基于随机化的受保护缓存架构的系统分析

Antoon Purnal, Lukas Giner, D. Gruss, I. Verbauwhede
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引用次数: 57

摘要

最近的安全缓存设计旨在通过随机化从内存地址到缓存集的映射来减轻侧信道攻击。当供应商调查这些缓存的部署时,了解它们的实际安全性是至关重要的。在本文中,我们将现有的基于随机化的安全缓存整合到一个通用缓存模型中。然后,我们通过将现有设计(包括CEASER-S和SCATTERCACHE)映射到该模型的实例,全面分析了它们的安全性。我们使用新颖的PRIME+PRUNE+PROBE技术为随机缓存量身定制缓存攻击,并使用突发访问,自引导和多步骤分析对其进行优化。PRIME+ PRUNE+PROBE构建概率但可靠的驱逐集,使以前被认为在计算上不可行的攻击成为可能。我们还模拟了端到端攻击,从易受攻击的AES实现中泄露机密。最后,对CEASER-S的一个案例研究表明,随机化算法中的密码弱点可能导致完全的安全颠覆。我们的系统分析为随机缓存提供了更现实和可比较的安全级别。当我们量化设计参数如何影响安全级别时,我们的工作为安全缓存设计的未来工作带来了重要的结论。
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Systematic Analysis of Randomization-based Protected Cache Architectures
Recent secure cache designs aim to mitigate side-channel attacks by randomizing the mapping from memory addresses to cache sets. As vendors investigate deployment of these caches, it is crucial to understand their actual security.In this paper, we consolidate existing randomization-based secure caches into a generic cache model. We then comprehensively analyze the security of existing designs, including CEASER-S and SCATTERCACHE, by mapping them to instances of this model. We tailor cache attacks for randomized caches using a novel PRIME+PRUNE+PROBE technique, and optimize it using burst accesses, bootstrapping, and multi-step profiling. PRIME+ PRUNE+PROBE constructs probabilistic but reliable eviction sets, enabling attacks previously assumed to be computationally infeasible. We also simulate an end-to-end attack, leaking secrets from a vulnerable AES implementation. Finally, a case study of CEASER-S reveals that cryptographic weaknesses in the randomization algorithm can lead to a complete security subversion.Our systematic analysis yields more realistic and comparable security levels for randomized caches. As we quantify how design parameters influence the security level, our work leads to important conclusions for future work on secure cache designs.
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