coqui-tts/TTS/tts/models/vits.py

from dataclasses import dataclass, field
from typing import Dict, List, Tuple

import torch
from coqpit import Coqpit
from torch import nn
from torch.cuda.amp.autocast_mode import autocast

from TTS.tts.layers.glow_tts.duration_predictor import DurationPredictor
from TTS.tts.layers.glow_tts.monotonic_align import generate_path, maximum_path
from TTS.tts.layers.vits.discriminator import VitsDiscriminator
from TTS.tts.layers.vits.networks import PosteriorEncoder, ResidualCouplingBlocks, TextEncoder
from TTS.tts.layers.vits.stochastic_duration_predictor import StochasticDurationPredictor

# from TTS.tts.layers.vits.sdp import StochasticDurationPredictor
from TTS.tts.models.base_tts import BaseTTS
from TTS.tts.utils.data import sequence_mask
from TTS.tts.utils.speakers import get_speaker_manager
from TTS.tts.utils.synthesis import synthesis
from TTS.tts.utils.visual import plot_alignment
from TTS.utils.audio import AudioProcessor
from TTS.utils.trainer_utils import get_optimizer, get_scheduler
from TTS.vocoder.models.hifigan_generator import HifiganGenerator
from TTS.vocoder.utils.generic_utils import plot_results


def segment(x: torch.tensor, segment_indices: torch.tensor, segment_size=4):
    """Segment each sample in a batch based on the provided segment indices"""
    segments = torch.zeros_like(x[:, :, :segment_size])
    for i in range(x.size(0)):
        index_start = segment_indices[i]
        index_end = index_start + segment_size
        segments[i] = x[i, :, index_start:index_end]
    return segments


def rand_segment(x: torch.tensor, x_lengths: torch.tensor = None, segment_size=4):
    """Create random segments based on the input lengths."""
    B, _, T = x.size()
    if x_lengths is None:
        x_lengths = T
    max_idxs = x_lengths - segment_size + 1
    assert all(max_idxs > 0), " [!] At least one sample is shorter than the segment size."
    ids_str = (torch.rand([B]).type_as(x) * max_idxs).long()
    ret = segment(x, ids_str, segment_size)
    return ret, ids_str


@dataclass
class VitsArgs(Coqpit):
    """VITS model arguments.

    Args:

        num_chars (int):
            Number of characters in the vocabulary. Defaults to 100.

        out_channels (int):
            Number of output channels. Defaults to 513.

        spec_segment_size (int):
            Decoder input segment size. Defaults to 32 `(32 * hoplength = waveform length)`.

        hidden_channels (int):
            Number of hidden channels of the model. Defaults to 192.

        hidden_channels_ffn_text_encoder (int):
            Number of hidden channels of the feed-forward layers of the text encoder transformer. Defaults to 256.

        num_heads_text_encoder (int):
            Number of attention heads of the text encoder transformer. Defaults to 2.

        num_layers_text_encoder (int):
            Number of transformer layers in the text encoder. Defaults to 6.

        kernel_size_text_encoder (int):
            Kernel size of the text encoder transformer FFN layers. Defaults to 3.

        dropout_p_text_encoder (float):
            Dropout rate of the text encoder. Defaults to 0.1.

        dropout_p_duration_predictor (float):
            Dropout rate of the duration predictor. Defaults to 0.1.

        kernel_size_posterior_encoder (int):
            Kernel size of the posterior encoder's WaveNet layers. Defaults to 5.

        dilatation_posterior_encoder (int):
            Dilation rate of the posterior encoder's WaveNet layers. Defaults to 1.

        num_layers_posterior_encoder (int):
            Number of posterior encoder's WaveNet layers. Defaults to 16.

        kernel_size_flow (int):
            Kernel size of the Residual Coupling layers of the flow network. Defaults to 5.

        dilatation_flow (int):
            Dilation rate of the Residual Coupling WaveNet layers of the flow network. Defaults to 1.

