# coding=utf-8 # Copyright (c) 2020, NVIDIA CORPORATION. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """Finetune utilities.""" import torch import torch.nn.functional as F from functools import partial from megatron import get_args from megatron import print_rank_0 from megatron import get_timers from megatron import mpu from megatron.checkpointing import load_checkpoint from megatron.checkpointing import save_checkpoint from megatron.training import evaluate_and_print_results from megatron.training import setup_model_and_optimizer from megatron.training import train_step from megatron.training import training_log from megatron.utils import check_adlr_autoresume_termination from megatron.utils import average_losses_across_data_parallel_group def process_batch(batch): """Process batch and produce inputs for the model.""" images = batch[0].cuda().contiguous() labels = batch[1].cuda().contiguous() return images, labels def cross_entropy_loss_func(labels, output_tensor): logits = output_tensor # Cross-entropy loss. loss = F.cross_entropy(logits.contiguous().float(), labels) # Reduce loss for logging. averaged_loss = average_losses_across_data_parallel_group([loss]) return loss, {'lm loss': averaged_loss[0]} def _cross_entropy_forward_step(batch, model): """Simple forward step with cross-entropy loss.""" timers = get_timers() # Get the batch. timers("batch generator").start() try: batch_ = next(batch) except BaseException: batch_ = batch images, labels = process_batch(batch_) timers("batch generator").stop() # Forward model. output_tensor = model(images) return output_tensor, partial(cross_entropy_loss_func, labels) def build_data_loader(dataset, micro_batch_size, num_workers, drop_last): """Data loader. Note that batch-size is the local (per GPU) batch-size.""" # Sampler. world_size = mpu.get_data_parallel_world_size() rank = mpu.get_data_parallel_rank() sampler = torch.utils.data.distributed.DistributedSampler( dataset, num_replicas=world_size, rank=rank ) # Data loader. Note that batch size is the per GPU batch size. data_loader = torch.utils.data.DataLoader( dataset, batch_size=micro_batch_size, sampler=sampler, shuffle=False, num_workers=num_workers, drop_last=drop_last, pin_memory=True, ) return data_loader def _build_infinite_size_dataloader(dataloader): """Build a looped dataloader with infinite size.""" iterator = dataloader.__iter__() while True: try: yield iterator.__next__() except StopIteration: iterator = dataloader.__iter__() def _build_train_valid_dataloaders(train_dataset, valid_dataset): """Traing and validation dataloaders.""" args = get_args() print_rank_0('building train and validation dataloaders ...') # Training dataset. train_dataloader = build_data_loader(train_dataset, args.micro_batch_size, args.num_workers, not args.keep_last) # Set the training iterations. args.train_iters_per_epoch = len(train_dataloader) args.train_iters = args.epochs * args.train_iters_per_epoch # Validation dataset. For this dataset, we do not need to set up # shuffling so we can just use a simple infinite loop. valid_dataloader_ = build_data_loader(valid_dataset, args.micro_batch_size, args.num_workers, not args.keep_last) valid_dataloader = _build_infinite_size_dataloader(valid_dataloader_) # Now that we've built the data loaders, set batch_size arguments # to the actual batch size the model will see for this dataset. # This is necessary so pipeline transfers know what size they are # and the LR schedule, which is based on samples seen, gets set # correctly. args.orig_micro_batch_size = args.micro_batch_size args.orig_global_batch_size = args.global_batch_size return train_dataloader, valid_dataloader def _train( model, optimizer, lr_scheduler, forward_step, train_dataloader, valid_dataloader, end_of_epoch_callback, ): """Train the model.""" args = get_args() timers = get_timers() # Turn on training mode which enables dropout. for m in model: m.train() # Tracking loss. losses_dict_sum = {} # Starting epoch and iteration start_epoch = args.iteration // args.train_iters_per_epoch