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import argparse
import math
import random
import os
from util import *
import numpy as np
import torch
torch.backends.cudnn.benchmark = True
from torch import nn, autograd
from torch import 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 torch.optim import lr_scheduler
import copy
import kornia.augmentation as K
import kornia
import lpips
from model import *
from dataset import ImageFolder
from distributed import (
get_rank,
synchronize,
reduce_loss_dict,
reduce_sum,
get_world_size,
)
mse_criterion = nn.MSELoss()
def test(args, genA2B, genB2A, testA_loader, testB_loader, name, step):
testA_loader = iter(testA_loader)
testB_loader = iter(testB_loader)
with torch.no_grad():
test_sample_num = 16
genA2B.eval(), genB2A.eval()
A2B = []
B2A = []
for i in range(test_sample_num):
real_A = testA_loader.next()
real_B = testB_loader.next()
real_A, real_B = real_A.cuda(), real_B.cuda()
A2B_content, A2B_style = genA2B.encode(real_A)
B2A_content, B2A_style = genB2A.encode(real_B)
if i % 2 == 0:
A2B_mod1 = torch.randn([1, args.latent_dim]).cuda()
B2A_mod1 = torch.randn([1, args.latent_dim]).cuda()
A2B_mod2 = torch.randn([1, args.latent_dim]).cuda()
B2A_mod2 = torch.randn([1, args.latent_dim]).cuda()
fake_B2B, _, _ = genA2B(real_B)
fake_A2A, _, _ = genB2A(real_A)
colsA = [real_A, fake_A2A]
colsB = [real_B, fake_B2B]
fake_A2B_1 = genA2B.decode(A2B_content, A2B_mod1)
fake_B2A_1 = genB2A.decode(B2A_content, B2A_mod1)
fake_A2B_2 = genA2B.decode(A2B_content, A2B_mod2)
fake_B2A_2 = genB2A.decode(B2A_content, B2A_mod2)
fake_A2B_3 = genA2B.decode(A2B_content, B2A_style)
fake_B2A_3 = genB2A.decode(B2A_content, A2B_style)
colsA += [fake_A2B_3, fake_A2B_1, fake_A2B_2]
colsB += [fake_B2A_3, fake_B2A_1, fake_B2A_2]
fake_A2B2A, _, _ = genB2A(fake_A2B_3, A2B_style)
fake_B2A2B, _, _ = genA2B(fake_B2A_3, B2A_style)
colsA.append(fake_A2B2A)
colsB.append(fake_B2A2B)
fake_A2B2A, _, _ = genB2A(fake_A2B_1, A2B_style)
fake_B2A2B, _, _ = genA2B(fake_B2A_1, B2A_style)
colsA.append(fake_A2B2A)
colsB.append(fake_B2A2B)
fake_A2B2A, _, _ = genB2A(fake_A2B_2, A2B_style)
fake_B2A2B, _, _ = genA2B(fake_B2A_2, B2A_style)
colsA.append(fake_A2B2A)
colsB.append(fake_B2A2B)
fake_A2B2A, _, _ = genB2A(fake_A2B_1)
fake_B2A2B, _, _ = genA2B(fake_B2A_1)
colsA.append(fake_A2B2A)
colsB.append(fake_B2A2B)
colsA = torch.cat(colsA, 2).detach().cpu()
colsB = torch.cat(colsB, 2).detach().cpu()
A2B.append(colsA)
B2A.append(colsB)
A2B = torch.cat(A2B, 0)
B2A = torch.cat(B2A, 0)
utils.save_image(A2B, f'{im_path}/{name}_A2B_{str(step).zfill(6)}.jpg', normalize=True, range=(-1, 1), nrow=16)
utils.save_image(B2A, f'{im_path}/{name}_B2A_{str(step).zfill(6)}.jpg', normalize=True, range=(-1, 1), nrow=16)
genA2B.train(), genB2A.train()
def train(args, trainA_loader, trainB_loader, testA_loader, testB_loader, G_A2B, G_B2A, D_A, D_B, G_optim, D_optim, device):
G_A2B.train(), G_B2A.train(), D_A.train(), D_B.train()
trainA_loader = sample_data(trainA_loader)
trainB_loader = sample_data(trainB_loader)
G_scheduler = lr_scheduler.StepLR(G_optim, step_size=100000, gamma=0.5)
D_scheduler = lr_scheduler.StepLR(D_optim, step_size=100000, gamma=0.5)
pbar = range(args.iter)
if get_rank() == 0:
pbar = tqdm(pbar, initial=args.start_iter, dynamic_ncols=True, smoothing=0.1)
loss_dict = {}
mean_path_length_A2B = 0
mean_path_length_B2A = 0
if args.distributed:
G_A2B_module = G_A2B.module
G_B2A_module = G_B2A.module
D_A_module = D_A.module
D_B_module = D_B.module
D_L_module = D_L.module
else:
G_A2B_module = G_A2B
G_B2A_module = G_B2A
D_A_module = D_A
D_B_module = D_B
D_L_module = D_L
for idx in pbar:
i = idx + args.start_iter
if i > args.iter:
print('Done!')
