GraFF: A Multi-FPGA System with Memory Semantic Fabric for Scalable Graph Processing

2022 International Conference on Field-Programmable Technology (ICFPT) Pub Date : 2022-12-05 DOI:10.1109/ICFPT56656.2022.9974189

Xu Zhang, Yisong Chang, Tianyue Lu, Ke Liu, Ke Zhang, Mingyu Chen

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Abstract

FPGA has been a promising solution for graph processing in many scenarios. With a rapid growth in graph size, the on/off-chip memory capacity of a single FPGA is insufficient to hold large-scale graphs. To tackle such problem, in this position paper, we introduce GraFF, a Graph processing system with multiple FPGAs interconnected via a custom memory semantic Fabric. In order to efficiently exploit system parallelism, we first split the traversal of graph data into a series of independent fine-grained flits that are concurrently delivered among FPGAs as sheer memory semantic transactions. Then we relax FPGAs' synchronization from strict barrier boundaries between adjacent supersteps to fully parallelize graph traversing and computing. We build a prototype of GraFF with four custom FPGA nodes. Preliminary evaluation result based on the Breadth First Search (BFS) algorithm shows that the peak performance of GraFF reaches up to 6.23 GTEPS. Moreover, GraFF exhibits linear scalability when the number of FPGAs rises from one to four.

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基于记忆语义结构的多fpga可扩展图形处理系统

FPGA已经成为许多场景中图形处理的一个很有前途的解决方案。随着图形大小的快速增长，单个FPGA的片上/片外内存容量不足以容纳大规模图形。为了解决这样的问题，在这篇论文中，我们介绍了GraFF，一个通过自定义内存语义结构连接多个fpga的图形处理系统。为了有效地利用系统并行性，我们首先将图数据的遍历拆分为一系列独立的细粒度flits，这些flits作为纯内存语义事务并发地在fpga之间传递。然后，我们将fpga的同步从相邻超步之间的严格屏障边界放宽到完全并行图遍历和计算。我们用四个自定义FPGA节点构建了GraFF的原型。基于广度优先搜索(BFS)算法的初步评价结果表明，GraFF的峰值性能可达6.23 GTEPS。此外，当fpga数量从一个增加到四个时，GraFF表现出线性可扩展性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 International Conference on Field-Programmable Technology (ICFPT)

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