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This repository contains the source code for the project LandMark, the groundbreaking large-scale 3D real-world city scene modeling and rendering system. The project is built upon GridNeRF (CVPR23). Please refer to the paper and project page for more details.
Extending from GridNeRF, LandMark drastically improves training and rendering efficiency with parallelism, operators and kernels, as well as a polish over the algorithm. Including:
- Large-scale, high-quality novel view rendering:
- For the first time, we realized efficient training of 3D neural scenes on over 100 square kilometers of city data; and the rendering resolution reached 4K. We used over 200 billion learnable parameters to model the scene.
- Multiple feature extensions:
- Beyond rendering, we showcased layout adjustment such as removing or adding a building, and scene stylization with alternative appearance such as changes of lighting and seasons.
- Training, rendering integrated system:
- We delivered a system covering algorithms, operators, computing systems, which serves as a solid foundation for the training, rendering and application of real-world 3D large models.
- Distributed rendering system:
- For real-time rendering of large scale GridNeRF model.
And now it's possible to train and render with your own LandMark models and enjoy your creativity.
Your likes and contributions to the community are exactly what we need!
The LandMark supports plenty of features at present:
-
GridNeRF Sequential Model Training
-
GridNeRF Parallel Model Training
- Branch Parallel
- Plane Parallel
- Channel Parallel
-
GridNeRF Hybrid Parallel Traning with Model Parallel & DDP Training
-
GridNeRF Sequential Model Rendering
-
Pytorch DDP both on training and rendering
-
MatrixCity Datasets Supports
-
Real-time Distributed Rendering System
-
Parameter loader with dynamic fetching to support infinite area
It's highly recommended to read the DOCUMENTATION about the implementations of our parallel acceleration and dynamic fetching strategies.
You must have a NVIDIA GPU card with CUDA installed on the system. This library has been tested with single and multiple A100 GPUs.
The LandMark repository files contains configuration files to help you create a proper environment
git clone https://github.com/InternLandMark/LandMark.git
cd ./LandMark
export PYTHONPATH=$YOUR_PREFIX_PATH/LandMark/:$PYTHONPATH
We recommend using Conda to manage complicated dependencies:
cd LandMark
conda create --name landmark -y python=3.9.16
conda activate landmark
python -m pip install --upgrade pip
This library has been tested with version 3.9.16 of Python.
Install pytorch with CUDA using the commands below once and for all:
pip install torch==1.13.1+cu116 torchvision==0.14.1+cu116 --extra-index-url https://download.pytorch.org/whl/cu116
This library has been tested with version 11.6 of CUDA.
We provide requirements.txt for setting the environment easily.
pip install -r requirements.txt
For confidentiality requirements, the native datasets we use as shown above will not be released. To ideal reproduce result, MatrixCity dataset is highly recommanded. More details about how to reproducing please refer to the following Chapter: MatrixCity Dataset. We have prepared tuned configuration files and dedicated dataloader for the MatrixCity dataset.
Large scale scenes captured from the real world are most suitable for our method. We recommend using dataset of a building, a well-known LandMark and even a small town. Prepare about 250 ~ 300 images of the reconstruction target. Make sure enough overlapping.
Reform your dataset as the following structure:
- your_dataset/
- images/
- image_0.png
- image_1.png
- image_2.png
- ...
- transforms_train.json
- transforms_test.json
- images/
Folder images/ contains all the images in the training and test sets.
Camera poses in both multi-focal and single focal length formats are supported in transforms_xxx.json
### single focal example ###
{
"camera_model": "SIMPLE_PINHOLE",
"fl_x": 427,
"fl_y": 427,
"w": 547,
"h": 365,
"frames": [
{
"file_path": "./images/image_0.png",
"transform_matrix": []
}
]
}
### multi focal example ###
{
"camera_model": "SIMPLE_PINHOLE",
"frames": [
{
"fl_x": 1116,
"fl_y": 1116,
"w": 1420,
"h": 1065,
"file_path": "./images/image_0.png",
"transform_matrix": []
}
]
}
Extracting poses and sparse point-cloud model using COLMAP as other NeRF methods.
Then transfer the poses data using commands below:
python app/tools/colmap2nerf.py --recon_dir data/your_dataset/sparse/0 --output_dir data/your_dataset
A transforms_train.json and a transforms_test.json files will be generated in the your_dataset/ folder with single focal supported
Referring to the app/tools/config_parser.py and the app/tools/dataloader/city_dataset.py for help.
We provide a configuration file confs/city.txt as an example to help you initialize your experiments.
There are bunches of arguments for customization. We divide them into four types for better understanding
Some important arguments are demonstrated here. Don't forget to specify path-related arguments before proceeding.
-
experiment
- dataroot - Path of the base of datasets. Use
LandMark/datasetsto manage all datasets - datadir - Path of your dataset. It's a relative path to the base of datasets
- dataset_name - Set the type of dataloader rather than the dataset. Using
"city"as recommended - basedir - Where to save your training checkpoint. Using
LandMark/logby default
- dataroot - Path of the base of datasets. Use
-
train
- start_iters - Number of start iteration in training
- n_iters - Total number of iterations in training
- batch_size - Training batch size
- add_nerf - Which iteration to use nerf brunch
-
render
- sampling_opt - Whether to use sampling optimization when rendering
-
model
- resMode - Resolution mode in muti-resolution model
For more details about arguments, refer to the LandMark/app/config_parser.py
Tune the --ub and --lb arguments to achieve ideal result in the experiments.
Now it's time to train your own LandMark model:
python app/trainer.py --config confs/city.txt
The training checkpoints and images will be saved in LandMark/log/your_expname by default.
