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/rfc7311.txt | 843 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 843 insertions(+) create mode 100644 doc/rfc/rfc7311.txt (limited to 'doc/rfc/rfc7311.txt') diff --git a/doc/rfc/rfc7311.txt b/doc/rfc/rfc7311.txt new file mode 100644 index 0000000..a6b064e --- /dev/null +++ b/doc/rfc/rfc7311.txt @@ -0,0 +1,843 @@ + + + + + + +Internet Engineering Task Force (IETF) P. Mohapatra +Request for Comments: 7311 Sproute Networks +Category: Standards Track R. Fernando +ISSN: 2070-1721 E. Rosen + Cisco Systems, Inc. + J. Uttaro + AT&T + August 2014 + + + The Accumulated IGP Metric Attribute for BGP + +Abstract + + Routing protocols that have been designed to run within a single + administrative domain (IGPs) generally do so by assigning a metric to + each link and then choosing, as the installed path between two nodes, + the path for which the total distance (sum of the metric of each link + along the path) is minimized. BGP, designed to provide routing over + a large number of independent administrative domains (autonomous + systems), does not make its path-selection decisions through the use + of a metric. It is generally recognized that any attempt to do so + would incur significant scalability problems as well as inter- + administration coordination problems. However, there are deployments + in which a single administration runs several contiguous BGP + networks. In such cases, it can be desirable, within that single + administrative domain, for BGP to select paths based on a metric, + just as an IGP would do. The purpose of this document is to provide + a specification for doing so. + +Status of This Memo + + This is an Internet Standards Track document. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Further information on + Internet Standards is available in Section 2 of RFC 5741. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + http://www.rfc-editor.org/info/rfc7311. + + + + + + + + +Mohapatra, et al. Standards Track [Page 1] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + +Copyright Notice + + Copyright (c) 2014 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (http://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. Code Components extracted from this document must + include Simplified BSD License text as described in Section 4.e of + the Trust Legal Provisions and are provided without warranty as + described in the Simplified BSD License. + +Table of Contents + + 1. Introduction ....................................................3 + 2. Specification of Requirements ...................................4 + 3. AIGP Attribute ..................................................4 + 3.1. Applicability Restrictions and Cautions ....................6 + 3.2. Handling a Malformed AIGP Attribute ........................6 + 3.3. Restrictions on Sending/Receiving ..........................6 + 3.4. Creating and Modifying the AIGP Attribute ..................7 + 3.4.1. Originating the AIGP Attribute ......................7 + 3.4.2. Modifications by the Originator .....................8 + 3.4.3. Modifications by a Non-Originator ...................8 + 4. Decision Process ...............................................10 + 4.1. When a Route Has an AIGP Attribute ........................11 + 4.2. When the Route to the Next Hop Has an AIGP Attribute ......11 + 5. Deployment Considerations ......................................12 + 6. IANA Considerations ............................................13 + 7. Security Considerations ........................................13 + 8. Acknowledgments ................................................13 + 9. References .....................................................14 + 9.1. Normative Reference .......................................14 + 9.2. Informative References ....................................14 + + + + + + + + + + + + + + +Mohapatra, et al. Standards Track [Page 2] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + +1. Introduction + + There are many routing protocols that have been designed to run + within a single administrative domain. These are known collectively + as "Interior Gateway Protocols" (IGPs). Typically, each link is + assigned a particular "metric" value. The path between two nodes can + then be assigned a "distance", which is the sum of the metrics of all + the links that belong to that path. An IGP selects the "shortest" + (minimal distance) path between any two nodes, perhaps subject to the + constraint that if the IGP provides multiple "areas", it may prefer + the shortest path within an area to a path that traverses more than + one area. Typically, the administration of the network has some + routing policy that can be approximated by selecting shortest paths + in this way. + + BGP, as distinguished from the IGPs, was designed to run over an + arbitrarily large number of administrative domains ("autonomous + systems" or "ASes") with limited