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multi_task_model.py
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multi_task_model.py
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# -*- coding: utf-8 -*-
"""
Created on Sun Feb 28 17:28:22 2016
@author: Bing Liu ([email protected])
Multi-task RNN model with an attention mechanism.
- Developped on top of the Tensorflow seq2seq_model.py example:
https://github.com/tensorflow/models/blob/master/tutorials/rnn/translate/seq2seq_model.py
- Note that this example code does not include output label dependency modeling.
One may add a loop function as in the rnn_decoder function in tensorflow
seq2seq.py example to feed emitted label embedding back to RNN state.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import random
import numpy as np
from six.moves import xrange # pylint: disable=redefined-builtin
import tensorflow as tf
import data_utils
import seq_labeling
import seq_classification
from tensorflow.contrib.rnn import BasicLSTMCell
from tensorflow.contrib.rnn import MultiRNNCell
from tensorflow.contrib.rnn import DropoutWrapper
from tensorflow.contrib.rnn import static_rnn
from tensorflow.contrib.rnn import static_bidirectional_rnn
class MultiTaskModel(object):
def __init__(self,
source_vocab_size,
tag_vocab_size,
label_vocab_size,
buckets,
word_embedding_size,
size,
num_layers,
max_gradient_norm,
batch_size,
dropout_keep_prob=1.0,
use_lstm=False,
bidirectional_rnn=True,
num_samples=1024,
use_attention=False,
task=None,
forward_only=False):
self.source_vocab_size = source_vocab_size
self.tag_vocab_size = tag_vocab_size
self.label_vocab_size = label_vocab_size
self.word_embedding_size = word_embedding_size
self.cell_size = size
self.num_layers = num_layers
self.buckets = buckets
self.batch_size = batch_size
self.bidirectional_rnn = bidirectional_rnn
self.global_step = tf.Variable(0, trainable=False)
# If we use sampled softmax, we need an output projection.
softmax_loss_function = None
# Create the internal multi-layer cell for our RNN.
def create_cell():
if not forward_only and dropout_keep_prob < 1.0:
single_cell = lambda: BasicLSTMCell(self.cell_size)
cell = MultiRNNCell([single_cell() for _ in range(self.num_layers)])
cell = DropoutWrapper(cell,
input_keep_prob=dropout_keep_prob,
output_keep_prob=dropout_keep_prob)
else:
single_cell = lambda: BasicLSTMCell(self.cell_size)
cell = MultiRNNCell([single_cell() for _ in range(self.num_layers)])
return cell
self.cell_fw = create_cell()
self.cell_bw = create_cell()
# Feeds for inputs.
self.encoder_inputs = []
self.tags = []
self.tag_weights = []
self.labels = []
self.sequence_length = tf.placeholder(tf.int32, [None],
name="sequence_length")
for i in xrange(buckets[-1][0]):
self.encoder_inputs.append(tf.placeholder(tf.int32, shape=[None],
name="encoder{0}".format(i)))
for i in xrange(buckets[-1][1]):
self.tags.append(tf.placeholder(tf.float32, shape=[None],
name="tag{0}".format(i)))
self.tag_weights.append(tf.placeholder(tf.float32, shape=[None],
name="weight{0}".format(i)))
self.labels.append(tf.placeholder(tf.float32, shape=[None], name="label"))
base_rnn_output = self.generate_rnn_output()
encoder_outputs, encoder_state, attention_states = base_rnn_output
if task['tagging'] == 1:
seq_labeling_outputs = seq_labeling.generate_sequence_output(
self.source_vocab_size,
encoder_outputs,
encoder_state,
self.tags,
self.sequence_length,
self.tag_vocab_size,
self.tag_weights,
buckets,
softmax_loss_function=softmax_loss_function,
use_attention=use_attention)
self.tagging_output, self.tagging_loss = seq_labeling_outputs
if task['intent'] == 1:
seq_intent_outputs = seq_classification.generate_single_output(
encoder_state,
attention_states,
self.sequence_length,
self.labels,
self.label_vocab_size,
buckets,
softmax_loss_function=softmax_loss_function,
use_attention=use_attention)
self.classification_output, self.classification_loss = seq_intent_outputs
if task['tagging'] == 1:
self.loss = self.tagging_loss
elif task['intent'] == 1:
self.loss = self.classification_loss
# Gradients and SGD update operation for training the model.
params = tf.trainable_variables()
if not forward_only:
opt = tf.train.AdamOptimizer()
if task['joint'] == 1:
# backpropagate the intent and tagging loss, one may further adjust
# the weights for the two costs.
gradients = tf.gradients([self.tagging_loss, self.classification_loss],
params)
elif task['tagging'] == 1:
gradients = tf.gradients(self.tagging_loss, params)
elif task['intent'] == 1:
gradients = tf.gradients(self.classification_loss, params)
clipped_gradients, norm = tf.clip_by_global_norm(gradients,
max_gradient_norm)
self.gradient_norm = norm
self.update = opt.apply_gradients(
zip(clipped_gradients, params), global_step=self.global_step)
self.saver = tf.train.Saver(tf.global_variables())
def generate_rnn_output(self):
"""
Generate RNN state outputs with word embeddings as inputs
"""
with tf.variable_scope("generate_seq_output"):
if self.bidirectional_rnn:
embedding = tf.get_variable("embedding",
[self.source_vocab_size,
self.word_embedding_size])
encoder_emb_inputs = list()
encoder_emb_inputs = [tf.nn.embedding_lookup(embedding, encoder_input)\
for encoder_input in self.encoder_inputs]
rnn_outputs = static_bidirectional_rnn(self.cell_fw,
self.cell_bw,
encoder_emb_inputs,
sequence_length=self.sequence_length,
dtype=tf.float32)
encoder_outputs, encoder_state_fw, encoder_state_bw = rnn_outputs
# with state_is_tuple = True, if num_layers > 1,
# here we simply use the state from last layer as the encoder state
state_fw = encoder_state_fw[-1]
state_bw = encoder_state_bw[-1]
encoder_state = tf.concat([tf.concat(state_fw, 1),
tf.concat(state_bw, 1)], 1)
top_states = [tf.reshape(e, [-1, 1, self.cell_fw.output_size \
+ self.cell_bw.output_size])
for e in encoder_outputs]
attention_states = tf.concat(top_states, 1)
else:
embedding = tf.get_variable("embedding",
[self.source_vocab_size,
self.word_embedding_size])
encoder_emb_inputs = list()
encoder_emb_inputs = [tf.nn.embedding_lookup(embedding, encoder_input)\
for encoder_input in self.encoder_inputs]
rnn_outputs = static_rnn(self.cell_fw,
encoder_emb_inputs,
sequence_length=self.sequence_length,
dtype=tf.float32)
encoder_outputs, encoder_state = rnn_outputs
# with state_is_tuple = True, if num_layers > 1,
# here we use the state from last layer as the encoder state
state = encoder_state[-1]
encoder_state = tf.concat(state, 1)
top_states = [tf.reshape(e, [-1, 1, self.cell_fw.output_size])
for e in encoder_outputs]
attention_states = tf.concat(top_states, 1)
return encoder_outputs, encoder_state, attention_states
def joint_step(self, session, encoder_inputs, tags, tag_weights,
labels, batch_sequence_length,
bucket_id, forward_only):
"""Run a step of the joint model feeding the given inputs.
Args:
session: tensorflow session to use.
encoder_inputs: list of numpy int vectors to feed as encoder inputs.
tags: list of numpy int vectors to feed as decoder inputs.
tag_weights: list of numpy float vectors to feed as tag weights.
labels: list of numpy int vectors to feed as sequence class labels.
bucket_id: which bucket of the model to use.
batch_sequence_length: batch_sequence_length
bucket_id: which bucket of the model to use.
forward_only: whether to do the backward step or only forward.
Returns:
A triple consisting of gradient norm (or None if we did not do backward),
average perplexity, output tags, and output class label.
Raises:
ValueError: if length of encoder_inputs, decoder_inputs, or
target_weights disagrees with bucket size for the specified bucket_id.
