import numpy as np from numpy.testing import assert_allclose, assert_equal import pytest import scipy.special as sc class TestInverseErrorFunction: def test_compliment(self): # Test erfcinv(1 - x) == erfinv(x) x = np.linspace(-1, 1, 101) assert_allclose(sc.erfcinv(1 - x), sc.erfinv(x), rtol=0, atol=1e-15) def test_literal_values(self): # calculated via https://keisan.casio.com/exec/system/1180573448 # for y = 0, 0.1, ... , 0.9 actual = sc.erfinv(np.linspace(0, 0.9, 10)) expected = [ 0, 0.08885599049425768701574, 0.1791434546212916764928, 0.27246271472675435562, 0.3708071585935579290583, 0.4769362762044698733814, 0.5951160814499948500193, 0.7328690779592168522188, 0.9061938024368232200712, 1.163087153676674086726, ] assert_allclose(actual, expected, rtol=0, atol=1e-15) @pytest.mark.parametrize( 'f, x, y', [ (sc.erfinv, -1, -np.inf), (sc.erfinv, 0, 0), (sc.erfinv, 1, np.inf), (sc.erfinv, -100, np.nan), (sc.erfinv, 100, np.nan), (sc.erfcinv, 0, np.inf), (sc.erfcinv, 1, -0.0), (sc.erfcinv, 2, -np.inf), (sc.erfcinv, -100, np.nan), (sc.erfcinv, 100, np.nan), ], ids=[ 'erfinv at lower bound', 'erfinv at midpoint', 'erfinv at upper bound', 'erfinv below lower bound', 'erfinv above upper bound', 'erfcinv at lower bound', 'erfcinv at midpoint', 'erfcinv at upper bound', 'erfcinv below lower bound', 'erfcinv above upper bound', ] ) def test_domain_bounds(self, f, x, y): assert_equal(f(x), y)