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train_generator.py
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train_generator.py
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import argparse
import logging.handlers
import os
import random
from collections import OrderedDict
from torch.optim.lr_scheduler import MultiStepLR
from torch.utils.data import TensorDataset, DataLoader, RandomSampler, SequentialSampler
from MultiWOZ import get_batch
from evaluator import evaluateModel
from tools import *
from transformer.Transformer import RespGenerator, UncertaintyLoss
def parse_opt():
parser = argparse.ArgumentParser()
parser.add_argument('--option', type=str, default="train", help="whether to train or test the model", choices=['train', 'test', 'postprocess'])
parser.add_argument('--emb_dim', type=int, default=128, help="the embedding dimension")
parser.add_argument('--dropout', type=float, default=0.2, help="dropout rate")
parser.add_argument('--resume', action='store_true', default=False, help="whether to resume previous run")
parser.add_argument('--batch_size', type=int, default=3, help="train/dev/test batch size")
parser.add_argument('--model', type=str, default="model", help="path to save or load models")
parser.add_argument('--data_dir', type=str, default='data', help="data dir")
parser.add_argument('--beam_size', type=int, default=2, help="beam size of act/response generator")
parser.add_argument('--max_seq_length', type=int, default=50, help="max input length")
parser.add_argument('--ngram', type=int, default=3, help="avoid n gram repeatness")
parser.add_argument('--layer_num', type=int, default=3, help="transformer layer num")
parser.add_argument('--evaluate_every', type=int, default=5, help="checkpoints")
parser.add_argument('--head', type=int, default=4, help="head num for transformer")
parser.add_argument("--learning_rate", default=1e-3, type=float, help="The initial learning rate for Adam.")
parser.add_argument("--output_file", default='output', type=str, help="path to save generated act/response")
parser.add_argument("--non_delex", default=False, action="store_true", help="non delex testing")
parser.add_argument("--hist_num", default=0,type=int, help="turn num of history")
parser.add_argument('--log', type=str, default='log', help="log file")
parser.add_argument('--act_source', type=str, choices=["pred", "bert",'groundtruth'], default='pred', help="action source for validate/test")
parser.add_argument('--seed', type=int, default=1, help="random seed for initialization")
args = parser.parse_args()
return args
args = parse_opt()
if args.option == 'train':
if not os.path.exists(args.model):
os.makedirs(args.model)
args.log = os.path.join(args.model, 'train.log')
elif args.option == 'test':
dir = os.path.dirname(args.model)
args.log = os.path.join(dir, 'test.log')
logger = logging.getLogger(__name__)
handler1 = logging.StreamHandler()
handler2 = logging.FileHandler(filename=args.log)
logger.setLevel(logging.DEBUG)
handler1.setLevel(logging.WARNING)
handler2.setLevel(logging.DEBUG)
formatter = logging.Formatter("%(asctime)s %(name)s %(levelname)s %(message)s")
handler1.setFormatter(formatter)
handler2.setFormatter(formatter)
logger.addHandler(handler1)
logger.addHandler(handler2)
device = torch.device('cuda' if torch.cuda.is_available() else "cpu")
def setup_seed(seed):
torch.manual_seed(seed)
torch.cuda.manual_seed_all(seed)
numpy.random.seed(seed)
random.seed(seed)
setup_seed(args.seed)
with open("{}/vocab.json".format(args.data_dir), 'r') as f:
vocabulary = json.load(f)
act_ontology = Constants.act_ontology
