Awesome

Retrieval-Augmented Decision Transformer: External Memory for In-context RL

Thomas Schmied¹, Fabian Paischer¹, Vihang Patil¹, Markus Hofmarcher², Razvan Pascanu^3,4, Sepp Hochreiter^1,5

¹ELLIS Unit Linz and LIT AI Lab, Institute for Machine Learning, JKU Linz, Austria
²Extensity AI, ³Google DeepMind, ⁴UCL, ⁵NXAI

This repository contains the source code for "Retrieval-Augmented Decision Transformer: External Memory for In-context RL". The paper is available on ArXiv.

Overview

This code-based is built on L2M and relies on open-source frameworks, including:

• PyTorch
• Huggingface transformers
• stable-baselines3
• wandb
• Hydra

What is in this repository?

.
├── configs                    # Contains all .yaml config files for Hydra to configure agents, envs, etc.
│   ├── agent_params            
│   ├── wandb_callback_params
│   ├── env_params
│   ├── eval_params
│   ├── run_params
│   └── config.yaml            # Main config file for Hydra - specifies log/data/model directories.
├── continual_world            # Submodule for Continual-World.
├── dmc2gym_custom             # Custom wrapper for DMControl.
├── figures             
├── src                        # Main source directory.
│   ├── algos                  # Contains agent/model/prompt classes.
│   ├── augmentations          # Image augmentations.
│   ├── buffers                # Contains replay trajectory buffers.
│   ├── callbacks              # Contains callbacks for training (e.g., WandB, evaluation, etc.).
│   ├── data                   # Contains data utilities.
│   ├── envs                   # Contains functionality for creating environments.
│   ├── exploration            # Contains exploration strategies.
│   ├── optimizers             # Contains optimizers.
│   ├── schedulers             # Contains learning rate schedulers.
│   ├── tokenizers_custom      # Contains custom tokenizers for discretizing states/actions.
│   ├── utils                  
│   └── __init__.py
├── LICENSE
├── README.md
├── environment.yaml
├── requirements.txt
├── precompute_img_embeds.py   # Script for pre-computing image embeddings.
├── evaluate.py                # Entry point for evaluating agents.
└── main.py                    # Entry point for training agents.

Installation

Environment configuration and dependencies are available in environment.yaml and requirements.txt.

First, create the conda environment.

conda env create -f environment.yaml
conda activate radt

Then install the remaining requirements (with MuJoCo already downloaded, if not see here):

pip install -r requirements.txt

Init the continualworld submodule and install:

git submodule init
git submodule update
cd continual_world
pip install .

Install meta-world:

pip install git+https://github.com/rlworkgroup/metaworld.git@18118a28c06893da0f363786696cc792457b062b

Install custom version of dmc2gym. Our version makes flatten_obs optional, and, thus, allows us to construct the full observation space of all DMControl envs.

cd dmc2gym_custom
pip install -e .

Installing minihack without sudo rights. In this case, follow instructions provided here.

To install the GPU version of faiss (which we used in our experiments), use:

pip uninstall faiss-cpu
conda install -c conda-forge faiss-gpu=1.7.4

In case this installation causes issues, we recommend installing via mamba.

MuJoCo installation

For the installation of MuJoCo and potential tips on troubleshooting, we refer to the L2M repository: https://github.com/ml-jku/L2M

Setup

Experiment configuration

This codebase relies on Hydra, which configures experiments via .yaml files. Hydra automatically creates the log folder structure for a given run, as specified in the respective config.yaml file.

The config.yaml is the main configuration entry point and contains the default parameters. The file references the respective default parameter files under the block defaults. In addition, config.yaml contains 4 important constants that configure the directory paths:

LOG_DIR: ../logs
DATA_DIR: ../data
SSD_DATA_DIR: ../data
MODELS_DIR: ../models

Datasets

The datasets we generated for grid-worlds are available on the Huggingface Hub 🤗, and can be downloaded using the huggingface-cli:

# Dark-Room
huggingface-cli download ml-jku/dark_room --local-dir=./dark_room --repo-type dataset
# Dark Key-Door
huggingface-cli download ml-jku/dark_keydoor --local-dir=./dark_keydoor --repo-type dataset
# MazeRunner
huggingface-cli download ml-jku/mazerunner --local-dir=./mazerunner --repo-type dataset

In addition, the datasets for grid-worlds and our Procgen datasets are available on our webserver. Download using:

# Dark-Room + Dark KeyDoor
wget --recursive --no-parent --no-host-directories --cut-dirs=2 -R "index.html*" https://ml.jku.at/research/RA-DT/downloads/minihack/dark_room
# MazeRunner
wget --recursive --no-parent --no-host-directories --cut-dirs=3 -R "index.html*" https://ml.jku.at/research/RA-DT/downloads/mazerunner/
# Procgen 2M
wget --recursive --no-parent --no-host-directories --cut-dirs=3 -R "index.html*" https://ml.jku.at/research/RA-DT/downloads/procgen_2M/
# Procgen 20M
wget --recursive --no-parent --no-host-directories --cut-dirs=3 -R "index.html*" https://ml.jku.at/research/RA-DT/downloads/procgen_20M/

Running experiments

In the following, we provide illustrative examples of how to run the experiments in the paper.

