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/rfc1587.txt | 955 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 955 insertions(+) create mode 100644 doc/rfc/rfc1587.txt (limited to 'doc/rfc/rfc1587.txt') diff --git a/doc/rfc/rfc1587.txt b/doc/rfc/rfc1587.txt new file mode 100644 index 0000000..6837290 --- /dev/null +++ b/doc/rfc/rfc1587.txt @@ -0,0 +1,955 @@ + + + + + + +Network Working Group R. Coltun +Request for Comments: 1587 RainbowBridge Communications +Category: Standards Track V. Fuller + Stanford University + March 1994 + + + The OSPF NSSA Option + +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. + +Table Of Contents + + 1.0 Abstract ................................................. 1 + 2.0 Overview ................................................. 2 + 2.1 Motivation ............................................... 2 + 2.2 Proposed Solution ........................................ 3 + 3.0 Implementation Details ................................... 5 + 3.1 The N-bit ................................................ 5 + 3.2 Type-7 Address Ranges .................................... 5 + 3.3 Type-7 LSAs .............................................. 5 + 3.4 Originating Type-7 LSAs .................................. 7 + 3.5 Calculating Type-7 AS External Routes .................... 8 + 3.6 Incremental Updates ...................................... 10 + 4.0 Originating Type-5 LSAs .................................. 10 + 4.1 Translating Type-7 LSAs .................................. 10 + 4.2 Flushing Translated Type-7 LSAs .......................... 13 + 5.0 Acknowledgements ......................................... 13 + 6.0 References ............................................... 13 + 7.0 Security Considerations .................................. 13 + 8.0 Authors' Addresses ....................................... 14 + Appendix A: Type-7 LSA Packet Format ......................... 15 + Appendix B: The Options Field ................................ 16 + Appendix C: Configuration Parameters ......................... 17 + +1.0 Abstract + + This document describes a new optional type of OSPF area, somewhat + humorously referred to as a "not-so-stubby" area (or NSSA). NSSAs + are similar to the existing OSPF stub area configuration option but + have the additional capability of importing AS external routes in a + limited fashion. + + + +Coltun & Fuller [Page 1] + +RFC 1587 OSPF NSSA Option March 1994 + + +2.0 Overview + +2.1 Motivation + + Wide-area transit networks (such as the NSFNET regionals) often have + connections to moderately-complex "leaf" sites. A leaf site may have + multiple IP network numbers assigned to it. + + Typically, one of the leaf site's networks is directly connected to a + router provided and administered by the transit network while the + others are distributed throughout and administered by the site. From + the transit network's perspective, all of the network numbers + associated with the site make up a single "stub" entity. For + example, BARRNet has one site composed of a class-B network, + 130.57.0.0, and a class-C network, 192.31.114.0. From BARRNet's + perspective, this configuration looks something like this: + + 192.31.114 + | + (cloud) + -------------- 130.57.4 + | + | + ------ 131.119.13 ------ + |BR18|------------|BR10| + ------ ------ + | + V + to BARRNet "core" OSPF system + + + where the "cloud" consists of the subnets of 130.57 and network + 192.31.114, all of which are learned by RIP on router BR18. + Topologically, this cloud looks very much like an OSPF stub area. + The advantages of running the cloud as an OSPF stub area are: + + 1. Type-5 routes (OSPF external link-state advertisements + (LSAs)) are not advertised beyond the router + labeled "BR10". This is advantageous because the + link between BR10 and BR18 may be a low-speed link + or the router BR18 may have limited resources. + + 2. The transit network is abstracted to the "leaf" + router BR18 by advertising only a default route + across the link between BR10 and BR18. + + 3. The cloud becomes a single, manageable "leaf" with + respect to the transit network. + + + +Coltun & Fuller [Page 2] + +RFC 1587 OSPF NSSA Option March 1994 + + + 4. The cloud can become, logically, a part of the transit + network's OSPF routing system. + + 5. Translated type-5 LSAs that are sent into the + backbone from the cloud (which is a separate + stub area) may be considered "leaf" nodes + when performing the Dijkstra calculation. + + However, the current definition of the OSPF protocol [1] imposes + topological limitations which restrict simple cloud topologies from + becoming OSPF stub areas. In particular, it is illegal for a stub + area to import routes external to OSPF; it is not possible for + routers BR18 and BR10 to both be members of the stub area and to + import the routes learned from RIP or other IP routing protocols as + type-5 (OSPF external LSAs) into the OSPF system. In order to run + OSPF out to BR18, BR18 must be a member of a non-stub area or the + OSPF backbone to import routes other than its directly-connected + network(s). Since it is not acceptable for BR18 to maintain all of + BARRNet's external (type-5) routes, BARRNet is forced by OSPF's + topological limitations to run OSPF out to BR10 and to run RIP + between BR18 and BR10. + +2.2 Proposed Solution + + This document describes a new optional type of OSPF area, somewhat + humorously referred to as a "not-so-stubby" area (or NSSA) which has + the capability of importing external routes in a limited fashion. + + The OSPF specification defines two general classes of area + configuration. The first allows type-5 LSAs to be flooded throughout + the area. In this configuration, type-5 LSAs may be originated by + routers internal to the area or flooded into the area by area border + routers. These areas, referred to herein as type-5 capable areas (or + just plain areas in the OSPF spec), are distinguished by the fact + that they can carry transit traffic. The backbone is always a type-5 + capable area. The second type of area configuration, called stub, + allows no type-5 LSAs to be propagated into/throughout the area and + instead depends on default routing to external destinations. + + NSSAs are defined in much the same manner as existing stub areas. To + support NSSAs, a new option bit (the "N" bit) and a new type of LSA + (type-7) area defined. The "N" bit ensures that routers belonging to + an NSSA agree on its configuration. Similar to the stub area's use + of the "E" bit, both NSSA neighbors must agree on the setting of the + "N" bit or the OSPF neighbor adjacency will not form. + + Type-7 LSAs provide for carrying external route information within an + NSSA. Type-7 AS External LSAs have virtually the same syntax as the + + + +Coltun & Fuller [Page 3] + +RFC 1587 OSPF NSSA Option March 1994 + + + Type-5 AS External LSAs with the obvious exception of the link-state + type (see section 3.2 for more details). There are two major semantic + differences between type-5 and type-7 LSAs. + + o Type-7 LSAs may be originated by and advertised + throughout an NSSA; as with stub areas, NSSA's do not + receive or originate type-5 LSAs. + + o Type-7 LSAs are advertised only within a single NSSA; + they are not flooded into the backbone area or any + other area by border routers, though the information + which they contain can be propagated into the backbone + area (see section 3.6). + + In order to allow limited exchange of external information across an + NSSA area border, NSSA border routers will translate selected type-7 + LSAs received from the NSSA into type-5 LSAs. These type-5 LSAs will + be flooded to all type-5 capable areas. NSSA area border routers may + be configured with address ranges so that several type-7 LSAs may be + represented by a single type-5 LSA. + + In addition, an NSSA area border router can originate a default + type-7 LSA (IP address of 0.0.0.0) into the NSSA. Default routes are + necessary because NSSAs do not receive full routing information and + must have a default route to route to AS-external destinations. Like + stub areas, NSSAs may be connected to the backbone at more than one + area border router, but may not be used as a transit area. Note that + the default route originated by an NSSA area border router is never + translated into a type-5 LSA, however, a default route originated by + an NSSA internal AS boundary router (one that is not also an area + border router) may be translated into a type-5 LSA. + + It should also be noted that unlike stub areas, all OSPF summary + routes (type-3 LSAs) must be imported into NSSAs. This is to ensure + that OSPF internal routes are always chosen over OSPF external + (type-7) routes. + + In our example topology the subnets of 130.57 and network 192.31.114, + will still be learned by RIP on router BR18 but now both BR10 and + BR18 can be in an NSSA and all of BARRNets external routes are hidden + from BR18; BR10 becomes an NSSA area border router and BR18 becomes + an AS boundary router internal to the NSSA. BR18 will import the + subnets of 130.57 and network 192.31.114 as type-7 LSAs into the + NSSA. BR10 then translates these routes into type-5 LSAs and floods + them into BARRNet's