Continual reinforcement learning baselines: experiment specifications, implementation of existing methods, and common metrics. Easily extensible to new methods.

Overview

Continual Reinforcement Learning

This repository provides a simple way to run continual reinforcement learning experiments in PyTorch, including evaluating existing baseline algorithms, writing your own agents, and specifying custom experiments.

Benchmark results can be seen in our paper (coming soon).

Quick Start (trains CLEAR on Atari)

Clone the repo, and cd into it.

pip install torch>=1.7.1 torchvision
pip install -e .
OMP_NUM_THREADS=1 CUDA_VISIBLE_DEVICES=0 PYTHONUNBUFFERED=1 python main.py --config-file configs/atari/clear_atari.json --output-dir tmp

Changelog

  • 09/15/21: Second pre-release of continual-RL codebase with Procgen, Minihack, CHORES benchmarks. Results in paper (coming soon).
  • 07/26/21: Pre-release of continual-RL codebase with Atari benchmark results in ATARI_RESULTS.md

Getting Started

Setup your environment

There are two flavors of installation: pip and conda.

Pip setup

pip install torch>=1.7.1 torchvision
pip install -e .

Depending on your platform you may need a different torch installation command. See https://pytorch.org/

If you prefer not to install continual_rl as a pip package, you can alternatively do pip install -r requirements.txt

Conda Setup

  1. Run this command to set up a conda environment with the required packages:

    conda env create -f environment.yml -n <venv_name> 
    

    Replace <venv_name> with a virtual environment name of your choosing. If you leave off the -n argument, the default name venv_continual_rl will be used.

  2. Activate your new virtual environment: conda activate <venv_name>

Benchmark Setup

Installation instructions for each benchmark are provided in BENCHMARK_INSTALL.md

Run an experiment (Command-line Mode)

An experiment is a list of tasks, executed sequentially. Each task manages the training of a policy on a single environment. A simple experiment can be run with:

python main.py --policy ppo --experiment mini_atari_3_tasks_3_cycles

The available policies are in continual_rl/available_policies.py. The available experiments are in continual_rl/experiment_specs.py.

Additional command-line arguments

In addition to --policy and --experiment, the following command-line arguments to main.py are also permitted:

  • --output-dir [tmp/<policy>_<experiment>_<timestamp>]: Where logs and saved models are stored

Any policy configuration changes can be made simply by appending --param new_value to the arguments passed to main. The default policy configs (e.g. hyperparameters) are in the config.py file within the policy's folder, and any of them can be set in this way.

For example:

python main.py --policy ppo --experiment mini_atari_3_tasks_3_cycles --learning_rate 1e-3

will override the default learning_rate, and instead use 1e-3.

Run an Experiment (Configuration File)

There is another way experiments can be run: in "config-file" mode instead of "command-line".

Configuration files are an easy way to keep track of large numbers of experiments, and enables resuming an experiment from where it left off.

A configuration file contains JSON representing a list of dictionaries, where each dictionary is a single experiment's configuration. The parameters in the dictionary are all exactly the same as those used by the command line (without --). In other words, they are the config settings found in the policy's config.py file. Example config files can be found in configs/.

When you run the code with:

python main.py --config-file <path_to_file/some_config_file.json> [--output-dir tmp]

A new folder with the name "some_config_file" will be created in output-dir (tmp if otherwise unspecified).

Each experiment in some_config_file.json will be executed sequentially, creating subfolders "0", "1", "2", etc. under output_dir/some_config_file. The subfolder number corresponds to the index of the experiment in the config file's list. Each time the command above is run, it will find the first experiment not yet started by finding the first missing numbered subfolder in output-dir. Thus you can safely run the same command on multiple machines (if they share a filesystem) or multiple sessions on the same machine, and each will be executing different experiments in your queue.

If you wish to resume an experiment from where it left off, you can add the argument:

--resume-id n

and it will resume the experiment corresponding to subfolder n. (This can also be used to start an experiment by its run id even if it hasn't been run yet, i.e. skipping forward in the config file's list.)

Environment Variables

Useful environment variables:

  1. OpenMP thread limit (required for IMPALA-based policies)

    OMP_NUM_THREADS=1
    
  2. Which CUDA devices are visible to the code. In this example GPUs 0 and 1.

    CUDA_VISIBLE_DEVICES=0,1
    
  3. Display Python log messages immediately to the terminal.

    PYTHONUNBUFFERED=1
    

Custom Code

High Level Code Structure

Experiments

An experiment is a list of tasks, executed sequentially. Each task represents the training of an agent on a single environment. The default set of experiments can be seen in experiment_spec.py.

Conceptually, experiments and tasks contain information that should be consistent between runs of the experiment across different algorithms, to maintain a consistent setting for a baseline.

