import pytest import numpy as np from numpy.testing import assert_allclose from sklearn.compose import ColumnTransformer from sklearn.datasets import load_diabetes from sklearn.datasets import load_iris from sklearn.datasets import make_classification from sklearn.datasets import make_regression from sklearn.dummy import DummyClassifier from sklearn.ensemble import RandomForestRegressor from sklearn.ensemble import RandomForestClassifier from sklearn.linear_model import LinearRegression from sklearn.linear_model import LogisticRegression from sklearn.impute import SimpleImputer from sklearn.inspection import permutation_importance from sklearn.model_selection import train_test_split from sklearn.metrics import ( get_scorer, mean_squared_error, r2_score, ) from sklearn.pipeline import make_pipeline from sklearn.preprocessing import KBinsDiscretizer from sklearn.preprocessing import OneHotEncoder from sklearn.preprocessing import StandardScaler from sklearn.preprocessing import scale from sklearn.utils import parallel_backend from sklearn.utils._testing import _convert_container @pytest.mark.parametrize("n_jobs", [1, 2]) @pytest.mark.parametrize("max_samples", [0.5, 1.0]) def test_permutation_importance_correlated_feature_regression(n_jobs, max_samples): # Make sure that feature highly correlated to the target have a higher # importance rng = np.random.RandomState(42) n_repeats = 5 X, y = load_diabetes(return_X_y=True) y_with_little_noise = (y + rng.normal(scale=0.001, size=y.shape[0])).reshape(-1, 1) X = np.hstack([X, y_with_little_noise]) clf = RandomForestRegressor(n_estimators=10, random_state=42) clf.fit(X, y) result = permutation_importance( clf, X, y, n_repeats=n_repeats, random_state=rng, n_jobs=n_jobs, max_samples=max_samples, ) assert result.importances.shape == (X.shape[1], n_repeats) # the correlated feature with y was added as the last column and should # have the highest importance assert np.all(result.importances_mean[-1] > result.importances_mean[:-1]) @pytest.mark.parametrize("n_jobs", [1, 2]) @pytest.mark.parametrize("max_samples", [0.5, 1.0]) def test_permutation_importance_correlated_feature_regression_pandas( n_jobs, max_samples ): pd = pytest.importorskip("pandas") # Make sure that feature highly correlated to the target have a higher # importance rng = np.random.RandomState(42) n_repeats = 5 dataset = load_iris() X, y = dataset.data, dataset.target y_with_little_noise = (y + rng.normal(scale=0.001, size=y.shape[0])).reshape(-1, 1) # Adds feature correlated with y as the last column X = pd.DataFrame(X, columns=dataset.feature_names) X["correlated_feature"] = y_with_little_noise clf = RandomForestClassifier(n_estimators=10, random_state=42) clf.fit(X, y) result = permutation_importance( clf, X, y, n_repeats=n_repeats, random_state=rng, n_jobs=n_jobs, max_samples=max_samples, ) assert result.importances.shape == (X.shape[1], n_repeats) # the correlated feature with y was added as the last column and should # have the highest importance assert np.all(result.importances_mean[-1] > result.importances_mean[:-1]) @pytest.mark.parametrize("n_jobs", [1, 2]) @pytest.mark.parametrize("max_samples", [0.5, 1.0]) def test_robustness_to_high_cardinality_noisy_feature(n_jobs, max_samples, seed=42): # Permutation variable importance should not be affected by the high # cardinality bias of traditional feature importances, especially when # computed on a held-out test set: rng = np.random.RandomState(seed) n_repeats = 5 n_samples = 1000 n_classes = 5 n_informative_features = 2 n_noise_features = 1 n_features = n_informative_features + n_noise_features # Generate a multiclass classification dataset and a set of informative # binary features that can be used to predict some classes of y exactly # while leaving some classes unexplained to make the problem harder. classes = np.arange(n_classes) y = rng.choice(classes, size=n_samples) X = np.hstack([(y == c).reshape(-1, 1) for c in classes[:n_informative_features]]) X = X.astype(np.float32) # Not all target classes are explained by the binary class indicator # features: assert n_informative_features < n_classes # Add 10 other noisy features with high cardinality (numerical) values # that can be used to overfit the training data. X = np.concatenate([X, rng.randn(n_samples, n_noise_features)], axis=1) assert X.shape == (n_samples, n_features) # Split the dataset to be able to evaluate on a held-out test set. The # Test size should be large enough for