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word2vec_optimized.py
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word2vec_optimized.py
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# 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.
# ==============================================================================
"""Multi-threaded word2vec unbatched skip-gram model.
Trains the model described in:
(Mikolov, et. al.) Efficient Estimation of Word Representations in Vector Space
ICLR 2013.
http://arxiv.org/abs/1301.3781
This model does true SGD (i.e. no minibatching). To do this efficiently, custom
ops are used to sequentially process data within a 'batch'.
The key ops used are:
* skipgram custom op that does input processing.
* neg_train custom op that efficiently calculates and applies the gradient using
true SGD.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import os
import sys
import threading
import time
from six.moves import xrange # pylint: disable=redefined-builtin
import numpy as np
import tensorflow as tf
from tensorflow.models.embedding import gen_word2vec as word2vec
flags = tf.app.flags
flags.DEFINE_string("save_path", None, "Directory to write the model.")
flags.DEFINE_string(
"train_data", None,
"Training data. E.g., unzipped file http://mattmahoney.net/dc/text8.zip.")
flags.DEFINE_string(
"eval_data", None, "Analogy questions. "
"See README.md for how to get 'questions-words.txt'.")
flags.DEFINE_integer("embedding_size", 200, "The embedding dimension size.")
flags.DEFINE_integer(
"epochs_to_train", 15,
"Number of epochs to train. Each epoch processes the training data once "
"completely.")
flags.DEFINE_float("learning_rate", 0.025, "Initial learning rate.")
flags.DEFINE_integer("num_neg_samples", 25,
"Negative samples per training example.")
flags.DEFINE_integer("batch_size", 500,
"Numbers of training examples each step processes "
"(no minibatching).")
flags.DEFINE_integer("concurrent_steps", 12,
"The number of concurrent training steps.")
flags.DEFINE_integer("window_size", 5,
"The number of words to predict to the left and right "
"of the target word.")
flags.DEFINE_integer("min_count", 5,
"The minimum number of word occurrences for it to be "
"included in the vocabulary.")
flags.DEFINE_float("subsample", 1e-3,
"Subsample threshold for word occurrence. Words that appear "
"with higher frequency will be randomly down-sampled. Set "
"to 0 to disable.")
flags.DEFINE_boolean(
"interactive", False,
"If true, enters an IPython interactive session to play with the trained "
"model. E.g., try model.analogy(b'france', b'paris', b'russia') and "
"model.nearby([b'proton', b'elephant', b'maxwell'])")
FLAGS = flags.FLAGS
class Options(object):
"""Options used by our word2vec model."""
def __init__(self):
# Model options.
# Embedding dimension.
self.emb_dim = FLAGS.embedding_size
# Training options.
# The training text file.
self.train_data = FLAGS.train_data
# Number of negative samples per example.
self.num_samples = FLAGS.num_neg_samples
# The initial learning rate.
self.learning_rate = FLAGS.learning_rate
# Number of epochs to train. After these many epochs, the learning
# rate decays linearly to zero and the training stops.
self.epochs_to_train = FLAGS.epochs_to_train
# Concurrent training steps.
self.concurrent_steps = FLAGS.concurrent_steps
# Number of examples for one training step.
self.batch_size = FLAGS.batch_size
# The number of words to predict to the left and right of the target word.
self.window_size = FLAGS.window_size
# The minimum number of word occurrences for it to be included in the
# vocabulary.
self.min_count = FLAGS.min_count
# Subsampling threshold for word occurrence.
self.subsample = FLAGS.subsample
# Where to write out summaries.
self.save_path = FLAGS.save_path
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
# Eval options.
# The text file for eval.
self.eval_data = FLAGS.eval_data
class Word2Vec(object):
"""Word2Vec model (Skipgram)."""
def __init__(self, options, session):
self._options = options
self._session = session
self._word2id = {}
self._id2word = []
self.build_graph()
self.build_eval_graph()
self.save_vocab()
def read_analogies(self):
"""Reads through the analogy question file.
Returns:
questions: a [n, 4] numpy array containing the analogy question's
word ids.
questions_skipped: questions skipped due to unknown words.
