# We can not use pytest here, because we run # build_tools/azure/test_pytest_soft_dependency.sh on these # tests to make sure estimator_checks works without pytest. import importlib import re import sys import unittest import warnings from inspect import isgenerator from numbers import Integral, Real import joblib import numpy as np import scipy.sparse as sp from sklearn import config_context, get_config from sklearn.base import BaseEstimator, ClassifierMixin, OutlierMixin, TransformerMixin from sklearn.cluster import MiniBatchKMeans from sklearn.datasets import ( load_iris, make_multilabel_classification, ) from sklearn.decomposition import PCA from sklearn.exceptions import ( ConvergenceWarning, EstimatorCheckFailedWarning, SkipTestWarning, ) from sklearn.linear_model import ( LinearRegression, LogisticRegression, MultiTaskElasticNet, SGDClassifier, ) from sklearn.mixture import GaussianMixture from sklearn.neighbors import KNeighborsRegressor from sklearn.preprocessing import StandardScaler from sklearn.svm import SVC, NuSVC from sklearn.utils import _array_api, all_estimators, deprecated from sklearn.utils._param_validation import Interval, StrOptions from sklearn.utils._test_common.instance_generator import ( _construct_instances, _get_expected_failed_checks, ) from sklearn.utils._testing import ( MinimalClassifier, MinimalRegressor, MinimalTransformer, SkipTest, ignore_warnings, raises, ) from sklearn.utils.estimator_checks import ( _check_name, _NotAnArray, _yield_all_checks, check_array_api_input, check_class_weight_balanced_linear_classifier, check_classifier_data_not_an_array, check_classifier_not_supporting_multiclass, check_classifiers_multilabel_output_format_decision_function, check_classifiers_multilabel_output_format_predict, check_classifiers_multilabel_output_format_predict_proba, check_classifiers_one_label_sample_weights, check_dataframe_column_names_consistency, check_decision_proba_consistency, check_dict_unchanged, check_dont_overwrite_parameters, check_estimator, check_estimator_cloneable, check_estimator_repr, check_estimator_sparse_array, check_estimator_sparse_matrix, check_estimator_sparse_tag, check_estimator_tags_renamed, check_estimators_nan_inf, check_estimators_overwrite_params, check_estimators_unfitted, check_fit_check_is_fitted, check_fit_score_takes_y, check_methods_sample_order_invariance, check_methods_subset_invariance, check_mixin_order, check_no_attributes_set_in_init, check_outlier_contamination, check_outlier_corruption, check_parameters_default_constructible, check_positive_only_tag_during_fit, check_regressor_data_not_an_array, check_requires_y_none, check_sample_weights_pandas_series, check_set_params, estimator_checks_generator, set_random_state, ) from sklearn.utils.fixes import CSR_CONTAINERS, SPARRAY_PRESENT from sklearn.utils.metaestimators import available_if from sklearn.utils.multiclass import type_of_target from sklearn.utils.validation import ( check_array, check_is_fitted, check_X_y, validate_data, ) class CorrectNotFittedError(ValueError): """Exception class to raise if estimator is used before fitting. Like NotFittedError, it inherits from ValueError, but not from AttributeError. Used for testing only. """ class BaseBadClassifier(ClassifierMixin, BaseEstimator): def fit(self, X, y): return self def predict(self, X): return np.ones(X.shape[0]) class ChangesDict(BaseEstimator): def __init__(self, key=0): self.key = key def fit(self, X, y=None): X, y = validate_data(self, X, y) return self def predict(self, X): X = check_array(X) self.key = 1000 return np.ones(X.shape[0]) class SetsWrongAttribute(BaseEstimator): def __init__(self, acceptable_key=0): self.acceptable_key = acceptable_key def fit(self, X, y=None): self.wrong_attribute = 0 X, y = validate_data(self, X, y) return self class ChangesWrongAttribute(BaseEstimator): def __init__(self, wrong_attribute=0): self.wrong_attribute = wrong_attribute def fit(self, X, y=None): self.wrong_attribute = 1 X, y = validate_data(self, X, y) return self class ChangesUnderscoreAttribute(BaseEstimator): def fit(self, X, y=None): self._good_attribute = 1 X, y = validate_data(self, X, y) return self class RaisesErrorInSetParams(BaseEstimator): def __init__(self, p=0): self.p = p def set_params(self, **kwargs): if "p" in kwargs: p = kwargs.pop("p") if p < 0: raise ValueError("p can't be less than 0") self.p = p return super().set_params(**kwargs) def fit(self, X, y=None): X, y = validate_data(self, X, y) return self class HasMutableParameters(BaseEstimator): def __init__(self, p=object()): self.p = p def fit(self, X, y=None): X, y = validate_data(self, X, y) return self class HasImmutableParameters(BaseEstimator): # Note that object is an uninitialized class, thus immutable. def __init__(self, p=42, q=np.int32(42), r=object): self.p = p self.q = q self.r = r def fit(self, X, y=None): X, y = validate_data(self, X, y) return self class ModifiesValueInsteadOfRaisingError(BaseEstimator): def __init__(self, p=0): self.p = p def set_params(self, **kwargs): if "p" in kwargs: p = kwargs.pop("p") if p < 0: p = 0 self.p = p return super().set_params(**kwargs) def fit(self, X, y=None): X, y = validate_data(self, X, y) return self class ModifiesAnotherValue(BaseEstimator): def __init__(self, a=0, b="method1"): self.a = a self.b = b def set_params(self, **kwargs): if "a" in kwargs: a = kwargs.pop("a") self.a = a if a is None: kwargs.pop("b") self.b = "method2" return super().set_params(**kwargs) def fit(self, X, y=None): X, y = validate_data(self, X, y) return self class NoCheckinPredict(BaseBadClassifier): def fit(self, X, y): X, y = validate_data(self, X, y) return self class NoSparseClassifier(BaseBadClassifier): def __init__(self, raise_for_type=None): # raise_for_type : str, expects "sparse_array" or "sparse_matrix" self.raise_for_type = raise_for_type def fit(self, X, y): X, y = validate_data(self, X, y, accept_sparse=["csr", "csc"]) if self.raise_for_type == "sparse_array": correct_type = isinstance(X, sp.sparray) elif self.raise_for_type == "sparse_matrix": correct_type = isinstance(X, sp.spmatrix) if correct_type: raise ValueError("Nonsensical Error") return self def predict(self, X): X = check_array(X) return np.ones(X.shape[0]) class CorrectNotFittedErrorClassifier(BaseBadClassifier): def fit(self, X, y): X, y = validate_data(self, X, y) self.coef_ = np.ones(X.shape[1]) return self def predict(self, X): check_is_fitted(self) X = check_array(X) return np.ones(X.shape[0]) class NoSampleWeightPandasSeriesType(BaseEstimator): def fit(self, X, y, sample_weight=None): # Convert data X, y = validate_data( self, X, y, accept_sparse=("csr", "csc"), multi_output=True, y_numeric=True ) # Function is only called after we verify that pandas is installed from pandas import Series if isinstance(sample_weight, Series): raise ValueError( "Estimator does not accept 'sample_weight'of type pandas.Series" ) return self def predict(self, X): X = check_array(X) return np.ones(X.shape[0]) class BadBalancedWeightsClassifier(BaseBadClassifier): def __init__(self, class_weight=None): self.class_weight = class_weight def fit(self, X, y): from sklearn.preprocessing import LabelEncoder from sklearn.utils import compute_class_weight label_encoder = LabelEncoder().fit(y) classes = label_encoder.classes_ class_weight = compute_class_weight(self.class_weight, classes=classes, y=y) # Intentionally modify the balanced class_weight # to simulate a bug and raise an exception if self.class_weight == "balanced": class_weight += 1.0 # Simply assigning coef_ to the class_weight self.coef_ = class_weight return self class BadTransformerWithoutMixin(BaseEstimator): def fit(self, X, y=None): X = validate_data(self, X) return self def transform(self, X): check_is_fitted(self) X = validate_data(self, X, reset=False) return X class NotInvariantPredict(BaseEstimator): def fit(self, X, y): # Convert data X, y = validate_data( self, X, y, accept_sparse=("csr", "csc"), multi_output=True, y_numeric=True ) return self def predict(self, X): # return 1 if X has more than one element else return 0 X = check_array(X) if X.shape[0] > 1: return np.ones(X.shape[0]) return np.zeros(X.shape[0]) class NotInvariantSampleOrder(BaseEstimator): def fit(self, X, y): X, y = validate_data( self, X, y, accept_sparse=("csr", "csc"), multi_output=True, y_numeric=True ) # store the original X to check for sample order later self._X = X return self def predict(self, X): X = check_array(X) # if the input contains the same elements but different sample order, # then just return zeros. if ( np.array_equiv(np.sort(X, axis=0), np.sort(self._X, axis=0)) and (X != self._X).any() ): return np.zeros(X.shape[0]) return X[:, 0] class OneClassSampleErrorClassifier(BaseBadClassifier): """Classifier allowing to trigger different behaviors when `sample_weight` reduces the number of classes to 1.""" def __init__(self, raise_when_single_class=False): self.raise_when_single_class = raise_when_single_class def fit(self, X, y, sample_weight=None): X, y = check_X_y( X, y, accept_sparse=("csr", "csc"), multi_output=True, y_numeric=True ) self.has_single_class_ = False self.classes_, y = np.unique(y, return_inverse=True) n_classes_ = self.classes_.shape[0] if n_classes_ < 2 and self.raise_when_single_class: self.has_single_class_ = True raise ValueError("normal class error") # find the number of class after trimming if sample_weight is not None: if isinstance(sample_weight, np.ndarray) and len(sample_weight) > 0: n_classes_ = np.count_nonzero(np.bincount(y, sample_weight)) if n_classes_ < 2: self.has_single_class_ = True raise ValueError("Nonsensical Error") return self def predict(self, X): check_is_fitted(self) X = check_array(X) if self.has_single_class_: return np.zeros(X.shape[0]) return np.ones(X.shape[0]) class LargeSparseNotSupportedClassifier(BaseEstimator): """Estimator that claims to support large sparse data (accept_large_sparse=True), but doesn't""" def __init__(self, raise_for_type=None): # raise_for_type : str, expects "sparse_array" or "sparse_matrix" self.raise_for_type = raise_for_type def fit(self, X, y): X, y = validate_data( self, X, y, accept_sparse=("csr", "csc", "coo"), accept_large_sparse=True, multi_output=True, y_numeric=True, ) if self.raise_for_type == "sparse_array": correct_type = isinstance(X, sp.sparray) elif self.raise_for_type == "sparse_matrix": correct_type = isinstance(X, sp.spmatrix) if correct_type: if X.format == "coo": if X.row.dtype == "int64" or X.col.dtype == "int64": raise ValueError("Estimator doesn't support 64-bit indices") elif X.format in ["csc", "csr"]: assert "int64" not in ( X.indices.dtype, X.indptr.dtype, ), "Estimator doesn't support 64-bit indices" return self class SparseTransformer(TransformerMixin, BaseEstimator): def __init__(self, sparse_container=None): self.sparse_container = sparse_container def fit(self, X, y=None): validate_data(self, X) return self def fit_transform(self, X, y=None): return self.fit(X, y).transform(X) def transform(self, X): check_is_fitted(self) X = validate_data(self, X, accept_sparse=True, reset=False) return self.sparse_container(X) class EstimatorInconsistentForPandas(BaseEstimator): def fit(self, X, y): try: from pandas import DataFrame if isinstance(X, DataFrame): self.value_ = X.iloc[0, 0] else: X = check_array(X) self.value_ = X[1, 0] return self except ImportError: X = check_array(X) self.value_ = X[1, 0] return self def predict(self, X): X = check_array(X) return np.array([self.value_] * X.shape[0]) class UntaggedBinaryClassifier(SGDClassifier): # Toy classifier that only supports binary classification, will fail tests. def fit(self, X, y, coef_init=None, intercept_init=None, sample_weight=None): super().fit(X, y, coef_init, intercept_init, sample_weight) if len(self.classes_) > 2: raise ValueError("Only 2 classes are supported") return self def partial_fit(self, X, y, classes=None, sample_weight=None): super().partial_fit(X=X, y=y, classes=classes, sample_weight=sample_weight) if len(self.classes_) > 2: raise ValueError("Only 2 classes are supported") return