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| from sympy.abc import t, w, x, y, z, n, k, m, p, i | |
| from sympy.assumptions import (ask, AssumptionsContext, Q, register_handler, | |
| remove_handler) | |
| from sympy.assumptions.assume import assuming, global_assumptions, Predicate | |
| from sympy.assumptions.cnf import CNF, Literal | |
| from sympy.assumptions.facts import (single_fact_lookup, | |
| get_known_facts, generate_known_facts_dict, get_known_facts_keys) | |
| from sympy.assumptions.handlers import AskHandler | |
| from sympy.assumptions.ask_generated import (get_all_known_facts, | |
| get_known_facts_dict) | |
| from sympy.core.add import Add | |
| from sympy.core.numbers import (I, Integer, Rational, oo, zoo, pi) | |
| from sympy.core.singleton import S | |
| from sympy.core.power import Pow | |
| from sympy.core.symbol import Str, symbols, Symbol | |
| from sympy.functions.combinatorial.factorials import factorial | |
| from sympy.functions.elementary.complexes import (Abs, im, re, sign) | |
| from sympy.functions.elementary.exponential import (exp, log) | |
| from sympy.functions.elementary.miscellaneous import sqrt | |
| from sympy.functions.elementary.trigonometric import ( | |
| acos, acot, asin, atan, cos, cot, sin, tan) | |
| from sympy.logic.boolalg import Equivalent, Implies, Xor, And, to_cnf | |
| from sympy.matrices import Matrix, SparseMatrix | |
| from sympy.testing.pytest import (XFAIL, slow, raises, warns_deprecated_sympy, | |
| _both_exp_pow) | |
| import math | |
| def test_int_1(): | |
| z = 1 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is True | |
| assert ask(Q.rational(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is True | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_int_11(): | |
| z = 11 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is True | |
| assert ask(Q.rational(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is True | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is True | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_int_12(): | |
| z = 12 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is True | |
| assert ask(Q.rational(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is True | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is True | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_float_1(): | |
| z = 1.0 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is None | |
| assert ask(Q.rational(z)) is None | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is None | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is None | |
| assert ask(Q.odd(z)) is None | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is None | |
| assert ask(Q.composite(z)) is None | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| z = 7.2123 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is None | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is None | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| # test for issue #12168 | |
| assert ask(Q.rational(math.pi)) is None | |
| def test_zero_0(): | |
| z = Integer(0) | |
| assert ask(Q.nonzero(z)) is False | |
| assert ask(Q.zero(z)) is True | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is True | |
| assert ask(Q.rational(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is False | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is True | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is True | |
| def test_negativeone(): | |
| z = Integer(-1) | |
| assert ask(Q.nonzero(z)) is True | |
| assert ask(Q.zero(z)) is False | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is True | |
| assert ask(Q.rational(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is False | |
| assert ask(Q.negative(z)) is True | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is True | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_infinity(): | |
| assert ask(Q.commutative(oo)) is True | |
| assert ask(Q.integer(oo)) is False | |
| assert ask(Q.rational(oo)) is False | |
| assert ask(Q.algebraic(oo)) is False | |
| assert ask(Q.real(oo)) is False | |
| assert ask(Q.extended_real(oo)) is True | |
| assert ask(Q.complex(oo)) is False | |
| assert ask(Q.irrational(oo)) is False | |
| assert ask(Q.imaginary(oo)) is False | |
| assert ask(Q.positive(oo)) is False | |
| assert ask(Q.extended_positive(oo)) is True | |
| assert ask(Q.negative(oo)) is False | |
| assert ask(Q.even(oo)) is False | |
| assert ask(Q.odd(oo)) is False | |
| assert ask(Q.finite(oo)) is False | |
| assert ask(Q.infinite(oo)) is True | |
| assert ask(Q.prime(oo)) is False | |
| assert ask(Q.composite(oo)) is False | |
| assert ask(Q.hermitian(oo)) is False | |
| assert ask(Q.antihermitian(oo)) is False | |
| assert ask(Q.positive_infinite(oo)) is True | |
| assert ask(Q.negative_infinite(oo)) is False | |
| def test_neg_infinity(): | |
| mm = S.NegativeInfinity | |
| assert ask(Q.commutative(mm)) is True | |
| assert ask(Q.integer(mm)) is False | |
| assert ask(Q.rational(mm)) is False | |
| assert ask(Q.algebraic(mm)) is False | |
| assert ask(Q.real(mm)) is False | |
| assert ask(Q.extended_real(mm)) is True | |
| assert ask(Q.complex(mm)) is False | |
| assert ask(Q.irrational(mm)) is False | |
| assert ask(Q.imaginary(mm)) is False | |
| assert ask(Q.positive(mm)) is False | |
| assert ask(Q.negative(mm)) is False | |
| assert ask(Q.extended_negative(mm)) is True | |
| assert ask(Q.even(mm)) is False | |
| assert ask(Q.odd(mm)) is False | |
| assert ask(Q.finite(mm)) is False | |
| assert ask(Q.infinite(oo)) is True | |
| assert ask(Q.prime(mm)) is False | |
| assert ask(Q.composite(mm)) is False | |
| assert ask(Q.hermitian(mm)) is False | |
| assert ask(Q.antihermitian(mm)) is False | |
| assert ask(Q.positive_infinite(-oo)) is False | |
| assert ask(Q.negative_infinite(-oo)) is True | |
| def test_complex_infinity(): | |
| assert ask(Q.commutative(zoo)) is True | |
| assert ask(Q.integer(zoo)) is False | |
| assert ask(Q.rational(zoo)) is False | |
| assert ask(Q.algebraic(zoo)) is False | |
| assert ask(Q.real(zoo)) is False | |
| assert ask(Q.extended_real(zoo)) is False | |
| assert ask(Q.complex(zoo)) is False | |
| assert ask(Q.irrational(zoo)) is False | |
| assert ask(Q.imaginary(zoo)) is False | |
| assert ask(Q.positive(zoo)) is False | |
| assert ask(Q.negative(zoo)) is False | |
| assert ask(Q.zero(zoo)) is False | |
| assert ask(Q.nonzero(zoo)) is False | |
| assert ask(Q.even(zoo)) is False | |
| assert ask(Q.odd(zoo)) is False | |
| assert ask(Q.finite(zoo)) is False | |
| assert ask(Q.infinite(zoo)) is True | |
| assert ask(Q.prime(zoo)) is False | |
| assert ask(Q.composite(zoo)) is False | |
| assert ask(Q.hermitian(zoo)) is False | |
| assert ask(Q.antihermitian(zoo)) is False | |
| assert ask(Q.positive_infinite(zoo)) is False | |
| assert ask(Q.negative_infinite(zoo)) is False | |
| def test_nan(): | |
| nan = S.NaN | |
| assert ask(Q.commutative(nan)) is True | |
| assert ask(Q.integer(nan)) is None | |
| assert ask(Q.rational(nan)) is None | |
| assert ask(Q.algebraic(nan)) is None | |
| assert ask(Q.real(nan)) is None | |
| assert ask(Q.extended_real(nan)) is None | |
| assert ask(Q.complex(nan)) is None | |
| assert ask(Q.irrational(nan)) is None | |
| assert ask(Q.imaginary(nan)) is None | |
| assert ask(Q.positive(nan)) is None | |
| assert ask(Q.nonzero(nan)) is None | |
| assert ask(Q.zero(nan)) is None | |
| assert ask(Q.even(nan)) is None | |
| assert ask(Q.odd(nan)) is None | |
| assert ask(Q.finite(nan)) is None | |
| assert ask(Q.infinite(nan)) is None | |
| assert ask(Q.prime(nan)) is None | |
| assert ask(Q.composite(nan)) is None | |
| assert ask(Q.hermitian(nan)) is None | |
| assert ask(Q.antihermitian(nan)) is None | |
| def test_Rational_number(): | |
| r = Rational(3, 4) | |
| assert ask(Q.commutative(r)) is True | |
| assert ask(Q.integer(r)) is False | |
| assert ask(Q.rational(r)) is True | |
| assert ask(Q.real(r)) is True | |
| assert ask(Q.complex(r)) is True | |
| assert ask(Q.irrational(r)) is False | |
| assert ask(Q.imaginary(r)) is False | |
| assert ask(Q.positive(r)) is True | |
| assert ask(Q.negative(r)) is False | |
| assert ask(Q.even(r)) is False | |
| assert ask(Q.odd(r)) is False | |
| assert ask(Q.finite(r)) is True | |
| assert ask(Q.prime(r)) is False | |
| assert ask(Q.composite(r)) is False | |
| assert ask(Q.hermitian(r)) is True | |
| assert ask(Q.antihermitian(r)) is False | |
| r = Rational(1, 4) | |
| assert ask(Q.positive(r)) is True | |
| assert ask(Q.negative(r)) is False | |
| r = Rational(5, 4) | |
| assert ask(Q.negative(r)) is False | |
| assert ask(Q.positive(r)) is True | |
| r = Rational(5, 3) | |
| assert ask(Q.positive(r)) is True | |
| assert ask(Q.negative(r)) is False | |
| r = Rational(-3, 4) | |
| assert ask(Q.positive(r)) is False | |
| assert ask(Q.negative(r)) is True | |
| r = Rational(-1, 4) | |
| assert ask(Q.positive(r)) is False | |
| assert ask(Q.negative(r)) is True | |
| r = Rational(-5, 4) | |
| assert ask(Q.negative(r)) is True | |
| assert ask(Q.positive(r)) is False | |
| r = Rational(-5, 3) | |
| assert ask(Q.positive(r)) is False | |
| assert ask(Q.negative(r)) is True | |
| def test_sqrt_2(): | |
| z = sqrt(2) | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_pi(): | |
| z = S.Pi | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| z = S.Pi + 1 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| z = 2*S.Pi | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| z = S.Pi ** 2 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| z = (1 + S.Pi) ** 2 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_E(): | |
| z = S.Exp1 | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is False | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_GoldenRatio(): | |
| z = S.GoldenRatio | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_TribonacciConstant(): | |
| z = S.TribonacciConstant | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is True | |
| assert ask(Q.real(z)) is True | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is True | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is True | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is True | |
| assert ask(Q.antihermitian(z)) is False | |
