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BasicSR/basicsr/metrics/psnr_ssim.py 0 → 100644
View file @ e2696ece
import cv2
import numpy as np
import torch
import torch.nn.functional as F
from basicsr.metrics.metric_util import reorder_image, to_y_channel
from basicsr.utils.color_util import rgb2ycbcr_pt
from basicsr.utils.registry import METRIC_REGISTRY
@METRIC_REGISTRY.register()
def calculate_psnr(img, img2, crop_border, input_order='HWC', test_y_channel=False, **kwargs):
"""Calculate PSNR (Peak Signal-to-Noise Ratio).
Reference: https://en.wikipedia.org/wiki/Peak_signal-to-noise_ratio
Args:
img (ndarray): Images with range [0, 255].
img2 (ndarray): Images with range [0, 255].
crop_border (int): Cropped pixels in each edge of an image. These pixels are not involved in the calculation.
input_order (str): Whether the input order is 'HWC' or 'CHW'. Default: 'HWC'.
test_y_channel (bool): Test on Y channel of YCbCr. Default: False.
Returns:
float: PSNR result.
"""
assert img.shape == img2.shape, (f'Image shapes are different: {img.shape}, {img2.shape}.')
if input_order not in ['HWC', 'CHW']:
raise ValueError(f'Wrong input_order {input_order}. Supported input_orders are "HWC" and "CHW"')
img = reorder_image(img, input_order=input_order)
img2 = reorder_image(img2, input_order=input_order)
if crop_border != 0:
img = img[crop_border:-crop_border, crop_border:-crop_border, ...]
img2 = img2[crop_border:-crop_border, crop_border:-crop_border, ...]
if test_y_channel:
img = to_y_channel(img)
img2 = to_y_channel(img2)
img = img.astype(np.float64)
img2 = img2.astype(np.float64)
mse = np.mean((img - img2)**2)
if mse == 0:
return float('inf')
return 10. * np.log10(255. * 255. / mse)
@METRIC_REGISTRY.register()
def calculate_psnr_pt(img, img2, crop_border, test_y_channel=False, **kwargs):
"""Calculate PSNR (Peak Signal-to-Noise Ratio) (PyTorch version).
Reference: https://en.wikipedia.org/wiki/Peak_signal-to-noise_ratio
Args:
img (Tensor): Images with range [0, 1], shape (n, 3/1, h, w).
img2 (Tensor): Images with range [0, 1], shape (n, 3/1, h, w).
crop_border (int): Cropped pixels in each edge of an image. These pixels are not involved in the calculation.
test_y_channel (bool): Test on Y channel of YCbCr. Default: False.
Returns:
float: PSNR result.
"""
assert img.shape == img2.shape, (f'Image shapes are different: {img.shape}, {img2.shape}.')
if crop_border != 0:
img = img[:, :, crop_border:-crop_border, crop_border:-crop_border]
img2 = img2[:, :, crop_border:-crop_border, crop_border:-crop_border]
if test_y_channel:
img = rgb2ycbcr_pt(img, y_only=True)
img2 = rgb2ycbcr_pt(img2, y_only=True)
img = img.to(torch.float64)
img2 = img2.to(torch.float64)
mse = torch.mean((img - img2)**2, dim=[1, 2, 3])
return 10. * torch.log10(1. / (mse + 1e-8))
@METRIC_REGISTRY.register()
def calculate_ssim(img, img2, crop_border, input_order='HWC', test_y_channel=False, **kwargs):
"""Calculate SSIM (structural similarity).
``Paper: Image quality assessment: From error visibility to structural similarity``
The results are the same as that of the official released MATLAB code in
https://ece.uwaterloo.ca/~z70wang/research/ssim/.
For three-channel images, SSIM is calculated for each channel and then
averaged.
Args:
img (ndarray): Images with range [0, 255].
img2 (ndarray): Images with range [0, 255].
crop_border (int): Cropped pixels in each edge of an image. These pixels are not involved in the calculation.
input_order (str): Whether the input order is 'HWC' or 'CHW'.
Default: 'HWC'.
test_y_channel (bool): Test on Y channel of YCbCr. Default: False.
Returns:
float: SSIM result.
"""
assert img.shape == img2.shape, (f'Image shapes are different: {img.shape}, {img2.shape}.')
if input_order not in ['HWC', 'CHW']:
raise ValueError(f'Wrong input_order {input_order}. Supported input_orders are "HWC" and "CHW"')
img = reorder_image(img, input_order=input_order)
img2 = reorder_image(img2, input_order=input_order)
if crop_border != 0:
img = img[crop_border:-crop_border, crop_border:-crop_border, ...]
img2 = img2[crop_border:-crop_border, crop_border:-crop_border, ...]
if test_y_channel:
img = to_y_channel(img)
img2 = to_y_channel(img2)
img = img.astype(np.float64)
img2 = img2.astype(np.float64)
ssims = []
for i in range(img.shape[2]):
ssims.append(_ssim(img[..., i], img2[..., i]))
return np.array(ssims).mean()
@METRIC_REGISTRY.register()
def calculate_ssim_pt(img, img2, crop_border, test_y_channel=False, **kwargs):
"""Calculate SSIM (structural similarity) (PyTorch version).
``Paper: Image quality assessment: From error visibility to structural similarity``
The results are the same as that of the official released MATLAB code in
https://ece.uwaterloo.ca/~z70wang/research/ssim/.
For three-channel images, SSIM is calculated for each channel and then
averaged.
Args:
img (Tensor): Images with range [0, 1], shape (n, 3/1, h, w).
img2 (Tensor): Images with range [0, 1], shape (n, 3/1, h, w).
crop_border (int): Cropped pixels in each edge of an image. These pixels are not involved in the calculation.
test_y_channel (bool): Test on Y channel of YCbCr. Default: False.
Returns:
float: SSIM result.
"""
assert img.shape == img2.shape, (f'Image shapes are different: {img.shape}, {img2.shape}.')
if crop_border != 0:
img = img[:, :, crop_border:-crop_border, crop_border:-crop_border]
img2 = img2[:, :, crop_border:-crop_border, crop_border:-crop_border]
if test_y_channel:
img = rgb2ycbcr_pt(img, y_only=True)
img2 = rgb2ycbcr_pt(img2, y_only=True)
img = img.to(torch.float64)
img2 = img2.to(torch.float64)
ssim = _ssim_pth(img * 255., img2 * 255.)
return ssim
def _ssim(img, img2):
"""Calculate SSIM (structural similarity) for one channel images.
It is called by func:`calculate_ssim`.
Args:
img (ndarray): Images with range [0, 255] with order 'HWC'.
img2 (ndarray): Images with range [0, 255] with order 'HWC'.
Returns:
float: SSIM result.
"""
c1 = (0.01 * 255)**2
c2 = (0.03 * 255)**2
kernel = cv2.getGaussianKernel(11, 1.5)
window = np.outer(kernel, kernel.transpose())
mu1 = cv2.filter2D(img, -1, window)[5:-5, 5:-5] # valid mode for window size 11
mu2 = cv2.filter2D(img2, -1, window)[5:-5, 5:-5]
mu1_sq = mu1**2
mu2_sq = mu2**2
mu1_mu2 = mu1 * mu2
sigma1_sq = cv2.filter2D(img**2, -1, window)[5:-5, 5:-5] - mu1_sq
sigma2_sq = cv2.filter2D(img2**2, -1, window)[5:-5, 5:-5] - mu2_sq
sigma12 = cv2.filter2D(img * img2, -1, window)[5:-5, 5:-5] - mu1_mu2
ssim_map = ((2 * mu1_mu2 + c1) * (2 * sigma12 + c2)) / ((mu1_sq + mu2_sq + c1) * (sigma1_sq + sigma2_sq + c2))
return ssim_map.mean()
def _ssim_pth(img, img2):
"""Calculate SSIM (structural similarity) (PyTorch version).
It is called by func:`calculate_ssim_pt`.
Args:
img (Tensor): Images with range [0, 1], shape (n, 3/1, h, w).
img2 (Tensor): Images with range [0, 1], shape (n, 3/1, h, w).
Returns:
float: SSIM result.
"""
c1 = (0.01 * 255)**2
c2 = (0.03 * 255)**2
kernel = cv2.getGaussianKernel(11, 1.5)
window = np.outer(kernel, kernel.transpose())
window = torch.from_numpy(window).view(1, 1, 11, 11).expand(img.size(1), 1, 11, 11).to(img.dtype).to(img.device)
mu1 = F.conv2d(img, window, stride=1, padding=0, groups=img.shape[1]) # valid mode
mu2 = F.conv2d(img2, window, stride=1, padding=0, groups=img2.shape[1]) # valid mode
mu1_sq = mu1.pow(2)
mu2_sq = mu2.pow(2)
mu1_mu2 = mu1 * mu2
sigma1_sq = F.conv2d(img * img, window, stride=1, padding=0, groups=img.shape[1]) - mu1_sq
sigma2_sq = F.conv2d(img2 * img2, window, stride=1, padding=0, groups=img.shape[1]) - mu2_sq
sigma12 = F.conv2d(img * img2, window, stride=1, padding=0, groups=img.shape[1]) - mu1_mu2
cs_map = (2 * sigma12 + c2) / (sigma1_sq + sigma2_sq + c2)
ssim_map = ((2 * mu1_mu2 + c1) / (mu1_sq + mu2_sq + c1)) * cs_map
return ssim_map.mean([1, 2, 3])
BasicSR/basicsr/metrics/test_metrics/test_psnr_ssim.py 0 → 100644
View file @ e2696ece
import cv2
import torch
from basicsr.metrics import calculate_psnr, calculate_ssim
from basicsr.metrics.psnr_ssim import calculate_psnr_pt, calculate_ssim_pt
from basicsr.utils import img2tensor
def test(img_path, img_path2, crop_border, test_y_channel=False):
img = cv2.imread(img_path, cv2.IMREAD_UNCHANGED)
img2 = cv2.imread(img_path2, cv2.IMREAD_UNCHANGED)
# --------------------- Numpy ---------------------
psnr = calculate_psnr(img, img2, crop_border=crop_border, input_order='HWC', test_y_channel=test_y_channel)
ssim = calculate_ssim(img, img2, crop_border=crop_border, input_order='HWC', test_y_channel=test_y_channel)
print(f'\tNumpy\tPSNR: {psnr:.6f} dB, \tSSIM: {ssim:.6f}')
# --------------------- PyTorch (CPU) ---------------------
img = img2tensor(img / 255., bgr2rgb=True, float32=True).unsqueeze_(0)
img2 = img2tensor(img2 / 255., bgr2rgb=True, float32=True).unsqueeze_(0)
psnr_pth = calculate_psnr_pt(img, img2, crop_border=crop_border, test_y_channel=test_y_channel)
ssim_pth = calculate_ssim_pt(img, img2, crop_border=crop_border, test_y_channel=test_y_channel)
print(f'\tTensor (CPU) \tPSNR: {psnr_pth[0]:.6f} dB, \tSSIM: {ssim_pth[0]:.6f}')
# --------------------- PyTorch (GPU) ---------------------
img = img.cuda()
img2 = img2.cuda()
psnr_pth = calculate_psnr_pt(img, img2, crop_border=crop_border, test_y_channel=test_y_channel)
ssim_pth = calculate_ssim_pt(img, img2, crop_border=crop_border, test_y_channel=test_y_channel)
print(f'\tTensor (GPU) \tPSNR: {psnr_pth[0]:.6f} dB, \tSSIM: {ssim_pth[0]:.6f}')
psnr_pth = calculate_psnr_pt(
torch.repeat_interleave(img, 2, dim=0),
torch.repeat_interleave(img2, 2, dim=0),
crop_border=crop_border,
test_y_channel=test_y_channel)
ssim_pth = calculate_ssim_pt(
torch.repeat_interleave(img, 2, dim=0),
torch.repeat_interleave(img2, 2, dim=0),
crop_border=crop_border,
test_y_channel=test_y_channel)
print(f'\tTensor (GPU batch) \tPSNR: {psnr_pth[0]:.6f}, {psnr_pth[1]:.6f} dB,'
f'\tSSIM: {ssim_pth[0]:.6f}, {ssim_pth[1]:.6f}')
if __name__ == '__main__':
test('tests/data/bic/baboon.png', 'tests/data/gt/baboon.png', crop_border=4, test_y_channel=False)
test('tests/data/bic/baboon.png', 'tests/data/gt/baboon.png', crop_border=4, test_y_channel=True)
test('tests/data/bic/comic.png', 'tests/data/gt/comic.png', crop_border=4, test_y_channel=False)
test('tests/data/bic/comic.png', 'tests/data/gt/comic.png', crop_border=4, test_y_channel=True)
BasicSR/basicsr/models/__init__.py 0 → 100644
View file @ e2696ece
import importlib
from copy import deepcopy
from os import path as osp
from basicsr.utils import get_root_logger, scandir
from basicsr.utils.registry import MODEL_REGISTRY
__all__ = ['build_model']
# automatically scan and import model modules for registry
# scan all the files under the 'models' folder and collect files ending with '_model.py'
model_folder = osp.dirname(osp.abspath(__file__))
model_filenames = [osp.splitext(osp.basename(v))[0] for v in scandir(model_folder) if v.endswith('_model.py')]
# import all the model modules
_model_modules = [importlib.import_module(f'basicsr.models.{file_name}') for file_name in model_filenames]
def build_model(opt):
"""Build model from options.
Args:
opt (dict): Configuration. It must contain:
model_type (str): Model type.
