English

Finite Pinwheel Scheduling: the k-Visits Problem

Data Structures and Algorithms 2025-10-21 v2

Abstract

Pinwheel Scheduling is a fundamental scheduling problem, in which each task ii is associated with a positive integer did_i, and the objective is to schedule one task per time slot, ensuring each task perpetually appears at least once in every did_i time slots. Although conjectured to be PSPACE-complete, it remains open whether Pinwheel Scheduling is NP-hard (unless a compact input encoding is used) or even contained in NP. We introduce k-Visits, a finite version of Pinwheel Scheduling, where given n deadlines, the goal is to schedule each task exactly k times. While we observe that the 1-Visit problem is trivial, we prove that 2-Visits is strongly NP-complete through a surprising reduction from Numerical 3-Dimensional Matching (N3DM). As intermediate steps in the reduction, we define NP-complete variants of N3DM which may be of independent interest. We further extend our strong NP-hardness result to a generalization of k-Visits k2k\geq 2 in which the deadline of each task may vary throughout the schedule, as well as to a similar generalization of Pinwheel Scheduling, thus making progress towards settling the complexity of Pinwheel Scheduling. Additionally, we prove that 2-Visits can be solved in linear time if all deadlines are distinct, rendering it one of the rare natural problems which exhibit the interesting dichotomy of being in P if their input is a set and NP-complete if the input is a multiset. We achieve this through a Turing reduction from 2-Visits to a variation of N3DM, which we call Position Matching. Based on this reduction, we also show an FPT algorithm for 2-Visits parameterized by a value related to how close the input deadlines are to each other, as well as a linear-time algorithm for instances with up to two distinct deadlines.

Keywords

Cite

@article{arxiv.2507.11681,
  title  = {Finite Pinwheel Scheduling: the k-Visits Problem},
  author = {Sotiris Kanellopoulos and Christos Pergaminelis and Maria Kokkou and Euripides Markou and Aris Pagourtzis},
  journal= {arXiv preprint arXiv:2507.11681},
  year   = {2025}
}
R2 v1 2026-07-01T04:03:08.308Z