Ares : Adaptive, Reconfigurable, Erasure coded, Atomic Storage
Abstract
Emulating a shared atomic , read/write storage system is a fundamental problem in distributed computing. Replicating atomic objects among a set of data hosts was the norm for traditional implementations (e.g., [ 11 ]) in order to guarantee the availability and accessibility of the data despite host failures. As replication is highly storage demanding, recent approaches suggested the use of erasure-codes to offer the same fault-tolerance while optimizing storage usage at the hosts. Initial works focused on a fixed set of data hosts. To guarantee longevity and scalability, a storage service should be able to dynamically mask hosts failures by allowing new hosts to join, and failed host to be removed without service interruptions. This work presents the first erasure-code -based atomic algorithm, called Ares , which allows the set of hosts to be modified in the course of an execution. Ares is composed of three main components: (i) a reconfiguration protocol , (ii) a read/write protocol , and (iii) a set of data access primitives (DAPs) . The design of Ares is modular and is such to accommodate the usage of various erasure-code parameters on a per-configuration basis. We provide bounds on the latency of read/write operations and analyze the storage and communication costs of the Ares algorithm.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Nov 12, 2022
- Source ID
- 10.1145/3510613
Entities
People
- Andria Trigeorgi
- Kishori Konwar
- Muriel Médard
- N. Prakash
- Nancy Lynch
- Nicolas Nicolaou
- Viveck Cadambe
Organizations
- Air Force Office of Scientific Research
- Intel Corporation
- Pennsylvania State University
- University of Cyprus