"""
opt = deepcopy(opt)
model = MODEL_REGISTRY.get(opt['model_type'])(opt)
logger = get_root_logger()
logger.info(f'Model [{model.__class__.__name__}] is created.')
return model
BasicSR/basicsr/models/base_model.py 0 → 100644
View file @ e2696ece
import os
import time
import torch
from collections import OrderedDict
from copy import deepcopy
from torch.nn.parallel import DataParallel, DistributedDataParallel
from basicsr.models import lr_scheduler as lr_scheduler
from basicsr.utils import get_root_logger
from basicsr.utils.dist_util import master_only
class BaseModel():
"""Base model."""
def __init__(self, opt):
self.opt = opt
self.device = torch.device('cuda' if opt['num_gpu'] != 0 else 'cpu')
self.is_train = opt['is_train']
self.schedulers = []
self.optimizers = []
def feed_data(self, data):
pass
def optimize_parameters(self):
pass
def get_current_visuals(self):
pass
def save(self, epoch, current_iter):
"""Save networks and training state."""
pass
def validation(self, dataloader, current_iter, tb_logger, save_img=False):
"""Validation function.
Args:
dataloader (torch.utils.data.DataLoader): Validation dataloader.
current_iter (int): Current iteration.
tb_logger (tensorboard logger): Tensorboard logger.
save_img (bool): Whether to save images. Default: False.
"""
if self.opt['dist']:
self.dist_validation(dataloader, current_iter, tb_logger, save_img)
else:
self.nondist_validation(dataloader, current_iter, tb_logger, save_img)
def _initialize_best_metric_results(self, dataset_name):
"""Initialize the best metric results dict for recording the best metric value and iteration."""
if hasattr(self, 'best_metric_results') and dataset_name in self.best_metric_results:
return
elif not hasattr(self, 'best_metric_results'):
self.best_metric_results = dict()
# add a dataset record
record = dict()
for metric, content in self.opt['val']['metrics'].items():
better = content.get('better', 'higher')
init_val = float('-inf') if better == 'higher' else float('inf')
record[metric] = dict(better=better, val=init_val, iter=-1)
self.best_metric_results[dataset_name] = record
def _update_best_metric_result(self, dataset_name, metric, val, current_iter):
if self.best_metric_results[dataset_name][metric]['better'] == 'higher':
if val >= self.best_metric_results[dataset_name][metric]['val']:
self.best_metric_results[dataset_name][metric]['val'] = val
self.best_metric_results[dataset_name][metric]['iter'] = current_iter
else:
if val <= self.best_metric_results[dataset_name][metric]['val']:
self.best_metric_results[dataset_name][metric]['val'] = val
self.best_metric_results[dataset_name][metric]['iter'] = current_iter
def model_ema(self, decay=0.999):
net_g = self.get_bare_model(self.net_g)
net_g_params = dict(net_g.named_parameters())
net_g_ema_params = dict(self.net_g_ema.named_parameters())
for k in net_g_ema_params.keys():
net_g_ema_params[k].data.mul_(decay).add_(net_g_params[k].data, alpha=1 - decay)
def get_current_log(self):
return self.log_dict
def model_to_device(self, net):
"""Model to device. It also warps models with DistributedDataParallel
or DataParallel.
Args:
net (nn.Module)
"""
net = net.to(self.device)
if self.opt['dist']:
find_unused_parameters = self.opt.get('find_unused_parameters', False)
net = DistributedDataParallel(
net, device_ids=[torch.cuda.current_device()], find_unused_parameters=find_unused_parameters)
elif self.opt['num_gpu'] > 1:
net = DataParallel(net)
return net
def get_optimizer(self, optim_type, params, lr, **kwargs):
if optim_type == 'Adam':
optimizer = torch.optim.Adam(params, lr, **kwargs)
elif optim_type == 'AdamW':
optimizer = torch.optim.AdamW(params, lr, **kwargs)
elif optim_type == 'Adamax':
optimizer = torch.optim.Adamax(params, lr, **kwargs)
elif optim_type == 'SGD':
optimizer = torch.optim.SGD(params, lr, **kwargs)
elif optim_type == 'ASGD':
optimizer = torch.optim.ASGD(params, lr, **kwargs)
elif optim_type == 'RMSprop':
optimizer = torch.optim.RMSprop(params, lr, **kwargs)
elif optim_type == 'Rprop':
optimizer = torch.optim.Rprop(params, lr, **kwargs)
else:
raise NotImplementedError(f'optimizer {optim_type} is not supported yet.')
return optimizer
def setup_schedulers(self):
"""Set up schedulers."""
train_opt = self.opt['train']
scheduler_type = train_opt['scheduler'].pop('type')
if scheduler_type in ['MultiStepLR', 'MultiStepRestartLR']:
for optimizer in self.optimizers:
self.schedulers.append(lr_scheduler.MultiStepRestartLR(optimizer, **train_opt['scheduler']))
elif scheduler_type == 'CosineAnnealingRestartLR':
for optimizer in self.optimizers:
self.schedulers.append(lr_scheduler.CosineAnnealingRestartLR(optimizer, **train_opt['scheduler']))
else:
raise NotImplementedError(f'Scheduler {scheduler_type} is not implemented yet.')
def get_bare_model(self, net):
"""Get bare model, especially under wrapping with
DistributedDataParallel or DataParallel.
"""
if isinstance(net, (DataParallel, DistributedDataParallel)):
net = net.module
return net
@master_only
def print_network(self, net):
"""Print the str and parameter number of a network.
Args:
net (nn.Module)
"""
if isinstance(net, (DataParallel, DistributedDataParallel)):
net_cls_str = f'{net.__class__.__name__} - {net.module.__class__.__name__}'
else:
net_cls_str = f'{net.__class__.__name__}'
net = self.get_bare_model(net)
net_str = str(net)
net_params = sum(map(lambda x: x.numel(), net.parameters()))
logger = get_root_logger()
logger.info(f'Network: {net_cls_str}, with parameters: {net_params:,d}')
logger.info(net_str)
def _set_lr(self, lr_groups_l):
"""Set learning rate for warm-up.
Args:
lr_groups_l (list): List for lr_groups, each for an optimizer.
"""
for optimizer, lr_groups in zip(self.optimizers, lr_groups_l):
for param_group, lr in zip(optimizer.param_groups, lr_groups):
param_group['lr'] = lr
def _get_init_lr(self):
"""Get the initial lr, which is set by the scheduler.
"""
init_lr_groups_l = []
for optimizer in self.optimizers:
init_lr_groups_l.append([v['initial_lr'] for v in optimizer.param_groups])
return init_lr_groups_l
def update_learning_rate(self, current_iter, warmup_iter=-1):
"""Update learning rate.
Args:
current_iter (int): Current iteration.
warmup_iter (int): Warm-up iter numbers. -1 for no warm-up.
Default: -1.
"""
if current_iter > 1:
for scheduler in self.schedulers:
scheduler.step()
# set up warm-up learning rate
if current_iter < warmup_iter:
# get initial lr for each group
init_lr_g_l = self._get_init_lr()
# modify warming-up learning rates
# currently only support linearly warm up
warm_up_lr_l = []
for init_lr_g in init_lr_g_l:
warm_up_lr_l.append([v / warmup_iter * current_iter for v in init_lr_g])
# set learning rate
self._set_lr(warm_up_lr_l)
def get_current_learning_rate(self):
return [param_group['lr'] for param_group in self.optimizers[0].param_groups]
@master_only
def save_network(self, net, net_label, current_iter, param_key='params'):
"""Save networks.
Args:
net (nn.Module | list[nn.Module]): Network(s) to be saved.
net_label (str): Network label.
current_iter (int): Current iter number.
param_key (str | list[str]): The parameter key(s) to save network.
Default: 'params'.
"""
if current_iter == -1:
current_iter = 'latest'
save_filename = f'{net_label}_{current_iter}.pth'
save_path = os.path.join(self.opt['path']['models'], save_filename)
net = net if isinstance(net, list) else [net]
param_key = param_key if isinstance(param_key, list) else [param_key]
assert len(net) == len(param_key), 'The lengths of net and param_key should be the same.'
save_dict = {}
for net_, param_key_ in zip(net, param_key):
net_ = self.get_bare_model(net_)
state_dict = net_.state_dict()
for key, param in state_dict.items():
if key.startswith('module.'): # remove unnecessary 'module.'
key = key[7:]
state_dict[key] = param.cpu()
save_dict[param_key_] = state_dict
# avoid occasional writing errors
retry = 3
while retry > 0:
try:
torch.save(save_dict, save_path)
except Exception as e:
logger = get_root_logger()
logger.warning(f'Save model error: {e}, remaining retry times: {retry - 1}')
time.sleep(1)
else:
break
finally:
retry -= 1
if retry == 0:
logger.warning(f'Still cannot save {save_path}. Just ignore it.')
# raise IOError(f'Cannot save {save_path}.')
def _print_different_keys_loading(self, crt_net, load_net, strict=True):
"""Print keys with different name or different size when loading models.
1. Print keys with different names.
2. If strict=False, print the same key but with different tensor size.
It also ignore these keys with different sizes (not load).
Args:
crt_net (torch model): Current network.
load_net (dict): Loaded network.
strict (bool): Whether strictly loaded. Default: True.
"""
crt_net = self.get_bare_model(crt_net)
crt_net = crt_net.state_dict()
crt_net_keys = set(crt_net.keys())
load_net_keys = set(load_net.keys())
logger = get_root_logger()
if crt_net_keys != load_net_keys:
logger.warning('Current net - loaded net:')
for v in sorted(list(crt_net_keys - load_net_keys)):
logger.warning(f' {v}')
logger.warning('Loaded net - current net:')
for v in sorted(list(load_net_keys - crt_net_keys)):
logger.warning(f' {v}')
# check the size for the same keys
if not strict:
common_keys = crt_net_keys & load_net_keys
for k in common_keys:
if crt_net[k].size() != load_net[k].size():
logger.warning(f'Size different, ignore [{k}]: crt_net: '
f'{crt_net[k].shape}; load_net: {load_net[k].shape}')
load_net[k + '.ignore'] = load_net.pop(k)
def load_network(self, net, load_path, strict=True, param_key='params'):
"""Load network.
Args:
load_path (str): The path of networks to be loaded.
net (nn.Module): Network.
strict (bool): Whether strictly loaded.
param_key (str): The parameter key of loaded network. If set to
None, use the root 'path'.
Default: 'params'.
"""
logger = get_root_logger()
net = self.get_bare_model(net)
load_net = torch.load(load_path, map_location=lambda storage, loc: storage)
if param_key is not None:
if param_key not in load_net and 'params' in load_net:
param_key = 'params'
logger.info('Loading: params_ema does not exist, use params.')
load_net = load_net[param_key]
logger.info(f'Loading {net.__class__.__name__} model from {load_path}, with param key: [{param_key}].')
# remove unnecessary 'module.'
for k, v in deepcopy(load_net).items():
if k.startswith('module.'):
load_net[k[7:]] = v
load_net.pop(k)
self._print_different_keys_loading(net, load_net, strict)
net.load_state_dict(load_net, strict=strict)
@master_only
def save_training_state(self, epoch, current_iter):
"""Save training states during training, which will be used for
resuming.
Args:
epoch (int): Current epoch.
current_iter (int): Current iteration.
"""
if current_iter != -1:
state = {'epoch': epoch, 'iter': current_iter, 'optimizers': [], 'schedulers': []}
for o in self.optimizers:
state['optimizers'].append(o.state_dict())
for s in self.schedulers:
state['schedulers'].append(s.state_dict())
save_filename = f'{current_iter}.state'
save_path = os.path.join(self.opt['path']['training_states'], save_filename)
# avoid occasional writing errors
retry = 3
while retry > 0:
try:
torch.save(state, save_path)
except Exception as e:
logger = get_root_logger()
logger.warning(f'Save training state error: {e}, remaining retry times: {retry - 1}')
time.sleep(1)
else:
break
finally:
retry -= 1
if retry == 0:
logger.warning(f'Still cannot save {save_path}. Just ignore it.')
# raise IOError(f'Cannot save {save_path}.')
def resume_training(self, resume_state):
"""Reload the optimizers and schedulers for resumed training.
Args:
resume_state (dict): Resume state.
"""
resume_optimizers = resume_state['optimizers']
resume_schedulers = resume_state['schedulers']
assert len(resume_optimizers) == len(self.optimizers), 'Wrong lengths of optimizers'
assert len(resume_schedulers) == len(self.schedulers), 'Wrong lengths of schedulers'
for i, o in enumerate(resume_optimizers):
self.optimizers[i].load_state_dict(o)
for i, s in enumerate(resume_schedulers):
self.schedulers[i].load_state_dict(s)
def reduce_loss_dict(self, loss_dict):
"""reduce loss dict.
In distributed training, it averages the losses among different GPUs .
Args:
loss_dict (OrderedDict): Loss dict.
"""
with torch.no_grad():
if self.opt['dist']:
keys = []
losses = []
for name, value in loss_dict.items():
keys.append(name)
losses.append(value)
losses = torch.stack(losses, 0)
torch.distributed.reduce(losses, dst=0)
if self.opt['rank'] == 0:
losses /= self.opt['world_size']
loss_dict = {key: loss for key, loss in zip(keys, losses)}
log_dict = OrderedDict()
for name, value in loss_dict.items():
log_dict[name] = value.mean().item()
return log_dict
BasicSR/basicsr/models/edvr_model.py 0 → 100644
View file @ e2696ece
from basicsr.utils import get_root_logger
from basicsr.utils.registry import MODEL_REGISTRY
from .video_base_model import VideoBaseModel
@MODEL_REGISTRY.register()
class EDVRModel(VideoBaseModel):
"""EDVR Model.
