Embedded reconfigurable computing: the ERA approach

G. Keramidas, Stephan Wong, Fakhar Anjam, Anthony Brandon, Roel Seedorf, Claudio Scordino, L. Carro, D. Matos, R. Giorgi, Stamatis Kavvadias, S. Mckee, Bhavishya Goel, Vasileios Spiliopoulos
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引用次数: 4

Abstract

The growing complexity and diversity of embedded systems-combined with continuing demands for higher performance and lower power consumption-places increasing pressure on embedded platforms designers. The target of the ERA project is to offer a holistic, multi-dimensional methodology to address these problems in a unified framework exploiting the inter- and intra-synergism between the reconfigurable hardware (core, memory, and network resources), the reconfigurable software (compiler and tools), and the run-time system. Starting from the hardware level, we design our platform via a structured approach that allows integration of reconfigurable computing elements, network fabrics, and memory hierarchy components. These hardware elements can adapt their composition, organization, and even instruction-set architectures to exploit tradeoffs in performance and power. Appropriate hardware resources can be selected both statically at design time and dynamically at run time. Hardware details are exposed to our custom operating system, our custom runtime system, and our adaptive compiler, and are even visible all the way up to the application level. The design philosophy followed in the ERA project proved efficient enough not only to enable a better choice of power/performance trade-offs but also to support fast platform prototyping of high-efficiency embedded system designs. In this paper, we present a brief overview of the design approach, the major outcomes, and the lessons learned in the ERA project.
嵌入式可重构计算:ERA方法
嵌入式系统日益增长的复杂性和多样性,以及对更高性能和更低功耗的持续需求,给嵌入式平台设计人员带来了越来越大的压力。ERA项目的目标是提供一个整体的、多维的方法,在一个统一的框架中利用可重构硬件(核心、内存和网络资源)、可重构软件(编译器和工具)和运行时系统之间的内部协同作用来解决这些问题。从硬件级别开始,我们通过结构化方法设计我们的平台,该方法允许集成可重构的计算元素、网络结构和内存层次结构组件。这些硬件元素可以调整它们的组成、组织,甚至指令集体系结构,以利用性能和功率方面的折衷。适当的硬件资源可以在设计时静态地选择,也可以在运行时动态地选择。硬件细节暴露给我们的自定义操作系统、自定义运行时系统和自适应编译器,甚至在应用程序级别上都是可见的。ERA项目遵循的设计理念被证明是足够高效的,不仅能够更好地选择功耗/性能权衡,而且还支持高效嵌入式系统设计的快速平台原型。在本文中,我们简要概述了ERA项目的设计方法、主要成果和经验教训。
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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