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pretrain_gpt2.py
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pretrain_gpt2.py
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# coding=utf-8
# Copyright (c) 2019, 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.
"""Pretrain GPT2"""
# Flag to use Pytorch ddp which uses overlapping communication and computation.
USE_TORCH_DDP = True
from datetime import datetime
import os
import math
from filelock import FileLock
import torch
import deepspeed
import pathlib
from contextlib import ExitStack
from arguments import get_args
from configure_data import configure_data
from fp16 import FP16_Module
from fp16 import FP16_Optimizer
from learning_rates import AnnealingLR
from model import GPT2Model
from model import gpt2_get_params_for_weight_decay_optimization
if USE_TORCH_DDP:
from model import PyTorchDistributedDataParallel as DDP
else:
from model import DistributedDataParallel as DDP
import mpu
from apex.optimizers import FusedAdam as Adam
from utils import Timers, set_random_seed
from utils import save_checkpoint
from utils import load_checkpoint
from utils import report_memory
from utils import print_args
from utils import print_rank_0
from utils import get_sample_writer
import torch.distributed as dist
from gpt2_data_loader import make_gpt2_dataloaders
def get_model(args):
"""Build the model."""
print_rank_0('building GPT2 model ...')
model = GPT2Model(num_layers=args.num_layers,
vocab_size=args.vocab_size,
hidden_size=args.hidden_size,
num_attention_heads=args.num_attention_heads,
embedding_dropout_prob=args.hidden_dropout,
attention_dropout_prob=args.attention_dropout,
output_dropout_prob=args.hidden_dropout,
max_sequence_length=args.max_position_embeddings,
max_memory_length=args.mem_length,
checkpoint_activations=args.checkpoint_activations,
checkpoint_num_layers=args.checkpoint_num_layers,
parallel_output=True,
relative_encoding=args.transformer_xl)
if mpu.get_data_parallel_rank() == 0:
print(' > number of parameters on model parallel rank {}: {}'.format(
mpu.get_model_parallel_rank(),
sum([p.nelement() for p in model.parameters()])), flush=True)
# To prevent OOM for model sizes that cannot fit in GPU memory in full precision
if hasattr(args, "deepspeed") and args.deepspeed and args.fp16:
model.half()
# GPU allocation.
model.cuda(torch.cuda.current_device())
# Fp16 conversion.
if args.fp16:
model = FP16_Module(model)
# Wrap model for distributed training.
if not args.deepspeed:
if USE_TORCH_DDP:
i = torch.cuda.current_device()
model = DDP(model, device_ids=[i], output_device=i,
process_group=mpu.get_data_parallel_group())
else:
model = DDP(model)
return model
def get_optimizer_param_groups(model):
# Build parameter groups (weight decay and non-decay).
while isinstance(model, (DDP, FP16_Module)):
model = model.module
param_groups = gpt2_get_params_for_weight_decay_optimization(model)
# Add model parallel attribute if it is not set.
for param_group in param_groups:
for param in param_group['params']:
if not hasattr(param, 'model_parallel'):
param.model_parallel = False
return param_groups
def get_optimizer(param_groups, args):
"""Set up the optimizer."""
if args.cpu_optimizer:
#Apex FusedAdam uses decoupled weight decay so use the same here
if args.cpu_torch_adam:
cpu_adam_optimizer = torch.optim.AdamW
else:
#TODO add option for decoupled weight decay in DeepCPUAdam
from deepspeed.ops.adam import DeepSpeedCPUAdam
cpu_adam_optimizer = DeepSpeedCPUAdam
optimizer = cpu_adam_optimizer(param_groups,
lr=args.lr, weight_decay=args.weight_decay)
else:
# Use FusedAdam.
optimizer = Adam(param_groups,
lr=args.lr, weight_decay=args.weight_decay)
print(f'Optimizer = {optimizer.__class__.__name__}')
if hasattr(args, "deepspeed") and args.deepspeed:
raise NotImplementedError
# fp16 wrapper is not required for DeepSpeed.
# return optimizer
# Wrap into fp16 optimizer.
if args.fp16:
optimizer = FP16_Optimizer(optimizer,
static_loss_scale=args.loss_scale,
dynamic_loss_scale=args.dynamic_loss_scale,
dynamic_loss_args={
'scale_window': args.loss_scale_window,
'min_scale': args.min_scale,
'delayed_shift': args.hysteresis})
return optimizer
def get_learning_rate_scheduler(optimizer, args):
"""Build the learning rate scheduler."""
