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773 lines
23 KiB
773 lines
23 KiB
"""
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Handlers for predicates related to set membership: integer, rational, etc.
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"""
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from sympy.assumptions import Q, ask
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from sympy.core import Add, Basic, Expr, Mul, Pow, S
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from sympy.core.numbers import (AlgebraicNumber, ComplexInfinity, Exp1, Float,
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GoldenRatio, ImaginaryUnit, Infinity, Integer, NaN, NegativeInfinity,
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Number, NumberSymbol, Pi, pi, Rational, TribonacciConstant, E)
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from sympy.core.logic import fuzzy_bool
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from sympy.functions import (Abs, acos, acot, asin, atan, cos, cot, exp, im,
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log, re, sin, tan)
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from sympy.core.numbers import I
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from sympy.core.relational import Eq
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from sympy.functions.elementary.complexes import conjugate
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from sympy.matrices import Determinant, MatrixBase, Trace
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from sympy.matrices.expressions.matexpr import MatrixElement
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from sympy.multipledispatch import MDNotImplementedError
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from .common import test_closed_group
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from ..predicates.sets import (IntegerPredicate, RationalPredicate,
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IrrationalPredicate, RealPredicate, ExtendedRealPredicate,
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HermitianPredicate, ComplexPredicate, ImaginaryPredicate,
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AntihermitianPredicate, AlgebraicPredicate)
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# IntegerPredicate
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def _IntegerPredicate_number(expr, assumptions):
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# helper function
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try:
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i = int(expr.round())
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if not (expr - i).equals(0):
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raise TypeError
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return True
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except TypeError:
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return False
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@IntegerPredicate.register_many(int, Integer) # type:ignore
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def _(expr, assumptions):
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return True
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@IntegerPredicate.register_many(Exp1, GoldenRatio, ImaginaryUnit, Infinity,
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NegativeInfinity, Pi, Rational, TribonacciConstant)
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def _(expr, assumptions):
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return False
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@IntegerPredicate.register(Expr)
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def _(expr, assumptions):
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ret = expr.is_integer
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if ret is None:
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raise MDNotImplementedError
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return ret
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@IntegerPredicate.register_many(Add, Pow)
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def _(expr, assumptions):
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"""
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* Integer + Integer -> Integer
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* Integer + !Integer -> !Integer
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* !Integer + !Integer -> ?
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"""
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if expr.is_number:
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return _IntegerPredicate_number(expr, assumptions)
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return test_closed_group(expr, assumptions, Q.integer)
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@IntegerPredicate.register(Mul)
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def _(expr, assumptions):
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"""
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* Integer*Integer -> Integer
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* Integer*Irrational -> !Integer
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* Odd/Even -> !Integer
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* Integer*Rational -> ?
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"""
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if expr.is_number:
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return _IntegerPredicate_number(expr, assumptions)
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_output = True
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for arg in expr.args:
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if not ask(Q.integer(arg), assumptions):
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if arg.is_Rational:
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if arg.q == 2:
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return ask(Q.even(2*expr), assumptions)
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if ~(arg.q & 1):
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return None
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elif ask(Q.irrational(arg), assumptions):
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if _output:
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_output = False
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else:
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return
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else:
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return
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return _output
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@IntegerPredicate.register(Abs)
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def _(expr, assumptions):
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return ask(Q.integer(expr.args[0]), assumptions)
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@IntegerPredicate.register_many(Determinant, MatrixElement, Trace)
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def _(expr, assumptions):
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return ask(Q.integer_elements(expr.args[0]), assumptions)
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# RationalPredicate
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@RationalPredicate.register(Rational)
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def _(expr, assumptions):
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return True
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@RationalPredicate.register(Float)
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def _(expr, assumptions):
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return None
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@RationalPredicate.register_many(Exp1, GoldenRatio, ImaginaryUnit, Infinity,
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NegativeInfinity, Pi, TribonacciConstant)
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def _(expr, assumptions):
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return False
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@RationalPredicate.register(Expr)
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def _(expr, assumptions):
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ret = expr.is_rational
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if ret is None:
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raise MDNotImplementedError
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return ret
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@RationalPredicate.register_many(Add, Mul)
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def _(expr, assumptions):
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"""
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* Rational + Rational -> Rational
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* Rational + !Rational -> !Rational
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* !Rational + !Rational -> ?