coordination among the various + administrations. BGP does not make its path-selection decisions + based on a metric; there is no such thing as an "inter-AS metric". + There are two fundamental reasons for this: + + - The distance between two nodes in a common administrative domain + may change at any time due to events occurring in that domain. + These changes are not propagated around the Internet unless they + actually cause the border routers of the domain to select routes + with different BGP attributes for some set of address prefixes. + This accords with a fundamental principle of scaling, viz., that + changes with only local significance must not have global effects. + If local changes in distance were always propagated around the + Internet, this principle would be violated. + + - A basic principle of inter-domain routing is that the different + administrative domains may have their own policies, which do not + have to be revealed to other domains and which certainly do not + have to be agreed to by other domains. Yet, the use of an inter- + AS metric in the Internet would have exactly these effects. + + There are, however, deployments in which a single administration runs + a network that has been sub-divided into multiple, contiguous ASes, + each running BGP. There are several reasons why a single + administrative domain may be broken into several ASes (which, in this + case, are not really autonomous.) It may be that the existing IGPs + do not scale well in the particular environment; it may be that a + more generalized topology is desired than could be obtained by use of + a single IGP domain; it may be that a more finely grained routing + policy is desired than can be supported by an IGP. In such + deployments, it can be useful to allow BGP to make its routing + + + +Mohapatra, et al. Standards Track [Page 3] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + decisions based on the IGP metric, so that BGP chooses the shortest + path between two nodes, even if the nodes are in two different ASes + within that same administrative domain. + + There are, in fact, some implementations that already do something + like this, using BGP's MULTI_EXIT_DISC (MED) attribute to carry a + value based on IGP metrics. However, that doesn't really provide + IGP-like shortest path routing, as the BGP decision process gives + priority to other factors, such as the AS_PATH length. Also, the + standard procedures for use of the MED do not ensure that the IGP + metric is properly accumulated so that it covers all the links along + the path. + + In this document, we define a new optional, non-transitive BGP + attribute, called the "Accumulated IGP Metric Attribute", or "AIGP + attribute", and specify the procedures for using it. + + The specified procedures prevent the AIGP attribute from "leaking + out" past an administrative domain boundary into the Internet. We + will refer to the set of ASes in a common administrative domain as an + "AIGP administrative domain". + + The specified procedures also ensure that the value in the AIGP + attribute has been accumulated all along the path from the + destination, i.e., that the AIGP attribute does not appear when there + are "gaps" along the path where the IGP metric is unknown. + +2. Specification of Requirements + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this + document are to be interpreted as described in [RFC2119]. + +3. AIGP Attribute + + The AIGP attribute is an optional, non-transitive BGP path attribute. + The attribute type code for the AIGP attribute is 26. + + The value field of the AIGP attribute is defined here to be a set of + elements encoded as "Type/Length/Value" (i.e., a set of TLVs). Each + such TLV is encoded as shown in Figure 1. + + + + + + + + + + +Mohapatra, et al. Standards Track [Page 4] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Type | Length | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | + ~ ~ + | Value | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+.......................... + + Figure 1: AIGP TLV + + - Type: A single octet encoding the TLV Type. Only type 1, "AIGP + TLV", is defined in this document. Use of other TLV types is + outside the scope of this document. + + - Length: Two octets encoding the length in octets of the TLV, + including the Type and Length fields. The length is encoded as an + unsigned binary integer. (Note that the minimum length is 3, + indicating that no Value field is present.) + + - Value: A field containing zero or more octets. + + This document defines only a single such TLV, the "AIGP TLV". The + AIGP TLV is encoded as follows: + + - Type: 1 + + - Length: 11 + + - Value: Accumulated IGP Metric. + + The value field of the AIGP TLV is always 8 octets long, and its + value is interpreted as an unsigned 64-bit integer. IGP metrics + are frequently expressed as 4-octet values. By using an 8-octet + field, we ensure that the AIGP attribute can be used to hold