def infer():
tar_id2vocab, BOS_ID, EOS_ID = get_vocab(args.dataset, args.batch_size)
vocab_size = len(tar_id2vocab)
print(args)
net = VAESeq2SeqInferModel(args.embed_dim, args.hidden_size,
args.latent_size, vocab_size)
model = paddle.Model(net)
model.prepare()
model.load(args.init_from_ckpt)
infer_output = paddle.ones((args.batch_size, 1), dtype='int64') * BOS_ID
space_token = ' '
line_token = '\n'
with io.open(args.infer_output_file, 'w', encoding='utf-8') as out_file:
predict_lines = model.predict_batch(infer_output)[0]
for line in predict_lines:
end_id = -1
if EOS_ID in line:
end_id = np.where(line == EOS_ID)[0][0]
new_line = [tar_id2vocab[e[0]] for e in line[:end_id]]
out_file.write(space_token.join(new_line))
out_file.write(line_token)
def build_text():
iw,vocab,_=get_vocab()
with open(text_path,'w',encoding='utf-8') as f:
data=load_data()
for post,resp in data:
post=" ".join(tokenize(post[0],vocab=vocab))
resp=" ".join(tokenize(resp[0],vocab=vocab))
f.write(post+"\t"+resp+"\n")
def get_embedding():
emb_path="datasets/temp/embedding.np"
if os.path.exists(emb_path):
return np.load(open(emb_path,'rb'))
else:
model=KeyedVectors.load_word2vec_format(model_path,binary=True)
iw,vocab,_=get_vocab()
size=len(list(vocab.keys()))
emb=np.zeros(shape=[size,emb_dim])
for word,index in vocab.items():
if index in [0,1] or word not in model.vocab:
continue
emb[index]=model[word]
np.save(open(emb_path,"wb"),emb)
return emb
def __init__(self, args):
super(DCTTS, self).__init__()
self.args = args
self.embed = nn.Embedding(len(data.get_vocab(args.lang)), args.Ce, padding_idx=0)
self.TextEnc = TextEncoder(d_in=args.Ce, d_out=args.Cx*2, d_hidden=args.Cx*2)
self.AudioEnc = AudioEncoder(d_in=args.n_mels, d_out=args.Cx, d_hidden=args.Cx)
self.Attention = DotProductAttention(d_hidden=args.Cx)
self.AudioDec = AudioDecoder(d_in=args.Cx*2, d_out=args.n_mels, d_hidden=args.Cy)
self.PostNet = PostNet(d_in=args.n_mels, d_out=args.n_mels, d_hidden=args.Cx)
self.F0Enc = nn.Sequential(
nn.Linear(1, 32),
nn.ReLU(),
nn.Linear(32, args.Cx*2),
nn.Tanh(),
)
import tensorflow as tf
import numpy as np
from data import get_vocab, load_train_data_pipe, data_iter_combine
from model_combine import COMBINE
sen_len = 40
label_num = 5
sparse_len = 140
crf_num = 10720
learning_rate = 0.02
batch_size = 10
num_epoch = 10
dropout = True
print('read vocab ...')
vocab_size, embedding_size, embedding, vocab_w2i = get_vocab()
num_hidden = embedding_size
label_onehot = {}
label_hotone = {}
label_onehot['b-person'] = 1
label_onehot['i-person'] = 2
label_onehot['b-organization'] = 3
label_onehot['i-organization'] = 4
label_onehot['o'] = 0
label_hotone[1] = 'b-person'
label_hotone[2] = 'i-person'
label_hotone[3] = 'b-organization'
label_hotone[4] = 'i-organization'
label_hotone[0] = 'o'
#coding:utf-8
import tensorflow as tf
from data import get_train_data, get_vocab, split_data, response_len, post_len, padding
import random
import os
from pprint import pprint
import numpy as np
import time
id2w, w2id, freq = get_vocab()
from emo_cls.classification import Classification
from seq2seq_attention_9emo import Seq2SeqAttentionMinDis, Seq2SeqAttentionMaxDis, Seq2SeqAttentionEmoContent
from seq2seq_attention_9emo import Seq2SeqAttentionHappy, Seq2SeqAttentionSad, Seq2SeqAttentionAnger, Seq2SeqAttentionDisgust
from seq2seq_attention_9emo import Seq2SeqAttentionLike #,Seq2SeqAttentionSurprise,Seq2SeqAttentionFear
train_datas, val_datas, test_datas = split_data()
keys = ['posts', 'postLen', 'resps', 'respLen', 'resp_tfidf']
train_datas = [train_datas[k] for k in keys]
val_datas = [val_datas[k] for k in keys]
print("train num:%s" % len(train_datas[0]))
seq_len = 20
batch_size = 128
D_step = 5
G_step = 1
is_debug = True
# Emotion Classifier
import random
import numpy as np
train_data_file = 'D:\\nlp\\我的实验\\句子相似度\\sick\\SICK_train.txt'
trial_data_file = 'D:\\nlp\\我的实验\\句子相似度\\sick\\SICK_trial.txt'
test_data_file = 'D:\\nlp\\我的实验\\句子相似度\\sick\\SICK_test_annotated.txt'
train_data = data.load_data(train_data_file)
trial_data = data.load_data(trial_data_file)
test_data = data.load_data(test_data_file)
train_data = train_data + trial_data
print('train data size: ', len(train_data))
print('test data size: ', len(test_data))
vocab, vocab_size, word_to_id, id_to_word, word_to_count = data.get_vocab(
train_data + test_data)
print('vocab size: ', vocab_size)
word_to_senses_path = 'D:\\nlp\\我的实验\\多义词\\trained_40w\\word_to_sense.txt'
