Configuring OSPFv3

This chapter describes how to configure Open Shortest Path First version 3 (OSPFv3) for IPv6 networks on the Cisco NX-OS device.

This chapter includes the following sections:

About OSPFv3

OSPFv3 is an IETF link-state protocol (see Overview section). An OSPFv3 router sends a special message, called a hello packet, out each OSPF-enabled interface to discover other OSPFv3 neighbor routers. Once a neighbor is discovered, the two routers compare information in the Hello packet to determine if the routers have compatible configurations. The neighbor routers attempt to establish adjacency, which means that the routers synchronize their link-state databases to ensure that they have identical OSPFv3 routing information. Adjacent routers share link-state advertisements (LSAs) that include information about the operational state of each link, the cost of the link, and any other neighbor information. The routers then flood these received LSAs out every OSPF-enabled interface so that all OSPFv3 routers eventually have identical link-state databases. When all OSPFv3 routers have identical link-state databases, the network is converged (see the Convergence section). Each router then uses Dijkstra’s Shortest Path First (SPF) algorithm to build its route table.

You can divide OSPFv3 networks into areas. Routers send most LSAs only within one area, which reduces the CPU and memory requirements for an OSPF-enabled router.

OSPFv3 supports IPv6. For information about OSPF for IPv4, see Configuring OSPFv2.

Comparison of OSPFv3 and OSPFv2

Much of the OSPFv3 protocol is the same as in OSPFv2. OSPFv3 is described in RFC 2740.

The key differences between the OSPFv3 and OSPFv2 protocols are as follows:

  • OSPFv3 expands on OSPFv2 to provide support for IPv6 routing prefixes and the larger size of IPv6 addresses.

  • LSAs in OSPFv3 are expressed as prefix and prefix length instead of address and mask.

  • The router ID and area ID are 32-bit numbers with no relationship to IPv6 addresses.

  • OSPFv3 uses link-local IPv6 addresses for neighbor discovery and other features.

  • OSPFv3 can use the IPv6 authentication trailer (RFC 6506) or IPSec (RFC 4552) for authentication. However, Cisco NX-OS does not support RFC 6506.

  • OSPFv3 redefines LSA types.

Hello Packet

OSPFv3 routers periodically send Hello packets on every OSPF-enabled interface. The hello interval determines how frequently the router sends these Hello packets and is configured per interface. OSPFv3 uses Hello packets for the following tasks:

  • Neighbor discovery

  • Keepalives

  • Bidirectional communications

  • Designated router election (see the Designated Routers section)

The Hello packet contains information about the originating OSPFv3 interface and router, including the assigned OSPFv3 cost of the link, the hello interval, and optional capabilities of the originating router. An OSPFv3 interface that receives these Hello packets determines if the settings are compatible with the receiving interface settings. Compatible interfaces are considered neighbors and are added to the neighbor table (see the Neighbors section).

Hello packets also include a list of router IDs for the routers that the originating interface has communicated with. If the receiving interface sees its own router ID in this list, then bidirectional communication has been established between the two interfaces.

OSPFv3 uses Hello packets as a keepalive message to determine if a neighbor is still communicating. If a router does not receive a Hello packet by the configured dead interval (usually a multiple of the hello interval), then the neighbor is removed from the local neighbor table.

Neighbors

An OSPFv3 interface must have a compatible configuration with a remote interface before the two can be considered neighbors. The two OSPFv3 interfaces must match the following criteria:

  • Hello interval

  • Dead interval

  • Area ID (see the Areas section)

  • Optional capabilities

If there is a match, the information is entered into the neighbor table:

  • Neighbor ID—The router ID of the neighbor router.

  • Priority—Priority of the neighbor router. The priority is used for designated router election (see the Designated Routers section).

  • State—Indication of whether the neighbor has just been heard from, is in the process of setting up bidirectional communications, is sharing the link-state information, or has achieved full adjacency.

  • Dead time—Indication of how long since the last Hello packet was received from this neighbor.

  • Link-local IPv6 Address—The link-local IPv6 address of the neighbor.

  • Designated Router—Indication of whether the neighbor has been declared the designated router or backup designated router (see the Designated Routers section).

  • Local interface—The local interface that received the Hello packet for this neighbor.

When the first Hello packet is received from a new neighbor, the neighbor is entered into the neighbor table in the initialization state. Once bidirectional communication is established, the neighbor state becomes two-way. ExStart and exchange states come next, as the two interfaces exchange their link-state database. Once this is all complete, the neighbor moves into the full state, which signifies full adjacency. If the neighbor fails to send any Hello packets in the dead interval, then the neighbor is moved to the down state and is no longer considered adjacent.

Adjacency

Not all neighbors establish adjacency. Depending on the network type and designated router establishment, some neighbors become fully adjacent and share LSAs with all their neighbors, while other neighbors do not. For more information, see the Designated Routers section.

Adjacency is established using Database Description (DD) packets, Link State Request (LSR) packets, and Link State Update (LSU) packets in OSPFv3. The Database Description packet includes the LSA headers from the link-state database of the neighbor (see the Link-State Database section). The local router compares these headers with its own link-state database and determines which LSAs are new or updated. The local router sends an LSR packet for each LSA that it needs new or updated information on. The neighbor responds with an LSU packet. This exchange continues until both routers have the same link-state information.

Designated Routers

Networks with multiple routers present a unique situation for OSPFv3. If every router floods the network with LSAs, the same link-state information is sent from multiple sources. Depending on the type of network, OSPFv3 might use a single router, the designated router (DR), to control the LSA floods and represent the network to the rest of the OSPFv3 area (see the Areas section). If the DR fails, OSPFv3 selects a backup designated router (BDR). If the DR fails, OSPFv3 uses the BDR.

Network types are as follows:

  • Point-to-point—A network that exists only between two routers. All neighbors on a point-to-point network establish adjacency and there is no DR.

  • Broadcast—A network with multiple routers that can communicate over a shared medium that allows broadcast traffic, such as Ethernet. OSPFv3 routers establish a DR and BDR that controls LSA flooding on the network. OSPFv3 uses the well-known IPv6 multicast addresses, FF02::5, and a MAC address of 0100.5300.0005 to communicate with neighbors.

The DR and BDR are selected based on the information in the Hello packet. When an interface sends a Hello packet, it sets the priority field and the DR and BDR field if it knows who the DR and BDR are. The routers follow an election procedure based on which routers declare themselves in the DR and BDR fields and the priority field in the Hello packet. As a final determinant, OSPFv3 chooses the highest router IDs as the DR and BDR.

All other routers establish adjacency with the DR and the BDR and use the IPv6 multicast address FF02::6 to send LSA updates to the DR and BDR. The following figure shows this adjacency relationship between all routers and the DR.

DRs are based on a router interface. A router might be the DR for one network and not for another network on a different interface.

Figure 1. DR in Multi-Access Network


Areas

You can limit the CPU and memory requirements that OSPFv3 puts on the routers by dividing an OSPFv3 network into areas. An area is a logical division of routers and links within an OSPFv3 domain that creates separate subdomains. LSA flooding is contained within an area, and the link-state database is limited to links within the area. You can assign an area ID to the interfaces within the defined area. The Area ID is a 32-bit value that can be expressed as a number or in dotted decimal notation, such as 10.2.3.1.

Cisco NX-OS always displays the area in dotted decimal notation.

If you define more than one area in an OSPFv3 network, you must also define the backbone area, which has the reserved area ID of 0. If you have more than one area, then one or more routers become area border routers (ABRs). An ABR connects to both the backbone area and at least one other defined area.

Figure 2. OSPFv3 Areas

The ABR has a separate link-state database for each area which it connects to. The ABR sends Inter-Area Prefix (type 3) LSAs (see the Route Summarization section) from one connected area to the backbone area. The backbone area sends summarized information about one area to another area. In the figure, Area 0 sends summarized information about Area 5 to Area 3.

OSPFv3 defines one other router type: the autonomous system boundary router (ASBR). This router connects an OSPFv3 area to another autonomous system. An autonomous system is a network controlled by a single technical administration entity. OSPFv3 can redistribute its routing information into another autonomous system or receive redistributed routes from another autonomous system. For more information, see the Advanced Features section.

Link-State Advertisement

OSPFv3 uses link-state advertisements (LSAs) to build its routing table.

Link-State Advertisement Types

OSPFv3 uses link-state advertisements (LSAs) to build its routing table.

The table shows the LSA types that are supported by Cisco NX-OS.

Type

Names

Description

1

Router LSA

LSA sent by every router. This LSA includes the state and cost of all links but does not include prefix information. Router LSAs trigger an SPF recalculation. Router LSAs are flooded to the local OSPFv3 area.

2

Network LSA

LSA sent by the DR. This LSA lists all routers in the multi-access network but does not include prefix information. Network LSAs trigger an SPF recalculation. See the Designated Routers section.

3

Inter-Area Prefix LSA

LSA sent by the area border router to an external area for each destination in local area. This LSA includes the link cost from the border router to the local destination. See the Areas section.

4

Inter-Area Router LSA

LSA sent by the area border router to an external area. This LSA advertises the link cost to the ASBR only. See the Areas section.

5

AS External LSA

LSA generated by the ASBR. This LSA includes the link cost to an external autonomous system destination. AS External LSAs are flooded throughout the autonomous system. See the Areas section.

7

Type-7 LSA

LSA generated by the ASBR within an NSSA. This LSA includes the link cost to an external autonomous system destination. Type-7 LSAs are flooded only within the local NSSA. See the Areas section.

8

Link LSA

LSA sent by every router, using a link-local flooding scope. (see the Flooding and LSA Group Pacing section). This LSA includes the link-local address and IPv6 prefixes for this link.

9

Intra-Area Prefix LSA

LSA sent by every router. This LSA includes any prefix or link state changes. Intra-Area Prefix LSAs are flooded to the local OSPFv3 area. This LSA does not trigger an SPF recalculation.

