Reinforcement learning framework and algorithms implemented in PyTorch.
Implemented algorithms:
- Skew-Fit
- example script
- paper
- Documentation
- Requires multiworld to be installed
- Reinforcement Learning with Imagined Goals (RIG)
- See this version of this repository.
- paper
- Temporal Difference Models (TDMs)
- Only implemented in v0.1.2 of RLkit. See Legacy Documentation section below.
- paper
- Documentation
- Hindsight Experience Replay (HER)
- (Double) Deep Q-Network (DQN)
- Soft Actor Critic (SAC)
- example script
- original paper and updated version
- TensorFlow implementation from author
- Includes the "min of Q" method, the entropy-constrained implementation, reparameterization trick, and numerical tanh-Normal Jacbian calcuation.
- Twin Delayed Deep Determinstic Policy Gradient (TD3)
- Advantage Weighted Actor Critic (AWAC)
To get started, checkout the example scripts, linked above.
- Use new
multiworld
code that requires explicit environment registration. - Make installation easier by adding
setup.py
and using defaultconf.py
.
- Log how many train steps were called
- Log
env_info
andagent_info
.
- Add rendering
- Fix SAC bug to account for future entropy (#41, #43)
- Add online algorithm mode (#42)
The initial release for 0.2 has the following major changes:
- Remove
Serializable
class and use default pickle scheme. - Remove
PyTorchModule
class and use nativetorch.nn.Module
directly. - Switch to batch-style training rather than online training.
- Makes code more amenable to parallelization.
- Implementing the online-version is straightforward.
- Refactor training code to be its own object, rather than being integrated
inside of
RLAlgorithm
. - Refactor sampling code to be its own object, rather than being integrated
inside of
RLAlgorithm
. - Implement Skew-Fit: State-Covering Self-Supervised Reinforcement Learning, a method for performing goal-directed exploration to maximize the entropy of visited states.
- Update soft actor-critic to more closely match TensorFlow implementation:
- Rename
TwinSAC
to justSAC
. - Only have Q networks.
- Remove unnecessary policy regualization terms.
- Use numerically stable Jacobian computation.
- Rename
Overall, the refactors are intended to make the code more modular and readable than the previous versions.
- Add RIG implementation
- Add HER implementation
- Add doodad support
- Upgraded to PyTorch v0.4
- Added Twin Soft Actor Critic Implementation
- Various small refactor (e.g. logger, evaluate code)
- Install and use the included Ananconda environment
$ conda env create -f environment/[linux-cpu|linux-gpu|mac]-env.yml
$ source activate rlkit
(rlkit) $ python examples/ddpg.py
Choose the appropriate .yml
file for your system.
These Anaconda environments use MuJoCo 1.5 and gym 0.10.5.
You'll need to get your own MuJoCo key if you want to use MuJoCo.
- Add this repo directory to your
PYTHONPATH
environment variable or simply run:
pip install -e .
- (Optional) Copy
conf.py
toconf_private.py
and edit to override defaults:
cp rlkit/launchers/conf.py rlkit/launchers/conf_private.py
- (Optional) If you plan on running the Skew-Fit experiments or the HER example with the Sawyer environment, then you need to install multiworld.
DISCLAIMER: the mac environment has only been tested without a GPU.
For an even more portable solution, try using the docker image provided in environment/docker
.
The Anaconda env should be enough, but this docker image addresses some of the rendering issues that may arise when using MuJoCo 1.5 and GPUs.
The docker image supports GPU, but it should work without a GPU.
To use a GPU with the image, you need to have nvidia-docker installed.
You can use a GPU by calling
import rlkit.torch.pytorch_util as ptu
ptu.set_gpu_mode(True)
before launching the scripts.
If you are using doodad
(see below), simply use the use_gpu
flag:
run_experiment(..., use_gpu=True)
During training, the results will be saved to a file called under
LOCAL_LOG_DIR/<exp_prefix>/<foldername>
LOCAL_LOG_DIR
is the directory set byrlkit.launchers.config.LOCAL_LOG_DIR
. Default name is 'output'.<exp_prefix>
is given either tosetup_logger
.<foldername>
is auto-generated and based off ofexp_prefix
.- inside this folder, you should see a file called
params.pkl
. To visualize a policy, run
(rlkit) $ python scripts/run_policy.py LOCAL_LOG_DIR/<exp_prefix>/<foldername>/params.pkl
or
(rlkit) $ python scripts/run_goal_conditioned_policy.py LOCAL_LOG_DIR/<exp_prefix>/<foldername>/params.pkl
depending on whether or not the policy is goal-conditioned.