Paper: EDVR: Video Restoration with Enhanced Deformable Convolutional Networks. # noqa: E501
"""
def __init__(self, opt):
super(EDVRModel, self).__init__(opt)
if self.is_train:
self.train_tsa_iter = opt['train'].get('tsa_iter')
def setup_optimizers(self):
train_opt = self.opt['train']
dcn_lr_mul = train_opt.get('dcn_lr_mul', 1)
logger = get_root_logger()
logger.info(f'Multiple the learning rate for dcn with {dcn_lr_mul}.')
if dcn_lr_mul == 1:
optim_params = self.net_g.parameters()
else: # separate dcn params and normal params for different lr
normal_params = []
dcn_params = []
for name, param in self.net_g.named_parameters():
if 'dcn' in name:
dcn_params.append(param)
else:
normal_params.append(param)
optim_params = [
{ # add normal params first
'params': normal_params,
'lr': train_opt['optim_g']['lr']
},
{
'params': dcn_params,
'lr': train_opt['optim_g']['lr'] * dcn_lr_mul
},
]
optim_type = train_opt['optim_g'].pop('type')
self.optimizer_g = self.get_optimizer(optim_type, optim_params, **train_opt['optim_g'])
self.optimizers.append(self.optimizer_g)
def optimize_parameters(self, current_iter):
if self.train_tsa_iter:
if current_iter == 1:
logger = get_root_logger()
logger.info(f'Only train TSA module for {self.train_tsa_iter} iters.')
for name, param in self.net_g.named_parameters():
if 'fusion' not in name:
param.requires_grad = False
elif current_iter == self.train_tsa_iter:
logger = get_root_logger()
logger.warning('Train all the parameters.')
for param in self.net_g.parameters():
param.requires_grad = True
super(EDVRModel, self).optimize_parameters(current_iter)
BasicSR/basicsr/models/esrgan_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import OrderedDict
from basicsr.utils.registry import MODEL_REGISTRY
from .srgan_model import SRGANModel
@MODEL_REGISTRY.register()
class ESRGANModel(SRGANModel):
"""ESRGAN model for single image super-resolution."""
def optimize_parameters(self, current_iter):
# optimize net_g
for p in self.net_d.parameters():
p.requires_grad = False
self.optimizer_g.zero_grad()
self.output = self.net_g(self.lq)
l_g_total = 0
loss_dict = OrderedDict()
if (current_iter % self.net_d_iters == 0 and current_iter > self.net_d_init_iters):
# pixel loss
if self.cri_pix:
l_g_pix = self.cri_pix(self.output, self.gt)
l_g_total += l_g_pix
loss_dict['l_g_pix'] = l_g_pix
# perceptual loss
if self.cri_perceptual:
l_g_percep, l_g_style = self.cri_perceptual(self.output, self.gt)
if l_g_percep is not None:
l_g_total += l_g_percep
loss_dict['l_g_percep'] = l_g_percep
if l_g_style is not None:
l_g_total += l_g_style
loss_dict['l_g_style'] = l_g_style
# gan loss (relativistic gan)
real_d_pred = self.net_d(self.gt).detach()
fake_g_pred = self.net_d(self.output)
l_g_real = self.cri_gan(real_d_pred - torch.mean(fake_g_pred), False, is_disc=False)
l_g_fake = self.cri_gan(fake_g_pred - torch.mean(real_d_pred), True, is_disc=False)
l_g_gan = (l_g_real + l_g_fake) / 2
l_g_total += l_g_gan
loss_dict['l_g_gan'] = l_g_gan
l_g_total.backward()
self.optimizer_g.step()
# optimize net_d
for p in self.net_d.parameters():
p.requires_grad = True
self.optimizer_d.zero_grad()
# gan loss (relativistic gan)
# In order to avoid the error in distributed training:
# "Error detected in CudnnBatchNormBackward: RuntimeError: one of
# the variables needed for gradient computation has been modified by
# an inplace operation",
# we separate the backwards for real and fake, and also detach the
# tensor for calculating mean.
# real
fake_d_pred = self.net_d(self.output).detach()
real_d_pred = self.net_d(self.gt)
l_d_real = self.cri_gan(real_d_pred - torch.mean(fake_d_pred), True, is_disc=True) * 0.5
l_d_real.backward()
# fake
fake_d_pred = self.net_d(self.output.detach())
l_d_fake = self.cri_gan(fake_d_pred - torch.mean(real_d_pred.detach()), False, is_disc=True) * 0.5
l_d_fake.backward()
self.optimizer_d.step()
loss_dict['l_d_real'] = l_d_real
loss_dict['l_d_fake'] = l_d_fake
loss_dict['out_d_real'] = torch.mean(real_d_pred.detach())
loss_dict['out_d_fake'] = torch.mean(fake_d_pred.detach())
self.log_dict = self.reduce_loss_dict(loss_dict)
if self.ema_decay > 0:
self.model_ema(decay=self.ema_decay)
BasicSR/basicsr/models/hifacegan_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import OrderedDict
from os import path as osp
from tqdm import tqdm
from basicsr.archs import build_network
from basicsr.losses import build_loss
from basicsr.metrics import calculate_metric
from basicsr.utils import imwrite, tensor2img
from basicsr.utils.registry import MODEL_REGISTRY
from .sr_model import SRModel
@MODEL_REGISTRY.register()
class HiFaceGANModel(SRModel):
"""HiFaceGAN model for generic-purpose face restoration.
No prior modeling required, works for any degradations.
Currently doesn't support EMA for inference.
"""
def init_training_settings(self):
train_opt = self.opt['train']
self.ema_decay = train_opt.get('ema_decay', 0)
if self.ema_decay > 0:
raise (NotImplementedError('HiFaceGAN does not support EMA now. Pass'))
self.net_g.train()
self.net_d = build_network(self.opt['network_d'])
self.net_d = self.model_to_device(self.net_d)
self.print_network(self.net_d)
# define losses
# HiFaceGAN does not use pixel loss by default
if train_opt.get('pixel_opt'):
self.cri_pix = build_loss(train_opt['pixel_opt']).to(self.device)
else:
self.cri_pix = None
if train_opt.get('perceptual_opt'):
self.cri_perceptual = build_loss(train_opt['perceptual_opt']).to(self.device)
else:
self.cri_perceptual = None
if train_opt.get('feature_matching_opt'):
self.cri_feat = build_loss(train_opt['feature_matching_opt']).to(self.device)
else:
self.cri_feat = None
if self.cri_pix is None and self.cri_perceptual is None:
raise ValueError('Both pixel and perceptual losses are None.')
if train_opt.get('gan_opt'):
self.cri_gan = build_loss(train_opt['gan_opt']).to(self.device)
self.net_d_iters = train_opt.get('net_d_iters', 1)
self.net_d_init_iters = train_opt.get('net_d_init_iters', 0)
# set up optimizers and schedulers
self.setup_optimizers()
self.setup_schedulers()
def setup_optimizers(self):
train_opt = self.opt['train']
# optimizer g
optim_type = train_opt['optim_g'].pop('type')
self.optimizer_g = self.get_optimizer(optim_type, self.net_g.parameters(), **train_opt['optim_g'])
self.optimizers.append(self.optimizer_g)
# optimizer d
optim_type = train_opt['optim_d'].pop('type')
self.optimizer_d = self.get_optimizer(optim_type, self.net_d.parameters(), **train_opt['optim_d'])
self.optimizers.append(self.optimizer_d)
def discriminate(self, input_lq, output, ground_truth):
"""
This is a conditional (on the input) discriminator
In Batch Normalization, the fake and real images are
recommended to be in the same batch to avoid disparate
statistics in fake and real images.
So both fake and real images are fed to D all at once.
"""
h, w = output.shape[-2:]
if output.shape[-2:] != input_lq.shape[-2:]:
lq = torch.nn.functional.interpolate(input_lq, (h, w))
real = torch.nn.functional.interpolate(ground_truth, (h, w))
fake_concat = torch.cat([lq, output], dim=1)
real_concat = torch.cat([lq, real], dim=1)
else:
fake_concat = torch.cat([input_lq, output], dim=1)
real_concat = torch.cat([input_lq, ground_truth], dim=1)
fake_and_real = torch.cat([fake_concat, real_concat], dim=0)
discriminator_out = self.net_d(fake_and_real)
pred_fake, pred_real = self._divide_pred(discriminator_out)
return pred_fake, pred_real
@staticmethod
def _divide_pred(pred):
"""
Take the prediction of fake and real images from the combined batch.
The prediction contains the intermediate outputs of multiscale GAN,
so it's usually a list
"""
if type(pred) == list:
fake = []
real = []
for p in pred:
fake.append([tensor[:tensor.size(0) // 2] for tensor in p])
real.append([tensor[tensor.size(0) // 2:] for tensor in p])
else:
fake = pred[:pred.size(0) // 2]
real = pred[pred.size(0) // 2:]
return fake, real
def optimize_parameters(self, current_iter):
# optimize net_g
for p in self.net_d.parameters():
p.requires_grad = False
self.optimizer_g.zero_grad()
self.output = self.net_g(self.lq)
l_g_total = 0
loss_dict = OrderedDict()
if (current_iter % self.net_d_iters == 0 and current_iter > self.net_d_init_iters):
# pixel loss
if self.cri_pix:
l_g_pix = self.cri_pix(self.output, self.gt)
l_g_total += l_g_pix
loss_dict['l_g_pix'] = l_g_pix
# perceptual loss
if self.cri_perceptual:
l_g_percep, l_g_style = self.cri_perceptual(self.output, self.gt)
if l_g_percep is not None:
l_g_total += l_g_percep
loss_dict['l_g_percep'] = l_g_percep
if l_g_style is not None:
l_g_total += l_g_style
loss_dict['l_g_style'] = l_g_style
# Requires real prediction for feature matching loss
pred_fake, pred_real = self.discriminate(self.lq, self.output, self.gt)
l_g_gan = self.cri_gan(pred_fake, True, is_disc=False)
l_g_total += l_g_gan
loss_dict['l_g_gan'] = l_g_gan
# feature matching loss
if self.cri_feat:
l_g_feat = self.cri_feat(pred_fake, pred_real)
l_g_total += l_g_feat
loss_dict['l_g_feat'] = l_g_feat
l_g_total.backward()
self.optimizer_g.step()
# optimize net_d
for p in self.net_d.parameters():
p.requires_grad = True
self.optimizer_d.zero_grad()
# TODO: Benchmark test between HiFaceGAN and SRGAN implementation:
# SRGAN use the same fake output for discriminator update
# while HiFaceGAN regenerate a new output using updated net_g
# This should not make too much difference though. Stick to SRGAN now.
# -------------------------------------------------------------------
# ---------- Below are original HiFaceGAN code snippet --------------
# -------------------------------------------------------------------
# with torch.no_grad():
# fake_image = self.net_g(self.lq)
# fake_image = fake_image.detach()
# fake_image.requires_grad_()
# pred_fake, pred_real = self.discriminate(self.lq, fake_image, self.gt)
# real
pred_fake, pred_real = self.discriminate(self.lq, self.output.detach(), self.gt)
l_d_real = self.cri_gan(pred_real, True, is_disc=True)
loss_dict['l_d_real'] = l_d_real
# fake
l_d_fake = self.cri_gan(pred_fake, False, is_disc=True)
loss_dict['l_d_fake'] = l_d_fake
l_d_total = (l_d_real + l_d_fake) / 2
l_d_total.backward()
self.optimizer_d.step()
self.log_dict = self.reduce_loss_dict(loss_dict)
if self.ema_decay > 0:
print('HiFaceGAN does not support EMA now. pass')
def validation(self, dataloader, current_iter, tb_logger, save_img=False):
"""
Warning: HiFaceGAN requires train() mode even for validation
For more info, see https://github.com/Lotayou/Face-Renovation/issues/31
Args:
dataloader (torch.utils.data.DataLoader): Validation dataloader.
current_iter (int): Current iteration.
tb_logger (tensorboard logger): Tensorboard logger.
save_img (bool): Whether to save images. Default: False.
"""
if self.opt['network_g']['type'] in ('HiFaceGAN', 'SPADEGenerator'):
self.net_g.train()
if self.opt['dist']:
self.dist_validation(dataloader, current_iter, tb_logger, save_img)
else:
print('In HiFaceGANModel: The new metrics package is under development.' +
'Using super method now (Only PSNR & SSIM are supported)')
super().nondist_validation(dataloader, current_iter, tb_logger, save_img)
def nondist_validation(self, dataloader, current_iter, tb_logger, save_img):
"""
TODO: Validation using updated metric system
The metrics are now evaluated after all images have been tested
This allows batch processing, and also allows evaluation of
distributional metrics, such as:
@ Frechet Inception Distance: FID
@ Maximum Mean Discrepancy: MMD
Warning:
Need careful batch management for different inference settings.
"""
dataset_name = dataloader.dataset.opt['name']
with_metrics = self.opt['val'].get('metrics') is not None
if with_metrics:
self.metric_results = dict() # {metric: 0 for metric in self.opt['val']['metrics'].keys()}
sr_tensors = []
gt_tensors = []
pbar = tqdm(total=len(dataloader), unit='image')
for val_data in dataloader:
img_name = osp.splitext(osp.basename(val_data['lq_path'][0]))[0]
self.feed_data(val_data)
self.test()
visuals = self.get_current_visuals() # detached cpu tensor, non-squeeze
sr_tensors.append(visuals['result'])
if 'gt' in visuals:
gt_tensors.append(visuals['gt'])
del self.gt
# tentative for out of GPU memory
del self.lq
del self.output
torch.cuda.empty_cache()
if save_img:
if self.opt['is_train']:
save_img_path = osp.join(self.opt['path']['visualization'], img_name,
f'{img_name}_{current_iter}.png')
else:
if self.opt['val']['suffix']:
save_img_path = osp.join(self.opt['path']['visualization'], dataset_name,
f'{img_name}_{self.opt["val"]["suffix"]}.png')
else:
save_img_path = osp.join(self.opt['path']['visualization'], dataset_name,
f'{img_name}_{self.opt["name"]}.png')
imwrite(tensor2img(visuals['result']), save_img_path)
pbar.update(1)
pbar.set_description(f'Test {img_name}')
pbar.close()
if with_metrics:
sr_pack = torch.cat(sr_tensors, dim=0)
gt_pack = torch.cat(gt_tensors, dim=0)
# calculate metrics
for name, opt_ in self.opt['val']['metrics'].items():
# The new metric caller automatically returns mean value
# FIXME: ERROR: calculate_metric only supports two arguments. Now the codes cannot be successfully run
self.metric_results[name] = calculate_metric(dict(sr_pack=sr_pack, gt_pack=gt_pack), opt_)
self._log_validation_metric_values(current_iter, dataset_name, tb_logger)
def save(self, epoch, current_iter):
if hasattr(self, 'net_g_ema'):
print('HiFaceGAN does not support EMA now. Fallback to normal mode.')
self.save_network(self.net_g, 'net_g', current_iter)
self.save_network(self.net_d, 'net_d', current_iter)
self.save_training_state(epoch, current_iter)
BasicSR/basicsr/models/lr_scheduler.py 0 → 100644
View file @ e2696ece
import math
from collections import Counter
from torch.optim.lr_scheduler import _LRScheduler
class MultiStepRestartLR(_LRScheduler):
""" MultiStep with restarts learning rate scheme.
