Inzynierka/Lib/site-packages/sklearn/feature_selection/_from_model.py

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2023-06-02 12:51:02 +02:00
# Authors: Gilles Louppe, Mathieu Blondel, Maheshakya Wijewardena
# License: BSD 3 clause
from copy import deepcopy
import numpy as np
from numbers import Integral, Real
from ._base import SelectorMixin
from ._base import _get_feature_importances
from ..base import BaseEstimator, clone, MetaEstimatorMixin
from ..utils._tags import _safe_tags
from ..utils.validation import check_is_fitted, check_scalar, _num_features
from ..utils._param_validation import HasMethods, Interval, Options
from ..exceptions import NotFittedError
from ..utils.metaestimators import available_if
def _calculate_threshold(estimator, importances, threshold):
"""Interpret the threshold value"""
if threshold is None:
# determine default from estimator
est_name = estimator.__class__.__name__
is_l1_penalized = hasattr(estimator, "penalty") and estimator.penalty == "l1"
is_lasso = "Lasso" in est_name
is_elasticnet_l1_penalized = "ElasticNet" in est_name and (
(hasattr(estimator, "l1_ratio_") and np.isclose(estimator.l1_ratio_, 1.0))
or (hasattr(estimator, "l1_ratio") and np.isclose(estimator.l1_ratio, 1.0))
)
if is_l1_penalized or is_lasso or is_elasticnet_l1_penalized:
# the natural default threshold is 0 when l1 penalty was used
threshold = 1e-5
else:
threshold = "mean"
if isinstance(threshold, str):
if "*" in threshold:
scale, reference = threshold.split("*")
scale = float(scale.strip())
reference = reference.strip()
if reference == "median":
reference = np.median(importances)
elif reference == "mean":
reference = np.mean(importances)
else:
raise ValueError("Unknown reference: " + reference)
threshold = scale * reference
elif threshold == "median":
threshold = np.median(importances)
elif threshold == "mean":
threshold = np.mean(importances)
else:
raise ValueError(
"Expected threshold='mean' or threshold='median' got %s" % threshold
)
else:
threshold = float(threshold)
return threshold
def _estimator_has(attr):
"""Check if we can delegate a method to the underlying estimator.
First, we check the fitted estimator if available, otherwise we
check the unfitted estimator.
"""
return lambda self: (
hasattr(self.estimator_, attr)
if hasattr(self, "estimator_")
else hasattr(self.estimator, attr)
)
class SelectFromModel(MetaEstimatorMixin, SelectorMixin, BaseEstimator):
"""Meta-transformer for selecting features based on importance weights.
.. versionadded:: 0.17
Read more in the :ref:`User Guide <select_from_model>`.
Parameters
----------
estimator : object
The base estimator from which the transformer is built.
This can be both a fitted (if ``prefit`` is set to True)
or a non-fitted estimator. The estimator should have a
``feature_importances_`` or ``coef_`` attribute after fitting.
Otherwise, the ``importance_getter`` parameter should be used.
threshold : str or float, default=None
The threshold value to use for feature selection. Features whose
absolute importance value is greater or equal are kept while the others
are discarded. If "median" (resp. "mean"), then the ``threshold`` value
is the median (resp. the mean) of the feature importances. A scaling
factor (e.g., "1.25*mean") may also be used. If None and if the
estimator has a parameter penalty set to l1, either explicitly
or implicitly (e.g, Lasso), the threshold used is 1e-5.
Otherwise, "mean" is used by default.
prefit : bool, default=False
Whether a prefit model is expected to be passed into the constructor
directly or not.
If `True`, `estimator` must be a fitted estimator.
If `False`, `estimator` is fitted and updated by calling
`fit` and `partial_fit`, respectively.
norm_order : non-zero int, inf, -inf, default=1
Order of the norm used to filter the vectors of coefficients below
``threshold`` in the case where the ``coef_`` attribute of the
estimator is of dimension 2.
max_features : int, callable, default=None
The maximum number of features to select.
- If an integer, then it specifies the maximum number of features to
allow.
- If a callable, then it specifies how to calculate the maximum number of
features allowed by using the output of `max_features(X)`.
- If `None`, then all features are kept.
To only select based on ``max_features``, set ``threshold=-np.inf``.
