Pointcept is a powerful and flexible codebase for point cloud perception research. It is also an official implementation of the following paper:
-
Masked Scene Contrast: A Scalable Framework for Unsupervised 3D Representation Learning
Xiaoyang Wu, Xin Wen, Xihui Liu, Hengshuang Zhao
IEEE Conference on Computer Vision and Pattern Recognition (CVPR) 2023
[ Pretrain ] [ MSC ] - [ arXiv ] [ Bib ] → soon -
Understanding Imbalanced Semantic Segmentation Through Neural Collapse (3D Part)
Zhisheng Zhong*, Jiequan Cui*, Yibo Yang*, Xiaoyang Wu, Xiaojuan Qi, Xiangyu Zhang, Jiaya Jia
IEEE Conference on Computer Vision and Pattern Recognition (CVPR) 2023
[ SemSeg ] [ CeCo ] - [ arXiv ] [ Bib ] [ 2D Part ] → soon -
Learning Context-aware Classifier for Semantic Segmentation (3D Part)
Zhuotao Tian, Jiequan Cui, Li Jiang, Xiaojuan Qi, Xin Lai, Yixin Chen, Shu Liu, Jiaya Jia
AAAI Conference on Artificial Intelligence (AAAI) 2023 - Oral
[ SemSeg ] [ CAC ] - [ arXiv ] [ Bib ] [ 2D Part ] → soon -
Point Transformer V2: Grouped Vector Attention and Partition-based Pooling
Xiaoyang Wu, Yixing Lao, Li Jiang, Xihui Liu, Hengshuang Zhao
Conference on Neural Information Processing Systems (NeurIPS) 2022
[ Backbone ] [ PTv2 ] - [ arXiv ] [ Bib ] → here -
Point Transformer
Hengshuang Zhao, Li Jiang, Jiaya Jia, Philip Torr, Vladlen Koltun
IEEE International Conference on Computer Vision (ICCV) 2021 - Oral
[ Backbone ] [ PTv1 ] - [ arXiv ] [ Bib ] → here
Additionally, Pointcept integrates the following excellent work: MinkUNet, SpUNet, Stratified Transformer, Mix3d, PointContrast, ContrastiveSceneContexts, and supports the following datasets: ScanNet, ScanNet200, S3DIS, ArkitScene, Semantic KITTI, ModelNet40.
- Mar, 2023: We released our codebase, Pointcept. Pointcept is a highly potent tool, as evidenced by its ability to significantly augment the baseline performance of SpUnet on the ScanNet validation set, resulting in an impressive mIoU score of 75.0%. Moreover, its remarkable flexibility is manifested through its expertly designed framework, which seamlessly facilitates the integration of cutting-edge methods. We welcome new work to join the Pointcept family and highly recommend reading Quick Start before starting your trail.
- Feb, 2023: MSC and CeCo accepted by CVPR 2023. MSC is a highly efficient and effective pretraining framework that facilitates cross-dataset large-scale pretraining, while CeCo is a segmentation method specifically designed for long-tail datasets. Both approaches are compatible with all existing backbone models in our codebase, and we will soon make the code available for public use.
- Jan, 2023: CAC, oral work of AAAI 2023, has expanded its 3D result with the incorporation of Pointcept. This addition will allow CAC to serve as a pluggable segmentor within our codebase.
- Sep, 2022: PTv2 accepted by NeurIPS 2022. It is a continuation of the Point Transformer. The proposed GVA theory can apply to most existing attention mechanisms, while Grid Pooling is also a practical addition to existing pooling methods.
