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code_SAS_VLM2Vec / src /trainer_layer_prune.py
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 import collections
import contextlib
import functools
import shutil
import sys
import time
from datetime import timedelta
from packaging import version
from accelerate import skip_first_batches, DistributedType, InitProcessGroupKwargs
from transformers import PretrainedConfig
from transformers.trainer import Trainer, TRAINING_ARGS_NAME, TRAINER_STATE_NAME
import torch.distributed as dist
from typing import Optional
import os
import torch
import math
from src.data.collator.train_collator import split_vlm_inputs, get_dense_rep, split_and_process_vlm_inputs
from src.model.model_layer_prune import MMEBModel
from src.loss_layer_prune import SimpleContrastiveLoss, DistributedContrastiveLoss
from src.grad_cache.grad_cache import GradCache
from torch.utils.data import DataLoader, Dataset, IterableDataset, RandomSampler, SequentialSampler
from transformers.training_args import OptimizerNames, ParallelMode, TrainingArguments
from transformers.trainer_callback import (
ExportableState,
TrainerState,
)
from transformers.trainer_utils import (
TrainOutput,
has_length,
speed_metrics, seed_worker,
)
from transformers.trainer_pt_utils import (
get_model_param_count,
)
from transformers.trainer import FSDP_MODEL_NAME
from transformers.utils import (
XLA_FSDPV2_MIN_VERSION,
is_accelerate_available,
is_apex_available,
is_torch_xla_available,
logging, is_sagemaker_mp_enabled,
CONFIG_NAME, WEIGHTS_NAME, SAFE_WEIGHTS_NAME,
ADAPTER_WEIGHTS_NAME, ADAPTER_SAFE_WEIGHTS_NAME
)
from src.utils import batch_to_device
from src.utils import print_master, print_rank
if is_apex_available():
from apex import amp
if is_torch_xla_available():
import torch_xla.core.xla_model as xm
from torch_xla import __version__ as XLA_VERSION
IS_XLA_FSDPV2_POST_2_2 = version.parse(XLA_VERSION) >= version.parse(XLA_FSDPV2_MIN_VERSION)
if IS_XLA_FSDPV2_POST_2_2:
pass
else:
IS_XLA_FSDPV2_POST_2_2 = False
logger = logging.get_logger(__name__)
class MMEBTrainer(Trainer):
def __init__(self, *args, **kwargs):
super(MMEBTrainer, self).__init__(*args, **kwargs)
self.is_ddp = dist.is_initialized()
self.processor = self.processing_class
self._dist_loss_scale_factor = dist.get_world_size() if self.is_ddp else 1
def get_batch_samples(self, epoch_iterator, num_batches):
batch_samples = []
num_items_in_batch = None
for _ in range(num_batches):
try:
batch_samples += [next(epoch_iterator)]
except StopIteration:
break
if len(batch_samples) > 0 and "labels" in batch_samples[0]:
# For now we don't support object detection
try:
num_items_in_batch = sum([(batch["labels"].ne(-100)).sum() for batch in batch_samples])
except (TypeError, AttributeError):
pass
if self.args.average_tokens_across_devices and num_items_in_batch is not None:
num_items_in_batch = self.accelerator.gather(num_items_in_batch).sum().item()
if torch.is_tensor(num_items_in_batch):
num_items_in_batch = num_items_in_batch.item()
return batch_samples, num_items_in_batch
def compute_loss(self, model, inputs, *args, **kwargs):
qry_inputs, tgt_inputs = inputs
return model(qry=qry_inputs, tgt=tgt_inputs)
def _save(self, output_dir: Optional[str] = None, state_dict=None):
os.makedirs(output_dir, exist_ok=True)
if state_dict is None:
state_dict = self.model.state_dict()
prefix = 'encoder.'
