Title :
Skywalk: A Topology for HPC Networks with Low-Delay Switches
Author :
Fujiwara, I. ; Koibuchi, Michihiro ; Matsutani, Hiroshi ; Casanova, H.
Author_Institution :
Nat. Inst. of Inf. / JST, Tokyo, Japan
Abstract :
With low-delay switches on the horizon, end-to-end latency in large-scale High Performance Computing (HPC) interconnects will be dominated by cable delays. In this context we define a new network topology, Skywalk, for deploying low-latency interconnects in upcoming HPC systems. Skywalk uses randomness to achieve low latency, but does so in a way that accounts for the physical layout of the topology so as to lead to further cable length and thus latency reductions. Via graph analysis and discrete-event simulation we show that Skywalk compares favorably (in terms of latency, cable length, and throughput) to traditional low-degree torus and moderate-degree hypercube topologies, to high-degree fully-connected Dragonfly topologies, to the HyperX topology, and to recently proposed fully random topologies.
Keywords :
discrete event simulation; graph theory; parallel processing; HPC networks; HyperX topology; Skywalk; cable delays; cable length; discrete-event simulation; fully random topologies; graph analysis; high-degree fully-connected Dragonfly topologies; large-scale high performance computing interconnects; latency reductions; low-degree torus; low-delay switches; low-latency interconnects; moderate-degree hypercube topologies; network topology; physical layout; Delays; Hypercubes; Layout; Network topology; Optical switches; Routing; Topology; Interconnection network; cabinet layout; high performance computing; network topology;
Conference_Titel :
Parallel and Distributed Processing Symposium, 2014 IEEE 28th International
Conference_Location :
Phoenix, AZ
Print_ISBN :
978-1-4799-3799-8
DOI :
10.1109/IPDPS.2014.37
