Configuring Internet Small Computer Systems Interface

Cisco MDS 9000 Family IP storage (IPS) services extend the reach of Fibre Channel SANs by using open-standard, IP-based technology. The switch allows IP hosts to access Fibre Channel storage using the Internet Small Computer Systems Interface (iSCSI) protocol.

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Noteblank.gif The iSCSI feature is specific to the Fibre Channel module with IPS ports and is available in Cisco MDS 9200 Switches or Cisco MDS 9500 Directors. In Cisco MDS NX-OS Release 7.3(0)DY(1) and later, iSCSI is not supported on Cisco MDS 9700 Directors with 24/10 port SAN Extension modules.

The Cisco MDS 9216i switch and the 14/2 Multiprotocol Services (MPS-14/2) module also allow you to use Fibre Channel, FCIP, and iSCSI features. The MPS-14/2 module is available for use in any switch in the Cisco MDS 9200 Series or Cisco MDS 9500 Series.


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Noteblank.gif For information on configuring Gigabit Ethernet interfaces, see “Basic Gigabit Ethernet Configuration for IPv4” section.


This chapter includes the following sections:

Overview of iSCSI

Cisco MDS 9000 Family IP Storage (IPS) services extend the reach of Fibre Channel SANs by using open-standard, IP-based technology. The iSCSI feature consists of routing iSCSI requests and responses between iSCSI hosts in an IP network and Fibre Channel storage devices in the Fibre Channel SAN that are accessible from any Fibre Channel interface of the Cisco MDS 9000 Family switch. Using the iSCSI protocol, the iSCSI driver allows an iSCSI host to transport SCSI requests and responses over an IP network. To use the iSCSI feature, you must explicitly enable iSCSI on the required switches in the fabric.

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Noteblank.gif The iSCSI feature is not supported on the Cisco Fabric Switch for HP c-Class Bladesystem and Cisco Fabric Switch for IBM BladeCenter.


The iSCSI feature consists of routing iSCSI requests and responses between iSCSI hosts in an IP network and Fibre Channel storage devices in the Fibre Channel SAN that are accessible from any Fibre Channel interface of the Cisco MDS 9000 Family switch (see Figure 4-1).

Figure 4-1 Transporting iSCSI Requests and Responses for Transparent iSCSI Routing

 

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Each iSCSI host that requires access to storage through the Fibre Channel module with IPS ports or MPS-14/2 module needs to have a compatible iSCSI driver installed. Using the iSCSI protocol, the iSCSI driver allows an iSCSI host to transport SCSI requests and responses over an IP network. From the host operating system perspective, the iSCSI driver appears to be an SCSI transport driver similar to a Fibre Channel driver in the host.

The Fibre Channel module with IPS ports or MPS-14/2 module provides transparent SCSI routing. IP hosts using the iSCSI protocol can transparently access targets on the Fibre Channel network. It (see Figure 4-1) provides an example of a typical configuration of iSCSI hosts connected to an Fibre Channel module with IPS ports or MPS-14/2 module through the IP network access Fibre Channel storage on the Fibre Channel SAN.

The Fibre Channel module with IPS ports or MPS-14/2 module create a separate iSCSI SAN view and Fibre Channel SAN view. For the iSCSI SAN view, the Fibre Channel module with IPS ports or MPS-14/2 module creates iSCSI virtual targets and then maps them to physical Fibre Channel targets available in the Fibre Channel SAN. They present the Fibre Channel targets to IP hosts as if the physical iSCSI targets were attached to the IP network (see Figure 4-2).

Figure 4-2 iSCSI SAN View—iSCSI Virtual Targets

 

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For the Fibre Channel SAN view, the Fibre Channel module with IPS ports or MPS-14/2 module presents iSCSI hosts as a virtual Fibre Channel host. The storage devices communicate with the virtual Fibre Channel host similar to communications performed with real Fibre Channel hosts (see Figure 4-3).

Figure 4-3 Fibre Channel SAN View—iSCSHI Host as an HBA

 

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The Fibre Channel module with IPS ports or MPS-14/2 modules transparently map the command between the iSCSI virtual target and the virtual Fibre Channel host (see Figure 4-4).

Figure 4-4 iSCSI to FCP (Fibre Channel) Routing

 

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Routing SCSI from the IP host to the Fibre Channel storage device consists of the following main actions:

  • The iSCSI requests and responses are transported over an IP network between the hosts and the Fibre Channel module with IPS ports or MPS-14/2 module.
  • The SCSI requests and responses are routed between the hosts on an IP network and the Fibre Channel storage device (converting iSCSI to FCP and vice versa). The Fibre Channel module with IPS ports or MPS-14/2 module performs this conversion and routing.
  • The FCP requests or responses are transported between the Fibre Channel module with IPS ports or MPS-14/2 module and the Fibre Channel storage devices.
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Noteblank.gif FCP (the Fibre Channel equivalent of iSCSI) carries SCSI commands over a Fibre Channel SAN.
Refer to the IETF standards for IP storage at http://www.ietf.org for information on the iSCSI protocol.


iSCSI Configuration Limits

iSCSI configuration has the following limits:

  • The maximum number of iSCSI and iSLB initiators supported in a fabric is 2000.
  • The maximum number of iSCSI and iSLB initiators supported is 200 per port.
  • The maximum number of iSCSI and iSLB sessions supported by an IPS port in either transparent or proxy initiator mode is 500.
  • The maximum number of iSCSI and iSLB session support by switch is 5000.
  • The maximum number of iSCSI and iSLB targets supported in a fabric is 6000.

Configuring iSCSI

This section describes how to configure iSCSI on the Cisco MDS 9000 Family switches.

This section includes the following sections:

Enabling iSCSI

To use the iSCSI feature, you must explicitly enable iSCSI on the required switches in the fabric. Alternatively, you can enable or disable the iSCSI feature directly on the required modules using Fabric Manager or Device Manager. By default, this feature is disabled in all switches in the Cisco MDS 9000 Family.

To enable iSCSI on any participating switch, follow these steps:

Command
Purpose

Step 1

switch# config terminalerminal

Enters the configuration commands, one per line. End with CNTL/Z.

Step 2

switch(config)# feature iscsi

Enables iSCSI on that switch.

switch(config)# no feature iscsi

Disables (default) iSCSI on that switch.

switch(config)# iscsi enable module <x>

Enables iSCSI modules on the switch.

Note New command added so that SME and iSCSI are available on the same switch.

switch(config)# no iscsi enable module <x>

Disables the iSCSI module on the switch.

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Caution blank.gif When you disable this feature, all related configurations are automatically discarded.

To enable iSCSI on any switch using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Figure 4-5 iSCSI Tables in Fabric Manager

 

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The Control tab is the default tab. You see the iSCSI enable status for all switches in the fabric that contain IPS ports.

Step 2blank.gif Choose enable from the Command column for each switch that you want to enable iSCSI on.

Step 3blank.gif Click the Apply Changes icon to save these changes.


 

To enable iSCSI on a module using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane.

Step 2blank.gif Click the Module Control tab.

You see the Module Control dialog box in the information pane (see Figure 4-6).

Figure 4-6 Module Control Dialog Box

 

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Step 3blank.gif Check the Mode Admin check box to enable iSCSI for a specified port on the selected module.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

To enable iSCSI on a module using Device Manager, follow these steps:


Step 1blank.gif Choose IP > iSCSI

You see the iSCSI table (see Figure 4-7).

Figure 4-7 iSCSI Table

 

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Step 2blank.gif Check the Mode Admin check box to enable iSCSI for the specified port on the selected module.

Step 3blank.gif Click Apply to save these changes.


 

Creating iSCSI Interfaces

Each physical Gigabit Ethernet interface on an Fibre Channel module with IPS ports, MPS-14/2 module or 1/10Gbps IPStorage port on a Cisco MDS 9250i Multiservice Fabric Switch can be used to translate and route iSCSI requests to Fibre Channel targets and responses in the opposite direction. To enable this capability, the corresponding iSCSI interface must be in an enabled state.

To enable iSCSI interfaces, follow these steps:


Step 1blank.gif Enable the required Gigabit Ethernet interface.

switch# config terminal
switch(config)# interface gigabitethernet 2/1
switch(config-if)# no shutdown
switch(config-if)# exit
switch(config)#
 

Step 2blank.gif Create the required iSCSI interface and enable the interface.

switch(config)# interface iscsi 2/1
switch(config-if)# no shutdown
 
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Noteblank.gif Use the tcp maximum-bandwidth-kbps and tcp maximum-bandwidth-mbps commands to configure the iSCSI speed and the switchport speed command to set the Physical IPStorage ports to 1Gbps or 10Gbps speed. The Cisco MDS switches do not limit the configuration of the iSCSI tcp maximum-bandwidth-kbps and maximum-bandwidth-mbps based on the speed of the underlying physical Gigabit Ethernet or IPStorage ports. Consequently, it is possible to configure iSCSI tcp maximum-bandwidth-kbps and tcp maximum-bandwidth-mbps commands to the equivalent of 10Gbps on a physical IPStorage port that is running at a 1Gbps speed. When configuring the tcp maximum bandwidth, ensure that it does not exceed the maximum speed of the physical IPStorage port.


Using the iSCSI Wizard

To use the iSCSI wizard in Fabric Manager, follow these steps:


Step 1blank.gif Click the iSCSI Setup Wizard icon.

You see the iSCSI Wizard Configure Initiator dialog box (see Figure 4-8).

Figure 4-8 iSCSI Wizard Configure Initiator Dialog Box

 

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Step 2blank.gif Select an existing iSCSI initiator or add the iSCSI node name or IP address for a new iSCSI initiator.

Step 3blank.gif Select the switch for this iSCSI initiator if you are adding a new iSCSI initiator and click Next.

You see the iSCSI Wizard Select Targets dialog box (see Figure 4-9).

Figure 4-9 iSCSI Wizard Select Targets Dialog Box

 

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Step 4blank.gif Select the VSAN and targets to associate with this iSCSI initiator and click Next.

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Noteblank.gif The iSCSI wizard turns on the Dynamic Import FC Targets feature.


You see the iSCSI Wizard Select Zone dialog box (see Figure 4-10).

Figure 4-10 iSCSI Wizard Select Zone Dialog Box

 

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Step 5blank.gif Set the zone name for this new iSCSI zone and check the ReadOnly check box if needed.

Step 6blank.gif Click Finish to create this iSCSI initiator.

If created, the target VSAN is added to the iSCSI host VSAN list.

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Noteblank.gif iSCSI wizard automatically turns on the Dynamic FC target import.



 

Presenting Fibre Channel Targets as iSCSI Targets

The Fibre Channel module with IPS ports or MPS-14/2 module presents physical Fibre Channel targets as iSCSI virtual targets, allowing them to be accessed by iSCSI hosts. The module presents these targets in one of the two ways:

  • Dynamic mapping—Automatically maps all the Fibre Channel target devices/ports as iSCSI devices. Use this mapping to create automatic iSCSI target names.
  • Static mapping—Manually creates iSCSI target devices and maps them to the whole Fibre Channel target port or a subset of Fibre Channel LUNs. With this mapping, you must specify unique iSCSI target names.

Static mapping should be used when iSCSI hosts should be restricted to subsets of LUs in the Fibre Channel targets and/or iSCSI access control is needed (see the “iSCSI Access Control” section). Also, static mapping allows the configuration of transparent failover if the LUs of the Fibre Channel targets are reachable by redundant Fibre Channel ports (see the “Transparent Target Failover” section).

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Noteblank.gif The Fibre Channel module with IPS ports or MPS-14/2 module does not import Fibre Channel targets to iSCSI by default. Either dynamic or static mapping must be configured before the Fibre Channel module with IPS ports or MPS-14/2 module makes Fibre Channel targets available to iSCSI initiators.


Dynamic Mapping

When you configure dynamic mapping the Fibre Channel module with IPS ports or MPS-14/2 module imports all Fibre Channel targets to the iSCSI domain and maps each physical Fibre Channel target port as one iSCSI target. That is, all LUs accessible through the physical storage target port are available as iSCSI LUs with the same LU number (LUN) as in the physical Fibre Channel target port.

The iSCSI target node name is created automatically using the iSCSI qualified name (IQN) format. The iSCSI qualified name is restricted to a maximum name length of 223 alphanumeric characters and a minimum length of 16 characters.

The Fibre Channel module with IPS ports or MPS-14/2 module creates an IQN formatted iSCSI target node name using the following conventions because the name must be unique in the SAN:

  • IPS Gigabit Ethernet ports that are not part of a Virtual Router Redundancy Protocol (VRRP) group or port channel use this format:
iqn.1987-05.com.cisco:05.<mgmt-ip-address>.<slot#>-<port#>-<sub-intf#>.<Target-pWWN>
 
  • IPS ports that are part of a VRRP group use this format:
iqn.1987-05.com.cisco:05.vrrp-<vrrp-ID#>-<vrrp-IP-addr>.<Target-pWWN>
 
  • Ports that are part of a port channel use this format:
iqn.1987-02.com.cisco:02.<mgmt-ip-address>.pc-<port-ch-sub-intf#>.<Target-pWWN>
 
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Noteblank.gif If you have configured a switch name, then the switch name is used instead of the management IP address. If you have not configured a switch name, the management IP address is used.


With this convention, each IPS port in a Cisco MDS 9000 Family switch creates a unique iSCSI target node name for the same Fibre Channel target port in the SAN.

For example, if an iSCSI target was created for a Fibre Channel target port with pWWN 31:00:11:22:33:44:55:66 and that pWWN contains LUN 0, LUN 1, and LUN 2, those LUNs would become available to an IP host through the iSCSI target node name iqn.1987-05.com.cisco:05. MDS_switch_management_IP_address.01-01.3100112233445566 (see Figure 4-11).

Figure 4-11 Dynamic Target Mapping

 

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Noteblank.gif Each iSCSI initiator may not have access to all targets depending on the configured access control mechanisms (see the “iSCSI Access Control” section).


To enable dynamic mapping of Fibre Channel targets into iSCSI, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi import target fc

Fibre Channel module with IPS ports and MPS-14/2 modules dynamically import all Fibre Channel targets in the Fibre Channel SAN into the IP network.

To enable dynamic mapping of Fibre Channel targets into iSCSI using Device Manager, follow these steps:


Step 1blank.gif Choose IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12).

Figure 4-12 iSCSI Configuration in Device Manager

 

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Step 2blank.gif Click the Target tab to display a list of existing iSCSI targets (see Figure 4-13).

Figure 4-13 iSCSI Targets Tab

 

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Step 3blank.gif Check the Dynamically Import FC Targets check box.

Step 4blank.gif Click Apply to save this change.


 

Static Mapping

You can manually (statically) create an iSCSI target by assigning a user-defined unique iSCSI node name to it. The iSCSI qualified name is restricted to a minimum length of 16 characters and a maximum of 223 characters. A statically mapped iSCSI target can either map the whole Fibre Channel target port (all LUNs in the target port mapped to the iSCSI target), or it can contain one or more LUs from a Fibre Channel target port (see Figure 4-14).

Figure 4-14 Statically Mapped iSCSI Targets

 

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To create a static iSCSI virtual target for the entire Fibre Channel target port using Device Manager, follow these steps:


Step 1blank.gif Click IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12).

Step 2blank.gif Click the Targets tab to display a list of existing iSCSI targets (see Figure 4-13).

Step 3blank.gif Click Create to create an iSCSI target.

You see the Create iSCSI Targets dialog box (See Figure 4-15).

Figure 4-15 Create iSCSI Targets Dialog Box

 

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Step 4blank.gif Set the iSCSI target node name in the iSCSI Name field, in IQN format.

Step 5blank.gif Set the Port WWN field for the Fibre Channel target port you are mapping.

Step 6blank.gif Click the Select from List radio button and set the iSCSI initiator node names or IP addresses that you want this virtual iSCSI target to access, or click the All radio button to let the iSCSI target access all iSCSI initiators. Also see the “iSCSI Access Control” section.

Step 7blank.gif Click the Select from List radio button and check each interface you want to advertise the iSCSI targets on or click the All radio button to advertise all interfaces.

Step 8blank.gif Click Apply to save this change.


 

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Tipblank.gif An iSCSI target cannot contain more than one Fibre Channel target port. If you have already mapped the whole Fibre Channel target port, you cannot use the LUN mapping option.


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Noteblank.gif See the “iSCSI-Based Access Control” section for more information on controlling access to statically mapped targets.


Advertising Static iSCSI Targets

You can limit the Gigabit Ethernet interfaces through which static iSCSI targets are advertised. By default iSCSI targets are advertised on all Gigabit Ethernet interfaces, subinterfaces, port channel interfaces, and port channel subinterfaces.

To configure a specific interface that should advertise the iSCSI virtual target using Device Manager, follow these steps:


Step 1blank.gif Select IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12).

Step 2blank.gif Click the Targets tab to display a list of existing iSCSI targets (see Figure 4-13).

Step 3blank.gif Right-click the iSCSI target that you want to modify and click Edit Advertised.

You see the Advertised Interfaces dialog box.

Step 4blank.gif (Optional) Right-click an interface that you want to delete and click Delete.

Step 5blank.gif (Optional) Click Create to advertise on more interfaces.

You see the Create Advertised Interfaces dialog box.


 

To configure a specific interface that should advertise the iSCSI virtual target, follow these steps:

Command
Purpose

Step 1

switch(config-iscsi-tgt)# advertise interface GigabitEthernet 2/5

Advertises the virtual target only on the specified interface. By default, it is advertised on all interfaces in all Fibre Channel module with IPS ports or MPS-14/2 modules.

Note To advertise the virtual target on multiple interfaces, issue the command for each interface.

switch(config-iscsi-tgt)# no advertise interface GigabitEthernet 2/5

Removes this interface from the list of interfaces from which this target is advertised.

iSCSI Virtual Target Configuration Examples

This section provides three examples of iSCSI virtual target configurations.

Example 1

This example assigns the whole Fibre Channel target as an iSCSI virtual target. All LUNs that are part of the Fibre Channel target are available as part of the iSCSI target (see Figure 4-16).

Figure 4-16 Assigning iSCSI Node Names

 

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iscsi virtual-target name iqn.1987-02.com.cisco.target-1
pWWN 28:00:01:02:03:04:05:06
 

Example 2

This example maps a subset of LUNs of a Fibre Channel target to three iSCSI virtual targets. Each iSCSI target only has one LUN (see Figure 4-17).

Figure 4-17 Mapping LUNs to an iSCSI Node Name

 

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iscsi virtual-target name iqn.1987-02.com.cisco.target-1
pWWN 28:00:01:02:03:04:05:06 fc-lun 0 iscsi-lun 0
iscsi virtual-target name iqn.1987-02.com.cisco.target-2
pWWN 28:00:01:02:03:04:05:06 fc-lun 1 iscsi-lun 0
iscsi virtual-target name iqn.1987-02.com.cisco.target-3
pWWN 28:00:01:02:03:04:05:06 fc-lun 2 iscsi-lun 0

Example 3

This example maps three subsets of Fibre Channel LUN targets to three iSCSI virtual targets. Two iSCSI targets have one LUN and the third iSCSI target has two LUNs (see Figure 4-18).

Figure 4-18 Mapping LUNs to Multiple iSCSI Node Names

 

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iscsi virtual-target name iqn.1987-02.com.cisco.target-1
pWWN 28:00:01:02:03:04:05:06 fc-lun 0 iscsi-lun 0
iscsi virtual-target name iqn.1987-02.com.cisco.target-2
pWWN 28:00:01:02:03:04:05:06 fc-lun 1 iscsi-lun 0
iscsi virtual-target name iqn.1987-02.com.cisco.target-3
pWWN 28:00:01:02:03:04:05:06 fc-lun 2 iscsi-lun 0
pWWN 28:00:01:02:03:04:05:06 fc-lun 3 iscsi-lun 1
 

Presenting iSCSI Hosts as Virtual Fibre Channel Hosts

The Fibre Channel module with IPS ports or MPS-14/2 module connects to the Fibre Channel storage devices on behalf of the iSCSI host to send commands and transfer data to and from the storage devices. These modules use a virtual Fibre Channel N port to access the Fibre Channel storage devices on behalf of the iSCSI host. iSCSI hosts are identified by either iSCSI qualified name (IQN) or IP address.

Initiator Identification

iSCSI hosts can be identified by the Fibre Channel module with IPS ports or MPS-14/2 module using the following:

  • iSCSI qualified name (IQN)

An iSCSI initiator is identified based on the iSCSI node name it provides in the iSCSI login. This mode can be useful if an iSCSI host has multiple IP addresses and you want to provide the same service independent of the IP address used by the host. An initiator with multiple IP addresses (multiple network interface cards—NICs) has one virtual N port on each IPS port to which it logs in.

  • IP address

An iSCSI initiator is identified based on the IP address of the iSCSI host. This mode is useful if an iSCSI host has multiple IP addresses and you want to provide different service-based on the IP address used by the host. It is also easier to get the IP address of a host compared to getting the iSCSI node name. A virtual N port is created for each IP address it uses to log in to iSCSI targets. If the host using one IP address logs in to multiple IPS ports, each IPS port will create one virtual N port for that IP address.

You can configure the iSCSI initiator identification mode on each IPS port and all the iSCSI hosts terminating on the IPS port will be identified according to that configuration. The default mode is to identify the initiator by name.

To specify the initiator identification mode, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters the configuration mode.

Step 2

switch(config)# interface iscsi 4/1

switch(config-if)#

Selects the iSCSI interface on the switch that identifies all the initiators.

Step 3

switch(config-if)# switchport initiator id ip-address

Identifies the iSCSI initiator based on the IP address.

switch(config-if)# switchport initiator id name

Identifies the iSCSI initiator based on the initiator node name. This is the default behavior.

To specify the initiator identification mode using Fabric Manager, follow these steps:


Step 1blank.gif Choose Interfaces > FC Logical from the Physical Attributes pane.

You see the interfaces configuration in the Information pane.

Step 2blank.gif Click the iSCSI tab.

You see the iSCSI interfaces configuration.

Step 3blank.gif Right-click the Initiator ID Mode field for the iSCSI interface that you want to modify and select name or ipaddress from the drop-down menu.

Step 4blank.gif Click Apply Changes to save this change.


 

Initiator Presentation Modes

Two modes are available to present iSCSI hosts in the Fibre Channel fabric: transparent initiator mode and proxy initiator mode.

  • In transparent initiator mode, each iSCSI host is presented as one virtual Fibre Channel host. The benefit of transparent mode is it allows a finer level of Fibre Channel access control configuration (similar to managing a “real” Fibre Channel host). Because of the one-to-one mapping from iSCSI to Fibre Channel, each host can have different zoning or LUN access control on the Fibre Channel storage device.
  • In proxy initiator mode, there is only one virtual Fibre Channel host per one IPS port and all iSCSI hosts use that to access Fibre Channel targets. In a scenario where the Fibre Channel storage device requires explicit LUN access control for every host, the static configuration for each iSCSI initiator can be overwhelming. In this case, using the proxy initiator mode simplifies the configuration.
caut.gif

Caution blank.gif Enabling proxy initiator mode of an iSCSI interface that is part of an iSLB VRRP group impacts load balancing on the interface. See the “Changing iSCSI Interface Parameters and the Impact on Load Balancing” section.

The Cisco MDS switches support the following iSCSI session limits:

  • The maximum number of iSCSI sessions on a switch is 5000.
  • The maximum number of iSCSI sessions per IPS port in transparent initiator mode is 500.
  • The maximum number of iSCSI sessions per IPS port in proxy initiator mode is 500.
  • The maximum number of concurrent sessions an IPS port can create is five (but the total number of sessions that can be supported is 500).
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Noteblank.gif If more than five iSCSI sessions try to come up simultaneously on a port, the initiator receives a temporary error and later retries to create a session.


Transparent Initiator Mode

Each iSCSI host is presented as one virtual Fibre Channel host (that is, one Fibre Channel N port). The benefit of transparent mode is it allows a finer-level of Fibre Channel access control configuration. Because of the one-to-one mapping from iSCSI to Fibre Channel, each host can have different zoning or LUN access control on the Fibre Channel storage device.

When an iSCSI host connects to the Fibre Channel module with IPS ports or MPS-14/2 module, a virtual host N port (HBA port) is created for the host (see Figure 4-19). Every Fibre Channel N port requires a unique Node WWN and Port WWN.

Figure 4-19 Virtual Host HBA Port

 

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After the virtual N port is created with the WWNs, a fabric login (FLOGI) is done through the virtual iSCSI interface of the IPS port. After the FLOGI is completed, the virtual N port is online in the Fibre Channel SAN and virtual N port is registered in the Fibre Channel name server. The Fibre Channel module with IPS ports or MPS-14/2 module registers the following entries in the Fibre Channel name server:

  • IP address of the iSCSI host in the IP-address field on the name server
  • IQN of the iSCSI host in the symbolic-node-name field of the name server
  • SCSI_FCP in the FC-4 type field of the name server
  • Initiator flag in the FC-4 feature of the name server
  • Vendor-specific iSCSI GW flag in the FC-4 type field to identify the N-port device as an iSCSI gateway device in the name server.

When all the iSCSI sessions from the iSCSI host are terminated, the Fibre Channel module with IPS ports or MPS-14/2 modules perform an explicit Fabric logout (FLOGO) to remove the virtual N-port device from the Fibre Channel SAN (this indirectly de-registers the device from the Fibre Channel name server).

For every iSCSI session from the host to the iSCSI virtual target there is a corresponding Fibre Channel session to the real Fibre Channel target. There are three iSCSI hosts (see Figure 4-19), and all three of them connect to the same Fibre Channel target. There is one Fibre Channel session from each of the three virtual Fibre Channel hosts to the target.

iSCSI Initiator Idle Timeout

iSCSI initiator idle timeout specifies the time for which the virtual Fibre Channel N port is kept idle after the initiator logs out from its last iSCSI session. The default value for this timer is 300 seconds. This is useful to avoid N ports logging in to and logging off of the Fibre Channel SAN as transient failure occurs in the IP network. This helps reduce unnecessary RSCNs being generated in the Fibre Channel SAN.

To configure the initiator idle timeout, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters the configuration mode.

Step 2

switch(config)# iscsi initiator idle-timeout 10

Configures the iSCSI initiators to have an idle timeout value of 10 seconds.

To configure the initiator idle timeout using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Step 2blank.gif Click the Globals tab.

You see the iSCSI global configuration.

Step 3blank.gif Right-click on the InitiatorIdle Timeout field that you want to modify and enter the new timeout value.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

WWN Assignment for iSCSI Initiators

An iSCSI host is mapped to an N port’s WWNs by one of the following mechanisms:

  • Dynamic mapping (default)
  • Static mapping

Dynamic Mapping

With dynamic mapping, an iSCSI host is mapped to a dynamically generated port WWN (pWWN) and node WWN (nWWN). Each time the iSCSI host connects it might be mapped to a different WWN. Use this option if no access control is required on the Fibre Channel target device (because the target device access control is usually configured using the host WWN).

The WWNs are allocated from the MDS switch's WWN pool. The WWN mapping to the iSCSI host is maintained as long as the iSCSI host has at least one iSCSI session to the IPS port. When all iSCSI sessions from the host are terminated and the Fibre Channel module with IPS ports or MPS-14/2 module performs an FLOGO for the virtual N port of the host, the WWNs are released back to the switch's Fibre Channel WWN pool. These addresses are then available for assignment to other iSCSI hosts requiring access to the Fibre Channel Fabric.

The following are three dynamic initiator modes are supported:

  • iSCSI—Dynamic initiators are treated as iSCSI initiators and can access dynamic virtual targets and configured iSCSI virtual targets.
  • iSLB—Dynamic initiators are treated as iSLB initiators.
  • Deny—Dynamic initiators are not allowed to log in to the MDS switch.

iSCSI dynamic mapping is the default mode of operation. This configuration is distributed using CFS.

note.gif

Noteblank.gif Configuring dynamic initiator modes is supported only through the CLI, not through Device Manager or Fabric Manager.


To configure dynamic mapping (using the name option) for an iSCSI initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi dynamic initiator islb

Specifies iSLB dynamic initiator mode.

switch(config)# iscsi dynamic initiator deny

Disallows dynamic initiators from logging on to the MDS switch.

switch(config)# no iscsi dynamic initiator islb

Reverts to iSCSI mode (default).

Static Mapping

With static mapping, an iSCSI host is mapped to a specific pWWN and nWWN. This mapping is maintained in persistent storage and each time the iSCSI host connects, the same WWN mapping is used. This mode is required if you use access control on the target device.

You can implement static mapping in one of two ways:

  • User assignment—You can specify your own unique WWN by providing them during the configuration process.
  • System assignment—You can request that the switch provide a WWN from the switch’s Fibre Channel WWN pool and keep the mapping in its configuration.
tip.gif

Tip We recommend using the system-assign option. If you manually assign a WWN, you must ensure its uniqueness (see the Cisco Fabric Manager Fabric Configuration Guide and Cisco MDS 9000 Family NX-OS Fabric Configuration Guide for more information). You should not use any previously assigned WWNs.


To configure static mapping (using the name option) for an iSCSI initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi initiator name iqn.1987-02.com.cisco.initiator

switch(config-iscsi-init)#

Configures an iSCSI initiator using the iSCSI name of the initiator node. The maximum name length is restricted to 223 alphanumeric characters. The minimum length is 16.

switch(config)# no iscsi initiator name iqn.1987-02.com.cisco.initiator

Deletes the configured iSCSI initiator.

