Colorful Vertex Recoloring of Bipartite Graphs

In vertex recoloring, we are given $n$ vertices with their initial coloring, and edges arrive in an online fashion. The algorithm must maintain a valid coloring by recoloring vertices, at a cost. The problem abstracts a scenario of job placement in machines (possibly in the cloud), where vertices represent jobs, colors represent machines, and edges represent ``anti affinity'' (disengagement) constraints. Online recoloring is a hard problem. One family of instances which is fairly well-understood is bipartite graphs, in which two colors are sufficient to satisfy all constraints. In this case it is known that the competitive ratio of vertex recoloring is $\Theta(\log n)$. We propose a generalization of the problem, which allows using additional colors (possibly at a higher cost), to improve overall performance. We analyze the simple case of bipartite graphs of bounded largest \emph{bond} (a bond of a connected graph is an edge-cut that partitions the graph into two connected components). First, we propose two algorithms. One exhibits a trade-off for the uniform-cost case: given $\Omega(\log\beta)\le c\le O(\log n)$ colors, the algorithm guarantees that its cost is at most $O(\frac{\log n}{c})$ times the optimal offline cost for two colors, where $n$ is the number of vertices and $\beta$ is the size of the largest bond. The other algorithm is for the case where the additional colors come at a higher cost, $D>1$: given $\Delta$ additional colors, where $\Delta$ is the maximum degree in the graph, the algorithm guarantees $O(\log D)$ competitiveness. As to lower bounds, we show that if the cost of the extra colors is $D>1$, no (randomized) algorithm can achieve a competitive ratio of $o(\log D)$. We also show that for bipartite graphs of unbounded bond size, any deterministic online algorithm has competitive ratio $\Omega(\min(D,\log n))$.