English

Locally Repairable Codes

Information Theory 2014-05-06 v2 Distributed, Parallel, and Cluster Computing Networking and Internet Architecture math.IT

Abstract

Distributed storage systems for large-scale applications typically use replication for reliability. Recently, erasure codes were used to reduce the large storage overhead, while increasing data reliability. A main limitation of off-the-shelf erasure codes is their high-repair cost during single node failure events. A major open problem in this area has been the design of codes that {\it i)} are repair efficient and {\it ii)} achieve arbitrarily high data rates. In this paper, we explore the repair metric of {\it locality}, which corresponds to the number of disk accesses required during a {\color{black}single} node repair. Under this metric we characterize an information theoretic trade-off that binds together locality, code distance, and the storage capacity of each node. We show the existence of optimal {\it locally repairable codes} (LRCs) that achieve this trade-off. The achievability proof uses a locality aware flow-graph gadget which leads to a randomized code construction. Finally, we present an optimal and explicit LRC that achieves arbitrarily high data-rates. Our locality optimal construction is based on simple combinations of Reed-Solomon blocks.

Keywords

Cite

@article{arxiv.1206.3804,
  title  = {Locally Repairable Codes},
  author = {Dimitris S. Papailiopoulos and Alexandros G. Dimakis},
  journal= {arXiv preprint arXiv:1206.3804},
  year   = {2014}
}

Comments

presented at ISIT 2012, accepted for publication in IEEE Trans. IT, 2014

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