def val(model, dataloader, mse_loss, rate_loss, ps):
if ps:
ps.log('Validating ... ')
else:
print('Validating ... ')
model.eval()
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
for idx, data in enumerate(dataloader):
# ps.log('%.0f%%' % (idx*100.0/len(dataloader)))
# pdb.set_trace() # 32*7+16 = 240
val_data = Variable(data, volatile=True)
# val_mask = Variable(mask, volatile=True)
# val_o_mask = Variable(o_mask, volatile=True)
# pdb.set_trace()
if opt.use_gpu:
val_data = val_data.cuda(async=True)
# val_mask = val_mask.cuda(async=True)
# val_o_mask = val_o_mask.cuda(async=True)
# reconstructed, imp_mask_sigmoid = model(val_data, val_mask, val_o_mask)
if opt.use_imp:
reconstructed, imp_mask_sigmoid = model(val_data)
else:
reconstructed = model(val_data)
# batch_loss = mse_loss(reconstructed, val_data, val_o_mask)
batch_loss = mse_loss(reconstructed, val_data)
batch_caffe_loss = batch_loss / (2 * opt.batch_size)
if opt.use_imp and rate_loss:
rate_loss_value = rate_loss(imp_mask_sigmoid)
total_loss = batch_caffe_loss + rate_loss_value
mse_loss_meter.add(batch_caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_value.data[0])
rate_display_meter.add(imp_mask_sigmoid.data.mean())
total_loss_meter.add(total_loss.data[0])
if opt.use_imp:
return mse_loss_meter.value()[0], rate_loss_meter.value(
)[0], total_loss_meter.value()[0], rate_display_meter.value()[0]
else:
return mse_loss_meter.value()[0]
def val(model, dataloader, mse_loss, rate_loss, ps):
if ps:
ps.log('validating ... ')
else:
print('run val ... ')
model.eval()
# avg_loss = 0
# progress_bar = tqdm(enumerate(dataloader), total=len(dataloader), ascii=True)
# print(type(next(iter(dataloader))))
# print(next(iter(dataloader)))
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
for idx, (data, _) in enumerate(dataloader):
# ps.log('%.0f%%' % (idx*100.0/len(dataloader)))
val_input = Variable(data, volatile=True)
if opt.use_gpu:
val_input = val_input.cuda(async=True)
reconstructed, imp_mask_sigmoid = model(val_input)
batch_loss = mse_loss(reconstructed, val_input)
batch_caffe_loss = batch_loss / (2 * opt.batch_size)
if opt.use_imp and rate_loss:
rate_loss_display = imp_mask_sigmoid
rate_loss_value = rate_loss(rate_loss_display)
total_loss = batch_caffe_loss + rate_loss_value
mse_loss_meter.add(batch_caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_value.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
# progress_bar.set_description('val_iter %d: loss = %.2f' % (idx+1, batch_caffe_loss.data[0]))
# progress_bar.set_description('val_iter %d: loss = %.2f' % (idx+1, total_loss_meter.value()[0] if opt.use_imp else mse_loss_meter.value()[0]))
# avg_loss += batch_caffe_loss.data[0]
# avg_loss /= len(dataloader)
# print('avg_loss =', avg_loss)
# print('meter loss =', loss_meter.value[0])
# print ('Total avg loss = {}'.format(avg_loss))
if opt.use_imp:
return mse_loss_meter.value()[0], rate_loss_meter.value(
)[0], total_loss_meter.value()[0], rate_display_meter.value()[0]
else:
return mse_loss_meter.value()[0]
def val(compression_model,
c_resnet_51,
dataloader,
class_loss,
rate_loss=None,
ps=None):
if ps:
ps.log('validating ... ')
else:
print('run val ... ')
compression_model.eval()
c_resnet_51.eval()
class_loss_meter = AverageValueMeter()
# if opt.use_imp:
top5_acc_meter = AverageValueMeter()
top1_acc_meter = AverageValueMeter()
# total_loss_meter = AverageValueMeter()
class_loss_meter.reset()
# if opt.use_imp:
top5_acc_meter.reset()
top1_acc_meter.reset()
# total_loss_meter.reset()
for idx, (data, label) in enumerate(dataloader):
#ps.log('%.0f%%' % (idx*100.0/len(dataloader)))
val_input = Variable(data, volatile=True)
label = Variable(label, volatile=True)
if opt.use_gpu:
val_input = val_input.cuda()
label = label.cuda()
# compressed_RGB = compression_model(val_input)
compressed_feat = compression_model(val_input, need_decode=False)
predicted = c_resnet_51(compressed_feat)
val_class_loss = class_loss(predicted, label)
class_loss_meter.add(val_class_loss.data[0])
acc1, acc5 = accuracy(predicted.data, label.data, topk=(1, 5))
top5_acc_meter.add(acc5[0])
top1_acc_meter.add(acc1[0])
return class_loss_meter.value()[0], top5_acc_meter.value(
)[0], top1_acc_meter.value()[0]
def train(**kwargs):
opt.parse(kwargs)
# log file
ps = PlotSaver("FrozenCNN_ResNet50_RGB_" +
time.strftime("%m_%d_%H:%M:%S") + ".log.txt")
# step1: Model
compression_model = getattr(models, opt.model)(
use_imp=opt.use_imp,
model_name="CWCNN_limu_ImageNet_imp_r={r}_γ={w}_for_resnet50".format(
r=opt.rate_loss_threshold, w=opt.rate_loss_weight)
if opt.use_imp else None)
compression_model.load(None, opt.compression_model_ckpt)
compression_model.eval()
# if use_original_RGB:
# resnet_50 = resnet50() # Official ResNet
# else:
# resnet_50 = ResNet50() # My ResNet
c_resnet_51 = cResNet51()
if opt.use_gpu:
# compression_model.cuda()
# resnet_50.cuda()
compression_model = multiple_gpu_process(compression_model)
c_resnet_51 = multiple_gpu_process(c_resnet_51)
# freeze the compression network
for param in compression_model.parameters():
# print (param.requires_grad)
param.requires_grad = False
cudnn.benchmark = True
# pdb.set_trace()
# step2: Data
normalize = transforms.Normalize(mean=[0.485, 0.456, 0.406],
std=[0.229, 0.224, 0.225])
train_data_transforms = transforms.Compose([
transforms.Resize(256),
transforms.RandomCrop(224),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(), normalize
])
val_data_transforms = transforms.Compose([
transforms.Resize(256),
transforms.CenterCrop(224),
transforms.ToTensor(), normalize
])
train_data = datasets.ImageFolder(opt.train_data_root,
train_data_transforms)
val_data = datasets.ImageFolder(opt.val_data_root, val_data_transforms)
train_dataloader = DataLoader(train_data,
opt.batch_size,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
val_dataloader = DataLoader(val_data,
opt.batch_size,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# step3: criterion and optimizer
class_loss = t.nn.CrossEntropyLoss()
lr = opt.lr
# optimizer = t.optim.Adam(resnet_50.parameters(), lr=lr, betas=(0.9, 0.999), weight_decay=opt.weight_decay)
optimizer = t.optim.SGD(c_resnet_51.parameters(),
lr=lr,
momentum=opt.momentum,
weight_decay=opt.weight_decay)
start_epoch = 0
if opt.resume:
start_epoch = c_resnet_51.module.load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training at epoch %d.' % start_epoch)
# step4: meters
class_loss_meter = AverageValueMeter()
class_acc_top5_meter = AverageValueMeter()
class_acc_top1_meter = AverageValueMeter()
# class_loss_meter = AverageMeter()
# class_acc_top5_meter = AverageMeter()
# class_acc_top1_meter = AverageMeter()
# ps init
ps.new_plot('train class loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_CE_loss")
ps.new_plot('val class loss', 1, xlabel="epoch", ylabel="val_CE_loss")
ps.new_plot('train top_5 acc',
opt.print_freq,
xlabel="iteration",
ylabel="train_top5_acc")
ps.new_plot('train top_1 acc',
opt.print_freq,
xlabel="iteration",
ylabel="train_top1_acc")
ps.new_plot('val top_5 acc', 1, xlabel="iteration", ylabel="val_top_5_acc")
ps.new_plot('val top_1 acc', 1, xlabel="iteration", ylabel="val_top_1_acc")
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
# per epoch avg loss meter
class_loss_meter.reset()
class_acc_top1_meter.reset()
class_acc_top5_meter.reset()
# cur_epoch_loss refresh every epoch
ps.new_plot("cur epoch train class loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="cur_train_CE_loss")
c_resnet_51.train()
for idx, (data, label) in enumerate(train_dataloader):
ipt = Variable(data)
label = Variable(label)
if opt.use_gpu:
ipt = ipt.cuda()
label = label.cuda()
optimizer.zero_grad()
