An Efficient Memory Partitioning Approach for Multi-Pattern Data Access via Data Reuse

Abstract

Memory bandwidth has become a bottleneck that impedes performance improvement during the parallelism optimization of the datapath. Memory partitioning is a practical approach to reduce bank-level conflicts and increase the bandwidth on a field-programmable gate array. In this work, we propose a memory partitioning approach for multi-pattern data access. First, we propose to combine multiple patterns into a single pattern to reduce the complexity of multi-pattern. Then, we propose to perform data reuse analysis on the combined pattern to find data reuse opportunities and the non-reusable data pattern. Finally, an efficient bank mapping algorithm with low complexity and low overhead is proposed to find the optimal memory partitioning solution. Experimental results demonstrated that compared to the state-of-the-art method, our proposed approach can reduce the number of block RAMS by 58.9% on average, with 79.6% reduction in SLICEs, 85.3% reduction in LUTs, 67.9% in reduction Flip-Flops, 54.6% reduction in DSP48Es, 83.9% reduction in SRLs, 50.0% reduction in storage overhead, 95.0% reduction in execution time, and 77.3% reduction in dynamic power consumption on average. Meanwhile, the performance can be improved by 14.0% on average.