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This chapter describes the basic interface configuration to get your switch up and running.
The main function of a switch is to relay frames from one data link to another. To relay the frames, the characteristics of the interfaces through which the frames are received and sent must be defined. The configured interfaces can be Fibre Channel interfaces, Gigabit Ethernet interfaces, the management interface (mgmt0), or VSAN interfaces.
This section includes the following topics:
For the Fibre Channel interfaces, you can configure the description parameter to provide a recognizable name for the interface. Using a unique name for each interface allows you to quickly identify the interface when you are looking at a listing of multiple interfaces. You can also use the description to identify the traffic or the use for that interface.
Each physical Fibre Channel interface in a switch may operate in one of several port modes: E port, F port, FL port, TL port, TE port, SD port, ST port, and B port (see Figure 2-1). Besides these modes, each interface may be configured in auto or Fx port modes. These two modes determine the port type during interface initialization.
Figure 2-1 Cisco MDS 9000 Family Switch Port Modes
Note Interfaces are created in VSAN 1 by default. See the Cisco MDS 9000 Family NX-OS Fabric Configuration Guide.
Each interface has an associated administrative configuration and an operational status:
Note When a module is removed and replaced with the same type of module, the configuration is retained. If a different type of module is inserted, then the original configuration is no longer retained.
Each interface is briefly described in the sections that follow.
In expansion port (E port) mode, an interface functions as a fabric expansion port. This port may be connected to another E port to create an Inter-Switch Link (ISL) between two switches. E ports carry frames between switches for configuration and fabric management. They serve as a conduit between switches for frames destined to remote N ports and NL ports. E ports support class 2, class 3, and class F service.
An E port connected to another switch may also be configured to form a PortChannel (see Chapter 6, “Configuring PortChannels”).
Note We recommend that you configure E ports on 16-port modules. If you must configure an E port on a 32-port oversubscribed module, then you can only use the first port in a group of four ports (for example, ports 1 through 4, 5 through 8, and so forth). The other three ports cannot be used.
In fabric port (F port) mode, an interface functions as a fabric port. This port may be connected to a peripheral device (host or disk) operating as an N port. An F port can be attached to only one N port. F ports support class 2 and class 3 service.
In fabric loop port (FL port) mode, an interface functions as a fabric loop port. This port may be connected to one or more NL ports (including FL ports in other switches) to form a public arbitrated loop. If more than one FL port is detected on the arbitrated loop during initialization, only one FL port becomes operational and the other FL ports enter nonparticipating mode. FL ports support class 2 and class 3 service.
Note FL port mode is not supported on 4-port 10-Gbps switching module interfaces.
An NP port is a port on a device that is in NPV mode and connected to the core switch via an F port. NP ports function like N ports except that in addition to providing N port operations, they also function as proxies for multiple, physical N ports.
Note A Cisco Nexus 5000 Series switch in NPV mode that runs Cisco NX-OS Release 4.2(1) or later releases supports trunking F port mode on NP ports. You can enable either, or both, VSAN trunking and an F port on an NP port.
For more details about NP ports and NPV, see Chapter7, “Configuring N Port Virtualization”
In translative loop port (TL port) mode, an interface functions as a translative loop port. It may be connected to one or more private loop devices (NL ports). TL ports are specific to Cisco MDS 9000 Family switches and have similar properties as FL ports. TL ports enable communication between a private loop device and one of the following devices:
TL ports support class 2 and class 3 services.
Private loop devices refer to legacy devices that reside on arbitrated loops. These devices are not aware of a switch fabric because they only communicate with devices on the same physical loop (see the “TL Port ALPA Caches” section).
Tip We recommend configuring devices attached to TL ports in zones that have up to 64 zone members.
Note TL port mode is not supported on Generation 2 switching module interfaces.
In trunking E port (TE port) mode, an interface functions as a trunking expansion port. It may be connected to another TE port to create an extended ISL (EISL) between two switches. TE ports are specific to Cisco MDS 9000 Family switches. They expand the functionality of E ports to support the following:
In TE port mode, all frames are transmitted in EISL frame format, which contains VSAN information. Interconnected switches use the VSAN ID to multiplex traffic from one or more VSANs across the same physical link. This feature is referred to as trunking in the Cisco MDS 9000 Family switches (see Chapter 5, “Configuring Trunking”). TE ports support class 2, class 3, and class F service.
