Phonetic posteriorgrams
Project description
High-Fidelity Neural Phonetic Posteriorgrams
Training, evaluation, and inference of neural phonetic posteriorgrams (PPGs) in PyTorch
Table of contents
Installation
An inference-only installation with our best model is pip-installable
pip install ppgs
To perform training, install training dependencies and FFMPEG.
pip install ppgs[train]
conda install -c conda-forge ffmpeg
If you wish to use the Charsiu representation, download the code, install both inference and training dependencies, and install Charsiu as a Git submodule.
# Clone
git clone git@github.com/interactiveaudiolab/ppgs
cd ppgs/
# Install dependencies
pip install -e .[train]
conda install -c conda-forge ffmpeg
# Download Charsiu
git submodule init
git submodule update
Inference
import ppgs
# Load speech audio at correct sample rate
audio = ppgs.load.audio(audio_file)
# Choose a gpu index to use for inference. Set to None to use cpu.
gpu = 0
# Infer PPGs
ppgs = ppgs.from_audio(audio, ppgs.SAMPLE_RATE, gpu=gpu)
Application programming interface (API)
ppgs.from_audio
def from_audio(
audio: torch.Tensor,
sample_rate: Union[int, float],
representation: str = ppgs.REPRESENTATION,
checkpoint: Optional[Union[str, bytes, os.PathLike]] = None,
gpu: int = None
) -> torch.Tensor:
"""Infer ppgs from audio
Arguments
audio
Batched audio to process
shape=(batch, 1, samples)
sample_rate
Audio sampling rate
representation
The representation to use, 'mel' and 'w2v2fb' are currently supported
checkpoint
The checkpoint file
gpu
The index of the GPU to use for inference
Returns
ppgs
Phonetic posteriorgrams
shape=(batch, len(ppgs.PHONEMES), frames)
"""
ppgs.from_file
def from_file(
file: Union[str, bytes, os.PathLike],
representation: str = ppgs.REPRESENTATION,
checkpoint: Optional[Union[str, bytes, os.PathLike]] = None,
gpu: Optional[int] = None
) -> torch.Tensor:
"""Infer ppgs from an audio file
Arguments
file
The audio file
representation
The representation to use, 'mel' and 'w2v2fb' are currently supported
checkpoint
The checkpoint file
gpu
The index of the GPU to use for inference
Returns
ppgs
Phonetic posteriorgram
shape=(len(ppgs.PHONEMES), frames)
"""
ppgs.from_file_to_file
def from_file_to_file(
audio_file: Union[str, bytes, os.PathLike],
output_file: Union[str, bytes, os.PathLike],
representation: str = ppgs.REPRESENTATION,
checkpoint: Optional[Union[str, bytes, os.PathLike]] = None,
gpu: Optional[int] = None
) -> None:
"""Infer ppg from an audio file and save to a torch tensor file
Arguments
audio_file
The audio file
output_file
The .pt file to save PPGs
representation
The representation to use, 'mel' and 'w2v2fb' are currently supported
checkpoint
The checkpoint file
gpu
The index of the GPU to use for inference
"""
ppgs.from_files_to_files
def from_files_to_files(
audio_files: List[Union[str, bytes, os.PathLike]],
output_files: List[Union[str, bytes, os.PathLike]],
representation: str = ppgs.REPRESENTATION,
checkpoint: Optional[Union[str, bytes, os.PathLike]] = None,
num_workers: int = 0,
gpu: Optional[int] = None,
max_frames: int = ppgs.MAX_INFERENCE_FRAMES
) -> None:
"""Infer ppgs from audio files and save to torch tensor files
Arguments
audio_files
The audio files
output_files
The .pt files to save PPGs
representation
The representation to use, 'mel' and 'w2v2fb' are currently supported
checkpoint
The checkpoint file
num_workers
Number of CPU threads for multiprocessing
gpu
The index of the GPU to use for inference
max_frames
The maximum number of frames on the GPU at once
"""
Command-line interface (CLI)
usage: python -m ppgs
[-h]
[--audio_files AUDIO_FILES [AUDIO_FILES ...]]
[--output_files OUTPUT_FILES [OUTPUT_FILES ...]]
[--representation REPRESENTATION]
[--checkpoint CHECKPOINT]
[--num-workers NUM_WORKERS]
[--gpu GPU]
[--max-frames MAX_TRAINING_FRAMES]
arguments:
--audio_files AUDIO_FILES [AUDIO_FILES ...]
Paths to input audio files
--output_files OUTPUT_FILES [OUTPUT_FILES ...]
