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clustergan.py
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clustergan.py
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from __future__ import print_function
try:
import argparse
import os
import numpy as np
from torch.autograd import Variable
from torch.autograd import grad as torch_grad
import torch
import torchvision
import torch.nn as nn
import torch.nn.functional as F
from torch.utils.data import DataLoader
from torchvision import datasets
import torchvision.transforms as transforms
from torchvision.utils import save_image
from itertools import chain as ichain
except ImportError as e:
print(e)
raise ImportError
os.makedirs("images", exist_ok=True)
parser = argparse.ArgumentParser(description="ClusterGAN Training Script")
parser.add_argument("-n", "--n_epochs", dest="n_epochs", default=200, type=int, help="Number of epochs")
parser.add_argument("-b", "--batch_size", dest="batch_size", default=64, type=int, help="Batch size")
parser.add_argument("-i", "--img_size", dest="img_size", type=int, default=28, help="Size of image dimension")
parser.add_argument("-d", "--latent_dim", dest="latent_dim", default=30, type=int, help="Dimension of latent space")
parser.add_argument("-l", "--lr", dest="learning_rate", type=float, default=0.0001, help="Learning rate")
parser.add_argument("-c", "--n_critic", dest="n_critic", type=int, default=5, help="Number of training steps for discriminator per iter")
parser.add_argument("-w", "--wass_flag", dest="wass_flag", action='store_true', help="Flag for Wasserstein metric")
args = parser.parse_args()
# Sample a random latent space vector
def sample_z(shape=64, latent_dim=10, n_c=10, fix_class=-1, req_grad=False):
assert (fix_class == -1 or (fix_class >= 0 and fix_class < n_c) ), "Requested class %i outside bounds."%fix_class
Tensor = torch.cuda.FloatTensor
# Sample noise as generator input, zn
zn = Variable(Tensor(0.75*np.random.normal(0, 1, (shape, latent_dim))), requires_grad=req_grad)
######### zc, zc_idx variables with grads, and zc to one-hot vector
# Pure one-hot vector generation
zc_FT = Tensor(shape, n_c).fill_(0)
zc_idx = torch.empty(shape, dtype=torch.long)
if (fix_class == -1):
zc_idx = zc_idx.random_(n_c).cuda()
zc_FT = zc_FT.scatter_(1, zc_idx.unsqueeze(1), 1.)
else:
zc_idx[:] = fix_class
zc_FT[:, fix_class] = 1
zc_idx = zc_idx.cuda()
zc_FT = zc_FT.cuda()
zc = Variable(zc_FT, requires_grad=req_grad)
# Return components of latent space variable
return zn, zc, zc_idx
def calc_gradient_penalty(netD, real_data, generated_data):
# GP strength
LAMBDA = 10
b_size = real_data.size()[0]
# Calculate interpolation
alpha = torch.rand(b_size, 1, 1, 1)
alpha = alpha.expand_as(real_data)
alpha = alpha.cuda()
interpolated = alpha * real_data.data + (1 - alpha) * generated_data.data
interpolated = Variable(interpolated, requires_grad=True)
interpolated = interpolated.cuda()
# Calculate probability of interpolated examples
prob_interpolated = netD(interpolated)
# Calculate gradients of probabilities with respect to examples
gradients = torch_grad(outputs=prob_interpolated, inputs=interpolated,
grad_outputs=torch.ones(prob_interpolated.size()).cuda(),
create_graph=True, retain_graph=True)[0]
# Gradients have shape (batch_size, num_channels, img_width, img_height),
# so flatten to easily take norm per example in batch
gradients = gradients.view(b_size, -1)
# Derivatives of the gradient close to 0 can cause problems because of
# the square root, so manually calculate norm and add epsilon
gradients_norm = torch.sqrt(torch.sum(gradients ** 2, dim=1) + 1e-12)
# Return gradient penalty
return LAMBDA * ((gradients_norm - 1) ** 2).mean()
# Weight Initializer
def initialize_weights(net):
for m in net.modules():
if isinstance(m, nn.Conv2d):
m.weight.data.normal_(0, 0.02)
m.bias.data.zero_()
elif isinstance(m, nn.ConvTranspose2d):
m.weight.data.normal_(0, 0.02)
m.bias.data.zero_()
elif isinstance(m, nn.Linear):
m.weight.data.normal_(0, 0.02)
m.bias.data.zero_()
# Softmax function
def softmax(x):
return F.softmax(x, dim=1)
class Reshape(nn.Module):
"""
Class for performing a reshape as a layer in a sequential model.
