jojonki/variational_autoencoder.py

## variational_autoencoder.py
'''This script demonstrates how to build a variational autoencoder with Keras.
Reference: "Auto-Encoding Variational Bayes" https://arxiv.org/abs/1312.6114
'''
import numpy as np
import matplotlib.pyplot as plt
from scipy.stats import norm

from keras.layers import Input, Dense, Lambda, Layer
from keras.models import Model
from keras import backend as K
from keras import metrics
from keras.datasets import mnist

batch_size = 100
original_dim = 784
latent_dim = 2
intermediate_dim = 256
epochs = 50
epsilon_std = 1.0


x = Input(shape=(original_dim,))
h = Dense(intermediate_dim, activation='relu')(x)
z_mean = Dense(latent_dim)(h)
z_log_var = Dense(latent_dim)(h)


def sampling(args):
    z_mean, z_log_var = args
    epsilon = K.random_normal(shape=(batch_size, latent_dim), mean=0.,
                              stddev=epsilon_std)
    return z_mean + K.exp(z_log_var / 2) * epsilon

# note that "output_shape" isn't necessary with the TensorFlow backend
z = Lambda(sampling, output_shape=(latent_dim,))([z_mean, z_log_var])

# we instantiate these layers separately so as to reuse them later
decoder_h = Dense(intermediate_dim, activation='relu')
decoder_mean = Dense(original_dim, activation='sigmoid')
h_decoded = decoder_h(z)
x_decoded_mean = decoder_mean(h_decoded)


# Custom loss layer
class CustomVariationalLayer(Layer):
    def __init__(self, **kwargs):
        self.is_placeholder = True
        super(CustomVariationalLayer, self).__init__(**kwargs)

    def vae_loss(self, x, x_decoded_mean):
        xent_loss = original_dim * metrics.binary_crossentropy(x, x_decoded_mean)
        kl_loss = - 0.5 * K.sum(1 + z_log_var - K.square(z_mean) - K.exp(z_log_var), axis=-1)
        return K.mean(xent_loss + kl_loss)

    def call(self, inputs):
        x = inputs[0]
        x_decoded_mean = inputs[1]
        loss = self.vae_loss(x, x_decoded_mean)
        self.add_loss(loss, inputs=inputs)
        # We won't actually use the output.
        return x

y = CustomVariationalLayer()([x, x_decoded_mean])
vae = Model(x, y)
vae.compile(optimizer='rmsprop', loss=None)


# train the VAE on MNIST digits
(x_train, y_train), (x_test, y_test) = mnist.load_data()

x_train = x_train.astype('float32') / 255.
x_test = x_test.astype('float32') / 255.
x_train = x_train.reshape((len(x_train), np.prod(x_train.shape[1:])))
x_test = x_test.reshape((len(x_test), np.prod(x_test.shape[1:])))
print(x_train.shape)
vae.fit(x_train,
        shuffle=True,
        epochs=epochs,
        batch_size=batch_size,
        validation_data=(x_test, x_test))

# build a model to project inputs on the latent space
encoder = Model(x, z_mean)

# display a 2D plot of the digit classes in the latent space
x_test_encoded = encoder.predict(x_test, batch_size=batch_size)
plt.figure(figsize=(6, 6))
plt.scatter(x_test_encoded[:, 0], x_test_encoded[:, 1], c=y_test)
plt.colorbar()
plt.show()

# build a digit generator that can sample from the learned distribution
decoder_input = Input(shape=(latent_dim,))
_h_decoded = decoder_h(decoder_input)
_x_decoded_mean = decoder_mean(_h_decoded)
generator = Model(decoder_input, _x_decoded_mean)

# display a 2D manifold of the digits
n = 15  # figure with 15x15 digits
digit_size = 28
figure = np.zeros((digit_size * n, digit_size * n))
# linearly spaced coordinates on the unit square were transformed through the inverse CDF (ppf) of the Gaussian
# to produce values of the latent variables z, since the prior of the latent space is Gaussian
grid_x = norm.ppf(np.linspace(0.05, 0.95, n))
grid_y = norm.ppf(np.linspace(0.05, 0.95, n))

for i, yi in enumerate(grid_x):
    for j, xi in enumerate(grid_y):
        z_sample = np.array([[xi, yi]])
        x_decoded = generator.predict(z_sample)
        digit = x_decoded[0].reshape(digit_size, digit_size)
        figure[i * digit_size: (i + 1) * digit_size,
               j * digit_size: (j + 1) * digit_size] = digit