importance measurements to be # stable: X_train, X_test, y_train, y_test = train_test_split( X, y, test_size=0.5, random_state=rng ) clf = RandomForestClassifier(n_estimators=5, random_state=rng) clf.fit(X_train, y_train) # Variable importances computed by impurity decrease on the tree node # splits often use the noisy features in splits. This can give misleading # impression that high cardinality noisy variables are the most important: tree_importances = clf.feature_importances_ informative_tree_importances = tree_importances[:n_informative_features] noisy_tree_importances = tree_importances[n_informative_features:] assert informative_tree_importances.max() < noisy_tree_importances.min() # Let's check that permutation-based feature importances do not have this # problem. r = permutation_importance( clf, X_test, y_test, n_repeats=n_repeats, random_state=rng, n_jobs=n_jobs, max_samples=max_samples, ) assert r.importances.shape == (X.shape[1], n_repeats) # Split the importances between informative and noisy features informative_importances = r.importances_mean[:n_informative_features] noisy_importances = r.importances_mean[n_informative_features:] # Because we do not have a binary variable explaining each target classes, # the RF model will have to use the random variable to make some # (overfitting) splits (as max_depth is not set). Therefore the noisy # variables will be non-zero but with small values oscillating around # zero: assert max(np.abs(noisy_importances)) > 1e-7 assert noisy_importances.max() < 0.05 # The binary features correlated with y should have a higher importance # than the high cardinality noisy features. # The maximum test accuracy is 2 / 5 == 0.4, each informative feature # contributing approximately a bit more than 0.2 of accuracy. assert informative_importances.min() > 0.15 def test_permutation_importance_mixed_types(): rng = np.random.RandomState(42) n_repeats = 4 # Last column is correlated with y X = np.array([[1.0, 2.0, 3.0, np.nan], [2, 1, 2, 1]]).T y = np.array([0, 1, 0, 1]) clf = make_pipeline(SimpleImputer(), LogisticRegression(solver="lbfgs")) clf.fit(X, y) result = permutation_importance(clf, X, y, n_repeats=n_repeats, random_state=rng) assert result.importances.shape == (X.shape[1], n_repeats) # the correlated feature with y is the last column and should # have the highest importance assert np.all(result.importances_mean[-1] > result.importances_mean[:-1]) # use another random state rng = np.random.RandomState(0) result2 = permutation_importance(clf, X, y, n_repeats=n_repeats, random_state=rng) assert result2.importances.shape == (X.shape[1], n_repeats) assert not np.allclose(result.importances, result2.importances) # the correlated feature with y is the last column and should # have the highest importance assert np.all(result2.importances_mean[-1] > result2.importances_mean[:-1]) def test_permutation_importance_mixed_types_pandas(): pd = pytest.importorskip("pandas") rng = np.random.RandomState(42) n_repeats = 5 # Last column is correlated with y X = pd.DataFrame({"col1": [1.0, 2.0, 3.0, np.nan], "col2": ["a", "b", "a", "b"]}) y = np.array([0, 1, 0, 1]) num_preprocess = make_pipeline(SimpleImputer(), StandardScaler()) preprocess = ColumnTransformer( [("num", num_preprocess, ["col1"]), ("cat", OneHotEncoder(), ["col2"])] ) clf = make_pipeline(preprocess, LogisticRegression(solver="lbfgs")) clf.fit(X, y) result = permutation_importance(clf, X, y, n_repeats=n_repeats, random_state=rng) assert result.importances.shape == (X.shape[1], n_repeats) # the correlated feature with y is the last column and should # have the highest importance assert np.all(result.importances_mean[-1] > result.importances_mean[:-1]) def test_permutation_importance_linear_regresssion(): X, y = make_regression(n_samples=500, n_features=10, random_state=0) X = scale(X) y = scale(y) lr = LinearRegression().fit(X, y) # this relationship can be computed in closed form expected_importances = 2 * lr.coef_**2 results = permutation_importance( lr, X, y, n_repeats=50, scoring="neg_mean_squared_error" ) assert_allclose( expected_importances, results.importances_mean, rtol=1e-1, atol=1e-6 ) @pytest.mark.parametrize("max_samples", [500, 1.0]) def test_permutation_importance_equivalence_sequential_parallel(max_samples): # regression test to make sure that sequential and parallel calls will # output the same results. # Also tests that max_samples equal to number of samples is equivalent to 1.0 X, y = make_regression(n_samples=500, n_features=10, random_state=0) lr = LinearRegression().fit(X, y) importance_sequential = permutation_importance( lr, X, y, n_repeats=5, random_state=0, n_jobs=1, max_samples=max_samples ) # First check that the problem is structured enough and that the model is # complex enough to not yield trivial, constant importances: imp_min = importance_sequential["importances"].min() imp_max = importance_sequential["importances"].max() assert imp_max - imp_min > 0.3 # The actually check that parallelism does not impact the results # either with shared memory (threading) or without isolated memory # via process-based parallelism using the default backend # ('loky' or 'multiprocessing') depending on the joblib version: # process-based parallelism (by default): importance_processes = permutation_importance( lr, X, y, n_repeats=5, random_state=0, n_jobs=2 ) assert_allclose( importance_processes["importances"], importance_sequential["importances"] ) # thread-based parallelism: with parallel_backend("threading"): importance_threading = permutation_importance( lr, X, y, n_repeats=5, random_state=0, n_jobs=2 ) assert_allclose( importance_threading["importances"], importance_sequential["importances"] ) @pytest.mark.parametrize("n_jobs", [None, 1, 2]) @pytest.mark.parametrize("max_samples", [0.5, 1.0]) def test_permutation_importance_equivalence_array_dataframe(n_jobs, max_samples): # This test checks that the column shuffling logic has the same behavior # both a dataframe and a simple numpy array. pd = pytest.importorskip("pandas") # regression test to make sure that sequential and parallel calls will # output the same results. X, y = make_regression(n_samples=100, n_features=5, random_state=0) X_df = pd.DataFrame(X) # Add a categorical feature that is statistically linked to y: binner = KBinsDiscretizer(n_bins=3, encode="ordinal") cat_column = binner.fit_transform(y.reshape(-1, 1)) # Concatenate the extra column to the numpy array: integers will be # cast to float values X = np.hstack([X, cat_column]) assert X.dtype.kind == "f" # Insert extra column as a non-numpy-native dtype (while keeping backward # compat for old pandas versions): if hasattr(pd, "Categorical"): cat_column = pd.Categorical(cat_column.ravel()) else: cat_column = cat_column.ravel() new_col_idx = len(X_df.columns) X_df[new_col_idx] = cat_column assert X_df[new_col_idx].dtype == cat_column.dtype # Stich an arbitrary index to the dataframe: X_df.index = np.arange(len(X_df)).astype(str) rf = RandomForestRegressor(n_estimators=5, max_depth=3, random_state=0) rf.fit(X, y) n_repeats = 3 importance_array = permutation_importance( rf, X, y, n_repeats=n_repeats, random_state=0, n_jobs=n_jobs, max_samples=max_samples, ) # First check that the problem is structured enough and that the model is # complex enough to not yield trivial, constant importances: imp_min = importance_array["importances"].min() imp_max = importance_array["importances"].max() assert imp_max - imp_min > 0.3 # Now check that importances computed on dataframe matche the values # of those computed on the array with the same data. importance_dataframe = permutation_importance( rf, X_df, y, n_repeats=n_repeats, random_state=0, n_jobs=n_jobs, max_samples=max_samples, ) assert_allclose( importance_array["importances"], importance_dataframe["importances"] ) @pytest.mark.parametrize("input_type", ["array", "dataframe"]) def test_permutation_importance_large_memmaped_data(input_type): # Smoke, non-regression test for: # https://github.com/scikit-learn/scikit-learn/issues/15810 n_samples, n_features = int(5e4), 4 X, y = make_classification( n_samples=n_samples, n_features=n_features, random_state=0 ) assert X.nbytes > 1e6 # trigger joblib memmaping X = _convert_container(X, input_type) clf = DummyClassifier(strategy="prior").fit(X, y) # Actual smoke test: should not raise any error: n_repeats = 5 r = permutation_importance(clf, X, y, n_repeats=n_repeats, n_jobs=2) # Auxiliary check: DummyClassifier is feature independent: # permutating feature should not change the predictions expected_importances = np.zeros((n_features, n_repeats)) assert_allclose(expected_importances, r.importances) def test_permutation_importance_sample_weight(): # Creating data with 2 features and 1000 samples, where the target # variable is a linear combination of the two features, such that # in half of the samples the impact of feature 1 is twice the impact of # feature 2, and vice versa on the