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train_model.py
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train_model.py
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# python train_model.py model={iphone,sony,blackberry} dped_dir=dped vgg_dir=vgg_pretrained/imagenet-vgg-verydeep-19.mat
import tensorflow as tf
import imageio
import numpy as np
import sys
tf.compat.v1.disable_v2_behavior()
from load_dataset import load_test_data, load_batch
from ssim import MultiScaleSSIM
import models
import utils
import vgg
# defining size of the training image patches
PATCH_WIDTH = 100
PATCH_HEIGHT = 100
PATCH_SIZE = PATCH_WIDTH * PATCH_HEIGHT * 3
# processing command arguments
phone, batch_size, train_size, learning_rate, num_train_iters, \
w_content, w_color, w_texture, w_tv, \
dped_dir, vgg_dir, eval_step = utils.process_command_args(sys.argv)
np.random.seed(0)
# defining system architecture
with tf.Graph().as_default(), tf.compat.v1.Session() as sess:
# placeholders for training data
phone_ = tf.compat.v1.placeholder(tf.float32, [None, PATCH_SIZE])
phone_image = tf.reshape(phone_, [-1, PATCH_HEIGHT, PATCH_WIDTH, 3])
dslr_ = tf.compat.v1.placeholder(tf.float32, [None, PATCH_SIZE])
dslr_image = tf.reshape(dslr_, [-1, PATCH_HEIGHT, PATCH_WIDTH, 3])
adv_ = tf.compat.v1.placeholder(tf.float32, [None, 1])
# get processed enhanced image
enhanced = models.resnet(phone_image)
# transform both dslr and enhanced images to grayscale
enhanced_gray = tf.reshape(tf.image.rgb_to_grayscale(enhanced), [-1, PATCH_WIDTH * PATCH_HEIGHT])
dslr_gray = tf.reshape(tf.image.rgb_to_grayscale(dslr_image),[-1, PATCH_WIDTH * PATCH_HEIGHT])
# push randomly the enhanced or dslr image to an adversarial CNN-discriminator
adversarial_ = tf.multiply(enhanced_gray, 1 - adv_) + tf.multiply(dslr_gray, adv_)
adversarial_image = tf.reshape(adversarial_, [-1, PATCH_HEIGHT, PATCH_WIDTH, 1])
discrim_predictions = models.adversarial(adversarial_image)
# losses
# 1) texture (adversarial) loss
discrim_target = tf.concat([adv_, 1 - adv_], 1)
loss_discrim = -tf.reduce_sum(discrim_target * tf.compat.v1.log(tf.clip_by_value(discrim_predictions, 1e-10, 1.0)))
loss_texture = -loss_discrim
correct_predictions = tf.equal(tf.argmax(discrim_predictions, 1), tf.argmax(discrim_target, 1))
discim_accuracy = tf.reduce_mean(tf.cast(correct_predictions, tf.float32))
# 2) content loss
CONTENT_LAYER = 'relu5_4'
enhanced_vgg = vgg.net(vgg_dir, vgg.preprocess(enhanced * 255))
dslr_vgg = vgg.net(vgg_dir, vgg.preprocess(dslr_image * 255))
content_size = utils._tensor_size(dslr_vgg[CONTENT_LAYER]) * batch_size
loss_content = 2 * tf.nn.l2_loss(enhanced_vgg[CONTENT_LAYER] - dslr_vgg[CONTENT_LAYER]) / content_size
# 3) color loss
enhanced_blur = utils.blur(enhanced)
dslr_blur = utils.blur(dslr_image)
loss_color = tf.reduce_sum(tf.pow(dslr_blur - enhanced_blur, 2))/(2 * batch_size)
# 4) total variation loss
batch_shape = (batch_size, PATCH_WIDTH, PATCH_HEIGHT, 3)
tv_y_size = utils._tensor_size(enhanced[:,1:,:,:])
tv_x_size = utils._tensor_size(enhanced[:,:,1:,:])
y_tv = tf.nn.l2_loss(enhanced[:,1:,:,:] - enhanced[:,:batch_shape[1]-1,:,:])
x_tv = tf.nn.l2_loss(enhanced[:,:,1:,:] - enhanced[:,:,:batch_shape[2]-1,:])
loss_tv = 2 * (x_tv/tv_x_size + y_tv/tv_y_size) / batch_size
# final loss
loss_generator = w_content * loss_content + w_texture * loss_texture + w_color * loss_color + w_tv * loss_tv
# psnr loss
enhanced_flat = tf.reshape(enhanced, [-1, PATCH_SIZE])
loss_mse = tf.reduce_sum(tf.pow(dslr_ - enhanced_flat, 2))/(PATCH_SIZE * batch_size)
loss_psnr = 20 * utils.log10(1.0 / tf.sqrt(loss_mse))
# optimize parameters of image enhancement (generator) and discriminator networks
generator_vars = [v for v in tf.compat.v1.global_variables() if v.name.startswith("generator")]
discriminator_vars = [v for v in tf.compat.v1.global_variables() if v.name.startswith("discriminator")]
train_step_gen = tf.compat.v1.train.AdamOptimizer(learning_rate).minimize(loss_generator, var_list=generator_vars)
train_step_disc = tf.compat.v1.train.AdamOptimizer(learning_rate).minimize(loss_discrim, var_list=discriminator_vars)
saver = tf.compat.v1.train.Saver(var_list=generator_vars, max_to_keep=100)
print('Initializing variables')
sess.run(tf.compat.v1.global_variables_initializer())
# loading training and test data
print("Loading test data...")