.. versionadded:: 0.20
.. versionchanged:: 1.1
`max_features` accepts a callable.
importance_getter : str or callable, default='auto'
If 'auto', uses the feature importance either through a ``coef_``
attribute or ``feature_importances_`` attribute of estimator.
Also accepts a string that specifies an attribute name/path
for extracting feature importance (implemented with `attrgetter`).
For example, give `regressor_.coef_` in case of
:class:`~sklearn.compose.TransformedTargetRegressor` or
`named_steps.clf.feature_importances_` in case of
:class:`~sklearn.pipeline.Pipeline` with its last step named `clf`.
If `callable`, overrides the default feature importance getter.
The callable is passed with the fitted estimator and it should
return importance for each feature.
.. versionadded:: 0.24
Attributes
----------
estimator_ : estimator
The base estimator from which the transformer is built. This attribute
exist only when `fit` has been called.
- If `prefit=True`, it is a deep copy of `estimator`.
- If `prefit=False`, it is a clone of `estimator` and fit on the data
passed to `fit` or `partial_fit`.
n_features_in_ : int
Number of features seen during :term:`fit`. Only defined if the
underlying estimator exposes such an attribute when fit.
.. versionadded:: 0.24
max_features_ : int
Maximum number of features calculated during :term:`fit`. Only defined
if the ``max_features`` is not `None`.
- If `max_features` is an `int`, then `max_features_ = max_features`.
- If `max_features` is a callable, then `max_features_ = max_features(X)`.
.. versionadded:: 1.1
feature_names_in_ : ndarray of shape (`n_features_in_`,)
Names of features seen during :term:`fit`. Defined only when `X`
has feature names that are all strings.
.. versionadded:: 1.0
threshold_ : float
The threshold value used for feature selection.
See Also
--------
RFE : Recursive feature elimination based on importance weights.
RFECV : Recursive feature elimination with built-in cross-validated
selection of the best number of features.
SequentialFeatureSelector : Sequential cross-validation based feature
selection. Does not rely on importance weights.
Notes
-----
Allows NaN/Inf in the input if the underlying estimator does as well.
Examples
--------
>>> from sklearn.feature_selection import SelectFromModel
>>> from sklearn.linear_model import LogisticRegression
>>> X = [[ 0.87, -1.34, 0.31 ],
... [-2.79, -0.02, -0.85 ],
... [-1.34, -0.48, -2.55 ],
... [ 1.92, 1.48, 0.65 ]]
>>> y = [0, 1, 0, 1]
>>> selector = SelectFromModel(estimator=LogisticRegression()).fit(X, y)
>>> selector.estimator_.coef_
array([[-0.3252302 , 0.83462377, 0.49750423]])
>>> selector.threshold_
0.55245...
>>> selector.get_support()
array([False, True, False])
>>> selector.transform(X)
array([[-1.34],
[-0.02],
[-0.48],
[ 1.48]])
Using a callable to create a selector that can use no more than half
of the input features.
>>> def half_callable(X):
... return round(len(X[0]) / 2)
>>> half_selector = SelectFromModel(estimator=LogisticRegression(),
... max_features=half_callable)
>>> _ = half_selector.fit(X, y)
>>> half_selector.max_features_
2
"""
_parameter_constraints: dict = {
"estimator": [HasMethods("fit")],
"threshold": [Interval(Real, None, None, closed="both"), str, None],
"prefit": ["boolean"],
"norm_order": [
Interval(Integral, None, -1, closed="right"),
Interval(Integral, 1, None, closed="left"),
Options(Real, {np.inf, -np.inf}),
],
"max_features": [Interval(Integral, 0, None, closed="left"), callable, None],
"importance_getter": [str, callable],
}
def __init__(
self,
estimator,
*,
threshold=None,
prefit=False,
norm_order=1,
max_features=None,
importance_getter="auto",
):
self.estimator = estimator
self.threshold = threshold
self.prefit = prefit
self.importance_getter = importance_getter
self.norm_order = norm_order
self.max_features = max_features
def _get_support_mask(self):
estimator = getattr(self, "estimator_", self.estimator)
max_features = getattr(self, "max_features_", self.max_features)
if self.prefit:
try:
check_is_fitted(self.estimator)
except NotFittedError as exc:
raise NotFittedError(
"When `prefit=True`, `estimator` is expected to be a fitted "
"estimator."