        num_layers_flow (int):
            Number of Residual Coupling WaveNet layers of the flow network. Defaults to 6.

        resblock_type_decoder (str):
            Type of the residual block in the decoder network. Defaults to "1".

        resblock_kernel_sizes_decoder (List[int]):
            Kernel sizes of the residual blocks in the decoder network. Defaults to `[3, 7, 11]`.

        resblock_dilation_sizes_decoder (List[List[int]]):
            Dilation sizes of the residual blocks in the decoder network. Defaults to `[[1, 3, 5], [1, 3, 5], [1, 3, 5]]`.

        upsample_rates_decoder (List[int]):
            Upsampling rates for each concecutive upsampling layer in the decoder network. The multiply of these
            values must be equal to the kop length used for computing spectrograms. Defaults to `[8, 8, 2, 2]`.

        upsample_initial_channel_decoder (int):
            Number of hidden channels of the first upsampling convolution layer of the decoder network. Defaults to 512.

        upsample_kernel_sizes_decoder (List[int]):
            Kernel sizes for each upsampling layer of the decoder network. Defaults to `[16, 16, 4, 4]`.

        use_sdp (int):
            Use Stochastic Duration Predictor. Defaults to True.

        noise_scale (float):
            Noise scale used for the sample noise tensor in training. Defaults to 1.0.

        inference_noise_scale (float):
            Noise scale used for the sample noise tensor in inference. Defaults to 0.667.

        length_scale (int):
            Scale factor for the predicted duration values. Smaller values result faster speech. Defaults to 1.

        noise_scale_dp (float):
            Noise scale used by the Stochastic Duration Predictor sample noise in training. Defaults to 1.0.

        inference_noise_scale_dp (float):
            Noise scale for the Stochastic Duration Predictor in inference. Defaults to 0.8.

        max_inference_len (int):
            Maximum inference length to limit the memory use. Defaults to None.

        init_discriminator (bool):
            Initialize the disciminator network if set True. Set False for inference. Defaults to True.

        use_spectral_norm_disriminator (bool):
            Use spectral normalization over weight norm in the discriminator. Defaults to False.

        use_speaker_embedding (bool):
            Enable/Disable speaker embedding for multi-speaker models. Defaults to False.

        num_speakers (int):
            Number of speakers for the speaker embedding layer. Defaults to 0.

        speakers_file (str):
            Path to the speaker mapping file for the Speaker Manager. Defaults to None.

        speaker_embedding_channels (int):
            Number of speaker embedding channels. Defaults to 256.

        use_d_vector_file (bool):
            Enable/Disable the use of d-vectors for multi-speaker training. Defaults to False.

        d_vector_dim (int):
            Number of d-vector channels. Defaults to 0.

        detach_dp_input (bool):
            Detach duration predictor's input from the network for stopping the gradients. Defaults to True.
    """

    num_chars: int = 100
    out_channels: int = 513
    spec_segment_size: int = 32
    hidden_channels: int = 192
    hidden_channels_ffn_text_encoder: int = 768
    num_heads_text_encoder: int = 2
    num_layers_text_encoder: int = 6
    kernel_size_text_encoder: int = 3
    dropout_p_text_encoder: int = 0.1
    dropout_p_duration_predictor: int = 0.5
    kernel_size_posterior_encoder: int = 5
    dilation_rate_posterior_encoder: int = 1
    num_layers_posterior_encoder: int = 16
    kernel_size_flow: int = 5
    dilation_rate_flow: int = 1
    num_layers_flow: int = 4
    resblock_type_decoder: int = "1"
    resblock_kernel_sizes_decoder: List[int] = field(default_factory=lambda: [3, 7, 11])
    resblock_dilation_sizes_decoder: List[List[int]] = field(default_factory=lambda: [[1, 3, 5], [1, 3, 5], [1, 3, 5]])
    upsample_rates_decoder: List[int] = field(default_factory=lambda: [8, 8, 2, 2])
    upsample_initial_channel_decoder: int = 512
    upsample_kernel_sizes_decoder: List[int] = field(default_factory=lambda: [16, 16, 4, 4])
    use_sdp: int = True
    noise_scale: float = 1.0
    inference_noise_scale: float = 0.667
    length_scale: int = 1
    noise_scale_dp: float = 1.0
    inference_noise_scale_dp: float = 1.
    max_inference_len: int = None
    init_discriminator: bool = True
    use_spectral_norm_disriminator: bool = False
    use_speaker_embedding: bool = False
    num_speakers: int = 0
    speakers_file: str = None
    speaker_embedding_channels: int = 256
    use_d_vector_file: bool = False
    d_vector_dim: int = 0
    detach_dp_input: bool = True