- Ubuntu: 18.04 or higher
- CUDA: 11.3 or higher
- PyTorch: 1.10.0 or higher
conda create -n pointcept python=3.8 -y
conda activate pointcept
conda install ninja -y
# Choose version you want here: https://pytorch.org/get-started/previous-versions/
conda install pytorch==1.12.1 torchvision==0.13.1 torchaudio==0.12.1 cudatoolkit=11.3 -c pytorch -y
conda install h5py pyyaml -c anaconda -y
conda install sharedarray tensorboard tensorboardx yapf addict einops scipy plyfile termcolor timm -c conda-forge -y
conda install pytorch-cluster pytorch-scatter pytorch-sparse -c pyg -y
pip install torch-geometric
# spconv (SparseUNet)
# refer https://github.com/traveller59/spconv
pip install spconv-cu113
# PTv1 & PTv2 or precise eval
cd libs/pointops
# usual
python setup.py install
# docker & multi GPU arch
TORCH_CUDA_ARCH_LIST="ARCH LIST" python setup.py install
# e.g. 7.5: RTX 3000; 8.0: a100 More available in: https://developer.nvidia.com/cuda-gpus
TORCH_CUDA_ARCH_LIST="7.5 8.0" python setup.py install
cd ../..
# Open3D (Visualization)
pip install open3d
# PPT
pip install ftfy regex tqdm
pip install git https://github.com/openai/CLIP.git
# stratified transformer
pip install torch-points3d
# fix dependence, caused by install torch-points3d
pip uninstall SharedArray
pip install SharedArray==3.2.1
cd libs/pointops2
python setup.py install
cd ../..
# MinkowskiEngine (SparseUNet)
# refer https://github.com/NVIDIA/MinkowskiEngine
# torchsparse (SPVCNN)
# refer https://github.com/mit-han-lab/torchsparse
# install method without sudo apt install
conda install google-sparsehash -c bioconda
export C_INCLUDE_PATH=${CONDA_PREFIX}/include:$C_INCLUDE_PATH
export CPLUS_INCLUDE_PATH=${CONDA_PREFIX}/include:CPLUS_INCLUDE_PATH
pip install --upgrade git https://github.com/mit-han-lab/torchsparse.git
# PointGroup
conda install -c bioconda google-sparsehash
cd libs/pointgroup_ops
python setup.py build_ext --include-dirs=YOUR_ENV_PATH/include
python setup.py install
cd ../..
The preprocessing support semantic and instance segmentation for both ScanNet20
, ScanNet200
and ScanNet Data Efficient
.
- Download the ScanNet v2 dataset.
- Run preprocessing code for raw ScanNet as follows:
# RAW_SCANNET_DIR: the directory of downloaded ScanNet v2 raw dataset.
# PROCESSED_SCANNET_DIR: the directory of processed ScanNet dataset (output dir).
python pointcept/datasets/preprocessing/scannet/preprocess_scannet.py --dataset_root ${RAW_SCANNET_DIR} --output_root ${PROCESSED_SCANNET_DIR}
- (Optional) Download ScanNet Data Efficient files:
# download-scannet.py is the official download script
# or follow instruction here: https://kaldir.vc.in.tum.de/scannet_benchmark/data_efficient/documentation#download
python download-scannet.py --data_efficient -o ${RAW_SCANNET_DIR}
# unzip downloads
cd ${RAW_SCANNET_DIR}/tasks
unzip limited-annotation-points.zip
unzip limited-bboxes.zip
unzip limited-reconstruction-scenes.zip
# copy files to processed dataset folder
cp -r ${RAW_SCANNET_DIR}/tasks ${PROCESSED_SCANNET_DIR}
- Link processed dataset to codebase:
# PROCESSED_SCANNET_DIR: the directory of processed ScanNet dataset.
mkdir data
ln -s ${RAW_SCANNET_DIR} ${CODEBASE_DIR}/data/scannet
- Download S3DIS data by filling this Google form. Download the
Stanford3dDataset_v1.2.zip
file and unzip it. - Run preprocessing code for S3DIS as follows:
# S3DIS_DIR: the directory of downloaded Stanford3dDataset_v1.2 dataset.
# RAW_S3DIS_DIR: the directory of Stanford2d3dDataset_noXYZ dataset. (optional, for parsing normal)
# PROCESSED_S3DIS_DIR: the directory of processed S3DIS dataset (output dir).
# S3DIS without aligned angle
python pointcept/datasets/preprocessing/s3dis/preprocess_s3dis.py --dataset_root ${S3DIS_DIR} --output_root ${PROCESSED_S3DIS_DIR}
# S3DIS with aligned angle (our old codebase choice)
python pointcept/datasets/preprocessing/s3dis/preprocess_s3dis.py --dataset_root ${S3DIS_DIR} --output_root ${PROCESSED_S3DIS_DIR} --align_angle
# S3DIS with normal vector (our new choice)
python pointcept/datasets/preprocessing/s3dis/preprocess_s3dis.py --dataset_root ${S3DIS_DIR} --output_root ${PROCESSED_S3DIS_DIR} --raw_root ${RAW_S3DIS_DIR} --parse_normal
python pointcept/datasets/preprocessing/s3dis/preprocess_s3dis.py --dataset_root ${S3DIS_DIR} --output_root ${PROCESSED_S3DIS_DIR} --raw_root ${RAW_S3DIS_DIR} --align_angle --parse_normal
- Link processed dataset to codebase.
# PROCESSED_S3DIS_DIR: the directory of processed S3DIS dataset.
mkdir data
ln -s ${RAW_S3DIS_DIR} ${CODEBASE_DIR}/data/s3dis
- Download Semantic KITTI dataset.
- Link dataset to codebase.
# SEMANTIC_KITTI_DIR: the directory of Semantic KITTI dataset.
mkdir -p data
ln -s ${SEMANTIC_KITTI_DIR} ${CODEBASE_DIR}/data/semantic_kitti
- Download modelnet40_normal_resampled.zip and unzip
- Link dataset to codebase.
mkdir -p data
ln -s ${MODELNET_DIR} ${CODEBASE_DIR}/data/modelnet40_normal_resampled
Train from scratch. The training processing is based on configs in configs
folder.
The training script will generate an experiment folder in exp
folder and backup essential code in the experiment folder.
Training config, log, tensorboard and checkpoints will also be saved into the experiment folder during the training process.
export CUDA_VISIBLE_DEVICES=${CUDA_VISIBLE_DEVICES}
# Script (Recommended)
sh scripts/train.sh -p ${INTERPRETER_PATH} -g ${NUM_GPU} -d ${DATASET_NAME} -c ${CONFIG_NAME} -n ${EXP_NAME}
# Direct
export PYTHONPATH=./
python tools/train.py --config-file ${CONFIG_PATH} --num-gpus ${NUM_GPU} --options save_path=${SAVE_PATH}
For example:
# By script (Recommended)
# -p is default set as python and can be ignored
sh scripts/train.sh -p python -d scannet -c semseg-ptv2m2-0-base -n semseg-ptv2m2-0-base
# Direct
export PYTHONPATH=./
python tools/train.py --config-file configs/scannet/semseg-pt-v2m2-0-base.py --options save_path=exp/scannet/semseg-ptv2m2-0-base
Resume training from checkpoint. If the training process is interrupted by accident, the following script can resume training from a given checkpoint.
export CUDA_VISIBLE_DEVICES=${CUDA_VISIBLE_DEVICES}
# Script (Recommended)
# simply add "-r true"
sh scripts/train.sh -p ${INTERPRETER_PATH} -g ${NUM_GPU} -d ${DATASET_NAME} -c ${CONFIG_NAME} -n ${EXP_NAME} -r true
# Direct
export PYTHONPATH=./
python tools/train.py --config-file ${CONFIG_PATH} --num-gpus ${NUM_GPU} --options save_path=${SAVE_PATH} resume=True weight=${CHECKPOINT_PATH}
The validation during training only evaluate model on point clouds after grid sampling (voxelization) and testing is needed to achieve a precise evaluation result. Our testing code support TTA (test time augmentation) testing. (Currently only support testing on a single GPU, I might add support to multi-gpus testing in the future version.)
# By script (Based on experiment folder created by training script)
sh scripts/test.sh -p ${INTERPRETER_PATH} -d ${DATASET_NAME} -n ${EXP_NAME} -w ${CHECKPOINT_NAME}
# Direct
export PYTHONPATH=./
python tools/test.py --config-file ${CONFIG_PATH} --options save_path=${SAVE_PATH} weight=${CHECKPOINT_PATH}
For example:
# By script (Based on experiment folder created by training script)
# -p is default set as python and can be ignored
# -w is default set as model_best and can be ignored
sh scripts/test.sh -p python -d scannet -n semseg-ptv2m2-0-base -w model_best
# Direct
export PYTHONPATH=./
python tools/test.py --config-file configs/scannet/semseg-pt-v2m2-0-base.py --options save_path=exp/scannet/semseg-ptv2m2-0-base weight=exp/scannet/semseg-ptv2m2-0-base/models/model_best.pth
Offset
is the separator of point clouds in batch data, and it is similar to the concept of Batch
in PyG.