assert all(k.startswith(prefix) for k in state_dict.keys()), list(state_dict.keys())
state_dict = {k[len(prefix):]: v for k, v in state_dict.items()}
self.model.encoder.save_pretrained(
output_dir, state_dict=state_dict, safe_serialization=self.args.save_safetensors
)
if self.tokenizer is not None:
self.tokenizer.save_pretrained(output_dir)
torch.save(self.args, os.path.join(output_dir, TRAINING_ARGS_NAME))
def _get_train_sampler(self) -> Optional[torch.utils.data.Sampler]:
# override original trainer's method
if self.train_dataset is None or not has_length(self.train_dataset):
return None
return RandomSampler(self.train_dataset)
def get_train_dataloader(self) -> DataLoader:
"""
override original trainer's method to disable self.accelerator.prepare since it will wrap DataLoaderDispatcher and lead to
(1) `RuntimeError: You can't use batches of different size with `dispatch_batches=True` or when using an `IterableDataset`.`
(2) all outputs of dataloader must be tensors
"""
if self.train_dataset is None:
raise ValueError("Trainer: training requires a train_dataset.")
train_dataset = self.train_dataset
data_collator = self.data_collator
train_dataset = self._remove_unused_columns(train_dataset, description="training")
dataloader_params = {
"batch_size": self._train_batch_size,
"collate_fn": data_collator,
"num_workers": self.args.dataloader_num_workers,
"pin_memory": self.args.dataloader_pin_memory,
"persistent_workers": self.args.dataloader_persistent_workers,
}
if not isinstance(train_dataset, torch.utils.data.IterableDataset):
dataloader_params["sampler"] = self._get_train_sampler()
dataloader_params["drop_last"] = self.args.dataloader_drop_last
dataloader_params["worker_init_fn"] = seed_worker
dataloader_params["prefetch_factor"] = self.args.dataloader_prefetch_factor
else:
dataloader_params["sampler"] = None
dataloader_params["shuffle"] = False
dataloader_params["drop_last"] = True
dataloader_params["prefetch_factor"] = None # # tune on both prefetch_factor and persistent_workers will cause hang at epoch2
return DataLoader(train_dataset, **dataloader_params)
def _load_from_checkpoint(self, resume_from_checkpoint, model=None):
self.model_args.checkpoint_path = resume_from_checkpoint
logger.info(f"Loading checkpoint from {resume_from_checkpoint}")
self.model = MMEBModel.load(self.model_args)
self.model_wrapped = self.model
def _inner_training_loop(
self, batch_size=None, args=None, resume_from_checkpoint=None, trial=None, ignore_keys_for_eval=None
):
self.accelerator.free_memory()
self._train_batch_size = batch_size
if self.args.auto_find_batch_size:
if self.state.train_batch_size != self._train_batch_size:
from accelerate.utils import release_memory
(self.model_wrapped,) = release_memory(self.model_wrapped)
self.model_wrapped = self.model
# Check for DeepSpeed *after* the intial pass and modify the config
if self.is_deepspeed_enabled:
# Temporarily unset `self.args.train_batch_size`
original_bs = self.args.per_device_train_batch_size
self.args.per_device_train_batch_size = self._train_batch_size // max(1, self.args.n_gpu)
self.propagate_args_to_deepspeed(True)
self.args.per_device_train_batch_size = original_bs
self.state.train_batch_size = self._train_batch_size
logger.debug(f"Currently training with a batch size of: {self._train_batch_size}")
# Data loader and number of training steps
train_dataloader = self.get_train_dataloader()
# Setting up training control variables:
# number of training epochs: num_train_epochs
# number of training steps per epoch: num_update_steps_per_epoch
# total number of training steps to execute: max_steps
total_train_batch_size = self._train_batch_size * args.gradient_accumulation_steps * args.world_size
len_dataloader = None
num_train_tokens = None
if has_length(train_dataloader):
len_dataloader = len(train_dataloader)
num_update_steps_per_epoch = len_dataloader // args.gradient_accumulation_steps
num_update_steps_per_epoch = max(num_update_steps_per_epoch, 1)
num_examples = self.num_examples(train_dataloader)
if args.max_steps > 0:
max_steps = args.max_steps
num_train_epochs = args.max_steps // num_update_steps_per_epoch + int(
args.max_steps % num_update_steps_per_epoch > 0
)
