GraM: scaling graph computation to the trillions

Proceedings of the Sixth ACM Symposium on Cloud Computing Pub Date : 2015-08-27 DOI:10.1145/2806777.2806849

Ming Wu, Fan Yang, Jilong Xue, Wencong Xiao, Youshan Miao, Lan Wei, Haoxiang Lin, Yafei Dai, Lidong Zhou

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引用次数: 133

Abstract

GraM is an efficient and scalable graph engine for a large class of widely used graph algorithms. It is designed to scale up to multicores on a single server, as well as scale out to multiple servers in a cluster, offering significant, often over an order-of-magnitude, improvement over existing distributed graph engines on evaluated graph algorithms. GraM is also capable of processing graphs that are significantly larger than previously reported. In particular, using 64 servers (1,024 physical cores), it performs a PageRank iteration in 140 seconds on a synthetic graph with over one trillion edges, setting a new milestone for graph engines. GraM's efficiency and scalability comes from a judicious architectural design that exploits the benefits of multi-core and RDMA. GraM uses a simple message-passing based scaling architecture for both scaling up and scaling out to expose inherent parallelism. It further benefits from a specially designed multi-core aware RDMA-based communication stack that preserves parallelism in a balanced way and allows overlapping of communication and computation. A high degree of parallelism often comes at the cost of lower efficiency due to resource fragmentation. GraM is equipped with an adaptive mechanism that evaluates the cost and benefit of parallelism to decide the appropriate configuration. Combined, these mechanisms allow GraM to scale up and out with high efficiency.

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GraM:将图计算缩放到数万亿

GraM是一种高效的、可扩展的图引擎，用于大量广泛使用的图算法。它旨在扩展到单个服务器上的多核，以及扩展到集群中的多个服务器，在评估图算法上提供比现有分布式图引擎显著(通常超过数量级)的改进。GraM还能够处理比以前报道的大得多的图。特别是，使用64台服务器(1024个物理内核)，它在140秒内对一个超过一万亿边的合成图执行一次PageRank迭代，为图引擎设定了一个新的里程碑。GraM的效率和可伸缩性来自明智的体系结构设计，该设计充分利用了多核和RDMA的优势。GraM使用一个简单的基于消息传递的扩展体系结构来向上扩展和向外扩展，以暴露固有的并行性。它还受益于专门设计的多核感知rdma通信堆栈，该堆栈以平衡的方式保持并行性，并允许通信和计算的重叠。高度的并行性通常是以由于资源分散而降低效率为代价的。GraM配备了一种自适应机制，用于评估并行性的成本和收益，以决定适当的配置。结合起来，这些机制允许GraM以高效率向上和向外扩展。

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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Proceedings of the Sixth ACM Symposium on Cloud Computing

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