| def test_I(): | |
| z = I | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is True | |
| assert ask(Q.real(z)) is False | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is True | |
| assert ask(Q.positive(z)) is False | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is False | |
| assert ask(Q.antihermitian(z)) is True | |
| z = 1 + I | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is True | |
| assert ask(Q.real(z)) is False | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is False | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is False | |
| assert ask(Q.antihermitian(z)) is False | |
| z = I*(1 + I) | |
| assert ask(Q.commutative(z)) is True | |
| assert ask(Q.integer(z)) is False | |
| assert ask(Q.rational(z)) is False | |
| assert ask(Q.algebraic(z)) is True | |
| assert ask(Q.real(z)) is False | |
| assert ask(Q.complex(z)) is True | |
| assert ask(Q.irrational(z)) is False | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.positive(z)) is False | |
| assert ask(Q.negative(z)) is False | |
| assert ask(Q.even(z)) is False | |
| assert ask(Q.odd(z)) is False | |
| assert ask(Q.finite(z)) is True | |
| assert ask(Q.prime(z)) is False | |
| assert ask(Q.composite(z)) is False | |
| assert ask(Q.hermitian(z)) is False | |
| assert ask(Q.antihermitian(z)) is False | |
| z = I**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| z = (-I)**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| z = (3*I)**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is False | |
| z = (1)**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| z = (-1)**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| z = (1+I)**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is False | |
| z = (I)**(I+3) | |
| assert ask(Q.imaginary(z)) is True | |
| assert ask(Q.real(z)) is False | |
| z = (I)**(I+2) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| z = (I)**(2) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| z = (I)**(3) | |
| assert ask(Q.imaginary(z)) is True | |
| assert ask(Q.real(z)) is False | |
| z = (3)**(I) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is False | |
| z = (I)**(0) | |
| assert ask(Q.imaginary(z)) is False | |
| assert ask(Q.real(z)) is True | |
| def test_bounded(): | |
| x, y, z = symbols('x,y,z') | |
| a = x + y | |
| x, y = a.args | |
| assert ask(Q.finite(a), Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(x)) is None | |
| assert ask(Q.finite(x), Q.finite(x)) is True | |
| assert ask(Q.finite(x), Q.finite(y)) is None | |
| assert ask(Q.finite(x), Q.complex(x)) is True | |
| assert ask(Q.finite(x), Q.extended_real(x)) is None | |
| assert ask(Q.finite(x + 1)) is None | |
| assert ask(Q.finite(x + 1), Q.finite(x)) is True | |
| a = x + y | |
| x, y = a.args | |
| # B + B | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y)) is True | |
| assert ask(Q.finite(a), Q.positive(x) & Q.finite(y)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y)) is True | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y)) is True | |
| assert ask(Q.finite(a), Q.positive(x) & Q.finite(y) | |
| & ~Q.positive(y)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.positive(x) | |
| & Q.positive(y)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) & ~Q.positive(x) | |
| & ~Q.positive(y)) is True | |
| # B + U | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y)) is False | |
| assert ask(Q.finite(a), Q.finite(x) | |
| & Q.positive_infinite(y)) is False | |
| assert ask(Q.finite(a), Q.positive(x) | |
| & Q.positive_infinite(y)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y) | |
| & ~Q.positive(y)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.positive(x) | |
| & Q.positive_infinite(y)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.positive(x) & ~Q.finite(y) | |
| & ~Q.positive(y)) is False | |
| # B + ? | |
| assert ask(Q.finite(a), Q.finite(x)) is None | |
| assert ask(Q.finite(a), Q.positive(x)) is None | |
| assert ask(Q.finite(a), Q.finite(x) | |
| & Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) | |
| & Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.positive(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.positive(x) | |
| & Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.positive(x) | |
| & ~Q.positive(y)) is None | |
| # U + U | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.positive_infinite(y)) is False | |
| assert ask(Q.finite(a), Q.positive_infinite(x) & ~Q.finite(y) | |
| & ~Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.extended_positive(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y) | |
| & ~Q.extended_positive(x) & ~Q.extended_positive(y)) is False | |
| # U + ? | |
| assert ask(Q.finite(a), ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(x) | |
| & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(x) | |
| & Q.positive_infinite(y)) is False | |
| assert ask(Q.finite(a), Q.extended_positive(x) | |
| & ~Q.finite(y) & ~Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), ~Q.extended_positive(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), ~Q.extended_positive(x) & ~Q.finite(y) | |
| & ~Q.extended_positive(y)) is False | |
| # ? + ? | |
| assert ask(Q.finite(a)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(x)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(x) | |
| & Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(x) | |
| & ~Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), ~Q.extended_positive(x) | |
| & Q.extended_positive(y)) is None | |
| assert ask(Q.finite(a), ~Q.extended_positive(x) | |
| & ~Q.extended_positive(y)) is None | |
| x, y, z = symbols('x,y,z') | |
| a = x + y + z | |
| x, y, z = a.args | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.negative(z)) is True | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.finite(z)) is True | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.positive(z)) is True | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & Q.finite(z)) is True | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & Q.positive(z)) is True | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.finite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive(y) | |
| & Q.positive(z)) is True | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.extended_positive(y) | |
| & Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative_infinite(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative_infinite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative_infinite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative_infinite(y) | |
| & Q.extended_negative(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) | |
| & Q.negative_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.negative_infinite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & ~Q.finite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & ~Q.finite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & ~Q.finite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & ~Q.finite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive_infinite(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive_infinite(y) | |
| & Q.negative_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & | |
| Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.positive_infinite(y) | |
| & Q.extended_positive(z)) is False | |
| assert ask(Q.finite(a), Q.negative(x) & Q.extended_negative(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.extended_negative(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x)) is None | |
| assert ask(Q.finite(a), Q.negative(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative(x) & Q.extended_positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.finite(z)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.positive(z)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y) | |
| & Q.positive(z)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.negative_infinite(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.negative_infinite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.negative_infinite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.negative_infinite(y) | |
| & Q.extended_negative(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) | |
| & Q.negative_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.negative_infinite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive_infinite(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive_infinite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.positive_infinite(y) | |
| & Q.extended_positive(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.extended_negative(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.extended_negative(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x)) is None | |
| assert ask(Q.finite(a), Q.finite(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.extended_positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y) | |
| & Q.positive(z)) is True | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.negative_infinite(y) | |
| & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & Q.negative_infinite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.negative_infinite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.negative_infinite(y) | |
| & Q.extended_negative(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) | |
| & Q.negative_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.negative_infinite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & ~Q.finite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive_infinite(y) | |
| & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive_infinite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.positive_infinite(y) | |
| & Q.extended_positive(z)) is False | |
| assert ask(Q.finite(a), Q.positive(x) & Q.extended_negative(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.extended_negative(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x)) is None | |
