def test_oneclass_adaboost_proba():
# Test predict_proba robustness for one class label input.
# In response to issue #7501
# https://github.com/scikit-learn/scikit-learn/issues/7501
y_t = np.ones(len(X))
clf = AdaBoostClassifier().fit(X, y_t)
assert_array_almost_equal(clf.predict_proba(X), np.ones((len(X), 1)))
def test_adaboostclassifier_without_sample_weight(algorithm):
X, y = iris.data, iris.target
base_estimator = NoSampleWeightWrapper(DummyClassifier())
clf = AdaBoostClassifier(base_estimator=base_estimator,
algorithm=algorithm)
err_msg = ("{} doesn't support sample_weight".format(
base_estimator.__class__.__name__))
with pytest.raises(ValueError, match=err_msg):
clf.fit(X, y)
def test_pickle():
# Check pickability.
import pickle
# Adaboost classifier
for alg in ['SAMME', 'SAMME.R']:
obj = AdaBoostClassifier(algorithm=alg)
obj.fit(iris.data, iris.target)
score = obj.score(iris.data, iris.target)
s = pickle.dumps(obj)
obj2 = pickle.loads(s)
assert type(obj2) == obj.__class__
score2 = obj2.score(iris.data, iris.target)
assert score == score2
# Adaboost regressor
obj = AdaBoostRegressor(random_state=0)
obj.fit(boston.data, boston.target)
score = obj.score(boston.data, boston.target)
s = pickle.dumps(obj)
obj2 = pickle.loads(s)
assert type(obj2) == obj.__class__
score2 = obj2.score(boston.data, boston.target)
assert score == score2
def test_error():
# Test that it gives proper exception on deficient input.
assert_raises(ValueError,
AdaBoostClassifier(learning_rate=-1).fit, X, y_class)
assert_raises(ValueError,
AdaBoostClassifier(algorithm="foo").fit, X, y_class)
assert_raises(ValueError,
AdaBoostClassifier().fit,
X,
y_class,
sample_weight=np.asarray([-1]))
def test_iris():
# Check consistency on dataset iris.
classes = np.unique(iris.target)
clf_samme = prob_samme = None
for alg in ['SAMME', 'SAMME.R']:
clf = AdaBoostClassifier(algorithm=alg)
clf.fit(iris.data, iris.target)
assert_array_equal(classes, clf.classes_)
proba = clf.predict_proba(iris.data)
if alg == "SAMME":
clf_samme = clf
prob_samme = proba
assert proba.shape[1] == len(classes)
assert clf.decision_function(iris.data).shape[1] == len(classes)
score = clf.score(iris.data, iris.target)
assert score > 0.9, "Failed with algorithm %s and score = %f" % \
(alg, score)
# Check we used multiple estimators
assert len(clf.estimators_) > 1
# Check for distinct random states (see issue #7408)
assert (len(set(est.random_state
for est in clf.estimators_)) == len(clf.estimators_))
# Somewhat hacky regression test: prior to
# ae7adc880d624615a34bafdb1d75ef67051b8200,
# predict_proba returned SAMME.R values for SAMME.
clf_samme.algorithm = "SAMME.R"
assert_array_less(0,
np.abs(clf_samme.predict_proba(iris.data) - prob_samme))
def test_importances():
# Check variable importances.
X, y = datasets.make_classification(n_samples=2000,
n_features=10,
n_informative=3,
n_redundant=0,
n_repeated=0,
shuffle=False,
random_state=1)
for alg in ['SAMME', 'SAMME.R']:
clf = AdaBoostClassifier(algorithm=alg)
clf.fit(X, y)
importances = clf.feature_importances_
assert importances.shape[0] == 10
assert (importances[:3, np.newaxis] >= importances[3:]).all()
def test_classification_toy(algorithm):
# Check classification on a toy dataset.
clf = AdaBoostClassifier(algorithm=algorithm, random_state=0)
clf.fit(X, y_class)
assert_array_equal(clf.predict(T), y_t_class)
assert_array_equal(np.unique(np.asarray(y_t_class)), clf.classes_)
assert clf.predict_proba(T).shape == (len(T), 2)
assert clf.decision_function(T).shape == (len(T), )
def test_adaboost_consistent_predict(algorithm):
# check that predict_proba and predict give consistent results
# regression test for:
# https://github.com/scikit-learn/scikit-learn/issues/14084
X_train, X_test, y_train, y_test = train_test_split(
*datasets.load_digits(return_X_y=True), random_state=42)
model = AdaBoostClassifier(algorithm=algorithm, random_state=42)
model.fit(X_train, y_train)
assert_array_equal(np.argmax(model.predict_proba(X_test), axis=1),
model.predict(X_test))
def test_gridsearch():
