You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.

332 lines
15 KiB

from sympy.core.numbers import (E, I, Rational, oo, pi)
from sympy.core.singleton import S
from sympy.core.symbol import (Symbol, symbols)
from sympy.functions.elementary.complexes import (Abs, re)
from sympy.functions.elementary.exponential import (exp, log)
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.functions.elementary.piecewise import Piecewise
from sympy.functions.elementary.trigonometric import (cos, cot, csc, sec, sin, tan)
from sympy.functions.special.error_functions import expint
from sympy.matrices.expressions.matexpr import MatrixSymbol
from sympy.simplify.simplify import simplify
from sympy.calculus.util import (function_range, continuous_domain, not_empty_in,
periodicity, lcim, is_convex,
stationary_points, minimum, maximum)
from sympy.sets.sets import (Interval, FiniteSet, Complement, Union)
from sympy.testing.pytest import raises, _both_exp_pow
from sympy.abc import x
a = Symbol('a', real=True)
def test_function_range():
x, y, a, b = symbols('x y a b')
assert function_range(sin(x), x, Interval(-pi/2, pi/2)
) == Interval(-1, 1)
assert function_range(sin(x), x, Interval(0, pi)
) == Interval(0, 1)
assert function_range(tan(x), x, Interval(0, pi)
) == Interval(-oo, oo)
assert function_range(tan(x), x, Interval(pi/2, pi)
) == Interval(-oo, 0)
assert function_range((x + 3)/(x - 2), x, Interval(-5, 5)
) == Union(Interval(-oo, Rational(2, 7)), Interval(Rational(8, 3), oo))
assert function_range(1/(x**2), x, Interval(-1, 1)
) == Interval(1, oo)
assert function_range(exp(x), x, Interval(-1, 1)
) == Interval(exp(-1), exp(1))
assert function_range(log(x) - x, x, S.Reals
) == Interval(-oo, -1)
assert function_range(sqrt(3*x - 1), x, Interval(0, 2)
) == Interval(0, sqrt(5))
assert function_range(x*(x - 1) - (x**2 - x), x, S.Reals
) == FiniteSet(0)
assert function_range(x*(x - 1) - (x**2 - x) + y, x, S.Reals
) == FiniteSet(y)
assert function_range(sin(x), x, Union(Interval(-5, -3), FiniteSet(4))
) == Union(Interval(-sin(3), 1), FiniteSet(sin(4)))
assert function_range(cos(x), x, Interval(-oo, -4)
) == Interval(-1, 1)
assert function_range(cos(x), x, S.EmptySet) == S.EmptySet
assert function_range(x/sqrt(x**2+1), x, S.Reals) == Interval.open(-1,1)
raises(NotImplementedError, lambda : function_range(
exp(x)*(sin(x) - cos(x))/2 - x, x, S.Reals))
raises(NotImplementedError, lambda : function_range(
sin(x) + x, x, S.Reals)) # issue 13273
raises(NotImplementedError, lambda : function_range(
log(x), x, S.Integers))
raises(NotImplementedError, lambda : function_range(
sin(x)/2, x, S.Naturals))
def test_continuous_domain():
x = Symbol('x')
assert continuous_domain(sin(x), x, Interval(0, 2*pi)) == Interval(0, 2*pi)
assert continuous_domain(tan(x), x, Interval(0, 2*pi)) == \
Union(Interval(0, pi/2, False, True), Interval(pi/2, pi*Rational(3, 2), True, True),
Interval(pi*Rational(3, 2), 2*pi, True, False))
assert continuous_domain((x - 1)/((x - 1)**2), x, S.Reals) == \
Union(Interval(-oo, 1, True, True), Interval(1, oo, True, True))
assert continuous_domain(log(x) + log(4*x - 1), x, S.Reals) == \
Interval(Rational(1, 4), oo, True, True)
assert continuous_domain(1/sqrt(x - 3), x, S.Reals) == Interval(3, oo, True, True)
assert continuous_domain(1/x - 2, x, S.Reals) == \
Union(Interval.open(-oo, 0), Interval.open(0, oo))
assert continuous_domain(1/(x**2 - 4) + 2, x, S.Reals) == \
