The Complexity of (Pk, P)-Arrowing

Abstract

For fixed nonnegative integers k and , the (Pk, P)-Arrowing problem asks whether a given graph, G, has a red/blue coloring of E(G) such that there are no red copies of Pk and no blue copies of P. The problem is trivial when (k,) ≤ 3, but has been shown to be coNP-complete when k = = 4. In this work, we show that the problem remains coNP-complete for all pairs of k and , except (3,4), and when (k,) ≤ 3. Our result is only the second hardness result for (F,H)-Arrowing for an infinite family of graphs and the first for 1-connected graphs. Previous hardness results for (F, H)-Arrowing depended on constructing graphs that avoided the creation of too many copies of F and H, allowing easier analysis of the reduction. This is clearly unavoidable with paths and thus requires a more careful approach. We define and prove the existence of special graphs that we refer to as ``transmitters.'' Using transmitters, we construct gadgets for three distinct cases: 1) k = 3 and ≥ 5, 2) > k ≥ 4, and 3) = k ≥ 4. For (P3, P4)-Arrowing we show a polynomial-time algorithm by reducing the problem to 2SAT, thus successfully categorizing the complexity of all (Pk, P)-Arrowing problems.