from abc import ABC, abstractmethod from copy import deepcopy from typing import Callable, Union import numpy as np from abstention.calibration import NoBiasVectorScaling, TempScaling, VectorScaling from scipy import optimize from sklearn.base import BaseEstimator from sklearn.calibration import CalibratedClassifierCV from sklearn.metrics import confusion_matrix from sklearn.model_selection import cross_val_predict import quapy as qp import quapy.functional as F from quapy.functional import get_divergence from quapy.classification.calibration import NBVSCalibration, BCTSCalibration, TSCalibration, VSCalibration from quapy.classification.svmperf import SVMperf from quapy.data import LabelledCollection from quapy.method.base import BaseQuantifier, BinaryQuantifier, OneVsAllGeneric # Abstract classes # ------------------------------------ class AggregativeQuantifier(BaseQuantifier, ABC): """ Abstract class for quantification methods that base their estimations on the aggregation of classification results. Aggregative quantifiers implement a pipeline that consists of generating classification predictions and aggregating them. For this reason, the training phase is implemented by :meth:`classification_fit` followed by :meth:`aggregation_fit`, while the testing phase is implemented by :meth:`classify` followed by :meth:`aggregate`. Subclasses of this abstract class must provide implementations for these methods. Aggregative quantifiers also maintain a :attr:`classifier` attribute. The method :meth:`fit` comes with a default implementation based on :meth:`classification_fit` and :meth:`aggregation_fit`. The method :meth:`quantify` comes with a default implementation based on :meth:`classify` and :meth:`aggregate`. """ val_split_ = None @property def val_split(self): return self.val_split_ @val_split.setter def val_split(self, val_split): if isinstance(val_split, LabelledCollection): print('warning: setting val_split with a LabelledCollection will be inefficient in' 'model selection. Rather pass the LabelledCollection at fit time') self.val_split_ = val_split def _check_init_parameters(self): """ Implements any check to be performed in the parameters of the init method before undertaking the training of the quantifier. This is made as to allow for a quick execution stop when the parameters are not valid. :return: Nothing. May raise an exception. """ pass def _check_non_empty_classes(self, data: LabelledCollection): """ Asserts all classes have positive instances. :param data: LabelledCollection :return: Nothing. May raise an exception. """ sample_prevs = data.prevalence() empty_classes = np.argwhere(sample_prevs==0).flatten() if len(empty_classes)>0: empty_class_names = data.classes_[empty_classes] raise ValueError(f'classes {empty_class_names} have no training examples') def fit(self, data: LabelledCollection, fit_classifier=True, val_split=None): """ Trains the aggregative quantifier. This comes down to training a classifier and an aggregation function. :param data: a :class:`quapy.data.base.LabelledCollection` consisting of the training data :param fit_classifier: whether to train the learner (default is True). Set to False if the learner has been trained outside the quantifier. :return: self """ self._check_init_parameters() classif_predictions = self.classifier_fit_predict(data, fit_classifier, predict_on=val_split) self.aggregation_fit(classif_predictions, data) return self def classifier_fit_predict(self, data: LabelledCollection, fit_classifier=True, predict_on=None): """ Trains the classifier if requested (`fit_classifier=True`) and generate the necessary predictions to train the aggregation function. :param data: a :class:`quapy.data.base.LabelledCollection` consisting of the training data :param fit_classifier: whether to train the learner (default is True). Set to False if the learner has been trained outside the quantifier. :param predict_on: specifies the set on which predictions need to be issued. This parameter can be specified as None (default) to indicate no prediction is needed; a float in (0, 1) to indicate the proportion of instances to be used for predictions (the remainder is used for training); an integer >1 to indicate that the predictions must be generated via k-fold cross-validation, using this integer as k; or the data sample itself on which to generate the predictions. """ assert isinstance(fit_classifier, bool), 'unexpected type for "fit_classifier", must be boolean' self._check_classifier(adapt_if_necessary=(self._classifier_method() == 'predict_proba')) if fit_classifier: self._check_non_empty_classes(data) if predict_on is None: predict_on = self.val_split if predict_on is None: if fit_classifier: self.classifier.fit(*data.Xy) predictions = None elif isinstance(predict_on, float): if fit_classifier: if not (0. < predict_on < 1.): raise ValueError(f'proportion {predict_on=} out of range, must be in (0,1)') train, val = data.split_stratified(train_prop=(1 - predict_on)) self.classifier.fit(*train.Xy) predictions = LabelledCollection(self.classify(val.X), val.y, classes=data.classes_) else: raise ValueError(f'wrong type for predict_on: since fit_classifier=False, ' f'the set on which predictions have to be issued must be ' f'explicitly indicated') elif isinstance(predict_on, LabelledCollection): if fit_classifier: self.classifier.fit(*data.Xy) predictions = LabelledCollection(self.classify(predict_on.X), predict_on.y, classes=predict_on.classes_) elif isinstance(predict_on, int): if fit_classifier: if predict_on <= 1: raise ValueError(f'invalid value {predict_on} in fit. ' f'Specify a integer >1 for kFCV estimation.') else: n_jobs = self.n_jobs if hasattr(self, 'n_jobs') else qp._get_njobs(None) predictions = cross_val_predict( self.classifier, *data.Xy, cv=predict_on, n_jobs=n_jobs, method=self._classifier_method()) predictions = LabelledCollection(predictions, data.y, classes=data.classes_) self.classifier.fit(*data.Xy) else: raise ValueError(f'wrong type for predict_on: since fit_classifier=False, ' f'the set on which predictions have to be issued must be ' f'explicitly indicated') else: raise ValueError( f'error: param "predict_on" ({type(predict_on)}) not understood; ' f'use either a float indicating the split proportion, or a ' f'tuple (X,y) indicating the validation partition') return predictions @abstractmethod def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Trains the aggregation function. :param classif_predictions: a LabelledCollection containing the label predictions issued by the classifier :param data: a :class:`quapy.data.base.LabelledCollection` consisting of the training data """ ... @property def classifier(self): """ Gives access to the classifier :return: the classifier (typically an sklearn's Estimator) """ return self.classifier_ @classifier.setter def classifier(self, classifier): """ Setter for the classifier :param