Files
2026-07-13 12:35:17 +08:00

515 lines
20 KiB
Python

import logging
import os
import pathlib
import shutil
import sys
from typing import Dict
import matplotlib
import utils
matplotlib.use('Agg')
import torch.utils.data
from torchmetrics import Metric, MeanMetric
import lightning.pytorch as pl
from lightning.pytorch.utilities.rank_zero import rank_zero_debug, rank_zero_info, rank_zero_only
from basics.base_module import CategorizedModule
from utils.hparams import hparams
from utils.training_utils import (
DsModelCheckpoint, DsTQDMProgressBar,
DsBatchSampler, DsTensorBoardLogger,
get_latest_checkpoint_path, get_strategy
)
from utils.phoneme_utils import load_phoneme_dictionary
torch.multiprocessing.set_sharing_strategy(os.getenv('TORCH_SHARE_STRATEGY', 'file_system'))
log_format = '%(asctime)s %(message)s'
logging.basicConfig(stream=sys.stdout, level=logging.INFO,
format=log_format, datefmt='%m/%d %I:%M:%S %p')
class BaseTask(pl.LightningModule):
"""
Base class for training tasks.
1. *load_ckpt*:
load checkpoint;
2. *training_step*:
record and log the loss;
3. *optimizer_step*:
run backwards step;
4. *start*:
load training configs, backup code, log to tensorboard, start training;
5. *configure_ddp* and *init_ddp_connection*:
start parallel training.
Subclasses should define:
1. *build_model*, *build_optimizer*, *build_scheduler*:
how to build the model, the optimizer and the training scheduler;
2. *_training_step*:
one training step of the model;
3. *on_validation_end* and *_on_validation_end*:
postprocess the validation output.
"""
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.max_batch_frames = hparams['max_batch_frames']
self.max_batch_size = hparams['max_batch_size']
self.max_val_batch_frames = hparams['max_val_batch_frames']
if self.max_val_batch_frames == -1:
hparams['max_val_batch_frames'] = self.max_val_batch_frames = self.max_batch_frames
self.max_val_batch_size = hparams['max_val_batch_size']
if self.max_val_batch_size == -1:
hparams['max_val_batch_size'] = self.max_val_batch_size = self.max_batch_size
self.training_sampler = None
self.skip_immediate_validation = False
self.skip_immediate_ckpt_save = False
self.phoneme_dictionary = load_phoneme_dictionary()
self.build_model()
self.valid_losses: Dict[str, Metric] = {}
self.valid_metrics: Dict[str, Metric] = {}
def _finish_init(self):
self.register_validation_loss('total_loss')
self.build_losses_and_metrics()
assert len(self.valid_losses) > 0, "No validation loss registered. Please check your configuration file."
###########
# Training, validation and testing
###########
def setup(self, stage):
self.train_dataset = self.dataset_cls('train')
self.valid_dataset = self.dataset_cls('valid')
self.num_replicas = (self.trainer.distributed_sampler_kwargs or {}).get('num_replicas', 1)
def get_need_freeze_state_dict_key(self, model_state_dict) -> list:
key_list = []
for i in hparams['frozen_params']:
for j in model_state_dict:
if j.startswith(i):
key_list.append(j)
return list(set(key_list))
def freeze_params(self) -> None:
model_state_dict = self.state_dict().keys()
freeze_key = self.get_need_freeze_state_dict_key(model_state_dict=model_state_dict)
for i in freeze_key:
params=self.get_parameter(i)
params.requires_grad = False
def unfreeze_all_params(self) -> None:
for i in self.model.parameters():
i.requires_grad = True
def load_finetune_ckpt(
self, state_dict
) -> None:
adapt_shapes = hparams['finetune_strict_shapes']
if not adapt_shapes:
cur_model_state_dict = self.state_dict()
unmatched_keys = []
for key, param in state_dict.items():
if key in cur_model_state_dict:
new_param = cur_model_state_dict[key]
if new_param.shape != param.shape:
unmatched_keys.append(key)
print('| Unmatched keys: ', key, new_param.shape, param.shape)
for key in unmatched_keys:
del state_dict[key]
self.load_state_dict(state_dict, strict=False)
def load_pre_train_model(self):
pre_train_ckpt_path = hparams['finetune_ckpt_path']
blacklist = hparams['finetune_ignored_params']
# whitelist=hparams['pre_train_whitelist']
if blacklist is None:
blacklist = []
# if whitelist is None:
# raise RuntimeError("")
if pre_train_ckpt_path is not None:
ckpt = torch.load(pre_train_ckpt_path)
# if ckpt.get('category') is None:
# raise RuntimeError("")
if isinstance(self.model, CategorizedModule):