) from exc
if callable(max_features):
# This branch is executed when `transform` is called directly and thus
# `max_features_` is not set and we fallback using `self.max_features`
# that is not validated
raise NotFittedError(
"When `prefit=True` and `max_features` is a callable, call `fit` "
"before calling `transform`."
)
elif max_features is not None and not isinstance(max_features, Integral):
raise ValueError(
f"`max_features` must be an integer. Got `max_features={max_features}` "
"instead."
)
scores = _get_feature_importances(
estimator=estimator,
getter=self.importance_getter,
transform_func="norm",
norm_order=self.norm_order,
)
threshold = _calculate_threshold(estimator, scores, self.threshold)
if self.max_features is not None:
mask = np.zeros_like(scores, dtype=bool)
candidate_indices = np.argsort(-scores, kind="mergesort")[:max_features]
mask[candidate_indices] = True
else:
mask = np.ones_like(scores, dtype=bool)
mask[scores < threshold] = False
return mask
def _check_max_features(self, X):
if self.max_features is not None:
n_features = _num_features(X)
if callable(self.max_features):
max_features = self.max_features(X)
else: # int
max_features = self.max_features
check_scalar(
max_features,
"max_features",
Integral,
min_val=0,
max_val=n_features,
)
self.max_features_ = max_features
def fit(self, X, y=None, **fit_params):
"""Fit the SelectFromModel meta-transformer.
Parameters
----------
X : array-like of shape (n_samples, n_features)
The training input samples.
y : array-like of shape (n_samples,), default=None
The target values (integers that correspond to classes in
classification, real numbers in regression).
**fit_params : dict
Other estimator specific parameters.
Returns
-------
self : object
Fitted estimator.
"""
self._validate_params()
self._check_max_features(X)
if self.prefit:
try:
check_is_fitted(self.estimator)
except NotFittedError as exc:
raise NotFittedError(
"When `prefit=True`, `estimator` is expected to be a fitted "
"estimator."
) from exc
self.estimator_ = deepcopy(self.estimator)
else:
self.estimator_ = clone(self.estimator)
self.estimator_.fit(X, y, **fit_params)
if hasattr(self.estimator_, "feature_names_in_"):
self.feature_names_in_ = self.estimator_.feature_names_in_
else:
self._check_feature_names(X, reset=True)
return self
@property
def threshold_(self):
"""Threshold value used for feature selection."""
scores = _get_feature_importances(
estimator=self.estimator_,
getter=self.importance_getter,
transform_func="norm",
norm_order=self.norm_order,
)
return _calculate_threshold(self.estimator, scores, self.threshold)
@available_if(_estimator_has("partial_fit"))
def partial_fit(self, X, y=None, **fit_params):
"""Fit the SelectFromModel meta-transformer only once.
Parameters
----------
X : array-like of shape (n_samples, n_features)
The training input samples.
y : array-like of shape (n_samples,), default=None
The target values (integers that correspond to classes in
classification, real numbers in regression).
**fit_params : dict
Other estimator specific parameters.
Returns
-------
self : object
Fitted estimator.
"""
first_call = not hasattr(self, "estimator_")
if first_call:
self._validate_params()
self._check_max_features(X)
if self.prefit:
if first_call:
try:
check_is_fitted(self.estimator)
except NotFittedError as exc:
raise NotFittedError(
"When `prefit=True`, `estimator` is expected to be a fitted "
"estimator."
) from exc
self.estimator_ = deepcopy(self.estimator)
return self
if first_call:
self.estimator_ = clone(self.estimator)
self.estimator_.partial_fit(X, y, **fit_params)
if hasattr(self.estimator_, "feature_names_in_"):
self.feature_names_in_ = self.estimator_.feature_names_in_
else:
self._check_feature_names(X, reset=first_call)
return self
@property
def n_features_in_(self):
"""Number of features seen during `fit`."""
# For consistency with other estimators we raise a AttributeError so
# that hasattr() fails if the estimator isn't fitted.
try:
check_is_fitted(self)
except NotFittedError as nfe:
raise AttributeError(
"{} object has no n_features_in_ attribute.".format(
self.__class__.__name__
)
) from nfe
return self.estimator_.n_features_in_
def _more_tags(self):
return {"allow_nan": _safe_tags(self.estimator, key="allow_nan")}