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char_rnn_model.py
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char_rnn_model.py
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import logging
import time
import numpy as np
import tensorflow as tf
from tensorflow.models.rnn import rnn
# Disable Tensorflow logging messages.
logging.getLogger('tensorflow').setLevel(logging.WARNING)
class CharRNN(object):
"""Character RNN model."""
def __init__(self, is_training, batch_size, num_unrollings, vocab_size,
hidden_size, max_grad_norm, embedding_size, num_layers,
learning_rate, model, dropout=0.0, input_dropout=0.0, use_batch=True):
self.batch_size = batch_size
self.num_unrollings = num_unrollings
if not use_batch:
self.batch_size = 1
self.num_unrollings = 1
self.hidden_size = hidden_size
self.vocab_size = vocab_size
self.max_grad_norm = max_grad_norm
self.num_layers = num_layers
self.embedding_size = embedding_size
self.model = model
self.dropout = dropout
self.input_dropout = input_dropout
if embedding_size <= 0:
self.input_size = vocab_size
# Don't do dropout on one hot representation.
self.input_dropout = 0.0
else:
self.input_size = embedding_size
self.model_size = (embedding_size * vocab_size + # embedding parameters
# lstm parameters
4 * hidden_size * (hidden_size + self.input_size + 1) +
# softmax parameters
vocab_size * (hidden_size + 1) +
# multilayer lstm parameters for extra layers.
(num_layers - 1) * 4 * hidden_size *
(hidden_size + hidden_size + 1))
# self.decay_rate = decay_rate
# Placeholder to feed in input and targets/labels data.
self.input_data = tf.placeholder(tf.int64,
[self.batch_size, self.num_unrollings],
name='inputs')
self.targets = tf.placeholder(tf.int64,
[self.batch_size, self.num_unrollings],
name='targets')
if self.model == 'rnn':
cell_fn = tf.nn.rnn_cell.BasicRNNCell
elif self.model == 'lstm':
cell_fn = tf.nn.rnn_cell.BasicLSTMCell
elif self.model == 'gru':
cell_fn = tf.nn.rnn_cell.GRUCell
params = {'input_size': self.input_size}
if self.model == 'lstm':
# add bias to forget gate in lstm.
params['forget_bias'] = 0.0
# Create multilayer cell.
cell = cell_fn(self.hidden_size,
**params)
cells = [cell]
params['input_size'] = self.hidden_size
# more explicit way to create cells for MultiRNNCell than
# [higher_layer_cell] * (self.num_layers - 1)
for i in range(self.num_layers-1):
higher_layer_cell = cell_fn(self.hidden_size,
**params)
cells.append(higher_layer_cell)
if is_training and self.dropout > 0:
cells = [tf.nn.rnn_cell.DropoutWrapper(cell,
output_keep_prob=1.0-self.dropout)
for cell in cells]
multi_cell = tf.nn.rnn_cell.MultiRNNCell(cells)
with tf.name_scope('initial_state'):
# zero_state is used to compute the intial state for cell.
self.zero_state = multi_cell.zero_state(self.batch_size, tf.float32)
# Placeholder to feed in initial state.
self.initial_state = tf.placeholder(tf.float32,
[self.batch_size, multi_cell.state_size],
'initial_state')
# Embeddings layers.
with tf.name_scope('embedding_layer'):
if embedding_size > 0:
self.embedding = tf.get_variable("embedding",
[self.vocab_size, self.embedding_size])
else:
self.embedding = tf.constant(np.eye(self.vocab_size), dtype=tf.float32)
inputs = tf.nn.embedding_lookup(self.embedding, self.input_data)
if is_training and self.input_dropout > 0:
inputs = tf.nn.dropout(inputs, 1 - self.input_dropout)
with tf.name_scope('slice_inputs'):
# Slice inputs into a list of shape [batch_size, 1] data colums.
sliced_inputs = [tf.squeeze(input_, [1])
for input_ in tf.split(1, self.num_unrollings, inputs)]