| assert ask(Q.finite(a), Q.positive(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive(x) & Q.extended_positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.negative_infinite(y) & Q.negative_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.negative_infinite(y) & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.negative_infinite(y)& Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.negative_infinite(y) & Q.extended_negative(z)) is False | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.negative_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.negative_infinite(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & ~Q.finite(y) & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & ~Q.finite(y) & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & ~Q.finite(y) & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & ~Q.finite(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.positive_infinite(y) & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.positive_infinite(y) & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.positive_infinite(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.extended_negative(y) & Q.extended_negative(z)) is False | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.extended_negative(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.negative_infinite(x) | |
| & Q.extended_positive(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.positive_infinite(z) | |
| & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.positive_infinite(y) | |
| & Q.positive_infinite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.positive_infinite(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.positive_infinite(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.extended_negative(y) | |
| & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.extended_negative(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.extended_positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.positive_infinite(y) & Q.positive_infinite(z)) is False | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.positive_infinite(y) & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.positive_infinite(y)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.positive_infinite(y) & Q.extended_positive(z)) is False | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.extended_negative(y) & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.extended_negative(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.positive_infinite(x) | |
| & Q.extended_positive(y) & Q.extended_positive(z)) is False | |
| assert ask(Q.finite(a), Q.extended_negative(x) | |
| & Q.extended_negative(y) & Q.extended_negative(z)) is None | |
| assert ask(Q.finite(a), Q.extended_negative(x) | |
| & Q.extended_negative(y)) is None | |
| assert ask(Q.finite(a), Q.extended_negative(x) | |
| & Q.extended_negative(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.extended_negative(x)) is None | |
| assert ask(Q.finite(a), Q.extended_negative(x) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.extended_negative(x) | |
| & Q.extended_positive(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(y) | |
| & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(a), Q.extended_positive(x) | |
| & Q.extended_positive(y) & Q.extended_positive(z)) is None | |
| assert ask(Q.finite(2*x)) is None | |
| assert ask(Q.finite(2*x), Q.finite(x)) is True | |
| x, y, z = symbols('x,y,z') | |
| a = x*y | |
| x, y = a.args | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y)) is False | |
| assert ask(Q.finite(a), Q.finite(x)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.finite(y)) is False | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y)) is False | |
| assert ask(Q.finite(a), ~Q.finite(x)) is None | |
| assert ask(Q.finite(a), Q.finite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(y)) is None | |
| assert ask(Q.finite(a)) is None | |
| a = x*y*z | |
| x, y, z = a.args | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & Q.finite(z)) is True | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y) | |
| & Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x) & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(x)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.finite(y) | |
| & Q.finite(z)) is False | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.finite(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.finite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y) | |
| & Q.finite(z)) is False | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y) | |
| & ~Q.finite(z)) is False | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x) & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(x)) is None | |
| assert ask(Q.finite(a), Q.finite(y) & Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(y) & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), Q.finite(y)) is None | |
| assert ask(Q.finite(a), ~Q.finite(y) & Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(y) & ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(y)) is None | |
| assert ask(Q.finite(a), Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(z)) is None | |
| assert ask(Q.finite(a), ~Q.finite(z) & Q.extended_nonzero(x) | |
| & Q.extended_nonzero(y) & Q.extended_nonzero(z)) is None | |
| assert ask(Q.finite(a), Q.extended_nonzero(x) & ~Q.finite(y) | |
| & Q.extended_nonzero(y) & ~Q.finite(z) | |
| & Q.extended_nonzero(z)) is False | |
| x, y, z = symbols('x,y,z') | |
| assert ask(Q.finite(x**2)) is None | |
| assert ask(Q.finite(2**x)) is None | |
| assert ask(Q.finite(2**x), Q.finite(x)) is True | |
| assert ask(Q.finite(x**x)) is None | |
| assert ask(Q.finite(S.Half ** x)) is None | |
| assert ask(Q.finite(S.Half ** x), Q.extended_positive(x)) is True | |
| assert ask(Q.finite(S.Half ** x), Q.extended_negative(x)) is None | |
| assert ask(Q.finite(2**x), Q.extended_negative(x)) is True | |
| assert ask(Q.finite(sqrt(x))) is None | |
| assert ask(Q.finite(2**x), ~Q.finite(x)) is False | |
| assert ask(Q.finite(x**2), ~Q.finite(x)) is False | |
| # sign function | |
| assert ask(Q.finite(sign(x))) is True | |
| assert ask(Q.finite(sign(x)), ~Q.finite(x)) is True | |
| # exponential functions | |
| assert ask(Q.finite(log(x))) is None | |
| assert ask(Q.finite(log(x)), Q.finite(x)) is None | |
| assert ask(Q.finite(log(x)), ~Q.zero(x)) is True | |
| assert ask(Q.finite(log(x)), Q.infinite(x)) is False | |
| assert ask(Q.finite(log(x)), Q.zero(x)) is False | |
| assert ask(Q.finite(exp(x))) is None | |
| assert ask(Q.finite(exp(x)), Q.finite(x)) is True | |
| assert ask(Q.finite(exp(2))) is True | |
| # trigonometric functions | |
| assert ask(Q.finite(sin(x))) is True | |
| assert ask(Q.finite(sin(x)), ~Q.finite(x)) is True | |
| assert ask(Q.finite(cos(x))) is True | |
| assert ask(Q.finite(cos(x)), ~Q.finite(x)) is True | |
| assert ask(Q.finite(2*sin(x))) is True | |
| assert ask(Q.finite(sin(x)**2)) is True | |
| assert ask(Q.finite(cos(x)**2)) is True | |
| assert ask(Q.finite(cos(x) + sin(x))) is True | |
| def test_bounded_xfail(): | |
| """We need to support relations in ask for this to work""" | |
| assert ask(Q.finite(sin(x)**x)) is True | |
| assert ask(Q.finite(cos(x)**x)) is True | |
| def test_commutative(): | |
| """By default objects are Q.commutative that is why it returns True | |
| for both key=True and key=False""" | |
| assert ask(Q.commutative(x)) is True | |
| assert ask(Q.commutative(x), ~Q.commutative(x)) is False | |
| assert ask(Q.commutative(x), Q.complex(x)) is True | |
| assert ask(Q.commutative(x), Q.imaginary(x)) is True | |
| assert ask(Q.commutative(x), Q.real(x)) is True | |
| assert ask(Q.commutative(x), Q.positive(x)) is True | |
| assert ask(Q.commutative(x), ~Q.commutative(y)) is True | |
| assert ask(Q.commutative(2*x)) is True | |
| assert ask(Q.commutative(2*x), ~Q.commutative(x)) is False | |
| assert ask(Q.commutative(x + 1)) is True | |
| assert ask(Q.commutative(x + 1), ~Q.commutative(x)) is False | |
| assert ask(Q.commutative(x**2)) is True | |
| assert ask(Q.commutative(x**2), ~Q.commutative(x)) is False | |
| assert ask(Q.commutative(log(x))) is True | |
| def test_complex(): | |
| assert ask(Q.complex(x)) is None | |
| assert ask(Q.complex(x), Q.complex(x)) is True | |
| assert ask(Q.complex(x), Q.complex(y)) is None | |
| assert ask(Q.complex(x), ~Q.complex(x)) is False | |
| assert ask(Q.complex(x), Q.real(x)) is True | |
| assert ask(Q.complex(x), ~Q.real(x)) is None | |
| assert ask(Q.complex(x), Q.rational(x)) is True | |
| assert ask(Q.complex(x), Q.irrational(x)) is True | |
| assert ask(Q.complex(x), Q.positive(x)) is True | |
| assert ask(Q.complex(x), Q.imaginary(x)) is True | |
| assert ask(Q.complex(x), Q.algebraic(x)) is True | |
| # a+b | |
| assert ask(Q.complex(x + 1), Q.complex(x)) is True | |
| assert ask(Q.complex(x + 1), Q.real(x)) is True | |
| assert ask(Q.complex(x + 1), Q.rational(x)) is True | |
| assert ask(Q.complex(x + 1), Q.irrational(x)) is True | |
| assert ask(Q.complex(x + 1), Q.imaginary(x)) is True | |
| assert ask(Q.complex(x + 1), Q.integer(x)) is True | |
| assert ask(Q.complex(x + 1), Q.even(x)) is True | |
| assert ask(Q.complex(x + 1), Q.odd(x)) is True | |
| assert ask(Q.complex(x + y), Q.complex(x) & Q.complex(y)) is True | |
| assert ask(Q.complex(x + y), Q.real(x) & Q.imaginary(y)) is True | |
| # a*x +b | |
| assert ask(Q.complex(2*x + 1), Q.complex(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.real(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.positive(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.rational(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.irrational(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.imaginary(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.integer(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.even(x)) is True | |
| assert ask(Q.complex(2*x + 1), Q.odd(x)) is True | |
| # x**2 | |
| assert ask(Q.complex(x**2), Q.complex(x)) is True | |
| assert ask(Q.complex(x**2), Q.real(x)) is True | |
| assert ask(Q.complex(x**2), Q.positive(x)) is True | |
| assert ask(Q.complex(x**2), Q.rational(x)) is True | |
| assert ask(Q.complex(x**2), Q.irrational(x)) is True | |
| assert ask(Q.complex(x**2), Q.imaginary(x)) is True | |
| assert ask(Q.complex(x**2), Q.integer(x)) is True | |
| assert ask(Q.complex(x**2), Q.even(x)) is True | |
| assert ask(Q.complex(x**2), Q.odd(x)) is True | |
| # 2**x | |
| assert ask(Q.complex(2**x), Q.complex(x)) is True | |
