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from sympy.concrete.summations import Sum
from sympy.core.add import Add
from sympy.core.basic import Basic
from sympy.core.expr import unchanged
from sympy.core.function import (count_ops, diff, expand, expand_multinomial, Function, Derivative)
from sympy.core.mul import Mul, _keep_coeff
from sympy.core import GoldenRatio
from sympy.core.numbers import (E, Float, I, oo, pi, Rational, zoo)
from sympy.core.relational import (Eq, Lt, Gt, Ge, Le)
from sympy.core.singleton import S
from sympy.core.symbol import (Symbol, symbols)
from sympy.core.sympify import sympify
from sympy.functions.combinatorial.factorials import (binomial, factorial)
from sympy.functions.elementary.complexes import (Abs, sign)
from sympy.functions.elementary.exponential import (exp, exp_polar, log)
from sympy.functions.elementary.hyperbolic import (cosh, csch, sinh)
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.functions.elementary.piecewise import Piecewise
from sympy.functions.elementary.trigonometric import (acos, asin, atan, cos, sin, sinc, tan)
from sympy.functions.special.error_functions import erf
from sympy.functions.special.gamma_functions import gamma
from sympy.functions.special.hyper import hyper
from sympy.functions.special.tensor_functions import KroneckerDelta
from sympy.geometry.polygon import rad
from sympy.integrals.integrals import (Integral, integrate)
from sympy.logic.boolalg import (And, Or)
from sympy.matrices.dense import (Matrix, eye)
from sympy.matrices.expressions.matexpr import MatrixSymbol
from sympy.polys.polytools import (factor, Poly)
from sympy.simplify.simplify import (besselsimp, hypersimp, inversecombine, logcombine, nsimplify, nthroot, posify, separatevars, signsimp, simplify)
from sympy.solvers.solvers import solve
from sympy.testing.pytest import XFAIL, slow, _both_exp_pow
from sympy.abc import x, y, z, t, a, b, c, d, e, f, g, h, i, n
def test_issue_7263():
assert abs((simplify(30.8**2 - 82.5**2 * sin(rad(11.6))**2)).evalf() - \
673.447451402970) < 1e-12
def test_factorial_simplify():
# There are more tests in test_factorials.py.
x = Symbol('x')
assert simplify(factorial(x)/x) == gamma(x)
assert simplify(factorial(factorial(x))) == factorial(factorial(x))
def test_simplify_expr():
x, y, z, k, n, m, w, s, A = symbols('x,y,z,k,n,m,w,s,A')
f = Function('f')
assert all(simplify(tmp) == tmp for tmp in [I, E, oo, x, -x, -oo, -E, -I])
e = 1/x + 1/y
assert e != (x + y)/(x*y)
assert simplify(e) == (x + y)/(x*y)
e = A**2*s**4/(4*pi*k*m**3)
assert simplify(e) == e
e = (4 + 4*x - 2*(2 + 2*x))/(2 + 2*x)
assert simplify(e) == 0
e = (-4*x*y**2 - 2*y**3 - 2*x**2*y)/(x + y)**2
assert simplify(e) == -2*y
e = -x - y - (x + y)**(-1)*y**2 + (x + y)**(-1)*x**2
assert simplify(e) == -2*y
e = (x + x*y)/x
assert simplify(e) == 1 + y
e = (f(x) + y*f(x))/f(x)
assert simplify(e) == 1 + y
e = (2 * (1/n - cos(n * pi)/n))/pi
assert simplify(e) == (-cos(pi*n) + 1)/(pi*n)*2
e = integrate(1/(x**3 + 1), x).diff(x)
assert simplify(e) == 1/(x**3 + 1)
e = integrate(x/(x**2 + 3*x + 1), x).diff(x)
assert simplify(e) == x/(x**2 + 3*x + 1)
f = Symbol('f')
A = Matrix([[2*k - m*w**2, -k], [-k, k - m*w**2]]).inv()
assert simplify((A*Matrix([0, f]))[1] -
(-f*(2*k - m*w**2)/(k**2 - (k - m*w**2)*(2*k - m*w**2)))) == 0
f = -x + y/(z + t) + z*x/(z + t) + z*a/(z + t) + t*x/(z + t)
assert simplify(f) == (y + a*z)/(z + t)
# issue 10347
expr = -x*(y**2 - 1)*(2*y**2*(x**2 - 1)/(a*(x**2 - y**2)**2) + (x**2 - 1)
/(a*(x**2 - y**2)))/(a*(x**2 - y**2)) + x*(-2*x**2*sqrt(-x**2*y**2 + x**2
+ y**2 - 1)*sin(z)/(a*(x**2 - y**2)**2) - x**2*sqrt(-x**2*y**2 + x**2 +
y**2 - 1)*sin(z)/(a*(x**2 - 1)*(x**2 - y**2)) + (x**2*sqrt((-x**2 + 1)*
(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(x**2 - 1) + sqrt(
(-x**2 + 1)*(y**2 - 1))*(x*(-x*y**2 + x)/sqrt(-x**2*y**2 + x**2 + y**2 -
1) + sqrt(-x**2*y**2 + x**2 + y**2 - 1))*sin(z))/(a*sqrt((-x**2 + 1)*(
y**2 - 1))*(x**2 - y**2)))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(a*
(x**2 - y**2)) + x*(-2*x**2*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a*
(x**2 - y**2)**2) - x**2*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a*
(x**2 - 1)*(x**2 - y**2)) + (x**2*sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2
*y**2 + x**2 + y**2 - 1)*cos(z)/(x**2 - 1) + x*sqrt((-x**2 + 1)*(y**2 -
1))*(-x*y**2 + x)*cos(z)/sqrt(-x**2*y**2 + x**2 + y**2 - 1) + sqrt((-x**2
+ 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z))/(a*sqrt((-x**2
+ 1)*(y**2 - 1))*(x**2 - y**2)))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(
z)/(a*(x**2 - y**2)) - y*sqrt((-x**2 + 1)*(y**2 - 1))*(-x*y*sqrt(-x**2*
y**2 + x**2 + y**2 - 1)*sin(z)/(a*(x**2 - y**2)*(y**2 - 1)) + 2*x*y*sqrt(
-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(a*(x**2 - y**2)**2) + (x*y*sqrt((
