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steminc
steminc / scikit-learn python
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Version:
0.15.2 ▾
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scikit-learn
/
multiclass.py
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"""
Multiclass and multilabel classification strategies
===================================================
This module implements multiclass learning algorithms:
- one-vs-the-rest / one-vs-all
- one-vs-one
- error correcting output codes
The estimators provided in this module are meta-estimators: they require a base
estimator to be provided in their constructor. For example, it is possible to
use these estimators to turn a binary classifier or a regressor into a
multiclass classifier. It is also possible to use these estimators with
multiclass estimators in the hope that their accuracy or runtime performance
improves.
All classifiers in scikit-learn implement multiclass classification; you
only need to use this module if you want to experiment with custom multiclass
strategies.
The one-vs-the-rest meta-classifier also implements a `predict_proba` method,
so long as such a method is implemented by the base classifier. This method
returns probabilities of class membership in both the single label and
multilabel case. Note that in the multilabel case, probabilities are the
marginal probability that a given sample falls in the given class. As such, in
the multilabel case the sum of these probabilities over all possible labels
for a given sample *will not* sum to unity, as they do in the single label
case.
"""
# Author: Mathieu Blondel <mathieu@mblondel.org>
#
# License: BSD 3 clause
import numpy as np
import warnings
from .base import BaseEstimator, ClassifierMixin, clone, is_classifier
from .base import MetaEstimatorMixin
from .preprocessing import LabelBinarizer
from .metrics.pairwise import euclidean_distances
from .utils import check_random_state
from .externals.joblib import Parallel
from .externals.joblib import delayed
def _fit_binary(estimator, X, y, classes=None):
"""Fit a single binary estimator."""
unique_y = np.unique(y)
if len(unique_y) == 1:
if classes is not None:
if y[0] == -1:
c = 0
else:
c = y[0]
warnings.warn("Label %s is present in all training examples." %
str(classes[c]))
estimator = _ConstantPredictor().fit(X, unique_y)
else:
estimator = clone(estimator)
estimator.fit(X, y)
return estimator
def _predict_binary(estimator, X):
"""Make predictions using a single binary estimator."""
try:
score = np.ravel(estimator.decision_function(X))
except (AttributeError, NotImplementedError):
# probabilities of the positive class
score = estimator.predict_proba(X)[:, 1]
return score
def _check_estimator(estimator):
"""Make sure that an estimator implements the necessary methods."""
if (not hasattr(estimator, "decision_function") and
not hasattr(estimator, "predict_proba")):
raise ValueError("The base estimator should implement "
"decision_function or predict_proba!")
def fit_ovr(estimator, X, y, n_jobs=1):
"""Fit a one-vs-the-rest strategy."""
_check_estimator(estimator)
lb = LabelBinarizer()
Y = lb.fit_transform(y)
estimators = Parallel(n_jobs=n_jobs)(
delayed(_fit_binary)(estimator, X, Y[:, i], classes=["not %s" % i, i])
for i in range(Y.shape[1]))
return estimators, lb
def predict_ovr(estimators, label_binarizer, X):
"""Make predictions using the one-vs-the-rest strategy."""
Y = np.array([_predict_binary(e, X) for e in estimators])
e = estimators[0]
thresh = 0 if hasattr(e, "decision_function") and is_classifier(e) else .5
return label_binarizer.inverse_transform(Y.T, threshold=thresh)
def predict_proba_ovr(estimators, X, is_multilabel):
"""Estimate probabilities using the one-vs-the-rest strategy.
If multilabel is true, returned matrix will not sum to one. Estimators
must have a predict_proba method."""
# Y[i,j] gives the probability that sample i has the label j.
# In the multi-label case, these are not disjoint.
Y = np.array([est.predict_proba(X)[:, 1] for est in estimators]).T
if not is_multilabel:
# Then, probabilities should be normalized to 1.
Y /= np.sum(Y, axis=1)[:, np.newaxis]
return Y
class _ConstantPredictor(BaseEstimator):
def fit(self, X, y):
self.y_ = y
return self
def predict(self, X):
return np.repeat(self.y_, X.shape[0])
def decision_function(self, X):
return np.repeat(self.y_, X.shape[0])
def predict_proba(self, X):
return np.repeat([np.hstack([1 - self.y_, self.y_])],
X.shape[0], axis=0)
class OneVsRestClassifier(BaseEstimator, ClassifierMixin, MetaEstimatorMixin):
"""One-vs-the-rest (OvR) multiclass/multilabel strategy
Also known as one-vs-all, this strategy consists in fitting one classifier
per class. For each classifier, the class is fitted against all the other
classes. In addition to its computational efficiency (only `n_classes`
classifiers are needed), one advantage of this approach is its
interpretability. Since each class is represented by one and one classifier
only, it is possible to gain knowledge about the class by inspecting its
corresponding classifier. This is the most commonly used strategy for
multiclass classification and is a fair default choice.
