""" Testing for Isolation Forest algorithm (sklearn.ensemble.iforest). """ # Authors: Nicolas Goix # Alexandre Gramfort # License: BSD 3 clause import pytest import numpy as np from sklearn.utils._testing import assert_array_equal from sklearn.utils._testing import assert_array_almost_equal from sklearn.utils._testing import assert_raises from sklearn.utils._testing import assert_warns_message from sklearn.utils._testing import ignore_warnings from sklearn.utils._testing import assert_allclose from sklearn.model_selection import ParameterGrid from sklearn.ensemble import IsolationForest from sklearn.ensemble._iforest import _average_path_length from sklearn.model_selection import train_test_split from sklearn.datasets import load_diabetes, load_iris from sklearn.utils import check_random_state from sklearn.metrics import roc_auc_score from scipy.sparse import csc_matrix, csr_matrix from unittest.mock import Mock, patch rng = check_random_state(0) # load the iris dataset # and randomly permute it iris = load_iris() perm = rng.permutation(iris.target.size) iris.data = iris.data[perm] iris.target = iris.target[perm] # also load the diabetes dataset # and randomly permute it diabetes = load_diabetes() perm = rng.permutation(diabetes.target.size) diabetes.data = diabetes.data[perm] diabetes.target = diabetes.target[perm] def test_iforest(): """Check Isolation Forest for various parameter settings.""" X_train = np.array([[0, 1], [1, 2]]) X_test = np.array([[2, 1], [1, 1]]) grid = ParameterGrid({"n_estimators": [3], "max_samples": [0.5, 1.0, 3], "bootstrap": [True, False]}) with ignore_warnings(): for params in grid: IsolationForest(random_state=rng, **params).fit(X_train).predict(X_test) def test_iforest_sparse(): """Check IForest for various parameter settings on sparse input.""" rng = check_random_state(0) X_train, X_test, y_train, y_test = train_test_split(diabetes.data[:50], diabetes.target[:50], random_state=rng) grid = ParameterGrid({"max_samples": [0.5, 1.0], "bootstrap": [True, False]}) for sparse_format in [csc_matrix, csr_matrix]: X_train_sparse = sparse_format(X_train) X_test_sparse = sparse_format(X_test) for params in grid: # Trained on sparse format sparse_classifier = IsolationForest( n_estimators=10, random_state=1, **params).fit(X_train_sparse) sparse_results = sparse_classifier.predict(X_test_sparse) # Trained on dense format dense_classifier = IsolationForest( n_estimators=10, random_state=1, **params).fit(X_train) dense_results = dense_classifier.predict(X_test) assert_array_equal(sparse_results, dense_results) def test_iforest_error(): """Test that it gives proper exception on deficient input.""" X = iris.data # Test max_samples assert_raises(ValueError, IsolationForest(max_samples=-1).fit, X) assert_raises(ValueError, IsolationForest(max_samples=0.0).fit, X) assert_raises(ValueError, IsolationForest(max_samples=2.0).fit, X) # The dataset has less than 256 samples, explicitly setting # max_samples > n_samples should result in a warning. If not set # explicitly there should be no warning assert_warns_message(UserWarning, "max_samples will be set to n_samples for estimation", IsolationForest(max_samples=1000).fit, X) # note that assert_no_warnings does not apply since it enables a # PendingDeprecationWarning triggered by scipy.sparse's use of # np.matrix. See issue #11251. with pytest.warns(None) as record: IsolationForest(max_samples='auto').fit(X) user_warnings = [each for each in record if issubclass(each.category, UserWarning)] assert len(user_warnings) == 0 with pytest.warns(None) as record: IsolationForest(max_samples=np.int64(2)).fit(X) user_warnings = [each for each in record if issubclass(each.category, UserWarning)] assert len(user_warnings) == 0 assert_raises(ValueError, IsolationForest(max_samples='foobar').fit, X) assert_raises(ValueError, IsolationForest(max_samples=1.5).fit, X) # test X_test n_features match X_train one: assert_raises(ValueError, IsolationForest().fit(X).predict, X[:, 1:]) def test_recalculate_max_depth(): """Check max_depth recalculation when max_samples is reset to n_samples""" X = iris.data clf = IsolationForest().fit(X) for est in clf.estimators_: assert est.max_depth == int(np.ceil(np.log2(X.shape[0]))) def test_max_samples_attribute(): X = iris.data clf = IsolationForest().fit(X) assert clf.max_samples_ == X.shape[0] clf = IsolationForest(max_samples=500) assert_warns_message(UserWarning, "max_samples will be set to n_samples for estimation", clf.fit, X) assert clf.max_samples_ == X.shape[0] clf = IsolationForest(max_samples=0.4).fit(X) assert clf.max_samples_ == 0.4*X.shape[0] def test_iforest_parallel_regression(): """Check parallel regression.""" rng = check_random_state(0) X_train, X_test, y_train, y_test = train_test_split(diabetes.data, diabetes.target, random_state=rng) ensemble = IsolationForest(n_jobs=3, random_state=0).fit(X_train) ensemble.set_params(n_jobs=1) y1 = ensemble.predict(X_test) ensemble.set_params(n_jobs=2) y2 = ensemble.predict(X_test) assert_array_almost_equal(y1, y2) ensemble = IsolationForest(n_jobs=1, random_state=0).fit(X_train) y3 = ensemble.predict(X_test) assert_array_almost_equal(y1, y3) def test_iforest_performance(): """Test Isolation Forest