The one-to-one corresponding output files
optional arguments:
-h, --help
Show this help message and exit
--representation REPRESENTATION
Representation to use for inference
--checkpoint CHECKPOINT
The checkpoint file
--num-workers NUM_WORKERS
Number of CPU threads for multiprocessing
--gpu GPU
The index of the GPU to use for inference. Defaults to CPU.
--max-frames MAX_FRAMES
Maximum number of frames in a batch
Distance
To compute the proposed normalized Jenson-Shannon divergence pronunciation
distance between two PPGs, use ppgs.distance().
def distance(
ppgX: torch.Tensor,
ppgY: torch.Tensor,
reduction: str = 'mean',
normalize: bool = True,
exponent: float = ppgs.SIMILARITY_EXPONENT
) -> torch.Tensor:
"""Compute the pronunciation distance between two aligned PPGs
Arguments
ppgX
Input PPG X
shape=(len(ppgs.PHONEMES), frames)
ppgY
Input PPG Y to compare with PPG X
shape=(len(ppgs.PHONEMES), frames)
reduction
Reduction to apply to the output. One of ['mean', 'none', 'sum'].
normalize
Apply similarity based normalization
exponent
Similarty exponent
Returns
Normalized Jenson-shannon divergence between PPGs
"""
Interpolate
def interpolate(
ppgX: torch.Tensor,
ppgY: torch.Tensor,
interp: Union[float, torch.Tensor]
) -> torch.Tensor:
"""Linear interpolation
Arguments
ppgX
Input PPG X
shape=(len(ppgs.PHONEMES), frames)
ppgY
Input PPG Y
shape=(len(ppgs.PHONEMES), frames)
interp
Interpolation values
scalar float OR shape=(frames,)
Returns
Interpolated PPGs
shape=(len(ppgs.PHONEMES), frames)
"""
Edit
import ppgs
# Get PPGs to edit
ppg = ppgs.from_file(audio_file, gpu=gpu)
# Constant-ratio time-stretching (slowing down)
grid = ppgs.edit.grid.constant(ppg, ratio=0.8)
slow = ppgs.edit.grid.sample(ppg, grid)
# Stretch to a desired length (e.g., 100 frames)
grid = ppgs.edit.grid.of_length(ppg, 100)
fixed = ppgs.edit.grid.sample(ppg, grid)
ppgs.edit.grid.constant
def constant(ppg: torch.Tensor, ratio: float) -> torch.Tensor:
"""Create a grid for constant-ratio time-stretching
Arguments
ppg
Input PPG
ratio
Time-stretching ratio; lower is slower
Returns
Constant-ratio grid for time-stretching ppg
"""
ppgs.edit.grid.from_alignments
def from_alignments(
source: pypar.Alignment,
target: pypar.Alignment,
sample_rate: int = ppgs.SAMPLE_RATE,
hopsize: int = ppgs.HOPSIZE
) -> torch.Tensor:
"""Create time-stretch grid to convert source alignment to target
Arguments
source
Forced alignment of PPG to stretch
target
Forced alignment of target PPG
sample_rate
Audio sampling rate
hopsize
Hopsize in samples
Returns
Grid for time-stretching source PPG
"""
ppgs.edit.grid.of_length
def of_length(ppg: torch.Tensor, length: int) -> torch.Tensor:
"""Create time-stretch grid to resample PPG to a specified length
Arguments
ppg
Input PPG
length
Target length
Returns
Grid of specified length for time-stretching ppg
"""
ppgs.edit.grid.sample
def grid_sample(ppg: torch.Tensor, grid: torch.Tensor) -> torch.Tensor:
"""Grid-based PPG interpolation
Arguments
ppg
Input PPG
grid
Grid of desired length; each item is a float-valued index into ppg
Returns
Interpolated PPG
"""
ppgs.edit.reallocate
def reallocate(
ppg: torch.Tensor,
source: str,
target: str,
value: Optional[float] = None
) -> torch.Tensor:
"""Reallocate probability from source phoneme to target phoneme
Arguments
ppg
Input PPG
shape=(len(ppgs.PHONEMES), frames)
source
Source phoneme
target
Target phoneme
value
Max amount to reallocate. If None, reallocates all probability.
