu(0, x)
1
>>> chebyshevu(1, x)
2*x
>>> chebyshevu(2, x)
4*x**2 - 1
>>> chebyshevu(n, x)
chebyshevu(n, x)
>>> chebyshevu(n, -x)
(-1)**n*chebyshevu(n, x)
>>> chebyshevu(-n, x)
-chebyshevu(n - 2, x)
>>> chebyshevu(n, 0)
cos(pi*n/2)
>>> chebyshevu(n, 1)
n + 1
>>> diff(chebyshevu(n, x), x)
(-x*chebyshevu(n, x) + (n + 1)*chebyshevt(n + 1, x))/(x**2 - 1)
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevt_root, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Chebyshev_polynomial
.. [2] http://mathworld.wolfram.com/ChebyshevPolynomialoftheFirstKind.html
.. [3] http://mathworld.wolfram.com/ChebyshevPolynomialoftheSecondKind.html
.. [4] http://functions.wolfram.com/Polynomials/ChebyshevT/
.. [5] http://functions.wolfram.com/Polynomials/ChebyshevU/
"""
_ortho_poly = staticmethod(chebyshevu_poly)
@classmethod
def eval(cls, n, x):
if not n.is_Number:
# Symbolic result U_n(x)
# U_n(-x) ---> (-1)**n * U_n(x)
if x.could_extract_minus_sign():
return S.NegativeOne**n * chebyshevu(n, -x)
# U_{-n}(x) ---> -U_{n-2}(x)
if n.could_extract_minus_sign():
if n == S.NegativeOne:
# n can not be -1 here
return S.Zero
elif not (-n - 2).could_extract_minus_sign():
return -chebyshevu(-n - 2, x)
# We can evaluate for some special values of x
if x.is_zero:
return cos(S.Half * S.Pi * n)
if x == S.One:
return S.One + n
elif x is S.Infinity:
return S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial
if n.is_negative:
# U_{-n}(x) ---> -U_{n-2}(x)
if n == S.NegativeOne:
return S.Zero
else:
return -cls._eval_at_order(-n - 2, x)
else:
return cls._eval_at_order(n, x)
def fdiff(self, argindex=2):
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt x
n, x = self.args
return ((n + 1) * chebyshevt(n + 1, x) - x * chebyshevu(n, x)) / (x**2 - 1)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, x, **kwargs):
from sympy import Sum
k = Dummy("k")
kern = S.NegativeOne**k * factorial(
n - k) * (2*x)**(n - 2*k) / (factorial(k) * factorial(n - 2*k))
return Sum(kern, (k, 0, floor(n/2)))
class chebyshevt_root(Function):
r"""
``chebyshev_root(n, k)`` returns the kth root (indexed from zero) of
the nth Chebyshev polynomial of the first kind; that is, if
0 <= k < n, ``chebyshevt(n, chebyshevt_root(n, k)) == 0``.
Examples
========
>>> from sympy import chebyshevt, chebyshevt_root
>>> chebyshevt_root(3, 2)
-sqrt(3)/2
>>> chebyshevt(3, chebyshevt_root(3, 2))
0
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
"""
@classmethod
def eval(cls, n, k):
if not ((0 <= k) and (k < n)):
raise ValueError("must have 0 <= k < n, "
"got k = %s and n = %s" % (k, n))
return cos(S.Pi*(2*k + 1)/(2*n))
class chebyshevu_root(Function):
r"""
``chebyshevu_root(n, k)`` returns the kth root (indexed from zero) of the
nth Chebyshev polynomial of the second kind; that is, if 0 <= k < n,
``chebyshevu(n, chebyshevu_root(n, k)) == 0``.
Examples
========
>>> from sympy import chebyshevu, chebyshevu_root
>>> chebyshevu_root(3, 2)
-sqrt(2)/2
>>> chebyshevu(3, chebyshevu_root(3, 2))
0
See Also
========
chebyshevt, chebyshevt_root, chebyshevu,
legendre, assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
"""
@classmethod
def eval(cls, n, k):
if not ((0 <= k) and (k < n)):
raise ValueError("must have 0 <= k < n, "
"got k = %s and n = %s" % (k, n))
return cos(S.Pi*(k + 1)/(n + 1))
#----------------------------------------------------------------------------
# Legendre polynomials and Associated Legendre polynomials
#
class legendre(OrthogonalPolynomial):
r"""
``legendre(n, x)`` gives the nth Legendre polynomial of x, $P_n(x)$
Explanation
===========
The Legendre polynomials are orthogonal on [-1, 1] with respect to
the constant weight 1. They satisfy $P_n(1) = 1$ for all n; further,
$P_n$ is odd for odd n and even for even n.
Examples
========
>>> from sympy import legendre, diff
>>> from sympy.abc import x, n
>>> legendre(0, x)
1
>>> legendre(1, x)
x
>>> legendre(2, x)
3*x**2/2 - 1/2
>>> legendre(n, x)
legendre(n, x)
>>> diff(legendre(n,x), x)
n*(x*legendre(n, x) - legendre(n - 1, x))/(x**2 - 1)
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevt_root, chebyshevu, chebyshevu_root,
assoc_legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Legendre_polynomial
.. [2] http://mathworld.wolfram.com/LegendrePolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/LegendreP/
.. [4] http://functions.wolfram.com/Polynomials/LegendreP2/
"""
_ortho_poly = staticmethod(legendre_poly)
@classmethod
def eval(cls, n, x):
if not n.is_Number:
# Symbolic result L_n(x)
# L_n(-x) ---> (-1)**n * L_n(x)
if x.could_extract_minus_sign():
return S.NegativeOne**n * legendre(n, -x)
# L_{-n}(x) ---> L_{n-1}(x)
if n.could_extract_minus_sign() and not(-n - 1).could_extract_minus_sign():
return legendre(-n - S.One, x)
# We can evaluate for some special values of x
if x.is_zero:
return sqrt(S.Pi)/(gamma(S.Half - n/2)*gamma(S.One + n/2))
elif x == S.One:
return S.One
elif x is S.Infinity:
return S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial;
# L_{-n}(x) ---> L_{n-1}(x)
if n.is_negative:
n = -n - S.One
return cls._eval_at_order(n, x)
def fdiff(self, argindex=2):
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt x
# Find better formula, this is unsuitable for x = +/-1
# http://www.autodiff.org/ad16/Oral/Buecker_Legendre.pdf says
# at x = 1:
# n*(n + 1)/2 , m = 0
# oo , m = 1
# -(n-1)*n*(n+1)*(n+2)/4 , m = 2
# 0 , m = 3, 4, ..., n
#
# at x = -1
# (-1)**(n+1)*n*(n + 1)/2 , m = 0
# (-1)**n*oo , m = 1
# (-1)**n*(n-1)*n*(n+1)*(n+2)/4 , m = 2
# 0 , m = 3, 4, ..., n
n, x = self.args
return n/(x**2 - 1)*(x*legendre(n, x) - legendre(n - 1, x))
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, x, **kwargs):
from sympy import Sum
k = Dummy("k")
kern = (-1)**k*binomial(n, k)**2*((1 + x)/2)**(n - k)*((1 - x)/2)**k
return Sum(kern, (k, 0, n))
class assoc_legendre(Function):
r"""
``assoc_legendre(n, m, x)`` gives $P_n^m(x)$, where n and m are
the degree and order or an expression which is related to the nth
order Legendre polynomial, $P_n(x)$ in the following manner:
.. math::
P_n^m(x) = (-1)^m (1 - x^2)^{\frac{m}{2}}
\frac{\mathrm{d}^m P_n(x)}{\mathrm{d} x^m}
Explanation
===========
Associated Legendre polynomials are orthogonal on [-1, 1] with:
- weight = 1 for the same m, and different n.
- weight = 1/(1-x**2) for the same n, and different m.
Examples
========
>>> from sympy import assoc_legendre
>>> from sympy.abc import x, m, n
>>> assoc_legendre(0,0, x)
1
>>> assoc_legendre(1,0, x)
x
>>> assoc_legendre(1,1, x)
-sqrt(1 - x**2)
>>> assoc_legendre(n,m,x)
assoc_legendre(n, m, x)
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevt_root, chebyshevu, chebyshevu_root,
legendre,
hermite,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Associated_Legendre_polynomials
.. [2] http://mathworld.wolfram.com/LegendrePolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/LegendreP/
.. [4] http://functions.wolfram.com/Polynomials/LegendreP2/
"""
@classmethod
def _eval_at_order(cls, n, m):
P = legendre_poly(n, _x, polys=True).diff((_x, m))
return (-1)**m * (1 - _x**2)**Rational(m, 2) * P.as_expr()
@classmethod
def eval(cls, n, m, x):
if m.could_extract_minus_sign():
# P^{-m}_n ---> F * P^m_n
return S.NegativeOne**(-m) * (factorial(m + n)/factorial(n - m)) * assoc_legendre(n, -m, x)
if m == 0:
# P^0_n ---> L_n
return legendre(n, x)
if x == 0:
return 2**m*sqrt(S.Pi) / (gamma((1 - m - n)/2)*gamma(1 - (m - n)/2))
if n.is_Number and m.is_Number and n.is_integer and m.is_integer:
if n.is_negative:
raise ValueError("%s : 1st index must be nonnegative integer (got %r)" % (cls, n))
if abs(m) > n:
raise ValueError("%s : abs('2nd index') must be <= '1st index' (got %r, %r)" % (cls, n, m))
return cls._eval_at_order(int(n), abs(int(m))).subs(_x, x)
def fdiff(self, argindex=3):
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt m
raise ArgumentIndexError(self, argindex)
elif argindex == 3:
# Diff wrt x
# Find better formula, this is unsuitable for x = 1
n, m, x = self.args
return 1/(x**2 - 1)*(x*n*assoc_legendre(n, m, x) - (m + n)*assoc_legendre(n - 1, m, x))
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, m, x, **kwargs):
from sympy import Sum
k = Dummy("k")
kern = factorial(2*n - 2*k)/(2**n*factorial(n - k)*factorial(
k)*factorial(n - 2*k - m))*(-1)**k*x**(n - m - 2*k)
return (1 - x**2)**(m/2) * Sum(kern, (k, 0, floor((n - m)*S.Half)))
def _eval_conjugate(self):
n, m, x = self.args
return self.func(n, m.conjugate(), x.conjugate())
#----------------------------------------------------------------------------
# Hermite polynomials
#
class hermite(OrthogonalPolynomial):
r"""
``hermite(n, x)`` gives the nth Hermite polynomial in x, $H_n(x)$
Explanation
===========
The Hermite polynomials are orthogonal on $(-\infty, \infty)$
with respect to the weight $\exp\left(-x^2\right)$.
Examples
========
>>> from sympy import hermite, diff
>>> from sympy.abc import x, n
>>> hermite(0, x)
1
>>> hermite(1, x)
2*x
>>> hermite(2, x)
4*x**2 - 2
>>> hermite(n, x)
hermite(n, x)
>>> diff(hermite(n,x), x)
2*n*hermite(n - 1, x)
>>> hermite(n, -x)
(-1)**n*hermite(n, x)
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
laguerre, assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Hermite_polynomial
.. [2] http://mathworld.wolfram.com/HermitePolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/HermiteH/
"""
_ortho_poly = staticmethod(hermite_poly)
@classmethod
def eval(cls, n, x):
if not n.is_Number:
# Symbolic result H_n(x)
# H_n(-x) ---> (-1)**n * H_n(x)
if x.could_extract_minus_sign():
return S.NegativeOne**n * hermite(n, -x)
# We can evaluate for some special values of x
if x.is_zero:
return 2**n * sqrt(S.Pi) / gamma((S.One - n)/2)
elif x is S.Infinity:
return S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial
if n.is_negative:
raise ValueError(
"The index n must be nonnegative integer (got %r)" % n)
else:
return cls._eval_at_order(n, x)
def fdiff(self, argindex=2):
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt x
n, x = self.args
return 2*n*hermite(n - 1, x)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, x, **kwargs):
from sympy import Sum
k = Dummy("k")
kern = (-1)**k / (factorial(k)*factorial(n - 2*k)) * (2*x)**(n - 2*k)
return factorial(n)*Sum(kern, (k, 0, floor(n/2)))
#----------------------------------------------------------------------------
# Laguerre polynomials
#
class laguerre(OrthogonalPolynomial):
r"""
Returns the nth Laguerre polynomial in x, $L_n(x)$.
Examples
========
>>> from sympy import laguerre, diff
>>> from sympy.abc import x, n
>>> laguerre(0, x)
1
>>> laguerre(1, x)
1 - x
>>> laguerre(2, x)
x**2/2 - 2*x + 1
>>> laguerre(3, x)
-x**3/6 + 3*x**2/2 - 3*x + 1
>>> laguerre(n, x)
laguerre(n, x)
>>> diff(laguerre(n, x), x)
-assoc_laguerre(n - 1, 1, x)
Parameters
==========
n : int
Degree of Laguerre polynomial. Must be ``n >= 0``.
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
assoc_laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Laguerre_polynomial
.. [2] http://mathworld.wolfram.com/LaguerrePolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/LaguerreL/
.. [4] http://functions.wolfram.com/Polynomials/LaguerreL3/
"""
_ortho_poly = staticmethod(laguerre_poly)
@classmethod
def eval(cls, n, x):
if n.is_integer is False:
raise ValueError("Error: n should be an integer.")
if not n.is_Number:
# Symbolic result L_n(x)
# L_{n}(-x) ---> exp(-x) * L_{-n-1}(x)
# L_{-n}(x) ---> exp(x) * L_{n-1}(-x)
if n.could_extract_minus_sign() and not(-n - 1).could_extract_minus_sign():
return exp(x)*laguerre(-n - 1, -x)
# We can evaluate for some special values of x
if x.is_zero:
return S.One
elif x is S.NegativeInfinity:
return S.Infinity
elif x is S.Infinity:
return S.NegativeOne**n * S.Infinity
else:
if n.is_negative:
return exp(x)*laguerre(-n - 1, -x)
else:
return cls._eval_at_order(n, x)
def fdiff(self, argindex=2):
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt x
n, x = self.args
return -assoc_laguerre(n - 1, 1, x)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, x, **kwargs):
from sympy import Sum
# Make sure n \in N_0
if n.is_negative:
return exp(x) * self._eval_rewrite_as_polynomial(-n - 1, -x, **kwargs)
if n.is_integer is False:
raise ValueError("Error: n should be an integer.")
k = Dummy("k")
kern = RisingFactorial(-n, k) / factorial(k)**2 * x**k
return Sum(kern, (k, 0, n))
class assoc_laguerre(OrthogonalPolynomial):
r"""
Returns the nth generalized Laguerre polynomial in x, $L_n(x)$.
Examples
========
>>> from sympy import assoc_laguerre, diff
>>> from sympy.abc import x, n, a
>>> assoc_laguerre(0, a, x)
1
>>> assoc_laguerre(1, a, x)
a - x + 1
>>> assoc_laguerre(2, a, x)
a**2/2 + 3*a/2 + x**2/2 + x*(-a - 2) + 1
>>> assoc_laguerre(3, a, x)
a**3/6 + a**2 + 11*a/6 - x**3/6 + x**2*(a/2 + 3/2) +
x*(-a**2/2 - 5*a/2 - 3) + 1
>>> assoc_laguerre(n, a, 0)
binomial(a + n, a)
>>> assoc_laguerre(n, a, x)
assoc_laguerre(n, a, x)
>>> assoc_laguerre(n, 0, x)
laguerre(n, x)
>>> diff(assoc_laguerre(n, a, x), x)
-assoc_laguerre(n - 1, a + 1, x)
>>> diff(assoc_laguerre(n, a, x), a)
Sum(assoc_laguerre(_k, a, x)/(-a + n), (_k, 0, n - 1))
Parameters
==========
n : int
Degree of Laguerre polynomial. Must be ``n >= 0``.
alpha : Expr
Arbitrary expression. For ``alpha=0`` regular Laguerre
polynomials will be generated.
