def test_incremental_pca_inverse(): # Test that the projection of data can be inverted. rng = np.random.RandomState(1999) n, p = 50, 3 X = rng.randn(n, p) # spherical data X[:, 1] *= .00001 # make middle component relatively small X += [5, 4, 3] # make a large mean # same check that we can find the original data from the transformed # signal (since the data is almost of rank n_components) ipca = IncrementalPCA(n_components=2, batch_size=10).fit(X) Y = ipca.transform(X) Y_inverse = ipca.inverse_transform(Y) assert_almost_equal(X, Y_inverse, decimal=3)
def test_incremental_pca_against_pca_iris(): # Test that IncrementalPCA and PCA are approximate (to a sign flip). X = iris.data Y_pca = PCA(n_components=2).fit_transform(X) Y_ipca = IncrementalPCA(n_components=2, batch_size=25).fit_transform(X) assert_almost_equal(np.abs(Y_pca), np.abs(Y_ipca), 1)
def test_incremental_pca_partial_fit(): # Test that fit and partial_fit get equivalent results. rng = np.random.RandomState(1999) n, p = 50, 3 X = rng.randn(n, p) # spherical data X[:, 1] *= .00001 # make middle component relatively small X += [5, 4, 3] # make a large mean # same check that we can find the original data from the transformed # signal (since the data is almost of rank n_components) batch_size = 10 ipca = IncrementalPCA(n_components=2, batch_size=batch_size).fit(X) pipca = IncrementalPCA(n_components=2, batch_size=batch_size) # Add one to make sure endpoint is included batch_itr = np.arange(0, n + 1, batch_size) for i, j in zip(batch_itr[:-1], batch_itr[1:]): pipca.partial_fit(X[i:j, :]) assert_almost_equal(ipca.components_, pipca.components_, decimal=3)
def test_incremental_pca_validation(): # Test that n_components is >=1 and <= n_features. X = np.array([[0, 1, 0], [1, 0, 0]]) n_samples, n_features = X.shape for n_components in [-1, 0, .99, 4]: with pytest.raises(ValueError, match="n_components={} invalid" " for n_features={}, need more rows than" " columns for IncrementalPCA" " processing".format(n_components, n_features)): IncrementalPCA(n_components, batch_size=10).fit(X) # Tests that n_components is also <= n_samples. n_components = 3 with pytest.raises(ValueError, match="n_components={} must be" " less or equal to the batch number of" " samples {}".format(n_components, n_samples)): IncrementalPCA(n_components=n_components).partial_fit(X)
def test_whitening(): # Test that PCA and IncrementalPCA transforms match to sign flip. X = datasets.make_low_rank_matrix(1000, 10, tail_strength=0., effective_rank=2, random_state=1999) prec = 3 n_samples, n_features = X.shape for nc in [None, 9]: pca = PCA(whiten=True, n_components=nc).fit(X) ipca = IncrementalPCA(whiten=True, n_components=nc, batch_size=250).fit(X) Xt_pca = pca.transform(X) Xt_ipca = ipca.transform(X) assert_almost_equal(np.abs(Xt_pca), np.abs(Xt_ipca), decimal=prec) Xinv_ipca = ipca.inverse_transform(Xt_ipca) Xinv_pca = pca.inverse_transform(Xt_pca) assert_almost_equal(X, Xinv_ipca, decimal=prec) assert_almost_equal(X, Xinv_pca, decimal=prec) assert_almost_equal(Xinv_pca, Xinv_ipca, decimal=prec)
def test_incremental_pca_against_pca_random_data(): # Test that IncrementalPCA and PCA are approximate (to a sign flip). rng = np.random.RandomState(1999) n_samples = 100 n_features = 3 X = rng.randn(n_samples, n_features) + 5 * rng.rand(1, n_features) Y_pca = PCA(n_components=3).fit_transform(X) Y_ipca = IncrementalPCA(n_components=3, batch_size=25).fit_transform(X) assert_almost_equal(np.abs(Y_pca), np.abs(Y_ipca), 1)
def test_incremental_pca_batch_values(): # Test that components_ values are stable over batch sizes. rng = np.random.RandomState(1999) n_samples = 100 n_features = 3 X = rng.randn(n_samples, n_features) all_components = [] batch_sizes = np.arange(20, 40, 3) for batch_size in batch_sizes: ipca = IncrementalPCA(n_components=None, batch_size=batch_size).fit(X) all_components.append(ipca.components_) for i, j in zip(all_components[:-1], all_components[1:]): assert_almost_equal(i, j, decimal=1)
