高并行复杂度图和内存硬函数

J. Alwen, Vladimir Serbinenko
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引用次数: 84

摘要

我们开发了新的理论工具来证明并行计算模型中某些函数(平摊)复杂度的下界。我们应用这些工具在并行随机Oracle模型(pROM)中构造了一类具有高平摊内存复杂度的函数;一种允许批量“同时”查询的标准ROM的变体。特别是,我们获得了一种新的,更健壮的记忆硬函数(MHF)类型;一种安全原语,最近在实践中作为对抗对安全相关功能的暴力攻击的有效手段而得到认可。在此过程中,我们还展示了先前mhf定义的一个重要缺点,并给出了解决该问题的新定义。我们开发的工具代表了强大的卵石范式(最初由Hewitt和Paterson [HP70]和Cook [Coo73]引入)对简单直观的并行设置的适应。我们定义了一个简单的图形博弈Gp,旨在以直观的方式抽象并行计算。作为概念上的贡献,我们定义了一种称为“累积复杂性”(CC)的图的卵石复杂性度量,并展示了它如何克服过去使用的更传统的复杂性度量所表现出的一个关键缺点(在并行设置中)。作为一项主要的技术贡献,我们给出了一个恒定度图族的明确构造,其Gp中的CC接近于任何相等大小的图的多对数因子内的最大值(类似于Tarjan等人[PTC76, LT82]的连续卵石游戏的图)。最后,对于给定的图G和相关函数fG,我们根据博弈Gp中G的CC导出了pROM中fG的平摊内存复杂度的下界。
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High Parallel Complexity Graphs and Memory-Hard Functions
We develop new theoretical tools for proving lower-bounds on the (amortized) complexity of certain functions in models of parallel computation. We apply the tools to construct a class of functions with high amortized memory complexity in the *parallel* Random Oracle Model (pROM); a variant of the standard ROM allowing for batches of *simultaneous* queries. In particular we obtain a new, more robust, type of Memory-Hard Functions (MHF); a security primitive which has recently been gaining acceptance in practice as an effective means of countering brute-force attacks on security relevant functions. Along the way we also demonstrate an important shortcoming of previous definitions of MHFs and give a new definition addressing the problem. The tools we develop represent an adaptation of the powerful pebbling paradigm (initially introduced by Hewitt and Paterson [HP70] and Cook [Coo73]) to a simple and intuitive parallel setting. We define a simple pebbling game Gp over graphs which aims to abstract parallel computation in an intuitive way. As a conceptual contribution we define a measure of pebbling complexity for graphs called *cumulative complexity* (CC) and show how it overcomes a crucial shortcoming (in the parallel setting) exhibited by more traditional complexity measures used in the past. As a main technical contribution we give an explicit construction of a constant in-degree family of graphs whose CC in Gp approaches maximality to within a polylogarithmic factor for any graph of equal size (analogous to the graphs of Tarjan et. al. [PTC76, LT82] for sequential pebbling games). Finally, for a given graph G and related function fG, we derive a lower-bound on the amortized memory complexity of fG in the pROM in terms of the CC of G in the game Gp.
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