# Copy cell to do unrolling and collect outputs.
outputs, final_state = rnn.rnn(multi_cell, sliced_inputs, initial_state=self.initial_state)
self.final_state = final_state
with tf.name_scope('flatten_ouputs'):
# Flatten the outputs into one dimension.
flat_outputs = tf.reshape(tf.concat(1, outputs), [-1, hidden_size])
with tf.name_scope('flatten_targets'):
# Flatten the targets too.
flat_targets = tf.reshape(tf.concat(1, self.targets), [-1])
# Create softmax parameters, weights and bias.
with tf.variable_scope('softmax') as sm_vs:
softmax_w = tf.get_variable("softmax_w", [hidden_size, vocab_size])
softmax_b = tf.get_variable("softmax_b", [vocab_size])
self.logits = tf.matmul(flat_outputs, softmax_w) + softmax_b
self.probs = tf.nn.softmax(self.logits)
with tf.name_scope('loss'):
# Compute mean cross entropy loss for each output.
loss = tf.nn.sparse_softmax_cross_entropy_with_logits(self.logits, flat_targets)
self.mean_loss = tf.reduce_mean(loss)
with tf.name_scope('loss_monitor'):
# Count the number of elements and the sum of mean_loss
# from each batch to compute the average loss.
count = tf.Variable(1.0, name='count')
sum_mean_loss = tf.Variable(1.0, name='sum_mean_loss')
self.reset_loss_monitor = tf.group(sum_mean_loss.assign(0.0),
count.assign(0.0),
name='reset_loss_monitor')
self.update_loss_monitor = tf.group(sum_mean_loss.assign(sum_mean_loss +
self.mean_loss),
count.assign(count + 1),
name='update_loss_monitor')
with tf.control_dependencies([self.update_loss_monitor]):
self.average_loss = sum_mean_loss / count
self.ppl = tf.exp(self.average_loss)
# Monitor the loss.
loss_summary_name = "average loss"
ppl_summary_name = "perplexity"
average_loss_summary = tf.scalar_summary(loss_summary_name, self.average_loss)
ppl_summary = tf.scalar_summary(ppl_summary_name, self.ppl)
# Monitor the loss.
self.summaries = tf.merge_summary([average_loss_summary, ppl_summary],
name='loss_monitor')
self.global_step = tf.get_variable('global_step', [],
initializer=tf.constant_initializer(0.0))
self.learning_rate = tf.constant(learning_rate)
if is_training:
# learning_rate = tf.train.exponential_decay(1.0, self.global_step,
# 5000, 0.1, staircase=True)
tvars = tf.trainable_variables()
grads, _ = tf.clip_by_global_norm(tf.gradients(self.mean_loss, tvars),
self.max_grad_norm)
# optimizer = tf.train.GradientDescentOptimizer(learning_rate)
# optimizer = tf.train.RMSPropOptimizer(learning_rate, decay_rate)
optimizer = tf.train.AdamOptimizer(self.learning_rate)
self.train_op = optimizer.apply_gradients(zip(grads, tvars),
global_step=self.global_step)
def run_epoch(self, session, data_size, batch_generator, is_training,
verbose=0, freq=10, summary_writer=None, debug=False):
"""Runs the model on the given data for one full pass."""
# epoch_size = ((data_size // self.batch_size) - 1) // self.num_unrollings
epoch_size = data_size // (self.batch_size * self.num_unrollings)
if data_size % (self.batch_size * self.num_unrollings) != 0:
epoch_size += 1
if verbose > 0:
logging.info('epoch_size: %d', epoch_size)
logging.info('data_size: %d', data_size)
logging.info('num_unrollings: %d', self.num_unrollings)
logging.info('batch_size: %d', self.batch_size)
if is_training:
extra_op = self.train_op
else:
extra_op = tf.no_op()
# Prepare initial state and reset the average loss
# computation.
state = self.zero_state.eval()
self.reset_loss_monitor.run()
start_time = time.time()
for step in range(epoch_size):