classifier: the classifier """ self.classifier_ = classifier def classify(self, instances): """ Provides the label predictions for the given instances. The predictions should respect the format expected by :meth:`aggregate`, e.g., posterior probabilities for probabilistic quantifiers, or crisp predictions for non-probabilistic quantifiers. The default one is "decision_function". :param instances: array-like of shape `(n_instances, n_features,)` :return: np.ndarray of shape `(n_instances,)` with label predictions """ return getattr(self.classifier, self._classifier_method())(instances) def _classifier_method(self): """ Name of the method that must be used for issuing label predictions. The default one is "decision_function". :return: string """ return 'decision_function' def _check_classifier(self, adapt_if_necessary=False): """ Guarantees that the underlying classifier implements the method required for issuing predictions, i.e., the method indicated by the :meth:`_classifier_method` :param adapt_if_necessary: if True, the method will try to comply with the required specifications """ assert hasattr(self.classifier, self._classifier_method()), \ f"the method does not implement the required {self._classifier_method()} method" def quantify(self, instances): """ Generate class prevalence estimates for the sample's instances by aggregating the label predictions generated by the classifier. :param instances: array-like :return: `np.ndarray` of shape `(n_classes)` with class prevalence estimates. """ classif_predictions = self.classify(instances) return self.aggregate(classif_predictions) @abstractmethod def aggregate(self, classif_predictions: np.ndarray): """ Implements the aggregation of label predictions. :param classif_predictions: `np.ndarray` of label predictions :return: `np.ndarray` of shape `(n_classes,)` with class prevalence estimates. """ ... @property def classes_(self): """ Class labels, in the same order in which class prevalence values are to be computed. This default implementation actually returns the class labels of the learner. :return: array-like """ return self.classifier.classes_ class AggregativeCrispQuantifier(AggregativeQuantifier, ABC): """ Abstract class for quantification methods that base their estimations on the aggregation of crips decisions as returned by a hard classifier. Aggregative crisp quantifiers thus extend Aggregative Quantifiers by implementing specifications about crisp predictions. """ def _classifier_method(self): """ Name of the method that must be used for issuing label predictions. For crisp quantifiers, the method is 'predict', that returns an array of shape `(n_instances,)` of label predictions. :return: the string "predict", i.e., the standard method name for scikit-learn hard predictions """ return 'predict' class AggregativeSoftQuantifier(AggregativeQuantifier, ABC): """ Abstract class for quantification methods that base their estimations on the aggregation of posterior probabilities as returned by a probabilistic classifier. Aggregative soft quantifiers thus extend Aggregative Quantifiers by implementing specifications about soft predictions. """ def _classifier_method(self): """ Name of the method that must be used for issuing label predictions. For probabilistic quantifiers, the method is 'predict_proba', that returns an array of shape `(n_instances, n_dimensions,)` with posterior probabilities. :return: the string "predict_proba", i.e., the standard method name for scikit-learn soft predictions """ return 'predict_proba' def _check_classifier(self, adapt_if_necessary=False): """ Guarantees that the underlying classifier implements the method indicated by the :meth:`_classifier_method`. In case it does not, the classifier is calibrated (by means of the Platt's calibration method implemented by scikit-learn in CalibratedClassifierCV, with cv=5). This calibration is only allowed if `adapt_if_necessary` is set to True. If otherwise (i.e., the classifier is not probabilistic, and `adapt_if_necessary` is set to False), an exception will be raised. :param adapt_if_necessary: a hard classifier is turned into a soft classifier if `adapt_if_necessary==True` """ if not hasattr(self.classifier, self._classifier_method()): if adapt_if_necessary: print(f'warning: The learner {self.classifier.__class__.__name__} does not seem to be ' f'probabilistic. The learner will be calibrated (using CalibratedClassifierCV).') self.classifier = CalibratedClassifierCV(self.classifier, cv=5) else: raise AssertionError(f'error: The learner {self.classifier.__class__.__name__} does not ' f'seem to be probabilistic. The learner cannot be calibrated since ' f'fit_classifier is set to False') class BinaryAggregativeQuantifier(AggregativeQuantifier, BinaryQuantifier): @property def pos_label(self): return self.classifier.classes_[1] @property def neg_label(self): return self.classifier.classes_[0] def fit(self, data: LabelledCollection, fit_classifier=True, val_split=None): self._check_binary(data, self.__class__.__name__) return super().fit(data, fit_classifier, val_split) # Methods # ------------------------------------ class CC(AggregativeCrispQuantifier): """ The most basic Quantification method. One that simply classifies all instances and counts how many have been attributed to each of the classes in order to compute class prevalence estimates. :param classifier: a sklearn's Estimator that generates a classifier """ def __init__(self, classifier: BaseEstimator): self.classifier = classifier def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Nothing to do here! :param classif_predictions: this is actually None """ pass def aggregate(self, classif_predictions: np.ndarray): """ Computes class prevalence estimates by counting the prevalence of each of the predicted labels. :param classif_predictions: array-like with label predictions :return: `np.ndarray` of shape `(n_classes,)` with class prevalence estimates. """ return F.prevalence_from_labels(classif_predictions, self.classes_) class ACC(AggregativeCrispQuantifier): """ `Adjusted Classify & Count `_, the "adjusted" variant of :class:`CC`, that corrects the predictions of CC according to the `misclassification rates`. :param classifier: a sklearn's Estimator that generates a classifier :param val_split: specifies the data used for generating classifier predictions. This specification can be made as float in (0, 1) indicating the proportion of stratified held-out validation set to be extracted from the training set; or as an integer (default 5), indicating that the predictions are to be generated in a `k`-fold cross-validation manner (with this integer indicating the value for `k`); or as a collection defining the specific set of data to use for validation. Alternatively, this set can be specified at fit time by indicating the exact set of data on which the predictions are to be generated. :param