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- """ Model training pipeline """
- import logging
- import os
- import numpy as np
- import moxing as mox
- import time
- import json
-
- import mindspore as ms
- from mindspore import FixedLossScaleManager, Model, Tensor, nn, context
- from mindspore.communication import get_group_size, get_rank, init
-
- from mindspore.context import ParallelMode
-
- from mindcv.data import create_dataset, create_loader, create_transforms
- from mindcv.engine import StateMonitor, TrainStep
- from mindcv.loss import create_loss
- from mindcv.models import create_model
- from mindcv.optim import create_optimizer
- from mindcv.scheduler import create_scheduler
- from mindcv.utils import AllReduceSum, set_seed
-
- from config import parse_args # isort: skip
-
- # TODO: arg parser already has a logger
- logger = logging.getLogger("train")
- logger.setLevel(logging.INFO)
- h1 = logging.StreamHandler()
- formatter1 = logging.Formatter("%(message)s")
- logger.addHandler(h1)
- h1.setFormatter(formatter1)
-
-
- def train(args):
- """main train function"""
-
- ms.set_context(mode=args.mode)
- if args.distribute:
- init()
- device_num = get_group_size()
- rank_id = get_rank()
- ms.set_auto_parallel_context(
- device_num=device_num,
- parallel_mode="data_parallel",
- gradients_mean=True,
- parameter_broadcast=True,
- )
- else:
- device_num = None
- rank_id = None
-
- set_seed(args.seed)
-
- # create dataset
- dataset_train = create_dataset(
- name=args.dataset,
- root=args.data_dir,
- split=args.train_split,
- shuffle=args.shuffle,
- num_samples=args.num_samples,
- num_shards=device_num,
- shard_id=rank_id,
- num_parallel_workers=args.num_parallel_workers,
- download=args.dataset_download,
- num_aug_repeats=args.aug_repeats,
- )
-
- if args.num_classes is None:
- num_classes = dataset_train.num_classes()
- else:
- num_classes = args.num_classes
-
- # create transforms
- transform_list = create_transforms(
- dataset_name=args.dataset,
- is_training=True,
- image_resize=args.image_resize,
- scale=args.scale,
- ratio=args.ratio,
- hflip=args.hflip,
- vflip=args.vflip,
- color_jitter=args.color_jitter,
- interpolation=args.interpolation,
- auto_augment=args.auto_augment,
- mean=args.mean,
- std=args.std,
- re_prob=args.re_prob,
- re_scale=args.re_scale,
- re_ratio=args.re_ratio,
- re_value=args.re_value,
- re_max_attempts=args.re_max_attempts,
- )
-
- # load dataset
- loader_train = create_loader(
- dataset=dataset_train,
- batch_size=args.batch_size,
- drop_remainder=args.drop_remainder,
- is_training=True,
- mixup=args.mixup,
- cutmix=args.cutmix,
- cutmix_prob=args.cutmix_prob,
- num_classes=num_classes,
- transform=transform_list,
- num_parallel_workers=args.num_parallel_workers,
- )
-
- if args.val_while_train:
- dataset_eval = create_dataset(
- name=args.dataset,
- root=args.data_dir,
- split=args.val_split,
- num_shards=device_num,
- shard_id=rank_id,
- num_parallel_workers=args.num_parallel_workers,
- download=args.dataset_download,
- )
-
- transform_list_eval = create_transforms(
- dataset_name=args.dataset,
- is_training=False,
- image_resize=args.image_resize,
- crop_pct=args.crop_pct,
- interpolation=args.interpolation,
- mean=args.mean,
- std=args.std,
- )
-
- loader_eval = create_loader(
- dataset=dataset_eval,
- batch_size=args.batch_size,
- drop_remainder=False,
- is_training=False,
- transform=transform_list_eval,
- num_parallel_workers=args.num_parallel_workers,
- )
- # validation dataset count
- eval_count = dataset_eval.get_dataset_size()
- if args.distribute:
- all_reduce = AllReduceSum()
- eval_count = all_reduce(Tensor(eval_count, ms.int32))
- else:
- loader_eval = None
-
- num_batches = loader_train.get_dataset_size()
- # Train dataset count
- train_count = dataset_train.get_dataset_size()
- if args.distribute:
- all_reduce = AllReduceSum()
