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n_best_asr_bert.py
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n_best_asr_bert.py
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import os
import sys
import json
import re
import time
import random
import argparse
from datetime import timedelta
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch import optim
from transformers import BertTokenizer,BertModel,RobertaTokenizer,RobertaModel,XLMRobertaTokenizer, XLMRobertaModel, get_linear_schedule_with_warmup
from transformers.optimization import AdamW
from transformers import *
install_path = os.path.dirname(os.path.abspath(__file__))
sys.path.append(install_path)
from utils.util import make_logger, get_exp_dir_bert
from utils.fscore import update_f1, compute_f1
from utils.dataset.tod_asr_util import read_wcn_data, prepare_wcn_dataloader, observability_lens, EpochInfoCollector
from utils.gpu_selection import auto_select_gpu
from utils.bert_xlnet_inputs import prepare_inputs_for_roberta
from utils.STC_util import convert_labels, reverse_top2bottom, onehot_to_scalar
from models.model import make_model
from models.optimization import BertAdam
import utils.Constants as Constants
MODEL_CLASSES = {
"bert": (BertModel,BertTokenizer,'bert-base-uncased'),
"roberta": (RobertaModel,RobertaTokenizer,'roberta-base'),
"xlm-roberta": (XLMRobertaModel,XLMRobertaTokenizer,'xlm-roberta-base'),
}
def parse_arguments():
parser = argparse.ArgumentParser()
######################### model structure #########################
parser.add_argument('--emb_size', type=int, default=256, help='word embedding dimension')
parser.add_argument('--hidden_size', type=int, default=512, help='hidden layer dimension')
parser.add_argument('--max_seq_len', type=int, default=None, help='max sequence length')
parser.add_argument('--n_layers', type=int, default=6, help='#transformer layers')
parser.add_argument('--n_head', type=int, default=4, help='#attention heads')
parser.add_argument('--d_k', type=int, default=64, help='dimension of k in attention')
parser.add_argument('--d_v', type=int, default=64, help='dimension of v in attention')
parser.add_argument('--score_util', default='pp', choices=['none', 'np', 'pp', 'mul'],
help='how to utilize scores in Transformer & BERT: np-naiveplus; pp-paramplus')
parser.add_argument('--sent_repr', default='bin_sa_cls',
choices=['cls', 'maxpool', 'attn', 'bin_lstm', 'bin_sa', 'bin_sa_cls', 'tok_sa_cls'],
help='sentence level representation')
parser.add_argument('--cls_type', default='stc', choices=['nc', 'tf_hd', 'stc'], help='classifier type')
######################### data & vocab #########################
parser.add_argument('--dataset', required=True, help='<domain>')
parser.add_argument('--dataroot', required=True, help='path to dataset')
parser.add_argument('--train_file', default='train', help='base file name of train dataset')
parser.add_argument('--valid_file', default='valid', help='base file name of valid dataset')
parser.add_argument('--test_file', default='test', help='base file name of test dataset')
parser.add_argument('--ontology_path', default=None, help='ontology')
######################## pretrained model (BERT) ########################
parser.add_argument('--bert_model_name', default='bert-base-uncased',
choices=['bert-base-uncased', 'bert-base-cased', 'bert-large-uncased', 'bert-large-cased'])
parser.add_argument('--fix_bert_model', action='store_true')
######################### training & testing options #########################
parser.add_argument('--testing', action='store_true', help=' test your model (default is training && testing)')
parser.add_argument('--deviceId', type=int, default=-1, help='train model on ith gpu. -1:cpu, 0:auto_select')
parser.add_argument('--random_seed', type=int, default=999, help='initial random seed')
parser.add_argument('--l2', type=float, default=0, help='weight decay')
