""" Test the ColumnTransformer. """ import pickle import re import warnings import numpy as np import pytest from numpy.testing import assert_allclose from scipy import sparse from sklearn.base import BaseEstimator, TransformerMixin from sklearn.compose import ( ColumnTransformer, make_column_selector, make_column_transformer, ) from sklearn.exceptions import NotFittedError from sklearn.feature_selection import VarianceThreshold from sklearn.preprocessing import ( FunctionTransformer, Normalizer, OneHotEncoder, StandardScaler, ) from sklearn.tests.metadata_routing_common import ( ConsumingTransformer, _Registry, check_recorded_metadata, ) from sklearn.utils._testing import ( _convert_container, assert_allclose_dense_sparse, assert_almost_equal, assert_array_equal, ) from sklearn.utils.fixes import CSR_CONTAINERS class Trans(TransformerMixin, BaseEstimator): def fit(self, X, y=None): return self def transform(self, X, y=None): # 1D Series -> 2D DataFrame if hasattr(X, "to_frame"): return X.to_frame() # 1D array -> 2D array if getattr(X, "ndim", 2) == 1: return np.atleast_2d(X).T return X class DoubleTrans(BaseEstimator): def fit(self, X, y=None): return self def transform(self, X): return 2 * X class SparseMatrixTrans(BaseEstimator): def __init__(self, csr_container): self.csr_container = csr_container def fit(self, X, y=None): return self def transform(self, X, y=None): n_samples = len(X) return self.csr_container(sparse.eye(n_samples, n_samples)) class TransNo2D(BaseEstimator): def fit(self, X, y=None): return self def transform(self, X, y=None): return X class TransRaise(BaseEstimator): def fit(self, X, y=None): raise ValueError("specific message") def transform(self, X, y=None): raise ValueError("specific message") def test_column_transformer(): X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_res_first1D = np.array([0, 1, 2]) X_res_second1D = np.array([2, 4, 6]) X_res_first = X_res_first1D.reshape(-1, 1) X_res_both = X_array cases = [ # single column 1D / 2D (0, X_res_first), ([0], X_res_first), # list-like ([0, 1], X_res_both), (np.array([0, 1]), X_res_both), # slice (slice(0, 1), X_res_first), (slice(0, 2), X_res_both), # boolean mask (np.array([True, False]), X_res_first), ([True, False], X_res_first), (np.array([True, True]), X_res_both), ([True, True], X_res_both), ] for selection, res in cases: ct = ColumnTransformer([("trans", Trans(), selection)], remainder="drop") assert_array_equal(ct.fit_transform(X_array), res) assert_array_equal(ct.fit(X_array).transform(X_array), res) # callable that returns any of the allowed specifiers ct = ColumnTransformer( [("trans", Trans(), lambda x: selection)], remainder="drop" ) assert_array_equal(ct.fit_transform(X_array), res) assert_array_equal(ct.fit(X_array).transform(X_array), res) ct = ColumnTransformer([("trans1", Trans(), [0]), ("trans2", Trans(), [1])]) assert_array_equal(ct.fit_transform(X_array), X_res_both) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_both) assert len(ct.transformers_) == 2 # test with transformer_weights transformer_weights = {"trans1": 0.1, "trans2": 10} both = ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", Trans(), [1])], transformer_weights=transformer_weights, ) res = np.vstack( [ transformer_weights["trans1"] * X_res_first1D, transformer_weights["trans2"] * X_res_second1D, ] ).T assert_array_equal(both.fit_transform(X_array), res) assert_array_equal(both.fit(X_array).transform(X_array), res) assert len(both.transformers_) == 2 both = ColumnTransformer( [("trans", Trans(), [0, 1])], transformer_weights={"trans": 0.1} ) assert_array_equal(both.fit_transform(X_array), 0.1 * X_res_both) assert_array_equal(both.fit(X_array).transform(X_array), 0.1 * X_res_both) assert len(both.transformers_) == 1 def test_column_transformer_tuple_transformers_parameter(): X_array = np.array([[0, 1, 2], [2, 4, 6]]).T transformers = [("trans1", Trans(), [0]), ("trans2", Trans(), [1])] ct_with_list = ColumnTransformer(transformers) ct_with_tuple = ColumnTransformer(tuple(transformers)) assert_array_equal( ct_with_list.fit_transform(X_array), ct_with_tuple.fit_transform(X_array) ) assert_array_equal( ct_with_list.fit(X_array).transform(X_array), ct_with_tuple.fit(X_array).transform(X_array), ) @pytest.mark.parametrize("constructor_name", ["dataframe", "polars"]) def test_column_transformer_dataframe(constructor_name): if constructor_name == "dataframe": dataframe_lib = pytest.importorskip("pandas") else: dataframe_lib = pytest.importorskip(constructor_name) X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_df = _convert_container( X_array, constructor_name, columns_name=["first", "second"] ) X_res_first = np.array([0, 1, 2]).reshape(-1, 1) X_res_both = X_array cases = [ # String keys: label based # list (["first"], X_res_first), (["first", "second"], X_res_both), # slice (slice("first", "second"), X_res_both), # int keys: positional # list ([0], X_res_first), ([0, 1], X_res_both), (np.array([0, 1]), X_res_both), # slice (slice(0, 1), X_res_first), (slice(0, 2), X_res_both), # boolean mask (np.array([True, False]), X_res_first), ([True, False], X_res_first), ] if constructor_name == "dataframe": # Scalars are only supported for pandas dataframes. cases.extend( [ # scalar (0, X_res_first), ("first", X_res_first), ( dataframe_lib.Series([True, False], index=["first", "second"]), X_res_first, ), ] ) for selection, res in cases: ct = ColumnTransformer([("trans", Trans(), selection)], remainder="drop") assert_array_equal(ct.fit_transform(X_df), res) assert_array_equal(ct.fit(X_df).transform(X_df), res) # callable that returns any of the allowed specifiers ct = ColumnTransformer( [("trans", Trans(), lambda X: selection)], remainder="drop" ) assert_array_equal(ct.fit_transform(X_df), res) assert_array_equal(ct.fit(X_df).transform(X_df), res) ct = ColumnTransformer( [("trans1", Trans(), ["first"]), ("trans2", Trans(), ["second"])] ) assert_array_equal(ct.fit_transform(X_df), X_res_both) assert_array_equal(ct.fit(X_df).transform(X_df), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] != "remainder" ct = ColumnTransformer([("trans1", Trans(), [0]), ("trans2", Trans(), [1])]) assert_array_equal(ct.fit_transform(X_df), X_res_both) assert_array_equal(ct.fit(X_df).transform(X_df), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] != "remainder" # test with transformer_weights transformer_weights = {"trans1": 0.1, "trans2": 10} both = ColumnTransformer( [("trans1", Trans(), ["first"]), ("trans2", Trans(), ["second"])], transformer_weights=transformer_weights, ) res = np.vstack( [ transformer_weights["trans1"] * X_df["first"], transformer_weights["trans2"] * X_df["second"], ] ).T assert_array_equal(both.fit_transform(X_df), res) assert_array_equal(both.fit(X_df).transform(X_df), res) assert len(both.transformers_) == 2 assert both.transformers_[-1][0] != "remainder" # test multiple columns both = ColumnTransformer( [("trans", Trans(), ["first", "second"])], transformer_weights={"trans": 0.1} ) assert_array_equal(both.fit_transform(X_df), 0.1 * X_res_both) assert_array_equal(both.fit(X_df).transform(X_df), 0.1 * X_res_both) assert len(both.transformers_) == 1 assert both.transformers_[-1][0] != "remainder" both = ColumnTransformer( [("trans", Trans(), [0, 1])], transformer_weights={"trans": 0.1} ) assert_array_equal(both.fit_transform(X_df), 0.1 * X_res_both) assert_array_equal(both.fit(X_df).transform(X_df), 0.1 * X_res_both) assert len(both.transformers_) == 1 assert both.transformers_[-1][0] != "remainder" # ensure pandas object is passed through class TransAssert(BaseEstimator): def __init__(self, expected_type_transform): self.expected_type_transform = expected_type_transform def fit(self, X, y=None): return self def transform(self, X, y=None): assert isinstance(X, self.expected_type_transform) if isinstance(X, dataframe_lib.Series): X = X.to_frame() return X ct = ColumnTransformer( [ ( "trans", TransAssert(expected_type_transform=dataframe_lib.DataFrame), ["first", "second"], ) ] ) ct.fit_transform(X_df) if constructor_name == "dataframe": # DataFrame protocol does not have 1d columns, so we only test on Pandas # dataframes. ct = ColumnTransformer( [ ( "trans", TransAssert(expected_type_transform=dataframe_lib.Series), "first", ) ], remainder="drop", ) ct.fit_transform(X_df) # Only test on pandas because the dataframe protocol requires string column # names # integer column spec + integer column names -> still use positional X_df2 = X_df.copy() X_df2.columns = [1, 0] ct = ColumnTransformer([("trans", Trans(), 0)], remainder="drop") assert_array_equal(ct.fit_transform(X_df2), X_res_first) assert_array_equal(ct.fit(X_df2).transform(X_df2), X_res_first) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert ct.transformers_[-1][1] == "drop" assert_array_equal(ct.transformers_[-1][2], [1]) @pytest.mark.parametrize("pandas", [True, False], ids=["pandas", "numpy"]) @pytest.mark.parametrize( "column_selection", [[], np.array([False, False]), [False, False]], ids=["list", "bool", "bool_int"], ) @pytest.mark.parametrize("callable_column", [False, True]) def