Intelegentny_Pszczelarz/.venv/Lib/site-packages/sklearn/neighbors/_kde.py

"""
Kernel Density Estimation
-------------------------
"""
# Author: Jake Vanderplas <jakevdp@cs.washington.edu>
import itertools
from numbers import Integral, Real

import numpy as np
from scipy.special import gammainc

from ..base import BaseEstimator
from ..neighbors._base import VALID_METRICS
from ..utils import check_random_state
from ..utils.validation import _check_sample_weight, check_is_fitted
from ..utils._param_validation import Interval, StrOptions
from ..utils.extmath import row_norms
from ._ball_tree import BallTree, DTYPE
from ._kd_tree import KDTree


VALID_KERNELS = [
    "gaussian",
    "tophat",
    "epanechnikov",
    "exponential",
    "linear",
    "cosine",
]

TREE_DICT = {"ball_tree": BallTree, "kd_tree": KDTree}


# TODO: implement a brute force version for testing purposes
# TODO: create a density estimation base class?
class KernelDensity(BaseEstimator):
    """Kernel Density Estimation.

    Read more in the :ref:`User Guide <kernel_density>`.

    Parameters
    ----------
    bandwidth : float or {"scott", "silverman"}, default=1.0
        The bandwidth of the kernel. If bandwidth is a float, it defines the
        bandwidth of the kernel. If bandwidth is a string, one of the estimation
        methods is implemented.

    algorithm : {'kd_tree', 'ball_tree', 'auto'}, default='auto'
        The tree algorithm to use.

    kernel : {'gaussian', 'tophat', 'epanechnikov', 'exponential', 'linear', \
                 'cosine'}, default='gaussian'
        The kernel to use.

    metric : str, default='euclidean'
        Metric to use for distance computation. See the
        documentation of `scipy.spatial.distance
        <https://docs.scipy.org/doc/scipy/reference/spatial.distance.html>`_ and
        the metrics listed in
        :class:`~sklearn.metrics.pairwise.distance_metrics` for valid metric
        values.

        Not all metrics are valid with all algorithms: refer to the
        documentation of :class:`BallTree` and :class:`KDTree`. Note that the
        normalization of the density output is correct only for the Euclidean
        distance metric.

    atol : float, default=0
        The desired absolute tolerance of the result.  A larger tolerance will
        generally lead to faster execution.

    rtol : float, default=0
        The desired relative tolerance of the result.  A larger tolerance will
        generally lead to faster execution.

    breadth_first : bool, default=True
        If true (default), use a breadth-first approach to the problem.
        Otherwise use a depth-first approach.

    leaf_size : int, default=40
        Specify the leaf size of the underlying tree.  See :class:`BallTree`
        or :class:`KDTree` for details.

    metric_params : dict, default=None
        Additional parameters to be passed to the tree for use with the
        metric.  For more information, see the documentation of
        :class:`BallTree` or :class:`KDTree`.

    Attributes
    ----------
    n_features_in_ : int
        Number of features seen during :term:`fit`.

        .. versionadded:: 0.24

    tree_ : ``BinaryTree`` instance
        The tree algorithm for fast generalized N-point problems.

    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.

    bandwidth_ : float
        Value of the bandwidth, given directly by the bandwidth parameter or
        estimated using the 'scott' or 'silverman' method.

        .. versionadded:: 1.0

    See Also
    --------
    sklearn.neighbors.KDTree : K-dimensional tree for fast generalized N-point
        problems.
    sklearn.neighbors.BallTree : Ball tree for fast generalized N-point
        problems.

    Examples
    --------
    Compute a gaussian kernel density estimate with a fixed bandwidth.

