Predicting the performance of scientific applications on distributed memory multiprocessors

Author

Abramson, D.

Author_Institution

Sch. of Comput. & Inf. Technol., Griffith Univ., Brisbane, Qld., Australia

fYear

1994

fDate

23-25 May 1994

Firstpage

285

Lastpage

292

Abstract

Porting scientific applications to parallel machines is one of the major challenges for scientists and computing professionals over the coming years. Existing codes span many thousands of lines and are often converted for parallel execution by someone other than the original author. Good tools are required to assist this process as much as possible. Two key design parameters that must be addressed on distributed memory computers are the way that parallel data structures are distributed across the machine and the way that processes are allocated to processors. The paper describes a tool called DCompose, which allows a user to rapidly determine the effect of different data decomposition and process allocation strategies. Using DCompose, important design decisions can be made before the translation of the program is started, and before the target platform is chosen

Keywords

data structures; distributed memory systems; natural sciences; natural sciences computing; parallel machines; parallel programming; performance evaluation; resource allocation; DCompose; design decisions; distributed memory computers; distributed memory multiprocessors; parallel data structures; parallel execution; parallel machines; performance prediction; process allocation strategies; scientific applications; Concurrent computing; Data communication; Data structures; Data visualization; Distributed computing; Hardware; Information technology; Instruments; Parallel machines; Programming profession;

fLanguage

English

Publisher

ieee

Conference_Titel

Scalable High-Performance Computing Conference, 1994., Proceedings of the

Conference_Location

Knoxville, TN

Print_ISBN

0-8186-5680-8

Type

conf

DOI

10.1109/SHPCC.1994.296656

Filename

296656