Worst-Case to Expander-Case Reductions
November 23, 2022 Β· Declared Dead Β· π Information Technology Convergence and Services
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Authors
Amir Abboud, Nathan Wallheimer
arXiv ID
2211.12833
Category
cs.DS: Data Structures & Algorithms
Citations
4
Venue
Information Technology Convergence and Services
Last Checked
4 months ago
Abstract
In recent years, the expander decomposition method was used to develop many graph algorithms, resulting in major improvements to longstanding complexity barriers. This powerful hammer has led the community to (1) believe that most problems are as easy on worst-case graphs as they are on expanders, and (2) suspect that expander decompositions are the key to breaking the remaining longstanding barriers in fine-grained complexity. We set out to investigate the extent to which these two things are true (and for which problems). Towards this end, we put forth the concept of worst-case to expander-case self-reductions. We design a collection of such reductions for fundamental graph problems, verifying belief (1) for them. The list includes $k$-Clique, $4$-Cycle, Maximum Cardinality Matching, Vertex-Cover, and Minimum Dominating Set. Interestingly, for most (but not all) of these problems the proof is via a simple gadget reduction, not via expander decompositions, showing that this hammer is effectively useless against the problem and contradicting (2).
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