-x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(z)/(y**2 -
1) + x*sqrt((-x**2 + 1)*(y**2 - 1))*(-x**2*y + y)*sin(z)/sqrt(-x**2*y**2
+ x**2 + y**2 - 1))/(a*sqrt((-x**2 + 1)*(y**2 - 1))*(x**2 - y**2)))*sin(
z)/(a*(x**2 - y**2)) + y*(x**2 - 1)*(-2*x*y*(x**2 - 1)/(a*(x**2 - y**2)
**2) + 2*x*y/(a*(x**2 - y**2)))/(a*(x**2 - y**2)) + y*(x**2 - 1)*(y**2 -
1)*(-x*y*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a*(x**2 - y**2)*(y**2
- 1)) + 2*x*y*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)/(a*(x**2 - y**2)
**2) + (x*y*sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 -
1)*cos(z)/(y**2 - 1) + x*sqrt((-x**2 + 1)*(y**2 - 1))*(-x**2*y + y)*cos(
z)/sqrt(-x**2*y**2 + x**2 + y**2 - 1))/(a*sqrt((-x**2 + 1)*(y**2 - 1)
)*(x**2 - y**2)))*cos(z)/(a*sqrt((-x**2 + 1)*(y**2 - 1))*(x**2 - y**2)
) - x*sqrt((-x**2 + 1)*(y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*sin(
z)**2/(a**2*(x**2 - 1)*(x**2 - y**2)*(y**2 - 1)) - x*sqrt((-x**2 + 1)*(
y**2 - 1))*sqrt(-x**2*y**2 + x**2 + y**2 - 1)*cos(z)**2/(a**2*(x**2 - 1)*(
x**2 - y**2)*(y**2 - 1))
assert simplify(expr) == 2*x/(a**2*(x**2 - y**2))
#issue 17631
assert simplify('((-1/2)*Boole(True)*Boole(False)-1)*Boole(True)') == \
Mul(sympify('(2 + Boole(True)*Boole(False))'), sympify('-Boole(True)/2'))
A, B = symbols('A,B', commutative=False)
assert simplify(A*B - B*A) == A*B - B*A
assert simplify(A/(1 + y/x)) == x*A/(x + y)
assert simplify(A*(1/x + 1/y)) == A/x + A/y #(x + y)*A/(x*y)
assert simplify(log(2) + log(3)) == log(6)
assert simplify(log(2*x) - log(2)) == log(x)
assert simplify(hyper([], [], x)) == exp(x)
def test_issue_3557():
f_1 = x*a + y*b + z*c - 1
f_2 = x*d + y*e + z*f - 1
f_3 = x*g + y*h + z*i - 1
solutions = solve([f_1, f_2, f_3], x, y, z, simplify=False)
assert simplify(solutions[y]) == \
(a*i + c*d + f*g - a*f - c*g - d*i)/ \
(a*e*i + b*f*g + c*d*h - a*f*h - b*d*i - c*e*g)
def test_simplify_other():
assert simplify(sin(x)**2 + cos(x)**2) == 1
assert simplify(gamma(x + 1)/gamma(x)) == x
assert simplify(sin(x)**2 + cos(x)**2 + factorial(x)/gamma(x)) == 1 + x
assert simplify(
Eq(sin(x)**2 + cos(x)**2, factorial(x)/gamma(x))) == Eq(x, 1)
nc = symbols('nc', commutative=False)
assert simplify(x + x*nc) == x*(1 + nc)
# issue 6123
# f = exp(-I*(k*sqrt(t) + x/(2*sqrt(t)))**2)
# ans = integrate(f, (k, -oo, oo), conds='none')
ans = I*(-pi*x*exp(I*pi*Rational(-3, 4) + I*x**2/(4*t))*erf(x*exp(I*pi*Rational(-3, 4))/
(2*sqrt(t)))/(2*sqrt(t)) + pi*x*exp(I*pi*Rational(-3, 4) + I*x**2/(4*t))/
(2*sqrt(t)))*exp(-I*x**2/(4*t))/(sqrt(pi)*x) - I*sqrt(pi) * \
(-erf(x*exp(I*pi/4)/(2*sqrt(t))) + 1)*exp(I*pi/4)/(2*sqrt(t))
assert simplify(ans) == -(-1)**Rational(3, 4)*sqrt(pi)/sqrt(t)
# issue 6370
assert simplify(2**(2 + x)/4) == 2**x
@_both_exp_pow
def test_simplify_complex():
cosAsExp = cos(x)._eval_rewrite_as_exp(x)
tanAsExp = tan(x)._eval_rewrite_as_exp(x)
assert simplify(cosAsExp*tanAsExp) == sin(x) # issue 4341
# issue 10124
assert simplify(exp(Matrix([[0, -1], [1, 0]]))) == Matrix([[cos(1),
-sin(1)], [sin(1), cos(1)]])
def test_simplify_ratio():
# roots of x**3-3*x+5
roots = ['(1/2 - sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3) + 1/((1/2 - '
'sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3))',
'1/((1/2 + sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3)) + '
'(1/2 + sqrt(3)*I/2)*(sqrt(21)/2 + 5/2)**(1/3)',
'-(sqrt(21)/2 + 5/2)**(1/3) - 1/(sqrt(21)/2 + 5/2)**(1/3)']
for r in roots:
r = S(r)
assert count_ops(simplify(r, ratio=1)) <= count_ops(r)
# If ratio=oo, simplify() is always applied:
assert simplify(r, ratio=oo) is not r
def test_simplify_measure():
measure1 = lambda expr: len(str(expr))
measure2 = lambda expr: -count_ops(expr)
# Return the most complicated result
expr = (x + 1)/(x + sin(x)**2 + cos(x)**2)
assert measure1(simplify(expr, measure=measure1)) <= measure1(expr)
assert measure2(simplify(expr, measure=measure2)) <= measure2(expr)
expr2 = Eq(sin(x)**2 + cos(x)**2, 1)
assert measure1(simplify(expr2, measure=measure1)) <= measure1(expr2)
assert measure2(simplify(expr2, measure=measure2)) <= measure2(expr2)
def test_simplify_rational():
expr = 2**x*2.**y
assert simplify(expr, rational = True) == 2**(x+y)
assert simplify(expr, rational = None) == 2.0**(x+y)
assert simplify(expr, rational = False) == expr
assert simplify('0.9 - 0.8 - 0.1', rational = True) == 0
def test_simplify_issue_1308():
assert simplify(exp(Rational(-1, 2)) + exp(Rational(-3, 2))) == \
(1 + E)*exp(Rational(-3, 2))
def test_issue_5652():
assert simplify(E + exp(-E)) == exp(-E) + E
n = symbols('n', commutative=False)
assert simplify(n + n**(-n)) == n + n**(-n)
def test_simplify_fail1():
x = Symbol('x')
y = Symbol('y')
e = (x + y)**2/(-4*x*y**2 - 2*y**3 - 2*x**2*y)
assert simplify(e) == 1 / (-2*y)
def test_nthroot():
assert nthroot(90 + 34*sqrt(7), 3) == sqrt(7) + 3
q = 1 + sqrt(2) - 2*sqrt(3) + sqrt(6) + sqrt(7)
