Understanding the future of energy-performance trade-off via DVFS in HPC environments

DVFS is a ubiquitous technique for CPU power management in modern computing systems. Reducing processor frequency/voltage leads to a decrease of CPU power consumption and an increase in the execution time. In this paper, we analyze which application/platform characteristics are necessary for a successful energy-performance trade-off of large scale parallel applications. We present a model that gives an upper bound on performance loss due to frequency scaling using the application parallel efficiency. The model was validated with performance measurements of large scale parallel applications. Then we track how application sensitivity to frequency scaling evolved over the last decade for different cluster generations. Finally, we study how cluster power consumption characteristics together with application sensitivity to frequency scaling determine the energy effectiveness of the DVFS technique.

► A model of CPU frequency scaling impact on MPI application performance.
► The model validation through measurements.
► An analysis of CPU frequency impact on parallel application execution.
► An overview of MPI application sensitivity to frequency scaling across different platform generations.
► A parametric analysis of DVFS energy-efficiency for MPI applications.