TY - GEN
T1 - VCacheshare
T2 - 2014 USENIX Annual Technical Conference, USENIX ATC 2014
AU - Meng, Fei
AU - Zhou, Li
AU - Ma, Xiaosong
AU - Uttamchandani, Sandeep
AU - Liu, Deng
N1 - Publisher Copyright:
© Proceedings of the 2014 USENIX Annual Technical Conference, USENIX ATC 2014. All rights reserved.
PY - 2014
Y1 - 2014
N2 - Server Flash Cache (SFC) is increasingly adopted in virtualization environments for IO acceleration. Deciding the optimal SFC allocation among VMs or VM disks is a major pain-point, dominantly handled manually by administrators. In this paper, we present vCacheShare, a dynamic, workload-aware, policy-driven framework for continuous and automated optimization of SFC space partitioning. Its decision-making is based on multiple IO access characteristics. In particular, vCacheShare adopts a cache utility model that captures both longer-term locality behavior and transient locality spikes. This paper validates the growing applicability of analytical programming techniques to solve real-time resource management problems, traditionally addressed using heuristics. We designed vCacheShare to coordinate with typical VM mobility events and implemented it within the widely used ESXi hypervisor. We performed extensive evaluation using 13 representative enterprise IO workloads, one IO benchmark, and two end-to-end deployment test cases targeting Virtual Desktop Infrastructure (VDI) and data warehousing scenarios respectively. Our results verified the advantage of vCacheShare over implicit management schemes such as global LRU, and confirmed its self-adaptive capability.
AB - Server Flash Cache (SFC) is increasingly adopted in virtualization environments for IO acceleration. Deciding the optimal SFC allocation among VMs or VM disks is a major pain-point, dominantly handled manually by administrators. In this paper, we present vCacheShare, a dynamic, workload-aware, policy-driven framework for continuous and automated optimization of SFC space partitioning. Its decision-making is based on multiple IO access characteristics. In particular, vCacheShare adopts a cache utility model that captures both longer-term locality behavior and transient locality spikes. This paper validates the growing applicability of analytical programming techniques to solve real-time resource management problems, traditionally addressed using heuristics. We designed vCacheShare to coordinate with typical VM mobility events and implemented it within the widely used ESXi hypervisor. We performed extensive evaluation using 13 representative enterprise IO workloads, one IO benchmark, and two end-to-end deployment test cases targeting Virtual Desktop Infrastructure (VDI) and data warehousing scenarios respectively. Our results verified the advantage of vCacheShare over implicit management schemes such as global LRU, and confirmed its self-adaptive capability.
UR - http://www.scopus.com/inward/record.url?scp=85077451961&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85077451961
T3 - Proceedings of the 2014 USENIX Annual Technical Conference, USENIX ATC 2014
SP - 133
EP - 144
BT - Proceedings of the 2014 USENIX Annual Technical Conference, USENIX ATC 2014
PB - USENIX Association
Y2 - 19 June 2014 through 20 June 2014
ER -