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wehub-resource-sync a203934033
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chore: import upstream snapshot with attribution
2026-07-13 13:34:58 +08:00

1347 lines
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Python

# Copyright (c) ModelScope Contributors. All rights reserved.
# Part of the implementation is borrowed from huggingface/transformers.
import collections
import datasets
import inspect
import json
import logging
import numpy as np
import os
import random
import re
import safetensors
import shutil
import time
import torch
import torch.distributed as dist
import torch.nn as nn
import torch.utils.checkpoint
import transformers
import warnings
from contextlib import contextmanager
from copy import copy
from datasets import Dataset as HfDataset
from functools import partial, wraps
from modelscope import check_local_model_is_latest
from packaging import version
from peft import PeftModel
from torch.utils.data import DataLoader
from transformers import PreTrainedModel
from transformers.integrations import is_deepspeed_zero3_enabled
from transformers.modeling_utils import unwrap_model
from transformers.trainer import OPTIMIZER_NAME, PREFIX_CHECKPOINT_DIR, SCHEDULER_NAME, TRAINER_STATE_NAME, ParallelMode
from transformers.trainer import Trainer as HfTrainer
from transformers.trainer import reissue_pt_warnings
from transformers.trainer_utils import IntervalStrategy
try:
from transformers.trainer_utils import sort_checkpoints
except ImportError:
sort_checkpoints = None
from types import MethodType
from typing import Callable, Dict, List, Optional
from swift.callbacks import callbacks_map
from swift.dataloader import BatchSamplerShard, DataLoaderDispatcher, DataLoaderShard
from swift.hub import get_hub
from swift.loss import loss_map
from swift.metrics import MeanMetric, compute_acc, eval_metrics_map
from swift.model import get_llm_model, get_lm_head_model, save_checkpoint
from swift.model.patcher import gather_sequence_parallel_outputs, revert_padding_free, transformers_seq_cls_forward
from swift.optimizers import OptimizerCallback, optimizers_map
from swift.sequence_parallel import SequenceParallelDispatcher, SequenceParallelSampler, sequence_parallel
from swift.template import Template, update_generation_config_eos_token
from swift.tuner_plugin import tuners_map
from swift.tuners import SwiftModel
from swift.utils import (HfConfigFactory, copy_files_by_pattern, deep_getattr, get_current_device, get_logger,
get_packed_seq_params, is_dist, is_mp, is_mp_ddp, ms_logger_context, seed_worker)
from .arguments import TrainingArguments
from .utils import (can_return_loss, dynamic_gradient_checkpointing, find_labels, get_function, get_resume_dir,
is_instance_of_ms_model, patch_modelscope_hub_timeout, replace_index_file)
logger = get_logger()
transformers_5 = version.parse(transformers.__version__) >= version.parse('5.0.0')
class SwiftMixin:
FLASH_CKPT_WAIT_TIMEOUT = 1800
def __init__(self,
model: PreTrainedModel,
args: TrainingArguments,
template: Template,
train_dataset: HfDataset,
eval_dataset: Optional[HfDataset] = None,
**kwargs) -> None:
if not hasattr(train_dataset, '__len__') and args.dataloader_num_workers > 1:
args.dataloader_num_workers = 1
logger.warning('Using IterableDataset, setting args.dataloader_num_workers to 1.')
self.compute_loss_func = None # Compatible with the older version of transformers
self.template = template
self.is_encoder_decoder = self.template.is_encoder_decoder
self.padding_free = self.template.padding_free
self.task_type = self.template.task_type
self.problem_type = getattr(model.config, 'problem_type', None)
self.optimizer_callback = optimizers_map[args.optimizer or 'default'](args, self)
if args.check_model and hasattr(model, 'model_dir'):
with ms_logger_context(logging.CRITICAL), patch_modelscope_hub_timeout():
config_info = self._collect_config_info()
config_info.update({
'invoked_by': 'local_trainer',
'third_party': 'swift',
'trainer_class': self.__class__.__name__,
})
check_local_model_is_latest(model.model_dir, user_agent=config_info)
if eval_dataset is None and args:
if getattr(args, 'eval_dataset', None):
# Avoid trainer throwing errors.
eval_dataset = []
else:
args.evaluation_strategy = IntervalStrategy.NO
args.eval_strategy = IntervalStrategy.NO
def _get_mean_metric():
return MeanMetric(nan_value=None, device=args.device)
self.custom_metrics = {
'train': collections.defaultdict(_get_mean_metric),
'eval': collections.defaultdict(_get_mean_metric)
}
self.hub = get_hub()
self.model_meta = model.model_meta
self.model_info = model.model_info
data_collator = self._get_data_collator(args, template)
kwargs.update(self.create_loss_and_eval_metric(args))
trainer_parameters = inspect.signature(HfTrainer.__init__).parameters
tokenizer_key = 'processing_class' if 'processing_class' in trainer_parameters else 'tokenizer'
kwargs[tokenizer_key] = template.tokenizer
# Pass callbacks in __init__ to correctly invoke on_init_end
callbacks = self._get_callbacks(args)
with self.hub.patch_hub():
super().__init__(
model=model,
args=args,
data_collator=data_collator,
train_dataset=train_dataset,
eval_dataset=eval_dataset,
callbacks=callbacks,
**kwargs)
# fix https://github.com/huggingface/transformers/pull/43919
if transformers_5:
self.accelerator.gradient_state.plugin_kwargs['num_steps'] = 1
if get_function(model.__class__.forward) is not get_function(model.forward):
self.label_names = find_labels(model)
self.can_return_loss = can_return_loss(model)
self.label_names = self.label_names or ['labels']
self.start_time = time.time()
self._fix_gradient_checkpointing()
self._patch_tasks()
update_generation_config_eos_token(self.model.generation_config, self.template)
if getattr(self.model, 'origin_generation_config', None):
self.model.origin_generation_config.eos_token_id = self.model.generation_config.eos_token_id
if self.args.resume_only_model and self.args.ignore_data_skip:
# The weights have already been loaded outside the trainer,
# so reading train_state is skipped here.
self.args.resume_from_checkpoint = None
def _get_data_collator(self, args, template):
padding_to = template.max_length if args.tuner_type == 'longlora' else None
return partial(template.data_collator, padding_to=padding_to)
def _get_callbacks(self, args):
callbacks = []
for callback in args.callbacks:
callbacks.append(callbacks_map[callback](args, self))
return callbacks
def _collect_config_info(self) -> Dict[str, str]:
"""
Collects trainer-specific configuration details.
Subclasses can override this method to provide additional configuration
information for model compatibility verification.
Returns:
Dict[str, str]: Configuration parameters as key-value pairs.