# Generate the batch and use [:-1] as inputs and [1:] as targets.
data = batch_generator.next()
inputs = np.array(data[:-1]).transpose()
targets = np.array(data[1:]).transpose()
ops = [self.average_loss, self.final_state, extra_op,
self.summaries, self.global_step, self.learning_rate]
feed_dict = {self.input_data: inputs, self.targets: targets,
self.initial_state: state}
results = session.run(ops, feed_dict)
average_loss, state, _, summary_str, global_step, lr = results
ppl = np.exp(average_loss)
if (verbose > 0) and ((step+1) % freq == 0):
logging.info("%.1f%%, step:%d, perplexity: %.3f, speed: %.0f words",
(step + 1) * 1.0 / epoch_size * 100, step, ppl,
(step + 1) * self.batch_size * self.num_unrollings /
(time.time() - start_time))
logging.info("Perplexity: %.3f, speed: %.0f words per sec",
ppl, (step + 1) * self.batch_size * self.num_unrollings /
(time.time() - start_time))
return ppl, summary_str, global_step
def sample_seq(self, session, length, start_text, vocab_index_dict,
index_vocab_dict, temperature=1.0, max_prob=True):
state = self.zero_state.eval()
# use start_text to warm up the RNN.
if start_text is not None and len(start_text) > 0:
seq = list(start_text)
for char in start_text[:-1]:
x = np.array([[char2id(char, vocab_index_dict)]])
state = session.run(self.final_state,
{self.input_data: x,
self.initial_state: state})
x = np.array([[char2id(start_text[-1], vocab_index_dict)]])
else:
vocab_size = len(vocab_index_dict.keys())
x = np.array([[np.random.randint(0, vocab_size)]])
seq = []
for i in range(length):
state, logits = session.run([self.final_state,
self.logits],
{self.input_data: x,
self.initial_state: state})
unnormalized_probs = np.exp((logits - np.max(logits)) / temperature)
probs = unnormalized_probs / np.sum(unnormalized_probs)
if max_prob:
sample = np.argmax(probs[0])
else:
sample = np.random.choice(self.vocab_size, 1, p=probs[0])[0]
seq.append(id2char(sample, index_vocab_dict))
x = np.array([[sample]])
return ''.join(seq)
class BatchGenerator(object):
"""Generate and hold batches."""
def __init__(self, text, batch_size, n_unrollings, vocab_size,
vocab_index_dict, index_vocab_dict):
self._text = text
self._text_size = len(text)
self._batch_size = batch_size
self.vocab_size = vocab_size
self._n_unrollings = n_unrollings
self.vocab_index_dict = vocab_index_dict
self.index_vocab_dict = index_vocab_dict
segment = self._text_size // batch_size
# number of elements in cursor list is the same as
# batch_size. each batch is just the collection of
# elements in where the cursors are pointing to.
self._cursor = [ offset * segment for offset in range(batch_size)]
self._last_batch = self._next_batch()
def _next_batch(self):
"""Generate a single batch from the current cursor position in the data."""
batch = np.zeros(shape=(self._batch_size), dtype=np.float)
for b in range(self._batch_size):
batch[b] = char2id(self._text[self._cursor[b]], self.vocab_index_dict)
self._cursor[b] = (self._cursor[b] + 1) % self._text_size
return batch
def next(self):
"""Generate the next array of batches from the data. The array consists of
the last batch of the previous array, followed by num_unrollings new ones.
"""
batches = [self._last_batch]
for step in range(self._n_unrollings):
batches.append(self._next_batch())
self._last_batch = batches[-1]
return batches
# Utility functions
def batches2string(batches, index_vocab_dict):
"""Convert a sequence of batches back into their (most likely) string
representation."""
s = [''] * batches[0].shape[0]
for b in batches:
s = [''.join(x) for x in zip(s, id2char_list(b, index_vocab_dict))]
return s
def characters(probabilities):
"""Turn a 1-hot encoding or a probability distribution over the possible
characters back into its (most likely) character representation."""
return [id2char(c) for c in np.argmax(probabilities, 1)]
def char2id(char, vocab_index_dict):
try:
return vocab_index_dict[char]
except KeyError:
logging.info('Unexpected char %s', char)
return 0
def id2char(index, index_vocab_dict):
return index_vocab_dict[index]
def id2char_list(lst, index_vocab_dict):
return [id2char(i, index_vocab_dict) for i in lst]