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CVAE.py
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CVAE.py
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#-*- coding: utf-8 -*-
from __future__ import division
import os
import time
import tensorflow as tf
import numpy as np
from ops import *
from utils import *
import prior_factory as prior
class CVAE(object):
model_name = "CVAE" # name for checkpoint
def __init__(self, sess, epoch, batch_size, z_dim, dataset_name, checkpoint_dir, result_dir, log_dir):
self.sess = sess
self.dataset_name = dataset_name
self.checkpoint_dir = checkpoint_dir
self.result_dir = result_dir
self.log_dir = log_dir
self.epoch = epoch
self.batch_size = batch_size
if dataset_name == 'mnist' or dataset_name == 'fashion-mnist':
# parameters
self.input_height = 28
self.input_width = 28
self.output_height = 28
self.output_width = 28
self.z_dim = z_dim # dimension of noise-vector
self.y_dim = 10 # dimension of condition-vector (label)
self.c_dim = 1
# train
self.learning_rate = 0.0002
self.beta1 = 0.5
# test
self.sample_num = 64 # number of generated images to be saved
# load mnist
self.data_X, self.data_y = load_mnist(self.dataset_name)
# get number of batches for a single epoch
self.num_batches = len(self.data_X) // self.batch_size
else:
raise NotImplementedError
# Gaussian Encoder
def encoder(self, x, y, is_training=True, reuse=False):
# Network Architecture is exactly same as in infoGAN (https://arxiv.org/abs/1606.03657)
# Architecture : (64)4c2s-(128)4c2s_BL-FC1024_BL-FC1_S
with tf.variable_scope("encoder", reuse=reuse):
# merge image and label
y = tf.reshape(y, [self.batch_size, 1, 1, self.y_dim])
x = conv_cond_concat(x, y)
net = lrelu(conv2d(x, 64, 4, 4, 2, 2, name='en_conv1'))
net = lrelu(bn(conv2d(net, 128, 4, 4, 2, 2, name='en_conv2'), is_training=is_training, scope='en_bn2'))
net = tf.reshape(net, [self.batch_size, -1])
net = lrelu(bn(linear(net, 1024, scope='en_fc3'), is_training=is_training, scope='en_bn3'))
gaussian_params = linear(net, 2 * self.z_dim, scope='en_fc4')
# The mean parameter is unconstrained
mean = gaussian_params[:, :self.z_dim]
# The standard deviation must be positive. Parametrize with a softplus and
# add a small epsilon for numerical stability
stddev = 1e-6 + tf.nn.softplus(gaussian_params[:, self.z_dim:])
return mean, stddev
# Bernoulli decoder
def decoder(self, z, y, is_training=True, reuse=False):
# Network Architecture is exactly same as in infoGAN (https://arxiv.org/abs/1606.03657)
# Architecture : FC1024_BR-FC7x7x128_BR-(64)4dc2s_BR-(1)4dc2s_S
with tf.variable_scope("decoder", reuse=reuse):
# merge noise and label
z = concat([z, y], 1)
net = tf.nn.relu(bn(linear(z, 1024, scope='de_fc1'), is_training=is_training, scope='de_bn1'))
net = tf.nn.relu(bn(linear(net, 128 * 7 * 7, scope='de_fc2'), is_training=is_training, scope='de_bn2'))
net = tf.reshape(net, [self.batch_size, 7, 7, 128])
net = tf.nn.relu(
bn(deconv2d(net, [self.batch_size, 14, 14, 64], 4, 4, 2, 2, name='de_dc3'), is_training=is_training,
scope='de_bn3'))
out = tf.nn.sigmoid(deconv2d(net, [self.batch_size, 28, 28, 1], 4, 4, 2, 2, name='de_dc4'))
return out
def build_model(self):
# some parameters
image_dims = [self.input_height, self.input_width, self.c_dim]
bs = self.batch_size
""" Graph Input """
# images
self.inputs = tf.placeholder(tf.float32, [bs] + image_dims, name='real_images')
# labels
self.y = tf.placeholder(tf.float32, [bs, self.y_dim], name='y')
