Abstract

The problem addressed here concerns a set of isolated processors, some unknown subset of which may be faulty, that communicate only by means of two-party messages. Each nonfaulty processor has a private value of information that must be communicated to each other nonfaulty processor. Nonfaulty processors always communicate honestly, whereas faulty processors may lie. The problem is to devise an algorithm in which processors communicate their own values and relay values received from others that allows each nonfaulty processor to infer a value for each other processor. The value inferred for a nonfaulty processor must be that processor's private value, and the value inferred for a faulty one must be consistent with the corresponding value inferred by each other nonfaulty processor. It is shown that the problem is solvable for, and only for, n ≥ 3 m + 1, where m is the number of faulty processors and n is the total number. It is also shown that if faulty processors can refuse to pass on information but cannot falsely relay information, the problem is solvable for arbitrary n ≥ m ≥ 0. This weaker assumption can be approximated in practice using cryptographic methods.

Keywords

RelayValue (mathematics)Computer scienceSet (abstract data type)ArithmeticParallel computingMathematicsProgramming languagePhysicsPower (physics)

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Publication Info

Year
1980
Type
article
Volume
27
Issue
2
Pages
228-234
Citations
2342
Access
Closed

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Marshall C. Pease, Robert E. Shostak, Leslie Lamport (1980). Reaching Agreement in the Presence of Faults. Journal of the ACM , 27 (2) , 228-234. https://doi.org/10.1145/322186.322188

Identifiers

DOI
10.1145/322186.322188