import tarfile    import re    from helpers import download    class ImdbMovieReviews:        DEFAULT_URL =         ‘http://ai.stanford.edu/~amaas/data/sentiment/aclImdb_v1.tar.gz‘        TOKEN_REGEX = re.compile(r‘[A-Za-z]+|[!?.:,()]‘)    def __init__(self, cache_dir, url=None):        self._cache_dir = cache_dir        self._url = url or type(self).DEFAULT_URL        def __iter__(self):            filepath = download(self._url, self._cache_dir)            with tarfile.open(filepath) as archive:                for filename in archive.getnames():                    if filename.startswith(‘aclImdb/train/pos/‘):                        yield self._read(archive, filename), True                    elif filename.startswith(‘aclImdb/train/neg/‘):                        yield self._read(archive, filename), False        def _read(self, archive, filename):            with archive.extractfile(filename) as file_:                data = file_.read().decode(‘utf-8‘)                data = type(self).TOKEN_REGEX.findall(data)                data = [x.lower() for x in data]                return data    import bz2    import numpy as np    class Embedding:        def __init__(self, vocabulary_path, embedding_path, length):            self._embedding = np.load(embedding_path)            with bz2.open(vocabulary_path, ‘rt‘) as file_:                self._vocabulary = {k.strip(): i for i, k in enumerate(file_)}            self._length = length        def __call__(self, sequence):            data = np.zeros((self._length, self._embedding.shape[1]))            indices = [self._vocabulary.get(x, 0) for x in sequence]            embedded = self._embedding[indices]            data[:len(sequence)] = embedded            return data        @property        def dimensions(self):            return self._embedding.shape[1]    import tensorflow as tf    from helpers import lazy_property    class SequenceClassificationModel:        def __init__(self, data, target, params):            self.data = data            self.target = target            self.params = params            self.prediction            self.cost            self.error            self.optimize        @lazy_property        def length(self):            used = tf.sign(tf.reduce_max(tf.abs(self.data), reduction_indices=2))            length = tf.reduce_sum(used, reduction_indices=1)            length = tf.cast(length, tf.int32)            return length        @lazy_property        def prediction(self):            # Recurrent network.            output, _ = tf.nn.dynamic_rnn(                self.params.rnn_cell(self.params.rnn_hidden),                self.data,                dtype=tf.float32,                sequence_length=self.length,            )            last = self._last_relevant(output, self.length)            # Softmax layer.            num_classes = int(self.target.get_shape()[1])            weight = tf.Variable(tf.truncated_normal(                [self.params.rnn_hidden, num_classes], stddev=0.01))            bias = tf.Variable(tf.constant(0.1, shape=[num_classes]))            prediction = tf.nn.softmax(tf.matmul(last, weight) + bias)            return prediction        @lazy_property        def cost(self):            cross_entropy = -tf.reduce_sum(self.target * tf.log(self.prediction))            return cross_entropy        @lazy_property        def error(self):            mistakes = tf.not_equal(                tf.argmax(self.target, 1), tf.argmax(self.prediction, 1))            return tf.reduce_mean(tf.cast(mistakes, tf.float32))        @lazy_property        def optimize(self):            gradient = self.params.optimizer.compute_gradients(self.cost)            try:                limit = self.params.gradient_clipping                gradient = [                    (tf.clip_by_value(g, -limit, limit), v)                    if g is not None else (None, v)                    for g, v in gradient]            except AttributeError:                print(‘No gradient clipping parameter specified.‘)            optimize = self.params.optimizer.apply_gradients(gradient)            return optimize        @staticmethod        def _last_relevant(output, length):            batch_size = tf.shape(output)[0]            max_length = int(output.get_shape()[1])            output_size = int(output.get_shape()[2])            index = tf.range(0, batch_size) * max_length + (length - 1)            flat = tf.reshape(output, [-1, output_size])            relevant = tf.gather(flat, index)            return relevant    import tensorflow as tf    from helpers import AttrDict    from Embedding import Embedding    from ImdbMovieReviews import ImdbMovieReviews    from preprocess_batched import preprocess_batched    from SequenceClassificationModel import SequenceClassificationModel    IMDB_DOWNLOAD_DIR = ‘./imdb‘    WIKI_VOCAB_DIR = ‘../01_wikipedia/wikipedia‘    WIKI_EMBED_DIR = ‘../01_wikipedia/wikipedia‘    params = AttrDict(        rnn_cell=tf.contrib.rnn.GRUCell,        rnn_hidden=300,        optimizer=tf.train.RMSPropOptimizer(0.002),        batch_size=20,    )    reviews = ImdbMovieReviews(IMDB_DOWNLOAD_DIR)    length = max(len(x[0]) for x in reviews)    embedding = Embedding(        WIKI_VOCAB_DIR + ‘/vocabulary.bz2‘,        WIKI_EMBED_DIR + ‘/embeddings.npy‘, length)    batches = preprocess_batched(reviews, length, embedding, params.batch_size)    data = tf.placeholder(tf.float32, [None, length, embedding.dimensions])    target = tf.placeholder(tf.float32, [None, 2])    model = SequenceClassificationModel(data, target, params)    sess = tf.Session()    sess.run(tf.initialize_all_variables())    for index, batch in enumerate(batches):        feed = {data: batch[0], target: batch[1]}        error, _ = sess.run([model.error, model.optimize], feed)        print(‘{}: {:3.1f}%‘.format(index + 1, 100 * error))