Project: torchlibrosa

PyTorch implemention of part of librosa functions.

Project Details

Latest version
0.1.0
Home Page
https://github.com/qiuqiangkong/torchlibrosa
PyPI Page
https://pypi.org/project/torchlibrosa/

Project Popularity

PageRank
0.00304595516776354
Number of downloads
160051

TorchLibrosa: PyTorch implementation of Librosa

This codebase provides PyTorch implementation of some librosa functions. If users previously used for training cpu-extracted features from librosa, but want to add GPU acceleration during training and evaluation, TorchLibrosa will provide almost identical features to standard torchlibrosa functions (numerical difference less than 1e-5).

Install

$ pip install torchlibrosa

Examples 1

Extract Log mel spectrogram with TorchLibrosa.

import torch
import torchlibrosa as tl

batch_size = 16
sample_rate = 22050
win_length = 2048
hop_length = 512
n_mels = 128

batch_audio = torch.empty(batch_size, sample_rate).uniform_(-1, 1)  # (batch_size, sample_rate)

# TorchLibrosa feature extractor the same as librosa.feature.melspectrogram()
feature_extractor = torch.nn.Sequential(
    tl.Spectrogram(
        hop_length=hop_length,
        win_length=win_length,
    ), tl.LogmelFilterBank(
        sr=sample_rate,
        n_mels=n_mels,
        is_log=False, # Default is true
    ))
batch_feature = feature_extractor(batch_audio) # (batch_size, 1, time_steps, mel_bins)

Examples 2

Extracting spectrogram, then log mel spectrogram, STFT and ISTFT with TorchLibrosa.

import torch
import torchlibrosa as tl

batch_size = 16
sample_rate = 22050
win_length = 2048
hop_length = 512
n_mels = 128

batch_audio = torch.empty(batch_size, sample_rate).uniform_(-1, 1)  # (batch_size, sample_rate)

# Spectrogram
spectrogram_extractor = tl.Spectrogram(n_fft=win_length, hop_length=hop_length)
sp = spectrogram_extractor.forward(batch_audio)   # (batch_size, 1, time_steps, freq_bins)

# Log mel spectrogram
logmel_extractor = tl.LogmelFilterBank(sr=sample_rate, n_fft=win_length, n_mels=n_mels)
logmel = logmel_extractor.forward(sp)   # (batch_size, 1, time_steps, mel_bins)

# STFT
stft_extractor = tl.STFT(n_fft=win_length, hop_length=hop_length)
(real, imag) = stft_extractor.forward(batch_audio)
# real: (batch_size, 1, time_steps, freq_bins), imag: (batch_size, 1, time_steps, freq_bins) #

# ISTFT
istft_extractor = tl.ISTFT(n_fft=win_length, hop_length=hop_length)
y = istft_extractor.forward(real, imag, length=batch_audio.shape[-1])    # (batch_size, samples_num)

Example 3

Check the compability of TorchLibrosa to Librosa. The numerical difference should be less than 1e-5.

python3 torchlibrosa/stft.py --device='cuda'    # --device='cpu' | 'cuda'

Contact

Qiuqiang Kong, qiuqiangkong@gmail.com

Cite

[1] Qiuqiang Kong, Yin Cao, Turab Iqbal, Yuxuan Wang, Wenwu Wang, and Mark D. Plumbley. "PANNs: Large-scale pretrained audio neural networks for audio pattern recognition." IEEE/ACM Transactions on Audio, Speech, and Language Processing 28 (2020): 2880-2894.

External links

Other related repos include:

torchaudio: https://github.com/pytorch/audio

Asteroid-filterbanks: https://github.com/asteroid-team/asteroid-filterbanks

Kapre: https://github.com/keunwoochoi/kapre