def train():
"""Train function."""
args = get_args("train")
if args.need_profiler:
from mindspore.profiler.profiling import Profiler
profiler = Profiler(output_path=args.outputs_dir,
is_detail=True,
is_show_op_path=True)
ds = create_dataset(args)
G_A = get_generator(args)
G_B = get_generator(args)
D_A = get_discriminator(args)
D_B = get_discriminator(args)
load_ckpt(args, G_A, G_B, D_A, D_B)
imgae_pool_A = ImagePool(args.pool_size)
imgae_pool_B = ImagePool(args.pool_size)
generator = Generator(G_A, G_B, args.lambda_idt > 0)
loss_D = DiscriminatorLoss(args, D_A, D_B)
loss_G = GeneratorLoss(args, generator, D_A, D_B)
optimizer_G = nn.Adam(generator.trainable_params(),
get_lr(args),
beta1=args.beta1)
optimizer_D = nn.Adam(loss_D.trainable_params(),
get_lr(args),
beta1=args.beta1)
net_G = TrainOneStepG(loss_G, generator, optimizer_G)
net_D = TrainOneStepD(loss_D, optimizer_D)
data_loader = ds.create_dict_iterator()
reporter = Reporter(args)
reporter.info('==========start training===============')
for _ in range(args.max_epoch):
reporter.epoch_start()
for data in data_loader:
img_A = data["image_A"]
img_B = data["image_B"]
res_G = net_G(img_A, img_B)
fake_A = res_G[0]
fake_B = res_G[1]
res_D = net_D(img_A, img_B, imgae_pool_A.query(fake_A),
imgae_pool_B.query(fake_B))
reporter.step_end(res_G, res_D)
reporter.visualizer(img_A, img_B, fake_A, fake_B)
reporter.epoch_end(net_G)
if args.need_profiler:
profiler.analyse()
break
reporter.info('==========end training===============')
loss_meter.update(loss.asnumpy())
if args.rank_save_ckpt_flag:
# ckpt progress
cb_params.cur_step_num = i + 1 # current step number
cb_params.batch_num = i + 2
ckpt_cb.step_end(run_context)
if i % args.log_interval == 0:
time_used = time.time() - t_end
epoch = int(i / args.steps_per_epoch)
fps = args.per_batch_size * (
i - old_progress) * args.group_size / time_used
if args.rank == 0:
args.logger.info(
'epoch[{}], iter[{}], {}, {:.2f} imgs/sec, lr:{}'.format(
epoch, i, loss_meter, fps, lr[i]))
t_end = time.time()
loss_meter.reset()
old_progress = i
if (i + 1) % args.steps_per_epoch == 0 and args.rank_save_ckpt_flag:
cb_params.cur_epoch_num += 1
if args.need_profiler:
if i == 10:
profiler.analyse()
break
args.logger.info('==========end training===============')
def train():
"""Train function."""
args = parse_args()
devid = int(os.getenv('DEVICE_ID', '0'))
context.set_context(mode=context.GRAPH_MODE, enable_auto_mixed_precision=True,
device_target=args.device_target, save_graphs=True, device_id=devid)
if args.need_profiler:
from mindspore.profiler.profiling import Profiler
profiler = Profiler(output_path=args.outputs_dir, is_detail=True, is_show_op_path=True)
loss_meter = AverageMeter('loss')
context.reset_auto_parallel_context()
parallel_mode = ParallelMode.STAND_ALONE
degree = 1
if args.is_distributed:
parallel_mode = ParallelMode.DATA_PARALLEL
degree = get_group_size()
context.set_auto_parallel_context(parallel_mode=parallel_mode, gradients_mean=True, device_num=degree)
network = YOLOV3DarkNet53(is_training=True)
# default is kaiming-normal
default_recurisive_init(network)
load_yolov3_params(args, network)
network = YoloWithLossCell(network)
args.logger.info('finish get network')
config = ConfigYOLOV3DarkNet53()
config.label_smooth = args.label_smooth
config.label_smooth_factor = args.label_smooth_factor
