RLs: Reinforcement Learning Algorithm Based On PyTorch.
This project includes SOTA or classic reinforcement learning (single and multi-agent) algorithms used for training agents by interacting with Unity through ml-agents Release 18 or with gym.
The goal of this framework is to provide stable implementations of standard RL algorithms and simultaneously enable fast prototyping of new methods. It aims to fill the need for a small, easily grokked codebase in which users can freely experiment with wild ideas (speculative research).
This project supports:
- Suitable for Windows, Linux, and OSX
- Single- and Multi-Agent training.
- Multiple type of observation sensors as input.
- Only need 3 steps to implement a new algorithm:
- policy write
.py
inrls/algorithms/{single/multi}
directory and make the policy inherit from super-class defined inrls/algorithms/base
- config write
.yaml
inrls/configs/algorithms/
directory and specify the super config type defined inrls/configs/algorithms/general.yaml
- register register new algorithm in
rls/algorithms/__init__.py
- policy write
- Only need 3 steps to adapt to a new training environment:
- wrapper write environment wrappers in
rls/envs/{new platform}
directory and make it inherit from super-class defined inrls/envs/env_base.py
- config write default configuration in
rls/configs/{new platform}
- register register new environment platform in
rls/envs/__init__.py
- wrapper write environment wrappers in
- Compatible with several environment platforms
- Unity3D ml-agents.
- PettingZoo
- gym, for now only two data types are compatibleββ
[Box, Discrete]
. Support parallel training using gym envs, just need to specify--copies
to how many agents you want to train in parallel.- environments:
- MuJoCo(v2.0.2.13)
- PyBullet
- gym_minigrid
- observation -> action:
- Discrete -> Discrete (observation type -> action type)
- Discrete -> Box
- Box -> Discrete
- Box -> Box
- Box/Discrete -> Tuple(Discrete, Discrete, Discrete)
- environments:
- Four types of Replay Buffer, Default is ER:
- Noisy Net for better exploration.
- Intrinsic Curiosity Module for almost all off-policy algorithms implemented.
- Parallel training multiple scenes for Gym
- Unified data format
method 1:
$ git clone https://github.com/StepNeverStop/RLs.git
$ cd RLs
$ conda create -n rls python=3.8
$ conda activate rls
# Windows
$ pip install -e .[windows]
# Linux or Mac OS
$ pip install -e .
method 1:
conda env create -f environment.yaml
If using ml-agents:
$ pip install -e .[unity]
You can download the builded docker image from here:
$ docker pull keavnn/rls:latest
If anyone who wants to send a PR, plz format all code-files first:
$ pip install -e .[pr]
$ python auto_format.py -d ./
For now, these algorithms are available:
- Multi-Agent training algorithms:
- Independent-SARL, i.e. IQL, I-DQN, etc.
- Value-Decomposition Networks, VDN
- Monotonic Value Function Factorisation Networks, QMIX
- Multi-head Attention based Q-value Mixing Network, Qatten
- Factorize with Transformation, Qtran
- Duplex Dueling Multi-Agent Q-Learning, QPLEX
- Multi-Agent Deep Deterministic Policy Gradient, MADDPG
- Single-Agent training algorithms(Some algorithms that only support continuous space problems use Gumbel-softmax trick
to implement discrete versions, i.e. DDPG):
- Policy Gradient, PG
- Actor Critic, AC
- Synchronous Advantage Actor Critic, A2C
- π₯Proximal Policy Optimization, PPO , DPPO
- Trust Region Policy Optimization, TRPO
- Natural Policy Gradient, NPG
- Deterministic Policy Gradient, DPG
- Deep Deterministic Policy Gradient, DDPG
- π₯Soft Actor Critic, SAC, Discrete SAC
- Tsallis Actor Critic, TAC
- π₯Twin Delayed Deep Deterministic Policy Gradient, TD3
- Deep Q-learning Network, DQN, 2013 , 2015
- Double Deep Q-learning Network, DDQN
- Dueling Double Deep Q-learning Network, DDDQN
- Deep Recurrent Q-learning Network, DRQN
- Deep Recurrent Double Q-learning, DRDQN
- Category 51, C51
- Quantile Regression DQN, QR-DQN
- Implicit Quantile Networks, IQN
- Rainbow DQN
- MaxSQN
- Soft Q-Learning, SQL
- Bootstrapped DQN
- Averaged DQN
- Hierachical training algorithms:
- Model-based algorithms:
- Offline algorithms(under implementation):
- Conservative Q-Learning for Offline Reinforcement Learning, CQL
- BCQ
- Benchmarking Batch Deep Reinforcement Learning Algorithms, Discrete
- Off-Policy Deep Reinforcement Learning without Exploration, Continuous
Algorithms | Discrete | Continuous | Image | RNN | Command parameter |
---|---|---|---|---|---|
PG | β | β | β | β | pg |
AC | β | β | β | β | ac |
A2C | β | β | β | β | a2c |
NPG | β | β | β | β | npg |
TRPO | β | β | β | β | trpo |
PPO | β | β | β | β | ppo |
DQN | β | β | β | dqn | |
Double DQN | β | β | β | ddqn | |
Dueling Double DQN | β | β | β | dddqn | |
Averaged DQN | β | β | β | averaged_dqn | |
Bootstrapped DQN | β | β | β | bootstrappeddqn | |
Soft Q-Learning | β | β | β | sql | |
C51 | β | β | β | c51 | |
QR-DQN | β | β | β | qrdqn | |
IQN | β | β | β | iqn | |
Rainbow | β | β | β | rainbow | |
DPG | β | β | β | β | dpg |
DDPG | β | β | β | β | ddpg |
TD3 | β | β | β | β | td3 |
SAC(has V network) | β | β | β | β | sac_v |
SAC | β | β | β | β | sac |
TAC | sac | β | β | β | tac |
MaxSQN | β | β | β | maxsqn | |
OC | β | β | β | β | oc |
AOC | β | β | β | β | aoc |
PPOC | β | β | β | β | ppoc |
IOC | β | β | β | β | ioc |
PlaNet | β | β | 1 | planet | |
Dreamer | β | β | β | 1 | dreamer |
DreamerV2 | β | β | β | 1 | dreamerv2 |
VDN | β | β | β | vdn | |
QMIX | β | β | β | qmix | |
Qatten | β | β | β | qatten | |
QPLEX | β | β | β | qplex | |
QTRAN | β | β | β | qtran | |
MADDPG | β | β | β | β | maddpg |
MASAC | β | β | β | β | masac |
CQL | β | β | β | cql_dqn | |
BCQ | β | β | β | β | bcq |
MVE | β | β | mve |
1 means must use rnn or rnn is used by default.
