clonar-voz / TTS /tts /models /neuralhmm_tts.py
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import os
from typing import Dict, List, Union
import torch
from coqpit import Coqpit
from torch import nn
from trainer.logging.tensorboard_logger import TensorboardLogger
from TTS.tts.layers.overflow.common_layers import Encoder, OverflowUtils
from TTS.tts.layers.overflow.neural_hmm import NeuralHMM
from TTS.tts.layers.overflow.plotting_utils import (
get_spec_from_most_probable_state,
plot_transition_probabilities_to_numpy,
)
from TTS.tts.models.base_tts import BaseTTS
from TTS.tts.utils.speakers import SpeakerManager
from TTS.tts.utils.text.tokenizer import TTSTokenizer
from TTS.tts.utils.visual import plot_alignment, plot_spectrogram
from TTS.utils.generic_utils import format_aux_input
from TTS.utils.io import load_fsspec
class NeuralhmmTTS(BaseTTS):
"""Neural HMM TTS model.
Paper::
https://arxiv.org/abs/2108.13320
Paper abstract::
Neural sequence-to-sequence TTS has achieved significantly better output quality
than statistical speech synthesis using HMMs.However, neural TTS is generally not probabilistic
and uses non-monotonic attention. Attention failures increase training time and can make
synthesis babble incoherently. This paper describes how the old and new paradigms can be
combined to obtain the advantages of both worlds, by replacing attention in neural TTS with
an autoregressive left-right no-skip hidden Markov model defined by a neural network.
Based on this proposal, we modify Tacotron 2 to obtain an HMM-based neural TTS model with
monotonic alignment, trained to maximise the full sequence likelihood without approximation.
We also describe how to combine ideas from classical and contemporary TTS for best results.
The resulting example system is smaller and simpler than Tacotron 2, and learns to speak with
fewer iterations and less data, whilst achieving comparable naturalness prior to the post-net.
Our approach also allows easy control over speaking rate. Audio examples and code
are available at https://shivammehta25.github.io/Neural-HMM/ .
Note:
- This is a parameter efficient version of OverFlow (15.3M vs 28.6M). Since it has half the
number of parameters as OverFlow the synthesis output quality is suboptimal (but comparable to Tacotron2
without Postnet), but it learns to speak with even lesser amount of data and is still significantly faster
than other attention-based methods.
- Neural HMMs uses flat start initialization i.e it computes the means and std and transition probabilities
of the dataset and uses them to initialize the model. This benefits the model and helps with faster learning
If you change the dataset or want to regenerate the parameters change the `force_generate_statistics` and
`mel_statistics_parameter_path` accordingly.
- To enable multi-GPU training, set the `use_grad_checkpointing=False` in config.
This will significantly increase the memory usage. This is because to compute
the actual data likelihood (not an approximation using MAS/Viterbi) we must use
all the states at the previous time step during the forward pass to decide the
probability distribution at the current step i.e the difference between the forward
algorithm and viterbi approximation.
Check :class:`TTS.tts.configs.neuralhmm_tts_config.NeuralhmmTTSConfig` for class arguments.