n_jobs: number of parallel workers :param solver: indicates the method to be used for obtaining the final estimates. The choice 'exact' comes down to solving the system of linear equations :math:`Ax=B` where `A` is a matrix containing the class-conditional probabilities of the predictions (e.g., the tpr and fpr in binary) and `B` is the vector of prevalence values estimated via CC, as :math:`x=A^{-1}B`. This solution might not exist for degenerated classifiers, in which case the method defaults to classify and count (i.e., does not attempt any adjustment). Another option is to search for the prevalence vector that minimizes the L2 norm of :math:`|Ax-B|`. The latter is achieved by indicating solver='minimize'. This one generally works better, and is the default parameter. More details about this can be consulted in `Bunse, M. "On Multi-Class Extensions of Adjusted Classify and Count", on proceedings of the 2nd International Workshop on Learning to Quantify: Methods and Applications (LQ 2022), ECML/PKDD 2022, Grenoble (France) `_. """ def __init__(self, classifier: BaseEstimator, val_split=5, n_jobs=None, solver='minimize'): self.classifier = classifier self.val_split = val_split self.n_jobs = qp._get_njobs(n_jobs) self.solver = solver def _check_init_parameters(self): assert self.solver in ['exact', 'minimize'], "unknown solver; valid ones are 'exact', 'minimize'" def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Estimates the misclassification rates. :param classif_predictions: classifier predictions with true labels """ pred_labels, true_labels = classif_predictions.Xy self.cc = CC(self.classifier) self.Pte_cond_estim_ = self.getPteCondEstim(self.classifier.classes_, true_labels, pred_labels) @classmethod def getPteCondEstim(cls, classes, y, y_): # estimate the matrix with entry (i,j) being the estimate of P(hat_yi|yj), that is, the probability that a # document that belongs to yj ends up being classified as belonging to yi conf = confusion_matrix(y, y_, labels=classes).T conf = conf.astype(float) class_counts = conf.sum(axis=0) for i, _ in enumerate(classes): if class_counts[i] == 0: conf[i, i] = 1 else: conf[:, i] /= class_counts[i] return conf def aggregate(self, classif_predictions): prevs_estim = self.cc.aggregate(classif_predictions) return ACC.solve_adjustment(self.Pte_cond_estim_, prevs_estim, solver=self.solver) @classmethod def solve_adjustment(cls, PteCondEstim, prevs_estim, solver='exact'): """ Solves the system linear system :math:`Ax = B` with :math:`A` = `PteCondEstim` and :math:`B` = `prevs_estim` :param PteCondEstim: a `np.ndarray` of shape `(n_classes,n_classes,)` with entry `(i,j)` being the estimate of :math:`P(y_i|y_j)`, that is, the probability that an instance that belongs to :math:`y_j` ends up being classified as belonging to :math:`y_i` :param prevs_estim: a `np.ndarray` of shape `(n_classes,)` with the class prevalence estimates :param solver: indicates the method to use for solving the system of linear equations. Valid options are 'exact' (tries to solve the system --may fail if the misclassificatin matrix has rank < n_classes) or 'optim_minimize' (minimizes a norm --always exists). :return: an adjusted `np.ndarray` of shape `(n_classes,)` with the corrected class prevalence estimates """ A = PteCondEstim B = prevs_estim if solver == 'exact': # attempts an exact solution of the linear system (may fail) try: adjusted_prevs = np.linalg.solve(A, B) adjusted_prevs = np.clip(adjusted_prevs, 0, 1) adjusted_prevs /= adjusted_prevs.sum() except np.linalg.LinAlgError: adjusted_prevs = prevs_estim # no way to adjust them! return adjusted_prevs elif solver == 'minimize': # poses the problem as an optimization one, and tries to minimize the norm of the differences def loss(prev): return np.linalg.norm(A @ prev - B) return F.optim_minimize(loss, n_classes=A.shape[0]) class PCC(AggregativeSoftQuantifier): """ `Probabilistic Classify & Count `_, the probabilistic variant of CC that relies on the posterior probabilities returned by a probabilistic classifier. :param classifier: a sklearn's Estimator that generates a classifier """ def __init__(self, classifier: BaseEstimator): self.classifier = classifier def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Nothing to do here! :param classif_predictions: this is actually None """ pass def aggregate(self, classif_posteriors): return F.prevalence_from_probabilities(classif_posteriors, binarize=False) class PACC(AggregativeSoftQuantifier): """ `Probabilistic Adjusted Classify & Count `_, the probabilistic variant of ACC that relies on the posterior probabilities returned by a probabilistic classifier. :param classifier: a sklearn's Estimator that generates a classifier :param val_split: specifies the data used for generating classifier predictions. This specification can be made as float in (0, 1) indicating the proportion of stratified held-out validation set to be extracted from the training set; or as an integer (default 5), indicating that the predictions are to be generated in a `k`-fold cross-validation manner (with this integer indicating the value for `k`). Alternatively, this set can be specified at fit time by indicating the exact set of data on which the predictions are to be generated. :param n_jobs: number of parallel workers :param solver: indicates the method to be used for obtaining the final estimates. The choice 'exact' comes down to solving the system of linear equations :math:`Ax=B` where `A` is a matrix containing the class-conditional probabilities of the predictions (e.g., the tpr and fpr in binary) and `B` is the vector of prevalence values estimated via CC, as :math:`x=A^{-1}B`. This solution might not exist for degenerated classifiers, in which case the method defaults to classify and count (i.e., does not attempt any adjustment). Another option is to search for the prevalence vector that minimizes the L2 norm of :math:`|Ax-B|`. The latter is achieved by indicating solver='minimize'. This one generally works better, and is the default parameter. More details about this can be consulted in `Bunse, M. "On Multi-Class Extensions of Adjusted Classify and Count", on proceedings of the 2nd International Workshop on Learning to Quantify: Methods and Applications (LQ 2022), ECML/PKDD 2022, Grenoble (France) `_. """ def __init__(self, classifier: BaseEstimator, val_split=5, n_jobs=None, solver='minimize'): self.classifier = classifier self.val_split = val_split self.n_jobs = qp._get_njobs(n_jobs) self.solver = solver def _check_init_parameters(self): assert self.solver in ['exact', 'minimize'], "unknown solver; valid ones are 'exact', 'minimize'" def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Estimates the misclassification rates :param classif_predictions: classifier soft predictions with true labels """ posteriors, true_labels = classif_predictions.Xy self.pcc = PCC(self.classifier) self.Pte_cond_estim_ = self.getPteCondEstim(self.classifier.classes_, true_labels, posteriors) def aggregate(self, classif_posteriors): prevs_estim = self.pcc.aggregate(classif_posteriors) return ACC.solve_adjustment(self.Pte_cond_estim_, prevs_estim, solver=self.solver) @classmethod def getPteCondEstim(cls, classes, y, y_): # estimate the matrix with entry (i,j) being the estimate of P(hat_yi|yj), that is, the probability that a # document that belongs to yj ends up being classified as belonging to yi n_classes = len(classes) confusion = np.eye(n_classes) for i, class_ in enumerate(classes): idx = y == class_ if idx.any(): confusion[i] = y_[idx].mean(axis=0) return confusion.T class EMQ(AggregativeSoftQuantifier): """ `Expectation Maximization for Quantification `_ (EMQ), aka `Saerens-Latinne-Decaestecker` (SLD) algorithm. EMQ consists of using the well-known `Expectation Maximization algorithm` to iteratively update the posterior probabilities generated by a probabilistic classifier and the class prevalence estimates obtained via maximum-likelihood estimation, in a mutually recursive way, until convergence. This implementation also gives access to the heuristics proposed by `Alexandari et al. paper `_. These heuristics consist of using, as the training prevalence, an estimate of it obtained via k-fold cross validation (instead of the true training prevalence), and to recalibrate the posterior probabilities of the classifier. :param classifier: a sklearn's Estimator that generates a classifier :param val_split: specifies the data used for generating classifier predictions. This specification can be made as float in (0, 1) indicating the proportion of stratified held-out validation set to be extracted from the training set; or as an integer, indicating that the predictions are to be generated in a `k`-fold cross-validation manner (with this integer indicating the value for `k`, default 5); or as a collection defining the specific set of data to use for validation. Alternatively, this set can be specified at fit time by indicating the exact set of data on which the predictions are to be generated. This hyperparameter is only meant to be used when the heuristics are to be applied, i.e., if a recalibration is required. The default value is None (meaning the recalibration is not required). In case this hyperparameter is set to a value other than None, but the recalibration is not required (recalib=None), a warning message will be raised. :param exact_train_prev: set to True (default) for using the true training prevalence as the initial observation; set to False for computing the training prevalence as an estimate of it, i.e., as the expected value of the posterior probabilities of the training instances. :param recalib: a string indicating the method of recalibration. Available choices include "nbvs" (No-Bias Vector Scaling), "bcts" (Bias-Corrected Temperature Scaling, default), "ts" (Temperature Scaling), and "vs" (Vector Scaling). Default is None (no recalibration). :param n_jobs: number of parallel workers. Only used for recalibrating the classifier if `val_split` is set to an integer `k` --the number of folds. """ MAX_ITER = 1000 EPSILON = 1e-4 def __init__(self, classifier: BaseEstimator, val_split=None, exact_train_prev=True, recalib=None, n_jobs=None): self.classifier = classifier self.val_split = val_split self.exact_train_prev = exact_train_prev self.recalib = recalib self.n_jobs = n_jobs @classmethod def EMQ_BCTS(cls, classifier: BaseEstimator, n_jobs=None): """ Constructs an instance of EMQ using the best configuration found in the `Alexandari et al. paper `_, i.e., one that relies on Bias-Corrected Temperature Scaling (BCTS) as a recalibration function, and that uses an estimate of the training prevalence instead of the true training prevalence. :param classifier: a sklearn's Estimator that generates a classifier :param n_jobs: number of parallel workers. :return: An instance of EMQ with BCTS """ return EMQ(classifier, val_split=5, exact_train_prev=False, recalib='bcts', n_jobs=n_jobs) def _check_init_parameters(self): if self.val_split is not None: if self.exact_train_prev and self.recalib is None: raise RuntimeWarning(f'The parameter {self.val_split=} was specified for EMQ, while the parameters ' f'{self.exact_train_prev=} and {self.recalib=}. This has no effect and causes an unnecessary ' f'overload.') else: if self.recalib is not None: print(f'[warning] The parameter {self.recalib=} requires the val_split be different from None. ' f'This parameter will be set to 5. To avoid this warning, set this value to a float value ' f'indicating the proportion of training data to be used as validation, or to an integer ' f'indicating the number of folds for kFCV.') self.val_split=5 def classify(self, instances): """ Provides the posterior probabilities for the given instances. If the classifier was required to be recalibrated, then these posteriors are recalibrated accordingly. :param instances: array-like of shape `(n_instances, n_dimensions,)` :return: np.ndarray of shape `(n_instances, n_classes,)` with posterior probabilities """ posteriors = self.classifier.predict_proba(instances) if hasattr(self, 'calibration_function') and self.calibration_function is not None: posteriors = self.calibration_function(posteriors) return posteriors def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): if self.recalib is not None: P, y = classif_predictions.Xy if self.recalib == 'nbvs': calibrator = NoBiasVectorScaling() elif self.recalib == 'bcts': calibrator = TempScaling(bias_positions='all') elif self.recalib == 'ts': calibrator = TempScaling() elif self.recalib == 'vs': calibrator = VectorScaling() else: raise ValueError('invalid param argument for recalibration method; available ones are ' '"nbvs", "bcts", "ts", and "vs".') self.calibration_function = calibrator(P, np.eye(data.n_classes)[y], posterior_supplied=True) if self.exact_train_prev: self.train_prevalence = data.prevalence() else: train_posteriors = classif_predictions.X if self.recalib is not None: train_posteriors = self.calibration_function(train_posteriors) self.train_prevalence = F.prevalence_from_probabilities(train_posteriors) def aggregate(self, classif_posteriors, epsilon=EPSILON): priors, posteriors = self.EM(self.train_prevalence, classif_posteriors, epsilon) return priors def predict_proba(self, instances, epsilon=EPSILON): """ Returns the posterior probabilities updated by the EM algorithm. :param instances: np.ndarray of shape `(n_instances, n_dimensions)` :param epsilon: error tolerance :return: np.ndarray of shape `(n_instances, n_classes)` """ classif_posteriors = self.classify(instances) priors, posteriors = self.EM(self.train_prevalence, classif_posteriors, epsilon) return posteriors @classmethod def EM(cls, tr_prev, posterior_probabilities, epsilon=EPSILON): """ Computes the `Expectation