Direction-optimizing Label Propagation Framework for Structure Detection in Graphs: Design, Implementation, and Experimental Analysis

Q2 Mathematics
Xu T. Liu, A. Lumsdaine, M. Halappanavar, K. Barker, A. Gebremedhin
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引用次数: 1

Abstract

Label Propagation is not only a well-known machine learning algorithm for classification but also an effective method for discovering communities and connected components in networks. We propose a new Direction-optimizing Label Propagation Algorithm (DOLPA) framework that enhances the performance of the standard Label Propagation Algorithm (LPA), increases its scalability, and extends its versatility and application scope. As a central feature, the DOLPA framework relies on the use of frontiers and alternates between label push and label pull operations to attain high performance. It is formulated in such a way that the same basic algorithm can be used for finding communities or connected components in graphs by only changing the objective function used. Additionally, DOLPA has parameters for tuning the processing order of vertices in a graph to reduce the number of edges visited and improve the quality of solution obtained. We present the design and implementation of the enhanced algorithm as well as our shared-memory parallelization of it using OpenMP. We also present an extensive experimental evaluation of our implementations using the LFR benchmark and real-world networks drawn from various domains. Compared with an implementation of LPA for community detection available in a widely used network analysis software, we achieve at most five times the F-Score while maintaining similar runtime for graphs with overlapping communities. We also compare DOLPA against an implementation of the Louvain method for community detection using the same LFR-graphs and show that DOLPA achieves about three times the F-Score at just 10% of the runtime. For connected component decomposition, our algorithm achieves orders of magnitude speedups over the basic LP-based algorithm on large-diameter graphs, up to 13.2× speedup over the Shiloach-Vishkin algorithm, and up to 1.6× speedup over Afforest on an Intel Xeon processor using 40 threads.
用于图中结构检测的方向优化标签传播框架:设计、实现和实验分析
标签传播不仅是一种著名的分类机器学习算法,也是发现网络中社区和连接组件的有效方法。我们提出了一种新的方向优化标签传播算法(DOLPA)框架,该框架提高了标准标签传播算法的性能,增加了其可扩展性,并扩展了其通用性和应用范围。作为一个核心功能,DOLPA框架依赖于边界的使用,并在标签推送和标签拉取操作之间交替,以获得高性能。它的公式化方式是,只需改变所使用的目标函数,就可以使用相同的基本算法来寻找图中的社区或连通分量。此外,DOLPA具有用于调整图中顶点处理顺序的参数,以减少访问的边的数量并提高获得的解决方案的质量。我们介绍了增强算法的设计和实现,以及我们使用OpenMP对其进行的共享内存并行化。我们还使用LFR基准和来自各个领域的真实世界网络对我们的实现进行了广泛的实验评估。与广泛使用的网络分析软件中用于社区检测的LPA实现相比,我们实现了最多五倍的F-Score,同时为具有重叠社区的图保持相似的运行时间。我们还将DOLPA与使用相同LFR图进行社区检测的Louvain方法的实现进行了比较,并表明DOLPA仅在10%的运行时间内就达到了约三倍的F-Score。对于连接组件分解,我们的算法在大直径图上比基于LP的基本算法实现了几个数量级的加速,在使用40个线程的Intel Xeon处理器上比Shiloach Vishkin算法实现了13.2倍的加速,比Afreest算法实现了1.6倍的加速。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Experimental Algorithmics
Journal of Experimental Algorithmics Mathematics-Theoretical Computer Science
CiteScore
3.10
自引率
0.00%
发文量
29
期刊介绍: The ACM JEA is a high-quality, refereed, archival journal devoted to the study of discrete algorithms and data structures through a combination of experimentation and classical analysis and design techniques. It focuses on the following areas in algorithms and data structures: ■combinatorial optimization ■computational biology ■computational geometry ■graph manipulation ■graphics ■heuristics ■network design ■parallel processing ■routing and scheduling ■searching and sorting ■VLSI design
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