11

Grace LSA

LSA sent by a restarting router, using a link-local flooding scope. This LSA is used for a graceful restart of OSPFv3. See the High Availability and Graceful Restart section.

Link Cost

Each OSPFv3 interface is assigned a link cost. The cost is an arbitrary number. By default, Cisco NX-OS assigns a cost that is the configured reference bandwidth divided by the interface bandwidth. By default, the reference bandwidth is 40 Gbps. The link cost is carried in the LSA updates for each link.

Flooding and LSA Group Pacing

OSPFv3 floods LSA updates to different sections of the network, depending on the LSA type. OSPFv3 uses the following flooding scopes:

  • Link-local—LSA is flooded only on the local link. Used for Link LSAs and Grace LSAs.

  • Area-local—LSA is flooded throughout a single OSPF area only. Used for Router LSAs, Network LSAs, Inter-Area-Prefix LSAs, Inter-Area-Router LSAs, and Intra-Area-Prefix LSAs.

  • AS scope—LSA is flooded throughout the routing domain. An AS scope is used for AS External LSAs.

LSA flooding guarantees that all routers in the network have identical routing information. LSA flooding depends on the OSPFv3 area configuration (see the Areas section). The LSAs are flooded based on the link-state refresh time (every 30 minutes by default). Each LSA has its own link-state refresh time.

You can control the flooding rate of LSA updates in your network by using the LSA group pacing feature. LSA group pacing can reduce high CPU or buffer utilization. This feature groups LSAs with similar link-state refresh times to allow OSPFv3 to pack multiple LSAs into an OSPFv3 Update message.

By default, LSAs with link-state refresh times within 10 seconds of each other are grouped together. You should lower this value for large link-state databases or raise it for smaller databases to optimize the OSPFv3 load on your network.

Link-State Database

Each router maintains a link-state database for the OSPFv3 network. This database contains all the collected LSAs and includes information on all the routes through the network. OSPFv3 uses this information to calculate the bast path to each destination and populates the routing table with these best paths.

LSAs are removed from the link-state database if no LSA update has been received within a set interval, called the MaxAge. Routers flood a repeat of the LSA every 30 minutes to prevent accurate link-state information from being aged out. Cisco NX-OS supports the LSA grouping feature to prevent all LSAs from refreshing at the same time. For more information, see the Flooding and LSA Group Pacing section.

Multi-Area Adjacency

OSPFv3 multi-area adjacency allows you to configure a link on the primary interface that is in more than one area. This link becomes the preferred intra-area link in those areas. Multi-area adjacency establishes a point-to-point unnumbered link in an OSPFv3 area that provides a topological path for that area. The primary adjacency uses the link to advertise an unnumbered point-to-point link in the Router LSA for the corresponding area when the neighbor state is full.

The multi-area interface exists as a logical construct over an existing primary interface for OSPF; however, the neighbor state on the primary interface is independent of the multi-area interface. The multi-area interface establishes a neighbor relationship with the corresponding multi-area interface on the neighboring router. See the Configuring Multi-Area Adjacency section for more information.

OSPFv3 and the IPv6 Unicast RIB

OSPFv3 runs the Dijkstra shortest path first algorithm on the link-state database. This algorithm selects the best path to each destination based on the sum of all the link costs for each link in the path. The shortest path for each destination is then put in the OSPFv3 route table. When the OSPFv3 network is converged, this route table feeds into the IPv6 unicast Routing Information Base (RIB). OSPFv3 communicates with the IPv6 unicast RIB to do the following:

  • Add or remove routes

  • Handle route redistribution from other protocols

  • Provide convergence updates to remove stale OSPFv3 routes and for stub router advertisements (see the Multiple OSPFv3 Instances section).

OSPFv3 also runs a modified Dijkstra algorithm for fast recalculation for Inter-Area Prefix, Inter-Area Router, AS-External, type-7, and Intra-Area Prefix (type 3, 4, 5, 7, 8) LSA changes.

Address Family Support

Cisco NX-OS supports multiple address families, such as unicast IPv6 and multicast IPv6. OSPFv3 features that are specific to an address family are as follows:

  • Default routes

  • Route summarization

  • Route redistribution

  • Filter lists for border routers

  • SPF optimization

Use the address-family ipv6 unicast command to enter the IPv6 unicast address family configuration mode when configuring these features.

Authentication

You can configure authentication on OSPFv3 messages to prevent unauthorized or invalid routing updates in your network.

RFC 4552 provides authentication to OSPFv3 using an IPv6 Authentication Header (AH) or Encapsulating Security Payload (ESP) extension header. Cisco NX-OS supports RFC 4552 by using the IPv6 AH header to authenticate OSPFv3 packets.

Cisco NX-OS supports the IP Security (IPSec) authentication method and the Message Digest 5 (MD5) or Secure Hash Algorithm 1 (SHA-1) algorithm to authenticate OSPFv3 packets. OSPFv3 IPSec authentication supports static keys using commands.

Advanced Features

Cisco NX-OS supports advanced OSPFv3 features that enhance the usability and scalability of OSPFv3 in the network.

Stub Area

You can limit the amount of external routing information that floods an area by making it a stub area. A stub area is an area that does not allow AS External (type 5) LSAs (see the Link-State Advertisement section). These LSAs are usually flooded throughout the local autonomous system to propagate external route information. Stub areas have the following requirements:

  • All routers in the stub area are stub routers. See the Stub Routing section.

  • No ASBR routers exist in the stub area.

  • You cannot configure virtual links in the stub area.

The figure shows an example an OSPFv3 autonomous system where all routers in area 0.0.0.10 have to go through the ABR to reach external autonomous systems. Area 0.0.0.10 can be configured as a stub area.

Figure 3. Stub Area


Stub areas use a default route for all traffic that needs to go through the backbone area to the external autonomous system. The default route is an Inter-Area-Prefix LSA with the prefix length set to 0 for IPv6.

Not-So-Stubby Area

A Not-So-Stubby Area (NSSA) is similar to the stub area, except that an NSSA allows you to import autonomous system external routes within an NSSA using redistribution. The NSSA ASBR redistributes these routes and generates type-7 LSAs that it floods throughout the NSSA. You can optionally configure the ABR that connects the NSSA to other areas to translate this type-7 LSA to AS External (type 5) LSAs. The ABR then floods these AS External LSAs throughout the OSPFv3 autonomous system. Summarization and filtering are supported during the translation. See the Link-State Advertisement section for details on type-7 LSAs.

You can, for example, use NSSA to simplify administration if you are connecting a central site using OSPFv3 to a remote site that is using a different routing protocol. Before NSSA, the connection between the corporate site border router and a remote router could not be run as an OSPFv3 stub area because routes for the remote site could not be redistributed into a stub area. With NSSA, you can extend OSPFv3 to cover the remote connection by defining the area between the corporate router and remote router as an NSSA. (see the Configuring NSSA section).

The backbone Area 0 cannot be an NSSA


Note


Beginning with Cisco NX-OS Release 9.3(1), OSPF became compliant with RFC 3101 section 2.5(3). When an Area Border Router attached to a Not-so-Stubby Area receives a default route LSA with P-bit clear, it should be ignored. OSPF had been previously adding the default route under these conditions.

If you have already designed your networks with RFC non-compliant behavior and expect a default route to be added on NSSA ABR, you will see a change in behavior when you upgrade to Cisco NX-OS Release 9.3(1) and later.

If you decide to continue with the old behavior, you have the option to enable it with the default-route nssa-abr pbit-clear command. This command was implemented in Cisco NX-OS Release 9.3(1).


Virtual Links

Virtual links allow you to connect an OSPFv3 area ABR to a backbone area ABR when a direct physical connection is not available. The figure shows a virtual link that connects Area 3 to the backbone area through Area 5.

Figure 4. Virtual Links


You can also use virtual links to temporarily recover from a partitioned area, which occurs when a link within the area fails, isolating part of the area from reaching the designated ABR to the backbone area.

Route Redistribution

OSPFv3 can learn routes from other routing protocols by using route redistribution. See the Route Redistribution Overview section. You configure OSPFv3 to assign a link cost for these redistributed routes or a default link cost for all redistributed routes.

Route redistribution uses route maps to control which external routes are redistributed. You must configure a route map with the redistribution to control which routes are passed into OSPFv3. A route map allows you to filter routes based on attributes such as the destination, origination protocol, route type, route tag, and so on. You can use route maps to modify parameters in the AS External (type 5) and NSSA External (type 7) LSAs before these external routes are advertised in the local OSPFv3 autonomous system. For more information, see Configuring Route Policy Manager.

Route Summarization

Because OSPFv3 shares all learned routes with every OSPF-enabled router, you might want to use route summarization to reduce the number of unique routes that are flooded to every OSPF-enabled router. Route summarization simplifies route tables by replacing more-specific addresses with an address that represents all the specific addresses. For example, you can replace 2010:11:22:0:1000::1 and 2010:11:22:0:2000:679:1 with one summary address, 2010:11:22::/32.

Typically, you would summarize at the boundaries of area border routers (ABRs). Although you could configure summarization between any two areas, it is better to summarize in the direction of the backbone so that the backbone receives all the aggregate addresses and injects them, already summarized, into other areas. The two types of summarization are as follows:

  • Inter-area route summarization

  • External route summarization

You configure inter-area route summarization on ABRs, summarizing routes between areas in the autonomous system. To take advantage of summarization, assign network numbers in areas in a contiguous way to be able to lump these addresses into one range.

External route summarization is specific to external routes that are injected into OSPFv3 using route redistribution. You should make sure that external ranges that are being summarized are contiguous. Summarizing overlapping ranges from two different routers could cause packets to be sent to the wrong destination. Configure external route summarization on ASBRs that are redistributing routes into OSPF.

When you configure a summary address, Cisco NX-OS automatically configures a discard route for the summary address to prevent routing black holes and route loops.

High Availability and Graceful Restart

Cisco NX-OS provides a multilevel high-availability architecture. OSPFv3 supports stateful restart, which is also referred to as non-stop routing (NSR). If OSPFv3 experiences problems, it attempts to restart from its previous run-time state. The neighbors do not register any neighbor event in this case. If the first restart is not successful and another problem occurs, OSPFv3 attempts a graceful restart.

A graceful restart, or non-stop forwarding (NSF), allows OSPFv3 to remain in the data forwarding path through a process restart. When OSPFv3 needs to perform a graceful restart, it sends a link-local Grace (type 11) LSA. This restarting OSPFv3 platform is called NSF capable.

The Grace LSA includes a grace period, which is a specified time that the neighbor OSPFv3 interfaces hold onto the LSAs from the restarting OSPFv3 interface. (Typically, OSPFv3 tears down the adjacency and discards all LSAs from a down or restarting OSPFv3 interface.) The participating neighbors, which are called NSF helpers, keep all LSAs that originate from the restarting OSPFv3 interface as if the interface was still adjacent.

When the restarting OSPFv3 interface is operational again, it rediscovers its neighbors, establishes adjacency, and starts sending its LSA updates again. At this point, the NSF helpers recognize that the graceful restart has finished.

Stateful restart is used in the following scenarios:

  • First recovery attempt after the process experiences problems

  • User-initiated switchover using the system switchover command

Graceful restart is used in the following scenarios:

  • Second recovery attempt after the process experiences problems within a 4-minute interval

  • Manual restart of the process using the restart ospfv3 command

  • Active supervisor removal

  • Active supervisor reload using the reload module active-sup command

Multiple OSPFv3 Instances

Cisco NX-OS supports multiple instances of the OSPFv3 protocol. By default, every instance uses the same system router ID. You must manually configure the router ID for each instance if the instances are in the same OSPFv3 autonomous system. For the number of supported OSPFv3 instances, see the Cisco Nexus 9000 Series NX-OS Verified Scalability Guide.

The OSPFv3 header includes an instance ID field to identify that OSPFv3 packet for a particular OSPFv3 instance. You can assign the OSPFv3 instance. The interface drops all OSPFv3 packets that do not have a matching OSPFv3 instance ID in the packet header.

Cisco NX-OS allows only one OSPFv3 instance on an interface.

SPF Optimization

Cisco NX-OS optimizes the SPF algorithm in the following ways:

  • Partial SPF for Network (type 2) LSAs, Inter-Area Prefix (type 3) LSAs, and AS External (type 5) LSAs—When there is a change on any of these LSAs, Cisco NX-OS performs a faster partial calculation rather than running the whole SPF calculation.

  • SPF timers—You can configure different timers for controlling SPF calculations. These timers include exponential backoff for subsequent SPF calculations. The exponential backoff limits the CPU load of multiple SPF calculations.

BFD

This feature supports bidirectional forwarding detection (BFD) for IPv6. BFD is a detection protocol that provides fast forwarding-path failure detection times. BFD provides subsecond failure detection between two adjacent devices and can be less CPU-intensive than protocol hello messages, because some of the BFD load can be distributed onto the data plane on supported modules. See the Cisco Nexus 9000 Series NX-OS Interfaces Configuration Guide for more information.

Virtualization Support

Cisco NX-OS supports multiple process instances of OSPFv3. Each OSPFv3 instance can support multiple virtual routing and forwarding (VRF) instances, up to the system limit. For the number of supported OSPFv3 instances, see the Cisco Nexus 9000 Series NX-OS Verified Scalability Guide.

Prerequisites for OSPFv3

OSPFv3 has the following prerequisites:

  • You must be familiar with routing fundamentals to configure OSPFv3.

  • You must be logged on to the switch.

  • You have configured at least one interface for IPv6 that is capable of communicating with a remote OSPFv3 neighbor.

  • You have installed the Enterprise Services license.

  • You have completed the OSPFv3 network strategy and planning for your network. For example, you must decide whether multiple areas are required.

  • You have enabled OSPF (see the Enabling OSPFv3 section).

  • You are familiar with IPv6 addressing and basic configuration. See Configuring IPv6 for information on IPv6 routing and addressing.

Guidelines and Limitations for OSPFv3

OSPFv3 has the following configuration guidelines and limitations:

  • The graceful-restart planned-only command under OSPFv2 on reload converts to the graceful-restart command.

    This is not causing any impact on the functionality. If the graceful-restart planned-only is not in the configuration, this problem is not applicable for that device.

    This occurs when the Cisco NX-OS release is 9.3(2) and CSCvs57583 is not included in the release. A workaround is to unconfigure the graceful-restart command and reconfigure the old command.

  • Names in the prefix-list are case-insensitive. We recommend using unique names. Do not use the same name by modifying uppercase and lowercase characters. For example, CTCPrimaryNetworks and CtcPrimaryNetworks are not two different entries.

  • If you enter the no graceful-restart planned only command, graceful restart is disabled.

  • Cisco NX-OS displays areas in dotted decimal notation regardless of whether you enter the area in decimal or dotted decimal notation.

  • If you configure OSPFv3 in a virtual port channel (vPC) environment, use the following timer commands in router configuration mode on the core switch to ensure fast OSPF convergence when a vPC peer link is shut down:

    switch(config-router)# timers throttle spf 1 50 50
    switch(config-router)# timers lsa-arrival 10
  • In scaled scenarios, when the number of interfaces and link-state advertisements in an OSPF process is large, the snmp-walk on OSPF MIB objects is expected to time out with a small-values timeout at the SNMP agent. If you observe a timeout on the querying SNMP agent while polling OSPF MIB objects, increase the timeout value on the polling SNMP agent.

  • The following guidelines and limitations apply to the administrative distance feature:

    • When an OSPF route has two or more equal cost paths, configuring the administrative distance is non-deterministic for the match ip route-source command.

    • For matching route sources in OSPFv3 routes, you must configure match ip route-source instead of match ipv6 route-source because the route sources and router IDs for OSPFv3 are IPv4 addresses.

    • Configuring the administrative distance is supported only for the match route-type , match ipv6 address prefix-list , and match ip route-source prefix-list commands. The other match statements are ignored.

    • The discard route is always assigned an administrative distance of 220. No configuration in the table map applies to OSPF discard routes.

    • There is no preference among the match route-type , match ipv6 address , and match ip route-source commands for setting the administrative distance of OSPF routes. In this way, the behavior of the table map for setting the administrative distance in Cisco NX-OS OSPF is different from the behavior in Cisco IOS OSPF.

  • If you configure the delay restore seconds command in vPC configuration mode and if the VLANs on the multichassis EtherChannel trunk (MCT) are announced by OSPFv2 or OSPFv3 using switch virtual interfaces (SVIs), those SVIs are announced with MAX_LINK_COST on the vPC secondary node during the configured time. As a result, all route or host programming completes after the vPC synchronization operation (on a peer reload of the secondary vPC node) before attracting traffic. This behavior allows for minimal packet loss for any north-to-south traffic.

  • If you configure the same area-id for the primary area and any multiarea, the configuration is accepted without displaying an error. When you configure the primary area and any multiareas, do not use the same area-id.


Note


If you are familiar with the Cisco IOS CLI, be aware that the Cisco NX-OS commands for this feature might differ from the Cisco IOS commands that you would use.


  • If you use the network ip address mask command under OSPF, an error message will be displayed, and you will be prompted to enable OSPF under an interface with area area id command.

  • While OSPF support are aggressive timers, these are not commended as aggressive timers will bring the adjancency down quickly as well as cause CPU churn. We recommend you to use the default timers and use BFD (Bidirectional Forwarding Detection) to get sub-second failure detection.

Default Settings

The table lists the default settings for OSPFv3 parameters.

Table 1. Default OSPFv3 Parameters

Parameters

Default

Administrative distance

110

Hello interval

10 seconds

Dead interval

40 seconds

Discard routes

Enabled

Graceful restart grace period

60 seconds

Graceful restart notify period

15 seconds

OSPFv3 feature

Disabled

Stub router advertisement announce time

600 seconds

Reference bandwidth for link cost calculation

40 Gb/s

LSA minimal arrival time

1000 milliseconds

LSA group pacing

10 seconds

SPF calculation initial delay time

200 milliseconds

SPF calculation minimum hold time

1000 milliseconds

SPF calculation maximum wait time

5000 milliseconds

Configuring Basic OSPFv3

Configure OSPFv3 after you have designed your OSPFv3 network.

Enabling OSPFv3

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

[no] feature ospfv3

Example:

switch(config)# feature ospfv3

Enables OSPFv3.

Using the no keyword with this command disables the OSPFv3 feature and removes all associated configuration.

Step 3

(Optional) show feature

Example:

switch(config)# show feature
(Optional)

Displays enabled and disabled features.

Step 4

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config
startup-config
(Optional)

Saves this configuration change.

Creating an OSPFv3 Instance

The first step in configuring OSPFv3 is to create an instance or OSPFv3 instance. You assign a unique instance tag for this OSPFv3 instance. The instance tag can be any string. For each OSPFv3 instance, you can also configure the following optional parameters:

  • Router ID—Configures the router ID for this OSPFv3 instance. If you do not use this parameter, the router ID selection algorithm is used. , see the Router IDs section.

  • Administrative distance—Rates the trustworthiness of a routing information source. For more information, see the Administrative Distance section.

  • Log adjacency changes—Creates a system message whenever an OSPFv3 neighbor changes its state.

  • Name lookup—Translates OSPF router IDs to hostnames, either by looking up the local hosts database or querying DNS names in IPv6.

