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Main Authors: Zhang, Guibin, Yue, Yanwei, Wang, Kun, Fang, Junfeng, Sui, Yongduo, Wang, Kai, Liang, Yuxuan, Cheng, Dawei, Pan, Shirui, Chen, Tianlong
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2402.01242
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author Zhang, Guibin
Yue, Yanwei
Wang, Kun
Fang, Junfeng
Sui, Yongduo
Wang, Kai
Liang, Yuxuan
Cheng, Dawei
Pan, Shirui
Chen, Tianlong
author_facet Zhang, Guibin
Yue, Yanwei
Wang, Kun
Fang, Junfeng
Sui, Yongduo
Wang, Kai
Liang, Yuxuan
Cheng, Dawei
Pan, Shirui
Chen, Tianlong
contents Graph Neural Networks (GNNs) excel in various graph learning tasks but face computational challenges when applied to large-scale graphs. A promising solution is to remove non-essential edges to reduce the computational overheads in GNN. Previous literature generally falls into two categories: topology-guided and semantic-guided. The former maintains certain graph topological properties yet often underperforms on GNNs due to low integration with neural network training. The latter performs well at lower sparsity on GNNs but faces performance collapse at higher sparsity levels. With this in mind, we take the first step to propose a new research line and concept termed Graph Sparse Training (GST), which dynamically manipulates sparsity at the data level. Specifically, GST initially constructs a topology & semantic anchor at a low training cost, followed by performing dynamic sparse training to align the sparse graph with the anchor. We introduce the Equilibria Sparsification Principle to guide this process, effectively balancing the preservation of both topological and semantic information. Ultimately, GST produces a sparse graph with maximum topological integrity and no performance degradation. Extensive experiments on 6 datasets and 5 backbones showcase that GST (I) identifies subgraphs at higher graph sparsity levels (1.67%~15.85% $\uparrow$) than state-of-the-art sparsification methods, (II) preserves more key spectral properties, (III) achieves 1.27-3.42$\times$ speedup in GNN inference and (IV) successfully helps graph adversarial defense and graph lottery tickets.
format Preprint
id arxiv_https___arxiv_org_abs_2402_01242
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Two Heads Are Better Than One: Boosting Graph Sparse Training via Semantic and Topological Awareness
Zhang, Guibin
Yue, Yanwei
Wang, Kun
Fang, Junfeng
Sui, Yongduo
Wang, Kai
Liang, Yuxuan
Cheng, Dawei
Pan, Shirui
Chen, Tianlong
Machine Learning
Graph Neural Networks (GNNs) excel in various graph learning tasks but face computational challenges when applied to large-scale graphs. A promising solution is to remove non-essential edges to reduce the computational overheads in GNN. Previous literature generally falls into two categories: topology-guided and semantic-guided. The former maintains certain graph topological properties yet often underperforms on GNNs due to low integration with neural network training. The latter performs well at lower sparsity on GNNs but faces performance collapse at higher sparsity levels. With this in mind, we take the first step to propose a new research line and concept termed Graph Sparse Training (GST), which dynamically manipulates sparsity at the data level. Specifically, GST initially constructs a topology & semantic anchor at a low training cost, followed by performing dynamic sparse training to align the sparse graph with the anchor. We introduce the Equilibria Sparsification Principle to guide this process, effectively balancing the preservation of both topological and semantic information. Ultimately, GST produces a sparse graph with maximum topological integrity and no performance degradation. Extensive experiments on 6 datasets and 5 backbones showcase that GST (I) identifies subgraphs at higher graph sparsity levels (1.67%~15.85% $\uparrow$) than state-of-the-art sparsification methods, (II) preserves more key spectral properties, (III) achieves 1.27-3.42$\times$ speedup in GNN inference and (IV) successfully helps graph adversarial defense and graph lottery tickets.
title Two Heads Are Better Than One: Boosting Graph Sparse Training via Semantic and Topological Awareness
topic Machine Learning
url https://arxiv.org/abs/2402.01242