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trainer.py
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trainer.py
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import argparse
import logging
import os
import random
import sys
import time
import glob
import numpy as np
import torch
import torch.nn as nn
import torch.optim as optim
from tensorboardX import SummaryWriter
from torch.nn.modules.loss import CrossEntropyLoss
from torch.utils.data import DataLoader
from tqdm import tqdm
from utils import DiceLoss
from torchvision import transforms
from utils import test_single_volume
from torch.nn import functional as F
from datasets.dataset_synapse import Synapse_dataset, RandomGenerator, SynapseDatasetFast
import matplotlib.pyplot as plt
import pandas as pd
import datetime
def inference(model, testloader, args, test_save_path=None):
model.eval()
metric_list = 0.0
for i_batch, sampled_batch in tqdm(enumerate(testloader)):
h, w = sampled_batch["image"].size()[2:]
image, label, case_name = sampled_batch["image"], sampled_batch["label"], sampled_batch['case_name'][0]
metric_i = test_single_volume(image, label, model, classes=args.num_classes, patch_size=[args.img_size, args.img_size],
test_save_path=test_save_path, case=case_name, z_spacing=args.z_spacing)
metric_list += np.array(metric_i)
logging.info(' idx %d case %s mean_dice %f mean_hd95 %f' % (i_batch, case_name, np.mean(metric_i, axis=0)[0], np.mean(metric_i, axis=0)[1]))
metric_list = metric_list / len(testloader.dataset)
for i in range(1, args.num_classes):
logging.info('Mean class %d mean_dice %f mean_hd95 %f' % (i, metric_list[i-1][0], metric_list[i-1][1]))
performance = np.mean(metric_list, axis=0)[0]
mean_hd95 = np.mean(metric_list, axis=0)[1]
logging.info('Testing performance in best val model: mean_dice : %f mean_hd95 : %f' % (performance, mean_hd95))
return performance, mean_hd95
def plot_result(dice, h, snapshot_path,args):
dict = {'mean_dice': dice, 'mean_hd95': h}
df = pd.DataFrame(dict)
plt.figure(0)
df['mean_dice'].plot()
resolution_value = 1200
plt.title('Mean Dice')
date_and_time = datetime.datetime.now()
filename = f'{args.model_name}_' + str(date_and_time)+'dice'+'.png'
save_mode_path = os.path.join(snapshot_path, filename)
plt.savefig(save_mode_path, format="png", dpi=resolution_value)
plt.figure(1)
df['mean_hd95'].plot()
plt.title('Mean hd95')
filename = f'{args.model_name}_' + str(date_and_time)+'hd95'+'.png'
save_mode_path = os.path.join(snapshot_path, filename)
#save csv
filename = f'{args.model_name}_' + str(date_and_time)+'results'+'.csv'
save_mode_path = os.path.join(snapshot_path, filename)
df.to_csv(save_mode_path, sep='\t')
def trainer_synapse(args, model, snapshot_path):
os.makedirs(os.path.join(snapshot_path, 'test'), exist_ok=True)
test_save_path = os.path.join(snapshot_path, 'test')
logging.basicConfig(filename=snapshot_path + "/log.txt", level=logging.INFO,
format='[%(asctime)s.%(msecs)03d] %(message)s', datefmt='%H:%M:%S')
logging.getLogger().addHandler(logging.StreamHandler(sys.stdout))
logging.info(str(args))
base_lr = args.base_lr
num_classes = args.num_classes
batch_size = args.batch_size * args.n_gpu
# max_iterations = args.max_iterations
x_transforms = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize([0.5], [0.5])
])
y_transforms = transforms.ToTensor()
if args.dstr_fast:
print("\n\nUSING FAST DATASET...\n")
db_train = SynapseDatasetFast(base_dir=args.root_path, list_dir=args.list_dir, split="train",img_size=args.img_size,
norm_x_transform = x_transforms, norm_y_transform = y_transforms)
else:
db_train = Synapse_dataset(base_dir=args.root_path, list_dir=args.list_dir, split="train",img_size=args.img_size,
norm_x_transform = x_transforms, norm_y_transform = y_transforms)
print("The length of train set is: {}".format(len(db_train)))
def worker_init_fn(worker_id):
random.seed(args.seed + worker_id)
trainloader = DataLoader(db_train, batch_size=batch_size, shuffle=True, num_workers=args.num_workers, pin_memory=True,
worker_init_fn=worker_init_fn)
