ReactSeq / onmt /trainer.py
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"""
This is the loadable seq2seq trainer library that is
in charge of training details, loss compute, and statistics.
See train.py for a use case of this library.
Note: To make this a general library, we implement *only*
mechanism things here(i.e. what to do), and leave the strategy
things to users(i.e. how to do it). Also see train.py(one of the
users of this library) for the strategy things we do.
"""
import time
import sys
import torch
import traceback
import onmt.utils
from onmt.utils.loss import LossCompute
from onmt.utils.logging import logger
from onmt.utils.scoring_utils import ScoringPreparator
from onmt.scorers import get_scorers_cls, build_scorers
def build_trainer(opt, device_id, model, vocabs, optim, model_saver=None):
"""
Simplify `Trainer` creation based on user `opt`s*
Args:
opt (:obj:`Namespace`): user options (usually from argument parsing)
model (:obj:`onmt.models.NMTModel`): the model to train
fields (dict): dict of fields
optim (:obj:`onmt.utils.Optimizer`): optimizer used during training
data_type (str): string describing the type of data
e.g. "text"
model_saver(:obj:`onmt.models.ModelSaverBase`): the utility object
used to save the model
"""
train_loss = LossCompute.from_opts(opt, model, vocabs["tgt"])
valid_loss = LossCompute.from_opts(opt, model, vocabs["tgt"], train=False)
scoring_preparator = ScoringPreparator(vocabs=vocabs, opt=opt)
validset_transforms = opt.data.get("valid", {}).get("transforms", None)
if validset_transforms:
scoring_preparator.warm_up(validset_transforms)
scorers_cls = get_scorers_cls(opt.valid_metrics)
valid_scorers = build_scorers(opt, scorers_cls)
trunc_size = opt.truncated_decoder # Badly named...
norm_method = opt.normalization
accum_count = opt.accum_count
accum_steps = opt.accum_steps
n_gpu = opt.world_size
parallel_mode = opt.parallel_mode
average_decay = opt.average_decay
average_every = opt.average_every
dropout = opt.dropout
attention_dropout = opt.attention_dropout
dropout_steps = opt.dropout_steps
zero_out_prompt_loss = opt.zero_out_prompt_loss
if device_id >= 0:
gpu_rank = opt.gpu_ranks[device_id]
else:
gpu_rank = -1
n_gpu = 0
earlystopper = (
onmt.utils.EarlyStopping(
opt.early_stopping, scorers=onmt.utils.scorers_from_opts(opt)
)
if opt.early_stopping > 0
else None
)
report_manager = onmt.utils.build_report_manager(opt, gpu_rank)
trainer = Trainer(
model,
train_loss,
valid_loss,
scoring_preparator,
valid_scorers,
optim,
trunc_size,
norm_method,
accum_count,
accum_steps,
n_gpu,
gpu_rank,
parallel_mode,
report_manager,
with_align=True if opt.lambda_align > 0 else False,
model_saver=model_saver,
average_decay=average_decay,
average_every=average_every,
model_dtype=opt.model_dtype,
earlystopper=earlystopper,
dropout=dropout,
attention_dropout=attention_dropout,
dropout_steps=dropout_steps,
zero_out_prompt_loss=zero_out_prompt_loss,
)
return trainer
class Trainer(object):
"""Class that controls the training process.
Args:
model(:py:class:`onmt.models.model.NMTModel`): model to train
train_loss(:obj:`onmt.utils.loss.LossComputeBase`):
training loss computation
valid_loss(:obj:`onmt.utils.loss.LossComputeBase`):
training loss computation
scoring_preparator(:obj:`onmt.translate.utils.ScoringPreparator`):
preparator for the calculation of metrics via the
_eval_handler method
valid_scorers (dict): keeps in memory the current values
of the validation metrics
optim(:obj:`onmt.utils.optimizers.Optimizer`):
the optimizer responsible for update
trunc_size(int): length of truncated back propagation
through time
accum_count(list): accumulate gradients this many times.
accum_steps(list): steps for accum gradients changes.
n_gpu (int): number of gpu.
gpu_rank (int): ordinal rank of the gpu in the list.
report_manager(:obj:`onmt.utils.ReportMgrBase`):
the object that creates reports, or None
with_align (bool): whether to jointly lear alignment
(Transformer)
model_saver(:obj:`onmt.models.ModelSaverBase`): the saver is
used to save a checkpoint.