In trunking F port (TF port) mode, an interface functions as a trunking expansion port. It may be connected to another trunked N port (TN port) or trunked NP port (TNP port) to create a link between a core switch and an NPV switch or an HBA to carry tagged frames. TF ports are specific to Cisco MDS 9000 Family switches. They expand the functionality of F ports to support VSAN trunking.
In TF port mode, all frames are transmitted in EISL frame format, which contains VSAN information. Interconnected switches use the VSAN ID to multiplex traffic from one or more VSANs across the same physical link. This feature is referred to as trunking in the Cisco MDS 9000 Family (see Chapter 5, “Configuring Trunking”). TF ports support class 2, class 3, and class F service.
In trunking NP port (TNP port) mode, an interface functions as a trunking expansion port. It may be connected to a trunked F port (TF port) to create a link to a core NPIV switch from an NPV switch to carry tagged frames.
In SPAN destination port (SD port) mode, an interface functions as a switched port analyzer (SPAN). The SPAN feature is specific to switches in the Cisco MDS 9000 Family. It monitors network traffic that passes though a Fibre Channel interface. This monitoring is done using a standard Fibre Channel analyzer (or a similar switch probe) that is attached to an SD port. SD ports do not receive frames, they only transmit a copy of the source traffic. The SPAN feature is nonintrusive and does not affect switching of network traffic for any SPAN source ports (see the Cisco MDS 9000 Family NX-OS System Management Configuration Guide).
In the SPAN tunnel port (ST port) mode, an interface functions as an entry point port in the source switch for the RSPAN Fibre Channel tunnel. The ST port mode and the remote SPAN (RSPAN) feature are specific to switches in the Cisco MDS 9000 Family. When configured in ST port mode, the interface cannot be attached to any device, and thus cannot be used for normal Fibre Channel traffic (see the Cisco MDS 9000 Family NX-OS System Management Configuration Guide).
Note ST port mode is not supported on the Cisco MDS 9124 Fabric Switch, the Cisco Fabric Switch for HP c-Class BladeSystem, and the Cisco Fabric Switch for IBM BladeCenter.
Interfaces configured as Fx ports can operate in either F port or FL port mode. The Fx port mode is determined during interface initialization depending on the attached N port or NL port. This administrative configuration disallows interfaces to operate in any other mode—for example, preventing an interface to connect to another switch.
While E ports typically interconnect Fibre Channel switches, some SAN extender devices, such as the Cisco PA-FC-1G Fibre Channel port adapter, implement a bridge port (B port) model to connect geographically dispersed fabrics. This model uses B ports as described in the T11 Standard FC-BB-2.
If an FCIP peer is a SAN extender device that only supports Fibre Channel B ports, you need to enable the B port mode for the FCIP link. When a B port is enabled, the E port functionality is also enabled and they coexist. If the B port is disabled, the E port functionality remains enabled (see the Cisco MDS 9000 Family NX-OS IP Services Configuration Guide).
Interfaces configured in auto mode can operate in one of the following modes: F port, FL port, E port, TE port, or TF port. The port mode is determined during interface initialization. For example, if the interface is connected to a node (host or disk), it operates in F port or FL port mode depending on the N port or NL port mode. If the interface is attached to a third-party switch, it operates in E port mode. If the interface is attached to another switch in the Cisco MDS 9000 Family, it may become operational in TE port mode (see Chapter 5, “Configuring Trunking”).
TL ports and SD ports are not determined during initialization and are administratively configured.
Note Fibre Channel interfaces on Storage Services Modules (SSMs) cannot be configured in auto mode.
The interface state depends on the administrative configuration of the interface and the dynamic state of the physical link.
The administrative state refers to the administrative configuration of the interface as described in Table 2-1 .
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Interface is disabled. If you administratively disable an interface by shutting down that interface, the physical link layer state change is ignored. |
The operational state indicates the current operational state of the interface as described in Table 2-2 .
Reason codes are dependent on the operational state of the interface as described in Table 2-3 .
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Administratively down—If you administratively configure an interface as down, you disable the interface. No traffic is received or transmitted. |
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See Table 2-4 . |
Note Only some of the reason codes are listed in Table 2-4.
If the administrative state is up and the operational state is down, the reason code differs based on the nonoperational reason code as described in Table 2-4 .
Interfaces on a port are shut down by default (unless you modified the initial configuration).
