IP Routing: OSPF Configuration Guide, Cisco IOS Release 15SY
Bias-Free Language
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This module describes how to configure Open Shortest Path First (OSPF). OSPF is an Interior Gateway Protocol (IGP) developed
by the OSPF working group of the Internet Engineering Task Force (IETF). OSPF was designed expressly for IP networks and it
supports IP subnetting and tagging of externally derived routing information. OSPF also allows packet authentication and uses
IP multicast when sending and receiving packets.
Cisco supports RFC 1253,
OSPF Version 2 Management Information Base, August 1991. The OSPF MIB defines an IP routing protocol that provides management information related to OSPF and is supported
by Cisco routers.
For protocol-independent features that work with OSPF, see the "Configuring IP Routing Protocol-Independent Features" module.
Finding Feature Information
Your software release may not support all the features documented in this module. For the latest caveats and feature information,
see Bug Search Tooland the release notes for your platform and software release. To find information about the features documented in this module,
and to see a list of the releases in which each feature is supported, see the feature information table.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature
Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Information About OSPF
Cisco OSPF Implementation
The Cisco implementation conforms to the OSPF Version 2 specifications detailed in the Internet RFC 2328. The following list
outlines key features supported in the Cisco OSPF implementation:
Stub areas—The definition of stub areas is supported.
Route redistribution—Routes learned via any IP routing protocol can be redistributed into any other IP routing protocol.
At the intradomain level, OSPF can import routes learned via Interior Gateway Routing Protocol (IGRP), Routing Information
Protocol (RIP), and Intermediate System-to-Intermediate System (IS-IS). OSPF routes can also be exported into IGRP, RIP, and
IS-IS. At the interdomain level, OSPF can import routes learned via Exterior Gateway Protocol (EGP) and Border Gateway Protocol
(BGP). OSPF routes can be exported into EGP and BGP.
Authentication—Plain text and message-digest algorithm 5 (MD5) authentication among neighboring routers within an area is
supported.
Routing interface parameters—Configurable parameters supported include interface output cost, retransmission interval, interface
transmit delay, router priority, router “dead” and hello intervals, and authentication key.
Virtual links—Virtual links are supported.
Not-so-stubby area (NSSA)—RFC 3101, which replaces and is backward compatible with RFC 1587.
OSPF over demand circuit—RFC 1793.
Router Coordination for OSPF
OSPF typically requires coordination among many internal routers: Area Border Routers (ABRs), which are routers connected
to multiple areas, and Autonomous System Boundary Routers (ASBRs). At a minimum, OSPF-based routers or access servers can
be configured with all default parameter values, no authentication, and interfaces assigned to areas. If you intend to customize
your environment, you must ensure coordinated configurations of all routers.
Route Distribution for OSPF
You can specify route redistribution; see the task “Redistribute Routing Information” in the
Network Protocols Configuration Guide, Part 1, for information on how to configure route redistribution.
The Cisco OSPF implementation allows you to alter certain interface-specific OSPF parameters, as needed. You are not required
to alter any of these parameters, but some interface parameters must be consistent across all routers in an attached network.
Those parameters are controlled by the
ipospfhello-interval,
ipospfdead-interval, and
ipospfauthentication-key interface configuration commands. Therefore, if you do configure any of these parameters, ensure that the configurations
for all routers on your network have compatible values.
By default, OSPF classifies different media into the following three types of networks:
Broadcast networks (Ethernet, Token Ring, and FDDI)
Nonbroadcast multiaccess (NBMA) networks (Switched Multimegabit Data Service [SMDS], Frame Relay, and X.25)
Point-to-point networks (High-Level Data Link Control [HDLC] and PPP)
You can configure your network as either a broadcast or an NBMA network.
X.25 and Frame Relay provide an optional broadcast capability that can be configured in the map to allow OSPF to run as a
broadcast network. See thex25map and
frame-relaymap command pages in the
Cisco IOS Wide-Area Networking Command Reference publication for more detail.
OSPF Network Type
You have the choice of configuring your OSPF network type as either broadcast or NBMA, regardless of the default media type.
Using this feature, you can configure broadcast networks as NBMA networks when, for example, you have routers in your network
that do not support multicast addressing. You also can configure NBMA networks (such as X.25, Frame Relay, and SMDS) as broadcast
networks. This feature saves you from needing to configure neighbors, as described in the “Configuring OSPF for Nonbroadcast
Networks”section later in this module.
Configuring NBMA networks as either broadcast or nonbroadcast assumes that there are virtual circuits (VCs) from every router
to every router, that is, a fully meshed network. This is not true in some cases, for example, because of cost constraints
or when you have only a partially meshed network. In these cases, you can configure the OSPF network type as a point-to-multipoint
network. Routing between two routers that are not directly connected will go through the router that has VCs to both routers.
Note that you need not configure neighbors when using this feature.
An OSPF point-to-multipoint interface is defined as a numbered point-to-point interface having one or more neighbors. It
creates multiple host routes. An OSPF point-to-multipoint network has the following benefits compared to NBMA and point-to-point
networks:
Point-to-multipoint is easier to configure because it requires no configuration of neighbor commands, it consumes only one
IP subnet, and it requires no designated router election.
It costs less because it does not require a fully meshed topology.
It is more reliable because it maintains connectivity in the event of VC failure.
On point-to-multipoint broadcast networks, there is no need to specify neighbors. However, you can specify neighbors with
the
neighbor router configuration command, in which case you should specify a cost to that neighbor.
Before the
point-to-multipoint keyword was added to the
ipospfnetwork interface configuration command, some OSPF point-to-multipoint protocol traffic was treated as multicast traffic. Therefore,
the
neighbor router configuration command was not needed for point-to-multipoint interfaces because multicast took care of the traffic.
Hello, update, and acknowledgment messages were sent using multicast. In particular, multicast hello messages discovered all
neighbors dynamically.
On any point-to-multipoint interface (broadcast or not), the Cisco IOS software assumed that the cost to each neighbor was
equal. The cost was configured with the
ipospfcost interface configuration command. In reality, the bandwidth to each neighbor is different, so the cost should differ. With
this feature, you can configure a separate cost to each neighbor. This feature applies to point-to-multipoint interfaces only.
Because many routers might be attached to an OSPF network, a
designated router is selected for the network. Special configuration parameters are needed in the designated router selection if broadcast
capability is not configured.
These parameters need only be configured in those devices that are themselves eligible to become the designated router or
backup designated router (in other words, routers with a nonzero router priority value).
You can specify the following neighbor parameters, as required:
Priority for a neighboring router
Nonbroadcast poll interval
On point-to-multipoint, nonbroadcast networks, use the
neighbor router configuration command to identify neighbors. Assigning a cost to a neighbor is optional.
Prior to Cisco IOS Release 12.0, some customers were using point-to-multipoint on nonbroadcast media (such as classic IP
over ATM), so their routers could not dynamically discover their neighbors. This feature allows the
neighbor router configuration command to be used on point-to-multipoint interfaces.
Area Parameters
Use OSPF Not-So-Stubby Areas (NSSA) feature to simplify administration if you are an Internet service provider (ISP) or
a network administrator that must connect a central site that is using OSPF to a remote site that is using a different routing
protocol.
Prior to NSSA, the connection between the corporate site border router and the remote router could not be run as an OSPF
stub area because routes for the remote site could not be redistributed into the stub area, and two routing protocols needed
to be maintained. A simple protocol such as RIP was usually run and handled the redistribution. With NSSA, you can extend
OSPF to cover the remote connection by defining the area between the corporate router and the remote router as an NSSA.
As with OSPF stub areas, NSSA areas cannot be injected with distributed routes via Type 5 LSAs. Route redistribution into
an NSSA area is possible only with a special type of LSA that is known as Type 7 that can exist only in an NSSA area. An NSSA
ASBR generates the Type 7 LSA so that the routes can be redistributed, and an NSSA ABR translates the Type 7 LSA into a Type
5 LSA, which can be flooded throughout the whole OSPF routing domain. Summarization and filtering are supported during the
translation.