Each task has a type (i.e. subclasses TaskBase) based on what type of preprocessing the observation may require. For instance, ImageTasks will resize your image to the specified size, and permute the channels to match PyTorch's requirements. Only the most basic pre-processing happens here; everything else should be handled by the policy.

Policies

Policies are the core of how an agent operates, and have 3 key functions:

  1. During compute_action(), given an observation, a policy produces an action to take and an instance of TimestepData containing information necessary for the train step.
  2. In get_environment_runner(), Policies specify what type of EnvironmentRunner they should be run with, described further below.
  3. During policy.train() the policy updates its parameters according to the data collected and passed in.

Policy configuration files allow convenient specification of hyperparameters and feature flags, easily settable either via command line (--my_arg) or in a config file.

Conceptually, policies (and policy_configs) contain information that is specific to the algorithm currently being run, and is not expected to be held consistent for experiments using other policies (e.g. clip_eps for PPO).

Environment Runners

EnvironmentRunners specify how the environment should be called; they contain the core loop (observation to action to next observation). The available EnvironmentRunners are:

  1. EnvironmentRunnerSync: Runs environments individually, synchronously.
  2. EnvironmentRunnerBatch: Passes a batch of observations to policy.compute_action, and runs the environments in parallel.
  3. EnvironmentRunnerFullParallel: Spins up a specified number of processes and runs the environment for n steps (or until the end of the episode) separately on each.

More detail about what each Runner provides to the policy are specified in the collect_data method of each Runner.

Creating a new Policy

  1. Duplicate the prototype folder in policies/, renaming it to something distinctive to your new policy.

  2. Rename all other instances of the word "prototype" in filenames, class names, and imports in your new directory.

  3. Your X_policy_config.py file contains all configurations that will automatically be accepted as command line arguments or config file parameters, provided you follow the pattern provided (add a new instance variable, and an entry in _load_dict_internal that populates the variable from a provided dictionary, or utilize _auto_load_class_parameters).

  4. Your X_policy.py file contains the meat of your implementation. What each method requires is described fully in policy_base.py

  5. Your X_timestep_data.py file contains any data you want stored from your compute_action, to be passed to your train step. This object contains one timestep's worth of data, and its .reward and .done will be populated by the environment_runner you select in your X_policy.py file.

    Note: if not using the FullParallel runner, compute_action can instead save data off into a more efficient structure. See: ppo_policy.py

  6. Create unit tests in tests/policies/X_policy (highly encouraged as much as possible)

  7. Add a new entry to available_policies.py

Create a new Environment Runner

If your policy requires a custom environment collection loop, you may consider subclassing EnvironmentRunnerBase. An example of doing this can be seen in IMPALA.

Create a new Experiment

Each entry in the experiments dictionary in experiment_specs.py contains a lambda that, when called, returns an instance of Experiment. The only current requirements for the list of tasks is that the observation space is the same for all tasks, and that the action space is discrete. How different sizes of action space is handled is up to the policy.

Create a new Task

If you want to create an experiment with tasks that cannot be handled with the existing TaskBase subclasses, implement a subclass of TaskBase according to the methods defined therein, using the existing tasks as a guide.

Create unit tests in tests/experiments/tasks/X_task.py

Contributing to the repository

Yes, please do! Pull requests encouraged. Please run pytest on the repository before submitting.

If there's anything you want to customize that does not seem possible, or seems overly challenging, feel free to file an issue in the issue tracker and I'll look into it as soon as possible.

This repository uses pytest for tests. Please write tests wherever possible, in the appropriate folder in tests/.

Comments
  • Best place to add code that will act as

    Best place to add code that will act as "callbacks"?

    I'm interested in extending continual_rl by implementing some of my group's own continual RL algorithm ideas. However, there has been some incompatibilities from what I can see so far. I was wondering if anyone had any advice on some of these issues. In particular, I'm interested in running code related to the policy once a task completes (i.e., code that would normally be put inside the policy class). As I mentioned, from what I can tell, there doesn't seem to be a great way of doing this so I figured I'd ask a few questions before proceeding.

    First, are there any recommended ways of doing this from the policy side without editing any source code? Meaning, solely from my own custom policy class which inherits from PolicyBase.

    Second, would editing the experiment and policy base classes be a reasonable method for approaching this. Essentially, I'd add "callbacks" to the experiment loop that call methods from the policy before a cycle, after a cycle, before a task, and after a task. This is currently the approach I'm learning towards.

    If you have any other suggestions or questions feel free to let me know.

    opened by Bpoole908 7
  • Cannot run the impala-based policy

    Cannot run the impala-based policy

    Hi, thanks for sharing your code.