Union(Interval.open(-oo, -2), Interval.open(-2, 2), Interval.open(2, oo))
domain = continuous_domain(log(tan(x)**2 + 1), x, S.Reals)
assert not domain.contains(3*pi/2)
assert domain.contains(5)
d = Symbol('d', even=True, zero=False)
assert continuous_domain(x**(1/d), x, S.Reals) == Interval(0, oo)
def test_not_empty_in():
assert not_empty_in(FiniteSet(x, 2*x).intersect(Interval(1, 2, True, False)), x) == \
Interval(S.Half, 2, True, False)
assert not_empty_in(FiniteSet(x, x**2).intersect(Interval(1, 2)), x) == \
Union(Interval(-sqrt(2), -1), Interval(1, 2))
assert not_empty_in(FiniteSet(x**2 + x, x).intersect(Interval(2, 4)), x) == \
Union(Interval(-sqrt(17)/2 - S.Half, -2),
Interval(1, Rational(-1, 2) + sqrt(17)/2), Interval(2, 4))
assert not_empty_in(FiniteSet(x/(x - 1)).intersect(S.Reals), x) == \
Complement(S.Reals, FiniteSet(1))
assert not_empty_in(FiniteSet(a/(a - 1)).intersect(S.Reals), a) == \
Complement(S.Reals, FiniteSet(1))
assert not_empty_in(FiniteSet((x**2 - 3*x + 2)/(x - 1)).intersect(S.Reals), x) == \
Complement(S.Reals, FiniteSet(1))
assert not_empty_in(FiniteSet(3, 4, x/(x - 1)).intersect(Interval(2, 3)), x) == \
Interval(-oo, oo)
assert not_empty_in(FiniteSet(4, x/(x - 1)).intersect(Interval(2, 3)), x) == \
Interval(S(3)/2, 2)
assert not_empty_in(FiniteSet(x/(x**2 - 1)).intersect(S.Reals), x) == \
Complement(S.Reals, FiniteSet(-1, 1))
assert not_empty_in(FiniteSet(x, x**2).intersect(Union(Interval(1, 3, True, True),
Interval(4, 5))), x) == \
Union(Interval(-sqrt(5), -2), Interval(-sqrt(3), -1, True, True),
Interval(1, 3, True, True), Interval(4, 5))
assert not_empty_in(FiniteSet(1).intersect(Interval(3, 4)), x) == S.EmptySet
assert not_empty_in(FiniteSet(x**2/(x + 2)).intersect(Interval(1, oo)), x) == \
Union(Interval(-2, -1, True, False), Interval(2, oo))
raises(ValueError, lambda: not_empty_in(x))
raises(ValueError, lambda: not_empty_in(Interval(0, 1), x))
raises(NotImplementedError,
lambda: not_empty_in(FiniteSet(x).intersect(S.Reals), x, a))
@_both_exp_pow
def test_periodicity():
x = Symbol('x')
y = Symbol('y')
z = Symbol('z', real=True)
assert periodicity(sin(2*x), x) == pi
assert periodicity((-2)*tan(4*x), x) == pi/4
assert periodicity(sin(x)**2, x) == 2*pi
assert periodicity(3**tan(3*x), x) == pi/3
assert periodicity(tan(x)*cos(x), x) == 2*pi
assert periodicity(sin(x)**(tan(x)), x) == 2*pi
assert periodicity(tan(x)*sec(x), x) == 2*pi
assert periodicity(sin(2*x)*cos(2*x) - y, x) == pi/2
assert periodicity(tan(x) + cot(x), x) == pi
assert periodicity(sin(x) - cos(2*x), x) == 2*pi
assert periodicity(sin(x) - 1, x) == 2*pi
assert periodicity(sin(4*x) + sin(x)*cos(x), x) == pi
assert periodicity(exp(sin(x)), x) == 2*pi
assert periodicity(log(cot(2*x)) - sin(cos(2*x)), x) == pi
assert periodicity(sin(2*x)*exp(tan(x) - csc(2*x)), x) == pi
assert periodicity(cos(sec(x) - csc(2*x)), x) == 2*pi
assert periodicity(tan(sin(2*x)), x) == pi
assert periodicity(2*tan(x)**2, x) == pi
assert periodicity(sin(x%4), x) == 4
assert periodicity(sin(x)%4, x) == 2*pi
assert periodicity(tan((3*x-2)%4), x) == Rational(4, 3)
assert periodicity((sqrt(2)*(x+1)+x) % 3, x) == 3 / (sqrt(2)+1)
assert periodicity((x**2+1) % x, x) is None
assert periodicity(sin(re(x)), x) == 2*pi
assert periodicity(sin(x)**2 + cos(x)**2, x) is S.Zero
assert periodicity(tan(x), y) is S.Zero
assert periodicity(sin(x) + I*cos(x), x) == 2*pi
assert periodicity(x - sin(2*y), y) == pi
