569 lines
20 KiB
Python
569 lines
20 KiB
Python
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# Authors: Nicolas Goix <nicolas.goix@telecom-paristech.fr>
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# Alexandre Gramfort <alexandre.gramfort@telecom-paristech.fr>
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# License: BSD 3 clause
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import numbers
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from numbers import Integral, Real
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from warnings import warn
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import numpy as np
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from scipy.sparse import issparse
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from ..base import OutlierMixin, _fit_context
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from ..tree import ExtraTreeRegressor
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from ..tree._tree import DTYPE as tree_dtype
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from ..utils import (
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check_array,
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check_random_state,
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gen_batches,
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)
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from ..utils._chunking import get_chunk_n_rows
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from ..utils._param_validation import Interval, RealNotInt, StrOptions
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from ..utils.validation import _num_samples, check_is_fitted
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from ._bagging import BaseBagging
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__all__ = ["IsolationForest"]
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class IsolationForest(OutlierMixin, BaseBagging):
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"""
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Isolation Forest Algorithm.
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Return the anomaly score of each sample using the IsolationForest algorithm
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The IsolationForest 'isolates' observations by randomly selecting a feature
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and then randomly selecting a split value between the maximum and minimum
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values of the selected feature.
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Since recursive partitioning can be represented by a tree structure, the
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number of splittings required to isolate a sample is equivalent to the path
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length from the root node to the terminating node.
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This path length, averaged over a forest of such random trees, is a
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measure of normality and our decision function.
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Random partitioning produces noticeably shorter paths for anomalies.
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Hence, when a forest of random trees collectively produce shorter path
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lengths for particular samples, they are highly likely to be anomalies.
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Read more in the :ref:`User Guide <isolation_forest>`.
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.. versionadded:: 0.18
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Parameters
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----------
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n_estimators : int, default=100
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The number of base estimators in the ensemble.
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max_samples : "auto", int or float, default="auto"
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The number of samples to draw from X to train each base estimator.
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- If int, then draw `max_samples` samples.
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- If float, then draw `max_samples * X.shape[0]` samples.
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- If "auto", then `max_samples=min(256, n_samples)`.
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If max_samples is larger than the number of samples provided,
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all samples will be used for all trees (no sampling).
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contamination : 'auto' or float, default='auto'
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The amount of contamination of the data set, i.e. the proportion
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of outliers in the data set. Used when fitting to define the threshold
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on the scores of the samples.
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- If 'auto', the threshold is determined as in the
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original paper.
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- If float, the contamination should be in the range (0, 0.5].
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.. versionchanged:: 0.22
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The default value of ``contamination`` changed from 0.1
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to ``'auto'``.
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max_features : int or float, default=1.0
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The number of features to draw from X to train each base estimator.
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- If int, then draw `max_features` features.
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- If float, then draw `max(1, int(max_features * n_features_in_))` features.
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Note: using a float number less than 1.0 or integer less than number of
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features will enable feature subsampling and leads to a longer runtime.
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bootstrap : bool, default=False
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If True, individual trees are fit on random subsets of the training
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data sampled with replacement. If False, sampling without replacement
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is performed.
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n_jobs : int, default=None
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The number of jobs to run in parallel for both :meth:`fit` and
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:meth:`predict`. ``None`` means 1 unless in a
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:obj:`joblib.parallel_backend` context. ``-1`` means using all
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processors. See :term:`Glossary <n_jobs>` for more details.
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random_state : int, RandomState instance or None, default=None
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Controls the pseudo-randomness of the selection of the feature
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and split values for each branching step and each tree in the forest.
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Pass an int for reproducible results across multiple function calls.
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See :term:`Glossary <random_state>`.
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verbose : int, default=0
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Controls the verbosity of the tree building process.
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warm_start : bool, default=False
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When set to ``True``, reuse the solution of the previous call to fit
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and add more estimators to the ensemble, otherwise, just fit a whole
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new forest. See :term:`the Glossary <warm_start>`.