Maximization` routine. :param tr_prev: array-like, the training prevalence :param posterior_probabilities: `np.ndarray` of shape `(n_instances, n_classes,)` with the posterior probabilities :param epsilon: float, the threshold different between two consecutive iterations to reach before stopping the loop :return: a tuple with the estimated prevalence values (shape `(n_classes,)`) and the corrected posterior probabilities (shape `(n_instances, n_classes,)`) """ Px = posterior_probabilities Ptr = np.copy(tr_prev) qs = np.copy(Ptr) # qs (the running estimate) is initialized as the training prevalence s, converged = 0, False qs_prev_ = None while not converged and s < EMQ.MAX_ITER: # E-step: ps is Ps(y|xi) ps_unnormalized = (qs / Ptr) * Px ps = ps_unnormalized / ps_unnormalized.sum(axis=1, keepdims=True) # M-step: qs = ps.mean(axis=0) if qs_prev_ is not None and qp.error.mae(qs, qs_prev_) < epsilon and s > 10: converged = True qs_prev_ = qs s += 1 if not converged: print('[warning] the method has reached the maximum number of iterations; it might have not converged') return qs, ps class HDy(AggregativeSoftQuantifier, BinaryAggregativeQuantifier): """ `Hellinger Distance y `_ (HDy). HDy is a probabilistic method for training binary quantifiers, that models quantification as the problem of minimizing the divergence (in terms of the Hellinger Distance) between two distributions of posterior probabilities returned by the classifier. One of the distributions is generated from the unlabelled examples and the other is generated from a validation set. This latter distribution is defined as a mixture of the class-conditional distributions of the posterior probabilities returned for the positive and negative validation examples, respectively. The parameters of the mixture thus represent the estimates of the class prevalence values. :param classifier: a sklearn's Estimator that generates a binary classifier :param val_split: a float in range (0,1) indicating the proportion of data to be used as a stratified held-out validation distribution, or a :class:`quapy.data.base.LabelledCollection` (the split itself), or an integer indicating the number of folds (default 5).. """ def __init__(self, classifier: BaseEstimator, val_split=5): self.classifier = classifier self.val_split = val_split def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Trains a HDy quantifier. :param data: the training set :param fit_classifier: set to False to bypass the training (the learner is assumed to be already fit) :param val_split: either a float in (0,1) indicating the proportion of training instances to use for validation (e.g., 0.3 for using 30% of the training set as validation data), or a :class:`quapy.data.base.LabelledCollection` indicating the validation set itself :return: self """ P, y = classif_predictions.Xy Px = P[:, self.pos_label] # takes only the P(y=+1|x) self.Pxy1 = Px[y == self.pos_label] self.Pxy0 = Px[y == self.neg_label] # pre-compute the histogram for positive and negative examples self.bins = np.linspace(10, 110, 11, dtype=int) # [10, 20, 30, ..., 100, 110] def hist(P, bins): h = np.histogram(P, bins=bins, range=(0, 1), density=True)[0] return h / h.sum() self.Pxy1_density = {bins: hist(self.Pxy1, bins) for bins in self.bins} self.Pxy0_density = {bins: hist(self.Pxy0, bins) for bins in self.bins} return self def aggregate(self, classif_posteriors): # "In this work, the number of bins b used in HDx and HDy was chosen from 10 to 110 in steps of 10, # and the final estimated a priori probability was taken as the median of these 11 estimates." # (González-Castro, et al., 2013). Px = classif_posteriors[:, self.pos_label] # takes only the P(y=+1|x) prev_estimations = [] # for bins in np.linspace(10, 110, 11, dtype=int): #[10, 20, 30, ..., 100, 110] # Pxy0_density, _ = np.histogram(self.Pxy0, bins=bins, range=(0, 1), density=True) # Pxy1_density, _ = np.histogram(self.Pxy1, bins=bins, range=(0, 1), density=True) for bins in self.bins: Pxy0_density = self.Pxy0_density[bins] Pxy1_density = self.Pxy1_density[bins] Px_test, _ = np.histogram(Px, bins=bins, range=(0, 1), density=True) # the authors proposed to search for the prevalence yielding the best matching as a linear search # at small steps (modern implementations resort to an optimization procedure, # see class DistributionMatching) prev_selected, min_dist = None, None for prev in F.prevalence_linspace(n_prevalences=101, repeats=1, smooth_limits_epsilon=0.0): Px_train = prev * Pxy1_density + (1 - prev) * Pxy0_density hdy = F.HellingerDistance(Px_train, Px_test) if prev_selected is None or hdy < min_dist: prev_selected, min_dist = prev, hdy prev_estimations.append(prev_selected) class1_prev = np.median(prev_estimations) return F.as_binary_prevalence(class1_prev) class DyS(AggregativeSoftQuantifier, BinaryAggregativeQuantifier): """ `DyS framework `_ (DyS). DyS is a generalization of HDy method, using a Ternary Search in order to find the prevalence that minimizes the distance between distributions. Details for the ternary search have been got from :param classifier: a sklearn's Estimator that generates a binary classifier :param val_split: a float in range (0,1) indicating the proportion of data to be used as a stratified held-out validation distribution, or a :class:`quapy.data.base.LabelledCollection` (the split itself), or an integer indicating the number of folds (default 5).. :param n_bins: an int with the number of bins to use to compute the histograms. :param divergence: a str indicating the name of divergence (currently supported ones are "HD" or "topsoe"), or a callable function computes the divergence between two distributions (two equally sized arrays). :param tol: a float with the tolerance for the ternary search algorithm. :param n_jobs: number of parallel workers. """ def __init__(self, classifier: BaseEstimator, val_split=5, n_bins=8, divergence: Union[str, Callable]= 'HD', tol=1e-05, n_jobs=None): self.classifier = classifier self.val_split = val_split self.tol = tol self.divergence = divergence self.n_bins = n_bins self.n_jobs = n_jobs def _ternary_search(self, f, left, right, tol): """ Find maximum of unimodal function f() within [left, right] """ while abs(right - left) >= tol: left_third = left + (right - left) / 3 right_third = right - (right - left) / 3 if f(left_third) > f(right_third): left = left_third else: right = right_third # Left and right are the current bounds; the maximum is between them return (left + right) / 2 def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): Px, y = classif_predictions.Xy Px = Px[:, self.pos_label] # takes only the P(y=+1|x) self.Pxy1 = Px[y == self.pos_label] self.Pxy0 = Px[y == self.neg_label] self.Pxy1_density = np.histogram(self.Pxy1, bins=self.n_bins, range=(0, 1), density=True)[0] self.Pxy0_density = np.histogram(self.Pxy0, bins=self.n_bins, range=(0, 1), density=True)[0] return