if args.training_shape:
config.multi_scale = [conver_training_shape(args)]
if args.resize_rate:
config.resize_rate = args.resize_rate
ds, data_size = create_yolo_dataset(image_dir=args.data_root, anno_path=args.annFile, is_training=True,
batch_size=args.per_batch_size, max_epoch=args.max_epoch,
device_num=args.group_size, rank=args.rank, config=config)
args.logger.info('Finish loading dataset')
args.steps_per_epoch = int(data_size / args.per_batch_size / args.group_size)
if not args.ckpt_interval:
args.ckpt_interval = args.steps_per_epoch
lr = get_lr(args)
opt = Momentum(params=get_param_groups(network),
learning_rate=Tensor(lr),
momentum=args.momentum,
weight_decay=args.weight_decay,
loss_scale=args.loss_scale)
is_gpu = context.get_context("device_target") == "GPU"
if is_gpu:
loss_scale_value = 1.0
loss_scale = FixedLossScaleManager(loss_scale_value, drop_overflow_update=False)
network = amp.build_train_network(network, optimizer=opt, loss_scale_manager=loss_scale,
level="O2", keep_batchnorm_fp32=True)
keep_loss_fp32(network)
else:
network = TrainingWrapper(network, opt)
network.set_train()
if args.rank_save_ckpt_flag:
# checkpoint save
ckpt_max_num = args.max_epoch * args.steps_per_epoch // args.ckpt_interval
ckpt_config = CheckpointConfig(save_checkpoint_steps=args.ckpt_interval,
keep_checkpoint_max=ckpt_max_num)
save_ckpt_path = os.path.join(args.outputs_dir, 'ckpt_' + str(args.rank) + '/')
ckpt_cb = ModelCheckpoint(config=ckpt_config,
directory=save_ckpt_path,
prefix='{}'.format(args.rank))
cb_params = _InternalCallbackParam()
cb_params.train_network = network
cb_params.epoch_num = ckpt_max_num
cb_params.cur_epoch_num = 1
run_context = RunContext(cb_params)
ckpt_cb.begin(run_context)
old_progress = -1
t_end = time.time()
data_loader = ds.create_dict_iterator(output_numpy=True)
for i, data in enumerate(data_loader):
images = data["image"]
input_shape = images.shape[2:4]
args.logger.info('iter[{}], shape{}'.format(i, input_shape[0]))
images = Tensor.from_numpy(images)
batch_y_true_0 = Tensor.from_numpy(data['bbox1'])
batch_y_true_1 = Tensor.from_numpy(data['bbox2'])
batch_y_true_2 = Tensor.from_numpy(data['bbox3'])
batch_gt_box0 = Tensor.from_numpy(data['gt_box1'])
batch_gt_box1 = Tensor.from_numpy(data['gt_box2'])
batch_gt_box2 = Tensor.from_numpy(data['gt_box3'])
input_shape = Tensor(tuple(input_shape[::-1]), ms.float32)
loss = network(images, batch_y_true_0, batch_y_true_1, batch_y_true_2, batch_gt_box0, batch_gt_box1,
batch_gt_box2, input_shape)
loss_meter.update(loss.asnumpy())
if args.rank_save_ckpt_flag:
# ckpt progress
cb_params.cur_step_num = i + 1 # current step number
cb_params.batch_num = i + 2
ckpt_cb.step_end(run_context)
if i % args.log_interval == 0:
time_used = time.time() - t_end
epoch = int(i / args.steps_per_epoch)
fps = args.per_batch_size * (i - old_progress) * args.group_size / time_used
if args.rank == 0:
args.logger.info(
'epoch[{}], iter[{}], {}, {:.2f} imgs/sec, lr:{}'.format(epoch, i, loss_meter, fps, lr[i]))
t_end = time.time()
loss_meter.reset()
old_progress = i
if (i + 1) % args.steps_per_epoch == 0 and args.rank_save_ckpt_flag:
cb_params.cur_epoch_num += 1
if args.need_profiler:
if i == 10:
profiler.analyse()
break
args.logger.info('==========end training===============')
def train():
"""Train function."""
