N. Simakov, Matthew D. Jones, T. Furlani, E. Siegmann, Robert Harrison
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引用次数: 0
摘要
英伟达™(NVIDIA®)Grace CPU 超级芯片和英伟达™(NVIDIA®)Grace Hopper 超级芯片的工程样品通过不同的基准和科学应用进行了测试。基准测试包括 HPCC 和 HPCG。基于实际应用的基准包括 AI-Benchmark-Alpha(TensorFlow 基准)、Gromacs、OpenFOAM 和 ROMS。性能与多个英特尔、AMD、ARM CPU 以及多个 x86 和英伟达™(NVIDIA®)GPU 系统进行了比较。根据 TDP 值对能效进行了简要评估。我们发现,在 HPCC 基准测试中,Grace 的单位内核性能与 AMD 米兰内核相近或更快,而高内核数往往使英伟达™ Grace CPU 超级芯片的单位节点性能与配备高带宽内存的英特尔蓝宝石锐龙相似:矩阵乘法(慢 17%)和 FFT(慢 6%),Linpack(快 9%))。在科学应用中,英伟达™(NVIDIA®)Grace CPU 超级芯片的性能在 Gromacs 中要慢 6% 到 18%,在 OpenFOAM 中要快 7%,在 ROMS 中则介于英特尔蓝宝石锐龙的 HBM 和 DDR 模式之间。在 Gromacs 中,CPU-GPU 的组合性能比任何经过测试的 x86-NVIDIA GPU 系统都要快得多(快 20% 到 117%)。总之,新的英伟达™(NVIDIA®)Grace Hopper 超级芯片和英伟达™(NVIDIA®)Grace CPU 超级芯片是高性能、高能效的高性能计算中心解决方案。
First Impressions of the NVIDIA Grace CPU Superchip and NVIDIA Grace Hopper Superchip for Scientific Workloads
The engineering samples of the NVIDIA Grace CPU Superchip and NVIDIA Grace Hopper Superchips were tested using different benchmarks and scientific applications. The benchmarks include HPCC and HPCG. The real application-based benchmark includes AI-Benchmark-Alpha (a TensorFlow benchmark), Gromacs, OpenFOAM, and ROMS. The performance was compared to multiple Intel, AMD, ARM CPUs and several x86 with NVIDIA GPU systems. A brief energy efficiency estimate was performed based on TDP values. We found that in HPCC benchmark tests, the per-core performance of Grace is similar to or faster than AMD Milan cores, and the high core count often allows NVIDIA Grace CPU Superchip to have per-node performance similar to Intel Sapphire Rapids with High Bandwidth Memory: slower in matrix multiplication (by 17%) and FFT (by 6%), faster in Linpack (by 9%)). In scientific applications, the NVIDIA Grace CPU Superchip performance is slower by 6% to 18% in Gromacs, faster by 7% in OpenFOAM, and right between HBM and DDR modes of Intel Sapphire Rapids in ROMS. The combined CPU-GPU performance in Gromacs is significantly faster (by 20% to 117% faster) than any tested x86-NVIDIA GPU system. Overall, the new NVIDIA Grace Hopper Superchip and NVIDIA Grace CPU Superchip Superchip are high-performance and most likely energy-efficient solutions for HPC centers.
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