    >>> from sklearn.neighbors import KernelDensity
    >>> import numpy as np
    >>> rng = np.random.RandomState(42)
    >>> X = rng.random_sample((100, 3))
    >>> kde = KernelDensity(kernel='gaussian', bandwidth=0.5).fit(X)
    >>> log_density = kde.score_samples(X[:3])
    >>> log_density
    array([-1.52955942, -1.51462041, -1.60244657])
    """

    _parameter_constraints: dict = {
        "bandwidth": [
            Interval(Real, 0, None, closed="neither"),
            StrOptions({"scott", "silverman"}),
        ],
        "algorithm": [StrOptions(set(TREE_DICT.keys()) | {"auto"})],
        "kernel": [StrOptions(set(VALID_KERNELS))],
        "metric": [
            StrOptions(
                set(itertools.chain(*[VALID_METRICS[alg] for alg in TREE_DICT.keys()]))
            )
        ],
        "atol": [Interval(Real, 0, None, closed="left")],
        "rtol": [Interval(Real, 0, None, closed="left")],
        "breadth_first": ["boolean"],
        "leaf_size": [Interval(Integral, 1, None, closed="left")],
        "metric_params": [None, dict],
    }

    def __init__(
        self,
        *,
        bandwidth=1.0,
        algorithm="auto",
        kernel="gaussian",
        metric="euclidean",
        atol=0,
        rtol=0,
        breadth_first=True,
        leaf_size=40,
        metric_params=None,
    ):
        self.algorithm = algorithm
        self.bandwidth = bandwidth
        self.kernel = kernel
        self.metric = metric
        self.atol = atol
        self.rtol = rtol
        self.breadth_first = breadth_first
        self.leaf_size = leaf_size
        self.metric_params = metric_params

    def _choose_algorithm(self, algorithm, metric):
        # given the algorithm string + metric string, choose the optimal
        # algorithm to compute the result.
        if algorithm == "auto":
            # use KD Tree if possible
            if metric in KDTree.valid_metrics:
                return "kd_tree"
            elif metric in BallTree.valid_metrics:
                return "ball_tree"
        else:  # kd_tree or ball_tree
            if metric not in TREE_DICT[algorithm].valid_metrics:
                raise ValueError(
                    "invalid metric for {0}: '{1}'".format(TREE_DICT[algorithm], metric)
                )
            return algorithm

    def fit(self, X, y=None, sample_weight=None):
        """Fit the Kernel Density model on the data.

        Parameters
        ----------
        X : array-like of shape (n_samples, n_features)
            List of n_features-dimensional data points.  Each row
            corresponds to a single data point.

        y : None
            Ignored. This parameter exists only for compatibility with
            :class:`~sklearn.pipeline.Pipeline`.

        sample_weight : array-like of shape (n_samples,), default=None
            List of sample weights attached to the data X.

            .. versionadded:: 0.20

        Returns
        -------
        self : object
            Returns the instance itself.
        """
        self._validate_params()

        algorithm = self._choose_algorithm(self.algorithm, self.metric)

        if isinstance(self.bandwidth, str):
            if self.bandwidth == "scott":
                self.bandwidth_ = X.shape[0] ** (-1 / (X.shape[1] + 4))
            elif self.bandwidth == "silverman":
                self.bandwidth_ = (X.shape[0] * (X.shape[1] + 2) / 4) ** (
                    -1 / (X.shape[1] + 4)
                )
        else:
            self.bandwidth_ = self.bandwidth

        X = self._validate_data(X, order="C", dtype=DTYPE)

        if sample_weight is not None:
            sample_weight = _check_sample_weight(
                sample_weight, X, DTYPE, only_non_negative=True
            )

        kwargs = self.metric_params
        if kwargs is None:
            kwargs = {}
        self.tree_ = TREE_DICT[algorithm](
            X,
            metric=self.metric,
            leaf_size=self.leaf_size,
            sample_weight=sample_weight,
            **kwargs,
        )
        return self

    def score_samples(self, X):
        """Compute the log-likelihood of each sample under the model.

        Parameters
        ----------
        X : array-like of shape (n_samples, n_features)
            An array of points to query.  Last dimension should match dimension
            of training data (n_features).

