def inference():
model = DFSeg_model.RedNet(num_classes=40, pretrained=False)
#model = nn.DataParallel(model)
load_ckpt(model, None, args.last_ckpt, device)
model.eval()
model.to(device)
val_data = SUNRGBD(transform=torchvision.transforms.Compose([scaleNorm(),
ToTensor(),
Normalize()]),
phase_train=False,
data_dir=args.data_dir
)
val_loader = DataLoader(val_data, batch_size=1, shuffle=False,num_workers=1, pin_memory=True)
acc_meter = AverageMeter()
intersection_meter = AverageMeter()
union_meter = AverageMeter()
a_meter = AverageMeter()
b_meter = AverageMeter()
with torch.no_grad():
for batch_idx, sample in enumerate(val_loader):
#origin_image = sample['origin_image'].numpy()
#origin_depth = sample['origin_depth'].numpy()
image = sample['image'].to(device)
depth = sample['depth'].to(device)
label = sample['label'].numpy()
with torch.no_grad():
pred = model(image, depth)
output = torch.max(pred, 1)[1] + 1
output = output.squeeze(0).cpu().numpy()
acc, pix = accuracy(output, label)
intersection, union = intersectionAndUnion(output, label, args.num_class)
acc_meter.update(acc, pix)
a_m, b_m = macc(output, label, args.num_class)
intersection_meter.update(intersection)
union_meter.update(union)
a_meter.update(a_m)
b_meter.update(b_m)
print('[{}] iter {}, accuracy: {}'
.format(datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"),
batch_idx, acc))
# img = image.cpu().numpy()
# print('origin iamge: ', type(origin_image))
#if args.visualize:
# visualize_result(origin_image, origin_depth, label-1, output-1, batch_idx, args)
iou = intersection_meter.sum / (union_meter.sum + 1e-10)
for i, _iou in enumerate(iou):
print('class [{}], IoU: {}'.format(i, _iou))
mAcc = (a_meter.average() / (b_meter.average()+1e-10))
print(mAcc.mean())
print('[Eval Summary]:')
print('Mean IoU: {:.4}, Accuracy: {:.2f}%'
.format(iou.mean(), acc_meter.average() * 100))
def train():
# 记录数据在tensorboard中显示
writer_loss = SummaryWriter(os.path.join(args.summary_dir, 'loss'))
# writer_loss1 = SummaryWriter(os.path.join(args.summary_dir, 'loss', 'loss1'))
# writer_loss2 = SummaryWriter(os.path.join(args.summary_dir, 'loss', 'loss2'))
# writer_loss3 = SummaryWriter(os.path.join(args.summary_dir, 'loss', 'loss3'))
writer_acc = SummaryWriter(os.path.join(args.summary_dir, 'macc'))
# 准备数据集
train_data = data_eval.ReadData(transform=transforms.Compose([
data_eval.scaleNorm(),
data_eval.RandomScale((1.0, 1.4)),
data_eval.RandomHSV((0.9, 1.1), (0.9, 1.1), (25, 25)),
data_eval.RandomCrop(image_h, image_w),
data_eval.RandomFlip(),
data_eval.ToTensor(),
data_eval.Normalize()
]),
data_dir=args.train_data_dir)
train_loader = DataLoader(train_data,
batch_size=args.batch_size,
shuffle=True,
num_workers=args.workers,
pin_memory=False,
drop_last=True)
val_data = data_eval.ReadData(transform=transforms.Compose([
data_eval.scaleNorm(),
data_eval.RandomScale((1.0, 1.4)),
data_eval.RandomCrop(image_h, image_w),
data_eval.ToTensor(),
data_eval.Normalize()
]),
data_dir=args.val_data_dir)
val_loader = DataLoader(val_data,
batch_size=args.batch_size,
shuffle=True,
num_workers=args.workers,
pin_memory=False,
drop_last=True)
num_train = len(train_data)
# num_val = len(val_data)
# build model
if args.last_ckpt:
model = MultiTaskCNN_Atten(38,
depth_channel=1,
pretrained=False,
arch='resnet50',
use_aspp=True)
else:
model = MultiTaskCNN_Atten(38,
depth_channel=1,
pretrained=True,
arch='resnet50',
use_aspp=True)
# build optimizer
if args.optimizer == 'rmsprop':
optimizer = torch.optim.RMSprop(model.parameters(), args.lr)
elif args.optimizer == 'sgd':
optimizer = torch.optim.SGD(model.parameters(),
args.lr,
momentum=0.9,
weight_decay=1e-4)
elif args.optimizer == 'adam':
optimizer = torch.optim.Adam(model.parameters(), args.lr)
else: # rmsprop
print('not supported optimizer \n')
return None
global_step = 0
max_miou_val = 0
loss_count = 0
# 如果有模型的训练权重,则获取global_step,start_epoch
if args.last_ckpt:
global_step, args.start_epoch = load_ckpt(model, optimizer,
args.last_ckpt, device)