After the training process completed, independent rendering test is available:
python app/renderer.py --config confs/city.txt --ckpt=log/your_expname/your_expname.th
The rendering results will be save in LandMark/log/your_expname/imgs_test_all by default.
- app/
- models/ - Contains sequential, parallel and dynamic fecthing implementations of GridNeRF models
- tools/ - Contains dataloaders, train/render utilities
- tests/ - Contains scripts for integerity test
- trainer.py - Manage running process for training
- renderer.py - Manage running process for training
- confs/ - Contains configuration files for experiments
- dist_renders - Code, introduction, scripts about distributed rendering system
- requirements.txt - Environment configuration file for pip
The trainer and the renderer both support pytorch DDP.
To train with DDP, use commands below:
python -m torch.distributed.launch --nproc_per_node=number_of_GPUs app/trainer.py --config confs/city.txt
To render with DDP, use commands below:
python -m torch.distributed.launch --nproc_per_node=number_of_GPUs app/renderer.py --config confs/city.txt --ckpt=log/your_expname/your_expname.th
Some arguments related to the multi-GPU environment might need to be set properly. Specify number_of_GPUs according to your actual environment.
For example:
- If training a sequential gridnerf model with N GPUs, it will enables
Nx DDP training - If training a gridnerf model by using branch parallel and plane_division
[2,2]configuration, and the total num of GPUs used are N, it will enablesN/(2x2)x DDP training.
Three types of Model Parallel strategies are currently supported for training:
- Channel Parallel
- Plane Parallel
- Branch Parallel
It is worth pointing out that all these strategies are adapted for large-scale scene reconstruction with over 2000 images and area of several acres
To involve these parallel features in your experiments, simply use the configuration files such as confs/city_multi_branch_parallel.txt. After setting the path arguments in the configuration file, you are ready to train a plug-and-play Branch Parallel model:
python -m torch.distributed.launch --nproc_per_node=number_of_GPUs app/trainer.py --config confs/city_multi_branch_parallel.txt
There are few differences in use between training a branch parallel model and a sequential model with DDP, but the training efficiency meet great acceleration. Especially in reconstruction tasks of large scale scenes, our Parallel strategies shows stable adaption of capability in accelerating the whole training process.
To render with the Parallel model after training, using the command as the sequential one
python app/renderer.py --config confs/city_multi_branch_parallel.txt --ckpt=log/your_expname/your_expname.th
Fully supports the brilliant MatrixCity dataset. Dedicated files are given for block_1 and block_2 in confs/matrixcity.
It's recommended to download the datases from OpenXLab ,or from BaiduNetDisk (password: hqnn).
The following files are needed to be downloaded and be organized as the original directory structure:
MatrixCity/small_city/aerial/train/block_1.tar
MatrixCity/small_city/aerial/train/block_2.tar
MatrixCity/small_city/aerial/test/block_1_test.tar
MatrixCity/small_city/aerial/test/block_2_test.tar
MatrixCity/small_city/aerial/pose/block_A/
After downloaded, the tar files are needed to be unarchived by tar -xf [tar_filename]
Lastly, the dataroot, datadir, and dataset_name in the config file should be set properly as follows:
dataroot = YOUR_MATRIXCITY_FOLDER_PATH/small_city/aerial/pose
datadir = block_A
dataset_name = matrixcity
For single GPU training and rendering, simply use:
# training
python app/trainer.py --config confs/matrixcity/matrixcity_2block_multi.txt
# rendering
python app/renderer.py --config confs/matrixcity/matrixcity_2block_multi.txt --ckpt log/matrix_city_block_1+2_multi/matrix_city_block_1+2_multi.th
For multi GPU DDP training and rendering:
# training
python -m torch.distributed.launch --nproc_per_node=number_of_GPUs app/trainer.py --config confs/matrixcity/matrixcity_2block_multi.txt
# single GPU rendering
python app/renderer.py --config confs/matrixcity/matrixcity_2block_multi.txt --ckpt log/matrix_city_block_1+2_multi/matrix_city_block_1+2_multi.th
# multi GPU rendering
python -m torch.distributed.launch --nproc_per_node=number_of_GPUs app/renderer.py --config confs/matrixcity/matrixcity_2block_multi.txt --ckpt log/matrix_city_block_1+2_multi/matrix_city_block_1+2_multi.th
Other training parallel methods are also available:
python -m torch.distributed.launch --nproc_per_node=number_of_GPUs app/trainer.py --config confs/matrixcity_2block_multi_branch_parallel.txt
In order to allow users to get started quickly, we provide two ckpt, which are trained based on the following two commands:
# matrix_city_block_1+2_multi.th
python app/trainer.py --config confs/matrixcity/matrixcity_2block_multi.txt
# matrix_city_block_1+2_multi_lowquality.th
python app/trainer.py --config confs/matrixcity/matrixcity_2block_lowquality.txt
If you want to skip the training phase, you can directly download them and use the following command to rendering.
# matrix_city_block_1+2_multi.th
python app/renderer.py --config confs/matrixcity/matrixcity_2block_multi.txt --ckpt your_dir/matrix_city_block_1+2_multi.th
# matrix_city_block_1+2_multi_lowquality.th
python app/renderer.py --config confs/matrixcity/matrixcity_2block_lowquality.txt --ckpt your_dir/matrix_city_block_1+2_multi_lowquality.th
Large-scale real-time distributed rendering system which supports over 100 km^2 scene and over 30 frames per second. To achieve large area and fast speed, we use multiple optimizations. Read dist_render/README.md for more detailes
The main work comes from the LandMark Team, Shanghai AI Laboratory.
Here are our honorable Contributors: