This is a framework for running common deep learning models for point cloud analysis tasks against classic benchmark. It heavily relies on Pytorch Geometric and Facebook Hydra.
The framework allows lean and yet complex model to be built with minimum effort and great reproducibility. It also provide a high level API to democratize deep learning on pointclouds.
- CUDA 10 or higher (if you want GPU version)
- Python 3.6 or higher + headers (python-dev)
- PyTorch 1.5 or higher (1.4 and 1.3.1 should also be working but are not actively supported moving forward)
- MinkowskiEngine (optional) see here for installation instructions
Install with
pip install torch
pip install torch-points3d
├─ benchmark # Output from various benchmark runs
├─ conf # All configurations for training nad evaluation leave there
├─ notebooks # A collection of notebooks that allow result exploration and network debugging
├─ docker # Docker image that can be used for inference or training
├─ docs # All the doc
├─ eval.py # Eval script
├─ find_neighbour_dist.py # Script to find optimal #neighbours within neighbour search operations
├─ forward_scripts # Script that runs a forward pass on possibly non annotated data
├─ outputs # All outputs from your runs sorted by date
├─ scripts # Some scripts to help manage the project
├─ torch_points3d
├─ core # Core components
├─ datasets # All code related to datasets
├─ metrics # All metrics and trackers
├─ models # All models
├─ modules # Basic modules that can be used in a modular way
├─ utils # Various utils
└─ visualization # Visualization
├─ test
└─ train.py # Main script to launch a training
As a general philosophy we have split datasets and models by task. For example, datasets has three subfolders:
- segmentation
- classification
- registration
- object_detection
where each folder contains the dataset related to each task.
- PointNet from Charles R. Qi et al.: PointNet: Deep Learning on Point Sets for 3D Classification and Segmentation (CVPR 2017)
- PointNet++ from Charles from Charles R. Qi et al.: PointNet++: Deep Hierarchical Feature Learning on Point Sets in a Metric Space
- RSConv from Yongcheng Liu et al.: Relation-Shape Convolutional Neural Network for Point Cloud Analysis (CVPR 2019)
- RandLA-Net from Qingyong Hu et al.: RandLA-Net: Efficient Semantic Segmentation of Large-Scale Point Clouds
- PointCNN from Yangyan Li et al.: PointCNN: Convolution On X-Transformed Points (NIPS 2018)
- KPConv from Hugues Thomas et al.: KPConv: Flexible and Deformable Convolution for Point Clouds (ICCV 2019)
- MinkowskiEngine from Christopher Choy et al.: 4D Spatio-Temporal ConvNets: Minkowski Convolutional Neural Networks (CVPR19)
- VoteNet from Charles R. Qi et al.: Deep Hough Voting for 3D Object Detection in Point Clouds (ICCV 19)
- FCGF from Christopher Choy et al.: Fully Convolutional Geometric Features (ICCV'19)
- PointGroup from Li Jiang et al.: PointGroup: Dual-Set Point Grouping for 3D Instance Segmentation
-
Scannet from Angela Dai et al.: ScanNet: Richly-annotated 3D Reconstructions of Indoor Scenes
-
S3DIS from Iro Armeni et al.: Joint 2D-3D-Semantic Data for Indoor Scene Understanding
* S3DIS 1x1
* S3DIS Room
* S3DIS Fused
- Shapenet from Angel X. Chang et al.: ShapeNet: An Information-Rich 3D Model Repository
- Scannet from Angela Dai et al.: ScanNet: Richly-annotated 3D Reconstructions of Indoor Scenes
- 3DMatch from Andy Zeng et al.: 3DMatch: Learning Local Geometric Descriptors from RGB-D Reconstructions
- ModelNet from Zhirong Wu et al.: 3D ShapeNets: A Deep Representation for Volumetric Shapes
from torch_points3d.applications.kpconv import KPConv
model = KPConv(
architecture="unet",
input_nc=3,
output_nc=5,
in_feat=32,
num_layers=4,
)
from torch_points3d.applications.pointnet2 import PointNet2
model = PointNet2(
architecture="unet",
input_nc=3,
output_nc=5,
num_layers=3,
multiscale=True,
config=None,
)
from torch_points3d.applications.rsconv import RSConv
model = RSConv(
architecture="unet",
input_nc=3,
output_nc=5,
num_layers=3,
multiscale=True,
config=None,
)
from torch_points3d.applications.votenet import VoteNet
model = VoteNet(
original=False, # Wether to create official VoteNet or use custom backbone.
