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SOTA Quest

This is an attempt by a hobbyist working in a resource-constrained context to create state of the art (SOTA) reinforcement learning models using sample factory. An excellent open source framework developed by Alex Petrenko. In essence it allows you to squeeze maximal juice out of your reinforcement learning (RL) hardware. Thus, it is highly valuable to someone like me who doesn't have access to a high-performance compute cluster but does have access to some GPU's.

SOTA Quest Logo: RDS Atari Bot

Understanding Key Concepts

PPO or proximal policy optimisation is a state of the art RL algorithm that looks to build on prior on-policy algorithms like reinforce by adding something called a clip-function. This helps to prevent too-big (destructive) policy updates from occuring which hampered prior algorithms and makes the algorithm very generally useful in a wide variety of settings. PPO is not the 'best' algorithm currently available (see MuZero, Agent 57 and Go-Explore for better examples) but it is very powerful and accessible to hobbyists which is why huggingface have focused on it.

PPO is not very sample efficient in that it requires a lot of examples to learn from. This is why Alex created Sample Factory to try and overcome some of the limitations inherent in more accessible implementations such as SB3 and cleanRL. I am one of the benficiaires of this effort.

Objectives of Project

The aim is to reach SOTA performance in as many environments as I can and learn a lot about RL and particularly on-policy algorithms in the process.

I have started with the Atari 57 environments as they provide a canonical baseline which is both well documented and also express a very general list of capabilities: https://paperswithcode.com/task/atari-games. The big companies are probably starting to move away from these now because they are largely considered 'solved' but there are still some games such as 'Venture' and 'Tutankham' who have been more generally ignored. Additionally games like 'Solaris' and 'Breakout' cannot be considered 'solved' as even SOTA algorithms obtain relatively meagre scores on these games. The best algorithms can only clear the Breakout board twice and then tend to get stuck in loops - a fact that is typically ignored.

Progress So Far

So far I have SOTA completed two of the easier Atari Environments:

Four environments are approaching SOTA performance:

These environments should be considered the generally easier ones to solve as evidenced by the timelines of the papers with code. I will not be able to sota them all (no algorithm can) but I should be able to prove that even a hobbyist can 'do' these things and make significant headway in their spare time. The aim is to achieve at least near SOTA results in at least 25% of the environments by the end of this year. This simply wouldn't be possible without sample-factory and the high performance it brings to the experiments.

Usage Notes

To use this version of sample factory you will need to do the following in order:

git clone https://github.com/MattStammers/sample-factory-sotaquest.git /
cd sample-factory-sotaquest  /
pip install pipenv /
pipenv --python={python version} /
pipenv shell /
pip install --upgrade setuptools pip wheel /
pip install -e . /

You may also need to run the below or a variant of it depending on your GPU setup - making sure the CUDA versions match exactly

pip install nvidia-cuda-runtime-cu11 --index-url https://pypi.ngc.nvidia.com --upgrade --force-reinstall
pip install torch torchvision torchaudio --index-url https://download.pytorch.org/whl/cu118 --upgrade --force-reinstall

Then you can run the script to run the atari games (however you must change your huggingface name and load the CLI credentials for this and WandB first or the models will not push to the hub):

bash ./scripts/atari_algo_runner.sh

Issues

Good luck. Feel free to reach out if you want help as I struggled at the start - feel free to raise an issue. However, the SF documentation is fantastic and explains the framework excellently. Start there first. Alex himself is highly responsive and will be able to answer any questions about the framework himself far better than I ever could. I can likely just help more with newbie questions.

The one thing which confused me initially is the --ALGO flag in the config. This as far as I can tell is just a placeholder which could be implemented if needed but SF is purely for on-policy RF (primarily PPO). There is a way to activate V-trace in the config and thus make the model an IMPALA-PPO model but SF is not designed for off-policy algo's like DQN. My recommendation would be to focus on PPO if like me you are still learning / at the start of your journey.

Sample Factory

High-throughput reinforcement learning codebase. Version 2.0.0 is out! 🤗

Resources:

What is Sample Factory?

Sample Factory is one of the fastest RL libraries. We focused on very efficient synchronous and asynchronous implementations of policy gradients (PPO).

Sample Factory is thoroughly tested, used by many researchers and practitioners, and is actively maintained. Our implementation is known to reach SOTA performance in a variety of domains in a short amount of time. Clips below demonstrate ViZDoom, IsaacGym, DMLab-30, Megaverse, Mujoco, and Atari agents trained with Sample Factory:

VizDoom agents traned using Sample Factory 2.0 IsaacGym agents traned using Sample Factory 2.0
DMLab-30 agents traned using Sample Factory 2.0 Megaverse agents traned using Sample Factory 2.0
Mujoco agents traned using Sample Factory 2.0 Atari agents traned using Sample Factory 2.0

Key features:

This Readme provides only a brief overview of the library. Visit full documentation at https://samplefactory.dev for more details.