This strategy can also be used for multilabel learning, where a classifier
is used to predict multiple labels for instance, by fitting on a 2-d matrix
in which cell [i, j] is 1 if sample i has label j and 0 otherwise.
In the multilabel learning literature, OvR is also known as the binary
relevance method.
Parameters
----------
estimator : estimator object
An estimator object implementing `fit` and one of `decision_function`
or `predict_proba`.
n_jobs : int, optional, default: 1
The number of jobs to use for the computation. If -1 all CPUs are used.
If 1 is given, no parallel computing code is used at all, which is
useful for debugging. For n_jobs below -1, (n_cpus + 1 + n_jobs) are
used. Thus for n_jobs = -2, all CPUs but one are used.
Attributes
----------
`estimators_` : list of `n_classes` estimators
Estimators used for predictions.
`classes_` : array, shape = [`n_classes`]
Class labels.
`label_binarizer_` : LabelBinarizer object
Object used to transform multiclass labels to binary labels and
vice-versa.
`multilabel_` : boolean
Whether a OneVsRestClassifier is a multilabel classifier.
"""
def __init__(self, estimator, n_jobs=1):
self.estimator = estimator
self.n_jobs = n_jobs
def fit(self, X, y):
"""Fit underlying estimators.
Parameters
----------
X : {array-like, sparse matrix}, shape = [n_samples, n_features]
Data.
y : array-like, shape = [n_samples] or [n_samples, n_classes]
Multi-class targets. An indicator matrix turns on multilabel
classification.
Returns
-------
self
"""
self.estimators_, self.label_binarizer_ = fit_ovr(self.estimator, X, y,
n_jobs=self.n_jobs)
return self
def _check_is_fitted(self):
if not hasattr(self, "estimators_"):
raise ValueError("The object hasn't been fitted yet!")
def predict(self, X):
"""Predict multi-class targets using underlying estimators.
Parameters
----------
X : {array-like, sparse matrix}, shape = [n_samples, n_features]
Data.
Returns
-------
y : array-like, shape = [n_samples]
Predicted multi-class targets.
"""
self._check_is_fitted()
return predict_ovr(self.estimators_, self.label_binarizer_, X)
def predict_proba(self, X):
"""Probability estimates.
The returned estimates for all classes are ordered by label of classes.
Note that in the multilabel case, each sample can have any number of
labels. This returns the marginal probability that the given sample has
the label in question. For example, it is entirely consistent that two
labels both have a 90% probability of applying to a given sample.
In the single label multiclass case, the rows of the returned matrix
sum to 1.
Parameters
----------
X : array-like, shape = [n_samples, n_features]
Returns
-------
T : array-like, shape = [n_samples, n_classes]
Returns the probability of the sample for each class in the model,
where classes are ordered as they are in `self.classes_`.
"""
return predict_proba_ovr(self.estimators_, X,
is_multilabel=self.multilabel_)
def decision_function(self, X):
"""Returns the distance of each sample from the decision boundary for
each class. This can only be used with estimators which implement the
decision_function method.
Parameters
----------
X : array-like, shape = [n_samples, n_features]
Returns
-------
T : array-like, shape = [n_samples, n_classes]
"""
if not hasattr(self.estimators_[0], "decision_function"):
raise AttributeError(
"Base estimator doesn't have a decision_function attribute.")
return np.array([est.decision_function(X).ravel()
for est in self.estimators_]).T
@property
def multilabel_(self):
"""Whether this is a multilabel classifier"""
return self.label_binarizer_.multilabel_
def score(self, X, y):
if self.multilabel_:
raise NotImplementedError(
"score is not supported for multilabel classifiers")
else:
return super(OneVsRestClassifier, self).score(X, y)
@property
def classes_(self):
return self.label_binarizer_.classes_
@property
def coef_(self):
self._check_is_fitted()
if not hasattr(self.estimators_[0], "coef_"):
raise AttributeError(
"Base estimator doesn't have a coef_ attribute.")
return np.array([e.coef_.ravel() for e in self.estimators_])
@property
def intercept_(self):
self._check_is_fitted()
if not hasattr(self.estimators_[0], "intercept_"):
raise AttributeError(
"Base estimator doesn't have an intercept_ attribute.")
