def validate(args):
rng = jax.random.PRNGKey(0)
model, variables = create_model(args.model, pretrained=True, rng=rng)
print(f'Created {args.model} model. Validating...')
if args.no_jit:
eval_step = lambda images, labels: eval_forward(
model, variables, images, labels)
else:
eval_step = jax.jit(lambda images, labels: eval_forward(
model, variables, images, labels))
dataset = create_dataset('imagenet', args.data)
data_config = resolve_data_config(vars(args), model=model)
loader = create_loader(dataset,
input_size=data_config['input_size'],
batch_size=args.batch_size,
use_prefetcher=False,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=8,
crop_pct=data_config['crop_pct'])
batch_time = AverageMeter()
correct_top1, correct_top5 = 0, 0
total_examples = 0
start_time = prev_time = time.time()
for batch_index, (images, labels) in enumerate(loader):
images = images.numpy().transpose(0, 2, 3, 1)
labels = labels.numpy()
top1_count, top5_count = eval_step(images, labels)
correct_top1 += int(top1_count)
correct_top5 += int(top5_count)
total_examples += images.shape[0]
batch_time.update(time.time() - prev_time)
if batch_index % 20 == 0 and batch_index > 0:
print(
f'Test: [{batch_index:>4d}/{len(loader)}] '
f'Rate: {images.shape[0] / batch_time.val:>5.2f}/s ({images.shape[0] / batch_time.avg:>5.2f}/s) '
f'Acc@1: {100 * correct_top1 / total_examples:>7.3f} '
f'Acc@5: {100 * correct_top5 / total_examples:>7.3f}')
prev_time = time.time()
acc_1 = 100 * correct_top1 / total_examples
acc_5 = 100 * correct_top5 / total_examples
print(
f'Validation complete. {total_examples / (prev_time - start_time):>5.2f} img/s. '
f'Acc@1 {acc_1:>7.3f}, Acc@5 {acc_5:>7.3f}')
return dict(top1=float(acc_1), top5=float(acc_5))
def main():
setup_default_logging()
args, args_text = _parse_args()
if args.log_wandb:
if has_wandb:
wandb.init(project=args.experiment, config=args)
else:
_logger.warning(
"You've requested to log metrics to wandb but package not found. "
"Metrics not being logged to wandb, try `pip install wandb`")
args.prefetcher = not args.no_prefetcher
args.distributed = False
if 'WORLD_SIZE' in os.environ:
args.distributed = int(os.environ['WORLD_SIZE']) > 1
args.device = 'cuda:0'
args.world_size = 1
args.rank = 0 # global rank
if args.distributed:
args.device = 'cuda:%d' % args.local_rank
torch.cuda.set_device(args.local_rank)
torch.distributed.init_process_group(backend='nccl',
init_method='env://')
args.world_size = torch.distributed.get_world_size()
args.rank = torch.distributed.get_rank()
_logger.info(
'Training in distributed mode with multiple processes, 1 GPU per process. Process %d, total %d.'
% (args.rank, args.world_size))
else:
_logger.info('Training with a single process on 1 GPUs.')
assert args.rank >= 0
# resolve AMP arguments based on PyTorch / Apex availability
use_amp = None
if args.amp:
# `--amp` chooses native amp before apex (APEX ver not actively maintained)
if has_native_amp:
args.native_amp = True
elif has_apex:
args.apex_amp = True
if args.apex_amp and has_apex:
use_amp = 'apex'
elif args.native_amp and has_native_amp:
use_amp = 'native'
elif args.apex_amp or args.native_amp:
_logger.warning(
"Neither APEX or native Torch AMP is available, using float32. "
"Install NVIDA apex or upgrade to PyTorch 1.6")
random_seed(args.seed, args.rank)
model_KD = None
if args.kd_model_path is not None:
model_KD = build_kd_model(args)
model = create_model(
args.model,
pretrained=args.pretrained,
num_classes=args.num_classes,
drop_rate=args.drop,
drop_connect_rate=args.drop_connect, # DEPRECATED, use drop_path
drop_path_rate=args.drop_path,
drop_block_rate=args.drop_block,
global_pool=args.gp,
bn_momentum=args.bn_momentum,
bn_eps=args.bn_eps,
scriptable=args.torchscript,
checkpoint_path=args.initial_checkpoint)
if args.num_classes is None:
assert hasattr(
model, 'num_classes'
), 'Model must have `num_classes` attr if not set on cmd line/config.'
args.num_classes = model.num_classes # FIXME handle model default vs config num_classes more elegantly
if args.local_rank == 0:
_logger.info(
f'Model {safe_model_name(args.model)} created, param count:{sum([m.numel() for m in model.parameters()])}'
)
data_config = resolve_data_config(vars(args),
model=model,
verbose=args.local_rank == 0)
# setup augmentation batch splits for contrastive loss or split bn
num_aug_splits = 0
if args.aug_splits > 0:
assert args.aug_splits > 1, 'A split of 1 makes no sense'
num_aug_splits = args.aug_splits
# enable split bn (separate bn stats per batch-portion)
if args.split_bn:
assert num_aug_splits > 1 or args.resplit
model = convert_splitbn_model(model, max(num_aug_splits, 2))
# move model to GPU, enable channels last layout if set
model.cuda()
if args.channels_last:
model = model.to(memory_format=torch.channels_last)
# setup synchronized BatchNorm for distributed training
if args.distributed and args.sync_bn:
assert not args.split_bn
if has_apex and use_amp == 'apex':
# Apex SyncBN preferred unless native amp is activated
model = convert_syncbn_model(model)
else:
model = torch.nn.SyncBatchNorm.convert_sync_batchnorm(model)
if args.local_rank == 0:
_logger.info(
'Converted model to use Synchronized BatchNorm. WARNING: You may have issues if using '
'zero initialized BN layers (enabled by default for ResNets) while sync-bn enabled.'
)
if args.torchscript:
assert not use_amp == 'apex', 'Cannot use APEX AMP with torchscripted model'
assert not args.sync_bn, 'Cannot use SyncBatchNorm with torchscripted model'
model = torch.jit.script(model)
optimizer = create_optimizer_v2(model, **optimizer_kwargs(cfg=args))
# setup automatic mixed-precision (AMP) loss scaling and op casting
amp_autocast = suppress # do nothing
loss_scaler = None
if use_amp == 'apex':
model, optimizer = amp.initialize(model, optimizer, opt_level='O1')
loss_scaler = ApexScaler()
if args.local_rank == 0:
_logger.info('Using NVIDIA APEX AMP. Training in mixed precision.')
elif use_amp == 'native':
amp_autocast = torch.cuda.amp.autocast
loss_scaler = NativeScaler()
if args.local_rank == 0:
_logger.info(
'Using native Torch AMP. Training in mixed precision.')
else:
if args.local_rank == 0:
_logger.info('AMP not enabled. Training in float32.')
