{"title":"Private information retrieval from locally repairable databases with colluding servers","authors":"Umberto Martínez-Peñas","doi":"10.1016/j.ffa.2024.102421","DOIUrl":null,"url":null,"abstract":"<div><p>We consider information-theoretical private information retrieval (PIR) from a coded database with colluding servers. We target, for the first time, locally repairable storage codes (LRCs). We consider any number of local groups <em>g</em>, locality <em>r</em>, local distance <em>δ</em> and dimension <em>k</em>. Our main contribution is a PIR scheme for maximally recoverable (MR) LRCs based on linearized Reed–Solomon codes, which achieve the smallest field sizes among MR-LRCs for many parameter regimes. In our scheme, nodes are identified with codeword symbols and servers are identified with local groups of nodes. Only locally non-redundant information is downloaded from each server, that is, only <em>r</em> nodes (out of <span><math><mi>r</mi><mo>+</mo><mi>δ</mi><mo>−</mo><mn>1</mn></math></span>) are downloaded per server. The PIR scheme achieves the (download) rate <span><math><mi>R</mi><mo>=</mo><mo>(</mo><mi>N</mi><mo>−</mo><mi>k</mi><mo>−</mo><mi>r</mi><mi>t</mi><mo>+</mo><mn>1</mn><mo>)</mo><mo>/</mo><mi>N</mi></math></span>, where <span><math><mi>N</mi><mo>=</mo><mi>g</mi><mi>r</mi></math></span> is the length of the MDS code obtained after removing the local parities, and for any <em>t</em> colluding servers such that <span><math><mi>k</mi><mo>+</mo><mi>r</mi><mi>t</mi><mo>≤</mo><mi>N</mi></math></span>. For an unbounded number of stored files, the obtained rate is strictly larger than those of known PIR schemes that work for any MDS code. Finally, the obtained PIR scheme can also be adapted when communication between the user and each server is performed via linear network coding, achieving the same rate as previous PIR schemes for this scenario but with polynomial finite field sizes, instead of exponential. Our rates are equal to those of PIR schemes for Reed–Solomon codes, but Reed–Solomon codes are incompatible with the MR-LRC property or linear network coding, thus our PIR scheme is less restrictive in its applications.</p></div>","PeriodicalId":50446,"journal":{"name":"Finite Fields and Their Applications","volume":"96 ","pages":"Article 102421"},"PeriodicalIF":1.2000,"publicationDate":"2024-03-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S1071579724000601/pdfft?md5=0fe90fcdc546f6a24d87a8e7912affb8&pid=1-s2.0-S1071579724000601-main.pdf","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Finite Fields and Their Applications","FirstCategoryId":"100","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S1071579724000601","RegionNum":3,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS","Score":null,"Total":0}
引用次数: 0
Abstract
We consider information-theoretical private information retrieval (PIR) from a coded database with colluding servers. We target, for the first time, locally repairable storage codes (LRCs). We consider any number of local groups g, locality r, local distance δ and dimension k. Our main contribution is a PIR scheme for maximally recoverable (MR) LRCs based on linearized Reed–Solomon codes, which achieve the smallest field sizes among MR-LRCs for many parameter regimes. In our scheme, nodes are identified with codeword symbols and servers are identified with local groups of nodes. Only locally non-redundant information is downloaded from each server, that is, only r nodes (out of ) are downloaded per server. The PIR scheme achieves the (download) rate , where is the length of the MDS code obtained after removing the local parities, and for any t colluding servers such that . For an unbounded number of stored files, the obtained rate is strictly larger than those of known PIR schemes that work for any MDS code. Finally, the obtained PIR scheme can also be adapted when communication between the user and each server is performed via linear network coding, achieving the same rate as previous PIR schemes for this scenario but with polynomial finite field sizes, instead of exponential. Our rates are equal to those of PIR schemes for Reed–Solomon codes, but Reed–Solomon codes are incompatible with the MR-LRC property or linear network coding, thus our PIR scheme is less restrictive in its applications.
我们考虑从有串通服务器的编码数据库中进行信息论私人信息检索(PIR)。我们首次将本地可修复存储代码(LRC)作为研究对象。我们的主要贡献是基于线性化里德-所罗门(Reed-Solomon)编码的最大可恢复(MR)LRC 的 PIR 方案,该方案在许多参数机制下实现了 MR-LRC 中最小的字段大小。在我们的方案中,节点由编码词符号标识,服务器由节点的本地组标识。每个服务器只下载本地非冗余信息,即每个服务器只下载 r 个节点(r+δ-1 中的 r 个)。PIR 方案的(下载)速率为 R=(N-k-rt+1)/N,其中 N=gr 为去除局部奇偶校验后得到的 MDS 代码长度,且对于任意 t 个串通服务器,k+rt≤N。对于不受限制的存储文件数量,所获得的速率严格大于那些适用于任何 MDS 代码的已知 PIR 方案。最后,当用户和每个服务器之间的通信是通过线性网络编码完成时,所获得的 PIR 方案也可以进行调整,在这种情况下获得与以前的 PIR 方案相同的速率,但有限场大小是多项式,而不是指数。我们的速率与里德-所罗门编码的 PIR 方案相当,但里德-所罗门编码与 MR-LRC 特性或线性网络编码不兼容,因此我们的 PIR 方案在应用上限制较少。
期刊介绍:
Finite Fields and Their Applications is a peer-reviewed technical journal publishing papers in finite field theory as well as in applications of finite fields. As a result of applications in a wide variety of areas, finite fields are increasingly important in several areas of mathematics, including linear and abstract algebra, number theory and algebraic geometry, as well as in computer science, statistics, information theory, and engineering.
For cohesion, and because so many applications rely on various theoretical properties of finite fields, it is essential that there be a core of high-quality papers on theoretical aspects. In addition, since much of the vitality of the area comes from computational problems, the journal publishes papers on computational aspects of finite fields as well as on algorithms and complexity of finite field-related methods.
The journal also publishes papers in various applications including, but not limited to, algebraic coding theory, cryptology, combinatorial design theory, pseudorandom number generation, and linear recurring sequences. There are other areas of application to be included, but the important point is that finite fields play a nontrivial role in the theory, application, or algorithm.