"""
if self.__class__.__name__ == 'Seq2SeqTrainer':
if not self.template.use_chat_template:
return {
'seq2seq_mode': 'pt',
}
else:
return {
'seq2seq_mode': 'sft',
}
return {}
@property
def tokenizer(self):
# compat transformers5.0
return self.processing_class
@contextmanager
def _patch_deepspeed_load_checkpoint(self):
from transformers import trainer
if not self.args.resume_from_checkpoint or not self.args.resume_only_model or not hasattr(
trainer, 'deepspeed_load_checkpoint'):
yield
return
origin_deepspeed_load_checkpoint = trainer.deepspeed_load_checkpoint
def deepspeed_load_checkpoint(*args, **kwargs):
try:
return origin_deepspeed_load_checkpoint(*args, **kwargs)
except Exception as e:
logger.warning('Failed to call deepspeed_load_checkpoint function. '
f'If `--resume_only_model true` is set, this warning can be ignored. {e}.')
trainer.deepspeed_load_checkpoint = deepspeed_load_checkpoint
try:
yield
finally:
trainer.deepspeed_load_checkpoint = origin_deepspeed_load_checkpoint
def get_use_logits_to_keep(self, default_value: bool = True):
use_logits_to_keep = self.args.use_logits_to_keep
if use_logits_to_keep is None:
base_model = self.template.get_base_model(self.model)
if self.model.model_meta.is_multimodal and not transformers_5:
use_logits_to_keep = False
elif 'logits_to_keep' not in inspect.signature(base_model.forward).parameters:
use_logits_to_keep = False
else:
use_logits_to_keep = default_value
self.args.use_logits_to_keep = use_logits_to_keep
logger.info_once(f'use_logits_to_keep: {use_logits_to_keep}')
return use_logits_to_keep
def _save_initial_model(self, output_dir):
# pissa/olora/lora-ga
model = unwrap_model(self.model)
if isinstance(model, PeftModel):
config = model.peft_config.get('default')
init_lora_weights = getattr(config, 'init_lora_weights', None)
if (isinstance(init_lora_weights, str)
and any(s in init_lora_weights for s in ('pissa', 'olora', 'lora-ga'))):
config.init_lora_weights = True
model.save_pretrained(os.path.join(output_dir, 'initial_model'))
config.init_lora_weights = init_lora_weights
def _save_converted_model(self, output_dir):
# pissa/olora/lora-ga
model = unwrap_model(self.model)
if isinstance(model, PeftModel):
config = model.peft_config.get('default')
init_lora_weights = getattr(config, 'init_lora_weights', None)
if isinstance(init_lora_weights, str):
config = copy(config)
# Save requires_grad state to protect against peft inject_adapter side effects
# (peft >= 0.18.1 incorrectly freezes active adapter when loading a temporary adapter)
requires_grad_state = {n: p.requires_grad for n, p in model.named_parameters()}
os.makedirs(os.path.join(output_dir, 'converted'), exist_ok=True)
if 'lora-ga' in init_lora_weights:
try:
from lora_ga.entrypoint import LoraGAContext
with LoraGAContext(model):
model.save_pretrained(
os.path.join(output_dir, 'converted', 'default'),
path_initial_model_for_weight_conversion=os.path.join(
os.path.dirname(output_dir), 'initial_model'),
)
model.peft_config['default'] = config
except ImportError as e:
error_message = """
Since 'LoRA-GA' is not implemented by PEFT, you will need to install it directly from GitHub.
Command: 'pip install git+https://github.com/lxline/LoRA-GA.git'.
"""
logger.info(error_message)
raise RuntimeError(error_message) from e
elif 'pissa' in init_lora_weights or 'olora' in init_lora_weights:
model.save_pretrained(
os.path.join(output_dir, 'converted', 'default'),
path_initial_model_for_weight_conversion=os.path.join(
os.path.dirname(output_dir), 'initial_model'),
)
model.peft_config['default'] = config
# Restore requires_grad state after conversion to prevent peft side effects
for n, p in model.named_parameters():
if n in requires_grad_state:
p.requires_grad = requires_grad_state[n]
def _load_rng_state(self, *args, **kwargs):
if self.args.resume_only_model:
return
return super()._load_rng_state(*args, **kwargs)
def _load_optimizer_and_scheduler(self, *args, **kwargs):
if self.args.resume_only_model:
return
super()._load_optimizer_and_scheduler(*args, **kwargs)
callbacks = set(getattr(self.args, 'callbacks', []))
ds_config = getattr(self.args, 'deepspeed', None) or {}
checkpoint_config = ds_config.get('checkpoint') if isinstance(ds_config, dict) else None
load_universal = isinstance(checkpoint_config, dict) and checkpoint_config.get('load_universal', False)
if 'deepspeed_elastic' in callbacks and load_universal:
self._fix_optimizer_step_device(self.optimizer)
if is_mp_ddp():
# fix mp+ddp adamw
for v in self.optimizer.state.values():
if 'step' in v:
# not on the same device
device_set = set([t.device for t in v.values()]) - {v['step'].device, torch.device('cpu')}
if len(device_set) >= 1:
v['step'] = v['step'].to('cpu')
@staticmethod
def _fix_optimizer_step_device(optimizer):
state = getattr(optimizer, 'state', None)
if not isinstance(state, dict):
return
for value in state.values():
if not isinstance(value, dict):
continue
step = value.get('step')
if not isinstance(step, torch.Tensor):
continue
target_device = None
for state_key, state_value in value.items():
if state_key == 'step':
continue
if isinstance(state_value, torch.Tensor) and state_value.device.type != 'cpu':
target_device = state_value.device
break
if target_device is not None and step.device != target_device:
value['step'] = step.to(target_device)
def _save_model(self, output_dir: Optional[str] = None, state_dict=None):
# If template defines a save_callback, delegate to it
if hasattr(self, 'template') and hasattr(self.template, 'save_callback'):
self.template.save_callback(self.model, output_dir)
return
# model
supported_classes = (SwiftModel, PreTrainedModel, PeftModel)
supported_names = ('SentenceTransformer', )
safe_serialization = self.args.safe_serialization
use_flash_ckpt = self.args.use_flash_ckpt
if not isinstance(self.model, supported_classes) and self.model.__class__.__name__ not in supported_names:
if state_dict is None:
state_dict = self.model.state_dict()
_unwrap_model = unwrap_model(self.model)
if isinstance(_unwrap_model, supported_classes):
save_kwargs = {'state_dict': state_dict, 'max_shard_size': self.args.max_shard_size}
if isinstance(_unwrap_model, PeftModel):
save_kwargs['selected_adapters'] = ['default']
if use_flash_ckpt:
_unwrap_model.save_pretrained(
output_dir,
safe_serialization=False,
save_function=self.flash_checkpointer.ckpt_agent.save,
**save_kwargs)
else:
_unwrap_model.save_pretrained(output_dir, safe_serialization=safe_serialization, **save_kwargs)
else:
logger.info('Trainer.model is not a `PreTrainedModel`, only saving its state dict.')