# Add linear learning rate scheduler.
if args.lr_decay_iters is not None:
num_iters = args.lr_decay_iters
else:
num_iters = args.train_iters
num_iters = max(1, num_iters)
init_step = -1
warmup_iter = args.warmup * num_iters
lr_scheduler = AnnealingLR(optimizer,
start_lr=args.lr,
warmup_iter=warmup_iter,
num_iters=num_iters,
decay_style=args.lr_decay_style,
last_iter=init_step,
decay_ratio=args.lr_decay_ratio)
return lr_scheduler
def setup_model_and_optimizer(args):
"""Setup model and optimizer."""
model = get_model(args)
param_groups = get_optimizer_param_groups(model)
if args.train_data is not None:
if args.deepspeed:
print_rank_0("DeepSpeed is enabled.")
model, optimizer, _, _ = deepspeed.initialize(
model=model,
model_parameters=param_groups,
args=args,
mpu=mpu,
dist_init_required=False
)
else:
optimizer = get_optimizer(param_groups, args)
lr_scheduler = get_learning_rate_scheduler(optimizer, args)
else:
optimizer, lr_scheduler = None, None
return model, optimizer, lr_scheduler
def get_masks_and_position_ids(data,
eod_token,
reset_position_ids,
reset_attention_mask,
loss_mask=None,
attention_mask=None,
transformer_xl=False,
mem_length=None):
# Extract batch size and sequence length.
batch_size, seq_length = data.size()
# Attention mask (lower triangular).
if transformer_xl:
if attention_mask is None:
attention_mask = torch.ones((1, seq_length, seq_length + mem_length), device=data.device)
attention_mask = torch.tril(torch.triu(attention_mask, 1 - seq_length + mem_length), mem_length)
else:
if reset_attention_mask:
att_mask_batch = batch_size
else:
att_mask_batch = 1
if attention_mask is None:
attention_mask = torch.ones((att_mask_batch, seq_length, seq_length), device=data.device)
attention_mask = torch.tril(attention_mask)
attention_mask = attention_mask.unsqueeze(1)
# Loss mask.
if loss_mask is None:
loss_mask = torch.ones(data.size(), dtype=torch.float, device=data.device)
# Position ids.
position_ids = torch.arange(seq_length, dtype=torch.long,
device=data.device)
position_ids = position_ids.unsqueeze(0).expand_as(data)
if not transformer_xl:
loss_mask[data == eod_token] = 0.0
# We need to clone as the ids will be modifed based on batch index.
if reset_position_ids:
position_ids = position_ids.clone()
if reset_position_ids or reset_attention_mask:
# Loop through the batches:
for b in range(batch_size):
# Find indecies where EOD token is.
eod_index = position_ids[b, data[b] == eod_token]
# Detach indecies from positions if going to modify positions.
if reset_position_ids:
eod_index = eod_index.clone()
# Loop through EOD indecies:
prev_index = 0
for j in range(eod_index.size()[0]):
i = eod_index[j]
# Mask attention loss.
if reset_attention_mask:
attention_mask[b, 0, (i+1):, :(i+1)] = 0
# Reset positions.
if reset_position_ids:
position_ids[b, (i+1):] -= (i + 1 - prev_index)
prev_index = i + 1
return attention_mask, loss_mask, position_ids
def get_batch(data_iterator, args, timers):
''' get_batch subdivides the source data into chunks of
length args.seq_length. If source is equal to the example
output of the data loading example, with a seq_length limit
of 2, we'd get the following two Variables for i = 0:
┌ a g m s ┐ ┌ b h n t ┐
└ b h n t ┘ └ c i o u ┘
Note that despite the name of the function, the subdivison of data is not
done along the batch dimension (i.e. dimension 1), since that was handled
by the data loader. The chunks are along dimension 0, corresponding
to the seq_len dimension in the LSTM. A Variable representing an appropriate
shard reset mask of the same dimensions is also returned.
'''
# Items and their type.
keys = ['text', 'target', 'loss_mask', 'attention_mask'] if args.xl_dataset else ['text', 'loss_mask']
datatype = torch.int64
# Broadcast data.
timers('data loader').start()
if data_iterator is not None:
data = next(data_iterator)
else:
data = None
timers('data loader').stop()
data_b = mpu.broadcast_data(keys, data, datatype)
# Unpack.
if args.xl_dataset:
tokens = data_b['text'].long()
labels = data_b['target'].long()
attention_mask = data_b['attention_mask'].float()
loss_mask = data_b['loss_mask'].float()
else:
tokens_ = data_b['text'].long()
loss_mask = data_b['loss_mask'].float()
labels = tokens_[:, 1:].contiguous()
loss_mask = loss_mask[:, 1:].contiguous()
tokens = tokens_[:, :-1].contiguous()
attention_mask = None
# Get the masks and postition ids.
attention_mask, loss_mask, position_ids = get_masks_and_position_ids(
tokens,
args.eod_token,
args.reset_position_ids,
args.reset_attention_mask,
loss_mask=loss_mask,
attention_mask=attention_mask,
transformer_xl=args.xl_dataset,
mem_length=args.mem_length)
# Convert
if args.fp16:
attention_mask = attention_mask.half()
return tokens, labels, loss_mask, attention_mask, position_ids
tokenizer = None
def forward_step(data_iterator, model, args, timers, mems):
"""Forward step."""
# Get the batch.
timers('batch generator').start()
tokens, labels, loss_mask, attention_mask, position_ids = get_batch(
data_iterator, args, timers)
# global last_tokens
# last_tokens = tokens.tolist()
# if last_tokens is not None:
# for i in range(len(tokens)):
# if tokens[i][0] != 0 and tokens[i][0] != last_tokens[i] + 1:
# breakpoint()
# last_tokens = tokens[:, -1].tolist()
timers('batch generator').stop()
# Forward model.
logits, *mems = model(tokens, position_ids, attention_mask, *mems)
losses = mpu.vocab_parallel_cross_entropy(logits.contiguous().float(),
labels)
loss_mask = loss_mask.view(-1)
loss = torch.sum(losses.view(-1) * loss_mask) / loss_mask.sum()
return loss, mems
def backward_step(optimizer, model, lm_loss, args, timers):
"""Backward step."""
# Total loss.
loss = lm_loss
# Backward pass.
if args.deepspeed:
model.backward(loss)
else:
optimizer.zero_grad()
if args.fp16:
optimizer.backward(loss, update_master_grads=False)
else:
loss.backward()
reduced_losses = lm_loss.view(1)
if args.deepspeed:
# DeepSpeed backward propagation already addressed all reduce communication.
# Reset the timer to avoid breaking timer logs below.
timers('allreduce').reset()
else:
torch.distributed.all_reduce(reduced_losses.data)
reduced_losses.data = reduced_losses.data / args.world_size
if not USE_TORCH_DDP:
timers('allreduce').start()
model.allreduce_params(reduce_after=False,
fp32_allreduce=args.fp32_allreduce)
timers('allreduce').stop()
lm_loss_reduced = reduced_losses
# Update master gradients.
if not args.deepspeed:
if args.fp16:
optimizer.update_master_grads()
# Clipping gradients helps prevent the exploding gradient.
if args.clip_grad > 0:
if not args.fp16:
mpu.clip_grad_norm(model.parameters(), args.clip_grad)
else:
optimizer.clip_master_grads(args.clip_grad)
return lm_loss_reduced
def see_memory_usage(message, force=False):
if not force:
return
dist.barrier()
if dist.get_rank() == 0:
print(message)
print("Memory Allocated ", torch.cuda.memory_allocated()/(1024*1024*1024), "GigaBytes")
print("Max Memory Allocated ", torch.cuda.max_memory_allocated()/(1024*1024*1024), "GigaBytes")
print("Cache Allocated ", torch.cuda.memory_cached()/(1024*1024*1024), "GigaBytes")
print("Max cache Allocated ", torch.cuda.max_memory_cached()/(1024*1024*1024), "GigaBytes")
print(" ")
#input("Press Any Key To Continue ..")
def train_step(data_iterator, model, optimizer, lr_scheduler,
args, timers, mems):
"""Single training step."""
while True:
# Forward model for one step.
timers('forward').start()
lm_loss, mems = forward_step(data_iterator, model, args, timers, mems)
timers('forward').stop()
#print_rank_0("loss is {}".format(lm_loss))
# Calculate gradients, reduce across processes, and clip.
timers('backward').start()
lm_loss_reduced = backward_step(optimizer, model, lm_loss, args, timers)
timers('backward').stop()
# Update parameters.
skipped_iter, complete = 0, False
timers('optimizer').start()
if args.deepspeed:
if model.is_gradient_accumulation_boundary():
model.step()
complete = True
if not (args.fp16 and optimizer.overflow):
lr_scheduler.step()
else:
skipped_iter = 1
else:
model.step()
else:
optimizer.step()
complete = True
# Update learning rate.
if not (args.fp16 and optimizer.overflow):
lr_scheduler.step()
else:
skipped_iter = 1
timers('optimizer').stop()
if complete:
break
return lm_loss_reduced, skipped_iter, mems
def report_iteration_metrics(summary_writer, optimizer, lr, loss, elapsed_time, step, total_step, args):
log_string = ' iteration {:8d}/{:8d} |'.format(step, total_step)
log_string += ' elapsed time per iteration (ms): {:.1f} |'.format(elapsed_time)
log_string += ' learning rate {:.3E} |'.format(lr)
log_string += ' lm loss {:.6E} |'.format(loss)
if args.fp16:
log_string += ' loss scale {:.1f} |'.format(
optimizer.cur_scale if args.deepspeed else optimizer.loss_scale)
print_rank_0(log_string)
if summary_writer is not None:
summary_writer.add_scalar(f'Train/lr', lr, step)
summary_writer.add_scalar(f'Train/train_loss', loss, step)
summary_writer.add_scalar(f'Train/elapsed_time', elapsed_time, step)
def report_evaluate_metrics(summary_writer, prefix, loss, ppl, step):
string = ' validation loss at {} | '.format(prefix)
string += 'LM loss: {:.6E} | '.format(loss)
string += 'LM PPL: {:.6E}'.format(ppl)
length = len(string) + 1
print_rank_0('-' * 100)
print_rank_0('-' * length)
print_rank_0(string)
print_rank_0('-' * length)
if summary_writer is not None:
summary_writer.add_scalar(f'Train/valid_ppl', ppl, step)
summary_writer.add_scalar(f'Train/valid_loss', loss, step)
def train(model, optimizer, lr_scheduler,
train_data_iterator, val_data_iterator, timers, args, summary_writer=None):
"""Train the model."""
# Turn on training mode which enables dropout.
model.train()
# Tracking loss.
total_lm_loss = 0.0
# Iterations.
skipped_iters = 0
timers('interval time').start()
report_memory_flag = True
mems = []
while args.iteration < args.train_iters:
lm_loss, skipped_iter, mems = train_step(train_data_iterator,
model,
optimizer,
lr_scheduler,
args, timers, mems)
skipped_iters += skipped_iter
args.iteration += 1
# Update losses.
total_lm_loss += lm_loss.data.detach().float()
# Logging.
if args.iteration % args.log_interval == 0:
learning_rate = optimizer.param_groups[0]['lr']
avg_lm_loss = total_lm_loss.item() / args.log_interval
elapsed_time = timers('interval time').elapsed()
report_iteration_metrics(summary_writer, optimizer, learning_rate, avg_lm_loss,
elapsed_time * 1000.0 / args.log_interval, args.iteration, args.train_iters, args)
total_lm_loss = 0.0
if report_memory_flag:
report_memory('after {} iterations'.format(args.iteration))
report_memory_flag = False
if USE_TORCH_DDP:
timers.log(['forward', 'backward', 'optimizer',
'batch generator', 'data loader'],
normalizer=args.log_interval)
else:
timers.log(['forward', 'backward', 'allreduce', 'optimizer',
'batch generator', 'data loader'],
normalizer=args.log_interval)
# Checkpointing
if args.save and args.save_interval and args.iteration % args.save_interval == 0:
save_checkpoint(args.iteration, model, optimizer, lr_scheduler, args)
# Evaluation
if args.eval_interval and args.iteration % args.eval_interval == 0 and args.do_valid:
prefix = 'iteration {}'.format(args.iteration)
evaluate_and_print_results(
prefix, val_data_iterator, model, args, timers, False, step=args.iteration, summary_writer=summary_writer)
if args.exit_interval and args.iteration % args.exit_interval == 0:
torch.distributed.barrier()
time_str = datetime.now().strftime('%Y-%m-%d %H:%M:%S')
rank = torch.distributed.get_rank()
print('rank: {} | time: {} | exiting the program at iteration {}'.
format(rank, time_str, args.iteration), flush=True)
exit()
return args.iteration, skipped_iters
def evaluate(data_iterator, model, args, timers, verbose=False):
"""Evaluation."""
# Turn on evaluation mode which disables dropout.
model.eval()
total_lm_loss = 0
mems = []
with torch.no_grad():
iteration = 0
while iteration < args.eval_iters:
iteration += 1
if verbose and iteration % args.log_interval == 0:
print_rank_0('Evaluating iter {}/{}'.format(iteration, args.eval_iters))
# Forward evaluation.
lm_loss, mems = forward_step(data_iterator, model, args, timers, mems=mems)
'''when contiguous memory optimizations are enabled, the buffers
allocated by the optimizations are deallocated during backward pass
in the absence of backward pass the buffers should be reset after each
forward pass'''
if args.deepspeed and args.deepspeed_activation_checkpointing:
deepspeed.checkpointing.reset()
# Reduce across processes.
if isinstance(model, DDP):
torch.distributed.all_reduce(lm_loss.data)
lm_loss.data = lm_loss.data / args.world_size
total_lm_loss += lm_loss.data.detach().float().item()
# Move model back to the train mode.
model.train()
total_lm_loss /= args.eval_iters
return total_lm_loss
def evaluate_and_print_results(prefix, data_iterator, model,
args, timers, verbose=False, step=None, summary_writer=None):
"""Helper function to evaluate and dump results on screen."""
lm_loss = evaluate(data_iterator, model, args, timers, verbose)
lm_ppl = math.exp(min(20, lm_loss))
report_evaluate_metrics(summary_writer, prefix, lm_loss, lm_ppl, step)
return lm_loss
'''
Optional DeepSpeed Activation Checkpointing features
Gives access to partition activations, contiguous memory optimizations
and cpu checkpointing.
Activation checkpoint requires keep track of the random states
and setting the random seed for each MP process. Megatron uses
mpu.get_cuda_rng_tracker and mpu.model_parallel_cuda_manual_seed
for keeping track of the random states and setting the random seeds.
Since they are used in places outside of activation checkpointing,
we overwrite them to maintain consistency.
This must be done before all the calls to mpu.model_parallel_cuda_manual_seed
'''
def set_deepspeed_activation_checkpointing(args):
deepspeed.checkpointing.configure(mpu, deepspeed_config=args.deepspeed_config, num_checkpoints=args.num_layers)
mpu.checkpoint = deepspeed.checkpointing.checkpoint
mpu.get_cuda_rng_tracker = deepspeed.checkpointing.get_cuda_rng_tracker
mpu.model_parallel_cuda_manual_seed = deepspeed.checkpointing.model_parallel_cuda_manual_seed
def initialize_distributed(args):
"""Initialize torch.distributed."""
# Manually set the device ids.
device = args.rank % torch.cuda.device_count()
if args.local_rank is not None:
device = args.local_rank
torch.cuda.set_device(device)
# Call the init process
init_method = 'tcp://'
master_ip = os.getenv('MASTER_ADDR', 'localhost')
master_port = os.getenv('MASTER_PORT', '6000')
init_method += master_ip + ':' + master_port
torch.distributed.init_process_group(
backend=args.distributed_backend,
world_size=args.world_size, rank=args.rank,
init_method=init_method)
# Set the model-parallel / data-parallel communicators.
mpu.initialize_model_parallel(args.model_parallel_size)
# Optional DeepSpeed Activation Checkpointing Features
#
if hasattr(args, "deepspeed") and args.deepspeed and args.deepspeed_activation_checkpointing:
set_deepspeed_activation_checkpointing(args)
def get_train_val_test_data(args):
"""Load the data on rank zero and boradcast number of tokens to all GPUS."""