- train_count = all_reduce(Tensor(train_count, ms.int32))
-
- # create model
- network = create_model(
- model_name=args.model,
- num_classes=num_classes,
- in_channels=args.in_channels,
- drop_rate=args.drop_rate,
- drop_path_rate=args.drop_path_rate,
- pretrained=args.pretrained,
- checkpoint_path=args.ckpt_path,
- ema=args.ema,
- )
-
- num_params = sum([param.size for param in network.get_parameters()])
-
- # create loss
- loss = create_loss(
- name=args.loss,
- reduction=args.reduction,
- label_smoothing=args.label_smoothing,
- aux_factor=args.aux_factor,
- )
-
- # create learning rate schedule
- lr_scheduler = create_scheduler(
- num_batches,
- scheduler=args.scheduler,
- lr=args.lr,
- min_lr=args.min_lr,
- warmup_epochs=args.warmup_epochs,
- warmup_factor=args.warmup_factor,
- decay_epochs=args.decay_epochs,
- decay_rate=args.decay_rate,
- milestones=args.multi_step_decay_milestones,
- num_epochs=args.epoch_size,
- lr_epoch_stair=args.lr_epoch_stair,
- num_cycles=args.num_cycles,
- cycle_decay=args.cycle_decay,
- )
-
- # resume training if ckpt_path is given
- if args.ckpt_path != "" and args.resume_opt:
- opt_ckpt_path = os.path.join(args.ckpt_save_dir, f"optim_{args.model}.ckpt")
- else:
- opt_ckpt_path = ""
-
- # create optimizer
- # TODO: consistent naming opt, name, dataset_name
- if args.ema or args.dynamic_loss_scale:
- optimizer = create_optimizer(
- network.trainable_params(),
- opt=args.opt,
- lr=lr_scheduler,
- weight_decay=args.weight_decay,
- momentum=args.momentum,
- nesterov=args.use_nesterov,
- filter_bias_and_bn=args.filter_bias_and_bn,
- checkpoint_path=opt_ckpt_path,
- eps=args.eps,
- )
- else:
- optimizer = create_optimizer(
- network.trainable_params(),
- opt=args.opt,
- lr=lr_scheduler,
- weight_decay=args.weight_decay,
- momentum=args.momentum,
- nesterov=args.use_nesterov,
- filter_bias_and_bn=args.filter_bias_and_bn,
- loss_scale=args.loss_scale,
- checkpoint_path=opt_ckpt_path,
- eps=args.eps,
- )
-
- # Define eval metrics.
- if num_classes >= 5:
- eval_metrics = {"Top_1_Accuracy": nn.Top1CategoricalAccuracy(), "Top_5_Accuracy": nn.Top5CategoricalAccuracy()}
- else:
- eval_metrics = {"Top_1_Accuracy": nn.Top1CategoricalAccuracy()}
-
- # init model
- # TODO: add dynamic_loss_scale for ema and clip_grad
- if args.ema or args.clip_grad:
- net_with_loss = nn.WithLossCell(network, loss)
- loss_scale_manager = nn.FixedLossScaleUpdateCell(loss_scale_value=args.loss_scale)
- ms.amp.auto_mixed_precision(net_with_loss, amp_level=args.amp_level)
- net_with_loss = TrainStep(
- net_with_loss,
- optimizer,
- scale_sense=loss_scale_manager,
- ema=args.ema,
- ema_decay=args.ema_decay,
- clip_grad=args.clip_grad,
- clip_value=args.clip_value,
- )
-
- eval_network = nn.WithEvalCell(network, loss, args.amp_level in ["O2", "O3", "auto"])
- model = Model(net_with_loss, eval_network=eval_network, metrics=eval_metrics, eval_indexes=[0, 1, 2])
- else:
- if args.dynamic_loss_scale:
- loss_scale_manager = ms.amp.DynamicLossScaleManager(
- init_loss_scale=args.loss_scale,
- scale_factor=2,
- scale_window=1000,
- )
- else:
- loss_scale_manager = FixedLossScaleManager(loss_scale=args.loss_scale, drop_overflow_update=False)
- model = Model(
- network,
- loss_fn=loss,
- optimizer=optimizer,
- metrics=eval_metrics,
- amp_level=args.amp_level,
- loss_scale_manager=loss_scale_manager,
- )
-
- # callback
- # save checkpoint, summary training loss
- # recorad val acc and do model selection if val dataset is availabe
- begin_epoch = 0
- if args.ckpt_path != "":
- if args.ckpt_path != "":
- begin_step = optimizer.global_step.asnumpy()[0]
- begin_epoch = args.ckpt_path.split("/")[-1].split("-")[1].split("_")[0]
- begin_epoch = int(begin_epoch)
-
- summary_dir = f"./{args.ckpt_save_dir}/summary"
- assert (
- args.ckpt_save_policy != "top_k" or args.val_while_train is True
- ), "ckpt_save_policy is top_k, val_while_train must be True."
