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import os
#os.environ['CUDA_VISIBLE_DEVICES'] = "0"
import argparse
import math
import random
import numpy as np
import torch
from torch import nn, optim
from torch.nn import functional as F
from torch.utils import data
import torch.distributed as dist
from torchvision import transforms, utils
from tqdm import tqdm
from PIL import Image
from util import *
from model.stylegan import lpips
from model.stylegan.model import Generator, Downsample
from model.vtoonify import VToonify, ConditionalDiscriminator
from model.bisenet.model import BiSeNet
from model.simple_augment import random_apply_affine
from model.stylegan.distributed import (
get_rank,
synchronize,
reduce_loss_dict,
reduce_sum,
get_world_size,
)
# In the paper, --weight for each style is set as follows,
# cartoon: default
# caricature: default
# pixar: 1 1 1 1 1 1 1 1 1 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5
# comic: 0.5 0.5 0.5 0.5 0.5 0.5 0.5 1 1 1 1 1 1 1 1 1 1 1
# arcane: 0.5 0.5 0.5 0.5 0.5 0.5 0.5 1 1 1 1 1 1 1 1 1 1 1
class TrainOptions():
def __init__(self):
self.parser = argparse.ArgumentParser(description="Train VToonify-T")
self.parser.add_argument("--iter", type=int, default=2000, help="total training iterations")
self.parser.add_argument("--batch", type=int, default=8, help="batch sizes for each gpus")
self.parser.add_argument("--lr", type=float, default=0.0001, help="learning rate")
self.parser.add_argument("--local_rank", type=int, default=0, help="local rank for distributed training")
self.parser.add_argument("--start_iter", type=int, default=0, help="start iteration")
self.parser.add_argument("--save_every", type=int, default=30000, help="interval of saving a checkpoint")
self.parser.add_argument("--save_begin", type=int, default=30000, help="when to start saving a checkpoint")
self.parser.add_argument("--log_every", type=int, default=200, help="interval of saving an intermediate image result")
self.parser.add_argument("--adv_loss", type=float, default=0.01, help="the weight of adv loss")
self.parser.add_argument("--grec_loss", type=float, default=0.1, help="the weight of mse recontruction loss")
self.parser.add_argument("--perc_loss", type=float, default=0.01, help="the weight of perceptual loss")
self.parser.add_argument("--tmp_loss", type=float, default=1.0, help="the weight of temporal consistency loss")
self.parser.add_argument("--encoder_path", type=str, default=None, help="path to the pretrained encoder model")
self.parser.add_argument("--direction_path", type=str, default='./checkpoint/directions.npy', help="path to the editing direction latents")
self.parser.add_argument("--stylegan_path", type=str, default='./checkpoint/stylegan2-ffhq-config-f.pt', help="path to the stylegan model")
self.parser.add_argument("--finetunegan_path", type=str, default='./checkpoint/cartoon/finetune-000600.pt', help="path to the finetuned stylegan model")
self.parser.add_argument("--weight", type=float, nargs=18, default=[1]*9+[0]*9, help="the weight for blending two models")
self.parser.add_argument("--faceparsing_path", type=str, default='./checkpoint/faceparsing.pth', help="path of the face parsing model")
self.parser.add_argument("--style_encoder_path", type=str, default='./checkpoint/encoder.pt', help="path of the style encoder")
self.parser.add_argument("--name", type=str, default='vtoonify_t_cartoon', help="saved model name")
self.parser.add_argument("--pretrain", action="store_true", help="if true, only pretrain the encoder")
def parse(self):
self.opt = self.parser.parse_args()
if self.opt.encoder_path is None:
self.opt.encoder_path = os.path.join('./checkpoint/', self.opt.name, 'pretrain.pt')
args = vars(self.opt)
if self.opt.local_rank == 0:
print('Load options')
for name, value in sorted(args.items()):
print('%s: %s' % (str(name), str(value)))
return self.opt
# pretrain E of vtoonify.
# We train E so that its the last-layer feature matches the original 8-th-layer input feature of G1
# See Model initialization in Sec. 4.1.2 for the detail
def pretrain(args, generator, g_optim, g_ema, parsingpredictor, down, directions, basemodel, device):
pbar = range(args.iter)
if get_rank() == 0:
pbar = tqdm(pbar, initial=args.start_iter, dynamic_ncols=True, smoothing=0.01)
recon_loss = torch.tensor(0.0, device=device)
loss_dict = {}
if args.distributed:
g_module = generator.module
else:
g_module = generator
accum = 0.5 ** (32 / (10 * 1000))
requires_grad(g_module.encoder, True)
for idx in pbar:
i = idx + args.start_iter
if i > args.iter:
print("Done!")