if use_flash_ckpt:
self.flash_checkpointer.ckpt_agent.save(state_dict, os.path.join(output_dir, 'pytorch_model.bin'))
else:
if safe_serialization:
safetensors.torch.save_file(state_dict, os.path.join(output_dir, 'model.safetensors'))
else:
torch.save(state_dict, os.path.join(output_dir, 'pytorch_model.bin'))
elif is_instance_of_ms_model(self.model):
if use_flash_ckpt:
PreTrainedModel.save_pretrained(
self.model,
output_dir,
state_dict=state_dict,
safe_serialization=False,
save_function=self.flash_checkpointer.ckpt_agent.save)
else:
# modelscope save_pretrained does not support safe_serialization
PreTrainedModel.save_pretrained(
self.model, output_dir, state_dict=state_dict, safe_serialization=safe_serialization)
elif self.args.tuner_type in tuners_map:
tuners_map[self.args.tuner_type].save_pretrained(
self.model, output_dir, state_dict=state_dict, safe_serialization=safe_serialization)
else:
if self.model.__class__.__name__ != 'SentenceTransformer':
save_kwargs = {'state_dict': state_dict, 'max_shard_size': self.args.max_shard_size}
if isinstance(self.model, PeftModel):
save_kwargs['selected_adapters'] = ['default']
if use_flash_ckpt:
self.model.save_pretrained(
output_dir,
safe_serialization=False,
save_function=self.flash_checkpointer.ckpt_agent.save,
**save_kwargs)
else:
self.model.save_pretrained(output_dir, safe_serialization=safe_serialization, **save_kwargs)
else:
@contextmanager
def save_context():
save_pretrained = self.model[0].auto_model.save_pretrained
_state_dict = {
key[len('0.auto_model.'):] if 'auto_model' in key else key: value
for key, value in state_dict.items()
}
self.model[0].auto_model.save_pretrained = partial(
self.model[0].auto_model.save_pretrained, state_dict=_state_dict)
yield
self.model[0].auto_model.save_pretrained = save_pretrained
with save_context():
if use_flash_ckpt:
self.model.save_pretrained(
output_dir,
state_dict=state_dict,
safe_serialization=False,
save_function=self.flash_checkpointer.ckpt_agent.save)
else:
self.model.save_pretrained(output_dir, safe_serialization=safe_serialization)
# copy sentencetransformers files
copy_files_by_pattern(
self.model.model_dir, output_dir, '*.py', exclude_patterns=['model.safetensors.index.json'])
copy_files_by_pattern(
self.model.model_dir, output_dir, '*.json', exclude_patterns=['model.safetensors.index.json'])
def _save(self, output_dir: Optional[str] = None, state_dict=None):
"""Compatible with swift and peft"""
# If we are executing this function, we are the process zero, so we don't check for that.
output_dir = output_dir if output_dir is not None else self.args.output_dir
os.makedirs(output_dir, exist_ok=True)
self._save_model(output_dir, state_dict)
# training_args.bin
torch.save(self.args, os.path.join(output_dir, 'training_args.bin'))
self._save_converted_model(output_dir)
# args.json
args_path = os.path.join(os.path.dirname(output_dir), 'args.json')
if os.path.exists(args_path):
shutil.copy(args_path, os.path.join(output_dir, 'args.json'))
# predict.jsonl
predict_jsonl = os.path.join(os.path.dirname(output_dir), 'predict.jsonl')
if os.path.exists(predict_jsonl):
shutil.move(predict_jsonl, os.path.join(output_dir, 'predict.jsonl'))
is_adapter = isinstance(self.model, (SwiftModel, PeftModel))
# tokenizer
if not is_adapter:
additional_saved_files = self.model_meta.additional_saved_files
save_checkpoint(
None,
self.template.processor,
output_dir,
model_dirs=[self.model.model_dir],
additional_saved_files=additional_saved_files)
if getattr(self.model, 'origin_generation_config', None):
self.model.origin_generation_config.save_pretrained(output_dir)
def _rotate_flash_checkpoints(self, use_mtime=False, output_dir=None) -> None:
if (self.args.save_total_limit is None or self.args.save_total_limit <= 0):
return
last_step = self._get_last_checkpoint_step()
# Check if we should delete older checkpoint(s)
if hasattr(self, '_sorted_checkpoints'):
checkpoints_sorted = self._sorted_checkpoints(use_mtime=use_mtime, output_dir=output_dir)
else:
output_dir = output_dir if output_dir is not None else self.args.output_dir
if sort_checkpoints is not None:
checkpoints_sorted = sort_checkpoints(
output_dir=output_dir,
checkpoint_prefix=PREFIX_CHECKPOINT_DIR,
use_mtime=use_mtime,
best_model_checkpoint=self.state.best_model_checkpoint,
)
else:
checkpoints = []
for path in os.listdir(output_dir) if os.path.isdir(output_dir) else []:
if re.match(f'^{PREFIX_CHECKPOINT_DIR}-([0-9]+)$', path):
checkpoints.append(os.path.join(output_dir, path))
ordering = os.path.getmtime if use_mtime else lambda path: int(path.rsplit('-', 1)[-1])
checkpoints_sorted = sorted(checkpoints, key=ordering)
valid_checkpoints = []
for path in checkpoints_sorted:
regex_match = re.match(f'.*{PREFIX_CHECKPOINT_DIR}-([0-9]+)', path)
if regex_match is not None and regex_match.groups() is not None:
step = int(regex_match.groups()[0])
if step <= last_step:
valid_checkpoints.append(path)
if len(valid_checkpoints) <= self.args.save_total_limit:
return
# If save_total_limit=1 with load_best_model_at_end=True,
# we could end up deleting the last checkpoint, which
# should be avoided and allow resuming
save_total_limit = self.args.save_total_limit
if (self.state.best_model_checkpoint is not None and self.args.save_total_limit == 1
and valid_checkpoints[-1] != self.state.best_model_checkpoint):
save_total_limit = 2
number_of_checkpoints_to_delete = max(0, len(valid_checkpoints) - save_total_limit)
checkpoints_to_be_deleted = valid_checkpoints[:number_of_checkpoints_to_delete]
for checkpoint in checkpoints_to_be_deleted:
logger.info(f'Deleting older checkpoint [{checkpoint}] '
f'due to save_total_limit = {self.args.save_total_limit}.')
shutil.rmtree(checkpoint, ignore_errors=True)
def get_last_checkpoint(self):
"""
Get the path of the last complete checkpoint. Some latter directories
may not have the complete checkpoint because the asynchronous
persistence may not finish. The step in the `dlrover_latest.txt` is
the last step of complete checkpoint. We can get the path by the step.
