import numpy as np from sklearn.utils.testing import (assert_array_almost_equal, assert_array_equal, assert_true, assert_raise_message) from sklearn.datasets import load_linnerud from sklearn.cross_decomposition import pls_, CCA from nose.tools import assert_equal def test_pls(): d = load_linnerud() X = d.data Y = d.target # 1) Canonical (symmetric) PLS (PLS 2 blocks canonical mode A) # =========================================================== # Compare 2 algo.: nipals vs. svd # ------------------------------ pls_bynipals = pls_.PLSCanonical(n_components=X.shape[1]) pls_bynipals.fit(X, Y) pls_bysvd = pls_.PLSCanonical(algorithm="svd", n_components=X.shape[1]) pls_bysvd.fit(X, Y) # check equalities of loading (up to the sign of the second column) assert_array_almost_equal( pls_bynipals.x_loadings_, pls_bysvd.x_loadings_, decimal=5, err_msg="nipals and svd implementations lead to different x loadings") assert_array_almost_equal( pls_bynipals.y_loadings_, pls_bysvd.y_loadings_, decimal=5, err_msg="nipals and svd implementations lead to different y loadings") # Check PLS properties (with n_components=X.shape[1]) # --------------------------------------------------- plsca = pls_.PLSCanonical(n_components=X.shape[1]) plsca.fit(X, Y) T = plsca.x_scores_ P = plsca.x_loadings_ Wx = plsca.x_weights_ U = plsca.y_scores_ Q = plsca.y_loadings_ Wy = plsca.y_weights_ def check_ortho(M, err_msg): K = np.dot(M.T, M) assert_array_almost_equal(K, np.diag(np.diag(K)), err_msg=err_msg) # Orthogonality of weights # ~~~~~~~~~~~~~~~~~~~~~~~~ check_ortho(Wx, "x weights are not orthogonal") check_ortho(Wy, "y weights are not orthogonal") # Orthogonality of latent scores # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ check_ortho(T, "x scores are not orthogonal") check_ortho(U, "y scores are not orthogonal") # Check X = TP' and Y = UQ' (with (p == q) components) # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ # center scale X, Y Xc, Yc, x_mean, y_mean, x_std, y_std =\ pls_._center_scale_xy(X.copy(), Y.copy(), scale=True) assert_array_almost_equal(Xc, np.dot(T, P.T), err_msg="X != TP'") assert_array_almost_equal(Yc, np.dot(U, Q.T), err_msg="Y != UQ'") # Check that rotations on training data lead to scores # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Xr = plsca.transform(X) assert_array_almost_equal(Xr, plsca.x_scores_, err_msg="rotation on X failed") Xr, Yr = plsca.transform(X, Y) assert_array_almost_equal(Xr, plsca.x_scores_, err_msg="rotation on X failed") assert_array_almost_equal(Yr, plsca.y_scores_, err_msg="rotation on Y failed") # "Non regression test" on canonical PLS # -------------------------------------- # The results were checked against the R-package plspm pls_ca = pls_.PLSCanonical(n_components=X.shape[1]) pls_ca.fit(X, Y) x_weights = np.array( [[-0.61330704, 0.25616119, -0.74715187], [-0.74697144, 0.11930791, 0.65406368], [-0.25668686, -0.95924297, -0.11817271]]) # x_weights_sign_flip holds columns of 1 or -1, depending on sign flip # between R and python x_weights_sign_flip = pls_ca.x_weights_ / x_weights x_rotations = np.array( [[-0.61330704, 0.41591889, -0.62297525], [-0.74697144, 0.31388326, 0.77368233], [-0.25668686, -0.89237972, -0.24121788]]) x_rotations_sign_flip = pls_ca.x_rotations_ / x_rotations y_weights = np.array( [[+0.58989127, 0.7890047, 0.1717553], [+0.77134053, -0.61351791, 0.16920272], [-0.23887670, -0.03267062, 0.97050016]]) y_weights_sign_flip = pls_ca.y_weights_ / y_weights y_rotations = np.array( [[+0.58989127, 0.7168115, 0.30665872], [+0.77134053, -0.70791757, 0.19786539], [-0.23887670, -0.00343595, 0.94162826]]) y_rotations_sign_flip = pls_ca.y_rotations_ / y_rotations # x_weights = X.dot(x_rotation) # Hence R/python sign flip should be the same in x_weight and x_rotation assert_array_almost_equal(x_rotations_sign_flip, x_weights_sign_flip) # This test that R / python give the same result up to column # sign indeterminacy assert_array_almost_equal(np.abs(x_rotations_sign_flip), 1, 4) assert_array_almost_equal(np.abs(x_weights_sign_flip), 1, 4) assert_array_almost_equal(y_rotations_sign_flip, y_weights_sign_flip) assert_array_almost_equal(np.abs(y_rotations_sign_flip), 1, 4) assert_array_almost_equal(np.abs(y_weights_sign_flip), 1, 4) # 2) Regression PLS (PLS2): "Non regression test" # =============================================== # The results were checked against the R-packages plspm, misOmics and pls pls_2 = pls_.PLSRegression(n_components=X.shape[1]) pls_2.fit(X, Y) x_weights = np.array( [[-0.61330704, -0.00443647, 0.78983213], [-0.74697144, -0.32172099, -0.58183269], [-0.25668686, 0.94682413, -0.19399983]]) x_weights_sign_flip = pls_2.x_weights_ / x_weights x_loadings = np.array( [[-0.61470416, -0.24574278, 0.78983213], [-0.65625755, -0.14396183, -0.58183269], [-0.51733059, 1.00609417, -0.19399983]]) x_loadings_sign_flip = pls_2.x_loadings_ / x_loadings y_weights = np.array( [[+0.32456184, 0.29892183, 0.20316322], [+0.42439636, 0.61970543, 0.19320542], [-0.13143144, -0.26348971, -0.17092916]]) y_weights_sign_flip = pls_2.y_weights_ / y_weights y_loadings = np.array( [[+0.32456184, 0.29892183, 0.20316322], [+0.42439636, 0.61970543, 0.19320542], [-0.13143144, -0.26348971, -0.17092916]]) y_loadings_sign_flip = pls_2.y_loadings_ / y_loadings # x_loadings[:, i] = Xi.dot(x_weights[:, i]) \forall i assert_array_almost_equal(x_loadings_sign_flip, x_weights_sign_flip, 4) assert_array_almost_equal(np.abs(x_loadings_sign_flip), 1, 4) assert_array_almost_equal(np.abs(x_weights_sign_flip), 1, 4) assert_array_almost_equal(y_loadings_sign_flip, y_weights_sign_flip, 4) assert_array_almost_equal(np.abs(y_loadings_sign_flip), 1, 4) assert_array_almost_equal(np.abs(y_weights_sign_flip), 1, 4) # 3) Another non-regression test of Canonical PLS on random dataset # ================================================================= # The results were checked against the R-package plspm n = 500 p_noise = 10 q_noise = 5 # 2 latents vars: np.random.seed(11) l1 = np.random.normal(size=n) l2 = np.random.normal(size=n) latents = np.array([l1, l1, l2, l2]).T X = latents + np.random.normal(size=4 * n).reshape((n, 4)) Y = latents + np.random.normal(size=4 * n).reshape((n, 4)) X = np.concatenate( (X, np.random.normal(size=p_noise * n).reshape(n, p_noise)), axis=1) Y = np.concatenate( (Y, np.random.normal(size=q_noise * n).reshape(n, q_noise)), axis=1) np.random.seed(None) pls_ca = pls_.PLSCanonical(n_components=3) pls_ca.fit(X, Y) x_weights = np.array( [[0.65803719, 0.19197924, 0.21769083], [0.7009113, 0.13303969, -0.15376699], [0.13528197, -0.68636408, 0.13856546], [0.16854574, -0.66788088, -0.12485304], [-0.03232333, -0.04189855, 0.40690153], [0.1148816, -0.09643158, 0.1613305], [0.04792138, -0.02384992, 0.17175319], [-0.06781, -0.01666137, -0.18556747], [-0.00266945, -0.00160224, 0.11893098], [-0.00849528, -0.07706095, 0.1570547], [-0.00949471, -0.02964127, 0.34657036], [-0.03572177, 0.0945091, 0.3414855], [0.05584937, -0.02028961, -0.57682568], [0.05744254, -0.01482333, -0.17431274]]) x_weights_sign_flip = pls_ca.x_weights_ / x_weights x_loadings = np.array( [[0.65649254, 0.1847647, 0.15270699], [0.67554234, 0.15237508, -0.09182247], [0.19219925, -0.67750975, 0.08673128], [0.2133631, -0.67034809, -0.08835483], [-0.03178912, -0.06668336, 0.43395268], [0.15684588, -0.13350241, 0.20578984], [0.03337736, -0.03807306, 0.09871553], [-0.06199844, 0.01559854, -0.1881785], [0.00406146, -0.00587025, 0.16413253], [-0.00374239, -0.05848466, 0.19140336], [0.00139214, -0.01033161, 0.32239136], [-0.05292828, 0.0953533, 0.31916881], [0.04031924, -0.01961045, -0.65174036], [0.06172484, -0.06597366, -0.1244497]]) x_loadings_sign_flip = pls_ca.x_loadings_ / x_loadings y_weights = np.array( [[0.66101097, 0.18672553, 0.22826092], [0.69347861, 0.18463471, -0.23995597], [0.14462724, -0.66504085, 0.17082434], [0.22247955, -0.6932605, -0.09832993], [0.07035859, 0.00714283, 0.67810124], [0.07765351, -0.0105204, -0.44108074], [-0.00917056, 0.04322147, 0.10062478], [-0.01909512, 0.06182718, 0.28830475], [0.01756709, 0.04797666, 0.32225745]]) y_weights_sign_flip = pls_ca.y_weights_ / y_weights y_loadings = np.array( [[0.68568625, 0.1674376, 0.0969508], [0.68782064, 0.20375837, -0.1164448], [0.11712173, -0.68046903, 0.12001505], [0.17860457, -0.6798319, -0.05089681], [0.06265739, -0.0277703, 0.74729584], [0.0914178, 0.00403751, -0.5135078], [-0.02196918, -0.01377169, 0.09564505], [-0.03288952, 0.09039729, 0.31858973], [0.04287624, 0.05254676, 0.27836841]]) y_loadings_sign_flip = pls_ca.y_loadings_ / y_loadings assert_array_almost_equal(x_loadings_sign_flip, x_weights_sign_flip, 4) assert_array_almost_equal(np.abs(x_weights_sign_flip), 1, 4) assert_array_almost_equal(np.abs(x_loadings_sign_flip), 1, 4) assert_array_almost_equal(y_loadings_sign_flip, y_weights_sign_flip, 4) assert_array_almost_equal(np.abs(y_weights_sign_flip), 1, 4) assert_array_almost_equal(np.abs(y_loadings_sign_flip), 1, 4) # Orthogonality of weights # ~~~~~~~~~~~~~~~~~~~~~~~~ check_ortho(pls_ca.x_weights_, "x weights are not orthogonal") check_ortho(pls_ca.y_weights_, "y weights are not orthogonal") # Orthogonality of latent scores # ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ check_ortho(pls_ca.x_scores_, "x scores are not orthogonal") check_ortho(pls_ca.y_scores_, "y scores are not orthogonal") def test_PLSSVD(): # Let's check the PLSSVD doesn't return all possible component but just # the specified number d = load_linnerud() X = d.data Y = d.target n_components = 2 for clf in [pls_.PLSSVD, pls_.PLSRegression, pls_.PLSCanonical]: pls = clf(n_components=n_components) pls.fit(X, Y) assert_equal(n_components, pls.y_scores_.shape[1]) def test_univariate_pls_regression(): # Ensure 1d Y is correctly interpreted d = load_linnerud() X = d.data Y = d.target clf = pls_.PLSRegression() # Compare 1d to column vector model1 = clf.fit(X, Y[:, 0]).coef_ model2 = clf.fit(X, Y[:, :1]).coef_ assert_array_almost_equal(model1, model2) def test_predict_transform_copy(): # check that the "copy" keyword works d = load_linnerud() X = d.data Y = d.target clf = pls_.PLSCanonical() X_copy = X.copy() Y_copy = Y.copy() clf.fit(X, Y) # check that results are identical with copy assert_array_almost_equal(clf.predict(X), clf.predict(X.copy(), copy=False)) assert_array_almost_equal(clf.transform(X), clf.transform(X.copy(), copy=False)) # check also if passing Y assert_array_almost_equal(clf.transform(X, Y), clf.transform(X.copy(), Y.copy(), copy=False)) # check that copy doesn't destroy # we do want to check exact equality here assert_array_equal(X_copy, X) assert_array_equal(Y_copy, Y) # also check that mean wasn't zero before (to make sure we didn't touch it) assert_true(np.all(X.mean(axis=0) != 0)) def test_scale_and_stability(): # We test scale=True parameter # This allows to check numerical stability over platforms as well d = load_linnerud() X1 = d.data Y1 = d.target # causes X[:, -1].std() to be zero X1[:, -1] = 1.0 # From bug #2821 # Test with X2, T2 s.t. clf.x_score[:, 1] == 0, clf.y_score[:, 1] == 0 # This test robustness of algorithm when dealing with value close to 0 X2 = np.array([[0., 0., 1.], [1., 0., 0.], [2., 2., 2.], [3., 5., 4.]]) Y2 = np.array([[0.1, -0.2], [0.9, 1.1], [6.2, 5.9], [11.9, 12.3]]) for (X, Y) in [(X1, Y1), (X2, Y2)]: X_std = X.std(axis=0, ddof=1) X_std[X_std == 0] = 1 Y_std = Y.std(axis=0, ddof=1) Y_std[Y_std == 0] = 1 X_s = (X - X.mean(axis=0)) / X_std Y_s = (Y - Y.mean(axis=0)) / Y_std for clf in [CCA(), pls_.PLSCanonical(), pls_.PLSRegression(), pls_.PLSSVD()]: clf.set_params(scale=True) X_score, Y_score = clf.fit_transform(X, Y) clf.set_params(scale=False) X_s_score, Y_s_score = clf.fit_transform(X_s, Y_s) assert_array_almost_equal(X_s_score, X_score) assert_array_almost_equal(Y_s_score, Y_score) # Scaling should be idempotent clf.set_params(scale=True) X_score, Y_score = clf.fit_transform(X_s, Y_s) assert_array_almost_equal(X_s_score, X_score) assert_array_almost_equal(Y_s_score, Y_score) def test_pls_errors(): d = load_linnerud() X = d.data Y = d.target for clf in [pls_.PLSCanonical(), pls_.PLSRegression(), pls_.PLSSVD()]: clf.n_components = 4 assert_raise_message(ValueError, "Invalid number of components", clf.fit, X, Y)