RFC 3101 allows you to configure an NSSA ABR router as a forced NSSA LSA translator. This means that the NSSA ABR router
will unconditionally assume the role of LSA translator, preempting the default behavior, which would only include it among
the candidates to be elected as translator.
Note
Even a forced translator might not translate all LSAs; translation depends on the contents of each LSA.
The figure below shows a network diagram in which OSPF Area 1 is defined as the stub area. The Enhanced Interior Gateway
Routing Protocol (EIGRP) routes cannot be propagated into the OSPF domain because routing redistribution is not allowed in
the stub area. However, once OSPF Area 1 is defined as an NSSA, an NSSA ASBR can inject the EIGRP routes into the OSPF NSSA
by creating Type 7 LSAs.
The redistributed routes from the RIP router will not be allowed into OSPF Area 1 because NSSA is an extension to the stub
area. The stub area characteristics will still exist, including the exclusion of Type 5 LSAs.
Route summarization is the consolidation of advertised addresses. This feature causes a single summary route to be advertised
to other areas by an ABR. In OSPF, an ABR will advertise networks in one area into another area. If the network numbers in
an area are assigned in a way such that they are contiguous, you can configure the ABR to advertise a summary route that covers
all the individual networks within the area that fall into the specified range.
When routes from other protocols are redistributed into OSPF (as described in the module "Configuring IP Routing Protocol-Independent
Features"), each route is advertised individually in an external LSA. However, you can configure the Cisco IOS software to
advertise a single route for all the redistributed routes that are covered by a specified network address and mask. Doing
so helps decrease the size of the OSPF link-state database.
In OSPF, all areas must be connected to a backbone area. If there is a break in backbone continuity, or the backbone is purposefully
partitioned, you can establish a virtual link. The two endpoints of a virtual link are ABRs. The virtual link must be configured
in both routers. The configuration information in each router consists of the other virtual endpoint (the other ABR) and the
nonbackbone area that the two routers have in common (called the transit area). Note that virtual links cannot be configured
through stub areas.
You can force an ASBR to generate a default route into an OSPF routing domain. Whenever you specifically configure redistribution
of routes into an OSPF routing domain, the router automatically becomes an ASBR. However, an ASBR does not, by default, generate
a defaultroute into the OSPF routing domain.
You can configure OSPF to look up Domain Naming System (DNS) names for use in all OSPF show EXEC command displays. You can
use this feature to more easily identify a router, because the router is displayed by name rather than by its router ID or
neighbor ID.
OSPF uses the largest IP address configured on the interfaces as its router ID. If the interface associated with this IP address
is ever brought down, or if the address is removed, the OSPF process must recalculate a new router ID and resend all its routing
information out its interfaces.
If a loopback interface is configured with an IP address, the Cisco IOS software will use this IP address as its router ID,
even if other interfaces have larger IP addresses. Because loopback interfaces never go down, greater stability in the routing
table is achieved.
OSPF automatically prefers a loopback interface over any other kind, and it chooses the highest IP address among all loopback
interfaces. If no loopback interfaces are present, the highest IP address in the router is chosen. You cannot tell OSPF to
use any particular interface.
In Cisco IOS Release 10.3 and later releases, by default OSPF calculates the OSPF metric for an interface according to the
bandwidth of the interface. For example, a 64-kbps link gets a metric of 1562, and a T1 link gets a metric of 64.
The OSPF metric is calculated as the ref-bw value divided by the bandwidth value, with the ref-bw value equal to 108 by default,
and the bandwidth value determined by the bandwidth interface configuration command. The calculation gives FDDI a metric of
1. If you have multiple links with high bandwidth, you might want to specify a larger number to differentiate the cost on
those links.
An administrative distance is a rating of the trustworthiness of a routing information source, such as an individual router
or a group of routers. Numerically, an administrative distance is an integer from 0 to 255. In general, the higher the value,
the lower the trust rating. An administrative distance of 255 means the routing information source cannot be trusted at all
and should be ignored.
OSPF uses three different administrative distances: intra-area, interarea, and external. Routes within an area are intra-area;
routes to another area are interarea; and routes from another routing domain learned via redistribution are external. The
default distance for each type of route is 110.
Because simplex interfaces between two devices on an Ethernet represent only one network segment, for OSPF you must configure
the sending interface to be a passive interface. This configuration prevents OSPF from sending hello packets for the sending
interface. Both devices are able to see each other via the hello packet generated for the receiving interface.
You can configure the delay time between when OSPF receives a topology change and when it starts a shortest path first (SPF)
calculation. You can also configure the hold time between two consecutive SPF calculations.
The OSPF on-demand circuit is an enhancement to the OSPF protocol that allows efficient operation over on-demand circuits
such as ISDN, X.25 switched virtual circuits (SVCs), and dialup lines. This feature supports RFC 1793, Extending OSPF to Support
Demand Circuits.
Prior to this feature, OSPF periodic hello and LSA updates would be exchanged between routers that connected the on-demand
link, even when no changes occurred in the hello or LSA information.
With this feature, periodic hellos are suppressed and the periodic refreshes of LSAs are not flooded over the demand circuit.
These packets bring up the link only when they are exchanged for the first time, or when a change occurs in the information
they contain. This operation allows the underlying data link layer to be closed when the network topology is stable.
This feature is useful when you want to connect telecommuters or branch offices to an OSPF backbone at a central site. In
this case, OSPF for on-demand circuits allows the benefits of OSPF over the entire domain, without excess connection costs.
Periodic refreshes of hello updates, LSA updates, and other protocol overhead are prevented from enabling the on-demand circuit
when there is no "real" data to send.
Overhead protocols such as hellos and LSAs are transferred over the on-demand circuit only upon initial setup and when they
reflect a change in the topology. This means that critical changes to the topology that require new SPF calculations are sent
in order to maintain network topology integrity. Periodic refreshes that do not include changes, however, are not sent across
the link.
The OSPF LSA group pacing feature allows the router to group OSPF LSAs and pace the refreshing, checksumming, and aging functions.
The group pacing results in more efficient use of the router.
The router groups OSPF LSAs and paces the refreshing, checksumming, and aging functions so that sudden increases in CPU usage
and network resources are avoided. This feature is most beneficial to large OSPF networks.
OSPF LSA group pacing is enabled by default. For typical customers, the default group pacing interval for refreshing, checksumming,
and aging is appropriate and you need not configure this feature.
Original LSA Behavior
Each OSPF LSA has an age, which indicates whether the LSA is still valid. Once the LSA reaches the maximum age (1 hour),
it is discarded. During the aging process, the originating router sends a refresh packet every 30 minutes to refresh the LSA.
Refresh packets are sent to keep the LSA from expiring, whether there has been a change in the network topology or not. Checksumming
is performed on all LSAs every 10 minutes. The router keeps track of LSAs that it generates and LSAs that it receives from
other routers. The router refreshes LSAs that it generated; it ages the LSAs that it received from other routers.
Prior to the LSA group pacing feature, the Cisco software would perform refreshing on a single timer and checksumming and
aging on another timer. In the case of refreshing, for example, the software would scan the whole database every 30 minutes,
refreshing every LSA that the router generated, no matter how old it was. The figure below illustrates all the LSAs being
refreshed at once. This process wasted CPU resources because only a small portion of the database needed to be refreshed.
A large OSPF database (several thousand LSAs) could have thousands of LSAs with different ages. Refreshing on a single timer
resulted in the age of all LSAs becoming synchronized, which resulted in much CPU processing at once. Furthermore, a large
number of LSAs could cause a sudden increase of network traffic, consuming a large amount of network resources in a short
time.
LSA Group Pacing with Multiple Timers
Configuring each LSA to have its own timer avoids excessive CPU processing and sudden network-traffic increase. To again
use the example of refreshing, each LSA gets refreshed when it is 30 minutes old, independent of other LSAs. So the CPU is
used only when necessary. However, LSAs being refreshed at frequent, random intervals would require many packets for the few
refreshed LSAs that the router must send, which would be inefficient use of bandwidth.
Therefore, the router delays the LSA refresh function for an interval of time instead of performing it when the individual
timers are reached. The accumulated LSAs constitute a group, which is then refreshed and sent out in one packet or more. Thus,
the refresh packets are paced, as are the checksumming and aging. The pacing interval is configurable; it defaults to 4 minutes,
which is randomized to further avoid synchronization.
The figure below illustrates the case of refresh packets. The first timeline illustrates individual LSA timers; the second
timeline illustrates individual LSA timers with group pacing.
The group pacing interval is inversely proportional to the number of LSAs that the router is refreshing, checksumming, and
aging. For example, if you have approximately 10,000 LSAs, decreasing the pacing interval would benefit you. If you have a
very small database (40 to 100 LSAs), increasing the pacing interval to 10 to 20 minutes might benefit you slightly.
The default value of pacing between LSA groups is 240 seconds (4 minutes). The range is from 10 seconds to 1800 seconds (30
minutes).
By default, OSPF floods new LSAs over all interfaces in the same area, except the interface on which the LSA arrives. Some
redundancy is desirable, because it ensures robust flooding. However, too much redundancy can waste bandwidth and might destabilize
the network due to excessive link and CPU usage in certain topologies. An example would be a fully meshed topology.
You can block OSPF flooding of LSAs in two ways, depending on the type of networks:
On broadcast, nonbroadcast, and point-to-point networks, you can block flooding over specified OSPF interfaces.
On point-to-multipoint networks, you can block flooding to a specified neighbor.
The growth of the Internet has increased the importance of scalability in IGPs such as OSPF. By design, OSPF requires LSAs
to be refreshed as they expire after 3600 seconds. Some implementations have tried to improve the flooding by reducing the
frequency to refresh from 30 minutes to about 50 minutes. This solution reduces the amount of refresh traffic but requires
at least one refresh before the LSA expires. The OSPF flooding reduction solution works by reducing unnecessary refreshing
and flooding of already known and unchanged information. To achieve this reduction, the LSAs are now flooded with the higher
bit set. The LSAs are now set as “do not age.”
Cisco routers do not support LSA Type 6 Multicast OSPF (MOSPF), and they generate syslog messages if they receive such packets.
If the router is receiving many MOSPF packets, you might want to configure the router to ignore the packets and thus prevent
a large number of syslog messages.
The former OSPF implementation for sending update packets needed to be more efficient. Some update packets were getting lost
in cases where the link was slow, a neighbor could not receive the updates quickly enough, or the router was out of buffer
space. For example, packets might be dropped if either of the following topologies existed:
A fast router was connected to a slower router over a point-to-point link.
During flooding, several neighbors sent updates to a single router at the same time.
OSPF update packets are now automatically paced so they are not sent less than 33 milliseconds apart. Pacing is also added
between resends to increase efficiency and minimize lost retransmissions. Also, you can display the LSAs waiting to be sent
out an interface. The benefit of pacing is that OSPF update and retransmission packets are sent more efficiently. There are
no configuration tasks for this feature; it occurs automatically.
You can display specific statistics such as the contents of IP routing tables, caches, and databases. Information provided
can be used to determine resource utilization and solve network problems. You can also display information about node reachability
and discover the routing path that your device packets are taking through the network.
How to Configure OSPF
To configure OSPF, perform the tasks described in the following sections. The tasks in the “Enabling OSPF” section are required;
the tasks in the remaining sections are optional, but might be required for your application. For information about the maximum
number of interfaces, see the “Restrictions for OSPF” section.
Enabling OSPF
SUMMARY STEPS
enable
configureterminal
router ospfprocess-id
networkip-addresswildcard-maskareaarea-id
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables privileged EXEC mode.
Enter your password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 3
router ospfprocess-id
Example:
Device(config)# router ospf 109
Enables OSPF routing and enters router configuration mode.
Step 4
networkip-addresswildcard-maskareaarea-id
Example:
Device(config-router)# network 192.168.129.16 0.0.0.3 area 20
Defines an interface on which OSPF runs and defines the area ID for that interface.
Step 5
end
Example:
Device(config-router)# end
Exits router configuration mode and returns to privileged EXEC mode.
Configuring OSPF Interface
Parameters
SUMMARY STEPS
enable
configureterminal
interfacetypenumber
ipospfcostcost
ipospfretransmit-intervalseconds
ipospftransmit-delayseconds
ipospfprioritynumber-value
ipospfhello-intervalseconds
ipospfdead-intervalseconds
ipospfauthentication-keykey
ipospfmessage-digest-keykey-idmd5key
ipospfauthentication [message-digest |
null]
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables
privileged EXEC mode.
Enter your
password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global
configuration mode.
Step 3
interfacetypenumber
Example:
Device(config)# interface Gigabitethernet 0/0
Configures an
interface type and enters interface configuration mode.
Step 4
ipospfcostcost
Example:
Device(config-if)# ip ospf cost 65
Explicitly
specifies the cost of sending a packet on an OSPF interface.
Step 5
ipospfretransmit-intervalseconds
Example:
Device(config-if)# ip ospf retransmit-interval 1
Specifies the
number of seconds between link-state advertisement (LSA) retransmissions for
adjacencies belonging to an OSPF interface.
Step 6
ipospftransmit-delayseconds
Example:
Device(config-if)# ip ospf transmit-delay
Sets the
estimated number of seconds required to send a link-state update packet on an
OSPF interface.
Step 7
ipospfprioritynumber-value
Example:
Device(config-if)# ip ospf priority 1
Sets priority
to help determine the OSPF designated router for a network.
Step 8
ipospfhello-intervalseconds
Example:
Device(config-if)# ip ospf hello-interval 1
Specifies the
length of time between the hello packets that the Cisco IOS software sends on
an OSPF interface.
Step 9
ipospfdead-intervalseconds
Example:
Device(config-if)# ip ospf dead-interval 1
Sets the
number of seconds that a device must wait before it declares a neighbor OSPF
router down because it has not received a hello packet.
Step 10
ipospfauthentication-keykey
Example:
Device(config-if)# ip ospf authentication-key 1
Assigns a
password to be used by neighboring OSPF routers on a network segment that is
using the OSPF simple password authentication.
Step 11
ipospfmessage-digest-keykey-idmd5key
Example:
Device(config-if)# ip ospf message-digest-key 1 md5 23456789
Enables OSPF
MD5 authentication. The values for the
key-id
and
key
arguments must match values specified for other neighbors on a network segment.
Step 12
ipospfauthentication [message-digest |
null]
Example:
Device(config-if)# ip ospf authentication message-digest
Specifies the
authentication type for an interface.
Step 13
end
Example:
Device(config-if)# end
Exits
interface configuration mode and returns to privileged EXEC mode.
Configuring OSPF over Different Physical Networks
Configuring OSPF for Point-to-Multipoint Broadcast Networks
SUMMARY STEPS
configureterminal
interfacetypenumber
ipospfnetworkpoint-to-multipoint
exit
routerospfprocess-id
neighborip-address [costnumber]
DETAILED STEPS
Command or Action
Purpose
Step 1
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 2
interfacetypenumber
Example:
Device(config)# interface gigabitethernet 0/0/0
Specifies an interface type and number, and enters interface configuration mode.
Step 3
ipospfnetworkpoint-to-multipoint
Example:
Device#(config-if) ip ospf network point-to-multipoint
Configures an interface as point-to-multipoint for broadcast media.
Step 4
exit
Example:
Device#(config-if) exit
Enters global configuration mode.
Step 5
routerospfprocess-id
Example:
Device#(config) router ospf 109
Configures an OSPF routing process and enters router configuration mode.
Specifies a neighbor and assigns a cost to the neighbor.
Note
Repeat this step for each neighbor if you want to specify a cost. Otherwise, neighbors will assume the cost of the interface,
based on the
ipospfcost interface configuration command.