(train_data, val_data, test_data) = (None, None, None)
global tokenizer
# Data loader only on rank 0 of each model parallel group.
if mpu.get_model_parallel_rank() == 0:
if args.use_npy_data_loader:
(train_data, val_data, test_data), num_tokens, \
eod_token = make_gpt2_dataloaders(args)
else:
data_config = configure_data()
data_config.set_defaults(data_set_type='GPT2', transpose=False)
(train_data, val_data, test_data), tokenizer = data_config.apply(
args)
num_tokens = tokenizer.num_tokens
eod_token = tokenizer.get_command('eos').Id
assert eod_token == tokenizer.get_command('pad').Id
before = num_tokens
after = before
multiple = args.make_vocab_size_divisible_by * \
mpu.get_model_parallel_world_size()
while (after % multiple) != 0:
after += 1
print_rank_0('> padded vocab (size: {}) with {} dummy '
'tokens (new size: {})'.format(
before, after - before, after))
print_rank_0('> found end-of-document token: {}'.format(eod_token))
token_counts = torch.cuda.LongTensor(
[after, eod_token, int(args.do_train), int(args.do_valid), int(args.do_test)])
else:
token_counts = torch.cuda.LongTensor([0, 0, 0, 0, 0])
# Broadcast num tokens.
torch.distributed.broadcast(token_counts,
mpu.get_model_parallel_src_rank(),
group=mpu.get_model_parallel_group())
num_tokens = token_counts[0].item()
eod_token = token_counts[1].item()
args.do_train = token_counts[2].item()
args.do_valid = token_counts[3].item()
args.do_test = token_counts[4].item()
return train_data, val_data, test_data, num_tokens, eod_token
def main():
"""Main training program."""
# Disable CuDNN.
torch.backends.cudnn.enabled = False
# Timer.
timers = Timers()
# Arguments.
args = get_args()
args.mem_length = args.mem_length if args.transformer_xl else 0
if args.load and not args.finetune:
args.experiment_name = os.path.basename(os.path.normpath(args.load))
else:
args.experiment_name = args.experiment_name + datetime.now().strftime("%m-%d-%H-%M")
if args.save:
args.save = os.path.join(args.save, args.experiment_name)
# Pytorch distributed.
initialize_distributed(args)
# Random seeds for reproducability.
set_random_seed(args.seed)
# Data stuff.
train_data, val_data, test_data, args.vocab_size, \
args.eod_token = get_train_val_test_data(args)
# Model, optimizer, and learning rate.
model, optimizer, lr_scheduler = setup_model_and_optimizer(args)
if args.load is not None:
with FileLock(os.path.join(pathlib.Path.home(), "checkpoint_lock"), timeout=-1):
args.iteration = load_checkpoint(model, optimizer, lr_scheduler, args)
else:
args.iteration = 0
torch.distributed.barrier()
summary_writer = None
if torch.distributed.get_rank() == 0:
print('Pretrain GPT2 model')
print_args(args)
summary_writer = get_sample_writer(base=args.summary_dir, name=args.experiment_name, iteration=args.iteration)
# Resume data loader if necessary.
if args.resume_dataloader:
if train_data is not None:
train_data.batch_sampler.start_iter = args.iteration % \
len(train_data)
if val_data is not None:
start_iter_val = (args.train_iters // args.save_interval) * \
args.eval_interval
val_data.batch_sampler.start_iter = start_iter_val % \
len(val_data)
if train_data is not None:
train_data_iterator = iter(train_data)
else:
train_data_iterator = None
if val_data is not None:
val_data_iterator = iter(val_data)
else:
val_data_iterator = None
# TODO: figure out how to properly set this especially when resuming training
iteration = 0
if args.train_iters > 0:
if args.do_train:
with ExitStack() as stack:
def save_on_exit(args_, model_, optimizer_, lr_scheduler_):
save_checkpoint(args_.iteration, model_, optimizer_, lr_scheduler_, args_)
# stack.callback(save_on_exit, args, model, optimizer, lr_scheduler)
iteration, skipped = train(model, optimizer,
lr_scheduler,
train_data_iterator,
val_data_iterator,
timers, args, summary_writer=summary_writer)
if args.do_valid:
prefix = 'the end of training for val data'
val_loss = evaluate_and_print_results(prefix, val_data_iterator,
model, args, timers, False)
if args.save and iteration != 0:
save_checkpoint(iteration, model, optimizer, lr_scheduler, args)
if test_data is not None:
test_data_iterator = iter(test_data)
else:
test_data_iterator = None
if args.do_test:
# Run on test data.
prefix = 'the end of training for test data'
evaluate_and_print_results(prefix, test_data_iterator,
model, args, timers, True)
if __name__ == "__main__":
main()