Dynamic quarantine of Internet worms

International Conference on Dependable Systems and Networks, 2004 Pub Date : 2004-06-28 DOI:10.1109/DSN.2004.1311878

Cynthia Wong, Chenxi Wang, D. Song, Stan Bielski, G. Ganger

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引用次数: 78

Abstract

If we limit the contact rate of worm traffic, can we alleviate and ultimately contain Internet worms? This paper sets out to answer this question. Specifically, we are interested in analyzing different deployment strategies of rate control mechanisms and the effect thereof on suppressing the spread of worm code. We use both analytical models and simulation experiments. We find that rate control at individual hosts or edge routers yields a slowdown that is linear in the number of hosts (or routers) with the rate limiting filters. Limiting contact rate at the backbone routers, however, is substantially more effective-it renders a slowdown comparable to deploying rate limiting filters at every individual host that is covered. This result holds true even when susceptible and infected hosts are patched and immunized dynamically. To provide context for our analysis, we examine real traffic traces obtained from a campus computing network. We observe that rate throttling could be enforced with minimal impact on legitimate communications. Two worms observed in the traces, however, would be significantly slowed down.

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互联网蠕虫的动态隔离

如果我们限制蠕虫流量的接触率，我们能减轻并最终遏制互联网蠕虫吗?本文试图回答这个问题。具体来说，我们感兴趣的是分析速率控制机制的不同部署策略及其对抑制蠕虫代码传播的影响。我们使用了分析模型和模拟实验。我们发现，在单个主机或边缘路由器上的速率控制产生的减速与速率限制过滤器的主机(或路由器)数量呈线性关系。然而，在骨干路由器上限制接触速率实际上更有效——它带来的减速与在覆盖的每个单独的主机上部署速率限制过滤器相当。即使在易感和受感染的宿主被动态修补和免疫时，这一结果也成立。为了为我们的分析提供背景，我们检查了从校园计算网络获得的真实流量轨迹。我们观察到，费率限制可以在对合法通信影响最小的情况下实施。然而，在痕迹中观察到的两种蠕虫的速度会明显减慢。

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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International Conference on Dependable Systems and Networks, 2004

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