| assert ask(Q.complex(2**x), Q.real(x)) is True | |
| assert ask(Q.complex(2**x), Q.positive(x)) is True | |
| assert ask(Q.complex(2**x), Q.rational(x)) is True | |
| assert ask(Q.complex(2**x), Q.irrational(x)) is True | |
| assert ask(Q.complex(2**x), Q.imaginary(x)) is True | |
| assert ask(Q.complex(2**x), Q.integer(x)) is True | |
| assert ask(Q.complex(2**x), Q.even(x)) is True | |
| assert ask(Q.complex(2**x), Q.odd(x)) is True | |
| assert ask(Q.complex(x**y), Q.complex(x) & Q.complex(y)) is True | |
| # trigonometric expressions | |
| assert ask(Q.complex(sin(x))) is True | |
| assert ask(Q.complex(sin(2*x + 1))) is True | |
| assert ask(Q.complex(cos(x))) is True | |
| assert ask(Q.complex(cos(2*x + 1))) is True | |
| # exponential | |
| assert ask(Q.complex(exp(x))) is True | |
| assert ask(Q.complex(exp(x))) is True | |
| # Q.complexes | |
| assert ask(Q.complex(Abs(x))) is True | |
| assert ask(Q.complex(re(x))) is True | |
| assert ask(Q.complex(im(x))) is True | |
| def test_even_query(): | |
| assert ask(Q.even(x)) is None | |
| assert ask(Q.even(x), Q.integer(x)) is None | |
| assert ask(Q.even(x), ~Q.integer(x)) is False | |
| assert ask(Q.even(x), Q.rational(x)) is None | |
| assert ask(Q.even(x), Q.positive(x)) is None | |
| assert ask(Q.even(2*x)) is None | |
| assert ask(Q.even(2*x), Q.integer(x)) is True | |
| assert ask(Q.even(2*x), Q.even(x)) is True | |
| assert ask(Q.even(2*x), Q.irrational(x)) is False | |
| assert ask(Q.even(2*x), Q.odd(x)) is True | |
| assert ask(Q.even(2*x), ~Q.integer(x)) is None | |
| assert ask(Q.even(3*x), Q.integer(x)) is None | |
| assert ask(Q.even(3*x), Q.even(x)) is True | |
| assert ask(Q.even(3*x), Q.odd(x)) is False | |
| assert ask(Q.even(x + 1), Q.odd(x)) is True | |
| assert ask(Q.even(x + 1), Q.even(x)) is False | |
| assert ask(Q.even(x + 2), Q.odd(x)) is False | |
| assert ask(Q.even(x + 2), Q.even(x)) is True | |
| assert ask(Q.even(7 - x), Q.odd(x)) is True | |
| assert ask(Q.even(7 + x), Q.odd(x)) is True | |
| assert ask(Q.even(x + y), Q.odd(x) & Q.odd(y)) is True | |
| assert ask(Q.even(x + y), Q.odd(x) & Q.even(y)) is False | |
| assert ask(Q.even(x + y), Q.even(x) & Q.even(y)) is True | |
| assert ask(Q.even(2*x + 1), Q.integer(x)) is False | |
| assert ask(Q.even(2*x*y), Q.rational(x) & Q.rational(x)) is None | |
| assert ask(Q.even(2*x*y), Q.irrational(x) & Q.irrational(x)) is None | |
| assert ask(Q.even(x + y + z), Q.odd(x) & Q.odd(y) & Q.even(z)) is True | |
| assert ask(Q.even(x + y + z + t), | |
| Q.odd(x) & Q.odd(y) & Q.even(z) & Q.integer(t)) is None | |
| assert ask(Q.even(Abs(x)), Q.even(x)) is True | |
| assert ask(Q.even(Abs(x)), ~Q.even(x)) is None | |
| assert ask(Q.even(re(x)), Q.even(x)) is True | |
| assert ask(Q.even(re(x)), ~Q.even(x)) is None | |
| assert ask(Q.even(im(x)), Q.even(x)) is True | |
| assert ask(Q.even(im(x)), Q.real(x)) is True | |
| assert ask(Q.even((-1)**n), Q.integer(n)) is False | |
| assert ask(Q.even(k**2), Q.even(k)) is True | |
| assert ask(Q.even(n**2), Q.odd(n)) is False | |
| assert ask(Q.even(2**k), Q.even(k)) is None | |
| assert ask(Q.even(x**2)) is None | |
| assert ask(Q.even(k**m), Q.even(k) & Q.integer(m) & ~Q.negative(m)) is None | |
| assert ask(Q.even(n**m), Q.odd(n) & Q.integer(m) & ~Q.negative(m)) is False | |
| assert ask(Q.even(k**p), Q.even(k) & Q.integer(p) & Q.positive(p)) is True | |
| assert ask(Q.even(n**p), Q.odd(n) & Q.integer(p) & Q.positive(p)) is False | |
| assert ask(Q.even(m**k), Q.even(k) & Q.integer(m) & ~Q.negative(m)) is None | |
| assert ask(Q.even(p**k), Q.even(k) & Q.integer(p) & Q.positive(p)) is None | |
| assert ask(Q.even(m**n), Q.odd(n) & Q.integer(m) & ~Q.negative(m)) is None | |
| assert ask(Q.even(p**n), Q.odd(n) & Q.integer(p) & Q.positive(p)) is None | |
| assert ask(Q.even(k**x), Q.even(k)) is None | |
| assert ask(Q.even(n**x), Q.odd(n)) is None | |
| assert ask(Q.even(x*y), Q.integer(x) & Q.integer(y)) is None | |
| assert ask(Q.even(x*x), Q.integer(x)) is None | |
| assert ask(Q.even(x*(x + y)), Q.integer(x) & Q.odd(y)) is True | |
| assert ask(Q.even(x*(x + y)), Q.integer(x) & Q.even(y)) is None | |
| def test_evenness_in_ternary_integer_product_with_odd(): | |
| # Tests that oddness inference is independent of term ordering. | |
| # Term ordering at the point of testing depends on SymPy's symbol order, so | |
| # we try to force a different order by modifying symbol names. | |
| assert ask(Q.even(x*y*(y + z)), Q.integer(x) & Q.integer(y) & Q.odd(z)) is True | |
| assert ask(Q.even(y*x*(x + z)), Q.integer(x) & Q.integer(y) & Q.odd(z)) is True | |
| def test_evenness_in_ternary_integer_product_with_even(): | |
| assert ask(Q.even(x*y*(y + z)), Q.integer(x) & Q.integer(y) & Q.even(z)) is None | |
| def test_extended_real(): | |
| assert ask(Q.extended_real(x), Q.positive_infinite(x)) is True | |
| assert ask(Q.extended_real(x), Q.positive(x)) is True | |
| assert ask(Q.extended_real(x), Q.zero(x)) is True | |
| assert ask(Q.extended_real(x), Q.negative(x)) is True | |
| assert ask(Q.extended_real(x), Q.negative_infinite(x)) is True | |
| assert ask(Q.extended_real(-x), Q.positive(x)) is True | |
| assert ask(Q.extended_real(-x), Q.negative(x)) is True | |
| assert ask(Q.extended_real(x + S.Infinity), Q.real(x)) is True | |
| assert ask(Q.extended_real(x), Q.infinite(x)) is None | |
| def test_rational(): | |
| assert ask(Q.rational(x), Q.integer(x)) is True | |
| assert ask(Q.rational(x), Q.irrational(x)) is False | |
| assert ask(Q.rational(x), Q.real(x)) is None | |
| assert ask(Q.rational(x), Q.positive(x)) is None | |
| assert ask(Q.rational(x), Q.negative(x)) is None | |
| assert ask(Q.rational(x), Q.nonzero(x)) is None | |
| assert ask(Q.rational(x), ~Q.algebraic(x)) is False | |
| assert ask(Q.rational(2*x), Q.rational(x)) is True | |
| assert ask(Q.rational(2*x), Q.integer(x)) is True | |
| assert ask(Q.rational(2*x), Q.even(x)) is True | |
| assert ask(Q.rational(2*x), Q.odd(x)) is True | |
| assert ask(Q.rational(2*x), Q.irrational(x)) is False | |
| assert ask(Q.rational(x/2), Q.rational(x)) is True | |
| assert ask(Q.rational(x/2), Q.integer(x)) is True | |
| assert ask(Q.rational(x/2), Q.even(x)) is True | |
| assert ask(Q.rational(x/2), Q.odd(x)) is True | |
| assert ask(Q.rational(x/2), Q.irrational(x)) is False | |
| assert ask(Q.rational(1/x), Q.rational(x)) is True | |
| assert ask(Q.rational(1/x), Q.integer(x)) is True | |
| assert ask(Q.rational(1/x), Q.even(x)) is True | |
| assert ask(Q.rational(1/x), Q.odd(x)) is True | |
| assert ask(Q.rational(1/x), Q.irrational(x)) is False | |
| assert ask(Q.rational(2/x), Q.rational(x)) is True | |
| assert ask(Q.rational(2/x), Q.integer(x)) is True | |
| assert ask(Q.rational(2/x), Q.even(x)) is True | |
| assert ask(Q.rational(2/x), Q.odd(x)) is True | |
| assert ask(Q.rational(2/x), Q.irrational(x)) is False | |
| assert ask(Q.rational(x), ~Q.algebraic(x)) is False | |
| # with multiple symbols | |
| assert ask(Q.rational(x*y), Q.irrational(x) & Q.irrational(y)) is None | |
| assert ask(Q.rational(y/x), Q.rational(x) & Q.rational(y)) is True | |
| assert ask(Q.rational(y/x), Q.integer(x) & Q.rational(y)) is True | |
| assert ask(Q.rational(y/x), Q.even(x) & Q.rational(y)) is True | |
| assert ask(Q.rational(y/x), Q.odd(x) & Q.rational(y)) is True | |
| assert ask(Q.rational(y/x), Q.irrational(x) & Q.rational(y)) is False | |
| for f in [exp, sin, tan, asin, atan, cos]: | |
| assert ask(Q.rational(f(7))) is False | |
| assert ask(Q.rational(f(7, evaluate=False))) is False | |
| assert ask(Q.rational(f(0, evaluate=False))) is True | |
| assert ask(Q.rational(f(x)), Q.rational(x)) is None | |
| assert ask(Q.rational(f(x)), Q.rational(x) & Q.nonzero(x)) is False | |
| for g in [log, acos]: | |
| assert ask(Q.rational(g(7))) is False | |
| assert ask(Q.rational(g(7, evaluate=False))) is False | |
| assert ask(Q.rational(g(1, evaluate=False))) is True | |
| assert ask(Q.rational(g(x)), Q.rational(x)) is None | |
| assert ask(Q.rational(g(x)), Q.rational(x) & Q.nonzero(x - 1)) is False | |
| for h in [cot, acot]: | |
| assert ask(Q.rational(h(7))) is False | |
| assert ask(Q.rational(h(7, evaluate=False))) is False | |
| assert ask(Q.rational(h(x)), Q.rational(x)) is False | |
| def test_hermitian(): | |
| assert ask(Q.hermitian(x)) is None | |
| assert ask(Q.hermitian(x), Q.antihermitian(x)) is None | |
| assert ask(Q.hermitian(x), Q.imaginary(x)) is False | |
| assert ask(Q.hermitian(x), Q.prime(x)) is True | |
| assert ask(Q.hermitian(x), Q.real(x)) is True | |
| assert ask(Q.hermitian(x), Q.zero(x)) is True | |
| assert ask(Q.hermitian(x + 1), Q.antihermitian(x)) is None | |
| assert ask(Q.hermitian(x + 1), Q.complex(x)) is None | |
| assert ask(Q.hermitian(x + 1), Q.hermitian(x)) is True | |
| assert ask(Q.hermitian(x + 1), Q.imaginary(x)) is False | |
| assert ask(Q.hermitian(x + 1), Q.real(x)) is True | |
| assert ask(Q.hermitian(x + I), Q.antihermitian(x)) is None | |
| assert ask(Q.hermitian(x + I), Q.complex(x)) is None | |
| assert ask(Q.hermitian(x + I), Q.hermitian(x)) is False | |
| assert ask(Q.hermitian(x + I), Q.imaginary(x)) is None | |
| assert ask(Q.hermitian(x + I), Q.real(x)) is False | |
| assert ask( | |
| Q.hermitian(x + y), Q.antihermitian(x) & Q.antihermitian(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.antihermitian(x) & Q.complex(y)) is None | |
| assert ask( | |
| Q.hermitian(x + y), Q.antihermitian(x) & Q.hermitian(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.antihermitian(x) & Q.imaginary(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.antihermitian(x) & Q.real(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.hermitian(x) & Q.complex(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.hermitian(x) & Q.hermitian(y)) is True | |
| assert ask(Q.hermitian(x + y), Q.hermitian(x) & Q.imaginary(y)) is False | |
| assert ask(Q.hermitian(x + y), Q.hermitian(x) & Q.real(y)) is True | |
| assert ask(Q.hermitian(x + y), Q.imaginary(x) & Q.complex(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.imaginary(x) & Q.imaginary(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.imaginary(x) & Q.real(y)) is False | |
| assert ask(Q.hermitian(x + y), Q.real(x) & Q.complex(y)) is None | |
