Exploring the performance implications of memory safety primitives in many-core processors executing multi-threaded workloads

Proceedings of the Fourth Workshop on Hardware and Architectural Support for Security and Privacy Pub Date : 2015-06-14 DOI:10.1145/2768566.2768572

Masab Ahmad, Syed Kamran Haider, Farrukh Hijaz, Marten van Dijk, O. Khan

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引用次数: 3

Abstract

Security is a vital consideration for today's processor architectures, both at the software and hardware layers. However, security schemes are known to incur significant performance overheads. For example, buffer overflow protection schemes perform software checks for bounds on program data structures, and incur performance overheads that are up to several orders of magnitude. To mitigate these overheads, prior works focus on either changing the security scheme itself, or selectively apply the security scheme to minimize program vulnerabilities. Most of these works also focus primarily on single core processors, with no prior work done in the context of multicore processors. In this paper, we show how increasing thread counts can help hide the latency overheads of security schemes. We also analyze the architectural implications in the context of multucores, and the insights and challenges associated with applying these security schemes on mutithreaded workloads.

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探索在执行多线程工作负载的多核处理器中内存安全原语的性能含义

安全性是当今处理器架构的一个重要考虑因素，无论是在软件层还是硬件层。然而，众所周知，安全方案会导致显著的性能开销。例如，缓冲区溢出保护方案对程序数据结构的边界执行软件检查，并导致高达几个数量级的性能开销。为了减少这些开销，以前的工作集中在更改安全方案本身，或者有选择地应用安全方案来最小化程序漏洞。这些工作中的大多数也主要集中在单核处理器上，没有在多核处理器上下文中做过的工作。在本文中，我们将展示增加线程计数如何帮助隐藏安全方案的延迟开销。我们还分析了多线程上下文中的体系结构含义，以及在多线程工作负载上应用这些安全方案的见解和挑战。

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 of the Fourth Workshop on Hardware and Architectural Support for Security and Privacy

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