def train_net(cfg):
# Enable the inbuilt cudnn auto-tuner to find the best algorithm to use
torch.backends.cudnn.benchmark = True
# Set up data augmentation
IMG_SIZE = cfg.CONST.IMG_H, cfg.CONST.IMG_W
CROP_SIZE = cfg.CONST.CROP_IMG_H, cfg.CONST.CROP_IMG_W
train_transforms = utils.data_transforms.Compose([
utils.data_transforms.RandomCrop(IMG_SIZE, CROP_SIZE),
utils.data_transforms.RandomBackground(
cfg.TRAIN.RANDOM_BG_COLOR_RANGE),
utils.data_transforms.ColorJitter(cfg.TRAIN.BRIGHTNESS,
cfg.TRAIN.CONTRAST,
cfg.TRAIN.SATURATION),
utils.data_transforms.RandomNoise(cfg.TRAIN.NOISE_STD),
utils.data_transforms.Normalize(mean=cfg.DATASET.MEAN,
std=cfg.DATASET.STD),
utils.data_transforms.RandomFlip(),
utils.data_transforms.RandomPermuteRGB(),
utils.data_transforms.ToTensor(),
])
val_transforms = utils.data_transforms.Compose([
utils.data_transforms.CenterCrop(IMG_SIZE, CROP_SIZE),
utils.data_transforms.RandomBackground(cfg.TEST.RANDOM_BG_COLOR_RANGE),
utils.data_transforms.Normalize(mean=cfg.DATASET.MEAN,
std=cfg.DATASET.STD),
utils.data_transforms.ToTensor(),
])
# Set up data loader
train_dataset_loader = utils.data_loaders.DATASET_LOADER_MAPPING[
cfg.DATASET.TRAIN_DATASET](cfg)
val_dataset_loader = utils.data_loaders.DATASET_LOADER_MAPPING[
cfg.DATASET.TEST_DATASET](cfg)
train_data_loader = torch.utils.data.DataLoader(
dataset=train_dataset_loader.get_dataset(
utils.data_loaders.DatasetType.TRAIN, cfg.CONST.N_VIEWS_RENDERING,
train_transforms),
batch_size=cfg.CONST.BATCH_SIZE,
num_workers=cfg.TRAIN.NUM_WORKER,
pin_memory=True,
shuffle=True,
drop_last=True)
val_data_loader = torch.utils.data.DataLoader(
dataset=val_dataset_loader.get_dataset(
utils.data_loaders.DatasetType.VAL, cfg.CONST.N_VIEWS_RENDERING,
val_transforms),
batch_size=1,
num_workers=1,
pin_memory=True,
shuffle=False)
# Set up networks
encoder = Encoder(cfg)
decoder = Decoder(cfg)
refiner = Refiner(cfg)
merger = Merger(cfg)
print('[DEBUG] %s Parameters in Encoder: %d.' %
(dt.now(), utils.network_utils.count_parameters(encoder)))
print('[DEBUG] %s Parameters in Decoder: %d.' %
(dt.now(), utils.network_utils.count_parameters(decoder)))
print('[DEBUG] %s Parameters in Refiner: %d.' %
(dt.now(), utils.network_utils.count_parameters(refiner)))
print('[DEBUG] %s Parameters in Merger: %d.' %
(dt.now(), utils.network_utils.count_parameters(merger)))
# Initialize weights of networks
encoder.apply(utils.network_utils.init_weights)
decoder.apply(utils.network_utils.init_weights)
refiner.apply(utils.network_utils.init_weights)
merger.apply(utils.network_utils.init_weights)
# Set up solver
if cfg.TRAIN.POLICY == 'adam':
encoder_solver = torch.optim.Adam(filter(lambda p: p.requires_grad,
encoder.parameters()),
lr=cfg.TRAIN.ENCODER_LEARNING_RATE,
betas=cfg.TRAIN.BETAS)
decoder_solver = torch.optim.Adam(decoder.parameters(),
lr=cfg.TRAIN.DECODER_LEARNING_RATE,
betas=cfg.TRAIN.BETAS)
refiner_solver = torch.optim.Adam(refiner.parameters(),
lr=cfg.TRAIN.REFINER_LEARNING_RATE,
betas=cfg.TRAIN.BETAS)
merger_solver = torch.optim.Adam(merger.parameters(),
lr=cfg.TRAIN.MERGER_LEARNING_RATE,
betas=cfg.TRAIN.BETAS)
elif cfg.TRAIN.POLICY == 'sgd':
encoder_solver = torch.optim.SGD(filter(lambda p: p.requires_grad,
encoder.parameters()),
lr=cfg.TRAIN.ENCODER_LEARNING_RATE,
momentum=cfg.TRAIN.MOMENTUM)
decoder_solver = torch.optim.SGD(decoder.parameters(),
lr=cfg.TRAIN.DECODER_LEARNING_RATE,