Thus nothing will be saved if this parameter is None.
average_decay (float): cf opt.average_decay
average_every (int): average model every x steps.
model_dtype (str): fp32 or fp16.
earlystopper (:obj:`onmt.utils.EarlyStopping`): add early
stopping mecanism
dropout (float): dropout value in RNN or FF layers.
attention_dropout (float): dropaout in attention layers.
dropout_steps (list): dropout values scheduling in steps.
zero_out_prompt_loss (bool): whether to zero-out the prompt loss
(mostly for LLM finetuning)."""
def __init__(
self,
model,
train_loss,
valid_loss,
scoring_preparator,
valid_scorers,
optim,
trunc_size=0,
norm_method="sents",
accum_count=[1],
accum_steps=[0],
n_gpu=1,
gpu_rank=1,
parallel_mode="data_parallel",
report_manager=None,
with_align=False,
model_saver=None,
average_decay=0,
average_every=1,
model_dtype="fp32",
earlystopper=None,
dropout=[0.3],
attention_dropout=[0.1],
dropout_steps=[0],
zero_out_prompt_loss=False,
):
# Basic attributes.
self.model = model
self.train_loss = train_loss
self.valid_loss = valid_loss
self.scoring_preparator = scoring_preparator
self.valid_scorers = valid_scorers
self.optim = optim
self.trunc_size = trunc_size
self.norm_method = norm_method
self.accum_count_l = accum_count
self.accum_count = accum_count[0]
self.accum_steps = accum_steps
self.n_gpu = n_gpu
self.gpu_rank = gpu_rank
self.parallel_mode = parallel_mode
self.report_manager = report_manager
self.with_align = with_align
self.model_saver = model_saver
self.average_decay = average_decay
self.moving_average = None
self.average_every = average_every
self.model_dtype = model_dtype
self.earlystopper = earlystopper
self.dropout = dropout
self.attention_dropout = attention_dropout
self.dropout_steps = dropout_steps
self.zero_out_prompt_loss = zero_out_prompt_loss
for i in range(len(self.accum_count_l)):
assert self.accum_count_l[i] > 0
# Set model in training mode.
self.model.train()
def _eval_handler(self, scorer, preds, texts_ref):
"""Trigger metrics calculations
Args:
scorer (:obj:``onmt.scorer.Scorer``): scorer.
preds, texts_ref: outputs of the scorer's `translate` method.
Returns:
The metric calculated by the scorer."""
return scorer.compute_score(preds, texts_ref)
def _accum_count(self, step):
for i in range(len(self.accum_steps)):
if step > self.accum_steps[i]:
_accum = self.accum_count_l[i]
return _accum
def _maybe_update_dropout(self, step):
for i in range(len(self.dropout_steps)):
if step > 1 and step == self.dropout_steps[i] + 1:
self.model.update_dropout(self.dropout[i], self.attention_dropout[i])
logger.info(
"Updated dropout/attn dropout to %f %f at step %d"
% (self.dropout[i], self.attention_dropout[i], step)
)
def _accum_batches(self, iterator):
batches = []
normalization = 0
self.accum_count = self._accum_count(self.optim.training_step)
for batch in iterator:
batches.append(batch)
if self.norm_method == "tokens":
num_tokens = (
batch["tgt"][:, 1:, 0].ne(self.train_loss.padding_idx).sum()
)
normalization += num_tokens.item()
normalization -= len(batch["tgt"]) # don't count for EOS
else:
normalization += len(batch["tgt"])
if len(batches) == self.accum_count:
yield batches, normalization
self.accum_count = self._accum_count(self.optim.training_step)
batches = []
normalization = 0
if batches:
yield batches, normalization
def _update_average(self, step):
if self.moving_average is None:
copy_params = [
params.detach().float() for params in self.model.parameters()
]
self.moving_average = copy_params
else:
average_decay = max(self.average_decay, 1 - (step + 1) / (step + 10))
for (i, avg), cpt in zip(
enumerate(self.moving_average), self.model.parameters()
):
self.moving_average[i] = (
1 - average_decay
) * avg + cpt.detach().float() * average_decay
def train(
self,
train_iter,
train_steps,
save_checkpoint_steps=5000,
valid_iter=None,
valid_steps=10000,
):
"""The main training loop by iterating over ``train_iter`` and possibly
running validation on ``valid_iter``.
