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Example_Based_Manga_Colorization

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Example_Based_Manga_Colorization / train.py
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import argparse
import os
import numpy as np
from PIL import Image
from skimage import color, io
import torch
from torch import nn, optim
from torch.nn import functional as F
from torch.utils import data
from torchvision import transforms
from tqdm import tqdm
# from ColorEncoder import ColorEncoder
from models import ColorEncoder, ColorUNet
from vgg_model import vgg19
from data.data_loader import MultiResolutionDataset
from utils import tensor_lab2rgb
from distributed import (
 get_rank,
 synchronize,
 reduce_loss_dict,
)
def mkdirss(dirpath):
 if not os.path.exists(dirpath):
 os.makedirs(dirpath)
def data_sampler(dataset, shuffle, distributed):
 if distributed:
 return data.distributed.DistributedSampler(dataset, shuffle=shuffle)
if shuffle:
 return data.RandomSampler(dataset)
else:
 return data.SequentialSampler(dataset)
def requires_grad(model, flag=True):
 for p in model.parameters():
 p.requires_grad = flag
def sample_data(loader):
 while True:
 for batch in loader:
 yield batch
def Lab2RGB_out(img_lab):
 img_lab = img_lab.detach().cpu()
 img_l = img_lab[:,:1,:,:]
 img_ab = img_lab[:,1:,:,:]
 # print(torch.max(img_l), torch.min(img_l))
 # print(torch.max(img_ab), torch.min(img_ab))
 img_l = img_l + 50
 pred_lab = torch.cat((img_l, img_ab), 1)[0,...].numpy()
 # grid_lab = utils.make_grid(pred_lab, nrow=1).numpy().astype("float64")
 # print(grid_lab.shape)
 out = (np.clip(color.lab2rgb(pred_lab.transpose(1, 2, 0)), 0, 1)* 255).astype("uint8")
 return out
def RGB2Lab(inputs):
 # input [0, 255] uint8
 # out l: [0, 100], ab: [-110, 110], float32
 return color.rgb2lab(inputs)
def Normalize(inputs):
 l = inputs[:, :, 0:1]
 ab = inputs[:, :, 1:3]
 l = l - 50
 lab = np.concatenate((l, ab), 2)
return lab.astype('float32')
def numpy2tensor(inputs):
 out = torch.from_numpy(inputs.transpose(2,0,1))
 return out
def tensor2numpy(inputs):
 out = inputs[0,...].detach().cpu().numpy().transpose(1,2,0)
 return out
def preprocessing(inputs):
 # input: rgb, [0, 255], uint8
 img_lab = Normalize(RGB2Lab(inputs))
 img = np.array(inputs, 'float32') # [0, 255]
 img = numpy2tensor(img)
 img_lab = numpy2tensor(img_lab)
 return img.unsqueeze(0), img_lab.unsqueeze(0)
def uncenter_l(inputs):
 l = inputs[:,:1,:,:] + 50
 ab = inputs[:,1:,:,:]
 return torch.cat((l, ab), 1)
def train(
 args,
 loader,
 colorEncoder,
 colorUNet,
 vggnet,
 g_optim,
 device,
):
 loader = sample_data(loader)
pbar = range(args.iter)
if get_rank() == 0:
 pbar = tqdm(pbar, initial=args.start_iter, dynamic_ncols=True, smoothing=0.01)
g_loss_val = 0
 loss_dict = {}
 recon_val_all = 0
 fea_val_all = 0
if args.distributed:
 colorEncoder_module = colorEncoder.module
 colorUNet_module = colorUNet.module
else:
 colorEncoder_module = colorEncoder
 colorUNet_module = colorUNet
for idx in pbar:
 i = idx + args.start_iter+1
if i > args.iter:
 print("Done!")