break
ori_A = next(trainA_loader)
ori_B = next(trainB_loader)
if isinstance(ori_A, list):
ori_A = ori_A[0]
if isinstance(ori_B, list):
ori_B = ori_B[0]
ori_A = ori_A.to(device)
ori_B = ori_B.to(device)
aug_A = aug(ori_A)
aug_B = aug(ori_B)
A = aug(ori_A[[np.random.randint(args.batch)]].expand_as(ori_A))
B = aug(ori_B[[np.random.randint(args.batch)]].expand_as(ori_B))
if i % args.d_reg_every == 0:
aug_A.requires_grad = True
aug_B.requires_grad = True
A2B_content, A2B_style = G_A2B.encode(A)
B2A_content, B2A_style = G_B2A.encode(B)
# get new style
aug_A2B_style = G_B2A.style_encode(aug_B)
aug_B2A_style = G_A2B.style_encode(aug_A)
rand_A2B_style = torch.randn([args.batch, args.latent_dim]).to(device).requires_grad_()
rand_B2A_style = torch.randn([args.batch, args.latent_dim]).to(device).requires_grad_()
# styles
idx = torch.randperm(2*args.batch)
input_A2B_style = torch.cat([rand_A2B_style, aug_A2B_style], 0)[idx][:args.batch]
idx = torch.randperm(2*args.batch)
input_B2A_style = torch.cat([rand_B2A_style, aug_B2A_style], 0)[idx][:args.batch]
fake_A2B = G_A2B.decode(A2B_content, input_A2B_style)
fake_B2A = G_B2A.decode(B2A_content, input_B2A_style)
# train disc
real_A_logit = D_A(aug_A)
real_B_logit = D_B(aug_B)
real_L_logit1 = D_L(rand_A2B_style)
real_L_logit2 = D_L(rand_B2A_style)
fake_B_logit = D_B(fake_A2B.detach())
fake_A_logit = D_A(fake_B2A.detach())
fake_L_logit1 = D_L(aug_A2B_style.detach())
fake_L_logit2 = D_L(aug_B2A_style.detach())
# global loss
D_loss = d_logistic_loss(real_A_logit, fake_A_logit) +\
d_logistic_loss(real_B_logit, fake_B_logit) +\
d_logistic_loss(real_L_logit1, fake_L_logit1) +\
d_logistic_loss(real_L_logit2, fake_L_logit2)
loss_dict['D_adv'] = D_loss
if i % args.d_reg_every == 0:
r1_A_loss = d_r1_loss(real_A_logit, aug_A)
r1_B_loss = d_r1_loss(real_B_logit, aug_B)
r1_L_loss = d_r1_loss(real_L_logit1, rand_A2B_style) + d_r1_loss(real_L_logit2, rand_B2A_style)
r1_loss = r1_A_loss + r1_B_loss + r1_L_loss
D_r1_loss = (args.r1 / 2 * r1_loss * args.d_reg_every)
D_loss += D_r1_loss
D_optim.zero_grad()
D_loss.backward()
D_optim.step()
#Generator
# adv loss
fake_B_logit = D_B(fake_A2B)
fake_A_logit = D_A(fake_B2A)
fake_L_logit1 = D_L(aug_A2B_style)
fake_L_logit2 = D_L(aug_B2A_style)
lambda_adv = (1, 1, 1)
G_adv_loss = 1 * (g_nonsaturating_loss(fake_A_logit, lambda_adv) +\
g_nonsaturating_loss(fake_B_logit, lambda_adv) +\
2*g_nonsaturating_loss(fake_L_logit1, (1,)) +\
2*g_nonsaturating_loss(fake_L_logit2, (1,)))
# style consis loss
G_con_loss = 50 * (A2B_style.var(0, unbiased=False).sum() + B2A_style.var(0, unbiased=False).sum())
# cycle recon
A2B2A_content, A2B2A_style = G_B2A.encode(fake_A2B)
B2A2B_content, B2A2B_style = G_A2B.encode(fake_B2A)
fake_A2B2A = G_B2A.decode(A2B2A_content, shuffle_batch(A2B_style))
fake_B2A2B = G_A2B.decode(B2A2B_content, shuffle_batch(B2A_style))
G_cycle_loss = 20 * (F.mse_loss(fake_A2B2A, A) + F.mse_loss(fake_B2A2B, B))
lpips_loss = 10 * (lpips_fn(fake_A2B2A, A).mean() + lpips_fn(fake_B2A2B, B).mean()) #10 for anime
# style reconstruction
G_style_loss = 5 * (mse_criterion(A2B2A_style, input_A2B_style) +\
mse_criterion(B2A2B_style, input_B2A_style))
G_loss = G_adv_loss + G_cycle_loss + G_con_loss + lpips_loss + G_style_loss
loss_dict['G_adv'] = G_adv_loss