break
with torch.no_grad():
# during pretraining, no geometric transformations are applied.
noise_sample = torch.randn(args.batch, 512).cuda()
ws_ = basemodel.style(noise_sample).unsqueeze(1).repeat(1,18,1) # random w
ws_[:, 3:7] += directions[torch.randint(0, directions.shape[0], (args.batch,)), 3:7] # w''=w'=w+n
img_gen, _ = basemodel([ws_], input_is_latent=True, truncation=0.5, truncation_latent=0) # image part of x'
img_gen = torch.clamp(img_gen, -1, 1).detach()
img_gen512 = down(img_gen.detach())
img_gen256 = down(img_gen512.detach()) # image part of x'_down
mask512 = parsingpredictor(2*torch.clamp(img_gen512, -1, 1))[0]
real_input = torch.cat((img_gen256, down(mask512)/16.0), dim=1).detach() # x'_down
# f_G1^(8)(w'')
real_feat, real_skip = g_ema.generator([ws_], input_is_latent=True, return_feature_ind = 6, truncation=0.5, truncation_latent=0)
real_feat = real_feat.detach()
real_skip = real_skip.detach()
# f_E^(last)(x'_down)
fake_feat, fake_skip = generator(real_input, style=None, return_feat=True)
# L_E in Eq.(1)
recon_loss = F.mse_loss(fake_feat, real_feat) + F.mse_loss(fake_skip, real_skip)
loss_dict["emse"] = recon_loss
generator.zero_grad()
recon_loss.backward()
g_optim.step()
accumulate(g_ema.encoder, g_module.encoder, accum)
loss_reduced = reduce_loss_dict(loss_dict)
emse_loss_val = loss_reduced["emse"].mean().item()
if get_rank() == 0:
pbar.set_description(
(
f"iter: {i:d}; emse: {emse_loss_val:.3f}"
)
)
if ((i+1) >= args.save_begin and (i+1) % args.save_every == 0) or (i+1) == args.iter:
if (i+1) == args.iter:
savename = f"checkpoint/%s/pretrain.pt"%(args.name)
else:
savename = f"checkpoint/%s/pretrain-%05d.pt"%(args.name, i+1)
torch.save(
{
#"g": g_module.encoder.state_dict(),
"g_ema": g_ema.encoder.state_dict(),
},
savename,
)
# generate paired data and train vtoonify, see Sec. 4.1.2 for the detail
def train(args, generator, discriminator, g_optim, d_optim, g_ema, percept, parsingpredictor, down, pspencoder, directions, basemodel, device):
pbar = range(args.iter)
if get_rank() == 0:
pbar = tqdm(pbar, initial=args.start_iter, smoothing=0.01, ncols=120, dynamic_ncols=False)
d_loss = torch.tensor(0.0, device=device)
g_loss = torch.tensor(0.0, device=device)
grec_loss = torch.tensor(0.0, device=device)
gfeat_loss = torch.tensor(0.0, device=device)
temporal_loss = torch.tensor(0.0, device=device)
loss_dict = {}
if args.distributed:
g_module = generator.module
d_module = discriminator.module
else:
g_module = generator
d_module = discriminator
accum = 0.5 ** (32 / (10 * 1000))
for idx in pbar:
i = idx + args.start_iter
if i > args.iter:
print("Done!")
break
###### This part is for data generation. Generate pair (x, y, w'') as in Fig. 5 of the paper
with torch.no_grad():
noise_sample = torch.randn(args.batch, 512).cuda()
wc = basemodel.style(noise_sample).unsqueeze(1).repeat(1,18,1) # random w
wc[:, 3:7] += directions[torch.randint(0, directions.shape[0], (args.batch,)), 3:7] # w'=w+n
wc = wc.detach()
xc, _ = basemodel([wc], input_is_latent=True, truncation=0.5, truncation_latent=0)
xc = torch.clamp(xc, -1, 1).detach() # x'
xl = pspencoder(F.adaptive_avg_pool2d(xc, 256))
xl = basemodel.style(xl.reshape(xl.shape[0]*xl.shape[1], xl.shape[2])).reshape(xl.shape) # E_s(x'_down)
xl = torch.cat((wc[:,0:7]*0.5, xl[:,7:18]), dim=1).detach() # w'' = concatenate w' and E_s(x'_down)
xs, _ = g_ema.generator([xl], input_is_latent=True)
xs = torch.clamp(xs, -1, 1).detach() # y'