"""
# Check if the sizes match.
encoder_size, tag_size = self.buckets[bucket_id]
if len(encoder_inputs) != encoder_size:
raise ValueError("Encoder length must be equal to the one in bucket,"
" %d != %d." % (len(encoder_inputs), encoder_size))
if len(tags) != tag_size:
raise ValueError("Decoder length must be equal to the one in bucket,"
" %d != %d." % (len(tags), tag_size))
if len(labels) != 1:
raise ValueError("Decoder length must be equal to the one in bucket,"
" %d != %d." % (len(labels), 1))
input_feed = {}
input_feed[self.sequence_length.name] = batch_sequence_length
for l in xrange(encoder_size):
input_feed[self.encoder_inputs[l].name] = encoder_inputs[l]
input_feed[self.tags[l].name] = tags[l]
input_feed[self.tag_weights[l].name] = tag_weights[l]
input_feed[self.labels[0].name] = labels[0]
# Output feed: depends on whether we do a backward step or not.
if not forward_only:
output_feed = [self.update, # Update Op that does SGD.
self.gradient_norm, # Gradient norm.
self.loss] # Loss for this batch.
for i in range(tag_size):
output_feed.append(self.tagging_output[i])
output_feed.append(self.classification_output[0])
else:
output_feed = [self.loss]
for i in range(tag_size):
output_feed.append(self.tagging_output[i])
output_feed.append(self.classification_output[0])
outputs = session.run(output_feed, input_feed)
if not forward_only:
return outputs[1], outputs[2], outputs[3:3+tag_size], outputs[-1]
else:
return None, outputs[0], outputs[1:1+tag_size], outputs[-1]
def tagging_step(self, session, encoder_inputs, tags, tag_weights,
batch_sequence_length, bucket_id, forward_only):
"""Run a step of the tagging model feeding the given inputs.
Args:
session: tensorflow session to use.
encoder_inputs: list of numpy int vectors to feed as encoder inputs.
tags: list of numpy int vectors to feed as decoder inputs.
tag_weights: list of numpy float vectors to feed as target weights.
batch_sequence_length: batch_sequence_length
bucket_id: which bucket of the model to use.
forward_only: whether to do the backward step or only forward.
Returns:
A triple consisting of gradient norm (or None if we did not do backward),
average perplexity, and the output tags.
Raises:
ValueError: if length of encoder_inputs, decoder_inputs, or
target_weights disagrees with bucket size for the specified bucket_id.
"""
# Check if the sizes match.
encoder_size, tag_size = self.buckets[bucket_id]
if len(encoder_inputs) != encoder_size:
raise ValueError("Encoder length must be equal to the one in bucket,"
" %d != %d." % (len(encoder_inputs), encoder_size))
if len(tags) != tag_size:
raise ValueError("Decoder length must be equal to the one in bucket,"
" %d != %d." % (len(tags), tag_size))
# Input feed: encoder inputs, decoder inputs, target_weights, as provided.
input_feed = {}
input_feed[self.sequence_length.name] = batch_sequence_length
for l in xrange(encoder_size):
input_feed[self.encoder_inputs[l].name] = encoder_inputs[l]
input_feed[self.tags[l].name] = tags[l]
input_feed[self.tag_weights[l].name] = tag_weights[l]
# Output feed: depends on whether we do a backward step or not.
if not forward_only:
output_feed = [self.update, # Update Op that does SGD.
self.gradient_norm, # Gradient norm.
self.loss] # Loss for this batch.
for i in range(tag_size):
output_feed.append(self.tagging_output[i])
else:
output_feed = [self.loss]
for i in range(tag_size):
output_feed.append(self.tagging_output[i])
outputs = session.run(output_feed, input_feed)
if not forward_only:
return outputs[1], outputs[2], outputs[3:3+tag_size]
else:
return None, outputs[0], outputs[1:1+tag_size]
def classification_step(self, session, encoder_inputs, labels,
batch_sequence_length, bucket_id, forward_only):
"""Run a step of the intent classification model feeding the given inputs.