the + sum of an arbitrary number of 4-octet values. + + When an AIGP attribute is created, it SHOULD contain no more than one + AIGP TLV. However, if it contains more than one AIGP TLV, only the + first one is used as described in Sections 3.4 and 4. In the + remainder of this document, we will use the term "value of the AIGP + TLV" to mean the value of the first AIGP TLV in the AIGP attribute. + Any other AIGP TLVs in the AIGP attribute MUST be passed along + unchanged if the AIGP attribute is passed along. + + + + + + + +Mohapatra, et al. Standards Track [Page 5] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + +3.1. Applicability Restrictions and Cautions + + This document only considers the use of the AIGP attribute in + networks where each router uses tunneling of some sort to deliver a + packet to its BGP next hop. Use of the AIGP attribute in other + scenarios is outside the scope of this document. + + If a Route Reflector supports the AIGP attribute but some of its + clients do not, then the routing choices that result may not all + reflect the intended routing policy. + +3.2. Handling a Malformed AIGP Attribute + + When receiving a BGP Update message containing a malformed AIGP + attribute, the attribute MUST be treated exactly as if it were an + unrecognized non-transitive attribute. That is, it "MUST be quietly + ignored and not passed along to other BGP peers" (see [BGP], Section + 5). This is equivalent to the "attribute discard" action specified + in [BGP-ERROR]. + + Note that an AIGP attribute MUST NOT be considered to be malformed + because it contains more than one TLV of a given type or because it + contains TLVs of unknown types. + + If a BGP path attribute is received that has the AIGP attribute + codepoint but also has the transitive bit set, the attribute MUST be + considered to be a malformed AIGP attribute and MUST be discarded as + specified in this section. + + If an AIGP attribute is received and its first AIGP TLV contains the + maximum value 0xffffffffffffffff, the attribute SHOULD be considered + to be malformed and SHOULD be discarded as specified in this section. + (Since the TLV value cannot be increased any further, it is not + useful for metric-based path selection.) + +3.3. Restrictions on Sending/Receiving + + An implementation that supports the AIGP attribute MUST support a + per-session configuration item, AIGP_SESSION, that indicates whether + the attribute is enabled or disabled for use on that session. + + - For Internal BGP (IBGP) sessions, and for External BGP (EBGP) + sessions between members of the same BGP Confederation + [BGP-CONFED], the default value of AIGP_SESSION SHOULD be + "enabled". + + - For all other External BGP (EBGP) sessions, the default value of + AIGP_SESSION MUST be "disabled". + + + +Mohapatra, et al. Standards Track [Page 6] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + The AIGP attribute MUST NOT be sent on any BGP session for which + AIGP_SESSION is disabled. + + If an AIGP attribute is received on a BGP session for which + AIGP_SESSION is disabled, the attribute MUST be treated exactly as if + it were an unrecognized non-transitive attribute. That is, it "MUST + be quietly ignored and not passed along to other BGP peers" (see + [BGP], Section 5). However, the fact that the attribute was received + SHOULD be logged (in a rate-limited manner). + +3.4. Creating and Modifying the AIGP Attribute + +3.4.1. Originating the AIGP Attribute + + An implementation that supports the AIGP attribute MUST support a + configuration item, AIGP_ORIGINATE, that enables or disables its + creation and attachment to routes. The default value of + AIGP_ORIGINATE MUST be "disabled". + + A BGP speaker MUST NOT add the AIGP attribute to any route whose path + leads outside the AIGP administrative domain to which the BGP speaker + belongs. When the AIGP attribute is used, changes in IGP routing + will directly impact BGP routing. Attaching the AIGP attribute to + customer routes, Internet routes, or other routes whose paths lead + outside the infrastructure of a particular AIGP administrative domain + could result in BGP scaling and/or thrashing problems. + + The AIGP attribute may be added only to routes that satisfy one of + the following conditions: + + - The route is a static route, not leading outside the AIGP + administrative domain, that is being redistributed into BGP; + + - The route is an IGP route that is being redistributed into BGP; + + - The route is an IBGP-learned route whose AS_PATH attribute is + empty; or + + - The route is an EBGP-learned route whose AS_PATH contains only + ASes that are in the same AIGP administrative domain as the BGP + speaker. + + A BGP speaker R MUST NOT add the AIGP attribute to any route for + which R does not set itself as the next hop. + + + + + + + +Mohapatra, et al. Standards Track [Page 7] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + It SHOULD be possible to set AIGP_ORIGINATE