# noises
self.z = tf.placeholder(tf.float32, [bs, self.z_dim], name='z')
""" Loss Function """
# encoding
mu, sigma = self.encoder(self.inputs, self.y, is_training=True, reuse=False)
# sampling by re-parameterization technique
z = mu + sigma * tf.random_normal(tf.shape(mu), 0, 1, dtype=tf.float32)
# decoding
out = self.decoder(z, self.y, is_training=True, reuse=False)
self.out = tf.clip_by_value(out, 1e-8, 1 - 1e-8)
# loss
marginal_likelihood = tf.reduce_sum(self.inputs * tf.log(self.out) + (1 - self.inputs) * tf.log(1 - self.out), [1, 2])
KL_divergence = 0.5 * tf.reduce_sum(tf.square(mu) + tf.square(sigma) - tf.log(1e-8 + tf.square(sigma)) - 1, [1])
self.neg_loglikelihood = -tf.reduce_mean(marginal_likelihood)
self.KL_divergence = tf.reduce_mean(KL_divergence)
ELBO = -self.neg_loglikelihood - self.KL_divergence
self.loss = -ELBO
""" Training """
# optimizers
t_vars = tf.trainable_variables()
with tf.control_dependencies(tf.get_collection(tf.GraphKeys.UPDATE_OPS)):
self.optim = tf.train.AdamOptimizer(self.learning_rate*5, beta1=self.beta1) \
.minimize(self.loss, var_list=t_vars)
"""" Testing """
# for test
self.fake_images = self.decoder(self.z, self.y, is_training=False, reuse=True)
""" Summary """
nll_sum = tf.summary.scalar("nll", self.neg_loglikelihood)
kl_sum = tf.summary.scalar("kl", self.KL_divergence)
loss_sum = tf.summary.scalar("loss", self.loss)
# final summary operations
self.merged_summary_op = tf.summary.merge_all()
def train(self):
# initialize all variables
tf.global_variables_initializer().run()
# graph inputs for visualize training results
self.sample_z = prior.gaussian(self.batch_size, self.z_dim)
self.test_labels = self.data_y[0:self.batch_size]
# saver to save model
self.saver = tf.train.Saver()
# summary writer
self.writer = tf.summary.FileWriter(self.log_dir + '/' + self.model_name, self.sess.graph)
# restore check-point if it exits
could_load, checkpoint_counter = self.load(self.checkpoint_dir)
if could_load:
start_epoch = (int)(checkpoint_counter / self.num_batches)
start_batch_id = checkpoint_counter - start_epoch * self.num_batches
counter = checkpoint_counter
print(" [*] Load SUCCESS")
else:
start_epoch = 0
start_batch_id = 0
counter = 1
print(" [!] Load failed...")
# loop for epoch
start_time = time.time()
for epoch in range(start_epoch, self.epoch):
# get batch data
for idx in range(start_batch_id, self.num_batches):
batch_images = self.data_X[idx*self.batch_size:(idx+1)*self.batch_size]
batch_labels = self.data_y[idx * self.batch_size:(idx + 1) * self.batch_size]
batch_z = np.random.uniform(-1, 1, [self.batch_size, self.z_dim]).astype(np.float32)
# update autoencoder
_, summary_str, loss, nll_loss, kl_loss = self.sess.run([self.optim, self.merged_summary_op, self.loss, self.neg_loglikelihood, self.KL_divergence],
feed_dict={self.inputs: batch_images, self.y: batch_labels, self.z: batch_z})
self.writer.add_summary(summary_str, counter)
# display training status
counter += 1
print("Epoch: [%2d] [%4d/%4d] time: %4.4f, loss: %.8f, nll: %.8f, kl: %.8f" \
% (epoch, idx, self.num_batches, time.time() - start_time, loss, nll_loss, kl_loss))
# save training results for every 300 steps
if np.mod(counter, 300) == 0:
samples = self.sess.run(self.fake_images,
feed_dict={self.z: self.sample_z, self.y: self.test_labels})
tot_num_samples = min(self.sample_num, self.batch_size)
manifold_h = int(np.floor(np.sqrt(tot_num_samples)))
manifold_w = int(np.floor(np.sqrt(tot_num_samples)))
