Homomorphism-Distinguishing Closedness for Graphs of Bounded Tree-Width

Abstract

Two graphs are homomorphism indistinguishable over a graph class F, denoted by G F H, if hom(F,G) = hom(F,H) for all F ∈ F where hom(F,G) denotes the number of homomorphisms from F to G. A classical result of Lov\'asz shows that isomorphism between graphs is equivalent to homomorphism indistinguishability over the class of all graphs. More recently, there has been a series of works giving natural algebraic and/or logical characterizations for homomorphism indistinguishability over certain restricted graph classes. A class of graphs F is homomorphism-distinguishing closed if, for every F F, there are graphs G and H such that G F H and hom(F,G) ≠ hom(F,H). Roberson conjectured that every class closed under taking minors and disjoint unions is homomorphism-distinguishing closed which implies that every such class defines a distinct equivalence relation between graphs. In this note, we confirm this conjecture for the classes Tk, k ≥ 1, containing all graphs of tree-width at most k. As an application of this result, we also characterize which subgraph counts are detected by the k-dimensional Weisfeiler-Leman algorithm. This answers an open question from [Arvind et al., J. Comput. Syst. Sci., 2020].