分组网络中的源路由和调度

Proceedings 2001 IEEE International Conference on Cluster Computing Pub Date : 2001-10-14 DOI:10.1109/SFCS.2001.959891

M. Andrews, Antonio Fernández, Ashish Goel, Lisa Zhang

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引用次数: 36

摘要

研究分组交换网络中的路由和调度问题。我们假设有一个对手控制每个注入的数据包的注入时间、源和目的地。如果网络中没有链路过载，这些数据包的一组路径是允许的。我们提出了第一个在线路由算法，它在可行的情况下找到一组可接受的路径。我们的算法使用简单的最短路径计算，一旦每个数据包被注入到其源处，就为其计算一条路径。链路的长度反映了当前的拥塞情况。我们还展示了如何在当今的互联网路由范式下实现我们的算法。当路径已知(由对手给出或如上所述计算)时，我们的目标是沿着给定的路径调度数据包，以便数据包经历较小的端到端延迟。确定性调度协议和分布式调度协议的最佳先验延迟界与路径长度呈指数关系。在本文中，我们提出了第一个确定性和分布式调度协议，它保证了每个数据包的多项式端到端延迟。最后，讨论了路由与调度相结合的效果。我们首先证明，无论如何选择路径，一些不稳定的调度协议仍然不稳定。然而，选择道路的自由可以带来不同。例如，我们证明，如果智能地选择路径，具有并行链路的环对于所有贪婪调度协议都是稳定的，而如果对手指定路径，则不是这种情况。

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Source routing and scheduling in packet networks

We study routing and scheduling in packet-switched networks. We assume an adversary that controls the injection time, source, and destination for each packet injected. A set of paths for these packets is admissible if no link in the network is overloaded. We present the first on-line routing algorithm that finds a set of admissible paths whenever this is feasible. Our algorithm calculates a path for each packet as soon as it is injected at its source using a simple shortest path computation. The length of a link reflects its current congestion. We also show how our algorithm can be implemented under today's Internet routing paradigms. When the paths are known (either given by the adversary or computed as above) our goal is to schedule the packets along the given paths so that the packets experience small end-to-end delays. The best previous delay bounds for deterministic and distributed scheduling protocols were exponential in the path length. In this paper we present the first deterministic and distributed scheduling protocol that guarantees a polynomial end-to-end delay for every packet. Finally, we discuss the effects of combining routing with scheduling. We first show that some, unstable scheduling protocols remain unstable no matter how the paths are chosen. However, the freedom to choose paths can make a difference. For example, we show that a ring with parallel links is stable for all greedy scheduling protocols if paths are chosen intelligently, whereas this is not the case if the adversary specifies the paths.

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Proceedings 2001 IEEE International Conference on Cluster Computing

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