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The multi-agent version of TORCS for developing control algorithms for fully autonomous driving in the cluttered, multi-agent settings of everyday life.

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MADRaS - Multi-Agent DRiving Simulator

This is a multi-agent version of TORCS, for multi-agent reinforcement learning. In other words, the multiple cars running simultaneously on a track can be controlled by different control algorithms - heuristic, reinforcement learning-based, etc.

Please check out the updated version of MADRaS here!

Dependencies

  • TORCS (the simulator)
  • Simulated Car Racing modules (the patch which creates a server-client model to expose the higher-level game features to the learning agent)
  • Python3 (all future development will be in Python3; an old Python2 branch also exists here)

Installation

It is assumed that you have TORCS installed (tested on version 1.3.6) from the source code on a machine with Ubuntu 14.04/16.04 LTS.

scr-client

Install the scr-client as follows:

  1. Download the scr-patch from here.
  2. Unpack the package scr-linux-patch.tgz in your base TORCS directory.
  3. This will create a new directory called scr-patch.
    cd scr-patch
  4. sh do_patch.sh (do_unpatch.sh to revert the modifications)
  5. Move to the parent TORCS directory
    cd ../
  6. Run the following commands:
    ./configure    
    make -j4    
    sudo make install -j4    
    sudo make datainstall -j4    
    

10 scr_server car should be available in the race configurations now.

  1. Download the C++ client from here.
  2. Unpack the package scr-client-cpp.tgz in your base TORCS directory.
  3. This will create a new directory called scr-client-cpp.
    cd scr-client-cpp
  4. make -j4
  5. At this point, multiple clients can join an instance of the TORCS game by:
    ./client    
    ./client port:3002
    
    Typical values are between 3001 and 3010 (3001 is the default)

Usage:

  1. Start a 'Quick Race' in TORCS in one terminal console (with the n agents being scr_*)
    torcs
    Close the TORCS window.
  2. From inside the multi-agent-torcs directory in one console:
    python3 playGame.py 3001
  3. From another console:
    python3 playGame.py 3002
    And so on...

In the game loop in playGame.py, the action at every timestep a_t can be supplied by any algorithm.

Note :

  1. playGame_DDPG.py has the code for a sample RL agent learning with the DDPG algorithm, while playGame.py has a dummy agent which just moves straight at every timestep.
  2. Headless rendering for multiple-agent learning is under development. Contributions and ideas would be greatly appreaciated!

For single-agent learning:

  1. Start a 'Quick Race' in TORCS in one terminal console. Choose only one scr car and as many as traffic cars as you want (preferably chenyi*1, since they're programmed to follow individual lanes at speeds low enough for the agent to learn to overtake)
  2. From inside the multi-agent-torcs directory in one console:
    python3 playGame_DDPG.py 3001
    or any other port.

Sample results for a DDPG agent learned to drive in traffic are available here.


Do check out the wiki for this project for in-depth information about TORCS and getting Deep (Reinforcement) Learning to work on it.


1 The chenyi* cars can be installed from Princeton's DeepDrive project, which also adds a few maps from training and testing the agents. The default cars in TORCS are all programmed heuristic racing agents, which do not serve as good stand-ins for 'traffic'. Hence, using chenyi's code is highly recommended.

Credits

The multi-agent learning simulator was developed by Abhishek Naik, extending ugo-nama-kun's gym-torcs, and yanpanlau's project under the guidance of Anirban Santara, Balaraman Ravindran, and Bharat Kaul, at Intel Labs.

Contributors

We believe MADRaS will enable new and veteran researchers in academia and the industry to make the dream of fully autonomous driving a reality. Towards the same, we believe that unlike the closed-source secretive technologies of the big players, this project will enable the community to work towards this goal together, pooling in thoughts and resources to achieve this dream faster. Hence, we're highly appreciative of all sorts of contributions, big or small, from fellow researchers and users :

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The multi-agent version of TORCS for developing control algorithms for fully autonomous driving in the cluttered, multi-agent settings of everyday life.

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