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引用次数: 24
摘要
本文建立了容忍最坏情况的分布式原子读/写存储实现的最佳情况时间复杂度的严格界限。我们研究异步健壮实现,其中一个写入器和一组读取器进程(客户机)访问通过一组2t+b+1服务器进程实现的原子存储,其中t可能失败:其中b可能是恶意的,其余可能崩溃。我们将幸运操作(读或写)定义为同步运行且无争用的操作。在实践中,人们常常认为幸运手术是最常见的。我们确定了一个幸运操作可以快速的确切条件,即在没有数据认证的一次通信往返中加速。我们表明,每一个幸运的写(回复)。尽管速度很快(如阅读)。, f)实际失败,当且仅当fw+f - r -b
This paper establishes tight bounds on the best-case time-complexity of distributed atomic read/write storage implementations that tolerate worst-case conditions. We study asynchronous robust implementations where a writer and a set of reader processes (clients) access an atomic storage implemented over a set of 2t+b+1 server processes of which t can fail: b of these can be malicious and the rest can crash. We define a lucky operation (read or write) as one that runs synchronously and without contention. It is often argued in practice that lucky operations are the most frequent. We determine the exact conditions under which a lucky operation can be fast, namely expedited in one-communication round-trip with no data authentication. We show that every lucky write (resp., read) can be fast despite fw (resp., fr) actual failures, if and only if fw+f rlest-b
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