# copyright (c) 2021 PaddlePaddle Authors. All Rights Reserve. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from cmath import nan import numpy as np import paddle import paddle.nn as nn import paddle.nn.functional as F from sklearn.metrics import hamming_loss from sklearn.metrics import accuracy_score as accuracy_metric from sklearn.metrics import multilabel_confusion_matrix from sklearn.preprocessing import binarize from easydict import EasyDict from ppcls.metric.avg_metrics import AvgMetrics from ppcls.utils.misc import AverageMeter, AttrMeter from ppcls.utils import logger class TopkAcc(AvgMetrics): def __init__(self, topk=(1, 5)): super().__init__() assert isinstance(topk, (int, list, tuple)) if isinstance(topk, int): topk = [topk] self.topk = topk self.reset() def reset(self): self.avg_meters = { f"top{k}": AverageMeter(f"top{k}") for k in self.topk } def forward(self, x, label): if isinstance(x, dict): x = x["logits"] output_dims = x.shape[-1] metric_dict = dict() for idx, k in enumerate(self.topk): if output_dims < k: msg = f"The output dims({output_dims}) is less than k({k}), and the argument {k} of Topk has been removed." logger.warning(msg) self.avg_meters.pop(f"top{k}") continue metric_dict[f"top{k}"] = paddle.metric.accuracy(x, label, k=k) self.avg_meters[f"top{k}"].update(metric_dict[f"top{k}"], x.shape[0]) self.topk = list(filter(lambda k: k <= output_dims, self.topk)) return metric_dict class mAP(nn.Layer): def __init__(self, descending=True): super().__init__() self.descending = descending def forward(self, similarities_matrix, query_img_id, gallery_img_id, keep_mask): metric_dict = dict() choosen_indices = paddle.argsort( similarities_matrix, axis=1, descending=self.descending) gallery_labels_transpose = paddle.transpose(gallery_img_id, [1, 0]) gallery_labels_transpose = paddle.broadcast_to( gallery_labels_transpose, shape=[ choosen_indices.shape[0], gallery_labels_transpose.shape[1] ]) choosen_label = paddle.index_sample(gallery_labels_transpose, choosen_indices) equal_flag = paddle.equal(choosen_label, query_img_id) if keep_mask is not None: keep_mask = paddle.index_sample( keep_mask.astype('float32'), choosen_indices) equal_flag = paddle.logical_and(equal_flag, keep_mask.astype('bool')) equal_flag = paddle.cast(equal_flag, 'float32') num_rel = paddle.sum(equal_flag, axis=1) num_rel = paddle.greater_than(num_rel, paddle.to_tensor(0.)) num_rel_index = paddle.nonzero(num_rel.astype("int")) num_rel_index = paddle.reshape(num_rel_index, [num_rel_index.shape[0]]) if paddle.numel(num_rel_index).item() == 0: metric_dict["mAP"] = np.nan return metric_dict equal_flag = paddle.index_select(equal_flag, num_rel_index, axis=0) acc_sum = paddle.cumsum(equal_flag, axis=1) div = paddle.arange(acc_sum.shape[1]).astype("float32") + 1 precision = paddle.divide(acc_sum, div) #calc map precision_mask = paddle.multiply(equal_flag, precision) ap = paddle.sum(precision_mask, axis=1) / paddle.sum(equal_flag, axis=1) metric_dict["mAP"] = paddle.mean(ap).numpy()[0] return metric_dict class mINP(nn.Layer): def __init__(self, descending=True): super().__init__() self.descending = descending def forward(self, similarities_matrix, query_img_id, gallery_img_id, keep_mask): metric_dict = dict() choosen_indices = paddle.argsort( similarities_matrix, axis=1, descending=self.descending) gallery_labels_transpose = paddle.transpose(gallery_img_id, [1, 0]) gallery_labels_transpose = paddle.broadcast_to( gallery_labels_transpose, shape=[ choosen_indices.shape[0], gallery_labels_transpose.shape[1] ]) choosen_label = paddle.index_sample(gallery_labels_transpose, choosen_indices) equal_flag = paddle.equal(choosen_label, query_img_id) if keep_mask is not None: keep_mask = paddle.indechmx_sample( keep_mask.astype('float32'), choosen_indices) equal_flag = paddle.logical_and(equal_flag, keep_mask.astype('bool')) equal_flag = paddle.cast(equal_flag, 'float32') num_rel = paddle.sum(equal_flag, axis=1) num_rel = paddle.greater_than(num_rel, paddle.to_tensor(0.)) num_rel_index = paddle.nonzero(num_rel.astype("int")) num_rel_index = paddle.reshape(num_rel_index, [num_rel_index.shape[0]]) equal_flag = paddle.index_select(equal_flag, num_rel_index, axis=0) #do accumulative sum div = paddle.arange(equal_flag.shape[1]).astype("float32") + 2 minus = paddle.divide(equal_flag, div) auxilary = paddle.subtract(equal_flag, minus) hard_index = paddle.argmax(auxilary, axis=1).astype("float32") all_INP = paddle.divide(paddle.sum(equal_flag, axis=1), hard_index) mINP = paddle.mean(all_INP) metric_dict["mINP"] = mINP.numpy()[0] return metric_dict class TprAtFpr(nn.Layer): def __init__(self, max_fpr=1 / 1000.): super().