test_column_transformer_empty_columns(pandas, column_selection, callable_column): # test case that ensures that the column transformer does also work when # a given transformer doesn't have any columns to work on X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_res_both = X_array if pandas: pd = pytest.importorskip("pandas") X = pd.DataFrame(X_array, columns=["first", "second"]) else: X = X_array if callable_column: column = lambda X: column_selection # noqa else: column = column_selection ct = ColumnTransformer( [("trans1", Trans(), [0, 1]), ("trans2", TransRaise(), column)] ) assert_array_equal(ct.fit_transform(X), X_res_both) assert_array_equal(ct.fit(X).transform(X), X_res_both) assert len(ct.transformers_) == 2 assert isinstance(ct.transformers_[1][1], TransRaise) ct = ColumnTransformer( [("trans1", TransRaise(), column), ("trans2", Trans(), [0, 1])] ) assert_array_equal(ct.fit_transform(X), X_res_both) assert_array_equal(ct.fit(X).transform(X), X_res_both) assert len(ct.transformers_) == 2 assert isinstance(ct.transformers_[0][1], TransRaise) ct = ColumnTransformer([("trans", TransRaise(), column)], remainder="passthrough") assert_array_equal(ct.fit_transform(X), X_res_both) assert_array_equal(ct.fit(X).transform(X), X_res_both) assert len(ct.transformers_) == 2 # including remainder assert isinstance(ct.transformers_[0][1], TransRaise) fixture = np.array([[], [], []]) ct = ColumnTransformer([("trans", TransRaise(), column)], remainder="drop") assert_array_equal(ct.fit_transform(X), fixture) assert_array_equal(ct.fit(X).transform(X), fixture) assert len(ct.transformers_) == 2 # including remainder assert isinstance(ct.transformers_[0][1], TransRaise) def test_column_transformer_output_indices(): # Checks for the output_indices_ attribute X_array = np.arange(6).reshape(3, 2) ct = ColumnTransformer([("trans1", Trans(), [0]), ("trans2", Trans(), [1])]) X_trans = ct.fit_transform(X_array) assert ct.output_indices_ == { "trans1": slice(0, 1), "trans2": slice(1, 2), "remainder": slice(0, 0), } assert_array_equal(X_trans[:, [0]], X_trans[:, ct.output_indices_["trans1"]]) assert_array_equal(X_trans[:, [1]], X_trans[:, ct.output_indices_["trans2"]]) # test with transformer_weights and multiple columns ct = ColumnTransformer( [("trans", Trans(), [0, 1])], transformer_weights={"trans": 0.1} ) X_trans = ct.fit_transform(X_array) assert ct.output_indices_ == {"trans": slice(0, 2), "remainder": slice(0, 0)} assert_array_equal(X_trans[:, [0, 1]], X_trans[:, ct.output_indices_["trans"]]) assert_array_equal(X_trans[:, []], X_trans[:, ct.output_indices_["remainder"]]) # test case that ensures that the attribute does also work when # a given transformer doesn't have any columns to work on ct = ColumnTransformer([("trans1", Trans(), [0, 1]), ("trans2", TransRaise(), [])]) X_trans = ct.fit_transform(X_array) assert ct.output_indices_ == { "trans1": slice(0, 2), "trans2": slice(0, 0), "remainder": slice(0, 0), } assert_array_equal(X_trans[:, [0, 1]], X_trans[:, ct.output_indices_["trans1"]]) assert_array_equal(X_trans[:, []], X_trans[:, ct.output_indices_["trans2"]]) assert_array_equal(X_trans[:, []], X_trans[:, ct.output_indices_["remainder"]]) ct = ColumnTransformer([("trans", TransRaise(), [])], remainder="passthrough") X_trans = ct.fit_transform(X_array) assert ct.output_indices_ == {"trans": slice(0, 0), "remainder": slice(0, 2)} assert_array_equal(X_trans[:, []], X_trans[:, ct.output_indices_["trans"]]) assert_array_equal(X_trans[:, [0, 1]], X_trans[:, ct.output_indices_["remainder"]]) def test_column_transformer_output_indices_df(): # Checks for the output_indices_ attribute with data frames pd = pytest.importorskip("pandas") X_df = pd.DataFrame(np.arange(6).reshape(3, 2), columns=["first", "second"]) ct = ColumnTransformer( [("trans1", Trans(), ["first"]), ("trans2", Trans(), ["second"])] ) X_trans = ct.fit_transform(X_df) assert ct.output_indices_ == { "trans1": slice(0, 1), "trans2": slice(1, 2), "remainder": slice(0, 0), } assert_array_equal(X_trans[:, [0]], X_trans[:, ct.output_indices_["trans1"]]) assert_array_equal(X_trans[:, [1]], X_trans[:, ct.output_indices_["trans2"]]) assert_array_equal(X_trans[:, []], X_trans[:, ct.output_indices_["remainder"]]) ct = ColumnTransformer([("trans1", Trans(), [0]), ("trans2", Trans(), [1])]) X_trans = ct.fit_transform(X_df) assert ct.output_indices_ == { "trans1": slice(0, 1), "trans2": slice(1, 2), "remainder": slice(0, 0), } assert_array_equal(X_trans[:, [0]], X_trans[:, ct.output_indices_["trans1"]]) assert_array_equal(X_trans[:, [1]], X_trans[:, ct.output_indices_["trans2"]]) assert_array_equal(X_trans[:, []], X_trans[:, ct.output_indices_["remainder"]]) @pytest.mark.parametrize("csr_container", CSR_CONTAINERS) def test_column_transformer_sparse_array(csr_container): X_sparse = csr_container(sparse.eye(3, 2)) # no distinction between 1D and 2D X_res_first = X_sparse[:, [0]] X_res_both = X_sparse for col in [(0,), [0], slice(0, 1)]: for remainder, res in [("drop", X_res_first), ("passthrough", X_res_both)]: ct = ColumnTransformer( [("trans", Trans(), col)], remainder=remainder, sparse_threshold=0.8 ) assert sparse.issparse(ct.fit_transform(X_sparse)) assert_allclose_dense_sparse(ct.fit_transform(X_sparse), res) assert_allclose_dense_sparse(ct.fit(X_sparse).transform(X_sparse), res) for col in [[0, 1], slice(0, 2)]: ct = ColumnTransformer([("trans", Trans(), col)], sparse_threshold=0.8) assert sparse.issparse(ct.fit_transform(X_sparse)) assert_allclose_dense_sparse(ct.fit_transform(X_sparse), X_res_both) assert_allclose_dense_sparse(ct.fit(X_sparse).transform(X_sparse), X_res_both) def test_column_transformer_list(): X_list = [[1, float("nan"), "a"], [0, 0, "b"]] expected_result = np.array( [ [1, float("nan"), 1, 0], [-1, 0, 0, 1], ] ) ct = ColumnTransformer( [ ("numerical", StandardScaler(), [0, 1]), ("categorical", OneHotEncoder(), [2]), ] ) assert_array_equal(ct.fit_transform(X_list), expected_result) assert_array_equal(ct.fit(X_list).transform(X_list), expected_result) @pytest.mark.parametrize("csr_container", CSR_CONTAINERS) def test_column_transformer_sparse_stacking(csr_container): X_array = np.array([[0, 1, 2], [2, 4, 6]]).T col_trans = ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", SparseMatrixTrans(csr_container), 1)], sparse_threshold=0.8, ) col_trans.fit(X_array) X_trans = col_trans.transform(X_array) assert sparse.issparse(X_trans) assert X_trans.shape == (X_trans.shape[0], X_trans.shape[0] + 1) assert_array_equal(X_trans.toarray()[:, 1:], np.eye(X_trans.shape[0])) assert len(col_trans.transformers_) == 2 assert col_trans.transformers_[-1][0] != "remainder" col_trans = ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", SparseMatrixTrans(csr_container), 1)], sparse_threshold=0.1, ) col_trans.fit(X_array) X_trans = col_trans.transform(X_array) assert not sparse.issparse(X_trans) assert X_trans.shape == (X_trans.shape[0], X_trans.shape[0] + 1) assert_array_equal(X_trans[:, 1:], np.eye(X_trans.shape[0])) def test_column_transformer_mixed_cols_sparse(): df = np.array([["a", 1, True], ["b", 2, False]], dtype="O") ct = make_column_transformer( (OneHotEncoder(), [0]), ("passthrough", [1, 2]), sparse_threshold=1.0 ) # this shouldn't fail, since boolean can be coerced into a numeric # See: https://github.com/scikit-learn/scikit-learn/issues/11912 X_trans = ct.fit_transform(df) assert X_trans.getformat() == "csr" assert_array_equal(X_trans.toarray(), np.array([[1, 0, 1, 1], [0, 1, 2, 0]])) ct = make_column_transformer( (OneHotEncoder(), [0]), ("passthrough", [0]), sparse_threshold=1.0 ) with pytest.raises(ValueError, match="For a sparse output, all columns should"): # this fails since strings `a` and `b` cannot be # coerced into a numeric. ct.fit_transform(df) def test_column_transformer_sparse_threshold(): X_array = np.array([["a", "b"], ["A", "B"]], dtype=object).T # above data has sparsity of 4 / 8 = 0.5 # apply threshold even if all sparse col_trans = ColumnTransformer( [("trans1", OneHotEncoder(), [0]), ("trans2", OneHotEncoder(), [1])], sparse_threshold=0.2, ) res = col_trans.fit_transform(X_array) assert not sparse.issparse(res) assert not col_trans.sparse_output_ # mixed -> sparsity of (4 + 2) / 8 = 0.75 for thres in [0.75001, 1]: col_trans = ColumnTransformer( [ ("trans1", OneHotEncoder(sparse_output=True), [0]), ("trans2", OneHotEncoder(sparse_output=False), [1]), ], sparse_threshold=thres, ) res = col_trans.fit_transform(X_array) assert sparse.issparse(res) assert col_trans.sparse_output_ for thres in [0.75, 0]: col_trans = ColumnTransformer( [ ("trans1", OneHotEncoder(sparse_output=True), [0]), ("trans2", OneHotEncoder(sparse_output=False), [1]), ], sparse_threshold=thres, ) res = col_trans.fit_transform(X_array) assert not sparse.issparse(res) assert not col_trans.sparse_output_ # if nothing is sparse -> no sparse for thres in [0.33, 0, 1]: col_trans = ColumnTransformer( [ ("trans1", OneHotEncoder(sparse_output=False), [0]), ("trans2", OneHotEncoder(sparse_output=False), [1]), ], sparse_threshold=thres, ) res = col_trans.fit_transform(X_array) assert not sparse.issparse(res) assert not col_trans.sparse_output_ def test_column_transformer_error_msg_1D(): X_array = np.array([[0.0, 1.0, 2.0], [2.0, 4.0, 6.0]]).T col_trans = ColumnTransformer([("trans", StandardScaler(), 0)]) msg = "1D data passed to a transformer" with pytest.raises(ValueError, match=msg): col_trans.fit(X_array) with pytest.raises(ValueError, match=msg): col_trans.fit_transform(X_array) col_trans = ColumnTransformer([("trans", TransRaise(), 0)]) for func in [col_trans.fit, col_trans.fit_transform]: with pytest.raises(ValueError, match="specific message"): func(X_array) def test_2D_transformer_output(): X_array = np.array([[0, 1, 2], [2, 4, 6]]).T # if one transformer is dropped, test that name is still correct ct = ColumnTransformer([("trans1", "drop", 0), ("trans2", TransNo2D(), 1)]) msg = "the 'trans2' transformer should be 2D" with pytest.raises(ValueError, match=msg): ct.fit_transform(X_array) # because fit is also doing transform, this raises already on fit with pytest.raises(ValueError, match=msg): ct.fit(X_array) def test_2D_transformer_output_pandas(): pd = pytest.importorskip("pandas") X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_df = pd.DataFrame(X_array, columns=["col1", "col2"]) # if one transformer is dropped, test that name is still correct ct = ColumnTransformer([("trans1", TransNo2D(), "col1")]) msg = "the 'trans1' transformer should be 2D" with pytest.raises(ValueError, match=msg): ct.fit_transform(X_df) # because fit is also doing transform, this raises already on fit with pytest.raises(ValueError, match=msg): ct.fit(X_df) @pytest.mark.parametrize("remainder", ["drop", "passthrough"]) def test_column_transformer_invalid_columns(remainder): X_array = np.array([[0, 1, 2], [2, 4, 6]]).T # general invalid for col in [1.5, ["string", 1], slice(1, "s"), np.array([1.0])]: ct = ColumnTransformer([("trans", Trans(), col)], remainder=remainder) with pytest.raises(ValueError, match="No valid specification"): ct.fit(X_array) # invalid for arrays for col in ["string", ["string", "other"], slice("a", "b")]: ct = ColumnTransformer([("trans", Trans(), col)], remainder=remainder) with pytest.raises(ValueError, match="Specifying the columns"): ct.fit(X_array) # transformed n_features does not match fitted n_features col = [0, 1] ct = ColumnTransformer([("trans", Trans(), col)], remainder=remainder) ct.fit(X_array) X_array_more = np.array([[0, 1, 2], [2, 4, 6], [3, 6, 9]]).T msg = "X has 3 features, but ColumnTransformer is expecting 2 features as input." with pytest.raises(ValueError, match=msg): ct.transform(X_array_more) X_array_fewer = np.array( [ [0, 1, 2], ] ).T err_msg = ( "X has 1 features, but ColumnTransformer is expecting 2 features as input." ) with pytest.raises(ValueError, match=err_msg): ct.transform(X_array_fewer) def test_column_transformer_invalid_transformer(): class NoTrans(BaseEstimator): def fit(self, X, y=None): return self def predict(self, X): return X X_array = np.array([[0, 1, 2], [2, 4, 6]]).T ct = ColumnTransformer([("trans", NoTrans(), [0])]) msg = "All estimators should implement fit and transform" with pytest.raises(TypeError, match=msg): ct.fit(X_array) def test_make_column_transformer(): scaler = StandardScaler() norm = Normalizer() ct = make_column_transformer((scaler, "first"), (norm, ["second"])) names, transformers, columns = zip(*ct.transformers) assert names == ("standardscaler", "normalizer") assert transformers == (scaler, norm) assert columns == ("first", ["second"]) def test_make_column_transformer_pandas(): pd = pytest.importorskip("pandas") X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_df = pd.DataFrame(X_array, columns=["first", "second"]) norm = Normalizer() ct1 = ColumnTransformer([("norm", Normalizer(), X_df.columns)]) ct2 = make_column_transformer((norm, X_df.columns)) assert_almost_equal(ct1.fit_transform(X_df), ct2.fit_transform(X_df)) def test_make_column_transformer_kwargs(): scaler = StandardScaler() norm = Normalizer() ct = make_column_transformer( (scaler, "first"), (norm, ["second"]), n_jobs=3, remainder="drop", sparse_threshold=0.5, ) assert ( ct.transformers == make_column_transformer((scaler, "first"), (norm, ["second"])).transformers ) assert ct.n_jobs == 3 assert ct.remainder == "drop" assert ct.sparse_threshold == 0.5 # invalid keyword parameters should raise an error message msg = re.escape( "make_column_transformer() got an unexpected " "keyword argument 'transformer_weights'" ) with pytest.raises(TypeError, match=msg): make_column_transformer( (scaler, "first"), (norm, ["second"]), transformer_weights={"pca": 10, "Transf": 1}, ) def test_make_column_transformer_remainder_transformer(): scaler = StandardScaler() norm = Normalizer() remainder = StandardScaler() ct = make_column_transformer( (scaler, "first"), (norm, ["second"]), remainder=remainder ) assert ct.remainder == remainder def test_column_transformer_get_set_params(): ct = ColumnTransformer( [("trans1", StandardScaler(), [0]), ("trans2", StandardScaler(), [1])] ) exp = { "n_jobs": None, "remainder": "drop", "sparse_threshold": 0.3, "trans1": ct.transformers[0][1], "trans1__copy": True, "trans1__with_mean": True, "trans1__with_std": True, "trans2": ct.transformers[1][1], "trans2__copy": True, "trans2__with_mean": True, "trans2__with_std": True, "transformers": ct.transformers, "transformer_weights": None, "verbose_feature_names_out": True, "verbose": False, } assert ct.get_params() == exp ct.set_params(trans1__with_mean=False) assert not ct.get_params()["trans1__with_mean"] ct.set_params(trans1="passthrough") exp = { "n_jobs": None, "remainder": "drop", "sparse_threshold": 0.3, "trans1": "passthrough", "trans2": ct.transformers[1][1], "trans2__copy": True, "trans2__with_mean": True, "trans2__with_std": True, "transformers": ct.transformers, "transformer_weights": None, "verbose_feature_names_out": True, "verbose": False, } assert ct.get_params() == exp def test_column_transformer_named_estimators(): X_array = np.array([[0.0, 1.0, 2.0], [2.0, 4.0, 6.0]]).T ct = ColumnTransformer( [ ("trans1", StandardScaler(), [0]), ("trans2", StandardScaler(with_std=False), [1]), ] ) assert not hasattr(ct, "transformers_") ct.fit(X_array) assert hasattr(ct, "transformers_") assert isinstance(ct.named_transformers_["trans1"], StandardScaler) assert isinstance(ct.named_transformers_.trans1, StandardScaler) assert isinstance(ct.named_transformers_["trans2"], StandardScaler) assert isinstance(ct.named_transformers_.trans2, StandardScaler) assert not ct.named_transformers_.trans2.with_std # check it are fitted transformers assert ct.named_transformers_.trans1.mean_ == 1.0 def test_column_transformer_cloning(): X_array = np.array([[0.0, 1.0, 2.0], [2.0, 4.0, 6.0]]).T ct = ColumnTransformer([("trans", StandardScaler(), [0])]) ct.fit(X_array) assert not hasattr(ct.transformers[0][1], "mean_") assert hasattr(ct.transformers_[0][1], "mean_") ct = ColumnTransformer([("trans", StandardScaler(), [0])]) ct.fit_transform(X_array) assert not hasattr(ct.transformers[0][1], "mean_") assert hasattr(ct.transformers_[0][1], "mean_") def test_column_transformer_get_feature_names(): X_array = np.array([[0.0, 1.0, 2.0], [2.0, 4.0, 6.0]]).T ct = ColumnTransformer([("trans", Trans(), [0, 1])]) # raise correct error when not fitted with pytest.raises(NotFittedError): ct.get_feature_names_out() # raise correct error when no feature names are available ct.fit(X_array) msg = re.escape( "Transformer trans (type Trans) does not provide get_feature_names_out" ) with pytest.raises(AttributeError, match=msg): ct.get_feature_names_out() def test_column_transformer_special_strings(): # one 'drop' -> ignore X_array = np.array([[0.0, 1.0, 2.0], [2.0, 4.0, 6.0]]).T ct = ColumnTransformer([("trans1", Trans(), [0]), ("trans2", "drop", [1])]) exp = np.array([[0.0], [1.0], [2.0]]) assert_array_equal(ct.fit_transform(X_array), exp) assert_array_equal(ct.fit(X_array).transform(X_array), exp) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] != "remainder" # all 'drop' -> return shape 0 array ct = ColumnTransformer([("trans1", "drop", [0]), ("trans2", "drop", [1])]) assert_array_equal(ct.fit(X_array).transform(X_array).shape, (3, 0)) assert_array_equal(ct.fit_transform(X_array).shape, (3, 0)) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] != "remainder" # 'passthrough' X_array = np.array([[0.0, 1.0, 2.0], [2.0, 4.0, 6.0]]).T ct = ColumnTransformer([("trans1", Trans(), [0]), ("trans2", "passthrough", [1])]) exp = X_array assert_array_equal(ct.fit_transform(X_array), exp) assert_array_equal(ct.fit(X_array).transform(X_array), exp) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] != "remainder" def test_column_transformer_remainder(): X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_res_first = np.array([0, 1, 2]).reshape(-1, 1) X_res_second = np.array([2, 4, 6]).reshape(-1, 1) X_res_both = X_array # default drop ct = ColumnTransformer([("trans1", Trans(), [0])]) assert_array_equal(ct.fit_transform(X_array), X_res_first) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_first) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert ct.transformers_[-1][1] == "drop" assert_array_equal(ct.transformers_[-1][2], [1]) # specify passthrough ct = ColumnTransformer([("trans", Trans(), [0])], remainder="passthrough") assert_array_equal(ct.fit_transform(X_array), X_res_both) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], FunctionTransformer) assert_array_equal(ct.transformers_[-1][2], [1]) # column order is not preserved (passed through added to end) ct = ColumnTransformer([("trans1", Trans(), [1])], remainder="passthrough") assert_array_equal(ct.fit_transform(X_array), X_res_both[:, ::-1]) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_both[:, ::-1]) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], FunctionTransformer) assert_array_equal(ct.transformers_[-1][2], [0]) # passthrough when all actual transformers are skipped ct = ColumnTransformer([("trans1", "drop", [0])], remainder="passthrough") assert_array_equal(ct.fit_transform(X_array), X_res_second) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_second) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], FunctionTransformer) assert_array_equal(ct.transformers_[-1][2], [1]) # check default for make_column_transformer ct = make_column_transformer((Trans(), [0])) assert ct.remainder == "drop" @pytest.mark.parametrize( "key", [[0], np.array([0]), slice(0, 1), np.array([True, False])] ) def test_column_transformer_remainder_numpy(key): # test different ways that columns are specified with passthrough X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_res_both = X_array ct = ColumnTransformer([("trans1", Trans(), key)], remainder="passthrough") assert_array_equal(ct.fit_transform(X_array), X_res_both) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], FunctionTransformer) assert_array_equal(ct.transformers_[-1][2], [1]) @pytest.mark.parametrize( "key", [ [0], slice(0, 1), np.array([True, False]), ["first"], "pd-index", np.array(["first"]), np.array(["first"], dtype=object), slice(None, "first"), slice("first", "first"), ], ) def test_column_transformer_remainder_pandas(key): # test different ways that columns are specified with passthrough pd = pytest.importorskip("pandas") if isinstance(key, str) and key == "pd-index": key = pd.Index(["first"]) X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_df = pd.DataFrame(X_array, columns=["first", "second"]) X_res_both = X_array ct = ColumnTransformer([("trans1", Trans(), key)], remainder="passthrough") assert_array_equal(ct.fit_transform(X_df), X_res_both) assert_array_equal(ct.fit(X_df).transform(X_df), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], FunctionTransformer) assert_array_equal(ct.transformers_[-1][2], [1]) @pytest.mark.parametrize( "key", [[0], np.array([0]), slice(0, 1), np.array([True, False, False])] ) def test_column_transformer_remainder_transformer(key): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).T X_res_both = X_array.copy() # second and third columns are doubled when remainder = DoubleTrans X_res_both[:, 1:3] *= 2 ct = ColumnTransformer([("trans1", Trans(), key)], remainder=DoubleTrans()) assert_array_equal(ct.fit_transform(X_array), X_res_both) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], DoubleTrans) assert_array_equal(ct.transformers_[-1][2], [1, 2]) def test_column_transformer_no_remaining_remainder_transformer(): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).T ct = ColumnTransformer([("trans1", Trans(), [0, 1, 2])], remainder=DoubleTrans()) assert_array_equal(ct.fit_transform(X_array), X_array) assert_array_equal(ct.fit(X_array).transform(X_array), X_array) assert len(ct.transformers_) == 1 assert ct.transformers_[-1][0] != "remainder" def test_column_transformer_drops_all_remainder_transformer(): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).T # columns are doubled when remainder = DoubleTrans X_res_both = 2 * X_array.copy()[:, 1:3] ct = ColumnTransformer([("trans1", "drop", [0])], remainder=DoubleTrans()) assert_array_equal(ct.fit_transform(X_array), X_res_both) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_both) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], DoubleTrans) assert_array_equal(ct.transformers_[-1][2], [1, 2]) @pytest.mark.parametrize("csr_container", CSR_CONTAINERS) def test_column_transformer_sparse_remainder_transformer(csr_container): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).T ct = ColumnTransformer( [("trans1", Trans(), [0])], remainder=SparseMatrixTrans(csr_container), sparse_threshold=0.8, ) X_trans = ct.fit_transform(X_array) assert sparse.issparse(X_trans) # SparseMatrixTrans creates 3 features for each column. There is # one column in ``transformers``, thus: assert X_trans.shape == (3, 3 + 1) exp_array = np.hstack((X_array[:, 0].reshape(-1, 1), np.eye(3))) assert_array_equal(X_trans.toarray(), exp_array) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], SparseMatrixTrans) assert_array_equal(ct.transformers_[-1][2], [1, 2]) @pytest.mark.parametrize("csr_container", CSR_CONTAINERS) def test_column_transformer_drop_all_sparse_remainder_transformer(csr_container): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).T ct = ColumnTransformer( [("trans1", "drop", [0])], remainder=SparseMatrixTrans(csr_container), sparse_threshold=0.8, ) X_trans = ct.fit_transform(X_array) assert sparse.issparse(X_trans) # SparseMatrixTrans creates 3 features for each column, thus: assert X_trans.shape == (3, 3) assert_array_equal(X_trans.toarray(), np.eye(3)) assert len(ct.transformers_) == 2 assert ct.transformers_[-1][0] == "remainder" assert isinstance(ct.transformers_[-1][1], SparseMatrixTrans) assert_array_equal(ct.transformers_[-1][2], [1, 2]) def test_column_transformer_get_set_params_with_remainder(): ct = ColumnTransformer( [("trans1", StandardScaler(), [0])], remainder=StandardScaler() ) exp = { "n_jobs": None, "remainder": ct.remainder, "remainder__copy": True, "remainder__with_mean": True, "remainder__with_std": True, "sparse_threshold": 0.3, "trans1": ct.transformers[0][1], "trans1__copy": True, "trans1__with_mean": True, "trans1__with_std": True, "transformers": ct.transformers, "transformer_weights": None, "verbose_feature_names_out": True, "verbose": False, } assert ct.get_params() == exp ct.set_params(remainder__with_std=False) assert not ct.get_params()["remainder__with_std"] ct.set_params(trans1="passthrough") exp = { "n_jobs": None, "remainder": ct.remainder, "remainder__copy": True, "remainder__with_mean": True, "remainder__with_std": False, "sparse_threshold": 0.3, "trans1": "passthrough", "transformers": ct.transformers, "transformer_weights": None, "verbose_feature_names_out": True, "verbose": False, } assert ct.get_params() == exp def test_column_transformer_no_estimators(): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).astype("float").T ct = ColumnTransformer([], remainder=StandardScaler()) params = ct.get_params() assert params["remainder__with_mean"] X_trans = ct.fit_transform(X_array) assert X_trans.shape == X_array.shape assert len(ct.transformers_) == 1 assert ct.transformers_[-1][0] == "remainder" assert ct.transformers_[-1][2] == [0, 1, 2] @pytest.mark.parametrize( ["est", "pattern"], [ ( ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", Trans(), [1])], remainder=DoubleTrans(), ), ( r"\[ColumnTransformer\].*\(1 of 3\) Processing trans1.* total=.*\n" r"\[ColumnTransformer\].*\(2 of 3\) Processing trans2.* total=.*\n" r"\[ColumnTransformer\].*\(3 of 3\) Processing remainder.* total=.*\n$" ), ), ( ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", Trans(), [1])], remainder="passthrough", ), ( r"\[ColumnTransformer\].*\(1 of 3\) Processing trans1.* total=.*\n" r"\[ColumnTransformer\].*\(2 of 3\) Processing trans2.* total=.*\n" r"\[ColumnTransformer\].*\(3 of 3\) Processing remainder.* total=.*\n$" ), ), ( ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", "drop", [1])], remainder="passthrough", ), ( r"\[ColumnTransformer\].*\(1 of 2\) Processing trans1.* total=.*\n" r"\[ColumnTransformer\].*\(2 of 2\) Processing remainder.* total=.*\n$" ), ), ( ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", "passthrough", [1])], remainder="passthrough", ), ( r"\[ColumnTransformer\].*\(1 of 3\) Processing trans1.* total=.*\n" r"\[ColumnTransformer\].*\(2 of 3\) Processing trans2.* total=.*\n" r"\[ColumnTransformer\].*\(3 of 3\) Processing remainder.* total=.*\n$" ), ), ( ColumnTransformer([("trans1", Trans(), [0])], remainder="passthrough"), ( r"\[ColumnTransformer\].*\(1 of 2\) Processing trans1.* total=.*\n" r"\[ColumnTransformer\].*\(2 of 2\) Processing remainder.* total=.*\n$" ), ), ( ColumnTransformer( [("trans1", Trans(), [0]), ("trans2", Trans(), [1])], remainder="drop" ), ( r"\[ColumnTransformer\].*\(1 of 2\) Processing trans1.* total=.*\n" r"\[ColumnTransformer\].*\(2 of 2\) Processing trans2.* total=.