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406 lines
12 KiB
406 lines
12 KiB
from __future__ import annotations
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from typing import Callable
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from sympy.core import S, Add, Expr, Basic, Mul, Pow, Rational
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from sympy.core.logic import fuzzy_not
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from sympy.logic.boolalg import Boolean
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from sympy.assumptions import ask, Q # type: ignore
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def refine(expr, assumptions=True):
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"""
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Simplify an expression using assumptions.
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Explanation
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===========
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Unlike :func:`~.simplify()` which performs structural simplification
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without any assumption, this function transforms the expression into
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the form which is only valid under certain assumptions. Note that
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``simplify()`` is generally not done in refining process.
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Refining boolean expression involves reducing it to ``S.true`` or
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``S.false``. Unlike :func:`~.ask()`, the expression will not be reduced
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if the truth value cannot be determined.
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Examples
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========
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>>> from sympy import refine, sqrt, Q
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>>> from sympy.abc import x
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>>> refine(sqrt(x**2), Q.real(x))
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Abs(x)
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>>> refine(sqrt(x**2), Q.positive(x))
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x
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>>> refine(Q.real(x), Q.positive(x))
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True
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>>> refine(Q.positive(x), Q.real(x))
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Q.positive(x)
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See Also
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========
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sympy.simplify.simplify.simplify : Structural simplification without assumptions.
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sympy.assumptions.ask.ask : Query for boolean expressions using assumptions.
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"""
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if not isinstance(expr, Basic):
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return expr
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if not expr.is_Atom:
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args = [refine(arg, assumptions) for arg in expr.args]
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# TODO: this will probably not work with Integral or Polynomial
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expr = expr.func(*args)
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if hasattr(expr, '_eval_refine'):
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ref_expr = expr._eval_refine(assumptions)
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if ref_expr is not None:
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return ref_expr
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name = expr.__class__.__name__
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handler = handlers_dict.get(name, None)
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if handler is None:
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return expr
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new_expr = handler(expr, assumptions)
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if (new_expr is None) or (expr == new_expr):
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return expr
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if not isinstance(new_expr, Expr):
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return new_expr
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return refine(new_expr, assumptions)
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def refine_abs(expr, assumptions):
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"""
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Handler for the absolute value.
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Examples
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========
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>>> from sympy import Q, Abs
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>>> from sympy.assumptions.refine import refine_abs
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>>> from sympy.abc import x
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>>> refine_abs(Abs(x), Q.real(x))
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>>> refine_abs(Abs(x), Q.positive(x))
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x
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>>> refine_abs(Abs(x), Q.negative(x))
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-x
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"""
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from sympy.functions.elementary.complexes import Abs
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arg = expr.args[0]
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if ask(Q.real(arg), assumptions) and \
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fuzzy_not(ask(Q.negative(arg), assumptions)):
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# if it's nonnegative
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return arg
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if ask(Q.negative(arg), assumptions):
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return -arg
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# arg is Mul
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if isinstance(arg, Mul):
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r = [refine(abs(a), assumptions) for a in arg.args]
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non_abs = []
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in_abs = []
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for i in r:
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if isinstance(i, Abs):
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in_abs.append(i.args[0])
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else:
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non_abs.append(i)
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return Mul(*non_abs) * Abs(Mul(*in_abs))
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def refine_Pow(expr, assumptions):
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"""
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Handler for instances of Pow.
