high performance computing on graphics processing units: hgpu.org

With the rising number of application accelerators, developers are looking for ways to evaluate new and competing platforms quickly, fairly, and early in the development cycle. As high-performance computing (HPC) applications increase their demands on application acceleration platforms, graphics processing units (GPUs) provide a potential solution for many developers looking for increased performance. Device performance metrics, such as Computational Density (CD), provide a useful but limited starting point for device comparison. The authors developed the Realizable Utilization (RU) metric and methodology to quantify the discrepancy between theoretical device performance shown by CD and the performance developers can achieve. As the RU score increases, the application is achieving a larger percentage of the computational power the device can provide. The authors survey technical publications about GPUs and use this data to analyze the RU scores for several arithmetic application kernels that are frequently accelerated in GPUs. The RU concepts presented in this paper are a first step towards a formalized comparison framework for diverse devices such as CPUs, FPGAs, GPUs and other novel architectures. GPU kernels for matrix multiplication, matrix decomposition, and N-body simulations show RU scores ranging from almost 0% to approaching 99% depending on the application, but all kernel areas show a significant decrease in RU as the computational capacities increase. Additionally, the RU scores show the higher realized performance of the GeForce 8 Series GPUs versus newer GPU architectures. This paper shows that applications running on GPUs with higher computational density report significantly lower RU scores than more mature GPUs with lower computational density. This trend implies that while the raw performance available is still increasing with newer GPUs, the achieved performance is not keeping pace with the theoretical capacities of the devices.