1 research outputs found
Randomized Load-balanced Routing for Fat-tree Networks
Fat-tree networks have been widely adopted to High Performance Computing
(HPC) clusters and to Data Center Networks (DCN). These parallel systems
usually have a large number of servers and hosts, which generate large volumes
of highly-volatile traffic. Thus, distributed load-balancing routing design
becomes critical to achieve high bandwidth utilization, and low-latency packet
delivery. Existing distributed designs rely on remote congestion feedbacks to
address congestion, which add overheads to collect and react to network-wide
congestion information. In contrast, we propose a simple but effective
load-balancing scheme, called Dynamic Randomized load-Balancing (DRB), to
achieve network-wide low levels of path collisions through local-link
adjustment which is free of communications and cooperations between switches.
First, we use D-mod-k path selection scheme to allocate default paths to all
source-destination (S-D) pairs in a fat-tree network, guaranteeing low levels
of path collision over downlinks for any set of active S-D pairs. Then, we
propose Threshold-based Two-Choice (TTC) randomized technique to balance uplink
traffic through local uplink adjustment at each switch. We theoretically show
that the proposed TTC for the uplink-load balancing in a fat-tree network have
a similar performance as the two-choice technique in the area of randomized
load balancing. Simulation results show that DRB with TTC technique achieves a
significant improvement over many randomized routing schemes for fat-tree
networks.Comment: 13 pages, 1 table, 6 figure