Buffer Sizing for Rate-Optimal Single-Rate Data-Flow Scheduling Revisited

Author

Moreira, Orlando ; Basten, Twan ; Geilen, Marc ; Stuijk, Sander

Author_Institution

ST-Ericsson, Innovation & Technol., Eindhoven, Netherlands

Volume

59

Issue

2

fYear

2010

Firstpage

188

Lastpage

201

Abstract

Single-Rate Data-Flow (SRDF) graphs, also known as Homogeneous Synchronous Data-Flow (HSDF) graphs or Marked Graphs, are often used to model the implementation and do temporal analysis of concurrent DSP and multimedia applications. An important problem in implementing applications expressed as SRDF graphs is the computation of the minimal amount of buffering needed to implement a static periodic schedule (SPS) that is optimal in terms of execution rate, or throughput. Ning and Gao [1] propose a linear-programming-based polynomial algorithm to compute this minimal storage amount, claiming optimality. We show via a counterexample that the proposed algorithm is not optimal. We prove that the problem is, in fact, NP-complete. We give an exact solution, and experimentally evaluate the degree of inaccuracy of the algorithm of Ning and Gao.

Keywords

data flow graphs; linear programming; processor scheduling; NP-complete problem; SRDF graphs; buffer minimization; concurrent DSP applications; homogeneous synchronous data flow graphs; linear-programming-based polynomial algorithm; marked graphs; rate-optimal single-rate data-flow scheduling; static periodic schedule; temporal analysis; Communication channels; Digital signal processing; Embedded system; Optimal scheduling; Polynomials; Processor scheduling; Production; Signal processing algorithms; Streaming media; System recovery; Throughput; Scheduling; buffer minimization; homogeneous synchronous data flow; single-rate data flow; throughput optimization.;

fLanguage

English

Journal_Title

Computers, IEEE Transactions on

Publisher

ieee

ISSN

0018-9340

Type

jour

DOI

10.1109/TC.2009.155

Filename

5282495