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main_1.py
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main_1.py
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import torch
import numpy
import argparse
numpy.random.seed(8)
torch.manual_seed(8)
torch.cuda.manual_seed(8)
from network_1 import VaeGan
from torch.autograd import Variable
from torch.utils.data import Dataset
from tensorboardX import SummaryWriter
from torch.optim import RMSprop,Adam,SGD
from torch.optim.lr_scheduler import ExponentialLR,MultiStepLR
import progressbar
from torchvision.utils import make_grid
from generator import CELEBA,CELEBA_SLURM
from utils import RollingMeasure
if __name__ == "__main__":
parser = argparse.ArgumentParser(description="VAEGAN")
parser.add_argument("--train_folder",action="store",dest="train_folder")
parser.add_argument("--test_folder",action="store",dest="test_folder")
parser.add_argument("--n_epochs",default=12,action="store",type=int,dest="n_epochs")
parser.add_argument("--z_size",default=128,action="store",type=int,dest="z_size")
parser.add_argument("--recon_level",default=3,action="store",type=int,dest="recon_level")
parser.add_argument("--lambda_mse",default=1e-6,action="store",type=float,dest="lambda_mse")
parser.add_argument("--lr",default=3e-4,action="store",type=float,dest="lr")
parser.add_argument("--decay_lr",default=0.75,action="store",type=float,dest="decay_lr")
parser.add_argument("--decay_mse",default=1,action="store",type=float,dest="decay_mse")
parser.add_argument("--decay_margin",default=1,action="store",type=float,dest="decay_margin")
parser.add_argument("--decay_equilibrium",default=1,action="store",type=float,dest="decay_equilibrium")
parser.add_argument("--slurm",default=False,action="store",type=bool,dest="slurm")
args = parser.parse_args()
train_folder = args.train_folder
test_folder = args.test_folder
z_size = args.z_size
recon_level = args.recon_level
decay_mse = args.decay_mse
decay_margin = args.decay_margin
n_epochs = args.n_epochs
lambda_mse = args.lambda_mse
lr = args.lr
decay_lr = args.decay_lr
decay_equilibrium = args.decay_equilibrium
slurm = args.slurm
writer = SummaryWriter(comment="_CELEBA_ALL")
net = VaeGan(z_size=z_size,recon_level=recon_level).cuda()
# DATASET
if not slurm:
dataloader = torch.utils.data.DataLoader(CELEBA(train_folder), batch_size=64,
shuffle=True, num_workers=4)
# DATASET for test
# if you want to split train from test just move some files in another dir
dataloader_test = torch.utils.data.DataLoader(CELEBA(test_folder), batch_size=100,
shuffle=False, num_workers=1)
else:
dataloader = torch.utils.data.DataLoader(CELEBA_SLURM(train_folder), batch_size=64,
shuffle=True, num_workers=4)
# DATASET for test
# if you want to split train from test just move some files in another dir
dataloader_test = torch.utils.data.DataLoader(CELEBA_SLURM(test_folder), batch_size=100,
shuffle=False, num_workers=1)
#margin and equilibirum
margin = 0.35
equilibrium = 0.68
#mse_lambda = 1.0
# OPTIM-LOSS
# an optimizer for each of the sub-networks, so we can selectively backprop
optimizer_encoder = RMSprop(params=net.encoder.parameters(),lr=lr,alpha=0.9,eps=1e-8,weight_decay=0,momentum=0,centered=False)
#lr_encoder = MultiStepLR(optimizer_encoder,milestones=[2],gamma=1)
lr_encoder = ExponentialLR(optimizer_encoder, gamma=decay_lr)
optimizer_decoder = RMSprop(params=net.decoder.parameters(),lr=lr,alpha=0.9,eps=1e-8,weight_decay=0,momentum=0,centered=False)
lr_decoder = ExponentialLR(optimizer_decoder, gamma=decay_lr)
#lr_decoder = MultiStepLR(optimizer_decoder,milestones=[2],gamma=1)
