def SCF_verification(net, feature_dim, device, step = None): net.eval() dataloader = get_loader('scf', batch_size=50).dataloader features11_total = torch.Tensor(np.zeros((200, feature_dim), dtype=np.float32)).to() features12_total, features21_total, features22_total = torch.zeros_like(features11_total), \ torch.zeros_like(features11_total), \ torch.zeros_like(features11_total) labels = torch.Tensor(np.zeros((200, 1), dtype=np.float32)).to(device) with torch.no_grad(): bs_total = 0 for index, (img1, img2, img1_flip, img2_flip, flag) in enumerate(dataloader): bs = len(flag) img1, img1_flip = img1.to(device), img1_flip.to(device) img2, img2_flip = img2.to(device), img2_flip.to(device) features11 = net(img1) features12 = net(img1_flip) features21 = net(img2) features22 = net(img2_flip) features11_total[bs_total:bs_total + bs] = features11 features12_total[bs_total:bs_total + bs] = features12 features21_total[bs_total:bs_total + bs] = features21 features22_total[bs_total:bs_total + bs] = features22 labels[bs_total:bs_total + bs] = flag bs_total += bs assert bs_total == 200, print('SCF pairs should be 200!') labels = labels.cpu().numpy() for cal_type in ['concat']: # cal_type: concat/sum/normal scores = tensor_pair_cosine_distance(features11_total, features12_total, features21_total, features22_total, type=cal_type) fpr, tpr, _ = roc_curve(labels, scores) # false positive rate / true positive rate roc_auc = auc(fpr, tpr) print(roc_auc)
def lfw_verification(net, feature_dim, device, resolution = 'hr', N =1, step=None): net.eval() if resolution == 'hr': dataloader = get_loader('LFWDataset_gz', batch_size=256).dataloader elif resolution == 'lr': dataloader = get_loader('LFWDataset_gz_lr', batch_size=256, N=N).dataloader # 6000 Image Pairs ( 3000 genuine and 3000 impostor matches) features11_total = torch.Tensor(np.zeros((6000, feature_dim), dtype=np.float32)).to(device) features12_total, features21_total, features22_total = torch.zeros_like(features11_total), \ torch.zeros_like(features11_total), \ torch.zeros_like(features11_total) labels = torch.Tensor(np.zeros((6000, 1), dtype=np.float32)).to(device) with torch.no_grad(): bs_total = 0 for index, (img1, img2, img1_flip, img2_flip, targets) in enumerate(dataloader): bs = len(targets) img1, img1_flip = img1.to(device), img1_flip.to(device) img2, img2_flip = img2.to(device), img2_flip.to(device) features11 = net(img1) features12 = net(img1_flip) features21 = net(img2) features22 = net(img2_flip) features11_total[bs_total:bs_total + bs] = features11 features12_total[bs_total:bs_total + bs] = features12 features21_total[bs_total:bs_total + bs] = features21 features22_total[bs_total:bs_total + bs] = features22 labels[bs_total:bs_total + bs] = targets bs_total += bs assert bs_total == 6000, print('LFW pairs should be 6,000!') labels = labels.cpu().numpy() for cal_type in ['concat']: # cal_type: concat/sum/normal scores = tensor_pair_cosine_distance(features11_total, features12_total, features21_total, features22_total, type=cal_type) fpr, tpr, _ = roc_curve(labels, scores) # false positive rate / true positive rate # if step == args.iterations: # np.savez('cnn_roc_{}.npz'.format(args.loss_type), name1=fpr, name2=tpr) # message = 'The fpr and tpr is saved to cnn_roc_{}.npz'.format(args.loss_type) # save_log(message, args.log_path) roc_auc = auc(fpr, tpr) accuracy = [] thd = [] folds = KFold(n=6000, n_folds=10, shuffle=False) # 1 for test, 9 for train thresholds = np.linspace(-10000, 10000, 10000 + 1) thresholds = thresholds / 10000 predicts = np.hstack((scores, labels)) for idx, (train, test) in enumerate(folds): best_thresh = find_best_threshold(thresholds, predicts[train]) # find the best threshold to say if these two persons are same or not accuracy.append(eval_acc(best_thresh, predicts[test])) thd.append(best_thresh) mean_acc, std = np.mean(accuracy), np.std(accuracy) # have 10 accuracies and then find the mean and std if step is not None: message = 'LFWACC={:.4f} std={:.4f} auc={:.4f} type:{} at {}iter.'.format(mean_acc, std, roc_auc, cal_type, step) else: message = 'LFWACC={:.4f} std={:.4f} auc={:.4f} type:{} at testing.'.format(mean_acc, std, roc_auc, cal_type) if step is None: np.savez('/home/tangjiawei/PycharmProjects/FYP_Face_Verification/saved/alexnet_hr/resnet_roc_{}.npz'.format(N), name1=fpr, name2=tpr) print(message)
def run(net, feature_dim, device, N =1, step=None): net.eval() dataloader = get_loader('LFWDataset_gz_lr', batch_size=256, N=N).dataloader # 6000 Image Pairs ( 3000 genuine and 3000 impostor matches) features11_total = torch.Tensor(np.zeros((6000, feature_dim), dtype=np.float32)).to(device) features12_total, features21_total, features22_total = torch.zeros_like(features11_total), \ torch.zeros_like(features11_total), \ torch.zeros_like(features11_total) labels = torch.Tensor(np.zeros((6000, 1), dtype=np.float32)).to(device) with torch.no_grad(): bs_total = 0 for index, (img1, img2, img1_flip, img2_flip, targets) in enumerate(dataloader): bs = len(targets) img1, img1_flip = img1.to(device), img1_flip.to(device) img2, img2_flip = img2.to(device), img2_flip.to(device) features11 = net(img1) features12 = net(img1_flip) features21 = net(img2) features22 = net(img2_flip) features11_total[bs_total:bs_total + bs] = features11 features12_total[bs_total:bs_total + bs] = features12 features21_total[bs_total:bs_total + bs] = features21 features22_total[bs_total:bs_total + bs] = features22 labels[bs_total:bs_total + bs] = targets bs_total += bs assert bs_total == 6000, print('LFW pairs should be 6,000!') labels = labels.cpu().numpy() for cal_type in ['concat']: # cal_type: concat/sum/normal scores = tensor_pair_cosine_distance(features11_total, features12_total, features21_total, features22_total, type=cal_type) fpr, tpr, _ = roc_curve(labels, scores) # false positive rate / true positive rate roc_auc = auc(fpr, tpr) accuracy = [] thd = [] folds = KFold(n=6000, n_folds=10, shuffle=False) # 1 for test, 9 for train thresholds = np.linspace(-10000, 10000, 10000 + 1) thresholds = thresholds / 10000 predicts = np.hstack((scores, labels)) for idx, (train, test) in enumerate(folds): best_thresh = find_best_threshold(thresholds, predicts[train]) # find the best threshold to say if these two persons are same or not accuracy.append(eval_acc(best_thresh, predicts[test])) thd.append(best_thresh) mean_acc, std = np.mean(accuracy), np.std(accuracy) # have 10 accuracies and then find the mean and std if step is not None: message = 'DF={} LFWACC={:.4f} std={:.4f} auc={:.4f} type:{} at {}iter.'.format(N, mean_acc, std, roc_auc, cal_type, step) logging.info(message) else: message = 'DF={} LFWACC={:.4f} std={:.4f} auc={:.4f} type:{} at testing.'.format(N, mean_acc, std, roc_auc, cal_type) logging.info(message) print(message)