See Also
========
jacobi, gegenbauer,
chebyshevt, chebyshevt_root, chebyshevu, chebyshevu_root,
legendre, assoc_legendre,
hermite,
laguerre,
sympy.polys.orthopolys.jacobi_poly
sympy.polys.orthopolys.gegenbauer_poly
sympy.polys.orthopolys.chebyshevt_poly
sympy.polys.orthopolys.chebyshevu_poly
sympy.polys.orthopolys.hermite_poly
sympy.polys.orthopolys.legendre_poly
sympy.polys.orthopolys.laguerre_poly
References
==========
.. [1] https://en.wikipedia.org/wiki/Laguerre_polynomial#Generalized_Laguerre_polynomials
.. [2] http://mathworld.wolfram.com/AssociatedLaguerrePolynomial.html
.. [3] http://functions.wolfram.com/Polynomials/LaguerreL/
.. [4] http://functions.wolfram.com/Polynomials/LaguerreL3/
"""
@classmethod
def eval(cls, n, alpha, x):
# L_{n}^{0}(x) ---> L_{n}(x)
if alpha.is_zero:
return laguerre(n, x)
if not n.is_Number:
# We can evaluate for some special values of x
if x.is_zero:
return binomial(n + alpha, alpha)
elif x is S.Infinity and n > 0:
return S.NegativeOne**n * S.Infinity
elif x is S.NegativeInfinity and n > 0:
return S.Infinity
else:
# n is a given fixed integer, evaluate into polynomial
if n.is_negative:
raise ValueError(
"The index n must be nonnegative integer (got %r)" % n)
else:
return laguerre_poly(n, x, alpha)
def fdiff(self, argindex=3):
from sympy import Sum
if argindex == 1:
# Diff wrt n
raise ArgumentIndexError(self, argindex)
elif argindex == 2:
# Diff wrt alpha
n, alpha, x = self.args
k = Dummy("k")
return Sum(assoc_laguerre(k, alpha, x) / (n - alpha), (k, 0, n - 1))
elif argindex == 3:
# Diff wrt x
n, alpha, x = self.args
return -assoc_laguerre(n - 1, alpha + 1, x)
else:
raise ArgumentIndexError(self, argindex)
def _eval_rewrite_as_polynomial(self, n, alpha, x, **kwargs):
from sympy import Sum
# Make sure n \in N_0
if n.is_negative or n.is_integer is False:
raise ValueError("Error: n should be a non-negative integer.")
k = Dummy("k")
kern = RisingFactorial(
-n, k) / (gamma(k + alpha + 1) * factorial(k)) * x**k
return gamma(n + alpha + 1) / factorial(n) * Sum(kern, (k, 0, n))
def _eval_conjugate(self):
n, alpha, x = self.args
return self.func(n, alpha.conjugate(), x.conjugate())
|
a34db0288d22d90883b29ddefc8dd5d322db25e3b92f3b9125e05f73098d21aa | from sympy import (symbols, Symbol, nan, oo, zoo, I, sinh, sin, pi, atan,
acos, Rational, sqrt, asin, acot, coth, E, S, tan, tanh, cos,
cosh, atan2, exp, log, asinh, acoth, atanh, O, cancel, Matrix, re, im,
Float, Pow, gcd, sec, csc, cot, diff, simplify, Heaviside, arg,
conjugate, series, FiniteSet, asec, acsc, Mul, sinc, jn,
AccumBounds, Interval, ImageSet, Lambda, besselj, Add)
from sympy.core.expr import unchanged
from sympy.core.function import ArgumentIndexError
from sympy.core.relational import Ne, Eq
from sympy.functions.elementary.piecewise import Piecewise
from sympy.sets.setexpr import SetExpr
from sympy.testing.pytest import XFAIL, slow, raises
x, y, z = symbols('x y z')
r = Symbol('r', real=True)
k = Symbol('k', integer=True)
p = Symbol('p', positive=True)
n = Symbol('n', negative=True)
np = Symbol('p', nonpositive=True)
nn = Symbol('n', nonnegative=True)
nz = Symbol('nz', nonzero=True)
ep = Symbol('ep', extended_positive=True)
en = Symbol('en', extended_negative=True)
enp = Symbol('ep', extended_nonpositive=True)
enn = Symbol('en', extended_nonnegative=True)
enz = Symbol('enz', extended_nonzero=True)
a = Symbol('a', algebraic=True)
na = Symbol('na', nonzero=True, algebraic=True)
def test_sin():
x, y = symbols('x y')
assert sin.nargs == FiniteSet(1)
assert sin(nan) is nan
assert sin(zoo) is nan
assert sin(oo) == AccumBounds(-1, 1)
assert sin(oo) - sin(oo) == AccumBounds(-2, 2)
assert sin(oo*I) == oo*I
assert sin(-oo*I) == -oo*I
assert 0*sin(oo) is S.Zero
assert 0/sin(oo) is S.Zero
assert 0 + sin(oo) == AccumBounds(-1, 1)
assert 5 + sin(oo) == AccumBounds(4, 6)
assert sin(0) == 0
assert sin(asin(x)) == x
assert sin(atan(x)) == x / sqrt(1 + x**2)
assert sin(acos(x)) == sqrt(1 - x**2)
assert sin(acot(x)) == 1 / (sqrt(1 + 1 / x**2) * x)
assert sin(acsc(x)) == 1 / x
assert sin(asec(x)) == sqrt(1 - 1 / x**2)
assert sin(atan2(y, x)) == y / sqrt(x**2 + y**2)
assert sin(pi*I) == sinh(pi)*I
assert sin(-pi*I) == -sinh(pi)*I
assert sin(-2*I) == -sinh(2)*I
assert sin(pi) == 0
assert sin(-pi) == 0
assert sin(2*pi) == 0
assert sin(-2*pi) == 0
assert sin(-3*10**73*pi) == 0
assert sin(7*10**103*pi) == 0
assert sin(pi/2) == 1
assert sin(-pi/2) == -1
assert sin(pi*Rational(5, 2)) == 1
assert sin(pi*Rational(7, 2)) == -1
ne = symbols('ne', integer=True, even=False)
e = symbols('e', even=True)
assert sin(pi*ne/2) == (-1)**(ne/2 - S.Half)
assert sin(pi*k/2).func == sin
assert sin(pi*e/2) == 0
assert sin(pi*k) == 0
assert sin(pi*k).subs(k, 3) == sin(pi*k/2).subs(k, 6) # issue 8298
assert sin(pi/3) == S.Half*sqrt(3)
assert sin(pi*Rational(-2, 3)) == Rational(-1, 2)*sqrt(3)
assert sin(pi/4) == S.Half*sqrt(2)
assert sin(-pi/4) == Rational(-1, 2)*sqrt(2)
assert sin(pi*Rational(17, 4)) == S.Half*sqrt(2)
assert sin(pi*Rational(-3, 4)) == Rational(-1, 2)*sqrt(2)
assert sin(pi/6) == S.Half
assert sin(-pi/6) == Rational(-1, 2)
assert sin(pi*Rational(7, 6)) == Rational(-1, 2)
assert sin(pi*Rational(-5, 6)) == Rational(-1, 2)
assert sin(pi*Rational(1, 5)) == sqrt((5 - sqrt(5)) / 8)
assert sin(pi*Rational(2, 5)) == sqrt((5 + sqrt(5)) / 8)
assert sin(pi*Rational(3, 5)) == sin(pi*Rational(2, 5))
assert sin(pi*Rational(4, 5)) == sin(pi*Rational(1, 5))
assert sin(pi*Rational(6, 5)) == -sin(pi*Rational(1, 5))
assert sin(pi*Rational(8, 5)) == -sin(pi*Rational(2, 5))
assert sin(pi*Rational(-1273, 5)) == -sin(pi*Rational(2, 5))
assert sin(pi/8) == sqrt((2 - sqrt(2))/4)
assert sin(pi/10) == Rational(-1, 4) + sqrt(5)/4
assert sin(pi/12) == -sqrt(2)/4 + sqrt(6)/4
assert sin(pi*Rational(5, 12)) == sqrt(2)/4 + sqrt(6)/4
assert sin(pi*Rational(-7, 12)) == -sqrt(2)/4 - sqrt(6)/4
assert sin(pi*Rational(-11, 12)) == sqrt(2)/4 - sqrt(6)/4
assert sin(pi*Rational(104, 105)) == sin(pi/105)
assert sin(pi*Rational(106, 105)) == -sin(pi/105)
assert sin(pi*Rational(-104, 105)) == -sin(pi/105)
assert sin(pi*Rational(-106, 105)) == sin(pi/105)
assert sin(x*I) == sinh(x)*I
assert sin(k*pi) == 0
assert sin(17*k*pi) == 0
assert sin(k*pi*I) == sinh(k*pi)*I
assert sin(r).is_real is True
assert sin(0, evaluate=False).is_algebraic
assert sin(a).is_algebraic is None
assert sin(na).is_algebraic is False
q = Symbol('q', rational=True)
assert sin(pi*q).is_algebraic
qn = Symbol('qn', rational=True, nonzero=True)
assert sin(qn).is_rational is False
assert sin(q).is_rational is None # issue 8653
assert isinstance(sin( re(x) - im(y)), sin) is True
assert isinstance(sin(-re(x) + im(y)), sin) is False
assert sin(SetExpr(Interval(0, 1))) == SetExpr(ImageSet(Lambda(x, sin(x)),
Interval(0, 1)))
for d in list(range(1, 22)) + [60, 85]:
for n in range(0, d*2 + 1):
x = n*pi/d
e = abs( float(sin(x)) - sin(float(x)) )
assert e < 1e-12
assert sin(0, evaluate=False).is_zero is True
assert sin(k*pi, evaluate=False).is_zero is None
assert sin(Add(1, -1, evaluate=False), evaluate=False).is_zero is True
def test_sin_cos():
for d in [1, 2, 3, 4, 5, 6, 10, 12, 15, 20, 24, 30, 40, 60, 120]: # list is not exhaustive...
for n in range(-2*d, d*2):
x = n*pi/d
assert sin(x + pi/2) == cos(x), "fails for %d*pi/%d" % (n, d)
assert sin(x - pi/2) == -cos(x), "fails for %d*pi/%d" % (n, d)
assert sin(x) == cos(x - pi/2), "fails for %d*pi/%d" % (n, d)
assert -sin(x) == cos(x + pi/2), "fails for %d*pi/%d" % (n, d)
def test_sin_series():
assert sin(x).series(x, 0, 9) == \
x - x**3/6 + x**5/120 - x**7/5040 + O(x**9)
def test_sin_rewrite():
assert sin(x).rewrite(exp) == -I*(exp(I*x) - exp(-I*x))/2
assert sin(x).rewrite(tan) == 2*tan(x/2)/(1 + tan(x/2)**2)
assert sin(x).rewrite(cot) == 2*cot(x/2)/(1 + cot(x/2)**2)
assert sin(sinh(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, sinh(3)).n()
assert sin(cosh(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, cosh(3)).n()
assert sin(tanh(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, tanh(3)).n()
assert sin(coth(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, coth(3)).n()
assert sin(sin(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, sin(3)).n()
assert sin(cos(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, cos(3)).n()
assert sin(tan(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, tan(3)).n()
assert sin(cot(x)).rewrite(
exp).subs(x, 3).n() == sin(x).rewrite(exp).subs(x, cot(3)).n()
assert sin(log(x)).rewrite(Pow) == I*x**-I / 2 - I*x**I /2
assert sin(x).rewrite(csc) == 1/csc(x)
assert sin(x).rewrite(cos) == cos(x - pi / 2, evaluate=False)
assert sin(x).rewrite(sec) == 1 / sec(x - pi / 2, evaluate=False)
assert sin(cos(x)).rewrite(Pow) == sin(cos(x))
def test_sin_expansion():
# Note: these formulas are not unique. The ones here come from the
# Chebyshev formulas.
assert sin(x + y).expand(trig=True) == sin(x)*cos(y) + cos(x)*sin(y)
assert sin(x - y).expand(trig=True) == sin(x)*cos(y) - cos(x)*sin(y)
assert sin(y - x).expand(trig=True) == cos(x)*sin(y) - sin(x)*cos(y)
assert sin(2*x).expand(trig=True) == 2*sin(x)*cos(x)
assert sin(3*x).expand(trig=True) == -4*sin(x)**3 + 3*sin(x)
assert sin(4*x).expand(trig=True) == -8*sin(x)**3*cos(x) + 4*sin(x)*cos(x)
assert sin(2).expand(trig=True) == 2*sin(1)*cos(1)
assert sin(3).expand(trig=True) == -4*sin(1)**3 + 3*sin(1)
def test_sin_AccumBounds():
assert sin(AccumBounds(-oo, oo)) == AccumBounds(-1, 1)
assert sin(AccumBounds(0, oo)) == AccumBounds(-1, 1)
assert sin(AccumBounds(-oo, 0)) == AccumBounds(-1, 1)
assert sin(AccumBounds(0, 2*S.Pi)) == AccumBounds(-1, 1)
assert sin(AccumBounds(0, S.Pi*Rational(3, 4))) == AccumBounds(0, 1)
assert sin(AccumBounds(S.Pi*Rational(3, 4), S.Pi*Rational(7, 4))) == AccumBounds(-1, sin(S.Pi*Rational(3, 4)))
assert sin(AccumBounds(S.Pi/4, S.Pi/3)) == AccumBounds(sin(S.Pi/4), sin(S.Pi/3))
assert sin(AccumBounds(S.Pi*Rational(3, 4), S.Pi*Rational(5, 6))) == AccumBounds(sin(S.Pi*Rational(5, 6)), sin(S.Pi*Rational(3, 4)))
def test_sin_fdiff():
assert sin(x).fdiff() == cos(x)
raises(ArgumentIndexError, lambda: sin(x).fdiff(2))
def test_trig_symmetry():
assert sin(-x) == -sin(x)
assert cos(-x) == cos(x)
assert tan(-x) == -tan(x)
assert cot(-x) == -cot(x)
assert sin(x + pi) == -sin(x)
assert sin(x + 2*pi) == sin(x)
assert sin(x + 3*pi) == -sin(x)
assert sin(x + 4*pi) == sin(x)
assert sin(x - 5*pi) == -sin(x)
assert cos(x + pi) == -cos(x)
assert cos(x + 2*pi) == cos(x)
assert cos(x + 3*pi) == -cos(x)
assert cos(x + 4*pi) == cos(x)
assert cos(x - 5*pi) == -cos(x)
assert tan(x + pi) == tan(x)
assert tan(x - 3*pi) == tan(x)
assert cot(x + pi) == cot(x)
assert cot(x - 3*pi) == cot(x)
assert sin(pi/2 - x) == cos(x)
assert sin(pi*Rational(3, 2) - x) == -cos(x)
assert sin(pi*Rational(5, 2) - x) == cos(x)
assert cos(pi/2 - x) == sin(x)
assert cos(pi*Rational(3, 2) - x) == -sin(x)
assert cos(pi*Rational(5, 2) - x) == sin(x)
assert tan(pi/2 - x) == cot(x)
assert tan(pi*Rational(3, 2) - x) == cot(x)
assert tan(pi*Rational(5, 2) - x) == cot(x)
assert cot(pi/2 - x) == tan(x)
assert cot(pi*Rational(3, 2) - x) == tan(x)
assert cot(pi*Rational(5, 2) - x) == tan(x)
assert sin(pi/2 + x) == cos(x)
assert cos(pi/2 + x) == -sin(x)
assert tan(pi/2 + x) == -cot(x)
assert cot(pi/2 + x) == -tan(x)
def test_cos():
x, y = symbols('x y')
assert cos.nargs == FiniteSet(1)
assert cos(nan) is nan
assert cos(oo) == AccumBounds(-1, 1)
assert cos(oo) - cos(oo) == AccumBounds(-2, 2)
assert cos(oo*I) is oo
assert cos(-oo*I) is oo
assert cos(zoo) is nan
assert cos(0) == 1
assert cos(acos(x)) == x
assert cos(atan(x)) == 1 / sqrt(1 + x**2)
assert cos(asin(x)) == sqrt(1 - x**2)
assert cos(acot(x)) == 1 / sqrt(1 + 1 / x**2)
assert cos(acsc(x)) == sqrt(1 - 1 / x**2)
assert cos(asec(x)) == 1 / x
assert cos(atan2(y, x)) == x / sqrt(x**2 + y**2)
assert cos(pi*I) == cosh(pi)
assert cos(-pi*I) == cosh(pi)
assert cos(-2*I) == cosh(2)
assert cos(pi/2) == 0
assert cos(-pi/2) == 0
assert cos(pi/2) == 0
assert cos(-pi/2) == 0
assert cos((-3*10**73 + 1)*pi/2) == 0
