Intelegentny_Pszczelarz/.venv/Lib/site-packages/sklearn/utils/metaestimators.py

"""Utilities for meta-estimators"""
# Author: Joel Nothman
#         Andreas Mueller
# License: BSD
from typing import List, Any
import warnings

from abc import ABCMeta, abstractmethod
from operator import attrgetter
import numpy as np
from contextlib import suppress

from ..utils import _safe_indexing
from ..utils._tags import _safe_tags
from ..base import BaseEstimator
from ._available_if import available_if, _AvailableIfDescriptor

__all__ = ["available_if", "if_delegate_has_method"]


class _BaseComposition(BaseEstimator, metaclass=ABCMeta):
    """Handles parameter management for classifiers composed of named estimators."""

    steps: List[Any]

    @abstractmethod
    def __init__(self):
        pass

    def _get_params(self, attr, deep=True):
        out = super().get_params(deep=deep)
        if not deep:
            return out

        estimators = getattr(self, attr)
        try:
            out.update(estimators)
        except (TypeError, ValueError):
            # Ignore TypeError for cases where estimators is not a list of
            # (name, estimator) and ignore ValueError when the list is not
            # formatted correctly. This is to prevent errors when calling
            # `set_params`. `BaseEstimator.set_params` calls `get_params` which
            # can error for invalid values for `estimators`.
            return out

        for name, estimator in estimators:
            if hasattr(estimator, "get_params"):
                for key, value in estimator.get_params(deep=True).items():
                    out["%s__%s" % (name, key)] = value
        return out

    def _set_params(self, attr, **params):
        # Ensure strict ordering of parameter setting:
        # 1. All steps
        if attr in params:
            setattr(self, attr, params.pop(attr))
        # 2. Replace items with estimators in params
        items = getattr(self, attr)
        if isinstance(items, list) and items:
            # Get item names used to identify valid names in params
            # `zip` raises a TypeError when `items` does not contains
            # elements of length 2
            with suppress(TypeError):
                item_names, _ = zip(*items)
                for name in list(params.keys()):
                    if "__" not in name and name in item_names:
                        self._replace_estimator(attr, name, params.pop(name))

        # 3. Step parameters and other initialisation arguments
        super().set_params(**params)
        return self

    def _replace_estimator(self, attr, name, new_val):
        # assumes `name` is a valid estimator name
        new_estimators = list(getattr(self, attr))
        for i, (estimator_name, _) in enumerate(new_estimators):
            if estimator_name == name:
                new_estimators[i] = (name, new_val)
                break
        setattr(self, attr, new_estimators)

    def _validate_names(self, names):
        if len(set(names)) != len(names):
            raise ValueError("Names provided are not unique: {0!r}".format(list(names)))
        invalid_names = set(names).intersection(self.get_params(deep=False))
        if invalid_names:
            raise ValueError(
                "Estimator names conflict with constructor arguments: {0!r}".format(
                    sorted(invalid_names)
                )
            )
        invalid_names = [name for name in names if "__" in name]
        if invalid_names:
            raise ValueError(
                "Estimator names must not contain __: got {0!r}".format(invalid_names)
            )


# TODO(1.3) remove
class _IffHasAttrDescriptor(_AvailableIfDescriptor):
    """Implements a conditional property using the descriptor protocol.

    Using this class to create a decorator will raise an ``AttributeError``
    if none of the delegates (specified in ``delegate_names``) is an attribute
    of the base object or the first found delegate does not have an attribute
    ``attribute_name``.

    This allows ducktyping of the decorated method based on
    ``delegate.attribute_name``. Here ``delegate`` is the first item in
    ``delegate_names`` for which ``hasattr(object, delegate) is True``.

