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The preemptive resource allocation problem

Author

Listed:
  • Kanthi Sarpatwar

    (IBM T. J. Watson Research Center)

  • Baruch Schieber

    (New Jersey Institute of Technology)

  • Hadas Shachnai

    (Technion)

Abstract

We revisit a classical scheduling model to incorporate modern trends in data center networks and cloud services. Addressing some key challenges in the allocation of shared resources to user requests (jobs) in such settings, we consider the following variants of the classic resource allocation problem (RAP). The input to our problems is a set J of jobs and a set M of homogeneous hosts, each has an available amount of some resource. Assuming that time is slotted, a job is associated with a release time, a due date, a weight and a given length, as well as its resource requirement. A feasible schedule is an allocation of the resource to a subset of the jobs, satisfying the job release times/due dates as well as the resource constraints. A crucial distinction between classic RAP and our problems is that we allow preemption and migration of jobs, motivated by virtualization techniques. We consider two natural objectives: throughput maximization (MaxT), which seeks a maximum weight subset of the jobs that can be feasibly scheduled on the hosts in M, and resource minimization (MinR), that is finding the minimum number of (homogeneous) hosts needed to feasibly schedule all jobs. Both problems are known to be NP-hard. We first present an $$\Omega (1)$$ Ω ( 1 ) -approximation algorithm for MaxT instances where time-windows form a laminar family of intervals. We then extend the algorithm to handle instances with arbitrary time-windows, assuming there is sufficient slack for each job to be completed. For MinR we study a more general setting with d resources and derive an $$O(\log d)$$ O ( log d ) -approximation for any fixed $$d \ge 1$$ d ≥ 1 , under the assumption that time-windows are not too small. This assumption can be removed leading to a slightly worse ratio of $$O(\log d\log ^* T)$$ O ( log d log ∗ T ) , where T is the maximum due date of any job.

Suggested Citation

  • Kanthi Sarpatwar & Baruch Schieber & Hadas Shachnai, 2024. "The preemptive resource allocation problem," Journal of Scheduling, Springer, vol. 27(1), pages 103-118, February.
    • Handle: RePEc:spr:jsched:v:27:y:2024:i:1:d:10.1007_s10951-023-00786-6
    DOI: 10.1007/s10951-023-00786-6
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    References listed on IDEAS

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    1. Frieze, A. M. & Clarke, M. R. B., 1984. "Approximation algorithms for the m-dimensional 0-1 knapsack problem: Worst-case and probabilistic analyses," European Journal of Operational Research, Elsevier, vol. 15(1), pages 100-109, January.
    2. Lisa Fleischer & Michel X. Goemans & Vahab S. Mirrokni & Maxim Sviridenko, 2011. "Tight Approximation Algorithms for Maximum Separable Assignment Problems," Mathematics of Operations Research, INFORMS, vol. 36(3), pages 416-431, August.
    3. Shinjini Pandey & Goutam Dutta & Harit Joshi, 2017. "Survey on Revenue Management in Media and Broadcasting," Interfaces, INFORMS, vol. 47(3), pages 195-213, June.
    4. A.A. Ageev & M.I. Sviridenko, 2004. "Pipage Rounding: A New Method of Constructing Algorithms with Proven Performance Guarantee," Journal of Combinatorial Optimization, Springer, vol. 8(3), pages 307-328, September.
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