TorchSparse is a high-performance neural network library for point cloud processing.
website | paper | presentation
TorchSparse depends on the Google Sparse Hash library.
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On Ubuntu, it can be installed by
sudo apt-get install libsparsehash-dev
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On Mac OS, it can be installed by
brew install google-sparsehash
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You can also compile the library locally (if you do not have the sudo permission) and add the library path to the environment variable
CPLUS_INCLUDE_PATH.
The latest released TorchSparse (v1.4.0) can then be installed by
pip install --upgrade git+https://github.com/mit-han-lab/[email protected]If you use TorchSparse in your code, please remember to specify the exact version in your dependencies.
For installation help and troubleshooting, please consult the Frequently Asked Questions before posting an issue.
We compare TorchSparse with MinkowskiEngine (where the latency is measured on NVIDIA GTX 1080Ti):
| MinkowskiEngine v0.4.3 | TorchSparse v1.0.0 | |
|---|---|---|
| MinkUNet18C (MACs / 10) | 224.7 ms | 124.3 ms |
| MinkUNet18C (MACs / 4) | 244.3 ms | 160.9 ms |
| MinkUNet18C (MACs / 2.5) | 269.6 ms | 214.3 ms |
| MinkUNet18C | 323.5 ms | 294.0 ms |
Sparse tensor (SparseTensor) is the main data structure for point cloud, which has two data fields:
- Coordinates (
coords): a 2D integer tensor with a shape of N x 4, where the first three dimensions correspond to quantized x, y, z coordinates, and the last dimension denotes the batch index. - Features (
feats): a 2D tensor with a shape of N x C, where C is the number of feature channels.
Most existing datasets provide raw point cloud data with float coordinates. We can use sparse_quantize (provided in torchsparse.utils.quantize) to voxelize x, y, z coordinates and remove duplicates:
coords -= np.min(coords, axis=0, keepdims=True)
coords, indices = sparse_quantize(coords, voxel_size, return_index=True)
coords = torch.tensor(coords, dtype=torch.int)
feats = torch.tensor(feats[indices], dtype=torch.float)
tensor = SparseTensor(coords=coords, feats=feats)We can then use sparse_collate_fn (provided in torchsparse.utils.collate) to assemble a batch of SparseTensor's (and add the batch dimension to coords). Please refer to this example for more details.
The neural network interface in TorchSparse is very similar to PyTorch:
from torch import nn
from torchsparse import nn as spnn
model = nn.Sequential(
spnn.Conv3d(in_channels, out_channels, kernel_size),
spnn.BatchNorm(out_channels),
spnn.ReLU(True),
)If you use TorchSparse in your research, please use the following BibTeX entries:
@inproceedings{tang2022torchsparse,
title = {{TorchSparse: Efficient Point Cloud Inference Engine}},
author = {Tang, Haotian and Liu, Zhijian and Li, Xiuyu and Lin, Yujun and Han, Song},
booktitle = {Conference on Machine Learning and Systems (MLSys)},
year = {2022}
}@inproceedings{tang2020searching,
title = {{Searching Efficient 3D Architectures with Sparse Point-Voxel Convolution}},
author = {Tang, Haotian and Liu, Zhijian and Zhao, Shengyu and Lin, Yujun and Lin, Ji and Wang, Hanrui and Han, Song},
booktitle = {European Conference on Computer Vision (ECCV)},
year = {2020}
}TorchSparse is inspired by many existing open-source libraries, including (but not limited to) MinkowskiEngine, SECOND and SparseConvNet.