English Β ο½ Β δΈζ Β
Yichao Huβ Jian Liβ Yajun Zhengβ Meng Caiβ Hua Wangβ
2024/10/24
: πππ We released the new Omni (MooER-omni-v1) and Speech-To-Speech Translation (MooER-S2ST-v1) models which support Mandarin input. The Omni model can hear, think and talk to you! See our demo here.2024/09/03
: We have open-sourced the training and inference code for MooER! You can follow this tutorial to train your own audio understanding model and tasks or fine-tune based on our 80k hours model.2024/08/27
: We released MooER-80K-v2 which was trained using 80K hours of data. The performance of the new model can be found below. Currently, it only supports the speech recognition task. The speech translation and the multi-task models will be released soon.2024/08/09
: We released a Gradio demo running on Moore Threads S4000.2024/08/09
: We released the inference code and the pretrained speech recognition and speech translation (zh->en) models using 5000 hours of data.2024/08/09
: We release MooER v0.1 technical report on arXiv.
- Technical report
- Inference code and pretrained ASR/AST models using 5k hours of data
- Pretrained ASR model using 80k hours of data
- Traning code for MooER
- LLM-based speech-to-speech translation (S2ST, Mandrin Chinese to English)
- GPT-4o-like audio-LLM supporting chat using speech
- Training code and technical report about our new Omni model
- Omni audio-LLM that supports multi-turn conversation
- Pretrained AST and multi-task models using 80k hours of data
- LLM-based timbre-preserving Speech-to-speech translation
π₯ Hi there! We have updated our Omni model with the ability to listen, think and talk! Check our examples here. Please refer to the Download, Inference and Gradio Demo sections for the model usage.
The training procedure of our model is demonstrated in the following figure. We will release the training code and the technical report soon!
We introduce MooER (ζ©θ³): an LLM-based speech recognition and translation model developed by Moore Threads. With the MooER framework, you can transcribe the speech into text (automatic speech recognition, ASR) and translate the speech into other languages (automatic speech translation, AST) in an LLM-based end-to-end manner. Some of the evaluation results of the MooER are presented in the subsequent section. More detailed experiments, along with our insights into model configurations, training strategies, etc, are provided in our technical report.
We proudly highlight that MooER is developed using Moore Threads S4000 GPUs. To the best of our knowledge, this is the first LLM-based speech model trained and inferred using entirely domestic GPUs.
We present the training data and the evaluation results below. For more comprehensive information, please refer to our report.
We utilize 5,000 hours of speech data (MT5K) to train our basic MooER-5K model. The data sources include:
Dataset | Duration |
---|---|
aishell2 | 137h |
librispeech | 131h |
multi_cn | 100h |
wenetspeech | 1361h |
in-house data | 3274h |
Note that, data from the open-source datasets were randomly selected from the full training set. The in-house speech data, collected internally without transcription, were transcribed using a third-party ASR service.
Since all the above datasets were originally collected only for the speech recognition task, no translation labels are available. We leveraged a third-party machine translation service to generate pseudo-labels for translation. No data filtering techniques were applied.
At this moment, we are also developing a new model trained with 80,000 hours of speech data.
The performance of speech recognition is evaluated using word error rate (WER) and character error rate (CER).
Language | Testset | Paraformer-large | SenseVoice-small | Qwen-audio | Whisper-large-v3 | SeamlessM4T-v2 | MooER-5K | MooER-80K | MooER-80K-v2 |
---|---|---|---|---|---|---|---|---|---|
Chinese | aishell1 | 1.93 | 3.03 | 1.43 | 7.86 | 4.09 | 1.93 | 1.25 | 1.00 |
aishell2_ios | 2.85 | 3.79 | 3.57 | 5.38 | 4.81 | 3.17 | 2.67 | 2.62 | |
test_magicdata | 3.66 | 3.81 | 5.31 | 8.36 | 9.69 | 3.48 | 2.52 | 2.17 | |
test_thchs | 3.99 | 5.17 | 4.86 | 9.06 | 7.14 | 4.11 | 3.14 | 3.00 | |
fleurs cmn_dev | 5.56 | 6.39 | 10.54 | 4.54 | 7.12 | 5.81 | 5.23 | 5.15 | |
fleurs cmn_test | 6.92 | 7.36 | 11.07 | 5.24 | 7.66 | 6.77 | 6.18 | 6.14 | |
average | 4.15 | 4.93 | 6.13 | 6.74 | 6.75 | 4.21 | 3.50 | 3.35 | |
English | librispeech test_clean | 14.15 | 4.07 | 2.15 | 3.42 | 2.77 | 7.78 | 4.11 | 3.57 |
librispeech test_other | 22.99 | 8.26 | 4.68 | 5.62 | 5.25 | 15.25 | 9.99 | 9.09 | |
fleurs eng_dev | 24.93 | 12.92 | 22.53 | 11.63 | 11.36 | 18.89 | 13.32 | 13.12 | |
fleurs eng_test | 26.81 | 13.41 | 22.51 | 12.57 | 11.82 | 20.41 | 14.97 | 14.74 | |
gigaspeech dev | 24.23 | 19.44 | 12.96 | 19.18 | 28.01 | 23.46 | 16.92 | 17.34 | |
gigaspeech test | 23.07 | 16.65 | 13.26 | 22.34 | 28.65 | 22.09 | 16.64 | 16.97 | |
average | 22.70 | 12.46 | 13.02 | 12.46 | 14.64 | 17.98 | 12.66 | 12.47 |
For speech translation, the performance is evaluated using BLEU score.