optimizer_discriminator = RMSprop(params=net.discriminator.parameters(),lr=lr,alpha=0.9,eps=1e-8,weight_decay=0,momentum=0,centered=False)
lr_discriminator = ExponentialLR(optimizer_discriminator, gamma=decay_lr)
#lr_discriminator = MultiStepLR(optimizer_discriminator,milestones=[2],gamma=1)
batch_number = len(dataloader)
step_index = 0
widgets = [
'Batch: ', progressbar.Counter(),
'/', progressbar.FormatCustomText('%(total)s', {"total": batch_number}),
' ', progressbar.Bar(marker="-", left='[', right=']'),
' ', progressbar.ETA(),
' ',
progressbar.DynamicMessage('loss_nle'),
' ',
progressbar.DynamicMessage('loss_encoder'),
' ',
progressbar.DynamicMessage('loss_decoder'),
' ',
progressbar.DynamicMessage('loss_discriminator'),
' ',
progressbar.DynamicMessage('loss_mse_layer'),
' ',
progressbar.DynamicMessage('loss_kld'),
' ',
progressbar.DynamicMessage("epoch")
]
if slurm:
print(args)
# for each epoch
for i in range(n_epochs):
progress = progressbar.ProgressBar(min_value=0, max_value=batch_number, initial_value=0,
widgets=widgets).start()
# reset rolling average
loss_nle_mean = RollingMeasure()
loss_encoder_mean = RollingMeasure()
loss_decoder_mean = RollingMeasure()
loss_discriminator_mean = RollingMeasure()
loss_reconstruction_layer_mean = RollingMeasure()
loss_kld_mean = RollingMeasure()
gan_gen_eq_mean = RollingMeasure()
gan_dis_eq_mean = RollingMeasure()
#print("LR:{}".format(lr_encoder.get_lr()))
# for each batch
for j, (data_batch,target_batch) in enumerate(dataloader):
# set to train mode
train_batch = len(data_batch)
net.train()
# target and input are the same images
data_target = Variable(target_batch, requires_grad=False).float().cuda()
data_in = Variable(data_batch, requires_grad=False).float().cuda()
# get output
out, out_labels, out_layer, mus, variances = net(data_in)
# split so we can get the different parts
out_layer_predicted = out_layer[:train_batch]
out_layer_original = out_layer[train_batch:-train_batch]
out_layer_sampled = out_layer[-train_batch:]
#labels
out_labels_predicted = out_labels[:train_batch]
out_labels_original = out_labels[train_batch:-train_batch]
out_labels_sampled = out_labels[-train_batch:]
# loss, nothing special here
nle_value, kl_value, mse_value_1,mse_value_2, bce_dis_original_value, bce_dis_sampled_value, \
bce_dis_predicted_value,bce_gen_sampled_value,bce_gen_predicted_value= VaeGan.loss(data_target, out, out_layer_original,
out_layer_predicted,out_layer_sampled, out_labels_original,
out_labels_predicted,out_labels_sampled, mus,
variances)
# THIS IS THE MOST IMPORTANT PART OF THE CODE
loss_encoder = torch.sum(kl_value)+torch.sum(mse_value_1)+torch.sum(mse_value_2)
loss_discriminator = torch.sum(bce_dis_original_value) + torch.sum(bce_dis_sampled_value)+ torch.sum(bce_dis_predicted_value)
loss_decoder = torch.sum(bce_gen_sampled_value) + torch.sum(bce_gen_predicted_value)
loss_decoder = torch.sum(lambda_mse/2 * mse_value_1)+ torch.sum(lambda_mse/2 * mse_value_2) + (1.0 - lambda_mse) * loss_decoder
# register mean values of the losses for logging
loss_nle_mean(torch.mean(nle_value).data.cpu().numpy()[0])
loss_discriminator_mean((torch.mean(bce_dis_original_value) + torch.mean(bce_dis_sampled_value)).data.cpu().numpy()[0])
loss_decoder_mean((torch.mean(lambda_mse * mse_value_1/2)+torch.mean(lambda_mse * mse_value_2/2) + (1 - lambda_mse) * (torch.mean(bce_gen_predicted_value) + torch.mean(bce_gen_sampled_value))).data.cpu().numpy()[0])
loss_encoder_mean((torch.mean(kl_value) + torch.mean(mse_value_1)+ torch.mean(mse_value_2)).data.cpu().numpy()[0])