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"""
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if expr.is_number:
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if expr.as_real_imag()[1]:
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return False
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return test_closed_group(expr, assumptions, Q.rational)
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@RationalPredicate.register(Pow)
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def _(expr, assumptions):
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"""
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* Rational ** Integer -> Rational
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* Irrational ** Rational -> Irrational
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* Rational ** Irrational -> ?
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"""
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if expr.base == E:
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x = expr.exp
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if ask(Q.rational(x), assumptions):
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return ask(~Q.nonzero(x), assumptions)
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return
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if ask(Q.integer(expr.exp), assumptions):
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return ask(Q.rational(expr.base), assumptions)
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elif ask(Q.rational(expr.exp), assumptions):
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if ask(Q.prime(expr.base), assumptions):
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return False
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@RationalPredicate.register_many(asin, atan, cos, sin, tan)
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def _(expr, assumptions):
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x = expr.args[0]
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if ask(Q.rational(x), assumptions):
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return ask(~Q.nonzero(x), assumptions)
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@RationalPredicate.register(exp)
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def _(expr, assumptions):
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x = expr.exp
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if ask(Q.rational(x), assumptions):
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return ask(~Q.nonzero(x), assumptions)
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@RationalPredicate.register_many(acot, cot)
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def _(expr, assumptions):
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x = expr.args[0]
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if ask(Q.rational(x), assumptions):
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return False
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@RationalPredicate.register_many(acos, log)
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def _(expr, assumptions):
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x = expr.args[0]
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if ask(Q.rational(x), assumptions):
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return ask(~Q.nonzero(x - 1), assumptions)
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# IrrationalPredicate
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@IrrationalPredicate.register(Expr)
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def _(expr, assumptions):
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ret = expr.is_irrational
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if ret is None:
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raise MDNotImplementedError
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return ret
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@IrrationalPredicate.register(Basic)
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def _(expr, assumptions):
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_real = ask(Q.real(expr), assumptions)
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if _real:
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_rational = ask(Q.rational(expr), assumptions)
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if _rational is None:
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return None
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return not _rational
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else:
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return _real
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# RealPredicate
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def _RealPredicate_number(expr, assumptions):
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# let as_real_imag() work first since the expression may
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# be simpler to evaluate
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i = expr.as_real_imag()[1].evalf(2)
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if i._prec != 1:
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return not i
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# allow None to be returned if we couldn't show for sure
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# that i was 0
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@RealPredicate.register_many(Abs, Exp1, Float, GoldenRatio, im, Pi, Rational,
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re, TribonacciConstant)
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def _(expr, assumptions):
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return True
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@RealPredicate.register_many(ImaginaryUnit, Infinity, NegativeInfinity)
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def _(expr, assumptions):
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return False
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@RealPredicate.register(Expr)
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def _(expr, assumptions):
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ret = expr.is_real
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if ret is None:
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raise MDNotImplementedError
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return ret
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@RealPredicate.register(Add)
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def _(expr, assumptions):
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"""
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* Real + Real -> Real
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* Real + (Complex & !Real) -> !Real
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"""
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if expr.is_number:
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return _RealPredicate_number(expr, assumptions)
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return test_closed_group(expr, assumptions, Q.real)
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@RealPredicate.register(Mul)
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def _(expr, assumptions):
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"""
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* Real*Real -> Real
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* Real*Imaginary -> !Real
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* Imaginary*Imaginary -> Real
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"""
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if expr.is_number:
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return _RealPredicate_number(expr, assumptions)
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result = True
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for arg in expr.args:
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if ask(Q.real(arg), assumptions):
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pass
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elif ask(Q.imaginary(arg), assumptions):
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result = result ^ True
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else:
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break
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else:
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return result
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@RealPredicate.register(Pow)
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def _(expr, assumptions):
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"""
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* Real**Integer -> Real