class Vits(BaseTTS):
    """VITS TTS model

    Paper::
        https://arxiv.org/pdf/2106.06103.pdf

    Paper Abstract::
        Several recent end-to-end text-to-speech (TTS) models enabling single-stage training and parallel
        sampling have been proposed, but their sample quality does not match that of two-stage TTS systems.
        In this work, we present a parallel endto-end TTS method that generates more natural sounding audio than
        current two-stage models. Our method adopts variational inference augmented with normalizing flows and
        an adversarial training process, which improves the expressive power of generative modeling. We also propose a
        stochastic duration predictor to synthesize speech with diverse rhythms from input text. With the
        uncertainty modeling over latent variables and the stochastic duration predictor, our method expresses the
        natural one-to-many relationship in which a text input can be spoken in multiple ways
        with different pitches and rhythms. A subjective human evaluation (mean opinion score, or MOS)
        on the LJ Speech, a single speaker dataset, shows that our method outperforms the best publicly
        available TTS systems and achieves a MOS comparable to ground truth.

    Check :class:`TTS.tts.configs.vits_config.VitsConfig` for class arguments.

    Examples:
        >>> from TTS.tts.configs import VitsConfig
        >>> from TTS.tts.models.vits import Vits
        >>> config = VitsConfig()
        >>> model = Vits(config)
    """

    # pylint: disable=dangerous-default-value

    def __init__(self, config: Coqpit):

        super().__init__()

        self.END2END = True

        if config.__class__.__name__ == "VitsConfig":
            # loading from VitsConfig
            if "num_chars" not in config:
                _, self.config, num_chars = self.get_characters(config)
                config.model_args.num_chars = num_chars
            else:
                self.config = config
                config.model_args.num_chars = config.num_chars
            args = self.config.model_args
        elif isinstance(config, VitsArgs):
            # loading from VitsArgs
            self.config = config
            args = config
        else:
            raise ValueError("config must be either a VitsConfig or VitsArgs")

        self.args = args

        self.init_multispeaker(config)

        self.length_scale = args.length_scale
        self.noise_scale = args.noise_scale
        self.inference_noise_scale = args.inference_noise_scale
        self.inference_noise_scale_dp = args.inference_noise_scale_dp
        self.noise_scale_dp = args.noise_scale_dp
        self.max_inference_len = args.max_inference_len
        self.spec_segment_size = args.spec_segment_size

        self.text_encoder = TextEncoder(
            args.num_chars,
            args.hidden_channels,
            args.hidden_channels,
            args.hidden_channels_ffn_text_encoder,
            args.num_heads_text_encoder,
            args.num_layers_text_encoder,
            args.kernel_size_text_encoder,
            args.dropout_p_text_encoder,
        )

        self.posterior_encoder = PosteriorEncoder(
            args.out_channels,
            args.hidden_channels,
            args.hidden_channels,
            kernel_size=args.kernel_size_posterior_encoder,
            dilation_rate=args.dilation_rate_posterior_encoder,
            num_layers=args.num_layers_posterior_encoder,
            cond_channels=self.embedded_speaker_dim,
        )

