TY - JOUR

T1 - Fair circulation of a token

AU - Ikeda, Satoshi

AU - Kubo, Izumi

AU - Okumoto, Norihiro

AU - Yamashita, Masafumi

PY - 2002/4/1

Y1 - 2002/4/1

N2 - Suppose that a distributed system is modeled by an undirected graph G = (V, E), where V and E, respectively, are the sets of processes and communication links. Israeli and Jalfon [6] proposed a simple self-stabilizing mutual exclusion algorithm: A token is circulated among the processes (i.e., vertices) and a process can access the critical section only when it holds the token. In order to guarantee equal access change to all processes, the token circulation is desired to be fair in the sense that all processes have the same probability of holding the token. However, the Israeli-Jalfon token circulation scheme does not meet the requirement. This paper proposes a new scheme for making it fair. We evaluate the average of the longest waiting times in terms of the cover time and show an O(deg(G)n 2) upper bound on the cover time for our scheme, where n and deg(G) are the number of processes and the maximum degree of G, respectively. The same (tight) upper bound is known for the Israeli-Jalfon scheme.

AB - Suppose that a distributed system is modeled by an undirected graph G = (V, E), where V and E, respectively, are the sets of processes and communication links. Israeli and Jalfon [6] proposed a simple self-stabilizing mutual exclusion algorithm: A token is circulated among the processes (i.e., vertices) and a process can access the critical section only when it holds the token. In order to guarantee equal access change to all processes, the token circulation is desired to be fair in the sense that all processes have the same probability of holding the token. However, the Israeli-Jalfon token circulation scheme does not meet the requirement. This paper proposes a new scheme for making it fair. We evaluate the average of the longest waiting times in terms of the cover time and show an O(deg(G)n 2) upper bound on the cover time for our scheme, where n and deg(G) are the number of processes and the maximum degree of G, respectively. The same (tight) upper bound is known for the Israeli-Jalfon scheme.

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U2 - 10.1109/71.995817

DO - 10.1109/71.995817

M3 - Article

AN - SCOPUS:0036530296

VL - 13

SP - 367

EP - 372

JO - IEEE Transactions on Parallel and Distributed Systems

JF - IEEE Transactions on Parallel and Distributed Systems

SN - 1045-9219

IS - 4

ER -