Configuring OSPF for Nonbroadcast Networks
SUMMARY STEPS
configureterminal
interfacetypenumber
ipospfnetworkpoint-to-multipointnon-broadcast
exit
routerospfprocess-id
neighborip-address [costnumber]
DETAILED STEPS
Command or Action
Purpose
Step 1
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 2
interfacetypenumber
Example:
Device(config)# interface gigabitethernet 0/0/0
Specifies an interface type and number, and enters interface configuration mode.
Step 3
ipospfnetworkpoint-to-multipointnon-broadcast
Example:
Device#(config-if) ip ospf network point-to-multipoint non-broadcast
Configures an interface as point-to-multipoint for nonbroadcast media.
Step 4
exit
Example:
Device#(config-if) exit
Enters global configuration mode.
Step 5
routerospfprocess-id
Example:
Device#(config) router ospf 109
Configures an OSPF routing process and enters router configuration mode.
Specifies a neighbor and assigns a cost to the neighbor.
Note
Repeat this step for each neighbor if you want to specify a cost. Otherwise, neighbors will assume the cost of the interface,
based on the
ipospfcost interface configuration command.
Configuring OSPF Area
Parameters
SUMMARY STEPS
enable
configureterminal
routerospfprocess-id
areaarea-idauthentication
areaarea-idstub [no summary]
areaarea-iddefault-costcost
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables
privileged EXEC mode.
Enter your
password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global
configuration mode.
Step 3
routerospfprocess-id
Example:
Device(config)# router ospf 10
Enables OSPF
routing and enters router configuration mode.
Step 4
areaarea-idauthentication
Example:
Device(config-router)# area 10.0.0.0 authentication
Enables
authentication for an OSPF area.
Step 5
areaarea-idstub [no summary]
Example:
Device(config-router)# area 10.0.0.0 stub no-summary
Defines an area
to be a stub area.
Step 6
areaarea-iddefault-costcost
Example:
Device(config-router)# area 10.0.0.0 default-cost 1
Specifies a
cost for the default summary route that is sent into a stub area or
not-so-stubby area (NSSA)
Step 7
end
Example:
Device(config-router)# end
Exits router
configuration mode and returns to privileged EXEC mode.
Configuring OSPFv2 NSSA
Configuring an OSPFv2 NSSA
Area and Its Parameters
Controls the
route summarization and filtering during the translation and limits the summary
to NSSA areas.
Step 8
end
Example:
Device(config-router)# end
Exits router
configuration mode and returns to privileged EXEC mode.
Configuring an NSSA ABR as a
Forced NSSA LSA Translator
SUMMARY STEPS
enable
configureterminal
routerospfprocess-id
areaarea-idnssatranslatetype7always
areaarea-idnssatranslatetype7suppress-fa
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables
privileged EXEC mode.
Enter your
password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global
configuration mode.
Step 3
routerospfprocess-id
Example:
Device(config)# router ospf 1
Enables OSPF
routing and enters router configuration mode.
The
process-id
argument identifies the OSPF process. The range is from 1 to 65535.
Step 4
areaarea-idnssatranslatetype7always
Example:
Device(config-router)# area 10 nssa translate type7 always
Configures a
Not-So-Stubby Area Area Border Router (NSSA ABR) device as a forced NSSA Link
State Advertisement (LSA) translator.
Note
You can use
the
always keyword
in the
areanssatranslate command to configure an NSSA ABR device
as a forced NSSA LSA translator. This command can be used if RFC 3101 is disabled and
RFC 1587 is used.
Step 5
areaarea-idnssatranslatetype7suppress-fa
Example:
Device(config-router)# area 10 nssa translate type7 suppress-fa
Allows ABR to
suppress the forwarding address in translated Type-5 LSA.
Step 6
end
Example:
Device(config-router)# end
Exits router
configuration mode and returns to privileged EXEC mode.
Disabling RFC 3101
Compatibility and Enabling RFC 1587 Compatibility
SUMMARY STEPS
enable
configureterminal
routerospfprocess-id
compatiblerfc1587
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables
privileged EXEC mode.
Enter your
password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global
configuration mode.
Step 3
routerospfprocess-id
Example:
Device(config)# router ospf 1
Enables OSPF
routing and enters router configuration mode.
The
process-id argument identifies the OSPF process.
Use
router ospfprocess-id command to enable OSPFv2 routing.
Step 4
compatiblerfc1587
Example:
Device(config-router)# compatible rfc1587
Enables the device to be RFC 1587 compliant.
Step 5
end
Example:
Device(config-router)# end
Exits router
configuration mode and returns to privileged EXEC mode.
Configuring OSPF NSSA Parameters
Prerequisites
Evaluate the
following considerations before you implement this feature:
You can set a
Type 7 default route that can be used to reach external destinations. When
configured, the device generates a Type 7 default into the Not-So-Stubby Area
(NSSA or the NSSA Area Border Router (ABR).
Every device
within the same area must agree that the area is NSSA; otherwise, the devices
cannot communicate.
Configuring Route Summarization Between OSPF Areas
Configuring Route Summarization When Redistributing Routes into OSPF
Forces the ASBR to generate a default route into the OSPF routing domain.
Note
The
always keyword includes the following exception when a route map is used. When a route map is used, the origination of the default
route by OSPF is not bound to the existence of a default route in the routing table.
Step 5
end
Example:
Device(config-router)# end
Exits router configuration mode and returns to privileged EXEC mode.
Configuring Lookup of DNS Names
SUMMARY STEPS
enable
configureterminal
ipospfname-lookup
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables privileged EXEC mode.
Enter your password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 3
ipospfname-lookup
Example:
Device# ip ospf name-lookup
Enables OSPF routing and enters router configuration mode.
Step 4
end
Example:
Device(config)# end
Exits global configuration mode and returns to privileged EXEC mode.
Forcing the Router ID Choice with a Loopback Interface
SUMMARY STEPS
configureterminal
interfacetypenumber
ipaddress ip-addressmask
DETAILED STEPS
Command or Action
Purpose
Step 1
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 2
interfacetypenumber
Example:
Device(config)# interface loopback 0
Creates a loopback interface and enters interface configuration mode.
Step 3
ipaddress ip-addressmask
Example:
Device#(config-if) ip address 192.108.1.27 255.255.255.0
Assigns an IP address to this interface.
Controlling Default
Metrics
SUMMARY STEPS
enable
configureterminal
router ospfprocess-id
auto-costreference-bandwidthref-bw
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables
privileged EXEC mode.
Enter your
password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global
configuration mode.
Step 3
router ospfprocess-id
Example:
Device# router ospf 109
Enables OSPF
routing and enters router configuration mode.
Exits router configuration mode and returns to privileged EXEC mode.
Configuring OSPF over On-Demand Circuits
SUMMARY STEPS
router ospf
process-id
interfacetype number
ip ospf demand-circuit
DETAILED STEPS
Command or Action
Purpose
Step 1
router ospf
process-id
Enables OSPF operation.
Step 2
interfacetype number
Enters interface configuration mode.
Step 3
ip ospf demand-circuit
Configures OSPF over an on-demand circuit.
What to do next
Note
You can prevent an interface from accepting demand-circuit requests from other routers to by specifying the
ignore keyword in the
ipospfdemand-circuit command.
Prerequisites
Evaluate the following considerations before implementing the On-Demand Circuits feature:
Because LSAs that include topology changes are flooded over an on-demand circuit, we recommend that you put demand circuits
within OSPF stub areas or within NSSAs to isolate the demand circuits from as many topology changes as possible.
Every router within a stub area or NSSA must have this feature loaded in order to take advantage of the on-demand circuit
functionality. If this feature is deployed within a regular area, all other regular areas must also support this feature before
the demand circuit functionality can take effect because Type 5 external LSAs are flooded throughout all areas.
Hub-and-spoke network topologies that have a point-to-multipoint (P2MP) OSPF interface type on a hub might not revert to
nondemand circuit mode when needed. You must simultaneously reconfigure OSPF on all interfaces on the P2MP segment when reverting
them from demand circuit mode to nondemand circuit mode.