        self.flow = ResidualCouplingBlocks(
            args.hidden_channels,
            args.hidden_channels,
            kernel_size=args.kernel_size_flow,
            dilation_rate=args.dilation_rate_flow,
            num_layers=args.num_layers_flow,
            cond_channels=self.embedded_speaker_dim,
        )

        if args.use_sdp:
            self.duration_predictor = StochasticDurationPredictor(
                args.hidden_channels,
                192,
                3,
                args.dropout_p_duration_predictor,
                4,
                cond_channels=self.embedded_speaker_dim,
            )
        else:
            self.duration_predictor = DurationPredictor(
                args.hidden_channels, 256, 3, args.dropout_p_duration_predictor, cond_channels=self.embedded_speaker_dim
            )

        self.waveform_decoder = HifiganGenerator(
            args.hidden_channels,
            1,
            args.resblock_type_decoder,
            args.resblock_dilation_sizes_decoder,
            args.resblock_kernel_sizes_decoder,
            args.upsample_kernel_sizes_decoder,
            args.upsample_initial_channel_decoder,
            args.upsample_rates_decoder,
            inference_padding=0,
            cond_channels=self.embedded_speaker_dim,
            conv_pre_weight_norm=False,
            conv_post_weight_norm=False,
            conv_post_bias=False,
        )

        if args.init_discriminator:
            self.disc = VitsDiscriminator(use_spectral_norm=args.use_spectral_norm_disriminator)

    def init_multispeaker(self, config: Coqpit, data: List = None):
        """Initialize multi-speaker modules of a model. A model can be trained either with a speaker embedding layer
        or with external `d_vectors` computed from a speaker encoder model.

        If you need a different behaviour, override this function for your model.

        Args:
            config (Coqpit): Model configuration.
            data (List, optional): Dataset items to infer number of speakers. Defaults to None.
        """
        if hasattr(config, "model_args"):
            config = config.model_args
        self.embedded_speaker_dim = 0
        # init speaker manager
        self.speaker_manager = get_speaker_manager(config, data=data)
        if config.num_speakers > 0 and self.speaker_manager.num_speakers == 0:
            self.speaker_manager.num_speakers = config.num_speakers
        self.num_speakers = self.speaker_manager.num_speakers
        # init speaker embedding layer
        if config.use_speaker_embedding and not config.use_d_vector_file:
            self.embedded_speaker_dim = config.speaker_embedding_channels
            self.emb_g = nn.Embedding(config.num_speakers, config.speaker_embedding_channels)
        # init d-vector usage
        if config.use_d_vector_file:
            self.embedded_speaker_dim = config.d_vector_dim

    @staticmethod
    def _set_cond_input(aux_input: Dict):
        """Set the speaker conditioning input based on the multi-speaker mode."""
        sid, g = None, None
        if "speaker_ids" in aux_input and aux_input["speaker_ids"] is not None:
            sid = aux_input["speaker_ids"]
            if sid.ndim == 0:
                sid = sid.unsqueeze_(0)
        if "d_vectors" in aux_input and aux_input["d_vectors"] is not None:
            g = aux_input["d_vectors"]
        return sid, g

    def forward(
        self,
        x: torch.tensor,
        x_lengths: torch.tensor,
        y: torch.tensor,
        y_lengths: torch.tensor,
        aux_input={"d_vectors": None, "speaker_ids": None},
    ) -> Dict:
        """Forward pass of the model.

        Args:
            x (torch.tensor): Batch of input character sequence IDs.
            x_lengths (torch.tensor): Batch of input character sequence lengths.
            y (torch.tensor): Batch of input spectrograms.
            y_lengths (torch.tensor): Batch of input spectrogram lengths.
            aux_input (dict, optional): Auxiliary inputs for multi-speaker training. Defaults to {"d_vectors": None, "speaker_ids": None}.

