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	from sympy.core.random import randint

	from sympy.core.numbers import Integer
	from sympy.matrices.dense import (Matrix, ones, zeros)

	from sympy.physics.quantum.matrixutils import (
	to_sympy, to_numpy, to_scipy_sparse, matrix_tensor_product,
	matrix_to_zero, matrix_zeros, numpy_ndarray, scipy_sparse_matrix
	)

	from sympy.external import import_module
	from sympy.testing.pytest import skip

	m = Matrix([[1, 2], [3, 4]])


	def test_sympy_to_sympy():
	assert to_sympy(m) == m


	def test_matrix_to_zero():
	assert matrix_to_zero(m) == m
	assert matrix_to_zero(Matrix([[0, 0], [0, 0]])) == Integer(0)

	np = import_module('numpy')


	def test_to_numpy():
	if not np:
	skip("numpy not installed.")

	result = np.array([[1, 2], [3, 4]], dtype='complex')
	assert (to_numpy(m) == result).all()


	def test_matrix_tensor_product():
	if not np:
	skip("numpy not installed.")

	l1 = zeros(4)
	for i in range(16):
	l1[i] = 2**i
	l2 = zeros(4)
	for i in range(16):
	l2[i] = i
	l3 = zeros(2)
	for i in range(4):
	l3[i] = i
	vec = Matrix([1, 2, 3])

	#test for Matrix known 4x4 matrices
	numpyl1 = np.array(l1.tolist())
	numpyl2 = np.array(l2.tolist())
	numpy_product = np.kron(numpyl1, numpyl2)
	args = [l1, l2]
	sympy_product = matrix_tensor_product(*args)
	assert numpy_product.tolist() == sympy_product.tolist()
	numpy_product = np.kron(numpyl2, numpyl1)
	args = [l2, l1]
	sympy_product = matrix_tensor_product(*args)
	assert numpy_product.tolist() == sympy_product.tolist()

	#test for other known matrix of different dimensions
	numpyl2 = np.array(l3.tolist())
	numpy_product = np.kron(numpyl1, numpyl2)
	args = [l1, l3]
	sympy_product = matrix_tensor_product(*args)
	assert numpy_product.tolist() == sympy_product.tolist()
	numpy_product = np.kron(numpyl2, numpyl1)
	args = [l3, l1]
	sympy_product = matrix_tensor_product(*args)
	assert numpy_product.tolist() == sympy_product.tolist()

	#test for non square matrix
	numpyl2 = np.array(vec.tolist())
	numpy_product = np.kron(numpyl1, numpyl2)
	args = [l1, vec]
	sympy_product = matrix_tensor_product(*args)
	assert numpy_product.tolist() == sympy_product.tolist()
	numpy_product = np.kron(numpyl2, numpyl1)
	args = [vec, l1]
	sympy_product = matrix_tensor_product(*args)
	assert numpy_product.tolist() == sympy_product.tolist()

	#test for random matrix with random values that are floats
	random_matrix1 = np.random.rand(randint(1, 5), randint(1, 5))
	random_matrix2 = np.random.rand(randint(1, 5), randint(1, 5))
	numpy_product = np.kron(random_matrix1, random_matrix2)
	args = [Matrix(random_matrix1.tolist()), Matrix(random_matrix2.tolist())]
	sympy_product = matrix_tensor_product(*args)
	assert not (sympy_product - Matrix(numpy_product.tolist())).tolist() > \
	(ones(sympy_product.rows, sympy_product.cols)*epsilon).tolist()

	#test for three matrix kronecker
	sympy_product = matrix_tensor_product(l1, vec, l2)

	numpy_product = np.kron(l1, np.kron(vec, l2))
	assert numpy_product.tolist() == sympy_product.tolist()


	scipy = import_module('scipy', import_kwargs={'fromlist': ['sparse']})


	def test_to_scipy_sparse():
	if not np:
	skip("numpy not installed.")
	if not scipy:
	skip("scipy not installed.")
	else:
	sparse = scipy.sparse

	result = sparse.csr_matrix([[1, 2], [3, 4]], dtype='complex')
	assert np.linalg.norm((to_scipy_sparse(m) - result).todense()) == 0.0

	epsilon = .000001


	def test_matrix_zeros_sympy():
	sym = matrix_zeros(4, 4, format='sympy')
	assert isinstance(sym, Matrix)

	def test_matrix_zeros_numpy():
	if not np:
	skip("numpy not installed.")

	num = matrix_zeros(4, 4, format='numpy')
	assert isinstance(num, numpy_ndarray)

	def test_matrix_zeros_scipy():
	if not np:
	skip("numpy not installed.")
	if not scipy:
	skip("scipy not installed.")

	sci = matrix_zeros(4, 4, format='scipy.sparse')
	assert isinstance(sci, scipy_sparse_matrix)