. 数据集

. 模型设计

. 训练

from keras.datasets import imdb

(X_train, y_train), (X_test, y_test) = imdb.load_data(path="imdb_full.pkl",

                                                      nb_words=None,

                                                      skip_top=,

                                                      maxlen=None,

                                                      test_split=0.1)

                                                      seed=,

                                                      start_char=,

                                                      oov_char=,

                                                      index_from=)

. path：如果你在本机上已有此数据集（位于'~/.keras/datasets/'+path），则载入。否则数据将下载到该目录下

. nb_words：整数或None，要考虑的最常见的单词数，任何出现频率更低的单词将会被编码到0的位置。

. skip_top：整数，忽略最常出现的若干单词，这些单词将会被编码为0

. maxlen：整数，最大序列长度，任何长度大于此值的序列将被截断

. seed：整数，用于数据重排的随机数种子

. start_char：字符，序列的起始将以该字符标记，默认为1因为0通常用作padding

. oov_char：字符，因nb_words或skip_top限制而cut掉的单词将被该字符代替

. index_from：整数，真实的单词（而不是类似于start_char的特殊占位符）将从这个下标开始

X_train和X_test：序列的列表，每个序列都是词下标的列表。如果指定了nb_words，则序列中可能的最大下标为nb_words-。如果指定了maxlen，则序列的最大可能长度为maxlen

y_train和y_test：为序列的标签，是一个二值list

X_train[]

[, , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , ]

y_train[]

if ngram_range > :

    print('Adding {}-gram features'.format(ngram_range))

    # Create set of unique n-gram from the training set.

    ngram_set = set()

    for input_list in X_train:

        for i in range(, ngram_range + ):

            set_of_ngram = create_ngram_set(input_list, ngram_value=i)

            ngram_set.update(set_of_ngram)

    print('ngram_set.pop')

    print(ngram_set.pop())

X_train shape: (, )

X_test shape: (, )

https://github.com/fchollet/keras/blob/master/examples/imdb_fasttext.py

model.add(Embedding(max_features,

                    embedding_dims,

                    input_length=maxlen))

model.add(GlobalAveragePooling1D())

https://keras-cn.readthedocs.io/en/latest/layers/embedding_layer/

http://www.cnblogs.com/bzjia-blog/p/3415790.html

https://keras-cn.readthedocs.io/en/latest/layers/pooling_layer/

'''This example demonstrates the use of fasttext for text classification

Based on Joulin et al's paper:

Bags of Tricks for Efficient Text Classification

https://arxiv.org/abs/1607.01759

Results on IMDB datasets with uni and bi-gram embeddings:

    Uni-gram: 0.8813 test accuracy after  epochs. 8s/epoch on i7 cpu.

    Bi-gram : 0.9056 test accuracy after  epochs. 2s/epoch on GTX 980M gpu.

'''

from __future__ import print_function

import numpy as np

np.random.seed()  # for reproducibility

from keras.preprocessing import sequence

from keras.models import Sequential

from keras.layers import Dense

from keras.layers import Embedding

from keras.layers import GlobalAveragePooling1D

from keras.datasets import imdb

def create_ngram_set(input_list, ngram_value=):

    """

    Extract a set of n-grams from a list of integers.

    >>> create_ngram_set([, , , , , ], ngram_value=)

    {(, ), (, ), (, ), (, )}

    >>> create_ngram_set([, , , , , ], ngram_value=)

    [(, , ), (, , ), (, , ), (, , )]

    """

    return set(zip(*[input_list[i:] for i in range(ngram_value)]))

def add_ngram(sequences, token_indice, ngram_range=):

    """

    Augment the input list of list (sequences) by appending n-grams values.