To configure static mapping for an iSCSI initiator using Device Manager, follow these steps:


Step 1blank.gif Select IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12). The Initiators tab is the default.

Step 2blank.gif Click Create to create an iSCSI initiator.

You see the Create iSCSI Initiators dialog box (see Figure 4-20).

Figure 4-20 Create iSCSI Initiators Dialog Box

 

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Step 3blank.gif Set the iSCSI node name or IP address and VSAN membership.

Step 4blank.gif In the Node WWN section, check the Persistent check box.

Step 5blank.gif Check the System Assigned check box if you want the switch to assign the nWWN or leave this unchecked and set the Static WWN field.

Step 6blank.gif In the Port WWN section, check the Persistent check box if you want to statically map pWWNs to the iSCSI initiator.

Step 7blank.gif If persistent, check the System Assigned check box and set the number of pWWNs to reserve for this iSCSI initiator if you want the switch to assign pWWNs. Alternately, you can leave this unchecked and set one or more pWWNs for this iSCSI initiator.

Step 8blank.gif (Optional) Set the AuthUser field if authentication is enabled. Also see the “iSCSI Session Authentication” section.

Step 9blank.gif Click Create to create this iSCSI initiator.


 

To configure static mapping (using the ip-address option) for an iSCSI initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi initiator ip-address 10.50.0.0

switch(config-iscsi-init)#

Configures an iSCSI initiator using the IPv4 address of the initiator node.

switch(config)# iscsi initiator ip-address 2001:0DB8:800:200C::417A

switch(config-iscsi-init)#

Configures an iSCSI initiator using the IPv6 unicast address of the initiator node.

switch(config)# no iscsi initiator ip-address 2001:0DB8:800:200C::417A

(Optional) Deletes the configured iSCSI initiator.

To assign the WWN for an iSCSI initiator, follow these steps:

Command
Purpose

Step 1

switch(config-iscsi-init)# static nWWN system-assign

Uses the switch’s WWN pool to allocate the nWWN for this iSCSI initiator and keeps it persistent.

switch(config-iscsi-init)# static nWWN 20:00:00:05:30:00:59:11

Assigns the user provided WWN as the nWWN for the iSCSI initiator. You can only specify one nWWN for each iSCSI node.

Step 2

switch(config-iscsi-init)# static pWWN system-assign 2

Uses the switch’s WWN pool to allocate two pWWNs for this iSCSI initiator and keeps them persistent. The range is from 1 to 64.

switch(config-iscsi-init)# static pWWN 21:00:00:20:37:73:3b:20

Assigns the user provided WWN as the pWWN for the iSCSI initiator.

note.gif

Noteblank.gif If the system-assign option is used to configure WWNs for an iSCSI initiator, when the configuration is saved to an ASCII file the system-assigned WWNs are also saved. Subsequently if you perform a write erase, you must manually delete the WWN configuration from the ASCII file. Failing to do so can cause duplicate WWN assignments if the ASCII configuration file is reapplied on the switch.


Making the Dynamic iSCSI Initiator WWN Mapping Static

After a dynamic iSCSI initiator has already logged in, you may decide to permanently keep the automatically assigned nWWN/pWWN mapping so this initiator uses the same mapping the next time it logs in.

You can convert a dynamic iSCSI initiator to static iSCSI initiator and make its WWNs persistent (see the “Dynamic Mapping” section).

note.gif

Noteblank.gif You cannot convert a dynamic iSCSI initiator to a static iSLB initiator or a dynamic iSLB initiator to a static iSCSI initiator.


note.gif

Noteblank.gif Making the dynamic pWWNs static after the initiator is created is supported only through the CLI, not through Device Manager or Fabric Manager. In Fabric Manager or Device Manager, you must delete and then recreate this initiator to have the pWWNs static.


To permanently keep the automatically assigned nWWN/pWWN mapping, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi save-initiator name iqn.1987-02.com.cisco.initiator

Saves the nWWN and pWWNs that have automatically been assigned to the iSCSI initiator whose name is specified.

switch(config)# iscsi save-initiator ip-address 10.10.100.11

Saves the nWWN and pWWNs that have automatically been assigned to the iSCSI initiator whose IPv4 address is specified.

switch(config)# iscsi save-initiator ip-address 2001:0DB8:800:200C::417A

Saves the nWWN and pWWNs that have automatically been assigned to the iSCSI initiator whose IPv6 unicast address is specified.

switch(config)# iscsi save-initiator

Saves the nWWN and pWWNs that have automatically been assigned to all the initiators.

Step 3

switch(config)# exit

switch#

Returns to EXEC mode.

Step 4

switch# copy running-config startup-config

Saves the nWWN/pWWN mapping configuration across system reboots.

Checking for WWN Conflicts

WWNs assigned to static iSCSI initiators by the system can be inadvertently returned to the system when an upgrade fails or you downgrade the system software (manually booting up an older Cisco MDS SAN-OS release without using the install all command). In these instances, the system can later assign those WWNs to other iSCSI initiators (dynamic or static) and cause conflicts.

You can address this problem by checking for and removing any configured WWNs that belong to the system whenever such scenarios occur.

To check for and remove WWN conflicts, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi duplicate-wwn-check

List of Potential WWN Conflicts:

--------------------------------

Node : iqn.test-local-nwwn:1-local-pwwn:1

nWWN : 22:03:00:0d:ec:02:cb:02

pWWN : 22:04:00:0d:ec:02:cb:02

Checks for WWN conflicts.

Step 3

switch(config)# iscsi initiator name iqn.test-local-nwwn:1-local-pwwn:1

Enters iSCSI initiator configuration mode for the initiator named iqn.test-local-nwwn:1-local-pwwn:1.

Step 4

switch(config-iscsi-init)# no static nWWN 22:03:00:0d:ec:02:cb:02

Removes a conflicting nWWN.

Step 5

switch(config-iscsi-init)# no static pWWN 22:04:00:0d:ec:02:cb:02

Removes a conflicting pWWN.

To permanently keep the automatically assigned nWWN mapping using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Step 2blank.gif Click the Initiators tab.

You see the iSCSI initiators configured.

Step 3blank.gif Check the Persistent Node WWN check box for the iSCSI initiators that you want to make static.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

Proxy Initiator Mode

In the event that the Fibre Channel storage device requires explicit LUN access control for every host use the transparent initiator mode (presenting one iSCSI host as one Fibre Channel host). Every iSCSI host has to be configured statically. This can mean several configuration tasks for each iSCSI host. If you do not need explicit LUN access control, using the proxy initiator mode simplifies the configuration.

In this mode, only one virtual host N port (HBA port) is created per IPS port. All the iSCSI hosts connecting to that IPS port will be multiplexed using the same virtual host N port (see Figure 4-21). This mode simplifies the task of statically binding WWNs. LUN mapping and assignment on the Fibre Channel storage array must be configured to allow access from the proxy virtual N port’s pWWN for all LUNs used by each iSCSI initiator that connects through this IPS port. The LUN is then assigned to each iSCSI initiator by configuring iSCSI virtual targets (see the “Static Mapping” section) with LUN mapping and iSCSI access control (see the “iSCSI Access Control” section).

Figure 4-21 Multiplexing IPS Ports

 

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Proxy initiator mode can be configured on a per IPS port basis, in which case only iSCSI initiators terminating on that IPS port will be in this mode.

When an IPS port is configured in proxy-initiator mode, fabric login (FLOGI) is done through the virtual iSCSI interface of the IPS port. After the FLOGI is completed, the proxy-initiator virtual N port is online in the Fibre Channel fabric and virtual N port is registered in the Fibre Channel name server. The Fibre Channel module with IPS ports or MPS-14/2 module registers the following entries in the Fibre Channel name server:

  • iSCSI interface name iSCSI slot /port is registered in the symbolic-node-name field of the name server
  • SCSI_FCP in the FC-4 type field of the name server
  • Initiator flag in the FC-4 feature of the name server
  • Vendor specific flag (iscsi-gw) in the FC-4 type field to identify the N-port device as an iSCSI gateway device in the name server

Similar to transparent initiator mode, the user can provide a pWWN and nWWN or request a system assigned WWN for the proxy initiator N port.

caut.gif

Caution blank.gif Enabling the proxy initiator mode of an iSCSI interface that is part of an iSLB VRRP group impacts load balancing on the interface. See the “Changing iSCSI Interface Parameters and the Impact on Load Balancing” section.

To configure the proxy initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# interface iscsi 4/1

switch(config-if)#

Selects the iSCSI interface on the switch that initiators will connect to.

Step 3

switch(config-if)# switchport proxy-initiator

Configures the proxy initiator mode with system-assignment nWWN and pWWN.

switch(config-if)# no switchport proxy-initiator

(Optional) Disables the proxy initiator mode.

Step 4

switch(config-if)# switchport proxy-initiator nWWN 11:11:11:11:11:11:11:11 pwwn 22:22:22:22:22:22:22:22

(Optional) Configures the proxy initiator mode using the specified WWNs.

switch(config-if)# no switchport proxy-initiator nWWN 11:11:11:11:11:11:11:11 pwwn 22:22:22:22:22:22:22:22

(Optional) Disables the proxy initiator mode.

To configure the proxy initiator using Fabric Manager, follow these steps:


Step 1blank.gif Expand Switches, expand Interfaces, and then select FC Logical in the Physical Attributes pane.

You see the Interface tables in the Information pane (see Figure 4-22).

Figure 4-22 FC Logical Interface Tables

 

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Step 2blank.gif In Device Manager, select Interface > Ethernet and iSCSI.

You see the Ethernet Interfaces and iSCSI dialog box (See in Figure 4-23).

Figure 4-23 Ethernet Interfaces and iSCSI Dialog Box

 

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Step 3blank.gif Click the iSCSI tab in either FM or DM.

You see the iSCSI interface configuration table (see Figure 4-24).

Figure 4-24 iSCSI Tab in Device Manager

 

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Step 4blank.gif Check the Proxy Mode Enable check box.

Step 5blank.gif Click the Apply Changes icon in Fabric Manager or click Apply in Device Manager to save these changes.


 

note.gif

Noteblank.gif When an interface is in proxy initiator mode, you can only configure Fibre Channel access control (zoning) based on the iSCSI interface’s proxy N port attributes—the WWN pairs or the FC ID. You cannot configure zoning using iSCSI attributes such as IP address or IQN of the iSCSI initiator. To enforce initiator-based access control, use iSCSI based access control (see the “iSCSI Access Control” section).


VSAN Membership for iSCSI

VSAN membership can be configured for an iSCSI interface, called the port VSAN. All the iSCSI devices that connect to this interface automatically become members of this VSAN, if it is not explicitly configured in a VSAN. The default port VSAN of an iSCSI interface is VSAN 1. Similar to Fibre Channel devices, iSCSI devices have two mechanisms by which VSAN membership can be defined.

  • iSCSI host—VSAN membership to iSCSI host. (This method takes precedent over the iSCSI interface).
  • iSCSI interface—VSAN membership to iSCSI interface. (All iSCSI hosts connecting to this iSCSI interface inherit the interface VSAN membership if the host is not configured in any VSAN by the iSCSI host method).

Configuring VSAN Membership for iSCSI Hosts

Individual iSCSI hosts can be configured to be in a specific VSAN. The specified VSAN overrides the iSCSI interface VSAN membership.

To assign VSAN membership for iSCSI hosts, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi initiator name iqn.1987-02.com.cisco.initiator

switch(config-iscsi-init)#

Configures an iSCSI initiator.

Step 3

switch(config-iscsi-init)# vsan 3

Assigns the iSCSI initiator node to a specified VSAN.

Note You can assign this host to one or more VSANs.

switch(config-iscsi-init)# no vsan 5

Removes the iSCSI node from the specified VSAN.

To assign VSAN membership for iSCSI hosts using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Step 2blank.gif Click the Initiators tab.

You see the iSCSI initiators configured.

Step 3blank.gif Fill in the VSAN Membership field to assign a VSAN to the iSCSI hosts.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

note.gif

Noteblank.gif When an initiator is configured in any other VSAN (other than VSAN 1), for example VSAN 2, the initiator is automatically removed from VSAN 1. If you also want it to be present in VSAN 1, you must explicitly configure the initiator in VSAN 1.


Configuring Default Port VSAN for iSCSI Interfaces

VSAN membership can be configured for an iSCSI interface, called the port VSAN. All the iSCSI devices that connect to this interface automatically become members of this VSAN, if it is not explicitly configured in a VSAN. In other words, the port VSAN of an iSCSI interface is the default VSAN for all dynamic iSCSI initiators. The default port VSAN of an iSCSI interface is VSAN 1.

caut.gif

Caution blank.gif Changing the VSAN membership of an iSCSI interface that is part of an iSLB VRRP group impacts load balancing on the interface. See the “Changing iSCSI Interface Parameters and the Impact on Load Balancing” section.

To change the default port VSAN for an iSCSI interface, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi interface vsan-membership

Enables you to configure VSAN membership for iSCSI interfaces.

Step 3

switch(config)# vsan database

switch(config-vsan-db)#

Configures the database for a VSAN. Application specific VSAN parameters cannot be configured from this prompt.

Step 4

switch(config - vsan-db)# vsan 2 interface iscsi 2/1

Assigns the membership of the iscsi 2/1 interface to the specified VSAN (VSAN 2).

switch(config - vsan-db)# no vsan 2 interface iscsi 2/1

Reverts to using the default VSAN as the port VSAN of the iSCSI interface.

To change the default port VSAN for an iSCSI interface using Device Manager, follow these steps:


Step 1blank.gif Choose Interface > Ethernet and iSCSI.

You see the Ethernet Interfaces and iSCSI dialog box (see Figure 4-23).

Step 2blank.gif Click the iSCSI tab.

You see the iSCSI interface configuration table (see Figure 4-24).

Step 3blank.gif Double-click the PortVSAN column and modify the default port VSAN.

Step 4blank.gif Click Apply to save these changes.


 

Example of VSAN Membership for iSCSI Devices

Figure 4-25 provides an example of VSAN membership for iSCSI devices:

  • iSCSI interface 1/1 is a member of VSAN Y.
  • iSCSI initiator host A has explicit VSAN membership to VSAN X.
  • Three iSCSI initiators (host A, host B, and host C) C connect to iSCSI interface 1/1.

Figure 4-25 VSAN Membership for iSCSI Interfaces

 

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Host A’s virtual Fibre Channel N port will be added to VSAN X because of explicit membership for the initiator. The virtual host-B and host-C N ports do not have any explicit membership configuration so they will inherit the iSCSI interface VSAN membership and be part of VSAN Y.

Advanced VSAN Membership for iSCSI Hosts

An iSCSI host can be a member of multiple VSANs. In this case, multiple virtual Fibre Channel hosts are created, one in each VSAN in which the iSCSI host is a member. This configuration is useful when certain resources such as Fibre Channel tape devices need to be shared among different VSANs.

iSCSI Access Control

Two methods of access control are available for iSCSI devices. Depending on the initiator mode used to present the iSCSI hosts in the Fibre Channel fabric, either or both of the access control methods can be used.

  • Fiber Channel zoning-based access control—Fibre Channel zoning has been extended to support iSCSI devices, and this extension has the advantage of having a uniform, flexible access control mechanism across the whole SAN. In the case of iSCSI, multiple iSCSI devices may be connected behind an iSCSI interface. Interface-based zoning may not be useful because all iSCSI devices behind the interface will automatically be within the same zone.
  • iSCSI ACL-based access control—iSCSI-based access control is applicable only if static iSCSI virtual targets are created. For a static iSCSI target, you can configure a list of iSCSI initiators that are allowed to access the targets. By default, static iSCSI virtual targets are not accessible to any iSCSI host.

Depending on the initiator mode used to present the iSCSI hosts in the Fibre Channel fabric, either or both the access control mechanisms can be used.

The following topics are included in this section:

Fibre Channel Zoning-Based Access Control

Cisco SAN-OS Release 3.x and NX-OS Release 4.1(1b) VSAN and zoning concepts have been extended to cover both Fibre Channel devices and iSCSI devices. Zoning is the standard access control mechanism for Fibre Channel devices, which is applied within the context of a VSAN. Fibre Channel zoning has been extended to support iSCSI devices, and this extension has the advantage of having a uniform, flexible access control mechanism across the whole SAN.

Common mechanisms for identifying members of a Fibre Channel zone are the following:

  • Fibre Channel device pWWN.
  • Interface and switch WWN. Device connecting via that interface is within the zone.

See the Cisco Fabric Manager Fabric Configuration Guide and Cisco MDS 9000 Family NX-OS Fabric Configuration Guide for details on Fibre Channel zoning.

In the case of iSCSI, multiple iSCSI devices may be connected behind an iSCSI interface. Interface-based zoning may not be useful because all the iSCSI devices behind the interface will automatically be within the same zone.

In transparent initiator mode (where one Fibre Channel virtual N port is created for each iSCSI host as described in the “Transparent Initiator Mode” section), if an iSCSI host has static WWN mapping then the standard Fibre Channel device pWWN-based zoning membership mechanism can be used.

Zoning membership mechanism has been enhanced to add iSCSI devices to zones based on the following:

  • IPv4 address/subnet mask
  • IPv6 address/prefix length
  • iSCSI qualified name (IQN)
  • Symbolic-node-name (IQN)

For iSCSI hosts that do not have a static WWN mapping, the feature allows the IP address or iSCSI node name to be specified as zone members. Note that iSCSI hosts that have static WWN mapping can also use these features. IP address based zone membership allows multiple devices to be specified in one command by providing the subnet mask.

note.gif

Noteblank.gif In proxy initiator mode, all iSCSI devices connecting to an IPS port gain access to the Fibre Channel fabric through a single virtual Fibre Channel N port. Zoning based on the iSCSI node name or IP address will not have any effect. If zoning based on pWWN is used, then all iSCSI devices connecting to that IPS port will be put in the same zone. To implement individual initiator access control in proxy initiator mode, configure an iSCSI ACL on the virtual target (see the “iSCSI-Based Access Control” section).


To add an iSCSI initiator to the zone database, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# zone name iSCSIzone vsan 1

switch(config-zone)

Creates a zone name for the iSCSI devices in the Fibre Channel module with IPS ports or MPS-14/2 module to be included.

Step 3

switch(config-zone)# member symbolic-nodename iqn.1987-02.com.cisco.initiator1

Assigns an iSCSI node name-based membership into a zone.

switch(config-zone)# no member symbolic-nodename iqn.1987-02.com.cisco.init1

(Optional) Deletes the specified device from a zone.

switch(config-zone)# member ip-address 10.50.1.1

Assigns an iSCSI IPv4 address-based membership into a zone.

switch(config-zone)# no member ip-address 10.50.1.1

(Optional) Deletes the specified device from a zone.

switch(config-zone)# member ipv6-address 2001:0DB8:800:200C::417A

Assigns an iSCSI IPv6 address-based membership into a zone.

switch(config-zone)# no member ipv6-address 2001:0DB8:800:200C::417A

Deletes the specified device from a zone.

switch(config-zone)# member pwwn 20:00:00:05:30:00:59:11

Assigns an iSCSI port WWN-based membership into a zone.

switch(config-zone)# no member pwwn 20:00:00:05:30:00:59:11

Deletes the device identified by the port WWN from a zone.

To add an iSCSI initiator to the zone database using Fabric Manager, follow these steps:


Step 1blank.gif Choose Zone > Edit Local Full Zone Database.

You see the Edit Local Zone Database dialog box (see Figure 4-26).

Figure 4-26 Edit Local Zone Database Dialog Box in Fabric Manager

 

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Step 2blank.gif Select the VSAN you want to add the iSCSI host initiator to and click OK.

You see the available zones and zone sets for that VSAN (see Figure 4-27).

Figure 4-27 Available Zones and Zone Sets

 

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Step 3blank.gif From the list of available devices with iSCSI host initiators, drag the initiators to add into the zone.

Step 4blank.gif Click Distribute to distribute the change.


 

iSCSI-Based Access Control

iSCSI-based access control is applicable only if static iSCSI virtual targets are created (see the “Static Mapping” section). For a static iSCSI target, you can configure a list of iSCSI initiators that are allowed to access the targets.

By default, static iSCSI virtual targets are not accessible to any iSCSI host. You must explicitly configure accessibility to allow an iSCSI virtual target to be accessed by all hosts. The initiator access list can contain one or more initiators. The iSCSI initiator can be identified by one of the following mechanisms:

  • iSCSI node name
  • IPv4 address and subnet
  • IPv6 address
note.gif

Noteblank.gif For a transparent mode iSCSI initiator, if both Fibre Channel zoning and iSCSI ACLs are used, then for every static iSCSI target that is accessible to the iSCSI host, the initiator’s virtual N port should be in the same Fibre Channel zone as the Fibre Channel target.


To configure access control in iSCSI follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi virtual-target name iqn.1987-02.com.cisco.initiator

switch(config-iscsi-tgt)#

Creates the iSCSI target name iqn.1987-02.com.cisco.initiator.

Step 3

switch(config-iscsi-tgt)# pWWN 26:00:01:02:03:04:05:06 switch(config-iscsi-tgt)#

Maps a virtual target node to a Fibre Channel target.

Step 4

switch(config-iscsi-tgt)# initiator iqn.1987-02.com.cisco.initiator1 permit

Allows the specified iSCSI initiator node to access this virtual target. You can issue this command multiple times to allow multiple initiators.

switch(config-iscsi-tgt)# no initiator iqn.1987-02.com.cisco.initiator1 permit

(Optional) Prevents the specified initiator node from accessing virtual targets.

switch(config-iscsi-tgt)# no initiator ip address 10.50.1.1 permit

Prevents the specified IPv4 address from accessing virtual targets.

switch(config-iscsi-tgt)# initiator ip address 10.50.1.0 255.255.255.0 permit

Allows all initiators in this IPv4 subnetwork (10.50.1/24) to access this virtual target.

switch(config-iscsi-tgt)# no initiator ip address 10.50.1.0 255.255.255.0 permit

Prevents all initiators in this IPv4 subnetwork from accessing virtual targets.

switch(config-iscsi-tgt)# initiator ip address 2001:0DB8:800:200C::/64 permit

Allows all initiators in this IPv6 subnetwork (2001:0DB8:800:200C::/64) to access this virtual target.

switch(config-iscsi-tgt)# no initiator ip address 2001:0DB8:800:200C::/64 permit

Prevents all initiators in this IPv6 subnetwork from accessing virtual targets.

switch(config-iscsi-tgt)# all-initiator-permit

Allows all initiator nodes to access this virtual target.

switch(config-iscsi-tgt)# no all-initiator-permit

Prevents any initiator from accessing virtual targets (default).

To configure access control in iSCSI using Device Manager, follow these steps:


Step 1blank.gif Select IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12).

Step 2blank.gif Click the Targets tab.

You see the iSCSI virtual targets.

Step 3blank.gif Uncheck the Initiators Access All check box if checked.

Step 4blank.gif Click Edit Access.

You see the Initiators Access dialog box.

Step 5blank.gif Click Create to add more initiators to the Initiator Access list.

You see the Create Initiators Access dialog box.

Step 6blank.gif Add the name or IP address for the initiator that you want to permit for this virtual target.

Step 7blank.gif Click Create to add this initiator to the Initiator Access List.


 

Enforcing Access Control

Fibre Channel module with IPS ports and MPS-14/2 modules use both iSCSI and Fibre Channel zoning-based access control lists to enforce access control. Access control is enforced both during the iSCSI discovery phase and the iSCSI session creation phase. Access control enforcement is not required during the I/O phase because the Fibre Channel module with IPS ports or MPS-14/2 module is responsible for the routing of iSCSI traffic to Fibre Channel.

  • iSCSI discovery phase—When an iSCSI host creates an iSCSI discovery session and queries for all iSCSI targets, the Fibre Channel module with IPS ports or MPS-14/2 module returns only the list of iSCSI targets this iSCSI host is allowed to access based on the access control policies discussed in the previous section. The Fibre Channel module with IPS ports or MPS-14/2 module does this by querying the Fibre Channel name server for all the devices in the same zone as the initiator in all VSANs. It then filters out the devices that are initiators by looking at the FC4-feature field of the FCNS entry. (If a device does not register as either initiator or target in the FC4-feature field, the Fibre Channel module with IPS ports or MPS-14/2 module will advertise it). It then responds to the iSCSI host with the list of targets. Each will have either a static iSCSI target name that you configure or a dynamic iSCSI target name that the Fibre Channel module with IPS ports or MPS-14/2 module creates for it (see the “Dynamic Mapping” section).
  • iSCSI session creation—When an IP host initiates an iSCSI session, the Fibre Channel module with IPS ports or MPS-14/2 module verifies if the specified iSCSI target (in the session login request) is allowed by both the access control mechanisms described in the “iSCSI-Based Access Control” section.

If the iSCSI target is a static mapped target, the Fibre Channel module with IPS ports or MPS-14/2 module verifies if the iSCSI host is allowed within the access list of the iSCSI target. If the IP host does not have access, its login is rejected. If the iSCSI host is allowed, it validates if the virtual Fibre Channel N port used by the iSCSI host and the Fibre Channel target mapped to the static iSCSI virtual target are in the same Fibre Channel zone.

If the iSCSI target is an autogenerated iSCSI target, then the Fibre Channel module with IPS ports or MPS-14/2 module extracts the WWN of the Fibre Channel target from the iSCSI target name and verifies if the initiator and the Fibre Channel target is in the same Fibre Channel zone or not. If they are, then access is allowed.

The Fibre Channel module with IPS ports or MPS-14/2 module uses the Fibre Channel virtual N port of the iSCSI host and does a zone-enforced name server query for the Fibre Channel target WWN. If the FC ID is returned by the name server, then the iSCSI session is accepted. Otherwise, the login request is rejected.

iSCSI Session Authentication

The Fibre Channel module with IPS ports or MPS-14/2 module supports the iSCSI authentication mechanism to authenticate the iSCSI hosts that request access to the storage devices. By default, the Fibre Channel module with IPS ports or MPS-14/2 modules allow CHAP or None authentication of iSCSI initiators. If authentication is always used, you must configure the switch to allow only CHAP authentication.

For CHAP user name or secret validation, you can use any method supported and allowed by the Cisco MDS AAA infrastructure. AAA authentication supports a RADIUS, TACACS+, or local authentication device. See the Cisco Fabric Manager Security Configuration Guide.

The aaa authentication iscsi command enables AAA authentication for the iSCSI host and specifies the method to use. See Cisco MDS 9000 Family NX-OS Security Configuration Guide

To configure AAA authentication for an iSCSI user, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# aaa authentication iscsi default group RadServerGrp

Uses RADIUS servers that are added in the group called RadServerGrp for the iSCSI CHAP authentication.

switch(config)# aaa authentication iscsi default group TacServerGrp

Uses TACACS+ servers that are added in the group called TacServerGrp for the iSCSI CHAP authentication.

switch(config)# aaa authentication iscsi default local

Uses the local password database for iSCSI CHAP authentication.

To configure AAA authentication for an iSCSI user using Fabric Manager, follow these steps:


Step 1blank.gif Choose Switches > Security > AAA in the Physical Attributes pane.

You see the AAA configuration in the Information pane.

Step 2blank.gif Click the Applications tab.

You see the AAA configuration per application (see Figure 4-28).

Figure 4-28 AAA per Application Configuration

 

183990.tif

Step 3blank.gif Right-click the ServerGroup Id List field for the iSCSI application and enter the server group that you want iSCSI to use.

note.gif

Noteblank.gif You should use an existing server group or create a new server group before configuring it for iSCSI session authentication.


Step 4blank.gif Click the Apply Changes icon to save these changes.


 

The following topics are included in this section:

Configuring Authentication Mechanism

You can configure iSCSI CHAP or None authentication at both the global level and at each interface level.

The authentication for a Gigabit Ethernet interface or subinterface overrides the authentication method configured at the global level.

If CHAP authentication is used, issue the iscsi authentication chap command at either the global level or at a per-interface level. If authentication should not be used at all, issue the iscsi authentication none command.

To configure the authentication mechanism for iSCSI, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi authentication chap

Configures CHAP as the default authentication mechanism globally for the Cisco MDS switch. CHAP authentication is required for all iSCSI sessions.

To configure AAA authentication for an iSCSI user using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Step 2blank.gif Click the Globals tab.

You see the iSCSI authentication configuration table.

Step 3blank.gif Select chap or none from the authMethod column.

Step 4blank.gif Click the Apply Changes icon in Fabric Manager to save these changes.


 

To configure the authentication mechanism for iSCSI sessions to a particular interface, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# interface GigabitEthernet 2/1.100

switch(config-if)#

Selects the Gigabit Ethernet interface.

Step 3

switch(config-if)# iscsi authentication none

Specifies that no authentication is required for iSCSI sessions to the selected interface.

To configure the authentication mechanism for iSCSI sessions to a particular interface using Fabric Manager, follow these steps:


Step 1blank.gif Choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

You see the Gigabit Ethernet configuration in the Information pane.

Step 2blank.gif Click the iSNS tab.

You see the iSCSI and iSNS configuration (see Figure 4-29).

