def test(net, epoch, dataLoader, testF, config):
net.eval()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
result = {"TP": {i:0 for i in range(8)}, "TA":{i:0 for i in range(8)}}
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(device=device_list[0]), mask.cuda(device=device_list[0])
out = net(image)
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASSES)(out, mask)
# detach()截断梯度的作用,截断后如果tensor中的data发生了变化,反向传播时会报错(和正向传播时候的值不一样了)
total_mask_loss += mask_loss.detach().item()
# dim表示对channle进行处理得到N,H,W
pred = torch.argmax(F.softmax(out, dim=1), dim=1)
# 计算iou
result = compute_iou(pred, mask, result)
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(mask_loss))
testF.write("Epoch:{} \n".format(epoch))
# 求出每一个类别的iou
for i in range(8):
# 计算每一类的交并比
result_string = "{}: {:.4f} \n".format(i, result["TP"][i]/result["TA"][i])
print(result_string)
# 写入测试log文件
testF.write(result_string)
testF.write("Epoch:{}, mask loss is {:.4f} \n".format(epoch, total_mask_loss / len(dataLoader)))
testF.flush()
def test(net, epoch, dataLoader, testF, config):
net.eval()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
result = {"TP": {i: 0 for i in range(8)}, "TA": {i: 0 for i in range(8)}}
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(device=device_list[0]), mask.cuda(
device=device_list[0])
out = net(image)
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASSES)(
out, mask)
total_mask_loss += mask_loss.detach().item()
pred = torch.argmax(F.softmax(out, dim=1), dim=1)
result = compute_iou(pred, mask, result)
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(mask_loss))
testF.write("Epoch:{} \n".format(epoch))
for i in range(8):
result_string = "{}: {:.4f} \n".format(
i, result["TP"][i] / result["TA"][i])
print(result_string)
testF.write(result_string)
testF.write("Epoch:{}, mask loss is {:.4f} \n".format(
epoch, total_mask_loss / len(dataLoader)))
testF.flush()
def val_epoch(net, epoch, dataLoader, valF, args):
logger.info("======start val epoch step=======")
net.eval()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
result = {"TP": {i: 0 for i in range(8)}, "TA": {i: 0 for i in range(8)}}
evaluator = Evaluator(args.number_class)
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
out = net(image)
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=args.number_class)(
out, mask)
total_mask_loss += mask_loss.detach().item()
pred = torch.argmax(F.softmax(out, dim=1), dim=1)
result = compute_iou(pred, mask, result)
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(mask_loss))
Acc = evaluator.Pixel_Accuracy()
Acc_class = evaluator.Pixel_Accuracy_Class()
mIoU = evaluator.Mean_Intersection_over_Union()
FWIoU = evaluator.Frequency_Weighted_Intersection_over_Union()
valF.write("Epoch:{}, val/mIoU is {:.4f} \n".format(epoch, mIoU))
valF.write("Epoch:{}, val/Acc is {:.4f} \n".format(epoch, Acc))
valF.write("Epoch:{}, val/Acc_class is {:.4f} \n".format(epoch, Acc_class))
valF.write("Epoch:{}, val/FWIoU is {:.4f} \n".format(epoch, FWIoU))
for i in range(8):
result_string = "{}: {:.4f} \n".format(
i, result["TP"][i] / result["TA"][i])
logger.info("val class result {}".format(result_string))
valF.write(result_string)
valF.write("Epoch:{}, mask loss is {:.4f} \n".format(
epoch, total_mask_loss / len(dataLoader)))
logger.info("Acc:{}, Acc_class:{}, mIoU:{}, fwIoU: {}".format(
Acc, Acc_class, mIoU, FWIoU))
valF.flush()
def main_gen():
# 1. 数据生成器
train_dataset = MyData(cf.params['root_dir'],
cf.params['train_csv'],
transforms=transforms.Compose([
ImageAug(),
ScaleAug(),
CutOut(64, 0.5),
ToTensor()
]))
val_dataset = MyData(cf.params['root_dir'],
cf.params['val_csv'],
transforms=transforms.Compose([ToTensor()]))
test_dataset = MyData(cf.params['root_dir'],