| assert ask(Q.hermitian(x + y), Q.real(x) & Q.real(y)) is True | |
| assert ask(Q.hermitian(I*x), Q.antihermitian(x)) is True | |
| assert ask(Q.hermitian(I*x), Q.complex(x)) is None | |
| assert ask(Q.hermitian(I*x), Q.hermitian(x)) is False | |
| assert ask(Q.hermitian(I*x), Q.imaginary(x)) is True | |
| assert ask(Q.hermitian(I*x), Q.real(x)) is False | |
| assert ask(Q.hermitian(x*y), Q.hermitian(x) & Q.real(y)) is True | |
| assert ask( | |
| Q.hermitian(x + y + z), Q.real(x) & Q.real(y) & Q.real(z)) is True | |
| assert ask(Q.hermitian(x + y + z), | |
| Q.real(x) & Q.real(y) & Q.imaginary(z)) is False | |
| assert ask(Q.hermitian(x + y + z), | |
| Q.real(x) & Q.imaginary(y) & Q.imaginary(z)) is None | |
| assert ask(Q.hermitian(x + y + z), | |
| Q.imaginary(x) & Q.imaginary(y) & Q.imaginary(z)) is None | |
| assert ask(Q.antihermitian(x)) is None | |
| assert ask(Q.antihermitian(x), Q.real(x)) is False | |
| assert ask(Q.antihermitian(x), Q.prime(x)) is False | |
| assert ask(Q.antihermitian(x + 1), Q.antihermitian(x)) is False | |
| assert ask(Q.antihermitian(x + 1), Q.complex(x)) is None | |
| assert ask(Q.antihermitian(x + 1), Q.hermitian(x)) is None | |
| assert ask(Q.antihermitian(x + 1), Q.imaginary(x)) is False | |
| assert ask(Q.antihermitian(x + 1), Q.real(x)) is None | |
| assert ask(Q.antihermitian(x + I), Q.antihermitian(x)) is True | |
| assert ask(Q.antihermitian(x + I), Q.complex(x)) is None | |
| assert ask(Q.antihermitian(x + I), Q.hermitian(x)) is None | |
| assert ask(Q.antihermitian(x + I), Q.imaginary(x)) is True | |
| assert ask(Q.antihermitian(x + I), Q.real(x)) is False | |
| assert ask(Q.antihermitian(x), Q.zero(x)) is True | |
| assert ask( | |
| Q.antihermitian(x + y), Q.antihermitian(x) & Q.antihermitian(y) | |
| ) is True | |
| assert ask( | |
| Q.antihermitian(x + y), Q.antihermitian(x) & Q.complex(y)) is None | |
| assert ask( | |
| Q.antihermitian(x + y), Q.antihermitian(x) & Q.hermitian(y)) is None | |
| assert ask( | |
| Q.antihermitian(x + y), Q.antihermitian(x) & Q.imaginary(y)) is True | |
| assert ask(Q.antihermitian(x + y), Q.antihermitian(x) & Q.real(y) | |
| ) is False | |
| assert ask(Q.antihermitian(x + y), Q.hermitian(x) & Q.complex(y)) is None | |
| assert ask(Q.antihermitian(x + y), Q.hermitian(x) & Q.hermitian(y) | |
| ) is None | |
| assert ask( | |
| Q.antihermitian(x + y), Q.hermitian(x) & Q.imaginary(y)) is None | |
| assert ask(Q.antihermitian(x + y), Q.hermitian(x) & Q.real(y)) is None | |
| assert ask(Q.antihermitian(x + y), Q.imaginary(x) & Q.complex(y)) is None | |
| assert ask(Q.antihermitian(x + y), Q.imaginary(x) & Q.imaginary(y)) is True | |
| assert ask(Q.antihermitian(x + y), Q.imaginary(x) & Q.real(y)) is False | |
| assert ask(Q.antihermitian(x + y), Q.real(x) & Q.complex(y)) is None | |
| assert ask(Q.antihermitian(x + y), Q.real(x) & Q.real(y)) is None | |
| assert ask(Q.antihermitian(I*x), Q.real(x)) is True | |
| assert ask(Q.antihermitian(I*x), Q.antihermitian(x)) is False | |
| assert ask(Q.antihermitian(I*x), Q.complex(x)) is None | |
| assert ask(Q.antihermitian(x*y), Q.antihermitian(x) & Q.real(y)) is True | |
| assert ask(Q.antihermitian(x + y + z), | |
| Q.real(x) & Q.real(y) & Q.real(z)) is None | |
| assert ask(Q.antihermitian(x + y + z), | |
| Q.real(x) & Q.real(y) & Q.imaginary(z)) is None | |
| assert ask(Q.antihermitian(x + y + z), | |
| Q.real(x) & Q.imaginary(y) & Q.imaginary(z)) is False | |
| assert ask(Q.antihermitian(x + y + z), | |
| Q.imaginary(x) & Q.imaginary(y) & Q.imaginary(z)) is True | |
| def test_imaginary(): | |
| assert ask(Q.imaginary(x)) is None | |
| assert ask(Q.imaginary(x), Q.real(x)) is False | |
| assert ask(Q.imaginary(x), Q.prime(x)) is False | |
| assert ask(Q.imaginary(x + 1), Q.real(x)) is False | |
| assert ask(Q.imaginary(x + 1), Q.imaginary(x)) is False | |
| assert ask(Q.imaginary(x + I), Q.real(x)) is False | |
| assert ask(Q.imaginary(x + I), Q.imaginary(x)) is True | |
| assert ask(Q.imaginary(x + y), Q.imaginary(x) & Q.imaginary(y)) is True | |
| assert ask(Q.imaginary(x + y), Q.real(x) & Q.real(y)) is False | |
| assert ask(Q.imaginary(x + y), Q.imaginary(x) & Q.real(y)) is False | |
| assert ask(Q.imaginary(x + y), Q.complex(x) & Q.real(y)) is None | |
| assert ask( | |
| Q.imaginary(x + y + z), Q.real(x) & Q.real(y) & Q.real(z)) is False | |
| assert ask(Q.imaginary(x + y + z), | |
| Q.real(x) & Q.real(y) & Q.imaginary(z)) is None | |
| assert ask(Q.imaginary(x + y + z), | |
| Q.real(x) & Q.imaginary(y) & Q.imaginary(z)) is False | |
| assert ask(Q.imaginary(I*x), Q.real(x)) is True | |
| assert ask(Q.imaginary(I*x), Q.imaginary(x)) is False | |
| assert ask(Q.imaginary(I*x), Q.complex(x)) is None | |
| assert ask(Q.imaginary(x*y), Q.imaginary(x) & Q.real(y)) is True | |
| assert ask(Q.imaginary(x*y), Q.real(x) & Q.real(y)) is False | |
| assert ask(Q.imaginary(I**x), Q.negative(x)) is None | |
| assert ask(Q.imaginary(I**x), Q.positive(x)) is None | |
| assert ask(Q.imaginary(I**x), Q.even(x)) is False | |
| assert ask(Q.imaginary(I**x), Q.odd(x)) is True | |
| assert ask(Q.imaginary(I**x), Q.imaginary(x)) is False | |
| assert ask(Q.imaginary((2*I)**x), Q.imaginary(x)) is False | |
| assert ask(Q.imaginary(x**0), Q.imaginary(x)) is False | |
| assert ask(Q.imaginary(x**y), Q.imaginary(x) & Q.imaginary(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.imaginary(x) & Q.real(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.real(x) & Q.imaginary(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.real(x) & Q.real(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.imaginary(x) & Q.integer(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.imaginary(y) & Q.integer(x)) is None | |
| assert ask(Q.imaginary(x**y), Q.imaginary(x) & Q.odd(y)) is True | |
| assert ask(Q.imaginary(x**y), Q.imaginary(x) & Q.rational(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.imaginary(x) & Q.even(y)) is False | |
| assert ask(Q.imaginary(x**y), Q.real(x) & Q.integer(y)) is False | |
| assert ask(Q.imaginary(x**y), Q.positive(x) & Q.real(y)) is False | |
| assert ask(Q.imaginary(x**y), Q.negative(x) & Q.real(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.negative(x) & Q.real(y) & ~Q.rational(y)) is False | |
| assert ask(Q.imaginary(x**y), Q.integer(x) & Q.imaginary(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.negative(x) & Q.rational(y) & Q.integer(2*y)) is True | |
| assert ask(Q.imaginary(x**y), Q.negative(x) & Q.rational(y) & ~Q.integer(2*y)) is False | |
| assert ask(Q.imaginary(x**y), Q.negative(x) & Q.rational(y)) is None | |
| assert ask(Q.imaginary(x**y), Q.real(x) & Q.rational(y) & ~Q.integer(2*y)) is False | |
| assert ask(Q.imaginary(x**y), Q.real(x) & Q.rational(y) & Q.integer(2*y)) is None | |
| # logarithm | |
| assert ask(Q.imaginary(log(I))) is True | |
| assert ask(Q.imaginary(log(2*I))) is False | |
| assert ask(Q.imaginary(log(I + 1))) is False | |
| assert ask(Q.imaginary(log(x)), Q.complex(x)) is None | |
| assert ask(Q.imaginary(log(x)), Q.imaginary(x)) is None | |
| assert ask(Q.imaginary(log(x)), Q.positive(x)) is False | |
| assert ask(Q.imaginary(log(exp(x))), Q.complex(x)) is None | |
| assert ask(Q.imaginary(log(exp(x))), Q.imaginary(x)) is None # zoo/I/a+I*b | |
| assert ask(Q.imaginary(log(exp(I)))) is True | |
| # exponential | |
| assert ask(Q.imaginary(exp(x)**x), Q.imaginary(x)) is False | |
| eq = Pow(exp(pi*I*x, evaluate=False), x, evaluate=False) | |
| assert ask(Q.imaginary(eq), Q.even(x)) is False | |
| eq = Pow(exp(pi*I*x/2, evaluate=False), x, evaluate=False) | |
| assert ask(Q.imaginary(eq), Q.odd(x)) is True | |
| assert ask(Q.imaginary(exp(3*I*pi*x)**x), Q.integer(x)) is False | |
| assert ask(Q.imaginary(exp(2*pi*I, evaluate=False))) is False | |
| assert ask(Q.imaginary(exp(pi*I/2, evaluate=False))) is True | |
| # issue 7886 | |
| assert ask(Q.imaginary(Pow(x, Rational(1, 4))), Q.real(x) & Q.negative(x)) is False | |
| def test_integer(): | |
| assert ask(Q.integer(x)) is None | |
| assert ask(Q.integer(x), Q.integer(x)) is True | |
| assert ask(Q.integer(x), ~Q.integer(x)) is False | |
| assert ask(Q.integer(x), ~Q.real(x)) is False | |
| assert ask(Q.integer(x), ~Q.positive(x)) is None | |
| assert ask(Q.integer(x), Q.even(x) | Q.odd(x)) is True | |
| assert ask(Q.integer(2*x), Q.integer(x)) is True | |
| assert ask(Q.integer(2*x), Q.even(x)) is True | |
| assert ask(Q.integer(2*x), Q.prime(x)) is True | |
| assert ask(Q.integer(2*x), Q.rational(x)) is None | |
| assert ask(Q.integer(2*x), Q.real(x)) is None | |
| assert ask(Q.integer(sqrt(2)*x), Q.integer(x)) is False | |
| assert ask(Q.integer(sqrt(2)*x), Q.irrational(x)) is None | |
| assert ask(Q.integer(x/2), Q.odd(x)) is False | |
| assert ask(Q.integer(x/2), Q.even(x)) is True | |
| assert ask(Q.integer(x/3), Q.odd(x)) is None | |
| assert ask(Q.integer(x/3), Q.even(x)) is None | |
| def test_negative(): | |
| assert ask(Q.negative(x), Q.negative(x)) is True | |
| assert ask(Q.negative(x), Q.positive(x)) is False | |
| assert ask(Q.negative(x), ~Q.real(x)) is False | |
| assert ask(Q.negative(x), Q.prime(x)) is False | |
| assert ask(Q.negative(x), ~Q.prime(x)) is None | |
| assert ask(Q.negative(-x), Q.positive(x)) is True | |
| assert ask(Q.negative(-x), ~Q.positive(x)) is None | |
| assert ask(Q.negative(-x), Q.negative(x)) is False | |
| assert ask(Q.negative(-x), Q.positive(x)) is True | |
| assert ask(Q.negative(x - 1), Q.negative(x)) is True | |
| assert ask(Q.negative(x + y)) is None | |
| assert ask(Q.negative(x + y), Q.negative(x)) is None | |
| assert ask(Q.negative(x + y), Q.negative(x) & Q.negative(y)) is True | |
| assert ask(Q.negative(x + y), Q.negative(x) & Q.nonpositive(y)) is True | |
| assert ask(Q.negative(2 + I)) is False | |
| # although this could be False, it is representative of expressions | |
| # that don't evaluate to a zero with precision | |
| assert ask(Q.negative(cos(I)**2 + sin(I)**2 - 1)) is None | |
| assert ask(Q.negative(-I + I*(cos(2)**2 + sin(2)**2))) is None | |
| assert ask(Q.negative(x**2)) is None | |
| assert ask(Q.negative(x**2), Q.real(x)) is False | |
| assert ask(Q.negative(x**1.4), Q.real(x)) is None | |
| assert ask(Q.negative(x**I), Q.positive(x)) is None | |
| assert ask(Q.negative(x*y)) is None | |