If you have rllab installed, you can also visualize the results
using rllab
's viskit, described at
the bottom of this page
tl;dr run
python rllab/viskit/frontend.py LOCAL_LOG_DIR/<exp_prefix>/
to visualize all experiments with a prefix of exp_prefix
. To only visualize a single run, you can do
python rllab/viskit/frontend.py LOCAL_LOG_DIR/<exp_prefix>/<folder name>
Alternatively, if you don't want to clone all of rllab
, a repository containing only viskit can be found here. You can similarly visualize results with.
python viskit/viskit/frontend.py LOCAL_LOG_DIR/<exp_prefix>/
This viskit
repo also has a few extra nice features, like plotting multiple Y-axis values at once, figure-splitting on multiple keys, and being able to filter hyperparametrs out.
To visualize a goal-conditioned policy, run
(rlkit) $ python scripts/run_goal_conditioned_policy.py
LOCAL_LOG_DIR/<exp_prefix>/<foldername>/params.pkl
The run_experiment
function makes it easy to run Python code on Amazon Web
Services (AWS) or Google Cloud Platform (GCP) by using
this fork of doodad.
It's as easy as:
from rlkit.launchers.launcher_util import run_experiment
def function_to_run(variant):
learning_rate = variant['learning_rate']
...
run_experiment(
function_to_run,
exp_prefix="my-experiment-name",
mode='ec2', # or 'gcp'
variant={'learning_rate': 1e-3},
)
You will need to set up parameters in config.py (see step one of Installation).
This requires some knowledge of AWS and/or GCP, which is beyond the scope of
this README.
To learn more, more about doodad
, go to the repository, which is based on this original repository.
- Implement policy-gradient algorithms.
- Implement model-based algorithms.
For Temporal Difference Models (TDMs) and the original implementation of
Reinforcement Learning with Imagined Goals (RIG), run
git checkout tags/v0.1.2
.
The algorithms are based on the following papers
Skew-Fit: State-Covering Self-Supervised Reinforcement Learning. Vitchyr H. Pong*, Murtaza Dalal*, Steven Lin*, Ashvin Nair, Shikhar Bahl, Sergey Levine. arXiv preprint, 2019.
Visual Reinforcement Learning with Imagined Goals. Ashvin Nair*, Vitchyr Pong*, Murtaza Dalal, Shikhar Bahl, Steven Lin, Sergey Levine. NeurIPS 2018.
Temporal Difference Models: Model-Free Deep RL for Model-Based Control. Vitchyr Pong*, Shixiang Gu*, Murtaza Dalal, Sergey Levine. ICLR 2018.
Hindsight Experience Replay. Marcin Andrychowicz, Filip Wolski, Alex Ray, Jonas Schneider, Rachel Fong, Peter Welinder, Bob McGrew, Josh Tobin, Pieter Abbeel, Wojciech Zaremba. NeurIPS 2017.
Deep Reinforcement Learning with Double Q-learning. Hado van Hasselt, Arthur Guez, David Silver. AAAI 2016.
Human-level control through deep reinforcement learning. Volodymyr Mnih, Koray Kavukcuoglu, David Silver, Andrei A. Rusu, Joel Veness, Marc G. Bellemare, Alex Graves, Martin Riedmiller, Andreas K. Fidjeland, Georg Ostrovski, Stig Petersen, Charles Beattie, Amir Sadik, Ioannis Antonoglou, Helen King, Dharshan Kumaran, Daan Wierstra, Shane Legg, Demis Hassabis. Nature 2015.
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, Sergey Levine. arXiv preprint, 2018.
Soft Actor-Critic: Off-Policy Maximum Entropy Deep Reinforcement Learning with a Stochastic Actor. Tuomas Haarnoja, Aurick Zhou, Pieter Abbeel, and Sergey Levine. ICML, 2018.
Addressing Function Approximation Error in Actor-Critic Methods Scott Fujimoto, Herke van Hoof, David Meger. ICML, 2018.
A lot of the coding infrastructure is based on rllab. The serialization and logger code are basically a carbon copy of the rllab versions.
The Dockerfile is based on the OpenAI mujoco-py Dockerfile.
Other major collaborators and contributions: