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Task‐based parallel strategies for computational fluid dynamic application in heterogeneous CPU/GPU resources
Author(s) -
Leandro Nesi Lucas,
da Silva Serpa Matheus,
Mello Schnorr Lucas,
Navaux Philippe Olivier Alexandre
Publication year - 2020
Publication title -
concurrency and computation: practice and experience
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.309
H-Index - 67
eISSN - 1532-0634
pISSN - 1532-0626
DOI - 10.1002/cpe.5772
Subject(s) - computer science , speedup , parallel computing , symmetric multiprocessor system , implementation , task (project management) , distributed computing , programming language , management , economics
Summary Parallel applications executing in contemporary heterogeneous clusters are complex to code and optimize. The task‐based programming model is an alternative to handle the coding complexity. This model consists of splitting the problem domain into tasks with dependencies through a directed acyclic graph, and submit the set of tasks to a runtime scheduler that maps each task dynamically to resources. We consider that computational fluid dynamics applications are typical in scientific computing but not enough exploited by designs that employ the task‐based programming model. This article presents task‐based parallel strategies for a simple CFD application that targets heterogeneous multi‐CPU/multi‐GPU computing resources. We design, develop, evaluate, and compare the performance of three parallel strategies (naive, ghost‐cells, and arrow) of a task‐based heterogeneous (CPU and GPU) application that simulates the flow of an incompressible Newtonian fluid with constant viscosity. All implementations rely on the StarPU runtime, and we use the StarVZ toolkit to conduct comprehensive performance analysis. Results indicate that the ghost cell strategy provides the best speedup (77×) considering the simulation time when the GPU resources still have available memory. However, the arrow strategy achieves better results when the simulation data increases.

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