backbone. + + + + + + +Coltun & Fuller [Page 4] + +RFC 1587 OSPF NSSA Option March 1994 + + +3.0 Implementation Details + +3.1 The N-bit + + The N-bit ensures that all members of a NSSA agree on the area's + configuration. Together, the N-bit and E-bit reflect an interface's + (and consequently the interface's associated area's) external LSA + flooding capability. As explained in section 10.5 of the OSPF + specification, if type-5 LSAs are not flooded into/throughout the + area, the E-bit must be clear in the option field of the received + Hello packets. Interfaces associated with an NSSA will not send or + receive type-5 LSAs on that interface but may send and receive type-7 + LSAs. Therefore, if the N-bit is set in the options field, the E-bit + must be cleared. + + To support the NSSA option an additional check must be made in the + function that handles receiving Hello packet to verify that both the + N-bit and the E-bit found in the Hello packet's option field match + the value of the options that have been configured in the receiving + interface. A mismatch in the options causes processing of the + received Hello packet to stop and the packet to be dropped. + +3.2 Type-7 Address Ranges + + NSSA area border routers may be configured with type-7 address + ranges. Each address range is defined as an [address,mask] pair. + Many separate type-7 networks may then be represented by in a single + address range (as advertised by a type-5 LSA), just as a subnetted + network is composed of many separate subnets. Area border routers + may then summarize type-7 routes by advertising a single type-5 route + for each type-7 address range. The type-5 route, resulting from a + type-7 address range match will be distributed to all type-5 capable + areas. Section 4.1 gives the details of generating type-5 routes + from type-7 address ranges. + + A type-7 address range includes the following configurable items. + + o An [address,mask] pair. + + o A status indication of either Advertise or + DoNotAdvertise. + + o External route tag. + +3.3 Type-7 LSAs: NSSA External Link-State Advertisements + + External routes are imported into NSSAs as type-7 LSAs by the NSSA's + AS boundary routers. An NSSA AS boundary routers is a router which + + + +Coltun & Fuller [Page 5] + +RFC 1587 OSPF NSSA Option March 1994 + + + has an interface associated with the NSSA and is exchanging routing + information with routers belonging to another AS. As with type-5 + LSAs a separate type-7 LSA is originated for each destination + network. To support NSSA areas, the link-state database must + therefore be expanded to contain a type-7 LSA. + + Type 7-LSAs are identical to type-5 LSAs except for the following + (see section 12.3.4 "AS external links" in the OSPF + specification). + + 1. The type field in the LSA header is 7. + + 2. Type-7 LSAs are only flooded within the NSSA. + The flooding of type-7 LSAs follow the same rules + as the flooding of type 1-4 LSAs. + + 3. Type-7 LSAs are kept within the NSSA's LSDB (are + area specific) whereas because type-5 LSAs are + flooded to all type-5 capable areas, type-5 LSAs + global scope in the router's LSDB. + + 4. At the area border router, selected type-7 LSAs are + translated into type 5-LSAs and flooded into the + backbone. + + 5. Type 7 LSAs have a propagate (P) bit which is + used to flag the area border router to translate the + type-7 LSA into a type-5 LSA. Examples of how the P-bit + is used for loop avoidance are in the following sections. + + 6. Those type-7 LSAs that are to be translated into type-5 + LSAs must have their forwarding address set. + Type-5 LSAs that have been translated from type-7 LSAs + for the most part must contain a forwarding address. + The execption to this is if the translation to a type-5 + LSA is the result of an address range match, in which + case the type-5 LSA will not contain a forwarding address + (see section 4.1 for details). + The forwarding address contained in type-5 LSAs will + result in more efficient routing to the AS external + networks when there are multiple NSSA area + border routers. Having the forwarding address in the + type-7 LSAs will ease the translation of type-7 into + type-5 LSAs as the NSSA area border router will + not be required to compute the forwarding address. + + If the network between the NSSA AS boundary router and the + adjacent AS is advertised into OSPF as an internal OSPF + + + +Coltun & Fuller [Page 6] + +RFC 1587 OSPF NSSA Option March 1994 + + + route, the forwarding address should be the next hop + address as is currently done in type-5 LSAs, but unlike + type-5 LSAs if the intervening network