        Returns:
            Dict: model outputs keyed by the output name.

        Shapes:
            - x: :math:`[B, T_seq]`
            - x_lengths: :math:`[B]`
            - y: :math:`[B, C, T_spec]`
            - y_lengths: :math:`[B]`
            - d_vectors: :math:`[B, C, 1]`
            - speaker_ids: :math:`[B]`
        """
        outputs = {}
        sid, g = self._set_cond_input(aux_input)
        x, m_p, logs_p, x_mask = self.text_encoder(x, x_lengths)

        # speaker embedding
        if self.num_speakers > 1 and sid is not None:
            g = self.emb_g(sid).unsqueeze(-1)  # [b, h, 1]

        # posterior encoder
        z, m_q, logs_q, y_mask = self.posterior_encoder(y, y_lengths, g=g)

        # flow layers
        z_p = self.flow(z, y_mask, g=g)

        # find the alignment path
        attn_mask = torch.unsqueeze(x_mask, -1) * torch.unsqueeze(y_mask, 2)
        with torch.no_grad():
            o_scale = torch.exp(-2 * logs_p)
            logp1 = torch.sum(-0.5 * math.log(2 * math.pi) - logs_p, [1]).unsqueeze(-1)  # [b, t, 1]
            logp2 = torch.einsum("klm, kln -> kmn", [o_scale, -0.5 * (z_p ** 2)])
            logp3 = torch.einsum("klm, kln -> kmn", [m_p * o_scale, z_p])
            logp4 = torch.sum(-0.5 * (m_p ** 2) * o_scale, [1]).unsqueeze(-1)  # [b, t, 1]
            logp = logp2 + logp3 + logp1 + logp4
            attn = maximum_path(logp, attn_mask.squeeze(1)).unsqueeze(1).detach()

        # duration predictor
        attn_durations = attn.sum(3)
        if self.args.use_sdp:
            nll_duration = self.duration_predictor(
                x.detach() if self.args.detach_dp_input else x,
                x_mask,
                attn_durations,
                g=g.detach() if self.args.detach_dp_input and g is not None else g,
            )
            nll_duration = torch.sum(nll_duration.float() / torch.sum(x_mask))
            outputs["nll_duration"] = nll_duration
        else:
            attn_log_durations = torch.log(attn_durations + 1e-6) * x_mask
            log_durations = self.duration_predictor(
                x.detach() if self.args.detach_dp_input else x,
                x_mask,
                g=g.detach() if self.args.detach_dp_input and g is not None else g,
            )
            loss_duration = torch.sum((log_durations - attn_log_durations) ** 2, [1, 2]) / torch.sum(x_mask)
            outputs["loss_duration"] = loss_duration

        # expand prior
        m_p = torch.einsum("klmn, kjm -> kjn", [attn, m_p])
        logs_p = torch.einsum("klmn, kjm -> kjn", [attn, logs_p])

        # select a random feature segment for the waveform decoder
        z_slice, slice_ids = rand_segment(z, y_lengths, self.spec_segment_size)
        o = self.waveform_decoder(z_slice, g=g)
        outputs.update(
            {
                "model_outputs": o,
                "alignments": attn.squeeze(1),
                "slice_ids": slice_ids,
                "z": z,
                "z_p": z_p,
                "m_p": m_p,
                "logs_p": logs_p,
                "m_q": m_q,
                "logs_q": logs_q,
            }
        )
        return outputs

    def inference(self, x, aux_input={"d_vectors": None, "speaker_ids": None}):
        """
        Shapes:
            - x: :math:`[B, T_seq]`
            - d_vectors: :math:`[B, C, 1]`
            - speaker_ids: :math:`[B]`
        """
        sid, g = self._set_cond_input(aux_input)
        x_lengths = torch.tensor(x.shape[1:2]).to(x.device)

        x, m_p, logs_p, x_mask = self.text_encoder(x, x_lengths)