Args:
session: tensorflow session to use.
encoder_inputs: list of numpy int vectors to feed as encoder inputs.
labels: list of numpy int vectors to feed as sequence class labels.
batch_sequence_length: batch_sequence_length
bucket_id: which bucket of the model to use.
forward_only: whether to do the backward step or only forward.
Returns:
A triple consisting of gradient norm (or None if we did not do backward),
average perplexity, and the output class label.
Raises:
ValueError: if length of encoder_inputs, decoder_inputs, or
target_weights disagrees with bucket size for the specified bucket_id.
"""
# Check if the sizes match.
encoder_size, target_size = self.buckets[bucket_id]
if len(encoder_inputs) != encoder_size:
raise ValueError("Encoder length must be equal to the one in bucket,"
" %d != %d." % (len(encoder_inputs), encoder_size))
# Input feed: encoder inputs, decoder inputs, target_weights, as provided.
input_feed = {}
input_feed[self.sequence_length.name] = batch_sequence_length
for l in xrange(encoder_size):
input_feed[self.encoder_inputs[l].name] = encoder_inputs[l]
input_feed[self.labels[0].name] = labels[0]
# Output feed: depends on whether we do a backward step or not.
if not forward_only:
output_feed = [self.update, # Update Op that does SGD.
self.gradient_norm, # Gradient norm.
self.loss, # Loss for this batch.
self.classification_output[0]]
else:
output_feed = [self.loss,
self.classification_output[0],]
outputs = session.run(output_feed, input_feed)
if not forward_only:
return outputs[1], outputs[2], outputs[3] # Gradient norm, loss, outputs.
else:
return None, outputs[0], outputs[1] # No gradient norm, loss, outputs.
def get_batch(self, data, bucket_id):
"""Get a random batch of data from the specified bucket, prepare for step.
To feed data in step(..) it must be a list of batch-major vectors, while
data here contains single length-major cases. So the main logic of this
function is to re-index data cases to be in the proper format for feeding.
Args:
data: a tuple of size len(self.buckets) in which each element contains
lists of pairs of input and output data that we use to create a batch.
bucket_id: integer, which bucket to get the batch for.
Returns:
The triple (encoder_inputs, decoder_inputs, target_weights) for
the constructed batch that has the proper format to call step(...) later.
"""
encoder_size, decoder_size = self.buckets[bucket_id]
encoder_inputs, decoder_inputs, labels = [], [], []
# Get a random batch of encoder and decoder inputs from data,
# pad them if needed, reverse encoder inputs and add GO to decoder.
batch_sequence_length_list= list()
for _ in xrange(self.batch_size):
encoder_input, decoder_input, label = random.choice(data[bucket_id])
batch_sequence_length_list.append(len(encoder_input))
# Encoder inputs are padded and then reversed.
encoder_pad = [data_utils.PAD_ID] * (encoder_size - len(encoder_input))
#encoder_inputs.append(list(reversed(encoder_input + encoder_pad)))
encoder_inputs.append(list(encoder_input + encoder_pad))
# Decoder inputs get an extra "GO" symbol, and are padded then.
decoder_pad_size = decoder_size - len(decoder_input)
decoder_inputs.append(decoder_input +
[data_utils.PAD_ID] * decoder_pad_size)
labels.append(label)
# Now we create batch-major vectors from the data selected above.
batch_encoder_inputs = []
batch_decoder_inputs = []
batch_weights = []
batch_labels = []
# Batch encoder inputs are just re-indexed encoder_inputs.
for length_idx in xrange(encoder_size):
batch_encoder_inputs.append(
np.array([encoder_inputs[batch_idx][length_idx]
for batch_idx in xrange(self.batch_size)], dtype=np.int32))
# Batch decoder inputs are re-indexed decoder_inputs, we create weights.
for length_idx in xrange(decoder_size):
batch_decoder_inputs.append(
np.array([decoder_inputs[batch_idx][length_idx]
for batch_idx in xrange(self.batch_size)], dtype=np.int32))
# Create target_weights to be 0 for targets that are padding.
batch_weight = np.ones(self.batch_size, dtype=np.float32)
for batch_idx in xrange(self.batch_size):