assert nthroot(expand_multinomial(q**3), 3) == q
assert nthroot(41 + 29*sqrt(2), 5) == 1 + sqrt(2)
assert nthroot(-41 - 29*sqrt(2), 5) == -1 - sqrt(2)
expr = 1320*sqrt(10) + 4216 + 2576*sqrt(6) + 1640*sqrt(15)
assert nthroot(expr, 5) == 1 + sqrt(6) + sqrt(15)
q = 1 + sqrt(2) + sqrt(3) + sqrt(5)
assert expand_multinomial(nthroot(expand_multinomial(q**5), 5)) == q
q = 1 + sqrt(2) + 7*sqrt(6) + 2*sqrt(10)
assert nthroot(expand_multinomial(q**5), 5, 8) == q
q = 1 + sqrt(2) - 2*sqrt(3) + 1171*sqrt(6)
assert nthroot(expand_multinomial(q**3), 3) == q
assert nthroot(expand_multinomial(q**6), 6) == q
def test_nthroot1():
q = 1 + sqrt(2) + sqrt(3) + S.One/10**20
p = expand_multinomial(q**5)
assert nthroot(p, 5) == q
q = 1 + sqrt(2) + sqrt(3) + S.One/10**30
p = expand_multinomial(q**5)
assert nthroot(p, 5) == q
@_both_exp_pow
def test_separatevars():
x, y, z, n = symbols('x,y,z,n')
assert separatevars(2*n*x*z + 2*x*y*z) == 2*x*z*(n + y)
assert separatevars(x*z + x*y*z) == x*z*(1 + y)
assert separatevars(pi*x*z + pi*x*y*z) == pi*x*z*(1 + y)
assert separatevars(x*y**2*sin(x) + x*sin(x)*sin(y)) == \
x*(sin(y) + y**2)*sin(x)
assert separatevars(x*exp(x + y) + x*exp(x)) == x*(1 + exp(y))*exp(x)
assert separatevars((x*(y + 1))**z).is_Pow # != x**z*(1 + y)**z
assert separatevars(1 + x + y + x*y) == (x + 1)*(y + 1)
assert separatevars(y/pi*exp(-(z - x)/cos(n))) == \
y*exp(x/cos(n))*exp(-z/cos(n))/pi
assert separatevars((x + y)*(x - y) + y**2 + 2*x + 1) == (x + 1)**2
# issue 4858
p = Symbol('p', positive=True)
assert separatevars(sqrt(p**2 + x*p**2)) == p*sqrt(1 + x)
assert separatevars(sqrt(y*(p**2 + x*p**2))) == p*sqrt(y*(1 + x))
assert separatevars(sqrt(y*(p**2 + x*p**2)), force=True) == \
p*sqrt(y)*sqrt(1 + x)
# issue 4865
assert separatevars(sqrt(x*y)).is_Pow
assert separatevars(sqrt(x*y), force=True) == sqrt(x)*sqrt(y)
# issue 4957
# any type sequence for symbols is fine
assert separatevars(((2*x + 2)*y), dict=True, symbols=()) == \
{'coeff': 1, x: 2*x + 2, y: y}
# separable
assert separatevars(((2*x + 2)*y), dict=True, symbols=[x]) == \
{'coeff': y, x: 2*x + 2}
assert separatevars(((2*x + 2)*y), dict=True, symbols=[]) == \
{'coeff': 1, x: 2*x + 2, y: y}
assert separatevars(((2*x + 2)*y), dict=True) == \
{'coeff': 1, x: 2*x + 2, y: y}
assert separatevars(((2*x + 2)*y), dict=True, symbols=None) == \
{'coeff': y*(2*x + 2)}
# not separable
assert separatevars(3, dict=True) is None
assert separatevars(2*x + y, dict=True, symbols=()) is None
assert separatevars(2*x + y, dict=True) is None
assert separatevars(2*x + y, dict=True, symbols=None) == {'coeff': 2*x + y}
# issue 4808
n, m = symbols('n,m', commutative=False)
assert separatevars(m + n*m) == (1 + n)*m
assert separatevars(x + x*n) == x*(1 + n)
# issue 4910
f = Function('f')
assert separatevars(f(x) + x*f(x)) == f(x) + x*f(x)
# a noncommutable object present
eq = x*(1 + hyper((), (), y*z))
assert separatevars(eq) == eq
s = separatevars(abs(x*y))
assert s == abs(x)*abs(y) and s.is_Mul
z = cos(1)**2 + sin(1)**2 - 1
a = abs(x*z)
s = separatevars(a)
assert not a.is_Mul and s.is_Mul and s == abs(x)*abs(z)
s = separatevars(abs(x*y*z))
assert s == abs(x)*abs(y)*abs(z)
# abs(x+y)/abs(z) would be better but we test this here to
# see that it doesn't raise
assert separatevars(abs((x+y)/z)) == abs((x+y)/z)
def test_separatevars_advanced_factor():
x, y, z = symbols('x,y,z')
assert separatevars(1 + log(x)*log(y) + log(x) + log(y)) == \
(log(x) + 1)*(log(y) + 1)
assert separatevars(1 + x - log(z) - x*log(z) - exp(y)*log(z) -
x*exp(y)*log(z) + x*exp(y) + exp(y)) == \
-((x + 1)*(log(z) - 1)*(exp(y) + 1))
x, y = symbols('x,y', positive=True)
assert separatevars(1 + log(x**log(y)) + log(x*y)) == \
(log(x) + 1)*(log(y) + 1)
def test_hypersimp():
n, k = symbols('n,k', integer=True)
assert hypersimp(factorial(k), k) == k + 1
assert hypersimp(factorial(k**2), k) is None
assert hypersimp(1/factorial(k), k) == 1/(k + 1)
assert hypersimp(2**k/factorial(k)**2, k) == 2/(k + 1)**2
assert hypersimp(binomial(n, k), k) == (n - k)/(k + 1)
assert hypersimp(binomial(n + 1, k), k) == (n - k + 1)/(k + 1)
term = (4*k + 1)*factorial(k)/factorial(2*k + 1)
assert hypersimp(term, k) == S.Half*((4*k + 5)/(3 + 14*k + 8*k**2))
term = 1/((2*k - 1)*factorial(2*k + 1))
assert hypersimp(term, k) == (k - S.Half)/((k + 1)*(2*k + 1)*(2*k + 3))
term = binomial(n, k)*(-1)**k/factorial(k)
assert hypersimp(term, k) == (k - n)/(k + 1)**2
def test_nsimplify():
x = Symbol("x")
assert nsimplify(0) == 0
assert nsimplify(-1) == -1
assert nsimplify(1) == 1
assert nsimplify(1 + x) == 1 + x
assert nsimplify(2.7) == Rational(27, 10)
assert nsimplify(1 - GoldenRatio) == (1 - sqrt(5))/2
assert nsimplify((1 + sqrt(5))/4, [GoldenRatio]) == GoldenRatio/2
assert nsimplify(2/GoldenRatio, [GoldenRatio]) == 2*GoldenRatio - 2
assert nsimplify(exp(pi*I*Rational(5, 3), evaluate=False)) == \
