Instruction-based energy estimation methodology for asymmetric manycore processor simulations

William J. Song; Sudhakar Yalamanchili; Saibal Mukhopadhyay; Arun F. Rodrigues

doi:10.4108/icstsimutools2012.247770

Instruction-based energy estimation methodology for asymmetric manycore processor simulations

William J. Song, Sudhakar Yalamanchili, Saibal Mukhopadhyay, Arun F. Rodrigues

Department of Electrical and Electronic Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

3 Citations (Scopus)

Abstract

Processor power is a complex function of device, packaging, microarchitecture, and application. Typical approaches to power simulation require detailed microarchitecture models to collect the statistical switching activity counts of processor components. In manycore simulations, the detailed core models are the main simulation speed bottleneck. In this paper, we propose an instruction-based energy estimation model for fast and scalable energy simulation. Importantly, in this approach the dynamic energy is modeled as a combination of three contributing factors: physical, microarchitectural, and workload properties. The model easily incorporates variations in physical parameters such as clock frequencies and supply voltages. When compared to commonly used cycle-level microarchitectural simulation approach with SPEC2006 benchmarks, the proposed instruction-based energy model incurred a 2.94% average error rate while achieving an average simulation time speedup of 74X for a 16-core asymmetric x86 ISA processor model with multiple clock domains operating at different frequencies.

Original language	English
Title of host publication	SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques
Editors	Jan Himmelspach, Francesco Quaglia, George Riley
Publisher	ICST
Pages	166-171
Number of pages	6
ISBN (Electronic)	9781450315104
DOIs	https://doi.org/10.4108/icstsimutools2012.247770
Publication status	Published - 2012
Event	5th International Conference on Simulation Tools and Techniques, SIMUTools 2012 - Desenzano del Garda, Italy Duration: 2012 Mar 19 → 2012 Mar 23

Publication series

Name	SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques

Other

Other	5th International Conference on Simulation Tools and Techniques, SIMUTools 2012
Country/Territory	Italy
City	Desenzano del Garda
Period	12/3/19 → 12/3/23

Bibliographical note

Publisher Copyright:
Copyright © 2012 ICST.

All Science Journal Classification (ASJC) codes

Modelling and Simulation

Access to Document

10.4108/icstsimutools2012.247770

Cite this

Song, W. J., Yalamanchili, S., Mukhopadhyay, S., & Rodrigues, A. F. (2012). Instruction-based energy estimation methodology for asymmetric manycore processor simulations. In J. Himmelspach, F. Quaglia, & G. Riley (Eds.), SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques (pp. 166-171). (SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques). ICST. https://doi.org/10.4108/icstsimutools2012.247770

Song, William J. ; Yalamanchili, Sudhakar ; Mukhopadhyay, Saibal et al. / Instruction-based energy estimation methodology for asymmetric manycore processor simulations. SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques. editor / Jan Himmelspach ; Francesco Quaglia ; George Riley. ICST, 2012. pp. 166-171 (SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques).

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title = "Instruction-based energy estimation methodology for asymmetric manycore processor simulations",

abstract = "Processor power is a complex function of device, packaging, microarchitecture, and application. Typical approaches to power simulation require detailed microarchitecture models to collect the statistical switching activity counts of processor components. In manycore simulations, the detailed core models are the main simulation speed bottleneck. In this paper, we propose an instruction-based energy estimation model for fast and scalable energy simulation. Importantly, in this approach the dynamic energy is modeled as a combination of three contributing factors: physical, microarchitectural, and workload properties. The model easily incorporates variations in physical parameters such as clock frequencies and supply voltages. When compared to commonly used cycle-level microarchitectural simulation approach with SPEC2006 benchmarks, the proposed instruction-based energy model incurred a 2.94% average error rate while achieving an average simulation time speedup of 74X for a 16-core asymmetric x86 ISA processor model with multiple clock domains operating at different frequencies.",

author = "Song, {William J.} and Sudhakar Yalamanchili and Saibal Mukhopadhyay and Rodrigues, {Arun F.}",

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doi = "10.4108/icstsimutools2012.247770",

language = "English",

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Song, WJ, Yalamanchili, S, Mukhopadhyay, S & Rodrigues, AF 2012, Instruction-based energy estimation methodology for asymmetric manycore processor simulations. in J Himmelspach, F Quaglia & G Riley (eds), SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques. SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques, ICST, pp. 166-171, 5th International Conference on Simulation Tools and Techniques, SIMUTools 2012, Desenzano del Garda, Italy, 12/3/19. https://doi.org/10.4108/icstsimutools2012.247770

Instruction-based energy estimation methodology for asymmetric manycore processor simulations. / Song, William J.; Yalamanchili, Sudhakar; Mukhopadhyay, Saibal et al.
SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques. ed. / Jan Himmelspach; Francesco Quaglia; George Riley. ICST, 2012. p. 166-171 (SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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T1 - Instruction-based energy estimation methodology for asymmetric manycore processor simulations

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AU - Yalamanchili, Sudhakar

AU - Mukhopadhyay, Saibal

AU - Rodrigues, Arun F.

PY - 2012

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N2 - Processor power is a complex function of device, packaging, microarchitecture, and application. Typical approaches to power simulation require detailed microarchitecture models to collect the statistical switching activity counts of processor components. In manycore simulations, the detailed core models are the main simulation speed bottleneck. In this paper, we propose an instruction-based energy estimation model for fast and scalable energy simulation. Importantly, in this approach the dynamic energy is modeled as a combination of three contributing factors: physical, microarchitectural, and workload properties. The model easily incorporates variations in physical parameters such as clock frequencies and supply voltages. When compared to commonly used cycle-level microarchitectural simulation approach with SPEC2006 benchmarks, the proposed instruction-based energy model incurred a 2.94% average error rate while achieving an average simulation time speedup of 74X for a 16-core asymmetric x86 ISA processor model with multiple clock domains operating at different frequencies.

AB - Processor power is a complex function of device, packaging, microarchitecture, and application. Typical approaches to power simulation require detailed microarchitecture models to collect the statistical switching activity counts of processor components. In manycore simulations, the detailed core models are the main simulation speed bottleneck. In this paper, we propose an instruction-based energy estimation model for fast and scalable energy simulation. Importantly, in this approach the dynamic energy is modeled as a combination of three contributing factors: physical, microarchitectural, and workload properties. The model easily incorporates variations in physical parameters such as clock frequencies and supply voltages. When compared to commonly used cycle-level microarchitectural simulation approach with SPEC2006 benchmarks, the proposed instruction-based energy model incurred a 2.94% average error rate while achieving an average simulation time speedup of 74X for a 16-core asymmetric x86 ISA processor model with multiple clock domains operating at different frequencies.

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BT - SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques

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Song WJ, Yalamanchili S, Mukhopadhyay S, Rodrigues AF. Instruction-based energy estimation methodology for asymmetric manycore processor simulations. In Himmelspach J, Quaglia F, Riley G, editors, SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques. ICST. 2012. p. 166-171. (SIMUTools 2012 - 5th International Conference on Simulation Tools and Techniques). doi: 10.4108/icstsimutools2012.247770

Instruction-based energy estimation methodology for asymmetric manycore processor simulations

Abstract

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All Science Journal Classification (ASJC) codes

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