assert cos((7*10**103 + 1)*pi/2) == 0
n = symbols('n', integer=True, even=False)
e = symbols('e', even=True)
assert cos(pi*n/2) == 0
assert cos(pi*e/2) == (-1)**(e/2)
assert cos(pi) == -1
assert cos(-pi) == -1
assert cos(2*pi) == 1
assert cos(5*pi) == -1
assert cos(8*pi) == 1
assert cos(pi/3) == S.Half
assert cos(pi*Rational(-2, 3)) == Rational(-1, 2)
assert cos(pi/4) == S.Half*sqrt(2)
assert cos(-pi/4) == S.Half*sqrt(2)
assert cos(pi*Rational(11, 4)) == Rational(-1, 2)*sqrt(2)
assert cos(pi*Rational(-3, 4)) == Rational(-1, 2)*sqrt(2)
assert cos(pi/6) == S.Half*sqrt(3)
assert cos(-pi/6) == S.Half*sqrt(3)
assert cos(pi*Rational(7, 6)) == Rational(-1, 2)*sqrt(3)
assert cos(pi*Rational(-5, 6)) == Rational(-1, 2)*sqrt(3)
assert cos(pi*Rational(1, 5)) == (sqrt(5) + 1)/4
assert cos(pi*Rational(2, 5)) == (sqrt(5) - 1)/4
assert cos(pi*Rational(3, 5)) == -cos(pi*Rational(2, 5))
assert cos(pi*Rational(4, 5)) == -cos(pi*Rational(1, 5))
assert cos(pi*Rational(6, 5)) == -cos(pi*Rational(1, 5))
assert cos(pi*Rational(8, 5)) == cos(pi*Rational(2, 5))
assert cos(pi*Rational(-1273, 5)) == -cos(pi*Rational(2, 5))
assert cos(pi/8) == sqrt((2 + sqrt(2))/4)
assert cos(pi/12) == sqrt(2)/4 + sqrt(6)/4
assert cos(pi*Rational(5, 12)) == -sqrt(2)/4 + sqrt(6)/4
assert cos(pi*Rational(7, 12)) == sqrt(2)/4 - sqrt(6)/4
assert cos(pi*Rational(11, 12)) == -sqrt(2)/4 - sqrt(6)/4
assert cos(pi*Rational(104, 105)) == -cos(pi/105)
assert cos(pi*Rational(106, 105)) == -cos(pi/105)
assert cos(pi*Rational(-104, 105)) == -cos(pi/105)
assert cos(pi*Rational(-106, 105)) == -cos(pi/105)
assert cos(x*I) == cosh(x)
assert cos(k*pi*I) == cosh(k*pi)
assert cos(r).is_real is True
assert cos(0, evaluate=False).is_algebraic
assert cos(a).is_algebraic is None
assert cos(na).is_algebraic is False
q = Symbol('q', rational=True)
assert cos(pi*q).is_algebraic
assert cos(pi*Rational(2, 7)).is_algebraic
assert cos(k*pi) == (-1)**k
assert cos(2*k*pi) == 1
for d in list(range(1, 22)) + [60, 85]:
for n in range(0, 2*d + 1):
x = n*pi/d
e = abs( float(cos(x)) - cos(float(x)) )
assert e < 1e-12
def test_issue_6190():
c = Float('123456789012345678901234567890.25', '')
for cls in [sin, cos, tan, cot]:
assert cls(c*pi) == cls(pi/4)
assert cls(4.125*pi) == cls(pi/8)
assert cls(4.7*pi) == cls((4.7 % 2)*pi)
def test_cos_series():
assert cos(x).series(x, 0, 9) == \
1 - x**2/2 + x**4/24 - x**6/720 + x**8/40320 + O(x**9)
def test_cos_rewrite():
assert cos(x).rewrite(exp) == exp(I*x)/2 + exp(-I*x)/2
assert cos(x).rewrite(tan) == (1 - tan(x/2)**2)/(1 + tan(x/2)**2)
assert cos(x).rewrite(cot) == -(1 - cot(x/2)**2)/(1 + cot(x/2)**2)
assert cos(sinh(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, sinh(3)).n()
assert cos(cosh(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, cosh(3)).n()
assert cos(tanh(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, tanh(3)).n()
assert cos(coth(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, coth(3)).n()
assert cos(sin(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, sin(3)).n()
assert cos(cos(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, cos(3)).n()
assert cos(tan(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, tan(3)).n()
assert cos(cot(x)).rewrite(
exp).subs(x, 3).n() == cos(x).rewrite(exp).subs(x, cot(3)).n()
assert cos(log(x)).rewrite(Pow) == x**I/2 + x**-I/2
assert cos(x).rewrite(sec) == 1/sec(x)
assert cos(x).rewrite(sin) == sin(x + pi/2, evaluate=False)
assert cos(x).rewrite(csc) == 1/csc(-x + pi/2, evaluate=False)
assert cos(sin(x)).rewrite(Pow) == cos(sin(x))
def test_cos_expansion():
assert cos(x + y).expand(trig=True) == cos(x)*cos(y) - sin(x)*sin(y)
assert cos(x - y).expand(trig=True) == cos(x)*cos(y) + sin(x)*sin(y)
assert cos(y - x).expand(trig=True) == cos(x)*cos(y) + sin(x)*sin(y)
assert cos(2*x).expand(trig=True) == 2*cos(x)**2 - 1
assert cos(3*x).expand(trig=True) == 4*cos(x)**3 - 3*cos(x)
assert cos(4*x).expand(trig=True) == 8*cos(x)**4 - 8*cos(x)**2 + 1
assert cos(2).expand(trig=True) == 2*cos(1)**2 - 1
assert cos(3).expand(trig=True) == 4*cos(1)**3 - 3*cos(1)
def test_cos_AccumBounds():
assert cos(AccumBounds(-oo, oo)) == AccumBounds(-1, 1)
assert cos(AccumBounds(0, oo)) == AccumBounds(-1, 1)
assert cos(AccumBounds(-oo, 0)) == AccumBounds(-1, 1)
assert cos(AccumBounds(0, 2*S.Pi)) == AccumBounds(-1, 1)
assert cos(AccumBounds(-S.Pi/3, S.Pi/4)) == AccumBounds(cos(-S.Pi/3), 1)
assert cos(AccumBounds(S.Pi*Rational(3, 4), S.Pi*Rational(5, 4))) == AccumBounds(-1, cos(S.Pi*Rational(3, 4)))
assert cos(AccumBounds(S.Pi*Rational(5, 4), S.Pi*Rational(4, 3))) == AccumBounds(cos(S.Pi*Rational(5, 4)), cos(S.Pi*Rational(4, 3)))
assert cos(AccumBounds(S.Pi/4, S.Pi/3)) == AccumBounds(cos(S.Pi/3), cos(S.Pi/4))
def test_cos_fdiff():
assert cos(x).fdiff() == -sin(x)
raises(ArgumentIndexError, lambda: cos(x).fdiff(2))
def test_tan():
assert tan(nan) is nan
assert tan(zoo) is nan
assert tan(oo) == AccumBounds(-oo, oo)
assert tan(oo) - tan(oo) == AccumBounds(-oo, oo)
assert tan.nargs == FiniteSet(1)
assert tan(oo*I) == I
assert tan(-oo*I) == -I
assert tan(0) == 0
assert tan(atan(x)) == x
assert tan(asin(x)) == x / sqrt(1 - x**2)
assert tan(acos(x)) == sqrt(1 - x**2) / x
assert tan(acot(x)) == 1 / x
assert tan(acsc(x)) == 1 / (sqrt(1 - 1 / x**2) * x)
assert tan(asec(x)) == sqrt(1 - 1 / x**2) * x
assert tan(atan2(y, x)) == y/x
assert tan(pi*I) == tanh(pi)*I
assert tan(-pi*I) == -tanh(pi)*I
assert tan(-2*I) == -tanh(2)*I
assert tan(pi) == 0
assert tan(-pi) == 0
assert tan(2*pi) == 0
assert tan(-2*pi) == 0
assert tan(-3*10**73*pi) == 0
assert tan(pi/2) is zoo
assert tan(pi*Rational(3, 2)) is zoo
assert tan(pi/3) == sqrt(3)
assert tan(pi*Rational(-2, 3)) == sqrt(3)
assert tan(pi/4) is S.One
assert tan(-pi/4) is S.NegativeOne
assert tan(pi*Rational(17, 4)) is S.One
assert tan(pi*Rational(-3, 4)) is S.One
assert tan(pi/5) == sqrt(5 - 2*sqrt(5))
assert tan(pi*Rational(2, 5)) == sqrt(5 + 2*sqrt(5))
assert tan(pi*Rational(18, 5)) == -sqrt(5 + 2*sqrt(5))
assert tan(pi*Rational(-16, 5)) == -sqrt(5 - 2*sqrt(5))
assert tan(pi/6) == 1/sqrt(3)
assert tan(-pi/6) == -1/sqrt(3)
assert tan(pi*Rational(7, 6)) == 1/sqrt(3)
assert tan(pi*Rational(-5, 6)) == 1/sqrt(3)
assert tan(pi/8) == -1 + sqrt(2)
assert tan(pi*Rational(3, 8)) == 1 + sqrt(2) # issue 15959
assert tan(pi*Rational(5, 8)) == -1 - sqrt(2)
assert tan(pi*Rational(7, 8)) == 1 - sqrt(2)
assert tan(pi/10) == sqrt(1 - 2*sqrt(5)/5)
assert tan(pi*Rational(3, 10)) == sqrt(1 + 2*sqrt(5)/5)
assert tan(pi*Rational(17, 10)) == -sqrt(1 + 2*sqrt(5)/5)
assert tan(pi*Rational(-31, 10)) == -sqrt(1 - 2*sqrt(5)/5)
assert tan(pi/12) == -sqrt(3) + 2
assert tan(pi*Rational(5, 12)) == sqrt(3) + 2
assert tan(pi*Rational(7, 12)) == -sqrt(3) - 2
assert tan(pi*Rational(11, 12)) == sqrt(3) - 2
assert tan(pi/24).radsimp() == -2 - sqrt(3) + sqrt(2) + sqrt(6)
assert tan(pi*Rational(5, 24)).radsimp() == -2 + sqrt(3) - sqrt(2) + sqrt(6)
assert tan(pi*Rational(7, 24)).radsimp() == 2 - sqrt(3) - sqrt(2) + sqrt(6)
assert tan(pi*Rational(11, 24)).radsimp() == 2 + sqrt(3) + sqrt(2) + sqrt(6)
assert tan(pi*Rational(13, 24)).radsimp() == -2 - sqrt(3) - sqrt(2) - sqrt(6)
assert tan(pi*Rational(17, 24)).radsimp() == -2 + sqrt(3) + sqrt(2) - sqrt(6)
assert tan(pi*Rational(19, 24)).radsimp() == 2 - sqrt(3) + sqrt(2) - sqrt(6)
assert tan(pi*Rational(23, 24)).radsimp() == 2 + sqrt(3) - sqrt(2) - sqrt(6)
assert tan(x*I) == tanh(x)*I
assert tan(k*pi) == 0
assert tan(17*k*pi) == 0
assert tan(k*pi*I) == tanh(k*pi)*I
assert tan(r).is_real is None
assert tan(r).is_extended_real is True
assert tan(0, evaluate=False).is_algebraic
assert tan(a).is_algebraic is None
assert tan(na).is_algebraic is False
assert tan(pi*Rational(10, 7)) == tan(pi*Rational(3, 7))
assert tan(pi*Rational(11, 7)) == -tan(pi*Rational(3, 7))
assert tan(pi*Rational(-11, 7)) == tan(pi*Rational(3, 7))
assert tan(pi*Rational(15, 14)) == tan(pi/14)
assert tan(pi*Rational(-15, 14)) == -tan(pi/14)
assert tan(r).is_finite is None
assert tan(I*r).is_finite is True
def test_tan_series():
assert tan(x).series(x, 0, 9) == \
x + x**3/3 + 2*x**5/15 + 17*x**7/315 + O(x**9)
def test_tan_rewrite():
neg_exp, pos_exp = exp(-x*I), exp(x*I)
assert tan(x).rewrite(exp) == I*(neg_exp - pos_exp)/(neg_exp + pos_exp)
assert tan(x).rewrite(sin) == 2*sin(x)**2/sin(2*x)
assert tan(x).rewrite(cos) == cos(x - S.Pi/2, evaluate=False)/cos(x)
assert tan(x).rewrite(cot) == 1/cot(x)
assert tan(sinh(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, sinh(3)).n()
assert tan(cosh(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, cosh(3)).n()
assert tan(tanh(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, tanh(3)).n()
assert tan(coth(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, coth(3)).n()
assert tan(sin(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, sin(3)).n()
assert tan(cos(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, cos(3)).n()
assert tan(tan(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, tan(3)).n()
assert tan(cot(x)).rewrite(
exp).subs(x, 3).n() == tan(x).rewrite(exp).subs(x, cot(3)).n()
assert tan(log(x)).rewrite(Pow) == I*(x**-I - x**I)/(x**-I + x**I)
assert 0 == (cos(pi/34)*tan(pi/34) - sin(pi/34)).rewrite(pow)
assert 0 == (cos(pi/17)*tan(pi/17) - sin(pi/17)).rewrite(pow)
assert tan(pi/19).rewrite(pow) == tan(pi/19)
assert tan(pi*Rational(8, 19)).rewrite(sqrt) == tan(pi*Rational(8, 19))
assert tan(x).rewrite(sec) == sec(x)/sec(x - pi/2, evaluate=False)
assert tan(x).rewrite(csc) == csc(-x + pi/2, evaluate=False)/csc(x)
assert tan(sin(x)).rewrite(Pow) == tan(sin(x))
assert tan(pi*Rational(2, 5), evaluate=False).rewrite(sqrt) == sqrt(sqrt(5)/8 +
Rational(5, 8))/(Rational(-1, 4) + sqrt(5)/4)
def test_tan_subs():
assert tan(x).subs(tan(x), y) == y
assert tan(x).subs(x, y) == tan(y)
assert tan(x).subs(x, S.Pi/2) is zoo
assert tan(x).subs(x, S.Pi*Rational(3, 2)) is zoo
def test_tan_expansion():
assert tan(x + y).expand(trig=True) == ((tan(x) + tan(y))/(1 - tan(x)*tan(y))).expand()
assert tan(x - y).expand(trig=True) == ((tan(x) - tan(y))/(1 + tan(x)*tan(y))).expand()
assert tan(x + y + z).expand(trig=True) == (
(tan(x) + tan(y) + tan(z) - tan(x)*tan(y)*tan(z))/
(1 - tan(x)*tan(y) - tan(x)*tan(z) - tan(y)*tan(z))).expand()
assert 0 == tan(2*x).expand(trig=True).rewrite(tan).subs([(tan(x), Rational(1, 7))])*24 - 7
assert 0 == tan(3*x).expand(trig=True).rewrite(tan).subs([(tan(x), Rational(1, 5))])*55 - 37
assert 0 == tan(4*x - pi/4).expand(trig=True).rewrite(tan).subs([(tan(x), Rational(1, 5))])*239 - 1
def test_tan_AccumBounds():
assert tan(AccumBounds(-oo, oo)) == AccumBounds(-oo, oo)
assert tan(AccumBounds(S.Pi/3, S.Pi*Rational(2, 3))) == AccumBounds(-oo, oo)
assert tan(AccumBounds(S.Pi/6, S.Pi/3)) == AccumBounds(tan(S.Pi/6), tan(S.Pi/3))
def test_tan_fdiff():
assert tan(x).fdiff() == tan(x)**2 + 1
raises(ArgumentIndexError, lambda: tan(x).fdiff(2))
def test_cot():
assert cot(nan) is nan
assert cot.nargs == FiniteSet(1)
assert cot(oo*I) == -I
assert cot(-oo*I) == I
assert cot(zoo) is nan
assert cot(0) is zoo
assert cot(2*pi) is zoo
assert cot(acot(x)) == x
assert cot(atan(x)) == 1 / x
assert cot(asin(x)) == sqrt(1 - x**2) / x
assert cot(acos(x)) == x / sqrt(1 - x**2)
assert cot(acsc(x)) == sqrt(1 - 1 / x**2) * x
assert cot(asec(x)) == 1 / (sqrt(1 - 1 / x**2) * x)
assert cot(atan2(y, x)) == x/y
assert cot(pi*I) == -coth(pi)*I
assert cot(-pi*I) == coth(pi)*I
assert cot(-2*I) == coth(2)*I
assert cot(pi) == cot(2*pi) == cot(3*pi)
assert cot(-pi) == cot(-2*pi) == cot(-3*pi)
assert cot(pi/2) == 0
assert cot(-pi/2) == 0
assert cot(pi*Rational(5, 2)) == 0
assert cot(pi*Rational(7, 2)) == 0
assert cot(pi/3) == 1/sqrt(3)
assert cot(pi*Rational(-2, 3)) == 1/sqrt(3)
assert cot(pi/4) is S.One
assert cot(-pi/4) is S.NegativeOne
assert cot(pi*Rational(17, 4)) is S.One
assert cot(pi*Rational(-3, 4)) is S.One
assert cot(pi/6) == sqrt(3)
assert cot(-pi/6) == -sqrt(3)
assert cot(pi*Rational(7, 6)) == sqrt(3)
assert cot(pi*Rational(-5, 6)) == sqrt(3)
assert cot(pi/8) == 1 + sqrt(2)
