Metadata-Version: 2.1
Name: mars-nerfstudio
Version: 0.3.3.post1
Summary: The official code repository for the paper: MARS: An Instance-aware, Modular and Realistic Simulator for Autonomous Driving
License: Apache 2.0
Project-URL: Homeage, https://open-air-sun.github.io/mars
Classifier: Development Status :: 3 - Alpha
Classifier: Programming Language :: Python
Requires-Python: >=3.8.0
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: nerfstudio>=0.3.2
Requires-Dist: torchtyping
Requires-Dist: torch<2.1.0

<div align="center"><h2>MARS: An Instance-aware, Modular and Realistic Simulator for Autonomous Driving</h1></div>

<p align="center">
    <!-- community badges -->
    <a href="https://open-air-sun.github.io/mars/"><img src="https://img.shields.io/badge/Project-Page-ffa"/></a>
    <!-- doc badges -->
    <a href="https://arxiv.org/abs/2307.15058">
        <img src='https://img.shields.io/badge/arXiv-Page-aff'>
    </a>
    <a href='https://open-air-sun.github.io/mars/static/data/MARS-poster.pdf'>
        <img src='https://img.shields.io/badge/Poster-PDF-pink' />
    </a>
</p>
<div align="center"><h4>CICAI 2023 Best Paper Runner-up Award</h4></div>
<div align="center">
  <img alt="" src="https://github.com/OPEN-AIR-SUN/mars/assets/107318439/b4c747e8-8165-4576-94c3-666c976063c6">
</div>

<div align="center"><h4>For business inquiries, please contact us at <a href="mailto:zhaohao@air.tsinghua.edu.cn">zhaohao@air.tsinghua.edu.cn</a>.</h4></div>

> We have just finished a refactorization of our codebase. Now you can use `pip install` to start using mars instantly! Please contact us without hesitation if you encounter any issues using the latest version. Thanks!

## 1. Installation: Setup the environment

### Prerequisites

You must have an NVIDIA video card with CUDA installed on the system. This library has been tested with version 11.7 of CUDA. You can find more information about installing CUDA [here](https://docs.nvidia.com/cuda/cuda-quick-start-guide/index.html).

#### Create environment

Nerfstudio requires `python >= 3.7`. We recommend using conda to manage dependencies. Make sure to install [Conda](https://docs.conda.io/en/latest/miniconda.html) before proceeding.

```bash
conda create --name mars -y python=3.9
conda activate mars
```

#### Installation

This section will walk you through the installation process. Our system is dependent on the <a href="https://github.com/NVlabs/tiny-cuda-nn">tiny-cuda-nn</a> project.

```bash
pip install mars-nerfstudio
cd /path/to/tiny-cuda-nn/bindings/torch
python setup.py install
```

## 2. Training from Scratch

The following will train a MARS model.

Our repository provides dataparser for KITTI and vKITTI2 datasets, for your own data, you can write your own dataparser or convert your own dataset to the format of the provided datasets.

### From Datasets

#### Data Preparation

The data used in our experiments should contain both the pose parameters of cameras and object tracklets. The camera parameters include the intrinsics and the extrinsics. The object tracklets include the bounding box poses, types, ids, etc. For more information, you can refer to KITTI-MOT or vKITTI2 datasets below.

#### KITTI

The [KITTI-MOT](https://www.cvlibs.net/datasets/kitti/eval_tracking.php) dataset should look like this:

```
.(KITTI_MOT_ROOT)
├── panoptic_maps                    # (Optional) panoptic segmentation from KITTI-STEP dataset.
│   ├── colors
│   │   └── sequence_id.txt
│   ├── train
│   │   └── sequence_id
│   │       └── frame_id.png
└── training
    ├── calib
    │   └── sequence_id.txt
    ├── completion_02                # (Optional) depth completion
    │   └── sequence_id
    │       └── frame_id.png
    ├── completion_03
    │   └── sequence_id
    │       └── frame_id.png
    ├── image_02
    │   └── sequence_id
    │       └── frame_id.png
    ├── image_03
    │   └── sequence_id
    │       └── frame_id.png
    ├── label_02
    │   └── sequence_id.txt
    └── oxts
        └── sequence_id.txt
```

> We use a [monocular depth estimation model](https://github.com/theNded/mini-omnidata) to generate the depth maps for KITTI-MOT dataset. [Here](https://drive.google.com/drive/folders/1Y-41OMCzDkdJ2P-YZHtCI-5YR9jAIKS2?usp=drive_link) is the estimation result of 0006 sequence of KITTI-MOT datasets. You can download and put them in the `KITTI-MOT/training` directory.

