Results 1 
4 of
4
Parallel Randomized Load Balancing
 In Symposium on Theory of Computing. ACM
, 1995
"... It is well known that after placing n balls independently and uniformly at random into n bins, the fullest bin holds \Theta(log n= log log n) balls with high probability. Recently, Azar et al. analyzed the following: randomly choose d bins for each ball, and then sequentially place each ball in the ..."
Abstract

Cited by 56 (8 self)
 Add to MetaCart
It is well known that after placing n balls independently and uniformly at random into n bins, the fullest bin holds \Theta(log n= log log n) balls with high probability. Recently, Azar et al. analyzed the following: randomly choose d bins for each ball, and then sequentially place each ball in the least full of its chosen bins [2]. They show that the fullest bin contains only log log n= log d + \Theta(1) balls with high probability. We explore extensions of this result to parallel and distributed settings. Our results focus on the tradeoff between the amount of communication and the final load. Given r rounds of communication, we provide lower bounds on the maximum load of \Omega\Gamma r p log n= log log n) for a wide class of strategies. Our results extend to the case where the number of rounds is allowed to grow with n. We then demonstrate parallelizations of the sequential strategy presented in Azar et al. that achieve loads within a constant factor of the lower bound for two ...
Allocating Weighted Jobs in Parallel
, 1997
"... It is well known that after placing m n balls independently and uniformly at random (i.u.r.) into n bins, the fullest bin contains \Theta(log n= log log n+ m n ) balls, with high probability. It is also known (see [Ste96]) that a maximum load of O \Gamma m n \Delta can be obtained for all m n ..."
Abstract

Cited by 12 (4 self)
 Add to MetaCart
It is well known that after placing m n balls independently and uniformly at random (i.u.r.) into n bins, the fullest bin contains \Theta(log n= log log n+ m n ) balls, with high probability. It is also known (see [Ste96]) that a maximum load of O \Gamma m n \Delta can be obtained for all m n if a ball is allocated in one (suitably chosen) of two (i.u.r.) bins. Stemann ([Ste96]) shows that r communication rounds suffice to guarantee a maximum load of maxf r p log n; O \Gamma m n \Delta g, with high probability. Adler et al. have shown in [ACMR95] that Stemanns protocol is optimal for constant r. In this paper we extend the above results in two directions: We generalize the lower bound to arbitrary r log log n. This implies that the result of Stemanns protocol is optimal for all r. Our main result is a generalization of Stemanns upper bound to weighted jobs: Let W A (W M ) denote the average (maximum) weight of the balls. Further let \Delta = W A =W M . Note that...
Parallel Continuous Randomized Load Balancing (Extended Abstract)
 In Proceedings of the Tenth ACM Symposium on Parallel Algorithms and Architectures
, 1998
"... ) Petra Berenbrink Department of Mathematics and Computer Science Paderborn University, Germany Email: pebe@unipaderborn.de Tom Friedetzky and Ernst W. Mayr y Institut fur Informatik Technische Universitat Munchen, Germany Email: (friedetzmayr)@informatik.tumuenchen.de Abstract Recently, ..."
Abstract

Cited by 8 (2 self)
 Add to MetaCart
) Petra Berenbrink Department of Mathematics and Computer Science Paderborn University, Germany Email: pebe@unipaderborn.de Tom Friedetzky and Ernst W. Mayr y Institut fur Informatik Technische Universitat Munchen, Germany Email: (friedetzmayr)@informatik.tumuenchen.de Abstract Recently, the subject of allocating tasks to servers has attracted much attention. There are several ways of distinguishing load balancing problems. There are sequential and parallel strategies, that is, placing the tasks one after the other or all of them in parallel. Another approach divides load balancing problems into continuous and static ones. In the continuous case new tasks are generated and consumed as time proceeds, in the second case the number of tasks is fixed. We present and analyze a parallel randomized continuous load balancing algorithm in a scenario where n processors continuously generate and consume tasks according to some given probability distribution. Each processor initiates l...
Simple Competitive Request Scheduling Strategies
 in 11th ACM Symposium on Parallel Architectures and Algorithms
, 1999
"... In this paper we study the problem of scheduling realtime requests in distributed data servers. We assume the time to be divided into time steps of equal length called rounds. During every round a set of requests arrives at the system, and every resource is able to fulfill one request per round. Ev ..."
Abstract

Cited by 2 (0 self)
 Add to MetaCart
In this paper we study the problem of scheduling realtime requests in distributed data servers. We assume the time to be divided into time steps of equal length called rounds. During every round a set of requests arrives at the system, and every resource is able to fulfill one request per round. Every request specifies two (distinct) resources and requires to get access to one of them. Furthermore, every request has a deadline of d, i.e. a request that arrives in round t has to be fulfilled during round t +d 1 at the latest. The number of requests which arrive during some round and the two alternative resources of every request are selected by an adversary. The goal is to maximize the number of requests that are fulfilled before their deadlines expire. We examine the scheduling problem in an online setting, i.e. new requests continuously arrive at the system, and we have to determine online an assignment of the requests to the resources in such a way that every resource has to fulfil...