is not advertised + into OSPF as an internal OSPF route, the forwarding + address should be any one of the router's active OSPF + interface addresses. + + Type-5 and type-7 metrics and path types are directly comparable. + +3.4 Originating Type-7 LSAs + + NSSA AS boundary routers may originate type-7 LSAs. All NSSA area + border routers must also be AS boundary routers since they all must + have the capability of translating a type-7 LSAs into a type-5 LSAs + (see section 3.6 routes for the translation algorithm). NSSA area + border routers must set the E-bit (external bit) as well as the B-bit + (border bit) in its router (type-1) LSAs (both in the backbone and in + the NSSA area). + + When an NSSA internal AS boundary router originates a type-7 LSA that + it wants to be translated into a type-5 LSA by the NSSA area border + router (and subsequently flooded into the backbone), it must set the + P-bit in the LS header's option field and add a valid forwarding + address in the type-7 LSA. + + If a router is attached to another AS and is also an NSSA area border + router, it may originate a both a type-5 and a type-7 LSA for the + same network. The type-5 LSA will be flooded to the backbone (and + all attached type-5 capable areas) and the type-7 will be flooded + into the NSSA. If this is the case, the P-bit must be reset in the + type-7 NSSA so the type-7 LSA isn't again translated into a type-5 + LSA by another NSSA area border router. + + A type-7 default route (network 0.0.0.0) may be originated into the + NSSA by an NSSA area border router or by an NSSA AS boundary router + which is internal to the NSSA. The type-7 default route originated + by the NSSA area border router must have the P-bit reset so that the + default route originated by the NSSA area border router will not find + its way out of the NSSA into the rest of the AS system via another + NSSA area border router. The type-7 default route originated by an + NSSA AS boundary router which is not an NSSA area border router may + have the P-bit set. Type-7 routes which are originated by the NSSA + area border router will not get added to other NSSA area border + router's routing table. + + A default route must not be injected into the NSSA as a summary + (type-3) LSA as in the stub area case. The reason for this is that + the preferred summary default route would be chosen over all more + + + +Coltun & Fuller [Page 7] + +RFC 1587 OSPF NSSA Option March 1994 + + + specific type-7 routes. Because summary routes are preferred to + external routes and to ensure that summary routes are chosen over + external within the NSSA, all summary routes (unlike stub areas in + which this is optional) must be imported into an NSSA. + +3.5 Calculating Type-7 AS External Routes + + This section is very similar to section 16.4 (Calculating AS external + routes) in the OSPF specification. An NSSA area border router should + examine both type-5 LSAs and type-7 LSAs if either type-5 or type-7 + routes need to be updated. Type-7 LSAs should be examined after + type-5 LSAs. An NSSA internal router should examine type-7 LSAs when + type-7 routes need to be recalculated. + + In relation to the steps to calculate the routing table as presented + in the OSPF specification (chapter 16, "Calculation of the Routing + Table"), type-7 LSAs should be examined after step 5 where the routes + to external destinations are calculated. + + Type-7 routes are calculated by examining type-7 LSAs. Each of LSAs + are considered in turn. Most type-7 LSAs describe routes to specific + IP destinations. A type-7 LSA can also describe a default route for + the NSSA (destination = DefaultDestination). For each type-7 LSA: + + 1. If the metric specified by the LSA is LSInfinity, the + age of the LSA equals MaxAge or the advertising router + field is equal to this router's router ID, examine the + next advertisement. + + 2. Call the destination described by the LSA N. Look up the + routing table entry for the AS boundary router (ASBR) that + originated the LSA. If no entry exists for the ASBR + (i.e., ASBR is unreachable), do nothing with this LSA and + consider the next in the list. + + If the destination is the default route (destination = + DefaultDestination) and if the originator of the LSA and + the calculating router are both NSSA area border routers + do nothing with this LSA and consider the next in the list. + + Else, this LSA describes an AS external path to destination + N. If the forwarding address (as specified in the forwarding + address field of the LSA) is 0.0.0.0, the packets routed + to the external destination N will be routed to the + originating ASBR. If the forwarding address is not 0.0.0.0, + look up the forwarding address in the routing table. Packets + routed to the external destination N will be routed within + the NSSA to this forwarding address. An intra-area path + + + +Coltun & Fuller [Page 8] + +RFC 1587 OSPF NSSA Option March 1994 + + + must therefore exist to the forwarding address. If no such + path exists, do nothing with the LSA and consider the next + in the list. + + Call the routing table distance to the forwarding address + (or the distance to the originating ASBR if the forwarding + address is 0.0.0.0) X, and the cost specified in the type-7 + LSA Y. X is in terms of the link-state metric, and Y is a + Type-1 or Type-2 external metric. + + 3. Now, look up the routing table entry for the destination + N. If no entries exist for N, install the AS external path + to N, with the next hop equal to the list of next hops to + the forwarding address/ASBR, and the advertising router equal + to ASBR. If the external metric type is 1, then the + path-type is set to Type-1 external and the cost is equal + to X + Y. If the external metric type is 2, the path-type + is set to Type-2 external, the link-state component of the + route's cost is X, and the Type-2 cost is Y. + + 4. Else, if the paths present in the table are not Type-1 or + Type-2 external paths, do nothing (AS external paths have + the lowest priority). + + 5. Otherwise, compare the cost of this new AS external path + to the ones present in the table. Note that type-5 and + type-7 routes are directly comparable. Type-1 external + paths are always shorter than Type-2 external paths. + Type-1 external paths are compared by looking at the sum + of the distance to the forwarding address/ASBR and the + advertised Type-1 paths (X+Y). Type-2 external paths are + compared by looking at the advertised Type-2 metrics, + and then if necessary, the distance to the forwarding + address/ASBR. + + When a type-5 LSA and a type-7 LSA are found to have the + same type and an equal distance, the following priorities + apply (listed from highest to lowest) for breaking the tie. + + a. Any type 5 LSA. + b. A type-7 LSA with the P-bit set and the forwarding + address non-zero. + c. Any other type-7 LSA. + + If the new path is shorter, it replaces the present paths + in the routing table entry. If the new path is the same + cost, it is added to the routing table entry's list of + paths. + + + +Coltun & Fuller [Page 9] + +RFC 1587 OSPF NSSA Option March 1994 + + +3.6 Incremental Updates + + Incremental updates for type-7 LSAs should be treated the same as + incremental updates for type-5 LSAs (see section 16.6 of the OSPF + specification). That is, if a new instance of a type-7 LSA is + received it is not necessary to recalculate the entire routing table. + If there is already an OSPF internal route to the destination + represented by the type-7 LSA, no recalculation is necessary. + Otherwise, the procedure in the proceeding section will have to be + performed but only for the external routes (type-5 and type-7) whose + networks describe the same networks as the newly received LSA. + +4.0 Originating Type-5 LSAs + +4.1 Translating Type-7 LSAs Into Type-5 LSAs + + This step is performed as part of the NSSA's Dijkstra calculation + after type-5 and type-7 routes have been calculated. If the + calculating router is not an area border router this translation + algorithm should be skipped. All reachable area border routers in + the NSSA should now be examined noting the one with the highest + router ID. If this router has the highest router ID, it will be the + one translating type-7 LSAs into type-5 LSAs for the NSSA, otherwise + the translation algorithm should not be performed. + + All type-7 routes that have been added to the routing table should be + examined. If the type-7 LSA (associated with the route being + examined) has the P-bit set and a non-zero forwarding address, the + following steps should be taken. + + The translation procedure must first check for a configured type-7 + address range. Recall that an type-7 address range consists of an + [address,mask] pair and a status indication of either Advertise or + DoNotAdvertise. At most a single type-5 LSA is made for each + range. If the route being examined falls within the type-7 + address range, (the [address,mask] pair of the route equal to or a + more specific instance of the [address,mask] pair of the type-7 + address range), one of following three actions may take place. + + 1. When the range's status indicates Advertise and the + route's address and mask are equal to the address + and