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gan_language.py
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gan_language.py
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import os, sys
sys.path.append(os.getcwd())
import time
import numpy as np
import tensorflow as tf
import language_helpers
import tflib as lib
import tflib.ops.linear
import tflib.ops.conv1d
import tflib.plot
# Download Google Billion Word at http://www.statmt.org/lm-benchmark/ and
# fill in the path to the extracted files here!
DATA_DIR = ''
if len(DATA_DIR) == 0:
raise Exception('Please specify path to data directory in gan_language.py!')
BATCH_SIZE = 64 # Batch size
ITERS = 200000 # How many iterations to train for
SEQ_LEN = 32 # Sequence length in characters
DIM = 512 # Model dimensionality. This is fairly slow and overfits, even on
# Billion Word. Consider decreasing for smaller datasets.
CRITIC_ITERS = 10 # How many critic iterations per generator iteration. We
# use 10 for the results in the paper, but 5 should work fine
# as well.
LAMBDA = 10 # Gradient penalty lambda hyperparameter.
MAX_N_EXAMPLES = 10000000 # Max number of data examples to load. If data loading
# is too slow or takes too much RAM, you can decrease
# this (at the expense of having less training data).
lib.print_model_settings(locals().copy())
lines, charmap, inv_charmap = language_helpers.load_dataset(
max_length=SEQ_LEN,
max_n_examples=MAX_N_EXAMPLES,
data_dir=DATA_DIR
)
def softmax(logits):
return tf.reshape(
tf.nn.softmax(
tf.reshape(logits, [-1, len(charmap)])
),
tf.shape(logits)
)
def make_noise(shape):
return tf.random_normal(shape)
def ResBlock(name, inputs):
output = inputs
output = tf.nn.relu(output)
output = lib.ops.conv1d.Conv1D(name+'.1', DIM, DIM, 5, output)
output = tf.nn.relu(output)
output = lib.ops.conv1d.Conv1D(name+'.2', DIM, DIM, 5, output)
return inputs + (0.3*output)
def Generator(n_samples, prev_outputs=None):
output = make_noise(shape=[n_samples, 128])
output = lib.ops.linear.Linear('Generator.Input', 128, SEQ_LEN*DIM, output)
output = tf.reshape(output, [-1, DIM, SEQ_LEN])
output = ResBlock('Generator.1', output)
output = ResBlock('Generator.2', output)
output = ResBlock('Generator.3', output)
output = ResBlock('Generator.4', output)
output = ResBlock('Generator.5', output)
output = lib.ops.conv1d.Conv1D('Generator.Output', DIM, len(charmap), 1, output)
output = tf.transpose(output, [0, 2, 1])
output = softmax(output)
return output
def Discriminator(inputs):
output = tf.transpose(inputs, [0,2,1])
output = lib.ops.conv1d.Conv1D('Discriminator.Input', len(charmap), DIM, 1, output)
output = ResBlock('Discriminator.1', output)
output = ResBlock('Discriminator.2', output)
output = ResBlock('Discriminator.3', output)
output = ResBlock('Discriminator.4', output)
output = ResBlock('Discriminator.5', output)
output = tf.reshape(output, [-1, SEQ_LEN*DIM])
output = lib.ops.linear.Linear('Discriminator.Output', SEQ_LEN*DIM, 1, output)
return output
real_inputs_discrete = tf.placeholder(tf.int32, shape=[BATCH_SIZE, SEQ_LEN])
real_inputs = tf.one_hot(real_inputs_discrete, len(charmap))
fake_inputs = Generator(BATCH_SIZE)
fake_inputs_discrete = tf.argmax(fake_inputs, fake_inputs.get_shape().ndims-1)
disc_real = Discriminator(real_inputs)
disc_fake = Discriminator(fake_inputs)
disc_cost = tf.reduce_mean(disc_fake) - tf.reduce_mean(disc_real)
gen_cost = -tf.reduce_mean(disc_fake)
# WGAN lipschitz-penalty
alpha = tf.random_uniform(
shape=[BATCH_SIZE,1,1],
minval=0.,
maxval=1.
)
differences = fake_inputs - real_inputs
interpolates = real_inputs + (alpha*differences)
gradients = tf.gradients(Discriminator(interpolates), [interpolates])[0]
slopes = tf.sqrt(tf.reduce_sum(tf.square(gradients), reduction_indices=[1,2]))
gradient_penalty = tf.reduce_mean((slopes-1.)**2)
disc_cost += LAMBDA*gradient_penalty
gen_params = lib.params_with_name('Generator')
disc_params = lib.params_with_name('Discriminator')
gen_train_op = tf.train.AdamOptimizer(learning_rate=1e-4, beta1=0.5, beta2=0.9).minimize(gen_cost, var_list=gen_params)
disc_train_op = tf.train.AdamOptimizer(learning_rate=1e-4, beta1=0.5, beta2=0.9).minimize(disc_cost, var_list=disc_params)
# Dataset iterator
def inf_train_gen():
while True:
np.random.shuffle(lines)
for i in xrange(0, len(lines)-BATCH_SIZE+1, BATCH_SIZE):
yield np.array(
[[charmap[c] for c in l] for l in lines[i:i+BATCH_SIZE]],
dtype='int32'
)
# During training we monitor JS divergence between the true & generated ngram
# distributions for n=1,2,3,4. To get an idea of the optimal values, we
# evaluate these statistics on a held-out set first.
true_char_ngram_lms = [language_helpers.NgramLanguageModel(i+1, lines[10*BATCH_SIZE:], tokenize=False) for i in xrange(4)]
validation_char_ngram_lms = [language_helpers.NgramLanguageModel(i+1, lines[:10*BATCH_SIZE], tokenize=False) for i in xrange(4)]
for i in xrange(4):
print "validation set JSD for n={}: {}".format(i+1, true_char_ngram_lms[i].js_with(validation_char_ngram_lms[i]))
true_char_ngram_lms = [language_helpers.NgramLanguageModel(i+1, lines, tokenize=False) for i in xrange(4)]
with tf.Session() as session:
session.run(tf.initialize_all_variables())
def generate_samples():
samples = session.run(fake_inputs)
samples = np.argmax(samples, axis=2)
decoded_samples = []
for i in xrange(len(samples)):
decoded = []
for j in xrange(len(samples[i])):
decoded.append(inv_charmap[samples[i][j]])
decoded_samples.append(tuple(decoded))
return decoded_samples
gen = inf_train_gen()
for iteration in xrange(ITERS):
start_time = time.time()
# Train generator
if iteration > 0:
_ = session.run(gen_train_op)
# Train critic
for i in xrange(CRITIC_ITERS):
_data = gen.next()
_disc_cost, _ = session.run(
[disc_cost, disc_train_op],
feed_dict={real_inputs_discrete:_data}
)
lib.plot.plot('time', time.time() - start_time)
lib.plot.plot('train disc cost', _disc_cost)
if iteration % 100 == 99:
samples = []
for i in xrange(10):
samples.extend(generate_samples())
for i in xrange(4):
lm = language_helpers.NgramLanguageModel(i+1, samples, tokenize=False)
lib.plot.plot('js{}'.format(i+1), lm.js_with(true_char_ngram_lms[i]))
with open('samples_{}.txt'.format(iteration), 'w') as f:
for s in samples:
s = "".join(s)
f.write(s + "\n")
if iteration % 100 == 99:
lib.plot.flush()
lib.plot.tick()