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Examples
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========
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>>> from sympy import Q
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>>> from sympy.assumptions.refine import refine_Pow
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>>> from sympy.abc import x,y,z
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>>> refine_Pow((-1)**x, Q.real(x))
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>>> refine_Pow((-1)**x, Q.even(x))
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1
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>>> refine_Pow((-1)**x, Q.odd(x))
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-1
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For powers of -1, even parts of the exponent can be simplified:
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>>> refine_Pow((-1)**(x+y), Q.even(x))
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(-1)**y
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>>> refine_Pow((-1)**(x+y+z), Q.odd(x) & Q.odd(z))
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(-1)**y
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>>> refine_Pow((-1)**(x+y+2), Q.odd(x))
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(-1)**(y + 1)
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>>> refine_Pow((-1)**(x+3), True)
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(-1)**(x + 1)
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"""
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from sympy.functions.elementary.complexes import Abs
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from sympy.functions import sign
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if isinstance(expr.base, Abs):
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if ask(Q.real(expr.base.args[0]), assumptions) and \
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ask(Q.even(expr.exp), assumptions):
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return expr.base.args[0] ** expr.exp
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if ask(Q.real(expr.base), assumptions):
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if expr.base.is_number:
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if ask(Q.even(expr.exp), assumptions):
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return abs(expr.base) ** expr.exp
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if ask(Q.odd(expr.exp), assumptions):
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return sign(expr.base) * abs(expr.base) ** expr.exp
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if isinstance(expr.exp, Rational):
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if isinstance(expr.base, Pow):
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return abs(expr.base.base) ** (expr.base.exp * expr.exp)
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if expr.base is S.NegativeOne:
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if expr.exp.is_Add:
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old = expr
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# For powers of (-1) we can remove
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# - even terms
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# - pairs of odd terms
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# - a single odd term + 1
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# - A numerical constant N can be replaced with mod(N,2)
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coeff, terms = expr.exp.as_coeff_add()
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terms = set(terms)
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even_terms = set()
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odd_terms = set()
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initial_number_of_terms = len(terms)
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for t in terms:
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if ask(Q.even(t), assumptions):
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even_terms.add(t)
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elif ask(Q.odd(t), assumptions):
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odd_terms.add(t)
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terms -= even_terms
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if len(odd_terms) % 2:
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terms -= odd_terms
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new_coeff = (coeff + S.One) % 2
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else:
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terms -= odd_terms
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new_coeff = coeff % 2
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if new_coeff != coeff or len(terms) < initial_number_of_terms:
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terms.add(new_coeff)
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expr = expr.base**(Add(*terms))
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# Handle (-1)**((-1)**n/2 + m/2)
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e2 = 2*expr.exp
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if ask(Q.even(e2), assumptions):
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if e2.could_extract_minus_sign():
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e2 *= expr.base
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if e2.is_Add:
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i, p = e2.as_two_terms()
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if p.is_Pow and p.base is S.NegativeOne:
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if ask(Q.integer(p.exp), assumptions):
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i = (i + 1)/2
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if ask(Q.even(i), assumptions):
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return expr.base**p.exp
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elif ask(Q.odd(i), assumptions):
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return expr.base**(p.exp + 1)
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else:
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return expr.base**(p.exp + i)
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if old != expr:
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return expr
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def refine_atan2(expr, assumptions):
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"""
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Handler for the atan2 function.
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Examples
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========
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>>> from sympy import Q, atan2
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>>> from sympy.assumptions.refine import refine_atan2
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>>> from sympy.abc import x, y
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>>> refine_atan2(atan2(y,x), Q.real(y) & Q.positive(x))
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atan(y/x)
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>>> refine_atan2(atan2(y,x), Q.negative(y) & Q.negative(x))
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atan(y/x) - pi
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>>> refine_atan2(atan2(y,x), Q.positive(y) & Q.negative(x))
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atan(y/x) + pi
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>>> refine_atan2(atan2(y,x), Q.zero(y) & Q.negative(x))
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pi
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>>> refine_atan2(atan2(y,x), Q.positive(y) & Q.zero(x))
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pi/2
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>>> refine_atan2(atan2(y,x), Q.negative(y) & Q.zero(x))
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-pi/2
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>>> refine_atan2(atan2(y,x), Q.zero(y) & Q.zero(x))
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nan
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"""
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from sympy.functions.elementary.trigonometric import atan
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y, x = expr.args
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if ask(Q.real(y) & Q.positive(x), assumptions):
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return atan(y / x)
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elif ask(Q.negative(y) & Q.negative(x), assumptions):
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return atan(y / x) - S.Pi
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elif ask(Q.positive(y) & Q.negative(x), assumptions):
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return atan(y / x) + S.Pi
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elif ask(Q.zero(y) & Q.negative(x), assumptions):
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return S.Pi
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elif ask(Q.positive(y) & Q.zero(x), assumptions):
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return S.Pi/2
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elif ask(Q.negative(y) & Q.zero(x), assumptions):
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return -S.Pi/2
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elif ask(Q.zero(y) & Q.zero(x), assumptions):
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return S.NaN
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else:
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return expr
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def refine_re(expr, assumptions):
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"""
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Handler for real part.