# May be slightly incorrect if the last batch in the training dataloader has a smaller size but it's
# the best we can do.
num_train_samples = args.max_steps * total_train_batch_size
if args.include_tokens_per_second:
num_train_tokens = (
self.num_tokens(train_dataloader, args.max_steps) * args.gradient_accumulation_steps
)
else:
max_steps = math.ceil(args.num_train_epochs * num_update_steps_per_epoch)
num_train_epochs = math.ceil(args.num_train_epochs)
num_train_samples = self.num_examples(train_dataloader) * args.num_train_epochs
if args.include_tokens_per_second:
num_train_tokens = self.num_tokens(train_dataloader) * args.num_train_epochs
elif args.max_steps > 0: # Rely on max_steps when dataloader does not have a working size
max_steps = args.max_steps
# Setting a very large number of epochs so we go as many times as necessary over the iterator.
num_train_epochs = sys.maxsize
num_update_steps_per_epoch = max_steps
num_examples = total_train_batch_size * args.max_steps
num_train_samples = args.max_steps * total_train_batch_size
if args.include_tokens_per_second:
num_train_tokens = self.num_tokens(train_dataloader, args.max_steps) * args.gradient_accumulation_steps
else:
raise ValueError(
"args.max_steps must be set to a positive value if dataloader does not have a length, was"
f" {args.max_steps}"
)
delay_optimizer_creation = is_sagemaker_mp_enabled() or self.is_fsdp_xla_enabled or self.is_fsdp_enabled
# We need to reset the scheduler, as its parameters may be different on subsequent calls
if self._created_lr_scheduler:
self.lr_scheduler = None
self._created_lr_scheduler = False
self.create_optimizer_and_scheduler(num_training_steps=max_steps)
self.state = TrainerState(
stateful_callbacks=[
cb for cb in self.callback_handler.callbacks + [self.control] if isinstance(cb, ExportableState)
]
)
self.state.is_hyper_param_search = trial is not None
self.state.train_batch_size = self._train_batch_size
# Compute absolute values for logging, eval, and save if given as ratio
if args.logging_steps is not None:
if args.logging_steps < 1:
self.state.logging_steps = math.ceil(max_steps * args.logging_steps)
else:
self.state.logging_steps = args.logging_steps
if args.eval_steps is not None:
if args.eval_steps < 1:
self.state.eval_steps = math.ceil(max_steps * args.eval_steps)
else:
self.state.eval_steps = args.eval_steps
if args.save_steps is not None:
if args.save_steps < 1:
self.state.save_steps = math.ceil(max_steps * args.save_steps)
else:
self.state.save_steps = args.save_steps
# Activate gradient checkpointing if needed
if args.gradient_checkpointing:
self.model.gradient_checkpointing_enable(gradient_checkpointing_kwargs=args.gradient_checkpointing_kwargs)
model = self._wrap_model(self.model_wrapped)
# as the model is wrapped, don't use `accelerator.prepare`
# this is for unhandled cases such as
# FSDP-XLA, SageMaker MP/DP, DataParallel, IPEX
use_accelerator_prepare = True if model is self.model else False
if delay_optimizer_creation:
if use_accelerator_prepare:
self._fsdp_qlora_plugin_updates()
self.model = self.accelerator.prepare(self.model)
self.create_optimizer_and_scheduler(num_training_steps=max_steps)
# prepare using `accelerator` prepare
if use_accelerator_prepare:
self.model.train()
if hasattr(self.lr_scheduler, "step"):
if self.use_apex:
model = self.accelerator.prepare(self.model)
else:
model, self.optimizer = self.accelerator.prepare(self.model, self.optimizer)
else:
# to handle cases wherein we pass "DummyScheduler" such as when it is specified in DeepSpeed config.
model, self.optimizer, self.lr_scheduler = self.accelerator.prepare(
self.model, self.optimizer, self.lr_scheduler
)
elif self.args.optim in [OptimizerNames.LOMO, OptimizerNames.ADALOMO]:
# In this case we are in DDP + LOMO, which should be supported
self.optimizer = self.accelerator.prepare(self.optimizer)
if self.is_fsdp_enabled:
self.model = self.model_wrapped = model
# for the rest of this function `model` is the outside model, whether it was wrapped or not
if model is not self.model:
self.model_wrapped = model
# backward compatibility
if self.is_deepspeed_enabled:
self.deepspeed = self.model_wrapped
# Check if saved optimizer or scheduler states exist
self._load_optimizer_and_scheduler(resume_from_checkpoint)