self.model.check_category(ckpt.get('category'))
state_dict = {}
for i in ckpt['state_dict']:
# if 'diffusion' in i:
# if i in rrrr:
# continue
skip = False
for b in blacklist:
if i.startswith(b):
skip = True
break
if skip:
continue
state_dict[i] = ckpt['state_dict'][i]
print(i)
return state_dict
else:
raise RuntimeError("")
def _build_model(self):
raise NotImplementedError()
def build_model(self):
self.model = self._build_model()
# utils.load_warp(self)
self.unfreeze_all_params()
if hparams['freezing_enabled']:
self.freeze_params()
if hparams['finetune_enabled'] and get_latest_checkpoint_path(pathlib.Path(hparams['work_dir'])) is None:
self.load_finetune_ckpt(self.load_pre_train_model())
self.print_arch()
@rank_zero_only
def print_arch(self):
utils.print_arch(self.model)
def build_losses_and_metrics(self):
raise NotImplementedError()
def register_validation_metric(self, name: str, metric: Metric):
assert isinstance(metric, Metric)
self.valid_metrics[name] = metric
def register_validation_loss(self, name: str, Aggregator: Metric = MeanMetric):
assert issubclass(Aggregator, Metric)
self.valid_losses[name] = Aggregator()
def run_model(self, sample, infer=False):
"""
steps:
1. run the full model
2. calculate losses if not infer
"""
raise NotImplementedError()
def on_train_epoch_start(self):
if self.training_sampler is not None:
self.training_sampler.set_epoch(self.current_epoch)
def _training_step(self, sample):
"""
:return: total loss: torch.Tensor, loss_log: dict, other_log: dict
"""
losses = self.run_model(sample)
total_loss = sum(losses.values())
return total_loss, {**losses, 'batch_size': float(sample['size'])}
def training_step(self, sample, batch_idx):
total_loss, log_outputs = self._training_step(sample)
# logs to progress bar
self.log_dict(log_outputs, prog_bar=True, logger=False, on_step=True, on_epoch=False)
self.log('lr', self.lr_schedulers().get_last_lr()[0], prog_bar=True, logger=False, on_step=True, on_epoch=False)
# logs to tensorboard
if self.global_step % hparams['log_interval'] == 0:
tb_log = {f'training/{k}': v for k, v in log_outputs.items()}
tb_log['training/lr'] = self.lr_schedulers().get_last_lr()[0]
self.logger.log_metrics(tb_log, step=self.global_step)
return total_loss
# def on_before_optimizer_step(self, *args, **kwargs):
# self.log_dict(grad_norm(self, norm_type=2))
def _on_validation_start(self):
pass
def on_validation_start(self):
if self.skip_immediate_validation:
rank_zero_debug("Skip validation")
return
self._on_validation_start()
for metric in self.valid_losses.values():
metric.to(self.device)
metric.reset()
for metric in self.valid_metrics.values():
metric.to(self.device)
metric.reset()
def _validation_step(self, sample, batch_idx):
"""
:param sample:
:param batch_idx:
:return: loss_log: dict, weight: int
"""
raise NotImplementedError()
def validation_step(self, sample, batch_idx):
"""
:param sample:
:param batch_idx:
"""
if self.skip_immediate_validation:
rank_zero_debug("Skip validation")
return
if sample['size'] > 0:
with torch.autocast(self.device.type, enabled=False):
losses, weight = self._validation_step(sample, batch_idx)
losses = {
'total_loss': sum(losses.values()),
**losses
}
for k, v in losses.items():
self.valid_losses[k].update(v, weight=weight)
def _on_validation_epoch_end(self):
pass
def on_validation_epoch_end(self):
if self.skip_immediate_validation:
self.skip_immediate_validation = False
self.skip_immediate_ckpt_save = True
return
self._on_validation_epoch_end()
loss_vals = {k: v.compute() for k, v in self.valid_losses.items()}
metric_vals = {k: v.compute() for k, v in self.valid_metrics.items()}
self.log('val_loss', loss_vals['total_loss'], on_epoch=True, prog_bar=True, logger=False, sync_dist=True)
self.logger.log_metrics({f'validation/{k}': v for k, v in loss_vals.items()}, step=self.global_step)
self.logger.log_metrics({f'metrics/{k}': v for k, v in metric_vals.items()}, step=self.global_step)
# noinspection PyMethodMayBeStatic
def build_scheduler(self, optimizer):
from utils import build_lr_scheduler_from_config
scheduler_args = hparams['lr_scheduler_args']
assert scheduler_args['scheduler_cls'] != ''
scheduler = build_lr_scheduler_from_config(optimizer, scheduler_args)
return scheduler
