English

STAR: Scaling Transactions through Asymmetric Replication

Databases 2019-07-23 v3

Abstract

In this paper, we present STAR, a new distributed in-memory database with asymmetric replication. By employing a single-node non-partitioned architecture for some replicas and a partitioned architecture for other replicas, STAR is able to efficiently run both highly partitionable workloads and workloads that involve cross-partition transactions. The key idea is a new phase-switching algorithm where the execution of single-partition and cross-partition transactions is separated. In the partitioned phase, single-partition transactions are run on multiple machines in parallel to exploit more concurrency. In the single-master phase, mastership for the entire database is switched to a single designated master node, which can execute these transactions without the use of expensive coordination protocols like two-phase commit. Because the master node has a full copy of the database, this phase-switching can be done at negligible cost. Our experiments on two popular benchmarks (YCSB and TPC-C) show that high availability via replication can coexist with fast serializable transaction execution in distributed in-memory databases, with STAR outperforming systems that employ conventional concurrency control and replication algorithms by up to one order of magnitude.

Keywords

Cite

@article{arxiv.1811.02059,
  title  = {STAR: Scaling Transactions through Asymmetric Replication},
  author = {Yi Lu and Xiangyao Yu and Samuel Madden},
  journal= {arXiv preprint arXiv:1811.02059},
  year   = {2019}
}
R2 v1 2026-06-23T05:05:19.214Z