break
img, img_ref, img_lab = next(loader)
# ima = img_ref.numpy()
 # ima = ima[0].astype('uint8')
 # ima = Image.fromarray(ima.transpose(1,2,0))
 # ima.show()
img = img.to(device) # GT [B, 3, 256, 256]
 img_lab = img_lab.to(device) # GT
img_ref = img_ref.to(device) # tps_transformed image RGB [B, 3, 256, 256]
img_l = img_lab[:,:1,:,:] / 50 # [-1, 1] target L
 img_ab = img_lab[:,1:,:,:] / 110 # [-1, 1] target ab
 # img_ref_ab = img_ref_lab[:,1:,:,:] / 110 # [-1, 1] ref ab
colorEncoder.train()
 colorUNet.train()
requires_grad(colorEncoder, True)
 requires_grad(colorUNet, True)
ref_color_vector = colorEncoder(img_ref / 255.)
fake_swap_ab = colorUNet((img_l, ref_color_vector)) # [-1, 1]
## recon l1 loss
 recon_loss = (F.smooth_l1_loss(fake_swap_ab, img_ab)) * 1
## feature loss
 real_img_rgb = img / 255.
 features_A = vggnet(real_img_rgb, layer_name='all')
fake_swap_rgb = tensor_lab2rgb(torch.cat((img_l*50+50, fake_swap_ab*110), 1)) # [0, 1]
 features_B = vggnet(fake_swap_rgb, layer_name='all')
 # fea_loss = F.l1_loss(features_A[-1], features_B[-1]) * 0.1
 # fea_loss = 0
fea_loss1 = F.l1_loss(features_A[0], features_B[0]) / 32 * 0.1
 fea_loss2 = F.l1_loss(features_A[1], features_B[1]) / 16 * 0.1
 fea_loss3 = F.l1_loss(features_A[2], features_B[2]) / 8 * 0.1
 fea_loss4 = F.l1_loss(features_A[3], features_B[3]) / 4 * 0.1
 fea_loss5 = F.l1_loss(features_A[4], features_B[4]) * 0.1
fea_loss = fea_loss1 + fea_loss2 + fea_loss3 + fea_loss4 + fea_loss5
loss_dict["recon"] = recon_loss
loss_dict["fea"] = fea_loss
g_optim.zero_grad()
 (recon_loss+fea_loss).backward()
 g_optim.step()
loss_reduced = reduce_loss_dict(loss_dict)
recon_val = loss_reduced["recon"].mean().item()
 recon_val_all += recon_val
 # recon_val = 0
 fea_val = loss_reduced["fea"].mean().item()
 fea_val_all += fea_val
 # fea_val = 0
if get_rank() == 0:
 pbar.set_description(
 (
 f"recon:{recon_val:.4f}; fea:{fea_val:.4f};"
 )
 )
if i % 50 == 0:
 print(f"recon_all:{recon_val_all/50:.4f}; fea_all:{fea_val_all/50:.4f};")
 recon_val_all = 0
 fea_val_all = 0
if i % 500 == 0:
 with torch.no_grad():
 colorEncoder.eval()
 colorUNet.eval()
imgsize = 256
 for inum in range(15):
 val_img_path = 'test_datasets/val_Manga/in%d.jpg' % (inum + 1)
 val_ref_path = 'test_datasets/val_Manga/ref%d.jpg' % (inum + 1)
 # val_img_path = 'test_datasets/val_daytime/day_sample/in%d.jpg'%(inum+1)
 # val_ref_path = 'test_datasets/val_daytime/night_sample/dark4.jpg'
 out_name = 'in%d_ref%d.png'%(inum+1, inum+1)
 val_img = Image.open(val_img_path).convert("RGB").resize((imgsize, imgsize))
 val_img_ref = Image.open(val_ref_path).convert("RGB").resize((imgsize, imgsize))
 val_img, val_img_lab = preprocessing(val_img)
 val_img_ref, val_img_ref_lab = preprocessing(val_img_ref)
# val_img = val_img.to(device)
 val_img_lab = val_img_lab.to(device)
 val_img_ref = val_img_ref.to(device)
 # val_img_ref_lab = val_img_ref_lab.to(device)
val_img_l = val_img_lab[:,:1,:,:] / 50. # [-1, 1]
 # val_img_ref_ab = val_img_ref_lab[:,1:,:,:] / 110. # [-1, 1]
ref_color_vector = colorEncoder(val_img_ref / 255.) # [0, 1]
 fake_swap_ab = colorUNet((val_img_l, ref_color_vector))
fake_img = torch.cat((val_img_l*50, fake_swap_ab*110), 1)