"""
def __init__(
self,
config: "NeuralhmmTTSConfig",
ap: "AudioProcessor" = None,
tokenizer: "TTSTokenizer" = None,
speaker_manager: SpeakerManager = None,
):
super().__init__(config, ap, tokenizer, speaker_manager)
# pass all config fields to `self`
# for fewer code change
self.config = config
for key in config:
setattr(self, key, config[key])
self.encoder = Encoder(config.num_chars, config.state_per_phone, config.encoder_in_out_features)
self.neural_hmm = NeuralHMM(
frame_channels=self.out_channels,
ar_order=self.ar_order,
deterministic_transition=self.deterministic_transition,
encoder_dim=self.encoder_in_out_features,
prenet_type=self.prenet_type,
prenet_dim=self.prenet_dim,
prenet_n_layers=self.prenet_n_layers,
prenet_dropout=self.prenet_dropout,
prenet_dropout_at_inference=self.prenet_dropout_at_inference,
memory_rnn_dim=self.memory_rnn_dim,
outputnet_size=self.outputnet_size,
flat_start_params=self.flat_start_params,
std_floor=self.std_floor,
use_grad_checkpointing=self.use_grad_checkpointing,
)
self.register_buffer("mean", torch.tensor(0))
self.register_buffer("std", torch.tensor(1))
def update_mean_std(self, statistics_dict: Dict):
self.mean.data = torch.tensor(statistics_dict["mean"])
self.std.data = torch.tensor(statistics_dict["std"])
def preprocess_batch(self, text, text_len, mels, mel_len):
if self.mean.item() == 0 or self.std.item() == 1:
statistics_dict = torch.load(self.mel_statistics_parameter_path)
self.update_mean_std(statistics_dict)
mels = self.normalize(mels)
return text, text_len, mels, mel_len
def normalize(self, x):
return x.sub(self.mean).div(self.std)
def inverse_normalize(self, x):
return x.mul(self.std).add(self.mean)
def forward(self, text, text_len, mels, mel_len):
"""
Forward pass for training and computing the log likelihood of a given batch.
Shapes:
Shapes:
text: :math:`[B, T_in]`
text_len: :math:`[B]`
mels: :math:`[B, T_out, C]`
mel_len: :math:`[B]`
"""
text, text_len, mels, mel_len = self.preprocess_batch(text, text_len, mels, mel_len)
encoder_outputs, encoder_output_len = self.encoder(text, text_len)
log_probs, fwd_alignments, transition_vectors, means = self.neural_hmm(
encoder_outputs, encoder_output_len, mels.transpose(1, 2), mel_len
)
outputs = {
"log_probs": log_probs,
"alignments": fwd_alignments,
"transition_vectors": transition_vectors,
"means": means,
}
return outputs
@staticmethod
def _training_stats(batch):
stats = {}
stats["avg_text_length"] = batch["text_lengths"].float().mean()
stats["avg_spec_length"] = batch["mel_lengths"].float().mean()
stats["avg_text_batch_occupancy"] = (batch["text_lengths"].float() / batch["text_lengths"].float().max()).mean()
stats["avg_spec_batch_occupancy"] = (batch["mel_lengths"].float() / batch["mel_lengths"].float().max()).mean()
return stats
def train_step(self, batch: dict, criterion: nn.Module):
text_input = batch["text_input"]
text_lengths = batch["text_lengths"]
mel_input = batch["mel_input"]
mel_lengths = batch["mel_lengths"]
outputs = self.forward(
text=text_input,
text_len=text_lengths,
mels=mel_input,
mel_len=mel_lengths,
)
loss_dict = criterion(outputs["log_probs"] / (mel_lengths.sum() + text_lengths.sum()))
# for printing useful statistics on terminal
loss_dict.update(self._training_stats(batch))
return outputs, loss_dict
def eval_step(self, batch: Dict, criterion: nn.Module):
return self.train_step(batch, criterion)
def _format_aux_input(self, aux_input: Dict, default_input_dict):
"""Set missing fields to their default value.
Args:
aux_inputs (Dict): Dictionary containing the auxiliary inputs.
"""
default_input_dict = default_input_dict.copy()
default_input_dict.update(
{
"sampling_temp": self.sampling_temp,
"max_sampling_time": self.max_sampling_time,
"duration_threshold": self.duration_threshold,
}
)
if aux_input:
return format_aux_input(default_input_dict, aux_input)
return default_input_dict
@torch.no_grad()
def inference(
self,
text: torch.Tensor,
aux_input={"x_lengths": None, "sampling_temp": None, "max_sampling_time": None, "duration_threshold": None},
): # pylint: disable=dangerous-default-value
"""Sampling from the model
Args:
text (torch.Tensor): :math:`[B, T_in]`
aux_inputs (_type_, optional): _description_. Defaults to None.
