def test(val_loader, model, criterion, epoch, use_cuda):
global best_acc
batch_time = AverageMeter()
data_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
# switch to evaluate mode
model.eval()
torch.set_grad_enabled(False)
end = time.time()
bar = Bar('Processing', max=len(val_loader))
for batch_idx, (inputs, targets) in enumerate(val_loader):
# measure data loading time
data_time.update(time.time() - end)
if use_cuda:
inputs, targets = inputs.cuda(), targets.cuda()
inputs, targets = torch.autograd.Variable(
inputs, volatile=True), torch.autograd.Variable(targets)
# compute output
outputs = model(inputs)
loss = criterion(outputs, targets)
# measure accuracy and record loss
prec1, prec5 = accuracy(outputs.data, targets.data, topk=(1, 5))
# losses.update(loss.data[0], inputs.size(0))
losses.update(loss.data, inputs.size(0))
#top1.update(prec1[0], inputs.size(0))
top1.update(prec1, inputs.size(0))
#top5.update(prec5[0], inputs.size(0))
top5.update(prec5, inputs.size(0))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
# plot progress
bar.suffix = '({batch}/{size}) Data: {data:.3f}s | Batch: {bt:.3f}s | Total: {total:} | ETA: {eta:} | Loss: {loss:.4f} | top1: {top1: .4f} | top5: {top5: .4f}'.format(
batch=batch_idx + 1,
size=len(val_loader),
data=data_time.avg,
bt=batch_time.avg,
total=bar.elapsed_td,
eta=bar.eta_td,
loss=losses.avg,
top1=top1.avg,
top5=top5.avg,
)
bar.next()
print(bar.suffix)
bar.finish()
return (losses.avg, top1.avg)
def train(train_loader, model, criterion, optimizer, epoch, use_cuda):
# switch to train mode
model.train()
torch.set_grad_enabled(True)
batch_time = AverageMeter()
data_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
end = time.time()
bar = Bar('Processing', max=len(train_loader))
show_step = len(train_loader) // 10
for batch_idx, (inputs, targets) in enumerate(train_loader):
batch_size = inputs.size(0)
if batch_size < args.train_batch:
continue
# measure data loading time
data_time.update(time.time() - end)
if use_cuda:
inputs, targets = inputs.cuda(), targets.cuda(async=True)
inputs, targets = torch.autograd.Variable(inputs), torch.autograd.Variable(targets)
# compute output
outputs = model(inputs)
loss = criterion(outputs, targets)
# measure accuracy and record loss
prec1, prec5 = accuracy(outputs.data, targets.data, topk=(1, 5))
losses.update(loss.data, inputs.size(0))
top1.update(prec1, inputs.size(0))
top5.update(prec5, inputs.size(0))
# compute gradient and do SGD step
optimizer.zero_grad()
loss.backward()
optimizer.step()
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
# plot progress
bar.suffix = '({batch}/{size}) Data: {data:.3f}s | Batch: {bt:.3f}s | Total: {total:} | ETA: {eta:} | Loss: {loss:.4f} | top1: {top1: .4f} | top5: {top5: .4f}'.format(
batch=batch_idx + 1,
size=len(train_loader),
data=data_time.val,
bt=batch_time.val,
total=bar.elapsed_td,
eta=bar.eta_td,
loss=losses.avg,
top1=top1.avg,
top5=top5.avg,
)
if (batch_idx) % show_step == 0:
print(bar.suffix)
bar.next()
bar.finish()
return (losses.avg, top1.avg)
def validate(test_loader, model, args, config):
"""Test the model on the validation set
We follow "fully convolutional" testing:
* Scale the video with shortest side =256
* Uniformly sample 10 clips within a video
* For each clip, crop K=3 regions of 256*256 along the longest side
* This is equivalent to 30-crop testing
"""
# set up meters
batch_time = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
cm_meter = AverageMeter()
model.eval()
# data prefetcher with noramlization
test_loader = ClipPrefetcherJoint(test_loader, config['input']['mean'],
config['input']['std'])
# loop over validation set
end = time.time()
input, target = test_loader.next()
i = 0
# for large models
if args.slice:
batch_size = input.size(1)
max_split_size = 1
for split_size in range(2, batch_size):
if (batch_size % split_size) == 0 and split_size > max_split_size:
max_split_size = split_size
num_batch_splits = batch_size // max_split_size
print("Split the input by size: {:d}x{:d}".format(
max_split_size, num_batch_splits))
while input is not None:
i += 1
# disable/enable gradients
with torch.no_grad():
