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VAEGAN.py
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VAEGAN.py
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from keras.models import Sequential, Model
from keras.layers import *
from keras.optimizers import *
import os
from keras import metrics, backend as K
from PIL import Image
import numpy as np
filenames = list()
labels = list()
images = os.path.join("img_align_celeba_png/")
annot = os.path.join("list_attr_celeba_png.txt")
with open(annot) as in_file:
count_datapoints = int(in_file.readline())
plaintext_labels = in_file.readline().split()
for line in in_file:
splitted = line.split()
filenames.append(os.path.join(images, splitted[0]))
properties_celebrity = [float(x) for x in splitted[1:]]
properties_celebrity = [max(0.0, x) for x in properties_celebrity]
labels.append(properties_celebrity)
assert len(filenames) == len(labels)
# print(labels[:4])
# print(filenames[:4])
show_number = len(filenames)
datasetlist = []
# print(plaintext_labels)
for filename, properties in zip(filenames[:show_number], labels[:show_number]):
image = Image.open(os.path.join(filename))
image = image.resize([64, 64], Image.ANTIALIAS)
image = (np.array(image) - 127.5 / 127.5)
# image = plt.imread(image)
# plt.imshow(image)
# plt.show()
datasetlist.append(image)
print(filename)
# print(properties)
dataset = np.array(datasetlist)
print(dataset.shape)
def sampling(args):
mean, logsigma = args
epsilon = K.random_normal(shape=(K.shape(mean)[0], 512), mean=0., stddev=1.0)
return mean + K.exp(logsigma / 2) * epsilon
def encoder(kernel, filter, rows, columns, channel):
X = Input(shape=(rows, columns, channel))
model = Conv2D(filters=filter, kernel_size=kernel, strides=2, padding='same')(X)
model = BatchNormalization(epsilon=1e-5)(model)
model = LeakyReLU(alpha=0.2)(model)
model = Conv2D(filters=filter*2, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = LeakyReLU(alpha=0.2)(model)
model = Conv2D(filters=filter*4, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = LeakyReLU(alpha=0.2)(model)
model = Conv2D(filters=filter*8, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = LeakyReLU(alpha=0.2)(model)
model = Flatten()(model)
mean = Dense(512)(model)
logsigma = Dense(512, activation='tanh')(model)
latent = Lambda(sampling, output_shape=(512,))([mean, logsigma])
meansigma = Model([X], [mean, logsigma, latent])
return meansigma
def decgen(kernel, filter, rows, columns, channel):
X = Input(shape=(512,))
model = Dense(filter*8*rows*columns)(X)
model = Reshape((rows, columns, filter * 8))(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = Activation('relu')(model)
model = Conv2DTranspose(filters=filter*4, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = Activation('relu')(model)
model = Conv2DTranspose(filters=filter*2, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = Activation('relu')(model)
model = Conv2DTranspose(filters=filter, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = Activation('relu')(model)
model = Conv2DTranspose(filters=channel, kernel_size=kernel, strides=2, padding='same')(model)
model = Activation('tanh')(model)
model = Model(X, model)
return model
def discriminator(kernel, filter, rows, columns, channel):
X = Input(shape=(rows, columns, channel))
model = Conv2D(filters=filter*2, kernel_size=kernel, strides=2, padding='same')(X)
model = LeakyReLU(alpha=0.2)(model)
model = Conv2D(filters=filter*4, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = LeakyReLU(alpha=0.2)(model)
model = Conv2D(filters=filter*8, kernel_size=kernel, strides=2, padding='same')(model)
model = BatchNormalization(epsilon=1e-5)(model)
model = LeakyReLU(alpha=0.2)(model)
model = Conv2D(filters=filter*8, kernel_size=kernel, strides=2, padding='same')(model)
dec = BatchNormalization(epsilon=1e-5)(model)
dec = LeakyReLU(alpha=0.2)(dec)
dec = Flatten()(dec)
dec = Dense(1, activation='sigmoid')(dec)
output = Model([X], [dec, model])
return output
batch_size = 512
rows = 64
columns = 64
channel = 3
epochs = 20000
datasize = len(dataset)
noise = np.random.normal(0, 1, (batch_size, 256))
# optimizers
SGDop = SGD(lr=0.0003)
ADAMop = Adam(lr=0.0002)
# encoder
E = encoder(5, 32, rows, columns, channel)
E.compile(optimizer=SGDop, loss='mse')
E.summary()
# generator/decoder
G = decgen(5, 32, rows, columns, channel)
G.compile(optimizer=SGDop, loss='mse')
G.summary()
# discriminator
D = discriminator(5, 32, rows, columns, channel)
D.compile(optimizer=SGDop, loss='mse')
D.summary()
D_fixed = discriminator(5, 32, rows, columns, channel)
D_fixed.compile(optimizer=SGDop, loss='mse')
# VAE
X = Input(shape=(rows, columns, channel))
# latent_rep = E(X)[0]
# output = G(latent_rep)
E_mean, E_logsigma, Z = E(X)
# Z = Input(shape=(512,))
# Z2 = Input(shape=(batch_size, 512))
output = G(Z)
G_dec = G(E_mean + E_logsigma)
D_fake, F_fake = D(output)
D_fromGen, F_fromGen = D(G_dec)
D_true, F_true = D(X)
VAE = Model(X, output)
kl = - 0.5 * K.sum(1 + E_logsigma - K.square(E_mean) - K.exp(E_logsigma), axis=-1)
crossent = 64 * metrics.mse(K.flatten(X), K.flatten(output))
VAEloss = K.mean(crossent + kl)
VAE.add_loss(VAEloss)
VAE.compile(optimizer=SGDop)
for epoch in range(epochs):
latent_vect = E.predict(dataset)[0]
encImg = G.predict(latent_vect)
fakeImg = G.predict(noise)
DlossTrue = D_true.train_on_batch(dataset, np.ones((batch_size, 1)))
DlossEnc = D_fromGen.train_on_batch(encImg, np.ones((batch_size, 1)))
DlossFake = D_fake.train_on_batch(fakeImg, np.zeros((batch_size, 1)))
cnt = epoch
while cnt > 3:
cnt = cnt - 4
if cnt == 0:
GlossEnc = G.train_on_batch(latent_vect, np.ones((batch_size, 1)))
GlossGen = G.train_on_batch(noise, np.ones((batch_size, 1)))
Eloss = VAE.train_on_batch(dataset, None)
chk = epoch
while chk > 50:
chk = chk - 51
if chk == 0:
D.save_weights('discriminator.h5')
G.save_weights('generator.h5')
E.save_weights('encoder.h5')
print("epoch number", epoch + 1)
print("loss:")
print("D:", DlossTrue, DlossEnc, DlossFake)
print("G:", GlossEnc, GlossGen)
print("VAE:", Eloss)
print('Training done,saving weights')
D.save_weights('discriminator.h5')
G.save_weights('generator.h5')
E.save_weights('encoder.h5')
print('end')