Audio data augmentation in PyTorch. Inspired by audiomentations.
- Supports CPU and GPU (CUDA) - speed is a priority
- Supports batches of multichannel (or mono) audio
- Transforms extend
nn.Module, so they can be integrated as a part of a pytorch neural network model - Most transforms are differentiable
- Three modes:
per_batch,per_exampleandper_channel - Cross-platform compatibility
- Permissive MIT license
- Aiming for high test coverage
pip install torch-audiomentations
import torch
from torch_audiomentations import Compose, Gain, PolarityInversion
# Initialize augmentation callable
apply_augmentation = Compose(
transforms=[
Gain(
min_gain_in_db=-15.0,
max_gain_in_db=5.0,
p=0.5,
),
PolarityInversion(p=0.5)
]
)
torch_device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
# Make an example tensor with white noise.
# This tensor represents 8 audio snippets with 2 channels (stereo) and 2 s of 16 kHz audio.
audio_samples = torch.rand(size=(8, 2, 32000), dtype=torch.float32, device=torch_device) - 0.5
# Apply augmentation. This varies the gain and polarity of (some of)
# the audio snippets in the batch independently.
perturbed_audio_samples = apply_augmentation(audio_samples, sample_rate=16000)- Target data processing is still in an experimental state (#3). Workaround: Use
freeze_parametersandunfreeze_parametersfor now if the target data is audio with the same shape as the input. - Using torch-audiomentations in a multiprocessing context can lead to memory leaks (#132). Workaround: If using torch-audiomentations in a multiprocessing context, it'll probably work better to run the transforms on CPU.
- Multi-GPU / DDP is not officially supported (#136). The author does not have a multi-GPU setup to test & fix this. Get in touch if you want to donate some hardware for this. Workaround: Run the transforms on single GPU instead.
PitchShiftdoes not support small pitch shifts, especially for low sample rates (#151). Workaround: If you need small pitch shifts applied to low sample rates, use PitchShift in audiomentations or torch-pitch-shift directly without the function for calculating efficient pitch-shift targets.
Contributors welcome!
Join the Asteroid's slack
to start discussing about torch-audiomentations with us.
We don't want data augmentation to be a bottleneck in model training speed. Here is a comparison of the time it takes to run 1D convolution:
torch-audiomentations is in an early development stage, so the APIs are subject to change.
Every transform has mode, p, and p_mode -- the parameters that decide how the augmentation is performed.
modedecides how the randomization of the augmentation is grouped and applied.pdecides the on/off probability of applying the augmentation.p_modedecides how the on/off of the augmentation is applied.
This visualization shows how different combinations of mode and p_mode would perform an augmentation.
Added in v0.5.0
Add background noise to the input audio.
Added in v0.7.0
Add colored noise to the input audio.
Added in v0.5.0
Convolve the given audio with impulse responses.
Added in v0.9.0
Apply band-pass filtering to the input audio.
Added in v0.10.0
Apply band-stop filtering to the input audio. Also known as notch filter.
Added in v0.1.0
Multiply the audio by a random amplitude factor to reduce or increase the volume. This technique can help a model become somewhat invariant to the overall gain of the input audio.
Warning: This transform can return samples outside the [-1, 1] range, which may lead to clipping or wrap distortion, depending on what you do with the audio in a later stage. See also https://en.wikipedia.org/wiki/Clipping_(audio)#Digital_clipping
Added in v0.8.0
Apply high-pass filtering to the input audio.
Added in v0.11.0
This transform returns the input unchanged. It can be used for simplifying the code in cases where data augmentation should be disabled.
Added in v0.8.0
Apply low-pass filtering to the input audio.
Added in v0.2.0
Apply a constant amount of gain, so that highest signal level present in each audio snippet in the batch becomes 0 dBFS, i.e. the loudest level allowed if all samples must be between -1 and 1.
This transform has an alternative mode (apply_to="only_too_loud_sounds") where it only applies to audio snippets that have extreme values outside the [-1, 1] range. This is useful for avoiding digital clipping in audio that is too loud, while leaving other audio untouched.
Added in v0.9.0
Pitch-shift sounds up or down without changing the tempo.
Added in v0.1.0
Flip the audio samples upside-down, reversing their polarity. In other words, multiply the waveform by -1, so negative values become positive, and vice versa. The result will sound the same compared to the original when played back in isolation. However, when mixed with other audio sources, the result may be different. This waveform inversion technique is sometimes used for audio cancellation or obtaining the difference between two waveforms. However, in the context of audio data augmentation, this transform can be useful when training phase-aware machine learning models.
