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odor-detection / projects /h_deformable_detr /train_net.py

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	#!/usr/bin/env python
	# Copyright (c) Facebook, Inc. and its affiliates.
	"""
	Training script using the new "LazyConfig" python config files.

	This scripts reads a given python config file and runs the training or evaluation.
	It can be used to train any models or dataset as long as they can be
	instantiated by the recursive construction defined in the given config file.

	Besides lazy construction of models, dataloader, etc., this scripts expects a
	few common configuration parameters currently defined in "configs/common/train.py".
	To add more complicated training logic, you can easily add other configs
	in the config file and implement a new train_net.py to handle them.
	"""
	import logging
	import os
	import sys
	import time
	import torch
	from torch.nn.parallel import DataParallel, DistributedDataParallel

	from detectron2.checkpoint import DetectionCheckpointer
	from detectron2.config import LazyConfig, instantiate
	from detectron2.engine import (
	SimpleTrainer,
	default_argument_parser,
	default_setup,
	default_writers,
	hooks,
	launch,
	)
	from detectron2.engine.defaults import create_ddp_model
	from detectron2.evaluation import inference_on_dataset, print_csv_format
	from detectron2.utils import comm

	sys.path.append(os.path.abspath(os.path.join(os.path.dirname(__file__), os.path.pardir)))

	logger = logging.getLogger("detrex")


	def match_name_keywords(n, name_keywords):
	out = False
	for b in name_keywords:
	if b in n:
	out = True
	break
	return out


	class Trainer(SimpleTrainer):
	"""
	We've combine Simple and AMP Trainer together.
	"""

	def __init__(
	self,
	model,
	dataloader,
	optimizer,
	amp=False,
	clip_grad_params=None,
	grad_scaler=None,
	):
	super().__init__(model=model, data_loader=dataloader, optimizer=optimizer)

	unsupported = "AMPTrainer does not support single-process multi-device training!"
	if isinstance(model, DistributedDataParallel):
	assert not (model.device_ids and len(model.device_ids) > 1), unsupported
	assert not isinstance(model, DataParallel), unsupported

	if amp:
	if grad_scaler is None:
	from torch.cuda.amp import GradScaler

	grad_scaler = GradScaler()
	self.grad_scaler = grad_scaler

	# set True to use amp training
	self.amp = amp

	# gradient clip hyper-params
	self.clip_grad_params = clip_grad_params

	def run_step(self):
	"""
	Implement the standard training logic described above.
	"""
	assert self.model.training, "[Trainer] model was changed to eval mode!"
	assert torch.cuda.is_available(), "[Trainer] CUDA is required for AMP training!"
	from torch.cuda.amp import autocast

	start = time.perf_counter()
	"""
	If you want to do something with the data, you can wrap the dataloader.
	"""
	data = next(self._data_loader_iter)
	data_time = time.perf_counter() - start

	"""
	If you want to do something with the losses, you can wrap the model.
	"""
	loss_dict = self.model(data)
	with autocast(enabled=self.amp):
	if isinstance(loss_dict, torch.Tensor):
	losses = loss_dict
	loss_dict = {"total_loss": loss_dict}
	else:
	losses = sum(loss_dict.values())

	"""
	If you need to accumulate gradients or do something similar, you can
	wrap the optimizer with your custom `zero_grad()` method.
	"""
	self.optimizer.zero_grad()

	if self.amp:
	self.grad_scaler.scale(losses).backward()
	if self.clip_grad_params is not None:
	self.grad_scaler.unscale_(self.optimizer)
	self.clip_grads(self.model.parameters())
	self.grad_scaler.step(self.optimizer)
	self.grad_scaler.update()
	else:
	losses.backward()
	if self.clip_grad_params is not None:
	self.clip_grads(self.model.parameters())
	self.optimizer.step()

	self._write_metrics(loss_dict, data_time)

	def clip_grads(self, params):
	params = list(filter(lambda p: p.requires_grad and p.grad is not None, params))
	if len(params) > 0:
	return torch.nn.utils.clip_grad_norm_(
	parameters=params,
	**self.clip_grad_params,
	)


