from __future__ import annotations import pytest from pybind11_tests import ConstructorStats np = pytest.importorskip("numpy") m = pytest.importorskip("pybind11_tests.eigen_matrix") ref = np.array( [ [0.0, 3, 0, 0, 0, 11], [22, 0, 0, 0, 17, 11], [7, 5, 0, 1, 0, 11], [0, 0, 0, 0, 0, 11], [0, 0, 14, 0, 8, 11], ] ) def assert_equal_ref(mat): np.testing.assert_array_equal(mat, ref) def assert_sparse_equal_ref(sparse_mat): assert_equal_ref(sparse_mat.toarray()) def test_fixed(): assert_equal_ref(m.fixed_c()) assert_equal_ref(m.fixed_r()) assert_equal_ref(m.fixed_copy_r(m.fixed_r())) assert_equal_ref(m.fixed_copy_c(m.fixed_c())) assert_equal_ref(m.fixed_copy_r(m.fixed_c())) assert_equal_ref(m.fixed_copy_c(m.fixed_r())) def test_dense(): assert_equal_ref(m.dense_r()) assert_equal_ref(m.dense_c()) assert_equal_ref(m.dense_copy_r(m.dense_r())) assert_equal_ref(m.dense_copy_c(m.dense_c())) assert_equal_ref(m.dense_copy_r(m.dense_c())) assert_equal_ref(m.dense_copy_c(m.dense_r())) def test_partially_fixed(): ref2 = np.array([[0.0, 1, 2, 3], [4, 5, 6, 7], [8, 9, 10, 11], [12, 13, 14, 15]]) np.testing.assert_array_equal(m.partial_copy_four_rm_r(ref2), ref2) np.testing.assert_array_equal(m.partial_copy_four_rm_c(ref2), ref2) np.testing.assert_array_equal(m.partial_copy_four_rm_r(ref2[:, 1]), ref2[:, [1]]) np.testing.assert_array_equal(m.partial_copy_four_rm_c(ref2[0, :]), ref2[[0], :]) np.testing.assert_array_equal( m.partial_copy_four_rm_r(ref2[:, (0, 2)]), ref2[:, (0, 2)] ) np.testing.assert_array_equal( m.partial_copy_four_rm_c(ref2[(3, 1, 2), :]), ref2[(3, 1, 2), :] ) np.testing.assert_array_equal(m.partial_copy_four_cm_r(ref2), ref2) np.testing.assert_array_equal(m.partial_copy_four_cm_c(ref2), ref2) np.testing.assert_array_equal(m.partial_copy_four_cm_r(ref2[:, 1]), ref2[:, [1]]) np.testing.assert_array_equal(m.partial_copy_four_cm_c(ref2[0, :]), ref2[[0], :]) np.testing.assert_array_equal( m.partial_copy_four_cm_r(ref2[:, (0, 2)]), ref2[:, (0, 2)] ) np.testing.assert_array_equal( m.partial_copy_four_cm_c(ref2[(3, 1, 2), :]), ref2[(3, 1, 2), :] ) # TypeError should be raise for a shape mismatch functions = [ m.partial_copy_four_rm_r, m.partial_copy_four_rm_c, m.partial_copy_four_cm_r, m.partial_copy_four_cm_c, ] matrix_with_wrong_shape = [[1, 2], [3, 4]] for f in functions: with pytest.raises(TypeError) as excinfo: f(matrix_with_wrong_shape) assert "incompatible function arguments" in str(excinfo.value) def test_mutator_descriptors(): zr = np.arange(30, dtype="float32").reshape(5, 6) # row-major zc = zr.reshape(6, 5).transpose() # column-major m.fixed_mutator_r(zr) m.fixed_mutator_c(zc) m.fixed_mutator_a(zr) m.fixed_mutator_a(zc) with pytest.raises(TypeError) as excinfo: m.fixed_mutator_r(zc) assert ( "(arg0: numpy.typing.NDArray[numpy.float32[5, 6]," " flags.writeable, flags.c_contiguous]) -> None" in str(excinfo.value) ) with pytest.raises(TypeError) as excinfo: m.fixed_mutator_c(zr) assert ( "(arg0: numpy.typing.NDArray[numpy.float32[5, 6]," " flags.writeable, flags.f_contiguous]) -> None" in str(excinfo.value) ) with pytest.raises(TypeError) as excinfo: m.fixed_mutator_a(np.array([[1, 2], [3, 4]], dtype="float32")) assert ( "(arg0: numpy.typing.NDArray[numpy.float32[5, 6], flags.writeable]) -> None" in