        if self.num_speakers > 0 and sid:
            g = self.emb_g(sid).unsqueeze(-1)

        if self.args.use_sdp:
            logw = self.duration_predictor(x, x_mask, g=g, reverse=True, noise_scale=self.inference_noise_scale_dp)
        else:
            logw = self.duration_predictor(x, x_mask, g=g)

        w = torch.exp(logw) * x_mask * self.length_scale
        w_ceil = torch.ceil(w)
        y_lengths = torch.clamp_min(torch.sum(w_ceil, [1, 2]), 1).long()
        y_mask = sequence_mask(y_lengths, None).to(x_mask.dtype)
        attn_mask = torch.unsqueeze(x_mask, 2) * torch.unsqueeze(y_mask, -1)
        attn = generate_path(w_ceil.squeeze(1), attn_mask.squeeze(1).transpose(1, 2))

        m_p = torch.matmul(attn.transpose(1, 2), m_p.transpose(1, 2)).transpose(1, 2)
        logs_p = torch.matmul(attn.transpose(1, 2), logs_p.transpose(1, 2)).transpose(1, 2)

        z_p = m_p + torch.randn_like(m_p) * torch.exp(logs_p) * self.inference_noise_scale
        z = self.flow(z_p, y_mask, g=g, reverse=True)
        o = self.waveform_decoder((z * y_mask)[:, :, : self.max_inference_len], g=g)

        outputs = {"model_outputs": o, "alignments": attn.squeeze(1), "z": z, "z_p": z_p, "m_p": m_p, "logs_p": logs_p}
        return outputs

    def voice_conversion(self, y, y_lengths, sid_src, sid_tgt):
        """TODO: create an end-point for voice conversion"""
        assert self.num_speakers > 0, "num_speakers have to be larger than 0."
        g_src = self.emb_g(sid_src).unsqueeze(-1)
        g_tgt = self.emb_g(sid_tgt).unsqueeze(-1)
        z, _, _, y_mask = self.enc_q(y, y_lengths, g=g_src)
        z_p = self.flow(z, y_mask, g=g_src)
        z_hat = self.flow(z_p, y_mask, g=g_tgt, reverse=True)
        o_hat = self.waveform_decoder(z_hat * y_mask, g=g_tgt)
        return o_hat, y_mask, (z, z_p, z_hat)

    def train_step(self, batch: dict, criterion: nn.Module, optimizer_idx: int) -> Tuple[Dict, Dict]:
        """Perform a single training step. Run the model forward pass and compute losses.

        Args:
            batch (Dict): Input tensors.
            criterion (nn.Module): Loss layer designed for the model.
            optimizer_idx (int): Index of optimizer to use. 0 for the generator and 1 for the discriminator networks.

        Returns:
            Tuple[Dict, Dict]: Model ouputs and computed losses.
        """
        # pylint: disable=attribute-defined-outside-init
        if optimizer_idx not in [0, 1]:
            raise ValueError(" [!] Unexpected `optimizer_idx`.")

        if optimizer_idx == 0:
            text_input = batch["text_input"]
            text_lengths = batch["text_lengths"]
            mel_lengths = batch["mel_lengths"]
            linear_input = batch["linear_input"]
            d_vectors = batch["d_vectors"]
            speaker_ids = batch["speaker_ids"]
            waveform = batch["waveform"]

            # generator pass
            outputs = self.forward(
                text_input,
                text_lengths,
                linear_input.transpose(1, 2),
                mel_lengths,
                aux_input={"d_vectors": d_vectors, "speaker_ids": speaker_ids},
            )

            # cache tensors for the discriminator
            self.y_disc_cache = None
            self.wav_seg_disc_cache = None
            self.y_disc_cache = outputs["model_outputs"]
            wav_seg = segment(
                waveform.transpose(1, 2),
                outputs["slice_ids"] * self.config.audio.hop_length,
                self.args.spec_segment_size * self.config.audio.hop_length,
            )
            self.wav_seg_disc_cache = wav_seg
            outputs["waveform_seg"] = wav_seg

