projektAI/venv/Lib/site-packages/sklearn/preprocessing/tests/test_common.py

import warnings

import pytest
import numpy as np

from scipy import sparse

from sklearn.datasets import load_iris
from sklearn.model_selection import train_test_split

from sklearn.base import clone

from sklearn.preprocessing import maxabs_scale
from sklearn.preprocessing import minmax_scale
from sklearn.preprocessing import scale
from sklearn.preprocessing import power_transform
from sklearn.preprocessing import quantile_transform
from sklearn.preprocessing import robust_scale

from sklearn.preprocessing import MaxAbsScaler
from sklearn.preprocessing import MinMaxScaler
from sklearn.preprocessing import StandardScaler
from sklearn.preprocessing import PowerTransformer
from sklearn.preprocessing import QuantileTransformer
from sklearn.preprocessing import RobustScaler

from sklearn.utils._testing import assert_array_equal
from sklearn.utils._testing import assert_allclose

iris = load_iris()


def _get_valid_samples_by_column(X, col):
    """Get non NaN samples in column of X"""
    return X[:, [col]][~np.isnan(X[:, col])]


@pytest.mark.parametrize(
    "est, func, support_sparse, strictly_positive, omit_kwargs",
    [(MaxAbsScaler(), maxabs_scale, True, False, []),
     (MinMaxScaler(), minmax_scale, False, False, ['clip']),
     (StandardScaler(), scale, False, False, []),
     (StandardScaler(with_mean=False), scale, True, False, []),
     (PowerTransformer('yeo-johnson'), power_transform, False, False, []),
     (PowerTransformer('box-cox'), power_transform, False, True, []),
     (QuantileTransformer(n_quantiles=10), quantile_transform, True, False,
     []),
     (RobustScaler(), robust_scale, False, False, []),
     (RobustScaler(with_centering=False), robust_scale, True, False, [])]
)
def test_missing_value_handling(est, func, support_sparse, strictly_positive,
                                omit_kwargs):
    # check that the preprocessing method let pass nan
    rng = np.random.RandomState(42)
    X = iris.data.copy()
    n_missing = 50
    X[rng.randint(X.shape[0], size=n_missing),
      rng.randint(X.shape[1], size=n_missing)] = np.nan
    if strictly_positive:
        X += np.nanmin(X) + 0.1
    X_train, X_test = train_test_split(X, random_state=1)
    # sanity check
    assert not np.all(np.isnan(X_train), axis=0).any()
    assert np.any(np.isnan(X_train), axis=0).all()
    assert np.any(np.isnan(X_test), axis=0).all()
    X_test[:, 0] = np.nan  # make sure this boundary case is tested

    with pytest.warns(None) as records:
        Xt = est.fit(X_train).transform(X_test)
    # ensure no warnings are raised
    assert len(records) == 0
    # missing values should still be missing, and only them
    assert_array_equal(np.isnan(Xt), np.isnan(X_test))

    # check that the function leads to the same results as the class
    with pytest.warns(None) as records:
        Xt_class = est.transform(X_train)
    assert len(records) == 0
    kwargs = est.get_params()
    # remove the parameters which should be omitted because they
    # are not defined in the sister function of the preprocessing class
    for kwarg in omit_kwargs:
        _ = kwargs.pop(kwarg)
    Xt_func = func(X_train, **kwargs)
    assert_array_equal(np.isnan(Xt_func), np.isnan(Xt_class))
    assert_allclose(Xt_func[~np.isnan(Xt_func)], Xt_class[~np.isnan(Xt_class)])

    # check that the inverse transform keep NaN
    Xt_inv = est.inverse_transform(Xt)
    assert_array_equal(np.isnan(Xt_inv), np.isnan(X_test))
    # FIXME: we can introduce equal_nan=True in recent version of numpy.
    # For the moment which just check that non-NaN values are almost equal.
    assert_allclose(Xt_inv[~np.isnan(Xt_inv)], X_test[~np.isnan(X_test)])

    for i in range(X.shape[1]):
        # train only on non-NaN
        est.fit(_get_valid_samples_by_column(X_train, i))
        # check transforming with NaN works even when training without NaN
        with pytest.warns(None) as records:
            Xt_col = est.transform(X_test[:, [i]])
        assert len(records) == 0
        assert_allclose(Xt_col, Xt[:, [i]])
        # check non-NaN is handled as before - the 1st column is all nan
        if not np.isnan(X_test[:, i]).all():
            Xt_col_nonan = est.transform(
                _get_valid_samples_by_column(X_test, i))
            assert_array_equal(Xt_col_nonan,
                               Xt_col[~np.isnan(Xt_col.squeeze())])

    if support_sparse:
        est_dense = clone(est)
        est_sparse = clone(est)