"""
def __init__(self, shape=[]):
super(Reshape, self).__init__()
self.shape = shape
def forward(self, x):
return x.view(x.size(0), *self.shape)
def extra_repr(self):
# (Optional)Set the extra information about this module. You can test
# it by printing an object of this class.
return 'shape={}'.format(
self.shape
)
class Generator_CNN(nn.Module):
"""
CNN to model the generator of a ClusterGAN
Input is a vector from representation space of dimension z_dim
output is a vector from image space of dimension X_dim
"""
# Architecture : FC1024_BR-FC7x7x128_BR-(64)4dc2s_BR-(1)4dc2s_S
def __init__(self, latent_dim, n_c, x_shape, verbose=False):
super(Generator_CNN, self).__init__()
self.name = 'generator'
self.latent_dim = latent_dim
self.n_c = n_c
self.x_shape = x_shape
self.ishape = (128, 7, 7)
self.iels = int(np.prod(self.ishape))
self.verbose = verbose
self.model = nn.Sequential(
# Fully connected layers
torch.nn.Linear(self.latent_dim + self.n_c, 1024),
nn.BatchNorm1d(1024),
nn.LeakyReLU(0.2, inplace=True),
torch.nn.Linear(1024, self.iels),
nn.BatchNorm1d(self.iels),
nn.LeakyReLU(0.2, inplace=True),
# Reshape to 128 x (7x7)
Reshape(self.ishape),
# Upconvolution layers
nn.ConvTranspose2d(128, 64, 4, stride=2, padding=1, bias=True),
nn.BatchNorm2d(64),
nn.LeakyReLU(0.2, inplace=True),
nn.ConvTranspose2d(64, 1, 4, stride=2, padding=1, bias=True),
nn.Sigmoid()
)
initialize_weights(self)
if self.verbose:
print("Setting up {}...\n".format(self.name))
print(self.model)
def forward(self, zn, zc):
z = torch.cat((zn, zc), 1)
x_gen = self.model(z)
# Reshape for output
x_gen = x_gen.view(x_gen.size(0), *self.x_shape)
return x_gen
class Encoder_CNN(nn.Module):
"""
CNN to model the encoder of a ClusterGAN
Input is vector X from image space if dimension X_dim
Output is vector z from representation space of dimension z_dim
"""
def __init__(self, latent_dim, n_c, verbose=False):
super(Encoder_CNN, self).__init__()
self.name = 'encoder'
self.channels = 1
self.latent_dim = latent_dim
self.n_c = n_c
self.cshape = (128, 5, 5)
self.iels = int(np.prod(self.cshape))
self.lshape = (self.iels,)
self.verbose = verbose
self.model = nn.Sequential(
# Convolutional layers
nn.Conv2d(self.channels, 64, 4, stride=2, bias=True),
nn.LeakyReLU(0.2, inplace=True),
nn.Conv2d(64, 128, 4, stride=2, bias=True),
nn.LeakyReLU(0.2, inplace=True),
# Flatten
Reshape(self.lshape),
# Fully connected layers
torch.nn.Linear(self.iels, 1024),
nn.LeakyReLU(0.2, inplace=True),
torch.nn.Linear(1024, latent_dim + n_c)
)
initialize_weights(self)
if self.verbose:
print("Setting up {}...\n".format(self.name))
print(self.model)
def forward(self, in_feat):
z_img = self.model(in_feat)
# Reshape for output
z = z_img.view(z_img.shape[0], -1)
# Separate continuous and one-hot components
zn = z[:, 0:self.latent_dim]
zc_logits = z[:, self.latent_dim:]
# Softmax on zc component
zc = softmax(zc_logits)
return zn, zc, zc_logits
class Discriminator_CNN(nn.Module):
"""
CNN to model the discriminator of a ClusterGAN
Input is tuple (X,z) of an image vector and its corresponding
representation z vector. For example, if X comes from the dataset, corresponding
z is Encoder(X), and if z is sampled from representation space, X is Generator(z)
Output is a 1-dimensional value
"""
# Architecture : (64)4c2s-(128)4c2s_BL-FC1024_BL-FC1_S
def __init__(self, wass_metric=False, verbose=False):
super(Discriminator_CNN, self).__init__()
self.name = 'discriminator'
self.channels = 1
self.cshape = (128, 5, 5)
self.iels = int(np.prod(self.cshape))
