Efficient $k$-Clique Listing: An Edge-Oriented Branching Strategy
Abstract
-clique listing is a vital graph mining operator with diverse applications in various networks. The state-of-the-art algorithms all adopt a branch-and-bound (BB) framework with a vertex-oriented branching strategy (called VBBkC), which forms a sub-branch by expanding a partial -clique with a vertex. These algorithms have the time complexity of , where is the number of edges in the graph and is the degeneracy of the graph. In this paper, we propose a BB framework with a new edge-oriented branching (called EBBkC), which forms a sub-branch by expanding a partial -clique with two vertices that connect each other (which correspond to an edge). We explore various edge orderings for EBBkC such that it achieves a time complexity of , where is an integer related to the maximum truss number of the graph and we have . The time complexity of EBBkC is better than that of VBBkC algorithms for since both and are bounded by . Furthermore, we develop specialized algorithms for sub-branches on dense graphs so that we can early-terminate them and apply the specialized algorithms. We conduct extensive experiments on 19 real graphs, and the results show that our newly developed EBBkC-based algorithms with the early termination technique consistently and largely outperform the state-of-the-art (VBBkC-based) algorithms.
Cite
@article{arxiv.2311.13798,
title = {Efficient $k$-Clique Listing: An Edge-Oriented Branching Strategy},
author = {Kaixin Wang and Kaiqiang Yu and Cheng Long},
journal= {arXiv preprint arXiv:2311.13798},
year = {2024}
}
Comments
This paper has been accepted by SIGMOD 2024