args = parse_args()
# init distributed
if args.is_distributed:
init()
args.rank = get_rank()
args.group_size = get_group_size()
# select for master rank save ckpt or all rank save, compatiable for model parallel
args.rank_save_ckpt_flag = 0
if args.is_save_on_master:
if args.rank == 0:
args.rank_save_ckpt_flag = 1
else:
args.rank_save_ckpt_flag = 1
# logger
args.outputs_dir = os.path.join(
args.ckpt_path,
datetime.datetime.now().strftime('%Y-%m-%d_time_%H_%M_%S'))
args.logger = get_logger(args.outputs_dir, args.rank)
args.logger.save_args(args)
if args.need_profiler:
from mindspore.profiler.profiling import Profiler
profiler = Profiler(output_path=args.outputs_dir,
is_detail=True,
is_show_op_path=True)
loss_meter = AverageMeter('loss')
context.reset_auto_parallel_context()
if args.is_distributed:
parallel_mode = ParallelMode.DATA_PARALLEL
degree = get_group_size()
else:
parallel_mode = ParallelMode.STAND_ALONE
degree = 1
context.set_auto_parallel_context(parallel_mode=parallel_mode,
mirror_mean=True,
device_num=degree)
network = YOLOV3DarkNet53(is_training=True)
# default is kaiming-normal
default_recurisive_init(network)
if args.resume_yolov3:
param_dict = load_checkpoint(args.resume_yolov3)
param_dict_new = {}
for key, values in param_dict.items():
args.logger.info('ckpt param name = {}'.format(key))
if key.startswith('moments.') or key.startswith('global_') or \
key.startswith('learning_rate') or key.startswith('momentum'):
continue
elif key.startswith('yolo_network.'):
key_new = key[13:]
if key_new.endswith('1.beta'):
key_new = key_new.replace('1.beta', 'batchnorm.beta')
if key_new.endswith('1.gamma'):
key_new = key_new.replace('1.gamma', 'batchnorm.gamma')
if key_new.endswith('1.moving_mean'):
key_new = key_new.replace('1.moving_mean',
'batchnorm.moving_mean')
if key_new.endswith('1.moving_variance'):
key_new = key_new.replace('1.moving_variance',
'batchnorm.moving_variance')
if key_new.endswith('.weight'):
if key_new.endswith('0.weight'):
key_new = key_new.replace('0.weight', 'conv.weight')
else:
key_new = key_new.replace('.weight', '.conv.weight')
if key_new.endswith('.bias'):
key_new = key_new.replace('.bias', '.conv.bias')
param_dict_new[key_new] = values
args.logger.info('in resume {}'.format(key_new))
else:
param_dict_new[key] = values
args.logger.info('in resume {}'.format(key))
args.logger.info('resume finished')
for _, param in network.parameters_and_names():
args.logger.info('network param name = {}'.format(param.name))
if param.name not in param_dict_new:
args.logger.info('not match param name = {}'.format(
param.name))
load_param_into_net(network, param_dict_new)
args.logger.info('load_model {} success'.format(args.resume_yolov3))
config = ConfigYOLOV3DarkNet53()
# convert fusion network to quantization aware network
if config.quantization_aware:
network = quant.convert_quant_network(network,
bn_fold=True,
per_channel=[True, False],
symmetric=[True, False])
network = YoloWithLossCell(network)
args.logger.info('finish get network')
config.label_smooth = args.label_smooth
config.label_smooth_factor = args.label_smooth_factor
if args.training_shape:
config.multi_scale = [conver_training_shape(args)]
if args.resize_rate:
config.resize_rate = args.resize_rate
ds, data_size = create_yolo_dataset(image_dir=args.data_root,
anno_path=args.annFile,
is_training=True,
batch_size=args.per_batch_size,
max_epoch=args.max_epoch,
device_num=args.group_size,
rank=args.rank,
config=config)
args.logger.info('Finish loading dataset')
args.steps_per_epoch = int(data_size / args.per_batch_size /
