import math from typing import List, Optional import numpy as np import scipy.sparse as sp from quapy.data import LabelledCollection # Extended classes # # 0 ~ True 0 # 1 ~ False 1 # 2 ~ False 0 # 3 ~ True 1 # _____________________ # | | | # | True 0 | False 1 | # |__________|__________| # | | | # | False 0 | True 1 | # |__________|__________| # class ExClassManager: @staticmethod def get_ex(n_classes: int, true_class: int, pred_class: int) -> int: return true_class * n_classes + pred_class @staticmethod def get_pred(n_classes: int, ex_class: int) -> int: return ex_class % n_classes @staticmethod def get_true(n_classes: int, ex_class: int) -> int: return ex_class // n_classes class ExtendedCollection(LabelledCollection): def __init__( self, instances: np.ndarray | sp.csr_matrix, labels: np.ndarray, classes: Optional[List] = None, ): super().__init__(instances, labels, classes=classes) def split_by_pred(self): _ncl = int(math.sqrt(self.n_classes)) _indexes = ExtendedCollection._split_index_by_pred(_ncl, self.instances) if isinstance(self.instances, np.ndarray): _instances = [ self.instances[ind] if ind.shape[0] > 0 else np.asarray([], dtype=int) for ind in _indexes ] elif isinstance(self.instances, sp.csr_matrix): _instances = [ self.instances[ind] if ind.shape[0] > 0 else sp.csr_matrix(np.empty((0, 0), dtype=int)) for ind in _indexes ] _labels = [ np.asarray( [ ExClassManager.get_true(_ncl, lbl) for lbl in (self.labels[ind] if len(ind) > 0 else []) ], dtype=int, ) for ind in _indexes ] return [ ExtendedCollection(inst, lbl, classes=range(0, _ncl)) for (inst, lbl) in zip(_instances, _labels) ] @classmethod def split_inst_by_pred( cls, n_classes: int, instances: np.ndarray | sp.csr_matrix ) -> (List[np.ndarray | sp.csr_matrix], List[float]): _indexes = cls._split_index_by_pred(n_classes, instances) if isinstance(instances, np.ndarray): _instances = [ instances[ind] if ind.shape[0] > 0 else np.asarray([], dtype=int) for ind in _indexes ] elif isinstance(instances, sp.csr_matrix): _instances = [ instances[ind] if ind.shape[0] > 0 else sp.csr_matrix(np.empty((0, 0), dtype=int)) for ind in _indexes ] norms = [inst.shape[0] / instances.shape[0] for inst in _instances] return _instances, norms @classmethod def _split_index_by_pred( cls, n_classes: int, instances: np.ndarray | sp.csr_matrix ) -> List[np.ndarray]: if isinstance(instances, np.ndarray): _pred_label = [np.argmax(inst[-n_classes:], axis=0) for inst in instances] elif isinstance(instances, sp.csr_matrix): _pred_label = [ np.argmax(inst[:, -n_classes:].toarray().flatten(), axis=0) for inst in instances ] else: raise ValueError("Unsupported matrix format") return [ np.asarray([j for (j, x) in enumerate(_pred_label) if x == i], dtype=int) for i in range(0, n_classes) ] @classmethod def extend_instances( cls, instances: np.ndarray | sp.csr_matrix, pred_proba: np.ndarray ) -> np.ndarray | sp.csr_matrix: if isinstance(instances, sp.csr_matrix): _pred_proba = sp.csr_matrix(pred_proba) n_x = sp.hstack([instances, _pred_proba]) elif isinstance(instances, np.ndarray): n_x = np.concatenate((instances, pred_proba), axis=1) else: raise ValueError("Unsupported matrix format") return n_x @classmethod def extend_collection( cls, base: LabelledCollection, pred_proba: np.ndarray, ): n_classes = base.n_classes # n_X = [ X | predicted probs. ] n_x = cls.extend_instances(base.X, pred_proba) # n_y = (exptected y, predicted y) pred_proba = pred_proba[:, -n_classes:] preds = np.argmax(pred_proba, axis=-1) n_y = np.asarray( [ ExClassManager.get_ex(n_classes, true_class, pred_class) for (true_class, pred_class) in zip(base.y, preds) ] ) return ExtendedCollection(n_x, n_y, classes=[*range(0, n_classes * n_classes)])