This repository contains code for the paper Label-Efficient Learning on Point Clouds using Approximate Convex Decompositions, published at ECCV 2020.
Thanks to yanx27 for an excellent PyTorch PointNet++ implementation Pointnet_Pointnet2_pytorch; our model implementation is based off that codebase.
If you find this codebase useful, please consider citing:
@inProceedings{selfsupacd,
title={Label-Efficient Learning on Point Clouds using Approximate Convex Decompositions},
author = {Matheus Gadelha and Aruni RoyChowdhury and Gopal Sharma and Evangelos Kalogerakis and Liangliang Cao and Erik Learned-Miller and Rui Wang and Subhransu Maji},
booktitle={European Conference on Computer Vision (ECCV)},
year={2020}
}
CUDA setup:
CUDA: '9.2.148' # torch.version.cuda
CuDNN: 7603 # torch.backends.cudnn.version()
Conda environment:
conda create -n acd-env python=3.6
pip install numpy six protobuf>=3.2.0
pip install torch torchvision
pip install matplotlib tqdm tensorboard_logger trimesh
For reference, we also tested using CUDA 10.1, and the corresponding torch and torchvision can be installed using pip install torch==1.6.0+cu101 torchvision==0.7.0+cu101 -f https://download.pytorch.org/whl/torch_stable.html
.
Download part segmentation dataset ShapeNet here and save in data/shapenetcore_partanno_segmentation_benchmark_v0_normal/
.
Download the pre-computed ACD components for the unlabeled ShapeNet core shapes from here and extract its content in data
.
Download the aligned and resampled ModelNet40 dataset for shape classication from here and save in data/modelnet40_normal_resampled/
.
From the project root, the following code snippet trained a model jointly on semantic segmentation on ShapeNetSeg, using 5 samples per shape category (i.e. 5 * 16 = 80 labeled training samples) and a pairwise contrastive loss over ACD components of the unlabeled ShapeNet Core data (for 9 epochs, decaying the learning rate at every epoch, with a batchsize of 24 shapes).
python train_partseg_shapenet_multigpu.py --seed 2001 \
--k_shot 5 --batch_size 24 --selfsup --step_size 1 --epoch 9 \
--ss_path data/ACDv2/
The models are stored in the experiment output folder, under checkpoints
sub-folder. Tensorboard logs and console output as txt file are saved under sub-folder logs
. The test performance is evaluated at the end of the training epochs (i.e. epoch 9 in this case) and written to the logfile.
Pretraining on ACD:
The following example command trains a PointNet++ network on the ACD task. The seed
is an integer that serves as an identifier for multiple runs of the same experiment. Random rotations around the "up" or Z axis is done as data augmentation during training(--rotation_z
). Only the best performing model based on the validation ACD loss is stored under the experiment output folder, under checkpoints
sub-folder. Tensorboard logs and console output as txt file are saved under sub-folder logs
.
python pretrain_partseg_shapenet.py --rotation_z --seed 1001 --gpu 0 \
--model pointnet2_part_seg_msg \
--batch_size 16 --step_size 1 \
--selfsup --retain_overlaps \
--ss_path data/ACDv2
Evaluate pre-trained model on ModelNet40:
- Evaluating on ModelNet with cross-validation of SVM (takes a while):
python test_acdfeat_modelnet.py --gpu 0 --sqrt --model pointnet2_part_seg_msg --log_dir $LOG_DIR --cross_val_svm
- Avoiding the cross-validation for the SVM C, one can also explicitly put the value as a runtime argument:
python test_acdfeat_modelnet.py --gpu 0 --sqrt --model pointnet2_part_seg_msg --log_dir $LOG_DIR --svm_c 220.0
- Examples of
LOG_DIR
can be found at the top of thetest_acdfeat_modelnet.py
code file. Basically it points to wherever the ACD pre-training script dumps its outputs.