Installation

Just install from PyPI:

pip install sample-factory

SF is known to work on Linux and macOS. There is no Windows support at this time. Please refer to the documentation for additional environment-specific installation notes.

Quickstart

Use command line to train an agent using one of the existing integrations, e.g. Mujoco (might need to run pip install sample-factory[mujoco]):

python -m sf_examples.mujoco.train_mujoco --env=mujoco_ant --experiment=Ant --train_dir=./train_dir

Stop the experiment (Ctrl+C) when the desired performance is reached and then evaluate the agent:

python -m sf_examples.mujoco.enjoy_mujoco --env=mujoco_ant --experiment=Ant --train_dir=./train_dir

Do the same in a pixel-based VizDoom environment (might need to run pip install sample-factory[vizdoom], please also see docs for VizDoom-specific instructions):

python -m sf_examples.vizdoom.train_vizdoom --env=doom_basic --experiment=DoomBasic --train_dir=./train_dir --num_workers=16 --num_envs_per_worker=10 --train_for_env_steps=1000000
python -m sf_examples.vizdoom.enjoy_vizdoom --env=doom_basic --experiment=DoomBasic --train_dir=./train_dir

Monitor any running or completed experiment with Tensorboard:

tensorboard --logdir=./train_dir

(or see the docs for WandB integration).

To continue from here, copy and modify one of the existing env integrations to train agents in your own custom environment. We provide examples for all kinds of supported environments, please refer to the documentation for more details.

Acknowledgements

This project would not be possible without amazing contributions from many people. I would like to thank:

  • Vladlen Koltun for amazing guidance and support, especially in the early stages of the project, for helping me solidify the ideas that eventually became this library.
  • My academic advisor Gaurav Sukhatme for supporting this project over the years of my PhD and for being overall an awesome mentor.
  • Zhehui Huang for his contributions to the original ICML submission, his diligent work on testing and evaluating the library and for adopting it in his own research.
  • Edward Beeching for his numerous awesome contributions to the codebase, including hybrid action distributions, new version of the custom model builder, multiple environment integrations, and also for promoting the library through the HuggingFace integration!
  • Andrew Zhang and Ming Wang for numerous contributions to the codebase and documentation during their HuggingFace internships!
  • Thomas Wolf and others at HuggingFace for the incredible (and unexpected) support and for the amazing work they are doing for the open-source community.
  • Erik Wijmans for feedback and insights and for his awesome implementation of RNN backprop using PyTorch's PackedSequence, multi-layer RNNs, and other features!
  • Tushar Kumar for contributing to the original paper and for his help with the fast queue implementation.
  • Costa Huang for developing CleanRL, for his work on benchmarking RL algorithms, and for awesome feedback and insights!
  • Denys Makoviichuk for developing rl_games, a very fast RL library, for inspiration and feedback on numerous features of this library (such as return normalizations, adaptive learning rate, and others).
  • Eugene Vinitsky for adopting this library in his own research and for his valuable feedback.
  • All my labmates at RESL who used Sample Factory in their projects and provided feedback and insights!

Huge thanks to all the people who are not mentioned here for your code contributions, PRs, issues, and questions! This project would not be possible without a community!

Citation

If you use this repository in your work or otherwise wish to cite it, please make reference to our ICML2020 paper.

@inproceedings{petrenko2020sf,
  author    = {Aleksei Petrenko and
               Zhehui Huang and
               Tushar Kumar and
               Gaurav S. Sukhatme and
               Vladlen Koltun},
  title     = {Sample Factory: Egocentric 3D Control from Pixels at 100000 {FPS}
               with Asynchronous Reinforcement Learning},
  booktitle = {Proceedings of the 37th International Conference on Machine Learning,
               {ICML} 2020, 13-18 July 2020, Virtual Event},
  series    = {Proceedings of Machine Learning Research},
  volume    = {119},
  pages     = {7652--7662},
  publisher = {{PMLR}},
  year      = {2020},
  url       = {http://proceedings.mlr.press/v119/petrenko20a.html},
  biburl    = {https://dblp.org/rec/conf/icml/PetrenkoHKSK20.bib},
  bibsource = {dblp computer science bibliography, https://dblp.org}
}

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