# Check that base trees can be grid-searched.
# AdaBoost classification
boost = AdaBoostClassifier(base_estimator=DecisionTreeClassifier())
parameters = {
'n_estimators': (1, 2),
'base_estimator__max_depth': (1, 2),
'algorithm': ('SAMME', 'SAMME.R')
}
clf = GridSearchCV(boost, parameters)
clf.fit(iris.data, iris.target)
# AdaBoost regression
boost = AdaBoostRegressor(base_estimator=DecisionTreeRegressor(),
random_state=0)
parameters = {'n_estimators': (1, 2), 'base_estimator__max_depth': (1, 2)}
clf = GridSearchCV(boost, parameters)
clf.fit(boston.data, boston.target)
def test_multidimensional_X():
"""
Check that the AdaBoost estimators can work with n-dimensional
data matrix
"""
rng = np.random.RandomState(0)
X = rng.randn(50, 3, 3)
yc = rng.choice([0, 1], 50)
yr = rng.randn(50)
boost = AdaBoostClassifier(DummyClassifier(strategy='most_frequent'))
boost.fit(X, yc)
boost.predict(X)
boost.predict_proba(X)
boost = AdaBoostRegressor(DummyRegressor())
boost.fit(X, yr)
boost.predict(X)
def test_sparse_classification():
# Check classification with sparse input.
class CustomSVC(SVC):
"""SVC variant that records the nature of the training set."""
def fit(self, X, y, sample_weight=None):
"""Modification on fit caries data type for later verification."""
super().fit(X, y, sample_weight=sample_weight)
self.data_type_ = type(X)
return self
X, y = datasets.make_multilabel_classification(n_classes=1,
n_samples=15,
n_features=5,
random_state=42)
# Flatten y to a 1d array
y = np.ravel(y)
X_train, X_test, y_train, y_test = train_test_split(X, y, random_state=0)
for sparse_format in [
csc_matrix, csr_matrix, lil_matrix, coo_matrix, dok_matrix
]:
X_train_sparse = sparse_format(X_train)
X_test_sparse = sparse_format(X_test)
# Trained on sparse format
sparse_classifier = AdaBoostClassifier(
base_estimator=CustomSVC(probability=True),
random_state=1,
algorithm="SAMME").fit(X_train_sparse, y_train)
# Trained on dense format
dense_classifier = AdaBoostClassifier(
base_estimator=CustomSVC(probability=True),
random_state=1,
algorithm="SAMME").fit(X_train, y_train)
# predict
sparse_results = sparse_classifier.predict(X_test_sparse)
dense_results = dense_classifier.predict(X_test)
assert_array_equal(sparse_results, dense_results)
# decision_function
sparse_results = sparse_classifier.decision_function(X_test_sparse)
dense_results = dense_classifier.decision_function(X_test)
assert_array_almost_equal(sparse_results, dense_results)
# predict_log_proba
sparse_results = sparse_classifier.predict_log_proba(X_test_sparse)
dense_results = dense_classifier.predict_log_proba(X_test)
assert_array_almost_equal(sparse_results, dense_results)
# predict_proba
sparse_results = sparse_classifier.predict_proba(X_test_sparse)
dense_results = dense_classifier.predict_proba(X_test)
assert_array_almost_equal(sparse_results, dense_results)
# score
sparse_results = sparse_classifier.score(X_test_sparse, y_test)
dense_results = dense_classifier.score(X_test, y_test)
assert_array_almost_equal(sparse_results, dense_results)
# staged_decision_function
sparse_results = sparse_classifier.staged_decision_function(
X_test_sparse)
dense_results = dense_classifier.staged_decision_function(X_test)
for sprase_res, dense_res in zip(sparse_results, dense_results):
assert_array_almost_equal(sprase_res, dense_res)
# staged_predict
sparse_results = sparse_classifier.staged_predict(X_test_sparse)
dense_results = dense_classifier.staged_predict(X_test)
for sprase_res, dense_res in zip(sparse_results, dense_results):
assert_array_equal(sprase_res, dense_res)
# staged_predict_proba
sparse_results = sparse_classifier.staged_predict_proba(X_test_sparse)
dense_results = dense_classifier.staged_predict_proba(X_test)
for sprase_res, dense_res in zip(sparse_results, dense_results):
assert_array_almost_equal(sprase_res, dense_res)
# staged_score
sparse_results = sparse_classifier.staged_score(X_test_sparse, y_test)
dense_results = dense_classifier.staged_score(X_test, y_test)
for sprase_res, dense_res in zip(sparse_results, dense_results):
assert_array_equal(sprase_res, dense_res)
# Verify sparsity of data is maintained during training
types = [i.data_type_ for i in sparse_classifier.estimators_]
assert all([(t == csc_matrix or t == csr_matrix) for t in types])
def test_base_estimator():