self def aggregate(self, classif_posteriors): Px = classif_posteriors[:, self.pos_label] # takes only the P(y=+1|x) Px_test = np.histogram(Px, bins=self.n_bins, range=(0, 1), density=True)[0] divergence = get_divergence(self.divergence) def distribution_distance(prev): Px_train = prev * self.Pxy1_density + (1 - prev) * self.Pxy0_density return divergence(Px_train, Px_test) class1_prev = self._ternary_search(f=distribution_distance, left=0, right=1, tol=self.tol) return F.as_binary_prevalence(class1_prev) class SMM(AggregativeSoftQuantifier, BinaryAggregativeQuantifier): """ `SMM method `_ (SMM). SMM is a simplification of matching distribution methods where the representation of the examples is created using the mean instead of a histogram (conceptually equivalent to PACC). :param classifier: a sklearn's Estimator that generates a binary classifier. :param val_split: a float in range (0,1) indicating the proportion of data to be used as a stratified held-out validation distribution, or a :class:`quapy.data.base.LabelledCollection` (the split itself), or an integer indicating the number of folds (default 5).. """ def __init__(self, classifier: BaseEstimator, val_split=5): self.classifier = classifier self.val_split = val_split def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): Px, y = classif_predictions.Xy Px = Px[:, self.pos_label] # takes only the P(y=+1|x) self.Pxy1 = Px[y == self.pos_label] self.Pxy0 = Px[y == self.neg_label] self.Pxy1_mean = np.mean(self.Pxy1) # equiv. TPR self.Pxy0_mean = np.mean(self.Pxy0) # equiv. FPR return self def aggregate(self, classif_posteriors): Px = classif_posteriors[:, self.pos_label] # takes only the P(y=+1|x) Px_mean = np.mean(Px) class1_prev = (Px_mean - self.Pxy0_mean)/(self.Pxy1_mean - self.Pxy0_mean) return F.as_binary_prevalence(class1_prev, clip_if_necessary=True) class DMy(AggregativeSoftQuantifier): """ Generic Distribution Matching quantifier for binary or multiclass quantification based on the space of posterior probabilities. This implementation takes the number of bins, the divergence, and the possibility to work on CDF as hyperparameters. :param classifier: a `sklearn`'s Estimator that generates a probabilistic classifier :param val_split: indicates the proportion of data to be used as a stratified held-out validation set to model the validation distribution. This parameter can be indicated as a real value (between 0 and 1), representing a proportion of validation data, or as an integer, indicating that the validation distribution should be estimated via `k`-fold cross validation (this integer stands for the number of folds `k`, defaults 5), or as a :class:`quapy.data.base.LabelledCollection` (the split itself). :param nbins: number of bins used to discretize the distributions (default 8) :param divergence: a string representing a divergence measure (currently, "HD" and "topsoe" are implemented) or a callable function taking two ndarrays of the same dimension as input (default "HD", meaning Hellinger Distance) :param cdf: whether to use CDF instead of PDF (default False) :param n_jobs: number of parallel workers (default None) """ def __init__(self, classifier, val_split=5, nbins=8, divergence: Union[str, Callable]='HD', cdf=False, search='optim_minimize', n_jobs=None): self.classifier = classifier self.val_split = val_split self.nbins = nbins self.divergence = divergence self.cdf = cdf self.search = search self.n_jobs = n_jobs # @classmethod # def HDy(cls, classifier, val_split=5, n_jobs=None): # from quapy.method.meta import MedianEstimator # # hdy = DMy(classifier=classifier, val_split=val_split, search='linear_search', divergence='HD') # hdy = AggregativeMedianEstimator(hdy, param_grid={'nbins': np.linspace(10, 110, 11).astype(int)}, n_jobs=n_jobs) # return hdy def _get_distributions(self, posteriors): histograms = [] post_dims = posteriors.shape[1] if post_dims == 2: # in binary quantification we can use only one class, since the other one is its complement post_dims = 1 for dim in range(post_dims): hist = np.histogram(posteriors[:, dim], bins=self.nbins, range=(0, 1))[0] histograms.append(hist) counts = np.vstack(histograms) distributions = counts/counts.sum(axis=1)[:,np.newaxis] if self.cdf: distributions = np.cumsum(distributions, axis=1) return distributions def aggregation_fit(self, classif_predictions: LabelledCollection, data: LabelledCollection): """ Trains the classifier (if requested) and generates the validation distributions out of the training data. The validation distributions have shape `(n, ch, nbins)`, with `n` the number of classes, `ch` the number of channels, and `nbins` the number of bins. In particular, let `V` be the validation distributions; then `di=V[i]` are the distributions obtained from training data labelled with class `i`; while `dij = di[j]` is the discrete distribution of posterior probabilities `P(Y=j|X=x)` for training data labelled with class `i`, and `dij[k]` is the fraction of instances with a value in the `k`-th bin. :param data: the training set :param fit_classifier: set to False to bypass the training (the learner is assumed to be already fit) :param val_split: either a float in (0,1) indicating the proportion of training instances to use for validation (e.g., 0.3 for using 30% of the training set as validation data), or a LabelledCollection indicating the validation set itself, or an int indicating the number k of folds to be used in kFCV to estimate the parameters """ posteriors, true_labels = classif_predictions.Xy n_classes = len(self.classifier.classes_) self.validation_distribution = qp.util.parallel( func=self._get_distributions, args=[posteriors[true_labels==cat] for cat in range(n_classes)], n_jobs=self.n_jobs, backend='threading' ) def aggregate(self, posteriors: np.ndarray): """ Searches for the mixture model parameter (the sought prevalence values) that yields a validation distribution (the mixture) that best matches the test distribution, in terms of the divergence measure of choice. In the multiclass case, with `n` the number of classes, the test and mixture distributions contain `n` channels (proper distributions of binned posterior probabilities), on which the divergence is computed independently. The matching is computed as an average of the divergence across all channels. :param posteriors: posterior probabilities of the instances in the sample :return: a vector of class prevalence estimates """ test_distribution = self._get_distributions(posteriors) divergence = get_divergence(self.divergence) n_classes, n_channels, nbins = self.validation_distribution.shape def loss(prev): prev = np.expand_dims(prev, axis=0) mixture_distribution = (prev @ self.validation_distribution.reshape(n_classes,-1)).reshape(n_channels, -1) divs = [divergence(test_distribution[ch], mixture_distribution[ch]) for ch in range(n_channels)] return np.mean(divs) return