Filling the Complexity Gaps for Colouring Planar and Bounded Degree Graphs

Abstract

A colouring of a graph G=(V,E) is a function c: V→\1,2,… \ such that c(u)≠ c(v) for every uv∈ E. A k-regular list assignment of G is a function L with domain V such that for every u∈ V, L(u) is a subset of \1, 2, …\ of size k. A colouring c of G respects a k-regular list assignment L of G if c(u)∈ L(u) for every u∈ V. A graph G is k-choosable if for every k-regular list assignment L of G, there exists a colouring of G that respects L. We may also ask if for a given k-regular list assignment L of a given graph G, there exists a colouring of G that respects L. This yields the k-Regular List Colouring problem. For k∈ \3,4\ we determine a family of classes G of planar graphs, such that either k-Regular List Colouring is NP-complete for instances (G,L) with G∈ G, or every G∈ G is k-choosable. By using known examples of non-3-choosable and non-4-choosable graphs, this enables us to classify the complexity of k-Regular List Colouring restricted to planar graphs, planar bipartite graphs, planar triangle-free graphs and to planar graphs with no 4-cycles and no 5-cycles. We also classify the complexity of k-Regular List Colouring and a number of related colouring problems for graphs with bounded maximum degree.