"""
step = self._get_last_checkpoint_step()
if step == 0:
return False
checkpoint_folder = f'{PREFIX_CHECKPOINT_DIR}-{step}'
ckpt_dir = os.path.join(self.args.output_dir, checkpoint_folder)
return ckpt_dir
def _get_last_checkpoint_step(self):
tracer_file = os.path.join(self.args.output_dir, 'dlrover_latest.txt')
if not os.path.exists(tracer_file):
return 0
with open(tracer_file, 'r') as f:
step = int(f.read())
return step
def get_resume_checkpoint(self):
"""
Get the path of the last complete checkpoint. Some latter directories
may not have the complete checkpoint because the asynchronous
persistence may not finish. The step in the `dlrover_latest.txt` is
the last step of complete checkpoint. We can get the path by the step.
"""
resume_dir = get_resume_dir(self.args.output_dir)
if resume_dir is None:
return None
tracer_file = os.path.join(resume_dir, 'dlrover_latest.txt')
if not os.path.exists(tracer_file):
return None
with open(tracer_file, 'r') as f:
step = int(f.read())
checkpoint_folder = f'{PREFIX_CHECKPOINT_DIR}-{step}'
ckpt_dir = os.path.join(resume_dir, checkpoint_folder)
with open(os.path.join(ckpt_dir, TRAINER_STATE_NAME), 'r', encoding='utf-8') as f:
train_state = json.load(f)
if train_state is not None and train_state.get('max_steps') == step:
return None
return ckpt_dir
def get_resume_checkpoint_until_find_ucp(self):
resume_dir = get_resume_dir(self.args.output_dir)
if resume_dir is None:
return None
tracer_file = os.path.join(resume_dir, 'ucp.txt')
if not os.path.exists(tracer_file):
step = 0
if step == 0:
return None
with open(tracer_file, 'r') as f:
step = int(f.read())
checkpoint_folder = f'{PREFIX_CHECKPOINT_DIR}-{step}'
ckpt_dir = os.path.join(resume_dir, checkpoint_folder)
return ckpt_dir
def wait_latest_checkpoint(self, timeout=None, max_steps=None):
"""
Wait for the latest checkpoint.
Args:
timeout (second): The timeout to wait.
"""
self.flash_checkpointer.async_save_engine.wait_latest_checkpoint(timeout, max_steps)
def _fix_zero3_gather_all_parameters(self) -> None:
if is_deepspeed_zero3_enabled() and not hasattr(self.deepspeed, '_zero3_consolidated_16bit_state_dict_origin'):
parameters = inspect.signature(self.deepspeed._zero3_consolidated_16bit_state_dict).parameters
if 'exclude_frozen_parameters' in parameters:
def _zero3_consolidated_16bit_state_dict(model, exclude_frozen_parameters=False):
unwrapped = unwrap_model(model)
exclude_frozen_parameters = False
if isinstance(unwrapped, SwiftModel) and unwrapped.has_additional_modules:
exclude_frozen_parameters = True
if isinstance(unwrapped, PeftModel):
exclude_frozen_parameters = True
return model._zero3_consolidated_16bit_state_dict_origin(exclude_frozen_parameters)
self.deepspeed._zero3_consolidated_16bit_state_dict_origin = (
self.deepspeed._zero3_consolidated_16bit_state_dict)
self.deepspeed._zero3_consolidated_16bit_state_dict = MethodType(_zero3_consolidated_16bit_state_dict,
self.deepspeed)
def _save_checkpoint(self, *args, **kwargs):
self.state.last_model_checkpoint = os.path.join(self.args.output_dir, f'checkpoint-{self.state.global_step}')
self._fix_zero3_gather_all_parameters()
if self.args.use_flash_ckpt:
result = self._save_flash_checkpoint(*args, **kwargs)
else:
result = super()._save_checkpoint(*args, **kwargs)
logger.info(f'Saving model checkpoint to {self.state.last_model_checkpoint}')
return result
def _save_flash_checkpoint(self, model, trial, metrics=None):
from dlrover.trainer.torch.flash_checkpoint.hf_trainer import HfDdpCheckpointer, HfDeepSpeedCheckpointer
from transformers.trainer import DeepSpeedSchedulerWrapper
from transformers.trainer_utils import SaveStrategy
run_dir = self._get_output_dir(trial=trial)
torch_native_save = torch.save
# Save model checkpoint
checkpoint_folder = f'{PREFIX_CHECKPOINT_DIR}-{self.state.global_step}'
output_dir = os.path.join(run_dir, checkpoint_folder)
if not hasattr(self, 'flash_checkpointer'):
if self.is_deepspeed_enabled:
self.flash_checkpointer = HfDeepSpeedCheckpointer(self.model_wrapped, run_dir)
elif not self.is_deepspeed_enabled and not self.is_fsdp_enabled:
self.flash_checkpointer = HfDdpCheckpointer(run_dir)
else:
raise ValueError('Flash Checkpoint only supports DeepSpeed or DDP.')
if self.hp_search_backend is None and trial is None:
self.store_flos()
torch.save = self.flash_checkpointer.ckpt_agent.save
self.save_model(output_dir, _internal_call=True)
if self.is_deepspeed_enabled:
self.model_wrapped.save_checkpoint(output_dir)
elif (self.args.should_save and not self.is_deepspeed_enabled and not self.is_fsdp_enabled):
# deepspeed.save_checkpoint above saves model/optim/sched
torch.save(
self.optimizer.state_dict(),
os.path.join(output_dir, OPTIMIZER_NAME),
)
# Save SCHEDULER & SCALER
is_deepspeed_custom_scheduler = (
self.is_deepspeed_enabled and not isinstance(self.lr_scheduler, DeepSpeedSchedulerWrapper))
if self.args.should_save and (not self.is_deepspeed_enabled or is_deepspeed_custom_scheduler):
with warnings.catch_warnings(record=True) as caught_warnings:
torch.save(
self.lr_scheduler.state_dict(),
os.path.join(output_dir, SCHEDULER_NAME),
)
reissue_pt_warnings(caught_warnings)
if self.args.save_strategy in [SaveStrategy.STEPS, SaveStrategy.EPOCH] and self.state.best_global_step:
best_checkpoint_folder = f'{PREFIX_CHECKPOINT_DIR}-{self.state.best_global_step}'
best_checkpoint_dir = os.path.join(run_dir, best_checkpoint_folder)
if os.path.exists(best_checkpoint_dir):
self.state.best_model_checkpoint = best_checkpoint_dir
# Save the Trainer state
if self.args.should_save:
# Update `ExportableState` callbacks and `TrainerControl` state to where we are currently
from transformers.trainer_callback import ExportableState
for cb in [
cb for cb in self.callback_handler.callbacks + [self.control] if isinstance(cb, ExportableState)
]:
cb_name = cb.__class__.__name__
cb_state = cb.state()
if isinstance(self.state.stateful_callbacks[cb_name], list):
self.state.stateful_callbacks[cb_name].append(cb_state)
else:
self.state.stateful_callbacks[cb_name] = cb_state
self.state.save_to_json(os.path.join(output_dir, TRAINER_STATE_NAME))
# Save RNG state in non-distributed training
rng_states = {
'python': random.getstate(),
'numpy': np.random.get_state(),
'cpu': torch.random.get_rng_state(),
}
if torch.cuda.is_available():
if self.args.parallel_mode == ParallelMode.DISTRIBUTED:
# In non distributed, we save the global
# CUDA RNG state (will take care of DataParallel)
rng_states['cuda'] = torch.cuda.random.get_rng_state_all()
else:
rng_states['cuda'] = torch.cuda.random.get_rng_state()
