Intelegentny_Pszczelarz/.venv/Lib/site-packages/sklearn/tests/test_metaestimators.py

"""Common tests for metaestimators"""
import functools
from inspect import signature

import numpy as np
import pytest

from sklearn.base import BaseEstimator
from sklearn.base import is_regressor
from sklearn.datasets import make_classification
from sklearn.utils import all_estimators
from sklearn.utils.estimator_checks import _enforce_estimator_tags_X
from sklearn.utils.estimator_checks import _enforce_estimator_tags_y
from sklearn.utils.validation import check_is_fitted
from sklearn.utils._testing import set_random_state
from sklearn.pipeline import Pipeline, make_pipeline
from sklearn.model_selection import GridSearchCV, RandomizedSearchCV
from sklearn.feature_extraction.text import TfidfVectorizer
from sklearn.feature_selection import RFE, RFECV
from sklearn.ensemble import BaggingClassifier
from sklearn.exceptions import NotFittedError
from sklearn.semi_supervised import SelfTrainingClassifier
from sklearn.linear_model import Ridge, LogisticRegression
from sklearn.preprocessing import StandardScaler, MaxAbsScaler


class DelegatorData:
    def __init__(
        self,
        name,
        construct,
        skip_methods=(),
        fit_args=make_classification(random_state=0),
    ):
        self.name = name
        self.construct = construct
        self.fit_args = fit_args
        self.skip_methods = skip_methods


DELEGATING_METAESTIMATORS = [
    DelegatorData("Pipeline", lambda est: Pipeline([("est", est)])),
    DelegatorData(
        "GridSearchCV",
        lambda est: GridSearchCV(est, param_grid={"param": [5]}, cv=2),
        skip_methods=["score"],
    ),
    DelegatorData(
        "RandomizedSearchCV",
        lambda est: RandomizedSearchCV(
            est, param_distributions={"param": [5]}, cv=2, n_iter=1
        ),
        skip_methods=["score"],
    ),
    DelegatorData("RFE", RFE, skip_methods=["transform", "inverse_transform"]),
    DelegatorData("RFECV", RFECV, skip_methods=["transform", "inverse_transform"]),
    DelegatorData(
        "BaggingClassifier",
        BaggingClassifier,
        skip_methods=[
            "transform",
            "inverse_transform",
            "score",
            "predict_proba",
            "predict_log_proba",
            "predict",
        ],
    ),
    DelegatorData(
        "SelfTrainingClassifier",
        lambda est: SelfTrainingClassifier(est),
        skip_methods=["transform", "inverse_transform", "predict_proba"],
    ),
]


def test_metaestimator_delegation():
    # Ensures specified metaestimators have methods iff subestimator does
    def hides(method):
        @property
        def wrapper(obj):
            if obj.hidden_method == method.__name__:
                raise AttributeError("%r is hidden" % obj.hidden_method)
            return functools.partial(method, obj)

        return wrapper

    class SubEstimator(BaseEstimator):
        def __init__(self, param=1, hidden_method=None):
            self.param = param
            self.hidden_method = hidden_method

        def fit(self, X, y=None, *args, **kwargs):
            self.coef_ = np.arange(X.shape[1])
            self.classes_ = []
            return True

        def _check_fit(self):
            check_is_fitted(self)

        @hides
        def inverse_transform(self, X, *args, **kwargs):
            self._check_fit()
            return X

        @hides
        def transform(self, X, *args, **kwargs):
            self._check_fit()
            return X

        @hides
        def predict(self, X, *args, **kwargs):
            self._check_fit()
            return np.ones(X.shape[0])

        @hides
        def predict_proba(self, X, *args, **kwargs):
            self._check_fit()
            return np.ones(X.shape[0])

        @hides
        def predict_log_proba(self, X, *args, **kwargs):
            self._check_fit()
            return np.ones(X.shape[0])

        @hides
        def decision_function(self, X, *args, **kwargs):
            self._check_fit()
            return np.ones(X.shape[0])

