Twin-width and types

Abstract

We study problems connected to first-order logic in graphs of bounded twin-width. Inspired by the approach of Bonnet et al. [FOCS 2020], we introduce a robust methodology of local types and describe their behavior in contraction sequences -- the decomposition notion underlying twin-width. We showcase the applicability of the methodology by proving the following two algorithmic results. In both statements, we fix a first-order formula (x1,…,xk) and a constant d, and we assume that on input we are given a graph G together with a contraction sequence of width at most d. (A) One can in time O(n) construct a data structure that can answer the following queries in time O( n): given w1,…,wk, decide whether φ(w1,…,wk) holds in G. (B) After O(n)-time preprocessing, one can enumerate all tuples w1,…,wk that satisfy φ(x1,…,xk) in G with O(1) delay. In the case of (A), the query time can be reduced to O(1/) at the expense of increasing the construction time to O(n1+), for any fixed >0. Finally, we also apply our tools to prove the following statement, which shows optimal bounds on the VC density of set systems that are first-order definable in graphs of bounded twin-width. (C) Let G be a graph of twin-width d, A be a subset of vertices of G, and (x1,…,xk,y1,…,yl) be a first-order formula. Then the number of different subsets of Ak definable by φ using l-tuples of vertices from G as parameters, is bounded by O(|A|l).