assert periodicity(exp(x), x) is None
assert periodicity(exp(I*x), x) == 2*pi
assert periodicity(exp(I*z), z) == 2*pi
assert periodicity(exp(z), z) is None
assert periodicity(exp(log(sin(z) + I*cos(2*z)), evaluate=False), z) == 2*pi
assert periodicity(exp(log(sin(2*z) + I*cos(z)), evaluate=False), z) == 2*pi
assert periodicity(exp(sin(z)), z) == 2*pi
assert periodicity(exp(2*I*z), z) == pi
assert periodicity(exp(z + I*sin(z)), z) is None
assert periodicity(exp(cos(z/2) + sin(z)), z) == 4*pi
assert periodicity(log(x), x) is None
assert periodicity(exp(x)**sin(x), x) is None
assert periodicity(sin(x)**y, y) is None
assert periodicity(Abs(sin(Abs(sin(x)))), x) == pi
assert all(periodicity(Abs(f(x)), x) == pi for f in (
cos, sin, sec, csc, tan, cot))
assert periodicity(Abs(sin(tan(x))), x) == pi
assert periodicity(Abs(sin(sin(x) + tan(x))), x) == 2*pi
assert periodicity(sin(x) > S.Half, x) == 2*pi
assert periodicity(x > 2, x) is None
assert periodicity(x**3 - x**2 + 1, x) is None
assert periodicity(Abs(x), x) is None
assert periodicity(Abs(x**2 - 1), x) is None
assert periodicity((x**2 + 4)%2, x) is None
assert periodicity((E**x)%3, x) is None
assert periodicity(sin(expint(1, x))/expint(1, x), x) is None
# returning `None` for any Piecewise
p = Piecewise((0, x < -1), (x**2, x <= 1), (log(x), True))
assert periodicity(p, x) is None
m = MatrixSymbol('m', 3, 3)
raises(NotImplementedError, lambda: periodicity(sin(m), m))
raises(NotImplementedError, lambda: periodicity(sin(m[0, 0]), m))
raises(NotImplementedError, lambda: periodicity(sin(m), m[0, 0]))
raises(NotImplementedError, lambda: periodicity(sin(m[0, 0]), m[0, 0]))
def test_periodicity_check():
x = Symbol('x')
y = Symbol('y')
assert periodicity(tan(x), x, check=True) == pi
assert periodicity(sin(x) + cos(x), x, check=True) == 2*pi
assert periodicity(sec(x), x) == 2*pi
assert periodicity(sin(x*y), x) == 2*pi/abs(y)
assert periodicity(Abs(sec(sec(x))), x) == pi
def test_lcim():
assert lcim([S.Half, S(2), S(3)]) == 6
assert lcim([pi/2, pi/4, pi]) == pi
assert lcim([2*pi, pi/2]) == 2*pi
assert lcim([S.One, 2*pi]) is None
assert lcim([S(2) + 2*E, E/3 + Rational(1, 3), S.One + E]) == S(2) + 2*E
def test_is_convex():
assert is_convex(1/x, x, domain=Interval.open(0, oo)) == True
assert is_convex(1/x, x, domain=Interval(-oo, 0)) == False
assert is_convex(x**2, x, domain=Interval(0, oo)) == True
assert is_convex(1/x**3, x, domain=Interval.Lopen(0, oo)) == True
assert is_convex(-1/x**3, x, domain=Interval.Ropen(-oo, 0)) == True
assert is_convex(log(x), x) == False
raises(NotImplementedError, lambda: is_convex(log(x), x, a))
def test_stationary_points():
x, y = symbols('x y')
assert stationary_points(sin(x), x, Interval(-pi/2, pi/2)
) == {-pi/2, pi/2}
assert stationary_points(sin(x), x, Interval.Ropen(0, pi/4)
) is S.EmptySet
assert stationary_points(tan(x), x,
) is S.EmptySet
assert stationary_points(sin(x)*cos(x), x, Interval(0, pi)
) == {pi/4, pi*Rational(3, 4)}
assert stationary_points(sec(x), x, Interval(0, pi)
) == {0, pi}
assert stationary_points((x+3)*(x-2), x
) == FiniteSet(Rational(-1, 2))
assert stationary_points((x + 3)/(x - 2), x, Interval(-5, 5)
) is S.EmptySet
assert stationary_points((x**2+3)/(x-2), x
) == {2 - sqrt(7), 2 + sqrt(7)}
assert stationary_points((x**2+3)/(x-2), x, Interval(0, 5)
) == {2 + sqrt(7)}
assert stationary_points(x**4 + x**3 - 5*x**2, x, S.Reals
) == FiniteSet(-2, 0, Rational(5, 4))