Figure 4-29 Configuring iSCSI Authentication on an Interface

 

184002.tif

Step 3blank.gif Right-click on the IscsiAuthMethod field and select none or chap.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

Configuring Local Authentication

See the Cisco Fabric Manager Security Configuration Guide and Cisco MDS 9000 Family NX-OS Security Guide to create the local password database. To create users in the local password database for the iSCSI initiator, the iSCSI keyword is mandatory.

To configure iSCSI users for local authentication, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# username iscsiuser password ffsffsfsffs345353554535 iscsi

Configures a user name (iscsiuser) and password (ffsffsfsffs345353554535) in the local database for iSCSI login authentication.

To configure iSCSI users for local authentication using Device Manager, follow these steps:


Step 1blank.gif Choose Security > iSCSI.

You see the iSCSI Security dialog box (see Figure 4-30).

Figure 4-30 iSCSI Security Dialog Box

 

184004.tif

Step 2blank.gif Complete the iSCSI User, Password, and Password Confirmation fields.

Step 3blank.gif Click Create to save this new user.


 

Restricting iSCSI Initiator Authentication

By default, the iSCSI initiator can use any user name in the RADIUS server or in the local database in authenticating itself to the Fibre Channel module with IPS ports or MPS-14/2 module (the CHAP user name is independent of the iSCSI initiator name). The Fibre Channel module with IPS ports or MPS-14/2 module allows the initiator to log in as long as it provides a correct response to the CHAP challenge sent by the switch. This can be a problem if one CHAP user name and password has been compromised.

To restrict an initiator to use a specific user name for CHAP authentication, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi initiator name iqn.1987-02.com.cisco.init

switch(config-iscsi-init)#

Enters the configuration submode for the initiator iqn.1987-02.com.cisco.init.

Step 3

switch(config-iscsi-init)#

username user1

Restricts the initiator iqn.1987-02.com.cisco.init to only authenticate using user1 as its CHAP user name.

Note Be sure to define user1 as an iSCSI user in the local AAA database or the RADIUS server.

To restrict an initiator to use a specific user name for CHAP authentication using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Step 2blank.gif Right-click the AuthUser field and enter the user name to which you want to restrict the iSCSI initiator.

Step 3blank.gif Click the Apply Changes icon to save these changes.


 

Configuring Mutual CHAP Authentication

The Fibre Channel module with IPS ports or MPS-14/2 module supports a mechanism by which the iSCSI initiator can authenticate the Cisco MDS switch’s iSCSI target during the iSCSI login phase. This authentication is available in addition to the Fibre Channel module with IPS ports or MPS-14/2 module authentication of the iSCSI initiator.

In addition to the Fibre Channel module with IPS ports or MPS-14/2 module authentication of the iSCSI initiator, the Fibre Channel module with IPS ports or MPS-14/2 module also supports a mechanism for the iSCSI initiator to authenticate the Cisco MDS switch’s iSCSI target during the iSCSI login phase. This authentication requires the user to configure a user name and password for the switch to present to the iSCSI initiator. The provided password is used to calculate a CHAP response to a CHAP challenge sent to the IPS port by the initiator.

To configure a global iSCSI target user name and password to be used by the switch to authenticate itself to an initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi authentication username testuser password abc123

Configures the switch user account (testuser) along with a password (abc123) specified in clear text (default) for all initiators. The password is limited to 128 characters.

switch(config)# iscsi authentication username user1 password 7!@*asdsfsdfjh!@df

Configures the switch user account (user1) along with the encrypted password specified by 7 (!@*asdsfsdfjh!@df) for all initiators.

switch(config)# iscsi authentication username user1 password 0 abcd12AAA

Configures the switch user account (user1) along with a password (abcd12AAA) specified in clear text (indicated by 0—default) for all initiators. The password is limited to 128 characters.

switch(config)# no iscsi authentication username testuser

Removes the global configuration for all initiators.

To configure a global iSCSI target user name and password to be used by the switch to authenticate itself to an initiator using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI tables in the Information pane (see Figure 4-5).

Step 2blank.gif Select the Globals tab.

You see the global iSCSI configuration.

Step 3blank.gif Fill in the Target UserName and Target Password fields.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

To configure a per-initiator iSCSI target’s user name and password used by the switch to authenticate itself to an initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi initiator name iqn.1987-02.com.cisco.initiator

switch(config-iscsi-init)#

Configures an iSCSI initiator using the iSCSI name of the initiator node.

Step 3

switch(config-iscsi-init)# mutual-chap username testuser password abcd12AAA

Configures the switch user account (testuser) along with a password (abcd12AAA) specified in clear text (default). The password is limited to 128 characters.

switch(config-iscsi-init)# mutual-chap username user1 password 7!@*asdsfsdfjh!@df

Configures the switch user account (user1) along with the encrypted password specified by 7 (!@*asdsfsdfjh!@df).

switch(config-iscsi-init)# no mutual-chap username testuser

Removes the switch authentication configuration.

Use the show running-config and the show iscsi global commands to display the global configuration. Use the show running-config and the show iscsi initiator configured commands to display the initiator specific configuration.(See the “Displaying iSCSI Information” section for command output examples).

To configure a per-initiator iSCSI target’s user name and password used by the switch to authenticate itself to an initiator using Device Manager, follow these steps:


Step 1blank.gif Choose IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12).

Step 2blank.gif Complete the Target UserName and Target Password fields for the initiator that you want to configure.

Step 3blank.gif Click Create to add this initiator to the Initiator Access List.


 

Configuring an iSCSI RADIUS Server

To configure an iSCSI RADIUS server, follow these steps:


Step 1blank.gif Configure the RADIUS server to allow access from the Cisco MDS switch's management Ethernet IP address.

Step 2blank.gif Configure the shared secret for the RADIUS server to authenticate the Cisco MDS switch.

Step 3blank.gif Configure the iSCSI users and passwords on the RADIUS server.


 

iSCSI Immediate Data and Unsolicited Data Features

Cisco MDS switches support the iSCSI immediate data and unsolicited data features if requested by the initiator during the login negotiation phase. Immediate data is iSCSI write data contained in the data segment of an iSCSI command protocol data unit (PDU), such as combining the write command and write data together in one PDU. Unsolicited data is iSCSI write data that an initiator sends to the iSCSI target, such as an MDS switch, in an iSCSI data-out PDU without having to receive an explicit ready to transfer (R2T) PDU from the target.

These two features help reduce I/O time for small write commands because it removes one round-trip between the initiator and the target for the R2T PDU. As an iSCSI target, the MDS switch allows up to 64 KB of unsolicited data per command. This is controlled by the FirstBurstLength parameter during iSCSI login negotiation phase.

If an iSCSI initiator supports immediate data and unsolicited data features, these features are automatically enabled on the MDS switch with no configuration required.

iSCSI Interface Advanced Features

Advanced configuration options are available for iSCSI interfaces on a per-IPS port basis. These configurations are similar to the advanced FCIP configurations and are already explained in that section (see Advanced FCIP Profile Configuration for more information).

To access these commands from the iSCSI interface, follow these steps:

Command
Purpose

Step 1

switch# config terminal
switch(config)#

Enters configuration mode.

Step 2

switch(config)# interface iscsi 4/1
switch(config-if)#

Selects the iSCSI interface on the switch.

Cisco MDS switches support the following advanced features for iSCSI interfaces:

iSCSI Listener Port

You can configure the TCP port number for the iSCSI interface that listens for new TCP connections. The default port number is 3260. Once you change the TCP port number, the iSCSI port only accepts TCP connections on the newly configured port.

TCP Tuning Parameters

You can configure the following TCP parameters:

Setting QoS Values

To set the QoS values, follow these steps:

Command
Purpose

Step 1

switch(config-if)# qos 3

Configures the differentiated services code point (DSCP) value of 3 to be applied to all outgoing IP packets in this iSCSI interface. The valid range for the iSCSI DSCP value is from 0 to 63.

Step 2

switch(config-if)# no qos 5

Reverts the switch to its factory default (marks all packets with DSCP value 0).

To set the QoS values using Fabric Manager, follow these steps:


Step 1blank.gif Expand Switches, expand Interfaces and then select FC Logical in the Physical Attributes pane.

You see the Interface tables in the Information pane (see Figure 4-22).

Step 2blank.gif In Device Manager, choose Interface > Ethernet and iSCSI.

You see the Ethernet Interfaces and iSCSI dialog box (see Figure 4-23).

Step 3blank.gif Click the iSCSI TCP tab in either Fabric Manager or Device Manager.

You see the iSCSI TCP configuration table.

Step 4blank.gif Set the QoS field from 1 to 6.

Step 5blank.gif Click the Apply Changes icon in Fabric Manager or click Apply in Device Manager to save these changes.


 

iSCSI Routing Modes

Cisco MDS 9000 Family switches support multiple iSCSI routing modes. Each mode negotiates different operational parameters, has different advantages and disadvantages, and is suitable for different usages.

  • Pass-thru mode

In pass-thru mode, the port on the Fibre Channel module with IPS ports or MPS 14/2 module converts and forwards read data frames from the Fibre Channel target to the iSCSI host frame-by-frame without buffering. This means that one data-in frame received is immediately sent out as one iSCSI data-in PDU.

In the opposite direction, the port on the Fibre Channel module with IPS ports or MPS 14/2 module limits the maximum size of iSCSI write data-out PDU that the iSCSI host can send to the maximum data size that the Fibre Channel target specifies that it can receive. The result is one iSCSI data-out PDU received sent out as one Fibre Channel data frame to the Fibre Channel target.

The absence of buffering in both directions leads to an advantage of lower forwarding latency. However, a small maximum data segment length usually results in lower data transfer performance from the host because of a higher processing overhead by the host system. Another benefit of this mode is iSCSI data digest can be enabled. This helps protect the integrity of iSCSI data carried in the PDU over what TCP checksum offers.

  • Store-and-forward mode (default)

In store-and-forward mode, the port on the Fibre Channel module with IPS ports or MPS 14/2 module assembles all the Fibre Channel data frames of an exchange to build one large iSCSI data-in PDU before forwarding it to the iSCSI client.

In the opposite direction, the port on the Fibre Channel module with IPS ports or MPS 14/2 module does not impose a small data segment size on the host so the iSCSI host can send an iSCSI data-out PDU of any size (up to 256 KB). The port then waits until the whole iSCSI data-out PDU is received before it converts, or splits, the PDU, and forwards Fibre Channel frames to the Fibre Channel target.

The advantage of this mode is higher data transfer performance from the host. The disadvantages are higher transfer latency and that the iSCSI data digest (CRC) cannot be used.

note.gif

Noteblank.gif The store-and-forward mode is the default forwarding mode.


  • Cut-through mode

Cut-through mode improves the read operation performance over store-and-forward mode. The port on the Fibre Channel module with IPS ports or MPS 14/2 module achieves this by forwarding each Fibre Channel data-in frame to the iSCSI host as it is received without waiting for the whole exchange complete. There is no difference for write data-out operations from store-and-forward mode.

Figure 4-31 compares the messages exchanged by the iSCSI routing modes.

Figure 4-31 iSCSI Routing Modes

 

130687.ps

Table 4-1 compares the advantages and disadvantages of the different iSCSI routing modes.

 

Table 4-1 Comparison of iSCSI Routing Modes

Mode
Advantages
Disadvantages

Pass-thru

Low-latency

Data digest can be used

Lower data transfer performance.

Store-and-forward

Higher data transfer performance

Data digest cannot be used.

Cut-thru

Improved read performance over store-and-forward

If the Fibre Channel target sent read data for different commands interchangeably, data of the first command is forwarded in cut-thru mode but the data of subsequent commands is buffered and the behavior is the same as store-and-forward mode.

Data digest cannot be used.

caut.gif

Caution blank.gif Changing the forwarding mode of an iSCSI interface that is part of an iSLB VRRP group impacts load balancing on the interface. See the “Changing iSCSI Interface Parameters and the Impact on Load Balancing” section.

Displaying iSCSI Information

Use the show iscsi command to obtain detailed information about iSCSI configurations.

This section includes the following topics:

Displaying iSCSI Interfaces

Use the show iscsi interface command to view the summary, counter, description, and status of the iSCSI interface. Use the output to verify the administrative mode, the interface status, TCP parameters currently used, and brief statistics.

Example 4-1 Displaying the iSCSI Interface Information

switch# show interface iscsi 4/1
iscsi4/1 is up
Hardware is GigabitEthernet
Port WWN is 20:cf:00:0c:85:90:3e:80
Admin port mode is ISCSI
Port mode is ISCSI
Speed is 1 Gbps
iSCSI initiator is identified by name
Number of iSCSI session: 0 (discovery session: 0)
Number of TCP connection: 0
Configured TCP parameters
Local Port is 3260
PMTU discover is enabled, reset timeout is 3600 sec
Keepalive-timeout is 60 sec
Minimum-retransmit-time is 300 ms
Max-retransmissions 4
Sack is enabled
QOS code point is 0
Maximum allowed bandwidth is 1000000 kbps
Minimum available bandwidth is 70000 kbps
Estimated round trip time is 1000 usec
Send buffer size is 4096 KB
Congestion window monitoring is enabled, burst size is 50 KB
Configured maximum jitter is 500 us
Forwarding mode: store-and-forward
TMF Queueing Mode : disabled
Proxy Initiator Mode : disabled
5 minutes input rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
5 minutes output rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
iSCSI statistics
Input 0 packets, 0 bytes
Command 0 pdus, Data-out 0 pdus, 0 bytes
Output 0 packets, 0 bytes
Response 0 pdus (with sense 0), R2T 0 pdus
Data-in 0 pdus, 0 bytes
 

Displaying iSCSI Statistics

Use the show iscsi stats command to view brief or detailed iSCSI statistics per iSCSI interface. See Example 4-2 and Example 4-3.

Example 4-2 displays iSCSI throughput on an IPS port in both inbound and outbound directions. It also displays the number of different types of iSCSI PDU received and transmitted by this IPS port.

Example 4-2 Displaying Brief iSCSI Statistics for an iSCSI Interface

switch# show iscsi stats iscsi 2/1
iscsi2/1
5 minutes input rate 704 bits/sec, 88 bytes/sec, 1 frames/sec
5 minutes output rate 704 bits/sec, 88 bytes/sec, 1 frames/sec
iSCSI statistics
974756 packets input, 142671620 bytes
Command 2352 pdus, Data-out 44198 pdus, 92364800 bytes, 0 fragments, unsolicited 0 bytes
output 1022920 packets, 143446248 bytes
Response 2352 pdus (with sense 266), R2T 1804 pdus
Data-in 90453 pdus, 92458248 bytes
 

Example 4-3displays detailed iSCSI statistics for an IPS port. Along with the traffic rate and the number of each iSCSI PDU type, it shows the number of FCP frames received and forwarded, the number of iSCSI login attempts, successes, and failures. It also shows the number of different types of iSCSI PDUs sent and received that are noncritical or occur less frequently, such as NOP in and out (NOP-In and NOP-Out), text request and response (Text-REQ and Text-RESP), and task management request and response (TMF-REQ and TMF-RESP).

Various types of errors and PDU or frame drop occurrences are also counted and displayed. For example, Bad header digest shows the number of iSCSI PDUs received that have a header digest that fails CRC verification. The iSCSI Drop section shows the number of PDUs that were dropped because of reasons such as target down, LUN mapping fail, Data CRC error, or unexpected Immediate or Unsolicited data. These statistics are helpful for debugging purposes when the feature is not working as expected.

The last section, Buffer Stats, gives statistics on the internal IPS packet buffer operation. This section is for debugging purposes only.

Example 4-3 Displaying Detailed iSCSI Statistics for the iSCSI Interface

switch# show iscsi stats iscsi 2/1 detail
iscsi2/1
5 minutes input rate 704 bits/sec, 88 bytes/sec, 1 frames/sec
5 minutes output rate 704 bits/sec, 88 bytes/sec, 1 frames/sec
iSCSI statistics
974454 packets input, 142656516 bytes
Command 2352 pdus, Data-out 44198 pdus, 92364800 bytes, 0 fragments, unsolicited 0 bytes
output 1022618 packets, 143431144 bytes
Response 2352 pdus (with sense 266), R2T 1804 pdus
Data-in 90453 pdus, 92458248 bytes
iSCSI Forward:
Command:2352 PDUs (Rcvd:2352)
Data-Out (Write):16236 PDUs (Rcvd 44198), 0 fragments, 92364800 bytes, unsolicited 0 bytes
FCP Forward:
Xfer_rdy:1804 (Rcvd:1804)
Data-In:90453 (Rcvd:90463), 92458248 bytes
Response:2352 (Rcvd:2362), with sense 266
TMF Resp:0
 
iSCSI Stats:
Login:attempt:13039, succeed:110, fail:12918, authen fail:0
Rcvd:NOP-Out:914582, Sent:NOP-In:914582
NOP-In:0, Sent:NOP-Out:0
TMF-REQ:0, Sent:TMF-RESP:0
Text-REQ:18, Sent:Text-RESP:27
SNACK:0
Unrecognized Opcode:0, Bad header digest:0
Command in window but not next:0, exceed wait queue limit:0
Received PDU in wrong phase:0
SCSI Busy responses:0
Immediate data failure::Separation:0
Unsolicited data failure::Separation:0, Segment:0
Add header:0
Sequence ID allocation failure:0
FCP Stats:
Total:Sent:47654
Received:96625 (Error:0, Unknown:0)
Sent:PLOGI:10, Rcvd:PLOGI_ACC:10, PLOGI_RJT:0
PRLI:10, Rcvd:PRLI_ACC:10, PRLI_RJT:0, Error:0, From initiator:0
LOGO:4, Rcvd:LOGO_ACC:0, LOGO_RJT:0
PRLO:4, Rcvd:PRLO_ACC:0, PRLO_RJT:0
ABTS:0, Rcvd:ABTS_ACC:0
TMF REQ:0
Self orig command:10, Rcvd:data:10, resp:10
Rcvd:PLOGI:156, Sent:PLOGI_ACC:0, PLOGI_RJT:156
LOGO:0, Sent:LOGO_ACC:0, LOGO_RJT:0
PRLI:8, Sent:PRLI_ACC:8, PRLI_RJT:0
PRLO:0, Sent:PRLO_ACC:0, PRLO_RJT:0
ADISC:0, Sent:ADISC_ACC:0, ADISC_RJT:0
ABTS:0
 
iSCSI Drop:
Command:Target down 0, Task in progress 0, LUN map fail 0
CmdSeqNo not in window 0, No Exchange ID 0, Reject 0
No task:0
Data-Out:0, Data CRC Error:0
TMF-Req:0, No task:0
Unsolicited data:0, Immediate command PDU:0
FCP Drop:
Xfer_rdy:0, Data-In:0, Response:0
 
Buffer Stats:
Buffer less than header size:0, Partial:45231, Split:322
Pullup give new buf:0, Out of contiguous buf:0, Unaligned m_data:0
 

Displaying Proxy Initiator Information

If the proxy initiator feature is enabled in the iSCSI interface, use the show interface iscsi command to display configured proxy initiator information (see Example 4-4 and Example 4-5).

Example 4-4 Displaying Proxy Initiator Information for the iSCSI Interface with System-Assigned WWNs

switch# show interface iscsi 4/1
iscsi4/1 is up
Hardware is GigabitEthernet
Port WWN is 20:c1:00:05:30:00:a7:9e
Admin port mode is ISCSI
Port mode is ISCSI
Speed is 1 Gbps
iSCSI initiator is identified by name
Number of iSCSI session: 0, Number of TCP connection: 0
Configured TCP parameters
Local Port is 3260
PMTU discover is enabled, reset timeout is 3600 sec
Keepalive-timeout is 60 sec
Minimum-retransmit-time is 300 ms
Max-retransmissions 4
Sack is disabled
QOS code point is 0
Forwarding mode: pass-thru
TMF Queueing Mode : disabled
Proxy Initiator Mode : enabled<----------------------------Proxy initiator is enabled
nWWN is 28:00:00:05:30:00:a7:a1 (system-assigned)<----System-assigned nWWN
pWWN is 28:01:00:05:30:00:a7:a1 (system-assigned)<---- System-assigned pWWN
5 minutes input rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
5 minutes output rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
iSCSI statistics
Input 7 packets, 2912 bytes
Command 0 pdus, Data-out 0 pdus, 0 bytes
Output 7 packets, 336 bytes
Response 0 pdus (with sense 0), R2T 0 pdus
Data-in 0 pdus, 0 bytes
 

Example 4-5 Displaying Proxy Initiator Information for the iSCSI Interface with User-Assigned WWNs

switch# show interface iscsi 4/2
iscsi4/2 is up
Hardware is GigabitEthernet
Port WWN is 20:c1:00:05:30:00:a7:9e
Admin port mode is ISCSI
Port mode is ISCSI
Speed is 1 Gbps
iSCSI initiator is identified by name
Number of iSCSI session: 0, Number of TCP connection: 0
Configured TCP parameters
Local Port is 3260
PMTU discover is enabled, reset timeout is 3600 sec
Keepalive-timeout is 60 sec
Minimum-retransmit-time is 300 ms
Max-retransmissions 4
Sack is disabled
QOS code point is 0
Forwarding mode: pass-thru
TMF Queueing Mode : disabled
Proxy Initiator Mode : enabled
nWWN is 11:11:11:11:11:11:11:11 (manually-configured)<----User-assigned nWWN
pWWN is 22:22:22:22:22:22:22:22 (manually-configured)<----User-assigned pWWN
5 minutes input rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
5 minutes output rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
iSCSI statistics
Input 7 packets, 2912 bytes
Command 0 pdus, Data-out 0 pdus, 0 bytes
Output 7 packets, 336 bytes
Response 0 pdus (with sense 0), R2T 0 pdus
Data-in 0 pdus, 0 bytes
 

Displaying Global iSCSI Information

Use the show iscsi global command to view the overall configuration and the iSCSI status. See Example 4-6.

Example 4-6 Displaying the Current Global iSCSI Configuration and State

switch# show iscsi global
iSCSI Global information
Authentication: CHAP, NONE
Import FC Target: Enabled
Initiator idle timeout: 300 seconds
Number of target node: 0
Number of portals: 11
Number of session: 0
Failed session: 0, Last failed initiator name:
 

Displaying iSCSI Sessions

Use the show iscsi session command to view details about the current iSCSI sessions in the switch. Without parameters, this command displays all sessions. The output can be filtered by specifying an initiator, a target, or both.

Example 4-7 displays one iSCSI initiator configured based on the IQN (iqn.1987-05.com.cisco:02.3021b0f2fda0.avanti12-w2k) and another based on its IPv4 address (10.10.100.199).

Example 4-7 Displaying Brief Information of All iSCSI Sessions

switch# show iscsi session
Initiator iqn.1987-05.com.cisco:02.3021b0f2fda0.avanti12-w2k
Initiator ip addr (s): 10.10.100.116
Session #1
Discovery session, ISID 00023d000043, Status active
 
Session #2
Target VT1
VSAN 1, ISID 00023d000046, Status active, no reservation
 
Session #3
Target VT2
VSAN 1, ISID 00023d000048, Status active, no reservation
 
Initiator 10.10.100.199
Initiator name iqn.1987-05.com.cisco.01.7e3183ae458a94b1cd6bc168cba09d2e
Session #1
Target VT2
VSAN 1, ISID 246700000000, Status active, no reservation
 
Session #2
Target VT1
VSAN 1, ISID 246b00000000, Status active, no reservation
 
Session #3
Target iqn.1987-05.com.cisco:05.switch.04-01.2100002037a6be32
VSAN 1, ISID 246e00000000, Status active, no reservation
 

Example 4-8 and Example 4-9 display the iSCSI initiator configured based on its IPv4 address (10.10.100.199).

Example 4-8 Displaying Brief Information About the Specified iSCSI Session

switch# show iscsi session initiator 10.10.100.199 target VT1
Initiator 10.10.100.199
Initiator name iqn.1987-05.com.cisco.01.7e3183ae458a94b1cd6bc168cba09d2e
Session #1
Target VT1
VSAN 1, ISID 246b00000000, Status active, no reservation
 

Example 4-9 Displaying Detailed Information About the Specified iSCSI Session

switch# show iscsi session initiator 10.10.100.199 target VT1 detail
Initiator 10.10.100.199 (oasis-qa)
Initiator name iqn.1987-05.com.cisco.01.7e3183ae458a94b1cd6bc168cba09d2e
Session #1 (index 3)
Target VT1
VSAN 1, ISID 246b00000000, TSIH 384, Status active, no reservation
Type Normal, ExpCmdSN 39, MaxCmdSN 54, Barrier 0
MaxBurstSize 0, MaxConn 0, DataPDUInOrder No
DataSeqInOrder No, InitialR2T Yes, ImmediateData No
Registered LUN 0, Mapped LUN 0
Stats:
PDU: Command: 38, Response: 38
Bytes: TX: 8712, RX: 0
Number of connection: 1
Connection #1
Local IP address: 10.10.100.200, Peer IP address: 10.10.100.199
CID 0, State: LOGGED_IN
StatSN 62, ExpStatSN 0
MaxRecvDSLength 1024, our_MaxRecvDSLength 1392
CSG 3, NSG 3, min_pdu_size 48 (w/ data 48)
AuthMethod none, HeaderDigest None (len 0), DataDigest None (len 0)
Version Min: 2, Max: 2
FC target: Up, Reorder PDU: No, Marker send: No (int 0)
Received MaxRecvDSLen key: No
 

Displaying iSCSI Initiators

Use the show iscsi initiator command to display information about all initiators connected to an iSCSI interface in the switch. The information can be filtered to display only the desired iSCSI initiator by specifying the initiator name. Detailed output of the iSCSI initiator can be obtained by specifying the detail option. The iscsi-session (and optionally detail) parameter displays only iSCSI session information. The fcp-session (and optionally detail) parameter displays only FCP session information. The output includes static and dynamic initiators. See Example 4-10 and Example 4-11.

Example 4-10 Displaying Information About Connected iSCSI Initiators

switch# show iscsi initiator
iSCSI Node name is iqn.1987-05.com.cisco:02.3021b0f2fda0.avanti12-w2k
Initiator ip addr (s): 10.10.100.116
iSCSI alias name: AVANTI12-W2K
Node WWN is 22:01:00:05:30:00:10:e1 (configured)
Member of vsans: 1, 2, 10
Number of Virtual n_ports: 1
Virtual Port WWN is 22:04:00:05:30:00:10:e1 (configured)
Interface iSCSI 4/1, Portal group tag: 0x180
VSAN ID 1, FCID 0x6c0202
VSAN ID 2, FCID 0x6e0000
VSAN ID 10, FCID 0x790000
 
iSCSI Node name is 10.10.100.199
iSCSI Initiator name: iqn.1987-05.com.cisco.01.7e3183ae458a94b1cd6bc168cba09d2e
iSCSI alias name: oasis-qa
Node WWN is 22:03:00:05:30:00:10:e1 (configured)
Member of vsans: 1, 5
Number of Virtual n_ports: 1
Virtual Port WWN is 22:00:00:05:30:00:10:e1 (configured)
Interface iSCSI 4/1, Portal group tag: 0x180
VSAN ID 5, FCID 0x640000
VSAN ID 1, FCID 0x6c0203
 

Example 4-11 Displaying Detailed Information About the iSCSI Initiator

switch# show iscsi initiator iqn.1987-05.com.cisco:02.3021b0f2fda0.avanti12-w2k detail
iSCSI Node name is iqn.1987-05.com.cisco:02.3021b0f2fda0.avanti12-w2k
Initiator ip addr (s): 10.10.100.116
iSCSI alias name: AVANTI12-W2K
Node WWN is 22:01:00:05:30:00:10:e1 (configured)
Member of vsans: 1, 2, 10
Number of Virtual n_ports: 1
 
Virtual Port WWN is 22:04:00:05:30:00:10:e1 (configured)
Interface iSCSI 4/1, Portal group tag is 0x180
VSAN ID 1, FCID 0x6c0202
1 FC sessions, 1 iSCSI sessions
iSCSI session details <-------------------iSCSI session details
Target: VT1
Statistics:
PDU: Command: 0, Response: 0
Bytes: TX: 0, RX: 0
Number of connection: 1
TCP parameters
Local 10.10.100.200:3260, Remote 10.10.100.116:4190
Path MTU: 1500 bytes
Retransmission timeout: 310 ms
Round trip time: Smoothed 160 ms, Variance: 38
Advertized window: Current: 61 KB, Maximum: 62 KB, Scale: 0
Peer receive window: Current: 63 KB, Maximum: 63 KB, Scale: 0
Congestion window: Current: 1 KB
 
FCP Session details <-------------------FCP session details
Target FCID: 0x6c01e8 (S_ID of this session: 0x6c0202)
pWWN: 21:00:00:20:37:62:c0:0c, nWWN: 20:00:00:20:37:62:c0:0c
Session state: CLEANUP
1 iSCSI sessions share this FC session
Target: VT1
Negotiated parameters
RcvDataFieldSize 1392 our_RcvDataFieldSize 1392
MaxBurstSize 0, EMPD: FALSE
Random Relative Offset: FALSE, Sequence-in-order: Yes
Statistics:
PDU: Command: 0, Response: 0
 

Use the show fcns database (and optionally detail) to display the Fibre Channel name server entry for the Fibre Channel N port created for iSCSI initiators in the SAN. See Example 4-12 and Example 4-13.

