Thermally Composable Hybrid Application Mapping for Real-Time Applications in Heterogeneous Many-Core Systems

2019 IEEE Real-Time Systems Symposium (RTSS) Pub Date : 2019-12-01 DOI:10.1109/RTSS46320.2019.00029

Behnaz Pourmohseni, Fedor Smirnov, Heba Khdr, S. Wildermann, J. Teich, J. Henkel

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引用次数: 11

Abstract

Modern embedded many-core systems host, among others, real-time applications which must be dynamically launched at run time. To this end, Hybrid Application Mapping (HAM) methodologies combine design-time analysis with runtime mapping techniques to enable dynamic application mapping with performance guarantees, e.g., w.r.t. real-time constraints. They rely on composability to derive the required performance guarantees in an isolated analysis of individual applications at design time. The ongoing process technology downsizing, however, has given rise to an increased on-chip temperature, so that the thermal integrity of the platform must be monitored and enforced at run time by means of Dynamic Thermal Management (DTM) techniques which use countermeasures e.g. DVFS and power gating. This, however, violates composability, as the thermally unsafe behavior of one application may trigger DTM countermeasures that affect other applications running in the thermally affected region which, in turn, may lead to the violation of their real-time constraints. As a remedy, this paper proposes, for the first time, a thermally composable HAM methodology that enforces thermal safety proactively at the launch time of applications and, thereby, prevents DTM interferences which react to thermal violations. To that end, we present (a) a novel thermal-safety analysis that can be integrated into the design-time analysis of HAM and (b) a set of thermal-safety admission checks that can be used at run time when launching an application. By establishing thermal composability among running applications, the proposed HAM approach enables providing thermally safe real-time guarantees for dynamically mapped applications in many-core systems. Experimental results for a variety of hard real-time applications on multiple heterogeneous many-core architectures demonstrate the efficiency and effectiveness of the proposed methodology.

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异构多核系统中实时应用的热可组合混合应用映射

现代嵌入式多核系统托管实时应用程序，这些应用程序必须在运行时动态启动。为此，混合应用程序映射(HAM)方法将设计时分析与运行时映射技术结合起来，使动态应用程序映射具有性能保证，例如，w.r.t.实时约束。它们依赖于可组合性，在设计时对单个应用程序进行独立分析时获得所需的性能保证。然而，随着工艺技术的不断缩小，芯片上的温度也越来越高，因此必须通过动态热管理(DTM)技术在运行时监测和加强平台的热完整性，该技术使用了DVFS和功率门控等对策。然而，这违反了可组合性，因为一个应用程序的热不安全行为可能触发DTM对策，从而影响在热影响区域运行的其他应用程序，进而可能导致违反其实时约束。作为补救措施，本文首次提出了一种热可组合的HAM方法，该方法可以在应用程序发射时主动加强热安全性，从而防止DTM干扰对热违规作出反应。为此，我们提出了(a)一种新的热安全分析，可以集成到HAM的设计时分析中;(b)一套热安全准入检查，可以在启动应用程序时运行时使用。通过在运行的应用程序之间建立热可组合性，所提出的HAM方法能够为多核系统中的动态映射应用程序提供热安全的实时保证。在多种异构多核体系结构上的各种硬实时应用的实验结果证明了所提出方法的效率和有效性。

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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2019 IEEE Real-Time Systems Symposium (RTSS)

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