ljy266987
add lfs
12bfd03
raw
history blame
7 kB
"""
This is a base lightning module that can be used to train a model.
The benefit of this abstraction is that all the logic outside of model definition can be reused for different models.
"""
import inspect
from abc import ABC
from typing import Any, Dict
import torch
from lightning import LightningModule
from lightning.pytorch.utilities import grad_norm
from matcha import utils
from matcha.utils.utils import plot_tensor
log = utils.get_pylogger(__name__)
class BaseLightningClass(LightningModule, ABC):
def update_data_statistics(self, data_statistics):
if data_statistics is None:
data_statistics = {
"mel_mean": 0.0,
"mel_std": 1.0,
}
self.register_buffer("mel_mean", torch.tensor(data_statistics["mel_mean"]))
self.register_buffer("mel_std", torch.tensor(data_statistics["mel_std"]))
def configure_optimizers(self) -> Any:
optimizer = self.hparams.optimizer(params=self.parameters())
if self.hparams.scheduler not in (None, {}):
scheduler_args = {}
# Manage last epoch for exponential schedulers
if "last_epoch" in inspect.signature(self.hparams.scheduler.scheduler).parameters:
if hasattr(self, "ckpt_loaded_epoch"):
current_epoch = self.ckpt_loaded_epoch - 1
else:
current_epoch = -1
scheduler_args.update({"optimizer": optimizer})
scheduler = self.hparams.scheduler.scheduler(**scheduler_args)
scheduler.last_epoch = current_epoch
return {
"optimizer": optimizer,
"lr_scheduler": {
"scheduler": scheduler,
"interval": self.hparams.scheduler.lightning_args.interval,
"frequency": self.hparams.scheduler.lightning_args.frequency,
"name": "learning_rate",
},
}
return {"optimizer": optimizer}
def get_losses(self, batch):
x, x_lengths = batch["x"], batch["x_lengths"]
y, y_lengths = batch["y"], batch["y_lengths"]
spks = batch["spks"]
dur_loss, prior_loss, diff_loss = self(
x=x,
x_lengths=x_lengths,
y=y,
y_lengths=y_lengths,
spks=spks,
out_size=self.out_size,
)
return {
"dur_loss": dur_loss,
"prior_loss": prior_loss,
"diff_loss": diff_loss,
}
def on_load_checkpoint(self, checkpoint: Dict[str, Any]) -> None:
self.ckpt_loaded_epoch = checkpoint["epoch"] # pylint: disable=attribute-defined-outside-init
def training_step(self, batch: Any, batch_idx: int):
loss_dict = self.get_losses(batch)
self.log(
"step",
float(self.global_step),
on_step=True,
prog_bar=True,
logger=True,
sync_dist=True,
)
self.log(
"sub_loss/train_dur_loss",
loss_dict["dur_loss"],
on_step=True,
on_epoch=True,
logger=True,
sync_dist=True,
)
self.log(
"sub_loss/train_prior_loss",
loss_dict["prior_loss"],
on_step=True,
on_epoch=True,
logger=True,
sync_dist=True,
)
self.log(
"sub_loss/train_diff_loss",
loss_dict["diff_loss"],
on_step=True,
on_epoch=True,
logger=True,
sync_dist=True,
)
total_loss = sum(loss_dict.values())
self.log(
"loss/train",
total_loss,
on_step=True,
on_epoch=True,
logger=True,
prog_bar=True,
sync_dist=True,
)
return {"loss": total_loss, "log": loss_dict}
def validation_step(self, batch: Any, batch_idx: int):
loss_dict = self.get_losses(batch)
self.log(
"sub_loss/val_dur_loss",
loss_dict["dur_loss"],
on_step=True,
on_epoch=True,
logger=True,
sync_dist=True,
)
self.log(
"sub_loss/val_prior_loss",
loss_dict["prior_loss"],
on_step=True,
on_epoch=True,
logger=True,
sync_dist=True,
)
self.log(
"sub_loss/val_diff_loss",
loss_dict["diff_loss"],
on_step=True,
on_epoch=True,
logger=True,
sync_dist=True,
)
total_loss = sum(loss_dict.values())
self.log(
"loss/val",
total_loss,
on_step=True,
on_epoch=True,
logger=True,
prog_bar=True,
sync_dist=True,
)
return total_loss
def on_validation_end(self) -> None:
if self.trainer.is_global_zero:
one_batch = next(iter(self.trainer.val_dataloaders))
if self.current_epoch == 0:
log.debug("Plotting original samples")
for i in range(2):
y = one_batch["y"][i].unsqueeze(0).to(self.device)
self.logger.experiment.add_image(
f"original/{i}",
plot_tensor(y.squeeze().cpu()),
self.current_epoch,
dataformats="HWC",
)
log.debug("Synthesising...")
for i in range(2):
x = one_batch["x"][i].unsqueeze(0).to(self.device)
x_lengths = one_batch["x_lengths"][i].unsqueeze(0).to(self.device)
spks = one_batch["spks"][i].unsqueeze(0).to(self.device) if one_batch["spks"] is not None else None
output = self.synthesise(x[:, :x_lengths], x_lengths, n_timesteps=10, spks=spks)
y_enc, y_dec = output["encoder_outputs"], output["decoder_outputs"]
attn = output["attn"]
self.logger.experiment.add_image(
f"generated_enc/{i}",
plot_tensor(y_enc.squeeze().cpu()),
self.current_epoch,
dataformats="HWC",
)
self.logger.experiment.add_image(
f"generated_dec/{i}",
plot_tensor(y_dec.squeeze().cpu()),
self.current_epoch,
dataformats="HWC",
)
self.logger.experiment.add_image(
f"alignment/{i}",
plot_tensor(attn.squeeze().cpu()),
self.current_epoch,
dataformats="HWC",
)
def on_before_optimizer_step(self, optimizer):
self.log_dict({f"grad_norm/{k}": v for k, v in grad_norm(self, norm_type=2).items()})