A Partial-Exclusion Repair Scheme for MDS Codes

TL;DR

This paper introduces a partial-exclusion repair scheme for MDS codes that reduces sub-packetization levels, making practical deployment more feasible while maintaining optimal repair properties.

Contribution

It proposes a novel PE repair framework with adjustable flexibility, providing new constructions of Reed-Solomon codes that outperform traditional schemes in sub-packetization efficiency.

Findings

Lower bounds on sub-packetization levels for PE repair schemes

New Reed-Solomon code constructions with reduced sub-packetization

Practical implementation demonstrating efficiency

Abstract

For scalar maximum distance separable (MDS) codes, the conventional repair schemes that achieve the cut-set bound with equality for the single-node repair have been proven to require a super-exponential sub-packetization level.As is well known, such an extremely high level severely limits the practical deployment of MDS codes.To address this challenge, we introduce a partial-exclusion (PE) repair scheme for scalar linear codes.In the proposed PE repair framework, each node is associated with an exclusion set.The cardinality of the exclusion set is called the flexibility of the node.The maximum value of flexibility over all nodes defines the \textit{flexibility} of the PE repair scheme. Notably, the conventional repair scheme is the special case of PE repair scheme where the flexibility is 1. Under the PE repair framework, for any valid flexibility, we establish a lower bound on the sub-packetization level of MDS codes that meet the cut-set bound with equality for single-node repair. To realize MDS codes attaining the cut-set bound under the PE repair framework, we propose two generic constructions of Reed-Solomon (RS) codes. Moreover, we demonstrate that for a sufficiently large flexibility, the sub-packetization level of our constructions is strictly lower than the known lower bound established for the conventional repair schemes.This implies that, from the perspective of sub-packetization level, our constructions outperform all existing and potential constructions designed for conventional repair schemes. Finally, we implement the repair process for these codes as executable Magma programs, thereby exhibiting the practical efficiency of our constructions.