Characterization of parallelism and deadlocks in distributed digital logic simulation

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Characterization of parallelism and deadlocks in distributed digital logic simulation

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Annual ACM IEEE Design Automation Conference archive
Proceedings of the 26th ACM/IEEE Design Automation Conference table of contents

Las Vegas, Nevada, United States

Pages: 81 - 86

Year of Publication: 1989

ISBN:0-89791-310-8

Authors

L. Soule	Computer Systems Laboratory, Stanford University, CA
A. Gupta	Computer Systems Laboratory, Stanford University, CA

Sponsors

SIGDA: ACM Special Interest Group on Design Automation
IEEE-CS\TCDA : TC Design Automation

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 1, Downloads (12 Months): 10, Citation Count: 14

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abstract references cited by index terms collaborative colleagues peer to peer

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ABSTRACT

This paper explores the suitability of the Chandy-Misra algorithm for digital logic simulation. We use four realistic circuits as benchmarks for our analysis, with one of them being the vector-unit controller for the Titan supercomputer from Ardent. Our results show that the average number of logic elements available for concurrent execution ranges from 10 to 111 for the four circuits, with an overall average of 68. Although this is twice as much parallelism as that obtained by traditional event-driven algorithms for these circuits, we feel it is still too low. One major factor limiting concurrency is the large number of global synchronization points — “deadlocks” in the Chandy-Misra terminology — that occur during execution. Towards the goal of reducing the number of deadlocks, the paper presents a classification of the types of deadlocks that occur during digital logic simulation. Four different types are identified and described intuitively in terms of circuit structure. Using domain specific knowledge, the paper proposes methods for reducing these deadlock occurrences. For one of the benchmark circuits, the use of the proposed techniques eliminated all deadlocks and increased the average parallelism from 40 to 160. We believe that the use of such domain knowledge will make the Chandy-Misra algorithm significantly more effective than it would be in its generic form.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

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	7	Larry Soulé , Tom Blank, Parallel logic simulation on general purpose machines, Proceedings of the 25th ACM/IEEE conference on Design automation, p.166-171, June 12-15, 1988, Atlantic City, New Jersey, United States
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CITED BY 14

	V. Kirshnaswamy , G. Hasteer , P. Banerjee, Automatic Parallelization of Compiled Event Driven VHDL Simulation, IEEE Transactions on Computers, v.51 n.4, p.380-394, April 2002
	Moon Jung Chung , Yunmo Chung, Efficient parallel logic simulation techniques for the connection machine, Proceedings of the 1990 conference on Supercomputing, p.606-614, October 1990, New York, New York, United States
	Moon Jung Chung , Yunmo Chung, Efficient parallel logic simulation techniques for the Connection Machine, Proceedings of the 1990 ACM/IEEE conference on Supercomputing, p.606-614, November 12-16, 1990, New York, New York
	John C. Willis , Daniel P. Siewiorek, Optimizing VHDL Compilation for Parallel Simulation, IEEE Design & Test, v.9 n.3, p.42-53, July 1992
	Jack V. Briner, Jr. , John L. Ellis , Gershon Kedem, Breaking the barrier of parallel simulation of digital systems, Proceedings of the 28th conference on ACM/IEEE design automation, p.223-226, June 17-22, 1991, San Francisco, California, United States
	Venkatram Krishnaswamy , Prithviraj Banerjee, Actor based parallel VHDL simulation using time warp, ACM SIGSIM Simulation Digest, v.26 n.1, p.135-142, July 1996
	A. Tucker , A. Gupta, Process control and scheduling issues for multiprogrammed shared-memory multiprocessors, ACM SIGOPS Operating Systems Review, v.23 n.5, p.159-166, Dec. 3–6, 1989
	Richard Simoni , Mark Horowitz, Modeling the performance of limited pointers directories for cache coherence, ACM SIGARCH Computer Architecture News, v.19 n.3, p.309-319, May 1991
	W.-D. Weber , A. Gupta, Exploring the benefits of multiple hardware contexts in a multiprocessor architecture: preliminary results, ACM SIGARCH Computer Architecture News, v.17 n.3, p.273-280, June 1989
	J. Torrellas , H. S. Lam , J. L. Hennessy, False Sharing and Spatial Locality in Multiprocessor Caches, IEEE Transactions on Computers, v.43 n.6, p.651-663, June 1994
	Larry Soulé , Anoop Gupta, An evaluation of the Chandy-Misra-Bryant algorithm for digital logic simulation, ACM Transactions on Modeling and Computer Simulation (TOMACS), v.1 n.4, p.308-347, Oct. 1991
	Anoop Gupta , Wolf-Dietrich Weber, Cache Invalidation Patterns in Shared-Memory Multiprocessors, IEEE Transactions on Computers, v.41 n.7, p.794-810, July 1992
	Sumit Ghosh, P2EDAS: Asynchronous, Distributed Event Driven Simulation Algorithm with Inconsistent Event Preemption for Accurate Execution of VHDL Descriptions on Parallel Processors, IEEE Transactions on Computers, v.50 n.1, p.28-50, January 2001
	Sumit Ghosh , Meng-Lin Yu, An Asynchronous Distributed Approach for the Simulation of Behavior-Level Models on Parallel Processors, IEEE Transactions on Parallel and Distributed Systems, v.6 n.6, p.639-652, June 1995