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Sound Concurrent Traces for Online Monitoring Technical Report


核心概念
The authors present a non-blocking vector clock algorithm to collect sound concurrent traces on the fly, addressing the challenge of monitoring concurrent programs online. They emphasize the importance of capturing necessary orderings in traces for effective monitoring.
要約

The technical report discusses the significance of capturing sound and faithful concurrent traces for online monitoring of concurrent programs. It introduces a vector clock algorithm that ensures correct ordering information in traces, highlighting the need for trace monitorability to avoid unsound verdicts. The report also evaluates the effectiveness and cost of trace collection approaches through experimentation on various benchmarks.

The report delves into defining trace soundness and faithfulness, exploring causal dependence relations, and establishing criteria for monitorability based on necessary orderings in traces. It further discusses optimal faithfulness ratios and potential optimizations in instrumentation to improve monitorability.

Overall, the content emphasizes the critical role of accurate trace collection in ensuring reliable online monitoring of concurrent programs, providing insights into key concepts and practical implementations.

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統計
Vector clock algorithms have been refined over several decades [19,56,6,66]. The quadratic bound on runtime complexity is a concern with existing approaches [19]. The tree clocks used in implementation improved performance [55].
引用
"The paper is concerned with providing representative traces for existing verification techniques to soundly monitor concurrent programs online." "Monitoring with unsound traces leads to unsound verdicts." "We envision an approach where multiple runs can guide instrumentation to reach optimal faithfulness."

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by Chukri Souei... 場所 arxiv.org 02-29-2024

https://arxiv.org/pdf/2402.18391.pdf
Sound Concurrent Traces for Online Monitoring Technical Report

深掘り質問

How can optimizing instrumentation help achieve optimal faithfulness ratios?

Optimizing instrumentation plays a crucial role in achieving optimal faithfulness ratios in trace collection for monitoring concurrent programs. By carefully selecting which events to capture and how to instrument them, we can focus on collecting only the necessary orderings required for monitoring specific properties. This optimization helps reduce unnecessary overhead and interference with program execution while ensuring that the collected traces are sound and faithful. One way to optimize instrumentation is by identifying the key synchronization actions and critical events relevant to the properties being monitored. By focusing on capturing these essential events, we can minimize the number of unnecessary orderings in the trace, leading to a more efficient and effective monitoring process. Additionally, optimizing instrumentation allows us to tailor the data collection process specifically for each property or scenario, ensuring that only relevant information is captured. Furthermore, optimizing instrumentation involves considering trade-offs between capturing sufficient ordering information for monitoring purposes and minimizing interference with program performance. By strategically choosing which events to instrument and how to collect them, we can strike a balance between accuracy in tracing concurrency behavior and efficiency in runtime monitoring. In essence, through careful optimization of instrumentation techniques, we can streamline the trace collection process, improve monitorability of concurrent executions, and ultimately achieve optimal faithfulness ratios that enhance the effectiveness of online monitoring systems.

How do linear traces differ from concurrent traces when it comes to monitoring complex concurrency primitives?

Linear traces differ significantly from concurrent traces when it comes to monitoring complex concurrency primitives due to their representation of event orderings in program executions. Linear Traces: Linear traces represent event sequences as total orders where every action is ordered relative to all other actions. They impose a strict sequential ordering on events regardless of whether they occur concurrently or not. Linear traces may lead to oversimplified representations of concurrent behavior by forcing all actions into a single linear sequence. Monitoring using linear traces may overlook subtle dependencies among concurrently executing actions since they prioritize total order over partial orders inherent in concurrency. Concurrent Traces: Concurrent traces capture partial orders reflecting causal dependencies between events occurring simultaneously or interleaved. They provide a more accurate depiction of real-world concurrency by preserving essential ordering constraints without enforcing unnecessary restrictions. Concurrent traces enable monitors...
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