内存带宽瓶颈及其编译器的改进

Proceedings 14th International Parallel and Distributed Processing Symposium. IPDPS 2000 Pub Date : 2000-05-01 DOI:10.1109/IPDPS.2000.845980

C. Ding, K. Kennedy

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引用次数: 60

摘要

随着CPU和内存之间的速度差距越来越大，内存层次结构已经成为限制程序性能的主要因素。到目前为止，硬件和软件创新的主要焦点一直是克服延迟。然而，延迟容忍技术的出现，如非阻塞缓存和软件预取，开始了通过重叠和流水线内存传输来交换延迟带宽的过程。由于实际延迟是消耗带宽的反比，如果没有无限带宽，内存延迟是不能完全容忍的。这种观点给我们带来了两个问题。当前的机器是否提供足够的数据带宽?如果不是，是否可以重构程序以消耗更少的带宽?本文分两部分回答了这些问题。第一部分定义了一个新的基于带宽的性能模型，并演示了由于内存带宽不足导致的严重性能瓶颈。第二部分描述了一组新的编译器优化，用于减少程序的带宽消耗。

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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The memory of bandwidth bottleneck and its amelioration by a compiler

As the speed gap between CPU and memory widens, memory hierarchy has become the primary factor limiting program performance. Until now, the principal focus of hardware and software innovations has been overcoming latency. However, the advent of latency tolerance techniques such as non-blocking cache and software prefetching begins the process of trading bandwidth for latency by overlapping and pipelining memory transfers. Since actual latency is the inverse of the consumed bandwidth, memory latency cannot be fully tolerated without infinite bandwidth. This perspective has led us to two questions. Do current machines provide sufficient data bandwidth? If not, can a program be restructured to consume less bandwidth? This paper answers these questions in two parts. The first part defines a new bandwidth-based performance model and demonstrates the serious performance bottleneck due to the lack of memory bandwidth. The second part describes a new set of compiler optimizations for reducing bandwidth consumption of programs.

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Proceedings 14th International Parallel and Distributed Processing Symposium. IPDPS 2000

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