# if not use_original_RGB:
# compressed_RGB = compression_model(ipt)
# else:
# compressed_RGB = ipt
# We just wanna compressed features, not to decode this.
compressed_feat = compression_model(ipt, need_decode=False)
# print ('RGB', compressed_RGB.requires_grad)
predicted = c_resnet_51(compressed_feat)
class_loss_ = class_loss(predicted, label)
class_loss_.backward()
optimizer.step()
class_loss_meter.add(class_loss_.data[0])
# class_loss_meter.update(class_loss_.data[0], ipt.size(0))
acc1, acc5 = accuracy(predicted.data, label.data, topk=(1, 5))
# pdb.set_trace()
class_acc_top1_meter.add(acc1[0])
class_acc_top5_meter.add(acc5[0])
# class_acc_top1_meter.update(acc1[0], ipt.size(0))
# class_acc_top5_meter.update(acc5[0], ipt.size(0))
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train class loss',
class_loss_meter.value()[0]
if opt.print_smooth else class_loss_.data[0])
ps.add_point(
'cur epoch train class loss',
class_loss_meter.value()[0]
if opt.print_smooth else class_loss_.data[0])
ps.add_point(
'train top_5 acc',
class_acc_top5_meter.value()[0]
if opt.print_smooth else acc5[0])
ps.add_point(
'train top_1 acc',
class_acc_top1_meter.value()[0]
if opt.print_smooth else acc1[0])
ps.log(
'Epoch %d/%d, Iter %d/%d, class loss = %.4f, top 5 acc = %.2f %%, top 1 acc = %.2f %%, lr = %.8f'
% (epoch, opt.max_epoch, idx, len(train_dataloader),
class_loss_meter.value()[0],
class_acc_top5_meter.value()[0],
class_acc_top1_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
pdb.set_trace()
if use_data_parallel:
c_resnet_51.module.save(optimizer, epoch)
# plot before val can ease me
ps.make_plot(
'train class loss'
) # all epoch share a same img, so give ""(default) to epoch
ps.make_plot('cur epoch train class loss', epoch)
ps.make_plot("train top_5 acc")
ps.make_plot("train top_1 acc")
val_class_loss, val_top5_acc, val_top1_acc = val(
compression_model, c_resnet_51, val_dataloader, class_loss, None,
ps)
ps.add_point('val class loss', val_class_loss)
ps.add_point('val top_5 acc', val_top5_acc)
ps.add_point('val top_1 acc', val_top1_acc)
ps.make_plot('val class loss')
ps.make_plot('val top_5 acc')
ps.make_plot('val top_1 acc')
ps.log(
'Epoch:{epoch}, lr:{lr}, train_class_loss: {train_class_loss}, train_top5_acc: {train_top5_acc} %, train_top1_acc: {train_top1_acc} %, \
val_class_loss: {val_class_loss}, val_top5_acc: {val_top5_acc} %, val_top1_acc: {val_top1_acc} %'
.format(epoch=epoch,
lr=lr,
train_class_loss=class_loss_meter.value()[0],
train_top5_acc=class_acc_top5_meter.value()[0],
train_top1_acc=class_acc_top1_meter.value()[0],
val_class_loss=val_class_loss,
val_top5_acc=val_top5_acc,
val_top1_acc=val_top1_acc))
# adjust lr
if epoch in opt.lr_decay_step_list:
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
def train(**kwargs):
opt.parse(kwargs)
# log file
ps = PlotSaver("Context_Baseline_p32_no_imp_plain_1_" +
time.strftime("%m_%d_%H:%M:%S") + ".log.txt")
# step1: Model
model = getattr(models, opt.model)(
use_imp=opt.use_imp,
model_name="Context_Baseline_p32_imp_r={r}_gama={w}_plain".format(
r=opt.rate_loss_threshold, w=opt.rate_loss_weight)
if opt.use_imp else "ContextBaseNoImpP32_Plain")
if opt.use_gpu:
model = multiple_gpu_process(model)
cudnn.benchmark = True
normalize = transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5])
data_transforms = transforms.Compose([transforms.ToTensor(), normalize])
train_data = datasets.ImageFolder(opt.train_data_root, data_transforms)
val_data = datasets.ImageFolder(opt.val_data_root, data_transforms)
# opt.batch_size --> 1
train_dataloader = DataLoader(train_data,
1,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
val_dataloader = DataLoader(val_data,
1,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# step3: criterion and optimizer
mse_loss = t.nn.MSELoss(size_average=False)
if opt.use_imp:
rate_loss = LimuRateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
lr = opt.lr
optimizer = t.optim.Adam(model.parameters(), lr=lr, betas=(0.9, 0.999))
start_epoch = 0
if opt.resume:
if use_data_parallel:
start_epoch = model.module.load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
else:
start_epoch = model.load(None if opt.finetune else optimizer,
opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training at epoch %d.' % start_epoch)
# step4: meters
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
previous_loss = 1e100
tolerant_now = 0
same_lr_epoch = 0
# ps init
ps.new_plot('train mse loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_mse_loss")
ps.new_plot('val mse loss', 1, xlabel="epoch", ylabel="val_mse_loss")
if opt.use_imp:
ps.new_plot('train rate value',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_value")
ps.new_plot('train rate loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_loss")
ps.new_plot('train total loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_total_loss")
ps.new_plot('val rate value',
1,
xlabel="iteration",
ylabel="val_rate_value")
ps.new_plot('val rate loss',
1,
xlabel="iteration",
ylabel="val_rate_loss")
ps.new_plot('val total loss',
1,
xlabel="iteration",
ylabel="val_total_loss")
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
same_lr_epoch += 1
# per epoch avg loss meter
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
else:
total_loss_meter = mse_loss_meter
# cur_epoch_loss refresh every epoch
ps.new_plot("cur epoch train mse loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="train_mse_loss")
# Init val
if (epoch == start_epoch + 1) and opt.init_val:
print('Init validation ... ')
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
# make plot
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss:{val_mse_loss}'
.format(
epoch=epoch,
lr=lr,
# train_mse_loss = mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
model.train()
def to_patches(x, patch_size):
print(type(x))
_, h, w = x.size()
print('original h,w', h, w)
dw = (patch_size - w % patch_size) if w % patch_size else 0
dh = (patch_size - h % patch_size) if h % patch_size else 0
x = F.pad(x, (dw // 2, dw - dw // 2, dh // 2, dh - dh // 2))
_, h, w = x.size()
print(h, w)
pdb.set_trace()
tv.utils.save_image(x.data, 'test_images/padded_original_img.png')
num_patch_x = w // patch_size
num_patch_y = h // patch_size
print(num_patch_x, num_patch_y)
patches = []
for i in range(num_patch_y):
for j in range(num_patch_x):
patch = x[:, i * patch_size:(i + 1) * patch_size,
j * patch_size:(j + 1) * patch_size]
patches.append(patch.contiguous())
if (j + 1) * patch_size < w:
extra_patch = x[:, i * patch_size:(i + 1) * patch_size,
(j + 1) * patch_size:w]
extra_patch
return patches
# _ is corresponding Label, compression doesn't use it.
for idx, (data, _) in enumerate(train_dataloader):
if idx == 0:
print('skip idx =', idx)
continue
# ipt = Variable(data[0])
ipt = data[0]
# if opt.use_gpu:
# # if not use_data_parallel: # because ipt is also target, so we still need to transfer it to CUDA
# ipt = ipt.cuda(async = True)
# ipt is a full image, so I need to split it into crops
# so set batch_size = 1 for simplicity at first
# pdb.set_trace()
tv.utils.save_image(ipt, "test_imgs/original.png")
patches = to_patches(ipt, opt.patch_size)
for (i, p) in enumerate(patches):
tv.utils.save_image(p, "test_imgs/%s.png" % i)
pdb.set_trace()
optimizer.zero_grad()
# reconstructed, imp_mask_sigmoid = model(ipt)
reconstructed = model(ipt)
# print ('imp_mask_height', model.imp_mask_height)
# pdb.set_trace()
# print ('type recons', type(reconstructed.data))
loss = mse_loss(reconstructed, ipt)
caffe_loss = loss / (2 * opt.batch_size)
if opt.use_imp:
rate_loss_display = imp_mask_sigmoid
rate_loss_ = rate_loss(rate_loss_display)
total_loss = caffe_loss + rate_loss_
else:
total_loss = caffe_loss
# 1.
total_loss.backward()
# caffe_loss.backward()
optimizer.step()
mse_loss_meter.add(caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
ps.add_point(
'cur epoch train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
# print (rate_loss_display.data.mean())
if opt.use_imp:
ps.add_point(
'train rate value',
rate_display_meter.value()[0]
if opt.print_smooth else rate_loss_display.data.mean())
ps.add_point(
'train rate loss',
rate_loss_meter.value()[0]
if opt.print_smooth else rate_loss_.data[0])
ps.add_point(
'train total loss',
total_loss_meter.value()[0]
if opt.print_smooth else total_loss.data[0])