# noinspection PyMethodMayBeStatic
def build_optimizer(self, model):
from utils import build_object_from_class_name
optimizer_args = hparams['optimizer_args']
assert optimizer_args['optimizer_cls'] != ''
if 'beta1' in optimizer_args and 'beta2' in optimizer_args and 'betas' not in optimizer_args:
optimizer_args['betas'] = (optimizer_args['beta1'], optimizer_args['beta2'])
optimizer = build_object_from_class_name(
optimizer_args['optimizer_cls'],
torch.optim.Optimizer,
model if optimizer_args['optimizer_cls'] == 'modules.optimizer.muon.Muon_AdamW' else model.parameters(),
**optimizer_args
)
return optimizer
def configure_optimizers(self):
optm = self.build_optimizer(self.model)
scheduler = self.build_scheduler(optm)
if scheduler is None:
return optm
return {
"optimizer": optm,
"lr_scheduler": {
"scheduler": scheduler,
"interval": "step",
"frequency": 1
}
}
def train_dataloader(self):
self.training_sampler = DsBatchSampler(
self.train_dataset,
max_batch_frames=self.max_batch_frames,
max_batch_size=self.max_batch_size,
num_replicas=self.num_replicas,
rank=self.global_rank,
sort_by_similar_size=hparams['sort_by_len'],
size_reversed=True,
required_batch_count_multiple=hparams['accumulate_grad_batches'],
shuffle_sample=True,
shuffle_batch=True
)
return torch.utils.data.DataLoader(
self.train_dataset,
collate_fn=self.train_dataset.collater,
batch_sampler=self.training_sampler,
num_workers=hparams['ds_workers'],
prefetch_factor=hparams['dataloader_prefetch_factor'],
pin_memory=True,
persistent_workers=True
)
def val_dataloader(self):
sampler = DsBatchSampler(
self.valid_dataset,
max_batch_frames=self.max_val_batch_frames,
max_batch_size=self.max_val_batch_size,
num_replicas=self.num_replicas,
rank=self.global_rank,
shuffle_sample=False,
shuffle_batch=False,
disallow_empty_batch=False,
pad_batch_assignment=False
)
return torch.utils.data.DataLoader(
self.valid_dataset,
collate_fn=self.valid_dataset.collater,
batch_sampler=sampler,
num_workers=hparams['ds_workers'],
prefetch_factor=hparams['dataloader_prefetch_factor'],
persistent_workers=True
)
def test_dataloader(self):
return self.val_dataloader()
def on_test_start(self):
self.on_validation_start()
def test_step(self, sample, batch_idx):
return self.validation_step(sample, batch_idx)
def on_test_end(self):
return self.on_validation_end()
###########
# Running configuration
###########
@classmethod
def start(cls):
task = cls()
# if pre_train is not None:
# task.load_state_dict(pre_train,strict=False)
# print("load success-------------------------------------------------------------------")
work_dir = pathlib.Path(hparams['work_dir'])
trainer = pl.Trainer(
accelerator=hparams['pl_trainer_accelerator'],
devices=hparams['pl_trainer_devices'],
num_nodes=hparams['pl_trainer_num_nodes'],
strategy=get_strategy(
hparams['pl_trainer_devices'],
hparams['pl_trainer_num_nodes'],
hparams['pl_trainer_accelerator'],
hparams['pl_trainer_strategy'],
hparams['pl_trainer_precision'],
),
precision=hparams['pl_trainer_precision'],
callbacks=[
DsModelCheckpoint(
dirpath=work_dir,
filename='model_ckpt_steps_{step}',
auto_insert_metric_name=False,
monitor='step',
mode='max',
save_last=False,
# every_n_train_steps=hparams['val_check_interval'],
save_top_k=hparams['num_ckpt_keep'],
permanent_ckpt_start=hparams['permanent_ckpt_start'],
permanent_ckpt_interval=hparams['permanent_ckpt_interval'],
verbose=True
),
# LearningRateMonitor(logging_interval='step'),
DsTQDMProgressBar(),
],
logger=DsTensorBoardLogger(
save_dir=str(work_dir),
name='lightning_logs',
version='latest'
),
gradient_clip_val=hparams['clip_grad_norm'],
val_check_interval=hparams['val_check_interval'] * hparams['accumulate_grad_batches'],
# so this is global_steps
check_val_every_n_epoch=None,
log_every_n_steps=1,
max_steps=hparams['max_updates'],
use_distributed_sampler=False,
num_sanity_val_steps=hparams['num_sanity_val_steps'],
accumulate_grad_batches=hparams['accumulate_grad_batches']
)
if not hparams['infer']: # train
@rank_zero_only
def train_payload_copy():
# Copy files to work_dir
binary_dir = pathlib.Path(hparams['binary_data_dir'])
spk_map_dst = work_dir / 'spk_map.json'
spk_map_src = binary_dir / 'spk_map.json'
shutil.copy(spk_map_src, spk_map_dst)
print(f'| Copied spk map to {spk_map_dst}.')
