OpenRL-v0.2.1 is updated on Dec 20, 2023
The main branch is the latest version of OpenRL, which is under active development. If you just want to have a try with OpenRL, you can switch to the stable branch.
Documentation | 中文介绍 | 中文文档
OpenRL is an open-source general reinforcement learning research framework that supports training for various tasks such as single-agent, multi-agent, offline RL, self-play, and natural language. Developed based on PyTorch, the goal of OpenRL is to provide a simple-to-use, flexible, efficient and sustainable platform for the reinforcement learning research community.
Currently, the features supported by OpenRL include:
-
A simple-to-use universal interface that supports training for all tasks/environments
-
Support for both single-agent and multi-agent tasks
-
Support for offline RL training with expert dataset
-
Support self-play training
-
Reinforcement learning training support for natural language tasks (such as dialogue)
-
Support DeepSpeed
-
Support Arena , which allows convenient evaluation of various agents (even submissions for JiDi) in a competitive environment.
-
Importing models and datasets from Hugging Face. Supports loading Stable-baselines3 models from Hugging Face for testing and training.
-
Tutorial on how to integrate user-defined environments into OpenRL.
-
Support for models such as LSTM, GRU, Transformer etc.
-
Multiple training acceleration methods including automatic mixed precision training and data collecting wth half precision policy network
-
User-defined training models, reward models, training data and environment support
-
Support for gymnasium environments
-
Support for Callbacks, which can be used to implement various functions such as logging, saving, and early stopping
-
Dictionary observation space support
-
Popular visualization tools such as wandb, tensorboardX are supported
-
Serial or parallel environment training while ensuring consistent results in both modes
-
Chinese and English documentation
-
Provides unit testing and code coverage testing
-
Compliant with Black Code Style guidelines and type checking
Algorithms currently supported by OpenRL (for more details, please refer to Gallery):
- Proximal Policy Optimization (PPO)
- Dual-clip PPO
- Multi-agent PPO (MAPPO)
- Joint-ratio Policy Optimization (JRPO)
- Generative Adversarial Imitation Learning (GAIL)
- Behavior Cloning (BC)
- Advantage Actor-Critic (A2C)
- Self-Play
- Deep Q-Network (DQN)
- Multi-Agent Transformer (MAT)
- Value-Decomposition Network (VDN)
- Soft Actor Critic (SAC)
- Deep Deterministic Policy Gradient (DDPG)
Environments currently supported by OpenRL (for more details, please refer to Gallery):
- Gymnasium
- MuJoCo
- PettingZoo
- MPE
- Chat Bot
- Atari
- StarCraft II
- SMACv2
- Omniverse Isaac Gym
- DeepMind Control
- Snake
- gym-pybullet-drones
- EnvPool
- GridWorld
- Super Mario Bros
- Gym Retro
- Crafter
This framework has undergone multiple iterations by the OpenRL-Lab team which has applied it in academic research. It has now become a mature reinforcement learning framework.
OpenRL-Lab will continue to maintain and update OpenRL, and we welcome everyone to join our open-source community to contribute towards the development of reinforcement learning.
For more information about OpenRL, please refer to the documentation.
- Welcome to OpenRL
- Outline
- Why OpenRL?
- Installation
- Use Docker
- Quick Start
- Gallery
- Projects Using OpenRL
- Feedback and Contribution
- Maintainers
- Supporters
- Citing OpenRL
- License
- Acknowledgments
Here we provide a table for the comparison of OpenRL and existing popular RL libraries. OpenRL employs a modular design and high-level abstraction, allowing users to accomplish training for various tasks through a unified and user-friendly interface.
Library | NLP/RLHF | Multi-agent | Self-Play Training | Offline RL | DeepSpeed |
---|---|---|---|---|---|
OpenRL | ✔️ | ✔️ | ✔️ | ✔️ | ✔️ |
Stable Baselines3 | ❌ | ❌ | ❌ | ❌ | ❌ |
Ray/RLlib | ❌ | ✔️ | ✔️ | ✔️ | ❌ |
DI-engine | ❌ | ✔️ | not fullly supported | ✔️ | ❌ |
Tianshou | ❌ | not fullly supported | not fullly supported | ✔️ | ❌ |
MARLlib | ❌ | ✔️ | not fullly supported | ❌ | ❌ |
MAPPO Benchmark | ❌ | ✔️ | ❌ | ❌ | ❌ |
RL4LMs | ✔️ | ❌ | ❌ | ❌ | ❌ |
trlx | ✔️ | ❌ | ❌ | ❌ | ✔️ |
trl | ✔️ | ❌ | ❌ | ❌ | ✔️ |
TimeChamber | ❌ | ❌ | ✔️ | ❌ | ❌ |
Users can directly install OpenRL via pip:
pip install openrl
If users are using Anaconda or Miniconda, they can also install OpenRL via conda:
conda install -c openrl openrl
Users who want to modify the source code can also install OpenRL from the source code:
git clone https://github.com/OpenRL-Lab/openrl.git && cd openrl
pip install -e .