# optionally resume from a checkpoint
resume_epoch = None
if args.resume:
resume_epoch = resume_checkpoint(
model,
args.resume,
optimizer=None if args.no_resume_opt else optimizer,
loss_scaler=None if args.no_resume_opt else loss_scaler,
log_info=args.local_rank == 0)
# setup exponential moving average of model weights, SWA could be used here too
model_ema = None
if args.model_ema:
# Important to create EMA model after cuda(), DP wrapper, and AMP but before SyncBN and DDP wrapper
model_ema = ModelEmaV2(
model,
decay=args.model_ema_decay,
device='cpu' if args.model_ema_force_cpu else None)
if args.resume:
load_checkpoint(model_ema.module, args.resume, use_ema=True)
# setup distributed training
if args.distributed:
if has_apex and use_amp == 'apex':
# Apex DDP preferred unless native amp is activated
if args.local_rank == 0:
_logger.info("Using NVIDIA APEX DistributedDataParallel.")
model = ApexDDP(model, delay_allreduce=True)
else:
if args.local_rank == 0:
_logger.info("Using native Torch DistributedDataParallel.")
model = NativeDDP(model,
device_ids=[args.local_rank],
broadcast_buffers=not args.no_ddp_bb)
# NOTE: EMA model does not need to be wrapped by DDP
# setup learning rate schedule and starting epoch
lr_scheduler, num_epochs = create_scheduler(args, optimizer)
start_epoch = 0
if args.start_epoch is not None:
# a specified start_epoch will always override the resume epoch
start_epoch = args.start_epoch
elif resume_epoch is not None:
start_epoch = resume_epoch
if lr_scheduler is not None and start_epoch > 0:
lr_scheduler.step(start_epoch)
if args.local_rank == 0:
_logger.info('Scheduled epochs: {}'.format(num_epochs))
# create the train and eval datasets
dataset_train = create_dataset(args.dataset,
root=args.data_dir,
split=args.train_split,
is_training=True,
class_map=args.class_map,
download=args.dataset_download,
batch_size=args.batch_size,
repeats=args.epoch_repeats)
dataset_eval = create_dataset(args.dataset,
root=args.data_dir,
split=args.val_split,
is_training=False,
class_map=args.class_map,
download=args.dataset_download,
batch_size=args.batch_size)
# setup mixup / cutmix
collate_fn = None
mixup_fn = None
mixup_active = args.mixup > 0 or args.cutmix > 0. or args.cutmix_minmax is not None
if mixup_active:
mixup_args = dict(mixup_alpha=args.mixup,
cutmix_alpha=args.cutmix,
cutmix_minmax=args.cutmix_minmax,
prob=args.mixup_prob,
switch_prob=args.mixup_switch_prob,
mode=args.mixup_mode,
label_smoothing=args.smoothing,
num_classes=args.num_classes)
if args.prefetcher:
assert not num_aug_splits # collate conflict (need to support deinterleaving in collate mixup)
collate_fn = FastCollateMixup(**mixup_args)
else:
mixup_fn = Mixup(**mixup_args)
# wrap dataset in AugMix helper
if num_aug_splits > 1:
dataset_train = AugMixDataset(dataset_train, num_splits=num_aug_splits)
# create data loaders w/ augmentation pipeiine
train_interpolation = args.train_interpolation
if args.no_aug or not train_interpolation:
train_interpolation = data_config['interpolation']
loader_train = create_loader(
dataset_train,
input_size=data_config['input_size'],
batch_size=args.batch_size,
is_training=True,
use_prefetcher=args.prefetcher,
no_aug=args.no_aug,
re_prob=args.reprob,
re_mode=args.remode,
re_count=args.recount,
re_split=args.resplit,
scale=args.scale,
ratio=args.ratio,
hflip=args.hflip,
vflip=args.vflip,
color_jitter=args.color_jitter,
auto_augment=args.aa,
num_aug_repeats=args.aug_repeats,
num_aug_splits=num_aug_splits,
interpolation=train_interpolation,
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
distributed=args.distributed,
collate_fn=collate_fn,
pin_memory=args.pin_mem,
use_multi_epochs_loader=args.use_multi_epochs_loader,
worker_seeding=args.worker_seeding,
)
loader_eval = create_loader(
dataset_eval,
input_size=data_config['input_size'],
batch_size=args.validation_batch_size or args.batch_size,
is_training=False,
use_prefetcher=args.prefetcher,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
distributed=args.distributed,
crop_pct=data_config['crop_pct'],
pin_memory=args.pin_mem,
)
# setup loss function
if args.jsd_loss:
assert num_aug_splits > 1 # JSD only valid with aug splits set
train_loss_fn = JsdCrossEntropy(num_splits=num_aug_splits,
smoothing=args.smoothing)
elif mixup_active:
# smoothing is handled with mixup target transform which outputs sparse, soft targets
if args.bce_loss:
train_loss_fn = BinaryCrossEntropy(
target_threshold=args.bce_target_thresh)
else:
train_loss_fn = SoftTargetCrossEntropy()
elif args.smoothing:
if args.bce_loss:
train_loss_fn = BinaryCrossEntropy(
smoothing=args.smoothing,
target_threshold=args.bce_target_thresh)
else:
train_loss_fn = LabelSmoothingCrossEntropy(
smoothing=args.smoothing)
else:
train_loss_fn = nn.CrossEntropyLoss()
train_loss_fn = train_loss_fn.cuda()
validate_loss_fn = nn.CrossEntropyLoss().cuda()
# setup checkpoint saver and eval metric tracking
eval_metric = args.eval_metric
best_metric = None
best_epoch = None
saver = None
output_dir = None
if args.rank == 0:
if args.experiment:
exp_name = args.experiment
else:
exp_name = '-'.join([
datetime.now().strftime("%Y%m%d-%H%M%S"),
safe_model_name(args.model),
str(data_config['input_size'][-1])
])
output_dir = get_outdir(
args.output if args.output else './output/train', exp_name)
decreasing = True if eval_metric == 'loss' else False
saver = CheckpointSaver(model=model,
optimizer=optimizer,
args=args,
model_ema=model_ema,
amp_scaler=loss_scaler,
checkpoint_dir=output_dir,
recovery_dir=output_dir,
decreasing=decreasing,
max_history=args.checkpoint_hist)
with open(os.path.join(output_dir, 'args.yaml'), 'w') as f:
f.write(args_text)
try:
for epoch in range(start_epoch, num_epochs):
if args.distributed and hasattr(loader_train.sampler, 'set_epoch'):
loader_train.sampler.set_epoch(epoch)
train_metrics = train_one_epoch(epoch,
model,
loader_train,
optimizer,
train_loss_fn,
args,
lr_scheduler=lr_scheduler,
saver=saver,
output_dir=output_dir,
amp_autocast=amp_autocast,
loss_scaler=loss_scaler,
model_ema=model_ema,
mixup_fn=mixup_fn,
model_KD=model_KD)
if args.distributed and args.dist_bn in ('broadcast', 'reduce'):
if args.local_rank == 0:
_logger.info(
"Distributing BatchNorm running means and vars")