cf.params['test_csv'],
transforms=transforms.Compose([ToTensor()]))
# 2. 数据加载器
kwargs = {
'num_workers': 0,
'pin_memory': True
} if torch.cuda.is_available() else {}
kwargs = {}
train_data_batch = DataLoader(train_dataset,
batch_size=4,
shuffle=True,
drop_last=True,
num_workers=1)
val_data_batch = DataLoader(val_dataset, batch_size=1)
test_data_batch = DataLoader(test_dataset, batch_size=1)
# 3. 模型加载
#lane_config = Config()
model = DeepLabv3Plus()
# 4. 损失函数、优化器
criterion = MySoftmaxCrossEntropyLoss(cf.params['num_class'])
optimizer = torch.optim.SGD(model.parameters(),
lr=cf.params['learning_rate'],
momentum=0.9)
# GPU
if torch.cuda.is_available():
model = model.to(device)
criterion = criterion.to(device)
for epoch in range(cf.params['epochs']):
train(epoch, train_data_batch, model, criterion, optimizer)
# print('loss:\t', loss)
valid(epoch, val_data_batch, model, criterion, optimizer)
# test()
# if epoch % 10 == 0:
# torch.save({'state_dict': model.state_dict()}, os.path.join(cf.params['model_save_path'],
# 'logs','laneNet{}.pth.tar'.format(epoch)))
torch.save({'state_dict': model.state_dict()},
os.path.join(cf.params['model_save_path'], 'finalNet.path'))
def train_epoch(net, epoch, dataLoader, optimizer, trainF, config):
net.train()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(device=device_list[0]), mask.cuda(
device=device_list[0])
# optimizer.zero将每个parameter的梯度清0
optimizer.zero_grad()
# 输出预测的mask
out = net(image)
# 计算交叉熵loss
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASSES)(
out, mask)
total_mask_loss += mask_loss.item()
mask_loss.backward()
optimizer.step()
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(
mask_loss.item()))
# 记录数据迭代了多少次
trainF.write("Epoch:{}, mask loss is {:.4f} \n".format(
epoch, total_mask_loss / len(dataLoader)))
trainF.flush()
def train_epoch(net, epoch, dataLoader, optimizer, trainF, config):
net.train()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
# for batch_item in dataprocess:
accumulation_steps = 8
grid = GridMask(10, 30, 360, 0.6, 1, 0.8)
for i, (batch_item) in enumerate(dataprocess):
grid.set_prob(i, 200)
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(device=device_list[0]), mask.cuda(
device=device_list[0])
# optimizer.zero_grad()
image = grid(image)
out = net(image)
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASSES)(
out, mask)
# total_mask_loss += loss.item()
total_mask_loss += mask_loss.item() / accumulation_steps
mask_loss.backward()
torch.nn.utils.clip_grad_norm_(net.parameters(), 0.25)
#torch.nn.utils.clip_grad_norm_(model.parameters(), max_norm=20, norm_type=2)
if ((i + 1) % accumulation_steps) == 0:
optimizer.step() # 反向传播,更新网络参数
optimizer.zero_grad() # 清空梯度
# optimizer.step()
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(
mask_loss.item()))
trainF.write("Epoch:{}, mask loss is {:.4f} \n".format(
epoch, total_mask_loss / len(dataLoader)))
trainF.flush()
def train_epoch(net, epoch, dataLoader, optimizer, trainF, config):
# 将模型设置为训练状态,此时对droupout的处理是随机失活,对bn层的处理是归一化
# net.eval(),将模型设置为评估状态,预测的时候使用,此时对dropout的处理的
# 使用全部神经元,并且乘以补偿系数,bn层时使用的是参数在batch下的移动平均
net.train()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(device=device_list[0]), mask.cuda(device=device_list[0])
# optimizer.zero将每个parameter的梯度清0
optimizer.zero_grad()
# 输出预测的mask
out = net(image)
# 计算每一类的交叉熵loss
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASSES)(out, mask)
# 计算总交叉熵loss
total_mask_loss += mask_loss.item()
# 反向传播
mask_loss.backward()
# 更新参数
optimizer.step()
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(mask_loss.item()))
# 将每次的loss值写入训练的log文件中
trainF.write("Epoch:{}, mask loss is {:.4f} \n".format(epoch, total_mask_loss / len(dataLoader)))
trainF.flush()
