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/rfc1093.txt | 507 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 507 insertions(+) create mode 100644 doc/rfc/rfc1093.txt (limited to 'doc/rfc/rfc1093.txt') diff --git a/doc/rfc/rfc1093.txt b/doc/rfc/rfc1093.txt new file mode 100644 index 0000000..42fa423 --- /dev/null +++ b/doc/rfc/rfc1093.txt @@ -0,0 +1,507 @@ + + + + + + +Network Working Group H.W. Braun +Request for Comments: 1093 Merit + February 1989 + + + The NSFNET Routing Architecture + +Status of this Memo + + This document describes the routing architecture for the NSFNET + centered around the new NSFNET Backbone, with specific emphasis on + the interface between the backbone and its attached networks. + Distribution of this memo is unlimited. + +Introduction + + This document describes the routing architecture for the NSFNET + centered around the new NSFNET Backbone, with specific emphasis on + the interface between the backbone and its attached networks. It + reflects and augments thoughts described in [1], discussions during + the Internet Engineering Task Force meeting at the San Diego + Supercomputing Center in March 1988, discussions on mailing lists, + especially on a backbone/regional network working group mailing list, + and a final discussion held at the IBM T.J. Watson Research Center in + Yorktown, NY, on the 21st of March 1988. The Yorktown meeting was + attended by Hans-Werner Braun (Merit), Scott Brim (Cornell + University), Mark Fedor (NYSERNet), Jeff Honig (Cornell University), + and Jacob Rekhter (IBM). Thanks also to: Milo Medin (NASA), John Moy + (Proteon) and Greg Satz (Cisco) for discussing this document by email + and/or phone. + + Understanding of [1] is highly recommended prior to reading this + document. + +1. Routing Overview + + The new NSFNET backbone forms the core of the overall NSFNET, which + connects to regional networks (or regional backbones) as well as to + peer networks (other backbones like the NASA Science Network or the + ARPANET). The NSFNET core uses a SPF based internal routing + protocol, adapted from the IS-IS protocol submitted by ANSI for + standardization to the ISO. The ANSI IS-IS protocol is based upon + work done at Digital Equipment Corporation. Its adaptation to the + Internet environment requires additional definitions, most notably to + the addressing structure, which will be described in a later + document. This adaptation was largely done by Jacob Rekhter of IBM + Research in Yorktown, NY. The RCP/PSP routing architecture was + largely implemented by Rick Boivie and his colleagues at IBM TCS in + + + +Braun [Page 1] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + Milford, CT. The adaptation of EGP to the NSS routing code and the + new requirements was done jointly by Jeff Honig (who spent about a + week to work on this at IBM Research) and Jacob Rekhter. Jeff is + integrating the changes done for the new EGP requirements into the + "gated" distributions. + + The IGP derives routing tables from Internet address information. + This information is flooded throughout the NSFNET core, and the + individual NSS nodes create or update their routing information after + running the SPF algorithm over the flooded information. A detailed + description of the NSFNET backbone IGP will be documented in a future + document. + + The routing interface between the NSFNET core and regional backbones + as well as peer networks utilizes the Exterior Gateway Protocol + (EGP). The EGP/IGP consistency and integrity at the interface points + is ensured by filtering mechanisms according to individual nodal + routing policy data bases [1]. EGP is selected as the routing + interface of choice between the NSFNET backbone and its regional + attachments due to its widespread implementation as well its ability + to utilize autonomous system designators and to allow for effective + firewalls between systems. In the longer run the hope is to replace + the EGP interface with a new inter Autonomous System protocol. Such a + new protocol should also allow to move the filtering of network + numbers or Autonomous Network number groups to the regional gateways + in order for the regional gateways to decide as to what routing + information they wish to receive. + + A general model is to ensure consistent routing information between + peer networks. This means that, e.g., the NSFNET core will have the + same sets of Internet network numbers in its routing tables as are + present in the ARPANET core. However, the redistribution of this + routing information is tightly controlled and based on Autonomous + System numbers. For example, ARPANET routes with the ARPANET + Autonomous System number will not be redistributed into regional or + other peer networks. If an NSFNET internal path exists to such a + network known to the ARPANET it may be redistributed into regional + networks, subject to further policy verification. Generally it may be + necessary to have different trust models for peer and subordinate + networks, while giving a greater level of trust to peer networks. + + The described use of EGP, which is further elaborated on in [1] + requires bidirectional translation of network information between the + IGP in use and EGP. + +2. Conclusions reached during the discussions + + The following conclusions were reached during the meeting and in + + + +Braun [Page 2] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + subsequent discussions: + + No DDN-only routes (ARPANET/MILNET) shall be announced into the + regional backbones. This is a specific case of the ability to + suppress information from specific Autonomous Systems, as + described later. + + Regional backbones are required to use an unique Autonomous System + number. Announcements from non-sanctioned autonomous systems, + relative to a particular site, will not be believed and will + instead trigger an alarm to the Network Operations Center. + + Regional backbone attachments must not require routes to local + subnets. This means