# important: at this point:
# self.model is the Transformers Model
# self.model_wrapped is DDP(Transformers Model), Deepspeed(Transformers Model),
# FSDP(Transformers Model), Dynamo Optimized Module(Transformers Model) etc.
# Train!
logger.info("***** Running training *****")
logger.info(f" Num examples = {num_examples:,}")
logger.info(f" Num Epochs = {num_train_epochs:,}")
logger.info(f" Instantaneous batch size per device = {self.args.per_device_train_batch_size:,}")
if self.args.per_device_train_batch_size != self._train_batch_size:
logger.info(f" Training with DataParallel so batch size has been adjusted to: {self._train_batch_size:,}")
logger.info(f" Total train batch size (w. parallel, distributed & accumulation) = {total_train_batch_size:,}")
logger.info(f" Gradient Accumulation steps = {args.gradient_accumulation_steps}")
logger.info(f" Total optimization steps = {max_steps:,}")
logger.info(f" Number of trainable parameters = {get_model_param_count(model, trainable_only=True):,}")
self.state.epoch = 0
start_time = time.time()
epochs_trained = 0
steps_trained_in_current_epoch = 0
steps_trained_progress_bar = None
# @ruimeng use steps_trained_in_current_epoch to skip batches for finding buggy data
# steps_trained_in_current_epoch = 42
# Check if continuing training from a checkpoint
if resume_from_checkpoint is not None and os.path.isfile(
os.path.join(resume_from_checkpoint, TRAINER_STATE_NAME)
):
self.state = TrainerState.load_from_json(os.path.join(resume_from_checkpoint, TRAINER_STATE_NAME))
self.compare_trainer_and_checkpoint_args(self.args, self.state)
self._load_callback_state()
epochs_trained = int(self.state.global_step // num_update_steps_per_epoch)
if not args.ignore_data_skip:
steps_trained_in_current_epoch = self.state.global_step % (num_update_steps_per_epoch)
steps_trained_in_current_epoch *= args.gradient_accumulation_steps
else:
steps_trained_in_current_epoch = 0
logger.info(" Continuing training from checkpoint, will skip to saved global_step")
logger.info(f" Continuing training from epoch {epochs_trained}")
logger.info(f" Continuing training from global step {self.state.global_step}")
if not args.ignore_data_skip:
logger.info(
f" Will skip the first {epochs_trained} epochs then the first"
f" {steps_trained_in_current_epoch} batches in the first epoch."
)
# Update the references
self.callback_handler.model = self.model
self.callback_handler.optimizer = self.optimizer
self.callback_handler.lr_scheduler = self.lr_scheduler
self.callback_handler.train_dataloader = train_dataloader
# This should be the same if the state has been saved but in case the training arguments changed, it's safer
# to set this after the load.
self.state.max_steps = max_steps
self.state.num_train_epochs = num_train_epochs
self.state.is_local_process_zero = self.is_local_process_zero()
self.state.is_world_process_zero = self.is_world_process_zero()
# tr_loss is a tensor to avoid synchronization of TPUs through .item()
tr_loss = torch.tensor(0.0).to(args.device)
# _total_loss_scalar is updated everytime .item() has to be called on tr_loss and stores the sum of all losses
self._total_loss_scalar = 0.0
self._globalstep_last_logged = self.state.global_step
model.zero_grad()
grad_norm: Optional[float] = None
self.control = self.callback_handler.on_train_begin(args, self.state, self.control)
if args.eval_on_start:
self._evaluate(trial, ignore_keys_for_eval, skip_scheduler=True)
total_batched_samples = 0
for epoch in range(epochs_trained, num_train_epochs):
epoch_dataloader = train_dataloader
if hasattr(epoch_dataloader.dataset, "set_epoch"):
# print(f'\t\tSetting new epoch={epoch}')
epoch_dataloader.dataset.set_epoch(epoch)
