/softlearning

Softlearning is a reinforcement learning framework for training maximum entropy policies in continuous domains. Includes the official implementation of the Soft Actor-Critic algorithm.

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Softlearning

Softlearning is a deep reinforcement learning toolbox for training maximum entropy policies in continuous domains. The implementation is fairly thin and primarily optimized for our own development purposes. It utilizes the tf.keras modules for most of the model classes (e.g. policies and value functions). We use Ray for the experiment orchestration. Ray Tune and Autoscaler implement several neat features that enable us to seamlessly run the same experiment scripts that we use for local prototyping to launch large-scale experiments on any chosen cloud service (e.g. GCP or AWS), and intelligently parallelize and distribute training for effective resource allocation.

This implementation uses Tensorflow. For a PyTorch implementation of soft actor-critic, take a look at rlkit.

Getting Started

Prerequisites

The environment can be run either locally using conda or inside a docker container. For conda installation, you need to have Conda installed. For docker installation you will need to have Docker and Docker Compose installed. Also, most of our environments currently require a MuJoCo license.

Conda Installation

  1. Download and install MuJoCo 1.50 and 2.00 from the MuJoCo website. We assume that the MuJoCo files are extracted to the default location (~/.mujoco/mjpro150 and ~/.mujoco/mujoco200_{platform}). Unfortunately, gym and dm_control expect different paths for MuJoCo 2.00 installation, which is why you will need to have it installed both in ~/.mujoco/mujoco200_{platform} and ~/.mujoco/mujoco200. The easiest way is to create a symlink from ~/.mujoco/mujoco200_{plaftorm} -> ~/.mujoco/mujoco200 with: ln -s ~/.mujoco/mujoco200_{platform} ~/.mujoco/mujoco200.

  2. Copy your MuJoCo license key (mjkey.txt) to ~/.mujoco/mjkey.txt:

  3. Clone softlearning

git clone https://github.com/rail-berkeley/softlearning.git ${SOFTLEARNING_PATH}
  1. Create and activate conda environment, install softlearning to enable command line interface.
cd ${SOFTLEARNING_PATH}
conda env create -f environment.yml
conda activate softlearning
pip install -e ${SOFTLEARNING_PATH}
  1. (Lance) Run the following instructions:
export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/home/lance_chao/.mujoco/mujoco210/bin
export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/usr/lib/nvidia
pip install "cython<3"
pip install robosuite

The environment should be ready to run. See examples section for examples of how to train and simulate the agents.

Finally, to deactivate and remove the conda environment:

conda deactivate
conda remove --name softlearning --all

Docker Installation

docker-compose

To build the image and run the container:

export MJKEY="$(cat ~/.mujoco/mjkey.txt)" \
    && docker-compose \
        -f ./docker/docker-compose.dev.cpu.yml \
        up \
        -d \
        --force-recreate

You can access the container with the typical Docker exec-command, i.e.

docker exec -it softlearning bash

See examples section for examples of how to train and simulate the agents.

Finally, to clean up the docker setup:

docker-compose \
    -f ./docker/docker-compose.dev.cpu.yml \
    down \
    --rmi all \
    --volumes

Examples

Training and simulating an agent

  1. To train the agent
softlearning run_example_local examples.development \
    --algorithm SAC \
    --universe gym \
    --domain HalfCheetah \
    --task v3 \
    --exp-name my-sac-experiment-1 \
    --checkpoint-frequency 1000  # Save the checkpoint to resume training later
  1. To simulate the resulting policy: First, find the absolute path that the checkpoint is saved to. By default (i.e. without specifying the log-dir argument to the previous script), the data is saved under ~/ray_results/<universe>/<domain>/<task>/<datatimestamp>-<exp-name>/<trial-id>/<checkpoint-id>. For example: ~/ray_results/gym/HalfCheetah/v3/2018-12-12T16-48-37-my-sac-experiment-1-0/mujoco-runner_0_seed=7585_2018-12-12_16-48-37xuadh9vd/checkpoint_1000/. The next command assumes that this path is found from ${SAC_CHECKPOINT_DIR} environment variable.
python -m examples.development.simulate_policy \
    ${SAC_CHECKPOINT_DIR} \
    --max-path-length 1000 \
    --num-rollouts 1 \
    --render-kwargs '{"mode": "human"}'

examples.development.main contains several different environments and there are more example scripts available in the /examples folder. For more information about the agents and configurations, run the scripts with --help flag: python ./examples/development/main.py --help

