Malicious Node Identification in Coded Distributed Storage Systems under Pollution Attacks

IF 0.7 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS
R. Gaeta, Marco Grangetto
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引用次数: 1

Abstract

In coding-based distributed storage systems (DSSs), a set of storage nodes (SNs) hold coded fragments of a data unit that collectively allow one to recover the original information. It is well known that data modification (a.k.a. pollution attack) is the Achilles’ heel of such coding systems; indeed, intentional modification of a single coded fragment has the potential to prevent the reconstruction of the original information because of error propagation induced by the decoding algorithm. The challenge we take in this work is to devise an algorithm to identify polluted coded fragments within the set encoding a data unit and to characterize its performance. To this end, we provide the following contributions: (i) We devise MIND (Malicious node IdeNtification in DSS), an algorithm that is general with respect to the encoding mechanism chosen for the DSS, it is able to cope with a heterogeneous allocation of coded fragments to SNs, and it is effective in successfully identifying polluted coded fragments in a low-redundancy scenario; (ii) We formally prove both MIND termination and correctness; (iii) We derive an accurate analytical characterization of MIND performance (hit probability and complexity); (iv) We develop a C++ prototype that implements MIND to validate the performance predictions of the analytical model. Finally, to show applicability of our work, we define performance and robustness metrics for an allocation of coded fragments to SNs and we apply the results of the analytical characterization of MIND performance to select coded fragments allocations yielding robustness to collusion as well as the highest probability to identify actual attackers.
污染攻击下编码分布式存储系统的恶意节点识别
在基于编码的分布式存储系统(DSSs)中,一组存储节点(SNs)保存数据单元的编码片段,这些片段共同允许人们恢复原始信息。众所周知,数据修改(又称污染攻击)是这类编码系统的致命弱点;事实上,对单个编码片段的有意修改有可能由于解码算法引起的错误传播而阻止原始信息的重建。我们在这项工作中面临的挑战是设计一种算法来识别编码数据单元的集合中受污染的编码片段并表征其性能。为此,我们提供了以下贡献:(i)我们设计了MIND(恶意节点识别),这是一种针对DSS选择的编码机制的通用算法,它能够处理编码片段到SNs的异构分配,并且在低冗余场景下有效地成功识别受污染的编码片段;(ii)我们正式证明MIND终止和正确性;(iii)我们得出了MIND性能的准确分析特征(命中概率和复杂性);(iv)我们开发了一个实现MIND的c++原型来验证分析模型的性能预测。最后,为了展示我们工作的适用性,我们定义了编码片段分配到SNs的性能和鲁棒性指标,并应用MIND性能分析表征的结果来选择编码片段分配,从而产生对共谋的鲁棒性以及识别实际攻击者的最高概率。
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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来源期刊
CiteScore
2.10
自引率
0.00%
发文量
9
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