distribute_bn(model, args.world_size, args.dist_bn == 'reduce')
eval_metrics = validate(model,
loader_eval,
validate_loss_fn,
args,
amp_autocast=amp_autocast)
if model_ema is not None and not args.model_ema_force_cpu:
if args.distributed and args.dist_bn in ('broadcast',
'reduce'):
distribute_bn(model_ema, args.world_size,
args.dist_bn == 'reduce')
ema_eval_metrics = validate(model_ema.module,
loader_eval,
validate_loss_fn,
args,
amp_autocast=amp_autocast,
log_suffix=' (EMA)')
eval_metrics = ema_eval_metrics
if lr_scheduler is not None:
# step LR for next epoch
lr_scheduler.step(epoch + 1, eval_metrics[eval_metric])
if output_dir is not None:
update_summary(epoch,
train_metrics,
eval_metrics,
os.path.join(output_dir, 'summary.csv'),
write_header=best_metric is None,
log_wandb=args.log_wandb and has_wandb)
if saver is not None:
# save proper checkpoint with eval metric
save_metric = eval_metrics[eval_metric]
best_metric, best_epoch = saver.save_checkpoint(
epoch, metric=save_metric)
except KeyboardInterrupt:
pass
if best_metric is not None:
_logger.info('*** Best metric: {0} (epoch {1})'.format(
best_metric, best_epoch))
def validate(args):
# might as well try to validate something
args.pretrained = args.pretrained or not args.checkpoint
args.prefetcher = not args.no_prefetcher
amp_autocast = suppress # do nothing
if args.amp:
if has_apex:
args.apex_amp = True
elif has_native_amp:
args.native_amp = True
else:
_logger.warning(
"Neither APEX or Native Torch AMP is available, using FP32.")
assert not args.apex_amp or not args.native_amp, "Only one AMP mode should be set."
if args.native_amp:
amp_autocast = torch.cuda.amp.autocast
if args.legacy_jit:
set_jit_legacy()
# create model
model = create_model(args.model,
pretrained=args.pretrained,
num_classes=args.num_classes,
in_chans=3,
global_pool=args.gp,
scriptable=args.torchscript)
if args.num_classes is None:
assert hasattr(
model, 'num_classes'
), 'Model must have `num_classes` attr if not set on cmd line/config.'
args.num_classes = model.num_classes
if args.checkpoint:
load_checkpoint(model, args.checkpoint, args.use_ema)
param_count = sum([m.numel() for m in model.parameters()])
_logger.info('Model %s created, param count: %d' %
(args.model, param_count))
data_config = resolve_data_config(vars(args), model=model)
model, test_time_pool = (
model, False) if args.no_test_pool else apply_test_time_pool(
model, data_config)
if args.torchscript:
torch.jit.optimized_execution(True)
model = torch.jit.script(model)
model = model.cuda()
if args.apex_amp:
model = amp.initialize(model, opt_level='O1')
if args.channels_last:
model = model.to(memory_format=torch.channels_last)
if args.num_gpu > 1:
model = torch.nn.DataParallel(model,
device_ids=list(range(args.num_gpu)))
criterion = nn.CrossEntropyLoss().cuda()
dataset = create_dataset(root=args.data,
name=args.dataset,
split=args.split,
load_bytes=args.tf_preprocessing,
class_map=args.class_map)
if args.valid_labels:
with open(args.valid_labels, 'r') as f:
valid_labels = {int(line.rstrip()) for line in f}
valid_labels = [i in valid_labels for i in range(args.num_classes)]
else:
valid_labels = None
if args.real_labels:
real_labels = RealLabelsImagenet(dataset.filenames(basename=True),
real_json=args.real_labels)
else:
real_labels = None
crop_pct = 1.0 if test_time_pool else data_config['crop_pct']
loader = create_loader(dataset,
input_size=data_config['input_size'],
batch_size=args.batch_size,
use_prefetcher=args.prefetcher,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
crop_pct=crop_pct,
pin_memory=args.pin_mem,
tf_preprocessing=args.tf_preprocessing)
batch_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
model.eval()
with torch.no_grad():
# warmup, reduce variability of first batch time, especially for comparing torchscript vs non
input = torch.randn((args.batch_size, ) +
data_config['input_size']).cuda()
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
model(input)
end = time.time()
for batch_idx, (input, target) in enumerate(loader):
if args.no_prefetcher:
target = target.cuda()
input = input.cuda()
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
# compute output
with amp_autocast():
output = model(input)
if valid_labels is not None:
output = output[:, valid_labels]
loss = criterion(output, target)
if real_labels is not None:
real_labels.add_result(output)
# measure accuracy and record loss
acc1, acc5 = accuracy(output.detach(), target, topk=(1, 5))
losses.update(loss.item(), input.size(0))
top1.update(acc1.item(), input.size(0))
top5.update(acc5.item(), input.size(0))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if batch_idx % args.log_freq == 0:
_logger.info(
'Test: [{0:>4d}/{1}] '
'Time: {batch_time.val:.3f}s ({batch_time.avg:.3f}s, {rate_avg:>7.2f}/s) '
'Loss: {loss.val:>7.4f} ({loss.avg:>6.4f}) '
'Acc@1: {top1.val:>7.3f} ({top1.avg:>7.3f}) '
'Acc@5: {top5.val:>7.3f} ({top5.avg:>7.3f})'.format(
batch_idx,
len(loader),
batch_time=batch_time,
rate_avg=input.size(0) / batch_time.avg,
loss=losses,
top1=top1,
top5=top5))
if real_labels is not None:
# real labels mode replaces topk values at the end
top1a, top5a = real_labels.get_accuracy(k=1), real_labels.get_accuracy(
k=5)
else:
top1a, top5a = top1.avg, top5.avg
results = OrderedDict(top1=round(top1a, 4),
top1_err=round(100 - top1a, 4),
top5=round(top5a, 4),
top5_err=round(100 - top5a, 4),
param_count=round(param_count / 1e6, 2),
img_size=data_config['input_size'][-1],
cropt_pct=crop_pct,
interpolation=data_config['interpolation'])
_logger.info(' * Acc@1 {:.3f} ({:.3f}) Acc@5 {:.3f} ({:.3f})'.format(
results['top1'], results['top1_err'], results['top5'],
results['top5_err']))
return results
def validate(args):
_logger.info(f'\n\n ---------------EVALUATION {args.eps}------------------------------- \n\n')
_logger.info("Argument parser collected the following arguments:")
for arg in vars(args):
_logger.info(f" {arg}:{getattr(args, arg)}")
_logger.info("\n")
# might as well try to validate something
args.pretrained = args.pretrained or not args.checkpoint
args.prefetcher = not args.no_prefetcher
amp_autocast = suppress # do nothing
if args.amp:
if has_native_amp:
args.native_amp = True
elif has_apex:
args.apex_amp = True
else:
_logger.warning("Neither APEX or Native Torch AMP is available.")