| assert ask(Q.negative(x*y), Q.positive(x) & Q.positive(y)) is False | |
| assert ask(Q.negative(x*y), Q.positive(x) & Q.negative(y)) is True | |
| assert ask(Q.negative(x*y), Q.complex(x) & Q.complex(y)) is None | |
| assert ask(Q.negative(x**y)) is None | |
| assert ask(Q.negative(x**y), Q.negative(x) & Q.even(y)) is False | |
| assert ask(Q.negative(x**y), Q.negative(x) & Q.odd(y)) is True | |
| assert ask(Q.negative(x**y), Q.positive(x) & Q.integer(y)) is False | |
| assert ask(Q.negative(Abs(x))) is False | |
| def test_nonzero(): | |
| assert ask(Q.nonzero(x)) is None | |
| assert ask(Q.nonzero(x), Q.real(x)) is None | |
| assert ask(Q.nonzero(x), Q.positive(x)) is True | |
| assert ask(Q.nonzero(x), Q.negative(x)) is True | |
| assert ask(Q.nonzero(x), Q.negative(x) | Q.positive(x)) is True | |
| assert ask(Q.nonzero(x + y)) is None | |
| assert ask(Q.nonzero(x + y), Q.positive(x) & Q.positive(y)) is True | |
| assert ask(Q.nonzero(x + y), Q.positive(x) & Q.negative(y)) is None | |
| assert ask(Q.nonzero(x + y), Q.negative(x) & Q.negative(y)) is True | |
| assert ask(Q.nonzero(2*x)) is None | |
| assert ask(Q.nonzero(2*x), Q.positive(x)) is True | |
| assert ask(Q.nonzero(2*x), Q.negative(x)) is True | |
| assert ask(Q.nonzero(x*y), Q.nonzero(x)) is None | |
| assert ask(Q.nonzero(x*y), Q.nonzero(x) & Q.nonzero(y)) is True | |
| assert ask(Q.nonzero(x**y), Q.nonzero(x)) is True | |
| assert ask(Q.nonzero(Abs(x))) is None | |
| assert ask(Q.nonzero(Abs(x)), Q.nonzero(x)) is True | |
| assert ask(Q.nonzero(log(exp(2*I)))) is False | |
| # although this could be False, it is representative of expressions | |
| # that don't evaluate to a zero with precision | |
| assert ask(Q.nonzero(cos(1)**2 + sin(1)**2 - 1)) is None | |
| def test_zero(): | |
| assert ask(Q.zero(x)) is None | |
| assert ask(Q.zero(x), Q.real(x)) is None | |
| assert ask(Q.zero(x), Q.positive(x)) is False | |
| assert ask(Q.zero(x), Q.negative(x)) is False | |
| assert ask(Q.zero(x), Q.negative(x) | Q.positive(x)) is False | |
| assert ask(Q.zero(x), Q.nonnegative(x) & Q.nonpositive(x)) is True | |
| assert ask(Q.zero(x + y)) is None | |
| assert ask(Q.zero(x + y), Q.positive(x) & Q.positive(y)) is False | |
| assert ask(Q.zero(x + y), Q.positive(x) & Q.negative(y)) is None | |
| assert ask(Q.zero(x + y), Q.negative(x) & Q.negative(y)) is False | |
| assert ask(Q.zero(2*x)) is None | |
| assert ask(Q.zero(2*x), Q.positive(x)) is False | |
| assert ask(Q.zero(2*x), Q.negative(x)) is False | |
| assert ask(Q.zero(x*y), Q.nonzero(x)) is None | |
| assert ask(Q.zero(Abs(x))) is None | |
| assert ask(Q.zero(Abs(x)), Q.zero(x)) is True | |
| assert ask(Q.integer(x), Q.zero(x)) is True | |
| assert ask(Q.even(x), Q.zero(x)) is True | |
| assert ask(Q.odd(x), Q.zero(x)) is False | |
| assert ask(Q.zero(x), Q.even(x)) is None | |
| assert ask(Q.zero(x), Q.odd(x)) is False | |
| assert ask(Q.zero(x) | Q.zero(y), Q.zero(x*y)) is True | |
| def test_odd_query(): | |
| assert ask(Q.odd(x)) is None | |
| assert ask(Q.odd(x), Q.odd(x)) is True | |
| assert ask(Q.odd(x), Q.integer(x)) is None | |
| assert ask(Q.odd(x), ~Q.integer(x)) is False | |
| assert ask(Q.odd(x), Q.rational(x)) is None | |
| assert ask(Q.odd(x), Q.positive(x)) is None | |
| assert ask(Q.odd(-x), Q.odd(x)) is True | |
| assert ask(Q.odd(2*x)) is None | |
| assert ask(Q.odd(2*x), Q.integer(x)) is False | |
| assert ask(Q.odd(2*x), Q.odd(x)) is False | |
| assert ask(Q.odd(2*x), Q.irrational(x)) is False | |
| assert ask(Q.odd(2*x), ~Q.integer(x)) is None | |
| assert ask(Q.odd(3*x), Q.integer(x)) is None | |
| assert ask(Q.odd(x/3), Q.odd(x)) is None | |
| assert ask(Q.odd(x/3), Q.even(x)) is None | |
| assert ask(Q.odd(x + 1), Q.even(x)) is True | |
| assert ask(Q.odd(x + 2), Q.even(x)) is False | |
| assert ask(Q.odd(x + 2), Q.odd(x)) is True | |
| assert ask(Q.odd(3 - x), Q.odd(x)) is False | |
| assert ask(Q.odd(3 - x), Q.even(x)) is True | |
| assert ask(Q.odd(3 + x), Q.odd(x)) is False | |
| assert ask(Q.odd(3 + x), Q.even(x)) is True | |
| assert ask(Q.odd(x + y), Q.odd(x) & Q.odd(y)) is False | |
| assert ask(Q.odd(x + y), Q.odd(x) & Q.even(y)) is True | |
| assert ask(Q.odd(x - y), Q.even(x) & Q.odd(y)) is True | |
| assert ask(Q.odd(x - y), Q.odd(x) & Q.odd(y)) is False | |
| assert ask(Q.odd(x + y + z), Q.odd(x) & Q.odd(y) & Q.even(z)) is False | |
| assert ask(Q.odd(x + y + z + t), | |
| Q.odd(x) & Q.odd(y) & Q.even(z) & Q.integer(t)) is None | |
| assert ask(Q.odd(2*x + 1), Q.integer(x)) is True | |
| assert ask(Q.odd(2*x + y), Q.integer(x) & Q.odd(y)) is True | |
| assert ask(Q.odd(2*x + y), Q.integer(x) & Q.even(y)) is False | |
| assert ask(Q.odd(2*x + y), Q.integer(x) & Q.integer(y)) is None | |
| assert ask(Q.odd(x*y), Q.odd(x) & Q.even(y)) is False | |
| assert ask(Q.odd(x*y), Q.odd(x) & Q.odd(y)) is True | |
| assert ask(Q.odd(2*x*y), Q.rational(x) & Q.rational(x)) is None | |
| assert ask(Q.odd(2*x*y), Q.irrational(x) & Q.irrational(x)) is None | |
| assert ask(Q.odd(Abs(x)), Q.odd(x)) is True | |
| assert ask(Q.odd((-1)**n), Q.integer(n)) is True | |
| assert ask(Q.odd(k**2), Q.even(k)) is False | |
| assert ask(Q.odd(n**2), Q.odd(n)) is True | |
| assert ask(Q.odd(3**k), Q.even(k)) is None | |
| assert ask(Q.odd(k**m), Q.even(k) & Q.integer(m) & ~Q.negative(m)) is None | |
| assert ask(Q.odd(n**m), Q.odd(n) & Q.integer(m) & ~Q.negative(m)) is True | |
| assert ask(Q.odd(k**p), Q.even(k) & Q.integer(p) & Q.positive(p)) is False | |
| assert ask(Q.odd(n**p), Q.odd(n) & Q.integer(p) & Q.positive(p)) is True | |
| assert ask(Q.odd(m**k), Q.even(k) & Q.integer(m) & ~Q.negative(m)) is None | |
| assert ask(Q.odd(p**k), Q.even(k) & Q.integer(p) & Q.positive(p)) is None | |
| assert ask(Q.odd(m**n), Q.odd(n) & Q.integer(m) & ~Q.negative(m)) is None | |
| assert ask(Q.odd(p**n), Q.odd(n) & Q.integer(p) & Q.positive(p)) is None | |
| assert ask(Q.odd(k**x), Q.even(k)) is None | |
| assert ask(Q.odd(n**x), Q.odd(n)) is None | |
| assert ask(Q.odd(x*y), Q.integer(x) & Q.integer(y)) is None | |
| assert ask(Q.odd(x*x), Q.integer(x)) is None | |
| assert ask(Q.odd(x*(x + y)), Q.integer(x) & Q.odd(y)) is False | |
| assert ask(Q.odd(x*(x + y)), Q.integer(x) & Q.even(y)) is None | |
| def test_oddness_in_ternary_integer_product_with_odd(): | |
| # Tests that oddness inference is independent of term ordering. | |
| # Term ordering at the point of testing depends on SymPy's symbol order, so | |
| # we try to force a different order by modifying symbol names. | |
| assert ask(Q.odd(x*y*(y + z)), Q.integer(x) & Q.integer(y) & Q.odd(z)) is False | |
| assert ask(Q.odd(y*x*(x + z)), Q.integer(x) & Q.integer(y) & Q.odd(z)) is False | |
| def test_oddness_in_ternary_integer_product_with_even(): | |
| assert ask(Q.odd(x*y*(y + z)), Q.integer(x) & Q.integer(y) & Q.even(z)) is None | |
| def test_prime(): | |
| assert ask(Q.prime(x), Q.prime(x)) is True | |
| assert ask(Q.prime(x), ~Q.prime(x)) is False | |
| assert ask(Q.prime(x), Q.integer(x)) is None | |
| assert ask(Q.prime(x), ~Q.integer(x)) is False | |
| assert ask(Q.prime(2*x), Q.integer(x)) is None | |
| assert ask(Q.prime(x*y)) is None | |
| assert ask(Q.prime(x*y), Q.prime(x)) is None | |
| assert ask(Q.prime(x*y), Q.integer(x) & Q.integer(y)) is None | |
| assert ask(Q.prime(4*x), Q.integer(x)) is False | |
| assert ask(Q.prime(4*x)) is None | |
| assert ask(Q.prime(x**2), Q.integer(x)) is False | |
| assert ask(Q.prime(x**2), Q.prime(x)) is False | |
| assert ask(Q.prime(x**y), Q.integer(x) & Q.integer(y)) is False | |
| def test_positive(): | |
| assert ask(Q.positive(cos(I) ** 2 + sin(I) ** 2 - 1)) is None | |
| assert ask(Q.positive(x), Q.positive(x)) is True | |
| assert ask(Q.positive(x), Q.negative(x)) is False | |
| assert ask(Q.positive(x), Q.nonzero(x)) is None | |
| assert ask(Q.positive(-x), Q.positive(x)) is False | |
| assert ask(Q.positive(-x), Q.negative(x)) is True | |
| assert ask(Q.positive(x + y), Q.positive(x) & Q.positive(y)) is True | |
| assert ask(Q.positive(x + y), Q.positive(x) & Q.nonnegative(y)) is True | |
| assert ask(Q.positive(x + y), Q.positive(x) & Q.negative(y)) is None | |
| assert ask(Q.positive(x + y), Q.positive(x) & Q.imaginary(y)) is False | |
| assert ask(Q.positive(2*x), Q.positive(x)) is True | |
| assumptions = Q.positive(x) & Q.negative(y) & Q.negative(z) & Q.positive(w) | |
| assert ask(Q.positive(x*y*z)) is None | |
| assert ask(Q.positive(x*y*z), assumptions) is True | |
| assert ask(Q.positive(-x*y*z), assumptions) is False | |
| assert ask(Q.positive(x**I), Q.positive(x)) is None | |
| assert ask(Q.positive(x**2), Q.positive(x)) is True | |
| assert ask(Q.positive(x**2), Q.negative(x)) is True | |
| assert ask(Q.positive(x**3), Q.negative(x)) is False | |
| assert ask(Q.positive(1/(1 + x**2)), Q.real(x)) is True | |
| assert ask(Q.positive(2**I)) is False | |
| assert ask(Q.positive(2 + I)) is False | |
| # although this could be False, it is representative of expressions | |
| # that don't evaluate to a zero with precision | |
| assert ask(Q.positive(cos(I)**2 + sin(I)**2 - 1)) is None | |
| assert ask(Q.positive(-I + I*(cos(2)**2 + sin(2)**2))) is None | |
| #exponential | |
| assert ask(Q.positive(exp(x)), Q.real(x)) is True | |
| assert ask(~Q.negative(exp(x)), Q.real(x)) is True | |
| assert ask(Q.positive(x + exp(x)), Q.real(x)) is None | |
| assert ask(Q.positive(exp(x)), Q.imaginary(x)) is None | |
| assert ask(Q.positive(exp(2*pi*I, evaluate=False)), Q.imaginary(x)) is True | |
| assert ask(Q.negative(exp(pi*I, evaluate=False)), Q.imaginary(x)) is True | |
| assert ask(Q.positive(exp(x*pi*I)), Q.even(x)) is True | |
| assert ask(Q.positive(exp(x*pi*I)), Q.odd(x)) is False | |
| assert ask(Q.positive(exp(x*pi*I)), Q.real(x)) is None | |
| # logarithm | |
| assert ask(Q.positive(log(x)), Q.imaginary(x)) is False | |
| assert ask(Q.positive(log(x)), Q.negative(x)) is False | |
| assert ask(Q.positive(log(x)), Q.positive(x)) is None | |
| assert ask(Q.positive(log(x + 2)), Q.positive(x)) is True | |
| # factorial | |
| assert ask(Q.positive(factorial(x)), Q.integer(x) & Q.positive(x)) | |
| assert ask(Q.positive(factorial(x)), Q.integer(x)) is None | |
| #absolute value | |
| assert ask(Q.positive(Abs(x))) is None # Abs(0) = 0 | |
