Accelerating Weather Prediction Using Near-Memory Reconfigurable Fabric

Ongoing climate change calls for fast and accurate weather and climate modeling. However, when solving large-scale weather prediction simulations, state-of-the-art CPU and GPU implementations suffer from limited performance and high energy consumption. These implementations are dominated by complex irregular memory access patterns and low arithmetic intensity that pose fundamental challenges to acceleration. To overcome these challenges, we propose and evaluate the use of near-memory acceleration using a reconfigurable fabric with high-bandwidth memory (HBM). We focus on compound stencils that are fundamental kernels in weather prediction models. By using high-level synthesis techniques, we develop NERO, an field-programmable gate array+HBM-based accelerator connected through Open Coherent Accelerator Processor Interface to an IBM POWER9 host system. Our experimental results show that NERO outperforms a 16-core POWER9 system by 5.3x and 12.7x when running two different compound stencil kernels. NERO reduces the energy consumption by 12x and 35x for the same two kernels over the POWER9 system with an energy efficiency of 1.61 GFLOPS/W and 21.01 GFLOPS/W. We conclude that employing near-memory acceleration solutions for weather prediction modeling is promising as a means to achieve both high performance and high energy efficiency.

Automated summary

The ongoing climate change requires fast and accurate weather and climate modeling. However, current CPU and GPU implementations face limitations in performance and energy consumption for large-scale weather prediction simulations. To overcome these challenges, near-memory acceleration using high-bandwidth memory (HBM) is proposed and evaluated. Experimental results show significant performance improvement and energy efficiency compared to traditional methods.