def example_gan(adversarial_optimizer, path, opt_g, opt_d, nb_epoch, generator, discriminator, latent_dim,
targets=gan_targets, loss='binary_crossentropy'):
csvpath = os.path.join(path, "history.csv")
if os.path.exists(csvpath):
print("Already exists: {}".format(csvpath))
return
print("Training: {}".format(csvpath))
# gan (x - > yfake, yreal), z generated on GPU
gan = simple_gan(generator, discriminator, normal_latent_sampling((latent_dim,)))
# print summary of models
generator.summary()
discriminator.summary()
gan.summary()
# build adversarial model
model = AdversarialModel(base_model=gan,
player_params=[generator.trainable_weights, discriminator.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(adversarial_optimizer=adversarial_optimizer,
player_optimizers=[opt_g, opt_d],
loss=loss)
# create callback to generate images
zsamples = np.random.normal(size=(10 * 10, latent_dim))
def generator_sampler():
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback(os.path.join(path, "epoch-{:03d}.png"), generator_sampler)
# train model
xtrain, xtest = mnist_data()
y = targets(xtrain.shape[0])
ytest = targets(xtest.shape[0])
callbacks = [generator_cb]
if K.backend() == "tensorflow":
callbacks.append(
TensorBoard(log_dir=os.path.join(path, 'logs'), histogram_freq=0, write_graph=True, write_images=True))
history = model.fit(x=xtrain, y=y, validation_data=(xtest, ytest), callbacks=callbacks, nb_epoch=nb_epoch,
batch_size=32)
# save history to CSV
df = pd.DataFrame(history.history)
df.to_csv(csvpath)
# save models
generator.save(os.path.join(path, "generator.h5"))
discriminator.save(os.path.join(path, "discriminator.h5"))
def example_gan(adversarial_optimizer, path, opt_g, opt_d, nb_epoch, generator, discriminator, latent_dim,
targets=gan_targets, loss='binary_crossentropy'):
csvpath = os.path.join(path, "history.csv")
if os.path.exists(csvpath):
print("Already exists: {}".format(csvpath))
return
print("Training: {}".format(csvpath))
# gan (x - > yfake, yreal), z generated on GPU
gan = simple_gan(generator, discriminator, normal_latent_sampling((latent_dim,)))
# print summary of models
generator.summary()
discriminator.summary()
gan.summary()
# build adversarial model
model = AdversarialModel(base_model=gan,
player_params=[generator.trainable_weights, discriminator.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(adversarial_optimizer=adversarial_optimizer,
player_optimizers=[opt_g, opt_d],
loss=loss)
# create callback to generate images
zsamples = np.random.normal(size=(10 * 10, latent_dim))
def generator_sampler():
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback(os.path.join(path, "epoch-{:03d}.png"), generator_sampler)
# train model
xtrain, xtest = mnist_data()
y = targets(xtrain.shape[0])
ytest = targets(xtest.shape[0])
callbacks = [generator_cb]
if K.backend() == "tensorflow":
callbacks.append(
TensorBoard(log_dir=os.path.join(path, 'logs'), histogram_freq=0, write_graph=True, write_images=True))
history = fit(model, x=xtrain, y=y, validation_data=(xtest, ytest), callbacks=callbacks, nb_epoch=nb_epoch,
batch_size=32)
# save history to CSV
df = pd.DataFrame(history.history)
df.to_csv(csvpath)
# save models
generator.save(os.path.join(path, "generator.h5"))
discriminator.save(os.path.join(path, "discriminator.h5"))
def example_aae(path, adversarial_optimizer):
# z \in R^100
latent_dim = 100
# x \in R^{28x28}
input_shape = (28, 28)
# generator (z -> x)
generator = model_generator(latent_dim, input_shape)
# encoder (x ->z)
encoder = model_encoder(latent_dim, input_shape)
# autoencoder (x -> x')
autoencoder = Model(encoder.inputs, generator(encoder(encoder.inputs)))
# discriminator (z -> y)
discriminator = model_discriminator(latent_dim)
# assemple AAE
x = encoder.inputs[0]
