Welcome to H2O LLM Studio, a framework and no-code GUI designed for
fine-tuning state-of-the-art large language models (LLMs).
- With H2O LLM Studio, you can
- Quickstart
- What's New
- Setup
- Run H2O LLM Studio GUI
- Run H2O LLM Studio GUI using Docker from a nightly build
- Run H2O LLM Studio GUI by building your own Docker image
- Run H2O LLM Studio with command line interface (CLI)
- Data format and example data
- Training your model
- Example: Run on OASST data via CLI
- Model checkpoints
- Documentation
- Contributing
- License
- easily and effectively fine-tune LLMs without the need for any coding experience.
- use a graphic user interface (GUI) specially designed for large language models.
- finetune any LLM using a large variety of hyperparameters.
- use recent finetuning techniques such as Low-Rank Adaptation (LoRA) and 8-bit model training with a low memory footprint.
- use Reinforcement Learning (RL) to finetune your model (experimental)
- use advanced evaluation metrics to judge generated answers by the model.
- track and compare your model performance visually. In addition, Neptune integration can be used.
- chat with your model and get instant feedback on your model performance.
- easily export your model to the Hugging Face Hub and share it with the community.
For questions, discussing, or just hanging out, come and join our Discord!
We offer several ways of getting started quickly.
Using CLI for fine-tuning LLMs:
- PR 539 Introduced a new problem type for DPO/IPO optimization. This optimization technique can be used as an alternative to RLHF.
- PR 288 Introduced Deepspeed for sharded training allowing to train larger models on machines with multiple GPUs. Requires NVLink. This feature replaces FSDP and offers more flexibility. Deepspeed requires a system installation of cudatoolkit and we recommend using version 11.8. See Recommended Install.
- PR 449 New problem type for Causal Classification Modeling allows to train binary and multiclass models using LLMs.
- PR 364 User secrets are now handled more securely and flexible. Support for handling secrets using the 'keyring' library was added. User settings are tried to be migrated automatically.
- PR 328 RLHF is now a separate problem type. Note that starting a new RLHF experiment from an old experiment that used RLHF is no longer supported. To continue from a previous experiment, please start a new experiment and enter the settings from the previous experiment manually.
- PR 308 Sequence to sequence models have been added as a new problem type.
- PR 152 Add RLHF functionality for fine-tuning LLMs.
- PR 132 Add 4bit training that allows training of larger LLM backbones with less GPU memory. See here for a comprehensive summary of this method.
- PR 40 Added functionality for supporting nested conversations in data. A new
parent_id_column
can be selected for datasets to support tree-like structures in your conversational data. Additionalaugmentation
settings have been added for this feature.
Please note that due to current rapid development we cannot guarantee full backwards compatibility of new functionality. We thus recommend to pin the version of the framework to the one you used for your experiments. For resetting, please delete/backup your data
and output
folders.
H2O LLM Studio requires a machine with Ubuntu 16.04+ and at least one recent Nvidia GPU with Nvidia drivers version >= 470.57.02. For larger models, we recommend at least 24GB of GPU memory.
For more information about installation prerequisites, see the Set up H2O LLM Studio guide in the documentation.
For a performance comparison of different GPUs, see the H2O LLM Studio performance guide in the documentation.
The recommended way to install H2O LLM Studio is using pipenv with Python 3.10. To install Python 3.10 on Ubuntu 16.04+, execute the following commands:
sudo add-apt-repository ppa:deadsnakes/ppa
sudo apt install python3.10
sudo apt-get install python3.10-distutils
curl -sS https://bootstrap.pypa.io/get-pip.py | python3.10
If deploying on a 'bare metal' machine running Ubuntu, one may need to install the required Nvidia drivers and CUDA. The following commands show how to retrieve the latest drivers for a machine running Ubuntu 20.04 as an example. One can update the following based on their OS.
wget https://developer.download.nvidia.com/compute/cuda/repos/ubuntu2004/x86_64/cuda-ubuntu2004.pin
sudo mv cuda-ubuntu2004.pin /etc/apt/preferences.d/cuda-repository-pin-600
wget https://developer.download.nvidia.com/compute/cuda/11.8.0/local_installers/cuda-repo-ubuntu2004-11-8-local_11.8.0-520.61.05-1_amd64.deb
sudo dpkg -i cuda-repo-ubuntu2004-11-8-local_11.8.0-520.61.05-1_amd64.deb
sudo cp /var/cuda-repo-ubuntu2004-11-8-local/cuda-*-keyring.gpg /usr/share/keyrings/
sudo apt-get update
sudo apt-get -y install cuda
alternatively, one can install cudatoolkits in a cuda environment:
conda create -n llmstudio python=3.10
conda activate llmstudio
conda install -c "nvidia/label/cuda-11.8.0" cuda-toolkit
The following command will create a virtual environment using pipenv and will install the dependencies using pipenv:
make setup
If you are having troubles installing the flash_attn package, consider running
make setup-no-flash
instead. This will install the dependencies without the flash_attn package. Note that this will disable the use of Flash Attention 2 and model training will be slower and consume more memory.