sympify('1/2 - sqrt(3)*I/2')
assert nsimplify(sin(pi*Rational(3, 5), evaluate=False)) == \
sympify('sqrt(sqrt(5)/8 + 5/8)')
assert nsimplify(sqrt(atan('1', evaluate=False))*(2 + I), [pi]) == \
sqrt(pi) + sqrt(pi)/2*I
assert nsimplify(2 + exp(2*atan('1/4')*I)) == sympify('49/17 + 8*I/17')
assert nsimplify(pi, tolerance=0.01) == Rational(22, 7)
assert nsimplify(pi, tolerance=0.001) == Rational(355, 113)
assert nsimplify(0.33333, tolerance=1e-4) == Rational(1, 3)
assert nsimplify(2.0**(1/3.), tolerance=0.001) == Rational(635, 504)
assert nsimplify(2.0**(1/3.), tolerance=0.001, full=True) == \
2**Rational(1, 3)
assert nsimplify(x + .5, rational=True) == S.Half + x
assert nsimplify(1/.3 + x, rational=True) == Rational(10, 3) + x
assert nsimplify(log(3).n(), rational=True) == \
sympify('109861228866811/100000000000000')
assert nsimplify(Float(0.272198261287950), [pi, log(2)]) == pi*log(2)/8
assert nsimplify(Float(0.272198261287950).n(3), [pi, log(2)]) == \
-pi/4 - log(2) + Rational(7, 4)
assert nsimplify(x/7.0) == x/7
assert nsimplify(pi/1e2) == pi/100
assert nsimplify(pi/1e2, rational=False) == pi/100.0
assert nsimplify(pi/1e-7) == 10000000*pi
assert not nsimplify(
factor(-3.0*z**2*(z**2)**(-2.5) + 3*(z**2)**(-1.5))).atoms(Float)
e = x**0.0
assert e.is_Pow and nsimplify(x**0.0) == 1
assert nsimplify(3.333333, tolerance=0.1, rational=True) == Rational(10, 3)
assert nsimplify(3.333333, tolerance=0.01, rational=True) == Rational(10, 3)
assert nsimplify(3.666666, tolerance=0.1, rational=True) == Rational(11, 3)
assert nsimplify(3.666666, tolerance=0.01, rational=True) == Rational(11, 3)
assert nsimplify(33, tolerance=10, rational=True) == Rational(33)
assert nsimplify(33.33, tolerance=10, rational=True) == Rational(30)
assert nsimplify(37.76, tolerance=10, rational=True) == Rational(40)
assert nsimplify(-203.1) == Rational(-2031, 10)
assert nsimplify(.2, tolerance=0) == Rational(1, 5)
assert nsimplify(-.2, tolerance=0) == Rational(-1, 5)
assert nsimplify(.2222, tolerance=0) == Rational(1111, 5000)
assert nsimplify(-.2222, tolerance=0) == Rational(-1111, 5000)
# issue 7211, PR 4112
assert nsimplify(S(2e-8)) == Rational(1, 50000000)
# issue 7322 direct test
assert nsimplify(1e-42, rational=True) != 0
# issue 10336
inf = Float('inf')
infs = (-oo, oo, inf, -inf)
for zi in infs:
ans = sign(zi)*oo
assert nsimplify(zi) == ans
assert nsimplify(zi + x) == x + ans
assert nsimplify(0.33333333, rational=True, rational_conversion='exact') == Rational(0.33333333)
# Make sure nsimplify on expressions uses full precision
assert nsimplify(pi.evalf(100)*x, rational_conversion='exact').evalf(100) == pi.evalf(100)*x
def test_issue_9448():
tmp = sympify("1/(1 - (-1)**(2/3) - (-1)**(1/3)) + 1/(1 + (-1)**(2/3) + (-1)**(1/3))")
assert nsimplify(tmp) == S.Half
def test_extract_minus_sign():
x = Symbol("x")
y = Symbol("y")
a = Symbol("a")
b = Symbol("b")
assert simplify(-x/-y) == x/y
assert simplify(-x/y) == -x/y
assert simplify(x/y) == x/y
assert simplify(x/-y) == -x/y
assert simplify(-x/0) == zoo*x
assert simplify(Rational(-5, 0)) is zoo
assert simplify(-a*x/(-y - b)) == a*x/(b + y)
def test_diff():
x = Symbol("x")
y = Symbol("y")
f = Function("f")
g = Function("g")
assert simplify(g(x).diff(x)*f(x).diff(x) - f(x).diff(x)*g(x).diff(x)) == 0
assert simplify(2*f(x)*f(x).diff(x) - diff(f(x)**2, x)) == 0
assert simplify(diff(1/f(x), x) + f(x).diff(x)/f(x)**2) == 0
assert simplify(f(x).diff(x, y) - f(x).diff(y, x)) == 0
def test_logcombine_1():
x, y = symbols("x,y")
a = Symbol("a")
z, w = symbols("z,w", positive=True)
b = Symbol("b", real=True)
assert logcombine(log(x) + 2*log(y)) == log(x) + 2*log(y)
assert logcombine(log(x) + 2*log(y), force=True) == log(x*y**2)
assert logcombine(a*log(w) + log(z)) == a*log(w) + log(z)
assert logcombine(b*log(z) + b*log(x)) == log(z**b) + b*log(x)
assert logcombine(b*log(z) - log(w)) == log(z**b/w)
assert logcombine(log(x)*log(z)) == log(x)*log(z)
assert logcombine(log(w)*log(x)) == log(w)*log(x)
assert logcombine(cos(-2*log(z) + b*log(w))) in [cos(log(w**b/z**2)),
cos(log(z**2/w**b))]
assert logcombine(log(log(x) - log(y)) - log(z), force=True) == \
log(log(x/y)/z)
assert logcombine((2 + I)*log(x), force=True) == (2 + I)*log(x)
assert logcombine((x**2 + log(x) - log(y))/(x*y), force=True) == \
(x**2 + log(x/y))/(x*y)
# the following could also give log(z*x**log(y**2)), what we
# are testing is that a canonical result is obtained
assert logcombine(log(x)*2*log(y) + log(z), force=True) == \
log(z*y**log(x**2))
assert logcombine((x*y + sqrt(x**4 + y**4) + log(x) - log(y))/(pi*x**Rational(2, 3)*
sqrt(y)**3), force=True) == (
x*y + sqrt(x**4 + y**4) + log(x/y))/(pi*x**Rational(2, 3)*y**Rational(3, 2))
assert logcombine(gamma(-log(x/y))*acos(-log(x/y)), force=True) == \
acos(-log(x/y))*gamma(-log(x/y))
assert logcombine(2*log(z)*log(w)*log(x) + log(z) + log(w)) == \
