This repository contains the code for the ICCV'23 paper:
GameFormer: Game-theoretic Modeling and Learning of Transformer-based Interactive Prediction and Planning for Autonomous Driving
Zhiyu Huang, Haochen Liu, Chen Lv
AutoMan Research Lab, Nanyang Technological University
[Paper] [arXiv] [Project Website]
In this repository, you can expect to find the following features:
Included 🤟:
- Code for interaction prediction using a joint model on Waymo Open Motion Dataset (WOMD)
- Code for open-loop planning on selected dynamic scenarios within WOMD
Not included 😵:
- Code for the marginal model with EM ensemble for interaction prediction on WOMD
- Code for closed-loop planning on WOMD. Please refer to our previous work DIPP for that.
- Code for packaging and submitting prediction results to the WOMD Interaction Prediction Challenge
For those interested in the nuPlan dataset experimentation, we invite you to visit the GameFormer Planner repository, which provides a more comprehensive planning framework.
- Download the Waymo Open Motion Dataset v1.1. Utilize data from
scenario/training_20s
orscenario/training
for training, and data fromscenario/validation
andscenario/validation_interactive
for testing. - Clone this repository and navigate to the directory:
git clone https://github.com/MCZhi/GameFormer.git && cd GameFormer
- Create a conda environment:
conda create -n gameformer python=3.8
- Activate the conda environment:
conda activate gameformer
- Install the required packages:
pip install -r requirements.txt
Navigate to the interaction_prediction directory:
cd interaction_prediction
NOTE: there might be some missing annoation issues in using training_20s
as train set, so please download scenario/training
instead.
Preprocess data for model training using the following command:
python data_process.py \
--load_path path/to/your/dataset/scenario/set_path \
--save_path path/to/your/processed_data/set_path \
--use_multiprocessing \
--processes=8
Specify --load_path
to the location of the downloaded set path, --save_path
to the desired processed data path, and enable --use_multiprocessing
for parallel data processing. You can perform this separately for the training
and validation_interactive
sets.
Train the model using the command:
bash train.sh 4 #number of GPUs
NOTE: Before training, specify the processed paths for --train_set
and --valid_set
inside the script file.
Set --name
to save logs and checkpoints. As referred in train.py
, you can also adjust other arguments like --seed
, --train_epochs
, --batch_size
for customed training.
Navigate to the open_loop_planning directory:
cd open_loop_planning
Preprocess data for model training using the following command:
python data_process.py \
--load_path path/to/your/dataset/training_20s \
--save_path path/to/your/processed_data \
--use_multiprocessing \
Set --load_path
to the location of the downloaded dataset, --save_path
to the desired processed data path, and enable --use_multiprocessing
for parallel data processing. You can perform this separately for the training and validation sets.
Train the model using the command:
python train.py \
--train_set path/to/your/processed_data/train \
--valid_set path/to/your/processed_data/valid
Specify the paths for --train_set
and --valid_set
. You can set the --levels
to determine the number of interaction levels. Adjust other parameters like --seed
, --train_epochs
, --batch_size
, and --learning_rate
as needed for training.
The training log and models will be saved in training_log/{name}
.
For testing, run:
python open_loop_test.py \
--test_set path/to/your/dataset/validation \
--model_path path/to/your/saved/model
Specify --test_set
as the path to the scenario/validation
data, and --model_path
as the path to your trained model. Use --render
to visualize planning and prediction results.
The testing result will be saved in testing_log/{name}
.
If you find this repository useful for your research, please consider giving us a star 🌟 and citing our paper.
@InProceedings{Huang_2023_ICCV,
author = {Huang, Zhiyu and Liu, Haochen and Lv, Chen},
title = {GameFormer: Game-theoretic Modeling and Learning of Transformer-based Interactive Prediction and Planning for Autonomous Driving},
booktitle = {Proceedings of the IEEE/CVF International Conference on Computer Vision (ICCV)},
month = {October},
year = {2023},
pages = {3903-3913}
}