A visual illustration of batch and offset is as follows:
Pointcept provides SparseUNet
implemented by SpConv
and MinkowskiEngine
. The SpConv version is recommended since SpConv is easy to install and faster than MinkowskiEngine. Meanwhile, SpConv is also widely applied in outdoor perception.
- SpConv (recommend)
The SpConv version SparseUNet
in the codebase was fully rewrite from Li Jiang's code, example running script is as follows:
# ScanNet val
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-0-base -n semseg-spunet-v1m1-0-base
# ScanNet200
sh scripts/train.sh -g 4 -d scannet200 -c semseg-spunet-v1m1-0-base -n semseg-spunet-v1m1-0-base
# S3DIS
sh scripts/train.sh -g 4 -d s3dis -c semseg-spunet-v1m1-0-base -n semseg-spunet-v1m1-0-base
# S3DIS (with normal)
sh scripts/train.sh -g 4 -d s3dis -c semseg-spunet-v1m1-0-cn-base -n semseg-spunet-v1m1-0-cn-base
# Semantic-KITTI
sh scripts/train.sh -g 2 -d semantic-kitti -c semseg-spunet-v1m1-0-base -n semseg-spunet-v1m1-0-base
# ModelNet40
sh scripts/train.sh -g 2 -d modelnet40 -c cls-spunet-v1m1-0-base -n cls-spunet-v1m1-0-base
# ScanNet Data Efficient
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-la20 -n semseg-spunet-v1m1-2-efficient-la20
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-la50 -n semseg-spunet-v1m1-2-efficient-la50
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-la100 -n semseg-spunet-v1m1-2-efficient-la100
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-la200 -n semseg-spunet-v1m1-2-efficient-la200
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-lr1 -n semseg-spunet-v1m1-2-efficient-lr1
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-lr5 -n semseg-spunet-v1m1-2-efficient-lr5
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-lr10 -n semseg-spunet-v1m1-2-efficient-lr10
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-2-efficient-lr20 -n semseg-spunet-v1m1-2-efficient-lr20
# Profile model run time
sh scripts/train.sh -g 4 -d scannet -c semseg-spunet-v1m1-0-enable-profiler -n semseg-spunet-v1m1-0-enable-profiler
- MinkowskiEngine
The MinkowskiEngine version SparseUNet
in the codebase was modified from original MinkowskiEngine repo, and example running script is as follows:
# Uncomment "# from .sparse_unet import *" in "pointcept/models/__init__.py"
# Uncomment "# from .mink_unet import *" in "pointcept/models/sparse_unet/__init__.py"
# ScanNet
sh scripts/train.sh -g 4 -d scannet -c semseg-minkunet34c-0-base -n semseg-minkunet34c-0-base
# ScanNet200
sh scripts/train.sh -g 4 -d scannet200 -c semseg-minkunet34c-0-base -n semseg-minkunet34c-0-base
# S3DIS
sh scripts/train.sh -g 4 -d s3dis -c semseg-minkunet34c-0-base -n semseg-minkunet34c-0-base
# Semantic-KITTI
sh scripts/train.sh -g 2 -d semantic-kitti -c semseg-minkunet34c-0-base -n semseg-minkunet34c-0-base
- PTv2 mode2 (recommend)
The original PTv2 was trained on 4 * RTX a6000 (48G memory). Even enabling AMP, the memory cost of the original PTv2 is slightly larger than 24G. Considering GPUs with 24G memory are much more accessible, I tuned the PTv2 on the latest Pointcept and made it runnable on 4 * RTX 3090 machines.
PTv2 Mode2
enables AMP and disables Position Encoding Multiplier & Grouped Linear. During our further research, we found that precise coordinates are not necessary for point cloud understanding (Replacing precise coordinates with grid coordinates doesn't influence the performance. Also, SparseUNet is an example). As for Grouped Linear, my implementation of Grouped Linear seems to cost more memory than the Linear layer provided by PyTorch. Benefiting from the codebase and better parameter tuning, we also relieve the overfitting problem. The reproducing performance is even better than the results reported in our paper.