self.lshape = (self.iels,)
self.wass = wass_metric
self.verbose = verbose
self.model = nn.Sequential(
# Convolutional layers
nn.Conv2d(self.channels, 64, 4, stride=2, bias=True),
nn.LeakyReLU(0.2, inplace=True),
nn.Conv2d(64, 128, 4, stride=2, bias=True),
nn.LeakyReLU(0.2, inplace=True),
# Flatten
Reshape(self.lshape),
# Fully connected layers
torch.nn.Linear(self.iels, 1024),
nn.LeakyReLU(0.2, inplace=True),
torch.nn.Linear(1024, 1),
)
# If NOT using Wasserstein metric, final Sigmoid
if (not self.wass):
self.model = nn.Sequential(self.model, torch.nn.Sigmoid())
initialize_weights(self)
if self.verbose:
print("Setting up {}...\n".format(self.name))
print(self.model)
def forward(self, img):
# Get output
validity = self.model(img)
return validity
# Training details
n_epochs = args.n_epochs
batch_size = args.batch_size
test_batch_size = 5000
lr = args.learning_rate
b1 = 0.5
b2 = 0.9
decay = 2.5*1e-5
n_skip_iter = args.n_critic
# Data dimensions
img_size = args.img_size
channels = 1
# Latent space info
latent_dim = args.latent_dim
n_c = 10
betan = 10
betac = 10
# Wasserstein+GP metric flag
wass_metric = args.wass_flag
x_shape = (channels, img_size, img_size)
cuda = True if torch.cuda.is_available() else False
device = torch.device('cuda:0' if torch.cuda.is_available() else 'cpu')
# Loss function
bce_loss = torch.nn.BCELoss()
xe_loss = torch.nn.CrossEntropyLoss()
mse_loss = torch.nn.MSELoss()
# Initialize generator and discriminator
generator = Generator_CNN(latent_dim, n_c, x_shape)
encoder = Encoder_CNN(latent_dim, n_c)
discriminator = Discriminator_CNN(wass_metric=wass_metric)
if cuda:
generator.cuda()
encoder.cuda()
discriminator.cuda()
bce_loss.cuda()
xe_loss.cuda()
mse_loss.cuda()
Tensor = torch.cuda.FloatTensor if cuda else torch.FloatTensor
# Configure data loader
os.makedirs("../../data/mnist", exist_ok=True)
dataloader = torch.utils.data.DataLoader(
datasets.MNIST(
"../../data/mnist",
train=True,
download=True,
transform=transforms.Compose(
[transforms.ToTensor()]
),
),
batch_size=batch_size,
shuffle=True,
)
# Test data loader
testdata = torch.utils.data.DataLoader(
datasets.MNIST(
"../../data/mnist",
train=False,
download=True,
transform=transforms.Compose(
[transforms.ToTensor()]
),
),
batch_size=batch_size,
shuffle=True,
)
test_imgs, test_labels = next(iter(testdata))
test_imgs = Variable(test_imgs.type(Tensor))
ge_chain = ichain(generator.parameters(),
encoder.parameters())
optimizer_GE = torch.optim.Adam(ge_chain, lr=lr, betas=(b1, b2), weight_decay=decay)
optimizer_D = torch.optim.Adam(discriminator.parameters(), lr=lr, betas=(b1, b2))
# ----------
# Training
# ----------
ge_l = []
d_l = []
c_zn = []
c_zc = []
c_i = []
# Training loop
print('\nBegin training session with %i epochs...\n'%(n_epochs))
for epoch in range(n_epochs):
for i, (imgs, itruth_label) in enumerate(dataloader):
# Ensure generator/encoder are trainable
generator.train()
encoder.train()
# Zero gradients for models
generator.zero_grad()
encoder.zero_grad()
discriminator.zero_grad()
# Configure input
real_imgs = Variable(imgs.type(Tensor))
# ---------------------------
# Train Generator + Encoder
# ---------------------------
optimizer_GE.zero_grad()
# Sample random latent variables
zn, zc, zc_idx = sample_z(shape=imgs.shape[0],
latent_dim=latent_dim,
n_c=n_c)
# Generate a batch of images
gen_imgs = generator(zn, zc)
# Discriminator output from real and generated samples
D_gen = discriminator(gen_imgs)
D_real = discriminator(real_imgs)
# Step for Generator & Encoder, n_skip_iter times less than for discriminator
if (i % n_skip_iter == 0):