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Examples
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========
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>>> from sympy.assumptions.refine import refine_re
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>>> from sympy import Q, re
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>>> from sympy.abc import x
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>>> refine_re(re(x), Q.real(x))
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x
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>>> refine_re(re(x), Q.imaginary(x))
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0
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"""
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arg = expr.args[0]
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if ask(Q.real(arg), assumptions):
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return arg
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if ask(Q.imaginary(arg), assumptions):
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return S.Zero
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return _refine_reim(expr, assumptions)
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def refine_im(expr, assumptions):
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"""
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Handler for imaginary part.
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Explanation
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===========
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>>> from sympy.assumptions.refine import refine_im
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>>> from sympy import Q, im
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>>> from sympy.abc import x
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>>> refine_im(im(x), Q.real(x))
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0
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>>> refine_im(im(x), Q.imaginary(x))
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-I*x
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"""
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arg = expr.args[0]
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if ask(Q.real(arg), assumptions):
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return S.Zero
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if ask(Q.imaginary(arg), assumptions):
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return - S.ImaginaryUnit * arg
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return _refine_reim(expr, assumptions)
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def refine_arg(expr, assumptions):
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"""
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Handler for complex argument
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Explanation
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===========
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>>> from sympy.assumptions.refine import refine_arg
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>>> from sympy import Q, arg
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>>> from sympy.abc import x
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>>> refine_arg(arg(x), Q.positive(x))
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0
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>>> refine_arg(arg(x), Q.negative(x))
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pi
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"""
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rg = expr.args[0]
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if ask(Q.positive(rg), assumptions):
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return S.Zero
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if ask(Q.negative(rg), assumptions):
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return S.Pi
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return None
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def _refine_reim(expr, assumptions):
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# Helper function for refine_re & refine_im
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expanded = expr.expand(complex = True)
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if expanded != expr:
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refined = refine(expanded, assumptions)
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if refined != expanded:
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return refined
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# Best to leave the expression as is
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return None
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def refine_sign(expr, assumptions):
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"""
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Handler for sign.
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Examples
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========
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>>> from sympy.assumptions.refine import refine_sign
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>>> from sympy import Symbol, Q, sign, im
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>>> x = Symbol('x', real = True)
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>>> expr = sign(x)
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>>> refine_sign(expr, Q.positive(x) & Q.nonzero(x))
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1
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>>> refine_sign(expr, Q.negative(x) & Q.nonzero(x))
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-1
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>>> refine_sign(expr, Q.zero(x))
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0
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>>> y = Symbol('y', imaginary = True)
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>>> expr = sign(y)
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>>> refine_sign(expr, Q.positive(im(y)))
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I
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>>> refine_sign(expr, Q.negative(im(y)))
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-I
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"""
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arg = expr.args[0]
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if ask(Q.zero(arg), assumptions):
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return S.Zero
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if ask(Q.real(arg)):
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if ask(Q.positive(arg), assumptions):
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return S.One
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if ask(Q.negative(arg), assumptions):
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return S.NegativeOne
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if ask(Q.imaginary(arg)):
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arg_re, arg_im = arg.as_real_imag()
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if ask(Q.positive(arg_im), assumptions):
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return S.ImaginaryUnit
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if ask(Q.negative(arg_im), assumptions):
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return -S.ImaginaryUnit
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return expr
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def refine_matrixelement(expr, assumptions):
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"""
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Handler for symmetric part.
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Examples
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========
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>>> from sympy.assumptions.refine import refine_matrixelement
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>>> from sympy import MatrixSymbol, Q
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>>> X = MatrixSymbol('X', 3, 3)
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>>> refine_matrixelement(X[0, 1], Q.symmetric(X))
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X[0, 1]
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>>> refine_matrixelement(X[1, 0], Q.symmetric(X))
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X[0, 1]
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"""
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from sympy.matrices.expressions.matexpr import MatrixElement
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matrix, i, j = expr.args
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if ask(Q.symmetric(matrix), assumptions):
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if (i - j).could_extract_minus_sign():
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return expr
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return MatrixElement(matrix, j, i)
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handlers_dict: dict[str, Callable[[Expr, Boolean], Expr]] = {
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'Abs': refine_abs,
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'Pow': refine_Pow,
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'atan2': refine_atan2,
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're': refine_re,
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'im': refine_im,
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'arg': refine_arg,
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'sign': refine_sign,
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'MatrixElement': refine_matrixelement
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}
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