args.group_size)
if not args.ckpt_interval:
args.ckpt_interval = args.steps_per_epoch
# lr scheduler
if args.lr_scheduler == 'exponential':
lr = warmup_step_lr(
args.lr,
args.lr_epochs,
args.steps_per_epoch,
args.warmup_epochs,
args.max_epoch,
gamma=args.lr_gamma,
)
elif args.lr_scheduler == 'cosine_annealing':
lr = warmup_cosine_annealing_lr(args.lr, args.steps_per_epoch,
args.warmup_epochs, args.max_epoch,
args.T_max, args.eta_min)
elif args.lr_scheduler == 'cosine_annealing_V2':
lr = warmup_cosine_annealing_lr_V2(args.lr, args.steps_per_epoch,
args.warmup_epochs, args.max_epoch,
args.T_max, args.eta_min)
elif args.lr_scheduler == 'cosine_annealing_sample':
lr = warmup_cosine_annealing_lr_sample(args.lr, args.steps_per_epoch,
args.warmup_epochs,
args.max_epoch, args.T_max,
args.eta_min)
else:
raise NotImplementedError(args.lr_scheduler)
opt = Momentum(params=get_param_groups(network),
learning_rate=Tensor(lr),
momentum=args.momentum,
weight_decay=args.weight_decay,
loss_scale=args.loss_scale)
network = TrainingWrapper(network, opt)
network.set_train()
if args.rank_save_ckpt_flag:
# checkpoint save
ckpt_max_num = args.max_epoch * args.steps_per_epoch // args.ckpt_interval
ckpt_config = CheckpointConfig(
save_checkpoint_steps=args.ckpt_interval,
keep_checkpoint_max=ckpt_max_num)
ckpt_cb = ModelCheckpoint(config=ckpt_config,
directory=args.outputs_dir,
prefix='{}'.format(args.rank))
cb_params = _InternalCallbackParam()
cb_params.train_network = network
cb_params.epoch_num = ckpt_max_num
cb_params.cur_epoch_num = 1
run_context = RunContext(cb_params)
ckpt_cb.begin(run_context)
old_progress = -1
t_end = time.time()
data_loader = ds.create_dict_iterator()
shape_record = ShapeRecord()
for i, data in enumerate(data_loader):
images = data["image"]
input_shape = images.shape[2:4]
args.logger.info('iter[{}], shape{}'.format(i, input_shape[0]))
shape_record.set(input_shape)
images = Tensor(images)
annos = data["annotation"]
if args.group_size == 1:
batch_y_true_0, batch_y_true_1, batch_y_true_2, batch_gt_box0, batch_gt_box1, batch_gt_box2 = \
batch_preprocess_true_box(annos, config, input_shape)
else:
batch_y_true_0, batch_y_true_1, batch_y_true_2, batch_gt_box0, batch_gt_box1, batch_gt_box2 = \
batch_preprocess_true_box_single(annos, config, input_shape)
batch_y_true_0 = Tensor(batch_y_true_0)
batch_y_true_1 = Tensor(batch_y_true_1)
batch_y_true_2 = Tensor(batch_y_true_2)
batch_gt_box0 = Tensor(batch_gt_box0)
batch_gt_box1 = Tensor(batch_gt_box1)
batch_gt_box2 = Tensor(batch_gt_box2)
input_shape = Tensor(tuple(input_shape[::-1]), ms.float32)
loss = network(images, batch_y_true_0, batch_y_true_1, batch_y_true_2,
batch_gt_box0, batch_gt_box1, batch_gt_box2,
input_shape)
loss_meter.update(loss.asnumpy())
if args.rank_save_ckpt_flag:
# ckpt progress
cb_params.cur_step_num = i + 1 # current step number
cb_params.batch_num = i + 2
ckpt_cb.step_end(run_context)
if i % args.log_interval == 0:
time_used = time.time() - t_end
epoch = int(i / args.steps_per_epoch)
fps = args.per_batch_size * (
i - old_progress) * args.group_size / time_used
if args.rank == 0:
args.logger.info(
'epoch[{}], iter[{}], {}, {:.2f} imgs/sec, lr:{}'.format(
epoch, i, loss_meter, fps, lr[i]))
t_end = time.time()
loss_meter.reset()
old_progress = i
if (i + 1) % args.steps_per_epoch == 0 and args.rank_save_ckpt_flag:
cb_params.cur_epoch_num += 1
if args.need_profiler:
if i == 10:
profiler.analyse()
break
args.logger.info('==========end training===============')
def train():
"""Train function."""
args = parse_args()
args.logger.save_args(args)
if args.need_profiler:
from mindspore.profiler.profiling import Profiler
profiler = Profiler(output_path=args.outputs_dir,
is_detail=True,
is_show_op_path=True)
loss_meter = AverageMeter('loss')
context.reset_auto_parallel_context()
parallel_mode = ParallelMode.STAND_ALONE
degree = 1
if args.is_distributed:
parallel_mode = ParallelMode.DATA_PARALLEL
degree = get_group_size()
context.set_auto_parallel_context(parallel_mode=parallel_mode,
gradients_mean=True,
device_num=degree)
network = YOLOV3DarkNet53(is_training=True)
# default is kaiming-normal
default_recurisive_init(network)
load_yolov3_quant_params(args, network)
config = ConfigYOLOV3DarkNet53()
# convert fusion network to quantization aware network
if config.quantization_aware:
network = quant.convert_quant_network(network,
bn_fold=True,
per_channel=[True, False],
symmetric=[True, False])
network = YoloWithLossCell(network)
args.logger.info('finish get network')
config.label_smooth = args.label_smooth
config.label_smooth_factor = args.label_smooth_factor
if args.training_shape:
config.multi_scale = [conver_training_shape(args)]
if args.resize_rate:
config.resize_rate = args.resize_rate
ds, data_size = create_yolo_dataset(image_dir=args.data_root,
anno_path=args.annFile,
is_training=True,
batch_size=args.per_batch_size,
max_epoch=args.max_epoch,
device_num=args.group_size,
rank=args.rank,
config=config)
args.logger.info('Finish loading dataset')
args.steps_per_epoch = int(data_size / args.per_batch_size /
args.group_size)
if not args.ckpt_interval:
args.ckpt_interval = args.steps_per_epoch
lr = get_lr(args)
opt = Momentum(params=get_param_groups(network),
learning_rate=Tensor(lr),
momentum=args.momentum,
weight_decay=args.weight_decay,
loss_scale=args.loss_scale)
network = TrainingWrapper(network, opt)
network.set_train()
if args.rank_save_ckpt_flag:
# checkpoint save
ckpt_max_num = args.max_epoch * args.steps_per_epoch // args.ckpt_interval
ckpt_config = CheckpointConfig(
save_checkpoint_steps=args.ckpt_interval,
keep_checkpoint_max=ckpt_max_num)
save_ckpt_path = os.path.join(args.outputs_dir,
'ckpt_' + str(args.rank) + '/')
ckpt_cb = ModelCheckpoint(config=ckpt_config,
directory=save_ckpt_path,
prefix='{}'.format(args.rank))
cb_params = _InternalCallbackParam()
cb_params.train_network = network
cb_params.epoch_num = ckpt_max_num
cb_params.cur_epoch_num = 1
run_context = RunContext(cb_params)
ckpt_cb.begin(run_context)
old_progress = -1
t_end = time.time()
data_loader = ds.create_dict_iterator(output_numpy=True, num_epochs=1)
shape_record = ShapeRecord()
for i, data in enumerate(data_loader):
images = data["image"]
input_shape = images.shape[2:4]
args.logger.info('iter[{}], shape{}'.format(i, input_shape[0]))
shape_record.set(input_shape)
images = Tensor.from_numpy(images)
annos = data["annotation"]
if args.group_size == 1:
batch_y_true_0, batch_y_true_1, batch_y_true_2, batch_gt_box0, batch_gt_box1, batch_gt_box2 = \
batch_preprocess_true_box(annos, config, input_shape)
else:
batch_y_true_0, batch_y_true_1, batch_y_true_2, batch_gt_box0, batch_gt_box1, batch_gt_box2 = \
batch_preprocess_true_box_single(annos, config, input_shape)
batch_y_true_0 = Tensor.from_numpy(batch_y_true_0)
batch_y_true_1 = Tensor.from_numpy(batch_y_true_1)
batch_y_true_2 = Tensor.from_numpy(batch_y_true_2)
batch_gt_box0 = Tensor.from_numpy(batch_gt_box0)
batch_gt_box1 = Tensor.from_numpy(batch_gt_box1)
batch_gt_box2 = Tensor.from_numpy(batch_gt_box2)
input_shape = Tensor(tuple(input_shape[::-1]), ms.float32)
loss = network(images, batch_y_true_0, batch_y_true_1, batch_y_true_2,
batch_gt_box0, batch_gt_box1, batch_gt_box2,
input_shape)
loss_meter.update(loss.asnumpy())
if args.rank_save_ckpt_flag:
# ckpt progress
cb_params.cur_step_num = i + 1 # current step number
cb_params.batch_num = i + 2
ckpt_cb.step_end(run_context)
if i % args.log_interval == 0:
time_used = time.time() - t_end
epoch = int(i / args.steps_per_epoch)
fps = args.per_batch_size * (
i - old_progress) * args.group_size / time_used
if args.rank == 0:
args.logger.info(
'epoch[{}], iter[{}], {}, {:.2f} imgs/sec, lr:{}'.format(
epoch, i, loss_meter, fps, lr[i]))
t_end = time.time()
loss_meter.reset()
old_progress = i
if (i + 1) % args.steps_per_epoch == 0 and args.rank_save_ckpt_flag:
cb_params.cur_epoch_num += 1
if args.need_profiler:
if i == 10:
profiler.analyse()
break
args.logger.info('==========end training===============')
def train():
"""Train function."""