def test_explained_variances(): # Test that PCA and IncrementalPCA calculations match X = datasets.make_low_rank_matrix(1000, 100, tail_strength=0., effective_rank=10, random_state=1999) prec = 3 n_samples, n_features = X.shape for nc in [None, 99]: pca = PCA(n_components=nc).fit(X) ipca = IncrementalPCA(n_components=nc, batch_size=100).fit(X) assert_almost_equal(pca.explained_variance_, ipca.explained_variance_, decimal=prec) assert_almost_equal(pca.explained_variance_ratio_, ipca.explained_variance_ratio_, decimal=prec) assert_almost_equal(pca.noise_variance_, ipca.noise_variance_, decimal=prec)
def test_incremental_pca_batch_rank(): # Test sample size in each batch is always larger or equal to n_components rng = np.random.RandomState(1999) n_samples = 100 n_features = 20 X = rng.randn(n_samples, n_features) all_components = [] batch_sizes = np.arange(20, 90, 3) for batch_size in batch_sizes: ipca = IncrementalPCA(n_components=20, batch_size=batch_size).fit(X) all_components.append(ipca.components_) for components_i, components_j in zip(all_components[:-1], all_components[1:]): assert_allclose_dense_sparse(components_i, components_j)
def test_incremental_pca_num_features_change(): # Test that changing n_components will raise an error. rng = np.random.RandomState(1999) n_samples = 100 X = rng.randn(n_samples, 20) X2 = rng.randn(n_samples, 50) ipca = IncrementalPCA(n_components=None) ipca.fit(X) with pytest.raises(ValueError): ipca.partial_fit(X2)
def test_incremental_pca(): # Incremental PCA on dense arrays. X = iris.data batch_size = X.shape[0] // 3 ipca = IncrementalPCA(n_components=2, batch_size=batch_size) pca = PCA(n_components=2) pca.fit_transform(X) X_transformed = ipca.fit_transform(X) assert X_transformed.shape == (X.shape[0], 2) np.testing.assert_allclose(ipca.explained_variance_ratio_.sum(), pca.explained_variance_ratio_.sum(), rtol=1e-3) for n_components in [1, 2, X.shape[1]]: ipca = IncrementalPCA(n_components, batch_size=batch_size) ipca.fit(X) cov = ipca.get_covariance() precision = ipca.get_precision() np.testing.assert_allclose(np.dot(cov, precision), np.eye(X.shape[1]), atol=1e-13)
def test_singular_values(): # Check that the IncrementalPCA output has the correct singular values rng = np.random.RandomState(0) n_samples = 1000 n_features = 100 X = datasets.make_low_rank_matrix(n_samples, n_features, tail_strength=0.0, effective_rank=10, random_state=rng) pca = PCA(n_components=10, svd_solver='full', random_state=rng).fit(X) ipca = IncrementalPCA(n_components=10, batch_size=100).fit(X) assert_array_almost_equal(pca.singular_values_, ipca.singular_values_, 2) # Compare to the Frobenius norm X_pca = pca.transform(X) X_ipca = ipca.transform(X) assert_array_almost_equal(np.sum(pca.singular_values_**2.0), np.linalg.norm(X_pca, "fro")**2.0, 12) assert_array_almost_equal(np.sum(ipca.singular_values_**2.0), np.linalg.norm(X_ipca, "fro")**2.0, 2) # Compare to the 2-norms of the score vectors assert_array_almost_equal(pca.singular_values_, np.sqrt(np.sum(X_pca**2.0, axis=0)), 12) assert_array_almost_equal(ipca.singular_values_, np.sqrt(np.sum(X_ipca**2.0, axis=0)), 2) # Set the singular values and see what we get back rng = np.random.RandomState(0) n_samples = 100 n_features = 110 X = datasets.make_low_rank_matrix(n_samples, n_features, tail_strength=0.0, effective_rank=3, random_state=rng) pca = PCA(n_components=3, svd_solver='full', random_state=rng) ipca = IncrementalPCA(n_components=3, batch_size=100) X_pca = pca.fit_transform(X) X_pca /= np.sqrt(np.sum(X_pca**2.0, axis=0)) X_pca[:, 0] *= 3.142 X_pca[:, 1] *= 2.718 X_hat = np.dot(X_pca, pca.components_) pca.fit(X_hat) ipca.fit(X_hat) assert_array_almost_equal(pca.singular_values_, [3.142, 2.718, 1.0], 14) assert_array_almost_equal(ipca.singular_values_, [3.142, 2.718, 1.0], 14)
