2. 「対話ボット」学習ロジックの実装
参考2:Tensorflow: Sequence-to-Sequence Models に含まれる、models/rnn配下の以下の3つのソースコードを基に、「対話ボット」に必要な修正を加える。実行時のメインメソッドを含む translate.py をchatbot.pyとして修正を加えた。
| No. | src | description |
| 1 | translate/seq2seq_model.py | Neural translation sequence-to-sequence model. |
| 2 | translate/data_utils.py | Helper functions for preparing translation data. |
| 3 | translate/translate.py | Binary that trains and runs the translation model. |
学習ロジック関連で、プログラムに修正を加えた点は以下だけである。
2. data_utils.py に対して「(LINEトーク履歴から作成した)学習用データ」の読み込み部分にprepare_line_talk_dataメソッドを作成
3. chatbot.py に対してdata_utils.py内のprepare_line_talk_dataメソッドを呼び出すように修正
3. 「対話ボット」対話ロジックの実装
対話ロジック関連で、プログラムに修正を加えた点は以下だけである。
3. chatbot.py に対して、Decode時の日本語の形態素解析処理の追加
英仏翻訳のためのsequence-to-sequenceモデルに対して、これだけの修正を加えるだけで、「対話ボット」として利用可能となる。
最終的に、以下の3つのソースコードとdataディレクトリを同階層に配備するだけで動作する。
ソースコードを以下に示す。
[Source Code : data_utils.py]
# Copyright 2016 y-euda. All Rights Reserved.
# The following modifications are added based on tensorflow/models/rnn/translate/data_utils.py.
# - prepare_line_talk_data() is created to load LINE talk data text file.
#
#==============================================================================
# Copyright 2015 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.
# ==============================================================================
"""Utilities for downloading data from WMT, tokenizing, vocabularies."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import gzip
import os
import re
from tensorflow.python.platform import gfile
import tensorflow as tf
# Special vocabulary symbols - we always put them at the start.
_PAD = b"_PAD"
_GO = b"_GO"
_EOS = b"_EOS"
_UNK = b"_UNK"
_START_VOCAB = [_PAD, _GO, _EOS, _UNK]
PAD_ID = 0
GO_ID = 1
EOS_ID = 2
UNK_ID = 3
# Regular expressions used to tokenize.
_WORD_SPLIT = re.compile(b"([.,!?\"':;)(])")
_DIGIT_RE = re.compile(br"\d")
def gunzip_file(gz_path, new_path):
"""Unzips from gz_path into new_path."""
print("Unpacking %s to %s" % (gz_path, new_path))
with gzip.open(gz_path, "rb") as gz_file:
with open(new_path, "wb") as new_file:
for line in gz_file:
new_file.write(line)
def basic_tokenizer(sentence):
"""Very basic tokenizer: split the sentence into a list of tokens."""
words = []
for space_separated_fragment in sentence.strip().split():
words.extend(_WORD_SPLIT.split(space_separated_fragment))
return [w for w in words if w]
def create_vocabulary(vocabulary_path, data_path, max_vocabulary_size,
tokenizer=None, normalize_digits=True):
"""Create vocabulary file (if it does not exist yet) from data file.
Data file is assumed to contain one sentence per line. Each sentence is
tokenized and digits are normalized (if normalize_digits is set).
Vocabulary contains the most-frequent tokens up to max_vocabulary_size.
We write it to vocabulary_path in a one-token-per-line format, so that later
token in the first line gets id=0, second line gets id=1, and so on.
Args:
vocabulary_path: path where the vocabulary will be created.
data_path: data file that will be used to create vocabulary.
max_vocabulary_size: limit on the size of the created vocabulary.
tokenizer: a function to use to tokenize each data sentence;
if None, basic_tokenizer will be used.
normalize_digits: Boolean; if true, all digits are replaced by 0s.
"""
if not gfile.Exists(vocabulary_path):
print("Creating vocabulary %s from data %s" % (vocabulary_path, data_path))
vocab = {}
with gfile.GFile(data_path, mode="rb") as f:
counter = 0
for line in f:
counter += 1
if counter % 100000 == 0:
print(" processing line %d" % counter)
line = tf.compat.as_bytes(line)
tokens = tokenizer(line) if tokenizer else basic_tokenizer(line)
for w in tokens:
word = _DIGIT_RE.sub(b"0", w) if normalize_digits else w
if word in vocab:
vocab[word] += 1
else:
vocab[word] = 1
vocab_list = _START_VOCAB + sorted(vocab, key=vocab.get, reverse=True)
if len(vocab_list) > max_vocabulary_size:
vocab_list = vocab_list[:max_vocabulary_size]
with gfile.GFile(vocabulary_path, mode="wb") as vocab_file:
for w in vocab_list:
vocab_file.write(w + b"\n")
def initialize_vocabulary(vocabulary_path):
"""Initialize vocabulary from file.
We assume the vocabulary is stored one-item-per-line, so a file:
dog
cat
will result in a vocabulary {"dog": 0, "cat": 1}, and this function will
also return the reversed-vocabulary ["dog", "cat"].
Args:
vocabulary_path: path to the file containing the vocabulary.
Returns:
a pair: the vocabulary (a dictionary mapping string to integers), and
the reversed vocabulary (a list, which reverses the vocabulary mapping).
Raises:
ValueError: if the provided vocabulary_path does not exist.
"""
if gfile.Exists(vocabulary_path):
rev_vocab = []
with gfile.GFile(vocabulary_path, mode="rb") as f:
rev_vocab.extend(f.readlines())
rev_vocab = [line.strip() for line in rev_vocab]
vocab = dict([(x, y) for (y, x) in enumerate(rev_vocab)])
return vocab, rev_vocab
else:
raise ValueError("Vocabulary file %s not found.", vocabulary_path)
def sentence_to_token_ids(sentence, vocabulary,
tokenizer=None, normalize_digits=True):
"""Convert a string to list of integers representing token-ids.
For example, a sentence "I have a dog" may become tokenized into
["I", "have", "a", "dog"] and with vocabulary {"I": 1, "have": 2,
"a": 4, "dog": 7"} this function will return [1, 2, 4, 7].
Args:
sentence: the sentence in bytes format to convert to token-ids.
vocabulary: a dictionary mapping tokens to integers.
tokenizer: a function to use to tokenize each sentence;
if None, basic_tokenizer will be used.
normalize_digits: Boolean; if true, all digits are replaced by 0s.
Returns:
a list of integers, the token-ids for the sentence.
"""
if tokenizer:
words = tokenizer(sentence)
else:
words = basic_tokenizer(sentence)
if not normalize_digits:
return [vocabulary.get(w, UNK_ID) for w in words]
# Normalize digits by 0 before looking words up in the vocabulary.
return [vocabulary.get(_DIGIT_RE.sub(b"0", w), UNK_ID) for w in words]
def data_to_token_ids(data_path, target_path, vocabulary_path,
tokenizer=None, normalize_digits=True):
"""Tokenize data file and turn into token-ids using given vocabulary file.
This function loads data line-by-line from data_path, calls the above
sentence_to_token_ids, and saves the result to target_path. See comment
for sentence_to_token_ids on the details of token-ids format.
Args:
data_path: path to the data file in one-sentence-per-line format.
target_path: path where the file with token-ids will be created.
vocabulary_path: path to the vocabulary file.
tokenizer: a function to use to tokenize each sentence;
if None, basic_tokenizer will be used.
normalize_digits: Boolean; if true, all digits are replaced by 0s.
"""
if not gfile.Exists(target_path):
print("Tokenizing data in %s" % data_path)
vocab, _ = initialize_vocabulary(vocabulary_path)
with gfile.GFile(data_path, mode="rb") as data_file:
with gfile.GFile(target_path, mode="w") as tokens_file:
counter = 0
for line in data_file:
counter += 1
if counter % 100000 == 0:
print(" tokenizing line %d" % counter)
token_ids = sentence_to_token_ids(line, vocab, tokenizer,
normalize_digits)
tokens_file.write(" ".join([str(tok) for tok in token_ids]) + "\n")
def prepare_line_talk_data(data_dir, in_vocabulary_size, out_vocabulary_size, tokenizer=None):
"""Get line talk data into data_dir, create vocabularies and tokenize data.
Args:
data_dir: directory in which the data sets will be stored.
in_vocabulary_size: size of the Input vocabulary to create and use.
out_vocabulary_size: size of the Output vocabulary to create and use.
tokenizer: a function to use to tokenize each data sentence;
if None, basic_tokenizer will be used.
Returns:
A tuple of 6 elements:
(1) path to the token-ids for Input training data-set,
(2) path to the token-ids for Output training data-set,
(3) path to the token-ids for Input development data-set,
(4) path to the token-ids for Output development data-set,
(5) path to the Input vocabulary file,
(6) path to the Output vocabulary file.
"""
# Get line_talk data to the specified directory.
train_path = os.path.join(data_dir, "line_talk_train")
dev_path = os.path.join(data_dir, "line_talk_dev")
# Create vocabularies of the appropriate sizes.
out_vocab_path = os.path.join(data_dir, "vocab%d.out" % out_vocabulary_size )
in_vocab_path = os.path.join(data_dir, "vocab%d.in" % in_vocabulary_size )
create_vocabulary(out_vocab_path, train_path + ".out", out_vocabulary_size, tokenizer)
create_vocabulary(in_vocab_path, train_path + ".in", in_vocabulary_size, tokenizer)
# Create token ids for the training data.
out_train_ids_path = train_path + (".ids%d.out" % out_vocabulary_size)
in_train_ids_path = train_path + (".ids%d.in" % in_vocabulary_size)
data_to_token_ids(train_path + ".out", out_train_ids_path, out_vocab_path, tokenizer)
data_to_token_ids(train_path + ".in", in_train_ids_path, in_vocab_path, tokenizer)
# Create token ids for the development data.
out_dev_ids_path = dev_path + (".ids%d.out" % out_vocabulary_size)
in_dev_ids_path = dev_path + (".ids%d.in" % in_vocabulary_size)
data_to_token_ids(dev_path + ".out", out_dev_ids_path, out_vocab_path, tokenizer)
data_to_token_ids(dev_path + ".in", in_dev_ids_path, in_vocab_path, tokenizer)
return (in_train_ids_path, out_train_ids_path,
in_dev_ids_path, out_dev_ids_path,
in_vocab_path, out_vocab_path)
[Source Code : chatbot.py]
# Copyright 2016 y-euda. All Rights Reserved.
# The following modifications are added based on tensorflow/models/rnn/translate/translate.py.
# - train() is modified to load LINE talk data text file.
# - decode() is modifed for the input sentence in Japanese.
#
# ==============================================================================
# Copyright 2015 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.
# ==============================================================================
"""Binary for training seq2seq models and decoding from them.
Running this program without --decode will download the line talk corpus into
the directory specified as --data_dir and tokenize it in a very basic way,
and then start training a model saving checkpoints to --train_dir.
Running with --decode starts an interactive loop so you can see how
the current checkpoint translates English sentences into French.
See the following papers for more information on neural translation models.
* http://arxiv.org/abs/1409.3215
* http://arxiv.org/abs/1409.0473
* http://arxiv.org/abs/1412.2007
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import math
import os
import random
import sys
import time
import logging
import numpy as np
import tensorflow as tf
import data_utils as data_utils
import seq2seq_model as seq2seq_model
from janome.tokenizer import Tokenizer
tf.app.flags.DEFINE_float("learning_rate", 0.5, "Learning rate.")
tf.app.flags.DEFINE_float("learning_rate_decay_factor", 0.99,
"Learning rate decays by this much.")
tf.app.flags.DEFINE_float("max_gradient_norm", 5.0,
"Clip gradients to this norm.")
tf.app.flags.DEFINE_integer("batch_size", 4, #64
"Batch size to use during training.")
tf.app.flags.DEFINE_integer("size", 256, "Size of each model layer.") #1024
tf.app.flags.DEFINE_integer("num_layers", 3, "Number of layers in the model.") #3
tf.app.flags.DEFINE_integer("en_vocab_size", 40000, "English vocabulary size.") #40000
tf.app.flags.DEFINE_integer("fr_vocab_size", 40000, "French vocabulary size.") #40000
tf.app.flags.DEFINE_string("data_dir", "line_talk_data", "Data directory")#data
tf.app.flags.DEFINE_string("train_dir", "line_talk_train", "Training directory.")#train
tf.app.flags.DEFINE_integer("max_train_data_size", 0,
"Limit on the size of training data (0: no limit).")
tf.app.flags.DEFINE_integer("steps_per_checkpoint", 100,#200
"How many training steps to do per checkpoint.")
tf.app.flags.DEFINE_boolean("decode", False,
"Set to True for interactive decoding.")
tf.app.flags.DEFINE_boolean("self_test", False,
"Run a self-test if this is set to True.")
tf.app.flags.DEFINE_boolean("use_fp16", False,
"Train using fp16 instead of fp32.")
FLAGS = tf.app.flags.FLAGS
# We use a number of buckets and pad to the closest one for efficiency.
# See seq2seq_model.Seq2SeqModel for details of how they work.
_buckets = [(5, 10), (10, 15), (20, 25), (40, 50)]
def read_data(source_path, target_path, max_size=None):
"""Read data from source and target files and put into buckets.
Args:
source_path: path to the files with token-ids for the source language.
target_path: path to the file with token-ids for the target language;
it must be aligned with the source file: n-th line contains the desired
output for n-th line from the source_path.
max_size: maximum number of lines to read, all other will be ignored;
if 0 or None, data files will be read completely (no limit).
Returns:
data_set: a list of length len(_buckets); data_set[n] contains a list of
(source, target) pairs read from the provided data files that fit
into the n-th bucket, i.e., such that len(source) < _buckets[n][0] and
len(target) < _buckets[n][1]; source and target are lists of token-ids.
"""
data_set = [[] for _ in _buckets]
with tf.gfile.GFile(source_path, mode="r") as source_file:
with tf.gfile.GFile(target_path, mode="r") as target_file:
source, target = source_file.readline(), target_file.readline()
counter = 0
while source and target and (not max_size or counter < max_size):
counter += 1
if counter % 100000 == 0:
print(" reading data line %d" % counter)
sys.stdout.flush()
source_ids = [int(x) for x in source.split()]
target_ids = [int(x) for x in target.split()]
target_ids.append(data_utils.EOS_ID)
for bucket_id, (source_size, target_size) in enumerate(_buckets):
if len(source_ids) < source_size and len(target_ids) < target_size:
data_set[bucket_id].append([source_ids, target_ids])
break
source, target = source_file.readline(), target_file.readline()
return data_set
def create_model(session, forward_only):
"""Create chat model and initialize or load parameters in session."""
dtype = tf.float16 if FLAGS.use_fp16 else tf.float32
model = seq2seq_model.Seq2SeqModel(
FLAGS.en_vocab_size,
FLAGS.fr_vocab_size,
_buckets,
FLAGS.size,
FLAGS.num_layers,
FLAGS.max_gradient_norm,
FLAGS.batch_size,
FLAGS.learning_rate,
FLAGS.learning_rate_decay_factor,
forward_only=forward_only,
dtype=dtype)
ckpt = tf.train.get_checkpoint_state(FLAGS.train_dir)
if ckpt and tf.gfile.Exists(ckpt.model_checkpoint_path):
print("Reading model parameters from %s" % ckpt.model_checkpoint_path)
model.saver.restore(session, ckpt.model_checkpoint_path)
else:
print("Created model with fresh parameters.")
session.run(tf.initialize_all_variables())
return model
def train():
"""Train a in->out chat model using LINE talk data."""