__init__() self.gt_pos_score_list = [] self.gt_neg_score_list = [] self.softmax = nn.Softmax(axis=-1) self.max_fpr = max_fpr self.max_tpr = 0. def forward(self, x, label): if isinstance(x, dict): x = x["logits"] x = self.softmax(x) for i, label_i in enumerate(label): if label_i[0] == 0: self.gt_neg_score_list.append(x[i][1].numpy()) else: self.gt_pos_score_list.append(x[i][1].numpy()) return {} def reset(self): self.gt_pos_score_list = [] self.gt_neg_score_list = [] self.max_tpr = 0. @property def avg(self): return self.max_tpr @property def avg_info(self): max_tpr = 0. result = "" gt_pos_score_list = np.array(self.gt_pos_score_list) gt_neg_score_list = np.array(self.gt_neg_score_list) for i in range(0, 10000): threshold = i / 10000. if len(gt_pos_score_list) == 0: continue tpr = np.sum( gt_pos_score_list > threshold) / len(gt_pos_score_list) if len(gt_neg_score_list) == 0 and tpr > max_tpr: max_tpr = tpr result = "threshold: {}, fpr: {}, tpr: {:.5f}".format( threshold, fpr, tpr) fpr = np.sum( gt_neg_score_list > threshold) / len(gt_neg_score_list) if fpr <= self.max_fpr and tpr > max_tpr: max_tpr = tpr result = "threshold: {}, fpr: {}, tpr: {:.5f}".format( threshold, fpr, tpr) self.max_tpr = max_tpr return result class Recallk(nn.Layer): def __init__(self, topk=(1, 5), descending=True): super().__init__() assert isinstance(topk, (int, list, tuple)) if isinstance(topk, int): topk = [topk] self.topk = topk self.descending = descending def forward(self, similarities_matrix, query_img_id, gallery_img_id, keep_mask): metric_dict = dict() #get cmc choosen_indices = paddle.argsort( similarities_matrix, axis=1, descending=self.descending) gallery_labels_transpose = paddle.transpose(gallery_img_id, [1, 0]) gallery_labels_transpose = paddle.broadcast_to( gallery_labels_transpose, shape=[ choosen_indices.shape[0], gallery_labels_transpose.shape[1] ]) choosen_label = paddle.index_sample(gallery_labels_transpose, choosen_indices) equal_flag = paddle.equal(choosen_label, query_img_id) if keep_mask is not None: keep_mask = paddle.index_sample( keep_mask.astype('float32'), choosen_indices) equal_flag = paddle.logical_and(equal_flag, keep_mask.astype('bool')) equal_flag = paddle.cast(equal_flag, 'float32') real_query_num = paddle.sum(equal_flag, axis=1) real_query_num = paddle.sum( paddle.greater_than(real_query_num, paddle.to_tensor(0.)).astype( "float32")) acc_sum = paddle.cumsum(equal_flag, axis=1) mask = paddle.greater_than(acc_sum, paddle.to_tensor(0.)).astype("float32") all_cmc = (paddle.sum(mask, axis=0) / real_query_num).numpy() for k in self.topk: metric_dict["recall{}".format(k)] = all_cmc[k - 1] return metric_dict class Precisionk(nn.Layer): def __init__(self, topk=(1, 5), descending=True): super().__init__() assert isinstance(topk, (int, list, tuple)) if isinstance(topk, int): topk = [topk] self.topk = topk self.descending = descending def forward(self, similarities_matrix, query_img_id, gallery_img_id, keep_mask): metric_dict = dict() #get cmc choosen_indices = paddle.argsort( similarities_matrix, axis=1, descending=self.descending) gallery_labels_transpose = paddle.transpose(gallery_img_id, [1, 0]) gallery_labels_transpose = paddle.broadcast_to( gallery_labels_transpose, shape=[ choosen_indices.shape[0], gallery_labels_transpose.shape[1] ]) choosen_label = paddle.index_sample(gallery_labels_transpose, choosen_indices) equal_flag = paddle.equal(choosen_label, query_img_id) if keep_mask is not None: keep_mask = paddle.index_sample( keep_mask.astype('float32'), choosen_indices) equal_flag = paddle.logical_and(equal_flag, keep_mask.astype('bool')) equal_flag = paddle.cast(equal_flag, 'float32') Ns = paddle.arange(gallery_img_id.shape[0]) + 1 equal_flag_cumsum = paddle.cumsum(equal_flag, axis=1) Precision_at_k = (paddle.mean(equal_flag_cumsum, axis=0) / Ns).numpy() for k in self.topk: metric_dict["precision@{}".format(k)] = Precision_at_k[k - 1] return metric_dict class DistillationTopkAcc(TopkAcc): def __init__(self, model_key, feature_key=None, topk=(1, 5)): super().