return np.array([e.intercept_.ravel() for e in self.estimators_])
def _fit_ovo_binary(estimator, X, y, i, j):
"""Fit a single binary estimator (one-vs-one)."""
cond = np.logical_or(y == i, y == j)
y = y[cond]
y_binary = np.empty(y.shape, np.int)
y_binary[y == i] = 0
y_binary[y == j] = 1
ind = np.arange(X.shape[0])
return _fit_binary(estimator, X[ind[cond]], y_binary, classes=[i, j])
def fit_ovo(estimator, X, y, n_jobs=1):
"""Fit a one-vs-one strategy."""
classes = np.unique(y)
n_classes = classes.shape[0]
estimators = Parallel(n_jobs=n_jobs)(
delayed(_fit_ovo_binary)(
estimator, X, y, classes[i], classes[j])
for i in range(n_classes) for j in range(i + 1, n_classes))
return estimators, classes
def predict_ovo(estimators, classes, X):
"""Make predictions using the one-vs-one strategy."""
n_samples = X.shape[0]
n_classes = classes.shape[0]
votes = np.zeros((n_samples, n_classes))
scores = np.zeros((n_samples, n_classes))
k = 0
for i in range(n_classes):
for j in range(i + 1, n_classes):
pred = estimators[k].predict(X)
score = _predict_binary(estimators[k], X)
scores[:, i] -= score
scores[:, j] += score
votes[pred == 0, i] += 1
votes[pred == 1, j] += 1
k += 1
# find all places with maximum votes per sample
maxima = votes == np.max(votes, axis=1)[:, np.newaxis]
# if there are ties, use scores to break them
if np.any(maxima.sum(axis=1) > 1):
scores[~maxima] = -np.inf
prediction = scores.argmax(axis=1)
else:
prediction = votes.argmax(axis=1)
return classes[prediction]
class OneVsOneClassifier(BaseEstimator, ClassifierMixin, MetaEstimatorMixin):
"""One-vs-one multiclass strategy
This strategy consists in fitting one classifier per class pair.
At prediction time, the class which received the most votes is selected.
Since it requires to fit `n_classes * (n_classes - 1) / 2` classifiers,
this method is usually slower than one-vs-the-rest, due to its
O(n_classes^2) complexity. However, this method may be advantageous for
algorithms such as kernel algorithms which don't scale well with
`n_samples`. This is because each individual learning problem only involves
a small subset of the data whereas, with one-vs-the-rest, the complete
dataset is used `n_classes` times.
Parameters
----------
estimator : estimator object
An estimator object implementing `fit` and one of `decision_function`
or `predict_proba`.
n_jobs : int, optional, default: 1
The number of jobs to use for the computation. If -1 all CPUs are used.
If 1 is given, no parallel computing code is used at all, which is
useful for debugging. For n_jobs below -1, (n_cpus + 1 + n_jobs) are
used. Thus for n_jobs = -2, all CPUs but one are used.
Attributes
----------
`estimators_` : list of `n_classes * (n_classes - 1) / 2` estimators
Estimators used for predictions.
`classes_` : numpy array of shape [n_classes]
Array containing labels.
"""
def __init__(self, estimator, n_jobs=1):
self.estimator = estimator
self.n_jobs = n_jobs
def fit(self, X, y):
"""Fit underlying estimators.
Parameters
----------
X : {array-like, sparse matrix}, shape = [n_samples, n_features]
Data.
y : numpy array of shape [n_samples]
Multi-class targets.
Returns
-------
self
"""
self.estimators_, self.classes_ = fit_ovo(self.estimator, X, y,
self.n_jobs)
return self
def predict(self, X):
"""Predict multi-class targets using underlying estimators.
Parameters
----------
X : {array-like, sparse matrix}, shape = [n_samples, n_features]
Data.
Returns
-------
y : numpy array of shape [n_samples]
Predicted multi-class targets.
"""
if not hasattr(self, "estimators_"):
raise ValueError("The object hasn't been fitted yet!")
return predict_ovo(self.estimators_, self.classes_, X)
def fit_ecoc(estimator, X, y, code_size=1.5, random_state=None, n_jobs=1):
"""
Fit an error-correcting output-code strategy.
Parameters
----------
estimator : estimator object
An estimator object implementing `fit` and one of `decision_function`
or `predict_proba`.
code_size : float, optional
Percentage of the number of classes to be used to create the code book.
random_state : numpy.RandomState, optional
The generator used to initialize the codebook. Defaults to
numpy.random.
