steps_per_epoch = len(train_dataset) // args.train_batch_size dev_steps_per_epoch = len(dev_features) // args.eval_batch_size if len(train_dataset) % args.train_batch_size != 0: steps_per_epoch += 1 if len(dev_dataset) % args.eval_batch_size != 0: dev_steps_per_epoch += 1 total_steps = steps_per_epoch * args.train_epochs print('steps per epoch:', steps_per_epoch) print('total steps:', total_steps) print('warmup steps:', int(args.warmup_rate * total_steps)) bert_config = AlbertConfig.from_json_file(args.bert_config_file) model = AlBertJointForNQ2(bert_config, long_n_top=5, short_n_top=5) utils.torch_show_all_params(model) utils.torch_init_model(model, args.init_restore_dir) if args.float16: model.half() model.to(device) if n_gpu > 1: model = torch.nn.DataParallel(model) # get the optimizer optimizer = get_optimization(model=model, float16=args.float16, learning_rate=args.lr, total_steps=total_steps, schedule=args.schedule, warmup_rate=args.warmup_rate, max_grad_norm=args.clip_norm,
def main(): parser = argparse.ArgumentParser() ## Required parameters parser.add_argument("--gpu_ids", default='0,1,2,3', type=str) parser.add_argument("--data_dir", default='origin_data/C3', type=str) parser.add_argument("--task_name", default='c3', type=str) parser.add_argument( "--bert_config_file", # albert_xxlarge_google_zh_v1121 # roberta_wwm_ext_large default= 'check_points/pretrain_models/albert_xxlarge_google_zh_v1121/bert_config.json', type=str) parser.add_argument( "--vocab_file", default='check_points/pretrain_models/google_bert_base/vocab.txt', type=str) parser.add_argument( "--output_dir", default='check_points/c3/albert_xxlarge_google_zh_v1121', type=str) ## Other parameters parser.add_argument( "--init_checkpoint", default= 'check_points/pretrain_models/albert_xxlarge_google_zh_v1121/pytorch_model.pth', type=str, help="Initial checkpoint (usually from a pre-trained BERT model).") parser.add_argument( "--do_lower_case", default=True, action='store_true', help= "Whether to lower case the input text. True for uncased models, False for cased models." ) parser.add_argument( "--max_seq_length", default=512, type=int, help= "The maximum total input sequence length after WordPiece tokenization. \n" "Sequences longer than this will be truncated, and sequences shorter \n" "than this will be padded.") parser.add_argument("--do_train", default=True, action='store_true', help="Whether to run training.") parser.add_argument("--do_eval", default=True, action='store_true', help="Whether to run eval on the dev set.") parser.add_argument("--train_batch_size", default=16, type=int, help="Total batch size for training.") parser.add_argument("--eval_batch_size", default=16, type=int, help="Total batch size for eval.") parser.add_argument("--learning_rate", default=2e-5, type=float, help="The initial learning rate for Adam.") parser.add_argument("--schedule", default='warmup_linear', type=str, help='schedule') parser.add_argument("--weight_decay_rate", default=0.01, type=float, help='weight_decay_rate') parser.add_argument('--clip_norm', type=float, default=1.0) parser.add_argument("--num_train_epochs", default=8.0, type=float, help="Total number of training epochs to perform.") parser.add_argument( "--warmup_proportion", default=0.05, type=float, help= "Proportion of training to perform linear learning rate warmup for. " "E.g., 0.1 = 10%% of training.") parser.add_argument("--no_cuda", default=False, action='store_true', help="Whether not to use CUDA when available") parser.add_argument('--float16', type=bool, default=True) parser.add_argument("--local_rank", type=int, default=-1, help="local_rank