parser.add_argument('--dropout', type=float, default=0., help='dropout rate at each non-recurrent layer')
parser.add_argument('--bert_dropout', type=float, default=0.1, help='dropout rate for BERT')
parser.add_argument('--batchSize', type=int, default=16, help='training batch size')
parser.add_argument('--max_norm', type=float, default=5.0, help='threshold of gradient clipping (2-norm)')
parser.add_argument('--max_epoch', type=int, default=50, help='max number of epochs to train')
parser.add_argument('--experiment', default='exp', help='experiment directories for storing models and logs')
parser.add_argument('--optim_choice', default='bertadam', choices=['adam', 'adamw', 'bertadam'], help='optimizer choice')
parser.add_argument('--lr', default=5e-4, type=float, help='learning rate')
parser.add_argument('--bert_lr', default=1e-5, type=float, help='learning rate for bert')
parser.add_argument('--warmup_proportion', type=float, default=0.1, help='warmup propotion')
parser.add_argument('--init_type', default='uf', choices=['uf', 'xuf', 'normal'], help='init type')
parser.add_argument('--init_range', type=float, default=0.2, help='init range, for naive uniform')
######################## system act #########################
parser.add_argument('--with_system_act', action='store_true', help='whether to include the last system act')
parser.add_argument('--coverage', type=float)
####################### Loss function setting ###############
parser.add_argument('--add_l2_loss',action='store_true',help='whether to add l2 loss between pure and asr transcripts')
###################### Pre-trained model config ##########################
parser.add_argument('--pre_trained_model',help = 'pre-trained model name to use among bert,roberta,xlm-roberta')
parser.add_argument('--tod_pre_trained_model',help = 'tod_pre_trained model checkpoint path')
##################### System act config ###################################
parser.add_argument('--without_system_act',action='store_true',help = 'parameter to decide to add system act')
##################### Config to decide on segement ids ###################################
parser.add_argument('--add_segment_ids',action='store_true', help = 'parameter to decide to add segment ids')
opt = parser.parse_args()
######################### option verification & adjustment #########################
# device definition
if opt.deviceId >= 0:
if opt.deviceId > 0:
opt.deviceId, gpu_name, valid_gpus = auto_select_gpu(assigned_gpu_id=opt.deviceId - 1)
elif opt.deviceId == 0:
opt.deviceId, gpu_name, valid_gpus = auto_select_gpu()
print('Valid GPU list: %s ; GPU %d (%s) is auto selected.' % (valid_gpus, opt.deviceId, gpu_name))
torch.cuda.set_device(opt.deviceId)
opt.device = torch.device('cuda')
else:
print('CPU is used.')
opt.device = torch.device('cpu')
# random seed set
random.seed(opt.random_seed)
np.random.seed(opt.random_seed)
torch.manual_seed(opt.random_seed)
if torch.cuda.is_available():
torch.cuda.manual_seed(opt.random_seed)
# d_model: just equals embedding size
opt.d_model = opt.emb_size
# ontology
opt.ontology = None if opt.ontology_path is None else \
json.load(open(opt.ontology_path))
return opt
def cal_ce_loss(bottom_scores_dict, batch_labels, top2bottom_dict, opt):
ce_losses = []
lin_keys = [k for k, v in top2bottom_dict.items() if len(v) > 1]
for k in lin_keys:
k_str = 'lin_%s' % k
bottom_indices = top2bottom_dict[k]
bottom_labels = batch_labels[:, bottom_indices]
bottom_scalar_labels = onehot_to_scalar(bottom_labels)
bottom_scores = bottom_scores_dict[k_str]
bottom_scores = torch.log(bottom_scores + 1e-12)
ce_loss = opt.ce_loss_function(bottom_scores, bottom_scalar_labels)
ce_losses.append(ce_loss)
return sum(ce_losses) / len(ce_losses)
def cal_total_loss(top_scores, bottom_scores_dict, batch_preds, batch_labels, memory, opt,asr_hidden_state=None,transcription_hidden_state=None):
batch_size= top_scores.size(0)
loss_record = 0.
total_loss = 0.