  • Maximum paths—Sets the maximum number of equal paths that OSPFv3 installs in the route table for a particular destination. Use this parameter for load balancing between multiple paths.

  • Reference bandwidth—Controls the calculated OSPFv3 cost metric for a network. The calculated cost is the reference bandwidth divided by the interface bandwidth. You can override the calculated cost by assigning a link cost when a network is added to the OSPFv3 instance. For more information, see the Configuring Networks in OSPFv3 section.

For more information about OSPFv3 instance parameters, see the Configuring Advanced OSPFv3 section.

Before you begin

You must enable OSPFv3 (see the Enabling OSPFv3 section).

Ensure that the OSPFv3 instance tag that you plan on using is not already in use on this router.

Use the show ospfv3 instance-tag command to verify that the instance tag is not in use.

OSPFv3 must be able to obtain a router identifier (for example, a configured loopback address) or you must configure the router ID option.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

[no] router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Note

 

The no router ospfv3 instance tag command does not remove OSPF configuration in interface mode. You must manually remove any OSPFv3 commands configured in interface mode.

Step 3

(Optional) router-id ip-address

Example:

switch(config-router)# router-id
192.0.2.1
(Optional)

Configures the OSPFv3 router ID. This ID uses the dotted decimal notation and identifies this OSPFv3 instance and must exist on a configured interface in the system.

Step 4

(Optional) show ipv6 ospfv3 instance-tag

Example:

switch(config-router)# show ipv6 ospfv3
201
(Optional)

Displays OSPFv3 information.

Step 5

(Optional) log-adjacency-changes [detail]

Example:

switch(config-router)#
log-adjacency-changes
(Optional)

Generates a system message whenever a neighbor changes state.

Step 6

(Optional) passive-interface default

Example:

switch(config-router)# passive-interface
default
(Optional)

Suppresses routing updates on all interfaces. This command is overridden by the VRF or interface command mode configuration.

Step 7

(Optional) distance number

Example:

switch(config-router-af)# distance 25
(Optional)

Configures the administrative distance for this OSPFv3 instance. The range is from 1 to 255. The default is 110.

Step 8

(Optional) maximum-paths paths

Example:

switch(config-router-af)# maximum-paths
4
(Optional)

Configures the maximum number of equal OSPFv3 paths to a destination in the route table. The range is from 1 to 16. The default is 8. This command is used for load balancing.

Step 9

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to create an OSPFv3 instance:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# copy running-config startup-config

Configuring Networks in OSPFv3

You can configure a network to OSPFv3 by associating it through the interface that the router uses to connect to that network (see the Neighbors section). You can add all networks to the default backbone area (Area 0), or you can create new areas using any decimal number or an IP address.


Note


All areas must connect to the backbone area either directly or through a virtual link.



Note


OSPFv3 is not enabled on an interface until you configure a valid IPv6 address for that interface.


Before you begin

You must enable OSPFv3 (see the Enabling OSPFv3 section).

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface interface-type slot/port

Example:

switch(config)# interface ethernet 1/2
switch(config-if)#

Enters interface configuration mode.

Step 3

ipv6 address ipv6-prefix/length

Example:

switch(config-if)# ipv6 address
2001:0DB8::1/48

Assigns an IPv6 address to this interface.

Step 4

ipv6 router ospfv3 instance-tag area area-id [secondaries none]

Example:

switch(config-if)# ipv6 router ospfv3
201 area 0

Adds the interface to the OSPFv3 instance and area.

Step 5

(Optional) show ipv6 ospfv3 instance-tag interface interface-type slot/port

Example:

switch(config-if)# show ipv6 ospfv3 201
interface ethernet 1/2
(Optional)

Displays OSPFv3 information.

Step 6

(Optional) ospfv3 cost number

Example:

switch(config-if)# ospfv3 cost 25
(Optional)

Configures the OSPFv3 cost metric for this interface. The default is to calculate a cost metric, based on the reference bandwidth and interface bandwidth. The range is from 1 to 65535.

Step 7

(Optional) ospfv3 dead-interval seconds

Example:

switch(config-if)# ospfv3 dead-interval 50
(Optional)

Configures the OSPFv3 dead interval, in seconds. The range is from 1 to 65535. The default is four times the hello interval, in seconds.

Step 8

(Optional) ospfv3 hello-interval seconds

Example:

switch(config-if)# ospfv3 hello-interval
25
(Optional)

Configures the OSPFv3 hello interval, in seconds. The range is from 1 to 65535. The default is 10 seconds.

Step 9

(Optional) ospfv3 instance instance

Example:

switch(config-if)# ospfv3 instance 25
(Optional)

Configures the OSPFv3 instance ID. The range is from 0 to 255. The default is 0. The instance ID is link-local in scope.

Step 10

(Optional) ospfv3 mtu-ignore

Example:

switch(config-if)# ospfv3 mtu-ignore
(Optional)

Configures OSPFv3 to ignore any IP maximum transmission unit (MTU) mismatch with a neighbor. The default is to not establish adjacency if the neighbor MTU does not match the local interface MTU.

Step 11

(Optional) ospfv3 network {broadcast | point-point}

Example:

switch(config-if)# ospfv3 network
broadcast
(Optional)

Sets the OSPFv3 network type.

Step 12

(Optional) [default | no] ospfv3 passive-interface

Example:

switch(config-if)# ospfv3
passive-interface
(Optional)

Suppresses routing updates on the interface. This command overrides the router or VRF command mode configuration. The default option removes this interface mode command and reverts to the router or VRF configuration, if present.

Step 13

(Optional) ospfv3 priority number

Example:

switch(config-if)# ospfv3 priority 25
(Optional)

Configures the OSPFv3 priority, used to determine the DR for an area. The range is from 0 to 255. The default is 1. See the Designated Routers section.

Step 14

(Optional) ospfv3 shutdown

Example:

switch(config-if)# ospfv3 shutdown
(Optional)

Shuts down the OSPFv3 instance on this interface.

Step 15

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to add a network area 0.0.0.10 in OSPFv3 instance 201:
switch# configure terminal
switch(config)# interface ethernet 1/2
switch(config-if)# ipv6 address 2001:0DB8::1/48
switch(config-if)# ipv6 router ospfv3 201 area 0.0.0.10
switch(config-if)# copy running-config startup-config

Configuring OSPFv3 IPSec Authentication

You can configure OSPFv3 IP security (IPSec) authentication for a process, an area, and/or an interface.

The authentication configuration is inherited from process to area to interface level. If authentication is configured at all three levels, the interface configuration takes precedence over the process and area configurations.

Before you begin

Ensure that you have enabled OSPFv3 (see the Enabling OSPFv3 section).

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 100
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

exit

Example:

switch(config-router)# exit
switch(config)#

Exits OSPFv3 router configuration mode.

Step 4

  • authentication ipsec spi spi auth [0 | 3 | 7] key
    Example:
    switch(config)# authentication ipsec spi 475 md5 11111111111111112222222222222222
  • area area authentication ipsec spi spi auth [0 | 3 | 7] key
    Example:
    switch(config)# area 0 authenticationipsec spi 475 
    md5 11111111111111112222222222222222
  • interface interface-type slot/port ospfv3 authentication ipsec spi spi auth [0 | 3 | 7] key
    Example:
    switch(config)# interface ethernet 1/1 switch(config-if)# ospfv3 authentication 
    ipsec spi 475 md5 11111111111111112222222222222222

Configuring authentication ipsec spi spi auth command has the following purpose:

  • Configures OSPFv3 IPSec authentication at the process (or VRF) level.

  • The spi argument specifies the security parameter index (SPI). The range is from 256 to 4294967295.

  • The auth argument specifies the type of authentication. The supported values are md5 or sha1.

  • 0 configures the password in cleartext. 3 configures the pass key as 3DES encrypted. 7 configures the key as Cisco type 7 encrypted.

  • If the cleartext option (0) is used, the key argument must be 32 characters long for md5 or 40 characters long for sha1.

Configuring area area authentication ipsec spi spi auth command has the following purpose:

  • Configures OSPFv3 IPSec authentication at the area level.

  • The spi argument specifies the security parameter index (SPI). The range is from 256 to 4294967295.

  • The auth argument specifies the type of authentication. The supported values are md5 or sha1.

  • 0 configures the password in cleartext. 3 configures the pass key as 3DES encrypted. 7 configures the key as Cisco type 7 encrypted.

  • If the cleartext option (0) is used, the key argument must be 32 characters long for md5 or 40 characters long for sha1.

    Note

     

    Use the area area authentication disable command to disable OSPFv3 IPSec authentication at the area level.

Configuring interface interface-type slot/port ospfv3 authentication ipsec spi spi auth command has the following purpose:

  • Configures OSPFv3 IPSec authentication for the specified interface.

  • The spi argument specifies the security parameter index (SPI). The range is from 256 to 4294967295.

  • The auth argument specifies the type of authentication. The supported values are md5 or sha1.

  • 0 configures the password in cleartext. 3 configures the pass key as 3DES encrypted. 7 configures the key as Cisco type 7 encrypted.

  • If the cleartext option (0) is used, the key argument must be 32 characters long for md5 or 40 characters long for sha1.

    Note

     

    Use the ospfv3 authentication disable command to disable OSPFv3 IPSec authentication for the specified interface.

Step 5

(Optional) show ospfv3 interface interface-type slot/port

Example:

switch(config)# show ospfv3 interface
ethernet 1/1
(Optional)

Displays the OSPFv3 authentication configuration at the interface level.

Step 6

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config
startup-config
(Optional)

Saves this configuration change.

Configuring Advanced OSPFv3

Configure OSPFv3 after you have designed your OSPFv3 network.

Configuring Filter Lists for Border Routers

You can separate your OSPFv3 domain into a series of areas that contain related networks. All areas must connect to the backbone area through an area border router (ABR). OSPFv3 domains can connect to external domains as well through an autonomous system border router (ASBR). See the Areas section.