z = encoder(x)
xpred = generator(z)
zreal = normal_latent_sampling((latent_dim, ))(x)
yreal = discriminator(zreal)
yfake = discriminator(z)
aae = Model(x, fix_names([xpred, yfake, yreal],
["xpred", "yfake", "yreal"]))
# print summary of models
generator.summary()
encoder.summary()
discriminator.summary()
autoencoder.summary()
# build adversarial model
generative_params = generator.trainable_weights + encoder.trainable_weights
model = AdversarialModel(
base_model=aae,
player_params=[generative_params, discriminator.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(
adversarial_optimizer=adversarial_optimizer,
player_optimizers=[Adam(1e-4, decay=1e-4),
Adam(1e-3, decay=1e-4)],
loss={
"yfake": "binary_crossentropy",
"yreal": "binary_crossentropy",
"xpred": "mean_squared_error"
},
compile_kwargs={
"loss_weights": {
"yfake": 1e-2,
"yreal": 1e-2,
"xpred": 1
}
})
# load mnist data
xtrain, xtest = mnist_data()
# callback for image grid of generated samples
def generator_sampler():
zsamples = np.random.normal(size=(10 * 10, latent_dim))
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback(
os.path.join(path, "generated-epoch-{:03d}.png"), generator_sampler)
# callback for image grid of autoencoded samples
def autoencoder_sampler():
xsamples = n_choice(xtest, 10)
xrep = np.repeat(xsamples, 9, axis=0)
xgen = autoencoder.predict(xrep).reshape((10, 9, 28, 28))
xsamples = xsamples.reshape((10, 1, 28, 28))
samples = np.concatenate((xsamples, xgen), axis=1)
return samples
autoencoder_cb = ImageGridCallback(
os.path.join(path, "autoencoded-epoch-{:03d}.png"),
autoencoder_sampler)
# train network
# generator, discriminator; pred, yfake, yreal
n = xtrain.shape[0]
y = [
xtrain,
np.ones((n, 1)),
np.zeros((n, 1)), xtrain,
np.zeros((n, 1)),
np.ones((n, 1))
]
ntest = xtest.shape[0]
ytest = [
xtest,
np.ones((ntest, 1)),
np.zeros((ntest, 1)), xtest,
np.zeros((ntest, 1)),
np.ones((ntest, 1))
]
history = model.fit(x=xtrain,
y=y,
validation_data=(xtest, ytest),
callbacks=[generator_cb, autoencoder_cb],
nb_epoch=100,
batch_size=32)
# save history
df = pd.DataFrame(history.history)
df.to_csv(os.path.join(path, "history.csv"))
# save model
encoder.save(os.path.join(path, "encoder.h5"))
generator.save(os.path.join(path, "generator.h5"))
discriminator.save(os.path.join(path, "discriminator.h5"))
def main():
# z \in R^100
latent_dim = 100
# x \in R^{28x28}
input_shape = (28, 28)
# generator (z -> x)
generator = model_generator(latent_dim, input_shape)
# encoder (x ->z)
encoder = model_encoder(latent_dim, input_shape)
# autoencoder (x -> x')
autoencoder = Model(encoder.inputs, generator(encoder(encoder.inputs)))
# discriminator (x -> y)
discriminator = model_discriminator(latent_dim, input_shape)
# bigan (x - > yfake, yreal), z generated on GPU
bigan = simple_bigan(generator, encoder, discriminator,
normal_latent_sampling((latent_dim, )))
generative_params = generator.trainable_weights + encoder.trainable_weights
# print summary of models
generator.summary()
encoder.summary()
discriminator.summary()
bigan.summary()
autoencoder.summary()
# build adversarial model
model = AdversarialModel(
base_model=bigan,
player_params=[generative_params, discriminator.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(
adversarial_optimizer=AdversarialOptimizerSimultaneous(),
player_optimizers=[Adam(1e-4, decay=1e-4),
Adam(1e-3, decay=1e-4)],
loss='binary_crossentropy')
# train model
xtrain, xtest = mnist_data()
def generator_sampler():
zsamples = np.random.normal(size=(10 * 10, latent_dim))
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback("output/bigan/generated-epoch-{:03d}.png",
generator_sampler)
def autoencoder_sampler():
xsamples = n_choice(xtest, 10)
xrep = np.repeat(xsamples, 9, axis=0)