args = parse_args()
devid = int(os.getenv('DEVICE_ID')) if os.getenv('DEVICE_ID') else 0
context.set_context(mode=context.GRAPH_MODE, enable_auto_mixed_precision=True,
device_target=args.device_target, save_graphs=True, device_id=devid)
# init distributed
if args.is_distributed:
if args.device_target == "Ascend":
init()
else:
init("nccl")
args.rank = get_rank()
args.group_size = get_group_size()
# select for master rank save ckpt or all rank save, compatiable for model parallel
args.rank_save_ckpt_flag = 0
if args.is_save_on_master:
if args.rank == 0:
args.rank_save_ckpt_flag = 1
else:
args.rank_save_ckpt_flag = 1
# logger
args.outputs_dir = os.path.join(args.ckpt_path,
datetime.datetime.now().strftime('%Y-%m-%d_time_%H_%M_%S'))
args.logger = get_logger(args.outputs_dir, args.rank)
args.logger.save_args(args)
if args.need_profiler:
from mindspore.profiler.profiling import Profiler
profiler = Profiler(output_path=args.outputs_dir, is_detail=True, is_show_op_path=True)
loss_meter = AverageMeter('loss')
context.reset_auto_parallel_context()
if args.is_distributed:
parallel_mode = ParallelMode.DATA_PARALLEL
degree = get_group_size()
else:
parallel_mode = ParallelMode.STAND_ALONE
degree = 1
context.set_auto_parallel_context(parallel_mode=parallel_mode, mirror_mean=True, device_num=degree)
network = YOLOV3DarkNet53(is_training=True)
# default is kaiming-normal
default_recurisive_init(network)
if args.pretrained_backbone:
network = load_backbone(network, args.pretrained_backbone, args)
args.logger.info('load pre-trained backbone {} into network'.format(args.pretrained_backbone))
else:
args.logger.info('Not load pre-trained backbone, please be careful')
if args.resume_yolov3:
param_dict = load_checkpoint(args.resume_yolov3)
param_dict_new = {}
for key, values in param_dict.items():
if key.startswith('moments.'):
continue
elif key.startswith('yolo_network.'):
param_dict_new[key[13:]] = values
args.logger.info('in resume {}'.format(key))
else:
param_dict_new[key] = values
args.logger.info('in resume {}'.format(key))
args.logger.info('resume finished')
load_param_into_net(network, param_dict_new)
args.logger.info('load_model {} success'.format(args.resume_yolov3))
network = YoloWithLossCell(network)
args.logger.info('finish get network')
config = ConfigYOLOV3DarkNet53()
config.label_smooth = args.label_smooth
config.label_smooth_factor = args.label_smooth_factor
if args.training_shape:
config.multi_scale = [conver_training_shape(args)]
if args.resize_rate:
config.resize_rate = args.resize_rate
ds, data_size = create_yolo_dataset(image_dir=args.data_root, anno_path=args.annFile, is_training=True,
batch_size=args.per_batch_size, max_epoch=args.max_epoch,
device_num=args.group_size, rank=args.rank, config=config)
args.logger.info('Finish loading dataset')
args.steps_per_epoch = int(data_size / args.per_batch_size / args.group_size)
if not args.ckpt_interval:
args.ckpt_interval = args.steps_per_epoch
# lr scheduler
if args.lr_scheduler == 'exponential':
lr = warmup_step_lr(args.lr,
args.lr_epochs,
args.steps_per_epoch,
args.warmup_epochs,
args.max_epoch,
gamma=args.lr_gamma,
)
elif args.lr_scheduler == 'cosine_annealing':