for distributed training on gpus") parser.add_argument('--seed', type=int, default=345, help="random seed for initialization") parser.add_argument( '--gradient_accumulation_steps', type=int, default=4, help= "Number of updates steps to accumualte before performing a backward/update pass." ) parser.add_argument('--setting_file', type=str, default='setting.txt') parser.add_argument('--log_file', type=str, default='log.txt') args = parser.parse_args() args.setting_file = os.path.join(args.output_dir, args.setting_file) args.log_file = os.path.join(args.output_dir, args.log_file) os.makedirs(args.output_dir, exist_ok=True) with open(args.setting_file, 'wt') as opt_file: opt_file.write('------------ Options -------------\n') print('------------ Options -------------') for k in args.__dict__: v = args.__dict__[k] opt_file.write('%s: %s\n' % (str(k), str(v))) print('%s: %s' % (str(k), str(v))) opt_file.write('-------------- End ----------------\n') print('------------ End -------------') os.environ["CUDA_VISIBLE_DEVICES"] = args.gpu_ids if os.path.exists(args.log_file): os.remove(args.log_file) if args.local_rank == -1 or args.no_cuda: device = torch.device("cuda" if torch.cuda.is_available() and not args.no_cuda else "cpu") n_gpu = torch.cuda.device_count() else: device = torch.device("cuda", args.local_rank) n_gpu = 1 # Initializes the distributed backend which will take care of sychronizing nodes/GPUs torch.distributed.init_process_group(backend='nccl') logger.info("device %s n_gpu %d distributed training %r", device, n_gpu, bool(args.local_rank != -1)) if args.gradient_accumulation_steps < 1: raise ValueError( "Invalid gradient_accumulation_steps parameter: {}, should be >= 1" .format(args.gradient_accumulation_steps)) args.train_batch_size = int(args.train_batch_size / args.gradient_accumulation_steps) random.seed(args.seed) np.random.seed(args.seed) torch.manual_seed(args.seed) if n_gpu > 0: torch.cuda.manual_seed_all(args.seed) if not args.do_train and not args.do_eval: raise ValueError( "At least one of `do_train` or `do_eval` must be True.") processor = c3Processor(args.data_dir) label_list = processor.get_labels() tokenizer = tokenization.BertTokenizer(vocab_file=args.vocab_file, do_lower_case=args.do_lower_case) train_examples = None num_train_steps = None if args.do_train: train_examples = processor.get_train_examples() num_train_steps = int( len(train_examples) / n_class / args.train_batch_size / args.gradient_accumulation_steps * args.num_train_epochs) if 'albert' in args.bert_config_file: if 'google' in args.bert_config_file: bert_config = AlbertConfig.from_json_file(args.bert_config_file) model = AlbertForMultipleChoice(bert_config, num_choices=n_class) else: bert_config = ALBertConfig.from_json_file(args.bert_config_file) model = ALBertForMultipleChoice(bert_config, num_choices=n_class) else: bert_config = BertConfig.from_json_file(args.bert_config_file) model = BertForMultipleChoice(bert_config, num_choices=n_class) if args.max_seq_length > bert_config.max_position_embeddings: raise ValueError( "Cannot use sequence length {} because the BERT model was only trained up to sequence length {}" .format(args.max_seq_length, bert_config.max_position_embeddings)) if args.init_checkpoint is not None: utils.torch_show_all_params(model) utils.torch_init_model(model, args.init_checkpoint) if args.float16: model.half() model.to(device) if args.local_rank != -1: model = torch.nn.parallel.DistributedDataParallel( model, device_ids=[args.local_rank], output_device=args.local_rank) elif