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.. versionadded:: 0.21
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Attributes
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----------
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estimator_ : :class:`~sklearn.tree.ExtraTreeRegressor` instance
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The child estimator template used to create the collection of
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fitted sub-estimators.
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.. versionadded:: 1.2
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`base_estimator_` was renamed to `estimator_`.
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estimators_ : list of ExtraTreeRegressor instances
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The collection of fitted sub-estimators.
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estimators_features_ : list of ndarray
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The subset of drawn features for each base estimator.
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estimators_samples_ : list of ndarray
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The subset of drawn samples (i.e., the in-bag samples) for each base
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estimator.
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max_samples_ : int
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The actual number of samples.
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offset_ : float
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Offset used to define the decision function from the raw scores. We
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have the relation: ``decision_function = score_samples - offset_``.
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``offset_`` is defined as follows. When the contamination parameter is
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set to "auto", the offset is equal to -0.5 as the scores of inliers are
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close to 0 and the scores of outliers are close to -1. When a
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contamination parameter different than "auto" is provided, the offset
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is defined in such a way we obtain the expected number of outliers
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(samples with decision function < 0) in training.
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.. versionadded:: 0.20
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n_features_in_ : int
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Number of features seen during :term:`fit`.
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.. versionadded:: 0.24
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feature_names_in_ : ndarray of shape (`n_features_in_`,)
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Names of features seen during :term:`fit`. Defined only when `X`
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has feature names that are all strings.
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.. versionadded:: 1.0
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See Also
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--------
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sklearn.covariance.EllipticEnvelope : An object for detecting outliers in a
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Gaussian distributed dataset.
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sklearn.svm.OneClassSVM : Unsupervised Outlier Detection.
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Estimate the support of a high-dimensional distribution.
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The implementation is based on libsvm.
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sklearn.neighbors.LocalOutlierFactor : Unsupervised Outlier Detection
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using Local Outlier Factor (LOF).
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Notes
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-----
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The implementation is based on an ensemble of ExtraTreeRegressor. The
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maximum depth of each tree is set to ``ceil(log_2(n))`` where
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:math:`n` is the number of samples used to build the tree
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(see (Liu et al., 2008) for more details).
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References
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----------
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.. [1] Liu, Fei Tony, Ting, Kai Ming and Zhou, Zhi-Hua. "Isolation forest."
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Data Mining, 2008. ICDM'08. Eighth IEEE International Conference on.
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.. [2] Liu, Fei Tony, Ting, Kai Ming and Zhou, Zhi-Hua. "Isolation-based
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anomaly detection." ACM Transactions on Knowledge Discovery from
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Data (TKDD) 6.1 (2012): 3.
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Examples
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--------
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>>> from sklearn.ensemble import IsolationForest
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>>> X = [[-1.1], [0.3], [0.5], [100]]
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>>> clf = IsolationForest(random_state=0).fit(X)
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>>> clf.predict([[0.1], [0], [90]])
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array([ 1, 1, -1])
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For an example of using isolation forest for anomaly detection see
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:ref:`sphx_glr_auto_examples_ensemble_plot_isolation_forest.py`.
