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gan_mnist.py
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gan_mnist.py
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import os, sys
sys.path.append(os.getcwd())
import time
import matplotlib
matplotlib.use('Agg')
import matplotlib.pyplot as plt
import numpy as np
import sklearn.datasets
import tflib as lib
import tflib.save_images
import tflib.mnist
import tflib.plot
import torch
import torch.autograd as autograd
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
torch.manual_seed(1)
use_cuda = torch.cuda.is_available()
if use_cuda:
gpu = 0
DIM = 64 # Model dimensionality
BATCH_SIZE = 50 # Batch size
CRITIC_ITERS = 5 # For WGAN and WGAN-GP, number of critic iters per gen iter
LAMBDA = 10 # Gradient penalty lambda hyperparameter
ITERS = 200000 # How many generator iterations to train for
OUTPUT_DIM = 784 # Number of pixels in MNIST (28*28)
lib.print_model_settings(locals().copy())
# ==================Definition Start======================
class Generator(nn.Module):
def __init__(self):
super(Generator, self).__init__()
preprocess = nn.Sequential(
nn.Linear(128, 4*4*4*DIM),
nn.ReLU(True),
)
block1 = nn.Sequential(
nn.ConvTranspose2d(4*DIM, 2*DIM, 5),
nn.ReLU(True),
)
block2 = nn.Sequential(
nn.ConvTranspose2d(2*DIM, DIM, 5),
nn.ReLU(True),
)
deconv_out = nn.ConvTranspose2d(DIM, 1, 8, stride=2)
self.block1 = block1
self.block2 = block2
self.deconv_out = deconv_out
self.preprocess = preprocess
self.sigmoid = nn.Sigmoid()
def forward(self, input):
output = self.preprocess(input)
output = output.view(-1, 4*DIM, 4, 4)
#print output.size()
output = self.block1(output)
#print output.size()
output = output[:, :, :7, :7]
#print output.size()
output = self.block2(output)
#print output.size()
output = self.deconv_out(output)
output = self.sigmoid(output)
#print output.size()
return output.view(-1, OUTPUT_DIM)
class Discriminator(nn.Module):
def __init__(self):
super(Discriminator, self).__init__()
main = nn.Sequential(
nn.Conv2d(1, DIM, 5, stride=2, padding=2),
# nn.Linear(OUTPUT_DIM, 4*4*4*DIM),
nn.ReLU(True),
nn.Conv2d(DIM, 2*DIM, 5, stride=2, padding=2),
# nn.Linear(4*4*4*DIM, 4*4*4*DIM),
nn.ReLU(True),
nn.Conv2d(2*DIM, 4*DIM, 5, stride=2, padding=2),
# nn.Linear(4*4*4*DIM, 4*4*4*DIM),
nn.ReLU(True),
# nn.Linear(4*4*4*DIM, 4*4*4*DIM),
# nn.LeakyReLU(True),
# nn.Linear(4*4*4*DIM, 4*4*4*DIM),
# nn.LeakyReLU(True),
)
self.main = main
self.output = nn.Linear(4*4*4*DIM, 1)
def forward(self, input):
input = input.view(-1, 1, 28, 28)
out = self.main(input)
out = out.view(-1, 4*4*4*DIM)
out = self.output(out)
return out.view(-1)
def generate_image(frame, netG):
noise = torch.randn(BATCH_SIZE, 128)
if use_cuda:
noise = noise.cuda(gpu)
noisev = autograd.Variable(noise, volatile=True)
samples = netG(noisev)
samples = samples.view(BATCH_SIZE, 28, 28)
# print samples.size()
samples = samples.cpu().data.numpy()
lib.save_images.save_images(
samples,
'tmp/mnist/samples_{}.png'.format(frame)
)
# Dataset iterator
train_gen, dev_gen, test_gen = lib.mnist.load(BATCH_SIZE, BATCH_SIZE)
def inf_train_gen():
while True:
for images,targets in train_gen():
yield images
def calc_gradient_penalty(netD, real_data, fake_data):
#print real_data.size()
alpha = torch.rand(BATCH_SIZE, 1)
alpha = alpha.expand(real_data.size())