to "enabled for the + routes of a particular IGP that are redistributed into BGP" (where "a + particular IGP" might be OSPF or IS-IS). Other policies determining + when and whether to originate an AIGP attribute are also possible, + depending on the needs of a particular deployment scenario. + + When originating an AIGP attribute for a BGP route to address prefix + P, the value of the AIGP TLV is set according to policy. There are a + number of useful policies, some of which are in the following list: + + - When a BGP speaker R is redistributing into BGP an IGP route to + address prefix P, the IGP will have computed a distance from R to + P. This distance MAY be assigned as the value of the AIGP TLV. + + - A BGP speaker R may be redistributing into BGP a static route to + address prefix P, for which a distance from R to P has been + configured. This distance MAY be assigned as the value of the + AIGP TLV. + + - A BGP speaker R may have received and installed a BGP-learned + route to prefix P, with next hop N. Or it may be redistributing a + static route to P, with next hop N. Then: + + * If R has an IGP route to N, the IGP-computed distance from R to + N MAY be used as the value of the AIGP TLV of the route to P. + + * If R has a BGP route to N, and an AIGP TLV attribute value has + been computed for that route (see Section 3.4.3), that value + MAY be used as the AIGP TLV value of the route to P. + +3.4.2. Modifications by the Originator + + If BGP speaker R is the originator of the AIGP attribute of prefix P, + and the distance from R to P changes at some point, R SHOULD issue a + new BGP update containing the new value of the AIGP TLV of the AIGP + attribute. (Here we use the term "distance" to refer to whatever + value the originator assigns to the AIGP TLV, however it is computed; + see Section 3.4.1.) However, if the difference between the new + distance and the distance advertised in the AIGP TLV is less than a + configurable threshold, the update MAY be suppressed. + +3.4.3. Modifications by a Non-Originator + + Suppose a BGP speaker R1 receives a route with an AIGP attribute + whose value is A and with a next hop whose value is R2. Suppose also + that R1 is about to redistribute that route on a BGP session that is + enabled for sending/receiving the attribute. + + + + +Mohapatra, et al. Standards Track [Page 8] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + If R1 does not change the next hop of the route, then R1 MUST NOT + change the AIGP attribute value of the route. + + In all the computations discussed in this section, the AIGP value + MUST be capped at its maximum unsigned value 0xffffffffffffffff. + Increasing the AIGP value MUST NOT cause the value to wrap around. + + Suppose R1 changes the next hop of the route from R2 to R1. If R1's + route to R2 is either (a) an IGP-learned route or (b) a static route + that does not require recursive next hop resolution, then R1 MUST + increase the value of the AIGP TLV by adding to A the distance from + R1 to R2. This distance is either the IGP-computed distance from R1 + to R2 or some value determined by policy. However, A MUST be + increased by a non-zero amount. + + It is possible that R1 and R2 above are EBGP neighbors and that there + is a direct link between them on which no IGP is running. Then, when + R1 changes the next hop of a route from R2 to R1, the AIGP TLV value + MUST be increased by a non-zero amount. The amount of the increase + SHOULD be such that it is properly comparable to the IGP metrics. + For example, if the IGP metric is a function of latency, then the + amount of the increase should be a function of the latency from R1 to + R2. + + Suppose R1 changes the next hop of the route from R2 to R1 and R1's + route to R2 is either (a) a BGP-learned route or (b) a static route + that requires recursive next-hop resolution. Then, the AIGP TLV + value needs to be increased in several steps, according to the + following procedure. (Note that this procedure is ONLY used when + recursive next-hop resolution is needed.) + + 1. Let Xattr be the new AIGP TLV value. + + 2. Initialize Xattr to A. + + 3. Set XNH to R2. + + 4. Find the route to XNH. + + 5. If the route to XNH does not require recursive next-hop + resolution, get the distance D from R1 to XNH. (Note that this + condition cannot be satisfied the first time through this + procedure.) If D is above a configurable threshold, set the AIGP + TLV value to Xattr+D. If D is below a configurable threshold, + set the AIGP TLV value to Xattr. In either case, exit this + procedure. + + + + + +Mohapatra, et al. Standards Track [Page 9] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + 6. If the route to XNH is a BGP-learned route that does NOT have an + AIGP attribute, then exit this procedure and do not pass on any + AIGP attribute. If the route has an AIGP attribute without an + AIGP TLV, then the AIGP attribute MAY be passed along unchanged. + + 7. If the