From Mesh Generation to Scientific Visualization: An End-to-End Approach to Parallel Supercomputing

ACM/IEEE SC 2006 Conference (SC'06) Pub Date : 2006-11-11 DOI:10.1145/1188455.1188551

Tiankai Tu, Hongfeng Yu, L. Ramírez-Guzmán, J. Bielak, O. Ghattas, K. Ma, D. O'Hallaron

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引用次数: 184

Abstract

Parallel supercomputing has traditionally focused on the inner kernel of scientific simulations: the solver. The front and back ends of the simulation pipeline - problem description and interpretation of the output - have taken a back seat to the solver when it comes to attention paid to scalability and performance, and are often relegated to offline, sequential computation. As the largest simulations move beyond the realm of the terascale and into the petascale, this decomposition in tasks and platforms becomes increasingly untenable. We propose an end-to-end approach in which all simulation components - meshing, partitioning, solver, and visualization - are tightly coupled and execute in parallel with shared data structures and no intermediate I/O. We present our implementation of this new approach in the context of octree-based finite element simulation of earthquake ground motion. Performance evaluation on up to 2048 processors demonstrates the ability of the end-to-end approach to overcome the scalability bottlenecks of the traditional approach

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从网格生成到科学可视化:并行超级计算的端到端方法

传统上，并行超级计算关注的是科学模拟的核心:求解器。仿真管道的前端和后端——问题描述和输出解释——在关注可伸缩性和性能时，已经让位于求解器，并且经常被降级为离线顺序计算。随着最大的模拟从万亿级扩展到千万亿级，这种任务和平台的分解变得越来越站不住脚。我们提出了一种端到端方法，其中所有仿真组件-网格划分，分区，求解器和可视化-紧密耦合并与共享数据结构并行执行，没有中间I/O。我们在基于八叉树的地震地面运动有限元模拟的背景下提出了这种新方法的实现。对多达2048个处理器的性能评估表明，端到端方法能够克服传统方法的可伸缩性瓶颈

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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ACM/IEEE SC 2006 Conference (SC'06)

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