Returns
--------
estimators : list of `int(n_classes * code_size)` estimators
Estimators used for predictions.
classes : numpy array of shape [n_classes]
Array containing labels.
`code_book_`: numpy array of shape [n_classes, code_size]
Binary array containing the code of each class.
"""
_check_estimator(estimator)
random_state = check_random_state(random_state)
classes = np.unique(y)
n_classes = classes.shape[0]
code_size = int(n_classes * code_size)
# FIXME: there are more elaborate methods than generating the codebook
# randomly.
code_book = random_state.random_sample((n_classes, code_size))
code_book[code_book > 0.5] = 1
if hasattr(estimator, "decision_function"):
code_book[code_book != 1] = -1
else:
code_book[code_book != 1] = 0
cls_idx = dict((c, i) for i, c in enumerate(classes))
Y = np.array([code_book[cls_idx[y[i]]] for i in range(X.shape[0])],
dtype=np.int)
estimators = Parallel(n_jobs=n_jobs)(
delayed(_fit_binary)(estimator, X, Y[:, i])
for i in range(Y.shape[1]))
return estimators, classes, code_book
def predict_ecoc(estimators, classes, code_book, X):
"""Make predictions using the error-correcting output-code strategy."""
Y = np.array([_predict_binary(e, X) for e in estimators]).T
pred = euclidean_distances(Y, code_book).argmin(axis=1)
return classes[pred]
class OutputCodeClassifier(BaseEstimator, ClassifierMixin, MetaEstimatorMixin):
"""(Error-Correcting) Output-Code multiclass strategy
Output-code based strategies consist in representing each class with a
binary code (an array of 0s and 1s). At fitting time, one binary
classifier per bit in the code book is fitted. At prediction time, the
classifiers are used to project new points in the class space and the class
closest to the points is chosen. The main advantage of these strategies is
that the number of classifiers used can be controlled by the user, either
for compressing the model (0 < code_size < 1) or for making the model more
robust to errors (code_size > 1). See the documentation for more details.
Parameters
----------
estimator : estimator object
An estimator object implementing `fit` and one of `decision_function`
or `predict_proba`.
code_size : float
Percentage of the number of classes to be used to create the code book.
A number between 0 and 1 will require fewer classifiers than
one-vs-the-rest. A number greater than 1 will require more classifiers
than one-vs-the-rest.
random_state : numpy.RandomState, optional
The generator used to initialize the codebook. Defaults to
numpy.random.
n_jobs : int, optional, default: 1
The number of jobs to use for the computation. If -1 all CPUs are used.
If 1 is given, no parallel computing code is used at all, which is
useful for debugging. For n_jobs below -1, (n_cpus + 1 + n_jobs) are
used. Thus for n_jobs = -2, all CPUs but one are used.
Attributes
----------
`estimators_` : list of `int(n_classes * code_size)` estimators
Estimators used for predictions.
`classes_` : numpy array of shape [n_classes]
Array containing labels.
`code_book_` : numpy array of shape [n_classes, code_size]
Binary array containing the code of each class.
References
----------
.. [1] "Solving multiclass learning problems via error-correcting output
codes",
Dietterich T., Bakiri G.,
Journal of Artificial Intelligence Research 2,
1995.
.. [2] "The error coding method and PICTs",
James G., Hastie T.,
Journal of Computational and Graphical statistics 7,
1998.
.. [3] "The Elements of Statistical Learning",
Hastie T., Tibshirani R., Friedman J., page 606 (second-edition)
2008.
"""
def __init__(self, estimator, code_size=1.5, random_state=None, n_jobs=1):
if (code_size <= 0):
raise ValueError("code_size should be greater than 0!")
self.estimator = estimator
self.code_size = code_size
self.random_state = random_state
self.n_jobs = n_jobs
def fit(self, X, y):
"""Fit underlying estimators.
Parameters
----------
X : {array-like, sparse matrix}, shape = [n_samples, n_features]
Data.
y : numpy array of shape [n_samples]
Multi-class targets.
Returns
-------
self
"""
self.estimators_, self.classes_, self.code_book_ = \
fit_ecoc(self.estimator, X, y, self.code_size, self.random_state,
self.n_jobs)
return self
def predict(self, X):
"""Predict multi-class targets using underlying estimators.
Parameters
----------
X : {array-like, sparse matrix}, shape = [n_samples, n_features]
Data.
Returns
-------
y : numpy array of shape [n_samples]
Predicted multi-class targets.
"""
if not hasattr(self, "estimators_"):
raise ValueError("The object hasn't been fitted yet!")
return predict_ecoc(self.estimators_, self.classes_,
self.code_book_, X)