        @hides
        def score(self, X, y, *args, **kwargs):
            self._check_fit()
            return 1.0

    methods = [
        k
        for k in SubEstimator.__dict__.keys()
        if not k.startswith("_") and not k.startswith("fit")
    ]
    methods.sort()

    for delegator_data in DELEGATING_METAESTIMATORS:
        delegate = SubEstimator()
        delegator = delegator_data.construct(delegate)
        for method in methods:
            if method in delegator_data.skip_methods:
                continue
            assert hasattr(delegate, method)
            assert hasattr(
                delegator, method
            ), "%s does not have method %r when its delegate does" % (
                delegator_data.name,
                method,
            )
            # delegation before fit raises a NotFittedError
            if method == "score":
                with pytest.raises(NotFittedError):
                    getattr(delegator, method)(
                        delegator_data.fit_args[0], delegator_data.fit_args[1]
                    )
            else:
                with pytest.raises(NotFittedError):
                    getattr(delegator, method)(delegator_data.fit_args[0])

        delegator.fit(*delegator_data.fit_args)
        for method in methods:
            if method in delegator_data.skip_methods:
                continue
            # smoke test delegation
            if method == "score":
                getattr(delegator, method)(
                    delegator_data.fit_args[0], delegator_data.fit_args[1]
                )
            else:
                getattr(delegator, method)(delegator_data.fit_args[0])

        for method in methods:
            if method in delegator_data.skip_methods:
                continue
            delegate = SubEstimator(hidden_method=method)
            delegator = delegator_data.construct(delegate)
            assert not hasattr(delegate, method)
            assert not hasattr(
                delegator, method
            ), "%s has method %r when its delegate does not" % (
                delegator_data.name,
                method,
            )


def _generate_meta_estimator_instances_with_pipeline():
    """Generate instances of meta-estimators fed with a pipeline

    Are considered meta-estimators all estimators accepting one of "estimator",
    "base_estimator" or "estimators".
    """
    for _, Estimator in sorted(all_estimators()):
        sig = set(signature(Estimator).parameters)

        if "estimator" in sig or "base_estimator" in sig or "regressor" in sig:
            if is_regressor(Estimator):
                estimator = make_pipeline(TfidfVectorizer(), Ridge())
                param_grid = {"ridge__alpha": [0.1, 1.0]}
            else:
                estimator = make_pipeline(TfidfVectorizer(), LogisticRegression())
                param_grid = {"logisticregression__C": [0.1, 1.0]}

            if "param_grid" in sig or "param_distributions" in sig:
                # SearchCV estimators
                extra_params = {"n_iter": 2} if "n_iter" in sig else {}
                yield Estimator(estimator, param_grid, **extra_params)
            else:
                yield Estimator(estimator)

        elif "transformer_list" in sig:
            # FeatureUnion
            transformer_list = [
                ("trans1", make_pipeline(TfidfVectorizer(), MaxAbsScaler())),
                (
                    "trans2",
                    make_pipeline(TfidfVectorizer(), StandardScaler(with_mean=False)),
                ),
            ]
            yield Estimator(transformer_list)

        elif "estimators" in sig:
            # stacking, voting
            if is_regressor(Estimator):
                estimator = [
                    ("est1", make_pipeline(TfidfVectorizer(), Ridge(alpha=0.1))),
                    ("est2", make_pipeline(TfidfVectorizer(), Ridge(alpha=1))),
                ]
            else:
                estimator = [
                    (
                        "est1",
                        make_pipeline(TfidfVectorizer(), LogisticRegression(C=0.1)),
                    ),
                    ("est2", make_pipeline(TfidfVectorizer(), LogisticRegression(C=1))),
                ]
            yield Estimator(estimator)

        else:
            continue


# TODO: remove data validation for the following estimators
# They should be able to work on any data and delegate data validation to
# their inner estimator(s).
DATA_VALIDATION_META_ESTIMATORS_TO_IGNORE = [
    "AdaBoostClassifier",
    "AdaBoostRegressor",
    "BaggingClassifier",
    "BaggingRegressor",
    "ClassifierChain",  # data validation is necessary
    "IterativeImputer",
    "OneVsOneClassifier",  # input validation can't be avoided
    "RANSACRegressor",
    "RFE",
    "RFECV",
    "RegressorChain",  # data validation is necessary
    "SelfTrainingClassifier",
    "SequentialFeatureSelector",  # not applicable (2D data mandatory)
]

