自动GPU网格几何选择的OPENMP内核

2018 30th International Symposium on Computer Architecture and High Performance Computing (SBAC-PAD) Pub Date : 2018-09-01 DOI:10.1109/CAHPC.2018.8645848

T. Lloyd, Artem Chikin, Sanket Kedia, D. Jain, J. N. Amaral

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引用次数: 6

摘要

现代超级计算机越来越多地使用gpu来提高每瓦特的性能。在openMP 4.0或更高版本中，为目标区域生成GPU代码需要选择网格几何形状来执行GPU内核。现有的工业级编译器使用一种简单的启发式方法，其任意数字对于所有内核都是恒定的。在描述了区域特征、网格几何形状和性能之间的关系之后，我们建立了一个机器学习模型，该模型成功地预测了这些核的合适几何形状，并在所研究的基准测试中获得了5%的几何平均值的性能改进。然而，这种预测是不切实际的，因为预测器的开销太高了。对预测器结果的仔细研究允许开发实用的低开销启发式，该启发式导致性能提高高达7倍，几何平均值为25.9%。本文描述了构建机器学习模型的方法，以及可用于行业强大编译器的实用低开销启发式方法。

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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Automated GPU Grid Geometry Selection for OPENMP Kernels

Modern supercomputers are increasingly using GPUs to improve performance per watt. Generating GPU code for target regions in openMP 4.0, or later versions, requires the selection of grid geometry to execute the GPU kernel. Existing industrial-strength compilers use a simple heuristic with arbitrary numbers that are constant for all kernels. After characterizing the relationship between region features, grid geometry and performance, we built a machine-learning model that successfully predicts a suitable geometry for such kernels and results in a performance improvement with a geometric mean of 5% across the benchmarks studied. However, this prediction is impractical because the overhead of the predictor is too high. A careful study of the results of the predictor allowed for the development of a practical low-overhead heuristic that resulted in a performance improvement of up to 7 times with a geometric mean of 25.9%. This paper describes the methodology to build the machine-learning model, and the practical low-overhead heuristic that can be used in industry-strong compilers.

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2018 30th International Symposium on Computer Architecture and High Performance Computing (SBAC-PAD)

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