mask of the type-7 range a type-5 LSA should be + originated if: + + o there currently is no type-5 LSA originated from + this router corresponding to the type-7 LSA, + + + + + +Coltun & Fuller [Page 10] + +RFC 1587 OSPF NSSA Option March 1994 + + + o the path type or the metric in the corresponding + type-5 LSA is different from the type-7 LSA or + + o The forwarding address in the corresponding + type-5 LSA is different from the type-7 LSA. + + The newly originated type-5 LSA will describe + the same network and have the same network mask, + metrics, forwarding address, external route tag + and path type as the type-7 LSA, however, the + advertising router field will be the router ID + of this area border router. + + 2. When the range's status indicates Advertise and the + route's address or mask indicates a more specific + route (i.e., the route's address is subsumed by the + range or the route has a longer mask), a type-5 LSA + is generated with link-state ID equal to the range's + address (if necessary, the link-state ID can also have + one or more of the range's "host" bits set; see + Appendix F of the OSPF specification for details), + the network mask, external route tag and + path type will be set to the configured type-7 range + values. The advertising router field will be the + router ID of this area border router. + The forwarding address will not be set. + The path type should always be set to the highest + path type that is subsumed by the net range. + The metric for the type-5 LSA will be set as follows: + + o if the path type is externl type 2, the type-5 + metric should be set to the largest type-7 metric + subsumed by this net range + 1. + + o if the path type is external type 1, the type-5 + metric should be set to the largest metric. + + For example, given a net range of [10.0.0.0, 255.0.0.0] + for an area that has type-7 routes of: + + 10.1.0.0 path type 1, metric 10 + 10.2.0.0 path type 1, metric 11 + 10.3.0.0 path type 2, metric 5 + + a type-5 LSA will be generated with a path type of 2 + and a metric of 6. + + + + + +Coltun & Fuller [Page 11] + +RFC 1587 OSPF NSSA Option March 1994 + + + As another example, given a net range of + [10.0.0.0, 255.0.0.0] for an area that has + type-7 routes of: + + 10.1.0.0 path type 1, metric 10 + 10.2.0.0 path type 1, metric 11 + 10.3.0.0 path type 1, metric 5 + + a type-5 LSA will be generated with a path type of 1 + and a metric of 11. + + These metric and path type rules will avoid routing + loops in the event that path type 1 and 2 are both + used within the area. + + 3. When the range's status indicates DoNotAdvertise, + the type-5 LSA is suppressed and the component networks + remain hidden from the rest of the AS. + + By default (given that the P-bit is set and the LSA has a + non-zero forwarding address) if a network is not contained + in any explicitly configured address range, a type-7 to + type-5 LSA translation will occur. + + A new instance of a type-5 LSA should be originated and + flooded to all attached type-5 capable areas if one of the + following is true. + + 1. There currently is no type-5 LSA originated from this + router corresponding to the type-7 LSA. + + 2. The path type or the metric in the corresponding + type-5 LSA is different from the type-7 LSA. + + 3. The forwarding address in the corresponding + type-5 LSA is different from the type-7 LSA. + + The newly originated type-5 LSAs will describe the same + network and have the same network mask, metrics, forwarding + address, external route tag and path type as the type-7 LSA. + The advertising router field will be the router ID of this + area border router. + + As with all newly originated type-5 LSAs, a type-5 LSA that + is the result of a type-7 to type-5 translation (type-7 range + or default case) is flooded to all attached type-5 capable + areas. + + + + +Coltun & Fuller [Page 12] + +RFC 1587 OSPF NSSA Option March 1994 + + +4.2 Flushing Translated Type-7 LSAs + + If an NSSA area border router has translated a type-7 LSA to a type-5 + LSA that should no longer be translated, the type-5 LSA should be + flushed (set to MaxAge and flooded). The translated type-5 LSA + should be flushed whenever the routing table entry that caused the + translation changes so that either the routing table entry is + unreachable or the entry's associated LSA is not a type-7 with the + P-bit set and a non-zero forwarding address. + +5.0 Acknowledgements + + This document was produced by the OSPF Working Group, chaired by John + Moy. + + In addition, the comments of the following individuals are also + acknowledged: + + Phani Jajjarvarpu cisco + Dino