backbone="kpconv",
input_nc=3,
num_classes=20,
mean_size_arr=[], # (num_classes, 3) If available, prior mean box sizes for each class
compute_loss=True,
in_feat=64, # Used for the bakcbone
)
We use Poetry for managing our packages. In order to get started, clone this repositories and run the following command from the root of the repo
poetry install --no-root
This will install all required dependencies in a new virtual environment.
Activate the environment
poetry shell
You can check that the install has been successful by running
python -m unittest -v
The repository is supporting Minkowski Engine which requires openblas-dev
and nvcc
if you have a CUDA device on your machine. First install openblas
sudo apt install libopenblas-dev
then make sure that nvcc
is in your path:
nvcc -V
If it's not then locate it (locate nvcc
) and add its location to your PATH
variable. On my machine:
export PATH="/usr/local/cuda-10.2/bin:$PATH"
You are now in a position to install MinkowskiEngine with GPU support:
poetry run pip install git+git://github.com/StanfordVL/MinkowskiEngine.git#v0.4.3
pip install pycuda
poetry run python train.py task=segmentation model_type=pointnet2 model_name=pointnet2_charlesssg dataset=shapenet-fixed
And you should see something like that
The config for pointnet++ is a good example of how to define a model and is as follow:
# PointNet++: Deep Hierarchical Feature Learning on Point Sets in a Metric Space (https://arxiv.org/abs/1706.02413)
# Credit Charles R. Qi: https://github.com/charlesq34/pointnet2/blob/master/models/pointnet2_part_seg_msg_one_hot.py
pointnet2_onehot:
architecture: pointnet2.PointNet2_D
conv_type: 'DENSE'
use_category: True
down_conv:
module_name: PointNetMSGDown
npoint: [1024, 256, 64, 16]
radii: [[0.05, 0.1], [0.1, 0.2], [0.2, 0.4], [0.4, 0.8]]
nsamples: [[16, 32], [16, 32], [16, 32], [16, 32]]
down_conv_nn:
[
[[FEAT, 16, 16, 32], [FEAT, 32, 32, 64]],
[[32 + 64, 64, 64, 128], [32 + 64, 64, 96, 128]],
[[128 + 128, 128, 196, 256], [128 + 128, 128, 196, 256]],
[[256 + 256, 256, 256, 512], [256 + 256, 256, 384, 512]],
]
up_conv:
module_name: DenseFPModule
up_conv_nn:
[
[512 + 512 + 256 + 256, 512, 512],
[512 + 128 + 128, 512, 512],
[512 + 64 + 32, 256, 256],
[256 + FEAT, 128, 128],
]
skip: True
mlp_cls:
nn: [128, 128]
dropout: 0.5
Model Name | # params | Speed Train / Test | Cross Entropy | OAcc | mIou | mAcc |
---|---|---|---|---|---|---|
pointnet2_original |
3,026,829 | 04:29 / 01:07(RTX 2060) | 0.0512 | 85.26 | 45.58 | 73.11 |
The data reported below correspond to the part segmentation problem for Shapenet for all categories. We report against mean instance IoU and mean class IoU (average of the mean instance IoU per class)
Model Name | Use Normals | # params | Speed Train / Test | Cross Entropy | CmIou | ImIou |
---|---|---|---|---|---|---|
pointnet2_charlesmsg |
Yes | 1,733,946 | 15:07 / 01:20 (K80) | 0.089 | 82.1 | 85.1 |
RSCNN_MSG |
No | 3,488,417 | 05:40 / 0:24 (RTX 2060) | 0.04 | 82.811 | 85.3 |
We provide a notebook based pyvista and panel that allows you to explore your past experiments visually. When using jupyter lab you will have to install an extension:
jupyter labextension install @pyviz/jupyterlab_pyviz
Run through the notebook and you should see a dashboard starting that looks like the following:
We provide a script for running a given pre trained model on custom data that may not be annotated. You will find an example of this for the part segmentation task on Shapenet. Just like for the rest of the codebase most of the customization happens through config files and the provided example can be extended to other datasets. You can also easily create your own from there. Going back to the part segmentation task, say you have a folder full of point clouds that you know are Airplanes, and you have the checkpoint of a model trained on Airplanes and potentially other classes, simply edit the config.yaml and shapenet.yaml and run the following command:
python forward_scripts/forward.py
The result of the forward run will be placed in the specified output_folder
and you can use the notebook provided to explore the results. Below is an example of the outcome of using a model trained on caps only to find the parts of airplanes and caps.