# Reset the past mems state at the beginning of each epoch if necessary.
if args.past_index >= 0:
self._past = None
steps_in_epoch = (
len(epoch_dataloader)
if len_dataloader is not None
else args.max_steps * args.gradient_accumulation_steps
)
self.control = self.callback_handler.on_epoch_begin(args, self.state, self.control)
if epoch == epochs_trained and resume_from_checkpoint is not None and steps_trained_in_current_epoch == 0:
self._load_rng_state(resume_from_checkpoint)
rng_to_sync = False
steps_skipped = 0
if steps_trained_in_current_epoch > 0:
epoch_dataloader = skip_first_batches(epoch_dataloader, steps_trained_in_current_epoch)
steps_skipped = steps_trained_in_current_epoch
steps_trained_in_current_epoch = 0
rng_to_sync = True
step = -1
epoch_iterator = iter(epoch_dataloader)
# We chunkify the epoch iterator into gradient accumulation steps `n` batches
remainder = num_examples % args.gradient_accumulation_steps
num_items_in_batch = None
if remainder == 0:
remainder = args.gradient_accumulation_steps
update_step = -1
total_updates = steps_in_epoch // args.gradient_accumulation_steps + 1
for _ in range(total_updates):
update_step += 1
num_batches = args.gradient_accumulation_steps if update_step != (total_updates - 1) else remainder
batch_samples, num_items_in_batch = self.get_batch_samples(epoch_iterator, num_batches)
for i, inputs in enumerate(batch_samples):
step += 1
total_batched_samples += 1
dataset_stat = collections.Counter(inputs[0]['global_dataset_name'])
# print_rank(f"dataset name: {str(set(inputs[0]['global_dataset_name']))}")
# for dname, count in sorted(dataset_stat.items(), key=lambda t:t[1], reverse=True):
# print_rank(f"\t\tdataset_name={dname}, count={count}")
is_last_step_and_steps_less_than_grad_acc = (
steps_in_epoch <= args.gradient_accumulation_steps and (step + 1) == steps_in_epoch
)
do_sync_step = is_last_step_and_steps_less_than_grad_acc or (
total_batched_samples % args.gradient_accumulation_steps == 0
)
# Since we perform prefetching, we need to manually set sync_gradients
if not do_sync_step:
self.accelerator.gradient_state._set_sync_gradients(False)
else:
self.accelerator.gradient_state._set_sync_gradients(True)
if self.args.include_num_input_tokens_seen:
main_input_name = getattr(self.model, "main_input_name", "input_ids")
if main_input_name not in inputs:
logger.warning(
"Tried to track the number of tokens seen, however the current model is "
"not configured properly to know what item is the input. To fix this, add "
"a `main_input_name` attribute to the model class you are using."
)
else:
input_tokens = inputs[main_input_name].numel()
input_tokens = torch.tensor(input_tokens, device=self.args.device, dtype=torch.int64)
self.state.num_input_tokens_seen += self.accelerator.gather(input_tokens).cpu().item()
if rng_to_sync:
self._load_rng_state(resume_from_checkpoint)
rng_to_sync = False
# Skip past any already trained steps if resuming training
if steps_trained_in_current_epoch > 0:
steps_trained_in_current_epoch -= 1
if steps_trained_progress_bar is not None:
steps_trained_progress_bar.update(1)
if steps_trained_in_current_epoch == 0:
self._load_rng_state(resume_from_checkpoint)
continue
elif steps_trained_progress_bar is not None:
steps_trained_progress_bar.close()
steps_trained_progress_bar = None
if step % args.gradient_accumulation_steps == 0:
self.control = self.callback_handler.on_step_begin(args, self.state, self.control)
# We explicitly want to avoid relying on `accelerator.accumulate` for generation training
context = (
functools.partial(self.accelerator.no_sync, model=model)
if i != len(batch_samples) - 1
else contextlib.nullcontext
)
with context():
tr_loss_step = self.training_step(model, inputs, num_items_in_batch)
if (
args.logging_nan_inf_filter
and not is_torch_xla_available()
and (torch.isnan(tr_loss_step) or torch.isinf(tr_loss_step))
):
# if loss is nan or inf simply add the average of previous logged losses
tr_loss = tr_loss + tr_loss / (1 + self.state.global_step - self._globalstep_last_logged)
else:
if tr_loss.device != tr_loss_step.device:
raise ValueError(
f"Calculated loss must be on the original device: {tr_loss.device} but device in use is {tr_loss_step.device}"
)
tr_loss = tr_loss + tr_loss_step
self.current_flos += float(self.floating_point_ops(inputs))
if do_sync_step:
# Since we perform prefetching, we need to manually set sync_gradients to True
self.accelerator.gradient_state._set_sync_gradients(True)
# Gradient clipping
if args.max_grad_norm is not None and args.max_grad_norm > 0:
# deepspeed does its own clipping
if self.use_apex:
# Revert to normal clipping otherwise, handling Apex or full precision
_grad_norm = torch.nn.utils.clip_grad_norm_(
amp.master_params(self.optimizer),
args.max_grad_norm,
)
else:
_grad_norm = self.accelerator.clip_grad_norm_(
model.parameters(),
args.max_grad_norm,
)
if (
is_accelerate_available()
and self.accelerator.distributed_type == DistributedType.DEEPSPEED
):
grad_norm = model.get_global_grad_norm()
# In some cases the grad norm may not return a float
if hasattr(grad_norm, "item"):
grad_norm = grad_norm.item()
else:
grad_norm = _grad_norm
self.control = self.callback_handler.on_pre_optimizer_step(args, self.state, self.control)
self.optimizer.step()
self.control = self.callback_handler.on_optimizer_step(args, self.state, self.control)
optimizer_was_run = not self.accelerator.optimizer_step_was_skipped
if optimizer_was_run:
# Delay optimizer scheduling until metrics are generated
if not isinstance(self.lr_scheduler, torch.optim.lr_scheduler.ReduceLROnPlateau):
self.lr_scheduler.step()
model.zero_grad()
self.state.global_step += 1
self.state.epoch = epoch + (step + 1 + steps_skipped) / steps_in_epoch
self.control = self.callback_handler.on_step_end(args, self.state, self.control)
self._maybe_log_save_evaluate(tr_loss, grad_norm, model, trial, epoch, ignore_keys_for_eval, time.time())
else:
self.control = self.callback_handler.on_substep_end(args, self.state, self.control)
# PyTorch/XLA relies on the data loader to insert the mark_step for
# each step. Since we are breaking the loop early, we need to manually
# insert the mark_step here.
if self.control.should_epoch_stop or self.control.should_training_stop:
if is_torch_xla_available():
xm.mark_step()
break
# We also need to break out of the nested loop
if self.control.should_epoch_stop or self.control.should_training_stop:
if is_torch_xla_available():
xm.mark_step()
break
if step < 0:
logger.warning(
"There seems not to be a single sample in your epoch_iterator, stopping training at step"
f" {self.state.global_step}! This is expected if you're using an IterableDataset and set"
f" num_steps ({max_steps}) higher than the number of available samples."
)
self.control.should_training_stop = True
self.control = self.callback_handler.on_epoch_end(args, self.state, self.control)
self._maybe_log_save_evaluate(tr_loss, grad_norm, model, trial, epoch, ignore_keys_for_eval, time.time())
if self.control.should_training_stop:
break
if args.past_index and hasattr(self, "_past"):
# Clean the state at the end of training
delattr(self, "_past")
logger.info("\n\nTraining completed. Do not forget to share your model on huggingface.co/models =)\n\n")
if args.load_best_model_at_end and self.state.best_model_checkpoint is not None:
# Wait for everyone to get here so we are sure the model has been saved by process 0.
if is_torch_xla_available():
xm.rendezvous("load_best_model_at_end")
elif args.parallel_mode == ParallelMode.DISTRIBUTED:
dist.barrier()
self._load_best_model()
# add remaining tr_loss
self._total_loss_scalar += tr_loss.item()
effective_global_step = max(self.state.global_step, 0.001) # Avoid ZeroDivisionError
train_loss = self._total_loss_scalar / effective_global_step
metrics = speed_metrics(
"train",
start_time,
num_samples=num_train_samples,
num_steps=self.state.max_steps,
num_tokens=num_train_tokens,
)
self.store_flos()
metrics["total_flos"] = self.state.total_flos
metrics["train_loss"] = train_loss
self.is_in_train = False
self._memory_tracker.stop_and_update_metrics(metrics)
self.log(metrics)
run_dir = self._get_output_dir(trial)
checkpoints_sorted = self._sorted_checkpoints(use_mtime=False, output_dir=run_dir)
# Delete the last checkpoint when save_total_limit=1 if it's different from the best checkpoint and process allowed to save.
if self.args.should_save and self.state.best_model_checkpoint is not None and self.args.save_total_limit == 1:
for checkpoint in checkpoints_sorted:
if not os.path.samefile(checkpoint, self.state.best_model_checkpoint):
logger.info(f"Deleting older checkpoint [{checkpoint}] due to args.save_total_limit")
shutil.rmtree(checkpoint, ignore_errors=True)
self.control = self.callback_handler.on_train_end(args, self.state, self.control)
# Wait for the checkpoint to be uploaded.
self._finish_current_push()
# After training we make sure to retrieve back the original forward pass method
# for the embedding layer by removing the forward post hook.
if self.neftune_noise_alpha is not None:
self._deactivate_neftune(self.model)
return TrainOutput(self.state.global_step, train_loss, metrics)
class GradCacheLateProcessTrainer(MMEBTrainer):
"""
Adapted from gradcache repo.
"""
def __init__(self, *args, **kwargs):
self.max_length = kwargs.get("max_length", 512)
if "max_length" in kwargs:
del kwargs["max_length"]
self.model_args = kwargs.get("model_args", None)
if "model_args" in kwargs:
del kwargs["model_args"]
super(GradCacheLateProcessTrainer, self).__init__(*args, **kwargs)
self.is_ddp = dist.is_initialized()
self._dist_loss_scale_factor = dist.get_world_size() if self.is_ddp else 1
loss_fn_cls = DistributedContrastiveLoss if self.is_ddp else SimpleContrastiveLoss
loss_fn = loss_fn_cls(temperature=self.model.temperature)
# process_fn = functools.partial(process_vlm_inputs_fns[self.args.model_backbone], processor=self.processing_class, max_length=self.max_length)
self.gc = GradCache(
models=[self.model, self.model],
chunk_sizes=[self.args.gc_q_chunk_size, self.args.gc_p_chunk_size],
loss_fn=loss_fn,
split_input_fn=split_and_process_vlm_inputs,
# process_fn=process_fn,
get_rep_fn=get_dense_rep,
fp16=self.args.fp16,
scaler=self.scaler if self.args.fp16 else None
)
def training_step(self, model, inputs, *args, **kwargs) -> torch.Tensor:
model.train()
queries, targets = inputs
queries = batch_to_device(queries, model.device)
targets = batch_to_device(targets, model.device)
queries, targets = {'qry': queries}, {'tgt': targets}
_distributed = self.args.local_rank > -1
if _distributed:
self.gc.models = [model, model]
loss = self.gc(queries, targets, no_sync_except_last=_distributed)
else:
loss = model(queries, targets)
return loss / self._dist_loss_scale_factor
def _save(self, output_dir: Optional[str] = None, state_dict=None):
print_master(f"Saving model to {output_dir}")
os.makedirs(output_dir, exist_ok=True)
if state_dict is None:
state_dict = self.model.state_dict()
prefix = 'encoder.'
assert all(k.startswith(prefix) for k in state_dict.keys()), list(state_dict.keys())
state_dict = {k[len(prefix):]: v for k, v in state_dict.items()}
self.model.encoder.save_pretrained(
output_dir, state_dict=state_dict, safe_serialization=self.args.save_safetensors
)
if self.tokenizer is not None:
self.tokenizer.save_pretrained(output_dir)
torch.save(self.args, os.path.join(output_dir, TRAINING_ARGS_NAME))
self.model.encoder.config.to_json_file(os.path.join(output_dir, 'config.json'))