Do not implement this feature on a broadcast-based network topology because the overhead protocols (such as hello and LSA
packets) cannot be successfully suppressed, which means the link will remain up.
Configuring the router for an OSPF on-demand circuit with an asynchronous interface is not a supported configuration. The
supported configuration is to use dialer interfaces on both ends of the circuit. For more information, refer to
Why OSPF Demand Circuit Keeps Bringing Up the Link .
Logging Neighbors Going Up or Down
SUMMARY STEPS
enable
configureterminal
router ospfprocess-id
log-adjacency-changes [detail]
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables privileged EXEC mode.
Enter your password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 3
router ospfprocess-id
Example:
Device(config)# router ospf 109
Enables OSPF routing and enters router configuration mode.
Configure the
log-adjacency-changes command if you want to know about OSPF neighbors going up or down without turning on the
debugipospfadjacency
EXEC command because the
log-adjacency-changes command provides a higher-level view of the peer relationship with less output. Configure the
log-adjacency-changesdetail command if you want to see messages for each state change.
Step 5
end
Example:
Device(config-router)# end
Exits router configuration mode and returns to privileged EXEC mode.
Changing the LSA Group Pacing Interval
SUMMARY STEPS
enable
configureterminal
router ospfprocess-id
timerspacinglsa-groupseconds
end
DETAILED STEPS
Command or Action
Purpose
Step 1
enable
Example:
Device> enable
Enables privileged EXEC mode.
Enter your password if prompted.
Step 2
configureterminal
Example:
Device# configure terminal
Enters global configuration mode.
Step 3
router ospfprocess-id
Example:
Device(config)# router ospf 109
Enables OSPF routing and enters router configuration mode.
Step 4
timerspacinglsa-groupseconds
Example:
Device(config-router)# timers pacing lsa-group 60
Changes the group pacing of LSAs.
Step 5
end
Example:
Device(config-router)# end
Exits router configuration mode and returns to privileged EXEC mode.
Blocking OSPF LSA Flooding
Command
Purpose
ipospfdatabase-filterallout
Blocks the flooding of OSPF LSA packets to the interface.
On point-to-multipoint networks, to block flooding of OSPF LSAs, use the following command in router configuration mode:
Command
Purpose
neighborip-addressdatabase-filterallout
Blocks the flooding of OSPF LSA packets to the specified neighbor.
Reducing LSA Flooding
Command
Purpose
ipospfflood-reduction
Suppresses the unnecessary flooding of LSAs in stable topologies.
Ignoring MOSPF LSA Packets
Command
Purpose
ignorelsamospf
Prevents the router from generating syslog messages when it receives MOSPF LSA packets.
Monitoring and Maintaining OSPF
Command
Purpose
show ip ospf [process-id]
Displays general information about OSPF routing processes.
showipospfborder-routers
Displays the internal OSPF routing table entries to the ABR and ASBR.
Displays a list of OSPF LSAs waiting to be flooded over an interface.
Restrictions for OSPF
On systems with a large number of interfaces, it may be possible to configure OSPF such that the number of links advertised
in the router LSA causes the link-state update packet to exceed the size of a “huge” Cisco buffer. To resolve this problem,
reduce the number of OSPF links or increase the huge buffer size by entering the
buffershugesizesize command.
A link-state update packet containing a router LSA typically has a fixed overhead of 196 bytes, and an additional 12 bytes
are required for each link description. With a huge buffer size of 18024 bytes, there can be a maximum of 1485 link descriptions.
Because the maximum size of an IP packet is 65,535 bytes, there is still an upper bound on the number of links possible on
a router.
Configuration Examples for OSPF
Example: OSPF Point-to-Multipoint
In the figure below, Router 1 uses data-link connection identifier (DLCI) 201 to communicate with Router 2, DLCI 202 to communicate
with Router 4, and DLCI 203 to communicate with Router 3. Router 2 uses DLCI 101 to communicate with Router 1 and DLCI 102
to communicate with Router 3. Router 3 communicates with Router 2 (DLCI 401) and Router 1 (DLCI 402). Router 4 communicates
with Router 1 (DLCI 301). Configuration examples follow the figure.
Router 1 Configuration
hostname Router 1
!
interface serial 1
ip address 10.0.0.2 255.0.0.0
ip ospf network point-to-multipoint
encapsulation frame-relay
frame-relay map ip 10.0.0.1 201 broadcast
frame-relay map ip 10.0.0.3 202 broadcast
frame-relay map ip 10.0.0.4 203 broadcast
!
router ospf 1
network 10.0.0.0 0.0.0.255 area 0
Router 2 Configuration
hostname Router 2
!
interface serial 0
ip address 10.0.0.1 255.0.0.0
ip ospf network point-to-multipoint
encapsulation frame-relay
frame-relay map ip 10.0.0.2 101 broadcast
frame-relay map ip 10.0.0.4 102 broadcast
!
router ospf 1
network 10.0.0.0 0.0.0.255 area 0
Router 3 Configuration
hostname Router 3
!
interface serial 3
ip address 10.0.0.4 255.0.0.0
ip ospf network point-to-multipoint
encapsulation frame-relay
clock rate 1000000
frame-relay map ip 10.0.0.1 401 broadcast
frame-relay map ip 10.0.0.2 402 broadcast
!
router ospf 1
network 10.0.0.0 0.0.0.255 area 0
Router 4 Configuration
hostname Router 4
!
interface serial 2
ip address 10.0.0.3 255.0.0.0
ip ospf network point-to-multipoint
encapsulation frame-relay
clock rate 2000000
frame-relay map ip 10.0.0.2 301 broadcast
!
router ospf 1
network 10.0.0.0 0.0.0.255 area 0
Example: OSPF
Point-to-Multipoint with Broadcast
The following
example illustrates a point-to-multipoint network with broadcast:
interface Serial0
ip address 10.0.1.1 255.255.255.0
encapsulation frame-relay
ip ospf cost 100
ip ospf network point-to-multipoint
frame-relay map ip 10.0.1.3 202 broadcast
frame-relay map ip 10.0.1.4 203 broadcast
frame-relay map ip 10.0.1.5 204 broadcast
frame-relay local-dlci 200
!
router ospf 1
network 10.0.1.0 0.0.0.255 area 0
neighbor 10.0.1.5 cost 5
neighbor 10.0.1.4 cost 10
The following
example shows the configuration of the neighbor at 10.0.1.3:
interface serial 0
ip address 10.0.1.3 255.255.255.0
ip ospf network point-to-multipoint
encapsulation frame-relay
frame-relay local-dlci 301
frame-relay map ip 10.0.1.1 300 broadcast
no shutdown
!
router ospf 1
network 10.0.1.0 0.0.0.255 area 0
The output shown
for neighbors in the first configuration is as follows:
Device# show ip ospf neighbor
Neighbor ID Pri State Dead Time Address Interface
172.16.1.1 1 FULL/ - 00:01:50 10.0.1.5 Serial0
172.16.1.4 1 FULL/ - 00:01:47 10.0.1.4 Serial0
172.16.1.8 1 FULL/ - 00:01:45 10.0.1.3 Serial0
The route
information in the first configuration is as follows:
Device# show ip route
Codes: C - connected, S - static, I - IGRP, R - RIP, M - mobile, B - BGP
D - EIGRP, EX - EIGRP external, O - OSPF, IA - OSPF inter area
N1 - OSPF NSSA external type 1, N2 - OSPF NSSA external type 2
E1 - OSPF external type 1, E2 - OSPF external type 2, E - EGP
i - IS-IS, L1 - IS-IS level-1, L2 - IS-IS level-2, * - candidate default
U - per-user static route, o - ODR
Gateway of last resort is not set
C 1.0.0.0/8 is directly connected, Loopback0
10.0.0.0/8 is variably subnetted, 4 subnets, 2 masks
O 10.0.1.3/32 [110/100] via 10.0.1.3, 00:39:08, Serial0
C 10.0.1.0/24 is directly connected, Serial0
O 10.0.1.5/32 [110/5] via 10.0.1.5, 00:39:08, Serial0
O 10.0.1.4/32 [110/10] via 10.0.1.4, 00:39:08, Serial0
Example: OSPF
Point-to-Multipoint with Nonbroadcast
The following
example illustrates a point-to-multipoint network with nonbroadcast:
interface Serial0
ip address 10.0.1.1 255.255.255.0
ip ospf network point-to-multipoint non-broadcast
encapsulation frame-relay
no keepalive
frame-relay local-dlci 200
frame-relay map ip 10.0.1.3 202
frame-relay map ip 10.0.1.4 203
frame-relay map ip 10.0.1.5 204
no shutdown
!