    See https://docs.python.org/3/howto/descriptor.html for an explanation of
    descriptors.
    """

    def __init__(self, fn, delegate_names, attribute_name):
        super().__init__(fn, self._check, attribute_name)
        self.delegate_names = delegate_names

    def _check(self, obj):
        warnings.warn(
            "if_delegate_has_method was deprecated in version 1.1 and will be "
            "removed in version 1.3. Use available_if instead.",
            FutureWarning,
        )

        delegate = None
        for delegate_name in self.delegate_names:
            try:
                delegate = attrgetter(delegate_name)(obj)
                break
            except AttributeError:
                continue

        if delegate is None:
            return False
        # raise original AttributeError
        getattr(delegate, self.attribute_name)

        return True


# TODO(1.3) remove
def if_delegate_has_method(delegate):
    """Create a decorator for methods that are delegated to a sub-estimator.

    .. deprecated:: 1.3
        `if_delegate_has_method` is deprecated in version 1.1 and will be removed in
        version 1.3. Use `available_if` instead.

    This enables ducktyping by hasattr returning True according to the
    sub-estimator.

    Parameters
    ----------
    delegate : str, list of str or tuple of str
        Name of the sub-estimator that can be accessed as an attribute of the
        base object. If a list or a tuple of names are provided, the first
        sub-estimator that is an attribute of the base object will be used.

    Returns
    -------
    callable
        Callable makes the decorated method available if the delegate
        has a method with the same name as the decorated method.
    """
    if isinstance(delegate, list):
        delegate = tuple(delegate)
    if not isinstance(delegate, tuple):
        delegate = (delegate,)

    return lambda fn: _IffHasAttrDescriptor(fn, delegate, attribute_name=fn.__name__)


def _safe_split(estimator, X, y, indices, train_indices=None):
    """Create subset of dataset and properly handle kernels.

    Slice X, y according to indices for cross-validation, but take care of
    precomputed kernel-matrices or pairwise affinities / distances.

    If ``estimator._pairwise is True``, X needs to be square and
    we slice rows and columns. If ``train_indices`` is not None,
    we slice rows using ``indices`` (assumed the test set) and columns
    using ``train_indices``, indicating the training set.

    Labels y will always be indexed only along the first axis.

    Parameters
    ----------
    estimator : object
        Estimator to determine whether we should slice only rows or rows and
        columns.

    X : array-like, sparse matrix or iterable
        Data to be indexed. If ``estimator._pairwise is True``,
        this needs to be a square array-like or sparse matrix.

    y : array-like, sparse matrix or iterable
        Targets to be indexed.

    indices : array of int
        Rows to select from X and y.
        If ``estimator._pairwise is True`` and ``train_indices is None``
        then ``indices`` will also be used to slice columns.

    train_indices : array of int or None, default=None
        If ``estimator._pairwise is True`` and ``train_indices is not None``,
        then ``train_indices`` will be use to slice the columns of X.

    Returns
    -------
    X_subset : array-like, sparse matrix or list
        Indexed data.

    y_subset : array-like, sparse matrix or list
        Indexed targets.

    """
    if _safe_tags(estimator, key="pairwise"):
        if not hasattr(X, "shape"):
            raise ValueError(
                "Precomputed kernels or affinity matrices have "
                "to be passed as arrays or sparse matrices."
            )
        # X is a precomputed square kernel matrix
        if X.shape[0] != X.shape[1]:
            raise ValueError("X should be a square kernel matrix")
        if train_indices is None:
            X_subset = X[np.ix_(indices, indices)]
        else:
            X_subset = X[np.ix_(indices, train_indices)]
    else:
        X_subset = _safe_indexing(X, indices)

    if y is not None:
        y_subset = _safe_indexing(y, indices)
    else:
        y_subset = None

    return X_subset, y_subset
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`"""Utilities for meta-estimators"""`
			`# Author: Joel Nothman`
			`# Andreas Mueller`
			`# License: BSD`
			`from typing import List, Any`
			`import warnings`

			`from abc import ABCMeta, abstractmethod`
			`from operator import attrgetter`
			`import numpy as np`
			`from contextlib import suppress`