assert cot(pi*Rational(3, 8)) == -1 + sqrt(2)
assert cot(pi*Rational(5, 8)) == 1 - sqrt(2)
assert cot(pi*Rational(7, 8)) == -1 - sqrt(2)
assert cot(pi/12) == sqrt(3) + 2
assert cot(pi*Rational(5, 12)) == -sqrt(3) + 2
assert cot(pi*Rational(7, 12)) == sqrt(3) - 2
assert cot(pi*Rational(11, 12)) == -sqrt(3) - 2
assert cot(pi/24).radsimp() == sqrt(2) + sqrt(3) + 2 + sqrt(6)
assert cot(pi*Rational(5, 24)).radsimp() == -sqrt(2) - sqrt(3) + 2 + sqrt(6)
assert cot(pi*Rational(7, 24)).radsimp() == -sqrt(2) + sqrt(3) - 2 + sqrt(6)
assert cot(pi*Rational(11, 24)).radsimp() == sqrt(2) - sqrt(3) - 2 + sqrt(6)
assert cot(pi*Rational(13, 24)).radsimp() == -sqrt(2) + sqrt(3) + 2 - sqrt(6)
assert cot(pi*Rational(17, 24)).radsimp() == sqrt(2) - sqrt(3) + 2 - sqrt(6)
assert cot(pi*Rational(19, 24)).radsimp() == sqrt(2) + sqrt(3) - 2 - sqrt(6)
assert cot(pi*Rational(23, 24)).radsimp() == -sqrt(2) - sqrt(3) - 2 - sqrt(6)
assert cot(x*I) == -coth(x)*I
assert cot(k*pi*I) == -coth(k*pi)*I
assert cot(r).is_real is None
assert cot(r).is_extended_real is True
assert cot(a).is_algebraic is None
assert cot(na).is_algebraic is False
assert cot(pi*Rational(10, 7)) == cot(pi*Rational(3, 7))
assert cot(pi*Rational(11, 7)) == -cot(pi*Rational(3, 7))
assert cot(pi*Rational(-11, 7)) == cot(pi*Rational(3, 7))
assert cot(pi*Rational(39, 34)) == cot(pi*Rational(5, 34))
assert cot(pi*Rational(-41, 34)) == -cot(pi*Rational(7, 34))
assert cot(x).is_finite is None
assert cot(r).is_finite is None
i = Symbol('i', imaginary=True)
assert cot(i).is_finite is True
assert cot(x).subs(x, 3*pi) is zoo
def test_tan_cot_sin_cos_evalf():
assert abs((tan(pi*Rational(8, 15))*cos(pi*Rational(8, 15))/sin(pi*Rational(8, 15)) - 1).evalf()) < 1e-14
assert abs((cot(pi*Rational(4, 15))*sin(pi*Rational(4, 15))/cos(pi*Rational(4, 15)) - 1).evalf()) < 1e-14
@XFAIL
def test_tan_cot_sin_cos_ratsimp():
assert 1 == (tan(pi*Rational(8, 15))*cos(pi*Rational(8, 15))/sin(pi*Rational(8, 15))).ratsimp()
assert 1 == (cot(pi*Rational(4, 15))*sin(pi*Rational(4, 15))/cos(pi*Rational(4, 15))).ratsimp()
def test_cot_series():
assert cot(x).series(x, 0, 9) == \
1/x - x/3 - x**3/45 - 2*x**5/945 - x**7/4725 + O(x**9)
# issue 6210
assert cot(x**4 + x**5).series(x, 0, 1) == \
x**(-4) - 1/x**3 + x**(-2) - 1/x + 1 + O(x)
assert cot(pi*(1-x)).series(x, 0, 3) == -1/(pi*x) + pi*x/3 + O(x**3)
assert cot(x).taylor_term(0, x) == 1/x
assert cot(x).taylor_term(2, x) is S.Zero
assert cot(x).taylor_term(3, x) == -x**3/45
def test_cot_rewrite():
neg_exp, pos_exp = exp(-x*I), exp(x*I)
assert cot(x).rewrite(exp) == I*(pos_exp + neg_exp)/(pos_exp - neg_exp)
assert cot(x).rewrite(sin) == sin(2*x)/(2*(sin(x)**2))
assert cot(x).rewrite(cos) == cos(x)/cos(x - pi/2, evaluate=False)
assert cot(x).rewrite(tan) == 1/tan(x)
assert cot(sinh(x)).rewrite(
exp).subs(x, 3).n() == cot(x).rewrite(exp).subs(x, sinh(3)).n()
assert cot(cosh(x)).rewrite(
exp).subs(x, 3).n() == cot(x).rewrite(exp).subs(x, cosh(3)).n()
assert cot(tanh(x)).rewrite(
exp).subs(x, 3).n() == cot(x).rewrite(exp).subs(x, tanh(3)).n()
assert cot(coth(x)).rewrite(
exp).subs(x, 3).n() == cot(x).rewrite(exp).subs(x, coth(3)).n()
assert cot(sin(x)).rewrite(
exp).subs(x, 3).n() == cot(x).rewrite(exp).subs(x, sin(3)).n()
assert cot(tan(x)).rewrite(
exp).subs(x, 3).n() == cot(x).rewrite(exp).subs(x, tan(3)).n()
assert cot(log(x)).rewrite(Pow) == -I*(x**-I + x**I)/(x**-I - x**I)
assert cot(pi*Rational(4, 34)).rewrite(pow).ratsimp() == (cos(pi*Rational(4, 34))/sin(pi*Rational(4, 34))).rewrite(pow).ratsimp()
assert cot(pi*Rational(4, 17)).rewrite(pow) == (cos(pi*Rational(4, 17))/sin(pi*Rational(4, 17))).rewrite(pow)
assert cot(pi/19).rewrite(pow) == cot(pi/19)
assert cot(pi/19).rewrite(sqrt) == cot(pi/19)
assert cot(x).rewrite(sec) == sec(x - pi / 2, evaluate=False) / sec(x)
assert cot(x).rewrite(csc) == csc(x) / csc(- x + pi / 2, evaluate=False)
assert cot(sin(x)).rewrite(Pow) == cot(sin(x))
assert cot(pi*Rational(2, 5), evaluate=False).rewrite(sqrt) == (Rational(-1, 4) + sqrt(5)/4)/\
sqrt(sqrt(5)/8 + Rational(5, 8))
def test_cot_subs():
assert cot(x).subs(cot(x), y) == y
assert cot(x).subs(x, y) == cot(y)
assert cot(x).subs(x, 0) is zoo
assert cot(x).subs(x, S.Pi) is zoo
def test_cot_expansion():
assert cot(x + y).expand(trig=True) == ((cot(x)*cot(y) - 1)/(cot(x) + cot(y))).expand()
assert cot(x - y).expand(trig=True) == (-(cot(x)*cot(y) + 1)/(cot(x) - cot(y))).expand()
assert cot(x + y + z).expand(trig=True) == (
(cot(x)*cot(y)*cot(z) - cot(x) - cot(y) - cot(z))/
(-1 + cot(x)*cot(y) + cot(x)*cot(z) + cot(y)*cot(z))).expand()
assert cot(3*x).expand(trig=True) == ((cot(x)**3 - 3*cot(x))/(3*cot(x)**2 - 1)).expand()
assert 0 == cot(2*x).expand(trig=True).rewrite(cot).subs([(cot(x), Rational(1, 3))])*3 + 4
assert 0 == cot(3*x).expand(trig=True).rewrite(cot).subs([(cot(x), Rational(1, 5))])*55 - 37
assert 0 == cot(4*x - pi/4).expand(trig=True).rewrite(cot).subs([(cot(x), Rational(1, 7))])*863 + 191
def test_cot_AccumBounds():
assert cot(AccumBounds(-oo, oo)) == AccumBounds(-oo, oo)
assert cot(AccumBounds(-S.Pi/3, S.Pi/3)) == AccumBounds(-oo, oo)
assert cot(AccumBounds(S.Pi/6, S.Pi/3)) == AccumBounds(cot(S.Pi/3), cot(S.Pi/6))
def test_cot_fdiff():
assert cot(x).fdiff() == -cot(x)**2 - 1
raises(ArgumentIndexError, lambda: cot(x).fdiff(2))
def test_sinc():
assert isinstance(sinc(x), sinc)
s = Symbol('s', zero=True)
assert sinc(s) is S.One
assert sinc(S.Infinity) is S.Zero
assert sinc(S.NegativeInfinity) is S.Zero
assert sinc(S.NaN) is S.NaN
assert sinc(S.ComplexInfinity) is S.NaN
n = Symbol('n', integer=True, nonzero=True)
assert sinc(n*pi) is S.Zero
assert sinc(-n*pi) is S.Zero
assert sinc(pi/2) == 2 / pi
assert sinc(-pi/2) == 2 / pi
assert sinc(pi*Rational(5, 2)) == 2 / (5*pi)
assert sinc(pi*Rational(7, 2)) == -2 / (7*pi)
assert sinc(-x) == sinc(x)
assert sinc(x).diff() == Piecewise(((x*cos(x) - sin(x)) / x**2, Ne(x, 0)), (0, True))
assert sinc(x).diff(x).equals(sinc(x).rewrite(sin).diff(x))
assert sinc(x).diff().subs(x, 0) is S.Zero
assert sinc(x).series() == 1 - x**2/6 + x**4/120 + O(x**6)
assert sinc(x).rewrite(jn) == jn(0, x)
assert sinc(x).rewrite(sin) == Piecewise((sin(x)/x, Ne(x, 0)), (1, True))
def test_asin():
assert asin(nan) is nan
assert asin.nargs == FiniteSet(1)
assert asin(oo) == -I*oo
assert asin(-oo) == I*oo
assert asin(zoo) is zoo
# Note: asin(-x) = - asin(x)
assert asin(0) == 0
assert asin(1) == pi/2
assert asin(-1) == -pi/2
assert asin(sqrt(3)/2) == pi/3
assert asin(-sqrt(3)/2) == -pi/3
assert asin(sqrt(2)/2) == pi/4
assert asin(-sqrt(2)/2) == -pi/4
assert asin(sqrt((5 - sqrt(5))/8)) == pi/5
assert asin(-sqrt((5 - sqrt(5))/8)) == -pi/5
assert asin(S.Half) == pi/6
assert asin(Rational(-1, 2)) == -pi/6
assert asin((sqrt(2 - sqrt(2)))/2) == pi/8
assert asin(-(sqrt(2 - sqrt(2)))/2) == -pi/8
assert asin((sqrt(5) - 1)/4) == pi/10
assert asin(-(sqrt(5) - 1)/4) == -pi/10
assert asin((sqrt(3) - 1)/sqrt(2**3)) == pi/12
assert asin(-(sqrt(3) - 1)/sqrt(2**3)) == -pi/12
# check round-trip for exact values:
for d in [5, 6, 8, 10, 12]:
for n in range(-(d//2), d//2 + 1):
if gcd(n, d) == 1:
assert asin(sin(n*pi/d)) == n*pi/d
assert asin(x).diff(x) == 1/sqrt(1 - x**2)
assert asin(0.2).is_real is True
assert asin(-2).is_real is False
assert asin(r).is_real is None
assert asin(-2*I) == -I*asinh(2)
assert asin(Rational(1, 7), evaluate=False).is_positive is True
assert asin(Rational(-1, 7), evaluate=False).is_positive is False
assert asin(p).is_positive is None
assert asin(sin(Rational(7, 2))) == Rational(-7, 2) + pi
assert asin(sin(Rational(-7, 4))) == Rational(7, 4) - pi
assert unchanged(asin, cos(x))
def test_asin_series():
assert asin(x).series(x, 0, 9) == \
x + x**3/6 + 3*x**5/40 + 5*x**7/112 + O(x**9)
t5 = asin(x).taylor_term(5, x)
assert t5 == 3*x**5/40
assert asin(x).taylor_term(7, x, t5, 0) == 5*x**7/112
def test_asin_rewrite():
assert asin(x).rewrite(log) == -I*log(I*x + sqrt(1 - x**2))
assert asin(x).rewrite(atan) == 2*atan(x/(1 + sqrt(1 - x**2)))
assert asin(x).rewrite(acos) == S.Pi/2 - acos(x)
assert asin(x).rewrite(acot) == 2*acot((sqrt(-x**2 + 1) + 1)/x)
assert asin(x).rewrite(asec) == -asec(1/x) + pi/2
assert asin(x).rewrite(acsc) == acsc(1/x)
def test_asin_fdiff():
assert asin(x).fdiff() == 1/sqrt(1 - x**2)
raises(ArgumentIndexError, lambda: asin(x).fdiff(2))
def test_acos():
assert acos(nan) is nan
assert acos(zoo) is zoo
assert acos.nargs == FiniteSet(1)
assert acos(oo) == I*oo
assert acos(-oo) == -I*oo
# Note: acos(-x) = pi - acos(x)
assert acos(0) == pi/2
assert acos(S.Half) == pi/3
assert acos(Rational(-1, 2)) == pi*Rational(2, 3)
assert acos(1) == 0
assert acos(-1) == pi
assert acos(sqrt(2)/2) == pi/4
assert acos(-sqrt(2)/2) == pi*Rational(3, 4)
# check round-trip for exact values:
for d in [5, 6, 8, 10, 12]:
for num in range(d):
if gcd(num, d) == 1:
assert acos(cos(num*pi/d)) == num*pi/d
assert acos(2*I) == pi/2 - asin(2*I)
assert acos(x).diff(x) == -1/sqrt(1 - x**2)
assert acos(0.2).is_real is True
assert acos(-2).is_real is False
assert acos(r).is_real is None
assert acos(Rational(1, 7), evaluate=False).is_positive is True
assert acos(Rational(-1, 7), evaluate=False).is_positive is True
assert acos(Rational(3, 2), evaluate=False).is_positive is False
assert acos(p).is_positive is None
assert acos(2 + p).conjugate() != acos(10 + p)
assert acos(-3 + n).conjugate() != acos(-3 + n)
assert acos(Rational(1, 3)).conjugate() == acos(Rational(1, 3))
assert acos(Rational(-1, 3)).conjugate() == acos(Rational(-1, 3))
assert acos(p + n*I).conjugate() == acos(p - n*I)
assert acos(z).conjugate() != acos(conjugate(z))
def test_acos_series():
assert acos(x).series(x, 0, 8) == \
pi/2 - x - x**3/6 - 3*x**5/40 - 5*x**7/112 + O(x**8)
assert acos(x).series(x, 0, 8) == pi/2 - asin(x).series(x, 0, 8)
t5 = acos(x).taylor_term(5, x)
assert t5 == -3*x**5/40
assert acos(x).taylor_term(7, x, t5, 0) == -5*x**7/112
assert acos(x).taylor_term(0, x) == pi/2
assert acos(x).taylor_term(2, x) is S.Zero
def test_acos_rewrite():
assert acos(x).rewrite(log) == pi/2 + I*log(I*x + sqrt(1 - x**2))
assert acos(x).rewrite(atan) == \
atan(sqrt(1 - x**2)/x) + (pi/2)*(1 - x*sqrt(1/x**2))
assert acos(0).rewrite(atan) == S.Pi/2
assert acos(0.5).rewrite(atan) == acos(0.5).rewrite(log)
assert acos(x).rewrite(asin) == S.Pi/2 - asin(x)
assert acos(x).rewrite(acot) == -2*acot((sqrt(-x**2 + 1) + 1)/x) + pi/2
assert acos(x).rewrite(asec) == asec(1/x)
assert acos(x).rewrite(acsc) == -acsc(1/x) + pi/2
def test_acos_fdiff():
assert acos(x).fdiff() == -1/sqrt(1 - x**2)
raises(ArgumentIndexError, lambda: acos(x).fdiff(2))
def test_atan():
assert atan(nan) is nan
assert atan.nargs == FiniteSet(1)
assert atan(oo) == pi/2
assert atan(-oo) == -pi/2
assert atan(zoo) == AccumBounds(-pi/2, pi/2)
assert atan(0) == 0
assert atan(1) == pi/4
assert atan(sqrt(3)) == pi/3
assert atan(-(1 + sqrt(2))) == pi*Rational(-3, 8)
assert atan(sqrt(5 - 2 * sqrt(5))) == pi/5
assert atan(-sqrt(1 - 2 * sqrt(5)/ 5)) == -pi/10
assert atan(sqrt(1 + 2 * sqrt(5) / 5)) == pi*Rational(3, 10)
assert atan(-2 + sqrt(3)) == -pi/12
assert atan(2 + sqrt(3)) == pi*Rational(5, 12)
assert atan(-2 - sqrt(3)) == pi*Rational(-5, 12)
# check round-trip for exact values:
for d in [5, 6, 8, 10, 12]:
for num in range(-(d//2), d//2 + 1):
if gcd(num, d) == 1:
assert atan(tan(num*pi/d)) == num*pi/d
assert atan(oo) == pi/2
assert atan(x).diff(x) == 1/(1 + x**2)
assert atan(r).is_real is True
assert atan(-2*I) == -I*atanh(2)
assert unchanged(atan, cot(x))
assert atan(cot(Rational(1, 4))) == Rational(-1, 4) + pi/2
assert acot(Rational(1, 4)).is_rational is False
for s in (x, p, n, np, nn, nz, ep, en, enp, enn, enz):
if s.is_real or s.is_extended_real is None:
assert s.is_nonzero is atan(s).is_nonzero
assert s.is_positive is atan(s).is_positive
assert s.is_negative is atan(s).is_negative
assert s.is_nonpositive is atan(s).is_nonpositive
assert s.is_nonnegative is atan(s).is_nonnegative
else:
assert s.is_extended_nonzero is atan(s).is_nonzero
assert s.is_extended_positive is atan(s).is_positive
