基于差分私有填充的封闭云数据库双目标SQL优化

IF 2.2 2区 计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS
Yaxing Chen, Qinghua Zheng, Zheng Yan
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引用次数: 0

摘要

支持硬件的enclave已被应用于有效地加强云数据库服务中的数据安全和隐私保护。然而,据报道,这种封闭的系统会遭受基于I/ o大小(也称为通信量)的侧信道攻击。尽管差分私有填充作为一种主要方法被用来防御这些攻击,但它引入了一个具有挑战性的双目标参数查询优化(BPQO)问题,目前的解决方案仍然不令人满意。具体来说,BPQO的目标是找到一个在查询性能和隐私损失之间进行权衡的帕累托最优计划;现有的解决方案存在计算效率低、云资源浪费大的问题。在本文中,我们提出了一种两阶段优化算法TPOA来解决BPQO问题。TPOA融合了两种新颖的思想:分而治之,根据参数的类型分别处理参数进行降维优化;按需优化,逐步构建一套必要的帕累托最优方案,而不是为了节省资源而寻求一套完整的方案。此外,为了提高TPOA算法的效率,我们在TPOA算法中引入了加速机制,提前剔除了非最优候选方案。我们从理论上证明了TPOA的正确性,从数值上分析了其复杂性,并在形式上给出了端到端的隐私分析。通过在综合基准和试验台基准上运行基线算法对其效率进行综合评估,我们可以得出结论:TPOA的总体效率提高了大约两个数量级,优于所有基准方法;加速机构使TPOA提高10-200倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Efficient Bi-objective SQL Optimization for Enclaved Cloud Databases with Differentially Private Padding
Hardware-enabled enclaves have been applied to efficiently enforce data security and privacy protection in cloud database services. Such enclaved systems, however, are reported to suffer from I/O-size (also referred to as communication-volume)-based side-channel attacks. Albeit differentially private padding has been exploited to defend against these attacks as a principle method, it introduces a challenging bi-objective parametric query optimization (BPQO) problem and current solutions are still not satisfactory. Concretely, the goal in BPQO is to find a Pareto-optimal plan that makes a tradeoff between query performance and privacy loss; existing solutions are subjected to poor computational efficiency and high cloud resource waste. In this article, we propose a two-phase optimization algorithm called TPOA to solve the BPQO problem. TPOA incorporates two novel ideas: divide-and-conquer to separately handle parameters according to their types in optimization for dimensionality reduction; on-demand-optimization to progressively build a set of necessary Pareto-optimal plans instead of seeking a complete set for saving resources. Besides, we introduce an acceleration mechanism in TPOA to improve its efficiency, which prunes the non-optimal candidate plans in advance. We theoretically prove the correctness of TPOA, numerically analyze its complexity, and formally give an end-to-end privacy analysis. Through a comprehensive evaluation on its efficiency by running baseline algorithms over synthetic and test-bed benchmarks, we can conclude that TPOA outperforms all benchmarked methods with an overall efficiency improvement of roughly two orders of magnitude; moreover, the acceleration mechanism speeds up TPOA by 10-200×.
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来源期刊
ACM Transactions on Database Systems
ACM Transactions on Database Systems 工程技术-计算机:软件工程
CiteScore
5.60
自引率
0.00%
发文量
15
审稿时长
>12 weeks
期刊介绍: Heavily used in both academic and corporate R&D settings, ACM Transactions on Database Systems (TODS) is a key publication for computer scientists working in data abstraction, data modeling, and designing data management systems. Topics include storage and retrieval, transaction management, distributed and federated databases, semantics of data, intelligent databases, and operations and algorithms relating to these areas. In this rapidly changing field, TODS provides insights into the thoughts of the best minds in database R&D.
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