Abstract
k-Set agreement is a central problem of fault-tolerant distributed computing. Considering a set of n processes, where up to t may commit failures, let us assume that each process proposes a value. The problem consists in defining an algorithm such that each non-faulty process decides a value, at most k different values are decided, and the decided values satisfy some context-depending validity condition. Algorithms solving k-set agreement in synchronous message-passing systems have been proposed for different failure models (mainly process crashes, and process Byzantine failures). Differently, k-set agreement cannot be solved in failure-prone asynchronous message-passing systems when t≥k. To circumvent this impossibility an asynchronous system must be enriched with additional computational power.Assuming t≥k, this paper presents two distributed algorithms that solve k-set agreement in asynchronous message-passing systems where up to t processes may commit crash failures (first algorithm) or more severe Byzantine failures (second algorithm). To circumvent k-set agreement impossibility, this article considers that the underlying system is enriched with the computability power provided by randomization. Interestingly, the algorithm that copes with Byzantine failures is signature-free, and ensures that no value proposed only by Byzantine processes can be decided by a non-faulty process. Both algorithms share basic design principles.
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