        Returns
        -------
        density : ndarray of shape (n_samples,)
            Log-likelihood of each sample in `X`. These are normalized to be
            probability densities, so values will be low for high-dimensional
            data.
        """
        check_is_fitted(self)
        # The returned density is normalized to the number of points.
        # For it to be a probability, we must scale it.  For this reason
        # we'll also scale atol.
        X = self._validate_data(X, order="C", dtype=DTYPE, reset=False)
        if self.tree_.sample_weight is None:
            N = self.tree_.data.shape[0]
        else:
            N = self.tree_.sum_weight
        atol_N = self.atol * N
        log_density = self.tree_.kernel_density(
            X,
            h=self.bandwidth_,
            kernel=self.kernel,
            atol=atol_N,
            rtol=self.rtol,
            breadth_first=self.breadth_first,
            return_log=True,
        )
        log_density -= np.log(N)
        return log_density

    def score(self, X, y=None):
        """Compute the total log-likelihood under the model.

        Parameters
        ----------
        X : array-like of shape (n_samples, n_features)
            List of n_features-dimensional data points.  Each row
            corresponds to a single data point.

        y : None
            Ignored. This parameter exists only for compatibility with
            :class:`~sklearn.pipeline.Pipeline`.

        Returns
        -------
        logprob : float
            Total log-likelihood of the data in X. This is normalized to be a
            probability density, so the value will be low for high-dimensional
            data.
        """
        return np.sum(self.score_samples(X))

    def sample(self, n_samples=1, random_state=None):
        """Generate random samples from the model.

        Currently, this is implemented only for gaussian and tophat kernels.

        Parameters
        ----------
        n_samples : int, default=1
            Number of samples to generate.

        random_state : int, RandomState instance or None, default=None
            Determines random number generation used to generate
            random samples. Pass an int for reproducible results
            across multiple function calls.
            See :term:`Glossary <random_state>`.

        Returns
        -------
        X : array-like of shape (n_samples, n_features)
            List of samples.
        """
        check_is_fitted(self)
        # TODO: implement sampling for other valid kernel shapes
        if self.kernel not in ["gaussian", "tophat"]:
            raise NotImplementedError()

        data = np.asarray(self.tree_.data)

        rng = check_random_state(random_state)
        u = rng.uniform(0, 1, size=n_samples)
        if self.tree_.sample_weight is None:
            i = (u * data.shape[0]).astype(np.int64)
        else:
            cumsum_weight = np.cumsum(np.asarray(self.tree_.sample_weight))
            sum_weight = cumsum_weight[-1]
            i = np.searchsorted(cumsum_weight, u * sum_weight)
        if self.kernel == "gaussian":
            return np.atleast_2d(rng.normal(data[i], self.bandwidth_))

        elif self.kernel == "tophat":
            # we first draw points from a d-dimensional normal distribution,
            # then use an incomplete gamma function to map them to a uniform
            # d-dimensional tophat distribution.
            dim = data.shape[1]
            X = rng.normal(size=(n_samples, dim))
            s_sq = row_norms(X, squared=True)
            correction = (
                gammainc(0.5 * dim, 0.5 * s_sq) ** (1.0 / dim)
                * self.bandwidth_
                / np.sqrt(s_sq)
            )
            return data[i] + X * correction[:, np.newaxis]

    def _more_tags(self):
        return {
            "_xfail_checks": {
                "check_sample_weights_invariance": (
                    "sample_weight must have positive values"
                ),
            }
        }
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`"""`
			`Kernel Density Estimation`
			`-------------------------`
			`"""`
			`# Author: Jake Vanderplas <jakevdp@cs.washington.edu>`
			`import itertools`
			`from numbers import Integral, Real`

			`import numpy as np`
			`from scipy.special import gammainc`

			`from ..base import BaseEstimator`
			`from ..neighbors._base import VALID_METRICS`
			`from ..utils import check_random_state`
			`from ..utils.validation import _check_sample_weight, check_is_fitted`
			`from ..utils._param_validation import Interval, StrOptions`
			`from ..utils.extmath import row_norms`
			`from ._ball_tree import BallTree, DTYPE`
			`from ._kd_tree import KDTree`


			`VALID_KERNELS = [`
			`"gaussian",`
			`"tophat",`
			`"epanechnikov",`
			`"exponential",`
			`"linear",`
			`"cosine",`
			`]`

			`TREE_DICT = {"ball_tree": BallTree, "kd_tree": KDTree}`


			`# TODO: implement a brute force version for testing purposes`
			`# TODO: create a density estimation base class?`
			`class KernelDensity(BaseEstimator):`
			`"""Kernel Density Estimation.`

			Read more in the :ref:`User Guide <kernel_density>`.

