进度图的递归分解

2009 Third IEEE International Conference on Secure Software Integration and Reliability Improvement Pub Date : 2009-07-08 DOI:10.1109/SSIRI.2009.19

D. Cape, B. McMillin, Benjamin W. Passer, Mayur Thakur

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引用次数: 1

摘要

状态转换系统的搜索是并发程序死锁检测的传统方法。本文研究了一种基于几何语义的死锁检测方法，该方法利用二同伦拓扑概念将状态空间划分为组件;然后，穷举搜索约简状态空间。先前的工作对状态空间进行了归纳划分。在本文中，我们展示了递归技术提供了更大的减少状态转换系统的大小，因此更有效的死锁检测。如果预处理可以有效地完成，那么对于大型问题，我们期望看到更有效的死锁检测，并最终更有效地验证一些时间属性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Recursive Decomposition of Progress Graphs

Search of a state transition system is traditionally how deadlock detection for concurrent programs has been accomplished. This paper examines an approach to deadlock detection that uses geometric semantics involving the topological notion of dihomotopy to partition the state-space into components; after that the reduced state-space is exhaustively searched. Prior work partitioned the state-space inductively. In this paper we show that a recursive technique provides greater reduction of the size of the state transition system and therefore more efficient deadlock detection. If the preprocessing can be done efficiently, then for large problems we expect to see more efficient deadlock detection and eventually more efficient verification of some temporal properties.

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2009 Third IEEE International Conference on Secure Software Integration and Reliability Improvement

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