# pdb.set_trace()
# progress_bar.set_description('epoch %d/%d, loss = %.2f' % (epoch, opt.max_epoch, total_loss.data[0]))
# 2.
# ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' % (epoch, opt.max_epoch, idx, len(train_dataloader), total_loss_meter.value()[0], lr))
# ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' % (epoch, opt.max_epoch, idx, len(train_dataloader), mse_loss_meter.value()[0], lr))
# ps.log('loss = %f' % caffe_loss.data[0])
# print(total_loss.data[0])
# input('waiting......')
if not opt.use_imp:
ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' %
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0], lr))
else:
ps.log(
'Epoch %d/%d, Iter %d/%d, loss = %.2f, mse_loss = %.2f, rate_loss = %.2f, rate_display = %.2f, lr = %.8f'
%
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0],
mse_loss_meter.value()[0], rate_loss_meter.value()[0],
rate_display_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
# import pdb
pdb.set_trace()
if use_data_parallel:
# print (type(model.module))
# print (model)
# print (type(model))
model.module.save(optimizer, epoch)
else:
model.save(optimizer, epoch)
# print ('case error', total_loss.data[0])
# print ('smoothed error', total_loss_meter.value()[0])
# plot before val can ease me
ps.make_plot('train mse loss'
) # all epoch share a same img, so give "" to epoch
ps.make_plot('cur epoch train mse loss', epoch)
if opt.use_imp:
ps.make_plot("train rate value")
ps.make_plot("train rate loss")
ps.make_plot("train total loss")
# val
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
# make plot
# ps.make_plot('train mse loss', "") # all epoch share a same img, so give "" to epoch
# ps.make_plot('cur epoch train mse loss',epoch)
ps.make_plot('val mse loss')
if opt.use_imp:
# ps.make_plot("train rate value","")
# ps.make_plot("train rate loss","")
# ps.make_plot("train total loss","")
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss: {train_mse_loss}, train_rate_loss: {train_rate_loss}, train_total_loss: {train_total_loss}, train_rate_display: {train_rate_display} \n\
val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
train_rate_loss=rate_loss_meter.value()[0],
train_total_loss=total_loss_meter.value()[0],
train_rate_display=rate_display_meter.value()[0],
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss:{train_mse_loss}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
# Adaptive adjust lr
# 每个lr,如果有opt.tolerant_max次比上次的val_loss还高,
# update learning rate
# if loss_meter.value()[0] > previous_loss:
if opt.use_early_adjust:
if total_loss_meter.value()[0] > previous_loss:
tolerant_now += 1
if tolerant_now == opt.tolerant_max:
tolerant_now = 0
same_lr_epoch = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Due to early stop anneal lr to', lr, 'at epoch',
epoch)
ps.log('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
else:
tolerant_now -= 1
# if same_lr_epoch and same_lr_epoch % opt.lr_anneal_epochs == 0:
# same_lr_epoch = 0
# tolerant_now = 0
# lr = lr * opt.lr_decay
# for param_group in optimizer.param_groups:
# param_group['lr'] = lr
# print ('Due to full epochs anneal lr to',lr,'at epoch',epoch)
# ps.log ('Due to full epochs anneal lr to %.10f at epoch %d' % (lr, epoch))
if opt.use_file_decay_lr and os.path.exists(opt.lr_decay_file):
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
# previous_loss = total_loss_meter.value()[0] if opt.use_imp else mse_loss_meter.value()[0]
previous_loss = total_loss_meter.value()[0]
def val(model, dataloader, mse_loss, rate_loss, ps, epoch, show_inf_imgs=True):
revert_transforms = transforms.Compose([
transforms.Normalize((-1, -1, -1), (2, 2, 2)),
transforms.Lambda(lambda tensor: t.clamp(tensor, 0.0, 1.0)),
])
if ps:
ps.log('validating ... ')
else:
print('run val ... ')
model.eval()
# avg_loss = 0
# progress_bar = tqdm(enumerate(dataloader), total=len(dataloader), ascii=True)
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
mse_loss_meter.reset()
if opt.use_imp:
rate_loss_meter.reset()
rate_display_meter.reset()
total_loss_meter.reset()
for idx, (data, _) in enumerate(dataloader):
val_input = Variable(data, volatile=True)
if opt.use_gpu:
val_input = val_input.cuda(async=True)
reconstructed = model(val_input)
batch_loss = mse_loss(reconstructed, val_input)
batch_caffe_loss = batch_loss / (2 * opt.batch_size)
if opt.use_imp and rate_loss:
rate_loss_display = imp_mask_sigmoid
rate_loss_value = rate_loss(rate_loss_display)
total_loss = batch_caffe_loss + rate_loss_value
mse_loss_meter.add(batch_caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_value.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
if show_inf_imgs:
if idx > 5:
continue
reconstructed_imgs = revert_transforms(reconstructed.data[0])
# pdb.set_trace()
# print ('save imgs ...')
dir_path = os.path.join(opt.save_inf_imgs_path, 'epoch_%d' % epoch)
if not os.path.exists(dir_path):
# print ('mkdir', dir_path)
os.makedirs(dir_path)
tv.utils.save_image(
reconstructed_imgs,
os.path.join(
dir_path, 'test_p{ps}_epoch{epoch}_idx{idx}.png'.format(
ps=opt.patch_size, epoch=epoch, idx=idx)))
tv.utils.save_image(
revert_transforms(val_input.data[0]),
os.path.join(dir_path, 'origin_{idx}.png'.format(idx=idx)))
if opt.use_imp:
return mse_loss_meter.value()[0], rate_loss_meter.value(
)[0], total_loss_meter.value()[0], rate_display_meter.value()[0]
else:
return mse_loss_meter.value()[0]
def train(**kwargs):
opt.parse(kwargs)
# log file
# tpse: test patch size effect
ps = PlotSaver(opt.exp_id[4:] + "_" + time.strftime("%m_%d__%H:%M:%S") +
".log.txt")
# step1: Model
model = getattr(models, opt.model)(
use_imp=opt.use_imp,
model_name="TPSE_p{ps}_imp_r={r}_gama={w}".format(
ps=opt.patch_size,
r=opt.rate_loss_threshold,
w=opt.rate_loss_weight)
if opt.use_imp else "TPSE_p{ps}_no_imp".format(ps=opt.patch_size))
if opt.use_gpu:
model = multiple_gpu_process(model)
cudnn.benchmark = True
normalize = transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5])
train_data_transforms = transforms.Compose([
transforms.RandomCrop(opt.patch_size),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(), normalize
])
val_data_transforms = transforms.Compose(
[transforms.CenterCrop(256),
transforms.ToTensor(), normalize])
train_data = datasets.ImageFolder(opt.train_data_root,
train_data_transforms)
val_data = datasets.ImageFolder(opt.val_data_root, val_data_transforms)
train_dataloader = DataLoader(train_data,
opt.batch_size,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
val_dataloader = DataLoader(val_data,
opt.batch_size,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# step3: criterion and optimizer
mse_loss = t.nn.MSELoss(size_average=False)
if opt.use_imp:
rate_loss = LimuRateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
lr = opt.lr
optimizer = t.optim.Adam(model.parameters(), lr=lr, betas=(0.9, 0.999))
start_epoch = 0
if opt.resume:
if use_data_parallel:
start_epoch = model.module.load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
else:
start_epoch = model.load(None if opt.finetune else optimizer,
opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training at epoch %d.' % start_epoch)
# step4: meters
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
previous_loss = 1e100
tolerant_now = 0
same_lr_epoch = 0
# ps init
ps.new_plot('train mse loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_mse_loss")
ps.new_plot('val mse loss', 1, xlabel="epoch", ylabel="val_mse_loss")
if opt.use_imp:
ps.new_plot('train rate value',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_value")
ps.new_plot('train rate loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_loss")
ps.new_plot('train total loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_total_loss")
ps.new_plot('val rate value',
1,
xlabel="epoch",
ylabel="val_rate_value")
ps.new_plot('val rate loss', 1, xlabel="epoch", ylabel="val_rate_loss")
ps.new_plot('val total loss',
1,
xlabel="epoch",
ylabel="val_total_loss")
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
same_lr_epoch += 1
# per epoch avg loss meter
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
else:
total_loss_meter = mse_loss_meter
ps.new_plot("cur epoch train mse loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="train_mse_loss")
# Init val
if (epoch == start_epoch + 1) and opt.init_val:
print('Init validation ... ')
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps, -1, True)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps,
-1, True)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
# make plot
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch, lr=lr, val_mse_loss=mse_val_loss))
# 开始训练
model.train()