			`Parameters`
			`----------`
			`bandwidth : float or {"scott", "silverman"}, default=1.0`
			`The bandwidth of the kernel. If bandwidth is a float, it defines the`
			`bandwidth of the kernel. If bandwidth is a string, one of the estimation`
			`methods is implemented.`

			`algorithm : {'kd_tree', 'ball_tree', 'auto'}, default='auto'`
			`The tree algorithm to use.`

			`kernel : {'gaussian', 'tophat', 'epanechnikov', 'exponential', 'linear', \`
			`'cosine'}, default='gaussian'`
			`The kernel to use.`

			`metric : str, default='euclidean'`
			`Metric to use for distance computation. See the`
			documentation of `scipy.spatial.distance
			<https://docs.scipy.org/doc/scipy/reference/spatial.distance.html>`_ and
			`the metrics listed in`
			:class:`~sklearn.metrics.pairwise.distance_metrics` for valid metric
			`values.`

			`Not all metrics are valid with all algorithms: refer to the`
			documentation of :class:`BallTree` and :class:`KDTree`. Note that the
			`normalization of the density output is correct only for the Euclidean`
			`distance metric.`

			`atol : float, default=0`
			`The desired absolute tolerance of the result. A larger tolerance will`
			`generally lead to faster execution.`

			`rtol : float, default=0`
			`The desired relative tolerance of the result. A larger tolerance will`
			`generally lead to faster execution.`

			`breadth_first : bool, default=True`
			`If true (default), use a breadth-first approach to the problem.`
			`Otherwise use a depth-first approach.`

			`leaf_size : int, default=40`
			Specify the leaf size of the underlying tree. See :class:`BallTree`
			or :class:`KDTree` for details.

			`metric_params : dict, default=None`
			`Additional parameters to be passed to the tree for use with the`
			`metric. For more information, see the documentation of`
			:class:`BallTree` or :class:`KDTree`.

			`Attributes`
			`----------`
			`n_features_in_ : int`
			Number of features seen during :term:`fit`.

			`.. versionadded:: 0.24`

			tree_ : ``BinaryTree`` instance
			`The tree algorithm for fast generalized N-point problems.`

			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.`

			`bandwidth_ : float`
			`Value of the bandwidth, given directly by the bandwidth parameter or`
			`estimated using the 'scott' or 'silverman' method.`

			`.. versionadded:: 1.0`

			`See Also`
			`--------`
			`sklearn.neighbors.KDTree : K-dimensional tree for fast generalized N-point`
			`problems.`
			`sklearn.neighbors.BallTree : Ball tree for fast generalized N-point`
			`problems.`

			`Examples`
			`--------`
			`Compute a gaussian kernel density estimate with a fixed bandwidth.`

			`>>> from sklearn.neighbors import KernelDensity`
			`>>> import numpy as np`
			`>>> rng = np.random.RandomState(42)`
			`>>> X = rng.random_sample((100, 3))`
			`>>> kde = KernelDensity(kernel='gaussian', bandwidth=0.5).fit(X)`
			`>>> log_density = kde.score_samples(X[:3])`
			`>>> log_density`
			`array([-1.52955942, -1.51462041, -1.60244657])`
			`"""`