        with pytest.warns(None) as records:
            Xt_dense = est_dense.fit(X_train).transform(X_test)
            Xt_inv_dense = est_dense.inverse_transform(Xt_dense)
        assert len(records) == 0
        for sparse_constructor in (sparse.csr_matrix, sparse.csc_matrix,
                                   sparse.bsr_matrix, sparse.coo_matrix,
                                   sparse.dia_matrix, sparse.dok_matrix,
                                   sparse.lil_matrix):
            # check that the dense and sparse inputs lead to the same results
            # precompute the matrix to avoid catching side warnings
            X_train_sp = sparse_constructor(X_train)
            X_test_sp = sparse_constructor(X_test)
            with pytest.warns(None) as records:
                warnings.simplefilter('ignore', PendingDeprecationWarning)
                Xt_sp = est_sparse.fit(X_train_sp).transform(X_test_sp)
            assert len(records) == 0
            assert_allclose(Xt_sp.A, Xt_dense)
            with pytest.warns(None) as records:
                warnings.simplefilter('ignore', PendingDeprecationWarning)
                Xt_inv_sp = est_sparse.inverse_transform(Xt_sp)
            assert len(records) == 0
            assert_allclose(Xt_inv_sp.A, Xt_inv_dense)


@pytest.mark.parametrize(
    "est, func",
    [(MaxAbsScaler(), maxabs_scale),
     (MinMaxScaler(), minmax_scale),
     (StandardScaler(), scale),
     (StandardScaler(with_mean=False), scale),
     (PowerTransformer('yeo-johnson'), power_transform),
     (PowerTransformer('box-cox'), power_transform,),
     (QuantileTransformer(n_quantiles=3), quantile_transform),
     (RobustScaler(), robust_scale),
     (RobustScaler(with_centering=False), robust_scale)]
)
def test_missing_value_pandas_na_support(est, func):
    # Test pandas IntegerArray with pd.NA
    pd = pytest.importorskip('pandas', minversion="1.0")

    X = np.array([[1, 2, 3, np.nan, np.nan, 4, 5, 1],
                  [np.nan, np.nan, 8, 4, 6, np.nan, np.nan, 8],
                  [1, 2, 3, 4, 5, 6, 7, 8]]).T

    # Creates dataframe with IntegerArrays with pd.NA
    X_df = pd.DataFrame(X, dtype="Int16", columns=['a', 'b', 'c'])
    X_df['c'] = X_df['c'].astype('int')

    X_trans = est.fit_transform(X)
    X_df_trans = est.fit_transform(X_df)

    assert_allclose(X_trans, X_df_trans)
Działa 2021-06-06 22:13:05 +02:00			`import warnings`

			`import pytest`
			`import numpy as np`

			`from scipy import sparse`

			`from sklearn.datasets import load_iris`
			`from sklearn.model_selection import train_test_split`

			`from sklearn.base import clone`

			`from sklearn.preprocessing import maxabs_scale`
			`from sklearn.preprocessing import minmax_scale`
			`from sklearn.preprocessing import scale`
			`from sklearn.preprocessing import power_transform`
			`from sklearn.preprocessing import quantile_transform`
			`from sklearn.preprocessing import robust_scale`

			`from sklearn.preprocessing import MaxAbsScaler`
			`from sklearn.preprocessing import MinMaxScaler`
			`from sklearn.preprocessing import StandardScaler`
			`from sklearn.preprocessing import PowerTransformer`
			`from sklearn.preprocessing import QuantileTransformer`
			`from sklearn.preprocessing import RobustScaler`

			`from sklearn.utils._testing import assert_array_equal`
			`from sklearn.utils._testing import assert_allclose`

			`iris = load_iris()`


			`def _get_valid_samples_by_column(X, col):`
			`"""Get non NaN samples in column of X"""`
			`return X[:, [col]][~np.isnan(X[:, col])]`


			`@pytest.mark.parametrize(`
			`"est, func, support_sparse, strictly_positive, omit_kwargs",`
			`[(MaxAbsScaler(), maxabs_scale, True, False, []),`
			`(MinMaxScaler(), minmax_scale, False, False, ['clip']),`
			`(StandardScaler(), scale, False, False, []),`
			`(StandardScaler(with_mean=False), scale, True, False, []),`
			`(PowerTransformer('yeo-johnson'), power_transform, False, False, []),`
			`(PowerTransformer('box-cox'), power_transform, False, True, []),`
			`(QuantileTransformer(n_quantiles=10), quantile_transform, True, False,`
			`[]),`
			`(RobustScaler(), robust_scale, False, False, []),`
			`(RobustScaler(with_centering=False), robust_scale, True, False, [])]`
			`)`
			`def test_missing_value_handling(est, func, support_sparse, strictly_positive,`
			`omit_kwargs):`
			`# check that the preprocessing method let pass nan`
			`rng = np.random.RandomState(42)`
			`X = iris.data.copy()`
			`n_missing = 50`
			`X[rng.randint(X.shape[0], size=n_missing),`
			`rng.randint(X.shape[1], size=n_missing)] = np.nan`
			`if strictly_positive:`
			`X += np.nanmin(X) + 0.1`
			`X_train, X_test = train_test_split(X, random_state=1)`
			`# sanity check`
			`assert not np.all(np.isnan(X_train), axis=0).any()`
			`assert np.any(np.isnan(X_train), axis=0).all()`
			`assert np.any(np.isnan(X_test), axis=0).all()`
			`X_test[:, 0] = np.nan # make sure this boundary case is tested`