log(z**log(w**2))*log(x) + log(w*z)
assert logcombine(3*log(w) + 3*log(z)) == log(w**3*z**3)
assert logcombine(x*(y + 1) + log(2) + log(3)) == x*(y + 1) + log(6)
assert logcombine((x + y)*log(w) + (-x - y)*log(3)) == (x + y)*log(w/3)
# a single unknown can combine
assert logcombine(log(x) + log(2)) == log(2*x)
eq = log(abs(x)) + log(abs(y))
assert logcombine(eq) == eq
reps = {x: 0, y: 0}
assert log(abs(x)*abs(y)).subs(reps) != eq.subs(reps)
def test_logcombine_complex_coeff():
i = Integral((sin(x**2) + cos(x**3))/x, x)
assert logcombine(i, force=True) == i
assert logcombine(i + 2*log(x), force=True) == \
i + log(x**2)
def test_issue_5950():
x, y = symbols("x,y", positive=True)
assert logcombine(log(3) - log(2)) == log(Rational(3,2), evaluate=False)
assert logcombine(log(x) - log(y)) == log(x/y)
assert logcombine(log(Rational(3,2), evaluate=False) - log(2)) == \
log(Rational(3,4), evaluate=False)
def test_posify():
x = symbols('x')
assert str(posify(
x +
Symbol('p', positive=True) +
Symbol('n', negative=True))) == '(_x + n + p, {_x: x})'
eq, rep = posify(1/x)
assert log(eq).expand().subs(rep) == -log(x)
assert str(posify([x, 1 + x])) == '([_x, _x + 1], {_x: x})'
p = symbols('p', positive=True)
n = symbols('n', negative=True)
orig = [x, n, p]
modified, reps = posify(orig)
assert str(modified) == '[_x, n, p]'
assert [w.subs(reps) for w in modified] == orig
assert str(Integral(posify(1/x + y)[0], (y, 1, 3)).expand()) == \
'Integral(1/_x, (y, 1, 3)) + Integral(_y, (y, 1, 3))'
assert str(Sum(posify(1/x**n)[0], (n,1,3)).expand()) == \
'Sum(_x**(-n), (n, 1, 3))'
# issue 16438
k = Symbol('k', finite=True)
eq, rep = posify(k)
assert eq.assumptions0 == {'positive': True, 'zero': False, 'imaginary': False,
'nonpositive': False, 'commutative': True, 'hermitian': True, 'real': True, 'nonzero': True,
'nonnegative': True, 'negative': False, 'complex': True, 'finite': True,
'infinite': False, 'extended_real':True, 'extended_negative': False,
'extended_nonnegative': True, 'extended_nonpositive': False,
'extended_nonzero': True, 'extended_positive': True}
def test_issue_4194():
# simplify should call cancel
f = Function('f')
assert simplify((4*x + 6*f(y))/(2*x + 3*f(y))) == 2
@XFAIL
def test_simplify_float_vs_integer():
# Test for issue 4473:
# https://github.com/sympy/sympy/issues/4473
assert simplify(x**2.0 - x**2) == 0
assert simplify(x**2 - x**2.0) == 0
def test_as_content_primitive():
assert (x/2 + y).as_content_primitive() == (S.Half, x + 2*y)
assert (x/2 + y).as_content_primitive(clear=False) == (S.One, x/2 + y)
assert (y*(x/2 + y)).as_content_primitive() == (S.Half, y*(x + 2*y))
assert (y*(x/2 + y)).as_content_primitive(clear=False) == (S.One, y*(x/2 + y))
# although the _as_content_primitive methods do not alter the underlying structure,
# the as_content_primitive function will touch up the expression and join
# bases that would otherwise have not been joined.
assert (x*(2 + 2*x)*(3*x + 3)**2).as_content_primitive() == \
(18, x*(x + 1)**3)
assert (2 + 2*x + 2*y*(3 + 3*y)).as_content_primitive() == \
(2, x + 3*y*(y + 1) + 1)
assert ((2 + 6*x)**2).as_content_primitive() == \
(4, (3*x + 1)**2)
assert ((2 + 6*x)**(2*y)).as_content_primitive() == \
(1, (_keep_coeff(S(2), (3*x + 1)))**(2*y))
assert (5 + 10*x + 2*y*(3 + 3*y)).as_content_primitive() == \
(1, 10*x + 6*y*(y + 1) + 5)
assert (5*(x*(1 + y)) + 2*x*(3 + 3*y)).as_content_primitive() == \
(11, x*(y + 1))
assert ((5*(x*(1 + y)) + 2*x*(3 + 3*y))**2).as_content_primitive() == \
(121, x**2*(y + 1)**2)
assert (y**2).as_content_primitive() == \
(1, y**2)
assert (S.Infinity).as_content_primitive() == (1, oo)
eq = x**(2 + y)
assert (eq).as_content_primitive() == (1, eq)
assert (S.Half**(2 + x)).as_content_primitive() == (Rational(1, 4), 2**-x)
assert (Rational(-1, 2)**(2 + x)).as_content_primitive() == \
(Rational(1, 4), (Rational(-1, 2))**x)
assert (Rational(-1, 2)**(2 + x)).as_content_primitive() == \
(Rational(1, 4), Rational(-1, 2)**x)
assert (4**((1 + y)/2)).as_content_primitive() == (2, 4**(y/2))
assert (3**((1 + y)/2)).as_content_primitive() == \
(1, 3**(Mul(S.Half, 1 + y, evaluate=False)))
assert (5**Rational(3, 4)).as_content_primitive() == (1, 5**Rational(3, 4))
assert (5**Rational(7, 4)).as_content_primitive() == (5, 5**Rational(3, 4))
assert Add(z*Rational(5, 7), 0.5*x, y*Rational(3, 2), evaluate=False).as_content_primitive() == \
(Rational(1, 14), 7.0*x + 21*y + 10*z)
assert (2**Rational(3, 4) + 2**Rational(1, 4)*sqrt(3)).as_content_primitive(radical=True) == \
(1, 2**Rational(1, 4)*(sqrt(2) + sqrt(3)))
def test_signsimp():
e = x*(-x + 1) + x*(x - 1)
assert signsimp(Eq(e, 0)) is S.true
assert Abs(x - 1) == Abs(1 - x)
assert signsimp(y - x) == y - x
assert signsimp(y - x, evaluate=False) == Mul(-1, x - y, evaluate=False)
def test_besselsimp():