After installation, users can check the version of OpenRL through command line:
openrl --version
Tips: No installation required, try OpenRL online through Colab:
OpenRL currently provides Docker images with and without GPU support. If the user's computer does not have an NVIDIA GPU, they can obtain an image without the GPU plugin using the following command:
sudo docker pull openrllab/openrl-cpu
If the user wants to accelerate training with a GPU, they can obtain it using the following command:
sudo docker pull openrllab/openrl
After successfully pulling the image, users can run OpenRL's Docker image using the following commands:
# Without GPU acceleration
sudo docker run -it openrllab/openrl-cpu
# With GPU acceleration
sudo docker run -it --gpus all --net host openrllab/openrl
Once inside the Docker container, users can check OpenRL's version and then run test cases using these commands:
# Check OpenRL version in Docker container
openrl --version
# Run test case
openrl --mode train --env CartPole-v1
OpenRL provides a simple and easy-to-use interface for beginners in reinforcement learning.
Below is an example of using the PPO algorithm to train the CartPole
environment:
# train_ppo.py
from openrl.envs.common import make
from openrl.modules.common import PPONet as Net
from openrl.runners.common import PPOAgent as Agent
env = make("CartPole-v1", env_num=9) # Create an environment and set the environment parallelism to 9.
net = Net(env) # Create neural network.
agent = Agent(net) # Initialize the agent.
agent.train(
total_time_steps=20000) # Start training and set the total number of steps to 20,000 for the running environment.
Training an agent using OpenRL only requires four simple steps: Create Environment => Initialize Model => Initialize Agent => Start Training!
For a well-trained agent, users can also easily test the agent:
# train_ppo.py
from openrl.envs.common import make
from openrl.modules.common import PPONet as Net
from openrl.runners.common import PPOAgent as Agent
agent = Agent(Net(make("CartPole-v1", env_num=9))) # Initialize trainer.
agent.train(total_time_steps=20000)
# Create an environment for test, set the parallelism of the environment to 9, and set the rendering mode to group_human.
env = make("CartPole-v1", env_num=9, render_mode="group_human")
agent.set_env(env) # The agent requires an interactive environment.
obs, info = env.reset() # Initialize the environment to obtain initial observations and environmental information.
while True:
action, _ = agent.act(obs) # The agent predicts the next action based on environmental observations.
# The environment takes one step according to the action, obtains the next observation, reward, whether it ends and environmental information.
obs, r, done, info = env.step(action)
if any(done): break
env.close() # Close test environment
Executing the above code on a regular laptop only takes a few seconds to complete the training. Below shows the visualization of the agent:
Tips: Users can also quickly train the CartPole
environment by executing a command line in the terminal.
openrl --mode train --env CartPole-v1
For training tasks such as multi-agent and natural language processing, OpenRL also provides a similarly simple and easy-to-use interface.
For information on how to perform multi-agent training, set hyperparameters for training, load training configurations, use wandb, save GIF animations, etc., please refer to:
For information on natural language task training, loading models/datasets on Hugging Face, customizing training models/reward models, etc., please refer to:
For more information about OpenRL, please refer to the documentation.
In order to facilitate users' familiarity with the framework, we provide more examples and demos of using OpenRL in Gallery. Users are also welcome to contribute their own training examples and demos to the Gallery.
We have listed research projects that use OpenRL in the OpenRL Project. If you are using OpenRL in your research project, you are also welcome to join this list.
- If you have any questions or find bugs, you can check or ask in the Issues.
- Join the QQ group: OpenRL Official Communication Group
- Join the slack group to discuss OpenRL usage and development with us.
- Join the Discord group to discuss OpenRL usage and development with us.
- Send an E-mail to: [email protected]
- Join the GitHub Discussion.
The OpenRL framework is still under continuous development and documentation. We welcome you to join us in making this project better:
- How to contribute code: Read the Contributors' Guide
- OpenRL Roadmap
At present, OpenRL is maintained by the following maintainers:
- Shiyu Huang(@huangshiyu13)
- Wenze Chen(@WentseChen)
- Yiwen Sun(@YiwenAI)
Welcome more contributors to join our maintenance team (send an E-mail to [email protected] to apply for joining the OpenRL team).
If our work has been helpful to you, please feel free to cite us:
@article{huang2023openrl,
title={OpenRL: A Unified Reinforcement Learning Framework},
author={Huang, Shiyu and Chen, Wentse and Sun, Yiwen and Bie, Fuqing and Tu, Wei-Wei},
journal={arXiv preprint arXiv:2312.16189},
year={2023}
}
OpenRL under the Apache 2.0 license.
The development of the OpenRL framework has drawn on the strengths of other reinforcement learning frameworks:
- Stable-baselines3: https://github.com/DLR-RM/stable-baselines3
- pytorch-a2c-ppo-acktr-gail: https://github.com/ikostrikov/pytorch-a2c-ppo-acktr-gail
- MAPPO: https://github.com/marlbenchmark/on-policy
- Gymnasium: https://github.com/Farama-Foundation/Gymnasium
- DI-engine: https://github.com/opendilab/DI-engine/
- Tianshou: https://github.com/thu-ml/tianshou
- RL4LMs: https://github.com/allenai/RL4LMs