__init__(topk=topk) self.model_key = model_key self.feature_key = feature_key def forward(self, x, label): if isinstance(x, dict): x = x[self.model_key] if self.feature_key is not None: x = x[self.feature_key] return super().forward(x, label) class GoogLeNetTopkAcc(TopkAcc): def __init__(self, topk=(1, 5)): super().__init__() assert isinstance(topk, (int, list, tuple)) if isinstance(topk, int): topk = [topk] self.topk = topk def forward(self, x, label): return super().forward(x[0], label) class MultiLabelMetric(AvgMetrics): def __init__(self, bi_threshold=0.5): super().__init__() self.bi_threshold = bi_threshold def _multi_hot_encode(self, output): logits = F.sigmoid(output).numpy() return binarize(logits, threshold=self.bi_threshold) class HammingDistance(MultiLabelMetric): """ Soft metric based label for multilabel classification Returns: The smaller the return value is, the better model is. """ def __init__(self): super().__init__() self.reset() def reset(self): self.avg_meters = {"HammingDistance": AverageMeter("HammingDistance")} def forward(self, output, target): preds = super()._multi_hot_encode(output) metric_dict = dict() metric_dict["HammingDistance"] = paddle.to_tensor( hamming_loss(target, preds)) self.avg_meters["HammingDistance"].update( metric_dict["HammingDistance"].numpy()[0], output.shape[0]) return metric_dict class AccuracyScore(MultiLabelMetric): """ Hard metric for multilabel classification Args: base: ["sample", "label"], default="sample" if "sample", return metric score based sample, if "label", return metric score based label. Returns: accuracy: """ def __init__(self, base="label"): super().__init__() assert base in ["sample", "label" ], 'must be one of ["sample", "label"]' self.base = base self.reset() def reset(self): self.avg_meters = {"AccuracyScore": AverageMeter("AccuracyScore")} def forward(self, output, target): preds = super()._multi_hot_encode(output) metric_dict = dict() if self.base == "sample": accuracy = accuracy_metric(target, preds) elif self.base == "label": mcm = multilabel_confusion_matrix(target, preds) tns = mcm[:, 0, 0] fns = mcm[:, 1, 0] tps = mcm[:, 1, 1] fps = mcm[:, 0, 1] accuracy = (sum(tps) + sum(tns)) / ( sum(tps) + sum(tns) + sum(fns) + sum(fps)) metric_dict["AccuracyScore"] = paddle.to_tensor(accuracy) self.avg_meters["AccuracyScore"].update( metric_dict["AccuracyScore"].numpy()[0], output.shape[0]) return metric_dict def get_attr_metrics(gt_label, preds_probs, threshold): """ index: evaluated label index adapted from "https://github.com/valencebond/Rethinking_of_PAR/blob/master/metrics/pedestrian_metrics.py" """ pred_label = (preds_probs > threshold).astype(int) eps = 1e-20 result = EasyDict() has_fuyi = gt_label == -1 pred_label[has_fuyi] = -1 ############################### # label metrics # TP + FN result.gt_pos = np.sum((gt_label == 1), axis=0).astype(float) # TN + FP result.gt_neg = np.sum((gt_label == 0), axis=0).astype(float) # TP result.true_pos = np.sum((gt_label == 1) * (pred_label == 1), axis=0).astype(float) # TN result.true_neg = np.sum((gt_label == 0) * (pred_label == 0), axis=0).astype(float) # FP result.false_pos = np.sum(((gt_label == 0) * (pred_label == 1)), axis=0).astype(float) # FN result.false_neg = np.sum(((gt_label == 1) * (pred_label == 0)), axis=0).astype(float) ################ # instance metrics result.gt_pos_ins = np.sum((gt_label == 1), axis=1).astype(float) result.true_pos_ins = np.sum((pred_label == 1), axis=1).astype(float) # true positive result.intersect_pos = np.sum((gt_label == 1) * (pred_label == 1), axis=1).astype(float) # IOU result.union_pos = np.sum(((gt_label == 1) + (pred_label == 1)), axis=1).astype(float) return result class ATTRMetric(nn.Layer): def __init__(self, threshold=0.5): super().__init__() self.threshold = threshold def reset(self): self.attrmeter = AttrMeter(threshold=0.5) def forward(self, output, target): metric_dict = get_attr_metrics(target[:, 0, :].numpy(), output.numpy(), self.threshold) self.attrmeter.update(metric_dict) return metric_dict