Returns
Edited PPG
"""
ppgs.edit.regex
def regex(
ppg: torch.Tensor,
source_phonemes: List[str],
target_phonemes: List[str]
) -> torch.Tensor:
"""Regex match and replace (via swap) for phoneme sequences
Arguments
ppg
Input PPG
shape=(len(ppgs.PHONEMES), frames)
source_phonemes
Source phoneme sequence
target_phonemes
Target phoneme sequence
Returns
Edited PPG
"""
ppgs.edit.shift
def shift(ppg: torch.Tensor, phoneme: str, value: float):
"""Shift probability of a phoneme and reallocate proportionally
Arguments
ppg
Input PPG
shape=(len(ppgs.PHONEMES), frames)
phoneme
Input phoneme
value
Maximal shift amount
Returns
Edited PPG
"""
ppgs.edit.swap
def swap(ppg: torch.Tensor, phonemeA: str, phonemeB: str) -> torch.Tensor:
"""Swap the probabilities of two phonemes
Arguments
ppg
Input PPG
shape=(len(ppg.PHONEMES), frames)
phonemeA
Input phoneme A
phonemeB
Input phoneme B
Returns
Edited PPG
"""
Sparsify
def sparsify(
ppg: torch.Tensor,
method: str = 'percentile',
threshold: torch.Tensor = torch.Tensor([0.85])
) -> torch.Tensor:
"""Make phonetic posteriorgrams sparse
Arguments
ppg
Input PPG
shape=(batch, len(ppgs.PHONEMES), frames)
method
Sparsification method. One of ['constant', 'percentile', 'topk'].
threshold
In [0, 1] for 'contant' and 'percentile'; integer > 0 for 'topk'.
Returns
Sparse phonetic posteriorgram
shape=(batch, len(ppgs.PHONEMES), frames)
"""
Training
Download
Downloads, unzips, and formats datasets. Stores datasets in data/datasets/.
Stores formatted datasets in data/cache/.
N.B. Common voice and TIMIT cannot be automatically downloaded. You must
manually download the tarballs and place them in data/sources/commonvoice
or data/sources/timit, respectively, prior to running the following.
python -m ppgs.data.download --datasets <datasets>
Preprocess
Prepares representations for training. Representations are stored
in data/cache/.
python -m ppgs.preprocess \
--datasets <datasets> \
--representatations <representations> \
--gpu <gpu> \
--num-workers <workers>
Partition
Partitions a dataset. You should not need to run this, as the partitions
used in our work are provided for each dataset in
ppgs/assets/partitions/.
python -m ppgs.partition --datasets <datasets>
Train
Trains a model. Checkpoints and logs are stored in runs/.
python -m ppgs.train --config <config> --dataset <dataset> --gpu <gpu>
If the config file has been previously run, the most recent checkpoint will automatically be loaded and training will resume from that checkpoint.
Monitor
You can monitor training via tensorboard.
tensorboard --logdir runs/ --port <port> --load_fast true
To use the torchutil notification system to receive notifications for long
jobs (download, preprocess, train, and evaluate), set the
PYTORCH_NOTIFICATION_URL environment variable to a supported webhook as
explained in the Apprise documentation.
Evaluate
Performs objective evaluation of phoneme accuracy. Results are stored
in eval/.
python -m ppgs.evaluate \
--config <name> \
--datasets <datasets> \
--checkpoint <checkpoint> \
--gpu <gpu>
Citation
IEEE
C. Churchwell, M. Morrison, and B. Pardo, "High-Fidelity Neural Phonetic Posteriorgrams," ICASSP 2024 Workshop on Explainable Machine Learning for Speech and Audio, April 2024.
BibTex
@inproceedings{churchwell2024high,
title={High-Fidelity Neural Phonetic Posteriorgrams},
author={Churchwell, Cameron and Morrison, Max and Pardo, Bryan},
booktitle={ICASSP 2024 Workshop on Explainable Machine Learning for Speech and Audio},
month={April},
year={2024}
}
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
ppgs-0.0.8.tar.gz
(2.6 MB
view details)
Built Distribution
ppgs-0.0.8-py3-none-any.whl
(2.9 MB
view details)
File details
Details for the file ppgs-0.0.8.tar.gz.
File metadata
- Download URL: ppgs-0.0.8.tar.gz
- Upload date:
- Size: 2.6 MB
- Tags: Source
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/5.1.1 CPython/3.11.9
File hashes
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 | 75d539c90994ae110cf79325b926affad4adc21c1b971ee2e5a2322f58fc8a46 |
|
| MD5 | a05606093cb5c6b8a65a22fd3525ca45 |
|
| BLAKE2b-256 | b293fbf9e4dadd755f1c58c6e6db28c50066d99915f9ea0936bc3ffdaea10634 |
File details
Details for the file ppgs-0.0.8-py3-none-any.whl.
File metadata
- Download URL: ppgs-0.0.8-py3-none-any.whl
- Upload date:
- Size: 2.9 MB
- Tags: Python 3
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/5.1.1 CPython/3.11.9
File hashes
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 | 70957719c99207888c0bd7160dcce9935f0d48984d4407a46917405adc611863 |
|
| MD5 | be347d590bea7f197b9faf3f53172566 |
|
| BLAKE2b-256 | 54270c12563fa3bda51021e4db9b5ef49ecbe8234d673e7cd6b9d9c2810b1bed |