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* Positive**Real -> Real
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* Real**(Integer/Even) -> Real if base is nonnegative
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* Real**(Integer/Odd) -> Real
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* Imaginary**(Integer/Even) -> Real
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* Imaginary**(Integer/Odd) -> not Real
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* Imaginary**Real -> ? since Real could be 0 (giving real)
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or 1 (giving imaginary)
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* b**Imaginary -> Real if log(b) is imaginary and b != 0
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and exponent != integer multiple of
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I*pi/log(b)
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* Real**Real -> ? e.g. sqrt(-1) is imaginary and
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sqrt(2) is not
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"""
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if expr.is_number:
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return _RealPredicate_number(expr, assumptions)
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if expr.base == E:
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return ask(
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Q.integer(expr.exp/I/pi) | Q.real(expr.exp), assumptions
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)
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if expr.base.func == exp or (expr.base.is_Pow and expr.base.base == E):
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if ask(Q.imaginary(expr.base.exp), assumptions):
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if ask(Q.imaginary(expr.exp), assumptions):
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return True
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# If the i = (exp's arg)/(I*pi) is an integer or half-integer
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# multiple of I*pi then 2*i will be an integer. In addition,
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# exp(i*I*pi) = (-1)**i so the overall realness of the expr
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# can be determined by replacing exp(i*I*pi) with (-1)**i.
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i = expr.base.exp/I/pi
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if ask(Q.integer(2*i), assumptions):
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return ask(Q.real((S.NegativeOne**i)**expr.exp), assumptions)
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return
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if ask(Q.imaginary(expr.base), assumptions):
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if ask(Q.integer(expr.exp), assumptions):
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odd = ask(Q.odd(expr.exp), assumptions)
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if odd is not None:
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return not odd
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return
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if ask(Q.imaginary(expr.exp), assumptions):
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imlog = ask(Q.imaginary(log(expr.base)), assumptions)
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if imlog is not None:
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# I**i -> real, log(I) is imag;
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# (2*I)**i -> complex, log(2*I) is not imag
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return imlog
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if ask(Q.real(expr.base), assumptions):
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if ask(Q.real(expr.exp), assumptions):
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if expr.exp.is_Rational and \
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ask(Q.even(expr.exp.q), assumptions):
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return ask(Q.positive(expr.base), assumptions)
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elif ask(Q.integer(expr.exp), assumptions):
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return True
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elif ask(Q.positive(expr.base), assumptions):
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return True
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elif ask(Q.negative(expr.base), assumptions):
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return False
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@RealPredicate.register_many(cos, sin)
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def _(expr, assumptions):
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if ask(Q.real(expr.args[0]), assumptions):
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return True
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@RealPredicate.register(exp)
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def _(expr, assumptions):
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return ask(
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Q.integer(expr.exp/I/pi) | Q.real(expr.exp), assumptions
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)
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@RealPredicate.register(log)
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def _(expr, assumptions):
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return ask(Q.positive(expr.args[0]), assumptions)
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@RealPredicate.register_many(Determinant, MatrixElement, Trace)
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def _(expr, assumptions):
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return ask(Q.real_elements(expr.args[0]), assumptions)
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# ExtendedRealPredicate
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@ExtendedRealPredicate.register(object)
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def _(expr, assumptions):
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return ask(Q.negative_infinite(expr)
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| Q.negative(expr)
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| Q.zero(expr)
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| Q.positive(expr)
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| Q.positive_infinite(expr),
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assumptions)
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@ExtendedRealPredicate.register_many(Infinity, NegativeInfinity)
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def _(expr, assumptions):
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return True
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@ExtendedRealPredicate.register_many(Add, Mul, Pow) # type:ignore
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def _(expr, assumptions):
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return test_closed_group(expr, assumptions, Q.extended_real)
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# HermitianPredicate
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@HermitianPredicate.register(object) # type:ignore
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def _(expr, assumptions):
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if isinstance(expr, MatrixBase):
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return None
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return ask(Q.real(expr), assumptions)
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@HermitianPredicate.register(Add) # type:ignore
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def _(expr, assumptions):
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"""
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* Hermitian + Hermitian -> Hermitian
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* Hermitian + !Hermitian -> !Hermitian
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"""
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if expr.is_number:
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raise MDNotImplementedError
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return test_closed_group(expr, assumptions, Q.hermitian)
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@HermitianPredicate.register(Mul) # type:ignore
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def _(expr, assumptions):
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"""
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As long as there is at most only one noncommutative term:
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* Hermitian*Hermitian -> Hermitian
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* Hermitian*Antihermitian -> !Hermitian
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* Antihermitian*Antihermitian -> Hermitian
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"""
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if expr.is_number:
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raise MDNotImplementedError
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nccount = 0
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result = True
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for arg in expr.args:
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if ask(Q.antihermitian(arg), assumptions):
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result = result ^ True
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elif not ask(Q.hermitian(arg), assumptions):
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break
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if ask(~Q.commutative(arg), assumptions):
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nccount += 1
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if nccount > 1:
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break
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else:
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return result
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@HermitianPredicate.register(Pow) # type:ignore
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def _(expr, assumptions):
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"""
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* Hermitian**Integer -> Hermitian
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"""
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if expr.is_number:
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raise MDNotImplementedError
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if expr.base == E:
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if ask(Q.hermitian(expr.exp), assumptions):
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return True
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raise MDNotImplementedError
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if ask(Q.hermitian(expr.base), assumptions):
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if ask(Q.integer(expr.exp), assumptions):
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return True
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raise MDNotImplementedError
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@HermitianPredicate.register_many(cos, sin) # type:ignore
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def _(expr, assumptions):
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if ask(Q.hermitian(expr.args[0]), assumptions):
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return True
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raise MDNotImplementedError
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@HermitianPredicate.register(exp) # type:ignore
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def _(expr, assumptions):
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if ask(Q.hermitian(expr.exp), assumptions):
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return True
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raise MDNotImplementedError
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@HermitianPredicate.register(MatrixBase) # type:ignore
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def _(mat, assumptions):
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rows, cols = mat.shape
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ret_val = True
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for i in range(rows):
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for j in range(i, cols):
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cond = fuzzy_bool(Eq(mat[i, j], conjugate(mat[j, i])))
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if cond is None:
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ret_val = None
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if cond == False:
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return False
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if ret_val is None:
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raise MDNotImplementedError
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return ret_val
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# ComplexPredicate
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@ComplexPredicate.register_many(Abs, cos, exp, im, ImaginaryUnit, log, Number, # type:ignore
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NumberSymbol, re, sin)
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def _(expr, assumptions):
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return True
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@ComplexPredicate.register_many(Infinity, NegativeInfinity) # type:ignore
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def _(expr, assumptions):
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return False
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@ComplexPredicate.register(Expr) # type:ignore
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def _(expr, assumptions):
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ret = expr.is_complex
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if ret is None:
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raise MDNotImplementedError
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return ret
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@ComplexPredicate.register_many(Add, Mul) # type:ignore
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def _(expr, assumptions):
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return test_closed_group(expr, assumptions, Q.complex)
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@ComplexPredicate.register(Pow) # type:ignore
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def _(expr, assumptions):
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if expr.base == E:
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return True
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return test_closed_group(expr, assumptions, Q.complex)
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@ComplexPredicate.register_many(Determinant, MatrixElement, Trace) # type:ignore
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def _(expr, assumptions):
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return ask(Q.complex_elements(expr.args[0]), assumptions)
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@ComplexPredicate.register(NaN) # type:ignore
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def _(expr, assumptions):
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return None
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# ImaginaryPredicate
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def _Imaginary_number(expr, assumptions):
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# let as_real_imag() work first since the expression may
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# be simpler to evaluate
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r = expr.as_real_imag()[0].evalf(2)
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if r._prec != 1:
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return not r
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# allow None to be returned if we couldn't show for sure
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# that r was 0
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@ImaginaryPredicate.register(ImaginaryUnit) # type:ignore
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def _(expr, assumptions):
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return True
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@ImaginaryPredicate.register(Expr) # type:ignore
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def _(expr, assumptions):
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ret = expr.is_imaginary
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if ret is None:
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raise MDNotImplementedError
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return ret
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@ImaginaryPredicate.register(Add) # type:ignore
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def _(expr, assumptions):
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"""
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* Imaginary + Imaginary -> Imaginary
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* Imaginary + Complex -> ?