- state_cb = StateMonitor(
- model,
- summary_dir=summary_dir,
- dataset_val=loader_eval,
- val_interval=args.val_interval,
- metric_name=list(eval_metrics.keys()),
- ckpt_dir=args.ckpt_save_dir,
- ckpt_save_interval=args.ckpt_save_interval,
- best_ckpt_name=args.model + "_best.ckpt",
- rank_id=rank_id,
- device_num=device_num,
- log_interval=args.log_interval,
- keep_checkpoint_max=args.keep_checkpoint_max,
- model_name=args.model,
- last_epoch=begin_epoch,
- ckpt_save_policy=args.ckpt_save_policy,
- ema=args.ema,
- dataset_sink_mode=args.dataset_sink_mode,
- )
-
- callbacks = [state_cb]
- # log
- if rank_id in [None, 0]:
- logger.info("-" * 40)
- logger.info(
- f"Num devices: {device_num if device_num is not None else 1} \n"
- f"Distributed mode: {args.distribute} \n"
- f"Num training samples: {train_count}"
- )
- if args.val_while_train:
- logger.info(f"Num validation samples: {eval_count}")
- logger.info(
- f"****************************************\n"
- f"Num classes: {num_classes} \n"
- f"Num batches: {num_batches} \n"
- f"Batch size: {args.batch_size} \n"
- f"****************************************\n"
- f"Auto augment: {args.auto_augment} \n"
- f"******************************\n"
- f"Model: {args.model} \n"
- f"Model param: {num_params} \n"
- f"drop_rate: {args.drop_rate} \n"
- f"drop_path_rate: {args.drop_path_rate} \n"
- f"dataset_sink_mode: {args.dataset_sink_mode} \n"
- f"amp_level: {args.amp_level} \n"
- f"ema: {args.ema} \n"
- f"****************************************\n"
- f"LR Scheduler: {args.scheduler}\n"
- f"warmup_epochs: {args.warmup_epochs} \n"
- f"decay_epochs: {args.decay_epochs} \n"
- f"epoch_size: {args.epoch_size} \n"
- f"num_cycles: {args.num_cycles} \n"
- f"cycle_decay: {args.cycle_decay} \n"
- f"lr: {args.lr} \n"
- f"min_lr: {args.min_lr} \n"
- f"****************************************\n"
- f"Optimizer: {args.opt} \n"
- f"weight_decay: {args.weight_decay} \n"
- f"filter_bias_and_bn: {args.filter_bias_and_bn} \n"
- f"loss_scale: {args.loss_scale} \n"
- f"use_nesterov: {args.use_nesterov} \n"
-
- )
- logger.info("-" * 40)
-
- if args.ckpt_path != "":
- logger.info(f"Resume training from {args.ckpt_path}, last step: {begin_step}, last epoch: {begin_epoch}")
- else:
- logger.info("Start training")
-
- model.train(args.epoch_size, loader_train, callbacks=callbacks, dataset_sink_mode=args.dataset_sink_mode)
-
- def C2netMultiObsToEnv(multi_data_url, data_dir):
- #--multi_data_url is json data, need to do json parsing for multi_data_url
- print(multi_data_url)
- multi_data_json = json.loads(multi_data_url)
- for i in range(len(multi_data_json)):
- zipfile_path = data_dir + "/" + multi_data_json[i]["dataset_name"]
- try:
- mox.file.copy(multi_data_json[i]["dataset_url"], zipfile_path)
- print("Successfully Download {} to {}".format(multi_data_json[i]["dataset_url"],zipfile_path))
- #get filename and unzip the dataset
