Run-time technique for simultaneous aging and power optimization in GPGPUs

Abstract

High-performance general-purpose graphics processing units (GPGPUs) may suffer from serious power and negative bias temperature instability (NBTI) problems. In this paper, we propose a framework for run-time aging and power optimization. Our technique is based on the observation that many GPGPU applications achieve optimal performance with only a portion of cores due to either bandwidth saturation or shared resource contention. During run-time, given the dynamically tracked NBTI-induced threshold voltage shift and the problem size of GPGPU applications, our algorithm returns the optimal number of cores using detailed performance modeling. The unused cores are power-gated for power saving and NBTI recovery. Experiments show that our proposed technique achieves on average 34% reduction in NBTI-induced threshold voltage shift and 19% power reduction, while the average performance degradation is less than 1%.