TY - GEN
T1 - Counting Cohesive Subgraphs with Hereditary Properties
AU - Li, Rong Hua
AU - Ye, Xiaowei
AU - Jin, Fusheng
AU - Wang, Yu Ping
AU - Yuan, Ye
AU - Wang, Guoren
N1 - Publisher Copyright:
© 2025 Copyright held by the owner/author(s).
PY - 2025/4/28
Y1 - 2025/4/28
N2 - The classic clique model has properties of hereditaries and cohesiveness. Here hereditaries means a subgraph of a clique is still a clique. Counting small cliques in a graph is a fundamental operation of numerous applications. However, the clique model is often too restrictive for practical use, leading to the focus on other relaxed-cliques with properties of hereditaries and cohesiveness. To address this issue, we investigate a new problem of counting general hereditary cohesive subgraphs (HCS). All subgraphs with properties of hereditaries and cohesiveness can be called a kind of HCS. To count HCS, we propose a general framework called HCSPivot, which can be applied to count all kinds of HCS. HCSPivot can count most HCS combinatorially without explicitly listing them. Two additional noteworthy features of HCSPivot are its ability to (1) simultaneously count HCS of any size and (2) simultaneously count HCS for each node or each edge. Based on our HCSPivot framework, we propose two novel algorithms with several carefully designed pruning techniques to count s-defective cliques and s-plexes, which are two specific types of HCS. We conduct extensive experiments on 8 large real-world graphs, and the results demonstrate the high efficiency and effectiveness of our solutions.
AB - The classic clique model has properties of hereditaries and cohesiveness. Here hereditaries means a subgraph of a clique is still a clique. Counting small cliques in a graph is a fundamental operation of numerous applications. However, the clique model is often too restrictive for practical use, leading to the focus on other relaxed-cliques with properties of hereditaries and cohesiveness. To address this issue, we investigate a new problem of counting general hereditary cohesive subgraphs (HCS). All subgraphs with properties of hereditaries and cohesiveness can be called a kind of HCS. To count HCS, we propose a general framework called HCSPivot, which can be applied to count all kinds of HCS. HCSPivot can count most HCS combinatorially without explicitly listing them. Two additional noteworthy features of HCSPivot are its ability to (1) simultaneously count HCS of any size and (2) simultaneously count HCS for each node or each edge. Based on our HCSPivot framework, we propose two novel algorithms with several carefully designed pruning techniques to count s-defective cliques and s-plexes, which are two specific types of HCS. We conduct extensive experiments on 8 large real-world graphs, and the results demonstrate the high efficiency and effectiveness of our solutions.
KW - Deftective Clique Counting
KW - Hereditary Cohesive Subgraph Counting
KW - Plex Counting
KW - Subgraph counting
UR - http://www.scopus.com/inward/record.url?scp=105005137292&partnerID=8YFLogxK
U2 - 10.1145/3696410.3714730
DO - 10.1145/3696410.3714730
M3 - Conference contribution
AN - SCOPUS:105005137292
T3 - WWW 2025 - Proceedings of the ACM Web Conference
SP - 3874
EP - 3884
BT - WWW 2025 - Proceedings of the ACM Web Conference
PB - Association for Computing Machinery, Inc
T2 - 34th ACM Web Conference, WWW 2025
Y2 - 28 April 2025 through 2 May 2025
ER -