def test_stronglyentanglinglayers_normal_edgecase(self, seed, tol): """Test sampling edge case of pennylane.init.strong_ent_layers_normal().""" n_layers = 3 p = strong_ent_layers_normal(n_layers=n_layers, n_wires=10, mean=1, std=0, seed=seed) p_mean = np.mean(np.array([np.mean(pp) for p_ in p for pp in p_])) assert np.allclose(p_mean, 1, atol=tol, rtol=0.)
def test_stronglyentanglinglayers_normal_dimensions( self, n_subsystems, n_layers): """Confirm that the pennylane.init.strong_ent_layers_normal() returns an array with the right dimensions.""" a = (n_layers, n_subsystems, 3) p = strong_ent_layers_normal(n_layers=n_layers, n_wires=n_subsystems, seed=0) dims = [p_.shape for p_ in p] assert dims == [a]
def test_stronglyentanglinglayers_normal_seed(self, seed, tol): """Confirm that pennylane.init.strong_ent_layers_normal() invokes the correct np.random sampling function for a given seed.""" mean = -2 std = 1 n_wires = 3 n_layers = 3 p = strong_ent_layers_normal(n_layers=n_layers, n_wires=n_wires, mean=mean, std=std, seed=seed) np.random.seed(seed) p_target = np.random.normal(loc=mean, scale=std, size=(n_layers, n_wires, 3)) assert np.allclose(p[0], p_target, atol=tol, rtol=0.)
class TestInitializationIntegration: """Tests integration with the parameter initialization functions from pennylane.init""" # TODO: Combine CV and Qubit tests, since the only difference is the device def make_n_features(self, n): """Helper to prepare dummy feature inputs for templates that have as many features as number of wires.""" return [i for i in range(n)] QUBIT_INIT = [(StronglyEntanglingLayers, {'weights': strong_ent_layers_uniform(n_layers=3, n_wires=2), 'wires': range(2)}), (StronglyEntanglingLayers, {'weights': strong_ent_layers_uniform(n_layers=2, n_wires=3), 'wires': range(3)}), (StronglyEntanglingLayers, {'weights': strong_ent_layers_normal(n_layers=3, n_wires=2), 'wires': range(2)}), (StronglyEntanglingLayers, {'weights': strong_ent_layers_normal(n_layers=2, n_wires=3), 'wires': range(3)}), (RandomLayers, {'weights': random_layers_uniform(n_layers=3, n_rots=2, n_wires=2), 'wires': range(2)}), (RandomLayers, {'weights': random_layers_uniform(n_layers=3, n_rots=2, n_wires=2), 'wires': range(2)}), (RandomLayers, {'weights': random_layers_normal(n_layers=2, n_rots=2, n_wires=3), 'wires': range(3)}), (RandomLayers, {'weights': random_layers_normal(n_layers=2, n_rots=2, n_wires=3), 'wires': range(3)}), (QAOAEmbedding, {'features': [1., 2.], 'weights': qaoa_embedding_uniform(n_layers=3, n_wires=2), 'wires': range(2)}), (QAOAEmbedding, {'features': [1., 2.], 'weights': qaoa_embedding_uniform(n_layers=3, n_wires=2), 'wires': range(2)}), (QAOAEmbedding, {'features': [1., 2.], 'weights': qaoa_embedding_normal(n_layers=2, n_wires=3), 'wires': range(3)}), (QAOAEmbedding, {'features': [1., 2.], 'weights': qaoa_embedding_normal(n_layers=2, n_wires=3), 'wires': range(3)}), (QAOAEmbedding, {'features': [1., 2.], 'weights': qaoa_embedding_normal(n_layers=2, n_wires=1), 'wires': range(1)}), (QAOAEmbedding, {'features': [1., 2.], 'weights': qaoa_embedding_uniform(n_layers=2, n_wires=1), 'wires': range(1)}) ] CV_INIT = [(CVNeuralNetLayers, {'theta_1': cvqnn_layers_theta_uniform(n_layers=3, n_wires=2), 'phi_1': cvqnn_layers_phi_uniform(n_layers=3, n_wires=2), 'varphi_1': cvqnn_layers_varphi_uniform(n_layers=3, n_wires=2), 'r': cvqnn_layers_r_uniform(n_layers=3, n_wires=2), 'phi_r': cvqnn_layers_phi_r_uniform(n_layers=3, n_wires=2), 'theta_2': cvqnn_layers_theta_uniform(n_layers=3, n_wires=2), 'phi_2': cvqnn_layers_phi_uniform(n_layers=3, n_wires=2), 'varphi_2': cvqnn_layers_varphi_uniform(n_layers=3, n_wires=2), 'a': cvqnn_layers_a_uniform(n_layers=3, n_wires=2), 'phi_a': cvqnn_layers_phi_a_uniform(n_layers=3, n_wires=2), 'k': cvqnn_layers_kappa_uniform(n_layers=3, n_wires=2), 'wires': range(2)}), (CVNeuralNetLayers, {'theta_1': cvqnn_layers_theta_normal(n_layers=3, n_wires=2), 'phi_1': cvqnn_layers_phi_normal(n_layers=3, n_wires=2), 'varphi_1': cvqnn_layers_varphi_normal(n_layers=3, n_wires=2), 'r': cvqnn_layers_r_normal(n_layers=3, n_wires=2), 'phi_r': cvqnn_layers_phi_r_normal(n_layers=3, n_wires=2), 'theta_2': cvqnn_layers_theta_normal(n_layers=3, n_wires=2), 'phi_2': cvqnn_layers_phi_normal(n_layers=3, n_wires=2), 'varphi_2': cvqnn_layers_varphi_normal(n_layers=3, n_wires=2), 'a': cvqnn_layers_a_normal(n_layers=3, n_wires=2), 'phi_a': cvqnn_layers_phi_a_normal(n_layers=3, n_wires=2), 'k': cvqnn_layers_kappa_normal(n_layers=3, n_wires=2), 'wires': range(2)}), (Interferometer, {'phi': interferometer_phi_uniform(n_wires=2), 'varphi': interferometer_varphi_uniform(n_wires=2), 'theta': interferometer_theta_uniform(n_wires=2), 'wires': range(2)}), (Interferometer, {'phi': interferometer_phi_normal(n_wires=2), 'varphi': interferometer_varphi_normal(n_wires=2), 'theta': interferometer_theta_normal(n_wires=2), 'wires': range(2)}), (Interferometer, {'phi': interferometer_phi_uniform(n_wires=3), 'varphi': interferometer_varphi_uniform(n_wires=3), 'theta': interferometer_theta_uniform(n_wires=3), 'wires': range(3)}), (Interferometer, {'phi': interferometer_phi_normal(n_wires=3), 'varphi': interferometer_varphi_normal(n_wires=3), 'theta': interferometer_theta_normal(n_wires=3), 'wires': range(3)}) ] @pytest.mark.parametrize("template, dict", QUBIT_INIT) def test_integration_qubit_init(self, template, dict): """Checks parameter initialization compatible with qubit templates.""" n_wires = len(dict['wires']) dev = qml.device('default.qubit', wires=n_wires) @qml.qnode(dev) def circuit(): template(**dict) return qml.expval(qml.Identity(0)) # Check that execution does not throw error circuit() @pytest.mark.parametrize("template, dict", CV_INIT) def test_integration_qubit_init(self, template, dict, gaussian_dummy): """Checks parameter initialization compatible with qubit templates.""" n_wires = len(dict['wires']) dev = gaussian_dummy(n_wires) @qml.qnode(dev) def circuit(): template(**dict) return qml.expval(qml.Identity(0)) # Check that execution does not throw error circuit()