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Introducing ⚔️ AI vs. AI ⚔️ a deep reinforcement learning multi-agents competition system
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CarlCochet
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ThomasSimonini

Introducing ⚔️ AI vs. AI ⚔️ a deep reinforcement learning multi-agents competition system

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We’re excited to introduce a new tool we created: ⚔️ AI vs. AI ⚔️, a deep reinforcement learning multi-agents competition system.

This tool, hosted on Spaces, allows us to create multi-agent competitions. It is composed of three elements:

  • A Space with a matchmaking algorithm that runs the model fights using a background task.
  • A Dataset containing the results.
  • A Leaderboard that gets the match history results and displays the models’ ELO.

Then, when a user pushes a trained model to the Hub, it gets evaluated and ranked against others. Thanks to that, we can evaluate your agents against other’s agents in a multi-agent setting.

In addition to being a useful tool for hosting multi-agent competitions, we think this tool can also be a robust evaluation technique in multi-agent settings. By playing against a lot of policies, your agents are evaluated against a wide range of behaviors. This should give you a good idea of the quality of your policy.

Let’s see how it works with our first competition host: SoccerTwos Challenge.

SoccerTwos example

How does AI vs. AI works?

AI vs. AI is an open-source tool developed at Hugging Face to rank the strength of reinforcement learning models in a multi-agent setting.

The idea is to get a relative measure of skill rather than an objective one by making the models play against each other continuously and use the matches results to assess their performance compared to all the other models and consequently get a view of the quality of their policy without requiring classic metrics.

The more agents are submitted for a given task or environment, the more representative the rating becomes.

To generate a rating based on match results in a competitive environment, we decided to base the rankings on the ELO rating system.

The core concept is that after a match ends, the rating of both players are updated based on the result and the ratings they had before the game. When a user with a high rating beats one with a low ranking, they won't get many points. Likewise, the loser would not lose many points in this case.

Conversely, if a low-rated player wins in an upset against a high-rated player, it will cause a more significant effect on both of their ratings.

In our context, we kept the system as simple as possible by not adding any alteration to the quantities gained or lost based on the starting ratings of the player. As such, gain and loss will always be the perfect opposite (+10 / -10, for instance), and the average ELO rating will stay constant at the starting rating. The choice of a 1200 ELO rating start is entirely arbitrary.

If you want to learn more about ELO and see some calculation example, we wrote an explanation in our Deep Reinforcement Learning Course here

Using this rating, it is possible to generate matches between models with comparable strengths automatically. There are several ways you can go about creating a matchmaking system, but here we decided to keep it fairly simple while guaranteeing a minimum amount of diversity in the matchups and also keeping most matches with fairly close opposing ratings.

AI vs AI Process

Here's how works the algorithm:

  1. Gather all the available models on the Hub. New models get a starting rating of 1200, while others keep the rating they have gained/lost through their previous matches.
  2. Create a queue from all these models.
  3. Pop the first element (model) from the queue, and then pop another random model in this queue from the n models with the closest ratings to the first model.
  4. Simulate this match by loading both models in the environment (a Unity executable, for instance) and gathering the results. For this implementation, we sent the results to a Hugging Face Dataset on the Hub.
  5. Compute the new rating of both models based on the received result and the ELO formula.
  6. Continue popping models two by two and simulating the matches until only one or zero models are in the queue.
  7. Save the resulting ratings and go back to step 1

To run this matchmaking process continuously, we use free Hugging Face Spaces hardware with a Scheduler to keep running the matchmaking process as a background task.

The Spaces is also used to fetch the ELO ratings of each model that have already been played and, from it display a leaderboard from which everyone can check the progress of the models.

Leaderboard

The process generally uses several Hugging Face Datasets to provide data persistence (here, matches history and model ratings).

Since the process also saves the matches' history, it is possible to see precisely the results of any given model. This can, for instance, allow you to check why your model struggles with another one, most notably using another demo Space to visualize matches like this one.

For now, this experiment is running with the MLAgent environment SoccerTwos for the Hugging Face Deep RL Course, however, the process and implementation, in general, are very much environment agnostic and could be used to evaluate for free a wide range of adversarial multi-agent settings.

Of course, it is important to remind again that this evaluation is a relative rating between the strengths of the submitted agents, and the ratings by themselves have no objective meaning contrary to other metrics. It only represents how good or bad a model performs compared to the other models in the pool. Still, given a large and varied enough pool of models (and enough matches played), this evaluation becomes a very solid way to represent the general performance of a model.

Our first AI vs. AI challenge experimentation: SoccerTwos Challenge ⚽

This challenge is Unit 7 of our free Deep Reinforcement Learning Course. It started on February 1st and will end on April 30th.

If you’re interested, you don’t need to participate in the course to be able to participate in the competition. You can start here 👉 https://huggingface.co/deep-rl-course/unit7/introduction

In this Unit, readers learned the basics of multi-agent reinforcement learning (MARL)by training a 2vs2 soccer team.

The environment used was made by the Unity ML-Agents team. The goal is simple: your team needs to score a goal. To do that, they need to beat the opponent's team and collaborate with their teammate.

SoccerTwos example

In addition to the leaderboard, we created a Space demo where people can choose two teams and visualize them playing 👉https://huggingface.co/spaces/unity/SoccerTwos

This experimentation is going well since we already have 48 models on the leaderboard Leaderboard

We also created a discord channel called ai-vs-ai-competition so that people can exchange with others and share advice.

Conclusion and what’s next?

Since the tool we developed is environment agnostic, we want to host more challenges in the future with PettingZoo and other multi-agent environments. If you have some environments or challenges you want to do, don’t hesitate to reach out to us.

In the future, we will host multiple multi-agent competitions with this tool and environments we created, such as SnowballFight.

Snowballfight gif

In addition to being a useful tool for hosting multi-agent competitions, we think that this tool can also be a robust evaluation technique in multi-agent settings: by playing against a lot of policies, your agents are evaluated against a wide range of behaviors, and you’ll get a good idea of the quality of your policy.

The best way to keep in touch is to join our discord server to exchange with us and with the community.

Citation

Citation: If you found this useful for your academic work, please consider citing our work, in text:

Cochet, Simonini, "Introducing AI vs. AI a deep reinforcement learning multi-agents competition system", Hugging Face Blog, 2023.

BibTeX citation:

@article{cochet-simonini2023,
  author = {Cochet, Carl and Simonini, Thomas},
  title = {Introducing AI vs. AI a deep reinforcement learning multi-agents competition system},
  journal = {Hugging Face Blog},
  year = {2023},
  note = {https://huggingface.co/blog/aivsai},
}