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model.py
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model.py
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from __future__ import division
import os
import time
from glob import glob
import tensorflow as tf
import numpy as np
from collections import namedtuple
from module import *
from utils import *
class cyclegan(object):
def __init__(self, sess, args):
self.sess = sess
self.batch_size = args.batch_size
self.image_size = args.fine_size
self.input_c_dim = args.input_nc
self.output_c_dim = args.output_nc
self.L1_lambda = args.L1_lambda
self.L2_lambda = args.L2_lambda
self.dataset_dir = args.dataset_dir
self.discriminator = discriminator
if args.use_resnet:
self.generator = generator_resnet
else:
self.generator = generator_unet
if args.use_lsgan:
self.criterionGAN = mae_criterion
else:
self.criterionGAN = sce_criterion
OPTIONS = namedtuple('OPTIONS', 'batch_size image_size \
gf_dim df_dim output_c_dim is_training')
self.options = OPTIONS._make((args.batch_size, args.fine_size,
args.ngf, args.ndf, args.output_nc,
args.phase == 'train'))
self._build_model()
self.saver = tf.train.Saver()
self.pool = ImagePool(args.max_size)
def _build_model(self):
self.real_data = tf.placeholder(tf.float32,
[None, self.image_size, self.image_size,
self.input_c_dim + self.output_c_dim +1+1],
name='real_A_and_B_images')
self.real_A = self.real_data[:, :, :, :self.input_c_dim]
self.real_B = self.real_data[:, :, :, self.input_c_dim:self.input_c_dim + self.output_c_dim]
self.mask_A = self.real_data[:,:,:,self.input_c_dim+self.output_c_dim:self.input_c_dim+self.output_c_dim+1]
self.mask_B = self.real_data[:,:,:,self.input_c_dim+self.output_c_dim+1:self.input_c_dim+self.output_c_dim+2]
self.fake_B = self.generator(self.real_A, self.options, False, name="generatorA2B")
self.fake_A_ = self.generator(self.fake_B, self.options, False, name="generatorB2A")
self.fake_A = self.generator(self.real_B, self.options, True, name="generatorB2A")
self.fake_B_ = self.generator(self.fake_A, self.options, True, name="generatorA2B")
self.DB_fake = self.discriminator(self.fake_B, self.options, reuse=False, name="discriminatorB")
self.DA_fake = self.discriminator(self.fake_A, self.options, reuse=False, name="discriminatorA")
self.g_loss_a2b = self.criterionGAN(self.DB_fake, tf.ones_like(self.DB_fake)) \
+ self.L1_lambda * abs_criterion(self.real_A, self.fake_A_) \
+ self.L1_lambda * abs_criterion(self.real_B, self.fake_B_)
self.g_loss_b2a = self.criterionGAN(self.DA_fake, tf.ones_like(self.DA_fake)) \
+ self.L1_lambda * abs_criterion(self.real_A, self.fake_A_) \
+ self.L1_lambda * abs_criterion(self.real_B, self.fake_B_)
self.g_loss = self.criterionGAN(self.DA_fake, tf.ones_like(self.DA_fake)) \
+ self.criterionGAN(self.DB_fake, tf.ones_like(self.DB_fake)) \
+ self.L1_lambda * abs_criterion(self.real_A, self.fake_A_) \
+ self.L1_lambda * abs_criterion(self.real_B, self.fake_B_) \
+ self.L2_lambda * mae_mask_criterion(self.real_A, self.fake_B, self.mask_A) \
+ self.L2_lambda * mae_mask_criterion(self.real_B, self.fake_A, self.mask_B)
self.fake_A_sample = tf.placeholder(tf.float32,
[None, self.image_size, self.image_size,
self.input_c_dim], name='fake_A_sample')