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* Imaginary + Real -> !Imaginary
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"""
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if expr.is_number:
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return _Imaginary_number(expr, assumptions)
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reals = 0
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for arg in expr.args:
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if ask(Q.imaginary(arg), assumptions):
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pass
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elif ask(Q.real(arg), assumptions):
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reals += 1
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else:
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break
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else:
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if reals == 0:
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return True
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if reals in (1, len(expr.args)):
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# two reals could sum 0 thus giving an imaginary
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return False
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@ImaginaryPredicate.register(Mul) # type:ignore
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def _(expr, assumptions):
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"""
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* Real*Imaginary -> Imaginary
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* Imaginary*Imaginary -> Real
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"""
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if expr.is_number:
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return _Imaginary_number(expr, assumptions)
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result = False
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reals = 0
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for arg in expr.args:
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|
if ask(Q.imaginary(arg), assumptions):
|
|
result = result ^ True
|
|
elif not ask(Q.real(arg), assumptions):
|
|
break
|
|
else:
|
|
if reals == len(expr.args):
|
|
return False
|
|
return result
|
|
|
|
@ImaginaryPredicate.register(Pow) # type:ignore
|
|
def _(expr, assumptions):
|
|
"""
|
|
* Imaginary**Odd -> Imaginary
|
|
* Imaginary**Even -> Real
|
|
* b**Imaginary -> !Imaginary if exponent is an integer
|
|
multiple of I*pi/log(b)
|
|
* Imaginary**Real -> ?
|
|
* Positive**Real -> Real
|
|
* Negative**Integer -> Real
|
|
* Negative**(Integer/2) -> Imaginary
|
|
* Negative**Real -> not Imaginary if exponent is not Rational
|
|
"""
|
|
if expr.is_number:
|
|
return _Imaginary_number(expr, assumptions)
|
|
|
|
if expr.base == E:
|
|
a = expr.exp/I/pi
|
|
return ask(Q.integer(2*a) & ~Q.integer(a), assumptions)
|
|
|
|
if expr.base.func == exp or (expr.base.is_Pow and expr.base.base == E):
