- Preface
- New and Changed Information
- Overview
- Configuring Ethernet Interfaces
- Configuring VLANs
- Configuring Private VLANs
- Configuring Access and Trunk Interfaces
- Configuring EtherChannels
- Configuring Virtual Port Channels
- Configuring Rapid PVST+
- Configuring Multiple Spanning Tree
- Configuring STP Extensions
- Configuring LLDP
- Configuring the MAC Address Table
- Configuring IGMP Snooping
- Configuring Traffic Storm Control
- Configuring the Fabric Extender
- Index
- Information About the Cisco Nexus 2000 Series Fabric Extender
- Fabric Extender Terminology
- Fabric Extender Features
- Oversubscription
- Management Model
- Forwarding Model
- Connection Model
- Port Numbering Convention
- Fabric Extender Image Management
- Fabric Extender Hardware
- Information About Associating a Fabric Extender to a Fabric Interface
- Configuring Fabric Extender Global Features
- Enabling the Fabric Extender Locator LED
- Redistributing the Links
Configuring the Fabric Extender
This chapter describes how to configure a Cisco Nexus 2000 Series Fabric Extender using the Cisco Nexus 5000 Series device and includes the following sections:
- Information About the Cisco Nexus 2000 Series Fabric Extender
- Fabric Extender Terminology
- Fabric Extender Features
- Oversubscription
- Management Model
- Forwarding Model
- Connection Model
- Port Numbering Convention
- Fabric Extender Image Management
- Fabric Extender Hardware
- Information About Associating a Fabric Extender to a Fabric Interface
- Configuring Fabric Extender Global Features
- Enabling the Fabric Extender Locator LED
- Redistributing the Links
- Verifying the Fabric Extender Configuration
- Verifying the Chassis Management Information
Information About the Cisco Nexus 2000 Series Fabric Extender
The Cisco Nexus 2000 Series Fabric Extender is a highly scalable and flexible server networking solution that works with Cisco Nexus 5000 Series switches to provide high-density, low-cost connectivity for server aggregation. Scaling across 1-Gigabit Ethernet, 10-Gigabit Ethernet, unified fabric, rack, and blade server environments, the Fabric Extender is designed to simplify data center architecture and operations.
The Fabric Extender integrates with its parent switch, a Cisco Nexus 5000 Series switch, to allow automatic provisioning and configuration taken from the settings on the parent switch. This integration allows large numbers of servers and hosts to be supported using the same feature set as the parent switch, including security and quality-of-service (QoS) configuration parameters, with a single management domain as shown in the following figure. The Fabric Extender and its parent switch enable a large multi-path, loop-free, active-active data center topology without the use of Spanning Tree Protocol (STP).
The Cisco Nexus 2000 Series Fabric Extender forwards all traffic to its parent Cisco Nexus 5000 Series switch over 10-Gigabit Ethernet fabric uplinks, allowing all traffic to be inspected by policies established on the Cisco Nexus 5000 Series switch.
No software is included with the Fabric Extender. Software is automatically downloaded and upgraded from its parent switch.
Fabric Extender Terminology
Some terms used in this document are as follows:
-
Fabric interface—A 10-Gigabit Ethernet uplink port designated for connection from the Fabric Extender to its parent switch. A fabric interface cannot be used for any other purpose. It must be directly connected to the parent switch.
Note
A fabric interface includes the corresponding interface on the parent switch. This interface is enabled when you enter the switchport mode fex-fabric command.
- Port channel fabric interface—A port channel uplink connection from the Fabric Extender to its parent switch. This connection consists of fabric interfaces bundled into a single logical channel.
-
Host interface—An Ethernet host interface for connection to a server or host system.
Note
Do not connect a bridge or switch to a host interface. These interfaces are designed to provide end host or server connectivity.
- Port channel host interface—A port channel host interface for connection to a server or host system.
Fabric Extender Features
The Cisco Nexus 2000 Series Fabric Extender allows a single switch—and a single consistent set of switch features—to be supported across a large number of hosts and servers. By supporting a large server-domain under a single management entity, policies can be enforced more efficiently.
Some of the features of the parent switch cannot be extended onto the Fabric Extender.
- Layer 2 Host Interfaces
- Host Port Channel
- VLANs and Private VLANs
- Virtual Port Channels
- Fibre Channel over Ethernet Support
- Protocol Offload
- Quality of Service
- Access Control Lists
- IGMP Snooping
- Switched Port Analyzer
- Fabric Interface Features
Layer 2 Host Interfaces
- All Fabric Extender host interfaces run as spanning tree edge ports with BPDU Guard enabled and cannot be configured as Spanning Tree network ports.
- Servers utilizing active/standby teaming, 802.3ad port channels, or other host-based link redundancy mechanisms can be connected to Fabric Extender host interfaces.
- Any device running spanning tree connected to a Fabric Extender host interface will result in that host interface being placed in an error-disabled state when a BPDU is received.
- Any edge switch that leverages a link redundancy mechanism not dependent on Spanning Tree such as Cisco Flexlink or vPC (with BPDUFilter enabled) may be connected to a Fabric Extender host interface. Since spanning tree is not utilized to eliminate loops, care must be taken to ensure a loop-free topology below the Fabric Extender host interfaces.
You can enable host interfaces to accept Cisco Discovery Protocol (CDP) packets. This protocol only works when it is enabled for both ends of a link.
Note |
CDP is not supported on fabric interfaces when the Fabric Extender is configured in a virtual port channel (vPC) topology. |
Ingress and egress packet counters are provided on each host interface.
For more information about BPDU Guard and CDP, see the Cisco Nexus 5000 Series NX-OS Layer 2 Switching Configuration Guide.
Host Port Channel
The Cisco Nexus 2248TP, Cisco Nexus 2232PP, and Cisco Nexus 2224PP support port channel host interface configurations. Up to eight interfaces can be combined in an port channel. The port channel can be configured with or without LACP.
VLANs and Private VLANs
The Fabric Extender supports Layer 2 VLAN trunks and IEEE 802.1Q VLAN encapsulation. Host interfaces can be members of private VLANs with the following restrictions:
- You can configure a host interface as an isolated or community access port only.
- You cannot configure a host interface as a promiscuous port.
- You cannot configure a host interface as a private VLAN trunk port.
For more information about VLANs, see the chapter in this guide on Configuring VLANs.
Virtual Port Channels
Using a virtual port channel (vPC) you can configure topologies where a Cisco Nexus 2000 Series Fabric Extender is connected to a pair of parent switches or a pair of Fabric Extenders are connected to a single parent switch. The vPC can provide multipath connections, which allow you to create redundancy between the nodes on your network.
Fibre Channel over Ethernet Support
The Cisco Nexus 2232PP supports Fibre Channel over Ethernet (FCoE) with the following restrictions:
- Only FCoE Initialization Protocol (FIP) enabled converged network adapters (CNAs) are supported on the Fabric Extender.
- Binding to a port channel is limited to only one member in the port channel.
For configuration details, see the Cisco Nexus 5000 Series NX-OS Fibre Channel over Ethernet Configuration Guide for the Nexus software release that you are using. The available versions of this document can be found at the following URL: http://www.cisco.com/en/US/products/ps9670/products_installation_and_configuration_guides_list.html.
Protocol Offload
To reduce the load on the control plane of the Cisco Nexus 5000 Series device, Cisco NX-OS provides the ability to offload link-level protocol processing to the Fabric Extender CPU. The following protocols are supported:
Quality of Service
The Fabric Extender provides two user queues for its quality-of-service (QoS) support, one for all no-drop classes and one for all drop classes. The classes configured on its parent switch are mapped to one of these two queues; traffic for no-drop classes is mapped to one queue and traffic for all drop classes is mapped to the other. Egress policies are also restricted to these two classes.
The parent switch provides two predefined type qos class maps for matching broadcast or multicast traffic; class-all-flood and class-ip-multicast. These classes are ignored on the Fabric Extender.
The Fabric Extender uses IEEE 802.1p class of service (CoS) values to associate traffic with the appropriate class. Per-port QoS configuration and CoS-based egress queuing is also supported.
Host interfaces support pause frames, which are implemented using IEEE 802.3x link-level flow control (LLC). By default, flow control send is on and flow control receive is off on all host interfaces. Autonegotiation is enabled on the host interfaces. Per-class flow control is set according to the QoS classes.
Host interfaces support jumbo frames (up to 9216 bytes); however, a per-host interface maximum transmission unit (MTU) is not supported. Instead, MTU is set according to the QoS classes. You modify MTU by setting policy and class maps on the parent switch. Because the Fabric Extender has only two user queues, the MTU for the drop-queue is set to the maximum MTU of all drop classes and the MTU on the no-drop queue is set to the maximum MTU of all no-drop classes.
For more information about LLC and quality-of-service, see the Cisco Nexus 5000 Series NX-OS Quality of Service Configuration Guide.
Access Control Lists
The Cisco Nexus 2000 Series Fabric Extender supports the full range of ingress access control lists (ACLs) that are available on its parent switch.
IGMP Snooping
IGMP snooping is supported on all host interfaces of the Fabric Extender.
The Fabric Extender and its parent switch support IGMPv3 snooping based only on the destination multicast MAC address. It does not support snooping based on the source MAC address or on proxy reports.
Note |
For more information about IGMP snooping, see http://tools.ietf.org/wg/magma/draft-ietf-magma-snoop/rfc4541.txt. Also, see the Cisco Nexus 5000 Series NX-OS Layer 2 Switching Configuration Guide Cisco Nexus 7000 Series NX-OS Multicast Routing Configuration Guide. |
Switched Port Analyzer
You can configure the host interfaces on the Fabric Extender as Switched Port Analyzer (SPAN) source ports. Fabric Extender ports cannot be configured as a SPAN destination. Only one SPAN session is supported for all the host interfaces on the same Fabric Extender. Ingress source (Rx), egress source (Tx), or both ingress and egress monitoring are supported.
Note |
All IP multicast traffic on the set of VLANs that a Fabric Extender host interface belongs to is captured in the SPAN session. You cannot separate the traffic by IP multicast group membership. If ingress monitoring and egress monitoring is configured for host interfaces on the same Fabric Extender, you might see a packet twice: once as the packet ingresses on an interface with Rx configured, and again as the packet egresses on an interface with Tx configured. |
For more information about SPAN, see the Cisco Nexus 5000 Series NX-OS System Management Configuration Guide for the Nexus software release that you are using. The available versions of this document can be found at the following URL: http://www.cisco.com/en/US/products/ps9670/products_installation_and_configuration_guides_list.html.
Fabric Interface Features
The FEX fabric interfaces support static port channels and priority flow control (PFC). PFC allows you to apply pause functionality to specific classes of traffic on an interface (instead of all the traffic on the interface). During the initial discovery and association process, SFP+ validation and digital optical monitoring (DOM) are performed as follows:
- The FEX performs a local check on the uplink SFP+ transceiver. If it fails the security check, the LED flashes but the link is still allowed to come up.
- The FEX local check is bypassed if it is running its backup image.
- The parent switch performs SFP validation again when the fabric interface is brought up. It keeps the fabric interface down if SFP validation fails.
Once an interface on the parent switch is configured in fex-fabric mode, all other features that were configured on that port and are not relevant to this mode are deactivated. If the interface is reconfigured to remove fex-fabric mode, the previous configurations are reactivated.
Note |
Per class flow control mode is enabled by default on the fabric interfaces. When a fabric interface is configured on the parent switch, PFC mode is enabled by default and cannot be changed. |
For more information about PFC, see the Cisco Nexus 5000 Series NX-OS Quality of Service Configuration Guide for the Nexus software release that you are using. The available versions of this document can be found at the following URL: http://www.cisco.com/en/US/products/ps9670/products_installation_and_configuration_guides_list.html.
Oversubscription
In a switching environment, oversubscription is the practice of connecting multiple devices to the same interface to optimize port usage. An interface can support a connection that runs at its maximum speed. Because most interfaces do not run at their maximum speeds, you can take advantage of unused bandwidth by sharing ports. In the case of the Cisco Nexus 2000 Series Fabric Extender, oversubscription, which is a function of the available fabric interfaces to active host interfaces, provides cost-effective scalability and flexibility for Ethernet environments.
The Cisco Nexus 2148T Fabric Extender has four 10-Gigabit Ethernet fabric interfaces and 48 1000BASE-T (1-Gigabit) Ethernet host interfaces. With this system, you can have any number of configurations. For example, you can configure the following:
- No oversubscription (40 host interfaces for four fabric interfaces)
- 1.2 to 1 oversubscription (48 host interfaces for four fabric interfaces)
- 4.8 to 1 oversubscription (48 host interfaces for one fabric interface)
The Cisco Nexus 2248TP Fabric Extender has four 10-Gigabit Ethernet fabric interfaces and 48 100/1000BASE-T (100-Mb/1-Gigabit) Ethernet host interfaces. It offers similar configurations to the Cisco Nexus 2148T when its host interfaces are running in Gigabit Ethernet mode.
The Cisco Nexus 2248TP can easily be run with no oversubscription when its host interfaces are running in 100-Mb mode.
The Cisco Nexus 2232PP Fabric Extender has eight 10-Gigabit Ethernet fabric interfaces and 32 10-Gigabit Ethernet host interfaces. With this system, you can configure a 4 to 1 oversubscription (4 host interfaces for one fabric interface) or higher.
Management Model
The Cisco Nexus 2000 Series Fabric Extender is managed by its parent switch over the fabric interfaces through a zero-touch configuration model. The switch discovers the Fabric Extender by detecting the fabric interfaces of the Fabric Extender.
After discovery, if the Fabric Extender has been correctly associated with the parent switch, the following operations are performed:
- The switch checks the software image compatibility and upgrades the Fabric Extender if necessary.
- The switch and Fabric Extender establish in-band IP connectivity with each other. The switch assigns an IP address in the range of loopback addresses (127.15.1.0/24) to the Fabric Extender to avoid conflicts with IP addresses that might be in use on the network.
- The switch pushes the configuration data to the Fabric Extender. The Fabric Extender does not store any configuration locally.
- The Fabric Extender updates the switch with its operational status. All Fabric Extender information is displayed using the switch commands for monitoring and troubleshooting.
Note |
Prior to Cisco NX-OS Release 4.1(3)N1(1), a Cisco Nexus 2000 Series Fabric Extender could be managed by one parent switch only. |
Forwarding Model
The Cisco Nexus 2000 Series Fabric Extender does not perform any local switching. All traffic is sent to the parent switch that provides central forwarding and policy enforcement, including host-to-host communications between two systems that are connected to the same Fabric Extender as shown in the following figure.
The forwarding model facilitates feature consistency between the Fabric Extender and its parent Cisco Nexus 5000 Series device.
Note |
The Fabric Extender provides end-host connectivity into the network fabric. As a result, BPDU Guard is enabled on all its host interfaces. If you connect a bridge or switch to a host interface, that interface is placed in an error-disabled state when a BPDU is received. You cannot disable BPDU Guard on the host interfaces of the Fabric Extender. |
The Fabric Extender supports egress multicast replication from the network to the host. Packets sent from the parent switch for multicast addresses attached to the Fabric Extender are replicated by the Fabric Extender ASICs and then sent to corresponding hosts.
Connection Model
Two methods (the static pinning fabric interface connection and the EtherChannel fabric interface connection) allow the traffic from an end host to the parent switch to be distributed when going through the Cisco Nexus 2000 Series Fabric Extender.
Static Pinning Fabric Interface Connection
To provide a deterministic relationship between the host interfaces and the parent switch, you can configure the Fabric Extender to use individual fabric interface connections. This configuration connects the 10-Gigabit Ethernet fabric interfaces as shown in the following figure. You can use any number of fabric interfaces up to the maximum available on the model of the Fabric Extender.
When the Fabric Extender is brought up, its host interfaces are distributed equally among the available fabric interfaces. As a result, the bandwidth that is dedicated to each end host toward the parent switch is never changed by the switch but instead is always specified by you.
Note |
If a fabric interface fails, all its associated host interfaces are brought down and remain down until the fabric interface is restored. |
You must use the pinning max-links command to create a number of pinned fabric interface connections so that the parent switch can determine a distribution of host interfaces. The host interfaces are divided by the number of the max-links and distributed accordingly. The default value is max-links 1.
Caution |
Changing the value of the max-links is disruptive; all the host interfaces on the Fabric Extender are brought down and back up as the parent switch reassigns its static pinning. |
The pinning order of the host interfaces is initially determined by the order in which the fabric interfaces were configured. When the parent switch is restarted, the configured fabric interfaces are pinned to the host interfaces in an ascending order by the port number of the fabric interface.
To guarantee a deterministic and sticky association across a reboot, you can manually redistribute the pinning.
Note |
The redistribution of the host interfaces will always be in an ascending order by the port number of the fabric interface. |
Port Channel Fabric Interface Connection
To provide load balancing between the host interfaces and the parent switch, you can configure the Fabric Extender to use a port channel fabric interface connection. This connection bundles 10-Gigabit Ethernet fabric interfaces into a single logical channel as shown in the following figure.
When you configure the Fabric Extender to use a port channel fabric interface connection to its parent switch, the switch load balances the traffic from the hosts that are connected to the host interface ports by using the following load-balancing criteria to select the link:
- For a Layer 2 frame, the switch uses the source and destination MAC addresses.
- For a Layer 3 frame, the switch uses the source and destination MAC addresses and the source and destination IP addresses.
Note |
A fabric interface that fails in the port channel does not trigger a change to the host interfaces. Traffic is automatically redistributed across the remaining links in the port channel fabric interface. If all links in the fabric port channel go down, all host interfaces on the FEX are set to the down state. |
Port Numbering Convention
The following port numbering convention is used for the Fabric Extender:
interface ethernet chassis/slot/port
where
-
chassis is configured by the administrator. A Fabric Extender must be directly connected to its parent Cisco Nexus 5000 Series device via individual fabric interfaces or a port channel fabric interface. You configure a chassis ID on a physical Ethernet interface or port channel on the switch to identify the Fabric Extender that is discovered through those interfaces. The chassis ID ranges from 100 to 199.
Note
The chassis ID is required only to access a host interface on the Fabric Extender. A value of less than 100 indicates a slot on the parent switch. The following port numbering convention is used for the interfaces on the switch:
interface ethernet slot/port
- slot identifies the slot number on the Fabric Extender.
- port identifies the port number on a specific slot and chassis ID.
Fabric Extender Image Management
No software ships with the Cisco Nexus 2000 Series Fabric Extender. The Fabric Extender image is bundled into the system image of the parent switch. The image is automatically verified and updated (if required) during the association process between the parent switch and the Fabric Extender.
When you enter the install all command, it upgrades the software on the parent Cisco Nexus 5000 Series switch and also upgrades the software on any attached Fabric Extender. To minimize downtime as much as possible, the Fabric Extender remains online while the installation process loads its new software image. Once the software image has successfully loaded, the parent switch and the Fabric Extender both automatically reboot.
This process is required to maintain version compatibility between the parent switch and the Fabric Extender.
Fabric Extender Hardware
The Cisco Nexus 2000 Series Fabric Extender architecture allows hardware configurations with various host interface counts and speeds.
Chassis
The Cisco Nexus 2000 Series Fabric Extender is a 1 RU chassis that is designed for rack mounting. The chassis supports redundant hot-swappable fans and power supplies.
Ethernet Interfaces
There are four models of the Cisco Nexus 2000 Series Fabric Extender:
- The Cisco Nexus 2148T has 48 1000BASE-T Ethernet host interfaces for its downlink connection to servers or hosts and 4 10-Gigabit Ethernet fabric interfaces with SFP+ interface adapters for its uplink connection to the parent switch.
- The Cisco Nexus 2224PP has 24 100BASE-T/1000Base-T Ethernet host interfaces for its downlink connection to servers or hosts and 2 10-Gigabit Ethernet fabric interfaces with SFP+ interface adapters for its uplink connection to the parent switch.
- The Cisco Nexus 2232PP has 32 10-Gigabit Ethernet host interfaces with SFP+ interface adapters and 8 10-Gigabit Ethernet fabric interfaces with SFP+ interface adapters for its uplink connection to the parent switch.
- The Cisco Nexus 2248TP has 48 100BASE-T/1000Base-T Ethernet host interfaces for its downlink connection to servers or hosts and 4 10-Gigabit Ethernet fabric interfaces with SFP+ interface adapters for its uplink connection to the parent switch.
Information About Associating a Fabric Extender to a Fabric Interface
A Cisco Nexus 2000 Series Fabric Extender is connected to its parent device through physical Ethernet interfaces or a port channel. By default, the parent device does not allow the attached Fabric Extender to connect until it has been assigned a FEX-number and is associated with the connected interface.
Note |
The Fabric Extender may connect to the switch through a number of separate physical Ethernet interfaces or one port channel interface. |
Caution |
Prior to Cisco NX-OS Release 4.1(3)N1(1), you could not connect the Ethernet interfaces of the Expansion Modules in the Cisco Nexus 5000 Series switch to a Fabric Extender. |
Note |
You must enable the Fabric Extender features with the feature fex command before you can configure and use a Fabric Extender that is connected to the parent switch. Prior to Release 4.1(3)N2(1), this functionality was enabled by default. |
- Associating a Fabric Extender to an Ethernet Interface
- Associating a Fabric Extender to a Port Channel
- Disassociating a Fabric Extender From an Interface
Associating a Fabric Extender to an Ethernet Interface
You can associate the Fabric Extender to an Ethernet interface.
Ensure that you have enabled the Fabric Extender feature.
1. switch# configure terminal
2. switch(config)# interface ethernet slot/port
3. switch(config-if)# switchport mode fex-fabric
4. switch(config-if)# fex associate FEX-number
5. (Optional) switch# show interface ethernet port/slot fex-intf
DETAILED STEPS
This example shows how to associate the Fabric Extender to an Ethernet interface on the parent device:
switch# configure terminal switch(config)# interface ethernet 1/40 switch(config-if)# switchport mode fex-fabric switch(config-if)# fex associate 101
This example shows how to display the association of the Fabric Extender and the parent device:
switch# show interface ethernet 1/40 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Eth1/40 Eth101/1/48 Eth101/1/47 Eth101/1/46 Eth101/1/45 Eth101/1/44 Eth101/1/43 Eth101/1/42 Eth101/1/41 Eth101/1/40 Eth101/1/39 Eth101/1/38 Eth101/1/37 Eth101/1/36 Eth101/1/35 Eth101/1/34 Eth101/1/33 Eth101/1/32 Eth101/1/31 Eth101/1/30 Eth101/1/29 Eth101/1/28 Eth101/1/27 Eth101/1/26 Eth101/1/25 Eth101/1/24 Eth101/1/23 Eth101/1/22 Eth101/1/21 Eth101/1/20 Eth101/1/19 Eth101/1/18 Eth101/1/17 Eth101/1/16 Eth101/1/15 Eth101/1/14 Eth101/1/13 Eth101/1/12 Eth101/1/11 Eth101/1/10 Eth101/1/9 Eth101/1/8 Eth101/1/7 Eth101/1/6 Eth101/1/5 Eth101/1/4 Eth101/1/3 Eth101/1/2 Eth101/1/1
Associating a Fabric Extender to a Port Channel
You can associate the Fabric Extender to a port channel.
Ensure that you have enabled the Fabric Extender feature.
1. configure terminal
2. interface port-channel channel
3. switchport mode fex-fabric
4. fex associate FEX-number
5. (Optional) show interface port-channel channel fex-intf
DETAILED STEPS
Examples
This example shows how to associate the Fabric Extender to a port channel interface on the parent device:
switch# configure terminal switch(config)# interface port-channel 4 switch(config-if)# switchport mode fex-fabric switch(config-if)# fex associate 101 switch(config-if)# exit switch(config)# interface ethernet 1/28 switch(config-if)# switchport mode fex-fabric switch(config-if)# fex associate 101 switch(config-if)# channel-group 4 switch(config-if)# exit switch(config)# interface ethernet 1/29 switch(config-if)# switchport mode fex-fabric switch(config-if)# fex associate 101 switch(config-if)# channel-group 4 switch(config-if)# exit switch(config)# interface ethernet 1/30 switch(config-if)# switchport mode fex-fabric switch(config-if)# fex associate 101 switch(config-if)# channel-group 4 switch(config-if)# exit switch(config)# interface ethernet 1/31 switch(config-if)# switchport mode fex-fabric switch(config-if)# fex associate 101 switch(config-if)# channel-group 4
Note |
You have to associate each Ethernet interface that is a member of the port channel as a fabric interface as shown in the above example. |
This example shows how to display the association of the Fabric Extender and the parent device:
switch# show interface port-channel 4 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Po4 Eth101/1/48 Eth101/1/47 Eth101/1/46 Eth101/1/45 Eth101/1/44 Eth101/1/43 Eth101/1/42 Eth101/1/41 Eth101/1/40 Eth101/1/39 Eth101/1/38 Eth101/1/37 Eth101/1/36 Eth101/1/35 Eth101/1/34 Eth101/1/33 Eth101/1/32 Eth101/1/31 Eth101/1/30 Eth101/1/29 Eth101/1/28 Eth101/1/27 Eth101/1/26 Eth101/1/25 Eth101/1/24 Eth101/1/23 Eth101/1/22 Eth101/1/21 Eth101/1/20 Eth101/1/19 Eth101/1/18 Eth101/1/17 Eth101/1/16 Eth101/1/15 Eth101/1/14 Eth101/1/13 Eth101/1/12 Eth101/1/11 Eth101/1/10 Eth101/1/9 Eth101/1/8 Eth101/1/7 Eth101/1/6 Eth101/1/5 Eth101/1/4 Eth101/1/3 Eth101/1/2 Eth101/1/1
Disassociating a Fabric Extender From an Interface
You can disassociate the Fabric Extender from an interface.
Ensure that you have enabled the Fabric Extender feature.
1. configure terminal
2. interface {ethernet slot/port | port-channel channel}
3. no fex associate
DETAILED STEPS
Configuring Fabric Extender Global Features
You can configure global features for a Fabric Extender.
Ensure that you have enabled the Fabric Extender feature.
1. configure terminal
2. fex FEX-number
3. (Optional) description desc
4. (Optional) no description
5. (Optional) type FEX-type
6. (Optional) no type
7. (Optional) pinning max-links uplinks
8. (Optional) no pinning max-links
9. (Optional) serial serial
10. (Optional) no serial
DETAILED STEPS
Enabling the Fabric Extender Locator LED
You can enable the locator beacon LED on the Fabric Extender. It allows you to locate a specific Fabric Extender in a rack.
Note |
Prior to Cisco NX-OS Release 4.1(3)N1(1), the locator beacon LED was enabled with the beacon FEX submode command. |
1. switch# locator-led fex FEX-number
2. (Optional) switch# no locator-led fex FEX-number
DETAILED STEPS
Command or Action | Purpose | |
---|---|---|
Step 1 | switch# locator-led fex FEX-number Example: switch# locator-led fex 101 |
Turns on the locator beacon LED for a specific Fabric Extender. |
Step 2 | switch# no locator-led fex FEX-number Example: switch# no locator-led fex 101 |
(Optional) Turns off the locator beacon LED for a specific Fabric Extender. |
Redistributing the Links
When you provision the Fabric Extender with statically pinned interfaces, the downlink host interfaces on the Fabric Extender are pinned to the fabric interfaces in the order they were initially configured. If you want to maintain a specific relationship of host interfaces to fabric interface across reboots, you should repin the links.
You may want to perform this function in these two situations:
Changing the Number of Links
If you initially configured a specific port on the parent switch, for example port 33, as your only fabric interface, all 48 host interfaces are pinned to this port. If you provision another port, for example 35, then you must enter the pinning max-links 2 command to redistribute the host interfaces. All host interfaces are brought down and host interfaces 1 to 24 are pinned to fabric interface 33 and host interfaces 25 to 48 are pinned to fabric interface 35.
Maintaining the Pinning Order
The pinning order of the host interfaces is initially determined by the order in which the fabric interfaces were configured. In this example, four fabric interfaces were configured in the following order:
switch# show interface ethernet 1/35 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Eth1/35 Eth101/1/12 Eth101/1/11 Eth101/1/10 Eth101/1/9 Eth101/1/8 Eth101/1/7 Eth101/1/6 Eth101/1/5 Eth101/1/4 Eth101/1/3 Eth101/1/2 Eth101/1/1 switch# show interface ethernet 1/33 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Eth1/33 Eth101/1/24 Eth101/1/23 Eth101/1/22 Eth101/1/21 Eth101/1/20 Eth101/1/19 Eth101/1/18 Eth101/1/17 Eth101/1/16 Eth101/1/15 Eth101/1/14 Eth101/1/13 switch# show interface ethernet 1/38 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Eth1/38 Eth101/1/36 Eth101/1/35 Eth101/1/34 Eth101/1/33 Eth101/1/32 Eth101/1/31 Eth101/1/30 Eth101/1/29 Eth101/1/28 Eth101/1/27 Eth101/1/26 Eth101/1/25 switch# show interface ethernet 1/40 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Eth1/40 Eth101/1/48 Eth101/1/47 Eth101/1/46 Eth101/1/45 Eth101/1/44 Eth101/1/43 Eth101/1/42 Eth101/1/41 Eth101/1/40 Eth101/1/39 Eth101/1/38 Eth101/1/37
The next time that you reboot the Fabric Extender, the configured fabric interfaces are pinned to the host interfaces in an ascending order by port number of the fabric interface. If you want to configure the same fixed distribution of host interfaces without restarting the Fabric Extender, enter the fex pinning redistribute command.
Redistributing Host Interfaces
You can redistribute the host interfaces on the Fabric Extender. Enter the fex pinning redistribute FEX-number command to redistribute the host connections. The range of the FEX-number is from 100 to 199.
This example shows how to redistribute the host interfaces on a Fabric Extender:
switch# fex pinning redistribute 101
Caution |
The fex pinning redistribute command disrupts all the host interface ports of the Fabric Extender. |
Verifying the Fabric Extender Configuration
To display configuration information about the defined interfaces on a Fabric Extender, perform one of the following tasks:
Command or Action |
Purpose |
---|---|
show fex [FEX-number] [detail] | Displays information about a specific Fabric Extender or all attached units. |
show interface type number fex-intf | Displays the Fabric Extender ports that are pinned to a specific switch interface. |
show interface fex-fabric | Displays the switch interfaces that have detected a Fabric Extender uplink. |
show interface ethernet number transceiver [fex-fabric] | Displays the SFP+ transceiver and diagnostic optical monitoring (DOM) information for the Fabric Extender uplinks. |
show feature-set | Displays the status of the feature sets on the device. |
Configuration Examples for the Fabric Extender
This example shows how to display all the attached Fabric Extender units:
switch# show fex FEX FEX FEX FEX Number Description State Model Serial ------------------------------------------------------------------------ 100 FEX0100 Online N2K-C2248TP-1GE JAF1339BDSK 101 FEX0101 Online N2K-C2232P-10GE JAF1333ADDD 102 FEX0102 Online N2K-C2232P-10GE JAS12334ABC
This example shows how to display the detailed status of a specific Fabric Extender:
switch# show fex 100 detail FEX: 100 Description: FEX0100 state: Online FEX version: 5.0(2)N1(1) [Switch version: 5.0(2)N1(1)] FEX Interim version: 5.0(2)N1(0.205) Switch Interim version: 5.0(2)N1(0.205) Extender Model: N2K-C2224TP-1GE, Extender Serial: JAF1427BQLG Part No: 73-13373-01 Card Id: 132, Mac Addr: 68:ef:bd:62:2a:42, Num Macs: 64 Module Sw Gen: 21 [Switch Sw Gen: 21] post level: complete pinning-mode: static Max-links: 1 Fabric port for control traffic: Eth1/29 Fabric interface state: Po100 - Interface Up. State: Active Eth1/29 - Interface Up. State: Active Eth1/30 - Interface Up. State: Active Fex Port State Fabric Port Primary Fabric Eth100/1/1 Up Po100 Po100 Eth100/1/2 Up Po100 Po100 Eth100/1/3 Up Po100 Po100 Eth100/1/4 Up Po100 Po100 Eth100/1/5 Up Po100 Po100 Eth100/1/6 Up Po100 Po100 Eth100/1/7 Up Po100 Po100 Eth100/1/8 Up Po100 Po100 Eth100/1/9 Up Po100 Po100 Eth100/1/10 Up Po100 Po100 Eth100/1/11 Up Po100 Po100 Eth100/1/12 Up Po100 Po100 Eth100/1/13 Up Po100 Po100 Eth100/1/14 Up Po100 Po100 Eth100/1/15 Up Po100 Po100 Eth100/1/16 Up Po100 Po100 Eth100/1/17 Up Po100 Po100 Eth100/1/18 Up Po100 Po100 Eth100/1/19 Up Po100 Po100 Eth100/1/20 Up Po100 Po100 Eth100/1/21 Up Po100 Po100 Eth100/1/22 Up Po100 Po100 Eth100/1/23 Up Po100 Po100 Eth100/1/24 Up Po100 Po100 Eth100/1/25 Up Po100 Po100 Eth100/1/26 Up Po100 Po100 Eth100/1/27 Up Po100 Po100 Eth100/1/28 Up Po100 Po100 Eth100/1/29 Up Po100 Po100 Eth100/1/30 Up Po100 Po100 Eth100/1/31 Up Po100 Po100 Eth100/1/32 Up Po100 Po100 Eth100/1/33 Up Po100 Po100 Eth100/1/34 Up Po100 Po100 Eth100/1/35 Up Po100 Po100 Eth100/1/36 Up Po100 Po100 Eth100/1/37 Up Po100 Po100 Eth100/1/38 Up Po100 Po100 Eth100/1/39 Up Po100 Po100 Eth100/1/40 Down Po100 Po100 Eth100/1/41 Up Po100 Po100 Eth100/1/42 Up Po100 Po100 Eth100/1/43 Up Po100 Po100 Eth100/1/44 Up Po100 Po100 Eth100/1/45 Up Po100 Po100 Eth100/1/46 Up Po100 Po100 Eth100/1/47 Up Po100 Po100 Eth100/1/48 Up Po100 Po100 Logs: 02/05/2010 20:12:17.764153: Module register received 02/05/2010 20:12:17.765408: Registration response sent 02/05/2010 20:12:17.845853: Module Online Sequence 02/05/2010 20:12:23.447218: Module Online
This example shows how to display the Fabric Extender interfaces pinned to a specific switch interface:
switch# show interface port-channel 100 fex-intf Fabric FEX Interface Interfaces --------------------------------------------------- Po100 Eth100/1/48 Eth100/1/47 Eth100/1/46 Eth100/1/45 Eth100/1/44 Eth100/1/43 Eth100/1/42 Eth100/1/41 Eth100/1/40 Eth100/1/39 Eth100/1/38 Eth100/1/37 Eth100/1/36 Eth100/1/35 Eth100/1/34 Eth100/1/33 Eth100/1/32 Eth100/1/31 Eth100/1/30 Eth100/1/29 Eth100/1/28 Eth100/1/27 Eth100/1/26 Eth100/1/25 Eth100/1/24 Eth100/1/22 Eth100/1/20 Eth100/1/19 Eth100/1/18 Eth100/1/17 Eth100/1/16 Eth100/1/15 Eth100/1/14 Eth100/1/13 Eth100/1/12 Eth100/1/11 Eth100/1/10 Eth100/1/9 Eth100/1/8 Eth100/1/7 Eth100/1/6 Eth100/1/5 Eth100/1/4 Eth100/1/3 Eth100/1/2 Eth100/1/1
This example shows how to display the switch interfaces that are connected to a Fabric Extender uplink:
switch# show interface fex-fabric Fabric Fabric Fex FEX Fex Port Port State Uplink Model Serial --------------------------------------------------------------- 100 Eth1/29 Active 3 N2K-C2248TP-1GE JAF1339BDSK 100 Eth1/30 Active 4 N2K-C2248TP-1GE JAF1339BDSK 102 Eth1/33 Active 1 N2K-C2232P-10GE JAS12334ABC 102 Eth1/34 Active 2 N2K-C2232P-10GE JAS12334ABC 102 Eth1/35 Active 3 N2K-C2232P-10GE JAS12334ABC 102 Eth1/36 Active 4 N2K-C2232P-10GE JAS12334ABC 101 Eth1/37 Active 5 N2K-C2232P-10GE JAF1333ADDD 101 Eth1/38 Active 6 N2K-C2232P-10GE JAF1333ADDD 101 Eth1/39 Active 7 N2K-C2232P-10GE JAF1333ADDD 101 Eth1/40 Active 8 N2K-C2232P-10GE JAF1333ADDD
This example shows how to display the SFP+ transceiver and diagnostic optical monitoring (DOM) information for Fabric Extender uplinks for an SFP+ transceiver that is plugged into the parent switch interface:
switch# show interface ethernet 1/40 transceiver Ethernet1/40 sfp is present name is CISCO-MOLEX INC part number is 74752-9026 revision is A0 serial number is MOC13321057 nominal bitrate is 12000 MBits/sec Link length supported for copper is 3 m(s) cisco id is -- cisco extended id number is 4
This example shows how to display the SFP+ transceiver and DOM information for Fabric Extender uplinks for an SFP+ transceiver that is plugged into the uplink port on the Fabric Extender:
switch# show interface ethernet 1/40 transceiver fex-fabric Ethernet1/40 sfp is present name is CISCO-MOLEX INC part number is 74752-9026 revision is A0 serial number is MOC13321057 nominal bitrate is 12000 MBits/sec Link length supported for 50/125mm fiber is 0 m(s) Link length supported for 62.5/125mm fiber is 0 m(s) cisco id is -- cisco extended id number is 4
Verifying the Chassis Management Information
To display configuration information used on the switch supervisor to manage the Fabric Extender, perform one of the following commands:
Command or Action |
Purpose |
---|---|
show diagnostic result fex FEX-number | Displays results from the diagnostic test for a Fabric Extender. |
show environment fex {all | FEX-number} [temperature | power | fan] | Displays the environmental sensor status. |
show inventory fex FEX-number | Displays inventory information for a Fabric Extender. |
show module fex FEX-number | Displays module information about a Fabric Extender. |
show sprom fex FEX-number {all | backplane | powersupply ps-num} | all | Displays the contents of the serial PROM (SPROM) on the Fabric Extender. |
Configuration Examples for Chassis Management
This example shows how to display the module information about all connected Fabric Extender units:
switch# show module fex FEX Mod Ports Card Type Model Status. --- --- ----- ---------------------------------- ------------------ ----------- 100 1 48 Fabric Extender 48x1GE + 4x10G Mod N2K-C2248TP-1GE present 101 1 32 Fabric Extender 32x10GE + 8x10G Mo N2K-C2232P-10GE present 102 1 32 Fabric Extender 32x10GE + 8x10G Mo N2K-C2232P-10GE present FEX Mod Sw Hw World-Wide-Name(s) (WWN) --- --- -------------- ------ ----------------------------------------------- 100 1 4.2(1)N1(1) 0.103 -- 101 1 4.2(1)N1(1) 1.0 -- 102 1 4.2(1)N1(1) 1.0 -- FEX Mod MAC-Address(es) Serial-Num --- --- -------------------------------------- ---------- 100 1 000d.ece3.2800 to 000d.ece3.282f JAF1339BDSK 101 1 000d.ecca.73c0 to 000d.ecca.73df JAF1333ADDD 102 1 000d.ecd6.bec0 to 000d.ecd6.bedf JAS12334ABC
This example shows how to display the module information about a specific Fabric Extender:
switch# show module fex 100 FEX Mod Ports Card Type Model Status. --- --- ----- ---------------------------------- ------------------ ----------- 100 1 48 Fabric Extender 48x1GE + 4x10G Mod N2K-C2248TP-1GE present FEX Mod Sw Hw World-Wide-Name(s) (WWN) --- --- -------------- ------ ----------------------------------------------- 100 1 4.2(1)N1(1) 0.103 -- FEX Mod MAC-Address(es) Serial-Num --- --- -------------------------------------- ---------- 100 1 000d.ece3.2800 to 000d.ece3.282f JAF1339BDSK
This example shows how to display the inventory information about a specific Fabric Extender:
switch# show inventory fex 101 NAME: "FEX 101 CHASSIS", DESCR: "N2K-C2248TP-1GE CHASSIS" PID: N2K-C2248TP-1GE , VID: V00 , SN: SSI13380FSM NAME: "FEX 101 Module 1", DESCR: "Fabric Extender Module: 48x1GE, 4x10GE Supervisor" PID: N2K-C2248TP-1GE , VID: V00 , SN: JAF1339BDSK NAME: "FEX 101 Fan 1", DESCR: "Fabric Extender Fan module" PID: N2K-C2248-FAN , VID: N/A , SN: N/A NAME: "FEX 101 Power Supply 2", DESCR: "Fabric Extender AC power supply" PID: NXK-PAC-400W , VID: 000, SN: LIT13370QD6
This example shows how to display diagnostic test results for a specific Fabric Extender:
switch# show diagnostic result fex 101 FEX-101: 48x1GE/Supervisor SerialNo : JAF1339BDSK Overall Diagnostic Result for FEX-101 : OK Test results: (. = Pass, F = Fail, U = Untested) TestPlatform: 0) SPROM: ---------------> . 1) Inband interface: ---------------> . 2) Fan: ---------------> . 3) Power Supply: ---------------> . 4) Temperature Sensor: ---------------> . TestForwardingPorts: Eth 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Port ------------------------------------------------------------------------ . . . . . . . . . . . . . . . . . . . . . . . . Eth 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 Port ------------------------------------------------------------------------ . . . . . . . . . . . . . . . . . . . . . . . . TestFabricPorts: Fabric 1 2 3 4 Port ------------ . . . .
This example shows how to display the environment status for a specific Fabric Extender:
switch# show environment fex 101 Temperature Fex 101: ----------------------------------------------------------------- Module Sensor MajorThresh MinorThres CurTemp Status (Celsius) (Celsius) (Celsius) ----------------------------------------------------------------- 1 Outlet-1 60 50 33 ok 1 Outlet-2 60 50 38 ok 1 Inlet-1 50 40 35 ok 1 Die-1 100 90 44 ok Fan Fex: 101: ------------------------------------------------------ Fan Model Hw Status ------------------------------------------------------ Chassis N2K-C2148-FAN -- failure PS-1 -- -- absent PS-2 NXK-PAC-400W -- ok Power Supply Fex 101: --------------------------------------------------------------------------- Voltage: 12 Volts ----------------------------------------------------- PS Model Power Power Status (Watts) (Amp) ----------------------------------------------------- 1 -- -- -- -- 2 NXK-PAC-400W 4.32 0.36 ok Mod Model Power Power Power Power Status Requested Requested Allocated Allocated (Watts) (Amp) (Watts) (Amp) --- ------------------- ------- ---------- --------- ---------- ---------- 1 N2K-C2248TP-1GE 0.00 0.00 0.00 0.00 powered-up Power Usage Summary: -------------------- Power Supply redundancy mode: redundant Total Power Capacity 4.32 W Power reserved for Supervisor(s) 0.00 W Power currently used by Modules 0.00 W ------------- Total Power Available 4.32 W -------------
This example shows how to display the SPROM for a specific Fabric Extender:
switch# show sprom fex 101 all DISPLAY FEX 101 SUP sprom contents Common block: Block Signature : 0xabab Block Version : 3 Block Length : 160 Block Checksum : 0x1a1e EEPROM Size : 65535 Block Count : 3 FRU Major Type : 0x6002 FRU Minor Type : 0x0 OEM String : Cisco Systems, Inc. Product Number : N2K-C2248TP-1GE Serial Number : JAF1339BDSK Part Number : 73-12748-01 Part Revision : 11 Mfg Deviation : 0 H/W Version : 0.103 Mfg Bits : 0 Engineer Use : 0 snmpOID : 9.12.3.1.9.78.3.0 Power Consump : 1666 RMA Code : 0-0-0-0 CLEI Code : XXXXXXXXXTBDV00 VID : V00 Supervisor Module specific block: Block Signature : 0x6002 Block Version : 2 Block Length : 103 Block Checksum : 0x2686 Feature Bits : 0x0 HW Changes Bits : 0x0 Card Index : 11016 MAC Addresses : 00-00-00-00-00-00 Number of MACs : 0 Number of EPLD : 0 Port Type-Num : 1-48;2-4 Sensor #1 : 60,50 Sensor #2 : 60,50 Sensor #3 : -128,-128 Sensor #4 : -128,-128 Sensor #5 : 50,40 Sensor #6 : -128,-128 Sensor #7 : -128,-128 Sensor #8 : -128,-128 Max Connector Power: 4000 Cooling Requirement: 65 Ambient Temperature: 40 DISPLAY FEX 101 backplane sprom contents: Common block: Block Signature : 0xabab Block Version : 3 Block Length : 160 Block Checksum : 0x1947 EEPROM Size : 65535 Block Count : 5 FRU Major Type : 0x6001 FRU Minor Type : 0x0 OEM String : Cisco Systems, Inc. Product Number : N2K-C2248TP-1GE Serial Number : SSI13380FSM Part Number : 68-3601-01 Part Revision : 03 Mfg Deviation : 0 H/W Version : 1.0 Mfg Bits : 0 Engineer Use : 0 snmpOID : 9.12.3.1.3.914.0.0 Power Consump : 0 RMA Code : 0-0-0-0 CLEI Code : XXXXXXXXXTDBV00 VID : V00 Chassis specific block: Block Signature : 0x6001 Block Version : 3 Block Length : 39 Block Checksum : 0x2cf Feature Bits : 0x0 HW Changes Bits : 0x0 Stackmib OID : 0 MAC Addresses : 00-0d-ec-e3-28-00 Number of MACs : 64 OEM Enterprise : 0 OEM MIB Offset : 0 MAX Connector Power: 0 WWN software-module specific block: Block Signature : 0x6005 Block Version : 1 Block Length : 0 Block Checksum : 0x66 wwn usage bits: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 License software-module specific block: Block Signature : 0x6006 Block Version : 1 Block Length : 16 Block Checksum : 0x86f lic usage bits: ff ff ff ff ff ff ff ff DISPLAY FEX 101 power-supply 2 sprom contents: Common block: Block Signature : 0xabab Block Version : 3 Block Length : 160 Block Checksum : 0x1673 EEPROM Size : 65535 Block Count : 2 FRU Major Type : 0xab01 FRU Minor Type : 0x0 OEM String : Cisco Systems Inc NXK-PAC-400W Product Number : NXK-PAC-400W Serial Number : LIT13370QD6 Part Number : 341 Part Revision : -037 CLEI Code : 5-01 01 000 VID : 000 snmpOID : 12336.12336.12336.12336.12336.12336.12374.12336 H/W Version : 43777.2 Current : 36 RMA Code : 200-32-32-32 Power supply specific block: Block Signature : 0x0 Block Version : 0 Block Length : 0 Block Checksum : 0x0 Feature Bits : 0x0 Current 110v : 36 Current 220v : 36 Stackmib OID : 0