self class TaggedBinaryClassifier(UntaggedBinaryClassifier): def fit(self, X, y): y_type = type_of_target(y, input_name="y", raise_unknown=True) if y_type != "binary": raise ValueError( "Only binary classification is supported. The type of the target " f"is {y_type}." ) return super().fit(X, y) # Toy classifier that only supports binary classification. def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.classifier_tags.multi_class = False return tags class RequiresPositiveXRegressor(LinearRegression): def fit(self, X, y): # reject sparse X to be able to call (X < 0).any() X, y = validate_data(self, X, y, accept_sparse=False, multi_output=True) if (X < 0).any(): raise ValueError("Negative values in data passed to X.") return super().fit(X, y) def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.input_tags.positive_only = True # reject sparse X to be able to call (X < 0).any() tags.input_tags.sparse = False return tags class RequiresPositiveYRegressor(LinearRegression): def fit(self, X, y): X, y = validate_data(self, X, y, accept_sparse=True, multi_output=True) if (y <= 0).any(): raise ValueError("negative y values not supported!") return super().fit(X, y) def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.target_tags.positive_only = True return tags class PoorScoreLogisticRegression(LogisticRegression): def decision_function(self, X): return super().decision_function(X) + 1 def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.classifier_tags.poor_score = True return tags class PartialFitChecksName(BaseEstimator): def fit(self, X, y): validate_data(self, X, y) return self def partial_fit(self, X, y): reset = not hasattr(self, "_fitted") validate_data(self, X, y, reset=reset) self._fitted = True return self class BrokenArrayAPI(BaseEstimator): """Make different predictions when using Numpy and the Array API""" def fit(self, X, y): return self def predict(self, X): enabled = get_config()["array_api_dispatch"] xp, _ = _array_api.get_namespace(X) if enabled: return xp.asarray([1, 2, 3]) else: return np.array([3, 2, 1]) def test_check_array_api_input(): try: importlib.import_module("array_api_strict") except ModuleNotFoundError: # pragma: nocover raise SkipTest("array-api-strict is required to run this test") with raises(AssertionError, match="Not equal to tolerance"): check_array_api_input( "BrokenArrayAPI", BrokenArrayAPI(), array_namespace="array_api_strict", check_values=True, ) def test_not_an_array_array_function(): not_array = _NotAnArray(np.ones(10)) msg = "Don't want to call array_function sum!" with raises(TypeError, match=msg): np.sum(not_array) # always returns True assert np.may_share_memory(not_array, None) def test_check_fit_score_takes_y_works_on_deprecated_fit(): # Tests that check_fit_score_takes_y works on a class with # a deprecated fit method class TestEstimatorWithDeprecatedFitMethod(BaseEstimator): @deprecated("Deprecated for the purpose of testing check_fit_score_takes_y") def fit(self, X, y): return self check_fit_score_takes_y("test", TestEstimatorWithDeprecatedFitMethod()) def test_check_estimator_with_class_removed(): """Test that passing a class instead of an instance fails.""" msg = "Passing a class was deprecated" with raises(TypeError, match=msg): check_estimator(LogisticRegression) def test_mutable_default_params(): """Test that constructor cannot have mutable default parameters.""" msg = ( "Parameter 'p' of estimator 'HasMutableParameters' is of type " "object which is not allowed" ) # check that the "default_constructible" test checks for mutable parameters check_parameters_default_constructible( "Immutable", HasImmutableParameters() ) # should pass with raises(AssertionError, match=msg): check_parameters_default_constructible("Mutable", HasMutableParameters()) def test_check_set_params(): """Check set_params doesn't fail and sets the right values.""" # check that values returned by get_params match set_params msg = "get_params result does not match what was passed to set_params" with raises(AssertionError, match=msg): check_set_params("test", ModifiesValueInsteadOfRaisingError()) with warnings.catch_warnings(record=True) as records: check_set_params("test", RaisesErrorInSetParams()) assert UserWarning in [rec.category for rec in records] with raises(AssertionError, match=msg): check_set_params("test", ModifiesAnotherValue()) def test_check_estimators_nan_inf(): # check that predict does input validation (doesn't accept dicts in input) msg = "Estimator NoCheckinPredict doesn't check for NaN and inf in predict" with raises(AssertionError, match=msg): check_estimators_nan_inf("NoCheckinPredict", NoCheckinPredict()) def test_check_dict_unchanged(): # check that estimator state does not change # at transform/predict/predict_proba time msg = "Estimator changes __dict__ during predict" with raises(AssertionError, match=msg): check_dict_unchanged("test", ChangesDict()) def test_check_sample_weights_pandas_series(): # check that sample_weights in fit accepts pandas.Series type try: from pandas import Series # noqa: F401 msg = ( "Estimator NoSampleWeightPandasSeriesType raises error if " "'sample_weight' parameter is of type pandas.Series" ) with raises(ValueError, match=msg): check_sample_weights_pandas_series( "NoSampleWeightPandasSeriesType", NoSampleWeightPandasSeriesType() ) except ImportError: pass def test_check_estimators_overwrite_params(): # check that `fit` only changes attributes that # are private (start with an _ or end with a _). msg = ( "Estimator ChangesWrongAttribute should not change or mutate " "the parameter wrong_attribute from 0 to 1 during fit." ) with raises(AssertionError, match=msg): check_estimators_overwrite_params( "ChangesWrongAttribute", ChangesWrongAttribute() ) check_estimators_overwrite_params("test", ChangesUnderscoreAttribute()) def test_check_dont_overwrite_parameters(): # check that `fit` doesn't add any public attribute msg = ( r"Estimator adds public attribute\(s\) during the fit method." " Estimators are only allowed to add private attributes" " either started with _ or ended" " with _ but wrong_attribute added" ) with raises(AssertionError, match=msg): check_dont_overwrite_parameters("test", SetsWrongAttribute()) def test_check_methods_sample_order_invariance(): # check for sample order invariance name = NotInvariantSampleOrder.__name__ method = "predict" msg = ( "{method} of {name} is not invariant when applied to a dataset" "with different sample order." ).format(method=method, name=name) with raises(AssertionError, match=msg): check_methods_sample_order_invariance( "NotInvariantSampleOrder", NotInvariantSampleOrder() ) def test_check_methods_subset_invariance(): # check for invariant method name = NotInvariantPredict.__name__ method = "predict" msg = ("{method} of {name} is not invariant when applied to a subset.").format( method=method, name=name ) with raises(AssertionError, match=msg): check_methods_subset_invariance("NotInvariantPredict", NotInvariantPredict()) def test_check_estimator_sparse_data(): # check for sparse data input handling name = NoSparseClassifier.__name__ msg = "Estimator %s doesn't seem to fail gracefully on sparse data" % name with raises(AssertionError, match=msg): check_estimator_sparse_matrix(name, NoSparseClassifier("sparse_matrix")) if SPARRAY_PRESENT: with raises(AssertionError, match=msg): check_estimator_sparse_array(name, NoSparseClassifier("sparse_array")) # Large indices test on bad estimator msg = ( "Estimator LargeSparseNotSupportedClassifier doesn't seem to " r"support \S{3}_64 matrix, and is not failing gracefully.*" ) with raises(AssertionError, match=msg): check_estimator_sparse_matrix( "LargeSparseNotSupportedClassifier", LargeSparseNotSupportedClassifier("sparse_matrix"), ) if SPARRAY_PRESENT: with raises(AssertionError, match=msg): check_estimator_sparse_array( "LargeSparseNotSupportedClassifier", LargeSparseNotSupportedClassifier("sparse_array"), ) def test_check_classifiers_one_label_sample_weights(): # check for classifiers reducing to less than two classes via sample weights name = OneClassSampleErrorClassifier.__name__ msg = ( f"{name} failed when fitted on one label after sample_weight " "trimming. Error message is not explicit, it should have " "'class'." ) with raises(AssertionError, match=msg): check_classifiers_one_label_sample_weights( "OneClassSampleErrorClassifier", OneClassSampleErrorClassifier() ) def test_check_estimator_not_fail_fast(): """Check the contents of the results returned with on_fail!="raise". This results should contain details about the observed failures, expected or not. """ check_results = check_estimator(BaseEstimator(), on_fail=None) assert isinstance(check_results, list) assert len(check_results) > 0 assert all( isinstance(item, dict) and set(item.keys()) == { "estimator", "check_name", "exception", "status", "expected_to_fail", "expected_to_fail_reason", } for item in check_results ) # Some tests are expected to fail, some are expected to pass. assert any(item["status"] == "failed" for item in check_results) assert any(item["status"] == "passed" for item in check_results) def test_check_estimator(): # tests that the estimator actually fails on "bad" estimators. # not a complete test of all checks, which are very extensive. # check that we have a fit method msg = "object has no attribute 'fit'" with raises(AttributeError, match=msg): check_estimator(BaseEstimator()) # does error on binary_only untagged estimator msg = "Only 2 classes are supported" with raises(ValueError, match=msg): check_estimator(UntaggedBinaryClassifier()) for csr_container in CSR_CONTAINERS: # non-regression test for estimators transforming to sparse data check_estimator(SparseTransformer(sparse_container=csr_container)) # doesn't error on actual estimator check_estimator(LogisticRegression()) check_estimator(LogisticRegression(C=0.01)) check_estimator(MultiTaskElasticNet()) # doesn't error on binary_only tagged estimator check_estimator(TaggedBinaryClassifier()) check_estimator(RequiresPositiveXRegressor()) # Check regressor with requires_positive_y estimator tag msg = "negative y values not supported!" with raises(ValueError, match=msg): check_estimator(RequiresPositiveYRegressor()) # Does not raise error on classifier with poor_score tag check_estimator(PoorScoreLogisticRegression()) def test_check_outlier_corruption(): # should raise AssertionError decision = np.array([0.0, 1.0, 1.5, 2.0]) with raises(AssertionError): check_outlier_corruption(1, 2, decision) # should pass decision = np.array([0.0, 1.0, 1.0, 2.0]) check_outlier_corruption(1, 2, decision) def test_check_estimator_sparse_tag(): """Test that check_estimator_sparse_tag raises error when sparse tag is misaligned.""" class EstimatorWithSparseConfig(BaseEstimator): def __init__(self, tag_sparse, accept_sparse, fit_error=None): self.tag_sparse = tag_sparse self.accept_sparse = accept_sparse self.fit_error = fit_error def fit(self, X, y=None): if self.fit_error: raise self.fit_error validate_data(self, X, y, accept_sparse=self.accept_sparse) return self def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.input_tags.sparse = self.tag_sparse return tags test_cases = [ {"tag_sparse": True, "accept_sparse": True, "error_type": None}, {"tag_sparse": False, "accept_sparse": False, "error_type": None}, {"tag_sparse": False, "accept_sparse": True, "error_type": AssertionError}, {"tag_sparse": True, "accept_sparse": False, "error_type": AssertionError}, ] for test_case in test_cases: estimator = EstimatorWithSparseConfig( test_case["tag_sparse"], test_case["accept_sparse"], ) if test_case["error_type"] is None: check_estimator_sparse_tag(estimator.__class__.__name__, estimator) else: with raises(test_case["error_type"]): check_estimator_sparse_tag(estimator.__class__.__name__, estimator) # estimator `tag_sparse=accept_sparse=False` fails on sparse data # but does not raise the appropriate error for fit_error in [TypeError("unexpected error"), KeyError("other error")]: estimator = EstimatorWithSparseConfig(False, False, fit_error) with raises(AssertionError): check_estimator_sparse_tag(estimator.__class__.__name__, estimator) def test_check_estimator_transformer_no_mixin(): # check that TransformerMixin is not required for transformer tests to run # but it fails since the tag is not set with raises(RuntimeError, "the `transformer_tags` tag is not set"): check_estimator(BadTransformerWithoutMixin()) def test_check_estimator_clones(): # check that check_estimator doesn't modify the estimator it receives iris = load_iris() for Estimator in [ GaussianMixture, LinearRegression, SGDClassifier, PCA, MiniBatchKMeans, ]: # without fitting with ignore_warnings(category=ConvergenceWarning): est = Estimator() set_random_state(est) old_hash = joblib.hash(est) check_estimator( est, expected_failed_checks=_get_expected_failed_checks(est) ) assert old_hash == joblib.hash(est) # with fitting with ignore_warnings(category=ConvergenceWarning): est = Estimator() set_random_state(est) est.fit(iris.data, iris.target) old_hash = joblib.hash(est) check_estimator( est, expected_failed_checks=_get_expected_failed_checks(est) ) assert old_hash == joblib.hash(est) def test_check_estimators_unfitted(): # check that a ValueError/AttributeError is raised when calling predict # on an unfitted estimator msg = "Estimator should raise a NotFittedError when calling" with raises(AssertionError, match=msg): check_estimators_unfitted("estimator", NoSparseClassifier()) # check that CorrectNotFittedError inherit from either ValueError # or AttributeError check_estimators_unfitted("estimator", CorrectNotFittedErrorClassifier()) def test_check_no_attributes_set_in_init(): class NonConformantEstimatorPrivateSet(BaseEstimator): def __init__(self): self.you_should_not_set_this_ = None class NonConformantEstimatorNoParamSet(BaseEstimator): def __init__(self, you_should_set_this_=None): pass class ConformantEstimatorClassAttribute(BaseEstimator): # making sure our __metadata_request__* class attributes are okay! __metadata_request__fit = {"foo": True} msg = ( "Estimator estimator_name should not set any" " attribute apart from parameters during init." r" Found attributes \['you_should_not_set_this_'\]." ) with raises(AssertionError, match=msg): check_no_attributes_set_in_init( "estimator_name", NonConformantEstimatorPrivateSet() ) msg = ( "Estimator estimator_name should store all parameters as an attribute" " during init" ) with raises(AttributeError, match=msg): check_no_attributes_set_in_init( "estimator_name", NonConformantEstimatorNoParamSet() ) # a private class attribute is okay! check_no_attributes_set_in_init( "estimator_name", ConformantEstimatorClassAttribute() ) # also check if cloning an estimator which has non-default set requests is # fine. Setting a non-default value via `set_{method}_request` sets the # private _metadata_request instance attribute which is copied in `clone`. with config_context(enable_metadata_routing=True): check_no_attributes_set_in_init( "estimator_name", ConformantEstimatorClassAttribute().set_fit_request(foo=True), ) def test_check_estimator_pairwise(): # check that check_estimator() works on estimator with _pairwise # kernel or metric # test precomputed kernel est = SVC(kernel="precomputed") check_estimator(est) # test precomputed metric est = KNeighborsRegressor(metric="precomputed") check_estimator(est, expected_failed_checks=_get_expected_failed_checks(est)) def test_check_classifier_data_not_an_array(): with raises(AssertionError, match="Not equal to tolerance"): check_classifier_data_not_an_array( "estimator_name", EstimatorInconsistentForPandas() ) def test_check_regressor_data_not_an_array(): with raises(AssertionError, match="Not equal to tolerance"): check_regressor_data_not_an_array( "estimator_name", EstimatorInconsistentForPandas() ) def test_check_dataframe_column_names_consistency(): err_msg = "Estimator does not have a feature_names_in_" with raises(ValueError, match=err_msg): check_dataframe_column_names_consistency("estimator_name", BaseBadClassifier()) check_dataframe_column_names_consistency("estimator_name", PartialFitChecksName()) lr = LogisticRegression() check_dataframe_column_names_consistency(lr.__class__.__name__, lr) lr.__doc__ = "Docstring that does not document the estimator's attributes" err_msg = ( "Estimator LogisticRegression does not document its feature_names_in_ attribute" ) with raises(ValueError, match=err_msg): check_dataframe_column_names_consistency(lr.__class__.__name__, lr) class _BaseMultiLabelClassifierMock(ClassifierMixin, BaseEstimator): def __init__(self, response_output): self.response_output = response_output def fit(self, X, y): return self def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.classifier_tags.multi_label = True return tags def test_check_classifiers_multilabel_output_format_predict(): n_samples, test_size, n_outputs = 100, 25, 5 _, y = make_multilabel_classification( n_samples=n_samples, n_features=2, n_classes=n_outputs, n_labels=3, length=50, allow_unlabeled=True, random_state=0, ) y_test = y[-test_size:] class MultiLabelClassifierPredict(_BaseMultiLabelClassifierMock): def predict(self, X): return self.response_output # 1. inconsistent array type clf = MultiLabelClassifierPredict(response_output=y_test.tolist()) err_msg = ( r"MultiLabelClassifierPredict.predict is expected to output a " r"NumPy array. Got instead." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict(clf.__class__.__name__, clf) # 2. inconsistent shape clf = MultiLabelClassifierPredict(response_output=y_test[:, :-1]) err_msg = ( r"MultiLabelClassifierPredict.predict outputs a NumPy array of " r"shape \(25, 4\) instead of \(25, 5\)." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict(clf.__class__.__name__, clf) # 3. inconsistent dtype clf = MultiLabelClassifierPredict(response_output=y_test.astype(np.float64)) err_msg = ( r"MultiLabelClassifierPredict.predict does not output the same " r"dtype than the targets." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict(clf.__class__.__name__, clf) def test_check_classifiers_multilabel_output_format_predict_proba(): n_samples, test_size, n_outputs = 100, 25, 5 _, y = make_multilabel_classification( n_samples=n_samples, n_features=2, n_classes=n_outputs, n_labels=3, length=50, allow_unlabeled=True, random_state=0, ) y_test = y[-test_size:] class MultiLabelClassifierPredictProba(_BaseMultiLabelClassifierMock): def predict_proba(self, X): return self.response_output for csr_container in CSR_CONTAINERS: # 1. unknown output type clf = MultiLabelClassifierPredictProba(response_output=csr_container(y_test)) err_msg = ( f"Unknown returned type .*{csr_container.__name__}.* by " r"MultiLabelClassifierPredictProba.predict_proba. A list or a Numpy " r"array is expected." ) with raises(ValueError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 2. for list output # 2.1. inconsistent length clf = MultiLabelClassifierPredictProba(response_output=y_test.tolist()) err_msg = ( "When MultiLabelClassifierPredictProba.predict_proba returns a list, " "the list should be of length n_outputs and contain NumPy arrays. Got " f"length of {test_size} instead of {n_outputs}." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 2.2. array of inconsistent shape response_output = [np.ones_like(y_test) for _ in range(n_outputs)] clf = MultiLabelClassifierPredictProba(response_output=response_output) err_msg = ( r"When MultiLabelClassifierPredictProba.predict_proba returns a list, " r"this list should contain NumPy arrays of shape \(n_samples, 2\). Got " r"NumPy arrays of shape \(25, 5\) instead of \(25, 2\)." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 2.3. array of inconsistent dtype response_output = [ np.ones(shape=(y_test.shape[0], 2), dtype=np.int64) for _ in range(n_outputs) ] clf = MultiLabelClassifierPredictProba(response_output=response_output) err_msg = ( "When MultiLabelClassifierPredictProba.predict_proba returns a list, " "it should contain NumPy arrays with floating dtype." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 2.4. array does not contain probability (each row should sum to 1) response_output = [ np.ones(shape=(y_test.shape[0], 2), dtype=np.float64) for _ in range(n_outputs) ] clf = MultiLabelClassifierPredictProba(response_output=response_output) err_msg = ( r"When MultiLabelClassifierPredictProba.predict_proba returns a list, " r"each NumPy array should contain probabilities for each class and " r"thus each row should sum to 1" ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 3 for array output # 3.1. array of inconsistent shape clf = MultiLabelClassifierPredictProba(response_output=y_test[:, :-1]) err_msg = ( r"When MultiLabelClassifierPredictProba.predict_proba returns a NumPy " r"array, the expected shape is \(n_samples, n_outputs\). Got \(25, 4\)" r" instead of \(25, 5\)." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 3.2. array of inconsistent dtype response_output = np.zeros_like(y_test, dtype=np.int64) clf = MultiLabelClassifierPredictProba(response_output=response_output) err_msg = ( r"When MultiLabelClassifierPredictProba.predict_proba returns a NumPy " r"array, the expected data type is floating." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) # 4. array does not contain probabilities clf = MultiLabelClassifierPredictProba(response_output=y_test * 2.0) err_msg = ( r"When MultiLabelClassifierPredictProba.predict_proba returns a NumPy " r"array, this array is expected to provide probabilities of the " r"positive class and should therefore contain values between 0 and 1." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_predict_proba( clf.__class__.__name__, clf, ) def test_check_classifiers_multilabel_output_format_decision_function(): n_samples, test_size, n_outputs = 100, 25, 5 _, y = make_multilabel_classification( n_samples=n_samples, n_features=2, n_classes=n_outputs, n_labels=3, length=50, allow_unlabeled=True, random_state=0, ) y_test = y[-test_size:] class MultiLabelClassifierDecisionFunction(_BaseMultiLabelClassifierMock): def decision_function(self, X): return self.response_output # 1. inconsistent array type clf = MultiLabelClassifierDecisionFunction(response_output=y_test.tolist()) err_msg = ( r"MultiLabelClassifierDecisionFunction.decision_function is expected " r"to output a NumPy array. Got instead." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_decision_function( clf.__class__.__name__, clf, ) # 2. inconsistent shape clf = MultiLabelClassifierDecisionFunction(response_output=y_test[:, :-1]) err_msg = ( r"MultiLabelClassifierDecisionFunction.decision_function is expected " r"to provide a NumPy array of shape \(n_samples, n_outputs\). Got " r"\(25, 4\) instead of \(25, 5\)" ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_decision_function( clf.__class__.__name__, clf, ) # 3. inconsistent dtype clf = MultiLabelClassifierDecisionFunction(response_output=y_test) err_msg = ( r"MultiLabelClassifierDecisionFunction.decision_function is expected " r"to output a floating dtype." ) with raises(AssertionError, match=err_msg): check_classifiers_multilabel_output_format_decision_function( clf.__class__.__name__, clf, ) def run_tests_without_pytest(): """Runs the tests in this file without using pytest.""" main_module = sys.modules["__main__"] test_functions = [ getattr(main_module, name) for name in dir(main_module) if name.startswith("test_") ] test_cases = [unittest.FunctionTestCase(fn) for fn in test_functions] suite = unittest.TestSuite() suite.addTests(test_cases) runner = unittest.TextTestRunner() runner.run(suite) def test_check_class_weight_balanced_linear_classifier(): # check that ill-computed balanced weights raises an exception msg = "Classifier estimator_name is not computing class_weight=balanced properly" with raises(AssertionError, match=msg): check_class_weight_balanced_linear_classifier( "estimator_name", BadBalancedWeightsClassifier() ) def test_all_estimators_all_public(): # all_estimator should not fail when pytest is not installed and return # only public estimators with warnings.catch_warnings(record=True) as record: estimators = all_estimators() # no warnings are raised assert not record for est in estimators: assert not est.