Args:
train_iter: An iterator that returns the next training batch.
train_steps: Run training for this many iterations.
save_checkpoint_steps: Save a checkpoint every this many
iterations.
valid_iter: A generator that returns the next validation batch.
valid_steps: Run evaluation every this many iterations.
Returns:
:obj:``nmt.Statistics``: training loss statistics"""
if valid_iter is None:
logger.info("Start training loop without validation...")
valid_stats = None
else:
logger.info(
"Start training loop and validate every %d steps...", valid_steps
)
logger.info("Scoring with: {}".format(self.scoring_preparator.transform))
total_stats = onmt.utils.Statistics()
report_stats = onmt.utils.Statistics()
self._start_report_manager(start_time=total_stats.start_time)
# Let's clean the GPUs before training loop
torch.cuda.empty_cache()
for i, (batches, normalization) in enumerate(self._accum_batches(train_iter)):
step = self.optim.training_step
# UPDATE DROPOUT
self._maybe_update_dropout(step)
if self.n_gpu > 1 and self.parallel_mode == "data_parallel":
normalization = sum(
onmt.utils.distributed.all_gather_list(normalization)
)
self._gradient_accumulation(
batches, normalization, total_stats, report_stats
)
if self.average_decay > 0 and i % self.average_every == 0:
self._update_average(step)
report_stats = self._maybe_report_training(
step, train_steps, self.optim.learning_rate(), report_stats
)
if valid_iter is not None and step % valid_steps == 0:
valid_stats = self.validate(
valid_iter, moving_average=self.moving_average
)
if step % valid_steps == 0 and self.gpu_rank <= 0:
self._report_step(
self.optim.learning_rate(),
step,
valid_stats=valid_stats,
train_stats=total_stats,
)
# Run patience mechanism
if self.earlystopper is not None:
self.earlystopper(valid_stats, step)
# If the patience has reached the limit, stop training
if self.earlystopper.has_stopped():
logger.info("earlystopper has_stopped!")
break
if self.model_saver is not None and (
save_checkpoint_steps != 0 and step % save_checkpoint_steps == 0
):
self.model_saver.save(step, moving_average=self.moving_average)
if train_steps > 0 and step >= train_steps:
break
if self.model_saver is not None:
self.model_saver.save(step, moving_average=self.moving_average)
return total_stats
def validate(self, valid_iter, moving_average=None):
"""Validate model.
Args:
valid_iter: validate data iterator
Returns:
:obj:``nmt.Statistics``: validation loss statistics"""
valid_model = self.model
if moving_average:
# swap model params w/ moving average
# (and keep the original parameters)
model_params_data = []
for avg, param in zip(self.moving_average, valid_model.parameters()):
model_params_data.append(param.data)
param.data = (
avg.data.half() if param.dtype == torch.float16 else avg.data
)
# Set model in validating mode.
valid_model.eval()
# raw_srcs = []
# raw_refs = []
with torch.no_grad():
stats = onmt.utils.Statistics()
start = time.time()
for batch in valid_iter:
src = batch["src"]
src_len = batch["srclen"]
tgt = batch["tgt"]
with torch.cuda.amp.autocast(enabled=self.optim.amp):
# F-prop through the model.
model_out, attns = valid_model(
src, tgt, src_len, with_align=self.with_align
)
# Compute loss.
_, batch_stats = self.valid_loss(batch, model_out, attns)
stats.update(batch_stats)
logger.info(
"""valid stats calculation
took: {} s.""".format(
time.time() - start
)
)
# Compute validation metrics (at batch.dataset level)
if len(self.valid_scorers) > 0:
computed_metrics = {}
start = time.time()
preds, texts_ref = self.scoring_preparator.translate(
model=self.model,
gpu_rank=self.gpu_rank,
step=self.optim.training_step,
)
logger.info(
"""The translation of the valid dataset for dynamic scoring
took : {} s.""".format(
time.time() - start
)
)
for i, metric in enumerate(self.valid_scorers):
logger.info("UPDATING VALIDATION {}".format(metric))
self.valid_scorers[metric]["value"] = self._eval_handler(
scorer=self.valid_scorers[metric]["scorer"],
preds=preds,
texts_ref=texts_ref,
)
computed_metrics[metric] = self.valid_scorers[metric]["value"]
logger.info(
"validation {}: {}".format(
metric, self.valid_scorers[metric]["value"]
)
)
# Compute stats
metric_stats = onmt.utils.Statistics(
0, 0, 0, 0, 0, computed_metrics
)
