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import pytest | |
from mpmath import * | |
def ae(a, b): | |
return abs(a-b) < 10**(-mp.dps+5) | |
def test_basic_integrals(): | |
for prec in [15, 30, 100]: | |
mp.dps = prec | |
assert ae(quadts(lambda x: x**3 - 3*x**2, [-2, 4]), -12) | |
assert ae(quadgl(lambda x: x**3 - 3*x**2, [-2, 4]), -12) | |
assert ae(quadts(sin, [0, pi]), 2) | |
assert ae(quadts(sin, [0, 2*pi]), 0) | |
assert ae(quadts(exp, [-inf, -1]), 1/e) | |
assert ae(quadts(lambda x: exp(-x), [0, inf]), 1) | |
assert ae(quadts(lambda x: exp(-x*x), [-inf, inf]), sqrt(pi)) | |
assert ae(quadts(lambda x: 1/(1+x*x), [-1, 1]), pi/2) | |
assert ae(quadts(lambda x: 1/(1+x*x), [-inf, inf]), pi) | |
assert ae(quadts(lambda x: 2*sqrt(1-x*x), [-1, 1]), pi) | |
mp.dps = 15 | |
def test_multiple_intervals(): | |
y,err = quad(lambda x: sign(x), [-0.5, 0.9, 1], maxdegree=2, error=True) | |
assert abs(y-0.5) < 2*err | |
def test_quad_symmetry(): | |
assert quadts(sin, [-1, 1]) == 0 | |
assert quadgl(sin, [-1, 1]) == 0 | |
def test_quad_infinite_mirror(): | |
# Check mirrored infinite interval | |
assert ae(quad(lambda x: exp(-x*x), [inf,-inf]), -sqrt(pi)) | |
assert ae(quad(lambda x: exp(x), [0,-inf]), -1) | |
def test_quadgl_linear(): | |
assert quadgl(lambda x: x, [0, 1], maxdegree=1).ae(0.5) | |
def test_complex_integration(): | |
assert quadts(lambda x: x, [0, 1+j]).ae(j) | |
def test_quadosc(): | |
mp.dps = 15 | |
assert quadosc(lambda x: sin(x)/x, [0, inf], period=2*pi).ae(pi/2) | |
# Double integrals | |
def test_double_trivial(): | |
assert ae(quadts(lambda x, y: x, [0, 1], [0, 1]), 0.5) | |
assert ae(quadts(lambda x, y: x, [-1, 1], [-1, 1]), 0.0) | |
def test_double_1(): | |
assert ae(quadts(lambda x, y: cos(x+y/2), [-pi/2, pi/2], [0, pi]), 4) | |
def test_double_2(): | |
assert ae(quadts(lambda x, y: (x-1)/((1-x*y)*log(x*y)), [0, 1], [0, 1]), euler) | |
def test_double_3(): | |
assert ae(quadts(lambda x, y: 1/sqrt(1+x*x+y*y), [-1, 1], [-1, 1]), 4*log(2+sqrt(3))-2*pi/3) | |
def test_double_4(): | |
assert ae(quadts(lambda x, y: 1/(1-x*x * y*y), [0, 1], [0, 1]), pi**2 / 8) | |
def test_double_5(): | |
assert ae(quadts(lambda x, y: 1/(1-x*y), [0, 1], [0, 1]), pi**2 / 6) | |
def test_double_6(): | |
assert ae(quadts(lambda x, y: exp(-(x+y)), [0, inf], [0, inf]), 1) | |
def test_double_7(): | |
assert ae(quadts(lambda x, y: exp(-x*x-y*y), [-inf, inf], [-inf, inf]), pi) | |
# Test integrals from "Experimentation in Mathematics" by Borwein, | |
# Bailey & Girgensohn | |
def test_expmath_integrals(): | |
for prec in [15, 30, 50]: | |
mp.dps = prec | |
assert ae(quadts(lambda x: x/sinh(x), [0, inf]), pi**2 / 4) | |
assert ae(quadts(lambda x: log(x)**2 / (1+x**2), [0, inf]), pi**3 / 8) | |
assert ae(quadts(lambda x: (1+x**2)/(1+x**4), [0, inf]), pi/sqrt(2)) | |
assert ae(quadts(lambda x: log(x)/cosh(x)**2, [0, inf]), log(pi)-2*log(2)-euler) | |
assert ae(quadts(lambda x: log(1+x**3)/(1-x+x**2), [0, inf]), 2*pi*log(3)/sqrt(3)) | |
assert ae(quadts(lambda x: log(x)**2 / (x**2+x+1), [0, 1]), 8*pi**3 / (81*sqrt(3))) | |
assert ae(quadts(lambda x: log(cos(x))**2, [0, pi/2]), pi/2 * (log(2)**2+pi**2/12)) | |
assert ae(quadts(lambda x: x**2 / sin(x)**2, [0, pi/2]), pi*log(2)) | |
assert ae(quadts(lambda x: x**2/sqrt(exp(x)-1), [0, inf]), 4*pi*(log(2)**2 + pi**2/12)) | |
assert ae(quadts(lambda x: x*exp(-x)*sqrt(1-exp(-2*x)), [0, inf]), pi*(1+2*log(2))/8) | |
mp.dps = 15 | |
# Do not reach full accuracy | |
def test_expmath_fail(): | |
assert ae(quadts(lambda x: sqrt(tan(x)), [0, pi/2]), pi*sqrt(2)/2) | |
assert ae(quadts(lambda x: atan(x)/(x*sqrt(1-x**2)), [0, 1]), pi*log(1+sqrt(2))/2) | |
assert ae(quadts(lambda x: log(1+x**2)/x**2, [0, 1]), pi/2-log(2)) | |
assert ae(quadts(lambda x: x**2/((1+x**4)*sqrt(1-x**4)), [0, 1]), pi/8) | |