Dark-Room

To train RA-DT (domain-specific), RA-DT (domain-agnosstic), and AD on Dark-Room 10x10 for 3 seeds each, run:

# RA-DT
python main.py -m seed=42,43,44 experiment_name=darkroom_10x10_radt_v1 env_params=dark_room agent_params=radt_disc_icl run_params=finetune eval_params=pretrain_icl agent_params.load_path.file_name=dt_medium_64_new +agent_params.reinit_policy=True

# RA-DT - domain-agnostic
python main.py -m seed=42,43,44 experiment_name=darkroom_10x10_radt_lm_v1 env_params=dark_room agent_params=radt_disc_icl run_params=finetune eval_params=pretrain_icl agent_params.load_path=null +agent_params/retriever_kwargs=discrete_s_r_rtg +agent_params.retriever_kwargs.beta=10

# AD
python main.py -m seed=42,43,44 experiment_name=darkroom_10x10_ad_v1 env_params=dark_room agent_params=ad_gridworlds run_params=finetune eval_params=pretrain_icl +agent_params.replay_buffer_kwargs.n_ep_later=100

Note that domain-specific RA-DT requires to load a pre-trained checkpoint. Pre-train a DT using:

python main.py -m seed=42 experiment_name=darkroom_10x10_dt_pretrain_v1 env_params=dark_room agent_params=dt_gridworlds run_params=finetune eval_params=pretrain_icl_grids agent_params.huggingface.use_fast_attn=False +wandb_callback_params=pretrain

Afterwards, the model path can be passed to RA-DT via agent_params.load_path.

Dark Key-Door

For the same methods on Dark Key-Door 10x10, run:

# RADT + deduplication
python main.py -m seed=42,43,44 experiment_name=dark_keydoor_10x10_radt_v1 env_params=dark_keydoor agent_params=radt_disc_icl agent_params/data_paths=dark_keydoor_10x10_train run_params=finetune eval_params=pretrain_icl agent_params.load_path='${MODELS_DIR}/minihack/dark_keydoor_10x10/dt_medium_64.zip' +agent_params.reinit_policy=True

# RADT + domain-agnostic
python main.py -m seed=42,43,44 experiment_name=dark_keydoor_10x10_radt_lm_v1 env_params=dark_keydoor agent_params=radt_disc_icl agent_params/data_paths=dark_keydoor_10x10_train run_params=finetune eval_params=pretrain_icl agent_params.load_path=null +agent_params/retriever_kwargs=discrete_s_r_rtg +agent_params.retriever_kwargs.beta=10

# AD
python main.py -m seed=42,43,44 experiment_name=dark_keydoor_10x10_ad_v1 env_params=dark_keydoor agent_params=ad_gridworlds agent_params/data_paths=dark_keydoor_10x10_train run_params=finetune eval_params=pretrain_icl +agent_params.replay_buffer_kwargs.n_ep_later=100

MazeRunner

For the same methods on MazeRunner 15x15, run:

# RA-DT
python main.py -m seed=42,43,44 experiment_name=mazerunner_radt_v1 env_params=mazerunner agent_params=radt_mazerunner run_params=finetune eval_params=pretrain_icl +agent_params.reinit_policy=True eval_params.eval_freq=100000 +eval_params.first_step=False eval_params.n_eval_episodes=30

# RA-DT domain-agnostic
python main.py -m seed=42,43,44 experiment_name=mazerunner_radt_lm_v1 env_params=mazerunner agent_params=radt_mazerunner run_params=finetune eval_params=pretrain_icl agent_params.load_path=null +agent_params/retriever_kwargs=discrete_r_rtg_mazerunner +agent_params.retriever_kwargs.beta=10 eval_params.eval_freq=100000 +eval_params.first_step=False eval_params.n_eval_episodes=30

# AD
python main.py -m seed=42,43,44 experiment_name=mazerunner_radt_ad_v1 env_params=mazerunner agent_params=ad_gridworlds agent_params/data_paths=mazerunner15x15 run_params=finetune eval_params=pretrain_icl agent_params.eval_context_len=800 agent_params.huggingface.max_length=400 agent_params.huggingface.n_positions=2400 +agent_params.replay_buffer_kwargs.n_ep_later=1000 eval_params.eval_freq=100000 +eval_params.first_step=False eval_params.n_eval_episodes=30

Citation

If you find this useful, please consider citing our work:

@article{schmied2024retrieval,
  title={Retrieval-Augmented Decision Transformer: External Memory for In-context RL},
  author={Schmied, Thomas and Paischer, Fabian and Patil, Vihang and Hofmarcher, Markus and Pascanu, Razvan and Hochreiter, Sepp},
  journal={ArXiv},
  year={2024},
  url={https://arxiv.org/abs/2410.07071}
}