On the Complexity of Restoring Corrupted Colorings

Abstract

In the problem, we are given a graph G, a (non-proper) vertex-coloring c : V(G) [r], and a positive integer k. The goal is to decide whether a proper r-coloring c' is obtainable from c by recoloring at most k vertices of G. Recently, Junosza-Szaniawski, Liedloff, and Rza\.zewski [SOFSEM 2015] asked whether the problem has a polynomial kernel parameterized by the number of recolorings k. In a full version of the manuscript, the authors together with Garnero and Montealegre, answered the question in the negative: for every r ≥ 3, the problem does not admit a polynomial kernel unless ⊂eq / . Independently of their work, we give an alternative proof of the theorem. Furthermore, we study the complexity of , where the only difference from is that instead of k recolorings we have a budget of k color swaps. We show that for every r ≥ 3, the problem is [1]-hard whereas is known to be FPT. Moreover, when r is part of the input, we observe both and are [1]-hard parameterized by treewidth. We also study promise variants of the problems, where we are guaranteed that a proper r-coloring c' is indeed obtainable from c by some finite number of swaps. For instance, we prove that for r=3, the problems and are -hard for planar graphs. As a consequence of our reduction, the problems cannot be solved in 2o(n) time unless the Exponential Time Hypothesis (ETH) fails.