English

Fusible HSTs and the randomized k-server conjecture

Data Structures and Algorithms 2021-07-30 v3 Metric Geometry Probability

Abstract

We exhibit an O((logk)6)O((\log k)^6)-competitive randomized algorithm for the kk-server problem on any metric space. It is shown that a potential-based algorithm for the fractional kk-server problem on hierarchically separated trees (HSTs) with competitive ratio f(k)f(k) can be used to obtain a randomized algorithm for any metric space with competitive ratio f(k)2O((logk)2)f(k)^2 O((\log k)^2). Employing the O((logk)2)O((\log k)^2)-competitive algorithm for HSTs from our joint work with Bubeck, Cohen, Lee, and M\k{a}dry (2017) yields the claimed bound. The best previous result independent of the geometry of the underlying metric space is the 2k12k-1 competitive ratio established for the deterministic work function algorithm by Koutsoupias and Papadimitriou (1995). Even for the special case when the underlying metric space is the real line, the best known competitive ratio was kk. Since deterministic algorithms can do no better than kk on any metric space with at least k+1k+1 points, this establishes that for every metric space on which the problem is non-trivial, randomized algorithms give an exponential improvement over deterministic algorithms.

Keywords

Cite

@article{arxiv.1711.01789,
  title  = {Fusible HSTs and the randomized k-server conjecture},
  author = {James R. Lee},
  journal= {arXiv preprint arXiv:1711.01789},
  year   = {2021}
}

Comments

There is a gap in the argument in Section 5.3.2 that requires a substantial revision to correct. See the author's web page for up to date information

R2 v1 2026-06-22T22:36:55.706Z