# We set weight to 0 if the corresponding target is a PAD symbol.
# The corresponding target is decoder_input shifted by 1 forward.
# if length_idx < decoder_size - 1:
# target = decoder_inputs[batch_idx][length_idx + 1]
# print (length_idx)
if decoder_inputs[batch_idx][length_idx] == data_utils.PAD_ID:
batch_weight[batch_idx] = 0.0
batch_weights.append(batch_weight)
batch_labels.append(
np.array([labels[batch_idx][0]
for batch_idx in xrange(self.batch_size)], dtype=np.int32))
batch_sequence_length = np.array(batch_sequence_length_list, dtype=np.int32)
return (batch_encoder_inputs, batch_decoder_inputs, batch_weights,
batch_sequence_length, batch_labels)
def get_one(self, data, bucket_id, sample_id):
"""Get a single sample data from the specified bucket, prepare for step.
To feed data in step(..) it must be a list of batch-major vectors, while
data here contains single length-major cases. So the main logic of this
function is to re-index data cases to be in the proper format for feeding.
Args:
data: a tuple of size len(self.buckets) in which each element contains
lists of pairs of input and output data that we use to create a batch.
bucket_id: integer, which bucket to get the batch for.
Returns:
The triple (encoder_inputs, decoder_inputs, target_weights) for
the constructed batch that has the proper format to call step(...) later.
"""
encoder_size, decoder_size = self.buckets[bucket_id]
encoder_inputs, decoder_inputs, labels = [], [], []
# Get a random batch of encoder and decoder inputs from data,
# pad them if needed, reverse encoder inputs and add GO to decoder.
batch_sequence_length_list= list()
#for _ in xrange(self.batch_size):
encoder_input, decoder_input, label = data[bucket_id][sample_id]
batch_sequence_length_list.append(len(encoder_input))
# Encoder inputs are padded and then reversed.
encoder_pad = [data_utils.PAD_ID] * (encoder_size - len(encoder_input))
#encoder_inputs.append(list(reversed(encoder_input + encoder_pad)))
encoder_inputs.append(list(encoder_input + encoder_pad))
# Decoder inputs get an extra "GO" symbol, and are padded then.
decoder_pad_size = decoder_size - len(decoder_input)
decoder_inputs.append(decoder_input +
[data_utils.PAD_ID] * decoder_pad_size)
labels.append(label)
# Now we create batch-major vectors from the data selected above.
batch_encoder_inputs = []
batch_decoder_inputs = []
batch_weights = []
batch_labels = []
# Batch encoder inputs are just re-indexed encoder_inputs.
for length_idx in xrange(encoder_size):
batch_encoder_inputs.append(
np.array([encoder_inputs[batch_idx][length_idx]
for batch_idx in xrange(1)], dtype=np.int32))
# Batch decoder inputs are re-indexed decoder_inputs, we create weights.
for length_idx in xrange(decoder_size):
batch_decoder_inputs.append(
np.array([decoder_inputs[batch_idx][length_idx]
for batch_idx in xrange(1)], dtype=np.int32))
# Create target_weights to be 0 for targets that are padding.
batch_weight = np.ones(1, dtype=np.float32)
for batch_idx in xrange(1):
# We set weight to 0 if the corresponding target is a PAD symbol.
# The corresponding target is decoder_input shifted by 1 forward.
# if length_idx < decoder_size - 1:
# target = decoder_inputs[batch_idx][length_idx + 1]
# print (length_idx)
if decoder_inputs[batch_idx][length_idx] == data_utils.PAD_ID:
batch_weight[batch_idx] = 0.0
batch_weights.append(batch_weight)
batch_labels.append(
np.array([labels[batch_idx][0]
for batch_idx in xrange(1)], dtype=np.int32))
batch_sequence_length = np.array(batch_sequence_length_list, dtype=np.int32)
return (batch_encoder_inputs, batch_decoder_inputs, batch_weights,
batch_sequence_length, batch_labels)