原生动物:自适应粒度缓存一致性

Hongzhou Zhao, Arrvindh Shriraman, Snehasish Kumar, S. Dwarkadas
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引用次数: 32

摘要

最先进的多处理器缓存层次结构将缓存组织中固定粒度的使用传播到一致性协议的设计中。不幸的是,通常选择固定粒度来匹配应用程序范围内的平均空间局部性,不仅会导致浪费带宽来满足单个线程的访问需求,而且还会导致共享数据的不必要的一致性流量。额外的带宽对并行应用程序的可伸缩性和总体能耗都有直接影响。在本文中,我们提出了Protozoa的设计,这是一组相干协议,可以消除不必要的相干流量并将数据移动匹配到应用程序的空间位置。Protozoa继续以传统的固定缓存线粒度维护元数据,同时1)支持可变读写缓存粒度,以便数据传输与应用程序的空间粒度相匹配;2)在写丢失请求的粒度上失效,以便不相关数据的读取器可以与写入器共存;3)潜在地支持缓存线内多个不重叠的写入器。从而避免了读写和读写错误共享的传统乒乓效应。我们的评估表明,原生动物持续降低失误率,提高实际利用的传输数据的比例。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Protozoa: adaptive granularity cache coherence
State-of-the-art multiprocessor cache hierarchies propagate the use of a fixed granularity in the cache organization to the design of the coherence protocol. Unfortunately, the fixed granularity, generally chosen to match average spatial locality across a range of applications, not only results in wasted bandwidth to serve an individual thread's access needs, but also results in unnecessary coherence traffic for shared data. The additional bandwidth has a direct impact on both the scalability of parallel applications and overall energy consumption. In this paper, we present the design of Protozoa, a family of coherence protocols that eliminate unnecessary coherence traffic and match data movement to an application's spatial locality. Protozoa continues to maintain metadata at a conventional fixed cache line granularity while 1) supporting variable read and write caching granularity so that data transfer matches application spatial granularity, 2) invalidating at the granularity of the write miss request so that readers to disjoint data can co-exist with writers, and 3) potentially supporting multiple non-overlapping writers within the cache line, thereby avoiding the traditional ping-pong effect of both read-write and write-write false sharing. Our evaluation demonstrates that Protozoa consistently reduce miss rate and improve the fraction of transmitted data that is actually utilized.
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