Code to reproduce the experiments in When to Trust Your Model: Model-Based Policy Optimization.
- Install MuJoCo 1.50 at
~/.mujoco/mjpro150
and copy your license key to~/.mujoco/mjkey.txt
- Clone
mbpo
git clone --recursive https://github.com/jannerm/mbpo.git
- Create a conda environment and install mbpo
cd mbpo
conda env create -f environment/gpu-env.yml
conda activate mbpo
pip install -e viskit
pip install -e .
Configuration files can be found in examples/config/
.
mbpo run_local examples.development --config=examples.config.halfcheetah.0 --gpus=1 --trial-gpus=1
Currently only running locally is supported.
To run on a different environment, you can modify the provided template. You will also need to provide the termination function for the environment in mbpo/static
. If you name the file the lowercase version of the environment name, it will be found automatically. See hopper.py
for an example.
This codebase contains viskit as a submodule. You can view saved runs with:
viskit ~/ray_mbpo --port 6008
assuming you used the default log_dir
.
The rollout length schedule is defined by a length-4 list in a config file. The format is [start_epoch, end_epoch, start_length, end_length]
, so the following:
'rollout_schedule': [20, 100, 1, 5]
corresponds to a model rollout length linearly increasing from 1 to 5 over epochs 20 to 100.
If you want to speed up training in terms of wall clock time (but possibly make the runs less sample-efficient), you can set a timeout for model training (max_model_t
, in seconds) or train the model less frequently (every model_train_freq
steps).
If you would like to compare to MBPO but do not have the resources to re-run all experiments, the learning curves found in Figure 2 of the paper (plus on the Humanoid environment) are available in this shared folder. See plot.py
for an example of how to read the pickle files with the results.
@inproceedings{janner2019mbpo,
author = {Michael Janner and Justin Fu and Marvin Zhang and Sergey Levine},
title = {When to Trust Your Model: Model-Based Policy Optimization},
booktitle = {Advances in Neural Information Processing Systems},
year = {2019}
}
The underlying soft actor-critic implementation in MBPO comes from Tuomas Haarnoja and Kristian Hartikainen's softlearning codebase. The modeling code is a slightly modified version of Kurtland Chua's PETS implementation.