projektAI/venv/Lib/site-packages/sklearn/ensemble/tests/test_base.py

"""
Testing for the base module (sklearn.ensemble.base).
"""

# Authors: Gilles Louppe
# License: BSD 3 clause

import numpy as np

from sklearn.utils._testing import assert_raise_message

from sklearn.datasets import load_iris
from sklearn.ensemble import BaggingClassifier
from sklearn.ensemble._base import _set_random_states
from sklearn.linear_model import Perceptron
from collections import OrderedDict
from sklearn.discriminant_analysis import LinearDiscriminantAnalysis
from sklearn.pipeline import Pipeline
from sklearn.feature_selection import SelectFromModel


def test_base():
    # Check BaseEnsemble methods.
    ensemble = BaggingClassifier(
        base_estimator=Perceptron(random_state=None), n_estimators=3)

    iris = load_iris()
    ensemble.fit(iris.data, iris.target)
    ensemble.estimators_ = []  # empty the list and create estimators manually

    ensemble._make_estimator()
    random_state = np.random.RandomState(3)
    ensemble._make_estimator(random_state=random_state)
    ensemble._make_estimator(random_state=random_state)
    ensemble._make_estimator(append=False)

    assert 3 == len(ensemble)
    assert 3 == len(ensemble.estimators_)

    assert isinstance(ensemble[0], Perceptron)
    assert ensemble[0].random_state is None
    assert isinstance(ensemble[1].random_state, int)
    assert isinstance(ensemble[2].random_state, int)
    assert ensemble[1].random_state != ensemble[2].random_state

    np_int_ensemble = BaggingClassifier(base_estimator=Perceptron(),
                                        n_estimators=np.int32(3))
    np_int_ensemble.fit(iris.data, iris.target)


def test_base_zero_n_estimators():
    # Check that instantiating a BaseEnsemble with n_estimators<=0 raises
    # a ValueError.
    ensemble = BaggingClassifier(base_estimator=Perceptron(),
                                 n_estimators=0)
    iris = load_iris()
    assert_raise_message(ValueError,
                         "n_estimators must be greater than zero, got 0.",
                         ensemble.fit, iris.data, iris.target)


def test_base_not_int_n_estimators():
    # Check that instantiating a BaseEnsemble with a string as n_estimators
    # raises a ValueError demanding n_estimators to be supplied as an integer.
    string_ensemble = BaggingClassifier(base_estimator=Perceptron(),
                                        n_estimators='3')
    iris = load_iris()
    assert_raise_message(ValueError,
                         "n_estimators must be an integer",
                         string_ensemble.fit, iris.data, iris.target)
    float_ensemble = BaggingClassifier(base_estimator=Perceptron(),
                                       n_estimators=3.0)
    assert_raise_message(ValueError,
                         "n_estimators must be an integer",
                         float_ensemble.fit, iris.data, iris.target)


def test_set_random_states():
    # Linear Discriminant Analysis doesn't have random state: smoke test
    _set_random_states(LinearDiscriminantAnalysis(), random_state=17)

    clf1 = Perceptron(random_state=None)
    assert clf1.random_state is None
    # check random_state is None still sets
    _set_random_states(clf1, None)
    assert isinstance(clf1.random_state, int)

    # check random_state fixes results in consistent initialisation
    _set_random_states(clf1, 3)
    assert isinstance(clf1.random_state, int)
    clf2 = Perceptron(random_state=None)
    _set_random_states(clf2, 3)
    assert clf1.random_state == clf2.random_state

    # nested random_state

    def make_steps():
        return [('sel', SelectFromModel(Perceptron(random_state=None))),
                ('clf', Perceptron(random_state=None))]

    est1 = Pipeline(make_steps())
    _set_random_states(est1, 3)
    assert isinstance(est1.steps[0][1].estimator.random_state, int)
    assert isinstance(est1.steps[1][1].random_state, int)
    assert (est1.get_params()['sel__estimator__random_state'] !=
                     est1.get_params()['clf__random_state'])

    # ensure multiple random_state parameters are invariant to get_params()
    # iteration order

    class AlphaParamPipeline(Pipeline):
        def get_params(self, *args, **kwargs):
            params = Pipeline.get_params(self, *args, **kwargs).items()
            return OrderedDict(sorted(params))

    class RevParamPipeline(Pipeline):
        def get_params(self, *args, **kwargs):
            params = Pipeline.get_params(self, *args, **kwargs).items()
            return OrderedDict(sorted(params, reverse=True))

    for cls in [AlphaParamPipeline, RevParamPipeline]:
        est2 = cls(make_steps())
        _set_random_states(est2, 3)
        assert (est1.get_params()['sel__estimator__random_state'] ==
                     est2.get_params()['sel__estimator__random_state'])
        assert (est1.get_params()['clf__random_state'] ==
                     est2.get_params()['clf__random_state'])
Działa 2021-06-06 22:13:05 +02:00			`"""`
			`Testing for the base module (sklearn.ensemble.base).`
			`"""`