# _ is corresponding Label, compression doesn't use it.
for idx, (data, _) in enumerate(train_dataloader):
ipt = Variable(data)
if opt.use_gpu:
ipt = ipt.cuda(async=True)
optimizer.zero_grad()
reconstructed = model(ipt)
loss = mse_loss(reconstructed, ipt)
caffe_loss = loss / (2 * opt.batch_size)
# 相对于8x8的SIZE
caffe_loss = caffe_loss / (
(opt.patch_size // 8)**2
) # 8 16 32 ... (size = 4 * size') * / 8 = 1 2 4 ... log2(*/8) = 0, 1, 2 ... 4^(log2(*/8)) = (*/8)^2
if opt.use_imp:
rate_loss_display = imp_mask_sigmoid
rate_loss_ = rate_loss(rate_loss_display)
total_loss = caffe_loss + rate_loss_
else:
total_loss = caffe_loss
total_loss.backward()
optimizer.step()
mse_loss_meter.add(caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
ps.add_point(
'cur epoch train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
# print (rate_loss_display.data.mean())
if opt.use_imp:
ps.add_point(
'train rate value',
rate_display_meter.value()[0]
if opt.print_smooth else rate_loss_display.data.mean())
ps.add_point(
'train rate loss',
rate_loss_meter.value()[0]
if opt.print_smooth else rate_loss_.data[0])
ps.add_point(
'train total loss',
total_loss_meter.value()[0]
if opt.print_smooth else total_loss.data[0])
if not opt.use_imp:
ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' %
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0], lr))
else:
ps.log(
'Epoch %d/%d, Iter %d/%d, loss = %.2f, mse_loss = %.2f, rate_loss = %.2f, rate_display = %.2f, lr = %.8f'
%
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0],
mse_loss_meter.value()[0], rate_loss_meter.value()[0],
rate_display_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
# import pdb
pdb.set_trace()
if use_data_parallel:
model.module.save(optimizer, epoch)
else:
model.save(optimizer, epoch)
# plot before val can ease me
ps.make_plot('train mse loss'
) # all epoch share a same img, so give "" to epoch
ps.make_plot('cur epoch train mse loss', epoch)
if opt.use_imp:
ps.make_plot("train rate value")
ps.make_plot("train rate loss")
ps.make_plot("train total loss")
# val
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps, epoch,
epoch % opt.show_inf_imgs_T == 0)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps,
epoch, epoch % opt.show_inf_imgs_T == 0)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss: {train_mse_loss}, train_rate_loss: {train_rate_loss}, train_total_loss: {train_total_loss}, train_rate_display: {train_rate_display} \n\
val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
train_rate_loss=rate_loss_meter.value()[0],
train_total_loss=total_loss_meter.value()[0],
train_rate_display=rate_display_meter.value()[0],
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss:{train_mse_loss}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
# Adaptive adjust lr
# 每个lr,如果有opt.tolerant_max次比上次的val_loss还高,
# update learning rate
# if loss_meter.value()[0] > previous_loss:
if opt.use_early_adjust:
if total_loss_meter.value()[0] > previous_loss:
tolerant_now += 1
if tolerant_now == opt.tolerant_max:
tolerant_now = 0
same_lr_epoch = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Due to early stop anneal lr to', lr, 'at epoch',
epoch)
ps.log('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
else:
tolerant_now -= 1
if same_lr_epoch and same_lr_epoch % opt.lr_anneal_epochs == 0:
same_lr_epoch = 0
tolerant_now = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Due to full epochs anneal lr to', lr, 'at epoch', epoch)
ps.log('Due to full epochs anneal lr to %.10f at epoch %d' %
(lr, epoch))
if opt.use_file_decay_lr and os.path.exists(opt.lr_decay_file):
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
previous_loss = total_loss_meter.value()[0]
def train(**kwargs):
opt.parse(kwargs)
# vis = Visualizer(opt.env)
# log file
ps = PlotSaver("Train_ImageNet12_With_ImpMap_" +
time.strftime("%m_%d_%H:%M:%S") + ".log.txt")
# step1: Model
model = getattr(models, opt.model)(
use_imp=opt.use_imp,
model_name="CWCNN_limu_ImageNet_imp_r={r}_γ={w}".format(
r=opt.rate_loss_threshold, w=opt.rate_loss_weight)
if opt.use_imp else None)
# if opt.use_imp else "test_pytorch")
if opt.use_gpu:
# model = multiple_gpu_process(model)
model.cuda()
# pdb.set_trace()
cudnn.benchmark = True
# step2: Data
normalize = transforms.Normalize(mean=[0.485, 0.456, 0.406],
std=[0.229, 0.224, 0.225])
train_data_transforms = transforms.Compose([
transforms.Resize(256),
#transforms.Scale(256),
transforms.RandomCrop(224),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
normalize
])
val_data_transforms = transforms.Compose([
transforms.Resize(256),
#transforms.Scale(256),
transforms.CenterCrop(224),
# transforms.TenCrop(224),
# transforms.Lambda(lambda crops: t.stack(([normalize(transforms.ToTensor()(crop)) for crop in crops]))),
transforms.ToTensor(),
normalize
])
# train_data = ImageNet_200k(opt.train_data_root, train=True, transforms=data_transforms)
# val_data = ImageNet_200k(opt.val_data_root, train = False, transforms=data_transforms)
train_data = datasets.ImageFolder(opt.train_data_root,
train_data_transforms)
val_data = datasets.ImageFolder(opt.val_data_root, val_data_transforms)
train_dataloader = DataLoader(train_data,
opt.batch_size,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
val_dataloader = DataLoader(val_data,
opt.batch_size,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# step3: criterion and optimizer
mse_loss = t.nn.MSELoss(size_average=False)
if opt.use_imp:
# rate_loss = RateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
rate_loss = LimuRateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
lr = opt.lr
optimizer = t.optim.Adam(model.parameters(), lr=lr, betas=(0.9, 0.999))
start_epoch = 0
if opt.resume:
if hasattr(model, 'module'):
start_epoch = model.module.load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
else:
start_epoch = model.load(None if opt.finetune else optimizer,
opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training at epoch %d.' % start_epoch)
# step4: meters
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
previous_loss = 1e100
tolerant_now = 0
same_lr_epoch = 0
# ps init
ps.new_plot('train mse loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_mse_loss")
ps.new_plot('val mse loss', 1, xlabel="epoch", ylabel="val_mse_loss")
if opt.use_imp:
ps.new_plot('train rate value',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_value")
ps.new_plot('train rate loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_loss")
ps.new_plot('train total loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_total_loss")
ps.new_plot('val rate value',
1,
xlabel="iteration",
ylabel="val_rate_value")
ps.new_plot('val rate loss',
1,
xlabel="iteration",
ylabel="val_rate_loss")
ps.new_plot('val total loss',
1,
xlabel="iteration",
ylabel="val_total_loss")
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
same_lr_epoch += 1
# per epoch avg loss meter
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
else:
total_loss_meter = mse_loss_meter
# cur_epoch_loss refresh every epoch
ps.new_plot("cur epoch train mse loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="train_mse_loss")
model.train()
# _ is corresponding Label, compression doesn't use it.
for idx, (data, _) in enumerate(train_dataloader):
ipt = Variable(data)
if opt.use_gpu:
ipt = ipt.cuda()
optimizer.zero_grad() # f**k it! Don't forget to clear grad!
reconstructed = model(ipt)
# print ('reconstructed tensor size :', reconstructed.size())
loss = mse_loss(reconstructed, ipt)
caffe_loss = loss / (2 * opt.batch_size)
if opt.use_imp:
# print ('use data_parallel?',use_data_parallel)
# pdb.set_trace()
rate_loss_display = (model.module if use_data_parallel else
model).imp_mask_sigmoid
rate_loss_ = rate_loss(rate_loss_display)
total_loss = caffe_loss + rate_loss_
else:
total_loss = caffe_loss
total_loss.backward()
optimizer.step()
mse_loss_meter.add(caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
ps.add_point(
'cur epoch train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
if opt.use_imp:
ps.add_point(
'train rate value',
rate_display_meter.value()[0]
if opt.print_smooth else rate_loss_display.data.mean())
ps.add_point(
'train rate loss',
rate_loss_meter.value()[0]
if opt.print_smooth else rate_loss_.data[0])
ps.add_point(
'train total loss',
total_loss_meter.value()[0]
if opt.print_smooth else total_loss.data[0])
if not opt.use_imp:
ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' %
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0], lr))
else:
ps.log(
'Epoch %d/%d, Iter %d/%d, loss = %.2f, mse_loss = %.2f, rate_loss = %.2f, rate_display = %.2f, lr = %.8f'
%
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0],
mse_loss_meter.value()[0], rate_loss_meter.value()[0],
rate_display_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
pdb.set_trace()
# data parallel
# if hasattr(model, 'module'):
if use_data_parallel:
model.module.save(optimizer, epoch)
else:
model.save(optimizer, epoch)
# plot before val can ease me
ps.make_plot(
'train mse loss'
) # all epoch share a same img, so give ""(default) to epoch
ps.make_plot('cur epoch train mse loss', epoch)
if opt.use_imp:
ps.make_plot("train rate value")
ps.make_plot("train rate loss")
ps.make_plot("train total loss")
# val
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss: {train_mse_loss}, train_rate_loss: {train_rate_loss}, train_total_loss: {train_total_loss}, train_rate_display: {train_rate_display} \n\
val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
train_rate_loss=rate_loss_meter.value()[0],
train_total_loss=total_loss_meter.value()[0],
train_rate_display=rate_display_meter.value()[0],
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss:{train_mse_loss}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
# Adaptive adjust lr
# 每个lr,如果有opt.tolerant_max次比上次的val_loss还高,
if opt.use_early_adjust:
if total_loss_meter.value()[0] > previous_loss:
tolerant_now += 1
if tolerant_now == opt.tolerant_max:
tolerant_now = 0
same_lr_epoch = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Anneal lr to', lr, 'at epoch', epoch,
'due to early stop.')
ps.log(
'Anneal lr to %.10f at epoch %d due to early stop.' %
(lr, epoch))
else:
tolerant_now -= 1
if same_lr_epoch and same_lr_epoch % opt.lr_anneal_epochs == 0:
same_lr_epoch = 0
tolerant_now = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Anneal lr to', lr, 'at epoch', epoch, 'due to full epochs.')
ps.log('Anneal lr to %.10f at epoch %d due to full epochs.' %
(lr, epoch))
previous_loss = total_loss_meter.value()[0]
def train(**kwargs):
opt.parse(kwargs)
# log file
logfile_name = "Cmpr_with_YOLOv2_" + opt.exp_desc + time.strftime(
"_%m_%d_%H:%M:%S") + ".log.txt"
ps = PlotSaver(logfile_name)
# step1: Model
model = getattr(models, opt.model)(
use_imp=opt.use_imp,
n=opt.feat_num,
input_4_ch=opt.input_4_ch,
model_name="Cmpr_yolo_imp_" + opt.exp_desc + "_r={r}_gama={w}".format(
r=opt.rate_loss_threshold, w=opt.rate_loss_weight)
if opt.use_imp else "Cmpr_yolo_no_imp_" + opt.exp_desc)
# pdb.set_trace()
if opt.use_gpu:
model = multiple_gpu_process(model)
cudnn.benchmark = True
# step2: Data
normalize = transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5])
train_data_transforms = transforms.Compose([
# transforms.RandomHorizontalFlip(), TODO: try to reimplement by myself to simultaneous operate on label and data
transforms.ToTensor(),
normalize
])
val_data_transforms = transforms.Compose(
[transforms.ToTensor(), normalize])
train_data = ImageCropWithBBoxMaskDataset(
opt.train_data_list,
train_data_transforms,
contrastive_degree=opt.contrastive_degree,
mse_bbox_weight=opt.input_original_bbox_weight)
val_data = ImageCropWithBBoxMaskDataset(
opt.val_data_list,
val_data_transforms,
contrastive_degree=opt.contrastive_degree,
mse_bbox_weight=opt.input_original_bbox_weight)
train_dataloader = DataLoader(train_data,
opt.batch_size,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
val_dataloader = DataLoader(val_data,
opt.batch_size,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# step3: criterion and optimizer
mse_loss = t.nn.MSELoss(size_average=False)
if opt.use_imp:
# TODO: new rate loss
rate_loss = RateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
# rate_loss = LimuRateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
def weighted_mse_loss(input, target, weight):
# weight[weight!=opt.mse_bbox_weight] = 1
# weight[weight==opt.mse_bbox_weight] = opt.mse_bbox_weight
# print('max val', weight.max())
# return mse_loss(input, target)
# weight_clone = weight.clone()
# weight_clone[weight_clone == opt.input_original_bbox_weight] = 0
# return t.sum(weight_clone * (input - target) ** 2)
weight_clone = t.ones_like(weight)
weight_clone[weight ==
opt.input_original_bbox_inner] = opt.mse_bbox_weight
return t.sum(weight_clone * (input - target)**2)
def yolo_rate_loss(imp_map, mask_r):
return rate_loss(imp_map)
# V2 contrastive_degree must be 0!
# return YoloRateLossV2(mask_r, opt.rate_loss_threshold, opt.rate_loss_weight)(imp_map)
lr = opt.lr
optimizer = t.optim.Adam(model.parameters(), lr=lr, betas=(0.9, 0.999))
start_epoch = 0
decay_file_create_time = -1 # 为了避免同一个文件反复衰减学习率, 所以判断修改时间
if opt.resume:
if use_data_parallel:
start_epoch = model.module.load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
else:
start_epoch = model.load(None if opt.finetune else optimizer,
opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training at epoch %d.' % start_epoch)
# step4: meters
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
previous_loss = 1e100
tolerant_now = 0
same_lr_epoch = 0
# ps init
ps.new_plot('train mse loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_mse_loss")
ps.new_plot('val mse loss', 1, xlabel="epoch", ylabel="val_mse_loss")
if opt.use_imp:
ps.new_plot('train rate value',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_value")
ps.new_plot('train rate loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_loss")
ps.new_plot('train total loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_total_loss")
ps.new_plot('val rate value',
1,
xlabel="iteration",
ylabel="val_rate_value")
ps.new_plot('val rate loss',
1,
xlabel="iteration",
ylabel="val_rate_loss")
ps.new_plot('val total loss',
1,
xlabel="iteration",
ylabel="val_total_loss")
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
same_lr_epoch += 1
# per epoch avg loss meter
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
else:
total_loss_meter = mse_loss_meter
# cur_epoch_loss refresh every epoch
# vis.refresh_plot('cur epoch train mse loss')
ps.new_plot("cur epoch train mse loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="train_mse_loss")
# progress_bar = tqdm(enumerate(train_dataloader), total=len(train_dataloader), ascii=True)
# progress_bar.set_description('epoch %d/%d, loss = 0.00' % (epoch, opt.max_epoch))
# Init val
if (epoch == start_epoch + 1) and opt.init_val:
print('Init validation ... ')
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, weighted_mse_loss, yolo_rate_loss,
ps)
else:
mse_val_loss = val(model, val_dataloader, weighted_mse_loss,
None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch, lr=lr, val_mse_loss=mse_val_loss))
if opt.only_init_val:
print('Only Init Val Over!')
return
model.train()
if epoch == start_epoch + 1:
print('Start training, please inspect log file %s!' % logfile_name)
# mask is the detection bounding box mask
for idx, (data, mask, o_mask) in enumerate(train_dataloader):
# pdb.set_trace()
data = Variable(data)
mask = Variable(mask)
o_mask = Variable(o_mask, requires_grad=False)
if opt.use_gpu:
data = data.cuda(async=True)
mask = mask.cuda(async=True)
o_mask = o_mask.cuda(async=True)
# pdb.set_trace()
optimizer.zero_grad()
reconstructed, imp_mask_sigmoid = model(data, mask, o_mask)
# print ('imp_mask_height', model.imp_mask_height)
# pdb.set_trace()
# print ('type recons', type(reconstructed.data))
loss = weighted_mse_loss(reconstructed, data, o_mask)
# loss = mse_loss(reconstructed, data)
caffe_loss = loss / (2 * opt.batch_size)
if opt.use_imp:
rate_loss_display = imp_mask_sigmoid
# rate_loss_ = rate_loss(rate_loss_display)
rate_loss_ = yolo_rate_loss(rate_loss_display, mask)
total_loss = caffe_loss + rate_loss_
else:
total_loss = caffe_loss
total_loss.backward()
optimizer.step()
mse_loss_meter.add(caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
ps.add_point(
'cur epoch train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
if opt.use_imp:
ps.add_point(
'train rate value',
rate_display_meter.value()[0]
if opt.print_smooth else rate_loss_display.data.mean())
ps.add_point(
'train rate loss',
rate_loss_meter.value()[0]
if opt.print_smooth else rate_loss_.data[0])
ps.add_point(
'train total loss',
total_loss_meter.value()[0]
if opt.print_smooth else total_loss.data[0])
if not opt.use_imp:
ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' %
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0], lr))
else:
ps.log(
'Epoch %d/%d, Iter %d/%d, loss = %.2f, mse_loss = %.2f, rate_loss = %.2f, rate_display = %.2f, lr = %.8f'
%
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0],
mse_loss_meter.value()[0], rate_loss_meter.value()[0],
rate_display_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
pdb.set_trace()
if epoch % opt.save_interval == 0:
print('save checkpoint file of epoch %d.' % epoch)
if use_data_parallel:
model.module.save(optimizer, epoch)
else:
model.save(optimizer, epoch)
ps.make_plot('train mse loss')
ps.make_plot('cur epoch train mse loss', epoch)
if opt.use_imp:
ps.make_plot("train rate value")
ps.make_plot("train rate loss")
ps.make_plot("train total loss")
if epoch % opt.eval_interval == 0:
print('Validating ...')
# val
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, weighted_mse_loss, yolo_rate_loss,
ps)
else:
mse_val_loss = val(model, val_dataloader, weighted_mse_loss,
None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss: {train_mse_loss}, train_rate_loss: {train_rate_loss}, train_total_loss: {train_total_loss}, train_rate_display: {train_rate_display} \n\
val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
train_rate_loss=rate_loss_meter.value()[0],
train_total_loss=total_loss_meter.value()[0],
train_rate_display=rate_display_meter.value()[0],
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss:{train_mse_loss}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
# Adaptive adjust lr
# 每个lr,如果有opt.tolerant_max次比上次的val_loss还高,
# update learning rate
# if loss_meter.value()[0] > previous_loss:
if opt.use_early_adjust:
if total_loss_meter.value()[0] > previous_loss:
tolerant_now += 1
if tolerant_now == opt.tolerant_max:
tolerant_now = 0
same_lr_epoch = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
ps.log('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
else:
tolerant_now -= 1
if epoch % opt.lr_anneal_epochs == 0:
# if same_lr_epoch and same_lr_epoch % opt.lr_anneal_epochs == 0:
same_lr_epoch = 0
tolerant_now = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Anneal lr to %.10f at epoch %d due to full epochs.' %
(lr, epoch))
ps.log('Anneal lr to %.10f at epoch %d due to full epochs.' %
(lr, epoch))
if opt.use_file_decay_lr and os.path.exists(opt.lr_decay_file):
cur_mtime = os.path.getmtime(opt.lr_decay_file)
if cur_mtime > decay_file_create_time:
decay_file_create_time = cur_mtime
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print(
'Anneal lr to %.10f at epoch %d due to decay-file indicator.'
% (lr, epoch))
ps.log(
'Anneal lr to %.10f at epoch %d due to decay-file indicator.'