			`_parameter_constraints: dict = {`
			`"bandwidth": [`
			`Interval(Real, 0, None, closed="neither"),`
			`StrOptions({"scott", "silverman"}),`
			`],`
			`"algorithm": [StrOptions(set(TREE_DICT.keys()) \| {"auto"})],`
			`"kernel": [StrOptions(set(VALID_KERNELS))],`
			`"metric": [`
			`StrOptions(`
			`set(itertools.chain(*[VALID_METRICS[alg] for alg in TREE_DICT.keys()]))`
			`)`
			`],`
			`"atol": [Interval(Real, 0, None, closed="left")],`
			`"rtol": [Interval(Real, 0, None, closed="left")],`
			`"breadth_first": ["boolean"],`
			`"leaf_size": [Interval(Integral, 1, None, closed="left")],`
			`"metric_params": [None, dict],`
			`}`

			`def __init__(`
			`self,`
			`*,`
			`bandwidth=1.0,`
			`algorithm="auto",`
			`kernel="gaussian",`
			`metric="euclidean",`
			`atol=0,`
			`rtol=0,`
			`breadth_first=True,`
			`leaf_size=40,`
			`metric_params=None,`
			`):`
			`self.algorithm = algorithm`
			`self.bandwidth = bandwidth`
			`self.kernel = kernel`
			`self.metric = metric`
			`self.atol = atol`
			`self.rtol = rtol`
			`self.breadth_first = breadth_first`
			`self.leaf_size = leaf_size`
			`self.metric_params = metric_params`

			`def _choose_algorithm(self, algorithm, metric):`
			`# given the algorithm string + metric string, choose the optimal`
			`# algorithm to compute the result.`
			`if algorithm == "auto":`
			`# use KD Tree if possible`
			`if metric in KDTree.valid_metrics:`
			`return "kd_tree"`
			`elif metric in BallTree.valid_metrics:`
			`return "ball_tree"`
			`else: # kd_tree or ball_tree`
			`if metric not in TREE_DICT[algorithm].valid_metrics:`
			`raise ValueError(`
			`"invalid metric for {0}: '{1}'".format(TREE_DICT[algorithm], metric)`
			`)`
			`return algorithm`

			`def fit(self, X, y=None, sample_weight=None):`
			`"""Fit the Kernel Density model on the data.`

			`Parameters`
			`----------`
			`X : array-like of shape (n_samples, n_features)`
			`List of n_features-dimensional data points. Each row`
			`corresponds to a single data point.`

			`y : None`
			`Ignored. This parameter exists only for compatibility with`
			:class:`~sklearn.pipeline.Pipeline`.

			`sample_weight : array-like of shape (n_samples,), default=None`
			`List of sample weights attached to the data X.`

			`.. versionadded:: 0.20`

			`Returns`
			`-------`
			`self : object`
			`Returns the instance itself.`
			`"""`
			`self._validate_params()`

			`algorithm = self._choose_algorithm(self.algorithm, self.metric)`

			`if isinstance(self.bandwidth, str):`
			`if self.bandwidth == "scott":`
			`self.bandwidth_ = X.shape[0] ** (-1 / (X.shape[1] + 4))`
			`elif self.bandwidth == "silverman":`
			`self.bandwidth_ = (X.shape[0] * (X.shape[1] + 2) / 4) ** (`
			`-1 / (X.shape[1] + 4)`
			`)`
			`else:`
			`self.bandwidth_ = self.bandwidth`

			`X = self._validate_data(X, order="C", dtype=DTYPE)`

			`if sample_weight is not None:`
			`sample_weight = _check_sample_weight(`
			`sample_weight, X, DTYPE, only_non_negative=True`
			`)`

			`kwargs = self.metric_params`
			`if kwargs is None:`
			`kwargs = {}`
			`self.tree_ = TREE_DICT[algorithm](`
			`X,`
			`metric=self.metric,`
			`leaf_size=self.leaf_size,`
			`sample_weight=sample_weight,`
			`**kwargs,`
			`)`
			`return self`

			`def score_samples(self, X):`
			`"""Compute the log-likelihood of each sample under the model.`

			`Parameters`
			`----------`
			`X : array-like of shape (n_samples, n_features)`
			`An array of points to query. Last dimension should match dimension`
			`of training data (n_features).`

