ref_dict = None

if "ACDC" in dataset:

ref_dict = {"4": 68, "8": 146, "16": 310,

"24": 450, "32": 588, "40": 724, "80": 1512}

else:

print("Error")

base_lr = args.base_lr

num_classes = args.num_classes

max_iterations = args.max_iterations

model = net_factory(net_type=args.model, in_chns=1, class_num=num_classes)

db_train = BaseDataSets_s2l(base_dir=args.root_path, fold=args.fold,

transform=transforms.Compose([RandomGenerator_s2l(args.patch_size)]))

db_val = BaseDataSets(base_dir=args.root_path,

fold=args.fold, split="val")

def worker_init_fn(worker_id):

random.seed(args.seed + worker_id)

total_slices = len(db_train)

print("Total silices is: {}, labeled slices is: {}".format(

total_slices, total_slices))

trainloader = DataLoader(db_train, batch_size=args.batch_size, shuffle=True,

num_workers=8, pin_memory=True, worker_init_fn=worker_init_fn)

valloader = DataLoader(db_val, batch_size=1, shuffle=False, num_workers=1)

model.train()

optimizer = optim.SGD(model.parameters(), lr=base_lr,

momentum=0.9, weight_decay=0.0001)

ce_loss = CrossEntropyLoss(ignore_index=4)

u_ce_loss = CrossEntropyLoss(ignore_index=4)

writer = SummaryWriter(snapshot_path + '/log')

logging.info("{} iterations per epoch".format(len(trainloader)))

iter_num = 0

max_epoch = max_iterations // len(trainloader) + 1

best_performance = 0.0

iterator = tqdm(range(max_epoch), ncols=70)

for epoch_num in iterator:

for i_batch, sampled_batch in enumerate(trainloader):

volume_batch, label_batch, weight_batch = sampled_batch[

'image'], sampled_batch['scribble'], sampled_batch['weight']

volume_batch, label_batch = volume_batch.cuda(), label_batch.cuda()

outputs = model(volume_batch)

loss_ce = ce_loss(outputs, label_batch.long())

if iter_num < args.thr_iter:

loss = loss_ce

else:

scribbles = label_batch.long().cpu()

mean_0, mean_1, mean_2, mean_3 = weight_batch[..., 0], weight_batch[..., 1], weight_batch[..., 2], \

weight_batch[..., 3]

# print(torch.zeros_like(mean_0).long().dtype, (4*torch.ones_like(scribbles.long())).dtype)

u_labels_0 = torch.where((mean_0 > args.thr_conf) & (scribbles == 4),

torch.zeros_like(mean_0), 4. * torch.ones_like(scribbles)).cuda()

u_labels_1 = torch.where((mean_1 > args.thr_conf) & (scribbles == 4),

torch.zeros_like(mean_1) + 1, 4. * torch.ones_like(scribbles)).cuda()

u_labels_2 = torch.where((mean_2 > args.thr_conf) & (scribbles == 4),

torch.zeros_like(mean_2) + 2, 4. * torch.ones_like(scribbles)).cuda()

u_labels_3 = torch.where((mean_3 > args.thr_conf) & (scribbles == 4),

torch.zeros_like(mean_3) + 3, 4. * torch.ones_like(scribbles)).cuda()

u_labels = torch.ones_like(u_labels_0).long() * 4

u_labels[u_labels_0 == 0] = 0

u_labels[u_labels_1 == 1] = 1

u_labels[u_labels_2 == 2] = 2

u_labels[u_labels_3 == 3] = 3

loss_u = u_ce_loss(outputs, u_labels)

loss = loss_ce + 0.5 * loss_u

optimizer.zero_grad()

loss.backward()

optimizer.step()

lr_ = base_lr * (1.0 - iter_num / max_iterations) ** 0.9

for param_group in optimizer.param_groups:

param_group['lr'] = lr_

iter_num = iter_num + 1

writer.add_scalar('info/lr', lr_, iter_num)

writer.add_scalar('info/total_loss', loss, iter_num)

writer.add_scalar('info/loss_ce', loss_ce, iter_num)

if iter_num > args.thr_iter:

writer.add_scalar('info/loss_weight', loss_u, iter_num)

if iter_num % 20 == 0:

image = volume_batch[1, 0:1, :, :]

image = (image - image.min()) / (image.max() - image.min())

