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PyTorch Implementation of Google's Parallel Tacotron 2: A Non-Autoregressive Neural TTS Model with Differentiable Duration Modeling

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Parallel Tacotron2

Pytorch Implementation of Google's Parallel Tacotron 2: A Non-Autoregressive Neural TTS Model with Differentiable Duration Modeling

Updates

  • 2021.05.25: Only the soft-DTW remains the last hurdle! Following the author's advice on the implementation, I took several tests on each module one by one under a supervised duration signal with L1 loss (FastSpeech2). Until now, I can confirm that all modules except soft-DTW are working well as follows (Synthesized Spectrogram, GT Spectrogram, Residual Alignment, and W from LearnedUpsampling from top to bottom).

    For the details, please check the latest commit log and the updated Implementation Issues section. Also, you can find the ongoing experiments at https://github.com/keonlee9420/FastSpeech2/commits/ptaco2.

  • 2021.05.15: Implementation done. Sanity checks on training and inference. But still the model cannot converge.

    I'm waiting for your contribution! Please inform me if you find any mistakes in my implementation or any valuable advice to train the model successfully. See the Implementation Issues section.

Training

Requirements

  • You can install the Python dependencies with

    pip3 install -r requirements.txt
  • Install fairseq (official document, github) to utilize LConvBlock. Please check #5 to resolve any issue on installing.

Datasets

The supported datasets:

  • LJSpeech: a single-speaker English dataset consists of 13100 short audio clips of a female speaker reading passages from 7 non-fiction books, approximately 24 hours in total.
  • (will be added more)

Preprocessing

After downloading the datasets, set the corpus_path in preprocess.yaml and run the preparation script:

python3 prepare_data.py config/LJSpeech/preprocess.yaml

Then, run the preprocessing script:

python3 preprocess.py config/LJSpeech/preprocess.yaml

Training

Train your model with

python3 train.py -p config/LJSpeech/preprocess.yaml -m config/LJSpeech/model.yaml -t config/LJSpeech/train.yaml

The model cannot converge yet. I'm debugging but it would be boosted if your awesome contribution is ready!

Inference

Inference

For a single inference, run

python3 synthesize.py --text "YOUR_DESIRED_TEXT" --restore_step 900000 --mode single -p config/LJSpeech/preprocess.yaml -m config/LJSpeech/model.yaml -t config/LJSpeech/train.yaml

The generated utterances will be saved in output/result/.

Batch Inference

Batch inference is also supported, try

python3 synthesize.py --source preprocessed_data/LJSpeech/val.txt --restore_step 900000 --mode batch -p config/LJSpeech/preprocess.yaml -m config/LJSpeech/model.yaml -t config/LJSpeech/train.yaml

to synthesize all utterances in preprocessed_data/LJSpeech/val.txt.

TensorBoard

Use

tensorboard --logdir output/log/LJSpeech

to serve TensorBoard on your localhost.

Implementation Issues

Overall, normalization or activation, which is not suggested in the original paper, is adequately arranged to prevent NaN value (gradient) on forward and backward calculations. (NaN indicates that something is wrong in the network)

Text Encoder

  1. Use the FFTBlock of FastSpeech2 for the transformer block of the text encoder.
  2. Use dropout 0.2 for the ConvBlock of the text encoder.
  3. To restore "proprietary normalization engine",
    • Apply the same text normalization as in FastSpeech2.
    • Implement grapheme_to_phoneme function. (See ./text/init).

Residual Encoder

  1. Use 80 channels mel-spectrogrom instead of 128-bin.
  2. Regular sinusoidal positional embedding is used in frame-level instead of combinations of three positional embeddings in Parallel Tacotron. As the model depends entirely on unsupervised learning for the position, this choice can be a reason for the fails on model converge.

Duration Predictor & Learned Upsampling

  1. Use nn.SiLU() for the swish activation.
  2. When obtaining W and C, concatenation operation is applied among S, E, and V after frame-domain (T domain) broadcasting of V.

Decoder

  1. Use LConvBlock and regular sinusoidal positional embedding.
  2. Iterative mel-spectrogram is projected by a linear layer.
  3. Apply nn.Tanh() to each LConvBLock output (following activation pattern of decoder part in FastSpeech2).

Loss

  1. Use optimization & scheduler of FastSpeech2 (which is from Attention is all you need as described in the original paper).
  2. Base on pytorch-softdtw-cuda (post) for the soft-DTW.
    1. Implement customized soft-DTW in model/soft_dtw_cuda.py, reflecting the recursion suggested in the original paper.
    2. In the original soft-DTW, the final loss is not assumed and therefore only E is computed. But employed as a loss function, jacobian product is added to return target derivetive of R w.r.t. input X.
    3. Currently, the maximum batch size is 8 in 24GiB GPU (TITAN RTX) due to space complexity problem in soft-DTW Loss.
      • In the original paper, a custom differentiable diagonal band operation was implemented and used to solve the complexity of O(T^2), but this part has not been explored in the current implementation yet.

Citation

@misc{lee2021parallel_tacotron2,
  author = {Lee, Keon},
  title = {Parallel-Tacotron2},
  year = {2021},
  publisher = {GitHub},
  journal = {GitHub repository},
  howpublished = {\url{https://github.com/keonlee9420/Parallel-Tacotron2}}
}

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