# A process can arrive here before the process 0 has a chance to
# save the model, in which case output_dir may not yet exist.
os.makedirs(output_dir, exist_ok=True)
if self.args.world_size <= 1:
torch.save(rng_states, os.path.join(output_dir, 'rng_state.pth'))
else:
torch.save(
rng_states,
os.path.join(output_dir, f'rng_state_{self.args.process_index}.pth'),
)
if self.args.safe_serialization:
torch.save({'safe_serialization': True}, 'safe_serialization')
replace_index_file(output_dir)
torch.save = torch_native_save
if (self.state.global_step == self.state.max_steps):
success = self.flash_checkpointer.save_checkpoint_to_storage(self.state.global_step, True)
else:
success = self.flash_checkpointer.save_checkpoint_to_storage(self.state.global_step)
if not success:
logger.info(f'Skip saving the checkpoint of step {self.state.global_step} '
'because the latest checkpoint is not finished.')
shutil.rmtree(output_dir, ignore_errors=True)
if self.args.push_to_hub:
self._push_from_checkpoint(output_dir)
# Maybe delete some older checkpoints.
if self.args.should_save:
self._rotate_flash_checkpoints(use_mtime=True, output_dir=run_dir)
@staticmethod
@contextmanager
def _fix_grad_norm_nan():
from accelerate import Accelerator
origin_clip_grad_norm_ = Accelerator.clip_grad_norm_
def clip_grad_norm_(self, parameters, *args, **kwargs):
# If NaN occurs, ignore weight updates.
parameters = list(parameters)
grad_norm = origin_clip_grad_norm_(self, parameters, *args, **kwargs)
if isinstance(grad_norm, torch.Tensor) and grad_norm.isnan().item():
for p in parameters:
p.grad = None
return grad_norm
Accelerator.clip_grad_norm_ = clip_grad_norm_
try:
yield
finally:
Accelerator.clip_grad_norm_ = origin_clip_grad_norm_
def _patch_tasks(self):
if isinstance(self.model, PeftModel):
model = self.model.model
else:
model = self.model
task_type = self.task_type
sp_enabled = self.template.sequence_parallel_size > 1
pf_enabled = bool(self.template.padding_free)
padding_side = 'left' if pf_enabled else self.template.padding_side
if 'SentenceTransformer' in model.__class__.__name__:
def forward_transformer(transformer, features: Dict[str, torch.Tensor],
**kwargs) -> Dict[str, torch.Tensor]:
trans_features = {
key: value
for key, value in features.items()
if key in ['input_ids', 'attention_mask', 'token_type_ids', 'inputs_embeds', 'position_ids']
}
outputs = transformer.auto_model(**trans_features, **kwargs, return_dict=True)
token_embeddings = outputs[0]
features['token_embeddings'] = token_embeddings
if transformer.auto_model.config.output_hidden_states and 'hidden_states' in outputs:
features['all_layer_embeddings'] = outputs['hidden_states']
return features
from sentence_transformers.models import Transformer
if isinstance(model[0], Transformer):
model[0].forward = MethodType(forward_transformer, model[0])
def forward_sentence_transformer(sentence_transformer, **kwargs) -> Dict[str, torch.Tensor]:
input = kwargs
kwargs = {}
for idx, (module_name, module) in enumerate(sentence_transformer.named_children()):
from sentence_transformers.models import Router
if isinstance(module, Router):
module_kwargs = kwargs
else:
module_kwarg_keys = []
if sentence_transformer.module_kwargs is not None:
module_kwarg_keys = sentence_transformer.module_kwargs.get(module_name, [])
module_kwargs = {
key: value
for key, value in kwargs.items() if key in module_kwarg_keys or (
hasattr(module, 'forward_kwargs') and key in module.forward_kwargs)
}
output = module(input, **module_kwargs)
if idx == 0 and self.template.padding_free:
output = revert_padding_free(output, input, padding_side)
input = output
return {'last_hidden_state': input['sentence_embedding']}
model.forward = MethodType(forward_sentence_transformer, model)
else:
def _register_llm_hooks_in_order(llm_model: nn.Module, hooks: List[Callable]):
# hooks are provided in desired execution order.
# We use prepend=True and register in reverse to preserve the order.
for hook in reversed(hooks):
llm_model.register_forward_hook(hook, with_kwargs=True, prepend=True)
def _get_hook_target_model(task_type_: str) -> nn.Module:
# For embedding, we hook on the LM-head model because embedding outputs are typically
# produced from `output.logits` by `patch_output_normalizer` (registered on LM-head model).
if task_type_ == 'embedding':
return get_lm_head_model(self.model, model_meta=self.model.model_meta)
return get_llm_model(self.model, model_meta=self.model.model_meta)
# --- seq_cls / reranker / generative_reranker / embedding unified pipeline ---
if task_type in {'seq_cls', 'reranker', 'generative_reranker', 'embedding'}:
llm_model = _get_hook_target_model(task_type)
hooks: List[Callable] = []
if sp_enabled:
def sp_gather_hook(module, args, input, output):
return gather_sequence_parallel_outputs(output)
hooks.append(sp_gather_hook)
if pf_enabled:
if sp_enabled:
def revert_padding_free_hook(module, args, input, output):
# Use full packed position ids cached by sequence_parallel.prepare_inputs
position_ids = sequence_parallel.real_position_ids
tmp_input = {'position_ids': position_ids}
return revert_padding_free(output, tmp_input, padding_side)
else:
def revert_padding_free_hook(module, args, input, output):
return revert_padding_free(output, input, padding_side)
hooks.append(revert_padding_free_hook)
if hooks:
_register_llm_hooks_in_order(llm_model, hooks)
# wrappers for seq_cls / reranker (pooling/head must see gathered/reverted outputs)
if task_type in {'seq_cls', 'reranker'} and (sp_enabled or pf_enabled):
lm_head_model = get_lm_head_model(self.model, model_meta=self.model.model_meta)
if task_type == 'seq_cls':
@wraps(model.forward.__func__)
def seq_cls_forward(model, *args, **kwargs):
sp_kwargs = dict(kwargs)
def inner_forward(*args, **_kwargs):
return llm_model(*args, **_kwargs)
return transformers_seq_cls_forward(
lm_head_model,
*args,
origin_forward=inner_forward,
padding_side=padding_side,
**sp_kwargs,
)
model.forward = MethodType(seq_cls_forward, model)
else:
@wraps(model.forward.__func__)
def reranker_forward(model, *args, **kwargs):
sp_kwargs = dict(kwargs)
def inner_forward(*args, **_kwargs):
return llm_model(*args, **_kwargs)
padding_free_fn = getattr(model, 'padding_free_fn', None)
if callable(padding_free_fn):
output = inner_forward(*args, **sp_kwargs)
return padding_free_fn(output, sp_kwargs, padding_side)
return transformers_seq_cls_forward(
lm_head_model,
*args,
origin_forward=inner_forward,
padding_side=padding_side,
**sp_kwargs,
)
model.forward = MethodType(reranker_forward, model)
def _fix_gradient_checkpointing(self):
# fix use_reentrant
if hasattr(torch.utils.checkpoint, '_old_checkpoint'): # avoid double patching
return
args = self.args
if args.gradient_checkpointing_kwargs:
use_reentrant_ = args.gradient_checkpointing_kwargs.get('use_reentrant')
else:
use_reentrant_ = None
if use_reentrant_ is None:
if is_dist() and not self.is_deepspeed_enabled and not self.is_fsdp_enabled:
use_reentrant_ = False
else:
use_reentrant_ = True
logger.info(f'use_reentrant: {use_reentrant_}')
_old_checkpoint = torch.utils.checkpoint.checkpoint
@wraps(_old_checkpoint)
def _new_checkpoint(*args, use_reentrant=None, **kwargs):
return _old_checkpoint(*args, use_reentrant=use_reentrant_, **kwargs)
torch.utils.checkpoint._old_checkpoint = _old_checkpoint
torch.utils.checkpoint.checkpoint = _new_checkpoint
try:
# Fix the old version of transformers.
import transformers.modeling_utils
transformers.modeling_utils.checkpoint = _new_checkpoint
except (ImportError, AttributeError):
pass
def _prepare_gradient_checkpointing(self, model) -> None:
args = self.args
HfConfigFactory.set_config_attr(model.config, 'use_cache', False)
if args.gradient_checkpointing or args.vit_gradient_checkpointing:
dynamic_gradient_checkpointing(model, args.vit_gradient_checkpointing)
gc_kwargs = {}
parameters = inspect.signature(model.gradient_checkpointing_enable).parameters
if 'gradient_checkpointing_kwargs' in parameters:
gc_kwargs['gradient_checkpointing_kwargs'] = args.gradient_checkpointing_kwargs
if args.gradient_checkpointing:
model.gradient_checkpointing_enable(**gc_kwargs)
model.enable_input_require_grads()
model_meta = model.model_meta
model_arch = model_meta.model_arch
if model_meta.is_multimodal and model_arch:
for vision_tower_name in model_arch.vision_tower:
vision_tower = deep_getattr(model, vision_tower_name)
if hasattr(vision_tower, 'enable_input_require_grads'):
try:
if args.vit_gradient_checkpointing:
vision_tower.gradient_checkpointing_enable(**gc_kwargs)
vision_tower.enable_input_require_grads()
else:
vision_tower.gradient_checkpointing_disable()
vision_tower.disable_input_require_grads()
except (NotImplementedError, AttributeError, ValueError) as e:
logger.warning(f'prepare gradient_checkpointing failed: {e}')
# Avoid vit_gradient_checkpointing being overwritten by transformers.Trainer.gradient_checkpointing_enable.
self.args.gradient_checkpointing = False
def train(self, *args, **kwargs):
if self.model_meta.is_multimodal:
models = []
for model_name in ['model', 'ref_model', 'value_model', 'teacher_model']:
model = getattr(self, model_name, None)
if isinstance(model, nn.Module):
models.append(model)
reward_model = getattr(self, 'reward_model', None)
if reward_model is not None:
if isinstance(reward_model, list):
models.extend([m for m in reward_model if isinstance(m, nn.Module)])
elif isinstance(reward_model, nn.Module):
models.append(reward_model)
models = list(set(self.accelerator.unwrap_model(model) for model in models)) # Deduplicate
self.template.register_post_encode_hook(models)
logger.info(f'Successfully registered post_encode hook: {[model.__class__.__name__ for model in models]}.')
self._save_initial_model(self.args.output_dir)
# gradient_checkpointing
gradient_checkpointing = self.args.gradient_checkpointing
base_model = self.template.get_base_model(self.accelerator.unwrap_model(self.model)) # fix peftmodel
self._prepare_gradient_checkpointing(base_model)
with self.hub.patch_hub(), self._fix_grad_norm_nan(), self._patch_skip_first_batches(
), self._patch_deepspeed_load_checkpoint():
res = super().train(*args, **kwargs)
self.template.remove_post_encode_hook()
self.args.gradient_checkpointing = gradient_checkpointing # recover
return res
def push_to_hub(self, *args, **kwargs):
with self.hub.patch_hub():
return super().push_to_hub(*args, **kwargs)
@staticmethod
def compute_custom_metrics(metrics, key_prefix: str = ''):
