• Title/Summary/Keyword: parallel control flow graph

Search Result 2, Processing Time 0.015 seconds

A Representation for Multithreaded Data-parallel Programs : PCFG(Parallel Control Flow Graph) (다중스레드 데이타 병렬 프로그램의 표현 : PCFG(Parallel Control Flow Graph))

  • 김정환
    • Journal of KIISE:Computer Systems and Theory
    • /
    • v.29 no.12
    • /
    • pp.655-664
    • /
    • 2002
  • In many data-parallel applications massive parallelism can be easily extracted through data distribution. But it often causes very long communication latency. This paper shows that task parallelism, which is extracted from data-parallel programs, can be exploited to hide such communication latency Unlike the most previous researches over exploitation of task parallelism which has not been considered together with data parallelism, this paper describes exploitation of task parallelism in the context of data parallelism. PCFG(Parallel Control Flow Graph) is proposed to represent a multithreaded program consisting of a few task threads each of which can include a few data-parallel loops. It is also described how a PCFG is constructed from a source data-parallel program through HDG(Hierarchical Dependence Graph) and how the multithreaded program can be constructed from the PCFG.

Abstract Visualization for Effective Debugging of Parallel Programs Based on Multi-threading (멀티 스레딩 기반 병렬 프로그램의 효과적인 디버깅을 위한 추상적 시각화)

  • Kim, Young-Joo
    • Journal of the Korea Institute of Information and Communication Engineering
    • /
    • v.20 no.3
    • /
    • pp.549-557
    • /
    • 2016
  • It is important for effective visualization to summarize not only a large amount of debugging information but also the mental models of abstract ideas. This paper presents an abstract visualization tool which provides effective visualization of thread structure and race information for OpenMP programs with critical sections and nested parallelism, using a partial order execution graph which captures logical concurrency among threads. This tool is supported by an on-the-fly trace-filtering technique to reduce space complexity of visualization information, and a graph abstraction technique to reduce visual complexity of nested parallelism and critical sections in the filtered trace. The graph abstraction of partial-order relation and race information is effective for understanding program execution and detecting to eliminate races, because the user can examine control flow of program and locations of races in a structural fashion.