assert s.is_extended_negative is atan(s).is_negative
assert s.is_extended_nonpositive is atan(s).is_nonpositive
assert s.is_extended_nonnegative is atan(s).is_nonnegative
assert s.is_extended_nonzero is atan(s).is_extended_nonzero
assert s.is_extended_positive is atan(s).is_extended_positive
assert s.is_extended_negative is atan(s).is_extended_negative
assert s.is_extended_nonpositive is atan(s).is_extended_nonpositive
assert s.is_extended_nonnegative is atan(s).is_extended_nonnegative
def test_atan_rewrite():
assert atan(x).rewrite(log) == I*(log(1 - I*x)-log(1 + I*x))/2
assert atan(x).rewrite(asin) == (-asin(1/sqrt(x**2 + 1)) + pi/2)*sqrt(x**2)/x
assert atan(x).rewrite(acos) == sqrt(x**2)*acos(1/sqrt(x**2 + 1))/x
assert atan(x).rewrite(acot) == acot(1/x)
assert atan(x).rewrite(asec) == sqrt(x**2)*asec(sqrt(x**2 + 1))/x
assert atan(x).rewrite(acsc) == (-acsc(sqrt(x**2 + 1)) + pi/2)*sqrt(x**2)/x
assert atan(-5*I).evalf() == atan(x).rewrite(log).evalf(subs={x:-5*I})
assert atan(5*I).evalf() == atan(x).rewrite(log).evalf(subs={x:5*I})
def test_atan_fdiff():
assert atan(x).fdiff() == 1/(x**2 + 1)
raises(ArgumentIndexError, lambda: atan(x).fdiff(2))
def test_atan2():
assert atan2.nargs == FiniteSet(2)
assert atan2(0, 0) is S.NaN
assert atan2(0, 1) == 0
assert atan2(1, 1) == pi/4
assert atan2(1, 0) == pi/2
assert atan2(1, -1) == pi*Rational(3, 4)
assert atan2(0, -1) == pi
assert atan2(-1, -1) == pi*Rational(-3, 4)
assert atan2(-1, 0) == -pi/2
assert atan2(-1, 1) == -pi/4
i = symbols('i', imaginary=True)
r = symbols('r', real=True)
eq = atan2(r, i)
ans = -I*log((i + I*r)/sqrt(i**2 + r**2))
reps = ((r, 2), (i, I))
assert eq.subs(reps) == ans.subs(reps)
x = Symbol('x', negative=True)
y = Symbol('y', negative=True)
assert atan2(y, x) == atan(y/x) - pi
y = Symbol('y', nonnegative=True)
assert atan2(y, x) == atan(y/x) + pi
y = Symbol('y')
assert atan2(y, x) == atan2(y, x, evaluate=False)
u = Symbol("u", positive=True)
assert atan2(0, u) == 0
u = Symbol("u", negative=True)
assert atan2(0, u) == pi
assert atan2(y, oo) == 0
assert atan2(y, -oo)== 2*pi*Heaviside(re(y)) - pi
assert atan2(y, x).rewrite(log) == -I*log((x + I*y)/sqrt(x**2 + y**2))
assert atan2(0, 0) is S.NaN
ex = atan2(y, x) - arg(x + I*y)
assert ex.subs({x:2, y:3}).rewrite(arg) == 0
assert ex.subs({x:2, y:3*I}).rewrite(arg) == -pi - I*log(sqrt(5)*I/5)
assert ex.subs({x:2*I, y:3}).rewrite(arg) == -pi/2 - I*log(sqrt(5)*I)
assert ex.subs({x:2*I, y:3*I}).rewrite(arg) == -pi + atan(Rational(2, 3)) + atan(Rational(3, 2))
i = symbols('i', imaginary=True)
r = symbols('r', real=True)
e = atan2(i, r)
rewrite = e.rewrite(arg)
reps = {i: I, r: -2}
assert rewrite == -I*log(abs(I*i + r)/sqrt(abs(i**2 + r**2))) + arg((I*i + r)/sqrt(i**2 + r**2))
assert (e - rewrite).subs(reps).equals(0)
assert atan2(0, x).rewrite(atan) == Piecewise((pi, re(x) < 0),
(0, Ne(x, 0)),
(nan, True))
assert atan2(0, r).rewrite(atan) == Piecewise((pi, r < 0), (0, Ne(r, 0)), (S.NaN, True))
assert atan2(0, i),rewrite(atan) == 0
assert atan2(0, r + i).rewrite(atan) == Piecewise((pi, r < 0), (0, True))
assert atan2(y, x).rewrite(atan) == Piecewise(
(2*atan(y/(x + sqrt(x**2 + y**2))), Ne(y, 0)),
(pi, re(x) < 0),
(0, (re(x) > 0) | Ne(im(x), 0)),
(nan, True))
assert conjugate(atan2(x, y)) == atan2(conjugate(x), conjugate(y))
assert diff(atan2(y, x), x) == -y/(x**2 + y**2)
assert diff(atan2(y, x), y) == x/(x**2 + y**2)
assert simplify(diff(atan2(y, x).rewrite(log), x)) == -y/(x**2 + y**2)
assert simplify(diff(atan2(y, x).rewrite(log), y)) == x/(x**2 + y**2)
assert str(atan2(1, 2).evalf(5)) == '0.46365'
raises(ArgumentIndexError, lambda: atan2(x, y).fdiff(3))
def test_issue_17461():
class A(Symbol):
is_extended_real = True
def _eval_evalf(self, prec):
return Float(5.0)
x = A('X')
y = A('Y')
assert abs(atan2(x, y).evalf() - 0.785398163397448) <= 1e-10
def test_acot():
assert acot(nan) is nan
assert acot.nargs == FiniteSet(1)
assert acot(-oo) == 0
assert acot(oo) == 0
assert acot(zoo) == 0
assert acot(1) == pi/4
assert acot(0) == pi/2
assert acot(sqrt(3)/3) == pi/3
assert acot(1/sqrt(3)) == pi/3
assert acot(-1/sqrt(3)) == -pi/3
assert acot(x).diff(x) == -1/(1 + x**2)
assert acot(r).is_extended_real is True
assert acot(I*pi) == -I*acoth(pi)
assert acot(-2*I) == I*acoth(2)
assert acot(x).is_positive is None
assert acot(n).is_positive is False
assert acot(p).is_positive is True
assert acot(I).is_positive is False
assert acot(Rational(1, 4)).is_rational is False
assert unchanged(acot, cot(x))
assert unchanged(acot, tan(x))
assert acot(cot(Rational(1, 4))) == Rational(1, 4)
assert acot(tan(Rational(-1, 4))) == Rational(1, 4) - pi/2
def test_acot_rewrite():
assert acot(x).rewrite(log) == I*(log(1 - I/x)-log(1 + I/x))/2
assert acot(x).rewrite(asin) == x*(-asin(sqrt(-x**2)/sqrt(-x**2 - 1)) + pi/2)*sqrt(x**(-2))
assert acot(x).rewrite(acos) == x*sqrt(x**(-2))*acos(sqrt(-x**2)/sqrt(-x**2 - 1))
assert acot(x).rewrite(atan) == atan(1/x)
assert acot(x).rewrite(asec) == x*sqrt(x**(-2))*asec(sqrt((x**2 + 1)/x**2))
assert acot(x).rewrite(acsc) == x*(-acsc(sqrt((x**2 + 1)/x**2)) + pi/2)*sqrt(x**(-2))
assert acot(-I/5).evalf() == acot(x).rewrite(log).evalf(subs={x:-I/5})
assert acot(I/5).evalf() == acot(x).rewrite(log).evalf(subs={x:I/5})
def test_acot_fdiff():
assert acot(x).fdiff() == -1/(x**2 + 1)
raises(ArgumentIndexError, lambda: acot(x).fdiff(2))
def test_attributes():
assert sin(x).args == (x,)
def test_sincos_rewrite():
assert sin(pi/2 - x) == cos(x)
assert sin(pi - x) == sin(x)
assert cos(pi/2 - x) == sin(x)
assert cos(pi - x) == -cos(x)
def _check_even_rewrite(func, arg):
"""Checks that the expr has been rewritten using f(-x) -> f(x)
arg : -x
"""
return func(arg).args[0] == -arg
def _check_odd_rewrite(func, arg):
"""Checks that the expr has been rewritten using f(-x) -> -f(x)
arg : -x
"""
return func(arg).func.is_Mul
def _check_no_rewrite(func, arg):
"""Checks that the expr is not rewritten"""
return func(arg).args[0] == arg
def test_evenodd_rewrite():
a = cos(2) # negative
b = sin(1) # positive
even = [cos]
odd = [sin, tan, cot, asin, atan, acot]
with_minus = [-1, -2**1024 * E, -pi/105, -x*y, -x - y]
for func in even:
for expr in with_minus:
assert _check_even_rewrite(func, expr)
assert _check_no_rewrite(func, a*b)
assert func(
x - y) == func(y - x) # it doesn't matter which form is canonical
for func in odd:
for expr in with_minus:
assert _check_odd_rewrite(func, expr)
assert _check_no_rewrite(func, a*b)
assert func(
x - y) == -func(y - x) # it doesn't matter which form is canonical
def test_issue_4547():
assert sin(x).rewrite(cot) == 2*cot(x/2)/(1 + cot(x/2)**2)
assert cos(x).rewrite(cot) == -(1 - cot(x/2)**2)/(1 + cot(x/2)**2)
assert tan(x).rewrite(cot) == 1/cot(x)
assert cot(x).fdiff() == -1 - cot(x)**2
def test_as_leading_term_issue_5272():
assert sin(x).as_leading_term(x) == x
assert cos(x).as_leading_term(x) == 1
assert tan(x).as_leading_term(x) == x
assert cot(x).as_leading_term(x) == 1/x
assert asin(x).as_leading_term(x) == x
assert acos(x).as_leading_term(x) == x
assert atan(x).as_leading_term(x) == x
assert acot(x).as_leading_term(x) == x
def test_leading_terms():
for func in [sin, cos, tan, cot, asin, acos, atan, acot]:
for a in (1/x, S.Half):
eq = func(a)
assert eq.as_leading_term(x) == eq
def test_atan2_expansion():
assert cancel(atan2(x**2, x + 1).diff(x) - atan(x**2/(x + 1)).diff(x)) == 0
assert cancel(atan(y/x).series(y, 0, 5) - atan2(y, x).series(y, 0, 5)
+ atan2(0, x) - atan(0)) == O(y**5)
assert cancel(atan(y/x).series(x, 1, 4) - atan2(y, x).series(x, 1, 4)
+ atan2(y, 1) - atan(y)) == O((x - 1)**4, (x, 1))
assert cancel(atan((y + x)/x).series(x, 1, 3) - atan2(y + x, x).series(x, 1, 3)
+ atan2(1 + y, 1) - atan(1 + y)) == O((x - 1)**3, (x, 1))
assert Matrix([atan2(y, x)]).jacobian([y, x]) == \
Matrix([[x/(y**2 + x**2), -y/(y**2 + x**2)]])
def test_aseries():
def t(n, v, d, e):
assert abs(
n(1/v).evalf() - n(1/x).series(x, dir=d).removeO().subs(x, v)) < e
t(atan, 0.1, '+', 1e-5)
t(atan, -0.1, '-', 1e-5)
t(acot, 0.1, '+', 1e-5)
t(acot, -0.1, '-', 1e-5)
def test_issue_4420():
i = Symbol('i', integer=True)
e = Symbol('e', even=True)
o = Symbol('o', odd=True)
# unknown parity for variable
assert cos(4*i*pi) == 1
assert sin(4*i*pi) == 0
assert tan(4*i*pi) == 0
assert cot(4*i*pi) is zoo
assert cos(3*i*pi) == cos(pi*i) # +/-1
assert sin(3*i*pi) == 0
assert tan(3*i*pi) == 0
assert cot(3*i*pi) is zoo
assert cos(4.0*i*pi) == 1
assert sin(4.0*i*pi) == 0
assert tan(4.0*i*pi) == 0
assert cot(4.0*i*pi) is zoo
assert cos(3.0*i*pi) == cos(pi*i) # +/-1
assert sin(3.0*i*pi) == 0
assert tan(3.0*i*pi) == 0
assert cot(3.0*i*pi) is zoo
assert cos(4.5*i*pi) == cos(0.5*pi*i)
assert sin(4.5*i*pi) == sin(0.5*pi*i)
assert tan(4.5*i*pi) == tan(0.5*pi*i)
assert cot(4.5*i*pi) == cot(0.5*pi*i)
# parity of variable is known
assert cos(4*e*pi) == 1
assert sin(4*e*pi) == 0
assert tan(4*e*pi) == 0
assert cot(4*e*pi) is zoo
assert cos(3*e*pi) == 1
assert sin(3*e*pi) == 0
assert tan(3*e*pi) == 0
assert cot(3*e*pi) is zoo
assert cos(4.0*e*pi) == 1
assert sin(4.0*e*pi) == 0
assert tan(4.0*e*pi) == 0
assert cot(4.0*e*pi) is zoo
assert cos(3.0*e*pi) == 1
assert sin(3.0*e*pi) == 0
assert tan(3.0*e*pi) == 0
assert cot(3.0*e*pi) is zoo
assert cos(4.5*e*pi) == cos(0.5*pi*e)
assert sin(4.5*e*pi) == sin(0.5*pi*e)
assert tan(4.5*e*pi) == tan(0.5*pi*e)
assert cot(4.5*e*pi) == cot(0.5*pi*e)
assert cos(4*o*pi) == 1
assert sin(4*o*pi) == 0
assert tan(4*o*pi) == 0
assert cot(4*o*pi) is zoo
assert cos(3*o*pi) == -1
assert sin(3*o*pi) == 0
assert tan(3*o*pi) == 0
assert cot(3*o*pi) is zoo
assert cos(4.0*o*pi) == 1
assert sin(4.0*o*pi) == 0
assert tan(4.0*o*pi) == 0
assert cot(4.0*o*pi) is zoo
assert cos(3.0*o*pi) == -1
assert sin(3.0*o*pi) == 0
assert tan(3.0*o*pi) == 0
assert cot(3.0*o*pi) is zoo
assert cos(4.5*o*pi) == cos(0.5*pi*o)
assert sin(4.5*o*pi) == sin(0.5*pi*o)
assert tan(4.5*o*pi) == tan(0.5*pi*o)
assert cot(4.5*o*pi) == cot(0.5*pi*o)
# x could be imaginary
assert cos(4*x*pi) == cos(4*pi*x)
assert sin(4*x*pi) == sin(4*pi*x)
assert tan(4*x*pi) == tan(4*pi*x)
assert cot(4*x*pi) == cot(4*pi*x)
assert cos(3*x*pi) == cos(3*pi*x)
assert sin(3*x*pi) == sin(3*pi*x)
assert tan(3*x*pi) == tan(3*pi*x)
assert cot(3*x*pi) == cot(3*pi*x)
assert cos(4.0*x*pi) == cos(4.0*pi*x)
assert sin(4.0*x*pi) == sin(4.0*pi*x)
assert tan(4.0*x*pi) == tan(4.0*pi*x)
assert cot(4.0*x*pi) == cot(4.0*pi*x)
assert cos(3.0*x*pi) == cos(3.0*pi*x)
assert sin(3.0*x*pi) == sin(3.0*pi*x)
assert tan(3.0*x*pi) == tan(3.0*pi*x)
assert cot(3.0*x*pi) == cot(3.0*pi*x)
assert cos(4.5*x*pi) == cos(4.5*pi*x)
assert sin(4.5*x*pi) == sin(4.5*pi*x)
assert tan(4.5*x*pi) == tan(4.5*pi*x)
assert cot(4.5*x*pi) == cot(4.5*pi*x)
def test_inverses():
raises(AttributeError, lambda: sin(x).inverse())
raises(AttributeError, lambda: cos(x).inverse())
assert tan(x).inverse() == atan
assert cot(x).inverse() == acot
raises(AttributeError, lambda: csc(x).inverse())
raises(AttributeError, lambda: sec(x).inverse())
assert asin(x).inverse() == sin
assert acos(x).inverse() == cos
assert atan(x).inverse() == tan
assert acot(x).inverse() == cot
def test_real_imag():
a, b = symbols('a b', real=True)
z = a + b*I
for deep in [True, False]:
assert sin(
z).as_real_imag(deep=deep) == (sin(a)*cosh(b), cos(a)*sinh(b))
assert cos(
z).as_real_imag(deep=deep) == (cos(a)*cosh(b), -sin(a)*sinh(b))
assert tan(z).as_real_imag(deep=deep) == (sin(2*a)/(cos(2*a) +
cosh(2*b)), sinh(2*b)/(cos(2*a) + cosh(2*b)))
assert cot(z).as_real_imag(deep=deep) == (-sin(2*a)/(cos(2*a) -
cosh(2*b)), sinh(2*b)/(cos(2*a) - cosh(2*b)))
assert sin(a).as_real_imag(deep=deep) == (sin(a), 0)
assert cos(a).as_real_imag(deep=deep) == (cos(a), 0)
assert tan(a).as_real_imag(deep=deep) == (tan(a), 0)
assert cot(a).as_real_imag(deep=deep) == (cot(a), 0)
@XFAIL
def test_sin_cos_with_infinity():
# Test for issue 5196
# https://github.com/sympy/sympy/issues/5196
assert sin(oo) is S.NaN
assert cos(oo) is S.NaN
@slow
def test_sincos_rewrite_sqrt():
# equivalent to testing rewrite(pow)
for p in [1, 3, 5, 17]:
for t in [1, 8]:
n = t*p
# The vertices `exp(i*pi/n)` of a regular `n`-gon can
# be expressed by means of nested square roots if and
# only if `n` is a product of Fermat primes, `p`, and
# powers of 2, `t'. The code aims to check all vertices
# not belonging to an `m`-gon for `m < n`(`gcd(i, n) == 1`).
# For large `n` this makes the test too slow, therefore
# the vertices are limited to those of index `i < 10`.
for i in range(1, min((n + 1)//2 + 1, 10)):
if 1 == gcd(i, n):
x = i*pi/n
s1 = sin(x).rewrite(sqrt)
c1 = cos(x).rewrite(sqrt)
assert not s1.has(cos, sin), "fails for %d*pi/%d" % (i, n)
assert not c1.has(cos, sin), "fails for %d*pi/%d" % (i, n)
assert 1e-3 > abs(sin(x.evalf(5)) - s1.evalf(2)), "fails for %d*pi/%d" % (i, n)
assert 1e-3 > abs(cos(x.evalf(5)) - c1.evalf(2)), "fails for %d*pi/%d" % (i, n)
assert cos(pi/14).rewrite(sqrt) == sqrt(cos(pi/7)/2 + S.Half)
assert cos(pi/257).rewrite(sqrt).evalf(64) == cos(pi/257).evalf(64)
assert cos(pi*Rational(-15, 2)/11, evaluate=False).rewrite(
sqrt) == -sqrt(-cos(pi*Rational(4, 11))/2 + S.Half)
assert cos(Mul(2, pi, S.Half, evaluate=False), evaluate=False).rewrite(
sqrt) == -1
e = cos(pi/3/17) # don't use pi/15 since that is caught at instantiation
a = (
-3*sqrt(-sqrt(17) + 17)*sqrt(sqrt(17) + 17)/64 -
3*sqrt(34)*sqrt(sqrt(17) + 17)/128 - sqrt(sqrt(17) +
17)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) + 17)
+ sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/64 - sqrt(-sqrt(17)
+ 17)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/128 - Rational(1, 32) +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/64 +
3*sqrt(2)*sqrt(sqrt(17) + 17)/128 + sqrt(34)*sqrt(-sqrt(17) + 17)/128
+ 13*sqrt(2)*sqrt(-sqrt(17) + 17)/128 + sqrt(17)*sqrt(-sqrt(17) +
17)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) + 17)
+ sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/128 + 5*sqrt(17)/32
+ sqrt(3)*sqrt(-sqrt(2)*sqrt(sqrt(17) + 17)*sqrt(sqrt(17)/32 +
sqrt(2)*sqrt(-sqrt(17) + 17)/32 +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/32 + Rational(15, 32))/8 -
5*sqrt(2)*sqrt(sqrt(17)/32 + sqrt(2)*sqrt(-sqrt(17) + 17)/32 +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/32 +
Rational(15, 32))*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/64 -
3*sqrt(2)*sqrt(-sqrt(17) + 17)*sqrt(sqrt(17)/32 +
sqrt(2)*sqrt(-sqrt(17) + 17)/32 +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/32 + Rational(15, 32))/32
+ sqrt(34)*sqrt(sqrt(17)/32 + sqrt(2)*sqrt(-sqrt(17) + 17)/32 +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/32 +
Rational(15, 32))*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/64 +
sqrt(sqrt(17)/32 + sqrt(2)*sqrt(-sqrt(17) + 17)/32 +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/32 + Rational(15, 32))/2 +
S.Half + sqrt(-sqrt(17) + 17)*sqrt(sqrt(17)/32 + sqrt(2)*sqrt(-sqrt(17) +
17)/32 + sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) -
sqrt(2)*sqrt(-sqrt(17) + 17) + sqrt(34)*sqrt(-sqrt(17) + 17) +
6*sqrt(17) + 34)/32 + Rational(15, 32))*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) -
sqrt(2)*sqrt(-sqrt(17) + 17) + sqrt(34)*sqrt(-sqrt(17) + 17) +
6*sqrt(17) + 34)/32 + sqrt(34)*sqrt(-sqrt(17) + 17)*sqrt(sqrt(17)/32 +
sqrt(2)*sqrt(-sqrt(17) + 17)/32 +
sqrt(2)*sqrt(-8*sqrt(2)*sqrt(sqrt(17) + 17) - sqrt(2)*sqrt(-sqrt(17) +
17) + sqrt(34)*sqrt(-sqrt(17) + 17) + 6*sqrt(17) + 34)/32 +
Rational(15, 32))/32)/2)
assert e.rewrite(sqrt) == a
assert e.n() == a.n()
# coverage of fermatCoords: multiplicity > 1; the following could be
# different but that portion of the code should be tested in some way
assert cos(pi/9/17).rewrite(sqrt) == \
sin(pi/9)*sin(pi*Rational(2, 17)) + cos(pi/9)*cos(pi*Rational(2, 17))
@slow
def test_tancot_rewrite_sqrt():
# equivalent to testing rewrite(pow)
for p in [1, 3, 5, 17]:
for t in [1, 8]:
n = t*p
for i in range(1, min((n + 1)//2 + 1, 10)):
if 1 == gcd(i, n):
x = i*pi/n
if 2*i != n and 3*i != 2*n:
t1 = tan(x).rewrite(sqrt)
assert not t1.has(cot, tan), "fails for %d*pi/%d" % (i, n)
assert 1e-3 > abs( tan(x.evalf(7)) - t1.evalf(4) ), "fails for %d*pi/%d" % (i, n)
if i != 0 and i != n:
c1 = cot(x).rewrite(sqrt)
assert not c1.has(cot, tan), "fails for %d*pi/%d" % (i, n)
assert 1e-3 > abs( cot(x.evalf(7)) - c1.evalf(4) ), "fails for %d*pi/%d" % (i, n)
def test_sec():
x = symbols('x', real=True)
z = symbols('z')
assert sec.nargs == FiniteSet(1)
assert sec(zoo) is nan
assert sec(0) == 1
assert sec(pi) == -1
assert sec(pi/2) is zoo
assert sec(-pi/2) is zoo
assert sec(pi/6) == 2*sqrt(3)/3
assert sec(pi/3) == 2
assert sec(pi*Rational(5, 2)) is zoo
assert sec(pi*Rational(9, 7)) == -sec(pi*Rational(2, 7))
assert sec(pi*Rational(3, 4)) == -sqrt(2) # issue 8421
assert sec(I) == 1/cosh(1)
assert sec(x*I) == 1/cosh(x)
assert sec(-x) == sec(x)
assert sec(asec(x)) == x
assert sec(z).conjugate() == sec(conjugate(z))
assert (sec(z).as_real_imag() ==
(cos(re(z))*cosh(im(z))/(sin(re(z))**2*sinh(im(z))**2 +
cos(re(z))**2*cosh(im(z))**2),
sin(re(z))*sinh(im(z))/(sin(re(z))**2*sinh(im(z))**2 +
cos(re(z))**2*cosh(im(z))**2)))
assert sec(x).expand(trig=True) == 1/cos(x)
assert sec(2*x).expand(trig=True) == 1/(2*cos(x)**2 - 1)
assert sec(x).is_extended_real == True
assert sec(z).is_real == None
assert sec(a).is_algebraic is None
assert sec(na).is_algebraic is False
assert sec(x).as_leading_term() == sec(x)
assert sec(0).is_finite == True
assert sec(x).is_finite == None
assert sec(pi/2).is_finite == False
assert series(sec(x), x, x0=0, n=6) == 1 + x**2/2 + 5*x**4/24 + O(x**6)
# https://github.com/sympy/sympy/issues/7166
assert series(sqrt(sec(x))) == 1 + x**2/4 + 7*x**4/96 + O(x**6)
# https://github.com/sympy/sympy/issues/7167
assert (series(sqrt(sec(x)), x, x0=pi*3/2, n=4) ==
1/sqrt(x - pi*Rational(3, 2)) + (x - pi*Rational(3, 2))**Rational(3, 2)/12 +
(x - pi*Rational(3, 2))**Rational(7, 2)/160 + O((x - pi*Rational(3, 2))**4, (x, pi*Rational(3, 2))))
assert sec(x).diff(x) == tan(x)*sec(x)
# Taylor Term checks
assert sec(z).taylor_term(4, z) == 5*z**4/24
assert sec(z).taylor_term(6, z) == 61*z**6/720
assert sec(z).taylor_term(5, z) == 0
def test_sec_rewrite():
assert sec(x).rewrite(exp) == 1/(exp(I*x)/2 + exp(-I*x)/2)
assert sec(x).rewrite(cos) == 1/cos(x)
assert sec(x).rewrite(tan) == (tan(x/2)**2 + 1)/(-tan(x/2)**2 + 1)
assert sec(x).rewrite(pow) == sec(x)
assert sec(x).rewrite(sqrt) == sec(x)
assert sec(z).rewrite(cot) == (cot(z/2)**2 + 1)/(cot(z/2)**2 - 1)
assert sec(x).rewrite(sin) == 1 / sin(x + pi / 2, evaluate=False)
assert sec(x).rewrite(tan) == (tan(x / 2)**2 + 1) / (-tan(x / 2)**2 + 1)
assert sec(x).rewrite(csc) == csc(-x + pi/2, evaluate=False)
def test_sec_fdiff():
assert sec(x).fdiff() == tan(x)*sec(x)
raises(ArgumentIndexError, lambda: sec(x).fdiff(2))
def test_csc():
x = symbols('x', real=True)
z = symbols('z')
# https://github.com/sympy/sympy/issues/6707
cosecant = csc('x')
alternate = 1/sin('x')
assert cosecant.equals(alternate) == True
assert alternate.equals(cosecant) == True
assert csc.nargs == FiniteSet(1)
assert csc(0) is zoo
assert csc(pi) is zoo
assert csc(zoo) is nan
assert csc(pi/2) == 1
assert csc(-pi/2) == -1
assert csc(pi/6) == 2
assert csc(pi/3) == 2*sqrt(3)/3
assert csc(pi*Rational(5, 2)) == 1
assert csc(pi*Rational(9, 7)) == -csc(pi*Rational(2, 7))
assert csc(pi*Rational(3, 4)) == sqrt(2) # issue 8421
assert csc(I) == -I/sinh(1)
assert csc(x*I) == -I/sinh(x)
assert csc(-x) == -csc(x)
assert csc(acsc(x)) == x
assert csc(z).conjugate() == csc(conjugate(z))
assert (csc(z).as_real_imag() ==
(sin(re(z))*cosh(im(z))/(sin(re(z))**2*cosh(im(z))**2 +
cos(re(z))**2*sinh(im(z))**2),
-cos(re(z))*sinh(im(z))/(sin(re(z))**2*cosh(im(z))**2 +
cos(re(z))**2*sinh(im(z))**2)))
assert csc(x).expand(trig=True) == 1/sin(x)
assert csc(2*x).expand(trig=True) == 1/(2*sin(x)*cos(x))
assert csc(x).is_extended_real == True
assert csc(z).is_real == None
assert csc(a).is_algebraic is None
assert csc(na).is_algebraic is False
assert csc(x).as_leading_term() == csc(x)
assert csc(0).is_finite == False
assert csc(x).is_finite == None
assert csc(pi/2).is_finite == True
assert series(csc(x), x, x0=pi/2, n=6) == \
1 + (x - pi/2)**2/2 + 5*(x - pi/2)**4/24 + O((x - pi/2)**6, (x, pi/2))
assert series(csc(x), x, x0=0, n=6) == \
1/x + x/6 + 7*x**3/360 + 31*x**5/15120 + O(x**6)
assert csc(x).diff(x) == -cot(x)*csc(x)
assert csc(x).taylor_term(2, x) == 0
assert csc(x).taylor_term(3, x) == 7*x**3/360
assert csc(x).taylor_term(5, x) == 31*x**5/15120
raises(ArgumentIndexError, lambda: csc(x).fdiff(2))
def test_asec():
z = Symbol('z', zero=True)
assert asec(z) is zoo
assert asec(nan) is nan
assert asec(1) == 0
assert asec(-1) == pi
assert asec(oo) == pi/2
assert asec(-oo) == pi/2
assert asec(zoo) == pi/2
assert asec(sec(pi*Rational(13, 4))) == pi*Rational(3, 4)
assert asec(1 + sqrt(5)) == pi*Rational(2, 5)
assert asec(2/sqrt(3)) == pi/6
assert asec(sqrt(4 - 2*sqrt(2))) == pi/8
assert asec(-sqrt(4 + 2*sqrt(2))) == pi*Rational(5, 8)
assert asec(sqrt(2 + 2*sqrt(5)/5)) == pi*Rational(3, 10)
assert asec(-sqrt(2 + 2*sqrt(5)/5)) == pi*Rational(7, 10)
assert asec(sqrt(2) - sqrt(6)) == pi*Rational(11, 12)
assert asec(x).diff(x) == 1/(x**2*sqrt(1 - 1/x**2))
assert asec(x).as_leading_term(x) == log(x)
assert asec(x).rewrite(log) == I*log(sqrt(1 - 1/x**2) + I/x) + pi/2
assert asec(x).rewrite(asin) == -asin(1/x) + pi/2
assert asec(x).rewrite(acos) == acos(1/x)
assert asec(x).rewrite(atan) == (2*atan(x + sqrt(x**2 - 1)) - pi/2)*sqrt(x**2)/x
assert asec(x).rewrite(acot) == (2*acot(x - sqrt(x**2 - 1)) - pi/2)*sqrt(x**2)/x
assert asec(x).rewrite(acsc) == -acsc(x) + pi/2
raises(ArgumentIndexError, lambda: asec(x).fdiff(2))
def test_asec_is_real():
assert asec(S.Half).is_real is False
n = Symbol('n', positive=True, integer=True)
assert asec(n).is_extended_real is True
assert asec(x).is_real is None
assert asec(r).is_real is None
t = Symbol('t', real=False, finite=True)
assert asec(t).is_real is False
def test_acsc():
assert acsc(nan) is nan
assert acsc(1) == pi/2
assert acsc(-1) == -pi/2
assert acsc(oo) == 0
assert acsc(-oo) == 0
assert acsc(zoo) == 0
assert acsc(0) is zoo
assert acsc(csc(3)) == -3 + pi
assert acsc(csc(4)) == -4 + pi
assert acsc(csc(6)) == 6 - 2*pi
assert unchanged(acsc, csc(x))
assert unchanged(acsc, sec(x))
assert acsc(2/sqrt(3)) == pi/3
assert acsc(csc(pi*Rational(13, 4))) == -pi/4
assert acsc(sqrt(2 + 2*sqrt(5)/5)) == pi/5
assert acsc(-sqrt(2 + 2*sqrt(5)/5)) == -pi/5
assert acsc(-2) == -pi/6
assert acsc(-sqrt(4 + 2*sqrt(2))) == -pi/8
assert acsc(sqrt(4 - 2*sqrt(2))) == pi*Rational(3, 8)
assert acsc(1 + sqrt(5)) == pi/10
assert acsc(sqrt(2) - sqrt(6)) == pi*Rational(-5, 12)
assert acsc(x).diff(x) == -1/(x**2*sqrt(1 - 1/x**2))
assert acsc(x).as_leading_term(x) == log(x)
assert acsc(x).rewrite(log) == -I*log(sqrt(1 - 1/x**2) + I/x)
assert acsc(x).rewrite(asin) == asin(1/x)
assert acsc(x).rewrite(acos) == -acos(1/x) + pi/2
assert acsc(x).rewrite(atan) == (-atan(sqrt(x**2 - 1)) + pi/2)*sqrt(x**2)/x
assert acsc(x).rewrite(acot) == (-acot(1/sqrt(x**2 - 1)) + pi/2)*sqrt(x**2)/x
assert acsc(x).rewrite(asec) == -asec(x) + pi/2
raises(ArgumentIndexError, lambda: acsc(x).fdiff(2))
def test_csc_rewrite():
assert csc(x).rewrite(pow) == csc(x)
assert csc(x).rewrite(sqrt) == csc(x)
assert csc(x).rewrite(exp) == 2*I/(exp(I*x) - exp(-I*x))
assert csc(x).rewrite(sin) == 1/sin(x)
assert csc(x).rewrite(tan) == (tan(x/2)**2 + 1)/(2*tan(x/2))
assert csc(x).rewrite(cot) == (cot(x/2)**2 + 1)/(2*cot(x/2))
assert csc(x).rewrite(cos) == 1/cos(x - pi/2, evaluate=False)
assert csc(x).rewrite(sec) == sec(-x + pi/2, evaluate=False)
# issue 17349
assert csc(1 - exp(-besselj(I, I))).rewrite(cos) == \
-1/cos(-pi/2 - 1 + cos(I*besselj(I, I)) +
I*cos(-pi/2 + I*besselj(I, I), evaluate=False), evaluate=False)
def test_issue_8653():
n = Symbol('n', integer=True)
assert sin(n).is_irrational is None
assert cos(n).is_irrational is None
assert tan(n).is_irrational is None
def test_issue_9157():
n = Symbol('n', integer=True, positive=True)
assert atan(n - 1).is_nonnegative is True
def test_trig_period():
x, y = symbols('x, y')
assert sin(x).period() == 2*pi
assert cos(x).period() == 2*pi
assert tan(x).period() == pi
assert cot(x).period() == pi
assert sec(x).period() == 2*pi
assert csc(x).period() == 2*pi
assert sin(2*x).period() == pi
assert cot(4*x - 6).period() == pi/4
assert cos((-3)*x).period() == pi*Rational(2, 3)
assert cos(x*y).period(x) == 2*pi/abs(y)
assert sin(3*x*y + 2*pi).period(y) == 2*pi/abs(3*x)
assert tan(3*x).period(y) is S.Zero
raises(NotImplementedError, lambda: sin(x**2).period(x))
def test_issue_7171():
assert sin(x).rewrite(sqrt) == sin(x)
assert sin(x).rewrite(pow) == sin(x)
def test_issue_11864():
w, k = symbols('w, k', real=True)
F = Piecewise((1, Eq(2*pi*k, 0)), (sin(pi*k)/(pi*k), True))
soln = Piecewise((1, Eq(2*pi*k, 0)), (sinc(pi*k), True))
assert F.rewrite(sinc) == soln
def test_real_assumptions():
z = Symbol('z', real=False, finite=True)
assert sin(z).is_real is None
assert cos(z).is_real is None
assert tan(z).is_real is False
assert sec(z).is_real is None
assert csc(z).is_real is None
assert cot(z).is_real is False
assert asin(p).is_real is None
assert asin(n).is_real is None
assert asec(p).is_real is None
assert asec(n).is_real is None
assert acos(p).is_real is None
assert acos(n).is_real is None
assert acsc(p).is_real is None
assert acsc(n).is_real is None
assert atan(p).is_positive is True
assert atan(n).is_negative is True
assert acot(p).is_positive is True
assert acot(n).is_negative is True
def test_issue_14320():
assert asin(sin(2)) == -2 + pi and (-pi/2 <= -2 + pi <= pi/2) and sin(2) == sin(-2 + pi)
assert asin(cos(2)) == -2 + pi/2 and (-pi/2 <= -2 + pi/2 <= pi/2) and cos(2) == sin(-2 + pi/2)
assert acos(sin(2)) == -pi/2 + 2 and (0 <= -pi/2 + 2 <= pi) and sin(2) == cos(-pi/2 + 2)
assert acos(cos(20)) == -6*pi + 20 and (0 <= -6*pi + 20 <= pi) and cos(20) == cos(-6*pi + 20)
assert acos(cos(30)) == -30 + 10*pi and (0 <= -30 + 10*pi <= pi) and cos(30) == cos(-30 + 10*pi)
assert atan(tan(17)) == -5*pi + 17 and (-pi/2 < -5*pi + 17 < pi/2) and tan(17) == tan(-5*pi + 17)
assert atan(tan(15)) == -5*pi + 15 and (-pi/2 < -5*pi + 15 < pi/2) and tan(15) == tan(-5*pi + 15)
assert atan(cot(12)) == -12 + pi*Rational(7, 2) and (-pi/2 < -12 + pi*Rational(7, 2) < pi/2) and cot(12) == tan(-12 + pi*Rational(7, 2))
assert acot(cot(15)) == -5*pi + 15 and (-pi/2 < -5*pi + 15 <= pi/2) and cot(15) == cot(-5*pi + 15)
assert acot(tan(19)) == -19 + pi*Rational(13, 2) and (-pi/2 < -19 + pi*Rational(13, 2) <= pi/2) and tan(19) == cot(-19 + pi*Rational(13, 2))
assert asec(sec(11)) == -11 + 4*pi and (0 <= -11 + 4*pi <= pi) and cos(11) == cos(-11 + 4*pi)
assert asec(csc(13)) == -13 + pi*Rational(9, 2) and (0 <= -13 + pi*Rational(9, 2) <= pi) and sin(13) == cos(-13 + pi*Rational(9, 2))
assert acsc(csc(14)) == -4*pi + 14 and (-pi/2 <= -4*pi + 14 <= pi/2) and sin(14) == sin(-4*pi + 14)
assert acsc(sec(10)) == pi*Rational(-7, 2) + 10 and (-pi/2 <= pi*Rational(-7, 2) + 10 <= pi/2) and cos(10) == sin(pi*Rational(-7, 2) + 10)
def test_issue_14543():
assert sec(2*pi + 11) == sec(11)
assert sec(2*pi - 11) == sec(11)
assert sec(pi + 11) == -sec(11)
assert sec(pi - 11) == -sec(11)
assert csc(2*pi + 17) == csc(17)
assert csc(2*pi - 17) == -csc(17)
assert csc(pi + 17) == -csc(17)
assert csc(pi - 17) == csc(17)
x = Symbol('x')
assert csc(pi/2 + x) == sec(x)
assert csc(pi/2 - x) == sec(x)
assert csc(pi*Rational(3, 2) + x) == -sec(x)
assert csc(pi*Rational(3, 2) - x) == -sec(x)
assert sec(pi/2 - x) == csc(x)
assert sec(pi/2 + x) == -csc(x)
assert sec(pi*Rational(3, 2) + x) == csc(x)
assert sec(pi*Rational(3, 2) - x) == -csc(x)
def test_as_real_imag():
