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Modeling Universal Globally Adaptive Load-Balanced Routing

  • Published:2019-09-10 Issue:2 Volume:6 Page:1-23
  • ISSN:2329-4949
  • Container-title:ACM Transactions on Parallel Computing
  • language:en
  • Short-container-title:ACM Trans. Parallel Comput.

Author:

Mollah Md Atiqul1,Wang Wenqi2,Faizian Peyman3,Rahman MD Shafayat2,Yuan Xin2,Pakin Scott4,Lang Michael4

Affiliation:

1. Oakland University, Rochester, Michigan

2. Florida State University, Tallahassee, Florida

3. University of North Florida, Jacksonville, Florida

4. Los Alamos National Laboratory, Los Alamos, New Mexico

Abstract

Universal globally adaptive load-balanced (UGAL) routing has been proposed for various interconnection networks and has been deployed in a number of current-generation supercomputers. Although UGAL-based schemes have been extensively studied, most existing results are based on either simulation or measurement. Without a theoretical understanding of UGAL, multiple questions remain: For which traffic patterns is UGAL most suited? In addition, what determines the performance of the UGAL-based scheme on a particular network configuration? In this work, we develop a set of throughput models for UGALbased on linear programming. We show that the throughput models are valid across the torus, Dragonfly, and Slim Fly network topologies. Finally, we identify a robust model that can accurately and efficiently predict UGAL throughput for a set of representative traffic patterns across different topologies. Our models not only provide a mechanism to predict UGAL performance on large-scale interconnection networks but also reveal the inner working of UGAL and further our understanding of this type of routing.

Funder

Advanced Simulation and Computing

Publisher

Association for Computing Machinery (ACM)

Subject

Computational Theory and Mathematics,Computer Science Applications,Hardware and Architecture,Modeling and Simulation,Software

Reference34 articles.

1. Slim Fly: A Cost Effective Low-Diameter Network Topology

2. Arjun Singh. 2005. Load-Balanced Routing in Interconnection Networks. Ph.D. Dissertation. Stanford University. Arjun Singh. 2005. Load-Balanced Routing in Interconnection Networks. Ph.D. Dissertation. Stanford University.

3. Technology-Driven, Highly-Scalable Dragonfly Topology

4. Indirect adaptive routing on large scale interconnection networks

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1. Analysis and prediction of performance variability in large-scale computing systems;The Journal of Supercomputing;2024-03-28

2. An Analysis of Long-Tailed Network Latency Distribution and Background Traffic on Dragonfly+;Benchmarking, Measuring, and Optimizing;2023

3. Analysis and Prediction of Performance Variability in Large-Scale Computing Systems;2023

4. Multi-Path Routing in the Jellyfish Network;2021 IEEE International Parallel and Distributed Processing Symposium Workshops (IPDPSW);2021-06

5. Global link arrangement for practical Dragonfly;Proceedings of the 34th ACM International Conference on Supercomputing;2020-06-29
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