from sympy.functions.special.bessel import (besseli, besselj, bessely)
from sympy.integrals.transforms import cosine_transform
assert besselsimp(exp(-I*pi*y/2)*besseli(y, z*exp_polar(I*pi/2))) == \
besselj(y, z)
assert besselsimp(exp(-I*pi*a/2)*besseli(a, 2*sqrt(x)*exp_polar(I*pi/2))) == \
besselj(a, 2*sqrt(x))
assert besselsimp(sqrt(2)*sqrt(pi)*x**Rational(1, 4)*exp(I*pi/4)*exp(-I*pi*a/2) *
besseli(Rational(-1, 2), sqrt(x)*exp_polar(I*pi/2)) *
besseli(a, sqrt(x)*exp_polar(I*pi/2))/2) == \
besselj(a, sqrt(x)) * cos(sqrt(x))
assert besselsimp(besseli(Rational(-1, 2), z)) == \
sqrt(2)*cosh(z)/(sqrt(pi)*sqrt(z))
assert besselsimp(besseli(a, z*exp_polar(-I*pi/2))) == \
exp(-I*pi*a/2)*besselj(a, z)
assert cosine_transform(1/t*sin(a/t), t, y) == \
sqrt(2)*sqrt(pi)*besselj(0, 2*sqrt(a)*sqrt(y))/2
assert besselsimp(x**2*(a*(-2*besselj(5*I, x) + besselj(-2 + 5*I, x) +
besselj(2 + 5*I, x)) + b*(-2*bessely(5*I, x) + bessely(-2 + 5*I, x) +
bessely(2 + 5*I, x)))/4 + x*(a*(besselj(-1 + 5*I, x)/2 - besselj(1 + 5*I, x)/2)
+ b*(bessely(-1 + 5*I, x)/2 - bessely(1 + 5*I, x)/2)) + (x**2 + 25)*(a*besselj(5*I, x)
+ b*bessely(5*I, x))) == 0
assert besselsimp(81*x**2*(a*(besselj(Rational(-5, 3), 9*x) - 2*besselj(Rational(1, 3), 9*x) + besselj(Rational(7, 3), 9*x))
+ b*(bessely(Rational(-5, 3), 9*x) - 2*bessely(Rational(1, 3), 9*x) + bessely(Rational(7, 3), 9*x)))/4 + x*(a*(9*besselj(Rational(-2, 3), 9*x)/2
- 9*besselj(Rational(4, 3), 9*x)/2) + b*(9*bessely(Rational(-2, 3), 9*x)/2 - 9*bessely(Rational(4, 3), 9*x)/2)) +
(81*x**2 - Rational(1, 9))*(a*besselj(Rational(1, 3), 9*x) + b*bessely(Rational(1, 3), 9*x))) == 0
assert besselsimp(besselj(a-1,x) + besselj(a+1, x) - 2*a*besselj(a, x)/x) == 0
assert besselsimp(besselj(a-1,x) + besselj(a+1, x) + besselj(a, x)) == (2*a + x)*besselj(a, x)/x
assert besselsimp(x**2* besselj(a,x) + x**3*besselj(a+1, x) + besselj(a+2, x)) == \
2*a*x*besselj(a + 1, x) + x**3*besselj(a + 1, x) - x**2*besselj(a + 2, x) + 2*x*besselj(a + 1, x) + besselj(a + 2, x)
def test_Piecewise():
e1 = x*(x + y) - y*(x + y)
e2 = sin(x)**2 + cos(x)**2
e3 = expand((x + y)*y/x)
s1 = simplify(e1)
s2 = simplify(e2)
s3 = simplify(e3)
assert simplify(Piecewise((e1, x < e2), (e3, True))) == \
Piecewise((s1, x < s2), (s3, True))
def test_polymorphism():
class A(Basic):
def _eval_simplify(x, **kwargs):
return S.One
a = A(S(5), S(2))
assert simplify(a) == 1
def test_issue_from_PR1599():
n1, n2, n3, n4 = symbols('n1 n2 n3 n4', negative=True)
assert simplify(I*sqrt(n1)) == -sqrt(-n1)
def test_issue_6811():
eq = (x + 2*y)*(2*x + 2)
assert simplify(eq) == (x + 1)*(x + 2*y)*2
# reject the 2-arg Mul -- these are a headache for test writing
assert simplify(eq.expand()) == \
2*x**2 + 4*x*y + 2*x + 4*y
def test_issue_6920():
e = [cos(x) + I*sin(x), cos(x) - I*sin(x),
cosh(x) - sinh(x), cosh(x) + sinh(x)]
ok = [exp(I*x), exp(-I*x), exp(-x), exp(x)]
# wrap in f to show that the change happens wherever ei occurs
f = Function('f')
assert [simplify(f(ei)).args[0] for ei in e] == ok
def test_issue_7001():
from sympy.abc import r, R
assert simplify(-(r*Piecewise((pi*Rational(4, 3), r <= R),
(-8*pi*R**3/(3*r**3), True)) + 2*Piecewise((pi*r*Rational(4, 3), r <= R),
(4*pi*R**3/(3*r**2), True)))/(4*pi*r)) == \
Piecewise((-1, r <= R), (0, True))
def test_inequality_no_auto_simplify():
# no simplify on creation but can be simplified
lhs = cos(x)**2 + sin(x)**2
rhs = 2
e = Lt(lhs, rhs, evaluate=False)
assert e is not S.true
assert simplify(e)
def test_issue_9398():
from sympy.core.numbers import Number
from sympy.polys.polytools import cancel
assert cancel(1e-14) != 0
assert cancel(1e-14*I) != 0
assert simplify(1e-14) != 0
assert simplify(1e-14*I) != 0
assert (I*Number(1.)*Number(10)**Number(-14)).simplify() != 0
assert cancel(1e-20) != 0
assert cancel(1e-20*I) != 0
assert simplify(1e-20) != 0
assert simplify(1e-20*I) != 0
assert cancel(1e-100) != 0
assert cancel(1e-100*I) != 0
assert simplify(1e-100) != 0
assert simplify(1e-100*I) != 0
f = Float("1e-1000")
assert cancel(f) != 0
assert cancel(f*I) != 0
assert simplify(f) != 0
assert simplify(f*I) != 0
def test_issue_9324_simplify():
M = MatrixSymbol('M', 10, 10)
e = M[0, 0] + M[5, 4] + 1304
assert simplify(e) == e
def test_issue_9817_simplify():
# simplify on trace of substituted explicit quadratic form of matrix
# expressions (a scalar) should return without errors (AttributeError)
# See issue #9817 and #9190 for the original bug more discussion on this
from sympy.matrices.expressions import Identity, trace
v = MatrixSymbol('v', 3, 1)
A = MatrixSymbol('A', 3, 3)
x = Matrix([i + 1 for i in range(3)])
X = Identity(3)
quadratic = v.T * A * v
assert simplify((trace(quadratic.as_explicit())).xreplace({v:x, A:X})) == 14
def test_issue_13474():
x = Symbol('x')
assert simplify(x + csch(sinc(1))) == x + csch(sinc(1))
@_both_exp_pow
def test_simplify_function_inverse():