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"""
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_parameter_constraints: dict = {
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"n_estimators": [Interval(Integral, 1, None, closed="left")],
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"max_samples": [
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StrOptions({"auto"}),
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Interval(Integral, 1, None, closed="left"),
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Interval(RealNotInt, 0, 1, closed="right"),
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],
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"contamination": [
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StrOptions({"auto"}),
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Interval(Real, 0, 0.5, closed="right"),
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],
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"max_features": [
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Integral,
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Interval(Real, 0, 1, closed="right"),
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],
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"bootstrap": ["boolean"],
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"n_jobs": [Integral, None],
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"random_state": ["random_state"],
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"verbose": ["verbose"],
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"warm_start": ["boolean"],
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}
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def __init__(
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self,
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*,
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n_estimators=100,
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max_samples="auto",
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contamination="auto",
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max_features=1.0,
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bootstrap=False,
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n_jobs=None,
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random_state=None,
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verbose=0,
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warm_start=False,
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):
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super().__init__(
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estimator=None,
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# here above max_features has no links with self.max_features
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bootstrap=bootstrap,
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bootstrap_features=False,
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n_estimators=n_estimators,
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max_samples=max_samples,
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max_features=max_features,
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warm_start=warm_start,
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n_jobs=n_jobs,
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random_state=random_state,
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verbose=verbose,
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)
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self.contamination = contamination
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def _get_estimator(self):
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return ExtraTreeRegressor(
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# here max_features has no links with self.max_features
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max_features=1,
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splitter="random",
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random_state=self.random_state,
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)
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def _set_oob_score(self, X, y):
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raise NotImplementedError("OOB score not supported by iforest")
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def _parallel_args(self):
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# ExtraTreeRegressor releases the GIL, so it's more efficient to use
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# a thread-based backend rather than a process-based backend so as
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# to avoid suffering from communication overhead and extra memory
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# copies.
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return {"prefer": "threads"}
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@_fit_context(prefer_skip_nested_validation=True)
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def fit(self, X, y=None, sample_weight=None):
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"""
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Fit estimator.
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Parameters
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----------
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X : {array-like, sparse matrix} of shape (n_samples, n_features)
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The input samples. Use ``dtype=np.float32`` for maximum
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efficiency. Sparse matrices are also supported, use sparse
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``csc_matrix`` for maximum efficiency.
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y : Ignored
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Not used, present for API consistency by convention.
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sample_weight : array-like of shape (n_samples,), default=None
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Sample weights. If None, then samples are equally weighted.
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Returns
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-------
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self : object
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Fitted estimator.
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"""
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X = self._validate_data(X, accept_sparse=["csc"], dtype=tree_dtype)
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if issparse(X):
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# Pre-sort indices to avoid that each individual tree of the
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# ensemble sorts the indices.
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X.sort_indices()
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rnd = check_random_state(self.random_state)
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y = rnd.uniform(size=X.shape[0])
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# ensure that max_sample is in [1, n_samples]:
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n_samples = X.shape[0]
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if isinstance(self.max_samples, str) and self.max_samples == "auto":
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max_samples = min(256, n_samples)
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elif isinstance(self.max_samples, numbers.Integral):
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if self.max_samples > n_samples:
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warn(
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"max_samples (%s) is greater than the "
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"total number of samples (%s). max_samples "
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"will be set to n_samples for estimation."
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% (self.max_samples, n_samples)
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)
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max_samples = n_samples
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else:
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max_samples = self.max_samples
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else: # max_samples is float
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max_samples = int(self.max_samples * X.shape[0])
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self.max_samples_ = max_samples
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max_depth = int(np.ceil(np.log2(max(max_samples, 2))))
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super()._fit(
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X,
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y,
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max_samples,
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max_depth=max_depth,
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sample_weight=sample_weight,
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check_input=False,
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)
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self._average_path_length_per_tree, self._decision_path_lengths = zip(
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*[
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(
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_average_path_length(tree.tree_.n_node_samples),
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tree.tree_.compute_node_depths(),
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)
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for tree in self.estimators_
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]
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)
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if self.contamination == "auto":
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# 0.5 plays a special role as described in the original paper.
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# we take the opposite as we consider the opposite of their score.
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self.offset_ = -0.5
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return self
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# Else, define offset_ wrt contamination parameter
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# To avoid performing input validation a second time we call
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# _score_samples rather than score_samples.
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# _score_samples expects a CSR matrix, so we convert if necessary.
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if issparse(X):
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X = X.tocsr()
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self.offset_ = np.percentile(self._score_samples(X), 100.0 * self.contamination)
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return self
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def predict(self, X):
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"""
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Predict if a particular sample is an outlier or not.