# Update statistics.
stats.update(metric_stats)
if moving_average:
for param_data, param in zip(model_params_data, self.model.parameters()):
param.data = param_data
# Set model back to training mode.
valid_model.train()
return stats
def _gradient_accumulation(
self, true_batches, normalization, total_stats, report_stats
):
"""Function that iterates over big batches = ``true_batches``
Perform a backward on the loss of each sub_batch and
finally update the params at the end of the big batch."""
if self.accum_count > 1:
self.optim.zero_grad(set_to_none=True)
for k, batch in enumerate(true_batches):
target_size = batch["tgt"].size(1)
# Truncated BPTT: reminder not compatible with accum > 1
if self.trunc_size:
trunc_size = self.trunc_size
else:
trunc_size = target_size
src = batch["src"]
src_len = batch["srclen"]
if src_len is not None:
report_stats.n_src_words += src_len.sum().item()
total_stats.n_src_words += src_len.sum().item()
tgt_outer = batch["tgt"]
bptt = False
for j in range(0, target_size - 1, trunc_size):
# 1. Create truncated target.
tgt = tgt_outer[:, j : j + trunc_size, :]
# 2. F-prop all but generator.
if self.accum_count == 1:
self.optim.zero_grad(set_to_none=True)
try:
with torch.cuda.amp.autocast(enabled=self.optim.amp):
model_out, attns = self.model(
src, tgt, src_len, bptt=bptt, with_align=self.with_align
)
bptt = True
# 3. Compute loss.
if self.zero_out_prompt_loss:
# The loss of the prompt will be set to zero.
batch = self.train_loss.ignore_prompt(batch)
loss, batch_stats = self.train_loss(
batch,
model_out,
attns,
trunc_start=j,
trunc_size=trunc_size,
)
if loss is not None:
loss /= normalization
self.optim.backward(loss)
total_stats.update(batch_stats)
report_stats.update(batch_stats)
except Exception as exc:
trace_content = traceback.format_exc()
if "CUDA out of memory" in trace_content:
logger.info(
"Step %d, cuda OOM - batch removed",
self.optim.training_step,
)
torch.cuda.empty_cache()
if self.n_gpu > 1 and self.parallel_mode == "tensor_parallel":
torch.distributed.destroy_process_group()
sys.exit()
else:
traceback.print_exc()
raise exc
# If truncated, don't backprop fully.
if self.model.decoder.state != {}:
self.model.decoder.detach_state()
# in case of multi step gradient accumulation,
# update only after accum batches
if self.n_gpu > 1 and self.parallel_mode == "data_parallel":
grads = [
p.grad.data
for p in self.model.parameters()
if p.requires_grad and p.grad is not None
]
onmt.utils.distributed.all_reduce_and_rescale_tensors(
grads, float(self.n_gpu)
)
self.optim.step()
def _start_report_manager(self, start_time=None):
"""Simple function to start report manager (if any)"""
if self.report_manager is not None:
if start_time is None:
self.report_manager.start()
else:
self.report_manager.start_time = start_time
def _maybe_report_training(self, step, num_steps, learning_rate, report_stats):
"""Simple function to report training stats (if report_manager is set)
see ``onmt.utils.ReportManagerBase.report_training`` for doc"""
if self.report_manager is not None:
return self.report_manager.report_training(
step,
num_steps,
learning_rate,
None
if self.earlystopper is None
else self.earlystopper.current_tolerance,
report_stats,
multigpu=self.n_gpu > 1 and self.parallel_mode == "data_parallel",
)
def _report_step(self, learning_rate, step, valid_stats=None, train_stats=None):
"""Simple function to report stats (if report_manager is set)
see ``onmt.utils.ReportManagerBase.report_step`` for doc"""
if self.report_manager is not None:
return self.report_manager.report_step(
learning_rate,
None
if self.earlystopper is None
else self.earlystopper.current_tolerance,
step,
valid_stats=valid_stats,
train_stats=train_stats,
)