assert not args.apex_amp or not args.native_amp, "Only one AMP mode should be set."
if args.native_amp:
amp_autocast = torch.cuda.amp.autocast
_logger.info('Validating in mixed precision with native PyTorch AMP.')
elif args.apex_amp:
_logger.info('Validating in mixed precision with NVIDIA APEX AMP.')
else:
_logger.info('Validating in float32. AMP not enabled.')
if args.legacy_jit:
set_jit_legacy()
# create model
model = create_model(
args.model,
pretrained=args.pretrained,
num_classes=args.num_classes,
in_chans=3,
global_pool=args.gp,
scriptable=args.torchscript)
if args.num_classes is None:
assert hasattr(model, 'num_classes'), 'Model must have `num_classes` attr if not set on cmd line/config.'
args.num_classes = model.num_classes
if args.checkpoint:
load_checkpoint(model, args.checkpoint, args.use_ema)
param_count = sum([m.numel() for m in model.parameters()])
_logger.info(
f'Model {args.model} created, param count: {param_count} ({(float(param_count)/(10.0**6)):.1f} M)'
)
data_config = resolve_data_config(vars(args), model=model, use_test_size=True, verbose=True)
test_time_pool = False
if not args.no_test_pool:
model, test_time_pool = apply_test_time_pool(model, data_config, use_test_size=True)
if args.torchscript:
torch.jit.optimized_execution(True)
model = torch.jit.script(model)
model = model.cuda()
if args.apex_amp:
model = amp.initialize(model, opt_level='O1')
if args.channels_last:
model = model.to(memory_format=torch.channels_last)
if args.num_gpu > 1:
model = torch.nn.DataParallel(model, device_ids=list(range(args.num_gpu)))
criterion = nn.CrossEntropyLoss().cuda()
dataset = create_dataset(
root=args.data_dir, name=args.dataset, split=args.split,
load_bytes=args.tf_preprocessing, class_map=args.class_map)
if args.valid_labels:
with open(args.valid_labels, 'r') as f:
valid_labels = {int(line.rstrip()) for line in f}
valid_labels = [i in valid_labels for i in range(args.num_classes)]
else:
valid_labels = None
if args.real_labels:
real_labels = RealLabelsImagenet(dataset.filenames(basename=True), real_json=args.real_labels)
else:
real_labels = None
crop_pct = 1.0 if test_time_pool else data_config['crop_pct']
loader = create_loader(
dataset,
input_size=data_config['input_size'],
batch_size=args.batch_size,
use_prefetcher=args.prefetcher,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
crop_pct=crop_pct,
pin_memory=args.pin_mem,
tf_preprocessing=args.tf_preprocessing)
batch_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
top1_fgm_ae = AverageMeter()
top5_fgm_ae = AverageMeter()
top1_pgd_ae = AverageMeter()
top5_pgd_ae = AverageMeter()
model.eval()
#with torch.no_grad():# TODO Requires grad
# warmup, reduce variability of first batch time, especially for comparing torchscript vs non
input = torch.randn((args.batch_size,) + tuple(data_config['input_size'])).cuda()
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
model(input)
end = time.time()
for batch_idx, (input, target) in enumerate(loader):
if args.no_prefetcher:
target = target.cuda()
input = input.cuda()
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
# compute output
with amp_autocast():
output = model(input)
if valid_labels is not None:
output = output[:, valid_labels]
loss = criterion(output, target)
if real_labels is not None:
real_labels.add_result(output)
# TODO <---------------------
# Generate adversarial examples for current inputs
input_fgm_ae = fast_gradient_method(
model_fn=model,
x=input,
eps=args.eps,
norm=np.inf,
clip_min=None,
clip_max=None,
)
input_pgd_ae = projected_gradient_descent(
model_fn=model,
x=input,
eps=args.eps,
eps_iter=0.01,
nb_iter=40,
norm=np.inf,
clip_min=None,
clip_max=None,
)
# Predict with Adversarial Examples
with torch.no_grad():
with amp_autocast():
output_fgm_ae = model(input_fgm_ae)
output_pgd_ae = model(input_pgd_ae)
# measure accuracy and record loss
acc1, acc5 = accuracy(output.detach(), target, topk=(1, 5))
losses.update(loss.item(), input.size(0))
top1.update(acc1.item(), input.size(0))
top5.update(acc5.item(), input.size(0))
acc1_fgm_ae, acc5_fgm_ae = accuracy(output_fgm_ae.detach(), target, topk=(1, 5))
acc1_pgd_ae, acc5_pgd_ae = accuracy(output_pgd_ae.detach(), target, topk=(1, 5))
top1_fgm_ae.update(acc1_fgm_ae.item(), input.size(0))
top5_fgm_ae.update(acc5_fgm_ae.item(), input.size(0))
top1_pgd_ae.update(acc1_pgd_ae.item(), input.size(0))
top5_pgd_ae.update(acc5_pgd_ae.item(), input.size(0))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if batch_idx % args.log_freq == 0:
_logger.info(
'Test: [{0:>4d}/{1}] '
'Time: {batch_time.val:.3f}s ({batch_time.avg:.3f}s, {rate_avg:>7.2f}/s) '
'Loss: {loss.val:>7.4f} ({loss.avg:>6.4f}) '
'Acc@1: {top1.val:>7.3f} ({top1.avg:>7.3f}) '
'Acc@5: {top5.val:>7.3f} ({top5.avg:>7.3f})'.format(
batch_idx, len(loader), batch_time=batch_time,
rate_avg=input.size(0) / batch_time.avg,
loss=losses, top1=top1, top5=top5))
if real_labels is not None:
raise NotImplementedError # TODO NOt modified for the adversarial examples mode
# real labels mode replaces topk values at the end
top1a, top5a = real_labels.get_accuracy(k=1), real_labels.get_accuracy(k=5)
else:
top1a, top5a = top1.avg, top5.avg
top1a_fgm_ae, top5a_fgm_ae = top1_fgm_ae.avg, top5_fgm_ae.avg
top1a_pgd_ae, top5a_pgd_ae = top1_pgd_ae.avg, top5_pgd_ae.avg
results = OrderedDict(
top1=round(top1a, 4), top1_err=round(100 - top1a, 4),
top5=round(top5a, 4), top5_err=round(100 - top5a, 4),
top1_fgm_ae=round(top1a_fgm_ae, 4),
top5_fgm_ae=round(top5a_fgm_ae, 4),
top1_pgd_ae=round(top1a_pgd_ae, 4),
top5_pgd_ae=round(top5a_pgd_ae, 4),
param_count=round(param_count / 1e6, 2),
img_size=data_config['input_size'][-1],
cropt_pct=crop_pct,
interpolation=data_config['interpolation'])
_logger.info(' * [Regular] Acc@1 {:.3f} ({:.3f}) Acc@5 {:.3f} ({:.3f})'.format(