start_iteration = args.iteration % args.train_iters_per_epoch iteration = args.iteration # Memory reporting flag. report_memory_flag = True # For each remaining epoch timers("interval-time").start() for epoch in range(start_epoch, args.epochs): print_rank_0("working on epoch {} ...".format(epoch + 1)) # Set the data loader epoch to shuffle the index iterator. train_dataloader.sampler.set_epoch(args.seed + epoch) # For all the batches in the dataset. for iteration_, batch in enumerate(train_dataloader): # Ignore the iterations before starting value if iteration_ < start_iteration: continue # Set to zero so the next epoch does not skip any batches. start_iteration = 0 # Train for one step. losses_dict, skipped_iter, grad_norm, num_zeros_in_grad = train_step( forward_step, batch, model, optimizer, lr_scheduler ) iteration += 1 # Logging. params_norm = None if args.log_params_norm: params_norm = calc_params_l2_norm(model) report_memory_flag = training_log( losses_dict, losses_dict_sum, optimizer.param_groups[0]["lr"], iteration, optimizer.get_loss_scale().item(), report_memory_flag, skipped_iter, grad_norm, params_norm, num_zeros_in_grad ) # Autoresume if args.adlr_autoresume and ( iteration % args.adlr_autoresume_interval == 0 ): check_adlr_autoresume_termination( iteration, model, optimizer, lr_scheduler ) # Checkpointing if ( args.save and args.save_interval and iteration % args.save_interval == 0 ): save_checkpoint(iteration, model, optimizer, lr_scheduler) # Evaluation if args.eval_interval and iteration % args.eval_interval == 0: prefix = "iteration {}".format(iteration) evaluate_and_print_results( prefix, forward_step, valid_dataloader, model, iteration, False, ) # Checkpointing at the end of each epoch. if args.save: save_checkpoint(iteration, model, optimizer, lr_scheduler) # Callback at the end of each epoch. if end_of_epoch_callback is not None: end_of_epoch_callback(model, epoch) def finetune( train_valid_datasets_provider, model_provider, forward_step=_cross_entropy_forward_step, end_of_epoch_callback_provider=None, ): """Main finetune function used across all tasks.""" args = get_args() timers = get_timers() # Train and validation data loaders. timers("train/valid/test dataset/dataloder").start() if args.epochs > 0: train_dataset, valid_dataset = train_valid_datasets_provider() train_dataloader, valid_dataloader = _build_train_valid_dataloaders( train_dataset, valid_dataset ) timers("train/valid/test dataset/dataloder").stop() # Build calback function. timers("callback function").start() end_of_epoch_callback = None if end_of_epoch_callback_provider is not None: end_of_epoch_callback = end_of_epoch_callback_provider() timers("callback function").stop() # Build model, optimizer and learning rate scheduler. timers("model and optimizer").start() model, optimizer, lr_scheduler = setup_model_and_optimizer(model_provider) timers("model and optimizer").stop() # If pretrained checkpoint is provided and we have not trained for # any iteration (i.e., iteration is zero), then load the pretrained # checkpoint. timers("pretrained checkpoint").start() if args.iteration == 0 and args.pretrained_checkpoint is not None: original_load = args.load args.load = args.pretrained_checkpoint _ = load_checkpoint(model, None, None, strict=False) args.load = original_load # This is critical when only model is loaded. We should make sure # master parameters are also updated. optimizer.reload_model_params() timers("pretrained checkpoint").stop() # Print setup timing. print_rank_0("done with setups ...") timers.log( [ "train/valid/test dataset/dataloder", "callback function", "model and optimizer", "pretrained checkpoint", ] ) print_rank_0("training ...") # Finetune the model. if args.epochs > 0: _train( model, optimizer, lr_scheduler, forward_step, train_dataloader, valid_dataloader, end_of_epoch_callback, ) # Or just evaluate. else: if end_of_epoch_callback is not None: print_rank_0("evaluation only mode, setting epoch to -1") end_of_epoch_callback(model, epoch=-1, output_predictions=True) print_rank_0("done :-)")