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Parameters
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----------
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X : {array-like, sparse matrix} of shape (n_samples, n_features)
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The input samples. Internally, it will be converted to
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``dtype=np.float32`` and if a sparse matrix is provided
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to a sparse ``csr_matrix``.
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Returns
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-------
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is_inlier : ndarray of shape (n_samples,)
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For each observation, tells whether or not (+1 or -1) it should
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be considered as an inlier according to the fitted model.
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"""
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check_is_fitted(self)
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decision_func = self.decision_function(X)
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is_inlier = np.ones_like(decision_func, dtype=int)
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is_inlier[decision_func < 0] = -1
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return is_inlier
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def decision_function(self, X):
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"""
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Average anomaly score of X of the base classifiers.
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The anomaly score of an input sample is computed as
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the mean anomaly score of the trees in the forest.
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The measure of normality of an observation given a tree is the depth
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of the leaf containing this observation, which is equivalent to
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the number of splittings required to isolate this point. In case of
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several observations n_left in the leaf, the average path length of
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a n_left samples isolation tree is added.
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Parameters
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----------
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X : {array-like, sparse matrix} of shape (n_samples, n_features)
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The input samples. Internally, it will be converted to
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``dtype=np.float32`` and if a sparse matrix is provided
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to a sparse ``csr_matrix``.
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Returns
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-------
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scores : ndarray of shape (n_samples,)
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The anomaly score of the input samples.
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The lower, the more abnormal. Negative scores represent outliers,
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positive scores represent inliers.
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"""
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# We subtract self.offset_ to make 0 be the threshold value for being
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# an outlier:
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return self.score_samples(X) - self.offset_
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def score_samples(self, X):
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"""
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Opposite of the anomaly score defined in the original paper.
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The anomaly score of an input sample is computed as
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the mean anomaly score of the trees in the forest.
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The measure of normality of an observation given a tree is the depth
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of the leaf containing this observation, which is equivalent to
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the number of splittings required to isolate this point. In case of
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several observations n_left in the leaf, the average path length of
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a n_left samples isolation tree is added.
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Parameters
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----------
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X : {array-like, sparse matrix} of shape (n_samples, n_features)
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The input samples.
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Returns
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-------
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scores : ndarray of shape (n_samples,)
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The anomaly score of the input samples.
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The lower, the more abnormal.
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"""
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# Check data
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X = self._validate_data(X, accept_sparse="csr", dtype=tree_dtype, reset=False)
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return self._score_samples(X)
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|
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|
def _score_samples(self, X):
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|
"""Private version of score_samples without input validation.
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||
|
|
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|
Input validation would remove feature names, so we disable it.
|
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|
"""
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|
# Code structure from ForestClassifier/predict_proba
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||
|
|
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|
check_is_fitted(self)
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||
|
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|
# Take the opposite of the scores as bigger is better (here less abnormal)
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|
return -self._compute_chunked_score_samples(X)
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|
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|
def _compute_chunked_score_samples(self, X):
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|
n_samples = _num_samples(X)
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||
|
|
||
|
if self._max_features == X.shape[1]:
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|
subsample_features = False
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|
else:
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|
subsample_features = True
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||
|
|
||
|
# We get as many rows as possible within our working_memory budget
|
||
|
# (defined by sklearn.get_config()['working_memory']) to store
|
||
|
# self._max_features in each row during computation.
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||
|
#
|
||
|
# Note:
|
||
|
# - this will get at least 1 row, even if 1 row of score will
|
||
|
# exceed working_memory.
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||
|
# - this does only account for temporary memory usage while loading
|
||
|
# the data needed to compute the scores -- the returned scores
|
||
|
# themselves are 1D.
|
||
|
|
||
|
chunk_n_rows = get_chunk_n_rows(
|
||
|
row_bytes=16 * self._max_features, max_n_rows=n_samples
|
||
|
)
|
||
|
slices = gen_batches(n_samples, chunk_n_rows)
|
||
|
|
||
|
scores = np.zeros(n_samples, order="f")
|
||
|
|
||
|
for sl in slices:
|
||
|
# compute score on the slices of test samples:
|
||
|
scores[sl] = self._compute_score_samples(X[sl], subsample_features)
|
||
|
|
||
|
return scores
|
||
|
|
||
|
def _compute_score_samples(self, X, subsample_features):
|
||
|
"""
|
||
|
Compute the score of each samples in X going through the extra trees.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
X : array-like or sparse matrix
|
||
|
Data matrix.
