def get_transforms(train=False, rescale_size=(256, 256), yolo=False): transforms = [] if train: transforms.append(my_T.Rescale(rescale_size, yolo)) transforms.append(my_T.Normalize()) transforms.append(my_T.ToTensor()) return my_T.Compose(transforms)
def get_test_transforms(rescale_size=(416, 416)): transforms = [ my_T.TestRescale(rescale_size), my_T.Normalize(), my_T.ToTensor() ] return my_T.Compose(transforms)
from torch.nn import DataParallel model = import_module('models.model_loader') precise_net, loss = model.get_full_model( net_name, loss_name, n_classes=5, alpha=alpha) c_loss = DependentLoss(alpha) checkpoint = torch.load(precise_net_path) precise_net.load_state_dict(checkpoint['state_dict']) precise_net = precise_net.to(DEVICE) precise_net = DataParallel(precise_net) precise_net.eval() ################# first get the threshold ##################### composed_transforms_tr = transforms.Compose([ tr.Normalize(mean=(0.12, 0.12, 0.12), std=(0.018, 0.018, 0.018)), tr.ToTensor2(5) ]) test_files = ["Patient_01"] ''' eval_dataset = THOR_Data( transform=composed_transforms_tr, path=data_path, file_list=test_files)''' eval_dataset = THOR_Data( path=data_path, file_list=test_files) eval_loader = DataLoader( eval_dataset, batch_size=1,
def main(args): max_precision = 0. torch.manual_seed(123) cudnn.benchmark = True setgpu(args.gpu) data_path = args.data_path train_files, test_files = get_cross_validation_paths(args.test_flag) composed_transforms_tr = transforms.Compose([ tr.Normalize(mean=(0.12, 0.12, 0.12), std=(0.018, 0.018, 0.018)), tr.ToTensor2(args.n_class) ]) eval_dataset = THOR_Data(transform=composed_transforms_tr, path=args.data_path, file_list=test_files, otsu=args.otsu) if args.if_dependent == 1: alpha = get_global_alpha(train_files, data_path) alpha = torch.from_numpy(alpha).float().to(DEVICE) alpha.requires_grad = False else: alpha = None model = import_module('models.model_loader') net, loss = model.get_full_model(args.model_name, args.loss_name, n_classes=args.n_class, alpha=alpha, if_closs=args.if_closs, class_weights=torch.FloatTensor( [1.0, 4.0, 2.0, 5.0, 3.0]).to(DEVICE)) start_epoch = args.start_epoch save_dir = args.save_dir logging.info(args) if args.resume: checkpoint = torch.load(args.resume) start_epoch = checkpoint['epoch'] + 1 net.load_state_dict(checkpoint['state_dict']) net = net.to(DEVICE) loss = loss.to(DEVICE) if len(args.gpu.split(',')) > 1 or args.gpu == 'all': net = DataParallel(net) optimizer = torch.optim.SGD(net.parameters(), args.lr, momentum=args.momentum, weight_decay=args.weight_decay) init_lr = np.copy(args.lr) def get_lr(epoch): if args.lr < 0.0001: return args.lr if epoch > 0: args.lr = args.lr * 0.95 logging.info('current learning rate is %f' % args.lr) return args.lr composed_transforms_tr = transforms.Compose([ tr.RandomZoom((512, 512)), tr.RandomHorizontalFlip(), tr.Normalize(mean=(0.12, 0.12, 0.12), std=(0.018, 0.018, 0.018)), tr.ToTensor2(args.n_class) ]) train_dataset = THOR_Data(transform=composed_transforms_tr, path=data_path, file_list=train_files, otsu=args.otsu) trainloader = DataLoader(train_dataset, batch_size=args.batch_size, shuffle=True, num_workers=4) break_flag = 0. high_dice = 0. selected_thresholds = np.zeros((args.n_class - 1, )) run_id = str(uuid.uuid4()) cur_train_stats_path = train_stats_path.format(run_id) cur_eval_stats_path = eval_stats_path.format(run_id) with open(cur_train_stats_path, 'w') as f: writer = csv.writer(f) writer.writerow(stats_fields) with open(cur_eval_stats_path, 'w') as f: writer = csv.writer(f) writer.writerow(stats_fields) for epoch in range(start_epoch, args.epochs + 1): train_loss, adaptive_thresholds = train(trainloader, net, loss, epoch, optimizer, get_lr, save_dir, cur_train_stats_path) if epoch < args.untest_epoch: continue break_flag += 1 eval_dice, eval_precision = evaluation(args, net, loss, epoch, eval_dataset, selected_thresholds, cur_eval_stats_path) if max_precision <= eval_precision: selected_thresholds = adaptive_thresholds max_precision = eval_precision logging.info( '************************ dynamic threshold saved successful ************************** !' ) if eval_dice >= high_dice: high_dice = eval_dice break_flag = 0 if len(args.gpu.split(',')) > 1 or args.gpu == 'all': state_dict = net.module.state_dict() else: state_dict = net.state_dict() torch.save( { 'epoch': epoch, 'save_dir': save_dir, 'state_dict': state_dict, 'optimizer': optimizer.state_dict(), 'args': args }, os.path.join(save_dir, '%d.ckpt' % epoch)) logging.info( '************************ model saved successful ************************** !' ) if break_flag > args.patient: break