loss_dict['G_con'] = G_con_loss
loss_dict['G_cycle'] = G_cycle_loss
loss_dict['lpips'] = lpips_loss
G_optim.zero_grad()
G_loss.backward()
G_optim.step()
G_scheduler.step()
D_scheduler.step()
accumulate(G_A2B_ema, G_A2B_module)
accumulate(G_B2A_ema, G_B2A_module)
loss_reduced = reduce_loss_dict(loss_dict)
D_adv_loss_val = loss_reduced['D_adv'].mean().item()
G_adv_loss_val = loss_reduced['G_adv'].mean().item()
G_cycle_loss_val = loss_reduced['G_cycle'].mean().item()
G_con_loss_val = loss_reduced['G_con'].mean().item()
lpips_val = loss_reduced['lpips'].mean().item()
if get_rank() == 0:
pbar.set_description(
(
f'Dadv: {D_adv_loss_val:.2f}; lpips: {lpips_val:.2f} '
f'Gadv: {G_adv_loss_val:.2f}; Gcycle: {G_cycle_loss_val:.2f}; GMS: {G_con_loss_val:.2f} {G_style_loss.item():.2f}'
)
)
if i % 1000 == 0:
with torch.no_grad():
test(args, G_A2B, G_B2A, testA_loader, testB_loader, 'normal', i)
test(args, G_A2B_ema, G_B2A_ema, testA_loader, testB_loader, 'ema', i)
if (i+1) % 2000 == 0:
torch.save(
{
'G_A2B': G_A2B_module.state_dict(),
'G_B2A': G_B2A_module.state_dict(),
'G_A2B_ema': G_A2B_ema.state_dict(),
'G_B2A_ema': G_B2A_ema.state_dict(),
'D_A': D_A_module.state_dict(),
'D_B': D_B_module.state_dict(),
'D_L': D_L_module.state_dict(),
'G_optim': G_optim.state_dict(),
'D_optim': D_optim.state_dict(),
'iter': i,
},
os.path.join(model_path, 'ck.pt'),
)
if __name__ == '__main__':
device = 'cuda'
parser = argparse.ArgumentParser()
parser.add_argument('--iter', type=int, default=300000)
parser.add_argument('--batch', type=int, default=4)
parser.add_argument('--n_sample', type=int, default=64)
parser.add_argument('--size', type=int, default=256)
parser.add_argument('--r1', type=float, default=10)
parser.add_argument('--lambda_cycle', type=int, default=1)
parser.add_argument('--path_regularize', type=float, default=2)
parser.add_argument('--path_batch_shrink', type=int, default=2)
parser.add_argument('--d_reg_every', type=int, default=16)
parser.add_argument('--g_reg_every', type=int, default=4)
parser.add_argument('--mixing', type=float, default=0.9)
parser.add_argument('--ckpt', type=str, default=None)
parser.add_argument('--lr', type=float, default=2e-3)
parser.add_argument('--local_rank', type=int, default=0)
parser.add_argument('--num_down', type=int, default=3)
parser.add_argument('--name', type=str, required=True)
parser.add_argument('--d_path', type=str, required=True)
parser.add_argument('--latent_dim', type=int, default=8)
parser.add_argument('--lr_mlp', type=float, default=0.01)
parser.add_argument('--n_res', type=int, default=1)
args = parser.parse_args()
n_gpu = int(os.environ['WORLD_SIZE']) if 'WORLD_SIZE' in os.environ else 1
args.distributed = False
if args.distributed:
torch.cuda.set_device(args.local_rank)
torch.distributed.init_process_group(backend='nccl', init_method='env://')
synchronize()
save_path = f'./{args.name}'
im_path = os.path.join(save_path, 'sample')
model_path = os.path.join(save_path, 'checkpoint')
os.makedirs(im_path, exist_ok=True)
os.makedirs(model_path, exist_ok=True)
args.n_mlp = 5
args.start_iter = 0
G_A2B = Generator( args.size, args.num_down, args.latent_dim, args.n_mlp, lr_mlp=args.lr_mlp, n_res=args.n_res).to(device)
D_A = Discriminator(args.size).to(device)