# "inverse" attribute does not guarantee that f(g(x)) is x
# so this simplification should not happen automatically.
# See issue #12140
x, y = symbols('x, y')
g = Function('g')
class f(Function):
def inverse(self, argindex=1):
return g
assert simplify(f(g(x))) == f(g(x))
assert inversecombine(f(g(x))) == x
assert simplify(f(g(x)), inverse=True) == x
assert simplify(f(g(sin(x)**2 + cos(x)**2)), inverse=True) == 1
assert simplify(f(g(x, y)), inverse=True) == f(g(x, y))
assert unchanged(asin, sin(x))
assert simplify(asin(sin(x))) == asin(sin(x))
assert simplify(2*asin(sin(3*x)), inverse=True) == 6*x
assert simplify(log(exp(x))) == log(exp(x))
assert simplify(log(exp(x)), inverse=True) == x
assert simplify(exp(log(x)), inverse=True) == x
assert simplify(log(exp(x), 2), inverse=True) == x/log(2)
assert simplify(log(exp(x), 2, evaluate=False), inverse=True) == x/log(2)
def test_clear_coefficients():
from sympy.simplify.simplify import clear_coefficients
assert clear_coefficients(4*y*(6*x + 3)) == (y*(2*x + 1), 0)
assert clear_coefficients(4*y*(6*x + 3) - 2) == (y*(2*x + 1), Rational(1, 6))
assert clear_coefficients(4*y*(6*x + 3) - 2, x) == (y*(2*x + 1), x/12 + Rational(1, 6))
assert clear_coefficients(sqrt(2) - 2) == (sqrt(2), 2)
assert clear_coefficients(4*sqrt(2) - 2) == (sqrt(2), S.Half)
assert clear_coefficients(S(3), x) == (0, x - 3)
assert clear_coefficients(S.Infinity, x) == (S.Infinity, x)
assert clear_coefficients(-S.Pi, x) == (S.Pi, -x)
assert clear_coefficients(2 - S.Pi/3, x) == (pi, -3*x + 6)
def test_nc_simplify():
from sympy.simplify.simplify import nc_simplify
from sympy.matrices.expressions import MatPow, Identity
from sympy.core import Pow
from functools import reduce
a, b, c, d = symbols('a b c d', commutative = False)
x = Symbol('x')
A = MatrixSymbol("A", x, x)
B = MatrixSymbol("B", x, x)
C = MatrixSymbol("C", x, x)
D = MatrixSymbol("D", x, x)
subst = {a: A, b: B, c: C, d:D}
funcs = {Add: lambda x,y: x+y, Mul: lambda x,y: x*y }
def _to_matrix(expr):
if expr in subst:
return subst[expr]
if isinstance(expr, Pow):
return MatPow(_to_matrix(expr.args[0]), expr.args[1])
elif isinstance(expr, (Add, Mul)):
return reduce(funcs[expr.func],[_to_matrix(a) for a in expr.args])
else:
return expr*Identity(x)
def _check(expr, simplified, deep=True, matrix=True):
assert nc_simplify(expr, deep=deep) == simplified
assert expand(expr) == expand(simplified)
if matrix:
m_simp = _to_matrix(simplified).doit(inv_expand=False)
assert nc_simplify(_to_matrix(expr), deep=deep) == m_simp
_check(a*b*a*b*a*b*c*(a*b)**3*c, ((a*b)**3*c)**2)
_check(a*b*(a*b)**-2*a*b, 1)
_check(a**2*b*a*b*a*b*(a*b)**-1, a*(a*b)**2, matrix=False)
_check(b*a*b**2*a*b**2*a*b**2, b*(a*b**2)**3)
_check(a*b*a**2*b*a**2*b*a**3, (a*b*a)**3*a**2)
_check(a**2*b*a**4*b*a**4*b*a**2, (a**2*b*a**2)**3)
_check(a**3*b*a**4*b*a**4*b*a, a**3*(b*a**4)**3*a**-3)
_check(a*b*a*b + a*b*c*x*a*b*c, (a*b)**2 + x*(a*b*c)**2)
_check(a*b*a*b*c*a*b*a*b*c, ((a*b)**2*c)**2)
_check(b**-1*a**-1*(a*b)**2, a*b)
_check(a**-1*b*c**-1, (c*b**-1*a)**-1)
expr = a**3*b*a**4*b*a**4*b*a**2*b*a**2*(b*a**2)**2*b*a**2*b*a**2
for _ in range(10):
expr *= a*b
_check(expr, a**3*(b*a**4)**2*(b*a**2)**6*(a*b)**10)
_check((a*b*a*b)**2, (a*b*a*b)**2, deep=False)
_check(a*b*(c*d)**2, a*b*(c*d)**2)
expr = b**-1*(a**-1*b**-1 - a**-1*c*b**-1)**-1*a**-1
assert nc_simplify(expr) == (1-c)**-1
# commutative expressions should be returned without an error
assert nc_simplify(2*x**2) == 2*x**2
def test_issue_15965():
A = Sum(z*x**y, (x, 1, a))
anew = z*Sum(x**y, (x, 1, a))
B = Integral(x*y, x)
bdo = x**2*y/2
assert simplify(A + B) == anew + bdo
assert simplify(A) == anew
assert simplify(B) == bdo
assert simplify(B, doit=False) == y*Integral(x, x)
def test_issue_17137():
assert simplify(cos(x)**I) == cos(x)**I
assert simplify(cos(x)**(2 + 3*I)) == cos(x)**(2 + 3*I)
def test_issue_21869():
x = Symbol('x', real=True)
y = Symbol('y', real=True)
expr = And(Eq(x**2, 4), Le(x, y))
assert expr.simplify() == expr
expr = And(Eq(x**2, 4), Eq(x, 2))
assert expr.simplify() == Eq(x, 2)
expr = And(Eq(x**3, x**2), Eq(x, 1))
assert expr.simplify() == Eq(x, 1)
expr = And(Eq(sin(x), x**2), Eq(x, 0))
assert expr.simplify() == Eq(x, 0)
expr = And(Eq(x**3, x**2), Eq(x, 2))
assert expr.simplify() == S.false
expr = And(Eq(y, x**2), Eq(x, 1))
