List 3-Coloring Graphs with No Induced $$P_6+rP_3$$

For an integer t, we let $$P_t$$ denote the t-vertex path. We write $$H+G$$ for the disjoint union of two graphs H and G, and for an integer r and a graph H, we write rH for the disjoint union of r copies of H. We say that a graph G is H-free if no induced subgraph of G is isomorphic to the graph H. In this paper, we study the complexity of k-coloring, for a fixed integer k, when restricted to the class of H-free graphs with a fixed graph H. We provide a polynomial-time algorithm to test if, for fixed r, a $$(P_6+rP_3)$$ -free is three-colorable, and find a coloring if one exists. We also solve the list version of this problem, where each vertex is assigned a list of possible colors, which is a subset of $$\{1,2,3\}$$ . This generalizes results of Broersma, Golovach, Paulusma, and Song, and results of Klimosova, Malik, Masařik, Novotna, Paulusma, and Slivova. Our proof uses a result of Ding, Seymour, and Winkler relating matchings and hitting sets in hypergraphs. We also prove that the problem of deciding if a $$(P_5+P_2)$$ -free graph has a k-coloring is NP-hard for every fixed $$k \ge 5$$ .