为现代分布式内存张量软件生成耦合集群代码

arXiv - PHYS - Chemical Physics Pub Date : 2024-09-10 DOI:arxiv-2409.06759

Jan Brandejs, Johann Pototschnig, Trond Saue

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引用次数: 0

摘要

科学团体正努力使其代码适应快速发展的基于 GPU 的高性能计算平台。分布式耦合集群（CC）计算领域也不例外。此外，我们对微小 QEDeffects 的应用需要高阶 CC，其中包括成千上万的张量收缩，这使得自动处理势在必行。我们面临的挑战是，如何通过捕捉问题的关键对称性来高效实现，同时保留对硬件的抽象。我们提出了张量编程框架tenpi，试图找到这种平衡。Tenpi 为 DIRAC 的大规模并行模块带来了高阶 CC 功能。架构和设计决策方案附有基准测试，以及 Summit、Frontier 和 LUMI 上的首次生产计算和最先进的张量收缩软件。

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Generating coupled cluster code for modern distributed memory tensor software

Scientific groups are struggling to adapt their codes to quickly-developing GPU-based HPC platforms. The domain of distributed coupled cluster (CC) calculations is not an exception. Moreover, our applications to tiny QED effects require higher-order CC which include thousands of tensor contractions, which makes automatic treatment imperative. The challenge is to allow efficient implementation by capturing key symmetries of the problem, while retaining the abstraction from the hardware. We present the tensor programming framework tenpi, which seeks to find this balance. It features a python library user interface, global optimization of intermediates, a visualization module and Fortran code generator that bridges the DIRAC package for relativistic molecular calculations to tensor contraction libraries. tenpi brings higher-order CC functionality to the massively parallel module of DIRAC. The architecture and design decision schemes are accompanied by benchmarks and by first production calculations on Summit, Frontier and LUMI along with state-of-the-art of tensor contraction software.

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arXiv - PHYS - Chemical Physics

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