Args:
optimizer (torch.nn.optimizer): Torch optimizer.
milestones (list): Iterations that will decrease learning rate.
gamma (float): Decrease ratio. Default: 0.1.
restarts (list): Restart iterations. Default: [0].
restart_weights (list): Restart weights at each restart iteration.
Default: [1].
last_epoch (int): Used in _LRScheduler. Default: -1.
"""
def __init__(self, optimizer, milestones, gamma=0.1, restarts=(0, ), restart_weights=(1, ), last_epoch=-1):
self.milestones = Counter(milestones)
self.gamma = gamma
self.restarts = restarts
self.restart_weights = restart_weights
assert len(self.restarts) == len(self.restart_weights), 'restarts and their weights do not match.'
super(MultiStepRestartLR, self).__init__(optimizer, last_epoch)
def get_lr(self):
if self.last_epoch in self.restarts:
weight = self.restart_weights[self.restarts.index(self.last_epoch)]
return [group['initial_lr'] * weight for group in self.optimizer.param_groups]
if self.last_epoch not in self.milestones:
return [group['lr'] for group in self.optimizer.param_groups]
return [group['lr'] * self.gamma**self.milestones[self.last_epoch] for group in self.optimizer.param_groups]
def get_position_from_periods(iteration, cumulative_period):
"""Get the position from a period list.
It will return the index of the right-closest number in the period list.
For example, the cumulative_period = [100, 200, 300, 400],
if iteration == 50, return 0;
if iteration == 210, return 2;
if iteration == 300, return 2.
Args:
iteration (int): Current iteration.
cumulative_period (list[int]): Cumulative period list.
Returns:
int: The position of the right-closest number in the period list.
"""
for i, period in enumerate(cumulative_period):
if iteration <= period:
return i
class CosineAnnealingRestartLR(_LRScheduler):
""" Cosine annealing with restarts learning rate scheme.
An example of config:
periods = [10, 10, 10, 10]
restart_weights = [1, 0.5, 0.5, 0.5]
eta_min=1e-7
It has four cycles, each has 10 iterations. At 10th, 20th, 30th, the
scheduler will restart with the weights in restart_weights.
Args:
optimizer (torch.nn.optimizer): Torch optimizer.
periods (list): Period for each cosine anneling cycle.
restart_weights (list): Restart weights at each restart iteration.
Default: [1].
eta_min (float): The minimum lr. Default: 0.
last_epoch (int): Used in _LRScheduler. Default: -1.
"""
def __init__(self, optimizer, periods, restart_weights=(1, ), eta_min=0, last_epoch=-1):
self.periods = periods
self.restart_weights = restart_weights
self.eta_min = eta_min
assert (len(self.periods) == len(
self.restart_weights)), 'periods and restart_weights should have the same length.'
self.cumulative_period = [sum(self.periods[0:i + 1]) for i in range(0, len(self.periods))]
super(CosineAnnealingRestartLR, self).__init__(optimizer, last_epoch)
def get_lr(self):
idx = get_position_from_periods(self.last_epoch, self.cumulative_period)
current_weight = self.restart_weights[idx]
nearest_restart = 0 if idx == 0 else self.cumulative_period[idx - 1]
current_period = self.periods[idx]
return [
self.eta_min + current_weight * 0.5 * (base_lr - self.eta_min) *
(1 + math.cos(math.pi * ((self.last_epoch - nearest_restart) / current_period)))
for base_lr in self.base_lrs
]
BasicSR/basicsr/models/realesrgan_model.py 0 → 100644
View file @ e2696ece
import numpy as np
import random
import torch
from collections import OrderedDict
from torch.nn import functional as F
from basicsr.data.degradations import random_add_gaussian_noise_pt, random_add_poisson_noise_pt
from basicsr.data.transforms import paired_random_crop
from basicsr.losses.loss_util import get_refined_artifact_map
from basicsr.models.srgan_model import SRGANModel
from basicsr.utils import DiffJPEG, USMSharp
from basicsr.utils.img_process_util import filter2D
from basicsr.utils.registry import MODEL_REGISTRY
@MODEL_REGISTRY.register(suffix='basicsr')
class RealESRGANModel(SRGANModel):
"""RealESRGAN Model for Real-ESRGAN: Training Real-World Blind Super-Resolution with Pure Synthetic Data.
It mainly performs:
1. randomly synthesize LQ images in GPU tensors
2. optimize the networks with GAN training.
"""
def __init__(self, opt):
super(RealESRGANModel, self).__init__(opt)
self.jpeger = DiffJPEG(differentiable=False).cuda() # simulate JPEG compression artifacts
self.usm_sharpener = USMSharp().cuda() # do usm sharpening
self.queue_size = opt.get('queue_size', 180)
@torch.no_grad()
def _dequeue_and_enqueue(self):
"""It is the training pair pool for increasing the diversity in a batch.
Batch processing limits the diversity of synthetic degradations in a batch. For example, samples in a
batch could not have different resize scaling factors. Therefore, we employ this training pair pool
to increase the degradation diversity in a batch.
"""
# initialize
b, c, h, w = self.lq.size()
if not hasattr(self, 'queue_lr'):
assert self.queue_size % b == 0, f'queue size {self.queue_size} should be divisible by batch size {b}'
self.queue_lr = torch.zeros(self.queue_size, c, h, w).cuda()
_, c, h, w = self.gt.size()
self.queue_gt = torch.zeros(self.queue_size, c, h, w).cuda()
self.queue_ptr = 0
if self.queue_ptr == self.queue_size: # the pool is full
# do dequeue and enqueue
# shuffle
idx = torch.randperm(self.queue_size)
self.queue_lr = self.queue_lr[idx]
self.queue_gt = self.queue_gt[idx]
# get first b samples
lq_dequeue = self.queue_lr[0:b, :, :, :].clone()
gt_dequeue = self.queue_gt[0:b, :, :, :].clone()
# update the queue
self.queue_lr[0:b, :, :, :] = self.lq.clone()
self.queue_gt[0:b, :, :, :] = self.gt.clone()
self.lq = lq_dequeue
self.gt = gt_dequeue
else:
# only do enqueue
self.queue_lr[self.queue_ptr:self.queue_ptr + b, :, :, :] = self.lq.clone()
self.queue_gt[self.queue_ptr:self.queue_ptr + b, :, :, :] = self.gt.clone()
self.queue_ptr = self.queue_ptr + b
@torch.no_grad()
def feed_data(self, data):
"""Accept data from dataloader, and then add two-order degradations to obtain LQ images.
"""
if self.is_train and self.opt.get('high_order_degradation', True):
# training data synthesis
self.gt = data['gt'].to(self.device)
self.gt_usm = self.usm_sharpener(self.gt)
self.kernel1 = data['kernel1'].to(self.device)
self.kernel2 = data['kernel2'].to(self.device)
self.sinc_kernel = data['sinc_kernel'].to(self.device)
ori_h, ori_w = self.gt.size()[2:4]
# ----------------------- The first degradation process ----------------------- #
# blur
out = filter2D(self.gt_usm, self.kernel1)
# random resize
updown_type = random.choices(['up', 'down', 'keep'], self.opt['resize_prob'])[0]
if updown_type == 'up':
scale = np.random.uniform(1, self.opt['resize_range'][1])
elif updown_type == 'down':
scale = np.random.uniform(self.opt['resize_range'][0], 1)
else:
scale = 1
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(out, scale_factor=scale, mode=mode)
# add noise
gray_noise_prob = self.opt['gray_noise_prob']
if np.random.uniform() < self.opt['gaussian_noise_prob']:
out = random_add_gaussian_noise_pt(
out, sigma_range=self.opt['noise_range'], clip=True, rounds=False, gray_prob=gray_noise_prob)
else:
out = random_add_poisson_noise_pt(
out,
scale_range=self.opt['poisson_scale_range'],
gray_prob=gray_noise_prob,
clip=True,
rounds=False)
# JPEG compression
jpeg_p = out.new_zeros(out.size(0)).uniform_(*self.opt['jpeg_range'])
out = torch.clamp(out, 0, 1) # clamp to [0, 1], otherwise JPEGer will result in unpleasant artifacts
out = self.jpeger(out, quality=jpeg_p)
# ----------------------- The second degradation process ----------------------- #
# blur
if np.random.uniform() < self.opt['second_blur_prob']:
out = filter2D(out, self.kernel2)
# random resize
updown_type = random.choices(['up', 'down', 'keep'], self.opt['resize_prob2'])[0]
if updown_type == 'up':
scale = np.random.uniform(1, self.opt['resize_range2'][1])
elif updown_type == 'down':
scale = np.random.uniform(self.opt['resize_range2'][0], 1)
else:
scale = 1
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(
out, size=(int(ori_h / self.opt['scale'] * scale), int(ori_w / self.opt['scale'] * scale)), mode=mode)
# add noise
gray_noise_prob = self.opt['gray_noise_prob2']
if np.random.uniform() < self.opt['gaussian_noise_prob2']:
out = random_add_gaussian_noise_pt(
out, sigma_range=self.opt['noise_range2'], clip=True, rounds=False, gray_prob=gray_noise_prob)
else:
out = random_add_poisson_noise_pt(
out,
scale_range=self.opt['poisson_scale_range2'],
gray_prob=gray_noise_prob,
clip=True,
rounds=False)
# JPEG compression + the final sinc filter
# We also need to resize images to desired sizes. We group [resize back + sinc filter] together
# as one operation.
# We consider two orders:
# 1. [resize back + sinc filter] + JPEG compression
# 2. JPEG compression + [resize back + sinc filter]
# Empirically, we find other combinations (sinc + JPEG + Resize) will introduce twisted lines.
if np.random.uniform() < 0.5:
# resize back + the final sinc filter
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(out, size=(ori_h // self.opt['scale'], ori_w // self.opt['scale']), mode=mode)
out = filter2D(out, self.sinc_kernel)
# JPEG compression
jpeg_p = out.new_zeros(out.size(0)).uniform_(*self.opt['jpeg_range2'])
out = torch.clamp(out, 0, 1)
out = self.jpeger(out, quality=jpeg_p)
else:
# JPEG compression
jpeg_p = out.new_zeros(out.size(0)).uniform_(*self.opt['jpeg_range2'])
out = torch.clamp(out, 0, 1)
out = self.jpeger(out, quality=jpeg_p)
# resize back + the final sinc filter
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(out, size=(ori_h // self.opt['scale'], ori_w // self.opt['scale']), mode=mode)
out = filter2D(out, self.sinc_kernel)
# clamp and round
self.lq = torch.clamp((out * 255.0).round(), 0, 255) / 255.
# random crop
gt_size = self.opt['gt_size']
(self.gt, self.gt_usm), self.lq = paired_random_crop([self.gt, self.gt_usm], self.lq, gt_size,
self.opt['scale'])
# training pair pool
self._dequeue_and_enqueue()
# sharpen self.gt again, as we have changed the self.gt with self._dequeue_and_enqueue
self.gt_usm = self.usm_sharpener(self.gt)
self.lq = self.lq.contiguous() # for the warning: grad and param do not obey the gradient layout contract
else:
# for paired training or validation
self.lq = data['lq'].to(self.device)
if 'gt' in data:
self.gt = data['gt'].to(self.device)
self.gt_usm = self.usm_sharpener(self.gt)
def nondist_validation(self, dataloader, current_iter, tb_logger, save_img):
# do not use the synthetic process during validation
self.is_train = False
super(RealESRGANModel, self).nondist_validation(dataloader, current_iter, tb_logger, save_img)
self.is_train = True
def optimize_parameters(self, current_iter):
# usm sharpening
l1_gt = self.gt_usm
percep_gt = self.gt_usm
gan_gt = self.gt_usm
if self.opt['l1_gt_usm'] is False:
l1_gt = self.gt
if self.opt['percep_gt_usm'] is False:
percep_gt = self.gt
if self.opt['gan_gt_usm'] is False:
gan_gt = self.gt
# optimize net_g
for p in self.net_d.parameters():
p.requires_grad = False
self.optimizer_g.zero_grad()
self.output = self.net_g(self.lq)
if self.cri_ldl:
self.output_ema = self.net_g_ema(self.lq)
l_g_total = 0
loss_dict = OrderedDict()
if (current_iter % self.net_d_iters == 0 and current_iter > self.net_d_init_iters):
# pixel loss
if self.cri_pix:
l_g_pix = self.cri_pix(self.output, l1_gt)
l_g_total += l_g_pix
loss_dict['l_g_pix'] = l_g_pix
if self.cri_ldl:
pixel_weight = get_refined_artifact_map(self.gt, self.output, self.output_ema, 7)
l_g_ldl = self.cri_ldl(torch.mul(pixel_weight, self.output), torch.mul(pixel_weight, self.gt))
l_g_total += l_g_ldl
loss_dict['l_g_ldl'] = l_g_ldl
# perceptual loss
if self.cri_perceptual:
l_g_percep, l_g_style = self.cri_perceptual(self.output, percep_gt)
if l_g_percep is not None:
l_g_total += l_g_percep
loss_dict['l_g_percep'] = l_g_percep
if l_g_style is not None:
l_g_total += l_g_style
loss_dict['l_g_style'] = l_g_style
# gan loss
fake_g_pred = self.net_d(self.output)
l_g_gan = self.cri_gan(fake_g_pred, True, is_disc=False)
l_g_total += l_g_gan
loss_dict['l_g_gan'] = l_g_gan
l_g_total.backward()
self.optimizer_g.step()
# optimize net_d
for p in self.net_d.parameters():
p.requires_grad = True
self.optimizer_d.zero_grad()
# real
real_d_pred = self.net_d(gan_gt)
l_d_real = self.cri_gan(real_d_pred, True, is_disc=True)
loss_dict['l_d_real'] = l_d_real
loss_dict['out_d_real'] = torch.mean(real_d_pred.detach())
l_d_real.backward()
# fake
fake_d_pred = self.net_d(self.output.detach().clone()) # clone for pt1.9
l_d_fake = self.cri_gan(fake_d_pred, False, is_disc=True)
loss_dict['l_d_fake'] = l_d_fake
loss_dict['out_d_fake'] = torch.mean(fake_d_pred.detach())
l_d_fake.backward()
self.optimizer_d.step()
if self.ema_decay > 0:
self.model_ema(decay=self.ema_decay)
self.log_dict = self.reduce_loss_dict(loss_dict)
BasicSR/basicsr/models/realesrnet_model.py 0 → 100644
View file @ e2696ece
import numpy as np
import random
import torch
from torch.nn import functional as F
from basicsr.data.degradations import random_add_gaussian_noise_pt, random_add_poisson_noise_pt
from basicsr.data.transforms import paired_random_crop
from basicsr.models.sr_model import SRModel
from basicsr.utils import DiffJPEG, USMSharp
from basicsr.utils.img_process_util import filter2D
from basicsr.utils.registry import MODEL_REGISTRY
@MODEL_REGISTRY.register(suffix='basicsr')
class RealESRNetModel(SRModel):
"""RealESRNet Model for Real-ESRGAN: Training Real-World Blind Super-Resolution with Pure Synthetic Data.
It is trained without GAN losses.
It mainly performs:
1. randomly synthesize LQ images in GPU tensors
2. optimize the networks with GAN training.
"""
def __init__(self, opt):
super(RealESRNetModel, self).__init__(opt)
self.jpeger = DiffJPEG(differentiable=False).cuda() # simulate JPEG compression artifacts
self.usm_sharpener = USMSharp().cuda() # do usm sharpening
self.queue_size = opt.get('queue_size', 180)
@torch.no_grad()
def _dequeue_and_enqueue(self):
"""It is the training pair pool for increasing the diversity in a batch.
Batch processing limits the diversity of synthetic degradations in a batch. For example, samples in a
batch could not have different resize scaling factors. Therefore, we employ this training pair pool
to increase the degradation diversity in a batch.
"""
# initialize
b, c, h, w = self.lq.size()
if not hasattr(self, 'queue_lr'):
assert self.queue_size % b == 0, f'queue size {self.queue_size} should be divisible by batch size {b}'
self.queue_lr = torch.zeros(self.queue_size, c, h, w).cuda()
_, c, h, w = self.gt.size()
self.queue_gt = torch.zeros(self.queue_size, c, h, w).cuda()
self.queue_ptr = 0
if self.queue_ptr == self.queue_size: # the pool is full
# do dequeue and enqueue
# shuffle
idx = torch.randperm(self.queue_size)
self.queue_lr = self.queue_lr[idx]
self.queue_gt = self.queue_gt[idx]
# get first b samples
lq_dequeue = self.queue_lr[0:b, :, :, :].clone()
gt_dequeue = self.queue_gt[0:b, :, :, :].clone()
# update the queue
self.queue_lr[0:b, :, :, :] = self.lq.clone()
self.queue_gt[0:b, :, :, :] = self.gt.clone()
self.lq = lq_dequeue
self.gt = gt_dequeue
else:
# only do enqueue
self.queue_lr[self.queue_ptr:self.queue_ptr + b, :, :, :] = self.lq.clone()
self.queue_gt[self.queue_ptr:self.queue_ptr + b, :, :, :] = self.gt.clone()
self.queue_ptr = self.queue_ptr + b
@torch.no_grad()
def feed_data(self, data):
"""Accept data from dataloader, and then add two-order degradations to obtain LQ images.
"""
if self.is_train and self.opt.get('high_order_degradation', True):
# training data synthesis
self.gt = data['gt'].to(self.device)
# USM sharpen the GT images
if self.opt['gt_usm'] is True:
self.gt = self.usm_sharpener(self.gt)
self.kernel1 = data['kernel1'].to(self.device)
self.kernel2 = data['kernel2'].to(self.device)
self.sinc_kernel = data['sinc_kernel'].to(self.device)
ori_h, ori_w = self.gt.size()[2:4]
# ----------------------- The first degradation process ----------------------- #
# blur
out = filter2D(self.gt, self.kernel1)
# random resize
updown_type = random.choices(['up', 'down', 'keep'], self.opt['resize_prob'])[0]
if updown_type == 'up':
scale = np.random.uniform(1, self.opt['resize_range'][1])
elif updown_type == 'down':
scale = np.random.uniform(self.opt['resize_range'][0], 1)
else:
scale = 1
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(out, scale_factor=scale, mode=mode)
# add noise
gray_noise_prob = self.opt['gray_noise_prob']
if np.random.uniform() < self.opt['gaussian_noise_prob']:
out = random_add_gaussian_noise_pt(
out, sigma_range=self.opt['noise_range'], clip=True, rounds=False, gray_prob=gray_noise_prob)
else:
out = random_add_poisson_noise_pt(
out,
scale_range=self.opt['poisson_scale_range'],
gray_prob=gray_noise_prob,
clip=True,
rounds=False)
# JPEG compression
jpeg_p = out.new_zeros(out.size(0)).uniform_(*self.opt['jpeg_range'])
out = torch.clamp(out, 0, 1) # clamp to [0, 1], otherwise JPEGer will result in unpleasant artifacts
out = self.jpeger(out, quality=jpeg_p)
# ----------------------- The second degradation process ----------------------- #
# blur
if np.random.uniform() < self.opt['second_blur_prob']:
out = filter2D(out, self.kernel2)
# random resize
updown_type = random.choices(['up', 'down', 'keep'], self.opt['resize_prob2'])[0]
if updown_type == 'up':
scale = np.random.uniform(1, self.opt['resize_range2'][1])
elif updown_type == 'down':
scale = np.random.uniform(self.opt['resize_range2'][0], 1)
else:
scale = 1
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(
out, size=(int(ori_h / self.opt['scale'] * scale), int(ori_w / self.opt['scale'] * scale)), mode=mode)
# add noise
gray_noise_prob = self.opt['gray_noise_prob2']
if np.random.uniform() < self.opt['gaussian_noise_prob2']:
out = random_add_gaussian_noise_pt(
out, sigma_range=self.opt['noise_range2'], clip=True, rounds=False, gray_prob=gray_noise_prob)
else:
out = random_add_poisson_noise_pt(
out,
scale_range=self.opt['poisson_scale_range2'],
gray_prob=gray_noise_prob,
clip=True,
rounds=False)
# JPEG compression + the final sinc filter
# We also need to resize images to desired sizes. We group [resize back + sinc filter] together
# as one operation.
# We consider two orders:
# 1. [resize back + sinc filter] + JPEG compression
# 2. JPEG compression + [resize back + sinc filter]
# Empirically, we find other combinations (sinc + JPEG + Resize) will introduce twisted lines.
if np.random.uniform() < 0.5:
# resize back + the final sinc filter
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(out, size=(ori_h // self.opt['scale'], ori_w // self.opt['scale']), mode=mode)
out = filter2D(out, self.sinc_kernel)
# JPEG compression
jpeg_p = out.new_zeros(out.size(0)).uniform_(*self.opt['jpeg_range2'])
out = torch.clamp(out, 0, 1)
out = self.jpeger(out, quality=jpeg_p)
else:
# JPEG compression
jpeg_p = out.new_zeros(out.size(0)).uniform_(*self.opt['jpeg_range2'])
out = torch.clamp(out, 0, 1)
out = self.jpeger(out, quality=jpeg_p)
# resize back + the final sinc filter
mode = random.choice(['area', 'bilinear', 'bicubic'])
out = F.interpolate(out, size=(ori_h // self.opt['scale'], ori_w // self.opt['scale']), mode=mode)
out = filter2D(out, self.sinc_kernel)
# clamp and round
self.lq = torch.clamp((out * 255.0).round(), 0, 255) / 255.
# random crop
gt_size = self.opt['gt_size']
self.gt, self.lq = paired_random_crop(self.gt, self.lq, gt_size, self.opt['scale'])
# training pair pool
self._dequeue_and_enqueue()
self.lq = self.lq.contiguous() # for the warning: grad and param do not obey the gradient layout contract
else:
# for paired training or validation
self.lq = data['lq'].to(self.device)
if 'gt' in data:
self.gt = data['gt'].to(self.device)
self.gt_usm = self.usm_sharpener(self.gt)
def nondist_validation(self, dataloader, current_iter, tb_logger, save_img):
# do not use the synthetic process during validation
self.is_train = False
super(RealESRNetModel, self).nondist_validation(dataloader, current_iter, tb_logger, save_img)
self.is_train = True
BasicSR/basicsr/models/sr_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import OrderedDict
from os import path as osp
from tqdm import tqdm
from basicsr.archs import build_network
from basicsr.losses import build_loss
from basicsr.metrics import calculate_metric
from basicsr.utils import get_root_logger, imwrite, tensor2img
from basicsr.utils.registry import MODEL_REGISTRY
from .base_model import BaseModel
@MODEL_REGISTRY.register()
class SRModel(BaseModel):
"""Base SR model for single image super-resolution."""
def __init__(self, opt):
super(SRModel, self).__init__(opt)
# define network
self.net_g = build_network(opt['network_g'])
self.net_g = self.model_to_device(self.net_g)
self.print_network(self.net_g)
# load pretrained models
load_path = self.opt['path'].get('pretrain_network_g', None)
if load_path is not None:
param_key = self.opt['path'].get('param_key_g', 'params')
self.load_network(self.net_g, load_path, self.opt['path'].get('strict_load_g', True), param_key)
if self.is_train:
self.init_training_settings()
def init_training_settings(self):
self.net_g.train()
train_opt = self.opt['train']
self.ema_decay = train_opt.get('ema_decay', 0)
if self.ema_decay > 0:
logger = get_root_logger()
logger.info(f'Use Exponential Moving Average with decay: {self.ema_decay}')
# define network net_g with Exponential Moving Average (EMA)
# net_g_ema is used only for testing on one GPU and saving
# There is no need to wrap with DistributedDataParallel
self.net_g_ema = build_network(self.opt['network_g']).to(self.device)
# load pretrained model
load_path = self.opt['path'].get('pretrain_network_g', None)
if load_path is not None:
self.load_network(self.net_g_ema, load_path, self.opt['path'].get('strict_load_g', True), 'params_ema')
else:
self.model_ema(0) # copy net_g weight
self.net_g_ema.eval()
# define losses
if train_opt.get('pixel_opt'):
self.cri_pix = build_loss(train_opt['pixel_opt']).to(self.device)
else:
self.cri_pix = None
if train_opt.get('perceptual_opt'):
self.cri_perceptual = build_loss(train_opt['perceptual_opt']).to(self.device)
else:
self.cri_perceptual = None
if self.cri_pix is None and self.cri_perceptual is None:
raise ValueError('Both pixel and perceptual losses are None.')
# set up optimizers and schedulers
self.setup_optimizers()
self.setup_schedulers()
def setup_optimizers(self):
train_opt = self.opt['train']
optim_params = []
for k, v in self.net_g.named_parameters():
if v.requires_grad:
optim_params.append(v)
else:
logger = get_root_logger()
logger.warning(f'Params {k} will not be optimized.')
