OpenMDS: An Open-Source Shell Generation Framework for High-Performance Design on Xilinx Multi-Die FPGAs

Abstract

FPGA is a promising platform in designing hardware due to its design flexibility and fast development cycle, despite the device's limited hardware resources. To address this, latest FPGAs have adopted a multi-die architecture that employs multiple dies in a single device to provide abundant hardware resources. However, the multi-die architecture causes critical timing issues when signal paths cross the die-to-die boundaries, adding another design challenge in using FPGA. We propose OpenMDS, an open-source shell generation framework for high-performance design on Xilinx multi-die FPGAs. Based on the user's design requirements, it generates an optimized shell for the target FPGA via die-level kernel encapsulation, automated bus pipelining, and customized floorplanning. To evaluate our shell generation, we compare its implementation results against Xilinx's Vitis framework. As a result, OpenMDS uses average 20% less logic resources than Vitis for the same shell functionality. To show its practicality, we use OpenMDS for the design of machine learning accelerator that contains multiple systolic-array processors. OpenMDS achieves 247MHz and 235MHz kernel frequency and 400MHz and 429MHz memory bus frequency for U50 and U280, respectively, for the accelerator design over 90% logic utilization, claiming up to 12.27% and 22.92% higher kernel and memory bus frequency over Vitis.