# MSE loss
if opt.add_l2_loss and (asr_hidden_state is not None) and (transcription_hidden_state is not None):
mse_loss = opt.mse_loss_function(asr_hidden_state,transcription_hidden_state)
loss_record += mse_loss.item() / batch_size
print("MSE loss",mse_loss.item())
total_loss += mse_loss
# bottom-label BCE loss
bottom_loss_flag = True
if bottom_loss_flag:
bottom_loss = opt.class_loss_function(batch_preds, batch_labels)
loss_record += bottom_loss.item() / batch_size
total_loss += bottom_loss
# top-label BCE loss
top_loss_flag = True
if top_loss_flag:
batch_top_labels = convert_labels(batch_labels, memory['bottom2top_mat'])
top_loss = opt.class_loss_function(top_scores, batch_top_labels)
loss_record += top_loss.item() / batch_size
total_loss += top_loss
# bottom-label CE loss for each top-label
ce_loss_flag = True
if ce_loss_flag:
ce_loss = cal_ce_loss(bottom_scores_dict, batch_labels,
memory['top2bottom_dict'], opt)
loss_record += ce_loss.item() / batch_size
total_loss += ce_loss
return loss_record, total_loss
def pred_one_sample(i, ts, bottom_scores_dict, memory, opt):
# ts: top scores
# i: index of the sample in a batch
pred_classes = []
top_ids = [j for j, p in enumerate(ts) if p > 0.5]
for ti in top_ids:
bottom_ids = memory['top2bottom_dict'][ti]
if len(bottom_ids) == 1:
pred_classes.append(memory['idx2label'][bottom_ids[0]])
else:
bs = bottom_scores_dict['lin_%d' % ti][i]
lbl_idx_in_vector = bs.data.cpu().numpy().argmax(axis=-1)
real_lbl_idx = bottom_ids[lbl_idx_in_vector]
lbl = memory['idx2label'][real_lbl_idx]
if not lbl.endswith('NONE'):
pred_classes.append(lbl)
return pred_classes
def filter_informative(labels, ontology):
# filter tuples by whether they are informative according to ontology
new_labels = []
for lbl in labels:
tup = lbl.split('-')
if len(tup) == 3 :
act, slot, value = tup
if slot == "this" or (slot in ontology["informable"] and len(ontology["informable"][slot]) > 1) :
new_labels.append(lbl)
else :
new_labels.append(lbl)
return new_labels
def train_epoch(model, data, opt, memory):
'''Epoch operation in training phase'''
model.train()
opt.optimizer.zero_grad()
TP, FP, FN = 0, 0, 0
corr, tot = 0, 0
losses = []
for step, batch in enumerate(data):
# prepare data
batch_labels,raw_in,raw_trans_in,raw_labels = batch
# prepare inputs for BERT/XLNET
inputs = {}
#pretrained_inputs,input_lens=prepare_inputs_for_bert_xlnet_seq_base(raw_in,opt.tokenizer,device=opt.device)
input_ids,seg_input_ids,input_lens=prepare_inputs_for_roberta(raw_in,opt.tokenizer,opt,device=opt.device)
trans_input_ids,trans_seg_input_ids,trans_input_lens=prepare_inputs_for_roberta(raw_trans_in,opt.tokenizer,opt,device=opt.device)
# forward
if not opt.add_segment_ids:
seg_input_ids = None
top_scores, bottom_scores_dict, batch_preds,asr_hidden_rep,trans_hidden_rep = model(opt,input_ids,trans_input_ids,seg_ids=seg_input_ids,trans_seg_ids=trans_seg_input_ids,classifier_input_type="asr")