self.fake_B_sample = tf.placeholder(tf.float32,
[None, self.image_size, self.image_size,
self.output_c_dim], name='fake_B_sample')
self.DB_real = self.discriminator(self.real_B, self.options, reuse=True, name="discriminatorB")
self.DA_real = self.discriminator(self.real_A, self.options, reuse=True, name="discriminatorA")
self.DB_fake_sample = self.discriminator(self.fake_B_sample, self.options, reuse=True, name="discriminatorB")
self.DA_fake_sample = self.discriminator(self.fake_A_sample, self.options, reuse=True, name="discriminatorA")
self.db_loss_real = self.criterionGAN(self.DB_real, tf.ones_like(self.DB_real))
self.db_loss_fake = self.criterionGAN(self.DB_fake_sample, tf.zeros_like(self.DB_fake_sample))
self.db_loss = (self.db_loss_real + self.db_loss_fake) / 2
self.da_loss_real = self.criterionGAN(self.DA_real, tf.ones_like(self.DA_real))
self.da_loss_fake = self.criterionGAN(self.DA_fake_sample, tf.zeros_like(self.DA_fake_sample))
self.da_loss = (self.da_loss_real + self.da_loss_fake) / 2
self.d_loss = self.da_loss + self.db_loss
self.g_loss_a2b_sum = tf.summary.scalar("g_loss_a2b", self.g_loss_a2b)
self.g_loss_b2a_sum = tf.summary.scalar("g_loss_b2a", self.g_loss_b2a)
self.g_loss_sum = tf.summary.scalar("g_loss", self.g_loss)
self.g_sum = tf.summary.merge([self.g_loss_a2b_sum, self.g_loss_b2a_sum, self.g_loss_sum])
self.db_loss_sum = tf.summary.scalar("db_loss", self.db_loss)
self.da_loss_sum = tf.summary.scalar("da_loss", self.da_loss)
self.d_loss_sum = tf.summary.scalar("d_loss", self.d_loss)
self.db_loss_real_sum = tf.summary.scalar("db_loss_real", self.db_loss_real)
self.db_loss_fake_sum = tf.summary.scalar("db_loss_fake", self.db_loss_fake)
self.da_loss_real_sum = tf.summary.scalar("da_loss_real", self.da_loss_real)
self.da_loss_fake_sum = tf.summary.scalar("da_loss_fake", self.da_loss_fake)
self.d_sum = tf.summary.merge(
[self.da_loss_sum, self.da_loss_real_sum, self.da_loss_fake_sum,
self.db_loss_sum, self.db_loss_real_sum, self.db_loss_fake_sum,
self.d_loss_sum]
)
self.test_A = tf.placeholder(tf.float32,
[None, self.image_size, self.image_size,
self.input_c_dim], name='test_A')
self.test_B = tf.placeholder(tf.float32,
[None, self.image_size, self.image_size,
self.output_c_dim], name='test_B')
self.testB = self.generator(self.test_A, self.options, True, name="generatorA2B")
self.testA = self.generator(self.test_B, self.options, True, name="generatorB2A")
t_vars = tf.trainable_variables()
self.d_vars = [var for var in t_vars if 'discriminator' in var.name]
self.g_vars = [var for var in t_vars if 'generator' in var.name]
for var in t_vars: print(var.name)
def train(self, args):
"""Train cyclegan"""
self.lr = tf.placeholder(tf.float32, None, name='learning_rate')
self.d_optim = tf.train.AdamOptimizer(self.lr, beta1=args.beta1) \
.minimize(self.d_loss, var_list=self.d_vars)
self.g_optim = tf.train.AdamOptimizer(self.lr, beta1=args.beta1) \
.minimize(self.g_loss, var_list=self.g_vars)
init_op = tf.global_variables_initializer()
self.sess.run(init_op)
self.writer = tf.summary.FileWriter("./logs", self.sess.graph)
counter = 1
start_time = time.time()
if args.continue_train and self.load(args.checkpoint_dir):
print(" [*] Load SUCCESS")
else:
print(" [!] Load failed...")
