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predict.py
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predict.py
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import csv
import argparse
import random
import numpy
from pytorch_transformers import BertTokenizer, BertModel
import torch
from torch.utils.data import DataLoader, random_split
from data_utils import build_tokenizer, build_embedding_matrix, Tokenizer4Bert, ABSADataset
from models import LSTM, MemNet, RAM, TD_LSTM, TC_LSTM, Cabasc, ATAE_LSTM, TNet_LF, AOA, MGAN, LCF_BERT
from models.aen import CrossEntropyLoss_LSR, AEN_BERT
from models.bert_spc import BERT_SPC
from train import logger
class Predictor:
def __init__(self, opt):
self.opt = opt
if 'bert' in opt.model_name:
tokenizer = Tokenizer4Bert(opt.max_seq_len, opt.pretrained_bert_name)
bert = BertModel.from_pretrained(opt.pretrained_bert_name)
self.model = opt.model_class(bert, opt).to(opt.device)
else:
tokenizer = build_tokenizer(
fnames=[opt.dataset_file['train'], opt.dataset_file['test']],
max_seq_len=opt.max_seq_len,
dat_fname='{0}_tokenizer.dat'.format(opt.dataset))
embedding_matrix = build_embedding_matrix(
word2idx=tokenizer.word2idx,
embed_dim=opt.embed_dim,
dat_fname='{0}_{1}_embedding_matrix.dat'.format(str(opt.embed_dim), opt.dataset))
self.model = opt.model_class(embedding_matrix, opt).to(opt.device)
# self.trainset = ABSADataset(opt.dataset_file['train'], tokenizer)
self.testset = ABSADataset(opt.dataset_file['test'], tokenizer)
# assert 0 <= opt.valset_ratio < 1
# if opt.valset_ratio > 0:
# valset_len = int(len(self.trainset) * opt.valset_ratio)
# self.trainset, self.valset = random_split(self.trainset, (len(self.trainset) - valset_len, valset_len))
# else:
# self.valset = self.testset
#
# if opt.device.type == 'cuda':
# logger.info('cuda memory allocated: {}'.format(torch.cuda.memory_allocated(device=opt.device.index)))
model_path = 'saved/'+opt.model_name+'.hdf5'
self.model.load_state_dict(torch.load(model_path))
def get_prediction(self, data_loader):
self.model.eval()
review_texts = []
prediction_probs = []
real_values = []
aspects = []
with torch.no_grad():
for t_batch, t_sample_batched in enumerate(data_loader):
t_sentence = t_sample_batched['raw_sentence']
t_aspect = t_sample_batched['aspect']
t_inputs = [t_sample_batched[col].to(self.opt.device) for col in self.opt.inputs_cols]
t_targets = t_sample_batched['polarity'].to(self.opt.device)
t_outputs = self.model(t_inputs)
# print(type(t_outputs))
# print(t_outputs.shape)
# print(t_outputs)
review_texts.extend(t_sentence)
# prediction_probs.extend(torch.argmax(t_outputs, -1))
prediction_probs.extend(t_outputs)
real_values.extend(t_targets)
aspects.extend(t_aspect)
prediction_probs = torch.stack(prediction_probs).cpu()
real_values = torch.stack(real_values).cpu()
print(len(review_texts))
print(type(prediction_probs))
p = prediction_probs.numpy()
print(type(p))
print(p.shape)
q = numpy.reshape(p, (668, 3))
print(q.shape)
print(q)
return review_texts, prediction_probs, real_values, aspects
def save_predictions(self):
test_data_loader = DataLoader(dataset=self.testset, batch_size=self.opt.batch_size, shuffle=False)
sentence, y_pred_probs, y_test, aspect = self.get_prediction(test_data_loader)
class_names = [0, 1, 2]
print(y_pred_probs)
print("/n")
print(y_pred_probs.shape)
return y_pred_probs
# for i in range(len(sentence)):
# print (sentence[i])
# print(aspect[i])
# print(y_pred_probs[i])
# csv_file = 'predictions/{}_predictions.csv'.format(self.opt.model_name)
# with open(csv_file, 'w', newline='') as pred_file:
# writer = csv.writer(pred_file)
# writer.writerow(['sentence', 'aspect', 'predicted sentiment', 'true sentiment'])
# for i in range(len(sentence)):
# writer.writerow([sentence[i], aspect[i], class_names[y_pred_probs[i]], class_names[y_test[i]]])
print('successfully wrote the csv file')
def main(model):
parser = argparse.ArgumentParser()
parser.add_argument('--model_name', default=model, type=str)
parser.add_argument('--dataset', default='law', type=str, help='twitter, restaurant, laptop')
parser.add_argument('--optimizer', default='adam', type=str)
parser.add_argument('--initializer', default='xavier_uniform_', type=str)
parser.add_argument('--learning_rate', default=2e-5, type=float, help='try 5e-5, 2e-5 for BERT, 1e-3 for others')
parser.add_argument('--dropout', default=0.1, type=float)
parser.add_argument('--l2reg', default=0.01, type=float)
parser.add_argument('--num_epoch', default=10, type=int, help='try larger number for non-BERT models')
parser.add_argument('--batch_size', default=16, type=int, help='try 16, 32, 64 for BERT models')
parser.add_argument('--log_step', default=5, type=int)
parser.add_argument('--embed_dim', default=300, type=int)
parser.add_argument('--hidden_dim', default=300, type=int)
parser.add_argument('--bert_dim', default=768, type=int)
parser.add_argument('--pretrained_bert_name', default='bert-base-uncased', type=str)
parser.add_argument('--max_seq_len', default=80, type=int)
parser.add_argument('--polarities_dim', default=3, type=int)
parser.add_argument('--hops', default=3, type=int)
parser.add_argument('--device', default='cpu', type=str, help='e.g. cuda:0')
parser.add_argument('--seed', default=None, type=int, help='set seed for reproducibility')
parser.add_argument('--valset_ratio', default=0, type=float,
help='set ratio between 0 and 1 for validation support')
# The following parameters are only valid for the lcf-bert model
parser.add_argument('--local_context_focus', default='cdm', type=str, help='local context focus mode, cdw or cdm')
parser.add_argument('--SRD', default=3, type=int,
help='semantic-relative-distance, see the paper of LCF-BERT model')
opt = parser.parse_args()
# opt = parser.parse_args()
if opt.seed is not None:
random.seed(opt.seed)
numpy.random.seed(opt.seed)
torch.manual_seed(opt.seed)
torch.cuda.manual_seed(opt.seed)
torch.backends.cudnn.deterministic = True
torch.backends.cudnn.benchmark = False
model_classes = {
'lstm': LSTM,
'td_lstm': TD_LSTM,
'tc_lstm': TC_LSTM,
'atae_lstm': ATAE_LSTM,
#'ian': IAN,
'memnet': MemNet,
'ram': RAM,
'cabasc': Cabasc,
'tnet_lf': TNet_LF,
'aoa': AOA,
'mgan': MGAN,
'bert_spc': BERT_SPC,
'aen_bert': AEN_BERT,
'lcf_bert': LCF_BERT,
# default hyper-parameters for LCF-BERT model is as follws:
# lr: 2e-5
# l2: 1e-5
# batch size: 16
# num epochs: 5
}
dataset_files = {
'law': {
'train': './datasets/semeval14/train.csv',
'test': './datasets/semeval14/test.csv'
}
}
input_colses = {
'lstm': ['text_raw_indices'],
'td_lstm': ['text_left_with_aspect_indices', 'text_right_with_aspect_indices'],
'tc_lstm': ['text_left_with_aspect_indices', 'text_right_with_aspect_indices', 'aspect_indices'],
'atae_lstm': ['text_raw_indices', 'aspect_indices'],
'ian': ['text_raw_indices', 'aspect_indices'],
'memnet': ['text_raw_without_aspect_indices', 'aspect_indices'],
'ram': ['text_raw_indices', 'aspect_indices', 'text_left_indices'],
'cabasc': ['text_raw_indices', 'aspect_indices', 'text_left_with_aspect_indices',
'text_right_with_aspect_indices'],
'tnet_lf': ['text_raw_indices', 'aspect_indices', 'aspect_in_text'],
'aoa': ['text_raw_indices', 'aspect_indices'],
'mgan': ['text_raw_indices', 'aspect_indices', 'text_left_indices'],
'bert_spc': ['text_bert_indices', 'bert_segments_ids'],
'aen_bert': ['text_raw_bert_indices', 'aspect_bert_indices'],
'lcf_bert': ['text_bert_indices', 'bert_segments_ids', 'text_raw_bert_indices', 'aspect_bert_indices'],
}
initializers = {
'xavier_uniform_': torch.nn.init.xavier_uniform_,
'xavier_normal_': torch.nn.init.xavier_normal,
'orthogonal_': torch.nn.init.orthogonal_,
}
optimizers = {
'adadelta': torch.optim.Adadelta, # default lr=1.0
'adagrad': torch.optim.Adagrad, # default lr=0.01
'adam': torch.optim.Adam, # default lr=0.001
'adamax': torch.optim.Adamax, # default lr=0.002
'asgd': torch.optim.ASGD, # default lr=0.01
'rmsprop': torch.optim.RMSprop, # default lr=0.01
'sgd': torch.optim.SGD,
}
opt.model_class = model_classes[opt.model_name]
opt.dataset_file = dataset_files[opt.dataset]
opt.inputs_cols = input_colses[opt.model_name]
opt.initializer = initializers[opt.initializer]
opt.optimizer = optimizers[opt.optimizer]
opt.device = torch.device('cuda' if torch.cuda.is_available() else 'cpu') \
if opt.device is None else torch.device(opt.device)
pred = Predictor(opt)
y_pred = pred.save_predictions()
return y_pred