Efficient synthesis of compressor trees on FPGAs

Abstract

FPGA performance is currently lacking for arithmetic circuits. Large sums of k > 2 integer values is a computationally intensive operation in applications such as digital signal and video processing. In ASIC design, compressor trees, such as Wallace and Dadda trees, are used for parallel accumulation; however, the LUT structure and fast carry-chains employed by modern FPGAs favor trees of carry-propagate adders (CPAs), which are a poor choice for ASIC design. This paper presents the first method to successfully synthesize compressor trees on LUT-based FPGAs. In particular, we have found that generalized parallel counters (GPCs) map quite well to LUTs on FPGAs; a heuristic, presented within, constructs a compressor tree from a library of GPCs that can efficiently be implemented on the target FPGA. Compared to the ternary adder trees produced by commercial synthesis tools, our heuristic reduces the combinational delay by 27.5%, on average, within a tolerable average area increase of 5.7%.