The Cisco NX-OS software implicitly performs a graceful shutdown in response to either of the following actions for interfaces operating in the E port mode:
A graceful shutdown ensures that no frames are lost when the interface is shutting down. When a shutdown is triggered either by you or the Cisco NX-OS software, the switches connected to the shutdown link coordinate with each other to ensure that all frames in the ports are safely sent through the link before shutting down. This enhancement reduces the chance of frame loss.
A graceful shutdown is not possible in the following situations:
Note This feature is only triggered if both switches at either end of this E port interface are MDS switches and are running Cisco SAN-OS Release 2.0(1b) or later, or MDS NX-OS Release 4.1(1a) or later.
By default, the port administrative speed for an interface is automatically calculated by the switch.
For internal ports on the Cisco Fabric Switch for HP c_Class BladeSystem and Cisco Fabric Switch for IBM BladeCenter, a port speed of 1 Gbps is not supported. Auto-negotiation is supported between 2 Gbps and 4 Gbps only. Also, if the BladeCenter is a T chassis, then port speeds are fixed at 2 Gbps and auto-negotiation is not enabled.
Autosensing speed is enabled on all 4-Gbps and 8-Gbps switching module interfaces by default. This configuration enables the interfaces to operate at speeds of 1 Gbps, 2 Gbps, or 4 Gbps on the 4-Gbps switching modules, and 8 Gbps on the 8-Gbps switching modules. When autosensing is enabled for an interface operating in dedicated rate mode, 4 Gbps of bandwidth is reserved, even if the port negotiates at an operating speed of 1 Gbps or 2 Gbps.
To avoid wasting unused bandwidth on 48-port and 24-port 4-Gbps and 8-Gbps Fibre Channel switching modules, you can specify that only 2 Gbps of required bandwidth be reserved, not the default of 4 Gbps or 8 Gbps. This feature shares the unused bandwidth within the port group provided that it does not exceed the rate limit configuration for the port. You can also use this feature for shared rate ports that are configured for autosensing.
Tip When migrating a host that supports up to 2-Gbps traffic (that is, not 4 Gbps with autosensing capabilities) to the 4-Gbps switching modules, use autosensing with a maximum bandwidth of 2 Gbps. When migrating a host that supports up to 4-Gbps traffic (that is, not 8 Gbps with autosensing capabilities) to the 8-Gbps switching modules, use autosensing with a maximum bandwidth of 4 Gbps.
You can set the frame format to EISL for all frames transmitted by the interface in SD port mode. If you sent the frame encapsulation to EISL, all outgoing frames are transmitted in the EISL frame format, regardless of the SPAN sources. See the Cisco MDS 9000 Family NX-OS System Management Configuration Guide.
Refer to the Cisco MDS 9000 Family NX-OS Interfaces Configuration Guide to configure frame encapsulation on an interface.
Figure 2-2 displays the status, link, and speed LEDs in a 16-port switching module.
Figure 2-2 Cisco MDS 9000 Family Switch Interface Modes
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Status LED1 |
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Link LEDs 1 and speed LEDs2 |
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Asset tag3 |
1.See the Cisco MDS 9000 Family NX-OS Fundamentals Configuration Guide. 2.See the “Speed LEDs” section. 3.Refer to the Cisco MDS 9000 Family hardware installation guide for your platform. |
Each port has one link LED on the left and one speed LED on the right.
The speed LED displays the speed of the port interface:
The speed LED also displays if the beacon mode is enabled or disabled:
Note Generation 2, Generation 3, and Generation 4 modules and fabric switches do not have speed LEDs.
The bit error rate threshold is used by the switch to detect an increased error rate before performance degradation seriously affects traffic.
The bit errors can occur for the following reasons:
A bit error rate threshold is detected when 15 error bursts occur in a 5-minute period. By default, the switch disables the interface when the threshold is reached. You can enter a shutdown and no shutdown command sequence to re-enable the interface.
You can configure the switch to not disable an interface when the threshold is crossed. By default, the threshold disables the interface.
The small form-factor pluggable (SFP) hardware transmitters are identified by their acronyms when displayed. Table 2-5 defines the acronyms used for SFPs.
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Private loop devices refer to legacy devices that reside on arbitrated loops. These devices are not aware of a switch fabric because they only communicate with devices on the same physical loop. The legacy devices are used in Fibre Channel networks, and devices outside the loop may need to communicate with them. The communication functionality is provided through TL ports. See the “Interface Modes” section.