plt.figure(figsize=(10, 10))
plt.imshow(figure, cmap='Greys_r')
plt.show()
	'''This script demonstrates how to build a variational autoencoder with Keras.
	Reference: "Auto-Encoding Variational Bayes" https://arxiv.org/abs/1312.6114
	'''
	import numpy as np
	import matplotlib.pyplot as plt
	from scipy.stats import norm

	from keras.layers import Input, Dense, Lambda, Layer
	from keras.models import Model
	from keras import backend as K
	from keras import metrics
	from keras.datasets import mnist

	batch_size = 100
	original_dim = 784
	latent_dim = 2
	intermediate_dim = 256
	epochs = 50
	epsilon_std = 1.0


	x = Input(shape=(original_dim,))
	h = Dense(intermediate_dim, activation='relu')(x)
	z_mean = Dense(latent_dim)(h)
	z_log_var = Dense(latent_dim)(h)


	def sampling(args):
	z_mean, z_log_var = args
	epsilon = K.random_normal(shape=(batch_size, latent_dim), mean=0.,
	stddev=epsilon_std)
	return z_mean + K.exp(z_log_var / 2) * epsilon

	# note that "output_shape" isn't necessary with the TensorFlow backend
	z = Lambda(sampling, output_shape=(latent_dim,))([z_mean, z_log_var])

	# we instantiate these layers separately so as to reuse them later
	decoder_h = Dense(intermediate_dim, activation='relu')
	decoder_mean = Dense(original_dim, activation='sigmoid')
	h_decoded = decoder_h(z)
	x_decoded_mean = decoder_mean(h_decoded)


	# Custom loss layer
	class CustomVariationalLayer(Layer):
	def __init__(self, **kwargs):
	self.is_placeholder = True
	super(CustomVariationalLayer, self).__init__(**kwargs)

	def vae_loss(self, x, x_decoded_mean):
	xent_loss = original_dim * metrics.binary_crossentropy(x, x_decoded_mean)
	kl_loss = - 0.5 * K.sum(1 + z_log_var - K.square(z_mean) - K.exp(z_log_var), axis=-1)
	return K.mean(xent_loss + kl_loss)

	def call(self, inputs):
	x = inputs[0]
	x_decoded_mean = inputs[1]
	loss = self.vae_loss(x, x_decoded_mean)
	self.add_loss(loss, inputs=inputs)
	# We won't actually use the output.
	return x

	y = CustomVariationalLayer()([x, x_decoded_mean])
	vae = Model(x, y)
	vae.compile(optimizer='rmsprop', loss=None)


	# train the VAE on MNIST digits
	(x_train, y_train), (x_test, y_test) = mnist.load_data()

	x_train = x_train.astype('float32') / 255.
	x_test = x_test.astype('float32') / 255.
	x_train = x_train.reshape((len(x_train), np.prod(x_train.shape[1:])))
	x_test = x_test.reshape((len(x_test), np.prod(x_test.shape[1:])))
	print(x_train.shape)
	vae.fit(x_train,
	shuffle=True,
	epochs=epochs,
	batch_size=batch_size,
	validation_data=(x_test, x_test))

	# build a model to project inputs on the latent space
	encoder = Model(x, z_mean)

	# display a 2D plot of the digit classes in the latent space
	x_test_encoded = encoder.predict(x_test, batch_size=batch_size)
	plt.figure(figsize=(6, 6))
	plt.scatter(x_test_encoded[:, 0], x_test_encoded[:, 1], c=y_test)
	plt.colorbar()
	plt.show()

	# build a digit generator that can sample from the learned distribution
	decoder_input = Input(shape=(latent_dim,))
	_h_decoded = decoder_h(decoder_input)
	_x_decoded_mean = decoder_mean(_h_decoded)
	generator = Model(decoder_input, _x_decoded_mean)

	# display a 2D manifold of the digits
	n = 15 # figure with 15x15 digits
	digit_size = 28
	figure = np.zeros((digit_size * n, digit_size * n))
	# linearly spaced coordinates on the unit square were transformed through the inverse CDF (ppf) of the Gaussian
	# to produce values of the latent variables z, since the prior of the latent space is Gaussian
	grid_x = norm.ppf(np.linspace(0.05, 0.95, n))
	grid_y = norm.ppf(np.linspace(0.05, 0.95, n))

	for i, yi in enumerate(grid_x):
	for j, xi in enumerate(grid_y):
	z_sample = np.array([[xi, yi]])
	x_decoded = generator.predict(z_sample)
	digit = x_decoded[0].reshape(digit_size, digit_size)
	figure[i * digit_size: (i + 1) * digit_size,
	j * digit_size: (j + 1) * digit_size] = digit

	plt.figure(figsize=(10, 10))
	plt.imshow(figure, cmap='Greys_r')
	plt.show()