0.5 Petabyte Simulation of a 45-Qubit Quantum Circuit

SC17: International Conference for High Performance Computing, Networking, Storage and Analysis Pub Date : 2017-04-04 DOI:10.1145/3126908.3126947

Thomas Häner, Damian S. Steiger

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引用次数: 142

Abstract

Near-term quantum computers will soon reach sizes that are challenging to directly simulate, even when employing the most powerful supercomputers. Yet, the ability to simulate these early devices using classical computers is crucial for calibration, validation, and benchmarking. In order to make use of the full potential of systems featuring multi- and many-core processors, we use automatic code generation and optimization of compute kernels, which also enables performance portability. We apply a scheduling algorithm to quantum supremacy circuits in order to reduce the required communication and simulate a 45-qubit circuit on the Cori II supercomputer using 8, 192 nodes and 0.5 petabytes of memory. To our knowledge, this constitutes the largest quantum circuit simulation to this date. Our highly-tuned kernels in combination with the reduced communication requirements allow an improvement in time-to-solution over state-of-the-art simulations by more than an order of magnitude at every scale. CCS CONCEPTS Applied computing $\rightarrow$ Physics;

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45-Qubit量子电路的0.5 pb模拟

短期内，量子计算机将很快达到难以直接模拟的规模，即使使用最强大的超级计算机也是如此。然而，使用经典计算机模拟这些早期设备的能力对于校准、验证和基准测试至关重要。为了充分利用具有多核和多核处理器的系统的潜力，我们使用自动代码生成和计算内核的优化，这也使性能可移植性。为了减少所需的通信，我们将调度算法应用于量子霸权电路，并在Cori II超级计算机上使用8,192个节点和0.5 pb的内存模拟45量子位电路。据我们所知，这是迄今为止最大的量子电路模拟。我们高度调整的内核与减少的通信要求相结合，可以在每个尺度上比最先进的模拟提高一个数量级以上的解决时间。CCS概念应用计算$\右箭头$物理;

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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SC17: International Conference for High Performance Computing, Networking, Storage and Analysis

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