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dualgan.py
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dualgan.py
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from __future__ import print_function, division
import scipy
from keras.datasets import mnist
from keras.layers import Input, Dense, Reshape, Flatten, Dropout, Concatenate
from keras.layers import BatchNormalization, Activation, ZeroPadding2D
from keras.layers.advanced_activations import LeakyReLU
from keras.layers.convolutional import UpSampling2D, Conv2D
from keras.models import Sequential, Model
from keras.optimizers import RMSprop, Adam
from keras.utils import to_categorical
import keras.backend as K
import matplotlib.pyplot as plt
import sys
import numpy as np
class DUALGAN():
def __init__(self):
self.img_rows = 28
self.img_cols = 28
self.channels = 1
self.img_dim = self.img_rows*self.img_cols
optimizer = Adam(0.0002, 0.5)
# Build and compile the discriminators
self.D_A = self.build_discriminator()
self.D_A.compile(loss=self.wasserstein_loss,
optimizer=optimizer,
metrics=['accuracy'])
self.D_B = self.build_discriminator()
self.D_B.compile(loss=self.wasserstein_loss,
optimizer=optimizer,
metrics=['accuracy'])
#-------------------------
# Construct Computational
# Graph of Generators
#-------------------------
# Build the generators
self.G_AB = self.build_generator()
self.G_BA = self.build_generator()
# For the combined model we will only train the generators
self.D_A.trainable = False
self.D_B.trainable = False
# The generator takes images from their respective domains as inputs
imgs_A = Input(shape=(self.img_dim,))
imgs_B = Input(shape=(self.img_dim,))
# Generators translates the images to the opposite domain
fake_B = self.G_AB(imgs_A)
fake_A = self.G_BA(imgs_B)
# The discriminators determines validity of translated images
valid_A = self.D_A(fake_A)
valid_B = self.D_B(fake_B)
# Generators translate the images back to their original domain
recov_A = self.G_BA(fake_B)
recov_B = self.G_AB(fake_A)
# The combined model (stacked generators and discriminators)
self.combined = Model(inputs=[imgs_A, imgs_B], outputs=[valid_A, valid_B, recov_A, recov_B])
self.combined.compile(loss=[self.wasserstein_loss, self.wasserstein_loss, 'mae', 'mae'],
optimizer=optimizer,
loss_weights=[1, 1, 100, 100])
def build_generator(self):
X = Input(shape=(self.img_dim,))
model = Sequential()
model.add(Dense(256, input_dim=self.img_dim))
model.add(LeakyReLU(alpha=0.2))
model.add(BatchNormalization(momentum=0.8))
model.add(Dropout(0.4))
model.add(Dense(512))
model.add(LeakyReLU(alpha=0.2))
model.add(BatchNormalization(momentum=0.8))
model.add(Dropout(0.4))
model.add(Dense(1024))
model.add(LeakyReLU(alpha=0.2))
model.add(BatchNormalization(momentum=0.8))
model.add(Dropout(0.4))
model.add(Dense(self.img_dim, activation='tanh'))
X_translated = model(X)
return Model(X, X_translated)
def build_discriminator(self):
img = Input(shape=(self.img_dim,))
model = Sequential()
model.add(Dense(512, input_dim=self.img_dim))
model.add(LeakyReLU(alpha=0.2))
model.add(Dense(256))
model.add(LeakyReLU(alpha=0.2))
model.add(BatchNormalization(momentum=0.8))
model.add(Dense(1))
validity = model(img)
return Model(img, validity)
def sample_generator_input(self, X, batch_size):
# Sample random batch of images from X
idx = np.random.randint(0, X.shape[0], batch_size)
return X[idx]
def wasserstein_loss(self, y_true, y_pred):
return K.mean(y_true * y_pred)
def train(self, epochs, batch_size=128, sample_interval=50):
# Load the dataset
(X_train, _), (_, _) = mnist.load_data()
# Rescale -1 to 1
X_train = (X_train.astype(np.float32) - 127.5) / 127.5
# Domain A and B (rotated)
X_A = X_train[:int(X_train.shape[0]/2)]
X_B = scipy.ndimage.interpolation.rotate(X_train[int(X_train.shape[0]/2):], 90, axes=(1, 2))
X_A = X_A.reshape(X_A.shape[0], self.img_dim)
X_B = X_B.reshape(X_B.shape[0], self.img_dim)
clip_value = 0.01
n_critic = 4
# Adversarial ground truths
valid = -np.ones((batch_size, 1))
fake = np.ones((batch_size, 1))
for epoch in range(epochs):
# Train the discriminator for n_critic iterations
for _ in range(n_critic):
# ----------------------
# Train Discriminators
# ----------------------
# Sample generator inputs
imgs_A = self.sample_generator_input(X_A, batch_size)
imgs_B = self.sample_generator_input(X_B, batch_size)
# Translate images to their opposite domain
fake_B = self.G_AB.predict(imgs_A)
fake_A = self.G_BA.predict(imgs_B)
# Train the discriminators
D_A_loss_real = self.D_A.train_on_batch(imgs_A, valid)
D_A_loss_fake = self.D_A.train_on_batch(fake_A, fake)
D_B_loss_real = self.D_B.train_on_batch(imgs_B, valid)
D_B_loss_fake = self.D_B.train_on_batch(fake_B, fake)
D_A_loss = 0.5 * np.add(D_A_loss_real, D_A_loss_fake)
D_B_loss = 0.5 * np.add(D_B_loss_real, D_B_loss_fake)
# Clip discriminator weights
for d in [self.D_A, self.D_B]:
for l in d.layers:
weights = l.get_weights()
weights = [np.clip(w, -clip_value, clip_value) for w in weights]
l.set_weights(weights)
# ------------------
# Train Generators
# ------------------
# Train the generators
g_loss = self.combined.train_on_batch([imgs_A, imgs_B], [valid, valid, imgs_A, imgs_B])
# Plot the progress
print ("%d [D1 loss: %f] [D2 loss: %f] [G loss: %f]" \
% (epoch, D_A_loss[0], D_B_loss[0], g_loss[0]))
# If at save interval => save generated image samples
if epoch % sample_interval == 0:
self.save_imgs(epoch, X_A, X_B)
def save_imgs(self, epoch, X_A, X_B):
r, c = 4, 4
# Sample generator inputs
imgs_A = self.sample_generator_input(X_A, c)
imgs_B = self.sample_generator_input(X_B, c)
# Images translated to their opposite domain
fake_B = self.G_AB.predict(imgs_A)
fake_A = self.G_BA.predict(imgs_B)
gen_imgs = np.concatenate([imgs_A, fake_B, imgs_B, fake_A])
gen_imgs = gen_imgs.reshape((r, c, self.img_rows, self.img_cols, 1))
# Rescale images 0 - 1
gen_imgs = 0.5 * gen_imgs + 0.5
fig, axs = plt.subplots(r, c)
cnt = 0
for i in range(r):
for j in range(c):
axs[i,j].imshow(gen_imgs[i, j, :,:,0], cmap='gray')
axs[i,j].axis('off')
cnt += 1
fig.savefig("images/mnist_%d.png" % epoch)
plt.close()
if __name__ == '__main__':
gan = DUALGAN()
gan.train(epochs=30000, batch_size=32, sample_interval=200)