results['top1'], results['top1_err'], results['top5'], results['top5_err']))
_logger.info(' * [FGM Adversarial Attack] Acc@1 {:.3f} Acc@5 {:.3f} '.format(
results['top1_fgm_ae'], results['top5_fgm_ae']))
_logger.info(' * [PGD Adversarial Attack] Acc@1 {:.3f} Acc@5 {:.3f} '.format(
results['top1_pgd_ae'], results['top5_pgd_ae']))
return results
def main():
setup_default_logging()
args, args_text = _parse_args()
args.prefetcher = not args.no_prefetcher
args.distributed = False
if 'WORLD_SIZE' in os.environ:
args.distributed = int(os.environ['WORLD_SIZE']) > 1
args.device = 'cuda:0'
args.world_size = 1
args.rank = 0 # global rank
if args.distributed:
args.device = 'cuda:%d' % args.local_rank
torch.cuda.set_device(args.local_rank)
torch.distributed.init_process_group(backend='nccl', init_method='env://')
args.world_size = torch.distributed.get_world_size()
args.rank = torch.distributed.get_rank()
_logger.info('Training in distributed mode with multiple processes, 1 GPU per process. Process %d, total %d.'
% (args.rank, args.world_size))
else:
_logger.info('Training with a single process on 1 GPUs.')
assert args.rank >= 0
# resolve AMP arguments based on PyTorch / Apex availability
use_amp = None
if args.amp:
# for backwards compat, `--amp` arg tries apex before native amp
if has_apex:
args.apex_amp = True
elif has_native_amp:
args.native_amp = True
if args.apex_amp and has_apex:
use_amp = 'apex'
elif args.native_amp and has_native_amp:
use_amp = 'native'
elif args.apex_amp or args.native_amp:
_logger.warning("Neither APEX or native Torch AMP is available, using float32. "
"Install NVIDA apex or upgrade to PyTorch 1.6")
torch.manual_seed(args.seed + args.rank)
####################################################################################
# Start - SparseML optional load weights from SparseZoo
####################################################################################
if args.initial_checkpoint == "zoo":
# Load checkpoint from base weights associated with given SparseZoo recipe
if args.sparseml_recipe.startswith("zoo:"):
args.initial_checkpoint = Zoo.download_recipe_base_framework_files(
args.sparseml_recipe,
extensions=[".pth.tar", ".pth"]
)[0]
else:
raise ValueError(
"Attempting to load weights from SparseZoo recipe, but not given a "
"SparseZoo recipe stub. When initial-checkpoint is set to 'zoo'. "
"sparseml-recipe must start with 'zoo:' and be a SparseZoo model "
f"stub. sparseml-recipe was set to {args.sparseml_recipe}"
)
elif args.initial_checkpoint.startswith("zoo:"):
# Load weights from a SparseZoo model stub
zoo_model = Zoo.load_model_from_stub(args.initial_checkpoint)
args.initial_checkpoint = zoo_model.download_framework_files(extensions=[".pth"])
####################################################################################
# End - SparseML optional load weights from SparseZoo
####################################################################################
model = create_model(
args.model,
pretrained=args.pretrained,
num_classes=args.num_classes,
drop_rate=args.drop,
drop_connect_rate=args.drop_connect, # DEPRECATED, use drop_path
drop_path_rate=args.drop_path,
drop_block_rate=args.drop_block,
global_pool=args.gp,
bn_tf=args.bn_tf,
bn_momentum=args.bn_momentum,
bn_eps=args.bn_eps,
scriptable=args.torchscript,
checkpoint_path=args.initial_checkpoint)
if args.num_classes is None:
assert hasattr(model, 'num_classes'), 'Model must have `num_classes` attr if not set on cmd line/config.'
args.num_classes = model.num_classes # FIXME handle model default vs config num_classes more elegantly
if args.local_rank == 0:
_logger.info('Model %s created, param count: %d' %
(args.model, sum([m.numel() for m in model.parameters()])))
data_config = resolve_data_config(vars(args), model=model, verbose=args.local_rank == 0)
# setup augmentation batch splits for contrastive loss or split bn
num_aug_splits = 0
if args.aug_splits > 0:
assert args.aug_splits > 1, 'A split of 1 makes no sense'
num_aug_splits = args.aug_splits
# enable split bn (separate bn stats per batch-portion)
if args.split_bn:
assert num_aug_splits > 1 or args.resplit
model = convert_splitbn_model(model, max(num_aug_splits, 2))
# move model to GPU, enable channels last layout if set
model.cuda()
if args.channels_last:
model = model.to(memory_format=torch.channels_last)
# setup synchronized BatchNorm for distributed training
if args.distributed and args.sync_bn:
assert not args.split_bn
if has_apex and use_amp != 'native':
# Apex SyncBN preferred unless native amp is activated
model = convert_syncbn_model(model)
else:
model = torch.nn.SyncBatchNorm.convert_sync_batchnorm(model)
if args.local_rank == 0:
_logger.info(
'Converted model to use Synchronized BatchNorm. WARNING: You may have issues if using '
'zero initialized BN layers (enabled by default for ResNets) while sync-bn enabled.')
if args.torchscript:
assert not use_amp == 'apex', 'Cannot use APEX AMP with torchscripted model'
assert not args.sync_bn, 'Cannot use SyncBatchNorm with torchscripted model'
model = torch.jit.script(model)
optimizer = create_optimizer(args, model)
# setup automatic mixed-precision (AMP) loss scaling and op casting
amp_autocast = suppress # do nothing
loss_scaler = None
if use_amp == 'apex':
model, optimizer = amp.initialize(model, optimizer, opt_level='O1')
loss_scaler = ApexScaler()
if args.local_rank == 0:
_logger.info('Using NVIDIA APEX AMP. Training in mixed precision.')
elif use_amp == 'native':
amp_autocast = torch.cuda.amp.autocast
loss_scaler = NativeScaler()
if args.local_rank == 0:
_logger.info('Using native Torch AMP. Training in mixed precision.')
else:
if args.local_rank == 0:
_logger.info('AMP not enabled. Training in float32.')