__class__.__name__.startswith("_") if __name__ == "__main__": # This module is run as a script to check that we have no dependency on # pytest for estimator checks. run_tests_without_pytest() def test_estimator_checks_generator_skipping_tests(): # Make sure the checks generator skips tests that are expected to fail est = next(_construct_instances(NuSVC)) expected_to_fail = _get_expected_failed_checks(est) checks = estimator_checks_generator( est, legacy=True, expected_failed_checks=expected_to_fail, mark="skip" ) # making sure we use a class that has expected failures assert len(expected_to_fail) > 0 skipped_checks = [] for estimator, check in checks: try: check(estimator) except SkipTest: skipped_checks.append(_check_name(check)) # all checks expected to fail are skipped # some others might also be skipped, if their dependencies are not installed. assert set(expected_to_fail.keys()) <= set(skipped_checks) def test_xfail_count_with_no_fast_fail(): """Test that the right number of xfail warnings are raised when on_fail is "warn". It also checks the number of raised EstimatorCheckFailedWarning, and checks the output of check_estimator. """ est = NuSVC() expected_failed_checks = _get_expected_failed_checks(est) # This is to make sure we test a class that has some expected failures assert len(expected_failed_checks) > 0 with warnings.catch_warnings(record=True) as records: logs = check_estimator( est, expected_failed_checks=expected_failed_checks, on_fail="warn", ) xfail_warns = [w for w in records if w.category != SkipTestWarning] assert all([rec.category == EstimatorCheckFailedWarning for rec in xfail_warns]) assert len(xfail_warns) == len(expected_failed_checks) xfailed = [log for log in logs if log["status"] == "xfail"] assert len(xfailed) == len(expected_failed_checks) def test_check_estimator_callback(): """Test that the callback is called with the right arguments.""" call_count = {"xfail": 0, "skipped": 0, "passed": 0, "failed": 0} def callback( *, estimator, check_name, exception, status, expected_to_fail, expected_to_fail_reason, ): assert status in ("xfail", "skipped", "passed", "failed") nonlocal call_count call_count[status] += 1 est = NuSVC() expected_failed_checks = _get_expected_failed_checks(est) # This is to make sure we test a class that has some expected failures assert len(expected_failed_checks) > 0 with warnings.catch_warnings(record=True): check_estimator( est, expected_failed_checks=expected_failed_checks, on_fail=None, callback=callback, ) all_checks_count = len(list(estimator_checks_generator(est, legacy=True))) assert call_count["xfail"] == len(expected_failed_checks) assert call_count["passed"] > 0 assert call_count["failed"] == 0 assert call_count["skipped"] == ( all_checks_count - call_count["xfail"] - call_count["passed"] ) # FIXME: this test should be uncommented when the checks will be granular # enough. In 0.24, these tests fail due to low estimator performance. def test_minimal_class_implementation_checks(): # Check that third-party library can run tests without inheriting from # BaseEstimator. # FIXME raise SkipTest minimal_estimators = [MinimalTransformer(), MinimalRegressor(), MinimalClassifier()] for estimator in minimal_estimators: check_estimator(estimator) def test_check_fit_check_is_fitted(): class Estimator(BaseEstimator): def __init__(self, behavior="attribute"): self.behavior = behavior def fit(self, X, y, **kwargs): if self.behavior == "attribute": self.is_fitted_ = True elif self.behavior == "method": self._is_fitted = True return self @available_if(lambda self: self.behavior in {"method", "always-true"}) def __sklearn_is_fitted__(self): if self.behavior == "always-true": return True return hasattr(self, "_is_fitted") with raises(Exception, match="passes check_is_fitted before being fit"): check_fit_check_is_fitted("estimator", Estimator(behavior="always-true")) check_fit_check_is_fitted("estimator", Estimator(behavior="method")) check_fit_check_is_fitted("estimator", Estimator(behavior="attribute")) def test_check_requires_y_none(): class Estimator(BaseEstimator): def fit(self, X, y): X, y = check_X_y(X, y) with warnings.catch_warnings(record=True) as record: check_requires_y_none("estimator", Estimator()) # no warnings are raised assert not [r.message for r in record] def test_non_deterministic_estimator_skip_tests(): # check estimators with non_deterministic tag set to True # will skip certain tests, refer to issue #22313 for details for Estimator in [MinimalTransformer, MinimalRegressor, MinimalClassifier]: all_tests = list(_yield_all_checks(Estimator(), legacy=True)) assert check_methods_sample_order_invariance in all_tests assert check_methods_subset_invariance in all_tests class MyEstimator(Estimator): def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.non_deterministic = True return tags all_tests = list(_yield_all_checks(MyEstimator(), legacy=True)) assert check_methods_sample_order_invariance not in all_tests assert check_methods_subset_invariance not in all_tests def test_check_outlier_contamination(): """Check the test for the contamination parameter in the outlier detectors.""" # Without any parameter constraints, the estimator will early exit the test by # returning None. class OutlierDetectorWithoutConstraint(OutlierMixin, BaseEstimator): """Outlier detector without parameter validation.""" def __init__(self, contamination=0.1): self.contamination = contamination def fit(self, X, y=None, sample_weight=None): return self # pragma: no cover def predict(self, X, y=None): return np.ones(X.shape[0]) detector = OutlierDetectorWithoutConstraint() assert check_outlier_contamination(detector.__class__.__name__, detector) is None # Now, we check that with the parameter constraints, the test should only be valid # if an Interval constraint with bound in [0, 1] is provided. class OutlierDetectorWithConstraint(OutlierDetectorWithoutConstraint): _parameter_constraints = {"contamination": [StrOptions({"auto"})]} detector = OutlierDetectorWithConstraint() err_msg = "contamination constraints should contain a Real Interval constraint." with raises(AssertionError, match=err_msg): check_outlier_contamination(detector.