xgen = autoencoder.predict(xrep).reshape((10, 9, 28, 28))
xsamples = xsamples.reshape((10, 1, 28, 28))
x = np.concatenate((xsamples, xgen), axis=1)
return x
autoencoder_cb = ImageGridCallback(
"output/bigan/autoencoded-epoch-{:03d}.png", autoencoder_sampler)
y = gan_targets(xtrain.shape[0])
ytest = gan_targets(xtest.shape[0])
history = model.fit(x=xtrain,
y=y,
validation_data=(xtest, ytest),
callbacks=[generator_cb, autoencoder_cb],
nb_epoch=100,
batch_size=32)
df = pd.DataFrame(history.history)
df.to_csv("output/bigan/history.csv")
encoder.save("output/bigan/encoder.h5")
generator.save("output/bigan/generator.h5")
discriminator.save("output/bigan/discriminator.h5")
def example_bigan(path, adversarial_optimizer):
# z \in R^100
latent_dim = 25
# x \in R^{28x28}
input_shape = (28, 28)
# generator (z -> x)
generator = model_generator(latent_dim, input_shape)
# encoder (x ->z)
encoder = model_encoder(latent_dim, input_shape)
# autoencoder (x -> x')
autoencoder = Model(encoder.inputs, generator(encoder(encoder.inputs)))
# discriminator (x -> y)
discriminator_train, discriminator_test = model_discriminator(
latent_dim, input_shape)
# bigan (z, x - > yfake, yreal)
bigan_generator = simple_bigan(generator, encoder, discriminator_test)
bigan_discriminator = simple_bigan(generator, encoder, discriminator_train)
# z generated on GPU based on batch dimension of x
x = bigan_generator.inputs[1]
z = normal_latent_sampling((latent_dim, ))(x)
# eliminate z from inputs
bigan_generator = Model([x],
fix_names(bigan_generator([z, x]),
bigan_generator.output_names))
bigan_discriminator = Model([x],
fix_names(bigan_discriminator([z, x]),
bigan_discriminator.output_names))
generative_params = generator.trainable_weights + encoder.trainable_weights
# print summary of models
generator.summary()
encoder.summary()
discriminator_train.summary()
bigan_discriminator.summary()
autoencoder.summary()
# build adversarial model
model = AdversarialModel(
player_models=[bigan_generator, bigan_discriminator],
player_params=[
generative_params, discriminator_train.trainable_weights
],
player_names=["generator", "discriminator"])
model.adversarial_compile(
adversarial_optimizer=adversarial_optimizer,
player_optimizers=[Adam(1e-4, decay=1e-4),
Adam(1e-3, decay=1e-4)],
loss='binary_crossentropy')
# load mnist data
xtrain, xtest = mnist_data()
# callback for image grid of generated samples
def generator_sampler():
zsamples = np.random.normal(size=(10 * 10, latent_dim))
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback(
os.path.join(path, "generated-epoch-{:03d}.png"), generator_sampler)
# callback for image grid of autoencoded samples
def autoencoder_sampler():
xsamples = n_choice(xtest, 10)
xrep = np.repeat(xsamples, 9, axis=0)
xgen = autoencoder.predict(xrep).reshape((10, 9, 28, 28))
xsamples = xsamples.reshape((10, 1, 28, 28))
x = np.concatenate((xsamples, xgen), axis=1)
return x
autoencoder_cb = ImageGridCallback(
os.path.join(path, "autoencoded-epoch-{:03d}.png"),
autoencoder_sampler)
# train network
y = gan_targets(xtrain.shape[0])
ytest = gan_targets(xtest.shape[0])
history = model.fit(x=xtrain,
y=y,
validation_data=(xtest, ytest),
callbacks=[generator_cb, autoencoder_cb],
nb_epoch=100,
batch_size=32)
# save history
df = pd.DataFrame(history.history)
df.to_csv(os.path.join(path, "history.csv"))
# save model
encoder.save(os.path.join(path, "encoder.h5"))
generator.save(os.path.join(path, "generator.h5"))
discriminator_train.save(os.path.join(path, "discriminator.h5"))
def example_aae(path, adversarial_optimizer):
# z \in R^100
latent_dim = 100
# x \in R^{28x28}
input_shape = (28, 28)
# generator (z -> x)
generator = model_generator(latent_dim, input_shape)
# encoder (x ->z)
encoder = model_encoder(latent_dim, input_shape)