            # compute discriminator scores and features
            outputs["scores_disc_fake"], outputs["feats_disc_fake"], _, outputs["feats_disc_real"] = self.disc(
                outputs["model_outputs"], wav_seg
            )

            # compute losses
            with autocast(enabled=False):  # use float32 for the criterion
                loss_dict = criterion[optimizer_idx](
                    waveform_hat=outputs["model_outputs"].float(),
                    waveform=wav_seg.float(),
                    z_p=outputs["z_p"].float(),
                    logs_q=outputs["logs_q"].float(),
                    m_p=outputs["m_p"].float(),
                    logs_p=outputs["logs_p"].float(),
                    z_len=mel_lengths,
                    scores_disc_fake=outputs["scores_disc_fake"],
                    feats_disc_fake=outputs["feats_disc_fake"],
                    feats_disc_real=outputs["feats_disc_real"],
                )

            # handle the duration loss
            if self.args.use_sdp:
                loss_dict["nll_duration"] = outputs["nll_duration"]
                loss_dict["loss"] += outputs["nll_duration"]
            else:
                loss_dict["loss_duration"] = outputs["loss_duration"]
                loss_dict["loss"] += outputs["loss_duration"]

        elif optimizer_idx == 1:
            # discriminator pass
            outputs = {}

            # compute scores and features
            outputs["scores_disc_fake"], _, outputs["scores_disc_real"], _ = self.disc(self.y_disc_cache.detach(), self.wav_seg_disc_cache)

            # compute loss
            with autocast(enabled=False):  # use float32 for the criterion
                loss_dict = criterion[optimizer_idx](
                    outputs["scores_disc_real"],
                    outputs["scores_disc_fake"],
                )
        return outputs, loss_dict

    def train_log(
        self, ap: AudioProcessor, batch: Dict, outputs: List, name_prefix="train"
    ):  # pylint: disable=no-self-use
        """Create visualizations and waveform examples.

        For example, here you can plot spectrograms and generate sample sample waveforms from these spectrograms to
        be projected onto Tensorboard.

        Args:
            ap (AudioProcessor): audio processor used at training.
            batch (Dict): Model inputs used at the previous training step.
            outputs (Dict): Model outputs generated at the previoud training step.

        Returns:
            Tuple[Dict, np.ndarray]: training plots and output waveform.
        """
        y_hat = outputs[0]["model_outputs"]
        y = outputs[0]["waveform_seg"]
        figures = plot_results(y_hat, y, ap, name_prefix)
        sample_voice = y_hat[0].squeeze(0).detach().cpu().numpy()
        audios = {f"{name_prefix}/audio": sample_voice}

        alignments = outputs[0]["alignments"]
        align_img = alignments[0].data.cpu().numpy().T

        figures.update(
            {
                "alignment": plot_alignment(align_img, output_fig=False),
            }
        )

        return figures, audios

    @torch.no_grad()
    def eval_step(self, batch: dict, criterion: nn.Module, optimizer_idx: int):
        return self.train_step(batch, criterion, optimizer_idx)

    def eval_log(self, ap: AudioProcessor, batch: dict, outputs: dict):
        return self.train_log(ap, batch, outputs, "eval")

    @torch.no_grad()
    def test_run(self, ap) -> Tuple[Dict, Dict]:
        """Generic test run for `tts` models used by `Trainer`.

        You can override this for a different behaviour.