"""
questions = []
questions_skipped = 0
with open(self._options.eval_data, "rb") as analogy_f:
for line in analogy_f:
if line.startswith(b":"): # Skip comments.
continue
words = line.strip().lower().split(b" ")
ids = [self._word2id.get(w.strip()) for w in words]
if None in ids or len(ids) != 4:
questions_skipped += 1
else:
questions.append(np.array(ids))
print("Eval analogy file: ", self._options.eval_data)
print("Questions: ", len(questions))
print("Skipped: ", questions_skipped)
self._analogy_questions = np.array(questions, dtype=np.int32)
def build_graph(self):
"""Build the model graph."""
opts = self._options
# The training data. A text file.
(words, counts, words_per_epoch, current_epoch, total_words_processed,
examples, labels) = word2vec.skipgram(filename=opts.train_data,
batch_size=opts.batch_size,
window_size=opts.window_size,
min_count=opts.min_count,
subsample=opts.subsample)
(opts.vocab_words, opts.vocab_counts,
opts.words_per_epoch) = self._session.run([words, counts, words_per_epoch])
opts.vocab_size = len(opts.vocab_words)
print("Data file: ", opts.train_data)
print("Vocab size: ", opts.vocab_size - 1, " + UNK")
print("Words per epoch: ", opts.words_per_epoch)
self._id2word = opts.vocab_words
for i, w in enumerate(self._id2word):
self._word2id[w] = i
# Declare all variables we need.
# Input words embedding: [vocab_size, emb_dim]
w_in = tf.Variable(
tf.random_uniform(
[opts.vocab_size,
opts.emb_dim], -0.5 / opts.emb_dim, 0.5 / opts.emb_dim),
name="w_in")
# Global step: scalar, i.e., shape [].
w_out = tf.Variable(tf.zeros([opts.vocab_size, opts.emb_dim]), name="w_out")
# Global step: []
global_step = tf.Variable(0, name="global_step")
# Linear learning rate decay.
words_to_train = float(opts.words_per_epoch * opts.epochs_to_train)
lr = opts.learning_rate * tf.maximum(
0.0001,
1.0 - tf.cast(total_words_processed, tf.float32) / words_to_train)
# Training nodes.
inc = global_step.assign_add(1)
with tf.control_dependencies([inc]):
train = word2vec.neg_train(w_in,
w_out,
examples,
labels,
lr,
vocab_count=opts.vocab_counts.tolist(),
num_negative_samples=opts.num_samples)
self._w_in = w_in
self._examples = examples
self._labels = labels
self._lr = lr
self._train = train
self.global_step = global_step
self._epoch = current_epoch
self._words = total_words_processed
def save_vocab(self):
"""Save the vocabulary to a file so the model can be reloaded."""
opts = self._options
with open(os.path.join(opts.save_path, "vocab.txt"), "w") as f:
for i in xrange(opts.vocab_size):
vocab_word = tf.compat.as_text(opts.vocab_words[i]).encode("utf-8")
f.write("%s %d\n" % (vocab_word,
opts.vocab_counts[i]))
def build_eval_graph(self):
"""Build the evaluation graph."""
# Eval graph
opts = self._options
# Each analogy task is to predict the 4th word (d) given three
# words: a, b, c. E.g., a=italy, b=rome, c=france, we should
# predict d=paris.
# The eval feeds three vectors of word ids for a, b, c, each of
# which is of size N, where N is the number of analogies we want to
# evaluate in one batch.
analogy_a = tf.placeholder(dtype=tf.int32) # [N]
analogy_b = tf.placeholder(dtype=tf.int32) # [N]
analogy_c = tf.placeholder(dtype=tf.int32) # [N]
# Normalized word embeddings of shape [vocab_size, emb_dim].
nemb = tf.nn.l2_normalize(self._w_in, 1)
# Each row of a_emb, b_emb, c_emb is a word's embedding vector.
# They all have the shape [N, emb_dim]
a_emb = tf.gather(nemb, analogy_a) # a's embs
b_emb = tf.gather(nemb, analogy_b) # b's embs
c_emb = tf.gather(nemb, analogy_c) # c's embs
# We expect that d's embedding vectors on the unit hyper-sphere is
# near: c_emb + (b_emb - a_emb), which has the shape [N, emb_dim].
target = c_emb + (b_emb - a_emb)
# Compute cosine distance between each pair of target and vocab.
# dist has shape [N, vocab_size].
dist = tf.matmul(target, nemb, transpose_b=True)
# For each question (row in dist), find the top 4 words.
_, pred_idx = tf.nn.top_k(dist, 4)
# Nodes for computing neighbors for a given word according to
# their cosine distance.
nearby_word = tf.placeholder(dtype=tf.int32) # word id
nearby_emb = tf.gather(nemb, nearby_word)
nearby_dist = tf.matmul(nearby_emb, nemb, transpose_b=True)
nearby_val, nearby_idx = tf.nn.top_k(nearby_dist,
min(1000, opts.vocab_size))
# Nodes in the construct graph which are used by training and
# evaluation to run/feed/fetch.
self._analogy_a = analogy_a
self._analogy_b = analogy_b
self._analogy_c = analogy_c
self._analogy_pred_idx = pred_idx
self._nearby_word = nearby_word
self._nearby_val = nearby_val
self._nearby_idx = nearby_idx
# Properly initialize all variables.
tf.global_variables_initializer().run()
self.saver = tf.train.Saver()
def _train_thread_body(self):
initial_epoch, = self._session.run([self._epoch])
while True:
_, epoch = self._session.run([self._train, self._epoch])
if epoch != initial_epoch:
break
def train(self):
"""Train the model."""