Testset | Speech-LLaMA | Whisper-large-v3 | Qwen-audio | Qwen2-audio | SeamlessM4T-v2 | MooER-5K | MooER-5K-MTL |
---|---|---|---|---|---|---|---|
CoVoST1 zh2en | - | 13.5 | 13.5 | - | 25.3 | - | 30.2 |
CoVoST2 zh2en | 12.3 | 12.2 | 15.7 | 24.4 | 22.2 | 23.4 | 25.2 |
CCMT2019 dev | - | 15.9 | 12.0 | - | 14.8 | - | 19.6 |
Currently, only Linux is supported. Ensure that git
and python
are installed on your system. We recommend Python version >=3.8
. It is highly recommanded to install conda
to create a virtual environment.
For efficient LLM inference, GPUs should be used. For Moore Threads S3000/S4000 users, please install MUSA toolkit rc2.1.0. A docker image is also available for S4000 users. If you use other GPUs, install your own drivers/toolkits (e.g. cuda).
Build the environment with the following steps:
git clone https://github.com/MooreThreads/MooER
cd MooER
# (optional) create env using conda
conda create -n mooer python=3.8
conda activate mooer
# install the dependencies
apt update
apt install ffmpeg sox
pip install -r requirements.txt
Docker image usage for Moore Threads S4000 users is provided:
sudo docker run -it \
--privileged \
--name=torch_musa_release \
--env MTHREADS_VISIBLE_DEVICES=all \
-p 10010:10010 \
--shm-size 80g \
--ulimit memlock=-1 \
mtspeech/mooer:v1.0-rc2.1.0-v1.1.0-qy2 \
/bin/bash
# If you are nvidia user, you can try this image with cuda 11.7
sudo docker run -it \
--privileged \
--gpus all \
-p 10010:10010 \
--shm-size 80g \
--ulimit memlock=-1 \
mtspeech/mooer:v1.0-cuda11.7-cudnn8 \
/bin/bash
The new MooER-Omni-v1 and MooER-S2ST-v1 are available. Please download them manually and place the checkpoints in pretrained_models
.
# MooER-Omni-v1
git lfs clone https://modelscope.cn/models/MooreThreadsSpeech/MooER-omni-v1
# MooER-S2ST-v1
git lfs clone https://modelscope.cn/models/MooreThreadsSpeech/MooER-S2ST-v1
The new MooER-80K-v2 is released. You can download the new model and update pretrained_models
.
# use modelscope
git lfs clone https://modelscope.cn/models/MooreThreadsSpeech/MooER-MTL-80K
# use huggingface
git lfs clone https://huggingface.co/mtspeech/MooER-MTL-80K
The md5sum's of the updated files are provided.
./pretrained_models/
`-- asr
|-- adapter_project.pt # af9022e2853f9785cab49017a18de82c
`-- lora_weights
|-- README.md
|-- adapter_config.json # ad3e3bfe9447b808b9cc16233ffacaaf
`-- adapter_model.bin # 3c22b9895859b01efe49b017e8ed6ec7
First, download the pretrained models from ModelScope or HuggingFace.
# use modelscope
git lfs clone https://modelscope.cn/models/MooreThreadsSpeech/MooER-MTL-5K
# use huggingface
git lfs clone https://huggingface.co/mtspeech/MooER-MTL-5K
Put the downloaded files in pretrained_models
cp MooER-MTL-5K/* pretrained_models
Then, download Qwen2-7B-Instruct
by:
# use modelscope
git lfs clone https://modelscope.cn/models/qwen/qwen2-7b-instruct
# use huggingface
git lfs clone https://huggingface.co/Qwen/Qwen2-7B-Instruct
Put the downloaded files into pretrained_models/Qwen2-7B-Instruct
.
Finally, all these files should be orgnized as follows. The md5sum's are also provided.
./pretrained_models/
|-- paraformer_encoder
| |-- am.mvn # dc1dbdeeb8961f012161cfce31eaacaf
| `-- paraformer-encoder.pth # 2ef398e80f9f3e87860df0451e82caa9
|-- asr
| |-- adapter_project.pt # 2462122fb1655c97d3396f8de238c7ed
| `-- lora_weights
| |-- README.md
| |-- adapter_config.json # 8a76aab1f830be138db491fe361661e6
| `-- adapter_model.bin # 0fe7a36de164ebe1fc27500bc06c8811
|-- ast
| |-- adapter_project.pt # 65c05305382af0b28964ac3d65121667
| `-- lora_weights
| |-- README.md
| |-- adapter_config.json # 8a76aab1f830be138db491fe361661e6
| `-- adapter_model.bin # 12c51badbe57298070f51902abf94cd4
|-- asr_ast_mtl
| |-- adapter_project.pt # 83195d39d299f3b39d1d7ddebce02ef6
| `-- lora_weights
| |-- README.md
| |-- adapter_config.json # 8a76aab1f830be138db491fe361661e6
| `-- adapter_model.bin # a0f730e6ddd3231322b008e2339ed579
|-- Qwen2-7B-Instruct
| |-- model-00001-of-00004.safetensors # d29bf5c5f667257e9098e3ff4eec4a02
| |-- model-00002-of-00004.safetensors # 75d33ab77aba9e9bd856f3674facbd17
| |-- model-00003-of-00004.safetensors # bc941028b7343428a9eb0514eee580a3
| |-- model-00004-of-00004.safetensors # 07eddec240f1d81a91ca13eb51eb7af3
| |-- model.safetensors.index.json
| |-- config.json # 8d67a66d57d35dc7a907f73303486f4e
| |-- configuration.json # 040f5895a7c8ae7cf58c622e3fcc1ba5
| |-- generation_config.json # 5949a57de5fd3148ac75a187c8daec7e
| |-- merges.txt # e78882c2e224a75fa8180ec610bae243
| |-- tokenizer.json # 1c74fd33061313fafc6e2561d1ac3164
| |-- tokenizer_config.json # 5c05592e1adbcf63503fadfe429fb4cc
| |-- vocab.json # 613b8e4a622c4a2c90e9e1245fc540d6
| |-- LICENSE
| `-- README.md
|-- README.md
`-- configuration.json
We have open-sourced the training and inference code for MooER! You can follow this tutorial to train your own audio understanding model or fine-tune based on 80k hours model.
You can specify your own audio files and change the model settings.
