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etrain.py
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etrain.py
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import torch
from torch.autograd import Variable
import os
os.environ["CUDA_VISIBLE_DEVICES"] = "0"
import argparse
from datetime import datetime
from net.bgnet import Net
from utils.tdataloader import get_loader
from utils.utils import clip_gradient, AvgMeter, poly_lr
import torch.nn.functional as F
import numpy as np
file = open("log/BGNet.txt", "a")
torch.manual_seed(2021)
torch.cuda.manual_seed(2021)
np.random.seed(2021)
torch.backends.cudnn.benchmark = True
def structure_loss(pred, mask):
weit = 1 + 5 * torch.abs(F.avg_pool2d(mask, kernel_size=31, stride=1, padding=15) - mask)
wbce = F.binary_cross_entropy_with_logits(pred, mask, reduction='mean')
wbce = (weit * wbce).sum(dim=(2, 3)) / weit.sum(dim=(2, 3))
pred = torch.sigmoid(pred)
inter = ((pred * mask) * weit).sum(dim=(2, 3))
union = ((pred + mask) * weit).sum(dim=(2, 3))
wiou = 1 - (inter + 1) / (union - inter + 1)
return (wbce + wiou).mean()
def dice_loss(predict, target):
smooth = 1
p = 2
valid_mask = torch.ones_like(target)
predict = predict.contiguous().view(predict.shape[0], -1)
target = target.contiguous().view(target.shape[0], -1)
valid_mask = valid_mask.contiguous().view(valid_mask.shape[0], -1)
num = torch.sum(torch.mul(predict, target) * valid_mask, dim=1) * 2 + smooth
den = torch.sum((predict.pow(p) + target.pow(p)) * valid_mask, dim=1) + smooth
loss = 1 - num / den
return loss.mean()
def train(train_loader, model, optimizer, epoch):
model.train()
loss_record3, loss_record2, loss_record1, loss_recorde = AvgMeter(), AvgMeter(), AvgMeter(), AvgMeter()
for i, pack in enumerate(train_loader, start=1):
optimizer.zero_grad()
# ---- data prepare ----
images, gts, edges = pack
images = Variable(images).cuda()
gts = Variable(gts).cuda()
edges = Variable(edges).cuda()
# ---- forward ----
lateral_map_3, lateral_map_2, lateral_map_1, edge_map = model(images)
# ---- loss function ----
loss3 = structure_loss(lateral_map_3, gts)
loss2 = structure_loss(lateral_map_2, gts)
loss1 = structure_loss(lateral_map_1, gts)
losse = dice_loss(edge_map, edges)
loss = loss3 + loss2 + loss1 + 3*losse
# ---- backward ----
loss.backward()
clip_gradient(optimizer, opt.clip)
optimizer.step()
# ---- recording loss ----
loss_record3.update(loss3.data, opt.batchsize)
loss_record2.update(loss2.data, opt.batchsize)
loss_record1.update(loss1.data, opt.batchsize)
loss_recorde.update(losse.data, opt.batchsize)
# ---- train visualization ----
if i % 60 == 0 or i == total_step:
print('{} Epoch [{:03d}/{:03d}], Step [{:04d}/{:04d}], '
'[lateral-3: {:.4f}], [lateral-2: {:.4f}], [lateral-1: {:.4f}], [edge: {:,.4f}]'.
format(datetime.now(), epoch, opt.epoch, i, total_step,
loss_record3.avg, loss_record2.avg, loss_record1.avg, loss_recorde.avg))
file.write('{} Epoch [{:03d}/{:03d}], Step [{:04d}/{:04d}], '
'[lateral-3: {:.4f}], [lateral-2: {:.4f}], [lateral-1: {:.4f}], [edge: {:,.4f}]\n'.
format(datetime.now(), epoch, opt.epoch, i, total_step,
loss_record3.avg, loss_record2.avg, loss_record1.avg, loss_recorde.avg))
save_path = 'checkpoints/{}/'.format(opt.train_save)
os.makedirs(save_path, exist_ok=True)
if (epoch + 1) % 5 == 0 or (epoch + 1) == opt.epoch:
torch.save(model.state_dict(), save_path + 'BGNet-%d.pth' % epoch)
print('[Saving Snapshot:]', save_path + 'BGNet-%d.pth' % epoch)
file.write('[Saving Snapshot:]' + save_path + 'BGNet-%d.pth' % epoch + '\n')
if __name__ == '__main__':
parser = argparse.ArgumentParser()
parser.add_argument('--epoch', type=int,
default=25, help='epoch number')
parser.add_argument('--lr', type=float,
default=1e-4, help='learning rate')
parser.add_argument('--batchsize', type=int,
default=16, help='training batch size')
parser.add_argument('--trainsize', type=int,
default=416, help='training dataset size')
parser.add_argument('--clip', type=float,
default=0.5, help='gradient clipping margin')
parser.add_argument('--train_path', type=str,
default='./data/TrainDataset', help='path to train dataset')
parser.add_argument('--train_save', type=str,
default='BGNet')
opt = parser.parse_args()
# ---- build models ----
model = Net().cuda()
params = model.parameters()
optimizer = torch.optim.Adam(params, opt.lr)
image_root = '{}/Imgs/'.format(opt.train_path)
gt_root = '{}/GT/'.format(opt.train_path)
edge_root = '{}/Edge/'.format(opt.train_path)
train_loader = get_loader(image_root, gt_root, edge_root, batchsize=opt.batchsize, trainsize=opt.trainsize)
total_step = len(train_loader)
print("Start Training")
for epoch in range(opt.epoch):
poly_lr(optimizer, opt.lr, epoch, opt.epoch)
train(train_loader, model, optimizer, epoch)
file.close()