Example 4-12 Displaying the FCNS Database Contents

switch# show fcns database
VSAN 1:
--------------------------------------------------------------------------
FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE
--------------------------------------------------------------------------
0x020101 N 22:04:00:05:30:00:35:e1 (Cisco) scsi-fcp:init isc..w <--iSCSI
0x020102 N 22:02:00:05:30:00:35:e1 (Cisco) scsi-fcp:init isc..w initiator
0x0205d4 NL 21:00:00:04:cf:da:fe:c6 (Seagate) scsi-fcp:target
0x0205d5 NL 21:00:00:04:cf:e6:e4:4b (Seagate) scsi-fcp:target
...
Total number of entries = 10
 
VSAN 2:
--------------------------------------------------------------------------
FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE
--------------------------------------------------------------------------
0xef0001 N 22:02:00:05:30:00:35:e1 (Cisco) scsi-fcp:init isc..w
Total number of entries = 1
 
VSAN 3:
--------------------------------------------------------------------------
FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE
--------------------------------------------------------------------------
0xed0001 N 22:02:00:05:30:00:35:e1 (Cisco) scsi-fcp:init isc..w
Total number of entries = 1
 

Example 4-13 Displaying the FCNS Database in Detail

switch# show fcns database detail
------------------------
VSAN:1 FCID:0x020101
------------------------
port-wwn (vendor) :22:04:00:05:30:00:35:e1 (Cisco)
node-wwn :22:03:00:05:30:00:35:e1
class :2,3
node-ip-addr :10.2.2.12 <--- iSCSI initiator's IPv4 address
ipa :ff ff ff ff ff ff ff ff
fc4-types:fc4_features:scsi-fcp:init iscsi-gw
symbolic-port-name :
symbolic-node-name :iqn.1991-05.com.microsoft:oasis2-dell <--- iSCSI initiator's IQN
port-type :N
port-ip-addr :0.0.0.0
fabric-port-wwn :22:01:00:05:30:00:35:de
hard-addr :0x000000
------------------------
VSAN:1 FCID:0x020102
------------------------
port-wwn (vendor) :22:02:00:05:30:00:35:e1 (Cisco)
node-wwn :22:01:00:05:30:00:35:e1
class :2,3
node-ip-addr :10.2.2.11
ipa :ff ff ff ff ff ff ff ff
fc4-types:fc4_features:scsi-fcp:init iscsi-gw
symbolic-port-name :
symbolic-node-name :iqn.1987-05.com.cisco.01.14ac33ba567f986f174723b5f9f2377
port-type :N
port-ip-addr :0.0.0.0
fabric-port-wwn :22:01:00:05:30:00:35:de
hard-addr :0x000000
...
Total number of entries = 10
======================================================================
------------------------
VSAN:2 FCID:0xef0001
------------------------
port-wwn (vendor) :22:02:00:05:30:00:35:e1 (Cisco)
node-wwn :22:01:00:05:30:00:35:e1
class :2,3
node-ip-addr :10.2.2.11
ipa :ff ff ff ff ff ff ff ff
fc4-types:fc4_features:scsi-fcp:init iscsi-gw
symbolic-port-name :
symbolic-node-name :iqn.1987-05.com.cisco.01.14ac33ba567f986f174723b5f9f2377
port-type :N
port-ip-addr :0.0.0.0
fabric-port-wwn :22:01:00:05:30:00:35:de
hard-addr :0x000000
Total number of entries = 1
...
 

Use the show iscsi initiator configured to display information about all the configured iSCSI initiators. Specifying the name shows information about the desired initiator. See Example 4-14.

Example 4-14 Displaying Information About Configured Initiators

switch# show iscsi initiator configured
iSCSI Node name is iqn.1987-05.com.cisco:02.3021b0f2fda0.avanti12-w2k
Member of vsans: 1, 2, 10
Node WWN is 22:01:00:05:30:00:10:e1
No. of PWWN: 5
Port WWN is 22:04:00:05:30:00:10:e1
Port WWN is 22:05:00:05:30:00:10:e1
Port WWN is 22:06:00:05:30:00:10:e1
Port WWN is 22:07:00:05:30:00:10:e1
Port WWN is 22:08:00:05:30:00:10:e1
 
iSCSI Node name is 10.10.100.199
Member of vsans: 1, 5
Node WWN is 22:03:00:05:30:00:10:e1
No. of PWWN: 4
Port WWN is 22:00:00:05:30:00:10:e1
Port WWN is 22:09:00:05:30:00:10:e1
Port WWN is 22:0a:00:05:30:00:10:e1
Port WWN is 22:0b:00:05:30:00:10:e1
 
User Name for Mutual CHAP: testuser

Displaying iSCSI Virtual Targets

Use the show iscsi virtual-target to display information about the Fibre Channel targets exported as iSCSI virtual targets to the iSCSI initiators. The output includes static as well as dynamic targets. See Example 4-15.

Example 4-15 Displaying Exported Targets

switch# show iscsi virtual-target
target: VT1
* Port WWN 21:00:00:20:37:62:c0:0c
Configured node
all initiator permit is enabled
 
target: VT2
Port WWN 21:00:00:04:cf:4c:52:c1
Configured node
all initiator permit is disabled
target: iqn.1987-05.com.cisco:05.switch.04-01.2100002037a6be32
Port WWN 21:00:00:20:37:a6:be:32, VSAN 1
Auto-created node
 

Displaying iSCSI User Information

The show user-account iscsi command displays all configured iSCSI user names. See Example 4-16.

Example 4-16 Displaying iSCSI User Names

switch# show user-account iscsi
username:iscsiuser
secret: dsfffsffsffasffsdffg
 
username:user2
secret:cshadhdhsadadjajdjas
 

Configuring iSLB

The iSCSI server load balancing (iSLB) feature provides a means to easily configure large scale iSCSI deployments containing hundreds or even thousands of initiators. iSLB provides the following features:

  • The iSLB initiator configuration is simplified with support for initiator targets and auto-zones.
  • Cisco Fabric Services (CFS) eliminates the need for manual configuration by distributing the iSLB initiator configuration among all MDS switches in the fabric.
  • Dynamic load balancing of iSLB initiators is available using iSCSI login redirect and VRRP.

When not using iSLB, configuring iSCSI requires the following:

  • You need to perform multiple configuration steps on the MDS switch, including the following:

blank.gif Initiator configuration using static pWWN and VSAN.

blank.gif Zoning configuration for initiators and targets.

blank.gif Optional create virtual target and give access to the initiator.

blank.gif Configuration of target LUN mapping and masking on the storage system for the initiator based on the static pWWN created for the initiator on the MDS switch.

  • You need to duplicate the configuration manually on multiple MDS switches.
  • There is no load balancing for IPS ports. For example:

blank.gif The Virtual Router Redundancy Protocol (VRRP) only supports active and backup, not load balancing.

blank.gif You must use multiple VRRP groups and configure hosts in different groups.

iSLB provides the following features:

  • The iSLB initiator configuration is simplified with support for initiator targets and auto-zones.
  • Cisco Fabric Services (CFS) eliminates the need for manual configuration by distributing the iSLB initiator configuration among all MDS switches in the fabric.
note.gif

Noteblank.gif Only statically mapped iSLB initiator configuration is distributed throughout the fabric using CFS. Dynamically and statically mapped iSCSI initiator configurations are not distributed.


  • Dynamic load balancing of iSLB initiators is available using iSCSI login redirect and VRRP.

This section covers the following topics:

note.gif

Noteblank.gif Before configuring iSLB, you must enable iSCSI (see the “Enabling iSCSI” section).


note.gif

Noteblank.gif For iSLB, all switches in the fabric must be running Cisco MDS SAN-OS Release 2.1(1a) or later.


iSLB Configuration Limits

iSLB configuration has the following limits:

  • The maximum number of iSLB and iSCSI initiators supported in a fabric is 2000.
  • The maximum number of iSLB and iSCSI sessions supported by an IPS port in either transparent or proxy initiator mode is 500.
  • The maximum number of iSLB initiators supported in a fabric is 2000.
  • The maximum number of iSLB initiators and iSCSI sessions supported by a switch is 5000.
  • The maximum number of iSLB sessions per IPS port in either transparent or proxy initiator mode is 500.
  • The maximum number of iSLB and iSCSI targets supported in a fabric is 6000.
  • The maximum number of switches in a fabric that can have iSLB with CFS distribution enabled is four.
  • No more than 200 new iSLB initiators can be added to the pending configuration. Before adding more initiators, you must commit the configuration.
  • You cannot disable iSCSI if you have more than 200 iSLB initiators in the running configuration. Reduce the number of iSLB initiators to fewer than 200 before disabling iSCSI.
  • iSLB can be used without CFS distribution but if iSLB auto-zone feature is used, traffic is disrupted when any zoneset is activated.
  • If IVR and iSLB features are enabled in the same fabric, you should have at least one switch in the fabric where both these features are enabled. Any zoning-related configuration and activation (for normal zones, IVR zones, or iSLB zones) must be performed on this switch. Otherwise, there may be traffic disruption in the fabric.

iSLB Configuration Prerequisites

Perform the following prerequisite actions prior to configuring iSLB:

iSLB Initiators

iSLB initiators provide the following features in addition to those supported by iSCSI initiators:

  • An iSLB initiator also supports iSLB virtual targets.
  • Initiator targets–These targets are configured for a particular initiator.
  • Load balancing using iSCSI login redirect and VRRP–If iSCSI login redirect is enabled, the IPS Manager redirects incoming sessions to the best interface based on the calculated load for each interface.
  • Configuration distribution to other switches using CFS.

iSLB initiators provide the following features in addition to those supported by iSCSI initiators:

  • An iSLB initiator also supports iSLB virtual targets. These targets are very similar to iSCSI virtual targets with the exception that they do not include the advertise interface option and as a result are distributable using CFS.
  • Initiator targets–—These targets are configured for a particular initiator.
  • Load balancing using iSCSI login redirect and VRRP—If load balancing is enabled, the IPS Manager redirects incoming sessions to the best interface based on the calculated load for each interface.
  • Configuration distribution to other switches using CFS.

Configuring iSLB Using Device Manager

To configure iSLB using Device Manager, follow these steps:


Step 1blank.gif Choose IP > iSCSI iSLB.

You see the iSCSI iSLB dialog box (see Figure 4-32).

Figure 4-32 iSCSI iSLB Dialog Box

 

184008.tif

Step 2blank.gif Click Create to create a new iSCSI iSLB initiator.

You see the Create iSCSI iSLB Initiators dialog box (see Figure 4-33).

Figure 4-33 Create iSCSI iSLB Initiators Dialog Box

 

154438.tif

Step 3blank.gif Set the Name or IP Address field to the iSLB name or IP address.

Step 4blank.gif Set the VSAN Membership field to the VSAN that you want the iSLB initiator in.

Also see the “Assigning VSAN Membership for iSLB Initiators” section.

Step 5blank.gif Check the Persistent check box to convert a dynamic nWWN to static for the iSLB initiator.

Also see the “Making the Dynamic iSLB Initiator WWN Mapping Static” section.

Step 6blank.gif (Optional) Check the SystemAssigned check box to have the switch assign the nWWN.

Step 7blank.gif (Optional) Set the Static WWN field to manually assign the static nWWN. You must ensure uniqueness for this nWWN.

Step 8blank.gif (Optional) Check the Port WWN Mapping Persistent check box to convert dynamic pWWNs to static for the iSLB initiator.

See the “Making the Dynamic iSLB Initiator WWN Mapping Static” section.

Step 9blank.gif (Optional) Check the SystemAssigned check box and set the number of pWWNs you want to have the switch assign the PWWN.

Step 10blank.gif (Optional) Set the Static WWN(s) field to manually assign the static pWWNs.

You must ensure uniqueness for these pWWN.

Step 11blank.gif (Optional) Set the AuthUser field to the username that you want to restrict the iSLB initiator to for iSLB authentication.

Also see the “Restricting iSLB Initiator Authentication” section.

Step 12blank.gif Fill in the Username and Password fields to configure iSLB initiator target CHAP authentication.

Also see the “Configuring iSLB Session Authentication” section.

Step 13blank.gif In the Initiator Specific Target section, set the pWWN to configure an iSLB initiator target.

Step 14blank.gif (Optional) Set the Name field to a globally unique identifier (IQN).

Step 15blank.gif (Optional) Check the NoAutoZoneCreation check box to disable auto-zoning.

Step 16blank.gif (Optional) Check the TresspassMode check box.

Also see the “LUN Trespass for Storage Port Failover” section.

Step 17blank.gif (Optional) Check the RevertToPrimary check box to revert back to the primary port after an HA failover when the primary port comes back up.

Step 18blank.gif Set the PrimaryVsan to the VSAN for the iSLB initiator target.

Step 19blank.gif Click Create to create this iSLB initiator.

Step 20blank.gif If CFS is enabled, select commit from the CFS drop-down menu.


 

Configuring iSLB Initiators

This section includes the following topics:

Configuring iSLB Initiator Names or IP Addresses

You must specify the iSLB initiator name or IP address before configuring it.

note.gif

Noteblank.gif Specifying the iSLB initiator name or IP address is the same as for an iSCSI initiator. See the “Static Mapping” section.


To enter iSLB initiator configuration submode using the name option for an iSLB initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator name iqn.1987-02.com.cisco.initiator

switch(config-islb-init)#

Configures an iSLB initiator using the iSCSI name of the initiator node (iqn.1987-02.com.cisco.initiator) and enters iSLB initiator configuration submode. The maximum name length is 223 alphanumeric characters. The minimum length is 16.

switch(config)# no lslb initiator name iqn.1987-02.com.cisco.initiator

Deletes the configured iSLB initiator.

To enter iSLB initiator configuration submode using the ip-address option for an iSLB initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator ip-address 10.1.1.3

switch(config-islb-init)#

Configures an iSLB initiator using the IPv4 address of the initiator node and enters iSLB initiator configuration submode.

switch(config)# no islb initiator ip-address 10.1.1.3

Deletes the configured iSLB initiator.

switch(config)# islb initiator ip-address 2001:0DB8:800:200C::417A

switch(config-islb-init)#

Configures an iSLB initiator using the IPv6 unicast address of the initiator node and enters iSLB initiator configuration submode.

switch(config)# no islb initiator ip-address 2001:0DB8:800:200C::417A

Deletes the configured iSLB initiator.

Assigning WWNs to iSLB Initiators

An iSLB host is mapped to an N port’s WWNs by one of the following mechanisms:

  • Dynamic mapping (default)
  • Static mapping
note.gif

Noteblank.gif Assigning WWNs for iSLB initiators is the same as for iSCSI initiators. For information on dynamic and static mapping, see the “WWN Assignment for iSCSI Initiators” section.


tip.gif

Tipblank.gif We recommend using the SystemAssign system-assign option. If you manually assign a WWN, you must ensure its uniqueness (see the Cisco Fabric Manager Fabric Configuration Guide and Cisco MDS 9000 Family NX-OS Fabric Configuration Guide for more information). You should not use any previously assigned WWNs.


See the Configuring iSLB Using Device Manager.

Making the Dynamic iSLB Initiator WWN Mapping Static

After a dynamic iSLB initiator has logged in, you may decide to permanently keep the automatically assigned nWWN/pWWN mapping to allow this initiator to use the same mapping the next time it logs in (see the “Dynamic Mapping” section).

You can convert a dynamic iSLB initiator to a static iSLB initiator and make its WWNs persistent

note.gif

Noteblank.gif You cannot convert a dynamic iSCSI initiator to a static iSLB initiator or a dynamic iSLB initiator to a static iSCSI initiator (see the “Dynamic Mapping” section on page 4-20).


note.gif

Noteblank.gif Making the dynamic mapping for iSLB initiators static is the same as for iSCSI. See the “Making the Dynamic iSLB Initiator WWN Mapping Static” section“Making the Dynamic iSCSI Initiator WWN Mapping Static” section.


note.gif

Noteblank.gif Only statically mapped iSLB initiator configuration is distributed throughout the fabric using CFS. Dynamically and statically configured iSCSI initiator configurations are not distributed.


See the Configuring iSLB Using Device Manager.

To permanently keep the automatically assigned nWWN/pWWN mapping, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb save-initiator name iqn.1987-02.com.cisco.initiator

Saves the nWWNs and pWWNs that have automatically been assigned to the iSLB initiator whose name is specified.

switch(config)# islb save-initiator

10.10.100.11

Saves the nWWNs and pWWNs that have automatically been assigned to the iSLB initiator whose IPv4 address is specified.

switch(config)# iscsi save-initiator ip-address 2001:0DB8:800:200C::417A

Saves the nWWNs and pWWNs that have automatically been assigned to the iSCSI initiator whose IPv6 unicast address is specified.

switch(config)# islb save-initiator

Saves the nWWNs and pWWNs that have automatically been assigned to all the iSLB initiators.

Step 3

switch(config)# exit

switch#

Returns to EXEC mode.

Step 4

switch# copy running-config startup-config

Saves the nWWN/pWWN mapping configuration across system reboots.

Configuring iSLB Target Access Mapping

In iSLB, all fabric distributed configurations including iSCSI virtual target access are part of the iSCSI initiator configuration. Access is granted using the pWWN or the device alias. You can specify the one or more of the following optional parameters:

  • Secondary pWWN
  • Secondary device alias
  • LUN mapping
  • IQN

In addition, you can disable auto zoning.

If you configure an IQN for an initiator target then that name is used to identify the target. Otherwise, an unique IQN is generated for the initiator target.

To configure iSLB initiator access to an iSCSI virtual target, follow these steps:

Command
Purpose

Step 1

switch# config terminal

Enters configuration mode.

Step 2

switch(config)# islb initiator ip-address 10.1.1.3

switch(config-iscsi-islb-init)#

Configures the initiator using a name and enters iSLB initiator configuration submode.

Step 3

switch(config-iscsi-islb-init)# target pwwn 26:00:01:02:03:04:05:06

Grants iSLB initiator access to the target using a pWWN with auto zoning enabled (default).

switch(config-iscsi-islb-init)# target pwwn 26:00:01:02:03:04:05:06 no-zone

Grants iSLB initiator access to the target using a pWWN with auto zoning disabled.

switch(config-iscsi-islb-init)# target device-alias SampleAlias

Grants iSLB initiator access to the target using a device alias with auto zoning enabled (default).

switch(config-iscsi-islb-init)# target device-alias SampleAlias fc-lun 0x1234 iscsi-lun 0x2345

Grants iSLB initiator access to the target using a devices alias and optional LUN mapping.

switch(config-iscsi-islb-init)# target device-alias SampleAlias iqn-name iqn.1987-01.com.cisco.initiator

Grants iSLB initiator access to the target using a devices alias and an optional IQN.

switch(config-iscsi-islb-init)# target device-alias SampleAlias sec-device-alias SecondaryAlias

Grants iSLB initiator access to the target using a devices alias and an optional secondary device alias.

switch(config-iscsi-islb-init)# target device-alias SampleAlias sec-pwwn 26:01:02:03:04:05:06:07

Grants iSLB initiator access to the target using a devices alias and an optional secondary pWWN.

switch(config-iscsi-init)# no target pwwn 26:00:01:02:03:04:05:06

Removes the target access.

To verify the iSLB target configuration, use the show islb initiator configured command.

switch# show islb initiator configured
iSCSI Node name is 10.1.1.3
 
Number of Initiator Targets: 1
 
Initiator Target: iqn.1987-05.com.cisco:05.ips-hac4
Port WWN 50:06:04:82:ca:e1:26:8d
Zoning Enabled
No. of LU mapping: 3
iSCSI LUN: 0x0001, FC LUN: 0x0001
iSCSI LUN: 0x0002, FC LUN: 0x0002
iSCSI LUN: 0x0003, FC LUN: 0x0003
 

Assigning VSAN Membership for iSLB Initiators

Individual iSLB hosts can be configured to be in a specific VSAN (similar to the DPVM feature for Fibre Channel. The specified VSAN overrides the iSCSI interface VSAN membership.

For more information, see the Cisco MDS 9000 Family NX-OS Fabric Manager Fabric Configuration Guide.

note.gif

Noteblank.gif Specifying the iSLB initiator VSAN is the same as for an iSCSI initiator. See the VSAN Membership for iSCSI.


To assign VSAN membership for iSLB initiators, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator ip-address 10.1.1.3

switch(config-islb-init)#

Configures an iSLB initiator using its IPv4 address and enters iSLB initiator configuration submode.

Step 3

switch(config-islb-init)# vsan 3

Assigns the iSLB initiator node to a specified VSAN.

Note You can assign this host to one or more VSANs.

switch(config-islb-init)# no vsan 3

Removes the iSLB initiator from the specified VSAN.

note.gif

Noteblank.gif When an iSLB initiator is configured in any other VSAN (other than VSAN 1, the default VSAN), for example VSAN 2, the initiator is automatically removed from VSAN 1. If you also want it to be present in VSAN 1, you must explicitly configure the initiator in VSAN 1.


See the Configuring iSLB Using Device Manager.

Configuring Metrics for Load Balancing

You can assign a load metric to each initiator for weighted load balancing. The load calculated is based on the number of initiators on a given iSCSI interface. This feature accommodates initiators with different bandwidth requirements. For example, you could assign a higher load metric to a database server than to a web server. Weighted load balancing also accommodates initiators with different link speeds.

Also, you can configure initiator targets using the device alias or the pWWN. If you configure an IQN for an initiator target, then that name is used to identify the initiator target. Otherwise, a unique IQN is generated for the initiator target.

For more information on load balancing, see the “Load Balancing Using VRRP” section.

Choose IP > iSCSI iSLB in Device Manager and set the LoadMetric field to change the load balancing metric for an iSLB initiator.

See the Configuring iSLB Using Device Manager.

To configure a weight for load balancing, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator name iqn.1987-02.com.cisco.initiator

switch(config-iscsi-init)#

Configures an iSLB initiator using the name of the initiator node and enters iSLB initiator configuration mode.

Step 3

switch(config-iscsi-init)# metric 100

Assigns 100 as the weight metric for this iSLB initiator.

Step 4

switch(config-iscsi-init)# no metric 100

Reverts to the default value (1000).

Verifying iSLB Initiator Configuration

To verify the iSLB initiator configuration, use the show islb initiator configured command.

switch# show islb initiator configured
iSCSI Node name is 10.1.1.2
Member of vsans: 10
Node WWN is 23:02:00:0c:85:90:3e:82
Load Balance Metric: 100
Number of Initiator Targets: 1
 
Initiator Target: test-targt
Port WWN 01:01:01:01:02:02:02:02
Primary PWWN VSAN 1
Zoning support is enabled
Trespass support is disabled
Revert to primary support is disabled
 

Configuring iSLB Initiator Targets

You can configure initiator targets using the device alias or the pWWN. You can also optionally specify one or more of the following optional parameters:

  • Secondary pWWN
  • Secondary device alias
  • LUN mapping
  • IQN
  • VSAN identifier
note.gif

Noteblank.gif The VSAN identifier is optional if the target is online. If the target is not online, the VSAN identifier is required.


In addition, you can disable auto-zoning.

If you configure an IQN for an initiator target, then that name is used to identify the initiator target. Otherwise, a unique IQN is generated for the initiator target.

To configure iSLB initiator targets, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator ip-address 10.1.1.3

switch(config-islb-init)#

Configures an iSLB initiator using its IPv4 address and enters iSLB initiator configuration submode.

Step 3

switch(config-iscsi-islb-init)# target pwwn 26:00:01:02:03:04:05:06

Configures the iSLB initiator target using a pWWN with auto-zoning enabled (default).

switch(config-iscsi-islb-init)# target pwwn 26:00:01:02:03:04:05:06 no-zone

Configures the iSLB initiator target using a pWWN with auto-zoning disabled.

switch(config-iscsi-islb-init)# target device-alias SampleAlias

Configures the iSLB initiator target using a device alias with auto-zoning enabled (default).

switch(config-iscsi-islb-init)# target device-alias SampleAlias fc-lun 0x1234 iscsi-lun 0x2345

Configures the iSLB initiator target using a device alias and optional LUN mapping.

Note The CLI interprets the LUN identifier value as a hexadecimal value whether or not the 0x prefix is included.

switch(config-iscsi-islb-init)# target device-alias SampleAlias iqn-name iqn.1987-01.com.cisco.initiator

Configures the iSLB initiator target using a device alias and an optional IQN.

switch(config-iscsi-islb-init)# target device-alias SampleAlias sec-device-alias SecondaryAlias

Configures the iSLB initiator target using a device alias and an optional secondary device alias.

switch(config-iscsi-islb-init)# target device-alias SampleAlias sec-pwwn 26:01:02:03:04:05:06:07

Configures the iSLB initiator target using a device alias and an optional secondary pWWN.

switch(config-iscsi-islb-init)# target device-alias SampleAlias vsan 10

Configures the iSLB initiator target using a device alias and the VSAN identifier.

Note The VSAN identifier is optional is if the target is online. If the target is not online, the VSAN identifier is required.

switch(config-iscsi-init)# no target pwwn 26:00:01:02:03:04:05:06

Removes the iSLB initiator target.

To configure additional iSLB initiator targets using Device Manager, follow these steps:


Step 1blank.gif Choose IP > iSCSI iSLB.

You see the iSCSI iSLB dialog box (see Figure 4-32).

Step 2blank.gif Click on the initiator you want to add targets to and click Edit Initiator Specific Targets.

You see the Initiator Specific Target dialog box.

Step 3blank.gif Click Create to create a new initiator target.

You see the Create Initiator Specific Target dialog box (see Figure 4-34).

Figure 4-34 Create Initiator Specific Target Dialog Box

 

184007.tif

Step 4blank.gif Fill in the pWWN field with the initiator target pWWN.

Step 5blank.gif (Optional) Set the Name field to a globally unique identifier (IQN).

Step 6blank.gif (Optional) Check the NoAutoZoneCreation check box to disable auto-zoning (see Figure 4-33).

Step 7blank.gif (Optional) Check the TresspassMode check box. See the “LUN Trespass for Storage Port Failover” section.

Step 8blank.gif (Optional) Check the RevertToPrimary check box to revert back to the primary port after an HA failover when the primary port comes back up.

Step 9blank.gif Set the PrimaryVsan to the VSAN for the iSLB initiator target.

Step 10blank.gif Click Create to create this iSLB initiator target.

Step 11blank.gif If CFS is enabled, select commit from the CFS drop-down menu.

Configuring and Activating Zones for iSLB Initiators and Initiator Targets

You can configure a zone name where the iSLB initiators and initiator targets are added. If you do not specify a zone name, the IPS manager creates one dynamically. iSLB zone sets have the following considerations:

  • Auto-zoning of the initiator with the initiator targets is enabled by default.
  • A zone set must be active in a VSAN for auto-zones to be created in that VSAN.
  • iSLB zone set activation might fail if another zone set activation is in process or if the zoning database is locked. Retry the iSLB zone set activation if a failure occurs. To avoid this problem, only perform only one zoning related operation (normal zones, IVR zones, or iSLB zones) at a time.
  • Auto-zones are created when the zone set is activated and there has been at least one change in the zoneset. The activation has no effect if only the auto-zones have changed.
caut.gif

Caution blank.gif If IVR and iSLB are enabled in the same fabric, at least one switch in the fabric must have both features enabled. Any zoning related configuration or activation operation (for normal zones, IVR zones, or iSLB zones) must be performed on this switch. Otherwise, traffic might be disrupted in the fabric.

To configure the iSLB initiator optional auto-zone name and activate the zone set, follow these steps:

Command
Purpose

Step 1

switch# config terminal

Enters configuration mode.

Step 2

switch(config)# islb initiator ip-address 10.1.1.3

switch(config-islb-init)#

Configures an iSLB initiator using its IPv4 address and enters iSLB initiator configuration submode.

Step 3

switch(config-islb-init)# zonename IslbZone

Specifies the zone name where the initiators and the initiator targets are added (optional).

switch(config-islb-init)# no zonename IslbZone

Removes the initiators and initiator targets from the zone and adds them to a dynamically created zone (default).

Step 4

switch(config-islb-init)# exit

Returns to configuration mode.

Step 5

switch(config)# islb zoneset activate

Activates zoning for the iSLB initiators and initiator targets with zoning enabled and creates auto-zones if no zone names are configured.

Note This step is not required if CFS is enabled. CFS automatically activates the zone when the configuration changes are committed.

Choose IP > iSCSI iSLB in Device Manager and set the autoZoneName field to change the auto zone name for an iSLB initiator.

See the Configuring iSLB Using Device Manager.

Verifying iSLB Zoning Configuration

The following example shows the show zoneset active command output when the dynamically generated zone name is used:

switch# show zoneset active
zoneset name zoneset-1 vsan 1
zone name ips_zone_5d9603bcff68008a6fc5862a6670ca09 vsan 1
* fcid 0x010009 [ip-address 10.1.1.3]
pwwn 22:00:00:04:cf:75:28:4d
pwwn 22:00:00:04:cf:75:ed:53
pwwn 22:00:00:04:cf:75:21:d5
pwwn 22:00:00:04:cf:75:ee:59
.
.
.
 