F.argmin_prevalence(loss, n_classes, method=self.search) def newELM(svmperf_base=None, loss='01', C=1): """ Explicit Loss Minimization (ELM) quantifiers. Quantifiers based on ELM represent a family of methods based on structured output learning; these quantifiers rely on classifiers that have been optimized using a quantification-oriented loss measure. This implementation relies on `Joachims’ SVM perf `_ structured output learning algorithm, which has to be installed and patched for the purpose (see this `script `_). This function equivalent to: >>> CC(SVMperf(svmperf_base, loss, C)) :param svmperf_base: path to the folder containing the binary files of `SVM perf`; if set to None (default) this path will be obtained from qp.environ['SVMPERF_HOME'] :param loss: the loss to optimize (see :attr:`quapy.classification.svmperf.SVMperf.valid_losses`) :param C: trade-off between training error and margin (default 0.01) :return: returns an instance of CC set to work with SVMperf (with loss and C set properly) as the underlying classifier """ if svmperf_base is None: svmperf_base = qp.environ['SVMPERF_HOME'] assert svmperf_base is not None, \ 'param svmperf_base was not specified, and the variable SVMPERF_HOME has not been set in the environment' return CC(SVMperf(svmperf_base, loss=loss, C=C)) def newSVMQ(svmperf_base=None, C=1): """ SVM(Q) is an Explicit Loss Minimization (ELM) quantifier set to optimize for the `Q` loss combining a classification-oriented loss and a quantification-oriented loss, as proposed by `Barranquero et al. 2015 `_. Equivalent to: >>> CC(SVMperf(svmperf_base, loss='q', C=C)) Quantifiers based on ELM represent a family of methods based on structured output learning; these quantifiers rely on classifiers that have been optimized using a quantification-oriented loss measure. This implementation relies on `Joachims’ SVM perf `_ structured output learning algorithm, which has to be installed and patched for the purpose (see this `script `_). This function is a wrapper around CC(SVMperf(svmperf_base, loss, C)) :param svmperf_base: path to the folder containing the binary files of `SVM perf`; if set to None (default) this path will be obtained from qp.environ['SVMPERF_HOME'] :param C: trade-off between training error and margin (default 0.01) :return: returns an instance of CC set to work with SVMperf (with loss and C set properly) as the underlying classifier """ return newELM(svmperf_base, loss='q', C=C) def newSVMKLD(svmperf_base=None, C=1): """ SVM(KLD) is an Explicit Loss Minimization (ELM) quantifier set to optimize for the Kullback-Leibler Divergence as proposed by `Esuli et al. 2015 `_. Equivalent to: >>> CC(SVMperf(svmperf_base, loss='kld', C=C)) Quantifiers based on ELM represent a family of methods based on structured output learning; these quantifiers rely on classifiers that have been optimized using a quantification-oriented loss measure. This implementation relies on `Joachims’ SVM perf `_ structured output learning algorithm, which has to be installed and patched for the purpose (see this `script `_). This function is a wrapper around CC(SVMperf(svmperf_base, loss, C)) :param svmperf_base: path to the folder containing the binary files of `SVM perf`; if set to None (default) this path will be obtained from qp.environ['SVMPERF_HOME'] :param C: trade-off between training error and margin (default 0.01) :return: returns an instance of CC set to work with SVMperf (with loss and C set properly) as the underlying classifier """ return newELM(svmperf_base, loss='kld', C=C) def newSVMKLD(svmperf_base=None, C=1): """ SVM(KLD) is an Explicit Loss Minimization (ELM) quantifier set to optimize for the Kullback-Leibler Divergence normalized via the logistic function, as proposed by `Esuli et al. 2015 `_. Equivalent to: >>> CC(SVMperf(svmperf_base, loss='nkld', C=C)) Quantifiers based on ELM represent a family of methods based on structured output learning; these quantifiers rely on classifiers that have been optimized using a quantification-oriented loss measure. This implementation relies on `Joachims’ SVM perf `_ structured output learning algorithm, which has to be installed and patched for the purpose (see this `script `_). This function is a wrapper around CC(SVMperf(svmperf_base, loss, C)) :param svmperf_base: path to the folder containing the binary files of `SVM perf`; if set to None (default) this path will be obtained from qp.environ['SVMPERF_HOME'] :param C: trade-off between training error and margin (default 0.01) :return: returns an instance of CC set to work with SVMperf (with loss and C set properly) as the underlying classifier """ return newELM(svmperf_base, loss='nkld', C=C) def newSVMAE(svmperf_base=None, C=1): """ SVM(KLD) is an Explicit Loss Minimization (ELM) quantifier set to optimize for the Absolute Error as first used by `Moreo and Sebastiani, 2021 `_. Equivalent to: >>> CC(SVMperf(svmperf_base, loss='mae', C=C)) Quantifiers based on ELM represent a family of methods based on structured output learning; these quantifiers rely on classifiers that have been optimized using a quantification-oriented loss measure. This implementation relies on `Joachims’ SVM perf `_ structured output learning algorithm, which has to be installed and patched for the purpose (see this `script `_). This function is a wrapper around CC(SVMperf(svmperf_base, loss, C)) :param svmperf_base: path to the folder containing the binary files of `SVM perf`; if set to None (default) this path will be obtained from qp.environ['SVMPERF_HOME'] :param C: trade-off between training error and margin (default 0.01) :return: returns an instance of CC set to work with SVMperf (with loss and C set properly) as the underlying classifier """ return newELM(svmperf_base, loss='mae', C=C) def newSVMRAE(svmperf_base=None, C=1): """ SVM(KLD) is an Explicit Loss Minimization (ELM) quantifier set to optimize for the Relative Absolute Error as first used by `Moreo and Sebastiani, 2021 `_. Equivalent to: >>> CC(SVMperf(svmperf_base, loss='mrae', C=C)) Quantifiers based on ELM represent a family of methods based on structured output learning; these quantifiers rely on classifiers that have been optimized using a quantification-oriented loss measure. This implementation relies on `Joachims’ SVM perf `_ structured output learning algorithm, which has to be installed and patched for the purpose (see this `script `_). This function is a wrapper around CC(SVMperf(svmperf_base, loss, C)) :param svmperf_base: path to the folder containing the binary files of `SVM perf`; if set to None (default) this path will be obtained from qp.environ['SVMPERF_HOME'] :param C: trade-off between training error and margin (default 0.01) :return: returns an instance of CC set to work with SVMperf (with loss and C set properly) as the underlying classifier """ return newELM(svmperf_base, loss='mrae', C=C) class