# top_scores -> (batch, #top_classes)
# batch_preds -> (batch, #bottom_classes) # not used in this case
# bottom_scores_dict -> 'lin_i': (batch, #bottom_classes_per_top_label)
# in which 'i' is the index of top-label
# backward
loss_record, total_loss = cal_total_loss(top_scores, bottom_scores_dict, batch_preds, batch_labels, memory, opt,asr_hidden_rep,trans_hidden_rep)
losses.append(loss_record)
total_loss.backward()
if (step + 1) % opt.n_accum_steps == 0:
# clip gradient
if opt.optim_choice.lower() != 'bertadam' and opt.max_norm > 0:
params = list(filter(lambda p: p.requires_grad, list(model.parameters())))
torch.nn.utils.clip_grad_norm_(params, opt.max_norm)
# update parameters
if opt.optim_choice.lower() in ['adam', 'bertadam']:
opt.optimizer.step()
elif opt.optim_choice.lower() == 'adamw':
opt.optimizer.step()
opt.scheduler.step()
# clear gradients
opt.optimizer.zero_grad()
# calculate performance
for i, (ts, gold) in enumerate(zip(top_scores.tolist(), raw_labels)):
pred_classes = pred_one_sample(i, ts, bottom_scores_dict, memory, opt)
TP, FP, FN = update_f1(pred_classes, gold, TP, FP, FN)
tot += 1
if set(pred_classes) == set(gold):
corr += 1
mean_loss = np.mean(losses)
p, r, f = compute_f1(TP, FP, FN)
acc = corr / tot * 100
return mean_loss, (p, r, f), acc
def eval_epoch(model, data, opt, memory, fp, efp):
'''Epoch operation in evaluating phase'''
model.eval()
# sake of observability
raw_inputs = []
whole_pred_classes = []
true_golds = []
matches = []
TP, FP, FN = 0, 0, 0
corr, tot = 0, 0
losses = []
all_cases = []
err_cases = []
utt_id = 0
for j, batch in enumerate(data):
# prepare data
batch_labels,raw_in,raw_trans_in,raw_labels = batch
# prepare inputs for BERT/XLNET
inputs = {}
input_ids,seg_input_ids,input_lens=prepare_inputs_for_roberta(raw_in,opt.tokenizer,opt,device=opt.device)
trans_input_ids,trans_seg_input_ids,trans_input_lens=prepare_inputs_for_roberta(raw_trans_in,opt.tokenizer,opt,device=opt.device)
# forward
if not opt.add_segment_ids:
seg_input_ids = None
top_scores, bottom_scores_dict, batch_preds,asr_hidden_rep,trans_hidden_rep = model(opt,input_ids,trans_input_ids,seg_ids=seg_input_ids,trans_seg_ids=trans_seg_input_ids,classifier_input_type="asr")
#top_scores, bottom_scores_dict, batch_preds = model(inputs, masks, return_attns=False)
loss, _ = cal_total_loss(top_scores, bottom_scores_dict, batch_preds, batch_labels, memory, opt)
losses.append(loss)
# calculate performance
batch_pred_classes = []
batch_ids = []
for i, (ts, gold, raw) in enumerate(zip(top_scores.tolist(), raw_labels, raw_in)):
pred_classes = pred_one_sample(i, ts, bottom_scores_dict, memory, opt)
# ontology filter
if opt.ontology is not None:
pred_classes = filter_informative(pred_classes, opt.ontology)
gold = filter_informative(gold, opt.ontology)
TP, FP, FN = update_f1(pred_classes, gold, TP, FP, FN)
tot += 1
if set(pred_classes) == set(gold):
corr += 1
batch_pred_classes.append(pred_classes)
batch_ids.append(utt_id)
utt_id += 1
# keep intermediate results
res_info = '%s\t<=>\t%s\t<=>\t%s\n' % (
' '.join(raw), ';'.join(pred_classes), ';'.join(gold))
fp.write(res_info)
if set(pred_classes) != set(gold):
