A PyTorch implementation of "Graph Wavelet Neural Network" (ICLR 2019)

Last update: Dec 16, 2022

Overview

Graph Wavelet Neural Network

⠀⠀

A PyTorch implementation of Graph Wavelet Neural Network (ICLR 2019).

Abstract

We present graph wavelet neural network (GWNN), a novel graph convolutional neural network (CNN), leveraging graph wavelet transform to address the shortcomings of previous spectral graph CNN methods that depend on graph Fourier transform. Different from graph Fourier transform, graph wavelet transform can be obtained via a fast algorithm without requiring matrix eigendecomposition with high computational cost. Moreover, graph wavelets are sparse and localized in vertex domain, offering high efficiency and good interpretability for graph convolution. The proposed GWNN significantly outperforms previous spectral graph CNNs in the task of graph-based semi-supervised classification on three benchmark datasets: Cora, Citeseer and Pubmed.

A reference Tensorflow implementation is accessible [here].

This repository provides an implementation of Graph Wavelet Neural Network as described in the paper:

Graph Wavelet Neural Network. Bingbing Xu, Huawei Shen, Qi Cao, Yunqi Qiu, Xueqi Cheng. ICLR, 2019. [Paper]

Requirements

The codebase is implemented in Python 3.5.2. package versions used for development are just below.

networkx          2.4
tqdm              4.28.1
numpy             1.15.4
pandas            0.23.4
texttable         1.5.0
scipy             1.1.0
argparse          1.1.0
torch             1.1.0
torch-scatter     1.4.0
torch-sparse      0.4.3
torch-cluster     1.4.5
torch-geometric   1.3.2
torchvision       0.3.0
scikit-learn      0.20.0
PyGSP             0.5.1

Datasets

The code takes the **edge list** of the graph in a csv file. Every row indicates an edge between two nodes separated by a comma. The first row is a header. Nodes should be indexed starting with 0. A sample graph for `Cora` is included in the `input/` directory. In addition to the edgelist there is a JSON file with the sparse features and a csv with the target variable.

The **feature matrix** is a sparse binary one it is stored as a json. Nodes are keys of the json and feature indices are the values. For each node feature column ids are stored as elements of a list. The feature matrix is structured as:

{ 0: [0, 1, 38, 1968, 2000, 52727],
  1: [10000, 20, 3],
  2: [],
  ...
  n: [2018, 10000]}

The **target vector** is a csv with two columns and headers, the first contains the node identifiers the second the targets. This csv is sorted by node identifiers and the target column contains the class meberships indexed from zero.

NODE ID	Target
0	3
1	1
2	0
3	1
...	...
n	3

Options

Training the model is handled by the src/main.py script which provides the following command line arguments.

Input and output options

  --edge-path        STR   Input graph path.   Default is `input/cora_edges.csv`.
  --features-path    STR   Features path.      Default is `input/cora_features.json`.
  --target-path      STR   Target path.        Default is `input/cora_target.csv`.
  --log-path         STR   Log path.           Default is `logs/cora_logs.json`.

Model options

  --epochs                INT       Number of Adam epochs.         Default is 200.
  --learning-rate         FLOAT     Number of training epochs.     Default is 0.01.
  --weight-decay          FLOAT     Weight decay.                  Default is 5*10**-4.
  --filters               INT       Number of filters.             Default is 16.
  --dropout               FLOAT     Dropout probability.           Default is 0.5.
  --test-size             FLOAT     Test set ratio.                Default is 0.2.
  --seed                  INT       Random seeds.                  Default is 42.
  --approximation-order   INT       Chebyshev polynomial order.    Default is 3.
  --tolerance             FLOAT     Wavelet coefficient limit.     Default is 10**-4.
  --scale                 FLOAT     Heat kernel scale.             Default is 1.0.

Examples

The following commands learn the weights of a graph wavelet neural network and saves the logs. The first example trains a graph wavelet neural network on the default dataset with standard hyperparameter settings. Saving the logs at the default path.

python src/main.py

Training a model with more filters in the first layer.

python src/main.py --filters 32

Approximationg the wavelets with polynomials that have an order of 5.

python src/main.py --approximation-order 5

License

GNU License

Comments

what's the meanning of the "feature matrix"?

Hello author, sorry about a stupid question. But the Cora dataset has Cora.cites corresponding your cora_edges.csv, and Cora.content's paper index and paper category for your cora_target.csv, so I don't understand the meanning of your cora_features.json . In the beginning, I just think it's an adjacency matrix of all nodes(paper index), however, the content are inconsistent. Such as ,in cora_edges.csv it's as the picture as follw: and in cora_features.json it's : So I am confused , and hope for your answer. Thank you very much.

opened by CindyTing 7
How can l use this code for graph classification ?

Hi @benedekrozemberczki ,

Let me first thank you for this promising work.

I would like to apply your GWNN to graph classification problems rather than nodes classification.

Do you have any extension for that ?