assert expr.simplify() == And(Eq(y,1), Eq(x, 1))
expr = And(Eq(y**2, 1), Eq(y, x**2), Eq(x, 1))
assert expr.simplify() == And(Eq(y,1), Eq(x, 1))
expr = And(Eq(y**2, 4), Eq(y, 2*x**2), Eq(x, 1))
assert expr.simplify() == And(Eq(y,2), Eq(x, 1))
expr = And(Eq(y**2, 4), Eq(y, x**2), Eq(x, 1))
assert expr.simplify() == S.false
def test_issue_7971_21740():
z = Integral(x, (x, 1, 1))
assert z != 0
assert simplify(z) is S.Zero
assert simplify(S.Zero) is S.Zero
z = simplify(Float(0))
assert z is not S.Zero and z == 0.0
@slow
def test_issue_17141_slow():
# Should not give RecursionError
assert simplify((2**acos(I+1)**2).rewrite('log')) == 2**((pi + 2*I*log(-1 +
sqrt(1 - 2*I) + I))**2/4)
def test_issue_17141():
# Check that there is no RecursionError
assert simplify(x**(1 / acos(I))) == x**(2/(pi - 2*I*log(1 + sqrt(2))))
assert simplify(acos(-I)**2*acos(I)**2) == \
log(1 + sqrt(2))**4 + pi**2*log(1 + sqrt(2))**2/2 + pi**4/16
assert simplify(2**acos(I)**2) == 2**((pi - 2*I*log(1 + sqrt(2)))**2/4)
p = 2**acos(I+1)**2
assert simplify(p) == p
def test_simplify_kroneckerdelta():
i, j = symbols("i j")
K = KroneckerDelta
assert simplify(K(i, j)) == K(i, j)
assert simplify(K(0, j)) == K(0, j)
assert simplify(K(i, 0)) == K(i, 0)
assert simplify(K(0, j).rewrite(Piecewise) * K(1, j)) == 0
assert simplify(K(1, i) + Piecewise((1, Eq(j, 2)), (0, True))) == K(1, i) + K(2, j)
# issue 17214
assert simplify(K(0, j) * K(1, j)) == 0
n = Symbol('n', integer=True)
assert simplify(K(0, n) * K(1, n)) == 0
M = Matrix(4, 4, lambda i, j: K(j - i, n) if i <= j else 0)
assert simplify(M**2) == Matrix([[K(0, n), 0, K(1, n), 0],
[0, K(0, n), 0, K(1, n)],
[0, 0, K(0, n), 0],
[0, 0, 0, K(0, n)]])
assert simplify(eye(1) * KroneckerDelta(0, n) *
KroneckerDelta(1, n)) == Matrix([[0]])
assert simplify(S.Infinity * KroneckerDelta(0, n) *
KroneckerDelta(1, n)) is S.NaN
def test_issue_17292():
assert simplify(abs(x)/abs(x**2)) == 1/abs(x)
# this is bigger than the issue: check that deep processing works
assert simplify(5*abs((x**2 - 1)/(x - 1))) == 5*Abs(x + 1)
def test_issue_19822():
expr = And(Gt(n-2, 1), Gt(n, 1))
assert simplify(expr) == Gt(n, 3)
def test_issue_18645():
expr = And(Ge(x, 3), Le(x, 3))
assert simplify(expr) == Eq(x, 3)
expr = And(Eq(x, 3), Le(x, 3))
assert simplify(expr) == Eq(x, 3)
@XFAIL
def test_issue_18642():
i = Symbol("i", integer=True)
n = Symbol("n", integer=True)
expr = And(Eq(i, 2 * n), Le(i, 2*n -1))
assert simplify(expr) == S.false
@XFAIL
def test_issue_18389():
n = Symbol("n", integer=True)
expr = Eq(n, 0) | (n >= 1)
assert simplify(expr) == Ge(n, 0)
def test_issue_8373():
x = Symbol('x', real=True)
assert simplify(Or(x < 1, x >= 1)) == S.true
def test_issue_7950():
expr = And(Eq(x, 1), Eq(x, 2))
assert simplify(expr) == S.false
def test_issue_22020():
expr = I*pi/2 -oo
assert simplify(expr) == expr
# Used to throw an error
def test_issue_19484():
assert simplify(sign(x) * Abs(x)) == x
e = x + sign(x + x**3)
assert simplify(Abs(x + x**3)*e) == x**3 + x*Abs(x**3 + x) + x
e = x**2 + sign(x**3 + 1)
assert simplify(Abs(x**3 + 1) * e) == x**3 + x**2*Abs(x**3 + 1) + 1
f = Function('f')
e = x + sign(x + f(x)**3)
assert simplify(Abs(x + f(x)**3) * e) == x*Abs(x + f(x)**3) + x + f(x)**3
def test_issue_23543():
# Used to give an error
x, y, z = symbols("x y z", commutative=False)
assert (x*(y + z/2)).simplify() == x*(2*y + z)/2
def test_issue_11004():
def f(n):
return sqrt(2*pi*n) * (n/E)**n
def m(n, k):
return f(n) / (f(n/k)**k)
def p(n,k):
return m(n, k) / (k**n)
N, k = symbols('N k')
half = Float('0.5', 4)
z = log(p(n, k) / p(n, k + 1)).expand(force=True)
r = simplify(z.subs(n, N).n(4))
assert r == (
half*k*log(k)
- half*k*log(k + 1)
+ half*log(N)
- half*log(k + 1)
+ Float(0.9189224, 4)
)
def test_issue_19161():
polynomial = Poly('x**2').simplify()
assert (polynomial-x**2).simplify() == 0
def test_issue_22210():
d = Symbol('d', integer=True)
expr = 2*Derivative(sin(x), (x, d))
assert expr.simplify() == expr
def test_reduce_inverses_nc_pow():
x, y = symbols("x y", commutative=True)
Z = symbols("Z", commutative=False)
assert simplify(2**Z * y**Z) == 2**Z * y**Z
assert simplify(x**Z * y**Z) == x**Z * y**Z
x, y = symbols("x y", positive=True)
assert expand((x*y)**Z) == x**Z * y**Z
assert simplify(x**Z * y**Z) == expand((x*y)**Z)