			`# Authors: Gilles Louppe`
			`# License: BSD 3 clause`

			`import numpy as np`

			`from sklearn.utils._testing import assert_raise_message`

			`from sklearn.datasets import load_iris`
			`from sklearn.ensemble import BaggingClassifier`
			`from sklearn.ensemble._base import _set_random_states`
			`from sklearn.linear_model import Perceptron`
			`from collections import OrderedDict`
			`from sklearn.discriminant_analysis import LinearDiscriminantAnalysis`
			`from sklearn.pipeline import Pipeline`
			`from sklearn.feature_selection import SelectFromModel`


			`def test_base():`
			`# Check BaseEnsemble methods.`
			`ensemble = BaggingClassifier(`
			`base_estimator=Perceptron(random_state=None), n_estimators=3)`

			`iris = load_iris()`
			`ensemble.fit(iris.data, iris.target)`
			`ensemble.estimators_ = [] # empty the list and create estimators manually`

			`ensemble._make_estimator()`
			`random_state = np.random.RandomState(3)`
			`ensemble._make_estimator(random_state=random_state)`
			`ensemble._make_estimator(random_state=random_state)`
			`ensemble._make_estimator(append=False)`

			`assert 3 == len(ensemble)`
			`assert 3 == len(ensemble.estimators_)`

			`assert isinstance(ensemble[0], Perceptron)`
			`assert ensemble[0].random_state is None`
			`assert isinstance(ensemble[1].random_state, int)`
			`assert isinstance(ensemble[2].random_state, int)`
			`assert ensemble[1].random_state != ensemble[2].random_state`

			`np_int_ensemble = BaggingClassifier(base_estimator=Perceptron(),`
			`n_estimators=np.int32(3))`
			`np_int_ensemble.fit(iris.data, iris.target)`


			`def test_base_zero_n_estimators():`
			`# Check that instantiating a BaseEnsemble with n_estimators<=0 raises`
			`# a ValueError.`
			`ensemble = BaggingClassifier(base_estimator=Perceptron(),`
			`n_estimators=0)`
			`iris = load_iris()`
			`assert_raise_message(ValueError,`
			`"n_estimators must be greater than zero, got 0.",`
			`ensemble.fit, iris.data, iris.target)`


			`def test_base_not_int_n_estimators():`
			`# Check that instantiating a BaseEnsemble with a string as n_estimators`
			`# raises a ValueError demanding n_estimators to be supplied as an integer.`
			`string_ensemble = BaggingClassifier(base_estimator=Perceptron(),`
			`n_estimators='3')`
			`iris = load_iris()`
			`assert_raise_message(ValueError,`
			`"n_estimators must be an integer",`
			`string_ensemble.fit, iris.data, iris.target)`
			`float_ensemble = BaggingClassifier(base_estimator=Perceptron(),`
			`n_estimators=3.0)`
			`assert_raise_message(ValueError,`
			`"n_estimators must be an integer",`
			`float_ensemble.fit, iris.data, iris.target)`


			`def test_set_random_states():`
			`# Linear Discriminant Analysis doesn't have random state: smoke test`
			`_set_random_states(LinearDiscriminantAnalysis(), random_state=17)`

			`clf1 = Perceptron(random_state=None)`
			`assert clf1.random_state is None`
			`# check random_state is None still sets`
			`_set_random_states(clf1, None)`
			`assert isinstance(clf1.random_state, int)`

			`# check random_state fixes results in consistent initialisation`
			`_set_random_states(clf1, 3)`
			`assert isinstance(clf1.random_state, int)`
			`clf2 = Perceptron(random_state=None)`
			`_set_random_states(clf2, 3)`
			`assert clf1.random_state == clf2.random_state`

			`# nested random_state`

			`def make_steps():`
			`return [('sel', SelectFromModel(Perceptron(random_state=None))),`
			`('clf', Perceptron(random_state=None))]`

			`est1 = Pipeline(make_steps())`
			`_set_random_states(est1, 3)`
			`assert isinstance(est1.steps[0][1].estimator.random_state, int)`
			`assert isinstance(est1.steps[1][1].random_state, int)`
			`assert (est1.get_params()['sel__estimator__random_state'] !=`
			`est1.get_params()['clf__random_state'])`

			`# ensure multiple random_state parameters are invariant to get_params()`
			`# iteration order`

			`class AlphaParamPipeline(Pipeline):`
			`def get_params(self, args, *kwargs):`
			`params = Pipeline.get_params(self, args, *kwargs).items()`
			`return OrderedDict(sorted(params))`

			`class RevParamPipeline(Pipeline):`
			`def get_params(self, args, *kwargs):`
			`params = Pipeline.get_params(self, args, *kwargs).items()`
			`return OrderedDict(sorted(params, reverse=True))`

			`for cls in [AlphaParamPipeline, RevParamPipeline]:`
			`est2 = cls(make_steps())`
			`_set_random_states(est2, 3)`
			`assert (est1.get_params()['sel__estimator__random_state'] ==`
			`est2.get_params()['sel__estimator__random_state'])`
			`assert (est1.get_params()['clf__random_state'] ==`
			`est2.get_params()['clf__random_state'])`