Scalable multicomputer object spaces: a foundation for high performance systems

Proceedings. Third Working Conference on Massively Parallel Programming Models (Cat. No.97TB100228) Pub Date : 1997-11-12 DOI:10.1109/MPPM.1997.715974

S. Blackburn, R. Stanton

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引用次数: 2

Abstract

The development of scalable architectures at store levels of a layered model has concentrated on processor parallelism balanced against scalable memory bandwidth, primarily through distributed memory structures of one kind or another. A great deal of attention has been paid to hiding the distribution of memory to produce a single store image across the memory structure. It is unlikely that the distribution and concurrency aspects of scalable computing can be completely hidden at that level. This paper argues for a store layer which respects the need for caching and replication, and to do so at an "object" level granularity of memory use. These facets are interrelated through atomic processes, leading to an interface for the store which is strongly transactional in character. The paper describes the experimental performance of such a layer on a scalable multi-computer architecture. The behaviour of the store supports the view that a scalable cached "transactional" store architecture is a practical objective for high performance based on parallel computation across distributed memories.

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可伸缩的多计算机对象空间:高性能系统的基础

在分层模型的存储层上开发可伸缩的体系结构主要是通过一种或另一种分布式内存结构，集中在处理器并行性与可伸缩内存带宽之间的平衡上。为了在整个存储结构中产生一个单一的存储图像，人们已经对隐藏内存分布进行了大量的研究。可扩展计算的分布和并发性方面不太可能完全隐藏在该级别。本文提出了一个存储层，它尊重缓存和复制的需要，并在内存使用的“对象”级别粒度上这样做。这些方面通过原子过程相互关联，从而形成一个具有强事务性的存储接口。本文描述了该层在可扩展多计算机体系结构上的实验性能。存储的行为支持这样一种观点，即可扩展的缓存“事务性”存储架构是基于跨分布式内存并行计算的高性能的实际目标。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings. Third Working Conference on Massively Parallel Programming Models (Cat. No.97TB100228)

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