|
|
if ask(Q.imaginary(expr.base.exp), assumptions):
|
|
if ask(Q.imaginary(expr.exp), assumptions):
|
|
return False
|
|
i = expr.base.exp/I/pi
|
|
if ask(Q.integer(2*i), assumptions):
|
|
return ask(Q.imaginary((S.NegativeOne**i)**expr.exp), assumptions)
|
|
|
|
if ask(Q.imaginary(expr.base), assumptions):
|
|
if ask(Q.integer(expr.exp), assumptions):
|
|
odd = ask(Q.odd(expr.exp), assumptions)
|
|
if odd is not None:
|
|
return odd
|
|
return
|
|
|
|
if ask(Q.imaginary(expr.exp), assumptions):
|
|
imlog = ask(Q.imaginary(log(expr.base)), assumptions)
|
|
if imlog is not None:
|
|
# I**i -> real; (2*I)**i -> complex ==> not imaginary
|
|
return False
|
|
|
|
if ask(Q.real(expr.base) & Q.real(expr.exp), assumptions):
|
|
if ask(Q.positive(expr.base), assumptions):
|
|
return False
|
|
else:
|
|
rat = ask(Q.rational(expr.exp), assumptions)
|
|
if not rat:
|
|
return rat
|
|
if ask(Q.integer(expr.exp), assumptions):
|
|
return False
|
|
else:
|
|
half = ask(Q.integer(2*expr.exp), assumptions)
|
|
if half:
|
|
return ask(Q.negative(expr.base), assumptions)
|
|
return half
|
|
|
|
@ImaginaryPredicate.register(log) # type:ignore
|
|
def _(expr, assumptions):
|
|
if ask(Q.real(expr.args[0]), assumptions):
|
|
if ask(Q.positive(expr.args[0]), assumptions):
|
|
return False
|
|
return
|
|
# XXX it should be enough to do
|
|
# return ask(Q.nonpositive(expr.args[0]), assumptions)
|
|
# but ask(Q.nonpositive(exp(x)), Q.imaginary(x)) -> None;
|
|
# it should return True since exp(x) will be either 0 or complex
|
|
if expr.args[0].func == exp or (expr.args[0].is_Pow and expr.args[0].base == E):
|
|
if expr.args[0].exp in [I, -I]:
|
|
return True
|
|
im = ask(Q.imaginary(expr.args[0]), assumptions)
|
|
if im is False:
|
|
return False
|
|
|
|
@ImaginaryPredicate.register(exp) # type:ignore
|
|
def _(expr, assumptions):
|
|
a = expr.exp/I/pi
|
|
return ask(Q.integer(2*a) & ~Q.integer(a), assumptions)
|
|
|
|
@ImaginaryPredicate.register_many(Number, NumberSymbol) # type:ignore
|
|
def _(expr, assumptions):
|
|
return not (expr.as_real_imag()[1] == 0)
|
|
|
|
@ImaginaryPredicate.register(NaN) # type:ignore
|
|
def _(expr, assumptions):
|
|
return None
|
|
|
|
|
|
# AntihermitianPredicate
|
|
|
|
@AntihermitianPredicate.register(object) # type:ignore
|
|
def _(expr, assumptions):
|
|
if isinstance(expr, MatrixBase):
|
|
return None
|
|
if ask(Q.zero(expr), assumptions):
|
|
return True
|
|
return ask(Q.imaginary(expr), assumptions)
|
|
|
|
@AntihermitianPredicate.register(Add) # type:ignore
|
|
def _(expr, assumptions):
|
|
"""
|
|
* Antihermitian + Antihermitian -> Antihermitian
|
|
* Antihermitian + !Antihermitian -> !Antihermitian
|
|
"""
|
|
if expr.is_number:
|
|
raise MDNotImplementedError
|
|
return test_closed_group(expr, assumptions, Q.antihermitian)
|
|
|
|
@AntihermitianPredicate.register(Mul) # type:ignore
|
|
def _(expr, assumptions):
|
|
"""
|
|
As long as there is at most only one noncommutative term:
|
|
|
|
* Hermitian*Hermitian -> !Antihermitian
|
|
* Hermitian*Antihermitian -> Antihermitian
|
|
* Antihermitian*Antihermitian -> !Antihermitian
|
|
"""
|
|