The following example shows the show zoneset active command output when the configured zone name IslbZone is used:

switch# show zoneset active
zoneset name zoneset-1 vsan 1
zone name ips_zone_IslbZone vsan 1
ip-address 10.1.1.3
pwwn 22:00:00:04:cf:75:28:4d
pwwn 22:00:00:04:cf:75:ed:53
pwwn 22:00:00:04:cf:75:21:d5
pwwn 22:00:00:04:cf:75:ee:59
.
.
.

Configuring iSLB Session Authentication

The Fibre Channel module with IPS ports and MPS-14/2 module support the iSLB authentication mechanism to authenticate iSLB hosts that request access to storage. By default, the Fibre Channel module with IPS ports and MPS-14/2 module allow CHAP or None authentication of iSCSI initiators. If authentication is always used, you must configure the switch to allow only CHAP authentication.

For CHAP user name or secret validation you can use any method supported and allowed by the Cisco MDS AAA infrastructure (see the Cisco Fabric Manager Security Configuration GuideCisco MDS 9000 Family NX-OS Security Configuration Guide for more information). AAA authentication supports RADIUS, TACACS+, or a local authentication device.

note.gif

Noteblank.gif Specifying the iSLB session authentication is the same as for iSCSI. See the “iSCSI Session Authentication” section.


Restricting iSLB Initiator Authentication

By default, the iSLB initiator can use any user name in the RADIUS or local AAA database in authenticating itself to the Fibre Channel module with IPS ports or MPS-14/2 module (the CHAP user name is independent of the iSLB initiator name). The Fibre Channel module with IPS ports or MPS-14/2 module allows the initiator to log in as long as it provides a correct response to the CHAP challenge sent by the switch. This can be a problem if one CHAP user name and password have been compromised.

To restrict an initiator to use a specific user name for CHAP authentication, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator name iqn.1987-02.com.cisco.init

switch(config-islb-init)#

Configures an iSLB initiator using the IQN of the initiator node and enters iSLB initiator configuration mode.

Step 3

switch(config-islb-init)#

username user1

Restricts the initiator iqn.1987-02.com.cisco.init to only authenticate using user1 as its CHAP user name.

Note Be sure to define user1 as an iSCSI user in the local AAA database or the RADIUS server.

Choose IP > iSCSI iSLB in Device Manager and set the AuthName field to restrict an initiator to use a specific user name for CHAP authentication.

See the Configuring iSLB Using Device Manager.

Mutual CHAP Authentication

In addition to the Fibre Channel module with IPS ports and MPS-14/2 module authentication of the iSLB initiator, the Fibre Channel module with IPS ports and MPS-14/2 module also support a mechanism for the iSLB initiator to authenticate the Cisco MDS switch’s initiator target during the iSCSI login phase. This authentication requires the user to configure a user name and password for the switch to present to the iSLB initiator. The provided password is used to calculate a CHAP response to a CHAP challenge sent to the IPS port by the initiator.

To configure a per-initiator user name and password used by the switch to authenticate itself to an initiator, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb initiator name iqn.1987-02.com.cisco.initiator

switch(config-islb-init)#

Configures an iSLB initiator using the name of the initiator node and enters iSLB initiator configuration mode.

Step 3

switch(config-islb-init)# mutual-chap username testuser password dcba12LKJ

Configures the switch user account (testuser) along with a password (dcba12LKJ) specified in clear text (default). The password is limited to 128 characters.

switch(config-islb-init)# mutual-chap username testuser password 7!@*asdsfsdfjh!@df

Configures the switch user account (testuser) along with the encrypted password specified by 7 (!@*asdsfsdfjh!@df).

Step 4

switch(config-iscsi-init)# no mutual-chap username testuser

Removes the switch authentication configuration.

Choose IP > iSCSI iSLB in Device Manager and set the Target Username and Target Password fields to configure a per-initiator user name and password used by the switch to authenticate itself to an initiator.

See the Configuring iSLB Using Device Manager.

Verifying iSLB Authentication Configuration

Use the show running-config and the show iscsi global (see Example 4-6) commands to display the global configuration. Use the show running-config and the show islb initiator configured (see Example 4-14) commands to display the initiator specific configuration.

To verify the iSLB user name and mutual CHAP configuration, use the show islb initiator configured command:

switch# show islb initiator configured
iSCSI Node name is 10.1.1.3
Member of vsans: 3
User Name for login authentication: user1
User Name for Mutual CHAP: testuser
Load Balance Metric: 1000 Number of Initiator Targets: 1
Number of Initiator Targets: 1
 
Initiator Target: iqn.1987-05.com.cisco:05.ips-hac4
Port WWN 50:06:04:82:ca:e1:26:8d
Zoning Enabled
No. of LU mapping: 3
iSCSI LUN: 0x0001, FC LUN: 0x0001
iSCSI LUN: 0x0002, FC LUN: 0x0002
iSCSI LUN: 0x0003, FC LUN: 0x0003

Load Balancing Using VRRP

You can configure Virtual Router Redundancy Protocol (VRRP) load balancing for iSLB. The host is configured with a VRRP address as the portal address. When the VRRP master port receives the first iSCSI session from an initiator, it assigns a backup port to serve that particular host. The information is synchronized to all switches through CFS if recovery is needed when a master port fails. The initiator gets a temporary redirect iSCSI login response. The host then logs in to the backup port at its physical IP address. All iSCSI interfaces in a VRRP group that has load balancing enabled must have the same interface VSAN, authentication, proxy initiator mode, and forwarding mode.

You can configure Virtual Router Redundancy Protocol (VRRP) load balancing for iSLB. Figure 4-35 shows an example of load balancing using iSLB.

Figure 4-35 iSLB Initiator Load Balancing Example

 

154018.ps

The host is configured with a VRRP address as the portal address. When the VRRP master port receives the first iSCSI session from an initiator, it assigns a backup port to serve that particular host. This information is synchronized to all switches through CFS if recovery is needed when a master port fails. The initiator gets a temporary redirect iSCSI login response. The host then logs in to the backup port at its physical IP address. If the backup port goes down, the host will revert to the master port. The master port knows through CFS that the backup port has gone down and redirects the host to another backup port.

note.gif

Noteblank.gif If an Ethernet port channel is configured between the Fibre Channel module with IPS ports and an Ethernet switch, the load balancing policy on the Ethernet switch must be based on source/destination IP address only, not port numbers, for load balancing with VRRP to operate correctly.


note.gif

Noteblank.gif An initiator can also be redirected to the physical IP address of the master interface.


tip.gif

Tipblank.gif iSLB VRRP load balancing is based on the number of iSLB initiators and not number of sessions. Any iSLB initiator that has more targets configured than the other iSLB initiators (resulting in more sessions) should be configured with a higher load metric. For example, you can increase the load metric of the iSLB initiator with more targets to 3000 from the default value of 1000.


caut.gif

Caution blank.gif A Gigabit Ethernet interface configured for iSLB can only be in one VRRP group because redirected sessions do not carry information about the VRRP IP address or group. This restriction allows the slave backup port to uniquely identify the VRRP group to which it belongs.

Changing iSCSI Interface Parameters and the Impact on Load Balancing

All iSCSI interfaces in a VRRP group that has load balancing enabled must have the same interface VSAN, authentication, proxy initiator mode, and forwarding mode. When you need to change any of these parameters for the iSCSI interfaces in a VRRP group, you must do so one interface at a time. During the transition time when the parameter is changed on some interfaces in the VRRP group and not the others, the master port does not redirect new initiators and instead handles them locally.

caut.gif

Caution blank.gif Changing the VSAN, proxy initiator, authentication, and forwarding mode for iSCSI interfaces in a VRRP group can cause sessions to go down multiple times.

VRRP Load Balancing Algorithm for Selecting Gigabit Ethernet Interfaces

When the VRRP master receives an iSCSI session request from an initiator, it first checks for an existing mapping to one of the interfaces in that VRRP group. If such a mapping exists, the VRRP master redirects the initiator to that interface. If no such mapping exists, the VRRP master selects the least loaded interface and updates the selected interface’s load with the initiator’s iSLB metric (weight).

note.gif

Noteblank.gif The VRRP master interface is treated specially and it needs to take a lower load compared to the other interfaces. This is to account for the redirection work performed by the master interface for every session. A new initiator is assigned to the master interface only if the following is true for every other interface:

VRRP backup interface load > [2 * VRRP master interface load + 1]


Example 4-17 and Example 4-18 are based on the following configurations:

  • GigabitEthernet2/1.441 is the VRRP master interface for Switch1.
  • GigabitEthernet2/2.441 is the VRRP backup interface for Switch1.
  • GigabitEthernet1/1.441 is the VRRP backup interface for Switch2.
  • GigabitEthernet1/2.441 is the VRRP backup interface for Switch2.

Example 4-17 Load Distribution with the Default Metric

The follow example output shows the initial load distribution for three initiators with the default load metric value:

switch# show islb vrrp summary
.
.
.
--------------------------------------------------------------------------------
VR Id VRRP IP Switch WWN Ifindex Load
--------------------------------------------------------------------------------
M 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441 0
1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441 1000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441 1000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441 1000
-- Initiator To Interface Assignment --
--------------------------------------------------------------------------------
Initiator VR Id VRRP IP Switch WWN Ifindex
--------------------------------------------------------------------------------
iqn.cisco.test-linux.init0 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init1 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
 

The following example output shows load distribution for four initiators. The interface load metric value for the master interface changed from 0 to 1000.

switch# show islb vrrp summary
.
.
.
--------------------------------------------------------------------------------
VVR Id VRRP IP Switch WWN Ifindex Load
--------------------------------------------------------------------------------
M 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441 1000
1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441 1000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441 1000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441 1000
-- Initiator To Interface Assignment --
--------------------------------------------------------------------------------
Initiator VR Id VRRP IP Switch WWN Ifindex
--------------------------------------------------------------------------------
iqn.cisco.test-linux.init0 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init1 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init2 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init3 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441
 

The following example output shows load distribution for nine initiators. The interface load metric values for the backup interfaces have changed.

switch# show islb vrrp summary
.
.
.
--------------------------------------------------------------------------------
VVR Id VRRP IP Switch WWN Ifindex Load
--------------------------------------------------------------------------------
M 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441 1000
1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441 3000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441 3000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441 2000
-- Initiator To Interface Assignment --
--------------------------------------------------------------------------------
Initiator VR Id VRRP IP Switch WWN Ifindex
--------------------------------------------------------------------------------
iqn.cisco.test-linux.init0 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init1 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init2 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init3 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441
iqn.cisco.test-linux.init4 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init5 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init6 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init7 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init8 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441

Example 4-18 Load Distribution with the Metric Set to 3000 on One Initiator

The following example output shows the initial load distribution for three initiators with one initiator having load metric of 3000 and the remaining initiator with the default metric value:

switch# show islb vrrp summary
.
.
.
--------------------------------------------------------------------------------
VVR Id VRRP IP Switch WWN Ifindex Load
--------------------------------------------------------------------------------
M 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441 0
1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441 1000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441 3000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441 1000
-- Initiator To Interface Assignment --
--------------------------------------------------------------------------------
Initiator VR Id VRRP IP Switch WWN Ifindex
--------------------------------------------------------------------------------
iqn.cisco.test-linux.init0 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init1 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init2 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
 

The follow example output shows load distribution for four initiators. The interface load metric value for the master interface changed from 0 to 1000.

switch# show islb vrrp summary
.
.
.
--------------------------------------------------------------------------------
VVR Id VRRP IP Switch WWN Ifindex Load
--------------------------------------------------------------------------------
M 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441 1000
1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441 3000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441 1000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441 1000
-- Initiator To Interface Assignment --
--------------------------------------------------------------------------------
Initiator VR Id VRRP IP Switch WWN Ifindex
--------------------------------------------------------------------------------
iqn.cisco.test-linux.init0 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init1 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init2 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init3 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441
 

The following example output shows load distribution for nine initiators. The interface load metric values for the backup interfaces have changed.

switch# show islb vrrp summary
.
.
.
--------------------------------------------------------------------------------
VVR Id VRRP IP Switch WWN Ifindex Load
--------------------------------------------------------------------------------
M 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441 2000
1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441 3000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441 3000
1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441 3000
-- Initiator To Interface Assignment --
--------------------------------------------------------------------------------
Initiator VR Id VRRP IP Switch WWN Ifindex
--------------------------------------------------------------------------------
iqn.cisco.test-linux.init0 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/2.441
iqn.cisco.test-linux.init1 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init2 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init3 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441
iqn.cisco.test-linux.init4 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init5 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init6 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/1.441
iqn.cisco.test-linux.init7 1 10.10.122.115 20:00:00:0c:ce:5c:5b:c0 GigabitEthernet1/2.441
iqn.cisco.test-linux.init8 1 10.10.122.115 20:00:00:0b:5f:3c:01:80 GigabitEthernet2/1.441
 

Configuring Load Balancing Using VRRP

You must first configure VRRP on the Gigabit Ethernet interfaces on the switch that connect to the IP network before configuring VRRP for iSLB. For information on how to configure VRRP on a Gigabit Ethernet interface, see the “Virtual Router Redundancy Protocol” section.

To configure VRRP load balancing using Device Manager, follow these steps:


Step 1blank.gif Choose IP > iSCSI iSLB.

You see the iSCSI iSLB dialog box (see Figure 4-32).

Step 2blank.gif Click the VRRP tab.

Step 3blank.gif Click Create to configure VRRP load balancing for iSLB initiators.

You see the Create iSCSI iSLB VRRP dialog box (see Figure 4-36).

Figure 4-36 Create iSCSI iSLB VRRP Dialog Box

 

154435.tif

Step 4blank.gif Set the Vrld to the VRRP group number.

Step 5blank.gif Select either ipv4 or ipv6 and check the LoadBalance check box.

Step 6blank.gif Click Create to enable load balancing.

Step 7blank.gif If CFS is enabled, select commit from the CFS drop-down menu.


 

Enabling VRRP for Load Balancing

To enable or disable VRRP for iSLB, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# islb vrrp 10 load-balance

Enables iSLB VRRP for IPv4 VR group 10.

Step 3

switch(config)# no islb vrrp 10 load-balance

Disables iSLB VRRP for IPv4 VR group 10.

Step 4

switch(config)# islb vrrp ipv6 20 load-balance

Enables iSLB VRRP for IPv6 VR group 20.

Step 5

switch(config)# no islb vrrp ipv6 20 load-balance

Disables iSLB VRRP for IPv6 VR group 20.

Verifying iSLB VRRP Load Balancing Configuration

To verify the iSLB VRRP load balancing configuration for IPv4, use the show vrrp vr command:

switch# show vrrp vr 1
Interface VR IpVersion Pri Time Pre State VR IP addr
---------------------------------------------------------------------------
GigE1/5 1 IPv4 100 1 s master 10.10.10.1
GigE1/6 1 IPv4 100 1 s master 10.10.10.1
 

To verify the iSLB VRRP load balancing configuration for IPv6, use the show vrrp ipv6 vr command:

switch# show vrrp ipv6 vr 1
Interface VR IpVersion Pri Time Pre State VR IP addr
--------------------------------------------------------------------
GigE6/2 1 IPv6 100 100cs master 5000:1::100
PortCh 4 1 IPv6 100 100cs master 5000:1::100
 

Displaying iSLB VRRP Information

Use the show islb vrrp summary vr command to display VRRP load-balancing information:

switch# show islb vrrp summary vr 30
 
-- Groups For Load Balance --
------------------------------------------------------------------------------------------
VR Id VRRP Address Type Configured Status
------------------------------------------------------------------------------------------
30 IPv4 Enabled
 
-- Interfaces For Load Balance --
------------------------------------------------------------------------------------------
VR Id VRRP IP Switch WWN Ifindex Load
------------------------------------------------------------------------------------------
30 192.168.30.40 20:00:00:0d:ec:02:cb:00 GigabitEthernet3/1 2000
30 192.168.30.40 20:00:00:0d:ec:02:cb:00 GigabitEthernet3/2 2000
30 192.168.30.40 20:00:00:0d:ec:0c:6b:c0 GigabitEthernet4/1 2000
M 30 192.168.30.40 20:00:00:0d:ec:0c:6b:c0 GigabitEthernet4/2 1000
 

iSLB Configuration Distribution Using CFS

You can distribute the configuration for iSLB initiators and initiator targets on an MDS switch. This feature lets you synchronize the iSLB configuration across the fabric from the console of a single MDS switch. The iSCSI initiator idle timeout, global authentication, and iSCSI dynamic initiator mode parameters are also distributed. CFS distribution is disabled by default.

Configuration for iSLB initiators and initiator targets on an MDS switch can be distributed using the Cisco Fabric Services (CFS). This feature allows you to synchronize the iSLB configuration across the fabric from the console of a single MDS switch. The iSCSI initiator idle timeout, iSCSI dynamic initiator mode, and global authentication parameters are also distributed. CFS distribution is disabled by default (see the Cisco Fabric Manager System Management Configuration Guide and Cisco MDS 9000 Family NX-OS System Management Configuration Guide for more information).

After enabling the distribution, the first configuration starts an implicit session. All server configuration changes entered thereafter are stored in a temporary database and applied to all switches in the fabric (including the originating one) when you explicitly commit the database.

When CFS is enabled for iSLB, the first iSLB configuration operation starts a CFS session and locks the iSLB configuration in the fabric. The configuration changes are applied to the pending configuration database. When you make the changes to the fabric, the pending configuration is distributed to all the switches in the fabric. Each switch then validates the configuration. This check ensures the following:

  • The VSANs assigned to the iSLB initiators are configured on all the switches.
  • The static WWNs configured for the iSLB initiators are unique and available on all the switches.
  • The iSLB initiator node names do not conflict with the iSCSI initiators on all the switches.

After the check completes successfully, all the switches commit the pending configuration to the running configuration. If any check fails, the entire commit fails.

note.gif

Noteblank.gif iSLB is only fully supported when CFS is enabled. Using iSLB auto-zoning without enabling CFS mode may cause traffic disruption when any zone set is activated.


note.gif

Noteblank.gif CFS does not distribute non-iSLB initiator configurations or import Fibre Channel target settings.


Non-iSLB virtual targets will continue to support advertised interfaces option.

tip.gif

Tipblank.gif The pending changes are only available in the volatile directory and are discarded if the switch is restarted.


Distributing iSLB Configuration Using CFS

This section contains the following:

Enabling iSLB Configuration Distribution

To enable CFS distribution of the iSLB configuration, follow these steps:

Command
Purpose

Step 1

switch# config terminal

Enters configuration mode.

Step 2

switch(config)# islb distribute

Enables iSLB configuration distribution.

switch(config)# no islb distribute

Disables (default) iSLB configuration distribution.

To enable CFS distribution of the iSLB configuration using Device Manager, follow these steps:


Step 1blank.gif Choose Admin > CFS.

You see the CFS dialog box (see Figure 4-37).

Figure 4-37 Enabling CFS in Device Manager

 

183991.tif

Step 2blank.gif Set the Command field to enable for the iSLB feature.

Step 3blank.gif Click Apply to save this change.


 

Locking the Fabric

The first action that modifies the existing configuration creates the pending configuration and locks the feature in the fabric. Once you lock the fabric, the following conditions apply:

  • No other user can make any configuration changes to this feature.
  • A pending configuration is created by copying the active configuration. Modifications from this point on are made to the pending configuration and remain there until you commit the changes to the active configuration (and other switches in the fabric) or discard them.
note.gif

Noteblank.gif iSCSI configuration changes are not allowed when an iSLB CFS session is active.


Committing Changes to the Fabric

To apply the pending iSLB configuration changes to the active configuration and to other MDS switches in the fabric, you must commit the changes. The pending configuration changes are distributed and, on a successful commit, the configuration changes are applied to the active configuration in the MDS switches throughout the fabric, the automatic zones are activated, and the fabric lock is released.

To commit iSLB configuration changes to other MDS switches in the fabric, activate iSLB automatic zones, and release the fabric lock, follow these steps:

Command
Purpose

Step 1

switch# config terminal

Enters configuration mode.

Step 2

switch(config)# islb commit

Commits the iSLB configuration distribution, activates iSLB automatic zones, and releases the fabric lock.

To commit iSLB configuration changes to other MDS switches in the fabric, activate iSLB automatic zones, and release the fabric lock using Device Manager, follow these steps:


Step 1blank.gif Choose Admin > CFS.

You see the CFS Configuration dialog box (see Figure 4-37).

Step 2blank.gif Set the Command field to commit for the iSLB feature.

Step 3blank.gif Click Apply to save this change.


 

Discarding Pending Changes

At any time, you can discard the pending changes to the iSLB configuration and release the fabric lock. This action has no affect on the active configuration on any switch in the fabric.

To discard the pending iSLB configuration changes and release the fabric lock, follow these steps:

Command
Purpose

Step 1

switch# config terminal

Enters configuration mode.

Step 2

switch(config)# islb abort

Commits the iSLB configuration distribution.

To discard the pending iSLB configuration changes and release the fabric lock using Device Manager, follow these steps:


Step 1blank.gif Choose Admin > CFS.

You see the CFS Configuration dialog box (see Figure 4-37).

Step 2blank.gif Set the Command field to abort for the iSLB feature.

Step 3blank.gif Click Apply to save this change.


 

Clearing a Fabric Lock

If you have performed an iSLB configuration task and have not released the lock by either committing or discarding the changes, an administrator can release the lock from any switch in the fabric. If the administrator performs this task, your pending changes are discarded and the fabric lock is released.

note.gif

Noteblank.gif The pending changes are only available in the volatile directory and are discarded if the switch is restarted.


To release a fabric lock, issue the clear islb session command in EXEC mode using a login ID that has administrative privileges:

switch# clear islb session
 

To release a fabric lock using Device Manager, follow these steps:


Step 1blank.gif Choose Admin > CFS.

You see the CFS Configuration dialog box (see Figure 4-37).

Step 2blank.gif Set the Command field to clear for the iSLB feature.

Step 3blank.gif Click Apply to save this change.


 

CFS Merge Process

When two fabrics merge, CFS attempts to merge the iSLB configuration from both the fabrics. A designated switch (called the dominant switch) in one fabric sends its iSLB configuration to a designated switch (called the subordinate switch) in the other fabric. The subordinate switch compares its running configuration to the received configuration for any conflicts. If no conflicts are detected, it merges the two configurations and sends it to all the switches in both the fabrics. Each switch then validates the configuration. This check ensures the following:

  • VSANs assigned to the iSLB initiators are configured on all the switches.
  • The static WWNs configured for the iSLB initiators are unique and available on all the switches.
  • The iSLB initiator node names have no conflicts with iSCSI initiators on all the switches.

If this check completes successfully, the subordinate switch directs all the switches to commit the merged configuration to running configuration. If any check fails, the merge fails.

The show islb merge status command displays the exact reason for the failure. The first successful commit request after a merge failure takes the fabric out of the merge failure state.

Displaying Pending iSLB Configuration Changes

You can display the pending configuration changes using the show islb pending command:

switch# show islb pending
iscsi initiator idle-timeout 10
islb initiator ip-address 10.1.1.1
static pWWN 23:01:00:0c:85:90:3e:82
static pWWN 23:06:00:0c:85:90:3e:82
username test1
islb initiator ip-address 10.1.1.2
static nWWN 23:02:00:0c:85:90:3e:82
 

You can display the differences between the pending configuration and the current configuration using the show islb pending-diff command:

switch# show islb pending-diff
+iscsi initiator idle-timeout 10
islb initiator ip-address 10.1.1.1
+ static pWWN 23:06:00:0c:85:90:3e:82
+islb initiator ip-address 10.1.1.2
+ static nWWN 23:02:00:0c:85:90:3e:82
 

Displaying iSLB CFS Status

You can display the iSLB CFS status using the show islb session status command:

switch# show islb status
iSLB Distribute is enabled
iSLB CFS Session exists
 

Displaying iSLB CFS Distribution Session Status

You can display the status of the iSLB CFS distribution session using the show islb cfs-session status command:

switch# show islb cfs-session status
last action : fabric distribute enable
last action result : success
last action failure cause : success
 

Displaying iSLB CFS Merge Status

You can display the iSLB CFS merge status using the show islb merge status command:

switch# show islb merge status
Merge Status: Success
 

iSLB CFS Merge Status Conflicts

Merge conflicts may occur. User intervention is required for the following merge conflicts:

  • The iSCSI global authentication or iSCSI initiator idle timeout parameters are not configured the same in the two fabrics.
  • The same iSLB initiator is configured differently in the two fabrics.
  • An iSLB initiator in one fabric has the same name as an iSCSI initiator in the other fabric.
  • Duplicate pWWN/nWWN configuration is detected in the two fabric. For example, a pWWN/nWWN configured for an iSLB initiator on one fabric is configured for an iSCSI initiator or a different iSLB initiator in the other fabric.
  • A VSAN configured for an iSLB initiator in one fabric does not exist in the other fabric.
tip.gif

Tipblank.gif Check the syslog for details on merge conflicts.


User intervention is not required when the same iSLB initiator has a different set of non-conflicting initiator targets. The merged configuration is the union of all the initiator targets.

iSCSI High Availability

The following high availability features are available for iSCSI configurations:

Transparent Target Failover

The following high-availability features are available for iSCSI configurations:

  • iSCSI high availability with host running multi-path software—In this topology, you have recovery from failure of any of the components. The host multi-path software takes care of load balancing or failover across the different paths to access the storage.
  • iSCSI high availability with host not having multi-path software—Without multi-path software, the host does not have knowledge of the multiple paths to the same storage.

iSCSI High Availability with Host Running Multipath Software

Figure 4-38 shows the physical and logical topology for an iSCSI HA solution for hosts running multi-path software. In this scenario, the host has four iSCSI sessions. There are two iSCSI sessions from each host NIC to the two IPS ports.

Figure 4-38 Host Running Multipath Software

 

120743.ps

Each IPS ports is exporting the same two Fibre Channel target ports of the storage but as different iSCSI target names if you use dynamic iSCSI targets). So the two IPS ports are exporting a total of four iSCSI target devices. These four iSCSI targets map the same two ports of the Fibre Channel target.

The iSCSI host uses NIC-1 to connect to IPS port 1 and NIC-2 to connect to IPS port 2. Each IPS port exports two iSCSI targets, so the iSCSI host creates four iSCSI sessions.

If the iSCSI host NIC-1 fails (see Figure 4-38 for the physical view), then sessions 1 and 2 fail but we still have sessions 3 and 4.

If the IPS port 1 fails, the iSCSI host cannot connect to the IPS port, and sessions 1 and 2 fail. But sessions 3 and 4 are still available.

If the storage port 1 fails, then the IPS ports will terminate sessions 1 and 3 (put iSCSI virtual target iqn.com.cisco.mds-5.1-2.p1 and iqn-com.cisco.mds-5.1-1.p1 in offline state). But sessions 2 and 4 are still available.

In this topology, you have recovery from failure of any of the components. The host multi-path software takes care of load-balancing or failover across the different paths to access the storage.

iSCSI HA with Host Not Having Any Multipath Software

The above topology will not work if the host does not have multi-path software because the host has multiple sessions to the same storage. Without multi-path software the host does not have knowledge of the multiple paths to the same storage.

IP storage has two additional features that provide an HA solution in this scenario.

Statically imported iSCSI targets have an additional option to provide a secondary pWWN for the Fibre Channel target. This can be used when the physical Fibre Channel target is configured to have an LU visible across redundant ports. When the active port fails, the secondary port becomes active and the iSCSI session switches to use the new active port (see Figure 4-39).

Figure 4-39 Static Target Importing Through Two Fibre Channel Ports

 

91568.ps

In Figure 4-39, you can create an iSCSI virtual target that is mapped to both pWWN1 and pWWN2 to provide redundant access to the Fibre Channel targets.

The failover to a secondary port is done transparently by the IPS port without impacting the iSCSI session from the host. All outstanding I/Os are terminated with a check condition status when the primary port fails. New I/Os received during the failover are not completed and receive a busy status.

tip.gif

Tipblank.gif If you use LUN mapping, you can define a different secondary Fibre Channel LUN if the LU number is different.


Enable the optional revert-primary-port option to direct the IPS port to switch back to the primary port when the primary port is up again. If this option is disabled (default) and the primary port is up again after a switchover, the old sessions will remain with the secondary port and do not switch back to the primary port. However, any new session will use the primary port. This is the only situation when both the primary and secondary ports are used at the same time.

To create a static iSCSI virtual target, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi virtual-target name iqn.1987-02.com.cisco.initiator

Creates the iSCSI target name iqn.1987-02.com.cisco.initiator.

Step 3

switch(config-iscsi-tgt)# pwwn 26:00:01:02:03:04:05:06

Configures the primary port for this virtual target.

switch(config-iscsi-tgt)# pwwn 26:00:01:02:03:04:05:06 secondary-pwwn 26:00:01:02:03:10:11:12

Configures the primary and secondary ports for this virtual target.

switch(config-iscsi-tgt)# pwwn 26:00:01:02:03:04:05:06 fc-lun 0x1 iscsi-lun 0x0 sec-lun 0x3

Configures the primary port for this virtual target with LUN mapping and different LUN on the secondary Fibre Channel port.

Note The CLI interprets the LUN identifier value as a hexadecimal value whether or not the 0x prefix is included.

switch(config-iscsi-tgt)# no pwwn 26:00:01:02:03:04:05:06

Removes the primary port, secondary port, and LUN mapping configuration for this virtual target.

Step 4

switch(config-iscsi-tgt)# revert-primary-port

Configures the session failover redundancy for this virtual-target to switch all sessions back to primary port when the primary port comes back up.