*\n$" ), ), ( ColumnTransformer([("trans1", Trans(), [0])], remainder="drop"), r"\[ColumnTransformer\].*\(1 of 1\) Processing trans1.* total=.*\n$", ), ], ) @pytest.mark.parametrize("method", ["fit", "fit_transform"]) def test_column_transformer_verbose(est, pattern, method, capsys): X_array = np.array([[0, 1, 2], [2, 4, 6], [8, 6, 4]]).T func = getattr(est, method) est.set_params(verbose=False) func(X_array) assert not capsys.readouterr().out, "Got output for verbose=False" est.set_params(verbose=True) func(X_array) assert re.match(pattern, capsys.readouterr()[0]) def test_column_transformer_no_estimators_set_params(): ct = ColumnTransformer([]).set_params(n_jobs=2) assert ct.n_jobs == 2 def test_column_transformer_callable_specifier(): # assert that function gets the full array X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_res_first = np.array([[0, 1, 2]]).T def func(X): assert_array_equal(X, X_array) return [0] ct = ColumnTransformer([("trans", Trans(), func)], remainder="drop") assert_array_equal(ct.fit_transform(X_array), X_res_first) assert_array_equal(ct.fit(X_array).transform(X_array), X_res_first) assert callable(ct.transformers[0][2]) assert ct.transformers_[0][2] == [0] def test_column_transformer_callable_specifier_dataframe(): # assert that function gets the full dataframe pd = pytest.importorskip("pandas") X_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_res_first = np.array([[0, 1, 2]]).T X_df = pd.DataFrame(X_array, columns=["first", "second"]) def func(X): assert_array_equal(X.columns, X_df.columns) assert_array_equal(X.values, X_df.values) return ["first"] ct = ColumnTransformer([("trans", Trans(), func)], remainder="drop") assert_array_equal(ct.fit_transform(X_df), X_res_first) assert_array_equal(ct.fit(X_df).transform(X_df), X_res_first) assert callable(ct.transformers[0][2]) assert ct.transformers_[0][2] == ["first"] def test_column_transformer_negative_column_indexes(): X = np.random.randn(2, 2) X_categories = np.array([[1], [2]]) X = np.concatenate([X, X_categories], axis=1) ohe = OneHotEncoder() tf_1 = ColumnTransformer([("ohe", ohe, [-1])], remainder="passthrough") tf_2 = ColumnTransformer([("ohe", ohe, [2])], remainder="passthrough") assert_array_equal(tf_1.fit_transform(X), tf_2.fit_transform(X)) @pytest.mark.parametrize("array_type", [np.asarray, *CSR_CONTAINERS]) def test_column_transformer_mask_indexing(array_type): # Regression test for #14510 # Boolean array-like does not behave as boolean array with sparse matrices. X = np.transpose([[1, 2, 3], [4, 5, 6], [5, 6, 7], [8, 9, 10]]) X = array_type(X) column_transformer = ColumnTransformer( [("identity", FunctionTransformer(), [False, True, False, True])] ) X_trans = column_transformer.fit_transform(X) assert X_trans.shape == (3, 2) def test_n_features_in(): # make sure n_features_in is what is passed as input to the column # transformer. X = [[1, 2], [3, 4], [5, 6]] ct = ColumnTransformer([("a", DoubleTrans(), [0]), ("b", DoubleTrans(), [1])]) assert not hasattr(ct, "n_features_in_") ct.fit(X) assert ct.n_features_in_ == 2 @pytest.mark.parametrize( "cols, pattern, include, exclude", [ (["col_int", "col_float"], None, np.number, None), (["col_int", "col_float"], None, None, object), (["col_int", "col_float"], None, [int, float], None), (["col_str"], None, [object], None), (["col_str"], None, object, None), (["col_float"], None, float, None), (["col_float"], "at$", [np.number], None), (["col_int"], None, [int], None), (["col_int"], "^col_int", [np.number], None), (["col_float", "col_str"], "float|str", None, None), (["col_str"], "^col_s", None, [int]), ([], "str$", float, None), (["col_int", "col_float", "col_str"], None, [np.number, object], None), ], ) def test_make_column_selector_with_select_dtypes(cols, pattern, include, exclude): pd = pytest.importorskip("pandas") X_df = pd.DataFrame( { "col_int": np.array([0, 1, 2], dtype=int), "col_float": np.array([0.0, 1.0, 2.0], dtype=float), "col_str": ["one", "two", "three"], }, columns=["col_int", "col_float", "col_str"], ) selector = make_column_selector( dtype_include=include, dtype_exclude=exclude, pattern=pattern ) assert_array_equal(selector(X_df), cols) def test_column_transformer_with_make_column_selector(): # Functional test for column transformer + column selector pd = pytest.importorskip("pandas") X_df = pd.DataFrame( { "col_int": np.array([0, 1, 2], dtype=int), "col_float": np.array([0.0, 1.0, 2.0], dtype=float), "col_cat": ["one", "two", "one"], "col_str": ["low", "middle", "high"], }, columns=["col_int", "col_float", "col_cat", "col_str"], ) X_df["col_str"] = X_df["col_str"].astype("category") cat_selector = make_column_selector(dtype_include=["category", object]) num_selector = make_column_selector(dtype_include=np.number) ohe = OneHotEncoder() scaler = StandardScaler() ct_selector = make_column_transformer((ohe, cat_selector), (scaler, num_selector)) ct_direct = make_column_transformer( (ohe, ["col_cat", "col_str"]), (scaler, ["col_float", "col_int"]) ) X_selector = ct_selector.fit_transform(X_df) X_direct = ct_direct.fit_transform(X_df) assert_allclose(X_selector, X_direct) def test_make_column_selector_error(): selector = make_column_selector(dtype_include=np.number) X = np.array([[0.1, 0.2]]) msg = "make_column_selector can only be applied to pandas dataframes" with pytest.raises(ValueError, match=msg): selector(X) def test_make_column_selector_pickle(): pd = pytest.importorskip("pandas") X_df = pd.DataFrame( { "col_int": np.array([0, 1, 2], dtype=int), "col_float": np.array([0.0, 1.0, 2.0], dtype=float), "col_str": ["one", "two", "three"], }, columns=["col_int", "col_float", "col_str"], ) selector = make_column_selector(dtype_include=[object]) selector_picked = pickle.loads(pickle.dumps(selector)) assert_array_equal(selector(X_df), selector_picked(X_df)) @pytest.mark.parametrize( "empty_col", [[], np.array([], dtype=int), lambda x: []], ids=["list", "array", "callable"], ) def test_feature_names_empty_columns(empty_col): pd = pytest.importorskip("pandas") df = pd.DataFrame({"col1": ["a", "a", "b"], "col2": ["z", "z", "z"]}) ct = ColumnTransformer( transformers=[ ("ohe", OneHotEncoder(), ["col1", "col2"]), ("empty_features", OneHotEncoder(), empty_col), ], ) ct.fit(df) assert_array_equal( ct.get_feature_names_out(), ["ohe__col1_a", "ohe__col1_b", "ohe__col2_z"] ) @pytest.mark.parametrize( "selector", [ [1], lambda x: [1], ["col2"], lambda x: ["col2"], [False, True], lambda x: [False, True], ], ) def test_feature_names_out_pandas(selector): """Checks name when selecting only the second column""" pd = pytest.importorskip("pandas") df = pd.DataFrame({"col1": ["a", "a", "b"], "col2": ["z", "z", "z"]}) ct = ColumnTransformer([("ohe", OneHotEncoder(), selector)]) ct.fit(df) assert_array_equal(ct.get_feature_names_out(), ["ohe__col2_z"]) @pytest.mark.parametrize( "selector", [[1], lambda x: [1], [False, True], lambda x: [False, True]] ) def test_feature_names_out_non_pandas(selector): """Checks name when selecting the second column with numpy array""" X = [["a", "z"], ["a", "z"], ["b", "z"]] ct = ColumnTransformer([("ohe", OneHotEncoder(), selector)]) ct.fit(X) assert_array_equal(ct.get_feature_names_out(), ["ohe__x1_z"]) @pytest.mark.parametrize("remainder", ["passthrough", StandardScaler()]) def test_sk_visual_block_remainder(remainder): # remainder='passthrough' or an estimator will be shown in repr_html ohe = OneHotEncoder() ct = ColumnTransformer( transformers=[("ohe", ohe, ["col1", "col2"])], remainder=remainder ) visual_block = ct._sk_visual_block_() assert visual_block.names == ("ohe", "remainder") assert visual_block.name_details == (["col1", "col2"], "") assert visual_block.estimators == (ohe, remainder) def test_sk_visual_block_remainder_drop(): # remainder='drop' is not shown in repr_html ohe = OneHotEncoder() ct = ColumnTransformer(transformers=[("ohe", ohe, ["col1", "col2"])]) visual_block = ct._sk_visual_block_() assert visual_block.names == ("ohe",) assert visual_block.name_details == (["col1", "col2"],) assert visual_block.estimators == (ohe,) @pytest.mark.parametrize("remainder", ["passthrough", StandardScaler()]) def test_sk_visual_block_remainder_fitted_pandas(remainder): # Remainder shows the columns after fitting pd = pytest.importorskip("pandas") ohe = OneHotEncoder() ct = ColumnTransformer( transformers=[("ohe", ohe, ["col1", "col2"])], remainder=remainder ) df = pd.DataFrame( { "col1": ["a", "b", "c"], "col2": ["z", "z", "z"], "col3": [1, 2, 3], "col4": [3, 4, 5], } ) ct.fit(df) visual_block = ct._sk_visual_block_() assert visual_block.names == ("ohe", "remainder") assert visual_block.name_details == (["col1", "col2"], ["col3", "col4"]) assert visual_block.estimators == (ohe, remainder) @pytest.mark.parametrize("remainder", ["passthrough", StandardScaler()]) def test_sk_visual_block_remainder_fitted_numpy(remainder): # Remainder shows the indices after fitting X = np.array([[1, 2, 3], [4, 5, 6]], dtype=float) scaler = StandardScaler() ct = ColumnTransformer( transformers=[("scale", scaler, [0, 2])], remainder=remainder ) ct.fit(X) visual_block = ct._sk_visual_block_() assert visual_block.names == ("scale", "remainder") assert visual_block.name_details == ([0, 2], [1]) assert visual_block.estimators == (scaler, remainder) @pytest.mark.parametrize("explicit_colname", ["first", "second", 0, 1]) @pytest.mark.parametrize("remainder", [Trans(), "passthrough", "drop"]) def test_column_transformer_reordered_column_names_remainder( explicit_colname, remainder ): """Test the interaction between remainder and column transformer""" pd = pytest.importorskip("pandas") X_fit_array = np.array([[0, 1, 2], [2, 4, 6]]).T X_fit_df = pd.DataFrame(X_fit_array, columns=["first", "second"]) X_trans_array = np.array([[2, 4, 6], [0, 1, 2]]).T X_trans_df = pd.DataFrame(X_trans_array, columns=["second", "first"]) tf = ColumnTransformer([("bycol", Trans(), explicit_colname)], remainder=remainder) tf.fit(X_fit_df) X_fit_trans = tf.transform(X_fit_df) # Changing the order still works X_trans = tf.transform(X_trans_df) assert_allclose(X_trans, X_fit_trans) # extra columns are ignored X_extended_df = X_fit_df.copy() X_extended_df["third"] = [3, 6, 9] X_trans = tf.transform(X_extended_df) assert_allclose(X_trans, X_fit_trans) if isinstance(explicit_colname, str): # Raise error if columns are specified by names but input only allows # to specify by position, e.g. numpy array instead of a pandas df. X_array = X_fit_array.copy() err_msg = "Specifying the columns" with pytest.raises(ValueError, match=err_msg): tf.transform(X_array) def test_feature_name_validation_missing_columns_drop_passthough(): """Test the interaction between {'drop', 'passthrough'} and missing column names.""" pd = pytest.importorskip("pandas") X = np.ones(shape=(3, 4)) df = pd.DataFrame(X, columns=["a", "b", "c", "d"]) df_dropped = df.drop("c", axis=1) # with remainder='passthrough', all columns seen during `fit` must be # present tf = ColumnTransformer([("bycol", Trans(), [1])], remainder="passthrough") tf.fit(df) msg = r"columns are missing: {'c'}" with pytest.raises(ValueError, match=msg): tf.transform(df_dropped) # with remainder='drop', it is allowed to have column 'c' missing tf = ColumnTransformer([("bycol", Trans(), [1])], remainder="drop") tf.fit(df) df_dropped_trans = tf.transform(df_dropped) df_fit_trans = tf.transform(df) assert_allclose(df_dropped_trans, df_fit_trans) # bycol drops 'c', thus it is allowed for 'c' to be missing tf = ColumnTransformer([("bycol", "drop", ["c"])], remainder="passthrough") tf.fit(df) df_dropped_trans = tf.transform(df_dropped) df_fit_trans = tf.transform(df) assert_allclose(df_dropped_trans, df_fit_trans) def test_feature_names_in_(): """Feature names are stored in column transformer. Column transformer deliberately does not check for column name consistency. It only checks that the non-dropped names seen in `fit` are seen in `transform`. This behavior is already tested in `test_feature_name_validation_missing_columns_drop_passthough`""" pd = pytest.importorskip("pandas") feature_names = ["a", "c", "d"] df = pd.DataFrame([[1, 2, 3]], columns=feature_names) ct = ColumnTransformer([("bycol", Trans(), ["a", "d"])], remainder="passthrough") ct.fit(df) assert_array_equal(ct.feature_names_in_, feature_names) assert isinstance(ct.feature_names_in_, np.ndarray) assert ct.feature_names_in_.dtype == object class TransWithNames(Trans): def __init__(self, feature_names_out=None): self.feature_names_out = feature_names_out def get_feature_names_out(self, input_features=None): if self.feature_names_out is not None: return np.asarray(self.feature_names_out, dtype=object) return input_features @pytest.mark.parametrize( "transformers, remainder, expected_names", [ ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", ["d"]), ], "passthrough", ["bycol1__d", "bycol1__c", "bycol2__d", "remainder__a", "remainder__b"], ), ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", ["d"]), ], "drop", ["bycol1__d", "bycol1__c", "bycol2__d"], ), ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "drop", ["d"]), ], "passthrough", ["bycol1__b", "remainder__a", "remainder__c"], ), ( [ ("bycol1", TransWithNames(["pca1", "pca2"]), ["a", "b", "d"]), ], "passthrough", ["bycol1__pca1", "bycol1__pca2", "remainder__c"], ), ( [ ("bycol1", TransWithNames(["a", "b"]), ["d"]), ("bycol2", "passthrough", ["b"]), ], "drop", ["bycol1__a", "bycol1__b", "bycol2__b"], ), ( [ ("bycol1", TransWithNames([f"pca{i}" for i in range(2)]), ["b"]), ("bycol2", TransWithNames([f"pca{i}" for i in range(2)]), ["b"]), ], "passthrough", [ "bycol1__pca0", "bycol1__pca1", "bycol2__pca0", "bycol2__pca1", "remainder__a", "remainder__c", "remainder__d", ], ), ( [ ("bycol1", "drop", ["d"]), ], "drop", [], ), ( [ ("bycol1", TransWithNames(), slice(1, 3)), ], "drop", ["bycol1__b", "bycol1__c"], ), ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "drop", slice(3, 4)), ], "passthrough", ["bycol1__b", "remainder__a", "remainder__c"], ), ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", slice(3, 4)), ], "passthrough", ["bycol1__d", "bycol1__c", "bycol2__d", "remainder__a", "remainder__b"], ), ( [ ("bycol1", TransWithNames(), slice("b", "c")), ], "drop", ["bycol1__b", "bycol1__c"], ), ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "drop", slice("c", "d")), ], "passthrough", ["bycol1__b", "remainder__a"], ), ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", slice("c", "d")), ], "passthrough", [ "bycol1__d", "bycol1__c", "bycol2__c", "bycol2__d", "remainder__a", "remainder__b", ], ), ], ) def test_verbose_feature_names_out_true(transformers, remainder, expected_names): """Check feature_names_out for verbose_feature_names_out=True (default)""" pd = pytest.importorskip("pandas") df = pd.DataFrame([[1, 2, 3, 4]], columns=["a", "b", "c", "d"]) ct = ColumnTransformer( transformers, remainder=remainder, ) ct.fit(df) names = ct.get_feature_names_out() assert isinstance(names, np.ndarray) assert names.dtype == object assert_array_equal(names, expected_names) @pytest.mark.parametrize( "transformers, remainder, expected_names", [ ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", ["a"]), ], "passthrough", ["d", "c", "a", "b"], ), ( [ ("bycol1", TransWithNames(["a"]), ["d", "c"]), ("bycol2", "passthrough", ["d"]), ], "drop", ["a", "d"], ), ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "drop", ["d"]), ], "passthrough", ["b", "a", "c"], ), ( [ ("bycol1", TransWithNames(["pca1", "pca2"]), ["a", "b", "d"]), ], "passthrough", ["pca1", "pca2", "c"], ), ( [ ("bycol1", TransWithNames(["a", "c"]), ["d"]), ("bycol2", "passthrough", ["d"]), ], "drop", ["a", "c", "d"], ), ( [ ("bycol1", TransWithNames([f"pca{i}" for i in range(2)]), ["b"]), ("bycol2", TransWithNames([f"kpca{i}" for i in range(2)]), ["b"]), ], "passthrough", ["pca0", "pca1", "kpca0", "kpca1", "a", "c", "d"], ), ( [ ("bycol1", "drop", ["d"]), ], "drop", [], ), ( [ ("bycol1", TransWithNames(), slice(1, 2)), ("bycol2", "drop", ["d"]), ], "passthrough", ["b", "a", "c"], ), ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "drop", slice(3, 4)), ], "passthrough", ["b", "a", "c"], ), ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", slice(0, 2)), ], "drop", ["d", "c", "a", "b"], ), ( [ ("bycol1", TransWithNames(), slice("a", "b")), ("bycol2", "drop", ["d"]), ], "passthrough", ["a", "b", "c"], ), ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "drop", slice("c", "d")), ], "passthrough", ["b", "a"], ), ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", slice("a", "b")), ], "drop", ["d", "c", "a", "b"], ), ( [ ("bycol1", TransWithNames(), ["d", "c"]), ("bycol2", "passthrough", slice("b", "b")), ], "drop", ["d", "c", "b"], ), ], ) def test_verbose_feature_names_out_false(transformers, remainder, expected_names): """Check feature_names_out for verbose_feature_names_out=False""" pd = pytest.importorskip("pandas") df = pd.DataFrame([[1, 2, 3, 4]], columns=["a", "b", "c", "d"]) ct = ColumnTransformer( transformers, remainder=remainder, verbose_feature_names_out=False, ) ct.fit(df) names = ct.get_feature_names_out() assert isinstance(names, np.ndarray) assert names.dtype == object assert_array_equal(names, expected_names) @pytest.mark.parametrize( "transformers, remainder, colliding_columns", [ ( [ ("bycol1", TransWithNames(), ["b"]), ("bycol2", "passthrough", ["b"]), ], "drop", "['b']", ), ( [ ("bycol1", TransWithNames(["c", "d"]), ["c"]), ("bycol2", "passthrough", ["c"]), ], "drop", "['c']", ), ( [ ("bycol1", TransWithNames(["a"]), ["b"]), ("bycol2", "passthrough", ["b"]), ], "passthrough", "['a']", ), ( [ ("bycol1", TransWithNames(["a"]), ["b"]), ("bycol2", "drop", ["b"]), ], "passthrough", "['a']", ), ( [ ("bycol1", TransWithNames(["c", "b"]), ["b"]), ("bycol2", "passthrough", ["c", "b"]), ], "drop", "['b', 'c']", ), ( [ ("bycol1", TransWithNames(["a"]), ["b"]), ("bycol2", "passthrough", ["a"]), ("bycol3", TransWithNames(["a"]), ["b"]), ], "passthrough", "['a']", ), ( [ ("bycol1", TransWithNames(["a", "b"]), ["b"]), ("bycol2", "passthrough", ["a"]), ("bycol3", TransWithNames(["b"]), ["c"]), ], "passthrough", "['a', 'b']", ), ( [ ("bycol1", TransWithNames([f"pca{i}" for i in range(6)]), ["b"]), ("bycol2", TransWithNames([f"pca{i}" for i in range(6)]), ["b"]), ], "passthrough", "['pca0', 'pca1', 'pca2', 'pca3', 'pca4', ...]", ), ( [ ("bycol1", TransWithNames(["a", "b"]), slice(1, 2)), ("bycol2", "passthrough", ["a"]), ("bycol3", TransWithNames(["b"]), ["c"]), ], "passthrough", "['a', 'b']", ), ( [ ("bycol1", TransWithNames(["a", "b"]), ["b"]), ("bycol2", "passthrough", slice(0, 1)), ("bycol3", TransWithNames(["b"]), ["c"]), ], "passthrough", "['a', 'b']", ), ( [ ("bycol1", TransWithNames(["a", "b"]), slice("b", "c")), ("bycol2", "passthrough", ["a"]), ("bycol3", TransWithNames(["b"]), ["c"]), ], "passthrough", "['a', 'b']", ), ( [ ("bycol1", TransWithNames(["a", "b"]), ["b"]), ("bycol2", "passthrough", slice("a", "a")), ("bycol3", TransWithNames(["b"]), ["c"]), ], "passthrough", "['a', 'b']", ), ], ) def test_verbose_feature_names_out_false_errors( transformers, remainder, colliding_columns ): """Check feature_names_out for verbose_feature_names_out=False""" pd = pytest.importorskip("pandas") df = pd.DataFrame([[1, 2, 3, 4]], columns=["a", "b", "c", "d"]) ct = ColumnTransformer( transformers, remainder=remainder, verbose_feature_names_out=False, ) ct.fit(df) msg = re.escape( f"Output feature names: {colliding_columns} are not unique. Please set " "verbose_feature_names_out=True to add prefixes to feature names" ) with pytest.raises(ValueError, match=msg): ct.get_feature_names_out() @pytest.mark.parametrize("verbose_feature_names_out", [True, False]) @pytest.mark.parametrize("remainder", ["drop", "passthrough"]) def test_column_transformer_set_output(verbose_feature_names_out, remainder): """Check column transformer behavior with set_output.""" pd = pytest.importorskip("pandas") df = pd.DataFrame([[1, 2, 3, 4]], columns=["a", "b", "c", "d"], index=[10]) ct = ColumnTransformer( [("first", TransWithNames(), ["a", "c"]), ("second", TransWithNames(), ["d"])], remainder=remainder, verbose_feature_names_out=verbose_feature_names_out, ) X_trans = ct.fit_transform(df) assert isinstance(X_trans, np.ndarray) ct.set_output(transform="pandas") df_test = pd.DataFrame([[1, 2, 3, 4]], columns=df.columns, index=[20]) X_trans = ct.transform(df_test) assert isinstance(X_trans, pd.DataFrame) feature_names_out = ct.get_feature_names_out() assert_array_equal(X_trans.columns, feature_names_out) assert_array_equal(X_trans.index, df_test.index) @pytest.mark.parametrize("remainder", ["drop", "passthrough"]) @pytest.mark.parametrize("fit_transform", [True, False]) def test_column_transform_set_output_mixed(remainder, fit_transform): """Check ColumnTransformer outputs mixed types correctly.""" pd = pytest.importorskip("pandas") df = pd.DataFrame( { "pet": pd.Series(["dog", "cat", "snake"], dtype="category"), "color": pd.Series(["green", "blue", "red"], dtype="object"), "age": [1.4, 2.1, 4.4], "height": [20, 40, 10], "distance": pd.Series([20, pd.NA, 100], dtype="Int32"), } ) ct = ColumnTransformer( [ ( "color_encode", OneHotEncoder(sparse_output=False, dtype="int8"), ["color"], ), ("age", StandardScaler(), ["age"]), ], remainder=remainder, verbose_feature_names_out=False, ).set_output(transform="pandas") if fit_transform: X_trans = ct.fit_transform(df) else: X_trans = ct.fit(df).transform(df) assert isinstance(X_trans, pd.DataFrame) assert_array_equal(X_trans.columns, ct.get_feature_names_out()) expected_dtypes = { "color_blue": "int8", "color_green": "int8", "color_red": "int8", "age": "float64", "pet": "category", "height": "int64", "distance": "Int32", } for col, dtype in X_trans.dtypes.items(): assert dtype == expected_dtypes[col] @pytest.mark.parametrize("remainder", ["drop", "passthrough"]) def test_column_transform_set_output_after_fitting(remainder): pd = pytest.importorskip("pandas") df = pd.DataFrame( { "pet": pd.Series(["dog", "cat", "snake"], dtype="category"), "age": [1.4, 2.1, 4.4], "height": [20, 40, 10], } ) ct = ColumnTransformer( [ ( "color_encode", OneHotEncoder(sparse_output=False, dtype="int16"), ["pet"], ), ("age", StandardScaler(), ["age"]), ], remainder=remainder, verbose_feature_names_out=False, ) # fit without calling set_output X_trans = ct.fit_transform(df) assert isinstance(X_trans, np.ndarray) assert X_trans.dtype == "float64" ct.set_output(transform="pandas") X_trans_df = ct.transform(df) expected_dtypes = { "pet_cat": "int16", "pet_dog": "int16", "pet_snake": "int16", "height": "int64", "age": "float64", } for col, dtype in X_trans_df.dtypes.items(): assert dtype == expected_dtypes[col] # PandasOutTransformer that does not define get_feature_names_out and always expects # the input to be a DataFrame. class PandasOutTransformer(BaseEstimator): def __init__(self, offset=1.0): self.offset = offset def fit(self, X, y=None): pd = pytest.importorskip("pandas") assert isinstance(X, pd.DataFrame) return self def transform(self, X, y=None): pd = pytest.importorskip("pandas") assert isinstance(X, pd.DataFrame) return X - self.offset def set_output(self, transform=None): # This transformer will always output a DataFrame regardless of the # configuration. return self @pytest.mark.parametrize( "trans_1, expected_verbose_names, expected_non_verbose_names", [ ( PandasOutTransformer(offset=2.0), ["trans_0__feat1", "trans_1__feat0"], ["feat1", "feat0"], ), ( "drop", ["trans_0__feat1"], ["feat1"], ), ( "passthrough", ["trans_0__feat1", "trans_1__feat0"], ["feat1", "feat0"], ), ], ) def test_transformers_with_pandas_out_but_not_feature_names_out( trans_1, expected_verbose_names, expected_non_verbose_names ): """Check that set_config(transform="pandas") is compatible with more transformers. Specifically, if transformers returns a DataFrame, but does not define `get_feature_names_out`. """ pd = pytest.importorskip("pandas") X_df = pd.DataFrame({"feat0": [1.0, 2.0, 3.0], "feat1": [2.0, 3.0, 4.0]}) ct = ColumnTransformer( [ ("trans_0", PandasOutTransformer(offset=3.0), ["feat1"]), ("trans_1", trans_1, ["feat0"]), ] ) X_trans_np = ct.fit_transform(X_df) assert isinstance(X_trans_np, np.ndarray) # `ct` does not have `get_feature_names_out` because `PandasOutTransformer` does # not define the method. with pytest.raises(AttributeError, match="not provide get_feature_names_out"): ct.get_feature_names_out() # The feature names are prefixed because verbose_feature_names_out=True is default ct.set_output(transform="pandas") X_trans_df0 = ct.fit_transform(X_df) assert_array_equal(X_trans_df0.columns, expected_verbose_names) ct.set_params(verbose_feature_names_out=False) X_trans_df1 = ct.fit_transform(X_df) assert_array_equal(X_trans_df1.columns, expected_non_verbose_names) @pytest.mark.parametrize( "empty_selection", [[], np.array([False, False]), [False, False]], ids=["list", "bool", "bool_int"], ) def test_empty_selection_pandas_output(empty_selection): """Check that pandas output works when there is an empty selection. Non-regression test for gh-25487 """ pd = pytest.importorskip("pandas") X = pd.DataFrame([[1.0, 2.2], [3.0, 1.0]], columns=["a", "b"]) ct = ColumnTransformer( [ ("categorical", "passthrough", empty_selection), ("numerical", StandardScaler(), ["a", "b"]), ], verbose_feature_names_out=True, ) ct.set_output(transform="pandas") X_out = ct.fit_transform(X) assert_array_equal(X_out.columns, ["numerical__a", "numerical__b"]) ct.set_params(verbose_feature_names_out=False) X_out = ct.fit_transform(X) assert_array_equal(X_out.columns, ["a", "b"]) def test_raise_error_if_index_not_aligned(): """Check column transformer raises error if indices are not aligned. Non-regression test for gh-26210. """ pd = pytest.importorskip("pandas") X = pd.DataFrame([[1.0, 2.2], [3.0, 1.0]], columns=["a", "b"], index=[8, 3]) reset_index_transformer = FunctionTransformer( lambda x: x.reset_index(drop=True), feature_names_out="one-to-one" ) ct = ColumnTransformer( [ ("num1", "passthrough", ["a"]), ("num2", reset_index_transformer, ["b"]), ], ) ct.set_output(transform="pandas") msg = ( "Concatenating DataFrames from the transformer's output lead to" " an inconsistent number of samples. The output may have Pandas" " Indexes that do not match." ) with pytest.raises(ValueError, match=msg): ct.fit_transform(X) def test_remainder_set_output(): """Check that the output is set for the remainder. Non-regression test for #26306. """ pd = pytest.importorskip("pandas") df = pd.DataFrame({"a": [True, False, True], "b": [1, 2, 3]}) ct = make_column_transformer( (VarianceThreshold(), make_column_selector(dtype_include=bool)), remainder=VarianceThreshold(), verbose_feature_names_out=False, ) ct.set_output(transform="pandas") out = ct.fit_transform(df) pd.testing.assert_frame_equal(out, df) ct.set_output(transform="default") out = ct.fit_transform(df) assert isinstance(out, np.ndarray) # TODO(1.6): replace the warning by a ValueError exception def test_transform_pd_na(): """Check behavior when a tranformer's output contains pandas.NA It should emit a warning unless the output config is set to 'pandas'. """ pd = pytest.importorskip("pandas") if not