k-SUM Hardness Implies Treewidth-SETH
Abstract
We show that if k-SUM is hard, in the sense that the standard algorithm is essentially optimal, then a variant of the SETH called the Primal Treewidth SETH is true. Formally: if there is an and an algorithm which solves SAT in time , where is the width of a given tree decomposition of the primal graph of the input, then there exists a randomized algorithm which solves k-SUM in time for some and all sufficiently large . We also establish an analogous result for the k-XOR problem, where integer addition is replaced by component-wise addition modulo . As an application of our reduction we are able to revisit tight lower bounds on the complexity of several fundamental problems parameterized by treewidth (Independent Set, Max Cut, -Coloring). Our results imply that these bounds, which were initially shown under the SETH, also hold if one assumes the k-SUM or k-XOR Hypotheses, arguably increasing our confidence in their validity.
Cite
@article{arxiv.2510.08185,
title = {k-SUM Hardness Implies Treewidth-SETH},
author = {Michael Lampis},
journal= {arXiv preprint arXiv:2510.08185},
year = {2025}
}
Comments
SODA 2026