| assert ask(Q.positive(Abs(x)), Q.positive(x)) is True | |
| def test_nonpositive(): | |
| assert ask(Q.nonpositive(-1)) | |
| assert ask(Q.nonpositive(0)) | |
| assert ask(Q.nonpositive(1)) is False | |
| assert ask(~Q.positive(x), Q.nonpositive(x)) | |
| assert ask(Q.nonpositive(x), Q.positive(x)) is False | |
| assert ask(Q.nonpositive(sqrt(-1))) is False | |
| assert ask(Q.nonpositive(x), Q.imaginary(x)) is False | |
| def test_nonnegative(): | |
| assert ask(Q.nonnegative(-1)) is False | |
| assert ask(Q.nonnegative(0)) | |
| assert ask(Q.nonnegative(1)) | |
| assert ask(~Q.negative(x), Q.nonnegative(x)) | |
| assert ask(Q.nonnegative(x), Q.negative(x)) is False | |
| assert ask(Q.nonnegative(sqrt(-1))) is False | |
| assert ask(Q.nonnegative(x), Q.imaginary(x)) is False | |
| def test_real_basic(): | |
| assert ask(Q.real(x)) is None | |
| assert ask(Q.real(x), Q.real(x)) is True | |
| assert ask(Q.real(x), Q.nonzero(x)) is True | |
| assert ask(Q.real(x), Q.positive(x)) is True | |
| assert ask(Q.real(x), Q.negative(x)) is True | |
| assert ask(Q.real(x), Q.integer(x)) is True | |
| assert ask(Q.real(x), Q.even(x)) is True | |
| assert ask(Q.real(x), Q.prime(x)) is True | |
| assert ask(Q.real(x/sqrt(2)), Q.real(x)) is True | |
| assert ask(Q.real(x/sqrt(-2)), Q.real(x)) is False | |
| assert ask(Q.real(x + 1), Q.real(x)) is True | |
| assert ask(Q.real(x + I), Q.real(x)) is False | |
| assert ask(Q.real(x + I), Q.complex(x)) is None | |
| assert ask(Q.real(2*x), Q.real(x)) is True | |
| assert ask(Q.real(I*x), Q.real(x)) is False | |
| assert ask(Q.real(I*x), Q.imaginary(x)) is True | |
| assert ask(Q.real(I*x), Q.complex(x)) is None | |
| def test_real_pow(): | |
| assert ask(Q.real(x**2), Q.real(x)) is True | |
| assert ask(Q.real(sqrt(x)), Q.negative(x)) is False | |
| assert ask(Q.real(x**y), Q.real(x) & Q.integer(y)) is True | |
| assert ask(Q.real(x**y), Q.real(x) & Q.real(y)) is None | |
| assert ask(Q.real(x**y), Q.positive(x) & Q.real(y)) is True | |
| assert ask(Q.real(x**y), Q.imaginary(x) & Q.imaginary(y)) is None # I**I or (2*I)**I | |
| assert ask(Q.real(x**y), Q.imaginary(x) & Q.real(y)) is None # I**1 or I**0 | |
| assert ask(Q.real(x**y), Q.real(x) & Q.imaginary(y)) is None # could be exp(2*pi*I) or 2**I | |
| assert ask(Q.real(x**0), Q.imaginary(x)) is True | |
| assert ask(Q.real(x**y), Q.real(x) & Q.integer(y)) is True | |
| assert ask(Q.real(x**y), Q.positive(x) & Q.real(y)) is True | |
| assert ask(Q.real(x**y), Q.real(x) & Q.rational(y)) is None | |
| assert ask(Q.real(x**y), Q.imaginary(x) & Q.integer(y)) is None | |
| assert ask(Q.real(x**y), Q.imaginary(x) & Q.odd(y)) is False | |
| assert ask(Q.real(x**y), Q.imaginary(x) & Q.even(y)) is True | |
| assert ask(Q.real(x**(y/z)), Q.real(x) & Q.real(y/z) & Q.rational(y/z) & Q.even(z) & Q.positive(x)) is True | |
| assert ask(Q.real(x**(y/z)), Q.real(x) & Q.rational(y/z) & Q.even(z) & Q.negative(x)) is False | |
| assert ask(Q.real(x**(y/z)), Q.real(x) & Q.integer(y/z)) is True | |
| assert ask(Q.real(x**(y/z)), Q.real(x) & Q.real(y/z) & Q.positive(x)) is True | |
| assert ask(Q.real(x**(y/z)), Q.real(x) & Q.real(y/z) & Q.negative(x)) is False | |
| assert ask(Q.real((-I)**i), Q.imaginary(i)) is True | |
| assert ask(Q.real(I**i), Q.imaginary(i)) is True | |
| assert ask(Q.real(i**i), Q.imaginary(i)) is None # i might be 2*I | |
| assert ask(Q.real(x**i), Q.imaginary(i)) is None # x could be 0 | |
| assert ask(Q.real(x**(I*pi/log(x))), Q.real(x)) is True | |
| def test_real_functions(): | |
| # trigonometric functions | |
| assert ask(Q.real(sin(x))) is None | |
| assert ask(Q.real(cos(x))) is None | |
| assert ask(Q.real(sin(x)), Q.real(x)) is True | |
| assert ask(Q.real(cos(x)), Q.real(x)) is True | |
| # exponential function | |
| assert ask(Q.real(exp(x))) is None | |
| assert ask(Q.real(exp(x)), Q.real(x)) is True | |
| assert ask(Q.real(x + exp(x)), Q.real(x)) is True | |
| assert ask(Q.real(exp(2*pi*I, evaluate=False))) is True | |
| assert ask(Q.real(exp(pi*I, evaluate=False))) is True | |
| assert ask(Q.real(exp(pi*I/2, evaluate=False))) is False | |
| # logarithm | |
| assert ask(Q.real(log(I))) is False | |
| assert ask(Q.real(log(2*I))) is False | |
| assert ask(Q.real(log(I + 1))) is False | |
| assert ask(Q.real(log(x)), Q.complex(x)) is None | |
| assert ask(Q.real(log(x)), Q.imaginary(x)) is False | |
| assert ask(Q.real(log(exp(x))), Q.imaginary(x)) is None # exp(2*pi*I) is 1, log(exp(pi*I)) is pi*I (disregarding periodicity) | |
| assert ask(Q.real(log(exp(x))), Q.complex(x)) is None | |
| eq = Pow(exp(2*pi*I*x, evaluate=False), x, evaluate=False) | |
| assert ask(Q.real(eq), Q.integer(x)) is True | |
| assert ask(Q.real(exp(x)**x), Q.imaginary(x)) is True | |
| assert ask(Q.real(exp(x)**x), Q.complex(x)) is None | |
| # Q.complexes | |
| assert ask(Q.real(re(x))) is True | |
| assert ask(Q.real(im(x))) is True | |
| def test_matrix(): | |
| # hermitian | |
| assert ask(Q.hermitian(Matrix([[2, 2 + I, 4], [2 - I, 3, I], [4, -I, 1]]))) == True | |
| assert ask(Q.hermitian(Matrix([[2, 2 + I, 4], [2 + I, 3, I], [4, -I, 1]]))) == False | |
| z = symbols('z', complex=True) | |
| assert ask(Q.hermitian(Matrix([[2, 2 + I, z], [2 - I, 3, I], [4, -I, 1]]))) == None | |
| assert ask(Q.hermitian(SparseMatrix(((25, 15, -5), (15, 18, 0), (-5, 0, 11))))) == True | |
| assert ask(Q.hermitian(SparseMatrix(((25, 15, -5), (15, I, 0), (-5, 0, 11))))) == False | |
| assert ask(Q.hermitian(SparseMatrix(((25, 15, -5), (15, z, 0), (-5, 0, 11))))) == None | |
| # antihermitian | |
| A = Matrix([[0, -2 - I, 0], [2 - I, 0, -I], [0, -I, 0]]) | |
| B = Matrix([[-I, 2 + I, 0], [-2 + I, 0, 2 + I], [0, -2 + I, -I]]) | |
| assert ask(Q.antihermitian(A)) is True | |
| assert ask(Q.antihermitian(B)) is True | |
| assert ask(Q.antihermitian(A**2)) is False | |
| C = (B**3) | |
| C.simplify() | |
| assert ask(Q.antihermitian(C)) is True | |
| _A = Matrix([[0, -2 - I, 0], [z, 0, -I], [0, -I, 0]]) | |
| assert ask(Q.antihermitian(_A)) is None | |
| def test_algebraic(): | |
| assert ask(Q.algebraic(x)) is None | |
| assert ask(Q.algebraic(I)) is True | |
| assert ask(Q.algebraic(2*I)) is True | |
| assert ask(Q.algebraic(I/3)) is True | |
| assert ask(Q.algebraic(sqrt(7))) is True | |
| assert ask(Q.algebraic(2*sqrt(7))) is True | |
| assert ask(Q.algebraic(sqrt(7)/3)) is True | |
| assert ask(Q.algebraic(I*sqrt(3))) is True | |
| assert ask(Q.algebraic(sqrt(1 + I*sqrt(3)))) is True | |
| assert ask(Q.algebraic(1 + I*sqrt(3)**Rational(17, 31))) is True | |
| assert ask(Q.algebraic(1 + I*sqrt(3)**(17/pi))) is False | |
| for f in [exp, sin, tan, asin, atan, cos]: | |
| assert ask(Q.algebraic(f(7))) is False | |
| assert ask(Q.algebraic(f(7, evaluate=False))) is False | |
| assert ask(Q.algebraic(f(0, evaluate=False))) is True | |
| assert ask(Q.algebraic(f(x)), Q.algebraic(x)) is None | |
| assert ask(Q.algebraic(f(x)), Q.algebraic(x) & Q.nonzero(x)) is False | |
| for g in [log, acos]: | |
| assert ask(Q.algebraic(g(7))) is False | |
| assert ask(Q.algebraic(g(7, evaluate=False))) is False | |
| assert ask(Q.algebraic(g(1, evaluate=False))) is True | |
| assert ask(Q.algebraic(g(x)), Q.algebraic(x)) is None | |
| assert ask(Q.algebraic(g(x)), Q.algebraic(x) & Q.nonzero(x - 1)) is False | |
| for h in [cot, acot]: | |
| assert ask(Q.algebraic(h(7))) is False | |
| assert ask(Q.algebraic(h(7, evaluate=False))) is False | |
| assert ask(Q.algebraic(h(x)), Q.algebraic(x)) is False | |
| assert ask(Q.algebraic(sqrt(sin(7)))) is False | |
| assert ask(Q.algebraic(sqrt(y + I*sqrt(7)))) is None | |
| assert ask(Q.algebraic(2.47)) is True | |
| assert ask(Q.algebraic(x), Q.transcendental(x)) is False | |
| assert ask(Q.transcendental(x), Q.algebraic(x)) is False | |
| def test_global(): | |
| """Test ask with global assumptions""" | |
| assert ask(Q.integer(x)) is None | |
| global_assumptions.add(Q.integer(x)) | |
| assert ask(Q.integer(x)) is True | |
| global_assumptions.clear() | |
| assert ask(Q.integer(x)) is None | |
| def test_custom_context(): | |
| """Test ask with custom assumptions context""" | |
| assert ask(Q.integer(x)) is None | |
| local_context = AssumptionsContext() | |
| local_context.add(Q.integer(x)) | |
| assert ask(Q.integer(x), context=local_context) is True | |
| assert ask(Q.integer(x)) is None | |
| def test_functions_in_assumptions(): | |
| assert ask(Q.negative(x), Q.real(x) >> Q.positive(x)) is False | |
| assert ask(Q.negative(x), Equivalent(Q.real(x), Q.positive(x))) is False | |
| assert ask(Q.negative(x), Xor(Q.real(x), Q.negative(x))) is False | |
| def test_composite_ask(): | |
| assert ask(Q.negative(x) & Q.integer(x), | |
| assumptions=Q.real(x) >> Q.positive(x)) is False | |
| def test_composite_proposition(): | |
| assert ask(True) is True | |
| assert ask(False) is False | |
| assert ask(~Q.negative(x), Q.positive(x)) is True | |
| assert ask(~Q.real(x), Q.commutative(x)) is None | |
| assert ask(Q.negative(x) & Q.integer(x), Q.positive(x)) is False | |
| assert ask(Q.negative(x) & Q.integer(x)) is None | |
| assert ask(Q.real(x) | Q.integer(x), Q.positive(x)) is True | |
| assert ask(Q.real(x) | Q.integer(x)) is None | |
| assert ask(Q.real(x) >> Q.positive(x), Q.negative(x)) is False | |
| assert ask(Implies( | |
| Q.real(x), Q.positive(x), evaluate=False), Q.negative(x)) is False | |
| assert ask(Implies(Q.real(x), Q.positive(x), evaluate=False)) is None | |
| assert ask(Equivalent(Q.integer(x), Q.even(x)), Q.even(x)) is True | |
| assert ask(Equivalent(Q.integer(x), Q.even(x))) is None | |
| assert ask(Equivalent(Q.positive(x), Q.integer(x)), Q.integer(x)) is None | |
| assert ask(Q.real(x) | Q.integer(x), Q.real(x) | Q.integer(x)) is True | |
| def test_tautology(): | |
| assert ask(Q.real(x) | ~Q.real(x)) is True | |
| assert ask(Q.real(x) & ~Q.real(x)) is False | |
| def test_composite_assumptions(): | |
| assert ask(Q.real(x), Q.real(x) & Q.real(y)) is True | |
| assert ask(Q.positive(x), Q.positive(x) | Q.positive(y)) is None | |
| assert ask(Q.positive(x), Q.real(x) >> Q.positive(y)) is None | |
| assert ask(Q.real(x), ~(Q.real(x) >> Q.real(y))) is True | |
| def test_key_extensibility(): | |
| """test that you can add keys to the ask system at runtime""" | |
