340 lines
7.3 KiB
Python
340 lines
7.3 KiB
Python
import pytest
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import numpy as np
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import numpy.testing as npt
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import scipy.sparse
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import scipy.sparse.linalg as spla
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sparray_types = ('bsr', 'coo', 'csc', 'csr', 'dia', 'dok', 'lil')
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sparray_classes = [
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getattr(scipy.sparse, f'{T}_array') for T in sparray_types
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]
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A = np.array([
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[0, 1, 2, 0],
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[2, 0, 0, 3],
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[1, 4, 0, 0]
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])
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B = np.array([
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[0, 1],
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[2, 0]
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])
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X = np.array([
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[1, 0, 0, 1],
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[2, 1, 2, 0],
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[0, 2, 1, 0],
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[0, 0, 1, 2]
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], dtype=float)
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sparrays = [sparray(A) for sparray in sparray_classes]
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square_sparrays = [sparray(B) for sparray in sparray_classes]
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eig_sparrays = [sparray(X) for sparray in sparray_classes]
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parametrize_sparrays = pytest.mark.parametrize(
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"A", sparrays, ids=sparray_types
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)
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parametrize_square_sparrays = pytest.mark.parametrize(
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"B", square_sparrays, ids=sparray_types
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)
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parametrize_eig_sparrays = pytest.mark.parametrize(
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"X", eig_sparrays, ids=sparray_types
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)
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@parametrize_sparrays
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def test_sum(A):
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assert not isinstance(A.sum(axis=0), np.matrix), \
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"Expected array, got matrix"
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assert A.sum(axis=0).shape == (4,)
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assert A.sum(axis=1).shape == (3,)
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@parametrize_sparrays
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def test_mean(A):
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assert not isinstance(A.mean(axis=1), np.matrix), \
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"Expected array, got matrix"
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@parametrize_sparrays
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def test_todense(A):
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assert not isinstance(A.todense(), np.matrix), \
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"Expected array, got matrix"
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@parametrize_sparrays
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def test_indexing(A):
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if A.__class__.__name__[:3] in ('dia', 'coo', 'bsr'):
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return
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with pytest.raises(NotImplementedError):
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A[1, :]
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with pytest.raises(NotImplementedError):
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A[:, 1]
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with pytest.raises(NotImplementedError):
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A[1, [1, 2]]
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with pytest.raises(NotImplementedError):
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A[[1, 2], 1]
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assert A[[0]]._is_array, "Expected sparse array, got sparse matrix"
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assert A[1, [[1, 2]]]._is_array, "Expected ndarray, got sparse array"
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assert A[[[1, 2]], 1]._is_array, "Expected ndarray, got sparse array"
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assert A[:, [1, 2]]._is_array, "Expected sparse array, got something else"
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@parametrize_sparrays
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def test_dense_addition(A):
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X = np.random.random(A.shape)
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assert not isinstance(A + X, np.matrix), "Expected array, got matrix"
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@parametrize_sparrays
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def test_sparse_addition(A):
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assert (A + A)._is_array, "Expected array, got matrix"
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@parametrize_sparrays
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def test_elementwise_mul(A):
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assert np.all((A * A).todense() == A.power(2).todense())
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@parametrize_sparrays
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def test_elementwise_rmul(A):
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with pytest.raises(TypeError):
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None * A
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with pytest.raises(ValueError):
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np.eye(3) * scipy.sparse.csr_array(np.arange(6).reshape(2, 3))
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assert np.all((2 * A) == (A.todense() * 2))
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assert np.all((A.todense() * A) == (A.todense() ** 2))
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@parametrize_sparrays
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def test_matmul(A):
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assert np.all((A @ A.T).todense() == A.dot(A.T).todense())
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@parametrize_square_sparrays
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def test_pow(B):
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assert (B**0)._is_array, "Expected array, got matrix"
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assert (B**2)._is_array, "Expected array, got matrix"
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@parametrize_sparrays
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def test_sparse_divide(A):
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assert isinstance(A / A, np.ndarray)
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@parametrize_sparrays
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def test_dense_divide(A):
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assert (A / 2)._is_array, "Expected array, got matrix"
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@parametrize_sparrays
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def test_no_A_attr(A):
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with pytest.warns(np.VisibleDeprecationWarning):
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A.A
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@parametrize_sparrays
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def test_no_H_attr(A):
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with pytest.warns(np.VisibleDeprecationWarning):
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A.H
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@parametrize_sparrays
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def test_getrow_getcol(A):
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assert A.getcol(0)._is_array
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assert A.getrow(0)._is_array
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@parametrize_sparrays
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def test_docstr(A):
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if A.__doc__ is None:
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return
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docstr = A.__doc__.lower()
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for phrase in ('matrix', 'matrices'):
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assert phrase not in docstr
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# -- linalg --
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@parametrize_sparrays
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def test_as_linearoperator(A):
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L = spla.aslinearoperator(A)
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npt.assert_allclose(L * [1, 2, 3, 4], A @ [1, 2, 3, 4])
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@parametrize_square_sparrays
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def test_inv(B):
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if B.__class__.__name__[:3] != 'csc':
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return
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C = spla.inv(B)
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assert C._is_array
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npt.assert_allclose(C.todense(), np.linalg.inv(B.todense()))
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@parametrize_square_sparrays
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def test_expm(B):
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if B.__class__.__name__[:3] != 'csc':
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return
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Bmat = scipy.sparse.csc_matrix(B)
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C = spla.expm(B)
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assert C._is_array
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npt.assert_allclose(
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C.todense(),
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spla.expm(Bmat).todense()
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)
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@parametrize_square_sparrays
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def test_expm_multiply(B):
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if B.__class__.__name__[:3] != 'csc':
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return
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npt.assert_allclose(
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spla.expm_multiply(B, np.array([1, 2])),
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spla.expm(B) @ [1, 2]
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)
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@parametrize_sparrays
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def test_norm(A):
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C = spla.norm(A)
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npt.assert_allclose(C, np.linalg.norm(A.todense()))
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@parametrize_square_sparrays
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def test_onenormest(B):
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C = spla.onenormest(B)
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npt.assert_allclose(C, np.linalg.norm(B.todense(), 1))
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@parametrize_square_sparrays
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def test_spsolve(B):
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if B.__class__.__name__[:3] not in ('csc', 'csr'):
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return
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npt.assert_allclose(
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spla.spsolve(B, [1, 2]),
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np.linalg.solve(B.todense(), [1, 2])
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)
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def test_spsolve_triangular():
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X = scipy.sparse.csr_array([
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[1, 0, 0, 0],
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[2, 1, 0, 0],
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[3, 2, 1, 0],
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[4, 3, 2, 1],
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])
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spla.spsolve_triangular(X, [1, 2, 3, 4])
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@parametrize_square_sparrays
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def test_factorized(B):
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if B.__class__.__name__[:3] != 'csc':
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return
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LU = spla.factorized(B)
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npt.assert_allclose(
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LU(np.array([1, 2])),
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np.linalg.solve(B.todense(), [1, 2])
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)
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@parametrize_square_sparrays
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@pytest.mark.parametrize(
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"solver",
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["bicg", "bicgstab", "cg", "cgs", "gmres", "lgmres", "minres", "qmr",
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"gcrotmk", "tfqmr"]
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)
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def test_solvers(B, solver):
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if solver == "minres":
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kwargs = {}
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else:
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kwargs = {'atol': 1e-5}
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x, info = getattr(spla, solver)(B, np.array([1, 2]), **kwargs)
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assert info >= 0 # no errors, even if perhaps did not converge fully
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npt.assert_allclose(x, [1, 1], atol=1e-1)
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@parametrize_sparrays
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@pytest.mark.parametrize(
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"solver",
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["lsqr", "lsmr"]
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)
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def test_lstsqr(A, solver):
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x, *_ = getattr(spla, solver)(A, [1, 2, 3])
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npt.assert_allclose(A @ x, [1, 2, 3])
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@parametrize_eig_sparrays
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def test_eigs(X):
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e, v = spla.eigs(X, k=1)
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npt.assert_allclose(
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X @ v,
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e[0] * v
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)
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@parametrize_eig_sparrays
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def test_eigsh(X):
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X = X + X.T
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e, v = spla.eigsh(X, k=1)
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npt.assert_allclose(
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X @ v,
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e[0] * v
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)
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@parametrize_eig_sparrays
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def test_svds(X):
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u, s, vh = spla.svds(X, k=3)
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u2, s2, vh2 = np.linalg.svd(X.todense())
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s = np.sort(s)
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s2 = np.sort(s2[:3])
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npt.assert_allclose(s, s2, atol=1e-3)
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def test_splu():
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X = scipy.sparse.csc_array([
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[1, 0, 0, 0],
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[2, 1, 0, 0],
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[3, 2, 1, 0],
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[4, 3, 2, 1],
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])
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LU = spla.splu(X)
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npt.assert_allclose(LU.solve(np.array([1, 2, 3, 4])), [1, 0, 0, 0])
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def test_spilu():
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X = scipy.sparse.csc_array([
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[1, 0, 0, 0],
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[2, 1, 0, 0],
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[3, 2, 1, 0],
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[4, 3, 2, 1],
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])
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LU = spla.spilu(X)
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npt.assert_allclose(LU.solve(np.array([1, 2, 3, 4])), [1, 0, 0, 0])
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@parametrize_sparrays
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def test_power_operator(A):
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# https://github.com/scipy/scipy/issues/15948
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npt.assert_equal((A**2).todense(), (A.todense())**2)
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