that the locally attached network needs to + use a flat space, without subnet bits, at least from the NSS point + of view. The reason for this is that the EGP information + exchanged between the regional gateway and the NSS cannot include + subnet information. Therefore the NSS has no knowledge of remote + subnets. The safest way to get around this limitation is to use a + non-subnetted network (like a separate Class-C network) at the + interface between a regional backbone and the NSFNET backbone. + The other way is to use Proxy-ARP while having just the NSS think + that the network is not subnetted. In the latter case care must be + taken so that the E-PSP uses the proper local IP broadcast + address. + + Routing information received by the NSS from regional gateways + will be verified on both network number and autonomous system + number. + + Metric reconstitution is done on a per-network basis. The NSS + will construct the fixed metric it will use for a given network + number from its internal data base. Network metrics given to the + NSS via EGP will be ignored. The metrics used are a result of an + ordered list of preferred paths as supplied by the regional + backbones and the attached campuses. This metric is of relevance + only to the NSFNET core itself. The mechanisms are further + explained in [1]. + + Global metric reconstitution by Autonomous System numbers is + necessary in specific cases, such as peer networks. An example is + that ARPANET routes will be reconstituted to a global metric, as + determined by the NSS. + + EGP announcements into regional networks will use a fixed metric. + The metric used shall be "128." The 128-metric is somewhat + arbitrarily chosen to be high enough so that a regional backbone + will get a metric high enough from the NSFNET Core AS to allow a + + + +Braun [Page 3] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + comparison against other (most likely internal) routes. "128" is + also consistent with [2]. + + Peer network routes (e.g., ARPANET routes) are propagated through + the NSS structure. + + No DEFAULT routing information is distributed within the NSFNET + backbone, as the NSFNET core has the combined routing knowledge of + the attached regional and peer networks. + + We do not expect the requirement for damping of routing update + frequencies, at least initially. The frequency of net up/down + changes combined with the available bandwidth and CPU capacity do + not let the frequency of SPF floodings appear as being a major + problem. Simple metric changes as heard by a NSS via EGP will not + trigger updates. + + An allowed list of Source Autonomous System information will be + used to convert from the IGP to EGP, on a Destination Autonomous + System number basis, to allow for specific exclusion of definable + remote Autonomous System information. + + EGP must only announce networks for which the preferred path is + via the IGP. This means in particular that the EGP peer will + never announce via EGP what it learned via EGP on the same + interface, not even if the information was received from a third + EGP peer. This will avoid the back-distribution of information + learned via that same interface. The EGP peers of regional + gateways must only announce information belonging to their own + Autonomous System. + + EGP will be used in interior mode only. + + The regional backbones are responsible for generating DEFAULT + routing information at their option. One possibility is to + generate an IGP default on a peer base as long as the NSS EGP + connection is working. The EGP information will not include a + special indication for DEFAULT. + + It is highly desirable to have direct peer-peer connections, to + ease the implementation of a consistent routing data base. + + A single Autonomous System number may not be used with two E-PSPs + at the same time as long as the two E-PSP's belong to the same + NSS. Otherwise the same Autonomous System number can be used from + multiple points of attachment to the backbone and therefore can + talk to more than one E-PSP. However, this may result in + suboptimal routing unless multiple announcements are properly + + + +Braun [Page 4] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + engineered according to [1]. + + The administrator of the regional networks should be warned that + improper routing implementations within the region may create + suboptimal regional routing by using this restriction if no care + is taken in that: + + Only networks belonging to their own Autonomous System get + preferred over NSFNET backbone paths; this may extend to a + larger virtual Autonomous System if backdoor paths are + effectively implemented. + + IGP implementations should not echo back routing information + heard via the same path. + + If two regional networks decide to implement a backdoor + connection between themselves, then the backdoor must have a + firewall in so that information about their own Autonomous + System cannot flow in from the other Autonomous System. That + is, a regional network must not allow information about + networks that are interior to its Autonomous System to enter + via exterior routes. Likewise, if a regional network is + connected to the NSFNET via two NSS connections, the NSS cannot + send back information about the Autonomous System into the + Autonomous System where it originated. The end effect is that + partitions within an Autonomous System will not be healed by + using the NSS system. In addition, if three or more regionals + connect to each other via multiple back-door paths, it is + imperative that all back-door paths have firewalls that ensure + that the above restrictions are imposed. These actions are + necessary to prevent routing loops that involve the NSS system. + Furthermore routing information should only be accepted from + another regional backbone via backdoor paths for networks which + are positively desired to be reached via this same backdoor + path. + +3. EGP requirements for attached gateways + + The following EGP requirements are necessary for attached gateways; + they may require changes in existing vendor products: + + IGP to EGP routing exchanges need to be bidirectional. This + feature should be selectable by the gateway administrator, and by + default be configured OFF. + + The metric used when translating from EGP to IGP should be + configurable. + + + + +Braun [Page 5] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + It must be possible for IGP information to override EGP + information, so that the internal paths are preferred over + external paths. Overriding EGP information on an absolute basis, + where an external path would never be used as long as there is an + internal one, is acceptable. + + The ability to do route filtering in the regional gateways on a + per net basis is highly desirable to allow the regional gateways + to do a further selection as to what routes they would want to + redistribute into their network. + + The existence of an EGP connection should optionally lead to the + generation of a DEFAULT announcement for propagation via the IGP. + The DEFAULT metric should be independently configurable. + + EGP routes with a metric of "128" should be acceptable. In most + cases the regional backbone should ignore the EGP metric. + + The regional gateways must only announce networks known to their + own Autonomous System. At the very least they must not + redistribute routing information via EGP for routes previously + learned via EGP. + + It would be beneficial if the regional IGPs would tag routes as + being EGP derived. + + If the EGP peer (e.g., a NSS) terminates the EGP exchange the + previously learned routes should expire in a timely fashion. + +4. References + + [1] Rekhter, J., "EGP and Policy Based Routing in the New NSFNET + Backbone", T.J. Watson Research Center, IBM Corporation, March + 1988. Also as RFC 1092, February 1989. + + [2] Mills, D., "Autonomous Confederations", RFC 975, M/A-COM + Linkabit, February 1986. + + [3] Mills, D., "Exterior Gateway Formal Specification", RFC 904, + M/A-COM Linkabit, April 1984. + + [4] "Exterior Gateway Protocol, Version 3, Revisions and Extensions," + Working Notes of the IETF WG on EGP, Marianne L. Gardner and + Mike Karels, February 1988. + + [5] "Management and Operation of the NSFNET Backbone Network," + proposal to the National Science Foundation, Merit Computer + Network, August 1987. + + + +Braun [Page 6] + +RFC 1093 NSFNET Routing Architecture February 1989 + + +5. Appendix + + The following are extensions implemented for the "gated" EGP + implementation, as designed by Jeff Honig of the Cornell University + Theory Center. These extensions are still in the design stage and + may be changed over time. They are included here as an + implementation example. + + Changes to egpneighbor clause: + + egpneighbor
metricin + egpmetricout + ASin + ASout + nogendefault + acceptdefault + defaultout + validate + + metricin + + If specified, the metric of all nets received from this + neighbor are set to . + + egpmetricout + + If specified, the metric of all nets sent to this neighbor, + except default, are set to . + + ASin + + If specified, EGP packets received from this neighbor must + specify this AS number of an EGP error packet is generated. + The AS number is only checked at neighbor acquisition time. + + ASout + + If specified, this AS number is used on all EGP packets sent + to thiqs neighbor + + nogendefault + + If specified, this neighbor is not considered when + generating a gateway default. + + acceptdefault + + If specified, the default will be accepted from this + + + +Braun [Page 7] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + neighbor, otherwise it will be explicitly ignored. + + defaultout + + If specified, the internally generated default is send to + this neighbor in EGP updates. Default learned from other + gateways is not propogated. + + validate + + If specifed, all nets learned from this EGP neighbor must + have a corresponding 'validAS' clause or they will be + ignored. + + Addition of a validAS clause: + + validAS AS metric + + This clause specifies which AS a network may be learned from and + what internal metric to use when the net is learned. The + specifies the 'validate' option. Note that more than one may be + learned from more than one AS. + + Addition of sendAS and donotsendAS clauses: + + These clauses control the announcement of exterior (currently only + EGP) routes. Normally, exterior routes are not considered for + announcement. When the 'sendAS' or 'donotsendAS' clauses are + used, the announce/donotannounce, egpnetsreachable and other + restrictions still apply. The 'sendAS' and 'donotsendAS' clauses + are mutually exclusive by autonomous system. + + sendAS ASlist ... + + This clause specifies that only nets learned from as1, as2, ... + may be propogated to as0. + + donotsendAS ASlist ... + + This clause specifies that nets learned from as1, as2, ... may + not be propogated to , all other nets are propogated. + + An example of a "/etc/gated.conf" file could include the following: + + # + RIP supplier + # + autonomousystem (regional AS) + + + +Braun [Page 8] + +RFC 1093 NSFNET Routing Architecture February 1989 + + + # + egpneighbor (NSS address) ASin (NSS AS) nogendefault + metricin (metric) + # + sendAS (NSS AS) ASlist (regional AS) + # + + Where: + + Regional AS Is the AS number of the regional network + NSS address Is the IP address of the local NSS + NSS AS Is the AS number the NSFNET backbone + Metric Is the gated internal (time delay) metric that + EGP learned routes should have. This is the + metric used on output after conversion to a RIP + metric. Some values are: + + HELLO RIP + 100 1 + 148 2 + 219 3 + 325 4 + 481 5 + +Author's Address: + + Hans-Werner Braun + University of Michigan + Computing Center + 1075 Beal Avenue + Ann Arbor, MI 48109 + + Phone: (313) 763-4897 + + Email: HWB@MCR.UMICH.EDU + + + + + + + + + + + + + + + + +Braun [Page 9] + \ No newline at end of file -- cgit v1.2.3