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train
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#!/usr/bin/python3
import argparse
import itertools
import torchvision.transforms as transforms
from torch.utils.data import DataLoader
from PIL import Image
import torch
from models import Generator
from models import Discriminator
from utils import ReplayBuffer
from utils import LambdaLR
from utils import Logger
from utils import weights_init_normal
from datasets import ImageDataset
parser = argparse.ArgumentParser()
parser.add_argument('--epoch', type=int, default=0, help='starting epoch')
parser.add_argument('--n_epochs', type=int, default=64, help='number of epochs of training')
parser.add_argument('--batchSize', type=int, default=1, help='size of the batches')
parser.add_argument('--dataroot', type=str, default='datasets/sketch2images/', help='root directory of the dataset')
parser.add_argument('--lr', type=float, default=0.0002, help='initial learning rate')
parser.add_argument('--decay_epoch', type=int, default=32, help='epoch to start linearly decaying the learning rate to 0')
parser.add_argument('--size', type=int, default=256, help='size of the data crop (squared assumed)')
parser.add_argument('--input_nc', type=int, default=3, help='number of channels of input data')
parser.add_argument('--output_nc', type=int, default=3, help='number of channels of output data')
parser.add_argument('--cuda', action='store_true', help='use GPU computation')
parser.add_argument('--n_cpu', type=int, default=8, help='number of cpu threads to use during batch generation')
opt = parser.parse_args()
print(opt)
if torch.cuda.is_available() and not opt.cuda:
print("WARNING: You have a CUDA device, so you should probably run with --cuda")
device = torch.device("cuda:0" if opt.cuda else "cpu")
###### Definition of variables ######
# Networks
netG_A2B = Generator(opt.input_nc, opt.output_nc)
netG_B2A = Generator(opt.output_nc, opt.input_nc)
netD_A = Discriminator(opt.input_nc)
netD_B = Discriminator(opt.output_nc)
if opt.cuda:
netG_A2B.cuda()
netG_B2A.cuda()
netD_A.cuda()
netD_B.cuda()
netG_A2B.apply(weights_init_normal)
netG_B2A.apply(weights_init_normal)
netD_A.apply(weights_init_normal)
netD_B.apply(weights_init_normal)
# Lossess
criterion_GAN = torch.nn.MSELoss()
criterion_cycle = torch.nn.L1Loss()
criterion_identity = torch.nn.L1Loss()
# Optimizers & LR schedulers
optimizer_G = torch.optim.Adam(itertools.chain(netG_A2B.parameters(), netG_B2A.parameters()),
lr=opt.lr, betas=(0.5, 0.999))
optimizer_D_A = torch.optim.Adam(netD_A.parameters(), lr=opt.lr, betas=(0.5, 0.999))
optimizer_D_B = torch.optim.Adam(netD_B.parameters(), lr=opt.lr, betas=(0.5, 0.999))
lr_scheduler_G = torch.optim.lr_scheduler.LambdaLR(optimizer_G, lr_lambda=LambdaLR(opt.n_epochs, opt.epoch, opt.decay_epoch).step)
lr_scheduler_D_A = torch.optim.lr_scheduler.LambdaLR(optimizer_D_A, lr_lambda=LambdaLR(opt.n_epochs, opt.epoch, opt.decay_epoch).step)
lr_scheduler_D_B = torch.optim.lr_scheduler.LambdaLR(optimizer_D_B, lr_lambda=LambdaLR(opt.n_epochs, opt.epoch, opt.decay_epoch).step)
# Inputs & targets memory allocation
target_real = torch.ones(opt.batchSize, 1).to(device)
target_fake = torch.zeros(opt.batchSize, 1).to(device)
fake_A_buffer = ReplayBuffer()