# Prepare line talk data.
print("Preparing LINE talk data in %s" % FLAGS.data_dir)
in_train, out_train, in_dev, out_dev, _, _ = data_utils.prepare_line_talk_data(
FLAGS.data_dir, FLAGS.en_vocab_size, FLAGS.fr_vocab_size)
with tf.Session() as sess:
# Create model.
print("Creating %d layers of %d units." % (FLAGS.num_layers, FLAGS.size))
model = create_model(sess, False)
# Read data into buckets and compute their sizes.
print ("Reading development and training data (limit: %d)."
% FLAGS.max_train_data_size)
dev_set = read_data(in_dev, out_dev)
train_set = read_data(in_train, out_train, FLAGS.max_train_data_size)
train_bucket_sizes = [len(train_set[b]) for b in xrange(len(_buckets))]
train_total_size = float(sum(train_bucket_sizes))
# A bucket scale is a list of increasing numbers from 0 to 1 that we'll use
# to select a bucket. Length of [scale[i], scale[i+1]] is proportional to
# the size if i-th training bucket, as used later.
train_buckets_scale = [sum(train_bucket_sizes[:i + 1]) / train_total_size
for i in xrange(len(train_bucket_sizes))]
# This is the training loop.
step_time, loss = 0.0, 0.0
current_step = 0
previous_losses = []
while True:
# Choose a bucket according to data distribution. We pick a random number
# in [0, 1] and use the corresponding interval in train_buckets_scale.
random_number_01 = np.random.random_sample()
bucket_id = min([i for i in xrange(len(train_buckets_scale))
if train_buckets_scale[i] > random_number_01])
# Get a batch and make a step.
start_time = time.time()
encoder_inputs, decoder_inputs, target_weights = model.get_batch(
train_set, bucket_id)
_, step_loss, _ = model.step(sess, encoder_inputs, decoder_inputs,
target_weights, bucket_id, False)
step_time += (time.time() - start_time) / FLAGS.steps_per_checkpoint
loss += step_loss / FLAGS.steps_per_checkpoint
current_step += 1
# Once in a while, we save checkpoint, print statistics, and run evals.
if current_step % FLAGS.steps_per_checkpoint == 0:
# Print statistics for the previous epoch.
perplexity = math.exp(float(loss)) if loss < 300 else float("inf")
print ("global step %d learning rate %.4f step-time %.2f perplexity "
"%.2f" % (model.global_step.eval(), model.learning_rate.eval(),
step_time, perplexity))
# Decrease learning rate if no improvement was seen over last 3 times.
if len(previous_losses) > 2 and loss > max(previous_losses[-3:]):
sess.run(model.learning_rate_decay_op)
previous_losses.append(loss)
# Save checkpoint and zero timer and loss.
checkpoint_path = os.path.join(FLAGS.train_dir, "chatbot.ckpt")
model.saver.save(sess, checkpoint_path, global_step=model.global_step)
step_time, loss = 0.0, 0.0
# Run evals on development set and print their perplexity.
for bucket_id in xrange(len(_buckets)):
if len(dev_set[bucket_id]) == 0:
print(" eval: empty bucket %d" % (bucket_id))
continue
encoder_inputs, decoder_inputs, target_weights = model.get_batch(
dev_set, bucket_id)
_, eval_loss, _ = model.step(sess, encoder_inputs, decoder_inputs,
target_weights, bucket_id, True)
eval_ppx = math.exp(float(eval_loss)) if eval_loss < 300 else float(
"inf")
print(" eval: bucket %d perplexity %.2f" % (bucket_id, eval_ppx))
sys.stdout.flush()
#--decode --data_dir line_talk_data --train_dir line_talk_data
def decode():
with tf.Session() as sess:
# Create model and load parameters.
model = create_model(sess, True)
model.batch_size = 1 # We decode one sentence at a time.
