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Formalised Composition and Interaction for Heterogeneous Structured Parallelism

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Abstract

Deployed through skeleton frameworks, structured parallelism yields a clear and consistent structure across platforms by distinctly decoupling computations from the structure in a parallel programme. Structured programming is a viable and effective means of providing the separation of concerns, as it subdivides a system into building blocks (modules, skids or components) that can be independently created, and then used in different systems to drive multiple functionalities. Depending on its defined semantic, each building block wraps a unit of computing function, where the valid assembly of these building blocks forms a high-level structural parallel programming model. This paper proposes a grammar to build block components to execute computational functions in heterogeneous multi-core architectures. The grammar is validated against three different families of computing models: skeleton-based, general purpose, and domain-specific. In conjunction with the protocol, the grammar produces fully instrumented code for an application suite using the skeletal framework FastFlow.

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Notes

  1. A full working implementation of the SKIP framework, called PEI, is freely available as open-source software at: https://github.com/mehdi-goli/MC-FastFlow-PEI.

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Correspondence to Horacio González-Vélez.

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Goli, M., González-Vélez, H. Formalised Composition and Interaction for Heterogeneous Structured Parallelism. Int J Parallel Prog 46, 120–151 (2018). https://doi.org/10.1007/s10766-017-0511-4

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