Difference between revisions of "Paper:Ispass2013Carlson"

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The proposed multi-threaded application sampling methodology is able to derive an effective sampling strategy for candidate applications using architecture-independent metrics. Using this methodology, large input sets can now be simulated which would otherwise be infeasible, allowing for more accurate conclusions to be made than from studies using scaled-down input sets. Through the use of the proposed methodology, we can simulate less than 10% of the total application runtime in detail. On the SPEComp, NPB and PARSEC benchmarks, running on an 8-core simulated system, we achieve an average absolute error of 3.5%.
 
The proposed multi-threaded application sampling methodology is able to derive an effective sampling strategy for candidate applications using architecture-independent metrics. Using this methodology, large input sets can now be simulated which would otherwise be infeasible, allowing for more accurate conclusions to be made than from studies using scaled-down input sets. Through the use of the proposed methodology, we can simulate less than 10% of the total application runtime in detail. On the SPEComp, NPB and PARSEC benchmarks, running on an 8-core simulated system, we achieve an average absolute error of 3.5%.
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===Full text===
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[http://www.exascience.com/wp-content/uploads/2013/02/Carlson-Sampled-simulation.pdf Full paper PDF]
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===Bibtex entry===
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<pre>@INPROCEEDINGS{carlson2013ssomta,
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  author = {Trevor E. Carlson and Wim Heirman and Lieven Eeckhout},
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  title = {Sampled Simulation of Multi-Threaded Applications},
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  booktitle = {International Symposium on Performance Analysis of Systems and Software (ISPASS)},
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  year = {2013},
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  month = apr
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}
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</pre>

Revision as of 02:14, 19 February 2013

Trevor E. Carlson, Wim Heirman, Lieven Eeckhout

IEEE International Symposium on Performance Analysis of Systems and Software (ISPASS 2013)

Abstract

Sampling is a well-known workload reduction technique that allows one to speed up architectural simulation while accurately predicting performance. Previous sampling methods have been shown to accurately predict single-threaded application runtime based on its overall IPC. However, these previous approaches are unsuitable for general multi-threaded applications, for which IPC is not a good proxy for runtime. Additionally, we find that issues such as application periodicity and inter-thread synchronization play a significant role in determining how best to sample these applications.

The proposed multi-threaded application sampling methodology is able to derive an effective sampling strategy for candidate applications using architecture-independent metrics. Using this methodology, large input sets can now be simulated which would otherwise be infeasible, allowing for more accurate conclusions to be made than from studies using scaled-down input sets. Through the use of the proposed methodology, we can simulate less than 10% of the total application runtime in detail. On the SPEComp, NPB and PARSEC benchmarks, running on an 8-core simulated system, we achieve an average absolute error of 3.5%.

Full text

Full paper PDF

Bibtex entry

@INPROCEEDINGS{carlson2013ssomta,
  author = {Trevor E. Carlson and Wim Heirman and Lieven Eeckhout},
  title = {Sampled Simulation of Multi-Threaded Applications},
  booktitle = {International Symposium on Performance Analysis of Systems and Software (ISPASS)},
  year = {2013},
  month = apr
}