if args.slice:
# slice the inputs for testing
splited_inputs = torch.split(input, max_split_size, dim=1)
splited_outputs = []
for idx in range(num_batch_splits):
split_output = model(splited_inputs[idx])
# test time augmentation (minor performance boost)
flipped_split_input = torch.flip(splited_inputs[idx],
(-1, ))
flipped_split_output = model(flipped_split_input)
split_output = 0.5 * (split_output + flipped_split_output)
splited_outputs.append(split_output)
output = torch.mean(torch.stack(splited_outputs), dim=0)
else:
# forward all inputs
output, _, _ = model(input)
# print(output.size())
# test time augmentation (minor performance boost)
# always flip the last dim (width)
flipped_input = torch.flip(input, (-1, ))
flipped_output, _, _ = model(flipped_input)
output = 0.5 * (output + flipped_output)
# print(target[1].size())
# print(target[2].size())
# measure accuracy and record loss
acc1, acc5 = accuracy(output.data, target[0], topk=(1, 5))
top1.update(acc1.item(), input.size(0))
top5.update(acc5.item(), input.size(0))
batch_cm = confusion_matrix(output.data, target[0])
cm_meter.update(batch_cm.data.cpu().double())
# prefetch next batch
input, target = test_loader.next()
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
# printing
if i % (args.print_freq * 2) == 0:
print('Test: [{0}/{1}]\t'
'Time {batch_time.val:.3f} ({batch_time.avg:.3f})\t'
'Acc@1 {top1.val:.2f} ({top1.avg:.2f})\t'
'Acc@5 {top5.val:.2f} ({top5.avg:.2f})'.format(
i,
len(test_loader),
batch_time=batch_time,
top1=top1,
top5=top5))
cls_acc = mean_class_accuracy(cm_meter.sum)
print(
'***Acc@1 {top1.avg:.3f} Acc@5 {top5.avg:.3f} Mean Cls Acc {cls_acc:.3f}'
.format(top1=top1, top5=top5, cls_acc=100 * cls_acc))
return top1.avg, top5.avg
def validate(val_loader, model, epoch, args, config):
"""Test the model on the validation set"""
# set up meters
batch_time = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
cm_meter = AverageMeter()
# switch to evaluate mode
model.eval()
# data prefetcher with noramlization
val_loader = ClipPrefetcherJoint(val_loader, config['input']['mean'],
config['input']['std'])
# loop over validation set
end = time.time()
input, target = val_loader.next()
i = 0
while input is not None:
i += 1
with torch.no_grad():
# forward the model (without gradients)
output = model(input)
# print(target[0])
# measure accuracy and record loss
acc1, acc5 = accuracy(output[0].data, target[0], topk=(1, 5))
batch_cm = confusion_matrix(output[0].data, target[0])
if args.distributed:
reduced_acc1 = reduce_tensor(acc1, args.world_size)
reduced_acc5 = reduce_tensor(acc5, args.world_size)
reduced_cm = reduce_tensor(batch_cm.data,
args.world_size,
avg=False)
else:
reduced_acc1 = acc1
reduced_acc5 = acc5
reduced_cm = batch_cm.data
top1.update(reduced_acc1.item(), input.size(0))
top5.update(reduced_acc5.item(), input.size(0))
cm_meter.update(reduced_cm.cpu().clone())
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
# printing
if i % (args.print_freq * 2) == 0 and (args.local_rank == 0):
print('Test: [{0}/{1}]\t'
'Time {batch_time.val:.3f} ({batch_time.avg:.3f})\t'
'Acc@1 {top1.val:.2f} ({top1.avg:.2f})\t'
'Acc@5 {top5.val:.2f} ({top5.avg:.2f})'.format(
i,
len(val_loader),
batch_time=batch_time,
top1=top1,
top5=top5))
# prefetch next batch
input, target = val_loader.next()
# finish up
if args.local_rank == 0:
cls_acc = 100 * mean_class_accuracy(cm_meter.sum)
print(
'******Acc@1 {top1.avg:.3f} Acc@5 {top5.avg:.3f} Cls Acc {cls_acc:.3f}'
.format(top1=top1, top5=top5, cls_acc=cls_acc))
# log top-1/5 acc
writer.add_scalars('data/top1_accuracy', {"val": top1.avg}, epoch + 1)
writer.add_scalars('data/top5_accuracy', {"val": top5.avg}, epoch + 1)
writer.add_scalars('data/mean_cls_acc', {"val": cls_acc}, epoch + 1)
return top1.avg, top5.avg
def train(train_loader, model, optimizer, scheduler, epoch, args, config):
"""Training the model"""
# set up meters
batch_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
cm_meter = AverageMeter()
# number of iterations per epoch
num_iters = len(train_loader)
# switch to train mode
model.train()
