Leonardo Passig Horstmann, José Luis Conradi Hoffmann, Antônio Augusto Fröhlich
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引用次数: 0
Abstract
Monitoring the performance of multicore embedded systems is crucial to properly ensure their timing requirements. Collecting performance data is also very relevant for optimization and validation efforts. However, the strategies used to monitor and capture data in such systems are complex to design and implement since they must not interfere with the running system beyond the point at which the system’s timing and performance characteristics start to get affected by the monitoring strategies. In this paper, we extend a monitoring framework developed in previous work to encompass three monitoring strategies, namely Active and Passive Periodic monitoring and Job-based monitoring. Periodic monitoring follows a given sampling rate. Active Periodic relies on periodic timer interrupts to guarantee deterministic sampling, while Passive Periodic trades determinism for a less invasive strategy, sampling data only when ordinary system events are handled. Job-based follows an event-driven monitoring that samples data whenever a job leaves the CPU, thus building isolated traces for each job. We evaluate them according to overhead, latency, and jitter, where none of them presented an average impact on the system execution time higher than \(0.3\%\). Moreover, a qualitative analysis is conducted in terms of data quality. On one hand, while Periodic monitoring allows for configurable sampling rates, it does not account for the rescheduling of jobs and may capture mixed traces. On the other hand, Job-based monitoring provides data samples tied to the execution of each job while disregarding sampling rate configuration and may lose track of instant measures.
监控多核嵌入式系统的性能对于正确确保其时序要求至关重要。收集性能数据对于优化和验证工作也非常重要。然而,在此类系统中用于监控和捕获数据的策略在设计和实施上非常复杂,因为这些策略必须在系统的时序和性能特征开始受到监控策略影响时,才不会对运行中的系统造成干扰。在本文中,我们扩展了之前工作中开发的监控框架,使其包含三种监控策略,即主动和被动定期监控以及基于任务的监控。定期监控遵循给定的采样率。主动定期监控依赖于定期定时器中断来保证确定性采样,而被动定期监控则以较低的侵入性策略来换取确定性,即仅在处理普通系统事件时采样数据。基于作业的方法采用事件驱动监控,每当作业离开 CPU 时就会对数据进行采样,从而为每个作业建立独立的跟踪。我们根据开销、延迟和抖动对它们进行了评估,结果发现它们对系统执行时间的平均影响都不高于(0.3/%/)。此外,我们还对数据质量进行了定性分析。一方面,虽然周期监控允许可配置的采样率,但它没有考虑作业的重新安排,可能会捕获到混合的痕迹。另一方面,基于作业的监控可提供与每个作业执行相关的数据样本,但不考虑采样率配置,可能会丢失即时测量数据。
期刊介绍:
Embedded (electronic) systems have become the electronic engines of modern consumer and industrial devices, from automobiles to satellites, from washing machines to high-definition TVs, and from cellular phones to complete base stations. These embedded systems encompass a variety of hardware and software components which implement a wide range of functions including digital, analog and RF parts.
Although embedded systems have been designed for decades, the systematic design of such systems with well defined methodologies, automation tools and technologies has gained attention primarily in the last decade. Advances in silicon technology and increasingly demanding applications have significantly expanded the scope and complexity of embedded systems. These systems are only now becoming possible due to advances in methodologies, tools, architectures and design techniques.
Design Automation for Embedded Systems is a multidisciplinary journal which addresses the systematic design of embedded systems, focusing primarily on tools, methodologies and architectures for embedded systems, including HW/SW co-design, simulation and modeling approaches, synthesis techniques, architectures and design exploration, among others.
Design Automation for Embedded Systems offers a forum for scientist and engineers to report on their latest works on algorithms, tools, architectures, case studies and real design examples related to embedded systems hardware and software.
Design Automation for Embedded Systems is an innovative journal which distinguishes itself by welcoming high-quality papers on the methodology, tools, architectures and design of electronic embedded systems, leading to a true multidisciplinary system design journal.