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seq2seq_attention_model.py
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seq2seq_attention_model.py
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# Copyright 2016 The TensorFlow Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ==============================================================================
"""Sequence-to-Sequence with attention model for text summarization.
"""
from collections import namedtuple
import numpy as np
import seq2seq_lib
from six.moves import xrange
import tensorflow as tf
HParams = namedtuple('HParams',
'mode, min_lr, lr, batch_size, '
'enc_layers, enc_timesteps, dec_timesteps, '
'min_input_len, num_hidden, emb_dim, max_grad_norm, '
'num_softmax_samples')
def _extract_argmax_and_embed(embedding, output_projection=None,
update_embedding=True):
"""Get a loop_function that extracts the previous symbol and embeds it.
Args:
embedding: embedding tensor for symbols.
output_projection: None or a pair (W, B). If provided, each fed previous
output will first be multiplied by W and added B.
update_embedding: Boolean; if False, the gradients will not propagate
through the embeddings.
Returns:
A loop function.
"""
def loop_function(prev, _):
"""function that feed previous model output rather than ground truth."""
if output_projection is not None:
prev = tf.nn.xw_plus_b(
prev, output_projection[0], output_projection[1])
prev_symbol = tf.argmax(prev, 1)
# Note that gradients will not propagate through the second parameter of
# embedding_lookup.
emb_prev = tf.nn.embedding_lookup(embedding, prev_symbol)
if not update_embedding:
emb_prev = tf.stop_gradient(emb_prev)
return emb_prev
return loop_function
class Seq2SeqAttentionModel(object):
"""Wrapper for Tensorflow model graph for text sum vectors."""
def __init__(self, hps, vocab, num_gpus=0):
self._hps = hps
self._vocab = vocab
self._num_gpus = num_gpus
self._cur_gpu = 0
def run_train_step(self, sess, article_batch, abstract_batch, targets,
article_lens, abstract_lens, loss_weights):
to_return = [self._train_op, self._summaries, self._loss, self.global_step]
return sess.run(to_return,
feed_dict={self._articles: article_batch,
self._abstracts: abstract_batch,
self._targets: targets,
self._article_lens: article_lens,
self._abstract_lens: abstract_lens,
self._loss_weights: loss_weights})
def run_eval_step(self, sess, article_batch, abstract_batch, targets,
article_lens, abstract_lens, loss_weights):
to_return = [self._summaries, self._loss, self.global_step]
return sess.run(to_return,
feed_dict={self._articles: article_batch,
self._abstracts: abstract_batch,
self._targets: targets,
self._article_lens: article_lens,
self._abstract_lens: abstract_lens,
self._loss_weights: loss_weights})
def run_decode_step(self, sess, article_batch, abstract_batch, targets,
article_lens, abstract_lens, loss_weights):
to_return = [self._outputs, self.global_step]
return sess.run(to_return,
feed_dict={self._articles: article_batch,
self._abstracts: abstract_batch,
self._targets: targets,
self._article_lens: article_lens,
self._abstract_lens: abstract_lens,
self._loss_weights: loss_weights})
def _next_device(self):
"""Round robin the gpu device. (Reserve last gpu for expensive op)."""
if self._num_gpus == 0:
return ''
dev = '/gpu:%d' % self._cur_gpu
if self._num_gpus > 1:
self._cur_gpu = (self._cur_gpu + 1) % (self._num_gpus-1)
return dev
def _get_gpu(self, gpu_id):
if self._num_gpus <= 0 or gpu_id >= self._num_gpus:
return ''
return '/gpu:%d' % gpu_id
def _add_placeholders(self):
"""Inputs to be fed to the graph."""
hps = self._hps
self._articles = tf.placeholder(tf.int32,
[hps.batch_size, hps.enc_timesteps],
name='articles')
self._abstracts = tf.placeholder(tf.int32,
[hps.batch_size, hps.dec_timesteps],
name='abstracts')
self._targets = tf.placeholder(tf.int32,
[hps.batch_size, hps.dec_timesteps],
name='targets')
self._article_lens = tf.placeholder(tf.int32, [hps.batch_size],
name='article_lens')
self._abstract_lens = tf.placeholder(tf.int32, [hps.batch_size],
name='abstract_lens')
self._loss_weights = tf.placeholder(tf.float32,
[hps.batch_size, hps.dec_timesteps],
name='loss_weights')
def _add_seq2seq(self):
hps = self._hps
vsize = self._vocab.NumIds()
with tf.variable_scope('seq2seq'):
encoder_inputs = tf.unstack(tf.transpose(self._articles))
decoder_inputs = tf.unstack(tf.transpose(self._abstracts))
targets = tf.unstack(tf.transpose(self._targets))
loss_weights = tf.unstack(tf.transpose(self._loss_weights))
article_lens = self._article_lens
# Embedding shared by the input and outputs.
with tf.variable_scope('embedding'), tf.device('/cpu:0'):
embedding = tf.get_variable(
'embedding', [vsize, hps.emb_dim], dtype=tf.float32,
initializer=tf.truncated_normal_initializer(stddev=1e-4))
emb_encoder_inputs = [tf.nn.embedding_lookup(embedding, x)
for x in encoder_inputs]
emb_decoder_inputs = [tf.nn.embedding_lookup(embedding, x)
for x in decoder_inputs]
for layer_i in xrange(hps.enc_layers):
with tf.variable_scope('encoder%d'%layer_i), tf.device(
self._next_device()):
cell_fw = tf.contrib.rnn.LSTMCell(
hps.num_hidden,
initializer=tf.random_uniform_initializer(-0.1, 0.1, seed=123),
state_is_tuple=False)
cell_bw = tf.contrib.rnn.LSTMCell(
hps.num_hidden,
initializer=tf.random_uniform_initializer(-0.1, 0.1, seed=113),
state_is_tuple=False)
(emb_encoder_inputs, fw_state, _) = tf.contrib.rnn.static_bidirectional_rnn(
cell_fw, cell_bw, emb_encoder_inputs, dtype=tf.float32,
sequence_length=article_lens)
encoder_outputs = emb_encoder_inputs
with tf.variable_scope('output_projection'):
w = tf.get_variable(
'w', [hps.num_hidden, vsize], dtype=tf.float32,
initializer=tf.truncated_normal_initializer(stddev=1e-4))
w_t = tf.transpose(w)
v = tf.get_variable(
'v', [vsize], dtype=tf.float32,
initializer=tf.truncated_normal_initializer(stddev=1e-4))
with tf.variable_scope('decoder'), tf.device(self._next_device()):