G_B2A = Generator( args.size, args.num_down, args.latent_dim, args.n_mlp, lr_mlp=args.lr_mlp, n_res=args.n_res).to(device)
D_B = Discriminator(args.size).to(device)
D_L = LatDiscriminator(args.latent_dim).to(device)
lpips_fn = lpips.LPIPS(net='vgg').to(device)
G_A2B_ema = copy.deepcopy(G_A2B).to(device).eval()
G_B2A_ema = copy.deepcopy(G_B2A).to(device).eval()
g_reg_ratio = args.g_reg_every / (args.g_reg_every + 1)
d_reg_ratio = args.d_reg_every / (args.d_reg_every + 1)
G_optim = optim.Adam( list(G_A2B.parameters()) + list(G_B2A.parameters()), lr=args.lr, betas=(0, 0.99))
D_optim = optim.Adam(
list(D_L.parameters()) + list(D_A.parameters()) + list(D_B.parameters()),
lr=args.lr, betas=(0**d_reg_ratio, 0.99**d_reg_ratio))
if args.ckpt is not None:
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
G_A2B.load_state_dict(ckpt['G_A2B'])
G_B2A.load_state_dict(ckpt['G_B2A'])
G_A2B_ema.load_state_dict(ckpt['G_A2B_ema'])
G_B2A_ema.load_state_dict(ckpt['G_B2A_ema'])
D_A.load_state_dict(ckpt['D_A'])
D_B.load_state_dict(ckpt['D_B'])
D_L.load_state_dict(ckpt['D_L'])
G_optim.load_state_dict(ckpt['G_optim'])
D_optim.load_state_dict(ckpt['D_optim'])
args.start_iter = ckpt['iter']
if args.distributed:
G_A2B = nn.parallel.DistributedDataParallel(
G_A2B,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
)
D_A = nn.parallel.DistributedDataParallel(
D_A,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
)
G_B2A = nn.parallel.DistributedDataParallel(
G_B2A,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
)
D_B = nn.parallel.DistributedDataParallel(
D_B,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
)
D_L = nn.parallel.DistributedDataParallel(
D_L,
device_ids=[args.local_rank],
output_device=args.local_rank,
broadcast_buffers=False,
)
train_transform = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize(mean=(0.5, 0.5, 0.5), std=(0.5, 0.5, 0.5), inplace=True)
])
test_transform = transforms.Compose([
transforms.Resize((args.size, args.size)),
transforms.ToTensor(),
transforms.Normalize(mean=(0.5, 0.5, 0.5), std=(0.5, 0.5, 0.5), inplace=True)
])
aug = nn.Sequential(
K.RandomAffine(degrees=(-20,20), scale=(0.8, 1.2), translate=(0.1, 0.1), shear=0.15),
kornia.geometry.transform.Resize(256+30),
K.RandomCrop((256,256)),
K.RandomHorizontalFlip(),
)
d_path = args.d_path
trainA = ImageFolder(os.path.join(d_path, 'trainA'), train_transform)
trainB = ImageFolder(os.path.join(d_path, 'trainB'), train_transform)
testA = ImageFolder(os.path.join(d_path, 'testA'), test_transform)
testB = ImageFolder(os.path.join(d_path, 'testB'), test_transform)
trainA_loader = data.DataLoader(trainA, batch_size=args.batch,
sampler=data_sampler(trainA, shuffle=True, distributed=args.distributed), drop_last=True, pin_memory=True, num_workers=5)
trainB_loader = data.DataLoader(trainB, batch_size=args.batch,
sampler=data_sampler(trainB, shuffle=True, distributed=args.distributed), drop_last=True, pin_memory=True, num_workers=5)
testA_loader = data.DataLoader(testA, batch_size=1, shuffle=False)
testB_loader = data.DataLoader(testB, batch_size=1, shuffle=False)
train(args, trainA_loader, trainB_loader, testA_loader, testB_loader, G_A2B, G_B2A, D_A, D_B, G_optim, D_optim, device)
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