__class__.__name__, detector) # Add a correct interval constraint and check that the test passes. OutlierDetectorWithConstraint._parameter_constraints["contamination"] = [ Interval(Real, 0, 0.5, closed="right") ] detector = OutlierDetectorWithConstraint() check_outlier_contamination(detector.__class__.__name__, detector) incorrect_intervals = [ Interval(Integral, 0, 1, closed="right"), # not an integral interval Interval(Real, -1, 1, closed="right"), # lower bound is negative Interval(Real, 0, 2, closed="right"), # upper bound is greater than 1 Interval(Real, 0, 0.5, closed="left"), # lower bound include 0 ] err_msg = r"contamination constraint should be an interval in \(0, 0.5\]" for interval in incorrect_intervals: OutlierDetectorWithConstraint._parameter_constraints["contamination"] = [ interval ] detector = OutlierDetectorWithConstraint() with raises(AssertionError, match=err_msg): check_outlier_contamination(detector.__class__.__name__, detector) def test_decision_proba_tie_ranking(): """Check that in case with some probabilities ties, we relax the ranking comparison with the decision function. Non-regression test for: https://github.com/scikit-learn/scikit-learn/issues/24025 """ estimator = SGDClassifier(loss="log_loss") check_decision_proba_consistency("SGDClassifier", estimator) def test_yield_all_checks_legacy(): # Test that _yield_all_checks with legacy=True returns more checks. estimator = MinimalClassifier() legacy_checks = list(_yield_all_checks(estimator, legacy=True)) non_legacy_checks = list(_yield_all_checks(estimator, legacy=False)) assert len(legacy_checks) > len(non_legacy_checks) def get_check_name(check): try: return check.__name__ except AttributeError: return check.func.__name__ # Check that all non-legacy checks are included in legacy checks non_legacy_check_names = {get_check_name(check) for check in non_legacy_checks} legacy_check_names = {get_check_name(check) for check in legacy_checks} assert non_legacy_check_names.issubset(legacy_check_names) def test_check_estimator_cloneable_error(): """Check that the right error is raised when the estimator is not cloneable.""" class NotCloneable(BaseEstimator): def __sklearn_clone__(self): raise NotImplementedError("This estimator is not cloneable.") estimator = NotCloneable() msg = "Cloning of .* failed with error" with raises(AssertionError, match=msg): check_estimator_cloneable("NotCloneable", estimator) def test_estimator_repr_error(): """Check that the right error is raised when the estimator does not have a repr.""" class NotRepr(BaseEstimator): def __repr__(self): raise NotImplementedError("This estimator does not have a repr.") estimator = NotRepr() msg = "Repr of .* failed with error" with raises(AssertionError, match=msg): check_estimator_repr("NotRepr", estimator) def test_check_estimator_tags_renamed(): class BadEstimator1: def _more_tags(self): return None # pragma: no cover class BadEstimator2: def _get_tags(self): return None # pragma: no cover class OkayEstimator: def __sklearn_tags__(self): return None # pragma: no cover def _more_tags(self): return None # pragma: no cover msg = "has defined either `_more_tags` or `_get_tags`" with raises(TypeError, match=msg): check_estimator_tags_renamed("BadEstimator1", BadEstimator1()) with raises(TypeError, match=msg): check_estimator_tags_renamed("BadEstimator2", BadEstimator2()) # This shouldn't fail since we allow both __sklearn_tags__ and _more_tags # to exist so that third party estimators can easily support multiple sklearn # versions. check_estimator_tags_renamed("OkayEstimator", OkayEstimator()) def test_check_classifier_not_supporting_multiclass(): """Check that when the estimator has the wrong tags.classifier_tags.multi_class set, the test fails.""" class BadEstimator(BaseEstimator): # we don't actually need to define the tag here since we're running the test # manually, and BaseEstimator defaults to multi_output=False. def fit(self, X, y): return self msg = "The estimator tag `tags.classifier_tags.multi_class` is False" with raises(AssertionError, match=msg): check_classifier_not_supporting_multiclass("BadEstimator", BadEstimator()) # Test that set_output doesn't make the tests to fail. def test_estimator_with_set_output(): # Doing this since pytest is not available for this file. for lib in ["pandas", "polars"]: try: importlib.__import__(lib) except ImportError: raise SkipTest(f"Library {lib} is not installed") estimator = StandardScaler().set_output(transform=lib) check_estimator(estimator) def test_estimator_checks_generator(): """Check that checks_generator returns a generator.""" all_instance_gen_checks = estimator_checks_generator(LogisticRegression()) assert isgenerator(all_instance_gen_checks) def test_check_estimator_callback_with_fast_fail_error(): """Check that check_estimator fails correctly with on_fail='raise' and callback.""" with raises( ValueError, match="callback cannot be provided together with on_fail='raise'" ): check_estimator(LogisticRegression(), on_fail="raise", callback=lambda: None) def test_check_mixin_order(): """Test that the check raises an error when the mixin order is incorrect.""" class BadEstimator(BaseEstimator, TransformerMixin): def fit(self, X, y=None): return self msg = "TransformerMixin comes before/left side of BaseEstimator" with raises(AssertionError, match=re.escape(msg)): check_mixin_order("BadEstimator", BadEstimator()) def test_check_positive_only_tag_during_fit(): class RequiresPositiveXBadTag(RequiresPositiveXRegressor): def __sklearn_tags__(self): tags = super().__sklearn_tags__() tags.input_tags.positive_only = False return tags with raises( AssertionError, match="This happens when passing negative input values as X." ): check_positive_only_tag_during_fit( "RequiresPositiveXBadTag", RequiresPositiveXBadTag() )