# autoencoder (x -> x')
autoencoder = Model(encoder.inputs, generator(encoder(encoder.inputs)))
# discriminator (z -> y)
discriminator = model_discriminator(latent_dim)
# assemple AAE
x = encoder.inputs[0]
z = encoder(x)
xpred = generator(z)
zreal = normal_latent_sampling((latent_dim,))(x)
yreal = discriminator(zreal)
yfake = discriminator(z)
aae = Model(x, fix_names([xpred, yfake, yreal], ["xpred", "yfake", "yreal"]))
# print summary of models
generator.summary()
encoder.summary()
discriminator.summary()
autoencoder.summary()
# build adversarial model
generative_params = generator.trainable_weights + encoder.trainable_weights
model = AdversarialModel(base_model=aae,
player_params=[generative_params, discriminator.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(adversarial_optimizer=adversarial_optimizer,
player_optimizers=[Adam(1e-4, decay=1e-4), Adam(1e-3, decay=1e-4)],
loss={"yfake": "binary_crossentropy", "yreal": "binary_crossentropy",
"xpred": "mean_squared_error"},
compile_kwargs={"loss_weights": {"yfake": 1e-2, "yreal": 1e-2, "xpred": 1}})
# load mnist data
xtrain, xtest = mnist_data()
# callback for image grid of generated samples
def generator_sampler():
zsamples = np.random.normal(size=(10 * 10, latent_dim))
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback(os.path.join(path, "generated-epoch-{:03d}.png"), generator_sampler)
# callback for image grid of autoencoded samples
def autoencoder_sampler():
xsamples = n_choice(xtest, 10)
xrep = np.repeat(xsamples, 9, axis=0)
xgen = autoencoder.predict(xrep).reshape((10, 9, 28, 28))
xsamples = xsamples.reshape((10, 1, 28, 28))
samples = np.concatenate((xsamples, xgen), axis=1)
return samples
autoencoder_cb = ImageGridCallback(os.path.join(path, "autoencoded-epoch-{:03d}.png"), autoencoder_sampler)
# train network
# generator, discriminator; pred, yfake, yreal
n = xtrain.shape[0]
y = [xtrain, np.ones((n, 1)), np.zeros((n, 1)), xtrain, np.zeros((n, 1)), np.ones((n, 1))]
ntest = xtest.shape[0]
ytest = [xtest, np.ones((ntest, 1)), np.zeros((ntest, 1)), xtest, np.zeros((ntest, 1)), np.ones((ntest, 1))]
history = model.fit(x=xtrain, y=y, validation_data=(xtest, ytest), callbacks=[generator_cb, autoencoder_cb],
nb_epoch=100, batch_size=32)
# save history
df = pd.DataFrame(history.history)
df.to_csv(os.path.join(path, "history.csv"))
# save model
encoder.save(os.path.join(path, "encoder.h5"))
generator.save(os.path.join(path, "generator.h5"))
discriminator.save(os.path.join(path, "discriminator.h5"))
def main():
# z \in R^100
latent_dim = 100
# x \in R^{28x28}
input_shape = (28, 28)
# generator (z -> x)
generator = model_generator(latent_dim, input_shape)
# encoder (x ->z)
encoder = model_encoder(latent_dim, input_shape)
# autoencoder (x -> x')
autoencoder = Model(encoder.inputs, generator(encoder(encoder.inputs)))
# discriminator (x -> y)
discriminator = model_discriminator(latent_dim, input_shape)
# bigan (x - > yfake, yreal), z generated on GPU
bigan = simple_bigan(generator, encoder, discriminator, normal_latent_sampling((latent_dim,)))
generative_params = generator.trainable_weights + encoder.trainable_weights
# print summary of models
generator.summary()
encoder.summary()
discriminator.summary()
bigan.summary()
autoencoder.summary()
# build adversarial model
model = AdversarialModel(base_model=bigan,
player_params=[generative_params, discriminator.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(adversarial_optimizer=AdversarialOptimizerSimultaneous(),
player_optimizers=[Adam(1e-4, decay=1e-4), Adam(1e-3, decay=1e-4)],
loss='binary_crossentropy')
# train model
xtrain, xtest = mnist_data()
def generator_sampler():
zsamples = np.random.normal(size=(10 * 10, latent_dim))