Step 5

switch(config-iscsi-tgt)# no revert-primary-port

Directs the switch to continue using the secondary port for existing sessions and to use the primary port for new sessions (default).

To create a static iSCSI virtual target for the entire Fibre Channel target port using Device Manager, follow these steps:


Step 1blank.gif Click IP > iSCSI.

You see the iSCSI configuration (see Figure 4-12).

Step 2blank.gif Click the Targets tab to display a list of existing iSCSI targets shown (see Figure 4-13).

Step 3blank.gif Click Create to create an iSCSI target.

You see the Create iSCSI Targets dialog box (see Figure 4-15).

Step 4blank.gif Set the iSCSI target node name in the iSCSI Name field, in IQN format.

Step 5blank.gif Set the Port WWN field for the Fibre Channel target port you are mapping.

Step 6blank.gif Click the Select from List radio button and set the iSCSI initiator node names or IP addresses that you want this virtual iSCSI target to access, or click the All radio button to let the iSCSI target access all iSCSI initiators. See the “iSCSI Access Control” section.

Step 7blank.gif Chick the Select from List radio button and check each interface you want to advertise the iSCSI targets on or choose the All radio button to advertise all interfaces.

Step 8blank.gif Click Apply to save this change.


 

LUN Trespass for Storage Port Failover

In addition to the high availability of statically imported iSCSI targets, the trespass feature is available to enable the move of LUs, on an active port failure, from the active to the passive port of a statically imported iSCSI target.

In physical Fibre Channel targets, which are configured to have LUs visible over two Fibre Channel N ports, when the active port fails, the passive port takes over. Some physical Fibre Channel targets require that the trespass feature be used to move the LUs from the active port to the passive port. A statically imported iSCSI target's secondary pWWN option and an additional option of enabling the trespass feature is available for a physical Fibre Channel target with redundant ports. When the active port fails, the passive port becomes active, and if the trespass feature is enabled, the Cisco MDS switch sends a request to the target to move the LUs on the new active port. The iSCSI session switches to use the new active port and the moved LUs are accessed over the new active port (see Figure 4-40).

Figure 4-40 Virtual Target with an Active Primary Port

 

105219.ps

To enable the trespass feature for a static iSCSI virtual target, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# iscsi virtual-target name iqn.1987-02.com.cisco.initiator

switch(config-iscsi-tgt)#

Creates the iSCSI target name iqn.1987-02.com.cisco.initiator.

Step 3

switch(config-iscsi-tgt)# pwwn 50:00:00:a1:94:cc secondary-pwwn 50:00:00:a1:97:ac

Maps a virtual target node to a Fibre Channel target and configures a secondary pWWN.

Step 4

switch(config-iscsi-tgt)# trespass

Enables the trespass feature.

switch(config-iscsi-tgt)# no trespass

Disables the trespass feature (default).

Use the show iscsi virtual-target command to verify:

switch# show iscsi virtual-target iqn.1987-02.com.cisco.initiator
target: 1987-02.com.cisco.initiator
Port WWN 10:20:10:00:56:00:70:50
Configured node
all initiator permit is disabled
trespass support is enabled
 

In Device Manager, choose IP > iSCSI, select the Targets tab, and check the Trespass Mode check box to enable the trespass feature for a static iSCSI virtual target.

Multiple IPS Ports Connected to the Same IP Network

Figure 4-41 provides an example of a configuration with multiple Gigabit Ethernet interfaces in the same IP network.

Figure 4-41 Multiple Gigabit Ethernet Interfaces in the Same IP Network

 

90861.ps

In Figure 4-41, each iSCSI host discovers two iSCSI targets for every physical Fibre Channel target (with different names). The multi-pathing software on the host provides load-balancing over both paths. If one Gigabit Ethernet interface fails, the host multi-pathing software is not affected because it can use the second path.

VRRP-Based High Availability

Figure 4-42 provides an example of a VRRP-based high availability iSCSI configuration.

Figure 4-42 VRRP-Based iSCSI High Availability

 

90862.ps

In Figure 4-42, each iSCSI host discovers one iSCSI target for every physical Fibre Channel target. When the Gigabit Ethernet interface of the VRRP master fails, the iSCSI session is terminated. The host then reconnects to the target and the session comes up because the second Gigabit Ethernet interface has taken over the virtual IP address as the new master.

Ethernet Port Channel-Based High Availability

note.gif

Noteblank.gif All iSCSI data traffic for one iSCSI link is carried on one TCP connection. Consequently, the aggregated bandwidth is 1 Gbps for that iSCSI link.


Figure 4-43 provides a sample Ethernet Port Channel-based high availability iSCSI configuration.

Figure 4-43 Ethernet Port Channel-Based iSCSI High Availability

 

90863.ps

In Figure 4-43, each iSCSI host discovers one iSCSI target for every physical Fibre Channel target. The iSCSI session from the iSCSI host to the iSCSI virtual target (on the IPS port) uses one of the two physical interfaces (because an iSCSI session uses one TCP connection). When the Gigabit Ethernet interface fails, the Fibre Channel module with IPS ports and the Ethernet switch transparently forwards all the frames on to the second Gigabit Ethernet interface.

note.gif

Noteblank.gif If an Ethernet port channel is configured between the Fibre Channel module with IPS ports and an Ethernet switch, the load balancing policy on the Ethernet switch must be based on source/destination IP address only, not port numbers, for load balancing with VRRP to operate correctly.


iSCSI Authentication Setup Guidelines and Scenarios

This section provides guidelines on iSCSI authentication possibilities, setup requirements, and sample scenarios. It includes the following authentication setup guidelines:

note.gif

Noteblank.gif This section does not specify the steps to enter or exit EXEC mode, configuration mode, or any submode. Be sure to verify the prompt before entering any command.


caut.gif

Caution blank.gif Changing the authentication of an iSCSI interface that is part of an iSLB VRRP group impacts load balancing on the interface. See the “Changing iSCSI Interface Parameters and the Impact on Load Balancing” section.

Configuring No Authentication

Set the iSCSI authentication method to none to configure a network with no authentication:

In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane. Then select the Globals tab and set the AuthMethod drop-down menu to none and click Apply Changes.

switch(config)# iscsi authentication none
 

Configuring CHAP with Local Password Database

To configure authentication using the CHAP option with the local password database, follow these steps:


Step 1blank.gif Set the AAA authentication to use the local password database for the iSCSI protocol:

switch(config)# aaa authentication iscsi default local
 

Step 2blank.gif Set the iSCSI authentication method to require CHAP for all iSCSI clients:

switch(config)# iscsi authentication chap
 

Step 3blank.gif Configure the user names and passwords for iSCSI users:

switch(config)# username iscsi-user password abcd iscsi
note.gif

Noteblank.gif If you do not specify the iscsi option, the user name is assumed to be a Cisco MDS switch user instead of an iSCSI user.


Step 4blank.gif Verify the global iSCSI authentication setup:

switch# show iscsi global
iSCSI Global information Authentication: CHAP <----Verify
Import FC Target: Disabled
.
.
.
 


 

To configure authentication using the CHAP option with the local password database, follow these steps:


Step 1blank.gif Set the AAA authentication to use the local password database for the iSCSI protocol:

a.blank.gif In Fabric Manager, choose Switches > Security > AAA in the Physical Attributes pane.

b.blank.gif Click the Applications tab in the Information pane.

c.blank.gif Check the Local check box for the iSCSI row and click Apply Changes

Step 2blank.gif Set the iSCSI authentication method to require CHAP for all iSCSI clients:

a.blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane.

b.blank.gif Click the Globals tab in the Information pane.

c.blank.gif Set the AuthMethod drop-down menu to chap and click Apply Changes.

a.blank.gif iSCSI in the Physical Attributes pane.

b.blank.gif Click the Globals tab in the Information pane.

Configuring CHAP with External RADIUS Server

To configure authentication using the CHAP option with an external RADIUS server, follow these steps:


Step 1blank.gif Configure the password for the Cisco MDS switch as RADIUS client to the RADIUS server:

switch(config)# radius-server key mds-1
 

Step 2blank.gif Configure the RADIUS server IP address by performing one of the following:

  • Configure an IPv4 address:
switch(config)# radius-server host 10.1.1.10
 
  • Configure an IPv6 address:
switch(config)# radius-server host 2001:0DB8:800:200C::417A
 

Step 3blank.gif Configure the RADIUS server group IP address by performing one of the following:

  • Configure an IPv4 address:
switch(config)# aaa group server radius iscsi-radius-group
switch(config-radius)# server 10.1.1.1
 
  • Configure an IPv6 address:
switch(config)# aaa group server radius iscsi-radius-group
switch(config-radius)# server 001:0DB8:800:200C::4180
 
switch(config)# aaa authentication iscsi default group iscsi-radius-group
 

Step 4blank.gif Set up the iSCSI authentication method to require CHAP for all iSCSI clients:

switch(config)# iscsi authentication chap
 

Step 5blank.gif Verify that the global iSCSI authentication setup is for CHAP:

switch# show iscsi global
iSCSI Global information
Authentication: CHAP <---------------- Verify CHAP
.
.
.
 

Step 6blank.gif Verify that the AAA authentication information is for iSCSI”

switch# show aaa authentication
default: local
console: local
iscsi: group iscsi-radius-group <--------- Group name
dhchap: local
 
switch# show radius-server groups
total number of groups:2
 
following RADIUS server groups are configured:
group radius:
server: all configured radius servers
group iscsi-radius-group:
server: 10.1.1.1 on auth-port 1812, acct-port 1813
 
switch# show radius-server
Global RADIUS shared secret:mds-1 <-------- Verify secret
.
.
.
.
 
following RADIUS servers are configured:
10.1.1.1: <----------- Verify the server IPv4 address
available for authentication on port:1812
available for accounting on port:1813


 


Step 1blank.gif Configure the password for the Cisco MDS switch as RADIUS client to the RADIUS server:

a.blank.gif In Fabric Manager, choose Switches > Security > AAA > RADIUS in the Physical Attributes pane.

b.blank.gif Click the Default tab in the Information pane.

c.blank.gif Set the AuthKey field to the default password and click the Apply Changes icon.

Step 2blank.gif Configure the RADIUS server IP address:

a.blank.gif In Fabric Manager, choose Switches > Security > AAA > RADIUS in the Physical Attributes pane.

b.blank.gif Click the Server tab in the Information pane and click Create Row.

c.blank.gif Set the Index field to a unique number.

d.blank.gif Set the IP Type radio button to ipv4 or ipv6.

e.blank.gif Set the Name or IP Address field to the IP address of the RADIUS server and click Create.

Step 3blank.gif Create a RADIUS server group and add the RADIUS server to the group:

a.blank.gif In Fabric Manager, choose Switches > Security > AAA in the Physical Attributes pane.

b.blank.gif Select the Server Groups tab in the Information pane and click Create Row.

c.blank.gif Set the Index field to a unique number.

d.blank.gif Set the Protocol radio button to radius.

e.blank.gif Set the Name field to the server group name.

f.blank.gif Set the ServerIDList to the index value of the RADIUS server (as created in Step 2 c.) and click Create.

Step 4blank.gif Set up the authentication verification for the iSCSI protocol to go to the RADIUS server.

a.blank.gif In Fabric Manager, choose Switches > Security > AAA in the Physical Attributes pane.

b.blank.gif Click the Applications tab in the Information pane.

c.blank.gif Right-click on the iSCSI row in the Type, SubType, Function column.

d.blank.gif Set the ServerGroup IDList to the index value of the Server Group (as created in Step 3 c) and click Create.

Step 5blank.gif Set up the iSCSI authentication method to require CHAP for all iSCSI clients.

a.blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane.

b.blank.gif Select chap from the AuthMethod drop-down menu.

c.blank.gif Click the Apply Changes icon.

Step 6blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane.

Step 7blank.gif Click the Globals tab in the Information pane to verify that the global iSCSI authentication setup is for CHAP.

Step 8blank.gif In Fabric Manager, choose Switches > Security > AAA in the Physical Attributes pane.

Step 9blank.gif Click the Applications tab in the Information pane to verify the AAA authentication information for iSCSI.


 

To configure an iSCSI RADIUS server, follow these steps:


Step 1blank.gif Configure the RADIUS server to allow access from the Cisco MDS switch's management Ethernet IP address.

Step 2blank.gif Configure the shared secret for the RADIUS server to authenticate the Cisco MDS switch.

Step 3blank.gif Configure the iSCSI users and passwords on the RADIUS server.


 

iSCSI Transparent Mode Initiator

This scenario assumes the following configuration (see Figure 4-44):

  • No LUN mapping or LUN masking or any other access control for hosts on the target device
  • No iSCSI login authentication (that is, login authentication set to none)
  • The topology is as follows:

blank.gif iSCSI interface 7/1 is configured to identify initiators by IP address.

blank.gif iSCSI interface 7/5 is configured to identify initiators by node name.

blank.gif The iSCSI initiator host 1 with IPv4 address 10.11.1.10 and name iqn.1987-05.com.cisco:01.255891611111 connects to IPS port 7/1 is identified using IPv4 address (host 1 = 10.11.1.10).

blank.gif The iSCSI initiator host 2 with IPv4 address 10.15.1.10 and node name iqn.1987-05.com.cisco:01.25589167f74c connects to IPS port 7/5.

Figure 4-44 iSCSI Scenario 1

 

94136.ps

To configure scenario 1 (see Figure 4-44), follow these steps:


Step 1blank.gif Configure null authentication for all iSCSI hosts in Cisco MDS switches:

switch(config)# iscsi authentication none
 

Step 2blank.gif Configure iSCSI to dynamically import all Fibre Channel targets into the iSCSI SAN using auto-generated iSCSI target names:

switch(config)# iscsi import target fc
 

Step 3blank.gif Configure the Gigabit Ethernet interface in slot 7 port 1 with an IPv4 address and enable the interface:

switch(config)# interface gigabitethernet 7/1
switch(config-if)# ip address 10.11.1.1 255.255.255.0
switch(config-if)# no shutdown
note.gif

Noteblank.gif Host 2 is connected to this port.


Step 4blank.gif Configure the iSCSI interface in slot 7 port 1 to identify all dynamic iSCSI initiators by their IP address, and enable the interface:

switch(config)# interface iscsi 7/1
switch(config-if)# switchport initiator id ip-address
switch(config-if)# no shut
 

Step 5blank.gif Configure the Gigabit Ethernet interface in slot 7 port 5 with the IPv4 address and enable the interface:

switch(config)# interface gigabitethernet 7/5
switch(config-if)# ip address 10.15.1.1 255.255.255.0
switch(config-if)# no shutdown
 

Step 6blank.gif Configure the iSCSI interface in slot 7 port 5 to identify all dynamic iSCSI initiators by node name and enable the interface:

switch(config)# interface iscsi 7/5
switch(config-if)# switchport initiator id name
switch(config-if)# no shutdown
 
note.gif

Noteblank.gif Host 1 is connected to this port.


Step 7blank.gif Verify the available Fibre Channel targets (see Figure 4-44):

switch# show fcns database
VSAN 1:
--------------------------------------------------------------------------
FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE
--------------------------------------------------------------------------
0x6d0001 NL 21:00:00:20:37:6f:fd:97 (Seagate) scsi-fcp:target
0x6d0101 NL 21:00:00:20:37:6f:fe:54 (Seagate) scsi-fcp:target
0x6d0201 NL 21:00:00:20:37:a6:a6:5d (Seagate) scsi-fcp:target
Total number of entries = 3
 

Step 8blank.gif Create a zone named iscsi-zone-1 with host 1 and one Fibre Channel target in it:

note.gif

Noteblank.gif Use the IP address of the host in zone membership configuration because the iSCSI interface is configured to identify all hosts based on IP address.


switch(config)# zone name iscsi-zone-1 vsan 1
switch(config-zone)# member pwwn 21:00:00:20:37:6f:fd:97
switch(config-zone)# member ip-address 10.11.1.10
 

Step 9blank.gif Create a zone named iscsi-zone-2 with host 2 and two Fibre Channel targets in it:

note.gif

Noteblank.gif Use the symbolic node name of the iSCSI host in zone membership configuration because the iSCSI interface is configured to identify all hosts based on node name.


switch(config)# zone name iscsi-zone-2 vsan 1
switch(config-zone)# member pwwn 21:00:00:20:37:6f:fe:54
switch(config-zone)# member pwwn 21:00:00:20:37:a6:a6:5d
switch(config-zone)# member symbolic-nodename iqn.1987-05.com.cisco:01.25589167f74c
 

Step 10blank.gif Create a zone set and add the two zones as members:

switch(config)# zoneset name zoneset-iscsi vsan 1
switch(config-zoneset)# member iscsi-zone-1
switch(config-zoneset)# member iscsi-zone-2
 

Step 11blank.gif Activate the zone set:

switch(config)# zoneset activate name zoneset-iscsi vsan 1
 

Step 12blank.gif Display the active zone set:

note.gif

Noteblank.gif The iSCSI hosts are not connected so they do not have an FC ID yet.


switch# show zoneset active
zoneset name zoneset-iscsi vsan 1
zone name iscsi-zone-1 vsan 1
* fcid 0x6d0001 [pwwn 21:00:00:20:37:6f:fd:97] <-----------Target
symbolic-nodename 10.11.1.10 <--------------------------------- iSCSI host (host 1, not online)
 
zone name iscsi-zone-2 vsan 1
* fcid 0x6d0101 [pwwn 21:00:00:20:37:6f:fe:54] <------------Target
* fcid 0x6d0201 [pwwn 21:00:00:20:37:a6:a6:5d] <------------Target
symbolic-nodename iqn.1987-05.com.cisco:01.25589167f74c <-iSCSI host (host 2, not online)
 

Step 13blank.gif Bring up the iSCSI hosts (host 1 and host 2).

Step 14blank.gif Show all the iSCSI sessions (use the detail option for detailed information):

switch# show iscsi session
Initiator iqn.1987-05.com.cisco:01.25589167f74c <-----Host 2
Initiator ip addr (s): 10.15.1.11
Session #1
Target iqn.1987-05.com.cisco:05.172.22.92.166.07-05.21000020376ffe54
 
note.gif

Noteblank.gif The last part of the auto-created target name is the Fibre Channel target's pWWN.


VSAN 1, ISID 00023d000001, Status active, no reservation
 
Session #2
Target iqn.1987-05.com.cisco:05.172.22.92.166.07-05.2100002037a6a65d
VSAN 1, ISID 00023d000001, Status active, no reservation
 
Initiator 10.11.1.10 <-----------------------------------Host 1
Initiator name iqn.1987-05.com.cisco:01.e41695d16b1a
Session #1
Target iqn.1987-05.com.cisco:05.172.22.92.166.07-01.21000020376ffd97
VSAN 1, ISID 00023d000001, Status active, no reservation
 

Step 15blank.gif Verify the details of the two iSCSI initiators:

switch# show iscsi initiator

iSCSI Node name is iqn.1987-05.com.cisco:01.25589167f74c <---------

Initiator ip addr (s): 10.15.1.11

iSCSI alias name: oasis11.cisco.com

Node WWN is 20:02:00:0b:fd:44:68:c2 (dynamic)

Member of vsans: 1

Number of Virtual n_ports: 1

Virtual Port WWN is 20:03:00:0b:fd:44:68:c2 (dynamic)

Interface iSCSI 7/5, Portal group tag: 0x304

VSAN ID 1, FCID 0x6d0300

Host 2: Initiator ID based on node name because the initiator is entering iSCSI interface 7/5

iSCSI Node name is 10.11.1.10 <------------------------

iSCSI Initiator name: iqn.1987 - 05.com.cisco:01.e41695d16b1a

iSCSI alias name: oasis10.cisco.com

Node WWN is 20:04:00:0b:fd:44:68:c2 (dynamic)

Member of vsans: 1

Number of Virtual n_ports: 1

Virtual Port WWN is 20:05:00:0b:fd:44:68:c2 (dynamic)

Interface iSCSI 7/1, Portal group tag: 0x300

VSAN ID 1, FCID 0x6d0301

Host 1: Initiator ID based on IPv4 address because the initiator is entering iSCSI interface 7/1

Step 16blank.gif View the active zone set. The iSCSI initiators' FC IDs are resolved:

switch# show zoneset active

zoneset name zoneset-iscsi vsan 1

zone name iscsi-zone-1 vsan 1

* fcid 0x6d0001 [pwwn 21:00:00:20:37:6f:fd:97]

* fcid 0x6d0301 [symbolic-nodename 10.11.1.10] <-------------

FC ID resolved for
host 1

zone name iscsi-zone-2 vsan 1

* fcid 0x6d0101 [pwwn 21:00:00:20:37:6f:fe:54]

* fcid 0x6d0201 [pwwn 21:00:00:20:37:a6:a6:5d]

* fcid 0x6d0300 [symbolic-nodename iqn.1987-05.com.cisco:01.25589167f74c] <-------------------------

FC ID for host 2

Step 17blank.gif The Fibre Channel name server shows the virtual N ports created for the iSCSI hosts:

switch# show fcns database
VSAN 1:
--------------------------------------------------------------------------
FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE
--------------------------------------------------------------------------
0x6d0001 NL 21:00:00:20:37:6f:fd:97 (Seagate) scsi-fcp:target
0x6d0101 NL 21:00:00:20:37:6f:fe:54 (Seagate) scsi-fcp:target
0x6d0201 NL 21:00:00:20:37:a6:a6:5d (Seagate) scsi-fcp:target
0x6d0300 N 20:03:00:0b:fd:44:68:c2 (Cisco) scsi-fcp:init isc..w
0x6d0301 N 20:05:00:0b:fd:44:68:c2 (Cisco) scsi-fcp:init isc..w
 

Step 18blank.gif Verify the detailed output of the iSCSI initiator nodes in the Fibre Channel name server:

switch# show fcns database fcid 0x6d0300 detail vsan 1

------------------------

VSAN:1 FCID:0x6d0300

------------------------

port-wwn (vendor) :20:03:00:0b:fd:44:68:c2 (Cisco)

node-wwn :20:02:00:0b:fd:44:68:c2

class :2,3

node-ip-addr :10.15.1.11 <----------------------

ipa :ff ff ff ff ff ff ff ff

fc4-types:fc4_features:scsi-fcp:init iscsi-gw <------

symbolic-port-name :


 

IPv4 address of the iSCSI host

iSCSI gateway node

symbolic-node-name :iqn.1987-05.com.cisco:01.25589167f74c <--------------------

port-type :N

port-ip-addr :0.0.0.0

fabric-port-wwn :21:91:00:0b:fd:44:68:c0

hard-addr :0x000000

Total number of entries = 1

iSCSI initiator ID is based on the registered node name

switch# show fcns database fcid 0x6d0301 detail vsan 1

------------------------

VSAN:1 FCID:0x6d0301

------------------------

port-wwn (vendor) :20:05:00:0b:fd:44:68:c2 (Cisco)

node-wwn :20:04:00:0b:fd:44:68:c2

class :2,3

node-ip-addr :10.11.1.10

ipa :ff ff ff ff ff ff ff ff

fc4-types:fc4_features:scsi-fcp:init iscsi-gw <------

symbolic-port-name :

iSCSI gateway node

symbolic-node-name :10.11.1.10 <---------------------

port-type :N

port-ip-addr :0.0.0.0

fabric-port-wwn :21:81:00:0b:fd:44:68:c0

hard-addr :0x000000

iSCSI initiator ID is based on the IPv4 address registered in symbolic-node-name field


 

To configure scenario 1 (see Figure 4-44), follow these steps:


Step 1blank.gif Configure null authentication for all iSCSI hosts in Cisco MDS switches.

a.blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane.

b.blank.gif Select none from the AuthMethod drop-down menu in the Information pane.

c.blank.gif Click the Apply Changes icon.

Step 2blank.gif Configure iSCSI to dynamically import all Fibre Channel targets into the iSCSI SAN using auto-generated iSCSI target names.

a.blank.gif In Device Manager, click IP > iSCSI.

b.blank.gif Click the Targets tab.

c.blank.gif Check the Dynamically Import FC Targets check box.

d.blank.gif Click Apply.

Step 3blank.gif Configure the Gigabit Ethernet interface in slot 7 port 1 with an IPv4 address and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

b.blank.gif Select the IP Address tab in the Information pane and click Create Row.

c.blank.gif Set the IP address and subnet mask for the Gigabit Ethernet interface in slot 7 port 1.

d.blank.gif Click Create.

e.blank.gif Select the General tab and select up from the Admin drop-down menu for the Gigabit Ethernet interface in slot 7 port 1.

f.blank.gif Click the Apply Changes icon.

note.gif

Noteblank.gif Host 2 is connected to this port.


Step 4blank.gif Configure the iSCSI interface in slot 7 port 1 to identify all dynamic iSCSI initiators by their IP address, and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > FC Logical in the Physical Attributes pane.

b.blank.gif Click the iSCSI tab in the Information pane.

c.blank.gif Select ipaddress from the Initiator ID Mode drop-down menu and click the Apply Changes icon.

d.blank.gif In Device Manager, choose Interfaces > Ethernet and iSCSI.

e.blank.gif Click the iSCSI tab.

f.blank.gif Select up from the Admin drop-down menu for the iSCSI interface in slot 7 port 1.

g.blank.gif Click Apply.

Step 5blank.gif Configure the Gigabit Ethernet interface in slot 7 port 5 with an IPv4 address and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

b.blank.gif Click the IP Address tab in the Information pane and click Create Row.

c.blank.gif Set the IP address and subnet mask for the Gigabit Ethernet interface in slot 7 port 5.

d.blank.gif Click Create.

e.blank.gif Select the General tab and select up from the Admin drop-down menu for the Gigabit Ethernet interface in slot 7 port 5.

f.blank.gif Click the Apply Changes icon.

Step 6blank.gif Configure the iSCSI interface in slot 7 port 5 to identify all dynamic iSCSI initiators by node name and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > FC Logical in the Physical Attributes pane.

b.blank.gif Click the iSCSI tab in the Information pane.

c.blank.gif Select name from the Initiator ID Mode drop-down menu and click the Apply Changes icon.

d.blank.gif In Device Manager, choose Interfaces > Ethernet and iSCSI.

e.blank.gif Click the iSCSI tab.

f.blank.gif Select up from the Admin drop-down menu for the iSCSI interface in slot 7 port 5.

g.blank.gif Click Apply.

note.gif

Noteblank.gif Host 1 is connected to this port.


Step 7blank.gif Verify the available Fibre Channel targets.

a.blank.gif In Device Manager, Choose FC > Name Server.

b.blank.gif Click the General tab.

Step 8blank.gif Create a zone named iscsi-zone-1 with host 1 and one Fibre Channel target in it.

note.gif

Noteblank.gif Use the IP address of the host in zone membership configuration because the iSCSI interface is configured to identify all hosts based on IP address.


a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database.

b.blank.gif Select VSAN 1 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zones folder in the left navigation pane and click Insert.

d.blank.gif Set the Zone Name field to iscsi-zone-1 and click OK.

e.blank.gif Select the iscsi-zone-1 folder in the left navigation pane and click Insert.

f.blank.gif Set the ZoneBy radio button to WWN.

g.blank.gif Set the Port WWN to the pWWN for the Fibre Channel target (that is, 21:00:00:20:37:6f:fd:97) and click Add.

h.blank.gif Set the ZoneBy radio button to iSCSI IP Address/Subnet.

i.blank.gif Set the IP Address/Mask field to the IP Address for Host 1 iSCSI initiator (10.11.1.10) and click Add.

Step 9blank.gif Create a zone named iscsi-zone-2 with host 2 and two Fibre Channel targets in it.

note.gif

Noteblank.gif Use the symbolic node name of the iSCSI host in zone membership configuration because the iSCSI interface is configured to identify all hosts based on node name.


a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database from the main menu.

b.blank.gif Select VSAN 2 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zones folder in the left navigation pane and click Insert.

d.blank.gif Set the Zone Name field to iscsi-zone-2 and click OK.

e.blank.gif Select the iscsi-zone-2 folder in the left navigation pane and click Insert.

f.blank.gif Set the ZoneBy radio button to WWN.

g.blank.gif Set the Port WWN to the pWWN for one of the Fibre Channel targets (for example, 21:00:00:20:37:6f:fe:5). and click Add.

h.blank.gif Set the Port WWN to the pWWN for another of the Fibre Channel targets (for example, 21:00:00:20:37:a6:a6:5d). and click Add.

i.blank.gif Set the ZoneBy radio button to iSCSI name.

j.blank.gif Set the Port Name field to the symbolic name for host 2 (iqn.1987-05.com.cisco:01.25589167f74c) and click Add.

Step 10blank.gif Create a zone set, add the two zones as members, and activate the zone set.

note.gif

Noteblank.gif iSCSI interface is configured to identify all hosts based on node name.


a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database.

b.blank.gif Select VSAN 1 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zoneset folder in the left navigation pane and click Insert.

d.blank.gif Set the Zoneset Name to zonset-iscsi and click OK.

e.blank.gif Click on the zoneset-iscsi folder and click Insert.

f.blank.gif Set the Zone Name field to iscsi-zone-1 and click OK.

g.blank.gif Set the Zone Name field to iscsi-zone-2 and click OK.

h.blank.gif Click Activate to activate the new zone set.

i.blank.gif Click Continue Activation to finish the activation.