ABRs have the following optional configuration parameters:

  • Area range—Configures route summarization between areas. For more information, see the Configuring Route Summarization section.

  • Filter list—Filters the Inter-Area Prefix (type 3) LSAs on an ABR that are allowed in from an external area.

ASBRs also support filter lists.

Before you begin

Create the route map that the filter list uses to filter IP prefixes in incoming or outgoing Inter-Area Prefix (type 3) LSAs. See Configuring Route Policy Manager.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag

Step 3

address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#

Enters IPv6 unicast address family mode.

Step 4

area area-id filter-list route-map map-name {in | out}

Example:

switch(config-router-af)# area 0.0.0.10
filter-list route-map FilterLSAs in

Filters incoming or outgoing Inter-Area Prefix (type 3) LSAs on an ABR.

Step 5

(Optional) show ipv6 ospfv3 policy statistics area id filter-list {in | out}

Example:

switch(config-router-af)# show ipv6 ospfv3
policy statistics area 0.0.0.10
filter-list in
(Optional)

Displays OSPFv3 policy information.

Step 6

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to configure a filter list for a route map:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# address-family ipv6 unicast
switch(config-router-af)# area 0.0.0.10 filter-list route-map FilterLSAs in
switch(config-router-af)# copy running-config startup-config

Configuring Stub Areas

You can configure a stub area for part of an OSPFv3 domain where external traffic is not necessary. Stub areas block AS External (type 5) LSAs, limiting unnecessary routing to and from selected networks. See the Stub Area section. You can optionally block all summary routes from going into the stub area.

Before you begin

You must enable OSPF (see the Enabling OSPFv3 section).

Ensure that there are no virtual links or ASBRs in the proposed stub area.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

area area-id stub

Example:

switch(config-router)# area 0.0.0.10
stub

Creates this area as a stub area.

Step 4

(Optional) address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#
(Optional)

Enters IPv6 unicast address family mode.

Step 5

(Optional) area area-id default cost cost

Example:

switch(config-router-af)# area 0.0.0.10
default-cost 25
(Optional)

Sets the cost metric for the default summary route sent into this stub area. The range is from 0 to 16777215.

Step 6

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This shows how to create a stub area that blocks all summary route updates:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 stub no-summary
switch(config-router)# copy running-config startup-config

Configuring a Totally Stubby Area

You can create a totally stubby area and prevent all summary route updates from going into the stub area.

To create a totally stubby area, use the following command in router configuration mode:

Procedure

Command or Action Purpose

area area-id stub no-summary

Example:

switch(config-router)# area 20 stub
no-summary

Creates this area as a totally stubby area.

Configuring NSSA

You can configure an NSSA for part of an OSPFv3 domain where limited external traffic is required. You can optionally translate this external traffic to an AS External (type 5) LSA and flood the OSPFv3 domain with this routing information. An NSSA can be configured with the following optional parameters:

  • No redistribution—Redistributes routes that bypass the NSSA to other areas in the OSPFv3 autonomous system. Use this option when the NSSA ASBR is also an ABR.

  • Default information originate—Generates a Type-7 LSA for a default route to the external autonomous system. Use this option on an NSSA ASBR if the ASBR contains the default route in the routing table. This option can be used on an NSSA ABR whether or not the ABR contains the default route in the routing table.

  • Route map—Filters the external routes so that only those routes you want are flooded throughout the NSSA and other areas.

  • No summary—Blocks all summary routes from flooding the NSSA. Use this option on the NSSA ABR.

  • Translate—Translates Type-7 LSAs to AS External (type 5) LSAs for areas outside the NSSA. Use this command on an NSSA ABR to flood the redistributed routes throughout the OSPFv3 autonomous system. You can optionally suppress the forwarding address in these AS External LSAs.


    Note


    The translate option requires a separate area area-id nssa command, preceded by the area area-id nssa command that creates the NSSA and configures the other options.

Before you begin

You must enable OSPF (see the Enabling OSPFv3 section).

Ensure that there are no virtual links in the proposed NSSA and that it is not the backbone area.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

area area-id nssa [no-redistribution] [default-information-originate] [route-map map-name] [no-summary]

Example:

switch(config-router)# area 0.0.0.10
nssa

Creates this area as an NSSA.

Step 4

(Optional) area area-id nssa translate type7 {always | never} [suppress-fa]

Example:

switch(config-router)# area 0.0.0.10
nssa translate type7 always
(Optional)

Configures the NSSA to translate AS External (type 7) LSAs to NSSA External (type 5) LSAs.

Step 5

(Optional) address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#
(Optional)

Enters IPv6 unicast address family mode.

Step 6

(Optional) area area-id default cost cost

Example:

switch(config-router-af)# area 0.0.0.10
default-cost 25
(Optional)

Sets the cost metric for the default summary route sent into this NSSA. The range is from 0 to 16777215.

Step 7

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to create an NSSA that blocks all summary route updates:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 nssa no-summary
switch(config-router)# copy running-config startup-config
This example shows how to create an NSSA that generates a default route:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 nssa default-info-originate
switch(config-router)# copy running-config startup-config
This example shows how to create an NSSA that filters external routes and blocks all summary route updates:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 nssa route-map ExternalFilter no-summary
switch(config-router)# copy running-config startup-config
This example shows how to create an NSSA and then configure the NSSA to always translate AS External (type 7) LSAs to NSSA External (type 5) LSAs:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 nssa
switch(config-router)# area 0.0.0.10 nssa translate type 7 always
switch(config-router)# copy running-config startup-config
This example shows how to create an NSSA that blocks all summary route updates:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 nssa no-summary
switch(config-router)# copy running-config startup-config

Configuring Multi-Area Adjacency

You can add more than one area to an existing OSPFv3 interface. The additional logical interfaces support multi-area adjacency.

Before you begin

You must enable OSPF (see the Enabling OSPFv3 section).

Ensure that you have configured a primary area for the interface (see the Configuring Networks in OSPFv3 section).

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

interface interface-type slot/port

Example:

switch(config)# interface ethernet 1/2
switch(config-if)#

Enters interface configuration mode.

Step 3

ipv6 router ospfv3 instance-tag multi-area area-id

Example:

switch(config-if)# ipv6 router ospfv3
201 multi-area 3

Adds the interface to another area.

Step 4

(Optional) show ipv6 ospfv3 instance-tag interface interface-type slot/port

Example:

switch(config-if)# show ipv6 ospfv3 201
interface ethernet 1/2
(Optional)

Displays OSPFv3 information.

Step 5

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to add a second area to an OSPFv3 interface:
switch# configure terminal
switch(config)# interface ethernet 1/2
switch(config-if)# ipv6 address 2001:0DB8::1/48
switch(config-if)# ipv6 ospfv3 201 area 0.0.0.10
switch(config-if)# ipv6 ospfv3 201 multi-area 20
switch(config-if)# copy running-config startup-config

Configuring Virtual Links

A virtual link connects an isolated area to the backbone area through an intermediate area. See the Virtual Links section. You can configure the following optional parameters for a virtual link:

  • Dead interval—Sets the time that a neighbor waits for a Hello packet before declaring the local router as dead and tearing down adjacencies.

  • Hello interval—Sets the time between successive Hello packets.

  • Retransmit interval—Sets the estimated time between successive LSAs.

  • Transmit delay—Sets the estimated time to transmit an LSA to a neighbor.


Note


You must configure the virtual link on both routers involved before the link becomes active.


Before you begin

You must enable OSPF (see the Enabling OSPFv3 section.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

area area-id virtual-link router-id

Example:

switch(config-router)# area 0.0.0.10
virtual-link 2001:0DB8::1
switch(config-router-vlink)#

Creates one end of a virtual link to a remote router. You must create the virtual link on that remote router to complete the link.

Step 4

(Optional) show ipv6 ospfv3 virtual-link [brief]

Example:

switch(config-router-vlink)# show ipv6 ospfv3
virtual-link
(Optional)

Displays OSPFv3 virtual link information.

Step 5

(Optional) dead-interval seconds

Example:

switch(config-router-vlink)#
dead-interval 50
(Optional)

Configures the OSPFv3 dead interval, in seconds. The range is from 1 to 65535. The default is four times the hello interval, in seconds.

Step 6

(Optional) hello-interval seconds

Example:

switch(config-router-vlink)#
hello-interval 25
(Optional)

Configures the OSPFv3 hello interval, in seconds. The range is from 1 to 65535. The default is 10 seconds.

Step 7

(Optional) retransmit-interval seconds

Example:

switch(config-router-vlink)#
retransmit-interval 50
(Optional)

Configures the OSPFv3 retransmit interval, in seconds. The range is from 1 to 65535. The default is 5.

Step 8

(Optional) transmit-delay seconds

Example:

switch(config-router-vlink)#
transmit-delay 2
(Optional)

Configures the OSPFv3 transmit-delay, in seconds. The range is from 1 to 450. The default is 1.

Step 9

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

These examples show how to create a simple virtual link between two ABRs:

Configuration for ABR 1 (router ID 2001:0DB8::1) is as follows:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 virtual-link 2001:0DB8::10
switch(config-router-vlink)# copy running-config startup-config
Configuration for ABR 2 (router ID 2001:0DB8::10) is as follows:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# area 0.0.0.10 virtual-link 2001:0DB8::1
switch(config-router-vlink)# copy running-config startup-config

Configuring Redistribution

You can redistribute routes learned from other routing protocols into an OSPFv3 autonomous system through the ASBR.

You can configure the following optional parameters for route redistribution in OSPF:

  • Default information originate—Generates an AS External (type 5) LSA for a default route to the external autonomous system.


    Note


    Default information originate ignores match statements in the optional route map.


  • Default metric—Sets all redistributed routes to the same cost metric.