# set environment variables
export PYTHONIOENCODING=UTF-8
export LC_ALL=C
export PYTHONPATH=$PWD/src:$PYTHONPATH
# π₯ Speech-to-speech chat (use the Omni model)
python inference_s2st.py \
--task s2s_chat --batch_size 1 \
--cmvn_path pretrained_models/MooER-omni-v1/am.mvn \
--encoder_path pretrained_models/MooER-omni-v1/paraformer-encoder.pth \
--llm_path pretrained_models/MooER-omni-v1/llm \
--adapter_path pretrained_models/MooER-omni-v1/adapter_project.pt \
--lora_dir pretrained_models/MooER-omni-v1/lora \
--vocoder_path pretrained_models/MooER-omni-v1/g_00112000 \
--spk_encoder_path pretrained_models/MooER-omni-v1/spk_00112000 \
--prompt_wav_path pretrained_models/MooER-omni-v1/prompt.wav \
--wav_scp <your_wav_scp> \
--output_dir <your_output_dir>
# Speech-to-speech translation
python inference_s2st.py \
--task s2s_trans --batch_size 1 \
--cmvn_path pretrained_models/MooER-S2ST-v1/am.mvn \
--encoder_path pretrained_models/MooER-S2ST-v1/paraformer-encoder.pth \
--llm_path pretrained_models/MooER-S2ST-v1/llm \
--adapter_path pretrained_models/MooER-S2ST-v1/adapter_project.pt \
--lora_dir pretrained_models/MooER-S2ST-v1/lora \
--vocoder_path pretrained_models/MooER-S2ST-v1/g_00050000 \
--spk_encoder_path pretrained_models/MooER-S2ST-v1/spk_00050000 \
--prompt_wav_path pretrained_models/MooER-S2ST-v1/prompt.wav \
--wav_scp <your_wav_scp> \
--output_dir <your_output_dir>
# use your own audio file
python inference.py --wav_path /path/to/your_audio_file
# an scp file is also supported. The format of each line is: "uttid wav_path":
# test1 my_test_audio1.wav
# test2 my_test_audio2.wav
# ...
python inference.py --wav_scp /path/to/your_wav_scp
# change to an ASR model (only transcription)
python inference.py --task asr \
--cmvn_path pretrained_models/paraformer_encoder/am.mvn \
--encoder_path pretrained_models/paraformer_encoder/paraformer-encoder.pth \
--llm_path pretrained_models/Qwen2-7B-Instruct \
--adapter_path pretrained_models/asr/adapter_project.pt \
--lora_dir pretrained_models/asr/lora_weights \
--wav_path /path/to/your_audio_file
# change to an AST model (only translation)
python inference.py --task ast \
--cmvn_path pretrained_models/paraformer_encoder/am.mvn \
--encoder_path pretrained_models/paraformer_encoder/paraformer-encoder.pth \
--llm_path pretrained_models/Qwen2-7B-Instruct \
--adapter_path pretrained_models/ast/adapter_project.pt \
--lora_dir pretrained_models/ast/lora_weights \
--wav_path /path/to/your_audio_file
# Note: set `--task ast` if you want to use the asr/ast multitask model
# show all the parameters
python inference.py -h
We recommend to use an audio file shorter than 30s. The text in the audio should be less than 500 characters. It is also suggested that you convert the audio to a 16kHz 16bit mono WAV format before processing it (using ffmpeg
or sox
).
We provide a Gradio interface for a better experience. To use it, run the following commands:
# set the environment variables
export PYTHONPATH=$PWD/src:$PYTHONPATH
# π₯ Run the Omni model
python demo/app_s2s.py \
--task s2s_chat \
--cmvn_path pretrained_models/MooER-omni-v1/am.mvn \
--encoder_path pretrained_models/MooER-omni-v1/paraformer-encoder.pth \
--llm_path pretrained_models/MooER-omni-v1/llm \
--adapter_path pretrained_models/MooER-omni-v1/adapter_project.pt \
--lora_dir pretrained_models/MooER-omni-v1/lora \
--vocoder_path pretrained_models/MooER-omni-v1/g_00112000 \
--spk_encoder_path pretrained_models/MooER-omni-v1/spk_00112000 \
--prompt_wav_path pretrained_models/MooER-omni-v1/prompt.wav \
--server_port 10087
# Run the speech-to-speech translation
python demo/app_s2s.py \
--task s2s_trans \
--cmvn_path pretrained_models/MooER-S2ST-v1/am.mvn \
--encoder_path pretrained_models/MooER-S2ST-v1/paraformer-encoder.pth \
--llm_path pretrained_models/MooER-S2ST-v1/llm \
--adapter_path pretrained_models/MooER-S2ST-v1/adapter_project.pt \
--lora_dir pretrained_models/MooER-S2ST-v1/lora \
--vocoder_path pretrained_models/MooER-S2ST-v1/g_00050000 \
--spk_encoder_path pretrained_models/MooER-S2ST-v1/spk_00050000 \
--prompt_wav_path pretrained_models/MooER-S2ST-v1/prompt.wav \
--server_port 10087
# Run the ASR/AST multitask model
python demo/app.py
# Run the ASR-only model
python demo/app.py \
--task asr \
--adapter_path pretrained_models/asr/adapter_project.pt \
--lora_dir pretrained_models/asr/lora_weights \
--server_port 10087
# Run the AST-only model
python demo/app.py \
--task ast \
--adapter_path pretrained_models/ast/adapter_project.pt \
--lora_dir pretrained_models/ast/lora_weights \
--server_port 10087
You can specify --server_port
, --share
, --server_name
as needed.
Due to the lack of an HTTPS certificate, your access is limited to HTTP, for which modern browsers block the microphone access. As a workaround, you can manually grant access. For instance, in Chrome, navigate to chrome://flags/#unsafely-treat-insecure-origin-as-secure
and add the target address to the whitelist. For other browsers, please google for a similar workaround.
In the demo, using the streaming mode will yield faster results. However, please note that the beam size is restricted to be 1 in the streaming mode, which may slightly degrade the performance.
π€ No experience about how to run Gradio?
π» Don't have a machine to run the demo?
β Don't have time to install the dependencies?
β Just take a coffee and click here to try our online demo. It is running on a Moore Threads S4000 GPU server!
Please see the LICENSE.
We borrowed the speech encoder from FunASR.
The LLM code was borrowed from Qwen2.
Our training and inference codes are adapted from SLAM-LLM and Wenet.
We also got inspiration from other open-source repositories like whisper and SeamlessM4T. We would like to thank all the authors and contributors for their innovative ideas and codes.
If you find MooER useful for your research, please π this repo and cite our work using the following BibTeX:
@article{liang2024mooer,
title = {MooER: LLM-based Speech Recognition and Translation Models from Moore Threads},
author = {Zhenlin Liang, Junhao Xu, Yi Liu, Yichao Hu, Jian Li, Yajun Zheng, Meng Cai, Hua Wang},
journal = {arXiv preprint arXiv:2408.05101},
year = {2024}
}
If you encouter any problems, feel free to create an issue.
Moore Threads Website: https://www.mthreads.com/