Step 11blank.gif Bring up the iSCSI hosts (host 1 and host 2).

Step 12blank.gif Show all the iSCSI sessions.

a.blank.gif In Device Manager, choose Interfaces > Monitor > Ethernet.

b.blank.gif Click the iSCSI connections tab to show all the iSCSI sessions.

c.blank.gif In Device Manager, choose IP > iSCSI and select the Session Initiators tab.

d.blank.gif Click Details.

Step 13blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane to verify the details of the two iSCSI initiators

Step 14blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database to view the active zone set. The iSCSI initiators' FC IDs are resolved.

 

Step 15blank.gif In Device Manager, Choose FC > Name Server. The Fibre Channel name server shows the virtual N ports created for the iSCSI hosts.

Step 16blank.gif In Device Manager, Choose FC > Name Server.

Step 17blank.gif Click the Advanced tab. Verify the detailed output of the iSCSI initiator nodes in the Fibre Channel name server.


 

Target Storage Device Requiring LUN Mapping

Sample scenario 2 assumes the following configuration (see Figure 4-45):

  • Access control is based on Fibre Channel zoning.
  • There is target-based LUN mapping or LUN masking.
  • There is no iSCSI authentication (none).
  • The iSCSI initiator is assigned to different VSANs.

Figure 4-45 iSCSI Scenario 2

 

94137.ps

To configure scenario 2 (see Figure 4-45), follow these steps:


Step 1blank.gif Configure null authentication for all iSCSI hosts:

switch(config)# iscsi authentication none
 

Step 2blank.gif Configure iSCSI to dynamically import all Fibre Channel targets into the iSCSI SAN using auto-generated iSCSI target names:

switch(config)# iscsi import target fc
 

Step 3blank.gif Configure the Gigabit Ethernet interface in slot 7 port 1 with an IPv4 address and enable the interface:

switch(config)# interface gigabitethernet 7/1
switch(config-if)# ip address 10.11.1.1 255.255.255.0
switch(config-if)# no shutdown
 

Step 4blank.gif Configure the iSCSI interface in slot 7 port 1 to identify all dynamic iSCSI initiators by their IP address and enable the interface:

switch(config)# interface iscsi 7/1
switch(config-if)# switchport initiator id ip-address
switch(config-if)# no shutdown
 

Step 5blank.gif Configure the Gigabit Ethernet interface in slot 7 port 5 with the IPv4 address and enable the interface:

switch(config)# interface gigabitethernet 7/5
switch(config-if)# ip address 10.15.1.1 255.255.255.0
switch(config-if)# no shutdown
 

Step 6blank.gif Configure the iSCSI interface in slot 7 port 5 to identify all dynamic iSCSI initiators by IP address and enable the interface:

switch(config)# interface iscsi 7/5
switch(config-if)# switchport initiator id ip-address
switch(config-if)# no shutdown
 

Step 7blank.gif Add static configuration for each iSCSI initiator:

switch(config)# iscsi initiator name iqn.1987-05.com.cisco:01.e41695d16b1a <-----Host 2
switch(config-iscsi-init)# static pWWN system-assign 1
switch(config-iscsi-init)# static nWWN system-assign
 
switch(config)# iscsi initiator ip address 10.15.1.11 <-----------------------------------Host 1
switch(config-iscsi-init)# static pwwn system-assigned 1
switch(config-iscsi-init)# vsan 2
 
note.gif

Noteblank.gif Host 1 is configured in VSAN 2.


Step 8blank.gif View the configured WWNs:

note.gif

Noteblank.gif The WWNs are assigned by the system. The initiators are members of different VSANs.


switch# show iscsi initiator configured
iSCSI Node name is iqn.1987-05.com.cisco:01.e41695d16b1a
Member of vsans: 1
Node WWN is 20:03:00:0b:fd:44:68:c2
No. of PWWN: 1
Port WWN is 20:02:00:0b:fd:44:68:c2
 
iSCSI Node name is 10.15.1.11
Member of vsans: 2
No. of PWWN: 1
Port WWN is 20:06:00:0b:fd:44:68:c2
 

Step 9blank.gif Create a zone with host 1:

switch(config)# zone name iscsi-zone-1 vsan 1
 

Step 10blank.gif Add three members to the zone named iscsi-zone-1 :

note.gif

Noteblank.gif Fibre Channel storage for zone membership for the iSCSI initiator, either the iSCSI symbolic node name or the pWWN, can be used. In this case, the pWWN is persistent.


    • The following command is based on the symbolic node name.
switch(config-zone)# member symbolic-nodename iqn.1987-05.com.cisco:01.e41695d16b1a
 
    • The following command is based on the persistent pWWN assigned to the initiator. You can obtain the pWWN from the show iscsi initiator output.
switch(config-zone)# member pwwn 20:02:00:0b:fd:44:68:c2
 

Step 11blank.gif Create a zone with host 2 and two Fibre Channel targets:

note.gif

Noteblank.gif If the host is in VSAN 2, the Fibre Channel targets and zone must also be in VSAN 2.


switch(config)# zone name iscsi-zone-2 vsan 2
 

Step 12blank.gif Activate the zone set in VSAN 2:

switch(config)# zoneset activate name iscsi-zoneset-v2 vsan 2
Zoneset activation initiated. check zone status
switch# show zoneset active vsan 2
zoneset name iscsi-zoneset-v2 vsan 2
zone name iscsi-zone-2 vsan 2
* fcid 0x750001 [pwwn 21:00:00:20:37:6f:fe:54]
* fcid 0x750101 [pwwn 21:00:00:20:37:a6:a6:5d]
pwwn 20:06:00:0b:fd:44:68:c2 <-----------------Host is not online
 

Step 13blank.gif Start the iSCSI clients on both hosts and verify that sessions come up.

Step 14blank.gif Display the iSCSI sessions to verify the Fibre Channel target and the configured WWNs.

switch# show iscsi session

Initiator iqn.1987-05.com.cisco:01.e41695d16b1a

Initiator ip addr (s): 10.11.1.10

Session #1

Discovery session, ISID 00023d000001, Status active

 

Session #2

Target iqn.1987-05.com.cisco:05.172.22.92.166.07-01.21000020376ffd97 <----

VSAN 1, ISID 00023d000001, Status active, no reservation


To Fibre Channel target

Step 15blank.gif Display the iSCSI initiator to verify the configured nWWN and pWWN:

switch# show iscsi initiator

iSCSI Node name is iqn.1987-05.com.cisco:01.e41695d16b1a

Initiator ip addr (s): 10.11.1.10

iSCSI alias name: oasis10.cisco.com

Node WWN is 20:03:00:0b:fd:44:68:c2 (configured) <----------

Member of vsans: 1

Number of Virtual n_ports: 1

The configured nWWN

Virtual Port WWN is 20:02:00:0b:fd:44:68:c2 (configured) <----

Interface iSCSI 7/1, Portal group tag: 0x300

VSAN ID 1, FCID 0x680102

The configured pWWN

Step 16blank.gif Check the Fibre Channel name server:

switch# show fcns database vsan 1

VSAN 1:

-----------------------------------------------------------------

FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE

-----------------------------------------------------------------

0x680001 NL 21:00:00:20:37:6f:fd:97 (Seagate) scsi-fcp:target

 

0x680102 N 20:02:00:0b:fd:44:68:c2 (Cisco) scsi-fcp:init iscw <---

iSCSI initiator in name server

Step 17blank.gif Verify the details of the iSCSI initiator's FC ID in the name server:

switch(config)# show fcns database fcid 0x680102 detail vsan 1

------------------------

VSAN:1 FCID:0x680102

------------------------

port-wwn (vendor) :20:02:00:0b:fd:44:68:c2 (Cisco)

node-wwn :20:03:00:0b:fd:44:68:c2

class :2,3

node-ip-addr :10.11.1.10

ipa :ff ff ff ff ff ff ff ff

fc4-types:fc4_features:scsi-fcp:init iscsi-gw

symbolic-port-name :

symbolic-node-name :iqn.1987-05.com.cisco:01.e41695d16b1a

port-type :N

port-ip-addr :0.0.0.0

fabric-port-wwn :21:81:00:0b:fd:44:68:c0

iSCSI alias name: oasis10.cisco.com

Step 18blank.gif Check the Fibre Channel name server:

switch# show fcns database vsan 1

VSAN 1:

--------------------------------------------------------------

FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE

-----------------------------------------------------------------

0x680001 NL 21:00:00:20:37:6f:fd:97 (Seagate) scsi-fcp:target

 

0x680102 N 20:02:00:0b:fd:44:68:c2 (Cisco) scsi-fcp:init isc..w <-----

iSCSI initiator in name server

Step 19blank.gif Verify the details of the iSCSI initiator's FC ID in the name server:

switch(config)# show fcns database fcid 0x680102 detail vsan 1
------------------------
VSAN:1 FCID:0x680102
------------------------
port-wwn (vendor) :20:02:00:0b:fd:44:68:c2 (Cisco)
node-wwn :20:03:00:0b:fd:44:68:c2
class :2,3
node-ip-addr :10.11.1.10
ipa :ff ff ff ff ff ff ff ff
fc4-types:fc4_features:scsi-fcp:init iscsi-gw
symbolic-port-name :
symbolic-node-name :iqn.1987-05.com.cisco:01.e41695d16b1a
port-type :N
port-ip-addr :0.0.0.0
fabric-port-wwn :21:81:00:0b:fd:44:68:c0
hard-addr :0x000000
 

Step 20blank.gif Verify that zoning has resolved the FC ID for the iSCSI client:

switch# show zoneset active vsan 1
zoneset name iscsi-zoneset-v1 vsan 1
zone name iscsi-zone-1 vsan 1
* fcid 0x680001 [pwwn 21:00:00:20:37:6f:fd:97]
* fcid 0x680102 [pwwn 20:02:00:0b:fd:44:68:c2]
 

Step 21blank.gif Verify that the second initiator is connected to the two Fibre Channel targets in VSAN 2:

switch# show iscsi session initiator 10.15.1.11

Initiator 10.15.1.11

Initiator name iqn.1987-05.com.cisco:01.25589167f74c

Session #1

Target iqn.1987-05.com.cisco:05.172.22.92.166.07-05.21000020376ffe54 <--

VSAN 2, ISID 00023d000001, Status active, no reservation

Session to first target

Session #2

Target iqn.1987-05.com.cisco:05.172.22.92.166.07-05.2100002037a6a65d <--

VSAN 2, ISID 00023d000001, Status active, no reservation

Session to second target

switch# show iscsi initiator

iSCSI Node name is 10.15.1.11 <--- Initiator ID is the IP address

iSCSI Initiator name: iqn.1987-05.com.cisco:01.25589167f74c

iSCSI alias name: oasis11.cisco.com

Node WWN is 20:04:00:0b:fd:44:68:c2 (dynamic) <------------------------

Member of vsans: 2 <--- vsan membership

Number of Virtual n_ports: 1

Dynamic WWN as static WWN not assigned

Virtual Port WWN is 20:06:00:0b:fd:44:68:c2 (configured) <---------

Interface iSCSI 7/5, Portal group tag: 0x304

VSAN ID 2, FCID 0x750200

Static pWWN for the initiator

switch# show fcns database vsan 2

VSAN 2:

--------------------------------------------------------------------------

FCID TYPE PWWN (VENDOR) FC4-TYPE:FEATURE

--------------------------------------------------------------------------

0x750001 NL 21:00:00:20:37:6f:fe:54 (Seagate) scsi-fcp:target

0x750101 NL 21:00:00:20:37:a6:a6:5d (Seagate) scsi-fcp:target

0x750200 N 20:06:00:0b:fd:44:68:c2 (Cisco) scsi-fcp:init isc..w <--

Total number of entries = 3

iSCSI initiator entry in name server

switch# show fcns database fcid 0x750200 detail vsan 2

------------------------

VSAN:2 FCID:0x750200

------------------------

port-wwn (vendor) :20:06:00:0b:fd:44:68:c2 (Cisco)

node-wwn :20:04:00:0b:fd:44:68:c2

class :2,3

node-ip-addr :10.15.1.11

ipa :ff ff ff ff ff ff ff ff

fc4-types:fc4_features:scsi-fcp:init iscsi-gw

symbolic-port-name :

symbolic-node-name :10.15.1.11

port-type :N

port-ip-addr :0.0.0.0

fabric-port-wwn :21:91:00:0b:fd:44:68:c0

hard-addr :0x000000

Total number of entries = 1

switch# show zoneset active vsan 2

zoneset name iscsi-zoneset-v2 vsan 2

zone name iscsi-zone-2 vsan 2

* fcid 0x750001 [pwwn 21:00:00:20:37:6f:fe:54]

* fcid 0x750101 [pwwn 21:00:00:20:37:a6:a6:5d]

* fcid 0x750200 [pwwn 20:06:00:0b:fd:44:68:c2] <-------------------------

FC ID resolved for iSCSI initiator


 

To configure scenario 2 (see Figure 4-45), follow these steps:


Step 1blank.gif Configure null authentication for all iSCSI hosts.

a.blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane.

b.blank.gif Select none from the AuthMethod drop-down menu in the Information pane.

c.blank.gif Click the Apply Changes icon.

Step 2blank.gif Configure iSCSI to dynamically import all Fibre Channel targets into the iSCSI SAN using auto-generated iSCSI target names.

a.blank.gif In Device Manager, click IP > iSCSI.

b.blank.gif Click the Targets tab.

c.blank.gif Check the Dynamically Import FC Targets check box.

d.blank.gif Click Apply.

Step 3blank.gif Configure the Gigabit Ethernet interface in slot 7 port 1 with an IPv4 address and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

b.blank.gif Select the IP Address tab in the Information pane and click Create Row.

c.blank.gif Set the IP address and subnet mask for the Gigabit Ethernet interface in slot 7 port 1.

d.blank.gif Click Create.

e.blank.gif Click the General tab and select up from the Admin drop-down menu for the Gigabit Ethernet interface in slot 7 port 1.

f.blank.gif Click the Apply Changes icon.

Step 4blank.gif Configure the iSCSI interface in slot 7 port 1 to identify all dynamic iSCSI initiators by their IP address and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > FC Logical in the Physical Attributes pane.

b.blank.gif Select the iSCSI tab in the Information pane.

c.blank.gif Select ipaddress from the Initiator ID Mode drop-down menu and click the Apply Changes icon.

d.blank.gif In Device Manager, choose Interfaces > Ethernet and iSCSI.

e.blank.gif Click the iSCSI tab.

f.blank.gif Select up from the Admin drop-down menu for the iSCSI interface in slot 7 port 1.

g.blank.gif Click Apply.

Step 5blank.gif Configure the Gigabit Ethernet interface in slot 7 port 5 with the IPv4 address and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

b.blank.gif Click the IP Address tab in the Information pane and click Create Row.

c.blank.gif Set the IP address and subnet mask for the Gigabit Ethernet interface in slot 7 port 5.

d.blank.gif Click Create.

e.blank.gif Select the General tab and select up from the Admin drop-down menu for the Gigabit Ethernet interface in slot 7 port 5.

f.blank.gif Click the Apply Changes icon.

Step 6blank.gif Configure the iSCSI interface in slot 7 port 5 to identify all dynamic iSCSI initiators by IP address and enable the interface.

a.blank.gif In Fabric Manager, choose Switches > Interfaces > FC Logical in the Physical Attributes pane.

b.blank.gif Click the iSCSI tab in the Information pane.

c.blank.gif Select ipaddress from the Initiator ID Mode drop-down menu and click the Apply Changes icon.

d.blank.gif In Device Manager, choose Interfaces > Ethernet and iSCSI.

e.blank.gif Click the iSCSI tab.

f.blank.gif Select up from the Admin drop-down menu for the iSCSI interface in slot 7 port 5.

g.blank.gif Click Apply.

Step 7blank.gif Configure for static pWWN and nWWN for host 1.

a.blank.gif In Device Manager, choose IP > iSCSI.

b.blank.gif Click the Initiators tab.

c.blank.gif Check the Node Address Persistent and Node Address System-assigned check boxes the Host 1 iSCSI initiator.

d.blank.gif Click Apply.

Step 8blank.gif Configure for static pWWN for Host 2.

a.blank.gif In Device Manager, Choose IP > iSCSI.

b.blank.gif Click the Initiators tab.

c.blank.gif Right-click on the Host 2 iSCSI initiator and click Edit pWWN.

d.blank.gif Select 1 from the System-assigned Num field and click Apply.

Step 9blank.gif View the configured WWNs.

note.gif

Noteblank.gif The WWNs are assigned by the system. The initiators are members of different VSANs.


a.blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane.

b.blank.gif Click the Initiators tab.

Step 10blank.gif Create a zone for Host 1 and the iSCSI target in VSAN 1.

note.gif

Noteblank.gif Use the IP address of the host in zone membership configuration because the iSCSI interface is configured to identify all hosts based on IP address.


a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database.

b.blank.gif Select VSAN 1 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zones folder in the left navigation pane and click Insert.

d.blank.gif Set the Zone Name field to iscsi-zone-1 and click OK.

e.blank.gif Select the iscsi-zone-1 folder in the left navigation pane and click Insert.

f.blank.gif Set the ZoneBy radio button to WWN.

g.blank.gif Set the Port WWN to the pWWN for the Fibre Channel target (that is, 21:00:00:20:37:6f:fd:97). and click Add.

h.blank.gif Set the ZoneBy radio button to iSCSI IP Address/Subnet.

i.blank.gif Set the IP Address/Mask field to the IP Address for Host 1 iSCSI initiator (10.11.1.10) and click Add.

note.gif

Noteblank.gif Fibre Channel storage for zone membership for the iSCSI initiator, either the iSCSI symbolic node name or the pWWN, can be used. In this case, the pWWN is persistent.


Step 11blank.gif Create a zone set in VSAN 1 and activate it.

a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database.

b.blank.gif Select VSAN 1 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zoneset folder in the left navigation pane and click Insert.

d.blank.gif Set the Zoneset Name to zonset-iscsi-1 and click OK.

e.blank.gif Click on the zoneset-iscsi-1 folder and click Insert.

f.blank.gif Set the Zone Name field to iscsi-zone-1 and click OK.

g.blank.gif Click Activate to activate the new zone set.

h.blank.gif Click Continue Activation to finish the activation.

Step 12blank.gif Create a zone with host 2 and two Fibre Channel targets.

note.gif

Noteblank.gif If the host is in VSAN 2, the Fibre Channel targets and zone must also be in VSAN 2.


note.gif

Noteblank.gif iSCSI interface is configured to identify all hosts based on node name.


a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database.

b.blank.gif Select VSAN 2 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zones folder in the left navigation pane and click Insert.

d.blank.gif Set the Zone Name field to iscsi-zone-2 and click OK.

e.blank.gif Select the iscsi-zone-2 folder in the left navigation pane and click Insert.

f.blank.gif Set the ZoneBy radio button to WWN.

g.blank.gif Set the Port WWN to the pWWN for one of the Fibre Channel targets (for example, 21:00:00:20:37:6f:fe:5) and click Add.

h.blank.gif Set the Port WWN to the pWWN for another of the Fibre Channel targets (for example, 21:00:00:20:37:a6:a6:5d) and click Add.

i.blank.gif Set the ZoneBy radio button to iSCSI IP Address/Subnet.

j.blank.gif Set the IP Address/Mask field to the IP Address for Host 2 iSCSI initiator (10.15.1.11) and click Add.

Step 13blank.gif Create a zone set in VSAN 2 and activate it.

a.blank.gif In Fabric Manager, choose Zones > Edit Local Full Zone Database.

b.blank.gif Select VSAN 2 from the VSAN drop-down menu in the Edit Local Full Zone Database dialog box.

c.blank.gif Select the Zoneset folder in the left navigation pane and click Insert.

d.blank.gif Set the Zoneset Name to zonset-iscsi-2 and click OK.

e.blank.gif Click on the zoneset-iscsi-2 folder and click Insert.

f.blank.gif Set the Zone Name field to iscsi-zone-2 and click OK.

g.blank.gif Click Activate to activate the new zone set.

h.blank.gif Click Continue Activation to finish the activation.

Step 14blank.gif Start the iSCSI clients on both hosts.

Step 15blank.gif Show all the iSCSI sessions.

a.blank.gif In Device Manager, choose Interface > Monitor > Ethernet and select the iSCSI connections tab to show all the iSCSI sessions.

b.blank.gif In Device Manager, choose IP > iSCSI and select the Session Initiators tab.

c.blank.gif Click Details.

Step 16blank.gif In Fabric Manager, choose End Devices > iSCSI in the Physical Attributes pane to verify the details of the two iSCSI initiators.

Step 17blank.gif In Fabric Manager, choose Zones > E dit Local Full Zone Database to view the active zone set. The iSCSI initiators' FC IDs are resolved.

 

Step 18blank.gif In Device Manager, choose FC > Name Server. The Fibre Channel name server shows the virtual N ports created for the iSCSI hosts.

Step 19blank.gif In Device Manager, Choose FC > Name Server.

Step 20blank.gif Click the Advanced tab. Verify the detailed output of the iSCSI initiator nodes in the Fibre Channel name server.


 

Overview of Internet Storage Name Service

Internet Storage Name Service (iSNS) allows your existing TCP/IP network to function more effectively as a SAN by automating the discovery, management, and configuration of iSCSI devices. To facilitate these functions, the iSNS server and client function as follows:

  • The iSNS client registers iSCSI portals and all iSCSI devices accessible through them with an iSNS server.
  • The iSNS server provides the following services for the iSNS client:

blank.gif Device registration

blank.gif State change notification

blank.gif Remote domain discovery services

All iSCSI devices (both initiator and target) acting as iSNS clients, can register with an iSNS server. iSCSI initiators can then query the iSNS server for a list of targets. The iSNS server will respond with a list of targets that the querying client can access based on configured access control parameters.

A Cisco MDS 9000 Family switch can act as an iSNS client and register all available iSCSI targets with an external iSNS server. All switches in the Cisco MDS 9000 Family with Fibre Channel module with IPS ports or MPS-14/2 modules installed support iSNS server functionality. This allows external iSNS clients, such as an iSCSI initiator, to register with the switch and discover all available iSCSI targets in the SAN.

This section includes the following topics:

Overview of iSNS Client Functionality

Internet Storage Name Service (iSNS) allows your existing TCP/IP network to function more effectively as a SAN by automating the discovery, management, and configuration of iSCSI devices. The iSNS client registers iSCSI portals and all iSCSI devices accessible through them with an iSNS server. All iSCSI devices (both initiator and target) acting as iSNS clients can register with an iSNS server. When the iSNS client is unable to register or deregister objects with the iSNS server (for example, the client is unable to make a TCP connection to the iSNS server), it retries every minute to reregister all iSNS objects for the affected interfaces with the iSNS server.

The iSNS client functionality on each IPS interface (Gigabit Ethernet interface or subinterface or port channel) registers information with an iSNS server.

Once a profile is tagged to an interface, the switch opens a TCP connection to the iSNS server IP address (using the well-known iSNS port number 3205) in the profile and registers network entity and portal objects; a unique entity is associated with each IPS interface. The switch then searches the Fibre Channel name server (FCNS) database and switch configuration to find storage nodes to register with the iSNS server.

Statically mapped virtual targets are registered if the associated Fibre Channel pWWN is present in the FCNS database and no access control configuration prevents it. A dynamically mapped target is registered if dynamic target importing is enabled. See the “Presenting Fibre Channel Targets as iSCSI Targets” section for more details on how iSCSI imports Fibre Channel targets.

A storage node is deregistered from the iSNS server when it becomes unavailable when a configuration changes (such as access control change or dynamic import disabling) or the Fibre Channel storage port goes offline. It is registered again when the node comes back online.

When the iSNS client is unable to register or deregister objects with the iSNS server (for example, the client is unable to make a TCP connection to the iSNS server), it retries every minute to reregister all iSNS objects for the affected interfaces with the iSNS server. The iSNS client uses a registration interval value of 15 minutes. If the client fails to refresh the registration during this interval, the server will deregister the entries.

Untagging a profile also causes the network entity and portal to be deregistered from that interface.

note.gif

Noteblank.gif The iSNS client is not supported on a VRRP interface.


Creating an iSNS Client Profile

To create an iSNS profile, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# isns profile name MyIsns

switch(config-isns-profile)#

Creates a profile called MyIsns.

Step 3

switch(config-isns-profile)# server 10.10.100.211

Specifies an iSNS server IPv4 address for this profile.

Step 4

switch(config-isns-profile)# no server 10.10.100.211

Removes a configured iSNS server from this profile.

Step 5

switch(config-isns-profile)# server 2003::11

 

Specifies an iSNS server IPv6 address for this profile.

Step 6

switch(config-isns-profile)# no server 10.20.100.211

Removes a configured iSNS server from this profile.

To create an iSNS profile using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI in the Physical Attributes pane.

You see the iSCSI configuration in the Information pane (see Figure 4-12).

Step 2blank.gif Select the iSNS tab.

Step 3blank.gif You see the iSNS profiles configured (see Figure 4-46).

Figure 4-46 iSNS Profiles in Fabric Manager

 

184003.tif

Step 4blank.gif Click the Create Row icon.

You see the Create iSNS Profiles dialog box.

Step 5blank.gif Set the ProfileName field to the iSNS profile name that you want to create.

Step 6blank.gif Set the ProfileAddr field to the IP address of the iSNS server.

Step 7blank.gif Click Create to save these changes.


 

To remove an iSNS profile, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# no isns profile name OldIsns

Removes a configured iSNS profile called OldIsns.

To delete an iSNS profile using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSCSI from the Physical Attributes pane.

You see the iSCSI configuration in the Information pane (see Figure 4-12).

Step 2blank.gif Select the iSNS tab.

You see the iSNS profiles configured (see Figure 4-46).

Step 3blank.gif Right-click on the profile that you want to delete and click the Delete Row icon.


 

To tag a profile to an interface, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# interface gigabitethernet 4/1

switch(config-if)#

Configures the specified Gigabit Ethernet interface.

Step 3

switch(config-if)# isns MyIsns

Tags a profile to an interface.

To tag a profile to an interface using Fabric Manager, follow these steps:


Step 1blank.gif Choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

You see the Gigabit Ethernet configuration in the Information pane.

Step 2blank.gif Click the iSNS tab.

You see the iSNS profiles configured for these interfaces (see Figure 4-47).

Figure 4-47 iSNS Profiles in Fabric Manager

 

184002.tif

Step 3blank.gif Set the iSNS ProfileName field to the iSNS profile name that you want to add to this interface.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

To untag a profile from an interface, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# interface gigabitethernet 5/1

switch(config-if)#

Configures the specified Gigabit Ethernet interface.

Step 3

switch(config-if)# no isns OldIsns

Untags a profile from an interface.

Use the isns reregister command in EXEC mode to reregister associated iSNS objects with the iSNS server.

switch# isns reregister gigabitethernet 1/4
switch# isns reregister port-channel 1
 

To untag a profile from an interface using Fabric Manager, follow these steps:


Step 1blank.gif Choose Switches > Interfaces > Gigabit Ethernet in the Physical Attributes pane.

You see the Gigabit Ethernet Configuration in the Information pane.

Step 2blank.gif Click the iSNS tab.

You see the iSNS profiles configured for these interfaces (see Figure 4-47).

Step 3blank.gif Right-click the iSNS ProfileName field that you want to untag and delete the text in that field.

Step 4blank.gif Click the Apply Changes icon to save these changes.


 

Verifying iSNS Client Configuration

Use the show isns profile command to view configured iSNS profiles. Profile ABC has two portals registered with the iSNS server. Each portal corresponds to a particular interface. Profile XYZ has a specified iSNS server, but does not have any tagged interfaces configured (see Example 4-19 and Example 4-20).

Example 4-19 Displaying Information for Configured iSNS Profiles

switch# show isns profile
iSNS profile name ABC
tagged interface GigabitEthernet2/3
tagged interface GigabitEthernet2/2
iSNS Server 10.10.100.204
 
iSNS profile name XYZ
iSNS Server 10.10.100.211
 

Example 4-20 Displaying a Specified iSNS Profile

switch# show isns profile ABC
iSNS profile name ABC
tagged interface GigabitEthernet2/3
tagged interface GigabitEthernet2/2
iSNS Server 10.10.100.204
 

Use the show isns profile counters command to view all configured profiles with the iSNS PDU statistics for each tagged interface (see Example 4-21 and Example 4-22).

Example 4-21 Displaying Configured Profiles with iSNS Statistics

switch# show isns profile counters
iSNS profile name ABC
tagged interface port-channel 1
iSNS statistics
Input 54 pdus (registration/deregistration pdus only)
Reg pdus 37, Dereg pdus 17
Output 54 pdus (registration/deregistration pdus only)
Reg pdus 37, Dereg pdus 17
iSNS Server 10.10.100.204
 
iSNS profile name XYZ
tagged interface port-channel 2
iSNS statistics
Input 30 pdus (registration/deregistration pdus only)
Reg pdus 29, Dereg pdus 1
Output 30 pdus (registration/deregistration pdus only)
Reg pdus 29, Dereg pdus 1
iSNS Server 10.1.4.218
 

Example 4-22 Displaying iSNS Statistics for a Specified Profile

switch# show isns profile ABC counters
iSNS profile name ABC
tagged interface port-channel 1
iSNS statistics
Input 54 pdus (registration/deregistration pdus only)
Reg pdus 37, Dereg pdus 17
Output 54 pdus (registration/deregistration pdus only)
Reg pdus 37, Dereg pdus 17
iSNS Server 10.10.100.204
 

Use the show isns command to view all objects registered on the iSNS server and specified in the given profile (see Example 4-23).

