New reducible configurations for graph multicoloring with application to the experimental resolution of McDiarmid-Reed's Conjecture (extended version)

Abstract

A (a,b)-coloring of a graph G associates to each vertex a b-subset of a set of a colors in such a way that the color-sets of adjacent vertices are disjoint. We define general reduction tools for (a,b)-coloring of graphs for 2 a/b 3. In particular, using necessary and sufficient conditions for the existence of a (a,b)-coloring of a path with prescribed color-sets on its end-vertices, more complex (a,b)-colorability reductions are presented. The utility of these tools is exemplified on finite triangle-free induced subgraphs of the triangular lattice for which McDiarmid-Reed's conjecture asserts that they are all (9,4)-colorable. Computations on millions of such graphs generated randomly show that our tools allow to find a (9,4)-coloring for each of them except for one specific regular shape of graphs (that can be (9,4)-colored by an easy ad-hoc process). We thus obtain computational evidence towards the conjecture of McDiarmid\&Reed.