if expr.is_number:
|
|
raise MDNotImplementedError
|
|
nccount = 0
|
|
result = False
|
|
for arg in expr.args:
|
|
if ask(Q.antihermitian(arg), assumptions):
|
|
result = result ^ True
|
|
elif not ask(Q.hermitian(arg), assumptions):
|
|
break
|
|
if ask(~Q.commutative(arg), assumptions):
|
|
nccount += 1
|
|
if nccount > 1:
|
|
break
|
|
else:
|
|
return result
|
|
|
|
@AntihermitianPredicate.register(Pow) # type:ignore
|
|
def _(expr, assumptions):
|
|
"""
|
|
* Hermitian**Integer -> !Antihermitian
|
|
* Antihermitian**Even -> !Antihermitian
|
|
* Antihermitian**Odd -> Antihermitian
|
|
"""
|
|
if expr.is_number:
|
|
raise MDNotImplementedError
|
|
if ask(Q.hermitian(expr.base), assumptions):
|
|
if ask(Q.integer(expr.exp), assumptions):
|
|
return False
|
|
elif ask(Q.antihermitian(expr.base), assumptions):
|
|
if ask(Q.even(expr.exp), assumptions):
|
|
return False
|
|
elif ask(Q.odd(expr.exp), assumptions):
|
|
return True
|
|
raise MDNotImplementedError
|
|
|
|
@AntihermitianPredicate.register(MatrixBase) # type:ignore
|
|
def _(mat, assumptions):
|
|
rows, cols = mat.shape
|
|
ret_val = True
|
|
for i in range(rows):
|
|
for j in range(i, cols):
|
|
cond = fuzzy_bool(Eq(mat[i, j], -conjugate(mat[j, i])))
|
|
if cond is None:
|
|
ret_val = None
|
|
if cond == False:
|
|
return False
|
|
if ret_val is None:
|
|
raise MDNotImplementedError
|
|
return ret_val
|
|
|
|
|
|
# AlgebraicPredicate
|
|
|
|
@AlgebraicPredicate.register_many(AlgebraicNumber, Float, GoldenRatio, # type:ignore
|
|
ImaginaryUnit, TribonacciConstant)
|
|
def _(expr, assumptions):
|
|
return True
|
|
|
|
@AlgebraicPredicate.register_many(ComplexInfinity, Exp1, Infinity, # type:ignore
|
|
NegativeInfinity, Pi)
|
|
def _(expr, assumptions):
|
|
return False
|
|
|
|
@AlgebraicPredicate.register_many(Add, Mul) # type:ignore
|
|
def _(expr, assumptions):
|
|
return test_closed_group(expr, assumptions, Q.algebraic)
|
|
|
|
@AlgebraicPredicate.register(Pow) # type:ignore
|
|
def _(expr, assumptions):
|
|
if expr.base == E:
|
|
if ask(Q.algebraic(expr.exp), assumptions):
|
|
return ask(~Q.nonzero(expr.exp), assumptions)
|
|
return
|
|
return expr.exp.is_Rational and ask(Q.algebraic(expr.base), assumptions)
|
|
|
|
@AlgebraicPredicate.register(Rational) # type:ignore
|
|
def _(expr, assumptions):
|
|
return expr.q != 0
|
|
|
|
@AlgebraicPredicate.register_many(asin, atan, cos, sin, tan) # type:ignore
|
|
def _(expr, assumptions):
|
|
x = expr.args[0]
|
|
if ask(Q.algebraic(x), assumptions):
|
|
return ask(~Q.nonzero(x), assumptions)
|
|
|
|
@AlgebraicPredicate.register(exp) # type:ignore
|
|
def _(expr, assumptions):
|
|
x = expr.exp
|
|
if ask(Q.algebraic(x), assumptions):
|
|
return ask(~Q.nonzero(x), assumptions)
|
|
|
|
@AlgebraicPredicate.register_many(acot, cot) # type:ignore
|
|
def _(expr, assumptions):
|
|
x = expr.args[0]
|
|
if ask(Q.algebraic(x), assumptions):
|
|
return False
|
|
|
|
@AlgebraicPredicate.register_many(acos, log) # type:ignore
|
|
def _(expr, assumptions):
|
|
x = expr.args[0]
|
|
if ask(Q.algebraic(x), assumptions):
|
|
return ask(~Q.nonzero(x - 1), assumptions)
|