A collection of trained Reinforcement Learning (RL) agents, with tuned hyperparameters, using Stable Baselines3.
We are looking for contributors to complete the collection!
Goals of this repository:
- Provide a simple interface to train and enjoy RL agents
- Benchmark the different Reinforcement Learning algorithms
- Provide tuned hyperparameters for each environment and RL algorithm
- Have fun with the trained agents!
This is the SB3 version of the original SB2 rl-zoo.
Note: to download the repo with the trained agents, you must use git clone --recursive https://github.com/DLR-RM/rl-baselines3-zoo
in order to clone the submodule too.
If the trained agent exists, then you can see it in action using:
python enjoy.py --algo algo_name --env env_id
For example, enjoy A2C on Breakout during 5000 timesteps:
python enjoy.py --algo a2c --env BreakoutNoFrameskip-v4 --folder rl-trained-agents/ -n 5000
If you have trained an agent yourself, you need to do:
# exp-id 0 corresponds to the last experiment, otherwise, you can specify another ID
python enjoy.py --algo algo_name --env env_id -f logs/ --exp-id 0
To load the best model (when using evaluation environment):
python enjoy.py --algo algo_name --env env_id -f logs/ --exp-id 1 --load-best
To load a checkpoint (here the checkpoint name is rl_model_10000_steps.zip
):
python enjoy.py --algo algo_name --env env_id -f logs/ --exp-id 1 --load-checkpoint 10000
The hyperparameters for each environment are defined in hyperparameters/algo_name.yml
.
If the environment exists in this file, then you can train an agent using:
python train.py --algo algo_name --env env_id
For example (with tensorboard support):
python train.py --algo ppo --env CartPole-v1 --tensorboard-log /tmp/stable-baselines/
Evaluate the agent every 10000 steps using 10 episodes for evaluation:
python train.py --algo sac --env HalfCheetahBulletEnv-v0 --eval-freq 10000 --eval-episodes 10
Save a checkpoint of the agent every 100000 steps:
python train.py --algo td3 --env HalfCheetahBulletEnv-v0 --save-freq 100000
Continue training (here, load pretrained agent for Breakout and continue training for 5000 steps):
python train.py --algo a2c --env BreakoutNoFrameskip-v4 -i rl-trained-agents/a2c/BreakoutNoFrameskip-v4_1/BreakoutNoFrameskip-v4.zip -n 5000
When using off-policy algorithms, you can also save the replay buffer after training:
python train.py --algo sac --env Pendulum-v0 --save-replay-buffer
It will be automatically loaded if present when continuing training.
We use Optuna for optimizing the hyperparameters.
Note: hyperparameters search is not implemented for DQN for now.
when using SuccessiveHalvingPruner ("halving"), you must specify --n-jobs > 1
Budget of 1000 trials with a maximum of 50000 steps:
python train.py --algo ppo --env MountainCar-v0 -n 50000 -optimize --n-trials 1000 --n-jobs 2 \
--sampler tpe --pruner median
Distributed optimization using a shared database is also possible (see the corresponding Optuna documentation):
python train.py --algo ppo --env MountainCar-v0 -optimize --study-name test --storage sqlite:///example.db
You can specify in the hyperparameter config one or more wrapper to use around the environment:
for one wrapper:
env_wrapper: gym_minigrid.wrappers.FlatObsWrapper
for multiple, specify a list:
env_wrapper:
- utils.wrappers.DoneOnSuccessWrapper:
reward_offset: 1.0
- utils.wrappers.TimeFeatureWrapper
Note that you can easily specify parameters too.
You can specify keyword arguments to pass to the env constructor in the command line, using --env-kwargs
:
python enjoy.py --algo ppo --env MountainCar-v0 --env-kwargs goal_velocity:10
You can easily overwrite hyperparameters in the command line, using --hyperparams
:
python train.py --algo a2c --env MountainCarContinuous-v0 --hyperparams learning_rate:0.001 policy_kwargs:"dict(net_arch=[64, 64])"
Record 1000 steps:
python -m utils.record_video --algo ppo --env BipedalWalkerHardcore-v2 -n 1000
Final performance of the trained agents can be found in benchmark.md
. To compute them, simply run python -m utils.benchmark
.
NOTE: this is not a quantitative benchmark as it corresponds to only one run (cf issue #38). This benchmark is meant to check algorithm (maximal) performance, find potential bugs and also allow users to have access to pretrained agents.