route to XNH is a BGP-learned route that has an AIGP TLV + value of Y, then set Xattr to Xattr+Y and set XNH to the next hop + of this route. (The intention here is that Y is the AIGP TLV + value of the route as it was received by R1, without having been + modified by R1.) + + 8. Go to step 4. + + The AIGP TLV value of a given route depends on (a) the AIGP TLV + values of all the next hops that are recursively resolved during this + procedure, and (b) the IGP distance to any next hop that is not + recursively resolved. Any change due to (a) in any of these values + MUST trigger a new AIGP computation for that route. Whether a change + due to (b) triggers a new AIGP computation depends upon whether the + change in IGP distance exceeds a configurable threshold. + + If the AIGP attribute is carried across several ASes, each with its + own IGP domain, it is clear that these procedures are unlikely to + give a sensible result if the IGPs are different (e.g., some OSPF and + some IS-IS) or if the meaning of the metrics is different in the + different IGPs (e.g., if the metric represents bandwidth in some IGP + domains but represents latency in others). These procedures also are + unlikely to give a sensible result if the metric assigned to inter-AS + BGP links (on which no IGP is running) or to static routes is not + comparable to the IGP metrics. All such cases are outside the scope + of the current document. + +4. Decision Process + + Support for the AIGP attribute involves several modifications to the + tie-breaking procedures of the BGP "phase 2" decision described in + [BGP], Section 9.1.2.2. These modifications are described in + Sections 4.1 and 4.2. + + In some cases, the BGP decision process may install a route without + executing any tie-breaking procedures. This may happen, e.g., if + only one route to a given prefix has the highest degree of preference + (as defined in [BGP], Section 9.1.1). In this case, the AIGP + attribute is not considered. + + + + + + + +Mohapatra, et al. Standards Track [Page 10] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + In other cases, some routes may be eliminated before the tie-breaking + procedures are invoked, e.g., routes with AS-PATH attributes + indicating a loop or routes with unresolvable next hops. In these + cases, the AIGP attributes of the eliminated routes are not + considered. + +4.1. When a Route Has an AIGP Attribute + + Assuming that the BGP decision process invokes the tie-breaking + procedures, the procedures in this section MUST be executed BEFORE + any of the tie-breaking procedures described in [BGP], Section + 9.1.2.2 are executed. + + If any routes have an AIGP attribute containing an AIGP TLV, remove + from consideration all routes that do not have an AIGP attribute + containing an AIGP TLV. + + If router R is considering route T, where T has an AIGP attribute + with an AIGP TLV, + + - then R must compute the value A, defined as follows: set A to the + sum of (a) T's AIGP TLV value and (b) the IGP distance from R to + T's next hop. + + - remove from consideration all routes that are not tied for the + lowest value of A. + +4.2. When the Route to the Next Hop Has an AIGP Attribute + + Suppose that a given router R1 is comparing two BGP-learned routes, + such that either: + + - the two routes have equal AIGP TLV values, or else + + - neither of the two routes has an AIGP attribute containing an AIGP + TLV. + + The BGP decision process as specified in [BGP] makes use, in its tie- + breaking procedures, of "interior cost", defined as follows: + + interior cost of a route is determined by calculating the metric + to the NEXT_HOP for the route using the Routing Table. + + This document replaces the "interior cost" tie breaker of [BGP] with + a tie breaker based on the "AIGP-enhanced interior cost". Suppose + route T has a next hop of N. The "AIGP-enhanced interior cost" from + node R1 to node N is defined as follows: + + + + +Mohapatra, et al. Standards Track [Page 11] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + - Let R2 be the BGP next hop of the route to N after all recursive + resolution of the next hop is done. Let m be the IGP distance (or + in the case of a static route, the configured distance) from R1 to + R2. + + - If the installed route to N has an AIGP attribute with an AIGP + TLV, set A to its AIGP TLV value, computed according to the + procedure in Section 3.4.3. + + - If the installed route to N does not have an AIGP attribute with + an AIGP TLV, set A to 0. + + - The "AIGP-enhanced interior cost" of route T is the quantity A+m. + + The "interior cost" tie breaker of [BGP] is then applied, using the + "AIGP-enhanced interior cost" instead of the "interior cost" as + defined in [BGP]. + +5. Deployment Considerations + + - Using the AIGP attribute to achieve a desired routing policy will + be more effective if each BGP speaker can use it to choose from + among multiple routes. Thus, it is highly recommended