    I am trying to run with IMPALA-based policy in configuration-file mode, with configs/procgen/impala_procgen.json

    The command that I used: python main.py --config-file configs/procgen/impala_procgen.json

    However, I got all mean_episdoe_return equal to nan as follows (the outputs for setup are ignored):

    Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    [INFO:4981 monobeast:782 2021-11-05 16:09:24,182] Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    [INFO:4981 monobeast:782 2021-11-05 16:09:29,189] Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    [INFO:4981 monobeast:782 2021-11-05 16:09:34,195] Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    [INFO:4981 monobeast:782 2021-11-05 16:09:39,202] Steps 0 @ 0.0 SPS. Mean return nan. Stats:
    {'mean_episode_return': nan}
    

    I found that while interacting with the environment, the act() function is stopped at this point https://github.com/AGI-Labs/continual_rl/blob/bcf17d879e8a983340be233ff8f740c424d0f303/continual_rl/policies/impala/torchbeast/monobeast.py#L226. I have tried to check in forward() in the class ImpalaNet() and saw that it stopped at x = self._conv_net(x) https://github.com/AGI-Labs/continual_rl/blob/bcf17d879e8a983340be233ff8f740c424d0f303/continual_rl/policies/impala/nets.py#L55. I did some modifications by replacing it x = torch.rand(x.shape[0], 512), and the code can run successfully.

    I guess the problem may be caused by the shared memory of the actor's model? Can you give some hints to fix that?

    I have set up for 1 actor and 1 learner Here is some OS information:

    • OS: Ubuntu 20.04
    • Python: 3.7.11 with conda
    • GPU: RTX 3080
    • RAM: 128 GB
    • torch: 1.1.1+cu11.0
    • Docker: No
    • Branch used: develop

    Update: In ConvNet84x84 class, I manually set the intermediate_dim=1024 (for Procgen) and comment out this line https://github.com/AGI-Labs/continual_rl/blob/bcf17d879e8a983340be233ff8f740c424d0f303/continual_rl/utils/common_nets.py#L62, so code is runnable now. Maybe when forwarding the model with dummy input before calling init() causes problem?

    opened by tunglm2203 2
  • Clear replay buffer size

    Clear replay buffer size

    I just wanted to check that the replay buffer size for Clear (denoted "replay_buffer_frames" in the config files) is based on the number of transitions and not the number of unrolled trajectories?

    Thanks in advance!

    opened by skezle 1
  • NameNotFound error

    NameNotFound error

    Hi,

    I ran the the following code: python main.py --policy ppo --experiment procgen_6_tasks_5_cycles

    and I got this error: gym.error.NameNotFound: Environment procgen:procgen-climber doesn't exist.

    Any idea?

    opened by raymondchua 1
  • Enabling common configs (in this case, save frequency) for a policy, …

    Enabling common configs (in this case, save frequency) for a policy, …

    …which can be specified via config file or command line as normal. Also making it so task params can be passed in (though presently they're just left as the defaults). Also gym 0.26 is not backwards compatible, so enforcing an older version for now, since updating the codebase is less trivial. Also fixed one of the deprecation issues.

    opened by SamNPowers 0
  • Minihack benchmark with impala doesn't finish running

    Minihack benchmark with impala doesn't finish running

    I am trying to run the minihack benchmarks with impala. But after 35M steps the job dies and a lot of RAM is taken up by python processes. Impala doesn't use experience replay like clear to prevent forgetting, so I am not sure what is taking up all the RAM. I get the following errors from the log files after running:

    OMP_NUM_THREADS=1 python main.py --config-file configs/minihack/impala_minihack.json --resume-id=0.

    I get the following error in impala_logs.log:

    Screen Shot 2022-05-20 at 11 53 06 AM

    I get the following error in core_process.log:

    Screen Shot 2022-05-18 at 11 01 04 AM

    Any idea what this could be?

    opened by skezle 16
Releases(v1.0.0-alpha)
  • v1.0.0-alpha(Jul 27, 2021)

    The initial framework for developing policies and experiments for the continual reinforcement learning setting, where tasks are learned sequentially rather than concurrently. Initial policies include PPO, Impala, CLEAR, Progress & Compress, and Elastic Weight Consolidation.

    Source code(tar.gz)
    Source code(zip)
Course materials for Fall 2021 "CIS6930 Topics in Computing for Data Science" at New College of Florida

Fall 2021 CIS6930 Topics in Computing for Data Science This repository hosts course materials used for a 13-week course "CIS6930 Topics in Computing f

Yoshi Suhara 101 Nov 30, 2022
TensorFlow ROCm port

Documentation TensorFlow is an end-to-end open source platform for machine learning. It has a comprehensive, flexible ecosystem of tools, libraries, a

ROCm Software Platform 622 Jan 09, 2023
Unit-Convertor - Unit Convertor Built With Python

Python Unit Converter This project can convert Weigth,length and ... units for y

Mahdis Esmaeelian 1 May 31, 2022
shufflev2-yolov5:lighter, faster and easier to deploy

shufflev2-yolov5: lighter, faster and easier to deploy. Evolved from yolov5 and the size of model is only 1.7M (int8) and 3.3M (fp16). It can reach 10+ FPS on the Raspberry Pi 4B when the input size

pogg 1.5k Jan 05, 2023
deep-table implements various state-of-the-art deep learning and self-supervised learning algorithms for tabular data using PyTorch.

deep-table implements various state-of-the-art deep learning and self-supervised learning algorithms for tabular data using PyTorch.