% (lr, epoch))
previous_loss = total_loss_meter.value()[0]
def test(model, dataloader, test_batch_size, mse_loss, rate_loss):
model.eval()
progress_bar = tqdm(enumerate(dataloader), total=len(dataloader))
if opt.save_test_img:
if not os.path.exists(opt.test_imgs_save_path):
os.makedirs(opt.test_imgs_save_path)
print('Makedir %s for save test images!' % opt.test_imgs_save_path)
eval_loss = True # mse_loss, rate_loss, rate_disp
eval_on_RGB = True # RGB_mse, RGB_psnr
revert_transforms = transforms.Compose([
transforms.Normalize((-1, -1, -1), (2, 2, 2)),
# transforms.Normalize([-0.485/0.229, -0.456/0.224, -0.406/0.225], [1/0.229, 1/0.224, 1/0.225]),
transforms.Lambda(lambda tensor: t.clamp(tensor, 0.0, 1.0)),
transforms.ToPILImage()
])
mse = lambda x, y: np.mean(np.square(y - x))
psnr = lambda x, y: 10 * math.log10(255.**2 / mse(x, y))
mse_meter = AverageValueMeter()
psnr_meter = AverageValueMeter()
rate_disp_meter = AverageValueMeter()
caffe_loss_meter = AverageValueMeter()
rate_loss_meter = AverageValueMeter()
if opt.use_imp:
total_loss_meter = AverageValueMeter()
else:
total_loss_meter = caffe_loss_meter
for idx, data in progress_bar:
test_data = Variable(data, volatile=True)
# test_mask = Variable(mask, volatile=True)
# pdb.set_trace()
# mask[mask==1] = 0
# mask[mask==opt.contrastive_degree] = 1
# print ('type.mask', type(mask))
# o_mask_as_weight = o_mask.clone()
# pdb.set_trace()
# bbox_inner = (o_mask == opt.mse_bbox_weight)
# bbox_outer = (o_mask == 1)
# o_mask[bbox_inner] = 1
# o_mask[bbox_outer] = opt.mse_bbox_weight
# print (o_mask)
# pdb.set_trace()
# o_mask[...] = 1
# test_o_mask = Variable(o_mask, volatile=True)
# test_o_mask_as_weight = Variable(o_mask_as_weight, volatile=True)
# pdb.set_trace()
if opt.use_gpu:
test_data = test_data.cuda(async=True)
# test_mask = test_mask.cuda(async=True)
# test_o_mask = test_o_mask.cuda(async=True)
# test_o_mask_as_weight = test_o_mask_as_weight.cuda(async=True)
# o_mask = o_mask.cuda(async=True)
# pdb.set_trace()
if opt.use_imp:
reconstructed, imp_mask_sigmoid = model(test_data)
else:
reconstructed = model(test_data)
# only save the 1th image of batch
img_origin = revert_transforms(test_data.data.cpu()[0])
img_reconstructed = revert_transforms(reconstructed.data.cpu()[0])
if opt.save_test_img:
if opt.use_imp:
imp_map = transforms.ToPILImage()(
imp_mask_sigmoid.data.cpu()[0])
imp_map = imp_map.resize(
(imp_map.size[0] * 8, imp_map.size[1] * 8))
imp_map.save(
os.path.join(opt.test_imgs_save_path, "%d_imp.png" % idx))
img_origin.save(
os.path.join(opt.test_imgs_save_path, "%d_origin.png" % idx))
img_reconstructed.save(
os.path.join(opt.test_imgs_save_path, "%d_reconst.png" % idx))
if eval_loss:
mse_loss_v = mse_loss(reconstructed, test_data)
caffe_loss_v = mse_loss_v / (2 * test_batch_size)
caffe_loss_meter.add(caffe_loss_v.data[0])
if opt.use_imp:
rate_disp_meter.add(imp_mask_sigmoid.data.mean())
assert rate_loss is not None
rate_loss_v = rate_loss(imp_mask_sigmoid)
rate_loss_meter.add(rate_loss_v.data[0])
total_loss_v = caffe_loss_v + rate_loss_v
total_loss_meter.add(total_loss_v.data[0])
if eval_on_RGB:
origin_arr = np.array(img_origin)
reconst_arr = np.array(img_reconstructed)
RGB_mse_v = mse(origin_arr, reconst_arr)
RGB_psnr_v = psnr(origin_arr, reconst_arr)
mse_meter.add(RGB_mse_v)
psnr_meter.add(RGB_psnr_v)
if eval_loss:
print(
'avg_mse_loss = {m_l}, avg_rate_loss = {r_l}, avg_rate_disp = {r_d}, avg_tot_loss = {t_l}'
.format(m_l=caffe_loss_meter.value()[0],
r_l=rate_loss_meter.value()[0],
r_d=rate_disp_meter.value()[0],
t_l=total_loss_meter.value()[0]))
if eval_on_RGB:
print('RGB avg mse = {mse}, RGB avg psnr = {psnr}'.format(
mse=mse_meter.value()[0], psnr=psnr_meter.value()[0]))
def train(**kwargs):
opt.parse(kwargs)
# vis = Visualizer(opt.env)
# log file
ps = PlotSaver("CLIC_finetune_With_TestSet_0.13_" +
time.strftime("%m_%d_%H:%M:%S") + ".log.txt")
# step1: Model
# CWCNN_limu_ImageNet_imp_
model = getattr(models, opt.model)(
use_imp=opt.use_imp,
model_name="CLIC_imp_ft_testSet_2_r={r}_gama={w}".format(
r=opt.rate_loss_threshold, w=opt.rate_loss_weight)
if opt.use_imp else None)
# if opt.use_imp else "test_pytorch")
if opt.use_gpu:
model = multiple_gpu_process(model)
# model.cuda() # because I want model.imp_mask_sigmoid
# freeze the decoder network, and finetune the enc + imp with train + val set
if opt.freeze_decoder:
for param in model.module.decoder.parameters():
# print (param.requires_grad)
param.requires_grad = False
cudnn.benchmark = True
# step2: Data
# normalize = transforms.Normalize(
# mean=[0.485, 0.456, 0.406],
# std=[0.229, 0.224, 0.225]
# )
normalize = transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5])
# train_data_transforms = transforms.Compose(
# [
# transforms.Resize(256),
# # transforms.RandomCrop(128),
# # transforms.Resize((128,128)),
# # transforms.RandomHorizontalFlip(),
# transforms.ToTensor(),
# # transforms.Normalize((0.5,0.5,0.5),(0.5,0.5,0.5))
# normalize
# ]
# )
# val_data_transforms = transforms.Compose(
# [
# # transforms.Resize(256),
# # transforms.CenterCrop(128),
# # transforms.Resize((128,128)),
# # transforms.TenCrop(224),
# # transforms.Lambda(lambda crops: t.stack(([normalize(transforms.ToTensor()(crop)) for crop in crops]))),
# transforms.ToTensor(),
# normalize
# ]
# )
train_data_transforms = transforms.Compose([
transforms.Resize(256),
#transforms.Scale(256),
transforms.RandomCrop(224),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
normalize
])
val_data_transforms = transforms.Compose([
transforms.Resize(256),
#transforms.Scale(256),
transforms.CenterCrop(224),
# transforms.TenCrop(224),
# transforms.Lambda(lambda crops: t.stack(([normalize(transforms.ToTensor()(crop)) for crop in crops]))),
transforms.ToTensor(),
normalize
])
# train_data = ImageNet_200k(opt.train_data_root, train=True, transforms=data_transforms)
# val_data = ImageNet_200k(opt.val_data_root, train = False, transforms=data_transforms)
train_data = datasets.ImageFolder(opt.train_data_root,
train_data_transforms)
val_data = datasets.ImageFolder(opt.val_data_root, val_data_transforms)
train_dataloader = DataLoader(train_data,
opt.batch_size,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
# train_dataloader = DataLoader(train_data, opt.batch_size, shuffle=True, num_workers=opt.num_workers)
val_dataloader = DataLoader(val_data,
opt.batch_size,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# val_dataloader = DataLoader(val_data, opt.batch_size, shuffle=False, num_workers=opt.num_workers)
# step3: criterion and optimizer
mse_loss = t.nn.MSELoss(size_average=False)
if opt.use_imp:
# rate_loss = RateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
rate_loss = LimuRateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
lr = opt.lr
# print ('model.parameters():')
# print (model.parameters())
# optimizer = t.optim.Adam(model.parameters(), lr=lr, betas=(0.9, 0.999))
optimizer = t.optim.Adam(filter(lambda p: p.requires_grad,
model.parameters()),
lr=lr,
betas=(0.9, 0.999))
start_epoch = 0
if opt.resume:
if use_data_parallel:
start_epoch = model.module.load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
else:
start_epoch = model.load(None if opt.finetune else optimizer,
opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training at epoch %d.' % start_epoch)
# step4: meters
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
previous_loss = 1e100
tolerant_now = 0
same_lr_epoch = 0
# ps init
ps.new_plot('train mse loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_mse_loss")
ps.new_plot('val mse loss', 1, xlabel="epoch", ylabel="val_mse_loss")
if opt.use_imp:
ps.new_plot('train rate value',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_value")
ps.new_plot('train rate loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_loss")
ps.new_plot('train total loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_total_loss")
ps.new_plot('val rate value',
1,
xlabel="iteration",
ylabel="val_rate_value")
ps.new_plot('val rate loss',
1,
xlabel="iteration",
ylabel="val_rate_loss")
ps.new_plot('val total loss',
1,
xlabel="iteration",
ylabel="val_total_loss")
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
same_lr_epoch += 1
# per epoch avg loss meter
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
else:
total_loss_meter = mse_loss_meter
# cur_epoch_loss refresh every epoch
# vis.refresh_plot('cur epoch train mse loss')
ps.new_plot("cur epoch train mse loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="train_mse_loss")
# progress_bar = tqdm(enumerate(train_dataloader), total=len(train_dataloader), ascii=True)
# progress_bar.set_description('epoch %d/%d, loss = 0.00' % (epoch, opt.max_epoch))
# Init val
if (epoch == start_epoch + 1) and opt.init_val:
print('Init validation ... ')
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
# make plot
# ps.make_plot('train mse loss', "") # all epoch share a same img, so give "" to epoch
# ps.make_plot('cur epoch train mse loss',epoch)
ps.make_plot('val mse loss')
if opt.use_imp:
# ps.make_plot("train rate value","")
# ps.make_plot("train rate loss","")
# ps.make_plot("train total loss","")
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss:{val_mse_loss}'
.format(
epoch=epoch,
lr=lr,
# train_mse_loss = mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
model.train()
# mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
# _ is corresponding Label, compression doesn't use it.
for idx, (data, _) in enumerate(train_dataloader):
ipt = Variable(data)
if opt.use_gpu:
# if not use_data_parallel: # because ipt is also target, so we still need to transfer it to CUDA
ipt = ipt.cuda(async=True)
optimizer.zero_grad()
reconstructed, imp_mask_sigmoid = model(ipt)
# print ('imp_mask_height', model.imp_mask_height)
# pdb.set_trace()
# print ('type recons', type(reconstructed.data))
loss = mse_loss(reconstructed, ipt)
caffe_loss = loss / (2 * opt.batch_size)
if opt.use_imp:
# rate_loss_display = model.imp_mask_sigmoid
# rate_loss_display = (model.module if use_data_parallel else model).imp_mask_sigmoid
rate_loss_display = imp_mask_sigmoid
# rate_loss_display = model.imp_mask
# print ('type of display', type(rate_loss_display.data))
rate_loss_ = rate_loss(rate_loss_display)
# print (
# 'type of rate_loss_value',
# type(rate_loss_value.data)
# )
total_loss = caffe_loss + rate_loss_
else:
total_loss = caffe_loss
# 1.
total_loss.backward()
# caffe_loss.backward()
optimizer.step()
mse_loss_meter.add(caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_.data[0])
rate_display_meter.add(rate_loss_display.data.mean())
total_loss_meter.add(total_loss.data[0])
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
ps.add_point(
'cur epoch train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
# print (rate_loss_display.data.mean())
if opt.use_imp:
ps.add_point(
'train rate value',
rate_display_meter.value()[0]
if opt.print_smooth else rate_loss_display.data.mean())
ps.add_point(
'train rate loss',
rate_loss_meter.value()[0]
if opt.print_smooth else rate_loss_.data[0])
ps.add_point(
'train total loss',
total_loss_meter.value()[0]
if opt.print_smooth else total_loss.data[0])