lang_map_dst = work_dir / 'lang_map.json'
lang_map_src = binary_dir / 'lang_map.json'
shutil.copy(lang_map_src, lang_map_dst)
print(f'| Copied lang map to {lang_map_dst}.')
for lang in hparams['dictionaries'].keys():
dict_dst = work_dir / f'dictionary-{lang}.txt'
dict_src = binary_dir / f'dictionary-{lang}.txt'
shutil.copy(dict_src, dict_dst)
print(f'| Copied dictionary for language \'{lang}\' to {dict_dst}.')
train_payload_copy()
trainer.fit(task, ckpt_path=get_latest_checkpoint_path(work_dir))
else:
trainer.test(task)
def on_save_checkpoint(self, checkpoint):
if isinstance(self.model, CategorizedModule):
checkpoint['category'] = self.model.category
checkpoint['trainer_stage'] = self.trainer.state.stage.value
def on_load_checkpoint(self, checkpoint):
from lightning.pytorch.trainer.states import RunningStage
from utils import simulate_lr_scheduler
if checkpoint.get('trainer_stage', '') == RunningStage.VALIDATING.value:
self.skip_immediate_validation = True
optimizer_args = hparams['optimizer_args']
scheduler_args = hparams['lr_scheduler_args']
if 'beta1' in optimizer_args and 'beta2' in optimizer_args and 'betas' not in optimizer_args:
optimizer_args['betas'] = (optimizer_args['beta1'], optimizer_args['beta2'])
if checkpoint.get('optimizer_states', None):
opt_states = checkpoint['optimizer_states']
assert len(opt_states) == 1 # only support one optimizer
opt_state = opt_states[0]
for param_group in opt_state['param_groups']:
for k, v in optimizer_args.items():
if k in param_group and param_group[k] != v:
if 'lr_schedulers' in checkpoint and checkpoint['lr_schedulers'] and k == 'lr':
continue
rank_zero_info(f'| Overriding optimizer parameter {k} from checkpoint: {param_group[k]} -> {v}')
param_group[k] = v
if 'initial_lr' in param_group and param_group['initial_lr'] != optimizer_args['lr']:
rank_zero_info(
f'| Overriding optimizer parameter initial_lr from checkpoint: {param_group["initial_lr"]} -> {optimizer_args["lr"]}'
)
param_group['initial_lr'] = optimizer_args['lr']
if checkpoint.get('lr_schedulers', None):
assert checkpoint.get('optimizer_states', False)
assert len(checkpoint['lr_schedulers']) == 1 # only support one scheduler
checkpoint['lr_schedulers'][0] = simulate_lr_scheduler(
optimizer_args, scheduler_args,
step_count=checkpoint['global_step'],
num_param_groups=len(checkpoint['optimizer_states'][0]['param_groups'])
)
for param_group, new_lr in zip(
checkpoint['optimizer_states'][0]['param_groups'],
checkpoint['lr_schedulers'][0]['_last_lr'],
):
if param_group['lr'] != new_lr:
rank_zero_info(f'| Overriding optimizer parameter lr from checkpoint: {param_group["lr"]} -> {new_lr}')
param_group['lr'] = new_lr