Me arroja IndentationError: expected an indented block after function definition on line 43

Question

Lo que pasa es que estoy haciendo unas pruebas unitarias en python pero me arroja siempre el error de indentación.

import numpy as np
import unittest
import ComplexMatrix

class TestQuantumOperations(unittest.TestCase):
    def setUp(self):
        self.complex_vector1 = np.array([1 + 1j, 2 + 2j, 3 + 3j])
        self.complex_vector2 = np.array([1 + 1j, 2 + 2j, 4 + 4j])
        self.complex_matrix1 = np.array([[1 + 1j, 2 + 2j], [3 + 3j, 4 + 4j]])
        self.complex_matrix2 = np.array([[2 + 2j, 1 + 1j], [1 + 1j, 2 + 2j]])

    def test_add_complex_vectors(self):
        result = ComplexMatrix.add_complex_vectors(self.complex_vector1, self.complex_vector2)
        expected = np.array([2 + 2j, 4 + 4j, 7 + 7j])
        np.testing.assert_array_equal(result, expected)
        
    def test_addition_with_zero_vector(self):
        vector1 = np.array([1 + 2j, 3 + 4j, 5 + 6j])
        vector2 = np.zeros(3, dtype=complex)
        expected = np.array([1 + 2j, 3 + 4j, 5 + 6j])
        result = ComplexMatrix.add_complex_vectors(vector1, vector2)
        np.testing.assert_array_equal(result, expected)

    def test_inverse_complex_vector(self):
        result = ComplexMatrix.inverse_complex_vector(self.complex_vector1)
        expected = np.array([-1 - 1j, -2 - 2j, -3 - 3j])
        np.testing.assert_array_equal(result, expected)

    def test_scalar_multiplication_complex_vector(self):
        result = ComplexMatrix.scalar_multiplication_complex_vector(2, self.complex_vector1)
        expected = np.array([2 + 2j, 4 + 4j, 6 + 6j])
        np.testing.assert_array_equal(result, expected)

    def test_add_complex_matrices(self):
        result = ComplexMatrix.add_complex_matrices(self.complex_matrix1, self.complex_matrix2)
        expected = np.array([[3 + 3j, 3 + 3j], [4 + 4j, 6 + 6j]])
        np.testing.assert_array_equal(result, expected)

    def test_inverse_complex_matrix(self):
        result = ComplexMatrix.inverse_complex_matrix(self.complex_matrix1)
        expected = np.array([[-1 - 1j, -2 - 2j], [-3 - 3j, -4 - 4j]])
        np.testing.assert_array_equal(result, expected)

    def test_scalar_matrix_product(self):
        c = complex(2, 3)
        M = np.array([[complex(1, 2), complex(3, 4)], [complex(5, 6), complex(7, 8)]])
        expected_output = np.array([[complex(-4, 7), complex(-6, 17)], [complex(-8, 27), complex(-10, 37)]])
        self.assertTrue((ComplexMatrix.scalar_matrix_product(c, M) == expected_output).all())

    def test_matrix_transpose(self):
        A = np.array([[(2, 1), (3, -2)], [(5, -3), (1, 1)]])
        B = np.array([[(2, 1), (5, -3)], [(3, -2), (1, 1)]])
        np.testing.assert_array_equal(ComplexMatrix.matrix_transpose(A), B)

        A = np.array([[(2, 1)], [(3, -2)], [(5, -3)]])
        B = np.array([[(2, 1), (3, -2), (5, -3)]])
        np.testing.assert_array_equal(ComplexMatrix.matrix_transpose(A), B)

        A = np.array([[(1, 2)]])
        B = np.array([[(1, 2)]])
        np.testing.assert_array_equal(ComplexMatrix.matrix_transpose(A), B)

    def test_conjugate_matrix(self):
        result = ComplexMatrix.conjugate_matrix(self.complex_matrix1)
        expected = np.array([[1 - 1j, 2 - 2j], [3 - 3j, 4 - 4j]])
        np.testing.assert_array_equal(result, expected)

    def test_adjoint_matrix(self):
        result = ComplexMatrix.adjoint_matrix(self.complex_matrix1)
        expected = np.array([[1 - 1j, 3 - 3j], [2 - 2j, 4 - 4j]])
        np.testing.assert_array_equal(result, expected)

    def test_matrix_multiplication(self):
        result = ComplexMatrix.matrix_multiplication(self.complex_matrix1, self.complex_matrix2)
        expected = np.array([[6 + 6j, 6 + 6j], [18 + 18j, 18 + 18j]])
        np.testing.assert_array_equal(result, expected)

    def test_matrix_vector_action(self):
        result = ComplexMatrix.matrix_vector_action(self.complex_matrix1, self.complex_vector1)
        expected = np.array([10 + 10j, 22 + 22j])
        np.testing.assert_array_equal(result, expected)

    def test_inner_product(self):
        result = ComplexMatrix.inner_product(self.complex_vector1, self.complex_vector2)
        expected = 30 + 30j
        self.assertEqual(result, expected)

    def test_vector_norm(self):
        result = ComplexMatrix.vector_norm(self.complex_vector1)
        expected = np.sqrt(14)
        self.assertAlmostEqual(result, expected, places=9)

    def test_distance_between_vectors(self):
        result = ComplexMatrix.distance_between_vectors(self.complex_vector1, self.complex_vector2)
        expected = np.sqrt(2)
        self.assertAlmostEqual(result, expected, places=9)

    def test_unitary_matrix(self):
        result = ComplexMatrix.unitary_matrix(self.complex_matrix1)
        self.assertFalse(result)

    def test_hermitian_matrix(self):
        result = ComplexMatrix.hermitian_matrix(self.complex_matrix1)
        self.assertFalse(result)

    def test_tensor_product(self):
        result = ComplexMatrix.tensor_product(self.complex_vector1, self.complex_vector2)
        expected = np.array([[1 + 1j, 2 + 2j, 4 + 4j, 6 + 6j],
                                 [2 + 2j, 4 + 4j, 8 + 8j, 12 + 12j],
                                 [3 + 3j, 6 + 6j, 9 + 9j, 12 + 12j],
                                 [6 + 6j, 12 + 12j, 12 + 12j, 24 + 24j]])
        np.testing.assert_array_equal(result, expected)

    if __name__ == '_main_':
        unittest.main()