db_test = Synapse_dataset(base_dir=args.test_path, split="test_vol", list_dir=args.list_dir, img_size=args.img_size)
testloader = DataLoader(db_test, batch_size=1, shuffle=False, num_workers=1)
curr_epoch = 0
if args.continue_tr:
snapshot = os.path.join(args.output_dir, 'best_model.pth')
if not os.path.exists(snapshot):
saved_models = glob.glob(f"{args.output_dir}/{args.model_name}_epoch_*.pth")
if len(saved_models):
saved_eps = [int(ep.split("/")[-1].split('_')[-1][:-4]) for ep in saved_models]
max_saved_eps = max(saved_eps)
snapshot = snapshot.replace('best_model', args.model_name+'_epoch_'+str(max_saved_eps))
msg = model.load_state_dict(torch.load(snapshot))
print(f"Loaded {snapshot}", msg)
curr_epoch = max_saved_eps+1
else:
print("\nThere was no pre-trained model to continue!\nStart training from zero...\n")
if args.n_gpu > 1:
model = nn.DataParallel(model)
model.train()
ce_loss = CrossEntropyLoss()
dice_loss = DiceLoss(num_classes)
if args.optimizer.lower() == 'sgd':
optimizer = optim.SGD(model.parameters(), lr=base_lr, momentum=0.9, weight_decay=0.0001)
else: #AdamW
optimizer = optim.AdamW(model.parameters(), lr=0.0005, weight_decay=0.0)
scheduler = optim.lr_scheduler.ReduceLROnPlateau(optimizer, 'min', factor=0.5, patience=10)
writer = SummaryWriter(snapshot_path + '/log')
iter_num = 0
max_epoch = args.max_epochs
max_iterations = args.max_epochs * len(trainloader) # max_epoch = max_iterations // len(trainloader) + 1
logging.info("{} iterations per epoch. {} max iterations ".format(len(trainloader), max_iterations))
best_performance = 0.0
iterator = tqdm(range(max_epoch), ncols=70)
if curr_epoch > 0:
for epoch_num in iterator:
iter_num += len(trainloader)
curr_epoch -= 1
if not curr_epoch: break
dice_=[]
hd95_= []
dlw = args.dice_loss_weight # default: 0.6
for epoch_num in iterator:
for i_batch, sampled_batch in enumerate(trainloader):
image_batch, label_batch = sampled_batch['image'], sampled_batch['label']
# print("data shape---------", image_batch.shape, label_batch.shape)
image_batch, label_batch = image_batch.cuda(), label_batch.squeeze(1).cuda()
outputs = model(image_batch)
# outputs = F.interpolate(outputs, size=label_batch.shape[1:], mode='bilinear', align_corners=False)
loss_ce = ce_loss(outputs, label_batch[:].long())
loss_dice = dice_loss(outputs, label_batch, softmax=True)
loss = (1-dlw)*loss_ce + dlw*loss_dice
# print("loss-----------", loss)
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)
writer.add_scalar('info/loss_dice', loss_dice, iter_num)
logging.info('iteration %d : loss : %f, loss_ce: %f, loss_dice: %f' % (iter_num, loss.item(), loss_ce.item(), loss_dice.item()))
if iter_num % 20 == 0:
image = image_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)
# Test
eval_interval = args.eval_interval
if epoch_num >= int(max_epoch / 2) and (epoch_num + 1) % eval_interval == 0:
filename = f'{args.model_name}_epoch_{epoch_num}.pth'
save_mode_path = os.path.join(snapshot_path, filename)
torch.save(model.state_dict(), save_mode_path)
logging.info("save model to {}".format(save_mode_path))
logging.info("*" * 20)
logging.info(f"Running Inference after epoch {epoch_num}")
print(f"Epoch {epoch_num}")
mean_dice, mean_hd95 = inference(model, testloader, args, test_save_path=test_save_path)
dice_.append(mean_dice)
hd95_.append(mean_hd95)
model.train()
if epoch_num >= max_epoch - 1:
filename = f'{args.model_name}_epoch_{epoch_num}.pth'
save_mode_path = os.path.join(snapshot_path, filename)
torch.save(model.state_dict(), save_mode_path)
logging.info("save model to {}".format(save_mode_path))
if not (epoch_num + 1) % args.eval_interval == 0:
logging.info("*" * 20)
logging.info(f"Running Inference after epoch {epoch_num} (Last Epoch)")
print(f"Epoch {epoch_num}, Last Epcoh")
mean_dice, mean_hd95 = inference(model, testloader, args, test_save_path=test_save_path)
dice_.append(mean_dice)
hd95_.append(mean_hd95)
model.train()
iterator.close()
break
plot_result(dice_, hd95_, snapshot_path, args)
writer.close()
return "Training Finished!"