Example 4-23 Displaying iSNS Queries

switch# show isns query ABC gigabitethernet 2/3
iSNS server: 10.10.100.204
Init: iqn.1991-05.com.w2k
Alias: <MS SW iSCSI Initiator>
Tgt : iqn.1987-05.com.cisco:05.172.22.94.22.02-03
Tgt : iqn.1987-05.com.cisco:05.172.22.94.22.02-03.210000203762fa34
nWWN: 200000203762fa34
 

Use the show interface command to view the iSNS profile to which an interface is tagged (see Example 4-24).

Example 4-24 Displaying Tagged iSNS Interfaces

switch# show interface gigabitethernet 2/3
GigabitEthernet2/3 is up
Hardware is GigabitEthernet, address is 0005.3000.ae94
Internet address is 10.10.100.201/24
MTU 1500 bytes
Port mode is IPS
Speed is 1 Gbps
Beacon is turned off
Auto-Negotiation is turned on
iSNS profile ABC
^^^^^^^^^^^^^^^^
5 minutes input rate 112 bits/sec, 14 bytes/sec, 0 frames/sec
5 minutes output rate 0 bits/sec, 0 bytes/sec, 0 frames/sec
1935 packets input, 132567 bytes
4 multicast frames, 0 compressed
0 input errors, 0 frame, 0 overrun 0 fifo
1 packets output, 42 bytes, 0 underruns
0 output errors, 0 collisions, 0 fifo
0 carrier errors
 

iSNS Server Functionality

When enabled, the iSNS server on the Cisco 9000 Family MDS switch tracks all registered iSCSI devices. As a result, iSNS clients can locate other iSNS clients by querying the iSNS server. The iSNS server also provides the following functionalities:

  • Allows iSNS clients to register, deregister, and query other iSNS clients registered with the iSNS server.
  • Provides centralized management for enforcing access control to provide or deny access to targets from specific initiators.
  • Provides a notification mechanism for registered iSNS clients to receive change notifications on the status change of other iSNS clients.
  • Provides a single access control configuration for both Fibre Channel and iSCSI devices.
  • Discovers iSCSI targets that do not have direct IP connectivity to the iSCSI initiators.

Sample Scenario

The iSNS server provides uniform access control across Fibre Channel and iSCSI devices by utilizing both Fibre Channel zoning information and iSCSI access control information and configuration. An iSCSI initiator acting as an iSNS client only discovers devices it is allowed to access based on both sets of access control information. Figure 4-48 provides an example of this scenario.

Figure 4-48 Using iSNS Servers in the Cisco MDS Environment

 

130914.ps

In Figure 4-48, iqn.host1 and iqn.host2 are iSCSI initiators. P1 and P2 are Fibre Channel targets. The two initiators are in different zones: Zone 1 consists of iqn.host1 and target P1, and Zone 2 consists of iqn.host2 and target P2. iSNS server functionality is enabled on both switches, SW-1 and SW-2. The registration process proceeds as follows:

1.blank.gif Initiator iqn.host1 registers with SW-1, port Gigabitethernet2/1.

2.blank.gif Initiator iqn.host2 registers with SW-2, port Gigabitethernet3/1.

3.blank.gif Initiator iqn.host1 issues an iSNS query to SW-1 to determine all accessible targets.

4.blank.gif The iSNS server in turn queries the Fibre Channel name server (FCNS) to obtain a list of devices that are accessible (that is, in the same zone) by the query originator. This query yields only P1.

5.blank.gif The iSNS server then queries its own database to convert the Fibre Channel devices to the corresponding iSCSI targets. This is based on the iSCSI configuration, such as virtual-target and its access control setting or whether the dynamic Fibre Channel target import feature is enabled or disabled.

6.blank.gif The iSNS server sends a response back to the query initiator. This response contains a list all iSCSI portals known to the iSNS server. This means iqn.host1 can choose to log in to target P1 through either SW-1 (at Gigabitethernet 2/1) or SW-2 (at Gigabitethernet 3/1).

7.blank.gif If the initiator chooses to log in to SW-1 and later that port becomes inaccessible (for example, Gigabitethernet 2/1 goes down), the initiator has the choice to move to connect to target P1 through port Gigabitethernet 3/1 on SW-2 instead.

8.blank.gif If the target either goes down or is removed from the zone, the iSNS server sends out an iSNS State Change Notification (SCN) message to the initiator so that the initiator can remove the session.

Configuring an iSNS Server

This section describe how to configure an iSNS server on a Cisco MDS 9000 Family switch.

This section includes the following topics:

Enabling an iSNS Server

Before the iSNS server feature can be enabled, iSCSI must be enabled (see the “Enabling iSCSI” section). When you disable iSCSI, iSNS is automatically disabled. When the iSNS server is enabled on a switch, every IPS port whose corresponding iSCSI interface is up is capable of servicing iSNS registration and query requests from external iSNS clients.

To enable the iSNS server, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# isns-server enable

Enables the iSNS server.

switch(config)# no isns-server enable

Disables (default) the iSNS server.

To enable the iSNS server using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the Control tab and select enable from the Command drop-down menu for the iSNS server feature.

Step 3blank.gif Click the Apply Changes icon to save this change.


 

note.gif

Noteblank.gif If you are using VRRP IPv4 addresses for discovering targets from iSNS clients, ensure that the IP address is created using the secondary option (see “Adding Virtual Router IP Addresses” section).


iSNS Configuration Distribution

You can use the CFS infrastructure to distribute the iSCSI initiator configuration to iSNS servers across the fabric. This allows the iSNS server running on any switch to provide a querying iSNS client a list of iSCSI devices available anywhere on the fabric. For information on CFS, see the Cisco Fabric Manager System Management Configuration Guide and Cisco MDS 9000 Family NX-OS System Management Configuration Guide.

To enable iSNS configuration distribution using, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# isns distribute

Uses the CFS infrastructure to distribute the iSCSI virtual target configuration to all switches in the fabric.

switch(config)# no isns distribute

Stops (default) the distribution of iSCSI virtual target configuration to all switches in the fabric.

To enable iSNS configuration distribution using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the CFS tab and select enable from the Admin drop-down menu for iSNS.

Step 3blank.gif Select enable from the Global drop-down menu for iSNS.

Step 4blank.gif Click the Apply Changes icon to save this change.


 

Configuring the ESI Retry Count

The iSNS client registers information with its configured iSNS server using an iSNS profile. At registration, the client can indicate an entity status inquiry (ESI) interval of 60 seconds or more. If the client registers with an ESI interval set to zero (0), then the server does not monitor the client using ESI. In such cases, the client’s registrations remain valid until explicitly deregistered or the iSNS server feature is disabled.

The ESI retry count is the number of times the iSNS server queries iSNS clients for their entity status. The default ESI retry count is 3. The client sends the server a response to indicate that it is still alive. If the client fails to respond after the configured number of retries, the client is deregistered from the server.

To configure the ESI retry count for an iSNS server, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# isns esi retries 6

Configures the ESI to retry contacting the client up to 6 times. The range is 1 to 10.

switch(config)# no isns esi retries 6

Reverts to the default value of 3 retries.

Configuring a Registration Period

The iSNS client specifies the registration period with the iSNS Server. The iSNS Server keeps the registration active until the end of this period. If there are no commands from the iSNS client during this period, then the iSNS server removes the client registration from its database.

If the iSNS client does not specify a registration period, the iSNS server assumes a default value of 0, which keeps the registration active indefinitely. You can also manually configure the registration period on the MDS iSNS Server.

To configure the registration period on an iSNS Server, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# isns registration period 300

Configures the registration to be active for 300 seconds. The permissible registration period is between 0 to 65536 seconds.

switch(config)# no isns registration period

Reverts to the client registered timeout value, or the default value of 0.

To configure the registration period on an iSNS Server using Fabric Manager, follow these steps:


Step 1blank.gif Choose E nd Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the Servers tab.

You see the configured iSNS servers.

Step 3blank.gif Set the ESI NonResponse Threshold field to the ESI retry count value.

Step 4blank.gif Click the Apply Changes icon to save this change.


 

iSNS Client Registration and Deregistration

You can use the show isns database command to display all registered iSNS clients and their associated configuration.

An iSNS client cannot query the iSNS server until it has registered. iSNS client deregistration can occur either explicitly or when the iSNS server detects that it can no longer reach the client (through ESI monitoring).

iSNS client registration and deregistration result in status change notifications (SCNs) being generated to all interested iSNS clients.

Target Discovery

iSCSI initiators discover targets by issuing queries to the iSNS server. The server supports DevGetNext requests to search the list of targets and DevAttrQuery to determine target and portal details, such as the IP address or port number to which to connect.

On receiving a query request from the iSCSI client, the iSNS server queries the Fibre Channel Name Server (FCNS) to obtain a list of Fibre Channel targets that are accessible by the querying initiator. The result of this query depends on zoning configuration currently active and current configuration(s) of the initiator. The iSNS server will subsequently use the iSCSI target configuration(s) (virtual target and dynamic import configuration) to translate the Fibre Channel target to an equivalent iSCSI target. At this stage it also applies any access control configured for the virtual target. A response message with the target details is then sent back to the query initiator.

The iSNS server sends a consolidated response containing all possible targets and portals to the querying initiator. For example, if a Fibre Channel target is exported as different iSCSI targets on different IPS interfaces, the iSNS server will respond with a list of all possible iSCSI targets and portals.

In order to keep the list of targets updated, the iSNS server sends state change notifications (SCN) to the client whenever an iSCSI target becomes reachable or unreachable. The client is then expected to rediscover its list of accessible targets by initiating another iSNS query. Reachability of iSCSI targets changes when any one of the following occurs:

  • Target goes up or down.
  • Dynamic import of FC target configuration changes.
  • Zone set changes.
  • Default zone access control changes.
  • IPS interface state changes.
  • Initiator configuration change makes the target accessible or inaccessible.

Verifying the iSNS Server Configuration

Use the show isns config command to view the ESI interval and the summary information about the iSNS database contents (see Example 4-25).

Example 4-25 Displaying the iSNS Server Configuration of ESI Interval and Database Contents

switch# show isns config
Server Name: switch1(Cisco Systems) Up since: Fri Jul 30 04:08:16 2004
Index: 1 Version: 1 TCP Port: 3205
fabric distribute (remote sync): ON
ESI
Non Response Threshold: 5 Interval(seconds): 60
Database contents
Number of Entities: 2
Number of Portals: 3
Number of ISCSI devices: 4
Number of Portal Groups: 0
 

Use the show isns database command to view detailed information about the contents of the iSNS database (see Example 4-26 through Example 4-29). This command displays the full iSNS database giving all the entities, nodes, and portals registered in the database. This command without options only displays explicitly registered objects. The asterisk next to the VSAN ID indicates that the iSCSI node is in the default zone for that VSAN.

Example 4-26 Displaying Explicitly Registered Objects

switch# show isns database
Entity Id: dp-204
Index: 2 Last accessed: Fri Jul 30 04:08:46 2004
 
iSCSI Node Name: iqn.1991-05.comdp-2041
Entity Index: 2
Node Type: Initiator(2) Node Index: 0x1
SCN Bitmap: OBJ_UPDATED|OBJ ADDED|OBJ REMOVED|TARGET&SELF
Node Alias: <MS SW iSCSI Initiator>
 
VSANS: 1(*), 5(*)
Portal IP Address: 192.168.100.2 TCP Port: 4179
Entity Index: 2 Portal Index: 1
ESI Interval: 0 ESI Port: 4180 SCN Port: 4180

Example 4-27 Displaying the Full Database with Both Registered and Configured Nodes and Portals

switch# show isns database full
Entity Id: isns.entity.mds9000
Index: 1 Last accessed: Fri Jul 30 04:08:16 2004
 
iSCSI Node Name: iqn.com.cisco.disk1
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000001
WWN(s):
22:00:00:20:37:39:dc:45
VSANS:
iSCSI Node Name: iqn.isns-first-virtual-target
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000002
 
VSANS:
iSCSI Node Name: iqn.com.cisco.disk2
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000003
WWN(s):
22:00:00:20:37:39:dc:45
 
VSANS:
Portal IP Address: 192.168.100.5 TCP Port: 3205
Entity Index: 1 Portal Index: 3
 
Portal IP Address: 192.168.100.6 TCP Port: 3205
Entity Index: 1 Portal Index: 5
 
Entity Id: dp-204
Index: 2 Last accessed: Fri Jul 30 04:08:46 2004
 
iSCSI Node Name: iqn.1991-05.com.microsoft:dp-2041
Entity Index: 2
Node Type: Initiator(2) Node Index: 0x1
SCN Bitmap: OBJ_UPDATED|OBJ ADDED|OBJ REMOVED|TARGET&SELF
Node Alias: <MS SW iSCSI Initiator>
 
VSANS: 1(*), 5(*)
Portal IP Address: 192.168.100.2 TCP Port: 4179
Entity Index: 2 Portal Index: 1
ESI Interval: 0 ESI Port: 4180 SCN Port: 4180
 
note.gif

Noteblank.gif The local option is only available for virtual targets.


Example 4-28 Displaying the Virtual Target Information in a Local Switch

switch# show isns database virtual-targets local
Entity Id: isns.entity.mds9000
Index: 1 Last accessed: Fri Jul 30 04:08:16 2004
 
iSCSI Node Name: iqn.com.cisco.disk1
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000001
WWN(s):
22:00:00:20:37:39:dc:45
 
VSANS:
iSCSI Node Name: iqn.isns-first-virtual-target
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000002
 
VSANS:
iSCSI Node Name: iqn.com.cisco.disk2
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000003
WWN(s):
22:00:00:20:37:39:dc:45
 
VSANS:
Portal IP Address: 192.168.100.5 TCP Port: 3205
Entity Index: 1 Portal Index: 3
 
Portal IP Address: 192.168.100.6 TCP Port: 3205
Entity Index: 1 Portal Index: 5

Example 4-29 Displaying Virtual Target for a Specified Switch

switch# show isns database virtual-targets switch 20:00:00:0d:ec:01:04:40
Entity Id: isns.entity.mds9000
Index: 1 Last accessed: Fri Jul 30 04:08:16 2004
 
iSCSI Node Name: iqn.com.cisco.disk1
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000001
WWN(s):
22:00:00:20:37:39:dc:45
 
VSANS:
iSCSI Node Name: iqn.isns-first-virtual-target
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000002
 
VSANS:
iSCSI Node Name: iqn.com.cisco.disk2
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000003
WWN(s):
22:00:00:20:37:39:dc:45
 
VSANS:
Portal IP Address: 192.168.100.5 TCP Port: 3205
Entity Index: 1 Portal Index: 3
 
Portal IP Address: 192.168.100.6 TCP Port: 3205
Entity Index: 1 Portal Index: 5
 

Use the show isns node command to display attributes of nodes registered with the iSNS server (see Example 4-30 through Example 4-32). If you do not specify any options, the server displays the name and node type attribute in a compact format; one per line.

Example 4-30 Displaying Explicitly Registered Objects

switch# show isns node all
-------------------------------------------------------------------------------
iSCSI Node Name Type
-------------------------------------------------------------------------------
iqn.1987-05.com.cisco:05.switch1.02-03.22000020375a6c8 Target
...
iqn.com.cisco.disk1 Target
iqn.com.cisco.ipdisk Target
iqn.isns-first-virtual-target Target
iqn.1991-05.cw22 Target
iqn.1991-05.cw53 Target
 

Example 4-31 Displaying the Specified Node

switch# show isns node name iqn.com.cisco.disk1
iSCSI Node Name: iqn.com.cisco.disk1
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000001
WWN(s):
22:00:00:20:37:39:dc:45
VSANS: 1
 

Example 4-32 Displaying the Attribute Details for All Nodes

switch# show isns node all detail
iSCSI Node Name: iqn.1987-05.com.cisco:05.switch1.02-03.22000020375a6c8f
Entity Index: 1
Node Type: Target(1) Node Index: 0x3000003
Configured Switch WWN: 20:00:00:0d:ec:01:04:40
WWN(s):
22:00:00:20:37:5a:6c:8f
VSANS: 1
...
iSCSI Node Name: iqn.com.cisco.disk1
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000001
Configured Switch WWN: 20:00:00:0d:ec:01:04:40
WWN(s):
22:00:00:20:37:39:dc:45
VSANS: 1
 
iSCSI Node Name: iqn.com.cisco.ipdisk
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000002
Configured Switch WWN: 20:00:00:0d:ec:01:04:40
WWN(s):
22:00:00:20:37:5a:70:1a
VSANS: 1
 
iSCSI Node Name: iqn.isns-first-virtual-target
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000003
Configured Switch WWN: 20:00:00:0d:ec:01:04:40
 
iSCSI Node Name: iqn.parna.121212
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000004
Configured Switch WWN: 20:00:00:0d:ec:01:04:40
 
iSCSI Node Name: iqn.parna.121213
Entity Index: 1
Node Type: Target(1) Node Index: 0x80000005
Configured Switch WWN: 20:00:00:0d:ec:01:04:40
 

Use the show isns portal command to display the attributes of a portal along with its accessible nodes (see Example 4-33 through Example 4-37). You can specify portals by using the switch WWN-interface combination or the IP address-port number combination.

Example 4-33 Displaying the Attribute Information for All Portals

switch# show isns portal all
-------------------------------------------------------------------------------
IPAddress TCP Port Index SCN Port ESI port
-------------------------------------------------------------------------------
192.168.100.5 3205 3 - -
192.168.100.6 3205 5 - -
 

Example 4-34 Displaying Detailed Attribute Information for All Portals

switch# show isns portal all detail
Portal IP Address: 192.168.100.5 TCP Port: 3205
Entity Index: 1 Portal Index: 3
 
Portal IP Address: 192.168.100.6 TCP Port: 3205
Entity Index: 1 Portal Index: 5
 

Example 4-35 Displaying Virtual Portals

switch# show isns portal virtual
-------------------------------------------------------------------------------
IPAddress TCP Port Index SCN Port ESI port
-------------------------------------------------------------------------------
192.168.100.5 3205 3 - -
192.168.100.6 3205 5 - -
 

Example 4-36 Displaying Virtual Portals for a Specified Switch

switch# show isns portal virtual switch 20:00:00:0d:ec:01:04:40
-------------------------------------------------------------------------------
IPAddress TCP Port Index SCN Port ESI port
-------------------------------------------------------------------------------
192.168.100.5 3205 3 - -
192.168.100.6 3205 5 - -
 

Example 4-37 Displaying Detailed Information for the Virtual Portals in a Specified Switch

switch# show isns portal virtual switch 20:00:00:0d:ec:01:04:40 detail
Portal IP Address: 192.168.100.5 TCP Port: 3205
Entity Index: 1 Portal Index: 3
Switch WWN: 20:00:00:0d:ec:01:04:40
Interface: GigabitEthernet2/3
 
Portal IP Address: 192.168.100.6 TCP Port: 3205
Entity Index: 1 Portal Index: 5
Switch WWN: 20:00:00:0d:ec:01:04:40
Interface: GigabitEthernet2/5
 

Use the show isns entity command to display the attributes of an entity along with the list of portals and nodes in that entity (see Example 4-38 through Example 4-42). If you do not specify any option, this command displays the entity ID and number of nodes or portals associated with the entity in a compact format; one per line.

Example 4-38 Displaying All Registered Entries

switch1# show isns entity
-------------------------------------------------------------------------------
Entity ID Last Accessed
-------------------------------------------------------------------------------
dp-204 Tue Sep 7 23:15:42 2004
 

Example 4-39 Displaying All Entities in the Database

switch# show isns entity all
 
-------------------------------------------------------------------------------
Entity ID Last Accessed
-------------------------------------------------------------------------------
isns.entity.mds9000 Tue Sep 7 21:33:23 2004
 
dp-204 Tue Sep 7 23:15:42 2004
 

Example 4-40 Displaying the Entity with a Specified ID

switch1# show isns entity id dp-204
Entity Id: dp-204
Index: 2 Last accessed: Tue Sep 7 23:15:42 2004
 

Example 4-41 Displaying Detailed Information for All Entities in the Database

switch1# show isns entity all detail
Entity Id: isns.entity.mds9000
Index: 1 Last accessed: Tue Sep 7 21:33:23 2004
 
Entity Id: dp-204
Index: 2 Last accessed: Tue Sep 7 23:16:34 2004
 

Example 4-42 Displaying Virtual Entities

switch# show isns entity virtual
Entity Id: isns.entity.mds9000
Index: 1 Last accessed: Thu Aug 5 00:58:50 2004
 
Entity Id: dp-204
Index: 2 Last accessed: Thu Aug 5 01:00:23 2004
 

Use the show iscsi global config command to display information about import targets (see Example 4-43 and Example 4-44).

Example 4-43 Displaying the Import Target Settings for a Specified Switch

switch# show isns iscsi global config switch 20:00:00:05:ec:01:04:00
iSCSI Global configuration:
Switch: 20:00:00:05:ec:01:04:00 iSCSI Auto Import: Enabled
 

Example 4-44 Displaying the Import Target Settings for All Switches

switch# show isns iscsi global config all
iSCSI Global configuration:
Switch: 20:00:44:0d:ec:01:02:40 iSCSI Auto Import: Enabled
 

Use the show cfs peers command to display CFS peers switch information about the iSNS application (see Example 4-45).

Example 4-45 Displaying the CFS Peer Switch Information for the iSNS Application

switch# show cfs peers name isns
 
Scope : Physical
--------------------------------------------------
Switch WWN IP Address
--------------------------------------------------
20:00:00:00:ec:01:00:40 10.10.100.11 [Local]
 
Total number of entries = 1
 

iSNS Cloud Discovery

You can configure iSNS cloud discovery to automate the process of discovering iSNS servers in the IP network.

This section includes the following topics:

Cloud Discovery

When an iSNS server receives a query request, it responds with a list of available targets and the portals through which the initiator can reach the target. The IP network configuration outside the MDS switch may result in only a subset of Gigabit Ethernet interfaces being reachable from the initiator. To ensure that the set of portals returned to the initiator is reachable, the iSNS server needs to know the set of Gigabit Ethernet interfaces that are reachable from a given initiator.

note.gif

Noteblank.gif iSNS Cloud Discovery is not supported on the Cisco Fabric Switch for IBM BladeCenter and Cisco Fabric Switch for HP c-Class BladeSystem.


The iSNS cloud discovery feature provides information to the iSNS server on the various interfaces reachable from an initiator by partitioning the interfaces on a switch into disjointed IP clouds. This discovery is achieved by sending messages to all other known IPS ports that are currently up and, depending on the response (or the lack of it), determines if the remote IPS port is in the same IP network or in a different IP network.

Cloud discovery is initiated when the following events occur:

  • Manual requests from the CLI initiate cloud discovery from the CLI. This action causes the destruction of existing memberships and makes new ones.
  • Auto-discovery of the interface results in an interface being assigned to its correct cloud. All other cloud members are not affected. The membership of each cloud is built incrementally and is initiated by the following events:

blank.gif A Gigabit Ethernet interface comes up. This can be a local or remote Gigabit Ethernet interface.

blank.gif The IP address of a Gigabit Ethernet interface changes.

blank.gif The VRRP configuration on a port changes.

The iSNS server distributes cloud and membership information across all the switches using CFS. Therefore, the cloud membership view is the same on all the switches in the fabric.

note.gif

Noteblank.gif For CFS distribution to operate correctly for iSNS cloud discovery, all switches in the fabric must be running Cisco SAN-OS Release 3.0(1) or NX-OS 4.1(1b) and later.


Configuring iSNS Cloud Discovery

This section describes how to configure iSNS cloud discovery and includes the following topics:

Enabling iSNS Cloud Discovery

To enable iSNS cloud discovery, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# cloud-discovery enable

Enables iSNS cloud discovery.

switch(config)# no cloud-discovery enable

Disables (default) iSNS cloud discovery.

To enable iSNS cloud discovery using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the Control tab and select enable from the Command drop-down menu for the cloud discovery feature.

Step 3blank.gif Click the Apply Changes icon to save this change.


 

Initiating On-Demand iSNS Cloud Discovery

To initiate on-demand iSNS cloud discovery, use the cloud discover command in EXEC mode.

The following example shows how to initiate on-demand cloud discovery for the entire fabric:

switch# cloud discover
 

To initiate on-demand iSNS cloud discovery using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the Cloud Discovery tab and check the Manual Discovery check box.

Step 3blank.gif Click the Apply Changes icon to save this change.


 

Configuring Automatic iSNS Cloud Discovery

To configure automatic iSNS cloud discovery, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# cloud discovery auto

Enables (default) automatic iSNS cloud discovery.

switch(config)# no cloud discovery auto

Disables automatic iSNS cloud discovery.

To configure automatic iSNS cloud discovery using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the Cloud Discovery tab and check the AutoDiscovery check box.

Step 3blank.gif Click the Apply Changes icon to save this change.


 

Verifying Automatic iSNS Cloud Discovery Configuration

To verify the automatic iSNS cloud discovery configuration, use the show cloud discovery config command:

switch# show cloud discovery config
Auto discovery: Enabled
 

Configuring iSNS Cloud Discovery Distribution

To configure iSNS cloud discovery distribution using CFS, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# cloud discovery fabric distribute

Enables (default) iSNS cloud discovery fabric distribution.

switch(config)# no cloud discovery fabric distribute

Disables iSNS cloud discovery fabric distribution.

To configure iSNS cloud discovery CFS distribution using Fabric Manager, follow these steps:


Step 1blank.gif Choose End Devices > iSNS.

You see the iSNS configuration in the Information pane.

Step 2blank.gif Click the CFS tab and select enable from the Admin drop-down menu for the cloud discovery feature.

Step 3blank.gif Select enable from the Global drop-down menu for the cloud discovery feature.

Step 4blank.gif Click the Apply Changes icon to save this change.


 

Configuring iSNS Cloud Discovery Message Types

You can configure iSNS cloud discovery the type of message to use. By default, iSNS cloud discovery uses ICMP.

To configure iSNS cloud discovery message types, follow these steps:

Command
Purpose

Step 1

switch# config terminal

switch(config)#

Enters configuration mode.

Step 2

switch(config)# cloud discovery message icmp

Enables (default) iSNS cloud discovery using ICMP messages.

Note Only ICMP messages are supported.

Verifying Cloud Discovery Status

Use the show cloud discovery status command to verify the status of the cloud discovery operation:

switch# show cloud discovery status
Discovery status: Succeeded
 

Verifying Cloud Discovery Membership

Use the show cloud membership all command to verify the cloud membership for the switch:

switch# show cloud membership all
Cloud 2
GigabitEthernet1/5[20:00:00:0d:ec:02:c6:c0] IP Addr 10.10.10.5
GigabitEthernet1/6[20:00:00:0d:ec:02:c6:c0] IP Addr 10.10.10.6
#members=2
 

Use the show cloud membership unresolved command to verify the unresolved membership on the switch:

switch# show cloud membership unresolved
Undiscovered Cloud
No members
 

Displaying Cloud Discovery Statistics

Use the show cloud discovery statistics command to display the statistics for the cloud discovery operation:

switch# show cloud discovery statistics
Global statistics
Number of Auto Discovery = 1
Number of Manual Discovery = 0
Number of cloud discovery (ping) messages sent = 1
Number of cloud discovery (ping) success = 1
 

Default Settings

Table 4-2 lists the default settings for iSCSI parameters.

 

Table 4-2 Default iSCSI Parameters

Parameters
Default

Number of TCP connections

One per iSCSI session

minimum-retransmit-time

300 msec

keepalive-timeout

60 seconds

max-retransmissions

4 retransmissions

PMTU discovery

Enabled

pmtu-enable reset-timeout

3600 sec

SACK

Enabled

max-bandwidth

1 Gbps

min-available-bandwidth

70 Mbps

round-trip-time

1 msec

Buffer size

4096 KB

Control TCP and data connection

No packets are transmitted

TCP congestion window monitoring

Enabled

Burst size

50 KB

Jitter

500 microseconds

TCP connection mode

Active mode is enabled

Fibre Channel targets to iSCSI

Not imported

Advertising iSCSI target

Advertised on all Gigabit Ethernet interfaces, subinterfaces, port channel interfaces, and port channel subinterfaces

iSCSI hosts mapping to virtual Fibre Channel hosts

Dynamic mapping

Dynamic iSCSI initiators

Members of the VSAN 1

Identifying initiators

iSCSI node names

Advertising static virtual targets

No initiators are allowed to access a virtual target (unless explicitly configured)

iSCSI login authentication

CHAP or none authentication mechanism

revert-primary-port

Disabled

Header and data digest

Enabled automatically when iSCSI initiators send requests. This feature cannot be configured and is not available in store-and-forward mode.

iSNS registration interval

60 sec (not configurable)

iSNS registration interval retries

3

Fabric distribution

Disabled

Table 4-3 lists the default settings for iSLB parameters.

 

Table 4-3 Default iSLB Parameters

Parameters
Default

Fabric distribution

Disabled

Load balancing metric

1000