			`Returns`
			`-------`
			`density : ndarray of shape (n_samples,)`
			Log-likelihood of each sample in `X`. These are normalized to be
			`probability densities, so values will be low for high-dimensional`
			`data.`
			`"""`
			`check_is_fitted(self)`
			`# The returned density is normalized to the number of points.`
			`# For it to be a probability, we must scale it. For this reason`
			`# we'll also scale atol.`
			`X = self._validate_data(X, order="C", dtype=DTYPE, reset=False)`
			`if self.tree_.sample_weight is None:`
			`N = self.tree_.data.shape[0]`
			`else:`
			`N = self.tree_.sum_weight`
			`atol_N = self.atol * N`
			`log_density = self.tree_.kernel_density(`
			`X,`
			`h=self.bandwidth_,`
			`kernel=self.kernel,`
			`atol=atol_N,`
			`rtol=self.rtol,`
			`breadth_first=self.breadth_first,`
			`return_log=True,`
			`)`
			`log_density -= np.log(N)`
			`return log_density`

			`def score(self, X, y=None):`
			`"""Compute the total log-likelihood under the model.`

			`Parameters`
			`----------`
			`X : array-like of shape (n_samples, n_features)`
			`List of n_features-dimensional data points. Each row`
			`corresponds to a single data point.`

			`y : None`
			`Ignored. This parameter exists only for compatibility with`
			:class:`~sklearn.pipeline.Pipeline`.

			`Returns`
			`-------`
			`logprob : float`
			`Total log-likelihood of the data in X. This is normalized to be a`
			`probability density, so the value will be low for high-dimensional`
			`data.`
			`"""`
			`return np.sum(self.score_samples(X))`

			`def sample(self, n_samples=1, random_state=None):`
			`"""Generate random samples from the model.`

			`Currently, this is implemented only for gaussian and tophat kernels.`

			`Parameters`
			`----------`
			`n_samples : int, default=1`
			`Number of samples to generate.`

			`random_state : int, RandomState instance or None, default=None`
			`Determines random number generation used to generate`
			`random samples. Pass an int for reproducible results`
			`across multiple function calls.`
			See :term:`Glossary <random_state>`.

			`Returns`
			`-------`
			`X : array-like of shape (n_samples, n_features)`
			`List of samples.`
			`"""`
			`check_is_fitted(self)`
			`# TODO: implement sampling for other valid kernel shapes`
			`if self.kernel not in ["gaussian", "tophat"]:`
			`raise NotImplementedError()`

			`data = np.asarray(self.tree_.data)`

			`rng = check_random_state(random_state)`
			`u = rng.uniform(0, 1, size=n_samples)`
			`if self.tree_.sample_weight is None:`
			`i = (u * data.shape[0]).astype(np.int64)`
			`else:`
			`cumsum_weight = np.cumsum(np.asarray(self.tree_.sample_weight))`
			`sum_weight = cumsum_weight[-1]`
			`i = np.searchsorted(cumsum_weight, u * sum_weight)`
			`if self.kernel == "gaussian":`
			`return np.atleast_2d(rng.normal(data[i], self.bandwidth_))`

			`elif self.kernel == "tophat":`
			`# we first draw points from a d-dimensional normal distribution,`
			`# then use an incomplete gamma function to map them to a uniform`
			`# d-dimensional tophat distribution.`
			`dim = data.shape[1]`
			`X = rng.normal(size=(n_samples, dim))`
			`s_sq = row_norms(X, squared=True)`
			`correction = (`
			`gammainc(0.5 * dim, 0.5 * s_sq) ** (1.0 / dim)`
			`* self.bandwidth_`
			`/ np.sqrt(s_sq)`
			`)`
			`return data[i] + X * correction[:, np.newaxis]`

			`def _more_tags(self):`
			`return {`
			`"_xfail_checks": {`
			`"check_sample_weights_invariance": (`
			`"sample_weight must have positive values"`
			`),`
			`}`
			`}`