If you wish to use conda or another virtual environment, you can also install the dependencies using the requirements.txt file:
pip install -r requirements.txt
pip install flash-attn==2.3.3 --no-build-isolation # optional for Flash Attention 2
You can start H2O LLM Studio using the following command:
make llmstudio
This command will start the H2O wave server and app. Navigate to http://localhost:10101/ (we recommend using Chrome) to access H2O LLM Studio and start fine-tuning your models!
If you are running H2O LLM Studio with a custom environment other than Pipenv, you need to start the app as follows:
H2O_WAVE_APP_ADDRESS=http://127.0.0.1:8756 \
H2O_WAVE_MAX_REQUEST_SIZE=25MB \
H2O_WAVE_NO_LOG=true \
H2O_WAVE_PRIVATE_DIR="/download/@output/download" \
wave run app
Install Docker first by following instructions from NVIDIA Containers. H2O LLM Studio images are stored in the h2oai GCR vorvan container repository.
mkdir -p `pwd`/data
mkdir -p `pwd`/output
docker run \
--runtime=nvidia \
--shm-size=64g \
--init \
--rm \
-u `id -u`:`id -g` \
-p 10101:10101 \
-v `pwd`/data:/workspace/data \
-v `pwd`/output:/workspace/output \
-v ~/.cache:/home/llmstudio/.cache \
gcr.io/vorvan/h2oai/h2o-llmstudio:nightly
Navigate to http://localhost:10101/ (we recommend using Chrome) to access H2O LLM Studio and start fine-tuning your models!
(Note other helpful docker commands are docker ps
and docker kill
.)
docker build -t h2o-llmstudio .
docker run \
--runtime=nvidia \
--shm-size=64g \
--init \
--rm \
-u `id -u`:`id -g` \
-p 10101:10101 \
-v `pwd`/data:/workspace/data \
-v `pwd`/output:/workspace/output \
-v ~/.cache:/home/llmstudio/.cache \
h2o-llmstudio
Alternatively, you can run H2O LLM Studio GUI by using our self-hosted Docker image available here.
You can also use H2O LLM Studio with the command line interface (CLI) and specify the configuration file that contains all the experiment parameters. To finetune using H2O LLM Studio with CLI, activate the pipenv environment by running make shell
, and then use the following command:
python train.py -C {path_to_config_file}
To run on multiple GPUs in DDP mode, run the following command:
bash distributed_train.sh {NR_OF_GPUS} -C {path_to_config_file}
By default, the framework will run on the first k
GPUs. If you want to specify specific GPUs to run on, use the CUDA_VISIBLE_DEVICES
environment variable before the command.
To start an interactive chat with your trained model, use the following command:
python prompt.py -e {experiment_name}
where experiment_name
is the output folder of the experiment you want to chat with (see configuration).
The interactive chat will also work with model that were finetuned using the UI.
To publish the model to Hugging Face, use the following command:
make shell
python publish_to_hugging_face.py -p {path_to_experiment} -d {device} -a {api_key} -u {user_id} -m {model_name} -s {safe_serialization}
path_to_experiment
is the output folder of the experiment.
device
is the target device for running the model, either 'cpu' or 'cuda:0'. Default is 'cuda:0'.
api_key
is the Hugging Face API Key. If user logged in, it can be omitted.
user_id
is the Hugging Face user ID. If user logged in, it can be omitted.
model_name
is the name of the model to be published on Hugging Face. It can be omitted.
safe_serialization
is a flag indicating whether safe serialization should be used. Default is True.
For details on the data format required when importing your data or example data that you can use to try out H2O LLM Studio, see Data format in the H2O LLM Studio documentation.
With H2O LLM Studio, training your large language model is easy and intuitive. First, upload your dataset and then start training your model. Start by creating an experiment. You can then monitor and manage your experiment, compare experiments, or push the model to Hugging Face to share it with the community.
As an example, you can run an experiment on the OASST data via CLI. For instructions, see Run an experiment on the OASST data guide in the H2O LLM Studio documentation.
All open-source datasets and models are posted on H2O.ai's Hugging Face page and our H2OGPT repository.
Detailed documentation and frequently asked questions (FAQs) for H2O LLM Studio can be found at https://docs.h2o.ai/h2o-llmstudio/. If you wish to contribute to the docs, navigate to the /documentation
folder of this repo and refer to the README.md for more information.
We are happy to accept contributions to the H2O LLM Studio project. Please refer to the CONTRIBUTING.md file for more information.
H2O LLM Studio is licensed under the Apache 2.0 license. Please see the LICENSE file for more information.