			`from ..utils import _safe_indexing`
			`from ..utils._tags import _safe_tags`
			`from ..base import BaseEstimator`
			`from ._available_if import available_if, _AvailableIfDescriptor`

			`__all__ = ["available_if", "if_delegate_has_method"]`


			`class _BaseComposition(BaseEstimator, metaclass=ABCMeta):`
			`"""Handles parameter management for classifiers composed of named estimators."""`

			`steps: List[Any]`

			`@abstractmethod`
			`def __init__(self):`
			`pass`

			`def _get_params(self, attr, deep=True):`
			`out = super().get_params(deep=deep)`
			`if not deep:`
			`return out`

			`estimators = getattr(self, attr)`
			`try:`
			`out.update(estimators)`
			`except (TypeError, ValueError):`
			`# Ignore TypeError for cases where estimators is not a list of`
			`# (name, estimator) and ignore ValueError when the list is not`
			`# formatted correctly. This is to prevent errors when calling`
			# `set_params`. `BaseEstimator.set_params` calls `get_params` which
			# can error for invalid values for `estimators`.
			`return out`

			`for name, estimator in estimators:`
			`if hasattr(estimator, "get_params"):`
			`for key, value in estimator.get_params(deep=True).items():`
			`out["%s__%s" % (name, key)] = value`
			`return out`

			`def _set_params(self, attr, **params):`
			`# Ensure strict ordering of parameter setting:`
			`# 1. All steps`
			`if attr in params:`
			`setattr(self, attr, params.pop(attr))`
			`# 2. Replace items with estimators in params`
			`items = getattr(self, attr)`
			`if isinstance(items, list) and items:`
			`# Get item names used to identify valid names in params`
			# `zip` raises a TypeError when `items` does not contains
			`# elements of length 2`
			`with suppress(TypeError):`
			`item_names, _ = zip(*items)`
			`for name in list(params.keys()):`
			`if "__" not in name and name in item_names:`
			`self._replace_estimator(attr, name, params.pop(name))`

			`# 3. Step parameters and other initialisation arguments`
			`super().set_params(**params)`
			`return self`

			`def _replace_estimator(self, attr, name, new_val):`
			# assumes `name` is a valid estimator name
			`new_estimators = list(getattr(self, attr))`
			`for i, (estimator_name, _) in enumerate(new_estimators):`
			`if estimator_name == name:`
			`new_estimators[i] = (name, new_val)`
			`break`
			`setattr(self, attr, new_estimators)`

			`def _validate_names(self, names):`
			`if len(set(names)) != len(names):`
			`raise ValueError("Names provided are not unique: {0!r}".format(list(names)))`
			`invalid_names = set(names).intersection(self.get_params(deep=False))`
			`if invalid_names:`
			`raise ValueError(`
			`"Estimator names conflict with constructor arguments: {0!r}".format(`
			`sorted(invalid_names)`
			`)`
			`)`
			`invalid_names = [name for name in names if "__" in name]`
			`if invalid_names:`
			`raise ValueError(`
			`"Estimator names must not contain __: got {0!r}".format(invalid_names)`
			`)`


			`# TODO(1.3) remove`
			`class _IffHasAttrDescriptor(_AvailableIfDescriptor):`
			`"""Implements a conditional property using the descriptor protocol.`

			Using this class to create a decorator will raise an ``AttributeError``
			if none of the delegates (specified in ``delegate_names``) is an attribute
			`of the base object or the first found delegate does not have an attribute`
			``attribute_name``.

			`This allows ducktyping of the decorated method based on`
			``delegate.attribute_name``. Here ``delegate`` is the first item in
			``delegate_names`` for which ``hasattr(object, delegate) is True``.