    Note


    If you redistribute static routes, Cisco NX-OS requires the default-information originate command to successfully redistribute the default static route starting in 7.0(3)I7(6).


Before you begin

You must enable OSPF (see the Enabling OSPFv3 section).

Create the necessary route maps used for redistribution.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#

Enters IPv6 unicast address family mode.

Step 4

redistribute {bgpid | direct | isis id | rip id | static} route-map map-name

Example:

switch(config-router-af)# redistribute
bgp route-map FilterExternalBGP

Redistributes the selected protocol into OSPFv3 through the configured route map.

Note

 

If you redistribute static routes, Cisco NX-OS requires the default-information originate command to successfully redistribute the default static route starting in 7.0(3)I7(6).

Step 5

default-information originate [always] [route-map map-name]

Example:

switch(config-router-af)#
default-information-originate route-map DefaultRouteFilter

Creates a default route into this OSPFv3 domain if the default route exists in the RIB. Use the following optional keywords:

  • always —Always generates the default route of 0.0.0. even if the route does not exist in the RIB.

  • route-map —Generates the default route if the route map returns true.

Note

 

This command ignores match statements in the route map.

Step 6

default-metric cost

Example:

switch(config-router-af)# default-metric
25

Sets the cost metric for the redistributed routes. The range is from 1 to 16777214. This command does not apply to directly connected routes. Use a route map to set the default metric for directly connected routes.

Step 7

(Optional) copy running-config startup-config

Example:

switch(config-router-af)# copy running-config
startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to redistribute the Border Gateway Protocol (BGP) into OSPFv3:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# address-family ipv6 unicast
switch(config-router-af)# redistribute bgp route-map FilterExternalBGP
switch(config-router-af)# copy running-config startup-config

Limiting the Number of Redistributed Routes

Route redistribution can add many routes to the OSPFv3 route table. You can configure a maximum limit to the number of routes accepted from external protocols. OSPFv3 provides the following options to configure redistributed route limits:

  • Fixed limit—Logs a message when OSPFv3 reaches the configured maximum. OSPFv3 does not accept any more redistributed routes. You can optionally configure a threshold percentage of the maximum where OSPFv3 logs a warning when that threshold is passed.

  • Warning only—Logs a warning only when OSPFv3 reaches the maximum. OSPFv3 continues to accept redistributed routes.

  • Withdraw—Starts the configured timeout period when OSPFv3 reaches the maximum. After the timeout period, OSPFv3 requests all redistributed routes if the current number of redistributed routes is less than the maximum limit. If the current number of redistributed routes is at the maximum limit, OSPFv3 withdraws all redistributed routes. You must clear this condition before OSPFv3 accepts more redistributed routes. You can optionally configure the timeout period.

Before you begin

You must enable OSPF (see the Enabling OSPFv3 section).

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#

Enters IPv6 unicast address family mode.

Step 4

redistribute {bgpid | direct | isis id | rip id | static} route-map map-name

Example:

switch(config-router-af)# redistribute
bgp route-map FilterExternalBGP

Redistributes the selected protocol into OSPFv3 through the configured route map.

Step 5

redistribute maximum-prefixmax [threshold] [warning-only | withdraw [num-retries timemout]]

Example:

switch(config-router-af)# redistribute
maximum-prefix 1000 75 warning-only

Specifies a maximum number of prefixes that OSPFv2 distributes. The range is from 0 to 65536. Optionally, specifies the following:

  • threshold —Percent of maximum prefixes that triggers a warning message.

  • warning-only —Logs a warning message when the maximum number of prefixes is exceeded.

  • withdraw —Withdraws all redistributed routes and optionally tries to retrieve the redistributed routes. The num-retries range is from 1 to 12. The timeout range is from 60 to 600 seconds. The default is 300 seconds.

Step 6

(Optional) show running-config ospfv3

Example:

switch(config-router-af)# show
running-config ospf
(Optional)

Displays the OSPFv3 configuration.

Step 7

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to limit the number of redistributed routes into OSPF:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# address-family ipv6 unicast
switch(config-router-af)# redistribute bgp route-map FilterExternalBGP
switch(config-router-af)# redistribute maximum-prefix 1000 75

Configuring Route Summarization

You can configure route summarization for inter-area networks by configuring an address range that is summarized.You can also configure route summarization for external, redistributed routes by configuring a summary address for those routes on an ASBR. For more information, see the Route Summarization section.

Before you begin

You must enable OSPF (see the Enabling OSPFv3 section).

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)# 

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#

Enters IPv6 unicast address family mode.

Step 4

area area-id range ipv6-prefix/length [no-advertise] [cost cost]

Example:

switch(config-router-af)# area 0.0.0.10
range 2001:0DB8::/48 advertise

Creates a summary address on an ABR for a range of addresses and optionally advertises this summary address in a Inter-Area Prefix (type 3) LSA. The cost range is from 0 to 16777215.

Step 5

summary-address ipv6-prefix/length [no-advertise] [tag tag]

Example:

switch(config-router-af)#
summary-address 2001:0DB8::/48 tag 2

Creates a summary address on an ASBR for a range of addresses and optionally assigns a tag for this summary address that can be used for redistribution with route maps.

Step 6

(Optional) show ipv6 ospfv3 summary-address

Example:

switch(config-router-af)# show ipv6 ospfv3
summary-address
(Optional)

Displays information about OSPFv3 summary addresses.

Step 7

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to create summary addresses between areas on an ABR:

switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# address-family ipv6 unicast
switch(config-router-af)# area 0.0.0.10 range 2001:0DB8::/48
switch(config-router-af)# copy running-config startup-config

This example shows how to create summary addresses on an ASBR:

switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# address-family ipv6 unicast
switch(config-router-af)# summary-address 2001:0DB8::/48
switch(config-router-af)# no discard route internal
switch(config-router-af)# copy running-config startup-config

Configuring the Administrative Distance of Routes

You can set the administrative distance of routes added by OSPFv3 into the RIB.

The administrative distance is a rating of the trustworthiness of a routing information source. A higher value indicates a lower trust rating. Typically, a route can be learned through more than one routing protocol. The administrative distance is used to discriminate between routes learned from more than one routing protocol. The route with the lowest administrative distance is installed in the IP routing table.

Before you begin

Ensure that you have enabled OSPF (see the Configuring OSPFv3 section).

See the guidelines and limitations for this feature in the Guidelines and Limitations for OSPFv3 section.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#

Enters IPv6 unicast address family mode.

Step 4

[no] table-map map-name

Example:

switch(config-router-af)# table-map foo

Configures the policy for filtering or modifying OSPFv3 routes before sending them to the RIB. You can enter up to 63 alphanumeric characters for the map name.

Step 5

exit

Example:

switch(config-router-af)# exit
switch(config-router)#

Exits router address-family configuration mode.

Step 6

exit

Example:

switch(config-router)# exit
switch(config)#

Exits router configuration mode.

Step 7

route-map map-name [permit | deny ] [seq ]

Example:

switch(config)# route-map foo permit 10
switch(config-route-map)#

Creates a route map or enters route-map configuration mode for an existing route map. Use seq to order the entries in a route map.

Note

 

The permit option enables you to set the distance. If you use the deny option, the default distance is applied.

Step 8

match route-type route-type

Example:

switch(config-route-map)# match
route-type external

Matches against one of the following route types:

  • external—The external route (BGP, EIGRP, and OSPF type 1 or 2)

  • inter-area—The OSPF inter-area route

  • internal—The internal route (including the OSPF intra- or inter-area)

  • intra-area—The OSPF intra-area route

  • nssa-external—The NSSA external route (OSPF type 1 or 2)

  • type-1—The OSPF external type 1 route

  • type-2—The OSPF external type 2 route

Step 9

match ip route-source prefix-list name

Example:

switch(config-route-map)# match ip
route-source prefix-list p1

Matches the IPv6 route source address or router ID of a route to one or more IP prefix lists. Use the ip prefix-list command to create the prefix list.

Note

 

For OSPFv3, the router ID is 4 bytes.

Step 10

match ipv6 address prefix-list name

Example:

switch(config-route-map)# match ipv6
address prefix-list p1

Matches against one or more IPv6 prefix lists. Use the ip prefix-list command to create the prefix list.

Step 11

set distance value

Example:

switch(config-route-map)# set distance
150

Sets the administrative distance of routes for OSPFv3. The range is from 1 to 255.

Step 12

(Optional) copy running-config startup-config

Example:

switch(config-route-map)# copy
running-config startup-config
(Optional)

Saves this configuration change.

Example

This example shows how to configure the OSPFv3 administrative distance for inter-area routes to 150, for external routes to 200, and for all prefixes in prefix list p1 to 190:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# address-family ipv6 unicast
switch(config-router-af)# table-map foo
switch(config-router)# exit
switch(config)# exit
switch(config)# route-map foo permit 10
switch(config-route-map)# match route-type inter-area
switch(config-route-map)# set distance 150
switch(config)# route-map foo permit 20
switch(config-route-map)# match route-type external
switch(config-route-map)# set distance 200
switch(config)# route-map foo permit 30
switch(config-route-map)# match ip route-source prefix-list p1
switch(config-route-map)# match ipv6 address prefix-list p1
switch(config-route-map)# set distance 190
switch(config-route-map)# copy running-config startup-config

Modifying the Default Timers

OSPFv3 includes a number of timers that control the behavior of protocol messages and shortest path first (SPF) calculations. OSPFv3 includes the following optional timer parameters:

  • LSA arrival time—Sets the minimum interval allowed between LSAs arriving from a neighbor. LSAs that arrive faster than this time are dropped.

  • Pacing LSAs—Sets the interval at which LSAs are collected into a group and refreshed, checksummed, or aged. This timer controls how frequently LSA updates occur and optimizes how many are sent in an LSA update message (see the Flooding and LSA Group Pacing section.

