On power capping and performance optimization of multithreaded applications

Conoci, Stefano; Sanzo, Pierangelo Di; Pellegrini, Alessandro; Ciciani, Bruno; Quaglia, Francesco

doi:10.1002/cpe.6205

Cited by 5 publications

(3 citation statements)

References 36 publications

(39 reference statements)

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“…In terms of algorithmic comparison of the approach adopted by us to the other solutions described in Section 2 we shall mention that some of the latter differ in adopting an off-line approach, 31 using off-line data, 30 adopt additional code 32 and the majority employ various performance and/or energy models 30,37,38,[42][43][44] for optimization. We propose an on-line approach using auto measurements for runtime tuning without a need for code instrumentation at the cost of a specific application model described above.…”

Section: Discussionmentioning

confidence: 99%

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DEPO: A dynamic energy‐performance optimizer tool for automatic power capping for energy efficient high‐performance computing

2022

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In the article we propose an automatic power capping software tool DEPO that allows one to perform runtime optimization of performance and energy related metrics. For an assumed application model with an initialization phase followed by a running phase with uniform compute and memory intensity, the tool performs automatic tuning engaging one of the two exploration algorithms-linear search (LS) and golden section search (GSS), finds a power cap optimizing a given metric and sets it for the remaining computations. The considered metrics include energy (E), energy-delay sum, energy-delay product. We present experimental results obtained for a set of benchmarks that differ in compute and memory intensity-parallel custom built OpenMP implementations of: numerical integration, heat distribution simulation (HEAT), fast Fourier transform (FFT), and additionally NAS parallel benchmarks: CG, MG, BT, SP, and LU. Tests were performed using multi-core CPUs that are representatives of modern servers and the desktop family: 2 × Intel Xeon E5-2670 v3 CPU (Haswell-EP) and Intel i7-9700K CPU (Coffee Lake). The results show that our approach enabled considerable improvements for the tested metrics, for example, for HEAT and Coffee Lake we minimized energy by 50% at the cost of a 15% increase in execution time (LS), for FFT energy was minimized by 40% at a 25.5% increase in execution time (GSS), for SP and Haswell energy was minimized by 25% at the cost of an 18.5% time increase and for Coffee Lake energy was decreased by 56% with a 12% time increase. K E Y W O R D Sautomatic power capping, green computing, HPC, performance-energy trade-off, software tools INTRODUCTIONNowadays, providing high-performance computing (HPC) resources can be expensive, especially when the power required by computing centers exceeds megawatts. Under such circumstances, every method that allows users to decrease power consumption is extremely desirable, and even low energy savings are multiplied by the effects of scale. Thus, new

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Section: Discussionmentioning

confidence: 99%

“…Conoci et al 44 proposed techniques for optimization of throughput of a multithreaded application under a given power cap where two variables are considered: P‐state and the number of threads. The authors tested two strategies: exploration as well as model (with performance and power‐usage model construction) based.…”

Section: Related Workmentioning

confidence: 99%

DEPO: A dynamic energy‐performance optimizer tool for automatic power capping for energy efficient high‐performance computing

2022

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“…As a consequence, these studies does not rely on dynamic power capping but rather on a static user-defined power cap. Similarly, in [10] the authors adapted the number of cores and the frequency to match a defined power cap. In [33], the authors study the resources configuration to set in order to respect a power cap (hyperthreading, number of cores, .…”

Section: H Conclusionmentioning

confidence: 99%

Combining Uncore Frequency and Dynamic Power Capping to Improve Power Savings

Guermouche

2022

2022 IEEE International Parallel and Distributed Processing Symposium Workshops (IPDPSW)

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The US Department of Energy sets a limit of 20 to 30 MW for future exascale machines. In order to control their power consumption, modern processors provide many features. Power capping and uncore frequency scaling are examples of such features which allow to limit the power consumed by a processor.In this paper, we propose to combine dynamic power capping to uncore frequency scaling. We propose DUFP, an extension of DUF, an existing tool which dynamically adapts uncore frequency. DUFP dynamically adapts the processor power cap to the application needs. Finally, just like DUF, DUFP can tolerate performance loss up to a user-defined limit. With a controlled impact on performance, DUFP is able to provide power savings with no energy loss.The evaluation of DUFP shows that it manages to stay within the user-defined slowdown limits for most of the studied applications. Moreover, combining uncore frequency scaling to power capping: (i) improves power consumption by up to 13.98 % with additional energy savings for applications where uncore frequency scaling has a limited impact, (ii) improves power consumption by up to 7.90 % compared to using uncore frequency scaling by itself and (iii) leads to more than 5 % power savings at 5 % tolerated slowdown with no energy loss for most applications.

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