FO Value Discovery and Partial Vertex Cover Discovery
Abstract
We study solution discovery in the token-sliding model from a logical and cost-value optimization perspective. In solution discovery, we are given a graph, an initial placement of k tokens, and a movement budget b. The task is to find a reachable target configuration satisfying a prescribed condition. Our results are inspired by Partial Vertex Cover Discovery, where the condition is that the~k tokens cover at least t edges of the input graph. This objective is not merely a sum of independent occupied vertex contributions: each selected vertex contributes its degree, but edges with both endpoints selected have to be subtracted once. To capture this phenomenon, we introduce FO Value Discovery, an optimization problem in which the value of a selected tuple is given by unary vertex weights together with first-order definable correction terms. We further generalize the setting to FO Cost-Value Decision, where vertices carry both costs and values, and the task is to decide whether there is a tuple whose first-order value expression reaches a prescribed value threshold while respecting a cost bound. Finally, we study the parameterized complexity of Partial Vertex Cover Discovery and Vertex Cover Discovery. As a consequence of the logical meta-theorems, we obtain fixed-parameter tractability of Partial Vertex Cover Discovery on several graph classes, including classes of locally bounded cliquewidth. We also show that Partial Vertex Cover Discovery is W[1]-hard parameterized by k+b and fixed-parameter tractable on d-degenerate graphs parameterized by k+d. For Vertex Cover Discovery, we prove NP-hardness on planar graphs, W[1]-hardness parameterized by the clique cover number, even when a clique cover is supplied with the input, and W[1]-hardness with respect to parameter cutwidth.
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