optional arguments:
  -h, --help            show this help message and exit
  --universe {robosuite,dm_control,gym}
  --domain DOMAIN
  --task TASK
  --checkpoint-replay-pool CHECKPOINT_REPLAY_POOL
                        Whether a checkpoint should also saved the replay
                        pool. If set, takes precedence over
                        variant['run_params']['checkpoint_replay_pool']. Note
                        that the replay pool is saved (and constructed) piece
                        by piece so that each experience is saved only once.
  --algorithm ALGORITHM
  --policy {gaussian}
  --exp-name EXP_NAME
  --mode MODE
  --run-eagerly RUN_EAGERLY
                        Whether to run tensorflow in eager mode.
  --local-dir LOCAL_DIR
                        Destination local folder to save training results.
  --confirm-remote [CONFIRM_REMOTE]
                        Whether or not to query yes/no on remote run.
  --video-save-frequency VIDEO_SAVE_FREQUENCY
                        Save frequency for videos.
  --cpus CPUS           Cpus to allocate to ray process. Passed to `ray.init`.
  --gpus GPUS           Gpus to allocate to ray process. Passed to `ray.init`.
  --resources RESOURCES
                        Resources to allocate to ray process. Passed to
                        `ray.init`.
  --include-webui INCLUDE_WEBUI
                        Boolean flag indicating whether to start theweb UI,
                        which is a Jupyter notebook. Passed to `ray.init`.
  --temp-dir TEMP_DIR   If provided, it will specify the root temporary
                        directory for the Ray process. Passed to `ray.init`.
  --resources-per-trial RESOURCES_PER_TRIAL
                        Resources to allocate for each trial. Passed to
                        `tune.run`.
  --trial-cpus TRIAL_CPUS
                        CPUs to allocate for each trial. Note: this is only
                        used for Ray's internal scheduling bookkeeping, and is
                        not an actual hard limit for CPUs. Passed to
                        `tune.run`.
  --trial-gpus TRIAL_GPUS
                        GPUs to allocate for each trial. Note: this is only
                        used for Ray's internal scheduling bookkeeping, and is
                        not an actual hard limit for GPUs. Passed to
                        `tune.run`.
  --trial-extra-cpus TRIAL_EXTRA_CPUS
                        Extra CPUs to reserve in case the trials need to
                        launch additional Ray actors that use CPUs.
  --trial-extra-gpus TRIAL_EXTRA_GPUS
                        Extra GPUs to reserve in case the trials need to
                        launch additional Ray actors that use GPUs.
  --num-samples NUM_SAMPLES
                        Number of times to repeat each trial. Passed to
                        `tune.run`.
  --upload-dir UPLOAD_DIR
                        Optional URI to sync training results to (e.g.
                        s3://<bucket> or gs://<bucket>). Passed to `tune.run`.
  --trial-name-template TRIAL_NAME_TEMPLATE
                        Optional string template for trial name. For example:
                        '{trial.trial_id}-seed={trial.config[run_params][seed]
                        }' Passed to `tune.run`.
  --checkpoint-frequency CHECKPOINT_FREQUENCY
                        How many training iterations between checkpoints. A
                        value of 0 (default) disables checkpointing. If set,
                        takes precedence over
                        variant['run_params']['checkpoint_frequency']. Passed
                        to `tune.run`.
  --checkpoint-at-end CHECKPOINT_AT_END
                        Whether to checkpoint at the end of the experiment. If
                        set, takes precedence over
                        variant['run_params']['checkpoint_at_end']. Passed to
                        `tune.run`.
  --max-failures MAX_FAILURES
                        Try to recover a trial from its last checkpoint at
                        least this many times. Only applies if checkpointing
                        is enabled. Passed to `tune.run`.
  --restore RESTORE     Path to checkpoint. Only makes sense to set if running
                        1 trial. Defaults to None. Passed to `tune.run`.
  --server-port SERVER_PORT
                        Port number for launching TuneServer. Passed to
                        `tune.run`.

Resume training from a saved checkpoint

This feature is currently broken!

In order to resume training from previous checkpoint, run the original example main-script, with an additional --restore flag. For example, the previous example can be resumed as follows:

softlearning run_example_local examples.development \
    --algorithm SAC \
    --universe gym \
    --domain HalfCheetah \
    --task v3 \
    --exp-name my-sac-experiment-1 \
    --checkpoint-frequency 1000 \
    --restore ${SAC_CHECKPOINT_PATH}

References

The algorithms are based on the following papers:

Soft Actor-Critic Algorithms and Applications.
Tuomas Haarnoja*, Aurick Zhou*, Kristian Hartikainen*, George Tucker, Sehoon Ha, Jie Tan, Vikash Kumar, Henry Zhu, Abhishek Gupta, Pieter Abbeel, and Sergey Levine. arXiv preprint, 2018.
paper | videos

Latent Space Policies for Hierarchical Reinforcement Learning.
Tuomas Haarnoja*, Kristian Hartikainen*, Pieter Abbeel, and Sergey Levine. International Conference on Machine Learning (ICML), 2018.
paper | videos

Soft Actor-Critic: Off-Policy Maximum Entropy Deep Reinforcement Learning with a Stochastic Actor.
Tuomas Haarnoja, Aurick Zhou, Pieter Abbeel, and Sergey Levine. International Conference on Machine Learning (ICML), 2018.
paper | videos

Composable Deep Reinforcement Learning for Robotic Manipulation.
Tuomas Haarnoja, Vitchyr Pong, Aurick Zhou, Murtaza Dalal, Pieter Abbeel, Sergey Levine. International Conference on Robotics and Automation (ICRA), 2018.
paper | videos

Reinforcement Learning with Deep Energy-Based Policies.
Tuomas Haarnoja*, Haoran Tang*, Pieter Abbeel, Sergey Levine. International Conference on Machine Learning (ICML), 2017.
paper | videos

If Softlearning helps you in your academic research, you are encouraged to cite our paper. Here is an example bibtex:

@techreport{haarnoja2018sacapps,
  title={Soft Actor-Critic Algorithms and Applications},
  author={Tuomas Haarnoja and Aurick Zhou and Kristian Hartikainen and George Tucker and Sehoon Ha and Jie Tan and Vikash Kumar and Henry Zhu and Abhishek Gupta and Pieter Abbeel and Sergey Levine},
  journal={arXiv preprint arXiv:1812.05905},
  year={2018}
}