logs = {}
# Synchronize keys to avoid getting stuck.
if dist.is_initialized():
all_keys = [None] * dist.get_world_size()
dist.all_gather_object(all_keys, list(metrics.keys()))
for key in set().union(*all_keys):
if key not in metrics:
metrics[key]
for k, metric in sorted(metrics.items()):
k = f'{key_prefix}{k}'
value = metric.compute()
metric.reset()
if isinstance(value, dict):
if len(value) == 1:
val = list(value.values())[0]
logs[k] = val
else:
for k_suffix, val in value.items():
new_k = f'{k}_{k_suffix}'
logs[new_k] = val
else:
logs[k] = value
for k in list(logs.keys()):
if logs[k] is None:
logs.pop(k)
return logs
def log(self, logs: Dict[str, float], *args, **kwargs) -> None:
mode = 'train' if self.model.training else 'eval'
metrics = self.custom_metrics[mode]
prefix = 'eval_' if mode == 'eval' else ''
logs.update(self.compute_custom_metrics(metrics, prefix))
return super().log(logs, *args, **kwargs)
def _maybe_log_save_evaluate(self, tr_loss, *args, **kwargs):
if self.control.should_log and self.state.global_step > self._globalstep_last_logged:
self.control.should_log = False
# all_gather + mean() to get average loss over all processes
if version.parse(transformers.__version__) >= version.parse('5.2.0'):
from transformers.trainer_pt_utils import nested_gather
tr_loss_scalar = nested_gather(tr_loss, self.args.parallel_mode).mean().item()
else:
tr_loss_scalar = self._nested_gather(tr_loss).mean().item()
loss = tr_loss_scalar / (self.state.global_step - self._globalstep_last_logged)
logs: Dict[str, float] = {'loss': loss} # loss first
if version.parse(transformers.__version__) >= version.parse('4.38'):
grad_norm = args[0]
if grad_norm is not None:
logs['grad_norm'] = grad_norm.item() if isinstance(grad_norm, torch.Tensor) else grad_norm
logs['learning_rate'] = self._get_learning_rate()
tr_loss -= tr_loss
self._total_loss_scalar += tr_loss_scalar
self._globalstep_last_logged = self.state.global_step
self.store_flos()
self.log(logs)
if self.args.eval_use_evalscope and self.control.should_evaluate:
try:
self._evalscope_eval()
except Exception as e:
logger.warning(f'Failed to call EvalScope evaluation function: {e}.')
if not self.eval_dataset:
self.control.should_evaluate = False
super()._maybe_log_save_evaluate(tr_loss, *args, **kwargs)
def create_loss_and_eval_metric(self, args):
res = {}
if args.eval_metric is not None:
eval_metric = eval_metrics_map[args.eval_metric](args, self)
res['compute_metrics'], res['preprocess_logits_for_metrics'] = (eval_metric.compute_metrics,
eval_metric.preprocess_logits_for_metrics)
if args.loss_type is not None:
res['compute_loss_func'] = loss_map[args.loss_type](args, self)
return res
def create_optimizer_and_scheduler(self, num_training_steps: int):
self.optimizer_callback.create_optimizer_and_scheduler(num_training_steps)
def create_optimizer(self, model=None):
self._optimizer_ori = self.optimizer = self.optimizer_callback.create_optimizer(model=model)
if self.optimizer is not None:
self.optimizer.param_groups = [pg for pg in self.optimizer.param_groups if len(pg['params']) > 0]
return self.optimizer
def create_scheduler(self, num_training_steps: int, optimizer=None):
if optimizer is None:
# fix deepspeed & cosine_with_min_lr (transformers 5.8.0)
optimizer = getattr(self, '_optimizer_ori', None)
self.lr_scheduler = self.optimizer_callback.create_scheduler(num_training_steps, optimizer)
return self.lr_scheduler
@staticmethod
def _get_listwise_reranker_preds(logits, labels):
positive_indices = torch.nonzero(labels == 1, as_tuple=False).squeeze(-1).tolist()
positive_indices.append(labels.shape[0])
preds = []
for i in range(len(positive_indices) - 1):
start, end = positive_indices[i], positive_indices[i + 1]
preds.append(logits[start:end].argmax())
preds = torch.tensor(preds)
labels = torch.tensor([0] * (len(positive_indices) - 1))
return preds, labels
def _compute_acc(self, outputs, labels, cu_seqlens=None) -> None:
args = self.args
logits = outputs.logits
metrics = None
task_type = self.task_type
problem_type = self.problem_type
if task_type == 'embedding':
return
elif task_type == 'seq_cls':
if problem_type == 'regression':
return
elif problem_type == 'multi_label_classification':
preds = logits.sigmoid() > 0.5
metrics = {'acc': (labels == preds).all(dim=-1)}
else:
preds = logits.argmax(dim=-1)
metrics = compute_acc(preds, labels)
elif task_type == 'causal_lm':
preds = logits.argmax(dim=-1)
if self.template.sequence_parallel_size > 1:
# Gather preds and labels across the sp group
if isinstance(preds, np.ndarray):
preds = torch.from_numpy(preds).to(get_current_device())
if isinstance(labels, np.ndarray):
labels = torch.from_numpy(labels).to(get_current_device())
assert labels.shape[1] == preds.shape[1]
if sequence_parallel.rp_world_size > 1:
position_ids = sequence_parallel.real_position_ids
position_ids = sequence_parallel.pad(position_ids, padding_value=-1, position_ids=position_ids)
else:
position_ids = None
preds_output = sequence_parallel.gather(preds, dim=1, position_ids=position_ids)
labels_output = sequence_parallel.gather(labels, dim=1, position_ids=position_ids)
# roll back to fit compute_acc
labels_output = torch.roll(labels_output, shifts=1, dims=1)
preds = preds_output
labels = labels_output.int()
metrics = compute_acc(
preds,
labels,
acc_strategy=args.acc_strategy,
is_encoder_decoder=self.template.is_encoder_decoder,
cu_seqlens=cu_seqlens)
elif task_type in {'generative_reranker', 'reranker'}:
if logits.dim() == 2:
logits = logits.squeeze(-1)
if args.loss_type == 'listwise_reranker':
preds, labels = self._get_listwise_reranker_preds(logits, labels)
else:
preds = (logits > 0).long()
metrics = compute_acc(preds, labels.long())
if metrics:
mode = 'train' if self.model.training else 'eval'
for k, v in metrics.items():
self.custom_metrics[mode][k].update(v)
@torch.no_grad()
def _evalscope_eval(self):
from evalscope import TaskConfig, run_task
from ..pipelines.eval.utils import EvalModel
self.model.eval()
template = copy(self.template)
template.packing = False
template.padding_free = False
# prepare task config
task_config_kwargs = dict(
model=EvalModel(
model_name=f'model-step{self.state.global_step}',
model=self.model,
template=template,
max_batch_size=self.args.per_device_eval_batch_size,
),
eval_type='swift_custom',
datasets=self.args.eval_dataset,
dataset_args=self.args.eval_dataset_args,
limit=self.args.eval_limit,
work_dir=os.path.join(self.args.output_dir, 'eval'),
eval_batch_size=self.args.per_device_eval_batch_size,
generation_config=self.args.eval_generation_config or {'max_tokens': 512},
)
task_config_kwargs.update(self.args.extra_eval_args or {})
task_config = TaskConfig(**task_config_kwargs)
# start evaluation
eval_report = run_task(task_config)
# convert to dict
eval_dict = {f'test_{k}': v.score for k, v in eval_report.items()}
self.log(eval_dict)
self.model.train()
return eval_dict
def prepare_logits_to_keep(self, inputs):
labels = inputs['labels']
loss_scale = inputs.get('loss_scale')
if self.template.sequence_parallel_size > 1:
raise NotImplementedError()
if labels.shape[0] == 1 and not is_mp():