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback("output/bigan/generated-epoch-{:03d}.png", generator_sampler)
def autoencoder_sampler():
xsamples = n_choice(xtest, 10)
xrep = np.repeat(xsamples, 9, axis=0)
xgen = autoencoder.predict(xrep).reshape((10, 9, 28, 28))
xsamples = xsamples.reshape((10, 1, 28, 28))
x = np.concatenate((xsamples, xgen), axis=1)
return x
autoencoder_cb = ImageGridCallback("output/bigan/autoencoded-epoch-{:03d}.png", autoencoder_sampler)
y = gan_targets(xtrain.shape[0])
ytest = gan_targets(xtest.shape[0])
history = model.fit(x=xtrain, y=y, validation_data=(xtest, ytest), callbacks=[generator_cb, autoencoder_cb],
nb_epoch=100, batch_size=32)
df = pd.DataFrame(history.history)
df.to_csv("output/bigan/history.csv")
encoder.save("output/bigan/encoder.h5")
generator.save("output/bigan/generator.h5")
discriminator.save("output/bigan/discriminator.h5")
def example_bigan(path, adversarial_optimizer):
# z \in R^100
latent_dim = 25
# x \in R^{28x28}
input_shape = (28, 28)
# generator (z -> x)
generator = model_generator(latent_dim, input_shape)
# encoder (x ->z)
encoder = model_encoder(latent_dim, input_shape)
# autoencoder (x -> x')
autoencoder = Model(encoder.inputs, generator(encoder(encoder.inputs)))
# discriminator (x -> y)
discriminator_train, discriminator_test = model_discriminator(latent_dim, input_shape)
# bigan (z, x - > yfake, yreal)
bigan_generator = simple_bigan(generator, encoder, discriminator_test)
bigan_discriminator = simple_bigan(generator, encoder, discriminator_train)
# z generated on GPU based on batch dimension of x
x = bigan_generator.inputs[1]
z = normal_latent_sampling((latent_dim,))(x)
# eliminate z from inputs
bigan_generator = Model([x], fix_names(bigan_generator([z, x]), bigan_generator.output_names))
bigan_discriminator = Model([x], fix_names(bigan_discriminator([z, x]), bigan_discriminator.output_names))
generative_params = generator.trainable_weights + encoder.trainable_weights
# print summary of models
generator.summary()
encoder.summary()
discriminator_train.summary()
bigan_discriminator.summary()
autoencoder.summary()
# build adversarial model
model = AdversarialModel(player_models=[bigan_generator, bigan_discriminator],
player_params=[generative_params, discriminator_train.trainable_weights],
player_names=["generator", "discriminator"])
model.adversarial_compile(adversarial_optimizer=adversarial_optimizer,
player_optimizers=[Adam(1e-4, decay=1e-4), Adam(1e-3, decay=1e-4)],
loss='binary_crossentropy')
# load mnist data
xtrain, xtest = mnist_data()
# callback for image grid of generated samples
def generator_sampler():
zsamples = np.random.normal(size=(10 * 10, latent_dim))
return generator.predict(zsamples).reshape((10, 10, 28, 28))
generator_cb = ImageGridCallback(os.path.join(path, "generated-epoch-{:03d}.png"), generator_sampler)
# callback for image grid of autoencoded samples
def autoencoder_sampler():
xsamples = n_choice(xtest, 10)
xrep = np.repeat(xsamples, 9, axis=0)
xgen = autoencoder.predict(xrep).reshape((10, 9, 28, 28))
xsamples = xsamples.reshape((10, 1, 28, 28))
x = np.concatenate((xsamples, xgen), axis=1)
return x
autoencoder_cb = ImageGridCallback(os.path.join(path, "autoencoded-epoch-{:03d}.png"), autoencoder_sampler)
# train network
y = gan_targets(xtrain.shape[0])
ytest = gan_targets(xtest.shape[0])
history = model.fit(x=xtrain, y=y, validation_data=(xtest, ytest), callbacks=[generator_cb, autoencoder_cb],
nb_epoch=100, batch_size=32)
# save history
df = pd.DataFrame(history.history)
df.to_csv(os.path.join(path, "history.csv"))
# save model
encoder.save(os.path.join(path, "encoder.h5"))
generator.save(os.path.join(path, "generator.h5"))
discriminator_train.save(os.path.join(path, "discriminator.h5"))