TY - GEN
T1 - When eXtended para - Virtualization (XPV) meets NUMA
AU - Bui, Bao
AU - Jiokeng, Kevin
AU - Thomas, Gaël
AU - Mvondo, Djob
AU - Wapet, Lavoisier
AU - Hagimont, Daniel
AU - DePalma, Noel
AU - Teabe, Boris
AU - Tchana, Alain
AU - Muller, Gilles
N1 - Publisher Copyright:
© 2019 Association for Computing Machinery.
PY - 2019/3/25
Y1 - 2019/3/25
N2 - This paper addresses the problem of efficiently virtualizing NUMA architectures. The major challenge comes from the fact that the hypervisor regularly reconfigures the placement of a virtual machine (VM) over the NUMA topology. However, neither guest operating systems (OSes) nor system runtime libraries (e.g., Hotspot) are designed to consider NUMA topology changes at runtime, leading end user applications to unpredictable performance. This paper presents eXtended Para-Virtualization (XPV), a new principle to efficiently virtualize a NUMA architecture. XPV consists in revisiting the interface between the hypervisor and the guest OS, and between the guest OS and system runtime libraries (SRL) so that they can dynamically take into account NUMA topology changes. The paper presents a methodology for systematically adapting legacy hypervisors, OSes, and SRLs. We have applied our approach with less than 2k line of codes in two legacy hypervisors (Xen and KVM), two legacy guest OSes (Linux and FreeBSD), and three legacy SRLs (Hotspot, TCMalloc, and jemalloc). The evaluation results showed that XPV outperforms all existing solutions by up to 304%.
AB - This paper addresses the problem of efficiently virtualizing NUMA architectures. The major challenge comes from the fact that the hypervisor regularly reconfigures the placement of a virtual machine (VM) over the NUMA topology. However, neither guest operating systems (OSes) nor system runtime libraries (e.g., Hotspot) are designed to consider NUMA topology changes at runtime, leading end user applications to unpredictable performance. This paper presents eXtended Para-Virtualization (XPV), a new principle to efficiently virtualize a NUMA architecture. XPV consists in revisiting the interface between the hypervisor and the guest OS, and between the guest OS and system runtime libraries (SRL) so that they can dynamically take into account NUMA topology changes. The paper presents a methodology for systematically adapting legacy hypervisors, OSes, and SRLs. We have applied our approach with less than 2k line of codes in two legacy hypervisors (Xen and KVM), two legacy guest OSes (Linux and FreeBSD), and three legacy SRLs (Hotspot, TCMalloc, and jemalloc). The evaluation results showed that XPV outperforms all existing solutions by up to 304%.
KW - NUMA
KW - Virtualization
UR - https://www.scopus.com/pages/publications/85063911118
U2 - 10.1145/3302424.3303960
DO - 10.1145/3302424.3303960
M3 - Conference contribution
AN - SCOPUS:85063911118
T3 - Proceedings of the 14th EuroSys Conference 2019
BT - Proceedings of the 14th EuroSys Conference 2019
PB - Association for Computing Machinery
T2 - 14th European Conference on Computer Systems, EuroSys 2019
Y2 - 25 March 2019 through 28 March 2019
ER -