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train_classifier.py
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train_classifier.py
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import os
import sys
import argparse
import time
import random
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
from torch.autograd import Variable
# from sru import *
import dataloader
import modules
class Model(nn.Module):
def __init__(self, embedding, hidden_size=150, depth=1, dropout=0.3, cnn=False, nclasses=2):
super(Model, self).__init__()
self.cnn = cnn
self.drop = nn.Dropout(dropout)
self.emb_layer = modules.EmbeddingLayer(
embs = dataloader.load_embedding(embedding)
)
self.word2id = self.emb_layer.word2id
if cnn:
self.encoder = modules.CNN_Text(
self.emb_layer.n_d,
widths = [3,4,5],
filters=hidden_size
)
d_out = 3*hidden_size
else:
self.encoder = nn.LSTM(
self.emb_layer.n_d,
hidden_size//2,
depth,
dropout = dropout,
# batch_first=True,
bidirectional=True
)
d_out = hidden_size
# else:
# self.encoder = SRU(
# emb_layer.n_d,
# args.d,
# args.depth,
# dropout = args.dropout,
# )
# d_out = args.d
self.out = nn.Linear(d_out, nclasses)
def forward(self, input):
if self.cnn:
input = input.t()
emb = self.emb_layer(input)
emb = self.drop(emb)
if self.cnn:
output = self.encoder(emb)
else:
output, hidden = self.encoder(emb)
# output = output[-1]
output = torch.max(output, dim=0)[0].squeeze()
output = self.drop(output)
return self.out(output)
def text_pred(self, text, batch_size=32):
batches_x = dataloader.create_batches_x(
text,
batch_size, ##TODO
self.word2id
)
outs = []
with torch.no_grad():
for x in batches_x:
x = Variable(x)
if self.cnn:
x = x.t()
emb = self.emb_layer(x)
if self.cnn:
output = self.encoder(emb)
else:
output, hidden = self.encoder(emb)
# output = output[-1]
output = torch.max(output, dim=0)[0]
outs.append(F.softmax(self.out(output), dim=-1))
return torch.cat(outs, dim=0)
def eval_model(niter, model, input_x, input_y):
model.eval()
# N = len(valid_x)
# criterion = nn.CrossEntropyLoss()
correct = 0.0
cnt = 0.
# total_loss = 0.0
with torch.no_grad():
for x, y in zip(input_x, input_y):
x, y = Variable(x, volatile=True), Variable(y)
output = model(x)
# loss = criterion(output, y)
# total_loss += loss.item()*x.size(1)
pred = output.data.max(1)[1]
correct += pred.eq(y.data).cpu().sum()
cnt += y.numel()
model.train()
return correct.item()/cnt
def train_model(epoch, model, optimizer,
train_x, train_y,
test_x, test_y,
best_test, save_path):
model.train()
niter = epoch*len(train_x)
criterion = nn.CrossEntropyLoss()
cnt = 0
for x, y in zip(train_x, train_y):
niter += 1
cnt += 1
model.zero_grad()
x, y = Variable(x), Variable(y)
output = model(x)
loss = criterion(output, y)
loss.backward()
optimizer.step()
test_acc = eval_model(niter, model, test_x, test_y)
sys.stdout.write("Epoch={} iter={} lr={:.6f} train_loss={:.6f} test_err={:.6f}\n".format(
epoch, niter,
optimizer.param_groups[0]['lr'],
loss.item(),
test_acc
))
if test_acc > best_test:
best_test = test_acc
if save_path:
torch.save(model.state_dict(), save_path)
# test_err = eval_model(niter, model, test_x, test_y)
sys.stdout.write("\n")
return best_test
def save_data(data, labels, path, type='train'):
with open(os.path.join(path, type+'.txt'), 'w') as ofile:
for text, label in zip(data, labels):
ofile.write('{} {}\n'.format(label, ' '.join(text)))
def main(args):
if args.dataset == 'mr':
# data, label = dataloader.read_MR(args.path)
# train_x, train_y, test_x, test_y = dataloader.cv_split2(
# data, label,
# nfold=10,
# valid_id=args.cv
# )
#
# if args.save_data_split:
# save_data(train_x, train_y, args.path, 'train')
# save_data(test_x, test_y, args.path, 'test')
train_x, train_y = dataloader.read_corpus('/data/datasets/mr/train.txt')