# optionally resume from a checkpoint
resume_epoch = None
if args.resume:
resume_epoch = resume_checkpoint(
model, args.resume,
optimizer=None if args.no_resume_opt else optimizer,
loss_scaler=None if args.no_resume_opt else loss_scaler,
log_info=args.local_rank == 0)
# setup exponential moving average of model weights, SWA could be used here too
model_ema = None
if args.model_ema:
# Important to create EMA model after cuda(), DP wrapper, and AMP but before SyncBN and DDP wrapper
model_ema = ModelEmaV2(
model, decay=args.model_ema_decay, device='cpu' if args.model_ema_force_cpu else None)
if args.resume:
load_checkpoint(model_ema.module, args.resume, use_ema=True)
# setup distributed training
if args.distributed:
if has_apex and use_amp != 'native':
# Apex DDP preferred unless native amp is activated
if args.local_rank == 0:
_logger.info("Using NVIDIA APEX DistributedDataParallel.")
model = ApexDDP(model, delay_allreduce=True)
else:
if args.local_rank == 0:
_logger.info("Using native Torch DistributedDataParallel.")
model = NativeDDP(model, device_ids=[args.local_rank]) # can use device str in Torch >= 1.1
# NOTE: EMA model does not need to be wrapped by DDP
# setup learning rate schedule and starting epoch
lr_scheduler, num_epochs = create_scheduler(args, optimizer)
start_epoch = 0
if args.start_epoch is not None:
# a specified start_epoch will always override the resume epoch
start_epoch = args.start_epoch
elif resume_epoch is not None:
start_epoch = resume_epoch
if lr_scheduler is not None and start_epoch > 0:
lr_scheduler.step(start_epoch)
# create the train and eval datasets
dataset_train = create_dataset(
args.dataset, root=args.data_dir, split=args.train_split, is_training=True, batch_size=args.batch_size)
dataset_eval = create_dataset(
args.dataset, root=args.data_dir, split=args.val_split, is_training=False, batch_size=args.batch_size)
# setup mixup / cutmix
collate_fn = None
mixup_fn = None
mixup_active = args.mixup > 0 or args.cutmix > 0. or args.cutmix_minmax is not None
if mixup_active:
mixup_args = dict(
mixup_alpha=args.mixup, cutmix_alpha=args.cutmix, cutmix_minmax=args.cutmix_minmax,
prob=args.mixup_prob, switch_prob=args.mixup_switch_prob, mode=args.mixup_mode,
label_smoothing=args.smoothing, num_classes=args.num_classes)
if args.prefetcher:
assert not num_aug_splits # collate conflict (need to support deinterleaving in collate mixup)
collate_fn = FastCollateMixup(**mixup_args)
else:
mixup_fn = Mixup(**mixup_args)
# wrap dataset in AugMix helper
if num_aug_splits > 1:
dataset_train = AugMixDataset(dataset_train, num_splits=num_aug_splits)
# create data loaders w/ augmentation pipeiine
train_interpolation = args.train_interpolation
if args.no_aug or not train_interpolation:
train_interpolation = data_config['interpolation']
loader_train = create_loader(
dataset_train,
input_size=data_config['input_size'],
batch_size=args.batch_size,
is_training=True,
use_prefetcher=args.prefetcher,
no_aug=args.no_aug,
re_prob=args.reprob,
re_mode=args.remode,
re_count=args.recount,
re_split=args.resplit,
scale=args.scale,
ratio=args.ratio,
hflip=args.hflip,
vflip=args.vflip,
color_jitter=args.color_jitter,
auto_augment=args.aa,
num_aug_splits=num_aug_splits,
interpolation=train_interpolation,
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
distributed=args.distributed,
collate_fn=collate_fn,
pin_memory=args.pin_mem,
use_multi_epochs_loader=args.use_multi_epochs_loader
)
loader_eval = create_loader(
dataset_eval,
input_size=data_config['input_size'],
batch_size=args.validation_batch_size_multiplier * args.batch_size,
is_training=False,
use_prefetcher=args.prefetcher,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
distributed=args.distributed,
crop_pct=data_config['crop_pct'],
pin_memory=args.pin_mem,
)
# setup loss function
if args.jsd:
assert num_aug_splits > 1 # JSD only valid with aug splits set
train_loss_fn = JsdCrossEntropy(num_splits=num_aug_splits, smoothing=args.smoothing).cuda()
elif mixup_active:
# smoothing is handled with mixup target transform
train_loss_fn = SoftTargetCrossEntropy().cuda()
elif args.smoothing:
train_loss_fn = LabelSmoothingCrossEntropy(smoothing=args.smoothing).cuda()
else:
train_loss_fn = nn.CrossEntropyLoss().cuda()
validate_loss_fn = nn.CrossEntropyLoss().cuda()
# setup checkpoint saver and eval metric tracking
eval_metric = args.eval_metric
best_metric = None
best_epoch = None
saver = None
output_dir = ''
if args.local_rank == 0:
output_base = args.output if args.output else './output'
exp_name = '-'.join([
datetime.now().strftime("%Y%m%d-%H%M%S"),
args.model,
str(data_config['input_size'][-1])
])
output_dir = get_outdir(output_base, 'train', exp_name)
decreasing = True if eval_metric == 'loss' else False
saver = CheckpointSaver(
model=model, optimizer=optimizer, args=args, model_ema=model_ema, amp_scaler=loss_scaler,
checkpoint_dir=output_dir, recovery_dir=output_dir, decreasing=decreasing, max_history=args.checkpoint_hist)
with open(os.path.join(output_dir, 'args.yaml'), 'w') as f:
f.write(args_text)
####################################################################################
# Start SparseML Integration
####################################################################################
sparseml_loggers = (
[PythonLogger(), TensorBoardLogger(log_path=output_dir)]
if output_dir
else None
)
manager = ScheduledModifierManager.from_yaml(args.sparseml_recipe)
optimizer = ScheduledOptimizer(
optimizer,
model,
manager,
steps_per_epoch=len(loader_train),
loggers=sparseml_loggers
)
# override lr scheduler if recipe makes any LR updates
if any("LearningRate" in str(modifier) for modifier in manager.modifiers):
_logger.info("Disabling timm LR scheduler, managing LR using SparseML recipe")
lr_scheduler = None
if manager.max_epochs:
_logger.info(
f"Overriding max_epochs to {manager.max_epochs} from SparseML recipe"
)
num_epochs = manager.max_epochs or num_epochs
####################################################################################
