c497fd843d | ||
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README.md | ||
config.py | ||
ljspeech.py | ||
preprocess.py | ||
synthesize.py | ||
train.py |
README.md
WaveFlow with LJSpeech
Dataset
Download the datasaet.
wget https://data.keithito.com/data/speech/LJSpeech-1.1.tar.bz2
Extract the dataset.
tar xjvf LJSpeech-1.1.tar.bz2
Preprocess the dataset.
Assume the path to save the preprocessed dataset is ljspeech_waveflow
. Run the command below to preprocess the dataset.
python preprocess.py --input=LJSpeech-1.1/ --output=ljspeech_waveflow
Train the model
The training script requires 4 command line arguments.
--data
is the path of the training dataset, --output
is the path of the output directory (we recommend to use a subdirectory in runs
to manage different experiments.)
--device
should be "cpu" or "gpu", --nprocs
is the number of processes to train the model in parallel.
python train.py --data=ljspeech_waveflow/ --output=runs/test --device="gpu" --nprocs=1
If you want distributed training, set a larger --nprocs
(e.g. 4). Note that distributed training with cpu is not supported yet.
Synthesize
Synthesize waveform. We assume the --input
is a directory containing several mel spectrograms(log magnitude) in .npy
format. The output would be saved in --output
directory, containing several .wav
files, each with the same name as the mel spectrogram does.
--checkpoint_path
should be the path of the parameter file (.pdparams
) to load. Note that the extention name .pdparmas
is not included here.
--device
specifies to device to run synthesis on.
python synthesize.py --input=mels/ --output=wavs/ --checkpoint_path='step-2000000' --device="gpu" --verbose
Pretrained Model
Pretrained Model with residual channel equals 128 can be downloaded here. waveflow_ljspeech_ckpt_0.3.zip.