for epoch in range(args.epoch):
dataA = glob('./datasets/{}/*.*'.format(self.dataset_dir + '/trainA'))
dataB = glob('./datasets/{}/*.*'.format(self.dataset_dir + '/trainB'))
np.random.shuffle(dataA)
np.random.shuffle(dataB)
batch_idxs = min(min(len(dataA), len(dataB)), args.train_size) // self.batch_size
lr = args.lr if epoch < args.epoch_step else args.lr*(args.epoch-epoch)/(args.epoch-args.epoch_step)
for idx in range(0, batch_idxs):
batch_files = list(zip(dataA[idx * self.batch_size:(idx + 1) * self.batch_size],
dataB[idx * self.batch_size:(idx + 1) * self.batch_size]))
batch_images = [load_train_data(batch_file, args.load_size, args.fine_size) for batch_file in batch_files]
batch_images = np.array(batch_images).astype(np.float32)
# Update G network and record fake outputs
fake_A, fake_B, _, summary_str = self.sess.run(
[self.fake_A, self.fake_B, self.g_optim, self.g_sum],
feed_dict={self.real_data: batch_images, self.lr: lr})
self.writer.add_summary(summary_str, counter)
[fake_A, fake_B] = self.pool([fake_A, fake_B])
print self.mask_A.shape
# Update D network
_, summary_str = self.sess.run(
[self.d_optim, self.d_sum],
feed_dict={self.real_data: batch_images,
self.fake_A_sample: fake_A,
self.fake_B_sample: fake_B,
self.lr: lr})
self.writer.add_summary(summary_str, counter)
counter += 1
print(("Epoch: [%2d] [%4d/%4d] time: %4.4f" % (
epoch, idx, batch_idxs, time.time() - start_time)))
if np.mod(counter, args.print_freq) == 1:
self.sample_model(args.sample_dir, epoch, idx)
if np.mod(counter, args.save_freq) == 2:
self.save(args.checkpoint_dir, counter)
def save(self, checkpoint_dir, step):
model_name = "cyclegan.model"
model_dir = "%s_%s" % (self.dataset_dir, self.image_size)
checkpoint_dir = os.path.join(checkpoint_dir, model_dir)
if not os.path.exists(checkpoint_dir):
os.makedirs(checkpoint_dir)
self.saver.save(self.sess,
os.path.join(checkpoint_dir, model_name),
global_step=step)
def load(self, checkpoint_dir):
print(" [*] Reading checkpoint...")
model_dir = "%s_%s" % (self.dataset_dir, self.image_size)
checkpoint_dir = os.path.join(checkpoint_dir, model_dir)
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))
return True
else:
return False
def sample_model(self, sample_dir, epoch, idx):
dataA = glob('./datasets/{}/*.*'.format(self.dataset_dir + '/testA'))
dataB = glob('./datasets/{}/*.*'.format(self.dataset_dir + '/testB'))
np.random.shuffle(dataA)
np.random.shuffle(dataB)
batch_files = list(zip(dataA[:self.batch_size], dataB[:self.batch_size]))
sample_images = [load_train_data(batch_file, is_testing=True) for batch_file in batch_files]
sample_images = np.array(sample_images).astype(np.float32)
fake_A, fake_B = self.sess.run(
[self.fake_A, self.fake_B],
feed_dict={self.real_data: sample_images}
)
save_images(fake_A, [self.batch_size, 1],
'./{}/A_{:02d}_{:04d}.jpg'.format(sample_dir, epoch, idx))
save_images(fake_B, [self.batch_size, 1],
'./{}/B_{:02d}_{:04d}.jpg'.format(sample_dir, epoch, idx))
def test(self, args):
"""Test cyclegan"""
init_op = tf.global_variables_initializer()
self.sess.run(init_op)
if args.which_direction == 'AtoB':
sample_files = glob('./datasets/{}/*.*'.format(self.dataset_dir + '/testA'))
elif args.which_direction == 'BtoA':
sample_files = glob('./datasets/{}/*.*'.format(self.dataset_dir + '/testB'))
else:
raise Exception('--which_direction must be AtoB or BtoA')
if self.load(args.checkpoint_dir):
print(" [*] Load SUCCESS")
else:
print(" [!] Load failed...")
# write html for visual comparison
index_path = os.path.join(args.test_dir, '{0}_index.html'.format(args.which_direction))
index = open(index_path, "w")
index.write("<html><body><table><tr>")
index.write("<th>name</th><th>input</th><th>output</th></tr>")
out_var, in_var = (self.testB, self.test_A) if args.which_direction == 'AtoB' else (
self.testA, self.test_B)
for sample_file in sample_files:
print('Processing image: ' + sample_file)
sample_image = [load_test_data(sample_file, args.fine_size)]
sample_image = np.array(sample_image).astype(np.float32)
image_path = os.path.join(args.test_dir,
'{0}_{1}'.format(args.which_direction, os.path.basename(sample_file)))
fake_img = self.sess.run(out_var, feed_dict={in_var: sample_image})
save_images(fake_img, [1, 1], image_path)
index.write("<td>%s</td>" % os.path.basename(image_path))
index.write("<td><img src='%s'></td>" % (sample_file if os.path.isabs(sample_file) else (
'..' + os.path.sep + sample_file)))
index.write("<td><img src='%s'></td>" % (image_path if os.path.isabs(image_path) else (
'..' + os.path.sep + image_path)))
index.write("</tr>")
index.close()