def evaluation(args, net, loss, epoch, save_dir, test_files, saved_thresholds): start_time = time.time() net.eval() eval_loss = [] total_precision = [] total_recall = [] composed_transforms_tr = transforms.Compose([ tr.Normalize(mean=(0.12, 0.12, 0.12), std=(0.018, 0.018, 0.018)), tr.ToTensor2(args.n_class) ]) eval_dataset = THOR_Data(transform=composed_transforms_tr, path=args.data_path, file_list=test_files) evalloader = DataLoader(eval_dataset, batch_size=args.batch_size, shuffle=False, num_workers=4) cur_target = [] cur_predict = [] class_predict = [] class_target = [] for i, sample in enumerate(evalloader): data = sample['image'] target_c = sample['label_c'] target_s = sample['label_s'] data = data.to(DEVICE) target_c = target_c.to(DEVICE) target_s = target_s.to(DEVICE) with torch.no_grad(): output_s, output_c = net(data) cur_loss, _, _, c_p = loss(output_s, output_c, target_s, target_c) eval_loss.append(cur_loss.item()) cur_target.append(torch.argmax(target_s, 1).cpu().numpy()) cur_predict.append(torch.argmax(output_s, 1).cpu().numpy()) class_target.append(target_c.cpu().numpy()) class_predict.append(c_p.cpu().numpy()) cur_precision, cur_recall = metric(np.concatenate(class_predict, 0), np.concatenate(class_target, 0), saved_thresholds) total_precision.append(np.array(cur_precision)) total_recall.append(np.array(cur_recall)) TPVFs, dices, PPVs, FPVFs = segmentation_metrics( np.concatenate(cur_predict, 0), np.concatenate(cur_target, 0)) logging.info( '***************************************************************************' ) logging.info( 'Esophagus --> Global dice is [%.5f], TPR is [%.5f], Precision is [%.5f] ' % (dices[0], TPVFs[0], PPVs[0])) logging.info( 'heart --> Global dice is [%.5f], TPR is [%.5f], Precision is [%.5f] ' % (dices[1], TPVFs[1], PPVs[1])) logging.info( 'trachea --> Global dice is [%.5f], TPR is [%.5f], Precision is [%.5f] ' % (dices[2], TPVFs[2], PPVs[2])) logging.info( 'aorta --> Global dice is [%.5f], TPR is [%.5f], Precision is [%.5f] ' % (dices[3], TPVFs[3], PPVs[3])) total_precision = np.stack(total_precision, 1) total_recall = np.stack(total_recall, 1) logging.info( 'Epoch[%d], [precision=%.4f, -->%.3f, -->%.3f, -->%.3f, -->%.3f], using %.1f s!' % (epoch, np.mean(total_precision), np.mean(total_precision[0]), np.mean(total_precision[1]), np.mean(total_precision[2]), np.mean(total_precision[3]), time.time() - start_time)) logging.info( 'Epoch[%d], [recall=%.4f, -->%.3f, -->%.3f, -->%.3f, -->%.3f], using %.1f s!' % (epoch, np.mean(total_recall), np.mean(total_recall[0]), np.mean(total_recall[1]), np.mean(total_recall[2]), np.mean(total_recall[3]), time.time() - start_time)) logging.info( 'Epoch[%d], [total loss=%.6f], mean_dice=%.4f, using %.1f s!' % (epoch, np.mean(eval_loss), np.mean(dices), time.time() - start_time)) logging.info( '***************************************************************************' ) return np.mean(dices), np.mean(total_precision)
def main(args): torch.manual_seed(123) cudnn.benchmark = True setgpu(args.gpu) data_path = args.data_path train_files, test_files = get_cross_validation_paths(args.test_flag) model = import_module('models.model_loader') net_dict, loss = model.get_full_model( args.model_name, args.loss_name, n_classes=args.n_class) save_dir = args.save_dir logging.info(args) for net_name, net in net_dict.items(): net = net.to(DEVICE) #summary(net, (3, 512, 512)) loss = loss.to(DEVICE) optimizer_dict = {} for net_name, net in net_dict.items(): optimizer_dict[net_name] = torch.optim.SGD( net.parameters(), args.lr, momentum=args.momentum, weight_decay=args.weight_decay) ''' for name, param in net.named_parameters(): if param.requires_grad: print(name) print(param.shape) ''' init_lr = np.copy(args.lr) def get_lr(epoch): if args.lr < 0.0001: return args.lr if epoch > 0: args.lr = args.lr * 0.95 logging.info('current learning rate is %f' % args.lr) return args.lr composed_transforms_tr = transforms.Compose([ tr.RandomZoom((512, 512)), tr.RandomHorizontalFlip(), tr.Normalize(mean=(0.12, 0.12, 0.12), std=(0.018, 0.018, 0.018)), tr.ToTensor2(args.n_class)]) train_dataset = THOR_Data( transform=composed_transforms_tr, path=data_path, file_list=train_files) trainloader = DataLoader( train_dataset, batch_size=args.batch_size, shuffle=True, num_workers=4) # Pretrain ResUNet101 for epoch_normal in range(args.normal_epochs): train_normal(trainloader, net_dict, loss, epoch_normal, optimizer_dict, get_lr, save_dir) print('Pretrain ResUNet101 epoch %d done.' % epoch_normal) # Save state net_state_dict = [] for net_name, net in net_dict.items(): net_state_dict.append(net.state_dict()) optimizer_state_dict = [] for net_name, optimizer in optimizer_dict.items(): optimizer_state_dict.append(optimizer.state_dict()) torch.save({ 'epoch': epoch_normal, 'save_dir': save_dir, 'state_dict': net_state_dict, 'optimizer': optimizer_state_dict, 'args': args }, os.path.join(save_dir, '%d.ckpt' % epoch_normal)) # Train ResUNet101_lmser based on ResUNet101 for epoch_lmser in range(args.lmser_epochs): train_lmser(trainloader, net_dict, loss, epoch_lmser, optimizer_dict, get_lr, save_dir) print('Train ResUNet101_lmser epoch %d done.' % epoch_lmser)