3RNN/Lib/site-packages/scipy/linalg/tests/test_cythonized_array_utils.py
2024-05-26 19:49:15 +02:00

122 lines
3.8 KiB
Python

import numpy as np
from scipy.linalg import bandwidth, issymmetric, ishermitian
import pytest
from pytest import raises
def test_bandwidth_dtypes():
n = 5
for t in np.typecodes['All']:
A = np.zeros([n, n], dtype=t)
if t in 'eUVOMm':
raises(TypeError, bandwidth, A)
elif t == 'G': # No-op test. On win these pass on others fail.
pass
else:
_ = bandwidth(A)
def test_bandwidth_non2d_input():
A = np.array([1, 2, 3])
raises(ValueError, bandwidth, A)
A = np.array([[[1, 2, 3], [4, 5, 6]]])
raises(ValueError, bandwidth, A)
@pytest.mark.parametrize('T', [x for x in np.typecodes['All']
if x not in 'eGUVOMm'])
def test_bandwidth_square_inputs(T):
n = 20
k = 4
R = np.zeros([n, n], dtype=T, order='F')
# form a banded matrix inplace
R[[x for x in range(n)], [x for x in range(n)]] = 1
R[[x for x in range(n-k)], [x for x in range(k, n)]] = 1
R[[x for x in range(1, n)], [x for x in range(n-1)]] = 1
R[[x for x in range(k, n)], [x for x in range(n-k)]] = 1
assert bandwidth(R) == (k, k)
@pytest.mark.parametrize('T', [x for x in np.typecodes['All']
if x not in 'eGUVOMm'])
def test_bandwidth_rect_inputs(T):
n, m = 10, 20
k = 5
R = np.zeros([n, m], dtype=T, order='F')
# form a banded matrix inplace
R[[x for x in range(n)], [x for x in range(n)]] = 1
R[[x for x in range(n-k)], [x for x in range(k, n)]] = 1
R[[x for x in range(1, n)], [x for x in range(n-1)]] = 1
R[[x for x in range(k, n)], [x for x in range(n-k)]] = 1
assert bandwidth(R) == (k, k)
def test_issymetric_ishermitian_dtypes():
n = 5
for t in np.typecodes['All']:
A = np.zeros([n, n], dtype=t)
if t in 'eUVOMm':
raises(TypeError, issymmetric, A)
raises(TypeError, ishermitian, A)
elif t == 'G': # No-op test. On win these pass on others fail.
pass
else:
assert issymmetric(A)
assert ishermitian(A)
def test_issymmetric_ishermitian_invalid_input():
A = np.array([1, 2, 3])
raises(ValueError, issymmetric, A)
raises(ValueError, ishermitian, A)
A = np.array([[[1, 2, 3], [4, 5, 6]]])
raises(ValueError, issymmetric, A)
raises(ValueError, ishermitian, A)
A = np.array([[1, 2, 3], [4, 5, 6]])
raises(ValueError, issymmetric, A)
raises(ValueError, ishermitian, A)
def test_issymetric_complex_decimals():
A = np.arange(1, 10).astype(complex).reshape(3, 3)
A += np.arange(-4, 5).astype(complex).reshape(3, 3)*1j
# make entries decimal
A /= np.pi
A = A + A.T
assert issymmetric(A)
def test_ishermitian_complex_decimals():
A = np.arange(1, 10).astype(complex).reshape(3, 3)
A += np.arange(-4, 5).astype(complex).reshape(3, 3)*1j
# make entries decimal
A /= np.pi
A = A + A.T.conj()
assert ishermitian(A)
def test_issymmetric_approximate_results():
n = 20
rng = np.random.RandomState(123456789)
x = rng.uniform(high=5., size=[n, n])
y = x @ x.T # symmetric
p = rng.standard_normal([n, n])
z = p @ y @ p.T
assert issymmetric(z, atol=1e-10)
assert issymmetric(z, atol=1e-10, rtol=0.)
assert issymmetric(z, atol=0., rtol=1e-12)
assert issymmetric(z, atol=1e-13, rtol=1e-12)
def test_ishermitian_approximate_results():
n = 20
rng = np.random.RandomState(987654321)
x = rng.uniform(high=5., size=[n, n])
y = x @ x.T # symmetric
p = rng.standard_normal([n, n]) + rng.standard_normal([n, n])*1j
z = p @ y @ p.conj().T
assert ishermitian(z, atol=1e-10)
assert ishermitian(z, atol=1e-10, rtol=0.)
assert ishermitian(z, atol=0., rtol=1e-12)
assert ishermitian(z, atol=1e-13, rtol=1e-12)