lr = warmup_cosine_annealing_lr(args.lr,
args.steps_per_epoch,
args.warmup_epochs,
args.max_epoch,
args.T_max,
args.eta_min)
elif args.lr_scheduler == 'cosine_annealing_V2':
lr = warmup_cosine_annealing_lr_V2(args.lr,
args.steps_per_epoch,
args.warmup_epochs,
args.max_epoch,
args.T_max,
args.eta_min)
elif args.lr_scheduler == 'cosine_annealing_sample':
lr = warmup_cosine_annealing_lr_sample(args.lr,
args.steps_per_epoch,
args.warmup_epochs,
args.max_epoch,
args.T_max,
args.eta_min)
else:
raise NotImplementedError(args.lr_scheduler)
opt = Momentum(params=get_param_groups(network),
learning_rate=Tensor(lr),
momentum=args.momentum,
weight_decay=args.weight_decay,
loss_scale=args.loss_scale)
enable_amp = False
is_gpu = context.get_context("device_target") == "GPU"
if is_gpu:
enable_amp = True
if enable_amp:
loss_scale_value = 1.0
loss_scale = FixedLossScaleManager(loss_scale_value, drop_overflow_update=False)
network = amp.build_train_network(network, optimizer=opt, loss_scale_manager=loss_scale,
level="O2", keep_batchnorm_fp32=True)
keep_loss_fp32(network)
else:
network = TrainingWrapper(network, opt)
network.set_train()
if args.rank_save_ckpt_flag:
# checkpoint save
ckpt_max_num = args.max_epoch * args.steps_per_epoch // args.ckpt_interval
ckpt_config = CheckpointConfig(save_checkpoint_steps=args.ckpt_interval,
keep_checkpoint_max=ckpt_max_num)
ckpt_cb = ModelCheckpoint(config=ckpt_config,
directory=args.outputs_dir,
prefix='{}'.format(args.rank))
cb_params = _InternalCallbackParam()
cb_params.train_network = network
cb_params.epoch_num = ckpt_max_num
cb_params.cur_epoch_num = 1
run_context = RunContext(cb_params)
ckpt_cb.begin(run_context)
old_progress = -1
t_end = time.time()
data_loader = ds.create_dict_iterator()
for i, data in enumerate(data_loader):
images = data["image"]
input_shape = images.shape[2:4]
args.logger.info('iter[{}], shape{}'.format(i, input_shape[0]))
images = Tensor(images)
batch_y_true_0 = Tensor(data['bbox1'])
batch_y_true_1 = Tensor(data['bbox2'])
batch_y_true_2 = Tensor(data['bbox3'])
batch_gt_box0 = Tensor(data['gt_box1'])
batch_gt_box1 = Tensor(data['gt_box2'])
batch_gt_box2 = Tensor(data['gt_box3'])
input_shape = Tensor(tuple(input_shape[::-1]), ms.float32)
loss = network(images, batch_y_true_0, batch_y_true_1, batch_y_true_2, batch_gt_box0, batch_gt_box1,
batch_gt_box2, input_shape)
loss_meter.update(loss.asnumpy())
if args.rank_save_ckpt_flag:
# ckpt progress
cb_params.cur_step_num = i + 1 # current step number
cb_params.batch_num = i + 2
ckpt_cb.step_end(run_context)
if i % args.log_interval == 0:
time_used = time.time() - t_end
epoch = int(i / args.steps_per_epoch)
fps = args.per_batch_size * (i - old_progress) * args.group_size / time_used
if args.rank == 0:
args.logger.info(
'epoch[{}], iter[{}], {}, {:.2f} imgs/sec, lr:{}'.format(epoch, i, loss_meter, fps, lr[i]))
t_end = time.time()
loss_meter.reset()
old_progress = i
if (i + 1) % args.steps_per_epoch == 0 and args.rank_save_ckpt_flag:
cb_params.cur_epoch_num += 1
if args.need_profiler:
if i == 10:
profiler.analyse()
break
args.logger.info('==========end training===============')