alpha = alpha.cuda(gpu) if use_cuda else alpha
interpolates = alpha * real_data + ((1 - alpha) * fake_data)
if use_cuda:
interpolates = interpolates.cuda(gpu)
interpolates = autograd.Variable(interpolates, requires_grad=True)
disc_interpolates = netD(interpolates)
gradients = autograd.grad(outputs=disc_interpolates, inputs=interpolates,
grad_outputs=torch.ones(disc_interpolates.size()).cuda(gpu) if use_cuda else torch.ones(
disc_interpolates.size()),
create_graph=True, retain_graph=True, only_inputs=True)[0]
gradient_penalty = ((gradients.norm(2, dim=1) - 1) ** 2).mean() * LAMBDA
return gradient_penalty
# ==================Definition End======================
netG = Generator()
netD = Discriminator()
print netG
print netD
if use_cuda:
netD = netD.cuda(gpu)
netG = netG.cuda(gpu)
optimizerD = optim.Adam(netD.parameters(), lr=1e-4, betas=(0.5, 0.9))
optimizerG = optim.Adam(netG.parameters(), lr=1e-4, betas=(0.5, 0.9))
one = torch.FloatTensor([1])
mone = one * -1
if use_cuda:
one = one.cuda(gpu)
mone = mone.cuda(gpu)
data = inf_train_gen()
for iteration in xrange(ITERS):
start_time = time.time()
############################
# (1) Update D network
###########################
for p in netD.parameters(): # reset requires_grad
p.requires_grad = True # they are set to False below in netG update
for iter_d in xrange(CRITIC_ITERS):
_data = data.next()
real_data = torch.Tensor(_data)
if use_cuda:
real_data = real_data.cuda(gpu)
real_data_v = autograd.Variable(real_data)
netD.zero_grad()
# train with real
D_real = netD(real_data_v)
D_real = D_real.mean()
# print D_real
D_real.backward(mone)
# train with fake
noise = torch.randn(BATCH_SIZE, 128)
if use_cuda:
noise = noise.cuda(gpu)
noisev = autograd.Variable(noise, volatile=True) # totally freeze netG
fake = autograd.Variable(netG(noisev).data)
inputv = fake
D_fake = netD(inputv)
D_fake = D_fake.mean()
D_fake.backward(one)
# train with gradient penalty
gradient_penalty = calc_gradient_penalty(netD, real_data_v.data, fake.data)
gradient_penalty.backward()
D_cost = D_fake - D_real + gradient_penalty
Wasserstein_D = D_real - D_fake
optimizerD.step()
############################
# (2) Update G network
###########################
for p in netD.parameters():
p.requires_grad = False # to avoid computation
netG.zero_grad()
noise = torch.randn(BATCH_SIZE, 128)
if use_cuda:
noise = noise.cuda(gpu)
noisev = autograd.Variable(noise)
fake = netG(noisev)
G = netD(fake)
G = G.mean()
G.backward(mone)
G_cost = -G
optimizerG.step()
# Write logs and save samples
lib.plot.plot('tmp/mnist/time', time.time() - start_time)
lib.plot.plot('tmp/mnist/train disc cost', D_cost.cpu().data.numpy())
lib.plot.plot('tmp/mnist/train gen cost', G_cost.cpu().data.numpy())
lib.plot.plot('tmp/mnist/wasserstein distance', Wasserstein_D.cpu().data.numpy())
# Calculate dev loss and generate samples every 100 iters
if iteration % 100 == 99:
dev_disc_costs = []
for images,_ in dev_gen():
imgs = torch.Tensor(images)
if use_cuda:
imgs = imgs.cuda(gpu)
imgs_v = autograd.Variable(imgs, volatile=True)
D = netD(imgs_v)
_dev_disc_cost = -D.mean().cpu().data.numpy()
dev_disc_costs.append(_dev_disc_cost)
lib.plot.plot('tmp/mnist/dev disc cost', np.mean(dev_disc_costs))
generate_image(iteration, netG)
# Write logs every 100 iters
if (iteration < 5) or (iteration % 100 == 99):
lib.plot.flush()
lib.plot.tick()