vocab, ivocab = vocabulary['vocab'], vocabulary['rev']
tokenizer = Tokenizer(vocab, ivocab, False)
with open("{}/act_vocab.json".format(args.data_dir), 'r') as f:
act_vocabulary = json.load(f)
act_vocab, act_ivocab = act_vocabulary['vocab'], act_vocabulary['rev']
act_tokenizer = Tokenizer(act_vocab, act_ivocab, False)
logger.info("Loading Vocabulary of {} size".format(tokenizer.vocab_len))
# Loading the dataset
checkpoint_file = args.model
if 'train' in args.option:
*train_examples, _ = get_batch(args.data_dir, 'train', tokenizer, act_tokenizer, args.max_seq_length)
train_data = TensorDataset(*train_examples)
train_sampler = RandomSampler(train_data)
train_dataloader = DataLoader(train_data, sampler=train_sampler, batch_size=args.batch_size)
*val_examples, val_id = get_batch(args.data_dir, 'val', tokenizer, act_tokenizer, args.max_seq_length)
dialogs = json.load(open('{}/val.json'.format(args.data_dir)))
gt_turns = json.load(open('{}/val_reference.json'.format(args.data_dir)))
elif 'test' in args.option or 'postprocess' in args.option:
*val_examples, val_id = get_batch(args.data_dir, 'test', tokenizer, act_tokenizer, args.max_seq_length)
dialogs = json.load(open('{}/test.json'.format(args.data_dir)))
if args.non_delex:
gt_turns = json.load(open('{}/test_reference_nondelex.json'.format(args.data_dir)))
else:
gt_turns = json.load(open('{}/test_reference.json'.format(args.data_dir)))
eval_data = TensorDataset(*val_examples)
eval_sampler = SequentialSampler(eval_data)
eval_dataloader = DataLoader(eval_data, sampler=eval_sampler, batch_size=args.batch_size)
BLEU_calc = BLEUScorer()
F1_calc = F1Scorer()
best_BLEU = 0
weighted_loss_func = UncertaintyLoss(2)
weighted_loss_func.to(device)
resp_generator = RespGenerator(vocab_size=tokenizer.vocab_len,
act_vocab_size=act_tokenizer.vocab_len,
d_word_vec=args.emb_dim,
act_dim=Constants.act_len,
n_layers=args.layer_num,
d_model=args.emb_dim,
n_head=args.head,
dropout=args.dropout)
resp_generator.to(device)
bce_loss_func = torch.nn.BCEWithLogitsLoss()
bce_loss_func.to(device)
ce_loss_func = torch.nn.CrossEntropyLoss(ignore_index=Constants.PAD)
ce_loss_func.to(device)
label_list = Constants.functions + Constants.arguments
if args.option == 'train':
resp_generator.train()
if args.resume:
logger.info("Reloaing the encoder and act_generator from {}".format(checkpoint_file))
logger.info("Start Training with {} batches".format(len(train_dataloader)))
optimizer = torch.optim.Adam(filter(lambda x: x.requires_grad, list(resp_generator.parameters()) + list(weighted_loss_func.parameters())), betas=(0.9, 0.98), eps=1e-09)
scheduler = MultiStepLR(optimizer, milestones=[50, 100, 150, 200], gamma=0.5)
alpha = 0.1
for epoch in range(51):
for step, batch in enumerate(train_dataloader):
batch = tuple(t.to(device) for t in batch)
input_ids, action_masks, rep_in, resp_out, belief_state,\
bert_act_seq, act_in, act_out, all_label, act_input_mask,\
resp_input_mask, *_ = batch
resp_generator.zero_grad()
# act loss
logits, _, act_vecs = resp_generator.act_forward(
tgt_seq=act_in, src_seq=input_ids, bs=belief_state, input_mask=act_input_mask)
loss1 = ce_loss_func(
logits.contiguous().view(logits.size(0) * logits.size(1), -1).contiguous(),
act_out.contiguous().view(-1))
# response loss
resp_logits = resp_generator.resp_forward(tgt_seq=rep_in, src_seq=input_ids, act_vecs=act_vecs,
act_mask=action_masks, input_mask=resp_input_mask)
loss2 = ce_loss_func(
resp_logits.contiguous().view(resp_logits.size(0) * resp_logits.size(1), -1).contiguous(),
resp_out.contiguous().view(-1))
# overall loss
if epoch < 10:
loss = loss1
else:
loss = weighted_loss_func(loss1, loss2)
