保护缓存：创建有噪声的侧通道

IF 1.4 3区计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Computer Architecture Letters Pub Date : 2023-06-27 DOI:10.1109/LCA.2023.3289710

Fernando Mosquera;Krishna Kavi;Gayatri Mehta;Lizy John

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引用次数: 0

摘要

微体系结构创新，如深度缓存层次结构、无序执行、分支预测和推测执行，使处理器的设计能够满足不断增长的性能需求。然而，这些创新无意中引入了漏洞，这些漏洞被侧通道攻击和依赖推测执行的攻击所利用。在保持性能的同时减少攻击一直是一个挑战。在这封信中，我们提出了一种模糊缓存定时的方法，使侧通道攻击更难成功。我们使用带有随机化的小型保护缓存创建虚假缓存命中，并通过随机驱逐缓存行创建虚假缓存未命中。我们表明，我们的错误命中和错误未命中造成的性能损失非常小，我们的混淆会使常见的侧通道攻击（如Prime&Probe、Flush&Reload或Evict&Time）难以成功。

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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Guard Cache: Creating Noisy Side-Channels

Microarchitectural innovations such as deep cache hierarchies, out-of-order execution, branch prediction and speculative execution have made possible the design of processors that meet ever-increasing demands for performance. However, these innovations have inadvertently introduced vulnerabilities, which are exploited by side-channel attacks and attacks relying on speculative executions. Mitigating the attacks while preserving the performance has been a challenge. In this letter we present an approach to obfuscate cache timing, making it more difficult for side-channel attacks to succeed. We create false cache hits using a small Guard Cache with randomization, and false cache misses by randomly evicting cache lines. We show that our false hits and false misses cause very minimal performance penalties and our obfuscation can make it difficult for common side-channel attacks such as Prime &Probe, Flush &Reload or Evict &Time to succeed.

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来源期刊

IEEE Computer Architecture Letters COMPUTER SCIENCE, HARDWARE & ARCHITECTURE-

CiteScore

4.60

自引率

4.30%

发文量

期刊介绍： IEEE Computer Architecture Letters is a rigorously peer-reviewed forum for publishing early, high-impact results in the areas of uni- and multiprocessor computer systems, computer architecture, microarchitecture, workload characterization, performance evaluation and simulation techniques, and power-aware computing. Submissions are welcomed on any topic in computer architecture, especially but not limited to: microprocessor and multiprocessor systems, microarchitecture and ILP processors, workload characterization, performance evaluation and simulation techniques, compiler-hardware and operating system-hardware interactions, interconnect architectures, memory and cache systems, power and thermal issues at the architecture level, I/O architectures and techniques, independent validation of previously published results, analysis of unsuccessful techniques, domain-specific processor architectures (e.g., embedded, graphics, network, etc.), real-time and high-availability architectures, reconfigurable systems.