# This is for https://github.com/sympy/sympy/issues/17142
# If it start failing again in irrelevant builds or in the master
# please open up the issue again.
expr = atan(I/(I + I*tan(1)))
assert expr.as_real_imag() == (expr, 0)
def test_issue_18746():
e3 = cos(S.Pi*(x/4 + 1/4))
assert e3.period() == 8
|
fb2254711b34ef6aff93b8738b2e5ff61b5199b6324e7558f9e0476a455a8af5 | from sympy import (
Symbol, Dummy, gamma, I, oo, nan, zoo, factorial, sqrt, Rational,
multigamma, log, polygamma, digamma, trigamma, EulerGamma, pi, uppergamma, S, expand_func,
loggamma, sin, cos, O, lowergamma, exp, erf, erfc, exp_polar, harmonic,
zeta, conjugate, Ei, im, re, tanh, Abs)
from sympy.core.expr import unchanged
from sympy.core.function import ArgumentIndexError
from sympy.testing.pytest import raises
from sympy.testing.randtest import (test_derivative_numerically as td,
random_complex_number as randcplx,
verify_numerically as tn)
x = Symbol('x')
y = Symbol('y')
n = Symbol('n', integer=True)
w = Symbol('w', real=True)
def test_gamma():
assert gamma(nan) is nan
assert gamma(oo) is oo
assert gamma(-100) is zoo
assert gamma(0) is zoo
assert gamma(-100.0) is zoo
assert gamma(1) == 1
assert gamma(2) == 1
assert gamma(3) == 2
assert gamma(102) == factorial(101)
assert gamma(S.Half) == sqrt(pi)
assert gamma(Rational(3, 2)) == sqrt(pi)*S.Half
assert gamma(Rational(5, 2)) == sqrt(pi)*Rational(3, 4)
assert gamma(Rational(7, 2)) == sqrt(pi)*Rational(15, 8)
assert gamma(Rational(-1, 2)) == -2*sqrt(pi)
assert gamma(Rational(-3, 2)) == sqrt(pi)*Rational(4, 3)
assert gamma(Rational(-5, 2)) == sqrt(pi)*Rational(-8, 15)
assert gamma(Rational(-15, 2)) == sqrt(pi)*Rational(256, 2027025)
assert gamma(Rational(
-11, 8)).expand(func=True) == Rational(64, 33)*gamma(Rational(5, 8))
assert gamma(Rational(
-10, 3)).expand(func=True) == Rational(81, 280)*gamma(Rational(2, 3))
assert gamma(Rational(
14, 3)).expand(func=True) == Rational(880, 81)*gamma(Rational(2, 3))
assert gamma(Rational(
17, 7)).expand(func=True) == Rational(30, 49)*gamma(Rational(3, 7))
assert gamma(Rational(
19, 8)).expand(func=True) == Rational(33, 64)*gamma(Rational(3, 8))
assert gamma(x).diff(x) == gamma(x)*polygamma(0, x)
assert gamma(x - 1).expand(func=True) == gamma(x)/(x - 1)
assert gamma(x + 2).expand(func=True, mul=False) == x*(x + 1)*gamma(x)
assert conjugate(gamma(x)) == gamma(conjugate(x))
assert expand_func(gamma(x + Rational(3, 2))) == \
(x + S.Half)*gamma(x + S.Half)
assert expand_func(gamma(x - S.Half)) == \
gamma(S.Half + x)/(x - S.Half)
# Test a bug:
assert expand_func(gamma(x + Rational(3, 4))) == gamma(x + Rational(3, 4))
# XXX: Not sure about these tests. I can fix them by defining e.g.
# exp_polar.is_integer but I'm not sure if that makes sense.
assert gamma(3*exp_polar(I*pi)/4).is_nonnegative is False
assert gamma(3*exp_polar(I*pi)/4).is_extended_nonpositive is True
y = Symbol('y', nonpositive=True, integer=True)
assert gamma(y).is_real == False
y = Symbol('y', positive=True, noninteger=True)
assert gamma(y).is_real == True
assert gamma(-1.0, evaluate=False).is_real == False
assert gamma(0, evaluate=False).is_real == False
assert gamma(-2, evaluate=False).is_real == False
def test_gamma_rewrite():
assert gamma(n).rewrite(factorial) == factorial(n - 1)
def test_gamma_series():
assert gamma(x + 1).series(x, 0, 3) == \
1 - EulerGamma*x + x**2*(EulerGamma**2/2 + pi**2/12) + O(x**3)
assert gamma(x).series(x, -1, 3) == \
-1/(x + 1) + EulerGamma - 1 + (x + 1)*(-1 - pi**2/12 - EulerGamma**2/2 + \
EulerGamma) + (x + 1)**2*(-1 - pi**2/12 - EulerGamma**2/2 + EulerGamma**3/6 - \
polygamma(2, 1)/6 + EulerGamma*pi**2/12 + EulerGamma) + O((x + 1)**3, (x, -1))
def tn_branch(s, func):
from sympy import I, pi, exp_polar
from random import uniform
c = uniform(1, 5)
expr = func(s, c*exp_polar(I*pi)) - func(s, c*exp_polar(-I*pi))
eps = 1e-15
expr2 = func(s + eps, -c + eps*I) - func(s + eps, -c - eps*I)
return abs(expr.n() - expr2.n()).n() < 1e-10
def test_lowergamma():
from sympy import meijerg, exp_polar, I, expint
assert lowergamma(x, 0) == 0
assert lowergamma(x, y).diff(y) == y**(x - 1)*exp(-y)
assert td(lowergamma(randcplx(), y), y)
assert td(lowergamma(x, randcplx()), x)
assert lowergamma(x, y).diff(x) == \
gamma(x)*digamma(x) - uppergamma(x, y)*log(y) \
- meijerg([], [1, 1], [0, 0, x], [], y)
assert lowergamma(S.Half, x) == sqrt(pi)*erf(sqrt(x))
assert not lowergamma(S.Half - 3, x).has(lowergamma)
assert not lowergamma(S.Half + 3, x).has(lowergamma)
assert lowergamma(S.Half, x, evaluate=False).has(lowergamma)
assert tn(lowergamma(S.Half + 3, x, evaluate=False),
lowergamma(S.Half + 3, x), x)
assert tn(lowergamma(S.Half - 3, x, evaluate=False),
lowergamma(S.Half - 3, x), x)
assert tn_branch(-3, lowergamma)
assert tn_branch(-4, lowergamma)
assert tn_branch(Rational(1, 3), lowergamma)
assert tn_branch(pi, lowergamma)
assert lowergamma(3, exp_polar(4*pi*I)*x) == lowergamma(3, x)
assert lowergamma(y, exp_polar(5*pi*I)*x) == \
exp(4*I*pi*y)*lowergamma(y, x*exp_polar(pi*I))
assert lowergamma(-2, exp_polar(5*pi*I)*x) == \
lowergamma(-2, x*exp_polar(I*pi)) + 2*pi*I
assert conjugate(lowergamma(x, y)) == lowergamma(conjugate(x), conjugate(y))
assert conjugate(lowergamma(x, 0)) == 0
assert unchanged(conjugate, lowergamma(x, -oo))
assert lowergamma(
x, y).rewrite(expint) == -y**x*expint(-x + 1, y) + gamma(x)
k = Symbol('k', integer=True)
assert lowergamma(
k, y).rewrite(expint) == -y**k*expint(-k + 1, y) + gamma(k)
k = Symbol('k', integer=True, positive=False)
assert lowergamma(k, y).rewrite(expint) == lowergamma(k, y)
assert lowergamma(x, y).rewrite(uppergamma) == gamma(x) - uppergamma(x, y)
assert lowergamma(70, 6) == factorial(69) - 69035724522603011058660187038367026272747334489677105069435923032634389419656200387949342530805432320 * exp(-6)
assert (lowergamma(S(77) / 2, 6) - lowergamma(S(77) / 2, 6, evaluate=False)).evalf() < 1e-16
assert (lowergamma(-S(77) / 2, 6) - lowergamma(-S(77) / 2, 6, evaluate=False)).evalf() < 1e-16
def test_uppergamma():
from sympy import meijerg, exp_polar, I, expint
assert uppergamma(4, 0) == 6
assert uppergamma(x, y).diff(y) == -y**(x - 1)*exp(-y)
assert td(uppergamma(randcplx(), y), y)
assert uppergamma(x, y).diff(x) == \
uppergamma(x, y)*log(y) + meijerg([], [1, 1], [0, 0, x], [], y)
assert td(uppergamma(x, randcplx()), x)
p = Symbol('p', positive=True)
assert uppergamma(0, p) == -Ei(-p)
assert uppergamma(p, 0) == gamma(p)
assert uppergamma(S.Half, x) == sqrt(pi)*erfc(sqrt(x))
assert not uppergamma(S.Half - 3, x).has(uppergamma)
assert not uppergamma(S.Half + 3, x).has(uppergamma)
assert uppergamma(S.Half, x, evaluate=False).has(uppergamma)
assert tn(uppergamma(S.Half + 3, x, evaluate=False),
uppergamma(S.Half + 3, x), x)
assert tn(uppergamma(S.Half - 3, x, evaluate=False),
uppergamma(S.Half - 3, x), x)
assert unchanged(uppergamma, x, -oo)
assert unchanged(uppergamma, x, 0)
assert tn_branch(-3, uppergamma)
assert tn_branch(-4, uppergamma)
assert tn_branch(Rational(1, 3), uppergamma)
assert tn_branch(pi, uppergamma)
assert uppergamma(3, exp_polar(4*pi*I)*x) == uppergamma(3, x)
assert uppergamma(y, exp_polar(5*pi*I)*x) == \
exp(4*I*pi*y)*uppergamma(y, x*exp_polar(pi*I)) + \
gamma(y)*(1 - exp(4*pi*I*y))
assert uppergamma(-2, exp_polar(5*pi*I)*x) == \
uppergamma(-2, x*exp_polar(I*pi)) - 2*pi*I
assert uppergamma(-2, x) == expint(3, x)/x**2
assert conjugate(uppergamma(x, y)) == uppergamma(conjugate(x), conjugate(y))
assert unchanged(conjugate, uppergamma(x, -oo))
assert uppergamma(x, y).rewrite(expint) == y**x*expint(-x + 1, y)
assert uppergamma(x, y).rewrite(lowergamma) == gamma(x) - lowergamma(x, y)
assert uppergamma(70, 6) == 69035724522603011058660187038367026272747334489677105069435923032634389419656200387949342530805432320*exp(-6)
assert (uppergamma(S(77) / 2, 6) - uppergamma(S(77) / 2, 6, evaluate=False)).evalf() < 1e-16
assert (uppergamma(-S(77) / 2, 6) - uppergamma(-S(77) / 2, 6, evaluate=False)).evalf() < 1e-16
def test_polygamma():
from sympy import I
assert polygamma(n, nan) is nan
assert polygamma(0, oo) is oo
assert polygamma(0, -oo) is oo
assert polygamma(0, I*oo) is oo
assert polygamma(0, -I*oo) is oo
assert polygamma(1, oo) == 0
assert polygamma(5, oo) == 0
assert polygamma(0, -9) is zoo
assert polygamma(0, -9) is zoo
assert polygamma(0, -1) is zoo
assert polygamma(0, 0) is zoo
assert polygamma(0, 1) == -EulerGamma
assert polygamma(0, 7) == Rational(49, 20) - EulerGamma
assert polygamma(1, 1) == pi**2/6
assert polygamma(1, 2) == pi**2/6 - 1
assert polygamma(1, 3) == pi**2/6 - Rational(5, 4)
assert polygamma(3, 1) == pi**4 / 15
assert polygamma(3, 5) == 6*(Rational(-22369, 20736) + pi**4/90)
assert polygamma(5, 1) == 8 * pi**6 / 63
assert polygamma(1, S.Half) == pi**2 / 2
assert polygamma(2, S.Half) == -14*zeta(3)
assert polygamma(11, S.Half) == 176896*pi**12
def t(m, n):
x = S(m)/n
r = polygamma(0, x)
if r.has(polygamma):
return False
return abs(polygamma(0, x.n()).n() - r.n()).n() < 1e-10
assert t(1, 2)
assert t(3, 2)
assert t(-1, 2)
assert t(1, 4)
assert t(-3, 4)
assert t(1, 3)
assert t(4, 3)
assert t(3, 4)
assert t(2, 3)
assert t(123, 5)
assert polygamma(0, x).rewrite(zeta) == polygamma(0, x)
assert polygamma(1, x).rewrite(zeta) == zeta(2, x)
assert polygamma(2, x).rewrite(zeta) == -2*zeta(3, x)
assert polygamma(I, 2).rewrite(zeta) == polygamma(I, 2)
n1 = Symbol('n1')
n2 = Symbol('n2', real=True)
n3 = Symbol('n3', integer=True)
n4 = Symbol('n4', positive=True)
n5 = Symbol('n5', positive=True, integer=True)
assert polygamma(n1, x).rewrite(zeta) == polygamma(n1, x)
assert polygamma(n2, x).rewrite(zeta) == polygamma(n2, x)
assert polygamma(n3, x).rewrite(zeta) == polygamma(n3, x)
assert polygamma(n4, x).rewrite(zeta) == polygamma(n4, x)
assert polygamma(n5, x).rewrite(zeta) == (-1)**(n5 + 1) * factorial(n5) * zeta(n5 + 1, x)
assert polygamma(3, 7*x).diff(x) == 7*polygamma(4, 7*x)
assert polygamma(0, x).rewrite(harmonic) == harmonic(x - 1) - EulerGamma
assert polygamma(2, x).rewrite(harmonic) == 2*harmonic(x - 1, 3) - 2*zeta(3)
ni = Symbol("n", integer=True)
assert polygamma(ni, x).rewrite(harmonic) == (-1)**(ni + 1)*(-harmonic(x - 1, ni + 1)
+ zeta(ni + 1))*factorial(ni)
# Polygamma of non-negative integer order is unbranched:
from sympy import exp_polar
k = Symbol('n', integer=True, nonnegative=True)
assert polygamma(k, exp_polar(2*I*pi)*x) == polygamma(k, x)