        Returns:
            Tuple[Dict, Dict]: Test figures and audios to be projected to Tensorboard.
        """
        print(" | > Synthesizing test sentences.")
        test_audios = {}
        test_figures = {}
        test_sentences = self.config.test_sentences
        aux_inputs = self.get_aux_input()
        for idx, sen in enumerate(test_sentences):
            wav, alignment, _, _ = synthesis(
                self,
                sen,
                self.config,
                "cuda" in str(next(self.parameters()).device),
                ap,
                speaker_id=aux_inputs["speaker_id"],
                d_vector=aux_inputs["d_vector"],
                style_wav=aux_inputs["style_wav"],
                enable_eos_bos_chars=self.config.enable_eos_bos_chars,
                use_griffin_lim=True,
                do_trim_silence=False,
            ).values()

            test_audios["{}-audio".format(idx)] = wav
            test_figures["{}-alignment".format(idx)] = plot_alignment(alignment.T, output_fig=False)
        return test_figures, test_audios

    def get_optimizer(self) -> List:
        """Initiate and return the GAN optimizers based on the config parameters.

        It returnes 2 optimizers in a list. First one is for the generator and the second one is for the discriminator.

        Returns:
            List: optimizers.
        """
        gen_parameters =  [param for name, param in self.named_parameters() if not str.startswith(name, "disc.")]
        optimizer0 = get_optimizer(
            self.config.optimizer, self.config.optimizer_params, self.config.lr_gen, parameters=gen_parameters
        )
        optimizer1 = get_optimizer(self.config.optimizer, self.config.optimizer_params, self.config.lr_disc, self.disc)
        return [optimizer0, optimizer1]

    def get_lr(self) -> List:
        """Set the initial learning rates for each optimizer.

        Returns:
            List: learning rates for each optimizer.
        """
        return [self.config.lr_gen, self.config.lr_disc]

    def get_scheduler(self, optimizer) -> List:
        """Set the schedulers for each optimizer.

        Args:
            optimizer (List[`torch.optim.Optimizer`]): List of optimizers.

        Returns:
            List: Schedulers, one for each optimizer.
        """
        scheduler1 = get_scheduler(self.config.lr_scheduler_gen, self.config.lr_scheduler_gen_params, optimizer[0])
        scheduler2 = get_scheduler(self.config.lr_scheduler_disc, self.config.lr_scheduler_disc_params, optimizer[1])
        return [scheduler1, scheduler2]

    def get_criterion(self):
        """Get criterions for each optimizer. The index in the output list matches the optimizer idx used in
        `train_step()`"""
        from TTS.tts.layers.losses import (  # pylint: disable=import-outside-toplevel
            VitsDiscriminatorLoss,
            VitsGeneratorLoss,
        )

        return [VitsGeneratorLoss(self.config), VitsDiscriminatorLoss(self.config)]

    @staticmethod
    def make_symbols(config):
        """Create a custom arrangement of symbols used by the model. The output list of symbols propagate along the
        whole training and inference steps."""
        _pad = config.characters["pad"]
        _punctuations = config.characters["punctuations"]
        _letters = config.characters["characters"]
        _letters_ipa = config.characters["phonemes"]
        symbols = [_pad] + list(_punctuations) + list(_letters)
        if config.use_phonemes:
            symbols += list(_letters_ipa)
        return symbols

    @staticmethod
    def get_characters(config: Coqpit):
        if config.characters is not None:
            symbols = Vits.make_symbols(config)
        else:
            from TTS.tts.utils.text.symbols import (  # pylint: disable=import-outside-toplevel
                parse_symbols,
                phonemes,
                symbols,
            )

            config.characters = parse_symbols()
            if config.use_phonemes:
                symbols = phonemes
        num_chars = len(symbols) + getattr(config, "add_blank", False)
        return symbols, config, num_chars

    def load_checkpoint(
        self, config, checkpoint_path, eval=False
    ):  # pylint: disable=unused-argument, redefined-builtin
        """Load the model checkpoint and setup for training or inference"""
        state = torch.load(checkpoint_path, map_location=torch.device("cpu"))
        self.load_state_dict(state["model"])
        if eval:
            self.eval()
            assert not self.training