TY - GEN
T1 - Halflife
T2 - 19th European Conference on Computer Systems, EuroSys 2024
AU - Liu, Sen
AU - Gao, Yongbo
AU - Chen, Zixuan
AU - Ye, Jiarui
AU - Xu, Haiyang
AU - Liang, Furong
AU - Yan, Wei
AU - Tian, Zerui
AU - Sun, Quanwei
AU - Guo, Zehua
AU - Xu, Yang
N1 - Publisher Copyright:
© 2024 ACM.
PY - 2024/4/22
Y1 - 2024/4/22
N2 - Modern data centers (DCs) employ various traffic load balancers to achieve high bisection bandwidth. Among them, flowlet switching has shown remarkable performance in both load balancing and upper-layer protocol (e.g., TCP) friendliness. However, flowlet-based load balancers suffer from the inflexibility of flowlet timeout value (FTV) and result in sub-optimal performance under various application workloads. To this end, we propose Halflife, a novel flowlet-based load balancer that leverages fading FTVs to reroute traffic promptly under different workloads without any prior knowledge. Halflife not only balances traffic better, but also avoids the performance degradation caused by frequent oscillation or shifting of lows between paths. Furthermore, Halflife's fading mechanism is not only compatible with most flowlet-based load balancers, such as CONGA and LetFlow, but also improves their performance when leveraging flowlet switching in RDMA network. Through testbed experiments and simulations, we prove that Halflife improves the performance of CONGA and LetFlow by 10% ∼ 150%, and it outperforms other load balancers by 30% ∼ 200% across most application workloads.
AB - Modern data centers (DCs) employ various traffic load balancers to achieve high bisection bandwidth. Among them, flowlet switching has shown remarkable performance in both load balancing and upper-layer protocol (e.g., TCP) friendliness. However, flowlet-based load balancers suffer from the inflexibility of flowlet timeout value (FTV) and result in sub-optimal performance under various application workloads. To this end, we propose Halflife, a novel flowlet-based load balancer that leverages fading FTVs to reroute traffic promptly under different workloads without any prior knowledge. Halflife not only balances traffic better, but also avoids the performance degradation caused by frequent oscillation or shifting of lows between paths. Furthermore, Halflife's fading mechanism is not only compatible with most flowlet-based load balancers, such as CONGA and LetFlow, but also improves their performance when leveraging flowlet switching in RDMA network. Through testbed experiments and simulations, we prove that Halflife improves the performance of CONGA and LetFlow by 10% ∼ 150%, and it outperforms other load balancers by 30% ∼ 200% across most application workloads.
UR - http://www.scopus.com/inward/record.url?scp=85191995172&partnerID=8YFLogxK
U2 - 10.1145/3627703.3650062
DO - 10.1145/3627703.3650062
M3 - Conference contribution
AN - SCOPUS:85191995172
T3 - EuroSys 2024 - Proceedings of the 2024 European Conference on Computer Systems
SP - 66
EP - 81
BT - EuroSys 2024 - Proceedings of the 2024 European Conference on Computer Systems
PB - Association for Computing Machinery, Inc
Y2 - 22 April 2024 through 25 April 2024
ER -