# End SparseML Integration
####################################################################################
if args.local_rank == 0:
_logger.info('Scheduled epochs: {}'.format(num_epochs))
try:
for epoch in range(start_epoch, num_epochs):
if args.distributed and hasattr(loader_train.sampler, 'set_epoch'):
loader_train.sampler.set_epoch(epoch)
train_metrics = train_one_epoch(
epoch, model, loader_train, optimizer, train_loss_fn, args,
lr_scheduler=lr_scheduler, saver=saver, output_dir=output_dir,
amp_autocast=amp_autocast, loss_scaler=loss_scaler, model_ema=model_ema, mixup_fn=mixup_fn)
if args.distributed and args.dist_bn in ('broadcast', 'reduce'):
if args.local_rank == 0:
_logger.info("Distributing BatchNorm running means and vars")
distribute_bn(model, args.world_size, args.dist_bn == 'reduce')
eval_metrics = validate(model, loader_eval, validate_loss_fn, args, amp_autocast=amp_autocast)
if model_ema is not None and not args.model_ema_force_cpu:
if args.distributed and args.dist_bn in ('broadcast', 'reduce'):
distribute_bn(model_ema, args.world_size, args.dist_bn == 'reduce')
ema_eval_metrics = validate(
model_ema.module, loader_eval, validate_loss_fn, args, amp_autocast=amp_autocast, log_suffix=' (EMA)')
eval_metrics = ema_eval_metrics
if lr_scheduler is not None:
# step LR for next epoch
lr_scheduler.step(epoch + 1, eval_metrics[eval_metric])
update_summary(
epoch, train_metrics, eval_metrics, os.path.join(output_dir, 'summary.csv'),
write_header=best_metric is None)
if saver is not None:
# save proper checkpoint with eval metric
save_metric = eval_metrics[eval_metric]
best_metric, best_epoch = saver.save_checkpoint(epoch, metric=save_metric)
#################################################################################
# Start SparseML ONNX Export
#################################################################################
if output_dir:
_logger.info(
f"training complete, exporting ONNX to {output_dir}/model.onnx"
)
exporter = ModuleExporter(model, output_dir)
exporter.export_onnx(torch.randn((1, *data_config["input_size"])))
#################################################################################
# End SparseML ONNX Export
#################################################################################
except KeyboardInterrupt:
pass
if best_metric is not None:
_logger.info('*** Best metric: {0} (epoch {1})'.format(best_metric, best_epoch))
def validate(args):
# might as well try to validate something
args.pretrained = args.pretrained or not args.checkpoint
args.prefetcher = not args.no_prefetcher
# amp_autocast = suppress # do nothing
# if args.amp:
# if has_native_amp:
# args.native_amp = True
# elif has_apex:
# args.apex_amp = True
# else:
# _logger.warning("Neither APEX or Native Torch AMP is available.")
# assert not args.apex_amp or not args.native_amp, "Only one AMP mode should be set."
# if args.native_amp:
# amp_autocast = torch.cuda.amp.autocast
# _logger.info('Validating in mixed precision with native PyTorch AMP.')
# elif args.apex_amp:
# _logger.info('Validating in mixed precision with NVIDIA APEX AMP.')
# else:
# _logger.info('Validating in float32. AMP not enabled.')
if args.legacy_jit:
set_jit_legacy()
# create model
model = create_model(
args.model,
pretrained=args.pretrained,
num_classes=args.num_classes,
in_chans=3,
global_pool=args.gp,
scriptable=args.torchscript)
if args.num_classes is None:
assert hasattr(model, 'num_classes'), 'Model must have `num_classes` attr if not set on cmd line/config.'
args.num_classes = model.num_classes
if args.checkpoint:
load_checkpoint(model, args.checkpoint, args.use_ema)
param_count = sum([m.numel() for m in model.parameters()])
_logger.info('Model %s created, param count: %d' % (args.model, param_count))
data_config = resolve_data_config(vars(args), model=model, use_test_size=True)
test_time_pool = False
if not args.no_test_pool:
model, test_time_pool = apply_test_time_pool(model, data_config, use_test_size=True)
if args.torchscript:
torch.jit.optimized_execution(True)
model = torch.jit.script(model)
# model = model.cuda()
# if args.apex_amp:
# model = amp.initialize(model, opt_level='O1')
if args.channels_last:
model = model.to(memory_format=torch.channels_last)
# if args.num_gpu > 1:
# model = torch.nn.DataParallel(model, device_ids=list(range(args.num_gpu)))
# criterion = nn.CrossEntropyLoss().cuda()
criterion = nn.CrossEntropyLoss()
dataset = create_dataset(
root=args.data, name=args.dataset, split=args.split,
load_bytes=args.tf_preprocessing, class_map=args.class_map)
# added for post quantization calibration
calib_dataset = create_dataset(
root=args.data, name=args.dataset, split=args.split,
load_bytes=args.tf_preprocessing, class_map=args.class_map)
if args.valid_labels:
with open(args.valid_labels, 'r') as f:
valid_labels = {int(line.rstrip()) for line in f}
valid_labels = [i in valid_labels for i in range(args.num_classes)]
else:
valid_labels = None
if args.real_labels:
real_labels = RealLabelsImagenet(dataset.filenames(basename=True), real_json=args.real_labels)
else:
real_labels = None
crop_pct = 1.0 if test_time_pool else data_config['crop_pct']
loader = create_loader(
dataset,
input_size=data_config['input_size'],
batch_size=args.batch_size,
use_prefetcher=args.prefetcher,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
crop_pct=crop_pct,
pin_memory=args.pin_mem,
tf_preprocessing=args.tf_preprocessing)
#Also create loader for calibration dataset
calib_loader = create_loader(
calib_dataset,
input_size=data_config['input_size'],
batch_size=args.batch_size,
use_prefetcher=args.prefetcher,
interpolation=data_config['interpolation'],
mean=data_config['mean'],
std=data_config['std'],
num_workers=args.workers,
crop_pct=crop_pct,
pin_memory=args.pin_mem,
tf_preprocessing=args.tf_preprocessing)
batch_time = AverageMeter()
losses = AverageMeter()
top1 = AverageMeter()
top5 = AverageMeter()
print('Start calibration of quantization observers before post-quantization')
model_to_quantize = copy.deepcopy(model)
model_to_quantize.eval()