n_gpu > 1: model = torch.nn.DataParallel(model) optimizer = get_optimization( model=model, float16=args.float16, learning_rate=args.learning_rate, total_steps=num_train_steps, schedule=args.schedule, warmup_rate=args.warmup_proportion, max_grad_norm=args.clip_norm, weight_decay_rate=args.weight_decay_rate, opt_pooler=True) # multi_choice must update pooler global_step = 0 eval_dataloader = None if args.do_eval: eval_examples = processor.get_dev_examples() feature_dir = os.path.join( args.data_dir, 'dev_features{}.pkl'.format(args.max_seq_length)) if os.path.exists(feature_dir): eval_features = pickle.load(open(feature_dir, 'rb')) else: eval_features = convert_examples_to_features( eval_examples, label_list, args.max_seq_length, tokenizer) with open(feature_dir, 'wb') as w: pickle.dump(eval_features, w) input_ids = [] input_mask = [] segment_ids = [] label_id = [] for f in eval_features: input_ids.append([]) input_mask.append([]) segment_ids.append([]) for i in range(n_class): input_ids[-1].append(f[i].input_ids) input_mask[-1].append(f[i].input_mask) segment_ids[-1].append(f[i].segment_ids) label_id.append(f[0].label_id) all_input_ids = torch.tensor(input_ids, dtype=torch.long) all_input_mask = torch.tensor(input_mask, dtype=torch.long) all_segment_ids = torch.tensor(segment_ids, dtype=torch.long) all_label_ids = torch.tensor(label_id, dtype=torch.long) eval_data = TensorDataset(all_input_ids, all_input_mask, all_segment_ids, all_label_ids) if args.local_rank == -1: eval_sampler = SequentialSampler(eval_data) else: eval_sampler = DistributedSampler(eval_data) eval_dataloader = DataLoader(eval_data, sampler=eval_sampler, batch_size=args.eval_batch_size) if args.do_train: best_accuracy = 0 feature_dir = os.path.join( args.data_dir, 'train_features{}.pkl'.format(args.max_seq_length)) if os.path.exists(feature_dir): train_features = pickle.load(open(feature_dir, 'rb')) else: train_features = convert_examples_to_features( train_examples, label_list, args.max_seq_length, tokenizer) with open(feature_dir, 'wb') as w: pickle.dump(train_features, w) logger.info("***** Running training *****") logger.info(" Num examples = %d", len(train_examples)) logger.info(" Batch size = %d", args.train_batch_size) logger.info(" Num steps = %d", num_train_steps) input_ids = [] input_mask = [] segment_ids = [] label_id = [] for f in train_features: input_ids.append([]) input_mask.append([]) segment_ids.append([]) for i in range(n_class): input_ids[-1].append(f[i].input_ids) input_mask[-1].append(f[i].input_mask) segment_ids[-1].append(f[i].segment_ids) label_id.append(f[0].label_id) all_input_ids = torch.tensor(input_ids, dtype=torch.long) all_input_mask = torch.tensor(input_mask, dtype=torch.long) all_segment_ids = torch.tensor(segment_ids, dtype=torch.long) all_label_ids = torch.tensor(label_id, dtype=torch.long) train_data = TensorDataset(all_input_ids, all_input_mask, all_segment_ids, all_label_ids) if args.local_rank == -1: train_sampler = RandomSampler(train_data) else: train_sampler = DistributedSampler(train_data) train_dataloader = DataLoader(train_data, sampler=train_sampler, batch_size=args.train_batch_size, drop_last=True) steps_per_epoch = int(num_train_steps / args.num_train_epochs) for ie in range(int(args.num_train_epochs)): model.train() tr_loss = 0 nb_tr_examples, nb_tr_steps = 0, 0 with tqdm(total=int(steps_per_epoch), desc='Epoch %d' % (ie + 1)) as pbar: for step, batch in enumerate(train_dataloader): batch = tuple(t.to(device) for t in batch) input_ids, input_mask, segment_ids, label_ids = batch loss = model(input_ids, segment_ids, input_mask, label_ids) if n_gpu > 1: loss = loss.mean() # mean() to average on multi-gpu. if args.gradient_accumulation_steps > 1: loss = loss / args.gradient_accumulation_steps tr_loss += loss.item() if args.float16: optimizer.backward(loss) # modify learning rate with special warm up BERT uses # if args.fp16 is False, BertAdam is used and handles this automatically lr_this_step = args.learning_rate * warmup_linear( global_step / num_train_steps, args.warmup_proportion) for param_group in optimizer.param_groups: param_group['lr'] = lr_this_step else: loss.backward() nb_tr_examples += input_ids.size(0) if (step + 1) % args.gradient_accumulation_steps == 0: optimizer.step( ) # We have accumulated enought gradients model.zero_grad() global_step += 1 nb_tr_steps += 1 pbar.set_postfix({ 'loss': '{0:1.5f}'.format(tr_loss / (nb_tr_steps + 1e-5)) }) pbar.update(1) if args.do_eval: model.eval() eval_loss, eval_accuracy = 0, 0 nb_eval_steps, nb_eval_examples = 0, 0 logits_all = [] for input_ids, input_mask, segment_ids, label_ids in tqdm( eval_dataloader): input_ids = input_ids.to(device) input_mask = input_mask.to(device) segment_ids = segment_ids.to(device) label_ids = label_ids.to(device) with torch.no_grad(): tmp_eval_loss, logits = model(input_ids, segment_ids, input_mask, label_ids, return_logits=True) logits = logits.detach().cpu().numpy() label_ids = label_ids.cpu().numpy() for i in range(len(logits)): logits_all += [logits[i]] tmp_eval_accuracy = accuracy(logits, label_ids.reshape(-1)) eval_loss += tmp_eval_loss.mean().item() eval_accuracy += tmp_eval_accuracy nb_eval_examples += input_ids.size(0) nb_eval_steps += 1 eval_loss = eval_loss / nb_eval_steps eval_accuracy = eval_accuracy / nb_eval_examples if args.do_train: result = { 'eval_loss': eval_loss, 'eval_accuracy': eval_accuracy, 'global_step': global_step, 'loss': tr_loss / nb_tr_steps } else: result = { 'eval_loss': eval_loss, 'eval_accuracy': eval_accuracy } logger.info("***** Eval results *****") for key in sorted(result.keys()): logger.info(" %s = %s", key, str(result[key])) with open(args.log_file, 'a') as aw: aw.write( "-------------------global steps:{}-------------------\n" .format(global_step)) aw.write(str(json.dumps(result, indent=2)) + '\n') if eval_accuracy >= best_accuracy: torch.save(model.state_dict(), os.path.join(args.output_dir, "model_best.pt")) best_accuracy = eval_accuracy model.load_state_dict( torch.load(os.path.join(args.output_dir, "model_best.pt"))) torch.save(model.state_dict(), os.path.join(args.output_dir, "model.pt")) model.load_state_dict(torch.load(os.path.join(args.output_dir, "model.pt"))) if args.do_eval: logger.info("***** Running evaluation *****") logger.info(" Num examples = %d", len(eval_examples)) logger.info(" Batch size = %d", args.eval_batch_size) model.eval() eval_loss, eval_accuracy = 0, 0 nb_eval_steps, nb_eval_examples = 0, 0 logits_all = [] for input_ids, input_mask, segment_ids, label_ids in eval_dataloader: input_ids = input_ids.to(device) input_mask = input_mask.to(device) segment_ids = segment_ids.to(device) label_ids = label_ids.to(device) with torch.no_grad(): tmp_eval_loss, logits = model(input_ids, segment_ids, input_mask, label_ids, return_logits=True) logits = logits.detach().cpu().numpy() label_ids = label_ids.cpu().numpy() for i in range(len(logits)): logits_all += [logits[i]] tmp_eval_accuracy = accuracy(logits, label_ids.reshape(-1)) eval_loss += tmp_eval_loss.mean().item() eval_accuracy += tmp_eval_accuracy nb_eval_examples += input_ids.size(0) nb_eval_steps += 1 eval_loss = eval_loss / nb_eval_steps eval_accuracy = eval_accuracy / nb_eval_examples result = {'eval_loss': eval_loss, 'eval_accuracy': eval_accuracy} output_eval_file = os.path.join(args.output_dir, "results_dev.txt") with open(output_eval_file, "w") as writer: logger.info("***** Eval results *****") for key in sorted(result.keys()): logger.info(" %s = %s", key, str(result[key])) writer.write("%s = %s\n" % (key, str(result[key]))) output_eval_file = os.path.join(args.output_dir, "logits_dev.txt") with open(output_eval_file, "w") as f: for i in range(len(logits_all)): for j in range(len(logits_all[i])): f.write(str(logits_all[i][j])) if j == len(logits_all[i]) - 1: f.write("\n") else: f.write(" ") test_examples = processor.get_test_examples() feature_dir = os.path.join( args.data_dir, 'test_features{}.pkl'.format(args.max_seq_length)) if os.path.exists(feature_dir): test_features = pickle.load(open(feature_dir, 'rb')) else: test_features = convert_examples_to_features( test_examples, label_list, args.max_seq_length, tokenizer) with open(feature_dir, 'wb') as w: pickle.dump(test_features, w) logger.info("***** Running testing *****") logger.info(" Num examples = %d", len(test_examples)) logger.info(" Batch size = %d", args.eval_batch_size) input_ids = [] input_mask = [] segment_ids = [] label_id = [] for f in test_features: input_ids.append([]) input_mask.append([]) segment_ids.append([]) for i in range(n_class): input_ids[-1].append(f[i].input_ids) input_mask[-1].append(f[i].input_mask) segment_ids[-1].append(f[i].segment_ids) label_id.append(f[0].label_id) all_input_ids = torch.tensor(input_ids, dtype=torch.long) all_input_mask = torch.tensor(input_mask, dtype=torch.long) all_segment_ids = torch.tensor(segment_ids, dtype=torch.long) all_label_ids = torch.tensor(label_id, dtype=torch.long) test_data = TensorDataset(all_input_ids, all_input_mask, all_segment_ids, all_label_ids) if args.local_rank == -1: test_sampler = SequentialSampler(test_data) else: test_sampler = DistributedSampler(test_data) test_dataloader = DataLoader(test_data, sampler=test_sampler, batch_size=args.eval_batch_size) model.eval() test_loss, test_accuracy = 0, 0 nb_test_steps, nb_test_examples = 0, 0 logits_all = [] for input_ids, input_mask, segment_ids, label_ids in test_dataloader: input_ids = input_ids.to(device) input_mask = input_mask.to(device) segment_ids = segment_ids.to(device) label_ids = label_ids.to(device) with torch.no_grad(): tmp_test_loss, logits = model(input_ids, segment_ids, input_mask, label_ids, return_logits=True) logits = logits.detach().cpu().numpy() label_ids = label_ids.to('cpu').numpy() for i in range(len(logits)): logits_all += [logits[i]] tmp_test_accuracy = accuracy(logits, label_ids.reshape(-1)) test_loss += tmp_test_loss.mean().item() test_accuracy += tmp_test_accuracy nb_test_examples += input_ids.size(0) nb_test_steps += 1 test_loss = test_loss / nb_test_steps test_accuracy = test_accuracy / nb_test_examples result = {'test_loss': test_loss, 'test_accuracy': test_accuracy} output_test_file = os.path.join(args.output_dir, "results_test.txt") with open(output_test_file, "w") as writer: logger.info("***** Test results *****") for key in sorted(result.keys()): logger.info(" %s = %s", key, str(result[key])) writer.write("%s = %s\n" % (key, str(result[key]))) output_test_file = os.path.join(args.output_dir, "logits_test.txt") with open(output_test_file, "w") as f: for i in range(len(logits_all)): for j in range(len(logits_all[i])): f.write(str(logits_all[i][j])) if j == len(logits_all[i]) - 1: f.write("\n") else: f.write(" ")