- filename = os.path.splitext(multi_data_json[i]["dataset_name"])[0]
- filePath = data_dir + "/" + filename
- if not os.path.exists(filePath):
- os.makedirs(filePath)
- os.system("unzip {} -d {}".format(zipfile_path, filePath))
-
- except Exception as e:
- print('moxing download {} to {} failed: '.format(
- multi_data_json[i]["dataset_url"], zipfile_path) + str(e))
- #Set a cache file to determine whether the data has been copied to obs.
- #If this file exists during multi-card training, there is no need to copy the dataset multiple times.
- f = open("/cache/download_input.txt", 'w')
- f.close()
- try:
- if os.path.exists("/cache/download_input.txt"):
- print("download_input succeed")
- except Exception as e:
- print("download_input failed")
- return
-
-
- def DownloadFromQizhi(multi_data_url, data_dir):
- device_num = int(os.getenv('RANK_SIZE'))
- if device_num == 1:
- C2netMultiObsToEnv(multi_data_url,data_dir)
- context.set_context(mode=context.GRAPH_MODE,device_target=args.device_target)
- if device_num > 1:
- # set device_id and init for multi-card training
- context.set_context(mode=context.GRAPH_MODE, device_target=args.device_target, device_id=int(os.getenv('ASCEND_DEVICE_ID')))
- context.reset_auto_parallel_context()
- context.set_auto_parallel_context(device_num = device_num, parallel_mode=ParallelMode.DATA_PARALLEL, gradients_mean=True, parameter_broadcast=True)
- init()
- #Copying obs data does not need to be executed multiple times, just let the 0th card copy the data
- local_rank=int(os.getenv('RANK_ID'))
- if local_rank%8==0:
- C2netMultiObsToEnv(multi_data_url,data_dir)
- #If the cache file does not exist, it means that the copy data has not been completed,
- #and Wait for 0th card to finish copying data
- while not os.path.exists("/cache/download_input.txt"):
- time.sleep(1)
- return
-
-
- def EnvToObs(train_dir, obs_train_url):
- try:
- mox.file.copy_parallel(train_dir, obs_train_url)
- print("Successfully Upload {} to {}".format(train_dir,
- obs_train_url))
- except Exception as e:
- print('moxing upload {} to {} failed: '.format(train_dir,
- obs_train_url) + str(e))
- return
-
-
- def UploadToQizhi(train_dir, obs_train_url):
- device_num = int(os.getenv('RANK_SIZE'))
- local_rank=int(os.getenv('RANK_ID'))
- if device_num == 1:
- EnvToObs(train_dir, obs_train_url)
- if device_num > 1:
- if local_rank%8==0:
- EnvToObs(train_dir, obs_train_url)
- return
-
-
-
- if __name__ == '__main__':
- args = parse_args()
-
- # modelarts
- data_dir = '/cache/dataset'
- train_dir = '/cache/output'
- ckpt_url = '/cache/checkpoint.ckpt'
- if not os.path.exists(data_dir):
- os.makedirs(data_dir)
- if not os.path.exists(train_dir):
- os.makedirs(train_dir)
- print(args.multi_data_url)
- DownloadFromQizhi(args.multi_data_url, data_dir)
-
- train(args)
-
- UploadToQizhi(train_dir,args.train_url)
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