momentum=cfg.TRAIN.MOMENTUM)
refiner_solver = torch.optim.SGD(refiner.parameters(),
lr=cfg.TRAIN.REFINER_LEARNING_RATE,
momentum=cfg.TRAIN.MOMENTUM)
merger_solver = torch.optim.SGD(merger.parameters(),
lr=cfg.TRAIN.MERGER_LEARNING_RATE,
momentum=cfg.TRAIN.MOMENTUM)
else:
raise Exception('[FATAL] %s Unknown optimizer %s.' %
(dt.now(), cfg.TRAIN.POLICY))
# Set up learning rate scheduler to decay learning rates dynamically
encoder_lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(
encoder_solver,
milestones=cfg.TRAIN.ENCODER_LR_MILESTONES,
gamma=cfg.TRAIN.GAMMA)
decoder_lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(
decoder_solver,
milestones=cfg.TRAIN.DECODER_LR_MILESTONES,
gamma=cfg.TRAIN.GAMMA)
refiner_lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(
refiner_solver,
milestones=cfg.TRAIN.REFINER_LR_MILESTONES,
gamma=cfg.TRAIN.GAMMA)
merger_lr_scheduler = torch.optim.lr_scheduler.MultiStepLR(
merger_solver,
milestones=cfg.TRAIN.MERGER_LR_MILESTONES,
gamma=cfg.TRAIN.GAMMA)
if torch.cuda.is_available():
encoder = torch.nn.DataParallel(encoder).cuda()
decoder = torch.nn.DataParallel(decoder).cuda()
refiner = torch.nn.DataParallel(refiner).cuda()
merger = torch.nn.DataParallel(merger).cuda()
# Set up loss functions
bce_loss = torch.nn.BCELoss()
# Load pretrained model if exists
init_epoch = 0
best_iou = -1
best_epoch = -1
if 'WEIGHTS' in cfg.CONST and cfg.TRAIN.RESUME_TRAIN:
print('[INFO] %s Recovering from %s ...' %
(dt.now(), cfg.CONST.WEIGHTS))
checkpoint = torch.load(cfg.CONST.WEIGHTS)
init_epoch = checkpoint['epoch_idx']
best_iou = checkpoint['best_iou']
best_epoch = checkpoint['best_epoch']
encoder.load_state_dict(checkpoint['encoder_state_dict'])
decoder.load_state_dict(checkpoint['decoder_state_dict'])
if cfg.NETWORK.USE_REFINER:
refiner.load_state_dict(checkpoint['refiner_state_dict'])
if cfg.NETWORK.USE_MERGER:
merger.load_state_dict(checkpoint['merger_state_dict'])
print('[INFO] %s Recover complete. Current epoch #%d, Best IoU = %.4f at epoch #%d.' \
% (dt.now(), init_epoch, best_iou, best_epoch))
# Summary writer for TensorBoard
output_dir = os.path.join(cfg.DIR.OUT_PATH, '%s', dt.now().isoformat())
log_dir = output_dir % 'logs'
ckpt_dir = output_dir % 'checkpoints'
train_writer = SummaryWriter(os.path.join(log_dir, 'train'))
val_writer = SummaryWriter(os.path.join(log_dir, 'test'))
# Training loop
for epoch_idx in range(init_epoch, cfg.TRAIN.NUM_EPOCHES):
# Tick / tock
epoch_start_time = time()
# Batch average meterics
batch_time = utils.network_utils.AverageMeter()
data_time = utils.network_utils.AverageMeter()
encoder_losses = utils.network_utils.AverageMeter()
refiner_losses = utils.network_utils.AverageMeter()
# Adjust learning rate
encoder_lr_scheduler.step()
decoder_lr_scheduler.step()
refiner_lr_scheduler.step()
merger_lr_scheduler.step()
# switch models to training mode
encoder.train()
decoder.train()
merger.train()
refiner.train()
batch_end_time = time()
n_batches = len(train_data_loader)
for batch_idx, (taxonomy_names, sample_names, rendering_images,
ground_truth_volumes) in enumerate(train_data_loader):
# Measure data time
data_time.update(time() - batch_end_time)
# Get data from data loader
rendering_images = utils.network_utils.var_or_cuda(
rendering_images)
ground_truth_volumes = utils.network_utils.var_or_cuda(
ground_truth_volumes)