"""
usage: run.py [-h] [-c COPIES] [--seed SEED] [-r]
[-p {gym,unity,pettingzoo}]
[-a {maddpg,masac,vdn,qmix,qatten,qtran,qplex,aoc,ppoc,oc,ioc,planet,dreamer,dreamerv2,mve,cql_dqn,bcq,pg,npg,trpo,ppo,a2c,ac,dpg,ddpg,td3,sac_v,sac,tac,dqn,ddqn,dddqn,averaged_dqn,c51,qrdqn,rainbow,iqn,maxsqn,sql,bootstrappeddqn}]
[-i] [-l LOAD_PATH] [-m MODELS] [-n NAME]
[--config-file CONFIG_FILE] [--store-dir STORE_DIR]
[--episode-length EPISODE_LENGTH] [--hostname] [-e ENV_NAME]
[-f FILE_NAME] [-s] [-d DEVICE] [-t MAX_TRAIN_STEP]
optional arguments:
-h, --help show this help message and exit
-c COPIES, --copies COPIES
nums of environment copies that collect data in
parallel
--seed SEED specify the random seed of module random, numpy and
pytorch
-r, --render whether render game interface
-p {gym,unity,pettingzoo}, --platform {gym,unity,pettingzoo}
specify the platform of training environment
-a {maddpg,masac,vdn,qmix,qatten,qtran,qplex,aoc,ppoc,oc,ioc,planet,dreamer,dreamerv2,mve,cql_dqn,bcq,pg,npg,trpo,ppo,a2c,ac,dpg,ddpg,td3,sac_v,sac,tac,dqn,ddqn,dddqn,averaged_dqn,c51,qrdqn,rainbow,iqn,maxsqn,sql,bootstrappeddqn}, --algorithm {maddpg,masac,vdn,qmix,qatten,qtran,qplex,aoc,ppoc,oc,ioc,planet,dreamer,dreamerv2,mve,cql_dqn,bcq,pg,npg,trpo,ppo,a2c,ac,dpg,ddpg,td3,sac_v,sac,tac,dqn,ddqn,dddqn,averaged_dqn,c51,qrdqn,rainbow,iqn,maxsqn,sql,bootstrappeddqn}
specify the training algorithm
-i, --inference inference the trained model, not train policies
-l LOAD_PATH, --load-path LOAD_PATH
specify the name of pre-trained model that need to
load
-m MODELS, --models MODELS
specify the number of trails that using different
random seeds
-n NAME, --name NAME specify the name of this training task
--config-file CONFIG_FILE
specify the path of training configuration file
--store-dir STORE_DIR
specify the directory that store model, log and
others
--episode-length EPISODE_LENGTH
specify the maximum step per episode
--hostname whether concatenate hostname with the training name
-e ENV_NAME, --env-name ENV_NAME
specify the environment name
-f FILE_NAME, --file-name FILE_NAME
specify the path of builded training environment of
UNITY3D
-s, --save specify whether save models/logs/summaries while
training or not
-d DEVICE, --device DEVICE
specify the device that operate Torch.Tensor
-t MAX_TRAIN_STEP, --max-train-step MAX_TRAIN_STEP
specify the maximum training steps
"""
Example:
python run.py -s # save model and log while train
python run.py -p gym -a dqn -e CartPole-v0 -c 12 -n dqn_cartpole
python run.py -p unity -a ppo -n run_with_unity -c 1
The main training loop of pseudo-code in this repo is as:
# noinspection PyUnresolvedReferences
agent.episode_reset() # initialize rnn hidden state or something else
# noinspection PyUnresolvedReferences
obs = env.reset()
while True:
# noinspection PyUnresolvedReferences
env_rets = env.step(agent(obs))
# noinspection PyUnresolvedReferences
agent.episode_step(obs, env_rets) # store experience, save model, and train off-policy algorithms
obs = env_rets['obs']
if env_rets['done']:
break
# noinspection PyUnresolvedReferences
agent.episode_end() # train on-policy algorithms
If using this repository for your research, please cite:
@misc{RLs,
author = {Keavnn},
title = {RLs: A Featureless Reinforcement Learning Repository},
year = {2019},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/StepNeverStop/RLs}},
}
Any questions/errors about this project, please let me know in here.