from keras.preprocessing.sequence import pad_sequences from keras.preprocessing.text import Tokenizer from gensim.models import Word2Vec import numpy as np import gc def train_word2vec(documents, embedding_dim): """ train word2vector over training documents Args: documents (list): list of document embedding_dim (int): output wordvector size Returns: word_vectors(dict): dict containing words and their respective vectors """ model = Word2Vec(documents, min_count=1, size=embedding_dim) word_vectors = model.wv del model return word_vectors def create_embedding_matrix(tokenizer, word_vectors, embedding_dim): """ Create embedding matrix containing word indexes and respective vectors from word vectors Args: tokenizer (keras.preprocessing.text.Tokenizer): keras tokenizer object containing word indexes word_vectors (dict): dict containing word and their respective vectors embedding_dim (int): dimension of word vector Returns: """ nb_words = len(tokenizer.word_index) + 1 word_index = tokenizer.word_index embedding_matrix = np.zeros((nb_words, embedding_dim)) print("Embedding matrix shape: %s" % str(embedding_matrix.shape)) for word, i in word_index.items(): try: embedding_vector = word_vectors[word] if embedding_vector is not None: embedding_matrix[i] = embedding_vector except KeyError: print("vector not found for word - %s" % word) print('Null word embeddings: %d' % np.sum(np.sum(embedding_matrix, axis=1) == 0)) return embedding_matrix def word_embed_meta_data(documents, embedding_dim): """ Load tokenizer object for given vocabs list Args: documents (list): list of document embedding_dim (int): embedding dimension Returns: tokenizer (keras.preprocessing.text.Tokenizer): keras tokenizer object embedding_matrix (dict): dict with word_index and vector mapping """ documents = [str(x).lower().split() for x in documents] tokenizer = Tokenizer() tokenizer.fit_on_texts(documents) word_vector = train_word2vec(documents, embedding_dim) embedding_matrix = create_embedding_matrix(tokenizer, word_vector, embedding_dim) del word_vector gc.collect() return tokenizer, embedding_matrix def create_train_dev_set(tokenizer, sentences_pair, is_similar, max_sequence_length, validation_split_ratio): """ Create training and validation dataset Args: tokenizer (keras.preprocessing.text.Tokenizer): keras tokenizer object sentences_pair (list): list of tuple of sentences pairs is_similar (list): list containing labels if respective sentences in sentence1 and sentence2 are same or not (1 if same else 0) max_sequence_length (int): max sequence length of sentences to apply padding validation_split_ratio (float): contain ratio to split training data into validation data Returns: train_data_1 (list): list of input features for training set from sentences1 train_data_2 (list): list of input features for training set from sentences2 labels_train (np.array): array containing similarity score for training data leaks_train(np.array): array of training leaks features val_data_1 (list): list of input features for validation set from sentences1 val_data_2 (list): list of input features for validation set from sentences1 labels_val (np.array): array containing similarity score for validation data leaks_val (np.array): array of validation leaks features """ sentences1 = [x[0].lower() for x in sentences_pair] sentences2 = [x[1].lower() for x in sentences_pair] train_sequences_1 = tokenizer.texts_to_sequences(sentences1) train_sequences_2 = tokenizer.texts_to_sequences(sentences2) leaks = [[len(set(x1)), len(set(x2)), len(set(x1).intersection(x2))] for x1, x2 in zip(train_sequences_1, train_sequences_2)] train_padded_data_1 = pad_sequences(train_sequences_1, maxlen=max_sequence_length) train_padded_data_2 = pad_sequences(train_sequences_2, maxlen=max_sequence_length) train_labels = np.array(is_similar) leaks = np.array(leaks) shuffle_indices = np.random.permutation(np.arange(len(train_labels))) train_data_1_shuffled = train_padded_data_1[shuffle_indices] train_data_2_shuffled = train_padded_data_2[shuffle_indices] train_labels_shuffled = train_labels[shuffle_indices] leaks_shuffled = leaks[shuffle_indices] dev_idx = max(1, int(len(train_labels_shuffled) * validation_split_ratio)) del train_padded_data_1 del train_padded_data_2 gc.collect() train_data_1, val_data_1 = train_data_1_shuffled[:-dev_idx], train_data_1_shuffled[-dev_idx:] train_data_2, val_data_2 = train_data_2_shuffled[:-dev_idx], train_data_2_shuffled[-dev_idx:] labels_train, labels_val = train_labels_shuffled[:-dev_idx], train_labels_shuffled[-dev_idx:] leaks_train, leaks_val = leaks_shuffled[:-dev_idx], leaks_shuffled[-dev_idx:] return train_data_1, train_data_2, labels_train, leaks_train, val_data_1, val_data_2, labels_val, leaks_val def create_test_data(tokenizer, test_sentences_pair, max_sequence_length): """ Create training and validation dataset Args: tokenizer (keras.preprocessing.text.Tokenizer): keras tokenizer object test_sentences_pair (list): list of tuple of sentences pairs max_sequence_length (int): max sequence length of sentences to apply padding Returns: test_data_1 (list): list of input features for training set from sentences1 test_data_2 (list): list of input features for training set from sentences2 """ test_sentences1 = [str(x[0]).lower() for x in test_sentences_pair] test_sentences2 = [x[1].lower() for x in test_sentences_pair] test_sequences_1 = tokenizer.texts_to_sequences(test_sentences1) test_sequences_2 = tokenizer.texts_to_sequences(test_sentences2) leaks_test = [[len(set(x1)), len(set(x2)), len(set(x1).intersection(x2))] for x1, x2 in zip(test_sequences_1, test_sequences_2)] leaks_test = np.array(leaks_test) test_data_1 = pad_sequences(test_sequences_1, maxlen=max_sequence_length) test_data_2 = pad_sequences(test_sequences_2, maxlen=max_sequence_length) return test_data_1, test_data_2, leaks_test