使用动态可重构隔离单元的能量感知的粗粒度可重构架构

Syed M. A. H. Jafri, Ozan Bag, A. Hemani, Nasim Farahini, K. Paul, J. Plosila, H. Tenhunen
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引用次数: 23

摘要

本文提出了一种自适应架构,以提高粗粒度可重构架构(CGRAs)的能效。如今,平台承载着多个应用程序,具有任意的应用程序间通信和并发模式。每个应用程序本身可以有多个版本(具有不同并行度的实现),而最佳版本只能在运行时确定。对于这样的场景,传统的最坏情况设计和编译时映射决策既不是最优的,也不是理想的。针对此问题的现有解决方案使用昂贵的专用硬件在运行时配置操作点(使用DVFS)。作为专用硬件的替代方案,我们建议利用现代CGRAs的重新配置特性。我们的解决方案依赖于动态可重构隔离单元(DRICs)和自主并行、电压和频率选择算法(APVFS)。drc通过将现有资源配置为隔离单元来减少DVFS电路的开销。APVFS通过动态选择并行度、电压和频率三重奏来确保高效率,从而消耗最小的功率以满足可用资源的最后期限。使用代表性应用程序(矩阵乘法、FIR和FFT)的仿真结果显示,与传统的DVFS设计相比,功率和能量分别降低了23%和51%。合成结果证实,与最先进的DVFS方法相比,面积开销显着减少。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Energy-aware coarse-grained reconfigurable architectures using dynamically reconfigurable isolation cells
This paper presents a self adaptive architecture to enhance the energy efficiency of coarse-grained reconfigurable architectures (CGRAs). Today, platforms host multiple applications, with arbitrary inter-application communication and concurrency patterns. Each application itself can have multiple versions (implementations with different degree of parallelism) and the optimal version can only be determined at runtime. For such scenarios, traditional worst case designs and compile time mapping decisions are neither optimal nor desirable. Existing solutions to this problem employ costly dedicated hardware to configure the operating point at runtime (using DVFS). As an alternative to dedicated hardware, we propose exploiting the reconfiguration features of modern CGRAs. Our solution relies on dynamically reconfigurable isolation cells (DRICs) and autonomous parallelism, voltage, and frequency selection algorithm (APVFS). The DRICs reduce the overheads of DVFS circuitry by configuring the existing resources as isolation cells. APVFS ensures high efficiency by dynamically selecting the parallelism, voltage and frequency trio, which consumes minimum power to meet the deadlines on available resources. Simulation results using representative applications (Matrix multiplication, FIR, and FFT) showed up to 23% and 51% reduction in power and energy, respectively, compared to traditional DVFS designs. Synthesis results have confirmed significant reduction in area overheads compared to state of the art DVFS methods.
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