router ospf 1
network 10.0.1.0 0.0.0.255 area 0
neighbor 10.0.1.3 cost 5
neighbor 10.0.1.4 cost 10
neighbor 10.0.1.5 cost 15
The following
example is the configuration for the router on the other side:
interface Serial9/2
ip address 10.0.1.3 255.255.255.0
encapsulation frame-relay
ip ospf network point-to-multipoint non-broadcast
no ip mroute-cache
no keepalive
no fair-queue
frame-relay local-dlci 301
frame-relay map ip 10.0.1.1 300
no shutdown
!
router ospf 1
network 10.0.1.0 0.0.0.255 area 0
The output shown
for neighbors in the first configuration is as follows:
Device# show ip ospf neighbor
Neighbor ID Pri State Dead Time Address Interface
172.16.1.1 1 FULL/ - 00:01:52 10.0.1.5 Serial0
172.16.1.4 1 FULL/ - 00:01:52 10.0.1.4 Serial0
172.16.1.8 1 FULL/ - 00:01:52 10.0.1.3 Serial0
Example: Variable-Length Subnet Masks
OSPF, static routes, and IS-IS support variable-length subnet masks (VLSMs). With VLSMs, you can use different masks for
the same network number on different interfaces, which allows you to conserve IP addresses and more efficiently use available
address space.
In the following example, a 30-bit subnet mask is used, leaving two bits of address space reserved for serial-line host addresses.
There is sufficient host address space for two host endpoints on a point-to-point serial link.
interface ethernet 0
ip address 172.16.10.1 255.255.255.0
! 8 bits of host address space reserved for ethernets
interface serial 0
ip address 172.16.20.1 255.255.255.252
! 2 bits of address space reserved for serial lines
! Router is configured for OSPF and assigned AS 107
router ospf 107
! Specifies network directly connected to the router
network 172.16.0.0 0.0.255.255 area 0.0.0.0
Example: Configuring OSPF NSSA
In the following
example, an Open Shortest Path First (OSPF) stub network is configured to
include OSPF Area 0 and OSPF Area 1, using five devices. Device 3 is configured as the NSSA
Autonomous System Border Router (ASBR). Device 2 configured to be the NSSA
Area Border Router (ABR). OSPF Area 1 is defined
as a Not-So-Stubby Area (NSSA).
Device 1
hostname Device1
!
interface Loopback1
ip address 10.1.0.1 255.255.255.255
!
interface Ethernet0/0
ip address 192.168.0.1 255.255.255.0
ip ospf 1 area 0
no cdp enable
!
interface Serial10/0
description Device2 interface s11/0
ip address 192.168.10.1 255.255.255.0
ip ospf 1 area 1
serial restart-delay 0
no cdp enable
!
router ospf 1
area 1 nssa
!
end
Device 2
hostname Device2
!
!
interface Loopback1
ip address 10.1.0.2 255.255.255.255
!
interface Serial10/0
description Device1 interface s11/0
no ip address
shutdown
serial restart-delay 0
no cdp enable
!
interface Serial11/0
description Device1 interface s10/0
ip address 192.168.10.2 255.255.255.0
ip ospf 1 area 1
serial restart-delay 0
no cdp enable
!
interface Serial14/0
description Device3 interface s13/0
ip address 192.168.14.2 255.255.255.0
ip ospf 1 area 1
serial restart-delay 0
no cdp enable
!
router ospf 1
area 1 nssa
!
end
Device 3
hostname Device3
!
interface Loopback1
ip address 10.1.0.3 255.255.255.255
!
interface Ethernet3/0
ip address 192.168.3.3 255.255.255.0
no cdp enable
!
interface Serial13/0
description Device2 interface s14/0
ip address 192.168.14.3 255.255.255.0
ip ospf 1 area 1
serial restart-delay 0
no cdp enable
!
router ospf 1
log-adjacency-changes
area 1 nssa
redistribute rip subnets
!
router rip
version 2
redistribute ospf 1 metric 15
network 192.168.3.0
end
Device 4
hostname Device4
!
interface Loopback1
ip address 10.1.0.4 255.255.255.255
!
interface Ethernet3/0
ip address 192.168.3.4 255.255.255.0
no cdp enable
!
interface Ethernet4/1
ip address 192.168.41.4 255.255.255.0
!
router rip
version 2
network 192.168.3.0
network 192.168.41.0
!
end
Device 5
hostname Device5
!
interface Loopback1
ip address 10.1.0.5 255.255.255.255
!
interface Ethernet0/0
ip address 192.168.0.10 255.255.255.0
ip ospf 1 area 0
no cdp enable
!
interface Ethernet1/1
ip address 192.168.11.10 255.255.255.0
ip ospf 1 area 0
!
router ospf 1
!
end
Example: OSPF NSSA Area with
RFC 3101 Disabled and RFC 1587 Active
In the following
example, the output for the
showipospf and
showipospfdatabasenssa commands shows an Open Shortest Path First
Not-So-Stubby Area (OSPF NSSA) area where RFC 3101 is disabled, RFC 1587 is
active, and an NSSA Area Border Router (ABR) device is configured as a forced
NSSA LSA translator. If RFC 3101 is disabled, the forced NSSA LSA translator
remains inactive.
Device# show ip ospf
Routing Process "ospf 1" with ID 10.0.2.1
Start time: 00:00:25.512, Time elapsed: 00:01:02.200
Supports only single TOS(TOS0) routes
Supports opaque LSA
Supports Link-local Signaling (LLS)
Supports area transit capability
Supports NSSA (compatible with RFC 1587)
Event-log enabled, Maximum number of events: 1000, Mode: cyclic
Router is not originating router-LSAs with maximum metric
Initial SPF schedule delay 5000 msecs
Minimum hold time between two consecutive SPFs 10000 msecs
Maximum wait time between two consecutive SPFs 10000 msecs
Incremental-SPF disabled
Minimum LSA interval 5 secs
Minimum LSA arrival 1000 msecs
LSA group pacing timer 240 secs
Interface flood pacing timer 33 msecs
Retransmission pacing timer 66 msecs
Number of external LSA 0. Checksum Sum 0x000000
Number of opaque AS LSA 0. Checksum Sum 0x000000
Number of DCbitless external and opaque AS LSA 0
Number of DoNotAge external and opaque AS LSA 0
Number of areas in this router is 1. 0 normal 0 stub 1 nssa
Number of areas transit capable is 0
External flood list length 0
IETF NSF helper support enabled
Cisco NSF helper support enabled
Reference bandwidth unit is 100 mbps
Area 1
Number of interfaces in this area is 1
It is a NSSA area
Configured to translate Type-7 LSAs, inactive (RFC3101 support
disabled)
Area has no authentication
SPF algorithm last executed 00:00:07.160 ago
SPF algorithm executed 3 times
Area ranges are
Number of LSA 3. Checksum Sum 0x0245F0
Number of opaque link LSA 0. Checksum Sum 0x000000
Number of DCbitless LSA 0
Number of indication LSA 0
Number of DoNotAge LSA 0
Flood list length 0
The table below describes the
showipospf display fields and their descriptions.
Table 1. show ip ospf Field
Descriptions
Field
Description
Supports NSSA
(compatible with RFC 1587)
Specifies that RFC 1587 is
active or that the OSPF NSSA area is RFC 1587 compatible.