OneVsAllAggregative(OneVsAllGeneric, AggregativeQuantifier): """ Allows any binary quantifier to perform quantification on single-label datasets. The method maintains one binary quantifier for each class, and then l1-normalizes the outputs so that the class prevelences sum up to 1. This variant was used, along with the :class:`EMQ` quantifier, in `Gao and Sebastiani, 2016 `_. :param binary_quantifier: a quantifier (binary) that will be employed to work on multiclass model in a one-vs-all manner :param n_jobs: number of parallel workers :param parallel_backend: the parallel backend for joblib (default "loky"); this is helpful for some quantifiers (e.g., ELM-based ones) that cannot be run with multiprocessing, since the temp dir they create during fit will is removed and no longer available at predict time. """ def __init__(self, binary_quantifier, n_jobs=None, parallel_backend='multiprocessing'): assert isinstance(binary_quantifier, BaseQuantifier), \ f'{self.binary_quantifier} does not seem to be a Quantifier' assert isinstance(binary_quantifier, AggregativeQuantifier), \ f'{self.binary_quantifier} does not seem to be of type Aggregative' self.binary_quantifier = binary_quantifier self.n_jobs = qp._get_njobs(n_jobs) self.parallel_backend = parallel_backend def classify(self, instances): """ If the base quantifier is not probabilistic, returns a matrix of shape `(n,m,)` with `n` the number of instances and `m` the number of classes. The entry `(i,j)` is a binary value indicating whether instance `i `belongs to class `j`. The binary classifications are independent of each other, meaning that an instance can end up be attributed to 0, 1, or more classes. If the base quantifier is probabilistic, returns a matrix of shape `(n,m,2)` with `n` the number of instances and `m` the number of classes. The entry `(i,j,1)` (resp. `(i,j,0)`) is a value in [0,1] indicating the posterior probability that instance `i` belongs (resp. does not belong) to class `j`. The posterior probabilities are independent of each other, meaning that, in general, they do not sum up to one. :param instances: array-like :return: `np.ndarray` """ classif_predictions = self._parallel(self._delayed_binary_classification, instances) if isinstance(self.binary_quantifier, AggregativeSoftQuantifier): return np.swapaxes(classif_predictions, 0, 1) else: return classif_predictions.T def aggregate(self, classif_predictions): prevalences = self._parallel(self._delayed_binary_aggregate, classif_predictions) return F.normalize_prevalence(prevalences) def _delayed_binary_classification(self, c, X): return self.dict_binary_quantifiers[c].classify(X) def _delayed_binary_aggregate(self, c, classif_predictions): # the estimation for the positive class prevalence return self.dict_binary_quantifiers[c].aggregate(classif_predictions[:, c])[1] class AggregativeMedianEstimator(BinaryQuantifier): """ This method is a meta-quantifier that returns, as the estimated class prevalence values, the median of the estimation returned by differently (hyper)parameterized base quantifiers. The median of unit-vectors is only guaranteed to be a unit-vector for n=2 dimensions, i.e., in cases of binary quantification. :param base_quantifier: the base, binary quantifier :param random_state: a seed to be set before fitting any base quantifier (default None) :param param_grid: the grid or parameters towards which the median will be computed :param n_jobs: number of parllel workes """ def __init__(self, base_quantifier: AggregativeQuantifier, param_grid: dict, random_state=None, n_jobs=None): self.base_quantifier = base_quantifier self.param_grid = param_grid self.random_state = random_state self.n_jobs = qp._get_njobs(n_jobs) def get_params(self, deep=True): return self.base_quantifier.get_params(deep) def set_params(self, **params): self.base_quantifier.set_params(**params) def _delayed_fit(self, args): with qp.util.temp_seed(self.random_state): params, training = args model = deepcopy(self.base_quantifier) model.set_params(**params) model.fit(training) return model def _delayed_fit_classifier(self, args): with qp.util.temp_seed(self.random_state): print('enter job') cls_params, training, kwargs = args model = deepcopy(self.base_quantifier) model.set_params(**cls_params) predictions = model.classifier_fit_predict(training, **kwargs) print('exit job') return (model, predictions) def _delayed_fit_aggregation(self, args): with qp.util.temp_seed(self.random_state): ((model, predictions), q_params), training = args model = deepcopy(model) model.set_params(**q_params) model.aggregation_fit(predictions, training) return model def fit(self, training: LabelledCollection, **kwargs): import itertools self._check_binary(training, self.__class__.__name__) if isinstance(self.base_quantifier, AggregativeQuantifier): cls_configs, q_configs = qp.model_selection.group_params(self.param_grid) if len(cls_configs) > 1: models_preds = qp.util.parallel( self._delayed_fit_classifier, ((params, training, kwargs) for params in cls_configs), seed=qp.environ.get('_R_SEED', None), n_jobs=self.n_jobs, asarray=False, backend='threading' ) else: print('only 1') model = self.base_quantifier model.set_params(**cls_configs[0]) predictions = model.classifier_fit_predict(training, **kwargs) models_preds = [(model, predictions)] self.models = qp.util.parallel( self._delayed_fit_aggregation, ((setup, training) for setup in itertools.product(models_preds, q_configs)), seed=qp.environ.get('_R_SEED', None), n_jobs=self.n_jobs, backend='threading' ) else: configs = qp.model_selection.expand_grid(self.param_grid) self.models = qp.util.parallel( self._delayed_fit, ((params, training) for params in configs), seed=qp.environ.get('_R_SEED', None), n_jobs=self.n_jobs, backend='threading' ) return self def _delayed_predict(self, args): model, instances = args return model.quantify(instances) def quantify(self, instances): prev_preds = qp.util.parallel( self._delayed_predict, ((model, instances) for model in self.models), seed=qp.environ.get('_R_SEED', None), n_jobs=self.n_jobs, backend='threading' ) return np.median(prev_preds, axis=0) #--------------------------------------------------------------- # imports #--------------------------------------------------------------- from . import _threshold_optim T50 = _threshold_optim.T50 MAX = _threshold_optim.MAX X = _threshold_optim.X MS = _threshold_optim.MS MS2 = _threshold_optim.MS2 from . import _kdey KDEyML = _kdey.KDEyML KDEyHD = _kdey.KDEyHD KDEyCS = _kdey.KDEyCS #--------------------------------------------------------------- # aliases #--------------------------------------------------------------- ClassifyAndCount = CC AdjustedClassifyAndCount = ACC ProbabilisticClassifyAndCount = PCC ProbabilisticAdjustedClassifyAndCount = PACC ExpectationMaximizationQuantifier = EMQ DistributionMatchingY = DMy SLD = EMQ HellingerDistanceY = HDy MedianSweep = MS MedianSweep2 = MS2