Added in v0.5.0
Shift the audio forwards or backwards, with or without rollover
Added in v0.6.0
Given multichannel audio input (e.g. stereo), shuffle the channels, e.g. so left can become right and vice versa. This transform can help combat positional bias in machine learning models that input multichannel waveforms.
If the input audio is mono, this transform does nothing except emit a warning.
Added in v0.10.0
Reverse (invert) the audio along the time axis similar to random flip of an image in the visual domain. This can be relevant in the context of audio classification. It was successfully applied in the paper AudioCLIP: Extending CLIP to Image, Text and Audio
- Add new transforms:
Mix,Padding,RandomCropandSpliceOut
- Add new transform:
Identity - Add API for processing targets alongside inputs. Some transforms experimentally support this feature already.
- Add
ObjectDictoutput type as alternative totorch.Tensor. This alternative is opt-in for now (for backwards-compatibility), but note that the old output type (torch.Tensor) is deprecated and support for it will be removed in a future version. - Allow specifying a file path, a folder path, a list of files or a list of folders to
AddBackgroundNoiseandApplyImpulseResponse - Require newer version of
torch-pitch-shiftto ensure support for torchaudio 0.11 inPitchShift
- Fix a bug where
BandPassFilterdidn't work on GPU
- Add support for min SNR == max SNR in
AddBackgroundNoise - Add support for librosa 0.9.0
- Fix a bug where loaded audio snippets were sometimes resampled to an incompatible
length in
AddBackgroundNoise
- Implement
OneOfandSomeOffor applying one or more of a given set of transforms - Implement new transforms:
BandStopFilterandTimeInversion
- Put
ir_pathsin transform_parameters inApplyImpulseResponseso it is possible to inspect what impulse responses were used. This also givesfreeze_parameters()the expected behavior.
- Fix a bug where the actual bandwidth was twice as large as expected in
BandPassFilter. The default values have been updated accordingly. If you were previously specifyingmin_bandwidth_fractionand/ormax_bandwidth_fraction, you now need to double those numbers to get the same behavior as before.
- Officially mark python>=3.9 as supported
- Add parameter
compensate_for_propagation_delayinApplyImpulseResponse - Implement
BandPassFilter - Implement
PitchShift
- Support for torchaudio<=0.6 has been removed
- Implement
HighPassFilterandLowPassFilter
- Support for torchaudio<=0.6 is deprecated and will be removed in the future
- Support for pytorch<=1.6 has been removed
- Implement
AddColoredNoise
- Support for pytorch<=1.6 is deprecated and will be removed in the future
- Implement
ShuffleChannels
- Fix a bug where
AddBackgroundNoisedid not work on CUDA - Fix a bug where symlinked audio files/folders were not found when looking for audio files
- Use torch.fft.rfft instead of the torch.rfft (deprecated in pytorch 1.7) when possible. As a
bonus, the change also improves performance in
ApplyImpulseResponse.
- Release
AddBackgroundNoiseandApplyImpulseResponse - Implement
Shift
- Make
sample_rateoptional. Allow specifyingsample_ratein__init__instead offorward. This means torchaudio transforms can be used inComposenow.
- Remove support for 1-dimensional and 2-dimensional audio tensors. Only 3-dimensional audio tensors are supported now.
- Fix a bug where one could not use the
parametersmethod of thenn.Modulesubclass - Fix a bug where files with uppercase filename extension were not found
- Implement
Composefor applying multiple transforms - Implement utility functions
from_dictandfrom_yamlfor loading data augmentation configurations from dict, json or yaml - Officially support differentiability in most transforms
- Add support for alternative modes
per_batchandper_channel
- Transforms now return the input unchanged when they are in eval mode
- Implement
PeakNormalization - Expose
convolvein the API
- Simplify API for using CUDA tensors. The device is now inferred from the input tensor.
- Initial release with
GainandPolarityInversion
A GPU-enabled development environment for torch-audiomentations can be created with conda:
conda env create
pytest
- Format python code with black
- Use Google-style docstrings
- Use explicit relative imports, not absolute imports
The development of torch-audiomentations is kindly backed by Nomono.
Thanks to all contributors who help improving torch-audiomentations.