save_images(samples[:manifold_h * manifold_w, :, :, :], [manifold_h, manifold_w],
'./' + check_folder(self.result_dir + '/' + self.model_dir) + '/' + self.model_name + '_train_{:02d}_{:04d}.png'.format(
epoch, idx))
# After an epoch, start_batch_id is set to zero
# non-zero value is only for the first epoch after loading pre-trained model
start_batch_id = 0
# save model
self.save(self.checkpoint_dir, counter)
# show temporal results
self.visualize_results(epoch)
# save model for final step
self.save(self.checkpoint_dir, counter)
def visualize_results(self, epoch):
tot_num_samples = min(self.sample_num, self.batch_size)
image_frame_dim = int(np.floor(np.sqrt(tot_num_samples)))
""" random condition, random noise """
y = np.random.choice(self.y_dim, self.batch_size)
y_one_hot = np.zeros((self.batch_size, self.y_dim))
y_one_hot[np.arange(self.batch_size), y] = 1
z_sample = prior.gaussian(self.batch_size, self.z_dim)
samples = self.sess.run(self.fake_images, feed_dict={self.z: z_sample, self.y: y_one_hot})
save_images(samples[:image_frame_dim * image_frame_dim, :, :, :], [image_frame_dim, image_frame_dim],
check_folder(self.result_dir + '/' + self.model_dir) + '/' + self.model_name + '_epoch%03d' % epoch + '_test_all_classes.png')
""" specified condition, random noise """
n_styles = 10 # must be less than or equal to self.batch_size
np.random.seed()
si = np.random.choice(self.batch_size, n_styles)
for l in range(self.y_dim):
y = np.zeros(self.batch_size, dtype=np.int64) + l
y_one_hot = np.zeros((self.batch_size, self.y_dim))
y_one_hot[np.arange(self.batch_size), y] = 1
samples = self.sess.run(self.fake_images, feed_dict={self.z: z_sample, self.y: y_one_hot})
save_images(samples[:image_frame_dim * image_frame_dim, :, :, :], [image_frame_dim, image_frame_dim],
check_folder(self.result_dir + '/' + self.model_dir) + '/' + self.model_name + '_epoch%03d' % epoch + '_test_class_%d.png' % l)
samples = samples[si, :, :, :]
if l == 0:
all_samples = samples
else:
all_samples = np.concatenate((all_samples, samples), axis=0)
""" save merged images to check style-consistency """
canvas = np.zeros_like(all_samples)
for s in range(n_styles):
for c in range(self.y_dim):
canvas[s * self.y_dim + c, :, :, :] = all_samples[c * n_styles + s, :, :, :]
save_images(canvas, [n_styles, self.y_dim],
check_folder(self.result_dir + '/' + self.model_dir) + '/' + self.model_name + '_epoch%03d' % epoch + '_test_all_classes_style_by_style.png')
@property
def model_dir(self):
return "{}_{}_{}_{}".format(
self.model_name, self.dataset_name,
self.batch_size, self.z_dim)
def save(self, checkpoint_dir, step):
checkpoint_dir = os.path.join(checkpoint_dir, self.model_dir, self.model_name)
if not os.path.exists(checkpoint_dir):
os.makedirs(checkpoint_dir)
self.saver.save(self.sess,os.path.join(checkpoint_dir, self.model_name+'.model'), global_step=step)
def load(self, checkpoint_dir):
import re
print(" [*] Reading checkpoints...")
checkpoint_dir = os.path.join(checkpoint_dir, self.model_dir, self.model_name)
ckpt = tf.train.get_checkpoint_state(checkpoint_dir)
if ckpt and ckpt.model_checkpoint_path:
ckpt_name = os.path.basename(ckpt.model_checkpoint_path)
self.saver.restore(self.sess, os.path.join(checkpoint_dir, ckpt_name))
counter = int(next(re.finditer("(\d+)(?!.*\d)",ckpt_name)).group(0))
print(" [*] Success to read {}".format(ckpt_name))
return True, counter
else:
print(" [*] Failed to find a checkpoint")
return False, 0