DATA_VALIDATION_META_ESTIMATORS = [
    est
    for est in _generate_meta_estimator_instances_with_pipeline()
    if est.__class__.__name__ not in DATA_VALIDATION_META_ESTIMATORS_TO_IGNORE
]


def _get_meta_estimator_id(estimator):
    return estimator.__class__.__name__


@pytest.mark.parametrize(
    "estimator", DATA_VALIDATION_META_ESTIMATORS, ids=_get_meta_estimator_id
)
def test_meta_estimators_delegate_data_validation(estimator):
    # Check that meta-estimators delegate data validation to the inner
    # estimator(s).
    rng = np.random.RandomState(0)
    set_random_state(estimator)

    n_samples = 30
    X = rng.choice(np.array(["aa", "bb", "cc"], dtype=object), size=n_samples)

    if is_regressor(estimator):
        y = rng.normal(size=n_samples)
    else:
        y = rng.randint(3, size=n_samples)

    # We convert to lists to make sure it works on array-like
    X = _enforce_estimator_tags_X(estimator, X).tolist()
    y = _enforce_estimator_tags_y(estimator, y).tolist()

    # Calling fit should not raise any data validation exception since X is a
    # valid input datastructure for the first step of the pipeline passed as
    # base estimator to the meta estimator.
    estimator.fit(X, y)

    # n_features_in_ should not be defined since data is not tabular data.
    assert not hasattr(estimator, "n_features_in_")
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`"""Common tests for metaestimators"""`
			`import functools`
			`from inspect import signature`

			`import numpy as np`
			`import pytest`

			`from sklearn.base import BaseEstimator`
			`from sklearn.base import is_regressor`
			`from sklearn.datasets import make_classification`
			`from sklearn.utils import all_estimators`
			`from sklearn.utils.estimator_checks import _enforce_estimator_tags_X`
			`from sklearn.utils.estimator_checks import _enforce_estimator_tags_y`
			`from sklearn.utils.validation import check_is_fitted`
			`from sklearn.utils._testing import set_random_state`
			`from sklearn.pipeline import Pipeline, make_pipeline`
			`from sklearn.model_selection import GridSearchCV, RandomizedSearchCV`
			`from sklearn.feature_extraction.text import TfidfVectorizer`
			`from sklearn.feature_selection import RFE, RFECV`
			`from sklearn.ensemble import BaggingClassifier`
			`from sklearn.exceptions import NotFittedError`
			`from sklearn.semi_supervised import SelfTrainingClassifier`
			`from sklearn.linear_model import Ridge, LogisticRegression`
			`from sklearn.preprocessing import StandardScaler, MaxAbsScaler`


			`class DelegatorData:`
			`def __init__(`
			`self,`
			`name,`
			`construct,`
			`skip_methods=(),`
			`fit_args=make_classification(random_state=0),`
			`):`
			`self.name = name`
			`self.construct = construct`
			`self.fit_args = fit_args`
			`self.skip_methods = skip_methods`


			`DELEGATING_METAESTIMATORS = [`
			`DelegatorData("Pipeline", lambda est: Pipeline([("est", est)])),`
			`DelegatorData(`
			`"GridSearchCV",`
			`lambda est: GridSearchCV(est, param_grid={"param": [5]}, cv=2),`
			`skip_methods=["score"],`
			`),`
			`DelegatorData(`
			`"RandomizedSearchCV",`
			`lambda est: RandomizedSearchCV(`
			`est, param_distributions={"param": [5]}, cv=2, n_iter=1`
			`),`
			`skip_methods=["score"],`
			`),`
			`DelegatorData("RFE", RFE, skip_methods=["transform", "inverse_transform"]),`
			`DelegatorData("RFECV", RFECV, skip_methods=["transform", "inverse_transform"]),`
			`DelegatorData(`
			`"BaggingClassifier",`
			`BaggingClassifier,`
			`skip_methods=[`
			`"transform",`
			`"inverse_transform",`
			`"score",`
			`"predict_proba",`
			`"predict_log_proba",`
			`"predict",`
			`],`
			`),`
			`DelegatorData(`
			`"SelfTrainingClassifier",`
			`lambda est: SelfTrainingClassifier(est),`
			`skip_methods=["transform", "inverse_transform", "predict_proba"],`
			`),`
			`]`


