LakshminarayananKarthik scite author profile

Ternary content-addressable memories (TCAMs) have gained wide acceptance in the industry for storing and searching Access Control Lists (ACLs). In this paper, we propose algorithms for addressing two important problems that are encountered while using TCAMs: reducing range expansion and multi-match classification .Our first algorithm addresses the problem of expansion of rules with range fields to represent range rules in TCAMs, a single range rule is mapped to multiple TCAM entries, which reduces the utilization of TCAMs. We propose a new scheme called Database Independent Range PreEncoding (DIRPE) that, in comparison to earlier approaches, reduces the worst-case number of TCAM entries a single rule maps on to. DIRPE works without prior knowledge of the database, scales when a large number of ranges is present, and has good incremental update properties.Our second algorithm addresses the problem of finding multiple matches in a TCAM. When searched, TCAMs return the first matching entry; however, new applications require either the first few or all matching entries. We describe a novel algorithm, called Multi-match Using Discriminators (MUD), that finds multiple matches without storing any per-search state information in the TCAM, thus making it suitable for multi-threaded environments. MUD does not increase the number of TCAM entries needed, and hence scales to large databases.Our algorithms do not require any modifications to existing TCAMs and are hence relatively easy to deploy. We evaluate the algorithms using real-life and random databases.

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Achieving convergence-free routing using failure-carrying packets

LakshminarayananKarthik¹,

CaesarMatthew²,

RanganMurali³

et al. 2007

SIGCOMM Comput. Commun. Rev.

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Current distributed routing paradigms (such as link-state, distancevector, and path-vector) involve a convergence process consisting of an iterative exploration of intermediate routes triggered by certain events such as link failures. The convergence process increases router load, introduces outages and transient loops, and slows reaction to failures. We propose a new routing paradigm where the goal is not to reduce the convergence times but rather to eliminate the convergence process completely. To this end, we propose a technique called Failure-Carrying Packets (FCP) that allows data packets to autonomously discover a working path without requiring completely up-to-date state in routers. Our simulations, performed using real-world failure traces and Rocketfuel topologies, show that: (a) the overhead of FCP is very low, (b) unlike traditional link-state routing (such as OSPF), FCP can provide both low lossrate as well as low control overhead, (c) compared to prior work in backup path precomputations, FCP provides better routing guarantees under failures despite maintaining lesser state at the routers.

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A layered naming architecture for the internet

BalakrishnanHari

LakshminarayananKarthik

RatnasamySylvia

et al. 2004

SIGCOMM Comput. Commun. Rev.

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Currently the Internet has only one level of name resolution, DNS, which converts user-level domain names into IP addresses. In this paper we borrow liberally from the literature to argue that there should be three levels of name resolution: from user-level descriptors to service identifiers; from service identifiers to endpoint identifiers; and from endpoint identifiers to IP addresses. These additional levels of naming and resolution (1) allow services and data to be first class Internet objects (in that they can be directly and persistently named), (2) seamlessly accommodate mobility and multi-homing and (3) integrate middleboxes (such as NATs and firewalls) into the Internet architecture. We further argue that flat names are a natural choice for the service and endpoint identifiers. Hence, this architecture requires scalable resolution of flat names, a capability that distributed hash tables (DHTs) can provide.

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