test_data, test_answ = load_test_data(phone, dped_dir, PATCH_SIZE)
print("Test data was loaded\n")
print("Loading training data...")
train_data, train_answ = load_batch(phone, dped_dir, train_size, PATCH_SIZE)
print("Training data was loaded\n")
TEST_SIZE = test_data.shape[0]
num_test_batches = int(test_data.shape[0] / batch_size)
print('Training network')
train_loss_gen = 0.0
train_acc_discrim = 0.0
all_zeros = np.reshape(np.zeros((batch_size, 1)), [batch_size, 1])
test_crops = test_data[np.random.randint(0, TEST_SIZE, 5), :]
logs = open('models/' + phone + '.txt', "w+")
logs.close()
for i in range(num_train_iters):
# train generator
idx_train = np.random.randint(0, train_size, batch_size)
phone_images = train_data[idx_train]
dslr_images = train_answ[idx_train]
[loss_temp, temp] = sess.run([loss_generator, train_step_gen],
feed_dict={phone_: phone_images, dslr_: dslr_images, adv_: all_zeros})
train_loss_gen += loss_temp / eval_step
# train discriminator
idx_train = np.random.randint(0, train_size, batch_size)
# generate image swaps (dslr or enhanced) for discriminator
swaps = np.reshape(np.random.randint(0, 2, batch_size), [batch_size, 1])
phone_images = train_data[idx_train]
dslr_images = train_answ[idx_train]
[accuracy_temp, temp] = sess.run([discim_accuracy, train_step_disc],
feed_dict={phone_: phone_images, dslr_: dslr_images, adv_: swaps})
train_acc_discrim += accuracy_temp / eval_step
if i % eval_step == 0:
# test generator and discriminator CNNs
test_losses_gen = np.zeros((1, 6))
test_accuracy_disc = 0.0
loss_ssim = 0.0
for j in range(num_test_batches):
be = j * batch_size
en = (j+1) * batch_size
swaps = np.reshape(np.random.randint(0, 2, batch_size), [batch_size, 1])
phone_images = test_data[be:en]
dslr_images = test_answ[be:en]
[enhanced_crops, accuracy_disc, losses] = sess.run([enhanced, discim_accuracy, \
[loss_generator, loss_content, loss_color, loss_texture, loss_tv, loss_psnr]], \
feed_dict={phone_: phone_images, dslr_: dslr_images, adv_: swaps})
test_losses_gen += np.asarray(losses) / num_test_batches
test_accuracy_disc += accuracy_disc / num_test_batches
loss_ssim += MultiScaleSSIM(np.reshape(dslr_images * 255, [batch_size, PATCH_HEIGHT, PATCH_WIDTH, 3]),
enhanced_crops * 255) / num_test_batches
logs_disc = "step %d, %s | discriminator accuracy | train: %.4g, test: %.4g" % \
(i, phone, train_acc_discrim, test_accuracy_disc)
logs_gen = "generator losses | train: %.4g, test: %.4g | content: %.4g, color: %.4g, texture: %.4g, tv: %.4g | psnr: %.4g, ms-ssim: %.4g\n" % \
(train_loss_gen, test_losses_gen[0][0], test_losses_gen[0][1], test_losses_gen[0][2],
test_losses_gen[0][3], test_losses_gen[0][4], test_losses_gen[0][5], loss_ssim)
print(logs_disc)
print(logs_gen)
# save the results to log file
logs = open('models/' + phone + '.txt', "a")
logs.write(logs_disc)
logs.write('\n')
logs.write(logs_gen)
logs.write('\n')
logs.close()
# save visual results for several test image crops
enhanced_crops = sess.run(enhanced, feed_dict={phone_: test_crops, dslr_: dslr_images, adv_: all_zeros})
idx = 0
for crop in enhanced_crops:
before_after = np.hstack((np.reshape(test_crops[idx], [PATCH_HEIGHT, PATCH_WIDTH, 3]), crop))
imageio.imwrite('results/' + str(phone)+ "_" + str(idx) + '_iteration_' + str(i) + '.jpg', before_after)
idx += 1
train_loss_gen = 0.0
train_acc_discrim = 0.0
# save the model that corresponds to the current iteration
saver.save(sess, 'models/' + str(phone) + '_iteration_' + str(i) + '.ckpt', write_meta_graph=False)
# reload a different batch of training data
del train_data
del train_answ
train_data, train_answ = load_batch(phone, dped_dir, train_size, PATCH_SIZE)