Power dissipation has become one of the most critical factors for the continued development of both high-end and low-end computer systems. We present a complete system power simulator, called SoftWatt, that models the CPU, memory hierarchy, and a low-power disk subsystem and quantifies the power behavior of both the application and operating system. This tool, built on top of the SimOS infrastructure, uses validated analytical energy models to identify the power hotspots in the system components, capture relative contributions of the user and kernel code to the system power profile, identify the power-hungry operating system services and characterize the variance in kernel power profile with respect to workload. Our results using Spec JVM98 benchmark suite emphasize the importance of complete system simulation to understand the power impact of architecture and operating system on application execution.
%0 Conference Paper
%1 gurumurthi02softwatt
%A Gurumurthi, S.
%A Sivasubramaniam, A.
%A Irwin, M.J.
%A Vijaykrishnan, N.
%A Kandemir, M.
%D 2002
%J Eighth International Symposium on High-Performance Computer Architecture
%K SoftWatt benchmark estimation optimization performance power simulation tools
%P 141-150
%T Using complete machine simulation for software power estimation: the SoftWatt approach
%X Power dissipation has become one of the most critical factors for the continued development of both high-end and low-end computer systems. We present a complete system power simulator, called SoftWatt, that models the CPU, memory hierarchy, and a low-power disk subsystem and quantifies the power behavior of both the application and operating system. This tool, built on top of the SimOS infrastructure, uses validated analytical energy models to identify the power hotspots in the system components, capture relative contributions of the user and kernel code to the system power profile, identify the power-hungry operating system services and characterize the variance in kernel power profile with respect to workload. Our results using Spec JVM98 benchmark suite emphasize the importance of complete system simulation to understand the power impact of architecture and operating system on application execution.
@inproceedings{gurumurthi02softwatt,
abstract = {Power dissipation has become one of the most critical factors for the continued development of both high-end and low-end computer systems. We present a complete system power simulator, called SoftWatt, that models the CPU, memory hierarchy, and a low-power disk subsystem and quantifies the power behavior of both the application and operating system. This tool, built on top of the SimOS infrastructure, uses validated analytical energy models to identify the power hotspots in the system components, capture relative contributions of the user and kernel code to the system power profile, identify the power-hungry operating system services and characterize the variance in kernel power profile with respect to workload. Our results using Spec JVM98 benchmark suite emphasize the importance of complete system simulation to understand the power impact of architecture and operating system on application execution.},
added-at = {2009-01-19T17:57:08.000+0100},
author = {Gurumurthi, S. and Sivasubramaniam, A. and Irwin, M.J. and Vijaykrishnan, N. and Kandemir, M.},
biburl = {https://www.bibsonomy.org/bibtex/24ac0424d6e8797b50d655459fc3302a8/derkling},
interhash = {afe44fcb885511972dbfd21076d97e2f},
intrahash = {4ac0424d6e8797b50d655459fc3302a8},
issn = {1530-0897},
journal = {Eighth International Symposium on High-Performance Computer Architecture},
keywords = {SoftWatt benchmark estimation optimization performance power simulation tools},
month = {Feb.},
pages = { 141-150},
timestamp = {2009-01-19T17:57:08.000+0100},
title = {Using complete machine simulation for software power estimation: the SoftWatt approach},
year = 2002
}