We study the space complexity of implementing long-lived and one-shot adaptive renaming from multi-reader multi-writer registers, in an asynchronous distributed system with n processes. As a result of an f-adaptive renaming algorithm each participating process gets a distinct name in the range {1,…,f(k)} provided k processes participate. Let f:{1,…,n}→N be a non-decreasing function satisfying f(1)≤n−1 and let d=max{x∣f(x)≤n−1}. We show that any non-deterministic solo-terminating long-lived f-adaptive renaming object requires d+1 registers. This implies a lower bound of n−c registers for long-lived (k+c)-adaptive renaming, which we observe is tight. We also prove a lower bound of ⌊c+22(n−c)⌋ registers for implementing any non-deterministic solo-terminating one-shot (k+c)-adaptive renaming. We provide two one-shot renaming algorithms: a wait-free algorithm and an obstruction-free algorithm. Each algorithm employs a parameter to depict the tradeoff between space and adaptivity. When these parameters are chosen appropriately, this results in a wait-free one-shot (23k2)-adaptive renaming algorithm from ⌈n⌉+1 registers, and an obstruction-free one-shot f-adaptive renaming algorithm from only min{n,x∣f(x)≥2n}+1 registers.
@article{arxiv.1603.04067,
title = {Space Bounds for Adaptive Renaming},
author = {Maryam Helmi and Lisa Higham and Philipp Woelfel},
journal= {arXiv preprint arXiv:1603.04067},
year = {2016}
}