A Structural Investigation of the Approximability of Polynomial-Time Problems
April 25, 2022 Β· Declared Dead Β· π International Colloquium on Automata, Languages and Programming
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Authors
Karl Bringmann, Alejandro Cassis, Nick Fischer, Marvin KΓΌnnemann
arXiv ID
2204.11681
Category
cs.DS: Data Structures & Algorithms
Cross-listed
cs.CC
Citations
2
Venue
International Colloquium on Automata, Languages and Programming
Last Checked
4 months ago
Abstract
We initiate the systematic study of a recently introduced polynomial-time analogue of MaxSNP, which includes a large number of well-studied problems (including Nearest and Furthest Neighbor in the Hamming metric, Maximum Inner Product, optimization variants of $k$-XOR and Maximum $k$-Cover). Specifically, MaxSP$_k$ denotes the class of $O(m^k)$-time problems of the form $\max_{x_1,\dots, x_k} \#\{y:Ο(x_1,\dots,x_k,y)\}$ where $Ο$ is a quantifier-free first-order property and $m$ denotes the size of the relational structure. Assuming central hypotheses about clique detection in hypergraphs and MAX3SAT, we show that for any MaxSP$_k$ problem definable by a quantifier-free $m$-edge graph formula $Ο$, the best possible approximation guarantee in faster-than-exhaustive-search time $O(m^{k-Ξ΄})$ falls into one of four categories: * optimizable to exactness in time $O(m^{k-Ξ΄})$, * an (inefficient) approximation scheme, i.e., a $(1+Ξ΅)$-approximation in time $O(m^{k-f(Ξ΅)})$, * a (fixed) constant-factor approximation in time $O(m^{k-Ξ΄})$, or * an $m^Ξ΅$-approximation in time $O(m^{k-f(Ξ΅)})$. We obtain an almost complete characterization of these regimes, for MaxSP$_k$ as well as for an analogously defined minimization class MinSP$_k$. As our main technical contribution, we rule out approximation schemes for a large class of problems admitting constant-factor approximations, under the Sparse MAX3SAT hypothesis posed by (Alman, Vassilevska Williams'20). As general trends for the problems we consider, we find: (1) Exact optimizability has a simple algebraic characterization, (2) only few maximization problems do not admit a constant-factor approximation; these do not even have a subpolynomial-factor approximation, and (3) constant-factor approximation of minimization problems is equivalent to deciding whether the optimum is equal to 0.
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