Prerequisites for OTV
You must have basic understanding of routing, switching, and multicast concepts.
The documentation set for this product strives to use bias-free language. For the purposes of this documentation set, bias-free is defined as language that does not imply discrimination based on age, disability, gender, racial identity, ethnic identity, sexual orientation, socioeconomic status, and intersectionality. Exceptions may be present in the documentation due to language that is hardcoded in the user interfaces of the product software, language used based on RFP documentation, or language that is used by a referenced third-party product. Learn more about how Cisco is using Inclusive Language.
Overlay Transport Virtualization (OTV) is a MAC-in-IP method that extends Layer 2 connectivity across a transport network infrastructure. OTV provides Layer 2 connectivity between remote network sites by using MAC-address-based routing and IP-encapsulated forwarding across a transport network to provide support for applications that require Layer 2 adjacency.
The OTV application (also known as OTV) is one of the modules of the OTV architecture in Cisco software. OTV interacts with the following other modules of the OTV architecture in Cisco IOS software:
Layer 2 Intermediate System-to-Intermediate System (IS-IS)
Ethernet infrastructure
IP tunnel infrastructure
Layer 2 Forwarding Information Base (L2FIB)
Multilayer Routing Information Base (MLRIB)
Ethernet Operation, Administration, and Maintenance (OAM)
Internet Group Management Protocol (IGMP)
Address Resolution Protocol (ARP)
You deploy OTV on edge devices in each site. OTV requires no other changes to the sites or to the transport network.
You must have basic understanding of routing, switching, and multicast concepts.
Configure the join interface and all Layer 3 interfaces that face the IP core between the OTV edge devices with the highest maximum transmission unit (MTU) size supported by the IP core. OTV sets the Don’t Fragment (DF) bit in the IP header for all OTV control and data packets so that the core cannot fragment these packets.
Ensure that PIM is not enabled on the join interface; enable only passive PIM on the join interface. Configure SSM for the OTV data group multicast address range by using the ip pim passive command.
Ensure that a site identifier is configured and is the same for all edge devices in a same site. OTV brings down all overlays and generates a system message when it detects a mismatched site identifier from a neighbor edge device.
Only one internal interface (site-facing interface) can be configured on an edge device for all the overlays, multiple internal interface's are not supported.
Only physical interfaces/sub-interfaces/port-channel can be used as join-interfaces, GRE tunnels and loopback interfaces are not supported.
OTV is compatible only with a transport network configured for IPv4. IPv6 is not supported.
OTV cannot be configured on the same router on which Multiprotocol Label Switching (MPLS) is configured. If you try to configure an overlay interface on a router where MPLS is already configured, OTV creation will fail. Similarly, if you try to create an MPLS on a router where OTV is configured, MPLS creation will fail. You can remove a failed overlay interface configuration by using the no interface overlay x command.
The transport network must support the Protocol Independent Multicast (PIM) sparse mode (Any Source Multicast [ASM]) for the provider multicast group and Source Specific Multicast (SSM) for the delivery group.
If the device is not configured with OTV, the show bridge-domain command does not display any output.
Overlay Transport Virtualization (OTV) and Cisco Unified Border Element (Cisco UBE) cannot interoperate with each other on Cisco IOS XE software.
Maintains a list of overlays
Maintains a list of configured overlay parameters such as name, multicast address, encapsulation type, authentication, and OTV feature sets
Maintains the state of the overlay interface
Maintains the status of OTV VLAN membership from Ethernet infrastructure and the state of the authoritative edge device (AED) from IS-IS
Maintains a database of overlay adjacencies as reported by IS-IS
Maintains IP tunnel information and manages the encapsulation for data sent on the overlay network
Manages delivery groups (DGs) for each overlay by snooping multicast traffic and monitoring traffic streams for active DGs
Configures, starts, and stops the OTV IS-IS instance
Interfaces with IP multicast to join provider multicast groups for each overlay
Term |
Description |
---|---|
Edge device |
A device that performs typical Layer 2 learning and forwarding on it's internal interface (site-facing interface) and IP-based virtualization on transport-facing interfaces. OTV functionality occurs only in an edge device. You can configure multiple overlay interfaces on an edge device. You can also have multiple edge devices in the same site. |
Authoritative edge device (AED) |
An elected edge device that serves as the forwarder. OTV elects a forwarding device per site for each VLAN and designates the forwarding device as an AED. OTV provides loop-free multihoming by using this AED. The edge devices in a site communicate with each other through internal interfaces to elect an AED. |
Transport network |
A network that connects OTV sites. A transport network can be managed by customers or provided by a service provider or be a mix of both. OTV is compatible only with a transport network configured for IPv4. IPv6 is not supported. |
Join interface |
An uplink interface of an edge device. A join interface is a point-to-point routed interface. An edge device joins an overlay network through this interface. The IP address of this interface is used to advertise the reachability of a MAC address in a site. Both Ethernet and Packet over SONET (POS) interfaces are supported as join interfaces. The join interface connects the edge device to the transport network and it should be a Layer-3 interface. |
Internal interface (site-facing interface) |
A Layer 2 interface on an edge device that connects to the VLANs that are to be extended. These VLANs typically form a Layer 2 domain known as a site and can contain site-based switches or site-based routers. An internal interface is a Layer 2 access interface or a trunk interface regardless of whether the internal interface connects to a switch or a router. |
MAC-in-IP Routing |
The type of routing that associates the destination MAC address of the Layer 2 traffic with the join interface IP address of an edge device. The OTV control-plane protocol advertises the MAC-in-IP association to edge devices. In MAC routing, MAC addresses are reachable in an overlay network through the IP address of a remote edge device. Layer 2 traffic that is destined to a MAC address is encapsulated in an IP packet based on the MAC-in-IP mapping stored in the MAC table. |
Overlay interface |
A logical, multiaccess, multicast-capable interface. An overlay interface encapsulates Layer 2 frames in IP unicast or multicast headers. |
Overlay network |
A logical network that interconnects remote sites for MAC routing of Layer 2 traffic. An overlay network comprises multiple edge devices. |
Site |
A Layer 2 network that may be single-homed or multihomed to the transport network and the OTV overlay network. Edge devices that operate in an overlay network provide Layer 2 connectivity between sites. Layer 2 sites are physically separated from each other by the transport network. |
Site VLAN |
A dedicated VLAN on which an internal adjacency is established. OTV sends local hello messages on the site VLAN to detect other OTV edge devices in the same site. OTV also uses the site VLAN to determine the AED within edge devices in the same site. We recommend that you use a dedicated VLAN as a site VLAN. You should also ensure the following:
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An OTV overlay network provides Layer 2 connectivity between remote sites over a transport network. An overlay network consists of one or more edge devices in each site. The sites are interconnected using a control-plane protocol across the transport network.
The figure below shows two sites connected through edge devices to a transport network to create a virtual overlay network.
An overlay network maps MAC addresses of the hosts at a site to their respective edge devices IP addresses. After OTV identifies the edge device to which a Layer 2 frame is to be sent, OTV encapsulates the frame and sends the resulting IP packet by using the transport network routing protocols.
OTV can support more than one overlay network running IPv4 unicast forwarding or multicast flooding. Each overlay network can support more than one unique VLAN.
Note |
OTV does not extend Spanning Tree Protocol (STP) across sites. Each site runs its own STP instead of all sites being included in a large STP domain. This per-site STP topology allows the use of different STP modes, such as Per-VLAN Spanning Tree (PVST), Rapid-PVST, or Multiple Spanning Tree (MST), in each site. |
Each site consists of one or more edge devices and other internal routers, switches, or servers. OTV is configured only on an edge device. The OTV configuration is completely transparent to the rest of the site. For example, information about MAC learning, STP root bridge placement, and STP mode is transparent. An edge device has an internal interface that is part of the Layer 2 network and an external interface that is reachable through IP in the transport network.
An edge device performs typical Layer 2 learning and forwarding on its internal interface and transmits and receives encapsulated Layer 2 traffic on it's join interface through the transport network. An edge device sends and receives control-plane traffic through the join interface. The control-plane traffic exchanges reachability information between remote sites to build up a table that maps MAC addresses to the join interface IP address of the edge device that is local to that site.
OTV builds Layer 2 reachability information by communicating between edge devices with the overlay protocol. The overlay protocol forms adjacencies with all edge devices. After each edge device is adjacent with all its peers in an overlay network, the edge devices share MAC address reachability information with other edge devices that participate in the same overlay network.
OTV discovers edge devices through dynamic neighbor detection, which leverages the multicast support of the core.
For transport networks that support IP multicast, one multicast address (the control-group address) is used to encapsulate and exchange OTV control-plane protocol updates. Each edge device that participates in a particular overlay network shares the same control-group address with all other edge devices of the same overlay network. As soon as a control-group, data-group address and a join interface are configured on an edge device, the edge device sends an IGMP report message to join the control group. Edge devices act as hosts in the multicast network and send multicast IGMP report messages to the assigned multicast group address.
As in traditional link-state routing protocols, edge devices exchange OTV control-plane hellos to build adjacencies with other edge devices in the overlay network. After adjacencies are established, OTV control-plane link-state packets (LSPs) communicate MAC-to-IP mappings to adjacent edge devices. These LSPs contain the IP address of the remote edge device, VLAN IDs, and the learned MAC addresses that are reachable through that edge device.
Edge devices participate in data-plane learning on internal interfaces to build up the list of MAC addresses that are reachable within their site. OTV sends these locally learned MAC addresses in the OTV control-plane updates.
When an edge device receives a Layer 2 frame on an internal interface, OTV performs the MAC table lookup based on the destination address of the Layer 2 frame. If the frame is destined to a MAC address that is reachable locally, the frame is internally forwarded to that device. OTV performs no other actions and the processing of the frame is complete.
If the frame is destined to a MAC address learned over an overlay network, OTV performs the following tasks:
Strips the preamble and frame check sequence (FCS) from the Layer 2 frame.
Adds an OTV header to the Layer 2 frame and copies the 802.1Q information into the OTV header.
Adds the IP address to the packet based on the initial MAC address table lookup. This IP address is used as the destination address for the IP packet that is sent over the transport network.
OTV traffic appears as IP traffic to the transport network.
At the destination site, the edge device performs the reverse operation and presents the original Layer 2 frame to the local site. The edge device, based on the local MAC address table forwards the frame on its internal interface.
In the figure above, Site 1 communicates with Site 3 over the overlay network. Edge Device 1 receives the Layer 2 frame from MAC1 and looks up the destination MAC address, MAC3, in the MAC table. The edge device encapsulates the Layer 2 frame in an IP packet with the IP destination address set for Edge Device 3 (209.165.201.4). When Edge Device 3 receives the IP packet, the edge device strips off the IP header and sends the original Layer 2 frame over it's internal interface to reach the host having MAC address MAC3.
OTV uses a metric value to support seamless MAC mobility.
When an AED learns a new MAC address, the AED advertises the new address in OTV control-plane updates with a metric value of one if no other edge device has advertised that MAC address before.
In the case of a mobile MAC address, an AED advertises the newly learned, local MAC address with a metric value of zero. This metric value signals the remote edge device to stop advertising that MAC address. After the remote edge device stops advertising the moved MAC address, the AED that contains the new MAC address changes the metric value to one.
Virtual machine (VM) mobility is one common example of MAC mobility. VM mobility occurs when the virtual machine moves from one site to another. OTV detects this change based on the changed advertisement of the mobile MAC address.
You can use OTV to connect remote sites in multiple topologies.
In this sample topology, both sites are connected over a common transport network. The edge devices in both the sites have an overlay interface configured (interface overlay 1 and interface overlay 2) with the same control-group address, which makes both the edge devices join a common overlay network.
You can configure an edge device in more than one overlay network. Each overlay network use different control and data group multicast addresses.
In the figure above, Site 3 connects to Site 1 over Overlay Network 1 through overlay interface 3 on Edge Device 3. Site 3 also connects to Site 2 over Overlay Network 2 through overlay interface 4 on Edge Device 3. Each overlay network has different control-group and data-group addresses.
Note |
The VLAN's extended across different overlay network's should be unique. |
Site 3 uses Edge Device 3 to connect to both the overlay networks—Overlay Network 1 and Overlay Network 2. Edge Device 3 associates the same physical interface for both the overlay networks.
For resiliency and load balancing, a site can have multiple edge devices.
When more than one edge device exists in a site and both participate in the same overlay network, the site is considered multihomed. For the VLANs that are extended using OTV, one edge device is elected as an AED on a per-VLAN basis. OTV leverages a local VLAN to establish an adjacency between edge devices on their internal interfaces. The local VLAN that is shared by the internal interfaces is the site VLAN. The adjacency establishment over the site VLAN determines which edge device is authoritative for what VLANs.
Load balancing is achieved because each edge device is authoritative for a subset of all VLANs that are transported over the overlay. Link utilization to and from the transport is optimized.
The figure below shows the AED that is selected for a multihomed site in an overlay network.
In the figure above, Site 1 is a multihomed site with two physical interfaces connected to the transport network.
Dual site adjacency includes adjacency discovery over the overlay network and in the existing site VLAN. Dual site adjacency introduces additional resiliency and loop prevention. Loops may be caused by site VLAN partition or misconfiguration. Dual site adjacency also uses forwarding readiness notifications to detect when neighbor edge devices in the same site experience a change such as local failures (for example, the site VLAN or extended VLANs going down or the join interface going down). These forwarding readiness notifications trigger an immediate AED election for the site.
OTV sends forwarding readiness notifications to all neighbors of an edge device in the following isolation states:
Site isolation: All extended VLANs on an edge device go down.
Core isolation: All overlay adjacencies go down.
The dual site adjacency state results from the most recent adjacency state for either the overlay or the site VLAN adjacency. OTV determines AED election based on active dual site adjacencies only. An inactive dual site adjacency is ignored for AED election.
You must configure the same site identifier for all edge devices in a site. OTV advertises this site identifier in the IS-IS hello packets sent over the overlay network and on the local site VLAN. The combination of the IS-IS system ID and site identifier uniquely identifies the edge devices in a site.
The OTV control-plane creates adjacencies between remote sites to provide Layer 2 connectivity over a transport network. An OTV network performs the following functions:
Discovers remote sites and builds a control-protocol adjacency
Shares MAC routing information across an overlay network
An overlay network consists of one or more logical overlay interfaces that are configured on an edge device in each remote site that connects to the physical transport network. You associate the logical overlay interface with a physical interface (join-interface) that connects to the transport network. The OTV control plane is responsible for discovering edge devices in remote sites, creating control-protocol adjacencies to these sites, and establishing protocol adjacencies among the sites. The OTV control-plane protocol uses the IS-IS protocol to establish adjacencies and exchange MAC reachability across an overlay network.
Note |
You do not need to configure IS-IS to use OTV. IS-IS is enabled in the background after OTV is enabled. |
The OTV control-plane protocol also sends and receives MAC routing updates between remote sites and updates the Routing Information Base (RIB) with these MAC-to-IP address pairs.
An overlay interface is a logical interface that connects to remote edge devices in an overlay network through an associated physical interface (join interface) on the transport network. From the perspective of MAC-based forwarding in a site, an overlay interface is simply another bridged interface. As a bridged interface, unicast MAC addresses are associated with an overlay interface. An overlay interface is eligible for inclusion in the Outbound Interface List (OIL) for different multicast groups. However, no STP packets are forwarded over an overlay interface. Unknown unicast packets are also not flooded on an overlay interface. From the perspective of IP transport, an overlay interface is not visible.
OTV encapsulates Layer 2 frames in IP packets and transmits them over the transport network via the join interface.
The following commands must be configured for an overlay interface to be in the up state:
no shutdown
otv control-group
otv data-group
otv join-interface
OTV learns MAC-to-IP address pairs from the following:
MAC address learning on internal interface
OTV control-plane updates over an overlay network
Multicast address learning through IGMP snooping
OTV edge devices snoop IGMP traffic and issue a Group Membership-link-state packet (GM-LSP) to advertise the presence of receivers to remote edge devices. The remote edge devices include the overlay interface in the Outbound Interface List (OIL) for the corresponding multicast group. OTV does not program multicast MAC addresses in the forwarding tables but rather updates the OIL state as necessary.
All learned MAC addresses are stored in the RIB with the associated remote IP addresses.
The OTV control plane uses IS-IS link-state packets (LSPs) to propagate MAC address to IP address mappings to all edge devices in an overlay network. These address mappings contain the MAC address, VLAN ID, and the associated IP address of the edge device that the MAC address is reachable from.
An AED uses IGMP snooping to learn all multicast IP addresses in the local site. OTV includes these IP addresses in a special GM-LSP that is sent to remote edge devices in an overlay network.
OTV uses the control-group multicast address that is assigned from the transport network to create a unique multicast group between remote sites on an overlay network. Each edge device in an overlay network acts as a multicast host and sends an IGMP report message to join the control-group multicast address. OTV sends encapsulated OTV control-plane hello messages and MAC routing updates across this multicast group.
OTV uses IGMP snooping and group membership advertisements (GM-LSPs) to learn all multicast group members from remote sites. OTV also uses IGMP snooping to detect all multicast groups in a local site.
OTV can suppress unnecessary ARP messages from being sent over an overlay network. OTV builds a local Layer 3-to-Layer 2 mapping for remote hosts. Any ARP requests from local hosts are served by this ARP cache.
OTV supports stateless switchovers. A stateful switchover occurs when the active supervisor switches to the standby supervisor. There may be a few seconds of traffic loss while the OTV tunnel is recreated following a switchover.
OTV uses the IS-IS protocol for control-plane learning of MAC entries. The OTV IS-IS component is responsible for transporting MAC information across all VPN sites. It carries unicast and multicast MAC information encoded in type, length, values (TLVs).
On the internal interface, OTV IS-IS is responsible for sending IS-IS hello (IIH) packets on the site VLAN by using a multicast MAC destination address. Using a multicast MAC address ensures that all Layer 2 switches in a site forward the packet and that the packet reaches all other OTV edge devices. Each site has a configured site ID. The site ID is advertised by each edge device in these IS-IS hello messages. The site ID is used to identify all edge devices belonging to the same site. IS-IS assigns an AED for each VLAN. The AED for a VLAN is the edge device responsible for announcing local MACs for a given VLAN to remote sites and accepting packets destined for that VLAN.
On the overlay interface, OTV IS-IS is responsible for sending out IIH packets with site ID TLV on the multicast control-group. Using the control-group multicast ensures that all remote sites participating in the overlay network are automatically discovered and an adjacency is formed among all edge devices belonging to the same overlay network. OTV IS-IS also informs OTV whenever a new neighbor is discovered.
OTV IS-IS also handles fast MAC moves between remote sites and the local site and guards against fast oscillations in the event of misconfigurations where the same MAC address is used in multiple sites.
The creation of an overlay interface triggers the creation of an OTV IS-IS instance. OTV IS-IS supports multiple overlays. There is a one-to-one relationship between an OTV IS-IS instance and an overlay interface. OTV IS-IS discovers neighbors, forms adjacencies, and exchanges unicast MAC and multicast group information per overlay. All IS-IS databases, such as the adjacency database and the LSP database, are maintained per overlay.
OTV IS-IS forms only level-1 adjacencies. It advertises the primary IP address of the join interface in its hellos and protocol data units (PDUs). This address along with the system ID of the neighbor is added to OTV, which stores this information in its overlay adjacency database.
OTV IS-IS is a client of Multilayer Routing Information Base (MLRIB) for Layer 2. OTV IS-IS registers with MLRIB to get notifications for all local Layer 2 unicast and multicast address additions or deletions. Unicast MAC address information is put in OTV IS-IS LSPs, while multicast address information is put in OTV IS-IS multicast group PDUs for flooding to all remote sites.
Based on neighbor LSP advertisements, OTV IS-IS adds MAC reachability information for remote unicast and multicast group addresses to MLRIB. When OTV is disabled on a VLAN (the VLAN is removed from the list of OTV-advertised VLANs), OTV IS-IS withdraws the remote reachability information from MLRIB.
An overlay interface is a logical interface that connects to remote edge devices in an overlay network through an associated physical or port-channel interface (join-interface) on the transport network. After creating an overlay interface, you must associate the overlay interface with a join interface and configure control and data-group multicast addresses. For more information, see the “Associating an Overlay Interface with a Join Interface” and “Configuring a Multicast Group Address” sections.
Command or Action | Purpose | |
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Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
Step 3 |
interface overlay interface Example:
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Creates an OTV overlay interface and enters interface configuration mode.
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Step 4 |
no shutdown Example:
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Brings up the OTV overlay interface. |
Step 5 |
otv vpn-name name Example:
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(Optional) Creates an alias for the OTV overlay interface name.
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Step 6 |
description string Example:
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(Optional) Adds a description for the overlay network.
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Step 7 |
end Example:
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Exits interface configuration mode and returns to privileged EXEC mode. |
Before you associate an overlay interface with a physical interface, ensure that IGMP Version 3 (IGMPv3) is configured on the physical Layer 3 interface that you configure as the join interface.
After creating an overlay interface, perform this task to associate the overlay interface with a join interface. Define a physical Layer 3 interface as the join interface for the overlay interface, and associate the same with the overlay interface.
Command or Action | Purpose | |
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Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
Step 3 |
interface overlay interface Example:
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Creates an OTV overlay interface and enters interface configuration mode.
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Step 4 |
otv join-interface type number Example:
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Joins the OTV overlay interface with a physical Layer 3 interface.
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Step 5 |
end Example:
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Exits interface configuration mode and returns to privileged EXEC mode. |
To enable unicast and multicast IP forwarding on a join interface, perform the following tasks after creating the join interface:
Configure the IP address and mask for the join interface by using the ip address command.
Configure the join interface to operate in Protocol Independent Multicast (PIM) passive mode by using the ip pim passive command.
Enable IP multicast routing by using the ip multicast-routing distributed command.
Configure IGMPv3 on the join interface by using the ip igmp version 3 command.
The following commands are also necessary to be added globally to ensure multicast forwarding happens - these commands enable IGMP snooping on the internal interface:
ip igmp snooping querier version 3
ip igmp snooping querier
Perform this task to configure a unique multicast group address for each overlay network.
Command or Action | Purpose | |
---|---|---|
Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
Step 3 |
interface overlay interface Example:
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Creates an OTV overlay interface and enters interface configuration mode.
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Step 4 |
otv control-group multicast-address Example:
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Configures a multicast group address used by the OTV control plane for this OTV overlay network.
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Step 5 |
otv data-group multicast-address/mask Example:
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Configures one or more ranges of local IPv4 multicast data-group prefixes used for multicast data traffic.
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Step 6 |
end Example:
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Exits interface configuration mode and returns to privileged EXEC mode. |
Before configuring a VLAN over an overlay interface, ensure that there is connectivity for VLANs to be extended to the OTV edge device.
Ethernet service instances are configured with VLAN encapsulation on an overlay interface to define the VLANs that are part of an overlay network. MAC addresses learned on the service instances’ bridge domains are advertised to other edge devices on the overlay along with the service instances’ VLAN.
Command or Action | Purpose | |
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Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
Step 3 |
interface overlay interface Example:
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Creates an OTV overlay interface and enters interface configuration mode.
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Step 4 |
service instance interface ethernet Example:
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Configures an Ethernet service instance on the overlay interface being configured and enters service instance configuration mode.
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Step 5 |
encapsulation dot1q vlan-ID Example:
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Defines the VLAN encapsulation format as IEEE 802.1Q and specifies the VLAN identifier. |
Step 6 |
bridge-domain bridge-domain-ID Example:
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Binds the specified bridge domain to a service instance. |
Step 7 |
end Example:
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Exits service instance configuration mode and returns to privileged EXEC mode. |
A site bridge domain is used by OTV to identify the service instance where local hello messages should be sent. There should be an Ethernet service instance configured with the site bridge domain on the internal interface. OTV uses the configured VLAN encapsulation (if any) from this service instance to encapsulate local hello messages before sending out a message from the local interface.
A site identifier is advertised by each edge device in an overlay network and is used to identify all edge devices belonging to the same site. All edge devices in the same site should be configured with the same site identifier.
Command or Action | Purpose | |
---|---|---|
Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
Step 3 |
otv site bridge-domain bridge-domain-ID Example:
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Configures the site bridge domain for sending IS-IS hellos over site interfaces and enters OTV site configuration mode.
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Step 4 |
exit Example:
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Exits OTV site configuration mode and returns to global configuration mode. |
Step 5 |
otv site-identifier site-ID Example:
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Configures the site identifier.
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Step 6 |
end Example:
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Exits global configuration mode and returns to privileged EXEC mode. |
The following sample output shows the configuration of overlay interface 1:
Device#show running-config interface gigabitEthernet 0/0/2
!
interface GigabitEthernet0/0/2
description "Join Interface"
ip address 209.165.201.1 255.255.255.224
ip pim passive
ip igmp version 3
negotiation auto
end
Device#
Device#show running-config interface GigabitEthernet0/0/0
!
interface GigabitEthernet0/0/0
description "Internal Interface"
no ip address
negotiation auto
service instance 10 ethernet
encapsulation dot1q 10
bridge-domain 10
!
service instance 20 ethernet
encapsulation dot1q 20
bridge-domain 20
!
Device#
Device#show otv overlay1
Overlay Interface Overlay1
VPN name : overlay1
VPN ID : 1
State : UP
Fwd-capable : Yes
Fwd-ready : Yes
AED-Server : Yes
Backup AED-Server : No
AED Capable : Yes
IPv4 control group : 239.1.1.1
Mcast data group range(s): 232.1.1.0/28
Join interface(s) : GigabitEthernet0/0/2
Join IPv4 address : 209.165.201.1
Tunnel interface(s) : Tunnel0
Encapsulation format : GRE/IPv4
Site Bridge-Domain : 10
Capability : Multicast-reachable
Is Adjacency Server : No
Adj Server Configured : No
Prim/Sec Adj Svr(s) : None
Device#
Device#show otv overlay 1 vlan
Overlay 1 VLAN Configuration Information
Inst VLAN BD Auth ED State Site If(s)
0 20 20 *Device active Gi0/0/0:SI20
Total VLAN(s): 1
Device#
You can configure authentication for OTV IS-IS hello messages. OTV uses hello authentication to authenticate a remote site before OTV creates an adjacency to that remote site. Each overlay network uses a unique authentication key. An edge device creates an adjacency only with a remote site that shares the same authentication key and authentication method.
OTV supports the following authentication methods:
Clear text
Message digest algorithm 5 (MD5)
Command or Action | Purpose | |||
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Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
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Step 3 |
interface overlay interface Example:
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Creates an OTV overlay interface and enters interface configuration mode.
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Step 4 |
otv isis authentication mode {md5 | text} Example:
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Configures the authentication method. |
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Step 5 |
otv isis authentication key-chain key-chain-name Example:
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Configures an authentication key chain for edge device authentication.
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Step 6 |
end Example:
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Exits interface configuration mode and returns to privileged EXEC mode. |
Configure OTV to authenticate all incoming OTV IS-IS PDUs.
Command or Action | Purpose | |||
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Step 1 |
enable Example:
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Enables privileged EXEC mode.
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Step 2 |
configure terminal Example:
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Enters global configuration mode. |
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Step 3 |
otv isis overlay overlay-interface Example:
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Creates an OTV IS-IS instance and enters OTV IS-IS configuration mode.
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Step 4 |
authentication mode {md5 | text} Example:
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Configures the authentication method. |
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Step 5 |
authentication key-chain key-chain-name Example:
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Configures the authentication key chain for PDU authentication.
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Step 6 |
end Example:
|
Exits OTV IS-IS configuration mode and returns to privileged EXEC mode. |
An ARP cache is maintained by every OTV edge device and is populated by snooping ARP replies. Initial ARP requests are broadcast to all sites, but subsequent ARP requests are suppressed at the edge device and answered locally. OTV edge devices respond to ARP requests on behalf of remote hosts. Perform this task to allow ARP requests over an overlay network and to disable ARP caching on OTV edge devices.
Command or Action | Purpose | |
---|---|---|
Step 1 |
enable Example:
|
Enables privileged EXEC mode.
|
Step 2 |
configure terminal Example:
|
Enters global configuration mode. |
Step 3 |
interface overlay interface Example:
|
Creates an OTV overlay interface and enters interface configuration mode.
|
Step 4 |
no otv suppress arp-nd Example:
|
Allows ARP requests over an overlay network and disables ARP caching on edge devices.
|
Step 5 |
end Example:
|
Exits interface configuration mode and returns to privileged EXEC mode. |
Step 6 |
show otv [overlay overlay-interface] arp-nd-cache Example:
|
(Optional) Displays the OTV Layer 2 to Layer 3 address mapping cache used for ARP suppression. |
You can tune parameters for the overlay routing protocol.
Note |
We recommend that only experienced users of OTV perform these configurations. |
Command or Action | Purpose | |
---|---|---|
Step 1 |
enable Example:
|
Enables privileged EXEC mode.
|
Step 2 |
configure terminal Example:
|
Enters global configuration mode. |
Step 3 |
interface overlay interface Example:
|
Creates an OTV overlay interface and enters interface configuration mode. |
Step 4 |
otv isis csnp-interval seconds Example:
|
(Optional) Specifies the interval between complete sequence number PDUs (CSNPs) sent on an interface. Default interval value is 10. |
Step 5 |
otv isis hello-interval [seconds | minimal] Example:
|
(Optional) Specifies the interval between hello PDUs on an interface. Default interval value is 10. |
Step 6 |
otv isis hello-multiplier multiplier Example:
|
(Optional) Specifies the multiplier that is used to calculate the interval within which hello PDUs must be received to keep the OTV adjacency up. Default multiplier value is 3. |
Step 7 |
no otv isis hello padding Example:
|
(Optional) Pads OTV hello PDUs to the full MTU length. It is enabled by default. |
Step 8 |
otv isis lsp-interval milliseconds Example:
|
(Optional) Specifies the interval between LSP PDUs on an interface during flooding. Default interval value is 33. |
Step 9 |
otv isis metric {metric | maximum} [delay-metric | expense-metric | error-metric] Example:
|
(Optional) Configures the OTV metric on an interface. Default value is 10. |
Step 10 |
otv isis priority value Example:
|
(Optional) Configures the OTV priority for the designated router election. Default value is 64. |
Step 11 |
end Example:
|
Exits interface configuration mode and returns to privileged EXEC mode. |
Virtual Machine (VM1) should be reachable to the edge device 1. In this example, the MAC Address of VM1 is 000b.45b7.82c0.
The following example shows how to configure an edge device 1:
Device# 10:52 AM
ip multicast-routing distributed
!
ip igmp snooping querier version 3
ip igmp snooping querier
!
otv site bridge-domain 10
otv site-identifier 0000.0000.0001
!
interface overlay 1
no shutdown
otv vpn-name overlay1_site1
otv control-group 239.1.1.1
otv data-group 232.1.1.0/28
otv join-interface GigabitEthernet 0/0/2
!
service instance 20 ethernet
encapsulation dot1q 20
bridge-domain 20
!
interface GigabitEthernet 0/0/2
description "Join Interface"
ip address 209.165.201.1 255.255.255.224
ip pim passive
ip igmp version 3
!
interface GigabitEthernet 0/0/0
description "Internal Interface"
!
service instance 10 ethernet
encapsulation dot1q 10
bridge-domain 10
!
service instance 20 ethernet
encapsulation dot1q 20
bridge-domain 20
!
ip pim ssm default
The following example shows how to configure a Switch 1:
SW1#show running-config interface GigabitEthernet 0/0
!
interface GigabitEthernet0/0
description “Connected to Edge Device-1”
switchport
switchport trunk encapsulation dot1q
switchport mode trunk
mtu 9216
no ip address
end
SW1#
SW1#show running-config interface GigabitEthernet 0/1
!
interface GigabitEthernet0/1
description “Connected to VM1”
switchport
switchport access vlan 20
switchport mode access
mtu 9216
no ip address
end
SW1#
Virtual Machine (VM2) should be reachable to the edge device 2. In this example, the MAC Address of VM2 is 0013.5f1c.6ec0.
ip multicast-routing distributed
!
ip igmp snooping querier version 3
ip igmp snooping querier
!
otv site bridge-domain 11
otv site-identifier 0000.0000.0002
!
interface overlay 1
no shutdown
otv vpn-name overlay1_site2
otv control-group 239.1.1.1
otv data-group 232.1.1.0/28
otv join-interface GigabitEthernet 0/0/2
!
service instance 20 ethernet
encapsulation dot1q 20
bridge-domain 20
!
interface GigabitEthernet 0/0/2
description "Join Interface"
ip address 209.165.201.2 255.255.255.224
ip pim passive
ip igmp version 3
!
interface GigabitEthernet 0/0/0
description "Internal Interface"
!
service instance 11 ethernet
encapsulation dot1q 11
bridge-domain 11
!
service instance 20 ethernet
encapsulation dot1q 20
bridge-domain 20
!
ip pim ssm default
The following example shows how to configure a Switch 2:
SW2#show running-config interface GigabitEthernet 0/0
!
interface GigabitEthernet0/0
description “Connected to Edge Device-2”
switchport
switchport trunk encapsulation dot1q
switchport mode trunk
mtu 9216
no ip address
end
SW2#
SW2#show running-config interface GigabitEthernet 0/1
!
interface GigabitEthernet0/1
description “Connected to VM2”
switchport
switchport access vlan 20
switchport mode access
mtu 9216
no ip address
end
SW2#
The following example shows how to configure OTV using multicast.
ip multicast-routing distributed
ip igmp snooping querier version 3
ip igmp snooping querier
otv site bridge-domain 11
otv site-identifier 0000.0000.0002
interface GigabitEthernet0/0/0
description "ACCESS / INTERNAL INTERFACE"
no shutdown
negotiation auto
service instance 11 ethernet
encapsulation dot1q 11
bridge-domain 11
!
service instance 20 ethernet
encapsulation dot1q 20
bridge-domain 20
interface GigabitEthernet0/0/1
no ip address
no shutdown
negotiation auto
router ospf 14
router-id 14.14.14.1
interface GigabitEthernet0/0/2
description "JOIN INTERFACE"
encapsulation dot1Q 11
ip address 209.165.201.1 255.255.255.224
ip pim passive
ip igmp version 3
ip ospf 14 area 14
interface Overlay1
no ip address
no shutdown
otv control-group 239.1.1.1
otv data-group 232.1.1.0/28
otv join-interface GigabitEthernet0/0/2
service instance 11 ethernet
encapsulation dot1q 11
bridge-domain 11
CORE:
ip multicast-routing distributed
router ospf 14
router-id 14.14.14.2
interface Loopback14
ip address 14.14.14.14 255.255.255.255
ip ospf 14 area 14
ip pim rp-address 14.14.14.14
interface GigabitEthernet0/0/0
no ip address
no shutdown
negotiation auto
interface GigabitEthernet0/0/2
description "CORE INTERFACE CONNECTED TO ED1"
encapsulation dot1Q 14
ip address 209.165.201.1 255.255.255.224
ip pim sparse-mode
ip igmp version 3
ip ospf 14 area 14
interface GigabitEthernet0/0/0
no ip address
no shutdown
negotiation auto
interface GigabitEthernet0/0/1
description "CORE INTERFACE CONNECTED TO ED2"
encapsulation dot1Q 11
ip address 209.165.201.1 255.255.255.224
ip pim sparse-mode
ip igmp version 3
ip ospf 14 area 14
ED2:
ip multicast-routing distributed
ip igmp snooping querier version 3
ip igmp snooping querier
otv site bridge-domain 12
otv site-identifier 0000.0000.0003
interface GigabitEthernet0/0/0
description "ACCESS / INTERNAL INTERFACE"
no shutdown
negotiation auto
service instance 11 ethernet
encapsulation dot1q 11
bridge-domain 11
!
service instance 12 ethernet
encapsulation dot1q 12
bridge-domain 12
interface GigabitEthernet0/0/3
no ip address
no shutdown
negotiation auto
router ospf 14
router-id 14.14.14.3
interface GigabitEthernet0/0/4
description "JOIN INTERFACE"
encapsulation dot1Q 11
ip address 209.165.201.1 255.255.255.224
ip pim passive
ip igmp version 3
ip ospf 14 area 14
interface Overlay11
no ip address
no shutdown
otv control-group 239.1.1.1
otv data-group 232.1.1.0/28
otv join-interface GigabitEthernet0/0/4
service instance 11 ethernet
encapsulation dot1q 11
bridge-domain 11
The following is sample output from the show otv command:
Edge-Device-1#show otv overlay1
Overlay Interface Overlay1
VPN name : overlay1_site1
VPN ID : 1
State : UP
Fwd-capable : Yes
Fwd-ready : Yes
AED-Server : Yes
Backup AED-Server : No
AED Capable : Yes
IPv4 control group : 239.1.1.1
Mcast data group range(s): 232.1.1.0/28
Join interface(s) : GigabitEthernet0/0/2
Join IPv4 address : 209.165.201.1
Tunnel interface(s) : Tunnel0
Encapsulation format : GRE/IPv4
Site Bridge-Domain : 10
Capability : Multicast-reachable
Is Adjacency Server : No
Adj Server Configured : No
Prim/Sec Adj Svr(s) : None
Edge-Device-1#
The following sample output from the show otv adjacency command shows the OTV overlay adjacency status:
Edge-Device-1#show otv overlay 1 adjacency
Overlay Adjacency Database for overlay 1
Hostname System-ID Dest Addr Site-ID Up Time State
Edge-Device-2 e4aa.5d0f.9b00 209.165.201.2 0000.0000.0002 01:15:13 UP
Edge-Device-1#
The following sample output from the show otv vlan command shows the OTV VLAN AED status:
Edge-Device-1#show otv overlay 1 vlan
Overlay 1 VLAN Configuration Information
Inst VLAN BD Auth ED State Site If(s)
0 20 20 *Device active Gi0/0/0:SI20
Total VLAN(s): 1
Edge-Device-1#
The following sample output from the show otv route command shows the OTV unicast routing table:
Edge-Device-1#show otv overlay 1 route
Codes: BD - Bridge-Domain, AD - Admin-Distance,
SI - Service Instance, * - Backup Route
OTV Unicast MAC Routing Table for Overlay1
Inst VLAN BD MAC Address AD Owner Next Hops(s)
----------------------------------------------------------
0 20 20 000b.45b7.82c0 40 BD Eng Gi0/0/0:SI20
0 20 20 0013.5f1c.6ec0 50 ISIS Edge-Device-2
2 unicast routes displayed in Overlay1
----------------------------------------------------------
2 Total Unicast Routes Displayed
Edge-Device-1#
The following sample output from the show otv mroute command shows the OTV multicast routing table:
Device# show otv mroute
OTV Multicast Routing Table for Overlay1
Bridge-Domain = 2, s = *, g = *
Outgoing interface list:
Default, NoRedist
Incoming interface count = 0, Outgoing interface count = 1
Bridge-Domain = 3, s = *, g = *
Outgoing interface list:
Default, NoRedist
Incoming interface count = 0, Outgoing interface count = 1
Bridge-Domain = 4, s = *, g = *
Outgoing interface list:
Default, NoRedist
Incoming interface count = 0, Outgoing interface count = 1
Bridge-Domain = 10, s = *, g = 224.0.1.40
Outgoing interface list:
Overlay1, ED3
Incoming interface count = 0, Outgoing interface count = 1
Bridge-Domain = 11, s = *, g = *
Outgoing interface list:
Default, NoRedist
Incoming interface count = 0, Outgoing interface count = 1
5 multicast routes displayed in Overlay1
----------------------------------------------------------
5 Total Multicast Routes Displayed
The following sample output from the show otv data-group command shows the OTV data group multicast address mappings:
Device# show otv data-group
Flags: D - Local active source dynamically detected
S - Local active source statically configured
J - Data group has been joined in the core
U - Data group has not been joined in the core
Remote Active Sources for Overlay1
BD Active-Source Active-Group Delivery-Source Delivery-Group Flags
1 10.0.1.1 232.0.0.1 209.165.201.10 232.5.0.0 U
2 10.0.2.1 232.0.0.1 209.165.201.10 232.5.0.1 U
3 10.0.3.1 232.0.0.1 209.165.201.10 232.5.0.2 U
4 10.0.4.1 232.0.0.1 209.165.201.10 232.5.0.3 U
5 10.0.5.1 232.0.0.1 209.165.201.10 232.5.0.4 J
6 10.0.6.1 232.0.0.1 209.165.201.10 232.5.0.5 J
Displayed 6 remote data-group mappings
Local Active Sources for Overlay1
BD Active-Source Active-Group Delivery-Source Delivery-Group Flags
1 10.0.1.1 232.0.0.1 209.165.201.10 232.5.0.0 D
2 10.0.2.1 232.0.0.1 209.165.201.10 232.5.0.1 D
3 10.0.3.1 232.0.0.1 209.165.201.10 232.5.0.2 D
4 10.0.4.1 232.0.0.1 209.165.201.10 232.5.0.3 D
5 10.0.5.1 232.0.0.1 209.165.201.10 232.5.0.4 D
6 10.0.6.1 232.0.0.1 209.165.201.10 232.5.0.5 D
7 10.0.7.1 232.0.0.1 209.165.201.10 232.5.0.6 D
8 10.0.8.1 232.0.0.1 209.165.201.10 232.5.0.7 D
9 10.0.9.1 232.0.0.1 209.165.201.10 232.5.0.8 D
Displayed 9 local data-group mappings
The following is sample output for configuring OTV using multicast.
ED2#show otv
Overlay Interface Overlay1
VPN name : overlay1_site1
VPN ID : 1
State : UP
AED Capable : Yes
IPv4 control group : 239.1.1.1
Mcast data group range(s): 232.1.1.0/28
Join interface(s) : GigabitEthernet0/0/2
Join IPv4 address : 209.165.201.1
Tunnel interface(s) : Tunnel0
Encapsulation format : GRE/IPv4
Site Bridge-Domain : 10
Capability : Multicast-reachable
Is Adjacency Server : No
Adj Server Configured : No
Prim/Sec Adj Svr(s) : None
ED2#
MAC updates related to both VM1 and VM2:
ED2#show otv isis rib mac
Tag Overlay1:
MAC local rib for Overlay1 (Total 1)
L2 Topology ID Mac Address
14 000C.295E.EA91 --> MAC address VM1
[50/1] via 209.165.201.1(Overlay1), LSP[3/2]
ED2#
The below MAC addresses is sent to the other ED's [these MAC addresses are sent from ED2 to ED1]:
ED2#show otv isis rib redistribution mac
Tag Overlay1:
MAC redistribution local rib for Overlay1 (Total 3)
L2 Topology ID Mac Address
14 000C.297E.8CD5
State: Up/Best/Advertised Metric: 1
14 000C.2980.1494 --> MAC address VM2
State: Up/Best/Advertised Metric: 1
14 0050.56BF.4129
State: Up/Best/Advertised Metric: 1
ED2#
The below command is the one using which OTV does ARP suppression:
ED2#show otv arp-nd-cache
Overlay150 ARP/ND L3->L2 Address Mapping Cache
BD MAC Layer-3 Address Age (HH:MM:SS) Local/Remote
14 000c.295e.ea91 172.16.11.20 00:01:24 Remote
ED2#
Finally, the packet is routed out using the below table.
ED2#show otv route
Codes: BD - Bridge-Domain, AD - Admin-Distance,
SI - Service Instance, * - Backup Route
OTV Unicast MAC Routing Table for Overlay150
Inst VLAN BD MAC Address AD Owner Next Hops(s)
----------------------------------------------------------
0 14 14 000c.295e.ea91 50 ISIS ED1
0 14 14 000c.297e.8cd5 40 BD Eng Gi0/0/1:SI14
0 14 14 000c.2980.1494 40 BD Eng Gi0/0/1:SI14
0 14 14 0050.56bf.4129 40 BD Eng Gi0/0/1:SI14
4 unicast routes displayed in Overlay1
----------------------------------------------------------
4 Total Unicast Routes Displayed
ED2#
Use the following commands to display the required OTV configuration information. You can use one or more commands, as required, in any order.
Step 1 |
show otv [overlay overlay-interface] Use this command to display the overlay status and parameters. Example:
|
Step 2 |
show otv [overlay overlay-interface] arp-nd-cache Use this command to display the Layer 3 to Layer 2 address mapping cache that is used for ARP suppression. Example:
|
Step 3 |
show otv data-group [local | remote] [detail] Use this command to display the advertised multicast groups. Example:
|
Step 4 |
show otv log {event | error} Use this command to display the OTV debug log of events or errors. Example:
|
Step 5 |
show otv [overlay overlay-interface] adjacency Use this command to display information about neighbors in an overlay network. Example:
|
Step 6 |
show otv [overlay overlay-interface] vlan [authoritative] Use this command to display information about the enabled OTV VLANs. Example:
|
Step 7 |
show otv [overlay overlay-interface] site Use this command to display OTV site information such as the site VLAN and neighbors within the site. Example:
|
Step 8 |
show otv route Use this command to display unicast OTV MAC routes from the MLRIB route database. Example:
|
Step 9 |
show otv mroute Use this command to display OTV multicast routes from the MLRIB route database. Example:
|
Related Topic |
Document Title |
---|---|
Wide-area networking commands: complete command syntax, command mode, defaults, usage guidelines, and examples |
Description |
Link |
---|---|
The Cisco Support and Documentation website provides online resources to download documentation, software, and tools. Use these resources to install and configure the software and to troubleshoot and resolve technical issues with Cisco products and technologies. Access to most tools on the Cisco Support and Documentation website requires a Cisco.com user ID and password. |
The following table provides release information about the feature or features described in this module. This table lists only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise, subsequent releases of that software release train also support that feature.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Feature Name |
Releases |
Feature Information |
---|---|---|
OTV—Overlay Transport Virtualization |
Cisco IOS XE Release 3.5S |
OTV provides Layer 2 connectivity between remote network sites by using MAC-address-based routing and IP-encapsulated forwarding across a transport network to provide support for applications that require Layer 2 adjacency. The following commands were introduced or modified: authentication key-chain (OTV) , authentication mode (OTV) , authentication send-only (OTV) , clear otv arp-nd , clear otv isis , clear otv isis lspfull , clear otv isis neighbors , clear otv isis rib , debug l2fib , debug mlrib common , debug mlrib layer2 , debug otv , debug otv isis , debug platform software l2fib , debug platform software otv , debug platform hardware qfp feature otv client , debug platform hardware qfp feature otv datapath , hostname dynamic (OTV) , interface overlay , log-adjacency-changes (OTV) , lsp-gen-intervaL (OTV) , lsp-mtu (OTV) , lsp-refresh-interval (OTV) , max-lsp-lifetime (OTV) , nsf (OTV) , otv active-source , otv control-group , otv data-group , otv filter-fhrp , otv fragmentation , otv isis authentication , otv isis csnp-interval , otv isis hello-interval , otv isis hello-multiplier , otv isis hello padding , otv isis lsp-interval , otv isis metric , otv isis overlay , otv isis priority , otv isis retransmit-interval , otv isis retransmit-throttle-interval , otv isis site otv join-interface , otv mac flood , otv site bridge-domain , otv site-identifier , otv suppress arp-nd , otv vpn-name , prc-interval (OTV) , show l2fib , show mlrib common log , show mlrib layer2 log , show otv , show otv adjacency , show otv arp-nd-cache , show otv data-group , show otv isis database , show otv isis hostname , show otv isis lsp-log , show otv isis neighbors , show otv isis nsf , show otv isis protocol , show otv isis rib , show otv isis spf-log , show otv isis vlan-database , show otv log , show otv mroute , show otv route , show otv site , show otv statistics , show otv summary , show otv vlan , show platform hardware qfp feature otv client interface , show platform software l2fib fp , show platform software l2fib rp , show platform software otv fp , skeptical interval (OTV) , spf-interval (OTV) . |