that the + procedures of [BESTEXT] and [ADD-PATH] be used in conjunction with + the AIGP attribute. + + - If a Route Reflector does not pass all paths to its clients, then + it will tend to pass the paths for which the IGP distance from the + Route Reflector itself to the next hop is smallest. This may + result in a non-optimal choice by the clients. + + - When the procedures of this document are deployed, it must be + understood that frequent changes of the IGP distance towards a + certain prefix may result in equally frequent transmission of BGP + updates about that prefix. + + - In an IGP deployment, there are certain situations in which a + network link may be temporarily assigned a metric whose value is + the maximum metric value (or close to the maximum) for that IGP. + This is known as "costing out" the link. A link may be "costed + out" to deflect traffic from the link before the link is actually + brought down or to discourage traffic from using a link until all + the necessary state for that link has been set up (e.g., + [LDP-IGP-SYNC]). This assumes, of course, that a path containing + a "costed out" link will have a total distance that is larger than + any alternate path within the same IGP area; in that case, the + normal IGP decision process will choose the path that does not + contain the "costed out" link. + + + +Mohapatra, et al. Standards Track [Page 12] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + + Costing out a link will have the same effect on BGP routes that + carry the AIGP attribute. The value of the AIGP TLV will be + larger for a route (to a given prefix) that contains a "costed + out" link than for a route (to the same prefix) that does not. It + must be understood, though, that a route that carries an AIGP + attribute will be preferred to a route that does not, no matter + what the value of the AIGP TLV is. This is similar to the + behavior in, e.g., an OSPF area, where an intra-area route is + preferred to an inter-area or external route, even if the intra- + area route's distance is large. + +6. IANA Considerations + + IANA has assigned the codepoint 26 in the "BGP Path Attributes" + registry to the AIGP attribute. + + IANA has created a registry for "BGP AIGP Attribute Types". The Type + field consists of a single octet, with possible values from 1 to 255. + (The value 0 is "Reserved".) The registration procedure for this + registry is "Standards Action". Type 1 is defined as "AIGP" and + refers to this document. + +7. Security Considerations + + The spurious introduction, through error or malfeasance, of an AIGP + attribute could result in the selection of paths other than those + desired. + + Improper configuration on both ends of an EBGP connection could + result in an AIGP attribute being passed from one service provider to + another. This would likely result in an unsound selection of paths. + +8. Acknowledgments + + The authors would like to thank Waqas Alam, Rajiv Asati, Alia Atlas, + Ron Bonica, Bruno Decraene, Brian Dickson, Clarence Filsfils, Sue + Hares, Anoop Kapoor, Pratima Kini, Thomas Mangin, Robert Raszuk, + Yakov Rekhter, Eric Rosenberg, Samir Saad, John Scudder, Shyam + Sethuram, and Ilya Varlashkin for their input. + + + + + + + + + + + + +Mohapatra, et al. Standards Track [Page 13] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + +9. References + +9.1. Normative Reference + + [BGP] Rekhter, Y., Ed., Li, T., Ed., and S. Hares, Ed., "A + Border Gateway Protocol 4 (BGP-4)", RFC 4271, January + 2006. + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + +9.2. Informative References + + [ADD-PATH] Walton, D., Retana, A., Chen, E., and J. Scudder, + "Advertisement of Multiple Paths in BGP", Work in + Progress, October 2013. + + [BESTEXT] Marques, P., Fernando, R., Mohapatra, P., and H. + Gredler, "Advertisement of the best external route in + BGP", Work in Progress, January 2012. + + [BGP-CONFED] Traina, P., McPherson, D., and J. Scudder, "Autonomous + System Confederations for BGP", RFC 5065, August 2007. + + [BGP-ERROR] Chen, E., Scudder, J., Mohapatra, P., and K. Patel, + "Revised Error Handling for BGP UPDATE Messages", Work + in Progress, June 2014. + + [LDP-IGP-SYNC] Jork, M., Atlas, A., and L. Fang, "LDP IGP + Synchronization", RFC 5443, March 2009. + + + + + + + + + + + + + + + + + + + + + +Mohapatra, et al. Standards Track [Page 14] + +RFC 7311 AIGP Metric Attribute for BGP August 2014 + + +Authors' Addresses + + Pradosh Mohapatra + Sproute Networks + + EMail: mpradosh@yahoo.com + + + Rex Fernando + Cisco Systems, Inc. + 170 Tasman Drive + San Jose, CA 95134 + US + + EMail: rex@cisco.com + + + Eric C. Rosen + Cisco Systems, Inc. + 1414 Massachusetts Avenue + Boxborough, MA, 01719 + US + + EMail: erosen@cisco.com + + + James Uttaro + AT&T + 200 S. Laurel Avenue + Middletown, NJ 07748 + US + + EMail: uttaro@att.com + + + + + + + + + + + + + + + + + + +Mohapatra, et al. Standards Track [Page 15] + -- cgit v1.2.3