# Encode the generated images
enc_gen_zn, enc_gen_zc, enc_gen_zc_logits = encoder(gen_imgs)
# Calculate losses for z_n, z_c
zn_loss = mse_loss(enc_gen_zn, zn)
zc_loss = xe_loss(enc_gen_zc_logits, zc_idx)
# Check requested metric
if wass_metric:
# Wasserstein GAN loss
ge_loss = torch.mean(D_gen) + betan * zn_loss + betac * zc_loss
else:
# Vanilla GAN loss
valid = Variable(Tensor(gen_imgs.size(0), 1).fill_(1.0), requires_grad=False)
v_loss = bce_loss(D_gen, valid)
ge_loss = v_loss + betan * zn_loss + betac * zc_loss
ge_loss.backward(retain_graph=True)
optimizer_GE.step()
# ---------------------
# Train Discriminator
# ---------------------
optimizer_D.zero_grad()
# Measure discriminator's ability to classify real from generated samples
if wass_metric:
# Gradient penalty term
grad_penalty = calc_gradient_penalty(discriminator, real_imgs, gen_imgs)
# Wasserstein GAN loss w/gradient penalty
d_loss = torch.mean(D_real) - torch.mean(D_gen) + grad_penalty
else:
# Vanilla GAN loss
fake = Variable(Tensor(gen_imgs.size(0), 1).fill_(0.0), requires_grad=False)
real_loss = bce_loss(D_real, valid)
fake_loss = bce_loss(D_gen, fake)
d_loss = (real_loss + fake_loss) / 2
d_loss.backward()
optimizer_D.step()
# Save training losses
d_l.append(d_loss.item())
ge_l.append(ge_loss.item())
# Generator in eval mode
generator.eval()
encoder.eval()
# Set number of examples for cycle calcs
n_sqrt_samp = 5
n_samp = n_sqrt_samp * n_sqrt_samp
## Cycle through test real -> enc -> gen
t_imgs, t_label = test_imgs.data, test_labels
# Encode sample real instances
e_tzn, e_tzc, e_tzc_logits = encoder(t_imgs)
# Generate sample instances from encoding
teg_imgs = generator(e_tzn, e_tzc)
# Calculate cycle reconstruction loss
img_mse_loss = mse_loss(t_imgs, teg_imgs)
# Save img reco cycle loss
c_i.append(img_mse_loss.item())
## Cycle through randomly sampled encoding -> generator -> encoder
zn_samp, zc_samp, zc_samp_idx = sample_z(shape=n_samp,
latent_dim=latent_dim,
n_c=n_c)
# Generate sample instances
gen_imgs_samp = generator(zn_samp, zc_samp)
# Encode sample instances
zn_e, zc_e, zc_e_logits = encoder(gen_imgs_samp)
# Calculate cycle latent losses
lat_mse_loss = mse_loss(zn_e, zn_samp)
lat_xe_loss = xe_loss(zc_e_logits, zc_samp_idx)
# Save latent space cycle losses
c_zn.append(lat_mse_loss.item())
c_zc.append(lat_xe_loss.item())
# Save cycled and generated examples!
r_imgs, i_label = real_imgs.data[:n_samp], itruth_label[:n_samp]
e_zn, e_zc, e_zc_logits = encoder(r_imgs)
reg_imgs = generator(e_zn, e_zc)
save_image(reg_imgs.data[:n_samp],
'images/cycle_reg_%06i.png' %(epoch),
nrow=n_sqrt_samp, normalize=True)
save_image(gen_imgs_samp.data[:n_samp],
'images/gen_%06i.png' %(epoch),
nrow=n_sqrt_samp, normalize=True)
## Generate samples for specified classes
stack_imgs = []
for idx in range(n_c):
# Sample specific class
zn_samp, zc_samp, zc_samp_idx = sample_z(shape=n_c,
latent_dim=latent_dim,
n_c=n_c,
fix_class=idx)
# Generate sample instances
gen_imgs_samp = generator(zn_samp, zc_samp)
if (len(stack_imgs) == 0):
stack_imgs = gen_imgs_samp
else:
stack_imgs = torch.cat((stack_imgs, gen_imgs_samp), 0)
# Save class-specified generated examples!
save_image(stack_imgs,
'images/gen_classes_%06i.png' %(epoch),
nrow=n_c, normalize=True)
print ("[Epoch %d/%d] \n"\
"\tModel Losses: [D: %f] [GE: %f]" % (epoch,
n_epochs,
d_loss.item(),
ge_loss.item())
)
print("\tCycle Losses: [x: %f] [z_n: %f] [z_c: %f]"%(img_mse_loss.item(),
lat_mse_loss.item(),
lat_xe_loss.item())
)