efp.write(res_info)
err_cases.append((raw, pred_classes, gold))
all_cases.append((raw, pred_classes, gold))
# noting inputs, labels and predictions
raw_inputs.append(" ".join(raw))
whole_pred_classes.append(pred_classes)
true_golds.append(gold)
matches.append(True if set(pred_classes) == set(gold) else False)
mean_loss = np.mean(losses)
p, r, f = compute_f1(TP, FP, FN)
try:
acc = corr / tot * 100
except:
acc = 0
# err_analysis(err_cases)
# collecting overall useful values
eic = EpochInfoCollector(raw_inputs, whole_pred_classes, true_golds, matches, mean_loss, p, r, f, acc)
if opt.testing:
return mean_loss, (p, r, f), acc, all_cases, eic
else:
return mean_loss, (p, r, f), acc, eic
def train(model, train_dataloader, valid_dataloader, test_dataloader, opt, memory):
'''Start training'''
logger = make_logger(os.path.join(opt.exp_dir, 'log.train'))
t0 = time.time()
logger.info('Training starts at %s' % (time.asctime(time.localtime(time.time()))))
export_csv_model_name = "tod_asr_bert_stc"
best = {'epoch': 0, 'vf': 0., 'tef': 0.}
for i in range(opt.max_epoch):
# evaluating train set
start = time.time()
train_loss, (trp, trr, trf), tr_acc = train_epoch(model, train_dataloader, opt, memory)
logger.info('[Train]\tEpoch: %02d\tTime: %.2f\tLoss: %.2f\t(p/r/f): (%.2f/%.2f/%.2f)\tAcc: %.2f' %
(i, time.time()-start, train_loss, trp, trr, trf, tr_acc))
# evaluating valid set
with open(os.path.join(opt.exp_dir, 'valid.iter%d'%i), 'w') as fp, \
open(os.path.join(opt.exp_dir, 'valid.iter%d.err'%i), 'w') as efp:
start = time.time()
valid_loss, (vp, vr, vf), v_acc, v_eic = eval_epoch(model, valid_dataloader, opt, memory, fp, efp)
logger.info('[Valid]\tEpoch: %02d\tTime: %.2f\tLoss: %.2f\t(p/r/f): (%.2f/%.2f/%.2f)\tAcc: %.2f' %
(i, time.time()-start, valid_loss, vp, vr, vf, v_acc))
observability_lens(v_eic, i, "valid", opt.exp_dir, export_csv_model_name)
# evaluating test set
with open(os.path.join(opt.exp_dir, 'test.iter%d'%i), 'w') as fp, \
open(os.path.join(opt.exp_dir, 'test.iter%d.err'%i), 'w') as efp:
start = time.time()
test_loss, (tep, ter, tef), te_acc, te_eic = eval_epoch(model, test_dataloader, opt, memory, fp, efp)
logger.info('[Test]\tEpoch: %02d\tTime: %.2f\tLoss: %.2f\t(p/r/f): (%.2f/%.2f/%.2f)\tAcc: %.2f' %
(i, time.time()-start, test_loss, tep, ter, tef, te_acc))
observability_lens(te_eic, i, "test", opt.exp_dir, export_csv_model_name)
# save model
if vf > best['vf']:
best['epoch'] = i
best['vf'] = vf
best['tef'] = tef
best['v_acc'] = v_acc
best['te_acc'] = te_acc
model.save_model(os.path.join(opt.exp_dir, 'model.pt'))
logger.info('NEW BEST:\tEpoch: %02d\tvalid F1/Acc: %.2f/%.2f\ttest F1/Acc: %.2f/%.2f' % (
i, vf, v_acc, tef, te_acc))
logger.info('Done training. Elapsed time: %s' % timedelta(seconds=time.time() - t0))
logger.info('BEST RESULT:\tEpoch: %02d\tBest valid F1/Acc: %.2f/%.2f\ttest F1/Acc: %.2f/%.2f' % (
best['epoch'], best['vf'], best['v_acc'], best['tef'], best['te_acc']))
def test(model, train_dataloader, valid_dataloader, test_dataloader, opt, memory):