# pdb.set_trace()
# progress_bar.set_description('epoch %d/%d, loss = %.2f' % (epoch, opt.max_epoch, total_loss.data[0]))
# 2.
# ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' % (epoch, opt.max_epoch, idx, len(train_dataloader), total_loss_meter.value()[0], lr))
# ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' % (epoch, opt.max_epoch, idx, len(train_dataloader), mse_loss_meter.value()[0], lr))
# ps.log('loss = %f' % caffe_loss.data[0])
# print(total_loss.data[0])
# input('waiting......')
if not opt.use_imp:
ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' %
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0], lr))
else:
ps.log(
'Epoch %d/%d, Iter %d/%d, loss = %.2f, mse_loss = %.2f, rate_loss = %.2f, rate_display = %.2f, lr = %.8f'
%
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0],
mse_loss_meter.value()[0], rate_loss_meter.value()[0],
rate_display_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
# import pdb
pdb.set_trace()
if use_data_parallel:
# print (type(model.module))
# print (model)
# print (type(model))
model.module.save(optimizer, epoch)
else:
model.save(optimizer, epoch)
# print ('case error', total_loss.data[0])
# print ('smoothed error', total_loss_meter.value()[0])
# plot before val can ease me
ps.make_plot('train mse loss'
) # all epoch share a same img, so give "" to epoch
ps.make_plot('cur epoch train mse loss', epoch)
if opt.use_imp:
ps.make_plot("train rate value")
ps.make_plot("train rate loss")
ps.make_plot("train total loss")
# val
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
# make plot
# ps.make_plot('train mse loss', "") # all epoch share a same img, so give "" to epoch
# ps.make_plot('cur epoch train mse loss',epoch)
ps.make_plot('val mse loss')
if opt.use_imp:
# ps.make_plot("train rate value","")
# ps.make_plot("train rate loss","")
# ps.make_plot("train total loss","")
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss: {train_mse_loss}, train_rate_loss: {train_rate_loss}, train_total_loss: {train_total_loss}, train_rate_display: {train_rate_display} \n\
val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
train_rate_loss=rate_loss_meter.value()[0],
train_total_loss=total_loss_meter.value()[0],
train_rate_display=rate_display_meter.value()[0],
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss:{train_mse_loss}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
# Adaptive adjust lr
# 每个lr,如果有opt.tolerant_max次比上次的val_loss还高,
# update learning rate
# if loss_meter.value()[0] > previous_loss:
if opt.use_early_adjust:
if total_loss_meter.value()[0] > previous_loss:
tolerant_now += 1
if tolerant_now == opt.tolerant_max:
tolerant_now = 0
same_lr_epoch = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Due to early stop anneal lr to', lr, 'at epoch',
epoch)
ps.log('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
else:
tolerant_now -= 1
# if same_lr_epoch and same_lr_epoch % opt.lr_anneal_epochs == 0:
# same_lr_epoch = 0
# tolerant_now = 0
# lr = lr * opt.lr_decay
# for param_group in optimizer.param_groups:
# param_group['lr'] = lr
# print ('Due to full epochs anneal lr to',lr,'at epoch',epoch)
# ps.log ('Due to full epochs anneal lr to %.10f at epoch %d' % (lr, epoch))
if opt.use_file_decay_lr and os.path.exists(opt.lr_decay_file):
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
# previous_loss = total_loss_meter.value()[0] if opt.use_imp else mse_loss_meter.value()[0]
previous_loss = total_loss_meter.value()[0]
def train(**kwargs):
global batch_model_id
opt.parse(kwargs)
if opt.use_batch_process:
max_bp_times = len(opt.exp_ids)
if batch_model_id >= max_bp_times:
print('Batch Processing Done!')
return
else:
print('Cur Batch Processing ID is %d/%d.' %
(batch_model_id + 1, max_bp_times))
opt.r = opt.r_s[batch_model_id]
opt.exp_id = opt.exp_ids[batch_model_id]
opt.exp_desc = opt.exp_desc_LUT[opt.exp_id]
opt.plot_path = "plot/plot_%d" % opt.exp_id
print('Cur Model(exp_%d) r = %f, desc = %s. ' %
(opt.exp_id, opt.r, opt.exp_desc))
opt.make_new_dirs()
# log file
EvalVal = opt.only_init_val and opt.init_val and not opt.test_test
EvalTest = opt.only_init_val and opt.init_val and opt.test_test
EvalSuffix = ""
if EvalVal:
EvalSuffix = "_val"
if EvalTest:
EvalSuffix = "_test"
logfile_name = opt.exp_desc + time.strftime(
"_%m_%d_%H:%M:%S") + EvalSuffix + ".log.txt"
ps = PlotSaver(logfile_name, log_to_stdout=opt.log_to_stdout)
# step1: Model
# model = getattr(models, opt.model)(use_imp = opt.use_imp, n = opt.feat_num, model_name=opt.exp_desc + ("_r={r}_gm={w}".format(
# r=opt.rate_loss_threshold,
# w=opt.rate_loss_weight)
# if opt.use_imp else "_no_imp"))
model = getattr(models, opt.model)(use_imp=opt.use_imp,
n=opt.feat_num,
model_name=opt.exp_desc)
# print (model)
# pdb.set_trace()
global use_data_parallel
if opt.use_gpu:
model, use_data_parallel = multiple_gpu_process(model)
# real use gpu or cpu
opt.use_gpu = opt.use_gpu and use_data_parallel >= 0
cudnn.benchmark = True
# step2: Data
normalize = transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5])
train_data_transforms = transforms.Compose([
# transforms.RandomHorizontalFlip(), TODO: try to reimplement by myself to simultaneous operate on label and data
transforms.RandomCrop(128),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
normalize
])
val_data_transforms = transforms.Compose(
[transforms.CenterCrop(128),
transforms.ToTensor(), normalize])
caffe_data_transforms = transforms.Compose([transforms.CenterCrop(128)])
# transforms || data
train_data = ImageFilelist(
flist=opt.train_data_list,
transform=train_data_transforms,
)
val_data = ImageFilelist(
flist=opt.val_data_list,
prefix=opt.val_data_prefix,
transform=val_data_transforms,
)
val_data_caffe = ImageFilelist(flist=opt.val_data_list,
transform=caffe_data_transforms)
test_data_caffe = ImageFilelist(flist=opt.test_data_list,
transform=caffe_data_transforms)
if opt.make_caffe_data:
save_caffe_data(test_data_caffe)
print('Make caffe dataset over!')
return
# train_data = ImageCropWithBBoxMaskDataset(
# opt.train_data_list,
# train_data_transforms,
# contrastive_degree = opt.contrastive_degree,
# mse_bbox_weight = opt.input_original_bbox_weight
# )
# val_data = ImageCropWithBBoxMaskDataset(
# opt.val_data_list,
# val_data_transforms,
# contrastive_degree = opt.contrastive_degree,
# mse_bbox_weight = opt.input_original_bbox_weight
# )
train_dataloader = DataLoader(train_data,
opt.batch_size,
shuffle=True,
num_workers=opt.num_workers,
pin_memory=True)
val_dataloader = DataLoader(val_data,
opt.batch_size,
shuffle=False,
num_workers=opt.num_workers,
pin_memory=True)
# step3: criterion and optimizer
mse_loss = t.nn.MSELoss(size_average=False)
if opt.use_imp:
# TODO: new rate loss
rate_loss = RateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
# rate_loss = LimuRateLoss(opt.rate_loss_threshold, opt.rate_loss_weight)
def weighted_mse_loss(input, target, weight):
# weight[weight!=opt.mse_bbox_weight] = 1
# weight[weight==opt.mse_bbox_weight] = opt.mse_bbox_weight
# print('max val', weight.max())
# return mse_loss(input, target)
# weight_clone = weight.clone()
# weight_clone[weight_clone == opt.input_original_bbox_weight] = 0
# return t.sum(weight_clone * (input - target) ** 2)
weight_clone = t.ones_like(weight)
weight_clone[weight ==
opt.input_original_bbox_inner] = opt.mse_bbox_weight
return t.sum(weight_clone * (input - target)**2)
def yolo_rate_loss(imp_map, mask_r):
return rate_loss(imp_map)