			`See https://docs.python.org/3/howto/descriptor.html for an explanation of`
			`descriptors.`
			`"""`

			`def __init__(self, fn, delegate_names, attribute_name):`
			`super().__init__(fn, self._check, attribute_name)`
			`self.delegate_names = delegate_names`

			`def _check(self, obj):`
			`warnings.warn(`
			`"if_delegate_has_method was deprecated in version 1.1 and will be "`
			`"removed in version 1.3. Use available_if instead.",`
			`FutureWarning,`
			`)`

			`delegate = None`
			`for delegate_name in self.delegate_names:`
			`try:`
			`delegate = attrgetter(delegate_name)(obj)`
			`break`
			`except AttributeError:`
			`continue`

			`if delegate is None:`
			`return False`
			`# raise original AttributeError`
			`getattr(delegate, self.attribute_name)`

			`return True`


			`# TODO(1.3) remove`
			`def if_delegate_has_method(delegate):`
			`"""Create a decorator for methods that are delegated to a sub-estimator.`

			`.. deprecated:: 1.3`
			`if_delegate_has_method` is deprecated in version 1.1 and will be removed in
			version 1.3. Use `available_if` instead.

			`This enables ducktyping by hasattr returning True according to the`
			`sub-estimator.`

			`Parameters`
			`----------`
			`delegate : str, list of str or tuple of str`
			`Name of the sub-estimator that can be accessed as an attribute of the`
			`base object. If a list or a tuple of names are provided, the first`
			`sub-estimator that is an attribute of the base object will be used.`

			`Returns`
			`-------`
			`callable`
			`Callable makes the decorated method available if the delegate`
			`has a method with the same name as the decorated method.`
			`"""`
			`if isinstance(delegate, list):`
			`delegate = tuple(delegate)`
			`if not isinstance(delegate, tuple):`
			`delegate = (delegate,)`

			`return lambda fn: _IffHasAttrDescriptor(fn, delegate, attribute_name=fn.__name__)`


			`def _safe_split(estimator, X, y, indices, train_indices=None):`
			`"""Create subset of dataset and properly handle kernels.`

			`Slice X, y according to indices for cross-validation, but take care of`
			`precomputed kernel-matrices or pairwise affinities / distances.`

			If ``estimator._pairwise is True``, X needs to be square and
			we slice rows and columns. If ``train_indices`` is not None,
			we slice rows using ``indices`` (assumed the test set) and columns
			using ``train_indices``, indicating the training set.

			`Labels y will always be indexed only along the first axis.`

			`Parameters`
			`----------`
			`estimator : object`
			`Estimator to determine whether we should slice only rows or rows and`
			`columns.`

			`X : array-like, sparse matrix or iterable`
			Data to be indexed. If ``estimator._pairwise is True``,
			`this needs to be a square array-like or sparse matrix.`

			`y : array-like, sparse matrix or iterable`
			`Targets to be indexed.`

			`indices : array of int`
			`Rows to select from X and y.`
			If ``estimator._pairwise is True`` and ``train_indices is None``
			then ``indices`` will also be used to slice columns.

			`train_indices : array of int or None, default=None`
			If ``estimator._pairwise is True`` and ``train_indices is not None``,
			then ``train_indices`` will be use to slice the columns of X.

			`Returns`
			`-------`
			`X_subset : array-like, sparse matrix or list`
			`Indexed data.`

			`y_subset : array-like, sparse matrix or list`
			`Indexed targets.`

			`"""`
			`if _safe_tags(estimator, key="pairwise"):`
			`if not hasattr(X, "shape"):`
			`raise ValueError(`
			`"Precomputed kernels or affinity matrices have "`
			`"to be passed as arrays or sparse matrices."`
			`)`
			`# X is a precomputed square kernel matrix`
			`if X.shape[0] != X.shape[1]:`
			`raise ValueError("X should be a square kernel matrix")`
			`if train_indices is None:`
			`X_subset = X[np.ix_(indices, indices)]`
			`else:`
			`X_subset = X[np.ix_(indices, train_indices)]`
			`else:`
			`X_subset = _safe_indexing(X, indices)`

			`if y is not None:`
			`y_subset = _safe_indexing(y, indices)`
			`else:`
			`y_subset = None`

			`return X_subset, y_subset`