'''Start testing'''
logger = make_logger(os.path.join(opt.exp_dir, 'log.test'))
t0 = time.time()
logger.info('Testing starts at %s' % (time.asctime(time.localtime(time.time()))))
# evaluating train set
with open(os.path.join(opt.exp_dir, 'train.eval'), 'w') as fp, \
open(os.path.join(opt.exp_dir, 'train.eval.err'), 'w') as efp:
start = time.time()
train_loss, (trp, trr, trf), tr_acc, train_all_cases = eval_epoch(model, train_dataloader, opt, memory, fp, efp)
logger.info('[Train]\tTime: %.2f\tLoss: %.2f\t(p/r/f): (%.2f/%.2f/%.2f)\tAcc: %.2f' %
(time.time()-start, train_loss, trp, trr, trf, tr_acc))
# evaluating valid set
with open(os.path.join(opt.exp_dir, 'valid.eval'), 'w') as fp, \
open(os.path.join(opt.exp_dir, 'valid.eval.err'), 'w') as efp:
start = time.time()
valid_loss, (vp, vr, vf), v_acc, valid_all_cases = eval_epoch(model, valid_dataloader, opt, memory, fp, efp)
logger.info('[Valid]\tTime: %.2f\tLoss: %.2f\t(p/r/f): (%.2f/%.2f/%.2f)\tAcc: %.2f' %
(time.time()-start, valid_loss, vp, vr, vf, v_acc))
# evaluating test set
with open(os.path.join(opt.exp_dir, 'test.eval'), 'w') as fp, \
open(os.path.join(opt.exp_dir, 'test.eval.err'), 'w') as efp:
start = time.time()
test_loss, (tep, ter, tef), te_acc, test_all_cases = eval_epoch(model, test_dataloader, opt, memory, fp, efp)
logger.info('[Test]\tTime: %.2f\tLoss: %.2f\t(p/r/f): (%.2f/%.2f/%.2f)\tAcc: %.2f' %
(time.time()-start, test_loss, tep, ter, tef, te_acc))
logger.info('Done testing. Elapsed time: %s' % timedelta(seconds=time.time() - t0))
if __name__ == '__main__':
opt = parse_arguments()
if opt.tod_pre_trained_model:
opt.tokenizer = AutoTokenizer.from_pretrained(opt.tod_pre_trained_model)
opt.pretrained_model = AutoModel.from_pretrained(opt.tod_pre_trained_model)
else:
if MODEL_CLASSES.get(opt.pre_trained_model):
pre_trained_model,pre_trained_tokenizer,model_name = MODEL_CLASSES.get(opt.pre_trained_model)
opt.pretrained_model = pre_trained_model.from_pretrained(model_name)
opt.tokenizer = pre_trained_tokenizer.from_pretrained(model_name)
# memory
memory = torch.load(os.path.join(opt.dataroot, 'memory.pt'))
opt.word_vocab_size = opt.tokenizer.vocab_size # subword-level
if opt.with_system_act:
opt.sysact_vocab_size = len(memory['sysact2idx'])
opt.label_vocab_size = len(memory['label2idx'])
opt.top_label_vocab_size = len(memory['toplabel2idx'])
opt.top2bottom_dict = memory['top2bottom_dict']
memory['bottom2top_mat'] = reverse_top2bottom(memory['top2bottom_dict'])
print('word vocab size:', opt.word_vocab_size)
if opt.with_system_act:
print('system act vocab size:', opt.sysact_vocab_size)
print('#labels:', opt.label_vocab_size)
print('#top-labels:', opt.top_label_vocab_size)
print(opt)
# exp dir
opt.exp_dir = get_exp_dir_bert(opt)
if not opt.testing and not os.path.exists(opt.exp_dir):
os.makedirs(opt.exp_dir)
# model definition & num of params
model = make_model(opt)
model = model.to(opt.device)
trainable_parameters = list(filter(lambda p: p[1].requires_grad, model.named_parameters()))
n_params = sum([np.prod(p.size()) for n, p in trainable_parameters])