# When decoding, use model output from the previous step
# for the next step.
loop_function = None
if hps.mode == 'decode':
loop_function = _extract_argmax_and_embed(
embedding, (w, v), update_embedding=False)
cell = tf.contrib.rnn.LSTMCell(
hps.num_hidden,
initializer=tf.random_uniform_initializer(-0.1, 0.1, seed=113),
state_is_tuple=False)
encoder_outputs = [tf.reshape(x, [hps.batch_size, 1, 2*hps.num_hidden])
for x in encoder_outputs]
self._enc_top_states = tf.concat(axis=1, values=encoder_outputs)
self._dec_in_state = fw_state
# During decoding, follow up _dec_in_state are fed from beam_search.
# dec_out_state are stored by beam_search for next step feeding.
initial_state_attention = (hps.mode == 'decode')
decoder_outputs, self._dec_out_state = tf.contrib.legacy_seq2seq.attention_decoder(
emb_decoder_inputs, self._dec_in_state, self._enc_top_states,
cell, num_heads=1, loop_function=loop_function,
initial_state_attention=initial_state_attention)
with tf.variable_scope('output'), tf.device(self._next_device()):
model_outputs = []
for i in xrange(len(decoder_outputs)):
if i > 0:
tf.get_variable_scope().reuse_variables()
model_outputs.append(
tf.nn.xw_plus_b(decoder_outputs[i], w, v))
if hps.mode == 'decode':
with tf.variable_scope('decode_output'), tf.device('/cpu:0'):
best_outputs = [tf.argmax(x, 1) for x in model_outputs]
tf.logging.info('best_outputs%s', best_outputs[0].get_shape())
self._outputs = tf.concat(
axis=1, values=[tf.reshape(x, [hps.batch_size, 1]) for x in best_outputs])
self._topk_log_probs, self._topk_ids = tf.nn.top_k(
tf.log(tf.nn.softmax(model_outputs[-1])), hps.batch_size*2)
with tf.variable_scope('loss'), tf.device(self._next_device()):
def sampled_loss_func(inputs, labels):
with tf.device('/cpu:0'): # Try gpu.
labels = tf.reshape(labels, [-1, 1])
return tf.nn.sampled_softmax_loss(
weights=w_t, biases=v, labels=labels, inputs=inputs,
num_sampled=hps.num_softmax_samples, num_classes=vsize)
if hps.num_softmax_samples != 0 and hps.mode == 'train':
self._loss = seq2seq_lib.sampled_sequence_loss(
decoder_outputs, targets, loss_weights, sampled_loss_func)
else:
self._loss = tf.contrib.legacy_seq2seq.sequence_loss(
model_outputs, targets, loss_weights)
tf.summary.scalar('loss', tf.minimum(12.0, self._loss))
def _add_train_op(self):
"""Sets self._train_op, op to run for training."""
hps = self._hps
self._lr_rate = tf.maximum(
hps.min_lr, # min_lr_rate.
tf.train.exponential_decay(hps.lr, self.global_step, 30000, 0.98))
tvars = tf.trainable_variables()
with tf.device(self._get_gpu(self._num_gpus-1)):
grads, global_norm = tf.clip_by_global_norm(
tf.gradients(self._loss, tvars), hps.max_grad_norm)
tf.summary.scalar('global_norm', global_norm)
optimizer = tf.train.GradientDescentOptimizer(self._lr_rate)
tf.summary.scalar('learning rate', self._lr_rate)
self._train_op = optimizer.apply_gradients(
zip(grads, tvars), global_step=self.global_step, name='train_step')
def encode_top_state(self, sess, enc_inputs, enc_len):
"""Return the top states from encoder for decoder.
Args:
sess: tensorflow session.
enc_inputs: encoder inputs of shape [batch_size, enc_timesteps].
enc_len: encoder input length of shape [batch_size]
Returns:
enc_top_states: The top level encoder states.
dec_in_state: The decoder layer initial state.
"""
results = sess.run([self._enc_top_states, self._dec_in_state],
feed_dict={self._articles: enc_inputs,
self._article_lens: enc_len})
return results[0], results[1][0]
def decode_topk(self, sess, latest_tokens, enc_top_states, dec_init_states):
"""Return the topK results and new decoder states."""
feed = {
self._enc_top_states: enc_top_states,
self._dec_in_state:
np.squeeze(np.array(dec_init_states)),
self._abstracts:
np.transpose(np.array([latest_tokens])),
self._abstract_lens: np.ones([len(dec_init_states)], np.int32)}
results = sess.run(
[self._topk_ids, self._topk_log_probs, self._dec_out_state],
feed_dict=feed)
ids, probs, states = results[0], results[1], results[2]
new_states = [s for s in states]
return ids, probs, new_states
def build_graph(self):
self._add_placeholders()
self._add_seq2seq()
self.global_step = tf.Variable(0, name='global_step', trainable=False)
if self._hps.mode == 'train':
self._add_train_op()
self._summaries = tf.summary.merge_all()