63 Oct 17, 2022
Implementation of CVPR'21: RfD-Net: Point Scene Understanding by Semantic Instance Reconstruction

RfD-Net [Project Page] [Paper] [Video] RfD-Net: Point Scene Understanding by Semantic Instance Reconstruction Yinyu Nie, Ji Hou, Xiaoguang Han, Matthi

Yinyu Nie 162 Jan 06, 2023
Reinfore learning tool box, contains trpo, a3c algorithm for continous action space

RL_toolbox all the algorithm is running on pycharm IDE, or the package loss error may exist. implemented algorithm: trpo a3c a3c:for continous action

yupei.wu 44 Oct 10, 2022
It helps user to learn Pick-up lines and share if he has a better one

Pick-up-Lines-Generator(Open Source) It helps user to learn Pick-up lines Share and Add one or many to the DataBase Unique SQLite DataBase AI Undercon

knock_nott 0 May 04, 2022
A code implementation of AC-GC: Activation Compression with Guaranteed Convergence, in NeurIPS 2021.

Code For AC-GC: Lossy Activation Compression with Guaranteed Convergence This code is intended to be used as a supplemental material for submission to

Dave Evans 2 Nov 01, 2022
FuseDream: Training-Free Text-to-Image Generationwith Improved CLIP+GAN Space OptimizationFuseDream: Training-Free Text-to-Image Generationwith Improved CLIP+GAN Space Optimization

FuseDream This repo contains code for our paper (paper link): FuseDream: Training-Free Text-to-Image Generation with Improved CLIP+GAN Space Optimizat

XCL 191 Dec 31, 2022
Volumetric Correspondence Networks for Optical Flow, NeurIPS 2019.

VCN: Volumetric correspondence networks for optical flow [project website] Requirements python 3.6 pytorch 1.1.0-1.3.0 pytorch correlation module (opt

Gengshan Yang 144 Dec 06, 2022
RoIAlign & crop_and_resize for PyTorch

RoIAlign for PyTorch This is a PyTorch version of RoIAlign. This implementation is based on crop_and_resize and supports both forward and backward on

Long Chen 530 Jan 07, 2023
PyTorch implementations for our SIGGRAPH 2021 paper: Editable Free-viewpoint Video Using a Layered Neural Representation.

st-nerf We provide PyTorch implementations for our paper: Editable Free-viewpoint Video Using a Layered Neural Representation SIGGRAPH 2021 Jiakai Zha

Diplodocus 258 Jan 02, 2023
Optimized primitives for collective multi-GPU communication

NCCL Optimized primitives for inter-GPU communication. Introduction NCCL (pronounced "Nickel") is a stand-alone library of standard communication rout

NVIDIA Corporation 2k Jan 09, 2023
Codebase for Diffusion Models Beat GANS on Image Synthesis.

Codebase for Diffusion Models Beat GANS on Image Synthesis.

Katherine Crowson 128 Dec 02, 2022
Code for ICLR 2021 Paper, "Anytime Sampling for Autoregressive Models via Ordered Autoencoding"

Anytime Autoregressive Model Anytime Sampling for Autoregressive Models via Ordered Autoencoding , ICLR 21 Yilun Xu, Yang Song, Sahaj Gara, Linyuan Go

Yilun Xu 22 Sep 08, 2022
DeepMind's software stack for physics-based simulation and Reinforcement Learning environments, using MuJoCo.

dm_control: DeepMind Infrastructure for Physics-Based Simulation. DeepMind's software stack for physics-based simulation and Reinforcement Learning en

DeepMind 3k Dec 31, 2022
The source code of "SIDE: Center-based Stereo 3D Detector with Structure-aware Instance Depth Estimation", accepted to WACV 2022.

SIDE: Center-based Stereo 3D Detector with Structure-aware Instance Depth Estimation The source code of our work "SIDE: Center-based Stereo 3D Detecto

10 Dec 18, 2022
The original implementation of TNDM used in the NeurIPS 2021 paper (no longer being updated)

TNDM - Targeted Neural Dynamical Modeling Note: This code is no longer being updated. The official re-implementation can be found at: https://github.c

1 Jul 21, 2022
A quantum game modeling of pandemic (QHack 2022)

Contributors: @JongheumJung, @YoonjaeChung, @GyunghunKim Abstract In the regime of a global pandemic, leaders around the world need to consider variou

Yoonjae Chung 8 Apr 03, 2022