Ray tracing within a data parallel framework

Matthew Larsen, J. Meredith, P. Navrátil, H. Childs
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引用次数: 32

Abstract

Current architectural trends on supercomputers have dramatic increases in the number of cores and available computational power per die, but this power is increasingly difficult for programmers to harness effectively. High-level language constructs can simplify programming many-core devices, but this ease comes with a potential loss of processing power, particularly for cross-platform constructs. Recently, scientific visualization packages have embraced language constructs centering around data parallelism, with familiar operators such as map, reduce, gather, and scatter. Complete adoption of data parallelism will require that central visualization algorithms be revisited, and expressed in this new paradigm while preserving both functionality and performance. This investment has a large potential payoff: portable performance in software bases that can span over the many architectures that scientific visualization applications run on. With this work, we present a method for ray tracing consisting of entirely of data parallel primitives. Given the extreme computational power on nodes now prevalent on supercomputers, we believe that ray tracing can supplant rasterization as the work-horse graphics solution for scientific visualization. Our ray tracing method is relatively efficient, and we describe its performance with a series of tests, and also compare to leading-edge ray tracers that are optimized for specific platforms. We find that our data parallel approach leads to results that are acceptable for many scientific visualization use cases, with the key benefit of providing a single code base that can run on many architectures.
数据并行框架中的光线跟踪
当前超级计算机的架构趋势是,内核数量和每个芯片的可用计算能力都在急剧增加,但程序员越来越难以有效地利用这种能力。高级语言结构可以简化多核设备的编程,但是这种简化带来了处理能力的潜在损失,特别是对于跨平台结构。最近,科学可视化包已经包含了围绕数据并行性的语言结构,以及熟悉的操作符,如map、reduce、gather和scatter。完全采用数据并行性将需要重新审视中心可视化算法,并在保留功能和性能的同时以这种新范式表示。这项投资有很大的潜在回报:软件基础的可移植性能可以跨越科学可视化应用程序所运行的许多体系结构。通过这项工作,我们提出了一种完全由数据并行原语组成的光线追踪方法。考虑到超级计算机在节点上的极端计算能力,我们相信光线追踪可以取代栅格化,成为科学可视化的主要图形解决方案。我们的光线追踪方法相对有效,我们通过一系列测试描述了它的性能,并与针对特定平台优化的前沿光线追踪器进行了比较。我们发现,我们的数据并行方法产生的结果对于许多科学可视化用例来说都是可以接受的,其主要好处是提供了一个可以在许多体系结构上运行的单一代码库。
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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