assert stationary_points(exp(x), x
) is S.EmptySet
assert stationary_points(log(x) - x, x, S.Reals
) == {1}
assert stationary_points(cos(x), x, Union(Interval(0, 5), Interval(-6, -3))
) == {0, -pi, pi}
assert stationary_points(y, x, S.Reals
) == S.Reals
assert stationary_points(y, x, S.EmptySet) == S.EmptySet
def test_maximum():
x, y = symbols('x y')
assert maximum(sin(x), x) is S.One
assert maximum(sin(x), x, Interval(0, 1)) == sin(1)
assert maximum(tan(x), x) is oo
assert maximum(tan(x), x, Interval(-pi/4, pi/4)) is S.One
assert maximum(sin(x)*cos(x), x, S.Reals) == S.Half
assert simplify(maximum(sin(x)*cos(x), x, Interval(pi*Rational(3, 8), pi*Rational(5, 8)))
) == sqrt(2)/4
assert maximum((x+3)*(x-2), x) is oo
assert maximum((x+3)*(x-2), x, Interval(-5, 0)) == S(14)
assert maximum((x+3)/(x-2), x, Interval(-5, 0)) == Rational(2, 7)
assert simplify(maximum(-x**4-x**3+x**2+10, x)
) == 41*sqrt(41)/512 + Rational(5419, 512)
assert maximum(exp(x), x, Interval(-oo, 2)) == exp(2)
assert maximum(log(x) - x, x, S.Reals) is S.NegativeOne
assert maximum(cos(x), x, Union(Interval(0, 5), Interval(-6, -3))
) is S.One
assert maximum(cos(x)-sin(x), x, S.Reals) == sqrt(2)
assert maximum(y, x, S.Reals) == y
assert maximum(abs(a**3 + a), a, Interval(0, 2)) == 10
assert maximum(abs(60*a**3 + 24*a), a, Interval(0, 2)) == 528
assert maximum(abs(12*a*(5*a**2 + 2)), a, Interval(0, 2)) == 528
assert maximum(x/sqrt(x**2+1), x, S.Reals) == 1
raises(ValueError, lambda : maximum(sin(x), x, S.EmptySet))
raises(ValueError, lambda : maximum(log(cos(x)), x, S.EmptySet))
raises(ValueError, lambda : maximum(1/(x**2 + y**2 + 1), x, S.EmptySet))
raises(ValueError, lambda : maximum(sin(x), sin(x)))
raises(ValueError, lambda : maximum(sin(x), x*y, S.EmptySet))
raises(ValueError, lambda : maximum(sin(x), S.One))
def test_minimum():
x, y = symbols('x y')
assert minimum(sin(x), x) is S.NegativeOne
assert minimum(sin(x), x, Interval(1, 4)) == sin(4)
assert minimum(tan(x), x) is -oo
assert minimum(tan(x), x, Interval(-pi/4, pi/4)) is S.NegativeOne
assert minimum(sin(x)*cos(x), x, S.Reals) == Rational(-1, 2)
assert simplify(minimum(sin(x)*cos(x), x, Interval(pi*Rational(3, 8), pi*Rational(5, 8)))
) == -sqrt(2)/4
assert minimum((x+3)*(x-2), x) == Rational(-25, 4)
assert minimum((x+3)/(x-2), x, Interval(-5, 0)) == Rational(-3, 2)
assert minimum(x**4-x**3+x**2+10, x) == S(10)
assert minimum(exp(x), x, Interval(-2, oo)) == exp(-2)
assert minimum(log(x) - x, x, S.Reals) is -oo
assert minimum(cos(x), x, Union(Interval(0, 5), Interval(-6, -3))
) is S.NegativeOne
assert minimum(cos(x)-sin(x), x, S.Reals) == -sqrt(2)
assert minimum(y, x, S.Reals) == y
assert minimum(x/sqrt(x**2+1), x, S.Reals) == -1
raises(ValueError, lambda : minimum(sin(x), x, S.EmptySet))
raises(ValueError, lambda : minimum(log(cos(x)), x, S.EmptySet))
raises(ValueError, lambda : minimum(1/(x**2 + y**2 + 1), x, S.EmptySet))
raises(ValueError, lambda : minimum(sin(x), sin(x)))
raises(ValueError, lambda : minimum(sin(x), x*y, S.EmptySet))
raises(ValueError, lambda : minimum(sin(x), S.One))
def test_issue_19869():
t = symbols('t')
assert (maximum(sqrt(3)*(t - 1)/(3*sqrt(t**2 + 1)), t)
) == sqrt(3)/3
def test_issue_16469():
x = Symbol("x", real=True)
f = abs(x)
assert function_range(f, x, S.Reals) == Interval(0, oo, False, True)
@_both_exp_pow
def test_issue_18747():
assert periodicity(exp(pi*I*(x/4+S.Half/2)), x) == 8