TL port mode is not supported on the following hardware:
Table 2-6 lists the TL port translations supported in Cisco MDS 9000 Family switches.
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Figure 2-3 shows examples of TL port translation support.
Figure 2-3 TL Port Translation Support Examples
Although TL ports cannot be automatically configured, you can manually configure entries in arbitrated loop physical address (ALPA) caches. Generally, ALPA cache entries are automatically populated when an ALPA is assigned to a device. Each device is identified by its port world wide name (pWWN). When a device is allocated an ALPA, an entry for that device is automatically created in the ALPA cache.
A cache contains entries for recently allocated ALPA values. These caches are maintained on various TL ports. If a device already has an ALPA, the Cisco NX-OS software attempts to allocate the same ALPA to the device each time. The ALPA cache is maintained in persistent storage and saves information across switch reboots. The maximum cache size is 1000 entries. If the cache is full, and a new ALPA is allocated, the Cisco NX-OS software discards an inactive cache entry (if available) to make space for the new entry. See the “TL Port” section for more information on TL ports.
Refer to the Cisco MDS 9000 Family NX-OS Interfaces Configuration Guide to manage the TL Port ALPA cache.
The port guard feature is intended for use in environments where the system and application environment does not adapt quickly and efficiently to a port going down and back up, or to a port rapidly cycling up and down, which can happen in some failure modes. For example, if a system takes five seconds to stabilize after a port goes down, but the port is going up and down once a second, a more severe failure in the fabric might occur.
The port guard feature gives the SAN administrator the ability to prevent this issue from occurring in environments that are vulnerable to these problems. The port can be configured to stay down after the first failure or after a specified number of failures in a specified time period. This allows the SAN administrator to intervene and control the recovery, avoiding any problems caused by the cycling.
Using the port guard feature, you can restrict the number of error reports and bring a malfunctioning port to down state dynamically. A port can be configured to go into error-disabled state for specific types of failures.
A general link failure caused by link-down is the superset of all other causes. The sum of the number of all other causes equals to the number of link-down link failures. This means a port is brought to down state when it reaches the maximum number of allowed link failures or the number of specific causes.
The causes of link failure can be any of the following:
– Hardware recoverable errors.
Port monitor helps to monitor the performance and the status of ports and generate alerts when problems occur. You can configure the thresholds for various counters and trigger an event when the values cross the threshold settings.
The default port monitor policy has the following threshold values:
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Port monitor port guard is a feature that disables or shuts down a port when an event occurs. Depending on the configuration, when an event occurs the port is either error-disabled or flapped.
Port monitor port guard is a different or separate feature that functions based on the configuration of the errordisable command.
Each line card or module has a predefined set of ports which share the same backplane bandwidth called port groups. While oversubscription is a feature, the port group monitor feature helps to monitor the spine bandwidth utilization. An alarm syslog is generated so that you can provision the ports across port groups evenly to manage the oversubscription better.
When the port group monitor feature is enabled and a policy consisting of polling interval in seconds, and the raising and falling thresholds in percentage are specified, port group monitor generates a syslog if a port group traffic goes above the specified percentage of the maximum supported bandwidth for that port group (for rx and for tx) and another syslog if the value falls below the specified threshold.
The default port group policy has the following threshold values:
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Local switching can be enabled in Generation 4 modules, which allows traffic to be switched directly with a local crossbar when the traffic is directed from one port to another on the same line card. By using local switching, an extra switching step is avoided, which decreases the latency.
All data traffic between end devices in a SAN fabric is carried by Fibre Channel Class 3. In some cases, the traffic is carried by Class 2 services that use link-level, per-hop-based, and buffer-to-buffer flow control. These classes of service do not support end-to-end flow control. When there are slow devices attached to the fabric, the end devices do not accept the frames at the configured or negotiated rate. The slow devices lead to ISL credit shortage in the traffic destined for these devices and they congest the links. The credit shortage affects the unrelated flows in the fabric that use the same ISL link even though destination devices do not experience slow drain.
This feature provides various enhancements to detect slow drain devices that are causing congestion in the network and also provides a congestion avoidance function.
This feature is focused mainly on the edge ports that are connected to slow drain devices. The goal is to avoid or minimize the frames being stuck in the edge ports due to slow drain devices that are causing ISL blockage. To avoid or minimize the stuck condition, configure lesser frame timeout for the ports. No-credit timeout drops all packets once the slow drain is detected using the configured thresholds. The lesser frame timeout value helps to alleviate the slow drain condition that affects the fabric by dropping the packets on the edge ports sooner than the time they actually get timed out (500 ms). This function frees the buffer space in ISL, which can be used by other unrelated flows that do not experience slow drain condition.