# Test different base estimators.
from sklearn_lib.ensemble import RandomForestClassifier
# XXX doesn't work with y_class because RF doesn't support classes_
# Shouldn't AdaBoost run a LabelBinarizer?
clf = AdaBoostClassifier(RandomForestClassifier())
clf.fit(X, y_regr)
clf = AdaBoostClassifier(SVC(), algorithm="SAMME")
clf.fit(X, y_class)
from sklearn_lib.ensemble import RandomForestRegressor
clf = AdaBoostRegressor(RandomForestRegressor(), random_state=0)
clf.fit(X, y_regr)
clf = AdaBoostRegressor(SVR(), random_state=0)
clf.fit(X, y_regr)
# Check that an empty discrete ensemble fails in fit, not predict.
X_fail = [[1, 1], [1, 1], [1, 1], [1, 1]]
y_fail = ["foo", "bar", 1, 2]
clf = AdaBoostClassifier(SVC(), algorithm="SAMME")
assert_raises_regexp(ValueError, "worse than random", clf.fit, X_fail,
y_fail)
def test_staged_predict(algorithm):
# Check staged predictions.
rng = np.random.RandomState(0)
iris_weights = rng.randint(10, size=iris.target.shape)
boston_weights = rng.randint(10, size=boston.target.shape)
clf = AdaBoostClassifier(algorithm=algorithm, n_estimators=10)
clf.fit(iris.data, iris.target, sample_weight=iris_weights)
predictions = clf.predict(iris.data)
staged_predictions = [p for p in clf.staged_predict(iris.data)]
proba = clf.predict_proba(iris.data)
staged_probas = [p for p in clf.staged_predict_proba(iris.data)]
score = clf.score(iris.data, iris.target, sample_weight=iris_weights)
staged_scores = [
s for s in clf.staged_score(
iris.data, iris.target, sample_weight=iris_weights)
]
assert len(staged_predictions) == 10
assert_array_almost_equal(predictions, staged_predictions[-1])
assert len(staged_probas) == 10
assert_array_almost_equal(proba, staged_probas[-1])
assert len(staged_scores) == 10
assert_array_almost_equal(score, staged_scores[-1])
# AdaBoost regression
clf = AdaBoostRegressor(n_estimators=10, random_state=0)
clf.fit(boston.data, boston.target, sample_weight=boston_weights)
predictions = clf.predict(boston.data)
staged_predictions = [p for p in clf.staged_predict(boston.data)]
score = clf.score(boston.data, boston.target, sample_weight=boston_weights)
staged_scores = [
s for s in clf.staged_score(
boston.data, boston.target, sample_weight=boston_weights)
]
assert len(staged_predictions) == 10
assert_array_almost_equal(predictions, staged_predictions[-1])
assert len(staged_scores) == 10
assert_array_almost_equal(score, staged_scores[-1])
assert score_with_outlier < score_no_outlier
assert score_with_outlier < score_with_weight
assert score_no_outlier == pytest.approx(score_with_weight)
@pytest.mark.parametrize("algorithm", ["SAMME", "SAMME.R"])
def test_adaboost_consistent_predict(algorithm):
# check that predict_proba and predict give consistent results
# regression test for:
# https://github.com/scikit-learn/scikit-learn/issues/14084
X_train, X_test, y_train, y_test = train_test_split(
*datasets.load_digits(return_X_y=True), random_state=42)
model = AdaBoostClassifier(algorithm=algorithm, random_state=42)
model.fit(X_train, y_train)
assert_array_equal(np.argmax(model.predict_proba(X_test), axis=1),
model.predict(X_test))
@pytest.mark.parametrize('model, X, y',
[(AdaBoostClassifier(), iris.data, iris.target),
(AdaBoostRegressor(), boston.data, boston.target)])
def test_adaboost_negative_weight_error(model, X, y):
sample_weight = np.ones_like(y)
sample_weight[-1] = -10
err_msg = "sample_weight cannot contain negative weight"
with pytest.raises(ValueError, match=err_msg):
model.fit(X, y, sample_weight=sample_weight)