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Graph contrastive learning has made remarkable advances in settings where there is a scarcity of task-specific labels. Despite these advances, the significant computational overhead for representation inference incurred by existing methods that rely on intensive message passing makes them unsuitable for latency-constrained applications. In this paper, we present GraphECL, a simple and efficient contrastive learning method for fast inference on graphs. GraphECL does away with the need for expensive message passing during inference. Specifically, it introduces a novel coupling of the MLP and GNN models, where the former learns to computationally efficiently mimic the computations performed by the latter. We provide a theoretical analysis showing why MLP can capture essential structural information in neighbors well enough to match the performance of GNN in downstream tasks. The extensive experiments on widely used real-world benchmarks that show that GraphECL achieves superior performance and inference efficiency compared to state-of-the-art graph constrastive learning (GCL) methods on homophilous and heterophilous graphs. Code is available at: https: //github.com/tengxiao1/GraphECL.more » « lessFree, publicly-accessible full text available July 16, 2025
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Guo, Zhimeng ; Li, Jialiang ; Xiao, Teng ; Ma, Yao ; Wang, Suhang ( , In Proceedings of 32nd ACM International Conference on Information and Knowledge Management (CIKM 2023))
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Dai, Enyan ; Zhou, Shijie ; Guo, Zhimeng ; Wang, Suhang ( , In Proceedings of the 1st Learning on Graphs Conference (LoG 2022))
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Xiao, Teng ; Chen, Zhengyu ; Guo, Zhimeng ; Zhuang, Zeyang ; Wang, Suhang ( , In Proceedings of Thirty-sixth Conference on Neural Information Processing Systems (NeurIPS 2022))