loss.backward()
optimizer.step()
if step % 100 == 0:
print("epoch {} \tstep {} training \ttotal_loss {:.6f} \tact_loss {:.6f} \tresp_loss {:.6f}".format(epoch, step, loss.item(), loss1.item(), loss2.item()))
alpha = min(1, alpha + 0.1 * epoch)
scheduler.step()
if loss2.item() < 3.0 and loss1.item() < 3.0 and epoch > 0 and epoch % args.evaluate_every == 0:
logger.info("start evaluating BLEU on validation set")
resp_generator.eval()
# Start Evaluating after each epoch
model_turns = {}
TP, TN, FN, FP = 0, 0, 0, 0
for batch_step, batch in enumerate(eval_dataloader):
all_pred = []
batch = tuple(t.to(device) for t in batch)
input_ids, action_masks, rep_in, resp_out, belief_state, \
bert_act_seq, act_in, act_out, all_label, act_input_mask, \
resp_input_mask, *_ = batch
if args.act_source == 'bert':
act_in = bert_act_seq
elif args.act_source == 'pred':
hyps, act_logits = resp_generator.act_translate_batch(input_mask=act_input_mask, bs=belief_state, \
src_seq=input_ids, n_bm=args.beam_size,
max_token_seq_len=Constants.ACT_MAX_LEN)
for hyp_step, hyp in enumerate(hyps):
pre1 = [0] * Constants.act_len
if len(hyp) < Constants.ACT_MAX_LEN:
hyps[hyp_step] = list(hyps[hyp_step]) + [Constants.PAD] * (Constants.ACT_MAX_LEN - len(hyp))
for w in hyp:
if w not in [Constants.PAD, Constants.EOS]:
pre1[w - 3] = 1
all_pred.append(pre1)
all_pred = torch.Tensor(all_pred)
all_label = all_label.cpu()
TP, TN, FN, FP = obtain_TP_TN_FN_FP(all_pred, all_label, TP, TN, FN, FP)
act_in = torch.tensor(hyps, dtype=torch.long).to(device)
else:
pass
_, _, act_vecs = resp_generator.act_forward(tgt_seq=act_in, src_seq=input_ids, bs=belief_state,
input_mask=act_input_mask)
action_masks = act_in.eq(Constants.PAD) + act_in.eq(Constants.EOS)
resp_hyps = resp_generator.resp_translate_batch(bs=belief_state, act_vecs=act_vecs,
act_mask=action_masks, input_mask=resp_input_mask,
src_seq=input_ids, n_bm=args.beam_size,
max_token_seq_len=40)
for hyp_step, hyp in enumerate(resp_hyps):
pred = tokenizer.convert_id_to_tokens(hyp)
file_name = val_id[batch_step * args.batch_size + hyp_step]
if file_name not in model_turns:
model_turns[file_name] = [pred]
else:
model_turns[file_name].append(pred)
precision = TP / (TP + FP + 0.001)
recall = TP / (TP + FN + 0.001)
F1 = 2 * precision * recall / (precision + recall + 0.001)
print("precision is {:.6f} recall is {:.6f} F1 is {:.6f}".format(precision, recall, F1))
logger.info("precision is {:.6f} recall is {:.6f} F1 is {:.6f}".format(precision, recall, F1))
BLEU = BLEU_calc.score(model_turns, gt_turns)
inform, request = evaluateModel(model_turns)
print("{} epoch, Validation BLEU {:.4f}, inform {:.2f}, request {:.2f}, score {:.2f}".format(epoch, BLEU, inform, request, (inform + request) / 2 + 100 * BLEU))
logger.info("{} epoch, Validation BLEU {:.4f}, inform {:.2f}, request {:.2f}, score {:.2f}".format(epoch, BLEU, inform, request, (inform + request) / 2 + 100 * BLEU))
if request > best_BLEU:
save_name = 'inform-{:.2f}-request-{:.2f}-bleu-{:.4f}-seed-{}'.format(inform, request, BLEU, args.seed)
torch.save(resp_generator.state_dict(), os.path.join(checkpoint_file, save_name))
best_BLEU = request
resp_file = os.path.join(args.output_file, 'resp_pred.json')
with open(resp_file, 'w') as fp:
model_turns = OrderedDict(sorted(model_turns.items()))
json.dump(model_turns, fp, indent=2)
resp_generator.train()
elif args.option == "test":
resp_generator.load_state_dict(torch.load(args.model))
logger.info("Loading model from {}".format(checkpoint_file))
resp_generator.eval()
# Start Evaluating after each epoch
model_turns = {}
act_turns={}
TP, TN, FN, FP = 0, 0, 0, 0