performs well""" # Generate train/test data rng = check_random_state(2) X = 0.3 * rng.randn(120, 2) X_train = np.r_[X + 2, X - 2] X_train = X[:100] # Generate some abnormal novel observations X_outliers = rng.uniform(low=-4, high=4, size=(20, 2)) X_test = np.r_[X[100:], X_outliers] y_test = np.array([0] * 20 + [1] * 20) # fit the model clf = IsolationForest(max_samples=100, random_state=rng).fit(X_train) # predict scores (the lower, the more normal) y_pred = - clf.decision_function(X_test) # check that there is at most 6 errors (false positive or false negative) assert roc_auc_score(y_test, y_pred) > 0.98 @pytest.mark.parametrize("contamination", [0.25, "auto"]) def test_iforest_works(contamination): # toy sample (the last two samples are outliers) X = [[-2, -1], [-1, -1], [-1, -2], [1, 1], [1, 2], [2, 1], [6, 3], [-4, 7]] # Test IsolationForest clf = IsolationForest(random_state=rng, contamination=contamination) clf.fit(X) decision_func = -clf.decision_function(X) pred = clf.predict(X) # assert detect outliers: assert np.min(decision_func[-2:]) > np.max(decision_func[:-2]) assert_array_equal(pred, 6 * [1] + 2 * [-1]) def test_max_samples_consistency(): # Make sure validated max_samples in iforest and BaseBagging are identical X = iris.data clf = IsolationForest().fit(X) assert clf.max_samples_ == clf._max_samples def test_iforest_subsampled_features(): # It tests non-regression for #5732 which failed at predict. rng = check_random_state(0) X_train, X_test, y_train, y_test = train_test_split(diabetes.data[:50], diabetes.target[:50], random_state=rng) clf = IsolationForest(max_features=0.8) clf.fit(X_train, y_train) clf.predict(X_test) def test_iforest_average_path_length(): # It tests non-regression for #8549 which used the wrong formula # for average path length, strictly for the integer case # Updated to check average path length when input is <= 2 (issue #11839) result_one = 2.0 * (np.log(4.0) + np.euler_gamma) - 2.0 * 4.0 / 5.0 result_two = 2.0 * (np.log(998.0) + np.euler_gamma) - 2.0 * 998.0 / 999.0 assert_allclose(_average_path_length([0]), [0.0]) assert_allclose(_average_path_length([1]), [0.0]) assert_allclose(_average_path_length([2]), [1.0]) assert_allclose(_average_path_length([5]), [result_one]) assert_allclose(_average_path_length([999]), [result_two]) assert_allclose( _average_path_length(np.array([1, 2, 5, 999])), [0.0, 1.0, result_one, result_two], ) # _average_path_length is increasing avg_path_length = _average_path_length(np.arange(5)) assert_array_equal(avg_path_length, np.sort(avg_path_length)) def test_score_samples(): X_train = [[1, 1], [1, 2], [2, 1]] clf1 = IsolationForest(contamination=0.1).fit(X_train) clf2 = IsolationForest().fit(X_train) assert_array_equal(clf1.score_samples([[2., 2.]]), clf1.decision_function([[2., 2.]]) + clf1.offset_) assert_array_equal(clf2.score_samples([[2., 2.]]), clf2.decision_function([[2., 2.]]) + clf2.offset_) assert_array_equal(clf1.score_samples([[2., 2.]]), clf2.score_samples([[2., 2.]])) def test_iforest_warm_start(): """Test iterative addition of iTrees to an iForest """ rng = check_random_state(0) X = rng.randn(20, 2) # fit first 10 trees clf = IsolationForest(n_estimators=10, max_samples=20, random_state=rng, warm_start=True) clf.fit(X) # remember the 1st tree tree_1 = clf.estimators_[0] # fit another 10 trees clf.set_params(n_estimators=20) clf.fit(X) # expecting 20 fitted trees and no overwritten trees assert len(clf.estimators_) == 20 assert clf.estimators_[0] is tree_1 # mock get_chunk_n_rows to actually test more than one chunk (here one # chunk = 3 rows: @patch( "sklearn.ensemble._iforest.get_chunk_n_rows", side_effect=Mock(**{"return_value": 3}), ) @pytest.mark.parametrize( "contamination, n_predict_calls", [(0.25, 3), ("auto", 2)] ) def test_iforest_chunks_works1( mocked_get_chunk, contamination, n_predict_calls ): test_iforest_works(contamination) assert mocked_get_chunk.call_count == n_predict_calls # idem with chunk_size = 5 rows @patch( "sklearn.ensemble._iforest.get_chunk_n_rows", side_effect=Mock(**{"return_value": 10}), ) @pytest.mark.parametrize( "contamination, n_predict_calls", [(0.25, 3), ("auto", 2)] ) def test_iforest_chunks_works2( mocked_get_chunk, contamination, n_predict_calls ): test_iforest_works(contamination) assert mocked_get_chunk.call_count == n_predict_calls def test_iforest_with_uniform_data(): """Test whether iforest predicts inliers when using uniform data""" # 2-d array of all 1s X = np.ones((100, 10)) iforest = IsolationForest() iforest.fit(X) rng = np.random.RandomState(0) assert all(iforest.predict(X) == 1) assert all(iforest.predict(rng.randn(100, 10)) == 1) assert all(iforest.predict(X + 1) == 1) assert all(iforest.predict(X - 1) == 1) # 2-d array where columns contain the same value across rows X = np.repeat(rng.randn(1, 10), 100, 0) iforest = IsolationForest() iforest.fit(X) assert all(iforest.predict(X) == 1) assert all(iforest.predict(rng.randn(100, 10)) == 1) assert all(iforest.predict(np.ones((100, 10))) == 1) # Single row X = rng.randn(1, 10) iforest = IsolationForest() iforest.fit(X) assert all(iforest.predict(X) == 1) assert all(iforest.predict(rng.randn(100, 10)) == 1) assert all(iforest.predict(np.ones((100, 10))) == 1)