	def do_test(cfg, model):
	if "evaluator" in cfg.dataloader:
	ret = inference_on_dataset(
	model, instantiate(cfg.dataloader.test), instantiate(cfg.dataloader.evaluator)
	)
	print_csv_format(ret)
	return ret


	def do_train(args, cfg):
	"""
	Args:
	cfg: an object with the following attributes:
	model: instantiate to a module
	dataloader.{train,test}: instantiate to dataloaders
	dataloader.evaluator: instantiate to evaluator for test set
	optimizer: instantaite to an optimizer
	lr_multiplier: instantiate to a fvcore scheduler
	train: other misc config defined in `configs/common/train.py`, including:
	output_dir (str)
	init_checkpoint (str)
	amp.enabled (bool)
	max_iter (int)
	eval_period, log_period (int)
	device (str)
	checkpointer (dict)
	ddp (dict)
	"""
	model = instantiate(cfg.model)
	logger = logging.getLogger("detectron2")
	logger.info("Model:\n{}".format(model))
	model.to(cfg.train.device)

	# this is an hack of train_net
	param_dicts = [
	{
	"params": [
	p
	for n, p in model.named_parameters()
	if not match_name_keywords(n, ["backbone"])
	and not match_name_keywords(n, ["reference_points", "sampling_offsets"])
	and p.requires_grad
	],
	"lr": 2e-4,
	},
	{
	"params": [
	p
	for n, p in model.named_parameters()
	if match_name_keywords(n, ["backbone"]) and p.requires_grad
	],
	"lr": 2e-5,
	},
	{
	"params": [
	p
	for n, p in model.named_parameters()
	if match_name_keywords(n, ["reference_points", "sampling_offsets"])
	and p.requires_grad
	],
	"lr": 2e-5,
	},
	]
	optim = torch.optim.AdamW(param_dicts, 2e-4, weight_decay=1e-4)

	train_loader = instantiate(cfg.dataloader.train)

	model = create_ddp_model(model, **cfg.train.ddp)

	trainer = Trainer(
	model=model,
	dataloader=train_loader,
	optimizer=optim,
	amp=cfg.train.amp.enabled,
	clip_grad_params=cfg.train.clip_grad.params if cfg.train.clip_grad.enabled else None,
	)

	checkpointer = DetectionCheckpointer(
	model,
	cfg.train.output_dir,
	trainer=trainer,
	)

	trainer.register_hooks(
	[
	hooks.IterationTimer(),
	hooks.LRScheduler(scheduler=instantiate(cfg.lr_multiplier)),
	hooks.PeriodicCheckpointer(checkpointer, **cfg.train.checkpointer)
	if comm.is_main_process()
	else None,
	hooks.EvalHook(cfg.train.eval_period, lambda: do_test(cfg, model)),
	hooks.PeriodicWriter(
	default_writers(cfg.train.output_dir, cfg.train.max_iter),
	period=cfg.train.log_period,
	)
	if comm.is_main_process()
	else None,
	]
	)

	checkpointer.resume_or_load(cfg.train.init_checkpoint, resume=args.resume)
	if args.resume and checkpointer.has_checkpoint():
	# The checkpoint stores the training iteration that just finished, thus we start
	# at the next iteration
	start_iter = trainer.iter + 1
	else:
	start_iter = 0
	trainer.train(start_iter, cfg.train.max_iter)


	def main(args):
	cfg = LazyConfig.load(args.config_file)
	cfg = LazyConfig.apply_overrides(cfg, args.opts)
	default_setup(cfg, args)

	if args.eval_only:
	model = instantiate(cfg.model)
	model.to(cfg.train.device)
	model = create_ddp_model(model)
	DetectionCheckpointer(model).load(cfg.train.init_checkpoint)
	print(do_test(cfg, model))
	else:
	do_train(args, cfg)


	if __name__ == "__main__":
	args = default_argument_parser().parse_args()
	launch(
	main,
	args.num_gpus,
	num_machines=args.num_machines,
	machine_rank=args.machine_rank,
	dist_url=args.dist_url,
	args=(args,),
	)