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RFC1587 - The OSPF NSSA Option

王朝other·作者佚名  2008-05-31
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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.

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.

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

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.

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

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

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

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

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.

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,

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.

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.

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", RFC1583, Proteon, Inc., March 1994.

[2] Moy, J., "Multicast Extensions to OSPF", RFC1584, Proteon, Inc.,

Proteon, Inc., March 1994.

7.0 Security Considerations

Security issues are not discussed in this memo.

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

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.

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.

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).

 
 
 
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