Improved version of the Wave-U-Net for audio source separation, implemented in Pytorch.
Click here for the original Wave-U-Net implementation in Tensorflow. You can find more information about the model and results there as well.
- Multi-instrument separation by default, using a separate standard Wave-U-Net for each source (can be set to one model as well)
- More scalable to larger data: A depth parameter D can be set that employs D convolutions for each single convolution in the original Wave-U-Net
- More configurable: Layer type, resampling factor at each level etc. can be easily changed (different normalization, residual connections...)
- Fast training: Preprocesses the given dataset by saving the audio into HDF files, which can be read very quickly during training, thereby avoiding slowdown due to resampling and decoding
- Modular thanks to Pytorch: Easily replace components of the model with your own variants/layers/losses
- Better output handling: Separate output convolution for each source estimate with linear activation so amplitudes near 1 and -1 can be easily predicted, at test time thresholding to valid amplitude range [-1,1]
- Fixed or dynamic resampling: Either use fixed lowpass filter to avoid aliasing during resampling, or use a learnable convolution
GPU strongly recommended to avoid very long training times.
System requirements:
- Linux-based OS
- Python 3.6
- libsndfile
- ffmpeg
- CUDA 10.1 for GPU usage
Clone the repository:
git clone https://github.com/f90/Wave-U-Net-Pytorch.git
Recommended: Create a new virtual environment to install the required Python packages into, then activate the virtual environment:
virtualenv --python /usr/bin/python3.6 waveunet-env
source waveunet-env/bin/activate
Install all the required packages listed in the requirements.txt
:
pip3 install -r requirements.txt
We also provide a Singularity container which allows you to avoid installing the correct Python, CUDA and other system libraries, however we don't provide specific advice on how to run the container and so only do this if you have to or know what you are doing (since you need to mount dataset paths to the container etc.)
To pull the container, run
singularity pull shub://f90/Wave-U-Net-Pytorch
Then run the container from the directory where you cloned this repository to, using the commands listed further below in this readme.
To directly use the pre-trained models we provide for download to separate your own songs, now skip directly to the last section, since the datasets are not needed in that case.
To start training your own models, download the full MUSDB18HQ dataset and extract it into a folder of your choice. It should have two subfolders: "test" and "train" as well as a README.md file.
You can of course use your own datasets for training, but for this you would need to modify the code manually, which will not be discussed here. However, we provide a loading function for the normal MUSDB18 dataset as well.
To train a Wave-U-Net, the basic command to use is
python3.6 train.py --dataset_dir /PATH/TO/MUSDB18HQ
where the path to MUSDB18HQ dataset needs to be specified, which contains the train
and test
subfolders.
Add more command line parameters as needed:
--cuda
to activate GPU usage--hdf_dir PATH
to save the preprocessed data (HDF files) to custom location PATH, instead of the defaulthdf
subfolder in this repository--checkpoint_dir
and--log_dir
to specify where checkpoint files and logs are saved/loaded--load_model checkpoints/model_name/checkpoint_X
to start training with weights given by a certain checkpoint
For more config options, see train.py
.
Training progress can be monitored by using Tensorboard on the respective log_dir
.
After training, the model is evaluated on the MUSDB18HQ test set, and SDR/SIR/SAR metrics are reported for all instruments and written into both the Tensorboard, and in more detail also into a results.pkl
file in the checkpoint_dir
We provide the default model in a pre-trained form as download so you can separate your own songs right away.
Download our pretrained model here.
Extract the archive into the checkpoints
subfolder in this repository, so that you have one subfolder for each model (e.g. REPO/checkpoints/waveunet
)
To apply our pretrained model to any of your own songs, simply point to its audio file path using the input_path
parameter:
python3.6 predict.py --load_model checkpoints/waveunet/model --input "audio_examples/Cristina Vane - So Easy/mix.mp3"
- Add
--cuda
when using a GPU, it should be much quicker - Point
--input
to the music file you want to separate
By default, output is written where the input music file is located, using the original file name plus the instrument name as output file name. Use --output
to customise the output directory.
To run your own model:
- Point
--load_model
to the checkpoint file of the model you are using. If you used non-default hyper-parameters to train your own model, you must specify them here again so the correct model is set up and can receive the weights!