# if torch.cuda.device_count() > 1 and args.cuda and torch.cuda.is_available():
# print("Let's use", torch.cuda.device_count(), "GPUs!")
# model = torch.nn.DataParallel(model).to(device)
model = model.to(device)
model.train()
# cal_param(model, data)
loss_func = nn.CrossEntropyLoss()
for epoch in range(int(args.start_epoch), args.epochs):
torch.cuda.empty_cache()
# if epoch <= freeze_epoch:
# for layer in [model.conv1, model.maxpool,model.layer1, model.layer2, model.layer3, model.layer4]:
# for param in layer.parameters():
# param.requires_grad = False
tq = tqdm(total=len(train_loader) * args.batch_size)
if loss_count >= 10:
args.lr = 0.5 * args.lr
loss_count = 0
lr = poly_lr_scheduler(optimizer,
args.lr,
iter=epoch,
max_iter=args.epochs)
optimizer.param_groups[0]['lr'] = lr
# scheduler = torch.optim.lr_scheduler.StepLR(optimizer, 30, gamma=0.5)
tq.set_description('epoch %d, lr %f' % (epoch, args.lr))
loss_record = []
# loss1_record = []
# loss2_record = []
# loss3_record = []
local_count = 0
# print('1')
for batch_idx, data in enumerate(train_loader):
image = data['image'].to(device)
depth = data['depth'].to(device)
label = data['label'].long().to(device)
# print('label', label.shape)
output, output_sup1, output_sup2 = model(image, depth)
loss1 = loss_func(output, label)
loss2 = loss_func(output_sup1, label)
loss3 = loss_func(output_sup2, label)
loss = loss1 + loss2 + loss3
tq.update(args.batch_size)
tq.set_postfix(loss='%.6f' % loss)
optimizer.zero_grad()
loss.backward()
optimizer.step()
global_step += 1
local_count += image.data.shape[0]
# writer_loss.add_scalar('loss_step', loss, global_step)
# writer_loss1.add_scalar('loss1_step', loss1, global_step)
# writer_loss2.add_scalar('loss2_step', loss2, global_step)
# writer_loss3.add_scalar('loss3_step', loss3, global_step)
loss_record.append(loss.item())
# loss1_record.append(loss1.item())
# loss2_record.append(loss2.item())
# loss3_record.append(loss3.item())
if global_step % args.print_freq == 0 or global_step == 1:
for name, param in model.named_parameters():
writer_loss.add_histogram(name,
param.clone().cpu().data.numpy(),
global_step,
bins='doane')
writer_loss.add_graph(model, [image, depth])
grid_image1 = make_grid(image[:3].clone().cpu().data,
3,
normalize=True)
writer_loss.add_image('image', grid_image1, global_step)
grid_image2 = make_grid(depth[:3].clone().cpu().data,
3,
normalize=True)
writer_loss.add_image('depth', grid_image2, global_step)
grid_image3 = make_grid(utils.color_label(
torch.max(output[:3], 1)[1]),
3,
normalize=False,
range=(0, 255))
writer_loss.add_image('Predicted label', grid_image3,
global_step)
grid_image4 = make_grid(utils.color_label(label[:3]),
3,
normalize=False,
range=(0, 255))
writer_loss.add_image('Groundtruth label', grid_image4,
global_step)
tq.close()
loss_train_mean = np.mean(loss_record)
with open(log_file, 'a') as f:
f.write(str(epoch) + '\t' + str(loss_train_mean))
# loss1_train_mean = np.mean(loss1_record)
# loss2_train_mean = np.mean(loss2_record)
# loss3_train_mean = np.mean(loss3_record)
writer_loss.add_scalar('epoch/loss_epoch_train',
float(loss_train_mean), epoch)
# writer_loss1.add_scalar('epoch/sub_loss_epoch_train', float(loss1_train_mean), epoch)
# writer_loss2.add_scalar('epoch/sub_loss_epoch_train', float(loss2_train_mean), epoch)
# writer_loss3.add_scalar('epoch/sub_loss_epoch_train', float(loss3_train_mean), epoch)
print('loss for train : %f' % loss_train_mean)
print('----validation starting----')
# tq_val = tqdm(total=len(val_loader) * args.batch_size)
# tq_val.set_description('epoch %d' % epoch)
model.eval()
val_total_time = 0
with torch.no_grad():
sys.stdout.flush()
tbar = tqdm(val_loader)
acc_meter = AverageMeter()
intersection_meter = AverageMeter()
union_meter = AverageMeter()
a_meter = AverageMeter()
b_meter = AverageMeter()
for batch_idx, sample in enumerate(tbar):
# origin_image = sample['origin_image'].numpy()
# origin_depth = sample['origin_depth'].numpy()
image_val = sample['image'].to(device)
depth_val = sample['depth'].to(device)
label_val = sample['label'].numpy()
with torch.no_grad():
start = time.time()
pred = model(image_val, depth_val)
end = time.time()
duration = end - start
val_total_time += duration
# tq_val.set_postfix(fps ='%.4f' % (args.batch_size / (end - start)))
print_str = 'Test step [{}/{}].'.format(
batch_idx + 1, len(val_loader))
tbar.set_description(print_str)
output_val = torch.max(pred, 1)[1]
output_val = output_val.squeeze(0).cpu().numpy()
acc, pix = accuracy(output_val, label_val)
intersection, union = intersectionAndUnion(
output_val, label_val, args.num_class)
acc_meter.update(acc, pix)
a_m, b_m = macc(output_val, label_val, args.num_class)
intersection_meter.update(intersection)
union_meter.update(union)
a_meter.update(a_m)
b_meter.update(b_m)
fps = len(val_loader) / val_total_time
print('fps = %.4f' % fps)
tbar.close()
mAcc = (a_meter.average() / (b_meter.average() + 1e-10))
with open(log_file, 'a') as f:
f.write(' ' + str(mAcc.mean()) + '\n')
iou = intersection_meter.sum / (union_meter.sum + 1e-10)
writer_acc.add_scalar('epoch/Acc_epoch_train', mAcc.mean(), epoch)
print('----validation finished----')
model.train()
# # 每隔save_epoch_freq个epoch就保存一次权重
if epoch != args.start_epoch:
if iou.mean() >= max_miou_val:
print('mIoU:', iou.mean())
if not os.path.isdir(args.ckpt_dir):
os.mkdir(args.ckpt_dir)
save_ckpt(args.ckpt_dir, model, optimizer, global_step, epoch,
local_count, num_train)
max_miou_val = iou.mean()
# max_macc_val = mAcc.mean()
else:
loss_count += 1
torch.cuda.empty_cache()
def inference():
writer_image = SummaryWriter(os.path.join(args.summary_dir, 'segtest'))
model = MultiTaskCNN(38,
depth_channel=1,
pretrained=False,
arch='resnet50',
use_aspp=False)
load_ckpt(model, None, args.last_ckpt, device)
model.eval()
model = model.to(device)
val_data = data_eval.ReadData(transform=torchvision.transforms.Compose(
[data_eval.scaleNorm(),
data_eval.ToTensor(),
Normalize()]),
data_dir=args.data_dir)
val_loader = DataLoader(val_data,
batch_size=1,
shuffle=False,
num_workers=4,
pin_memory=False)
acc_meter = AverageMeter()
intersection_meter = AverageMeter()
union_meter = AverageMeter()
a_meter = AverageMeter()
b_meter = AverageMeter()
test_total_time = 0
with torch.no_grad():
for batch_idx, sample in enumerate(val_loader):
# origin_image = sample['origin_image'].to(device)
# origin_depth = sample['origin_depth'].to(device)
image = sample['image'].to(device)
depth = sample['depth'].to(device)
label = sample['label'].numpy()
show_label = sample['label'].long().to(device)
with torch.no_grad():
time1 = time.time()
pred = model(image, depth)
time2 = time.time()
test_total_time += (time2 - time1)
output = torch.max(pred, 1)[1]
# # output = output.squeeze(0).cpu().numpy()
output = output.cpu().numpy()
acc, pix = accuracy(output, label)
intersection, union = intersectionAndUnion(output, label,
args.num_class)
acc_meter.update(acc, pix)
a_m, b_m = macc(output, label, args.num_class)
