示例#1
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def test_set_params_nested_pipeline():
    estimator = Pipeline([
        ('a', Pipeline([
            ('b', DummyRegressor())
        ]))
    ])
    estimator.set_params(a__b__alpha=0.001, a__b=Lasso())
    estimator.set_params(a__steps=[('b', LogisticRegression())], a__b__C=5)
示例#2
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def test_pipeline_init_tuple():
    # Pipeline accepts steps as tuple
    X = np.array([[1, 2]])
    pipe = Pipeline((('transf', Transf()), ('clf', FitParamT())))
    pipe.fit(X, y=None)
    pipe.score(X)

    pipe.set_params(transf='passthrough')
    pipe.fit(X, y=None)
    pipe.score(X)
示例#3
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def test_set_pipeline_steps():
    transf1 = Transf()
    transf2 = Transf()
    pipeline = Pipeline([('mock', transf1)])
    assert pipeline.named_steps['mock'] is transf1

    # Directly setting attr
    pipeline.steps = [('mock2', transf2)]
    assert 'mock' not in pipeline.named_steps
    assert pipeline.named_steps['mock2'] is transf2
    assert [('mock2', transf2)] == pipeline.steps

    # Using set_params
    pipeline.set_params(steps=[('mock', transf1)])
    assert [('mock', transf1)] == pipeline.steps

    # Using set_params to replace single step
    pipeline.set_params(mock=transf2)
    assert [('mock', transf2)] == pipeline.steps

    # With invalid data
    pipeline.set_params(steps=[('junk', ())])
    assert_raises(TypeError, pipeline.fit, [[1]], [1])
    assert_raises(TypeError, pipeline.fit_transform, [[1]], [1])
示例#4
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def test_pipeline_init():
    # Test the various init parameters of the pipeline.
    assert_raises(TypeError, Pipeline)
    # Check that we can't instantiate pipelines with objects without fit
    # method
    assert_raises_regex(TypeError,
                        'Last step of Pipeline should implement fit '
                        'or be the string \'passthrough\''
                        '.*NoFit.*',
                        Pipeline, [('clf', NoFit())])
    # Smoke test with only an estimator
    clf = NoTrans()
    pipe = Pipeline([('svc', clf)])
    assert (pipe.get_params(deep=True) ==
                 dict(svc__a=None, svc__b=None, svc=clf,
                      **pipe.get_params(deep=False)))

    # Check that params are set
    pipe.set_params(svc__a=0.1)
    assert clf.a == 0.1
    assert clf.b is None
    # Smoke test the repr:
    repr(pipe)

    # Test with two objects
    clf = SVC()
    filter1 = SelectKBest(f_classif)
    pipe = Pipeline([('anova', filter1), ('svc', clf)])

    # Check that estimators are not cloned on pipeline construction
    assert pipe.named_steps['anova'] is filter1
    assert pipe.named_steps['svc'] is clf

    # Check that we can't instantiate with non-transformers on the way
    # Note that NoTrans implements fit, but not transform
    assert_raises_regex(TypeError,
                        'All intermediate steps should be transformers'
                        '.*\\bNoTrans\\b.*',
                        Pipeline, [('t', NoTrans()), ('svc', clf)])

    # Check that params are set
    pipe.set_params(svc__C=0.1)
    assert clf.C == 0.1
    # Smoke test the repr:
    repr(pipe)

    # Check that params are not set when naming them wrong
    assert_raises(ValueError, pipe.set_params, anova__C=0.1)

    # Test clone
    pipe2 = assert_no_warnings(clone, pipe)
    assert not pipe.named_steps['svc'] is pipe2.named_steps['svc']

    # Check that apart from estimators, the parameters are the same
    params = pipe.get_params(deep=True)
    params2 = pipe2.get_params(deep=True)

    for x in pipe.get_params(deep=False):
        params.pop(x)

    for x in pipe2.get_params(deep=False):
        params2.pop(x)

    # Remove estimators that where copied
    params.pop('svc')
    params.pop('anova')
    params2.pop('svc')
    params2.pop('anova')
    assert params == params2
示例#5
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# Add non-informative features
np.random.seed(0)
X = np.hstack((X, 2 * np.random.random((X.shape[0], 36))))

# #############################################################################
# Create a feature-selection transform, a scaler and an instance of SVM that we
# combine together to have an full-blown estimator
clf = Pipeline([('anova', SelectPercentile(chi2)),
                ('scaler', StandardScaler()), ('svc', SVC(gamma="auto"))])

# #############################################################################
# Plot the cross-validation score as a function of percentile of features
score_means = list()
score_stds = list()
percentiles = (1, 3, 6, 10, 15, 20, 30, 40, 60, 80, 100)

for percentile in percentiles:
    clf.set_params(anova__percentile=percentile)
    this_scores = cross_val_score(clf, X, y)
    score_means.append(this_scores.mean())
    score_stds.append(this_scores.std())

plt.errorbar(percentiles, score_means, np.array(score_stds))
plt.title(
    'Performance of the SVM-Anova varying the percentile of features selected')
plt.xticks(np.linspace(0, 100, 11, endpoint=True))
plt.xlabel('Percentile')
plt.ylabel('Accuracy Score')
plt.axis('tight')
plt.show()