			`with pytest.warns(None) as records:`
			`Xt = est.fit(X_train).transform(X_test)`
			`# ensure no warnings are raised`
			`assert len(records) == 0`
			`# missing values should still be missing, and only them`
			`assert_array_equal(np.isnan(Xt), np.isnan(X_test))`

			`# check that the function leads to the same results as the class`
			`with pytest.warns(None) as records:`
			`Xt_class = est.transform(X_train)`
			`assert len(records) == 0`
			`kwargs = est.get_params()`
			`# remove the parameters which should be omitted because they`
			`# are not defined in the sister function of the preprocessing class`
			`for kwarg in omit_kwargs:`
			`_ = kwargs.pop(kwarg)`
			`Xt_func = func(X_train, **kwargs)`
			`assert_array_equal(np.isnan(Xt_func), np.isnan(Xt_class))`
			`assert_allclose(Xt_func[~np.isnan(Xt_func)], Xt_class[~np.isnan(Xt_class)])`

			`# check that the inverse transform keep NaN`
			`Xt_inv = est.inverse_transform(Xt)`
			`assert_array_equal(np.isnan(Xt_inv), np.isnan(X_test))`
			`# FIXME: we can introduce equal_nan=True in recent version of numpy.`
			`# For the moment which just check that non-NaN values are almost equal.`
			`assert_allclose(Xt_inv[~np.isnan(Xt_inv)], X_test[~np.isnan(X_test)])`

			`for i in range(X.shape[1]):`
			`# train only on non-NaN`
			`est.fit(_get_valid_samples_by_column(X_train, i))`
			`# check transforming with NaN works even when training without NaN`
			`with pytest.warns(None) as records:`
			`Xt_col = est.transform(X_test[:, [i]])`
			`assert len(records) == 0`
			`assert_allclose(Xt_col, Xt[:, [i]])`
			`# check non-NaN is handled as before - the 1st column is all nan`
			`if not np.isnan(X_test[:, i]).all():`
			`Xt_col_nonan = est.transform(`
			`_get_valid_samples_by_column(X_test, i))`
			`assert_array_equal(Xt_col_nonan,`
			`Xt_col[~np.isnan(Xt_col.squeeze())])`

			`if support_sparse:`
			`est_dense = clone(est)`
			`est_sparse = clone(est)`

			`with pytest.warns(None) as records:`
			`Xt_dense = est_dense.fit(X_train).transform(X_test)`
			`Xt_inv_dense = est_dense.inverse_transform(Xt_dense)`
			`assert len(records) == 0`
			`for sparse_constructor in (sparse.csr_matrix, sparse.csc_matrix,`
			`sparse.bsr_matrix, sparse.coo_matrix,`
			`sparse.dia_matrix, sparse.dok_matrix,`
			`sparse.lil_matrix):`
			`# check that the dense and sparse inputs lead to the same results`
			`# precompute the matrix to avoid catching side warnings`
			`X_train_sp = sparse_constructor(X_train)`
			`X_test_sp = sparse_constructor(X_test)`
			`with pytest.warns(None) as records:`
			`warnings.simplefilter('ignore', PendingDeprecationWarning)`
			`Xt_sp = est_sparse.fit(X_train_sp).transform(X_test_sp)`
			`assert len(records) == 0`
			`assert_allclose(Xt_sp.A, Xt_dense)`
			`with pytest.warns(None) as records:`
			`warnings.simplefilter('ignore', PendingDeprecationWarning)`
			`Xt_inv_sp = est_sparse.inverse_transform(Xt_sp)`
			`assert len(records) == 0`
			`assert_allclose(Xt_inv_sp.A, Xt_inv_dense)`


			`@pytest.mark.parametrize(`
			`"est, func",`
			`[(MaxAbsScaler(), maxabs_scale),`
			`(MinMaxScaler(), minmax_scale),`
			`(StandardScaler(), scale),`
			`(StandardScaler(with_mean=False), scale),`
			`(PowerTransformer('yeo-johnson'), power_transform),`
			`(PowerTransformer('box-cox'), power_transform,),`
			`(QuantileTransformer(n_quantiles=3), quantile_transform),`
			`(RobustScaler(), robust_scale),`
			`(RobustScaler(with_centering=False), robust_scale)]`
			`)`
			`def test_missing_value_pandas_na_support(est, func):`
			`# Test pandas IntegerArray with pd.NA`
			`pd = pytest.importorskip('pandas', minversion="1.0")`

			`X = np.array([[1, 2, 3, np.nan, np.nan, 4, 5, 1],`
			`[np.nan, np.nan, 8, 4, 6, np.nan, np.nan, 8],`
			`[1, 2, 3, 4, 5, 6, 7, 8]]).T`

			`# Creates dataframe with IntegerArrays with pd.NA`
			`X_df = pd.DataFrame(X, dtype="Int16", columns=['a', 'b', 'c'])`
			`X_df['c'] = X_df['c'].astype('int')`

			`X_trans = est.fit_transform(X)`
			`X_df_trans = est.fit_transform(X_df)`

			`assert_allclose(X_trans, X_df_trans)`