optim_type = train_opt['optim_g'].pop('type')
self.optimizer_g = self.get_optimizer(optim_type, optim_params, **train_opt['optim_g'])
self.optimizers.append(self.optimizer_g)
def feed_data(self, data):
self.lq = data['lq'].to(self.device)
if 'gt' in data:
self.gt = data['gt'].to(self.device)
def optimize_parameters(self, current_iter):
self.optimizer_g.zero_grad()
self.output = self.net_g(self.lq)
l_total = 0
loss_dict = OrderedDict()
# pixel loss
if self.cri_pix:
l_pix = self.cri_pix(self.output, self.gt)
l_total += l_pix
loss_dict['l_pix'] = l_pix
# perceptual loss
if self.cri_perceptual:
l_percep, l_style = self.cri_perceptual(self.output, self.gt)
if l_percep is not None:
l_total += l_percep
loss_dict['l_percep'] = l_percep
if l_style is not None:
l_total += l_style
loss_dict['l_style'] = l_style
l_total.backward()
self.optimizer_g.step()
self.log_dict = self.reduce_loss_dict(loss_dict)
if self.ema_decay > 0:
self.model_ema(decay=self.ema_decay)
def test(self):
if hasattr(self, 'net_g_ema'):
self.net_g_ema.eval()
with torch.no_grad():
self.output = self.net_g_ema(self.lq)
else:
self.net_g.eval()
with torch.no_grad():
self.output = self.net_g(self.lq)
self.net_g.train()
def test_selfensemble(self):
# TODO: to be tested
# 8 augmentations
# modified from https://github.com/thstkdgus35/EDSR-PyTorch
def _transform(v, op):
# if self.precision != 'single': v = v.float()
v2np = v.data.cpu().numpy()
if op == 'v':
tfnp = v2np[:, :, :, ::-1].copy()
elif op == 'h':
tfnp = v2np[:, :, ::-1, :].copy()
elif op == 't':
tfnp = v2np.transpose((0, 1, 3, 2)).copy()
ret = torch.Tensor(tfnp).to(self.device)
# if self.precision == 'half': ret = ret.half()
return ret
# prepare augmented data
lq_list = [self.lq]
for tf in 'v', 'h', 't':
lq_list.extend([_transform(t, tf) for t in lq_list])
# inference
if hasattr(self, 'net_g_ema'):
self.net_g_ema.eval()
with torch.no_grad():
out_list = [self.net_g_ema(aug) for aug in lq_list]
else:
self.net_g.eval()
with torch.no_grad():
out_list = [self.net_g_ema(aug) for aug in lq_list]
self.net_g.train()
# merge results
for i in range(len(out_list)):
if i > 3:
out_list[i] = _transform(out_list[i], 't')
if i % 4 > 1:
out_list[i] = _transform(out_list[i], 'h')
if (i % 4) % 2 == 1:
out_list[i] = _transform(out_list[i], 'v')
output = torch.cat(out_list, dim=0)
self.output = output.mean(dim=0, keepdim=True)
def dist_validation(self, dataloader, current_iter, tb_logger, save_img):
if self.opt['rank'] == 0:
self.nondist_validation(dataloader, current_iter, tb_logger, save_img)
def nondist_validation(self, dataloader, current_iter, tb_logger, save_img):
dataset_name = dataloader.dataset.opt['name']
with_metrics = self.opt['val'].get('metrics') is not None
use_pbar = self.opt['val'].get('pbar', False)
if with_metrics:
if not hasattr(self, 'metric_results'): # only execute in the first run
self.metric_results = {metric: 0 for metric in self.opt['val']['metrics'].keys()}
# initialize the best metric results for each dataset_name (supporting multiple validation datasets)
self._initialize_best_metric_results(dataset_name)
# zero self.metric_results
if with_metrics:
self.metric_results = {metric: 0 for metric in self.metric_results}
metric_data = dict()
if use_pbar:
pbar = tqdm(total=len(dataloader), unit='image')
for idx, val_data in enumerate(dataloader):
img_name = osp.splitext(osp.basename(val_data['lq_path'][0]))[0]
self.feed_data(val_data)
self.test()
visuals = self.get_current_visuals()
sr_img = tensor2img([visuals['result']])
metric_data['img'] = sr_img
if 'gt' in visuals:
gt_img = tensor2img([visuals['gt']])
metric_data['img2'] = gt_img
del self.gt
# tentative for out of GPU memory
del self.lq
del self.output
torch.cuda.empty_cache()
if save_img:
if self.opt['is_train']:
save_img_path = osp.join(self.opt['path']['visualization'], img_name,
f'{img_name}_{current_iter}.png')
else:
if self.opt['val']['suffix']:
save_img_path = osp.join(self.opt['path']['visualization'], dataset_name,
f'{img_name}_{self.opt["val"]["suffix"]}.png')
else:
save_img_path = osp.join(self.opt['path']['visualization'], dataset_name,
f'{img_name}_{self.opt["name"]}.png')
imwrite(sr_img, save_img_path)
if with_metrics:
# calculate metrics
for name, opt_ in self.opt['val']['metrics'].items():
self.metric_results[name] += calculate_metric(metric_data, opt_)
if use_pbar:
pbar.update(1)
pbar.set_description(f'Test {img_name}')
if use_pbar:
pbar.close()
if with_metrics:
for metric in self.metric_results.keys():
self.metric_results[metric] /= (idx + 1)
# update the best metric result
self._update_best_metric_result(dataset_name, metric, self.metric_results[metric], current_iter)
self._log_validation_metric_values(current_iter, dataset_name, tb_logger)
def _log_validation_metric_values(self, current_iter, dataset_name, tb_logger):
log_str = f'Validation {dataset_name}\n'
for metric, value in self.metric_results.items():
log_str += f'\t # {metric}: {value:.4f}'
if hasattr(self, 'best_metric_results'):
log_str += (f'\tBest: {self.best_metric_results[dataset_name][metric]["val"]:.4f} @ '
f'{self.best_metric_results[dataset_name][metric]["iter"]} iter')
log_str += '\n'
logger = get_root_logger()
logger.info(log_str)
if tb_logger:
for metric, value in self.metric_results.items():
tb_logger.add_scalar(f'metrics/{dataset_name}/{metric}', value, current_iter)
def get_current_visuals(self):
out_dict = OrderedDict()
out_dict['lq'] = self.lq.detach().cpu()
out_dict['result'] = self.output.detach().cpu()
if hasattr(self, 'gt'):
out_dict['gt'] = self.gt.detach().cpu()
return out_dict
def save(self, epoch, current_iter):
if hasattr(self, 'net_g_ema'):
self.save_network([self.net_g, self.net_g_ema], 'net_g', current_iter, param_key=['params', 'params_ema'])
else:
self.save_network(self.net_g, 'net_g', current_iter)
self.save_training_state(epoch, current_iter)
BasicSR/basicsr/models/srgan_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import OrderedDict
from basicsr.archs import build_network
from basicsr.losses import build_loss
from basicsr.utils import get_root_logger
from basicsr.utils.registry import MODEL_REGISTRY
from .sr_model import SRModel
@MODEL_REGISTRY.register()
class SRGANModel(SRModel):
"""SRGAN model for single image super-resolution."""
def init_training_settings(self):
train_opt = self.opt['train']
self.ema_decay = train_opt.get('ema_decay', 0)
if self.ema_decay > 0:
logger = get_root_logger()
logger.info(f'Use Exponential Moving Average with decay: {self.ema_decay}')
# define network net_g with Exponential Moving Average (EMA)
# net_g_ema is used only for testing on one GPU and saving
# There is no need to wrap with DistributedDataParallel
self.net_g_ema = build_network(self.opt['network_g']).to(self.device)
# load pretrained model
load_path = self.opt['path'].get('pretrain_network_g', None)
if load_path is not None:
self.load_network(self.net_g_ema, load_path, self.opt['path'].get('strict_load_g', True), 'params_ema')
else:
self.model_ema(0) # copy net_g weight
self.net_g_ema.eval()
# define network net_d
self.net_d = build_network(self.opt['network_d'])
self.net_d = self.model_to_device(self.net_d)
self.print_network(self.net_d)
# load pretrained models
load_path = self.opt['path'].get('pretrain_network_d', None)
if load_path is not None:
param_key = self.opt['path'].get('param_key_d', 'params')
self.load_network(self.net_d, load_path, self.opt['path'].get('strict_load_d', True), param_key)
self.net_g.train()
self.net_d.train()
# define losses
if train_opt.get('pixel_opt'):
self.cri_pix = build_loss(train_opt['pixel_opt']).to(self.device)
else:
self.cri_pix = None
if train_opt.get('ldl_opt'):
self.cri_ldl = build_loss(train_opt['ldl_opt']).to(self.device)
else:
self.cri_ldl = None
if train_opt.get('perceptual_opt'):
self.cri_perceptual = build_loss(train_opt['perceptual_opt']).to(self.device)
else:
self.cri_perceptual = None
if train_opt.get('gan_opt'):
self.cri_gan = build_loss(train_opt['gan_opt']).to(self.device)
self.net_d_iters = train_opt.get('net_d_iters', 1)
self.net_d_init_iters = train_opt.get('net_d_init_iters', 0)
# set up optimizers and schedulers
self.setup_optimizers()
self.setup_schedulers()
def setup_optimizers(self):
train_opt = self.opt['train']
# optimizer g
optim_type = train_opt['optim_g'].pop('type')
self.optimizer_g = self.get_optimizer(optim_type, self.net_g.parameters(), **train_opt['optim_g'])
self.optimizers.append(self.optimizer_g)
# optimizer d
optim_type = train_opt['optim_d'].pop('type')
self.optimizer_d = self.get_optimizer(optim_type, self.net_d.parameters(), **train_opt['optim_d'])
self.optimizers.append(self.optimizer_d)
def optimize_parameters(self, current_iter):
# optimize net_g
for p in self.net_d.parameters():
p.requires_grad = False
self.optimizer_g.zero_grad()
self.output = self.net_g(self.lq)
l_g_total = 0
loss_dict = OrderedDict()
if (current_iter % self.net_d_iters == 0 and current_iter > self.net_d_init_iters):
# pixel loss
if self.cri_pix:
l_g_pix = self.cri_pix(self.output, self.gt)
l_g_total += l_g_pix
loss_dict['l_g_pix'] = l_g_pix
# perceptual loss
if self.cri_perceptual:
l_g_percep, l_g_style = self.cri_perceptual(self.output, self.gt)
if l_g_percep is not None:
l_g_total += l_g_percep
loss_dict['l_g_percep'] = l_g_percep
if l_g_style is not None:
l_g_total += l_g_style
loss_dict['l_g_style'] = l_g_style
# gan loss
fake_g_pred = self.net_d(self.output)
l_g_gan = self.cri_gan(fake_g_pred, True, is_disc=False)
l_g_total += l_g_gan
loss_dict['l_g_gan'] = l_g_gan
l_g_total.backward()
self.optimizer_g.step()
# optimize net_d
for p in self.net_d.parameters():
p.requires_grad = True
self.optimizer_d.zero_grad()
# real
real_d_pred = self.net_d(self.gt)
l_d_real = self.cri_gan(real_d_pred, True, is_disc=True)
loss_dict['l_d_real'] = l_d_real
loss_dict['out_d_real'] = torch.mean(real_d_pred.detach())
l_d_real.backward()
# fake
fake_d_pred = self.net_d(self.output.detach())
l_d_fake = self.cri_gan(fake_d_pred, False, is_disc=True)
loss_dict['l_d_fake'] = l_d_fake
loss_dict['out_d_fake'] = torch.mean(fake_d_pred.detach())
l_d_fake.backward()
self.optimizer_d.step()
self.log_dict = self.reduce_loss_dict(loss_dict)
if self.ema_decay > 0:
self.model_ema(decay=self.ema_decay)
def save(self, epoch, current_iter):
if hasattr(self, 'net_g_ema'):
self.save_network([self.net_g, self.net_g_ema], 'net_g', current_iter, param_key=['params', 'params_ema'])
else:
self.save_network(self.net_g, 'net_g', current_iter)
self.save_network(self.net_d, 'net_d', current_iter)
self.save_training_state(epoch, current_iter)
BasicSR/basicsr/models/stylegan2_model.py 0 → 100644
View file @ e2696ece
import cv2
import math
import numpy as np
import random
import torch
from collections import OrderedDict
from os import path as osp
from basicsr.archs import build_network
from basicsr.losses import build_loss
from basicsr.losses.gan_loss import g_path_regularize, r1_penalty
from basicsr.utils import imwrite, tensor2img
from basicsr.utils.registry import MODEL_REGISTRY
from .base_model import BaseModel
@MODEL_REGISTRY.register()
class StyleGAN2Model(BaseModel):
"""StyleGAN2 model."""