example_success={}
for batch_step, batch in enumerate(eval_dataloader):
all_pred = []
batch = tuple(t.to(device) for t in batch)
input_ids, action_masks, rep_in, resp_out, belief_state, bert_act_seq, act_in, act_out, all_label, \
act_input_mask, resp_input_mask, *_ = batch
if args.act_source == 'bert':
act_in = bert_act_seq
elif args.act_source == 'pred':
hyps, act_logits = resp_generator.act_translate_batch(input_mask=act_input_mask, bs=belief_state, \
src_seq=input_ids, n_bm=args.beam_size,
max_token_seq_len=Constants.ACT_MAX_LEN)
for hyp_step, hyp in enumerate(hyps):
pre1 = [0] * Constants.act_len
for w in hyp:
if w not in [Constants.PAD, Constants.EOS]:
pre1[w - 3] = 1
if len(hyp) < Constants.ACT_MAX_LEN:
hyps[hyp_step] = list(hyps[hyp_step]) + [Constants.PAD] * (Constants.ACT_MAX_LEN - len(hyp))
all_pred.append(pre1)
file_name = val_id[batch_step * args.batch_size + hyp_step]
if file_name not in act_turns:
act_turns[file_name] = [pre1]
else:
act_turns[file_name].append(pre1)
all_pred=torch.Tensor(all_pred)
all_label=all_label.cpu()
TP, TN, FN, FP = obtain_TP_TN_FN_FP(all_pred, all_label, TP, TN, FN, FP)
act_in = torch.tensor(hyps, dtype=torch.long).to(device)
else:
pass
_, _, act_vecs = resp_generator.act_forward(tgt_seq=act_in, src_seq=input_ids, bs=belief_state,
input_mask=act_input_mask)
action_masks = act_in.eq(Constants.PAD) + act_in.eq(Constants.EOS)
resp_hyps = resp_generator.resp_translate_batch(bs=belief_state, act_vecs=act_vecs, act_mask=action_masks,
input_mask=resp_input_mask,
src_seq=input_ids, n_bm=args.beam_size,
max_token_seq_len=40,gram_num=args.ngram)
for hyp_step, hyp in enumerate(resp_hyps):
pred = tokenizer.convert_id_to_tokens(hyp)
file_name = val_id[batch_step * args.batch_size + hyp_step]
if file_name not in model_turns:
model_turns[file_name] = [pred]
else:
model_turns[file_name].append(pred)
precision = TP / (TP + FP + 0.001)
recall = TP / (TP + FN + 0.001)
F1 = 2 * precision * recall / (precision + recall + 0.001)
print("precision is {:.6f} recall is {:.6f} F1 is {:.6f}".format(precision, recall, F1))
logger.info("precision is {:.6f} recall is {:.6f} F1 is {:.6f}".format(precision, recall, F1))
BLEU = BLEU_calc.score(model_turns, gt_turns)
inform, request = evaluateModel(model_turns, example_success)
print("Test BLEU {:.4f}, inform {:.2f}, request {:.2f}, score {:.2f}".format(BLEU, inform, request, (inform + request) / 2 + 100 * BLEU))
logger.info("Test BLEU {:.4f}, inform {:.2f}, request {:.2f}, score {:.2f}".format(BLEU, inform, request, (inform + request) / 2 + 100 * BLEU))
resp_file = os.path.join(args.output_file, 'resp_pred.json')
with open(resp_file, 'w') as fp:
model_turns = OrderedDict(sorted(model_turns.items()))
json.dump(model_turns, fp, indent=2)
act_file = os.path.join(args.output_file, 'act_pred.json')
with open(act_file, 'w') as fp:
act_turns = OrderedDict(sorted(act_turns.items()))
json.dump(act_turns, fp, indent=2)
with open('output/example_statistic.json','w') as f:
json.dump(example_success,f)
save_name = 'test-inform-{:.2f}-request-{:.2f}-bleu-{:.4f}'.format(inform, request, BLEU)
torch.save(resp_generator.state_dict(), os.path.join('model', save_name))
elif args.option == "postprocess":
resp_file = os.path.join(args.output_file, 'resp_pred.json')
with open(resp_file, 'r') as f:
model_turns = json.load(f)
success_rate = nondetokenize(model_turns, dialogs)
BLEU = BLEU_calc.score(model_turns, gt_turns)
print(BLEU)
resp_file = os.path.join(args.output_file, 'resp_non_delex_pred.json')
with open(resp_file, 'w') as fp:
model_turns = OrderedDict(sorted(model_turns.items()))
json.dump(model_turns, fp, indent=2)