Configured to
translate Type-7 LSAs, inactive (RFC3101 support disabled)
Specifies that OSPF NSSA area has an ABR device configured to act as a forced translator
of Type 7 LSAs. However, it is inactive because RFC 3101 is disabled
Device2# show ip ospf database nssa
Router Link States (Area 1)
LS age: 28
Options: (No TOS-capability, DC)
LS Type: Router Links
Link State ID: 10.0.2.1
Advertising Router: 10.0.2.1
LS Seq Number: 80000004
Checksum: 0x5CA2
Length: 36
Area Border Router
AS Boundary Router
Unconditional NSSA translator
Number of Links: 1
Link connected to: a Stub Network
(Link ID) Network/subnet number: 192.0.2.5
(Link Data) Network Mask: 255.255.255.0
Number of MTID metrics: 0
TOS 0 Metrics: 10
The table below describes the
showipospfdatabase nssa display fields and their descriptions.
Table 2. show ip ospf database nssa Field
Descriptions
Field
Description
Unconditional
NSSA translator
Specifies that NSSA ASBR device is a forced NSSA LSA
translator
Example: OSPF Routing and Route Redistribution
OSPF typically requires coordination among many internal routers, ABRs, and ASBRs. At a minimum, OSPF-based routers can be
configured with all default parameter values, with no authentication, and with interfaces assigned to areas.
Three types of examples follow:
The first is a simple configuration illustrating basic OSPF commands.
The second example illustrates a configuration for an internal router, ABR, and ASBRs within a single, arbitrarily assigned,
OSPF autonomous system.
The third example illustrates a more complex configuration and the application of various tools available for controlling
OSPF-based routing environments.
Example: Basic OSPF Configuration
The following example illustrates a simple OSPF configuration that enables OSPF routing process 9000, attaches Ethernet interface
0 to area 0.0.0.0, and redistributes RIP into OSPF and OSPF into RIP:
Example: Basic OSPF Configuration for Internal Router ABR and ASBRs
The following example illustrates the assignment of four area IDs to four IP address ranges. In the example, OSPF routing
process 109 is initialized, and four OSPF areas are defined: 10.9.50.0, 2, 3, and 0. Areas 10.9.50.0, 2, and 3 mask specific
address ranges, and area 0 enables OSPF for
allother networks.
router ospf 109
network 192.168.10.0 0.0.0.255 area 10.9.50.0
network 192.168.20.0 0.0.255.255 area 2
network 192.168.30.0 0.0.0.255 area 3
network 192.168.40.0 255.255.255.255 area 0
!
! Interface Ethernet0 is in area 10.9.50.0:
interface ethernet 0
ip address 192.168.10.5 255.255.255.0
!
! Interface Ethernet1 is in area 2:
interface ethernet 1
ip address 192.168.20.5 255.255.255.0
!
! Interface Ethernet2 is in area 2:
interface ethernet 2
ip address 192.168.20.7 255.255.255.0
!
! Interface Ethernet3 is in area 3:
interface ethernet 3
ip address 192.169.30.5 255.255.255.0
!
! Interface Ethernet4 is in area 0:
interface ethernet 4
ip address 192.168.40.1 255.255.255.0
!
! Interface Ethernet5 is in area 0:
interface ethernet 5
ip address 192.168.40.12 255.255.0.0
Each
networkarea router configuration command is evaluated sequentially, so the order of these commands in the configuration is important.
The Cisco software sequentially evaluates the address/wildcard-mask pair for each interface. See the
networkarea command page in the
Cisco IOS IP Routing: OSPF Command Reference for more information.
Consider the first
networkarea command. Area ID 10.9.50.0 is configured for the interface on which subnet 192.168.10.0 is located. Assume that a match is
determined for Ethernet interface 0. Ethernet interface 0 is attached to area 10.9.50.0 only.
The second
networkarea command is evaluated next. For area 2, the same process is then applied to all interfaces (except Ethernet interface 0).
Assume that a match is determined for Ethernet interface 1. OSPF is then enabled for that interface, and Ethernet interface
1 is attached to area 2.
This process of attaching interfaces to OSPF areas continues for all
networkarea commands. Note that the last
networkarea command in this example is a special case. With this command, all available interfaces (not explicitly attached to another
area) are attached to area 0.
Example: Complex Internal Router with ABR and ASBR
The following example outlines a configuration for several routers within a single OSPF autonomous system. The figure below
provides a general network map that illustrates this sample configuration.
In this configuration, five routers are configured with OSPF:
Router A and Router B are both internal routers within area 1.
Router C is an OSPF ABR. Note that for Router C, Area 1 is assigned to E3 and area 0 is assigned to S0.
Router D is an internal router in area 0 (backbone area). In this case, both
network router configuration commands specify the same area (area 0, or the backbone area).
Router E is an OSPF ASBR. Note that BGP routes are redistributed into OSPF and that these routes are advertised by OSPF.
Note
You do not need to include definitions of all areas in an OSPF autonomous system in the configuration of all routers in the
autonomous system. Only the
directly connected areas must be defined. In the example that follows, routes in area 0 are learned by the routers in area 1 (Router
A and Router B) when the ABR (Router C) injects summary LSAs into area 1.
The OSPF domain in BGP autonomous system 109 is connected to the outside world via the BGP link to the external peer at IP
address 10.0.0.6. Sample configurations follow.
Following is the sample configuration for the general network map shown in the figure above.
Router A Configuration—Internal Router
interface ethernet 1
ip address 192.168.1.1 255.255.255.0
router ospf 1
network 192.168.0.0 0.0.255.255 area 1
Router B Configuration—Internal Router
interface ethernet 2
ip address 192.168.1.2 255.255.255.0
router ospf 202
network 192.168.0.0 0.0.255.255 area 1
Router C Configuration—ABR
interface ethernet 3
ip address 192.168.1.3 255.255.255.0
interface serial 0
ip address 192.168.2.3 255.255.255.0
router ospf 999
network 192.168.1.0 0.0.0.255 area 1
network 192.168.2.0 0.0.0.255 area 0
Router D Configuration—Internal Router
interface ethernet 4
ip address 10.0.0.4 255.0.0.0
interface serial 1
ip address 192.168.2.4 255.255.255.0
router ospf 50
network 192.168.2.0 0.0.0.255 area 0
network 10.0.0.0 0.255.255.255 area 0
Router E Configuration—ASBR
interface ethernet 5
ip address 10.0.0.5 255.0.0.0
interface serial 2
ip address 172.16.1.5 255.255.255.0
router ospf 65001
network 10.0.0.0 0.255.255.255 area 0
redistribute bgp 109 metric 1 metric-type 1
router bgp 109
network 192.168.0.0
network 10.0.0.0
neighbor 172.16.1.6 remote-as 110
Example: Complex OSPF Configuration for ABR
The following sample configuration accomplishes several tasks in setting up an ABR. These tasks can be split into two general
categories:
Basic OSPF configuration
Route redistribution
The specific tasks outlined in this configuration are detailed briefly in the following descriptions. The figure below illustrates
the network address ranges and area assignments for the interfaces.
The basic configuration tasks in this example are as follows:
Configure address ranges for Ethernet interface 0 through Ethernet interface 3.
Enable OSPF on each interface.
Set up an OSPF authentication password for each area and network.
Assign link-state metrics and other OSPF interface configuration options.
Create a
stubarea with area ID 36.0.0.0. (Note that the
authentication and
stub options of the
area router configuration command are specified with separate
area command entries, but can be merged into a single
area command.)
Specify the backbone area (area 0).
Configuration tasks associated with redistribution are as follows:
Redistribute IGRP and RIP into OSPF with various options set (including including
metric-type,
metric,
tag, and
subnet).
Redistribute IGRP and OSPF into RIP.