def __init__(self, opt):
super(StyleGAN2Model, self).__init__(opt)
# define network net_g
self.net_g = build_network(opt['network_g'])
self.net_g = self.model_to_device(self.net_g)
self.print_network(self.net_g)
# load pretrained model
load_path = self.opt['path'].get('pretrain_network_g', None)
if load_path is not None:
param_key = self.opt['path'].get('param_key_g', 'params')
self.load_network(self.net_g, load_path, self.opt['path'].get('strict_load_g', True), param_key)
# latent dimension: self.num_style_feat
self.num_style_feat = opt['network_g']['num_style_feat']
num_val_samples = self.opt['val'].get('num_val_samples', 16)
self.fixed_sample = torch.randn(num_val_samples, self.num_style_feat, device=self.device)
if self.is_train:
self.init_training_settings()
def init_training_settings(self):
train_opt = self.opt['train']
# define network net_d
self.net_d = build_network(self.opt['network_d'])
self.net_d = self.model_to_device(self.net_d)
self.print_network(self.net_d)
# load pretrained model
load_path = self.opt['path'].get('pretrain_network_d', None)
if load_path is not None:
param_key = self.opt['path'].get('param_key_d', 'params')
self.load_network(self.net_d, load_path, self.opt['path'].get('strict_load_d', True), param_key)
# define network net_g with Exponential Moving Average (EMA)
# net_g_ema only used for testing on one GPU and saving, do not need to
# wrap with DistributedDataParallel
self.net_g_ema = build_network(self.opt['network_g']).to(self.device)
# load pretrained model
load_path = self.opt['path'].get('pretrain_network_g', None)
if load_path is not None:
self.load_network(self.net_g_ema, load_path, self.opt['path'].get('strict_load_g', True), 'params_ema')
else:
self.model_ema(0) # copy net_g weight
self.net_g.train()
self.net_d.train()
self.net_g_ema.eval()
# define losses
# gan loss (wgan)
self.cri_gan = build_loss(train_opt['gan_opt']).to(self.device)
# regularization weights
self.r1_reg_weight = train_opt['r1_reg_weight'] # for discriminator
self.path_reg_weight = train_opt['path_reg_weight'] # for generator
self.net_g_reg_every = train_opt['net_g_reg_every']
self.net_d_reg_every = train_opt['net_d_reg_every']
self.mixing_prob = train_opt['mixing_prob']
self.mean_path_length = 0
# set up optimizers and schedulers
self.setup_optimizers()
self.setup_schedulers()
def setup_optimizers(self):
train_opt = self.opt['train']
# optimizer g
net_g_reg_ratio = self.net_g_reg_every / (self.net_g_reg_every + 1)
if self.opt['network_g']['type'] == 'StyleGAN2GeneratorC':
normal_params = []
style_mlp_params = []
modulation_conv_params = []
for name, param in self.net_g.named_parameters():
if 'modulation' in name:
normal_params.append(param)
elif 'style_mlp' in name:
style_mlp_params.append(param)
elif 'modulated_conv' in name:
modulation_conv_params.append(param)
else:
normal_params.append(param)
optim_params_g = [
{ # add normal params first
'params': normal_params,
'lr': train_opt['optim_g']['lr']
},
{
'params': style_mlp_params,
'lr': train_opt['optim_g']['lr'] * 0.01
},
{
'params': modulation_conv_params,
'lr': train_opt['optim_g']['lr'] / 3
}
]
else:
normal_params = []
for name, param in self.net_g.named_parameters():
normal_params.append(param)
optim_params_g = [{ # add normal params first
'params': normal_params,
'lr': train_opt['optim_g']['lr']
}]
optim_type = train_opt['optim_g'].pop('type')
lr = train_opt['optim_g']['lr'] * net_g_reg_ratio
betas = (0**net_g_reg_ratio, 0.99**net_g_reg_ratio)
self.optimizer_g = self.get_optimizer(optim_type, optim_params_g, lr, betas=betas)
self.optimizers.append(self.optimizer_g)
# optimizer d
net_d_reg_ratio = self.net_d_reg_every / (self.net_d_reg_every + 1)
if self.opt['network_d']['type'] == 'StyleGAN2DiscriminatorC':
normal_params = []
linear_params = []
for name, param in self.net_d.named_parameters():
if 'final_linear' in name:
linear_params.append(param)
else:
normal_params.append(param)
optim_params_d = [
{ # add normal params first
'params': normal_params,
'lr': train_opt['optim_d']['lr']
},
{
'params': linear_params,
'lr': train_opt['optim_d']['lr'] * (1 / math.sqrt(512))
}
]
else:
normal_params = []
for name, param in self.net_d.named_parameters():
normal_params.append(param)
optim_params_d = [{ # add normal params first
'params': normal_params,
'lr': train_opt['optim_d']['lr']
}]
optim_type = train_opt['optim_d'].pop('type')
lr = train_opt['optim_d']['lr'] * net_d_reg_ratio
betas = (0**net_d_reg_ratio, 0.99**net_d_reg_ratio)
self.optimizer_d = self.get_optimizer(optim_type, optim_params_d, lr, betas=betas)
self.optimizers.append(self.optimizer_d)
def feed_data(self, data):
self.real_img = data['gt'].to(self.device)
def make_noise(self, batch, num_noise):
if num_noise == 1:
noises = torch.randn(batch, self.num_style_feat, device=self.device)
else:
noises = torch.randn(num_noise, batch, self.num_style_feat, device=self.device).unbind(0)
return noises
def mixing_noise(self, batch, prob):
if random.random() < prob:
return self.make_noise(batch, 2)
else:
return [self.make_noise(batch, 1)]
def optimize_parameters(self, current_iter):
loss_dict = OrderedDict()
# optimize net_d
for p in self.net_d.parameters():
p.requires_grad = True
self.optimizer_d.zero_grad()
batch = self.real_img.size(0)
noise = self.mixing_noise(batch, self.mixing_prob)
fake_img, _ = self.net_g(noise)
fake_pred = self.net_d(fake_img.detach())
real_pred = self.net_d(self.real_img)
# wgan loss with softplus (logistic loss) for discriminator
l_d = self.cri_gan(real_pred, True, is_disc=True) + self.cri_gan(fake_pred, False, is_disc=True)
loss_dict['l_d'] = l_d
# In wgan, real_score should be positive and fake_score should be
# negative
loss_dict['real_score'] = real_pred.detach().mean()
loss_dict['fake_score'] = fake_pred.detach().mean()
l_d.backward()
if current_iter % self.net_d_reg_every == 0:
self.real_img.requires_grad = True
real_pred = self.net_d(self.real_img)
l_d_r1 = r1_penalty(real_pred, self.real_img)
l_d_r1 = (self.r1_reg_weight / 2 * l_d_r1 * self.net_d_reg_every + 0 * real_pred[0])
# TODO: why do we need to add 0 * real_pred, otherwise, a runtime
# error will arise: RuntimeError: Expected to have finished
# reduction in the prior iteration before starting a new one.
# This error indicates that your module has parameters that were
# not used in producing loss.
loss_dict['l_d_r1'] = l_d_r1.detach().mean()
l_d_r1.backward()
self.optimizer_d.step()
# optimize net_g
for p in self.net_d.parameters():
p.requires_grad = False
self.optimizer_g.zero_grad()
noise = self.mixing_noise(batch, self.mixing_prob)
fake_img, _ = self.net_g(noise)
fake_pred = self.net_d(fake_img)
# wgan loss with softplus (non-saturating loss) for generator
l_g = self.cri_gan(fake_pred, True, is_disc=False)
loss_dict['l_g'] = l_g
l_g.backward()
if current_iter % self.net_g_reg_every == 0:
path_batch_size = max(1, batch // self.opt['train']['path_batch_shrink'])
noise = self.mixing_noise(path_batch_size, self.mixing_prob)
fake_img, latents = self.net_g(noise, return_latents=True)
l_g_path, path_lengths, self.mean_path_length = g_path_regularize(fake_img, latents, self.mean_path_length)
l_g_path = (self.path_reg_weight * self.net_g_reg_every * l_g_path + 0 * fake_img[0, 0, 0, 0])
# TODO: why do we need to add 0 * fake_img[0, 0, 0, 0]
l_g_path.backward()
loss_dict['l_g_path'] = l_g_path.detach().mean()
loss_dict['path_length'] = path_lengths
self.optimizer_g.step()
self.log_dict = self.reduce_loss_dict(loss_dict)
# EMA
self.model_ema(decay=0.5**(32 / (10 * 1000)))
def test(self):
with torch.no_grad():
self.net_g_ema.eval()
self.output, _ = self.net_g_ema([self.fixed_sample])
def dist_validation(self, dataloader, current_iter, tb_logger, save_img):
if self.opt['rank'] == 0:
self.nondist_validation(dataloader, current_iter, tb_logger, save_img)
def nondist_validation(self, dataloader, current_iter, tb_logger, save_img):
assert dataloader is None, 'Validation dataloader should be None.'
self.test()
result = tensor2img(self.output, min_max=(-1, 1))
if self.opt['is_train']:
save_img_path = osp.join(self.opt['path']['visualization'], 'train', f'train_{current_iter}.png')
else:
save_img_path = osp.join(self.opt['path']['visualization'], 'test', f'test_{self.opt["name"]}.png')
imwrite(result, save_img_path)
# add sample images to tb_logger
result = (result / 255.).astype(np.float32)
result = cv2.cvtColor(result, cv2.COLOR_BGR2RGB)
if tb_logger is not None:
tb_logger.add_image('samples', result, global_step=current_iter, dataformats='HWC')
def save(self, epoch, current_iter):
self.save_network([self.net_g, self.net_g_ema], 'net_g', current_iter, param_key=['params', 'params_ema'])
self.save_network(self.net_d, 'net_d', current_iter)
self.save_training_state(epoch, current_iter)
BasicSR/basicsr/models/swinir_model.py 0 → 100644
View file @ e2696ece
import torch
from torch.nn import functional as F
from basicsr.utils.registry import MODEL_REGISTRY
from .sr_model import SRModel
@MODEL_REGISTRY.register()
class SwinIRModel(SRModel):
def test(self):
# pad to multiplication of window_size
window_size = self.opt['network_g']['window_size']
scale = self.opt.get('scale', 1)
mod_pad_h, mod_pad_w = 0, 0
_, _, h, w = self.lq.size()
if h % window_size != 0:
mod_pad_h = window_size - h % window_size
if w % window_size != 0:
mod_pad_w = window_size - w % window_size
img = F.pad(self.lq, (0, mod_pad_w, 0, mod_pad_h), 'reflect')
if hasattr(self, 'net_g_ema'):
self.net_g_ema.eval()
with torch.no_grad():
self.output = self.net_g_ema(img)
else:
self.net_g.eval()
with torch.no_grad():
self.output = self.net_g(img)
self.net_g.train()
_, _, h, w = self.output.size()
self.output = self.output[:, :, 0:h - mod_pad_h * scale, 0:w - mod_pad_w * scale]
BasicSR/basicsr/models/video_base_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import Counter
from os import path as osp
from torch import distributed as dist
from tqdm import tqdm
from basicsr.metrics import calculate_metric
from basicsr.utils import get_root_logger, imwrite, tensor2img
from basicsr.utils.dist_util import get_dist_info
from basicsr.utils.registry import MODEL_REGISTRY
from .sr_model import SRModel
@MODEL_REGISTRY.register()
class VideoBaseModel(SRModel):
"""Base video SR model."""
def dist_validation(self, dataloader, current_iter, tb_logger, save_img):
dataset = dataloader.dataset
dataset_name = dataset.opt['name']
with_metrics = self.opt['val']['metrics'] is not None
# initialize self.metric_results
# It is a dict: {
# 'folder1': tensor (num_frame x len(metrics)),
# 'folder2': tensor (num_frame x len(metrics))
# }
if with_metrics:
if not hasattr(self, 'metric_results'): # only execute in the first run
self.metric_results = {}
num_frame_each_folder = Counter(dataset.data_info['folder'])
for folder, num_frame in num_frame_each_folder.items():
self.metric_results[folder] = torch.zeros(
num_frame, len(self.opt['val']['metrics']), dtype=torch.float32, device='cuda')
# initialize the best metric results
self._initialize_best_metric_results(dataset_name)
# zero self.metric_results
rank, world_size = get_dist_info()
if with_metrics:
for _, tensor in self.metric_results.items():
tensor.zero_()
metric_data = dict()
# record all frames (border and center frames)
if rank == 0:
pbar = tqdm(total=len(dataset), unit='frame')
for idx in range(rank, len(dataset), world_size):
val_data = dataset[idx]
val_data['lq'].unsqueeze_(0)
val_data['gt'].unsqueeze_(0)
folder = val_data['folder']
frame_idx, max_idx = val_data['idx'].split('/')
lq_path = val_data['lq_path']
self.feed_data(val_data)
self.test()
visuals = self.get_current_visuals()
result_img = tensor2img([visuals['result']])
metric_data['img'] = result_img
if 'gt' in visuals:
gt_img = tensor2img([visuals['gt']])
metric_data['img2'] = gt_img
del self.gt
# tentative for out of GPU memory
del self.lq
del self.output
torch.cuda.empty_cache()
if save_img:
if self.opt['is_train']:
raise NotImplementedError('saving image is not supported during training.')
else:
if 'vimeo' in dataset_name.lower(): # vimeo90k dataset
split_result = lq_path.split('/')
img_name = f'{split_result[-3]}_{split_result[-2]}_{split_result[-1].split(".")[0]}'
else: # other datasets, e.g., REDS, Vid4
img_name = osp.splitext(osp.basename(lq_path))[0]
if self.opt['val']['suffix']:
save_img_path = osp.join(self.opt['path']['visualization'], dataset_name, folder,
f'{img_name}_{self.opt["val"]["suffix"]}.png')
else:
save_img_path = osp.join(self.opt['path']['visualization'], dataset_name, folder,
f'{img_name}_{self.opt["name"]}.png')
imwrite(result_img, save_img_path)
if with_metrics:
# calculate metrics
for metric_idx, opt_ in enumerate(self.opt['val']['metrics'].values()):
result = calculate_metric(metric_data, opt_)
self.metric_results[folder][int(frame_idx), metric_idx] += result
# progress bar
if rank == 0:
for _ in range(world_size):
pbar.update(1)
pbar.set_description(f'Test {folder}: {int(frame_idx) + world_size}/{max_idx}')
if rank == 0:
pbar.close()
if with_metrics:
if self.opt['dist']:
# collect data among GPUs
for _, tensor in self.metric_results.items():
dist.reduce(tensor, 0)
dist.barrier()
else:
pass # assume use one gpu in non-dist testing
if rank == 0:
self._log_validation_metric_values(current_iter, dataset_name, tb_logger)
def nondist_validation(self, dataloader, current_iter, tb_logger, save_img):
logger = get_root_logger()
logger.warning('nondist_validation is not implemented. Run dist_validation.')
self.dist_validation(dataloader, current_iter, tb_logger, save_img)
def _log_validation_metric_values(self, current_iter, dataset_name, tb_logger):
# ----------------- calculate the average values for each folder, and for each metric ----------------- #
# average all frames for each sub-folder
# metric_results_avg is a dict:{
# 'folder1': tensor (len(metrics)),
# 'folder2': tensor (len(metrics))
# }
metric_results_avg = {
folder: torch.mean(tensor, dim=0).cpu()
for (folder, tensor) in self.metric_results.items()
}
# total_avg_results is a dict: {
# 'metric1': float,
# 'metric2': float
# }
total_avg_results = {metric: 0 for metric in self.opt['val']['metrics'].keys()}
for folder, tensor in metric_results_avg.items():
for idx, metric in enumerate(total_avg_results.keys()):
total_avg_results[metric] += metric_results_avg[folder][idx].item()
# average among folders
for metric in total_avg_results.keys():
total_avg_results[metric] /= len(metric_results_avg)
# update the best metric result
self._update_best_metric_result(dataset_name, metric, total_avg_results[metric], current_iter)
# ------------------------------------------ log the metric ------------------------------------------ #
log_str = f'Validation {dataset_name}\n'
for metric_idx, (metric, value) in enumerate(total_avg_results.items()):
log_str += f'\t # {metric}: {value:.4f}'
for folder, tensor in metric_results_avg.items():
log_str += f'\t # {folder}: {tensor[metric_idx].item():.4f}'
if hasattr(self, 'best_metric_results'):
log_str += (f'\n\t Best: {self.best_metric_results[dataset_name][metric]["val"]:.4f} @ '
f'{self.best_metric_results[dataset_name][metric]["iter"]} iter')
log_str += '\n'
logger = get_root_logger()
logger.info(log_str)
if tb_logger:
for metric_idx, (metric, value) in enumerate(total_avg_results.items()):
tb_logger.add_scalar(f'metrics/{metric}', value, current_iter)
for folder, tensor in metric_results_avg.items():
tb_logger.add_scalar(f'metrics/{metric}/{folder}', tensor[metric_idx].item(), current_iter)
BasicSR/basicsr/models/video_gan_model.py 0 → 100644
View file @ e2696ece
from basicsr.utils.registry import MODEL_REGISTRY
from .srgan_model import SRGANModel
from .video_base_model import VideoBaseModel
@MODEL_REGISTRY.register()
class VideoGANModel(SRGANModel, VideoBaseModel):
"""Video GAN model.