# Load vocabularies.
en_vocab_path = os.path.join(FLAGS.data_dir,
"vocab%d.in" % FLAGS.en_vocab_size)
fr_vocab_path = os.path.join(FLAGS.data_dir,
"vocab%d.out" % FLAGS.fr_vocab_size)
en_vocab, _ = data_utils.initialize_vocabulary(en_vocab_path)
_, rev_fr_vocab = data_utils.initialize_vocabulary(fr_vocab_path)
# Decode from standard input.
sys.stdout.write("> ")
sys.stdout.flush()
sentence = sys.stdin.readline()
t = Tokenizer()
tokens = t.tokenize(sentence.decode('utf-8'))
sentence = ' '.join([token.surface for token in tokens]).encode('utf-8')
print('([Morpho]:'+ sentence +')')
while sentence:
# Get token-ids for the input sentence.
token_ids = data_utils.sentence_to_token_ids(tf.compat.as_bytes(sentence), en_vocab)
# Which bucket does it belong to?
bucket_id = len(_buckets) - 1
for i, bucket in enumerate(_buckets):
if bucket[0] >= len(token_ids):
bucket_id = i
break
else:
logging.warning("Sentence truncated: %s", sentence)
# Get a 1-element batch to feed the sentence to the model.
encoder_inputs, decoder_inputs, target_weights = model.get_batch(
{bucket_id: [(token_ids, [])]}, bucket_id)
# Get output logits for the sentence.
_, _, output_logits = model.step(sess, encoder_inputs, decoder_inputs,
target_weights, bucket_id, True)
# This is a greedy decoder - outputs are just argmaxes of output_logits.
outputs = [int(np.argmax(logit, axis=1)) for logit in output_logits]
# If there is an EOS symbol in outputs, cut them at that point.
if data_utils.EOS_ID in outputs:
outputs = outputs[:outputs.index(data_utils.EOS_ID)]
# Print out French sentence corresponding to outputs.
print(" ".join([tf.compat.as_str(rev_fr_vocab[output]) for output in outputs]))
print("> ", end="")
sys.stdout.flush()
sentence = sys.stdin.readline()
t = Tokenizer()
tokens = t.tokenize(sentence.decode('utf-8'))
sentence = ' '.join([token.surface for token in tokens]).encode('utf-8')
print('([Morpho]:'+ sentence +')')
def self_test():
"""Test the translation model."""
with tf.Session() as sess:
print("Self-test for neural translation model.")
# Create model with vocabularies of 10, 2 small buckets, 2 layers of 32.
model = seq2seq_model.Seq2SeqModel(10, 10, [(3, 3), (6, 6)], 32, 2,
5.0, 32, 0.3, 0.99, num_samples=8)
sess.run(tf.initialize_all_variables())
# Fake data set for both the (3, 3) and (6, 6) bucket.
data_set = ([([1, 1], [2, 2]), ([3, 3], [4]), ([5], [6])],
[([1, 1, 1, 1, 1], [2, 2, 2, 2, 2]), ([3, 3, 3], [5, 6])])
for _ in xrange(5): # Train the fake model for 5 steps.
bucket_id = random.choice([0, 1])
encoder_inputs, decoder_inputs, target_weights = model.get_batch(
data_set, bucket_id)
model.step(sess, encoder_inputs, decoder_inputs, target_weights,
bucket_id, False)
def main(_):
if FLAGS.self_test:
self_test()
elif FLAGS.decode:
decode()
else:
train()
if __name__ == "__main__":
tf.app.run()
話題のTensorFlow・LINEトーク履歴を用いて対話ボットを作ってみた(1)
話題のTensorFlow・LINEトーク履歴を用いて対話ボットを作ってみた(2)
話題のTensorFlow・LINEトーク履歴を用いて対話ボットを作ってみた(3)
話題のTensorFlow・LINEトーク履歴を用いて対話ボットを作ってみた(5)