loss_reconstruction_layer_mean((torch.mean(mse_value_1)+torch.mean(mse_value_2)).data.cpu().numpy()[0])
loss_kld_mean(torch.mean(kl_value).data.cpu().numpy()[0])
# selectively disable the decoder of the discriminator if they are unbalanced
train_dis = True
train_dec = True
if torch.mean(bce_dis_original_value).data[0] < equilibrium-margin or torch.mean(bce_dis_sampled_value).data[0] < equilibrium-margin:
train_dis = False
if torch.mean(bce_dis_original_value).data[0] > equilibrium+margin or torch.mean(bce_dis_sampled_value).data[0] > equilibrium+margin:
train_dec = False
if train_dec is False and train_dis is False:
train_dis = True
train_dec = True
#aggiungo log
if train_dis:
gan_dis_eq_mean(1.0)
else:
gan_dis_eq_mean(0.0)
if train_dec:
gan_gen_eq_mean(1.0)
else:
gan_gen_eq_mean(0.0)
# BACKPROP
# clean grads
net.zero_grad()
# encoder
loss_encoder.backward(retain_graph=True)
# someone likes to clamp the grad here
#[p.grad.data.clamp_(-1,1) for p in net.encoder.parameters()]
# update parameters
optimizer_encoder.step()
# clean others, so they are not afflicted by encoder loss
net.zero_grad()
#decoder
if train_dec:
loss_decoder.backward(retain_graph=True)
#[p.grad.data.clamp_(-1,1) for p in net.decoder.parameters()]
optimizer_decoder.step()
#clean the discriminator
net.discriminator.zero_grad()
#discriminator
if train_dis:
loss_discriminator.backward()
#[p.grad.data.clamp_(-1,1) for p in net.discriminator.parameters()]
optimizer_discriminator.step()
# LOGGING
if not slurm:
progress.update(progress.value + 1, loss_nle=loss_nle_mean.measure,
loss_encoder=loss_encoder_mean.measure,
loss_decoder=loss_decoder_mean.measure,
loss_discriminator=loss_discriminator_mean.measure,
loss_mse_layer=loss_reconstruction_layer_mean.measure,
loss_kld=loss_kld_mean.measure,
epoch=i + 1)
if slurm:
progress.update(progress.value, loss_nle=loss_nle_mean.measure,
loss_encoder=loss_encoder_mean.measure,
loss_decoder=loss_decoder_mean.measure,
loss_discriminator=loss_discriminator_mean.measure,
loss_mse_layer=loss_reconstruction_layer_mean.measure,
loss_kld=loss_kld_mean.measure,
epoch=i + 1)
# EPOCH END
lr_encoder.step()
lr_decoder.step()
lr_discriminator.step()
margin *=decay_margin
equilibrium *=decay_equilibrium
#margin non puo essere piu alto di equilibrium
if margin > equilibrium:
equilibrium = margin
lambda_mse *=decay_mse
if lambda_mse > 1:
lambda_mse=1
progress.finish()
writer.add_scalar('loss_encoder', loss_encoder_mean.measure, step_index)
writer.add_scalar('loss_decoder', loss_decoder_mean.measure, step_index)
writer.add_scalar('loss_discriminator', loss_discriminator_mean.measure, step_index)
writer.add_scalar('loss_reconstruction', loss_nle_mean.measure, step_index)
writer.add_scalar('loss_kld',loss_kld_mean.measure,step_index)
writer.add_scalar('gan_gen',gan_gen_eq_mean.measure,step_index)
writer.add_scalar('gan_dis',gan_dis_eq_mean.measure,step_index)
for j, (data_batch,target_batch) in enumerate(dataloader_test):
net.eval()
data_in = Variable(data_batch, requires_grad=False).float().cuda()
data_target = Variable(target_batch, requires_grad=False).float().cuda()
out = net(data_in)
out = out.data.cpu()
out = (out + 1) / 2
out = make_grid(out, nrow=8)
writer.add_image("reconstructed", out, step_index)
out = net(None, 100)
out = out.data.cpu()
out = (out + 1) / 2
out = make_grid(out, nrow=8)
writer.add_image("generated", out, step_index)
out = data_target.data.cpu()
out = (out + 1) / 2
out = make_grid(out, nrow=8)
writer.add_image("original", out, step_index)
break
step_index += 1
exit(0)