fake_B_buffer = ReplayBuffer()
# Dataset loader
transforms_ = [ transforms.Resize(int(opt.size*1.12), Image.BICUBIC),
transforms.RandomCrop(opt.size),
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
transforms.Normalize((0.5,0.5,0.5), (0.5,0.5,0.5)) ]
dataloader = DataLoader(ImageDataset(opt.dataroot, transforms_=transforms_, unaligned=True),
batch_size=opt.batchSize, shuffle=True, num_workers=opt.n_cpu)
# Loss plot
logger = Logger(opt.n_epochs, len(dataloader))
###################################
###### Training ######
for epoch in range(opt.epoch, opt.n_epochs):
for i, batch in enumerate(dataloader):
# Set model input
real_A = batch['A'].to(device)
real_B = batch['B'].to(device)
print(real_A.shape)
print(real_B.shape)
###### Generators A2B and B2A ######
optimizer_G.zero_grad()
# Identity loss
# G_A2B(B) should equal B if real B is fed
same_B = netG_A2B(real_B)
loss_identity_B = criterion_identity(same_B, real_B)*5.0
# G_B2A(A) should equal A if real A is fed
same_A = netG_B2A(real_A)
loss_identity_A = criterion_identity(same_A, real_A)*5.0
# GAN loss
fake_B = netG_A2B(real_A)
pred_fake = netD_B(fake_B)
loss_GAN_A2B = criterion_GAN(pred_fake, target_real)
fake_A = netG_B2A(real_B)
pred_fake = netD_A(fake_A)
loss_GAN_B2A = criterion_GAN(pred_fake, target_real)
# Cycle loss
recovered_A = netG_B2A(fake_B)
loss_cycle_ABA = criterion_cycle(recovered_A, real_A)*10.0
recovered_B = netG_A2B(fake_A)
loss_cycle_BAB = criterion_cycle(recovered_B, real_B)*10.0
# Total loss
loss_G = loss_identity_A + loss_identity_B + loss_GAN_A2B + loss_GAN_B2A + loss_cycle_ABA + loss_cycle_BAB
loss_G.backward()
optimizer_G.step()
###################################
###### Discriminator A ######
optimizer_D_A.zero_grad()
# Real loss
pred_real = netD_A(real_A)
loss_D_real = criterion_GAN(pred_real, target_real)
# Fake loss
fake_A = fake_A_buffer.push_and_pop(fake_A)
pred_fake = netD_A(fake_A.detach())
loss_D_fake = criterion_GAN(pred_fake, target_fake)
# Total loss
loss_D_A = (loss_D_real + loss_D_fake)*0.5
loss_D_A.backward()
optimizer_D_A.step()
###################################
###### Discriminator B ######
optimizer_D_B.zero_grad()
# Real loss
pred_real = netD_B(real_B)
loss_D_real = criterion_GAN(pred_real, target_real)
# Fake loss
fake_B = fake_B_buffer.push_and_pop(fake_B)
pred_fake = netD_B(fake_B.detach())
loss_D_fake = criterion_GAN(pred_fake, target_fake)
# Total loss
loss_D_B = (loss_D_real + loss_D_fake)*0.5
loss_D_B.backward()
optimizer_D_B.step()
###################################
print("epoch")
# Progress report (http://localhost:8097)
logger.log({'loss_G': loss_G, 'loss_G_identity': (loss_identity_A + loss_identity_B), 'loss_G_GAN': (loss_GAN_A2B + loss_GAN_B2A),
'loss_G_cycle': (loss_cycle_ABA + loss_cycle_BAB), 'loss_D': (loss_D_A + loss_D_B)},
images={'real_A': real_A, 'real_B': real_B, 'fake_A': fake_A, 'fake_B': fake_B})
# Update learning rates
lr_scheduler_G.step()
lr_scheduler_D_A.step()
lr_scheduler_D_B.step()
# Save models checkpoints
torch.save(netG_A2B.state_dict(), 'output/netG_A2B.pth')
torch.save(netG_B2A.state_dict(), 'output/netG_B2A.pth')
torch.save(netD_A.state_dict(), 'output/netD_A.pth')
torch.save(netD_B.state_dict(), 'output/netD_B.pth')
###################################