Farinacci cisco + Jeff Honig Cornell University + John Moy Proteon, Inc. + Doug Williams IBM + +6.0 References + + [1] Moy, J., "OSPF Version 2", RFC 1583, Proteon, Inc., March 1994. + + [2] Moy, J., "Multicast Extensions to OSPF", RFC 1584, Proteon, Inc., + Proteon, Inc., March 1994. + +7.0 Security Considerations + + Security issues are not discussed in this memo. + + + + + + + + + + + + + + + + + +Coltun & Fuller [Page 13] + +RFC 1587 OSPF NSSA Option March 1994 + + +8.0 Authors' Addresses + + Rob Coltun + RainbowBridge Communications + + Phone: (301) 340-9416 + EMail: rcoltun@rainbow-bridge.com + + + Vince Fuller + BARRNet + Stanford University + Pine Hall 115 + Stanford, CA, 94305-4122 + + Phone: (415) 723-6860 + EMail: vaf@Valinor.Stanford.EDU + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Coltun & Fuller [Page 14] + +RFC 1587 OSPF NSSA Option March 1994 + + +Appendix A: Type-7 Packet Format + + 0 32 + ----------------------------------- + | | OPTS | 7 | + | ------------------ + | Link-State Header | + | | + ----------------------------------- + | Network Mask | + ----------------------------------- ______ + |E| Tos | metric | . + ----------------------------------- . repeated for each TOS + | Forwarding Address | . + ----------------------------------- . + | External Route Tag | ______ + ----------------------------------- + + The definitions of the link-state ID, network mask, metrics and + external route tag are the same as the definitions for the type-5 + LSAs (see A.4.5 in the OSPF specification) except for: + + The Forwarding Address + + If the network between the NSSA AS boundary router and the adjacent + AS is advertised into OSPF as an internal OSPF route, the forwarding + address should be the next hop address but if the intervening network + is not advertised into OSPF as an internal OSPF route, the forwarding + address should be any one of the router's active OSPF interface + addresses. + + + + + + + + + + + + + + + + + + + + + +Coltun & Fuller [Page 15] + +RFC 1587 OSPF NSSA Option March 1994 + + +Appendix B: The Options Field + + The OSPF options field is present in OSPF Hello packets, Database + Description packets and all link-state advertisements. See appendix + A.2 in the OSPF specification for a description of option field. + + ------------------------------------ + | * | * | * | * | N/P | MC | E | T | + ------------------------------------ + + The Type-7 LSA options field + + + T-bit: The T-bit describes the router's TOS capability. + + E-bit: Type-5 AS external link advertisements are not + flooded into/through OSPF stub and NSSA areas. + The E-bit ensures that all members of a stub area + agree on that area configuration. The E-bit is + meaningful only in OSPF Hello packets. When the + E-bit is reset in the Hello packet sent out a + particular interface, it means that the router + will neither send nor receive type-5 AS external + link state advertisements on that interface (in + other words, the interface connects to a stub + area). Two routers will not become neighbors + unless they agree on the state of the E-bit. + + MC-bit: The MC-bit describes the multicast capability of + the various pieces of the OSPF routing domain + [2]. + + N-bit: The N-bit describes the the router's NSSA + capability. The N-bit is used only in Hello + packets and ensures that all members of an NSSA + agree on that area's configuration. When the + N-bit is reset in the Hello packet sent out a + particular interface, it means that the router + will neither send nor receive type-7 LSAs on that + interface. Two routers will not form an adjacency + unless they agree on the state of the N-bit. If + the N-bit is set in the options field, the E-bit + must be reset. + + P-bit: The P-bit is used only in the type-7 LSA header. + It flags the NSSA area border router to translate + the type-7 LSA into a type-5 LSA. + + + + +Coltun & Fuller [Page 16] + +RFC 1587 OSPF NSSA Option March 1994 + + +Appendix C: Configuration Parameters + + Appendix C.2 in the OSPF specification lists the area parameters. + The area ID, list of address ranges for type-3 summary routes and + authentication type remain unchanged. Section 3.2 of this document + lists the configuration parameters for type-7 address ranges. + + For NSSAs the external capabilities of the area must be set to accept + type-7 external routes. Additionally there must be a way of + configuring the NSSA area border router to send a default route into + the NSSA using a specific metric (type-1 or type-2 and the actual + cost). + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Coltun & Fuller [Page 17] + -- cgit v1.2.3