#word_to_vector_path='D:\\nlp\\我的实验\\多义词\\trained_40w\\word_vectors.txt'
sense_to_vector_path = 'D:\\nlp\\我的实验\\多义词\\trained_40w\\sense_vectors.txt'
ass_vector = data.get_sense_ass(word_to_senses_path, sense_to_vector_path)
init_emb = data.fill_with_gloves(word_to_id, ass_vector)
#print(init_emb)
print('Embedding Size: %d' % init_emb.shape[1])
train_ndata = data.convert_to_numeric(train_data, word_to_id)
test_ndata = data.convert_to_numeric(test_data, word_to_id)
#model
import jieba
##分词器 thulac
import thulac
thu1 = thulac.thulac(seg_only=True) #只进行分词,不进行词性标注
text = thu1.cut("我爱北京天安门", text=True) #进行一句话分词
print(text)
#分词器 pynlpir
import pynlpir
pynlpir.open()
s = '欢迎科研人员、技术工程师、企事业单位与个人参与NLPIR平台的建设工作。'
pynlpir.segment(s, pos_tagging=False)
_, vocab, _ = get_vocab()
def sent2ids(sent):
# sent=" ".join(jieba.lcut(sent))
# sent=" ".join(thu1.cut(sent,text=True))
sent = " ".join(pynlpir.segment(sent, pos_tagging=False))
words = tokenize(sent, vocab)
print(words)
ids = [vocab.get(w, 1) for w in words]
print(ids)
l = len(ids)
return padding([ids], max_len=20), np.array([l]), np.array([20])
if __name__ == "__main__":
loss = train(model=model,
optimizer=optimizer,
input_variable=input_variable,
target_variable=target_variable,
criterion=criterion)
print_loss_total += loss
if iter % print_every == 0:
print_loss_avg = print_loss_total / print_every
print_loss_total = 0
print('%s (%d %d%%) %.4f' %
(timeSince(start, iter / n_epochs), iter,
iter / n_epochs * 100, print_loss_avg))
source_vocab, target_vocab = data.get_vocab()
# Actually training the model
model = model_transformer.Transformer(queries_dim=64,
keys_dim=64,
values_dim=64,
model_dim=512,
num_encoder_layers=6,
num_decoder_layers=6,
n_source_vocab=source_vocab,
n_target_vocab=target_vocab,
num_encoder_heads=8,
num_decoder_heads=8)
if use_cuda:
model = model.cuda()
from pprint import pprint
from matplotlib import cm
import matplotlib.pyplot as plt
import data
from data import get_vocab, get_padded_train_data, get_predicates, get_questions
from word2vec import get_embedding
import re
import random
base_weight_path = "./weights/"
base_encoded_path = "./datasets/predict/encoded_data"
question_len = data.question_len
predicate_len = data.predicate_len
id2w, vocab = get_vocab()
size = len(vocab)
embedding = get_embedding()
embedding = embedding / np.sqrt(
(np.sum(np.square(embedding), axis=-1, keepdims=True) + 1e-8)) #用这个效果好
#cos函数
def cosine(x1, x2):
return K.sum(x1 * x2, axis=-1) / (
K.sqrt(K.sum(x1 * x1, axis=-1) * K.sum(x2 * x2, axis=-1) + 1e-12)
) #cos
def neg_log_loss(x):
cos1 = x[0]
group.add_argument("--meta_dev",
type=str,
default="metaphor_data/validation.csv")
group.add_argument("--meta_test",
type=str,
default="metaphor_data/test.csv")
group.add_argument("--output", type=str, default="output.tsv")
args = vars(parser.parse_args())
logging.info(args)
(meta_train, meta_dev, meta_test) = \
(args["meta_train"], args["meta_dev"], args["meta_test"])
# Set seed to combat random effects
set_seed(args["seed"])
vocab, sentences = get_vocab(meta_train, meta_dev, meta_test)
bert = args["model"] == "bert"
# Metaphor data filenames
if args["dev"]:
(meta_test, meta_dev) = (meta_dev, meta_test)
meta_train = get_metaphor_data(meta_train,
args["batch_size"],
args["k"],
bert,
train=True)
meta_dev = get_metaphor_data(meta_dev, 8, args["k"], bert)
meta_test = get_metaphor_data(meta_test, 8, args["k"], bert)
# Initialise an empty model and train it.
if not os.path.exists(model_path): os.makedirs(model_path)
ckpt_prefix = os.path.join(model_path, "model")
paths['model_path'] = ckpt_prefix
result_path = os.path.join(output_path, "results")
paths['result_path'] = result_path
if not os.path.exists(result_path): os.makedirs(result_path)
log_path = os.path.join(result_path, "log.txt")
paths['log_path'] = log_path
get_logger(log_path).info(str(args))
if __name__ == '__main__':
build_word_index(args.word_embedding_file, args.src_vocab_file,
args.tgt_file, args.tgt_vocab_file)
src_vocab = get_vocab(args.src_vocab_file)
src_vocab_size = len(src_vocab)
src_unknown = src_vocab_size
src_padding = src_vocab_size + 1
#print(len(src_vocab))
#print(vocab_size)
tgt_vocab = get_vocab(args.tgt_vocab_file)
tgt_vocab_size = len(tgt_vocab)
tgt_unknown = tgt_vocab_size
tgt_padding = tgt_vocab_size + 1
#print(tgt_vocab)
embedding = load_word2vec_embedding(args.word_embedding_file,
args.embedding_dim, src_vocab_size)