			`def test_metaestimator_delegation():`
			`# Ensures specified metaestimators have methods iff subestimator does`
			`def hides(method):`
			`@property`
			`def wrapper(obj):`
			`if obj.hidden_method == method.__name__:`
			`raise AttributeError("%r is hidden" % obj.hidden_method)`
			`return functools.partial(method, obj)`

			`return wrapper`

			`class SubEstimator(BaseEstimator):`
			`def __init__(self, param=1, hidden_method=None):`
			`self.param = param`
			`self.hidden_method = hidden_method`

			`def fit(self, X, y=None, args, *kwargs):`
			`self.coef_ = np.arange(X.shape[1])`
			`self.classes_ = []`
			`return True`

			`def _check_fit(self):`
			`check_is_fitted(self)`

			`@hides`
			`def inverse_transform(self, X, args, *kwargs):`
			`self._check_fit()`
			`return X`

			`@hides`
			`def transform(self, X, args, *kwargs):`
			`self._check_fit()`
			`return X`

			`@hides`
			`def predict(self, X, args, *kwargs):`
			`self._check_fit()`
			`return np.ones(X.shape[0])`

			`@hides`
			`def predict_proba(self, X, args, *kwargs):`
			`self._check_fit()`
			`return np.ones(X.shape[0])`

			`@hides`
			`def predict_log_proba(self, X, args, *kwargs):`
			`self._check_fit()`
			`return np.ones(X.shape[0])`

			`@hides`
			`def decision_function(self, X, args, *kwargs):`
			`self._check_fit()`
			`return np.ones(X.shape[0])`

			`@hides`
			`def score(self, X, y, args, *kwargs):`
			`self._check_fit()`
			`return 1.0`

			`methods = [`
			`k`
			`for k in SubEstimator.__dict__.keys()`
			`if not k.startswith("_") and not k.startswith("fit")`
			`]`
			`methods.sort()`

			`for delegator_data in DELEGATING_METAESTIMATORS:`
			`delegate = SubEstimator()`
			`delegator = delegator_data.construct(delegate)`
			`for method in methods:`
			`if method in delegator_data.skip_methods:`
			`continue`
			`assert hasattr(delegate, method)`
			`assert hasattr(`
			`delegator, method`
			`), "%s does not have method %r when its delegate does" % (`
			`delegator_data.name,`
			`method,`
			`)`
			`# delegation before fit raises a NotFittedError`
			`if method == "score":`
			`with pytest.raises(NotFittedError):`
			`getattr(delegator, method)(`
			`delegator_data.fit_args[0], delegator_data.fit_args[1]`
			`)`
			`else:`
			`with pytest.raises(NotFittedError):`
			`getattr(delegator, method)(delegator_data.fit_args[0])`

			`delegator.fit(*delegator_data.fit_args)`
			`for method in methods:`
			`if method in delegator_data.skip_methods:`
			`continue`
			`# smoke test delegation`
			`if method == "score":`
			`getattr(delegator, method)(`
			`delegator_data.fit_args[0], delegator_data.fit_args[1]`
			`)`
			`else:`
			`getattr(delegator, method)(delegator_data.fit_args[0])`

			`for method in methods:`
			`if method in delegator_data.skip_methods:`
			`continue`
			`delegate = SubEstimator(hidden_method=method)`
			`delegator = delegator_data.construct(delegate)`
			`assert not hasattr(delegate, method)`
			`assert not hasattr(`
			`delegator, method`
			`), "%s has method %r when its delegate does not" % (`
			`delegator_data.name,`
			`method,`
			`)`


			`def _generate_meta_estimator_instances_with_pipeline():`
			`"""Generate instances of meta-estimators fed with a pipeline`

			`Are considered meta-estimators all estimators accepting one of "estimator",`
			`"base_estimator" or "estimators".`
			`"""`
			`for _, Estimator in sorted(all_estimators()):`
			`sig = set(signature(Estimator).parameters)`