  • Throttle LSAs—Sets rate limits for generating LSAs. This timer controls how frequently LSAs are generated after a topology change occurs.

  • Throttle SPF calculation—Controls how frequently the SPF calculation is run.

At the interface level, you can also control the following timers:

  • Retransmit interval—Sets the estimated time between successive LSAs.

  • Transmit delay—Sets the estimated time to transmit an LSA to a neighbor.

See the Configuring Networks in OSPFv3 section for information on the hello interval and dead timer.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

timers lsa-arrival msec

Example:

switch(config-router)# timers
lsa-arrival 2000

Sets the LSA arrival time in milliseconds. The range is from 10 to 600000. The default is 1000 milliseconds.

Step 4

timers lsa-group-pacing seconds

Example:

switch(config-router)# timers
lsa-group-pacing 200

Sets the interval in seconds for grouping LSAs. The range is from 1 to 1800. The default is 10 seconds.

Step 5

timers throttle lsa start-time hold-interval max-time

Example:

switch(config-router)# timers
throttle lsa network 350 5000 6000

Sets the rate limit in milliseconds for generating LSAs. You can configure the following timers:

  • start-time —The range is from 0 to 5000 milliseconds. The default value is 0 milliseconds.

  • hold-interval —The range is from 50 to 30,000 milliseconds. The default value is 5000 milliseconds.

  • max-time —The range is from 50 to 30,000 milliseconds. The default value is 5000 milliseconds.

Step 6

address-family ipv6 unicast

Example:

switch(config-router)# address-family
ipv6 unicast
switch(config-router-af)#

Enters IPv6 unicast address family mode.

Step 7

timers throttle spf delay-time hold-time max-time

Example:

switch(config-router-af)# timers throttle
spf 3000 2000

Sets the SPF best path schedule in seconds between SPF best path calculations with the following timers:

  • delay-time —The range is from 1 to 600,000 milliseconds. The default value is 200 milliseconds.

  • hold-time —The range is from 1 to 600,000 milliseconds. The default value is 1000 milliseconds.

  • max-wait —The range is from 1 to 600,000 milliseconds. The default value is 5000 milliseconds.

Step 8

interface type slot/port

Example:

switch(config)# interface ethernet 1/2
switch(config-if)#

Enters interface configuration mode.

Step 9

ospfv3 retransmit-interval seconds

Example:

switch(config-if)# ospfv3
retransmit-interval 30

Sets the estimated time in seconds between LSAs transmitted from this interface. The range is from 1 to 65535. The default is 5.

Step 10

ospfv3 transmit-delay seconds

Example:

switch(config-if)# ospfv3
transmit-delay 600

Sets the estimated time in seconds to transmit an LSA to a neighbor. The range is from 1 to 450. The default is 1.

Step 11

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to control LSA flooding with the lsa-group-pacing option:
switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# timers lsa-group-pacing 300
switch(config-router)# copy running-config startup-config

Configuring Graceful Restart

Graceful restart is enabled by default. You can configure the following optional parameters for graceful restart in an OSPFv3 instance:

  • Grace period—Configures how long neighbors should wait after a graceful restart has started before tearing down adjacencies.

  • Helper mode disabled—Disables helper mode on the local OSPFv3 instance. OSPFv3 does not participate in the graceful restart of a neighbor.

  • Planned graceful restart only—Configures OSPFv3 to support graceful restart only in the event of a planned restart.

Before you begin

You must enable OSPFv3 (see the Enabling OSPFv3 section).

Ensure that all neighbors are configured for graceful restart with matching optional parameters set.

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201 
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 3

graceful-restart

Example:

switch(config-router)# graceful-restart

Enables a graceful restart. A graceful restart is enabled by default.

Step 4

graceful-restart grace-period seconds

Example:

switch(config-router)# graceful-restart
grace-period 120

Sets the grace period, in seconds. The range is from 5 to 1800 seconds. The default is 60 seconds.

Step 5

graceful-restart helper-disable

Example:

switch(config-router)# graceful-restart
helper-disable

Disables helper mode. Enabled by default.

Step 6

graceful-restart planned-only

Example:

switch(config-router)# graceful-restart
planned-only

Configures graceful restart for planned restarts only.

Step 7

(Optional) show ipv6 ospfv3 instance-tag

Example:

switch(config-router)# show ipv6 ospfv3
201
(Optional)

Displays OPSFv3 information.

Step 8

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to enable a graceful restart if it has been disabled and set the grace period to 120 seconds:

switch# configure terminal
switch(config)# router ospfv3 201
switch(config-router)# graceful restart
switch(config-router)# graceful-restart grace-period 120
switch(config-router)# copy running-config startup-config

Restarting an OSPFv3 Instance

You can restart an OSPv3 instance. This action clears all neighbors for the instance.

To restart an OSPFv3 instance and remove all associated neighbors, use the following command:

Procedure

Command or Action Purpose

restart ospfv3 instance-tag

Example:

switch(config)# restart ospfv3 201

Restarts the OSPFv3 instance and removes all neighbors.

Configuring OSPFv3 with Virtualization

You can configure multiple OSPFv3 instances. You can also create multiple VRFs within the virtual device context (VDC) and use the same or multiple OSPFv3 instances in each VRF. You assign an OSPFv3 interface to a VRF.


Note


Configure all other parameters for an interface after you configure the VRF for an interface. Configuring a VRF for an interface deletes all the configuration for that interface.


Before you begin

You must enable OSPFv3 (see the Enabling OSPFv3 section).

Procedure

  Command or Action Purpose

Step 1

configure terminal

Example:

switch# configure terminal
switch(config)#

Enters global configuration mode.

Step 2

vrf context vrf-name

Example:

switch(config)# vrf context
RemoteOfficeVRF
switch(config-vrf)#

Creates a new VRF and enters VRF configuration mode.

Step 3

router ospfv3 instance-tag

Example:

switch(config)# router ospfv3 201
switch(config-router)#

Creates a new OSPFv3 instance with the configured instance tag.

Step 4

vrf vrf-name

Example:

switch(config-router)# vrf
RemoteOfficeVRF
switch(config-router-vrf)#

Enters router VRF configuration mode.

Step 5

(Optional) maximum-paths paths

Example:

switch(config-router-vrf)# maximum-paths
4
(Optional)

Configures the maximum number of equal OSPFv3 paths to a destination in the route table for this VRF. Use this command for load balancing.

Step 6

interface type slot/port

Example:

switch(config)# interface ethernet 1/2
switch(config-if)#

Enters interface configuration mode.

Step 7

vrf member vrf-name

Example:

switch(config-if)# vrf member
RemoteOfficeVRF

Adds this interface to a VRF.

Step 8

ipv6 address ipv6-prefix/length

Example:

switch(config-if)# ipv6 address
2001:0DB8::1/48

Configures an IP address for this interface. You must do this step after you assign this interface to a VRF.

Step 9

ipv6 ospfv3 instance-tag area area-id

Example:

switch(config-if)# ipv6 ospfv3 201
area 0

Assigns this interface to the OSPFv3 instance and area configured.

Step 10

(Optional) copy running-config startup-config

Example:

switch(config)# copy running-config startup-config
(Optional)

Copies the running configuration to the startup configuration.

Example

This example shows how to create a VRF and add an interface to the VRF:
switch# configure terminal
switch(config)# vrf context NewVRF
switch(config-vrf)# exit
switch(config)# router ospfv3 201
switch(config-router)# exit
switch(config)# interface ethernet 1/2
switch(config-if)# vrf member NewVRF
switch(config-if)# ipv6 address 2001:0DB8::1/48
switch(config-if)# ipv6 ospfv3 201 area 0
switch(config-if)# copy running-config startup-config

Encryption

Beginning with Cisco Nexus Release 10.2(1), you can encrypt and authenticate OSPFv3 messages using ESP encapsulation. OSPFv3 depends on IPSec for secure connection. IPSec supports two encapsulation types:

  • Authentication Header (AH)

  • Encapsulating Security Payload (ESP)

  • RFC4552 ‘Authentication/Confidentiality for OSPFv3’ covers both the above aspects

ESP configuration provides both encryption and authentication for OSPFv3 messages.

The following are the limitations:

  1. Only IPSec transport mode is supported and tunnel mode is not supported.

  2. AH and ESP configurations together are not allowed on an interface. Though two different interfaces can have AH and ESP.

  3. Non-disruptive rekeying as defined in section 10 of RFC 4552 is not supported.

  4. The following Encryption Algorithms will be supported under ESP:

    • AES-CBC (128 bit)

    • AES 192 bit and AES 256 bit will not be supported in this release.

    • 3DES-CBC

    • NULL

  5. The following Authentications will be supported under ESP:

    • SHA-1

    • NULL

  6. Both Encryption and Authentication algorithms cannot be configured NULL in one ESP CLI.

  7. An interface which is part of multiple areas use the same ESP parameters as the parent.

  8. On SPI conflict during configuration, error will be thrown to user and configuration will not be saved. So, while changing the ESP configuration the user must use different SPI for a new configuration.

  9. Max 128 SA/SPI values can be configured per OSPFv3 process.

You can configure ESP at the following levels:

  • Router

  • Area

  • Interface

  • Virtual Links

Configuring OSPFv3 Encryption at Router Level

You can configure OSPFv3 ESP to encrypt and authenticate OSPFv3 packets at the router level using the following commands.

Before you begin

Enable OSPFv3 feature.

Enable authentication package.

Procedure


Step 1

Enter the global configuration mode:

switch# configure terminal

Step 2

Enable OSPFv3:

switch(config)# feature ospfv3

Step 3

Enable authentication package:

switch(config)# feature imp

Step 4

Create a new OSPFv3 instance with the configured instance tag:

switch(config)# router ospfv3 instance-tag

Step 5

Enable IPSec ESP encryption:

switch(config-router)# encryption ipsec spi spi_id esp encrypt_algorithm [ 0 | 3 | 7 ] key authentication auth_algorithm [ 0 | 3 | 7 ] key .

