From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc2333.txt | 507 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 507 insertions(+) create mode 100644 doc/rfc/rfc2333.txt (limited to 'doc/rfc/rfc2333.txt') diff --git a/doc/rfc/rfc2333.txt b/doc/rfc/rfc2333.txt new file mode 100644 index 0000000..252ab29 --- /dev/null +++ b/doc/rfc/rfc2333.txt @@ -0,0 +1,507 @@ + + + + + + +Network Working Group D. Cansever +Request for Comments: 2333 GTE Laboratories, Inc. +Category: Standards Track April 1998 + + + NHRP Protocol Applicability Statement + +Status of this Memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (1998). All Rights Reserved. + +Abstract + + As required by the Routing Protocol Criteria [RFC 1264], this memo + discusses the applicability of the Next Hop Resolution Protocol + (NHRP) in routing of IP datagrams over Non-Broadcast Multiple Access + (NBMA) networks, such as ATM, SMDS and X.25. + +1. Protocol Documents + + The NHRP protocol description is defined in [1]. The NHRP MIB + description is defined in [2]. + +2. Introduction + + This document summarizes the key features of NHRP and discusses the + environments for which the protocol is well suited. For the purposes + of description, NHRP can be considered a generalization of Classical + IP and ARP over ATM which is defined in [3] and of the Transmission + of IP Datagrams over the SMDS Service, defined in [4]. This + generalization occurs in 2 distinct directions. + + Firstly, NHRP avoids the need to go through extra hops of routers + when the Source and Destination belong to different Logical Internet + Subnets (LIS). Of course, [3] and [4] specify that when the source + and destination belong to different LISs, the source station must + forward data packets to a router that is a member of multiple LISs, + even though the source and destination stations may be on the same + logical NBMA network. If the source and destination stations belong + to the same logical NBMA network, NHRP provides the source station + + + +Cansever Standards Track [Page 1] + +RFC 2333 NHRP Protocol Applicability April 1998 + + + with an inter-LIS address resolution mechanism at the end of which + both stations can exchange packets without having to use the services + of intermediate routers. This feature is also referred to as + "short-cut" routing. If the destination station is not part of the + logical NBMA network, NHRP provides the source with the NBMA address + of the current egress router towards the destination. + + The second generalization is that NHRP is not specific to a + particular NBMA technology. Of course, [3] assumes an ATM network + and [4] assumes an SMDS network at their respective subnetwork + layers. + + NHRP is specified for resolving the destination NBMA addresses of IP + datagrams over IP subnets within a large NBMA cloud. NHRP has been + designed to be extensible to network layer protocols other than IP, + possibly subject to other network layer protocol specific additions. + + As an important application of NHRP, the Multiprotocol Over ATM + (MPOA) Working Group of the ATM Forum has decided to adopt and to + integrate NHRP into its MPOA Protocol specification [5]. As such, + NHRP will be used in resolving the ATM addresses of MPOA packets + destined outside the originating subnet. + +3. Key Features + + NHRP provides a mechanism to obtain the NBMA network address of the + destination, or of a router along the path to the destination. NHRP + is not a routing protocol, but may make use of routing information. + This is further discussed in Section 5. + + The most prominent feature of NHRP is that it avoids extra router + hops in an NBMA with multiple LISs. To this goal, NHRP provides the + source with the NBMA address of the destination, if the destination + is directly attached to the NBMA. If the destination station is not + attached to the NBMA, then NHRP provides the source with the NBMA + address of an exit router that has connectivity to the destination. + In general, there may be multiple exit routers that have connectivity + to the destination. If NHRP uses the services of a dynamic routing + algorithm in fulfilling its function, which is necessary for robust + and scalable operation, then the exit router identified by NHRP + reflects the selection made by the network layer dynamic routing + protocol. In general, the selection made by the routing protocol + would often reflect a desirable attribute, such as identifying the + exit router that induces the least number of hops in the original + routed path. + + + + + + +Cansever Standards Track [Page 2] + +RFC 2333 NHRP Protocol Applicability April 1998 + + + NHRP is defined for avoiding extra hops in the delivery of IP packets + with a single destination. As such, it is not intended for direct + use in a point-to-multipoint communication setting. However, + elements of NHRP may be used in certain multicast scenarios for the + purpose of providing short cut routing. Such an effort is discussed + in [6]. In this case, NHRP would avoid intermediate routers in the + multicast path. The scalability of providing short-cut paths in a + multicast environment is an open issue. + + NHRP can be used in host-host, host-router and router-host + communications. When used in router-router communication, NHRP (as + defined in [1]) can produce persistent routing loops if the + underlying routing protocol looses information critical to loop + suppression. This may occur when there is a change in router metrics + across the autonomous system boundaries. NHRP for router-router + communication that avoids persistent forwarding loops will be + addressed in a separate document. + + A special case of router-router communication where loops will not + occur is when the destination host is directly adjacent to the non- + NBMA interface of the egress router. If it is believed that the + adjacency of the destination station to the egress router is a stable + topological configuration, then NHRP can safely be used in this + router-router communication scenario. If the NHRP Request has the Q + bit set, indicating that the requesting party is a router, and if the + destination station is directly adjacent to the egress router as a + stable topological configuration, then the egress router can issue a + corresponding NHRP reply. If the destination is not adjacent to the + egress router, and if Q bit is set in the Request, then a safe mode + of operation for the egress router would be to issue a negative NHRP + Reply (NAK) for this particular request, thereby enforce data packets + to follow the routed path. + + As a result of having inter-LIS address resolution capability, NHRP + allows the communicating parties to exchange packets by fully + utilizing the particular features of the NBMA network. One such + example is the use of QoS guarantees when the NMBA network is ATM. + + Here, due to short-cut routing, ATM provided QoS guarantees can be + implemented without having to deal with the issues of re-assembling + and re-segmenting IP packets at each network layer hop. + + NHRP protocol can be viewed as a client-server interaction. An NHRP + Client is the one who issues an NHRP Request. An NHRP Server is the + one who issues a reply to an NHRP request, or the one who forwards a + received NHRP request to another Server. Of course, an NHRP entity + may act both as a Client and a Server. + + + + +Cansever Standards Track [Page 3] + +RFC 2333 NHRP Protocol Applicability April 1998 + + +4. Use of NHRP + + In general, issuing an NHRP request is an application dependent + action [7]. For applications that do not have particular QoS + requirements, and that are executed within a short period of time, an + NBMA short-cut may not be a necessity. In situations where there is a + "cost" associated with NBMA short-cuts, such applications may be + better served by network layer hop-by-hop routing. Here, "cost" may + be understood in a monetary context, or as additional strain on the + equipment that implements short-cuts. Therefore, there is a trade-off + between the "cost" of a short-cut path and its utility to the user. + Reference [7] proposes that this trade-off should be addressed at the + application level. In an environment consisting of LANs and routers + that are interconnected via dedicated links, the basic routing + decision is whether to forward a packet to a router, or to broadcast + it locally. Such a decision on local vs. remote is based on the + destination address. When routing IP packets over an NBMA network, + where there is potentially a direct Source to Destination + connectivity with QoS options, the decision on local vs. remote is no + longer as fundamentally important as in the case where packets have + to traverse routers that are interconnected via dedicated links. + Thus, in an NBMA network with QoS options, the basic decision becomes + the one of short-cut vs. hop-by-hop network layer routing. In this + case, the relevant criterion becomes applications' QoS requirements + [7]. NHRP is particularly applicable for environments where the + decision on local vs. remote is superseded by the decision on short- + cut vs. hop-by-hop network layer routing. + + Let us assume that the trade-off is in favor of a short-cut NBMA + route. Generally, an NHRP request can be issued by a variety of NHRP + aware entities, including hosts and routers with NBMA interfaces. If + an IP packet traverses multiple hops before a short-cut path has been + established, then there is a chance that multiple short-cut paths + could be formed. In order to avoid such an undesirable situation, a + useful operation rule is to authorize only the following entities to + issue an NHRP request and to perform short-cut routing. + + i) The host that originates the IP packet, if the host has an NBMA + interface. + ii) The first router along the routing path of the IP packet such + that the next hop is reachable through the NBMA interface of + that particular router. + iii) A policy router within an NBMA network through which the IP + packet has to traverse. + + + + + + + +Cansever Standards Track [Page 4] + +RFC 2333 NHRP Protocol Applicability April 1998 + + +5. Protocol Scalability + + As previously indicated, NHRP is defined for the delivery of IP + packets with a single destination. Thus, this discussion is confined + to a unicast setting. The scalability of NHRP can be analyzed at + three distinct levels: + + o Client level + o LIS level + o Domain level + + At the the Client level, the scalability of NHRP is affected by the + processing and memory limitations of the NIC that provides interface + to the NBMA network. When the NBMA network is connection oriented, + such as ATM, NIC limitations may bound the scalability of NHRP in + certain applications. For example, a server that handles hundreds of + requests per second using an ATM interface may be bounded by the + performance characteristics of the corresponding NIC. Similarly, + when the NHRP Client resides at an NBMA interface of a router, memory + and processing limitations of router's NIC may bound the scalability + of NHRP. This is because routers generally deal with an aggregation + of traffic from multiple sources, which in turn creates a potentially + large number of SVCCs out of the router's NBMA interface. + + At the LIS level, the main issue is to maintain and deliver a sizable + number of NBMA to Network layer address mappings within large LISs. + To this goal, NHRP implementations can use the services of the Server + Cache Synchronization Protocol (SCSP) [8] that allows multiple + synchronized NHSs within an LIS, and hence resolve the associated + scalability issue. + + At the NHRP Domain level, network layer routing is used in resolving + the NBMA address of a destination outside the LIS. As such, the + scalability of NHRP is closely tied to the scalability of the network + layer routing protocol used by NHRP. Dynamic network layer routing + protocols are proven to scale well. Thus, when used in conjunction + with dynamic routing algorithms, at the NHRP domain level, NHRP + should scale in the same order as the routing algorithm, subject to + the assumption that all the routers along the path are NHRP aware. + If an NHRP Request is processed by a router that does not implement + NHRP, it will be silently discarded. Then, short-cuts cannot be + implemented and connectivity will be provided on a hop-by-hop basis. + + Thus, when NHRP is implemented in conjunction with dynamic network + layer routing, a scaling requirement for NHRP is that virtually all + the routers within a logical NBMA network should be NHRP aware. + + + + + +Cansever Standards Track [Page 5] + +RFC 2333 NHRP Protocol Applicability April 1998 + + + One can also use static routing in conjunction with NHRP. Then, not + all the routers in the NBMA network need to be NHRP aware. That is, + since the routers that need to process NHRP control messages are + specified by static routing, routers that are not included in the + manually defined static paths do not have to be NHRP aware. Of + course, static routing does not scale, and if the destination is off + the NBMA network, then the use of static routing could result in + persistently suboptimal routes. Use of static routing also has + fairly negative failure modes. + +6. Discussion + + NHRP does not replace existing routing protocols. In general, routing + protocols are used to determine the proper path from a source host or + router, or intermediate router, to a particular destination. If the + routing protocol indicates that the proper path is via an interface + to an NBMA network, then NHRP may be used at the NBMA interface to + resolve the destination IP address into the corresponding NBMA + address. Of course, the use of NHRP is subject to considerations + discussed in Section 4. + + Assuming that NHRP is applicable and the destination address has been + resolved, packets are forwarded using the particular data forwarding + and path determination mechanisms of the underlying NBMA network. + Here, the sequence of events are such that route determination is + performed by IP routing, independent of NHRP. Then, NHRP is used to + create a short-cut track upon the path determined by the IP routing + protocol. Therefore, NHRP "shortens" the routed path. NHRP (as + defined in [1]) is not sufficient to suppress