Traktor/myenv/Lib/site-packages/sympy/unify/tests/test_rewrite.py

from sympy.unify.rewrite import rewriterule
from sympy.core.basic import Basic
from sympy.core.singleton import S
from sympy.core.symbol import Symbol
from sympy.functions.elementary.trigonometric import sin
from sympy.abc import x, y
from sympy.strategies.rl import rebuild
from sympy.assumptions import Q

p, q = Symbol('p'), Symbol('q')

def test_simple():
    rl = rewriterule(Basic(p, S(1)), Basic(p, S(2)), variables=(p,))
    assert list(rl(Basic(S(3), S(1)))) == [Basic(S(3), S(2))]

    p1 = p**2
    p2 = p**3
    rl = rewriterule(p1, p2, variables=(p,))

    expr = x**2
    assert list(rl(expr)) == [x**3]

def test_simple_variables():
    rl = rewriterule(Basic(x, S(1)), Basic(x, S(2)), variables=(x,))
    assert list(rl(Basic(S(3), S(1)))) == [Basic(S(3), S(2))]

    rl = rewriterule(x**2, x**3, variables=(x,))
    assert list(rl(y**2)) == [y**3]

def test_moderate():
    p1 = p**2 + q**3
    p2 = (p*q)**4
    rl = rewriterule(p1, p2, (p, q))

    expr = x**2 + y**3
    assert list(rl(expr)) == [(x*y)**4]

def test_sincos():
    p1 = sin(p)**2 + sin(p)**2
    p2 = 1
    rl = rewriterule(p1, p2, (p, q))

    assert list(rl(sin(x)**2 + sin(x)**2)) == [1]
    assert list(rl(sin(y)**2 + sin(y)**2)) == [1]

def test_Exprs_ok():
    rl = rewriterule(p+q, q+p, (p, q))
    next(rl(x+y)).is_commutative
    str(next(rl(x+y)))

def test_condition_simple():
    rl = rewriterule(x, x+1, [x], lambda x: x < 10)
    assert not list(rl(S(15)))
    assert rebuild(next(rl(S(5)))) == 6


def test_condition_multiple():
    rl = rewriterule(x + y, x**y, [x,y], lambda x, y: x.is_integer)

    a = Symbol('a')
    b = Symbol('b', integer=True)
    expr = a + b
    assert list(rl(expr)) == [b**a]

    c = Symbol('c', integer=True)
    d = Symbol('d', integer=True)
    assert set(rl(c + d)) == {c**d, d**c}

def test_assumptions():
    rl = rewriterule(x + y, x**y, [x, y], assume=Q.integer(x))

    a, b = map(Symbol, 'ab')
    expr = a + b
    assert list(rl(expr, Q.integer(b))) == [b**a]
losowanie zdjec 2024-05-26 05:12:46 +02:00			`from sympy.unify.rewrite import rewriterule`
			`from sympy.core.basic import Basic`
			`from sympy.core.singleton import S`
			`from sympy.core.symbol import Symbol`
			`from sympy.functions.elementary.trigonometric import sin`
			`from sympy.abc import x, y`
			`from sympy.strategies.rl import rebuild`
			`from sympy.assumptions import Q`

			`p, q = Symbol('p'), Symbol('q')`

			`def test_simple():`
			`rl = rewriterule(Basic(p, S(1)), Basic(p, S(2)), variables=(p,))`
			`assert list(rl(Basic(S(3), S(1)))) == [Basic(S(3), S(2))]`

			`p1 = p**2`
			`p2 = p**3`
			`rl = rewriterule(p1, p2, variables=(p,))`

			`expr = x**2`
			`assert list(rl(expr)) == [x**3]`

			`def test_simple_variables():`
			`rl = rewriterule(Basic(x, S(1)), Basic(x, S(2)), variables=(x,))`
			`assert list(rl(Basic(S(3), S(1)))) == [Basic(S(3), S(2))]`

			`rl = rewriterule(x2, x3, variables=(x,))`
			`assert list(rl(y2)) == [y3]`

			`def test_moderate():`
			`p1 = p2 + q3`
			`p2 = (pq)*4`
			`rl = rewriterule(p1, p2, (p, q))`

			`expr = x2 + y3`
			`assert list(rl(expr)) == [(xy)*4]`

			`def test_sincos():`
			`p1 = sin(p)2 + sin(p)2`
			`p2 = 1`
			`rl = rewriterule(p1, p2, (p, q))`

			`assert list(rl(sin(x)2 + sin(x)2)) == [1]`
			`assert list(rl(sin(y)2 + sin(y)2)) == [1]`

			`def test_Exprs_ok():`
			`rl = rewriterule(p+q, q+p, (p, q))`
			`next(rl(x+y)).is_commutative`
			`str(next(rl(x+y)))`

			`def test_condition_simple():`
			`rl = rewriterule(x, x+1, [x], lambda x: x < 10)`
			`assert not list(rl(S(15)))`
			`assert rebuild(next(rl(S(5)))) == 6`


			`def test_condition_multiple():`
			`rl = rewriterule(x + y, x**y, [x,y], lambda x, y: x.is_integer)`

			`a = Symbol('a')`
			`b = Symbol('b', integer=True)`
			`expr = a + b`
			`assert list(rl(expr)) == [b**a]`

			`c = Symbol('c', integer=True)`
			`d = Symbol('d', integer=True)`
			`assert set(rl(c + d)) == {cd, dc}`

			`def test_assumptions():`
			`rl = rewriterule(x + y, x**y, [x, y], assume=Q.integer(x))`

			`a, b = map(Symbol, 'ab')`
			`expr = a + b`
			`assert list(rl(expr, Q.integer(b))) == [b**a]`