def test_incremental_pca_check_projection(): # Test that the projection of data is correct. rng = np.random.RandomState(1999) n, p = 100, 3 X = rng.randn(n, p) * .1 X[:10] += np.array([3, 4, 5]) Xt = 0.1 * rng.randn(1, p) + np.array([3, 4, 5]) # Get the reconstruction of the generated data X # Note that Xt has the same "components" as X, just separated # This is what we want to ensure is recreated correctly Yt = IncrementalPCA(n_components=2).fit(X).transform(Xt) # Normalize Yt /= np.sqrt((Yt ** 2).sum()) # Make sure that the first element of Yt is ~1, this means # the reconstruction worked as expected assert_almost_equal(np.abs(Yt[0][0]), 1., 1)
def test_n_components_none(): # Ensures that n_components == None is handled correctly rng = np.random.RandomState(1999) for n_samples, n_features in [(50, 10), (10, 50)]: X = rng.rand(n_samples, n_features) ipca = IncrementalPCA(n_components=None) # First partial_fit call, ipca.n_components_ is inferred from # min(X.shape) ipca.partial_fit(X) assert ipca.n_components_ == min(X.shape) # Second partial_fit call, ipca.n_components_ is inferred from # ipca.components_ computed from the first partial_fit call ipca.partial_fit(X) assert ipca.n_components_ == ipca.components_.shape[0]
def test_incremental_pca_sparse(matrix_class): # Incremental PCA on sparse arrays. X = iris.data pca = PCA(n_components=2) pca.fit_transform(X) X_sparse = matrix_class(X) batch_size = X_sparse.shape[0] // 3 ipca = IncrementalPCA(n_components=2, batch_size=batch_size) X_transformed = ipca.fit_transform(X_sparse) assert X_transformed.shape == (X_sparse.shape[0], 2) np.testing.assert_allclose(ipca.explained_variance_ratio_.sum(), pca.explained_variance_ratio_.sum(), rtol=1e-3) for n_components in [1, 2, X.shape[1]]: ipca = IncrementalPCA(n_components, batch_size=batch_size) ipca.fit(X_sparse) cov = ipca.get_covariance() precision = ipca.get_precision() np.testing.assert_allclose(np.dot(cov, precision), np.eye(X_sparse.shape[1]), atol=1e-13) with pytest.raises( TypeError, match="IncrementalPCA.partial_fit does not support " "sparse input. Either convert data to dense " "or use IncrementalPCA.fit to do so in batches."): ipca.partial_fit(X_sparse)
def test_incremental_pca_partial_fit_float_division(): # Test to ensure float division is used in all versions of Python # (non-regression test for issue #9489) rng = np.random.RandomState(0) A = rng.randn(5, 3) + 2 B = rng.randn(7, 3) + 5 pca = IncrementalPCA(n_components=2) pca.partial_fit(A) # Set n_samples_seen_ to be a floating point number instead of an int pca.n_samples_seen_ = float(pca.n_samples_seen_) pca.partial_fit(B) singular_vals_float_samples_seen = pca.singular_values_ pca2 = IncrementalPCA(n_components=2) pca2.partial_fit(A) pca2.partial_fit(B) singular_vals_int_samples_seen = pca2.singular_values_ np.testing.assert_allclose(singular_vals_float_samples_seen, singular_vals_int_samples_seen)
def test_incremental_pca_set_params(): # Test that components_ sign is stable over batch sizes. rng = np.random.RandomState(1999) n_samples = 100 n_features = 20 X = rng.randn(n_samples, n_features) X2 = rng.randn(n_samples, n_features) X3 = rng.randn(n_samples, n_features) ipca = IncrementalPCA(n_components=20) ipca.fit(X) # Decreasing number of components ipca.set_params(n_components=10) with pytest.raises(ValueError): ipca.partial_fit(X2) # Increasing number of components ipca.set_params(n_components=15) with pytest.raises(ValueError): ipca.partial_fit(X3) # Returning to original setting ipca.set_params(n_components=20) ipca.partial_fit(X)