You can specify the security policy index through spi_id and define the encryption algorithm through encrypt_algorithm which can be 3DES, AES 128 or null. Numbers 0, 3, and 7 specify the format of the key. You can define the authentication algorithm through auth_algorithm which can be SHA-1 or NULL.

Step 6

(Optional) Display OSPFv3 information:

switch(config)# show running-config ospfv3


Configuring OSPFv3 Encryption at Area Level

You can configure OSPFv3 ESP to encrypt and authenticate OSPFv3 packets at the area level using the following commands.

Before you begin

Enable OSPFv3 feature.

Enable authentication package.

Procedure


Step 1

Enter the global configuration mode:

switch# configure terminal

Step 2

Enable OSPFv3:

switch(config)# feature ospfv3

Step 3

Enable the authentication package:

switch(config)# feature imp

Step 4

Create a new OSPFv3 instance with the configured instance tag:

switch(config)# router ospfv3 instance-tag

Step 5

Enable IPSec ESP Encryption:

switch(config-router)#area area-num encryption ipsec spi spi_val esp encrypt_algorithm [ 0 | 3 | 7 ] key authentication auth_algorithm [ 0 | 3 | 7] key

You can specify the security policy index through spi_id and define the encryption algorithm through encrypt_algorithm which can be 3DES, AES 128 or null. Numbers 0, 3, and 7 specify the format of the key. You can define the authentication algorithm through auth_algorithm which can be SHA-1 or NULL.

Step 6

(Optional) Display OSPFv3 information:

switch(config)# show running-config ospfv3


Configuring OSPFv3 Encryption at Interface Level

You can configure OSPFv3 ESP to encrypt and authenticate OSPFv3 packets at the interface level using the following commands.

Before you begin

You must enable OSPFv3.

Enable authentication package.

Procedure


Step 1

Enter the global configuration mode:

switch# configure terminal

Step 2

Enable OSPFv3:

switch(config)# feature ospfv3

Step 3

Enables the authentication mode:

switch(config)# feature imp

Step 4

Enters the interface configuration mode:

switch(config)# interface ethernet interface

Step 5

Specify the OSPFv3 instance and area for the interface:

switch(config-if)# ipv6 router ospfv3 instance-tag area area-id

Step 6

Enable IPSec ESP Encryption:

switch(config-if)# ospfv3 encryption ipsec spi spi_id esp encrypt_algorithm [ 0 | 3 | 7 ] key authentication auth_algorithm [ 0 | 3 | 7] key

You can specify the security policy index through spi_id and define the encryption algorithm through encrypt_algorithm which can be 3DES, AES 128 or null. Numbers 0, 3 and 7 specify the format of the key. You can define the authentication algorithm through auth_algorithm which can be SHA-1 or NULL.

Step 7

(Optional) Display the running configuration on the interface:

switch(config-if)#show run interface interface


Configuration Example

The following example shows how to enable security for Ethernet interface 3/2:

switch# configure terminal
switch(config)# feature ospfv3
switch(config)# feature imp
switch(config)# interface ethernet 3/2
switch(config-if)# ipv6 router ospfv3 1 area 0.0.0.0
switch(config-if)# ospfv3 encryption ipsec spi 444 
  esp  Specify encryption parameters
switch(config-if)# ospfv3 encryption ipsec spi 444 esp
  3des  Use the triple DES algorithim
  aes   Use the AES algorithim
  
  null  Use NULL authentication
switch(config-if)# ospfv3 encryption ipsec spi 444 esp aes
  128  Use the 128-bit AES algorithim
switch(config-if)# ospfv3 encryption ipsec spi 444 esp aes 128
  0     Specifies an UNENCRYPTED encryption key will follow
  3     Specifies an 3DES ENCRYPTED encryption key will follow
  7     Specifies a Cisco type 7  ENCRYPTED encryption key will follow
  WORD  The UNENCRYPTED (cleartext) encryption key
switch(config-if)# ospfv3 encryption ipsec spi 444 esp aes 128 12345678123456781234567812345678 authentication null
switch(config-if)# sh ospfv3 interface
 Ethernet3/2 is up, line protocol is up
    IPv6 address 1:1:1:1::2/64
    Process ID 1 VRF default, Instance ID 0, area 0.0.0.0
    Enabled by interface configuration
    State DOWN, Network type BROADCAST, cost 40
    ESP Encryption AES, Authentication NULL, SPI 444, ConnId 444
switch(config-if)#                                                                  

Configuring OSPFv3 Encryption for Virtual Links

You can configure OSPFv3 ESP to encrypt and authenticate OSPFv3 packets for virtual links using the following commands.

Before you begin

Enable OSPFv3 feature.

Enable authentication package.

Procedure


Step 1

Enter the global configuration mode:

switch# configure terminal

Step 2

Enable OSPFv3:

switch(config)# feature ospfv3

Step 3

Enable the authentication package:

switch(config)# feature imp

Step 4

Create a new OSPFv3 instance with the configured instance tag:

switch(config)#router ospfv3 instance-tag

Step 5

Enable IPSec ESP Encryption:

switch(config-router)# encryption ipsec spi spi_id esp encrypt_algorithm [ 0 | 3 | 7 ] key authentication auth_algorithm [ 0 | 3 | 7] key

You can specify the security policy index through spi_id and define the encryption algorithm through encrypt_algorithm which can be 3DES, AES 128 or null. Numbers 0, 3 and 7 specify the format of the key. You can define the authentication algorithm through auth_algorithm which can be SHA-1 or NULL.

Step 6

(Optional) Display OSPFv3 information:

switch(config)# show running-config ospfv3


Configuration Example

The following example shows how to encrypt Virtual links:

switch(config)# feature ospfv3
switch(config)# feature imp
switch(config-if)# router ospfv3 1
switch(config-router)# area 0.0.0.1 virtual-link 3.3.3.3
switch(config-router-vlink)# encryption ipsec spi ?
<256-4294967295> SPI Value
switch(config-router-vlink)# encryption ipsec spi 256 esp ?
3des Use the triple DES algorithim
aes Use the AES algorithim

null Use NULL authentication
switch(config-router-vlink)# encryption ipsec spi 256 esp aes 128 123456789A123456789B123456789C12 authentication ?
null Use NULL authentication
sha1 Use the SHA1 algorithim
switch(config-router-vlink)# encryption ipsec spi 256 esp aes 128 123456789A123456789B123456789C12 authentication null                                                               

Note


To permit multiple OSPFv3 neighbors to have IPsec ESP, the following policy-map has to be applied for a control-plane:
ipv6 access-list copp-acl-ipsec
10 permit ahp any any
20 permit esp any any
class-map type control-plane match-any copp-class-critical-customized-copp
match access-group name copp-acl-ipsec
policy-map type control-plane customized-copp
class copp-class-critical-customized-copp
police cir 36000 kbps bc 1280000 bytes conform transmit violate drop
control-plane
service-policy input customized-copp

Verifying the OSPFv3 Configuration

To display the OSPFv3 configuration, perform one of the following tasks:

Command Purpose
show ipv6 ospfv3 [instance-tag] [vrf vrf-name]

Displays information about one or more OSPFv3 routing instances. The output includes the following area-level counts:

  • Interfaces in this area—A count of all interfaces added to this area (configured interfaces).

  • Active interfaces—A count of all interfaces considered to be in router link states and SPF (UP interfaces).

  • Passive interfaces—A count of all interfaces considered to be OSPF passive (no adjacencies will be formed).

  • Loopback interfaces—A count of all local loopback interfaces.

show ipv6 ospfv3 border-routers

Displays the internal OSPF routing table entries to an ABR and ASBR.

show ipv6 ospfv3 database

Displays lists of information related to the OSPFv3 database for a specific router.

show ipv6 ospfv3 interface type number [vrf {vrf-name | all | default | management}]

Displays the OSPFv3 interface information.

show ipv6 ospfv3 neighbors

Displays the neighbor information. Use the clear ospfv3 neighbors command to remove adjacency with all neighbors.

show ipv6 ospfv3 request-list

Displays a list of LSAs requested by a router.

show ipv6 ospfv3 retransmission-list

Displays a list of LSAs waiting to be retransmitted.

show ipv6 ospfv3 summary-address

Displays a list of all summary address redistribution information configured under an OSPFv3 instance.

show ospfv3 process

Displays the OSPFv3 authentication configuration at the process level.

show ospfv3 interface interface-type slot/port

Displays the OSPFv3 authentication configuration at the interface level.

show running-configuration ospfv3

Displays the current running OSPFv3 configuration.

Monitoring OSPFv3

To display OSPFv3 statistics, use the following commands:

Command Purpose
show ipv6 ospfv3 memory

Displays the OSPFv3 memory usage statistics.

show ipv6 ospfv3 policy statistics area area-id filter-list {in | out} [vrf {vrf-name | all | default | management}]

Displays the OSPFv3 route policy statistics for an area.

show ipv6 ospfv3 policy statistics redistribute {bgp id | direct | isis id | rip id | static vrf {vrf-name | all | default | management}]

Displays the OSPFv3 route policy statistics.

show ipv6 ospfv3 statistics [vrf {vrf-name | all | default | management}]

Displays the OSPFv3 event counters.

show ipv6 ospfv3 traffic interface-type number [vrf {vrf-name | all | default | management}]

Displays the OSPFv3 packet counters.

Configuration Examples for OSPFv3

This example shows how to configure OSPFv3:

This example shows how to configure OSPFv3:
feature ospfv3
router ospfv3 201
 router-id 290.0.2.1

interface ethernet 1/2
 ipv6 address 2001:0DB8::1/48
 ipv6 ospfv3 201 area 0.0.0.10