The following is a sample OSPF configuration:
interface ethernet 0
ip address 192.0.2.201 255.255.255.0
ip ospf authentication-key abcdefgh
ip ospf cost 10
!
interface ethernet 1
ip address 172.19.251.202 255.255.255.0
ip ospf authentication-key ijklmnop
ip ospf cost 20
ip ospf retransmit-interval 10
ip ospf transmit-delay 2
ip ospf priority 4
!
interface ethernet 2
ip address 172.19.254.2 255.255.255.0
ip ospf authentication-key abcdefgh
ip ospf cost 10
!
interface ethernet 3
ip address 10.56.0.0 255.255.0.0
ip ospf authentication-key ijklmnop
ip ospf cost 20
ip ospf dead-interval 80
In the following configuration, OSPF is on network 172.16.0.0:
router ospf 201
network 10.10.0.0 0.255.255.255 area 10.10.0.0
network 192.42.110.0 0.0.0.255 area 192.42.110.0
network 172.16.0.0 0.0.255.255 area 0
area 0 authentication
area 10.10.0.0 stub
area 10.10.0.0 authentication
area 10.10.0.0 default-cost 20
area 192.42.110.0 authentication
area 10.10.0.0 range 10.10.0.0 255.0.0.0
area 192.42.110.0 range 192.42.110.0 255.255.255.0
area 0 range 172.16.251.0 255.255.255.0
area 0 range 172.16.254.0 255.255.255.0
redistribute igrp 200 metric-type 2 metric 1 tag 200 subnets
redistribute rip metric-type 2 metric 1 tag 200
In the following configuration, IGRP autonomous system 200 is on 192.0.2.1:
The examples in this section illustrate the use of redistribution, with and without route maps. Examples from the IP and
Connectionless Network Service (CLNS) routing protocols are given.
The following example redistributes all OSPF routes into IGRP:
router igrp 109
redistribute ospf 110
The following example redistributes RIP routes with a hop count equal to 1 into OSPF. These routes will be redistributed
into OSPF as external LSAs with a metric of 5, a metric type of Type 1, and a tag equal to 1.
router ospf 109
redistribute rip route-map rip-to-ospf
!
route-map rip-to-ospf permit
match metric 1
set metric 5
set metric-type type1
set tag 1
The following example redistributes OSPF learned routes with tag 7 as a RIP metric of 15:
router rip
redistribute ospf 109 route-map 5
!
route-map 5 permit
match tag 7
set metric 15
The following example redistributes OSPF intra-area and interarea routes with next-hop routers on serial interface 0 into
BGP with an INTER_AS metric of 5:
router bgp 109
redistribute ospf 109 route-map 10
!
route-map 10 permit
match route-type internal
match interface serial 0
set metric 5
The following example redistributes two types of routes into the integrated IS-IS routing table (supporting both IP and CLNS).
The first type is OSPF external IP routes with tag 5; these routes are inserted into Level 2 IS-IS link state packets (LSPs)
with a metric of 5. The second type is ISO-IGRP derived CLNS prefix routes that match CLNS access list 2000; these routes
will be redistributed into IS-IS as Level 2 LSPs with a metric of 30.
router isis
redistribute ospf 109 route-map 2
redistribute iso-igrp nsfnet route-map 3
!
route-map 2 permit
match route-type external
match tag 5
set metric 5
set level level-2
!
route-map 3 permit
match address 2000
set metric 30
With the following configuration, OSPF external routes with tags 1, 2, 3, and 5 are redistributed into RIP with metrics of
1, 1, 5, and 5, respectively. The OSPF routes with a tag of 4 are not redistributed.
router rip
redistribute ospf 109 route-map 1
!
route-map 1 permit
match tag 1 2
set metric 1
!
route-map 1 permit
match tag 3
set metric 5
!
route-map 1 deny
match tag 4
!
route map 1 permit
match tag 5
set metric 5
In the following configuration, a RIP-learned route for network 192.168.0.0 and an ISO-IGRP-learned route with prefix 49.0001.0002
are redistributed into an IS-IS Level 2 LSP with a metric of 5:
router isis
redistribute rip route-map 1
redistribute iso-igrp remote route-map 1
!
route-map 1 permit
match ip address 1
match clns address 2
set metric 5
set level level-2
!
access-list 1 permit 192.168.0.0 0.0.255.255
clns filter-set 2 permit 49.0001.0002...
The following configuration example illustrates how a route map is referenced by the
default-information router configuration command. This type of reference is calledconditionaldefaultorigination. OSPF will originate the default route (network 0.0.0.0) with a Type 2 metric of 5 if 172.16.0.0 is in the routing table.
Note
Only routes external to the OSPF process can be used for tracking, such as non-OSPF routes or OSPF routes from a separate
OSPF process.
route-map ospf-default permit
match ip address 1
set metric 5
set metric-type type-2
!
access-list 1 permit 172.16.0.0 0.0.255.255
!
router ospf 109
default-information originate route-map ospf-default
Example: Changing the OSPF Administrative Distances
The following configuration changes the external distance to 200, making it less trustworthy. The figure below illustrates
the example.
The following configuration allows OSPF over an on-demand circuit, as shown in the figure below. Note that the on-demand
circuit is defined on one side only (BRI 0 on Router A); it is not required to be configured on both sides.
Router A Configuration
username RouterB password 7 060C1A2F47
isdn switch-type basic-5ess
ip routing
!
interface TokenRing0
ip address 192.168.50.5 255.255.255.0
no shutdown
!
interface BRI0
no cdp enable
description connected PBX 1485
ip address 192.168.45.30 255.255.255.0
encapsulation ppp
ip ospf demand-circuit
dialer map ip 192.0.2.6 name RouterB broadcast 61484
dialer-group 1
ppp authentication chap
no shutdown
!
router ospf 100
network 192.168.45.0 0.0.0.255 area 0
network 192.168.45.50 0.0.0.255 area 0
!
dialer-list 1 protocol ip permit
Router B Configuration
username RouterA password 7 04511E0804
isdn switch-type basic-5ess
ip routing
!
interface Ethernet0
ip address 192.168.50.16 255.255.255.0
no shutdown
!
interface BRI0
no cdp enable
description connected PBX 1484
ip address 192.168.45.17 255.255.255.0
encapsulation ppp
dialer map ip 192.168.45.19 name RouterA broadcast 61485
dialer-group 1
ppp authentication chap
no shutdown
!
router ospf 100
network 192.168.45.0 0.0.0.255 area 0
network 192.168.45.50 0.0.0.255 area 0
!
dialer-list 1 protocol ip permit
Example: LSA Group Pacing
The following example changes the OSPF pacing between LSA groups to 60 seconds:
router ospf
timers pacing lsa-group 60
Example: Blocking OSPF LSA Flooding
The following example prevents flooding of OSPF LSAs to broadcast, nonbroadcast, or point-to-point networks reachable through
Ethernet interface 0:
interface ethernet 0
ip ospf database-filter all out
The following example prevents flooding of OSPF LSAs to point-to-multipoint networks to the neighbor at IP address 10.10.10.45:
router ospf 109
neighbor 10.10.10.45 database-filter all out
Example: Ignoring MOSPF LSA Packets
The following example configures the router to suppress the sending of syslog messages when it receives MOSPF packets:
router ospf 109
ignore lsa mospf
Additional References for
OSPF Not-So-Stubby Areas (NSSA)
The Cisco
Support and Documentation website provides online resources to download
documentation, software, and tools. Use these resources to install and
configure the software and to troubleshoot and resolve technical issues with
Cisco products and technologies. Access to most tools on the Cisco Support and
Documentation website requires a Cisco.com user ID and password.
The following table provides release information about the feature or features described in this module. This table lists
only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise,
subsequent releases of that software release train also support that feature.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco
Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Table 3. Feature Information for
OSPF
Feature
Name
Releases
Feature
Information
OSPF
OSPF is an
IGP developed by the OSPF working group of the IETF. Designed expressly for IP
networks, OSPF supports IP subnetting and tagging of externally derived routing
information. OSPF also allows packet authentication and uses IP multicast when
sending and receiving packets.