Thank you

opened by Benjiou 4
the kernel

Hi, author， There was a variable in the code called diagnoal_weight_filter I think the variable should change in the trainning time,but it never changed when I debugging. It's so confusing. And I wonder if the variable conduct the same role as the diagnoal_weight_filer in the tensorflow implementation will change.

opened by maxmit233 3
Fatal Python error: Segmentation fault

hi, author. These days i've been watching the program. But when I run on this code, I find an error happened during the time. Can you give me some suggestions?

opened by Evelyn-coder 2
something about wavelet basis

Hello~, Thank you for your paper. when I read the paper, I think about what is the connection between wavelet basis and Fourier basis, can you give me some tips?

opened by ICDI0906 1

RuntimeError: the derivative for 'index' is not implemented

Hello, I was running the example and got this error.

python src/main.py
+---------------------+----------------------------+
|      Parameter      |           Value            |
+=====================+============================+
| Approximation order | 20                         |
+---------------------+----------------------------+
| Dropout             | 0.500                      |
+---------------------+----------------------------+
| Edge path           | ./input/cora_edges.csv     |
+---------------------+----------------------------+
| Epochs              | 300                        |
+---------------------+----------------------------+
| Features path       | ./input/cora_features.json |
+---------------------+----------------------------+
| Filters             | 16                         |
+---------------------+----------------------------+
| Learning rate       | 0.001                      |
+---------------------+----------------------------+
| Log path            | ./logs/cora_logs.json      |
+---------------------+----------------------------+
| Scale               | 1                          |
+---------------------+----------------------------+
| Seed                | 42                         |
+---------------------+----------------------------+
| Target path         | ./input/cora_target.csv    |
+---------------------+----------------------------+
| Test size           | 0.200                      |
+---------------------+----------------------------+
| Tolerance           | 0.000                      |
+---------------------+----------------------------+
| Weight decay        | 0.001                      |
+---------------------+----------------------------+

Wavelet calculation and sparsification started.

100%|███████████████████████████████████████████████████████████████████████████████████| 2708/2708 [00:11<00:00, 237.23it/s]
100%|███████████████████████████████████████████████████████████████████████████████████| 2708/2708 [00:11<00:00, 228.91it/s]

Normalizing the sparsified wavelets.

Density of wavelets: 0.2%.
Density of inverse wavelets: 0.04%.

Training.

Loss:   0%|                                                                                          | 0/300 [00:00<?, ?it/s]Traceback (most recent call last):
  File "src/main.py", line 24, in <module>
    main()
  File "src/main.py", line 18, in main
    trainer.fit()
  File "/home/paperspace/Thesis/GraphWaveletNeuralNetwork/src/gwnn.py", line 131, in fit
    prediction = self.model(self.phi_indices, self.phi_values , self.phi_inverse_indices, self.phi_inverse_values, self.feature_indices, self.feature_values)
  File "/home/paperspace/miniconda2/envs/thesis/lib/python3.6/site-packages/torch/nn/modules/module.py", line 489, in __call__
    result = self.forward(*input, **kwargs)
  File "/home/paperspace/Thesis/GraphWaveletNeuralNetwork/src/gwnn.py", line 44, in forward
    deep_features_1 = self.convolution_1(phi_indices, phi_values, phi_inverse_indices, phi_inverse_values, feature_indices, feature_values, self.args.dropout)
  File "/home/paperspace/miniconda2/envs/thesis/lib/python3.6/site-packages/torch/nn/modules/module.py", line 489, in __call__
    result = self.forward(*input, **kwargs)
  File "/home/paperspace/Thesis/GraphWaveletNeuralNetwork/src/gwnn_layer.py", line 55, in forward
    localized_features = spmm(phi_product_indices, phi_product_values, self.ncount, filtered_features)
  File "/home/paperspace/miniconda2/envs/thesis/lib/python3.6/site-packages/torch_sparse/spmm.py", line 21, in spmm
    out = scatter_add(out, row, dim=0, dim_size=m)
  File "/home/paperspace/miniconda2/envs/thesis/lib/python3.6/site-packages/torch_scatter/add.py", line 73, in scatter_add
    return out.scatter_add_(dim, index, src)
RuntimeError: the derivative for 'index' is not implemented

opened by youjinChung 1

Releases(v_00001)

v_00001(May 18, 2021)

Source code(tar.gz)
Source code(zip)

Owner

Benedek Rozemberczki

Machine Learning Engineer at AstraZeneca | PhD from The University of Edinburgh.

GitHub Repository

Training Very Deep Neural Networks Without Skip-Connections

DiracNets v2 update (January 2018): The code was updated for DiracNets-v2 in which we removed NCReLU by adding per-channel a and b multipliers without

585 Oct 12, 2022

Implementation of self-attention mechanisms for general purpose. Focused on computer vision modules. Ongoing repository.

Self-attention building blocks for computer vision applications in PyTorch Implementation of self attention mechanisms for computer vision in PyTorch

962 Dec 23, 2022

Data reduction pipeline for KOALA on the AAT.