other half of the samples. rng = np.random.RandomState(1) n_samples = 1000 n_features = 2 n_half_samples = n_samples // 2 x = rng.normal(0.0, 0.001, (n_samples, n_features)) y = np.zeros(n_samples) y[:n_half_samples] = 2 * x[:n_half_samples, 0] + x[:n_half_samples, 1] y[n_half_samples:] = x[n_half_samples:, 0] + 2 * x[n_half_samples:, 1] # Fitting linear regression with perfect prediction lr = LinearRegression(fit_intercept=False) lr.fit(x, y) # When all samples are weighted with the same weights, the ratio of # the two features importance should equal to 1 on expectation (when using # mean absolutes error as the loss function). pi = permutation_importance( lr, x, y, random_state=1, scoring="neg_mean_absolute_error", n_repeats=200 ) x1_x2_imp_ratio_w_none = pi.importances_mean[0] / pi.importances_mean[1] assert x1_x2_imp_ratio_w_none == pytest.approx(1, 0.01) # When passing a vector of ones as the sample_weight, results should be # the same as in the case that sample_weight=None. w = np.ones(n_samples) pi = permutation_importance( lr, x, y, random_state=1, scoring="neg_mean_absolute_error", n_repeats=200, sample_weight=w, ) x1_x2_imp_ratio_w_ones = pi.importances_mean[0] / pi.importances_mean[1] assert x1_x2_imp_ratio_w_ones == pytest.approx(x1_x2_imp_ratio_w_none, 0.01) # When the ratio between the weights of the first half of the samples and # the second half of the samples approaches to infinity, the ratio of # the two features importance should equal to 2 on expectation (when using # mean absolutes error as the loss function). w = np.hstack( [np.repeat(10.0**10, n_half_samples), np.repeat(1.0, n_half_samples)] ) lr.fit(x, y, w) pi = permutation_importance( lr, x, y, random_state=1, scoring="neg_mean_absolute_error", n_repeats=200, sample_weight=w, ) x1_x2_imp_ratio_w = pi.importances_mean[0] / pi.importances_mean[1] assert x1_x2_imp_ratio_w / x1_x2_imp_ratio_w_none == pytest.approx(2, 0.01) def test_permutation_importance_no_weights_scoring_function(): # Creating a scorer function that does not takes sample_weight def my_scorer(estimator, X, y): return 1 # Creating some data and estimator for the permutation test x = np.array([[1, 2], [3, 4]]) y = np.array([1, 2]) w = np.array([1, 1]) lr = LinearRegression() lr.fit(x, y) # test that permutation_importance does not return error when # sample_weight is None try: permutation_importance(lr, x, y, random_state=1, scoring=my_scorer, n_repeats=1) except TypeError: pytest.fail( "permutation_test raised an error when using a scorer " "function that does not accept sample_weight even though " "sample_weight was None" ) # test that permutation_importance raise exception when sample_weight is # not None with pytest.raises(TypeError): permutation_importance( lr, x, y, random_state=1, scoring=my_scorer, n_repeats=1, sample_weight=w ) @pytest.mark.parametrize( "list_single_scorer, multi_scorer", [ (["r2", "neg_mean_squared_error"], ["r2", "neg_mean_squared_error"]), ( ["r2", "neg_mean_squared_error"], { "r2": get_scorer("r2"), "neg_mean_squared_error": get_scorer("neg_mean_squared_error"), }, ), ( ["r2", "neg_mean_squared_error"], lambda estimator, X, y: { "r2": r2_score(y, estimator.predict(X)), "neg_mean_squared_error": -mean_squared_error(y, estimator.predict(X)), }, ), ], ) def test_permutation_importance_multi_metric(list_single_scorer, multi_scorer): # Test permutation importance when scoring contains multiple scorers # Creating some data and estimator for the permutation test x, y = make_regression(n_samples=500, n_features=10, random_state=0) lr = LinearRegression().fit(x, y) multi_importance = permutation_importance( lr, x, y, random_state=1, scoring=multi_scorer, n_repeats=2 ) assert set(multi_importance.keys()) == set(list_single_scorer) for scorer in list_single_scorer: multi_result = multi_importance[scorer] single_result = permutation_importance( lr, x, y, random_state=1, scoring=scorer, n_repeats=2 ) assert_allclose(multi_result.importances, single_result.importances) @pytest.mark.parametrize("max_samples", [-1, 5]) def test_permutation_importance_max_samples_error(max_samples): """Check that a proper error message is raised when `max_samples` is not set to a valid input value. """ X = np.array([(1.0, 2.0, 3.0, 4.0)]).T y = np.array([0, 1, 0, 1]) clf = LogisticRegression() clf.fit(X, y) err_msg = r"max_samples must be in \(0, n_samples\]" with pytest.raises(ValueError, match=err_msg): permutation_importance(clf, X, y, max_samples=max_samples)