intersection_meter.update(intersection)
union_meter.update(union)
a_meter.update(a_m)
b_meter.update(b_m)
if batch_idx % 50 == 0:
grid_image1 = make_grid(image[:1].clone().cpu().data,
1,
normalize=True)
writer_image.add_image('image', grid_image1, batch_idx)
grid_image2 = make_grid(depth[:1].clone().cpu().data,
1,
normalize=True)
writer_image.add_image('depth', grid_image2, batch_idx)
grid_image3 = make_grid(utils.color_label(
torch.max(pred[:1], 1)[1]),
1,
normalize=False,
range=(0, 255))
writer_image.add_image('Predicted label', grid_image3,
batch_idx)
grid_image4 = make_grid(utils.color_label(show_label[:1]),
1,
normalize=False,
range=(0, 255))
writer_image.add_image('Groundtruth label', grid_image4,
batch_idx)
print('[{}] iter {}, accuracy: {}'.format(
datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"),
batch_idx, acc))
# if batch_idx % 1 == 0:
# if args.visualize:
# visualize_result(origin_image, origin_depth, label, output, batch_idx, args)
# visualize_result(origin_image, origin_depth, label - 1, output - 1, batch_idx, args)
print('推理时间:', test_total_time / len(val_data), '\nfps:',
len(val_data) / test_total_time)
iou = intersection_meter.sum / (union_meter.sum + 1e-10)
for i, _iou in enumerate(iou):
print('class [{}], IoU: {}'.format(i, _iou))
# mAcc:Prediction和Ground Truth对应位置的“分类”准确率(每个像素)
mAcc = (a_meter.average() / (b_meter.average() + 1e-10))
print(mAcc.mean())
print('[Eval Summary]:')
print('Mean IoU: {:.4}, Accuracy: {:.2f}%'.format(
iou.mean(),
acc_meter.average() * 100))
def evaluate():
model = ACNet_models_V1.ACNet(num_class=5, pretrained=False)
load_ckpt(model, None, None, args.last_ckpt, device)
model.eval()
model.to(device)
val_data = ACNet_data.FreiburgForest(
transform=torchvision.transforms.Compose([
ACNet_data.ScaleNorm(),
ACNet_data.ToTensor(),
ACNet_data.Normalize()
]),
data_dirs=[args.test_dir],
modal1_name=args.modal1,
modal2_name=args.modal2,
)
val_loader = DataLoader(val_data, batch_size=1, shuffle=False, num_workers=1, pin_memory=True)
acc_meter = AverageMeter()
intersection_meter = AverageMeter()
union_meter = AverageMeter()
a_meter = AverageMeter()
b_meter = AverageMeter()
with torch.no_grad():
for batch_idx, sample in enumerate(val_loader):
modal1 = sample['modal1'].to(device)
modal2 = sample['modal2'].to(device)
label = sample['label'].numpy()
basename = sample['basename'][0]
with torch.no_grad():
pred = model(modal1, modal2)
output = torch.argmax(pred, 1) + 1
output = output.squeeze(0).cpu().numpy()
acc, pix = accuracy(output, label)
intersection, union = intersectionAndUnion(output, label, args.num_class)
acc_meter.update(acc, pix)
a_m, b_m = macc(output, label, args.num_class)
intersection_meter.update(intersection)
union_meter.update(union)
a_meter.update(a_m)
b_meter.update(b_m)
print('[{}] iter {}, accuracy: {}'
.format(datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"), batch_idx, acc))
if args.visualize:
visualize_result(modal1, modal2, label, output, batch_idx, args)
if args.save_predictions:
colored_output = utils.color_label_eval(output).astype(np.uint8)
imageio.imwrite(f'{args.output_dir}/{basename}_pred.png', colored_output.transpose([1, 2, 0]))
iou = intersection_meter.sum / (union_meter.sum + 1e-10)
for i, _iou in enumerate(iou):
print('class [{}], IoU: {}'.format(i, _iou))
mAcc = (a_meter.average() / (b_meter.average() + 1e-10))
print(mAcc.mean())
print('[Eval Summary]:')
print('Mean IoU: {:.4}, Accuracy: {:.2f}%'
.format(iou.mean(), acc_meter.average() * 100))