Note This feature is used mainly for edge ports that are connected to slow edge devices. Even though this feature can be applied to ISLs as well, we recommend that you apply this feature only for edge F ports and retain the default configuration for ISLs as E and TE ports. This feature is not supported on Generation 1 modules.
You can remotely configure the switch through the management interface (mgmt0). To configure a connection on the mgmt0 interface, you must configure either the IP version 4 (IPv4) parameters (IP address, subnet mask, and default gateway) or the IP version 6 (IPv6) parameters so that the switch is reachable.
Before you begin to configure the management interface manually, obtain the switch’s IPv4 address and subnet mask, or the IPv6 address.
The management port (mgmt0) is autosensing and operates in full-duplex mode at a speed of 10/100/1000 Mbps. Autosensing supports both the speed and the duplex mode. On a Supervisor-1 module, the default speed is 100 Mbps and the default duplex mode is auto. On a Supervisor-2 module, the default speed is auto and the default duplex mode is auto.
Note You need to explicitly configure a default gateway to connect to the switch and send IP packets or add a route for each subnet.
VSANs apply to Fibre Channel fabrics and enable you to configure multiple isolated SAN topologies within the same physical infrastructure. You can create an IP interface on top of a VSAN and then use this interface to send frames to this VSAN. To use this feature, you must configure the IP address for this VSAN. VSAN interfaces cannot be created for nonexisting VSANs.
Before you begin configuring the interfaces, ensure that the modules in the chassis are functioning as designed. For information about verifying the module status, refer to the Cisco NX-OS Fundamentals Configuration Guide.
This section includes the following topics:
The Generation 1 interfaces configuration guidelines apply to the following hardware:
Note Due to the hardware design of the MDS 9134 switch, we do not support interface out-of-service action on either of its two 10-Gigabit ports. This is because no internal port hardware resource is released when an out-of-service action is performed on these 10-Gigabit ports.
When configuring these host-optimized ports, the following port mode guidelines apply:
Note We recommend that you configure your E ports on a 16-port switching module. If you must configure an E port on a 32-port host-optimized switching module, the other three ports in that 4-port group cannot be used.
Note In the Cisco MDS 9100 Series, the groups of ports that are located on the left and outlined in white are full line rate. The other ports are host-optimized. Each group of 4 host-optimized ports have the same features as for the 32-port switching module.
Follow these guidelines when configuring private loops:
Follow these guidelines when creating or deleting VSAN interfaces:
Tip After configuring the VSAN interface, you can configure an IP address or Virtual Router Redundancy Protocol (VRRP) feature. See the Cisco MDS 9000 Family NX-OS IP Services Configuration Guide.
Table 2-7 lists the default settings for interface parameters.
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On (unless changed during initial setup) on non-NPV and NPIV core switches. Off on NPV switches. |
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This section includes the following topics:
For more information on configuring mgmt0 interfaces, refer to the Cisco MDS 9000 Family NX-OS Fundamentals Configuration Guide and Cisco MDS 9000 Family NX-OS IP Services Configuration Guide.
For more information on configuring Gigabit Ethernet interfaces, see the Cisco MDS 9000 Family NX-OS IP Services Configuration Guide.
Some configuration settings are similar for Fibre Channel, management, and VSAN interfaces. You can configure interfaces from DCNM-SAN by expanding Switches > FC Interfaces and selecting either the Physical or Logical interface type from the Physical Attributes pane.
For the Cisco Fabric Switch for HP c-Class BladeSystem and the Cisco Fabric Switch for IBM BladeCenter, you can configure a range of interfaces among internal ports or external ports, but you cannot mix both interface types within the same range. For example, “bay 1-10, bay 12” or “ext 0, ext 15-18” are valid ranges, but “bay 1-5, ext 15-17” is not.
To disable or enable an interface using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical. You see the interface configuration in the Information pane.
Step 4 Set the status or mode to the required status.
Step 5 (Optional) Set other configuration parameters using the other tabs.
To configure the interface mode using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical.
You see the interface configuration in the Information pane.
Step 3 Click Mode Admin. Set the desired interface mode from the Admin drop-down menu.
Step 4 (Optional) Set other configuration parameters using the other tabs.
Step 5 Click Apply Changes icon.
The 48-port 8-Gbps Advanced Fibre Channel module (DS-X9248-256K9) and the 32-port 8-Gbps Advanced Fibre Channel module (DS-X9232-256K9)can switch between two speed modes—the 1-, 2-, 4-, 8-Gbps or 10-Gbps. By default, the modules are online in the 1-, 2-, 4-, and 8-Gbps modes when they are loaded for the first time. There are two ways to change the ports to the 10-Gbps speed mode:
The following conditions apply when the ports in the module can be configured to 10-Gbps speed mode:
Only certain ports on the 48-port and 32-port 8-Gbps Advanced Fibre Channel modules are 10-Gbps capable. When running in 10-Gbps mode, the non-10-Gbps ports cannot be operational. They have to be either in shut state or out-of-service state.
To configure the interface mode using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical.
You see the interface configuration in the Information pane.
Step 3 Click Mode Admin. Set the desired interface mode from the Admin drop-down menu.
Step 4 (Optional) Set other configuration parameters using the other tabs.
Step 5 Click Apply Changes icon.
To configure the administrative speed of the interface using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical.
You see the interface configuration in the Information pane.
Step 3 Click Speed Admin. Set the desired speed from the drop-down menu.
The number indicates the speed in megabits per second (Mbps). You can set the speed to 1-Gbps, 2-Gbps, 4-Gbps, 8-Gbps, autoMax2G, autoMax4G, or auto (default).
Note On a Cisco Nexus 5000 Series switch that runs Cisco NX-OS Release 4.2(2), you can configure the 8-Gbps administrative speed only on a M1060 switch module. You can configure the speed to 1-Gbps, 2-Gbps, or 4-Gbps on all switch modules on a Cisco Nexus 5000 Series switch that runs Cisco NX-OS Release 4.2(2) or earlier releases.
To configure the administrative speed of the interface using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical.
You see the interface configuration in the Information pane.
Step 3 Click SpeedGroup. Set the desired speed group from the drop-down menu.
You can select any of the speed groups from the menu list—notApplicable, tenG, oneTwoFourEightG, or twoFourEightSixteenG.
Note For a DS-X9248-256K9 or DS-X9232-256K9 line card, the speed group must be set to tenG.
Using the port owner feature, you can specify the owner of a port and the purpose for which a port is used so that the other administrators are informed.
Note The port guard and port owner features are available for all ports regardless of the operational mode.
To specify or remove the port owner using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical.
You see the interface configuration in the Information pane.
Step 2 Click the General tab and then select the switch/port.
Step 3 In the Owner text box, enter a port owner and the purpose for which port is used.
To specify or remove the port owner using Device Manager, follow these steps:
Step 1 Double-click the interface in the modules panel.
Step 3 In the Owner text box, enter a port owner and the purpose for which the port is used.
By default, the beacon mode is disabled on all switches. The beacon mode is indicated by a flashing green light that helps you identify the physical location of the specified interface. Configuring the beacon mode has no effect on the operation of the interface.
To enable beacon mode for a specified interface or range of interfaces using DCNM-SAN, follow these steps:
Step 1 Expand Switches > Ethernet Interfaces > Physical > IPS (the Gigabit Ethernet Interfaces).
You see the interface configuration in the Information pane.
Step 2 Click the Beacon Mode and enable this option for the selected switch.
Note Even if you disable the switch port ignore bit-error threshold for an interface, the switch generates a syslog message when bit-error threshold events are detected.
You can configure attribute default values for various switch port attributes. These attributes will be applied globally to all future switch port configurations, even if you do not individually specify them at that time.
Private loops require setting the interface mode to TL.
To configure the TL interface mode using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical. You see the interface configuration in the Information pane.
Step 2 Click the General tab and click Mode Admin.
Step 3 Set the Mode Admin drop-down menu to the required status.
Step 4 (Optional) Set other configuration parameters using the other tabs.
To enable port guard using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical > Port Guard from the Physical Attributes pane.
You see the interfaces listed in the Information pane.
Step 2 Click the Link Down tab and then select a switch or port.
Step 3 Check the check box in the Enable column.
Step 4 (Optional) Enter the Duration in seconds and the number of flaps. If the values are 0, the port is brought to down state if the link flaps even once. Otherwise, the link is brought to down state if the link flaps for the number of flaps within the duration.
Step 5 Click Apply Changes to activate the configuration.
