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Generalising Multi-Agent Cooperation through Task-Agnostic Communication

This is the Python code for reproducing the experiments in the corresponding paper which is currently under review at Distributed Autonomous Robotic Systems (DARS 2024).

Setup

Please make sure you have:

  • Python 3.10+
  • CUDA GPU(s)

Start by cloning the repository and submodules, then enter the top-level directory:

git clone --recurse-submodules <>.git && cd marl-comms-optimisation

Set WANDB_ENTITY and WANDB_PROJECT for wandb logging in config.py

Each MARL suite requires its own setup. Use the relevant virtual environment for running the associated experiments.

Running VMAS Experiments

VMAS Setup

  1. Create a new virtual environment

    python -m venv vmas_env && source vmas_env/bin/activate

  2. Install dependencies

    pip install -r requirements_vmas.txt

  3. Create directories to store weights and samples

    mkdir weights && mkdir samples

In the sections that follow, substitute <task> with one of norm_discovery, norm_swarm, norm_flocking.

Collecting pre-training data

Uniformly randomly sample 1M observations from the observation space of Discovery or Swarm.

python sample_vmas.py --scenario <task> --steps 1000000 --random --device cpu

The results will be saved to samples/<task>_<time>.pt

Note: You can modify the number of agents you collect results for using the relevant task entry in scenario_config.py.

Training a task-agnostic comms strategy offline

Note: --latent is the expected latent dimension of the set autoencoder. To reproduce our work, this should be equal agent observation dim * no. of agents.

python train_sae.py --scenario <task> --latent <> --data samples/<task>_<time>.pt

A state dict is saved every 2000 steps to weights/sae_<task>_<epoch>_<time>.pt and weights/sae_<task>_latest.pt.

Note: if you have multiple samples (e.g. if you want to train a strategy for 1, 2, and 3 agents), then use train_sae_scaling.py instead, specifying a list like --data sample1.pt sample2.pt sample3.pt.

Training a task-specific comms strategy on-policy

Note: --pisa_dim <> is the dimension of each individual agent observation expected by the autoencoder.

python policy.py --train_specific --scenario <task> --pisa_dim <> --seed <> --home

As this policy trains, the learned task-specific communication strategy will be saved to weights/sae_policy_wk<worker_index>_<time>.pt every --eval_interval steps.

Testing comms strategies on-policy

Training stats should be saved to ~/ray_results where they can be viewed with tensorboard --logdir ~/ray_results

No-comms:

python policy.py --no_comms --scenario <task> --pisa_dim <> --seed <> --home

Task-agnostic:

python policy.py --task_agnostic --scenario <task> --pisa_dim <> --pisa_path weights/sae_<task>_latest.pt --seed <> --home

Task-specific:

python policy.py --task_specific --scenario <task> --pisa_dim <> --pisa_path weights/sae_policy_wk<worker_index>_<time>.pt --seed <> --home

Note: If you wish to train a policy with a different number of agents than the default (e.g. to test out-of-distribution performance of comms strategies), then specify --scaling_agents <> with the number of agents you wish to use.

Running Melting Pot Experiments

The instruction for this section are very similar to running the VMAS experiments above.

Melting Pot Setup

  1. Change directory to the Melting Pot folder

    cd meltingpot-marlcomms

  2. Create a new virtual environment

    python -m venv mp_env && source mp_venv/bin/activate

  3. Install dependencies

    pip install -r requirements_mp.txt && pip install -e .

  4. Create directories to store weights and samples

    mkdir weights && mkdir samples

Collecting pre-training data

Uniformly randomly sample 1M observations from the observation space of Discovery or Swarm.

python sample_meltingpot.py --scenario <task> --steps 1000000

The results will be saved to samples/<task>_<time>.pt

Training the image encoder

python train_cnn.py --scenario <task> --data_path samples/<task>_<time>.pt --image_width <>

Weights will be saved periodically to weights/cnn_<task>_best.pt.

Training a task-agnostic comms strategy offline

Note: --latent is the expected latent dimension of the set autoencoder. To reproduce our work, this should be equal agent observation dim * no. of agents.

python train_pisa.py --scenario <task> --data_path samples/<task>_<time>.pt --cnn_path weights/cnn_<task>_best.pt

Weights will be saved periodically to weights/pisa_<task>_best.pt

Training a task-specific comms strategy on-policy

Note: --pisa_dim <> is the dimension of each individual agent observation expected by the set autoencoder.

python policy_mp.py --train_specific --scenario <task> --cnn_path weights/cnn_<task>_best.pt --pisa_dim <> --seed <>

As this policy trains, the learned task-specific communication strategy will be saved to weights/pisa_policy_wk<worker_index>_<time>.pt every eval_interval steps.

Testing comms strategies on-policy

Training stats should be saved to ~/ray_results where they can be viewed with tensorboard --logdir ~/ray_results

No-comms:

python policy_mp.py --no_comms --scenario <task> --cnn_path weights/cnn_<task>_best.pt --pisa_dim <> --seed <>

Task-agnostic:

python policy_mp.py --task_agnostic --scenario <task> --cnn_path weights/cnn_<task>_best.pt --pisa_dim <> --pisa_path weights/pisa_<task>_best.pt --seed <>

Task-specific:

python policy_mp.py --task_specific --scenario <task> --cnn_path weights/cnn_<task>_best.pt --pisa_dim <> --pisa_path weights/pisa_policy_wk<worker_index>_<time>.pt --seed <>

Troubleshooting

If you have problems installing dmlab2d, please see instructions at https://github.com/google-deepmind/lab2d to build it from source.

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Task-Agnostic Communication for Multi-Agent Reinforcement Learning

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