KOALA KOALA, the Kilofibre Optical AAT Lenslet Array, is a wide-field, high efficiency, integral field unit used by the AAOmega spectrograph on the 3.

4 Sep 26, 2022

68 keypoint annotations for COFW test data

68 keypoint annotations for COFW test data This repository contains manually annotated 68 keypoints for COFW test data (original annotation of CFOW da

31 Dec 06, 2022

Implementation supporting the ICCV 2017 paper "GANs for Biological Image Synthesis"

GANs for Biological Image Synthesis This codes implements the ICCV-2017 paper "GANs for Biological Image Synthesis". The paper and its supplementary m

95 Nov 25, 2022

Implementation of Artificial Neural Network Algorithm

Artificial Neural Network This repository contain implementation of Artificial Neural Network Algorithm in several programming languanges and framewor

1 Sep 14, 2022

Repository for the paper "PoseAug: A Differentiable Pose Augmentation Framework for 3D Human Pose Estimation", CVPR 2021.

PoseAug: A Differentiable Pose Augmentation Framework for 3D Human Pose Estimation Code repository for the paper: PoseAug: A Differentiable Pose Augme

328 Dec 17, 2022

Official implementation for "Symbolic Learning to Optimize: Towards Interpretability and Scalability"

Symbolic Learning to Optimize This is the official implementation for ICLR-2022 paper "Symbolic Learning to Optimize: Towards Interpretability and Sca

8 Dec 19, 2022

Implementation of Common Image Evaluation Metrics by Sayed Nadim (sayednadim.github.io). The repo is built based on full reference image quality metrics such as L1, L2, PSNR, SSIM, LPIPS. and feature-level quality metrics such as FID, IS. It can be used for evaluating image denoising, colorization, inpainting, deraining, dehazing etc. where we have access to ground truth.

Image Quality Evaluation Metrics Implementation of some common full reference image quality metrics. The repo is built based on full reference image q

10 Jan 01, 2023

A very simple baseline to estimate 2D & 3D SMPL-compatible keypoints from a single color image.

Minimal Body A very simple baseline to estimate 2D & 3D SMPL-compatible keypoints from a single color image. The model file is only 51.2 MB and runs a

49 Dec 05, 2022

E-RAFT: Dense Optical Flow from Event Cameras

E-RAFT: Dense Optical Flow from Event Cameras This is the code for the paper E-RAFT: Dense Optical Flow from Event Cameras by Mathias Gehrig, Mario Mi

71 Dec 12, 2022

Open source simulator for autonomous vehicles built on Unreal Engine / Unity, from Microsoft AI & Research

Welcome to AirSim AirSim is a simulator for drones, cars and more, built on Unreal Engine (we now also have an experimental Unity release). It is open

13.8k Jan 05, 2023

Grammar Induction using a Template Tree Approach

Gitta Gitta ("Grammar Induction using a Template Tree Approach") is a method for inducing context-free grammars. It performs particularly well on data

36 Nov 15, 2022

Official implementation of the NRNS paper: No RL, No Simulation: Learning to Navigate without Navigating

No RL No Simulation (NRNS) Official implementation of the NRNS paper: No RL, No Simulation: Learning to Navigate without Navigating NRNS is a heriarch

20 Nov 29, 2022

MRQy is a quality assurance and checking tool for quantitative assessment of magnetic resonance imaging (MRI) data.

Front-end View Backend View Table of Contents Description Prerequisites Running Basic Information Measurements User Interface Feedback and usage Descr

58 Dec 02, 2022

Neurons Dataset API - The official dataloader and visualization tools for Neurons Datasets.

Neurons Dataset API - The official dataloader and visualization tools for Neurons Datasets. Introduction We propose our dataloader API for loading and

1 Nov 19, 2021

Multi-label Co-regularization for Semi-supervised Facial Action Unit Recognition (NeurIPS 2019)

MLCR This is the source code for paper Multi-label Co-regularization for Semi-supervised Facial Action Unit Recognition. Xuesong Niu, Hu Han, Shiguang

60 Nov 29, 2022

Code/data of the paper "Hand-Object Contact Prediction via Motion-Based Pseudo-Labeling and Guided Progressive Label Correction" (BMVC2021)

Hand-Object Contact Prediction (BMVC2021) This repository contains the code and data for the paper "Hand-Object Contact Prediction via Motion-Based Ps

13 Nov 07, 2022

Wordplay, an artificial Intelligence based crossword puzzle solver.

Wordplay, AI based crossword puzzle solver A crossword is a word puzzle that usually takes the form of a square or a rectangular grid of white- and bl

4 Nov 16, 2022

1st place solution in CCF BDCI 2021 ULSEG challenge

1st place solution in CCF BDCI 2021 ULSEG challenge This is the source code of the 1st place solution for ultrasound image angioma segmentation task (

30 Nov 22, 2022