bert_parameters = list(filter(lambda n_p: 'bert_encoder' in n_p[0], trainable_parameters))
n_bert_params = sum([np.prod(p.size()) for n, p in bert_parameters])
print(model)
print('num params: {}'.format(n_params))
print('num bert params: {}, {}%'.format(n_bert_params, 100 * n_bert_params / n_params))
# dataloader preparation
opt.n_accum_steps = 4 if opt.n_layers == 12 else 1
print("coverage ",opt.coverage)
train_data = read_wcn_data(os.path.join(opt.dataroot, opt.train_file),opt.coverage)
valid_data = read_wcn_data(os.path.join(opt.dataroot, opt.valid_file))
test_data = read_wcn_data(os.path.join(opt.dataroot, opt.test_file))
train_dataloader = prepare_wcn_dataloader(train_data, memory, int(opt.batchSize / opt.n_accum_steps),
opt.max_seq_len, opt.device, shuffle_flag=True)
valid_dataloader = prepare_wcn_dataloader(valid_data, memory, int(opt.batchSize / opt.n_accum_steps),
opt.max_seq_len, opt.device, shuffle_flag=False)
test_dataloader = prepare_wcn_dataloader(test_data, memory, int(opt.batchSize / opt.n_accum_steps),
opt.max_seq_len, opt.device, shuffle_flag=False)
# optimizer
params = list(model.parameters())
params = list(filter(lambda p: p.requires_grad, params))
named_params = list(model.named_parameters())
named_params = list(filter(lambda p: p[1].requires_grad, named_params))
no_decay = ['bias', 'LayerNorm.bias', 'LayerNorm.weight']
is_bert = lambda name: 'bert_encoder' in name
is_decay = lambda name: not any(nd in name for nd in no_decay)
optimizer_grouped_parameters = []
for n, p in named_params:
params_group = {}
params_group['params'] = p
params_group['weight_decay'] = 0.01 if is_decay(n) else 0
params_group['lr'] = opt.bert_lr if is_bert(n) else opt.lr
optimizer_grouped_parameters.append(params_group)
if opt.optim_choice == 'adam':
opt.optimizer = optim.Adam(params, lr=opt.lr, betas=(0.9, 0.999), eps=1e-8, weight_decay=opt.l2)
elif opt.optim_choice.lower() == 'bertadam':
num_train_optimization_steps = (len(train_dataloader.dataset) // opt.batchSize + 1) * opt.max_epoch
opt.optimizer = BertAdam(
optimizer_grouped_parameters,
lr=opt.lr, warmup=opt.warmup_proportion,
t_total=num_train_optimization_steps
)
elif opt.optim_choice.lower() == 'adamw':
num_train_optimization_steps = (len(train_dataloader.dataset) // opt.batchSize + 1) * opt.max_epoch
opt.optimizer = AdamW(optimizer_grouped_parameters, lr=opt.lr, correct_bias=False)
opt.scheduler = get_linear_schedule_with_warmup(
opt.optimizer,
num_warmup_steps=int(opt.warmup_proportion * num_train_optimization_steps),
num_training_steps=num_train_optimization_steps
) # PyTorch scheduler
# loss function
opt.class_loss_function = nn.BCELoss(reduction='sum')
opt.ce_loss_function = nn.NLLLoss(reduction='sum')
opt.mse_loss_function = nn.MSELoss()
# training or testing
if opt.testing:
model.load_model(os.path.join(opt.exp_dir, 'model.pt'))
test(model, train_dataloader, valid_dataloader, test_dataloader, opt, memory)
else:
train(model, train_dataloader, valid_dataloader, test_dataloader, opt, memory)