Returns:
outputs: Dictionary containing the following
- mel (torch.Tensor): :math:`[B, T_out, C]`
- hmm_outputs_len (torch.Tensor): :math:`[B]`
- state_travelled (List[List[int]]): List of lists containing the state travelled for each sample in the batch.
- input_parameters (list[torch.FloatTensor]): Input parameters to the neural HMM.
- output_parameters (list[torch.FloatTensor]): Output parameters to the neural HMM.
"""
default_input_dict = {
"x_lengths": torch.sum(text != 0, dim=1),
}
aux_input = self._format_aux_input(aux_input, default_input_dict)
encoder_outputs, encoder_output_len = self.encoder.inference(text, aux_input["x_lengths"])
outputs = self.neural_hmm.inference(
encoder_outputs,
encoder_output_len,
sampling_temp=aux_input["sampling_temp"],
max_sampling_time=aux_input["max_sampling_time"],
duration_threshold=aux_input["duration_threshold"],
)
mels, mel_outputs_len = outputs["hmm_outputs"], outputs["hmm_outputs_len"]
mels = self.inverse_normalize(mels)
outputs.update({"model_outputs": mels, "model_outputs_len": mel_outputs_len})
outputs["alignments"] = OverflowUtils.double_pad(outputs["alignments"])
return outputs
@staticmethod
def get_criterion():
return NLLLoss()
@staticmethod
def init_from_config(config: "NeuralhmmTTSConfig", samples: Union[List[List], List[Dict]] = None, verbose=True):
"""Initiate model from config
Args:
config (VitsConfig): Model config.
samples (Union[List[List], List[Dict]]): Training samples to parse speaker ids for training.
Defaults to None.
verbose (bool): If True, print init messages. Defaults to True.
"""
from TTS.utils.audio import AudioProcessor
ap = AudioProcessor.init_from_config(config, verbose)
tokenizer, new_config = TTSTokenizer.init_from_config(config)
speaker_manager = SpeakerManager.init_from_config(config, samples)
return NeuralhmmTTS(new_config, ap, tokenizer, speaker_manager)
def load_checkpoint(
self, config: Coqpit, checkpoint_path: str, eval: bool = False, strict: bool = True, cache=False
): # pylint: disable=unused-argument, redefined-builtin
state = load_fsspec(checkpoint_path, map_location=torch.device("cpu"))
self.load_state_dict(state["model"])
if eval:
self.eval()
assert not self.training
def on_init_start(self, trainer):
"""If the current dataset does not have normalisation statistics and initialisation transition_probability it computes them otherwise loads."""
if not os.path.isfile(trainer.config.mel_statistics_parameter_path) or trainer.config.force_generate_statistics:
dataloader = trainer.get_train_dataloader(
training_assets=None, samples=trainer.train_samples, verbose=False
)
print(
f" | > Data parameters not found for: {trainer.config.mel_statistics_parameter_path}. Computing mel normalization parameters..."
)
data_mean, data_std, init_transition_prob = OverflowUtils.get_data_parameters_for_flat_start(
dataloader, trainer.config.out_channels, trainer.config.state_per_phone
)
print(
f" | > Saving data parameters to: {trainer.config.mel_statistics_parameter_path}: value: {data_mean, data_std, init_transition_prob}"
)
statistics = {
"mean": data_mean.item(),
"std": data_std.item(),
"init_transition_prob": init_transition_prob.item(),
}
torch.save(statistics, trainer.config.mel_statistics_parameter_path)
else:
print(
f" | > Data parameters found for: {trainer.config.mel_statistics_parameter_path}. Loading mel normalization parameters..."