# V2 contrastive_degree must be 0!
# return YoloRateLossV2(mask_r, opt.rate_loss_threshold, opt.rate_loss_weight)(imp_map)
start_epoch = 0
decay_file_create_time = -1 # 为了避免同一个文件反复衰减学习率, 所以判断修改时间
previous_loss = 1e100
tolerant_now = 0
same_lr_epoch = 0
lr = opt.lr
optimizer = t.optim.Adam(model.parameters(), lr=lr, betas=(0.9, 0.999))
if opt.resume:
start_epoch = (model.module if use_data_parallel == 1 else model).load(
None if opt.finetune else optimizer, opt.resume, opt.finetune)
if opt.finetune:
print('Finetune from model checkpoint file', opt.resume)
else:
print('Resume training from checkpoint file', opt.resume)
print('Continue training from epoch %d.' % start_epoch)
same_lr_epoch = start_epoch % opt.lr_anneal_epochs
decay_times = start_epoch // opt.lr_anneal_epochs
lr = opt.lr * (opt.lr_decay**decay_times)
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Decay lr %d times, now lr is %e.' % (decay_times, lr))
# step4: meters
mse_loss_meter = AverageValueMeter()
if opt.use_imp:
rate_loss_meter = AverageValueMeter()
rate_display_meter = AverageValueMeter()
total_loss_meter = AverageValueMeter()
# ps init
ps.new_plot('train mse loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_mse_loss")
ps.new_plot('val mse loss', 1, xlabel="epoch", ylabel="val_mse_loss")
if opt.use_imp:
ps.new_plot('train rate value',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_value")
ps.new_plot('train rate loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_rate_loss")
ps.new_plot('train total loss',
opt.print_freq,
xlabel="iteration",
ylabel="train_total_loss")
ps.new_plot('val rate value',
1,
xlabel="iteration",
ylabel="val_rate_value")
ps.new_plot('val rate loss',
1,
xlabel="iteration",
ylabel="val_rate_loss")
ps.new_plot('val total loss',
1,
xlabel="iteration",
ylabel="val_total_loss")
# 如果测试时是600,max_epoch也是600
if opt.only_init_val and opt.max_epoch <= start_epoch:
opt.max_epoch = start_epoch + 2
for epoch in range(start_epoch + 1, opt.max_epoch + 1):
same_lr_epoch += 1
# per epoch avg loss meter
mse_loss_meter.reset()
if opt.use_imp:
rate_display_meter.reset()
rate_loss_meter.reset()
total_loss_meter.reset()
else:
total_loss_meter = mse_loss_meter
# cur_epoch_loss refresh every epoch
# vis.refresh_plot('cur epoch train mse loss')
ps.new_plot("cur epoch train mse loss",
opt.print_freq,
xlabel="iteration in cur epoch",
ylabel="train_mse_loss")
# progress_bar = tqdm(enumerate(train_dataloader), total=len(train_dataloader), ascii=True)
# progress_bar.set_description('epoch %d/%d, loss = 0.00' % (epoch, opt.max_epoch))
# Init val
if (epoch == start_epoch + 1) and opt.init_val:
print('Init validation ... ')
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Init Val @ Epoch:{epoch}, lr:{lr}, val_mse_loss: {val_mse_loss}'
.format(epoch=epoch, lr=lr, val_mse_loss=mse_val_loss))
if opt.only_init_val:
print('Only Init Val Over!')
return
model.train()
# if epoch == start_epoch + 1:
# print ('Start training, please inspect log file %s!' % logfile_name)
# mask is the detection bounding box mask
for idx, data in enumerate(train_dataloader):
# pdb.set_trace()
data = Variable(data)
# mask = Variable(mask)
# o_mask = Variable(o_mask, requires_grad=False)
if opt.use_gpu:
data = data.cuda(async=True)
# mask = mask.cuda(async = True)
# o_mask = o_mask.cuda(async = True)
# pdb.set_trace()
optimizer.zero_grad()
if opt.use_imp:
reconstructed, imp_mask_sigmoid = model(data)
else:
reconstructed = model(data)
# print ('imp_mask_height', model.imp_mask_height)
# pdb.set_trace()
# print ('type recons', type(reconstructed.data))
loss = mse_loss(reconstructed, data)
# loss = mse_loss(reconstructed, data)
caffe_loss = loss / (2 * opt.batch_size)
if opt.use_imp:
rate_loss_ = rate_loss(imp_mask_sigmoid)
# rate_loss_ = yolo_rate_loss(imp_mask_sigmoid, mask)
total_loss = caffe_loss + rate_loss_
else:
total_loss = caffe_loss
total_loss.backward()
optimizer.step()
mse_loss_meter.add(caffe_loss.data[0])
if opt.use_imp:
rate_loss_meter.add(rate_loss_.data[0])
rate_display_meter.add(imp_mask_sigmoid.data.mean())
total_loss_meter.add(total_loss.data[0])
if idx % opt.print_freq == opt.print_freq - 1:
ps.add_point(
'train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
ps.add_point(
'cur epoch train mse loss',
mse_loss_meter.value()[0]
if opt.print_smooth else caffe_loss.data[0])
if opt.use_imp:
ps.add_point(
'train rate value',
rate_display_meter.value()[0]
if opt.print_smooth else imp_mask_sigmoid.data.mean())
ps.add_point(
'train rate loss',
rate_loss_meter.value()[0]
if opt.print_smooth else rate_loss_.data[0])
ps.add_point(
'train total loss',
total_loss_meter.value()[0]
if opt.print_smooth else total_loss.data[0])
if not opt.use_imp:
ps.log('Epoch %d/%d, Iter %d/%d, loss = %.2f, lr = %.8f' %
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0], lr))
else:
ps.log(
'Epoch %d/%d, Iter %d/%d, loss = %.2f, mse_loss = %.2f, rate_loss = %.2f, rate_display = %.2f, lr = %.8f'
%
(epoch, opt.max_epoch, idx, len(train_dataloader),
total_loss_meter.value()[0],
mse_loss_meter.value()[0], rate_loss_meter.value()[0],
rate_display_meter.value()[0], lr))
# 进入debug模式
if os.path.exists(opt.debug_file):
pdb.set_trace()
if epoch % opt.save_interval == 0:
print('Save checkpoint file of epoch %d.' % epoch)
if use_data_parallel == 1:
model.module.save(optimizer, epoch)
else:
model.save(optimizer, epoch)
ps.make_plot('train mse loss')
ps.make_plot('cur epoch train mse loss', epoch)
if opt.use_imp:
ps.make_plot("train rate value")
ps.make_plot("train rate loss")
ps.make_plot("train total loss")
if epoch % opt.eval_interval == 0:
print('Validating ...')
# val
if opt.use_imp:
mse_val_loss, rate_val_loss, total_val_loss, rate_val_display = val(
model, val_dataloader, mse_loss, rate_loss, ps)
else:
mse_val_loss = val(model, val_dataloader, mse_loss, None, ps)
ps.add_point('val mse loss', mse_val_loss)
if opt.use_imp:
ps.add_point('val rate value', rate_val_display)
ps.add_point('val rate loss', rate_val_loss)
ps.add_point('val total loss', total_val_loss)
ps.make_plot('val mse loss')
if opt.use_imp:
ps.make_plot('val rate value')
ps.make_plot('val rate loss')
ps.make_plot('val total loss')
# log sth.
if opt.use_imp:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss: {train_mse_loss}, train_rate_loss: {train_rate_loss}, train_total_loss: {train_total_loss}, train_rate_display: {train_rate_display} \n\
val_mse_loss: {val_mse_loss}, val_rate_loss: {val_rate_loss}, val_total_loss: {val_total_loss}, val_rate_display: {val_rate_display} '
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
train_rate_loss=rate_loss_meter.value()[0],
train_total_loss=total_loss_meter.value()[0],
train_rate_display=rate_display_meter.value()[0],
val_mse_loss=mse_val_loss,
val_rate_loss=rate_val_loss,
val_total_loss=total_val_loss,
val_rate_display=rate_val_display))
else:
ps.log(
'Epoch:{epoch}, lr:{lr}, train_mse_loss:{train_mse_loss}, val_mse_loss:{val_mse_loss}'
.format(epoch=epoch,
lr=lr,
train_mse_loss=mse_loss_meter.value()[0],
val_mse_loss=mse_val_loss))
# Adaptive adjust lr
# 每个lr,如果有opt.tolerant_max次比上次的val_loss还高,
# update learning rate
# if loss_meter.value()[0] > previous_loss:
if opt.use_early_adjust:
if total_loss_meter.value()[0] > previous_loss:
tolerant_now += 1
if tolerant_now == opt.tolerant_max:
tolerant_now = 0
same_lr_epoch = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
ps.log('Due to early stop anneal lr to %.10f at epoch %d' %
(lr, epoch))
else:
# tolerant_now -= 1
tolerant_now = 0
if epoch % opt.lr_anneal_epochs == 0:
# if same_lr_epoch and same_lr_epoch % opt.lr_anneal_epochs == 0:
same_lr_epoch = 0
tolerant_now = 0
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print('Anneal lr to %.10f at epoch %d due to full epochs.' %
(lr, epoch))
ps.log('Anneal lr to %.10f at epoch %d due to full epochs.' %
(lr, epoch))
if opt.use_file_decay_lr and os.path.exists(opt.lr_decay_file):
cur_mtime = os.path.getmtime(opt.lr_decay_file)
if cur_mtime > decay_file_create_time:
decay_file_create_time = cur_mtime
lr = lr * opt.lr_decay
for param_group in optimizer.param_groups:
param_group['lr'] = lr
print(
'Anneal lr to %.10f at epoch %d due to decay-file indicator.'
% (lr, epoch))
ps.log(
'Anneal lr to %.10f at epoch %d due to decay-file indicator.'
% (lr, epoch))
previous_loss = total_loss_meter.value()[0]
if opt.use_batch_process:
batch_model_id += 1
train(kwargs)