# but negative integers are branched!
k = Symbol('n', integer=True)
assert polygamma(k, exp_polar(2*I*pi)*x).args == (k, exp_polar(2*I*pi)*x)
# Polygamma of order -1 is loggamma:
assert polygamma(-1, x) == loggamma(x)
# But smaller orders are iterated integrals and don't have a special name
assert polygamma(-2, x).func is polygamma
# Test a bug
assert polygamma(0, -x).expand(func=True) == polygamma(0, -x)
assert polygamma(2, 2.5).is_positive == False
assert polygamma(2, -2.5).is_positive == False
assert polygamma(3, 2.5).is_positive == True
assert polygamma(3, -2.5).is_positive is True
assert polygamma(-2, -2.5).is_positive is None
assert polygamma(-3, -2.5).is_positive is None
assert polygamma(2, 2.5).is_negative == True
assert polygamma(3, 2.5).is_negative == False
assert polygamma(3, -2.5).is_negative == False
assert polygamma(2, -2.5).is_negative is True
assert polygamma(-2, -2.5).is_negative is None
assert polygamma(-3, -2.5).is_negative is None
assert polygamma(I, 2).is_positive is None
assert polygamma(I, 3).is_negative is None
# issue 17350
assert polygamma(pi, 3).evalf() == polygamma(pi, 3)
assert (I*polygamma(I, pi)).as_real_imag() == \
(-im(polygamma(I, pi)), re(polygamma(I, pi)))
assert (tanh(polygamma(I, 1))).rewrite(exp) == \
(exp(polygamma(I, 1)) - exp(-polygamma(I, 1)))/(exp(polygamma(I, 1)) + exp(-polygamma(I, 1)))
assert (I / polygamma(I, 4)).rewrite(exp) == \
I*sqrt(re(polygamma(I, 4))**2 + im(polygamma(I, 4))**2)\
/((re(polygamma(I, 4)) + I*im(polygamma(I, 4)))*Abs(polygamma(I, 4)))
assert unchanged(polygamma, 2.3, 1.0)
# issue 12569
assert unchanged(im, polygamma(0, I))
assert polygamma(Symbol('a', positive=True), Symbol('b', positive=True)).is_real is True
assert polygamma(0, I).is_real is None
def test_polygamma_expand_func():
assert polygamma(0, x).expand(func=True) == polygamma(0, x)
assert polygamma(0, 2*x).expand(func=True) == \
polygamma(0, x)/2 + polygamma(0, S.Half + x)/2 + log(2)
assert polygamma(1, 2*x).expand(func=True) == \
polygamma(1, x)/4 + polygamma(1, S.Half + x)/4
assert polygamma(2, x).expand(func=True) == \
polygamma(2, x)
assert polygamma(0, -1 + x).expand(func=True) == \
polygamma(0, x) - 1/(x - 1)
assert polygamma(0, 1 + x).expand(func=True) == \
1/x + polygamma(0, x )
assert polygamma(0, 2 + x).expand(func=True) == \
1/x + 1/(1 + x) + polygamma(0, x)
assert polygamma(0, 3 + x).expand(func=True) == \
polygamma(0, x) + 1/x + 1/(1 + x) + 1/(2 + x)
assert polygamma(0, 4 + x).expand(func=True) == \
polygamma(0, x) + 1/x + 1/(1 + x) + 1/(2 + x) + 1/(3 + x)
assert polygamma(1, 1 + x).expand(func=True) == \
polygamma(1, x) - 1/x**2
assert polygamma(1, 2 + x).expand(func=True, multinomial=False) == \
polygamma(1, x) - 1/x**2 - 1/(1 + x)**2
assert polygamma(1, 3 + x).expand(func=True, multinomial=False) == \
polygamma(1, x) - 1/x**2 - 1/(1 + x)**2 - 1/(2 + x)**2
assert polygamma(1, 4 + x).expand(func=True, multinomial=False) == \
polygamma(1, x) - 1/x**2 - 1/(1 + x)**2 - \
1/(2 + x)**2 - 1/(3 + x)**2
assert polygamma(0, x + y).expand(func=True) == \
polygamma(0, x + y)
assert polygamma(1, x + y).expand(func=True) == \
polygamma(1, x + y)
assert polygamma(1, 3 + 4*x + y).expand(func=True, multinomial=False) == \
polygamma(1, y + 4*x) - 1/(y + 4*x)**2 - \
1/(1 + y + 4*x)**2 - 1/(2 + y + 4*x)**2
assert polygamma(3, 3 + 4*x + y).expand(func=True, multinomial=False) == \
polygamma(3, y + 4*x) - 6/(y + 4*x)**4 - \
6/(1 + y + 4*x)**4 - 6/(2 + y + 4*x)**4
assert polygamma(3, 4*x + y + 1).expand(func=True, multinomial=False) == \
polygamma(3, y + 4*x) - 6/(y + 4*x)**4
e = polygamma(3, 4*x + y + Rational(3, 2))
assert e.expand(func=True) == e
e = polygamma(3, x + y + Rational(3, 4))
assert e.expand(func=True, basic=False) == e
def test_digamma():
from sympy import I
assert digamma(nan) == nan
assert digamma(oo) == oo
assert digamma(-oo) == oo
assert digamma(I*oo) == oo
assert digamma(-I*oo) == oo
assert digamma(-9) == zoo
assert digamma(-9) == zoo
assert digamma(-1) == zoo
assert digamma(0) == zoo
assert digamma(1) == -EulerGamma
assert digamma(7) == Rational(49, 20) - EulerGamma
def t(m, n):
x = S(m)/n
r = digamma(x)
if r.has(digamma):
return False
return abs(digamma(x.n()).n() - r.n()).n() < 1e-10
assert t(1, 2)
assert t(3, 2)
assert t(-1, 2)
assert t(1, 4)
assert t(-3, 4)
assert t(1, 3)
assert t(4, 3)
assert t(3, 4)
assert t(2, 3)
assert t(123, 5)
assert digamma(x).rewrite(zeta) == polygamma(0, x)
assert digamma(x).rewrite(harmonic) == harmonic(x - 1) - EulerGamma
assert digamma(I).is_real is None
assert digamma(x,evaluate=False).fdiff() == polygamma(1, x)
assert digamma(x,evaluate=False).is_real is None
assert digamma(x,evaluate=False).is_positive is None
assert digamma(x,evaluate=False).is_negative is None
assert digamma(x,evaluate=False).rewrite(polygamma) == polygamma(0, x)
def test_digamma_expand_func():
assert digamma(x).expand(func=True) == polygamma(0, x)
assert digamma(2*x).expand(func=True) == \
polygamma(0, x)/2 + polygamma(0, Rational(1, 2) + x)/2 + log(2)
assert digamma(-1 + x).expand(func=True) == \
polygamma(0, x) - 1/(x - 1)
assert digamma(1 + x).expand(func=True) == \
1/x + polygamma(0, x )
assert digamma(2 + x).expand(func=True) == \
1/x + 1/(1 + x) + polygamma(0, x)
assert digamma(3 + x).expand(func=True) == \
polygamma(0, x) + 1/x + 1/(1 + x) + 1/(2 + x)
assert digamma(4 + x).expand(func=True) == \
polygamma(0, x) + 1/x + 1/(1 + x) + 1/(2 + x) + 1/(3 + x)
assert digamma(x + y).expand(func=True) == \
polygamma(0, x + y)
def test_trigamma():
assert trigamma(nan) == nan
assert trigamma(oo) == 0
assert trigamma(1) == pi**2/6
assert trigamma(2) == pi**2/6 - 1
assert trigamma(3) == pi**2/6 - Rational(5, 4)
assert trigamma(x, evaluate=False).rewrite(zeta) == zeta(2, x)
assert trigamma(x, evaluate=False).rewrite(harmonic) == \
trigamma(x).rewrite(polygamma).rewrite(harmonic)
assert trigamma(x,evaluate=False).fdiff() == polygamma(2, x)
assert trigamma(x,evaluate=False).is_real is None
assert trigamma(x,evaluate=False).is_positive is None
assert trigamma(x,evaluate=False).is_negative is None
assert trigamma(x,evaluate=False).rewrite(polygamma) == polygamma(1, x)
def test_trigamma_expand_func():
assert trigamma(2*x).expand(func=True) == \
polygamma(1, x)/4 + polygamma(1, Rational(1, 2) + x)/4
assert trigamma(1 + x).expand(func=True) == \
polygamma(1, x) - 1/x**2
assert trigamma(2 + x).expand(func=True, multinomial=False) == \
polygamma(1, x) - 1/x**2 - 1/(1 + x)**2
assert trigamma(3 + x).expand(func=True, multinomial=False) == \
polygamma(1, x) - 1/x**2 - 1/(1 + x)**2 - 1/(2 + x)**2
assert trigamma(4 + x).expand(func=True, multinomial=False) == \
polygamma(1, x) - 1/x**2 - 1/(1 + x)**2 - \
1/(2 + x)**2 - 1/(3 + x)**2
assert trigamma(x + y).expand(func=True) == \
polygamma(1, x + y)
assert trigamma(3 + 4*x + y).expand(func=True, multinomial=False) == \
polygamma(1, y + 4*x) - 1/(y + 4*x)**2 - \
1/(1 + y + 4*x)**2 - 1/(2 + y + 4*x)**2
def test_loggamma():
raises(TypeError, lambda: loggamma(2, 3))
raises(ArgumentIndexError, lambda: loggamma(x).fdiff(2))
assert loggamma(-1) is oo
assert loggamma(-2) is oo
assert loggamma(0) is oo
assert loggamma(1) == 0
assert loggamma(2) == 0
assert loggamma(3) == log(2)
assert loggamma(4) == log(6)
n = Symbol("n", integer=True, positive=True)
assert loggamma(n) == log(gamma(n))
assert loggamma(-n) is oo
assert loggamma(n/2) == log(2**(-n + 1)*sqrt(pi)*gamma(n)/gamma(n/2 + S.Half))
from sympy import I
assert loggamma(oo) is oo
assert loggamma(-oo) is zoo
assert loggamma(I*oo) is zoo
assert loggamma(-I*oo) is zoo
assert loggamma(zoo) is zoo
assert loggamma(nan) is nan
L = loggamma(Rational(16, 3))
E = -5*log(3) + loggamma(Rational(1, 3)) + log(4) + log(7) + log(10) + log(13)
assert expand_func(L).doit() == E
assert L.n() == E.n()
L = loggamma(Rational(19, 4))
E = -4*log(4) + loggamma(Rational(3, 4)) + log(3) + log(7) + log(11) + log(15)
assert expand_func(L).doit() == E
assert L.n() == E.n()
L = loggamma(Rational(23, 7))
E = -3*log(7) + log(2) + loggamma(Rational(2, 7)) + log(9) + log(16)
assert expand_func(L).doit() == E
assert L.n() == E.n()
L = loggamma(Rational(19, 4) - 7)
E = -log(9) - log(5) + loggamma(Rational(3, 4)) + 3*log(4) - 3*I*pi
assert expand_func(L).doit() == E
assert L.n() == E.n()
L = loggamma(Rational(23, 7) - 6)
E = -log(19) - log(12) - log(5) + loggamma(Rational(2, 7)) + 3*log(7) - 3*I*pi
assert expand_func(L).doit() == E
assert L.n() == E.n()
assert loggamma(x).diff(x) == polygamma(0, x)
s1 = loggamma(1/(x + sin(x)) + cos(x)).nseries(x, n=4)
s2 = (-log(2*x) - 1)/(2*x) - log(x/pi)/2 + (4 - log(2*x))*x/24 + O(x**2) + \
log(x)*x**2/2
assert (s1 - s2).expand(force=True).removeO() == 0
s1 = loggamma(1/x).series(x)
s2 = (1/x - S.Half)*log(1/x) - 1/x + log(2*pi)/2 + \
x/12 - x**3/360 + x**5/1260 + O(x**7)
assert ((s1 - s2).expand(force=True)).removeO() == 0
assert loggamma(x).rewrite('intractable') == log(gamma(x))
s1 = loggamma(x).series(x)
assert s1 == -log(x) - EulerGamma*x + pi**2*x**2/12 + x**3*polygamma(2, 1)/6 + \
pi**4*x**4/360 + x**5*polygamma(4, 1)/120 + O(x**6)
assert s1 == loggamma(x).rewrite('intractable').series(x)
assert conjugate(loggamma(x)) == loggamma(conjugate(x))
assert conjugate(loggamma(0)) is oo
assert conjugate(loggamma(1)) == loggamma(conjugate(1))
assert conjugate(loggamma(-oo)) == conjugate(zoo)
assert loggamma(Symbol('v', positive=True)).is_real is True
assert loggamma(Symbol('v', zero=True)).is_real is False
assert loggamma(Symbol('v', negative=True)).is_real is False
assert loggamma(Symbol('v', nonpositive=True)).is_real is False
assert loggamma(Symbol('v', nonnegative=True)).is_real is None
assert loggamma(Symbol('v', imaginary=True)).is_real is None
assert loggamma(Symbol('v', real=True)).is_real is None
assert loggamma(Symbol('v')).is_real is None
assert loggamma(S.Half).is_real is True
assert loggamma(0).is_real is False
assert loggamma(Rational(-1, 2)).is_real is False
assert loggamma(I).is_real is None
assert loggamma(2 + 3*I).is_real is None
def tN(N, M):
assert loggamma(1/x)._eval_nseries(x, n=N).getn() == M
tN(0, 0)
tN(1, 1)
tN(2, 2)
tN(3, 3)
tN(4, 4)
tN(5, 5)
def test_polygamma_expansion():
# A. & S., pa. 259 and 260
assert polygamma(0, 1/x).nseries(x, n=3) == \
-log(x) - x/2 - x**2/12 + O(x**3)
assert polygamma(1, 1/x).series(x, n=5) == \
x + x**2/2 + x**3/6 + O(x**5)
assert polygamma(3, 1/x).nseries(x, n=11) == \
2*x**3 + 3*x**4 + 2*x**5 - x**7 + 4*x**9/3 + O(x**11)
def test_issue_8657():
n = Symbol('n', negative=True, integer=True)
m = Symbol('m', integer=True)
o = Symbol('o', positive=True)
p = Symbol('p', negative=True, integer=False)
assert gamma(n).is_real is False
assert gamma(m).is_real is None
assert gamma(o).is_real is True
assert gamma(p).is_real is True
assert gamma(w).is_real is None
def test_issue_8524():
x = Symbol('x', positive=True)
y = Symbol('y', negative=True)
z = Symbol('z', positive=False)
p = Symbol('p', negative=False)
q = Symbol('q', integer=True)
r = Symbol('r', integer=False)
e = Symbol('e', even=True, negative=True)
assert gamma(x).is_positive is True
assert gamma(y).is_positive is None
assert gamma(z).is_positive is None
assert gamma(p).is_positive is None
assert gamma(q).is_positive is None
assert gamma(r).is_positive is None
assert gamma(e + S.Half).is_positive is True
assert gamma(e - S.Half).is_positive is False
def test_issue_14450():
assert uppergamma(Rational(3, 8), x).evalf() == uppergamma(Rational(3, 8), x)
assert lowergamma(x, Rational(3, 8)).evalf() == lowergamma(x, Rational(3, 8))
# some values from Wolfram Alpha for comparison
assert abs(uppergamma(Rational(3, 8), 2).evalf() - 0.07105675881) < 1e-9
assert abs(lowergamma(Rational(3, 8), 2).evalf() - 2.2993794256) < 1e-9
def test_issue_14528():
k = Symbol('k', integer=True, nonpositive=True)
assert isinstance(gamma(k), gamma)
def test_multigamma():
from sympy import Product
p = Symbol('p')
_k = Dummy('_k')
assert multigamma(x, p).dummy_eq(pi**(p*(p - 1)/4)*\
Product(gamma(x + (1 - _k)/2), (_k, 1, p)))
assert conjugate(multigamma(x, p)).dummy_eq(pi**((conjugate(p) - 1)*\
conjugate(p)/4)*Product(gamma(conjugate(x) + (1-conjugate(_k))/2), (_k, 1, p)))
assert conjugate(multigamma(x, 1)) == gamma(conjugate(x))
p = Symbol('p', positive=True)
assert conjugate(multigamma(x, p)).dummy_eq(pi**((p - 1)*p/4)*\
Product(gamma(conjugate(x) + (1-conjugate(_k))/2), (_k, 1, p)))
assert multigamma(nan, 1) is nan
assert multigamma(oo, 1).doit() is oo
assert multigamma(1, 1) == 1
assert multigamma(2, 1) == 1
assert multigamma(3, 1) == 2
assert multigamma(102, 1) == factorial(101)
assert multigamma(S.Half, 1) == sqrt(pi)
assert multigamma(1, 2) == pi
assert multigamma(2, 2) == pi/2
assert multigamma(1, 3) is zoo
assert multigamma(2, 3) == pi**2/2
assert multigamma(3, 3) == 3*pi**2/2
assert multigamma(x, 1).diff(x) == gamma(x)*polygamma(0, x)
assert multigamma(x, 2).diff(x) == sqrt(pi)*gamma(x)*gamma(x - S.Half)*\
polygamma(0, x) + sqrt(pi)*gamma(x)*gamma(x - S.Half)*polygamma(0, x - S.Half)
assert multigamma(x - 1, 1).expand(func=True) == gamma(x)/(x - 1)
assert multigamma(x + 2, 1).expand(func=True, mul=False) == x*(x + 1)*\
gamma(x)
assert multigamma(x - 1, 2).expand(func=True) == sqrt(pi)*gamma(x)*\
gamma(x + S.Half)/(x**3 - 3*x**2 + x*Rational(11, 4) - Rational(3, 4))
assert multigamma(x - 1, 3).expand(func=True) == pi**Rational(3, 2)*gamma(x)**2*\
gamma(x + S.Half)/(x**5 - 6*x**4 + 55*x**3/4 - 15*x**2 + x*Rational(31, 4) - Rational(3, 2))
assert multigamma(n, 1).rewrite(factorial) == factorial(n - 1)
assert multigamma(n, 2).rewrite(factorial) == sqrt(pi)*\
factorial(n - Rational(3, 2))*factorial(n - 1)
assert multigamma(n, 3).rewrite(factorial) == pi**Rational(3, 2)*\
factorial(n - 2)*factorial(n - Rational(3, 2))*factorial(n - 1)
assert multigamma(Rational(-1, 2), 3, evaluate=False).is_real == False
assert multigamma(S.Half, 3, evaluate=False).is_real == False
assert multigamma(0, 1, evaluate=False).is_real == False
assert multigamma(1, 3, evaluate=False).is_real == False
assert multigamma(-1.0, 3, evaluate=False).is_real == False
assert multigamma(0.7, 3, evaluate=False).is_real == True
assert multigamma(3, 3, evaluate=False).is_real == True
def test_gamma_as_leading_term():
assert gamma(x).as_leading_term(x) == 1/x
assert gamma(2 + x).as_leading_term(x) == S(1)
assert gamma(cos(x)).as_leading_term(x) == S(1)
assert gamma(sin(x)).as_leading_term(x) == 1/x
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