Example running script is as follows:
# ptv2m2: PTv2 mode2, disable PEM & Grouped Linear, GPU memory cost < 24G (recommend)
# ScanNet
sh scripts/train.sh -g 4 -d scannet -c semseg-pt-v2m2-0-base -n semseg-pt-v2m2-0-base
# ScanNet test benchmark (train on train set and val set)
sh scripts/train.sh -g 4 -d scannet -c semseg-pt-v2m2-1-benchmark-submit -n semseg-pt-v2m2-1-benchmark-submit
# ScanNet200
sh scripts/train.sh -g 4 -d scannet200 -c semseg-pt-v2m2-0-base -n semseg-pt-v2m2-0-base
# S3DIS
sh scripts/train.sh -g 4 -d s3dis -c semseg-pt-v2m2-0-base -n semseg-pt-v2m2-0-base
- PTv2 mode1
PTv2 mode1
is the original PTv2 we reported in our paper, example running script is as follows:
# ptv2m1: PTv2 mode1, Original PTv2, GPU memory cost > 24G
# ScanNet
sh scripts/train.sh -g 4 -d scannet -c semseg-pt-v2m1-0-base -n semseg-pt-v2m1-0-base
# ScanNet200
sh scripts/train.sh -g 4 -d scannet200 -c semseg-pt-v2m1-0-base -n semseg-pt-v2m1-0-base
# S3DIS
sh scripts/train.sh -g 4 -d s3dis -c semseg-pt-v2m1-0-base -n semseg-pt-v2m1-0-base
- PTv1
The original PTv1 is also available in our Pointcept codebase. I haven't run PTv1 for a long time, but I have ensured that the example running script works well.
# ScanNet
sh scripts/train.sh -g 4 -d scannet -c semseg-pt-v1-0-base -n semseg-pt-v1-0-base
# ScanNet200
sh scripts/train.sh -g 4 -d scannet200 -c semseg-pt-v1-0-base -n semseg-pt-v1-0-base
# S3DIS
sh scripts/train.sh -g 4 -d s3dis -c semseg-pt-v1-0-base -n semseg-pt-v1-0-base
- Uncomment
# from .stratified_transformer import *
inpointcept/models/__init__.py
. - Refer Optional Installation to install dependence.
- Training with the following example running scripts:
# stv1m1: Stratified Transformer mode1, Modified from the original Stratified Transformer code.
# PTv2m2: Stratified Transformer mode2, My rewrite version (recommend).
# ScanNet
sh scripts/train.sh -g 4 -d scannet -c semseg-st-v1m2-0-refined -n semseg-st-v1m2-0-refined
sh scripts/train.sh -g 4 -d scannet -c semseg-st-v1m1-0-origin -n semseg-st-v1m1-0-origin
# ScanNet200
sh scripts/train.sh -g 4 -d scannet200 -c semseg-st-v1m2-0-refined -n semseg-st-v1m2-0-refined
# S3DIS
sh scripts/train.sh -g 4 -d s3dis -c semseg-st-v1m2-0-refined -n semseg-st-v1m2-0-refined
I did not tune the parameters for Stratified Transformer and just ensured it could run.
SPVCNN
is baseline model of SPVNAS, it is also a practical baseline for outdoor dataset.
# Semantic-KITTI
sh scripts/train.sh -g 2 -d semantic-kitti -c semseg-spvcnn-v1m1-0-base -n semseg-spvcnn-v1m1-0-base
If you find Pointcept useful to your research, please cite our work:
@misc{pointcept2023,
title={Pointcept: A Codebase for Point Cloud Perception Research},
author={Pointcept Contributors},
howpublished = {\url{https://github.com/Pointcept/Pointcept}},
year={2023}
}
Pointcept is designed by Xiaoyang, named by Yixing and the logo is created by Yuechen. It is derived from Hengshuang's Semseg and inspirited by several repos, e.g., MinkowskiEngine, pointnet2, mmcv, and Detectron2.