str(excinfo.value) ) zr.flags.writeable = False with pytest.raises(TypeError): m.fixed_mutator_r(zr) with pytest.raises(TypeError): m.fixed_mutator_a(zr) def test_cpp_casting(): assert m.cpp_copy(m.fixed_r()) == 22.0 assert m.cpp_copy(m.fixed_c()) == 22.0 z = np.array([[5.0, 6], [7, 8]]) assert m.cpp_copy(z) == 7.0 assert m.cpp_copy(m.get_cm_ref()) == 21.0 assert m.cpp_copy(m.get_rm_ref()) == 21.0 assert m.cpp_ref_c(m.get_cm_ref()) == 21.0 assert m.cpp_ref_r(m.get_rm_ref()) == 21.0 with pytest.raises(RuntimeError) as excinfo: # Can't reference m.fixed_c: it contains floats, m.cpp_ref_any wants doubles m.cpp_ref_any(m.fixed_c()) assert "Unable to cast Python instance" in str(excinfo.value) with pytest.raises(RuntimeError) as excinfo: # Can't reference m.fixed_r: it contains floats, m.cpp_ref_any wants doubles m.cpp_ref_any(m.fixed_r()) assert "Unable to cast Python instance" in str(excinfo.value) assert m.cpp_ref_any(m.ReturnTester.create()) == 1.0 assert m.cpp_ref_any(m.get_cm_ref()) == 21.0 assert m.cpp_ref_any(m.get_cm_ref()) == 21.0 def test_pass_readonly_array(): z = np.full((5, 6), 42.0) z.flags.writeable = False np.testing.assert_array_equal(z, m.fixed_copy_r(z)) np.testing.assert_array_equal(m.fixed_r_const(), m.fixed_r()) assert not m.fixed_r_const().flags.writeable np.testing.assert_array_equal(m.fixed_copy_r(m.fixed_r_const()), m.fixed_r_const()) def test_nonunit_stride_from_python(): counting_mat = np.arange(9.0, dtype=np.float32).reshape((3, 3)) second_row = counting_mat[1, :] second_col = counting_mat[:, 1] np.testing.assert_array_equal(m.double_row(second_row), 2.0 * second_row) np.testing.assert_array_equal(m.double_col(second_row), 2.0 * second_row) np.testing.assert_array_equal(m.double_complex(second_row), 2.0 * second_row) np.testing.assert_array_equal(m.double_row(second_col), 2.0 * second_col) np.testing.assert_array_equal(m.double_col(second_col), 2.0 * second_col) np.testing.assert_array_equal(m.double_complex(second_col), 2.0 * second_col) counting_3d = np.arange(27.0, dtype=np.float32).reshape((3, 3, 3)) slices = [counting_3d[0, :, :], counting_3d[:, 0, :], counting_3d[:, :, 0]] for ref_mat in slices: np.testing.assert_array_equal(m.double_mat_cm(ref_mat), 2.0 * ref_mat) np.testing.assert_array_equal(m.double_mat_rm(ref_mat), 2.0 * ref_mat) # Mutator: m.double_threer(second_row) m.double_threec(second_col) np.testing.assert_array_equal(counting_mat, [[0.0, 2, 2], [6, 16, 10], [6, 14, 8]]) def test_negative_stride_from_python(msg): """Eigen doesn't support (as of yet) negative strides. When a function takes an Eigen matrix by copy or const reference, we can pass a numpy array that has negative strides. Otherwise, an exception will be thrown as Eigen will not be able to map the numpy array.""" counting_mat = np.arange(9.0, dtype=np.float32).reshape((3, 3)) counting_mat = counting_mat[::-1, ::-1] second_row = counting_mat[1, :] second_col = counting_mat[:, 1] np.testing.assert_array_equal(m.double_row(second_row), 2.0 * second_row) np.testing.assert_array_equal(m.double_col(second_row), 2.0 * second_row) np.testing.assert_array_equal(m.double_complex(second_row), 2.0 * second_row) np.testing.assert_array_equal(m.double_row(second_col), 2.0 * second_col) np.testing.assert_array_equal(m.double_col(second_col), 2.0 * second_col) np.testing.assert_array_equal(m.double_complex(second_col), 2.0 * second_col) counting_3d = np.arange(27.0, dtype=np.float32).reshape((3, 3, 3)) counting_3d = counting_3d[::-1, ::-1, ::-1] slices = [counting_3d[0, :, :], counting_3d[:, 0, :], counting_3d[:, :, 0]] for ref_mat in slices: np.testing.assert_array_equal(m.double_mat_cm(ref_mat), 2.0 * ref_mat) np.testing.assert_array_equal(m.double_mat_rm(ref_mat), 2.0 * ref_mat) # Mutator: with pytest.raises(TypeError) as excinfo: m.double_threer(second_row) assert ( msg(excinfo.value) == """ double_threer(): incompatible function arguments. The following argument types are supported: 1. (arg0: numpy.typing.NDArray[numpy.float32[1, 3], flags.writeable]) -> None Invoked with: """ + repr(np.array([5.0, 4.0, 3.0], dtype="float32")) ) with pytest.raises(TypeError) as excinfo: m.double_threec(second_col) assert ( msg(excinfo.value) == """ double_threec(): incompatible function arguments. The following argument types are supported: 1. (arg0: numpy.typing.NDArray[numpy.float32[3, 1], flags.writeable]) -> None Invoked with: """ + repr(np.array([7.0, 4.0, 1.0], dtype="float32")) ) def test_block_runtime_error_type_caster_eigen_ref_made_a_copy(): with pytest.raises(RuntimeError) as excinfo: m.block(ref, 0, 0, 0, 0) assert str(excinfo.value) == "type_caster for Eigen::Ref made a copy." def test_nonunit_stride_to_python(): assert np.all(m.diagonal(ref) == ref.diagonal()) assert np.all(m.diagonal_1(ref) == ref.diagonal(1)) for i in range(-5, 7): assert np.all(m.diagonal_n(ref, i) == ref.diagonal(i)), f"m.diagonal_n({i})" # Must be order="F", otherwise the type_caster will make a copy and # m.block() will return a dangling reference (heap-use-after-free). rof = np.asarray(ref, order="F") assert np.all(m.block(rof, 2, 1, 3, 3) == rof[2:5, 1:4]) assert np.all(m.block(rof, 1, 4, 4, 2) == rof[1:, 4:]) assert np.all(m.block(rof, 1, 4, 3, 2) == rof[1:4, 4:]) def test_eigen_ref_to_python(): chols = [m.cholesky1, m.cholesky2, m.cholesky3, m.cholesky4] for i, chol in enumerate(chols, start=1): mymat = chol(np.array([[1.0, 2, 4], [2, 13, 23], [4, 23, 77]])) assert np.all( mymat == np.array([[1, 0, 0], [2, 3, 0], [4, 5, 6]]) ), f"cholesky{i}" def assign_both(a1, a2, r, c, v): a1[r, c] = v a2[r, c] = v def array_copy_but_one(a, r, c, v): z = np.array(a, copy=True) z[r, c] = v return z def test_eigen_return_references(): """Tests various ways of returning references and non-referencing copies""" primary = np.ones((10, 10)) a = m.ReturnTester() a_get1 = a.get() assert not a_get1.flags.owndata assert a_get1.flags.writeable assign_both(a_get1, primary, 3, 3, 5) a_get2 = a.get_ptr() assert not a_get2.flags.owndata assert a_get2.flags.writeable assign_both(a_get1, primary, 2, 3, 6) a_view1 = a.view() assert not a_view1.flags.owndata assert not a_view1.flags.writeable with pytest.raises(ValueError): a_view1[2, 3] = 4 a_view2 = a.view_ptr() assert not a_view2.flags.owndata assert not a_view2.flags.writeable with pytest.raises(ValueError): a_view2[2, 3] = 4 a_copy1 = a.copy_get() assert a_copy1.flags.owndata assert a_copy1.flags.writeable np.testing.assert_array_equal(a_copy1, primary) a_copy1[7, 7] = -44 # Shouldn't affect anything else c1want = array_copy_but_one(primary, 7, 7, -44) a_copy2 = a.copy_view() assert a_copy2.flags.owndata assert a_copy2.flags.writeable np.testing.assert_array_equal(a_copy2, primary) a_copy2[4, 4] = -22 # Shouldn't affect anything else c2want = array_copy_but_one(primary, 4, 4, -22) a_ref1 = a.ref() assert not a_ref1.flags.owndata assert a_ref1.flags.writeable assign_both(a_ref1, primary, 1, 1, 15) a_ref2 = a.ref_const() assert not a_ref2.flags.owndata assert not a_ref2.flags.writeable with pytest.raises(ValueError): a_ref2[5, 5] = 33 a_ref3 = a.ref_safe() assert not a_ref3.flags.owndata assert a_ref3.flags.writeable assign_both(a_ref3, primary, 0, 7, 99) a_ref4 = a.ref_const_safe() assert not a_ref4.flags.owndata assert not a_ref4.flags.writeable with pytest.raises(ValueError): a_ref4[7, 0] = 987654321 a_copy3 = a.copy_ref() assert a_copy3.flags.owndata assert a_copy3.flags.writeable np.testing.assert_array_equal(a_copy3, primary) a_copy3[8, 1] = 11 c3want = array_copy_but_one(primary, 8, 1, 11) a_copy4 = a.copy_ref_const() assert a_copy4.flags.owndata assert a_copy4.flags.writeable np.testing.assert_array_equal(a_copy4, primary) a_copy4[8, 4] = 88 c4want = array_copy_but_one(primary, 8, 4, 88) a_block1 = a.block(3, 3, 2, 2) assert not a_block1.flags.owndata assert a_block1.flags.writeable a_block1[0, 0] = 55 primary[3, 3] = 55 a_block2 = a.block_safe(2, 2, 3, 2) assert not a_block2.flags.owndata assert a_block2.flags.writeable a_block2[2, 1] = -123 primary[4, 3] = -123 a_block3 = a.block_const(6, 7, 4, 3) assert not a_block3.flags.owndata assert not a_block3.flags.writeable with pytest.raises(ValueError): a_block3[2, 2] = -44444 a_copy5 = a.copy_block(2, 2, 2, 3) assert a_copy5.flags.owndata assert a_copy5.flags.writeable np.testing.assert_array_equal(a_copy5, primary[2:4, 2:5]) a_copy5[1, 1] = 777 c5want = array_copy_but_one(primary[2:4, 2:5], 1, 1, 777) a_corn1 = a.corners() assert not a_corn1.flags.owndata assert a_corn1.flags.writeable a_corn1 *= 50 a_corn1[1, 1] = 999 primary[0, 0] = 50 primary[0, 9] = 50 primary[9, 0] = 50 primary[9, 9] = 999 a_corn2 = a.corners_const() assert not a_corn2.flags.owndata assert not a_corn2.flags.writeable with pytest.raises(ValueError): a_corn2[1, 0] = 51 # All of the changes made all the way along should be visible everywhere # now (except for the copies, of course) np.testing.assert_array_equal(a_get1, primary) np.testing.assert_array_equal(a_get2, primary) np.testing.assert_array_equal(a_view1, primary) np.testing.assert_array_equal(a_view2, primary) np.testing.assert_array_equal(a_ref1, primary) np.testing.assert_array_equal(a_ref2, primary) np.testing.assert_array_equal(a_ref3, primary) np.testing.assert_array_equal(a_ref4, primary) np.testing.assert_array_equal(a_block1, primary[3:5, 3:5]) np.testing.assert_array_equal(a_block2, primary[2:5, 2:4]) np.testing.assert_array_equal(a_block3, primary[6:10, 7:10]) np.testing.assert_array_equal( a_corn1, primary[0 :: primary.shape[0] - 1, 0 :: primary.shape[1] - 1] ) np.testing.assert_array_equal( a_corn2, primary[0 :: primary.shape[0] - 1, 0 :: primary.shape[1] - 1] ) np.testing.assert_array_equal(a_copy1, c1want) np.testing.assert_array_equal(a_copy2, c2want) np.testing.assert_array_equal(a_copy3, c3want) np.testing.assert_array_equal(a_copy4, c4want) np.testing.assert_array_equal(a_copy5, c5want) def assert_keeps_alive(cl, method, *args): cstats = ConstructorStats.get(cl) start_with = cstats.alive() a = cl() assert cstats.alive() == start_with + 1 z = method(a, *args) assert cstats.alive() == start_with + 1 del a # Here's the keep alive in action: assert cstats.alive() == start_with + 1 del z # Keep alive should have expired: assert cstats.alive() == start_with def test_eigen_keepalive(): a = m.ReturnTester() cstats = ConstructorStats.get(m.ReturnTester) assert cstats.alive() == 1 unsafe = [a.ref(), a.ref_const(), a.block(1, 2, 3, 4)] copies = [ a.copy_get(), a.copy_view(), a.copy_ref(), a.copy_ref_const(), a.copy_block(4, 3, 2, 1), ] del a assert cstats.alive() == 0 del unsafe del copies for meth in [ m.ReturnTester.get, m.ReturnTester.get_ptr, m.ReturnTester.view, m.ReturnTester.view_ptr, m.ReturnTester.ref_safe, m.ReturnTester.ref_const_safe, m.ReturnTester.corners, m.ReturnTester.corners_const, ]: assert_keeps_alive(m.ReturnTester, meth) for meth in [m.ReturnTester.block_safe, m.ReturnTester.block_const]: assert_keeps_alive(m.ReturnTester, meth, 4, 3, 2, 1) def test_eigen_ref_mutators(): """Tests Eigen's ability to mutate numpy values""" orig = np.array([[1.0, 2, 3], [4, 5, 6], [7, 8, 9]]) zr = np.array(orig) zc = np.array(orig, order="F") m.add_rm(zr, 1, 0, 100) assert np.all(zr == np.array([[1.0, 2, 3], [104, 5, 6], [7, 8, 9]])) m.add_cm(zc, 1, 0, 200) assert np.all(zc == np.array([[1.0, 2, 3], [204, 5, 6], [7, 8, 9]])) m.add_any(zr, 1, 0, 20) assert np.all(zr == np.array([[1.0, 2, 3], [124, 5, 6], [7, 8, 9]])) m.add_any(zc, 1, 0, 10) assert np.all(zc == np.array([[1.0, 2, 3], [214, 5, 6], [7, 8, 9]])) # Can't reference a col-major array with a row-major Ref, and vice versa: with pytest.raises(TypeError): m.add_rm(zc, 1, 0, 1) with pytest.raises(TypeError): m.add_cm(zr, 1, 0, 1) # Overloads: m.add1(zr, 1, 0, -100) m.add2(zr, 1, 0, -20) assert np.all(zr == orig) m.add1(zc, 1, 0, -200) m.add2(zc, 1, 0, -10) assert np.all(zc == orig) # a non-contiguous slice (this won't work on either the row- or # column-contiguous refs, but should work for the any) cornersr = zr[0::2, 0::2] cornersc = zc[0::2, 0::2] assert np.all(cornersr == np.array([[1.0, 3], [7, 9]])) assert np.all(cornersc == np.array([[1.0, 3], [7, 9]])) with pytest.raises(TypeError): m.add_rm(cornersr, 0, 1, 25) with pytest.raises(TypeError): m.add_cm(cornersr, 0, 1, 25) with pytest.raises(TypeError): m.add_rm(cornersc, 0, 1, 25) with pytest.raises(TypeError): m.add_cm(cornersc, 0, 1, 25) m.add_any(cornersr, 0, 1, 25) m.add_any(cornersc, 0, 1, 44) assert np.all(zr == np.array([[1.0, 2, 28], [4, 5, 6], [7, 8, 9]])) assert np.all(zc == np.array([[1.0, 2, 47], [4, 5, 6], [7, 8, 9]])) # You shouldn't be allowed to pass a non-writeable array to a mutating Eigen method: zro = zr[0:4, 0:4] zro.flags.writeable = False with pytest.raises(TypeError): m.add_rm(zro, 0, 0, 0) with pytest.raises(TypeError): m.add_any(zro, 0, 0, 0) with pytest.raises(TypeError): m.add1(zro, 0, 0, 0) with pytest.raises(TypeError): m.add2(zro, 0, 0, 0) # integer array shouldn't be passable to a double-matrix-accepting mutating func: zi = np.array([[1, 2], [3, 4]]) with pytest.raises(TypeError): m.add_rm(zi) def test_numpy_ref_mutators(): """Tests numpy mutating Eigen matrices (for returned Eigen::Ref<...>s)""" m.reset_refs() # In case another test already changed it zc = m.get_cm_ref() zcro = m.get_cm_const_ref() zr = m.get_rm_ref() zrro = m.get_rm_const_ref() assert [zc[1, 2], zcro[1, 2], zr[1, 2], zrro[1, 2]] == [23] * 4 assert not zc.flags.owndata assert zc.flags.writeable assert not zr.flags.owndata assert zr.flags.writeable assert not zcro.flags.owndata assert not zcro.flags.writeable assert not zrro.flags.owndata assert not zrro.flags.writeable zc[1, 2] = 99 expect = np.array([[11.0, 12, 13], [21, 22, 99], [31, 32, 33]]) # We should have just changed zc, of course, but also zcro and the original eigen matrix assert np.all(zc == expect) assert np.all(zcro == expect) assert np.all(m.get_cm_ref() == expect) zr[1, 2] = 99 assert np.all(zr == expect) assert np.all(zrro == expect) assert np.all(m.get_rm_ref() == expect) # Make sure the readonly ones are numpy-readonly: with pytest.raises(ValueError): zcro[1, 2] = 6 with pytest.raises(ValueError): zrro[1, 2] = 6 # We should be able to explicitly copy like this (and since we're copying, # the const should drop away) y1 = np.array(m.get_cm_const_ref()) assert y1.flags.owndata assert y1.flags.writeable # We should get copies of the eigen data, which was modified above: assert y1[1, 2] == 99 y1[1, 2] += 12 assert y1[1, 2] == 111 assert zc[1, 2] == 99 # Make sure we aren't referencing the original def test_both_ref_mutators(): """Tests a complex chain of nested eigen/numpy references""" m.reset_refs() # In case another test already changed it z = m.get_cm_ref() # numpy -> eigen z[0, 2] -= 3 z2 = m.incr_matrix(z, 1) # numpy -> eigen -> numpy -> eigen z2[1, 1] += 6 z3 = m.incr_matrix(z, 2) # (numpy -> eigen)^3 z3[2, 2] += -5 z4 = m.incr_matrix(z, 3) # (numpy -> eigen)^4 z4[1, 1] -= 1 z5 = m.incr_matrix(z, 4) # (numpy -> eigen)^5 z5[0, 0] = 0 assert np.all(z == z2) assert np.all(z == z3) assert np.all(z == z4) assert np.all(z == z5) expect = np.array([[0.0, 22, 20], [31, 37, 33], [41, 42, 38]]) assert np.all(z == expect) y = np.array(range(100), dtype="float64").reshape(10, 10) y2 = m.incr_matrix_any(y, 10) # np -> eigen -> np y3 = m.incr_matrix_any( y2[0::2, 0::2], -33 ) # np -> eigen -> np slice -> np -> eigen -> np y4 = m.even_rows(y3) # numpy -> eigen slice -> (... y3) y5 = m.even_cols(y4) # numpy -> eigen slice -> (... y4) y6 = m.incr_matrix_any(y5, 1000) # numpy -> eigen -> (... y5) # Apply same mutations using just numpy: yexpect = np.array(range(100), dtype="float64").reshape(10, 10) yexpect += 10 yexpect[0::2, 0::2] -= 33 yexpect[0::4, 0::4] += 1000 assert np.all(y6 == yexpect[0::4, 0::4]) assert np.all(y5 == yexpect[0::4, 0::4]) assert np.all(y4 == yexpect[0::4, 0::2]) assert np.all(y3 == yexpect[0::2, 0::2]) assert np.all(y2 == yexpect) assert np.all(y == yexpect) def test_nocopy_wrapper(): # get_elem requires a column-contiguous matrix reference, but should be # callable with other types of matrix (via copying): int_matrix_colmajor = np.array( [[1, 2, 3], [4, 5, 6], [7, 8, 9]], dtype="l", order="F" ) dbl_matrix_colmajor = np.array( int_matrix_colmajor, dtype="double", order="F", copy=True ) int_matrix_rowmajor = np.array(int_matrix_colmajor, order="C", copy=True) dbl_matrix_rowmajor = np.array( int_matrix_rowmajor, dtype="double", order="C", copy=True ) # All should be callable via get_elem: assert m.get_elem(int_matrix_colmajor) == 8 assert m.get_elem(dbl_matrix_colmajor) == 8 assert m.get_elem(int_matrix_rowmajor) == 8 assert m.get_elem(dbl_matrix_rowmajor) == 8 # All but the second should fail with m.get_elem_nocopy: with pytest.raises(TypeError) as excinfo: m.get_elem_nocopy(int_matrix_colmajor) assert "get_elem_nocopy(): incompatible function arguments." in str(excinfo.value) assert ", flags.f_contiguous" in str(excinfo.value) assert m.get_elem_nocopy(dbl_matrix_colmajor) == 8 with pytest.raises(TypeError) as excinfo: m.get_elem_nocopy(int_matrix_rowmajor) assert "get_elem_nocopy(): incompatible function arguments." in str(excinfo.value) assert ", flags.f_contiguous" in str(excinfo.value) with pytest.raises(TypeError) as excinfo: m.get_elem_nocopy(dbl_matrix_rowmajor) assert "get_elem_nocopy(): incompatible function arguments." in str(excinfo.value) assert ", flags.f_contiguous" in str(excinfo.value) # For the row-major test, we take a long matrix in row-major, so only the third is allowed: with pytest.raises(TypeError) as excinfo: m.get_elem_rm_nocopy(int_matrix_colmajor) assert "get_elem_rm_nocopy(): incompatible function arguments." in str( excinfo.value ) assert ", flags.c_contiguous" in str(excinfo.value) with pytest.raises(TypeError) as excinfo: m.get_elem_rm_nocopy(dbl_matrix_colmajor) assert "get_elem_rm_nocopy(): incompatible function arguments." in str( excinfo.value ) assert ", flags.c_contiguous" in str(excinfo.value) assert m.get_elem_rm_nocopy(int_matrix_rowmajor) == 8 with pytest.raises(TypeError) as excinfo: m.get_elem_rm_nocopy(dbl_matrix_rowmajor) assert "get_elem_rm_nocopy(): incompatible function arguments." in str( excinfo.value ) assert ", flags.c_contiguous" in str(excinfo.value) def test_eigen_ref_life_support(): """Ensure the lifetime of temporary arrays created by the `Ref` caster The `Ref` caster sometimes creates a copy which needs to stay alive. This needs to happen both for directs casts (just the array) or indirectly (e.g. list of arrays). """ a = np.full(shape=10, fill_value=8, dtype=np.int8) assert m.get_elem_direct(a) == 8 list_of_a = [a] assert m.get_elem_indirect(list_of_a) == 8 def test_special_matrix_objects(): assert np.all(m.incr_diag(7) == np.diag([1.0, 2, 3, 4, 5, 6, 7])) asymm = np.array([[1.0, 2, 3, 4], [5, 6, 7, 8], [9, 10, 11, 12], [13, 14, 15, 16]]) symm_lower = np.array(asymm) symm_upper = np.array(asymm) for i in range(4): for j in range(i + 1, 4): symm_lower[i, j] = symm_lower[j, i] symm_upper[j, i] = symm_upper[i, j] assert np.all(m.symmetric_lower(asymm) == symm_lower) assert np.all(m.symmetric_upper(asymm) == symm_upper) def test_dense_signature(doc): assert ( doc(m.double_col) == """ double_col(arg0: numpy.typing.NDArray[numpy.float32[m, 1]]) -> numpy.typing.NDArray[numpy.float32[m, 1]] """ ) assert ( doc(m.double_row) == """ double_row(arg0: numpy.typing.NDArray[numpy.float32[1, n]]) -> numpy.typing.NDArray[numpy.float32[1, n]] """ ) assert doc(m.double_complex) == ( """ double_complex(arg0: numpy.typing.NDArray[numpy.complex64[m, 1]])""" """ -> numpy.typing.NDArray[numpy.complex64[m, 1]] """ ) assert doc(m.double_mat_rm) == ( """ double_mat_rm(arg0: numpy.typing.NDArray[numpy.float32[m, n]])""" """ -> numpy.typing.NDArray[numpy.float32[m, n]] """ ) def test_defaults(doc): assert "\n" not in str(doc(m.defaults_mat)) assert "\n" not in str(doc(m.defaults_vec)) def test_named_arguments(): a = np.array([[1.0, 2], [3, 4], [5, 6]]) b = np.ones((2, 1)) assert np.all(m.matrix_multiply(a, b) == np.array([[3.0], [7], [11]])) assert np.all(m.matrix_multiply(A=a, B=b) == np.array([[3.0], [7], [11]])) assert np.all(m.matrix_multiply(B=b, A=a) == np.array([[3.0], [7], [11]])) with pytest.raises(ValueError) as excinfo: m.matrix_multiply(b, a) assert str(excinfo.value) == "Nonconformable matrices!" with pytest.raises(ValueError) as excinfo: m.matrix_multiply(A=b, B=a) assert str(excinfo.value) == "Nonconformable matrices!" with pytest.raises(ValueError) as excinfo: m.matrix_multiply(B=a, A=b) assert str(excinfo.value) == "Nonconformable matrices!" def test_sparse(): pytest.importorskip("scipy") assert_sparse_equal_ref(m.sparse_r()) assert_sparse_equal_ref(m.sparse_c()) assert_sparse_equal_ref(m.sparse_copy_r(m.sparse_r())) assert_sparse_equal_ref(m.sparse_copy_c(m.sparse_c())) assert_sparse_equal_ref(m.sparse_copy_r(m.sparse_c())) assert_sparse_equal_ref(m.sparse_copy_c(m.sparse_r())) def test_sparse_signature(doc): pytest.importorskip("scipy") assert ( doc(m.sparse_copy_r) == """ sparse_copy_r(arg0: scipy.sparse.csr_matrix[numpy.float32]) -> scipy.sparse.csr_matrix[numpy.float32] """ ) assert ( doc(m.sparse_copy_c) == """ sparse_copy_c(arg0: scipy.sparse.csc_matrix[numpy.float32]) -> scipy.sparse.csc_matrix[numpy.float32] """ ) def test_issue738(): """Ignore strides on a length-1 dimension (even if they would be incompatible length > 1)""" assert np.all(m.iss738_f1(np.array([[1.0, 2, 3]])) == np.array([[1.0, 102, 203]])) assert np.all( m.iss738_f1(np.array([[1.0], [2], [3]])) == np.array([[1.0], [12], [23]]) ) assert np.all(m.iss738_f2(np.array([[1.0, 2, 3]])) == np.array([[1.0, 102, 203]])) assert np.all( m.iss738_f2(np.array([[1.0], [2], [3]])) == np.array([[1.0], [12], [23]]) ) @pytest.mark.parametrize("func", [m.iss738_f1, m.iss738_f2]) @pytest.mark.parametrize("sizes", [(0, 2), (2, 0)]) def test_zero_length(func, sizes): """Ignore strides on a length-0 dimension (even if they would be incompatible length > 1)""" assert np.all(func(np.zeros(sizes)) == np.zeros(sizes)) def test_issue1105(): """Issue 1105: 1xN or Nx1 input arrays weren't accepted for eigen compile-time row vectors or column vector""" assert m.iss1105_row(np.ones((1, 7))) assert m.iss1105_col(np.ones((7, 1))) # These should still fail (incompatible dimensions): with pytest.raises(TypeError) as excinfo: m.iss1105_row(np.ones((7, 1))) assert "incompatible function arguments" in str(excinfo.value) with pytest.raises(TypeError) as excinfo: m.iss1105_col(np.ones((1, 7))) assert "incompatible function arguments" in str(excinfo.value) def test_custom_operator_new(): """Using Eigen types as member variables requires a class-specific operator new with proper alignment""" o = m.CustomOperatorNew() np.testing.assert_allclose(o.a, 0.0) np.testing.assert_allclose(o.b.diagonal(), 1.0)