Supporting unbounded process parallelism in the SPC programming model

Author

Van Gemund, Arjan J C

Author_Institution

Dept. of Electr. Eng., Delft Univ. of Technol., Netherlands

fYear

1997

fDate

18-21 Dec 1997

Firstpage

168

Lastpage

173

Abstract

In automatic mapping of parallel programs to target parallel machines the efficiency of the compile-time cost estimation needed to steer the optimization process is highly dependent on the choice of programming model. Recently a new parallel programming model, called SPC, has been introduced that specifically aims at the efficient computation of reliable cost estimates, paving the way for automatic mapping. In SPC all algorithm level parallelism is explicitly specified, relying on compile-time transformation of the possibly unbounded algorithm level (data) parallelism to that of the actual target machine. In this paper we present SPC´s process-algebraic framework in terms of which we demonstrate that the transformations needed to efficiently support unbounded process parallelism at program level are straightforward

Keywords

parallel machines; parallel programming; performance evaluation; SPC programming model; automatic mapping; compile-time cost estimation; compile-time transformation; parallel programs; process-algebraic framework; programming model; target parallel machines; unbounded algorithm level parallelism; unbounded process parallelism; Automatic programming; Computational efficiency; Concurrent computing; Cost function; High performance computing; Parallel languages; Parallel processing; Parallel programming; Pipeline processing; Prediction methods;

fLanguage

English

Publisher

ieee

Conference_Titel

High-Performance Computing, 1997. Proceedings. Fourth International Conference on

Conference_Location

Bangalore

Print_ISBN

0-8186-8067-9

Type

conf

DOI

10.1109/HIPC.1997.634488

Filename

634488