Consistent Hashing with Bounded Loads
Abstract
Designing algorithms for balanced allocation of clients to servers in dynamic settings is a challenging problem for a variety of reasons. Both servers and clients may be added and/or removed from the system periodically, and the main objectives of allocation algorithms are: the uniformity of the allocation, and the number of moves after adding or removing a server or a client. The most popular solution for our dynamic settings is Consistent Hashing. However, the load balancing of consistent hashing is no better than a random assignment of clients to servers, so with of each, we expect many servers to be overloaded with clients. In this paper, with clients and servers, we get a guaranteed max-load of 2 while only moving an expected constant number of clients for each update. We take an arbitrary user specified balancing parameter . With balls and bins in the system, we want no load above . Meanwhile we want to bound the expected number of balls that have to be moved when a ball or server is added or removed. Compared with general lower bounds without capacity constraints, we show that in our algorithm when a ball or bin is inserted or deleted, the expected number of balls that have to be moved is increased only by a multiplicative factor for (Theorem 4) and by a factor for (Theorem 3). Technically, the latter bound is the most challenging to prove. It implies that we for superconstant only pay a negligible cost in extra moves. We also get the same bounds for the simpler problem where we instead of a user specified balancing parameter have a fixed bin capacity for all bins.
Cite
@article{arxiv.1608.01350,
title = {Consistent Hashing with Bounded Loads},
author = {Vahab Mirrokni and Mikkel Thorup and Morteza Zadimoghaddam},
journal= {arXiv preprint arXiv:1608.01350},
year = {2017}
}