FastRW: A Dataflow-Efficient and Memory-Aware Accelerator for Graph Random Walk on FPGAs

Abstract

Graph random walk (GRW) sampling is becoming increasingly important with the widespread popularity of graph applications. It involves some walkers that wander through the graph to capture the desirable properties and reduce the size of the original graph. However, previous research suffers long sampling latency and severe memory access bottlenecks due to intrinsic data dependency and irregular vertex distribution. This paper proposes FastRW, a dedicated accelerator to release GRW acceleration on FPGAs. FastRW first schedules walkers' execution to address data dependency and mask long sampling latency. Then, FastRW leverages pipeline specialization and bit-level optimization to customize a processing engine with five modules and achieve a pipelining dataflow. Finally, to alleviate the differential accesses caused by irregular vertex distribution, FastRW implements a hybrid memory architecture to provide parallel access ports according to the vertex's degree. We evaluate FastRW with two classic GRW algorithms on a wide range of real-world graph datasets. The experimental results show that FastRW achieves a speedup of 14.13× on average over the system running on two 8-core Intel CPUs. FastRW also achieves 3.28×∼198.24× energy efficiency over the architecture implemented on V100 GPU.