A repartitioning hypergraph model for dynamic load balancing

In parallel adaptive applications, the computational structure of the applications changes over time, leading to load imbalances even though the initial load distributions were balanced. To restore balance and to keep communication volume low in further iterations of the applications, dynamic load b...

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Veröffentlicht in:	Journal of parallel and distributed computing 2009-08, Vol.69 (8), p.711-724
Hauptverfasser:	Catalyurek, Umit V., Boman, Erik G., Devine, Karen D., Bozdağ, Doruk, Heaphy, Robert T., Riesen, Lee Ann
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Computer science control theory systems Computer systems and distributed systems. User interface Distributed memory computers Dynamic load balancing Exact sciences and technology Hypergraph partitioning Information retrieval. Graph Parallel algorithms Scientific computing Software Theoretical computing
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container_title	Journal of parallel and distributed computing
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creator	Catalyurek, Umit V. Boman, Erik G. Devine, Karen D. Bozdağ, Doruk Heaphy, Robert T. Riesen, Lee Ann
description	In parallel adaptive applications, the computational structure of the applications changes over time, leading to load imbalances even though the initial load distributions were balanced. To restore balance and to keep communication volume low in further iterations of the applications, dynamic load balancing (repartitioning) of the changed computational structure is required. Repartitioning differs from static load balancing (partitioning) due to the additional requirement of minimizing migration cost to move data from an existing partition to a new partition. In this paper, we present a novel repartitioning hypergraph model for dynamic load balancing that accounts for both communication volume in the application and migration cost to move data, in order to minimize the overall cost. The use of a hypergraph-based model allows us to accurately model communication costs rather than approximate them with graph-based models. We show that the new model can be realized using hypergraph partitioning with fixed vertices and describe our parallel multilevel implementation within the Zoltan load balancing toolkit. To the best of our knowledge, this is the first implementation for dynamic load balancing based on hypergraph partitioning. To demonstrate the effectiveness of our approach, we conducted experiments on a Linux cluster with 1024 processors. The results show that, in terms of reducing total cost, our new model compares favorably to the graph-based dynamic load balancing approaches, and multilevel approaches improve the repartitioning quality significantly.
doi_str_mv	10.1016/j.jpdc.2009.04.011
format	Article
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To restore balance and to keep communication volume low in further iterations of the applications, dynamic load balancing (repartitioning) of the changed computational structure is required. Repartitioning differs from static load balancing (partitioning) due to the additional requirement of minimizing migration cost to move data from an existing partition to a new partition. In this paper, we present a novel repartitioning hypergraph model for dynamic load balancing that accounts for both communication volume in the application and migration cost to move data, in order to minimize the overall cost. The use of a hypergraph-based model allows us to accurately model communication costs rather than approximate them with graph-based models. We show that the new model can be realized using hypergraph partitioning with fixed vertices and describe our parallel multilevel implementation within the Zoltan load balancing toolkit. 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source	ScienceDirect Journals (5 years ago - present)
subjects	Applied sciences Computer science control theory systems Computer systems and distributed systems. User interface Distributed memory computers Dynamic load balancing Exact sciences and technology Hypergraph partitioning Information retrieval. Graph Parallel algorithms Scientific computing Software Theoretical computing
title	A repartitioning hypergraph model for dynamic load balancing
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