> We download the KITTI-STEP annotations and generate the panoptic segmentation maps for KITTI-MOT dataset. You can download the demo panoptic maps [here](https://drive.google.com/drive/folders/1obAyq1jlHbyA9CS9Rg66N3YyI_sjpfGB?usp=drive_link) and put them in the `KITTI-MOT` directory, or you can visit the official website of [KITTI-STEP](https://www.cvlibs.net/datasets/kitti/eval_step.php) for more information.

To train a reconstruction model, you can use the following command:

```bash
ns-train mars-kitti-car-depth-recon --data /data/kitti-MOT/training/image_02/0006
```

or if you want to use the Python script (please refer to the `launch.json` file in the `.vscode` directory):

```bash
python nerfstudio/nerfstudio/scripts/train.py mars-kitti-car-depth-recon --data /data/kitti-MOT/training/image_02/0006
```

#### vKITTI2

The [vKITTI2](https://europe.naverlabs.com/research/computer-vision/proxy-virtual-worlds-vkitti-2/) dataset should look like this:

```
.(vKITTI2_ROOT)
└── sequence_id
    └── scene_name
        ├── bbox.txt
        ├── colors.txt
        ├── extrinsic.txt
        ├── info.txt
        ├── instrinsic.txt
        ├── pose.txt
        └── frames
            ├── depth
            │   ├── Camera_0
            │   │   └── frame_id.png
            │   └── Camera_1
            │   │   └── frame_id.png
            ├── instanceSegmentation
            │   ├── Camera_0
            │   │   └── frame_id.png
            │   └── Camera_1
            │   │   └── frame_id.png
            ├── classSegmentation
            │   ├── Camera_0
            │   │   └── frame_id.png
            │   └── Camera_1
            │   │   └── frame_id.png
            └── rgb
                ├── Camera_0
                │   └── frame_id.png
                └── Camera_1
                    └── frame_id.png
```

To train a reconstruction model, you can use the following command:

```bash
ns-train mars-vkitti-car-depth-recon --data /data/vkitti/Scene06/clone
```

or if you want to use the python script:

```bash
python nerfstudio/nerfstudio/scripts/train.py mars-vkitti-car-depth-recon --data /data/vkitti/Scene06/clone
```

#### Your Own Data

For your own data, you can refer to the above data structure and write your own dataparser, or you can convert your own dataset to the format of the dataset above.

### From Pre-Trained Model

Our model uses nerfstudio as the training framework, we provide the reconstruction and novel view synthesis tasks checkpoints.

Our pre-trained model is uploaded to Google Drive, you can refer to the below table to download the model.


<center>
<table class="tg">
<thead>
  <tr>
    <th>Dataset</th>
    <th>Scene</th>
    <th>Setting</th>
    <th>Start-End</th>
    <th>Steps</th>
    <th>PSNR</th>
    <th>SSIM</th>
    <th>Download</th>
    <th>Wandb</th>
  </tr>
</thead>
<tbody>
  <tr>
    <td rowspan="4">KITTI-MOT</td>
    <td>0006</td>
    <td>Reconstruction</td>
    <td>65-120</td>
    <td>400k</td>
    <td>27.96</td>
    <td>0.900</td>
    <td><a href="https://drive.google.com/drive/folders/118qj8GA1lnkx90yXREAwWtARJquEIn6d?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/ff6tjef7">report</a></td>
  </tr>
  <tr>
    <td>0006</td>
    <td>Novel View Synthesis 75%</td>
    <td>65-120</td>
    <td>200k</td>
    <td>27.32</td>
    <td>0.890</td>
    <td><a href="https://drive.google.com/drive/folders/117MIMkaDhEPDhoyCAAr8o_xATj891STP?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/ns8w2guc">report</a></td>
  </tr>
  <tr>
    <td>0006</td>
    <td>Novel View Synthesis 50%</td>
    <td>65-120</td>
    <td>200k</td>
    <td>26.80</td>
    <td>0.883</td>
    <td><a href="https://drive.google.com/drive/folders/12BnkfO6Jv33MUfBbW1s2BWfm0pAlWecX?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/bk97y3mp">report</a></td>
  </tr>
  <tr>
    <td>0006</td>
    <td>Novel View Synthesis 25%</td>
    <td>65-120</td>
    <td>200k</td>
    <td>25.87</td>
    <td>0.866</td>
    <td><a href="https://drive.google.com/drive/folders/12Esij9r9f4wAf5mFvvJ1uWV3DgEZu7eg?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/r1mbaeqw">report</a></td>
  </tr>
  <tr>
    <td rowspan="3">Vitural KITTI-2</td>
    <td>Scene06</td>
    <td>Novel View Synthesis 75%</td>
    <td>0-237</td>
    <td>600k</td>
    <td>32.32</td>
    <td>0.940</td>
    <td><a href="https://drive.google.com/drive/folders/10S6GcbfyIUCAgxwr6Mp7FgYcBzY-eWgB?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/3747qu1z">report</a></td>
  </tr>
  <tr>
    <td>Scene06</td>
    <td>Novel View Synthesis 50%</td>
    <td>0-237</td>
    <td>600k</td>
    <td>32.16</td>
    <td>0.938</td>
    <td><a href="https://drive.google.com/drive/folders/1-m943ggGEgXRdK7NYGtGFEhWX4PA6DiT?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/fch9iiy8">report</a></td>
  </tr>
  <tr>
    <td>Scene06</td>
    <td>Novel View Synthesis 25%</td>
    <td>0-237</td>
    <td>600k</td>
    <td>30.87</td>
    <td>0.935</td>
    <td><a href="https://drive.google.com/drive/folders/1-9mvzbd1j4vFJ7Zy3CBMWezOHmSpEfcx?usp=drive_link">model</a></td>
    <td><a href="https://api.wandb.ai/links/wuzirui-research/ne5xa2n1">report</a></td>
  </tr>
</tbody>
</table>
</center>


You can use the following command to train a model from a pre-trained model:

```bash
ns-train mars-kitti-car-depth-recon --data /data/kitti-MOT/training/image_02/0006 --load-dir outputs/experiment_name/method_name/timestamp/nerfstudio
```

### Model Configs

Our modular framework supports combining different architectures for each node by modifying model configurations. Here's an example of using Nerfacto for background and our category-level object model:

```python
model=SceneGraphModelConfig(
    background_model=NerfactoModelConfig(),
    object_model_template=CarNeRFModelConfig(_target=CarNeRF),
    object_representation="class-wise",
    object_ray_sample_strategy="remove-bg",
)
```

> If you choose to use the category-level object model, please make sure that the `use_car_latents=True` and the latent codes exists. We provide latent codes of some sequences on KITTI-MOT and vKITTI2 datasets [here](https://drive.google.com/drive/folders/1E4YjMwkDbRsF4Hb1UK0iBDkz-tFVx3Me?usp=sharing).

For more information, please refer to our provided configurations at `mars/cicai_configs.py`. We use wandb for logging by default, you can also specify other viewers (tensorboard/nerfstudio-viewer supported) with the `--vis` config. Please refer to the nerfstudio documentation for details.

## Render

If you want to render with our pre-trained model, you should visit [here](https://drive.google.com/drive/folders/1-5NR2n3o5zD9ViWwovATOshKYfH3us1I?usp=drive_link) to download our checkpoints and **config**. To run the render script, you need to ensure that your config is the same as the `config.yml` that you load in.

You can use the following command to render. You can modify output format and directory by specificing `--output-format` and `--output-path` :


```bash
python scripts/cicai_render.py --load-config outputs/kitti-recon-65-120/mars-kitti-car-depth-recon/2023-10-30_212654/config.yml --output-format video

or

python scripts/cicai_render.py --load-config outputs/kitti-recon-65-120/mars-kitti-car-depth-recon/2023-10-30_212654/config.yml --output-format images --output-path /path/to/your/output/directory
```

## Citation

You can find our paper [here](https://open-air-sun.github.io/mars/static/data/CICAI_MARS_FullPaper.pdf). If you use this library or find the repo useful for your research, please consider citing:

```
@article{wu2023mars,
  author    = {Wu, Zirui and Liu, Tianyu and Luo, Liyi and Zhong, Zhide and Chen, Jianteng and Xiao, Hongmin and Hou, Chao and Lou, Haozhe and Chen, Yuantao and Yang, Runyi and Huang, Yuxin and Ye, Xiaoyu and Yan, Zike and Shi, Yongliang and Liao, Yiyi and Zhao, Hao},
  title     = {MARS: An Instance-aware, Modular and Realistic Simulator for Autonomous Driving},
  journal   = {CICAI},
  year      = {2023},
}
```

## Acknoledgement

Part of our code is borrowed from [Nerfstudio](https://nerf.studio). This project is sponsored by Tsinghua-Toyota Joint Research Fund (20223930097) and Baidu Inc. through Apollo-AIR Joint Research Center.

## Notice

This open-sourced version will be actively maintained and regularly updated. For more features, please contact us for a commercial version.