Finally, for people interested in deploying their models to production environments, we provide a Dockerfile as well as a build script. Say you have trained a network for semantic segmentation that gave the weight <outputfolder/weights.pt>
, the following command will build a docker image for you:
cd docker
./build.sh outputfolder/weights.pt
You can then use it to run a forward pass on a all the point clouds in input_path
and generate the results in output_path
docker run -v /test_data:/in -v /test_data/out:/out pointnet2_charlesssg:latest python3 forward_scripts/forward.py dataset=shapenet data.forward_category=Cap input_path="/in" output_path="/out"
The -v
option mounts a local directory to the container's file system. For example in the command line above, /test_data/out
will be mounted at the location /out
. As a consequence, all files written in /out
will be available in the folder /test_data/out
on your machine.
We advice to use snakeviz
and cProfile
Use cProfile to profile your code
poetry run python -m cProfile -o {your_name}.prof train.py ... debugging.profiling=True
And visualize results using snakeviz.
snakeviz {your_name}.prof
It is also possible to use torch.utils.bottleneck
python -m torch.utils.bottleneck /path/to/source/script.py [args]
Ensure that at least PyTorch 1.4.0 is installed and verify that cuda/bin
and cuda/include
are in your $PATH
and $CPATH
respectively, e.g.:
$ python -c "import torch; print(torch.__version__)"
>>> 1.4.0
$ echo $PATH
>>> /usr/local/cuda/bin:...
$ echo $CPATH
>>> /usr/local/cuda/include:...
When we update the version of Pytorch that is used, the compiled packages need to be reinstalled, otherwise you will run into an error that looks like this:
... scatter_cpu.cpython-36m-x86_64-linux-gnu.so: undefined symbol: _ZN3c1012CUDATensorIdEv
This can happen for the following libraries:
- torch-points-kernels
- torch-scatter
- torch-cluster
- torch-sparse
An easy way to fix this is to run the following command with the virtual env activated:
pip uninstall torch-scatter torch-sparse torch-cluster torch-points-kernels -y
rm -rf ~/.cache/pip
poetry install
This can happen when trying to run the code on a different GPU than the one used to compile the torch-points-kernels
library. Uninstall torch-points-kernels
, clear cache, and reinstall after setting the TORCH_CUDA_ARCH_LIST
environment variable. For example, for compiling with a Tesla T4 (Turing 7.5) and running the code on a Tesla V100 (Volta 7.0) use:
export TORCH_CUDA_ARCH_LIST="7.0;7.5"
See this useful chart for more architecture compatibility.
Raises OSError: [WinError 6] The handle is invalid
/ wandb: ERROR W&B process failed to launch
Wandb is currently broken on Windows (see this issue), a workaround is to use the command line argument wandb.log=false
Contributions are welcome! The only asks are that you stick to the styling and that you add tests as you add more features!
For styling you can use pre-commit hooks to help you:
pre-commit install
A sequence of checks will be run for you and you may have to add the fixed files again to the stashed files.
When it comes to docstrings we use numpy style docstrings, for those who use Visual Studio Code, there is a great extension that can help with that. Install it and set the format to numpy and you should be good to go!
Finaly, if you want to have a direct chat with us feel free to join our slack, just shoot us an email and we'll add you.
If you find our work useful, do not hesitate to cite it:
@misc{
tp3d,
author = {Chaton, T. and Chaulet N.},
title = {Torch Points3D}, year = {2020},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/nicolas-chaulet/torch-points3d}}
}
and please also include a citation to the models or the datasets you have used in your experiments!