# device_map may encounter device mismatch issues.
loss_mask = (labels != -100)[0]
labels = labels[:, loss_mask]
labels = nn.functional.pad(labels, (1, 0), value=-100)
if loss_scale is not None:
loss_scale = loss_scale[:, loss_mask]
inputs['loss_scale'] = nn.functional.pad(loss_scale, (1, 0), value=0)
logits_to_keep = nn.functional.pad(loss_mask[1:], (0, 1), value=True)
else:
logits_to_keep = labels.shape[-1] - ((labels != -100).int().argmax(-1).min().item()) + 1
assert logits_to_keep > 0
labels = labels[:, -logits_to_keep:]
if loss_scale is not None:
inputs['loss_scale'] = loss_scale[:, -logits_to_keep:]
inputs['labels'] = labels
inputs['logits_to_keep'] = logits_to_keep
def get_cu_seqlens(self, position_ids, logits_to_keep) -> torch.Tensor:
cu_seqlens = get_packed_seq_params(position_ids)['cu_seq_lens_q']
res_cu_seqlens = cu_seqlens.clone()
if isinstance(logits_to_keep, torch.Tensor):
for i in range(cu_seqlens.shape[0] - 1):
start, end = cu_seqlens[i], cu_seqlens[i + 1]
res_cu_seqlens[i + 1:] -= (~logits_to_keep[start:end]).sum()
elif isinstance(logits_to_keep, int):
res_cu_seqlens[1:] -= position_ids.shape[-1] + 1 - logits_to_keep
return res_cu_seqlens
@contextmanager
def _patch_skip_first_batches(self):
from transformers import trainer
origin_skip_first_batches = trainer.skip_first_batches
def skip_first_batches(dataloader, num_batches=0):
if isinstance(dataloader, (DataLoaderShard, DataLoaderDispatcher)):
# DataLoaderMixin
return self.get_train_dataloader(skip_batches=num_batches)
else:
return origin_skip_first_batches(dataloader, num_batches)
trainer.skip_first_batches = skip_first_batches
try:
yield
finally:
trainer.skip_first_batches = origin_skip_first_batches
class DataLoaderMixin:
def get_sp_dataloader(self, dataset, batch_size, skip_batches=0):
data_collator = self.data_collator
if isinstance(dataset, datasets.Dataset):
dataset = self._remove_unused_columns(dataset, description='training')
else:
data_collator = self._get_collator_with_removed_columns(data_collator, description='training')
if hasattr(dataset, '__len__'):
sampler = SequenceParallelSampler(sequence_parallel, dataset, seed=42)
dataloader_params = {
'batch_size': 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(dataset, torch.utils.data.IterableDataset):
if skip_batches > 0:
from accelerate.data_loader import SkipBatchSampler
sampler = SkipBatchSampler(sampler, skip_batches=skip_batches * batch_size)
dataloader_params['sampler'] = sampler
dataloader_params['drop_last'] = self.args.dataloader_drop_last
dataloader_params['worker_init_fn'] = partial(
seed_worker, num_workers=self.args.dataloader_num_workers, rank=sequence_parallel.dp_rank)
return DataLoaderShard(dataset, device=self.accelerator.device, **dataloader_params)
else:
dataloader_params = {
'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,
'prefetch_factor': self.args.dataloader_prefetch_factor
}
if dist.is_initialized() and dataloader_params['prefetch_factor']:
dataloader_params['prefetch_factor'] = dataloader_params['prefetch_factor'] * dist.get_world_size()
dataloader = DataLoader(dataset, batch_size=batch_size, **dataloader_params)
dataloader = SequenceParallelDispatcher(
dataloader, sequence_parallel, self.accelerator.device, skip_batches=skip_batches)
return dataloader
def get_train_dataloader(self, skip_batches=0):
dataloader = None
if self.template.sequence_parallel_size > 1:
dataloader = self.get_sp_dataloader(self.train_dataset, self._train_batch_size, skip_batches=skip_batches)
if dataloader is None:
# Higher efficiency
if self.train_dataset is None:
raise ValueError('Trainer: training requires a train_dataset.')
args = self.args
train_dataset = self.train_dataset
dataloader_params = {
'collate_fn': self.data_collator,
'num_workers': args.dataloader_num_workers,
'pin_memory': args.dataloader_pin_memory,
'persistent_workers': args.dataloader_persistent_workers,
'prefetch_factor': args.dataloader_prefetch_factor
}
batch_sampler_params = {
'drop_last':
args.dataloader_drop_last,
'shuffle':
args.train_dataloader_shuffle,
'data_seed':
args.data_seed,
'tp_size':
args.deepspeed['tensor_parallel']['autotp_size']
if args.deepspeed and 'tensor_parallel' in args.deepspeed else 1,
}
if hasattr(train_dataset, '__len__'):
if args.group_by_length:
batch_sampler_params['group_by_length'] = args.group_by_length
batch_sampler_params['lengths'] = train_dataset['lengths']
batch_sampler = BatchSamplerShard(
len(train_dataset), batch_size=self._train_batch_size, **batch_sampler_params)
dataloader_params['worker_init_fn'] = partial(
seed_worker, num_workers=self.args.dataloader_num_workers, rank=self.args.process_index)
if skip_batches > 0:
from accelerate.data_loader import SkipBatchSampler
batch_sampler = SkipBatchSampler(batch_sampler, skip_batches=skip_batches)
dataloader_params['batch_sampler'] = batch_sampler
dataloader = DataLoaderShard(train_dataset, device=self.accelerator.device, **dataloader_params)
else:
# IterableDataset
if dist.is_initialized() and dataloader_params['prefetch_factor']:
dataloader_params['prefetch_factor'] = dataloader_params['prefetch_factor'] * dist.get_world_size()
dataloader = DataLoader(train_dataset, batch_size=self._train_batch_size, **dataloader_params)
dataloader = DataLoaderDispatcher(dataloader, self.accelerator.device, skip_batches=skip_batches)
return dataloader
@contextmanager
def _disable_group_by_length(self):
group_by_length = getattr(self.args, 'group_by_length', False)
self.args.group_by_length = False
try:
yield
finally:
self.args.group_by_length = group_by_length
def get_eval_dataloader(self, eval_dataset=None):
dataloader = None
if self.template.sequence_parallel_size > 1:
if eval_dataset is None and self.eval_dataset is None:
raise ValueError('Trainer: evaluation requires an eval_dataset.')
eval_dataset = eval_dataset if eval_dataset is not None else self.eval_dataset
dataloader = self.get_sp_dataloader(eval_dataset, self.args.eval_batch_size)
if dataloader is None:
with self._disable_group_by_length():
return super().get_eval_dataloader(eval_dataset=eval_dataset)
return dataloader