MaPU: A novel mathematical computing architecture

2016 IEEE International Symposium on High Performance Computer Architecture (HPCA) Pub Date : 2016-03-12 DOI:10.1109/HPCA.2016.7446086

Donglin Wang, Xueliang Du, Leizu Yin, Chen Lin, Hong Ma, Weili Ren, Huijuan Wang, Xingang Wang, Shaolin Xie, L. Wang, Zijun Liu, Tao Wang, Zhonghua Pu, Guangxin Ding, Mengchen Zhu, Lipeng Yang, Ruoshan Guo, Zhiwei Zhang, Xiao Lin, Jie Hao, Yongyong Yang, Wenqin Sun, Fabiao Zhou, NuoZhou Xiao, Q. Cui, Xiaoqin Wang

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引用次数: 21

Abstract

As the feature size of the semiconductor process is scaling down to 10nm and below, it is possible to assemble systems with high performance processors that can theoretically provide computational power of up to tens of PLOPS. However, the power consumption of these systems is also rocketing up to tens of millions watts, and the actual performance is only around 60% of the theoretical performance. Today, power efficiency and sustained performance have become the main foci of processor designers. Traditional computing architecture such as superscalar and GPGPU are proven to be power inefficient, and there is a big gap between the actual and peak performance. In this paper, we present the MaPU architecture, a novel architecture which is suitable for data-intensive computing with great power efficiency and sustained computation throughput. To achieve this goal, MaPU attempts to optimize the application from a system perspective, including the hardware, algorithm and corresponding program model. It uses an innovative multi-granularity parallel memory system with intrinsic shuffle ability, cascading pipelines with wide SIMD data paths and a state-machine-based program model. When executing typical signal processing algorithms, a single MaPU core implemented with a 40nm process exhibits a sustained performance of 134 GLOPS while consuming only 2.8 W in power, which increases the actual power efficiency by an order of magnitude comparable with the traditional CPU and GPGPU.

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MaPU:一种新颖的数学计算架构

随着半导体工艺的特征尺寸缩小到10nm及以下，有可能组装具有高性能处理器的系统，理论上可以提供高达数十PLOPS的计算能力。然而，这些系统的功耗也飙升至数千万瓦，实际性能仅为理论性能的60%左右。如今，功耗效率和持续性能已成为处理器设计者关注的焦点。传统的计算架构如超标量和GPGPU被证明是低功耗的，并且实际性能与峰值性能之间存在很大差距。本文提出了一种适用于数据密集型计算的新型架构——MaPU架构，该架构具有较高的功耗效率和持续的计算吞吐量。为了实现这一目标，MaPU尝试从系统的角度对应用程序进行优化，包括硬件、算法和相应的程序模型。它采用一种创新的多粒度并行存储系统，具有内在的shuffle能力，具有宽SIMD数据路径的级联管道和基于状态机的程序模型。在执行典型的信号处理算法时，采用40nm工艺实现的单个MaPU内核在功耗仅为2.8 W的情况下，具有134 GLOPS的持续性能，与传统CPU和GPGPU相比，实际功率效率提高了一个数量级。

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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来源期刊

2016 IEEE International Symposium on High Performance Computer Architecture (HPCA)

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