persistent forwarding + loops when used for router-router communication if the underlying + routing protocol looses information critical to loop suppression [9]. + Work is in progress [10] to augment NHRP to enable its use for the + router-router communication without persistent forwarding loops. + + When the routed path keeps changing on some relatively short time + scale, such as seconds, this situation will have an effect on the + operation of NHRP. In certain router-router operations, changes in + the routed path could create persistent routing loops. In host- + router, or router-host communications, frequent changes in routed + paths could result in inefficiencies such as frequent creation of + short-cut paths which are short lived. + +7. Security Considerations + + NHRP is an address resolution protocol, and SCSP is a database + synchronization protocol. As such, they are possibly subject to + server (for NHRP) or peer (for SCSP) spoofing and denial of service + attacks. They both provide authentication mechanisms to allow their + + + +Cansever Standards Track [Page 6] + +RFC 2333 NHRP Protocol Applicability April 1998 + + + use in environments in which spoofing is a concern. Details can be + found in sections 5.3.4 in [1] and B.3.1 in [8]. There are no + additional security constraints or concerns raised in this document + that are not already discussed in the referenced sections. + +References + + [1] Luciani, J., Katz, D., Piscitello, D., Cole, B., and + N. Doraswamy, "NMBA Next Hop Resolution Protocol (NHRP)", RFC + 2332, April 1998. + + [2] Greene, M., and J. Luciani, "NHRP Management Information Base", + Work in Progress. + + + [3] Laubach, M., and J. Halpern, "Classical IP and ARP over ATM", RFC + 2225, April 1998. + + [4] Lawrance, J., and D. Piscitello, "The Transmission of IP + datagrams over the SMDS service", RFC 1209, March 1991. + + [5] Multiprotocol Over ATM Version 1.0, ATM Forum Document + af-mpoa-0087.000 + + [6] Rekhter, Y., and D. Farinacci, "Support for Sparse Mode PIM over + ATM", Work in Progress. + + [7] Rekhter, Y., and D. Kandlur, "Local/Remote" Forwarding Decision + in Switched Data Link Subnetworks", RFC 1937, May 1996. + + [8] Luciani, J., Armitage, G., Halpern, J., and N. Doraswamy, "Server + Cache Synchronization Protocol (SCSP) - NBMA", RFC 2334, April + 1998. + + [9] Cole, R., Shur, D., and C. Villamizar, "IP over ATM: A Framework + Document", RFC 1932, April 1996. + + [10] Rekhter, Y., "NHRP for Destinations off the NBMA Subnetwork", + Work in Progress. + +Acknowledgements + + The author acknowledges valuable contributions and comments from many + participants of the ION Working Group, in particular from Joel + Halpern of Newbridge Networks, David Horton of Centre for Information + Technology Research, Andy Malis of Nexion, Yakov Rekhter and George + Swallow of Cisco Systems and Curtis Villamizar of ANS. + + + + +Cansever Standards Track [Page 7] + +RFC 2333 NHRP Protocol Applicability April 1998 + + +Author's Address + + Derya H. Cansever + GTE Laboratories Inc. + 40 Sylvan Rd. MS 51 + Waltham MA 02254 + + Phone: +1 617 466 4086 + EMail: dcansever@gte.com + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Cansever Standards Track [Page 8] + +RFC 2333 NHRP Protocol Applicability April 1998 + + +Full Copyright Statement + + Copyright (C) The Internet Society (1998). All Rights Reserved. + + This document and translations of it may be copied and furnished to + others, and derivative works that comment on or otherwise explain it + or assist in its implementation may be prepared, copied, published + and distributed, in whole or in part, without restriction of any + kind, provided that the above copyright notice and this paragraph are + included on all such copies and derivative works. However, this + document itself may not be modified in any way, such as by removing + the copyright notice or references to the Internet Society or other + Internet organizations, except as needed for the purpose of + developing Internet standards in which case the procedures for + copyrights defined in the Internet Standards process must be + followed, or as required to translate it into languages other than + English. + + The limited permissions granted above are perpetual and will not be + revoked by the Internet Society or its successors or assigns. + + This document and the information contained herein is provided on an + "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING + TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING + BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION + HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF + MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + + + + + + + + + + + + + + + + + + + + + + + + +Cansever Standards Track [Page 9] + -- cgit v1.2.3