    Example: adding bi-gram

    >>> sequences = [[, , , ], [, , , , ]]

    >>> token_indice = {(, ): , (, ): , (, ): }

    >>> add_ngram(sequences, token_indice, ngram_range=)

    [[, , , , , ], [, , , , , , ]]

    Example: adding tri-gram

    >>> sequences = [[, , , ], [, , , , ]]

    >>> token_indice = {(, ): , (, ): , (, ): , (, , ): }

    >>> add_ngram(sequences, token_indice, ngram_range=)

    [[, , , , ], [, , , , , , ]]

    """

    new_sequences = []

    for input_list in sequences:

        new_list = input_list[:]

        for i in range(len(new_list) - ngram_range + ):

            for ngram_value in range(, ngram_range + ):

                ngram = tuple(new_list[i:i + ngram_value])

                if ngram in token_indice:

                    new_list.append(token_indice[ngram])

        new_sequences.append(new_list)

    return new_sequences

# Set parameters:

# ngram_range =  will add bi-grams features

ngram_range =

max_features =

maxlen =

batch_size =

embedding_dims =

nb_epoch = 

print('Loading data...')

(X_train, y_train), (X_test, y_test) = imdb.load_data(

    path="/home/zhenghan/keras/imdb_full.pkl",

    nb_words=max_features

)

# truncate the dataset

truncate_rate = 0.4

X_train = X_train[:int(len(X_train) * truncate_rate)]

y_train = y_train[:int(len(y_train) * truncate_rate)]

X_test = X_test[:int(len(X_test) * truncate_rate)]

y_test = y_test[:int(len(y_test) * truncate_rate)]

print("X_train[0]")

print(X_train[])

print('y_train[0]')

print(y_train[])

print(len(X_train), 'train sequences')

print(len(X_test), 'test sequences')

print('Average train sequence length: {}'.format(np.mean(list(map(len, X_train)), dtype=int)))

print('Average test sequence length: {}'.format(np.mean(list(map(len, X_test)), dtype=int)))

if ngram_range > :

    print('Adding {}-gram features'.format(ngram_range))

    # Create set of unique n-gram from the training set.

    ngram_set = set()

    for input_list in X_train:

        for i in range(, ngram_range + ):

            set_of_ngram = create_ngram_set(input_list, ngram_value=i)

            ngram_set.update(set_of_ngram)

    print('ngram_set.pop')

    print(ngram_set.pop())

    # Dictionary mapping n-gram token to a unique integer.

    # Integer values are greater than max_features in order

    # to avoid collision with existing features.

    start_index = max_features +

    token_indice = {v: k + start_index for k, v in enumerate(ngram_set)}

    indice_token = {token_indice[k]: k for k in token_indice}

    # max_features is the highest integer that could be found in the dataset.

    max_features = np.max(list(indice_token.keys())) +

    print('max_features: ')

    print(max_features)

    # Augmenting X_train and X_test with n-grams features

    X_train = add_ngram(X_train, token_indice, ngram_range)

    X_test = add_ngram(X_test, token_indice, ngram_range)

    print("X_train[0]")

    print(X_train[])

    print('X_test[0]')

    print(X_test[])

    print('Average train sequence length: {}'.format(np.mean(list(map(len, X_train)), dtype=int)))

    print('Average test sequence length: {}'.format(np.mean(list(map(len, X_test)), dtype=int)))

print('Pad sequences (samples x time)')

X_train = sequence.pad_sequences(X_train, maxlen=maxlen)

X_test = sequence.pad_sequences(X_test, maxlen=maxlen)

print('X_train shape:', X_train.shape)

print('X_test shape:', X_test.shape)

print('Build model...')

model = Sequential()

# we start off with an efficient embedding layer which maps

# our vocab indices into embedding_dims dimensions

model.add(Embedding(max_features,

                    embedding_dims,

                    input_length=maxlen))

# we add a GlobalAveragePooling1D, which will average the embeddings

# of all words in the document

model.add(GlobalAveragePooling1D())

# We project onto a single unit output layer, and squash it with a sigmoid:

model.add(Dense(, activation='sigmoid'))

model.compile(loss='binary_crossentropy',

              optimizer='adam',

              metrics=['accuracy'])

model.fit(X_train, y_train,

          batch_size=batch_size,

          nb_epoch=nb_epoch,

          validation_data=(X_test, y_test))

https://keras-cn.readthedocs.io/en/latest/other/datasets/

https://keras-cn.readthedocs.io/en/latest/preprocessing/sequence/