sample = np.concatenate((tensor2numpy(val_img), tensor2numpy(val_img_ref), Lab2RGB_out(fake_img)), 1)
out_dir = 'training_logs/%s/%06d'%(args.experiment_name, i)
 mkdirss(out_dir)
 io.imsave('%s/%s'%(out_dir, out_name), sample.astype('uint8'))
 torch.cuda.empty_cache()
 if i % 2500 == 0:
 out_dir = "experiments/%s"%(args.experiment_name)
 mkdirss(out_dir)
 torch.save(
 {
 "colorEncoder": colorEncoder_module.state_dict(),
 "colorUNet": colorUNet_module.state_dict(),
 "g_optim": g_optim.state_dict(),
 "args": args,
 },
 f"%s/{str(i).zfill(6)}.pt"%(out_dir),
 )
if __name__ == "__main__":
 device = "cuda"
torch.backends.cudnn.benchmark = True
parser = argparse.ArgumentParser()
parser.add_argument("--datasets", type=str)
 parser.add_argument("--iter", type=int, default=100000)
 parser.add_argument("--batch", type=int, default=16)
 parser.add_argument("--size", type=int, default=256)
 parser.add_argument("--ckpt", type=str, default=None)
 parser.add_argument("--lr", type=float, default=0.0001)
 parser.add_argument("--experiment_name", type=str, default="default")
 parser.add_argument("--wandb", action="store_true")
 parser.add_argument("--local_rank", type=int, default=0)
args = parser.parse_args()
n_gpu = int(os.environ["WORLD_SIZE"]) if "WORLD_SIZE" in os.environ else 1
 args.distributed = n_gpu > 1
if args.distributed:
 torch.cuda.set_device(args.local_rank)
 torch.distributed.init_process_group(backend="nccl", init_method="env://")
 synchronize()
args.start_iter = 0
vggnet = vgg19(pretrained_path = './experiments/VGG19/vgg19-dcbb9e9d.pth', require_grad = False)
 vggnet = vggnet.to(device)
 vggnet.eval()
colorEncoder = ColorEncoder(color_dim=512).to(device)
 colorUNet = ColorUNet(bilinear=True).to(device)
g_optim = optim.Adam(
 list(colorEncoder.parameters()) + list(colorUNet.parameters()),
 lr=args.lr,
 betas=(0.9, 0.99),
 )
if args.ckpt is not None:
 print("load model:", args.ckpt)
ckpt = torch.load(args.ckpt, map_location=lambda storage, loc: storage)
try:
 ckpt_name = os.path.basename(args.ckpt)
 args.start_iter = int(os.path.splitext(ckpt_name)[0])
except ValueError:
 pass
colorEncoder.load_state_dict(ckpt["colorEncoder"])
 colorUNet.load_state_dict(ckpt["colorUNet"])
 g_optim.load_state_dict(ckpt["g_optim"])
# print(args.distributed)
if args.distributed:
 colorEncoder = nn.parallel.DistributedDataParallel(
 colorEncoder,
 device_ids=[args.local_rank],
 output_device=args.local_rank,
 broadcast_buffers=False,
 )
colorUNet = nn.parallel.DistributedDataParallel(
 colorUNet,
 device_ids=[args.local_rank],
 output_device=args.local_rank,
 broadcast_buffers=False,
 )
transform = transforms.Compose(
 [
 transforms.RandomHorizontalFlip(),
 transforms.RandomVerticalFlip(),
 transforms.RandomRotation(degrees=(0, 360))
 ]
 )
datasets = []
 dataset = MultiResolutionDataset(args.datasets, transform, args.size)
 datasets.append(dataset)
loader = data.DataLoader(
 data.ConcatDataset(datasets),
 batch_size=args.batch,
 sampler=data_sampler(dataset, shuffle=True, distributed=args.distributed),
 drop_last=True,
 )
train(
 args,
 loader,
 colorEncoder,
 colorUNet,
 vggnet,
 g_optim,
 device,
 )