Jaewoo Lee, Kieu-My Phan, Xiaozhe Gu, Jiyeon Lee, A. Easwaran, I. Shin, Insup Lee
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引用次数: 70
摘要
混合临界系统由多个不同临界的组件组成。虽然混合临界调度在单处理器情况下已经得到了广泛的研究,但多处理器情况下的有效调度问题在很大程度上仍然是开放的。我们设计了一种基于流体模型的多处理器混合临界调度算法,称为MC-Fluid,其中每个任务按其临界依赖率的比例执行。我们提出了MC-Fluid的精确可调度性条件和一个多项式复杂度的临界相关执行率的最优分配算法。针对MC-Fluid基于流体假设而无法在实际硬件平台上构建调度的问题,我们提出了MC-DP-Fair算法,该算法可以生成非流体调度,同时保持MC-Fluid的可调度性。MC- fluid的加速因子为(1 + v 5)/2(1.618),是多处理器MC调度中最著名的加速因子,仿真结果表明MC- dp - fair优于现有的所有算法。
MC-Fluid: Fluid Model-Based Mixed-Criticality Scheduling on Multiprocessors
A mixed-criticality system consists of multiple components with different criticalities. While mixed-criticality scheduling has been extensively studied for the uniprocessor case, the problem of efficient scheduling for the multiprocessor case has largely remained open. We design a fluid model-based multiprocessor mixed-criticality scheduling algorithm, called MC-Fluid, in which each task is executed in proportion to its criticality-dependent rate. We propose an exact schedulability condition for MC-Fluid and an optimal assignment algorithm for criticality-dependent execution rates with polynomial complexity. Since MC-Fluid cannot construct a schedule on real hardware platforms due to the fluid assumption, we propose MC-DP-Fair algorithm, which can generate a non-fluid schedule while preserving the same schedulability properties as MC-Fluid. We show that MC-Fluid has a speedup factor of (1 + v 5)/2 ( 1.618), which is best known in multiprocessor MC scheduling, and simulation results show that MC-DP-Fair outperforms all existing algorithms.
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