#post training static quantization
if args.quant_option == 'static':
qconfig_dict = {"": torch.quantization.default_static_qconfig}
model_to_quantize = copy.deepcopy(model_fp)
qconfig_dict = {"": torch.quantization.get_default_qconfig('qnnpack')}
model_to_quantize.eval()
# prepare
model_prepared = quantize_fx.prepare_fx(model_to_quantize, qconfig_dict)
# calibrate
with torch.no_grad():
# warmup, reduce variability of first batch time, especially for comparing torchscript vs non
input = torch.randn((args.batch_size,) + tuple(data_config['input_size']))
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
model(input)
end = time.time()
for batch_idx, (input, target) in enumerate(loader):
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
if valid_labels is not None:
output = output[:, valid_labels]
loss = criterion(output, target)
if real_labels is not None:
real_labels.add_result(output)
# measure accuracy and record loss
acc1, acc5 = accuracy(output.detach(), target, topk=(1, 5))
losses.update(loss.item(), input.size(0))
top1.update(acc1.item(), input.size(0))
top5.update(acc5.item(), input.size(0))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if batch_idx % args.log_freq == 0:
_logger.info(
'Test: [{0:>4d}/{1}] '
'Time: {batch_time.val:.3f}s ({batch_time.avg:.3f}s, {rate_avg:>7.2f}/s) '
'Loss: {loss.val:>7.4f} ({loss.avg:>6.4f}) '
'Acc@1: {top1.val:>7.3f} ({top1.avg:>7.3f}) '
'Acc@5: {top5.val:>7.3f} ({top5.avg:>7.3f})'.format(
batch_idx, len(loader), batch_time=batch_time,
rate_avg=input.size(0) / batch_time.avg,
loss=losses, top1=top1, top5=top5))
# quantize
model_quantized = quantize_fx.convert_fx(model_prepared)
#post training dynamic/weight only quantization
elif args.quant_option == 'dynamic':
qconfig_dict = {"": torch.quantization.default_dynamic_qconfig}
# prepare
model_prepared = quantize_fx.prepare_fx(model_to_quantize, qconfig_dict)
# no calibration needed when we only have dynamici/weight_only quantization
# quantize
model_quantized = quantize_fx.convert_fx(model_prepared)
else:
_logger.warning("Invalid quantization option. Set option to default(static)")
#
# fusion
#
model_to_quantize = copy.deepcopy(model_fp)
model_fused = quantize_fx.fuse_fx(model_to_quantize)
model = model_fused
with torch.no_grad():
# warmup, reduce variability of first batch time, especially for comparing torchscript vs non
# input = torch.randn((args.batch_size,) + tuple(data_config['input_size'])).cuda()
input = torch.randn((args.batch_size,) + tuple(data_config['input_size']))
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
model(input)
end = time.time()
for batch_idx, (input, target) in enumerate(loader):
# if args.no_prefetcher:
# target = target.cuda()
# input = input.cuda()
if args.channels_last:
input = input.contiguous(memory_format=torch.channels_last)
# compute output
# with amp_autocast():
# output = model(input)
if valid_labels is not None:
output = output[:, valid_labels]
loss = criterion(output, target)
if real_labels is not None:
real_labels.add_result(output)
# measure accuracy and record loss
acc1, acc5 = accuracy(output.detach(), target, topk=(1, 5))
losses.update(loss.item(), input.size(0))
top1.update(acc1.item(), input.size(0))
top5.update(acc5.item(), input.size(0))
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if batch_idx % args.log_freq == 0:
_logger.info(
'Test: [{0:>4d}/{1}] '
'Time: {batch_time.val:.3f}s ({batch_time.avg:.3f}s, {rate_avg:>7.2f}/s) '
'Loss: {loss.val:>7.4f} ({loss.avg:>6.4f}) '
'Acc@1: {top1.val:>7.3f} ({top1.avg:>7.3f}) '
'Acc@5: {top5.val:>7.3f} ({top5.avg:>7.3f})'.format(
batch_idx, len(loader), batch_time=batch_time,
rate_avg=input.size(0) / batch_time.avg,
loss=losses, top1=top1, top5=top5))
if real_labels is not None:
# real labels mode replaces topk values at the end
top1a, top5a = real_labels.get_accuracy(k=1), real_labels.get_accuracy(k=5)
else:
top1a, top5a = top1.avg, top5.avg
results = OrderedDict(
top1=round(top1a, 4), top1_err=round(100 - top1a, 4),
top5=round(top5a, 4), top5_err=round(100 - top5a, 4),
param_count=round(param_count / 1e6, 2),
img_size=data_config['input_size'][-1],
cropt_pct=crop_pct,
interpolation=data_config['interpolation'])
_logger.info(' * Acc@1 {:.3f} ({:.3f}) Acc@5 {:.3f} ({:.3f})'.format(
results['top1'], results['top1_err'], results['top5'], results['top5_err']))
return results
def data_creator(config):
# torch.manual_seed(args.seed + torch.distributed.get_rank())
args = config["args"]
train_dir = join(args.data_dir, "train")
val_dir = join(args.data_dir, "val")
if args.mock_data:
util.mock_data(train_dir, val_dir)
# todo: verbose should depend on rank
data_config = resolve_data_config(vars(args), verbose=True)
dataset_train = create_dataset(args.dataset,
root=args.data_dir,
split=args.train_split,
is_training=True,
batch_size=args.batch_size)
dataset_eval = create_dataset(args.dataset,
root=args.data_dir,
split=args.val_split,
is_training=False,
batch_size=args.batch_size)
collate_fn = None
if args.prefetcher and args.mixup > 0:
# collate conflict (need to support deinterleaving in collate mixup)
assert args.num_aug_splits == 0
collate_fn = FastCollateMixup(args.mixup, args.smoothing,
args.num_classes)
common_params = dict(input_size=data_config["input_size"],
use_prefetcher=args.prefetcher,
mean=data_config["mean"],
std=data_config["std"],
num_workers=1,
distributed=args.distributed,
pin_memory=args.pin_mem)
train_loader = create_loader(
dataset_train,
is_training=True,
batch_size=config[BATCH_SIZE],
re_prob=args.reprob,
re_mode=args.remode,
re_count=args.recount,
re_split=args.resplit,
collate_fn=collate_fn,
color_jitter=args.color_jitter,
auto_augment=args.aa,
interpolation=args.train_interpolation,
num_aug_splits=args.num_aug_splits, # always 0 right now
**common_params)
eval_loader = create_loader(
dataset_eval,
is_training=False,
batch_size=args.validation_batch_size_multiplier * config[BATCH_SIZE],
interpolation=data_config["interpolation"],
crop_pct=data_config["crop_pct"],
**common_params)
return train_loader, eval_loader
