Bomberman:在设计阶段定义和击败滴答作响的硬件定时炸弹

Timothy Trippel, K. Shin, K. Bush, Matthew Hicks
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引用次数: 8

摘要

为了应对不断增加的设计复杂性,集成电路设计人员增加了设计团队的规模和对第三方知识产权(IP)的依赖。两者都是以信任为代价的:在计算上不可能彻底验证设计不受所有可能的恶意修改(即硬件木马)的影响。更糟糕的是,与软件不同,硬件修改是永久性的:硬件没有“补丁”机制;而且功能强大:它们是颠覆上层软件的立足点。为了应对这种威胁,之前的工作使用静态和动态分析技术来验证硬件设计是无木马的。不幸的是,研究人员继续揭示这些“一刀切”的、基于启发式的方法的弱点。我们不是试图检测所有可能的硬件木马,而是采取分而治之的方式解决硬件木马威胁的第一步:定义和消除定时炸弹木马(ttt),迫使攻击者实现更大的木马设计,通过现有的验证和侧通道防御可以检测到。像许多系统级软件防御(例如,地址空间布局随机化(ASLR)和数据执行预防(DEP)),我们的目标是系统地压缩硬件攻击者的设计空间。首先,我们根据ttt的功能行为构造了ttt的定义。接下来,我们将此定义转换为在硬件中实现TTT行为所需的基本组件。使用这些组件,我们将所有已知ttt的集合扩展到总共六个变体—包括未见的变体。利用我们的定义,我们设计并实现了一个特定于ttt的动态验证工具链扩展,称为Bomber-man。使用四种现实世界的硬件设计,我们展示了Bomberman检测所有TTT变体的能力,其中先前的防御失败,误报率<1.2%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bomberman: Defining and Defeating Hardware Ticking Timebombs at Design-time
To cope with ever-increasing design complexities, integrated circuit designers increase both the size of their design teams and their reliance on third-party intellectual property (IP). Both come at the expense of trust: it is computationally infeasible to exhaustively verify that a design is free of all possible malicious modifications (i.e., hardware Trojans). Making matters worse, unlike software, hardware modifications are permanent: there is no "patching" mechanism for hardware; and powerful: they serve as a foothold for subverting software that sits above.To counter this threat, prior work uses both static and dynamic analysis techniques to verify hardware designs are Trojan-free. Unfortunately, researchers continue to reveal weaknesses in these "one-size-fits-all", heuristic-based approaches. Instead of attempting to detect all possible hardware Trojans, we take the first step in addressing the hardware Trojan threat in a divide-and-conquer fashion: defining and eliminating Ticking Timebomb Trojans (TTTs), forcing attackers to implement larger Trojan designs detectable via existing verification and side-channel defenses. Like many system-level software defenses (e.g., Address Space Layout Randomization (ASLR) and Data Execution Prevention (DEP)), our goal is to systematically constrict the hardware attacker’s design space.First, we construct a definition of TTTs derived from their functional behavior. Next, we translate this definition into fundamental components required to realize TTT behavior in hardware. Using these components, we expand the set of all known TTTs to a total of six variants—including unseen variants. Leveraging our definition, we design and implement a TTT-specific dynamic verification toolchain extension, called Bomber-man. Using four real-world hardware designs, we demonstrate Bomberman’s ability to detect all TTT variants, where previous defenses fail, with <1.2% false positives.
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