A Theory of Packet Flows Based on Law-of-Mass-Action Scheduling

2012 IEEE 31st Symposium on Reliable Distributed Systems Pub Date : 2012-10-08 DOI:10.1109/SRDS.2012.2

Thomas Meyer, C. Tschudin

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引用次数: 5

Abstract

Designing dynamically robust protocols is not a simple task with current classic work-conserving scheduling, where packets are sent out as soon as processing and transmission capacity is available. We show that deviating from this fundamental queuing assumption leads to much more controllable and analyzable forms of protocols. At the core of our work is a queue-scheduling discipline based on the chemical "Law of Mass Action" (LoMA) that serves a queue with a rate proportional to its fill level. In this paper we introduce our LoMA-scheduling approach and provide a solid mathematical framework adopted from chemistry that simplifies the analysis of the corresponding queueing networks, including the prediction of the underlying protocols' dynamics. We demonstrate the elegance of our model by implementing and analyzing a TCP-compatible "chemical" congestion control algorithm C3A with only a few interacting queues (another novelty of our approach). We also show the application of our theory to gossip protocols, explain an effective implementation of the scheduler and discuss possibilities of how to integrate mass-action scheduling into traditional networking environments.

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基于质量-动作调度定律的分组流理论

设计动态健壮的协议并不是一项简单的任务，当前经典的节省工作的调度，在这种调度中，只要处理和传输能力可用，数据包就会发送出去。我们表明，偏离这个基本的排队假设会导致更可控和可分析的协议形式。我们工作的核心是基于化学“质量作用定律”(LoMA)的队列调度学科，该学科以与其填充水平成比例的速率为队列提供服务。在本文中，我们介绍了我们的loma调度方法，并提供了一个来自化学的坚实数学框架，简化了相应队列网络的分析，包括对底层协议动态的预测。我们通过实现和分析一个tcp兼容的“化学”拥塞控制算法C3A来展示我们模型的优雅之处，该算法只有几个交互队列(我们方法的另一个新颖之处)。我们还展示了我们的理论在八卦协议中的应用，解释了调度程序的有效实现，并讨论了如何将大规模动作调度集成到传统网络环境中的可能性。

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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2012 IEEE 31st Symposium on Reliable Distributed Systems

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