def test_epoch(net, epoch, dataloader, writer, logger, config):
net.eval()
total_mask_loss = 0.0
dataprocess = tqdm(dataloader)
confusion_matrix = np.zeros((config.NUM_CLASS, config.NUM_CLASS))
logger.info("Val EPOCH {}: ".format(epoch))
with torch.no_grad():
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(), mask.cuda()
out = net(image)
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASS)(
out, mask)
total_mask_loss += mask_loss.detach().item()
confusion_matrix += get_confusion_matrix(mask, out, mask.size(),
config.NUM_CLASS)
dataprocess.set_description_str('epoch{}:'.format(epoch))
dataprocess.set_postfix_str('mask loss is {:.4f}'.format(
mask_loss.item()))
logger.info("\taverage loss is {:.4f}".format(total_mask_loss /
len(dataloader)))
pos = confusion_matrix.sum(0)
res = confusion_matrix.sum(1)
tp = np.diag(confusion_matrix)
IoU_array = (tp / np.maximum(1.0, pos + res - tp))
for i in range(8):
print('{} IoU is : {}'.format(i, IoU_array[i]))
logger.info('\t{} Iou is : {}'.format(i, IoU_array[i]))
miou = IoU_array[1:].mean()
logger.info('Val miou is : {:.4f}'.format(miou))
with writer as w:
w.add_scalar('EPOCH Loss', total_mask_loss / len(dataloader),
epoch)
w.add_scalar('EPOCH mIoU', miou, epoch)
print('epoch{}: miou is {}'.format(epoch, miou))
def train_epoch(net, epoch, dataloader, optimizer, writer, logger, config):
#iter = 0
net.train()
confusion_matrix = np.zeros((config.NUM_CLASS, config.NUM_CLASS))
total_mask_loss = 0.0
dataprocess = tqdm(dataloader)
logging.info("Train Epoch {}:".format(epoch))
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
if torch.cuda.is_available():
image, mask = image.cuda(), mask.cuda()
optimizer.zero_grad()
out = net(image)
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=config.NUM_CLASS)(out,
mask)
confusion_matrix += get_confusion_matrix(
mask,
out,
mask.size(),
config.NUM_CLASS,
)
#if iter % 10 == 0:
#w.add_scalar('Epoch{}:Loss'.format(epoch), mask_loss.item(), iter)
#iter += 1
total_mask_loss += mask_loss.item()
mask_loss.backward()
optimizer.step()
dataprocess.set_description('epoch:{}'.format(epoch))
dataprocess.set_postfix_str('mask loss:{:.4f}'.format(
mask_loss.item()))
logger.info("\taverage loss is : {:.3f}".format(total_mask_loss /
len(dataloader)))
#confusion matrix
pos = confusion_matrix.sum(0)
res = confusion_matrix.sum(1)
tp = np.diag(confusion_matrix)
IoU_array = (tp / np.maximum(1.0, pos + res - tp))
for i in range(8):
print('{} iou is : {:.4f}'.format(i, IoU_array[i]))
logger.info("\t {} iou is : {:.4f}".format(i, IoU_array[i]))
miou = IoU_array[1:].mean()
print('EPOCH mIoU is : {}'.format(miou))
logger.info("Train mIoU is : {:.4f}".format(miou))
with writer as w:
w.add_scalar('EPOCH Loss', total_mask_loss / len(dataloader), epoch)
w.add_scalar('Train miou', miou, epoch)
def train_epoch(net, epoch, dataLoader, optimizer, trainF, args):
logger.info("======start training epoch step=======")
net.train()
total_mask_loss = 0.0
dataprocess = tqdm(dataLoader)
for batch_item in dataprocess:
image, mask = batch_item['image'], batch_item['mask']
optimizer.zero_grad()
out = net(image)
logger.info("train predict shape: {}".format(out.shape))
mask_loss = MySoftmaxCrossEntropyLoss(nbclasses=args.number_class)(
out, mask)
total_mask_loss += mask_loss.item()
mask_loss.backward()
# optimizer 进行更新
optimizer.step()
dataprocess.set_description_str("epoch:{}".format(epoch))
dataprocess.set_postfix_str("mask_loss:{:.4f}".format(
mask_loss.item()))
# 记录数据迭代了多少次
trainF.write("Epoch:{}, mask loss is {:.4f} \n".format(
epoch, total_mask_loss / len(dataLoader)))
trainF.flush()
def loss_func(predict, target, nbclasses, epoch):
''' can modify or add losses '''
ce_loss = MySoftmaxCrossEntropyLoss(nbclasses=nbclasses)(predict, target)
return ce_loss