# data prefetcher with noramlization
train_loader = ClipPrefetcherJoint(train_loader, config['input']['mean'],
config['input']['std'])
# main loop
end = time.time()
input, target = train_loader.next()
i = 0
while input is not None:
# input & target are pre-fetched
i += 1
# print(target)
# compute output
# print(input.size())
# print(target[0].size())
# print(target[1].size())
# print(target[2].size())
output, loss = model(input, targets=target)
# compute gradient and do SGD step
optimizer.zero_grad()
loss.backward()
optimizer.step()
# printing (on the first GPU)
# print(i)
# print(args.print_freq)
if (i % args.print_freq) == 0:
# only check the stats when necessary
# avoid additional cost at each iter
acc1, acc5 = accuracy(output.data, target[0], topk=(1, 5))
batch_cm = confusion_matrix(output.data, target[0])
# measure accuracy and record loss
if args.distributed:
reduced_loss = reduce_tensor(loss.data, args.world_size)
reduced_acc1 = reduce_tensor(acc1, args.world_size)
reduced_acc5 = reduce_tensor(acc5, args.world_size)
reduced_cm = reduce_tensor(batch_cm.data,
args.world_size,
avg=False)
else:
reduced_loss = loss.mean().data
reduced_acc1 = acc1
reduced_acc5 = acc5
reduced_cm = batch_cm.data
losses.update(reduced_loss.item(), input.size(0))
top1.update(reduced_acc1.item(), input.size(0))
top5.update(reduced_acc5.item(), input.size(0))
cm_meter.update(reduced_cm.cpu().clone())
# measure elapsed time
torch.cuda.synchronize()
batch_time.update((time.time() - end) / args.print_freq)
end = time.time()
if args.local_rank == 0:
lr = scheduler.get_lr()[0]
print('Epoch: [{0}][{1}/{2}]\t'
'Time {batch_time.val:.3f} ({batch_time.avg:.3f})\t'
'Loss {loss.val:.3f} ({loss.avg:.3f})\t'
'Acc@1 {top1.val:.2f} ({top1.avg:.2f})\t'
'Acc@5 {top5.val:.2f} ({top5.avg:.2f})'.format(
epoch + 1,
i,
num_iters,
batch_time=batch_time,
loss=losses,
top1=top1,
top5=top5))
# log loss / lr
writer.add_scalar('data/training_loss', losses.val,
epoch * num_iters + i)
writer.add_scalar('data/learning_rate', lr,
epoch * num_iters + i)
# step the lr scheduler after each iteration
scheduler.step()
# prefetch next batch
input, target = train_loader.next()
# finish up
if args.local_rank == 0:
# print & step the learning rate
lr = scheduler.get_lr()[0]
cls_acc = 100 * mean_class_accuracy(cm_meter.sum)
print("[Train]: Epoch {:d} finished with lr={:f}".format(
epoch + 1, lr))
# log top-1/5 acc
writer.add_scalars('data/top1_accuracy', {"train": top1.avg},
epoch + 1)
writer.add_scalars('data/top5_accuracy', {"train": top5.avg},
epoch + 1)
writer.add_scalars('data/mean_cls_acc', {"train": cls_acc}, epoch + 1)
return
top1 = AverageMeter('Acc@1', ':6.2f')
top5 = AverageMeter('Acc@5', ':6.2f')
cnt = 0
for image, target in data_loader_test:
image_resized = []
for im in image:
image_resized += [cv2.resize(im, (width, height))]
image = np.asarray(image_resized)
if floating_model:
input_data = (np.float32(image) - input_mean) / input_std
else:
input_data = image.astype(np.uint8)
interpreter.set_tensor(input_details[0]['index'], input_data)
interpreter.invoke()
output_data = interpreter.get_tensor(output_details[0]['index'])
cnt += 1
acc1, acc5 = accuracy(torch.from_numpy(output_data), torch.from_numpy(target+1), topk=(1, 5))
print('.', end='')
top1.update(acc1[0], image.shape[0])
top5.update(acc5[0], image.shape[0])
if cnt >= 1000:
break
print('\nEvaluation accuracy on %d images, %2.3f %2.3f' % (len(data_loader_test), top1.avg, top5.avg))
def test(val_loader, model, criterion, epoch, use_cuda):
global best_acc
batch_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
# switch to evaluate mode
model.eval()
# torch.set_grad_enabled(False)
end = time.time()
if args.local_rank == 0:
bar = Bar('Processing', max=len(val_loader))
prefetcher = data_prefetcher(val_loader)
inputs, targets = prefetcher.next()
batch_idx = -1
while inputs is not None:
# for batch_idx, (inputs, targets) in enumerate(val_loader):
batch_idx += 1
# if use_cuda:
# inputs, targets = inputs.cuda(), targets.cuda()
# inputs, targets = torch.autograd.Variable(inputs, volatile=True), torch.autograd.Variable(targets)
# compute output
with torch.no_grad():
outputs = model(inputs)