hasattr(pd, "Float64Dtype"): pytest.skip( "The issue with pd.NA tested here does not happen in old versions that do" " not have the extension dtypes" ) df = pd.DataFrame({"a": [1.5, None]}) ct = make_column_transformer(("passthrough", ["a"])) # No warning with non-extension dtypes and np.nan with warnings.catch_warnings(): warnings.simplefilter("error") ct.fit_transform(df) df = df.convert_dtypes() # Error with extension dtype and pd.NA with pytest.warns(FutureWarning, match=r"set_output\(transform='pandas'\)"): ct.fit_transform(df) # No warning when output is set to pandas with warnings.catch_warnings(): warnings.simplefilter("error") ct.set_output(transform="pandas") ct.fit_transform(df) ct.set_output(transform="default") # No warning when there are no pd.NA with warnings.catch_warnings(): warnings.simplefilter("error") ct.fit_transform(df.fillna(-1.0)) def test_dataframe_different_dataframe_libraries(): """Check fitting and transforming on pandas and polars dataframes.""" pd = pytest.importorskip("pandas") pl = pytest.importorskip("polars") X_train_np = np.array([[0, 1], [2, 4], [4, 5]]) X_test_np = np.array([[1, 2], [1, 3], [2, 3]]) # Fit on pandas and transform on polars X_train_pd = pd.DataFrame(X_train_np, columns=["a", "b"]) X_test_pl = pl.DataFrame(X_test_np, schema=["a", "b"]) ct = make_column_transformer((Trans(), [0, 1])) ct.fit(X_train_pd) out_pl_in = ct.transform(X_test_pl) assert_array_equal(out_pl_in, X_test_np) # Fit on polars and transform on pandas X_train_pl = pl.DataFrame(X_train_np, schema=["a", "b"]) X_test_pd = pd.DataFrame(X_test_np, columns=["a", "b"]) ct.fit(X_train_pl) out_pd_in = ct.transform(X_test_pd) assert_array_equal(out_pd_in, X_test_np) @pytest.mark.parametrize("transform_output", ["default", "pandas"]) def test_column_transformer_remainder_passthrough_naming_consistency(transform_output): """Check that when `remainder="passthrough"`, inconsistent naming is handled correctly by the underlying `FunctionTransformer`. Non-regression test for: https://github.com/scikit-learn/scikit-learn/issues/28232 """ pd = pytest.importorskip("pandas") X = pd.DataFrame(np.random.randn(10, 4)) preprocessor = ColumnTransformer( transformers=[("scaler", StandardScaler(), [0, 1])], remainder="passthrough", ).set_output(transform=transform_output) X_trans = preprocessor.fit_transform(X) assert X_trans.shape == X.shape expected_column_names = [ "scaler__x0", "scaler__x1", "remainder__x2", "remainder__x3", ] if hasattr(X_trans, "columns"): assert X_trans.columns.tolist() == expected_column_names assert preprocessor.get_feature_names_out().tolist() == expected_column_names @pytest.mark.parametrize("dataframe_lib", ["pandas", "polars"]) def test_column_transformer_column_renaming(dataframe_lib): """Check that we properly rename columns when using `ColumnTransformer` and selected columns are redundant between transformers. Non-regression test for: https://github.com/scikit-learn/scikit-learn/issues/28260 """ lib = pytest.importorskip(dataframe_lib) df = lib.DataFrame({"x1": [1, 2, 3], "x2": [10, 20, 30], "x3": [100, 200, 300]}) transformer = ColumnTransformer( transformers=[ ("A", "passthrough", ["x1", "x2", "x3"]), ("B", FunctionTransformer(), ["x1", "x2"]), ("C", StandardScaler(), ["x1", "x3"]), # special case of empty transformer ("D", FunctionTransformer(lambda x: x[[]]), ["x1", "x2", "x3"]), ], verbose_feature_names_out=True, ).set_output(transform=dataframe_lib) df_trans = transformer.fit_transform(df) assert list(df_trans.columns) == [ "A__x1", "A__x2", "A__x3", "B__x1", "B__x2", "C__x1", "C__x3", ] @pytest.mark.parametrize("dataframe_lib", ["pandas", "polars"]) def test_column_transformer_error_with_duplicated_columns(dataframe_lib): """Check that we raise an error when using `ColumnTransformer` and the columns names are duplicated between transformers.""" lib = pytest.importorskip(dataframe_lib) df = lib.DataFrame({"x1": [1, 2, 3], "x2": [10, 20, 30], "x3": [100, 200, 300]}) transformer = ColumnTransformer( transformers=[ ("A", "passthrough", ["x1", "x2", "x3"]), ("B", FunctionTransformer(), ["x1", "x2"]), ("C", StandardScaler(), ["x1", "x3"]), # special case of empty transformer ("D", FunctionTransformer(lambda x: x[[]]), ["x1", "x2", "x3"]), ], verbose_feature_names_out=False, ).set_output(transform=dataframe_lib) err_msg = re.escape( "Duplicated feature names found before concatenating the outputs of the " "transformers: ['x1', 'x2', 'x3'].\n" "Transformer A has conflicting columns names: ['x1', 'x2', 'x3'].\n" "Transformer B has conflicting columns names: ['x1', 'x2'].\n" "Transformer C has conflicting columns names: ['x1', 'x3'].\n" ) with pytest.raises(ValueError, match=err_msg): transformer.fit_transform(df) # Metadata Routing Tests # ====================== @pytest.mark.parametrize("method", ["transform", "fit_transform", "fit"]) def test_routing_passed_metadata_not_supported(method): """Test that the right error message is raised when metadata is passed while not supported when `enable_metadata_routing=False`.""" X = np.array([[0, 1, 2], [2, 4, 6]]).T y = [1, 2, 3] trs = ColumnTransformer([("trans", Trans(), [0])]).fit(X, y) with pytest.raises( ValueError, match="is only supported if enable_metadata_routing=True" ): getattr(trs, method)([[1]], sample_weight=[1], prop="a") @pytest.mark.usefixtures("enable_slep006") @pytest.mark.parametrize("method", ["transform", "fit_transform", "fit"]) def test_metadata_routing_for_column_transformer(method): """Test that metadata is routed correctly for column transformer.""" X = np.array([[0, 1, 2], [2, 4, 6]]).T y = [1, 2, 3] registry = _Registry() sample_weight, metadata = [1], "a" trs = ColumnTransformer( [ ( "trans", ConsumingTransformer(registry=registry) .set_fit_request(sample_weight=True, metadata=True) .set_transform_request(sample_weight=True, metadata=True), [0], ) ] ) if method == "transform": trs.fit(X, y) trs.transform(X, sample_weight=sample_weight, metadata=metadata) else: getattr(trs, method)(X, y, sample_weight=sample_weight, metadata=metadata) assert len(registry) for _trs in registry: check_recorded_metadata( obj=_trs, method=method, sample_weight=sample_weight, metadata=metadata ) @pytest.mark.usefixtures("enable_slep006") def test_metadata_routing_no_fit_transform(): """Test metadata routing when the sub-estimator doesn't implement ``fit_transform``.""" class NoFitTransform(BaseEstimator): def fit(self, X, y=None, sample_weight=None, metadata=None): assert sample_weight assert metadata return self def transform(self, X, sample_weight=None, metadata=None): assert sample_weight assert metadata return X X = np.array([[0, 1, 2], [2, 4, 6]]).T y = [1, 2, 3] _Registry() sample_weight, metadata = [1], "a" trs = ColumnTransformer( [ ( "trans", NoFitTransform() .set_fit_request(sample_weight=True, metadata=True) .set_transform_request(sample_weight=True, metadata=True), [0], ) ] ) trs.fit(X, y, sample_weight=sample_weight, metadata=metadata) trs.fit_transform(X, y, sample_weight=sample_weight, metadata=metadata) @pytest.mark.usefixtures("enable_slep006") @pytest.mark.parametrize("method", ["transform", "fit_transform", "fit"]) def test_metadata_routing_error_for_column_transformer(method): """Test that the right error is raised when metadata is not requested.""" X = np.array([[0, 1, 2], [2, 4, 6]]).T y = [1, 2, 3] sample_weight, metadata = [1], "a" trs = ColumnTransformer([("trans", ConsumingTransformer(), [0])]) error_message = ( "[sample_weight, metadata] are passed but are not explicitly set as requested" f" or not for ConsumingTransformer.{method}" ) with pytest.raises(ValueError, match=re.escape(error_message)): if method == "transform": trs.fit(X, y) trs.transform(X, sample_weight=sample_weight, metadata=metadata) else: getattr(trs, method)(X, y, sample_weight=sample_weight, metadata=metadata) @pytest.mark.usefixtures("enable_slep006") def test_get_metadata_routing_works_without_fit(): # Regression test for https://github.com/scikit-learn/scikit-learn/issues/28186 # Make sure ct.get_metadata_routing() works w/o having called fit. ct = ColumnTransformer([("trans", ConsumingTransformer(), [0])]) ct.get_metadata_routing() @pytest.mark.usefixtures("enable_slep006") def test_remainder_request_always_present(): # Test that remainder request is always present. ct = ColumnTransformer( [("trans", StandardScaler(), [0])], remainder=ConsumingTransformer() .set_fit_request(metadata=True) .set_transform_request(metadata=True), ) router = ct.get_metadata_routing() assert router.consumes("fit", ["metadata"]) == set(["metadata"]) @pytest.mark.usefixtures("enable_slep006") def test_unused_transformer_request_present(): # Test that the request of a transformer is always present even when not # used due to no selected columns. ct = ColumnTransformer( [ ( "trans", ConsumingTransformer() .set_fit_request(metadata=True) .set_transform_request(metadata=True), lambda X: [], ) ] ) router = ct.get_metadata_routing() assert router.consumes("fit", ["metadata"]) == set(["metadata"]) # End of Metadata Routing Tests # =============================