| # make sure the key is not defined | |
| raises(AttributeError, lambda: ask(Q.my_key(x))) | |
| # Old handler system | |
| class MyAskHandler(AskHandler): | |
| def Symbol(expr, assumptions): | |
| return True | |
| try: | |
| with warns_deprecated_sympy(): | |
| register_handler('my_key', MyAskHandler) | |
| with warns_deprecated_sympy(): | |
| assert ask(Q.my_key(x)) is True | |
| with warns_deprecated_sympy(): | |
| assert ask(Q.my_key(x + 1)) is None | |
| finally: | |
| # We have to disable the stacklevel testing here because this raises | |
| # the warning twice from two different places | |
| with warns_deprecated_sympy(): | |
| remove_handler('my_key', MyAskHandler) | |
| del Q.my_key | |
| raises(AttributeError, lambda: ask(Q.my_key(x))) | |
| # New handler system | |
| class MyPredicate(Predicate): | |
| pass | |
| try: | |
| Q.my_key = MyPredicate() | |
| def _(expr, assumptions): | |
| return True | |
| assert ask(Q.my_key(x)) is True | |
| assert ask(Q.my_key(x+1)) is None | |
| finally: | |
| del Q.my_key | |
| raises(AttributeError, lambda: ask(Q.my_key(x))) | |
| def test_type_extensibility(): | |
| """test that new types can be added to the ask system at runtime | |
| """ | |
| from sympy.core import Basic | |
| class MyType(Basic): | |
| pass | |
| def _(expr, assumptions): | |
| return True | |
| assert ask(Q.prime(MyType())) is True | |
| def test_single_fact_lookup(): | |
| known_facts = And(Implies(Q.integer, Q.rational), | |
| Implies(Q.rational, Q.real), | |
| Implies(Q.real, Q.complex)) | |
| known_facts_keys = {Q.integer, Q.rational, Q.real, Q.complex} | |
| known_facts_cnf = to_cnf(known_facts) | |
| mapping = single_fact_lookup(known_facts_keys, known_facts_cnf) | |
| assert mapping[Q.rational] == {Q.real, Q.rational, Q.complex} | |
| def test_generate_known_facts_dict(): | |
| known_facts = And(Implies(Q.integer(x), Q.rational(x)), | |
| Implies(Q.rational(x), Q.real(x)), | |
| Implies(Q.real(x), Q.complex(x))) | |
| known_facts_keys = {Q.integer(x), Q.rational(x), Q.real(x), Q.complex(x)} | |
| assert generate_known_facts_dict(known_facts_keys, known_facts) == \ | |
| {Q.complex: ({Q.complex}, set()), | |
| Q.integer: ({Q.complex, Q.integer, Q.rational, Q.real}, set()), | |
| Q.rational: ({Q.complex, Q.rational, Q.real}, set()), | |
| Q.real: ({Q.complex, Q.real}, set())} | |
| def test_known_facts_consistent(): | |
| """"Test that ask_generated.py is up-to-date""" | |
| x = Symbol('x') | |
| fact = get_known_facts(x) | |
| # test cnf clauses of fact between unary predicates | |
| cnf = CNF.to_CNF(fact) | |
| clauses = set() | |
| clauses.update(frozenset(Literal(lit.arg.function, lit.is_Not) for lit in sorted(cl, key=str)) for cl in cnf.clauses) | |
| assert get_all_known_facts() == clauses | |
| # test dictionary of fact between unary predicates | |
| keys = [pred(x) for pred in get_known_facts_keys()] | |
| mapping = generate_known_facts_dict(keys, fact) | |
| assert get_known_facts_dict() == mapping | |
| def test_Add_queries(): | |
| assert ask(Q.prime(12345678901234567890 + (cos(1)**2 + sin(1)**2))) is True | |
| assert ask(Q.even(Add(S(2), S(2), evaluate=0))) is True | |
| assert ask(Q.prime(Add(S(2), S(2), evaluate=0))) is False | |
| assert ask(Q.integer(Add(S(2), S(2), evaluate=0))) is True | |
| def test_positive_assuming(): | |
| with assuming(Q.positive(x + 1)): | |
| assert not ask(Q.positive(x)) | |
| def test_issue_5421(): | |
| raises(TypeError, lambda: ask(pi/log(x), Q.real)) | |
| def test_issue_3906(): | |
| raises(TypeError, lambda: ask(Q.positive)) | |
| def test_issue_5833(): | |
| assert ask(Q.positive(log(x)**2), Q.positive(x)) is None | |
| assert ask(~Q.negative(log(x)**2), Q.positive(x)) is True | |
| def test_issue_6732(): | |
| raises(ValueError, lambda: ask(Q.positive(x), Q.positive(x) & Q.negative(x))) | |
| raises(ValueError, lambda: ask(Q.negative(x), Q.positive(x) & Q.negative(x))) | |
| def test_issue_7246(): | |
| assert ask(Q.positive(atan(p)), Q.positive(p)) is True | |
| assert ask(Q.positive(atan(p)), Q.negative(p)) is False | |
| assert ask(Q.positive(atan(p)), Q.zero(p)) is False | |
| assert ask(Q.positive(atan(x))) is None | |
| assert ask(Q.positive(asin(p)), Q.positive(p)) is None | |
| assert ask(Q.positive(asin(p)), Q.zero(p)) is None | |
| assert ask(Q.positive(asin(Rational(1, 7)))) is True | |
| assert ask(Q.positive(asin(x)), Q.positive(x) & Q.nonpositive(x - 1)) is True | |
| assert ask(Q.positive(asin(x)), Q.negative(x) & Q.nonnegative(x + 1)) is False | |
| assert ask(Q.positive(acos(p)), Q.positive(p)) is None | |
| assert ask(Q.positive(acos(Rational(1, 7)))) is True | |
| assert ask(Q.positive(acos(x)), Q.nonnegative(x + 1) & Q.nonpositive(x - 1)) is True | |
| assert ask(Q.positive(acos(x)), Q.nonnegative(x - 1)) is None | |
| assert ask(Q.positive(acot(x)), Q.positive(x)) is True | |
| assert ask(Q.positive(acot(x)), Q.real(x)) is True | |
| assert ask(Q.positive(acot(x)), Q.imaginary(x)) is False | |
| assert ask(Q.positive(acot(x))) is None | |
| def test_issue_7246_failing(): | |
| #Move this test to test_issue_7246 once | |
| #the new assumptions module is improved. | |
| assert ask(Q.positive(acos(x)), Q.zero(x)) is True | |
| def test_check_old_assumption(): | |
| x = symbols('x', real=True) | |
| assert ask(Q.real(x)) is True | |
| assert ask(Q.imaginary(x)) is False | |
| assert ask(Q.complex(x)) is True | |
| x = symbols('x', imaginary=True) | |
| assert ask(Q.real(x)) is False | |
| assert ask(Q.imaginary(x)) is True | |
| assert ask(Q.complex(x)) is True | |
| x = symbols('x', complex=True) | |
| assert ask(Q.real(x)) is None | |
| assert ask(Q.complex(x)) is True | |
| x = symbols('x', positive=True) | |
| assert ask(Q.positive(x)) is True | |
| assert ask(Q.negative(x)) is False | |
| assert ask(Q.real(x)) is True | |
| x = symbols('x', commutative=False) | |
| assert ask(Q.commutative(x)) is False | |
| x = symbols('x', negative=True) | |
| assert ask(Q.positive(x)) is False | |
| assert ask(Q.negative(x)) is True | |
| x = symbols('x', nonnegative=True) | |
| assert ask(Q.negative(x)) is False | |
| assert ask(Q.positive(x)) is None | |
| assert ask(Q.zero(x)) is None | |
| x = symbols('x', finite=True) | |
| assert ask(Q.finite(x)) is True | |
| x = symbols('x', prime=True) | |
| assert ask(Q.prime(x)) is True | |
| assert ask(Q.composite(x)) is False | |
| x = symbols('x', composite=True) | |
| assert ask(Q.prime(x)) is False | |
| assert ask(Q.composite(x)) is True | |
| x = symbols('x', even=True) | |
| assert ask(Q.even(x)) is True | |
| assert ask(Q.odd(x)) is False | |
| x = symbols('x', odd=True) | |
| assert ask(Q.even(x)) is False | |
| assert ask(Q.odd(x)) is True | |
| x = symbols('x', nonzero=True) | |
| assert ask(Q.nonzero(x)) is True | |
| assert ask(Q.zero(x)) is False | |
| x = symbols('x', zero=True) | |
| assert ask(Q.zero(x)) is True | |
| x = symbols('x', integer=True) | |
| assert ask(Q.integer(x)) is True | |
| x = symbols('x', rational=True) | |
| assert ask(Q.rational(x)) is True | |
| assert ask(Q.irrational(x)) is False | |
| x = symbols('x', irrational=True) | |
| assert ask(Q.irrational(x)) is True | |
| assert ask(Q.rational(x)) is False | |
| def test_issue_9636(): | |
| assert ask(Q.integer(1.0)) is None | |
| assert ask(Q.prime(3.0)) is None | |
| assert ask(Q.composite(4.0)) is None | |
| assert ask(Q.even(2.0)) is None | |
| assert ask(Q.odd(3.0)) is None | |
| def test_autosimp_used_to_fail(): | |
| # See issue #9807 | |
| assert ask(Q.imaginary(0**I)) is None | |
| assert ask(Q.imaginary(0**(-I))) is None | |
| assert ask(Q.real(0**I)) is None | |
| assert ask(Q.real(0**(-I))) is None | |
| def test_custom_AskHandler(): | |
| from sympy.logic.boolalg import conjuncts | |
| # Old handler system | |
| class MersenneHandler(AskHandler): | |
| def Integer(expr, assumptions): | |
| if ask(Q.integer(log(expr + 1, 2))): | |
| return True | |
| def Symbol(expr, assumptions): | |
| if expr in conjuncts(assumptions): | |
| return True | |
| try: | |
| with warns_deprecated_sympy(): | |
| register_handler('mersenne', MersenneHandler) | |
| n = Symbol('n', integer=True) | |
| with warns_deprecated_sympy(): | |
| assert ask(Q.mersenne(7)) | |
| with warns_deprecated_sympy(): | |
| assert ask(Q.mersenne(n), Q.mersenne(n)) | |
| finally: | |
| del Q.mersenne | |
| # New handler system | |
| class MersennePredicate(Predicate): | |
| pass | |
| try: | |
| Q.mersenne = MersennePredicate() | |
| def _(expr, assumptions): | |
| if ask(Q.integer(log(expr + 1, 2))): | |
| return True | |
| def _(expr, assumptions): | |
| if expr in conjuncts(assumptions): | |
| return True | |
| assert ask(Q.mersenne(7)) | |
| assert ask(Q.mersenne(n), Q.mersenne(n)) | |
| finally: | |
| del Q.mersenne | |
| def test_polyadic_predicate(): | |
| class SexyPredicate(Predicate): | |
| pass | |
| try: | |
| Q.sexyprime = SexyPredicate() | |
| def _(int1, int2, assumptions): | |
| args = sorted([int1, int2]) | |
| if not all(ask(Q.prime(a), assumptions) for a in args): | |
| return False | |
| return args[1] - args[0] == 6 | |
| def _(int1, int2, int3, assumptions): | |
| args = sorted([int1, int2, int3]) | |
| if not all(ask(Q.prime(a), assumptions) for a in args): | |
| return False | |
| return args[2] - args[1] == 6 and args[1] - args[0] == 6 | |
| assert ask(Q.sexyprime(5, 11)) | |
| assert ask(Q.sexyprime(7, 13, 19)) | |
| finally: | |
| del Q.sexyprime | |
| def test_Predicate_handler_is_unique(): | |
| # Undefined predicate does not have a handler | |
| assert Predicate('mypredicate').handler is None | |
| # Handler of defined predicate is unique to the class | |
| class MyPredicate(Predicate): | |
| pass | |
| mp1 = MyPredicate(Str('mp1')) | |
| mp2 = MyPredicate(Str('mp2')) | |
| assert mp1.handler is mp2.handler | |
| def test_relational(): | |
| assert ask(Q.eq(x, 0), Q.zero(x)) | |
| assert not ask(Q.eq(x, 0), Q.nonzero(x)) | |
| assert not ask(Q.ne(x, 0), Q.zero(x)) | |
| assert ask(Q.ne(x, 0), Q.nonzero(x)) | |
| def test_issue_25221(): | |
| assert ask(Q.transcendental(x), Q.algebraic(x) | Q.positive(y,y)) is None | |
| assert ask(Q.transcendental(x), Q.algebraic(x) | (0 > y)) is None | |
| assert ask(Q.transcendental(x), Q.algebraic(x) | Q.gt(0,y)) is None | |