Step 6 Click the TrustSec Violation tab, and then select a switch or port.
Step 7 Check the check box in the Enable column.
Step 8 (Optional) Enter the duration in seconds and the number of flaps. If the values are 0, the port is brought to down state if a trustsec violation occurs even once. Otherwise, the link is brought to down state if there is trustsec violation for the number of flaps within the duration.
Step 9 Click the Bit Errors, Signal Loss, Sync Loss, Link-reset, and Credit Loss tabs and complete the port guard configuration.
Step 10 Click Apply Changes to activate the configuration.
To enable port guard for single or multiple interfaces using Device Manager, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical > Port Guard from the Physical Attributes pane.
You see the FC Interfaces listed.
Step 2 Click the Link Down tab, and then select the switch or port.
Step 3 Check the check box in the Enable column.
Step 4 (Optional) Enter the duration in seconds and the number of flaps. If the values are 0, the port goes into a down state even if the link flaps once. Otherwise, the link goes into a down state if the link flaps for the number of flaps within the duration.
Step 5 Click Apply Changes to activate the configuration.
Step 6 Click the TrustSec Violation tab, and then select the switch or port.
Step 7 Check the check box in the Enable column.
Step 8 (Optional) Enter the Duration in seconds and the number of flaps. If the values are 0, the port is brought to down state if a trustsec violation occurs even once. Otherwise, the link is brought to down state if a trustsec violation occurs for the number of flaps within the duration.
Step 9 Click Apply Changes to activate the configuration.
Note By default, the port monitor port guard is disabled. To enable this feature, you must explicitly configure the port monitor port guard feature on a particular counter by performing Step 3 or Step 4.
To configure the management interface using DCNM-SAN, follow these steps:
Step 1 Select a VSAN in the Logical Domains pane.
Step 2 In the Physical Attributes pane, expand Switches > Management.
You see the interface configuration in the Information pane.
Step 3 Click the IP Addresses tab and set the Interface, IP Address/Mask field.
Step 4 Click the General tab and set the Status Admin to up.
Step 5 (Optional) Set other configuration parameters using the other tabs.
To create a VSAN interface using DCNM-SAN, follow these steps:
Step 1 Expand Switches > Management.
You see the Create Interface dialog box.
Step 3 Select the switch and VSAN ID for which you want to configure a VSAN interface.
Note You can only create a VSAN interface for an existing VSAN. If the VSAN does not exist, you cannot create a VSAN interface for it.
Step 4 Set IPAddress/Mask to the IP address and subnet mask for the new VSAN interface.
Step 5 Click Create to create the VSAN interface or click Close to close the dialog box without creating the VSAN interface.
This section includes the following topics:
To display the interfaces owned using Device Manager, follow these steps:
Step 1 From the menu bar, click the Ports All drop-down button.
Step 2 From the drop-down list, select Owned.
You can use DCNM-SAN or Device Manager to collect interface statistics on any switch. These statistics are collected at intervals that you can set.
Note In DCNM-SAN, you can collect interface statistics by expanding ISLs and selecting Statistics from the Physical Attributes pane.
To obtain and display interface counters using Device Manager, follow these steps:
Step 1 From the menu bar, click Interface. Select Monitor.
Select any of the Interfaces that are displayed. For example, Virtual FC Enabled.
Step 2 Set both the number of seconds at which you want to poll the interface statistics and how you want the data represented in the Interval drop-down menus. For example, click 10s and LastValue/sec.
Step 3 Select any tab to view those related statistics.
Step 4 (Optional) Click the Pencil icon to reset the cumulative counters.
Step 5 (Optional) Click the Save icon to save the gathered statistics to a file or select the Print icon to print the statistics.
Step 6 Click Close when you are finished gathering and displaying statistics.
To show the SFP types for an interface using DCNM-SAN, follow these steps:
Step 1 Expand Switches > FC Interfaces > Physical. You see the interface configuration in the Information pane.
Step 2 Click the Physical tab to see the transmitter type for the selected interface.
To monitor a particular group using Device Manager, follow these steps:
Step 1 Right-click any port group module and select Check Oversubscription.
The Check Oversubscription table is displayed.
Step 2 From the Monitor drop-down list, select one particular group to monitor.
The Device Manager displays the monitoring table of the selected group with counters on each interval and displays the line chart automatically. From the Monitoring table, you can also choose the Bar chart icon to view the selected group as bar charts.