Matching Triangles and Basing Hardness on an Extremely Popular Conjecture
Author(s)
Abboud, Amir; Williams, Virginia Vassilevska; Yu, Huacheng
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© 2018 Society for Industrial and Applied Mathematics. Due to the lack of unconditional polynomial lower bounds, it is now in fashion to prove conditional lower bounds in order to advance our understanding of the class P. The vast majority of these lower bounds are based on one of three famous hypotheses: the 3-SUM conjecture, the all pairs shortest paths (APSP) conjecture, and the Strong Exponential Time Hypothesis. Only circumstantial evidence is known in support of these hypotheses, and no formal relationship between them is known. In hopes of obtaining “less conditional” and therefore more reliable lower bounds, we consider the conjecture that at least one of the above three hypotheses is true. We design novel reductions from 3-SUM, APSP, and CNF-SAT, and derive interesting consequences of this very plausible conjecture, including tight n3−o(1) lower bounds for purely combinatorial problems about the triangles in unweighted graphs; new n1−o(1) lower bounds for the amortized update and query times of dynamic algorithms for Single-Source Reachability, Strongly Connected Components, and Max-Flow; new n1.5−o(1) lower bound for computing a set of n st-maximum-flow values in a directed graph with n nodes and Õ(n) edges; and a hierarchy of natural graph problems on n nodes with complexity nc for c ∈ (2, 3). Only slightly nontrivial consequences of this conjecture were known prior to our work. Along the way we also obtain new conditional lower bounds for the Single-Source Max-Flow problem.
Date issued
2018-01Department
Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science; Massachusetts Institute of Technology. Computer Science and Artificial Intelligence LaboratoryPublisher
Society for Industrial & Applied Mathematics (SIAM)
Citation
Abboud, Amir, Williams, Virginia Vassilevska and Yu, Huacheng. 2018. "Matching Triangles and Basing Hardness on an Extremely Popular Conjecture." 47 (3).
Version: Final published version
ISSN
0097-5397
1095-7111
Keywords
General Mathematics, General Computer Science