Abstract
Massive spatial parallelism at low energy gives FPGAs the potential to be core components in large scale high performance computing (HPC) systems. In this paper we present four major design steps that harness high-level synthesis (HLS) to implement scalable spatial FPGA algorithms. To aid productivity, we introduce the open source library hlslib to complement HLS. We evaluate kernels designed with our approach on an FPGA accelerator board, demonstrating high performance and board utilization with enhanced programmer productivity. By following our guidelines, programmers can use HLS to develop efficient parallel algorithms for FPGA, scaling their implementations with increased resources on future hardware.
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