DSIM: scaling time warp to 1,033 processors

Author

Chen, Gilbert ; Szymanski, Boleslaw K.

Author_Institution

The MathWorks, Inc., Natick, MA, USA

fYear

2005

fDate

4-7 Dec. 2005

Abstract

This paper presents the design, implementation and performance of a time warp simulator, called DSIM, which targets clusters comprised of thousands of processors. DSIM employs a novel technique for GVT computation, called the time quantum GVT algorithm that requires no message acknowledgement, relies on constant-length messages and is efficient on clusters with large numbers of processors. Its implementation uses a technique called Local Fossil Collection to alleviate the overhead of memory reclamation and to support efficient event management. DSIM is also equipped with a simple programming interface to ease programming and debugging of simulations. Experimental results obtained on the PHOLD benchmark demonstrated that DSIM can process as many as 228 million events per second on 1033 processors.

Keywords

quantum computing; time warp simulation; virtual machines; workstation clusters; DSIM; GVT computation; PHOLD benchmark; constant-length messages; debugging; event management; local fossil collection; memory reclamation; programming interface; scaling time warp; time quantum GVT algorithm; time warp simulator; Clustering algorithms; Computational modeling; Computer simulation; Concurrent computing; Delay; Discrete event simulation; Distributed computing; Memory management; Quantum computing; Time warp simulation;

fLanguage

English

Publisher

ieee

Conference_Titel

Simulation Conference, 2005 Proceedings of the Winter

Print_ISBN

0-7803-9519-0

Type

conf

DOI

10.1109/WSC.2005.1574269

Filename

1574269