test_x, test_y = dataloader.read_corpus('/data/datasets/mr/test.txt')
elif args.dataset == 'imdb':
train_x, train_y = dataloader.read_corpus(os.path.join('/data/nlp/datasets/imdb',
'train_tok.csv'),
clean=False, MR=True, shuffle=True)
test_x, test_y = dataloader.read_corpus(os.path.join('/data/nlp/datasets/imdb',
'test_tok.csv'),
clean=False, MR=True, shuffle=True)
else:
train_x, train_y = dataloader.read_corpus('proj/to_di/data/{}/'
'train_tok.csv'.format(args.dataset),
clean=False, MR=False, shuffle=True)
test_x, test_y = dataloader.read_corpus('proj/to_di/data/{}/'
'test_tok.csv'.format(args.dataset),
clean=False, MR=False, shuffle=True)
nclasses = max(train_y) + 1
# elif args.dataset == 'subj':
# data, label = dataloader.read_SUBJ(args.path)
# elif args.dataset == 'cr':
# data, label = dataloader.read_CR(args.path)
# elif args.dataset == 'mpqa':
# data, label = dataloader.read_MPQA(args.path)
# elif args.dataset == 'trec':
# train_x, train_y, test_x, test_y = dataloader.read_TREC(args.path)
# data = train_x + test_x
# label = None
# elif args.dataset == 'sst':
# train_x, train_y, valid_x, valid_y, test_x, test_y = dataloader.read_SST(args.path)
# data = train_x + valid_x + test_x
# label = None
# else:
# raise Exception("unknown dataset: {}".format(args.dataset))
# if args.dataset == 'trec':
# elif args.dataset != 'sst':
# train_x, train_y, valid_x, valid_y, test_x, test_y = dataloader.cv_split(
# data, label,
# nfold = 10,
# test_id = args.cv
# )
model = Model(args.embedding, args.d, args.depth, args.dropout, args.cnn, nclasses).cuda()
need_grad = lambda x: x.requires_grad
optimizer = optim.Adam(
filter(need_grad, model.parameters()),
lr = args.lr
)
train_x, train_y = dataloader.create_batches(
train_x, train_y,
args.batch_size,
model.word2id,
)
# valid_x, valid_y = dataloader.create_batches(
# valid_x, valid_y,
# args.batch_size,
# emb_layer.word2id,
# )
test_x, test_y = dataloader.create_batches(
test_x, test_y,
args.batch_size,
model.word2id,
)
best_test = 0
# test_err = 1e+8
for epoch in range(args.max_epoch):
best_test = train_model(epoch, model, optimizer,
train_x, train_y,
# valid_x, valid_y,
test_x, test_y,
best_test, args.save_path
)
if args.lr_decay>0:
optimizer.param_groups[0]['lr'] *= args.lr_decay
# sys.stdout.write("best_valid: {:.6f}\n".format(
# best_valid
# ))
sys.stdout.write("test_err: {:.6f}\n".format(
best_test
))
if __name__ == "__main__":
argparser = argparse.ArgumentParser(sys.argv[0], conflict_handler='resolve')
argparser.add_argument("--cnn", action='store_true', help="whether to use cnn")
argparser.add_argument("--lstm", action='store_true', help="whether to use lstm")
argparser.add_argument("--dataset", type=str, default="mr", help="which dataset")
argparser.add_argument("--embedding", type=str, required=True, help="word vectors")
argparser.add_argument("--batch_size", "--batch", type=int, default=32)
argparser.add_argument("--max_epoch", type=int, default=70)
argparser.add_argument("--d", type=int, default=150)
argparser.add_argument("--dropout", type=float, default=0.3)
argparser.add_argument("--depth", type=int, default=1)
argparser.add_argument("--lr", type=float, default=0.001)
argparser.add_argument("--lr_decay", type=float, default=0)
argparser.add_argument("--cv", type=int, default=0)
argparser.add_argument("--save_path", type=str, default='')
argparser.add_argument("--save_data_split", action='store_true', help="whether to save train/test split")
argparser.add_argument("--gpu_id", type=int, default=0)
args = argparser.parse_args()
# args.save_path = os.path.join(args.save_path, args.dataset)
print (args)
torch.cuda.set_device(args.gpu_id)
main(args)