			`if "estimator" in sig or "base_estimator" in sig or "regressor" in sig:`
			`if is_regressor(Estimator):`
			`estimator = make_pipeline(TfidfVectorizer(), Ridge())`
			`param_grid = {"ridge__alpha": [0.1, 1.0]}`
			`else:`
			`estimator = make_pipeline(TfidfVectorizer(), LogisticRegression())`
			`param_grid = {"logisticregression__C": [0.1, 1.0]}`

			`if "param_grid" in sig or "param_distributions" in sig:`
			`# SearchCV estimators`
			`extra_params = {"n_iter": 2} if "n_iter" in sig else {}`
			`yield Estimator(estimator, param_grid, **extra_params)`
			`else:`
			`yield Estimator(estimator)`

			`elif "transformer_list" in sig:`
			`# FeatureUnion`
			`transformer_list = [`
			`("trans1", make_pipeline(TfidfVectorizer(), MaxAbsScaler())),`
			`(`
			`"trans2",`
			`make_pipeline(TfidfVectorizer(), StandardScaler(with_mean=False)),`
			`),`
			`]`
			`yield Estimator(transformer_list)`

			`elif "estimators" in sig:`
			`# stacking, voting`
			`if is_regressor(Estimator):`
			`estimator = [`
			`("est1", make_pipeline(TfidfVectorizer(), Ridge(alpha=0.1))),`
			`("est2", make_pipeline(TfidfVectorizer(), Ridge(alpha=1))),`
			`]`
			`else:`
			`estimator = [`
			`(`
			`"est1",`
			`make_pipeline(TfidfVectorizer(), LogisticRegression(C=0.1)),`
			`),`
			`("est2", make_pipeline(TfidfVectorizer(), LogisticRegression(C=1))),`
			`]`
			`yield Estimator(estimator)`

			`else:`
			`continue`


			`# TODO: remove data validation for the following estimators`
			`# They should be able to work on any data and delegate data validation to`
			`# their inner estimator(s).`
			`DATA_VALIDATION_META_ESTIMATORS_TO_IGNORE = [`
			`"AdaBoostClassifier",`
			`"AdaBoostRegressor",`
			`"BaggingClassifier",`
			`"BaggingRegressor",`
			`"ClassifierChain", # data validation is necessary`
			`"IterativeImputer",`
			`"OneVsOneClassifier", # input validation can't be avoided`
			`"RANSACRegressor",`
			`"RFE",`
			`"RFECV",`
			`"RegressorChain", # data validation is necessary`
			`"SelfTrainingClassifier",`
			`"SequentialFeatureSelector", # not applicable (2D data mandatory)`
			`]`

			`DATA_VALIDATION_META_ESTIMATORS = [`
			`est`
			`for est in _generate_meta_estimator_instances_with_pipeline()`
			`if est.__class__.__name__ not in DATA_VALIDATION_META_ESTIMATORS_TO_IGNORE`
			`]`


			`def _get_meta_estimator_id(estimator):`
			`return estimator.__class__.__name__`


			`@pytest.mark.parametrize(`
			`"estimator", DATA_VALIDATION_META_ESTIMATORS, ids=_get_meta_estimator_id`
			`)`
			`def test_meta_estimators_delegate_data_validation(estimator):`
			`# Check that meta-estimators delegate data validation to the inner`
			`# estimator(s).`
			`rng = np.random.RandomState(0)`
			`set_random_state(estimator)`

			`n_samples = 30`
			`X = rng.choice(np.array(["aa", "bb", "cc"], dtype=object), size=n_samples)`

			`if is_regressor(estimator):`
			`y = rng.normal(size=n_samples)`
			`else:`
			`y = rng.randint(3, size=n_samples)`

			`# We convert to lists to make sure it works on array-like`
			`X = _enforce_estimator_tags_X(estimator, X).tolist()`
			`y = _enforce_estimator_tags_y(estimator, y).tolist()`

			`# Calling fit should not raise any data validation exception since X is a`
			`# valid input datastructure for the first step of the pipeline passed as`
			`# base estimator to the meta estimator.`
			`estimator.fit(X, y)`

			`# n_features_in_ should not be defined since data is not tabular data.`
			`assert not hasattr(estimator, "n_features_in_")`