7 atari games from OpenAI benchmark (NoFrameskip-v4 versions).
RL Algo | BeamRider | Breakout | Enduro | Pong | Qbert | Seaquest | SpaceInvaders |
---|---|---|---|---|---|---|---|
A2C | |||||||
PPO | |||||||
DQN |
Additional Atari Games (to be completed):
RL Algo | MsPacman |
---|---|
A2C | |
PPO | |
DQN |
RL Algo | CartPole-v1 | MountainCar-v0 | Acrobot-v1 | Pendulum-v0 | MountainCarContinuous-v0 |
---|---|---|---|---|---|
A2C | |||||
PPO | |||||
DQN | N/A | N/A | |||
DDPG | N/A | N/A | N/A | ||
SAC | N/A | N/A | N/A | ||
TD3 | N/A | N/A | N/A |
RL Algo | BipedalWalker-v2 | LunarLander-v2 | LunarLanderContinuous-v2 | BipedalWalkerHardcore-v2 | CarRacing-v0 |
---|---|---|---|---|---|
A2C | |||||
PPO | |||||
DQN | N/A | N/A | N/A | N/A | |
DDPG | N/A | ||||
SAC | N/A | ||||
TD3 | N/A | ||||
TRPO |
See https://github.com/bulletphysics/bullet3/tree/master/examples/pybullet/gym/pybullet_envs.
Similar to MuJoCo Envs but with a free simulator: pybullet. We are using BulletEnv-v0
version.
Note: those environments are derived from Roboschool and are much harder than the Mujoco version (see Pybullet issue)
RL Algo | Walker2D | HalfCheetah | Ant | Reacher | Hopper | Humanoid |
---|---|---|---|---|---|---|
A2C | ||||||
PPO | ||||||
DDPG | ||||||
SAC | ||||||
TD3 | ||||||
TRPO |
PyBullet Envs (Continued)
RL Algo | Minitaur | MinitaurDuck | InvertedDoublePendulum | InvertedPendulumSwingup |
---|---|---|---|---|
A2C | ||||
PPO | ||||
DDPG | ||||
SAC | ||||
TD3 | ||||
TRPO |
See https://github.com/maximecb/gym-minigrid A simple, lightweight and fast Gym environments implementation of the famous gridworld.
RL Algo | Empty | FourRooms | DoorKey | MultiRoom | Fetch |
---|---|---|---|---|---|
A2C | |||||
PPO | |||||
DDPG | |||||
SAC | |||||
TRPO |
There are 19 environment groups (variations for each) in total.
Note that you need to specify --gym-packages gym_minigrid with enjoy.py and train.py as it is not a standard Gym environment, as well as installing the custom Gym package module or putting it in python path.
pip install gym-minigrid
python train.py --algo ppo --env MiniGrid-DoorKey-5x5-v0 --gym-packages gym_minigrid
This does the same thing as:
import gym_minigrid
Also, you may need to specify a Gym environment wrapper in hyperparameters, as MiniGrid environments have Dict observation space, which is not supported by StableBaselines for now.
MiniGrid-DoorKey-5x5-v0:
env_wrapper: gym_minigrid.wrappers.FlatObsWrapper
You can train agents online using colab notebook.
Min version: stable-baselines3[extra] >= 0.6.0
apt-get install swig cmake ffmpeg
pip install -r requirements.txt
Please see Stable Baselines3 README for alternatives.
Build docker image (CPU):
make docker-cpu
GPU:
USE_GPU=True make docker-gpu
Pull built docker image (CPU):
docker pull stablebaselines/rl-baselines3-zoo-cpu
GPU image:
docker pull stablebaselines/rl-baselines3-zoo
Run script in the docker image:
./scripts/run_docker_cpu.sh python train.py --algo ppo --env CartPole-v1
To run tests, first install pytest, then:
make pytest
Same for type checking with pytype:
make type
To cite this repository in publications:
@misc{rl-zoo3,
author = {Raffin, Antonin},
title = {RL Baselines3 Zoo},
year = {2020},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/DLR-RM/rl-baselines3-zoo}},
}
If you trained an agent that is not present in the rl zoo, please submit a Pull Request (containing the hyperparameters and the score too).
We would like to thanks our contributors: @iandanforth, @tatsubori @Shade5