loss = criterion(outputs, targets)
# measure accuracy and record loss
prec1, prec5 = accuracy(outputs.data, targets.data, topk=(1, 5))
reduced_loss = reduce_tensor(loss.data)
prec1 = reduce_tensor(prec1)
prec5 = reduce_tensor(prec5)
# to_python_float incurs a host<->device sync
losses.update(to_python_float(reduced_loss), inputs.size(0))
top1.update(to_python_float(prec1), inputs.size(0))
top5.update(to_python_float(prec5), inputs.size(0))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
# plot progress
if args.local_rank == 0:
bar.suffix = 'Valid({batch}/{size}) | Batch: {bt:.3f}s | Total: {total:} | Loss: {loss:.4f} | top1: {top1: .4f} | top5: {top5: .4f}'.format(
batch=batch_idx + 1,
size=len(val_loader),
bt=batch_time.avg,
total=bar.elapsed_td,
loss=losses.avg,
top1=top1.avg,
top5=top5.avg,
)
bar.next()
inputs, targets = prefetcher.next()
if args.local_rank == 0:
print(bar.suffix)
bar.finish()
return (losses.avg, top1.avg)
def train(train_loader, model, criterion, optimizer, epoch, use_cuda):
# switch to train mode
model.train()
torch.set_grad_enabled(True)
batch_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
end = time.time()
if args.local_rank == 0:
bar = Bar('Processing', max=len(train_loader))
show_step = len(train_loader) // 10
prefetcher = data_prefetcher(train_loader)
inputs, targets = prefetcher.next()
batch_idx = -1
while inputs is not None:
# for batch_idx, (inputs, targets) in enumerate(train_loader):
batch_idx += 1
batch_size = inputs.size(0)
if batch_size < args.train_batch:
break
# measure data loading time
# if use_cuda:
# inputs, targets = inputs.cuda(), targets.cuda(async=True)
# inputs, targets = torch.autograd.Variable(inputs), torch.autograd.Variable(targets)
if args.mixup:
inputs, targets_a, targets_b, lam = mixup_data(inputs, targets, args.alpha, use_cuda)
outputs = model(inputs)
loss_func = mixup_criterion(targets_a, targets_b, lam)
old_loss = loss_func(criterion, outputs)
else:
outputs = model(inputs)
old_loss = criterion(outputs, targets)
# compute gradient and do SGD step
optimizer.zero_grad()
# loss.backward()
with amp.scale_loss(old_loss, optimizer) as loss:
loss.backward()
optimizer.step()
if batch_idx % args.print_freq == 0:
# measure accuracy and record loss
prec1, prec5 = accuracy(outputs.data, targets.data, topk=(1, 5))
reduced_loss = reduce_tensor(loss.data)
prec1 = reduce_tensor(prec1)
prec5 = reduce_tensor(prec5)
# to_python_float incurs a host<->device sync
losses.update(to_python_float(reduced_loss), inputs.size(0))
top1.update(to_python_float(prec1), inputs.size(0))
top5.update(to_python_float(prec5), inputs.size(0))
torch.cuda.synchronize()
# measure elapsed time
batch_time.update((time.time() - end) / args.print_freq)
end = time.time()
if args.local_rank == 0: # plot progress
bar.suffix = '({batch}/{size}) | Batch: {bt:.3f}s | Total: {total:} | Loss: {loss:.4f} | top1: {top1: .4f} | top5: {top5: .4f}'.format(
batch=batch_idx + 1,
size=len(train_loader),
bt=batch_time.val,
total=bar.elapsed_td,
loss=losses.avg,
top1=top1.avg,
top5=top5.avg,
)
bar.next()
if (batch_idx) % show_step == 0 and args.local_rank == 0:
print('E%d' % (epoch) + bar.suffix)
inputs, targets = prefetcher.next()
if args.local_rank == 0:
bar.finish()
return (losses.avg, top1.avg)
if __name__ == '__main__':
train_batch_size = 1
eval_batch_size = 1
data_path = 'data/imagenet_1k'
# modelpath = 'data/mobilenet_v2_fp32_scripted.pth'
modelpath = 'data/mobilenet_v2_int8_static_qnnpack.pth'
scripted_model = torch.jit.load(modelpath)
data_loader, data_loader_test = prepare_data_loaders(data_path)
top1 = AverageMeter('Acc@1', ':6.2f')
top5 = AverageMeter('Acc@5', ':6.2f')
for cnt, (image, target) in enumerate(data_loader_test):
output = scripted_model(image)
acc1, acc5 = accuracy(output, target, topk=(1, 5))
print('.', end='')
top1.update(acc1[0], image.shape[0])
top5.update(acc5[0], image.shape[0])
if cnt >= 1000:
break
print('\nEvaluation accuracy on %d images, %2.3f %2.3f' %
(len(data_loader_test), top1.avg, top5.avg))
# testIm = cv2.imread('fox.jpg')
# testIm = testIm[:, :, ::-1]
# output = scripted_model(testImTensor)
