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cyclegan-cut

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cyclegan-cut / train.py

qninhdt

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	import time
	import torch
	from options.train_options import TrainOptions
	from data import create_dataset
	from models import create_model
	from util.visualizer import Visualizer


	if __name__ == "__main__":
	opt = TrainOptions().parse() # get training options
	dataset = create_dataset(
	opt
	) # create a dataset given opt.dataset_mode and other options
	dataset_size = len(dataset) # get the number of images in the dataset.

	model = create_model(opt)
	# create a model given opt.model and other options
	print("The number of training images = %d" % dataset_size)

	visualizer = Visualizer(
	opt
	) # create a visualizer that display/save images and plots
	opt.visualizer = visualizer
	total_iters = 0 # the total number of training iterations

	optimize_time = 0.1

	times = []
	for epoch in range(
	opt.epoch_count, opt.n_epochs + opt.n_epochs_decay + 1
	): # outer loop for different epochs; we save the model by <epoch_count>, <epoch_count>+<save_latest_freq>
	epoch_start_time = time.time() # timer for entire epoch
	iter_data_time = time.time() # timer for data loading per iteration
	epoch_iter = 0 # the number of training iterations in current epoch, reset to 0 every epoch
	visualizer.reset() # reset the visualizer: make sure it saves the results to HTML at least once every epoch

	dataset.set_epoch(epoch)
	for i, data in enumerate(dataset): # inner loop within one epoch
	iter_start_time = time.time() # timer for computation per iteration
	if total_iters % opt.print_freq == 0:
	t_data = iter_start_time - iter_data_time

	batch_size = data["A"].size(0)
	total_iters += batch_size
	epoch_iter += batch_size
	if len(opt.gpu_ids) > 0:
	torch.cuda.synchronize()
	optimize_start_time = time.time()
	if epoch == opt.epoch_count and i == 0:
	model.data_dependent_initialize(data)
	model.setup(
	opt
	) # regular setup: load and print networks; create schedulers
	model.parallelize()
	model.set_input(data) # unpack data from dataset and apply preprocessing
	model.optimize_parameters() # calculate loss functions, get gradients, update network weights
	if len(opt.gpu_ids) > 0:
	torch.cuda.synchronize()
	optimize_time = (
	time.time() - optimize_start_time
	) / batch_size * 0.005 + 0.995 * optimize_time

	if (
	total_iters % opt.display_freq == 0
	): # display images on visdom and save images to a HTML file
	save_result = total_iters % opt.update_html_freq == 0
	model.compute_visuals()
	visualizer.display_current_results(
	model.get_current_visuals(), epoch, save_result
	)

	if (
	total_iters % opt.print_freq == 0
	): # print training losses and save logging information to the disk
	losses = model.get_current_losses()
	visualizer.print_current_losses(
	epoch, epoch_iter, losses, optimize_time, t_data
	)
	if opt.display_id is None or opt.display_id > 0:
	visualizer.plot_current_losses(
	epoch, float(epoch_iter) / dataset_size, losses
	)

	if (
	total_iters % opt.save_latest_freq == 0
	): # cache our latest model every <save_latest_freq> iterations
	print(
	"saving the latest model (epoch %d, total_iters %d)"
	% (epoch, total_iters)
	)
	print(
	opt.name
	) # it's useful to occasionally show the experiment name on console
	save_suffix = "iter_%d" % total_iters if opt.save_by_iter else "latest"
	model.save_networks(save_suffix)

	iter_data_time = time.time()

	if (
	epoch % opt.save_epoch_freq == 0
	): # cache our model every <save_epoch_freq> epochs
	print(
	"saving the model at the end of epoch %d, iters %d"
	% (epoch, total_iters)
	)
	model.save_networks("latest")
	model.save_networks(epoch)

	print(
	"End of epoch %d / %d \t Time Taken: %d sec"
	% (epoch, opt.n_epochs + opt.n_epochs_decay, time.time() - epoch_start_time)
	)
	model.update_learning_rate() # update learning rates at the end of every epoch.