|
||
|
|
||
|
subsample_features : bool
|
||
|
Whether features should be subsampled.
|
||
|
"""
|
||
|
n_samples = X.shape[0]
|
||
|
|
||
|
depths = np.zeros(n_samples, order="f")
|
||
|
|
||
|
average_path_length_max_samples = _average_path_length([self._max_samples])
|
||
|
|
||
|
for tree_idx, (tree, features) in enumerate(
|
||
|
zip(self.estimators_, self.estimators_features_)
|
||
|
):
|
||
|
X_subset = X[:, features] if subsample_features else X
|
||
|
|
||
|
leaves_index = tree.apply(X_subset, check_input=False)
|
||
|
|
||
|
depths += (
|
||
|
self._decision_path_lengths[tree_idx][leaves_index]
|
||
|
+ self._average_path_length_per_tree[tree_idx][leaves_index]
|
||
|
- 1.0
|
||
|
)
|
||
|
denominator = len(self.estimators_) * average_path_length_max_samples
|
||
|
scores = 2 ** (
|
||
|
# For a single training sample, denominator and depth are 0.
|
||
|
# Therefore, we set the score manually to 1.
|
||
|
-np.divide(
|
||
|
depths, denominator, out=np.ones_like(depths), where=denominator != 0
|
||
|
)
|
||
|
)
|
||
|
return scores
|
||
|
|
||
|
def _more_tags(self):
|
||
|
return {
|
||
|
"_xfail_checks": {
|
||
|
"check_sample_weights_invariance": (
|
||
|
"zero sample_weight is not equivalent to removing samples"
|
||
|
),
|
||
|
}
|
||
|
}
|
||
|
|
||
|
|
||
|
def _average_path_length(n_samples_leaf):
|
||
|
"""
|
||
|
The average path length in a n_samples iTree, which is equal to
|
||
|
the average path length of an unsuccessful BST search since the
|
||
|
latter has the same structure as an isolation tree.
|
||
|
Parameters
|
||
|
----------
|
||
|
n_samples_leaf : array-like of shape (n_samples,)
|
||
|
The number of training samples in each test sample leaf, for
|
||
|
each estimators.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
average_path_length : ndarray of shape (n_samples,)
|
||
|
"""
|
||
|
|
||
|
n_samples_leaf = check_array(n_samples_leaf, ensure_2d=False)
|
||
|
|
||
|
n_samples_leaf_shape = n_samples_leaf.shape
|
||
|
n_samples_leaf = n_samples_leaf.reshape((1, -1))
|
||
|
average_path_length = np.zeros(n_samples_leaf.shape)
|
||
|
|
||
|
mask_1 = n_samples_leaf <= 1
|
||
|
mask_2 = n_samples_leaf == 2
|
||
|
not_mask = ~np.logical_or(mask_1, mask_2)
|
||
|
|
||
|
average_path_length[mask_1] = 0.0
|
||
|
average_path_length[mask_2] = 1.0
|
||
|
average_path_length[not_mask] = (
|
||
|
2.0 * (np.log(n_samples_leaf[not_mask] - 1.0) + np.euler_gamma)
|
||
|
- 2.0 * (n_samples_leaf[not_mask] - 1.0) / n_samples_leaf[not_mask]
|
||
|
)
|
||
|
|
||
|
return average_path_length.reshape(n_samples_leaf_shape)
|