# Train the encoder, decoder, refiner, and merger
image_features = encoder(rendering_images)
raw_features, generated_volumes = decoder(image_features)
if cfg.NETWORK.USE_MERGER and epoch_idx >= cfg.TRAIN.EPOCH_START_USE_MERGER:
generated_volumes = merger(raw_features, generated_volumes)
else:
generated_volumes = torch.mean(generated_volumes, dim=1)
encoder_loss = bce_loss(generated_volumes,
ground_truth_volumes) * 10
if cfg.NETWORK.USE_REFINER and epoch_idx >= cfg.TRAIN.EPOCH_START_USE_REFINER:
generated_volumes = refiner(generated_volumes)
refiner_loss = bce_loss(generated_volumes,
ground_truth_volumes) * 10
else:
refiner_loss = encoder_loss
# Gradient decent
encoder.zero_grad()
decoder.zero_grad()
refiner.zero_grad()
merger.zero_grad()
if cfg.NETWORK.USE_REFINER and epoch_idx >= cfg.TRAIN.EPOCH_START_USE_REFINER:
encoder_loss.backward(retain_graph=True)
refiner_loss.backward()
else:
encoder_loss.backward()
encoder_solver.step()
decoder_solver.step()
refiner_solver.step()
merger_solver.step()
# Append loss to average metrics
encoder_losses.update(encoder_loss.item())
refiner_losses.update(refiner_loss.item())
# Append loss to TensorBoard
n_itr = epoch_idx * n_batches + batch_idx
train_writer.add_scalar('EncoderDecoder/BatchLoss',
encoder_loss.item(), n_itr)
train_writer.add_scalar('Refiner/BatchLoss', refiner_loss.item(),
n_itr)
# Tick / tock
batch_time.update(time() - batch_end_time)
batch_end_time = time()
print('[INFO] %s [Epoch %d/%d][Batch %d/%d] BatchTime = %.3f (s) DataTime = %.3f (s) EDLoss = %.4f RLoss = %.4f' % \
(dt.now(), epoch_idx + 1, cfg.TRAIN.NUM_EPOCHES, batch_idx + 1, n_batches, \
batch_time.val, data_time.val, encoder_loss.item(), refiner_loss.item()))
# Append epoch loss to TensorBoard
train_writer.add_scalar('EncoderDecoder/EpochLoss', encoder_losses.avg,
epoch_idx + 1)
train_writer.add_scalar('Refiner/EpochLoss', refiner_losses.avg,
epoch_idx + 1)
# Tick / tock
epoch_end_time = time()
print('[INFO] %s Epoch [%d/%d] EpochTime = %.3f (s) EDLoss = %.4f RLoss = %.4f' %
(dt.now(), epoch_idx + 1, cfg.TRAIN.NUM_EPOCHES, epoch_end_time - epoch_start_time, \
encoder_losses.avg, refiner_losses.avg))
# Update Rendering Views
if cfg.TRAIN.UPDATE_N_VIEWS_RENDERING:
n_views_rendering = random.randint(1, cfg.CONST.N_VIEWS_RENDERING)
train_data_loader.dataset.set_n_views_rendering(n_views_rendering)
print('[INFO] %s Epoch [%d/%d] Update #RenderingViews to %d' % \
(dt.now(), epoch_idx + 2, cfg.TRAIN.NUM_EPOCHES, n_views_rendering))
# Validate the training models
iou = test_net(cfg, epoch_idx + 1, output_dir, val_data_loader,
val_writer, encoder, decoder, refiner, merger)
# Save weights to file
if (epoch_idx + 1) % cfg.TRAIN.SAVE_FREQ == 0:
if not os.path.exists(ckpt_dir):
os.makedirs(ckpt_dir)
utils.network_utils.save_checkpoints(cfg, \
os.path.join(ckpt_dir, 'ckpt-epoch-%04d.pth' % (epoch_idx + 1)), \
epoch_idx + 1, encoder, encoder_solver, decoder, decoder_solver, \
refiner, refiner_solver, merger, merger_solver, best_iou, best_epoch)
if iou > best_iou:
if not os.path.exists(ckpt_dir):
os.makedirs(ckpt_dir)
best_iou = iou
best_epoch = epoch_idx + 1
utils.network_utils.save_checkpoints(cfg, \
os.path.join(ckpt_dir, 'best-ckpt.pth'), \
epoch_idx + 1, encoder, encoder_solver, decoder, decoder_solver, \
refiner, refiner_solver, merger, merger_solver, best_iou, best_epoch)
# Close SummaryWriter for TensorBoard
train_writer.close()
val_writer.close()
