You can have only two devices as vPC peers; each device can serve as a vPC peer to only one other vPC peer. The vPC peer devices can also have non-vPC links to other devices.

See the following figure for invalid vPC peer configurations.

To make a valid configuration, you first configure a port channel on each device and then configure the vPC domain. You assign the port channel on each device as a vPC Peer-Link, using the same vPC domain ID. For redundancy, we recommend that you should configure at least two of the dedicated ports into the port channel because if one of the interfaces in the vPC Peer-Link fails, the device automatically falls back to use another interface in the vPC Peer-Link.

Note	We recommend that you configure the Layer 2 port channels in trunk mode.

Many operational parameters and configuration parameters must be the same in each device connected by a vPC Peer-Link (see the Compatibility Parameters for vPC Interfaces section). Because each device is completely independent on the management plane, you must ensure that the devices are compatible on the critical parameters. vPC peer devices have separate control planes. After configuring the vPC Peer-Link, you should display the configuration on each vPC peer device to ensure that the configurations are compatible.

Note	You must ensure that the two devices connected by the vPC Peer-Link have certain identical operational and configuration parameters. For more information on required configuration consistency, see the Compatibility Parameters for vPC Interfaces section.

When you configure the vPC Peer-Link, the vPC peer devices negotiate that one of the connected devices is the primary device and the other connected device is the secondary device (see the “Configuring vPCs” section). By default, the Cisco NX-OS software uses the lowest MAC address to elect the primary device. However, if the role priority is set, then the device with the lowest priority will be elected as the primary device. The software takes different actions on each device—that is, the primary and secondary—only in certain failover conditions. If the primary device fails, the secondary device becomes the new primary device when the system recovers, and the previously primary device is now the secondary device.

You can also configure which of the vPC devices is the primary device. Changing the priority of the vPC peer devices can cause the interfaces in your network to go up and down. If you want to configure the role priority again to make one vPC device the primary device, configure the role priority on both the primary vPC device with a lower priority value and the secondary vPC device with the higher value. Then, shut down the port channel that is the vPC Peer-Link on both devices by entering the shutdown command, and finally reenable the port channel on both devices by entering the no shutdown command.

Note	We recommend that you use two different modules for redundancy on each vPC peer device on each vPC Peer-Link.

The software keeps all traffic that forwards across the vPC peer devices as local traffic. A packet that ingresses the port channel uses one of the local links rather than moving across the vPC Peer-Link. Unknown unicast, multicast, and broadcast traffic (including STP BPDUs) are flooded across the vPC Peer-Link. The software keeps the multicast forwarding state synchronized on both of the vPC peer devices.

You can configure any of the standard load-balancing schemes on both the vPC Peer-Link devices and the downstream device (see the Configuring Port Channels chapter for information about load balancing).

Configuration information flows across the vPC Peer-Links using the Cisco Fabric Services over Ethernet (CFSoE) protocol. (See the CFSoE section for more information about CFSoE.)

All MAC addresses for those VLANs configured on both devices are synchronized between vPC peer devices. The software uses CFSoE for this synchronization. (See the CFSoE section for information about CFSoE.)

If the vPC Peer-Link fails, the software checks the status of the remote vPC peer device using the peer-keepalive link, which is a link between vPC peer devices that ensures that both devices are up. If the vPC peer device is up, the secondary vPC device disables all vPC ports on its device, to prevent loops and disappearing or flooding traffic. The data then forwards down the remaining active links of the port channel.

Note	We recommend that you create and configure a separate VRF and configure a Layer 3 port on each vPC peer device in that VRF for the vPC peer-keepalive link. The default ports and VRF for the peer-keepalive are the management ports and VRF.

The software learns of a vPC peer device failure when the keepalive messages are not returned over the peer-keepalive link.

Use a separate link (vPC peer-keepalive link) to send configurable keepalive messages between the vPC peer devices. The keepalive messages on the vPC peer-keepalive link determines whether a failure is on the vPC Peer-Link only or on the vPC peer device. The keepalive messages are used only when all the links in the vPC Peer-Link fail. See the “Peer-Keepalive Link and Messages” section for information about the keepalive message.

You must manually configure the following features to conform to the primary/secondary mapping of each of the vPC peer devices:

• STP root—Configure the primary vPC peer device as the STP primary root device and configure the vPC secondary device to be the STP secondary root device. See the “vPC Peer-Links and STP” section for more information about vPCs and STP.

  • We recommend that you configure the vPC Peer-Link interfaces as STP network ports so that Bridge Assurance is enabled on all vPC Peer-Links.

  • We recommend that you configure Rapid per VLAN Spanning Tree plus (PVST+) so that the primary device is the root for all VLANs and configure Multiple Spanning Tree (MST) so that the primary device is the root for all instances.

• Layer 3 VLAN network interface—Configure Layer 3 connectivity from each vPC peer device by configuring a VLAN network interface for the same VLAN from both devices.

• HSRP active—If you want to use Hot Standby Router Protocol (HSRP) and VLAN interfaces on the vPC peer devices, configure the primary vPC peer device with the HSRP active highest priority. Configure the secondary device to be the HSRP standby and ensure that you have VLAN interfaces on each vPC device that are in the same administrative and operational mode. (See the “vPC Peer-Links and Routing” section for more information on vPC and HSRP.)

While you configure Unidirectional Link Detection (UDLD), note the following recommendations:

• If LACP is used as port-channel aggregation protocol, UDLD is not required in a vPC domain.

• If LACP is not used as the port-channel aggregation protocol (static port-channel), use UDLD in normal mode on vPC member ports.

• If STP is used without Bridge Assurance and if LACP is not used, use UDLD in normal mode on vPC orphan ports.

The configuration parameters in this section must be configured identically on both devices of the vPC Peer-Link; otherwise, the vPC moves fully or partially into a suspended mode.

Note	You must ensure that all interfaces in the vPC have the identical operational and configuration parameters listed in this section.

Note	Enter the show vpc consistency-parameters command to display the configured values on all interfaces in the vPC. The displayed configurations are only those configurations that would limit the vPC Peer-Link and vPC from coming up.

The devices automatically check for compatibility for some of these parameters on the vPC interfaces. The per-interface parameters must be consistent per interface, and the global parameters must be consistent globally:

• Port-channel mode: on, off, or active (port-channel mode can, however, be active/passive on each side of the vPC peer)

• The [no] lacp suspend-individual pxe configuration must be the same on both the sides of the vPC.

• Link speed per channel

• Duplex mode per channel

• Trunk mode per channel:

  • Native VLAN

  • VLANs allowed on trunk

  • Tagging of native VLAN traffic

• Spanning Tree Protocol (STP) mode

• STP region configuration for Multiple Spanning Tree

• Enable/disable state per VLAN

• STP global settings:

  • Bridge Assurance setting

  • Port type setting

  • Loop Guard settings

• STP interface settings:

  • Port type setting

  • Loop Guard

  • Root Guard

• Maximum Transmission Unit (MTU)

If any of these parameters are not enabled or defined on either device, the vPC consistency check ignores those parameters.

Note

To ensure that none of the vPC interfaces are in the suspend mode, enter the show vpc brief and show vpc consistency-parameters commands and check the syslog messages. In the output of show vpc or show vpc brief command, after every 50th configured vPC port-channel the following message will be displayed: Please check "show vpc consistency-parameters vpc <vpc-num>" for the consistency reason of down vpc and for type-2 consistency reasons for any vpc.

When any of the following parameters are not configured identically on both vPC peer devices, a misconfiguration might cause undesirable behavior in the traffic flow:

• MAC aging timers

• Static MAC entries

• VLAN interface—Each device on the end of the vPC Peer-Link must have a VLAN interface configured for the same VLAN on both ends and they must be in the same administrative and operational mode. Those VLANs configured on only one device of the vPC Peer-Link do not pass traffic using the vPC or vPC Peer-Link. You must create all VLANs on both the primary and secondary vPC devices, or the VLAN will be suspended.

• All ACL configurations and parameters

• Quality of Service (QoS) configuration and parameters

• STP interface settings:

  • BPDU Filter

  • BPDU Guard

  • Cost

  • Link type

  • Priority

  • VLANs (Rapid PVST+)

• Port security

• Cisco Trusted Security (CTS)

• Dynamic Host Configuration Protocol (DHCP) snooping

• Network Access Control (NAC)

• Dynamic ARP Inspection (DAI)

• IP source guard (IPSG)

• Internet Group Management Protocol (IGMP) snooping

• Hot Standby Routing Protocol (HSRP)

• Protocol Independent Multicast (PIM)

• Gateway Load-Balancing Protocol (GLBP)

• All routing protocol configurations

To ensure that all the configuration parameters are compatible, we recommend that you display the configurations for each vPC peer device once you configure the vPC.

You can configure the graceful consistency check feature, which suspends only the links on the secondary peer device when a mismatch is introduced in a working vPC. This feature is configurable only in the CLI and is enabled by default.

The graceful consistency-check command is configured by default.

As part of the consistency check of all parameters from the list of parameters that must be identical, the system checks the consistency of all VLANs.

The vPC remains operational, and only the inconsistent VLANs are brought down. This per-VLAN consistency check feature cannot be disabled and does not apply to Multiple Spanning Tree (MST) VLANs.

LACP uses the system MAC address of the vPC domain to form the LACP Aggregation Group (LAG) ID for the vPC. (See the “Configuring Port Channels” chapter for information about LAG-ID and LACP.)

You can use LACP on all the vPC port channels, including those channels from the downstream device. We recommend that you configure LACP with active mode on the interfaces on each port channel on the vPC peer devices. This configuration allows you to more easily detect compatibility between devices, unidirectional links, and multihop connection, and provides dynamic reaction to run-time changes and link failures.

We recommend that you manually configure the system priority on the vPC Peer-Link devices to ensure that the vPC Peer-Link devices have a higher LACP priority than the downstream connected devices. A lower numerical value system priority means a higher LACP priority.

Note	When manually configuring the system priority, you must ensure that you assign the same priority value on both vPC peer devices. If the vPC peer devices have different system priority values, vPC does not come up.

Although vPCs provide a loop-free Layer 2 topology, STP is still required to provide a fail-safe mechanism to protect against any incorrect or defective cabling or possible misconfiguration. When you first bring up a vPC, STP reconverges. STP treats the vPC Peer-Link as a special link and always includes the vPC Peer-Link in the STP active topology.

We recommend that you set all the vPC Peer-Link interfaces to the STP network port type so that Bridge Assurance is automatically enabled on all vPC Peer-Links. We also recommend that you do not enable any of the STP enhancement features on vPC Peer-Links. If the STP enhancements are already configured, they do not cause any problems for the vPC Peer-Links..

When you are running both MST and Rapid PVST+, ensure that the PVST simulation feature is correctly configured.

See the Cisco Nexus 9000 Series NX-OS Layer 2 Switching Configuration Guide for information about STP enhancement features and PVST simulation.

Note	You must configure a list of parameters to be identical on the vPC peer devices on both sides of the vPC Peer-Link. See the “Compatibility Parameters for vPC Interfaces” section for information about these required matched settings.

STP is distributed; that is, the protocol continues running on both vPC peer devices. However, the configuration on the vPC peer device elected as the primary device controls the STP process for the vPC interfaces on the secondary vPC peer device.

The primary vPC device synchronizes the STP state on the vPC secondary peer device using Cisco Fabric Services over Ethernet (CFSoE). See the “vPC and Orphan Ports” section for information about CFSoE.

The STP process for vPC also relies on the periodic keepalive messages to determine when one of the connected devices on the vPC Peer-Link fails. See the “Peer-Keepalive Link and Messages” section for information about these messages.

The vPC manager performs a proposal/handshake agreement between the vPC peer devices that set the primary and secondary devices and coordinates the two devices for STP. The primary vPC peer device then controls the STP protocol on both the primary and secondary devices. We recommend that you configure the primary vPC peer device as the STP primary root device and configure the secondary VPC device to be the STP secondary root device.

If the primary vPC peer device fails over to the secondary vPC peer device, there is no change in the STP topology.

The BPDUs uses the MAC address set for the vPC for the STP bridge ID in the designated bridge ID field. The vPC primary device sends these BPDUs on the vPC interfaces.

You must configure both ends of vPC Peer-Link with the identical STP configuration for the following parameters:

• STP global settings:

  • STP mode

  • STP region configuration for MST

  • Enable/disable state per VLAN

  • Bridge Assurance setting

  • Port type setting

  • Loop Guard settings

• STP interface settings:

  • Port type setting

  • Loop Guard

  • Root Guard

Note	If any of these parameters are misconfigured, the Cisco NX-OS software suspends all interfaces in the vPC. Check the syslog and enter the show vpc brief command to see if the vPC interfaces are suspended.

Ensure that the following STP interface configurations are identical on both sides of the vPC Peer-Links or you may see unpredictable behavior in the traffic flow:

• BPDU Filter

• BPDU Guard

• Cost

• Link type

• Priority

• VLANs (PVRST+)

Note	Display the configuration on both sides of the vPC Peer-Link to ensure that the settings are identical.

You can use the show spanning-tree command to display information about the vPC when that feature is enabled. See the Cisco Nexus 9000 Series NX-OS Layer 2 Switching Configuration Guide for an example.

Note	We recommend that you configure the ports on the downstream devices as STP edge ports. You should configure all host ports connected to a switch as STP edge ports. See the Cisco Nexus 9000 Series NX-OS Layer 2 Switching Configuration Guide for more information about STP port types.

The vPC peer switch feature was added to Cisco NX-OS to address performance concerns around STP convergence. This feature allows a pair of Cisco Nexus 9000 Series devices to appear as a single STP root in the Layer 2 topology. This feature eliminates the need to pin the STP root to the vPC primary switch and improves vPC convergence if the vPC primary switch fails.

To avoid loops, the vPC Peer-Link is excluded from the STP computation. In vPC peer switch mode, STP BPDUs are sent from both vPC peer devices to avoid issues related to STP BPDU timeout on the downstream switches, which can cause traffic disruption.

This feature can be used with the pure peer switch topology in which the devices all belong to the vPC.

Note

Peer-switch feature is supported on networks that use vPC and STP-based redundancy is not supported. If the vPC Peer-Link fail in a hybrid peer-switch configuration, you can lose traffic. In this scenario, the vPC peers use the same STP root ID as well as the same bridge ID. The access switch traffic is split in two with half going to the first vPC peer and the other half to the second vPC peer. With vPC Peer-Link failure, there is no impact to the north/south traffic but the east/west traffic is lost.

See the Cisco Nexus 9000 Series NX-OS Layer 2 Switching Configuration Guide for information about STP enhancement features and Rapid PVST+.

You can configure vPC peer devices to act as the gateway even for packets that are destined to the vPC peer device’s MAC address.

Use the peer-gateway command to configure this feature.

Note	You can use the mode auto command to automatically enable this feature. See the “Enabling Certain vPC Commands Automatically” section for more information about using this command.

Note	The peer-gateway exclude-vlan variation of the command that specifies VLANs to be excluded from peer-gateway functionality is not supported. The peer-gateway exclude-vlan command that is used when configuring a VLAN interface for Layer 3 backup routing on vPC peer devices is not supported.

Some network-attached storage (NAS) devices or load balancers might have features that help to optimize the performances of particular applications. These features enable the device to avoid a routing-table lookup when responding to a request that originated from a host that is not locally attached to the same subnet. Such devices might reply to traffic using the MAC address of the sender Cisco Nexus 9000 Series device rather than the common HSRP gateway. This behavior is noncomplaint with some basic Ethernet RFC standards. Packets that reach a vPC device for the nonlocal router MAC address are sent across the vPC Peer-Link and could be dropped by the built in vPC loop avoidance mechanism if the final destination is behind another vPC.

The vPC peer-gateway capability allows a vPC switch to act as the active gateway for packets that are addressed to the router MAC address of the vPC peer. This feature enables local forwarding of packets without the need to cross the vPC Peer-Link. In this scenario, the feature optimizes use of the vPC Peer-Link and avoids potential traffic loss.

Configuring the peer-gateway feature must be done on both primary and secondary vPC peers and is nondisruptive to the operations of the device or to the vPC traffic. The vPC peer-gateway feature can be configured globally under the vPC domain submode.

When you enable this feature, Cisco NX-OS automatically disables IP redirects on all interface VLANs mapped over a vPC VLAN to avoid generation of IP redirect messages for packets switched through the peer gateway router.

Packets that arrive at the peer-gateway vPC device have their Time to Live (TTL) decremented, so that packets carrying a TTL of 1 might get dropped in transit due to TTL expiration. You should take this situation into account when the peer-gateway feature is enabled and particular network protocols that source packets with a TTL of 1 operate on a vPC VLAN.

A feature was added to Cisco NX-OS to address table synchronization across vPC peers using the reliable transport mechanism of the Cisco Fabric Service over Ethernet (CFSoE) protocol. You must enable the ip arp synchronize and ipv6 nd synchronize commands to support faster convergence of address tables between the vPC peers. This convergence overcomes the delay that occurs in ARP table restoration for IPv4 or ND table restoration for IPv6 when the vPC Peer-Link port channel flaps or when a vPC peer comes back online.

Note	You can use the mode auto command to automatically enable this feature. See the “Enabling Certain vPC Commands Automatically” section for information about using this command.

The Cisco NX-OS software for the Nexus 9000 Series devices supports the following on a vPC:

• PIM Any Source Multicast (ASM).

• PIM Source-Specific Multicast (SSM) (7.0(3)I4(1) and later).

Note	The Cisco NX-OS software does not support Product Independent Multicast (PIM), Source-Specific Multicast (SSM) or Bidirectional (BIDR) on a vPC.

The software keeps the multicast forwarding state synchronized on both of the vPC peer devices. The IGMP snooping process on a vPC peer device shares the learned group information with the other vPC peer device through the vPC Peer-Link; the multicast states are always synchronized on both vPC peer devices. The PIM process in vPC mode ensures that only one of the vPC peer devices forwards the multicast traffic to the receivers.

Each vPC peer is a Layer 2 or Layer 3 device. Multicast traffic flows from only one of the vPC peer devices. You might see duplicate packets in the following scenarios:

• Orphan hosts

• When the source and receivers are in the Layer 2 vPC cloud in different VLANs with multicast routing enabled and a vPC member link goes down.

You might see negligible traffic loss in the following scenarios:

• When you reload the vPC peer device that is forwarding the traffic.

• When you restart PIM on the vPC peer device that is forwarding the traffic.

Overall multicast convergence times are scale and vPC role change / PIM restart duration dependent.

Ensure that you dual-attach all Layer 3 devices to both vPC peer devices. If one vPC peer device goes down, the other vPC peer device continues to forward all multicast traffic normally.

The following outlines vPC PIM and vPC IGMP/IGMP snooping:

• vPC PIM—The PIM process in vPC mode ensures that only one vPC peer device forwards multicast traffic. The PIM process in vPC mode synchronizes the source state with both vPC peer devices and elects which vPC peer device forwards the traffic.

• vPC IGMP/IGMP snooping—The IGMP process in vPC mode synchronizes the designated router (DR) information on both vPC peer devices. Dual DRs are available for IGMP when you are in vPC mode. Dual DRs are not available when you are not in vPC mode, because both vPC peer devices maintain the multicast group information between the peers.

Note

A PIM adjacency between a Switched Virtual Interface (SVI) on a vPC VLAN (a VLAN that is carried on a vPC Peer-Link) and a downstream device is not supported; this configuration can result in dropped multicast packets. If a PIM neighbor relationship is required with a downstream device, a physical Layer 3 interface must be used on the Nexus switches instead of a vPC SVI. For SVIs on vPC VLANs, only one PIM adjacency is supported, which is with the vPC peer switch. PIM adjacencies over the vPC Peer-Link with devices other than the vPC peer switch for the vPC-SVI are not supported.

You should enable or disable IGMP snooping identically on both vPC peer devices, and all the feature configurations should be identical. IGMP snooping is on by default.

Note	The following commands are not supported in vPC mode: ip pim spt-threshold infinity ip pim use-shared-tree-only

See the Cisco Nexus 9000 Series NX-OS Multicast Routing Configuration Guide for more information about multicasting.

By default, a multicast router sends PIM joins upstream only if it has interested receivers. These interested receivers can either be IGMP hosts (they communicate through IGMP reports) or other multicast routers (they communicate through PIM joins).

In the Cisco NX-OS vPC implementation, PIM works in dual designated router (DR) mode. That is, if a vPC device is a DR on a vPC SVI outgoing interface (OIF), its peer automatically assumes the proxy DR role. IGMP adds an OIF (the report is learned on that OIF) to the forwarding if the OIF is a DR. With dual DRs, both vPC devices have an identical (*,G) entry with respect to the vPC SVI OIFs as shown in this example:

VPC Device1:
------------
(*,G)
oif1 (igmp)
VPC Device2:
------------
(*,G)
oif1 (igmp)

When the multicast source is in a Layer 3 cloud (outside the vPC domain), one vPC peer is elected as the forwarder for the source. This forwarder election is based on the metrics to reach the source. If there is a tie, the vPC primary is chosen as the forwarder. Only the forwarder has the vPC OIFs in its associated (S,G) and the nonforwarder (S,G) has 0 OIFs. Therefore, only the forwarder sends PIM (S,G) joins toward the source as shown in this example:

VPC Device1 (say this is Forwarder for Source 'S'):
------------
(*,G)
oif1 (igmp)
(S,G)
oif1 (mrib)
VPC Device2:
------------
(*,G)
oif1 (igmp)
(S,G)
NULL

In the case of a failure (for example, a Layer 3 Reverse Path Forwarding (RPF) link on the forwarder becomes inoperable or the forwarder gets reloaded), if the current nonforwarder ends up becoming the forwarder, it has to start sending PIM joins for (S,G) toward the source to pull the traffic. Depending upon the number of hops to reach the source, this operation might take some time (PIM is a hop-by-hop protocol).

To eliminate this issue and get better convergence, use the ip pim pre-build-spt command. This command enables PIM send joins even if the multicast route has 0 OIFs. In a vPC device, the nonforwarder sends PIM (S,G) joins upstream toward the source. The downside is that the link bandwidth upstream from the nonforwarder gets used for the traffic that is ultimately dropped by it. The benefits that result with better convergence far outweigh the link bandwidth usage. Therefore, we recommend that you use this command if you use vPCs.

The First Hop Redundancy Protocols (FHRPs) interoperate with vPCs. The Hot Standby Routing Protocol (HSRP), Gateway Load Balancing Protocol (GLBP), and Virtual Router Redundancy Protocol (VRRP) all interoperate with vPCs. We recommend that you dual-attach all Layer 3 devices to both vPC peer devices.

The primary FHRP device responds to ARP requests, even though the secondary vPC device forwards the data traffic.

To simplify initial configuration verification and vPC/HSRP troubleshooting, you can configure the primary vPC peer device with the FHRP active router highest priority.

In addition, you can use the priority command in the if-hsrp configuration mode to configure failover thresholds for when a group state enabled on a vPC Peer-Link is in standby or in listen state. You can configure lower and upper thresholds to prevent the interface from going up and down.

VRRP acts similarly to HSRP when running on vPC peer devices. You should configure VRRP the same way that you configure HSRP. For GLBP, the forwarders on both vPC peer devices forward traffic.

When the primary vPC peer device fails over to the secondary vPC peer device, the FHRP traffic continues to flow seamlessly.

We recommend that you configure routing adjacency between the two vPC peer devices to act as a backup routing path. If one vPC peer device loses Layer 3 uplinks, the vPC can redirect the routed traffic to the other vPC peer device and leverage its active Layer 3 uplinks.

You can configure the inter-switch link for a backup routing path in the following ways:

• Create a Layer 3 link between the two vPC peer devices.

• Use the non-VPC VLAN trunk with a dedicated VLAN interface.

• Use a vPC Peer-Link with a dedicated VLAN interface.

We do not recommend that you configure the burnt-in MAC address option (use-bia) for HSRP or manually configure virtual MAC addresses for any FHRP protocol in a vPC environment because these configurations can adversely affect vPC load balancing. The HSRP use-bia option is not supported on vPCs. When you are configuring custom MAC addresses, you must configure the same MAC address on both vPC peer devices.

You can use the delay restore command to configure a restore timer that delays the vPC coming back up until after the peer adjacency forms and the VLAN interfaces are back up. This feature enables you to avoid packet drops when the routing tables might not be converged before the vPC is once again passing traffic. Use the delay restore command to configure this feature.

To delay the VLAN interfaces on the restored vPC peer device from coming up, use the interfaces-vlan option of the delay restore command.

See the Cisco Nexus 9000 Series NX-OS Unicast Routing Configuration Guide for more information about FHRPs and routing.

You can use VLAN network interfaces on the vPC peer devices to link to Layer 3 of the network for such applications as HSRP and PIM. Ensure that you have a VLAN network interface configured on each peer device and that the interface is connected to the same VLAN on each device. Also, each VLAN interface must be in the same administrative and operational mode. For more information about configuring VLAN network interfaces, see the “Configuring Layer 3 Interfaces” chapter.

If a failover occurs on the vPC Peer-Link, the VLAN interfaces on the vPC peer devices are also affected. If a vPC Peer-Link fails, the system brings down associated VLAN interfaces on the secondary vPC peer device.

You can ensure that specified VLAN interfaces do not go down on the vPC secondary device when the vPC Peer-Link fails.

Use the dual-active exclude interface-vlan command to configure this feature.

The Cisco Fabric Services over Ethernet (CFSoE) is a reliable state transport mechanism that is used to synchronize the actions of the vPC peer devices. CFSoE carries messages and packets for many features linked with vPC, such as STP and IGMP. Information is carried in CFS/CFSoE protocol data units (PDUs).

When you enable the vPC feature, the device automatically enables CFSoE, and you do not have to configure anything. CFSoE distributions for vPCs do not need the capabilities to distribute over IP or the CFS regions. You do not need to configure anything for the CFSoE feature to work correctly on vPCs.

The CFSoE transport is local to each VDC.

You can use the show mac address-table command to display the MAC addresses that CFSoE synchronizes for the vPC Peer-Link.

Note	Do not enter the no cfs eth distribute or the no cfs distribute command. You must enable CFSoE for vPC functionality. If you do enter either of these commands with vPC enabled, the system displays an error message.

When you enter the show cfs application command, the output displays “Physical-eth,” which shows the applications that are using CFSoE.

CFS also transports data over TCP/IP. See the Cisco Nexus 9000 Series NX-OS System Management Configuration Guide for more information about CFS over IP.

Note	The software does not support CFS regions.

When a device that is not vPC-capable connects to each peer, the connected ports are known as orphan ports because they are not members of a vPC. The device’s link to one peer will be active (forwarding) and the other link will be standby (blocking) due to STP.

If a vPC Peer-Link failure or restoration occurs, an orphan port’s connectivity might be bound to the vPC failure or restoration process. For example, if a device’s active orphan port connects to the secondary vPC peer, the device loses any connections through the primary peer if a vPC Peer-Link failure occurs and the vPC ports are suspended by the secondary peer. If the secondary peer were to also suspend the active orphan port, the device’s standby port becomes active, provides a connection to the primary peer, and restores connectivity. You can configure in the CLI that specific orphan ports are suspended by the secondary peer when it suspends its vPC ports and are restored when the vPC is restored.

You can configure the Cisco Nexus 9000 Series device to restore vPC services when its peer fails to come online by using the auto-recovery command. You must save this setting in the startup configuration. On reload, if the vPC Peer-Link is down and three consecutive peer-keepalive messages are lost, the secondary device assumes the primary STP role and the primary LACP role. The software reinitializes the vPCs, bringing up its local ports. Because there are no peers, the consistency check is bypassed for the local vPC ports. The device elects itself to be the STP primary regardless of its role priority and also acts as the primary device for LACP port roles.

Note	You can use the mode auto command to automatically enable this feature. See the“Enabling Certain vPC Commands Automatically” section for information about using this command.

vPC peer auto recovery can be delayed using auto-recovery reload-delay command. Auto-recovery reload-delay time is used on peer that comes up first. The reload-delay time command is used to wait for both peers to recover and to keep existing roles before auto recovery starts. The device then resumes primary role to recovered switch.

When the other peer device completes its reload and adjacency forms, the following process occurs:

1. The first vPC peer maintains its current role to avoid any transition reset to other protocols. The peer accepts the other available role.

2. When an adjacency forms, consistency checks are performed and appropriate actions are taken.

This example shows a topology that uses Layer 3 links to connect a Layer 3 device to the Cisco Nexus 9000 switches that are part of the a vPC domain

Note	Interconnecting the two entities together in this way allows to support Layer 3 unicast and multicast communication.

Layer 3 devices can initiate Layer 3 routing protocol adjacencies with both vPC peer devices.

One or multiple Layer 3 links can be used to connect a Layer 3 device to each vPC peer device. Cisco Nexus 9000 series devices support Layer 3 Equal Cost Multipathing (ECMP) with up to 16 hardware load-sharing paths per prefix. Traffic from a vPC peer device to a Layer 3 device can be load-balanced across all the Layer 3 links interconnecting the two devices together.

Using Layer 3 ECMP on the Layer 3 device can effectively use all Layer 3 links from the device to the vPC domain. Traffic from a Layer 3 device to the vPC domain can be load-balanced across all the Layer 3 links interconnecting the two entities together.

Follow these guidelines when connecting a Layer 3 device to the vPC domain using Layer 3 links:

• Use separate Layer 3 links to connect Layer 3 devices to the vPCdomain. Each link represents a point-to-point Layer 3 connection and should get assigned an IP address taken from a small IP subnet (/30 or /31).

• If the Layer 3 peering is required for multiple VRFs, it is recommended to define multiple sub-interfaces, each mapped to an individual VRF.

This example shows peering between the two vPC peer devices with a Layer 3 backup routed path. If the Layer 3 uplinks on vPC peer device 1 or vPC peer device 2 fail, the path between the two peer devices is used to redirect traffic to the switch that has the Layer 3 uplinks in the up state.

The Layer 3 backup routing path can be implemented using a dedicated interface VLAN (such as SVI) over the vPC Peer-Link or by using dedicated Layer 2 or Layer 3 links across the two vPC peer devices.

In this scenario, the Nexus 9000 devices part of the vPC domain are simply used as a Layer 2 transit path to allow the routers connected to them to establish Layer 3 peering and communication.

The Layer 3 devices can peer with each other in following two methods. Peering also depends on the specific device deployed for this role.

• Defining a VLAN network interface (SVI) for a VLAN that is extended between the Layer 3 devices through the intermediate Cisco Nexus 9000 vPC peer switches.

• Defining a Layer 3 port-channel interface on each Layer 3 device and establishing a point-to-point Layer 3 peering.

Note	In deployments where the Layer 3 peering must be established for multiple VRFs, the first method require the definition on the Layer 3 devices of a VLAN (and SVI) per VRF. For the second method, it is possible to create a Layer 3 port-channel subinterface per VRF

This example is similar to the peering between routers topology. In this case also, the Cisco Nexus 9000 devices that are part of the same vPC domain are only used as Layer 2 transit paths. The difference here is that there are two pairs of Cisco Nexus 9000 switches. Each switch that is connected with a Layer 3 device using a vPC connection, also establishes a back-to-back vPC connection between them. The difference is that the vPC domains are only used as Layer 2 transit paths.

This topology is commonly used when you want to establish connectivity between separate data centers that are interconnected with direct links (dark fibers or DWDM circuits). The two pairs of Cisco Nexus 9000 switches, in this case, provide only Layer 2 extension services, allowing the Layer 3 devices to peer with each other at Layer 3.

This example shows the Layer 3 device attached to the vPC domain through two different types of links, Layer 2 links and Layer 3 links.

When you require both routed and bridged traffic, use individual Layer 3 links for routed traffic and a separate Layer 2 port-channel for bridged traffic, as shown in following figure.

The Layer 2 links are used for bridged traffic (traffic staying in the same VLAN) or inter-VLAN traffic (assuming vPC domain hosts the interface VLAN and associated HSRP configuration).

The Layer 3 links are used for routing protocol peering adjacency with each vPC peer device.

The purpose of this topology is to attract specific traffic to go through the Layer 3 device. Layer 3 links are also used to carry routed traffic from a Layer 3 device to the vPC domain.

When routing protocol peering adjacency is required to be established between the two data centers, a best practice is to add dedicated Layer 3 links between the two sites as shown in this example.

An alternative design to what is shown in the previous section (Peering Between Two Routers with vPC Devices as Transit Switches), uses two pairs of Cisco Nexus 9000 switches that are deployed in each data center for providing both Layer 2 and Layer 3 extension services. When routing protocol peering adjacency is required to be established between the two pairs of Cisco Nexus 9000 devices, the best practice is to add dedicated Layer 3 links between the two sites as shown in the following example.

The vPC link between the two data centers carry bridged traffic or inter-VLAN traffic while the dedicated Layer 3 links carry the routed traffic across the two sites.

The back-to-back vPC connection between the two data centers carry bridged traffic or inter-VLAN traffic while the dedicated Layer 3 links carry the routed traffic across the two sites.

This example shows when the Layer 3 device is single-attached to the vPC domain, you can use a non-vPC VLAN with a dedicated inter-switch link to establish the routing protocol peering adjacency between the Layer 3 device and each vPC peer device. However, the non-vPC VLAN must be configured to use a static MAC that is different than the vPC VLAN.

Note	Configuring the vPC VLAN (and vPC Peer-Link) for this purpose is not supported.

Beginning with Cisco NX-OS Release 7.0(3)I5(1), an alternative method has been introduced to establish Layer 3 peering between a Layer 3 router and a pair of Cisco Nexus 9000 vPC switches.

Note	Peering directly over a vPC connection is supported only for Layer 3 unicast communication but not for Layer 3 multicast traffic. If you require Layer 3 multicast, you must establish peering over dedicated Layer 3 links

In this scenario, the Layer 3 peering between the external router and the Cisco Nexus 9000 switches that are part of a same vPC domain is established directly on a VLAN carried on the vPC connection. The external router in this case peers with SVI interfaces defined on each vPC device. As for the scenario shown in previous figure 12, the external router could use an SVI or a Layer 3 Port-Channel to peer with the vPC devices (multiple SVIs or Port-Channel subinterfaces could be used for a multi-VRF deployment).

This deployment model requires configuring layer3 peer-router command as part of the vPC domain. You can adopt the same approach for establishing Layer 2 and Layer 3 connectivity on a vPC back-to-back connection established between two separate pairs of vPC switches.

In this deployment model, SVI interfaces in the same VLAN is configured on all the four Cisco Nexus 9000 switches to establish routing peering and connectivity between them.