opts = self._options
initial_epoch, initial_words = self._session.run([self._epoch, self._words])
workers = []
for _ in xrange(opts.concurrent_steps):
t = threading.Thread(target=self._train_thread_body)
t.start()
workers.append(t)
last_words, last_time = initial_words, time.time()
while True:
time.sleep(5) # Reports our progress once a while.
(epoch, step, words, lr) = self._session.run(
[self._epoch, self.global_step, self._words, self._lr])
now = time.time()
last_words, last_time, rate = words, now, (words - last_words) / (
now - last_time)
print("Epoch %4d Step %8d: lr = %5.3f words/sec = %8.0f\r" % (epoch, step,
lr, rate),
end="")
sys.stdout.flush()
if epoch != initial_epoch:
break
for t in workers:
t.join()
def _predict(self, analogy):
"""Predict the top 4 answers for analogy questions."""
idx, = self._session.run([self._analogy_pred_idx], {
self._analogy_a: analogy[:, 0],
self._analogy_b: analogy[:, 1],
self._analogy_c: analogy[:, 2]
})
return idx
def eval(self):
"""Evaluate analogy questions and reports accuracy."""
# How many questions we get right at precision@1.
correct = 0
try:
total = self._analogy_questions.shape[0]
except AttributeError as e:
raise AttributeError("Need to read analogy questions.")
start = 0
while start < total:
limit = start + 2500
sub = self._analogy_questions[start:limit, :]
idx = self._predict(sub)
start = limit
for question in xrange(sub.shape[0]):
for j in xrange(4):
if idx[question, j] == sub[question, 3]:
# Bingo! We predicted correctly. E.g., [italy, rome, france, paris].
correct += 1
break
elif idx[question, j] in sub[question, :3]:
# We need to skip words already in the question.
continue
else:
# The correct label is not the precision@1
break
print()
print("Eval %4d/%d accuracy = %4.1f%%" % (correct, total,
correct * 100.0 / total))
def analogy(self, w0, w1, w2):
"""Predict word w3 as in w0:w1 vs w2:w3."""
wid = np.array([[self._word2id.get(w, 0) for w in [w0, w1, w2]]])
idx = self._predict(wid)
for c in [self._id2word[i] for i in idx[0, :]]:
if c not in [w0, w1, w2]:
print(c)
break
print("unknown")
def nearby(self, words, num=20):
"""Prints out nearby words given a list of words."""
ids = np.array([self._word2id.get(x, 0) for x in words])
vals, idx = self._session.run(
[self._nearby_val, self._nearby_idx], {self._nearby_word: ids})
for i in xrange(len(words)):
print("\n%s\n=====================================" % (words[i]))
for (neighbor, distance) in zip(idx[i, :num], vals[i, :num]):
print("%-20s %6.4f" % (self._id2word[neighbor], distance))
def _start_shell(local_ns=None):
# An interactive shell is useful for debugging/development.
import IPython
user_ns = {}
if local_ns:
user_ns.update(local_ns)
user_ns.update(globals())
IPython.start_ipython(argv=[], user_ns=user_ns)
def main(_):
"""Train a word2vec model."""
if not FLAGS.train_data or not FLAGS.eval_data or not FLAGS.save_path:
print("--train_data --eval_data and --save_path must be specified.")
sys.exit(1)
opts = Options()
with tf.Graph().as_default(), tf.Session() as session:
with tf.device("/cpu:0"):
model = Word2Vec(opts, session)
model.read_analogies() # Read analogy questions
for _ in xrange(opts.epochs_to_train):
model.train() # Process one epoch
model.eval() # Eval analogies.
# Perform a final save.
model.saver.save(session, os.path.join(opts.save_path, "model.ckpt"),
global_step=model.global_step)
if FLAGS.interactive:
# E.g.,
# [0]: model.analogy(b'france', b'paris', b'russia')
# [1]: model.nearby([b'proton', b'elephant', b'maxwell'])
_start_shell(locals())
if __name__ == "__main__":
tf.app.run()