Use multiple inheritance.
It will first use the functions of :class:`SRGANModel`:
- :func:`init_training_settings`
- :func:`setup_optimizers`
- :func:`optimize_parameters`
- :func:`save`
Then find functions in :class:`VideoBaseModel`.
"""
BasicSR/basicsr/models/video_recurrent_gan_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import OrderedDict
from basicsr.archs import build_network
from basicsr.losses import build_loss
from basicsr.utils import get_root_logger
from basicsr.utils.registry import MODEL_REGISTRY
from .video_recurrent_model import VideoRecurrentModel
@MODEL_REGISTRY.register()
class VideoRecurrentGANModel(VideoRecurrentModel):
def init_training_settings(self):
train_opt = self.opt['train']
self.ema_decay = train_opt.get('ema_decay', 0)
if self.ema_decay > 0:
logger = get_root_logger()
logger.info(f'Use Exponential Moving Average with decay: {self.ema_decay}')
# build network net_g with Exponential Moving Average (EMA)
# net_g_ema only used for testing on one GPU and saving.
# There is no need to wrap with DistributedDataParallel
self.net_g_ema = build_network(self.opt['network_g']).to(self.device)
# load pretrained model
load_path = self.opt['path'].get('pretrain_network_g', None)
if load_path is not None:
self.load_network(self.net_g_ema, load_path, self.opt['path'].get('strict_load_g', True), 'params_ema')
else:
self.model_ema(0) # copy net_g weight
self.net_g_ema.eval()
# define network net_d
self.net_d = build_network(self.opt['network_d'])
self.net_d = self.model_to_device(self.net_d)
self.print_network(self.net_d)
# load pretrained models
load_path = self.opt['path'].get('pretrain_network_d', None)
if load_path is not None:
param_key = self.opt['path'].get('param_key_d', 'params')
self.load_network(self.net_d, load_path, self.opt['path'].get('strict_load_d', True), param_key)
self.net_g.train()
self.net_d.train()
# define losses
if train_opt.get('pixel_opt'):
self.cri_pix = build_loss(train_opt['pixel_opt']).to(self.device)
else:
self.cri_pix = None
if train_opt.get('perceptual_opt'):
self.cri_perceptual = build_loss(train_opt['perceptual_opt']).to(self.device)
else:
self.cri_perceptual = None
if train_opt.get('gan_opt'):
self.cri_gan = build_loss(train_opt['gan_opt']).to(self.device)
self.net_d_iters = train_opt.get('net_d_iters', 1)
self.net_d_init_iters = train_opt.get('net_d_init_iters', 0)
# set up optimizers and schedulers
self.setup_optimizers()
self.setup_schedulers()
def setup_optimizers(self):
train_opt = self.opt['train']
if train_opt['fix_flow']:
normal_params = []
flow_params = []
for name, param in self.net_g.named_parameters():
if 'spynet' in name: # The fix_flow now only works for spynet.
flow_params.append(param)
else:
normal_params.append(param)
optim_params = [
{ # add flow params first
'params': flow_params,
'lr': train_opt['lr_flow']
},
{
'params': normal_params,
'lr': train_opt['optim_g']['lr']
},
]
else:
optim_params = self.net_g.parameters()
# optimizer g
optim_type = train_opt['optim_g'].pop('type')
self.optimizer_g = self.get_optimizer(optim_type, optim_params, **train_opt['optim_g'])
self.optimizers.append(self.optimizer_g)
# optimizer d
optim_type = train_opt['optim_d'].pop('type')
self.optimizer_d = self.get_optimizer(optim_type, self.net_d.parameters(), **train_opt['optim_d'])
self.optimizers.append(self.optimizer_d)
def optimize_parameters(self, current_iter):
logger = get_root_logger()
# optimize net_g
for p in self.net_d.parameters():
p.requires_grad = False
if self.fix_flow_iter:
if current_iter == 1:
logger.info(f'Fix flow network and feature extractor for {self.fix_flow_iter} iters.')
for name, param in self.net_g.named_parameters():
if 'spynet' in name or 'edvr' in name:
param.requires_grad_(False)
elif current_iter == self.fix_flow_iter:
logger.warning('Train all the parameters.')
self.net_g.requires_grad_(True)
self.optimizer_g.zero_grad()
self.output = self.net_g(self.lq)
_, _, c, h, w = self.output.size()
l_g_total = 0
loss_dict = OrderedDict()
if (current_iter % self.net_d_iters == 0 and current_iter > self.net_d_init_iters):
# pixel loss
if self.cri_pix:
l_g_pix = self.cri_pix(self.output, self.gt)
l_g_total += l_g_pix
loss_dict['l_g_pix'] = l_g_pix
# perceptual loss
if self.cri_perceptual:
l_g_percep, l_g_style = self.cri_perceptual(self.output.view(-1, c, h, w), self.gt.view(-1, c, h, w))
if l_g_percep is not None:
l_g_total += l_g_percep
loss_dict['l_g_percep'] = l_g_percep
if l_g_style is not None:
l_g_total += l_g_style
loss_dict['l_g_style'] = l_g_style
# gan loss
fake_g_pred = self.net_d(self.output.view(-1, c, h, w))
l_g_gan = self.cri_gan(fake_g_pred, True, is_disc=False)
l_g_total += l_g_gan
loss_dict['l_g_gan'] = l_g_gan
l_g_total.backward()
self.optimizer_g.step()
# optimize net_d
for p in self.net_d.parameters():
p.requires_grad = True
self.optimizer_d.zero_grad()
# real
# reshape to (b*n, c, h, w)
real_d_pred = self.net_d(self.gt.view(-1, c, h, w))
l_d_real = self.cri_gan(real_d_pred, True, is_disc=True)
loss_dict['l_d_real'] = l_d_real
loss_dict['out_d_real'] = torch.mean(real_d_pred.detach())
l_d_real.backward()
# fake
# reshape to (b*n, c, h, w)
fake_d_pred = self.net_d(self.output.view(-1, c, h, w).detach())
l_d_fake = self.cri_gan(fake_d_pred, False, is_disc=True)
loss_dict['l_d_fake'] = l_d_fake
loss_dict['out_d_fake'] = torch.mean(fake_d_pred.detach())
l_d_fake.backward()
self.optimizer_d.step()
self.log_dict = self.reduce_loss_dict(loss_dict)
if self.ema_decay > 0:
self.model_ema(decay=self.ema_decay)
def save(self, epoch, current_iter):
if self.ema_decay > 0:
self.save_network([self.net_g, self.net_g_ema], 'net_g', current_iter, param_key=['params', 'params_ema'])
else:
self.save_network(self.net_g, 'net_g', current_iter)
self.save_network(self.net_d, 'net_d', current_iter)
self.save_training_state(epoch, current_iter)
BasicSR/basicsr/models/video_recurrent_model.py 0 → 100644
View file @ e2696ece
import torch
from collections import Counter
from os import path as osp
from torch import distributed as dist
from tqdm import tqdm
from basicsr.metrics import calculate_metric
from basicsr.utils import get_root_logger, imwrite, tensor2img
from basicsr.utils.dist_util import get_dist_info
from basicsr.utils.registry import MODEL_REGISTRY
from .video_base_model import VideoBaseModel
@MODEL_REGISTRY.register()
class VideoRecurrentModel(VideoBaseModel):
def __init__(self, opt):
super(VideoRecurrentModel, self).__init__(opt)
if self.is_train:
self.fix_flow_iter = opt['train'].get('fix_flow')
def setup_optimizers(self):
train_opt = self.opt['train']
flow_lr_mul = train_opt.get('flow_lr_mul', 1)
logger = get_root_logger()
logger.info(f'Multiple the learning rate for flow network with {flow_lr_mul}.')
if flow_lr_mul == 1:
optim_params = self.net_g.parameters()
else: # separate flow params and normal params for different lr
normal_params = []
flow_params = []
for name, param in self.net_g.named_parameters():
if 'spynet' in name:
flow_params.append(param)
else:
normal_params.append(param)
optim_params = [
{ # add normal params first
'params': normal_params,
'lr': train_opt['optim_g']['lr']
},
{
'params': flow_params,
'lr': train_opt['optim_g']['lr'] * flow_lr_mul
},
]
optim_type = train_opt['optim_g'].pop('type')
self.optimizer_g = self.get_optimizer(optim_type, optim_params, **train_opt['optim_g'])
self.optimizers.append(self.optimizer_g)
def optimize_parameters(self, current_iter):
if self.fix_flow_iter:
logger = get_root_logger()
if current_iter == 1:
logger.info(f'Fix flow network and feature extractor for {self.fix_flow_iter} iters.')
for name, param in self.net_g.named_parameters():
if 'spynet' in name or 'edvr' in name:
param.requires_grad_(False)
elif current_iter == self.fix_flow_iter:
logger.warning('Train all the parameters.')
self.net_g.requires_grad_(True)
super(VideoRecurrentModel, self).optimize_parameters(current_iter)
def dist_validation(self, dataloader, current_iter, tb_logger, save_img):
dataset = dataloader.dataset
dataset_name = dataset.opt['name']
with_metrics = self.opt['val']['metrics'] is not None
# initialize self.metric_results
# It is a dict: {
# 'folder1': tensor (num_frame x len(metrics)),
# 'folder2': tensor (num_frame x len(metrics))
# }
if with_metrics:
if not hasattr(self, 'metric_results'): # only execute in the first run
self.metric_results = {}
num_frame_each_folder = Counter(dataset.data_info['folder'])
for folder, num_frame in num_frame_each_folder.items():
self.metric_results[folder] = torch.zeros(
num_frame, len(self.opt['val']['metrics']), dtype=torch.float32, device='cuda')
# initialize the best metric results
self._initialize_best_metric_results(dataset_name)
# zero self.metric_results
rank, world_size = get_dist_info()
if with_metrics:
for _, tensor in self.metric_results.items():
tensor.zero_()
metric_data = dict()
num_folders = len(dataset)
num_pad = (world_size - (num_folders % world_size)) % world_size
if rank == 0:
pbar = tqdm(total=len(dataset), unit='folder')
# Will evaluate (num_folders + num_pad) times, but only the first num_folders results will be recorded.
# (To avoid wait-dead)
for i in range(rank, num_folders + num_pad, world_size):
idx = min(i, num_folders - 1)
val_data = dataset[idx]
folder = val_data['folder']
# compute outputs
val_data['lq'].unsqueeze_(0)
val_data['gt'].unsqueeze_(0)
self.feed_data(val_data)
val_data['lq'].squeeze_(0)
val_data['gt'].squeeze_(0)
self.test()
visuals = self.get_current_visuals()
# tentative for out of GPU memory
del self.lq
del self.output
if 'gt' in visuals:
del self.gt
torch.cuda.empty_cache()
if self.center_frame_only:
visuals['result'] = visuals['result'].unsqueeze(1)
if 'gt' in visuals:
visuals['gt'] = visuals['gt'].unsqueeze(1)
# evaluate
if i < num_folders:
for idx in range(visuals['result'].size(1)):
result = visuals['result'][0, idx, :, :, :]
result_img = tensor2img([result]) # uint8, bgr
metric_data['img'] = result_img
if 'gt' in visuals:
gt = visuals['gt'][0, idx, :, :, :]
gt_img = tensor2img([gt]) # uint8, bgr
metric_data['img2'] = gt_img
if save_img:
if self.opt['is_train']:
raise NotImplementedError('saving image is not supported during training.')
else:
if self.center_frame_only: # vimeo-90k
clip_ = val_data['lq_path'].split('/')[-3]
seq_ = val_data['lq_path'].split('/')[-2]
name_ = f'{clip_}_{seq_}'
img_path = osp.join(self.opt['path']['visualization'], dataset_name, folder,
f"{name_}_{self.opt['name']}.png")
else: # others
img_path = osp.join(self.opt['path']['visualization'], dataset_name, folder,
f"{idx:08d}_{self.opt['name']}.png")
# image name only for REDS dataset
imwrite(result_img, img_path)
# calculate metrics
if with_metrics:
for metric_idx, opt_ in enumerate(self.opt['val']['metrics'].values()):
result = calculate_metric(metric_data, opt_)
self.metric_results[folder][idx, metric_idx] += result
# progress bar
if rank == 0:
for _ in range(world_size):
pbar.update(1)
pbar.set_description(f'Folder: {folder}')
if rank == 0:
pbar.close()
if with_metrics:
if self.opt['dist']:
# collect data among GPUs
for _, tensor in self.metric_results.items():
dist.reduce(tensor, 0)
dist.barrier()
if rank == 0:
self._log_validation_metric_values(current_iter, dataset_name, tb_logger)
def test(self):
n = self.lq.size(1)
self.net_g.eval()
flip_seq = self.opt['val'].get('flip_seq', False)
self.center_frame_only = self.opt['val'].get('center_frame_only', False)
if flip_seq:
self.lq = torch.cat([self.lq, self.lq.flip(1)], dim=1)
with torch.no_grad():
self.output = self.net_g(self.lq)
if flip_seq:
output_1 = self.output[:, :n, :, :, :]
output_2 = self.output[:, n:, :, :, :].flip(1)
self.output = 0.5 * (output_1 + output_2)
if self.center_frame_only:
self.output = self.output[:, n // 2, :, :, :]
self.net_g.train()
BasicSR/basicsr/ops/dcn/__init__.py 0 → 100644
View file @ e2696ece
from .deform_conv import (DeformConv, DeformConvPack, ModulatedDeformConv, ModulatedDeformConvPack, deform_conv,
modulated_deform_conv)
__all__ = [
'DeformConv', 'DeformConvPack', 'ModulatedDeformConv', 'ModulatedDeformConvPack', 'deform_conv',
'modulated_deform_conv'
]
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