# during training, random geometric transformations are applied.
imgs, _ = random_apply_affine(torch.cat((xc.detach(),xs), dim=1), 0.2, None)
real_input1024 = imgs[:,0:3].detach() # image part of x
real_input512 = down(real_input1024).detach()
real_input256 = down(real_input512).detach()
mask512 = parsingpredictor(2*real_input512)[0]
mask256 = down(mask512).detach()
mask = F.adaptive_avg_pool2d(mask512, 1024).detach() # parsing part of x
real_output = imgs[:,3:].detach() # y
real_input = torch.cat((real_input256, mask256/16.0), dim=1) # x_down
# for log, sample a fixed input-output pair (x_down, y, w'')
if idx == 0 or i == 0:
samplein = real_input.clone().detach()
sampleout = real_output.clone().detach()
samplexl = xl.clone().detach()
###### This part is for training discriminator
requires_grad(g_module.encoder, False)
requires_grad(g_module.fusion_out, False)
requires_grad(g_module.fusion_skip, False)
requires_grad(discriminator, True)
fake_output = generator(real_input, xl)
fake_pred = discriminator(F.adaptive_avg_pool2d(fake_output, 256))
real_pred = discriminator(F.adaptive_avg_pool2d(real_output, 256))
# L_adv in Eq.(3)
d_loss = d_logistic_loss(real_pred, fake_pred) * args.adv_loss
loss_dict["d"] = d_loss
discriminator.zero_grad()
d_loss.backward()
d_optim.step()
###### This part is for training generator (encoder and fusion modules)
requires_grad(g_module.encoder, True)
requires_grad(g_module.fusion_out, True)
requires_grad(g_module.fusion_skip, True)
requires_grad(discriminator, False)
fake_output = generator(real_input, xl)
fake_pred = discriminator(F.adaptive_avg_pool2d(fake_output, 256))
# L_adv in Eq.(3)
g_loss = g_nonsaturating_loss(fake_pred) * args.adv_loss
# L_rec in Eq.(2)
grec_loss = F.mse_loss(fake_output, real_output) * args.grec_loss
gfeat_loss = percept(F.adaptive_avg_pool2d(fake_output, 512), # 1024 will out of memory
F.adaptive_avg_pool2d(real_output, 512)).sum() * args.perc_loss # 256 will get blurry output
loss_dict["g"] = g_loss
loss_dict["gr"] = grec_loss
loss_dict["gf"] = gfeat_loss
w = random.randint(0,1024-896)
h = random.randint(0,1024-896)
crop_input = torch.cat((real_input1024[:,:,w:w+896,h:h+896], mask[:,:,w:w+896,h:h+896]/16.0), dim=1).detach()
crop_input = down(down(crop_input))
crop_fake_output = fake_output[:,:,w:w+896,h:h+896]
fake_crop_output = generator(crop_input, xl)
# L_tmp in Eq.(4), gradually increase the weight of L_tmp
temporal_loss = ((fake_crop_output-crop_fake_output)**2).mean() * max(idx/(args.iter/2.0)-1, 0) * args.tmp_loss
loss_dict["tp"] = temporal_loss
generator.zero_grad()
(g_loss + grec_loss + gfeat_loss + temporal_loss).backward()
g_optim.step()
accumulate(g_ema.encoder, g_module.encoder, accum)
accumulate(g_ema.fusion_out, g_module.fusion_out, accum)
accumulate(g_ema.fusion_skip, g_module.fusion_skip, accum)
loss_reduced = reduce_loss_dict(loss_dict)
d_loss_val = loss_reduced["d"].mean().item()
g_loss_val = loss_reduced["g"].mean().item()
gr_loss_val = loss_reduced["gr"].mean().item()
gf_loss_val = loss_reduced["gf"].mean().item()
tmp_loss_val = loss_reduced["tp"].mean().item()
if get_rank() == 0:
pbar.set_description(
(
f"iter: {i:d}; advd: {d_loss_val:.3f}; advg: {g_loss_val:.3f}; mse: {gr_loss_val:.3f}; "
f"perc: {gf_loss_val:.3f}; tmp: {tmp_loss_val:.3f}"
)
)
if i % args.log_every == 0 or (i+1) == args.iter:
with torch.no_grad():
g_ema.eval()
sample = g_ema(samplein, samplexl)
sample = F.interpolate(torch.cat((sampleout, sample), dim=0), 256)
utils.save_image(
sample,
f"log/%s/%05d.jpg"%(args.name, i),
nrow=int(args.batch),
normalize=True,
range=(-1, 1),
)
if ((i+1) >= args.save_begin and (i+1) % args.save_every == 0) or (i+1) == args.iter:
if (i+1) == args.iter:
savename = f"checkpoint/%s/vtoonify.pt"%(args.name)
else:
savename = f"checkpoint/%s/vtoonify_%05d.pt"%(args.name, i+1)
torch.save(
{
#"g": g_module.state_dict(),
#"d": d_module.state_dict(),
"g_ema": g_ema.state_dict(),
},
savename,
)
if __name__ == "__main__":
device = "cuda"
parser = TrainOptions()
args = parser.parse()
if args.local_rank == 0:
print('*'*98)
if not os.path.exists("log/%s/"%(args.name)):
os.makedirs("log/%s/"%(args.name))
if not os.path.exists("checkpoint/%s/"%(args.name)):
os.makedirs("checkpoint/%s/"%(args.name))
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()
generator = VToonify(backbone = 'toonify').to(device)
generator.apply(weights_init)
g_ema = VToonify(backbone = 'toonify').to(device)
g_ema.eval()
basemodel = Generator(1024, 512, 8, 2).to(device) # G0
finetunemodel = Generator(1024, 512, 8, 2).to(device)
basemodel.load_state_dict(torch.load(args.stylegan_path, map_location=lambda storage, loc: storage)['g_ema'])
finetunemodel.load_state_dict(torch.load(args.finetunegan_path, map_location=lambda storage, loc: storage)['g_ema'])
fused_state_dict = blend_models(finetunemodel, basemodel, args.weight) # G1
generator.generator.load_state_dict(fused_state_dict) # load G1
g_ema.generator.load_state_dict(fused_state_dict)
requires_grad(basemodel, False)
requires_grad(generator.generator, False)
requires_grad(g_ema.generator, False)
if not args.pretrain:
generator.encoder.load_state_dict(torch.load(args.encoder_path, map_location=lambda storage, loc: storage)["g_ema"])
# we initialize the fusion modules to map f_G \otimes f_E to f_G.
for k in generator.fusion_out:
k.weight.data *= 0.01
k.weight[:,0:k.weight.shape[0],1,1].data += torch.eye(k.weight.shape[0]).cuda()
for k in generator.fusion_skip:
k.weight.data *= 0.01
k.weight[:,0:k.weight.shape[0],1,1].data += torch.eye(k.weight.shape[0]).cuda()
accumulate(g_ema.encoder, generator.encoder, 0)
accumulate(g_ema.fusion_out, generator.fusion_out, 0)
accumulate(g_ema.fusion_skip, generator.fusion_skip, 0)
g_parameters = list(generator.encoder.parameters())
if not args.pretrain:
g_parameters = g_parameters + list(generator.fusion_out.parameters()) + list(generator.fusion_skip.parameters())
g_optim = optim.Adam(
g_parameters,
lr=args.lr,
betas=(0.9, 0.99),
)
if args.distributed:
generator = nn.parallel.DistributedDataParallel(
generator,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
find_unused_parameters=True,
)
parsingpredictor = BiSeNet(n_classes=19)
parsingpredictor.load_state_dict(torch.load(args.faceparsing_path, map_location=lambda storage, loc: storage))
parsingpredictor.to(device).eval()
requires_grad(parsingpredictor, False)
# we apply gaussian blur to the images to avoid flickers caused during downsampling
down = Downsample(kernel=[1, 3, 3, 1], factor=2).to(device)
requires_grad(down, False)
directions = torch.tensor(np.load(args.direction_path)).to(device)
if not args.pretrain:
discriminator = ConditionalDiscriminator(256).to(device)
d_optim = optim.Adam(
discriminator.parameters(),
lr=args.lr,
betas=(0.9, 0.99),
)
if args.distributed:
discriminator = nn.parallel.DistributedDataParallel(
discriminator,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
find_unused_parameters=True,
)
percept = lpips.PerceptualLoss(model="net-lin", net="vgg", use_gpu=device.startswith("cuda"), gpu_ids=[args.local_rank])
requires_grad(percept.model.net, False)
pspencoder = load_psp_standalone(args.style_encoder_path, device)
if args.local_rank == 0:
print('Load models and data successfully loaded!')
if args.pretrain:
pretrain(args, generator, g_optim, g_ema, parsingpredictor, down, directions, basemodel, device)
else:
train(args, generator, discriminator, g_optim, d_optim, g_ema, percept, parsingpredictor, down, pspencoder, directions, basemodel, device)
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