writer.add_image('train/Image', image, iter_num)

outputs = torch.argmax(torch.softmax(

outputs, dim=1), dim=1, keepdim=True)

writer.add_image('train/Prediction',

outputs[1, ...] * 50, iter_num)

labs = label_batch[1, ...].unsqueeze(0) * 50

writer.add_image('train/GroundTruth', labs, iter_num)

if iter_num > 0 and iter_num % 200 == 0:

model.eval()

metric_list = 0.0

for i_batch, sampled_batch in enumerate(valloader):

metric_i = test_single_volume(

sampled_batch["image"], sampled_batch["label"], model, classes=num_classes)

metric_list += np.array(metric_i)

metric_list = metric_list / len(db_val)

for class_i in range(num_classes-1):

writer.add_scalar(

'info/val_{}_dice'.format(class_i+1), metric_list[class_i, 0], iter_num)

writer.add_scalar(

'info/val_{}_hd95'.format(class_i+1), metric_list[class_i, 1], iter_num)

performance = np.mean(metric_list, axis=0)[0]

mean_hd95 = np.mean(metric_list, axis=0)[1]

writer.add_scalar('info/val_mean_dice', performance, iter_num)

writer.add_scalar('info/val_mean_hd95', mean_hd95, iter_num)

if performance > best_performance:

best_performance = performance

save_mode_path = os.path.join(snapshot_path,

'iter_{}_dice_{}.pth'.format(

iter_num, round(best_performance, 4)))

save_best = os.path.join(

snapshot_path, '{}_best_model.pth'.format(args.model))

torch.save(model.state_dict(), save_mode_path)

torch.save(model.state_dict(), save_best)

logging.info(

'iteration %d : mean_dice : %f mean_hd95 : %f' % (iter_num, performance, mean_hd95))

model.train()

if iter_num % 3000 == 0:

save_mode_path = os.path.join(

snapshot_path, 'iter_' + str(iter_num) + '.pth')

torch.save(model.state_dict(), save_mode_path)

logging.info("save model to {}".format(save_mode_path))

if iter_num > 0 and iter_num % args.period_iter == 0:

logging.info("update weight start")

ds = trainloader.dataset

if not os.path.exists(os.path.join(snapshot_path, 'ensemble', str(iter_num))):

os.makedirs(os.path.join(snapshot_path,

'ensemble', str(iter_num)))

# for idx, images in tqdm(ds.images.items(), total=len(ds)):

for idx, images in ds.images.items():

img = images['image']

img = zoom(

img, (256 / img.shape[0], 256 / img.shape[1]), order=0)

img = torch.from_numpy(img).unsqueeze(

0).unsqueeze(0).cuda()

with torch.no_grad():

pred = torch.nn.functional.softmax(model(img), dim=1)

pred = pred.squeeze(0).cpu().numpy()

pred = zoom(

pred, (1, images['image'].shape[0] / 256, images['image'].shape[1] / 256), order=0)

pred = torch.from_numpy(pred)

weight = torch.from_numpy(images['weight'])

x0, x1, x2, x3 = pred[0], pred[1], pred[2], pred[3]

weight[..., 0] = args.alpha * x0 + \

(1 - args.alpha) * weight[..., 0]

weight[..., 1] = args.alpha * x1 + \

(1 - args.alpha) * weight[..., 1]

weight[..., 2] = args.alpha * x2 + \

(1 - args.alpha) * weight[..., 2]

weight[..., 3] = args.alpha * x3 + \

(1 - args.alpha) * weight[..., 3]

trainloader.dataset.images[idx]['weight'] = weight.numpy()

# img = Image.fromarray(np.array((weight[..., 1] + weight[..., 2] + weight[..., 3]).cpu().numpy() * 255, dtype=np.uint8))

# img = img.convert('RGB')

# if not os.path.exists(os.path.join(snapshot_path, 'ensemble', str(iter_num), images['id'].split('_')[0])):

# os.mkdir(os.path.join(snapshot_path, 'ensemble', str(iter_num), images['id'].split('_')[0]))

# img.save(os.path.join(snapshot_path, 'ensemble', str(iter_num), images['id'].split('_')[0], images['id'].replace('.h5', '.png')))

logging.info("update weight end")

if iter_num >= max_iterations:

break

if iter_num >= max_iterations:

iterator.close()

break

writer.close()