)
statistics = torch.load(trainer.config.mel_statistics_parameter_path)
data_mean, data_std, init_transition_prob = (
statistics["mean"],
statistics["std"],
statistics["init_transition_prob"],
)
print(f" | > Data parameters loaded with value: {data_mean, data_std, init_transition_prob}")
trainer.config.flat_start_params["transition_p"] = (
init_transition_prob.item() if torch.is_tensor(init_transition_prob) else init_transition_prob
)
OverflowUtils.update_flat_start_transition(trainer.model, init_transition_prob)
trainer.model.update_mean_std(statistics)
@torch.inference_mode()
def _create_logs(self, batch, outputs, ap): # pylint: disable=no-self-use, unused-argument
alignments, transition_vectors = outputs["alignments"], outputs["transition_vectors"]
means = torch.stack(outputs["means"], dim=1)
figures = {
"alignment": plot_alignment(alignments[0].exp(), title="Forward alignment", fig_size=(20, 20)),
"log_alignment": plot_alignment(
alignments[0].exp(), title="Forward log alignment", plot_log=True, fig_size=(20, 20)
),
"transition_vectors": plot_alignment(transition_vectors[0], title="Transition vectors", fig_size=(20, 20)),
"mel_from_most_probable_state": plot_spectrogram(
get_spec_from_most_probable_state(alignments[0], means[0]), fig_size=(12, 3)
),
"mel_target": plot_spectrogram(batch["mel_input"][0], fig_size=(12, 3)),
}
# sample one item from the batch -1 will give the smalles item
print(" | > Synthesising audio from the model...")
inference_output = self.inference(
batch["text_input"][-1].unsqueeze(0), aux_input={"x_lengths": batch["text_lengths"][-1].unsqueeze(0)}
)
figures["synthesised"] = plot_spectrogram(inference_output["model_outputs"][0], fig_size=(12, 3))
states = [p[1] for p in inference_output["input_parameters"][0]]
transition_probability_synthesising = [p[2].cpu().numpy() for p in inference_output["output_parameters"][0]]
for i in range((len(transition_probability_synthesising) // 200) + 1):
start = i * 200
end = (i + 1) * 200
figures[f"synthesised_transition_probabilities/{i}"] = plot_transition_probabilities_to_numpy(
states[start:end], transition_probability_synthesising[start:end]
)
audio = ap.inv_melspectrogram(inference_output["model_outputs"][0].T.cpu().numpy())
return figures, {"audios": audio}
def train_log(
self, batch: dict, outputs: dict, logger: "Logger", assets: dict, steps: int
): # pylint: disable=unused-argument
"""Log training progress."""
figures, audios = self._create_logs(batch, outputs, self.ap)
logger.train_figures(steps, figures)
logger.train_audios(steps, audios, self.ap.sample_rate)
def eval_log(
self, batch: Dict, outputs: Dict, logger: "Logger", assets: Dict, steps: int
): # pylint: disable=unused-argument
"""Compute and log evaluation metrics."""
# Plot model parameters histograms
if isinstance(logger, TensorboardLogger):
# I don't know if any other loggers supports this
for tag, value in self.named_parameters():
tag = tag.replace(".", "/")
logger.writer.add_histogram(tag, value.data.cpu().numpy(), steps)
figures, audios = self._create_logs(batch, outputs, self.ap)
logger.eval_figures(steps, figures)
logger.eval_audios(steps, audios, self.ap.sample_rate)
def test_log(
self, outputs: dict, logger: "Logger", assets: dict, steps: int # pylint: disable=unused-argument
) -> None:
logger.test_audios(steps, outputs[1], self.ap.sample_rate)
logger.test_figures(steps, outputs[0])
class NLLLoss(nn.Module):
"""Negative log likelihood loss."""
def forward(self, log_prob: torch.Tensor) -> dict: # pylint: disable=no-self-use
"""Compute the loss.
Args:
logits (Tensor): [B, T, D]
Returns:
Tensor: [1]
"""
return_dict = {}
return_dict["loss"] = -log_prob.mean()
return return_dict